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1 734 jeremybenn
/* ieee754-sf.S single-precision floating point support for ARM
2
 
3
   Copyright (C) 2003, 2004, 2005, 2007, 2008, 2009  Free Software Foundation, Inc.
4
   Contributed by Nicolas Pitre (nico@cam.org)
5
 
6
   This file is free software; you can redistribute it and/or modify it
7
   under the terms of the GNU General Public License as published by the
8
   Free Software Foundation; either version 3, or (at your option) any
9
   later version.
10
 
11
   This file is distributed in the hope that it will be useful, but
12
   WITHOUT ANY WARRANTY; without even the implied warranty of
13
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
14
   General Public License for more details.
15
 
16
   Under Section 7 of GPL version 3, you are granted additional
17
   permissions described in the GCC Runtime Library Exception, version
18
   3.1, as published by the Free Software Foundation.
19
 
20
   You should have received a copy of the GNU General Public License and
21
   a copy of the GCC Runtime Library Exception along with this program;
22
   see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
23
   .  */
24
 
25
/*
26
 * Notes:
27
 *
28
 * The goal of this code is to be as fast as possible.  This is
29
 * not meant to be easy to understand for the casual reader.
30
 *
31
 * Only the default rounding mode is intended for best performances.
32
 * Exceptions aren't supported yet, but that can be added quite easily
33
 * if necessary without impacting performances.
34
 */
35
 
36
#ifdef L_arm_negsf2
37
 
38
ARM_FUNC_START negsf2
39
ARM_FUNC_ALIAS aeabi_fneg negsf2
40
 
41
        eor     r0, r0, #0x80000000     @ flip sign bit
42
        RET
43
 
44
        FUNC_END aeabi_fneg
45
        FUNC_END negsf2
46
 
47
#endif
48
 
49
#ifdef L_arm_addsubsf3
50
 
51
ARM_FUNC_START aeabi_frsub
52
 
53
        eor     r0, r0, #0x80000000     @ flip sign bit of first arg
54
        b       1f
55
 
56
ARM_FUNC_START subsf3
57
ARM_FUNC_ALIAS aeabi_fsub subsf3
58
 
59
        eor     r1, r1, #0x80000000     @ flip sign bit of second arg
60
#if defined(__INTERWORKING_STUBS__)
61
        b       1f                      @ Skip Thumb-code prologue
62
#endif
63
 
64
ARM_FUNC_START addsf3
65
ARM_FUNC_ALIAS aeabi_fadd addsf3
66
 
67
1:      @ Look for zeroes, equal values, INF, or NAN.
68
        movs    r2, r0, lsl #1
69
        do_it   ne, ttt
70
        COND(mov,s,ne)  r3, r1, lsl #1
71
        teqne   r2, r3
72
        COND(mvn,s,ne)  ip, r2, asr #24
73
        COND(mvn,s,ne)  ip, r3, asr #24
74
        beq     LSYM(Lad_s)
75
 
76
        @ Compute exponent difference.  Make largest exponent in r2,
77
        @ corresponding arg in r0, and positive exponent difference in r3.
78
        mov     r2, r2, lsr #24
79
        rsbs    r3, r2, r3, lsr #24
80
        do_it   gt, ttt
81
        addgt   r2, r2, r3
82
        eorgt   r1, r0, r1
83
        eorgt   r0, r1, r0
84
        eorgt   r1, r0, r1
85
        do_it   lt
86
        rsblt   r3, r3, #0
87
 
88
        @ If exponent difference is too large, return largest argument
89
        @ already in r0.  We need up to 25 bit to handle proper rounding
90
        @ of 0x1p25 - 1.1.
91
        cmp     r3, #25
92
        do_it   hi
93
        RETc(hi)
94
 
95
        @ Convert mantissa to signed integer.
96
        tst     r0, #0x80000000
97
        orr     r0, r0, #0x00800000
98
        bic     r0, r0, #0xff000000
99
        do_it   ne
100
        rsbne   r0, r0, #0
101
        tst     r1, #0x80000000
102
        orr     r1, r1, #0x00800000
103
        bic     r1, r1, #0xff000000
104
        do_it   ne
105
        rsbne   r1, r1, #0
106
 
107
        @ If exponent == difference, one or both args were denormalized.
108
        @ Since this is not common case, rescale them off line.
109
        teq     r2, r3
110
        beq     LSYM(Lad_d)
111
LSYM(Lad_x):
112
 
113
        @ Compensate for the exponent overlapping the mantissa MSB added later
114
        sub     r2, r2, #1
115
 
116
        @ Shift and add second arg to first arg in r0.
117
        @ Keep leftover bits into r1.
118
        shiftop adds r0 r0 r1 asr r3 ip
119
        rsb     r3, r3, #32
120
        shift1  lsl, r1, r1, r3
121
 
122
        @ Keep absolute value in r0-r1, sign in r3 (the n bit was set above)
123
        and     r3, r0, #0x80000000
124
        bpl     LSYM(Lad_p)
125
#if defined(__thumb2__)
126
        negs    r1, r1
127
        sbc     r0, r0, r0, lsl #1
128
#else
129
        rsbs    r1, r1, #0
130
        rsc     r0, r0, #0
131
#endif
132
 
133
        @ Determine how to normalize the result.
134
LSYM(Lad_p):
135
        cmp     r0, #0x00800000
136
        bcc     LSYM(Lad_a)
137
        cmp     r0, #0x01000000
138
        bcc     LSYM(Lad_e)
139
 
140
        @ Result needs to be shifted right.
141
        movs    r0, r0, lsr #1
142
        mov     r1, r1, rrx
143
        add     r2, r2, #1
144
 
145
        @ Make sure we did not bust our exponent.
146
        cmp     r2, #254
147
        bhs     LSYM(Lad_o)
148
 
149
        @ Our result is now properly aligned into r0, remaining bits in r1.
150
        @ Pack final result together.
151
        @ Round with MSB of r1. If halfway between two numbers, round towards
152
        @ LSB of r0 = 0.
153
LSYM(Lad_e):
154
        cmp     r1, #0x80000000
155
        adc     r0, r0, r2, lsl #23
156
        do_it   eq
157
        biceq   r0, r0, #1
158
        orr     r0, r0, r3
159
        RET
160
 
161
        @ Result must be shifted left and exponent adjusted.
162
LSYM(Lad_a):
163
        movs    r1, r1, lsl #1
164
        adc     r0, r0, r0
165
        tst     r0, #0x00800000
166
        sub     r2, r2, #1
167
        bne     LSYM(Lad_e)
168
 
169
        @ No rounding necessary since r1 will always be 0 at this point.
170
LSYM(Lad_l):
171
 
172
#if __ARM_ARCH__ < 5
173
 
174
        movs    ip, r0, lsr #12
175
        moveq   r0, r0, lsl #12
176
        subeq   r2, r2, #12
177
        tst     r0, #0x00ff0000
178
        moveq   r0, r0, lsl #8
179
        subeq   r2, r2, #8
180
        tst     r0, #0x00f00000
181
        moveq   r0, r0, lsl #4
182
        subeq   r2, r2, #4
183
        tst     r0, #0x00c00000
184
        moveq   r0, r0, lsl #2
185
        subeq   r2, r2, #2
186
        cmp     r0, #0x00800000
187
        movcc   r0, r0, lsl #1
188
        sbcs    r2, r2, #0
189
 
190
#else
191
 
192
        clz     ip, r0
193
        sub     ip, ip, #8
194
        subs    r2, r2, ip
195
        shift1  lsl, r0, r0, ip
196
 
197
#endif
198
 
199
        @ Final result with sign
200
        @ If exponent negative, denormalize result.
201
        do_it   ge, et
202
        addge   r0, r0, r2, lsl #23
203
        rsblt   r2, r2, #0
204
        orrge   r0, r0, r3
205
#if defined(__thumb2__)
206
        do_it   lt, t
207
        lsrlt   r0, r0, r2
208
        orrlt   r0, r3, r0
209
#else
210
        orrlt   r0, r3, r0, lsr r2
211
#endif
212
        RET
213
 
214
        @ Fixup and adjust bit position for denormalized arguments.
215
        @ Note that r2 must not remain equal to 0.
216
LSYM(Lad_d):
217
        teq     r2, #0
218
        eor     r1, r1, #0x00800000
219
        do_it   eq, te
220
        eoreq   r0, r0, #0x00800000
221
        addeq   r2, r2, #1
222
        subne   r3, r3, #1
223
        b       LSYM(Lad_x)
224
 
225
LSYM(Lad_s):
226
        mov     r3, r1, lsl #1
227
 
228
        mvns    ip, r2, asr #24
229
        do_it   ne
230
        COND(mvn,s,ne)  ip, r3, asr #24
231
        beq     LSYM(Lad_i)
232
 
233
        teq     r2, r3
234
        beq     1f
235
 
236
        @ Result is x + 0.0 = x or 0.0 + y = y.
237
        teq     r2, #0
238
        do_it   eq
239
        moveq   r0, r1
240
        RET
241
 
242
1:      teq     r0, r1
243
 
244
        @ Result is x - x = 0.
245
        do_it   ne, t
246
        movne   r0, #0
247
        RETc(ne)
248
 
249
        @ Result is x + x = 2x.
250
        tst     r2, #0xff000000
251
        bne     2f
252
        movs    r0, r0, lsl #1
253
        do_it   cs
254
        orrcs   r0, r0, #0x80000000
255
        RET
256
2:      adds    r2, r2, #(2 << 24)
257
        do_it   cc, t
258
        addcc   r0, r0, #(1 << 23)
259
        RETc(cc)
260
        and     r3, r0, #0x80000000
261
 
262
        @ Overflow: return INF.
263
LSYM(Lad_o):
264
        orr     r0, r3, #0x7f000000
265
        orr     r0, r0, #0x00800000
266
        RET
267
 
268
        @ At least one of r0/r1 is INF/NAN.
269
        @   if r0 != INF/NAN: return r1 (which is INF/NAN)
270
        @   if r1 != INF/NAN: return r0 (which is INF/NAN)
271
        @   if r0 or r1 is NAN: return NAN
272
        @   if opposite sign: return NAN
273
        @   otherwise return r0 (which is INF or -INF)
274
LSYM(Lad_i):
275
        mvns    r2, r2, asr #24
276
        do_it   ne, et
277
        movne   r0, r1
278
        COND(mvn,s,eq)  r3, r3, asr #24
279
        movne   r1, r0
280
        movs    r2, r0, lsl #9
281
        do_it   eq, te
282
        COND(mov,s,eq)  r3, r1, lsl #9
283
        teqeq   r0, r1
284
        orrne   r0, r0, #0x00400000     @ quiet NAN
285
        RET
286
 
287
        FUNC_END aeabi_frsub
288
        FUNC_END aeabi_fadd
289
        FUNC_END addsf3
290
        FUNC_END aeabi_fsub
291
        FUNC_END subsf3
292
 
293
ARM_FUNC_START floatunsisf
294
ARM_FUNC_ALIAS aeabi_ui2f floatunsisf
295
 
296
        mov     r3, #0
297
        b       1f
298
 
299
ARM_FUNC_START floatsisf
300
ARM_FUNC_ALIAS aeabi_i2f floatsisf
301
 
302
        ands    r3, r0, #0x80000000
303
        do_it   mi
304
        rsbmi   r0, r0, #0
305
 
306
1:      movs    ip, r0
307
        do_it   eq
308
        RETc(eq)
309
 
310
        @ Add initial exponent to sign
311
        orr     r3, r3, #((127 + 23) << 23)
312
 
313
        .ifnc   ah, r0
314
        mov     ah, r0
315
        .endif
316
        mov     al, #0
317
        b       2f
318
 
319
        FUNC_END aeabi_i2f
320
        FUNC_END floatsisf
321
        FUNC_END aeabi_ui2f
322
        FUNC_END floatunsisf
323
 
324
ARM_FUNC_START floatundisf
325
ARM_FUNC_ALIAS aeabi_ul2f floatundisf
326
 
327
        orrs    r2, r0, r1
328
#if !defined (__VFP_FP__) && !defined(__SOFTFP__)
329
        do_it   eq, t
330
        mvfeqs  f0, #0.0
331
#else
332
        do_it   eq
333
#endif
334
        RETc(eq)
335
 
336
        mov     r3, #0
337
        b       1f
338
 
339
ARM_FUNC_START floatdisf
340
ARM_FUNC_ALIAS aeabi_l2f floatdisf
341
 
342
        orrs    r2, r0, r1
343
#if !defined (__VFP_FP__) && !defined(__SOFTFP__)
344
        do_it   eq, t
345
        mvfeqs  f0, #0.0
346
#else
347
        do_it   eq
348
#endif
349
        RETc(eq)
350
 
351
        ands    r3, ah, #0x80000000     @ sign bit in r3
352
        bpl     1f
353
#if defined(__thumb2__)
354
        negs    al, al
355
        sbc     ah, ah, ah, lsl #1
356
#else
357
        rsbs    al, al, #0
358
        rsc     ah, ah, #0
359
#endif
360
1:
361
#if !defined (__VFP_FP__) && !defined(__SOFTFP__)
362
        @ For hard FPA code we want to return via the tail below so that
363
        @ we can return the result in f0 as well as in r0 for backwards
364
        @ compatibility.
365
        str     lr, [sp, #-8]!
366
        adr     lr, LSYM(f0_ret)
367
#endif
368
 
369
        movs    ip, ah
370
        do_it   eq, tt
371
        moveq   ip, al
372
        moveq   ah, al
373
        moveq   al, #0
374
 
375
        @ Add initial exponent to sign
376
        orr     r3, r3, #((127 + 23 + 32) << 23)
377
        do_it   eq
378
        subeq   r3, r3, #(32 << 23)
379
2:      sub     r3, r3, #(1 << 23)
380
 
381
#if __ARM_ARCH__ < 5
382
 
383
        mov     r2, #23
384
        cmp     ip, #(1 << 16)
385
        do_it   hs, t
386
        movhs   ip, ip, lsr #16
387
        subhs   r2, r2, #16
388
        cmp     ip, #(1 << 8)
389
        do_it   hs, t
390
        movhs   ip, ip, lsr #8
391
        subhs   r2, r2, #8
392
        cmp     ip, #(1 << 4)
393
        do_it   hs, t
394
        movhs   ip, ip, lsr #4
395
        subhs   r2, r2, #4
396
        cmp     ip, #(1 << 2)
397
        do_it   hs, e
398
        subhs   r2, r2, #2
399
        sublo   r2, r2, ip, lsr #1
400
        subs    r2, r2, ip, lsr #3
401
 
402
#else
403
 
404
        clz     r2, ip
405
        subs    r2, r2, #8
406
 
407
#endif
408
 
409
        sub     r3, r3, r2, lsl #23
410
        blt     3f
411
 
412
        shiftop add r3 r3 ah lsl r2 ip
413
        shift1  lsl, ip, al, r2
414
        rsb     r2, r2, #32
415
        cmp     ip, #0x80000000
416
        shiftop adc r0 r3 al lsr r2 r2
417
        do_it   eq
418
        biceq   r0, r0, #1
419
        RET
420
 
421
3:      add     r2, r2, #32
422
        shift1  lsl, ip, ah, r2
423
        rsb     r2, r2, #32
424
        orrs    al, al, ip, lsl #1
425
        shiftop adc r0 r3 ah lsr r2 r2
426
        do_it   eq
427
        biceq   r0, r0, ip, lsr #31
428
        RET
429
 
430
#if !defined (__VFP_FP__) && !defined(__SOFTFP__)
431
 
432
LSYM(f0_ret):
433
        str     r0, [sp, #-4]!
434
        ldfs    f0, [sp], #4
435
        RETLDM
436
 
437
#endif
438
 
439
        FUNC_END floatdisf
440
        FUNC_END aeabi_l2f
441
        FUNC_END floatundisf
442
        FUNC_END aeabi_ul2f
443
 
444
#endif /* L_addsubsf3 */
445
 
446
#ifdef L_arm_muldivsf3
447
 
448
ARM_FUNC_START mulsf3
449
ARM_FUNC_ALIAS aeabi_fmul mulsf3
450
 
451
        @ Mask out exponents, trap any zero/denormal/INF/NAN.
452
        mov     ip, #0xff
453
        ands    r2, ip, r0, lsr #23
454
        do_it   ne, tt
455
        COND(and,s,ne)  r3, ip, r1, lsr #23
456
        teqne   r2, ip
457
        teqne   r3, ip
458
        beq     LSYM(Lml_s)
459
LSYM(Lml_x):
460
 
461
        @ Add exponents together
462
        add     r2, r2, r3
463
 
464
        @ Determine final sign.
465
        eor     ip, r0, r1
466
 
467
        @ Convert mantissa to unsigned integer.
468
        @ If power of two, branch to a separate path.
469
        @ Make up for final alignment.
470
        movs    r0, r0, lsl #9
471
        do_it   ne
472
        COND(mov,s,ne)  r1, r1, lsl #9
473
        beq     LSYM(Lml_1)
474
        mov     r3, #0x08000000
475
        orr     r0, r3, r0, lsr #5
476
        orr     r1, r3, r1, lsr #5
477
 
478
#if __ARM_ARCH__ < 4
479
 
480
        @ Put sign bit in r3, which will be restored into r0 later.
481
        and     r3, ip, #0x80000000
482
 
483
        @ Well, no way to make it shorter without the umull instruction.
484
        do_push {r3, r4, r5}
485
        mov     r4, r0, lsr #16
486
        mov     r5, r1, lsr #16
487
        bic     r0, r0, r4, lsl #16
488
        bic     r1, r1, r5, lsl #16
489
        mul     ip, r4, r5
490
        mul     r3, r0, r1
491
        mul     r0, r5, r0
492
        mla     r0, r4, r1, r0
493
        adds    r3, r3, r0, lsl #16
494
        adc     r1, ip, r0, lsr #16
495
        do_pop  {r0, r4, r5}
496
 
497
#else
498
 
499
        @ The actual multiplication.
500
        umull   r3, r1, r0, r1
501
 
502
        @ Put final sign in r0.
503
        and     r0, ip, #0x80000000
504
 
505
#endif
506
 
507
        @ Adjust result upon the MSB position.
508
        cmp     r1, #(1 << 23)
509
        do_it   cc, tt
510
        movcc   r1, r1, lsl #1
511
        orrcc   r1, r1, r3, lsr #31
512
        movcc   r3, r3, lsl #1
513
 
514
        @ Add sign to result.
515
        orr     r0, r0, r1
516
 
517
        @ Apply exponent bias, check for under/overflow.
518
        sbc     r2, r2, #127
519
        cmp     r2, #(254 - 1)
520
        bhi     LSYM(Lml_u)
521
 
522
        @ Round the result, merge final exponent.
523
        cmp     r3, #0x80000000
524
        adc     r0, r0, r2, lsl #23
525
        do_it   eq
526
        biceq   r0, r0, #1
527
        RET
528
 
529
        @ Multiplication by 0x1p*: let''s shortcut a lot of code.
530
LSYM(Lml_1):
531
        teq     r0, #0
532
        and     ip, ip, #0x80000000
533
        do_it   eq
534
        moveq   r1, r1, lsl #9
535
        orr     r0, ip, r0, lsr #9
536
        orr     r0, r0, r1, lsr #9
537
        subs    r2, r2, #127
538
        do_it   gt, tt
539
        COND(rsb,s,gt)  r3, r2, #255
540
        orrgt   r0, r0, r2, lsl #23
541
        RETc(gt)
542
 
543
        @ Under/overflow: fix things up for the code below.
544
        orr     r0, r0, #0x00800000
545
        mov     r3, #0
546
        subs    r2, r2, #1
547
 
548
LSYM(Lml_u):
549
        @ Overflow?
550
        bgt     LSYM(Lml_o)
551
 
552
        @ Check if denormalized result is possible, otherwise return signed 0.
553
        cmn     r2, #(24 + 1)
554
        do_it   le, t
555
        bicle   r0, r0, #0x7fffffff
556
        RETc(le)
557
 
558
        @ Shift value right, round, etc.
559
        rsb     r2, r2, #0
560
        movs    r1, r0, lsl #1
561
        shift1  lsr, r1, r1, r2
562
        rsb     r2, r2, #32
563
        shift1  lsl, ip, r0, r2
564
        movs    r0, r1, rrx
565
        adc     r0, r0, #0
566
        orrs    r3, r3, ip, lsl #1
567
        do_it   eq
568
        biceq   r0, r0, ip, lsr #31
569
        RET
570
 
571
        @ One or both arguments are denormalized.
572
        @ Scale them leftwards and preserve sign bit.
573
LSYM(Lml_d):
574
        teq     r2, #0
575
        and     ip, r0, #0x80000000
576
1:      do_it   eq, tt
577
        moveq   r0, r0, lsl #1
578
        tsteq   r0, #0x00800000
579
        subeq   r2, r2, #1
580
        beq     1b
581
        orr     r0, r0, ip
582
        teq     r3, #0
583
        and     ip, r1, #0x80000000
584
2:      do_it   eq, tt
585
        moveq   r1, r1, lsl #1
586
        tsteq   r1, #0x00800000
587
        subeq   r3, r3, #1
588
        beq     2b
589
        orr     r1, r1, ip
590
        b       LSYM(Lml_x)
591
 
592
LSYM(Lml_s):
593
        @ Isolate the INF and NAN cases away
594
        and     r3, ip, r1, lsr #23
595
        teq     r2, ip
596
        do_it   ne
597
        teqne   r3, ip
598
        beq     1f
599
 
600
        @ Here, one or more arguments are either denormalized or zero.
601
        bics    ip, r0, #0x80000000
602
        do_it   ne
603
        COND(bic,s,ne)  ip, r1, #0x80000000
604
        bne     LSYM(Lml_d)
605
 
606
        @ Result is 0, but determine sign anyway.
607
LSYM(Lml_z):
608
        eor     r0, r0, r1
609
        bic     r0, r0, #0x7fffffff
610
        RET
611
 
612
1:      @ One or both args are INF or NAN.
613
        teq     r0, #0x0
614
        do_it   ne, ett
615
        teqne   r0, #0x80000000
616
        moveq   r0, r1
617
        teqne   r1, #0x0
618
        teqne   r1, #0x80000000
619
        beq     LSYM(Lml_n)             @ 0 * INF or INF * 0 -> NAN
620
        teq     r2, ip
621
        bne     1f
622
        movs    r2, r0, lsl #9
623
        bne     LSYM(Lml_n)             @ NAN *  -> NAN
624
1:      teq     r3, ip
625
        bne     LSYM(Lml_i)
626
        movs    r3, r1, lsl #9
627
        do_it   ne
628
        movne   r0, r1
629
        bne     LSYM(Lml_n)             @  * NAN -> NAN
630
 
631
        @ Result is INF, but we need to determine its sign.
632
LSYM(Lml_i):
633
        eor     r0, r0, r1
634
 
635
        @ Overflow: return INF (sign already in r0).
636
LSYM(Lml_o):
637
        and     r0, r0, #0x80000000
638
        orr     r0, r0, #0x7f000000
639
        orr     r0, r0, #0x00800000
640
        RET
641
 
642
        @ Return a quiet NAN.
643
LSYM(Lml_n):
644
        orr     r0, r0, #0x7f000000
645
        orr     r0, r0, #0x00c00000
646
        RET
647
 
648
        FUNC_END aeabi_fmul
649
        FUNC_END mulsf3
650
 
651
ARM_FUNC_START divsf3
652
ARM_FUNC_ALIAS aeabi_fdiv divsf3
653
 
654
        @ Mask out exponents, trap any zero/denormal/INF/NAN.
655
        mov     ip, #0xff
656
        ands    r2, ip, r0, lsr #23
657
        do_it   ne, tt
658
        COND(and,s,ne)  r3, ip, r1, lsr #23
659
        teqne   r2, ip
660
        teqne   r3, ip
661
        beq     LSYM(Ldv_s)
662
LSYM(Ldv_x):
663
 
664
        @ Substract divisor exponent from dividend''s
665
        sub     r2, r2, r3
666
 
667
        @ Preserve final sign into ip.
668
        eor     ip, r0, r1
669
 
670
        @ Convert mantissa to unsigned integer.
671
        @ Dividend -> r3, divisor -> r1.
672
        movs    r1, r1, lsl #9
673
        mov     r0, r0, lsl #9
674
        beq     LSYM(Ldv_1)
675
        mov     r3, #0x10000000
676
        orr     r1, r3, r1, lsr #4
677
        orr     r3, r3, r0, lsr #4
678
 
679
        @ Initialize r0 (result) with final sign bit.
680
        and     r0, ip, #0x80000000
681
 
682
        @ Ensure result will land to known bit position.
683
        @ Apply exponent bias accordingly.
684
        cmp     r3, r1
685
        do_it   cc
686
        movcc   r3, r3, lsl #1
687
        adc     r2, r2, #(127 - 2)
688
 
689
        @ The actual division loop.
690
        mov     ip, #0x00800000
691
1:      cmp     r3, r1
692
        do_it   cs, t
693
        subcs   r3, r3, r1
694
        orrcs   r0, r0, ip
695
        cmp     r3, r1, lsr #1
696
        do_it   cs, t
697
        subcs   r3, r3, r1, lsr #1
698
        orrcs   r0, r0, ip, lsr #1
699
        cmp     r3, r1, lsr #2
700
        do_it   cs, t
701
        subcs   r3, r3, r1, lsr #2
702
        orrcs   r0, r0, ip, lsr #2
703
        cmp     r3, r1, lsr #3
704
        do_it   cs, t
705
        subcs   r3, r3, r1, lsr #3
706
        orrcs   r0, r0, ip, lsr #3
707
        movs    r3, r3, lsl #4
708
        do_it   ne
709
        COND(mov,s,ne)  ip, ip, lsr #4
710
        bne     1b
711
 
712
        @ Check exponent for under/overflow.
713
        cmp     r2, #(254 - 1)
714
        bhi     LSYM(Lml_u)
715
 
716
        @ Round the result, merge final exponent.
717
        cmp     r3, r1
718
        adc     r0, r0, r2, lsl #23
719
        do_it   eq
720
        biceq   r0, r0, #1
721
        RET
722
 
723
        @ Division by 0x1p*: let''s shortcut a lot of code.
724
LSYM(Ldv_1):
725
        and     ip, ip, #0x80000000
726
        orr     r0, ip, r0, lsr #9
727
        adds    r2, r2, #127
728
        do_it   gt, tt
729
        COND(rsb,s,gt)  r3, r2, #255
730
        orrgt   r0, r0, r2, lsl #23
731
        RETc(gt)
732
 
733
        orr     r0, r0, #0x00800000
734
        mov     r3, #0
735
        subs    r2, r2, #1
736
        b       LSYM(Lml_u)
737
 
738
        @ One or both arguments are denormalized.
739
        @ Scale them leftwards and preserve sign bit.
740
LSYM(Ldv_d):
741
        teq     r2, #0
742
        and     ip, r0, #0x80000000
743
1:      do_it   eq, tt
744
        moveq   r0, r0, lsl #1
745
        tsteq   r0, #0x00800000
746
        subeq   r2, r2, #1
747
        beq     1b
748
        orr     r0, r0, ip
749
        teq     r3, #0
750
        and     ip, r1, #0x80000000
751
2:      do_it   eq, tt
752
        moveq   r1, r1, lsl #1
753
        tsteq   r1, #0x00800000
754
        subeq   r3, r3, #1
755
        beq     2b
756
        orr     r1, r1, ip
757
        b       LSYM(Ldv_x)
758
 
759
        @ One or both arguments are either INF, NAN, zero or denormalized.
760
LSYM(Ldv_s):
761
        and     r3, ip, r1, lsr #23
762
        teq     r2, ip
763
        bne     1f
764
        movs    r2, r0, lsl #9
765
        bne     LSYM(Lml_n)             @ NAN /  -> NAN
766
        teq     r3, ip
767
        bne     LSYM(Lml_i)             @ INF /  -> INF
768
        mov     r0, r1
769
        b       LSYM(Lml_n)             @ INF / (INF or NAN) -> NAN
770
1:      teq     r3, ip
771
        bne     2f
772
        movs    r3, r1, lsl #9
773
        beq     LSYM(Lml_z)             @  / INF -> 0
774
        mov     r0, r1
775
        b       LSYM(Lml_n)             @  / NAN -> NAN
776
2:      @ If both are nonzero, we need to normalize and resume above.
777
        bics    ip, r0, #0x80000000
778
        do_it   ne
779
        COND(bic,s,ne)  ip, r1, #0x80000000
780
        bne     LSYM(Ldv_d)
781
        @ One or both arguments are zero.
782
        bics    r2, r0, #0x80000000
783
        bne     LSYM(Lml_i)             @  / 0 -> INF
784
        bics    r3, r1, #0x80000000
785
        bne     LSYM(Lml_z)             @ 0 /  -> 0
786
        b       LSYM(Lml_n)             @ 0 / 0 -> NAN
787
 
788
        FUNC_END aeabi_fdiv
789
        FUNC_END divsf3
790
 
791
#endif /* L_muldivsf3 */
792
 
793
#ifdef L_arm_cmpsf2
794
 
795
        @ The return value in r0 is
796
        @
797
        @   0  if the operands are equal
798
        @   1  if the first operand is greater than the second, or
799
        @      the operands are unordered and the operation is
800
        @      CMP, LT, LE, NE, or EQ.
801
        @   -1 if the first operand is less than the second, or
802
        @      the operands are unordered and the operation is GT
803
        @      or GE.
804
        @
805
        @ The Z flag will be set iff the operands are equal.
806
        @
807
        @ The following registers are clobbered by this function:
808
        @   ip, r0, r1, r2, r3
809
 
810
ARM_FUNC_START gtsf2
811
ARM_FUNC_ALIAS gesf2 gtsf2
812
        mov     ip, #-1
813
        b       1f
814
 
815
ARM_FUNC_START ltsf2
816
ARM_FUNC_ALIAS lesf2 ltsf2
817
        mov     ip, #1
818
        b       1f
819
 
820
ARM_FUNC_START cmpsf2
821
ARM_FUNC_ALIAS nesf2 cmpsf2
822
ARM_FUNC_ALIAS eqsf2 cmpsf2
823
        mov     ip, #1                  @ how should we specify unordered here?
824
 
825
1:      str     ip, [sp, #-4]!
826
 
827
        @ Trap any INF/NAN first.
828
        mov     r2, r0, lsl #1
829
        mov     r3, r1, lsl #1
830
        mvns    ip, r2, asr #24
831
        do_it   ne
832
        COND(mvn,s,ne)  ip, r3, asr #24
833
        beq     3f
834
 
835
        @ Compare values.
836
        @ Note that 0.0 is equal to -0.0.
837
2:      add     sp, sp, #4
838
        orrs    ip, r2, r3, lsr #1      @ test if both are 0, clear C flag
839
        do_it   ne
840
        teqne   r0, r1                  @ if not 0 compare sign
841
        do_it   pl
842
        COND(sub,s,pl)  r0, r2, r3              @ if same sign compare values, set r0
843
 
844
        @ Result:
845
        do_it   hi
846
        movhi   r0, r1, asr #31
847
        do_it   lo
848
        mvnlo   r0, r1, asr #31
849
        do_it   ne
850
        orrne   r0, r0, #1
851
        RET
852
 
853
        @ Look for a NAN.
854
3:      mvns    ip, r2, asr #24
855
        bne     4f
856
        movs    ip, r0, lsl #9
857
        bne     5f                      @ r0 is NAN
858
4:      mvns    ip, r3, asr #24
859
        bne     2b
860
        movs    ip, r1, lsl #9
861
        beq     2b                      @ r1 is not NAN
862
5:      ldr     r0, [sp], #4            @ return unordered code.
863
        RET
864
 
865
        FUNC_END gesf2
866
        FUNC_END gtsf2
867
        FUNC_END lesf2
868
        FUNC_END ltsf2
869
        FUNC_END nesf2
870
        FUNC_END eqsf2
871
        FUNC_END cmpsf2
872
 
873
ARM_FUNC_START aeabi_cfrcmple
874
 
875
        mov     ip, r0
876
        mov     r0, r1
877
        mov     r1, ip
878
        b       6f
879
 
880
ARM_FUNC_START aeabi_cfcmpeq
881
ARM_FUNC_ALIAS aeabi_cfcmple aeabi_cfcmpeq
882
 
883
        @ The status-returning routines are required to preserve all
884
        @ registers except ip, lr, and cpsr.
885
6:      do_push {r0, r1, r2, r3, lr}
886
        ARM_CALL cmpsf2
887
        @ Set the Z flag correctly, and the C flag unconditionally.
888
        cmp     r0, #0
889
        @ Clear the C flag if the return value was -1, indicating
890
        @ that the first operand was smaller than the second.
891
        do_it   mi
892
        cmnmi   r0, #0
893
        RETLDM  "r0, r1, r2, r3"
894
 
895
        FUNC_END aeabi_cfcmple
896
        FUNC_END aeabi_cfcmpeq
897
        FUNC_END aeabi_cfrcmple
898
 
899
ARM_FUNC_START  aeabi_fcmpeq
900
 
901
        str     lr, [sp, #-8]!
902
        ARM_CALL aeabi_cfcmple
903
        do_it   eq, e
904
        moveq   r0, #1  @ Equal to.
905
        movne   r0, #0  @ Less than, greater than, or unordered.
906
        RETLDM
907
 
908
        FUNC_END aeabi_fcmpeq
909
 
910
ARM_FUNC_START  aeabi_fcmplt
911
 
912
        str     lr, [sp, #-8]!
913
        ARM_CALL aeabi_cfcmple
914
        do_it   cc, e
915
        movcc   r0, #1  @ Less than.
916
        movcs   r0, #0  @ Equal to, greater than, or unordered.
917
        RETLDM
918
 
919
        FUNC_END aeabi_fcmplt
920
 
921
ARM_FUNC_START  aeabi_fcmple
922
 
923
        str     lr, [sp, #-8]!
924
        ARM_CALL aeabi_cfcmple
925
        do_it   ls, e
926
        movls   r0, #1  @ Less than or equal to.
927
        movhi   r0, #0  @ Greater than or unordered.
928
        RETLDM
929
 
930
        FUNC_END aeabi_fcmple
931
 
932
ARM_FUNC_START  aeabi_fcmpge
933
 
934
        str     lr, [sp, #-8]!
935
        ARM_CALL aeabi_cfrcmple
936
        do_it   ls, e
937
        movls   r0, #1  @ Operand 2 is less than or equal to operand 1.
938
        movhi   r0, #0  @ Operand 2 greater than operand 1, or unordered.
939
        RETLDM
940
 
941
        FUNC_END aeabi_fcmpge
942
 
943
ARM_FUNC_START  aeabi_fcmpgt
944
 
945
        str     lr, [sp, #-8]!
946
        ARM_CALL aeabi_cfrcmple
947
        do_it   cc, e
948
        movcc   r0, #1  @ Operand 2 is less than operand 1.
949
        movcs   r0, #0  @ Operand 2 is greater than or equal to operand 1,
950
                        @ or they are unordered.
951
        RETLDM
952
 
953
        FUNC_END aeabi_fcmpgt
954
 
955
#endif /* L_cmpsf2 */
956
 
957
#ifdef L_arm_unordsf2
958
 
959
ARM_FUNC_START unordsf2
960
ARM_FUNC_ALIAS aeabi_fcmpun unordsf2
961
 
962
        mov     r2, r0, lsl #1
963
        mov     r3, r1, lsl #1
964
        mvns    ip, r2, asr #24
965
        bne     1f
966
        movs    ip, r0, lsl #9
967
        bne     3f                      @ r0 is NAN
968
1:      mvns    ip, r3, asr #24
969
        bne     2f
970
        movs    ip, r1, lsl #9
971
        bne     3f                      @ r1 is NAN
972
2:      mov     r0, #0                  @ arguments are ordered.
973
        RET
974
3:      mov     r0, #1                  @ arguments are unordered.
975
        RET
976
 
977
        FUNC_END aeabi_fcmpun
978
        FUNC_END unordsf2
979
 
980
#endif /* L_unordsf2 */
981
 
982
#ifdef L_arm_fixsfsi
983
 
984
ARM_FUNC_START fixsfsi
985
ARM_FUNC_ALIAS aeabi_f2iz fixsfsi
986
 
987
        @ check exponent range.
988
        mov     r2, r0, lsl #1
989
        cmp     r2, #(127 << 24)
990
        bcc     1f                      @ value is too small
991
        mov     r3, #(127 + 31)
992
        subs    r2, r3, r2, lsr #24
993
        bls     2f                      @ value is too large
994
 
995
        @ scale value
996
        mov     r3, r0, lsl #8
997
        orr     r3, r3, #0x80000000
998
        tst     r0, #0x80000000         @ the sign bit
999
        shift1  lsr, r0, r3, r2
1000
        do_it   ne
1001
        rsbne   r0, r0, #0
1002
        RET
1003
 
1004
1:      mov     r0, #0
1005
        RET
1006
 
1007
2:      cmp     r2, #(127 + 31 - 0xff)
1008
        bne     3f
1009
        movs    r2, r0, lsl #9
1010
        bne     4f                      @ r0 is NAN.
1011
3:      ands    r0, r0, #0x80000000     @ the sign bit
1012
        do_it   eq
1013
        moveq   r0, #0x7fffffff         @ the maximum signed positive si
1014
        RET
1015
 
1016
4:      mov     r0, #0                  @ What should we convert NAN to?
1017
        RET
1018
 
1019
        FUNC_END aeabi_f2iz
1020
        FUNC_END fixsfsi
1021
 
1022
#endif /* L_fixsfsi */
1023
 
1024
#ifdef L_arm_fixunssfsi
1025
 
1026
ARM_FUNC_START fixunssfsi
1027
ARM_FUNC_ALIAS aeabi_f2uiz fixunssfsi
1028
 
1029
        @ check exponent range.
1030
        movs    r2, r0, lsl #1
1031
        bcs     1f                      @ value is negative
1032
        cmp     r2, #(127 << 24)
1033
        bcc     1f                      @ value is too small
1034
        mov     r3, #(127 + 31)
1035
        subs    r2, r3, r2, lsr #24
1036
        bmi     2f                      @ value is too large
1037
 
1038
        @ scale the value
1039
        mov     r3, r0, lsl #8
1040
        orr     r3, r3, #0x80000000
1041
        shift1  lsr, r0, r3, r2
1042
        RET
1043
 
1044
1:      mov     r0, #0
1045
        RET
1046
 
1047
2:      cmp     r2, #(127 + 31 - 0xff)
1048
        bne     3f
1049
        movs    r2, r0, lsl #9
1050
        bne     4f                      @ r0 is NAN.
1051
3:      mov     r0, #0xffffffff         @ maximum unsigned si
1052
        RET
1053
 
1054
4:      mov     r0, #0                  @ What should we convert NAN to?
1055
        RET
1056
 
1057
        FUNC_END aeabi_f2uiz
1058
        FUNC_END fixunssfsi
1059
 
1060
#endif /* L_fixunssfsi */

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