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1 //===------------------------- UnwindCursor.hpp ---------------------------===//
2 //
3 //                     The LLVM Compiler Infrastructure
4 //
5 // This file is dual licensed under the MIT and the University of Illinois Open
6 // Source Licenses. See LICENSE.TXT for details.
7 //
8 //
9 // C++ interface to lower levels of libuwind
10 //===----------------------------------------------------------------------===//
11 
12 #ifndef __UNWINDCURSOR_HPP__
13 #define __UNWINDCURSOR_HPP__
14 
15 #include <algorithm>
16 #include <stdint.h>
17 #include <stdio.h>
18 #include <stdlib.h>
19 #include <pthread.h>
20 #include <unwind.h>
21 
22 #if __APPLE__
23   #include <mach-o/dyld.h>
24 #endif
25 
26 #include "libunwind.h"
27 
28 #include "AddressSpace.hpp"
29 #include "Registers.hpp"
30 #include "DwarfInstructions.hpp"
31 #include "CompactUnwinder.hpp"
32 #include "config.h"
33 
34 namespace libunwind {
35 
36 #if _LIBUNWIND_SUPPORT_DWARF_UNWIND
37 /// Cache of recently found FDEs.
38 template <typename A>
39 class _LIBUNWIND_HIDDEN DwarfFDECache {
40   typedef typename A::pint_t pint_t;
41 public:
42   static pint_t findFDE(pint_t mh, pint_t pc);
43   static void add(pint_t mh, pint_t ip_start, pint_t ip_end, pint_t fde);
44   static void removeAllIn(pint_t mh);
45   static void iterateCacheEntries(void (*func)(unw_word_t ip_start,
46                                                unw_word_t ip_end,
47                                                unw_word_t fde, unw_word_t mh));
48 
49 private:
50 
51   struct entry {
52     pint_t mh;
53     pint_t ip_start;
54     pint_t ip_end;
55     pint_t fde;
56   };
57 
58   // These fields are all static to avoid needing an initializer.
59   // There is only one instance of this class per process.
60   static pthread_rwlock_t _lock;
61 #if __APPLE__
62   static void dyldUnloadHook(const struct mach_header *mh, intptr_t slide);
63   static bool _registeredForDyldUnloads;
64 #endif
65   // Can't use std::vector<> here because this code is below libc++.
66   static entry *_buffer;
67   static entry *_bufferUsed;
68   static entry *_bufferEnd;
69   static entry _initialBuffer[64];
70 };
71 
72 template <typename A>
73 typename DwarfFDECache<A>::entry *
74 DwarfFDECache<A>::_buffer = _initialBuffer;
75 
76 template <typename A>
77 typename DwarfFDECache<A>::entry *
78 DwarfFDECache<A>::_bufferUsed = _initialBuffer;
79 
80 template <typename A>
81 typename DwarfFDECache<A>::entry *
82 DwarfFDECache<A>::_bufferEnd = &_initialBuffer[64];
83 
84 template <typename A>
85 typename DwarfFDECache<A>::entry DwarfFDECache<A>::_initialBuffer[64];
86 
87 template <typename A>
88 pthread_rwlock_t DwarfFDECache<A>::_lock = PTHREAD_RWLOCK_INITIALIZER;
89 
90 #if __APPLE__
91 template <typename A>
92 bool DwarfFDECache<A>::_registeredForDyldUnloads = false;
93 #endif
94 
95 template <typename A>
findFDE(pint_t mh,pint_t pc)96 typename A::pint_t DwarfFDECache<A>::findFDE(pint_t mh, pint_t pc) {
97   pint_t result = 0;
98   _LIBUNWIND_LOG_NON_ZERO(::pthread_rwlock_rdlock(&_lock));
99   for (entry *p = _buffer; p < _bufferUsed; ++p) {
100     if ((mh == p->mh) || (mh == 0)) {
101       if ((p->ip_start <= pc) && (pc < p->ip_end)) {
102         result = p->fde;
103         break;
104       }
105     }
106   }
107   _LIBUNWIND_LOG_NON_ZERO(::pthread_rwlock_unlock(&_lock));
108   return result;
109 }
110 
111 template <typename A>
add(pint_t mh,pint_t ip_start,pint_t ip_end,pint_t fde)112 void DwarfFDECache<A>::add(pint_t mh, pint_t ip_start, pint_t ip_end,
113                            pint_t fde) {
114   _LIBUNWIND_LOG_NON_ZERO(::pthread_rwlock_wrlock(&_lock));
115   if (_bufferUsed >= _bufferEnd) {
116     size_t oldSize = (size_t)(_bufferEnd - _buffer);
117     size_t newSize = oldSize * 4;
118     // Can't use operator new (we are below it).
119     entry *newBuffer = (entry *)malloc(newSize * sizeof(entry));
120     memcpy(newBuffer, _buffer, oldSize * sizeof(entry));
121     if (_buffer != _initialBuffer)
122       free(_buffer);
123     _buffer = newBuffer;
124     _bufferUsed = &newBuffer[oldSize];
125     _bufferEnd = &newBuffer[newSize];
126   }
127   _bufferUsed->mh = mh;
128   _bufferUsed->ip_start = ip_start;
129   _bufferUsed->ip_end = ip_end;
130   _bufferUsed->fde = fde;
131   ++_bufferUsed;
132 #if __APPLE__
133   if (!_registeredForDyldUnloads) {
134     _dyld_register_func_for_remove_image(&dyldUnloadHook);
135     _registeredForDyldUnloads = true;
136   }
137 #endif
138   _LIBUNWIND_LOG_NON_ZERO(::pthread_rwlock_unlock(&_lock));
139 }
140 
141 template <typename A>
removeAllIn(pint_t mh)142 void DwarfFDECache<A>::removeAllIn(pint_t mh) {
143   _LIBUNWIND_LOG_NON_ZERO(::pthread_rwlock_wrlock(&_lock));
144   entry *d = _buffer;
145   for (const entry *s = _buffer; s < _bufferUsed; ++s) {
146     if (s->mh != mh) {
147       if (d != s)
148         *d = *s;
149       ++d;
150     }
151   }
152   _bufferUsed = d;
153   _LIBUNWIND_LOG_NON_ZERO(::pthread_rwlock_unlock(&_lock));
154 }
155 
156 #if __APPLE__
157 template <typename A>
dyldUnloadHook(const struct mach_header * mh,intptr_t)158 void DwarfFDECache<A>::dyldUnloadHook(const struct mach_header *mh, intptr_t ) {
159   removeAllIn((pint_t) mh);
160 }
161 #endif
162 
163 template <typename A>
iterateCacheEntries(void (* func)(unw_word_t ip_start,unw_word_t ip_end,unw_word_t fde,unw_word_t mh))164 void DwarfFDECache<A>::iterateCacheEntries(void (*func)(
165     unw_word_t ip_start, unw_word_t ip_end, unw_word_t fde, unw_word_t mh)) {
166   _LIBUNWIND_LOG_NON_ZERO(::pthread_rwlock_wrlock(&_lock));
167   for (entry *p = _buffer; p < _bufferUsed; ++p) {
168     (*func)(p->ip_start, p->ip_end, p->fde, p->mh);
169   }
170   _LIBUNWIND_LOG_NON_ZERO(::pthread_rwlock_unlock(&_lock));
171 }
172 #endif // _LIBUNWIND_SUPPORT_DWARF_UNWIND
173 
174 
175 #define arrayoffsetof(type, index, field) ((size_t)(&((type *)0)[index].field))
176 
177 #if _LIBUNWIND_SUPPORT_COMPACT_UNWIND
178 template <typename A> class UnwindSectionHeader {
179 public:
UnwindSectionHeader(A & addressSpace,typename A::pint_t addr)180   UnwindSectionHeader(A &addressSpace, typename A::pint_t addr)
181       : _addressSpace(addressSpace), _addr(addr) {}
182 
version() const183   uint32_t version() const {
184     return _addressSpace.get32(_addr +
185                                offsetof(unwind_info_section_header, version));
186   }
commonEncodingsArraySectionOffset() const187   uint32_t commonEncodingsArraySectionOffset() const {
188     return _addressSpace.get32(_addr +
189                                offsetof(unwind_info_section_header,
190                                         commonEncodingsArraySectionOffset));
191   }
commonEncodingsArrayCount() const192   uint32_t commonEncodingsArrayCount() const {
193     return _addressSpace.get32(_addr + offsetof(unwind_info_section_header,
194                                                 commonEncodingsArrayCount));
195   }
personalityArraySectionOffset() const196   uint32_t personalityArraySectionOffset() const {
197     return _addressSpace.get32(_addr + offsetof(unwind_info_section_header,
198                                                 personalityArraySectionOffset));
199   }
personalityArrayCount() const200   uint32_t personalityArrayCount() const {
201     return _addressSpace.get32(
202         _addr + offsetof(unwind_info_section_header, personalityArrayCount));
203   }
indexSectionOffset() const204   uint32_t indexSectionOffset() const {
205     return _addressSpace.get32(
206         _addr + offsetof(unwind_info_section_header, indexSectionOffset));
207   }
indexCount() const208   uint32_t indexCount() const {
209     return _addressSpace.get32(
210         _addr + offsetof(unwind_info_section_header, indexCount));
211   }
212 
213 private:
214   A                     &_addressSpace;
215   typename A::pint_t     _addr;
216 };
217 
218 template <typename A> class UnwindSectionIndexArray {
219 public:
UnwindSectionIndexArray(A & addressSpace,typename A::pint_t addr)220   UnwindSectionIndexArray(A &addressSpace, typename A::pint_t addr)
221       : _addressSpace(addressSpace), _addr(addr) {}
222 
functionOffset(uint32_t index) const223   uint32_t functionOffset(uint32_t index) const {
224     return _addressSpace.get32(
225         _addr + arrayoffsetof(unwind_info_section_header_index_entry, index,
226                               functionOffset));
227   }
secondLevelPagesSectionOffset(uint32_t index) const228   uint32_t secondLevelPagesSectionOffset(uint32_t index) const {
229     return _addressSpace.get32(
230         _addr + arrayoffsetof(unwind_info_section_header_index_entry, index,
231                               secondLevelPagesSectionOffset));
232   }
lsdaIndexArraySectionOffset(uint32_t index) const233   uint32_t lsdaIndexArraySectionOffset(uint32_t index) const {
234     return _addressSpace.get32(
235         _addr + arrayoffsetof(unwind_info_section_header_index_entry, index,
236                               lsdaIndexArraySectionOffset));
237   }
238 
239 private:
240   A                   &_addressSpace;
241   typename A::pint_t   _addr;
242 };
243 
244 template <typename A> class UnwindSectionRegularPageHeader {
245 public:
UnwindSectionRegularPageHeader(A & addressSpace,typename A::pint_t addr)246   UnwindSectionRegularPageHeader(A &addressSpace, typename A::pint_t addr)
247       : _addressSpace(addressSpace), _addr(addr) {}
248 
kind() const249   uint32_t kind() const {
250     return _addressSpace.get32(
251         _addr + offsetof(unwind_info_regular_second_level_page_header, kind));
252   }
entryPageOffset() const253   uint16_t entryPageOffset() const {
254     return _addressSpace.get16(
255         _addr + offsetof(unwind_info_regular_second_level_page_header,
256                          entryPageOffset));
257   }
entryCount() const258   uint16_t entryCount() const {
259     return _addressSpace.get16(
260         _addr +
261         offsetof(unwind_info_regular_second_level_page_header, entryCount));
262   }
263 
264 private:
265   A &_addressSpace;
266   typename A::pint_t _addr;
267 };
268 
269 template <typename A> class UnwindSectionRegularArray {
270 public:
UnwindSectionRegularArray(A & addressSpace,typename A::pint_t addr)271   UnwindSectionRegularArray(A &addressSpace, typename A::pint_t addr)
272       : _addressSpace(addressSpace), _addr(addr) {}
273 
functionOffset(uint32_t index) const274   uint32_t functionOffset(uint32_t index) const {
275     return _addressSpace.get32(
276         _addr + arrayoffsetof(unwind_info_regular_second_level_entry, index,
277                               functionOffset));
278   }
encoding(uint32_t index) const279   uint32_t encoding(uint32_t index) const {
280     return _addressSpace.get32(
281         _addr +
282         arrayoffsetof(unwind_info_regular_second_level_entry, index, encoding));
283   }
284 
285 private:
286   A &_addressSpace;
287   typename A::pint_t _addr;
288 };
289 
290 template <typename A> class UnwindSectionCompressedPageHeader {
291 public:
UnwindSectionCompressedPageHeader(A & addressSpace,typename A::pint_t addr)292   UnwindSectionCompressedPageHeader(A &addressSpace, typename A::pint_t addr)
293       : _addressSpace(addressSpace), _addr(addr) {}
294 
kind() const295   uint32_t kind() const {
296     return _addressSpace.get32(
297         _addr +
298         offsetof(unwind_info_compressed_second_level_page_header, kind));
299   }
entryPageOffset() const300   uint16_t entryPageOffset() const {
301     return _addressSpace.get16(
302         _addr + offsetof(unwind_info_compressed_second_level_page_header,
303                          entryPageOffset));
304   }
entryCount() const305   uint16_t entryCount() const {
306     return _addressSpace.get16(
307         _addr +
308         offsetof(unwind_info_compressed_second_level_page_header, entryCount));
309   }
encodingsPageOffset() const310   uint16_t encodingsPageOffset() const {
311     return _addressSpace.get16(
312         _addr + offsetof(unwind_info_compressed_second_level_page_header,
313                          encodingsPageOffset));
314   }
encodingsCount() const315   uint16_t encodingsCount() const {
316     return _addressSpace.get16(
317         _addr + offsetof(unwind_info_compressed_second_level_page_header,
318                          encodingsCount));
319   }
320 
321 private:
322   A &_addressSpace;
323   typename A::pint_t _addr;
324 };
325 
326 template <typename A> class UnwindSectionCompressedArray {
327 public:
UnwindSectionCompressedArray(A & addressSpace,typename A::pint_t addr)328   UnwindSectionCompressedArray(A &addressSpace, typename A::pint_t addr)
329       : _addressSpace(addressSpace), _addr(addr) {}
330 
functionOffset(uint32_t index) const331   uint32_t functionOffset(uint32_t index) const {
332     return UNWIND_INFO_COMPRESSED_ENTRY_FUNC_OFFSET(
333         _addressSpace.get32(_addr + index * sizeof(uint32_t)));
334   }
encodingIndex(uint32_t index) const335   uint16_t encodingIndex(uint32_t index) const {
336     return UNWIND_INFO_COMPRESSED_ENTRY_ENCODING_INDEX(
337         _addressSpace.get32(_addr + index * sizeof(uint32_t)));
338   }
339 
340 private:
341   A &_addressSpace;
342   typename A::pint_t _addr;
343 };
344 
345 template <typename A> class UnwindSectionLsdaArray {
346 public:
UnwindSectionLsdaArray(A & addressSpace,typename A::pint_t addr)347   UnwindSectionLsdaArray(A &addressSpace, typename A::pint_t addr)
348       : _addressSpace(addressSpace), _addr(addr) {}
349 
functionOffset(uint32_t index) const350   uint32_t functionOffset(uint32_t index) const {
351     return _addressSpace.get32(
352         _addr + arrayoffsetof(unwind_info_section_header_lsda_index_entry,
353                               index, functionOffset));
354   }
lsdaOffset(uint32_t index) const355   uint32_t lsdaOffset(uint32_t index) const {
356     return _addressSpace.get32(
357         _addr + arrayoffsetof(unwind_info_section_header_lsda_index_entry,
358                               index, lsdaOffset));
359   }
360 
361 private:
362   A                   &_addressSpace;
363   typename A::pint_t   _addr;
364 };
365 #endif // _LIBUNWIND_SUPPORT_COMPACT_UNWIND
366 
367 
368 class _LIBUNWIND_HIDDEN AbstractUnwindCursor {
369 public:
~AbstractUnwindCursor()370   virtual             ~AbstractUnwindCursor() {}
371   virtual bool        validReg(int) = 0;
372   virtual unw_word_t  getReg(int) = 0;
373   virtual void        setReg(int, unw_word_t) = 0;
374   virtual bool        validFloatReg(int) = 0;
375   virtual unw_fpreg_t getFloatReg(int) = 0;
376   virtual void        setFloatReg(int, unw_fpreg_t) = 0;
377   virtual int         step() = 0;
378   virtual void        getInfo(unw_proc_info_t *) = 0;
379   virtual void        jumpto() = 0;
380   virtual bool        isSignalFrame() = 0;
381   virtual bool        getFunctionName(char *bf, size_t ln, unw_word_t *off) = 0;
382   virtual void        setInfoBasedOnIPRegister(bool isReturnAddr = false) = 0;
383   virtual const char *getRegisterName(int num) = 0;
384 #if __arm__
385   virtual void        saveVFPAsX() = 0;
386 #endif
387 };
388 
389 
390 /// UnwindCursor contains all state (including all register values) during
391 /// an unwind.  This is normally stack allocated inside a unw_cursor_t.
392 template <typename A, typename R>
393 class UnwindCursor : public AbstractUnwindCursor{
394   typedef typename A::pint_t pint_t;
395 public:
396                       UnwindCursor(unw_context_t *context, A &as);
397                       UnwindCursor(A &as, void *threadArg);
~UnwindCursor()398   virtual             ~UnwindCursor() {}
399   virtual bool        validReg(int);
400   virtual unw_word_t  getReg(int);
401   virtual void        setReg(int, unw_word_t);
402   virtual bool        validFloatReg(int);
403   virtual unw_fpreg_t getFloatReg(int);
404   virtual void        setFloatReg(int, unw_fpreg_t);
405   virtual int         step();
406   virtual void        getInfo(unw_proc_info_t *);
407   virtual void        jumpto();
408   virtual bool        isSignalFrame();
409   virtual bool        getFunctionName(char *buf, size_t len, unw_word_t *off);
410   virtual void        setInfoBasedOnIPRegister(bool isReturnAddress = false);
411   virtual const char *getRegisterName(int num);
412 #if __arm__
413   virtual void        saveVFPAsX();
414 #endif
415 
operator delete(void *,size_t)416   void            operator delete(void *, size_t) {}
417 
418 private:
419 
420 #if LIBCXXABI_ARM_EHABI
421   bool getInfoFromEHABISection(pint_t pc, const UnwindInfoSections &sects);
422 #endif
423 
424 #if _LIBUNWIND_SUPPORT_DWARF_UNWIND
425   bool getInfoFromDwarfSection(pint_t pc, const UnwindInfoSections &sects,
426                                             uint32_t fdeSectionOffsetHint=0);
stepWithDwarfFDE()427   int stepWithDwarfFDE() {
428     return DwarfInstructions<A, R>::stepWithDwarf(_addressSpace,
429                                               (pint_t)this->getReg(UNW_REG_IP),
430                                               (pint_t)_info.unwind_info,
431                                               _registers);
432   }
433 #endif
434 
435 #if _LIBUNWIND_SUPPORT_COMPACT_UNWIND
436   bool getInfoFromCompactEncodingSection(pint_t pc,
437                                             const UnwindInfoSections &sects);
stepWithCompactEncoding()438   int stepWithCompactEncoding() {
439   #if _LIBUNWIND_SUPPORT_DWARF_UNWIND
440     if ( compactSaysUseDwarf() )
441       return stepWithDwarfFDE();
442   #endif
443     R dummy;
444     return stepWithCompactEncoding(dummy);
445   }
446 
stepWithCompactEncoding(Registers_x86_64 &)447   int stepWithCompactEncoding(Registers_x86_64 &) {
448     return CompactUnwinder_x86_64<A>::stepWithCompactEncoding(
449         _info.format, _info.start_ip, _addressSpace, _registers);
450   }
451 
stepWithCompactEncoding(Registers_x86 &)452   int stepWithCompactEncoding(Registers_x86 &) {
453     return CompactUnwinder_x86<A>::stepWithCompactEncoding(
454         _info.format, (uint32_t)_info.start_ip, _addressSpace, _registers);
455   }
456 
stepWithCompactEncoding(Registers_ppc &)457   int stepWithCompactEncoding(Registers_ppc &) {
458     return UNW_EINVAL;
459   }
460 
stepWithCompactEncoding(Registers_arm64 &)461   int stepWithCompactEncoding(Registers_arm64 &) {
462     return CompactUnwinder_arm64<A>::stepWithCompactEncoding(
463         _info.format, _info.start_ip, _addressSpace, _registers);
464   }
465 
compactSaysUseDwarf(uint32_t * offset=NULL) const466   bool compactSaysUseDwarf(uint32_t *offset=NULL) const {
467     R dummy;
468     return compactSaysUseDwarf(dummy, offset);
469   }
470 
compactSaysUseDwarf(Registers_x86_64 &,uint32_t * offset) const471   bool compactSaysUseDwarf(Registers_x86_64 &, uint32_t *offset) const {
472     if ((_info.format & UNWIND_X86_64_MODE_MASK) == UNWIND_X86_64_MODE_DWARF) {
473       if (offset)
474         *offset = (_info.format & UNWIND_X86_64_DWARF_SECTION_OFFSET);
475       return true;
476     }
477     return false;
478   }
479 
compactSaysUseDwarf(Registers_x86 &,uint32_t * offset) const480   bool compactSaysUseDwarf(Registers_x86 &, uint32_t *offset) const {
481     if ((_info.format & UNWIND_X86_MODE_MASK) == UNWIND_X86_MODE_DWARF) {
482       if (offset)
483         *offset = (_info.format & UNWIND_X86_DWARF_SECTION_OFFSET);
484       return true;
485     }
486     return false;
487   }
488 
compactSaysUseDwarf(Registers_ppc &,uint32_t *) const489   bool compactSaysUseDwarf(Registers_ppc &, uint32_t *) const {
490     return true;
491   }
492 
compactSaysUseDwarf(Registers_arm64 &,uint32_t * offset) const493   bool compactSaysUseDwarf(Registers_arm64 &, uint32_t *offset) const {
494     if ((_info.format & UNWIND_ARM64_MODE_MASK) == UNWIND_ARM64_MODE_DWARF) {
495       if (offset)
496         *offset = (_info.format & UNWIND_ARM64_DWARF_SECTION_OFFSET);
497       return true;
498     }
499     return false;
500   }
501 #endif // _LIBUNWIND_SUPPORT_COMPACT_UNWIND
502 
503 #if _LIBUNWIND_SUPPORT_DWARF_UNWIND
dwarfEncoding() const504   compact_unwind_encoding_t dwarfEncoding() const {
505     R dummy;
506     return dwarfEncoding(dummy);
507   }
508 
dwarfEncoding(Registers_x86_64 &) const509   compact_unwind_encoding_t dwarfEncoding(Registers_x86_64 &) const {
510     return UNWIND_X86_64_MODE_DWARF;
511   }
512 
dwarfEncoding(Registers_x86 &) const513   compact_unwind_encoding_t dwarfEncoding(Registers_x86 &) const {
514     return UNWIND_X86_MODE_DWARF;
515   }
516 
dwarfEncoding(Registers_ppc &) const517   compact_unwind_encoding_t dwarfEncoding(Registers_ppc &) const {
518     return 0;
519   }
520 
dwarfEncoding(Registers_arm64 &) const521   compact_unwind_encoding_t dwarfEncoding(Registers_arm64 &) const {
522     return UNWIND_ARM64_MODE_DWARF;
523   }
524 #endif // _LIBUNWIND_SUPPORT_DWARF_UNWIND
525 
526 
527   A               &_addressSpace;
528   R                _registers;
529   unw_proc_info_t  _info;
530   bool             _unwindInfoMissing;
531   bool             _isSignalFrame;
532 };
533 
534 
535 template <typename A, typename R>
UnwindCursor(unw_context_t * context,A & as)536 UnwindCursor<A, R>::UnwindCursor(unw_context_t *context, A &as)
537     : _addressSpace(as), _registers(context), _unwindInfoMissing(false),
538       _isSignalFrame(false) {
539   static_assert(sizeof(UnwindCursor<A, R>) < sizeof(unw_cursor_t),
540                 "UnwindCursor<> does not fit in unw_cursor_t");
541   memset(&_info, 0, sizeof(_info));
542 }
543 
544 template <typename A, typename R>
UnwindCursor(A & as,void *)545 UnwindCursor<A, R>::UnwindCursor(A &as, void *)
546     : _addressSpace(as), _unwindInfoMissing(false), _isSignalFrame(false) {
547   memset(&_info, 0, sizeof(_info));
548   // FIXME
549   // fill in _registers from thread arg
550 }
551 
552 
553 template <typename A, typename R>
validReg(int regNum)554 bool UnwindCursor<A, R>::validReg(int regNum) {
555   return _registers.validRegister(regNum);
556 }
557 
558 template <typename A, typename R>
getReg(int regNum)559 unw_word_t UnwindCursor<A, R>::getReg(int regNum) {
560   return _registers.getRegister(regNum);
561 }
562 
563 template <typename A, typename R>
setReg(int regNum,unw_word_t value)564 void UnwindCursor<A, R>::setReg(int regNum, unw_word_t value) {
565   _registers.setRegister(regNum, (typename A::pint_t)value);
566 }
567 
568 template <typename A, typename R>
validFloatReg(int regNum)569 bool UnwindCursor<A, R>::validFloatReg(int regNum) {
570   return _registers.validFloatRegister(regNum);
571 }
572 
573 template <typename A, typename R>
getFloatReg(int regNum)574 unw_fpreg_t UnwindCursor<A, R>::getFloatReg(int regNum) {
575   return _registers.getFloatRegister(regNum);
576 }
577 
578 template <typename A, typename R>
setFloatReg(int regNum,unw_fpreg_t value)579 void UnwindCursor<A, R>::setFloatReg(int regNum, unw_fpreg_t value) {
580   _registers.setFloatRegister(regNum, value);
581 }
582 
jumpto()583 template <typename A, typename R> void UnwindCursor<A, R>::jumpto() {
584   _registers.jumpto();
585 }
586 
587 #if __arm__
saveVFPAsX()588 template <typename A, typename R> void UnwindCursor<A, R>::saveVFPAsX() {
589   _registers.saveVFPAsX();
590 }
591 #endif
592 
593 template <typename A, typename R>
getRegisterName(int regNum)594 const char *UnwindCursor<A, R>::getRegisterName(int regNum) {
595   return _registers.getRegisterName(regNum);
596 }
597 
isSignalFrame()598 template <typename A, typename R> bool UnwindCursor<A, R>::isSignalFrame() {
599   return _isSignalFrame;
600 }
601 
602 #if LIBCXXABI_ARM_EHABI
603 struct EHABIIndexEntry {
604   uint32_t functionOffset;
605   uint32_t data;
606 };
607 
608 // Unable to unwind in the ARM index table (section 5 EHABI).
609 #define UNW_EXIDX_CANTUNWIND 0x1
610 
signExtendPrel31(uint32_t data)611 static inline uint32_t signExtendPrel31(uint32_t data) {
612   return data | ((data & 0x40000000u) << 1);
613 }
614 
615 extern "C" _Unwind_Reason_Code __aeabi_unwind_cpp_pr0(
616     _Unwind_State state, _Unwind_Control_Block *ucbp, _Unwind_Context *context);
617 extern "C" _Unwind_Reason_Code __aeabi_unwind_cpp_pr1(
618     _Unwind_State state, _Unwind_Control_Block *ucbp, _Unwind_Context *context);
619 extern "C" _Unwind_Reason_Code __aeabi_unwind_cpp_pr2(
620     _Unwind_State state, _Unwind_Control_Block *ucbp, _Unwind_Context *context);
621 
622 template<typename A>
623 struct EHABISectionIterator {
624   typedef EHABISectionIterator _Self;
625 
626   typedef std::random_access_iterator_tag iterator_category;
627   typedef typename A::pint_t value_type;
628   typedef typename A::pint_t* pointer;
629   typedef typename A::pint_t& reference;
630   typedef size_t size_type;
631   typedef size_t difference_type;
632 
beginlibunwind::EHABISectionIterator633   static _Self begin(A& addressSpace, const UnwindInfoSections& sects) {
634     return _Self(addressSpace, sects, 0);
635   }
endlibunwind::EHABISectionIterator636   static _Self end(A& addressSpace, const UnwindInfoSections& sects) {
637     return _Self(addressSpace, sects, sects.arm_section_length);
638   }
639 
EHABISectionIteratorlibunwind::EHABISectionIterator640   EHABISectionIterator(A& addressSpace, const UnwindInfoSections& sects, size_t i)
641       : _addressSpace(&addressSpace), _sects(&sects), _i(i) {}
642 
operator ++libunwind::EHABISectionIterator643   _Self& operator++() { ++_i; return *this; }
operator +=libunwind::EHABISectionIterator644   _Self& operator+=(size_t a) { _i += a; return *this; }
operator --libunwind::EHABISectionIterator645   _Self& operator--() { assert(_i > 0); --_i; return *this; }
operator -=libunwind::EHABISectionIterator646   _Self& operator-=(size_t a) { assert(_i >= a); _i -= a; return *this; }
647 
operator +libunwind::EHABISectionIterator648   _Self operator+(size_t a) { _Self out = *this; out._i += a; return out; }
operator -libunwind::EHABISectionIterator649   _Self operator-(size_t a) { assert(_i >= a); _Self out = *this; out._i -= a; return out; }
650 
operator -libunwind::EHABISectionIterator651   size_t operator-(const _Self& other) { return _i - other._i; }
652 
operator ==libunwind::EHABISectionIterator653   bool operator==(const _Self& other) const {
654     assert(_addressSpace == other._addressSpace);
655     assert(_sects == other._sects);
656     return _i == other._i;
657   }
658 
operator *libunwind::EHABISectionIterator659   typename A::pint_t operator*() const { return functionAddress(); }
660 
functionAddresslibunwind::EHABISectionIterator661   typename A::pint_t functionAddress() const {
662     typename A::pint_t indexAddr = _sects->arm_section + arrayoffsetof(
663         EHABIIndexEntry, _i, functionOffset);
664     return indexAddr + signExtendPrel31(_addressSpace->get32(indexAddr));
665   }
666 
dataAddresslibunwind::EHABISectionIterator667   typename A::pint_t dataAddress() {
668     typename A::pint_t indexAddr = _sects->arm_section + arrayoffsetof(
669         EHABIIndexEntry, _i, data);
670     return indexAddr;
671   }
672 
673  private:
674   size_t _i;
675   A* _addressSpace;
676   const UnwindInfoSections* _sects;
677 };
678 
679 template <typename A, typename R>
getInfoFromEHABISection(pint_t pc,const UnwindInfoSections & sects)680 bool UnwindCursor<A, R>::getInfoFromEHABISection(
681     pint_t pc,
682     const UnwindInfoSections &sects) {
683   EHABISectionIterator<A> begin =
684       EHABISectionIterator<A>::begin(_addressSpace, sects);
685   EHABISectionIterator<A> end =
686       EHABISectionIterator<A>::end(_addressSpace, sects);
687 
688   EHABISectionIterator<A> itNextPC = std::upper_bound(begin, end, pc);
689   if (itNextPC == begin || itNextPC == end)
690     return false;
691   EHABISectionIterator<A> itThisPC = itNextPC - 1;
692 
693   pint_t thisPC = itThisPC.functionAddress();
694   pint_t nextPC = itNextPC.functionAddress();
695   pint_t indexDataAddr = itThisPC.dataAddress();
696 
697   if (indexDataAddr == 0)
698     return false;
699 
700   uint32_t indexData = _addressSpace.get32(indexDataAddr);
701   if (indexData == UNW_EXIDX_CANTUNWIND)
702     return false;
703 
704   // If the high bit is set, the exception handling table entry is inline inside
705   // the index table entry on the second word (aka |indexDataAddr|). Otherwise,
706   // the table points at an offset in the exception handling table (section 5 EHABI).
707   pint_t exceptionTableAddr;
708   uint32_t exceptionTableData;
709   bool isSingleWordEHT;
710   if (indexData & 0x80000000) {
711     exceptionTableAddr = indexDataAddr;
712     // TODO(ajwong): Should this data be 0?
713     exceptionTableData = indexData;
714     isSingleWordEHT = true;
715   } else {
716     exceptionTableAddr = indexDataAddr + signExtendPrel31(indexData);
717     exceptionTableData = _addressSpace.get32(exceptionTableAddr);
718     isSingleWordEHT = false;
719   }
720 
721   // Now we know the 3 things:
722   //   exceptionTableAddr -- exception handler table entry.
723   //   exceptionTableData -- the data inside the first word of the eht entry.
724   //   isSingleWordEHT -- whether the entry is in the index.
725   unw_word_t personalityRoutine = 0xbadf00d;
726   bool scope32 = false;
727   uintptr_t lsda = 0xbadf00d;
728 
729   // If the high bit in the exception handling table entry is set, the entry is
730   // in compact form (section 6.3 EHABI).
731   if (exceptionTableData & 0x80000000) {
732     // Grab the index of the personality routine from the compact form.
733     int choice = (exceptionTableData & 0x0f000000) >> 24;
734     int extraWords = 0;
735     switch (choice) {
736       case 0:
737         personalityRoutine = (unw_word_t) &__aeabi_unwind_cpp_pr0;
738         extraWords = 0;
739         scope32 = false;
740         break;
741       case 1:
742         personalityRoutine = (unw_word_t) &__aeabi_unwind_cpp_pr1;
743         extraWords = (exceptionTableData & 0x00ff0000) >> 16;
744         scope32 = false;
745         break;
746       case 2:
747         personalityRoutine = (unw_word_t) &__aeabi_unwind_cpp_pr2;
748         extraWords = (exceptionTableData & 0x00ff0000) >> 16;
749         scope32 = true;
750         break;
751       default:
752         _LIBUNWIND_ABORT("unknown personality routine");
753         return false;
754     }
755 
756     if (isSingleWordEHT) {
757       if (extraWords != 0) {
758         _LIBUNWIND_ABORT("index inlined table detected but pr function "
759                          "requires extra words");
760         return false;
761       }
762     }
763   } else {
764     pint_t personalityAddr =
765         exceptionTableAddr + signExtendPrel31(exceptionTableData);
766     personalityRoutine = personalityAddr;
767 
768     // ARM EHABI # 6.2, # 9.2
769     //
770     //  +---- ehtp
771     //  v
772     // +--------------------------------------+
773     // | +--------+--------+--------+-------+ |
774     // | |0| prel31 to personalityRoutine   | |
775     // | +--------+--------+--------+-------+ |
776     // | |      N |      unwind opcodes     | |  <-- UnwindData
777     // | +--------+--------+--------+-------+ |
778     // | | Word 2        unwind opcodes     | |
779     // | +--------+--------+--------+-------+ |
780     // | ...                                  |
781     // | +--------+--------+--------+-------+ |
782     // | | Word N        unwind opcodes     | |
783     // | +--------+--------+--------+-------+ |
784     // | | LSDA                             | |  <-- lsda
785     // | | ...                              | |
786     // | +--------+--------+--------+-------+ |
787     // +--------------------------------------+
788 
789     uint32_t *UnwindData = reinterpret_cast<uint32_t*>(exceptionTableAddr) + 1;
790     uint32_t FirstDataWord = *UnwindData;
791     size_t N = ((FirstDataWord >> 24) & 0xff);
792     size_t NDataWords = N + 1;
793     lsda = reinterpret_cast<uintptr_t>(UnwindData + NDataWords);
794   }
795 
796   _info.start_ip = thisPC;
797   _info.end_ip = nextPC;
798   _info.handler = personalityRoutine;
799   _info.unwind_info = exceptionTableAddr;
800   _info.lsda = lsda;
801   // flags is pr_cache.additional. See EHABI #7.2 for definition of bit 0.
802   _info.flags = isSingleWordEHT ? 1 : 0 | scope32 ? 0x2 : 0;  // Use enum?
803 
804   return true;
805 }
806 #endif
807 
808 #if _LIBUNWIND_SUPPORT_DWARF_UNWIND
809 template <typename A, typename R>
getInfoFromDwarfSection(pint_t pc,const UnwindInfoSections & sects,uint32_t fdeSectionOffsetHint)810 bool UnwindCursor<A, R>::getInfoFromDwarfSection(pint_t pc,
811                                                 const UnwindInfoSections &sects,
812                                                 uint32_t fdeSectionOffsetHint) {
813   typename CFI_Parser<A>::FDE_Info fdeInfo;
814   typename CFI_Parser<A>::CIE_Info cieInfo;
815   bool foundFDE = false;
816   bool foundInCache = false;
817   // If compact encoding table gave offset into dwarf section, go directly there
818   if (fdeSectionOffsetHint != 0) {
819     foundFDE = CFI_Parser<A>::findFDE(_addressSpace, pc, sects.dwarf_section,
820                                     (uint32_t)sects.dwarf_section_length,
821                                     sects.dwarf_section + fdeSectionOffsetHint,
822                                     &fdeInfo, &cieInfo);
823   }
824 #if _LIBUNWIND_SUPPORT_DWARF_INDEX
825   if (!foundFDE && (sects.dwarf_index_section != 0)) {
826     // Have eh_frame_hdr section which is index into dwarf section.
827     // TO DO: implement index search
828   }
829 #endif
830   if (!foundFDE) {
831     // otherwise, search cache of previously found FDEs.
832     pint_t cachedFDE = DwarfFDECache<A>::findFDE(sects.dso_base, pc);
833     if (cachedFDE != 0) {
834       foundFDE =
835           CFI_Parser<A>::findFDE(_addressSpace, pc, sects.dwarf_section,
836                                  (uint32_t)sects.dwarf_section_length,
837                                  cachedFDE, &fdeInfo, &cieInfo);
838       foundInCache = foundFDE;
839     }
840   }
841   if (!foundFDE) {
842     // Still not found, do full scan of __eh_frame section.
843     foundFDE = CFI_Parser<A>::findFDE(_addressSpace, pc, sects.dwarf_section,
844                                       (uint32_t)sects.dwarf_section_length, 0,
845                                       &fdeInfo, &cieInfo);
846   }
847   if (foundFDE) {
848     typename CFI_Parser<A>::PrologInfo prolog;
849     if (CFI_Parser<A>::parseFDEInstructions(_addressSpace, fdeInfo, cieInfo, pc,
850                                             &prolog)) {
851       // Save off parsed FDE info
852       _info.start_ip          = fdeInfo.pcStart;
853       _info.end_ip            = fdeInfo.pcEnd;
854       _info.lsda              = fdeInfo.lsda;
855       _info.handler           = cieInfo.personality;
856       _info.gp                = prolog.spExtraArgSize;
857       _info.flags             = 0;
858       _info.format            = dwarfEncoding();
859       _info.unwind_info       = fdeInfo.fdeStart;
860       _info.unwind_info_size  = (uint32_t)fdeInfo.fdeLength;
861       _info.extra             = (unw_word_t) sects.dso_base;
862 
863       // Add to cache (to make next lookup faster) if we had no hint
864       // and there was no index.
865       if (!foundInCache && (fdeSectionOffsetHint == 0)) {
866   #if _LIBUNWIND_SUPPORT_DWARF_INDEX
867         if (sects.dwarf_index_section == 0)
868   #endif
869         DwarfFDECache<A>::add(sects.dso_base, fdeInfo.pcStart, fdeInfo.pcEnd,
870                               fdeInfo.fdeStart);
871       }
872       return true;
873     }
874   }
875   //_LIBUNWIND_DEBUG_LOG("can't find/use FDE for pc=0x%llX\n", (uint64_t)pc);
876   return false;
877 }
878 #endif // _LIBUNWIND_SUPPORT_DWARF_UNWIND
879 
880 
881 #if _LIBUNWIND_SUPPORT_COMPACT_UNWIND
882 template <typename A, typename R>
getInfoFromCompactEncodingSection(pint_t pc,const UnwindInfoSections & sects)883 bool UnwindCursor<A, R>::getInfoFromCompactEncodingSection(pint_t pc,
884                                               const UnwindInfoSections &sects) {
885   const bool log = false;
886   if (log)
887     fprintf(stderr, "getInfoFromCompactEncodingSection(pc=0x%llX, mh=0x%llX)\n",
888             (uint64_t)pc, (uint64_t)sects.dso_base);
889 
890   const UnwindSectionHeader<A> sectionHeader(_addressSpace,
891                                                 sects.compact_unwind_section);
892   if (sectionHeader.version() != UNWIND_SECTION_VERSION)
893     return false;
894 
895   // do a binary search of top level index to find page with unwind info
896   pint_t targetFunctionOffset = pc - sects.dso_base;
897   const UnwindSectionIndexArray<A> topIndex(_addressSpace,
898                                            sects.compact_unwind_section
899                                          + sectionHeader.indexSectionOffset());
900   uint32_t low = 0;
901   uint32_t high = sectionHeader.indexCount();
902   uint32_t last = high - 1;
903   while (low < high) {
904     uint32_t mid = (low + high) / 2;
905     //if ( log ) fprintf(stderr, "\tmid=%d, low=%d, high=%d, *mid=0x%08X\n",
906     //mid, low, high, topIndex.functionOffset(mid));
907     if (topIndex.functionOffset(mid) <= targetFunctionOffset) {
908       if ((mid == last) ||
909           (topIndex.functionOffset(mid + 1) > targetFunctionOffset)) {
910         low = mid;
911         break;
912       } else {
913         low = mid + 1;
914       }
915     } else {
916       high = mid;
917     }
918   }
919   const uint32_t firstLevelFunctionOffset = topIndex.functionOffset(low);
920   const uint32_t firstLevelNextPageFunctionOffset =
921       topIndex.functionOffset(low + 1);
922   const pint_t secondLevelAddr =
923       sects.compact_unwind_section + topIndex.secondLevelPagesSectionOffset(low);
924   const pint_t lsdaArrayStartAddr =
925       sects.compact_unwind_section + topIndex.lsdaIndexArraySectionOffset(low);
926   const pint_t lsdaArrayEndAddr =
927       sects.compact_unwind_section + topIndex.lsdaIndexArraySectionOffset(low+1);
928   if (log)
929     fprintf(stderr, "\tfirst level search for result index=%d "
930                     "to secondLevelAddr=0x%llX\n",
931                     low, (uint64_t) secondLevelAddr);
932   // do a binary search of second level page index
933   uint32_t encoding = 0;
934   pint_t funcStart = 0;
935   pint_t funcEnd = 0;
936   pint_t lsda = 0;
937   pint_t personality = 0;
938   uint32_t pageKind = _addressSpace.get32(secondLevelAddr);
939   if (pageKind == UNWIND_SECOND_LEVEL_REGULAR) {
940     // regular page
941     UnwindSectionRegularPageHeader<A> pageHeader(_addressSpace,
942                                                  secondLevelAddr);
943     UnwindSectionRegularArray<A> pageIndex(
944         _addressSpace, secondLevelAddr + pageHeader.entryPageOffset());
945     // binary search looks for entry with e where index[e].offset <= pc <
946     // index[e+1].offset
947     if (log)
948       fprintf(stderr, "\tbinary search for targetFunctionOffset=0x%08llX in "
949                       "regular page starting at secondLevelAddr=0x%llX\n",
950               (uint64_t) targetFunctionOffset, (uint64_t) secondLevelAddr);
951     low = 0;
952     high = pageHeader.entryCount();
953     while (low < high) {
954       uint32_t mid = (low + high) / 2;
955       if (pageIndex.functionOffset(mid) <= targetFunctionOffset) {
956         if (mid == (uint32_t)(pageHeader.entryCount() - 1)) {
957           // at end of table
958           low = mid;
959           funcEnd = firstLevelNextPageFunctionOffset + sects.dso_base;
960           break;
961         } else if (pageIndex.functionOffset(mid + 1) > targetFunctionOffset) {
962           // next is too big, so we found it
963           low = mid;
964           funcEnd = pageIndex.functionOffset(low + 1) + sects.dso_base;
965           break;
966         } else {
967           low = mid + 1;
968         }
969       } else {
970         high = mid;
971       }
972     }
973     encoding = pageIndex.encoding(low);
974     funcStart = pageIndex.functionOffset(low) + sects.dso_base;
975     if (pc < funcStart) {
976       if (log)
977         fprintf(
978             stderr,
979             "\tpc not in table, pc=0x%llX, funcStart=0x%llX, funcEnd=0x%llX\n",
980             (uint64_t) pc, (uint64_t) funcStart, (uint64_t) funcEnd);
981       return false;
982     }
983     if (pc > funcEnd) {
984       if (log)
985         fprintf(
986             stderr,
987             "\tpc not in table, pc=0x%llX, funcStart=0x%llX, funcEnd=0x%llX\n",
988             (uint64_t) pc, (uint64_t) funcStart, (uint64_t) funcEnd);
989       return false;
990     }
991   } else if (pageKind == UNWIND_SECOND_LEVEL_COMPRESSED) {
992     // compressed page
993     UnwindSectionCompressedPageHeader<A> pageHeader(_addressSpace,
994                                                     secondLevelAddr);
995     UnwindSectionCompressedArray<A> pageIndex(
996         _addressSpace, secondLevelAddr + pageHeader.entryPageOffset());
997     const uint32_t targetFunctionPageOffset =
998         (uint32_t)(targetFunctionOffset - firstLevelFunctionOffset);
999     // binary search looks for entry with e where index[e].offset <= pc <
1000     // index[e+1].offset
1001     if (log)
1002       fprintf(stderr, "\tbinary search of compressed page starting at "
1003                       "secondLevelAddr=0x%llX\n",
1004               (uint64_t) secondLevelAddr);
1005     low = 0;
1006     last = pageHeader.entryCount() - 1;
1007     high = pageHeader.entryCount();
1008     while (low < high) {
1009       uint32_t mid = (low + high) / 2;
1010       if (pageIndex.functionOffset(mid) <= targetFunctionPageOffset) {
1011         if ((mid == last) ||
1012             (pageIndex.functionOffset(mid + 1) > targetFunctionPageOffset)) {
1013           low = mid;
1014           break;
1015         } else {
1016           low = mid + 1;
1017         }
1018       } else {
1019         high = mid;
1020       }
1021     }
1022     funcStart = pageIndex.functionOffset(low) + firstLevelFunctionOffset
1023                                                               + sects.dso_base;
1024     if (low < last)
1025       funcEnd =
1026           pageIndex.functionOffset(low + 1) + firstLevelFunctionOffset
1027                                                               + sects.dso_base;
1028     else
1029       funcEnd = firstLevelNextPageFunctionOffset + sects.dso_base;
1030     if (pc < funcStart) {
1031       _LIBUNWIND_DEBUG_LOG("malformed __unwind_info, pc=0x%llX not in second  "
1032                            "level compressed unwind table. funcStart=0x%llX\n",
1033                             (uint64_t) pc, (uint64_t) funcStart);
1034       return false;
1035     }
1036     if (pc > funcEnd) {
1037       _LIBUNWIND_DEBUG_LOG("malformed __unwind_info, pc=0x%llX not in second  "
1038                           "level compressed unwind table. funcEnd=0x%llX\n",
1039                            (uint64_t) pc, (uint64_t) funcEnd);
1040       return false;
1041     }
1042     uint16_t encodingIndex = pageIndex.encodingIndex(low);
1043     if (encodingIndex < sectionHeader.commonEncodingsArrayCount()) {
1044       // encoding is in common table in section header
1045       encoding = _addressSpace.get32(
1046           sects.compact_unwind_section +
1047           sectionHeader.commonEncodingsArraySectionOffset() +
1048           encodingIndex * sizeof(uint32_t));
1049     } else {
1050       // encoding is in page specific table
1051       uint16_t pageEncodingIndex =
1052           encodingIndex - (uint16_t)sectionHeader.commonEncodingsArrayCount();
1053       encoding = _addressSpace.get32(secondLevelAddr +
1054                                      pageHeader.encodingsPageOffset() +
1055                                      pageEncodingIndex * sizeof(uint32_t));
1056     }
1057   } else {
1058     _LIBUNWIND_DEBUG_LOG("malformed __unwind_info at 0x%0llX bad second "
1059                          "level page\n",
1060                           (uint64_t) sects.compact_unwind_section);
1061     return false;
1062   }
1063 
1064   // look up LSDA, if encoding says function has one
1065   if (encoding & UNWIND_HAS_LSDA) {
1066     UnwindSectionLsdaArray<A> lsdaIndex(_addressSpace, lsdaArrayStartAddr);
1067     uint32_t funcStartOffset = (uint32_t)(funcStart - sects.dso_base);
1068     low = 0;
1069     high = (uint32_t)(lsdaArrayEndAddr - lsdaArrayStartAddr) /
1070                     sizeof(unwind_info_section_header_lsda_index_entry);
1071     // binary search looks for entry with exact match for functionOffset
1072     if (log)
1073       fprintf(stderr,
1074               "\tbinary search of lsda table for targetFunctionOffset=0x%08X\n",
1075               funcStartOffset);
1076     while (low < high) {
1077       uint32_t mid = (low + high) / 2;
1078       if (lsdaIndex.functionOffset(mid) == funcStartOffset) {
1079         lsda = lsdaIndex.lsdaOffset(mid) + sects.dso_base;
1080         break;
1081       } else if (lsdaIndex.functionOffset(mid) < funcStartOffset) {
1082         low = mid + 1;
1083       } else {
1084         high = mid;
1085       }
1086     }
1087     if (lsda == 0) {
1088       _LIBUNWIND_DEBUG_LOG("found encoding 0x%08X with HAS_LSDA bit set for "
1089                     "pc=0x%0llX, but lsda table has no entry\n",
1090                     encoding, (uint64_t) pc);
1091       return false;
1092     }
1093   }
1094 
1095   // extact personality routine, if encoding says function has one
1096   uint32_t personalityIndex = (encoding & UNWIND_PERSONALITY_MASK) >>
1097                               (__builtin_ctz(UNWIND_PERSONALITY_MASK));
1098   if (personalityIndex != 0) {
1099     --personalityIndex; // change 1-based to zero-based index
1100     if (personalityIndex > sectionHeader.personalityArrayCount()) {
1101       _LIBUNWIND_DEBUG_LOG("found encoding 0x%08X with personality index %d,  "
1102                             "but personality table has only %d entires\n",
1103                             encoding, personalityIndex,
1104                             sectionHeader.personalityArrayCount());
1105       return false;
1106     }
1107     int32_t personalityDelta = (int32_t)_addressSpace.get32(
1108         sects.compact_unwind_section +
1109         sectionHeader.personalityArraySectionOffset() +
1110         personalityIndex * sizeof(uint32_t));
1111     pint_t personalityPointer = sects.dso_base + (pint_t)personalityDelta;
1112     personality = _addressSpace.getP(personalityPointer);
1113     if (log)
1114       fprintf(stderr, "getInfoFromCompactEncodingSection(pc=0x%llX), "
1115                       "personalityDelta=0x%08X, personality=0x%08llX\n",
1116               (uint64_t) pc, personalityDelta, (uint64_t) personality);
1117   }
1118 
1119   if (log)
1120     fprintf(stderr, "getInfoFromCompactEncodingSection(pc=0x%llX), "
1121                     "encoding=0x%08X, lsda=0x%08llX for funcStart=0x%llX\n",
1122             (uint64_t) pc, encoding, (uint64_t) lsda, (uint64_t) funcStart);
1123   _info.start_ip = funcStart;
1124   _info.end_ip = funcEnd;
1125   _info.lsda = lsda;
1126   _info.handler = personality;
1127   _info.gp = 0;
1128   _info.flags = 0;
1129   _info.format = encoding;
1130   _info.unwind_info = 0;
1131   _info.unwind_info_size = 0;
1132   _info.extra = sects.dso_base;
1133   return true;
1134 }
1135 #endif // _LIBUNWIND_SUPPORT_COMPACT_UNWIND
1136 
1137 
1138 template <typename A, typename R>
setInfoBasedOnIPRegister(bool isReturnAddress)1139 void UnwindCursor<A, R>::setInfoBasedOnIPRegister(bool isReturnAddress) {
1140   pint_t pc = (pint_t)this->getReg(UNW_REG_IP);
1141 #if LIBCXXABI_ARM_EHABI
1142   // Remove the thumb bit so the IP represents the actual instruction address.
1143   // This matches the behaviour of _Unwind_GetIP on arm.
1144   pc &= (pint_t)~0x1;
1145 #endif
1146 
1147   // If the last line of a function is a "throw" the compiler sometimes
1148   // emits no instructions after the call to __cxa_throw.  This means
1149   // the return address is actually the start of the next function.
1150   // To disambiguate this, back up the pc when we know it is a return
1151   // address.
1152   if (isReturnAddress)
1153     --pc;
1154 
1155   // Ask address space object to find unwind sections for this pc.
1156   UnwindInfoSections sects;
1157   if (_addressSpace.findUnwindSections(pc, sects)) {
1158 #if _LIBUNWIND_SUPPORT_COMPACT_UNWIND
1159     // If there is a compact unwind encoding table, look there first.
1160     if (sects.compact_unwind_section != 0) {
1161       if (this->getInfoFromCompactEncodingSection(pc, sects)) {
1162   #if _LIBUNWIND_SUPPORT_DWARF_UNWIND
1163         // Found info in table, done unless encoding says to use dwarf.
1164         uint32_t dwarfOffset;
1165         if ((sects.dwarf_section != 0) && compactSaysUseDwarf(&dwarfOffset)) {
1166           if (this->getInfoFromDwarfSection(pc, sects, dwarfOffset)) {
1167             // found info in dwarf, done
1168             return;
1169           }
1170         }
1171   #endif
1172         // If unwind table has entry, but entry says there is no unwind info,
1173         // record that we have no unwind info.
1174         if (_info.format == 0)
1175           _unwindInfoMissing = true;
1176         return;
1177       }
1178     }
1179 #endif // _LIBUNWIND_SUPPORT_COMPACT_UNWIND
1180 
1181 #if _LIBUNWIND_SUPPORT_DWARF_UNWIND
1182     // If there is dwarf unwind info, look there next.
1183     if (sects.dwarf_section != 0) {
1184       if (this->getInfoFromDwarfSection(pc, sects)) {
1185         // found info in dwarf, done
1186         return;
1187       }
1188     }
1189 #endif
1190 
1191 #if LIBCXXABI_ARM_EHABI
1192     // If there is ARM EHABI unwind info, look there next.
1193     if (sects.arm_section != 0 && this->getInfoFromEHABISection(pc, sects))
1194       return;
1195 #endif
1196   }
1197 
1198 #if _LIBUNWIND_SUPPORT_DWARF_UNWIND
1199   // There is no static unwind info for this pc. Look to see if an FDE was
1200   // dynamically registered for it.
1201   pint_t cachedFDE = DwarfFDECache<A>::findFDE(0, pc);
1202   if (cachedFDE != 0) {
1203     CFI_Parser<LocalAddressSpace>::FDE_Info fdeInfo;
1204     CFI_Parser<LocalAddressSpace>::CIE_Info cieInfo;
1205     const char *msg = CFI_Parser<A>::decodeFDE(_addressSpace,
1206                                                 cachedFDE, &fdeInfo, &cieInfo);
1207     if (msg == NULL) {
1208       typename CFI_Parser<A>::PrologInfo prolog;
1209       if (CFI_Parser<A>::parseFDEInstructions(_addressSpace, fdeInfo, cieInfo,
1210                                                                 pc, &prolog)) {
1211         // save off parsed FDE info
1212         _info.start_ip         = fdeInfo.pcStart;
1213         _info.end_ip           = fdeInfo.pcEnd;
1214         _info.lsda             = fdeInfo.lsda;
1215         _info.handler          = cieInfo.personality;
1216         _info.gp               = prolog.spExtraArgSize;
1217                                   // Some frameless functions need SP
1218                                   // altered when resuming in function.
1219         _info.flags            = 0;
1220         _info.format           = dwarfEncoding();
1221         _info.unwind_info      = fdeInfo.fdeStart;
1222         _info.unwind_info_size = (uint32_t)fdeInfo.fdeLength;
1223         _info.extra            = 0;
1224         return;
1225       }
1226     }
1227   }
1228 
1229   // Lastly, ask AddressSpace object about platform specific ways to locate
1230   // other FDEs.
1231   pint_t fde;
1232   if (_addressSpace.findOtherFDE(pc, fde)) {
1233     CFI_Parser<LocalAddressSpace>::FDE_Info fdeInfo;
1234     CFI_Parser<LocalAddressSpace>::CIE_Info cieInfo;
1235     if (!CFI_Parser<A>::decodeFDE(_addressSpace, fde, &fdeInfo, &cieInfo)) {
1236       // Double check this FDE is for a function that includes the pc.
1237       if ((fdeInfo.pcStart <= pc) && (pc < fdeInfo.pcEnd)) {
1238         typename CFI_Parser<A>::PrologInfo prolog;
1239         if (CFI_Parser<A>::parseFDEInstructions(_addressSpace, fdeInfo,
1240                                                 cieInfo, pc, &prolog)) {
1241           // save off parsed FDE info
1242           _info.start_ip         = fdeInfo.pcStart;
1243           _info.end_ip           = fdeInfo.pcEnd;
1244           _info.lsda             = fdeInfo.lsda;
1245           _info.handler          = cieInfo.personality;
1246           _info.gp               = prolog.spExtraArgSize;
1247           _info.flags            = 0;
1248           _info.format           = dwarfEncoding();
1249           _info.unwind_info      = fdeInfo.fdeStart;
1250           _info.unwind_info_size = (uint32_t)fdeInfo.fdeLength;
1251           _info.extra            = 0;
1252           return;
1253         }
1254       }
1255     }
1256   }
1257 #endif // #if _LIBUNWIND_SUPPORT_DWARF_UNWIND
1258 
1259   // no unwind info, flag that we can't reliably unwind
1260   _unwindInfoMissing = true;
1261 }
1262 
1263 template <typename A, typename R>
step()1264 int UnwindCursor<A, R>::step() {
1265   // Bottom of stack is defined is when unwind info cannot be found.
1266   if (_unwindInfoMissing)
1267     return UNW_STEP_END;
1268 
1269   // Use unwinding info to modify register set as if function returned.
1270   int result;
1271 #if _LIBUNWIND_SUPPORT_COMPACT_UNWIND
1272   result = this->stepWithCompactEncoding();
1273 #elif _LIBUNWIND_SUPPORT_DWARF_UNWIND
1274   result = this->stepWithDwarfFDE();
1275 #elif LIBCXXABI_ARM_EHABI
1276   result = UNW_STEP_SUCCESS;
1277 #elif defined(__i386__) || defined(__x86_64__) || defined(__mips__) || defined(__mips64)
1278   // ToDo: really?
1279   result = UNW_STEP_SUCCESS;
1280 #else
1281   #error Need _LIBUNWIND_SUPPORT_COMPACT_UNWIND or \
1282               _LIBUNWIND_SUPPORT_DWARF_UNWIND or \
1283               LIBCXXABI_ARM_EHABI
1284 #endif
1285 
1286   // update info based on new PC
1287   if (result == UNW_STEP_SUCCESS) {
1288     this->setInfoBasedOnIPRegister(true);
1289     if (_unwindInfoMissing)
1290       return UNW_STEP_END;
1291     if (_info.gp)
1292       setReg(UNW_REG_SP, getReg(UNW_REG_SP) + _info.gp);
1293   }
1294 
1295   return result;
1296 }
1297 
1298 template <typename A, typename R>
getInfo(unw_proc_info_t * info)1299 void UnwindCursor<A, R>::getInfo(unw_proc_info_t *info) {
1300   *info = _info;
1301 }
1302 
1303 template <typename A, typename R>
getFunctionName(char * buf,size_t bufLen,unw_word_t * offset)1304 bool UnwindCursor<A, R>::getFunctionName(char *buf, size_t bufLen,
1305                                                            unw_word_t *offset) {
1306   return _addressSpace.findFunctionName((pint_t)this->getReg(UNW_REG_IP),
1307                                          buf, bufLen, offset);
1308 }
1309 
1310 }; // namespace libunwind
1311 
1312 #endif // __UNWINDCURSOR_HPP__
1313