1 //===-- sanitizer_coverage.cc ---------------------------------------------===//
2 //
3 //                     The LLVM Compiler Infrastructure
4 //
5 // This file is distributed under the University of Illinois Open Source
6 // License. See LICENSE.TXT for details.
7 //
8 //===----------------------------------------------------------------------===//
9 //
10 // Sanitizer Coverage.
11 // This file implements run-time support for a poor man's coverage tool.
12 //
13 // Compiler instrumentation:
14 // For every interesting basic block the compiler injects the following code:
15 // if (Guard < 0) {
16 //    __sanitizer_cov(&Guard);
17 // }
18 // At the module start up time __sanitizer_cov_module_init sets the guards
19 // to consecutive negative numbers (-1, -2, -3, ...).
20 // It's fine to call __sanitizer_cov more than once for a given block.
21 //
22 // Run-time:
23 //  - __sanitizer_cov(): record that we've executed the PC (GET_CALLER_PC).
24 //    and atomically set Guard to -Guard.
25 //  - __sanitizer_cov_dump: dump the coverage data to disk.
26 //  For every module of the current process that has coverage data
27 //  this will create a file module_name.PID.sancov.
28 //
29 // The file format is simple: the first 8 bytes is the magic,
30 // one of 0xC0BFFFFFFFFFFF64 and 0xC0BFFFFFFFFFFF32. The last byte of the
31 // magic defines the size of the following offsets.
32 // The rest of the data is the offsets in the module.
33 //
34 // Eventually, this coverage implementation should be obsoleted by a more
35 // powerful general purpose Clang/LLVM coverage instrumentation.
36 // Consider this implementation as prototype.
37 //
38 // FIXME: support (or at least test with) dlclose.
39 //===----------------------------------------------------------------------===//
40 
41 #include "sanitizer_allocator_internal.h"
42 #include "sanitizer_common.h"
43 #include "sanitizer_libc.h"
44 #include "sanitizer_mutex.h"
45 #include "sanitizer_procmaps.h"
46 #include "sanitizer_stacktrace.h"
47 #include "sanitizer_symbolizer.h"
48 #include "sanitizer_flags.h"
49 
50 static const u64 kMagic64 = 0xC0BFFFFFFFFFFF64ULL;
51 static const u64 kMagic32 = 0xC0BFFFFFFFFFFF32ULL;
52 
53 static atomic_uint32_t dump_once_guard;  // Ensure that CovDump runs only once.
54 
55 static atomic_uintptr_t coverage_counter;
56 static atomic_uintptr_t caller_callee_counter;
57 
ResetGlobalCounters()58 static void ResetGlobalCounters() {
59   return atomic_store(&coverage_counter, 0, memory_order_relaxed);
60   return atomic_store(&caller_callee_counter, 0, memory_order_relaxed);
61 }
62 
63 // pc_array is the array containing the covered PCs.
64 // To make the pc_array thread- and async-signal-safe it has to be large enough.
65 // 128M counters "ought to be enough for anybody" (4M on 32-bit).
66 
67 // With coverage_direct=1 in ASAN_OPTIONS, pc_array memory is mapped to a file.
68 // In this mode, __sanitizer_cov_dump does nothing, and CovUpdateMapping()
69 // dump current memory layout to another file.
70 
71 static bool cov_sandboxed = false;
72 static fd_t cov_fd = kInvalidFd;
73 static unsigned int cov_max_block_size = 0;
74 static bool coverage_enabled = false;
75 static const char *coverage_dir;
76 
77 namespace __sanitizer {
78 
79 class CoverageData {
80  public:
81   void Init();
82   void Enable();
83   void Disable();
84   void ReInit();
85   void BeforeFork();
86   void AfterFork(int child_pid);
87   void Extend(uptr npcs);
88   void Add(uptr pc, u32 *guard);
89   void IndirCall(uptr caller, uptr callee, uptr callee_cache[],
90                  uptr cache_size);
91   void DumpCallerCalleePairs();
92   void DumpTrace();
93   void DumpAsBitSet();
94   void DumpCounters();
95   void DumpOffsets();
96   void DumpAll();
97 
98   ALWAYS_INLINE
99   void TraceBasicBlock(u32 *id);
100 
101   void InitializeGuardArray(s32 *guards);
102   void InitializeGuards(s32 *guards, uptr n, const char *module_name,
103                         uptr caller_pc);
104   void InitializeCounters(u8 *counters, uptr n);
105   void ReinitializeGuards();
106   uptr GetNumberOf8bitCounters();
107   uptr Update8bitCounterBitsetAndClearCounters(u8 *bitset);
108 
109   uptr *data();
110   uptr size();
111 
112  private:
113   void DirectOpen();
114   void UpdateModuleNameVec(uptr caller_pc, uptr range_beg, uptr range_end);
115 
116   // Maximal size pc array may ever grow.
117   // We MmapNoReserve this space to ensure that the array is contiguous.
118   static const uptr kPcArrayMaxSize = FIRST_32_SECOND_64(
119       1 << (SANITIZER_ANDROID ? 24 : (SANITIZER_WINDOWS ? 27 : 26)),
120       1 << 27);
121   // The amount file mapping for the pc array is grown by.
122   static const uptr kPcArrayMmapSize = 64 * 1024;
123 
124   // pc_array is allocated with MmapNoReserveOrDie and so it uses only as
125   // much RAM as it really needs.
126   uptr *pc_array;
127   // Index of the first available pc_array slot.
128   atomic_uintptr_t pc_array_index;
129   // Array size.
130   atomic_uintptr_t pc_array_size;
131   // Current file mapped size of the pc array.
132   uptr pc_array_mapped_size;
133   // Descriptor of the file mapped pc array.
134   fd_t pc_fd;
135 
136   // Vector of coverage guard arrays, protected by mu.
137   InternalMmapVectorNoCtor<s32*> guard_array_vec;
138 
139   struct NamedPcRange {
140     const char *copied_module_name;
141     uptr beg, end; // elements [beg,end) in pc_array.
142   };
143 
144   // Vector of module and compilation unit pc ranges.
145   InternalMmapVectorNoCtor<NamedPcRange> comp_unit_name_vec;
146   InternalMmapVectorNoCtor<NamedPcRange> module_name_vec;
147 
148   struct CounterAndSize {
149     u8 *counters;
150     uptr n;
151   };
152 
153   InternalMmapVectorNoCtor<CounterAndSize> counters_vec;
154   uptr num_8bit_counters;
155 
156   // Caller-Callee (cc) array, size and current index.
157   static const uptr kCcArrayMaxSize = FIRST_32_SECOND_64(1 << 18, 1 << 24);
158   uptr **cc_array;
159   atomic_uintptr_t cc_array_index;
160   atomic_uintptr_t cc_array_size;
161 
162   // Tracing event array, size and current pointer.
163   // We record all events (basic block entries) in a global buffer of u32
164   // values. Each such value is the index in pc_array.
165   // So far the tracing is highly experimental:
166   //   - not thread-safe;
167   //   - does not support long traces;
168   //   - not tuned for performance.
169   static const uptr kTrEventArrayMaxSize = FIRST_32_SECOND_64(1 << 22, 1 << 30);
170   u32 *tr_event_array;
171   uptr tr_event_array_size;
172   u32 *tr_event_pointer;
173   static const uptr kTrPcArrayMaxSize    = FIRST_32_SECOND_64(1 << 22, 1 << 27);
174 
175   StaticSpinMutex mu;
176 };
177 
178 static CoverageData coverage_data;
179 
180 void CovUpdateMapping(const char *path, uptr caller_pc = 0);
181 
DirectOpen()182 void CoverageData::DirectOpen() {
183   InternalScopedString path(kMaxPathLength);
184   internal_snprintf((char *)path.data(), path.size(), "%s/%zd.sancov.raw",
185                     coverage_dir, internal_getpid());
186   pc_fd = OpenFile(path.data(), RdWr);
187   if (pc_fd == kInvalidFd) {
188     Report("Coverage: failed to open %s for reading/writing\n", path.data());
189     Die();
190   }
191 
192   pc_array_mapped_size = 0;
193   CovUpdateMapping(coverage_dir);
194 }
195 
Init()196 void CoverageData::Init() {
197   pc_fd = kInvalidFd;
198 }
199 
Enable()200 void CoverageData::Enable() {
201   if (pc_array)
202     return;
203   pc_array = reinterpret_cast<uptr *>(
204       MmapNoReserveOrDie(sizeof(uptr) * kPcArrayMaxSize, "CovInit"));
205   atomic_store(&pc_array_index, 0, memory_order_relaxed);
206   if (common_flags()->coverage_direct) {
207     atomic_store(&pc_array_size, 0, memory_order_relaxed);
208   } else {
209     atomic_store(&pc_array_size, kPcArrayMaxSize, memory_order_relaxed);
210   }
211 
212   cc_array = reinterpret_cast<uptr **>(MmapNoReserveOrDie(
213       sizeof(uptr *) * kCcArrayMaxSize, "CovInit::cc_array"));
214   atomic_store(&cc_array_size, kCcArrayMaxSize, memory_order_relaxed);
215   atomic_store(&cc_array_index, 0, memory_order_relaxed);
216 
217   // Allocate tr_event_array with a guard page at the end.
218   tr_event_array = reinterpret_cast<u32 *>(MmapNoReserveOrDie(
219       sizeof(tr_event_array[0]) * kTrEventArrayMaxSize + GetMmapGranularity(),
220       "CovInit::tr_event_array"));
221   MprotectNoAccess(
222       reinterpret_cast<uptr>(&tr_event_array[kTrEventArrayMaxSize]),
223       GetMmapGranularity());
224   tr_event_array_size = kTrEventArrayMaxSize;
225   tr_event_pointer = tr_event_array;
226 
227   num_8bit_counters = 0;
228 }
229 
InitializeGuardArray(s32 * guards)230 void CoverageData::InitializeGuardArray(s32 *guards) {
231   Enable();  // Make sure coverage is enabled at this point.
232   s32 n = guards[0];
233   for (s32 j = 1; j <= n; j++) {
234     uptr idx = atomic_load_relaxed(&pc_array_index);
235     atomic_store_relaxed(&pc_array_index, idx + 1);
236     guards[j] = -static_cast<s32>(idx + 1);
237   }
238 }
239 
Disable()240 void CoverageData::Disable() {
241   if (pc_array) {
242     UnmapOrDie(pc_array, sizeof(uptr) * kPcArrayMaxSize);
243     pc_array = nullptr;
244   }
245   if (cc_array) {
246     UnmapOrDie(cc_array, sizeof(uptr *) * kCcArrayMaxSize);
247     cc_array = nullptr;
248   }
249   if (tr_event_array) {
250     UnmapOrDie(tr_event_array,
251                sizeof(tr_event_array[0]) * kTrEventArrayMaxSize +
252                    GetMmapGranularity());
253     tr_event_array = nullptr;
254     tr_event_pointer = nullptr;
255   }
256   if (pc_fd != kInvalidFd) {
257     CloseFile(pc_fd);
258     pc_fd = kInvalidFd;
259   }
260 }
261 
ReinitializeGuards()262 void CoverageData::ReinitializeGuards() {
263   // Assuming single thread.
264   atomic_store(&pc_array_index, 0, memory_order_relaxed);
265   for (uptr i = 0; i < guard_array_vec.size(); i++)
266     InitializeGuardArray(guard_array_vec[i]);
267 }
268 
ReInit()269 void CoverageData::ReInit() {
270   Disable();
271   if (coverage_enabled) {
272     if (common_flags()->coverage_direct) {
273       // In memory-mapped mode we must extend the new file to the known array
274       // size.
275       uptr size = atomic_load(&pc_array_size, memory_order_relaxed);
276       uptr npcs = size / sizeof(uptr);
277       Enable();
278       if (size) Extend(npcs);
279       if (coverage_enabled) CovUpdateMapping(coverage_dir);
280     } else {
281       Enable();
282     }
283   }
284   // Re-initialize the guards.
285   // We are single-threaded now, no need to grab any lock.
286   CHECK_EQ(atomic_load(&pc_array_index, memory_order_relaxed), 0);
287   ReinitializeGuards();
288 }
289 
BeforeFork()290 void CoverageData::BeforeFork() {
291   mu.Lock();
292 }
293 
AfterFork(int child_pid)294 void CoverageData::AfterFork(int child_pid) {
295   // We are single-threaded so it's OK to release the lock early.
296   mu.Unlock();
297   if (child_pid == 0) ReInit();
298 }
299 
300 // Extend coverage PC array to fit additional npcs elements.
Extend(uptr npcs)301 void CoverageData::Extend(uptr npcs) {
302   if (!common_flags()->coverage_direct) return;
303   SpinMutexLock l(&mu);
304 
305   uptr size = atomic_load(&pc_array_size, memory_order_relaxed);
306   size += npcs * sizeof(uptr);
307 
308   if (coverage_enabled && size > pc_array_mapped_size) {
309     if (pc_fd == kInvalidFd) DirectOpen();
310     CHECK_NE(pc_fd, kInvalidFd);
311 
312     uptr new_mapped_size = pc_array_mapped_size;
313     while (size > new_mapped_size) new_mapped_size += kPcArrayMmapSize;
314     CHECK_LE(new_mapped_size, sizeof(uptr) * kPcArrayMaxSize);
315 
316     // Extend the file and map the new space at the end of pc_array.
317     uptr res = internal_ftruncate(pc_fd, new_mapped_size);
318     int err;
319     if (internal_iserror(res, &err)) {
320       Printf("failed to extend raw coverage file: %d\n", err);
321       Die();
322     }
323 
324     uptr next_map_base = ((uptr)pc_array) + pc_array_mapped_size;
325     void *p = MapWritableFileToMemory((void *)next_map_base,
326                                       new_mapped_size - pc_array_mapped_size,
327                                       pc_fd, pc_array_mapped_size);
328     CHECK_EQ((uptr)p, next_map_base);
329     pc_array_mapped_size = new_mapped_size;
330   }
331 
332   atomic_store(&pc_array_size, size, memory_order_release);
333 }
334 
InitializeCounters(u8 * counters,uptr n)335 void CoverageData::InitializeCounters(u8 *counters, uptr n) {
336   if (!counters) return;
337   CHECK_EQ(reinterpret_cast<uptr>(counters) % 16, 0);
338   n = RoundUpTo(n, 16); // The compiler must ensure that counters is 16-aligned.
339   SpinMutexLock l(&mu);
340   counters_vec.push_back({counters, n});
341   num_8bit_counters += n;
342 }
343 
UpdateModuleNameVec(uptr caller_pc,uptr range_beg,uptr range_end)344 void CoverageData::UpdateModuleNameVec(uptr caller_pc, uptr range_beg,
345                                        uptr range_end) {
346   auto sym = Symbolizer::GetOrInit();
347   if (!sym)
348     return;
349   const char *module_name = sym->GetModuleNameForPc(caller_pc);
350   if (!module_name) return;
351   if (module_name_vec.empty() ||
352       module_name_vec.back().copied_module_name != module_name)
353     module_name_vec.push_back({module_name, range_beg, range_end});
354   else
355     module_name_vec.back().end = range_end;
356 }
357 
InitializeGuards(s32 * guards,uptr n,const char * comp_unit_name,uptr caller_pc)358 void CoverageData::InitializeGuards(s32 *guards, uptr n,
359                                     const char *comp_unit_name,
360                                     uptr caller_pc) {
361   // The array 'guards' has n+1 elements, we use the element zero
362   // to store 'n'.
363   CHECK_LT(n, 1 << 30);
364   guards[0] = static_cast<s32>(n);
365   InitializeGuardArray(guards);
366   SpinMutexLock l(&mu);
367   uptr range_end = atomic_load(&pc_array_index, memory_order_relaxed);
368   uptr range_beg = range_end - n;
369   comp_unit_name_vec.push_back({comp_unit_name, range_beg, range_end});
370   guard_array_vec.push_back(guards);
371   UpdateModuleNameVec(caller_pc, range_beg, range_end);
372 }
373 
374 static const uptr kBundleCounterBits = 16;
375 
376 // When coverage_order_pcs==true and SANITIZER_WORDSIZE==64
377 // we insert the global counter into the first 16 bits of the PC.
BundlePcAndCounter(uptr pc,uptr counter)378 uptr BundlePcAndCounter(uptr pc, uptr counter) {
379   if (SANITIZER_WORDSIZE != 64 || !common_flags()->coverage_order_pcs)
380     return pc;
381   static const uptr kMaxCounter = (1 << kBundleCounterBits) - 1;
382   if (counter > kMaxCounter)
383     counter = kMaxCounter;
384   CHECK_EQ(0, pc >> (SANITIZER_WORDSIZE - kBundleCounterBits));
385   return pc | (counter << (SANITIZER_WORDSIZE - kBundleCounterBits));
386 }
387 
UnbundlePc(uptr bundle)388 uptr UnbundlePc(uptr bundle) {
389   if (SANITIZER_WORDSIZE != 64 || !common_flags()->coverage_order_pcs)
390     return bundle;
391   return (bundle << kBundleCounterBits) >> kBundleCounterBits;
392 }
393 
UnbundleCounter(uptr bundle)394 uptr UnbundleCounter(uptr bundle) {
395   if (SANITIZER_WORDSIZE != 64 || !common_flags()->coverage_order_pcs)
396     return 0;
397   return bundle >> (SANITIZER_WORDSIZE - kBundleCounterBits);
398 }
399 
400 // If guard is negative, atomically set it to -guard and store the PC in
401 // pc_array.
Add(uptr pc,u32 * guard)402 void CoverageData::Add(uptr pc, u32 *guard) {
403   atomic_uint32_t *atomic_guard = reinterpret_cast<atomic_uint32_t*>(guard);
404   s32 guard_value = atomic_load(atomic_guard, memory_order_relaxed);
405   if (guard_value >= 0) return;
406 
407   atomic_store(atomic_guard, -guard_value, memory_order_relaxed);
408   if (!pc_array) return;
409 
410   uptr idx = -guard_value - 1;
411   if (idx >= atomic_load(&pc_array_index, memory_order_acquire))
412     return;  // May happen after fork when pc_array_index becomes 0.
413   CHECK_LT(idx * sizeof(uptr),
414            atomic_load(&pc_array_size, memory_order_acquire));
415   uptr counter = atomic_fetch_add(&coverage_counter, 1, memory_order_relaxed);
416   pc_array[idx] = BundlePcAndCounter(pc, counter);
417 }
418 
419 // Registers a pair caller=>callee.
420 // When a given caller is seen for the first time, the callee_cache is added
421 // to the global array cc_array, callee_cache[0] is set to caller and
422 // callee_cache[1] is set to cache_size.
423 // Then we are trying to add callee to callee_cache [2,cache_size) if it is
424 // not there yet.
425 // If the cache is full we drop the callee (may want to fix this later).
IndirCall(uptr caller,uptr callee,uptr callee_cache[],uptr cache_size)426 void CoverageData::IndirCall(uptr caller, uptr callee, uptr callee_cache[],
427                              uptr cache_size) {
428   if (!cc_array) return;
429   atomic_uintptr_t *atomic_callee_cache =
430       reinterpret_cast<atomic_uintptr_t *>(callee_cache);
431   uptr zero = 0;
432   if (atomic_compare_exchange_strong(&atomic_callee_cache[0], &zero, caller,
433                                      memory_order_seq_cst)) {
434     uptr idx = atomic_fetch_add(&cc_array_index, 1, memory_order_relaxed);
435     CHECK_LT(idx * sizeof(uptr),
436              atomic_load(&cc_array_size, memory_order_acquire));
437     callee_cache[1] = cache_size;
438     cc_array[idx] = callee_cache;
439   }
440   CHECK_EQ(atomic_load(&atomic_callee_cache[0], memory_order_relaxed), caller);
441   for (uptr i = 2; i < cache_size; i++) {
442     uptr was = 0;
443     if (atomic_compare_exchange_strong(&atomic_callee_cache[i], &was, callee,
444                                        memory_order_seq_cst)) {
445       atomic_fetch_add(&caller_callee_counter, 1, memory_order_relaxed);
446       return;
447     }
448     if (was == callee)  // Already have this callee.
449       return;
450   }
451 }
452 
GetNumberOf8bitCounters()453 uptr CoverageData::GetNumberOf8bitCounters() {
454   return num_8bit_counters;
455 }
456 
457 // Map every 8bit counter to a 8-bit bitset and clear the counter.
Update8bitCounterBitsetAndClearCounters(u8 * bitset)458 uptr CoverageData::Update8bitCounterBitsetAndClearCounters(u8 *bitset) {
459   uptr num_new_bits = 0;
460   uptr cur = 0;
461   // For better speed we map 8 counters to 8 bytes of bitset at once.
462   static const uptr kBatchSize = 8;
463   CHECK_EQ(reinterpret_cast<uptr>(bitset) % kBatchSize, 0);
464   for (uptr i = 0, len = counters_vec.size(); i < len; i++) {
465     u8 *c = counters_vec[i].counters;
466     uptr n = counters_vec[i].n;
467     CHECK_EQ(n % 16, 0);
468     CHECK_EQ(cur % kBatchSize, 0);
469     CHECK_EQ(reinterpret_cast<uptr>(c) % kBatchSize, 0);
470     if (!bitset) {
471       internal_bzero_aligned16(c, n);
472       cur += n;
473       continue;
474     }
475     for (uptr j = 0; j < n; j += kBatchSize, cur += kBatchSize) {
476       CHECK_LT(cur, num_8bit_counters);
477       u64 *pc64 = reinterpret_cast<u64*>(c + j);
478       u64 *pb64 = reinterpret_cast<u64*>(bitset + cur);
479       u64 c64 = *pc64;
480       u64 old_bits_64 = *pb64;
481       u64 new_bits_64 = old_bits_64;
482       if (c64) {
483         *pc64 = 0;
484         for (uptr k = 0; k < kBatchSize; k++) {
485           u64 x = (c64 >> (8 * k)) & 0xff;
486           if (x) {
487             u64 bit = 0;
488             /**/ if (x >= 128) bit = 128;
489             else if (x >= 32) bit = 64;
490             else if (x >= 16) bit = 32;
491             else if (x >= 8) bit = 16;
492             else if (x >= 4) bit = 8;
493             else if (x >= 3) bit = 4;
494             else if (x >= 2) bit = 2;
495             else if (x >= 1) bit = 1;
496             u64 mask = bit << (8 * k);
497             if (!(new_bits_64 & mask)) {
498               num_new_bits++;
499               new_bits_64 |= mask;
500             }
501           }
502         }
503         *pb64 = new_bits_64;
504       }
505     }
506   }
507   CHECK_EQ(cur, num_8bit_counters);
508   return num_new_bits;
509 }
510 
data()511 uptr *CoverageData::data() {
512   return pc_array;
513 }
514 
size()515 uptr CoverageData::size() {
516   return atomic_load(&pc_array_index, memory_order_relaxed);
517 }
518 
519 // Block layout for packed file format: header, followed by module name (no
520 // trailing zero), followed by data blob.
521 struct CovHeader {
522   int pid;
523   unsigned int module_name_length;
524   unsigned int data_length;
525 };
526 
CovWritePacked(int pid,const char * module,const void * blob,unsigned int blob_size)527 static void CovWritePacked(int pid, const char *module, const void *blob,
528                            unsigned int blob_size) {
529   if (cov_fd == kInvalidFd) return;
530   unsigned module_name_length = internal_strlen(module);
531   CovHeader header = {pid, module_name_length, blob_size};
532 
533   if (cov_max_block_size == 0) {
534     // Writing to a file. Just go ahead.
535     WriteToFile(cov_fd, &header, sizeof(header));
536     WriteToFile(cov_fd, module, module_name_length);
537     WriteToFile(cov_fd, blob, blob_size);
538   } else {
539     // Writing to a socket. We want to split the data into appropriately sized
540     // blocks.
541     InternalScopedBuffer<char> block(cov_max_block_size);
542     CHECK_EQ((uptr)block.data(), (uptr)(CovHeader *)block.data());
543     uptr header_size_with_module = sizeof(header) + module_name_length;
544     CHECK_LT(header_size_with_module, cov_max_block_size);
545     unsigned int max_payload_size =
546         cov_max_block_size - header_size_with_module;
547     char *block_pos = block.data();
548     internal_memcpy(block_pos, &header, sizeof(header));
549     block_pos += sizeof(header);
550     internal_memcpy(block_pos, module, module_name_length);
551     block_pos += module_name_length;
552     char *block_data_begin = block_pos;
553     const char *blob_pos = (const char *)blob;
554     while (blob_size > 0) {
555       unsigned int payload_size = Min(blob_size, max_payload_size);
556       blob_size -= payload_size;
557       internal_memcpy(block_data_begin, blob_pos, payload_size);
558       blob_pos += payload_size;
559       ((CovHeader *)block.data())->data_length = payload_size;
560       WriteToFile(cov_fd, block.data(), header_size_with_module + payload_size);
561     }
562   }
563 }
564 
565 // If packed = false: <name>.<pid>.<sancov> (name = module name).
566 // If packed = true and name == 0: <pid>.<sancov>.<packed>.
567 // If packed = true and name != 0: <name>.<sancov>.<packed> (name is
568 // user-supplied).
CovOpenFile(InternalScopedString * path,bool packed,const char * name,const char * extension="sancov")569 static fd_t CovOpenFile(InternalScopedString *path, bool packed,
570                        const char *name, const char *extension = "sancov") {
571   path->clear();
572   if (!packed) {
573     CHECK(name);
574     path->append("%s/%s.%zd.%s", coverage_dir, name, internal_getpid(),
575                 extension);
576   } else {
577     if (!name)
578       path->append("%s/%zd.%s.packed", coverage_dir, internal_getpid(),
579                   extension);
580     else
581       path->append("%s/%s.%s.packed", coverage_dir, name, extension);
582   }
583   error_t err;
584   fd_t fd = OpenFile(path->data(), WrOnly, &err);
585   if (fd == kInvalidFd)
586     Report("SanitizerCoverage: failed to open %s for writing (reason: %d)\n",
587            path->data(), err);
588   return fd;
589 }
590 
591 // Dump trace PCs and trace events into two separate files.
DumpTrace()592 void CoverageData::DumpTrace() {
593   uptr max_idx = tr_event_pointer - tr_event_array;
594   if (!max_idx) return;
595   auto sym = Symbolizer::GetOrInit();
596   if (!sym)
597     return;
598   InternalScopedString out(32 << 20);
599   for (uptr i = 0, n = size(); i < n; i++) {
600     const char *module_name = "<unknown>";
601     uptr module_address = 0;
602     sym->GetModuleNameAndOffsetForPC(UnbundlePc(pc_array[i]), &module_name,
603                                      &module_address);
604     out.append("%s 0x%zx\n", module_name, module_address);
605   }
606   InternalScopedString path(kMaxPathLength);
607   fd_t fd = CovOpenFile(&path, false, "trace-points");
608   if (fd == kInvalidFd) return;
609   WriteToFile(fd, out.data(), out.length());
610   CloseFile(fd);
611 
612   fd = CovOpenFile(&path, false, "trace-compunits");
613   if (fd == kInvalidFd) return;
614   out.clear();
615   for (uptr i = 0; i < comp_unit_name_vec.size(); i++)
616     out.append("%s\n", comp_unit_name_vec[i].copied_module_name);
617   WriteToFile(fd, out.data(), out.length());
618   CloseFile(fd);
619 
620   fd = CovOpenFile(&path, false, "trace-events");
621   if (fd == kInvalidFd) return;
622   uptr bytes_to_write = max_idx * sizeof(tr_event_array[0]);
623   u8 *event_bytes = reinterpret_cast<u8*>(tr_event_array);
624   // The trace file could be huge, and may not be written with a single syscall.
625   while (bytes_to_write) {
626     uptr actually_written;
627     if (WriteToFile(fd, event_bytes, bytes_to_write, &actually_written) &&
628         actually_written <= bytes_to_write) {
629       bytes_to_write -= actually_written;
630       event_bytes += actually_written;
631     } else {
632       break;
633     }
634   }
635   CloseFile(fd);
636   VReport(1, " CovDump: Trace: %zd PCs written\n", size());
637   VReport(1, " CovDump: Trace: %zd Events written\n", max_idx);
638 }
639 
640 // This function dumps the caller=>callee pairs into a file as a sequence of
641 // lines like "module_name offset".
DumpCallerCalleePairs()642 void CoverageData::DumpCallerCalleePairs() {
643   uptr max_idx = atomic_load(&cc_array_index, memory_order_relaxed);
644   if (!max_idx) return;
645   auto sym = Symbolizer::GetOrInit();
646   if (!sym)
647     return;
648   InternalScopedString out(32 << 20);
649   uptr total = 0;
650   for (uptr i = 0; i < max_idx; i++) {
651     uptr *cc_cache = cc_array[i];
652     CHECK(cc_cache);
653     uptr caller = cc_cache[0];
654     uptr n_callees = cc_cache[1];
655     const char *caller_module_name = "<unknown>";
656     uptr caller_module_address = 0;
657     sym->GetModuleNameAndOffsetForPC(caller, &caller_module_name,
658                                      &caller_module_address);
659     for (uptr j = 2; j < n_callees; j++) {
660       uptr callee = cc_cache[j];
661       if (!callee) break;
662       total++;
663       const char *callee_module_name = "<unknown>";
664       uptr callee_module_address = 0;
665       sym->GetModuleNameAndOffsetForPC(callee, &callee_module_name,
666                                        &callee_module_address);
667       out.append("%s 0x%zx\n%s 0x%zx\n", caller_module_name,
668                  caller_module_address, callee_module_name,
669                  callee_module_address);
670     }
671   }
672   InternalScopedString path(kMaxPathLength);
673   fd_t fd = CovOpenFile(&path, false, "caller-callee");
674   if (fd == kInvalidFd) return;
675   WriteToFile(fd, out.data(), out.length());
676   CloseFile(fd);
677   VReport(1, " CovDump: %zd caller-callee pairs written\n", total);
678 }
679 
680 // Record the current PC into the event buffer.
681 // Every event is a u32 value (index in tr_pc_array_index) so we compute
682 // it once and then cache in the provided 'cache' storage.
683 //
684 // This function will eventually be inlined by the compiler.
TraceBasicBlock(u32 * id)685 void CoverageData::TraceBasicBlock(u32 *id) {
686   // Will trap here if
687   //  1. coverage is not enabled at run-time.
688   //  2. The array tr_event_array is full.
689   *tr_event_pointer = *id - 1;
690   tr_event_pointer++;
691 }
692 
DumpCounters()693 void CoverageData::DumpCounters() {
694   if (!common_flags()->coverage_counters) return;
695   uptr n = coverage_data.GetNumberOf8bitCounters();
696   if (!n) return;
697   InternalScopedBuffer<u8> bitset(n);
698   coverage_data.Update8bitCounterBitsetAndClearCounters(bitset.data());
699   InternalScopedString path(kMaxPathLength);
700 
701   for (uptr m = 0; m < module_name_vec.size(); m++) {
702     auto r = module_name_vec[m];
703     CHECK(r.copied_module_name);
704     CHECK_LE(r.beg, r.end);
705     CHECK_LE(r.end, size());
706     const char *base_name = StripModuleName(r.copied_module_name);
707     fd_t fd =
708         CovOpenFile(&path, /* packed */ false, base_name, "counters-sancov");
709     if (fd == kInvalidFd) return;
710     WriteToFile(fd, bitset.data() + r.beg, r.end - r.beg);
711     CloseFile(fd);
712     VReport(1, " CovDump: %zd counters written for '%s'\n", r.end - r.beg,
713             base_name);
714   }
715 }
716 
DumpAsBitSet()717 void CoverageData::DumpAsBitSet() {
718   if (!common_flags()->coverage_bitset) return;
719   if (!size()) return;
720   InternalScopedBuffer<char> out(size());
721   InternalScopedString path(kMaxPathLength);
722   for (uptr m = 0; m < module_name_vec.size(); m++) {
723     uptr n_set_bits = 0;
724     auto r = module_name_vec[m];
725     CHECK(r.copied_module_name);
726     CHECK_LE(r.beg, r.end);
727     CHECK_LE(r.end, size());
728     for (uptr i = r.beg; i < r.end; i++) {
729       uptr pc = UnbundlePc(pc_array[i]);
730       out[i] = pc ? '1' : '0';
731       if (pc)
732         n_set_bits++;
733     }
734     const char *base_name = StripModuleName(r.copied_module_name);
735     fd_t fd = CovOpenFile(&path, /* packed */false, base_name, "bitset-sancov");
736     if (fd == kInvalidFd) return;
737     WriteToFile(fd, out.data() + r.beg, r.end - r.beg);
738     CloseFile(fd);
739     VReport(1,
740             " CovDump: bitset of %zd bits written for '%s', %zd bits are set\n",
741             r.end - r.beg, base_name, n_set_bits);
742   }
743 }
744 
DumpOffsets()745 void CoverageData::DumpOffsets() {
746   auto sym = Symbolizer::GetOrInit();
747   if (!common_flags()->coverage_pcs) return;
748   CHECK_NE(sym, nullptr);
749   InternalMmapVector<uptr> offsets(0);
750   InternalScopedString path(kMaxPathLength);
751   for (uptr m = 0; m < module_name_vec.size(); m++) {
752     offsets.clear();
753     uptr num_words_for_magic = SANITIZER_WORDSIZE == 64 ? 1 : 2;
754     for (uptr i = 0; i < num_words_for_magic; i++)
755       offsets.push_back(0);
756     auto r = module_name_vec[m];
757     CHECK(r.copied_module_name);
758     CHECK_LE(r.beg, r.end);
759     CHECK_LE(r.end, size());
760     for (uptr i = r.beg; i < r.end; i++) {
761       uptr pc = UnbundlePc(pc_array[i]);
762       uptr counter = UnbundleCounter(pc_array[i]);
763       if (!pc) continue; // Not visited.
764       uptr offset = 0;
765       sym->GetModuleNameAndOffsetForPC(pc, nullptr, &offset);
766       offsets.push_back(BundlePcAndCounter(offset, counter));
767     }
768 
769     CHECK_GE(offsets.size(), num_words_for_magic);
770     SortArray(offsets.data(), offsets.size());
771     for (uptr i = 0; i < offsets.size(); i++)
772       offsets[i] = UnbundlePc(offsets[i]);
773 
774     uptr num_offsets = offsets.size() - num_words_for_magic;
775     u64 *magic_p = reinterpret_cast<u64*>(offsets.data());
776     CHECK_EQ(*magic_p, 0ULL);
777     // FIXME: we may want to write 32-bit offsets even in 64-mode
778     // if all the offsets are small enough.
779     *magic_p = SANITIZER_WORDSIZE == 64 ? kMagic64 : kMagic32;
780 
781     const char *module_name = StripModuleName(r.copied_module_name);
782     if (cov_sandboxed) {
783       if (cov_fd != kInvalidFd) {
784         CovWritePacked(internal_getpid(), module_name, offsets.data(),
785                        offsets.size() * sizeof(offsets[0]));
786         VReport(1, " CovDump: %zd PCs written to packed file\n", num_offsets);
787       }
788     } else {
789       // One file per module per process.
790       fd_t fd = CovOpenFile(&path, false /* packed */, module_name);
791       if (fd == kInvalidFd) continue;
792       WriteToFile(fd, offsets.data(), offsets.size() * sizeof(offsets[0]));
793       CloseFile(fd);
794       VReport(1, " CovDump: %s: %zd PCs written\n", path.data(), num_offsets);
795     }
796   }
797   if (cov_fd != kInvalidFd)
798     CloseFile(cov_fd);
799 }
800 
DumpAll()801 void CoverageData::DumpAll() {
802   if (!coverage_enabled || common_flags()->coverage_direct) return;
803   if (atomic_fetch_add(&dump_once_guard, 1, memory_order_relaxed))
804     return;
805   DumpAsBitSet();
806   DumpCounters();
807   DumpTrace();
808   DumpOffsets();
809   DumpCallerCalleePairs();
810 }
811 
CovPrepareForSandboxing(__sanitizer_sandbox_arguments * args)812 void CovPrepareForSandboxing(__sanitizer_sandbox_arguments *args) {
813   if (!args) return;
814   if (!coverage_enabled) return;
815   cov_sandboxed = args->coverage_sandboxed;
816   if (!cov_sandboxed) return;
817   cov_max_block_size = args->coverage_max_block_size;
818   if (args->coverage_fd >= 0) {
819     cov_fd = (fd_t)args->coverage_fd;
820   } else {
821     InternalScopedString path(kMaxPathLength);
822     // Pre-open the file now. The sandbox won't allow us to do it later.
823     cov_fd = CovOpenFile(&path, true /* packed */, nullptr);
824   }
825 }
826 
MaybeOpenCovFile(const char * name)827 fd_t MaybeOpenCovFile(const char *name) {
828   CHECK(name);
829   if (!coverage_enabled) return kInvalidFd;
830   InternalScopedString path(kMaxPathLength);
831   return CovOpenFile(&path, true /* packed */, name);
832 }
833 
CovBeforeFork()834 void CovBeforeFork() {
835   coverage_data.BeforeFork();
836 }
837 
CovAfterFork(int child_pid)838 void CovAfterFork(int child_pid) {
839   coverage_data.AfterFork(child_pid);
840 }
841 
MaybeDumpCoverage()842 static void MaybeDumpCoverage() {
843   if (common_flags()->coverage)
844     __sanitizer_cov_dump();
845 }
846 
InitializeCoverage(bool enabled,const char * dir)847 void InitializeCoverage(bool enabled, const char *dir) {
848   if (coverage_enabled)
849     return;  // May happen if two sanitizer enable coverage in the same process.
850   coverage_enabled = enabled;
851   coverage_dir = dir;
852   coverage_data.Init();
853   if (enabled) coverage_data.Enable();
854   if (!common_flags()->coverage_direct) Atexit(__sanitizer_cov_dump);
855   AddDieCallback(MaybeDumpCoverage);
856 }
857 
ReInitializeCoverage(bool enabled,const char * dir)858 void ReInitializeCoverage(bool enabled, const char *dir) {
859   coverage_enabled = enabled;
860   coverage_dir = dir;
861   coverage_data.ReInit();
862 }
863 
CoverageUpdateMapping()864 void CoverageUpdateMapping() {
865   if (coverage_enabled)
866     CovUpdateMapping(coverage_dir);
867 }
868 
869 } // namespace __sanitizer
870 
871 extern "C" {
__sanitizer_cov(u32 * guard)872 SANITIZER_INTERFACE_ATTRIBUTE void __sanitizer_cov(u32 *guard) {
873   coverage_data.Add(StackTrace::GetPreviousInstructionPc(GET_CALLER_PC()),
874                     guard);
875 }
__sanitizer_cov_with_check(u32 * guard)876 SANITIZER_INTERFACE_ATTRIBUTE void __sanitizer_cov_with_check(u32 *guard) {
877   atomic_uint32_t *atomic_guard = reinterpret_cast<atomic_uint32_t*>(guard);
878   if (static_cast<s32>(
879           __sanitizer::atomic_load(atomic_guard, memory_order_relaxed)) < 0)
880     __sanitizer_cov(guard);
881 }
882 SANITIZER_INTERFACE_ATTRIBUTE void
__sanitizer_cov_indir_call16(uptr callee,uptr callee_cache16[])883 __sanitizer_cov_indir_call16(uptr callee, uptr callee_cache16[]) {
884   coverage_data.IndirCall(StackTrace::GetPreviousInstructionPc(GET_CALLER_PC()),
885                           callee, callee_cache16, 16);
886 }
__sanitizer_cov_init()887 SANITIZER_INTERFACE_ATTRIBUTE void __sanitizer_cov_init() {
888   coverage_enabled = true;
889   coverage_dir = common_flags()->coverage_dir;
890   coverage_data.Init();
891 }
__sanitizer_cov_dump()892 SANITIZER_INTERFACE_ATTRIBUTE void __sanitizer_cov_dump() {
893   coverage_data.DumpAll();
894 }
895 SANITIZER_INTERFACE_ATTRIBUTE void
__sanitizer_cov_module_init(s32 * guards,uptr npcs,u8 * counters,const char * comp_unit_name)896 __sanitizer_cov_module_init(s32 *guards, uptr npcs, u8 *counters,
897                             const char *comp_unit_name) {
898   coverage_data.InitializeGuards(guards, npcs, comp_unit_name, GET_CALLER_PC());
899   coverage_data.InitializeCounters(counters, npcs);
900   if (!common_flags()->coverage_direct) return;
901   if (SANITIZER_ANDROID && coverage_enabled) {
902     // dlopen/dlclose interceptors do not work on Android, so we rely on
903     // Extend() calls to update .sancov.map.
904     CovUpdateMapping(coverage_dir, GET_CALLER_PC());
905   }
906   coverage_data.Extend(npcs);
907 }
908 SANITIZER_INTERFACE_ATTRIBUTE
__sanitizer_maybe_open_cov_file(const char * name)909 sptr __sanitizer_maybe_open_cov_file(const char *name) {
910   return (sptr)MaybeOpenCovFile(name);
911 }
912 SANITIZER_INTERFACE_ATTRIBUTE
__sanitizer_get_total_unique_coverage()913 uptr __sanitizer_get_total_unique_coverage() {
914   return atomic_load(&coverage_counter, memory_order_relaxed);
915 }
916 
917 SANITIZER_INTERFACE_ATTRIBUTE
__sanitizer_get_total_unique_caller_callee_pairs()918 uptr __sanitizer_get_total_unique_caller_callee_pairs() {
919   return atomic_load(&caller_callee_counter, memory_order_relaxed);
920 }
921 
922 SANITIZER_INTERFACE_ATTRIBUTE
__sanitizer_cov_trace_func_enter(u32 * id)923 void __sanitizer_cov_trace_func_enter(u32 *id) {
924   __sanitizer_cov_with_check(id);
925   coverage_data.TraceBasicBlock(id);
926 }
927 SANITIZER_INTERFACE_ATTRIBUTE
__sanitizer_cov_trace_basic_block(u32 * id)928 void __sanitizer_cov_trace_basic_block(u32 *id) {
929   __sanitizer_cov_with_check(id);
930   coverage_data.TraceBasicBlock(id);
931 }
932 SANITIZER_INTERFACE_ATTRIBUTE
__sanitizer_reset_coverage()933 void __sanitizer_reset_coverage() {
934   ResetGlobalCounters();
935   coverage_data.ReinitializeGuards();
936   internal_bzero_aligned16(
937       coverage_data.data(),
938       RoundUpTo(coverage_data.size() * sizeof(coverage_data.data()[0]), 16));
939 }
940 SANITIZER_INTERFACE_ATTRIBUTE
__sanitizer_get_coverage_guards(uptr ** data)941 uptr __sanitizer_get_coverage_guards(uptr **data) {
942   *data = coverage_data.data();
943   return coverage_data.size();
944 }
945 
946 SANITIZER_INTERFACE_ATTRIBUTE
__sanitizer_get_number_of_counters()947 uptr __sanitizer_get_number_of_counters() {
948   return coverage_data.GetNumberOf8bitCounters();
949 }
950 
951 SANITIZER_INTERFACE_ATTRIBUTE
__sanitizer_update_counter_bitset_and_clear_counters(u8 * bitset)952 uptr __sanitizer_update_counter_bitset_and_clear_counters(u8 *bitset) {
953   return coverage_data.Update8bitCounterBitsetAndClearCounters(bitset);
954 }
955 // Default empty implementations (weak). Users should redefine them.
956 SANITIZER_INTERFACE_ATTRIBUTE SANITIZER_WEAK_ATTRIBUTE
__sanitizer_cov_trace_cmp()957 void __sanitizer_cov_trace_cmp() {}
958 SANITIZER_INTERFACE_ATTRIBUTE SANITIZER_WEAK_ATTRIBUTE
__sanitizer_cov_trace_switch()959 void __sanitizer_cov_trace_switch() {}
960 } // extern "C"
961