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[/] [openrisc/] [trunk/] [gnu-old/] [gdb-7.1/] [opcodes/] [m32r-desc.c] - Blame information for rev 849

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Line No. Rev Author Line
1 227 jeremybenn
/* CPU data for m32r.
2
 
3
THIS FILE IS MACHINE GENERATED WITH CGEN.
4
 
5
Copyright 1996-2010 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 "m32r-desc.h"
32
#include "m32r-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
  { "m32r", MACH_M32R },
50
  { "m32rx", MACH_M32RX },
51
  { "m32r2", MACH_M32R2 },
52
  { "max", MACH_MAX },
53
  { 0, 0 }
54
};
55
 
56
static const CGEN_ATTR_ENTRY ISA_attr[] ATTRIBUTE_UNUSED =
57
{
58
  { "m32r", ISA_M32R },
59
  { "max", ISA_MAX },
60
  { 0, 0 }
61
};
62
 
63
static const CGEN_ATTR_ENTRY PIPE_attr[] ATTRIBUTE_UNUSED =
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
 
73
const 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
 
86
const 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
 
96
const 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
  { 0, 0, 0 }
109
};
110
 
111
const CGEN_ATTR_TABLE m32r_cgen_insn_attr_table[] =
112
{
113
  { "MACH", & MACH_attr[0], & MACH_attr[0] },
114
  { "PIPE", & PIPE_attr[0], & PIPE_attr[0] },
115
  { "ALIAS", &bool_attr[0], &bool_attr[0] },
116
  { "VIRTUAL", &bool_attr[0], &bool_attr[0] },
117
  { "UNCOND-CTI", &bool_attr[0], &bool_attr[0] },
118
  { "COND-CTI", &bool_attr[0], &bool_attr[0] },
119
  { "SKIP-CTI", &bool_attr[0], &bool_attr[0] },
120
  { "DELAY-SLOT", &bool_attr[0], &bool_attr[0] },
121
  { "RELAXABLE", &bool_attr[0], &bool_attr[0] },
122
  { "RELAXED", &bool_attr[0], &bool_attr[0] },
123
  { "NO-DIS", &bool_attr[0], &bool_attr[0] },
124
  { "PBB", &bool_attr[0], &bool_attr[0] },
125
  { "FILL-SLOT", &bool_attr[0], &bool_attr[0] },
126
  { "SPECIAL", &bool_attr[0], &bool_attr[0] },
127
  { "SPECIAL_M32R", &bool_attr[0], &bool_attr[0] },
128
  { "SPECIAL_FLOAT", &bool_attr[0], &bool_attr[0] },
129
  { 0, 0, 0 }
130
};
131
 
132
/* Instruction set variants.  */
133
 
134
static const CGEN_ISA m32r_cgen_isa_table[] = {
135
  { "m32r", 32, 32, 16, 32 },
136
  { 0, 0, 0, 0, 0 }
137
};
138
 
139
/* Machine variants.  */
140
 
141
static const CGEN_MACH m32r_cgen_mach_table[] = {
142
  { "m32r", "m32r", MACH_M32R, 0 },
143
  { "m32rx", "m32rx", MACH_M32RX, 0 },
144
  { "m32r2", "m32r2", MACH_M32R2, 0 },
145
  { 0, 0, 0, 0 }
146
};
147
 
148
static CGEN_KEYWORD_ENTRY m32r_cgen_opval_gr_names_entries[] =
149
{
150
  { "fp", 13, {0, {{{0, 0}}}}, 0, 0 },
151
  { "lr", 14, {0, {{{0, 0}}}}, 0, 0 },
152
  { "sp", 15, {0, {{{0, 0}}}}, 0, 0 },
153
  { "r0", 0, {0, {{{0, 0}}}}, 0, 0 },
154
  { "r1", 1, {0, {{{0, 0}}}}, 0, 0 },
155
  { "r2", 2, {0, {{{0, 0}}}}, 0, 0 },
156
  { "r3", 3, {0, {{{0, 0}}}}, 0, 0 },
157
  { "r4", 4, {0, {{{0, 0}}}}, 0, 0 },
158
  { "r5", 5, {0, {{{0, 0}}}}, 0, 0 },
159
  { "r6", 6, {0, {{{0, 0}}}}, 0, 0 },
160
  { "r7", 7, {0, {{{0, 0}}}}, 0, 0 },
161
  { "r8", 8, {0, {{{0, 0}}}}, 0, 0 },
162
  { "r9", 9, {0, {{{0, 0}}}}, 0, 0 },
163
  { "r10", 10, {0, {{{0, 0}}}}, 0, 0 },
164
  { "r11", 11, {0, {{{0, 0}}}}, 0, 0 },
165
  { "r12", 12, {0, {{{0, 0}}}}, 0, 0 },
166
  { "r13", 13, {0, {{{0, 0}}}}, 0, 0 },
167
  { "r14", 14, {0, {{{0, 0}}}}, 0, 0 },
168
  { "r15", 15, {0, {{{0, 0}}}}, 0, 0 }
169
};
170
 
171
CGEN_KEYWORD m32r_cgen_opval_gr_names =
172
{
173
  & m32r_cgen_opval_gr_names_entries[0],
174
  19,
175
  0, 0, 0, 0, ""
176
};
177
 
178
static CGEN_KEYWORD_ENTRY m32r_cgen_opval_cr_names_entries[] =
179
{
180
  { "psw", 0, {0, {{{0, 0}}}}, 0, 0 },
181
  { "cbr", 1, {0, {{{0, 0}}}}, 0, 0 },
182
  { "spi", 2, {0, {{{0, 0}}}}, 0, 0 },
183
  { "spu", 3, {0, {{{0, 0}}}}, 0, 0 },
184
  { "bpc", 6, {0, {{{0, 0}}}}, 0, 0 },
185
  { "bbpsw", 8, {0, {{{0, 0}}}}, 0, 0 },
186
  { "bbpc", 14, {0, {{{0, 0}}}}, 0, 0 },
187
  { "evb", 5, {0, {{{0, 0}}}}, 0, 0 },
188
  { "cr0", 0, {0, {{{0, 0}}}}, 0, 0 },
189
  { "cr1", 1, {0, {{{0, 0}}}}, 0, 0 },
190
  { "cr2", 2, {0, {{{0, 0}}}}, 0, 0 },
191
  { "cr3", 3, {0, {{{0, 0}}}}, 0, 0 },
192
  { "cr4", 4, {0, {{{0, 0}}}}, 0, 0 },
193
  { "cr5", 5, {0, {{{0, 0}}}}, 0, 0 },
194
  { "cr6", 6, {0, {{{0, 0}}}}, 0, 0 },
195
  { "cr7", 7, {0, {{{0, 0}}}}, 0, 0 },
196
  { "cr8", 8, {0, {{{0, 0}}}}, 0, 0 },
197
  { "cr9", 9, {0, {{{0, 0}}}}, 0, 0 },
198
  { "cr10", 10, {0, {{{0, 0}}}}, 0, 0 },
199
  { "cr11", 11, {0, {{{0, 0}}}}, 0, 0 },
200
  { "cr12", 12, {0, {{{0, 0}}}}, 0, 0 },
201
  { "cr13", 13, {0, {{{0, 0}}}}, 0, 0 },
202
  { "cr14", 14, {0, {{{0, 0}}}}, 0, 0 },
203
  { "cr15", 15, {0, {{{0, 0}}}}, 0, 0 }
204
};
205
 
206
CGEN_KEYWORD m32r_cgen_opval_cr_names =
207
{
208
  & m32r_cgen_opval_cr_names_entries[0],
209
  24,
210
  0, 0, 0, 0, ""
211
};
212
 
213
static CGEN_KEYWORD_ENTRY m32r_cgen_opval_h_accums_entries[] =
214
{
215
  { "a0", 0, {0, {{{0, 0}}}}, 0, 0 },
216
  { "a1", 1, {0, {{{0, 0}}}}, 0, 0 }
217
};
218
 
219
CGEN_KEYWORD m32r_cgen_opval_h_accums =
220
{
221
  & m32r_cgen_opval_h_accums_entries[0],
222
  2,
223
  0, 0, 0, 0, ""
224
};
225
 
226
 
227
/* The hardware table.  */
228
 
229
#define A(a) (1 << CGEN_HW_##a)
230
 
231
const CGEN_HW_ENTRY m32r_cgen_hw_table[] =
232
{
233
  { "h-memory", HW_H_MEMORY, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
234
  { "h-sint", HW_H_SINT, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
235
  { "h-uint", HW_H_UINT, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
236
  { "h-addr", HW_H_ADDR, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
237
  { "h-iaddr", HW_H_IADDR, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
238
  { "h-pc", HW_H_PC, CGEN_ASM_NONE, 0, { 0|A(PROFILE)|A(PC), { { { (1<<MACH_BASE), 0 } } } } },
239
  { "h-hi16", HW_H_HI16, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
240
  { "h-slo16", HW_H_SLO16, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
241
  { "h-ulo16", HW_H_ULO16, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
242
  { "h-gr", HW_H_GR, CGEN_ASM_KEYWORD, (PTR) & m32r_cgen_opval_gr_names, { 0|A(CACHE_ADDR)|A(PROFILE), { { { (1<<MACH_BASE), 0 } } } } },
243
  { "h-cr", HW_H_CR, CGEN_ASM_KEYWORD, (PTR) & m32r_cgen_opval_cr_names, { 0, { { { (1<<MACH_BASE), 0 } } } } },
244
  { "h-accum", HW_H_ACCUM, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
245
  { "h-accums", HW_H_ACCUMS, CGEN_ASM_KEYWORD, (PTR) & m32r_cgen_opval_h_accums, { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } } } } },
246
  { "h-cond", HW_H_COND, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
247
  { "h-psw", HW_H_PSW, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
248
  { "h-bpsw", HW_H_BPSW, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
249
  { "h-bbpsw", HW_H_BBPSW, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
250
  { "h-lock", HW_H_LOCK, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } },
251
  { 0, 0, CGEN_ASM_NONE, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } }
252
};
253
 
254
#undef A
255
 
256
 
257
/* The instruction field table.  */
258
 
259
#define A(a) (1 << CGEN_IFLD_##a)
260
 
261
const CGEN_IFLD m32r_cgen_ifld_table[] =
262
{
263
  { M32R_F_NIL, "f-nil", 0, 0, 0, 0, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
264
  { M32R_F_ANYOF, "f-anyof", 0, 0, 0, 0, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
265
  { M32R_F_OP1, "f-op1", 0, 32, 0, 4, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
266
  { M32R_F_OP2, "f-op2", 0, 32, 8, 4, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
267
  { M32R_F_COND, "f-cond", 0, 32, 4, 4, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
268
  { M32R_F_R1, "f-r1", 0, 32, 4, 4, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
269
  { M32R_F_R2, "f-r2", 0, 32, 12, 4, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
270
  { M32R_F_SIMM8, "f-simm8", 0, 32, 8, 8, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
271
  { M32R_F_SIMM16, "f-simm16", 0, 32, 16, 16, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
272
  { M32R_F_SHIFT_OP2, "f-shift-op2", 0, 32, 8, 3, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
273
  { M32R_F_UIMM3, "f-uimm3", 0, 32, 5, 3, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
274
  { M32R_F_UIMM4, "f-uimm4", 0, 32, 12, 4, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
275
  { M32R_F_UIMM5, "f-uimm5", 0, 32, 11, 5, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
276
  { M32R_F_UIMM8, "f-uimm8", 0, 32, 8, 8, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
277
  { M32R_F_UIMM16, "f-uimm16", 0, 32, 16, 16, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
278
  { M32R_F_UIMM24, "f-uimm24", 0, 32, 8, 24, { 0|A(RELOC)|A(ABS_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
279
  { M32R_F_HI16, "f-hi16", 0, 32, 16, 16, { 0|A(SIGN_OPT), { { { (1<<MACH_BASE), 0 } } } }  },
280
  { M32R_F_DISP8, "f-disp8", 0, 32, 8, 8, { 0|A(RELOC)|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
281
  { M32R_F_DISP16, "f-disp16", 0, 32, 16, 16, { 0|A(RELOC)|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
282
  { M32R_F_DISP24, "f-disp24", 0, 32, 8, 24, { 0|A(RELOC)|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
283
  { M32R_F_OP23, "f-op23", 0, 32, 9, 3, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
284
  { M32R_F_OP3, "f-op3", 0, 32, 14, 2, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
285
  { M32R_F_ACC, "f-acc", 0, 32, 8, 1, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
286
  { M32R_F_ACCS, "f-accs", 0, 32, 12, 2, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
287
  { M32R_F_ACCD, "f-accd", 0, 32, 4, 2, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
288
  { M32R_F_BITS67, "f-bits67", 0, 32, 6, 2, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
289
  { M32R_F_BIT4, "f-bit4", 0, 32, 4, 1, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
290
  { M32R_F_BIT14, "f-bit14", 0, 32, 14, 1, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
291
  { M32R_F_IMM1, "f-imm1", 0, 32, 15, 1, { 0, { { { (1<<MACH_BASE), 0 } } } }  },
292
  { 0, 0, 0, 0, 0, 0, { 0, { { { (1<<MACH_BASE), 0 } } } } }
293
};
294
 
295
#undef A
296
 
297
 
298
 
299
/* multi ifield declarations */
300
 
301
 
302
 
303
/* multi ifield definitions */
304
 
305
 
306
/* The operand table.  */
307
 
308
#define A(a) (1 << CGEN_OPERAND_##a)
309
#define OPERAND(op) M32R_OPERAND_##op
310
 
311
const CGEN_OPERAND m32r_cgen_operand_table[] =
312
{
313
/* pc: program counter */
314
  { "pc", M32R_OPERAND_PC, HW_H_PC, 0, 0,
315
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_NIL] } },
316
    { 0|A(SEM_ONLY), { { { (1<<MACH_BASE), 0 } } } }  },
317
/* sr: source register */
318
  { "sr", M32R_OPERAND_SR, HW_H_GR, 12, 4,
319
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R2] } },
320
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
321
/* dr: destination register */
322
  { "dr", M32R_OPERAND_DR, HW_H_GR, 4, 4,
323
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R1] } },
324
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
325
/* src1: source register 1 */
326
  { "src1", M32R_OPERAND_SRC1, HW_H_GR, 4, 4,
327
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R1] } },
328
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
329
/* src2: source register 2 */
330
  { "src2", M32R_OPERAND_SRC2, HW_H_GR, 12, 4,
331
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R2] } },
332
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
333
/* scr: source control register */
334
  { "scr", M32R_OPERAND_SCR, HW_H_CR, 12, 4,
335
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R2] } },
336
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
337
/* dcr: destination control register */
338
  { "dcr", M32R_OPERAND_DCR, HW_H_CR, 4, 4,
339
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_R1] } },
340
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
341
/* simm8: 8 bit signed immediate */
342
  { "simm8", M32R_OPERAND_SIMM8, HW_H_SINT, 8, 8,
343
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_SIMM8] } },
344
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
345
/* simm16: 16 bit signed immediate */
346
  { "simm16", M32R_OPERAND_SIMM16, HW_H_SINT, 16, 16,
347
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_SIMM16] } },
348
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
349
/* uimm3: 3 bit unsigned number */
350
  { "uimm3", M32R_OPERAND_UIMM3, HW_H_UINT, 5, 3,
351
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM3] } },
352
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
353
/* uimm4: 4 bit trap number */
354
  { "uimm4", M32R_OPERAND_UIMM4, HW_H_UINT, 12, 4,
355
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM4] } },
356
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
357
/* uimm5: 5 bit shift count */
358
  { "uimm5", M32R_OPERAND_UIMM5, HW_H_UINT, 11, 5,
359
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM5] } },
360
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
361
/* uimm8: 8 bit unsigned immediate */
362
  { "uimm8", M32R_OPERAND_UIMM8, HW_H_UINT, 8, 8,
363
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM8] } },
364
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
365
/* uimm16: 16 bit unsigned immediate */
366
  { "uimm16", M32R_OPERAND_UIMM16, HW_H_UINT, 16, 16,
367
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM16] } },
368
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
369
/* imm1: 1 bit immediate */
370
  { "imm1", M32R_OPERAND_IMM1, HW_H_UINT, 15, 1,
371
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_IMM1] } },
372
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } } } }  },
373
/* accd: accumulator destination register */
374
  { "accd", M32R_OPERAND_ACCD, HW_H_ACCUMS, 4, 2,
375
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_ACCD] } },
376
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } } } }  },
377
/* accs: accumulator source register */
378
  { "accs", M32R_OPERAND_ACCS, HW_H_ACCUMS, 12, 2,
379
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_ACCS] } },
380
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } } } }  },
381
/* acc: accumulator reg (d) */
382
  { "acc", M32R_OPERAND_ACC, HW_H_ACCUMS, 8, 1,
383
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_ACC] } },
384
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } } } }  },
385
/* hash: # prefix */
386
  { "hash", M32R_OPERAND_HASH, HW_H_SINT, 0, 0,
387
    { 0, { (const PTR) 0 } },
388
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
389
/* hi16: high 16 bit immediate, sign optional */
390
  { "hi16", M32R_OPERAND_HI16, HW_H_HI16, 16, 16,
391
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_HI16] } },
392
    { 0|A(SIGN_OPT), { { { (1<<MACH_BASE), 0 } } } }  },
393
/* slo16: 16 bit signed immediate, for low() */
394
  { "slo16", M32R_OPERAND_SLO16, HW_H_SLO16, 16, 16,
395
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_SIMM16] } },
396
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
397
/* ulo16: 16 bit unsigned immediate, for low() */
398
  { "ulo16", M32R_OPERAND_ULO16, HW_H_ULO16, 16, 16,
399
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM16] } },
400
    { 0, { { { (1<<MACH_BASE), 0 } } } }  },
401
/* uimm24: 24 bit address */
402
  { "uimm24", M32R_OPERAND_UIMM24, HW_H_ADDR, 8, 24,
403
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_UIMM24] } },
404
    { 0|A(RELOC)|A(ABS_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
405
/* disp8: 8 bit displacement */
406
  { "disp8", M32R_OPERAND_DISP8, HW_H_IADDR, 8, 8,
407
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_DISP8] } },
408
    { 0|A(RELAX)|A(RELOC)|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
409
/* disp16: 16 bit displacement */
410
  { "disp16", M32R_OPERAND_DISP16, HW_H_IADDR, 16, 16,
411
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_DISP16] } },
412
    { 0|A(RELOC)|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
413
/* disp24: 24 bit displacement */
414
  { "disp24", M32R_OPERAND_DISP24, HW_H_IADDR, 8, 24,
415
    { 0, { (const PTR) &m32r_cgen_ifld_table[M32R_F_DISP24] } },
416
    { 0|A(RELAX)|A(RELOC)|A(PCREL_ADDR), { { { (1<<MACH_BASE), 0 } } } }  },
417
/* condbit: condition bit */
418
  { "condbit", M32R_OPERAND_CONDBIT, HW_H_COND, 0, 0,
419
    { 0, { (const PTR) 0 } },
420
    { 0|A(SEM_ONLY), { { { (1<<MACH_BASE), 0 } } } }  },
421
/* accum: accumulator */
422
  { "accum", M32R_OPERAND_ACCUM, HW_H_ACCUM, 0, 0,
423
    { 0, { (const PTR) 0 } },
424
    { 0|A(SEM_ONLY), { { { (1<<MACH_BASE), 0 } } } }  },
425
/* sentinel */
426
  { 0, 0, 0, 0, 0,
427
    { 0, { (const PTR) 0 } },
428
    { 0, { { { (1<<MACH_BASE), 0 } } } } }
429
};
430
 
431
#undef A
432
 
433
 
434
/* The instruction table.  */
435
 
436
#define OP(field) CGEN_SYNTAX_MAKE_FIELD (OPERAND (field))
437
#define A(a) (1 << CGEN_INSN_##a)
438
 
439
static const CGEN_IBASE m32r_cgen_insn_table[MAX_INSNS] =
440
{
441
  /* Special null first entry.
442
     A `num' value of zero is thus invalid.
443
     Also, the special `invalid' insn resides here.  */
444
  { 0, 0, 0, 0, { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } } },
445
/* add $dr,$sr */
446
  {
447
    M32R_INSN_ADD, "add", "add", 16,
448
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
449
  },
450
/* add3 $dr,$sr,$hash$slo16 */
451
  {
452
    M32R_INSN_ADD3, "add3", "add3", 32,
453
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
454
  },
455
/* and $dr,$sr */
456
  {
457
    M32R_INSN_AND, "and", "and", 16,
458
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
459
  },
460
/* and3 $dr,$sr,$uimm16 */
461
  {
462
    M32R_INSN_AND3, "and3", "and3", 32,
463
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
464
  },
465
/* or $dr,$sr */
466
  {
467
    M32R_INSN_OR, "or", "or", 16,
468
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
469
  },
470
/* or3 $dr,$sr,$hash$ulo16 */
471
  {
472
    M32R_INSN_OR3, "or3", "or3", 32,
473
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
474
  },
475
/* xor $dr,$sr */
476
  {
477
    M32R_INSN_XOR, "xor", "xor", 16,
478
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
479
  },
480
/* xor3 $dr,$sr,$uimm16 */
481
  {
482
    M32R_INSN_XOR3, "xor3", "xor3", 32,
483
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
484
  },
485
/* addi $dr,$simm8 */
486
  {
487
    M32R_INSN_ADDI, "addi", "addi", 16,
488
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
489
  },
490
/* addv $dr,$sr */
491
  {
492
    M32R_INSN_ADDV, "addv", "addv", 16,
493
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
494
  },
495
/* addv3 $dr,$sr,$simm16 */
496
  {
497
    M32R_INSN_ADDV3, "addv3", "addv3", 32,
498
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
499
  },
500
/* addx $dr,$sr */
501
  {
502
    M32R_INSN_ADDX, "addx", "addx", 16,
503
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
504
  },
505
/* bc.s $disp8 */
506
  {
507
    M32R_INSN_BC8, "bc8", "bc.s", 16,
508
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
509
  },
510
/* bc.l $disp24 */
511
  {
512
    M32R_INSN_BC24, "bc24", "bc.l", 32,
513
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
514
  },
515
/* beq $src1,$src2,$disp16 */
516
  {
517
    M32R_INSN_BEQ, "beq", "beq", 32,
518
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
519
  },
520
/* beqz $src2,$disp16 */
521
  {
522
    M32R_INSN_BEQZ, "beqz", "beqz", 32,
523
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
524
  },
525
/* bgez $src2,$disp16 */
526
  {
527
    M32R_INSN_BGEZ, "bgez", "bgez", 32,
528
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
529
  },
530
/* bgtz $src2,$disp16 */
531
  {
532
    M32R_INSN_BGTZ, "bgtz", "bgtz", 32,
533
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
534
  },
535
/* blez $src2,$disp16 */
536
  {
537
    M32R_INSN_BLEZ, "blez", "blez", 32,
538
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
539
  },
540
/* bltz $src2,$disp16 */
541
  {
542
    M32R_INSN_BLTZ, "bltz", "bltz", 32,
543
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
544
  },
545
/* bnez $src2,$disp16 */
546
  {
547
    M32R_INSN_BNEZ, "bnez", "bnez", 32,
548
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
549
  },
550
/* bl.s $disp8 */
551
  {
552
    M32R_INSN_BL8, "bl8", "bl.s", 16,
553
    { 0|A(FILL_SLOT)|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
554
  },
555
/* bl.l $disp24 */
556
  {
557
    M32R_INSN_BL24, "bl24", "bl.l", 32,
558
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
559
  },
560
/* bcl.s $disp8 */
561
  {
562
    M32R_INSN_BCL8, "bcl8", "bcl.s", 16,
563
    { 0|A(FILL_SLOT)|A(COND_CTI), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_O, 0 } } } }
564
  },
565
/* bcl.l $disp24 */
566
  {
567
    M32R_INSN_BCL24, "bcl24", "bcl.l", 32,
568
    { 0|A(COND_CTI), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
569
  },
570
/* bnc.s $disp8 */
571
  {
572
    M32R_INSN_BNC8, "bnc8", "bnc.s", 16,
573
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
574
  },
575
/* bnc.l $disp24 */
576
  {
577
    M32R_INSN_BNC24, "bnc24", "bnc.l", 32,
578
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
579
  },
580
/* bne $src1,$src2,$disp16 */
581
  {
582
    M32R_INSN_BNE, "bne", "bne", 32,
583
    { 0|A(COND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
584
  },
585
/* bra.s $disp8 */
586
  {
587
    M32R_INSN_BRA8, "bra8", "bra.s", 16,
588
    { 0|A(FILL_SLOT)|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
589
  },
590
/* bra.l $disp24 */
591
  {
592
    M32R_INSN_BRA24, "bra24", "bra.l", 32,
593
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
594
  },
595
/* bncl.s $disp8 */
596
  {
597
    M32R_INSN_BNCL8, "bncl8", "bncl.s", 16,
598
    { 0|A(FILL_SLOT)|A(COND_CTI), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_O, 0 } } } }
599
  },
600
/* bncl.l $disp24 */
601
  {
602
    M32R_INSN_BNCL24, "bncl24", "bncl.l", 32,
603
    { 0|A(COND_CTI), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
604
  },
605
/* cmp $src1,$src2 */
606
  {
607
    M32R_INSN_CMP, "cmp", "cmp", 16,
608
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
609
  },
610
/* cmpi $src2,$simm16 */
611
  {
612
    M32R_INSN_CMPI, "cmpi", "cmpi", 32,
613
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
614
  },
615
/* cmpu $src1,$src2 */
616
  {
617
    M32R_INSN_CMPU, "cmpu", "cmpu", 16,
618
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
619
  },
620
/* cmpui $src2,$simm16 */
621
  {
622
    M32R_INSN_CMPUI, "cmpui", "cmpui", 32,
623
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
624
  },
625
/* cmpeq $src1,$src2 */
626
  {
627
    M32R_INSN_CMPEQ, "cmpeq", "cmpeq", 16,
628
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_OS, 0 } } } }
629
  },
630
/* cmpz $src2 */
631
  {
632
    M32R_INSN_CMPZ, "cmpz", "cmpz", 16,
633
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_OS, 0 } } } }
634
  },
635
/* div $dr,$sr */
636
  {
637
    M32R_INSN_DIV, "div", "div", 32,
638
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
639
  },
640
/* divu $dr,$sr */
641
  {
642
    M32R_INSN_DIVU, "divu", "divu", 32,
643
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
644
  },
645
/* rem $dr,$sr */
646
  {
647
    M32R_INSN_REM, "rem", "rem", 32,
648
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
649
  },
650
/* remu $dr,$sr */
651
  {
652
    M32R_INSN_REMU, "remu", "remu", 32,
653
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
654
  },
655
/* remh $dr,$sr */
656
  {
657
    M32R_INSN_REMH, "remh", "remh", 32,
658
    { 0, { { { (1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
659
  },
660
/* remuh $dr,$sr */
661
  {
662
    M32R_INSN_REMUH, "remuh", "remuh", 32,
663
    { 0, { { { (1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
664
  },
665
/* remb $dr,$sr */
666
  {
667
    M32R_INSN_REMB, "remb", "remb", 32,
668
    { 0, { { { (1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
669
  },
670
/* remub $dr,$sr */
671
  {
672
    M32R_INSN_REMUB, "remub", "remub", 32,
673
    { 0, { { { (1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
674
  },
675
/* divuh $dr,$sr */
676
  {
677
    M32R_INSN_DIVUH, "divuh", "divuh", 32,
678
    { 0, { { { (1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
679
  },
680
/* divb $dr,$sr */
681
  {
682
    M32R_INSN_DIVB, "divb", "divb", 32,
683
    { 0, { { { (1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
684
  },
685
/* divub $dr,$sr */
686
  {
687
    M32R_INSN_DIVUB, "divub", "divub", 32,
688
    { 0, { { { (1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
689
  },
690
/* divh $dr,$sr */
691
  {
692
    M32R_INSN_DIVH, "divh", "divh", 32,
693
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
694
  },
695
/* jc $sr */
696
  {
697
    M32R_INSN_JC, "jc", "jc", 16,
698
    { 0|A(SPECIAL)|A(COND_CTI), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_O, 0 } } } }
699
  },
700
/* jnc $sr */
701
  {
702
    M32R_INSN_JNC, "jnc", "jnc", 16,
703
    { 0|A(SPECIAL)|A(COND_CTI), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_O, 0 } } } }
704
  },
705
/* jl $sr */
706
  {
707
    M32R_INSN_JL, "jl", "jl", 16,
708
    { 0|A(FILL_SLOT)|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
709
  },
710
/* jmp $sr */
711
  {
712
    M32R_INSN_JMP, "jmp", "jmp", 16,
713
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
714
  },
715
/* ld $dr,@$sr */
716
  {
717
    M32R_INSN_LD, "ld", "ld", 16,
718
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
719
  },
720
/* ld $dr,@($slo16,$sr) */
721
  {
722
    M32R_INSN_LD_D, "ld-d", "ld", 32,
723
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
724
  },
725
/* ldb $dr,@$sr */
726
  {
727
    M32R_INSN_LDB, "ldb", "ldb", 16,
728
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
729
  },
730
/* ldb $dr,@($slo16,$sr) */
731
  {
732
    M32R_INSN_LDB_D, "ldb-d", "ldb", 32,
733
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
734
  },
735
/* ldh $dr,@$sr */
736
  {
737
    M32R_INSN_LDH, "ldh", "ldh", 16,
738
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
739
  },
740
/* ldh $dr,@($slo16,$sr) */
741
  {
742
    M32R_INSN_LDH_D, "ldh-d", "ldh", 32,
743
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
744
  },
745
/* ldub $dr,@$sr */
746
  {
747
    M32R_INSN_LDUB, "ldub", "ldub", 16,
748
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
749
  },
750
/* ldub $dr,@($slo16,$sr) */
751
  {
752
    M32R_INSN_LDUB_D, "ldub-d", "ldub", 32,
753
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
754
  },
755
/* lduh $dr,@$sr */
756
  {
757
    M32R_INSN_LDUH, "lduh", "lduh", 16,
758
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
759
  },
760
/* lduh $dr,@($slo16,$sr) */
761
  {
762
    M32R_INSN_LDUH_D, "lduh-d", "lduh", 32,
763
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
764
  },
765
/* ld $dr,@$sr+ */
766
  {
767
    M32R_INSN_LD_PLUS, "ld-plus", "ld", 16,
768
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
769
  },
770
/* ld24 $dr,$uimm24 */
771
  {
772
    M32R_INSN_LD24, "ld24", "ld24", 32,
773
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
774
  },
775
/* ldi8 $dr,$simm8 */
776
  {
777
    M32R_INSN_LDI8, "ldi8", "ldi8", 16,
778
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
779
  },
780
/* ldi16 $dr,$hash$slo16 */
781
  {
782
    M32R_INSN_LDI16, "ldi16", "ldi16", 32,
783
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
784
  },
785
/* lock $dr,@$sr */
786
  {
787
    M32R_INSN_LOCK, "lock", "lock", 16,
788
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
789
  },
790
/* machi $src1,$src2 */
791
  {
792
    M32R_INSN_MACHI, "machi", "machi", 16,
793
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
794
  },
795
/* machi $src1,$src2,$acc */
796
  {
797
    M32R_INSN_MACHI_A, "machi-a", "machi", 16,
798
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
799
  },
800
/* maclo $src1,$src2 */
801
  {
802
    M32R_INSN_MACLO, "maclo", "maclo", 16,
803
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
804
  },
805
/* maclo $src1,$src2,$acc */
806
  {
807
    M32R_INSN_MACLO_A, "maclo-a", "maclo", 16,
808
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
809
  },
810
/* macwhi $src1,$src2 */
811
  {
812
    M32R_INSN_MACWHI, "macwhi", "macwhi", 16,
813
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
814
  },
815
/* macwhi $src1,$src2,$acc */
816
  {
817
    M32R_INSN_MACWHI_A, "macwhi-a", "macwhi", 16,
818
    { 0|A(SPECIAL), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
819
  },
820
/* macwlo $src1,$src2 */
821
  {
822
    M32R_INSN_MACWLO, "macwlo", "macwlo", 16,
823
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
824
  },
825
/* macwlo $src1,$src2,$acc */
826
  {
827
    M32R_INSN_MACWLO_A, "macwlo-a", "macwlo", 16,
828
    { 0|A(SPECIAL), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
829
  },
830
/* mul $dr,$sr */
831
  {
832
    M32R_INSN_MUL, "mul", "mul", 16,
833
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_S, 0 } } } }
834
  },
835
/* mulhi $src1,$src2 */
836
  {
837
    M32R_INSN_MULHI, "mulhi", "mulhi", 16,
838
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
839
  },
840
/* mulhi $src1,$src2,$acc */
841
  {
842
    M32R_INSN_MULHI_A, "mulhi-a", "mulhi", 16,
843
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
844
  },
845
/* mullo $src1,$src2 */
846
  {
847
    M32R_INSN_MULLO, "mullo", "mullo", 16,
848
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
849
  },
850
/* mullo $src1,$src2,$acc */
851
  {
852
    M32R_INSN_MULLO_A, "mullo-a", "mullo", 16,
853
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
854
  },
855
/* mulwhi $src1,$src2 */
856
  {
857
    M32R_INSN_MULWHI, "mulwhi", "mulwhi", 16,
858
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
859
  },
860
/* mulwhi $src1,$src2,$acc */
861
  {
862
    M32R_INSN_MULWHI_A, "mulwhi-a", "mulwhi", 16,
863
    { 0|A(SPECIAL), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
864
  },
865
/* mulwlo $src1,$src2 */
866
  {
867
    M32R_INSN_MULWLO, "mulwlo", "mulwlo", 16,
868
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
869
  },
870
/* mulwlo $src1,$src2,$acc */
871
  {
872
    M32R_INSN_MULWLO_A, "mulwlo-a", "mulwlo", 16,
873
    { 0|A(SPECIAL), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
874
  },
875
/* mv $dr,$sr */
876
  {
877
    M32R_INSN_MV, "mv", "mv", 16,
878
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
879
  },
880
/* mvfachi $dr */
881
  {
882
    M32R_INSN_MVFACHI, "mvfachi", "mvfachi", 16,
883
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
884
  },
885
/* mvfachi $dr,$accs */
886
  {
887
    M32R_INSN_MVFACHI_A, "mvfachi-a", "mvfachi", 16,
888
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
889
  },
890
/* mvfaclo $dr */
891
  {
892
    M32R_INSN_MVFACLO, "mvfaclo", "mvfaclo", 16,
893
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
894
  },
895
/* mvfaclo $dr,$accs */
896
  {
897
    M32R_INSN_MVFACLO_A, "mvfaclo-a", "mvfaclo", 16,
898
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
899
  },
900
/* mvfacmi $dr */
901
  {
902
    M32R_INSN_MVFACMI, "mvfacmi", "mvfacmi", 16,
903
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
904
  },
905
/* mvfacmi $dr,$accs */
906
  {
907
    M32R_INSN_MVFACMI_A, "mvfacmi-a", "mvfacmi", 16,
908
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
909
  },
910
/* mvfc $dr,$scr */
911
  {
912
    M32R_INSN_MVFC, "mvfc", "mvfc", 16,
913
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
914
  },
915
/* mvtachi $src1 */
916
  {
917
    M32R_INSN_MVTACHI, "mvtachi", "mvtachi", 16,
918
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
919
  },
920
/* mvtachi $src1,$accs */
921
  {
922
    M32R_INSN_MVTACHI_A, "mvtachi-a", "mvtachi", 16,
923
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
924
  },
925
/* mvtaclo $src1 */
926
  {
927
    M32R_INSN_MVTACLO, "mvtaclo", "mvtaclo", 16,
928
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
929
  },
930
/* mvtaclo $src1,$accs */
931
  {
932
    M32R_INSN_MVTACLO_A, "mvtaclo-a", "mvtaclo", 16,
933
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
934
  },
935
/* mvtc $sr,$dcr */
936
  {
937
    M32R_INSN_MVTC, "mvtc", "mvtc", 16,
938
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
939
  },
940
/* neg $dr,$sr */
941
  {
942
    M32R_INSN_NEG, "neg", "neg", 16,
943
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
944
  },
945
/* nop */
946
  {
947
    M32R_INSN_NOP, "nop", "nop", 16,
948
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
949
  },
950
/* not $dr,$sr */
951
  {
952
    M32R_INSN_NOT, "not", "not", 16,
953
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
954
  },
955
/* rac */
956
  {
957
    M32R_INSN_RAC, "rac", "rac", 16,
958
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
959
  },
960
/* rac $accd,$accs,$imm1 */
961
  {
962
    M32R_INSN_RAC_DSI, "rac-dsi", "rac", 16,
963
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
964
  },
965
/* rach */
966
  {
967
    M32R_INSN_RACH, "rach", "rach", 16,
968
    { 0, { { { (1<<MACH_M32R), 0 } }, { { PIPE_S, 0 } } } }
969
  },
970
/* rach $accd,$accs,$imm1 */
971
  {
972
    M32R_INSN_RACH_DSI, "rach-dsi", "rach", 16,
973
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
974
  },
975
/* rte */
976
  {
977
    M32R_INSN_RTE, "rte", "rte", 16,
978
    { 0|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
979
  },
980
/* seth $dr,$hash$hi16 */
981
  {
982
    M32R_INSN_SETH, "seth", "seth", 32,
983
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
984
  },
985
/* sll $dr,$sr */
986
  {
987
    M32R_INSN_SLL, "sll", "sll", 16,
988
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O_OS, 0 } } } }
989
  },
990
/* sll3 $dr,$sr,$simm16 */
991
  {
992
    M32R_INSN_SLL3, "sll3", "sll3", 32,
993
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
994
  },
995
/* slli $dr,$uimm5 */
996
  {
997
    M32R_INSN_SLLI, "slli", "slli", 16,
998
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O_OS, 0 } } } }
999
  },
1000
/* sra $dr,$sr */
1001
  {
1002
    M32R_INSN_SRA, "sra", "sra", 16,
1003
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O_OS, 0 } } } }
1004
  },
1005
/* sra3 $dr,$sr,$simm16 */
1006
  {
1007
    M32R_INSN_SRA3, "sra3", "sra3", 32,
1008
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
1009
  },
1010
/* srai $dr,$uimm5 */
1011
  {
1012
    M32R_INSN_SRAI, "srai", "srai", 16,
1013
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O_OS, 0 } } } }
1014
  },
1015
/* srl $dr,$sr */
1016
  {
1017
    M32R_INSN_SRL, "srl", "srl", 16,
1018
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O_OS, 0 } } } }
1019
  },
1020
/* srl3 $dr,$sr,$simm16 */
1021
  {
1022
    M32R_INSN_SRL3, "srl3", "srl3", 32,
1023
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
1024
  },
1025
/* srli $dr,$uimm5 */
1026
  {
1027
    M32R_INSN_SRLI, "srli", "srli", 16,
1028
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O_OS, 0 } } } }
1029
  },
1030
/* st $src1,@$src2 */
1031
  {
1032
    M32R_INSN_ST, "st", "st", 16,
1033
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1034
  },
1035
/* st $src1,@($slo16,$src2) */
1036
  {
1037
    M32R_INSN_ST_D, "st-d", "st", 32,
1038
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
1039
  },
1040
/* stb $src1,@$src2 */
1041
  {
1042
    M32R_INSN_STB, "stb", "stb", 16,
1043
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1044
  },
1045
/* stb $src1,@($slo16,$src2) */
1046
  {
1047
    M32R_INSN_STB_D, "stb-d", "stb", 32,
1048
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
1049
  },
1050
/* sth $src1,@$src2 */
1051
  {
1052
    M32R_INSN_STH, "sth", "sth", 16,
1053
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1054
  },
1055
/* sth $src1,@($slo16,$src2) */
1056
  {
1057
    M32R_INSN_STH_D, "sth-d", "sth", 32,
1058
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
1059
  },
1060
/* st $src1,@+$src2 */
1061
  {
1062
    M32R_INSN_ST_PLUS, "st-plus", "st", 16,
1063
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1064
  },
1065
/* sth $src1,@$src2+ */
1066
  {
1067
    M32R_INSN_STH_PLUS, "sth-plus", "sth", 16,
1068
    { 0|A(SPECIAL), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_O, 0 } } } }
1069
  },
1070
/* stb $src1,@$src2+ */
1071
  {
1072
    M32R_INSN_STB_PLUS, "stb-plus", "stb", 16,
1073
    { 0|A(SPECIAL), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_O, 0 } } } }
1074
  },
1075
/* st $src1,@-$src2 */
1076
  {
1077
    M32R_INSN_ST_MINUS, "st-minus", "st", 16,
1078
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1079
  },
1080
/* sub $dr,$sr */
1081
  {
1082
    M32R_INSN_SUB, "sub", "sub", 16,
1083
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
1084
  },
1085
/* subv $dr,$sr */
1086
  {
1087
    M32R_INSN_SUBV, "subv", "subv", 16,
1088
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
1089
  },
1090
/* subx $dr,$sr */
1091
  {
1092
    M32R_INSN_SUBX, "subx", "subx", 16,
1093
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_OS, 0 } } } }
1094
  },
1095
/* trap $uimm4 */
1096
  {
1097
    M32R_INSN_TRAP, "trap", "trap", 16,
1098
    { 0|A(FILL_SLOT)|A(UNCOND_CTI), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1099
  },
1100
/* unlock $src1,@$src2 */
1101
  {
1102
    M32R_INSN_UNLOCK, "unlock", "unlock", 16,
1103
    { 0, { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1104
  },
1105
/* satb $dr,$sr */
1106
  {
1107
    M32R_INSN_SATB, "satb", "satb", 32,
1108
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
1109
  },
1110
/* sath $dr,$sr */
1111
  {
1112
    M32R_INSN_SATH, "sath", "sath", 32,
1113
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
1114
  },
1115
/* sat $dr,$sr */
1116
  {
1117
    M32R_INSN_SAT, "sat", "sat", 32,
1118
    { 0|A(SPECIAL), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_NONE, 0 } } } }
1119
  },
1120
/* pcmpbz $src2 */
1121
  {
1122
    M32R_INSN_PCMPBZ, "pcmpbz", "pcmpbz", 16,
1123
    { 0|A(SPECIAL), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_OS, 0 } } } }
1124
  },
1125
/* sadd */
1126
  {
1127
    M32R_INSN_SADD, "sadd", "sadd", 16,
1128
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
1129
  },
1130
/* macwu1 $src1,$src2 */
1131
  {
1132
    M32R_INSN_MACWU1, "macwu1", "macwu1", 16,
1133
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
1134
  },
1135
/* msblo $src1,$src2 */
1136
  {
1137
    M32R_INSN_MSBLO, "msblo", "msblo", 16,
1138
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
1139
  },
1140
/* mulwu1 $src1,$src2 */
1141
  {
1142
    M32R_INSN_MULWU1, "mulwu1", "mulwu1", 16,
1143
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
1144
  },
1145
/* maclh1 $src1,$src2 */
1146
  {
1147
    M32R_INSN_MACLH1, "maclh1", "maclh1", 16,
1148
    { 0, { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_S, 0 } } } }
1149
  },
1150
/* sc */
1151
  {
1152
    M32R_INSN_SC, "sc", "sc", 16,
1153
    { 0|A(SPECIAL)|A(SKIP_CTI), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_O, 0 } } } }
1154
  },
1155
/* snc */
1156
  {
1157
    M32R_INSN_SNC, "snc", "snc", 16,
1158
    { 0|A(SPECIAL)|A(SKIP_CTI), { { { (1<<MACH_M32RX)|(1<<MACH_M32R2), 0 } }, { { PIPE_O, 0 } } } }
1159
  },
1160
/* clrpsw $uimm8 */
1161
  {
1162
    M32R_INSN_CLRPSW, "clrpsw", "clrpsw", 16,
1163
    { 0|A(SPECIAL_M32R), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1164
  },
1165
/* setpsw $uimm8 */
1166
  {
1167
    M32R_INSN_SETPSW, "setpsw", "setpsw", 16,
1168
    { 0|A(SPECIAL_M32R), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1169
  },
1170
/* bset $uimm3,@($slo16,$sr) */
1171
  {
1172
    M32R_INSN_BSET, "bset", "bset", 32,
1173
    { 0|A(SPECIAL_M32R), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
1174
  },
1175
/* bclr $uimm3,@($slo16,$sr) */
1176
  {
1177
    M32R_INSN_BCLR, "bclr", "bclr", 32,
1178
    { 0|A(SPECIAL_M32R), { { { (1<<MACH_BASE), 0 } }, { { PIPE_NONE, 0 } } } }
1179
  },
1180
/* btst $uimm3,$sr */
1181
  {
1182
    M32R_INSN_BTST, "btst", "btst", 16,
1183
    { 0|A(SPECIAL_M32R), { { { (1<<MACH_BASE), 0 } }, { { PIPE_O, 0 } } } }
1184
  },
1185
};
1186
 
1187
#undef OP
1188
#undef A
1189
 
1190
/* Initialize anything needed to be done once, before any cpu_open call.  */
1191
 
1192
static void
1193
init_tables (void)
1194
{
1195
}
1196
 
1197
static const CGEN_MACH * lookup_mach_via_bfd_name (const CGEN_MACH *, const char *);
1198
static void build_hw_table      (CGEN_CPU_TABLE *);
1199
static void build_ifield_table  (CGEN_CPU_TABLE *);
1200
static void build_operand_table (CGEN_CPU_TABLE *);
1201
static void build_insn_table    (CGEN_CPU_TABLE *);
1202
static void m32r_cgen_rebuild_tables (CGEN_CPU_TABLE *);
1203
 
1204
/* Subroutine of m32r_cgen_cpu_open to look up a mach via its bfd name.  */
1205
 
1206
static const CGEN_MACH *
1207
lookup_mach_via_bfd_name (const CGEN_MACH *table, const char *name)
1208
{
1209
  while (table->name)
1210
    {
1211
      if (strcmp (name, table->bfd_name) == 0)
1212
        return table;
1213
      ++table;
1214
    }
1215
  abort ();
1216
}
1217
 
1218
/* Subroutine of m32r_cgen_cpu_open to build the hardware table.  */
1219
 
1220
static void
1221
build_hw_table (CGEN_CPU_TABLE *cd)
1222
{
1223
  int i;
1224
  int machs = cd->machs;
1225
  const CGEN_HW_ENTRY *init = & m32r_cgen_hw_table[0];
1226
  /* MAX_HW is only an upper bound on the number of selected entries.
1227
     However each entry is indexed by it's enum so there can be holes in
1228
     the table.  */
1229
  const CGEN_HW_ENTRY **selected =
1230
    (const CGEN_HW_ENTRY **) xmalloc (MAX_HW * sizeof (CGEN_HW_ENTRY *));
1231
 
1232
  cd->hw_table.init_entries = init;
1233
  cd->hw_table.entry_size = sizeof (CGEN_HW_ENTRY);
1234
  memset (selected, 0, MAX_HW * sizeof (CGEN_HW_ENTRY *));
1235
  /* ??? For now we just use machs to determine which ones we want.  */
1236
  for (i = 0; init[i].name != NULL; ++i)
1237
    if (CGEN_HW_ATTR_VALUE (&init[i], CGEN_HW_MACH)
1238
        & machs)
1239
      selected[init[i].type] = &init[i];
1240
  cd->hw_table.entries = selected;
1241
  cd->hw_table.num_entries = MAX_HW;
1242
}
1243
 
1244
/* Subroutine of m32r_cgen_cpu_open to build the hardware table.  */
1245
 
1246
static void
1247
build_ifield_table (CGEN_CPU_TABLE *cd)
1248
{
1249
  cd->ifld_table = & m32r_cgen_ifld_table[0];
1250
}
1251
 
1252
/* Subroutine of m32r_cgen_cpu_open to build the hardware table.  */
1253
 
1254
static void
1255
build_operand_table (CGEN_CPU_TABLE *cd)
1256
{
1257
  int i;
1258
  int machs = cd->machs;
1259
  const CGEN_OPERAND *init = & m32r_cgen_operand_table[0];
1260
  /* MAX_OPERANDS is only an upper bound on the number of selected entries.
1261
     However each entry is indexed by it's enum so there can be holes in
1262
     the table.  */
1263
  const CGEN_OPERAND **selected = xmalloc (MAX_OPERANDS * sizeof (* selected));
1264
 
1265
  cd->operand_table.init_entries = init;
1266
  cd->operand_table.entry_size = sizeof (CGEN_OPERAND);
1267
  memset (selected, 0, MAX_OPERANDS * sizeof (CGEN_OPERAND *));
1268
  /* ??? For now we just use mach to determine which ones we want.  */
1269
  for (i = 0; init[i].name != NULL; ++i)
1270
    if (CGEN_OPERAND_ATTR_VALUE (&init[i], CGEN_OPERAND_MACH)
1271
        & machs)
1272
      selected[init[i].type] = &init[i];
1273
  cd->operand_table.entries = selected;
1274
  cd->operand_table.num_entries = MAX_OPERANDS;
1275
}
1276
 
1277
/* Subroutine of m32r_cgen_cpu_open to build the hardware table.
1278
   ??? This could leave out insns not supported by the specified mach/isa,
1279
   but that would cause errors like "foo only supported by bar" to become
1280
   "unknown insn", so for now we include all insns and require the app to
1281
   do the checking later.
1282
   ??? On the other hand, parsing of such insns may require their hardware or
1283
   operand elements to be in the table [which they mightn't be].  */
1284
 
1285
static void
1286
build_insn_table (CGEN_CPU_TABLE *cd)
1287
{
1288
  int i;
1289
  const CGEN_IBASE *ib = & m32r_cgen_insn_table[0];
1290
  CGEN_INSN *insns = xmalloc (MAX_INSNS * sizeof (CGEN_INSN));
1291
 
1292
  memset (insns, 0, MAX_INSNS * sizeof (CGEN_INSN));
1293
  for (i = 0; i < MAX_INSNS; ++i)
1294
    insns[i].base = &ib[i];
1295
  cd->insn_table.init_entries = insns;
1296
  cd->insn_table.entry_size = sizeof (CGEN_IBASE);
1297
  cd->insn_table.num_init_entries = MAX_INSNS;
1298
}
1299
 
1300
/* Subroutine of m32r_cgen_cpu_open to rebuild the tables.  */
1301
 
1302
static void
1303
m32r_cgen_rebuild_tables (CGEN_CPU_TABLE *cd)
1304
{
1305
  int i;
1306
  CGEN_BITSET *isas = cd->isas;
1307
  unsigned int machs = cd->machs;
1308
 
1309
  cd->int_insn_p = CGEN_INT_INSN_P;
1310
 
1311
  /* Data derived from the isa spec.  */
1312
#define UNSET (CGEN_SIZE_UNKNOWN + 1)
1313
  cd->default_insn_bitsize = UNSET;
1314
  cd->base_insn_bitsize = UNSET;
1315
  cd->min_insn_bitsize = 65535; /* Some ridiculously big number.  */
1316
  cd->max_insn_bitsize = 0;
1317
  for (i = 0; i < MAX_ISAS; ++i)
1318
    if (cgen_bitset_contains (isas, i))
1319
      {
1320
        const CGEN_ISA *isa = & m32r_cgen_isa_table[i];
1321
 
1322
        /* Default insn sizes of all selected isas must be
1323
           equal or we set the result to 0, meaning "unknown".  */
1324
        if (cd->default_insn_bitsize == UNSET)
1325
          cd->default_insn_bitsize = isa->default_insn_bitsize;
1326
        else if (isa->default_insn_bitsize == cd->default_insn_bitsize)
1327
          ; /* This is ok.  */
1328
        else
1329
          cd->default_insn_bitsize = CGEN_SIZE_UNKNOWN;
1330
 
1331
        /* Base insn sizes of all selected isas must be equal
1332
           or we set the result to 0, meaning "unknown".  */
1333
        if (cd->base_insn_bitsize == UNSET)
1334
          cd->base_insn_bitsize = isa->base_insn_bitsize;
1335
        else if (isa->base_insn_bitsize == cd->base_insn_bitsize)
1336
          ; /* This is ok.  */
1337
        else
1338
          cd->base_insn_bitsize = CGEN_SIZE_UNKNOWN;
1339
 
1340
        /* Set min,max insn sizes.  */
1341
        if (isa->min_insn_bitsize < cd->min_insn_bitsize)
1342
          cd->min_insn_bitsize = isa->min_insn_bitsize;
1343
        if (isa->max_insn_bitsize > cd->max_insn_bitsize)
1344
          cd->max_insn_bitsize = isa->max_insn_bitsize;
1345
      }
1346
 
1347
  /* Data derived from the mach spec.  */
1348
  for (i = 0; i < MAX_MACHS; ++i)
1349
    if (((1 << i) & machs) != 0)
1350
      {
1351
        const CGEN_MACH *mach = & m32r_cgen_mach_table[i];
1352
 
1353
        if (mach->insn_chunk_bitsize != 0)
1354
        {
1355
          if (cd->insn_chunk_bitsize != 0 && cd->insn_chunk_bitsize != mach->insn_chunk_bitsize)
1356
            {
1357
              fprintf (stderr, "m32r_cgen_rebuild_tables: conflicting insn-chunk-bitsize values: `%d' vs. `%d'\n",
1358
                       cd->insn_chunk_bitsize, mach->insn_chunk_bitsize);
1359
              abort ();
1360
            }
1361
 
1362
          cd->insn_chunk_bitsize = mach->insn_chunk_bitsize;
1363
        }
1364
      }
1365
 
1366
  /* Determine which hw elements are used by MACH.  */
1367
  build_hw_table (cd);
1368
 
1369
  /* Build the ifield table.  */
1370
  build_ifield_table (cd);
1371
 
1372
  /* Determine which operands are used by MACH/ISA.  */
1373
  build_operand_table (cd);
1374
 
1375
  /* Build the instruction table.  */
1376
  build_insn_table (cd);
1377
}
1378
 
1379
/* Initialize a cpu table and return a descriptor.
1380
   It's much like opening a file, and must be the first function called.
1381
   The arguments are a set of (type/value) pairs, terminated with
1382
   CGEN_CPU_OPEN_END.
1383
 
1384
   Currently supported values:
1385
   CGEN_CPU_OPEN_ISAS:    bitmap of values in enum isa_attr
1386
   CGEN_CPU_OPEN_MACHS:   bitmap of values in enum mach_attr
1387
   CGEN_CPU_OPEN_BFDMACH: specify 1 mach using bfd name
1388
   CGEN_CPU_OPEN_ENDIAN:  specify endian choice
1389
   CGEN_CPU_OPEN_END:     terminates arguments
1390
 
1391
   ??? Simultaneous multiple isas might not make sense, but it's not (yet)
1392
   precluded.  */
1393
 
1394
CGEN_CPU_DESC
1395
m32r_cgen_cpu_open (enum cgen_cpu_open_arg arg_type, ...)
1396
{
1397
  CGEN_CPU_TABLE *cd = (CGEN_CPU_TABLE *) xmalloc (sizeof (CGEN_CPU_TABLE));
1398
  static int init_p;
1399
  CGEN_BITSET *isas = 0;  /* 0 = "unspecified" */
1400
  unsigned int machs = 0; /* 0 = "unspecified" */
1401
  enum cgen_endian endian = CGEN_ENDIAN_UNKNOWN;
1402
  va_list ap;
1403
 
1404
  if (! init_p)
1405
    {
1406
      init_tables ();
1407
      init_p = 1;
1408
    }
1409
 
1410
  memset (cd, 0, sizeof (*cd));
1411
 
1412
  va_start (ap, arg_type);
1413
  while (arg_type != CGEN_CPU_OPEN_END)
1414
    {
1415
      switch (arg_type)
1416
        {
1417
        case CGEN_CPU_OPEN_ISAS :
1418
          isas = va_arg (ap, CGEN_BITSET *);
1419
          break;
1420
        case CGEN_CPU_OPEN_MACHS :
1421
          machs = va_arg (ap, unsigned int);
1422
          break;
1423
        case CGEN_CPU_OPEN_BFDMACH :
1424
          {
1425
            const char *name = va_arg (ap, const char *);
1426
            const CGEN_MACH *mach =
1427
              lookup_mach_via_bfd_name (m32r_cgen_mach_table, name);
1428
 
1429
            machs |= 1 << mach->num;
1430
            break;
1431
          }
1432
        case CGEN_CPU_OPEN_ENDIAN :
1433
          endian = va_arg (ap, enum cgen_endian);
1434
          break;
1435
        default :
1436
          fprintf (stderr, "m32r_cgen_cpu_open: unsupported argument `%d'\n",
1437
                   arg_type);
1438
          abort (); /* ??? return NULL? */
1439
        }
1440
      arg_type = va_arg (ap, enum cgen_cpu_open_arg);
1441
    }
1442
  va_end (ap);
1443
 
1444
  /* Mach unspecified means "all".  */
1445
  if (machs == 0)
1446
    machs = (1 << MAX_MACHS) - 1;
1447
  /* Base mach is always selected.  */
1448
  machs |= 1;
1449
  if (endian == CGEN_ENDIAN_UNKNOWN)
1450
    {
1451
      /* ??? If target has only one, could have a default.  */
1452
      fprintf (stderr, "m32r_cgen_cpu_open: no endianness specified\n");
1453
      abort ();
1454
    }
1455
 
1456
  cd->isas = cgen_bitset_copy (isas);
1457
  cd->machs = machs;
1458
  cd->endian = endian;
1459
  /* FIXME: for the sparc case we can determine insn-endianness statically.
1460
     The worry here is where both data and insn endian can be independently
1461
     chosen, in which case this function will need another argument.
1462
     Actually, will want to allow for more arguments in the future anyway.  */
1463
  cd->insn_endian = endian;
1464
 
1465
  /* Table (re)builder.  */
1466
  cd->rebuild_tables = m32r_cgen_rebuild_tables;
1467
  m32r_cgen_rebuild_tables (cd);
1468
 
1469
  /* Default to not allowing signed overflow.  */
1470
  cd->signed_overflow_ok_p = 0;
1471
 
1472
  return (CGEN_CPU_DESC) cd;
1473
}
1474
 
1475
/* Cover fn to m32r_cgen_cpu_open to handle the simple case of 1 isa, 1 mach.
1476
   MACH_NAME is the bfd name of the mach.  */
1477
 
1478
CGEN_CPU_DESC
1479
m32r_cgen_cpu_open_1 (const char *mach_name, enum cgen_endian endian)
1480
{
1481
  return m32r_cgen_cpu_open (CGEN_CPU_OPEN_BFDMACH, mach_name,
1482
                               CGEN_CPU_OPEN_ENDIAN, endian,
1483
                               CGEN_CPU_OPEN_END);
1484
}
1485
 
1486
/* Close a cpu table.
1487
   ??? This can live in a machine independent file, but there's currently
1488
   no place to put this file (there's no libcgen).  libopcodes is the wrong
1489
   place as some simulator ports use this but they don't use libopcodes.  */
1490
 
1491
void
1492
m32r_cgen_cpu_close (CGEN_CPU_DESC cd)
1493
{
1494
  unsigned int i;
1495
  const CGEN_INSN *insns;
1496
 
1497
  if (cd->macro_insn_table.init_entries)
1498
    {
1499
      insns = cd->macro_insn_table.init_entries;
1500
      for (i = 0; i < cd->macro_insn_table.num_init_entries; ++i, ++insns)
1501
        if (CGEN_INSN_RX ((insns)))
1502
          regfree (CGEN_INSN_RX (insns));
1503
    }
1504
 
1505
  if (cd->insn_table.init_entries)
1506
    {
1507
      insns = cd->insn_table.init_entries;
1508
      for (i = 0; i < cd->insn_table.num_init_entries; ++i, ++insns)
1509
        if (CGEN_INSN_RX (insns))
1510
          regfree (CGEN_INSN_RX (insns));
1511
    }
1512
 
1513
  if (cd->macro_insn_table.init_entries)
1514
    free ((CGEN_INSN *) cd->macro_insn_table.init_entries);
1515
 
1516
  if (cd->insn_table.init_entries)
1517
    free ((CGEN_INSN *) cd->insn_table.init_entries);
1518
 
1519
  if (cd->hw_table.entries)
1520
    free ((CGEN_HW_ENTRY *) cd->hw_table.entries);
1521
 
1522
  if (cd->operand_table.entries)
1523
    free ((CGEN_HW_ENTRY *) cd->operand_table.entries);
1524
 
1525
  free (cd);
1526
}
1527
 

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