1 /*
2  * Copyright (C) 2008 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 #include "mem_map.h"
18 
19 #include <inttypes.h>
20 #include <stdlib.h>
21 #if !defined(ANDROID_OS) && !defined(__Fuchsia__) && !defined(_WIN32)
22 #include <sys/resource.h>
23 #endif
24 
25 #if defined(__linux__)
26 #include <sys/prctl.h>
27 #endif
28 
29 #include <map>
30 #include <memory>
31 #include <sstream>
32 
33 #include "android-base/stringprintf.h"
34 #include "android-base/unique_fd.h"
35 
36 #include "allocator.h"
37 #include "bit_utils.h"
38 #include "globals.h"
39 #include "logging.h"  // For VLOG_IS_ON.
40 #include "memory_tool.h"
41 #include "mman.h"  // For the PROT_* and MAP_* constants.
42 #include "utils.h"
43 
44 #ifndef MAP_ANONYMOUS
45 #define MAP_ANONYMOUS MAP_ANON
46 #endif
47 
48 namespace art {
49 
50 using android::base::StringPrintf;
51 using android::base::unique_fd;
52 
53 template<class Key, class T, AllocatorTag kTag, class Compare = std::less<Key>>
54 using AllocationTrackingMultiMap =
55     std::multimap<Key, T, Compare, TrackingAllocator<std::pair<const Key, T>, kTag>>;
56 
57 using Maps = AllocationTrackingMultiMap<void*, MemMap*, kAllocatorTagMaps>;
58 
59 // All the non-empty MemMaps. Use a multimap as we do a reserve-and-divide (eg ElfMap::Load()).
60 static Maps* gMaps GUARDED_BY(MemMap::GetMemMapsLock()) = nullptr;
61 
62 // A map containing unique strings used for indentifying anonymous mappings
63 static std::map<std::string, int> debugStrMap GUARDED_BY(MemMap::GetMemMapsLock());
64 
65 // Retrieve iterator to a `gMaps` entry that is known to exist.
GetGMapsEntry(const MemMap & map)66 Maps::iterator GetGMapsEntry(const MemMap& map) REQUIRES(MemMap::GetMemMapsLock()) {
67   DCHECK(map.IsValid());
68   DCHECK(gMaps != nullptr);
69   for (auto it = gMaps->lower_bound(map.BaseBegin()), end = gMaps->end();
70        it != end && it->first == map.BaseBegin();
71        ++it) {
72     if (it->second == &map) {
73       return it;
74     }
75   }
76   LOG(FATAL) << "MemMap not found";
77   UNREACHABLE();
78 }
79 
operator <<(std::ostream & os,const Maps & mem_maps)80 std::ostream& operator<<(std::ostream& os, const Maps& mem_maps) {
81   os << "MemMap:" << std::endl;
82   for (auto it = mem_maps.begin(); it != mem_maps.end(); ++it) {
83     void* base = it->first;
84     MemMap* map = it->second;
85     CHECK_EQ(base, map->BaseBegin());
86     os << *map << std::endl;
87   }
88   return os;
89 }
90 
91 std::mutex* MemMap::mem_maps_lock_ = nullptr;
92 
93 #if USE_ART_LOW_4G_ALLOCATOR
94 // Handling mem_map in 32b address range for 64b architectures that do not support MAP_32BIT.
95 
96 // The regular start of memory allocations. The first 64KB is protected by SELinux.
97 static constexpr uintptr_t LOW_MEM_START = 64 * KB;
98 
99 // Generate random starting position.
100 // To not interfere with image position, take the image's address and only place it below. Current
101 // formula (sketch):
102 //
103 // ART_BASE_ADDR      = 0001XXXXXXXXXXXXXXX
104 // ----------------------------------------
105 //                    = 0000111111111111111
106 // & ~(kPageSize - 1) =~0000000000000001111
107 // ----------------------------------------
108 // mask               = 0000111111111110000
109 // & random data      = YYYYYYYYYYYYYYYYYYY
110 // -----------------------------------
111 // tmp                = 0000YYYYYYYYYYY0000
112 // + LOW_MEM_START    = 0000000000001000000
113 // --------------------------------------
114 // start
115 //
116 // arc4random as an entropy source is exposed in Bionic, but not in glibc. When we
117 // do not have Bionic, simply start with LOW_MEM_START.
118 
119 // Function is standalone so it can be tested somewhat in mem_map_test.cc.
120 #ifdef __BIONIC__
CreateStartPos(uint64_t input)121 uintptr_t CreateStartPos(uint64_t input) {
122   CHECK_NE(0, ART_BASE_ADDRESS);
123 
124   // Start with all bits below highest bit in ART_BASE_ADDRESS.
125   constexpr size_t leading_zeros = CLZ(static_cast<uint32_t>(ART_BASE_ADDRESS));
126   constexpr uintptr_t mask_ones = (1 << (31 - leading_zeros)) - 1;
127 
128   // Lowest (usually 12) bits are not used, as aligned by page size.
129   constexpr uintptr_t mask = mask_ones & ~(kPageSize - 1);
130 
131   // Mask input data.
132   return (input & mask) + LOW_MEM_START;
133 }
134 #endif
135 
GenerateNextMemPos()136 static uintptr_t GenerateNextMemPos() {
137 #ifdef __BIONIC__
138   uint64_t random_data;
139   arc4random_buf(&random_data, sizeof(random_data));
140   return CreateStartPos(random_data);
141 #else
142   // No arc4random on host, see above.
143   return LOW_MEM_START;
144 #endif
145 }
146 
147 // Initialize linear scan to random position.
148 uintptr_t MemMap::next_mem_pos_ = GenerateNextMemPos();
149 #endif
150 
151 // Return true if the address range is contained in a single memory map by either reading
152 // the gMaps variable or the /proc/self/map entry.
ContainedWithinExistingMap(uint8_t * ptr,size_t size,std::string * error_msg)153 bool MemMap::ContainedWithinExistingMap(uint8_t* ptr, size_t size, std::string* error_msg) {
154   uintptr_t begin = reinterpret_cast<uintptr_t>(ptr);
155   uintptr_t end = begin + size;
156 
157   {
158     std::lock_guard<std::mutex> mu(*mem_maps_lock_);
159     for (auto& pair : *gMaps) {
160       MemMap* const map = pair.second;
161       if (begin >= reinterpret_cast<uintptr_t>(map->Begin()) &&
162           end <= reinterpret_cast<uintptr_t>(map->End())) {
163         return true;
164       }
165     }
166   }
167 
168   if (error_msg != nullptr) {
169     PrintFileToLog("/proc/self/maps", LogSeverity::ERROR);
170     *error_msg = StringPrintf("Requested region 0x%08" PRIxPTR "-0x%08" PRIxPTR " does not overlap "
171                               "any existing map. See process maps in the log.", begin, end);
172   }
173   return false;
174 }
175 
176 // CheckMapRequest to validate a non-MAP_FAILED mmap result based on
177 // the expected value, calling munmap if validation fails, giving the
178 // reason in error_msg.
179 //
180 // If the expected_ptr is null, nothing is checked beyond the fact
181 // that the actual_ptr is not MAP_FAILED. However, if expected_ptr is
182 // non-null, we check that pointer is the actual_ptr == expected_ptr,
183 // and if not, report in error_msg what the conflict mapping was if
184 // found, or a generic error in other cases.
CheckMapRequest(uint8_t * expected_ptr,void * actual_ptr,size_t byte_count,std::string * error_msg)185 bool MemMap::CheckMapRequest(uint8_t* expected_ptr, void* actual_ptr, size_t byte_count,
186                             std::string* error_msg) {
187   // Handled first by caller for more specific error messages.
188   CHECK(actual_ptr != MAP_FAILED);
189 
190   if (expected_ptr == nullptr) {
191     return true;
192   }
193 
194   uintptr_t actual = reinterpret_cast<uintptr_t>(actual_ptr);
195   uintptr_t expected = reinterpret_cast<uintptr_t>(expected_ptr);
196 
197   if (expected_ptr == actual_ptr) {
198     return true;
199   }
200 
201   // We asked for an address but didn't get what we wanted, all paths below here should fail.
202   int result = TargetMUnmap(actual_ptr, byte_count);
203   if (result == -1) {
204     PLOG(WARNING) << StringPrintf("munmap(%p, %zd) failed", actual_ptr, byte_count);
205   }
206 
207   if (error_msg != nullptr) {
208     // We call this here so that we can try and generate a full error
209     // message with the overlapping mapping. There's no guarantee that
210     // that there will be an overlap though, since
211     // - The kernel is not *required* to honor expected_ptr unless MAP_FIXED is
212     //   true, even if there is no overlap
213     // - There might have been an overlap at the point of mmap, but the
214     //   overlapping region has since been unmapped.
215 
216     // Tell the client the mappings that were in place at the time.
217     if (kIsDebugBuild) {
218       PrintFileToLog("/proc/self/maps", LogSeverity::WARNING);
219     }
220 
221     std::ostringstream os;
222     os <<  StringPrintf("Failed to mmap at expected address, mapped at "
223                         "0x%08" PRIxPTR " instead of 0x%08" PRIxPTR,
224                         actual, expected);
225     *error_msg = os.str();
226   }
227   return false;
228 }
229 
CheckReservation(uint8_t * expected_ptr,size_t byte_count,const char * name,const MemMap & reservation,std::string * error_msg)230 bool MemMap::CheckReservation(uint8_t* expected_ptr,
231                               size_t byte_count,
232                               const char* name,
233                               const MemMap& reservation,
234                               /*out*/std::string* error_msg) {
235   if (!reservation.IsValid()) {
236     *error_msg = StringPrintf("Invalid reservation for %s", name);
237     return false;
238   }
239   DCHECK_ALIGNED(reservation.Begin(), kPageSize);
240   if (reservation.Begin() != expected_ptr) {
241     *error_msg = StringPrintf("Bad image reservation start for %s: %p instead of %p",
242                               name,
243                               reservation.Begin(),
244                               expected_ptr);
245     return false;
246   }
247   if (byte_count > reservation.Size()) {
248     *error_msg = StringPrintf("Insufficient reservation, required %zu, available %zu",
249                               byte_count,
250                               reservation.Size());
251     return false;
252   }
253   return true;
254 }
255 
256 
257 #if USE_ART_LOW_4G_ALLOCATOR
TryMemMapLow4GB(void * ptr,size_t page_aligned_byte_count,int prot,int flags,int fd,off_t offset)258 void* MemMap::TryMemMapLow4GB(void* ptr,
259                                     size_t page_aligned_byte_count,
260                                     int prot,
261                                     int flags,
262                                     int fd,
263                                     off_t offset) {
264   void* actual = TargetMMap(ptr, page_aligned_byte_count, prot, flags, fd, offset);
265   if (actual != MAP_FAILED) {
266     // Since we didn't use MAP_FIXED the kernel may have mapped it somewhere not in the low
267     // 4GB. If this is the case, unmap and retry.
268     if (reinterpret_cast<uintptr_t>(actual) + page_aligned_byte_count >= 4 * GB) {
269       TargetMUnmap(actual, page_aligned_byte_count);
270       actual = MAP_FAILED;
271     }
272   }
273   return actual;
274 }
275 #endif
276 
SetDebugName(void * map_ptr,const char * name,size_t size)277 void MemMap::SetDebugName(void* map_ptr, const char* name, size_t size) {
278   // Debug naming is only used for Android target builds. For Linux targets,
279   // we'll still call prctl but it wont do anything till we upstream the prctl.
280   if (kIsTargetFuchsia || !kIsTargetBuild) {
281     return;
282   }
283 
284   // lock as std::map is not thread-safe
285   std::lock_guard<std::mutex> mu(*mem_maps_lock_);
286 
287   std::string debug_friendly_name("dalvik-");
288   debug_friendly_name += name;
289   auto it = debugStrMap.find(debug_friendly_name);
290 
291   if (it == debugStrMap.end()) {
292     it = debugStrMap.insert(std::make_pair(std::move(debug_friendly_name), 1)).first;
293   }
294 
295   DCHECK(it != debugStrMap.end());
296 #if defined(PR_SET_VMA) && defined(__linux__)
297   prctl(PR_SET_VMA, PR_SET_VMA_ANON_NAME, map_ptr, size, it->first.c_str());
298 #else
299   // Prevent variable unused compiler errors.
300   UNUSED(map_ptr, size);
301 #endif
302 }
303 
MapAnonymous(const char * name,uint8_t * addr,size_t byte_count,int prot,bool low_4gb,bool reuse,MemMap * reservation,std::string * error_msg,bool use_debug_name)304 MemMap MemMap::MapAnonymous(const char* name,
305                             uint8_t* addr,
306                             size_t byte_count,
307                             int prot,
308                             bool low_4gb,
309                             bool reuse,
310                             /*inout*/MemMap* reservation,
311                             /*out*/std::string* error_msg,
312                             bool use_debug_name) {
313 #ifndef __LP64__
314   UNUSED(low_4gb);
315 #endif
316   if (byte_count == 0) {
317     *error_msg = "Empty MemMap requested.";
318     return Invalid();
319   }
320   size_t page_aligned_byte_count = RoundUp(byte_count, kPageSize);
321 
322   int flags = MAP_PRIVATE | MAP_ANONYMOUS;
323   if (reuse) {
324     // reuse means it is okay that it overlaps an existing page mapping.
325     // Only use this if you actually made the page reservation yourself.
326     CHECK(addr != nullptr);
327     DCHECK(reservation == nullptr);
328 
329     DCHECK(ContainedWithinExistingMap(addr, byte_count, error_msg)) << *error_msg;
330     flags |= MAP_FIXED;
331   } else if (reservation != nullptr) {
332     CHECK(addr != nullptr);
333     if (!CheckReservation(addr, byte_count, name, *reservation, error_msg)) {
334       return MemMap::Invalid();
335     }
336     flags |= MAP_FIXED;
337   }
338 
339   unique_fd fd;
340 
341   // We need to store and potentially set an error number for pretty printing of errors
342   int saved_errno = 0;
343 
344   void* actual = MapInternal(addr,
345                              page_aligned_byte_count,
346                              prot,
347                              flags,
348                              fd.get(),
349                              0,
350                              low_4gb);
351   saved_errno = errno;
352 
353   if (actual == MAP_FAILED) {
354     if (error_msg != nullptr) {
355       if (kIsDebugBuild || VLOG_IS_ON(oat)) {
356         PrintFileToLog("/proc/self/maps", LogSeverity::WARNING);
357       }
358 
359       *error_msg = StringPrintf("Failed anonymous mmap(%p, %zd, 0x%x, 0x%x, %d, 0): %s. "
360                                     "See process maps in the log.",
361                                 addr,
362                                 page_aligned_byte_count,
363                                 prot,
364                                 flags,
365                                 fd.get(),
366                                 strerror(saved_errno));
367     }
368     return Invalid();
369   }
370   if (!CheckMapRequest(addr, actual, page_aligned_byte_count, error_msg)) {
371     return Invalid();
372   }
373 
374   if (use_debug_name) {
375     SetDebugName(actual, name, page_aligned_byte_count);
376   }
377 
378   if (reservation != nullptr) {
379     // Re-mapping was successful, transfer the ownership of the memory to the new MemMap.
380     DCHECK_EQ(actual, reservation->Begin());
381     reservation->ReleaseReservedMemory(byte_count);
382   }
383   return MemMap(name,
384                 reinterpret_cast<uint8_t*>(actual),
385                 byte_count,
386                 actual,
387                 page_aligned_byte_count,
388                 prot,
389                 reuse);
390 }
391 
MapDummy(const char * name,uint8_t * addr,size_t byte_count)392 MemMap MemMap::MapDummy(const char* name, uint8_t* addr, size_t byte_count) {
393   if (byte_count == 0) {
394     return Invalid();
395   }
396   const size_t page_aligned_byte_count = RoundUp(byte_count, kPageSize);
397   return MemMap(name, addr, byte_count, addr, page_aligned_byte_count, 0, /* reuse= */ true);
398 }
399 
400 template<typename A, typename B>
PointerDiff(A * a,B * b)401 static ptrdiff_t PointerDiff(A* a, B* b) {
402   return static_cast<ptrdiff_t>(reinterpret_cast<intptr_t>(a) - reinterpret_cast<intptr_t>(b));
403 }
404 
ReplaceWith(MemMap * source,std::string * error)405 bool MemMap::ReplaceWith(MemMap* source, /*out*/std::string* error) {
406 #if !HAVE_MREMAP_SYSCALL
407   UNUSED(source);
408   *error = "Cannot perform atomic replace because we are missing the required mremap syscall";
409   return false;
410 #else  // !HAVE_MREMAP_SYSCALL
411   CHECK(source != nullptr);
412   CHECK(source->IsValid());
413   if (!MemMap::kCanReplaceMapping) {
414     *error = "Unable to perform atomic replace due to runtime environment!";
415     return false;
416   }
417   // neither can be reuse.
418   if (source->reuse_ || reuse_) {
419     *error = "One or both mappings is not a real mmap!";
420     return false;
421   }
422   // TODO Support redzones.
423   if (source->redzone_size_ != 0 || redzone_size_ != 0) {
424     *error = "source and dest have different redzone sizes";
425     return false;
426   }
427   // Make sure they have the same offset from the actual mmap'd address
428   if (PointerDiff(BaseBegin(), Begin()) != PointerDiff(source->BaseBegin(), source->Begin())) {
429     *error =
430         "source starts at a different offset from the mmap. Cannot atomically replace mappings";
431     return false;
432   }
433   // mremap doesn't allow the final [start, end] to overlap with the initial [start, end] (it's like
434   // memcpy but the check is explicit and actually done).
435   if (source->BaseBegin() > BaseBegin() &&
436       reinterpret_cast<uint8_t*>(BaseBegin()) + source->BaseSize() >
437       reinterpret_cast<uint8_t*>(source->BaseBegin())) {
438     *error = "destination memory pages overlap with source memory pages";
439     return false;
440   }
441   // Change the protection to match the new location.
442   int old_prot = source->GetProtect();
443   if (!source->Protect(GetProtect())) {
444     *error = "Could not change protections for source to those required for dest.";
445     return false;
446   }
447 
448   // Do the mremap.
449   void* res = mremap(/*old_address*/source->BaseBegin(),
450                      /*old_size*/source->BaseSize(),
451                      /*new_size*/source->BaseSize(),
452                      /*flags*/MREMAP_MAYMOVE | MREMAP_FIXED,
453                      /*new_address*/BaseBegin());
454   if (res == MAP_FAILED) {
455     int saved_errno = errno;
456     // Wasn't able to move mapping. Change the protection of source back to the original one and
457     // return.
458     source->Protect(old_prot);
459     *error = std::string("Failed to mremap source to dest. Error was ") + strerror(saved_errno);
460     return false;
461   }
462   CHECK(res == BaseBegin());
463 
464   // The new base_size is all the pages of the 'source' plus any remaining dest pages. We will unmap
465   // them later.
466   size_t new_base_size = std::max(source->base_size_, base_size_);
467 
468   // Invalidate *source, don't unmap it though since it is already gone.
469   size_t source_size = source->size_;
470   source->Invalidate();
471 
472   size_ = source_size;
473   base_size_ = new_base_size;
474   // Reduce base_size if needed (this will unmap the extra pages).
475   SetSize(source_size);
476 
477   return true;
478 #endif  // !HAVE_MREMAP_SYSCALL
479 }
480 
MapFileAtAddress(uint8_t * expected_ptr,size_t byte_count,int prot,int flags,int fd,off_t start,bool low_4gb,const char * filename,bool reuse,MemMap * reservation,std::string * error_msg)481 MemMap MemMap::MapFileAtAddress(uint8_t* expected_ptr,
482                                 size_t byte_count,
483                                 int prot,
484                                 int flags,
485                                 int fd,
486                                 off_t start,
487                                 bool low_4gb,
488                                 const char* filename,
489                                 bool reuse,
490                                 /*inout*/MemMap* reservation,
491                                 /*out*/std::string* error_msg) {
492   CHECK_NE(0, prot);
493   CHECK_NE(0, flags & (MAP_SHARED | MAP_PRIVATE));
494 
495   // Note that we do not allow MAP_FIXED unless reuse == true or we have an existing
496   // reservation, i.e we expect this mapping to be contained within an existing map.
497   if (reuse) {
498     // reuse means it is okay that it overlaps an existing page mapping.
499     // Only use this if you actually made the page reservation yourself.
500     CHECK(expected_ptr != nullptr);
501     DCHECK(reservation == nullptr);
502     DCHECK(error_msg != nullptr);
503     DCHECK(ContainedWithinExistingMap(expected_ptr, byte_count, error_msg))
504         << ((error_msg != nullptr) ? *error_msg : std::string());
505     flags |= MAP_FIXED;
506   } else if (reservation != nullptr) {
507     DCHECK(error_msg != nullptr);
508     if (!CheckReservation(expected_ptr, byte_count, filename, *reservation, error_msg)) {
509       return Invalid();
510     }
511     flags |= MAP_FIXED;
512   } else {
513     CHECK_EQ(0, flags & MAP_FIXED);
514     // Don't bother checking for an overlapping region here. We'll
515     // check this if required after the fact inside CheckMapRequest.
516   }
517 
518   if (byte_count == 0) {
519     *error_msg = "Empty MemMap requested";
520     return Invalid();
521   }
522   // Adjust 'offset' to be page-aligned as required by mmap.
523   int page_offset = start % kPageSize;
524   off_t page_aligned_offset = start - page_offset;
525   // Adjust 'byte_count' to be page-aligned as we will map this anyway.
526   size_t page_aligned_byte_count = RoundUp(byte_count + page_offset, kPageSize);
527   // The 'expected_ptr' is modified (if specified, ie non-null) to be page aligned to the file but
528   // not necessarily to virtual memory. mmap will page align 'expected' for us.
529   uint8_t* page_aligned_expected =
530       (expected_ptr == nullptr) ? nullptr : (expected_ptr - page_offset);
531 
532   size_t redzone_size = 0;
533   if (kRunningOnMemoryTool && kMemoryToolAddsRedzones && expected_ptr == nullptr) {
534     redzone_size = kPageSize;
535     page_aligned_byte_count += redzone_size;
536   }
537 
538   uint8_t* actual = reinterpret_cast<uint8_t*>(MapInternal(page_aligned_expected,
539                                                            page_aligned_byte_count,
540                                                            prot,
541                                                            flags,
542                                                            fd,
543                                                            page_aligned_offset,
544                                                            low_4gb));
545   if (actual == MAP_FAILED) {
546     if (error_msg != nullptr) {
547       auto saved_errno = errno;
548 
549       if (kIsDebugBuild || VLOG_IS_ON(oat)) {
550         PrintFileToLog("/proc/self/maps", LogSeverity::WARNING);
551       }
552 
553       *error_msg = StringPrintf("mmap(%p, %zd, 0x%x, 0x%x, %d, %" PRId64
554                                 ") of file '%s' failed: %s. See process maps in the log.",
555                                 page_aligned_expected, page_aligned_byte_count, prot, flags, fd,
556                                 static_cast<int64_t>(page_aligned_offset), filename,
557                                 strerror(saved_errno));
558     }
559     return Invalid();
560   }
561   if (!CheckMapRequest(expected_ptr, actual, page_aligned_byte_count, error_msg)) {
562     return Invalid();
563   }
564   if (redzone_size != 0) {
565     const uint8_t *real_start = actual + page_offset;
566     const uint8_t *real_end = actual + page_offset + byte_count;
567     const uint8_t *mapping_end = actual + page_aligned_byte_count;
568 
569     MEMORY_TOOL_MAKE_NOACCESS(actual, real_start - actual);
570     MEMORY_TOOL_MAKE_NOACCESS(real_end, mapping_end - real_end);
571     page_aligned_byte_count -= redzone_size;
572   }
573 
574   if (reservation != nullptr) {
575     // Re-mapping was successful, transfer the ownership of the memory to the new MemMap.
576     DCHECK_EQ(actual, reservation->Begin());
577     reservation->ReleaseReservedMemory(byte_count);
578   }
579   return MemMap(filename,
580                 actual + page_offset,
581                 byte_count,
582                 actual,
583                 page_aligned_byte_count,
584                 prot,
585                 reuse,
586                 redzone_size);
587 }
588 
MemMap(MemMap && other)589 MemMap::MemMap(MemMap&& other) noexcept
590     : MemMap() {
591   swap(other);
592 }
593 
~MemMap()594 MemMap::~MemMap() {
595   Reset();
596 }
597 
DoReset()598 void MemMap::DoReset() {
599   DCHECK(IsValid());
600 
601   // Unlike Valgrind, AddressSanitizer requires that all manually poisoned memory is unpoisoned
602   // before it is returned to the system.
603   if (redzone_size_ != 0) {
604     MEMORY_TOOL_MAKE_UNDEFINED(
605         reinterpret_cast<char*>(base_begin_) + base_size_ - redzone_size_,
606         redzone_size_);
607   }
608 
609   if (!reuse_) {
610     MEMORY_TOOL_MAKE_UNDEFINED(base_begin_, base_size_);
611     if (!already_unmapped_) {
612       int result = TargetMUnmap(base_begin_, base_size_);
613       if (result == -1) {
614         PLOG(FATAL) << "munmap failed";
615       }
616     }
617   }
618 
619   Invalidate();
620 }
621 
Invalidate()622 void MemMap::Invalidate() {
623   DCHECK(IsValid());
624 
625   // Remove it from gMaps.
626   std::lock_guard<std::mutex> mu(*mem_maps_lock_);
627   auto it = GetGMapsEntry(*this);
628   gMaps->erase(it);
629 
630   // Mark it as invalid.
631   base_size_ = 0u;
632   DCHECK(!IsValid());
633 }
634 
swap(MemMap & other)635 void MemMap::swap(MemMap& other) {
636   if (IsValid() || other.IsValid()) {
637     std::lock_guard<std::mutex> mu(*mem_maps_lock_);
638     DCHECK(gMaps != nullptr);
639     auto this_it = IsValid() ? GetGMapsEntry(*this) : gMaps->end();
640     auto other_it = other.IsValid() ? GetGMapsEntry(other) : gMaps->end();
641     if (IsValid()) {
642       DCHECK(this_it != gMaps->end());
643       DCHECK_EQ(this_it->second, this);
644       this_it->second = &other;
645     }
646     if (other.IsValid()) {
647       DCHECK(other_it != gMaps->end());
648       DCHECK_EQ(other_it->second, &other);
649       other_it->second = this;
650     }
651     // Swap members with the `mem_maps_lock_` held so that `base_begin_` matches
652     // with the `gMaps` key when other threads try to use `gMaps`.
653     SwapMembers(other);
654   } else {
655     SwapMembers(other);
656   }
657 }
658 
SwapMembers(MemMap & other)659 void MemMap::SwapMembers(MemMap& other) {
660   name_.swap(other.name_);
661   std::swap(begin_, other.begin_);
662   std::swap(size_, other.size_);
663   std::swap(base_begin_, other.base_begin_);
664   std::swap(base_size_, other.base_size_);
665   std::swap(prot_, other.prot_);
666   std::swap(reuse_, other.reuse_);
667   std::swap(already_unmapped_, other.already_unmapped_);
668   std::swap(redzone_size_, other.redzone_size_);
669 }
670 
MemMap(const std::string & name,uint8_t * begin,size_t size,void * base_begin,size_t base_size,int prot,bool reuse,size_t redzone_size)671 MemMap::MemMap(const std::string& name, uint8_t* begin, size_t size, void* base_begin,
672                size_t base_size, int prot, bool reuse, size_t redzone_size)
673     : name_(name), begin_(begin), size_(size), base_begin_(base_begin), base_size_(base_size),
674       prot_(prot), reuse_(reuse), already_unmapped_(false), redzone_size_(redzone_size) {
675   if (size_ == 0) {
676     CHECK(begin_ == nullptr);
677     CHECK(base_begin_ == nullptr);
678     CHECK_EQ(base_size_, 0U);
679   } else {
680     CHECK(begin_ != nullptr);
681     CHECK(base_begin_ != nullptr);
682     CHECK_NE(base_size_, 0U);
683 
684     // Add it to gMaps.
685     std::lock_guard<std::mutex> mu(*mem_maps_lock_);
686     DCHECK(gMaps != nullptr);
687     gMaps->insert(std::make_pair(base_begin_, this));
688   }
689 }
690 
RemapAtEnd(uint8_t * new_end,const char * tail_name,int tail_prot,std::string * error_msg,bool use_debug_name)691 MemMap MemMap::RemapAtEnd(uint8_t* new_end,
692                           const char* tail_name,
693                           int tail_prot,
694                           std::string* error_msg,
695                           bool use_debug_name) {
696   return RemapAtEnd(new_end,
697                     tail_name,
698                     tail_prot,
699                     MAP_PRIVATE | MAP_FIXED | MAP_ANONYMOUS,
700                     /* fd= */ -1,
701                     /* offset= */ 0,
702                     error_msg,
703                     use_debug_name);
704 }
705 
RemapAtEnd(uint8_t * new_end,const char * tail_name,int tail_prot,int flags,int fd,off_t offset,std::string * error_msg,bool use_debug_name)706 MemMap MemMap::RemapAtEnd(uint8_t* new_end,
707                           const char* tail_name,
708                           int tail_prot,
709                           int flags,
710                           int fd,
711                           off_t offset,
712                           std::string* error_msg,
713                           bool use_debug_name) {
714   DCHECK_GE(new_end, Begin());
715   DCHECK_LE(new_end, End());
716   DCHECK_LE(begin_ + size_, reinterpret_cast<uint8_t*>(base_begin_) + base_size_);
717   DCHECK_ALIGNED(begin_, kPageSize);
718   DCHECK_ALIGNED(base_begin_, kPageSize);
719   DCHECK_ALIGNED(reinterpret_cast<uint8_t*>(base_begin_) + base_size_, kPageSize);
720   DCHECK_ALIGNED(new_end, kPageSize);
721   uint8_t* old_end = begin_ + size_;
722   uint8_t* old_base_end = reinterpret_cast<uint8_t*>(base_begin_) + base_size_;
723   uint8_t* new_base_end = new_end;
724   DCHECK_LE(new_base_end, old_base_end);
725   if (new_base_end == old_base_end) {
726     return Invalid();
727   }
728   size_t new_size = new_end - reinterpret_cast<uint8_t*>(begin_);
729   size_t new_base_size = new_base_end - reinterpret_cast<uint8_t*>(base_begin_);
730   DCHECK_LE(begin_ + new_size, reinterpret_cast<uint8_t*>(base_begin_) + new_base_size);
731   size_t tail_size = old_end - new_end;
732   uint8_t* tail_base_begin = new_base_end;
733   size_t tail_base_size = old_base_end - new_base_end;
734   DCHECK_EQ(tail_base_begin + tail_base_size, old_base_end);
735   DCHECK_ALIGNED(tail_base_size, kPageSize);
736 
737   MEMORY_TOOL_MAKE_UNDEFINED(tail_base_begin, tail_base_size);
738   // Note: Do not explicitly unmap the tail region, mmap() with MAP_FIXED automatically
739   // removes old mappings for the overlapping region. This makes the operation atomic
740   // and prevents other threads from racing to allocate memory in the requested region.
741   uint8_t* actual = reinterpret_cast<uint8_t*>(TargetMMap(tail_base_begin,
742                                                           tail_base_size,
743                                                           tail_prot,
744                                                           flags,
745                                                           fd,
746                                                           offset));
747   if (actual == MAP_FAILED) {
748     PrintFileToLog("/proc/self/maps", LogSeverity::WARNING);
749     *error_msg = StringPrintf("map(%p, %zd, 0x%x, 0x%x, %d, 0) failed. See process "
750                               "maps in the log.", tail_base_begin, tail_base_size, tail_prot, flags,
751                               fd);
752     return Invalid();
753   }
754   // Update *this.
755   if (new_base_size == 0u) {
756     std::lock_guard<std::mutex> mu(*mem_maps_lock_);
757     auto it = GetGMapsEntry(*this);
758     gMaps->erase(it);
759   }
760 
761   if (use_debug_name) {
762     SetDebugName(actual, tail_name, tail_base_size);
763   }
764 
765   size_ = new_size;
766   base_size_ = new_base_size;
767   // Return the new mapping.
768   return MemMap(tail_name, actual, tail_size, actual, tail_base_size, tail_prot, false);
769 }
770 
TakeReservedMemory(size_t byte_count)771 MemMap MemMap::TakeReservedMemory(size_t byte_count) {
772   uint8_t* begin = Begin();
773   ReleaseReservedMemory(byte_count);  // Performs necessary DCHECK()s on this reservation.
774   size_t base_size = RoundUp(byte_count, kPageSize);
775   return MemMap(name_, begin, byte_count, begin, base_size, prot_, /* reuse= */ false);
776 }
777 
ReleaseReservedMemory(size_t byte_count)778 void MemMap::ReleaseReservedMemory(size_t byte_count) {
779   // Check the reservation mapping.
780   DCHECK(IsValid());
781   DCHECK(!reuse_);
782   DCHECK(!already_unmapped_);
783   DCHECK_EQ(redzone_size_, 0u);
784   DCHECK_EQ(begin_, base_begin_);
785   DCHECK_EQ(size_, base_size_);
786   DCHECK_ALIGNED(begin_, kPageSize);
787   DCHECK_ALIGNED(size_, kPageSize);
788 
789   // Check and round up the `byte_count`.
790   DCHECK_NE(byte_count, 0u);
791   DCHECK_LE(byte_count, size_);
792   byte_count = RoundUp(byte_count, kPageSize);
793 
794   if (byte_count == size_) {
795     Invalidate();
796   } else {
797     // Shrink the reservation MemMap and update its `gMaps` entry.
798     std::lock_guard<std::mutex> mu(*mem_maps_lock_);
799     auto it = GetGMapsEntry(*this);
800     auto node = gMaps->extract(it);
801     begin_ += byte_count;
802     size_ -= byte_count;
803     base_begin_ = begin_;
804     base_size_ = size_;
805     node.key() = base_begin_;
806     gMaps->insert(std::move(node));
807   }
808 }
809 
MadviseDontNeedAndZero()810 void MemMap::MadviseDontNeedAndZero() {
811   if (base_begin_ != nullptr || base_size_ != 0) {
812     if (!kMadviseZeroes) {
813       memset(base_begin_, 0, base_size_);
814     }
815 #ifdef _WIN32
816     // It is benign not to madvise away the pages here.
817     PLOG(WARNING) << "MemMap::MadviseDontNeedAndZero does not madvise on Windows.";
818 #else
819     int result = madvise(base_begin_, base_size_, MADV_DONTNEED);
820     if (result == -1) {
821       PLOG(WARNING) << "madvise failed";
822     }
823 #endif
824   }
825 }
826 
Sync()827 bool MemMap::Sync() {
828 #ifdef _WIN32
829   // TODO: add FlushViewOfFile support.
830   PLOG(ERROR) << "MemMap::Sync unsupported on Windows.";
831   return false;
832 #else
833   // Historical note: To avoid Valgrind errors, we temporarily lifted the lower-end noaccess
834   // protection before passing it to msync() when `redzone_size_` was non-null, as Valgrind
835   // only accepts page-aligned base address, and excludes the higher-end noaccess protection
836   // from the msync range. b/27552451.
837   return msync(BaseBegin(), BaseSize(), MS_SYNC) == 0;
838 #endif
839 }
840 
Protect(int prot)841 bool MemMap::Protect(int prot) {
842   if (base_begin_ == nullptr && base_size_ == 0) {
843     prot_ = prot;
844     return true;
845   }
846 
847 #ifndef _WIN32
848   if (mprotect(base_begin_, base_size_, prot) == 0) {
849     prot_ = prot;
850     return true;
851   }
852 #endif
853 
854   PLOG(ERROR) << "mprotect(" << reinterpret_cast<void*>(base_begin_) << ", " << base_size_ << ", "
855               << prot << ") failed";
856   return false;
857 }
858 
CheckNoGaps(MemMap & begin_map,MemMap & end_map)859 bool MemMap::CheckNoGaps(MemMap& begin_map, MemMap& end_map) {
860   std::lock_guard<std::mutex> mu(*mem_maps_lock_);
861   CHECK(begin_map.IsValid());
862   CHECK(end_map.IsValid());
863   CHECK(HasMemMap(begin_map));
864   CHECK(HasMemMap(end_map));
865   CHECK_LE(begin_map.BaseBegin(), end_map.BaseBegin());
866   MemMap* map = &begin_map;
867   while (map->BaseBegin() != end_map.BaseBegin()) {
868     MemMap* next_map = GetLargestMemMapAt(map->BaseEnd());
869     if (next_map == nullptr) {
870       // Found a gap.
871       return false;
872     }
873     map = next_map;
874   }
875   return true;
876 }
877 
DumpMaps(std::ostream & os,bool terse)878 void MemMap::DumpMaps(std::ostream& os, bool terse) {
879   std::lock_guard<std::mutex> mu(*mem_maps_lock_);
880   DumpMapsLocked(os, terse);
881 }
882 
DumpMapsLocked(std::ostream & os,bool terse)883 void MemMap::DumpMapsLocked(std::ostream& os, bool terse) {
884   const auto& mem_maps = *gMaps;
885   if (!terse) {
886     os << mem_maps;
887     return;
888   }
889 
890   // Terse output example:
891   //   [MemMap: 0x409be000+0x20P~0x11dP+0x20P~0x61cP+0x20P prot=0x3 LinearAlloc]
892   //   [MemMap: 0x451d6000+0x6bP(3) prot=0x3 large object space allocation]
893   // The details:
894   //   "+0x20P" means 0x20 pages taken by a single mapping,
895   //   "~0x11dP" means a gap of 0x11d pages,
896   //   "+0x6bP(3)" means 3 mappings one after another, together taking 0x6b pages.
897   os << "MemMap:" << std::endl;
898   for (auto it = mem_maps.begin(), maps_end = mem_maps.end(); it != maps_end;) {
899     MemMap* map = it->second;
900     void* base = it->first;
901     CHECK_EQ(base, map->BaseBegin());
902     os << "[MemMap: " << base;
903     ++it;
904     // Merge consecutive maps with the same protect flags and name.
905     constexpr size_t kMaxGaps = 9;
906     size_t num_gaps = 0;
907     size_t num = 1u;
908     size_t size = map->BaseSize();
909     CHECK_ALIGNED(size, kPageSize);
910     void* end = map->BaseEnd();
911     while (it != maps_end &&
912         it->second->GetProtect() == map->GetProtect() &&
913         it->second->GetName() == map->GetName() &&
914         (it->second->BaseBegin() == end || num_gaps < kMaxGaps)) {
915       if (it->second->BaseBegin() != end) {
916         ++num_gaps;
917         os << "+0x" << std::hex << (size / kPageSize) << "P";
918         if (num != 1u) {
919           os << "(" << std::dec << num << ")";
920         }
921         size_t gap =
922             reinterpret_cast<uintptr_t>(it->second->BaseBegin()) - reinterpret_cast<uintptr_t>(end);
923         CHECK_ALIGNED(gap, kPageSize);
924         os << "~0x" << std::hex << (gap / kPageSize) << "P";
925         num = 0u;
926         size = 0u;
927       }
928       CHECK_ALIGNED(it->second->BaseSize(), kPageSize);
929       ++num;
930       size += it->second->BaseSize();
931       end = it->second->BaseEnd();
932       ++it;
933     }
934     os << "+0x" << std::hex << (size / kPageSize) << "P";
935     if (num != 1u) {
936       os << "(" << std::dec << num << ")";
937     }
938     os << " prot=0x" << std::hex << map->GetProtect() << " " << map->GetName() << "]" << std::endl;
939   }
940 }
941 
HasMemMap(MemMap & map)942 bool MemMap::HasMemMap(MemMap& map) {
943   void* base_begin = map.BaseBegin();
944   for (auto it = gMaps->lower_bound(base_begin), end = gMaps->end();
945        it != end && it->first == base_begin; ++it) {
946     if (it->second == &map) {
947       return true;
948     }
949   }
950   return false;
951 }
952 
GetLargestMemMapAt(void * address)953 MemMap* MemMap::GetLargestMemMapAt(void* address) {
954   size_t largest_size = 0;
955   MemMap* largest_map = nullptr;
956   DCHECK(gMaps != nullptr);
957   for (auto it = gMaps->lower_bound(address), end = gMaps->end();
958        it != end && it->first == address; ++it) {
959     MemMap* map = it->second;
960     CHECK(map != nullptr);
961     if (largest_size < map->BaseSize()) {
962       largest_size = map->BaseSize();
963       largest_map = map;
964     }
965   }
966   return largest_map;
967 }
968 
Init()969 void MemMap::Init() {
970   if (mem_maps_lock_ != nullptr) {
971     // dex2oat calls MemMap::Init twice since its needed before the runtime is created.
972     return;
973   }
974   mem_maps_lock_ = new std::mutex();
975   // Not for thread safety, but for the annotation that gMaps is GUARDED_BY(mem_maps_lock_).
976   std::lock_guard<std::mutex> mu(*mem_maps_lock_);
977   DCHECK(gMaps == nullptr);
978   gMaps = new Maps;
979 
980   TargetMMapInit();
981 }
982 
Shutdown()983 void MemMap::Shutdown() {
984   if (mem_maps_lock_ == nullptr) {
985     // If MemMap::Shutdown is called more than once, there is no effect.
986     return;
987   }
988   {
989     // Not for thread safety, but for the annotation that gMaps is GUARDED_BY(mem_maps_lock_).
990     std::lock_guard<std::mutex> mu(*mem_maps_lock_);
991     DCHECK(gMaps != nullptr);
992     delete gMaps;
993     gMaps = nullptr;
994   }
995   delete mem_maps_lock_;
996   mem_maps_lock_ = nullptr;
997 }
998 
SetSize(size_t new_size)999 void MemMap::SetSize(size_t new_size) {
1000   CHECK_LE(new_size, size_);
1001   size_t new_base_size = RoundUp(new_size + static_cast<size_t>(PointerDiff(Begin(), BaseBegin())),
1002                                  kPageSize);
1003   if (new_base_size == base_size_) {
1004     size_ = new_size;
1005     return;
1006   }
1007   CHECK_LT(new_base_size, base_size_);
1008   MEMORY_TOOL_MAKE_UNDEFINED(
1009       reinterpret_cast<void*>(reinterpret_cast<uintptr_t>(BaseBegin()) +
1010                               new_base_size),
1011       base_size_ - new_base_size);
1012   CHECK_EQ(TargetMUnmap(reinterpret_cast<void*>(
1013                         reinterpret_cast<uintptr_t>(BaseBegin()) + new_base_size),
1014                         base_size_ - new_base_size), 0)
1015                         << new_base_size << " " << base_size_;
1016   base_size_ = new_base_size;
1017   size_ = new_size;
1018 }
1019 
MapInternalArtLow4GBAllocator(size_t length,int prot,int flags,int fd,off_t offset)1020 void* MemMap::MapInternalArtLow4GBAllocator(size_t length,
1021                                             int prot,
1022                                             int flags,
1023                                             int fd,
1024                                             off_t offset) {
1025 #if USE_ART_LOW_4G_ALLOCATOR
1026   void* actual = MAP_FAILED;
1027 
1028   bool first_run = true;
1029 
1030   std::lock_guard<std::mutex> mu(*mem_maps_lock_);
1031   for (uintptr_t ptr = next_mem_pos_; ptr < 4 * GB; ptr += kPageSize) {
1032     // Use gMaps as an optimization to skip over large maps.
1033     // Find the first map which is address > ptr.
1034     auto it = gMaps->upper_bound(reinterpret_cast<void*>(ptr));
1035     if (it != gMaps->begin()) {
1036       auto before_it = it;
1037       --before_it;
1038       // Start at the end of the map before the upper bound.
1039       ptr = std::max(ptr, reinterpret_cast<uintptr_t>(before_it->second->BaseEnd()));
1040       CHECK_ALIGNED(ptr, kPageSize);
1041     }
1042     while (it != gMaps->end()) {
1043       // How much space do we have until the next map?
1044       size_t delta = reinterpret_cast<uintptr_t>(it->first) - ptr;
1045       // If the space may be sufficient, break out of the loop.
1046       if (delta >= length) {
1047         break;
1048       }
1049       // Otherwise, skip to the end of the map.
1050       ptr = reinterpret_cast<uintptr_t>(it->second->BaseEnd());
1051       CHECK_ALIGNED(ptr, kPageSize);
1052       ++it;
1053     }
1054 
1055     // Try to see if we get lucky with this address since none of the ART maps overlap.
1056     actual = TryMemMapLow4GB(reinterpret_cast<void*>(ptr), length, prot, flags, fd, offset);
1057     if (actual != MAP_FAILED) {
1058       next_mem_pos_ = reinterpret_cast<uintptr_t>(actual) + length;
1059       return actual;
1060     }
1061 
1062     if (4U * GB - ptr < length) {
1063       // Not enough memory until 4GB.
1064       if (first_run) {
1065         // Try another time from the bottom;
1066         ptr = LOW_MEM_START - kPageSize;
1067         first_run = false;
1068         continue;
1069       } else {
1070         // Second try failed.
1071         break;
1072       }
1073     }
1074 
1075     uintptr_t tail_ptr;
1076 
1077     // Check pages are free.
1078     bool safe = true;
1079     for (tail_ptr = ptr; tail_ptr < ptr + length; tail_ptr += kPageSize) {
1080       if (msync(reinterpret_cast<void*>(tail_ptr), kPageSize, 0) == 0) {
1081         safe = false;
1082         break;
1083       } else {
1084         DCHECK_EQ(errno, ENOMEM);
1085       }
1086     }
1087 
1088     next_mem_pos_ = tail_ptr;  // update early, as we break out when we found and mapped a region
1089 
1090     if (safe == true) {
1091       actual = TryMemMapLow4GB(reinterpret_cast<void*>(ptr), length, prot, flags, fd, offset);
1092       if (actual != MAP_FAILED) {
1093         return actual;
1094       }
1095     } else {
1096       // Skip over last page.
1097       ptr = tail_ptr;
1098     }
1099   }
1100 
1101   if (actual == MAP_FAILED) {
1102     LOG(ERROR) << "Could not find contiguous low-memory space.";
1103     errno = ENOMEM;
1104   }
1105   return actual;
1106 #else
1107   UNUSED(length, prot, flags, fd, offset);
1108   LOG(FATAL) << "Unreachable";
1109   UNREACHABLE();
1110 #endif
1111 }
1112 
MapInternal(void * addr,size_t length,int prot,int flags,int fd,off_t offset,bool low_4gb)1113 void* MemMap::MapInternal(void* addr,
1114                           size_t length,
1115                           int prot,
1116                           int flags,
1117                           int fd,
1118                           off_t offset,
1119                           bool low_4gb) {
1120 #ifdef __LP64__
1121   // When requesting low_4g memory and having an expectation, the requested range should fit into
1122   // 4GB.
1123   if (low_4gb && (
1124       // Start out of bounds.
1125       (reinterpret_cast<uintptr_t>(addr) >> 32) != 0 ||
1126       // End out of bounds. For simplicity, this will fail for the last page of memory.
1127       ((reinterpret_cast<uintptr_t>(addr) + length) >> 32) != 0)) {
1128     LOG(ERROR) << "The requested address space (" << addr << ", "
1129                << reinterpret_cast<void*>(reinterpret_cast<uintptr_t>(addr) + length)
1130                << ") cannot fit in low_4gb";
1131     return MAP_FAILED;
1132   }
1133 #else
1134   UNUSED(low_4gb);
1135 #endif
1136   DCHECK_ALIGNED(length, kPageSize);
1137   // TODO:
1138   // A page allocator would be a useful abstraction here, as
1139   // 1) It is doubtful that MAP_32BIT on x86_64 is doing the right job for us
1140   void* actual = MAP_FAILED;
1141 #if USE_ART_LOW_4G_ALLOCATOR
1142   // MAP_32BIT only available on x86_64.
1143   if (low_4gb && addr == nullptr) {
1144     // The linear-scan allocator has an issue when executable pages are denied (e.g., by selinux
1145     // policies in sensitive processes). In that case, the error code will still be ENOMEM. So
1146     // the allocator will scan all low 4GB twice, and still fail. This is *very* slow.
1147     //
1148     // To avoid the issue, always map non-executable first, and mprotect if necessary.
1149     const int orig_prot = prot;
1150     const int prot_non_exec = prot & ~PROT_EXEC;
1151     actual = MapInternalArtLow4GBAllocator(length, prot_non_exec, flags, fd, offset);
1152 
1153     if (actual == MAP_FAILED) {
1154       return MAP_FAILED;
1155     }
1156 
1157     // See if we need to remap with the executable bit now.
1158     if (orig_prot != prot_non_exec) {
1159       if (mprotect(actual, length, orig_prot) != 0) {
1160         PLOG(ERROR) << "Could not protect to requested prot: " << orig_prot;
1161         TargetMUnmap(actual, length);
1162         errno = ENOMEM;
1163         return MAP_FAILED;
1164       }
1165     }
1166     return actual;
1167   }
1168 
1169   actual = TargetMMap(addr, length, prot, flags, fd, offset);
1170 #else
1171 #if defined(__LP64__)
1172   if (low_4gb && addr == nullptr) {
1173     flags |= MAP_32BIT;
1174   }
1175 #endif
1176   actual = TargetMMap(addr, length, prot, flags, fd, offset);
1177 #endif
1178   return actual;
1179 }
1180 
operator <<(std::ostream & os,const MemMap & mem_map)1181 std::ostream& operator<<(std::ostream& os, const MemMap& mem_map) {
1182   os << StringPrintf("[MemMap: %p-%p prot=0x%x %s]",
1183                      mem_map.BaseBegin(), mem_map.BaseEnd(), mem_map.GetProtect(),
1184                      mem_map.GetName().c_str());
1185   return os;
1186 }
1187 
TryReadable()1188 void MemMap::TryReadable() {
1189   if (base_begin_ == nullptr && base_size_ == 0) {
1190     return;
1191   }
1192   CHECK_NE(prot_ & PROT_READ, 0);
1193   volatile uint8_t* begin = reinterpret_cast<volatile uint8_t*>(base_begin_);
1194   volatile uint8_t* end = begin + base_size_;
1195   DCHECK(IsAligned<kPageSize>(begin));
1196   DCHECK(IsAligned<kPageSize>(end));
1197   // Read the first byte of each page. Use volatile to prevent the compiler from optimizing away the
1198   // reads.
1199   for (volatile uint8_t* ptr = begin; ptr < end; ptr += kPageSize) {
1200     // This read could fault if protection wasn't set correctly.
1201     uint8_t value = *ptr;
1202     UNUSED(value);
1203   }
1204 }
1205 
ZeroAndReleasePages(void * address,size_t length)1206 void ZeroAndReleasePages(void* address, size_t length) {
1207   if (length == 0) {
1208     return;
1209   }
1210   uint8_t* const mem_begin = reinterpret_cast<uint8_t*>(address);
1211   uint8_t* const mem_end = mem_begin + length;
1212   uint8_t* const page_begin = AlignUp(mem_begin, kPageSize);
1213   uint8_t* const page_end = AlignDown(mem_end, kPageSize);
1214   if (!kMadviseZeroes || page_begin >= page_end) {
1215     // No possible area to madvise.
1216     std::fill(mem_begin, mem_end, 0);
1217   } else {
1218     // Spans one or more pages.
1219     DCHECK_LE(mem_begin, page_begin);
1220     DCHECK_LE(page_begin, page_end);
1221     DCHECK_LE(page_end, mem_end);
1222     std::fill(mem_begin, page_begin, 0);
1223 #ifdef _WIN32
1224     LOG(WARNING) << "ZeroAndReleasePages does not madvise on Windows.";
1225 #else
1226     CHECK_NE(madvise(page_begin, page_end - page_begin, MADV_DONTNEED), -1) << "madvise failed";
1227 #endif
1228     std::fill(page_end, mem_end, 0);
1229   }
1230 }
1231 
AlignBy(size_t size)1232 void MemMap::AlignBy(size_t size) {
1233   CHECK_EQ(begin_, base_begin_) << "Unsupported";
1234   CHECK_EQ(size_, base_size_) << "Unsupported";
1235   CHECK_GT(size, static_cast<size_t>(kPageSize));
1236   CHECK_ALIGNED(size, kPageSize);
1237   CHECK(!reuse_);
1238   if (IsAlignedParam(reinterpret_cast<uintptr_t>(base_begin_), size) &&
1239       IsAlignedParam(base_size_, size)) {
1240     // Already aligned.
1241     return;
1242   }
1243   uint8_t* base_begin = reinterpret_cast<uint8_t*>(base_begin_);
1244   uint8_t* base_end = base_begin + base_size_;
1245   uint8_t* aligned_base_begin = AlignUp(base_begin, size);
1246   uint8_t* aligned_base_end = AlignDown(base_end, size);
1247   CHECK_LE(base_begin, aligned_base_begin);
1248   CHECK_LE(aligned_base_end, base_end);
1249   size_t aligned_base_size = aligned_base_end - aligned_base_begin;
1250   CHECK_LT(aligned_base_begin, aligned_base_end)
1251       << "base_begin = " << reinterpret_cast<void*>(base_begin)
1252       << " base_end = " << reinterpret_cast<void*>(base_end);
1253   CHECK_GE(aligned_base_size, size);
1254   // Unmap the unaligned parts.
1255   if (base_begin < aligned_base_begin) {
1256     MEMORY_TOOL_MAKE_UNDEFINED(base_begin, aligned_base_begin - base_begin);
1257     CHECK_EQ(TargetMUnmap(base_begin, aligned_base_begin - base_begin), 0)
1258         << "base_begin=" << reinterpret_cast<void*>(base_begin)
1259         << " aligned_base_begin=" << reinterpret_cast<void*>(aligned_base_begin);
1260   }
1261   if (aligned_base_end < base_end) {
1262     MEMORY_TOOL_MAKE_UNDEFINED(aligned_base_end, base_end - aligned_base_end);
1263     CHECK_EQ(TargetMUnmap(aligned_base_end, base_end - aligned_base_end), 0)
1264         << "base_end=" << reinterpret_cast<void*>(base_end)
1265         << " aligned_base_end=" << reinterpret_cast<void*>(aligned_base_end);
1266   }
1267   std::lock_guard<std::mutex> mu(*mem_maps_lock_);
1268   if (base_begin < aligned_base_begin) {
1269     auto it = GetGMapsEntry(*this);
1270     auto node = gMaps->extract(it);
1271     node.key() = aligned_base_begin;
1272     gMaps->insert(std::move(node));
1273   }
1274   base_begin_ = aligned_base_begin;
1275   base_size_ = aligned_base_size;
1276   begin_ = aligned_base_begin;
1277   size_ = aligned_base_size;
1278   DCHECK(gMaps != nullptr);
1279 }
1280 
1281 }  // namespace art
1282