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[/] [openrisc/] [trunk/] [gnu-src/] [gcc-4.5.1/] [gcc/] [config/] [arm/] [unwind-arm.c] - Blame information for rev 298

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1 282 jeremybenn
/* ARM EABI compliant unwinding routines.
2
   Copyright (C) 2004, 2005, 2009 Free Software Foundation, Inc.
3
   Contributed by Paul Brook
4
 
5
   This file is free software; you can redistribute it and/or modify it
6
   under the terms of the GNU General Public License as published by the
7
   Free Software Foundation; either version 3, or (at your option) any
8
   later version.
9
 
10
   This file is distributed in the hope that it will be useful, but
11
   WITHOUT ANY WARRANTY; without even the implied warranty of
12
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
13
   General Public License for more details.
14
 
15
   Under Section 7 of GPL version 3, you are granted additional
16
   permissions described in the GCC Runtime Library Exception, version
17
   3.1, as published by the Free Software Foundation.
18
 
19
   You should have received a copy of the GNU General Public License and
20
   a copy of the GCC Runtime Library Exception along with this program;
21
   see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
22
   <http://www.gnu.org/licenses/>.  */
23
 
24
#include "unwind.h"
25
 
26
/* We add a prototype for abort here to avoid creating a dependency on
27
   target headers.  */
28
extern void abort (void);
29
 
30
/* Definitions for C++ runtime support routines.  We make these weak
31
   declarations to avoid pulling in libsupc++ unnecessarily.  */
32
typedef unsigned char bool;
33
 
34
typedef struct _ZSt9type_info type_info; /* This names C++ type_info type */
35
 
36
void __attribute__((weak)) __cxa_call_unexpected(_Unwind_Control_Block *ucbp);
37
bool __attribute__((weak)) __cxa_begin_cleanup(_Unwind_Control_Block *ucbp);
38
bool __attribute__((weak)) __cxa_type_match(_Unwind_Control_Block *ucbp,
39
                                            const type_info *rttip,
40
                                            bool is_reference,
41
                                            void **matched_object);
42
 
43
_Unwind_Ptr __attribute__((weak))
44
__gnu_Unwind_Find_exidx (_Unwind_Ptr, int *);
45
 
46
/* Misc constants.  */
47
#define R_IP    12
48
#define R_SP    13
49
#define R_LR    14
50
#define R_PC    15
51
 
52
#define EXIDX_CANTUNWIND 1
53
#define uint32_highbit (((_uw) 1) << 31)
54
 
55
#define UCB_FORCED_STOP_FN(ucbp) ((ucbp)->unwinder_cache.reserved1)
56
#define UCB_PR_ADDR(ucbp) ((ucbp)->unwinder_cache.reserved2)
57
#define UCB_SAVED_CALLSITE_ADDR(ucbp) ((ucbp)->unwinder_cache.reserved3)
58
#define UCB_FORCED_STOP_ARG(ucbp) ((ucbp)->unwinder_cache.reserved4)
59
 
60
struct core_regs
61
{
62
  _uw r[16];
63
};
64
 
65
/* We use normal integer types here to avoid the compiler generating
66
   coprocessor instructions.  */
67
struct vfp_regs
68
{
69
  _uw64 d[16];
70
  _uw pad;
71
};
72
 
73
struct vfpv3_regs
74
{
75
  /* Always populated via VSTM, so no need for the "pad" field from
76
     vfp_regs (which is used to store the format word for FSTMX).  */
77
  _uw64 d[16];
78
};
79
 
80
struct fpa_reg
81
{
82
  _uw w[3];
83
};
84
 
85
struct fpa_regs
86
{
87
  struct fpa_reg f[8];
88
};
89
 
90
struct wmmxd_regs
91
{
92
  _uw64 wd[16];
93
};
94
 
95
struct wmmxc_regs
96
{
97
  _uw wc[4];
98
};
99
 
100
/* Unwind descriptors.  */
101
 
102
typedef struct
103
{
104
  _uw16 length;
105
  _uw16 offset;
106
} EHT16;
107
 
108
typedef struct
109
{
110
  _uw length;
111
  _uw offset;
112
} EHT32;
113
 
114
/* The ABI specifies that the unwind routines may only use core registers,
115
   except when actually manipulating coprocessor state.  This allows
116
   us to write one implementation that works on all platforms by
117
   demand-saving coprocessor registers.
118
 
119
   During unwinding we hold the coprocessor state in the actual hardware
120
   registers and allocate demand-save areas for use during phase1
121
   unwinding.  */
122
 
123
typedef struct
124
{
125
  /* The first fields must be the same as a phase2_vrs.  */
126
  _uw demand_save_flags;
127
  struct core_regs core;
128
  _uw prev_sp; /* Only valid during forced unwinding.  */
129
  struct vfp_regs vfp;
130
  struct vfpv3_regs vfp_regs_16_to_31;
131
  struct fpa_regs fpa;
132
  struct wmmxd_regs wmmxd;
133
  struct wmmxc_regs wmmxc;
134
} phase1_vrs;
135
 
136
#define DEMAND_SAVE_VFP 1       /* VFP state has been saved if not set */
137
#define DEMAND_SAVE_VFP_D 2     /* VFP state is for FLDMD/FSTMD if set */
138
#define DEMAND_SAVE_VFP_V3 4    /* VFPv3 state for regs 16 .. 31 has
139
                                   been saved if not set */
140
#define DEMAND_SAVE_WMMXD 8     /* iWMMXt data registers have been
141
                                   saved if not set.  */
142
#define DEMAND_SAVE_WMMXC 16    /* iWMMXt control registers have been
143
                                   saved if not set.  */
144
 
145
/* This must match the structure created by the assembly wrappers.  */
146
typedef struct
147
{
148
  _uw demand_save_flags;
149
  struct core_regs core;
150
} phase2_vrs;
151
 
152
 
153
/* An exception index table entry.  */
154
 
155
typedef struct __EIT_entry
156
{
157
  _uw fnoffset;
158
  _uw content;
159
} __EIT_entry;
160
 
161
/* Assembly helper functions.  */
162
 
163
/* Restore core register state.  Never returns.  */
164
void __attribute__((noreturn)) restore_core_regs (struct core_regs *);
165
 
166
 
167
/* Coprocessor register state manipulation functions.  */
168
 
169
/* Routines for FLDMX/FSTMX format...  */
170
void __gnu_Unwind_Save_VFP (struct vfp_regs * p);
171
void __gnu_Unwind_Restore_VFP (struct vfp_regs * p);
172
void __gnu_Unwind_Save_WMMXD (struct wmmxd_regs * p);
173
void __gnu_Unwind_Restore_WMMXD (struct wmmxd_regs * p);
174
void __gnu_Unwind_Save_WMMXC (struct wmmxc_regs * p);
175
void __gnu_Unwind_Restore_WMMXC (struct wmmxc_regs * p);
176
 
177
/* ...and those for FLDMD/FSTMD format...  */
178
void __gnu_Unwind_Save_VFP_D (struct vfp_regs * p);
179
void __gnu_Unwind_Restore_VFP_D (struct vfp_regs * p);
180
 
181
/* ...and those for VLDM/VSTM format, saving/restoring only registers
182
   16 through 31.  */
183
void __gnu_Unwind_Save_VFP_D_16_to_31 (struct vfpv3_regs * p);
184
void __gnu_Unwind_Restore_VFP_D_16_to_31 (struct vfpv3_regs * p);
185
 
186
/* Restore coprocessor state after phase1 unwinding.  */
187
static void
188
restore_non_core_regs (phase1_vrs * vrs)
189
{
190
  if ((vrs->demand_save_flags & DEMAND_SAVE_VFP) == 0)
191
    {
192
      if (vrs->demand_save_flags & DEMAND_SAVE_VFP_D)
193
        __gnu_Unwind_Restore_VFP_D (&vrs->vfp);
194
      else
195
        __gnu_Unwind_Restore_VFP (&vrs->vfp);
196
    }
197
 
198
  if ((vrs->demand_save_flags & DEMAND_SAVE_VFP_V3) == 0)
199
    __gnu_Unwind_Restore_VFP_D_16_to_31 (&vrs->vfp_regs_16_to_31);
200
 
201
  if ((vrs->demand_save_flags & DEMAND_SAVE_WMMXD) == 0)
202
    __gnu_Unwind_Restore_WMMXD (&vrs->wmmxd);
203
  if ((vrs->demand_save_flags & DEMAND_SAVE_WMMXC) == 0)
204
    __gnu_Unwind_Restore_WMMXC (&vrs->wmmxc);
205
}
206
 
207
/* A better way to do this would probably be to compare the absolute address
208
   with a segment relative relocation of the same symbol.  */
209
 
210
extern int __text_start;
211
extern int __data_start;
212
 
213
/* The exception index table location.  */
214
extern __EIT_entry __exidx_start;
215
extern __EIT_entry __exidx_end;
216
 
217
/* ABI defined personality routines.  */
218
extern _Unwind_Reason_Code __aeabi_unwind_cpp_pr0 (_Unwind_State,
219
    _Unwind_Control_Block *, _Unwind_Context *);// __attribute__((weak));
220
extern _Unwind_Reason_Code __aeabi_unwind_cpp_pr1 (_Unwind_State,
221
    _Unwind_Control_Block *, _Unwind_Context *) __attribute__((weak));
222
extern _Unwind_Reason_Code __aeabi_unwind_cpp_pr2 (_Unwind_State,
223
    _Unwind_Control_Block *, _Unwind_Context *) __attribute__((weak));
224
 
225
/* ABI defined routine to store a virtual register to memory.  */
226
 
227
_Unwind_VRS_Result _Unwind_VRS_Get (_Unwind_Context *context,
228
                                    _Unwind_VRS_RegClass regclass,
229
                                    _uw regno,
230
                                    _Unwind_VRS_DataRepresentation representation,
231
                                    void *valuep)
232
{
233
  phase1_vrs *vrs = (phase1_vrs *) context;
234
 
235
  switch (regclass)
236
    {
237
    case _UVRSC_CORE:
238
      if (representation != _UVRSD_UINT32
239
          || regno > 15)
240
        return _UVRSR_FAILED;
241
      *(_uw *) valuep = vrs->core.r[regno];
242
      return _UVRSR_OK;
243
 
244
    case _UVRSC_VFP:
245
    case _UVRSC_FPA:
246
    case _UVRSC_WMMXD:
247
    case _UVRSC_WMMXC:
248
      return _UVRSR_NOT_IMPLEMENTED;
249
 
250
    default:
251
      return _UVRSR_FAILED;
252
    }
253
}
254
 
255
 
256
/* ABI defined function to load a virtual register from memory.  */
257
 
258
_Unwind_VRS_Result _Unwind_VRS_Set (_Unwind_Context *context,
259
                                    _Unwind_VRS_RegClass regclass,
260
                                    _uw regno,
261
                                    _Unwind_VRS_DataRepresentation representation,
262
                                    void *valuep)
263
{
264
  phase1_vrs *vrs = (phase1_vrs *) context;
265
 
266
  switch (regclass)
267
    {
268
    case _UVRSC_CORE:
269
      if (representation != _UVRSD_UINT32
270
          || regno > 15)
271
        return _UVRSR_FAILED;
272
 
273
      vrs->core.r[regno] = *(_uw *) valuep;
274
      return _UVRSR_OK;
275
 
276
    case _UVRSC_VFP:
277
    case _UVRSC_FPA:
278
    case _UVRSC_WMMXD:
279
    case _UVRSC_WMMXC:
280
      return _UVRSR_NOT_IMPLEMENTED;
281
 
282
    default:
283
      return _UVRSR_FAILED;
284
    }
285
}
286
 
287
 
288
/* ABI defined function to pop registers off the stack.  */
289
 
290
_Unwind_VRS_Result _Unwind_VRS_Pop (_Unwind_Context *context,
291
                                    _Unwind_VRS_RegClass regclass,
292
                                    _uw discriminator,
293
                                    _Unwind_VRS_DataRepresentation representation)
294
{
295
  phase1_vrs *vrs = (phase1_vrs *) context;
296
 
297
  switch (regclass)
298
    {
299
    case _UVRSC_CORE:
300
      {
301
        _uw *ptr;
302
        _uw mask;
303
        int i;
304
 
305
        if (representation != _UVRSD_UINT32)
306
          return _UVRSR_FAILED;
307
 
308
        mask = discriminator & 0xffff;
309
        ptr = (_uw *) vrs->core.r[R_SP];
310
        /* Pop the requested registers.  */
311
        for (i = 0; i < 16; i++)
312
          {
313
            if (mask & (1 << i))
314
              vrs->core.r[i] = *(ptr++);
315
          }
316
        /* Writeback the stack pointer value if it wasn't restored.  */
317
        if ((mask & (1 << R_SP)) == 0)
318
          vrs->core.r[R_SP] = (_uw) ptr;
319
      }
320
      return _UVRSR_OK;
321
 
322
    case _UVRSC_VFP:
323
      {
324
        _uw start = discriminator >> 16;
325
        _uw count = discriminator & 0xffff;
326
        struct vfp_regs tmp;
327
        struct vfpv3_regs tmp_16_to_31;
328
        int tmp_count;
329
        _uw *sp;
330
        _uw *dest;
331
        int num_vfpv3_regs = 0;
332
 
333
        /* We use an approximation here by bounding _UVRSD_DOUBLE
334
           register numbers at 32 always, since we can't detect if
335
           VFPv3 isn't present (in such a case the upper limit is 16).  */
336
        if ((representation != _UVRSD_VFPX && representation != _UVRSD_DOUBLE)
337
            || start + count > (representation == _UVRSD_VFPX ? 16 : 32)
338
            || (representation == _UVRSD_VFPX && start >= 16))
339
          return _UVRSR_FAILED;
340
 
341
        /* Check if we're being asked to pop VFPv3-only registers
342
           (numbers 16 through 31).  */
343
        if (start >= 16)
344
          num_vfpv3_regs = count;
345
        else if (start + count > 16)
346
          num_vfpv3_regs = start + count - 16;
347
 
348
        if (num_vfpv3_regs && representation != _UVRSD_DOUBLE)
349
          return _UVRSR_FAILED;
350
 
351
        /* Demand-save coprocessor registers for stage1.  */
352
        if (start < 16 && (vrs->demand_save_flags & DEMAND_SAVE_VFP))
353
          {
354
            vrs->demand_save_flags &= ~DEMAND_SAVE_VFP;
355
 
356
            if (representation == _UVRSD_DOUBLE)
357
              {
358
                /* Save in FLDMD/FSTMD format.  */
359
                vrs->demand_save_flags |= DEMAND_SAVE_VFP_D;
360
                __gnu_Unwind_Save_VFP_D (&vrs->vfp);
361
              }
362
            else
363
              {
364
                /* Save in FLDMX/FSTMX format.  */
365
                vrs->demand_save_flags &= ~DEMAND_SAVE_VFP_D;
366
                __gnu_Unwind_Save_VFP (&vrs->vfp);
367
              }
368
          }
369
 
370
        if (num_vfpv3_regs > 0
371
            && (vrs->demand_save_flags & DEMAND_SAVE_VFP_V3))
372
          {
373
            vrs->demand_save_flags &= ~DEMAND_SAVE_VFP_V3;
374
            __gnu_Unwind_Save_VFP_D_16_to_31 (&vrs->vfp_regs_16_to_31);
375
          }
376
 
377
        /* Restore the registers from the stack.  Do this by saving the
378
           current VFP registers to a memory area, moving the in-memory
379
           values into that area, and restoring from the whole area.
380
           For _UVRSD_VFPX we assume FSTMX standard format 1.  */
381
        if (representation == _UVRSD_VFPX)
382
          __gnu_Unwind_Save_VFP (&tmp);
383
        else
384
          {
385
            /* Save registers 0 .. 15 if required.  */
386
            if (start < 16)
387
              __gnu_Unwind_Save_VFP_D (&tmp);
388
 
389
            /* Save VFPv3 registers 16 .. 31 if required.  */
390
            if (num_vfpv3_regs)
391
              __gnu_Unwind_Save_VFP_D_16_to_31 (&tmp_16_to_31);
392
          }
393
 
394
        /* Work out how many registers below register 16 need popping.  */
395
        tmp_count = num_vfpv3_regs > 0 ? 16 - start : count;
396
 
397
        /* Copy registers below 16, if needed.
398
           The stack address is only guaranteed to be word aligned, so
399
           we can't use doubleword copies.  */
400
        sp = (_uw *) vrs->core.r[R_SP];
401
        if (tmp_count > 0)
402
          {
403
            tmp_count *= 2;
404
            dest = (_uw *) &tmp.d[start];
405
            while (tmp_count--)
406
              *(dest++) = *(sp++);
407
          }
408
 
409
        /* Copy VFPv3 registers numbered >= 16, if needed.  */
410
        if (num_vfpv3_regs > 0)
411
          {
412
            /* num_vfpv3_regs is needed below, so copy it.  */
413
            int tmp_count_2 = num_vfpv3_regs * 2;
414
            int vfpv3_start = start < 16 ? 16 : start;
415
 
416
            dest = (_uw *) &tmp_16_to_31.d[vfpv3_start - 16];
417
            while (tmp_count_2--)
418
              *(dest++) = *(sp++);
419
          }
420
 
421
        /* Skip the format word space if using FLDMX/FSTMX format.  */
422
        if (representation == _UVRSD_VFPX)
423
          sp++;
424
 
425
        /* Set the new stack pointer.  */
426
        vrs->core.r[R_SP] = (_uw) sp;
427
 
428
        /* Reload the registers.  */
429
        if (representation == _UVRSD_VFPX)
430
          __gnu_Unwind_Restore_VFP (&tmp);
431
        else
432
          {
433
            /* Restore registers 0 .. 15 if required.  */
434
            if (start < 16)
435
              __gnu_Unwind_Restore_VFP_D (&tmp);
436
 
437
            /* Restore VFPv3 registers 16 .. 31 if required.  */
438
            if (num_vfpv3_regs > 0)
439
              __gnu_Unwind_Restore_VFP_D_16_to_31 (&tmp_16_to_31);
440
          }
441
      }
442
      return _UVRSR_OK;
443
 
444
    case _UVRSC_FPA:
445
      return _UVRSR_NOT_IMPLEMENTED;
446
 
447
    case _UVRSC_WMMXD:
448
      {
449
        _uw start = discriminator >> 16;
450
        _uw count = discriminator & 0xffff;
451
        struct wmmxd_regs tmp;
452
        _uw *sp;
453
        _uw *dest;
454
 
455
        if ((representation != _UVRSD_UINT64) || start + count > 16)
456
          return _UVRSR_FAILED;
457
 
458
        if (vrs->demand_save_flags & DEMAND_SAVE_WMMXD)
459
          {
460
            /* Demand-save resisters for stage1.  */
461
            vrs->demand_save_flags &= ~DEMAND_SAVE_WMMXD;
462
            __gnu_Unwind_Save_WMMXD (&vrs->wmmxd);
463
          }
464
 
465
        /* Restore the registers from the stack.  Do this by saving the
466
           current WMMXD registers to a memory area, moving the in-memory
467
           values into that area, and restoring from the whole area.  */
468
        __gnu_Unwind_Save_WMMXD (&tmp);
469
 
470
        /* The stack address is only guaranteed to be word aligned, so
471
           we can't use doubleword copies.  */
472
        sp = (_uw *) vrs->core.r[R_SP];
473
        dest = (_uw *) &tmp.wd[start];
474
        count *= 2;
475
        while (count--)
476
          *(dest++) = *(sp++);
477
 
478
        /* Set the new stack pointer.  */
479
        vrs->core.r[R_SP] = (_uw) sp;
480
 
481
        /* Reload the registers.  */
482
        __gnu_Unwind_Restore_WMMXD (&tmp);
483
      }
484
      return _UVRSR_OK;
485
 
486
    case _UVRSC_WMMXC:
487
      {
488
        int i;
489
        struct wmmxc_regs tmp;
490
        _uw *sp;
491
 
492
        if ((representation != _UVRSD_UINT32) || discriminator > 16)
493
          return _UVRSR_FAILED;
494
 
495
        if (vrs->demand_save_flags & DEMAND_SAVE_WMMXC)
496
          {
497
            /* Demand-save resisters for stage1.  */
498
            vrs->demand_save_flags &= ~DEMAND_SAVE_WMMXC;
499
            __gnu_Unwind_Save_WMMXC (&vrs->wmmxc);
500
          }
501
 
502
        /* Restore the registers from the stack.  Do this by saving the
503
           current WMMXC registers to a memory area, moving the in-memory
504
           values into that area, and restoring from the whole area.  */
505
        __gnu_Unwind_Save_WMMXC (&tmp);
506
 
507
        sp = (_uw *) vrs->core.r[R_SP];
508
        for (i = 0; i < 4; i++)
509
          if (discriminator & (1 << i))
510
            tmp.wc[i] = *(sp++);
511
 
512
        /* Set the new stack pointer.  */
513
        vrs->core.r[R_SP] = (_uw) sp;
514
 
515
        /* Reload the registers.  */
516
        __gnu_Unwind_Restore_WMMXC (&tmp);
517
      }
518
      return _UVRSR_OK;
519
 
520
    default:
521
      return _UVRSR_FAILED;
522
    }
523
}
524
 
525
 
526
/* Core unwinding functions.  */
527
 
528
/* Calculate the address encoded by a 31-bit self-relative offset at address
529
   P.  */
530
static inline _uw
531
selfrel_offset31 (const _uw *p)
532
{
533
  _uw offset;
534
 
535
  offset = *p;
536
  /* Sign extend to 32 bits.  */
537
  if (offset & (1 << 30))
538
    offset |= 1u << 31;
539
  else
540
    offset &= ~(1u << 31);
541
 
542
  return offset + (_uw) p;
543
}
544
 
545
 
546
/* Perform a binary search for RETURN_ADDRESS in TABLE.  The table contains
547
   NREC entries.  */
548
 
549
static const __EIT_entry *
550
search_EIT_table (const __EIT_entry * table, int nrec, _uw return_address)
551
{
552
  _uw next_fn;
553
  _uw this_fn;
554
  int n, left, right;
555
 
556
  if (nrec == 0)
557
    return (__EIT_entry *) 0;
558
 
559
  left = 0;
560
  right = nrec - 1;
561
 
562
  while (1)
563
    {
564
      n = (left + right) / 2;
565
      this_fn = selfrel_offset31 (&table[n].fnoffset);
566
      if (n != nrec - 1)
567
        next_fn = selfrel_offset31 (&table[n + 1].fnoffset) - 1;
568
      else
569
        next_fn = (_uw)0 - 1;
570
 
571
      if (return_address < this_fn)
572
        {
573
          if (n == left)
574
            return (__EIT_entry *) 0;
575
          right = n - 1;
576
        }
577
      else if (return_address <= next_fn)
578
        return &table[n];
579
      else
580
        left = n + 1;
581
    }
582
}
583
 
584
/* Find the exception index table eintry for the given address.
585
   Fill in the relevant fields of the UCB.
586
   Returns _URC_FAILURE if an error occurred, _URC_OK on success.  */
587
 
588
static _Unwind_Reason_Code
589
get_eit_entry (_Unwind_Control_Block *ucbp, _uw return_address)
590
{
591
  const __EIT_entry * eitp;
592
  int nrec;
593
 
594
  /* The return address is the address of the instruction following the
595
     call instruction (plus one in thumb mode).  If this was the last
596
     instruction in the function the address will lie in the following
597
     function.  Subtract 2 from the address so that it points within the call
598
     instruction itself.  */
599
  return_address -= 2;
600
 
601
  if (__gnu_Unwind_Find_exidx)
602
    {
603
      eitp = (const __EIT_entry *) __gnu_Unwind_Find_exidx (return_address,
604
                                                            &nrec);
605
      if (!eitp)
606
        {
607
          UCB_PR_ADDR (ucbp) = 0;
608
          return _URC_FAILURE;
609
        }
610
    }
611
  else
612
    {
613
      eitp = &__exidx_start;
614
      nrec = &__exidx_end - &__exidx_start;
615
    }
616
 
617
  eitp = search_EIT_table (eitp, nrec, return_address);
618
 
619
  if (!eitp)
620
    {
621
      UCB_PR_ADDR (ucbp) = 0;
622
      return _URC_FAILURE;
623
    }
624
  ucbp->pr_cache.fnstart = selfrel_offset31 (&eitp->fnoffset);
625
 
626
  /* Can this frame be unwound at all?  */
627
  if (eitp->content == EXIDX_CANTUNWIND)
628
    {
629
      UCB_PR_ADDR (ucbp) = 0;
630
      return _URC_END_OF_STACK;
631
    }
632
 
633
  /* Obtain the address of the "real" __EHT_Header word.  */
634
 
635
  if (eitp->content & uint32_highbit)
636
    {
637
      /* It is immediate data.  */
638
      ucbp->pr_cache.ehtp = (_Unwind_EHT_Header *)&eitp->content;
639
      ucbp->pr_cache.additional = 1;
640
    }
641
  else
642
    {
643
      /* The low 31 bits of the content field are a self-relative
644
         offset to an _Unwind_EHT_Entry structure.  */
645
      ucbp->pr_cache.ehtp =
646
        (_Unwind_EHT_Header *) selfrel_offset31 (&eitp->content);
647
      ucbp->pr_cache.additional = 0;
648
    }
649
 
650
  /* Discover the personality routine address.  */
651
  if (*ucbp->pr_cache.ehtp & (1u << 31))
652
    {
653
      /* One of the predefined standard routines.  */
654
      _uw idx = (*(_uw *) ucbp->pr_cache.ehtp >> 24) & 0xf;
655
      if (idx == 0)
656
        UCB_PR_ADDR (ucbp) = (_uw) &__aeabi_unwind_cpp_pr0;
657
      else if (idx == 1)
658
        UCB_PR_ADDR (ucbp) = (_uw) &__aeabi_unwind_cpp_pr1;
659
      else if (idx == 2)
660
        UCB_PR_ADDR (ucbp) = (_uw) &__aeabi_unwind_cpp_pr2;
661
      else
662
        { /* Failed */
663
          UCB_PR_ADDR (ucbp) = 0;
664
          return _URC_FAILURE;
665
        }
666
    }
667
  else
668
    {
669
      /* Execute region offset to PR */
670
      UCB_PR_ADDR (ucbp) = selfrel_offset31 (ucbp->pr_cache.ehtp);
671
    }
672
  return _URC_OK;
673
}
674
 
675
 
676
/* Perform phase2 unwinding.  VRS is the initial virtual register state.  */
677
 
678
static void __attribute__((noreturn))
679
unwind_phase2 (_Unwind_Control_Block * ucbp, phase2_vrs * vrs)
680
{
681
  _Unwind_Reason_Code pr_result;
682
 
683
  do
684
    {
685
      /* Find the entry for this routine.  */
686
      if (get_eit_entry (ucbp, vrs->core.r[R_PC]) != _URC_OK)
687
        abort ();
688
 
689
      UCB_SAVED_CALLSITE_ADDR (ucbp) = vrs->core.r[R_PC];
690
 
691
      /* Call the pr to decide what to do.  */
692
      pr_result = ((personality_routine) UCB_PR_ADDR (ucbp))
693
        (_US_UNWIND_FRAME_STARTING, ucbp, (_Unwind_Context *) vrs);
694
    }
695
  while (pr_result == _URC_CONTINUE_UNWIND);
696
 
697
  if (pr_result != _URC_INSTALL_CONTEXT)
698
    abort();
699
 
700
  restore_core_regs (&vrs->core);
701
}
702
 
703
/* Perform phase2 forced unwinding.  */
704
 
705
static _Unwind_Reason_Code
706
unwind_phase2_forced (_Unwind_Control_Block *ucbp, phase2_vrs *entry_vrs,
707
                      int resuming)
708
{
709
  _Unwind_Stop_Fn stop_fn = (_Unwind_Stop_Fn) UCB_FORCED_STOP_FN (ucbp);
710
  void *stop_arg = (void *)UCB_FORCED_STOP_ARG (ucbp);
711
  _Unwind_Reason_Code pr_result = 0;
712
  /* We use phase1_vrs here even though we do not demand save, for the
713
     prev_sp field.  */
714
  phase1_vrs saved_vrs, next_vrs;
715
 
716
  /* Save the core registers.  */
717
  saved_vrs.core = entry_vrs->core;
718
  /* We don't need to demand-save the non-core registers, because we
719
     unwind in a single pass.  */
720
  saved_vrs.demand_save_flags = 0;
721
 
722
  /* Unwind until we reach a propagation barrier.  */
723
  do
724
    {
725
      _Unwind_State action;
726
      _Unwind_Reason_Code entry_code;
727
      _Unwind_Reason_Code stop_code;
728
 
729
      /* Find the entry for this routine.  */
730
      entry_code = get_eit_entry (ucbp, saved_vrs.core.r[R_PC]);
731
 
732
      if (resuming)
733
        {
734
          action = _US_UNWIND_FRAME_RESUME | _US_FORCE_UNWIND;
735
          resuming = 0;
736
        }
737
      else
738
        action = _US_UNWIND_FRAME_STARTING | _US_FORCE_UNWIND;
739
 
740
      if (entry_code == _URC_OK)
741
        {
742
          UCB_SAVED_CALLSITE_ADDR (ucbp) = saved_vrs.core.r[R_PC];
743
 
744
          next_vrs = saved_vrs;
745
 
746
          /* Call the pr to decide what to do.  */
747
          pr_result = ((personality_routine) UCB_PR_ADDR (ucbp))
748
            (action, ucbp, (void *) &next_vrs);
749
 
750
          saved_vrs.prev_sp = next_vrs.core.r[R_SP];
751
        }
752
      else
753
        {
754
          /* Treat any failure as the end of unwinding, to cope more
755
             gracefully with missing EH information.  Mixed EH and
756
             non-EH within one object will usually result in failure,
757
             because the .ARM.exidx tables do not indicate the end
758
             of the code to which they apply; but mixed EH and non-EH
759
             shared objects should return an unwind failure at the
760
             entry of a non-EH shared object.  */
761
          action |= _US_END_OF_STACK;
762
 
763
          saved_vrs.prev_sp = saved_vrs.core.r[R_SP];
764
        }
765
 
766
      stop_code = stop_fn (1, action, ucbp->exception_class, ucbp,
767
                           (void *)&saved_vrs, stop_arg);
768
      if (stop_code != _URC_NO_REASON)
769
        return _URC_FAILURE;
770
 
771
      if (entry_code != _URC_OK)
772
        return entry_code;
773
 
774
      saved_vrs = next_vrs;
775
    }
776
  while (pr_result == _URC_CONTINUE_UNWIND);
777
 
778
  if (pr_result != _URC_INSTALL_CONTEXT)
779
    {
780
      /* Some sort of failure has occurred in the pr and probably the
781
         pr returned _URC_FAILURE.  */
782
      return _URC_FAILURE;
783
    }
784
 
785
  restore_core_regs (&saved_vrs.core);
786
}
787
 
788
/* This is a very limited implementation of _Unwind_GetCFA.  It returns
789
   the stack pointer as it is about to be unwound, and is only valid
790
   while calling the stop function during forced unwinding.  If the
791
   current personality routine result is going to run a cleanup, this
792
   will not be the CFA; but when the frame is really unwound, it will
793
   be.  */
794
 
795
_Unwind_Word
796
_Unwind_GetCFA (_Unwind_Context *context)
797
{
798
  return ((phase1_vrs *) context)->prev_sp;
799
}
800
 
801
/* Perform phase1 unwinding.  UCBP is the exception being thrown, and
802
   entry_VRS is the register state on entry to _Unwind_RaiseException.  */
803
 
804
_Unwind_Reason_Code
805
__gnu_Unwind_RaiseException (_Unwind_Control_Block *, phase2_vrs *);
806
 
807
_Unwind_Reason_Code
808
__gnu_Unwind_RaiseException (_Unwind_Control_Block * ucbp,
809
                             phase2_vrs * entry_vrs)
810
{
811
  phase1_vrs saved_vrs;
812
  _Unwind_Reason_Code pr_result;
813
 
814
  /* Set the pc to the call site.  */
815
  entry_vrs->core.r[R_PC] = entry_vrs->core.r[R_LR];
816
 
817
  /* Save the core registers.  */
818
  saved_vrs.core = entry_vrs->core;
819
  /* Set demand-save flags.  */
820
  saved_vrs.demand_save_flags = ~(_uw) 0;
821
 
822
  /* Unwind until we reach a propagation barrier.  */
823
  do
824
    {
825
      /* Find the entry for this routine.  */
826
      if (get_eit_entry (ucbp, saved_vrs.core.r[R_PC]) != _URC_OK)
827
        return _URC_FAILURE;
828
 
829
      /* Call the pr to decide what to do.  */
830
      pr_result = ((personality_routine) UCB_PR_ADDR (ucbp))
831
        (_US_VIRTUAL_UNWIND_FRAME, ucbp, (void *) &saved_vrs);
832
    }
833
  while (pr_result == _URC_CONTINUE_UNWIND);
834
 
835
  /* We've unwound as far as we want to go, so restore the original
836
     register state.  */
837
  restore_non_core_regs (&saved_vrs);
838
  if (pr_result != _URC_HANDLER_FOUND)
839
    {
840
      /* Some sort of failure has occurred in the pr and probably the
841
         pr returned _URC_FAILURE.  */
842
      return _URC_FAILURE;
843
    }
844
 
845
  unwind_phase2 (ucbp, entry_vrs);
846
}
847
 
848
/* Resume unwinding after a cleanup has been run.  UCBP is the exception
849
   being thrown and ENTRY_VRS is the register state on entry to
850
   _Unwind_Resume.  */
851
_Unwind_Reason_Code
852
__gnu_Unwind_ForcedUnwind (_Unwind_Control_Block *,
853
                           _Unwind_Stop_Fn, void *, phase2_vrs *);
854
 
855
_Unwind_Reason_Code
856
__gnu_Unwind_ForcedUnwind (_Unwind_Control_Block *ucbp,
857
                           _Unwind_Stop_Fn stop_fn, void *stop_arg,
858
                           phase2_vrs *entry_vrs)
859
{
860
  UCB_FORCED_STOP_FN (ucbp) = (_uw) stop_fn;
861
  UCB_FORCED_STOP_ARG (ucbp) = (_uw) stop_arg;
862
 
863
  /* Set the pc to the call site.  */
864
  entry_vrs->core.r[R_PC] = entry_vrs->core.r[R_LR];
865
 
866
  return unwind_phase2_forced (ucbp, entry_vrs, 0);
867
}
868
 
869
_Unwind_Reason_Code
870
__gnu_Unwind_Resume (_Unwind_Control_Block *, phase2_vrs *);
871
 
872
_Unwind_Reason_Code
873
__gnu_Unwind_Resume (_Unwind_Control_Block * ucbp, phase2_vrs * entry_vrs)
874
{
875
  _Unwind_Reason_Code pr_result;
876
 
877
  /* Recover the saved address.  */
878
  entry_vrs->core.r[R_PC] = UCB_SAVED_CALLSITE_ADDR (ucbp);
879
 
880
  if (UCB_FORCED_STOP_FN (ucbp))
881
    {
882
      unwind_phase2_forced (ucbp, entry_vrs, 1);
883
 
884
      /* We can't return failure at this point.  */
885
      abort ();
886
    }
887
 
888
  /* Call the cached PR.  */
889
  pr_result = ((personality_routine) UCB_PR_ADDR (ucbp))
890
        (_US_UNWIND_FRAME_RESUME, ucbp, (_Unwind_Context *) entry_vrs);
891
 
892
  switch (pr_result)
893
    {
894
    case _URC_INSTALL_CONTEXT:
895
      /* Upload the registers to enter the landing pad.  */
896
      restore_core_regs (&entry_vrs->core);
897
 
898
    case _URC_CONTINUE_UNWIND:
899
      /* Continue unwinding the next frame.  */
900
      unwind_phase2 (ucbp, entry_vrs);
901
 
902
    default:
903
      abort ();
904
    }
905
}
906
 
907
_Unwind_Reason_Code
908
__gnu_Unwind_Resume_or_Rethrow (_Unwind_Control_Block *, phase2_vrs *);
909
 
910
_Unwind_Reason_Code
911
__gnu_Unwind_Resume_or_Rethrow (_Unwind_Control_Block * ucbp,
912
                                phase2_vrs * entry_vrs)
913
{
914
  if (!UCB_FORCED_STOP_FN (ucbp))
915
    return __gnu_Unwind_RaiseException (ucbp, entry_vrs);
916
 
917
  /* Set the pc to the call site.  */
918
  entry_vrs->core.r[R_PC] = entry_vrs->core.r[R_LR];
919
  /* Continue unwinding the next frame.  */
920
  return unwind_phase2_forced (ucbp, entry_vrs, 0);
921
}
922
 
923
/* Clean up an exception object when unwinding is complete.  */
924
void
925
_Unwind_Complete (_Unwind_Control_Block * ucbp __attribute__((unused)))
926
{
927
}
928
 
929
 
930
/* Get the _Unwind_Control_Block from an _Unwind_Context.  */
931
 
932
static inline _Unwind_Control_Block *
933
unwind_UCB_from_context (_Unwind_Context * context)
934
{
935
  return (_Unwind_Control_Block *) _Unwind_GetGR (context, R_IP);
936
}
937
 
938
 
939
/* Free an exception.  */
940
 
941
void
942
_Unwind_DeleteException (_Unwind_Exception * exc)
943
{
944
  if (exc->exception_cleanup)
945
    (*exc->exception_cleanup) (_URC_FOREIGN_EXCEPTION_CAUGHT, exc);
946
}
947
 
948
 
949
/* Perform stack backtrace through unwind data.  */
950
_Unwind_Reason_Code
951
__gnu_Unwind_Backtrace(_Unwind_Trace_Fn trace, void * trace_argument,
952
                       phase2_vrs * entry_vrs);
953
_Unwind_Reason_Code
954
__gnu_Unwind_Backtrace(_Unwind_Trace_Fn trace, void * trace_argument,
955
                       phase2_vrs * entry_vrs)
956
{
957
  phase1_vrs saved_vrs;
958
  _Unwind_Reason_Code code;
959
 
960
  _Unwind_Control_Block ucb;
961
  _Unwind_Control_Block *ucbp = &ucb;
962
 
963
  /* Set the pc to the call site.  */
964
  entry_vrs->core.r[R_PC] = entry_vrs->core.r[R_LR];
965
 
966
  /* Save the core registers.  */
967
  saved_vrs.core = entry_vrs->core;
968
  /* Set demand-save flags.  */
969
  saved_vrs.demand_save_flags = ~(_uw) 0;
970
 
971
  do
972
    {
973
      /* Find the entry for this routine.  */
974
      if (get_eit_entry (ucbp, saved_vrs.core.r[R_PC]) != _URC_OK)
975
        {
976
          code = _URC_FAILURE;
977
          break;
978
        }
979
 
980
      /* The dwarf unwinder assumes the context structure holds things
981
         like the function and LSDA pointers.  The ARM implementation
982
         caches these in the exception header (UCB).  To avoid
983
         rewriting everything we make the virtual IP register point at
984
         the UCB.  */
985
      _Unwind_SetGR((_Unwind_Context *)&saved_vrs, 12, (_Unwind_Ptr) ucbp);
986
 
987
      /* Call trace function.  */
988
      if ((*trace) ((_Unwind_Context *) &saved_vrs, trace_argument)
989
          != _URC_NO_REASON)
990
        {
991
          code = _URC_FAILURE;
992
          break;
993
        }
994
 
995
      /* Call the pr to decide what to do.  */
996
      code = ((personality_routine) UCB_PR_ADDR (ucbp))
997
        (_US_VIRTUAL_UNWIND_FRAME | _US_FORCE_UNWIND,
998
         ucbp, (void *) &saved_vrs);
999
    }
1000
  while (code != _URC_END_OF_STACK
1001
         && code != _URC_FAILURE);
1002
 
1003
  restore_non_core_regs (&saved_vrs);
1004
  return code;
1005
}
1006
 
1007
 
1008
/* Common implementation for ARM ABI defined personality routines.
1009
   ID is the index of the personality routine, other arguments are as defined
1010
   by __aeabi_unwind_cpp_pr{0,1,2}.  */
1011
 
1012
static _Unwind_Reason_Code
1013
__gnu_unwind_pr_common (_Unwind_State state,
1014
                        _Unwind_Control_Block *ucbp,
1015
                        _Unwind_Context *context,
1016
                        int id)
1017
{
1018
  __gnu_unwind_state uws;
1019
  _uw *data;
1020
  _uw offset;
1021
  _uw len;
1022
  _uw rtti_count;
1023
  int phase2_call_unexpected_after_unwind = 0;
1024
  int in_range = 0;
1025
  int forced_unwind = state & _US_FORCE_UNWIND;
1026
 
1027
  state &= _US_ACTION_MASK;
1028
 
1029
  data = (_uw *) ucbp->pr_cache.ehtp;
1030
  uws.data = *(data++);
1031
  uws.next = data;
1032
  if (id == 0)
1033
    {
1034
      uws.data <<= 8;
1035
      uws.words_left = 0;
1036
      uws.bytes_left = 3;
1037
    }
1038
  else
1039
    {
1040
      uws.words_left = (uws.data >> 16) & 0xff;
1041
      uws.data <<= 16;
1042
      uws.bytes_left = 2;
1043
      data += uws.words_left;
1044
    }
1045
 
1046
  /* Restore the saved pointer.  */
1047
  if (state == _US_UNWIND_FRAME_RESUME)
1048
    data = (_uw *) ucbp->cleanup_cache.bitpattern[0];
1049
 
1050
  if ((ucbp->pr_cache.additional & 1) == 0)
1051
    {
1052
      /* Process descriptors.  */
1053
      while (*data)
1054
        {
1055
          _uw addr;
1056
          _uw fnstart;
1057
 
1058
          if (id == 2)
1059
            {
1060
              len = ((EHT32 *) data)->length;
1061
              offset = ((EHT32 *) data)->offset;
1062
              data += 2;
1063
            }
1064
          else
1065
            {
1066
              len = ((EHT16 *) data)->length;
1067
              offset = ((EHT16 *) data)->offset;
1068
              data++;
1069
            }
1070
 
1071
          fnstart = ucbp->pr_cache.fnstart + (offset & ~1);
1072
          addr = _Unwind_GetGR (context, R_PC);
1073
          in_range = (fnstart <= addr && addr < fnstart + (len & ~1));
1074
 
1075
          switch (((offset & 1) << 1) | (len & 1))
1076
            {
1077
            case 0:
1078
              /* Cleanup.  */
1079
              if (state != _US_VIRTUAL_UNWIND_FRAME
1080
                  && in_range)
1081
                {
1082
                  /* Cleanup in range, and we are running cleanups.  */
1083
                  _uw lp;
1084
 
1085
                  /* Landing pad address is 31-bit pc-relative offset.  */
1086
                  lp = selfrel_offset31 (data);
1087
                  data++;
1088
                  /* Save the exception data pointer.  */
1089
                  ucbp->cleanup_cache.bitpattern[0] = (_uw) data;
1090
                  if (!__cxa_begin_cleanup (ucbp))
1091
                    return _URC_FAILURE;
1092
                  /* Setup the VRS to enter the landing pad.  */
1093
                  _Unwind_SetGR (context, R_PC, lp);
1094
                  return _URC_INSTALL_CONTEXT;
1095
                }
1096
              /* Cleanup not in range, or we are in stage 1.  */
1097
              data++;
1098
              break;
1099
 
1100
            case 1:
1101
              /* Catch handler.  */
1102
              if (state == _US_VIRTUAL_UNWIND_FRAME)
1103
                {
1104
                  if (in_range)
1105
                    {
1106
                      /* Check for a barrier.  */
1107
                      _uw rtti;
1108
                      bool is_reference = (data[0] & uint32_highbit) != 0;
1109
                      void *matched;
1110
 
1111
                      /* Check for no-throw areas.  */
1112
                      if (data[1] == (_uw) -2)
1113
                        return _URC_FAILURE;
1114
 
1115
                      /* The thrown object immediately follows the ECB.  */
1116
                      matched = (void *)(ucbp + 1);
1117
                      if (data[1] != (_uw) -1)
1118
                        {
1119
                          /* Match a catch specification.  */
1120
                          rtti = _Unwind_decode_target2 ((_uw) &data[1]);
1121
                          if (!__cxa_type_match (ucbp, (type_info *) rtti,
1122
                                                 is_reference,
1123
                                                 &matched))
1124
                            matched = (void *)0;
1125
                        }
1126
 
1127
                      if (matched)
1128
                        {
1129
                          ucbp->barrier_cache.sp =
1130
                            _Unwind_GetGR (context, R_SP);
1131
                          ucbp->barrier_cache.bitpattern[0] = (_uw) matched;
1132
                          ucbp->barrier_cache.bitpattern[1] = (_uw) data;
1133
                          return _URC_HANDLER_FOUND;
1134
                        }
1135
                    }
1136
                  /* Handler out of range, or not matched.  */
1137
                }
1138
              else if (ucbp->barrier_cache.sp == _Unwind_GetGR (context, R_SP)
1139
                       && ucbp->barrier_cache.bitpattern[1] == (_uw) data)
1140
                {
1141
                  /* Matched a previous propagation barrier.  */
1142
                  _uw lp;
1143
 
1144
                  /* Setup for entry to the handler.  */
1145
                  lp = selfrel_offset31 (data);
1146
                  _Unwind_SetGR (context, R_PC, lp);
1147
                  _Unwind_SetGR (context, 0, (_uw) ucbp);
1148
                  return _URC_INSTALL_CONTEXT;
1149
                }
1150
              /* Catch handler not matched.  Advance to the next descriptor.  */
1151
              data += 2;
1152
              break;
1153
 
1154
            case 2:
1155
              rtti_count = data[0] & 0x7fffffff;
1156
              /* Exception specification.  */
1157
              if (state == _US_VIRTUAL_UNWIND_FRAME)
1158
                {
1159
                  if (in_range && (!forced_unwind || !rtti_count))
1160
                    {
1161
                      /* Match against the exception specification.  */
1162
                      _uw i;
1163
                      _uw rtti;
1164
                      void *matched;
1165
 
1166
                      for (i = 0; i < rtti_count; i++)
1167
                        {
1168
                          matched = (void *)(ucbp + 1);
1169
                          rtti = _Unwind_decode_target2 ((_uw) &data[i + 1]);
1170
                          if (__cxa_type_match (ucbp, (type_info *) rtti, 0,
1171
                                                &matched))
1172
                            break;
1173
                        }
1174
 
1175
                      if (i == rtti_count)
1176
                        {
1177
                          /* Exception does not match the spec.  */
1178
                          ucbp->barrier_cache.sp =
1179
                            _Unwind_GetGR (context, R_SP);
1180
                          ucbp->barrier_cache.bitpattern[0] = (_uw) matched;
1181
                          ucbp->barrier_cache.bitpattern[1] = (_uw) data;
1182
                          return _URC_HANDLER_FOUND;
1183
                        }
1184
                    }
1185
                  /* Handler out of range, or exception is permitted.  */
1186
                }
1187
              else if (ucbp->barrier_cache.sp == _Unwind_GetGR (context, R_SP)
1188
                       && ucbp->barrier_cache.bitpattern[1] == (_uw) data)
1189
                {
1190
                  /* Matched a previous propagation barrier.  */
1191
                  _uw lp;
1192
                  /* Record the RTTI list for __cxa_call_unexpected.  */
1193
                  ucbp->barrier_cache.bitpattern[1] = rtti_count;
1194
                  ucbp->barrier_cache.bitpattern[2] = 0;
1195
                  ucbp->barrier_cache.bitpattern[3] = 4;
1196
                  ucbp->barrier_cache.bitpattern[4] = (_uw) &data[1];
1197
 
1198
                  if (data[0] & uint32_highbit)
1199
                    phase2_call_unexpected_after_unwind = 1;
1200
                  else
1201
                    {
1202
                      data += rtti_count + 1;
1203
                      /* Setup for entry to the handler.  */
1204
                      lp = selfrel_offset31 (data);
1205
                      data++;
1206
                      _Unwind_SetGR (context, R_PC, lp);
1207
                      _Unwind_SetGR (context, 0, (_uw) ucbp);
1208
                      return _URC_INSTALL_CONTEXT;
1209
                    }
1210
                }
1211
              if (data[0] & uint32_highbit)
1212
                data++;
1213
              data += rtti_count + 1;
1214
              break;
1215
 
1216
            default:
1217
              /* Should never happen.  */
1218
              return _URC_FAILURE;
1219
            }
1220
          /* Finished processing this descriptor.  */
1221
        }
1222
    }
1223
 
1224
  if (__gnu_unwind_execute (context, &uws) != _URC_OK)
1225
    return _URC_FAILURE;
1226
 
1227
  if (phase2_call_unexpected_after_unwind)
1228
    {
1229
      /* Enter __cxa_unexpected as if called from the call site.  */
1230
      _Unwind_SetGR (context, R_LR, _Unwind_GetGR (context, R_PC));
1231
      _Unwind_SetGR (context, R_PC, (_uw) &__cxa_call_unexpected);
1232
      return _URC_INSTALL_CONTEXT;
1233
    }
1234
 
1235
  return _URC_CONTINUE_UNWIND;
1236
}
1237
 
1238
 
1239
/* ABI defined personality routine entry points.  */
1240
 
1241
_Unwind_Reason_Code
1242
__aeabi_unwind_cpp_pr0 (_Unwind_State state,
1243
                        _Unwind_Control_Block *ucbp,
1244
                        _Unwind_Context *context)
1245
{
1246
  return __gnu_unwind_pr_common (state, ucbp, context, 0);
1247
}
1248
 
1249
_Unwind_Reason_Code
1250
__aeabi_unwind_cpp_pr1 (_Unwind_State state,
1251
                        _Unwind_Control_Block *ucbp,
1252
                        _Unwind_Context *context)
1253
{
1254
  return __gnu_unwind_pr_common (state, ucbp, context, 1);
1255
}
1256
 
1257
_Unwind_Reason_Code
1258
__aeabi_unwind_cpp_pr2 (_Unwind_State state,
1259
                        _Unwind_Control_Block *ucbp,
1260
                        _Unwind_Context *context)
1261
{
1262
  return __gnu_unwind_pr_common (state, ucbp, context, 2);
1263
}

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