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LeafOS / LeafOS-Project / android_art / c210ab55bcebda93f4e21d6df6e1dca5a5e152c5 / . / odrefresh / odrefresh.cc
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/*
* Copyright (C) 2020 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 "odrefresh.h"
#include <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <limits.h>
#include <stdio.h>
#include <string.h>
#include <sys/stat.h>
#include <sysexits.h>
#include <time.h>
#include <unistd.h>
#include <algorithm>
#include <cerrno>
#include <cstdarg>
#include <cstdint>
#include <cstdio>
#include <cstdlib>
#include <cstring>
#include <filesystem>
#include <fstream>
#include <functional>
#include <initializer_list>
#include <iosfwd>
#include <iostream>
#include <iterator>
#include <memory>
#include <optional>
#include <ostream>
#include <set>
#include <sstream>
#include <string>
#include <string_view>
#include <system_error>
#include <type_traits>
#include <unordered_map>
#include <unordered_set>
#include <utility>
#include <vector>
#include "android-base/chrono_utils.h"
#include "android-base/file.h"
#include "android-base/function_ref.h"
#include "android-base/logging.h"
#include "android-base/macros.h"
#include "android-base/parseint.h"
#include "android-base/properties.h"
#include "android-base/result.h"
#include "android-base/scopeguard.h"
#include "android-base/stringprintf.h"
#include "android-base/strings.h"
#include "android-modules-utils/sdk_level.h"
#include "arch/instruction_set.h"
#include "base/file_utils.h"
#include "base/logging.h"
#include "base/macros.h"
#include "base/os.h"
#include "base/stl_util.h"
#include "base/unix_file/fd_file.h"
#include "com_android_apex.h"
#include "com_android_art.h"
#include "dex/art_dex_file_loader.h"
#include "exec_utils.h"
#include "gc/collector/mark_compact.h"
#include "odr_artifacts.h"
#include "odr_common.h"
#include "odr_config.h"
#include "odr_fs_utils.h"
#include "odr_metrics.h"
#include "odrefresh/odrefresh.h"
#include "palette/palette.h"
#include "palette/palette_types.h"
#include "tools/cmdline_builder.h"
namespace art {
namespace odrefresh {
namespace {
namespace apex = com::android::apex;
namespace art_apex = com::android::art;
using ::android::base::Basename;
using ::android::base::Dirname;
using ::android::base::Join;
using ::android::base::ParseInt;
using ::android::base::Result;
using ::android::base::SetProperty;
using ::android::base::Split;
using ::android::base::StartsWith;
using ::android::base::StringPrintf;
using ::android::base::Timer;
using ::android::modules::sdklevel::IsAtLeastU;
using ::android::modules::sdklevel::IsAtLeastV;
using ::art::tools::CmdlineBuilder;
// Name of cache info file in the ART Apex artifact cache.
constexpr const char* kCacheInfoFile = "cache-info.xml";
// Maximum execution time for odrefresh from start to end.
constexpr time_t kMaximumExecutionSeconds = 480;
// Maximum execution time for any child process spawned.
constexpr time_t kMaxChildProcessSeconds = 120;
constexpr mode_t kFileMode = S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH;
constexpr const char* kFirstBootImageBasename = "boot.art";
constexpr const char* kMinimalBootImageBasename = "boot_minimal.art";
// The default compiler filter for primary boot image.
constexpr const char* kPrimaryCompilerFilter = "speed-profile";
// The compiler filter for boot image mainline extension. We don't have profiles for mainline BCP
// jars, so we always use "verify".
constexpr const char* kMainlineCompilerFilter = "verify";
void EraseFiles(const std::vector<std::unique_ptr<File>>& files) {
for (auto& file : files) {
file->Erase(/*unlink=*/true);
}
}
// Moves `files` to the directory `output_directory_path`.
//
// If any of the files cannot be moved, then all copies of the files are removed from both
// the original location and the output location.
//
// Returns true if all files are moved, false otherwise.
bool MoveOrEraseFiles(const std::vector<std::unique_ptr<File>>& files,
std::string_view output_directory_path) {
std::vector<std::unique_ptr<File>> output_files;
for (auto& file : files) {
std::string file_basename(Basename(file->GetPath()));
std::string output_file_path = ART_FORMAT("{}/{}", output_directory_path, file_basename);
std::string input_file_path = file->GetPath();
output_files.emplace_back(OS::CreateEmptyFileWriteOnly(output_file_path.c_str()));
if (output_files.back() == nullptr) {
PLOG(ERROR) << "Failed to open " << QuotePath(output_file_path);
output_files.pop_back();
EraseFiles(output_files);
EraseFiles(files);
return false;
}
if (fchmod(output_files.back()->Fd(), kFileMode) != 0) {
PLOG(ERROR) << "Could not set file mode on " << QuotePath(output_file_path);
EraseFiles(output_files);
EraseFiles(files);
return false;
}
size_t file_bytes = file->GetLength();
if (!output_files.back()->Copy(file.get(), /*offset=*/0, file_bytes)) {
PLOG(ERROR) << "Failed to copy " << QuotePath(file->GetPath()) << " to "
<< QuotePath(output_file_path);
EraseFiles(output_files);
EraseFiles(files);
return false;
}
if (!file->Erase(/*unlink=*/true)) {
PLOG(ERROR) << "Failed to erase " << QuotePath(file->GetPath());
EraseFiles(output_files);
EraseFiles(files);
return false;
}
if (output_files.back()->FlushCloseOrErase() != 0) {
PLOG(ERROR) << "Failed to flush and close file " << QuotePath(output_file_path);
EraseFiles(output_files);
EraseFiles(files);
return false;
}
}
return true;
}
// Gets the `ApexInfo` associated with the currently active ART APEX.
std::optional<apex::ApexInfo> GetArtApexInfo(const std::vector<apex::ApexInfo>& info_list) {
auto it = std::find_if(info_list.begin(), info_list.end(), [](const apex::ApexInfo& info) {
return info.getModuleName() == "com.android.art";
});
return it != info_list.end() ? std::make_optional(*it) : std::nullopt;
}
// Returns cache provenance information based on the current APEX version and filesystem
// information.
art_apex::ModuleInfo GenerateModuleInfo(const apex::ApexInfo& apex_info) {
// The lastUpdateMillis is an addition to ApexInfoList.xsd to support samegrade installs.
int64_t last_update_millis =
apex_info.hasLastUpdateMillis() ? apex_info.getLastUpdateMillis() : 0;
return art_apex::ModuleInfo{apex_info.getModuleName(),
apex_info.getVersionCode(),
apex_info.getVersionName(),
last_update_millis};
}
// Returns cache provenance information for all APEXes.
std::vector<art_apex::ModuleInfo> GenerateModuleInfoList(
const std::vector<apex::ApexInfo>& apex_info_list) {
std::vector<art_apex::ModuleInfo> module_info_list;
std::transform(apex_info_list.begin(),
apex_info_list.end(),
std::back_inserter(module_info_list),
GenerateModuleInfo);
return module_info_list;
}
// Returns a rewritten path based on environment variables for interesting paths.
std::string RewriteParentDirectoryIfNeeded(const std::string& path) {
if (StartsWith(path, "/system/")) {
return GetAndroidRoot() + path.substr(7);
} else if (StartsWith(path, "/system_ext/")) {
return GetSystemExtRoot() + path.substr(11);
} else {
return path;
}
}
template <typename T>
Result<void> CheckComponents(
const std::vector<T>& expected_components,
const std::vector<T>& actual_components,
const std::function<Result<void>(const T& expected, const T& actual)>& custom_checker =
[](const T&, const T&) -> Result<void> { return {}; }) {
if (expected_components.size() != actual_components.size()) {
return Errorf(
"Component count differs ({} != {})", expected_components.size(), actual_components.size());
}
for (size_t i = 0; i < expected_components.size(); ++i) {
const T& expected = expected_components[i];
const T& actual = actual_components[i];
if (expected.getFile() != actual.getFile()) {
return Errorf(
"Component {} file differs ('{}' != '{}')", i, expected.getFile(), actual.getFile());
}
if (expected.getSize() != actual.getSize()) {
return Errorf(
"Component {} size differs ({} != {})", i, expected.getSize(), actual.getSize());
}
if (expected.getChecksums() != actual.getChecksums()) {
return Errorf("Component {} checksums differ ('{}' != '{}')",
i,
expected.getChecksums(),
actual.getChecksums());
}
Result<void> result = custom_checker(expected, actual);
if (!result.ok()) {
return Errorf("Component {} {}", i, result.error().message());
}
}
return {};
}
Result<void> CheckSystemServerComponents(
const std::vector<art_apex::SystemServerComponent>& expected_components,
const std::vector<art_apex::SystemServerComponent>& actual_components) {
return CheckComponents<art_apex::SystemServerComponent>(
expected_components,
actual_components,
[](const art_apex::SystemServerComponent& expected,
const art_apex::SystemServerComponent& actual) -> Result<void> {
if (expected.getIsInClasspath() != actual.getIsInClasspath()) {
return Errorf("isInClasspath differs ({} != {})",
expected.getIsInClasspath(),
actual.getIsInClasspath());
}
return {};
});
}
template <typename T>
std::vector<T> GenerateComponents(
const std::vector<std::string>& jars,
const std::function<T(const std::string& path, uint64_t size, const std::string& checksum)>&
custom_generator) {
std::vector<T> components;
for (const std::string& path : jars) {
std::string actual_path = RewriteParentDirectoryIfNeeded(path);
struct stat sb;
if (stat(actual_path.c_str(), &sb) == -1) {
PLOG(ERROR) << "Failed to stat component: " << QuotePath(actual_path);
return {};
}
std::optional<uint32_t> checksum;
std::string error_msg;
ArtDexFileLoader dex_loader(actual_path);
if (!dex_loader.GetMultiDexChecksum(&checksum, &error_msg)) {
LOG(ERROR) << "Failed to get multi-dex checksum: " << error_msg;
return {};
}
const std::string checksum_str =
checksum.has_value() ? StringPrintf("%08x", checksum.value()) : std::string();
Result<T> component = custom_generator(path, static_cast<uint64_t>(sb.st_size), checksum_str);
if (!component.ok()) {
LOG(ERROR) << "Failed to generate component: " << component.error();
return {};
}
components.push_back(*std::move(component));
}
return components;
}
std::vector<art_apex::Component> GenerateComponents(const std::vector<std::string>& jars) {
return GenerateComponents<art_apex::Component>(
jars, [](const std::string& path, uint64_t size, const std::string& checksum) {
return art_apex::Component{path, size, checksum};
});
}
// Checks whether a group of artifacts exists. Returns true if all are present, false otherwise.
// If `checked_artifacts` is present, adds checked artifacts to `checked_artifacts`.
bool ArtifactsExist(const OdrArtifacts& artifacts,
bool check_art_file,
/*out*/ std::string* error_msg,
/*out*/ std::vector<std::string>* checked_artifacts = nullptr) {
std::vector<const char*> paths{artifacts.OatPath().c_str(), artifacts.VdexPath().c_str()};
if (check_art_file) {
paths.push_back(artifacts.ImagePath().c_str());
}
for (const char* path : paths) {
if (!OS::FileExists(path)) {
if (errno == EACCES) {
PLOG(ERROR) << "Failed to stat() " << path;
}
*error_msg = "Missing file: " + QuotePath(path);
return false;
}
}
// This should be done after checking all artifacts because either all of them are valid or none
// of them is valid.
if (checked_artifacts != nullptr) {
for (const char* path : paths) {
checked_artifacts->emplace_back(path);
}
}
return true;
}
void AddDex2OatCommonOptions(/*inout*/ CmdlineBuilder& args) {
args.Add("--android-root=out/empty");
args.Add("--abort-on-hard-verifier-error");
args.Add("--no-abort-on-soft-verifier-error");
args.Add("--compilation-reason=boot");
args.Add("--image-format=lz4");
args.Add("--force-determinism");
args.Add("--resolve-startup-const-strings=true");
// Avoid storing dex2oat cmdline in oat header. We want to be sure that the compiled artifacts
// are identical regardless of where the compilation happened. But some of the cmdline flags tends
// to be unstable, e.g. those contains FD numbers. To avoid the problem, the whole cmdline is not
// added to the oat header.
args.Add("--avoid-storing-invocation");
}
bool IsCpuSetSpecValid(const std::string& cpu_set) {
for (const std::string& str : Split(cpu_set, ",")) {
int id;
if (!ParseInt(str, &id, 0)) {
return false;
}
}
return true;
}
Result<void> AddDex2OatConcurrencyArguments(/*inout*/ CmdlineBuilder& args,
bool is_compilation_os,
const OdrSystemProperties& system_properties) {
std::string threads;
if (is_compilation_os) {
threads = system_properties.GetOrEmpty("dalvik.vm.background-dex2oat-threads",
"dalvik.vm.dex2oat-threads");
} else {
threads = system_properties.GetOrEmpty("dalvik.vm.boot-dex2oat-threads");
}
args.AddIfNonEmpty("-j%s", threads);
std::string cpu_set;
if (is_compilation_os) {
cpu_set = system_properties.GetOrEmpty("dalvik.vm.background-dex2oat-cpu-set",
"dalvik.vm.dex2oat-cpu-set");
} else {
cpu_set = system_properties.GetOrEmpty("dalvik.vm.boot-dex2oat-cpu-set");
}
if (!cpu_set.empty()) {
if (!IsCpuSetSpecValid(cpu_set)) {
return Errorf("Invalid CPU set spec '{}'", cpu_set);
}
args.Add("--cpu-set=%s", cpu_set);
}
return {};
}
void AddDex2OatDebugInfo(/*inout*/ CmdlineBuilder& args) {
args.Add("--generate-mini-debug-info");
args.Add("--strip");
}
void AddDex2OatInstructionSet(/*inout*/ CmdlineBuilder& args,
InstructionSet isa,
const OdrSystemProperties& system_properties) {
const char* isa_str = GetInstructionSetString(isa);
args.Add("--instruction-set=%s", isa_str);
std::string features_prop = ART_FORMAT("dalvik.vm.isa.{}.features", isa_str);
args.AddIfNonEmpty("--instruction-set-features=%s", system_properties.GetOrEmpty(features_prop));
std::string variant_prop = ART_FORMAT("dalvik.vm.isa.{}.variant", isa_str);
args.AddIfNonEmpty("--instruction-set-variant=%s", system_properties.GetOrEmpty(variant_prop));
}
// Returns true if any profile has been added, or false if no profile exists, or error if any error
// occurred.
Result<bool> AddDex2OatProfile(
/*inout*/ CmdlineBuilder& args,
/*inout*/ std::vector<std::unique_ptr<File>>& output_files,
const std::vector<std::string>& profile_paths) {
bool has_any_profile = false;
for (const std::string& path : profile_paths) {
std::unique_ptr<File> profile_file(OS::OpenFileForReading(path.c_str()));
if (profile_file != nullptr) {
args.Add("--profile-file-fd=%d", profile_file->Fd());
output_files.emplace_back(std::move(profile_file));
has_any_profile = true;
} else if (errno != ENOENT) {
return ErrnoErrorf("Failed to open profile file '{}'", path);
}
}
return has_any_profile;
}
Result<void> AddBootClasspathFds(/*inout*/ CmdlineBuilder& args,
/*inout*/ std::vector<std::unique_ptr<File>>& output_files,
const std::vector<std::string>& bcp_jars) {
std::vector<std::string> bcp_fds;
for (const std::string& jar : bcp_jars) {
// Special treatment for Compilation OS. JARs in staged APEX may not be visible to Android, and
// may only be visible in the VM where the staged APEX is mounted. On the contrary, JARs in
// /system is not available by path in the VM, and can only made available via (remote) FDs.
if (StartsWith(jar, "/apex/")) {
bcp_fds.emplace_back("-1");
} else {
std::string actual_path = RewriteParentDirectoryIfNeeded(jar);
std::unique_ptr<File> jar_file(OS::OpenFileForReading(actual_path.c_str()));
if (jar_file == nullptr) {
return ErrnoErrorf("Failed to open a BCP jar '{}'", actual_path);
}
bcp_fds.push_back(std::to_string(jar_file->Fd()));
output_files.push_back(std::move(jar_file));
}
}
args.AddRuntime("-Xbootclasspathfds:%s", Join(bcp_fds, ':'));
return {};
}
Result<void> AddCacheInfoFd(/*inout*/ CmdlineBuilder& args,
/*inout*/ std::vector<std::unique_ptr<File>>& readonly_files_raii,
const std::string& cache_info_filename) {
std::unique_ptr<File> cache_info_file(OS::OpenFileForReading(cache_info_filename.c_str()));
if (cache_info_file == nullptr) {
return ErrnoErrorf("Failed to open a cache info file '{}'", cache_info_filename);
}
args.Add("--cache-info-fd=%d", cache_info_file->Fd());
readonly_files_raii.push_back(std::move(cache_info_file));
return {};
}
std::string GetBootImageComponentBasename(const std::string& jar_path, bool is_first_jar) {
if (is_first_jar) {
return kFirstBootImageBasename;
}
std::string jar_name = Basename(jar_path);
return "boot-" + ReplaceFileExtension(jar_name, "art");
}
Result<void> AddCompiledBootClasspathFdsIfAny(
/*inout*/ CmdlineBuilder& args,
/*inout*/ std::vector<std::unique_ptr<File>>& output_files,
const std::vector<std::string>& bcp_jars,
InstructionSet isa,
const std::vector<std::string>& boot_image_locations) {
std::vector<std::string> bcp_image_fds;
std::vector<std::string> bcp_oat_fds;
std::vector<std::string> bcp_vdex_fds;
std::vector<std::unique_ptr<File>> opened_files;
bool added_any = false;
std::string artifact_dir;
for (size_t i = 0; i < bcp_jars.size(); i++) {
const std::string& jar = bcp_jars[i];
std::string basename = GetBootImageComponentBasename(jar, /*is_first_jar=*/i == 0);
// If there is an entry in `boot_image_locations` for the current jar, update `artifact_dir` for
// the current jar and the subsequent jars.
for (const std::string& location : boot_image_locations) {
if (Basename(location) == basename) {
artifact_dir = Dirname(location);
break;
}
}
CHECK(!artifact_dir.empty());
std::string image_path = ART_FORMAT("{}/{}", artifact_dir, basename);
image_path = GetSystemImageFilename(image_path.c_str(), isa);
std::unique_ptr<File> image_file(OS::OpenFileForReading(image_path.c_str()));
if (image_file != nullptr) {
bcp_image_fds.push_back(std::to_string(image_file->Fd()));
opened_files.push_back(std::move(image_file));
added_any = true;
} else if (errno == ENOENT) {
bcp_image_fds.push_back("-1");
} else {
return ErrnoErrorf("Failed to open boot image file '{}'", image_path);
}
std::string oat_path = ReplaceFileExtension(image_path, "oat");
std::unique_ptr<File> oat_file(OS::OpenFileForReading(oat_path.c_str()));
if (oat_file != nullptr) {
bcp_oat_fds.push_back(std::to_string(oat_file->Fd()));
opened_files.push_back(std::move(oat_file));
added_any = true;
} else if (errno == ENOENT) {
bcp_oat_fds.push_back("-1");
} else {
return ErrnoErrorf("Failed to open boot image file '{}'", oat_path);
}
std::string vdex_path = ReplaceFileExtension(image_path, "vdex");
std::unique_ptr<File> vdex_file(OS::OpenFileForReading(vdex_path.c_str()));
if (vdex_file != nullptr) {
bcp_vdex_fds.push_back(std::to_string(vdex_file->Fd()));
opened_files.push_back(std::move(vdex_file));
added_any = true;
} else if (errno == ENOENT) {
bcp_vdex_fds.push_back("-1");
} else {
return ErrnoErrorf("Failed to open boot image file '{}'", vdex_path);
}
}
// Add same amount of FDs as BCP JARs, or none.
if (added_any) {
std::move(opened_files.begin(), opened_files.end(), std::back_inserter(output_files));
args.AddRuntime("-Xbootclasspathimagefds:%s", Join(bcp_image_fds, ':'));
args.AddRuntime("-Xbootclasspathoatfds:%s", Join(bcp_oat_fds, ':'));
args.AddRuntime("-Xbootclasspathvdexfds:%s", Join(bcp_vdex_fds, ':'));
}
return {};
}
std::string GetStagingLocation(const std::string& staging_dir, const std::string& path) {
return staging_dir + "/" + Basename(path);
}
WARN_UNUSED bool CheckCompilationSpace() {
// Check the available storage space against an arbitrary threshold because dex2oat does not
// report when it runs out of storage space and we do not want to completely fill
// the users data partition.
//
// We do not have a good way of pre-computing the required space for a compilation step, but
// typically observe no more than 48MiB as the largest total size of AOT artifacts for a single
// dex2oat invocation, which includes an image file, an executable file, and a verification data
// file.
static constexpr uint64_t kMinimumSpaceForCompilation = 48 * 1024 * 1024;
uint64_t bytes_available;
const std::string& art_apex_data_path = GetArtApexData();
if (!GetFreeSpace(art_apex_data_path, &bytes_available)) {
return false;
}
if (bytes_available < kMinimumSpaceForCompilation) {
LOG(WARNING) << "Low space for " << QuotePath(art_apex_data_path) << " (" << bytes_available
<< " bytes)";
return false;
}
return true;
}
bool HasVettedDeviceSystemServerProfiles() {
// While system_server profiles were bundled on the device prior to U+, they were not used by
// default or rigorously tested, so we cannot vouch for their efficacy.
static const bool kDeviceIsAtLeastU = IsAtLeastU();
return kDeviceIsAtLeastU;
}
} // namespace
CompilationOptions CompilationOptions::CompileAll(const OnDeviceRefresh& odr) {
CompilationOptions options;
for (InstructionSet isa : odr.Config().GetBootClasspathIsas()) {
options.boot_images_to_generate_for_isas.emplace_back(
isa, BootImages{.primary_boot_image = true, .boot_image_mainline_extension = true});
}
options.system_server_jars_to_compile = odr.AllSystemServerJars();
return options;
}
int BootImages::Count() const {
int count = 0;
if (primary_boot_image) {
count++;
}
if (boot_image_mainline_extension) {
count++;
}
return count;
}
OdrMetrics::BcpCompilationType BootImages::GetTypeForMetrics() const {
if (primary_boot_image && boot_image_mainline_extension) {
return OdrMetrics::BcpCompilationType::kPrimaryAndMainline;
}
if (boot_image_mainline_extension) {
return OdrMetrics::BcpCompilationType::kMainline;
}
LOG(FATAL) << "Unexpected BCP compilation type";
UNREACHABLE();
}
int CompilationOptions::CompilationUnitCount() const {
int count = 0;
for (const auto& [isa, boot_images] : boot_images_to_generate_for_isas) {
count += boot_images.Count();
}
count += system_server_jars_to_compile.size();
return count;
}
OnDeviceRefresh::OnDeviceRefresh(const OdrConfig& config)
: OnDeviceRefresh(config,
config.GetArtifactDirectory() + "/" + kCacheInfoFile,
std::make_unique<ExecUtils>(),
CheckCompilationSpace) {}
OnDeviceRefresh::OnDeviceRefresh(const OdrConfig& config,
const std::string& cache_info_filename,
std::unique_ptr<ExecUtils> exec_utils,
android::base::function_ref<bool()> check_compilation_space)
: config_(config),
cache_info_filename_(cache_info_filename),
start_time_(time(nullptr)),
exec_utils_(std::move(exec_utils)),
check_compilation_space_(check_compilation_space) {
// Updatable APEXes should not have DEX files in the DEX2OATBOOTCLASSPATH. At the time of
// writing i18n is a non-updatable APEX and so does appear in the DEX2OATBOOTCLASSPATH.
dex2oat_boot_classpath_jars_ = Split(config_.GetDex2oatBootClasspath(), ":");
all_systemserver_jars_ = Split(config_.GetSystemServerClasspath(), ":");
systemserver_classpath_jars_ = {all_systemserver_jars_.begin(), all_systemserver_jars_.end()};
boot_classpath_jars_ = Split(config_.GetBootClasspath(), ":");
std::string standalone_system_server_jars_str = config_.GetStandaloneSystemServerJars();
if (!standalone_system_server_jars_str.empty()) {
std::vector<std::string> standalone_systemserver_jars =
Split(standalone_system_server_jars_str, ":");
std::move(standalone_systemserver_jars.begin(),
standalone_systemserver_jars.end(),
std::back_inserter(all_systemserver_jars_));
}
}
time_t OnDeviceRefresh::GetExecutionTimeUsed() const { return time(nullptr) - start_time_; }
time_t OnDeviceRefresh::GetExecutionTimeRemaining() const {
return std::max(static_cast<time_t>(0),
kMaximumExecutionSeconds - GetExecutionTimeUsed());
}
time_t OnDeviceRefresh::GetSubprocessTimeout() const {
return std::min(GetExecutionTimeRemaining(), kMaxChildProcessSeconds);
}
std::optional<std::vector<apex::ApexInfo>> OnDeviceRefresh::GetApexInfoList() const {
std::optional<apex::ApexInfoList> info_list =
apex::readApexInfoList(config_.GetApexInfoListFile().c_str());
if (!info_list.has_value()) {
return std::nullopt;
}
// We are only interested in active APEXes that contain compilable JARs.
std::unordered_set<std::string_view> relevant_apexes;
relevant_apexes.reserve(info_list->getApexInfo().size());
for (const std::vector<std::string>* jar_list :
{&all_systemserver_jars_, &boot_classpath_jars_}) {
for (const std::string& jar : *jar_list) {
std::string_view apex = ApexNameFromLocation(jar);
if (!apex.empty()) {
relevant_apexes.insert(apex);
}
}
}
// The ART APEX is always relevant no matter it contains any compilable JAR or not, because it
// contains the runtime.
relevant_apexes.insert("com.android.art");
std::vector<apex::ApexInfo> filtered_info_list;
std::copy_if(info_list->getApexInfo().begin(),
info_list->getApexInfo().end(),
std::back_inserter(filtered_info_list),
[&](const apex::ApexInfo& info) {
return info.getIsActive() && relevant_apexes.count(info.getModuleName()) != 0;
});
return filtered_info_list;
}
Result<art_apex::CacheInfo> OnDeviceRefresh::ReadCacheInfo() const {
std::optional<art_apex::CacheInfo> cache_info = art_apex::read(cache_info_filename_.c_str());
if (!cache_info.has_value()) {
if (errno != 0) {
return ErrnoErrorf("Failed to load {}", QuotePath(cache_info_filename_));
} else {
return Errorf("Failed to parse {}", QuotePath(cache_info_filename_));
}
}
return cache_info.value();
}
Result<void> OnDeviceRefresh::WriteCacheInfo() const {
if (OS::FileExists(cache_info_filename_.c_str())) {
if (unlink(cache_info_filename_.c_str()) != 0) {
return ErrnoErrorf("Failed to unlink file {}", QuotePath(cache_info_filename_));
}
}
std::string dir_name = Dirname(cache_info_filename_);
if (!EnsureDirectoryExists(dir_name)) {
return Errorf("Could not create directory {}", QuotePath(dir_name));
}
std::vector<art_apex::KeyValuePair> system_properties;
for (const auto& [key, value] : config_.GetSystemProperties()) {
if (!art::ContainsElement(kIgnoredSystemProperties, key)) {
system_properties.emplace_back(key, value);
}
}
std::optional<std::vector<apex::ApexInfo>> apex_info_list = GetApexInfoList();
if (!apex_info_list.has_value()) {
return Errorf("Could not update {}: no APEX info", QuotePath(cache_info_filename_));
}
std::optional<apex::ApexInfo> art_apex_info = GetArtApexInfo(apex_info_list.value());
if (!art_apex_info.has_value()) {
return Errorf("Could not update {}: no ART APEX info", QuotePath(cache_info_filename_));
}
art_apex::ModuleInfo art_module_info = GenerateModuleInfo(art_apex_info.value());
std::vector<art_apex::ModuleInfo> module_info_list =
GenerateModuleInfoList(apex_info_list.value());
std::vector<art_apex::Component> bcp_components = GenerateBootClasspathComponents();
std::vector<art_apex::Component> dex2oat_bcp_components =
GenerateDex2oatBootClasspathComponents();
std::vector<art_apex::SystemServerComponent> system_server_components =
GenerateSystemServerComponents();
std::ofstream out(cache_info_filename_.c_str());
if (out.fail()) {
return ErrnoErrorf("Could not create cache info file {}", QuotePath(cache_info_filename_));
}
std::unique_ptr<art_apex::CacheInfo> info(new art_apex::CacheInfo(
{art_apex::KeyValuePairList(system_properties)},
{art_module_info},
{art_apex::ModuleInfoList(module_info_list)},
{art_apex::Classpath(bcp_components)},
{art_apex::Classpath(dex2oat_bcp_components)},
{art_apex::SystemServerComponents(system_server_components)},
config_.GetCompilationOsMode() ? std::make_optional(true) : std::nullopt));
art_apex::write(out, *info);
out.close();
if (out.fail()) {
return ErrnoErrorf("Could not write cache info file {}", QuotePath(cache_info_filename_));
}
return {};
}
static void ReportNextBootAnimationProgress(uint32_t current_compilation,
uint32_t number_of_compilations) {
// We arbitrarily show progress until 90%, expecting that our compilations take a large chunk of
// boot time.
uint32_t value = (90 * current_compilation) / number_of_compilations;
SetProperty("service.bootanim.progress", std::to_string(value));
}
std::vector<art_apex::Component> OnDeviceRefresh::GenerateBootClasspathComponents() const {
return GenerateComponents(boot_classpath_jars_);
}
std::vector<art_apex::Component> OnDeviceRefresh::GenerateDex2oatBootClasspathComponents() const {
return GenerateComponents(dex2oat_boot_classpath_jars_);
}
std::vector<art_apex::SystemServerComponent> OnDeviceRefresh::GenerateSystemServerComponents()
const {
return GenerateComponents<art_apex::SystemServerComponent>(
all_systemserver_jars_,
[&](const std::string& path, uint64_t size, const std::string& checksum) {
bool isInClasspath = ContainsElement(systemserver_classpath_jars_, path);
return art_apex::SystemServerComponent{path, size, checksum, isInClasspath};
});
}
std::vector<std::string> OnDeviceRefresh::GetArtBcpJars() const {
std::string art_root = GetArtRoot() + "/";
std::vector<std::string> art_bcp_jars;
for (const std::string& jar : dex2oat_boot_classpath_jars_) {
if (StartsWith(jar, art_root)) {
art_bcp_jars.push_back(jar);
}
}
CHECK(!art_bcp_jars.empty());
return art_bcp_jars;
}
std::vector<std::string> OnDeviceRefresh::GetFrameworkBcpJars() const {
std::string art_root = GetArtRoot() + "/";
std::vector<std::string> framework_bcp_jars;
for (const std::string& jar : dex2oat_boot_classpath_jars_) {
if (!StartsWith(jar, art_root)) {
framework_bcp_jars.push_back(jar);
}
}
CHECK(!framework_bcp_jars.empty());
return framework_bcp_jars;
}
std::vector<std::string> OnDeviceRefresh::GetMainlineBcpJars() const {
// Elements in `dex2oat_boot_classpath_jars_` should be at the beginning of
// `boot_classpath_jars_`, followed by mainline BCP jars.
CHECK_LT(dex2oat_boot_classpath_jars_.size(), boot_classpath_jars_.size());
CHECK(std::equal(dex2oat_boot_classpath_jars_.begin(),
dex2oat_boot_classpath_jars_.end(),
boot_classpath_jars_.begin(),
boot_classpath_jars_.begin() + dex2oat_boot_classpath_jars_.size()));
return {boot_classpath_jars_.begin() + dex2oat_boot_classpath_jars_.size(),
boot_classpath_jars_.end()};
}
std::string OnDeviceRefresh::GetPrimaryBootImage(bool on_system, bool minimal) const {
DCHECK(!on_system || !minimal);
const char* basename = minimal ? kMinimalBootImageBasename : kFirstBootImageBasename;
if (on_system) {
// Typically "/system/framework/boot.art".
return GetPrebuiltPrimaryBootImageDir() + "/" + basename;
} else {
// Typically "/data/misc/apexdata/com.android.art/dalvik-cache/boot.art".
return config_.GetArtifactDirectory() + "/" + basename;
}
}
std::string OnDeviceRefresh::GetPrimaryBootImagePath(bool on_system,
bool minimal,
InstructionSet isa) const {
// Typically "/data/misc/apexdata/com.android.art/dalvik-cache/<isa>/boot.art".
return GetSystemImageFilename(GetPrimaryBootImage(on_system, minimal).c_str(), isa);
}
std::string OnDeviceRefresh::GetSystemBootImageFrameworkExtension() const {
std::vector<std::string> framework_bcp_jars = GetFrameworkBcpJars();
std::string basename =
GetBootImageComponentBasename(framework_bcp_jars[0], /*is_first_jar=*/false);
// Typically "/system/framework/boot-framework.art".
return ART_FORMAT("{}/framework/{}", GetAndroidRoot(), basename);
}
std::string OnDeviceRefresh::GetSystemBootImageFrameworkExtensionPath(InstructionSet isa) const {
// Typically "/system/framework/<isa>/boot-framework.art".
return GetSystemImageFilename(GetSystemBootImageFrameworkExtension().c_str(), isa);
}
std::string OnDeviceRefresh::GetBootImageMainlineExtension(bool on_system) const {
std::vector<std::string> mainline_bcp_jars = GetMainlineBcpJars();
std::string basename =
GetBootImageComponentBasename(mainline_bcp_jars[0], /*is_first_jar=*/false);
if (on_system) {
// Typically "/system/framework/boot-framework-adservices.art".
return ART_FORMAT("{}/framework/{}", GetAndroidRoot(), basename);
} else {
// Typically "/data/misc/apexdata/com.android.art/dalvik-cache/boot-framework-adservices.art".
return ART_FORMAT("{}/{}", config_.GetArtifactDirectory(), basename);
}
}
std::string OnDeviceRefresh::GetBootImageMainlineExtensionPath(bool on_system,
InstructionSet isa) const {
// Typically
// "/data/misc/apexdata/com.android.art/dalvik-cache/<isa>/boot-framework-adservices.art".
return GetSystemImageFilename(GetBootImageMainlineExtension(on_system).c_str(), isa);
}
std::vector<std::string> OnDeviceRefresh::GetBestBootImages(InstructionSet isa,
bool include_mainline_extension) const {
std::vector<std::string> locations;
std::string unused_error_msg;
bool primary_on_data = false;
if (PrimaryBootImageExist(
/*on_system=*/false, /*minimal=*/false, isa, &unused_error_msg)) {
primary_on_data = true;
locations.push_back(GetPrimaryBootImage(/*on_system=*/false, /*minimal=*/false));
} else {
locations.push_back(GetPrimaryBootImage(/*on_system=*/true, /*minimal=*/false));
if (!IsAtLeastU()) {
// Prior to U, there was a framework extension.
locations.push_back(GetSystemBootImageFrameworkExtension());
}
}
if (include_mainline_extension) {
if (BootImageMainlineExtensionExist(/*on_system=*/false, isa, &unused_error_msg)) {
locations.push_back(GetBootImageMainlineExtension(/*on_system=*/false));
} else {
// If the primary boot image is on /data, it means we have regenerated all boot images, so the
// mainline extension must be on /data too.
CHECK(!primary_on_data)
<< "Mainline extension not found while primary boot image is on /data";
locations.push_back(GetBootImageMainlineExtension(/*on_system=*/true));
}
}
return locations;
}
std::string OnDeviceRefresh::GetSystemServerImagePath(bool on_system,
const std::string& jar_path) const {
if (on_system) {
if (LocationIsOnApex(jar_path)) {
return GetSystemOdexFilenameForApex(jar_path, config_.GetSystemServerIsa());
}
std::string jar_name = Basename(jar_path);
std::string image_name = ReplaceFileExtension(jar_name, "art");
const char* isa_str = GetInstructionSetString(config_.GetSystemServerIsa());
// Typically "/system/framework/oat/<isa>/services.art".
return ART_FORMAT("{}/oat/{}/{}", Dirname(jar_path), isa_str, image_name);
} else {
// Typically
// "/data/misc/apexdata/.../dalvik-cache/<isa>/system@framework@services.jar@classes.art".
const std::string image = GetApexDataImage(jar_path);
return GetSystemImageFilename(image.c_str(), config_.GetSystemServerIsa());
}
}
WARN_UNUSED bool OnDeviceRefresh::RemoveArtifactsDirectory() const {
if (config_.GetDryRun()) {
LOG(INFO) << "Directory " << QuotePath(config_.GetArtifactDirectory())
<< " and contents would be removed (dry-run).";
return true;
}
return RemoveDirectory(config_.GetArtifactDirectory());
}
WARN_UNUSED bool OnDeviceRefresh::PrimaryBootImageExist(
bool on_system,
bool minimal,
InstructionSet isa,
/*out*/ std::string* error_msg,
/*out*/ std::vector<std::string>* checked_artifacts) const {
std::string path = GetPrimaryBootImagePath(on_system, minimal, isa);
OdrArtifacts artifacts = OdrArtifacts::ForBootImage(path);
if (!ArtifactsExist(artifacts, /*check_art_file=*/true, error_msg, checked_artifacts)) {
return false;
}
// Prior to U, there was a split between the primary boot image and the extension on /system, so
// they need to be checked separately. This does not apply to the boot image on /data.
if (on_system && !IsAtLeastU()) {
std::string extension_path = GetSystemBootImageFrameworkExtensionPath(isa);
OdrArtifacts extension_artifacts = OdrArtifacts::ForBootImage(extension_path);
if (!ArtifactsExist(
extension_artifacts, /*check_art_file=*/true, error_msg, checked_artifacts)) {
return false;
}
}
return true;
}
WARN_UNUSED bool OnDeviceRefresh::BootImageMainlineExtensionExist(
bool on_system,
InstructionSet isa,
/*out*/ std::string* error_msg,
/*out*/ std::vector<std::string>* checked_artifacts) const {
std::string path = GetBootImageMainlineExtensionPath(on_system, isa);
OdrArtifacts artifacts = OdrArtifacts::ForBootImage(path);
return ArtifactsExist(artifacts, /*check_art_file=*/true, error_msg, checked_artifacts);
}
bool OnDeviceRefresh::SystemServerArtifactsExist(
bool on_system,
/*out*/ std::string* error_msg,
/*out*/ std::set<std::string>* jars_missing_artifacts,
/*out*/ std::vector<std::string>* checked_artifacts) const {
for (const std::string& jar_path : all_systemserver_jars_) {
const std::string image_location = GetSystemServerImagePath(on_system, jar_path);
const OdrArtifacts artifacts = OdrArtifacts::ForSystemServer(image_location);
// .art files are optional and are not generated for all jars by the build system.
const bool check_art_file = !on_system;
std::string error_msg_tmp;
if (!ArtifactsExist(artifacts, check_art_file, &error_msg_tmp, checked_artifacts)) {
jars_missing_artifacts->insert(jar_path);
*error_msg = error_msg->empty() ? error_msg_tmp : *error_msg + "\n" + error_msg_tmp;
}
}
return jars_missing_artifacts->empty();
}
WARN_UNUSED bool OnDeviceRefresh::CheckSystemPropertiesAreDefault() const {
// We don't have to check properties that match `kCheckedSystemPropertyPrefixes` here because none
// of them is persistent. This only applies when `cache-info.xml` does not exist. When
// `cache-info.xml` exists, we call `CheckSystemPropertiesHaveNotChanged` instead.
DCHECK(std::none_of(std::begin(kCheckedSystemPropertyPrefixes),
std::end(kCheckedSystemPropertyPrefixes),
[](const char* prefix) { return StartsWith(prefix, "persist."); }));
const OdrSystemProperties& system_properties = config_.GetSystemProperties();
for (const SystemPropertyConfig& system_property_config : *kSystemProperties.get()) {
std::string property = system_properties.GetOrEmpty(system_property_config.name);
DCHECK_NE(property, "");
if (property != system_property_config.default_value) {
LOG(INFO) << "System property " << system_property_config.name << " has a non-default value ("
<< property << ").";
return false;
}
}
return true;
}
WARN_UNUSED bool OnDeviceRefresh::CheckSystemPropertiesHaveNotChanged(
const art_apex::CacheInfo& cache_info) const {
std::unordered_map<std::string, std::string> cached_system_properties;
std::unordered_set<std::string> checked_properties;
const art_apex::KeyValuePairList* list = cache_info.getFirstSystemProperties();
if (list == nullptr) {
// This should never happen. We have already checked the ART module version, and the cache
// info is generated by the latest version of the ART module if it exists.
LOG(ERROR) << "Missing system properties from cache-info.";
return false;
}
for (const art_apex::KeyValuePair& pair : list->getItem()) {
cached_system_properties[pair.getK()] = pair.getV();
checked_properties.insert(pair.getK());
}
const OdrSystemProperties& system_properties = config_.GetSystemProperties();
for (const auto& [key, value] : system_properties) {
if (!art::ContainsElement(kIgnoredSystemProperties, key)) {
checked_properties.insert(key);
}
}
for (const std::string& name : checked_properties) {
std::string property = system_properties.GetOrEmpty(name);
std::string cached_property = cached_system_properties[name];
if (property != cached_property) {
LOG(INFO) << "System property " << name << " value changed (before: \"" << cached_property
<< "\", now: \"" << property << "\").";
return false;
}
}
return true;
}
WARN_UNUSED bool OnDeviceRefresh::CheckBuildUserfaultFdGc() const {
bool build_enable_uffd_gc =
config_.GetSystemProperties().GetBool("ro.dalvik.vm.enable_uffd_gc", /*default_value=*/false);
bool is_at_most_u = !IsAtLeastV();
bool kernel_supports_uffd = KernelSupportsUffd();
if (!art::odrefresh::CheckBuildUserfaultFdGc(
build_enable_uffd_gc, is_at_most_u, kernel_supports_uffd)) {
// Normally, this should not happen. If this happens, the system image was probably built with a
// wrong PRODUCT_ENABLE_UFFD_GC flag.
LOG(WARNING) << ART_FORMAT(
"Userfaultfd GC check failed (build_enable_uffd_gc: {}, is_at_most_u: {}, "
"kernel_supports_uffd: {}).",
build_enable_uffd_gc,
is_at_most_u,
kernel_supports_uffd);
return false;
}
return true;
}
WARN_UNUSED PreconditionCheckResult OnDeviceRefresh::CheckPreconditionForSystem(
const std::vector<apex::ApexInfo>& apex_info_list) const {
if (!CheckSystemPropertiesAreDefault()) {
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kApexVersionMismatch);
}
if (!CheckBuildUserfaultFdGc()) {
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kApexVersionMismatch);
}
std::optional<apex::ApexInfo> art_apex_info = GetArtApexInfo(apex_info_list);
if (!art_apex_info.has_value()) {
// This should never happen, further up-to-date checks are not possible if it does.
LOG(ERROR) << "Could not get ART APEX info.";
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kUnknown);
}
if (!art_apex_info->getIsFactory()) {
LOG(INFO) << "Updated ART APEX mounted";
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kApexVersionMismatch);
}
if (std::any_of(apex_info_list.begin(),
apex_info_list.end(),
[](const apex::ApexInfo& apex_info) { return !apex_info.getIsFactory(); })) {
LOG(INFO) << "Updated APEXes mounted";
return PreconditionCheckResult::BootImageMainlineExtensionNotOk(
OdrMetrics::Trigger::kApexVersionMismatch);
}
return PreconditionCheckResult::AllOk();
}
WARN_UNUSED static bool CheckModuleInfo(const art_apex::ModuleInfo& cached_info,
const apex::ApexInfo& current_info) {
if (cached_info.getVersionCode() != current_info.getVersionCode()) {
LOG(INFO) << ART_FORMAT("APEX ({}) version code mismatch (before: {}, now: {})",
current_info.getModuleName(),
cached_info.getVersionCode(),
current_info.getVersionCode());
return false;
}
if (cached_info.getVersionName() != current_info.getVersionName()) {
LOG(INFO) << ART_FORMAT("APEX ({}) version name mismatch (before: {}, now: {})",
current_info.getModuleName(),
cached_info.getVersionName(),
current_info.getVersionName());
return false;
}
// Check lastUpdateMillis for samegrade installs. If `cached_info` is missing the lastUpdateMillis
// field then it is not current with the schema used by this binary so treat it as a samegrade
// update. Otherwise check whether the lastUpdateMillis changed.
const int64_t cached_last_update_millis =
cached_info.hasLastUpdateMillis() ? cached_info.getLastUpdateMillis() : -1;
if (cached_last_update_millis != current_info.getLastUpdateMillis()) {
LOG(INFO) << ART_FORMAT("APEX ({}) last update time mismatch (before: {}, now: {})",
current_info.getModuleName(),
cached_info.getLastUpdateMillis(),
current_info.getLastUpdateMillis());
return false;
}
return true;
}
WARN_UNUSED PreconditionCheckResult OnDeviceRefresh::CheckPreconditionForData(
const std::vector<com::android::apex::ApexInfo>& apex_info_list) const {
Result<art_apex::CacheInfo> cache_info = ReadCacheInfo();
if (!cache_info.ok()) {
if (cache_info.error().code() == ENOENT) {
// If the cache info file does not exist, it usually means it's the first boot, or the
// dalvik-cache directory is cleared by odsign due to corrupted files. Set the trigger to be
// `kApexVersionMismatch` to force generate the cache info file and compile if necessary.
LOG(INFO) << "No prior cache-info file: " << QuotePath(cache_info_filename_);
} else {
// This should not happen unless odrefresh is updated to a new version that is not compatible
// with an old cache-info file. Further up-to-date checks are not possible if it does.
LOG(ERROR) << cache_info.error().message();
}
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kApexVersionMismatch);
}
if (!CheckSystemPropertiesHaveNotChanged(cache_info.value())) {
// We don't have a trigger kind for system property changes. For now, we reuse
// `kApexVersionMismatch` as it implies the expected behavior: re-compile regardless of the last
// compilation attempt.
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kApexVersionMismatch);
}
// Check whether the current cache ART module info differs from the current ART module info.
const art_apex::ModuleInfo* cached_art_info = cache_info->getFirstArtModuleInfo();
if (cached_art_info == nullptr) {
LOG(ERROR) << "Missing ART APEX info from cache-info.";
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kApexVersionMismatch);
}
std::optional<apex::ApexInfo> current_art_info = GetArtApexInfo(apex_info_list);
if (!current_art_info.has_value()) {
// This should never happen, further up-to-date checks are not possible if it does.
LOG(ERROR) << "Could not get ART APEX info.";
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kUnknown);
}
if (!CheckModuleInfo(*cached_art_info, *current_art_info)) {
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kApexVersionMismatch);
}
// Check boot class components.
//
// This checks the size and checksums of odrefresh compilable files on the DEX2OATBOOTCLASSPATH
// (the Odrefresh constructor determines which files are compilable). If the number of files
// there changes, or their size or checksums change then compilation will be triggered.
//
// The boot class components may change unexpectedly, for example an OTA could update
// framework.jar.
const std::vector<art_apex::Component> current_dex2oat_bcp_components =
GenerateDex2oatBootClasspathComponents();
const art_apex::Classpath* cached_dex2oat_bcp_components =
cache_info->getFirstDex2oatBootClasspath();
if (cached_dex2oat_bcp_components == nullptr) {
LOG(INFO) << "Missing Dex2oatBootClasspath components.";
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kApexVersionMismatch);
}
Result<void> result = CheckComponents(current_dex2oat_bcp_components,
cached_dex2oat_bcp_components->getComponent());
if (!result.ok()) {
LOG(INFO) << "Dex2OatClasspath components mismatch: " << result.error();
return PreconditionCheckResult::NoneOk(OdrMetrics::Trigger::kDexFilesChanged);
}
// Check whether the current cached module info differs from the current module info.
const art_apex::ModuleInfoList* cached_module_info_list = cache_info->getFirstModuleInfoList();
if (cached_module_info_list == nullptr) {
LOG(ERROR) << "Missing APEX info list from cache-info.";
return PreconditionCheckResult::BootImageMainlineExtensionNotOk(
OdrMetrics::Trigger::kApexVersionMismatch);
}
std::unordered_map<std::string, const art_apex::ModuleInfo*> cached_module_info_map;
for (const art_apex::ModuleInfo& module_info : cached_module_info_list->getModuleInfo()) {
cached_module_info_map[module_info.getName()] = &module_info;
}
// Note that apex_info_list may omit APEXes that are included in cached_module_info - e.g. if an
// apex used to be compilable, but now isn't. That won't be detected by this loop, but will be
// detected below in CheckComponents.
for (const apex::ApexInfo& current_apex_info : apex_info_list) {
auto& apex_name = current_apex_info.getModuleName();
auto it = cached_module_info_map.find(apex_name);
if (it == cached_module_info_map.end()) {
LOG(INFO) << "Missing APEX info from cache-info (" << apex_name << ").";
return PreconditionCheckResult::BootImageMainlineExtensionNotOk(
OdrMetrics::Trigger::kApexVersionMismatch);
}
const art_apex::ModuleInfo* cached_module_info = it->second;
if (!CheckModuleInfo(*cached_module_info, current_apex_info)) {
return PreconditionCheckResult::BootImageMainlineExtensionNotOk(
OdrMetrics::Trigger::kApexVersionMismatch);
}
}
const std::vector<art_apex::Component> current_bcp_components = GenerateBootClasspathComponents();
const art_apex::Classpath* cached_bcp_components = cache_info->getFirstBootClasspath();
if (cached_bcp_components == nullptr) {
LOG(INFO) << "Missing BootClasspath components.";
return PreconditionCheckResult::BootImageMainlineExtensionNotOk(
OdrMetrics::Trigger::kApexVersionMismatch);
}
result = CheckComponents(current_bcp_components, cached_bcp_components->getComponent());
if (!result.ok()) {
LOG(INFO) << "BootClasspath components mismatch: " << result.error();
// Boot classpath components can be dependencies of system_server components, so system_server
// components need to be recompiled if boot classpath components are changed.
return PreconditionCheckResult::BootImageMainlineExtensionNotOk(
OdrMetrics::Trigger::kDexFilesChanged);
}
// Check system server components.
//
// This checks the size and checksums of odrefresh compilable files on the
// SYSTEMSERVERCLASSPATH (the Odrefresh constructor determines which files are compilable). If
// the number of files there changes, or their size or checksums change then compilation will be
// triggered.
//
// The system_server components may change unexpectedly, for example an OTA could update
// services.jar.
const std::vector<art_apex::SystemServerComponent> current_system_server_components =
GenerateSystemServerComponents();
const art_apex::SystemServerComponents* cached_system_server_components =
cache_info->getFirstSystemServerComponents();
if (cached_system_server_components == nullptr) {
LOG(INFO) << "Missing SystemServerComponents.";
return PreconditionCheckResult::SystemServerNotOk(OdrMetrics::Trigger::kApexVersionMismatch);
}
result = CheckSystemServerComponents(current_system_server_components,
cached_system_server_components->getComponent());
if (!result.ok()) {
LOG(INFO) << "SystemServerComponents mismatch: " << result.error();
return PreconditionCheckResult::SystemServerNotOk(OdrMetrics::Trigger::kDexFilesChanged);
}
return PreconditionCheckResult::AllOk();
}
WARN_UNUSED BootImages OnDeviceRefresh::CheckBootClasspathArtifactsAreUpToDate(
OdrMetrics& metrics,
InstructionSet isa,
const PreconditionCheckResult& system_result,
const PreconditionCheckResult& data_result,
/*out*/ std::vector<std::string>* checked_artifacts) const {
const char* isa_str = GetInstructionSetString(isa);
BootImages boot_images_on_system{.primary_boot_image = false,
.boot_image_mainline_extension = false};
if (system_result.IsPrimaryBootImageOk()) {
// We can use the artifacts on /system. Check if they exist.
std::string error_msg;
if (PrimaryBootImageExist(/*on_system=*/true, /*minimal=*/false, isa, &error_msg)) {
boot_images_on_system.primary_boot_image = true;
} else {
LOG(INFO) << "Incomplete primary boot image or framework extension on /system: " << error_msg;
}
}
if (boot_images_on_system.primary_boot_image && system_result.IsBootImageMainlineExtensionOk()) {
std::string error_msg;
if (BootImageMainlineExtensionExist(/*on_system=*/true, isa, &error_msg)) {
boot_images_on_system.boot_image_mainline_extension = true;
} else {
LOG(INFO) << "Incomplete boot image mainline extension on /system: " << error_msg;
}
}
if (boot_images_on_system.Count() == BootImages::kMaxCount) {
LOG(INFO) << ART_FORMAT("Boot images on /system OK ({})", isa_str);
// Nothing to compile.
return BootImages{.primary_boot_image = false, .boot_image_mainline_extension = false};
}
LOG(INFO) << ART_FORMAT("Checking boot images /data ({})", isa_str);
BootImages boot_images_on_data{.primary_boot_image = false,
.boot_image_mainline_extension = false};
if (data_result.IsPrimaryBootImageOk()) {
std::string error_msg;
if (PrimaryBootImageExist(
/*on_system=*/false, /*minimal=*/false, isa, &error_msg, checked_artifacts)) {
boot_images_on_data.primary_boot_image = true;
} else {
LOG(INFO) << "Incomplete primary boot image on /data: " << error_msg;
metrics.SetTrigger(OdrMetrics::Trigger::kMissingArtifacts);
// Add the minimal boot image to `checked_artifacts` if exists. This is to prevent the minimal
// boot image from being deleted. It does not affect the return value because we should still
// attempt to generate a full boot image even if the minimal one exists.
if (PrimaryBootImageExist(
/*on_system=*/false, /*minimal=*/true, isa, &error_msg, checked_artifacts)) {
LOG(INFO) << ART_FORMAT("Found minimal primary boot image ({})", isa_str);
}
}
} else {
metrics.SetTrigger(data_result.GetTrigger());
}
if (boot_images_on_system.primary_boot_image || boot_images_on_data.primary_boot_image) {
if (data_result.IsBootImageMainlineExtensionOk()) {
std::string error_msg;
if (BootImageMainlineExtensionExist(
/*on_system=*/false, isa, &error_msg, checked_artifacts)) {
boot_images_on_data.boot_image_mainline_extension = true;
} else {
LOG(INFO) << "Incomplete boot image mainline extension on /data: " << error_msg;
metrics.SetTrigger(OdrMetrics::Trigger::kMissingArtifacts);
}
} else {
metrics.SetTrigger(data_result.GetTrigger());
}
}
BootImages boot_images_to_generate{
.primary_boot_image =
!boot_images_on_system.primary_boot_image && !boot_images_on_data.primary_boot_image,
.boot_image_mainline_extension = !boot_images_on_system.boot_image_mainline_extension &&
!boot_images_on_data.boot_image_mainline_extension,
};
if (boot_images_to_generate.Count() == 0) {
LOG(INFO) << ART_FORMAT("Boot images on /data OK ({})", isa_str);
}
return boot_images_to_generate;
}
std::set<std::string> OnDeviceRefresh::CheckSystemServerArtifactsAreUpToDate(
OdrMetrics& metrics,
const PreconditionCheckResult& system_result,
const PreconditionCheckResult& data_result,
/*out*/ std::vector<std::string>* checked_artifacts) const {
std::set<std::string> jars_to_compile;
std::set<std::string> jars_missing_artifacts_on_system;
if (system_result.IsSystemServerOk()) {
// We can use the artifacts on /system. Check if they exist.
std::string error_msg;
if (SystemServerArtifactsExist(
/*on_system=*/true, &error_msg, &jars_missing_artifacts_on_system)) {
LOG(INFO) << "system_server artifacts on /system OK";
return {};
}
LOG(INFO) << "Incomplete system server artifacts on /system: " << error_msg;
LOG(INFO) << "Checking system server artifacts /data";
} else {
jars_missing_artifacts_on_system = AllSystemServerJars();
}
std::set<std::string> jars_missing_artifacts_on_data;
std::string error_msg;
if (data_result.IsSystemServerOk()) {
SystemServerArtifactsExist(
/*on_system=*/false, &error_msg, &jars_missing_artifacts_on_data, checked_artifacts);
} else {
jars_missing_artifacts_on_data = AllSystemServerJars();
}
std::set_intersection(jars_missing_artifacts_on_system.begin(),
jars_missing_artifacts_on_system.end(),
jars_missing_artifacts_on_data.begin(),
jars_missing_artifacts_on_data.end(),
std::inserter(jars_to_compile, jars_to_compile.end()));
if (!jars_to_compile.empty()) {
if (data_result.IsSystemServerOk()) {
LOG(INFO) << "Incomplete system_server artifacts on /data: " << error_msg;
metrics.SetTrigger(OdrMetrics::Trigger::kMissingArtifacts);
} else {
metrics.SetTrigger(data_result.GetTrigger());
}
return jars_to_compile;
}
LOG(INFO) << "system_server artifacts on /data OK";
return {};
}
Result<void> OnDeviceRefresh::CleanupArtifactDirectory(
OdrMetrics& metrics, const std::vector<std::string>& artifacts_to_keep) const {
const std::string& artifact_dir = config_.GetArtifactDirectory();
std::unordered_set<std::string> artifact_set{artifacts_to_keep.begin(), artifacts_to_keep.end()};
// When anything unexpected happens, remove all artifacts.
auto remove_artifact_dir = android::base::make_scope_guard([&]() {
if (!RemoveDirectory(artifact_dir)) {
LOG(ERROR) << "Failed to remove the artifact directory";
}
});
std::vector<std::filesystem::directory_entry> entries;
std::error_code ec;
for (const auto& entry : std::filesystem::recursive_directory_iterator(artifact_dir, ec)) {
// Save the entries and use them later because modifications during the iteration will result in
// undefined behavior;
entries.push_back(entry);
}
if (ec && ec.value() != ENOENT) {
metrics.SetStatus(ec.value() == EPERM ? OdrMetrics::Status::kDalvikCachePermissionDenied :
OdrMetrics::Status::kIoError);
return Errorf("Failed to iterate over entries in the artifact directory: {}", ec.message());
}
for (const std::filesystem::directory_entry& entry : entries) {
std::string path = entry.path().string();
if (entry.is_regular_file()) {
if (!ContainsElement(artifact_set, path)) {
LOG(INFO) << "Removing " << path;
if (unlink(path.c_str()) != 0) {
metrics.SetStatus(OdrMetrics::Status::kIoError);
return ErrnoErrorf("Failed to remove file {}", QuotePath(path));
}
}
} else if (!entry.is_directory()) {
// Neither a regular file nor a directory. Unexpected file type.
LOG(INFO) << "Removing " << path;
if (unlink(path.c_str()) != 0) {
metrics.SetStatus(OdrMetrics::Status::kIoError);
return ErrnoErrorf("Failed to remove file {}", QuotePath(path));
}
}
}
remove_artifact_dir.Disable();
return {};
}
Result<void> OnDeviceRefresh::RefreshExistingArtifacts() const {
const std::string& artifact_dir = config_.GetArtifactDirectory();
if (!OS::DirectoryExists(artifact_dir.c_str())) {
return {};
}
std::vector<std::filesystem::directory_entry> entries;
std::error_code ec;
for (const auto& entry : std::filesystem::recursive_directory_iterator(artifact_dir, ec)) {
// Save the entries and use them later because modifications during the iteration will result in
// undefined behavior;
entries.push_back(entry);
}
if (ec) {
return Errorf("Failed to iterate over entries in the artifact directory: {}", ec.message());
}
for (const std::filesystem::directory_entry& entry : entries) {
std::string path = entry.path().string();
if (entry.is_regular_file()) {
// Unexpected files are already removed by `CleanupArtifactDirectory`. We can safely assume
// that all the remaining files are good.
LOG(INFO) << "Refreshing " << path;
std::string content;
if (!android::base::ReadFileToString(path, &content)) {
return Errorf("Failed to read file {}", QuotePath(path));
}
if (unlink(path.c_str()) != 0) {
return ErrnoErrorf("Failed to remove file {}", QuotePath(path));
}
if (!android::base::WriteStringToFile(content, path)) {
return Errorf("Failed to write file {}", QuotePath(path));
}
if (chmod(path.c_str(), kFileMode) != 0) {
return ErrnoErrorf("Failed to chmod file {}", QuotePath(path));
}
}
}
return {};
}
WARN_UNUSED ExitCode
OnDeviceRefresh::CheckArtifactsAreUpToDate(OdrMetrics& metrics,
/*out*/ CompilationOptions* compilation_options) const {
metrics.SetStage(OdrMetrics::Stage::kCheck);
// Clean-up helper used to simplify clean-ups and handling failures there.
auto cleanup_and_compile_all = [&, this]() {
*compilation_options = CompilationOptions::CompileAll(*this);
if (!RemoveArtifactsDirectory()) {
metrics.SetStatus(OdrMetrics::Status::kIoError);
return ExitCode::kCleanupFailed;
}
return ExitCode::kCompilationRequired;
};
std::optional<std::vector<apex::ApexInfo>> apex_info_list = GetApexInfoList();
if (!apex_info_list.has_value()) {
// This should never happen, further up-to-date checks are not possible if it does.
LOG(ERROR) << "Could not get APEX info.";
metrics.SetTrigger(OdrMetrics::Trigger::kUnknown);
return cleanup_and_compile_all();
}
std::optional<apex::ApexInfo> art_apex_info = GetArtApexInfo(apex_info_list.value());
if (!art_apex_info.has_value()) {
// This should never happen, further up-to-date checks are not possible if it does.
LOG(ERROR) << "Could not get ART APEX info.";
metrics.SetTrigger(OdrMetrics::Trigger::kUnknown);
return cleanup_and_compile_all();
}
// Record ART APEX version for metrics reporting.
metrics.SetArtApexVersion(art_apex_info->getVersionCode());
// Log the version so there's a starting point for any issues reported (b/197489543).
LOG(INFO) << "ART APEX version " << art_apex_info->getVersionCode();
// Record ART APEX last update milliseconds (used in compilation log).
metrics.SetArtApexLastUpdateMillis(art_apex_info->getLastUpdateMillis());
InstructionSet system_server_isa = config_.GetSystemServerIsa();
std::vector<std::string> checked_artifacts;
PreconditionCheckResult system_result = CheckPreconditionForSystem(apex_info_list.value());
PreconditionCheckResult data_result = CheckPreconditionForData(apex_info_list.value());
for (InstructionSet isa : config_.GetBootClasspathIsas()) {
BootImages boot_images_to_generate = CheckBootClasspathArtifactsAreUpToDate(
metrics, isa, system_result, data_result, &checked_artifacts);
if (boot_images_to_generate.Count() > 0) {
compilation_options->boot_images_to_generate_for_isas.emplace_back(isa,
boot_images_to_generate);
// system_server artifacts are invalid without valid boot classpath artifacts.
if (isa == system_server_isa) {
compilation_options->system_server_jars_to_compile = AllSystemServerJars();
}
}
}
if (compilation_options->system_server_jars_to_compile.empty()) {
compilation_options->system_server_jars_to_compile = CheckSystemServerArtifactsAreUpToDate(
metrics, system_result, data_result, &checked_artifacts);
}
bool compilation_required = compilation_options->CompilationUnitCount() > 0;
if (!compilation_required && !data_result.IsAllOk()) {
// Return kCompilationRequired to generate the cache info even if there's nothing to compile.
compilation_required = true;
metrics.SetTrigger(data_result.GetTrigger());
}
// Always keep the cache info.
checked_artifacts.push_back(cache_info_filename_);
Result<void> result = CleanupArtifactDirectory(metrics, checked_artifacts);
if (!result.ok()) {
LOG(ERROR) << result.error();
return ExitCode::kCleanupFailed;
}
return compilation_required ? ExitCode::kCompilationRequired : ExitCode::kOkay;
}
WARN_UNUSED CompilationResult OnDeviceRefresh::RunDex2oat(
const std::string& staging_dir,
const std::string& debug_message,
InstructionSet isa,
const std::vector<std::string>& dex_files,
const std::vector<std::string>& boot_classpath,
const std::vector<std::string>& input_boot_images,
const OdrArtifacts& artifacts,
CmdlineBuilder&& extra_args,
/*inout*/ std::vector<std::unique_ptr<File>>& readonly_files_raii) const {
CmdlineBuilder args;
args.Add(config_.GetDex2Oat());
AddDex2OatCommonOptions(args);
AddDex2OatDebugInfo(args);
AddDex2OatInstructionSet(args, isa, config_.GetSystemProperties());
Result<void> result = AddDex2OatConcurrencyArguments(
args, config_.GetCompilationOsMode(), config_.GetSystemProperties());
if (!result.ok()) {
return CompilationResult::Error(OdrMetrics::Status::kUnknown, result.error().message());
}
// dex2oat reads some system properties from cache-info.xml generated by odrefresh.
result = AddCacheInfoFd(args, readonly_files_raii, cache_info_filename_);
if (!result.ok()) {
return CompilationResult::Error(OdrMetrics::Status::kUnknown, result.error().message());
}
for (const std::string& dex_file : dex_files) {
std::string actual_path = RewriteParentDirectoryIfNeeded(dex_file);
args.Add("--dex-file=%s", dex_file);
std::unique_ptr<File> file(OS::OpenFileForReading(actual_path.c_str()));
if (file == nullptr) {
return CompilationResult::Error(
OdrMetrics::Status::kIoError,
ART_FORMAT("Failed to open dex file '{}': {}", actual_path, strerror(errno)));
}
args.Add("--dex-fd=%d", file->Fd());
readonly_files_raii.push_back(std::move(file));
}
args.AddRuntime("-Xbootclasspath:%s", Join(boot_classpath, ":"));
result = AddBootClasspathFds(args, readonly_files_raii, boot_classpath);
if (!result.ok()) {
return CompilationResult::Error(OdrMetrics::Status::kIoError, result.error().message());
}
if (!input_boot_images.empty()) {
args.Add("--boot-image=%s", Join(input_boot_images, ':'));
result = AddCompiledBootClasspathFdsIfAny(
args, readonly_files_raii, boot_classpath, isa, input_boot_images);
if (!result.ok()) {
return CompilationResult::Error(OdrMetrics::Status::kIoError, result.error().message());
}
}
args.Add("--oat-location=%s", artifacts.OatPath());
std::pair<std::string, const char*> location_kind_pairs[] = {
std::make_pair(artifacts.ImagePath(), artifacts.ImageKind()),
std::make_pair(artifacts.OatPath(), "oat"),
std::make_pair(artifacts.VdexPath(), "output-vdex")};
std::vector<std::unique_ptr<File>> staging_files;
for (const auto& [location, kind] : location_kind_pairs) {
std::string staging_location = GetStagingLocation(staging_dir, location);
std::unique_ptr<File> staging_file(OS::CreateEmptyFile(staging_location.c_str()));
if (staging_file == nullptr) {
return CompilationResult::Error(
OdrMetrics::Status::kIoError,
ART_FORMAT("Failed to create {} file '{}': {}", kind, staging_location, strerror(errno)));
}
// Don't check the state of the staging file. It doesn't need to be flushed because it's removed
// after the compilation regardless of success or failure.
staging_file->MarkUnchecked();
args.Add(StringPrintf("--%s-fd=%d", kind, staging_file->Fd()));
staging_files.emplace_back(std::move(staging_file));
}
std::string install_location = Dirname(artifacts.OatPath());
if (!EnsureDirectoryExists(install_location)) {
return CompilationResult::Error(
OdrMetrics::Status::kIoError,
ART_FORMAT("Error encountered when preparing directory '{}'", install_location));
}
args.Concat(std::move(extra_args));
Timer timer;
time_t timeout = GetSubprocessTimeout();
std::string cmd_line = Join(args.Get(), ' ');
LOG(INFO) << ART_FORMAT("{}: {} [timeout {}s]", debug_message, cmd_line, timeout);
if (config_.GetDryRun()) {
LOG(INFO) << "Compilation skipped (dry-run).";
return CompilationResult::Ok();
}
std::string error_msg;
ExecResult dex2oat_result = exec_utils_->ExecAndReturnResult(args.Get(), timeout, &error_msg);
if (dex2oat_result.exit_code != 0) {
return CompilationResult::Dex2oatError(
dex2oat_result.exit_code < 0 ?
error_msg :
ART_FORMAT("dex2oat returned an unexpected code: {}", dex2oat_result.exit_code),
timer.duration().count(),
dex2oat_result);
}
if (!MoveOrEraseFiles(staging_files, install_location)) {
return CompilationResult::Error(
OdrMetrics::Status::kIoError,
ART_FORMAT("Failed to commit artifacts to '{}'", install_location));
}
return CompilationResult::Dex2oatOk(timer.duration().count(), dex2oat_result);
}
WARN_UNUSED CompilationResult
OnDeviceRefresh::RunDex2oatForBootClasspath(const std::string& staging_dir,
const std::string& debug_name,
InstructionSet isa,
const std::vector<std::string>& dex_files,
const std::vector<std::string>& boot_classpath,
const std::vector<std::string>& input_boot_images,
const std::string& output_path) const {
CmdlineBuilder args;
std::vector<std::unique_ptr<File>> readonly_files_raii;
// Compile as a single image for fewer files and slightly less memory overhead.
args.Add("--single-image");
if (input_boot_images.empty()) {
// Primary boot image.
std::string art_boot_profile_file = GetArtRoot() + "/etc/boot-image.prof";
std::string framework_boot_profile_file = GetAndroidRoot() + "/etc/boot-image.prof";
Result<bool> has_any_profile = AddDex2OatProfile(
args, readonly_files_raii, {art_boot_profile_file, framework_boot_profile_file});
if (!has_any_profile.ok()) {
return CompilationResult::Error(OdrMetrics::Status::kIoError,
has_any_profile.error().message());
}
if (!*has_any_profile) {
return CompilationResult::Error(OdrMetrics::Status::kIoError, "Missing boot image profile");
}
const std::string& compiler_filter = config_.GetBootImageCompilerFilter();
if (!compiler_filter.empty()) {
args.Add("--compiler-filter=%s", compiler_filter);
} else {
args.Add("--compiler-filter=%s", kPrimaryCompilerFilter);
}
args.Add(StringPrintf("--base=0x%08x", ART_BASE_ADDRESS));
std::string dirty_image_objects_file(GetAndroidRoot() + "/etc/dirty-image-objects");
std::unique_ptr<File> file(OS::OpenFileForReading(dirty_image_objects_file.c_str()));
if (file != nullptr) {
args.Add("--dirty-image-objects-fd=%d", file->Fd());
readonly_files_raii.push_back(std::move(file));
} else if (errno == ENOENT) {
LOG(WARNING) << ART_FORMAT("Missing dirty objects file '{}'", dirty_image_objects_file);
} else {
return CompilationResult::Error(OdrMetrics::Status::kIoError,
ART_FORMAT("Failed to open dirty objects file '{}': {}",
dirty_image_objects_file,
strerror(errno)));
}
std::string preloaded_classes_file(GetAndroidRoot() + "/etc/preloaded-classes");
file.reset(OS::OpenFileForReading(preloaded_classes_file.c_str()));
if (file != nullptr) {
args.Add("--preloaded-classes-fds=%d", file->Fd());
readonly_files_raii.push_back(std::move(file));
} else if (errno == ENOENT) {
LOG(WARNING) << ART_FORMAT("Missing preloaded classes file '{}'", preloaded_classes_file);
} else {
return CompilationResult::Error(OdrMetrics::Status::kIoError,
ART_FORMAT("Failed to open preloaded classes file '{}': {}",
preloaded_classes_file,
strerror(errno)));
}
} else {
// Mainline extension.
args.Add("--compiler-filter=%s", kMainlineCompilerFilter);
}
const OdrSystemProperties& system_properties = config_.GetSystemProperties();
args.AddRuntimeIfNonEmpty("-Xms%s", system_properties.GetOrEmpty("dalvik.vm.image-dex2oat-Xms"))
.AddRuntimeIfNonEmpty("-Xmx%s", system_properties.GetOrEmpty("dalvik.vm.image-dex2oat-Xmx"));
return RunDex2oat(
staging_dir,
ART_FORMAT("Compiling boot classpath ({}, {})", GetInstructionSetString(isa), debug_name),
isa,
dex_files,
boot_classpath,
input_boot_images,
OdrArtifacts::ForBootImage(output_path),
std::move(args),
readonly_files_raii);
}
WARN_UNUSED CompilationResult
OnDeviceRefresh::CompileBootClasspath(const std::string& staging_dir,
InstructionSet isa,
BootImages boot_images,
const std::function<void()>& on_dex2oat_success) const {
DCHECK_GT(boot_images.Count(), 0);
DCHECK_IMPLIES(boot_images.primary_boot_image, boot_images.boot_image_mainline_extension);
CompilationResult result = CompilationResult::Ok();
if (config_.GetMinimal()) {
result.Merge(
CompilationResult::Error(OdrMetrics::Status::kUnknown, "Minimal boot image requested"));
}
if (!check_compilation_space_()) {
result.Merge(CompilationResult::Error(OdrMetrics::Status::kNoSpace, "Insufficient space"));
}
if (result.IsOk() && boot_images.primary_boot_image) {
CompilationResult primary_result = RunDex2oatForBootClasspath(
staging_dir,
"primary",
isa,
dex2oat_boot_classpath_jars_,
dex2oat_boot_classpath_jars_,
/*input_boot_images=*/{},
GetPrimaryBootImagePath(/*on_system=*/false, /*minimal=*/false, isa));
result.Merge(primary_result);
if (primary_result.IsOk()) {
on_dex2oat_success();
// Remove the minimal boot image only if the full boot image is successfully generated.
std::string path = GetPrimaryBootImagePath(/*on_system=*/false, /*minimal=*/true, isa);
OdrArtifacts artifacts = OdrArtifacts::ForBootImage(path);
unlink(artifacts.ImagePath().c_str());
unlink(artifacts.OatPath().c_str());
unlink(artifacts.VdexPath().c_str());
}
}
if (!result.IsOk() && boot_images.primary_boot_image) {
LOG(ERROR) << "Compilation of primary BCP failed: " << result.error_msg;
// Fall back to generating a minimal boot image.
// The compilation of the full boot image will be retried on later reboots with a backoff
// time, and the minimal boot image will be removed once the compilation of the full boot
// image succeeds.
std::string ignored_error_msg;
if (PrimaryBootImageExist(
/*on_system=*/false, /*minimal=*/true, isa, &ignored_error_msg)) {
LOG(INFO) << "Minimal boot image already up-to-date";
return result;
}
std::vector<std::string> art_bcp_jars = GetArtBcpJars();
CompilationResult minimal_result = RunDex2oatForBootClasspath(
staging_dir,
"minimal",
isa,
art_bcp_jars,
art_bcp_jars,
/*input_boot_images=*/{},
GetPrimaryBootImagePath(/*on_system=*/false, /*minimal=*/true, isa));
result.Merge(minimal_result);
if (!minimal_result.IsOk()) {
LOG(ERROR) << "Compilation of minimal BCP failed: " << result.error_msg;
}
return result;
}
if (result.IsOk() && boot_images.boot_image_mainline_extension) {
CompilationResult mainline_result =
RunDex2oatForBootClasspath(staging_dir,
"mainline",
isa,
GetMainlineBcpJars(),
boot_classpath_jars_,
GetBestBootImages(isa, /*include_mainline_extension=*/false),
GetBootImageMainlineExtensionPath(/*on_system=*/false, isa));
result.Merge(mainline_result);
if (mainline_result.IsOk()) {
on_dex2oat_success();
}
}
if (!result.IsOk() && boot_images.boot_image_mainline_extension) {
LOG(ERROR) << "Compilation of mainline BCP failed: " << result.error_msg;
}
return result;
}
WARN_UNUSED CompilationResult OnDeviceRefresh::RunDex2oatForSystemServer(
const std::string& staging_dir,
const std::string& dex_file,
const std::vector<std::string>& classloader_context) const {
CmdlineBuilder args;
std::vector<std::unique_ptr<File>> readonly_files_raii;
InstructionSet isa = config_.GetSystemServerIsa();
std::string output_path = GetSystemServerImagePath(/*on_system=*/false, dex_file);
std::string actual_jar_path = RewriteParentDirectoryIfNeeded(dex_file);
std::string profile = actual_jar_path + ".prof";
const std::string& compiler_filter = config_.GetSystemServerCompilerFilter();
bool maybe_add_profile = !compiler_filter.empty() || HasVettedDeviceSystemServerProfiles();
bool has_added_profile = false;
if (maybe_add_profile) {
Result<bool> has_any_profile = AddDex2OatProfile(args, readonly_files_raii, {profile});
if (!has_any_profile.ok()) {
return CompilationResult::Error(OdrMetrics::Status::kIoError,
has_any_profile.error().message());
}
has_added_profile = *has_any_profile;
}
if (!compiler_filter.empty()) {
args.Add("--compiler-filter=%s", compiler_filter);
} else if (has_added_profile) {
args.Add("--compiler-filter=speed-profile");
} else {
args.Add("--compiler-filter=speed");
}
std::string context_path = Join(classloader_context, ':');
if (art::ContainsElement(systemserver_classpath_jars_, dex_file)) {
args.Add("--class-loader-context=PCL[%s]", context_path);
} else {
args.Add("--class-loader-context=PCL[];PCL[%s]", context_path);
}
if (!classloader_context.empty()) {
std::vector<int> fds;
for (const std::string& path : classloader_context) {
std::string actual_path = RewriteParentDirectoryIfNeeded(path);
std::unique_ptr<File> file(OS::OpenFileForReading(actual_path.c_str()));
if (file == nullptr) {
return CompilationResult::Error(
OdrMetrics::Status::kIoError,
ART_FORMAT(
"Failed to open classloader context '{}': {}", actual_path, strerror(errno)));
}
fds.emplace_back(file->Fd());
readonly_files_raii.emplace_back(std::move(file));
}
args.Add("--class-loader-context-fds=%s", Join(fds, ':'));
}
const OdrSystemProperties& system_properties = config_.GetSystemProperties();
args.AddRuntimeIfNonEmpty("-Xms%s", system_properties.GetOrEmpty("dalvik.vm.dex2oat-Xms"))
.AddRuntimeIfNonEmpty("-Xmx%s", system_properties.GetOrEmpty("dalvik.vm.dex2oat-Xmx"));
return RunDex2oat(staging_dir,
ART_FORMAT("Compiling {}", Basename(dex_file)),
isa,
{dex_file},
boot_classpath_jars_,
GetBestBootImages(isa, /*include_mainline_extension=*/true),
OdrArtifacts::ForSystemServer(output_path),
std::move(args),
readonly_files_raii);
}
WARN_UNUSED CompilationResult
OnDeviceRefresh::CompileSystemServer(const std::string& staging_dir,
const std::set<std::string>& system_server_jars_to_compile,
const std::function<void()>& on_dex2oat_success) const {
DCHECK(!system_server_jars_to_compile.empty());
CompilationResult result = CompilationResult::Ok();
std::vector<std::string> classloader_context;
if (!check_compilation_space_()) {
LOG(ERROR) << "Compilation of system_server failed: Insufficient space";
return CompilationResult::Error(OdrMetrics::Status::kNoSpace, "Insufficient space");
}
for (const std::string& jar : all_systemserver_jars_) {
if (ContainsElement(system_server_jars_to_compile, jar)) {
CompilationResult current_result =
RunDex2oatForSystemServer(staging_dir, jar, classloader_context);
result.Merge(current_result);
if (current_result.IsOk()) {
on_dex2oat_success();
} else {
LOG(ERROR) << ART_FORMAT("Compilation of {} failed: {}", Basename(jar), result.error_msg);
}
}
if (ContainsElement(systemserver_classpath_jars_, jar)) {
classloader_context.emplace_back(jar);
}
}
return result;
}
WARN_UNUSED ExitCode OnDeviceRefresh::Compile(OdrMetrics& metrics,
CompilationOptions compilation_options) const {
const char* staging_dir = nullptr;
metrics.SetStage(OdrMetrics::Stage::kPreparation);
// If partial compilation is disabled, we should compile everything regardless of what's in
// `compilation_options`.
if (!config_.GetPartialCompilation()) {
compilation_options = CompilationOptions::CompileAll(*this);
if (!RemoveArtifactsDirectory()) {
metrics.SetStatus(OdrMetrics::Status::kIoError);
return ExitCode::kCleanupFailed;
}
}
if (!EnsureDirectoryExists(config_.GetArtifactDirectory())) {
LOG(ERROR) << "Failed to prepare artifact directory";
metrics.SetStatus(errno == EPERM ? OdrMetrics::Status::kDalvikCachePermissionDenied :
OdrMetrics::Status::kIoError);
return ExitCode::kCleanupFailed;
}
if (config_.GetRefresh()) {
Result<void> result = RefreshExistingArtifacts();
if (!result.ok()) {
LOG(ERROR) << "Failed to refresh existing artifacts: " << result.error();
metrics.SetStatus(OdrMetrics::Status::kIoError);
return ExitCode::kCleanupFailed;
}
}
// Emit cache info before compiling. This can be used to throttle compilation attempts later.
Result<void> result = WriteCacheInfo();
if (!result.ok()) {
LOG(ERROR) << result.error();
metrics.SetStatus(OdrMetrics::Status::kIoError);
return ExitCode::kCleanupFailed;
}
if (!config_.GetStagingDir().empty()) {
staging_dir = config_.GetStagingDir().c_str();
} else {
// Create staging area and assign label for generating compilation artifacts.
if (PaletteCreateOdrefreshStagingDirectory(&staging_dir) != PALETTE_STATUS_OK) {
metrics.SetStatus(OdrMetrics::Status::kStagingFailed);
return ExitCode::kCleanupFailed;
}
}
std::string error_msg;
uint32_t dex2oat_invocation_count = 0;
uint32_t total_dex2oat_invocation_count = compilation_options.CompilationUnitCount();
ReportNextBootAnimationProgress(dex2oat_invocation_count, total_dex2oat_invocation_count);
auto advance_animation_progress = [&]() {
ReportNextBootAnimationProgress(++dex2oat_invocation_count, total_dex2oat_invocation_count);
};
const std::vector<InstructionSet>& bcp_instruction_sets = config_.GetBootClasspathIsas();
DCHECK(!bcp_instruction_sets.empty() && bcp_instruction_sets.size() <= 2);
InstructionSet system_server_isa = config_.GetSystemServerIsa();
bool system_server_isa_failed = false;
std::optional<std::pair<OdrMetrics::Stage, OdrMetrics::Status>> first_failure;
for (const auto& [isa, boot_images_to_generate] :
compilation_options.boot_images_to_generate_for_isas) {
OdrMetrics::Stage stage = (isa == bcp_instruction_sets.front()) ?
OdrMetrics::Stage::kPrimaryBootClasspath :
OdrMetrics::Stage::kSecondaryBootClasspath;
CompilationResult bcp_result =
CompileBootClasspath(staging_dir, isa, boot_images_to_generate, advance_animation_progress);
metrics.SetDex2OatResult(stage, bcp_result.elapsed_time_ms, bcp_result.dex2oat_result);
metrics.SetBcpCompilationType(stage, boot_images_to_generate.GetTypeForMetrics());
if (!bcp_result.IsOk()) {
if (isa == system_server_isa) {
system_server_isa_failed = true;
}
first_failure = first_failure.value_or(std::make_pair(stage, bcp_result.status));
}
}
// Don't compile system server if the compilation of BCP failed.
if (!system_server_isa_failed && !compilation_options.system_server_jars_to_compile.empty()) {
OdrMetrics::Stage stage = OdrMetrics::Stage::kSystemServerClasspath;
CompilationResult ss_result = CompileSystemServer(
staging_dir, compilation_options.system_server_jars_to_compile, advance_animation_progress);
metrics.SetDex2OatResult(stage, ss_result.elapsed_time_ms, ss_result.dex2oat_result);
if (!ss_result.IsOk()) {
first_failure = first_failure.value_or(std::make_pair(stage, ss_result.status));
}
}
if (first_failure.has_value()) {
LOG(ERROR) << "Compilation failed, stage: " << first_failure->first
<< " status: " << first_failure->second;
metrics.SetStage(first_failure->first);
metrics.SetStatus(first_failure->second);
if (!config_.GetDryRun() && !RemoveDirectory(staging_dir)) {
return ExitCode::kCleanupFailed;
}
return ExitCode::kCompilationFailed;
}
metrics.SetStage(OdrMetrics::Stage::kComplete);
metrics.SetStatus(OdrMetrics::Status::kOK);
return ExitCode::kCompilationSuccess;
}
} // namespace odrefresh
} // namespace art