* elf32-ppc.c (LWZU_0_X_11): Delete.
[binutils.git] / gas / config / tc-tahoe.c
blob435283e575f575600a3da13b145b89d1dcd92d94
1 /* This file is tc-tahoe.c
3 Copyright 1987, 1988, 1989, 1990, 1991, 1992, 1995, 2000, 2001, 2002,
4 2003, 2004, 2005 Free Software Foundation, Inc.
6 This file is part of GAS, the GNU Assembler.
8 GAS is free software; you can redistribute it and/or modify
9 it under the terms of the GNU General Public License as published by
10 the Free Software Foundation; either version 2, or (at your option)
11 any later version.
13 GAS is distributed in the hope that it will be useful,
14 but WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 GNU General Public License for more details.
18 You should have received a copy of the GNU General Public License
19 along with GAS; see the file COPYING. If not, write to the Free
20 Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA
21 02110-1301, USA. */
23 #include "as.h"
24 #include "safe-ctype.h"
25 #include "obstack.h"
27 /* This bit glommed from tahoe-inst.h. */
29 typedef unsigned char byte;
30 typedef byte tahoe_opcodeT;
32 /* This is part of tahoe-ins-parse.c & friends.
33 We want to parse a tahoe instruction text into a tree defined here. */
35 #define TIT_MAX_OPERANDS 4 /* Maximum number of operands in one
36 single tahoe instruction. */
38 struct top /* Tahoe instruction operand. */
40 int top_ndx; /* -1, or index register. eg 7=[R7]. */
41 int top_reg; /* -1, or register number. eg 7 = R7 or (R7). */
42 byte top_mode; /* Addressing mode byte. This byte, defines
43 which of the 11 modes opcode is. */
45 char top_access; /* Access type wanted for this operand
46 'b'branch ' 'no-instruction 'amrvw'. */
47 char top_width; /* Operand width expected, one of "bwlq?-:!". */
49 char * top_error; /* Say if operand is inappropriate. */
51 segT seg_of_operand; /* Segment as returned by expression(). */
53 expressionS exp_of_operand; /* The expression as parsed by expression(). */
55 byte top_dispsize; /* Number of bytes in the displacement if we
56 can figure it out. */
59 /* The addressing modes for an operand. These numbers are the actual values
60 for certain modes, so be careful if you screw with them. */
61 #define TAHOE_DIRECT_REG 0x50
62 #define TAHOE_REG_DEFERRED 0x60
64 #define TAHOE_REG_DISP 0xE0
65 #define TAHOE_REG_DISP_DEFERRED 0xF0
67 #define TAHOE_IMMEDIATE 0x8F
68 #define TAHOE_IMMEDIATE_BYTE 0x88
69 #define TAHOE_IMMEDIATE_WORD 0x89
70 #define TAHOE_IMMEDIATE_LONGWORD 0x8F
71 #define TAHOE_ABSOLUTE_ADDR 0x9F
73 #define TAHOE_DISPLACED_RELATIVE 0xEF
74 #define TAHOE_DISP_REL_DEFERRED 0xFF
76 #define TAHOE_AUTO_DEC 0x7E
77 #define TAHOE_AUTO_INC 0x8E
78 #define TAHOE_AUTO_INC_DEFERRED 0x9E
79 /* INDEXED_REG is decided by the existence or lack of a [reg]. */
81 /* These are encoded into top_width when top_access=='b'
82 and it's a psuedo op. */
83 #define TAHOE_WIDTH_ALWAYS_JUMP '-'
84 #define TAHOE_WIDTH_CONDITIONAL_JUMP '?'
85 #define TAHOE_WIDTH_BIG_REV_JUMP '!'
86 #define TAHOE_WIDTH_BIG_NON_REV_JUMP ':'
88 /* The hex code for certain tahoe commands and modes.
89 This is just for readability. */
90 #define TAHOE_JMP 0x71
91 #define TAHOE_PC_REL_LONG 0xEF
92 #define TAHOE_BRB 0x11
93 #define TAHOE_BRW 0x13
94 /* These, when 'ored' with, or added to, a register number,
95 set up the number for the displacement mode. */
96 #define TAHOE_PC_OR_BYTE 0xA0
97 #define TAHOE_PC_OR_WORD 0xC0
98 #define TAHOE_PC_OR_LONG 0xE0
100 struct tit /* Get it out of the sewer, it stands for
101 tahoe instruction tree (Geeze!). */
103 tahoe_opcodeT tit_opcode; /* The opcode. */
104 byte tit_operands; /* How many operands are here. */
105 struct top tit_operand[TIT_MAX_OPERANDS]; /* Operands. */
106 char *tit_error; /* "" or fatal error text. */
109 /* end: tahoe-inst.h */
111 /* tahoe.c - tahoe-specific -
112 Not part of gas yet. */
114 #include "opcode/tahoe.h"
116 /* This is the number to put at the beginning of the a.out file. */
117 long omagic = OMAGIC;
119 /* These chars start a comment anywhere in a source file (except inside
120 another comment or a quoted string. */
121 const char comment_chars[] = "#;";
123 /* These chars only start a comment at the beginning of a line. */
124 const char line_comment_chars[] = "#";
126 /* Chars that can be used to separate mant from exp in floating point nums. */
127 const char EXP_CHARS[] = "eE";
129 /* Chars that mean this number is a floating point constant
130 as in 0f123.456
131 or 0d1.234E-12 (see exp chars above)
132 Note: The Tahoe port doesn't support floating point constants. This is
133 consistent with 'as' If it's needed, I can always add it later. */
134 const char FLT_CHARS[] = "df";
136 /* Also be aware that MAXIMUM_NUMBER_OF_CHARS_FOR_FLOAT may have to be
137 changed in read.c . Ideally it shouldn't have to know about it at all,
138 but nothing is ideal around here.
139 (The tahoe has plenty of room, so the change currently isn't needed.) */
141 static struct tit t; /* A tahoe instruction after decoding. */
143 void float_cons ();
144 /* A table of pseudo ops (sans .), the function called, and an integer op
145 that the function is called with. */
147 const pseudo_typeS md_pseudo_table[] =
149 {"dfloat", float_cons, 'd'},
150 {"ffloat", float_cons, 'f'},
154 /* For Tahoe, relative addresses of "just the right length" are pretty easy.
155 The branch displacement is always the last operand, even in
156 synthetic instructions.
157 For Tahoe, we encode the relax_substateTs (in e.g. fr_substate) as:
159 4 3 2 1 0 bit number
160 ---/ /--+-------+-------+-------+-------+-------+
161 | what state ? | how long ? |
162 ---/ /--+-------+-------+-------+-------+-------+
164 The "how long" bits are 00=byte, 01=word, 10=long.
165 This is a Un*x convention.
166 Not all lengths are legit for a given value of (what state).
167 The four states are listed below.
168 The "how long" refers merely to the displacement length.
169 The address usually has some constant bytes in it as well.
171 States for Tahoe address relaxing.
172 1. TAHOE_WIDTH_ALWAYS_JUMP (-)
173 Format: "b-"
174 Tahoe opcodes are: (Hex)
175 jr 11
176 jbr 11
177 Simple branch.
178 Always, 1 byte opcode, then displacement/absolute.
179 If word or longword, change opcode to brw or jmp.
181 2. TAHOE_WIDTH_CONDITIONAL_JUMP (?)
182 J<cond> where <cond> is a simple flag test.
183 Format: "b?"
184 Tahoe opcodes are: (Hex)
185 jneq/jnequ 21
186 jeql/jeqlu 31
187 jgtr 41
188 jleq 51
189 jgeq 81
190 jlss 91
191 jgtru a1
192 jlequ b1
193 jvc c1
194 jvs d1
195 jlssu/jcs e1
196 jgequ/jcc f1
197 Always, you complement 4th bit to reverse the condition.
198 Always, 1-byte opcode, then 1-byte displacement.
200 3. TAHOE_WIDTH_BIG_REV_JUMP (!)
201 Jbc/Jbs where cond tests a memory bit.
202 Format: "rlvlb!"
203 Tahoe opcodes are: (Hex)
204 jbs 0e
205 jbc 1e
206 Always, you complement 4th bit to reverse the condition.
207 Always, 1-byte opcde, longword, longword-address, 1-word-displacement
209 4. TAHOE_WIDTH_BIG_NON_REV_JUMP (:)
210 JaoblXX/Jbssi
211 Format: "rlmlb:"
212 Tahoe opcodes are: (Hex)
213 aojlss 2f
214 jaoblss 2f
215 aojleq 3f
216 jaobleq 3f
217 jbssi 5f
218 Always, we cannot reverse the sense of the branch; we have a word
219 displacement.
221 We need to modify the opcode is for class 1, 2 and 3 instructions.
222 After relax() we may complement the 4th bit of 2 or 3 to reverse sense of
223 branch.
225 We sometimes store context in the operand literal. This way we can figure out
226 after relax() what the original addressing mode was. (Was is pc_rel, or
227 pc_rel_disp? That sort of thing.) */
229 /* These displacements are relative to the START address of the
230 displacement which is at the start of the displacement, not the end of
231 the instruction. The hardware pc_rel is at the end of the instructions.
232 That's why all the displacements have the length of the displacement added
233 to them. (WF + length(word))
235 The first letter is Byte, Word.
236 2nd letter is Forward, Backward. */
237 #define BF (1 + 127)
238 #define BB (1 + -128)
239 #define WF (2 + 32767)
240 #define WB (2 + -32768)
241 /* Dont need LF, LB because they always reach. [They are coded as 0.] */
243 #define C(a,b) ENCODE_RELAX(a, b)
244 /* This macro has no side-effects. */
245 #define ENCODE_RELAX(what,length) (((what) << 2) + (length))
246 #define RELAX_STATE(s) ((s) >> 2)
247 #define RELAX_LENGTH(s) ((s) & 3)
249 #define STATE_ALWAYS_BRANCH 1
250 #define STATE_CONDITIONAL_BRANCH 2
251 #define STATE_BIG_REV_BRANCH 3
252 #define STATE_BIG_NON_REV_BRANCH 4
253 #define STATE_PC_RELATIVE 5
255 #define STATE_BYTE 0
256 #define STATE_WORD 1
257 #define STATE_LONG 2
258 #define STATE_UNDF 3 /* Symbol undefined in pass1. */
260 /* This is the table used by gas to figure out relaxing modes. The fields are
261 forward_branch reach, backward_branch reach, number of bytes it would take,
262 where the next biggest branch is. */
263 const relax_typeS md_relax_table[] =
266 1, 1, 0, 0
267 }, /* Error sentinel 0,0 */
269 1, 1, 0, 0
270 }, /* Unused 0,1 */
272 1, 1, 0, 0
273 }, /* Unused 0,2 */
275 1, 1, 0, 0
276 }, /* Unused 0,3 */
277 /* Unconditional branch cases "jrb"
278 The relax part is the actual displacement */
280 BF, BB, 1, C (1, 1)
281 }, /* Brb B`foo 1,0 */
283 WF, WB, 2, C (1, 2)
284 }, /* Brw W`foo 1,1 */
286 0, 0, 5, 0
287 }, /* Jmp L`foo 1,2 */
289 1, 1, 0, 0
290 }, /* Unused 1,3 */
291 /* Reversible Conditional Branch. If the branch won't reach, reverse
292 it, and jump over a brw or a jmp that will reach. The relax part is the
293 actual address. */
295 BF, BB, 1, C (2, 1)
296 }, /* b<cond> B`foo 2,0 */
298 WF + 2, WB + 2, 4, C (2, 2)
299 }, /* brev over, brw W`foo, over: 2,1 */
301 0, 0, 7, 0
302 }, /* brev over, jmp L`foo, over: 2,2 */
304 1, 1, 0, 0
305 }, /* Unused 2,3 */
306 /* Another type of reversible branch. But this only has a word
307 displacement. */
309 1, 1, 0, 0
310 }, /* Unused 3,0 */
312 WF, WB, 2, C (3, 2)
313 }, /* jbX W`foo 3,1 */
315 0, 0, 8, 0
316 }, /* jrevX over, jmp L`foo, over: 3,2 */
318 1, 1, 0, 0
319 }, /* Unused 3,3 */
320 /* These are the non reversible branches, all of which have a word
321 displacement. If I can't reach, branch over a byte branch, to a
322 jump that will reach. The jumped branch jumps over the reaching
323 branch, to continue with the flow of the program. It's like playing
324 leap frog. */
326 1, 1, 0, 0
327 }, /* Unused 4,0 */
329 WF, WB, 2, C (4, 2)
330 }, /* aobl_ W`foo 4,1 */
332 0, 0, 10, 0
333 }, /*aobl_ W`hop,br over,hop: jmp L^foo,over 4,2*/
335 1, 1, 0, 0
336 }, /* Unused 4,3 */
337 /* Normal displacement mode, no jumping or anything like that.
338 The relax points to one byte before the address, thats why all
339 the numbers are up by one. */
341 BF + 1, BB + 1, 2, C (5, 1)
342 }, /* B^"foo" 5,0 */
344 WF + 1, WB + 1, 3, C (5, 2)
345 }, /* W^"foo" 5,1 */
347 0, 0, 5, 0
348 }, /* L^"foo" 5,2 */
350 1, 1, 0, 0
351 }, /* Unused 5,3 */
354 #undef C
355 #undef BF
356 #undef BB
357 #undef WF
358 #undef WB
359 /* End relax stuff. */
361 /* Handle of the OPCODE hash table. NULL means any use before
362 md_begin() will crash. */
363 static struct hash_control *op_hash;
365 /* Init function. Build the hash table. */
367 void
368 md_begin (void)
370 struct tot *tP;
371 char *errorval = 0;
372 int synthetic_too = 1; /* If 0, just use real opcodes. */
374 op_hash = hash_new ();
376 for (tP = totstrs; *tP->name && !errorval; tP++)
377 errorval = hash_insert (op_hash, tP->name, &tP->detail);
379 if (synthetic_too)
380 for (tP = synthetic_totstrs; *tP->name && !errorval; tP++)
381 errorval = hash_insert (op_hash, tP->name, &tP->detail);
383 if (errorval)
384 as_fatal (errorval);
387 const char *md_shortopts = "ad:STt:V";
389 struct option md_longopts[] =
391 {NULL, no_argument, NULL, 0}
394 size_t md_longopts_size = sizeof (md_longopts);
397 md_parse_option (int c, char *arg)
399 switch (c)
401 case 'a':
402 as_warn (_("The -a option doesn't exist. (Despite what the man page says!"));
403 break;
405 case 'd':
406 as_warn (_("Displacement length %s ignored!"), arg);
407 break;
409 case 'S':
410 as_warn (_("SYMBOL TABLE not implemented"));
411 break;
413 case 'T':
414 as_warn (_("TOKEN TRACE not implemented"));
415 break;
417 case 't':
418 as_warn (_("I don't need or use temp. file \"%s\"."), arg);
419 break;
421 case 'V':
422 as_warn (_("I don't use an interpass file! -V ignored"));
423 break;
425 default:
426 return 0;
429 return 1;
432 void
433 md_show_usage (FILE *stream)
435 fprintf (stream, _("\
436 Tahoe options:\n\
437 -a ignored\n\
438 -d LENGTH ignored\n\
439 -J ignored\n\
440 -S ignored\n\
441 -t FILE ignored\n\
442 -T ignored\n\
443 -V ignored\n"));
446 /* The functions in this section take numbers in the machine format, and
447 munges them into Tahoe byte order.
448 They exist primarily for cross assembly purpose.
449 Knows about order of bytes in address. */
451 void
452 md_number_to_chars (char con[], /* Return 'nbytes' of chars here. */
453 valueT value, /* The value of the bits. */
454 int nbytes) /* Number of bytes in the output. */
456 number_to_chars_bigendian (con, value, nbytes);
459 void
460 md_apply_fix3 (fixS *fixP ATTRIBUTE_UNUSED,
461 valueT * valP ATTRIBUTE_UNUSED,
462 segT seg ATTRIBUTE_UNUSED)
464 /* Should never be called. */
465 know (0);
468 void
469 md_number_to_disp (char con[]m /* Return 'nbytes' of chars here. */
470 long int value, /* The value of the bits. */
471 int nbytes) /* Number of bytes in the output. */
473 md_number_to_chars (con, value, nbytes);
476 void
477 md_number_to_field (char con[], /* Return 'nbytes' of chars here. */
478 long int value, /* The value of the bits. */
479 int nbytes) /* Number of bytes in the output. */
481 md_number_to_chars (con, value, nbytes);
484 /* Put the bits in an order that a tahoe will understand, despite the ordering
485 of the native machine.
486 On Tahoe: first 4 bytes are normal unsigned big endian long,
487 next three bytes are symbolnum, in kind of 3 byte big endian (least sig. byte last).
488 The last byte is broken up with bit 7 as pcrel,
489 bits 6 & 5 as length,
490 bit 4 as extern and the last nibble as 'undefined'. */
492 void
493 tc_aout_fix_to_chars (char *where,
494 fixS *fixP,
495 relax_addressT segment_address_in_file)
497 long r_symbolnum;
499 know (fixP->fx_addsy != NULL);
501 md_number_to_chars (where,
502 fixP->fx_frag->fr_address + fixP->fx_where - segment_address_in_file,
505 r_symbolnum = (S_IS_DEFINED (fixP->fx_addsy)
506 ? S_GET_TYPE (fixP->fx_addsy)
507 : fixP->fx_addsy->sy_number);
509 where[4] = (r_symbolnum >> 16) & 0x0ff;
510 where[5] = (r_symbolnum >> 8) & 0x0ff;
511 where[6] = r_symbolnum & 0x0ff;
512 where[7] = (((is_pcrel (fixP) << 7) & 0x80)
513 | ((((fixP->fx_type == FX_8 || fixP->fx_type == FX_PCREL8
515 : (fixP->fx_type == FX_16 || fixP->fx_type == FX_PCREL16
517 : (fixP->fx_type == FX_32 || fixP->fx_type == FX_PCREL32
519 : 42)))) << 5) & 0x60)
520 | ((!S_IS_DEFINED (fixP->fx_addsy) << 4) & 0x10));
523 /* Relocate byte stuff. */
525 /* This is for broken word. */
526 int md_short_jump_size = 3;
528 void
529 md_create_short_jump (char *ptr,
530 addressT from_addr,
531 addressT to_addr,
532 fragS *frag,
533 symbolS *to_symbol)
535 valueT offset;
537 offset = to_addr - (from_addr + 1);
538 *ptr++ = TAHOE_BRW;
539 md_number_to_chars (ptr, offset, 2);
542 int md_long_jump_size = 6;
543 const int md_reloc_size = 8; /* Size of relocation record. */
545 void
546 md_create_long_jump (char *ptr,
547 addressT from_addr,
548 addressT to_addr,
549 fragS *frag,
550 symbolS *to_symbol)
552 valueT offset;
554 offset = to_addr - (from_addr + 4);
555 *ptr++ = TAHOE_JMP;
556 *ptr++ = TAHOE_PC_REL_LONG;
557 md_number_to_chars (ptr, offset, 4);
560 /* md_estimate_size_before_relax(), called just before relax().
561 Any symbol that is now undefined will not become defined.
562 Return the correct fr_subtype in the frag and the growth beyond
563 fr_fix. */
566 md_estimate_size_before_relax (fragS *fragP, segT segment_type)
568 if (RELAX_LENGTH (fragP->fr_subtype) == STATE_UNDF)
570 if (S_GET_SEGMENT (fragP->fr_symbol) != segment)
572 /* Non-relaxable cases. */
573 char *p;
574 int old_fr_fix;
576 old_fr_fix = fragP->fr_fix;
577 p = fragP->fr_literal + old_fr_fix;
578 switch (RELAX_STATE (fragP->fr_subtype))
580 case STATE_PC_RELATIVE:
581 *p |= TAHOE_PC_OR_LONG;
582 /* We now know how big it will be, one long word. */
583 fragP->fr_fix += 1 + 4;
584 fix_new (fragP, old_fr_fix + 1, fragP->fr_symbol,
585 fragP->fr_offset, FX_PCREL32, NULL);
586 break;
588 case STATE_CONDITIONAL_BRANCH:
589 *fragP->fr_opcode ^= 0x10; /* Reverse sense of branch. */
590 *p++ = 6;
591 *p++ = TAHOE_JMP;
592 *p++ = TAHOE_PC_REL_LONG;
593 fragP->fr_fix += 1 + 1 + 1 + 4;
594 fix_new (fragP, old_fr_fix + 3, fragP->fr_symbol,
595 fragP->fr_offset, FX_PCREL32, NULL);
596 break;
598 case STATE_BIG_REV_BRANCH:
599 *fragP->fr_opcode ^= 0x10; /* Reverse sense of branch. */
600 *p++ = 0;
601 *p++ = 6;
602 *p++ = TAHOE_JMP;
603 *p++ = TAHOE_PC_REL_LONG;
604 fragP->fr_fix += 2 + 2 + 4;
605 fix_new (fragP, old_fr_fix + 4, fragP->fr_symbol,
606 fragP->fr_offset, FX_PCREL32, NULL);
607 break;
609 case STATE_BIG_NON_REV_BRANCH:
610 *p++ = 2;
611 *p++ = 0;
612 *p++ = TAHOE_BRB;
613 *p++ = 6;
614 *p++ = TAHOE_JMP;
615 *p++ = TAHOE_PC_REL_LONG;
616 fragP->fr_fix += 2 + 2 + 2 + 4;
617 fix_new (fragP, old_fr_fix + 6, fragP->fr_symbol,
618 fragP->fr_offset, FX_PCREL32, NULL);
619 break;
621 case STATE_ALWAYS_BRANCH:
622 *fragP->fr_opcode = TAHOE_JMP;
623 *p++ = TAHOE_PC_REL_LONG;
624 fragP->fr_fix += 1 + 4;
625 fix_new (fragP, old_fr_fix + 1, fragP->fr_symbol,
626 fragP->fr_offset, FX_PCREL32, NULL);
627 break;
629 default:
630 abort ();
632 frag_wane (fragP);
634 /* Return the growth in the fixed part of the frag. */
635 return fragP->fr_fix - old_fr_fix;
638 /* Relaxable cases. Set up the initial guess for the variable
639 part of the frag. */
640 switch (RELAX_STATE (fragP->fr_subtype))
642 case STATE_PC_RELATIVE:
643 fragP->fr_subtype = ENCODE_RELAX (STATE_PC_RELATIVE, STATE_BYTE);
644 break;
645 case STATE_CONDITIONAL_BRANCH:
646 fragP->fr_subtype = ENCODE_RELAX (STATE_CONDITIONAL_BRANCH, STATE_BYTE);
647 break;
648 case STATE_BIG_REV_BRANCH:
649 fragP->fr_subtype = ENCODE_RELAX (STATE_BIG_REV_BRANCH, STATE_WORD);
650 break;
651 case STATE_BIG_NON_REV_BRANCH:
652 fragP->fr_subtype = ENCODE_RELAX (STATE_BIG_NON_REV_BRANCH, STATE_WORD);
653 break;
654 case STATE_ALWAYS_BRANCH:
655 fragP->fr_subtype = ENCODE_RELAX (STATE_ALWAYS_BRANCH, STATE_BYTE);
656 break;
660 if (fragP->fr_subtype >= sizeof (md_relax_table) / sizeof (md_relax_table[0]))
661 abort ();
663 /* Return the size of the variable part of the frag. */
664 return md_relax_table[fragP->fr_subtype].rlx_length;
667 /* Called after relax() is finished.
668 In: Address of frag.
669 fr_type == rs_machine_dependent.
670 fr_subtype is what the address relaxed to.
672 Out: Any fixSs and constants are set up.
673 Caller will turn frag into a ".space 0". */
675 void
676 md_convert_frag (object_headers *headers, segT seg, fragS *fragP)
678 char *addressP; /* -> _var to change. */
679 char *opcodeP; /* -> opcode char(s) to change. */
680 short int extension = 0; /* Size of relaxed address.
681 Added to fr_fix: incl. ALL var chars. */
682 symbolS *symbolP;
683 long int where;
684 long int address_of_var;
685 /* Where, in file space, is _var of *fragP? */
686 long int target_address;
687 /* Where, in file space, does addr point? */
689 know (fragP->fr_type == rs_machine_dependent);
690 where = fragP->fr_fix;
691 addressP = fragP->fr_literal + where;
692 opcodeP = fragP->fr_opcode;
693 symbolP = fragP->fr_symbol;
694 know (symbolP);
695 target_address = S_GET_VALUE (symbolP) + fragP->fr_offset;
696 address_of_var = fragP->fr_address + where;
698 switch (fragP->fr_subtype)
700 case ENCODE_RELAX (STATE_PC_RELATIVE, STATE_BYTE):
701 /* *addressP holds the registers number, plus 0x10, if it's deferred
702 mode. To set up the right mode, just OR the size of this displacement. */
703 /* Byte displacement. */
704 *addressP++ |= TAHOE_PC_OR_BYTE;
705 *addressP = target_address - (address_of_var + 2);
706 extension = 2;
707 break;
709 case ENCODE_RELAX (STATE_PC_RELATIVE, STATE_WORD):
710 /* Word displacement. */
711 *addressP++ |= TAHOE_PC_OR_WORD;
712 md_number_to_chars (addressP, target_address - (address_of_var + 3), 2);
713 extension = 3;
714 break;
716 case ENCODE_RELAX (STATE_PC_RELATIVE, STATE_LONG):
717 /* Long word displacement. */
718 *addressP++ |= TAHOE_PC_OR_LONG;
719 md_number_to_chars (addressP, target_address - (address_of_var + 5), 4);
720 extension = 5;
721 break;
723 case ENCODE_RELAX (STATE_CONDITIONAL_BRANCH, STATE_BYTE):
724 *addressP = target_address - (address_of_var + 1);
725 extension = 1;
726 break;
728 case ENCODE_RELAX (STATE_CONDITIONAL_BRANCH, STATE_WORD):
729 *opcodeP ^= 0x10; /* Reverse sense of test. */
730 *addressP++ = 3; /* Jump over word branch. */
731 *addressP++ = TAHOE_BRW;
732 md_number_to_chars (addressP, target_address - (address_of_var + 4), 2);
733 extension = 4;
734 break;
736 case ENCODE_RELAX (STATE_CONDITIONAL_BRANCH, STATE_LONG):
737 *opcodeP ^= 0x10; /* Reverse sense of test. */
738 *addressP++ = 6;
739 *addressP++ = TAHOE_JMP;
740 *addressP++ = TAHOE_PC_REL_LONG;
741 md_number_to_chars (addressP, target_address, 4);
742 extension = 7;
743 break;
745 case ENCODE_RELAX (STATE_ALWAYS_BRANCH, STATE_BYTE):
746 *addressP = target_address - (address_of_var + 1);
747 extension = 1;
748 break;
750 case ENCODE_RELAX (STATE_ALWAYS_BRANCH, STATE_WORD):
751 *opcodeP = TAHOE_BRW;
752 md_number_to_chars (addressP, target_address - (address_of_var + 2), 2);
753 extension = 2;
754 break;
756 case ENCODE_RELAX (STATE_ALWAYS_BRANCH, STATE_LONG):
757 *opcodeP = TAHOE_JMP;
758 *addressP++ = TAHOE_PC_REL_LONG;
759 md_number_to_chars (addressP, target_address - (address_of_var + 5), 4);
760 extension = 5;
761 break;
763 case ENCODE_RELAX (STATE_BIG_REV_BRANCH, STATE_WORD):
764 md_number_to_chars (addressP, target_address - (address_of_var + 2), 2);
765 extension = 2;
766 break;
768 case ENCODE_RELAX (STATE_BIG_REV_BRANCH, STATE_LONG):
769 *opcodeP ^= 0x10;
770 *addressP++ = 0;
771 *addressP++ = 6;
772 *addressP++ = TAHOE_JMP;
773 *addressP++ = TAHOE_PC_REL_LONG;
774 md_number_to_chars (addressP, target_address, 4);
775 extension = 8;
776 break;
778 case ENCODE_RELAX (STATE_BIG_NON_REV_BRANCH, STATE_WORD):
779 md_number_to_chars (addressP, target_address - (address_of_var + 2), 2);
780 extension = 2;
781 break;
783 case ENCODE_RELAX (STATE_BIG_NON_REV_BRANCH, STATE_LONG):
784 *addressP++ = 0;
785 *addressP++ = 2;
786 *addressP++ = TAHOE_BRB;
787 *addressP++ = 6;
788 *addressP++ = TAHOE_JMP;
789 *addressP++ = TAHOE_PC_REL_LONG;
790 md_number_to_chars (addressP, target_address, 4);
791 extension = 10;
792 break;
794 default:
795 BAD_CASE (fragP->fr_subtype);
796 break;
798 fragP->fr_fix += extension;
802 /* This is the stuff for md_assemble. */
803 #define FP_REG 13
804 #define SP_REG 14
805 #define PC_REG 15
806 #define BIGGESTREG PC_REG
808 /* Parse the string pointed to by START
809 If it represents a valid register, point START to the character after
810 the last valid register char, and return the register number (0-15).
811 If invalid, leave START alone, return -1.
812 The format has to be exact. I don't do things like eat leading zeros
813 or the like.
814 Note: This doesn't check for the next character in the string making
815 this invalid. Ex: R123 would return 12, it's the callers job to check
816 what start is point to apon return.
818 Valid registers are R1-R15, %1-%15, FP (13), SP (14), PC (15)
819 Case doesn't matter. */
822 tahoe_reg_parse (char **start) /* A pointer to the string to parse. */
824 char *regpoint = *start;
825 int regnum = -1;
827 switch (*regpoint++)
829 case '%': /* Registers can start with a %,
830 R or r, and then a number. */
831 case 'R':
832 case 'r':
833 if (ISDIGIT (*regpoint))
835 /* Got the first digit. */
836 regnum = *regpoint++ - '0';
837 if ((regnum == 1) && ISDIGIT (*regpoint))
839 /* Its a two digit number. */
840 regnum = 10 + (*regpoint++ - '0');
841 if (regnum > BIGGESTREG)
842 regnum = -1;
845 break;
846 case 'F': /* Is it the FP. */
847 case 'f':
848 switch (*regpoint++)
850 case 'p':
851 case 'P':
852 regnum = FP_REG;
854 break;
855 case 's': /* How about the SP. */
856 case 'S':
857 switch (*regpoint++)
859 case 'p':
860 case 'P':
861 regnum = SP_REG;
863 break;
864 case 'p': /* Or the PC even. */
865 case 'P':
866 switch (*regpoint++)
868 case 'c':
869 case 'C':
870 regnum = PC_REG;
872 break;
875 if (regnum != -1)
876 /* No error, so move string pointer. */
877 *start = regpoint;
879 return regnum;
882 /* This chops up an operand and figures out its modes and stuff.
883 It's a little touchy about extra characters.
884 Optex to start with one extra character so it can be overwritten for
885 the backward part of the parsing.
886 You can't put a bunch of extra characters in side to
887 make the command look cute. ie: * foo ( r1 ) [ r0 ]
888 If you like doing a lot of typing, try COBOL!
889 Actually, this parser is a little weak all around. It's designed to be
890 used with compliers, so I emphasize correct decoding of valid code quickly
891 rather that catching every possible error.
892 Note: This uses the expression function, so save input_line_pointer before
893 calling.
895 Sperry defines the semantics of address modes (and values)
896 by a two-letter code, explained here.
898 letter 1: access type
900 a address calculation - no data access, registers forbidden
901 b branch displacement
902 m read - let go of bus - write back "modify"
903 r read
904 w write
905 v bit field address: like 'a' but registers are OK
907 letter 2: data type (i.e. width, alignment)
909 b byte
910 w word
911 l longword
912 q quadword (Even regs < 14 allowed) (if 12, you get a warning)
913 - unconditional synthetic jbr operand
914 ? simple synthetic reversible branch operand
915 ! complex synthetic reversible branch operand
916 : complex synthetic non-reversible branch operand
918 The '-?!:' letter 2's are not for external consumption. They are used
919 by GAS for psuedo ops relaxing code.
921 After parsing topP has:
923 top_ndx: -1, or the index register. eg 7=[R7]
924 top_reg: -1, or register number. eg 7 = R7 or (R7)
925 top_mode: The addressing mode byte. This byte, defines which of
926 the 11 modes opcode is.
927 top_access: Access type wanted for this operand 'b'branch ' '
928 no-instruction 'amrvw'
929 top_width: Operand width expected, one of "bwlq?-:!"
930 exp_of_operand: The expression as parsed by expression()
931 top_dispsize: Number of bytes in the displacement if we can figure it
932 out and it's relevant.
934 Need syntax checks built. */
936 void
937 tip_op (char *optex, /* The users text input, with one leading character. */
938 struct top *topP) /* The tahoe instruction with some fields already set:
939 in: access, width
940 out: ndx, reg, mode, error, dispsize. */
942 int mode = 0; /* This operand's mode. */
943 char segfault = *optex; /* To keep the back parsing from freaking. */
944 char *point = optex + 1; /* Parsing from front to back. */
945 char *end; /* Parsing from back to front. */
946 int reg = -1; /* major register, -1 means absent. */
947 int imreg = -1; /* Major register in immediate mode. */
948 int ndx = -1; /* index register number, -1 means absent. */
949 char dec_inc = ' '; /* Is the SP auto-incremented '+' or
950 auto-decremented '-' or neither ' '. */
951 int immediate = 0; /* 1 if '$' immediate mode. */
952 int call_width = 0; /* If the caller casts the displacement. */
953 int abs_width = 0; /* The width of the absolute displacement. */
954 int com_width = 0; /* Displacement width required by branch. */
955 int deferred = 0; /* 1 if '*' deferral is used. */
956 byte disp_size = 0; /* How big is this operand. 0 == don't know. */
957 char *op_bad = ""; /* Bad operand error. */
958 char *tp, *temp, c; /* Temporary holders. */
959 char access = topP->top_access;/* Save on a deref. */
960 char width = topP->top_width;
961 int really_none = 0; /* Empty expressions evaluate to 0
962 but I need to know if it's there or not. */
963 expressionS *expP; /* -> expression values for this operand. */
965 /* Does this command restrict the displacement size. */
966 if (access == 'b')
967 com_width = (width == 'b' ? 1 :
968 (width == 'w' ? 2 :
969 (width == 'l' ? 4 : 0)));
971 *optex = '\0'; /* This is kind of a back stop for all
972 the searches to fail on if needed. */
973 if (*point == '*')
975 /* A dereference? */
976 deferred = 1;
977 point++;
980 /* Force words into a certain mode. */
981 /* Using the ^ operator is ambiguous. If I have an absolute label
982 called 'w' set to, say 2, and I have the expression 'w^1', do I get
983 1, forced to be in word displacement mode, or do I get the value of
984 'w' or'ed with 1 (3 in this case).
985 The default is 'w' as an offset, so that's what I use.
986 Stick with `, it does the same, and isn't ambig. */
988 if (*point != '\0' && ((point[1] == '^') || (point[1] == '`')))
989 switch (*point)
991 case 'b':
992 case 'B':
993 case 'w':
994 case 'W':
995 case 'l':
996 case 'L':
997 if (com_width)
998 as_warn (_("Casting a branch displacement is bad form, and is ignored."));
999 else
1001 c = TOLOWER (*point);
1002 call_width = ((c == 'b') ? 1 :
1003 ((c == 'w') ? 2 : 4));
1005 point += 2;
1006 break;
1009 /* Setting immediate mode. */
1010 if (*point == '$')
1012 immediate = 1;
1013 point++;
1016 /* I've pulled off all the easy stuff off the front, move to the end and
1017 yank. */
1019 for (end = point; *end != '\0'; end++) /* Move to the end. */
1022 if (end != point) /* Null string? */
1023 end--;
1025 if (end > point && *end == ' ' && end[-1] != '\'')
1026 end--; /* Hop white space. */
1028 /* Is this an index reg. */
1029 if ((*end == ']') && (end[-1] != '\''))
1031 temp = end;
1033 /* Find opening brace. */
1034 for (--end; (*end != '[' && end != point); end--)
1037 /* If I found the opening brace, get the index register number. */
1038 if (*end == '[')
1040 tp = end + 1; /* tp should point to the start of a reg. */
1041 ndx = tahoe_reg_parse (&tp);
1042 if (tp != temp)
1043 /* Reg. parse error. */
1044 ndx = -1;
1045 else
1046 /* Found it, move past brace. */
1047 end--;
1049 if (ndx == -1)
1051 op_bad = _("Couldn't parse the [index] in this operand.");
1052 end = point; /* Force all the rest of the tests to fail. */
1055 else
1057 op_bad = _("Couldn't find the opening '[' for the index of this operand.");
1058 end = point; /* Force all the rest of the tests to fail. */
1062 /* Post increment? */
1063 if (*end == '+')
1065 dec_inc = '+';
1066 /* was: *end--; */
1067 end--;
1070 /* Register in parens? */
1071 if ((*end == ')') && (end[-1] != '\''))
1073 temp = end;
1075 /* Find opening paren. */
1076 for (--end; (*end != '(' && end != point); end--)
1079 /* If I found the opening paren, get the register number. */
1080 if (*end == '(')
1082 tp = end + 1;
1083 reg = tahoe_reg_parse (&tp);
1084 if (tp != temp)
1086 /* Not a register, but could be part of the expression. */
1087 reg = -1;
1088 /* Rest the pointer back. */
1089 end = temp;
1091 else
1092 /* Found the reg. move before opening paren. */
1093 end--;
1095 else
1097 op_bad = _("Couldn't find the opening '(' for the deref of this operand.");
1098 /* Force all the rest of the tests to fail. */
1099 end = point;
1103 /* Pre decrement? */
1104 if (*end == '-')
1106 if (dec_inc != ' ')
1108 op_bad = _("Operand can't be both pre-inc and post-dec.");
1109 end = point;
1111 else
1113 dec_inc = '-';
1114 end--;
1118 /* Everything between point and end is the 'expression', unless it's
1119 a register name. */
1120 c = end[1];
1121 end[1] = '\0';
1123 tp = point;
1124 /* Get the immediate register if it is there. */
1125 imreg = tahoe_reg_parse (&point);
1126 if (*point != '\0')
1128 /* If there is junk after point, then the it's not immediate reg. */
1129 point = tp;
1130 imreg = -1;
1133 if (imreg != -1 && reg != -1)
1134 op_bad = _("I parsed 2 registers in this operand.");
1136 /* Evaluate whats left of the expression to see if it's valid.
1137 Note again: This assumes that the calling expression has saved
1138 input_line_pointer. (Nag, nag, nag!). */
1139 if (*op_bad == '\0')
1141 /* Statement has no syntax goofs yet: let's sniff the expression. */
1142 input_line_pointer = point;
1143 expP = &(topP->exp_of_operand);
1144 topP->seg_of_operand = expression (expP);
1145 switch (expP->X_op)
1147 case O_absent:
1148 /* No expression. For BSD4.2 compatibility, missing expression is
1149 absolute 0. */
1150 expP->X_op = O_constant;
1151 expP->X_add_number = 0;
1152 really_none = 1;
1153 case O_constant:
1154 /* For SEG_ABSOLUTE, we shouldn't need to set X_op_symbol,
1155 X_add_symbol to any particular value. */
1156 /* But, we will program defensively. Since this situation occurs
1157 rarely so it costs us little to do so. */
1158 expP->X_add_symbol = NULL;
1159 expP->X_op_symbol = NULL;
1160 /* How many bytes are needed to express this abs value? */
1161 abs_width =
1162 ((((expP->X_add_number & 0xFFFFFF80) == 0)
1163 || ((expP->X_add_number & 0xFFFFFF80) == 0xFFFFFF80)) ? 1 :
1164 (((expP->X_add_number & 0xFFFF8000) == 0)
1165 || ((expP->X_add_number & 0xFFFF8000) == 0xFFFF8000)) ? 2 : 4);
1167 case O_symbol:
1168 break;
1170 default:
1171 /* Major bug. We can't handle the case of an operator
1172 expression in a synthetic opcode variable-length
1173 instruction. We don't have a frag type that is smart
1174 enough to relax an operator, and so we just force all
1175 operators to behave like SEG_PASS1s. Clearly, if there is
1176 a demand we can invent a new or modified frag type and
1177 then coding up a frag for this case will be easy. */
1178 need_pass_2 = 1;
1179 op_bad = _("Can't relocate expression error.");
1180 break;
1182 case O_big:
1183 /* This is an error. Tahoe doesn't allow any expressions
1184 bigger that a 32 bit long word. Any bigger has to be referenced
1185 by address. */
1186 op_bad = _("Expression is too large for a 32 bits.");
1187 break;
1190 if (*input_line_pointer != '\0')
1191 op_bad = _("Junk at end of expression.");
1194 end[1] = c;
1196 /* I'm done, so restore optex. */
1197 *optex = segfault;
1199 /* At this point in the game, we (in theory) have all the components of
1200 the operand at least parsed. Now it's time to check for syntax/semantic
1201 errors, and build the mode.
1202 This is what I have:
1203 deferred = 1 if '*'
1204 call_width = 0,1,2,4
1205 abs_width = 0,1,2,4
1206 com_width = 0,1,2,4
1207 immediate = 1 if '$'
1208 ndx = -1 or reg num
1209 dec_inc = '-' or '+' or ' '
1210 reg = -1 or reg num
1211 imreg = -1 or reg num
1212 topP->exp_of_operand
1213 really_none. */
1214 /* Is there a displacement size? */
1215 disp_size = (call_width ? call_width :
1216 (com_width ? com_width :
1217 abs_width ? abs_width : 0));
1219 if (*op_bad == '\0')
1221 if (imreg != -1)
1223 /* Rn */
1224 mode = TAHOE_DIRECT_REG;
1225 if (deferred
1226 || immediate
1227 || (dec_inc != ' ')
1228 || (reg != -1)
1229 || !really_none)
1230 op_bad = _("Syntax error in direct register mode.");
1231 else if (ndx != -1)
1232 op_bad = _("You can't index a register in direct register mode.");
1233 else if (imreg == SP_REG && access == 'r')
1234 op_bad =
1235 _("SP can't be the source operand with direct register addressing.");
1236 else if (access == 'a')
1237 op_bad = _("Can't take the address of a register.");
1238 else if (access == 'b')
1239 op_bad = _("Direct Register can't be used in a branch.");
1240 else if (width == 'q' && ((imreg % 2) || (imreg > 13)))
1241 op_bad = _("For quad access, the register must be even and < 14.");
1242 else if (call_width)
1243 op_bad = _("You can't cast a direct register.");
1245 if (*op_bad == '\0')
1247 /* No errors, check for warnings. */
1248 if (width == 'q' && imreg == 12)
1249 as_warn (_("Using reg 14 for quadwords can tromp the FP register."));
1251 reg = imreg;
1254 /* We know: imm = -1. */
1256 else if (dec_inc == '-')
1258 /* -(SP) */
1259 mode = TAHOE_AUTO_DEC;
1260 if (deferred || immediate || !really_none)
1261 op_bad = _("Syntax error in auto-dec mode.");
1262 else if (ndx != -1)
1263 op_bad = _("You can't have an index auto dec mode.");
1264 else if (access == 'r')
1265 op_bad = _("Auto dec mode cant be used for reading.");
1266 else if (reg != SP_REG)
1267 op_bad = _("Auto dec only works of the SP register.");
1268 else if (access == 'b')
1269 op_bad = _("Auto dec can't be used in a branch.");
1270 else if (width == 'q')
1271 op_bad = _("Auto dec won't work with quadwords.");
1273 /* We know: imm = -1, dec_inc != '-'. */
1275 else if (dec_inc == '+')
1277 if (immediate || !really_none)
1278 op_bad = _("Syntax error in one of the auto-inc modes.");
1279 else if (deferred)
1281 /* *(SP)+ */
1282 mode = TAHOE_AUTO_INC_DEFERRED;
1283 if (reg != SP_REG)
1284 op_bad = _("Auto inc deferred only works of the SP register.");
1285 else if (ndx != -1)
1286 op_bad = _("You can't have an index auto inc deferred mode.");
1287 else if (access == 'b')
1288 op_bad = _("Auto inc can't be used in a branch.");
1290 else
1292 /* (SP)+ */
1293 mode = TAHOE_AUTO_INC;
1294 if (access == 'm' || access == 'w')
1295 op_bad = _("You can't write to an auto inc register.");
1296 else if (reg != SP_REG)
1297 op_bad = _("Auto inc only works of the SP register.");
1298 else if (access == 'b')
1299 op_bad = _("Auto inc can't be used in a branch.");
1300 else if (width == 'q')
1301 op_bad = _("Auto inc won't work with quadwords.");
1302 else if (ndx != -1)
1303 op_bad = _("You can't have an index in auto inc mode.");
1306 /* We know: imm = -1, dec_inc == ' '. */
1308 else if (reg != -1)
1310 if ((ndx != -1) && (reg == SP_REG))
1311 op_bad = _("You can't index the sp register.");
1312 if (deferred)
1314 /* *<disp>(Rn) */
1315 mode = TAHOE_REG_DISP_DEFERRED;
1316 if (immediate)
1317 op_bad = _("Syntax error in register displaced mode.");
1319 else if (really_none)
1320 /* (Rn) */
1321 mode = TAHOE_REG_DEFERRED;
1322 else
1323 /* <disp>(Rn) */
1324 mode = TAHOE_REG_DISP;
1326 /* We know: imm = -1, dec_inc == ' ', Reg = -1 */
1328 else
1330 if (really_none)
1331 op_bad = _("An offest is needed for this operand.");
1332 if (deferred && immediate)
1334 /* *$<ADDR> */
1335 mode = TAHOE_ABSOLUTE_ADDR;
1336 disp_size = 4;
1338 else if (immediate)
1340 /* $<disp> */
1341 mode = TAHOE_IMMEDIATE;
1342 if (ndx != -1)
1343 op_bad = _("You can't index a register in immediate mode.");
1344 if (access == 'a')
1345 op_bad = _("Immediate access can't be used as an address.");
1346 /* ponder the wisdom of a cast because it doesn't do any good. */
1348 else if (deferred)
1349 /* *<disp> */
1350 mode = TAHOE_DISP_REL_DEFERRED;
1351 else
1352 /* <disp> */
1353 mode = TAHOE_DISPLACED_RELATIVE;
1357 /* At this point, all the errors we can do have be checked for.
1358 We can build the 'top'. */
1359 topP->top_ndx = ndx;
1360 topP->top_reg = reg;
1361 topP->top_mode = mode;
1362 topP->top_error = op_bad;
1363 topP->top_dispsize = disp_size;
1366 /* This converts a string into a tahoe instruction.
1367 The string must be a bare single instruction in tahoe (with BSD4 frobs)
1368 format.
1369 It provides at most one fatal error message (which stops the scan)
1370 some warning messages as it finds them.
1371 The tahoe instruction is returned in exploded form.
1373 The exploded instruction is returned to a struct tit of your choice.
1374 #include "tahoe-inst.h" to know what a struct tit is. */
1376 static void
1377 tip (struct tit *titP, /* We build an exploded instruction here. */
1378 char *instring) /* Text of a vax instruction: we modify. */
1380 struct tot_wot *twP = NULL; /* How to bit-encode this opcode. */
1381 char *p; /* 1/skip whitespace.2/scan vot_how. */
1382 char *q;
1383 unsigned char count; /* Counts number of operands seen. */
1384 struct top *operandp; /* Scan operands in struct tit. */
1385 char *alloperr = ""; /* Error over all operands. */
1386 char c; /* Remember char, (we clobber it with '\0' temporarily). */
1387 char *save_input_line_pointer;
1389 if (*instring == ' ')
1390 ++instring; /* Skip leading whitespace. */
1391 for (p = instring; *p && *p != ' '; p++)
1394 /* Scanned up to end of operation-code. */
1395 /* Operation-code is ended with whitespace. */
1396 if (p == instring)
1398 titP->tit_error = _("No operator");
1399 count = 0;
1400 titP->tit_opcode = 0;
1402 else
1404 c = *p;
1405 *p = '\0';
1407 /* Here with instring pointing to what better be an op-name, and p
1408 pointing to character just past that.
1409 We trust instring points to an op-name, with no whitespace. */
1410 twP = (struct tot_wot *) hash_find (op_hash, instring);
1411 /* Restore char after op-code. */
1412 *p = c;
1413 if (twP == 0)
1415 titP->tit_error = _("Unknown operator");
1416 count = 0;
1417 titP->tit_opcode = 0;
1419 else
1421 /* We found a match! So let's pick up as many operands as the
1422 instruction wants, and even gripe if there are too many.
1423 We expect comma to separate each operand.
1424 We let instring track the text, while p tracks a part of the
1425 struct tot. */
1427 /* No operands seen yet. */
1428 count = 0;
1429 /* Point past the operation code. */
1430 instring = p + (*p != '\0');
1431 /* tip_op() screws with the input_line_pointer, so save it before
1432 I jump in. */
1433 save_input_line_pointer = input_line_pointer;
1435 for (p = twP->args, operandp = titP->tit_operand;
1436 !*alloperr && *p;
1437 operandp++, p += 2)
1439 /* Here to parse one operand. Leave instring pointing just
1440 past any one ',' that marks the end of this operand. */
1441 if (!p[1])
1442 as_fatal (_("Compiler bug: ODD number of bytes in arg structure %s."),
1443 twP->args);
1444 else if (*instring)
1446 for (q = instring; (*q != ',' && *q != '\0'); q++)
1447 /* Jump quoted characters. */
1448 if (*q == '\'' && q[1] != '\0')
1449 q++;
1451 c = *q;
1452 /* Q points to ',' or '\0' that ends argument. C is that
1453 character. */
1454 *q = '\0';
1455 operandp->top_access = p[0];
1456 operandp->top_width = p[1];
1457 tip_op (instring - 1, operandp);
1458 /* Restore input text. */
1459 *q = c;
1461 if (*(operandp->top_error))
1462 alloperr = operandp->top_error;
1464 /* Next operand (if any). */
1465 instring = q + (c ? 1 : 0);
1466 /* Won another argument, may have an operr. */
1467 count++;
1469 else
1470 alloperr = _("Not enough operands");
1472 /* Restore the pointer. */
1473 input_line_pointer = save_input_line_pointer;
1475 if (!*alloperr)
1477 /* Skip whitespace. */
1478 if (*instring == ' ')
1479 instring ++;
1481 if (*instring)
1482 alloperr = _("Too many operands");
1485 titP->tit_error = alloperr;
1489 titP->tit_opcode = twP->code;
1490 titP->tit_operands = count;
1493 void
1494 md_assemble (char *instruction_string)
1496 char *p;
1497 struct top *operandP; /* An operand. Scans all operands. */
1498 expressionS *expP; /* -> expression values for this operand. */
1499 /* These refer to an instruction operand expression. */
1500 segT to_seg; /* Target segment of the address. */
1501 valueT this_add_number;
1502 symbolS *this_add_symbol; /* +ve (minuend) symbol. */
1503 char *opcodeP; /* Where it is in a frag. */
1504 int dispsize; /* From top_dispsize: tahoe_operand_width (in bytes). */
1505 int is_undefined; /* 1 if operand expression's segment not known yet. */
1506 int pc_rel; /* Is this operand pc relative? */
1508 /* Decode the operand. */
1509 tip (&t, instruction_string);
1511 /* Check to see if this operand decode properly.
1512 Notice that we haven't made any frags yet.
1513 If it goofed, then this instruction will wedge in any pass,
1514 and we can safely flush it, without causing interpass symbol phase
1515 errors. That is, without changing label values in different passes. */
1517 if (*t.tit_error)
1518 as_warn (_("Ignoring statement due to \"%s\""), t.tit_error);
1519 else
1521 /* We saw no errors in any operands - try to make frag(s). */
1522 /* Emit op-code. */
1523 /* Remember where it is, in case we want to modify the op-code later. */
1524 opcodeP = frag_more (1);
1525 *opcodeP = t.tit_opcode;
1526 /* Now do each operand. */
1527 for (operandP = t.tit_operand;
1528 operandP < t.tit_operand + t.tit_operands;
1529 operandP++)
1530 { /* for each operand */
1531 expP = &(operandP->exp_of_operand);
1532 if (operandP->top_ndx >= 0)
1534 /* Indexed addressing byte
1535 Legality of indexed mode already checked: it is OK. */
1536 FRAG_APPEND_1_CHAR (0x40 + operandP->top_ndx);
1537 } /* if(top_ndx>=0) */
1539 /* Here to make main operand frag(s). */
1540 this_add_number = expP->X_add_number;
1541 this_add_symbol = expP->X_add_symbol;
1542 to_seg = operandP->seg_of_operand;
1543 know (to_seg == SEG_UNKNOWN \
1544 || to_seg == SEG_ABSOLUTE \
1545 || to_seg == SEG_DATA \
1546 || to_seg == SEG_TEXT \
1547 || to_seg == SEG_BSS);
1548 is_undefined = (to_seg == SEG_UNKNOWN);
1549 /* Do we know how big this operand is? */
1550 dispsize = operandP->top_dispsize;
1551 pc_rel = 0;
1552 /* Deal with the branch possibilities. (Note, this doesn't include jumps.) */
1553 if (operandP->top_access == 'b')
1555 /* Branches must be expressions. A psuedo branch can also jump to
1556 an absolute address. */
1557 if (to_seg == now_seg || is_undefined)
1559 /* If is_undefined, then it might BECOME now_seg by relax time. */
1560 if (dispsize)
1562 /* I know how big the branch is supposed to be (it's a normal
1563 branch), so I set up the frag, and let GAS do the rest. */
1564 p = frag_more (dispsize);
1565 fix_new (frag_now, p - frag_now->fr_literal,
1566 this_add_symbol, this_add_number,
1567 size_to_fx (dispsize, 1),
1568 NULL);
1570 else
1572 /* If we don't know how big it is, then its a synthetic branch,
1573 so we set up a simple relax state. */
1574 switch (operandP->top_width)
1576 case TAHOE_WIDTH_CONDITIONAL_JUMP:
1577 /* Simple (conditional) jump. I may have to reverse the
1578 condition of opcodeP, and then jump to my destination.
1579 I set 1 byte aside for the branch off set, and could need 6
1580 more bytes for the pc_rel jump. */
1581 frag_var (rs_machine_dependent, 7, 1,
1582 ENCODE_RELAX (STATE_CONDITIONAL_BRANCH,
1583 is_undefined ? STATE_UNDF : STATE_BYTE),
1584 this_add_symbol, this_add_number, opcodeP);
1585 break;
1586 case TAHOE_WIDTH_ALWAYS_JUMP:
1587 /* Simple (unconditional) jump. I may have to convert this to
1588 a word branch, or an absolute jump. */
1589 frag_var (rs_machine_dependent, 5, 1,
1590 ENCODE_RELAX (STATE_ALWAYS_BRANCH,
1591 is_undefined ? STATE_UNDF : STATE_BYTE),
1592 this_add_symbol, this_add_number, opcodeP);
1593 break;
1594 /* The smallest size for the next 2 cases is word. */
1595 case TAHOE_WIDTH_BIG_REV_JUMP:
1596 frag_var (rs_machine_dependent, 8, 2,
1597 ENCODE_RELAX (STATE_BIG_REV_BRANCH,
1598 is_undefined ? STATE_UNDF : STATE_WORD),
1599 this_add_symbol, this_add_number,
1600 opcodeP);
1601 break;
1602 case TAHOE_WIDTH_BIG_NON_REV_JUMP:
1603 frag_var (rs_machine_dependent, 10, 2,
1604 ENCODE_RELAX (STATE_BIG_NON_REV_BRANCH,
1605 is_undefined ? STATE_UNDF : STATE_WORD),
1606 this_add_symbol, this_add_number,
1607 opcodeP);
1608 break;
1609 default:
1610 as_fatal (_("Compliler bug: Got a case (%d) I wasn't expecting."),
1611 operandP->top_width);
1615 else
1617 /* to_seg != now_seg && to_seg != seg_unknown (still in branch)
1618 In other words, I'm jumping out of my segment so extend the
1619 branches to jumps, and let GAS fix them. */
1621 /* These are "branches" what will always be branches around a jump
1622 to the correct address in real life.
1623 If to_seg is SEG_ABSOLUTE, just encode the branch in,
1624 else let GAS fix the address. */
1626 switch (operandP->top_width)
1628 /* The theory:
1629 For SEG_ABSOLUTE, then mode is ABSOLUTE_ADDR, jump
1630 to that address (not pc_rel).
1631 For other segs, address is a long word PC rel jump. */
1632 case TAHOE_WIDTH_CONDITIONAL_JUMP:
1633 /* b<cond> */
1634 /* To reverse the condition in a TAHOE branch,
1635 complement bit 4 */
1636 *opcodeP ^= 0x10;
1637 p = frag_more (7);
1638 *p++ = 6;
1639 *p++ = TAHOE_JMP;
1640 *p++ = (operandP->top_mode ==
1641 TAHOE_ABSOLUTE_ADDR ? TAHOE_ABSOLUTE_ADDR :
1642 TAHOE_PC_REL_LONG);
1643 fix_new (frag_now, p - frag_now->fr_literal,
1644 this_add_symbol, this_add_number,
1645 (to_seg != SEG_ABSOLUTE) ? FX_PCREL32 : FX_32, NULL);
1647 /* Now (eg) BLEQ 1f
1648 JMP foo
1649 1: */
1650 break;
1652 case TAHOE_WIDTH_ALWAYS_JUMP:
1653 /* Br, just turn it into a jump. */
1654 *opcodeP = TAHOE_JMP;
1655 p = frag_more (5);
1656 *p++ = (operandP->top_mode ==
1657 TAHOE_ABSOLUTE_ADDR ? TAHOE_ABSOLUTE_ADDR :
1658 TAHOE_PC_REL_LONG);
1659 fix_new (frag_now, p - frag_now->fr_literal,
1660 this_add_symbol, this_add_number,
1661 (to_seg != SEG_ABSOLUTE) ? FX_PCREL32 : FX_32, NULL);
1662 /* Now (eg) JMP foo. */
1663 break;
1665 case TAHOE_WIDTH_BIG_REV_JUMP:
1666 p = frag_more (8);
1667 *opcodeP ^= 0x10;
1668 *p++ = 0;
1669 *p++ = 6;
1670 *p++ = TAHOE_JMP;
1671 *p++ = (operandP->top_mode ==
1672 TAHOE_ABSOLUTE_ADDR ? TAHOE_ABSOLUTE_ADDR :
1673 TAHOE_PC_REL_LONG);
1674 fix_new (frag_now, p - frag_now->fr_literal,
1675 this_add_symbol, this_add_number,
1676 (to_seg != SEG_ABSOLUTE) ? FX_PCREL32 : FX_32, NULL);
1677 /* Now (eg) ACBx 1f
1678 JMP foo
1679 1: */
1680 break;
1682 case TAHOE_WIDTH_BIG_NON_REV_JUMP:
1683 p = frag_more (10);
1684 *p++ = 0;
1685 *p++ = 2;
1686 *p++ = TAHOE_BRB;
1687 *p++ = 6;
1688 *p++ = TAHOE_JMP;
1689 *p++ = (operandP->top_mode ==
1690 TAHOE_ABSOLUTE_ADDR ? TAHOE_ABSOLUTE_ADDR :
1691 TAHOE_PC_REL_LONG);
1692 fix_new (frag_now, p - frag_now->fr_literal,
1693 this_add_symbol, this_add_number,
1694 (to_seg != SEG_ABSOLUTE) ? FX_PCREL32 : FX_32, NULL);
1695 /* Now (eg) xOBxxx 1f
1696 BRB 2f
1697 1: JMP @#foo
1698 2: */
1699 break;
1700 case 'b':
1701 case 'w':
1702 as_warn (_("Real branch displacements must be expressions."));
1703 break;
1704 default:
1705 as_fatal (_("Complier error: I got an unknown synthetic branch :%c"),
1706 operandP->top_width);
1707 break;
1711 else
1713 /* It ain't a branch operand. */
1714 switch (operandP->top_mode)
1716 /* Auto-foo access, only works for one reg (SP)
1717 so the only thing needed is the mode. */
1718 case TAHOE_AUTO_DEC:
1719 case TAHOE_AUTO_INC:
1720 case TAHOE_AUTO_INC_DEFERRED:
1721 FRAG_APPEND_1_CHAR (operandP->top_mode);
1722 break;
1724 /* Numbered Register only access. Only thing needed is the
1725 mode + Register number. */
1726 case TAHOE_DIRECT_REG:
1727 case TAHOE_REG_DEFERRED:
1728 FRAG_APPEND_1_CHAR (operandP->top_mode + operandP->top_reg);
1729 break;
1731 /* An absolute address. It's size is always 5 bytes.
1732 (mode_type + 4 byte address). */
1733 case TAHOE_ABSOLUTE_ADDR:
1734 know ((this_add_symbol == NULL));
1735 p = frag_more (5);
1736 *p = TAHOE_ABSOLUTE_ADDR;
1737 md_number_to_chars (p + 1, this_add_number, 4);
1738 break;
1740 /* Immediate data. If the size isn't known, then it's an address
1741 + and offset, which is 4 bytes big. */
1742 case TAHOE_IMMEDIATE:
1743 if (this_add_symbol != NULL)
1745 p = frag_more (5);
1746 *p++ = TAHOE_IMMEDIATE_LONGWORD;
1747 fix_new (frag_now, p - frag_now->fr_literal,
1748 this_add_symbol, this_add_number,
1749 FX_32, NULL);
1751 else
1753 /* It's an integer, and I know it's size. */
1754 if ((unsigned) this_add_number < 0x40)
1755 /* Will it fit in a literal? */
1756 FRAG_APPEND_1_CHAR ((byte) this_add_number);
1757 else
1759 p = frag_more (dispsize + 1);
1760 switch (dispsize)
1762 case 1:
1763 *p++ = TAHOE_IMMEDIATE_BYTE;
1764 *p = (byte) this_add_number;
1765 break;
1766 case 2:
1767 *p++ = TAHOE_IMMEDIATE_WORD;
1768 md_number_to_chars (p, this_add_number, 2);
1769 break;
1770 case 4:
1771 *p++ = TAHOE_IMMEDIATE_LONGWORD;
1772 md_number_to_chars (p, this_add_number, 4);
1773 break;
1777 break;
1779 /* Distance from the PC. If the size isn't known, we have to relax
1780 into it. The difference between this and disp(sp) is that
1781 this offset is pc_rel, and disp(sp) isn't.
1782 Note the drop through code. */
1784 case TAHOE_DISPLACED_RELATIVE:
1785 case TAHOE_DISP_REL_DEFERRED:
1786 operandP->top_reg = PC_REG;
1787 pc_rel = 1;
1789 /* Register, plus a displacement mode. Save the register number,
1790 and weather its deffered or not, and relax the size if it isn't
1791 known. */
1792 case TAHOE_REG_DISP:
1793 case TAHOE_REG_DISP_DEFERRED:
1794 if (operandP->top_mode == TAHOE_DISP_REL_DEFERRED
1795 || operandP->top_mode == TAHOE_REG_DISP_DEFERRED)
1796 /* Deffered mode is always 0x10 higher than it's non-deffered sibling. */
1797 operandP->top_reg += 0x10;
1799 /* Is this a value out of this segment?
1800 The first part of this conditional is a cludge to make gas
1801 produce the same output as 'as' when there is a lable, in
1802 the current segment, displacing a register. It's strange,
1803 and no one in their right mind would do it, but it's easy
1804 to cludge. */
1805 if ((dispsize == 0 && !pc_rel)
1806 || (to_seg != now_seg && !is_undefined && to_seg != SEG_ABSOLUTE))
1807 dispsize = 4;
1809 if (dispsize == 0)
1811 /* We have a SEG_UNKNOWN symbol, or the size isn't cast.
1812 It might turn out to be in the same segment as
1813 the instruction, permitting relaxation. */
1814 p = frag_var (rs_machine_dependent, 5, 2,
1815 ENCODE_RELAX (STATE_PC_RELATIVE,
1816 is_undefined ? STATE_UNDF : STATE_BYTE),
1817 this_add_symbol, this_add_number, 0);
1818 *p = operandP->top_reg;
1820 else
1822 /* Either this is an abs, or a cast. */
1823 p = frag_more (dispsize + 1);
1824 switch (dispsize)
1826 case 1:
1827 *p = TAHOE_PC_OR_BYTE + operandP->top_reg;
1828 break;
1829 case 2:
1830 *p = TAHOE_PC_OR_WORD + operandP->top_reg;
1831 break;
1832 case 4:
1833 *p = TAHOE_PC_OR_LONG + operandP->top_reg;
1834 break;
1836 fix_new (frag_now, p + 1 - frag_now->fr_literal,
1837 this_add_symbol, this_add_number,
1838 size_to_fx (dispsize, pc_rel), NULL);
1840 break;
1841 default:
1842 as_fatal (_("Barf, bad mode %x\n"), operandP->top_mode);
1849 /* We have no need to default values of symbols. */
1851 symbolS *
1852 md_undefined_symbol (char *name)
1854 return 0;
1857 /* Round up a section size to the appropriate boundary. */
1859 valueT
1860 md_section_align (segT segment, valueT size)
1862 /* Round all sects to multiple of 8. */
1863 return ((size + 7) & ~7);
1866 /* Exactly what point is a PC-relative offset relative TO?
1867 On the sparc, they're relative to the address of the offset, plus
1868 its size. This gets us to the following instruction.
1869 (??? Is this right? FIXME-SOON) */
1871 long
1872 md_pcrel_from (fixS *fixP)
1874 return (((fixP->fx_type == FX_8
1875 || fixP->fx_type == FX_PCREL8)
1877 : ((fixP->fx_type == FX_16
1878 || fixP->fx_type == FX_PCREL16)
1880 : ((fixP->fx_type == FX_32
1881 || fixP->fx_type == FX_PCREL32)
1883 : 0))) + fixP->fx_where + fixP->fx_frag->fr_address);
1887 tc_is_pcrel (fixS *fixP)
1889 /* Should never be called. */
1890 know (0);
1891 return 0;