3 THIS FILE IS MACHINE GENERATED WITH CGEN.
5 Copyright 1996, 1997, 1998, 1999, 2000, 2001 Free Software Foundation, Inc.
7 This file is part of the GNU Binutils and/or GDB, the GNU debugger.
9 This program 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 2, or (at your option)
14 This program is distributed in the hope that it will be useful,
15 but WITHOUT ANY WARRANTY; without even the implied warranty of
16 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17 GNU General Public License for more details.
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 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
32 #include "fr30-desc.h"
35 #include "libiberty.h"
39 static const CGEN_ATTR_ENTRY bool_attr
[] =
46 static const CGEN_ATTR_ENTRY MACH_attr
[] =
48 { "base", MACH_BASE
},
49 { "fr30", MACH_FR30
},
54 static const CGEN_ATTR_ENTRY ISA_attr
[] =
61 const CGEN_ATTR_TABLE fr30_cgen_ifield_attr_table
[] =
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] },
73 const CGEN_ATTR_TABLE fr30_cgen_hardware_attr_table
[] =
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] },
83 const CGEN_ATTR_TABLE fr30_cgen_operand_attr_table
[] =
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 { "HASH-PREFIX", &bool_attr
[0], &bool_attr
[0] },
98 const CGEN_ATTR_TABLE fr30_cgen_insn_attr_table
[] =
100 { "MACH", & MACH_attr
[0], & MACH_attr
[0] },
101 { "ALIAS", &bool_attr
[0], &bool_attr
[0] },
102 { "VIRTUAL", &bool_attr
[0], &bool_attr
[0] },
103 { "UNCOND-CTI", &bool_attr
[0], &bool_attr
[0] },
104 { "COND-CTI", &bool_attr
[0], &bool_attr
[0] },
105 { "SKIP-CTI", &bool_attr
[0], &bool_attr
[0] },
106 { "DELAY-SLOT", &bool_attr
[0], &bool_attr
[0] },
107 { "RELAXABLE", &bool_attr
[0], &bool_attr
[0] },
108 { "RELAX", &bool_attr
[0], &bool_attr
[0] },
109 { "NO-DIS", &bool_attr
[0], &bool_attr
[0] },
110 { "PBB", &bool_attr
[0], &bool_attr
[0] },
111 { "NOT-IN-DELAY-SLOT", &bool_attr
[0], &bool_attr
[0] },
115 /* Instruction set variants. */
117 static const CGEN_ISA fr30_cgen_isa_table
[] = {
118 { "fr30", 16, 16, 16, 48 },
122 /* Machine variants. */
124 static const CGEN_MACH fr30_cgen_mach_table
[] = {
125 { "fr30", "fr30", MACH_FR30
},
129 static CGEN_KEYWORD_ENTRY fr30_cgen_opval_gr_names_entries
[] =
131 { "r0", 0, {0, {0}}, 0, 0 },
132 { "r1", 1, {0, {0}}, 0, 0 },
133 { "r2", 2, {0, {0}}, 0, 0 },
134 { "r3", 3, {0, {0}}, 0, 0 },
135 { "r4", 4, {0, {0}}, 0, 0 },
136 { "r5", 5, {0, {0}}, 0, 0 },
137 { "r6", 6, {0, {0}}, 0, 0 },
138 { "r7", 7, {0, {0}}, 0, 0 },
139 { "r8", 8, {0, {0}}, 0, 0 },
140 { "r9", 9, {0, {0}}, 0, 0 },
141 { "r10", 10, {0, {0}}, 0, 0 },
142 { "r11", 11, {0, {0}}, 0, 0 },
143 { "r12", 12, {0, {0}}, 0, 0 },
144 { "r13", 13, {0, {0}}, 0, 0 },
145 { "r14", 14, {0, {0}}, 0, 0 },
146 { "r15", 15, {0, {0}}, 0, 0 },
147 { "ac", 13, {0, {0}}, 0, 0 },
148 { "fp", 14, {0, {0}}, 0, 0 },
149 { "sp", 15, {0, {0}}, 0, 0 }
152 CGEN_KEYWORD fr30_cgen_opval_gr_names
=
154 & fr30_cgen_opval_gr_names_entries
[0],
159 static CGEN_KEYWORD_ENTRY fr30_cgen_opval_cr_names_entries
[] =
161 { "cr0", 0, {0, {0}}, 0, 0 },
162 { "cr1", 1, {0, {0}}, 0, 0 },
163 { "cr2", 2, {0, {0}}, 0, 0 },
164 { "cr3", 3, {0, {0}}, 0, 0 },
165 { "cr4", 4, {0, {0}}, 0, 0 },
166 { "cr5", 5, {0, {0}}, 0, 0 },
167 { "cr6", 6, {0, {0}}, 0, 0 },
168 { "cr7", 7, {0, {0}}, 0, 0 },
169 { "cr8", 8, {0, {0}}, 0, 0 },
170 { "cr9", 9, {0, {0}}, 0, 0 },
171 { "cr10", 10, {0, {0}}, 0, 0 },
172 { "cr11", 11, {0, {0}}, 0, 0 },
173 { "cr12", 12, {0, {0}}, 0, 0 },
174 { "cr13", 13, {0, {0}}, 0, 0 },
175 { "cr14", 14, {0, {0}}, 0, 0 },
176 { "cr15", 15, {0, {0}}, 0, 0 }
179 CGEN_KEYWORD fr30_cgen_opval_cr_names
=
181 & fr30_cgen_opval_cr_names_entries
[0],
186 static CGEN_KEYWORD_ENTRY fr30_cgen_opval_dr_names_entries
[] =
188 { "tbr", 0, {0, {0}}, 0, 0 },
189 { "rp", 1, {0, {0}}, 0, 0 },
190 { "ssp", 2, {0, {0}}, 0, 0 },
191 { "usp", 3, {0, {0}}, 0, 0 },
192 { "mdh", 4, {0, {0}}, 0, 0 },
193 { "mdl", 5, {0, {0}}, 0, 0 }
196 CGEN_KEYWORD fr30_cgen_opval_dr_names
=
198 & fr30_cgen_opval_dr_names_entries
[0],
203 static CGEN_KEYWORD_ENTRY fr30_cgen_opval_h_ps_entries
[] =
205 { "ps", 0, {0, {0}}, 0, 0 }
208 CGEN_KEYWORD fr30_cgen_opval_h_ps
=
210 & fr30_cgen_opval_h_ps_entries
[0],
215 static CGEN_KEYWORD_ENTRY fr30_cgen_opval_h_r13_entries
[] =
217 { "r13", 0, {0, {0}}, 0, 0 }
220 CGEN_KEYWORD fr30_cgen_opval_h_r13
=
222 & fr30_cgen_opval_h_r13_entries
[0],
227 static CGEN_KEYWORD_ENTRY fr30_cgen_opval_h_r14_entries
[] =
229 { "r14", 0, {0, {0}}, 0, 0 }
232 CGEN_KEYWORD fr30_cgen_opval_h_r14
=
234 & fr30_cgen_opval_h_r14_entries
[0],
239 static CGEN_KEYWORD_ENTRY fr30_cgen_opval_h_r15_entries
[] =
241 { "r15", 0, {0, {0}}, 0, 0 }
244 CGEN_KEYWORD fr30_cgen_opval_h_r15
=
246 & fr30_cgen_opval_h_r15_entries
[0],
252 /* The hardware table. */
254 #if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
255 #define A(a) (1 << CGEN_HW_##a)
257 #define A(a) (1 << CGEN_HW_/**/a)
260 const CGEN_HW_ENTRY fr30_cgen_hw_table
[] =
262 { "h-memory", HW_H_MEMORY
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
263 { "h-sint", HW_H_SINT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
264 { "h-uint", HW_H_UINT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
265 { "h-addr", HW_H_ADDR
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
266 { "h-iaddr", HW_H_IADDR
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
267 { "h-pc", HW_H_PC
, CGEN_ASM_NONE
, 0, { 0|A(PROFILE
)|A(PC
), { (1<<MACH_BASE
) } } },
268 { "h-gr", HW_H_GR
, CGEN_ASM_KEYWORD
, (PTR
) & fr30_cgen_opval_gr_names
, { 0|A(CACHE_ADDR
)|A(PROFILE
), { (1<<MACH_BASE
) } } },
269 { "h-cr", HW_H_CR
, CGEN_ASM_KEYWORD
, (PTR
) & fr30_cgen_opval_cr_names
, { 0, { (1<<MACH_BASE
) } } },
270 { "h-dr", HW_H_DR
, CGEN_ASM_KEYWORD
, (PTR
) & fr30_cgen_opval_dr_names
, { 0, { (1<<MACH_BASE
) } } },
271 { "h-ps", HW_H_PS
, CGEN_ASM_KEYWORD
, (PTR
) & fr30_cgen_opval_h_ps
, { 0, { (1<<MACH_BASE
) } } },
272 { "h-r13", HW_H_R13
, CGEN_ASM_KEYWORD
, (PTR
) & fr30_cgen_opval_h_r13
, { 0, { (1<<MACH_BASE
) } } },
273 { "h-r14", HW_H_R14
, CGEN_ASM_KEYWORD
, (PTR
) & fr30_cgen_opval_h_r14
, { 0, { (1<<MACH_BASE
) } } },
274 { "h-r15", HW_H_R15
, CGEN_ASM_KEYWORD
, (PTR
) & fr30_cgen_opval_h_r15
, { 0, { (1<<MACH_BASE
) } } },
275 { "h-nbit", HW_H_NBIT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
276 { "h-zbit", HW_H_ZBIT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
277 { "h-vbit", HW_H_VBIT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
278 { "h-cbit", HW_H_CBIT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
279 { "h-ibit", HW_H_IBIT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
280 { "h-sbit", HW_H_SBIT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
281 { "h-tbit", HW_H_TBIT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
282 { "h-d0bit", HW_H_D0BIT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
283 { "h-d1bit", HW_H_D1BIT
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
284 { "h-ccr", HW_H_CCR
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
285 { "h-scr", HW_H_SCR
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
286 { "h-ilm", HW_H_ILM
, CGEN_ASM_NONE
, 0, { 0, { (1<<MACH_BASE
) } } },
287 { 0, 0, CGEN_ASM_NONE
, 0, {0, {0}} }
293 /* The instruction field table. */
295 #if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
296 #define A(a) (1 << CGEN_IFLD_##a)
298 #define A(a) (1 << CGEN_IFLD_/**/a)
301 const CGEN_IFLD fr30_cgen_ifld_table
[] =
303 { FR30_F_NIL
, "f-nil", 0, 0, 0, 0, { 0, { (1<<MACH_BASE
) } } },
304 { FR30_F_ANYOF
, "f-anyof", 0, 0, 0, 0, { 0, { (1<<MACH_BASE
) } } },
305 { FR30_F_OP1
, "f-op1", 0, 16, 0, 4, { 0, { (1<<MACH_BASE
) } } },
306 { FR30_F_OP2
, "f-op2", 0, 16, 4, 4, { 0, { (1<<MACH_BASE
) } } },
307 { FR30_F_OP3
, "f-op3", 0, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
308 { FR30_F_OP4
, "f-op4", 0, 16, 12, 4, { 0, { (1<<MACH_BASE
) } } },
309 { FR30_F_OP5
, "f-op5", 0, 16, 4, 1, { 0, { (1<<MACH_BASE
) } } },
310 { FR30_F_CC
, "f-cc", 0, 16, 4, 4, { 0, { (1<<MACH_BASE
) } } },
311 { FR30_F_CCC
, "f-ccc", 16, 16, 0, 8, { 0, { (1<<MACH_BASE
) } } },
312 { FR30_F_RJ
, "f-Rj", 0, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
313 { FR30_F_RI
, "f-Ri", 0, 16, 12, 4, { 0, { (1<<MACH_BASE
) } } },
314 { FR30_F_RS1
, "f-Rs1", 0, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
315 { FR30_F_RS2
, "f-Rs2", 0, 16, 12, 4, { 0, { (1<<MACH_BASE
) } } },
316 { FR30_F_RJC
, "f-Rjc", 16, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
317 { FR30_F_RIC
, "f-Ric", 16, 16, 12, 4, { 0, { (1<<MACH_BASE
) } } },
318 { FR30_F_CRJ
, "f-CRj", 16, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
319 { FR30_F_CRI
, "f-CRi", 16, 16, 12, 4, { 0, { (1<<MACH_BASE
) } } },
320 { FR30_F_U4
, "f-u4", 0, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
321 { FR30_F_U4C
, "f-u4c", 0, 16, 12, 4, { 0, { (1<<MACH_BASE
) } } },
322 { FR30_F_I4
, "f-i4", 0, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
323 { FR30_F_M4
, "f-m4", 0, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
324 { FR30_F_U8
, "f-u8", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
325 { FR30_F_I8
, "f-i8", 0, 16, 4, 8, { 0, { (1<<MACH_BASE
) } } },
326 { FR30_F_I20_4
, "f-i20-4", 0, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
327 { FR30_F_I20_16
, "f-i20-16", 16, 16, 0, 16, { 0, { (1<<MACH_BASE
) } } },
328 { FR30_F_I32
, "f-i32", 16, 32, 0, 32, { 0|A(SIGN_OPT
), { (1<<MACH_BASE
) } } },
329 { FR30_F_UDISP6
, "f-udisp6", 0, 16, 8, 4, { 0, { (1<<MACH_BASE
) } } },
330 { FR30_F_DISP8
, "f-disp8", 0, 16, 4, 8, { 0, { (1<<MACH_BASE
) } } },
331 { FR30_F_DISP9
, "f-disp9", 0, 16, 4, 8, { 0, { (1<<MACH_BASE
) } } },
332 { FR30_F_DISP10
, "f-disp10", 0, 16, 4, 8, { 0, { (1<<MACH_BASE
) } } },
333 { FR30_F_S10
, "f-s10", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
334 { FR30_F_U10
, "f-u10", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
335 { FR30_F_REL9
, "f-rel9", 0, 16, 8, 8, { 0|A(PCREL_ADDR
), { (1<<MACH_BASE
) } } },
336 { FR30_F_DIR8
, "f-dir8", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
337 { FR30_F_DIR9
, "f-dir9", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
338 { FR30_F_DIR10
, "f-dir10", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
339 { FR30_F_REL12
, "f-rel12", 0, 16, 5, 11, { 0|A(PCREL_ADDR
), { (1<<MACH_BASE
) } } },
340 { FR30_F_REGLIST_HI_ST
, "f-reglist_hi_st", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
341 { FR30_F_REGLIST_LOW_ST
, "f-reglist_low_st", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
342 { FR30_F_REGLIST_HI_LD
, "f-reglist_hi_ld", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
343 { FR30_F_REGLIST_LOW_LD
, "f-reglist_low_ld", 0, 16, 8, 8, { 0, { (1<<MACH_BASE
) } } },
344 { 0, 0, 0, 0, 0, 0, {0, {0}} }
350 /* The operand table. */
352 #if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
353 #define A(a) (1 << CGEN_OPERAND_##a)
355 #define A(a) (1 << CGEN_OPERAND_/**/a)
357 #if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
358 #define OPERAND(op) FR30_OPERAND_##op
360 #define OPERAND(op) FR30_OPERAND_/**/op
363 const CGEN_OPERAND fr30_cgen_operand_table
[] =
365 /* pc: program counter */
366 { "pc", FR30_OPERAND_PC
, HW_H_PC
, 0, 0,
367 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
368 /* Ri: destination register */
369 { "Ri", FR30_OPERAND_RI
, HW_H_GR
, 12, 4,
370 { 0, { (1<<MACH_BASE
) } } },
371 /* Rj: source register */
372 { "Rj", FR30_OPERAND_RJ
, HW_H_GR
, 8, 4,
373 { 0, { (1<<MACH_BASE
) } } },
374 /* Ric: target register coproc insn */
375 { "Ric", FR30_OPERAND_RIC
, HW_H_GR
, 12, 4,
376 { 0, { (1<<MACH_BASE
) } } },
377 /* Rjc: source register coproc insn */
378 { "Rjc", FR30_OPERAND_RJC
, HW_H_GR
, 8, 4,
379 { 0, { (1<<MACH_BASE
) } } },
380 /* CRi: coprocessor register */
381 { "CRi", FR30_OPERAND_CRI
, HW_H_CR
, 12, 4,
382 { 0, { (1<<MACH_BASE
) } } },
383 /* CRj: coprocessor register */
384 { "CRj", FR30_OPERAND_CRJ
, HW_H_CR
, 8, 4,
385 { 0, { (1<<MACH_BASE
) } } },
386 /* Rs1: dedicated register */
387 { "Rs1", FR30_OPERAND_RS1
, HW_H_DR
, 8, 4,
388 { 0, { (1<<MACH_BASE
) } } },
389 /* Rs2: dedicated register */
390 { "Rs2", FR30_OPERAND_RS2
, HW_H_DR
, 12, 4,
391 { 0, { (1<<MACH_BASE
) } } },
392 /* R13: General Register 13 */
393 { "R13", FR30_OPERAND_R13
, HW_H_R13
, 0, 0,
394 { 0, { (1<<MACH_BASE
) } } },
395 /* R14: General Register 14 */
396 { "R14", FR30_OPERAND_R14
, HW_H_R14
, 0, 0,
397 { 0, { (1<<MACH_BASE
) } } },
398 /* R15: General Register 15 */
399 { "R15", FR30_OPERAND_R15
, HW_H_R15
, 0, 0,
400 { 0, { (1<<MACH_BASE
) } } },
401 /* ps: Program Status register */
402 { "ps", FR30_OPERAND_PS
, HW_H_PS
, 0, 0,
403 { 0, { (1<<MACH_BASE
) } } },
404 /* u4: 4 bit unsigned immediate */
405 { "u4", FR30_OPERAND_U4
, HW_H_UINT
, 8, 4,
406 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
407 /* u4c: 4 bit unsigned immediate */
408 { "u4c", FR30_OPERAND_U4C
, HW_H_UINT
, 12, 4,
409 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
410 /* u8: 8 bit unsigned immediate */
411 { "u8", FR30_OPERAND_U8
, HW_H_UINT
, 8, 8,
412 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
413 /* i8: 8 bit unsigned immediate */
414 { "i8", FR30_OPERAND_I8
, HW_H_UINT
, 4, 8,
415 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
416 /* udisp6: 6 bit unsigned immediate */
417 { "udisp6", FR30_OPERAND_UDISP6
, HW_H_UINT
, 8, 4,
418 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
419 /* disp8: 8 bit signed immediate */
420 { "disp8", FR30_OPERAND_DISP8
, HW_H_SINT
, 4, 8,
421 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
422 /* disp9: 9 bit signed immediate */
423 { "disp9", FR30_OPERAND_DISP9
, HW_H_SINT
, 4, 8,
424 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
425 /* disp10: 10 bit signed immediate */
426 { "disp10", FR30_OPERAND_DISP10
, HW_H_SINT
, 4, 8,
427 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
428 /* s10: 10 bit signed immediate */
429 { "s10", FR30_OPERAND_S10
, HW_H_SINT
, 8, 8,
430 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
431 /* u10: 10 bit unsigned immediate */
432 { "u10", FR30_OPERAND_U10
, HW_H_UINT
, 8, 8,
433 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
434 /* i32: 32 bit immediate */
435 { "i32", FR30_OPERAND_I32
, HW_H_UINT
, 0, 32,
436 { 0|A(HASH_PREFIX
)|A(SIGN_OPT
), { (1<<MACH_BASE
) } } },
437 /* m4: 4 bit negative immediate */
438 { "m4", FR30_OPERAND_M4
, HW_H_SINT
, 8, 4,
439 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
440 /* i20: 20 bit immediate */
441 { "i20", FR30_OPERAND_I20
, HW_H_UINT
, 0, 20,
442 { 0|A(HASH_PREFIX
)|A(VIRTUAL
), { (1<<MACH_BASE
) } } },
443 /* dir8: 8 bit direct address */
444 { "dir8", FR30_OPERAND_DIR8
, HW_H_UINT
, 8, 8,
445 { 0, { (1<<MACH_BASE
) } } },
446 /* dir9: 9 bit direct address */
447 { "dir9", FR30_OPERAND_DIR9
, HW_H_UINT
, 8, 8,
448 { 0, { (1<<MACH_BASE
) } } },
449 /* dir10: 10 bit direct address */
450 { "dir10", FR30_OPERAND_DIR10
, HW_H_UINT
, 8, 8,
451 { 0, { (1<<MACH_BASE
) } } },
452 /* label9: 9 bit pc relative address */
453 { "label9", FR30_OPERAND_LABEL9
, HW_H_IADDR
, 8, 8,
454 { 0|A(PCREL_ADDR
), { (1<<MACH_BASE
) } } },
455 /* label12: 12 bit pc relative address */
456 { "label12", FR30_OPERAND_LABEL12
, HW_H_IADDR
, 5, 11,
457 { 0|A(PCREL_ADDR
), { (1<<MACH_BASE
) } } },
458 /* reglist_low_ld: 8 bit low register mask for ldm */
459 { "reglist_low_ld", FR30_OPERAND_REGLIST_LOW_LD
, HW_H_UINT
, 8, 8,
460 { 0, { (1<<MACH_BASE
) } } },
461 /* reglist_hi_ld: 8 bit high register mask for ldm */
462 { "reglist_hi_ld", FR30_OPERAND_REGLIST_HI_LD
, HW_H_UINT
, 8, 8,
463 { 0, { (1<<MACH_BASE
) } } },
464 /* reglist_low_st: 8 bit low register mask for stm */
465 { "reglist_low_st", FR30_OPERAND_REGLIST_LOW_ST
, HW_H_UINT
, 8, 8,
466 { 0, { (1<<MACH_BASE
) } } },
467 /* reglist_hi_st: 8 bit high register mask for stm */
468 { "reglist_hi_st", FR30_OPERAND_REGLIST_HI_ST
, HW_H_UINT
, 8, 8,
469 { 0, { (1<<MACH_BASE
) } } },
470 /* cc: condition codes */
471 { "cc", FR30_OPERAND_CC
, HW_H_UINT
, 4, 4,
472 { 0, { (1<<MACH_BASE
) } } },
473 /* ccc: coprocessor calc */
474 { "ccc", FR30_OPERAND_CCC
, HW_H_UINT
, 0, 8,
475 { 0|A(HASH_PREFIX
), { (1<<MACH_BASE
) } } },
476 /* nbit: negative bit */
477 { "nbit", FR30_OPERAND_NBIT
, HW_H_NBIT
, 0, 0,
478 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
479 /* vbit: overflow bit */
480 { "vbit", FR30_OPERAND_VBIT
, HW_H_VBIT
, 0, 0,
481 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
483 { "zbit", FR30_OPERAND_ZBIT
, HW_H_ZBIT
, 0, 0,
484 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
485 /* cbit: carry bit */
486 { "cbit", FR30_OPERAND_CBIT
, HW_H_CBIT
, 0, 0,
487 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
488 /* ibit: interrupt bit */
489 { "ibit", FR30_OPERAND_IBIT
, HW_H_IBIT
, 0, 0,
490 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
491 /* sbit: stack bit */
492 { "sbit", FR30_OPERAND_SBIT
, HW_H_SBIT
, 0, 0,
493 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
494 /* tbit: trace trap bit */
495 { "tbit", FR30_OPERAND_TBIT
, HW_H_TBIT
, 0, 0,
496 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
497 /* d0bit: division 0 bit */
498 { "d0bit", FR30_OPERAND_D0BIT
, HW_H_D0BIT
, 0, 0,
499 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
500 /* d1bit: division 1 bit */
501 { "d1bit", FR30_OPERAND_D1BIT
, HW_H_D1BIT
, 0, 0,
502 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
503 /* ccr: condition code bits */
504 { "ccr", FR30_OPERAND_CCR
, HW_H_CCR
, 0, 0,
505 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
506 /* scr: system condition bits */
507 { "scr", FR30_OPERAND_SCR
, HW_H_SCR
, 0, 0,
508 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
509 /* ilm: interrupt level mask */
510 { "ilm", FR30_OPERAND_ILM
, HW_H_ILM
, 0, 0,
511 { 0|A(SEM_ONLY
), { (1<<MACH_BASE
) } } },
512 { 0, 0, 0, 0, 0, {0, {0}} }
518 /* The instruction table. */
520 #define OP(field) CGEN_SYNTAX_MAKE_FIELD (OPERAND (field))
521 #if defined (__STDC__) || defined (ALMOST_STDC) || defined (HAVE_STRINGIZE)
522 #define A(a) (1 << CGEN_INSN_##a)
524 #define A(a) (1 << CGEN_INSN_/**/a)
527 static const CGEN_IBASE fr30_cgen_insn_table
[MAX_INSNS
] =
529 /* Special null first entry.
530 A `num' value of zero is thus invalid.
531 Also, the special `invalid' insn resides here. */
532 { 0, 0, 0, 0, {0, {0}} },
535 FR30_INSN_ADD
, "add", "add", 16,
536 { 0, { (1<<MACH_BASE
) } }
540 FR30_INSN_ADDI
, "addi", "add", 16,
541 { 0, { (1<<MACH_BASE
) } }
545 FR30_INSN_ADD2
, "add2", "add2", 16,
546 { 0, { (1<<MACH_BASE
) } }
550 FR30_INSN_ADDC
, "addc", "addc", 16,
551 { 0, { (1<<MACH_BASE
) } }
555 FR30_INSN_ADDN
, "addn", "addn", 16,
556 { 0, { (1<<MACH_BASE
) } }
560 FR30_INSN_ADDNI
, "addni", "addn", 16,
561 { 0, { (1<<MACH_BASE
) } }
565 FR30_INSN_ADDN2
, "addn2", "addn2", 16,
566 { 0, { (1<<MACH_BASE
) } }
570 FR30_INSN_SUB
, "sub", "sub", 16,
571 { 0, { (1<<MACH_BASE
) } }
575 FR30_INSN_SUBC
, "subc", "subc", 16,
576 { 0, { (1<<MACH_BASE
) } }
580 FR30_INSN_SUBN
, "subn", "subn", 16,
581 { 0, { (1<<MACH_BASE
) } }
585 FR30_INSN_CMP
, "cmp", "cmp", 16,
586 { 0, { (1<<MACH_BASE
) } }
590 FR30_INSN_CMPI
, "cmpi", "cmp", 16,
591 { 0, { (1<<MACH_BASE
) } }
595 FR30_INSN_CMP2
, "cmp2", "cmp2", 16,
596 { 0, { (1<<MACH_BASE
) } }
600 FR30_INSN_AND
, "and", "and", 16,
601 { 0, { (1<<MACH_BASE
) } }
605 FR30_INSN_OR
, "or", "or", 16,
606 { 0, { (1<<MACH_BASE
) } }
610 FR30_INSN_EOR
, "eor", "eor", 16,
611 { 0, { (1<<MACH_BASE
) } }
615 FR30_INSN_ANDM
, "andm", "and", 16,
616 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
620 FR30_INSN_ANDH
, "andh", "andh", 16,
621 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
625 FR30_INSN_ANDB
, "andb", "andb", 16,
626 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
630 FR30_INSN_ORM
, "orm", "or", 16,
631 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
635 FR30_INSN_ORH
, "orh", "orh", 16,
636 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
640 FR30_INSN_ORB
, "orb", "orb", 16,
641 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
645 FR30_INSN_EORM
, "eorm", "eor", 16,
646 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
650 FR30_INSN_EORH
, "eorh", "eorh", 16,
651 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
655 FR30_INSN_EORB
, "eorb", "eorb", 16,
656 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
660 FR30_INSN_BANDL
, "bandl", "bandl", 16,
661 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
665 FR30_INSN_BORL
, "borl", "borl", 16,
666 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
670 FR30_INSN_BEORL
, "beorl", "beorl", 16,
671 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
675 FR30_INSN_BANDH
, "bandh", "bandh", 16,
676 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
680 FR30_INSN_BORH
, "borh", "borh", 16,
681 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
685 FR30_INSN_BEORH
, "beorh", "beorh", 16,
686 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
690 FR30_INSN_BTSTL
, "btstl", "btstl", 16,
691 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
695 FR30_INSN_BTSTH
, "btsth", "btsth", 16,
696 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
700 FR30_INSN_MUL
, "mul", "mul", 16,
701 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
705 FR30_INSN_MULU
, "mulu", "mulu", 16,
706 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
710 FR30_INSN_MULH
, "mulh", "mulh", 16,
711 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
715 FR30_INSN_MULUH
, "muluh", "muluh", 16,
716 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
720 FR30_INSN_DIV0S
, "div0s", "div0s", 16,
721 { 0, { (1<<MACH_BASE
) } }
725 FR30_INSN_DIV0U
, "div0u", "div0u", 16,
726 { 0, { (1<<MACH_BASE
) } }
730 FR30_INSN_DIV1
, "div1", "div1", 16,
731 { 0, { (1<<MACH_BASE
) } }
735 FR30_INSN_DIV2
, "div2", "div2", 16,
736 { 0, { (1<<MACH_BASE
) } }
740 FR30_INSN_DIV3
, "div3", "div3", 16,
741 { 0, { (1<<MACH_BASE
) } }
745 FR30_INSN_DIV4S
, "div4s", "div4s", 16,
746 { 0, { (1<<MACH_BASE
) } }
750 FR30_INSN_LSL
, "lsl", "lsl", 16,
751 { 0, { (1<<MACH_BASE
) } }
755 FR30_INSN_LSLI
, "lsli", "lsl", 16,
756 { 0, { (1<<MACH_BASE
) } }
760 FR30_INSN_LSL2
, "lsl2", "lsl2", 16,
761 { 0, { (1<<MACH_BASE
) } }
765 FR30_INSN_LSR
, "lsr", "lsr", 16,
766 { 0, { (1<<MACH_BASE
) } }
770 FR30_INSN_LSRI
, "lsri", "lsr", 16,
771 { 0, { (1<<MACH_BASE
) } }
775 FR30_INSN_LSR2
, "lsr2", "lsr2", 16,
776 { 0, { (1<<MACH_BASE
) } }
780 FR30_INSN_ASR
, "asr", "asr", 16,
781 { 0, { (1<<MACH_BASE
) } }
785 FR30_INSN_ASRI
, "asri", "asr", 16,
786 { 0, { (1<<MACH_BASE
) } }
790 FR30_INSN_ASR2
, "asr2", "asr2", 16,
791 { 0, { (1<<MACH_BASE
) } }
795 FR30_INSN_LDI8
, "ldi8", "ldi:8", 16,
796 { 0, { (1<<MACH_BASE
) } }
798 /* ldi:20 $i20,$Ri */
800 FR30_INSN_LDI20
, "ldi20", "ldi:20", 32,
801 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
803 /* ldi:32 $i32,$Ri */
805 FR30_INSN_LDI32
, "ldi32", "ldi:32", 48,
806 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
810 FR30_INSN_LD
, "ld", "ld", 16,
811 { 0, { (1<<MACH_BASE
) } }
815 FR30_INSN_LDUH
, "lduh", "lduh", 16,
816 { 0, { (1<<MACH_BASE
) } }
820 FR30_INSN_LDUB
, "ldub", "ldub", 16,
821 { 0, { (1<<MACH_BASE
) } }
823 /* ld @($R13,$Rj),$Ri */
825 FR30_INSN_LDR13
, "ldr13", "ld", 16,
826 { 0, { (1<<MACH_BASE
) } }
828 /* lduh @($R13,$Rj),$Ri */
830 FR30_INSN_LDR13UH
, "ldr13uh", "lduh", 16,
831 { 0, { (1<<MACH_BASE
) } }
833 /* ldub @($R13,$Rj),$Ri */
835 FR30_INSN_LDR13UB
, "ldr13ub", "ldub", 16,
836 { 0, { (1<<MACH_BASE
) } }
838 /* ld @($R14,$disp10),$Ri */
840 FR30_INSN_LDR14
, "ldr14", "ld", 16,
841 { 0, { (1<<MACH_BASE
) } }
843 /* lduh @($R14,$disp9),$Ri */
845 FR30_INSN_LDR14UH
, "ldr14uh", "lduh", 16,
846 { 0, { (1<<MACH_BASE
) } }
848 /* ldub @($R14,$disp8),$Ri */
850 FR30_INSN_LDR14UB
, "ldr14ub", "ldub", 16,
851 { 0, { (1<<MACH_BASE
) } }
853 /* ld @($R15,$udisp6),$Ri */
855 FR30_INSN_LDR15
, "ldr15", "ld", 16,
856 { 0, { (1<<MACH_BASE
) } }
860 FR30_INSN_LDR15GR
, "ldr15gr", "ld", 16,
861 { 0, { (1<<MACH_BASE
) } }
865 FR30_INSN_LDR15DR
, "ldr15dr", "ld", 16,
866 { 0, { (1<<MACH_BASE
) } }
870 FR30_INSN_LDR15PS
, "ldr15ps", "ld", 16,
871 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
875 FR30_INSN_ST
, "st", "st", 16,
876 { 0, { (1<<MACH_BASE
) } }
880 FR30_INSN_STH
, "sth", "sth", 16,
881 { 0, { (1<<MACH_BASE
) } }
885 FR30_INSN_STB
, "stb", "stb", 16,
886 { 0, { (1<<MACH_BASE
) } }
888 /* st $Ri,@($R13,$Rj) */
890 FR30_INSN_STR13
, "str13", "st", 16,
891 { 0, { (1<<MACH_BASE
) } }
893 /* sth $Ri,@($R13,$Rj) */
895 FR30_INSN_STR13H
, "str13h", "sth", 16,
896 { 0, { (1<<MACH_BASE
) } }
898 /* stb $Ri,@($R13,$Rj) */
900 FR30_INSN_STR13B
, "str13b", "stb", 16,
901 { 0, { (1<<MACH_BASE
) } }
903 /* st $Ri,@($R14,$disp10) */
905 FR30_INSN_STR14
, "str14", "st", 16,
906 { 0, { (1<<MACH_BASE
) } }
908 /* sth $Ri,@($R14,$disp9) */
910 FR30_INSN_STR14H
, "str14h", "sth", 16,
911 { 0, { (1<<MACH_BASE
) } }
913 /* stb $Ri,@($R14,$disp8) */
915 FR30_INSN_STR14B
, "str14b", "stb", 16,
916 { 0, { (1<<MACH_BASE
) } }
918 /* st $Ri,@($R15,$udisp6) */
920 FR30_INSN_STR15
, "str15", "st", 16,
921 { 0, { (1<<MACH_BASE
) } }
925 FR30_INSN_STR15GR
, "str15gr", "st", 16,
926 { 0, { (1<<MACH_BASE
) } }
930 FR30_INSN_STR15DR
, "str15dr", "st", 16,
931 { 0, { (1<<MACH_BASE
) } }
935 FR30_INSN_STR15PS
, "str15ps", "st", 16,
936 { 0, { (1<<MACH_BASE
) } }
940 FR30_INSN_MOV
, "mov", "mov", 16,
941 { 0, { (1<<MACH_BASE
) } }
945 FR30_INSN_MOVDR
, "movdr", "mov", 16,
946 { 0, { (1<<MACH_BASE
) } }
950 FR30_INSN_MOVPS
, "movps", "mov", 16,
951 { 0, { (1<<MACH_BASE
) } }
955 FR30_INSN_MOV2DR
, "mov2dr", "mov", 16,
956 { 0, { (1<<MACH_BASE
) } }
960 FR30_INSN_MOV2PS
, "mov2ps", "mov", 16,
961 { 0, { (1<<MACH_BASE
) } }
965 FR30_INSN_JMP
, "jmp", "jmp", 16,
966 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
), { (1<<MACH_BASE
) } }
970 FR30_INSN_JMPD
, "jmpd", "jmp:d", 16,
971 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
975 FR30_INSN_CALLR
, "callr", "call", 16,
976 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
), { (1<<MACH_BASE
) } }
980 FR30_INSN_CALLRD
, "callrd", "call:d", 16,
981 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
985 FR30_INSN_CALL
, "call", "call", 16,
986 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
), { (1<<MACH_BASE
) } }
988 /* call:d $label12 */
990 FR30_INSN_CALLD
, "calld", "call:d", 16,
991 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
995 FR30_INSN_RET
, "ret", "ret", 16,
996 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
), { (1<<MACH_BASE
) } }
1000 FR30_INSN_RET_D
, "ret:d", "ret:d", 16,
1001 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1005 FR30_INSN_INT
, "int", "int", 16,
1006 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
), { (1<<MACH_BASE
) } }
1010 FR30_INSN_INTE
, "inte", "inte", 16,
1011 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
), { (1<<MACH_BASE
) } }
1015 FR30_INSN_RETI
, "reti", "reti", 16,
1016 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1020 FR30_INSN_BRAD
, "brad", "bra:d", 16,
1021 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1025 FR30_INSN_BRA
, "bra", "bra", 16,
1026 { 0|A(NOT_IN_DELAY_SLOT
)|A(UNCOND_CTI
), { (1<<MACH_BASE
) } }
1030 FR30_INSN_BNOD
, "bnod", "bno:d", 16,
1031 { 0|A(NOT_IN_DELAY_SLOT
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1035 FR30_INSN_BNO
, "bno", "bno", 16,
1036 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1040 FR30_INSN_BEQD
, "beqd", "beq:d", 16,
1041 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1045 FR30_INSN_BEQ
, "beq", "beq", 16,
1046 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1050 FR30_INSN_BNED
, "bned", "bne:d", 16,
1051 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1055 FR30_INSN_BNE
, "bne", "bne", 16,
1056 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1060 FR30_INSN_BCD
, "bcd", "bc:d", 16,
1061 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1065 FR30_INSN_BC
, "bc", "bc", 16,
1066 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1070 FR30_INSN_BNCD
, "bncd", "bnc:d", 16,
1071 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1075 FR30_INSN_BNC
, "bnc", "bnc", 16,
1076 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1080 FR30_INSN_BND
, "bnd", "bn:d", 16,
1081 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1085 FR30_INSN_BN
, "bn", "bn", 16,
1086 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1090 FR30_INSN_BPD
, "bpd", "bp:d", 16,
1091 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1095 FR30_INSN_BP
, "bp", "bp", 16,
1096 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1100 FR30_INSN_BVD
, "bvd", "bv:d", 16,
1101 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1105 FR30_INSN_BV
, "bv", "bv", 16,
1106 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1110 FR30_INSN_BNVD
, "bnvd", "bnv:d", 16,
1111 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1115 FR30_INSN_BNV
, "bnv", "bnv", 16,
1116 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1120 FR30_INSN_BLTD
, "bltd", "blt:d", 16,
1121 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1125 FR30_INSN_BLT
, "blt", "blt", 16,
1126 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1130 FR30_INSN_BGED
, "bged", "bge:d", 16,
1131 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1135 FR30_INSN_BGE
, "bge", "bge", 16,
1136 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1140 FR30_INSN_BLED
, "bled", "ble:d", 16,
1141 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1145 FR30_INSN_BLE
, "ble", "ble", 16,
1146 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1150 FR30_INSN_BGTD
, "bgtd", "bgt:d", 16,
1151 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1155 FR30_INSN_BGT
, "bgt", "bgt", 16,
1156 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1160 FR30_INSN_BLSD
, "blsd", "bls:d", 16,
1161 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1165 FR30_INSN_BLS
, "bls", "bls", 16,
1166 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1170 FR30_INSN_BHID
, "bhid", "bhi:d", 16,
1171 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
)|A(DELAY_SLOT
), { (1<<MACH_BASE
) } }
1175 FR30_INSN_BHI
, "bhi", "bhi", 16,
1176 { 0|A(NOT_IN_DELAY_SLOT
)|A(COND_CTI
), { (1<<MACH_BASE
) } }
1178 /* dmov $R13,@$dir10 */
1180 FR30_INSN_DMOVR13
, "dmovr13", "dmov", 16,
1181 { 0, { (1<<MACH_BASE
) } }
1183 /* dmovh $R13,@$dir9 */
1185 FR30_INSN_DMOVR13H
, "dmovr13h", "dmovh", 16,
1186 { 0, { (1<<MACH_BASE
) } }
1188 /* dmovb $R13,@$dir8 */
1190 FR30_INSN_DMOVR13B
, "dmovr13b", "dmovb", 16,
1191 { 0, { (1<<MACH_BASE
) } }
1193 /* dmov @$R13+,@$dir10 */
1195 FR30_INSN_DMOVR13PI
, "dmovr13pi", "dmov", 16,
1196 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1198 /* dmovh @$R13+,@$dir9 */
1200 FR30_INSN_DMOVR13PIH
, "dmovr13pih", "dmovh", 16,
1201 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1203 /* dmovb @$R13+,@$dir8 */
1205 FR30_INSN_DMOVR13PIB
, "dmovr13pib", "dmovb", 16,
1206 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1208 /* dmov @$R15+,@$dir10 */
1210 FR30_INSN_DMOVR15PI
, "dmovr15pi", "dmov", 16,
1211 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1213 /* dmov @$dir10,$R13 */
1215 FR30_INSN_DMOV2R13
, "dmov2r13", "dmov", 16,
1216 { 0, { (1<<MACH_BASE
) } }
1218 /* dmovh @$dir9,$R13 */
1220 FR30_INSN_DMOV2R13H
, "dmov2r13h", "dmovh", 16,
1221 { 0, { (1<<MACH_BASE
) } }
1223 /* dmovb @$dir8,$R13 */
1225 FR30_INSN_DMOV2R13B
, "dmov2r13b", "dmovb", 16,
1226 { 0, { (1<<MACH_BASE
) } }
1228 /* dmov @$dir10,@$R13+ */
1230 FR30_INSN_DMOV2R13PI
, "dmov2r13pi", "dmov", 16,
1231 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1233 /* dmovh @$dir9,@$R13+ */
1235 FR30_INSN_DMOV2R13PIH
, "dmov2r13pih", "dmovh", 16,
1236 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1238 /* dmovb @$dir8,@$R13+ */
1240 FR30_INSN_DMOV2R13PIB
, "dmov2r13pib", "dmovb", 16,
1241 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1243 /* dmov @$dir10,@-$R15 */
1245 FR30_INSN_DMOV2R15PD
, "dmov2r15pd", "dmov", 16,
1246 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1248 /* ldres @$Ri+,$u4 */
1250 FR30_INSN_LDRES
, "ldres", "ldres", 16,
1251 { 0, { (1<<MACH_BASE
) } }
1253 /* stres $u4,@$Ri+ */
1255 FR30_INSN_STRES
, "stres", "stres", 16,
1256 { 0, { (1<<MACH_BASE
) } }
1258 /* copop $u4c,$ccc,$CRj,$CRi */
1260 FR30_INSN_COPOP
, "copop", "copop", 32,
1261 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1263 /* copld $u4c,$ccc,$Rjc,$CRi */
1265 FR30_INSN_COPLD
, "copld", "copld", 32,
1266 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1268 /* copst $u4c,$ccc,$CRj,$Ric */
1270 FR30_INSN_COPST
, "copst", "copst", 32,
1271 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1273 /* copsv $u4c,$ccc,$CRj,$Ric */
1275 FR30_INSN_COPSV
, "copsv", "copsv", 32,
1276 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1280 FR30_INSN_NOP
, "nop", "nop", 16,
1281 { 0, { (1<<MACH_BASE
) } }
1285 FR30_INSN_ANDCCR
, "andccr", "andccr", 16,
1286 { 0, { (1<<MACH_BASE
) } }
1290 FR30_INSN_ORCCR
, "orccr", "orccr", 16,
1291 { 0, { (1<<MACH_BASE
) } }
1295 FR30_INSN_STILM
, "stilm", "stilm", 16,
1296 { 0, { (1<<MACH_BASE
) } }
1300 FR30_INSN_ADDSP
, "addsp", "addsp", 16,
1301 { 0, { (1<<MACH_BASE
) } }
1305 FR30_INSN_EXTSB
, "extsb", "extsb", 16,
1306 { 0, { (1<<MACH_BASE
) } }
1310 FR30_INSN_EXTUB
, "extub", "extub", 16,
1311 { 0, { (1<<MACH_BASE
) } }
1315 FR30_INSN_EXTSH
, "extsh", "extsh", 16,
1316 { 0, { (1<<MACH_BASE
) } }
1320 FR30_INSN_EXTUH
, "extuh", "extuh", 16,
1321 { 0, { (1<<MACH_BASE
) } }
1323 /* ldm0 ($reglist_low_ld) */
1325 FR30_INSN_LDM0
, "ldm0", "ldm0", 16,
1326 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1328 /* ldm1 ($reglist_hi_ld) */
1330 FR30_INSN_LDM1
, "ldm1", "ldm1", 16,
1331 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1333 /* stm0 ($reglist_low_st) */
1335 FR30_INSN_STM0
, "stm0", "stm0", 16,
1336 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1338 /* stm1 ($reglist_hi_st) */
1340 FR30_INSN_STM1
, "stm1", "stm1", 16,
1341 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1345 FR30_INSN_ENTER
, "enter", "enter", 16,
1346 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1350 FR30_INSN_LEAVE
, "leave", "leave", 16,
1351 { 0, { (1<<MACH_BASE
) } }
1355 FR30_INSN_XCHB
, "xchb", "xchb", 16,
1356 { 0|A(NOT_IN_DELAY_SLOT
), { (1<<MACH_BASE
) } }
1363 /* Initialize anything needed to be done once, before any cpu_open call. */
1370 /* Subroutine of fr30_cgen_cpu_open to look up a mach via its bfd name. */
1372 static const CGEN_MACH
*
1373 lookup_mach_via_bfd_name (table
, name
)
1374 const CGEN_MACH
*table
;
1379 if (strcmp (name
, table
->bfd_name
) == 0)
1386 /* Subroutine of fr30_cgen_cpu_open to build the hardware table. */
1393 int machs
= cd
->machs
;
1394 const CGEN_HW_ENTRY
*init
= & fr30_cgen_hw_table
[0];
1395 /* MAX_HW is only an upper bound on the number of selected entries.
1396 However each entry is indexed by it's enum so there can be holes in
1398 const CGEN_HW_ENTRY
**selected
=
1399 (const CGEN_HW_ENTRY
**) xmalloc (MAX_HW
* sizeof (CGEN_HW_ENTRY
*));
1401 cd
->hw_table
.init_entries
= init
;
1402 cd
->hw_table
.entry_size
= sizeof (CGEN_HW_ENTRY
);
1403 memset (selected
, 0, MAX_HW
* sizeof (CGEN_HW_ENTRY
*));
1404 /* ??? For now we just use machs to determine which ones we want. */
1405 for (i
= 0; init
[i
].name
!= NULL
; ++i
)
1406 if (CGEN_HW_ATTR_VALUE (&init
[i
], CGEN_HW_MACH
)
1408 selected
[init
[i
].type
] = &init
[i
];
1409 cd
->hw_table
.entries
= selected
;
1410 cd
->hw_table
.num_entries
= MAX_HW
;
1413 /* Subroutine of fr30_cgen_cpu_open to build the hardware table. */
1416 build_ifield_table (cd
)
1419 cd
->ifld_table
= & fr30_cgen_ifld_table
[0];
1422 /* Subroutine of fr30_cgen_cpu_open to build the hardware table. */
1425 build_operand_table (cd
)
1429 int machs
= cd
->machs
;
1430 const CGEN_OPERAND
*init
= & fr30_cgen_operand_table
[0];
1431 /* MAX_OPERANDS is only an upper bound on the number of selected entries.
1432 However each entry is indexed by it's enum so there can be holes in
1434 const CGEN_OPERAND
**selected
=
1435 (const CGEN_OPERAND
**) xmalloc (MAX_OPERANDS
* sizeof (CGEN_OPERAND
*));
1437 cd
->operand_table
.init_entries
= init
;
1438 cd
->operand_table
.entry_size
= sizeof (CGEN_OPERAND
);
1439 memset (selected
, 0, MAX_OPERANDS
* sizeof (CGEN_OPERAND
*));
1440 /* ??? For now we just use mach to determine which ones we want. */
1441 for (i
= 0; init
[i
].name
!= NULL
; ++i
)
1442 if (CGEN_OPERAND_ATTR_VALUE (&init
[i
], CGEN_OPERAND_MACH
)
1444 selected
[init
[i
].type
] = &init
[i
];
1445 cd
->operand_table
.entries
= selected
;
1446 cd
->operand_table
.num_entries
= MAX_OPERANDS
;
1449 /* Subroutine of fr30_cgen_cpu_open to build the hardware table.
1450 ??? This could leave out insns not supported by the specified mach/isa,
1451 but that would cause errors like "foo only supported by bar" to become
1452 "unknown insn", so for now we include all insns and require the app to
1453 do the checking later.
1454 ??? On the other hand, parsing of such insns may require their hardware or
1455 operand elements to be in the table [which they mightn't be]. */
1458 build_insn_table (cd
)
1462 const CGEN_IBASE
*ib
= & fr30_cgen_insn_table
[0];
1463 CGEN_INSN
*insns
= (CGEN_INSN
*) xmalloc (MAX_INSNS
* sizeof (CGEN_INSN
));
1465 memset (insns
, 0, MAX_INSNS
* sizeof (CGEN_INSN
));
1466 for (i
= 0; i
< MAX_INSNS
; ++i
)
1467 insns
[i
].base
= &ib
[i
];
1468 cd
->insn_table
.init_entries
= insns
;
1469 cd
->insn_table
.entry_size
= sizeof (CGEN_IBASE
);
1470 cd
->insn_table
.num_init_entries
= MAX_INSNS
;
1473 /* Subroutine of fr30_cgen_cpu_open to rebuild the tables. */
1476 fr30_cgen_rebuild_tables (cd
)
1480 unsigned int isas
= cd
->isas
;
1482 unsigned int machs
= cd
->machs
;
1485 cd
->int_insn_p
= CGEN_INT_INSN_P
;
1487 /* Data derived from the isa spec. */
1488 #define UNSET (CGEN_SIZE_UNKNOWN + 1)
1489 cd
->default_insn_bitsize
= UNSET
;
1490 cd
->base_insn_bitsize
= UNSET
;
1491 cd
->min_insn_bitsize
= 65535; /* some ridiculously big number */
1492 cd
->max_insn_bitsize
= 0;
1493 for (i
= 0; i
< MAX_ISAS
; ++i
)
1494 if (((1 << i
) & isas
) != 0)
1496 const CGEN_ISA
*isa
= & fr30_cgen_isa_table
[i
];
1498 /* Default insn sizes of all selected isas must be equal or we set
1499 the result to 0, meaning "unknown". */
1500 if (cd
->default_insn_bitsize
== UNSET
)
1501 cd
->default_insn_bitsize
= isa
->default_insn_bitsize
;
1502 else if (isa
->default_insn_bitsize
== cd
->default_insn_bitsize
)
1505 cd
->default_insn_bitsize
= CGEN_SIZE_UNKNOWN
;
1507 /* Base insn sizes of all selected isas must be equal or we set
1508 the result to 0, meaning "unknown". */
1509 if (cd
->base_insn_bitsize
== UNSET
)
1510 cd
->base_insn_bitsize
= isa
->base_insn_bitsize
;
1511 else if (isa
->base_insn_bitsize
== cd
->base_insn_bitsize
)
1514 cd
->base_insn_bitsize
= CGEN_SIZE_UNKNOWN
;
1516 /* Set min,max insn sizes. */
1517 if (isa
->min_insn_bitsize
< cd
->min_insn_bitsize
)
1518 cd
->min_insn_bitsize
= isa
->min_insn_bitsize
;
1519 if (isa
->max_insn_bitsize
> cd
->max_insn_bitsize
)
1520 cd
->max_insn_bitsize
= isa
->max_insn_bitsize
;
1525 #if 0 /* Does nothing?? */
1526 /* Data derived from the mach spec. */
1527 for (i
= 0; i
< MAX_MACHS
; ++i
)
1528 if (((1 << i
) & machs
) != 0)
1530 const CGEN_MACH
*mach
= & fr30_cgen_mach_table
[i
];
1536 /* Determine which hw elements are used by MACH. */
1537 build_hw_table (cd
);
1539 /* Build the ifield table. */
1540 build_ifield_table (cd
);
1542 /* Determine which operands are used by MACH/ISA. */
1543 build_operand_table (cd
);
1545 /* Build the instruction table. */
1546 build_insn_table (cd
);
1549 /* Initialize a cpu table and return a descriptor.
1550 It's much like opening a file, and must be the first function called.
1551 The arguments are a set of (type/value) pairs, terminated with
1554 Currently supported values:
1555 CGEN_CPU_OPEN_ISAS: bitmap of values in enum isa_attr
1556 CGEN_CPU_OPEN_MACHS: bitmap of values in enum mach_attr
1557 CGEN_CPU_OPEN_BFDMACH: specify 1 mach using bfd name
1558 CGEN_CPU_OPEN_ENDIAN: specify endian choice
1559 CGEN_CPU_OPEN_END: terminates arguments
1561 ??? Simultaneous multiple isas might not make sense, but it's not (yet)
1564 ??? We only support ISO C stdargs here, not K&R.
1565 Laziness, plus experiment to see if anything requires K&R - eventually
1566 K&R will no longer be supported - e.g. GDB is currently trying this. */
1569 fr30_cgen_cpu_open (enum cgen_cpu_open_arg arg_type
, ...)
1571 CGEN_CPU_TABLE
*cd
= (CGEN_CPU_TABLE
*) xmalloc (sizeof (CGEN_CPU_TABLE
));
1573 unsigned int isas
= 0; /* 0 = "unspecified" */
1574 unsigned int machs
= 0; /* 0 = "unspecified" */
1575 enum cgen_endian endian
= CGEN_ENDIAN_UNKNOWN
;
1584 memset (cd
, 0, sizeof (*cd
));
1586 va_start (ap
, arg_type
);
1587 while (arg_type
!= CGEN_CPU_OPEN_END
)
1591 case CGEN_CPU_OPEN_ISAS
:
1592 isas
= va_arg (ap
, unsigned int);
1594 case CGEN_CPU_OPEN_MACHS
:
1595 machs
= va_arg (ap
, unsigned int);
1597 case CGEN_CPU_OPEN_BFDMACH
:
1599 const char *name
= va_arg (ap
, const char *);
1600 const CGEN_MACH
*mach
=
1601 lookup_mach_via_bfd_name (fr30_cgen_mach_table
, name
);
1603 machs
|= 1 << mach
->num
;
1606 case CGEN_CPU_OPEN_ENDIAN
:
1607 endian
= va_arg (ap
, enum cgen_endian
);
1610 fprintf (stderr
, "fr30_cgen_cpu_open: unsupported argument `%d'\n",
1612 abort (); /* ??? return NULL? */
1614 arg_type
= va_arg (ap
, enum cgen_cpu_open_arg
);
1618 /* mach unspecified means "all" */
1620 machs
= (1 << MAX_MACHS
) - 1;
1621 /* base mach is always selected */
1623 /* isa unspecified means "all" */
1625 isas
= (1 << MAX_ISAS
) - 1;
1626 if (endian
== CGEN_ENDIAN_UNKNOWN
)
1628 /* ??? If target has only one, could have a default. */
1629 fprintf (stderr
, "fr30_cgen_cpu_open: no endianness specified\n");
1635 cd
->endian
= endian
;
1636 /* FIXME: for the sparc case we can determine insn-endianness statically.
1637 The worry here is where both data and insn endian can be independently
1638 chosen, in which case this function will need another argument.
1639 Actually, will want to allow for more arguments in the future anyway. */
1640 cd
->insn_endian
= endian
;
1642 /* Table (re)builder. */
1643 cd
->rebuild_tables
= fr30_cgen_rebuild_tables
;
1644 fr30_cgen_rebuild_tables (cd
);
1646 /* Default to not allowing signed overflow. */
1647 cd
->signed_overflow_ok_p
= 0;
1649 return (CGEN_CPU_DESC
) cd
;
1652 /* Cover fn to fr30_cgen_cpu_open to handle the simple case of 1 isa, 1 mach.
1653 MACH_NAME is the bfd name of the mach. */
1656 fr30_cgen_cpu_open_1 (mach_name
, endian
)
1657 const char *mach_name
;
1658 enum cgen_endian endian
;
1660 return fr30_cgen_cpu_open (CGEN_CPU_OPEN_BFDMACH
, mach_name
,
1661 CGEN_CPU_OPEN_ENDIAN
, endian
,
1665 /* Close a cpu table.
1666 ??? This can live in a machine independent file, but there's currently
1667 no place to put this file (there's no libcgen). libopcodes is the wrong
1668 place as some simulator ports use this but they don't use libopcodes. */
1671 fr30_cgen_cpu_close (cd
)
1674 if (cd
->insn_table
.init_entries
)
1675 free ((CGEN_INSN
*) cd
->insn_table
.init_entries
);
1676 if (cd
->hw_table
.entries
)
1677 free ((CGEN_HW_ENTRY
*) cd
->hw_table
.entries
);