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[/] [or1k/] [trunk/] [gdb-5.3/] [sim/] [common/] [sim-bits.h] - Blame information for rev 1765

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1 1181 sfurman
/* The common simulator framework for GDB, the GNU Debugger.
2
 
3
   Copyright 2002 Free Software Foundation, Inc.
4
 
5
   Contributed by Andrew Cagney and Red Hat.
6
 
7
   This file is part of GDB.
8
 
9
   This program is free software; you can redistribute it and/or modify
10
   it under the terms of the GNU General Public License as published by
11
   the Free Software Foundation; either version 2 of the License, or
12
   (at your option) any later version.
13
 
14
   This program is distributed in the hope that it will be useful,
15
   but WITHOUT ANY WARRANTY; without even the implied warranty of
16
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
17
   GNU General Public License for more details.
18
 
19
   You should have received a copy of the GNU General Public License
20
   along with this program; if not, write to the Free Software
21
   Foundation, Inc., 59 Temple Place - Suite 330,
22
   Boston, MA 02111-1307, USA.  */
23
 
24
 
25
#ifndef _SIM_BITS_H_
26
#define _SIM_BITS_H_
27
 
28
 
29
/* Bit manipulation routines:
30
 
31
   Bit numbering: The bits are numbered according to the target ISA's
32
   convention.  That being controlled by WITH_TARGET_WORD_MSB.  For
33
   the PowerPC (WITH_TARGET_WORD_MSB == 0) the numbering is 0..31
34
   while for the MIPS (WITH_TARGET_WORD_MSB == 31) it is 31..0.
35
 
36
   Size convention: Each macro is in three forms - <MACRO>32 which
37
   operates in 32bit quantity (bits are numbered 0..31); <MACRO>64
38
   which operates using 64bit quantites (and bits are numbered 0..63);
39
   and <MACRO> which operates using the bit size of the target
40
   architecture (bits are still numbered 0..63), with 32bit
41
   architectures ignoring the first 32bits leaving bit 32 as the most
42
   significant.
43
 
44
   NB: Use EXTRACTED, MSEXTRACTED and LSEXTRACTED as a guideline for
45
   naming.  LSMASK and LSMASKED are wrong.
46
 
47
   BIT*(POS): `*' bit constant with just 1 bit set.
48
 
49
   LSBIT*(OFFSET): `*' bit constant with just 1 bit set - LS bit is
50
   zero.
51
 
52
   MSBIT*(OFFSET): `*' bit constant with just 1 bit set - MS bit is
53
   zero.
54
 
55
   MASK*(FIRST, LAST): `*' bit constant with bits [FIRST .. LAST]
56
   set. The <MACRO> (no size) version permits FIRST >= LAST and
57
   generates a wrapped bit mask vis ([0..LAST] | [FIRST..LSB]).
58
 
59
   LSMASK*(FIRST, LAST): Like MASK - LS bit is zero.
60
 
61
   MSMASK*(FIRST, LAST): Like MASK - LS bit is zero.
62
 
63
   MASKED*(VALUE, FIRST, LAST): Masks out all but bits [FIRST
64
   .. LAST].
65
 
66
   LSMASKED*(VALUE, FIRST, LAST): Like MASKED - LS bit is zero.
67
 
68
   MSMASKED*(VALUE, FIRST, LAST): Like MASKED - MS bit is zero.
69
 
70
   EXTRACTED*(VALUE, FIRST, LAST): Masks out bits [FIRST .. LAST] but
71
   also right shifts the masked value so that bit LAST becomes the
72
   least significant (right most).
73
 
74
   LSEXTRACTED*(VALUE, FIRST, LAST): Same as extracted - LS bit is
75
   zero.
76
 
77
   MSEXTRACTED*(VALUE, FIRST, LAST): Same as extracted - MS bit is
78
   zero.
79
 
80
   SHUFFLED**(VALUE, OLD, NEW): Mask then move a single bit from OLD
81
   new NEW.
82
 
83
   MOVED**(VALUE, OLD_FIRST, OLD_LAST, NEW_FIRST, NEW_LAST): Moves
84
   things around so that bits OLD_FIRST..OLD_LAST are masked then
85
   moved to NEW_FIRST..NEW_LAST.
86
 
87
   INSERTED*(VALUE, FIRST, LAST): Takes VALUE and `inserts' the (LAST
88
   - FIRST + 1) least significant bits into bit positions [ FIRST
89
   .. LAST ].  This is almost the complement to EXTRACTED.
90
 
91
   IEA_MASKED(SHOULD_MASK, ADDR): Convert the address to the targets
92
   natural size.  If in 32bit mode, discard the high 32bits.
93
 
94
   EXTEND*(VALUE): Convert the `*' bit value to the targets natural
95
   word size.  Sign extend the value if needed.
96
 
97
   ALIGN_*(VALUE): Round the value upwards so that it is aligned to a
98
   `_*' byte boundary.
99
 
100
   FLOOR_*(VALUE): Truncate the value so that it is aligned to a `_*'
101
   byte boundary.
102
 
103
   ROT*(VALUE, NR_BITS): Return the `*' bit VALUE rotated by NR_BITS
104
   right (positive) or left (negative).
105
 
106
   ROTL*(VALUE, NR_BITS): Return the `*' bit value rotated by NR_BITS
107
   left.  0 <= NR_BITS <= `*'.
108
 
109
   ROTR*(VALUE, NR_BITS): Return the `*' bit value rotated by NR_BITS
110
   right.  0 <= NR_BITS <= N.
111
 
112
   SEXT*(VALUE, SIGN_BIT): Treat SIGN_BIT as VALUEs sign, extend it ti
113
   `*' bits.
114
 
115
   Note: Only the BIT* and MASK* macros return a constant that can be
116
   used in variable declarations.
117
 
118
   */
119
 
120
 
121
/* compute the number of bits between START and STOP */
122
 
123
#if (WITH_TARGET_WORD_MSB == 0)
124
#define _MAKE_WIDTH(START, STOP) (STOP - START + 1)
125
#else
126
#define _MAKE_WIDTH(START, STOP) (START - STOP + 1)
127
#endif
128
 
129
 
130
 
131
/* compute the number shifts required to move a bit between LSB (MSB)
132
   and POS */
133
 
134
#if (WITH_TARGET_WORD_MSB == 0)
135
#define _LSB_SHIFT(WIDTH, POS) (WIDTH - 1 - POS)
136
#else
137
#define _LSB_SHIFT(WIDTH, POS) (POS)
138
#endif
139
 
140
#if (WITH_TARGET_WORD_MSB == 0)
141
#define _MSB_SHIFT(WIDTH, POS) (POS)
142
#else
143
#define _MSB_SHIFT(WIDTH, POS) (WIDTH - 1 - POS)
144
#endif
145
 
146
 
147
/* compute the absolute bit position given the OFFSET from the MSB(LSB)
148
   NB: _MAKE_xxx_POS (WIDTH, _MAKE_xxx_SHIFT (WIDTH, POS)) == POS */
149
 
150
#if (WITH_TARGET_WORD_MSB == 0)
151
#define _MSB_POS(WIDTH, SHIFT) (SHIFT)
152
#else
153
#define _MSB_POS(WIDTH, SHIFT) (WIDTH - 1 - SHIFT)
154
#endif
155
 
156
#if (WITH_TARGET_WORD_MSB == 0)
157
#define _LSB_POS(WIDTH, SHIFT) (WIDTH - 1 - SHIFT)
158
#else
159
#define _LSB_POS(WIDTH, SHIFT) (SHIFT)
160
#endif
161
 
162
 
163
/* convert a 64 bit position into a corresponding 32bit position. MSB
164
   pos handles the posibility that the bit lies beyond the 32bit
165
   boundary */
166
 
167
#if (WITH_TARGET_WORD_MSB == 0)
168
#define _MSB_32(START, STOP) (START <= STOP \
169
                              ? (START < 32 ? 0 : START - 32) \
170
                              : (STOP < 32 ? 0 : STOP - 32))
171
#define _MSB_16(START, STOP) (START <= STOP \
172
                              ? (START < 48 ? 0 : START - 48) \
173
                              : (STOP < 48 ? 0 : STOP - 48))
174
#else
175
#define _MSB_32(START, STOP) (START >= STOP \
176
                              ? (START >= 32 ? 31 : START) \
177
                              : (STOP >= 32 ? 31 : STOP))
178
#define _MSB_16(START, STOP) (START >= STOP \
179
                              ? (START >= 16 ? 15 : START) \
180
                              : (STOP >= 16 ? 15 : STOP))
181
#endif
182
 
183
#if (WITH_TARGET_WORD_MSB == 0)
184
#define _LSB_32(START, STOP) (START <= STOP \
185
                              ? (STOP < 32 ? 0 : STOP - 32) \
186
                              : (START < 32 ? 0 : START - 32))
187
#define _LSB_16(START, STOP) (START <= STOP \
188
                              ? (STOP < 48 ? 0 : STOP - 48) \
189
                              : (START < 48 ? 0 : START - 48))
190
#else
191
#define _LSB_32(START, STOP) (START >= STOP \
192
                              ? (STOP >= 32 ? 31 : STOP) \
193
                              : (START >= 32 ? 31 : START))
194
#define _LSB_16(START, STOP) (START >= STOP \
195
                              ? (STOP >= 16 ? 15 : STOP) \
196
                              : (START >= 16 ? 15 : START))
197
#endif
198
 
199
#if (WITH_TARGET_WORD_MSB == 0)
200
#define _MSB(START, STOP) (START <= STOP ? START : STOP)
201
#else
202
#define _MSB(START, STOP) (START >= STOP ? START : STOP)
203
#endif
204
 
205
#if (WITH_TARGET_WORD_MSB == 0)
206
#define _LSB(START, STOP) (START <= STOP ? STOP : START)
207
#else
208
#define _LSB(START, STOP) (START >= STOP ? STOP : START)
209
#endif
210
 
211
 
212
/* LS/MS Bit operations */
213
 
214
#define LSBIT8(POS)  ((unsigned8) 1 << (POS))
215
#define LSBIT16(POS) ((unsigned16)1 << (POS))
216
#define LSBIT32(POS) ((unsigned32)1 << (POS))
217
#define LSBIT64(POS) ((unsigned64)1 << (POS))
218
 
219
#if (WITH_TARGET_WORD_BITSIZE == 64)
220
#define LSBIT(POS) LSBIT64 (POS)
221
#endif
222
#if (WITH_TARGET_WORD_BITSIZE == 32)
223
#define LSBIT(POS) ((unsigned32)((POS) >= 32 \
224
                                 ? 0 \
225
                                 : (1 << ((POS) >= 32 ? 0 : (POS)))))
226
#endif
227
#if (WITH_TARGET_WORD_BITSIZE == 16)
228
#define LSBIT(POS) ((unsigned16)((POS) >= 16 \
229
                                 ? 0 \
230
                                 : (1 << ((POS) >= 16 ? 0 : (POS)))))
231
#endif
232
 
233
 
234
#define MSBIT8(POS)  ((unsigned8) 1 << ( 8 - 1 - (POS)))
235
#define MSBIT16(POS) ((unsigned16)1 << (16 - 1 - (POS)))
236
#define MSBIT32(POS) ((unsigned32)1 << (32 - 1 - (POS)))
237
#define MSBIT64(POS) ((unsigned64)1 << (64 - 1 - (POS)))
238
 
239
#if (WITH_TARGET_WORD_BITSIZE == 64)
240
#define MSBIT(POS) MSBIT64 (POS)
241
#endif
242
#if (WITH_TARGET_WORD_BITSIZE == 32)
243
#define MSBIT(POS) ((unsigned32)((POS) < 32 \
244
                                 ? 0 \
245
                                 : (1 << ((POS) < 32 ? 0 : (64 - 1) - (POS)))))
246
#endif
247
#if (WITH_TARGET_WORD_BITSIZE == 16)
248
#define MSBIT(POS) ((unsigned16)((POS) < 48 \
249
                                 ? 0 \
250
                                 : (1 << ((POS) < 48 ? 0 : (64 - 1) - (POS)))))
251
#endif
252
 
253
 
254
/* Bit operations */
255
 
256
#define BIT4(POS)  (1 << _LSB_SHIFT (4, (POS)))
257
#define BIT5(POS)  (1 << _LSB_SHIFT (5, (POS)))
258
#define BIT10(POS) (1 << _LSB_SHIFT (10, (POS)))
259
 
260
#if (WITH_TARGET_WORD_MSB == 0)
261
#define BIT8  MSBIT8
262
#define BIT16 MSBIT16
263
#define BIT32 MSBIT32
264
#define BIT64 MSBIT64
265
#define BIT   MSBIT
266
#else
267
#define BIT8  LSBIT8
268
#define BIT16 LSBIT16
269
#define BIT32 LSBIT32
270
#define BIT64 LSBIT64
271
#define BIT   LSBIT
272
#endif
273
 
274
 
275
 
276
/* multi bit mask */
277
 
278
/* 111111 -> mmll11 -> mm11ll */
279
#define _MASKn(WIDTH, START, STOP) (((unsigned##WIDTH)(-1) \
280
                                     >> (_MSB_SHIFT (WIDTH, START) \
281
                                         + _LSB_SHIFT (WIDTH, STOP))) \
282
                                    << _LSB_SHIFT (WIDTH, STOP))
283
 
284
#if (WITH_TARGET_WORD_MSB == 0)
285
#define _POS_LE(START, STOP) (START <= STOP)
286
#else
287
#define _POS_LE(START, STOP) (STOP <= START)
288
#endif
289
 
290
#if (WITH_TARGET_WORD_BITSIZE == 64)
291
#define MASK(START, STOP) \
292
     (_POS_LE ((START), (STOP)) \
293
      ? _MASKn(64, \
294
               _MSB ((START), (STOP)), \
295
               _LSB ((START), (STOP)) ) \
296
      : (_MASKn(64, _MSB_POS (64, 0), (STOP)) \
297
         | _MASKn(64, (START), _LSB_POS (64, 0))))
298
#endif
299
#if (WITH_TARGET_WORD_BITSIZE == 32)
300
#define MASK(START, STOP) \
301
     (_POS_LE ((START), (STOP)) \
302
      ? (_POS_LE ((STOP), _MSB_POS (64, 31)) \
303
         ? 0 \
304
         : _MASKn (32, \
305
                   _MSB_32 ((START), (STOP)), \
306
                   _LSB_32 ((START), (STOP)))) \
307
      : (_MASKn (32, \
308
                 _LSB_32 ((START), (STOP)), \
309
                 _LSB_POS (32, 0)) \
310
         | (_POS_LE ((STOP), _MSB_POS (64, 31)) \
311
            ? 0 \
312
            : _MASKn (32, \
313
                      _MSB_POS (32, 0), \
314
                      _MSB_32 ((START), (STOP))))))
315
#endif
316
#if (WITH_TARGET_WORD_BITSIZE == 16)
317
#define MASK(START, STOP) \
318
     (_POS_LE ((START), (STOP)) \
319
      ? (_POS_LE ((STOP), _MSB_POS (64, 15)) \
320
         ? 0 \
321
         : _MASKn (16, \
322
                   _MSB_16 ((START), (STOP)), \
323
                   _LSB_16 ((START), (STOP)))) \
324
      : (_MASKn (16, \
325
                 _LSB_16 ((START), (STOP)), \
326
                 _LSB_POS (16, 0)) \
327
         | (_POS_LE ((STOP), _MSB_POS (64, 15)) \
328
            ? 0 \
329
            : _MASKn (16, \
330
                      _MSB_POS (16, 0), \
331
                      _MSB_16 ((START), (STOP))))))
332
#endif
333
#if !defined (MASK)
334
#error "MASK never undefined"
335
#endif
336
 
337
 
338
/* Multi-bit mask on least significant bits */
339
 
340
#define _LSMASKn(WIDTH, FIRST, LAST) _MASKn (WIDTH, \
341
                                             _LSB_POS (WIDTH, FIRST), \
342
                                             _LSB_POS (WIDTH, LAST))
343
 
344
#define LSMASK8(FIRST, LAST)   _LSMASKn ( 8, (FIRST), (LAST))
345
#define LSMASK16(FIRST, LAST)  _LSMASKn (16, (FIRST), (LAST))
346
#define LSMASK32(FIRST, LAST)  _LSMASKn (32, (FIRST), (LAST))
347
#define LSMASK64(FIRST, LAST)  _LSMASKn (64, (FIRST), (LAST))
348
 
349
#define LSMASK(FIRST, LAST) (MASK (_LSB_POS (64, FIRST), _LSB_POS (64, LAST)))
350
 
351
 
352
/* Multi-bit mask on most significant bits */
353
 
354
#define _MSMASKn(WIDTH, FIRST, LAST) _MASKn (WIDTH, \
355
                                             _MSB_POS (WIDTH, FIRST), \
356
                                             _MSB_POS (WIDTH, LAST))
357
 
358
#define MSMASK8(FIRST, LAST)  _MSMASKn ( 8, (FIRST), (LAST))
359
#define MSMASK16(FIRST, LAST) _MSMASKn (16, (FIRST), (LAST))
360
#define MSMASK32(FIRST, LAST) _MSMASKn (32, (FIRST), (LAST))
361
#define MSMASK64(FIRST, LAST) _MSMASKn (64, (FIRST), (LAST))
362
 
363
#define MSMASK(FIRST, LAST) (MASK (_MSB_POS (64, FIRST), _MSB_POS (64, LAST)))
364
 
365
 
366
 
367
#if (WITH_TARGET_WORD_MSB == 0)
368
#define MASK8  MSMASK8
369
#define MASK16 MSMASK16
370
#define MASK32 MSMASK32
371
#define MASK64 MSMASK64
372
#else
373
#define MASK8  LSMASK8
374
#define MASK16 LSMASK16
375
#define MASK32 LSMASK32
376
#define MASK64 LSMASK64
377
#endif
378
 
379
 
380
 
381
/* mask the required bits, leaving them in place */
382
 
383
INLINE_SIM_BITS(unsigned8)  LSMASKED8  (unsigned8  word, int first, int last);
384
INLINE_SIM_BITS(unsigned16) LSMASKED16 (unsigned16 word, int first, int last);
385
INLINE_SIM_BITS(unsigned32) LSMASKED32 (unsigned32 word, int first, int last);
386
INLINE_SIM_BITS(unsigned64) LSMASKED64 (unsigned64 word, int first, int last);
387
 
388
INLINE_SIM_BITS(unsigned_word) LSMASKED (unsigned_word word, int first, int last);
389
 
390
INLINE_SIM_BITS(unsigned8)  MSMASKED8  (unsigned8  word, int first, int last);
391
INLINE_SIM_BITS(unsigned16) MSMASKED16 (unsigned16 word, int first, int last);
392
INLINE_SIM_BITS(unsigned32) MSMASKED32 (unsigned32 word, int first, int last);
393
INLINE_SIM_BITS(unsigned64) MSMASKED64 (unsigned64 word, int first, int last);
394
 
395
INLINE_SIM_BITS(unsigned_word) MSMASKED (unsigned_word word, int first, int last);
396
 
397
#if (WITH_TARGET_WORD_MSB == 0)
398
#define MASKED8  MSMASKED8
399
#define MASKED16 MSMASKED16
400
#define MASKED32 MSMASKED32
401
#define MASKED64 MSMASKED64
402
#define MASKED   MSMASKED
403
#else
404
#define MASKED8  LSMASKED8
405
#define MASKED16 LSMASKED16
406
#define MASKED32 LSMASKED32
407
#define MASKED64 LSMASKED64
408
#define MASKED LSMASKED
409
#endif
410
 
411
 
412
 
413
/* extract the required bits aligning them with the lsb */
414
 
415
INLINE_SIM_BITS(unsigned8)  LSEXTRACTED8  (unsigned8  val, int start, int stop);
416
INLINE_SIM_BITS(unsigned16) LSEXTRACTED16 (unsigned16 val, int start, int stop);
417
INLINE_SIM_BITS(unsigned32) LSEXTRACTED32 (unsigned32 val, int start, int stop);
418
INLINE_SIM_BITS(unsigned64) LSEXTRACTED64 (unsigned64 val, int start, int stop);
419
 
420
INLINE_SIM_BITS(unsigned_word) LSEXTRACTED (unsigned_word val, int start, int stop);
421
 
422
INLINE_SIM_BITS(unsigned8)  MSEXTRACTED8  (unsigned8  val, int start, int stop);
423
INLINE_SIM_BITS(unsigned16) MSEXTRACTED16 (unsigned16 val, int start, int stop);
424
INLINE_SIM_BITS(unsigned32) MSEXTRACTED32 (unsigned32 val, int start, int stop);
425
INLINE_SIM_BITS(unsigned64) MSEXTRACTED64 (unsigned64 val, int start, int stop);
426
 
427
INLINE_SIM_BITS(unsigned_word) MSEXTRACTED (unsigned_word val, int start, int stop);
428
 
429
#if (WITH_TARGET_WORD_MSB == 0)
430
#define EXTRACTED8  MSEXTRACTED8
431
#define EXTRACTED16 MSEXTRACTED16
432
#define EXTRACTED32 MSEXTRACTED32
433
#define EXTRACTED64 MSEXTRACTED64
434
#define EXTRACTED   MSEXTRACTED
435
#else
436
#define EXTRACTED8  LSEXTRACTED8
437
#define EXTRACTED16 LSEXTRACTED16
438
#define EXTRACTED32 LSEXTRACTED32
439
#define EXTRACTED64 LSEXTRACTED64
440
#define EXTRACTED   LSEXTRACTED
441
#endif
442
 
443
 
444
 
445
/* move a single bit around */
446
/* NB: the wierdness (N>O?N-O:0) is to stop a warning from GCC */
447
#define _SHUFFLEDn(N, WORD, OLD, NEW) \
448
((OLD) < (NEW) \
449
 ? (((unsigned##N)(WORD) \
450
     >> (((NEW) > (OLD)) ? ((NEW) - (OLD)) : 0)) \
451
    & MASK32((NEW), (NEW))) \
452
 : (((unsigned##N)(WORD) \
453
     << (((OLD) > (NEW)) ? ((OLD) - (NEW)) : 0)) \
454
    & MASK32((NEW), (NEW))))
455
 
456
#define SHUFFLED32(WORD, OLD, NEW) _SHUFFLEDn (32, WORD, OLD, NEW)
457
#define SHUFFLED64(WORD, OLD, NEW) _SHUFFLEDn (64, WORD, OLD, NEW)
458
 
459
#define SHUFFLED(WORD, OLD, NEW) _SHUFFLEDn (_word, WORD, OLD, NEW)
460
 
461
 
462
/* Insert a group of bits into a bit position */
463
 
464
INLINE_SIM_BITS(unsigned8)  LSINSERTED8  (unsigned8  val, int start, int stop);
465
INLINE_SIM_BITS(unsigned16) LSINSERTED16 (unsigned16 val, int start, int stop);
466
INLINE_SIM_BITS(unsigned32) LSINSERTED32 (unsigned32 val, int start, int stop);
467
INLINE_SIM_BITS(unsigned64) LSINSERTED64 (unsigned64 val, int start, int stop);
468
INLINE_SIM_BITS(unsigned_word) LSINSERTED (unsigned_word val, int start, int stop);
469
 
470
INLINE_SIM_BITS(unsigned8)  MSINSERTED8  (unsigned8  val, int start, int stop);
471
INLINE_SIM_BITS(unsigned16) MSINSERTED16 (unsigned16 val, int start, int stop);
472
INLINE_SIM_BITS(unsigned32) MSINSERTED32 (unsigned32 val, int start, int stop);
473
INLINE_SIM_BITS(unsigned64) MSINSERTED64 (unsigned64 val, int start, int stop);
474
INLINE_SIM_BITS(unsigned_word) MSINSERTED (unsigned_word val, int start, int stop);
475
 
476
#if (WITH_TARGET_WORD_MSB == 0)
477
#define INSERTED8  MSINSERTED8
478
#define INSERTED16 MSINSERTED16
479
#define INSERTED32 MSINSERTED32
480
#define INSERTED64 MSINSERTED64
481
#define INSERTED   MSINSERTED
482
#else
483
#define INSERTED8  LSINSERTED8
484
#define INSERTED16 LSINSERTED16
485
#define INSERTED32 LSINSERTED32
486
#define INSERTED64 LSINSERTED64
487
#define INSERTED   LSINSERTED
488
#endif
489
 
490
 
491
 
492
/* MOVE bits from one loc to another (combination of extract/insert) */
493
 
494
#define MOVED8(VAL,OH,OL,NH,NL)  INSERTED8 (EXTRACTED8 ((VAL), OH, OL), NH, NL)
495
#define MOVED16(VAL,OH,OL,NH,NL) INSERTED16(EXTRACTED16((VAL), OH, OL), NH, NL)
496
#define MOVED32(VAL,OH,OL,NH,NL) INSERTED32(EXTRACTED32((VAL), OH, OL), NH, NL)
497
#define MOVED64(VAL,OH,OL,NH,NL) INSERTED64(EXTRACTED64((VAL), OH, OL), NH, NL)
498
#define MOVED(VAL,OH,OL,NH,NL)   INSERTED  (EXTRACTED  ((VAL), OH, OL), NH, NL)
499
 
500
 
501
 
502
/* Sign extend the quantity to the targets natural word size */
503
 
504
#define EXTEND4(X)  (LSSEXT ((X), 3))
505
#define EXTEND5(X)  (LSSEXT ((X), 4))
506
#define EXTEND8(X)  ((signed_word)(signed8)(X))
507
#define EXTEND11(X)  (LSSEXT ((X), 10))
508
#define EXTEND15(X)  (LSSEXT ((X), 14))
509
#define EXTEND16(X) ((signed_word)(signed16)(X))
510
#define EXTEND24(X)  (LSSEXT ((X), 23))
511
#define EXTEND32(X) ((signed_word)(signed32)(X))
512
#define EXTEND64(X) ((signed_word)(signed64)(X))
513
 
514
/* depending on MODE return a 64bit or 32bit (sign extended) value */
515
#if (WITH_TARGET_WORD_BITSIZE == 64)
516
#define EXTENDED(X)     ((signed64)(signed32)(X))
517
#endif
518
#if (WITH_TARGET_WORD_BITSIZE == 32)
519
#define EXTENDED(X)     (X)
520
#endif
521
#if (WITH_TARGET_WORD_BITSIZE == 16)
522
#define EXTENDED(X)     (X)
523
#endif
524
 
525
 
526
/* memory alignment macro's */
527
#define _ALIGNa(A,X)  (((X) + ((A) - 1)) & ~((A) - 1))
528
#define _FLOORa(A,X)  ((X) & ~((A) - 1))
529
 
530
#define ALIGN_8(X)      _ALIGNa (8, X)
531
#define ALIGN_16(X)     _ALIGNa (16, X)
532
 
533
#define ALIGN_PAGE(X)   _ALIGNa (0x1000, X)
534
#define FLOOR_PAGE(X)   ((X) & ~(0x1000 - 1))
535
 
536
 
537
/* bit bliting macro's */
538
#define BLIT32(V, POS, BIT) \
539
do { \
540
  if (BIT) \
541
    V |= BIT32 (POS); \
542
  else \
543
    V &= ~BIT32 (POS); \
544
} while (0)
545
#define MBLIT32(V, LO, HI, VAL) \
546
do { \
547
  (V) = (((V) & ~MASK32 ((LO), (HI))) \
548
         | INSERTED32 (VAL, LO, HI)); \
549
} while (0)
550
 
551
 
552
 
553
/* some rotate functions.  The generic macro's ROT, ROTL, ROTR are
554
   intentionally omited. */
555
 
556
 
557
INLINE_SIM_BITS(unsigned8)  ROT8  (unsigned8  val, int shift);
558
INLINE_SIM_BITS(unsigned16) ROT16 (unsigned16 val, int shift);
559
INLINE_SIM_BITS(unsigned32) ROT32 (unsigned32 val, int shift);
560
INLINE_SIM_BITS(unsigned64) ROT64 (unsigned64 val, int shift);
561
 
562
 
563
INLINE_SIM_BITS(unsigned8)  ROTL8  (unsigned8  val, int shift);
564
INLINE_SIM_BITS(unsigned16) ROTL16 (unsigned16 val, int shift);
565
INLINE_SIM_BITS(unsigned32) ROTL32 (unsigned32 val, int shift);
566
INLINE_SIM_BITS(unsigned64) ROTL64 (unsigned64 val, int shift);
567
 
568
 
569
INLINE_SIM_BITS(unsigned8)  ROTR8  (unsigned8  val, int shift);
570
INLINE_SIM_BITS(unsigned16) ROTR16 (unsigned16 val, int shift);
571
INLINE_SIM_BITS(unsigned32) ROTR32 (unsigned32 val, int shift);
572
INLINE_SIM_BITS(unsigned64) ROTR64 (unsigned64 val, int shift);
573
 
574
 
575
 
576
/* Sign extension operations */
577
 
578
INLINE_SIM_BITS(unsigned8)  LSSEXT8  (signed8  val, int sign_bit);
579
INLINE_SIM_BITS(unsigned16) LSSEXT16 (signed16 val, int sign_bit);
580
INLINE_SIM_BITS(unsigned32) LSSEXT32 (signed32 val, int sign_bit);
581
INLINE_SIM_BITS(unsigned64) LSSEXT64 (signed64 val, int sign_bit);
582
INLINE_SIM_BITS(unsigned_word) LSSEXT (signed_word val, int sign_bit);
583
 
584
INLINE_SIM_BITS(unsigned8)  MSSEXT8  (signed8  val, int sign_bit);
585
INLINE_SIM_BITS(unsigned16) MSSEXT16 (signed16 val, int sign_bit);
586
INLINE_SIM_BITS(unsigned32) MSSEXT32 (signed32 val, int sign_bit);
587
INLINE_SIM_BITS(unsigned64) MSSEXT64 (signed64 val, int sign_bit);
588
INLINE_SIM_BITS(unsigned_word) MSSEXT (signed_word val, int sign_bit);
589
 
590
#if (WITH_TARGET_WORD_MSB == 0)
591
#define SEXT8  MSSEXT8
592
#define SEXT16 MSSEXT16
593
#define SEXT32 MSSEXT32
594
#define SEXT64 MSSEXT64
595
#define SEXT   MSSEXT
596
#else
597
#define SEXT8  LSSEXT8
598
#define SEXT16 LSSEXT16
599
#define SEXT32 LSSEXT32
600
#define SEXT64 LSSEXT64
601
#define SEXT   LSSEXT
602
#endif
603
 
604
 
605
 
606
#if H_REVEALS_MODULE_P (SIM_BITS_INLINE)
607
#include "sim-bits.c"
608
#endif
609
 
610
#endif /* _SIM_BITS_H_ */

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