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[/] [openrisc/] [trunk/] [gnu-src/] [gcc-4.2.2/] [gcc/] [config/] [arm/] [lib1funcs.asm] - Blame information for rev 199

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1 38 julius
@ libgcc routines for ARM cpu.
2
@ Division routines, written by Richard Earnshaw, (rearnsha@armltd.co.uk)
3
 
4
/* Copyright 1995, 1996, 1998, 1999, 2000, 2003, 2004, 2005
5
   Free Software Foundation, Inc.
6
 
7
This file is free software; you can redistribute it and/or modify it
8
under the terms of the GNU General Public License as published by the
9
Free Software Foundation; either version 2, or (at your option) any
10
later version.
11
 
12
In addition to the permissions in the GNU General Public License, the
13
Free Software Foundation gives you unlimited permission to link the
14
compiled version of this file into combinations with other programs,
15
and to distribute those combinations without any restriction coming
16
from the use of this file.  (The General Public License restrictions
17
do apply in other respects; for example, they cover modification of
18
the file, and distribution when not linked into a combine
19
executable.)
20
 
21
This file is distributed in the hope that it will be useful, but
22
WITHOUT ANY WARRANTY; without even the implied warranty of
23
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
24
General Public License for more details.
25
 
26
You should have received a copy of the GNU General Public License
27
along with this program; see the file COPYING.  If not, write to
28
the Free Software Foundation, 51 Franklin Street, Fifth Floor,
29
Boston, MA 02110-1301, USA.  */
30
/* ------------------------------------------------------------------------ */
31
 
32
/* We need to know what prefix to add to function names.  */
33
 
34
#ifndef __USER_LABEL_PREFIX__
35
#error  __USER_LABEL_PREFIX__ not defined
36
#endif
37
 
38
/* ANSI concatenation macros.  */
39
 
40
#define CONCAT1(a, b) CONCAT2(a, b)
41
#define CONCAT2(a, b) a ## b
42
 
43
/* Use the right prefix for global labels.  */
44
 
45
#define SYM(x) CONCAT1 (__USER_LABEL_PREFIX__, x)
46
 
47
#ifdef __ELF__
48
#ifdef __thumb__
49
#define __PLT__  /* Not supported in Thumb assembler (for now).  */
50
#else
51
#define __PLT__ (PLT)
52
#endif
53
#define TYPE(x) .type SYM(x),function
54
#define SIZE(x) .size SYM(x), . - SYM(x)
55
#define LSYM(x) .x
56
#else
57
#define __PLT__
58
#define TYPE(x)
59
#define SIZE(x)
60
#define LSYM(x) x
61
#endif
62
 
63
/* Function end macros.  Variants for interworking.  */
64
 
65
@ This selects the minimum architecture level required.
66
#define __ARM_ARCH__ 3
67
 
68
#if defined(__ARM_ARCH_3M__) || defined(__ARM_ARCH_4__) \
69
        || defined(__ARM_ARCH_4T__)
70
/* We use __ARM_ARCH__ set to 4 here, but in reality it's any processor with
71
   long multiply instructions.  That includes v3M.  */
72
# undef __ARM_ARCH__
73
# define __ARM_ARCH__ 4
74
#endif
75
 
76
#if defined(__ARM_ARCH_5__) || defined(__ARM_ARCH_5T__) \
77
        || defined(__ARM_ARCH_5E__) || defined(__ARM_ARCH_5TE__) \
78
        || defined(__ARM_ARCH_5TEJ__)
79
# undef __ARM_ARCH__
80
# define __ARM_ARCH__ 5
81
#endif
82
 
83
#if defined(__ARM_ARCH_6__) || defined(__ARM_ARCH_6J__) \
84
        || defined(__ARM_ARCH_6K__) || defined(__ARM_ARCH_6Z__) \
85
        || defined(__ARM_ARCH_6ZK__)
86
# undef __ARM_ARCH__
87
# define __ARM_ARCH__ 6
88
#endif
89
 
90
#ifndef __ARM_ARCH__
91
#error Unable to determine architecture.
92
#endif
93
 
94
/* How to return from a function call depends on the architecture variant.  */
95
 
96
#if (__ARM_ARCH__ > 4) || defined(__ARM_ARCH_4T__)
97
 
98
# define RET            bx      lr
99
# define RETc(x)        bx##x   lr
100
 
101
/* Special precautions for interworking on armv4t.  */
102
# if (__ARM_ARCH__ == 4)
103
 
104
/* Always use bx, not ldr pc.  */
105
#  if (defined(__thumb__) || defined(__THUMB_INTERWORK__))
106
#    define __INTERWORKING__
107
#   endif /* __THUMB__ || __THUMB_INTERWORK__ */
108
 
109
/* Include thumb stub before arm mode code.  */
110
#  if defined(__thumb__) && !defined(__THUMB_INTERWORK__)
111
#   define __INTERWORKING_STUBS__
112
#  endif /* __thumb__ && !__THUMB_INTERWORK__ */
113
 
114
#endif /* __ARM_ARCH == 4 */
115
 
116
#else
117
 
118
# define RET            mov     pc, lr
119
# define RETc(x)        mov##x  pc, lr
120
 
121
#endif
122
 
123
.macro  cfi_pop         advance, reg, cfa_offset
124
#ifdef __ELF__
125
        .pushsection    .debug_frame
126
        .byte   0x4             /* DW_CFA_advance_loc4 */
127
        .4byte  \advance
128
        .byte   (0xc0 | \reg)   /* DW_CFA_restore */
129
        .byte   0xe             /* DW_CFA_def_cfa_offset */
130
        .uleb128 \cfa_offset
131
        .popsection
132
#endif
133
.endm
134
.macro  cfi_push        advance, reg, offset, cfa_offset
135
#ifdef __ELF__
136
        .pushsection    .debug_frame
137
        .byte   0x4             /* DW_CFA_advance_loc4 */
138
        .4byte  \advance
139
        .byte   (0x80 | \reg)   /* DW_CFA_offset */
140
        .uleb128 (\offset / -4)
141
        .byte   0xe             /* DW_CFA_def_cfa_offset */
142
        .uleb128 \cfa_offset
143
        .popsection
144
#endif
145
.endm
146
.macro cfi_start        start_label, end_label
147
#ifdef __ELF__
148
        .pushsection    .debug_frame
149
LSYM(Lstart_frame):
150
        .4byte  LSYM(Lend_cie) - LSYM(Lstart_cie) @ Length of CIE
151
LSYM(Lstart_cie):
152
        .4byte  0xffffffff      @ CIE Identifier Tag
153
        .byte   0x1     @ CIE Version
154
        .ascii  "\0"    @ CIE Augmentation
155
        .uleb128 0x1    @ CIE Code Alignment Factor
156
        .sleb128 -4     @ CIE Data Alignment Factor
157
        .byte   0xe     @ CIE RA Column
158
        .byte   0xc     @ DW_CFA_def_cfa
159
        .uleb128 0xd
160
        .uleb128 0x0
161
 
162
        .align 2
163
LSYM(Lend_cie):
164
        .4byte  LSYM(Lend_fde)-LSYM(Lstart_fde) @ FDE Length
165
LSYM(Lstart_fde):
166
        .4byte  LSYM(Lstart_frame)      @ FDE CIE offset
167
        .4byte  \start_label    @ FDE initial location
168
        .4byte  \end_label-\start_label @ FDE address range
169
        .popsection
170
#endif
171
.endm
172
.macro cfi_end  end_label
173
#ifdef __ELF__
174
        .pushsection    .debug_frame
175
        .align  2
176
LSYM(Lend_fde):
177
        .popsection
178
\end_label:
179
#endif
180
.endm
181
 
182
/* Don't pass dirn, it's there just to get token pasting right.  */
183
 
184
.macro  RETLDM  regs=, cond=, unwind=, dirn=ia
185
#if defined (__INTERWORKING__)
186
        .ifc "\regs",""
187
        ldr\cond        lr, [sp], #8
188
        .else
189
        ldm\cond\dirn   sp!, {\regs, lr}
190
        .endif
191
        .ifnc "\unwind", ""
192
        /* Mark LR as restored.  */
193
97:     cfi_pop 97b - \unwind, 0xe, 0x0
194
        .endif
195
        bx\cond lr
196
#else
197
        .ifc "\regs",""
198
        ldr\cond        pc, [sp], #8
199
        .else
200
        ldm\cond\dirn   sp!, {\regs, pc}
201
        .endif
202
#endif
203
.endm
204
 
205
 
206
.macro ARM_LDIV0 name
207
        str     lr, [sp, #-8]!
208
98:     cfi_push 98b - __\name, 0xe, -0x8, 0x8
209
        bl      SYM (__div0) __PLT__
210
        mov     r0, #0                  @ About as wrong as it could be.
211
        RETLDM  unwind=98b
212
.endm
213
 
214
 
215
.macro THUMB_LDIV0 name
216
        push    { r1, lr }
217
98:     cfi_push 98b - __\name, 0xe, -0x4, 0x8
218
        bl      SYM (__div0)
219
        mov     r0, #0                  @ About as wrong as it could be.
220
#if defined (__INTERWORKING__)
221
        pop     { r1, r2 }
222
        bx      r2
223
#else
224
        pop     { r1, pc }
225
#endif
226
.endm
227
 
228
.macro FUNC_END name
229
        SIZE (__\name)
230
.endm
231
 
232
.macro DIV_FUNC_END name
233
        cfi_start       __\name, LSYM(Lend_div0)
234
LSYM(Ldiv0):
235
#ifdef __thumb__
236
        THUMB_LDIV0 \name
237
#else
238
        ARM_LDIV0 \name
239
#endif
240
        cfi_end LSYM(Lend_div0)
241
        FUNC_END \name
242
.endm
243
 
244
.macro THUMB_FUNC_START name
245
        .globl  SYM (\name)
246
        TYPE    (\name)
247
        .thumb_func
248
SYM (\name):
249
.endm
250
 
251
/* Function start macros.  Variants for ARM and Thumb.  */
252
 
253
#ifdef __thumb__
254
#define THUMB_FUNC .thumb_func
255
#define THUMB_CODE .force_thumb
256
#else
257
#define THUMB_FUNC
258
#define THUMB_CODE
259
#endif
260
 
261
.macro FUNC_START name
262
        .text
263
        .globl SYM (__\name)
264
        TYPE (__\name)
265
        .align 0
266
        THUMB_CODE
267
        THUMB_FUNC
268
SYM (__\name):
269
.endm
270
 
271
/* Special function that will always be coded in ARM assembly, even if
272
   in Thumb-only compilation.  */
273
 
274
#if defined(__INTERWORKING_STUBS__)
275
.macro  ARM_FUNC_START name
276
        FUNC_START \name
277
        bx      pc
278
        nop
279
        .arm
280
/* A hook to tell gdb that we've switched to ARM mode.  Also used to call
281
   directly from other local arm routines.  */
282
_L__\name:
283
.endm
284
#define EQUIV .thumb_set
285
/* Branch directly to a function declared with ARM_FUNC_START.
286
   Must be called in arm mode.  */
287
.macro  ARM_CALL name
288
        bl      _L__\name
289
.endm
290
#else
291
.macro  ARM_FUNC_START name
292
        .text
293
        .globl SYM (__\name)
294
        TYPE (__\name)
295
        .align 0
296
        .arm
297
SYM (__\name):
298
.endm
299
#define EQUIV .set
300
.macro  ARM_CALL name
301
        bl      __\name
302
.endm
303
#endif
304
 
305
.macro  FUNC_ALIAS new old
306
        .globl  SYM (__\new)
307
#if defined (__thumb__)
308
        .thumb_set      SYM (__\new), SYM (__\old)
309
#else
310
        .set    SYM (__\new), SYM (__\old)
311
#endif
312
.endm
313
 
314
.macro  ARM_FUNC_ALIAS new old
315
        .globl  SYM (__\new)
316
        EQUIV   SYM (__\new), SYM (__\old)
317
#if defined(__INTERWORKING_STUBS__)
318
        .set    SYM (_L__\new), SYM (_L__\old)
319
#endif
320
.endm
321
 
322
#ifdef __thumb__
323
/* Register aliases.  */
324
 
325
work            .req    r4      @ XXXX is this safe ?
326
dividend        .req    r0
327
divisor         .req    r1
328
overdone        .req    r2
329
result          .req    r2
330
curbit          .req    r3
331
#endif
332
#if 0
333
ip              .req    r12
334
sp              .req    r13
335
lr              .req    r14
336
pc              .req    r15
337
#endif
338
 
339
/* ------------------------------------------------------------------------ */
340
/*              Bodies of the division and modulo routines.                 */
341
/* ------------------------------------------------------------------------ */
342
.macro ARM_DIV_BODY dividend, divisor, result, curbit
343
 
344
#if __ARM_ARCH__ >= 5 && ! defined (__OPTIMIZE_SIZE__)
345
 
346
        clz     \curbit, \dividend
347
        clz     \result, \divisor
348
        sub     \curbit, \result, \curbit
349
        rsbs    \curbit, \curbit, #31
350
        addne   \curbit, \curbit, \curbit, lsl #1
351
        mov     \result, #0
352
        addne   pc, pc, \curbit, lsl #2
353
        nop
354
        .set    shift, 32
355
        .rept   32
356
        .set    shift, shift - 1
357
        cmp     \dividend, \divisor, lsl #shift
358
        adc     \result, \result, \result
359
        subcs   \dividend, \dividend, \divisor, lsl #shift
360
        .endr
361
 
362
#else /* __ARM_ARCH__ < 5 || defined (__OPTIMIZE_SIZE__) */
363
#if __ARM_ARCH__ >= 5
364
 
365
        clz     \curbit, \divisor
366
        clz     \result, \dividend
367
        sub     \result, \curbit, \result
368
        mov     \curbit, #1
369
        mov     \divisor, \divisor, lsl \result
370
        mov     \curbit, \curbit, lsl \result
371
        mov     \result, #0
372
 
373
#else /* __ARM_ARCH__ < 5 */
374
 
375
        @ Initially shift the divisor left 3 bits if possible,
376
        @ set curbit accordingly.  This allows for curbit to be located
377
        @ at the left end of each 4 bit nibbles in the division loop
378
        @ to save one loop in most cases.
379
        tst     \divisor, #0xe0000000
380
        moveq   \divisor, \divisor, lsl #3
381
        moveq   \curbit, #8
382
        movne   \curbit, #1
383
 
384
        @ Unless the divisor is very big, shift it up in multiples of
385
        @ four bits, since this is the amount of unwinding in the main
386
        @ division loop.  Continue shifting until the divisor is
387
        @ larger than the dividend.
388
1:      cmp     \divisor, #0x10000000
389
        cmplo   \divisor, \dividend
390
        movlo   \divisor, \divisor, lsl #4
391
        movlo   \curbit, \curbit, lsl #4
392
        blo     1b
393
 
394
        @ For very big divisors, we must shift it a bit at a time, or
395
        @ we will be in danger of overflowing.
396
1:      cmp     \divisor, #0x80000000
397
        cmplo   \divisor, \dividend
398
        movlo   \divisor, \divisor, lsl #1
399
        movlo   \curbit, \curbit, lsl #1
400
        blo     1b
401
 
402
        mov     \result, #0
403
 
404
#endif /* __ARM_ARCH__ < 5 */
405
 
406
        @ Division loop
407
1:      cmp     \dividend, \divisor
408
        subhs   \dividend, \dividend, \divisor
409
        orrhs   \result,   \result,   \curbit
410
        cmp     \dividend, \divisor,  lsr #1
411
        subhs   \dividend, \dividend, \divisor, lsr #1
412
        orrhs   \result,   \result,   \curbit,  lsr #1
413
        cmp     \dividend, \divisor,  lsr #2
414
        subhs   \dividend, \dividend, \divisor, lsr #2
415
        orrhs   \result,   \result,   \curbit,  lsr #2
416
        cmp     \dividend, \divisor,  lsr #3
417
        subhs   \dividend, \dividend, \divisor, lsr #3
418
        orrhs   \result,   \result,   \curbit,  lsr #3
419
        cmp     \dividend, #0                   @ Early termination?
420
        movnes  \curbit,   \curbit,  lsr #4     @ No, any more bits to do?
421
        movne   \divisor,  \divisor, lsr #4
422
        bne     1b
423
 
424
#endif /* __ARM_ARCH__ < 5 || defined (__OPTIMIZE_SIZE__) */
425
 
426
.endm
427
/* ------------------------------------------------------------------------ */
428
.macro ARM_DIV2_ORDER divisor, order
429
 
430
#if __ARM_ARCH__ >= 5
431
 
432
        clz     \order, \divisor
433
        rsb     \order, \order, #31
434
 
435
#else
436
 
437
        cmp     \divisor, #(1 << 16)
438
        movhs   \divisor, \divisor, lsr #16
439
        movhs   \order, #16
440
        movlo   \order, #0
441
 
442
        cmp     \divisor, #(1 << 8)
443
        movhs   \divisor, \divisor, lsr #8
444
        addhs   \order, \order, #8
445
 
446
        cmp     \divisor, #(1 << 4)
447
        movhs   \divisor, \divisor, lsr #4
448
        addhs   \order, \order, #4
449
 
450
        cmp     \divisor, #(1 << 2)
451
        addhi   \order, \order, #3
452
        addls   \order, \order, \divisor, lsr #1
453
 
454
#endif
455
 
456
.endm
457
/* ------------------------------------------------------------------------ */
458
.macro ARM_MOD_BODY dividend, divisor, order, spare
459
 
460
#if __ARM_ARCH__ >= 5 && ! defined (__OPTIMIZE_SIZE__)
461
 
462
        clz     \order, \divisor
463
        clz     \spare, \dividend
464
        sub     \order, \order, \spare
465
        rsbs    \order, \order, #31
466
        addne   pc, pc, \order, lsl #3
467
        nop
468
        .set    shift, 32
469
        .rept   32
470
        .set    shift, shift - 1
471
        cmp     \dividend, \divisor, lsl #shift
472
        subcs   \dividend, \dividend, \divisor, lsl #shift
473
        .endr
474
 
475
#else /* __ARM_ARCH__ < 5 || defined (__OPTIMIZE_SIZE__) */
476
#if __ARM_ARCH__ >= 5
477
 
478
        clz     \order, \divisor
479
        clz     \spare, \dividend
480
        sub     \order, \order, \spare
481
        mov     \divisor, \divisor, lsl \order
482
 
483
#else /* __ARM_ARCH__ < 5 */
484
 
485
        mov     \order, #0
486
 
487
        @ Unless the divisor is very big, shift it up in multiples of
488
        @ four bits, since this is the amount of unwinding in the main
489
        @ division loop.  Continue shifting until the divisor is
490
        @ larger than the dividend.
491
1:      cmp     \divisor, #0x10000000
492
        cmplo   \divisor, \dividend
493
        movlo   \divisor, \divisor, lsl #4
494
        addlo   \order, \order, #4
495
        blo     1b
496
 
497
        @ For very big divisors, we must shift it a bit at a time, or
498
        @ we will be in danger of overflowing.
499
1:      cmp     \divisor, #0x80000000
500
        cmplo   \divisor, \dividend
501
        movlo   \divisor, \divisor, lsl #1
502
        addlo   \order, \order, #1
503
        blo     1b
504
 
505
#endif /* __ARM_ARCH__ < 5 */
506
 
507
        @ Perform all needed substractions to keep only the reminder.
508
        @ Do comparisons in batch of 4 first.
509
        subs    \order, \order, #3              @ yes, 3 is intended here
510
        blt     2f
511
 
512
1:      cmp     \dividend, \divisor
513
        subhs   \dividend, \dividend, \divisor
514
        cmp     \dividend, \divisor,  lsr #1
515
        subhs   \dividend, \dividend, \divisor, lsr #1
516
        cmp     \dividend, \divisor,  lsr #2
517
        subhs   \dividend, \dividend, \divisor, lsr #2
518
        cmp     \dividend, \divisor,  lsr #3
519
        subhs   \dividend, \dividend, \divisor, lsr #3
520
        cmp     \dividend, #1
521
        mov     \divisor, \divisor, lsr #4
522
        subges  \order, \order, #4
523
        bge     1b
524
 
525
        tst     \order, #3
526
        teqne   \dividend, #0
527
        beq     5f
528
 
529
        @ Either 1, 2 or 3 comparison/substractions are left.
530
2:      cmn     \order, #2
531
        blt     4f
532
        beq     3f
533
        cmp     \dividend, \divisor
534
        subhs   \dividend, \dividend, \divisor
535
        mov     \divisor,  \divisor,  lsr #1
536
3:      cmp     \dividend, \divisor
537
        subhs   \dividend, \dividend, \divisor
538
        mov     \divisor,  \divisor,  lsr #1
539
4:      cmp     \dividend, \divisor
540
        subhs   \dividend, \dividend, \divisor
541
5:
542
 
543
#endif /* __ARM_ARCH__ < 5 || defined (__OPTIMIZE_SIZE__) */
544
 
545
.endm
546
/* ------------------------------------------------------------------------ */
547
.macro THUMB_DIV_MOD_BODY modulo
548
        @ Load the constant 0x10000000 into our work register.
549
        mov     work, #1
550
        lsl     work, #28
551
LSYM(Loop1):
552
        @ Unless the divisor is very big, shift it up in multiples of
553
        @ four bits, since this is the amount of unwinding in the main
554
        @ division loop.  Continue shifting until the divisor is
555
        @ larger than the dividend.
556
        cmp     divisor, work
557
        bhs     LSYM(Lbignum)
558
        cmp     divisor, dividend
559
        bhs     LSYM(Lbignum)
560
        lsl     divisor, #4
561
        lsl     curbit,  #4
562
        b       LSYM(Loop1)
563
LSYM(Lbignum):
564
        @ Set work to 0x80000000
565
        lsl     work, #3
566
LSYM(Loop2):
567
        @ For very big divisors, we must shift it a bit at a time, or
568
        @ we will be in danger of overflowing.
569
        cmp     divisor, work
570
        bhs     LSYM(Loop3)
571
        cmp     divisor, dividend
572
        bhs     LSYM(Loop3)
573
        lsl     divisor, #1
574
        lsl     curbit,  #1
575
        b       LSYM(Loop2)
576
LSYM(Loop3):
577
        @ Test for possible subtractions ...
578
  .if \modulo
579
        @ ... On the final pass, this may subtract too much from the dividend,
580
        @ so keep track of which subtractions are done, we can fix them up
581
        @ afterwards.
582
        mov     overdone, #0
583
        cmp     dividend, divisor
584
        blo     LSYM(Lover1)
585
        sub     dividend, dividend, divisor
586
LSYM(Lover1):
587
        lsr     work, divisor, #1
588
        cmp     dividend, work
589
        blo     LSYM(Lover2)
590
        sub     dividend, dividend, work
591
        mov     ip, curbit
592
        mov     work, #1
593
        ror     curbit, work
594
        orr     overdone, curbit
595
        mov     curbit, ip
596
LSYM(Lover2):
597
        lsr     work, divisor, #2
598
        cmp     dividend, work
599
        blo     LSYM(Lover3)
600
        sub     dividend, dividend, work
601
        mov     ip, curbit
602
        mov     work, #2
603
        ror     curbit, work
604
        orr     overdone, curbit
605
        mov     curbit, ip
606
LSYM(Lover3):
607
        lsr     work, divisor, #3
608
        cmp     dividend, work
609
        blo     LSYM(Lover4)
610
        sub     dividend, dividend, work
611
        mov     ip, curbit
612
        mov     work, #3
613
        ror     curbit, work
614
        orr     overdone, curbit
615
        mov     curbit, ip
616
LSYM(Lover4):
617
        mov     ip, curbit
618
  .else
619
        @ ... and note which bits are done in the result.  On the final pass,
620
        @ this may subtract too much from the dividend, but the result will be ok,
621
        @ since the "bit" will have been shifted out at the bottom.
622
        cmp     dividend, divisor
623
        blo     LSYM(Lover1)
624
        sub     dividend, dividend, divisor
625
        orr     result, result, curbit
626
LSYM(Lover1):
627
        lsr     work, divisor, #1
628
        cmp     dividend, work
629
        blo     LSYM(Lover2)
630
        sub     dividend, dividend, work
631
        lsr     work, curbit, #1
632
        orr     result, work
633
LSYM(Lover2):
634
        lsr     work, divisor, #2
635
        cmp     dividend, work
636
        blo     LSYM(Lover3)
637
        sub     dividend, dividend, work
638
        lsr     work, curbit, #2
639
        orr     result, work
640
LSYM(Lover3):
641
        lsr     work, divisor, #3
642
        cmp     dividend, work
643
        blo     LSYM(Lover4)
644
        sub     dividend, dividend, work
645
        lsr     work, curbit, #3
646
        orr     result, work
647
LSYM(Lover4):
648
  .endif
649
 
650
        cmp     dividend, #0                    @ Early termination?
651
        beq     LSYM(Lover5)
652
        lsr     curbit,  #4                     @ No, any more bits to do?
653
        beq     LSYM(Lover5)
654
        lsr     divisor, #4
655
        b       LSYM(Loop3)
656
LSYM(Lover5):
657
  .if \modulo
658
        @ Any subtractions that we should not have done will be recorded in
659
        @ the top three bits of "overdone".  Exactly which were not needed
660
        @ are governed by the position of the bit, stored in ip.
661
        mov     work, #0xe
662
        lsl     work, #28
663
        and     overdone, work
664
        beq     LSYM(Lgot_result)
665
 
666
        @ If we terminated early, because dividend became zero, then the
667
        @ bit in ip will not be in the bottom nibble, and we should not
668
        @ perform the additions below.  We must test for this though
669
        @ (rather relying upon the TSTs to prevent the additions) since
670
        @ the bit in ip could be in the top two bits which might then match
671
        @ with one of the smaller RORs.
672
        mov     curbit, ip
673
        mov     work, #0x7
674
        tst     curbit, work
675
        beq     LSYM(Lgot_result)
676
 
677
        mov     curbit, ip
678
        mov     work, #3
679
        ror     curbit, work
680
        tst     overdone, curbit
681
        beq     LSYM(Lover6)
682
        lsr     work, divisor, #3
683
        add     dividend, work
684
LSYM(Lover6):
685
        mov     curbit, ip
686
        mov     work, #2
687
        ror     curbit, work
688
        tst     overdone, curbit
689
        beq     LSYM(Lover7)
690
        lsr     work, divisor, #2
691
        add     dividend, work
692
LSYM(Lover7):
693
        mov     curbit, ip
694
        mov     work, #1
695
        ror     curbit, work
696
        tst     overdone, curbit
697
        beq     LSYM(Lgot_result)
698
        lsr     work, divisor, #1
699
        add     dividend, work
700
  .endif
701
LSYM(Lgot_result):
702
.endm
703
/* ------------------------------------------------------------------------ */
704
/*              Start of the Real Functions                                 */
705
/* ------------------------------------------------------------------------ */
706
#ifdef L_udivsi3
707
 
708
        FUNC_START udivsi3
709
        FUNC_ALIAS aeabi_uidiv udivsi3
710
 
711
#ifdef __thumb__
712
 
713
        cmp     divisor, #0
714
        beq     LSYM(Ldiv0)
715
        mov     curbit, #1
716
        mov     result, #0
717
 
718
        push    { work }
719
        cmp     dividend, divisor
720
        blo     LSYM(Lgot_result)
721
 
722
        THUMB_DIV_MOD_BODY 0
723
 
724
        mov     r0, result
725
        pop     { work }
726
        RET
727
 
728
#else /* ARM version.  */
729
 
730
        subs    r2, r1, #1
731
        RETc(eq)
732
        bcc     LSYM(Ldiv0)
733
        cmp     r0, r1
734
        bls     11f
735
        tst     r1, r2
736
        beq     12f
737
 
738
        ARM_DIV_BODY r0, r1, r2, r3
739
 
740
        mov     r0, r2
741
        RET
742
 
743
11:     moveq   r0, #1
744
        movne   r0, #0
745
        RET
746
 
747
12:     ARM_DIV2_ORDER r1, r2
748
 
749
        mov     r0, r0, lsr r2
750
        RET
751
 
752
#endif /* ARM version */
753
 
754
        DIV_FUNC_END udivsi3
755
 
756
FUNC_START aeabi_uidivmod
757
#ifdef __thumb__
758
        push    {r0, r1, lr}
759
        bl      SYM(__udivsi3)
760
        POP     {r1, r2, r3}
761
        mul     r2, r0
762
        sub     r1, r1, r2
763
        bx      r3
764
#else
765
        stmfd   sp!, { r0, r1, lr }
766
        bl      SYM(__udivsi3)
767
        ldmfd   sp!, { r1, r2, lr }
768
        mul     r3, r2, r0
769
        sub     r1, r1, r3
770
        RET
771
#endif
772
        FUNC_END aeabi_uidivmod
773
 
774
#endif /* L_udivsi3 */
775
/* ------------------------------------------------------------------------ */
776
#ifdef L_umodsi3
777
 
778
        FUNC_START umodsi3
779
 
780
#ifdef __thumb__
781
 
782
        cmp     divisor, #0
783
        beq     LSYM(Ldiv0)
784
        mov     curbit, #1
785
        cmp     dividend, divisor
786
        bhs     LSYM(Lover10)
787
        RET
788
 
789
LSYM(Lover10):
790
        push    { work }
791
 
792
        THUMB_DIV_MOD_BODY 1
793
 
794
        pop     { work }
795
        RET
796
 
797
#else  /* ARM version.  */
798
 
799
        subs    r2, r1, #1                      @ compare divisor with 1
800
        bcc     LSYM(Ldiv0)
801
        cmpne   r0, r1                          @ compare dividend with divisor
802
        moveq   r0, #0
803
        tsthi   r1, r2                          @ see if divisor is power of 2
804
        andeq   r0, r0, r2
805
        RETc(ls)
806
 
807
        ARM_MOD_BODY r0, r1, r2, r3
808
 
809
        RET
810
 
811
#endif /* ARM version.  */
812
 
813
        DIV_FUNC_END umodsi3
814
 
815
#endif /* L_umodsi3 */
816
/* ------------------------------------------------------------------------ */
817
#ifdef L_divsi3
818
 
819
        FUNC_START divsi3
820
        FUNC_ALIAS aeabi_idiv divsi3
821
 
822
#ifdef __thumb__
823
        cmp     divisor, #0
824
        beq     LSYM(Ldiv0)
825
 
826
        push    { work }
827
        mov     work, dividend
828
        eor     work, divisor           @ Save the sign of the result.
829
        mov     ip, work
830
        mov     curbit, #1
831
        mov     result, #0
832
        cmp     divisor, #0
833
        bpl     LSYM(Lover10)
834
        neg     divisor, divisor        @ Loops below use unsigned.
835
LSYM(Lover10):
836
        cmp     dividend, #0
837
        bpl     LSYM(Lover11)
838
        neg     dividend, dividend
839
LSYM(Lover11):
840
        cmp     dividend, divisor
841
        blo     LSYM(Lgot_result)
842
 
843
        THUMB_DIV_MOD_BODY 0
844
 
845
        mov     r0, result
846
        mov     work, ip
847
        cmp     work, #0
848
        bpl     LSYM(Lover12)
849
        neg     r0, r0
850
LSYM(Lover12):
851
        pop     { work }
852
        RET
853
 
854
#else /* ARM version.  */
855
 
856
        cmp     r1, #0
857
        eor     ip, r0, r1                      @ save the sign of the result.
858
        beq     LSYM(Ldiv0)
859
        rsbmi   r1, r1, #0                      @ loops below use unsigned.
860
        subs    r2, r1, #1                      @ division by 1 or -1 ?
861
        beq     10f
862
        movs    r3, r0
863
        rsbmi   r3, r0, #0                      @ positive dividend value
864
        cmp     r3, r1
865
        bls     11f
866
        tst     r1, r2                          @ divisor is power of 2 ?
867
        beq     12f
868
 
869
        ARM_DIV_BODY r3, r1, r0, r2
870
 
871
        cmp     ip, #0
872
        rsbmi   r0, r0, #0
873
        RET
874
 
875
10:     teq     ip, r0                          @ same sign ?
876
        rsbmi   r0, r0, #0
877
        RET
878
 
879
11:     movlo   r0, #0
880
        moveq   r0, ip, asr #31
881
        orreq   r0, r0, #1
882
        RET
883
 
884
12:     ARM_DIV2_ORDER r1, r2
885
 
886
        cmp     ip, #0
887
        mov     r0, r3, lsr r2
888
        rsbmi   r0, r0, #0
889
        RET
890
 
891
#endif /* ARM version */
892
 
893
        DIV_FUNC_END divsi3
894
 
895
FUNC_START aeabi_idivmod
896
#ifdef __thumb__
897
        push    {r0, r1, lr}
898
        bl      SYM(__divsi3)
899
        POP     {r1, r2, r3}
900
        mul     r2, r0
901
        sub     r1, r1, r2
902
        bx      r3
903
#else
904
        stmfd   sp!, { r0, r1, lr }
905
        bl      SYM(__divsi3)
906
        ldmfd   sp!, { r1, r2, lr }
907
        mul     r3, r2, r0
908
        sub     r1, r1, r3
909
        RET
910
#endif
911
        FUNC_END aeabi_idivmod
912
 
913
#endif /* L_divsi3 */
914
/* ------------------------------------------------------------------------ */
915
#ifdef L_modsi3
916
 
917
        FUNC_START modsi3
918
 
919
#ifdef __thumb__
920
 
921
        mov     curbit, #1
922
        cmp     divisor, #0
923
        beq     LSYM(Ldiv0)
924
        bpl     LSYM(Lover10)
925
        neg     divisor, divisor                @ Loops below use unsigned.
926
LSYM(Lover10):
927
        push    { work }
928
        @ Need to save the sign of the dividend, unfortunately, we need
929
        @ work later on.  Must do this after saving the original value of
930
        @ the work register, because we will pop this value off first.
931
        push    { dividend }
932
        cmp     dividend, #0
933
        bpl     LSYM(Lover11)
934
        neg     dividend, dividend
935
LSYM(Lover11):
936
        cmp     dividend, divisor
937
        blo     LSYM(Lgot_result)
938
 
939
        THUMB_DIV_MOD_BODY 1
940
 
941
        pop     { work }
942
        cmp     work, #0
943
        bpl     LSYM(Lover12)
944
        neg     dividend, dividend
945
LSYM(Lover12):
946
        pop     { work }
947
        RET
948
 
949
#else /* ARM version.  */
950
 
951
        cmp     r1, #0
952
        beq     LSYM(Ldiv0)
953
        rsbmi   r1, r1, #0                      @ loops below use unsigned.
954
        movs    ip, r0                          @ preserve sign of dividend
955
        rsbmi   r0, r0, #0                      @ if negative make positive
956
        subs    r2, r1, #1                      @ compare divisor with 1
957
        cmpne   r0, r1                          @ compare dividend with divisor
958
        moveq   r0, #0
959
        tsthi   r1, r2                          @ see if divisor is power of 2
960
        andeq   r0, r0, r2
961
        bls     10f
962
 
963
        ARM_MOD_BODY r0, r1, r2, r3
964
 
965
10:     cmp     ip, #0
966
        rsbmi   r0, r0, #0
967
        RET
968
 
969
#endif /* ARM version */
970
 
971
        DIV_FUNC_END modsi3
972
 
973
#endif /* L_modsi3 */
974
/* ------------------------------------------------------------------------ */
975
#ifdef L_dvmd_tls
976
 
977
        FUNC_START div0
978
        FUNC_ALIAS aeabi_idiv0 div0
979
        FUNC_ALIAS aeabi_ldiv0 div0
980
 
981
        RET
982
 
983
        FUNC_END aeabi_ldiv0
984
        FUNC_END aeabi_idiv0
985
        FUNC_END div0
986
 
987
#endif /* L_divmodsi_tools */
988
/* ------------------------------------------------------------------------ */
989
#ifdef L_dvmd_lnx
990
@ GNU/Linux division-by zero handler.  Used in place of L_dvmd_tls
991
 
992
/* Constant taken from .  */
993
#define SIGFPE  8
994
 
995
        .code   32
996
        FUNC_START div0
997
 
998
        stmfd   sp!, {r1, lr}
999
        mov     r0, #SIGFPE
1000
        bl      SYM(raise) __PLT__
1001
        RETLDM  r1
1002
 
1003
        FUNC_END div0
1004
 
1005
#endif /* L_dvmd_lnx */
1006
/* ------------------------------------------------------------------------ */
1007
/* Dword shift operations.  */
1008
/* All the following Dword shift variants rely on the fact that
1009
        shft xxx, Reg
1010
   is in fact done as
1011
        shft xxx, (Reg & 255)
1012
   so for Reg value in (32...63) and (-1...-31) we will get zero (in the
1013
   case of logical shifts) or the sign (for asr).  */
1014
 
1015
#ifdef __ARMEB__
1016
#define al      r1
1017
#define ah      r0
1018
#else
1019
#define al      r0
1020
#define ah      r1
1021
#endif
1022
 
1023
/* Prevent __aeabi double-word shifts from being produced on SymbianOS.  */
1024
#ifndef __symbian__
1025
 
1026
#ifdef L_lshrdi3
1027
 
1028
        FUNC_START lshrdi3
1029
        FUNC_ALIAS aeabi_llsr lshrdi3
1030
 
1031
#ifdef __thumb__
1032
        lsr     al, r2
1033
        mov     r3, ah
1034
        lsr     ah, r2
1035
        mov     ip, r3
1036
        sub     r2, #32
1037
        lsr     r3, r2
1038
        orr     al, r3
1039
        neg     r2, r2
1040
        mov     r3, ip
1041
        lsl     r3, r2
1042
        orr     al, r3
1043
        RET
1044
#else
1045
        subs    r3, r2, #32
1046
        rsb     ip, r2, #32
1047
        movmi   al, al, lsr r2
1048
        movpl   al, ah, lsr r3
1049
        orrmi   al, al, ah, lsl ip
1050
        mov     ah, ah, lsr r2
1051
        RET
1052
#endif
1053
        FUNC_END aeabi_llsr
1054
        FUNC_END lshrdi3
1055
 
1056
#endif
1057
 
1058
#ifdef L_ashrdi3
1059
 
1060
        FUNC_START ashrdi3
1061
        FUNC_ALIAS aeabi_lasr ashrdi3
1062
 
1063
#ifdef __thumb__
1064
        lsr     al, r2
1065
        mov     r3, ah
1066
        asr     ah, r2
1067
        sub     r2, #32
1068
        @ If r2 is negative at this point the following step would OR
1069
        @ the sign bit into all of AL.  That's not what we want...
1070
        bmi     1f
1071
        mov     ip, r3
1072
        asr     r3, r2
1073
        orr     al, r3
1074
        mov     r3, ip
1075
1:
1076
        neg     r2, r2
1077
        lsl     r3, r2
1078
        orr     al, r3
1079
        RET
1080
#else
1081
        subs    r3, r2, #32
1082
        rsb     ip, r2, #32
1083
        movmi   al, al, lsr r2
1084
        movpl   al, ah, asr r3
1085
        orrmi   al, al, ah, lsl ip
1086
        mov     ah, ah, asr r2
1087
        RET
1088
#endif
1089
 
1090
        FUNC_END aeabi_lasr
1091
        FUNC_END ashrdi3
1092
 
1093
#endif
1094
 
1095
#ifdef L_ashldi3
1096
 
1097
        FUNC_START ashldi3
1098
        FUNC_ALIAS aeabi_llsl ashldi3
1099
 
1100
#ifdef __thumb__
1101
        lsl     ah, r2
1102
        mov     r3, al
1103
        lsl     al, r2
1104
        mov     ip, r3
1105
        sub     r2, #32
1106
        lsl     r3, r2
1107
        orr     ah, r3
1108
        neg     r2, r2
1109
        mov     r3, ip
1110
        lsr     r3, r2
1111
        orr     ah, r3
1112
        RET
1113
#else
1114
        subs    r3, r2, #32
1115
        rsb     ip, r2, #32
1116
        movmi   ah, ah, lsl r2
1117
        movpl   ah, al, lsl r3
1118
        orrmi   ah, ah, al, lsr ip
1119
        mov     al, al, lsl r2
1120
        RET
1121
#endif
1122
        FUNC_END aeabi_llsl
1123
        FUNC_END ashldi3
1124
 
1125
#endif
1126
 
1127
#endif /* __symbian__ */
1128
 
1129
/* ------------------------------------------------------------------------ */
1130
/* These next two sections are here despite the fact that they contain Thumb
1131
   assembler because their presence allows interworked code to be linked even
1132
   when the GCC library is this one.  */
1133
 
1134
/* Do not build the interworking functions when the target architecture does
1135
   not support Thumb instructions.  (This can be a multilib option).  */
1136
#if defined __ARM_ARCH_4T__ || defined __ARM_ARCH_5T__\
1137
      || defined __ARM_ARCH_5TE__ || defined __ARM_ARCH_5TEJ__ \
1138
      || __ARM_ARCH__ >= 6
1139
 
1140
#if defined L_call_via_rX
1141
 
1142
/* These labels & instructions are used by the Arm/Thumb interworking code.
1143
   The address of function to be called is loaded into a register and then
1144
   one of these labels is called via a BL instruction.  This puts the
1145
   return address into the link register with the bottom bit set, and the
1146
   code here switches to the correct mode before executing the function.  */
1147
 
1148
        .text
1149
        .align 0
1150
        .force_thumb
1151
 
1152
.macro call_via register
1153
        THUMB_FUNC_START _call_via_\register
1154
 
1155
        bx      \register
1156
        nop
1157
 
1158
        SIZE    (_call_via_\register)
1159
.endm
1160
 
1161
        call_via r0
1162
        call_via r1
1163
        call_via r2
1164
        call_via r3
1165
        call_via r4
1166
        call_via r5
1167
        call_via r6
1168
        call_via r7
1169
        call_via r8
1170
        call_via r9
1171
        call_via sl
1172
        call_via fp
1173
        call_via ip
1174
        call_via sp
1175
        call_via lr
1176
 
1177
#endif /* L_call_via_rX */
1178
 
1179
#if defined L_interwork_call_via_rX
1180
 
1181
/* These labels & instructions are used by the Arm/Thumb interworking code,
1182
   when the target address is in an unknown instruction set.  The address
1183
   of function to be called is loaded into a register and then one of these
1184
   labels is called via a BL instruction.  This puts the return address
1185
   into the link register with the bottom bit set, and the code here
1186
   switches to the correct mode before executing the function.  Unfortunately
1187
   the target code cannot be relied upon to return via a BX instruction, so
1188
   instead we have to store the resturn address on the stack and allow the
1189
   called function to return here instead.  Upon return we recover the real
1190
   return address and use a BX to get back to Thumb mode.
1191
 
1192
   There are three variations of this code.  The first,
1193
   _interwork_call_via_rN(), will push the return address onto the
1194
   stack and pop it in _arm_return().  It should only be used if all
1195
   arguments are passed in registers.
1196
 
1197
   The second, _interwork_r7_call_via_rN(), instead stores the return
1198
   address at [r7, #-4].  It is the caller's responsibility to ensure
1199
   that this address is valid and contains no useful data.
1200
 
1201
   The third, _interwork_r11_call_via_rN(), works in the same way but
1202
   uses r11 instead of r7.  It is useful if the caller does not really
1203
   need a frame pointer.  */
1204
 
1205
        .text
1206
        .align 0
1207
 
1208
        .code   32
1209
        .globl _arm_return
1210
LSYM(Lstart_arm_return):
1211
        cfi_start       LSYM(Lstart_arm_return) LSYM(Lend_arm_return)
1212
        cfi_push        0, 0xe, -0x8, 0x8
1213
        nop     @ This nop is for the benefit of debuggers, so that
1214
                @ backtraces will use the correct unwind information.
1215
_arm_return:
1216
        RETLDM  unwind=LSYM(Lstart_arm_return)
1217
        cfi_end LSYM(Lend_arm_return)
1218
 
1219
        .globl _arm_return_r7
1220
_arm_return_r7:
1221
        ldr     lr, [r7, #-4]
1222
        bx      lr
1223
 
1224
        .globl _arm_return_r11
1225
_arm_return_r11:
1226
        ldr     lr, [r11, #-4]
1227
        bx      lr
1228
 
1229
.macro interwork_with_frame frame, register, name, return
1230
        .code   16
1231
 
1232
        THUMB_FUNC_START \name
1233
 
1234
        bx      pc
1235
        nop
1236
 
1237
        .code   32
1238
        tst     \register, #1
1239
        streq   lr, [\frame, #-4]
1240
        adreq   lr, _arm_return_\frame
1241
        bx      \register
1242
 
1243
        SIZE    (\name)
1244
.endm
1245
 
1246
.macro interwork register
1247
        .code   16
1248
 
1249
        THUMB_FUNC_START _interwork_call_via_\register
1250
 
1251
        bx      pc
1252
        nop
1253
 
1254
        .code   32
1255
        .globl LSYM(Lchange_\register)
1256
LSYM(Lchange_\register):
1257
        tst     \register, #1
1258
        streq   lr, [sp, #-8]!
1259
        adreq   lr, _arm_return
1260
        bx      \register
1261
 
1262
        SIZE    (_interwork_call_via_\register)
1263
 
1264
        interwork_with_frame r7,\register,_interwork_r7_call_via_\register
1265
        interwork_with_frame r11,\register,_interwork_r11_call_via_\register
1266
.endm
1267
 
1268
        interwork r0
1269
        interwork r1
1270
        interwork r2
1271
        interwork r3
1272
        interwork r4
1273
        interwork r5
1274
        interwork r6
1275
        interwork r7
1276
        interwork r8
1277
        interwork r9
1278
        interwork sl
1279
        interwork fp
1280
        interwork ip
1281
        interwork sp
1282
 
1283
        /* The LR case has to be handled a little differently...  */
1284
        .code 16
1285
 
1286
        THUMB_FUNC_START _interwork_call_via_lr
1287
 
1288
        bx      pc
1289
        nop
1290
 
1291
        .code 32
1292
        .globl .Lchange_lr
1293
.Lchange_lr:
1294
        tst     lr, #1
1295
        stmeqdb r13!, {lr, pc}
1296
        mov     ip, lr
1297
        adreq   lr, _arm_return
1298
        bx      ip
1299
 
1300
        SIZE    (_interwork_call_via_lr)
1301
 
1302
#endif /* L_interwork_call_via_rX */
1303
#endif /* Arch supports thumb.  */
1304
 
1305
#ifndef __symbian__
1306
#include "ieee754-df.S"
1307
#include "ieee754-sf.S"
1308
#include "bpabi.S"
1309
#endif /* __symbian__ */

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