]> git.saurik.com Git - apple/dyld.git/blob - src/dyld_process_info.cpp
dyld-851.27.tar.gz
[apple/dyld.git] / src / dyld_process_info.cpp
1 /* -*- mode: C++; c-basic-offset: 4; tab-width: 4 -*-
2 *
3 * Copyright (c) 2016 Apple Inc. All rights reserved.
4 *
5 * @APPLE_LICENSE_HEADER_START@
6 *
7 * This file contains Original Code and/or Modifications of Original Code
8 * as defined in and that are subject to the Apple Public Source License
9 * Version 2.0 (the 'License'). You may not use this file except in
10 * compliance with the License. Please obtain a copy of the License at
11 * http://www.opensource.apple.com/apsl/ and read it before using this
12 * file.
13 *
14 * The Original Code and all software distributed under the License are
15 * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
16 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
17 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
18 * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
19 * Please see the License for the specific language governing rights and
20 * limitations under the License.
21 *
22 * @APPLE_LICENSE_HEADER_END@
23 */
24
25 #include <dlfcn.h>
26 #include <stdlib.h>
27 #include <string.h>
28 #include <limits.h>
29 #include <stdio.h>
30 #include <libproc.h>
31 #include <sys/param.h>
32 #include <mach/shared_region.h>
33 #include <mach/mach_vm.h>
34 #include <mach/vm_region.h>
35 #include <libkern/OSAtomic.h>
36 #include <mach-o/dyld_process_info.h>
37 #include <mach-o/dyld_images.h>
38
39 #include "MachOFile.h"
40 #include "dyld_process_info_internal.h"
41 #include "Tracing.h"
42
43 // this was in dyld_priv.h but it is no longer exported
44 extern "C" {
45 const struct dyld_all_image_infos* _dyld_get_all_image_infos();
46 }
47
48 RemoteBuffer& RemoteBuffer::operator=(RemoteBuffer&& other) {
49 std::swap(_localAddress, other._localAddress);
50 std::swap(_size, other._size);
51 std::swap(_kr, other._kr);
52 return *this;
53 }
54
55 RemoteBuffer::RemoteBuffer() : _localAddress(0), _size(0), _kr(KERN_SUCCESS) {}
56 RemoteBuffer::RemoteBuffer(std::tuple<mach_vm_address_t,vm_size_t,kern_return_t> T)
57 : _localAddress(std::get<0>(T)), _size(std::get<1>(T)), _kr(std::get<2>(T)) {}
58
59 RemoteBuffer::RemoteBuffer(task_t task, mach_vm_address_t remote_address, size_t remote_size, bool allow_truncation)
60 : RemoteBuffer(RemoteBuffer::create(task, remote_address, remote_size, allow_truncation)) {};
61
62 std::pair<mach_vm_address_t, kern_return_t>
63 RemoteBuffer::map(task_t task, mach_vm_address_t remote_address, vm_size_t size) {
64 static kern_return_t (*mvrn)(vm_map_t, mach_vm_address_t*, mach_vm_size_t, mach_vm_offset_t, int, vm_map_read_t, mach_vm_address_t,
65 boolean_t, vm_prot_t*, vm_prot_t*, vm_inherit_t) = nullptr;
66 vm_prot_t cur_protection = VM_PROT_NONE;
67 vm_prot_t max_protection = VM_PROT_READ;
68 if (size == 0) {
69 return std::make_pair(MACH_VM_MIN_ADDRESS, KERN_INVALID_ARGUMENT);
70 }
71 mach_vm_address_t localAddress = 0;
72 #if TARGET_OS_SIMULATOR
73 static dispatch_once_t onceToken;
74 dispatch_once(&onceToken, ^{
75 mvrn = (kern_return_t (*)(vm_map_t, mach_vm_address_t*, mach_vm_size_t, mach_vm_offset_t, int, vm_map_read_t, mach_vm_address_t,
76 boolean_t, vm_prot_t*, vm_prot_t*, vm_inherit_t))dlsym(RTLD_DEFAULT, "mach_vm_remap_new");
77 if (mvrn == nullptr) {
78 // We are running on a system that does not support task_read ports, use the old call
79 mvrn = (kern_return_t (*)(vm_map_t, mach_vm_address_t*, mach_vm_size_t, mach_vm_offset_t, int, vm_map_read_t, mach_vm_address_t,
80 boolean_t, vm_prot_t*, vm_prot_t*, vm_inherit_t))dlsym(RTLD_DEFAULT, "mach_vm_remap");
81 }
82 });
83 #else
84 mvrn = &mach_vm_remap_new;
85 #endif
86 auto kr = mvrn(mach_task_self(),
87 &localAddress,
88 size,
89 0, // mask
90 VM_FLAGS_ANYWHERE | VM_FLAGS_RESILIENT_CODESIGN | VM_FLAGS_RESILIENT_MEDIA,
91 task,
92 remote_address,
93 true,
94 &cur_protection,
95 &max_protection,
96 VM_INHERIT_NONE);
97 // The call is not succesfull return
98 if (kr != KERN_SUCCESS) {
99 return std::make_pair(MACH_VM_MIN_ADDRESS, kr);
100 }
101 // If it is not a shared buffer then copy it into a local buffer so our results are coherent in the event
102 // the page goes way due to storage removal, etc. We have to do this because even after we read the page the
103 // contents might go away of the object is paged out and then the backing region is disconnected (for example, if
104 // we are copying some memory in the middle of a mach-o that is on a USB drive that is disconnected after we perform
105 // the mapping). Once we copy them into a local buffer the memory will be handled by the default pager instead of
106 // potentially being backed by the mmap pager, and thus will be guaranteed not to mutate out from under us.
107 void* buffer = malloc(size);
108 if (buffer == nullptr) {
109 (void)vm_deallocate(mach_task_self(), (vm_address_t)localAddress, size);
110 return std::make_pair(MACH_VM_MIN_ADDRESS, KERN_NO_SPACE);
111 }
112 memcpy(buffer, (void *)localAddress, size);
113 (void)vm_deallocate(mach_task_self(), (vm_address_t)localAddress, size);
114 return std::make_pair((vm_address_t)buffer, KERN_SUCCESS);
115 }
116
117 std::tuple<mach_vm_address_t,vm_size_t,kern_return_t> RemoteBuffer::create(task_t task,
118 mach_vm_address_t remote_address,
119 size_t size,
120 bool allow_truncation) {
121 mach_vm_address_t localAddress;
122 kern_return_t kr;
123 // Try the initial map
124 std::tie(localAddress, kr) = map(task, remote_address, size);
125 if (kr == KERN_SUCCESS) return std::make_tuple(localAddress, size, kr);
126 // The first attempt failed, truncate if possible and try again. We only need to try once since the largest
127 // truncatable buffer we map is less than a single page. To be more general we would need to try repeatedly in a
128 // loop.
129 if (allow_truncation) {
130 size = PAGE_SIZE - remote_address%PAGE_SIZE;
131 std::tie(localAddress, kr) = map(task, remote_address, size);
132 if (kr == KERN_SUCCESS) return std::make_tuple(localAddress, size, kr);
133 }
134 // If we reach this then the mapping completely failed
135 return std::make_tuple(MACH_VM_MIN_ADDRESS, 0, kr);
136 }
137
138 RemoteBuffer::~RemoteBuffer() {
139 if (!_localAddress) { return; }
140 free((void*)_localAddress);
141 }
142 void *RemoteBuffer::getLocalAddress() const { return (void *)_localAddress; }
143 size_t RemoteBuffer::getSize() const { return _size; }
144 kern_return_t RemoteBuffer::getKernelReturn() const { return _kr; }
145
146 void withRemoteBuffer(task_t task, mach_vm_address_t remote_address, size_t remote_size, bool allow_truncation, kern_return_t *kr, void (^block)(void *buffer, size_t size)) {
147 kern_return_t krSink = KERN_SUCCESS;
148 if (kr == nullptr) {
149 kr = &krSink;
150 }
151 RemoteBuffer buffer(task, remote_address, remote_size, allow_truncation);
152 *kr = buffer.getKernelReturn();
153 if (*kr == KERN_SUCCESS) {
154 block(buffer.getLocalAddress(), buffer.getSize());
155 }
156 }
157
158
159 //
160 // Opaque object returned by _dyld_process_info_create()
161 //
162
163 struct __attribute__((visibility("hidden"))) dyld_process_info_deleter { // deleter
164 // dyld_process_info_deleter() {};
165 // dyld_process_info_deleter(const dyld_process_info_deleter&) { }
166 // dyld_process_info_deleter(dyld_process_info_deleter&) {}
167 // dyld_process_info_deleter(dyld_process_info_deleter&&) {}
168 void operator()(dyld_process_info_base* p) const {
169 if (p) {
170 free(p);
171 }
172 };
173 };
174
175 static dyld_process_info_deleter deleter;
176 typedef std::unique_ptr<dyld_process_info_base, dyld_process_info_deleter> dyld_process_info_ptr;
177
178 struct __attribute__((visibility("hidden"))) dyld_process_info_base {
179 template<typename T1, typename T2>
180 static dyld_process_info_ptr make(task_t task, const T1& allImageInfo, uint64_t timestamp, kern_return_t* kr);
181 template<typename T>
182 static dyld_process_info_ptr makeSuspended(task_t task, const T& allImageInfo, kern_return_t* kr);
183
184 std::atomic<uint32_t>& retainCount() const { return _retainCount; }
185 dyld_process_cache_info* cacheInfo() const { return (dyld_process_cache_info*)(((char*)this) + _cacheInfoOffset); }
186 dyld_process_aot_cache_info* aotCacheInfo() const { return (dyld_process_aot_cache_info*)(((char*)this) + _aotCacheInfoOffset); }
187 dyld_process_state_info* stateInfo() const { return (dyld_process_state_info*)(((char*)this) + _stateInfoOffset); }
188 dyld_platform_t platform() const { return _platform; }
189
190 void forEachImage(void (^callback)(uint64_t machHeaderAddress, const uuid_t uuid, const char* path)) const;
191 void forEachAotImage(bool (^callback)(uint64_t x86Address, uint64_t aotAddress, uint64_t aotSize, uint8_t* aotImageKey, size_t aotImageKeySize)) const;
192 void forEachSegment(uint64_t machHeaderAddress, void (^callback)(uint64_t segmentAddress, uint64_t segmentSize, const char* segmentName)) const;
193
194 bool reserveSpace(size_t space) {
195 if (_freeSpace < space) { return false; }
196 _freeSpace -= space;
197 return true;
198 }
199
200 void retain()
201 {
202 _retainCount++;
203 }
204
205 void release()
206 {
207 uint32_t newCount = --_retainCount;
208
209 if ( newCount == 0 ) {
210 free(this);
211 }
212 }
213
214 private:
215 struct ImageInfo {
216 uuid_t uuid;
217 uint64_t loadAddress;
218 const char* path;
219 uint32_t segmentStartIndex;
220 uint32_t segmentsCount;
221 };
222
223 struct SegmentInfo {
224 const char* name;
225 uint64_t addr;
226 uint64_t size;
227 };
228
229 dyld_process_info_base(dyld_platform_t platform, unsigned imageCount, unsigned aotImageCount, size_t totalSize);
230 void* operator new (size_t, void* buf) { return buf; }
231
232 static bool inCache(uint64_t addr) { return (addr > SHARED_REGION_BASE) && (addr < SHARED_REGION_BASE+SHARED_REGION_SIZE); }
233 bool addImage(task_t task, bool sameCacheAsThisProcess, uint64_t imageAddress, uint64_t imagePath, const char* imagePathLocal);
234
235 bool addAotImage(dyld_aot_image_info_64 aotImageInfo);
236
237 kern_return_t addDyldImage(task_t task, uint64_t dyldAddress, uint64_t dyldPathAddress, const char* localPath);
238
239 bool invalid() { return ((char*)_stringRevBumpPtr < (char*)_curSegment); }
240 const char* copyPath(task_t task, uint64_t pathAddr);
241 const char* addString(const char*, size_t);
242 const char* copySegmentName(const char*);
243
244 void addInfoFromLoadCommands(const mach_header* mh, uint64_t addressInTask, size_t size);
245 kern_return_t addInfoFromRemoteLoadCommands(task_t task, uint64_t remoteMH);
246
247 void inspectLocalImageLoadCommands(uint64_t imageAddress, void* func);
248 kern_return_t inspectRemoteImageLoadCommands(task_t task, uint64_t imageAddress, void* func);
249
250 mutable std::atomic<uint32_t> _retainCount;
251 const uint32_t _cacheInfoOffset;
252 const uint32_t _aotCacheInfoOffset;
253 const uint32_t _stateInfoOffset;
254 const uint32_t _imageInfosOffset;
255 const uint32_t _aotImageInfosOffset;
256 const uint32_t _segmentInfosOffset;
257 size_t _freeSpace;
258 dyld_platform_t _platform;
259 ImageInfo* const _firstImage;
260 ImageInfo* _curImage;
261 dyld_aot_image_info_64* const _firstAotImage;
262 dyld_aot_image_info_64* _curAotImage;
263 SegmentInfo* const _firstSegment;
264 SegmentInfo* _curSegment;
265 uint32_t _curSegmentIndex;
266 char* _stringRevBumpPtr;
267
268 // dyld_process_cache_info cacheInfo;
269 // dyld_process_state_info stateInfo;
270 // ImageInfo images[];
271 // SegmentInfo segments[];
272 // char stringPool[]
273 };
274
275 dyld_process_info_base::dyld_process_info_base(dyld_platform_t platform, unsigned imageCount, unsigned aotImageCount, size_t totalSize)
276 : _retainCount(1), _cacheInfoOffset(sizeof(dyld_process_info_base)),
277 _aotCacheInfoOffset(sizeof(dyld_process_info_base) + sizeof(dyld_process_cache_info)),
278 _stateInfoOffset(sizeof(dyld_process_info_base) + sizeof(dyld_process_cache_info) + sizeof(dyld_process_aot_cache_info)),
279 _imageInfosOffset(sizeof(dyld_process_info_base) + sizeof(dyld_process_cache_info) + sizeof(dyld_process_aot_cache_info) + sizeof(dyld_process_state_info)),
280 _aotImageInfosOffset(sizeof(dyld_process_info_base) + sizeof(dyld_process_cache_info) + sizeof(dyld_process_aot_cache_info) + sizeof(dyld_process_state_info) + imageCount*sizeof(ImageInfo)),
281 _segmentInfosOffset(sizeof(dyld_process_info_base) + sizeof(dyld_process_cache_info) + sizeof(dyld_process_aot_cache_info) + sizeof(dyld_process_state_info) + imageCount*sizeof(ImageInfo) + aotImageCount*sizeof(dyld_aot_image_info_64)),
282 _freeSpace(totalSize), _platform(platform),
283 _firstImage((ImageInfo*)(((uint8_t*)this) + _imageInfosOffset)),
284 _curImage((ImageInfo*)(((uint8_t*)this) + _imageInfosOffset)),
285 _firstAotImage((dyld_aot_image_info_64*)(((uint8_t*)this) + _aotImageInfosOffset)),
286 _curAotImage((dyld_aot_image_info_64*)(((uint8_t*)this) + _aotImageInfosOffset)),
287 _firstSegment((SegmentInfo*)(((uint8_t*)this) + _segmentInfosOffset)),
288 _curSegment((SegmentInfo*)(((uint8_t*)this) + _segmentInfosOffset)),
289 _curSegmentIndex(0),
290 _stringRevBumpPtr((char*)(this)+totalSize)
291 {
292 }
293
294 template<typename T1, typename T2>
295 dyld_process_info_ptr dyld_process_info_base::make(task_t task, const T1& allImageInfo, uint64_t timestamp, kern_return_t* kr)
296 {
297 __block dyld_process_info_ptr result = nullptr;
298
299 // bail out of dyld is too old
300 if ( allImageInfo.version < 15 ) {
301 *kr = KERN_FAILURE;
302 return nullptr;
303 }
304
305 // Check if the process is suspended
306 if (allImageInfo.infoArrayChangeTimestamp == 0) {
307 result = dyld_process_info_base::makeSuspended<T1>(task, allImageInfo, kr);
308 // If we have a result return it, otherwise rescan
309 if (result) {
310 // If it returned the process is suspended and there is nothing more to do
311 return std::move(result);
312 }
313 usleep(1000 * 50); // 50ms
314 // Not exactly correct, but conveys that operation may succeed in the future
315 *kr = KERN_RESOURCE_SHORTAGE;
316 return nullptr;
317 }
318
319 // Test to see if there are no changes and we can exit early
320 if (timestamp != 0 && timestamp == allImageInfo.infoArrayChangeTimestamp) {
321 *kr = KERN_SUCCESS;
322 return nullptr;
323 }
324
325 uint64_t currentTimestamp = allImageInfo.infoArrayChangeTimestamp;
326 mach_vm_address_t infoArray = allImageInfo.infoArray;
327 if (infoArray == 0) {
328 usleep(1000 * 50); // 50ms
329 // Not exactly correct, but conveys that operation may succeed in the future
330 *kr = KERN_RESOURCE_SHORTAGE;
331 return nullptr;
332 };
333
334 // For the moment we are going to truncate any image list longer than 8192 because some programs do
335 // terrible things that corrupt their own image lists and we need to stop clients from crashing
336 // reading them. We can try to do something more advanced in the future. rdar://27446361
337 uint32_t imageCount = allImageInfo.infoArrayCount;
338 imageCount = MIN(imageCount, 8192);
339 size_t imageArraySize = imageCount * sizeof(T2);
340
341 withRemoteBuffer(task, infoArray, imageArraySize, false, kr, ^(void *buffer, size_t size) {
342 // figure out how many path strings will need to be copied and their size
343 T2* imageArray = (T2 *)buffer;
344 const dyld_all_image_infos* myInfo = _dyld_get_all_image_infos();
345 bool sameCacheAsThisProcess = !allImageInfo.processDetachedFromSharedRegion
346 && !myInfo->processDetachedFromSharedRegion
347 && ((memcmp(myInfo->sharedCacheUUID, &allImageInfo.sharedCacheUUID[0], 16) == 0)
348 && (myInfo->sharedCacheSlide == allImageInfo.sharedCacheSlide));
349 unsigned countOfPathsNeedingCopying = 0;
350 if ( sameCacheAsThisProcess ) {
351 for (uint32_t i=0; i < imageCount; ++i) {
352 if ( !inCache(imageArray[i].imageFilePath) )
353 ++countOfPathsNeedingCopying;
354 }
355 }
356 else {
357 countOfPathsNeedingCopying = imageCount+1;
358 }
359 unsigned imageCountWithDyld = imageCount+1;
360
361 // allocate result object
362 size_t allocationSize = sizeof(dyld_process_info_base)
363 + sizeof(dyld_process_cache_info)
364 + sizeof(dyld_process_aot_cache_info)
365 + sizeof(dyld_process_state_info)
366 + sizeof(ImageInfo)*(imageCountWithDyld)
367 + sizeof(dyld_aot_image_info_64)*(allImageInfo.aotInfoCount) // add the size necessary for aot info to this buffer
368 + sizeof(SegmentInfo)*imageCountWithDyld*10
369 + countOfPathsNeedingCopying*PATH_MAX;
370 void* storage = malloc(allocationSize);
371 if (storage == nullptr) {
372 *kr = KERN_NO_SPACE;
373 result = nullptr;
374 return;
375 }
376 auto info = dyld_process_info_ptr(new (storage) dyld_process_info_base(allImageInfo.platform, imageCountWithDyld, allImageInfo.aotInfoCount, allocationSize), deleter);
377 (void)info->reserveSpace(sizeof(dyld_process_info_base)+sizeof(dyld_process_cache_info)+sizeof(dyld_process_state_info)+sizeof(dyld_process_aot_cache_info));
378 (void)info->reserveSpace(sizeof(ImageInfo)*imageCountWithDyld);
379
380 // fill in base info
381 dyld_process_cache_info* cacheInfo = info->cacheInfo();
382 memcpy(cacheInfo->cacheUUID, &allImageInfo.sharedCacheUUID[0], 16);
383 cacheInfo->cacheBaseAddress = allImageInfo.sharedCacheBaseAddress;
384 cacheInfo->privateCache = allImageInfo.processDetachedFromSharedRegion;
385 // if no cache is used, allImageInfo has all zeros for cache UUID
386 cacheInfo->noCache = true;
387 for (int i=0; i < 16; ++i) {
388 if ( cacheInfo->cacheUUID[i] != 0 ) {
389 cacheInfo->noCache = false;
390 }
391 }
392
393 // fill in aot shared cache info
394 dyld_process_aot_cache_info* aotCacheInfo = info->aotCacheInfo();
395 memcpy(aotCacheInfo->cacheUUID, &allImageInfo.aotSharedCacheUUID[0], 16);
396 aotCacheInfo->cacheBaseAddress = allImageInfo.aotSharedCacheBaseAddress;
397
398 dyld_process_state_info* stateInfo = info->stateInfo();
399 stateInfo->timestamp = currentTimestamp;
400 stateInfo->imageCount = imageCountWithDyld;
401 stateInfo->initialImageCount = (uint32_t)(allImageInfo.initialImageCount+1);
402 stateInfo->dyldState = dyld_process_state_dyld_initialized;
403
404 if ( allImageInfo.libSystemInitialized != 0 ) {
405 stateInfo->dyldState = dyld_process_state_libSystem_initialized;
406 if ( allImageInfo.initialImageCount != imageCount ) {
407 stateInfo->dyldState = dyld_process_state_program_running;
408 }
409 }
410 if ( allImageInfo.errorMessage != 0 ) {
411 stateInfo->dyldState = allImageInfo.terminationFlags ? dyld_process_state_terminated_before_inits : dyld_process_state_dyld_terminated;
412 }
413 // fill in info for dyld
414 if ( allImageInfo.dyldPath != 0 ) {
415 if ((*kr = info->addDyldImage(task, allImageInfo.dyldImageLoadAddress, allImageInfo.dyldPath, NULL))) {
416 *kr = KERN_FAILURE;
417 result = nullptr;
418 return;
419 }
420 }
421 // fill in info for each image
422 for (uint32_t i=0; i < imageCount; ++i) {
423 if (!info->addImage(task, sameCacheAsThisProcess, imageArray[i].imageLoadAddress, imageArray[i].imageFilePath, NULL)) {
424 *kr = KERN_FAILURE;
425 result = nullptr;
426 return;
427 }
428 }
429 // sanity check internal data did not overflow
430 if ( info->invalid() ) {
431 *kr = KERN_FAILURE;
432 result = nullptr;
433 return;
434 }
435
436 result = std::move(info);
437 });
438
439 mach_vm_address_t aotImageArray = allImageInfo.aotInfoArray;
440 // shortcircuit this code path if aotImageArray == 0 (32 vs 64 bit struct difference)
441 // and if result == nullptr, since we need to append aot image infos to the process info struct
442 if (aotImageArray != 0 && result != nullptr) {
443 uint32_t aotImageCount = allImageInfo.aotInfoCount;
444 size_t aotImageArraySize = aotImageCount * sizeof(dyld_aot_image_info_64);
445
446 withRemoteBuffer(task, aotImageArray, aotImageArraySize, false, kr, ^(void *buffer, size_t size) {
447 dyld_aot_image_info_64* imageArray = (dyld_aot_image_info_64*)buffer;
448 for (uint32_t i = 0; i < aotImageCount; i++) {
449 if (!result->addAotImage(imageArray[i])) {
450 *kr = KERN_FAILURE;
451 result = nullptr;
452 return;
453 }
454 }
455 });
456 }
457 return std::move(result);
458 }
459
460 template<typename T>
461 dyld_process_info_ptr dyld_process_info_base::makeSuspended(task_t task, const T& allImageInfo, kern_return_t* kr)
462 {
463 pid_t pid;
464 if ((*kr = pid_for_task(task, &pid))) {
465 return NULL;
466 }
467
468 mach_task_basic_info ti;
469 mach_msg_type_number_t count = MACH_TASK_BASIC_INFO_COUNT;
470 if ((*kr = task_info(task, MACH_TASK_BASIC_INFO, (task_info_t)&ti, &count))) {
471 return nullptr;
472 }
473
474 // The task is not suspended, exit
475 if (ti.suspend_count == 0) {
476 return nullptr;
477 }
478
479 __block unsigned imageCount = 0; // main executable and dyld
480 __block uint64_t mainExecutableAddress = 0;
481 __block uint64_t dyldAddress = 0;
482 char dyldPathBuffer[PATH_MAX+1];
483 char mainExecutablePathBuffer[PATH_MAX+1];
484 __block char * dyldPath = &dyldPathBuffer[0];
485 __block char * mainExecutablePath = &mainExecutablePathBuffer[0];
486 __block dyld3::Platform platformID = dyld3::Platform::unknown;
487 mach_vm_size_t size;
488 for (mach_vm_address_t address = 0; ; address += size) {
489 vm_region_basic_info_data_64_t info;
490 mach_port_t objectName;
491 unsigned int infoCount = VM_REGION_BASIC_INFO_COUNT_64;
492 if (kern_return_t r = mach_vm_region(task, &address, &size, VM_REGION_BASIC_INFO,
493 (vm_region_info_t)&info, &infoCount, &objectName)) {
494 break;
495 }
496 if ( info.protection != (VM_PROT_READ|VM_PROT_EXECUTE) )
497 continue;
498 // read start of vm region to verify it is a mach header
499 withRemoteObject(task, address, NULL, ^(mach_header_64 mhBuffer){
500 if ( (mhBuffer.magic != MH_MAGIC) && (mhBuffer.magic != MH_MAGIC_64) )
501 return;
502 // now know the region is the start of a mach-o file
503 if ( mhBuffer.filetype == MH_EXECUTE ) {
504 mainExecutableAddress = address;
505 int len = proc_regionfilename(pid, mainExecutableAddress, mainExecutablePath, PATH_MAX);
506 if ( len != 0 ) {
507 mainExecutablePath[len] = '\0';
508 }
509 ++imageCount;
510 }
511 else if ( mhBuffer.filetype == MH_DYLINKER ) {
512 dyldAddress = address;
513 int len = proc_regionfilename(pid, dyldAddress, dyldPath, PATH_MAX);
514 if ( len != 0 ) {
515 dyldPath[len] = '\0';
516 }
517 ++imageCount;
518 }
519 });
520 //fprintf(stderr, "vm region: addr=0x%llX, size=0x%llX, prot=0x%X\n", (uint64_t)address, (uint64_t)size, info.protection);
521 }
522 //fprintf(stderr, "dyld: addr=0x%llX, path=%s\n", dyldAddress, dyldPathBuffer);
523 //fprintf(stderr, "app: addr=0x%llX, path=%s\n", mainExecutableAddress, mainExecutablePathBuffer);
524
525 // explicitly set aot image count to 0 in the suspended case
526 unsigned aotImageCount = 0;
527
528 // allocate result object
529 size_t allocationSize = sizeof(dyld_process_info_base)
530 + sizeof(dyld_process_cache_info)
531 + sizeof(dyld_process_aot_cache_info)
532 + sizeof(dyld_process_state_info)
533 + sizeof(ImageInfo)*(imageCount)
534 + sizeof(dyld_aot_image_info_64)*aotImageCount // this should always be 0, but including it here to be explicit
535 + sizeof(SegmentInfo)*imageCount*10
536 + imageCount*PATH_MAX;
537 void* storage = malloc(allocationSize);
538 if (storage == nullptr) {
539 *kr = KERN_NO_SPACE;
540 return nullptr;
541 }
542 auto obj = dyld_process_info_ptr(new (storage) dyld_process_info_base((dyld_platform_t)platformID, imageCount, aotImageCount, allocationSize), deleter);
543 (void)obj->reserveSpace(sizeof(dyld_process_info_base)+sizeof(dyld_process_cache_info)+sizeof(dyld_process_aot_cache_info)+sizeof(dyld_process_state_info));
544 // fill in base info
545 dyld_process_cache_info* cacheInfo = obj->cacheInfo();
546 bzero(cacheInfo->cacheUUID, 16);
547 cacheInfo->cacheBaseAddress = 0;
548 cacheInfo->noCache = true;
549 cacheInfo->privateCache = false;
550
551 // zero out aot cache info
552 dyld_process_aot_cache_info* aotCacheInfo = obj->aotCacheInfo();
553 bzero(aotCacheInfo->cacheUUID, 16);
554 aotCacheInfo->cacheBaseAddress = 0;
555
556 dyld_process_state_info* stateInfo = obj->stateInfo();
557 stateInfo->timestamp = 0;
558 stateInfo->imageCount = imageCount;
559 stateInfo->initialImageCount = imageCount;
560 stateInfo->dyldState = dyld_process_state_not_started;
561
562 // fill in info for dyld
563 if ( dyldAddress != 0 ) {
564 if ((*kr = obj->addDyldImage(task, dyldAddress, 0, dyldPath))) {
565 return nullptr;
566 }
567 }
568
569 // fill in info for each image
570 if ( mainExecutableAddress != 0 ) {
571 if (!obj->addImage(task, false, mainExecutableAddress, 0, mainExecutablePath)) {
572 return nullptr;
573 }
574 }
575
576 if (allImageInfo.infoArrayChangeTimestamp != 0) {
577 return nullptr;
578 }
579
580 count = MACH_TASK_BASIC_INFO_COUNT;
581 if ((*kr = task_info(task, MACH_TASK_BASIC_INFO, (task_info_t)&ti, &count))) {
582 return nullptr;
583 }
584
585 // The task is not suspended, exit
586 if (ti.suspend_count == 0) {
587 return nullptr;
588 }
589
590 return obj;
591 }
592
593
594
595 const char* dyld_process_info_base::addString(const char* str, size_t maxlen)
596 {
597 size_t len = strnlen(str, maxlen) + 1;
598 // If we don't have enough space return an empty string
599 if (!reserveSpace(len)) { return ""; }
600 _stringRevBumpPtr -= len;
601 strlcpy(_stringRevBumpPtr, str, len);
602 return _stringRevBumpPtr;
603 }
604
605 const char* dyld_process_info_base::copyPath(task_t task, uint64_t stringAddressInTask)
606 {
607 __block const char* retval = "";
608 withRemoteBuffer(task, stringAddressInTask, PATH_MAX, true, nullptr, ^(void *buffer, size_t size) {
609 retval = addString(static_cast<const char *>(buffer), size);
610 });
611 return retval;
612 }
613
614 bool dyld_process_info_base::addImage(task_t task, bool sameCacheAsThisProcess, uint64_t imageAddress, uint64_t imagePath, const char* imagePathLocal)
615 {
616 _curImage->loadAddress = imageAddress;
617 _curImage->segmentStartIndex = _curSegmentIndex;
618 if ( imagePathLocal != NULL ) {
619 _curImage->path = addString(imagePathLocal, PATH_MAX);
620 } else if ( sameCacheAsThisProcess && inCache(imagePath) ) {
621 _curImage->path = (const char*)imagePath;
622 } else if (imagePath) {
623 _curImage->path = copyPath(task, imagePath);
624 } else {
625 _curImage->path = "";
626 }
627
628 if ( sameCacheAsThisProcess && inCache(imageAddress) ) {
629 addInfoFromLoadCommands((mach_header*)imageAddress, imageAddress, 32*1024);
630 } else if (addInfoFromRemoteLoadCommands(task, imageAddress) != KERN_SUCCESS) {
631 // The image is not here, return early
632 return false;
633 }
634 _curImage->segmentsCount = _curSegmentIndex - _curImage->segmentStartIndex;
635 _curImage++;
636 return true;
637 }
638
639 bool dyld_process_info_base::addAotImage(dyld_aot_image_info_64 aotImageInfo) {
640 if (!reserveSpace(sizeof(dyld_aot_image_info_64))) {
641 return false;
642 }
643 _curAotImage->x86LoadAddress = aotImageInfo.x86LoadAddress;
644 _curAotImage->aotLoadAddress = aotImageInfo.aotLoadAddress;
645 _curAotImage->aotImageSize = aotImageInfo.aotImageSize;
646 memcpy(_curAotImage->aotImageKey, aotImageInfo.aotImageKey, sizeof(aotImageInfo.aotImageKey));
647
648 _curAotImage++;
649 return true;
650 }
651
652 kern_return_t dyld_process_info_base::addInfoFromRemoteLoadCommands(task_t task, uint64_t remoteMH) {
653 __block kern_return_t kr = KERN_SUCCESS;
654 __block size_t headerPagesSize = 0;
655 __block bool done = false;
656
657 //Since the minimum we can reasonably map is a page, map that.
658 withRemoteBuffer(task, remoteMH, PAGE_SIZE, false, &kr, ^(void * buffer, size_t size) {
659 const mach_header* mh = (const mach_header*)buffer;
660 headerPagesSize = sizeof(mach_header) + mh->sizeofcmds;
661 if (headerPagesSize <= PAGE_SIZE) {
662 addInfoFromLoadCommands(mh, remoteMH, size);
663 done = true;
664 }
665 });
666
667 //The load commands did not fit in the first page, but now we know the size, so remap and try again
668 if (!done) {
669 if (kr != KERN_SUCCESS) {
670 return kr;
671 }
672 withRemoteBuffer(task, remoteMH, headerPagesSize, false, &kr, ^(void * buffer, size_t size) {
673 addInfoFromLoadCommands((mach_header*)buffer, remoteMH, size);
674 });
675 }
676
677 return kr;
678 }
679
680 kern_return_t dyld_process_info_base::addDyldImage(task_t task, uint64_t dyldAddress, uint64_t dyldPathAddress, const char* localPath)
681 {
682 __block kern_return_t kr = KERN_SUCCESS;
683 _curImage->loadAddress = dyldAddress;
684 _curImage->segmentStartIndex = _curSegmentIndex;
685 if ( localPath != NULL ) {
686 _curImage->path = addString(localPath, PATH_MAX);
687 }
688 else {
689 _curImage->path = copyPath(task, dyldPathAddress);
690 if ( kr != KERN_SUCCESS)
691 return kr;
692 }
693
694 kr = addInfoFromRemoteLoadCommands(task, dyldAddress);
695 if ( kr != KERN_SUCCESS)
696 return kr;
697
698 _curImage->segmentsCount = _curSegmentIndex - _curImage->segmentStartIndex;
699 _curImage++;
700 return KERN_SUCCESS;
701 }
702
703
704 void dyld_process_info_base::addInfoFromLoadCommands(const mach_header* mh, uint64_t addressInTask, size_t size)
705 {
706 const load_command* startCmds = NULL;
707 if ( mh->magic == MH_MAGIC_64 )
708 startCmds = (load_command*)((char *)mh + sizeof(mach_header_64));
709 else if ( mh->magic == MH_MAGIC )
710 startCmds = (load_command*)((char *)mh + sizeof(mach_header));
711 else
712 return; // not a mach-o file, or wrong endianness
713
714 const load_command* const cmdsEnd = (load_command*)((char*)startCmds + mh->sizeofcmds);
715 const load_command* cmd = startCmds;
716 for(uint32_t i = 0; i < mh->ncmds; ++i) {
717 const load_command* nextCmd = (load_command*)((char *)cmd + cmd->cmdsize);
718 if ( (cmd->cmdsize < 8) || (nextCmd > cmdsEnd) || (nextCmd < startCmds) ) {
719 return; // malformed load command
720 }
721 if ( cmd->cmd == LC_UUID ) {
722 const uuid_command* uuidCmd = (uuid_command*)cmd;
723 memcpy(_curImage->uuid, uuidCmd->uuid, 16);
724 }
725 else if ( cmd->cmd == LC_SEGMENT ) {
726 if (!reserveSpace(sizeof(SegmentInfo))) { break; }
727 const segment_command* segCmd = (segment_command*)cmd;
728 _curSegment->name = copySegmentName(segCmd->segname);
729 _curSegment->addr = segCmd->vmaddr;
730 _curSegment->size = segCmd->vmsize;
731 _curSegment++;
732 _curSegmentIndex++;
733 }
734 else if ( cmd->cmd == LC_SEGMENT_64 ) {
735 if (!reserveSpace(sizeof(SegmentInfo))) { break; }
736 const segment_command_64* segCmd = (segment_command_64*)cmd;
737 _curSegment->name = copySegmentName(segCmd->segname);
738 _curSegment->addr = segCmd->vmaddr;
739 _curSegment->size = segCmd->vmsize;
740 _curSegment++;
741 _curSegmentIndex++;
742 }
743 cmd = nextCmd;
744 }
745 }
746
747 const char* dyld_process_info_base::copySegmentName(const char* name)
748 {
749 // don't copy names of standard segments into string pool
750 static const char* stdSegNames[] = {
751 "__TEXT", "__DATA", "__LINKEDIT",
752 "__DATA_DIRTY", "__DATA_CONST",
753 "__OBJC", "__OBJC_CONST",
754 "__AUTH", "__AUTH_CONST",
755 NULL
756 };
757 for (const char** s=stdSegNames; *s != NULL; ++s) {
758 if ( strcmp(name, *s) == 0 )
759 return *s;
760 }
761 // copy custom segment names into string pool
762 return addString(name, 16);
763 }
764
765 void dyld_process_info_base::forEachImage(void (^callback)(uint64_t machHeaderAddress, const uuid_t uuid, const char* path)) const
766 {
767 for (const ImageInfo* p = _firstImage; p < _curImage; ++p) {
768 callback(p->loadAddress, p->uuid, p->path);
769 }
770 }
771
772
773 #if TARGET_OS_OSX
774 void dyld_process_info_base::forEachAotImage(bool (^callback)(uint64_t x86Address, uint64_t aotAddress, uint64_t aotSize, uint8_t* aotImageKey, size_t aotImageKeySize)) const
775 {
776 for (const dyld_aot_image_info_64* p = _firstAotImage; p < _curAotImage; ++p) {
777 if (!callback(p->x86LoadAddress, p->aotLoadAddress, p->aotImageSize, (uint8_t*)p->aotImageKey, sizeof(p->aotImageKey))) {
778 break;
779 }
780 }
781 }
782 #endif
783
784 void dyld_process_info_base::forEachSegment(uint64_t machHeaderAddress, void (^callback)(uint64_t segmentAddress, uint64_t segmentSize, const char* segmentName)) const
785 {
786 for (const ImageInfo* p = _firstImage; p < _curImage; ++p) {
787 if ( p->loadAddress == machHeaderAddress ) {
788 uint64_t slide = 0;
789 for (uint32_t i=0; i < p->segmentsCount; ++i) {
790 const SegmentInfo* seg = &_firstSegment[p->segmentStartIndex+i];
791 if ( strcmp(seg->name, "__TEXT") == 0 ) {
792 slide = machHeaderAddress - seg->addr;
793 break;
794 }
795 }
796 for (uint32_t i=0; i < p->segmentsCount; ++i) {
797 const SegmentInfo* seg = &_firstSegment[p->segmentStartIndex+i];
798 callback(seg->addr + slide, seg->size, seg->name);
799 }
800 break;
801 }
802 }
803 }
804
805 dyld_process_info _dyld_process_info_create(task_t task, uint64_t timestamp, kern_return_t* kr)
806 {
807 __block dyld_process_info result = nullptr;
808 kern_return_t krSink = KERN_SUCCESS;
809 if (kr == nullptr) {
810 kr = &krSink;
811 }
812 *kr = KERN_SUCCESS;
813
814 task_dyld_info_data_t task_dyld_info;
815 mach_msg_type_number_t count = TASK_DYLD_INFO_COUNT;
816 if ( kern_return_t r = task_info(task, TASK_DYLD_INFO, (task_info_t)&task_dyld_info, &count) ) {
817 *kr = r;
818 return nullptr;
819 }
820
821 //The kernel will return MACH_VM_MIN_ADDRESS for an executable that has not had dyld loaded
822 if (task_dyld_info.all_image_info_addr == MACH_VM_MIN_ADDRESS) {
823 *kr = KERN_FAILURE;
824 return nullptr;
825 }
826
827 for (auto i = 0; i < 10; ++i) {
828 withRemoteBuffer(task, task_dyld_info.all_image_info_addr, (size_t)task_dyld_info.all_image_info_size, false, kr, ^(void *buffer, size_t size) {
829 dyld_process_info_ptr base;
830 if (task_dyld_info.all_image_info_format == TASK_DYLD_ALL_IMAGE_INFO_32 ) {
831 const dyld_all_image_infos_32* info = (const dyld_all_image_infos_32*)buffer;
832 base = dyld_process_info_base::make<dyld_all_image_infos_32, dyld_image_info_32>(task, *info, timestamp, kr);
833 } else {
834 const dyld_all_image_infos_64* info = (const dyld_all_image_infos_64*)buffer;
835 base = dyld_process_info_base::make<dyld_all_image_infos_64, dyld_image_info_64>(task, *info, timestamp, kr);
836 }
837 if (base) {
838 if (result) {
839 free((void*)result);
840 }
841 result = base.release();
842 }
843 });
844 if (kr == KERN_SUCCESS) { break; }
845 }
846 return result;
847 }
848
849 void _dyld_process_info_get_state(dyld_process_info info, dyld_process_state_info* stateInfo)
850 {
851 *stateInfo = *info->stateInfo();
852 }
853
854 void _dyld_process_info_get_cache(dyld_process_info info, dyld_process_cache_info* cacheInfo)
855 {
856 *cacheInfo = *info->cacheInfo();
857 }
858
859 void _dyld_process_info_get_aot_cache(dyld_process_info info, dyld_process_aot_cache_info* aotCacheInfo)
860 {
861 *aotCacheInfo = *info->aotCacheInfo();
862 }
863
864 void _dyld_process_info_retain(dyld_process_info object)
865 {
866 const_cast<dyld_process_info_base*>(object)->retain();
867 }
868
869 dyld_platform_t _dyld_process_info_get_platform(dyld_process_info object) {
870 return const_cast<dyld_process_info_base*>(object)->platform();
871 }
872
873 void _dyld_process_info_release(dyld_process_info object)
874 {
875 const_cast<dyld_process_info_base*>(object)->release();
876 }
877
878 void _dyld_process_info_for_each_image(dyld_process_info info, void (^callback)(uint64_t machHeaderAddress, const uuid_t uuid, const char* path))
879 {
880 info->forEachImage(callback);
881 }
882
883 #if TARGET_OS_OSX
884 void _dyld_process_info_for_each_aot_image(dyld_process_info info, bool (^callback)(uint64_t x86Address, uint64_t aotAddress, uint64_t aotSize, uint8_t* aotImageKey, size_t aotImageKeySize))
885 {
886 info->forEachAotImage(callback);
887 }
888 #endif
889
890 void _dyld_process_info_for_each_segment(dyld_process_info info, uint64_t machHeaderAddress, void (^callback)(uint64_t segmentAddress, uint64_t segmentSize, const char* segmentName))
891 {
892 info->forEachSegment(machHeaderAddress, callback);
893 }
894
895
896