/* * Copyright (C) 2017 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include #include #include #include #include #include #include #include #include #include "MemoryFileAtOffset.h" #include "MemoryRange.h" namespace unwindstack { bool MapInfo::InitFileMemoryFromPreviousReadOnlyMap(MemoryFileAtOffset* memory) { // One last attempt, see if the previous map is read-only with the // same name and stretches across this map. if (prev_real_map == nullptr || prev_real_map->flags != PROT_READ) { return false; } uint64_t map_size = end - prev_real_map->end; if (!memory->Init(name, prev_real_map->offset, map_size)) { return false; } uint64_t max_size; if (!Elf::GetInfo(memory, &max_size) || max_size < map_size) { return false; } if (!memory->Init(name, prev_real_map->offset, max_size)) { return false; } elf_offset = offset - prev_real_map->offset; elf_start_offset = prev_real_map->offset; return true; } Memory* MapInfo::GetFileMemory() { std::unique_ptr memory(new MemoryFileAtOffset); if (offset == 0) { if (memory->Init(name, 0)) { return memory.release(); } return nullptr; } // These are the possibilities when the offset is non-zero. // - There is an elf file embedded in a file, and the offset is the // the start of the elf in the file. // - There is an elf file embedded in a file, and the offset is the // the start of the executable part of the file. The actual start // of the elf is in the read-only segment preceeding this map. // - The whole file is an elf file, and the offset needs to be saved. // // Map in just the part of the file for the map. If this is not // a valid elf, then reinit as if the whole file is an elf file. // If the offset is a valid elf, then determine the size of the map // and reinit to that size. This is needed because the dynamic linker // only maps in a portion of the original elf, and never the symbol // file data. uint64_t map_size = end - start; if (!memory->Init(name, offset, map_size)) { return nullptr; } // Check if the start of this map is an embedded elf. uint64_t max_size = 0; if (Elf::GetInfo(memory.get(), &max_size)) { elf_start_offset = offset; if (max_size > map_size) { if (memory->Init(name, offset, max_size)) { return memory.release(); } // Try to reinit using the default map_size. if (memory->Init(name, offset, map_size)) { return memory.release(); } elf_start_offset = 0; return nullptr; } return memory.release(); } // No elf at offset, try to init as if the whole file is an elf. if (memory->Init(name, 0) && Elf::IsValidElf(memory.get())) { elf_offset = offset; // Need to check how to set the elf start offset. If this map is not // the r-x map of a r-- map, then use the real offset value. Otherwise, // use 0. if (prev_real_map == nullptr || prev_real_map->offset != 0 || prev_real_map->flags != PROT_READ || prev_real_map->name != name) { elf_start_offset = offset; } return memory.release(); } // See if the map previous to this one contains a read-only map // that represents the real start of the elf data. if (InitFileMemoryFromPreviousReadOnlyMap(memory.get())) { return memory.release(); } // Failed to find elf at start of file or at read-only map, return // file object from the current map. if (memory->Init(name, offset, map_size)) { return memory.release(); } return nullptr; } Memory* MapInfo::CreateMemory(const std::shared_ptr& process_memory) { if (end <= start) { return nullptr; } elf_offset = 0; // Fail on device maps. if (flags & MAPS_FLAGS_DEVICE_MAP) { return nullptr; } // First try and use the file associated with the info. if (!name.empty()) { Memory* memory = GetFileMemory(); if (memory != nullptr) { return memory; } } if (process_memory == nullptr) { return nullptr; } memory_backed_elf = true; // Need to verify that this elf is valid. It's possible that // only part of the elf file to be mapped into memory is in the executable // map. In this case, there will be another read-only map that includes the // first part of the elf file. This is done if the linker rosegment // option is used. std::unique_ptr memory(new MemoryRange(process_memory, start, end - start, 0)); if (Elf::IsValidElf(memory.get())) { // Might need to peek at the next map to create a memory object that // includes that map too. if (offset != 0 || name.empty() || next_real_map == nullptr || offset >= next_real_map->offset || next_real_map->name != name) { return memory.release(); } // There is a possibility that the elf object has already been created // in the next map. Since this should be a very uncommon path, just // redo the work. If this happens, the elf for this map will eventually // be discarded. MemoryRanges* ranges = new MemoryRanges; ranges->Insert(new MemoryRange(process_memory, start, end - start, 0)); ranges->Insert(new MemoryRange(process_memory, next_real_map->start, next_real_map->end - next_real_map->start, next_real_map->offset - offset)); return ranges; } // Find the read-only map by looking at the previous map. The linker // doesn't guarantee that this invariant will always be true. However, // if that changes, there is likely something else that will change and // break something. if (offset == 0 || name.empty() || prev_real_map == nullptr || prev_real_map->name != name || prev_real_map->offset >= offset) { memory_backed_elf = false; return nullptr; } // Make sure that relative pc values are corrected properly. elf_offset = offset - prev_real_map->offset; // Use this as the elf start offset, otherwise, you always get offsets into // the r-x section, which is not quite the right information. elf_start_offset = prev_real_map->offset; MemoryRanges* ranges = new MemoryRanges; ranges->Insert(new MemoryRange(process_memory, prev_real_map->start, prev_real_map->end - prev_real_map->start, 0)); ranges->Insert(new MemoryRange(process_memory, start, end - start, elf_offset)); return ranges; } Elf* MapInfo::GetElf(const std::shared_ptr& process_memory, ArchEnum expected_arch) { { // Make sure no other thread is trying to add the elf to this map. std::lock_guard guard(mutex_); if (elf.get() != nullptr) { return elf.get(); } bool locked = false; if (Elf::CachingEnabled() && !name.empty()) { Elf::CacheLock(); locked = true; if (Elf::CacheGet(this)) { Elf::CacheUnlock(); return elf.get(); } } Memory* memory = CreateMemory(process_memory); if (locked) { if (Elf::CacheAfterCreateMemory(this)) { delete memory; Elf::CacheUnlock(); return elf.get(); } } elf.reset(new Elf(memory)); // If the init fails, keep the elf around as an invalid object so we // don't try to reinit the object. elf->Init(); if (elf->valid() && expected_arch != elf->arch()) { // Make the elf invalid, mismatch between arch and expected arch. elf->Invalidate(); } if (locked) { Elf::CacheAdd(this); Elf::CacheUnlock(); } } if (!elf->valid()) { elf_start_offset = offset; } else if (prev_real_map != nullptr && elf_start_offset != offset && prev_real_map->offset == elf_start_offset && prev_real_map->name == name) { // If there is a read-only map then a read-execute map that represents the // same elf object, make sure the previous map is using the same elf // object if it hasn't already been set. std::lock_guard guard(prev_real_map->mutex_); if (prev_real_map->elf.get() == nullptr) { prev_real_map->elf = elf; prev_real_map->memory_backed_elf = memory_backed_elf; } else { // Discard this elf, and use the elf from the previous map instead. elf = prev_real_map->elf; } } return elf.get(); } bool MapInfo::GetFunctionName(uint64_t addr, std::string* name, uint64_t* func_offset) { { // Make sure no other thread is trying to update this elf object. std::lock_guard guard(mutex_); if (elf == nullptr) { return false; } } // No longer need the lock, once the elf object is created, it is not deleted // until this object is deleted. return elf->GetFunctionName(addr, name, func_offset); } uint64_t MapInfo::GetLoadBias(const std::shared_ptr& process_memory) { int64_t cur_load_bias = load_bias.load(); if (cur_load_bias != INT64_MAX) { return cur_load_bias; } { // Make sure no other thread is trying to add the elf to this map. std::lock_guard guard(mutex_); if (elf != nullptr) { if (elf->valid()) { cur_load_bias = elf->GetLoadBias(); load_bias = cur_load_bias; return cur_load_bias; } else { load_bias = 0; return 0; } } } // Call lightweight static function that will only read enough of the // elf data to get the load bias. std::unique_ptr memory(CreateMemory(process_memory)); cur_load_bias = Elf::GetLoadBias(memory.get()); load_bias = cur_load_bias; return cur_load_bias; } MapInfo::~MapInfo() { std::string* id = build_id.load(); if (id != nullptr) { delete id; } } const std::string& MapInfo::GetBuildID() { std::string* id = build_id.load(); if (id != nullptr) { return *id; } // No need to lock, at worst if multiple threads do this at the same // time it should be detected and only one thread should win and // save the data. std::unique_ptr cur_build_id(new std::string); // Now need to see if the elf object exists. // Make sure no other thread is trying to add the elf to this map. mutex_.lock(); Elf* elf_obj = elf.get(); mutex_.unlock(); if (elf_obj != nullptr) { *cur_build_id = elf_obj->GetBuildID(); } else { // This will only work if we can get the file associated with this memory. // If this is only available in memory, then the section name information // is not present and we will not be able to find the build id info. std::unique_ptr memory(GetFileMemory()); if (memory != nullptr) { *cur_build_id = Elf::GetBuildID(memory.get()); } } std::string* expected_id = nullptr; // Strong version since we need to reliably return the stored pointer. if (build_id.compare_exchange_strong(expected_id, cur_build_id.get())) { // Value saved, so make sure the memory is not freed. return *cur_build_id.release(); } else { // The expected value is set to the stored value on failure. return *expected_id; } } std::string MapInfo::GetPrintableBuildID() { std::string raw_build_id = GetBuildID(); if (raw_build_id.empty()) { return ""; } std::string printable_build_id; for (const char& c : raw_build_id) { // Use %hhx to avoid sign extension on abis that have signed chars. printable_build_id += android::base::StringPrintf("%02hhx", c); } return printable_build_id; } } // namespace unwindstack