1 /* Assemble V850 instructions.
2 Copyright (C) 1996 Free Software Foundation, Inc.
4 This program is free software; you can redistribute it and/or modify
5 it under the terms of the GNU General Public License as published by
6 the Free Software Foundation; either version 2 of the License, or
7 (at your option) any later version.
9 This program is distributed in the hope that it will be useful,
10 but WITHOUT ANY WARRANTY; without even the implied warranty of
11 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 GNU General Public License for more details.
14 You should have received a copy of the GNU General Public License
15 along with this program; if not, write to the Free Software
16 Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
19 #include "opcode/v850.h"
24 #define OP(x) ((x & 0x3f) << 5)
25 #define OP_MASK OP (0x3f)
27 /* conditional branch opcode */
28 #define BOP(x) ((0x0b << 7) | (x & 0x0f))
29 #define BOP_MASK ((0x0f << 7) | 0x0f)
31 /* one-word opcodes */
32 #define one(x) ((unsigned int) (x))
34 /* two-word opcodes */
35 #define two(x,y) ((unsigned int) (x) | ((unsigned int) (y) << 16))
39 /* The functions used to insert and extract complicated operands. */
41 /* Note: There is a conspiracy between these functions and
42 v850_insert_operand() in gas/config/tc-v850.c. Error messages
43 containing the string 'out of range' will be ignored unless a
44 specific command line option is given to GAS. */
46 static const char * not_valid
= N_ ("displacement value is not in range and is not aligned");
47 static const char * out_of_range
= N_ ("displacement value is out of range");
48 static const char * not_aligned
= N_ ("displacement value is not aligned");
50 static const char * immediate_out_of_range
= N_ ("immediate value is out of range");
53 insert_d9 (insn
, value
, errmsg
)
58 if (value
> 0xff || value
< -0x100)
61 * errmsg
= _("branch value not in range and to odd offset");
63 * errmsg
= _("branch value out of range");
65 else if ((value
% 2) != 0)
66 * errmsg
= _("branch to odd offset");
68 return (insn
| ((value
& 0x1f0) << 7) | ((value
& 0x0e) << 3));
72 extract_d9 (insn
, invalid
)
76 unsigned long ret
= ((insn
& 0xf800) >> 7) | ((insn
& 0x0070) >> 3);
78 if ((insn
& 0x8000) != 0)
85 insert_d22 (insn
, value
, errmsg
)
90 if (value
> 0x1fffff || value
< -0x200000)
93 * errmsg
= _("branch value not in range and to an odd offset");
95 * errmsg
= _("branch value out of range");
97 else if ((value
% 2) != 0)
98 * errmsg
= _("branch to odd offset");
100 return (insn
| ((value
& 0xfffe) << 16) | ((value
& 0x3f0000) >> 16));
104 extract_d22 (insn
, invalid
)
108 signed long ret
= ((insn
& 0xfffe0000) >> 16) | ((insn
& 0x3f) << 16);
110 return (unsigned long) ((ret
<< 10) >> 10);
114 insert_d16_15 (insn
, value
, errmsg
)
117 const char ** errmsg
;
119 if (value
> 0x7fff || value
< -0x8000)
121 if ((value
% 2) != 0)
122 * errmsg
= _(not_valid
);
124 * errmsg
= _(out_of_range
);
126 else if ((value
% 2) != 0)
127 * errmsg
= _(not_aligned
);
129 return insn
| ((value
& 0xfffe) << 16);
133 extract_d16_15 (insn
, invalid
)
137 signed long ret
= (insn
& 0xfffe0000);
143 insert_d8_7 (insn
, value
, errmsg
)
146 const char ** errmsg
;
148 if (value
> 0xff || value
< 0)
150 if ((value
% 2) != 0)
151 * errmsg
= _(not_valid
);
153 * errmsg
= _(out_of_range
);
155 else if ((value
% 2) != 0)
156 * errmsg
= _(not_aligned
);
160 return (insn
| (value
& 0x7f));
164 extract_d8_7 (insn
, invalid
)
168 unsigned long ret
= (insn
& 0x7f);
174 insert_d8_6 (insn
, value
, errmsg
)
177 const char ** errmsg
;
179 if (value
> 0xff || value
< 0)
181 if ((value
% 4) != 0)
182 *errmsg
= _(not_valid
);
184 * errmsg
= _(out_of_range
);
186 else if ((value
% 4) != 0)
187 * errmsg
= _(not_aligned
);
191 return (insn
| (value
& 0x7e));
195 extract_d8_6 (insn
, invalid
)
199 unsigned long ret
= (insn
& 0x7e);
205 insert_d5_4 (insn
, value
, errmsg
)
208 const char ** errmsg
;
210 if (value
> 0x1f || value
< 0)
213 * errmsg
= _(not_valid
);
215 *errmsg
= _(out_of_range
);
218 * errmsg
= _(not_aligned
);
222 return (insn
| (value
& 0x0f));
226 extract_d5_4 (insn
, invalid
)
230 unsigned long ret
= (insn
& 0x0f);
236 insert_d16_16 (insn
, value
, errmsg
)
239 const char ** errmsg
;
241 if (value
> 0x7fff || value
< -0x8000)
242 * errmsg
= _(out_of_range
);
244 return (insn
| ((value
& 0xfffe) << 16) | ((value
& 1) << 5));
248 extract_d16_16 (insn
, invalid
)
252 signed long ret
= insn
& 0xfffe0000;
256 ret
|= ((insn
& 0x20) >> 5);
262 insert_i9 (insn
, value
, errmsg
)
265 const char ** errmsg
;
267 if (value
> 0xff || value
< -0x100)
268 * errmsg
= _(immediate_out_of_range
);
270 return insn
| ((value
& 0x1e0) << 13) | (value
& 0x1f);
274 extract_i9 (insn
, invalid
)
278 signed long ret
= insn
& 0x003c0000;
283 ret
|= (insn
& 0x1f);
289 insert_u9 (insn
, value
, errmsg
)
292 const char ** errmsg
;
295 * errmsg
= _(immediate_out_of_range
);
297 return insn
| ((value
& 0x1e0) << 13) | (value
& 0x1f);
301 extract_u9 (insn
, invalid
)
305 unsigned long ret
= insn
& 0x003c0000;
309 ret
|= (insn
& 0x1f);
315 insert_spe (insn
, value
, errmsg
)
318 const char ** errmsg
;
321 * errmsg
= _("invalid register for stack adjustment");
323 return insn
& (~ 0x180000);
327 extract_spe (insn
, invalid
)
335 insert_i5div (insn
, value
, errmsg
)
338 const char ** errmsg
;
343 * errmsg
= _("immediate value not in range and not even");
345 * errmsg
= _(immediate_out_of_range
);
348 * errmsg
= _("immediate value must be even");
352 return insn
| ((value
& 0x1e) << 17);
356 extract_i5div (insn
, invalid
)
360 unsigned long ret
= insn
& 0x3c0000;
370 /* Warning: code in gas/config/tc-v850.c examines the contents of this array.
371 If you change any of the values here, be sure to look for side effects in
373 const struct v850_operand v850_operands
[] =
376 { 0, 0, NULL
, NULL
, 0 },
378 /* The R1 field in a format 1, 6, 7, or 9 insn. */
379 #define R1 (UNUSED + 1)
380 { 5, 0, NULL
, NULL
, V850_OPERAND_REG
},
382 /* As above, but register 0 is not allowed. */
383 #define R1_NOTR0 (R1 + 1)
384 { 5, 0, NULL
, NULL
, V850_OPERAND_REG
| V850_NOT_R0
},
386 /* The R2 field in a format 1, 2, 4, 5, 6, 7, 9 insn. */
387 #define R2 (R1_NOTR0 + 1)
388 { 5, 11, NULL
, NULL
, V850_OPERAND_REG
},
390 /* As above, but register 0 is not allowed. */
391 #define R2_NOTR0 (R2 + 1)
392 { 5, 11, NULL
, NULL
, V850_OPERAND_REG
| V850_NOT_R0
},
394 /* The imm5 field in a format 2 insn. */
395 #define I5 (R2_NOTR0 + 1)
396 { 5, 0, NULL
, NULL
, V850_OPERAND_SIGNED
},
398 /* The unsigned imm5 field in a format 2 insn. */
400 { 5, 0, NULL
, NULL
, 0 },
402 /* The imm16 field in a format 6 insn. */
403 #define I16 (I5U + 1)
404 { 16, 16, NULL
, NULL
, V850_OPERAND_SIGNED
},
406 /* The signed disp7 field in a format 4 insn. */
408 { 7, 0, NULL
, NULL
, 0},
410 /* The disp16 field in a format 6 insn. */
411 #define D16_15 (D7 + 1)
412 { 15, 17, insert_d16_15
, extract_d16_15
, V850_OPERAND_SIGNED
},
414 /* The 3 bit immediate field in format 8 insn. */
415 #define B3 (D16_15 + 1)
416 { 3, 11, NULL
, NULL
, 0 },
418 /* The 4 bit condition code in a setf instruction */
419 #define CCCC (B3 + 1)
420 { 4, 0, NULL
, NULL
, V850_OPERAND_CC
},
422 /* The unsigned DISP8 field in a format 4 insn. */
423 #define D8_7 (CCCC + 1)
424 { 7, 0, insert_d8_7
, extract_d8_7
, 0 },
426 /* The unsigned DISP8 field in a format 4 insn. */
427 #define D8_6 (D8_7 + 1)
428 { 6, 1, insert_d8_6
, extract_d8_6
, 0 },
430 /* System register operands. */
431 #define SR1 (D8_6 + 1)
432 { 5, 0, NULL
, NULL
, V850_OPERAND_SRG
},
436 { 0, 0, NULL
, NULL
, V850_OPERAND_EP
},
438 /* The imm16 field (unsigned) in a format 6 insn. */
439 #define I16U (EP + 1)
440 { 16, 16, NULL
, NULL
, 0},
442 /* The R2 field as a system register. */
443 #define SR2 (I16U + 1)
444 { 5, 11, NULL
, NULL
, V850_OPERAND_SRG
},
446 /* The disp16 field in a format 8 insn. */
447 #define D16 (SR2 + 1)
448 { 16, 16, NULL
, NULL
, V850_OPERAND_SIGNED
},
450 /* The DISP9 field in a format 3 insn, relaxable. */
451 #define D9_RELAX (D16 + 1)
452 { 9, 0, insert_d9
, extract_d9
, V850_OPERAND_RELAX
| V850_OPERAND_SIGNED
| V850_OPERAND_DISP
},
454 /* The DISP22 field in a format 4 insn, relaxable.
455 This _must_ follow D9_RELAX; the assembler assumes that the longer
456 version immediately follows the shorter version for relaxing. */
457 #define D22 (D9_RELAX + 1)
458 { 22, 0, insert_d22
, extract_d22
, V850_OPERAND_SIGNED
| V850_OPERAND_DISP
},
460 /* The signed disp4 field in a format 4 insn. */
462 { 4, 0, NULL
, NULL
, 0},
464 /* The unsigned disp5 field in a format 4 insn. */
465 #define D5_4 (D4 + 1)
466 { 4, 0, insert_d5_4
, extract_d5_4
, 0 },
468 /* The disp16 field in an format 7 unsigned byte load insn. */
469 #define D16_16 (D5_4 + 1)
470 { -1, 0xfffe0020, insert_d16_16
, extract_d16_16
, 0 },
472 /* Third register in conditional moves. */
473 #define R3 (D16_16 + 1)
474 { 5, 27, NULL
, NULL
, V850_OPERAND_REG
},
476 /* Condition code in conditional moves. */
477 #define MOVCC (R3 + 1)
478 { 4, 17, NULL
, NULL
, V850_OPERAND_CC
},
480 /* The imm9 field in a multiply word. */
481 #define I9 (MOVCC + 1)
482 { 9, 0, insert_i9
, extract_i9
, V850_OPERAND_SIGNED
},
484 /* The unsigned imm9 field in a multiply word. */
486 { 9, 0, insert_u9
, extract_u9
, 0 },
488 /* A list of registers in a prepare/dispose instruction. */
489 #define LIST12 (U9 + 1)
490 { -1, 0xffe00001, NULL
, NULL
, V850E_PUSH_POP
},
492 /* The IMM6 field in a call instruction. */
493 #define I6 (LIST12 + 1)
494 { 6, 0, NULL
, NULL
, 0 },
496 /* The 16 bit immediate following a 32 bit instruction. */
497 #define IMM16 (I6 + 1)
498 { 16, 16, NULL
, NULL
, V850_OPERAND_SIGNED
| V850E_IMMEDIATE16
},
500 /* The 32 bit immediate following a 32 bit instruction. */
501 #define IMM32 (IMM16 + 1)
502 { 0, 0, NULL
, NULL
, V850E_IMMEDIATE32
},
504 /* The imm5 field in a push/pop instruction. */
505 #define IMM5 (IMM32 + 1)
506 { 5, 1, NULL
, NULL
, 0 },
508 /* Reg2 in dispose instruction. */
509 #define R2DISPOSE (IMM5 + 1)
510 { 5, 16, NULL
, NULL
, V850_OPERAND_REG
| V850_NOT_R0
},
512 /* Stack pointer in prepare instruction. */
513 #define SP (R2DISPOSE + 1)
514 { 2, 19, insert_spe
, extract_spe
, V850_OPERAND_REG
},
516 /* The IMM5 field in a divide N step instruction. */
517 #define I5DIV (SP + 1)
518 { 9, 0, insert_i5div
, extract_i5div
, V850_OPERAND_SIGNED
},
520 /* The list of registers in a PUSHMH/POPMH instruction. */
521 #define LIST18_H (I5DIV + 1)
522 { -1, 0xfff8000f, NULL
, NULL
, V850E_PUSH_POP
},
524 /* The list of registers in a PUSHML/POPML instruction. */
525 #define LIST18_L (LIST18_H + 1)
526 { -1, 0xfff8001f, NULL
, NULL
, V850E_PUSH_POP
}, /* The setting of the 4th bit is a flag to disassmble() in v850-dis.c */
530 /* reg-reg instruction format (Format I) */
533 /* imm-reg instruction format (Format II) */
536 /* conditional branch instruction format (Format III) */
537 #define IF3 {D9_RELAX}
539 /* 3 operand instruction (Format VI) */
540 #define IF6 {I16, R1, R2}
542 /* 3 operand instruction (Format VI) */
543 #define IF6U {I16U, R1, R2}
549 The format of the opcode table is:
551 NAME OPCODE MASK { OPERANDS } MEMOP PROCESSOR
553 NAME is the name of the instruction.
554 OPCODE is the instruction opcode.
555 MASK is the opcode mask; this is used to tell the disassembler
556 which bits in the actual opcode must match OPCODE.
557 OPERANDS is the list of operands.
558 MEMOP specifies which operand (if any) is a memory operand.
559 PROCESSORS specifies which CPU(s) support the opcode.
561 The disassembler reads the table in order and prints the first
562 instruction which matches, so this table is sorted to put more
563 specific instructions before more general instructions. It is also
564 sorted by major opcode.
566 The table is also sorted by name. This is used by the assembler.
567 When parsing an instruction the assembler finds the first occurance
568 of the name of the instruciton in this table and then attempts to
569 match the instruction's arguments with description of the operands
570 associated with the entry it has just found in this table. If the
571 match fails the assembler looks at the next entry in this table.
572 If that entry has the same name as the previous entry, then it
573 tries to match the instruction against that entry and so on. This
574 is how the assembler copes with multiple, different formats of the
577 const struct v850_opcode v850_opcodes
[] =
579 { "breakpoint", 0xffff, 0xffff, {UNUSED
}, 0, PROCESSOR_ALL
},
581 { "jmp", one (0x0060), one (0xffe0), {R1
}, 1, PROCESSOR_ALL
},
583 /* load/store instructions */
584 { "sld.bu", one (0x0300), one (0x0780), {D7
, EP
, R2_NOTR0
}, 1, PROCESSOR_V850EA
},
585 { "sld.bu", one (0x0060), one (0x07f0), {D4
, EP
, R2_NOTR0
}, 1, PROCESSOR_V850E
},
587 { "sld.hu", one (0x0400), one (0x0780), {D8_7
, EP
, R2_NOTR0
}, 1, PROCESSOR_V850EA
},
588 { "sld.hu", one (0x0070), one (0x07f0), {D5_4
, EP
, R2_NOTR0
}, 1, PROCESSOR_V850E
},
590 { "sld.b", one (0x0060), one (0x07f0), {D4
, EP
, R2
}, 1, PROCESSOR_V850EA
},
591 { "sld.b", one (0x0300), one (0x0780), {D7
, EP
, R2
}, 1, PROCESSOR_V850E
},
592 { "sld.b", one (0x0300), one (0x0780), {D7
, EP
, R2
}, 1, PROCESSOR_V850
},
594 { "sld.h", one (0x0070), one (0x07f0), {D5_4
, EP
, R2
}, 1, PROCESSOR_V850EA
},
595 { "sld.h", one (0x0400), one (0x0780), {D8_7
, EP
, R2
}, 1, PROCESSOR_V850E
},
596 { "sld.h", one (0x0400), one (0x0780), {D8_7
, EP
, R2
}, 1, PROCESSOR_V850
},
597 { "sld.w", one (0x0500), one (0x0781), {D8_6
, EP
, R2
}, 1, PROCESSOR_ALL
},
598 { "sst.b", one (0x0380), one (0x0780), {R2
, D7
, EP
}, 2, PROCESSOR_ALL
},
599 { "sst.h", one (0x0480), one (0x0780), {R2
, D8_7
, EP
}, 2, PROCESSOR_ALL
},
600 { "sst.w", one (0x0501), one (0x0781), {R2
, D8_6
, EP
}, 2, PROCESSOR_ALL
},
602 { "pushml", two (0x07e0, 0x0001), two (0xfff0, 0x0007), {LIST18_L
}, 0, PROCESSOR_V850EA
},
603 { "pushmh", two (0x07e0, 0x0003), two (0xfff0, 0x0007), {LIST18_H
}, 0, PROCESSOR_V850EA
},
604 { "popml", two (0x07f0, 0x0001), two (0xfff0, 0x0007), {LIST18_L
}, 0, PROCESSOR_V850EA
},
605 { "popmh", two (0x07f0, 0x0003), two (0xfff0, 0x0007), {LIST18_H
}, 0, PROCESSOR_V850EA
},
606 { "prepare", two (0x0780, 0x0003), two (0xffc0, 0x001f), {LIST12
, IMM5
, SP
}, 0, PROCESSOR_NOT_V850
},
607 { "prepare", two (0x0780, 0x000b), two (0xffc0, 0x001f), {LIST12
, IMM5
, IMM16
}, 0, PROCESSOR_NOT_V850
},
608 { "prepare", two (0x0780, 0x0013), two (0xffc0, 0x001f), {LIST12
, IMM5
, IMM16
}, 0, PROCESSOR_NOT_V850
},
609 { "prepare", two (0x0780, 0x001b), two (0xffc0, 0x001f), {LIST12
, IMM5
, IMM32
}, 0, PROCESSOR_NOT_V850
},
610 { "prepare", two (0x0780, 0x0001), two (0xffc0, 0x001f), {LIST12
, IMM5
}, 0, PROCESSOR_NOT_V850
},
611 { "dispose", one (0x0640), one (0xffc0), {IMM5
, LIST12
, R2DISPOSE
},0, PROCESSOR_NOT_V850
},
612 { "dispose", two (0x0640, 0x0000), two (0xffc0, 0x001f), {IMM5
, LIST12
}, 0, PROCESSOR_NOT_V850
},
614 { "ld.b", two (0x0700, 0x0000), two (0x07e0, 0x0000), {D16
, R1
, R2
}, 1, PROCESSOR_ALL
},
615 { "ld.h", two (0x0720, 0x0000), two (0x07e0, 0x0001), {D16_15
, R1
, R2
}, 1, PROCESSOR_ALL
},
616 { "ld.w", two (0x0720, 0x0001), two (0x07e0, 0x0001), {D16_15
, R1
, R2
}, 1, PROCESSOR_ALL
},
617 { "ld.bu", two (0x0780, 0x0001), two (0x07c0, 0x0001), {D16_16
, R1
, R2_NOTR0
}, 1, PROCESSOR_NOT_V850
},
618 { "ld.hu", two (0x07e0, 0x0001), two (0x07e0, 0x0001), {D16_15
, R1
, R2_NOTR0
}, 1, PROCESSOR_NOT_V850
},
619 { "st.b", two (0x0740, 0x0000), two (0x07e0, 0x0000), {R2
, D16
, R1
}, 2, PROCESSOR_ALL
},
620 { "st.h", two (0x0760, 0x0000), two (0x07e0, 0x0001), {R2
, D16_15
, R1
}, 2, PROCESSOR_ALL
},
621 { "st.w", two (0x0760, 0x0001), two (0x07e0, 0x0001), {R2
, D16_15
, R1
}, 2, PROCESSOR_ALL
},
623 /* byte swap/extend instructions */
624 { "zxb", one (0x0080), one (0xffe0), {R1_NOTR0
}, 0, PROCESSOR_NOT_V850
},
625 { "zxh", one (0x00c0), one (0xffe0), {R1_NOTR0
}, 0, PROCESSOR_NOT_V850
},
626 { "sxb", one (0x00a0), one (0xffe0), {R1_NOTR0
}, 0, PROCESSOR_NOT_V850
},
627 { "sxh", one (0x00e0), one (0xffe0), {R1_NOTR0
}, 0, PROCESSOR_NOT_V850
},
628 { "bsh", two (0x07e0, 0x0342), two (0x07ff, 0x07ff), {R2
, R3
}, 0, PROCESSOR_NOT_V850
},
629 { "bsw", two (0x07e0, 0x0340), two (0x07ff, 0x07ff), {R2
, R3
}, 0, PROCESSOR_NOT_V850
},
630 { "hsw", two (0x07e0, 0x0344), two (0x07ff, 0x07ff), {R2
, R3
}, 0, PROCESSOR_NOT_V850
},
632 /* jump table instructions */
633 { "switch", one (0x0040), one (0xffe0), {R1
}, 1, PROCESSOR_NOT_V850
},
634 { "callt", one (0x0200), one (0xffc0), {I6
}, 0, PROCESSOR_NOT_V850
},
635 { "ctret", two (0x07e0, 0x0144), two (0xffff, 0xffff), {0}, 0, PROCESSOR_NOT_V850
},
637 /* arithmetic operation instructions */
638 { "setf", two (0x07e0, 0x0000), two (0x07f0, 0xffff), {CCCC
, R2
}, 0, PROCESSOR_ALL
},
639 { "cmov", two (0x07e0, 0x0320), two (0x07e0, 0x07e1), {MOVCC
, R1
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
640 { "cmov", two (0x07e0, 0x0300), two (0x07e0, 0x07e1), {MOVCC
, I5
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
642 { "mul", two (0x07e0, 0x0220), two (0x07e0, 0x07ff), {R1
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
643 { "mul", two (0x07e0, 0x0240), two (0x07e0, 0x07c3), {I9
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
644 { "mulu", two (0x07e0, 0x0222), two (0x07e0, 0x07ff), {R1
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
645 { "mulu", two (0x07e0, 0x0242), two (0x07e0, 0x07c3), {U9
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
647 { "div", two (0x07e0, 0x02c0), two (0x07e0, 0x07ff), {R1
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
648 { "divu", two (0x07e0, 0x02c2), two (0x07e0, 0x07ff), {R1
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
649 { "divhu", two (0x07e0, 0x0282), two (0x07e0, 0x07ff), {R1
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
650 { "divh", two (0x07e0, 0x0280), two (0x07e0, 0x07ff), {R1
, R2
, R3
}, 0, PROCESSOR_NOT_V850
},
651 { "divh", OP (0x02), OP_MASK
, {R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
653 { "divhn", two (0x07e0, 0x0280), two (0x07e0, 0x07c3), {I5DIV
, R1
, R2
, R3
}, 0, PROCESSOR_V850EA
},
654 { "divhun", two (0x07e0, 0x0282), two (0x07e0, 0x07c3), {I5DIV
, R1
, R2
, R3
}, 0, PROCESSOR_V850EA
},
655 { "divn", two (0x07e0, 0x02c0), two (0x07e0, 0x07c3), {I5DIV
, R1
, R2
, R3
}, 0, PROCESSOR_V850EA
},
656 { "divun", two (0x07e0, 0x02c2), two (0x07e0, 0x07c3), {I5DIV
, R1
, R2
, R3
}, 0, PROCESSOR_V850EA
},
657 { "sdivhn", two (0x07e0, 0x0180), two (0x07e0, 0x07c3), {I5DIV
, R1
, R2
, R3
}, 0, PROCESSOR_V850EA
},
658 { "sdivhun", two (0x07e0, 0x0182), two (0x07e0, 0x07c3), {I5DIV
, R1
, R2
, R3
}, 0, PROCESSOR_V850EA
},
659 { "sdivn", two (0x07e0, 0x01c0), two (0x07e0, 0x07c3), {I5DIV
, R1
, R2
, R3
}, 0, PROCESSOR_V850EA
},
660 { "sdivun", two (0x07e0, 0x01c2), two (0x07e0, 0x07c3), {I5DIV
, R1
, R2
, R3
}, 0, PROCESSOR_V850EA
},
662 { "nop", one (0x00), one (0xffff), {0}, 0, PROCESSOR_ALL
},
663 { "mov", OP (0x10), OP_MASK
, {I5
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
664 { "mov", one (0x0620), one (0xffe0), {IMM32
, R1_NOTR0
}, 0, PROCESSOR_NOT_V850
},
665 { "mov", OP (0x00), OP_MASK
, {R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
666 { "movea", OP (0x31), OP_MASK
, {I16
, R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
667 { "movhi", OP (0x32), OP_MASK
, {I16U
, R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
668 { "add", OP (0x0e), OP_MASK
, IF1
, 0, PROCESSOR_ALL
},
669 { "add", OP (0x12), OP_MASK
, IF2
, 0, PROCESSOR_ALL
},
670 { "addi", OP (0x30), OP_MASK
, IF6
, 0, PROCESSOR_ALL
},
671 { "sub", OP (0x0d), OP_MASK
, IF1
, 0, PROCESSOR_ALL
},
672 { "subr", OP (0x0c), OP_MASK
, IF1
, 0, PROCESSOR_ALL
},
673 { "mulh", OP (0x17), OP_MASK
, {I5
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
674 { "mulh", OP (0x07), OP_MASK
, {R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
675 { "mulhi", OP (0x37), OP_MASK
, {I16
, R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
676 { "cmp", OP (0x0f), OP_MASK
, IF1
, 0, PROCESSOR_ALL
},
677 { "cmp", OP (0x13), OP_MASK
, IF2
, 0, PROCESSOR_ALL
},
679 /* saturated operation instructions */
680 { "satadd", OP (0x11), OP_MASK
, {I5
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
681 { "satadd", OP (0x06), OP_MASK
, {R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
682 { "satsub", OP (0x05), OP_MASK
, {R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
683 { "satsubi", OP (0x33), OP_MASK
, {I16
, R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
684 { "satsubr", OP (0x04), OP_MASK
, {R1
, R2_NOTR0
}, 0, PROCESSOR_ALL
},
686 /* logical operation instructions */
687 { "tst", OP (0x0b), OP_MASK
, IF1
, 0, PROCESSOR_ALL
},
688 { "or", OP (0x08), OP_MASK
, IF1
, 0, PROCESSOR_ALL
},
689 { "ori", OP (0x34), OP_MASK
, IF6U
, 0, PROCESSOR_ALL
},
690 { "and", OP (0x0a), OP_MASK
, IF1
, 0, PROCESSOR_ALL
},
691 { "andi", OP (0x36), OP_MASK
, IF6U
, 0, PROCESSOR_ALL
},
692 { "xor", OP (0x09), OP_MASK
, IF1
, 0, PROCESSOR_ALL
},
693 { "xori", OP (0x35), OP_MASK
, IF6U
, 0, PROCESSOR_ALL
},
694 { "not", OP (0x01), OP_MASK
, IF1
, 0, PROCESSOR_ALL
},
695 { "sar", OP (0x15), OP_MASK
, {I5U
, R2
}, 0, PROCESSOR_ALL
},
696 { "sar", two (0x07e0, 0x00a0), two (0x07e0, 0xffff), {R1
, R2
}, 0, PROCESSOR_ALL
},
697 { "shl", OP (0x16), OP_MASK
, {I5U
, R2
}, 0, PROCESSOR_ALL
},
698 { "shl", two (0x07e0, 0x00c0), two (0x07e0, 0xffff), {R1
, R2
}, 0, PROCESSOR_ALL
},
699 { "shr", OP (0x14), OP_MASK
, {I5U
, R2
}, 0, PROCESSOR_ALL
},
700 { "shr", two (0x07e0, 0x0080), two (0x07e0, 0xffff), {R1
, R2
}, 0, PROCESSOR_ALL
},
701 { "sasf", two (0x07e0, 0x0200), two (0x07f0, 0xffff), {CCCC
, R2
}, 0, PROCESSOR_NOT_V850
},
703 /* branch instructions */
705 { "bgt", BOP (0xf), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
706 { "bge", BOP (0xe), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
707 { "blt", BOP (0x6), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
708 { "ble", BOP (0x7), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
709 /* unsigned integer */
710 { "bh", BOP (0xb), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
711 { "bnh", BOP (0x3), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
712 { "bl", BOP (0x1), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
713 { "bnl", BOP (0x9), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
715 { "be", BOP (0x2), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
716 { "bne", BOP (0xa), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
718 { "bv", BOP (0x0), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
719 { "bnv", BOP (0x8), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
720 { "bn", BOP (0x4), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
721 { "bp", BOP (0xc), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
722 { "bc", BOP (0x1), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
723 { "bnc", BOP (0x9), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
724 { "bz", BOP (0x2), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
725 { "bnz", BOP (0xa), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
726 { "br", BOP (0x5), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
727 { "bsa", BOP (0xd), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
731 We use the short form in the opcode/mask fields. The assembler
732 will twiddle bits as necessary if the long form is needed. */
735 { "jgt", BOP (0xf), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
736 { "jge", BOP (0xe), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
737 { "jlt", BOP (0x6), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
738 { "jle", BOP (0x7), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
739 /* unsigned integer */
740 { "jh", BOP (0xb), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
741 { "jnh", BOP (0x3), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
742 { "jl", BOP (0x1), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
743 { "jnl", BOP (0x9), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
745 { "je", BOP (0x2), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
746 { "jne", BOP (0xa), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
748 { "jv", BOP (0x0), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
749 { "jnv", BOP (0x8), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
750 { "jn", BOP (0x4), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
751 { "jp", BOP (0xc), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
752 { "jc", BOP (0x1), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
753 { "jnc", BOP (0x9), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
754 { "jz", BOP (0x2), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
755 { "jnz", BOP (0xa), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
756 { "jsa", BOP (0xd), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
757 { "jbr", BOP (0x5), BOP_MASK
, IF3
, 0, PROCESSOR_ALL
},
759 { "jr", one (0x0780), two (0xffc0, 0x0001), {D22
}, 0, PROCESSOR_ALL
},
760 { "jarl", one (0x0780), two (0x07c0, 0x0001), {D22
, R2
}, 0, PROCESSOR_ALL
},
762 /* bit manipulation instructions */
763 { "set1", two (0x07c0, 0x0000), two (0xc7e0, 0x0000), {B3
, D16
, R1
}, 2, PROCESSOR_ALL
},
764 { "set1", two (0x07e0, 0x00e0), two (0x07e0, 0xffff), {R2
, R1
}, 2, PROCESSOR_NOT_V850
},
765 { "not1", two (0x47c0, 0x0000), two (0xc7e0, 0x0000), {B3
, D16
, R1
}, 2, PROCESSOR_ALL
},
766 { "not1", two (0x07e0, 0x00e2), two (0x07e0, 0xffff), {R2
, R1
}, 2, PROCESSOR_NOT_V850
},
767 { "clr1", two (0x87c0, 0x0000), two (0xc7e0, 0x0000), {B3
, D16
, R1
}, 2, PROCESSOR_ALL
},
768 { "clr1", two (0x07e0, 0x00e4), two (0x07e0, 0xffff), {R2
, R1
}, 2, PROCESSOR_NOT_V850
},
769 { "tst1", two (0xc7c0, 0x0000), two (0xc7e0, 0x0000), {B3
, D16
, R1
}, 2, PROCESSOR_ALL
},
770 { "tst1", two (0x07e0, 0x00e6), two (0x07e0, 0xffff), {R2
, R1
}, 2, PROCESSOR_NOT_V850
},
772 /* special instructions */
773 { "di", two (0x07e0, 0x0160), two (0xffff, 0xffff), {0}, 0, PROCESSOR_ALL
},
774 { "ei", two (0x87e0, 0x0160), two (0xffff, 0xffff), {0}, 0, PROCESSOR_ALL
},
775 { "halt", two (0x07e0, 0x0120), two (0xffff, 0xffff), {0}, 0, PROCESSOR_ALL
},
776 { "reti", two (0x07e0, 0x0140), two (0xffff, 0xffff), {0}, 0, PROCESSOR_ALL
},
777 { "trap", two (0x07e0, 0x0100), two (0xffe0, 0xffff), {I5U
}, 0, PROCESSOR_ALL
},
778 { "ldsr", two (0x07e0, 0x0020), two (0x07e0, 0xffff), {R1
, SR2
}, 0, PROCESSOR_ALL
},
779 { "stsr", two (0x07e0, 0x0040), two (0x07e0, 0xffff), {SR1
, R2
}, 0, PROCESSOR_ALL
},
780 { 0, 0, 0, {0}, 0, 0 },
784 const int v850_num_opcodes
=
785 sizeof (v850_opcodes
) / sizeof (v850_opcodes
[0]);
