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android / device / google / cuttlefish / 84d01e0e9 / . / host / commands / assemble_cvd / disk_flags.cc
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/*
* Copyright (C) 2019 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 "host/commands/assemble_cvd/disk_flags.h"
#include <android-base/logging.h>
#include <android-base/strings.h>
#include <fruit/fruit.h>
#include <gflags/gflags.h>
#include <sys/statvfs.h>
#include <fstream>
#include "common/libs/fs/shared_buf.h"
#include "common/libs/utils/environment.h"
#include "common/libs/utils/files.h"
#include "common/libs/utils/size_utils.h"
#include "common/libs/utils/subprocess.h"
#include "host/commands/assemble_cvd/boot_config.h"
#include "host/commands/assemble_cvd/boot_image_utils.h"
#include "host/commands/assemble_cvd/super_image_mixer.h"
#include "host/libs/config/bootconfig_args.h"
#include "host/libs/config/cuttlefish_config.h"
#include "host/libs/config/data_image.h"
#include "host/libs/image_aggregator/image_aggregator.h"
#include "host/libs/vm_manager/crosvm_manager.h"
// Taken from external/avb/libavb/avb_slot_verify.c; this define is not in the headers
#define VBMETA_MAX_SIZE 65536ul
DECLARE_string(system_image_dir);
DEFINE_string(boot_image, "",
"Location of cuttlefish boot image. If empty it is assumed to be "
"boot.img in the directory specified by -system_image_dir.");
DEFINE_string(data_image, "", "Location of the data partition image.");
DEFINE_string(super_image, "", "Location of the super partition image.");
DEFINE_string(misc_image, "",
"Location of the misc partition image. If the image does not "
"exist, a blank new misc partition image is created.");
DEFINE_string(metadata_image, "", "Location of the metadata partition image "
"to be generated.");
DEFINE_string(vendor_boot_image, "",
"Location of cuttlefish vendor boot image. If empty it is assumed to "
"be vendor_boot.img in the directory specified by -system_image_dir.");
DEFINE_string(vbmeta_image, "",
"Location of cuttlefish vbmeta image. If empty it is assumed to "
"be vbmeta.img in the directory specified by -system_image_dir.");
DEFINE_string(vbmeta_system_image, "",
"Location of cuttlefish vbmeta_system image. If empty it is assumed to "
"be vbmeta_system.img in the directory specified by -system_image_dir.");
DEFINE_string(otheros_esp_image, "",
"Location of cuttlefish esp image. If the image does not exist, "
"and --otheros_root_image is specified, an esp partition image "
"is created with default bootloaders.");
DEFINE_string(otheros_kernel_path, "",
"Location of cuttlefish otheros kernel.");
DEFINE_string(otheros_initramfs_path, "",
"Location of cuttlefish otheros initramfs.img.");
DEFINE_string(otheros_root_image, "",
"Location of cuttlefish otheros root filesystem image.");
DEFINE_int32(blank_metadata_image_mb, 16,
"The size of the blank metadata image to generate, MB.");
DEFINE_int32(blank_sdcard_image_mb, 2048,
"If enabled, the size of the blank sdcard image to generate, MB.");
DECLARE_string(bootloader);
DECLARE_bool(use_sdcard);
DECLARE_string(initramfs_path);
DECLARE_string(kernel_path);
DECLARE_bool(resume);
DECLARE_bool(protected_vm);
namespace cuttlefish {
using vm_manager::CrosvmManager;
bool ResolveInstanceFiles() {
if (FLAGS_system_image_dir.empty()) {
LOG(ERROR) << "--system_image_dir must be specified.";
return false;
}
// If user did not specify location of either of these files, expect them to
// be placed in --system_image_dir location.
std::string default_boot_image = FLAGS_system_image_dir + "/boot.img";
SetCommandLineOptionWithMode("boot_image", default_boot_image.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
std::string default_data_image = FLAGS_system_image_dir + "/userdata.img";
SetCommandLineOptionWithMode("data_image", default_data_image.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
std::string default_metadata_image = FLAGS_system_image_dir + "/metadata.img";
SetCommandLineOptionWithMode("metadata_image", default_metadata_image.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
std::string default_super_image = FLAGS_system_image_dir + "/super.img";
SetCommandLineOptionWithMode("super_image", default_super_image.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
std::string default_misc_image = FLAGS_system_image_dir + "/misc.img";
SetCommandLineOptionWithMode("misc_image", default_misc_image.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
std::string default_esp_image = FLAGS_system_image_dir + "/esp.img";
SetCommandLineOptionWithMode("otheros_esp_image", default_esp_image.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
std::string default_vendor_boot_image = FLAGS_system_image_dir
+ "/vendor_boot.img";
SetCommandLineOptionWithMode("vendor_boot_image",
default_vendor_boot_image.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
std::string default_vbmeta_image = FLAGS_system_image_dir + "/vbmeta.img";
SetCommandLineOptionWithMode("vbmeta_image", default_vbmeta_image.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
std::string default_vbmeta_system_image = FLAGS_system_image_dir
+ "/vbmeta_system.img";
SetCommandLineOptionWithMode("vbmeta_system_image",
default_vbmeta_system_image.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
return true;
}
std::vector<ImagePartition> os_composite_disk_config() {
std::vector<ImagePartition> partitions;
partitions.push_back(ImagePartition{
.label = "misc",
.image_file_path = FLAGS_misc_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "boot_a",
.image_file_path = FLAGS_boot_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "boot_b",
.image_file_path = FLAGS_boot_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "vendor_boot_a",
.image_file_path = FLAGS_vendor_boot_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "vendor_boot_b",
.image_file_path = FLAGS_vendor_boot_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "vbmeta_a",
.image_file_path = FLAGS_vbmeta_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "vbmeta_b",
.image_file_path = FLAGS_vbmeta_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "vbmeta_system_a",
.image_file_path = FLAGS_vbmeta_system_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "vbmeta_system_b",
.image_file_path = FLAGS_vbmeta_system_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "super",
.image_file_path = FLAGS_super_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "userdata",
.image_file_path = FLAGS_data_image,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "metadata",
.image_file_path = FLAGS_metadata_image,
.read_only = true,
});
if (!FLAGS_otheros_root_image.empty()) {
partitions.push_back(ImagePartition{
.label = "otheros_esp",
.image_file_path = FLAGS_otheros_esp_image,
.type = kEfiSystemPartition,
.read_only = true,
});
partitions.push_back(ImagePartition{
.label = "otheros_root",
.image_file_path = FLAGS_otheros_root_image,
.read_only = true,
});
}
return partitions;
}
std::vector<ImagePartition> persistent_composite_disk_config(
const CuttlefishConfig::InstanceSpecific& instance) {
std::vector<ImagePartition> partitions;
// Note that if the position of uboot_env changes, the environment for
// u-boot must be updated as well (see boot_config.cc and
// cuttlefish.fragment in external/u-boot).
partitions.push_back(ImagePartition{
.label = "uboot_env",
.image_file_path = instance.uboot_env_image_path(),
});
if (!FLAGS_protected_vm) {
partitions.push_back(ImagePartition{
.label = "frp",
.image_file_path = instance.factory_reset_protected_path(),
});
}
partitions.push_back(ImagePartition{
.label = "bootconfig",
.image_file_path = instance.persistent_bootconfig_path(),
});
return partitions;
}
static std::chrono::system_clock::time_point LastUpdatedInputDisk(
const std::vector<ImagePartition>& partitions) {
std::chrono::system_clock::time_point ret;
for (auto& partition : partitions) {
if (partition.label == "frp") {
continue;
}
auto partition_mod_time = FileModificationTime(partition.image_file_path);
if (partition_mod_time > ret) {
ret = partition_mod_time;
}
}
return ret;
}
bool DoesCompositeMatchCurrentDiskConfig(
const std::string& prior_disk_config_path,
const std::vector<ImagePartition>& partitions) {
std::string current_disk_config_path = prior_disk_config_path + ".tmp";
std::ostringstream disk_conf;
for (auto& partition : partitions) {
disk_conf << partition.image_file_path << "\n";
}
{
// This file acts as a descriptor of the cuttlefish disk contents in a VMM agnostic way (VMMs
// used are QEMU and CrosVM at the time of writing). This file is used to determine if the
// disk config for the pending boot matches the disk from the past boot.
std::ofstream file_out(current_disk_config_path.c_str(), std::ios::binary);
file_out << disk_conf.str();
CHECK(file_out.good()) << "Disk config verification failed.";
}
if (!FileExists(prior_disk_config_path) ||
ReadFile(prior_disk_config_path) != ReadFile(current_disk_config_path)) {
CHECK(cuttlefish::RenameFile(current_disk_config_path, prior_disk_config_path))
<< "Unable to delete the old disk config descriptor";
LOG(DEBUG) << "Disk Config has changed since last boot. Regenerating composite disk.";
return false;
} else {
RemoveFile(current_disk_config_path);
return true;
}
}
bool ShouldCreateCompositeDisk(const std::string& composite_disk_path,
const std::vector<ImagePartition>& partitions) {
if (!FileExists(composite_disk_path)) {
return true;
}
auto composite_age = FileModificationTime(composite_disk_path);
return composite_age < LastUpdatedInputDisk(partitions);
}
bool ShouldCreateOsCompositeDisk(const CuttlefishConfig& config) {
return ShouldCreateCompositeDisk(config.os_composite_disk_path(),
os_composite_disk_config());
}
static uint64_t AvailableSpaceAtPath(const std::string& path) {
struct statvfs vfs;
if (statvfs(path.c_str(), &vfs) != 0) {
int error_num = errno;
LOG(ERROR) << "Could not find space available at " << path << ", error was "
<< strerror(error_num);
return 0;
}
// f_frsize (block size) * f_bavail (free blocks) for unprivileged users.
return static_cast<uint64_t>(vfs.f_frsize) * vfs.f_bavail;
}
bool CreateOsCompositeDisk(const CuttlefishConfig& config) {
if (!SharedFD::Open(config.os_composite_disk_path().c_str(),
O_WRONLY | O_CREAT, 0644)
->IsOpen()) {
LOG(ERROR) << "Could not ensure " << config.os_composite_disk_path()
<< " exists";
return false;
}
if (config.vm_manager() == CrosvmManager::name()) {
// Check if filling in the sparse image would run out of disk space.
auto existing_sizes = SparseFileSizes(FLAGS_data_image);
if (existing_sizes.sparse_size == 0 && existing_sizes.disk_size == 0) {
LOG(ERROR) << "Unable to determine size of \"" << FLAGS_data_image
<< "\". Does this file exist?";
}
auto available_space = AvailableSpaceAtPath(FLAGS_data_image);
if (available_space < existing_sizes.sparse_size - existing_sizes.disk_size) {
// TODO(schuffelen): Duplicate this check in run_cvd when it can run on a separate machine
LOG(ERROR) << "Not enough space remaining in fs containing " << FLAGS_data_image;
LOG(ERROR) << "Wanted " << (existing_sizes.sparse_size - existing_sizes.disk_size);
LOG(ERROR) << "Got " << available_space;
return false;
} else {
LOG(DEBUG) << "Available space: " << available_space;
LOG(DEBUG) << "Sparse size of \"" << FLAGS_data_image << "\": "
<< existing_sizes.sparse_size;
LOG(DEBUG) << "Disk size of \"" << FLAGS_data_image << "\": "
<< existing_sizes.disk_size;
}
std::string header_path =
config.AssemblyPath("os_composite_gpt_header.img");
std::string footer_path =
config.AssemblyPath("os_composite_gpt_footer.img");
CreateCompositeDisk(os_composite_disk_config(), header_path, footer_path,
config.os_composite_disk_path());
} else {
// If this doesn't fit into the disk, it will fail while aggregating. The
// aggregator doesn't maintain any sparse attributes.
AggregateImage(os_composite_disk_config(), config.os_composite_disk_path());
}
return true;
}
bool CreatePersistentCompositeDisk(
const CuttlefishConfig& config,
const CuttlefishConfig::InstanceSpecific& instance) {
if (!SharedFD::Open(instance.persistent_composite_disk_path().c_str(),
O_WRONLY | O_CREAT, 0644)
->IsOpen()) {
LOG(ERROR) << "Could not ensure "
<< instance.persistent_composite_disk_path() << " exists";
return false;
}
if (config.vm_manager() == CrosvmManager::name()) {
std::string header_path =
instance.PerInstancePath("persistent_composite_gpt_header.img");
std::string footer_path =
instance.PerInstancePath("persistent_composite_gpt_footer.img");
CreateCompositeDisk(persistent_composite_disk_config(instance), header_path,
footer_path, instance.persistent_composite_disk_path());
} else {
AggregateImage(persistent_composite_disk_config(instance),
instance.persistent_composite_disk_path());
}
return true;
}
class BootImageRepacker : public Feature {
public:
INJECT(BootImageRepacker(const CuttlefishConfig& config)) : config_(config) {}
// Feature
std::string Name() const override { return "BootImageRepacker"; }
std::unordered_set<Feature*> Dependencies() const override { return {}; }
bool Enabled() const override {
// If we are booting a protected VM, for now, assume that image repacking
// isn't trusted. Repacking requires resigning the image and keys from an
// android host aren't trusted.
return !config_.protected_vm();
}
protected:
bool Setup() override {
if (!FileHasContent(FLAGS_boot_image)) {
LOG(ERROR) << "File not found: " << FLAGS_boot_image;
return false;
}
if (!FileHasContent(FLAGS_vendor_boot_image)) {
LOG(ERROR) << "File not found: " << FLAGS_vendor_boot_image;
return false;
}
if (FLAGS_kernel_path.size()) {
const std::string new_boot_image_path =
config_.AssemblyPath("boot_repacked.img");
bool success =
RepackBootImage(FLAGS_kernel_path, FLAGS_boot_image,
new_boot_image_path, config_.assembly_dir());
if (!success) {
LOG(ERROR) << "Failed to regenerate the boot image with the new kernel";
return false;
}
SetCommandLineOptionWithMode("boot_image", new_boot_image_path.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
}
if (FLAGS_kernel_path.size() || FLAGS_initramfs_path.size()) {
const std::string new_vendor_boot_image_path =
config_.AssemblyPath("vendor_boot_repacked.img");
// Repack the vendor boot images if kernels and/or ramdisks are passed in.
if (FLAGS_initramfs_path.size()) {
bool success = RepackVendorBootImage(
FLAGS_initramfs_path, FLAGS_vendor_boot_image,
new_vendor_boot_image_path, config_.assembly_dir(),
config_.bootconfig_supported());
if (!success) {
LOG(ERROR) << "Failed to regenerate the vendor boot image with the "
"new ramdisk";
} else {
// This control flow implies a kernel with all configs built in.
// If it's just the kernel, repack the vendor boot image without a
// ramdisk.
bool success = RepackVendorBootImageWithEmptyRamdisk(
FLAGS_vendor_boot_image, new_vendor_boot_image_path,
config_.assembly_dir(), config_.bootconfig_supported());
if (!success) {
LOG(ERROR) << "Failed to regenerate the vendor boot image without "
"a ramdisk";
return false;
}
}
SetCommandLineOptionWithMode(
"vendor_boot_image", new_vendor_boot_image_path.c_str(),
google::FlagSettingMode::SET_FLAGS_DEFAULT);
}
}
return true;
}
private:
const CuttlefishConfig& config_;
};
static void GeneratePersistentBootconfig(
const CuttlefishConfig& config,
const CuttlefishConfig::InstanceSpecific& instance) {
const auto bootconfig_path = instance.persistent_bootconfig_path();
if (!FileExists(bootconfig_path)) {
CreateBlankImage(bootconfig_path, 1 /* mb */, "none");
}
auto bootconfig_fd = SharedFD::Open(bootconfig_path, O_RDWR);
CHECK(bootconfig_fd->IsOpen())
<< "Unable to open bootconfig file: " << bootconfig_fd->StrError();
// Cuttlefish for the time being won't be able to support OTA from a
// non-bootconfig kernel to a bootconfig-kernel (or vice versa) IF the device
// is stopped (via stop_cvd). This is rarely an issue since OTA testing run
// on cuttlefish is done within one launch cycle of the device. If this ever
// becomes an issue, this code will have to be rewritten.
if (!config.bootconfig_supported()) {
return;
}
const std::string bootconfig =
android::base::Join(BootconfigArgsFromConfig(config, instance), "\n") +
"\n";
ssize_t bytesWritten = WriteAll(bootconfig_fd, bootconfig);
CHECK(bytesWritten == bootconfig.size());
LOG(DEBUG) << "Bootconfig parameters from vendor boot image and config are "
<< ReadFile(bootconfig_path);
const off_t bootconfig_size_bytes =
AlignToPowerOf2(bootconfig.size(), PARTITION_SIZE_SHIFT);
CHECK(bootconfig_fd->Truncate(bootconfig_size_bytes) == 0)
<< "`truncate --size=" << bootconfig_size_bytes << " bytes "
<< bootconfig_path << "` failed:" << bootconfig_fd->StrError();
}
class InitializeMetadataImage : public Feature {
public:
INJECT(InitializeMetadataImage()) {}
// Feature
std::string Name() const override { return "InitializeMetadataImage"; }
bool Enabled() const override { return true; }
private:
std::unordered_set<Feature*> Dependencies() const override { return {}; }
bool Setup() override {
if (!FileExists(FLAGS_metadata_image)) {
bool success = CreateBlankImage(FLAGS_metadata_image,
FLAGS_blank_metadata_image_mb, "none");
if (!success) {
LOG(ERROR) << "Failed to create \"" << FLAGS_metadata_image
<< "\" with size " << FLAGS_blank_metadata_image_mb;
}
return success;
}
return true;
}
};
class InitializeAccessKregistryImage : public Feature {
public:
INJECT(InitializeAccessKregistryImage(
const CuttlefishConfig& config,
const CuttlefishConfig::InstanceSpecific& instance))
: config_(config), instance_(instance) {}
// Feature
std::string Name() const override { return "InitializeAccessKregistryImage"; }
bool Enabled() const override { return !config_.protected_vm(); }
private:
std::unordered_set<Feature*> Dependencies() const override { return {}; }
bool Setup() {
if (FileExists(instance_.access_kregistry_path())) {
return true;
}
bool success =
CreateBlankImage(instance_.access_kregistry_path(), 2 /* mb */, "none");
if (!success) {
LOG(ERROR) << "Failed to create access_kregistry_path \""
<< instance_.access_kregistry_path() << "\"";
return false;
}
return true;
}
const CuttlefishConfig& config_;
const CuttlefishConfig::InstanceSpecific& instance_;
};
class InitializePstore : public Feature {
public:
INJECT(InitializePstore(const CuttlefishConfig& config,
const CuttlefishConfig::InstanceSpecific& instance))
: config_(config), instance_(instance) {}
// Feature
std::string Name() const override { return "InitializePstore"; }
bool Enabled() const override { return !config_.protected_vm(); }
private:
std::unordered_set<Feature*> Dependencies() const override { return {}; }
bool Setup() {
if (FileExists(instance_.pstore_path())) {
return true;
}
bool success =
CreateBlankImage(instance_.pstore_path(), 2 /* mb */, "none");
if (!success) {
LOG(ERROR) << "Failed to create pstore_path \"" << instance_.pstore_path()
<< "\"";
return false;
}
return true;
}
const CuttlefishConfig& config_;
const CuttlefishConfig::InstanceSpecific& instance_;
};
class InitializeSdCard : public Feature {
public:
INJECT(InitializeSdCard(const CuttlefishConfig& config,
const CuttlefishConfig::InstanceSpecific& instance))
: config_(config), instance_(instance) {}
// Feature
std::string Name() const override { return "InitializeSdCard"; }
bool Enabled() const override {
return FLAGS_use_sdcard && !config_.protected_vm();
}
private:
std::unordered_set<Feature*> Dependencies() const override { return {}; }
bool Setup() {
if (FileExists(instance_.sdcard_path())) {
return true;
}
bool success = CreateBlankImage(instance_.sdcard_path(),
FLAGS_blank_sdcard_image_mb, "sdcard");
if (!success) {
LOG(ERROR) << "Failed to create sdcard \"" << instance_.sdcard_path()
<< "\"";
return false;
}
return true;
}
const CuttlefishConfig& config_;
const CuttlefishConfig::InstanceSpecific& instance_;
};
static fruit::Component<> DiskChangesComponent(const FetcherConfig* fetcher,
const CuttlefishConfig* config) {
return fruit::createComponent()
.bindInstance(*fetcher)
.bindInstance(*config)
.addMultibinding<Feature, InitializeMetadataImage>()
.addMultibinding<Feature, BootImageRepacker>()
.install(FixedMiscImagePathComponent, &FLAGS_misc_image)
.install(InitializeMiscImageComponent)
.install(FixedDataImagePathComponent, &FLAGS_data_image)
.install(InitializeDataImageComponent)
// Create esp if necessary
.install(InitializeEspImageComponent, &FLAGS_otheros_esp_image,
&FLAGS_otheros_kernel_path, &FLAGS_otheros_initramfs_path);
}
static fruit::Component<> DiskChangesPerInstanceComponent(
const FetcherConfig* fetcher, const CuttlefishConfig* config,
const CuttlefishConfig::InstanceSpecific* instance) {
return fruit::createComponent()
.bindInstance(*fetcher)
.bindInstance(*config)
.bindInstance(*instance)
.addMultibinding<Feature, InitializeAccessKregistryImage>()
.addMultibinding<Feature, InitializePstore>()
.addMultibinding<Feature, InitializeSdCard>()
.install(InitBootloaderEnvPartitionComponent);
}
void CreateDynamicDiskFiles(const FetcherConfig& fetcher_config,
const CuttlefishConfig& config) {
// TODO(schuffelen): Unify this with the other injector created in
// assemble_cvd.cpp
fruit::Injector<> injector(DiskChangesComponent, &fetcher_config, &config);
const auto& features = injector.getMultibindings<Feature>();
CHECK(Feature::RunSetup(features)) << "Failed to run feature setup.";
for (const auto& instance : config.Instances()) {
fruit::Injector<> instance_injector(DiskChangesPerInstanceComponent,
&fetcher_config, &config, &instance);
const auto& instance_features =
instance_injector.getMultibindings<Feature>();
CHECK(Feature::RunSetup(instance_features))
<< "Failed to run instance feature setup.";
}
// If we are booting a protected VM, for now, assume we want a super minimal
// environment with no userdata encryption, limited debug, no FRP emulation, a
// static env for the bootloader, no SD-Card and no resume-on-reboot HAL
// support.
if (!FLAGS_protected_vm) {
for (const auto& instance : config.Instances()) {
const auto frp = instance.factory_reset_protected_path();
if (!FileExists(frp)) {
CreateBlankImage(frp, 1 /* mb */, "none");
}
GeneratePersistentBootconfig(config, instance);
}
}
for (const auto& instance : config.Instances()) {
bool compositeMatchesDiskConfig = DoesCompositeMatchCurrentDiskConfig(
instance.PerInstancePath("persistent_composite_disk_config.txt"),
persistent_composite_disk_config(instance));
bool oldCompositeDisk =
ShouldCreateCompositeDisk(instance.persistent_composite_disk_path(),
persistent_composite_disk_config(instance));
if (!compositeMatchesDiskConfig || oldCompositeDisk) {
CHECK(CreatePersistentCompositeDisk(config, instance))
<< "Failed to create persistent composite disk";
}
}
// libavb expects to be able to read the maximum vbmeta size, so we must
// provide a partition which matches this or the read will fail
for (const auto& vbmeta_image : { FLAGS_vbmeta_image, FLAGS_vbmeta_system_image }) {
if (FileSize(vbmeta_image) != VBMETA_MAX_SIZE) {
auto fd = SharedFD::Open(vbmeta_image, O_RDWR);
CHECK(fd->Truncate(VBMETA_MAX_SIZE) == 0)
<< "`truncate --size=" << VBMETA_MAX_SIZE << " " << vbmeta_image << "` "
<< "failed: " << fd->StrError();
}
}
CHECK(FileHasContent(FLAGS_bootloader))
<< "File not found: " << FLAGS_bootloader;
if (SuperImageNeedsRebuilding(fetcher_config, config)) {
bool success = RebuildSuperImage(fetcher_config, config, FLAGS_super_image);
CHECK(success) << "Super image rebuilding requested but could not be completed.";
}
bool oldOsCompositeDisk = ShouldCreateOsCompositeDisk(config);
bool osCompositeMatchesDiskConfig = DoesCompositeMatchCurrentDiskConfig(
config.AssemblyPath("os_composite_disk_config.txt"),
os_composite_disk_config());
if (!osCompositeMatchesDiskConfig || oldOsCompositeDisk || !FLAGS_resume) {
CHECK(CreateOsCompositeDisk(config))
<< "Failed to create OS composite disk";
for (auto instance : config.Instances()) {
if (FLAGS_resume) {
LOG(INFO) << "Requested to continue an existing session, (the default) "
<< "but the disk files have become out of date. Wiping the "
<< "old session files and starting a new session for device "
<< instance.serial_number();
}
if (FileExists(instance.access_kregistry_path())) {
CreateBlankImage(instance.access_kregistry_path(), 2 /* mb */, "none");
}
if (FileExists(instance.pstore_path())) {
CreateBlankImage(instance.pstore_path(), 2 /* mb */, "none");
}
}
}
if (!FLAGS_protected_vm) {
for (auto instance : config.Instances()) {
auto overlay_path = instance.PerInstancePath("overlay.img");
bool missingOverlay = !FileExists(overlay_path);
bool newOverlay = FileModificationTime(overlay_path) <
FileModificationTime(config.os_composite_disk_path());
if (missingOverlay || !FLAGS_resume || newOverlay) {
CreateQcowOverlay(config.crosvm_binary(),
config.os_composite_disk_path(), overlay_path);
}
}
}
for (auto instance : config.Instances()) {
// Check that the files exist
for (const auto& file : instance.virtual_disk_paths()) {
if (!file.empty()) {
CHECK(FileHasContent(file)) << "File not found: " << file;
}
}
}
}
} // namespace cuttlefish