1 /* rl78-parse.y Renesas RL78 parser
2 Copyright (C) 2011-2016 Free Software Foundation, Inc.
3
4 This file is part of GAS, the GNU Assembler.
5
6 GAS 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)
9 any later version.
10
11 GAS is distributed in the hope that it will be useful,
12 but WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 GNU General Public License for more details.
15
16 You should have received a copy of the GNU General Public License
17 along with GAS; see the file COPYING. If not, write to the Free
18 Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA
19 02110-1301, USA. */
20 %{
21
22 #include "as.h"
23 #include "safe-ctype.h"
24 #include "rl78-defs.h"
25
26 static int rl78_lex (void);
27
28 /* Ok, here are the rules for using these macros...
29
30 B*() is used to specify the base opcode bytes. Fields to be filled
31 in later, leave zero. Call this first.
32
33 F() and FE() are used to fill in fields within the base opcode bytes. You MUST
34 call B*() before any F() or FE().
35
36 [UN]*O*(), PC*() appends operands to the end of the opcode. You
37 must call P() and B*() before any of these, so that the fixups
38 have the right byte location.
39 O = signed, UO = unsigned, NO = negated, PC = pcrel
40
41 IMM() adds an immediate and fills in the field for it.
42 NIMM() same, but negates the immediate.
43 NBIMM() same, but negates the immediate, for sbb.
44 DSP() adds a displacement, and fills in the field for it.
45
46 Note that order is significant for the O, IMM, and DSP macros, as
47 they append their data to the operand buffer in the order that you
48 call them.
49
50 Use "disp" for displacements whenever possible; this handles the
51 "0" case properly. */
52
53 #define B1(b1) rl78_base1 (b1)
54 #define B2(b1, b2) rl78_base2 (b1, b2)
55 #define B3(b1, b2, b3) rl78_base3 (b1, b2, b3)
56 #define B4(b1, b2, b3, b4) rl78_base4 (b1, b2, b3, b4)
57
58 /* POS is bits from the MSB of the first byte to the LSB of the last byte. */
59 #define F(val,pos,sz) rl78_field (val, pos, sz)
60 #define FE(exp,pos,sz) rl78_field (exp_val (exp), pos, sz);
61
62 #define O1(v) rl78_op (v, 1, RL78REL_DATA)
63 #define O2(v) rl78_op (v, 2, RL78REL_DATA)
64 #define O3(v) rl78_op (v, 3, RL78REL_DATA)
65 #define O4(v) rl78_op (v, 4, RL78REL_DATA)
66
67 #define PC1(v) rl78_op (v, 1, RL78REL_PCREL)
68 #define PC2(v) rl78_op (v, 2, RL78REL_PCREL)
69 #define PC3(v) rl78_op (v, 3, RL78REL_PCREL)
70
71 #define IMM(v,pos) F (immediate (v, RL78REL_SIGNED, pos), pos, 2); \
72 if (v.X_op != O_constant && v.X_op != O_big) rl78_linkrelax_imm (pos)
73 #define NIMM(v,pos) F (immediate (v, RL78REL_NEGATIVE, pos), pos, 2)
74 #define NBIMM(v,pos) F (immediate (v, RL78REL_NEGATIVE_BORROW, pos), pos, 2)
75 #define DSP(v,pos,msz) if (!v.X_md) rl78_relax (RL78_RELAX_DISP, pos); \
76 else rl78_linkrelax_dsp (pos); \
77 F (displacement (v, msz), pos, 2)
78
79 #define id24(a,b2,b3) B3 (0xfb+a, b2, b3)
80
81 static int expr_is_sfr (expressionS);
82 static int expr_is_saddr (expressionS);
83 static int expr_is_word_aligned (expressionS);
84 static int exp_val (expressionS exp);
85
86 static int need_flag = 0;
87 static int rl78_in_brackets = 0;
88 static int rl78_last_token = 0;
89 static char * rl78_init_start;
90 static char * rl78_last_exp_start = 0;
91 static int rl78_bit_insn = 0;
92
93 #define YYDEBUG 1
94 #define YYERROR_VERBOSE 1
95
96 #define NOT_SADDR rl78_error ("Expression not 0xFFE20 to 0xFFF1F")
97 #define SA(e) if (!expr_is_saddr (e)) NOT_SADDR;
98
99 #define SET_SA(e) e.X_md = BFD_RELOC_RL78_SADDR
100
101 #define NOT_SFR rl78_error ("Expression not 0xFFF00 to 0xFFFFF")
102 #define SFR(e) if (!expr_is_sfr (e)) NOT_SFR;
103
104 #define NOT_SFR_OR_SADDR rl78_error ("Expression not 0xFFE20 to 0xFFFFF")
105
106 #define NOT_ES if (rl78_has_prefix()) rl78_error ("ES: prefix not allowed here");
107
108 #define WA(x) if (!expr_is_word_aligned (x)) rl78_error ("Expression not word-aligned");
109
110 #define ISA_G10(s) if (!rl78_isa_g10()) rl78_error (s " is only supported on the G10")
111 #define ISA_G13(s) if (!rl78_isa_g13()) rl78_error (s " is only supported on the G13")
112 #define ISA_G14(s) if (!rl78_isa_g14()) rl78_error (s " is only supported on the G14")
113
114 static void check_expr_is_bit_index (expressionS);
115 #define Bit(e) check_expr_is_bit_index (e);
116
117 /* Returns TRUE (non-zero) if the expression is a constant in the
118 given range. */
119 static int check_expr_is_const (expressionS, int vmin, int vmax);
120
121 /* Convert a "regb" value to a "reg_xbc" value. Error if other
122 registers are passed. Needed to avoid reduce-reduce conflicts. */
123 static int
reg_xbc(int reg)124 reg_xbc (int reg)
125 {
126 switch (reg)
127 {
128 case 0: /* X */
129 return 0x10;
130 case 3: /* B */
131 return 0x20;
132 case 2: /* C */
133 return 0x30;
134 default:
135 rl78_error ("Only X, B, or C allowed here");
136 return 0;
137 }
138 }
139
140 %}
141
142 %name-prefix="rl78_"
143
144 %union {
145 int regno;
146 expressionS exp;
147 }
148
149 %type <regno> regb regb_na regw regw_na FLAG sfr
150 %type <regno> A X B C D E H L AX BC DE HL
151 %type <exp> EXPR
152
153 %type <regno> addsub addsubw andor1 bt_bf setclr1 oneclrb oneclrw
154 %type <regno> incdec incdecw
155
156 %token A X B C D E H L AX BC DE HL
157 %token SPL SPH PSW CS ES PMC MEM
158 %token FLAG SP CY
159 %token RB0 RB1 RB2 RB3
160
161 %token EXPR UNKNOWN_OPCODE IS_OPCODE
162
163 %token DOT_S DOT_B DOT_W DOT_L DOT_A DOT_UB DOT_UW
164
165 %token ADD ADDC ADDW AND_ AND1
166 /* BC is also a register pair */
167 %token BF BH BNC BNH BNZ BR BRK BRK1 BT BTCLR BZ
168 %token CALL CALLT CLR1 CLRB CLRW CMP CMP0 CMPS CMPW
169 %token DEC DECW DI DIVHU DIVWU
170 %token EI
171 %token HALT
172 %token INC INCW
173 %token MACH MACHU MOV MOV1 MOVS MOVW MULH MULHU MULU
174 %token NOP NOT1
175 %token ONEB ONEW OR OR1
176 %token POP PUSH
177 %token RET RETI RETB ROL ROLC ROLWC ROR RORC
178 %token SAR SARW SEL SET1 SHL SHLW SHR SHRW
179 %token SKC SKH SKNC SKNH SKNZ SKZ STOP SUB SUBC SUBW
180 %token XCH XCHW XOR XOR1
181
182 %%
183 /* ====================================================================== */
184
185 statement :
186
187 UNKNOWN_OPCODE
188 { as_bad (_("Unknown opcode: %s"), rl78_init_start); }
189
190 /* The opcodes are listed in approximately alphabetical order. */
191
192 /* For reference:
193
194 sfr = special function register - symbol, 0xFFF00 to 0xFFFFF
195 sfrp = special function register - symbol, 0xFFF00 to 0xFFFFE, even only
196 saddr = 0xFFE20 to 0xFFF1F
197 saddrp = 0xFFE20 to 0xFFF1E, even only
198
199 addr20 = 0x00000 to 0xFFFFF
200 addr16 = 0x00000 to 0x0FFFF, even only for 16-bit ops
201 addr5 = 0x00000 to 0x000BE, even only
202 */
203
204 /* ---------------------------------------------------------------------- */
205
206 /* addsub is ADD, ADDC, SUB, SUBC, AND, OR, XOR, and parts of CMP. */
207
208 | addsub A ',' '#' EXPR
209 { B1 (0x0c|$1); O1 ($5); }
210
211 | addsub EXPR {SA($2)} ',' '#' EXPR
212 { B1 (0x0a|$1); SET_SA ($2); O1 ($2); O1 ($6); }
213
214 | addsub A ',' A
215 { B2 (0x61, 0x01|$1); }
216
217 | addsub A ',' regb_na
218 { B2 (0x61, 0x08|$1); F ($4, 13, 3); }
219
220 | addsub regb_na ',' A
221 { B2 (0x61, 0x00|$1); F ($2, 13, 3); }
222
223 | addsub A ',' EXPR {SA($4)}
224 { B1 (0x0b|$1); SET_SA ($4); O1 ($4); }
225
226 | addsub A ',' opt_es '!' EXPR
227 { B1 (0x0f|$1); O2 ($6); rl78_linkrelax_addr16 (); }
228
229 | addsub A ',' opt_es '[' HL ']'
230 { B1 (0x0d|$1); }
231
232 | addsub A ',' opt_es '[' HL '+' EXPR ']'
233 { B1 (0x0e|$1); O1 ($8); }
234
235 | addsub A ',' opt_es '[' HL '+' B ']'
236 { B2 (0x61, 0x80|$1); }
237
238 | addsub A ',' opt_es '[' HL '+' C ']'
239 { B2 (0x61, 0x82|$1); }
240
241 | addsub opt_es '!' EXPR ',' '#' EXPR
242 { if ($1 != 0x40)
243 { rl78_error ("Only CMP takes these operands"); }
244 else
245 { B1 (0x00|$1); O2 ($4); O1 ($7); rl78_linkrelax_addr16 (); }
246 }
247
248 /* ---------------------------------------------------------------------- */
249
250 | addsubw AX ',' '#' EXPR
251 { B1 (0x04|$1); O2 ($5); }
252
253 | addsubw AX ',' regw
254 { B1 (0x01|$1); F ($4, 5, 2); }
255
256 | addsubw AX ',' EXPR {SA($4)}
257 { B1 (0x06|$1); SET_SA ($4); O1 ($4); }
258
259 | addsubw AX ',' opt_es '!' EXPR
260 { B1 (0x02|$1); O2 ($6); rl78_linkrelax_addr16 (); }
261
262 | addsubw AX ',' opt_es '[' HL '+' EXPR ']'
263 { B2 (0x61, 0x09|$1); O1 ($8); }
264
265 | addsubw AX ',' opt_es '[' HL ']'
266 { B3 (0x61, 0x09|$1, 0); }
267
268 | addsubw SP ',' '#' EXPR
269 { B1 ($1 ? 0x20 : 0x10); O1 ($5);
270 if ($1 == 0x40)
271 rl78_error ("CMPW SP,#imm not allowed");
272 }
273
274 /* ---------------------------------------------------------------------- */
275
276 | andor1 CY ',' sfr '.' EXPR {Bit($6)}
277 { B3 (0x71, 0x08|$1, $4); FE ($6, 9, 3); }
278
279 | andor1 CY ',' EXPR '.' EXPR {Bit($6)}
280 { if (expr_is_sfr ($4))
281 { B2 (0x71, 0x08|$1); FE ($6, 9, 3); O1 ($4); }
282 else if (expr_is_saddr ($4))
283 { B2 (0x71, 0x00|$1); FE ($6, 9, 3); SET_SA ($4); O1 ($4); }
284 else
285 NOT_SFR_OR_SADDR;
286 }
287
288 | andor1 CY ',' A '.' EXPR {Bit($6)}
289 { B2 (0x71, 0x88|$1); FE ($6, 9, 3); }
290
291 | andor1 CY ',' opt_es '[' HL ']' '.' EXPR {Bit($9)}
292 { B2 (0x71, 0x80|$1); FE ($9, 9, 3); }
293
294 /* ---------------------------------------------------------------------- */
295
296 | BC '$' EXPR
297 { B1 (0xdc); PC1 ($3); rl78_linkrelax_branch (); }
298
299 | BNC '$' EXPR
300 { B1 (0xde); PC1 ($3); rl78_linkrelax_branch (); }
301
302 | BZ '$' EXPR
303 { B1 (0xdd); PC1 ($3); rl78_linkrelax_branch (); }
304
305 | BNZ '$' EXPR
306 { B1 (0xdf); PC1 ($3); rl78_linkrelax_branch (); }
307
308 | BH '$' EXPR
309 { B2 (0x61, 0xc3); PC1 ($3); rl78_linkrelax_branch (); }
310
311 | BNH '$' EXPR
312 { B2 (0x61, 0xd3); PC1 ($3); rl78_linkrelax_branch (); }
313
314 /* ---------------------------------------------------------------------- */
315
316 | bt_bf sfr '.' EXPR ',' '$' EXPR
317 { B3 (0x31, 0x80|$1, $2); FE ($4, 9, 3); PC1 ($7); }
318
319 | bt_bf EXPR '.' EXPR ',' '$' EXPR
320 { if (expr_is_sfr ($2))
321 { B2 (0x31, 0x80|$1); FE ($4, 9, 3); O1 ($2); PC1 ($7); }
322 else if (expr_is_saddr ($2))
323 { B2 (0x31, 0x00|$1); FE ($4, 9, 3); SET_SA ($2); O1 ($2); PC1 ($7); }
324 else
325 NOT_SFR_OR_SADDR;
326 }
327
328 | bt_bf A '.' EXPR ',' '$' EXPR
329 { B2 (0x31, 0x01|$1); FE ($4, 9, 3); PC1 ($7); }
330
331 | bt_bf opt_es '[' HL ']' '.' EXPR ',' '$' EXPR
332 { B2 (0x31, 0x81|$1); FE ($7, 9, 3); PC1 ($10); }
333
334 /* ---------------------------------------------------------------------- */
335
336 | BR AX
337 { B2 (0x61, 0xcb); }
338
339 | BR '$' EXPR
340 { B1 (0xef); PC1 ($3); rl78_linkrelax_branch (); }
341
342 | BR '$' '!' EXPR
343 { B1 (0xee); PC2 ($4); rl78_linkrelax_branch (); }
344
345 | BR '!' EXPR
346 { B1 (0xed); O2 ($3); rl78_linkrelax_branch (); }
347
348 | BR '!' '!' EXPR
349 { B1 (0xec); O3 ($4); rl78_linkrelax_branch (); }
350
351 /* ---------------------------------------------------------------------- */
352
353 | BRK
354 { B2 (0x61, 0xcc); }
355
356 | BRK1
357 { B1 (0xff); }
358
359 /* ---------------------------------------------------------------------- */
360
361 | CALL regw
362 { B2 (0x61, 0xca); F ($2, 10, 2); }
363
364 | CALL '$' '!' EXPR
365 { B1 (0xfe); PC2 ($4); }
366
367 | CALL '!' EXPR
368 { B1 (0xfd); O2 ($3); }
369
370 | CALL '!' '!' EXPR
371 { B1 (0xfc); O3 ($4); rl78_linkrelax_branch (); }
372
373 | CALLT '[' EXPR ']'
374 { if ($3.X_op != O_constant)
375 rl78_error ("CALLT requires a numeric address");
376 else
377 {
378 int i = $3.X_add_number;
379 if (i < 0x80 || i > 0xbe)
380 rl78_error ("CALLT address not 0x80..0xbe");
381 else if (i & 1)
382 rl78_error ("CALLT address not even");
383 else
384 {
385 B2 (0x61, 0x84);
386 F ((i >> 1) & 7, 9, 3);
387 F ((i >> 4) & 7, 14, 2);
388 }
389 }
390 }
391
392 /* ---------------------------------------------------------------------- */
393
394 | setclr1 CY
395 { B2 (0x71, $1 ? 0x88 : 0x80); }
396
397 | setclr1 sfr '.' EXPR
398 { B3 (0x71, 0x0a|$1, $2); FE ($4, 9, 3); }
399
400 | setclr1 EXPR '.' EXPR
401 { if (expr_is_sfr ($2))
402 { B2 (0x71, 0x0a|$1); FE ($4, 9, 3); O1 ($2); }
403 else if (expr_is_saddr ($2))
404 { B2 (0x71, 0x02|$1); FE ($4, 9, 3); SET_SA ($2); O1 ($2); }
405 else
406 NOT_SFR_OR_SADDR;
407 }
408
409 | setclr1 A '.' EXPR
410 { B2 (0x71, 0x8a|$1); FE ($4, 9, 3); }
411
412 | setclr1 opt_es '!' EXPR '.' EXPR
413 { B2 (0x71, 0x00+$1*0x08); FE ($6, 9, 3); O2 ($4); rl78_linkrelax_addr16 (); }
414
415 | setclr1 opt_es '[' HL ']' '.' EXPR
416 { B2 (0x71, 0x82|$1); FE ($7, 9, 3); }
417
418 /* ---------------------------------------------------------------------- */
419
420 | oneclrb A
421 { B1 (0xe1|$1); }
422 | oneclrb X
423 { B1 (0xe0|$1); }
424 | oneclrb B
425 { B1 (0xe3|$1); }
426 | oneclrb C
427 { B1 (0xe2|$1); }
428
429 | oneclrb EXPR {SA($2)}
430 { B1 (0xe4|$1); SET_SA ($2); O1 ($2); }
431
432 | oneclrb opt_es '!' EXPR
433 { B1 (0xe5|$1); O2 ($4); rl78_linkrelax_addr16 (); }
434
435 /* ---------------------------------------------------------------------- */
436
437 | oneclrw AX
438 { B1 (0xe6|$1); }
439 | oneclrw BC
440 { B1 (0xe7|$1); }
441
442 /* ---------------------------------------------------------------------- */
443
444 | CMP0 A
445 { B1 (0xd1); }
446
447 | CMP0 X
448 { B1 (0xd0); }
449
450 | CMP0 B
451 { B1 (0xd3); }
452
453 | CMP0 C
454 { B1 (0xd2); }
455
456 | CMP0 EXPR {SA($2)}
457 { B1 (0xd4); SET_SA ($2); O1 ($2); }
458
459 | CMP0 opt_es '!' EXPR
460 { B1 (0xd5); O2 ($4); rl78_linkrelax_addr16 (); }
461
462 /* ---------------------------------------------------------------------- */
463
464 | CMPS X ',' opt_es '[' HL '+' EXPR ']'
465 { B2 (0x61, 0xde); O1 ($8); }
466
467 /* ---------------------------------------------------------------------- */
468
469 | incdec regb
470 { B1 (0x80|$1); F ($2, 5, 3); }
471
472 | incdec EXPR {SA($2)}
473 { B1 (0xa4|$1); SET_SA ($2); O1 ($2); }
474 | incdec '!' EXPR
475 { B1 (0xa0|$1); O2 ($3); rl78_linkrelax_addr16 (); }
476 | incdec ES ':' '!' EXPR
477 { B2 (0x11, 0xa0|$1); O2 ($5); }
478 | incdec '[' HL '+' EXPR ']'
479 { B2 (0x61, 0x59+$1); O1 ($5); }
480 | incdec ES ':' '[' HL '+' EXPR ']'
481 { B3 (0x11, 0x61, 0x59+$1); O1 ($7); }
482
483 /* ---------------------------------------------------------------------- */
484
485 | incdecw regw
486 { B1 (0xa1|$1); F ($2, 5, 2); }
487
488 | incdecw EXPR {SA($2)}
489 { B1 (0xa6|$1); SET_SA ($2); O1 ($2); }
490
491 | incdecw opt_es '!' EXPR
492 { B1 (0xa2|$1); O2 ($4); rl78_linkrelax_addr16 (); }
493
494 | incdecw opt_es '[' HL '+' EXPR ']'
495 { B2 (0x61, 0x79+$1); O1 ($6); }
496
497 /* ---------------------------------------------------------------------- */
498
499 | DI
500 { B3 (0x71, 0x7b, 0xfa); }
501
502 | EI
503 { B3 (0x71, 0x7a, 0xfa); }
504
505 /* ---------------------------------------------------------------------- */
506
507 | MULHU { ISA_G14 ("MULHU"); }
508 { B3 (0xce, 0xfb, 0x01); }
509
510 | MULH { ISA_G14 ("MULH"); }
511 { B3 (0xce, 0xfb, 0x02); }
512
513 | MULU X
514 { B1 (0xd6); }
515
516 | DIVHU { ISA_G14 ("DIVHU"); }
517 { B3 (0xce, 0xfb, 0x03); }
518
519 /* Note that the DIVWU encoding was changed from [0xce,0xfb,0x04] to
520 [0xce,0xfb,0x0b]. Different versions of the Software Manual exist
521 with the same version number, but varying encodings. The version
522 here matches the hardware. */
523
524 | DIVWU { ISA_G14 ("DIVWU"); }
525 { B3 (0xce, 0xfb, 0x0b); }
526
527 | MACHU { ISA_G14 ("MACHU"); }
528 { B3 (0xce, 0xfb, 0x05); }
529
530 | MACH { ISA_G14 ("MACH"); }
531 { B3 (0xce, 0xfb, 0x06); }
532
533 /* ---------------------------------------------------------------------- */
534
535 | HALT
536 { B2 (0x61, 0xed); }
537
538 /* ---------------------------------------------------------------------- */
539 /* Note that opt_es is included even when it's not an option, to avoid
540 shift/reduce conflicts. The NOT_ES macro produces an error if ES:
541 is given by the user. */
542
543 | MOV A ',' '#' EXPR
544 { B1 (0x51); O1 ($5); }
545 | MOV regb_na ',' '#' EXPR
546 { B1 (0x50); F($2, 5, 3); O1 ($5); }
547
548 | MOV sfr ',' '#' EXPR
549 { if ($2 != 0xfd)
550 { B2 (0xce, $2); O1 ($5); }
551 else
552 { B1 (0x41); O1 ($5); }
553 }
554
555 | MOV opt_es EXPR ',' '#' EXPR {NOT_ES}
556 { if (expr_is_sfr ($3))
557 { B1 (0xce); O1 ($3); O1 ($6); }
558 else if (expr_is_saddr ($3))
559 { B1 (0xcd); SET_SA ($3); O1 ($3); O1 ($6); }
560 else
561 NOT_SFR_OR_SADDR;
562 }
563
564 | MOV '!' EXPR ',' '#' EXPR
565 { B1 (0xcf); O2 ($3); O1 ($6); rl78_linkrelax_addr16 (); }
566
567 | MOV ES ':' '!' EXPR ',' '#' EXPR
568 { B2 (0x11, 0xcf); O2 ($5); O1 ($8); }
569
570 | MOV regb_na ',' A
571 { B1 (0x70); F ($2, 5, 3); }
572
573 | MOV A ',' regb_na
574 { B1 (0x60); F ($4, 5, 3); }
575
576 | MOV opt_es EXPR ',' A {NOT_ES}
577 { if (expr_is_sfr ($3))
578 { B1 (0x9e); O1 ($3); }
579 else if (expr_is_saddr ($3))
580 { B1 (0x9d); SET_SA ($3); O1 ($3); }
581 else
582 NOT_SFR_OR_SADDR;
583 }
584
585 | MOV A ',' opt_es '!' EXPR
586 { B1 (0x8f); O2 ($6); rl78_linkrelax_addr16 (); }
587
588 | MOV '!' EXPR ',' A
589 { B1 (0x9f); O2 ($3); rl78_linkrelax_addr16 (); }
590
591 | MOV ES ':' '!' EXPR ',' A
592 { B2 (0x11, 0x9f); O2 ($5); }
593
594 | MOV regb_na ',' opt_es '!' EXPR
595 { B1 (0xc9|reg_xbc($2)); O2 ($6); rl78_linkrelax_addr16 (); }
596
597 | MOV A ',' opt_es EXPR {NOT_ES}
598 { if (expr_is_saddr ($5))
599 { B1 (0x8d); SET_SA ($5); O1 ($5); }
600 else if (expr_is_sfr ($5))
601 { B1 (0x8e); O1 ($5); }
602 else
603 NOT_SFR_OR_SADDR;
604 }
605
606 | MOV regb_na ',' opt_es EXPR {SA($5)} {NOT_ES}
607 { B1 (0xc8|reg_xbc($2)); SET_SA ($5); O1 ($5); }
608
609 | MOV A ',' sfr
610 { B2 (0x8e, $4); }
611
612 | MOV sfr ',' regb
613 { if ($4 != 1)
614 rl78_error ("Only A allowed here");
615 else
616 { B2 (0x9e, $2); }
617 }
618
619 | MOV sfr ',' opt_es EXPR {SA($5)} {NOT_ES}
620 { if ($2 != 0xfd)
621 rl78_error ("Only ES allowed here");
622 else
623 { B2 (0x61, 0xb8); SET_SA ($5); O1 ($5); }
624 }
625
626 | MOV A ',' opt_es '[' DE ']'
627 { B1 (0x89); }
628
629 | MOV opt_es '[' DE ']' ',' A
630 { B1 (0x99); }
631
632 | MOV opt_es '[' DE '+' EXPR ']' ',' '#' EXPR
633 { B1 (0xca); O1 ($6); O1 ($10); }
634
635 | MOV A ',' opt_es '[' DE '+' EXPR ']'
636 { B1 (0x8a); O1 ($8); }
637
638 | MOV opt_es '[' DE '+' EXPR ']' ',' A
639 { B1 (0x9a); O1 ($6); }
640
641 | MOV A ',' opt_es '[' HL ']'
642 { B1 (0x8b); }
643
644 | MOV opt_es '[' HL ']' ',' A
645 { B1 (0x9b); }
646
647 | MOV opt_es '[' HL '+' EXPR ']' ',' '#' EXPR
648 { B1 (0xcc); O1 ($6); O1 ($10); }
649
650 | MOV A ',' opt_es '[' HL '+' EXPR ']'
651 { B1 (0x8c); O1 ($8); }
652
653 | MOV opt_es '[' HL '+' EXPR ']' ',' A
654 { B1 (0x9c); O1 ($6); }
655
656 | MOV A ',' opt_es '[' HL '+' B ']'
657 { B2 (0x61, 0xc9); }
658
659 | MOV opt_es '[' HL '+' B ']' ',' A
660 { B2 (0x61, 0xd9); }
661
662 | MOV A ',' opt_es '[' HL '+' C ']'
663 { B2 (0x61, 0xe9); }
664
665 | MOV opt_es '[' HL '+' C ']' ',' A
666 { B2 (0x61, 0xf9); }
667
668 | MOV opt_es EXPR '[' B ']' ',' '#' EXPR
669 { B1 (0x19); O2 ($3); O1 ($9); }
670
671 | MOV A ',' opt_es EXPR '[' B ']'
672 { B1 (0x09); O2 ($5); }
673
674 | MOV opt_es EXPR '[' B ']' ',' A
675 { B1 (0x18); O2 ($3); }
676
677 | MOV opt_es EXPR '[' C ']' ',' '#' EXPR
678 { B1 (0x38); O2 ($3); O1 ($9); }
679
680 | MOV A ',' opt_es EXPR '[' C ']'
681 { B1 (0x29); O2 ($5); }
682
683 | MOV opt_es EXPR '[' C ']' ',' A
684 { B1 (0x28); O2 ($3); }
685
686 | MOV opt_es EXPR '[' BC ']' ',' '#' EXPR
687 { B1 (0x39); O2 ($3); O1 ($9); }
688
689 | MOV opt_es '[' BC ']' ',' '#' EXPR
690 { B3 (0x39, 0, 0); O1 ($8); }
691
692 | MOV A ',' opt_es EXPR '[' BC ']'
693 { B1 (0x49); O2 ($5); }
694
695 | MOV A ',' opt_es '[' BC ']'
696 { B3 (0x49, 0, 0); }
697
698 | MOV opt_es EXPR '[' BC ']' ',' A
699 { B1 (0x48); O2 ($3); }
700
701 | MOV opt_es '[' BC ']' ',' A
702 { B3 (0x48, 0, 0); }
703
704 | MOV opt_es '[' SP '+' EXPR ']' ',' '#' EXPR {NOT_ES}
705 { B1 (0xc8); O1 ($6); O1 ($10); }
706
707 | MOV opt_es '[' SP ']' ',' '#' EXPR {NOT_ES}
708 { B2 (0xc8, 0); O1 ($8); }
709
710 | MOV A ',' opt_es '[' SP '+' EXPR ']' {NOT_ES}
711 { B1 (0x88); O1 ($8); }
712
713 | MOV A ',' opt_es '[' SP ']' {NOT_ES}
714 { B2 (0x88, 0); }
715
716 | MOV opt_es '[' SP '+' EXPR ']' ',' A {NOT_ES}
717 { B1 (0x98); O1 ($6); }
718
719 | MOV opt_es '[' SP ']' ',' A {NOT_ES}
720 { B2 (0x98, 0); }
721
722 /* ---------------------------------------------------------------------- */
723
724 | mov1 CY ',' EXPR '.' EXPR
725 { if (expr_is_saddr ($4))
726 { B2 (0x71, 0x04); FE ($6, 9, 3); SET_SA ($4); O1 ($4); }
727 else if (expr_is_sfr ($4))
728 { B2 (0x71, 0x0c); FE ($6, 9, 3); O1 ($4); }
729 else
730 NOT_SFR_OR_SADDR;
731 }
732
733 | mov1 CY ',' A '.' EXPR
734 { B2 (0x71, 0x8c); FE ($6, 9, 3); }
735
736 | mov1 CY ',' sfr '.' EXPR
737 { B3 (0x71, 0x0c, $4); FE ($6, 9, 3); }
738
739 | mov1 CY ',' opt_es '[' HL ']' '.' EXPR
740 { B2 (0x71, 0x84); FE ($9, 9, 3); }
741
742 | mov1 EXPR '.' EXPR ',' CY
743 { if (expr_is_saddr ($2))
744 { B2 (0x71, 0x01); FE ($4, 9, 3); SET_SA ($2); O1 ($2); }
745 else if (expr_is_sfr ($2))
746 { B2 (0x71, 0x09); FE ($4, 9, 3); O1 ($2); }
747 else
748 NOT_SFR_OR_SADDR;
749 }
750
751 | mov1 A '.' EXPR ',' CY
752 { B2 (0x71, 0x89); FE ($4, 9, 3); }
753
754 | mov1 sfr '.' EXPR ',' CY
755 { B3 (0x71, 0x09, $2); FE ($4, 9, 3); }
756
757 | mov1 opt_es '[' HL ']' '.' EXPR ',' CY
758 { B2 (0x71, 0x81); FE ($7, 9, 3); }
759
760 /* ---------------------------------------------------------------------- */
761
762 | MOVS opt_es '[' HL '+' EXPR ']' ',' X
763 { B2 (0x61, 0xce); O1 ($6); }
764
765 /* ---------------------------------------------------------------------- */
766
767 | MOVW AX ',' '#' EXPR
768 { B1 (0x30); O2 ($5); }
769
770 | MOVW regw_na ',' '#' EXPR
771 { B1 (0x30); F ($2, 5, 2); O2 ($5); }
772
773 | MOVW opt_es EXPR ',' '#' EXPR {NOT_ES}
774 { if (expr_is_saddr ($3))
775 { B1 (0xc9); SET_SA ($3); O1 ($3); O2 ($6); }
776 else if (expr_is_sfr ($3))
777 { B1 (0xcb); O1 ($3); O2 ($6); }
778 else
779 NOT_SFR_OR_SADDR;
780 }
781
782 | MOVW AX ',' opt_es EXPR {NOT_ES}
783 { if (expr_is_saddr ($5))
784 { B1 (0xad); SET_SA ($5); O1 ($5); WA($5); }
785 else if (expr_is_sfr ($5))
786 { B1 (0xae); O1 ($5); WA($5); }
787 else
788 NOT_SFR_OR_SADDR;
789 }
790
791 | MOVW opt_es EXPR ',' AX {NOT_ES}
792 { if (expr_is_saddr ($3))
793 { B1 (0xbd); SET_SA ($3); O1 ($3); WA($3); }
794 else if (expr_is_sfr ($3))
795 { B1 (0xbe); O1 ($3); WA($3); }
796 else
797 NOT_SFR_OR_SADDR;
798 }
799
800 | MOVW AX ',' regw_na
801 { B1 (0x11); F ($4, 5, 2); }
802
803 | MOVW regw_na ',' AX
804 { B1 (0x10); F ($2, 5, 2); }
805
806 | MOVW AX ',' opt_es '!' EXPR
807 { B1 (0xaf); O2 ($6); WA($6); rl78_linkrelax_addr16 (); }
808
809 | MOVW opt_es '!' EXPR ',' AX
810 { B1 (0xbf); O2 ($4); WA($4); rl78_linkrelax_addr16 (); }
811
812 | MOVW AX ',' opt_es '[' DE ']'
813 { B1 (0xa9); }
814
815 | MOVW opt_es '[' DE ']' ',' AX
816 { B1 (0xb9); }
817
818 | MOVW AX ',' opt_es '[' DE '+' EXPR ']'
819 { B1 (0xaa); O1 ($8); }
820
821 | MOVW opt_es '[' DE '+' EXPR ']' ',' AX
822 { B1 (0xba); O1 ($6); }
823
824 | MOVW AX ',' opt_es '[' HL ']'
825 { B1 (0xab); }
826
827 | MOVW opt_es '[' HL ']' ',' AX
828 { B1 (0xbb); }
829
830 | MOVW AX ',' opt_es '[' HL '+' EXPR ']'
831 { B1 (0xac); O1 ($8); }
832
833 | MOVW opt_es '[' HL '+' EXPR ']' ',' AX
834 { B1 (0xbc); O1 ($6); }
835
836 | MOVW AX ',' opt_es EXPR '[' B ']'
837 { B1 (0x59); O2 ($5); }
838
839 | MOVW opt_es EXPR '[' B ']' ',' AX
840 { B1 (0x58); O2 ($3); }
841
842 | MOVW AX ',' opt_es EXPR '[' C ']'
843 { B1 (0x69); O2 ($5); }
844
845 | MOVW opt_es EXPR '[' C ']' ',' AX
846 { B1 (0x68); O2 ($3); }
847
848 | MOVW AX ',' opt_es EXPR '[' BC ']'
849 { B1 (0x79); O2 ($5); }
850
851 | MOVW AX ',' opt_es '[' BC ']'
852 { B3 (0x79, 0, 0); }
853
854 | MOVW opt_es EXPR '[' BC ']' ',' AX
855 { B1 (0x78); O2 ($3); }
856
857 | MOVW opt_es '[' BC ']' ',' AX
858 { B3 (0x78, 0, 0); }
859
860 | MOVW AX ',' opt_es '[' SP '+' EXPR ']' {NOT_ES}
861 { B1 (0xa8); O1 ($8); WA($8);}
862
863 | MOVW AX ',' opt_es '[' SP ']' {NOT_ES}
864 { B2 (0xa8, 0); }
865
866 | MOVW opt_es '[' SP '+' EXPR ']' ',' AX {NOT_ES}
867 { B1 (0xb8); O1 ($6); WA($6); }
868
869 | MOVW opt_es '[' SP ']' ',' AX {NOT_ES}
870 { B2 (0xb8, 0); }
871
872 | MOVW regw_na ',' EXPR {SA($4)}
873 { B1 (0xca); F ($2, 2, 2); SET_SA ($4); O1 ($4); WA($4); }
874
875 | MOVW regw_na ',' opt_es '!' EXPR
876 { B1 (0xcb); F ($2, 2, 2); O2 ($6); WA($6); rl78_linkrelax_addr16 (); }
877
878 | MOVW SP ',' '#' EXPR
879 { B2 (0xcb, 0xf8); O2 ($5); }
880
881 | MOVW SP ',' AX
882 { B2 (0xbe, 0xf8); }
883
884 | MOVW AX ',' SP
885 { B2 (0xae, 0xf8); }
886
887 | MOVW regw_na ',' SP
888 { B3 (0xcb, 0xf8, 0xff); F ($2, 2, 2); }
889
890 /* ---------------------------------------------------------------------- */
891
892 | NOP
893 { B1 (0x00); }
894
895 /* ---------------------------------------------------------------------- */
896
897 | NOT1 CY
898 { B2 (0x71, 0xc0); }
899
900 /* ---------------------------------------------------------------------- */
901
902 | POP regw
903 { B1 (0xc0); F ($2, 5, 2); }
904
905 | POP PSW
906 { B2 (0x61, 0xcd); };
907
908 | PUSH regw
909 { B1 (0xc1); F ($2, 5, 2); }
910
911 | PUSH PSW
912 { B2 (0x61, 0xdd); };
913
914 /* ---------------------------------------------------------------------- */
915
916 | RET
917 { B1 (0xd7); }
918
919 | RETI
920 { B2 (0x61, 0xfc); }
921
922 | RETB
923 { B2 (0x61, 0xec); }
924
925 /* ---------------------------------------------------------------------- */
926
927 | ROL A ',' EXPR
928 { if (check_expr_is_const ($4, 1, 1))
929 { B2 (0x61, 0xeb); }
930 }
931
932 | ROLC A ',' EXPR
933 { if (check_expr_is_const ($4, 1, 1))
934 { B2 (0x61, 0xdc); }
935 }
936
937 | ROLWC AX ',' EXPR
938 { if (check_expr_is_const ($4, 1, 1))
939 { B2 (0x61, 0xee); }
940 }
941
942 | ROLWC BC ',' EXPR
943 { if (check_expr_is_const ($4, 1, 1))
944 { B2 (0x61, 0xfe); }
945 }
946
947 | ROR A ',' EXPR
948 { if (check_expr_is_const ($4, 1, 1))
949 { B2 (0x61, 0xdb); }
950 }
951
952 | RORC A ',' EXPR
953 { if (check_expr_is_const ($4, 1, 1))
954 { B2 (0x61, 0xfb);}
955 }
956
957 /* ---------------------------------------------------------------------- */
958
959 | SAR A ',' EXPR
960 { if (check_expr_is_const ($4, 1, 7))
961 { B2 (0x31, 0x0b); FE ($4, 9, 3); }
962 }
963
964 | SARW AX ',' EXPR
965 { if (check_expr_is_const ($4, 1, 15))
966 { B2 (0x31, 0x0f); FE ($4, 8, 4); }
967 }
968
969 /* ---------------------------------------------------------------------- */
970
971 | SEL RB0
972 { B2 (0x61, 0xcf); }
973
974 | SEL RB1
975 { B2 (0x61, 0xdf); }
976
977 | SEL RB2
978 { B2 (0x61, 0xef); }
979
980 | SEL RB3
981 { B2 (0x61, 0xff); }
982
983 /* ---------------------------------------------------------------------- */
984
985 | SHL A ',' EXPR
986 { if (check_expr_is_const ($4, 1, 7))
987 { B2 (0x31, 0x09); FE ($4, 9, 3); }
988 }
989
990 | SHL B ',' EXPR
991 { if (check_expr_is_const ($4, 1, 7))
992 { B2 (0x31, 0x08); FE ($4, 9, 3); }
993 }
994
995 | SHL C ',' EXPR
996 { if (check_expr_is_const ($4, 1, 7))
997 { B2 (0x31, 0x07); FE ($4, 9, 3); }
998 }
999
1000 | SHLW AX ',' EXPR
1001 { if (check_expr_is_const ($4, 1, 15))
1002 { B2 (0x31, 0x0d); FE ($4, 8, 4); }
1003 }
1004
1005 | SHLW BC ',' EXPR
1006 { if (check_expr_is_const ($4, 1, 15))
1007 { B2 (0x31, 0x0c); FE ($4, 8, 4); }
1008 }
1009
1010 /* ---------------------------------------------------------------------- */
1011
1012 | SHR A ',' EXPR
1013 { if (check_expr_is_const ($4, 1, 7))
1014 { B2 (0x31, 0x0a); FE ($4, 9, 3); }
1015 }
1016
1017 | SHRW AX ',' EXPR
1018 { if (check_expr_is_const ($4, 1, 15))
1019 { B2 (0x31, 0x0e); FE ($4, 8, 4); }
1020 }
1021
1022 /* ---------------------------------------------------------------------- */
1023
1024 | SKC
1025 { B2 (0x61, 0xc8); rl78_relax (RL78_RELAX_BRANCH, 0); }
1026
1027 | SKH
1028 { B2 (0x61, 0xe3); rl78_relax (RL78_RELAX_BRANCH, 0); }
1029
1030 | SKNC
1031 { B2 (0x61, 0xd8); rl78_relax (RL78_RELAX_BRANCH, 0); }
1032
1033 | SKNH
1034 { B2 (0x61, 0xf3); rl78_relax (RL78_RELAX_BRANCH, 0); }
1035
1036 | SKNZ
1037 { B2 (0x61, 0xf8); rl78_relax (RL78_RELAX_BRANCH, 0); }
1038
1039 | SKZ
1040 { B2 (0x61, 0xe8); rl78_relax (RL78_RELAX_BRANCH, 0); }
1041
1042 /* ---------------------------------------------------------------------- */
1043
1044 | STOP
1045 { B2 (0x61, 0xfd); }
1046
1047 /* ---------------------------------------------------------------------- */
1048
1049 | XCH A ',' regb_na
1050 { if ($4 == 0) /* X */
1051 { B1 (0x08); }
1052 else
1053 { B2 (0x61, 0x88); F ($4, 13, 3); }
1054 }
1055
1056 | XCH A ',' opt_es '!' EXPR
1057 { B2 (0x61, 0xaa); O2 ($6); rl78_linkrelax_addr16 (); }
1058
1059 | XCH A ',' opt_es '[' DE ']'
1060 { B2 (0x61, 0xae); }
1061
1062 | XCH A ',' opt_es '[' DE '+' EXPR ']'
1063 { B2 (0x61, 0xaf); O1 ($8); }
1064
1065 | XCH A ',' opt_es '[' HL ']'
1066 { B2 (0x61, 0xac); }
1067
1068 | XCH A ',' opt_es '[' HL '+' EXPR ']'
1069 { B2 (0x61, 0xad); O1 ($8); }
1070
1071 | XCH A ',' opt_es '[' HL '+' B ']'
1072 { B2 (0x61, 0xb9); }
1073
1074 | XCH A ',' opt_es '[' HL '+' C ']'
1075 { B2 (0x61, 0xa9); }
1076
1077 | XCH A ',' EXPR
1078 { if (expr_is_sfr ($4))
1079 { B2 (0x61, 0xab); O1 ($4); }
1080 else if (expr_is_saddr ($4))
1081 { B2 (0x61, 0xa8); SET_SA ($4); O1 ($4); }
1082 else
1083 NOT_SFR_OR_SADDR;
1084 }
1085
1086 /* ---------------------------------------------------------------------- */
1087
1088 | XCHW AX ',' regw_na
1089 { B1 (0x31); F ($4, 5, 2); }
1090
1091 /* ---------------------------------------------------------------------- */
1092
1093 ; /* end of statement */
1094
1095 /* ---------------------------------------------------------------------- */
1096
1097 opt_es : /* nothing */
1098 | ES ':'
1099 { rl78_prefix (0x11); }
1100 ;
1101
1102 regb : X { $$ = 0; }
1103 | A { $$ = 1; }
1104 | C { $$ = 2; }
1105 | B { $$ = 3; }
1106 | E { $$ = 4; }
1107 | D { $$ = 5; }
1108 | L { $$ = 6; }
1109 | H { $$ = 7; }
1110 ;
1111
1112 regb_na : X { $$ = 0; }
1113 | C { $$ = 2; }
1114 | B { $$ = 3; }
1115 | E { $$ = 4; }
1116 | D { $$ = 5; }
1117 | L { $$ = 6; }
1118 | H { $$ = 7; }
1119 ;
1120
1121 regw : AX { $$ = 0; }
1122 | BC { $$ = 1; }
1123 | DE { $$ = 2; }
1124 | HL { $$ = 3; }
1125 ;
1126
1127 regw_na : BC { $$ = 1; }
1128 | DE { $$ = 2; }
1129 | HL { $$ = 3; }
1130 ;
1131
1132 sfr : SPL { $$ = 0xf8; }
1133 | SPH { $$ = 0xf9; }
1134 | PSW { $$ = 0xfa; }
1135 | CS { $$ = 0xfc; }
1136 | ES { $$ = 0xfd; }
1137 | PMC { $$ = 0xfe; }
1138 | MEM { $$ = 0xff; }
1139 ;
1140
1141 /* ---------------------------------------------------------------------- */
1142 /* Shortcuts for groups of opcodes with common encodings. */
1143
1144 addsub : ADD { $$ = 0x00; }
1145 | ADDC { $$ = 0x10; }
1146 | SUB { $$ = 0x20; }
1147 | SUBC { $$ = 0x30; }
1148 | CMP { $$ = 0x40; }
1149 | AND_ { $$ = 0x50; }
1150 | OR { $$ = 0x60; }
1151 | XOR { $$ = 0x70; }
1152 ;
1153
1154 addsubw : ADDW { $$ = 0x00; }
1155 | SUBW { $$ = 0x20; }
1156 | CMPW { $$ = 0x40; }
1157 ;
1158
1159 andor1 : AND1 { $$ = 0x05; rl78_bit_insn = 1; }
1160 | OR1 { $$ = 0x06; rl78_bit_insn = 1; }
1161 | XOR1 { $$ = 0x07; rl78_bit_insn = 1; }
1162 ;
1163
1164 bt_bf : BT { $$ = 0x02; rl78_bit_insn = 1; rl78_linkrelax_branch (); }
1165 | BF { $$ = 0x04; rl78_bit_insn = 1; rl78_linkrelax_branch (); }
1166 | BTCLR { $$ = 0x00; rl78_bit_insn = 1; }
1167 ;
1168
1169 setclr1 : SET1 { $$ = 0; rl78_bit_insn = 1; }
1170 | CLR1 { $$ = 1; rl78_bit_insn = 1; }
1171 ;
1172
1173 oneclrb : ONEB { $$ = 0x00; }
1174 | CLRB { $$ = 0x10; }
1175 ;
1176
1177 oneclrw : ONEW { $$ = 0x00; }
1178 | CLRW { $$ = 0x10; }
1179 ;
1180
1181 incdec : INC { $$ = 0x00; }
1182 | DEC { $$ = 0x10; }
1183 ;
1184
1185 incdecw : INCW { $$ = 0x00; }
1186 | DECW { $$ = 0x10; }
1187 ;
1188
1189 mov1 : MOV1 { rl78_bit_insn = 1; }
1190 ;
1191
1192 %%
1193 /* ====================================================================== */
1194
1195 static struct
1196 {
1197 const char * string;
1198 int token;
1199 int val;
1200 }
1201 token_table[] =
1202 {
1203 { "r0", X, 0 },
1204 { "r1", A, 1 },
1205 { "r2", C, 2 },
1206 { "r3", B, 3 },
1207 { "r4", E, 4 },
1208 { "r5", D, 5 },
1209 { "r6", L, 6 },
1210 { "r7", H, 7 },
1211 { "x", X, 0 },
1212 { "a", A, 1 },
1213 { "c", C, 2 },
1214 { "b", B, 3 },
1215 { "e", E, 4 },
1216 { "d", D, 5 },
1217 { "l", L, 6 },
1218 { "h", H, 7 },
1219
1220 { "rp0", AX, 0 },
1221 { "rp1", BC, 1 },
1222 { "rp2", DE, 2 },
1223 { "rp3", HL, 3 },
1224 { "ax", AX, 0 },
1225 { "bc", BC, 1 },
1226 { "de", DE, 2 },
1227 { "hl", HL, 3 },
1228
1229 { "RB0", RB0, 0 },
1230 { "RB1", RB1, 1 },
1231 { "RB2", RB2, 2 },
1232 { "RB3", RB3, 3 },
1233
1234 { "sp", SP, 0 },
1235 { "cy", CY, 0 },
1236
1237 { "spl", SPL, 0xf8 },
1238 { "sph", SPH, 0xf9 },
1239 { "psw", PSW, 0xfa },
1240 { "cs", CS, 0xfc },
1241 { "es", ES, 0xfd },
1242 { "pmc", PMC, 0xfe },
1243 { "mem", MEM, 0xff },
1244
1245 { ".s", DOT_S, 0 },
1246 { ".b", DOT_B, 0 },
1247 { ".w", DOT_W, 0 },
1248 { ".l", DOT_L, 0 },
1249 { ".a", DOT_A , 0},
1250 { ".ub", DOT_UB, 0 },
1251 { ".uw", DOT_UW , 0},
1252
1253 { "c", FLAG, 0 },
1254 { "z", FLAG, 1 },
1255 { "s", FLAG, 2 },
1256 { "o", FLAG, 3 },
1257 { "i", FLAG, 8 },
1258 { "u", FLAG, 9 },
1259
1260 #define OPC(x) { #x, x, IS_OPCODE }
1261
1262 OPC(ADD),
1263 OPC(ADDC),
1264 OPC(ADDW),
1265 { "and", AND_, IS_OPCODE },
1266 OPC(AND1),
1267 OPC(BC),
1268 OPC(BF),
1269 OPC(BH),
1270 OPC(BNC),
1271 OPC(BNH),
1272 OPC(BNZ),
1273 OPC(BR),
1274 OPC(BRK),
1275 OPC(BRK1),
1276 OPC(BT),
1277 OPC(BTCLR),
1278 OPC(BZ),
1279 OPC(CALL),
1280 OPC(CALLT),
1281 OPC(CLR1),
1282 OPC(CLRB),
1283 OPC(CLRW),
1284 OPC(CMP),
1285 OPC(CMP0),
1286 OPC(CMPS),
1287 OPC(CMPW),
1288 OPC(DEC),
1289 OPC(DECW),
1290 OPC(DI),
1291 OPC(DIVHU),
1292 OPC(DIVWU),
1293 OPC(EI),
1294 OPC(HALT),
1295 OPC(INC),
1296 OPC(INCW),
1297 OPC(MACH),
1298 OPC(MACHU),
1299 OPC(MOV),
1300 OPC(MOV1),
1301 OPC(MOVS),
1302 OPC(MOVW),
1303 OPC(MULH),
1304 OPC(MULHU),
1305 OPC(MULU),
1306 OPC(NOP),
1307 OPC(NOT1),
1308 OPC(ONEB),
1309 OPC(ONEW),
1310 OPC(OR),
1311 OPC(OR1),
1312 OPC(POP),
1313 OPC(PUSH),
1314 OPC(RET),
1315 OPC(RETI),
1316 OPC(RETB),
1317 OPC(ROL),
1318 OPC(ROLC),
1319 OPC(ROLWC),
1320 OPC(ROR),
1321 OPC(RORC),
1322 OPC(SAR),
1323 OPC(SARW),
1324 OPC(SEL),
1325 OPC(SET1),
1326 OPC(SHL),
1327 OPC(SHLW),
1328 OPC(SHR),
1329 OPC(SHRW),
1330 OPC(SKC),
1331 OPC(SKH),
1332 OPC(SKNC),
1333 OPC(SKNH),
1334 OPC(SKNZ),
1335 OPC(SKZ),
1336 OPC(STOP),
1337 OPC(SUB),
1338 OPC(SUBC),
1339 OPC(SUBW),
1340 OPC(XCH),
1341 OPC(XCHW),
1342 OPC(XOR),
1343 OPC(XOR1),
1344 };
1345
1346 #define NUM_TOKENS (sizeof (token_table) / sizeof (token_table[0]))
1347
1348 void
rl78_lex_init(char * beginning,char * ending)1349 rl78_lex_init (char * beginning, char * ending)
1350 {
1351 rl78_init_start = beginning;
1352 rl78_lex_start = beginning;
1353 rl78_lex_end = ending;
1354 rl78_in_brackets = 0;
1355 rl78_last_token = 0;
1356
1357 rl78_bit_insn = 0;
1358
1359 setbuf (stdout, 0);
1360 }
1361
1362 /* Return a pointer to the '.' in a bit index expression (like
1363 foo.5), or NULL if none is found. */
1364 static char *
find_bit_index(char * tok)1365 find_bit_index (char *tok)
1366 {
1367 char *last_dot = NULL;
1368 char *last_digit = NULL;
1369 while (*tok && *tok != ',')
1370 {
1371 if (*tok == '.')
1372 {
1373 last_dot = tok;
1374 last_digit = NULL;
1375 }
1376 else if (*tok >= '0' && *tok <= '7'
1377 && last_dot != NULL
1378 && last_digit == NULL)
1379 {
1380 last_digit = tok;
1381 }
1382 else if (ISSPACE (*tok))
1383 {
1384 /* skip */
1385 }
1386 else
1387 {
1388 last_dot = NULL;
1389 last_digit = NULL;
1390 }
1391 tok ++;
1392 }
1393 if (last_dot != NULL
1394 && last_digit != NULL)
1395 return last_dot;
1396 return NULL;
1397 }
1398
1399 static int
rl78_lex(void)1400 rl78_lex (void)
1401 {
1402 /*unsigned int ci;*/
1403 char * save_input_pointer;
1404 char * bit = NULL;
1405
1406 while (ISSPACE (*rl78_lex_start)
1407 && rl78_lex_start != rl78_lex_end)
1408 rl78_lex_start ++;
1409
1410 rl78_last_exp_start = rl78_lex_start;
1411
1412 if (rl78_lex_start == rl78_lex_end)
1413 return 0;
1414
1415 if (ISALPHA (*rl78_lex_start)
1416 || (*rl78_lex_start == '.' && ISALPHA (rl78_lex_start[1])))
1417 {
1418 unsigned int i;
1419 char * e;
1420 char save;
1421
1422 for (e = rl78_lex_start + 1;
1423 e < rl78_lex_end && ISALNUM (*e);
1424 e ++)
1425 ;
1426 save = *e;
1427 *e = 0;
1428
1429 for (i = 0; i < NUM_TOKENS; i++)
1430 if (strcasecmp (rl78_lex_start, token_table[i].string) == 0
1431 && !(token_table[i].val == IS_OPCODE && rl78_last_token != 0)
1432 && !(token_table[i].token == FLAG && !need_flag))
1433 {
1434 rl78_lval.regno = token_table[i].val;
1435 *e = save;
1436 rl78_lex_start = e;
1437 rl78_last_token = token_table[i].token;
1438 return token_table[i].token;
1439 }
1440 *e = save;
1441 }
1442
1443 if (rl78_last_token == 0)
1444 {
1445 rl78_last_token = UNKNOWN_OPCODE;
1446 return UNKNOWN_OPCODE;
1447 }
1448
1449 if (rl78_last_token == UNKNOWN_OPCODE)
1450 return 0;
1451
1452 if (*rl78_lex_start == '[')
1453 rl78_in_brackets = 1;
1454 if (*rl78_lex_start == ']')
1455 rl78_in_brackets = 0;
1456
1457 /* '.' is funny - the syntax includes it for bitfields, but only for
1458 bitfields. We check for it specially so we can allow labels
1459 with '.' in them. */
1460
1461 if (rl78_bit_insn
1462 && *rl78_lex_start == '.'
1463 && find_bit_index (rl78_lex_start) == rl78_lex_start)
1464 {
1465 rl78_last_token = *rl78_lex_start;
1466 return *rl78_lex_start ++;
1467 }
1468
1469 if ((rl78_in_brackets && *rl78_lex_start == '+')
1470 || strchr ("[],#!$:", *rl78_lex_start))
1471 {
1472 rl78_last_token = *rl78_lex_start;
1473 return *rl78_lex_start ++;
1474 }
1475
1476 /* Again, '.' is funny. Look for '.<digit>' at the end of the line
1477 or before a comma, which is a bitfield, not an expression. */
1478
1479 if (rl78_bit_insn)
1480 {
1481 bit = find_bit_index (rl78_lex_start);
1482 if (bit)
1483 *bit = 0;
1484 else
1485 bit = NULL;
1486 }
1487
1488 save_input_pointer = input_line_pointer;
1489 input_line_pointer = rl78_lex_start;
1490 rl78_lval.exp.X_md = 0;
1491 expression (&rl78_lval.exp);
1492
1493 if (bit)
1494 *bit = '.';
1495
1496 rl78_lex_start = input_line_pointer;
1497 input_line_pointer = save_input_pointer;
1498 rl78_last_token = EXPR;
1499 return EXPR;
1500 }
1501
1502 int
rl78_error(const char * str)1503 rl78_error (const char * str)
1504 {
1505 int len;
1506
1507 len = rl78_last_exp_start - rl78_init_start;
1508
1509 as_bad ("%s", rl78_init_start);
1510 as_bad ("%*s^ %s", len, "", str);
1511 return 0;
1512 }
1513
1514 static int
expr_is_sfr(expressionS exp)1515 expr_is_sfr (expressionS exp)
1516 {
1517 unsigned long v;
1518
1519 if (exp.X_op != O_constant)
1520 return 0;
1521
1522 v = exp.X_add_number;
1523 if (0xFFF00 <= v && v <= 0xFFFFF)
1524 return 1;
1525 return 0;
1526 }
1527
1528 static int
expr_is_saddr(expressionS exp)1529 expr_is_saddr (expressionS exp)
1530 {
1531 unsigned long v;
1532
1533 if (exp.X_op != O_constant)
1534 return 1;
1535
1536 v = exp.X_add_number;
1537 if (0xFFE20 <= v && v <= 0xFFF1F)
1538 return 1;
1539 return 0;
1540 }
1541
1542 static int
expr_is_word_aligned(expressionS exp)1543 expr_is_word_aligned (expressionS exp)
1544 {
1545 unsigned long v;
1546
1547 if (exp.X_op != O_constant)
1548 return 1;
1549
1550 v = exp.X_add_number;
1551 if (v & 1)
1552 return 0;
1553 return 1;
1554
1555 }
1556
1557 static void
check_expr_is_bit_index(expressionS exp)1558 check_expr_is_bit_index (expressionS exp)
1559 {
1560 int val;
1561
1562 if (exp.X_op != O_constant)
1563 {
1564 rl78_error (_("bit index must be a constant"));
1565 return;
1566 }
1567 val = exp.X_add_number;
1568
1569 if (val < 0 || val > 7)
1570 rl78_error (_("rtsd size must be 0..7"));
1571 }
1572
1573 static int
exp_val(expressionS exp)1574 exp_val (expressionS exp)
1575 {
1576 if (exp.X_op != O_constant)
1577 {
1578 rl78_error (_("constant expected"));
1579 return 0;
1580 }
1581 return exp.X_add_number;
1582 }
1583
1584 static int
check_expr_is_const(expressionS e,int vmin,int vmax)1585 check_expr_is_const (expressionS e, int vmin, int vmax)
1586 {
1587 static char buf[100];
1588 if (e.X_op != O_constant
1589 || e.X_add_number < vmin
1590 || e.X_add_number > vmax)
1591 {
1592 if (vmin == vmax)
1593 sprintf (buf, "%d expected here", vmin);
1594 else
1595 sprintf (buf, "%d..%d expected here", vmin, vmax);
1596 rl78_error(buf);
1597 return 0;
1598 }
1599 return 1;
1600 }
1601