1 /* Assemble Matsushita MN10200 instructions.
2 Copyright (C) 1996-2019 Free Software Foundation, Inc.
4 This file is part of the GNU opcodes library.
6 This library is free software; you can redistribute it and/or modify
7 it under the terms of the GNU General Public License as published by
8 the Free Software Foundation; either version 3, or (at your option)
11 It is distributed in the hope that it will be useful, but WITHOUT
12 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
13 or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
14 License for more details.
16 You should have received a copy of the GNU General Public License
17 along with this program; if not, write to the Free Software
18 Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston,
19 MA 02110-1301, USA. */
22 #include "opcode/mn10200.h"
25 const struct mn10200_operand mn10200_operands
[] = {
29 /* dn register in the first register operand position. */
30 #define DN0 (UNUSED+1)
31 {2, 0, MN10200_OPERAND_DREG
},
33 /* dn register in the second register operand position. */
35 {2, 2, MN10200_OPERAND_DREG
},
37 /* dm register in the first register operand position. */
39 {2, 0, MN10200_OPERAND_DREG
},
41 /* dm register in the second register operand position. */
43 {2, 2, MN10200_OPERAND_DREG
},
45 /* an register in the first register operand position. */
47 {2, 0, MN10200_OPERAND_AREG
},
49 /* an register in the second register operand position. */
51 {2, 2, MN10200_OPERAND_AREG
},
53 /* am register in the first register operand position. */
55 {2, 0, MN10200_OPERAND_AREG
},
57 /* am register in the second register operand position. */
59 {2, 2, MN10200_OPERAND_AREG
},
61 /* 8 bit unsigned immediate which may promote to a 16bit
62 unsigned immediate. */
64 {8, 0, MN10200_OPERAND_PROMOTE
},
66 /* 16 bit unsigned immediate which may promote to a 32bit
67 unsigned immediate. */
68 #define IMM16 (IMM8+1)
69 {16, 0, MN10200_OPERAND_PROMOTE
},
71 /* 16 bit pc-relative immediate which may promote to a 16bit
72 pc-relative immediate. */
73 #define IMM16_PCREL (IMM16+1)
74 {16, 0, MN10200_OPERAND_PCREL
| MN10200_OPERAND_RELAX
| MN10200_OPERAND_SIGNED
},
76 /* 16bit unsigned dispacement in a memory operation which
77 may promote to a 32bit displacement. */
78 #define IMM16_MEM (IMM16_PCREL+1)
79 {16, 0, MN10200_OPERAND_PROMOTE
| MN10200_OPERAND_MEMADDR
},
81 /* 24 immediate, low 16 bits in the main instruction
82 word, 8 in the extension word. */
84 #define IMM24 (IMM16_MEM+1)
85 {24, 0, MN10200_OPERAND_EXTENDED
},
87 /* 32bit pc-relative offset. */
88 #define IMM24_PCREL (IMM24+1)
89 {24, 0, MN10200_OPERAND_EXTENDED
| MN10200_OPERAND_PCREL
| MN10200_OPERAND_SIGNED
},
91 /* 32bit memory offset. */
92 #define IMM24_MEM (IMM24_PCREL+1)
93 {24, 0, MN10200_OPERAND_EXTENDED
| MN10200_OPERAND_MEMADDR
},
95 /* Processor status word. */
96 #define PSW (IMM24_MEM+1)
97 {0, 0, MN10200_OPERAND_PSW
},
101 {0, 0, MN10200_OPERAND_MDR
},
103 /* Index register. */
105 {2, 4, MN10200_OPERAND_DREG
},
107 /* 8 bit signed displacement, may promote to 16bit signed dispacement. */
109 {8, 0, MN10200_OPERAND_SIGNED
| MN10200_OPERAND_PROMOTE
},
111 /* 16 bit signed displacement, may promote to 32bit dispacement. */
113 {16, 0, MN10200_OPERAND_SIGNED
| MN10200_OPERAND_PROMOTE
},
115 /* 8 bit pc-relative displacement. */
116 #define SD8N_PCREL (SD16+1)
117 {8, 0, MN10200_OPERAND_SIGNED
| MN10200_OPERAND_PCREL
| MN10200_OPERAND_RELAX
},
119 /* 8 bit signed immediate which may promote to 16bit signed immediate. */
120 #define SIMM8 (SD8N_PCREL+1)
121 {8, 0, MN10200_OPERAND_SIGNED
| MN10200_OPERAND_PROMOTE
},
123 /* 16 bit signed immediate which may promote to 32bit immediate. */
124 #define SIMM16 (SIMM8+1)
125 {16, 0, MN10200_OPERAND_SIGNED
| MN10200_OPERAND_PROMOTE
},
127 /* 16 bit signed immediate which may not promote. */
128 #define SIMM16N (SIMM16+1)
129 {16, 0, MN10200_OPERAND_SIGNED
| MN10200_OPERAND_NOCHECK
},
131 /* Either an open paren or close paren. */
132 #define PAREN (SIMM16N+1)
133 {0, 0, MN10200_OPERAND_PAREN
},
135 /* dn register that appears in the first and second register positions. */
136 #define DN01 (PAREN+1)
137 {2, 0, MN10200_OPERAND_DREG
| MN10200_OPERAND_REPEATED
},
139 /* an register that appears in the first and second register positions. */
140 #define AN01 (DN01+1)
141 {2, 0, MN10200_OPERAND_AREG
| MN10200_OPERAND_REPEATED
},
144 #define MEM(ADDR) PAREN, ADDR, PAREN
145 #define MEM2(ADDR1,ADDR2) PAREN, ADDR1, ADDR2, PAREN
149 The format of the opcode table is:
151 NAME OPCODE MASK { OPERANDS }
153 NAME is the name of the instruction.
154 OPCODE is the instruction opcode.
155 MASK is the opcode mask; this is used to tell the disassembler
156 which bits in the actual opcode must match OPCODE.
157 OPERANDS is the list of operands.
159 The disassembler reads the table in order and prints the first
160 instruction which matches, so this table is sorted to put more
161 specific instructions before more general instructions. It is also
162 sorted by major opcode. */
164 const struct mn10200_opcode mn10200_opcodes
[] = {
165 { "mov", 0x8000, 0xf000, FMT_2
, {SIMM8
, DN01
}},
166 { "mov", 0x80, 0xf0, FMT_1
, {DN1
, DM0
}},
167 { "mov", 0xf230, 0xfff0, FMT_4
, {DM1
, AN0
}},
168 { "mov", 0xf2f0, 0xfff0, FMT_4
, {AN1
, DM0
}},
169 { "mov", 0xf270, 0xfff0, FMT_4
, {AN1
, AM0
}},
170 { "mov", 0xf3f0, 0xfffc, FMT_4
, {PSW
, DN0
}},
171 { "mov", 0xf3d0, 0xfff3, FMT_4
, {DN1
, PSW
}},
172 { "mov", 0xf3e0, 0xfffc, FMT_4
, {MDR
, DN0
}},
173 { "mov", 0xf3c0, 0xfff3, FMT_4
, {DN1
, MDR
}},
174 { "mov", 0x20, 0xf0, FMT_1
, {MEM(AN1
), DM0
}},
175 { "mov", 0x6000, 0xf000, FMT_2
, {MEM2(SD8
, AN1
), DM0
}},
176 { "mov", 0xf7c00000, 0xfff00000, FMT_6
, {MEM2(SD16
, AN1
), DM0
}},
177 { "mov", 0xf4800000, 0xfff00000, FMT_7
, {MEM2(IMM24
,AN1
), DM0
}},
178 { "mov", 0xf140, 0xffc0, FMT_4
, {MEM2(DI
, AN1
), DM0
}},
179 { "mov", 0xc80000, 0xfc0000, FMT_3
, {MEM(IMM16_MEM
), DN0
}},
180 { "mov", 0xf4c00000, 0xfffc0000, FMT_7
, {MEM(IMM24_MEM
), DN0
}},
181 { "mov", 0x7000, 0xf000, FMT_2
, {MEM2(SD8
,AN1
), AM0
}},
182 { "mov", 0x7000, 0xf000, FMT_2
, {MEM(AN1
), AM0
}},
183 { "mov", 0xf7b00000, 0xfff00000, FMT_6
, {MEM2(SD16
, AN1
), AM0
}},
184 { "mov", 0xf4f00000, 0xfff00000, FMT_7
, {MEM2(IMM24
,AN1
), AM0
}},
185 { "mov", 0xf100, 0xffc0, FMT_4
, {MEM2(DI
, AN1
), AM0
}},
186 { "mov", 0xf7300000, 0xfffc0000, FMT_6
, {MEM(IMM16_MEM
), AN0
}},
187 { "mov", 0xf4d00000, 0xfffc0000, FMT_7
, {MEM(IMM24_MEM
), AN0
}},
188 { "mov", 0x00, 0xf0, FMT_1
, {DM0
, MEM(AN1
)}},
189 { "mov", 0x4000, 0xf000, FMT_2
, {DM0
, MEM2(SD8
, AN1
)}},
190 { "mov", 0xf7800000, 0xfff00000, FMT_6
, {DM0
, MEM2(SD16
, AN1
)}},
191 { "mov", 0xf4000000, 0xfff00000, FMT_7
, {DM0
, MEM2(IMM24
, AN1
)}},
192 { "mov", 0xf1c0, 0xffc0, FMT_4
, {DM0
, MEM2(DI
, AN1
)}},
193 { "mov", 0xc00000, 0xfc0000, FMT_3
, {DN0
, MEM(IMM16_MEM
)}},
194 { "mov", 0xf4400000, 0xfffc0000, FMT_7
, {DN0
, MEM(IMM24_MEM
)}},
195 { "mov", 0x5000, 0xf000, FMT_2
, {AM0
, MEM2(SD8
, AN1
)}},
196 { "mov", 0x5000, 0xf000, FMT_2
, {AM0
, MEM(AN1
)}},
197 { "mov", 0xf7a00000, 0xfff00000, FMT_6
, {AM0
, MEM2(SD16
, AN1
)}},
198 { "mov", 0xf4100000, 0xfff00000, FMT_7
, {AM0
, MEM2(IMM24
,AN1
)}},
199 { "mov", 0xf180, 0xffc0, FMT_4
, {AM0
, MEM2(DI
, AN1
)}},
200 { "mov", 0xf7200000, 0xfffc0000, FMT_6
, {AN0
, MEM(IMM16_MEM
)}},
201 { "mov", 0xf4500000, 0xfffc0000, FMT_7
, {AN0
, MEM(IMM24_MEM
)}},
202 { "mov", 0xf80000, 0xfc0000, FMT_3
, {SIMM16
, DN0
}},
203 { "mov", 0xf4700000, 0xfffc0000, FMT_7
, {IMM24
, DN0
}},
204 { "mov", 0xdc0000, 0xfc0000, FMT_3
, {IMM16
, AN0
}},
205 { "mov", 0xf4740000, 0xfffc0000, FMT_7
, {IMM24
, AN0
}},
207 { "movx", 0xf57000, 0xfff000, FMT_5
, {MEM2(SD8
, AN1
), DM0
}},
208 { "movx", 0xf7700000, 0xfff00000, FMT_6
, {MEM2(SD16
, AN1
), DM0
}},
209 { "movx", 0xf4b00000, 0xfff00000, FMT_7
, {MEM2(IMM24
,AN1
), DM0
}},
210 { "movx", 0xf55000, 0xfff000, FMT_5
, {DM0
, MEM2(SD8
, AN1
)}},
211 { "movx", 0xf7600000, 0xfff00000, FMT_6
, {DM0
, MEM2(SD16
, AN1
)}},
212 { "movx", 0xf4300000, 0xfff00000, FMT_7
, {DM0
, MEM2(IMM24
, AN1
)}},
214 { "movb", 0xf52000, 0xfff000, FMT_5
, {MEM2(SD8
, AN1
), DM0
}},
215 { "movb", 0xf7d00000, 0xfff00000, FMT_6
, {MEM2(SD16
, AN1
), DM0
}},
216 { "movb", 0xf4a00000, 0xfff00000, FMT_7
, {MEM2(IMM24
,AN1
), DM0
}},
217 { "movb", 0xf040, 0xffc0, FMT_4
, {MEM2(DI
, AN1
), DM0
}},
218 { "movb", 0xf4c40000, 0xfffc0000, FMT_7
, {MEM(IMM24_MEM
), DN0
}},
219 { "movb", 0x10, 0xf0, FMT_1
, {DM0
, MEM(AN1
)}},
220 { "movb", 0xf51000, 0xfff000, FMT_5
, {DM0
, MEM2(SD8
, AN1
)}},
221 { "movb", 0xf7900000, 0xfff00000, FMT_6
, {DM0
, MEM2(SD16
, AN1
)}},
222 { "movb", 0xf4200000, 0xfff00000, FMT_7
, {DM0
, MEM2(IMM24
, AN1
)}},
223 { "movb", 0xf0c0, 0xffc0, FMT_4
, {DM0
, MEM2(DI
, AN1
)}},
224 { "movb", 0xc40000, 0xfc0000, FMT_3
, {DN0
, MEM(IMM16_MEM
)}},
225 { "movb", 0xf4440000, 0xfffc0000, FMT_7
, {DN0
, MEM(IMM24_MEM
)}},
227 { "movbu", 0x30, 0xf0, FMT_1
, {MEM(AN1
), DM0
}},
228 { "movbu", 0xf53000, 0xfff000, FMT_5
, {MEM2(SD8
, AN1
), DM0
}},
229 { "movbu", 0xf7500000, 0xfff00000, FMT_6
, {MEM2(SD16
, AN1
), DM0
}},
230 { "movbu", 0xf4900000, 0xfff00000, FMT_7
, {MEM2(IMM24
,AN1
), DM0
}},
231 { "movbu", 0xf080, 0xffc0, FMT_4
, {MEM2(DI
, AN1
), DM0
}},
232 { "movbu", 0xcc0000, 0xfc0000, FMT_3
, {MEM(IMM16_MEM
), DN0
}},
233 { "movbu", 0xf4c80000, 0xfffc0000, FMT_7
, {MEM(IMM24_MEM
), DN0
}},
235 { "ext", 0xf3c1, 0xfff3, FMT_4
, {DN1
}},
236 { "extx", 0xb0, 0xfc, FMT_1
, {DN0
}},
237 { "extxu", 0xb4, 0xfc, FMT_1
, {DN0
}},
238 { "extxb", 0xb8, 0xfc, FMT_1
, {DN0
}},
239 { "extxbu", 0xbc, 0xfc, FMT_1
, {DN0
}},
241 { "add", 0x90, 0xf0, FMT_1
, {DN1
, DM0
}},
242 { "add", 0xf200, 0xfff0, FMT_4
, {DM1
, AN0
}},
243 { "add", 0xf2c0, 0xfff0, FMT_4
, {AN1
, DM0
}},
244 { "add", 0xf240, 0xfff0, FMT_4
, {AN1
, AM0
}},
245 { "add", 0xd400, 0xfc00, FMT_2
, {SIMM8
, DN0
}},
246 { "add", 0xf7180000, 0xfffc0000, FMT_6
, {SIMM16
, DN0
}},
247 { "add", 0xf4600000, 0xfffc0000, FMT_7
, {IMM24
, DN0
}},
248 { "add", 0xd000, 0xfc00, FMT_2
, {SIMM8
, AN0
}},
249 { "add", 0xf7080000, 0xfffc0000, FMT_6
, {SIMM16
, AN0
}},
250 { "add", 0xf4640000, 0xfffc0000, FMT_7
, {IMM24
, AN0
}},
251 { "addc", 0xf280, 0xfff0, FMT_4
, {DN1
, DM0
}},
252 { "addnf", 0xf50c00, 0xfffc00, FMT_5
, {SIMM8
, AN0
}},
254 { "sub", 0xa0, 0xf0, FMT_1
, {DN1
, DM0
}},
255 { "sub", 0xf210, 0xfff0, FMT_4
, {DN1
, AN0
}},
256 { "sub", 0xf2d0, 0xfff0, FMT_4
, {AN1
, DM0
}},
257 { "sub", 0xf250, 0xfff0, FMT_4
, {AN1
, AM0
}},
258 { "sub", 0xf71c0000, 0xfffc0000, FMT_6
, {IMM16
, DN0
}},
259 { "sub", 0xf4680000, 0xfffc0000, FMT_7
, {IMM24
, DN0
}},
260 { "sub", 0xf70c0000, 0xfffc0000, FMT_6
, {IMM16
, AN0
}},
261 { "sub", 0xf46c0000, 0xfffc0000, FMT_7
, {IMM24
, AN0
}},
262 { "subc", 0xf290, 0xfff0, FMT_4
, {DN1
, DM0
}},
264 { "mul", 0xf340, 0xfff0, FMT_4
, {DN1
, DM0
}},
265 { "mulu", 0xf350, 0xfff0, FMT_4
, {DN1
, DM0
}},
267 { "divu", 0xf360, 0xfff0, FMT_4
, {DN1
, DM0
}},
269 { "cmp", 0xf390, 0xfff0, FMT_4
, {DN1
, DM0
}},
270 { "cmp", 0xf220, 0xfff0, FMT_4
, {DM1
, AN0
}},
271 { "cmp", 0xf2e0, 0xfff0, FMT_4
, {AN1
, DM0
}},
272 { "cmp", 0xf260, 0xfff0, FMT_4
, {AN1
, AM0
}},
273 { "cmp", 0xd800, 0xfc00, FMT_2
, {SIMM8
, DN0
}},
274 { "cmp", 0xf7480000, 0xfffc0000, FMT_6
, {SIMM16
, DN0
}},
275 { "cmp", 0xf4780000, 0xfffc0000, FMT_7
, {IMM24
, DN0
}},
276 { "cmp", 0xec0000, 0xfc0000, FMT_3
, {IMM16
, AN0
}},
277 { "cmp", 0xf47c0000, 0xfffc0000, FMT_7
, {IMM24
, AN0
}},
279 { "and", 0xf300, 0xfff0, FMT_4
, {DN1
, DM0
}},
280 { "and", 0xf50000, 0xfffc00, FMT_5
, {IMM8
, DN0
}},
281 { "and", 0xf7000000, 0xfffc0000, FMT_6
, {SIMM16N
, DN0
}},
282 { "and", 0xf7100000, 0xffff0000, FMT_6
, {SIMM16N
, PSW
}},
283 { "or", 0xf310, 0xfff0, FMT_4
, {DN1
, DM0
}},
284 { "or", 0xf50800, 0xfffc00, FMT_5
, {IMM8
, DN0
}},
285 { "or", 0xf7400000, 0xfffc0000, FMT_6
, {SIMM16N
, DN0
}},
286 { "or", 0xf7140000, 0xffff0000, FMT_6
, {SIMM16N
, PSW
}},
287 { "xor", 0xf320, 0xfff0, FMT_4
, {DN1
, DM0
}},
288 { "xor", 0xf74c0000, 0xfffc0000, FMT_6
, {SIMM16N
, DN0
}},
289 { "not", 0xf3e4, 0xfffc, FMT_4
, {DN0
}},
291 { "asr", 0xf338, 0xfffc, FMT_4
, {DN0
}},
292 { "lsr", 0xf33c, 0xfffc, FMT_4
, {DN0
}},
293 { "ror", 0xf334, 0xfffc, FMT_4
, {DN0
}},
294 { "rol", 0xf330, 0xfffc, FMT_4
, {DN0
}},
296 { "btst", 0xf50400, 0xfffc00, FMT_5
, {IMM8
, DN0
}},
297 { "btst", 0xf7040000, 0xfffc0000, FMT_6
, {SIMM16N
, DN0
}},
298 { "bset", 0xf020, 0xfff0, FMT_4
, {DM0
, MEM(AN1
)}},
299 { "bclr", 0xf030, 0xfff0, FMT_4
, {DM0
, MEM(AN1
)}},
301 { "beq", 0xe800, 0xff00, FMT_2
, {SD8N_PCREL
}},
302 { "bne", 0xe900, 0xff00, FMT_2
, {SD8N_PCREL
}},
303 { "blt", 0xe000, 0xff00, FMT_2
, {SD8N_PCREL
}},
304 { "ble", 0xe300, 0xff00, FMT_2
, {SD8N_PCREL
}},
305 { "bge", 0xe200, 0xff00, FMT_2
, {SD8N_PCREL
}},
306 { "bgt", 0xe100, 0xff00, FMT_2
, {SD8N_PCREL
}},
307 { "bcs", 0xe400, 0xff00, FMT_2
, {SD8N_PCREL
}},
308 { "bls", 0xe700, 0xff00, FMT_2
, {SD8N_PCREL
}},
309 { "bcc", 0xe600, 0xff00, FMT_2
, {SD8N_PCREL
}},
310 { "bhi", 0xe500, 0xff00, FMT_2
, {SD8N_PCREL
}},
311 { "bvc", 0xf5fc00, 0xffff00, FMT_5
, {SD8N_PCREL
}},
312 { "bvs", 0xf5fd00, 0xffff00, FMT_5
, {SD8N_PCREL
}},
313 { "bnc", 0xf5fe00, 0xffff00, FMT_5
, {SD8N_PCREL
}},
314 { "bns", 0xf5ff00, 0xffff00, FMT_5
, {SD8N_PCREL
}},
315 { "bra", 0xea00, 0xff00, FMT_2
, {SD8N_PCREL
}},
317 { "beqx", 0xf5e800, 0xffff00, FMT_5
, {SD8N_PCREL
}},
318 { "bnex", 0xf5e900, 0xffff00, FMT_5
, {SD8N_PCREL
}},
319 { "bltx", 0xf5e000, 0xffff00, FMT_5
, {SD8N_PCREL
}},
320 { "blex", 0xf5e300, 0xffff00, FMT_5
, {SD8N_PCREL
}},
321 { "bgex", 0xf5e200, 0xffff00, FMT_5
, {SD8N_PCREL
}},
322 { "bgtx", 0xf5e100, 0xffff00, FMT_5
, {SD8N_PCREL
}},
323 { "bcsx", 0xf5e400, 0xffff00, FMT_5
, {SD8N_PCREL
}},
324 { "blsx", 0xf5e700, 0xffff00, FMT_5
, {SD8N_PCREL
}},
325 { "bccx", 0xf5e600, 0xffff00, FMT_5
, {SD8N_PCREL
}},
326 { "bhix", 0xf5e500, 0xffff00, FMT_5
, {SD8N_PCREL
}},
327 { "bvcx", 0xf5ec00, 0xffff00, FMT_5
, {SD8N_PCREL
}},
328 { "bvsx", 0xf5ed00, 0xffff00, FMT_5
, {SD8N_PCREL
}},
329 { "bncx", 0xf5ee00, 0xffff00, FMT_5
, {SD8N_PCREL
}},
330 { "bnsx", 0xf5ef00, 0xffff00, FMT_5
, {SD8N_PCREL
}},
332 { "jmp", 0xfc0000, 0xff0000, FMT_3
, {IMM16_PCREL
}},
333 { "jmp", 0xf4e00000, 0xffff0000, FMT_7
, {IMM24_PCREL
}},
334 { "jmp", 0xf000, 0xfff3, FMT_4
, {PAREN
,AN1
,PAREN
}},
335 { "jsr", 0xfd0000, 0xff0000, FMT_3
, {IMM16_PCREL
}},
336 { "jsr", 0xf4e10000, 0xffff0000, FMT_7
, {IMM24_PCREL
}},
337 { "jsr", 0xf001, 0xfff3, FMT_4
, {PAREN
,AN1
,PAREN
}},
339 { "nop", 0xf6, 0xff, FMT_1
, {UNUSED
}},
341 { "rts", 0xfe, 0xff, FMT_1
, {UNUSED
}},
342 { "rti", 0xeb, 0xff, FMT_1
, {UNUSED
}},
344 /* Extension. We need some instruction to trigger "emulated syscalls"
345 for our simulator. */
346 { "syscall", 0xf010, 0xffff, FMT_4
, {UNUSED
}},
348 /* Extension. When talking to the simulator, gdb requires some instruction
349 that will trigger a "breakpoint" (really just an instruction that isn't
350 otherwise used by the tools. This instruction must be the same size
351 as the smallest instruction on the target machine. In the case of the
352 mn10x00 the "break" instruction must be one byte. 0xff is available on
353 both mn10x00 architectures. */
354 { "break", 0xff, 0xff, FMT_1
, {UNUSED
}},
360 const int mn10200_num_opcodes
=
361 sizeof (mn10200_opcodes
) / sizeof (mn10200_opcodes
[0]);
projects / thirdparty / binutils-gdb.git / blob