/* * Copyright (C) 2015 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 "offline_profiling_info.h" #include "errno.h" #include #include #include #include #include #include "art_method-inl.h" #include "base/mutex.h" #include "base/scoped_flock.h" #include "base/stl_util.h" #include "base/systrace.h" #include "base/unix_file/fd_file.h" #include "jit/profiling_info.h" #include "os.h" #include "safe_map.h" namespace art { const uint8_t ProfileCompilationInfo::kProfileMagic[] = { 'p', 'r', 'o', '\0' }; const uint8_t ProfileCompilationInfo::kProfileVersion[] = { '0', '0', '1', '\0' }; static constexpr uint16_t kMaxDexFileKeyLength = PATH_MAX; // Transform the actual dex location into relative paths. // Note: this is OK because we don't store profiles of different apps into the same file. // Apps with split apks don't cause trouble because each split has a different name and will not // collide with other entries. std::string ProfileCompilationInfo::GetProfileDexFileKey(const std::string& dex_location) { DCHECK(!dex_location.empty()); size_t last_sep_index = dex_location.find_last_of('/'); if (last_sep_index == std::string::npos) { return dex_location; } else { DCHECK(last_sep_index < dex_location.size()); return dex_location.substr(last_sep_index + 1); } } bool ProfileCompilationInfo::AddMethodsAndClasses( const std::vector& methods, const std::set& resolved_classes) { for (const MethodReference& method : methods) { if (!AddMethodIndex(GetProfileDexFileKey(method.dex_file->GetLocation()), method.dex_file->GetLocationChecksum(), method.dex_method_index)) { return false; } } for (const DexCacheResolvedClasses& dex_cache : resolved_classes) { if (!AddResolvedClasses(dex_cache)) { return false; } } return true; } bool ProfileCompilationInfo::MergeAndSave(const std::string& filename, uint64_t* bytes_written, bool force) { ScopedTrace trace(__PRETTY_FUNCTION__); ScopedFlock flock; std::string error; if (!flock.Init(filename.c_str(), O_RDWR | O_NOFOLLOW | O_CLOEXEC, /* block */ false, &error)) { LOG(WARNING) << "Couldn't lock the profile file " << filename << ": " << error; return false; } int fd = flock.GetFile()->Fd(); // Load the file but keep a copy around to be able to infer if the content has changed. ProfileCompilationInfo fileInfo; ProfileLoadSatus status = fileInfo.LoadInternal(fd, &error); if (status == kProfileLoadSuccess) { // Merge the content of file into the current object. if (MergeWith(fileInfo)) { // If after the merge we have the same data as what is the file there's no point // in actually doing the write. The file will be exactly the same as before. if (Equals(fileInfo)) { if (bytes_written != nullptr) { *bytes_written = 0; } return true; } } else { LOG(WARNING) << "Could not merge previous profile data from file " << filename; if (!force) { return false; } } } else if (force && ((status == kProfileLoadVersionMismatch) || (status == kProfileLoadBadData))) { // Log a warning but don't return false. We will clear the profile anyway. LOG(WARNING) << "Clearing bad or obsolete profile data from file " << filename << ": " << error; } else { LOG(WARNING) << "Could not load profile data from file " << filename << ": " << error; return false; } // We need to clear the data because we don't support appending to the profiles yet. if (!flock.GetFile()->ClearContent()) { PLOG(WARNING) << "Could not clear profile file: " << filename; return false; } // This doesn't need locking because we are trying to lock the file for exclusive // access and fail immediately if we can't. bool result = Save(fd); if (result) { VLOG(profiler) << "Successfully saved profile info to " << filename << " Size: " << GetFileSizeBytes(filename); if (bytes_written != nullptr) { *bytes_written = GetFileSizeBytes(filename); } } else { VLOG(profiler) << "Failed to save profile info to " << filename; } return result; } // Returns true if all the bytes were successfully written to the file descriptor. static bool WriteBuffer(int fd, const uint8_t* buffer, size_t byte_count) { while (byte_count > 0) { int bytes_written = TEMP_FAILURE_RETRY(write(fd, buffer, byte_count)); if (bytes_written == -1) { return false; } byte_count -= bytes_written; // Reduce the number of remaining bytes. buffer += bytes_written; // Move the buffer forward. } return true; } // Add the string bytes to the buffer. static void AddStringToBuffer(std::vector* buffer, const std::string& value) { buffer->insert(buffer->end(), value.begin(), value.end()); } // Insert each byte, from low to high into the buffer. template static void AddUintToBuffer(std::vector* buffer, T value) { for (size_t i = 0; i < sizeof(T); i++) { buffer->push_back((value >> (i * kBitsPerByte)) & 0xff); } } static constexpr size_t kLineHeaderSize = 3 * sizeof(uint16_t) + // method_set.size + class_set.size + dex_location.size sizeof(uint32_t); // checksum /** * Serialization format: * magic,version,number_of_lines * dex_location1,number_of_methods1,number_of_classes1,dex_location_checksum1, \ * method_id11,method_id12...,class_id1,class_id2... * dex_location2,number_of_methods2,number_of_classes2,dex_location_checksum2, \ * method_id21,method_id22...,,class_id1,class_id2... * ..... **/ bool ProfileCompilationInfo::Save(int fd) { ScopedTrace trace(__PRETTY_FUNCTION__); DCHECK_GE(fd, 0); // Cache at most 5KB before writing. static constexpr size_t kMaxSizeToKeepBeforeWriting = 5 * KB; // Use a vector wrapper to avoid keeping track of offsets when we add elements. std::vector buffer; WriteBuffer(fd, kProfileMagic, sizeof(kProfileMagic)); WriteBuffer(fd, kProfileVersion, sizeof(kProfileVersion)); AddUintToBuffer(&buffer, static_cast(info_.size())); for (const auto& it : info_) { if (buffer.size() > kMaxSizeToKeepBeforeWriting) { if (!WriteBuffer(fd, buffer.data(), buffer.size())) { return false; } buffer.clear(); } const std::string& dex_location = it.first; const DexFileData& dex_data = it.second; if (dex_data.method_set.empty() && dex_data.class_set.empty()) { continue; } if (dex_location.size() >= kMaxDexFileKeyLength) { LOG(WARNING) << "DexFileKey exceeds allocated limit"; return false; } // Make sure that the buffer has enough capacity to avoid repeated resizings // while we add data. size_t required_capacity = buffer.size() + kLineHeaderSize + dex_location.size() + sizeof(uint16_t) * (dex_data.class_set.size() + dex_data.method_set.size()); buffer.reserve(required_capacity); DCHECK_LE(dex_location.size(), std::numeric_limits::max()); DCHECK_LE(dex_data.method_set.size(), std::numeric_limits::max()); DCHECK_LE(dex_data.class_set.size(), std::numeric_limits::max()); AddUintToBuffer(&buffer, static_cast(dex_location.size())); AddUintToBuffer(&buffer, static_cast(dex_data.method_set.size())); AddUintToBuffer(&buffer, static_cast(dex_data.class_set.size())); AddUintToBuffer(&buffer, dex_data.checksum); // uint32_t AddStringToBuffer(&buffer, dex_location); for (auto method_it : dex_data.method_set) { AddUintToBuffer(&buffer, method_it); } for (auto class_id : dex_data.class_set) { AddUintToBuffer(&buffer, class_id); } DCHECK_EQ(required_capacity, buffer.size()) << "Failed to add the expected number of bytes in the buffer"; } return WriteBuffer(fd, buffer.data(), buffer.size()); } ProfileCompilationInfo::DexFileData* ProfileCompilationInfo::GetOrAddDexFileData( const std::string& dex_location, uint32_t checksum) { auto info_it = info_.find(dex_location); if (info_it == info_.end()) { info_it = info_.Put(dex_location, DexFileData(checksum)); } if (info_it->second.checksum != checksum) { LOG(WARNING) << "Checksum mismatch for dex " << dex_location; return nullptr; } return &info_it->second; } bool ProfileCompilationInfo::AddResolvedClasses(const DexCacheResolvedClasses& classes) { const std::string dex_location = GetProfileDexFileKey(classes.GetDexLocation()); const uint32_t checksum = classes.GetLocationChecksum(); DexFileData* const data = GetOrAddDexFileData(dex_location, checksum); if (data == nullptr) { return false; } data->class_set.insert(classes.GetClasses().begin(), classes.GetClasses().end()); return true; } bool ProfileCompilationInfo::AddMethodIndex(const std::string& dex_location, uint32_t checksum, uint16_t method_idx) { DexFileData* const data = GetOrAddDexFileData(dex_location, checksum); if (data == nullptr) { return false; } data->method_set.insert(method_idx); return true; } bool ProfileCompilationInfo::AddClassIndex(const std::string& dex_location, uint32_t checksum, uint16_t class_idx) { DexFileData* const data = GetOrAddDexFileData(dex_location, checksum); if (data == nullptr) { return false; } data->class_set.insert(class_idx); return true; } bool ProfileCompilationInfo::ProcessLine(SafeBuffer& line_buffer, uint16_t method_set_size, uint16_t class_set_size, uint32_t checksum, const std::string& dex_location) { for (uint16_t i = 0; i < method_set_size; i++) { uint16_t method_idx = line_buffer.ReadUintAndAdvance(); if (!AddMethodIndex(dex_location, checksum, method_idx)) { return false; } } for (uint16_t i = 0; i < class_set_size; i++) { uint16_t class_def_idx = line_buffer.ReadUintAndAdvance(); if (!AddClassIndex(dex_location, checksum, class_def_idx)) { return false; } } return true; } // Tests for EOF by trying to read 1 byte from the descriptor. // Returns: // 0 if the descriptor is at the EOF, // -1 if there was an IO error // 1 if the descriptor has more content to read static int testEOF(int fd) { uint8_t buffer[1]; return TEMP_FAILURE_RETRY(read(fd, buffer, 1)); } // Reads an uint value previously written with AddUintToBuffer. template T ProfileCompilationInfo::SafeBuffer::ReadUintAndAdvance() { static_assert(std::is_unsigned::value, "Type is not unsigned"); CHECK_LE(ptr_current_ + sizeof(T), ptr_end_); T value = 0; for (size_t i = 0; i < sizeof(T); i++) { value += ptr_current_[i] << (i * kBitsPerByte); } ptr_current_ += sizeof(T); return value; } bool ProfileCompilationInfo::SafeBuffer::CompareAndAdvance(const uint8_t* data, size_t data_size) { if (ptr_current_ + data_size > ptr_end_) { return false; } if (memcmp(ptr_current_, data, data_size) == 0) { ptr_current_ += data_size; return true; } return false; } ProfileCompilationInfo::ProfileLoadSatus ProfileCompilationInfo::SafeBuffer::FillFromFd( int fd, const std::string& source, /*out*/std::string* error) { size_t byte_count = ptr_end_ - ptr_current_; uint8_t* buffer = ptr_current_; while (byte_count > 0) { int bytes_read = TEMP_FAILURE_RETRY(read(fd, buffer, byte_count)); if (bytes_read == 0) { *error += "Profile EOF reached prematurely for " + source; return kProfileLoadBadData; } else if (bytes_read < 0) { *error += "Profile IO error for " + source + strerror(errno); return kProfileLoadIOError; } byte_count -= bytes_read; buffer += bytes_read; } return kProfileLoadSuccess; } ProfileCompilationInfo::ProfileLoadSatus ProfileCompilationInfo::ReadProfileHeader( int fd, /*out*/uint16_t* number_of_lines, /*out*/std::string* error) { // Read magic and version const size_t kMagicVersionSize = sizeof(kProfileMagic) + sizeof(kProfileVersion) + sizeof(uint16_t); // number of lines SafeBuffer safe_buffer(kMagicVersionSize); ProfileLoadSatus status = safe_buffer.FillFromFd(fd, "ReadProfileHeader", error); if (status != kProfileLoadSuccess) { return status; } if (!safe_buffer.CompareAndAdvance(kProfileMagic, sizeof(kProfileMagic))) { *error = "Profile missing magic"; return kProfileLoadVersionMismatch; } if (!safe_buffer.CompareAndAdvance(kProfileVersion, sizeof(kProfileVersion))) { *error = "Profile version mismatch"; return kProfileLoadVersionMismatch; } *number_of_lines = safe_buffer.ReadUintAndAdvance(); return kProfileLoadSuccess; } ProfileCompilationInfo::ProfileLoadSatus ProfileCompilationInfo::ReadProfileLineHeader( int fd, /*out*/ProfileLineHeader* line_header, /*out*/std::string* error) { SafeBuffer header_buffer(kLineHeaderSize); ProfileLoadSatus status = header_buffer.FillFromFd(fd, "ReadProfileHeader", error); if (status != kProfileLoadSuccess) { return status; } uint16_t dex_location_size = header_buffer.ReadUintAndAdvance(); line_header->method_set_size = header_buffer.ReadUintAndAdvance(); line_header->class_set_size = header_buffer.ReadUintAndAdvance(); line_header->checksum = header_buffer.ReadUintAndAdvance(); if (dex_location_size == 0 || dex_location_size > kMaxDexFileKeyLength) { *error = "DexFileKey has an invalid size: " + std::to_string(dex_location_size); return kProfileLoadBadData; } SafeBuffer location_buffer(dex_location_size); status = location_buffer.FillFromFd(fd, "ReadProfileHeaderDexLocation", error); if (status != kProfileLoadSuccess) { return status; } line_header->dex_location.assign( reinterpret_cast(location_buffer.Get()), dex_location_size); return kProfileLoadSuccess; } ProfileCompilationInfo::ProfileLoadSatus ProfileCompilationInfo::ReadProfileLine( int fd, const ProfileLineHeader& line_header, /*out*/std::string* error) { // Make sure that we don't try to read everything in memory (in case the profile if full). // Split readings in chunks of at most 10kb. static constexpr uint16_t kMaxNumberOfEntriesToRead = 5120; uint16_t methods_left_to_read = line_header.method_set_size; uint16_t classes_left_to_read = line_header.class_set_size; while ((methods_left_to_read > 0) || (classes_left_to_read > 0)) { uint16_t methods_to_read = std::min(kMaxNumberOfEntriesToRead, methods_left_to_read); uint16_t max_classes_to_read = kMaxNumberOfEntriesToRead - methods_to_read; uint16_t classes_to_read = std::min(max_classes_to_read, classes_left_to_read); size_t line_size = sizeof(uint16_t) * (methods_to_read + classes_to_read); SafeBuffer line_buffer(line_size); ProfileLoadSatus status = line_buffer.FillFromFd(fd, "ReadProfileLine", error); if (status != kProfileLoadSuccess) { return status; } if (!ProcessLine(line_buffer, methods_to_read, classes_to_read, line_header.checksum, line_header.dex_location)) { *error = "Error when reading profile file line"; return kProfileLoadBadData; } methods_left_to_read -= methods_to_read; classes_left_to_read -= classes_to_read; } return kProfileLoadSuccess; } bool ProfileCompilationInfo::Load(int fd) { std::string error; ProfileLoadSatus status = LoadInternal(fd, &error); if (status == kProfileLoadSuccess) { return true; } else { PLOG(WARNING) << "Error when reading profile " << error; return false; } } ProfileCompilationInfo::ProfileLoadSatus ProfileCompilationInfo::LoadInternal( int fd, std::string* error) { ScopedTrace trace(__PRETTY_FUNCTION__); DCHECK_GE(fd, 0); struct stat stat_buffer; if (fstat(fd, &stat_buffer) != 0) { return kProfileLoadIOError; } // We allow empty profile files. // Profiles may be created by ActivityManager or installd before we manage to // process them in the runtime or profman. if (stat_buffer.st_size == 0) { return kProfileLoadSuccess; } // Read profile header: magic + version + number_of_lines. uint16_t number_of_lines; ProfileLoadSatus status = ReadProfileHeader(fd, &number_of_lines, error); if (status != kProfileLoadSuccess) { return status; } while (number_of_lines > 0) { ProfileLineHeader line_header; // First, read the line header to get the amount of data we need to read. status = ReadProfileLineHeader(fd, &line_header, error); if (status != kProfileLoadSuccess) { return status; } // Now read the actual profile line. status = ReadProfileLine(fd, line_header, error); if (status != kProfileLoadSuccess) { return status; } number_of_lines--; } // Check that we read everything and that profiles don't contain junk data. int result = testEOF(fd); if (result == 0) { return kProfileLoadSuccess; } else if (result < 0) { return kProfileLoadIOError; } else { *error = "Unexpected content in the profile file"; return kProfileLoadBadData; } } bool ProfileCompilationInfo::MergeWith(const ProfileCompilationInfo& other) { // First verify that all checksums match. This will avoid adding garbage to // the current profile info. // Note that the number of elements should be very small, so this should not // be a performance issue. for (const auto& other_it : other.info_) { auto info_it = info_.find(other_it.first); if ((info_it != info_.end()) && (info_it->second.checksum != other_it.second.checksum)) { LOG(WARNING) << "Checksum mismatch for dex " << other_it.first; return false; } } // All checksums match. Import the data. for (const auto& other_it : other.info_) { const std::string& other_dex_location = other_it.first; const DexFileData& other_dex_data = other_it.second; auto info_it = info_.find(other_dex_location); if (info_it == info_.end()) { info_it = info_.Put(other_dex_location, DexFileData(other_dex_data.checksum)); } info_it->second.method_set.insert(other_dex_data.method_set.begin(), other_dex_data.method_set.end()); info_it->second.class_set.insert(other_dex_data.class_set.begin(), other_dex_data.class_set.end()); } return true; } bool ProfileCompilationInfo::ContainsMethod(const MethodReference& method_ref) const { auto info_it = info_.find(GetProfileDexFileKey(method_ref.dex_file->GetLocation())); if (info_it != info_.end()) { if (method_ref.dex_file->GetLocationChecksum() != info_it->second.checksum) { return false; } const std::set& methods = info_it->second.method_set; return methods.find(method_ref.dex_method_index) != methods.end(); } return false; } bool ProfileCompilationInfo::ContainsClass(const DexFile& dex_file, uint16_t class_def_idx) const { auto info_it = info_.find(GetProfileDexFileKey(dex_file.GetLocation())); if (info_it != info_.end()) { if (dex_file.GetLocationChecksum() != info_it->second.checksum) { return false; } const std::set& classes = info_it->second.class_set; return classes.find(class_def_idx) != classes.end(); } return false; } uint32_t ProfileCompilationInfo::GetNumberOfMethods() const { uint32_t total = 0; for (const auto& it : info_) { total += it.second.method_set.size(); } return total; } uint32_t ProfileCompilationInfo::GetNumberOfResolvedClasses() const { uint32_t total = 0; for (const auto& it : info_) { total += it.second.class_set.size(); } return total; } std::string ProfileCompilationInfo::DumpInfo(const std::vector* dex_files, bool print_full_dex_location) const { std::ostringstream os; if (info_.empty()) { return "ProfileInfo: empty"; } os << "ProfileInfo:"; const std::string kFirstDexFileKeySubstitute = ":classes.dex"; for (const auto& it : info_) { os << "\n"; const std::string& location = it.first; const DexFileData& dex_data = it.second; if (print_full_dex_location) { os << location; } else { // Replace the (empty) multidex suffix of the first key with a substitute for easier reading. std::string multidex_suffix = DexFile::GetMultiDexSuffix(location); os << (multidex_suffix.empty() ? kFirstDexFileKeySubstitute : multidex_suffix); } const DexFile* dex_file = nullptr; if (dex_files != nullptr) { for (size_t i = 0; i < dex_files->size(); i++) { if (location == (*dex_files)[i]->GetLocation()) { dex_file = (*dex_files)[i]; } } } os << "\n\tmethods: "; for (const auto method_it : dex_data.method_set) { if (dex_file != nullptr) { os << "\n\t\t" << PrettyMethod(method_it, *dex_file, true); } else { os << method_it << ","; } } os << "\n\tclasses: "; for (const auto class_it : dex_data.class_set) { if (dex_file != nullptr) { os << "\n\t\t" << PrettyType(class_it, *dex_file); } else { os << class_it << ","; } } } return os.str(); } bool ProfileCompilationInfo::Equals(const ProfileCompilationInfo& other) { return info_.Equals(other.info_); } std::set ProfileCompilationInfo::GetResolvedClasses() const { std::set ret; for (auto&& pair : info_) { const std::string& profile_key = pair.first; const DexFileData& data = pair.second; // TODO: Is it OK to use the same location for both base and dex location here? DexCacheResolvedClasses classes(profile_key, profile_key, data.checksum); classes.AddClasses(data.class_set.begin(), data.class_set.end()); ret.insert(classes); } return ret; } void ProfileCompilationInfo::ClearResolvedClasses() { for (auto& pair : info_) { pair.second.class_set.clear(); } } } // namespace art