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/*
* Copyright (C) 2021 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 "artd.h"
#include <fcntl.h>
#include <sys/mount.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <unistd.h>
#include <climits>
#include <csignal>
#include <cstddef>
#include <cstdint>
#include <cstdlib>
#include <cstring>
#include <filesystem>
#include <functional>
#include <iterator>
#include <map>
#include <memory>
#include <mutex>
#include <optional>
#include <ostream>
#include <regex>
#include <string>
#include <string_view>
#include <system_error>
#include <type_traits>
#include <unordered_set>
#include <utility>
#include <vector>
#include "aidl/com/android/server/art/BnArtd.h"
#include "aidl/com/android/server/art/DexoptTrigger.h"
#include "aidl/com/android/server/art/IArtdCancellationSignal.h"
#include "android-base/errors.h"
#include "android-base/file.h"
#include "android-base/logging.h"
#include "android-base/result.h"
#include "android-base/scopeguard.h"
#include "android-base/strings.h"
#include "android/binder_auto_utils.h"
#include "android/binder_interface_utils.h"
#include "android/binder_manager.h"
#include "android/binder_process.h"
#include "base/compiler_filter.h"
#include "base/file_magic.h"
#include "base/file_utils.h"
#include "base/globals.h"
#include "base/logging.h"
#include "base/macros.h"
#include "base/mem_map.h"
#include "base/memfd.h"
#include "base/os.h"
#include "base/zip_archive.h"
#include "cmdline_types.h"
#include "dex/dex_file_loader.h"
#include "exec_utils.h"
#include "file_utils.h"
#include "fstab/fstab.h"
#include "oat/oat_file_assistant.h"
#include "oat/oat_file_assistant_context.h"
#include "odrefresh/odrefresh.h"
#include "path_utils.h"
#include "profman/profman_result.h"
#include "selinux/android.h"
#include "service.h"
#include "tools/binder_utils.h"
#include "tools/cmdline_builder.h"
#include "tools/tools.h"
namespace art {
namespace artd {
namespace {
using ::aidl::com::android::server::art::ArtdDexoptResult;
using ::aidl::com::android::server::art::ArtifactsLocation;
using ::aidl::com::android::server::art::ArtifactsPath;
using ::aidl::com::android::server::art::CopyAndRewriteProfileResult;
using ::aidl::com::android::server::art::DexMetadataPath;
using ::aidl::com::android::server::art::DexoptOptions;
using ::aidl::com::android::server::art::DexoptTrigger;
using ::aidl::com::android::server::art::FileVisibility;
using ::aidl::com::android::server::art::FsPermission;
using ::aidl::com::android::server::art::GetDexoptNeededResult;
using ::aidl::com::android::server::art::GetDexoptStatusResult;
using ::aidl::com::android::server::art::IArtdCancellationSignal;
using ::aidl::com::android::server::art::MergeProfileOptions;
using ::aidl::com::android::server::art::OutputArtifacts;
using ::aidl::com::android::server::art::OutputProfile;
using ::aidl::com::android::server::art::PriorityClass;
using ::aidl::com::android::server::art::ProfilePath;
using ::aidl::com::android::server::art::RuntimeArtifactsPath;
using ::aidl::com::android::server::art::VdexPath;
using ::android::base::Dirname;
using ::android::base::ErrnoError;
using ::android::base::Error;
using ::android::base::Join;
using ::android::base::make_scope_guard;
using ::android::base::ReadFileToString;
using ::android::base::Result;
using ::android::base::Split;
using ::android::base::StringReplace;
using ::android::base::Tokenize;
using ::android::base::WriteStringToFd;
using ::android::base::WriteStringToFile;
using ::android::fs_mgr::FstabEntry;
using ::art::service::ValidateClassLoaderContext;
using ::art::service::ValidateDexPath;
using ::art::tools::CmdlineBuilder;
using ::art::tools::Fatal;
using ::art::tools::GetProcMountsAncestorsOfPath;
using ::art::tools::NonFatal;
using ::ndk::ScopedAStatus;
using TmpProfilePath = ProfilePath::TmpProfilePath;
using WritableProfilePath = ProfilePath::WritableProfilePath;
constexpr const char* kServiceName = "artd";
constexpr const char* kPreRebootServiceName = "artd_pre_reboot";
constexpr const char* kArtdCancellationSignalType = "ArtdCancellationSignal";
constexpr const char* kDefaultPreRebootTmpDir = "/mnt/artd_tmp";
// Timeout for short operations, such as merging profiles.
constexpr int kShortTimeoutSec = 60; // 1 minute.
// Timeout for long operations, such as compilation. We set it to be smaller than the Package
// Manager watchdog (PackageManagerService.WATCHDOG_TIMEOUT, 10 minutes), so that if the operation
// is called from the Package Manager's thread handler, it will be aborted before that watchdog
// would take down the system server.
constexpr int kLongTimeoutSec = 570; // 9.5 minutes.
std::optional<int64_t> GetSize(std::string_view path) {
std::error_code ec;
int64_t size = std::filesystem::file_size(path, ec);
if (ec) {
// It is okay if the file does not exist. We don't have to log it.
if (ec.value() != ENOENT) {
LOG(ERROR) << ART_FORMAT("Failed to get the file size of '{}': {}", path, ec.message());
}
return std::nullopt;
}
return size;
}
// Deletes a file. Returns the size of the deleted file, or 0 if the deleted file is empty or an
// error occurs.
int64_t GetSizeAndDeleteFile(const std::string& path) {
std::optional<int64_t> size = GetSize(path);
if (!size.has_value()) {
return 0;
}
std::error_code ec;
if (!std::filesystem::remove(path, ec)) {
LOG(ERROR) << ART_FORMAT("Failed to remove '{}': {}", path, ec.message());
return 0;
}
return size.value();
}
Result<CompilerFilter::Filter> ParseCompilerFilter(const std::string& compiler_filter_str) {
CompilerFilter::Filter compiler_filter;
if (!CompilerFilter::ParseCompilerFilter(compiler_filter_str.c_str(), &compiler_filter)) {
return Errorf("Failed to parse compiler filter '{}'", compiler_filter_str);
}
return compiler_filter;
}
OatFileAssistant::DexOptTrigger DexOptTriggerFromAidl(int32_t aidl_value) {
OatFileAssistant::DexOptTrigger trigger{};
if ((aidl_value & static_cast<int32_t>(DexoptTrigger::COMPILER_FILTER_IS_BETTER)) != 0) {
trigger.targetFilterIsBetter = true;
}
if ((aidl_value & static_cast<int32_t>(DexoptTrigger::COMPILER_FILTER_IS_SAME)) != 0) {
trigger.targetFilterIsSame = true;
}
if ((aidl_value & static_cast<int32_t>(DexoptTrigger::COMPILER_FILTER_IS_WORSE)) != 0) {
trigger.targetFilterIsWorse = true;
}
if ((aidl_value & static_cast<int32_t>(DexoptTrigger::PRIMARY_BOOT_IMAGE_BECOMES_USABLE)) != 0) {
trigger.primaryBootImageBecomesUsable = true;
}
if ((aidl_value & static_cast<int32_t>(DexoptTrigger::NEED_EXTRACTION)) != 0) {
trigger.needExtraction = true;
}
return trigger;
}
ArtifactsLocation ArtifactsLocationToAidl(OatFileAssistant::Location location) {
switch (location) {
case OatFileAssistant::Location::kLocationNoneOrError:
return ArtifactsLocation::NONE_OR_ERROR;
case OatFileAssistant::Location::kLocationOat:
return ArtifactsLocation::DALVIK_CACHE;
case OatFileAssistant::Location::kLocationOdex:
return ArtifactsLocation::NEXT_TO_DEX;
case OatFileAssistant::Location::kLocationDm:
return ArtifactsLocation::DM;
// No default. All cases should be explicitly handled, or the compilation will fail.
}
// This should never happen. Just in case we get a non-enumerator value.
LOG(FATAL) << "Unexpected Location " << location;
}
Result<bool> CreateDir(const std::string& path) {
std::error_code ec;
bool created = std::filesystem::create_directory(path, ec);
if (ec) {
return Errorf("Failed to create directory '{}': {}", path, ec.message());
}
return created;
}
Result<void> PrepareArtifactsDir(const std::string& path, const FsPermission& fs_permission) {
bool created = OR_RETURN(CreateDir(path));
auto cleanup = make_scope_guard([&] {
if (created) {
std::error_code ec;
std::filesystem::remove(path, ec);
}
});
if (chmod(path.c_str(), DirFsPermissionToMode(fs_permission)) != 0) {
return ErrnoErrorf("Failed to chmod directory '{}'", path);
}
OR_RETURN(Chown(path, fs_permission));
cleanup.Disable();
return {};
}
Result<void> PrepareArtifactsDirs(const OutputArtifacts& output_artifacts,
/*out*/ std::string* oat_dir_path) {
if (output_artifacts.artifactsPath.isInDalvikCache) {
return {};
}
std::filesystem::path oat_path(
OR_RETURN(BuildArtifactsPath(output_artifacts.artifactsPath)).oat_path);
std::filesystem::path isa_dir = oat_path.parent_path();
std::filesystem::path oat_dir = isa_dir.parent_path();
DCHECK_EQ(oat_dir.filename(), "oat");
OR_RETURN(PrepareArtifactsDir(oat_dir, output_artifacts.permissionSettings.dirFsPermission));
OR_RETURN(PrepareArtifactsDir(isa_dir, output_artifacts.permissionSettings.dirFsPermission));
*oat_dir_path = oat_dir;
return {};
}
Result<FileVisibility> GetFileVisibility(const std::string& file) {
std::error_code ec;
std::filesystem::file_status status = std::filesystem::status(file, ec);
if (!std::filesystem::status_known(status)) {
return Errorf("Failed to get status of '{}': {}", file, ec.message());
}
if (!std::filesystem::exists(status)) {
return FileVisibility::NOT_FOUND;
}
return (status.permissions() & std::filesystem::perms::others_read) !=
std::filesystem::perms::none ?
FileVisibility::OTHER_READABLE :
FileVisibility::NOT_OTHER_READABLE;
}
Result<ArtdCancellationSignal*> ToArtdCancellationSignal(IArtdCancellationSignal* input) {
if (input == nullptr) {
return Error() << "Cancellation signal must not be nullptr";
}
// We cannot use `dynamic_cast` because ART code is compiled with `-fno-rtti`, so we have to check
// the magic number.
int64_t type;
if (!input->getType(&type).isOk() ||
type != reinterpret_cast<intptr_t>(kArtdCancellationSignalType)) {
// The cancellation signal must be created by `Artd::createCancellationSignal`.
return Error() << "Invalid cancellation signal type";
}
return static_cast<ArtdCancellationSignal*>(input);
}
Result<void> CopyFile(const std::string& src_path, const NewFile& dst_file) {
std::string content;
if (!ReadFileToString(src_path, &content)) {
return Errorf("Failed to read file '{}': {}", src_path, strerror(errno));
}
if (!WriteStringToFd(content, dst_file.Fd())) {
return Errorf("Failed to write file '{}': {}", dst_file.TempPath(), strerror(errno));
}
if (fsync(dst_file.Fd()) != 0) {
return Errorf("Failed to flush file '{}': {}", dst_file.TempPath(), strerror(errno));
}
if (lseek(dst_file.Fd(), /*offset=*/0, SEEK_SET) != 0) {
return Errorf(
"Failed to reset the offset for file '{}': {}", dst_file.TempPath(), strerror(errno));
}
return {};
}
Result<void> SetLogVerbosity() {
std::string options =
android::base::GetProperty("dalvik.vm.artd-verbose", /*default_value=*/"oat");
if (options.empty()) {
return {};
}
CmdlineType<LogVerbosity> parser;
CmdlineParseResult<LogVerbosity> result = parser.Parse(options);
if (!result.IsSuccess()) {
return Error() << result.GetMessage();
}
gLogVerbosity = result.ReleaseValue();
return {};
}
CopyAndRewriteProfileResult AnalyzeCopyAndRewriteProfileFailure(
File* src, ProfmanResult::CopyAndUpdateResult result) {
DCHECK(result == ProfmanResult::kCopyAndUpdateNoMatch ||
result == ProfmanResult::kCopyAndUpdateErrorFailedToLoadProfile);
auto bad_profile = [&](std::string_view error_msg) {
return CopyAndRewriteProfileResult{
.status = CopyAndRewriteProfileResult::Status::BAD_PROFILE,
.errorMsg = ART_FORMAT("Failed to load profile '{}': {}", src->GetPath(), error_msg)};
};
CopyAndRewriteProfileResult no_profile{.status = CopyAndRewriteProfileResult::Status::NO_PROFILE,
.errorMsg = ""};
int64_t length = src->GetLength();
if (length < 0) {
return bad_profile(strerror(-length));
}
if (length == 0) {
return no_profile;
}
std::string error_msg;
uint32_t magic;
if (!ReadMagicAndReset(src->Fd(), &magic, &error_msg)) {
return bad_profile(error_msg);
}
if (IsZipMagic(magic)) {
std::unique_ptr<ZipArchive> zip_archive(
ZipArchive::OpenFromOwnedFd(src->Fd(), src->GetPath().c_str(), &error_msg));
if (zip_archive == nullptr) {
return bad_profile(error_msg);
}
std::unique_ptr<ZipEntry> zip_entry(zip_archive->Find("primary.prof", &error_msg));
if (zip_entry == nullptr || zip_entry->GetUncompressedLength() == 0) {
return no_profile;
}
}
if (result == ProfmanResult::kCopyAndUpdateNoMatch) {
return bad_profile(
"The profile does not match the APK (The checksums in the profile do not match the "
"checksums of the .dex files in the APK)");
}
return bad_profile("The profile is in the wrong format or an I/O error has occurred");
}
// Returns the fd on success, or an invalid fd if the dex file contains no profile, or error if any
// error occurs.
Result<File> ExtractEmbeddedProfileToFd(const std::string& dex_path) {
std::unique_ptr<File> dex_file = OR_RETURN(OpenFileForReading(dex_path));
std::string error_msg;
uint32_t magic;
if (!ReadMagicAndReset(dex_file->Fd(), &magic, &error_msg)) {
return Error() << error_msg;
}
if (!IsZipMagic(magic)) {
if (DexFileLoader::IsMagicValid(magic)) {
// The dex file can be a plain dex file. This is expected.
return File();
}
return Error() << "File is neither a zip file nor a plain dex file";
}
std::unique_ptr<ZipArchive> zip_archive(
ZipArchive::OpenFromOwnedFd(dex_file->Fd(), dex_path.c_str(), &error_msg));
if (zip_archive == nullptr) {
return Error() << error_msg;
}
constexpr const char* kEmbeddedProfileEntry = "assets/art-profile/baseline.prof";
std::unique_ptr<ZipEntry> zip_entry(zip_archive->Find(kEmbeddedProfileEntry, &error_msg));
size_t size;
if (zip_entry == nullptr || (size = zip_entry->GetUncompressedLength()) == 0) {
// From system/libziparchive/zip_error.cpp.
constexpr const char* kEntryNotFound = "Entry not found";
if (error_msg != kEntryNotFound) {
LOG(WARNING) << ART_FORMAT(
"Failed to find zip entry '{}' in '{}': {}", kEmbeddedProfileEntry, dex_path, error_msg);
}
// The dex file doesn't necessarily contain a profile. This is expected.
return File();
}
// The name is for debugging only.
std::string memfd_name =
ART_FORMAT("{} extracted in memory from {}", kEmbeddedProfileEntry, dex_path);
File memfd(memfd_create(memfd_name.c_str(), /*flags=*/0),
memfd_name,
/*check_usage=*/false);
if (!memfd.IsValid()) {
return ErrnoError() << "Failed to create memfd";
}
if (ftruncate(memfd.Fd(), size) != 0) {
return ErrnoError() << "Failed to ftruncate memfd";
}
// Map with MAP_SHARED because we're feeding the fd to profman.
MemMap mem_map = MemMap::MapFile(size,
PROT_READ | PROT_WRITE,
MAP_SHARED,
memfd.Fd(),
/*start=*/0,
/*low_4gb=*/false,
memfd_name.c_str(),
&error_msg);
if (!mem_map.IsValid()) {
return Errorf("Failed to mmap memfd: {}", error_msg);
}
if (!zip_entry->ExtractToMemory(mem_map.Begin(), &error_msg)) {
return Errorf("Failed to extract '{}': {}", kEmbeddedProfileEntry, error_msg);
}
// Reopen the memfd with readonly to make SELinux happy when the fd is passed to a child process
// who doesn't have write permission. (b/303909581)
std::string path = ART_FORMAT("/proc/self/fd/{}", memfd.Fd());
File memfd_readonly(
open(path.c_str(), O_RDONLY), memfd_name, /*check_usage=*/false, /*read_only_mode=*/true);
if (!memfd_readonly.IsOpened()) {
return ErrnoErrorf("Failed to open file '{}' ('{}')", path, memfd_name);
}
return memfd_readonly;
}
class FdLogger {
public:
void Add(const NewFile& file) { fd_mapping_.emplace_back(file.Fd(), file.TempPath()); }
void Add(const File& file) { fd_mapping_.emplace_back(file.Fd(), file.GetPath()); }
std::string GetFds() {
std::vector<int> fds;
fds.reserve(fd_mapping_.size());
for (const auto& [fd, path] : fd_mapping_) {
fds.push_back(fd);
}
return Join(fds, ':');
}
private:
std::vector<std::pair<int, std::string>> fd_mapping_;
friend std::ostream& operator<<(std::ostream& os, const FdLogger& fd_logger);
};
std::ostream& operator<<(std::ostream& os, const FdLogger& fd_logger) {
for (const auto& [fd, path] : fd_logger.fd_mapping_) {
os << fd << ":" << path << ' ';
}
return os;
}
} // namespace
#define RETURN_FATAL_IF_PRE_REBOOT(options) \
if (options.is_pre_reboot) { \
return Fatal("This method is not supported in Pre-reboot Dexopt mode"); \
}
#define RETURN_FATAL_IF_NOT_PRE_REBOOT(options) \
if (!options.is_pre_reboot) { \
return Fatal("This method is only supported in Pre-reboot Dexopt mode"); \
}
#define RETURN_FATAL_IF_ARG_IS_PRE_REBOOT_IMPL(expected, arg, log_name) \
{ \
auto&& __return_fatal_tmp = PreRebootFlag(arg); \
if (expected != __return_fatal_tmp) { \
return Fatal(ART_FORMAT("Expected flag 'isPreReboot' in argument '{}' to be {}, got {}", \
log_name, \
expected, \
__return_fatal_tmp)); \
} \
}
#define RETURN_FATAL_IF_PRE_REBOOT_MISMATCH(options, arg, log_name) \
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT_IMPL(options.is_pre_reboot, arg, log_name)
#define RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(arg, log_name) \
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT_IMPL(false, arg, log_name)
Result<void> Restorecon(
const std::string& path,
const std::optional<OutputArtifacts::PermissionSettings::SeContext>& se_context,
bool recurse) {
if (!kIsTargetAndroid) {
return {};
}
unsigned int flags = recurse ? SELINUX_ANDROID_RESTORECON_RECURSE : 0;
int res = 0;
if (se_context.has_value()) {
res = selinux_android_restorecon_pkgdir(
path.c_str(), se_context->seInfo.c_str(), se_context->uid, flags);
} else {
res = selinux_android_restorecon(path.c_str(), flags);
}
if (res != 0) {
return ErrnoErrorf("Failed to restorecon directory '{}'", path);
}
return {};
}
ScopedAStatus Artd::isAlive(bool* _aidl_return) {
*_aidl_return = true;
return ScopedAStatus::ok();
}
ScopedAStatus Artd::deleteArtifacts(const ArtifactsPath& in_artifactsPath, int64_t* _aidl_return) {
RETURN_FATAL_IF_PRE_REBOOT(options_);
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_artifactsPath, "artifactsPath");
RawArtifactsPath path = OR_RETURN_FATAL(BuildArtifactsPath(in_artifactsPath));
*_aidl_return = 0;
*_aidl_return += GetSizeAndDeleteFile(path.oat_path);
*_aidl_return += GetSizeAndDeleteFile(path.vdex_path);
*_aidl_return += GetSizeAndDeleteFile(path.art_path);
return ScopedAStatus::ok();
}
ScopedAStatus Artd::getDexoptStatus(const std::string& in_dexFile,
const std::string& in_instructionSet,
const std::optional<std::string>& in_classLoaderContext,
GetDexoptStatusResult* _aidl_return) {
RETURN_FATAL_IF_PRE_REBOOT(options_);
Result<OatFileAssistantContext*> ofa_context = GetOatFileAssistantContext();
if (!ofa_context.ok()) {
return NonFatal("Failed to get runtime options: " + ofa_context.error().message());
}
std::unique_ptr<ClassLoaderContext> context;
std::string error_msg;
auto oat_file_assistant = OatFileAssistant::Create(in_dexFile,
in_instructionSet,
in_classLoaderContext,
/*load_executable=*/false,
/*only_load_trusted_executable=*/true,
ofa_context.value(),
&context,
&error_msg);
if (oat_file_assistant == nullptr) {
return NonFatal("Failed to create OatFileAssistant: " + error_msg);
}
std::string ignored_odex_status;
OatFileAssistant::Location location;
oat_file_assistant->GetOptimizationStatus(&_aidl_return->locationDebugString,
&_aidl_return->compilerFilter,
&_aidl_return->compilationReason,
&ignored_odex_status,
&location);
_aidl_return->artifactsLocation = ArtifactsLocationToAidl(location);
// We ignore odex_status because it is not meaningful. It can only be either "up-to-date",
// "apk-more-recent", or "io-error-no-oat", which means it doesn't give us information in addition
// to what we can learn from compiler_filter because compiler_filter will be the actual compiler
// filter, "run-from-apk-fallback", and "run-from-apk" in those three cases respectively.
DCHECK(ignored_odex_status == "up-to-date" || ignored_odex_status == "apk-more-recent" ||
ignored_odex_status == "io-error-no-oat");
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::isProfileUsable(const ProfilePath& in_profile,
const std::string& in_dexFile,
bool* _aidl_return) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_profile, "profile");
std::string profile_path = OR_RETURN_FATAL(BuildProfileOrDmPath(in_profile));
OR_RETURN_FATAL(ValidateDexPath(in_dexFile));
FdLogger fd_logger;
CmdlineBuilder art_exec_args = OR_RETURN_FATAL(GetArtExecCmdlineBuilder());
CmdlineBuilder args;
args.Add(OR_RETURN_FATAL(GetProfman()));
Result<std::unique_ptr<File>> profile = OpenFileForReading(profile_path);
if (!profile.ok()) {
if (profile.error().code() == ENOENT) {
*_aidl_return = false;
return ScopedAStatus::ok();
}
return NonFatal(
ART_FORMAT("Failed to open profile '{}': {}", profile_path, profile.error().message()));
}
args.Add("--reference-profile-file-fd=%d", profile.value()->Fd());
fd_logger.Add(*profile.value());
std::unique_ptr<File> dex_file = OR_RETURN_NON_FATAL(OpenFileForReading(in_dexFile));
args.Add("--apk-fd=%d", dex_file->Fd());
fd_logger.Add(*dex_file);
art_exec_args.Add("--keep-fds=%s", fd_logger.GetFds()).Add("--").Concat(std::move(args));
LOG(INFO) << "Running profman: " << Join(art_exec_args.Get(), /*separator=*/" ")
<< "\nOpened FDs: " << fd_logger;
Result<int> result = ExecAndReturnCode(art_exec_args.Get(), kShortTimeoutSec);
if (!result.ok()) {
return NonFatal("Failed to run profman: " + result.error().message());
}
LOG(INFO) << ART_FORMAT("profman returned code {}", result.value());
if (result.value() != ProfmanResult::kSkipCompilationSmallDelta &&
result.value() != ProfmanResult::kSkipCompilationEmptyProfiles) {
return NonFatal(ART_FORMAT("profman returned an unexpected code: {}", result.value()));
}
*_aidl_return = result.value() == ProfmanResult::kSkipCompilationSmallDelta;
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::CopyAndRewriteProfileImpl(File src,
OutputProfile* dst_aidl,
const std::string& dex_path,
CopyAndRewriteProfileResult* aidl_return) {
RETURN_FATAL_IF_PRE_REBOOT_MISMATCH(options_, *dst_aidl, "dst");
std::string dst_path = OR_RETURN_FATAL(BuildFinalProfilePath(dst_aidl->profilePath));
OR_RETURN_FATAL(ValidateDexPath(dex_path));
FdLogger fd_logger;
CmdlineBuilder art_exec_args = OR_RETURN_FATAL(GetArtExecCmdlineBuilder());
CmdlineBuilder args;
args.Add(OR_RETURN_FATAL(GetProfman())).Add("--copy-and-update-profile-key");
args.Add("--profile-file-fd=%d", src.Fd());
fd_logger.Add(src);
std::unique_ptr<File> dex_file = OR_RETURN_NON_FATAL(OpenFileForReading(dex_path));
args.Add("--apk-fd=%d", dex_file->Fd());
fd_logger.Add(*dex_file);
std::unique_ptr<NewFile> dst =
OR_RETURN_NON_FATAL(NewFile::Create(dst_path, dst_aidl->fsPermission));
args.Add("--reference-profile-file-fd=%d", dst->Fd());
fd_logger.Add(*dst);
art_exec_args.Add("--keep-fds=%s", fd_logger.GetFds()).Add("--").Concat(std::move(args));
LOG(INFO) << "Running profman: " << Join(art_exec_args.Get(), /*separator=*/" ")
<< "\nOpened FDs: " << fd_logger;
Result<int> result = ExecAndReturnCode(art_exec_args.Get(), kShortTimeoutSec);
if (!result.ok()) {
return NonFatal("Failed to run profman: " + result.error().message());
}
LOG(INFO) << ART_FORMAT("profman returned code {}", result.value());
if (result.value() == ProfmanResult::kCopyAndUpdateNoMatch ||
result.value() == ProfmanResult::kCopyAndUpdateErrorFailedToLoadProfile) {
*aidl_return = AnalyzeCopyAndRewriteProfileFailure(
&src, static_cast<ProfmanResult::CopyAndUpdateResult>(result.value()));
return ScopedAStatus::ok();
}
if (result.value() != ProfmanResult::kCopyAndUpdateSuccess) {
return NonFatal(ART_FORMAT("profman returned an unexpected code: {}", result.value()));
}
OR_RETURN_NON_FATAL(dst->Keep());
aidl_return->status = CopyAndRewriteProfileResult::Status::SUCCESS;
dst_aidl->profilePath.id = dst->TempId();
dst_aidl->profilePath.tmpPath = dst->TempPath();
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::copyAndRewriteProfile(const ProfilePath& in_src,
OutputProfile* in_dst,
const std::string& in_dexFile,
CopyAndRewriteProfileResult* _aidl_return) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_src, "src");
std::string src_path = OR_RETURN_FATAL(BuildProfileOrDmPath(in_src));
Result<std::unique_ptr<File>> src = OpenFileForReading(src_path);
if (!src.ok()) {
if (src.error().code() == ENOENT) {
_aidl_return->status = CopyAndRewriteProfileResult::Status::NO_PROFILE;
return ScopedAStatus::ok();
}
return NonFatal(
ART_FORMAT("Failed to open src profile '{}': {}", src_path, src.error().message()));
}
return CopyAndRewriteProfileImpl(std::move(*src.value()), in_dst, in_dexFile, _aidl_return);
}
ndk::ScopedAStatus Artd::copyAndRewriteEmbeddedProfile(OutputProfile* in_dst,
const std::string& in_dexFile,
CopyAndRewriteProfileResult* _aidl_return) {
OR_RETURN_FATAL(ValidateDexPath(in_dexFile));
Result<File> src = ExtractEmbeddedProfileToFd(in_dexFile);
if (!src.ok()) {
return NonFatal(ART_FORMAT(
"Failed to extract profile from dex file '{}': {}", in_dexFile, src.error().message()));
}
if (!src->IsValid()) {
_aidl_return->status = CopyAndRewriteProfileResult::Status::NO_PROFILE;
return ScopedAStatus::ok();
}
return CopyAndRewriteProfileImpl(std::move(src.value()), in_dst, in_dexFile, _aidl_return);
}
ndk::ScopedAStatus Artd::commitTmpProfile(const TmpProfilePath& in_profile) {
RETURN_FATAL_IF_PRE_REBOOT_MISMATCH(options_, in_profile, "profile");
std::string tmp_profile_path = OR_RETURN_FATAL(BuildTmpProfilePath(in_profile));
std::string ref_profile_path = OR_RETURN_FATAL(BuildFinalProfilePath(in_profile));
std::error_code ec;
std::filesystem::rename(tmp_profile_path, ref_profile_path, ec);
if (ec) {
return NonFatal(ART_FORMAT(
"Failed to move '{}' to '{}': {}", tmp_profile_path, ref_profile_path, ec.message()));
}
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::deleteProfile(const ProfilePath& in_profile) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_profile, "profile");
std::string profile_path = OR_RETURN_FATAL(BuildProfileOrDmPath(in_profile));
std::error_code ec;
std::filesystem::remove(profile_path, ec);
if (ec) {
LOG(ERROR) << ART_FORMAT("Failed to remove '{}': {}", profile_path, ec.message());
}
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::getProfileVisibility(const ProfilePath& in_profile,
FileVisibility* _aidl_return) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_profile, "profile");
std::string profile_path = OR_RETURN_FATAL(BuildProfileOrDmPath(in_profile));
*_aidl_return = OR_RETURN_NON_FATAL(GetFileVisibility(profile_path));
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::getArtifactsVisibility(const ArtifactsPath& in_artifactsPath,
FileVisibility* _aidl_return) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_artifactsPath, "artifactsPath");
std::string oat_path = OR_RETURN_FATAL(BuildArtifactsPath(in_artifactsPath)).oat_path;
*_aidl_return = OR_RETURN_NON_FATAL(GetFileVisibility(oat_path));
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::getDexFileVisibility(const std::string& in_dexFile,
FileVisibility* _aidl_return) {
OR_RETURN_FATAL(ValidateDexPath(in_dexFile));
*_aidl_return = OR_RETURN_NON_FATAL(GetFileVisibility(in_dexFile));
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::getDmFileVisibility(const DexMetadataPath& in_dmFile,
FileVisibility* _aidl_return) {
std::string dm_path = OR_RETURN_FATAL(BuildDexMetadataPath(in_dmFile));
*_aidl_return = OR_RETURN_NON_FATAL(GetFileVisibility(dm_path));
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::mergeProfiles(const std::vector<ProfilePath>& in_profiles,
const std::optional<ProfilePath>& in_referenceProfile,
OutputProfile* in_outputProfile,
const std::vector<std::string>& in_dexFiles,
const MergeProfileOptions& in_options,
bool* _aidl_return) {
std::vector<std::string> profile_paths;
for (const ProfilePath& profile : in_profiles) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(profile, "profiles");
std::string profile_path = OR_RETURN_FATAL(BuildProfileOrDmPath(profile));
if (profile.getTag() == ProfilePath::dexMetadataPath) {
return Fatal(ART_FORMAT("Does not support DM file, got '{}'", profile_path));
}
profile_paths.push_back(std::move(profile_path));
}
RETURN_FATAL_IF_PRE_REBOOT_MISMATCH(options_, *in_outputProfile, "outputProfile");
std::string output_profile_path =
OR_RETURN_FATAL(BuildFinalProfilePath(in_outputProfile->profilePath));
for (const std::string& dex_file : in_dexFiles) {
OR_RETURN_FATAL(ValidateDexPath(dex_file));
}
if (in_options.forceMerge + in_options.dumpOnly + in_options.dumpClassesAndMethods > 1) {
return Fatal("Only one of 'forceMerge', 'dumpOnly', and 'dumpClassesAndMethods' can be set");
}
FdLogger fd_logger;
CmdlineBuilder art_exec_args = OR_RETURN_FATAL(GetArtExecCmdlineBuilder());
CmdlineBuilder args;
args.Add(OR_RETURN_FATAL(GetProfman()));
std::vector<std::unique_ptr<File>> profile_files;
for (const std::string& profile_path : profile_paths) {
Result<std::unique_ptr<File>> profile_file = OpenFileForReading(profile_path);
if (!profile_file.ok()) {
if (profile_file.error().code() == ENOENT) {
// Skip non-existing file.
continue;
}
return NonFatal(ART_FORMAT(
"Failed to open profile '{}': {}", profile_path, profile_file.error().message()));
}
args.Add("--profile-file-fd=%d", profile_file.value()->Fd());
fd_logger.Add(*profile_file.value());
profile_files.push_back(std::move(profile_file.value()));
}
if (profile_files.empty()) {
LOG(INFO) << "Merge skipped because there are no existing profiles";
*_aidl_return = false;
return ScopedAStatus::ok();
}
std::unique_ptr<NewFile> output_profile_file =
OR_RETURN_NON_FATAL(NewFile::Create(output_profile_path, in_outputProfile->fsPermission));
if (in_referenceProfile.has_value()) {
if (in_options.dumpOnly || in_options.dumpClassesAndMethods) {
return Fatal(
"Reference profile must not be set when 'dumpOnly' or 'dumpClassesAndMethods' is set");
}
// `in_referenceProfile` can be either a Pre-reboot profile or an ordinary one.
std::string reference_profile_path =
OR_RETURN_FATAL(BuildProfileOrDmPath(*in_referenceProfile));
if (in_referenceProfile->getTag() == ProfilePath::dexMetadataPath) {
return Fatal(ART_FORMAT("Does not support DM file, got '{}'", reference_profile_path));
}
OR_RETURN_NON_FATAL(CopyFile(reference_profile_path, *output_profile_file));
}
if (in_options.dumpOnly || in_options.dumpClassesAndMethods) {
args.Add("--dump-output-to-fd=%d", output_profile_file->Fd());
} else {
// profman is ok with this being an empty file when in_referenceProfile isn't set.
args.Add("--reference-profile-file-fd=%d", output_profile_file->Fd());
}
fd_logger.Add(*output_profile_file);
std::vector<std::unique_ptr<File>> dex_files;
for (const std::string& dex_path : in_dexFiles) {
std::unique_ptr<File> dex_file = OR_RETURN_NON_FATAL(OpenFileForReading(dex_path));
args.Add("--apk-fd=%d", dex_file->Fd());
fd_logger.Add(*dex_file);
dex_files.push_back(std::move(dex_file));
}
if (in_options.dumpOnly || in_options.dumpClassesAndMethods) {
args.Add(in_options.dumpOnly ? "--dump-only" : "--dump-classes-and-methods");
} else {
args.AddIfNonEmpty("--min-new-classes-percent-change=%s",
props_->GetOrEmpty("dalvik.vm.bgdexopt.new-classes-percent"))
.AddIfNonEmpty("--min-new-methods-percent-change=%s",
props_->GetOrEmpty("dalvik.vm.bgdexopt.new-methods-percent"))
.AddIf(in_options.forceMerge, "--force-merge-and-analyze")
.AddIf(in_options.forBootImage, "--boot-image-merge");
}
art_exec_args.Add("--keep-fds=%s", fd_logger.GetFds()).Add("--").Concat(std::move(args));
LOG(INFO) << "Running profman: " << Join(art_exec_args.Get(), /*separator=*/" ")
<< "\nOpened FDs: " << fd_logger;
Result<int> result = ExecAndReturnCode(art_exec_args.Get(), kShortTimeoutSec);
if (!result.ok()) {
return NonFatal("Failed to run profman: " + result.error().message());
}
LOG(INFO) << ART_FORMAT("profman returned code {}", result.value());
if (result.value() == ProfmanResult::kSkipCompilationSmallDelta ||
result.value() == ProfmanResult::kSkipCompilationEmptyProfiles) {
*_aidl_return = false;
return ScopedAStatus::ok();
}
ProfmanResult::ProcessingResult expected_result =
(in_options.dumpOnly || in_options.dumpClassesAndMethods) ? ProfmanResult::kSuccess :
ProfmanResult::kCompile;
if (result.value() != expected_result) {
return NonFatal(ART_FORMAT("profman returned an unexpected code: {}", result.value()));
}
OR_RETURN_NON_FATAL(output_profile_file->Keep());
*_aidl_return = true;
in_outputProfile->profilePath.id = output_profile_file->TempId();
in_outputProfile->profilePath.tmpPath = output_profile_file->TempPath();
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::getDexoptNeeded(const std::string& in_dexFile,
const std::string& in_instructionSet,
const std::optional<std::string>& in_classLoaderContext,
const std::string& in_compilerFilter,
int32_t in_dexoptTrigger,
GetDexoptNeededResult* _aidl_return) {
Result<OatFileAssistantContext*> ofa_context = GetOatFileAssistantContext();
if (!ofa_context.ok()) {
return NonFatal("Failed to get runtime options: " + ofa_context.error().message());
}
std::unique_ptr<ClassLoaderContext> context;
std::string error_msg;
auto oat_file_assistant = OatFileAssistant::Create(in_dexFile,
in_instructionSet,
in_classLoaderContext,
/*load_executable=*/false,
/*only_load_trusted_executable=*/true,
ofa_context.value(),
&context,
&error_msg);
if (oat_file_assistant == nullptr) {
return NonFatal("Failed to create OatFileAssistant: " + error_msg);
}
OatFileAssistant::DexOptStatus status;
_aidl_return->isDexoptNeeded =
oat_file_assistant->GetDexOptNeeded(OR_RETURN_FATAL(ParseCompilerFilter(in_compilerFilter)),
DexOptTriggerFromAidl(in_dexoptTrigger),
&status);
_aidl_return->isVdexUsable = status.IsVdexUsable();
_aidl_return->artifactsLocation = ArtifactsLocationToAidl(status.GetLocation());
std::optional<bool> has_dex_files = oat_file_assistant->HasDexFiles(&error_msg);
if (!has_dex_files.has_value()) {
return NonFatal("Failed to open dex file: " + error_msg);
}
_aidl_return->hasDexCode = *has_dex_files;
return ScopedAStatus::ok();
}
ndk::ScopedAStatus Artd::dexopt(
const OutputArtifacts& in_outputArtifacts,
const std::string& in_dexFile,
const std::string& in_instructionSet,
const std::optional<std::string>& in_classLoaderContext,
const std::string& in_compilerFilter,
const std::optional<ProfilePath>& in_profile,
const std::optional<VdexPath>& in_inputVdex,
const std::optional<DexMetadataPath>& in_dmFile,
PriorityClass in_priorityClass,
const DexoptOptions& in_dexoptOptions,
const std::shared_ptr<IArtdCancellationSignal>& in_cancellationSignal,
ArtdDexoptResult* _aidl_return) {
_aidl_return->cancelled = false;
RETURN_FATAL_IF_PRE_REBOOT_MISMATCH(options_, in_outputArtifacts, "outputArtifacts");
RawArtifactsPath artifacts_path =
OR_RETURN_FATAL(BuildArtifactsPath(in_outputArtifacts.artifactsPath));
OR_RETURN_FATAL(ValidateDexPath(in_dexFile));
// `in_profile` can be either a Pre-reboot profile or an ordinary one.
std::optional<std::string> profile_path =
in_profile.has_value() ?
std::make_optional(OR_RETURN_FATAL(BuildProfileOrDmPath(in_profile.value()))) :
std::nullopt;
ArtdCancellationSignal* cancellation_signal =
OR_RETURN_FATAL(ToArtdCancellationSignal(in_cancellationSignal.get()));
std::unique_ptr<ClassLoaderContext> context = nullptr;
if (in_classLoaderContext.has_value()) {
context = ClassLoaderContext::Create(in_classLoaderContext.value());
if (context == nullptr) {
return Fatal(
ART_FORMAT("Class loader context '{}' is invalid", in_classLoaderContext.value()));
}
}
std::string oat_dir_path; // For restorecon, can be empty if the artifacts are in dalvik-cache.
OR_RETURN_NON_FATAL(PrepareArtifactsDirs(in_outputArtifacts, &oat_dir_path));
// First-round restorecon. artd doesn't have the permission to create files with the
// `apk_data_file` label, so we need to restorecon the "oat" directory first so that files will
// inherit `dalvikcache_data_file` rather than `apk_data_file`.
if (!in_outputArtifacts.artifactsPath.isInDalvikCache) {
OR_RETURN_NON_FATAL(restorecon_(
oat_dir_path, in_outputArtifacts.permissionSettings.seContext, /*recurse=*/true));
}
FdLogger fd_logger;
CmdlineBuilder art_exec_args = OR_RETURN_FATAL(GetArtExecCmdlineBuilder());
CmdlineBuilder args;
args.Add(OR_RETURN_FATAL(GetDex2Oat()));
const FsPermission& fs_permission = in_outputArtifacts.permissionSettings.fileFsPermission;
std::unique_ptr<File> dex_file = OR_RETURN_NON_FATAL(OpenFileForReading(in_dexFile));
args.Add("--zip-fd=%d", dex_file->Fd()).Add("--zip-location=%s", in_dexFile);
fd_logger.Add(*dex_file);
struct stat dex_st = OR_RETURN_NON_FATAL(Fstat(*dex_file));
if ((dex_st.st_mode & S_IROTH) == 0) {
if (fs_permission.isOtherReadable) {
return NonFatal(ART_FORMAT(
"Outputs cannot be other-readable because the dex file '{}' is not other-readable",
dex_file->GetPath()));
}
// Negative numbers mean no `chown`. 0 means root.
// Note: this check is more strict than it needs to be. For example, it doesn't allow the
// outputs to belong to a group that is a subset of the dex file's group. This is for
// simplicity, and it's okay as we don't have to handle such complicated cases in practice.
if ((fs_permission.uid > 0 && static_cast<uid_t>(fs_permission.uid) != dex_st.st_uid) ||
(fs_permission.gid > 0 && static_cast<gid_t>(fs_permission.gid) != dex_st.st_uid &&
static_cast<gid_t>(fs_permission.gid) != dex_st.st_gid)) {
return NonFatal(ART_FORMAT(
"Outputs' owner doesn't match the dex file '{}' (outputs: {}:{}, dex file: {}:{})",
dex_file->GetPath(),
fs_permission.uid,
fs_permission.gid,
dex_st.st_uid,
dex_st.st_gid));
}
}
std::unique_ptr<NewFile> oat_file =
OR_RETURN_NON_FATAL(NewFile::Create(artifacts_path.oat_path, fs_permission));
args.Add("--oat-fd=%d", oat_file->Fd()).Add("--oat-location=%s", artifacts_path.oat_path);
fd_logger.Add(*oat_file);
std::unique_ptr<NewFile> vdex_file =
OR_RETURN_NON_FATAL(NewFile::Create(artifacts_path.vdex_path, fs_permission));
args.Add("--output-vdex-fd=%d", vdex_file->Fd());
fd_logger.Add(*vdex_file);
std::vector<NewFile*> files_to_commit{oat_file.get(), vdex_file.get()};
std::vector<std::string_view> files_to_delete;
std::unique_ptr<NewFile> art_file = nullptr;
if (in_dexoptOptions.generateAppImage) {
art_file = OR_RETURN_NON_FATAL(NewFile::Create(artifacts_path.art_path, fs_permission));
args.Add("--app-image-fd=%d", art_file->Fd());
args.AddIfNonEmpty("--image-format=%s", props_->GetOrEmpty("dalvik.vm.appimageformat"));
fd_logger.Add(*art_file);
files_to_commit.push_back(art_file.get());
} else {
files_to_delete.push_back(artifacts_path.art_path);
}
std::unique_ptr<NewFile> swap_file = nullptr;
if (ShouldCreateSwapFileForDexopt()) {
std::string swap_file_path = ART_FORMAT("{}.swap", artifacts_path.oat_path);
swap_file =
OR_RETURN_NON_FATAL(NewFile::Create(swap_file_path, FsPermission{.uid = -1, .gid = -1}));
args.Add("--swap-fd=%d", swap_file->Fd());
fd_logger.Add(*swap_file);
}
std::vector<std::unique_ptr<File>> context_files;
if (context != nullptr) {
std::vector<std::string> flattened_context = context->FlattenDexPaths();
std::string dex_dir = Dirname(in_dexFile);
std::vector<int> context_fds;
for (const std::string& context_element : flattened_context) {
std::string context_path = std::filesystem::path(dex_dir).append(context_element);
OR_RETURN_FATAL(ValidateDexPath(context_path));
std::unique_ptr<File> context_file = OR_RETURN_NON_FATAL(OpenFileForReading(context_path));
context_fds.push_back(context_file->Fd());
fd_logger.Add(*context_file);
context_files.push_back(std::move(context_file));
}
args.AddIfNonEmpty("--class-loader-context-fds=%s", Join(context_fds, /*separator=*/':'))
.Add("--class-loader-context=%s", in_classLoaderContext.value())
.Add("--classpath-dir=%s", dex_dir);
}
std::unique_ptr<File> input_vdex_file = nullptr;
if (in_inputVdex.has_value()) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_inputVdex.value(), "inputVdex");
std::string input_vdex_path = OR_RETURN_FATAL(BuildVdexPath(in_inputVdex.value()));
input_vdex_file = OR_RETURN_NON_FATAL(OpenFileForReading(input_vdex_path));
args.Add("--input-vdex-fd=%d", input_vdex_file->Fd());
fd_logger.Add(*input_vdex_file);
}
std::unique_ptr<File> dm_file = nullptr;
if (in_dmFile.has_value()) {
std::string dm_path = OR_RETURN_FATAL(BuildDexMetadataPath(in_dmFile.value()));
dm_file = OR_RETURN_NON_FATAL(OpenFileForReading(dm_path));
args.Add("--dm-fd=%d", dm_file->Fd());
fd_logger.Add(*dm_file);
}
std::unique_ptr<File> profile_file = nullptr;
if (profile_path.has_value()) {
profile_file = OR_RETURN_NON_FATAL(OpenFileForReading(profile_path.value()));
args.Add("--profile-file-fd=%d", profile_file->Fd());
fd_logger.Add(*profile_file);
struct stat profile_st = OR_RETURN_NON_FATAL(Fstat(*profile_file));
if (fs_permission.isOtherReadable && (profile_st.st_mode & S_IROTH) == 0) {
return NonFatal(ART_FORMAT(
"Outputs cannot be other-readable because the profile '{}' is not other-readable",
profile_file->GetPath()));
}
// TODO(b/260228411): Check uid and gid.
}
// Second-round restorecon. Restorecon recursively after the output files are created, so that the
// SELinux context is applied to all of them. The SELinux context of a file is mostly inherited
// from the parent directory upon creation, but the MLS label is not inherited, so we need to
// restorecon every file so that they have the right MLS label. If the files are in dalvik-cache,
// there's no need to restorecon because they inherits the SELinux context of the dalvik-cache
// directory and they don't need to have MLS labels.
if (!in_outputArtifacts.artifactsPath.isInDalvikCache) {
OR_RETURN_NON_FATAL(restorecon_(
oat_dir_path, in_outputArtifacts.permissionSettings.seContext, /*recurse=*/true));
}
AddBootImageFlags(args);
AddCompilerConfigFlags(
in_instructionSet, in_compilerFilter, in_priorityClass, in_dexoptOptions, args);
AddPerfConfigFlags(in_priorityClass, art_exec_args, args);
// For being surfaced in crash reports on crashes.
args.Add("--comments=%s", in_dexoptOptions.comments);
art_exec_args.Add("--keep-fds=%s", fd_logger.GetFds()).Add("--").Concat(std::move(args));
LOG(INFO) << "Running dex2oat: " << Join(art_exec_args.Get(), /*separator=*/" ")
<< "\nOpened FDs: " << fd_logger;
ExecCallbacks callbacks{
.on_start =
[&](pid_t pid) {
std::lock_guard<std::mutex> lock(cancellation_signal->mu_);
cancellation_signal->pids_.insert(pid);
// Handle cancellation signals sent before the process starts.
if (cancellation_signal->is_cancelled_) {
int res = kill_(pid, SIGKILL);
DCHECK_EQ(res, 0);
}
},
.on_end =
[&](pid_t pid) {
std::lock_guard<std::mutex> lock(cancellation_signal->mu_);
// The pid should no longer receive kill signals sent by `cancellation_signal`.
cancellation_signal->pids_.erase(pid);
},
};
ProcessStat stat;
Result<int> result = ExecAndReturnCode(art_exec_args.Get(), kLongTimeoutSec, callbacks, &stat);
_aidl_return->wallTimeMs = stat.wall_time_ms;
_aidl_return->cpuTimeMs = stat.cpu_time_ms;
if (!result.ok()) {
{
std::lock_guard<std::mutex> lock(cancellation_signal->mu_);
if (cancellation_signal->is_cancelled_) {
_aidl_return->cancelled = true;
return ScopedAStatus::ok();
}
}
return NonFatal("Failed to run dex2oat: " + result.error().message());
}
LOG(INFO) << ART_FORMAT("dex2oat returned code {}", result.value());
if (result.value() != 0) {
return NonFatal(ART_FORMAT("dex2oat returned an unexpected code: {}", result.value()));
}
int64_t size_bytes = 0;
int64_t size_before_bytes = 0;
for (const NewFile* file : files_to_commit) {
size_bytes += GetSize(file->TempPath()).value_or(0);
size_before_bytes += GetSize(file->FinalPath()).value_or(0);
}
for (std::string_view path : files_to_delete) {
size_before_bytes += GetSize(path).value_or(0);
}
OR_RETURN_NON_FATAL(NewFile::CommitAllOrAbandon(files_to_commit, files_to_delete));
_aidl_return->sizeBytes = size_bytes;
_aidl_return->sizeBeforeBytes = size_before_bytes;
return ScopedAStatus::ok();
}
ScopedAStatus ArtdCancellationSignal::cancel() {
std::lock_guard<std::mutex> lock(mu_);
is_cancelled_ = true;
for (pid_t pid : pids_) {
int res = kill_(pid, SIGKILL);
DCHECK_EQ(res, 0);
}
return ScopedAStatus::ok();
}
ScopedAStatus ArtdCancellationSignal::getType(int64_t* _aidl_return) {
*_aidl_return = reinterpret_cast<intptr_t>(kArtdCancellationSignalType);
return ScopedAStatus::ok();
}
ScopedAStatus Artd::createCancellationSignal(
std::shared_ptr<IArtdCancellationSignal>* _aidl_return) {
*_aidl_return = ndk::SharedRefBase::make<ArtdCancellationSignal>(kill_);
return ScopedAStatus::ok();
}
ScopedAStatus Artd::cleanup(const std::vector<ProfilePath>& in_profilesToKeep,
const std::vector<ArtifactsPath>& in_artifactsToKeep,
const std::vector<VdexPath>& in_vdexFilesToKeep,
const std::vector<RuntimeArtifactsPath>& in_runtimeArtifactsToKeep,
bool in_keepPreRebootStagedFiles,
int64_t* _aidl_return) {
RETURN_FATAL_IF_PRE_REBOOT(options_);
std::unordered_set<std::string> files_to_keep;
for (const ProfilePath& profile : in_profilesToKeep) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(profile, "profilesToKeep");
files_to_keep.insert(OR_RETURN_FATAL(BuildProfileOrDmPath(profile)));
}
for (const ArtifactsPath& artifacts : in_artifactsToKeep) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(artifacts, "artifactsToKeep");
RawArtifactsPath path = OR_RETURN_FATAL(BuildArtifactsPath(artifacts));
files_to_keep.insert(std::move(path.oat_path));
files_to_keep.insert(std::move(path.vdex_path));
files_to_keep.insert(std::move(path.art_path));
}
for (const VdexPath& vdex : in_vdexFilesToKeep) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(vdex, "vdexFilesToKeep");
files_to_keep.insert(OR_RETURN_FATAL(BuildVdexPath(vdex)));
}
std::string android_data = OR_RETURN_NON_FATAL(GetAndroidDataOrError());
std::string android_expand = OR_RETURN_NON_FATAL(GetAndroidExpandOrError());
for (const RuntimeArtifactsPath& runtime_image_path : in_runtimeArtifactsToKeep) {
OR_RETURN_FATAL(ValidateRuntimeArtifactsPath(runtime_image_path));
std::vector<std::string> files =
ListRuntimeArtifactsFiles(android_data, android_expand, runtime_image_path);
std::move(files.begin(), files.end(), std::inserter(files_to_keep, files_to_keep.end()));
}
*_aidl_return = 0;
for (const std::string& file : ListManagedFiles(android_data, android_expand)) {
if (files_to_keep.find(file) == files_to_keep.end() &&
(!in_keepPreRebootStagedFiles || !IsPreRebootStagedFile(file))) {
LOG(INFO) << ART_FORMAT("Cleaning up obsolete file '{}'", file);
*_aidl_return += GetSizeAndDeleteFile(file);
}
}
return ScopedAStatus::ok();
}
ScopedAStatus Artd::isInDalvikCache(const std::string& in_dexFile, bool* _aidl_return) {
// The artifacts should be in the global dalvik-cache directory if:
// (1). the dex file is on a system partition, even if the partition is remounted read-write,
// or
// (2). the dex file is in any other readonly location. (At the time of writing, this only
// include Incremental FS.)
//
// We cannot rely on access(2) because:
// - It doesn't take effective capabilities into account, from which artd gets root access
// to the filesystem.
// - The `faccessat` variant with the `AT_EACCESS` flag, which takes effective capabilities
// into account, is not supported by bionic.
OR_RETURN_FATAL(ValidateDexPath(in_dexFile));
std::vector<FstabEntry> entries = OR_RETURN_NON_FATAL(GetProcMountsAncestorsOfPath(in_dexFile));
// The last one controls because `/proc/mounts` reflects the sequence of `mount`.
for (auto it = entries.rbegin(); it != entries.rend(); it++) {
if (it->fs_type == "overlay") {
// Ignore the overlays created by `remount`.
continue;
}
// We need to special-case Incremental FS since it is tagged as read-write while it's actually
// not.
*_aidl_return = (it->flags & MS_RDONLY) != 0 || it->fs_type == "incremental-fs";
return ScopedAStatus::ok();
}
return NonFatal(ART_FORMAT("Fstab entries not found for '{}'", in_dexFile));
}
ScopedAStatus Artd::deleteRuntimeArtifacts(const RuntimeArtifactsPath& in_runtimeArtifactsPath,
int64_t* _aidl_return) {
RETURN_FATAL_IF_PRE_REBOOT(options_);
OR_RETURN_FATAL(ValidateRuntimeArtifactsPath(in_runtimeArtifactsPath));
*_aidl_return = 0;
std::string android_data = OR_LOG_AND_RETURN_OK(GetAndroidDataOrError());
std::string android_expand = OR_LOG_AND_RETURN_OK(GetAndroidExpandOrError());
for (const std::string& file :
ListRuntimeArtifactsFiles(android_data, android_expand, in_runtimeArtifactsPath)) {
*_aidl_return += GetSizeAndDeleteFile(file);
}
return ScopedAStatus::ok();
}
ScopedAStatus Artd::getArtifactsSize(const ArtifactsPath& in_artifactsPath, int64_t* _aidl_return) {
RETURN_FATAL_IF_PRE_REBOOT(options_);
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_artifactsPath, "artifactsPath");
RawArtifactsPath path = OR_RETURN_FATAL(BuildArtifactsPath(in_artifactsPath));
*_aidl_return = 0;
*_aidl_return += GetSize(path.oat_path).value_or(0);
*_aidl_return += GetSize(path.vdex_path).value_or(0);
*_aidl_return += GetSize(path.art_path).value_or(0);
return ScopedAStatus::ok();
}
ScopedAStatus Artd::getVdexFileSize(const VdexPath& in_vdexPath, int64_t* _aidl_return) {
RETURN_FATAL_IF_PRE_REBOOT(options_);
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_vdexPath, "vdexPath");
std::string vdex_path = OR_RETURN_FATAL(BuildVdexPath(in_vdexPath));
*_aidl_return = GetSize(vdex_path).value_or(0);
return ScopedAStatus::ok();
}
ScopedAStatus Artd::getRuntimeArtifactsSize(const RuntimeArtifactsPath& in_runtimeArtifactsPath,
int64_t* _aidl_return) {
RETURN_FATAL_IF_PRE_REBOOT(options_);
OR_RETURN_FATAL(ValidateRuntimeArtifactsPath(in_runtimeArtifactsPath));
*_aidl_return = 0;
std::string android_data = OR_LOG_AND_RETURN_OK(GetAndroidDataOrError());
std::string android_expand = OR_LOG_AND_RETURN_OK(GetAndroidExpandOrError());
for (const std::string& file :
ListRuntimeArtifactsFiles(android_data, android_expand, in_runtimeArtifactsPath)) {
*_aidl_return += GetSize(file).value_or(0);
}
return ScopedAStatus::ok();
}
ScopedAStatus Artd::getProfileSize(const ProfilePath& in_profile, int64_t* _aidl_return) {
RETURN_FATAL_IF_PRE_REBOOT(options_);
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(in_profile, "profile");
std::string profile_path = OR_RETURN_FATAL(BuildProfileOrDmPath(in_profile));
*_aidl_return = GetSize(profile_path).value_or(0);
return ScopedAStatus::ok();
}
ScopedAStatus Artd::commitPreRebootStagedFiles(
const std::vector<ArtifactsPath>& in_artifacts,
const std::vector<WritableProfilePath>& in_profiles) {
RETURN_FATAL_IF_PRE_REBOOT(options_);
std::vector<std::pair<std::string, std::string>> files_to_move;
std::vector<std::string> files_to_remove;
for (const ArtifactsPath& artifacts : in_artifacts) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(artifacts, "artifacts");
ArtifactsPath pre_reboot_artifacts = artifacts;
pre_reboot_artifacts.isPreReboot = true;
auto src_artifacts = std::make_unique<RawArtifactsPath>(
OR_RETURN_FATAL(BuildArtifactsPath(pre_reboot_artifacts)));
auto dst_artifacts =
std::make_unique<RawArtifactsPath>(OR_RETURN_FATAL(BuildArtifactsPath(artifacts)));
if (OS::FileExists(src_artifacts->oat_path.c_str())) {
files_to_move.emplace_back(src_artifacts->oat_path, dst_artifacts->oat_path);
files_to_move.emplace_back(src_artifacts->vdex_path, dst_artifacts->vdex_path);
if (OS::FileExists(src_artifacts->art_path.c_str())) {
files_to_move.emplace_back(src_artifacts->art_path, dst_artifacts->art_path);
} else {
files_to_remove.push_back(dst_artifacts->art_path);
}
}
}
for (const WritableProfilePath& profile : in_profiles) {
RETURN_FATAL_IF_ARG_IS_PRE_REBOOT(profile, "profiles");
WritableProfilePath pre_reboot_profile = profile;
PreRebootFlag(pre_reboot_profile) = true;
auto src_profile = std::make_unique<std::string>(
OR_RETURN_FATAL(BuildWritableProfilePath(pre_reboot_profile)));
auto dst_profile =
std::make_unique<std::string>(OR_RETURN_FATAL(BuildWritableProfilePath(profile)));
if (OS::FileExists(src_profile->c_str())) {
files_to_move.emplace_back(*src_profile, *dst_profile);
}
}
OR_RETURN_NON_FATAL(MoveAllOrAbandon(files_to_move, files_to_remove));
for (const auto& [src_path, dst_path] : files_to_move) {
LOG(INFO) << ART_FORMAT("Committed Pre-reboot staged file '{}' to '{}'", src_path, dst_path);
}
return ScopedAStatus::ok();
}
Result<void> Artd::Start() {
OR_RETURN(SetLogVerbosity());
MemMap::Init();
ScopedAStatus status = ScopedAStatus::fromStatus(AServiceManager_registerLazyService(
this->asBinder().get(), options_.is_pre_reboot ? kPreRebootServiceName : kServiceName));
if (!status.isOk()) {
return Error() << status.getDescription();
}
ABinderProcess_startThreadPool();
return {};
}
Result<OatFileAssistantContext*> Artd::GetOatFileAssistantContext() {
std::lock_guard<std::mutex> lock(ofa_context_mu_);
if (ofa_context_ == nullptr) {
ofa_context_ = std::make_unique<OatFileAssistantContext>(
std::make_unique<OatFileAssistantContext::RuntimeOptions>(
OatFileAssistantContext::RuntimeOptions{
.image_locations = *OR_RETURN(GetBootImageLocations()),
.boot_class_path = *OR_RETURN(GetBootClassPath()),
.boot_class_path_locations = *OR_RETURN(GetBootClassPath()),
.deny_art_apex_data_files = DenyArtApexDataFiles(),
}));
std::string error_msg;
if (!ofa_context_->FetchAll(&error_msg)) {
return Error() << error_msg;
}
}
return ofa_context_.get();
}
Result<const std::vector<std::string>*> Artd::GetBootImageLocations() {
std::lock_guard<std::mutex> lock(cache_mu_);
if (!cached_boot_image_locations_.has_value()) {
std::string location_str;
if (UseJitZygoteLocked()) {
location_str = GetJitZygoteBootImageLocation();
} else if (std::string value = GetUserDefinedBootImageLocationsLocked(); !value.empty()) {
location_str = std::move(value);
} else {
std::string error_msg;
std::string android_root = GetAndroidRootSafe(&error_msg);
if (!error_msg.empty()) {
return Errorf("Failed to get ANDROID_ROOT: {}", error_msg);
}
location_str = GetDefaultBootImageLocation(android_root, DenyArtApexDataFilesLocked());
}
cached_boot_image_locations_ = Split(location_str, ":");
}
return &cached_boot_image_locations_.value();
}
Result<const std::vector<std::string>*> Artd::GetBootClassPath() {
std::lock_guard<std::mutex> lock(cache_mu_);
if (!cached_boot_class_path_.has_value()) {
const char* env_value = getenv("BOOTCLASSPATH");
if (env_value == nullptr || strlen(env_value) == 0) {
return Errorf("Failed to get environment variable 'BOOTCLASSPATH'");
}
cached_boot_class_path_ = Split(env_value, ":");
}
return &cached_boot_class_path_.value();
}
bool Artd::UseJitZygote() {
std::lock_guard<std::mutex> lock(cache_mu_);
return UseJitZygoteLocked();
}
bool Artd::UseJitZygoteLocked() {
if (!cached_use_jit_zygote_.has_value()) {
cached_use_jit_zygote_ =
props_->GetBool("persist.device_config.runtime_native_boot.profilebootclasspath",
"dalvik.vm.profilebootclasspath",
/*default_value=*/false);
}
return cached_use_jit_zygote_.value();
}
const std::string& Artd::GetUserDefinedBootImageLocations() {
std::lock_guard<std::mutex> lock(cache_mu_);
return GetUserDefinedBootImageLocationsLocked();
}
const std::string& Artd::GetUserDefinedBootImageLocationsLocked() {
if (!cached_user_defined_boot_image_locations_.has_value()) {
cached_user_defined_boot_image_locations_ = props_->GetOrEmpty("dalvik.vm.boot-image");
}
return cached_user_defined_boot_image_locations_.value();
}
bool Artd::DenyArtApexDataFiles() {
std::lock_guard<std::mutex> lock(cache_mu_);
return DenyArtApexDataFilesLocked();
}
bool Artd::DenyArtApexDataFilesLocked() {
if (!cached_deny_art_apex_data_files_.has_value()) {
cached_deny_art_apex_data_files_ =
!props_->GetBool("odsign.verification.success", /*default_value=*/false);
}
return cached_deny_art_apex_data_files_.value();
}
Result<std::string> Artd::GetProfman() { return BuildArtBinPath("profman"); }
Result<CmdlineBuilder> Artd::GetArtExecCmdlineBuilder() {
CmdlineBuilder args;
args.Add(OR_RETURN(BuildArtBinPath("art_exec")))
.Add("--drop-capabilities")
.AddIf(options_.is_pre_reboot, "--process-name-suffix=Pre-reboot Dexopt chroot");
return args;
}
bool Artd::ShouldUseDex2Oat64() {
return !props_->GetOrEmpty("ro.product.cpu.abilist64").empty() &&
props_->GetBool("dalvik.vm.dex2oat64.enabled", /*default_value=*/false);
}
Result<std::string> Artd::GetDex2Oat() {
std::string binary_name = ShouldUseDex2Oat64() ? "dex2oat64" : "dex2oat32";
// TODO(b/234351700): Should we use the "d" variant?
return BuildArtBinPath(binary_name);
}
bool Artd::ShouldCreateSwapFileForDexopt() {
// Create a swap file by default. Dex2oat will decide whether to use it or not.
return props_->GetBool("dalvik.vm.dex2oat-swap", /*default_value=*/true);
}
void Artd::AddBootImageFlags(/*out*/ CmdlineBuilder& args) {
if (UseJitZygote()) {
args.Add("--force-jit-zygote");
} else {
args.AddIfNonEmpty("--boot-image=%s", GetUserDefinedBootImageLocations());
}
}
void Artd::AddCompilerConfigFlags(const std::string& instruction_set,
const std::string& compiler_filter,
PriorityClass priority_class,
const DexoptOptions& dexopt_options,
/*out*/ CmdlineBuilder& args) {
args.Add("--instruction-set=%s", instruction_set);
std::string features_prop = ART_FORMAT("dalvik.vm.isa.{}.features", instruction_set);
args.AddIfNonEmpty("--instruction-set-features=%s", props_->GetOrEmpty(features_prop));
std::string variant_prop = ART_FORMAT("dalvik.vm.isa.{}.variant", instruction_set);
args.AddIfNonEmpty("--instruction-set-variant=%s", props_->GetOrEmpty(variant_prop));
args.Add("--compiler-filter=%s", compiler_filter)
.Add("--compilation-reason=%s", dexopt_options.compilationReason);
args.AddIf(priority_class >= PriorityClass::INTERACTIVE, "--compact-dex-level=none");
args.AddIfNonEmpty("--max-image-block-size=%s",
props_->GetOrEmpty("dalvik.vm.dex2oat-max-image-block-size"))
.AddIfNonEmpty("--very-large-app-threshold=%s",
props_->GetOrEmpty("dalvik.vm.dex2oat-very-large"))
.AddIfNonEmpty(
"--resolve-startup-const-strings=%s",
props_->GetOrEmpty("dalvik.vm.dex2oat-resolve-startup-strings"));
args.AddIf(dexopt_options.debuggable, "--debuggable")
.AddIf(props_->GetBool("debug.generate-debug-info", /*default_value=*/false),
"--generate-debug-info")
.AddIf(props_->GetBool("dalvik.vm.dex2oat-minidebuginfo", /*default_value=*/false),
"--generate-mini-debug-info");
args.AddRuntimeIf(DenyArtApexDataFiles(), "-Xdeny-art-apex-data-files")
.AddRuntime("-Xtarget-sdk-version:%d", dexopt_options.targetSdkVersion)
.AddRuntimeIf(dexopt_options.hiddenApiPolicyEnabled, "-Xhidden-api-policy:enabled");
}
void Artd::AddPerfConfigFlags(PriorityClass priority_class,
/*out*/ CmdlineBuilder& art_exec_args,
/*out*/ CmdlineBuilder& dex2oat_args) {
// CPU set and number of threads.
std::string default_cpu_set_prop = "dalvik.vm.dex2oat-cpu-set";
std::string default_threads_prop = "dalvik.vm.dex2oat-threads";
std::string cpu_set;
std::string threads;
if (priority_class >= PriorityClass::BOOT) {
cpu_set = props_->GetOrEmpty("dalvik.vm.boot-dex2oat-cpu-set");
threads = props_->GetOrEmpty("dalvik.vm.boot-dex2oat-threads");
} else if (priority_class >= PriorityClass::INTERACTIVE_FAST) {
cpu_set = props_->GetOrEmpty("dalvik.vm.restore-dex2oat-cpu-set", default_cpu_set_prop);
threads = props_->GetOrEmpty("dalvik.vm.restore-dex2oat-threads", default_threads_prop);
} else if (priority_class <= PriorityClass::BACKGROUND) {
cpu_set = props_->GetOrEmpty("dalvik.vm.background-dex2oat-cpu-set", default_cpu_set_prop);
threads = props_->GetOrEmpty("dalvik.vm.background-dex2oat-threads", default_threads_prop);
} else {
cpu_set = props_->GetOrEmpty(default_cpu_set_prop);
threads = props_->GetOrEmpty(default_threads_prop);
}
dex2oat_args.AddIfNonEmpty("--cpu-set=%s", cpu_set).AddIfNonEmpty("-j%s", threads);
if (priority_class < PriorityClass::BOOT) {
art_exec_args
.Add(priority_class <= PriorityClass::BACKGROUND ? "--set-task-profile=Dex2OatBackground" :
"--set-task-profile=Dex2OatBootComplete")
.Add("--set-priority=background");
}
dex2oat_args.AddRuntimeIfNonEmpty("-Xms%s", props_->GetOrEmpty("dalvik.vm.dex2oat-Xms"))
.AddRuntimeIfNonEmpty("-Xmx%s", props_->GetOrEmpty("dalvik.vm.dex2oat-Xmx"));
// Enable compiling dex files in isolation on low ram devices.
// It takes longer but reduces the memory footprint.
dex2oat_args.AddIf(props_->GetBool("ro.config.low_ram", /*default_value=*/false),
"--compile-individually");
for (const std::string& flag :
Tokenize(props_->GetOrEmpty("dalvik.vm.dex2oat-flags"), /*delimiters=*/" ")) {
dex2oat_args.AddIfNonEmpty("%s", flag);
}
}
Result<int> Artd::ExecAndReturnCode(const std::vector<std::string>& args,
int timeout_sec,
const ExecCallbacks& callbacks,
ProcessStat* stat) const {
std::string error_msg;
ExecResult result =
exec_utils_->ExecAndReturnResult(args, timeout_sec, callbacks, stat, &error_msg);
if (result.status != ExecResult::kExited) {
return Error() << error_msg;
}
return result.exit_code;
}
Result<struct stat> Artd::Fstat(const File& file) const {
struct stat st;
if (fstat_(file.Fd(), &st) != 0) {
return Errorf("Unable to fstat file '{}'", file.GetPath());
}
return st;
}
Result<void> Artd::BindMountNewDir(const std::string& source, const std::string& target) const {
OR_RETURN(CreateDir(source));
OR_RETURN(BindMount(source, target));
OR_RETURN(restorecon_(target, /*se_context=*/std::nullopt, /*recurse=*/false));
return {};
}
Result<void> Artd::BindMount(const std::string& source, const std::string& target) const {
if (mount_(source.c_str(),
target.c_str(),
/*fs_type=*/nullptr,
MS_BIND | MS_PRIVATE,
/*data=*/nullptr) != 0) {
return ErrnoErrorf("Failed to bind-mount '{}' at '{}'", source, target);
}
return {};
}
ScopedAStatus Artd::preRebootInit() {
RETURN_FATAL_IF_NOT_PRE_REBOOT(options_);
std::string tmp_dir = pre_reboot_tmp_dir_.value_or(kDefaultPreRebootTmpDir);
std::string preparation_done_file = tmp_dir + "/preparation_done";
std::string classpath_file = tmp_dir + "/classpath.txt";
std::string art_apex_data_dir = tmp_dir + "/art_apex_data";
std::string odrefresh_dir = tmp_dir + "/odrefresh";
bool preparation_done = OS::FileExists(preparation_done_file.c_str());
if (!preparation_done) {
std::error_code ec;
bool is_empty = std::filesystem::is_empty(tmp_dir, ec);
if (ec) {
return NonFatal(ART_FORMAT("Failed to check dir '{}': {}", tmp_dir, ec.message()));
}
if (!is_empty) {
return Fatal("preRebootInit must not be concurrently called or retried after failure");
}
}
OR_RETURN_NON_FATAL(PreRebootInitClearEnvs());
OR_RETURN_NON_FATAL(
PreRebootInitSetEnvFromFile(init_environ_rc_path_.value_or("/init.environ.rc")));
if (!preparation_done) {
OR_RETURN_NON_FATAL(PreRebootInitDeriveClasspath(classpath_file));
}
OR_RETURN_NON_FATAL(PreRebootInitSetEnvFromFile(classpath_file));
if (!preparation_done) {
OR_RETURN_NON_FATAL(BindMountNewDir(art_apex_data_dir, GetArtApexData()));
OR_RETURN_NON_FATAL(BindMountNewDir(odrefresh_dir, "/data/misc/odrefresh"));
OR_RETURN_NON_FATAL(PreRebootInitBootImages());
}
if (!preparation_done) {
if (!WriteStringToFile(/*content=*/"", preparation_done_file)) {
return NonFatal(
ART_FORMAT("Failed to write '{}': {}", preparation_done_file, strerror(errno)));
}
}
return ScopedAStatus::ok();
}
Result<void> Artd::PreRebootInitClearEnvs() {
if (clearenv() != 0) {
return ErrnoErrorf("Failed to clear environment variables");
}
return {};
}
Result<void> Artd::PreRebootInitSetEnvFromFile(const std::string& path) {
std::regex export_line_pattern("\\s*export\\s+(.+?)\\s+(.+)");
std::string content;
if (!ReadFileToString(path, &content)) {
return ErrnoErrorf("Failed to read '{}'", path);
}
bool found = false;
for (const std::string& line : Split(content, "\n")) {
if (line.find_first_of("\\\"") != std::string::npos) {
return Errorf("Backslashes and quotes in env var file are not supported for now, got '{}'",
line);
}
std::smatch match;
if (!std::regex_match(line, match, export_line_pattern)) {
continue;
}
const std::string& key = match[1].str();
const std::string& value = match[2].str();
LOG(INFO) << ART_FORMAT("Setting environment variable '{}' to '{}'", key, value);
if (setenv(key.c_str(), value.c_str(), /*replace=*/1) != 0) {
return ErrnoErrorf("Failed to set environment variable '{}' to '{}'", key, value);
}
found = true;
}
if (!found) {
return Errorf("Malformed env var file '{}': {}", path, content);
}
return {};
}
Result<void> Artd::PreRebootInitDeriveClasspath(const std::string& path) {
std::unique_ptr<File> output(OS::CreateEmptyFile(path.c_str()));
if (output == nullptr) {
return ErrnoErrorf("Failed to create '{}'", path);
}
CmdlineBuilder args = OR_RETURN(GetArtExecCmdlineBuilder());
args.Add("--keep-fds=%d", output->Fd())
.Add("--")
.Add("/apex/com.android.sdkext/bin/derive_classpath")
.Add("/proc/self/fd/%d", output->Fd());
LOG(INFO) << "Running derive_classpath: " << Join(args.Get(), /*separator=*/" ");
Result<int> result = ExecAndReturnCode(args.Get(), kShortTimeoutSec);
if (!result.ok()) {
return Errorf("Failed to run derive_classpath: {}", result.error().message());
}
LOG(INFO) << ART_FORMAT("derive_classpath returned code {}", result.value());
if (result.value() != 0) {
return Errorf("derive_classpath returned an unexpected code: {}", result.value());
}
if (output->FlushClose() != 0) {
return ErrnoErrorf("Failed to flush and close '{}'", path);
}
return {};
}
Result<void> Artd::PreRebootInitBootImages() {
CmdlineBuilder args = OR_RETURN(GetArtExecCmdlineBuilder());
args.Add("--")
.Add(OR_RETURN(BuildArtBinPath("odrefresh")))
.Add("--only-boot-images")
.Add("--compile");
LOG(INFO) << "Running odrefresh: " << Join(args.Get(), /*separator=*/" ");
Result<int> result = ExecAndReturnCode(args.Get(), kLongTimeoutSec);
if (!result.ok()) {
return Errorf("Failed to run odrefresh: {}", result.error().message());
}
LOG(INFO) << ART_FORMAT("odrefresh returned code {}", result.value());
if (result.value() != odrefresh::ExitCode::kCompilationSuccess &&
result.value() != odrefresh::ExitCode::kOkay) {
return Errorf("odrefresh returned an unexpected code: {}", result.value());
}
return {};
}
ScopedAStatus Artd::validateDexPath(const std::string& in_dexFile,
std::optional<std::string>* _aidl_return) {
RETURN_FATAL_IF_NOT_PRE_REBOOT(options_);
if (Result<void> result = ValidateDexPath(in_dexFile); !result.ok()) {
*_aidl_return = result.error().message();
} else {
*_aidl_return = std::nullopt;
}
return ScopedAStatus::ok();
}
ScopedAStatus Artd::validateClassLoaderContext(const std::string& in_dexFile,
const std::string& in_classLoaderContext,
std::optional<std::string>* _aidl_return) {
RETURN_FATAL_IF_NOT_PRE_REBOOT(options_);
if (Result<void> result = ValidateClassLoaderContext(in_dexFile, in_classLoaderContext);
!result.ok()) {
*_aidl_return = result.error().message();
} else {
*_aidl_return = std::nullopt;
}
return ScopedAStatus::ok();
}
} // namespace artd
} // namespace art