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fuchsia / fuchsia / 7a571633dfc484f4f078e6d4fead9f29fecb2528 / . / zircon / system / ulib / paver / device-partitioner.cc
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// Copyright 2018 The Fuchsia Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "device-partitioner.h"
#include <dirent.h>
#include <errno.h>
#include <fcntl.h>
#include <libgen.h>
#include <chromeos-disk-setup/chromeos-disk-setup.h>
#include <fuchsia/boot/llcpp/fidl.h>
#include <fuchsia/device/llcpp/fidl.h>
#include <fuchsia/hardware/block/llcpp/fidl.h>
#include <fuchsia/hardware/block/partition/llcpp/fidl.h>
#include <fuchsia/hardware/skipblock/llcpp/fidl.h>
#include <lib/fdio/directory.h>
#include <lib/fdio/fd.h>
#include <lib/fdio/fdio.h>
#include <lib/fdio/unsafe.h>
#include <lib/fdio/watcher.h>
#include <lib/fzl/fdio.h>
#include <zircon/status.h>
#include <string>
#include <string_view>
#include <utility>
#include <fbl/auto_call.h>
#include <fbl/function.h>
#include <fbl/string_buffer.h>
#include <fs-management/fvm.h>
#include <gpt/cros.h>
#include <zxcrypt/volume.h>
#include "pave-logging.h"
namespace paver {
namespace {
namespace block = ::llcpp::fuchsia::hardware::block;
namespace partition = ::llcpp::fuchsia::hardware::block::partition;
namespace skipblock = ::llcpp::fuchsia::hardware::skipblock;
constexpr char kEfiName[] = "EFI Gigaboot";
constexpr char kFvmPartitionName[] = "fvm";
constexpr char kZirconAName[] = "ZIRCON-A";
constexpr char kZirconBName[] = "ZIRCON-B";
constexpr char kZirconRName[] = "ZIRCON-R";
bool KernelFilterCallback(const gpt_partition_t& part, const uint8_t kern_type[GPT_GUID_LEN],
fbl::StringPiece partition_name) {
char cstring_name[GPT_NAME_LEN];
utf16_to_cstring(cstring_name, reinterpret_cast<const uint16_t*>(part.name), GPT_NAME_LEN);
return memcmp(part.type, kern_type, GPT_GUID_LEN) == 0 &&
strncmp(cstring_name, partition_name.data(), partition_name.length()) == 0;
}
bool IsFvmPartition(const gpt_partition_t& part) {
const uint8_t partition_type[GPT_GUID_LEN] = GUID_FVM_VALUE;
return memcmp(part.type, partition_type, GPT_GUID_LEN) == 0;
}
bool IsGigabootPartition(const gpt_partition_t& part) {
const uint8_t efi_type[GPT_GUID_LEN] = GUID_EFI_VALUE;
char cstring_name[GPT_NAME_LEN];
utf16_to_cstring(cstring_name, reinterpret_cast<const uint16_t*>(part.name), GPT_NAME_LEN);
// Disk-paved EFI: Identified by "EFI Gigaboot" label.
const bool gigaboot_efi = strncmp(cstring_name, kEfiName, strlen(kEfiName)) == 0;
return memcmp(part.type, efi_type, GPT_GUID_LEN) == 0 && gigaboot_efi;
}
constexpr size_t ReservedHeaderBlocks(size_t blk_size) {
constexpr size_t kReservedEntryBlocks = (16 * 1024);
return (kReservedEntryBlocks + 2 * blk_size) / blk_size;
}
// Helper function to auto-deduce type.
template <typename T>
fbl::unique_ptr<T> WrapUnique(T* ptr) {
return fbl::unique_ptr<T>(ptr);
}
zx_status_t OpenPartition(const fbl::unique_fd& devfs_root, const char* path,
fbl::Function<bool(const zx::channel&)> should_filter_file,
zx_duration_t timeout, zx::channel* out_partition) {
ZX_ASSERT(path != nullptr);
struct CallbackInfo {
zx::channel* out_partition;
fbl::Function<bool(const zx::channel&)> should_filter_file;
};
CallbackInfo info = {
.out_partition = out_partition,
.should_filter_file = std::move(should_filter_file),
};
auto cb = [](int dirfd, int event, const char* filename, void* cookie) {
if (event != WATCH_EVENT_ADD_FILE) {
return ZX_OK;
}
if ((strcmp(filename, ".") == 0) || strcmp(filename, "..") == 0) {
return ZX_OK;
}
fzl::UnownedFdioCaller caller(dirfd);
zx::channel partition_local, partition_remote;
if (zx::channel::create(0, &partition_local, &partition_remote) != ZX_OK) {
return ZX_OK;
}
if (fdio_service_connect_at(caller.borrow_channel(), filename, partition_remote.release()) !=
ZX_OK) {
return ZX_OK;
}
auto info = static_cast<CallbackInfo*>(cookie);
if (info->should_filter_file(partition_local)) {
return ZX_OK;
}
if (info->out_partition) {
*(info->out_partition) = std::move(partition_local);
}
return ZX_ERR_STOP;
};
fbl::unique_fd dir_fd(openat(devfs_root.get(), path, O_RDONLY));
if (!dir_fd) {
return ZX_ERR_IO;
}
zx_time_t deadline = zx_deadline_after(timeout);
if (fdio_watch_directory(dir_fd.get(), cb, deadline, &info) != ZX_ERR_STOP) {
return ZX_ERR_NOT_FOUND;
}
return ZX_OK;
}
constexpr char kBlockDevPath[] = "class/block/";
zx_status_t OpenBlockPartition(const fbl::unique_fd& devfs_root, const uint8_t* unique_guid,
const uint8_t* type_guid, zx_duration_t timeout,
zx::channel* out_partition) {
ZX_ASSERT(unique_guid || type_guid);
auto cb = [&](const zx::channel& chan) {
if (type_guid) {
auto result = partition::Partition::Call::GetTypeGuid(zx::unowned(chan));
if (!result.ok()) {
return true;
}
auto& response = result.value();
if (response.status != ZX_OK ||
memcmp(response.guid->value.data(), type_guid, partition::GUID_LENGTH) != 0) {
return true;
}
}
if (unique_guid) {
auto result = partition::Partition::Call::GetInstanceGuid(zx::unowned(chan));
if (!result.ok()) {
return true;
}
const auto& response = result.value();
if (response.status != ZX_OK ||
memcmp(response.guid->value.data(), unique_guid, partition::GUID_LENGTH) != 0) {
return true;
}
}
return false;
};
return OpenPartition(devfs_root, kBlockDevPath, cb, timeout, out_partition);
}
constexpr char kSkipBlockDevPath[] = "class/skip-block/";
zx_status_t OpenSkipBlockPartition(const fbl::unique_fd& devfs_root, const uint8_t* type_guid,
zx_duration_t timeout, zx::channel* out_partition) {
ZX_ASSERT(type_guid);
auto cb = [&](const zx::channel& chan) {
auto result = skipblock::SkipBlock::Call::GetPartitionInfo(zx::unowned(chan));
if (!result.ok()) {
return true;
}
const auto& response = result.value();
if (response.status != ZX_OK || memcmp(response.partition_info.partition_guid.data(), type_guid,
skipblock::GUID_LEN) != 0) {
return true;
}
return false;
};
return OpenPartition(devfs_root, kSkipBlockDevPath, cb, timeout, out_partition);
}
bool HasSkipBlockDevice(const fbl::unique_fd& devfs_root) {
// Our proxy for detected a skip-block device is by checking for the
// existence of a device enumerated under the skip-block class.
const uint8_t type[GPT_GUID_LEN] = GUID_ZIRCON_A_VALUE;
return OpenSkipBlockPartition(devfs_root, type, ZX_SEC(1), nullptr) == ZX_OK;
}
// Attempts to open and overwrite the first block of the underlying
// partition. Does not rebind partition drivers.
//
// At most one of |unique_guid| and |type_guid| may be nullptr.
zx_status_t WipeBlockPartition(const fbl::unique_fd& devfs_root, const uint8_t* unique_guid,
const uint8_t* type_guid) {
zx::channel chan;
zx_status_t status = OpenBlockPartition(devfs_root, unique_guid, type_guid, ZX_SEC(3), &chan);
if (status != ZX_OK) {
ERROR("Warning: Could not open partition to wipe: %s\n", zx_status_get_string(status));
return status;
}
// Overwrite the first block to (hackily) ensure the destroyed partition
// doesn't "reappear" in place.
BlockPartitionClient block_partition(std::move(chan));
size_t block_size;
status = block_partition.GetBlockSize(&block_size);
if (status != ZX_OK) {
ERROR("Warning: Could not get block size of partition: %s\n", zx_status_get_string(status));
return status;
}
// Rely on vmos being 0 initialized.
zx::vmo vmo;
status = zx::vmo::create(fbl::round_up(block_size, ZX_PAGE_SIZE), 0, &vmo);
if (status != ZX_OK) {
ERROR("Warning: Could not create vmo: %s\n", zx_status_get_string(status));
return status;
}
status = block_partition.Write(vmo, block_size);
if (status != ZX_OK) {
ERROR("Warning: Could not write to block device: %s\n", zx_status_get_string(status));
return status;
}
if ((status = block_partition.Flush()) != ZX_OK) {
ERROR("Warning: Failed to synchronize block device: %s\n", zx_status_get_string(status));
return status;
}
return ZX_OK;
}
// Implementation of abr::Client which works with a contiguous partition storing abr::Data.
class AbrPartitionClient : public abr::Client {
public:
// |partition| should contain abr::Data with no offset.
static zx_status_t Create(std::unique_ptr<PartitionClient> partition,
std::unique_ptr<abr::Client>* out) {
size_t block_size;
if (zx_status_t status = partition->GetBlockSize(&block_size); status != ZX_OK) {
return status;
}
zx::vmo vmo;
if (zx_status_t status = zx::vmo::create(fbl::round_up(block_size, ZX_PAGE_SIZE), 0, &vmo);
status != ZX_OK) {
return status;
}
if (zx_status_t status = partition->Read(vmo, block_size); status != ZX_OK) {
return status;
}
abr::Data data;
if (zx_status_t status = vmo.read(&data, 0, sizeof(data)); status != ZX_OK) {
return status;
}
out->reset(new AbrPartitionClient(std::move(partition), std::move(vmo), block_size, data));
return ZX_OK;
}
zx_status_t Persist(abr::Data data) override {
UpdateCrc(&data);
if (memcmp(&data, &data_, sizeof(data)) == 0) {
return ZX_OK;
}
if (zx_status_t status = vmo_.write(&data, 0, sizeof(data)); status != ZX_OK) {
return status;
}
if (zx_status_t status = partition_->Write(vmo_, block_size_); status != ZX_OK) {
return status;
}
data_ = data;
return ZX_OK;
}
const abr::Data& Data() const override { return data_; }
private:
AbrPartitionClient(std::unique_ptr<PartitionClient> partition, zx::vmo vmo, size_t block_size,
const abr::Data& data)
: partition_(std::move(partition)),
vmo_(std::move(vmo)),
block_size_(block_size),
data_(data) {}
std::unique_ptr<PartitionClient> partition_;
zx::vmo vmo_;
size_t block_size_;
abr::Data data_;
};
// Extracts value from "zvb.current_slot" argument in boot arguments.
std::optional<std::string_view> GetBootSlot(std::string_view boot_args) {
for (size_t begin = 0, end;
(end = boot_args.find_first_of('\0', begin)) != std::string_view::npos; begin = end + 1) {
const size_t sep = boot_args.find_first_of('=', begin);
if (sep + 1 < end) {
std::string_view key(&boot_args[begin], sep - begin);
if (key.compare("zvb.current_slot") == 0) {
return std::string_view(&boot_args[sep + 1], end - (sep + 1));
}
}
}
return std::nullopt;
}
} // namespace
const char* PartitionName(Partition type) {
switch (type) {
case Partition::kBootloader:
return "Bootloader";
case Partition::kZirconA:
return "Zircon A";
case Partition::kZirconB:
return "Zircon B";
case Partition::kZirconR:
return "Zircon R";
case Partition::kVbMetaA:
return "VBMeta A";
case Partition::kVbMetaB:
return "VBMeta B";
case Partition::kVbMetaR:
return "VBMeta R";
case Partition::kFuchsiaVolumeManager:
return "Fuchsia Volume Manager";
default:
return "Unknown";
}
}
fbl::unique_ptr<DevicePartitioner> DevicePartitioner::Create(fbl::unique_fd devfs_root,
zx::channel svc_root, Arch arch,
zx::channel block_device) {
std::optional<fbl::unique_fd> block_dev;
std::optional<fbl::unique_fd> block_dev_dup;
if (block_device) {
int fd;
zx_status_t status = fdio_fd_create(block_device.release(), &fd);
if (status != ZX_OK) {
ERROR(
"Unable to create fd from block_device channel. Does it implement fuchsia.io.Node?: %s\n",
zx_status_get_string(status));
return nullptr;
}
block_dev.emplace(fd);
block_dev_dup = block_dev->duplicate();
}
fbl::unique_ptr<DevicePartitioner> device_partitioner;
if ((SkipBlockDevicePartitioner::Initialize(devfs_root.duplicate(), std::move(svc_root),
&device_partitioner) == ZX_OK) ||
(CrosDevicePartitioner::Initialize(devfs_root.duplicate(), arch, std::move(block_dev_dup),
&device_partitioner) == ZX_OK) ||
(EfiDevicePartitioner::Initialize(devfs_root.duplicate(), arch, std::move(block_dev),
&device_partitioner) == ZX_OK) ||
(FixedDevicePartitioner::Initialize(std::move(devfs_root), &device_partitioner) == ZX_OK)) {
return device_partitioner;
}
return nullptr;
}
/*====================================================*
* GPT Common *
*====================================================*/
bool GptDevicePartitioner::FindGptDevices(const fbl::unique_fd& devfs_root, GptDevices* out) {
fbl::unique_fd d_fd(openat(devfs_root.get(), kBlockDevPath, O_RDONLY));
if (!d_fd) {
ERROR("Cannot inspect block devices\n");
return false;
}
DIR* d = fdopendir(d_fd.release());
if (d == nullptr) {
ERROR("Cannot inspect block devices\n");
return false;
}
const auto closer = fbl::MakeAutoCall([&]() { closedir(d); });
struct dirent* de;
GptDevices found_devices;
while ((de = readdir(d)) != nullptr) {
fbl::unique_fd fd(openat(dirfd(d), de->d_name, O_RDWR));
if (!fd) {
continue;
}
fzl::FdioCaller caller(std::move(fd));
auto result = block::Block::Call::GetInfo(caller.channel());
if (!result.ok()) {
continue;
}
const auto& response = result.value();
if (response.status != ZX_OK) {
continue;
}
if (response.info->flags & BLOCK_FLAG_REMOVABLE) {
continue;
}
auto result2 = ::llcpp::fuchsia::device::Controller::Call::GetTopologicalPath(caller.channel());
if (result2.status() != ZX_OK) {
continue;
}
const auto& response2 = result2.value();
if (response2.status != ZX_OK) {
continue;
}
std::string path_str(response2.path.data(), static_cast<size_t>(response2.path.size()));
// The GPT which will be a non-removable block device that isn't a partition itself.
if (path_str.find("part-") == std::string::npos) {
found_devices.push_back(std::make_pair(path_str, caller.release()));
}
}
if (found_devices.empty()) {
ERROR("No candidate GPT found\n");
return false;
}
*out = std::move(found_devices);
return true;
}
zx_status_t GptDevicePartitioner::InitializeProvidedGptDevice(
fbl::unique_fd devfs_root, fbl::unique_fd gpt_device,
fbl::unique_ptr<GptDevicePartitioner>* gpt_out) {
fzl::UnownedFdioCaller caller(gpt_device.get());
auto result = block::Block::Call::GetInfo(caller.channel());
if (!result.ok()) {
ERROR("Warning: Could not acquire GPT block info: %s\n", zx_status_get_string(result.status()));
return result.status();
}
const auto& response = result.value();
if (response.status != ZX_OK) {
ERROR("Warning: Could not acquire GPT block info: %s\n", zx_status_get_string(response.status));
return response.status;
}
fbl::unique_ptr<GptDevice> gpt;
if (GptDevice::Create(gpt_device.get(), response.info->block_size, response.info->block_count,
&gpt) != ZX_OK) {
ERROR("Failed to get GPT info\n");
return ZX_ERR_BAD_STATE;
}
if (!gpt->Valid()) {
ERROR("Located GPT is invalid; Attempting to initialize\n");
if (gpt->RemoveAllPartitions() != ZX_OK) {
ERROR("Failed to create empty GPT\n");
return ZX_ERR_BAD_STATE;
}
if (gpt->Sync() != ZX_OK) {
ERROR("Failed to sync empty GPT\n");
return ZX_ERR_BAD_STATE;
}
auto result = block::Block::Call::RebindDevice(caller.channel());
if (!result.ok() || result.value().status != ZX_OK) {
ERROR("Failed to re-read GPT\n");
return ZX_ERR_BAD_STATE;
}
}
*gpt_out = WrapUnique(new GptDevicePartitioner(devfs_root.duplicate(), std::move(gpt_device),
std::move(gpt), *(response.info)));
return ZX_OK;
}
zx_status_t GptDevicePartitioner::InitializeGpt(fbl::unique_fd devfs_root, Arch arch,
std::optional<fbl::unique_fd> block_device,
fbl::unique_ptr<GptDevicePartitioner>* gpt_out) {
if (arch != Arch::kX64) {
return ZX_ERR_NOT_FOUND;
}
if (block_device) {
return InitializeProvidedGptDevice(std::move(devfs_root), *std::move(block_device), gpt_out);
}
GptDevices gpt_devices;
if (!FindGptDevices(devfs_root, &gpt_devices)) {
ERROR("Failed to find GPT\n");
return ZX_ERR_NOT_FOUND;
}
std::unique_ptr<GptDevicePartitioner> gpt_partitioner;
for (auto& [_, gpt_device] : gpt_devices) {
fzl::UnownedFdioCaller caller(gpt_device.get());
auto result = block::Block::Call::GetInfo(caller.channel());
if (!result.ok()) {
ERROR("Warning: Could not acquire GPT block info: %s\n",
zx_status_get_string(result.status()));
return result.status();
}
const auto& response = result.value();
if (response.status != ZX_OK) {
ERROR("Warning: Could not acquire GPT block info: %s\n",
zx_status_get_string(response.status));
return response.status;
}
fbl::unique_ptr<GptDevice> gpt;
if (GptDevice::Create(gpt_device.get(), response.info->block_size, response.info->block_count,
&gpt) != ZX_OK) {
ERROR("Failed to get GPT info\n");
return ZX_ERR_BAD_STATE;
}
if (!gpt->Valid()) {
continue;
}
auto partitioner = WrapUnique(new GptDevicePartitioner(
devfs_root.duplicate(), std::move(gpt_device), std::move(gpt), *(response.info)));
if (partitioner->FindPartition(IsFvmPartition, nullptr, nullptr) != ZX_OK) {
continue;
}
if (gpt_partitioner) {
ERROR("Found multiple block devices with valid GPTs. Unsuppported.\n");
return ZX_ERR_NOT_SUPPORTED;
}
gpt_partitioner = std::move(partitioner);
}
if (gpt_partitioner) {
*gpt_out = std::move(gpt_partitioner);
return ZX_OK;
}
ERROR(
"Unable to find a valid GPT on this device with the expected partitions. "
"Please run *one* of the following command(s):\n");
for (const auto& [gpt_path, _] : gpt_devices) {
ERROR("install-disk-image init-partition-tables --block-device %s\n", gpt_path.c_str());
}
return ZX_ERR_NOT_FOUND;
}
struct PartitionPosition {
size_t start; // Block, inclusive
size_t length; // In Blocks
};
zx_status_t GptDevicePartitioner::FindFirstFit(size_t bytes_requested, size_t* start_out,
size_t* length_out) const {
LOG("Looking for space\n");
// Gather GPT-related information.
size_t blocks_requested = (bytes_requested + block_info_.block_size - 1) / block_info_.block_size;
// Sort all partitions by starting block.
// For simplicity, include the 'start' and 'end' reserved spots as
// partitions.
size_t partition_count = 0;
PartitionPosition partitions[gpt::kPartitionCount + 2];
const size_t reserved_blocks = ReservedHeaderBlocks(block_info_.block_size);
partitions[partition_count].start = 0;
partitions[partition_count++].length = reserved_blocks;
partitions[partition_count].start = block_info_.block_count - reserved_blocks;
partitions[partition_count++].length = reserved_blocks;
for (uint32_t i = 0; i < gpt::kPartitionCount; i++) {
const gpt_partition_t* p = gpt_->GetPartition(i);
if (!p) {
continue;
}
partitions[partition_count].start = p->first;
partitions[partition_count].length = p->last - p->first + 1;
LOG("Partition seen with start %zu, end %zu (length %zu)\n", p->first, p->last,
partitions[partition_count].length);
partition_count++;
}
LOG("Sorting\n");
qsort(partitions, partition_count, sizeof(PartitionPosition), [](const void* p1, const void* p2) {
ssize_t s1 = static_cast<ssize_t>(static_cast<const PartitionPosition*>(p1)->start);
ssize_t s2 = static_cast<ssize_t>(static_cast<const PartitionPosition*>(p2)->start);
return static_cast<int>(s1 - s2);
});
// Look for space between the partitions. Since the reserved spots of the
// GPT were included in |partitions|, all available space will be located
// "between" partitions.
for (size_t i = 0; i < partition_count - 1; i++) {
const size_t next = partitions[i].start + partitions[i].length;
LOG("Partition[%zu] From Block [%zu, %zu) ... (next partition starts at block %zu)\n", i,
partitions[i].start, next, partitions[i + 1].start);
if (next > partitions[i + 1].start) {
ERROR("Corrupted GPT\n");
return ZX_ERR_IO;
}
const size_t free_blocks = partitions[i + 1].start - next;
LOG(" There are %zu free blocks (%zu requested)\n", free_blocks, blocks_requested);
if (free_blocks >= blocks_requested) {
*start_out = next;
*length_out = free_blocks;
return ZX_OK;
}
}
ERROR("No GPT space found\n");
return ZX_ERR_NO_RESOURCES;
}
zx_status_t GptDevicePartitioner::CreateGptPartition(const char* name, uint8_t* type,
uint64_t offset, uint64_t blocks,
uint8_t* out_guid) const {
zx_cprng_draw(out_guid, GPT_GUID_LEN);
zx_status_t status;
if ((status = gpt_->AddPartition(name, type, out_guid, offset, blocks, 0)) != ZX_OK) {
ERROR("Failed to add partition\n");
return ZX_ERR_IO;
}
if ((status = gpt_->Sync()) != ZX_OK) {
ERROR("Failed to sync GPT\n");
return ZX_ERR_IO;
}
if ((status = gpt_->ClearPartition(offset, 1)) != ZX_OK) {
ERROR("Failed to clear first block of new partition\n");
return status;
}
auto result = block::Block::Call::RebindDevice(Channel());
if (!result.ok()) {
ERROR("Failed to rebind GPT\n");
return result.status();
}
const auto& response = result.value();
if (response.status != ZX_OK) {
ERROR("Failed to rebind GPT\n");
return response.status;
}
return ZX_OK;
}
zx_status_t GptDevicePartitioner::AddPartition(
const char* name, uint8_t* type, size_t minimum_size_bytes, size_t optional_reserve_bytes,
std::unique_ptr<PartitionClient>* out_partition) const {
uint64_t start, length;
zx_status_t status;
if ((status = FindFirstFit(minimum_size_bytes, &start, &length)) != ZX_OK) {
ERROR("Couldn't find fit\n");
return status;
}
LOG("Found space in GPT - OK %zu @ %zu\n", length, start);
if (optional_reserve_bytes) {
// If we can fulfill the requested size, and we still have space for the
// optional reserve section, then we should shorten the amount of blocks
// we're asking for.
//
// This isn't necessary, but it allows growing the GPT later, if necessary.
const size_t optional_reserve_blocks = optional_reserve_bytes / block_info_.block_size;
if (length - optional_reserve_bytes > (minimum_size_bytes / block_info_.block_size)) {
LOG("Space for reserve - OK\n");
length -= optional_reserve_blocks;
}
} else {
length = fbl::round_up(minimum_size_bytes, block_info_.block_size) / block_info_.block_size;
}
LOG("Final space in GPT - OK %zu @ %zu\n", length, start);
uint8_t guid[GPT_GUID_LEN];
if ((status = CreateGptPartition(name, type, start, length, guid)) != ZX_OK) {
return status;
}
LOG("Added partition, waiting for bind\n");
zx::channel chan;
if ((status = OpenBlockPartition(devfs_root_, guid, type, ZX_SEC(15), &chan)) != ZX_OK) {
ERROR("Added partition, waiting for bind - NOT FOUND\n");
return status;
}
if (out_partition) {
out_partition->reset(new BlockPartitionClient(std::move(chan)));
}
LOG("Added partition, waiting for bind - OK\n");
return ZX_OK;
}
zx_status_t GptDevicePartitioner::FindPartition(FilterCallback filter,
std::unique_ptr<PartitionClient>* out_partition,
gpt_partition_t** out) const {
for (uint32_t i = 0; i < gpt::kPartitionCount; i++) {
gpt_partition_t* p = gpt_->GetPartition(i);
if (!p) {
continue;
}
if (filter(*p)) {
LOG("Found partition in GPT, partition %u\n", i);
if (out) {
*out = p;
}
if (out_partition) {
zx_status_t status;
zx::channel chan;
status = OpenBlockPartition(devfs_root_, p->guid, p->type, ZX_SEC(5), &chan);
if (status != ZX_OK) {
ERROR("Couldn't open partition\n");
return status;
}
out_partition->reset(new BlockPartitionClient(std::move(chan)));
}
return ZX_OK;
}
}
return ZX_ERR_NOT_FOUND;
}
zx_status_t GptDevicePartitioner::WipePartitions(WipeCheck check_cb) const {
bool modify = false;
for (uint32_t i = 0; i < gpt::kPartitionCount; i++) {
const gpt_partition_t* p = gpt_->GetPartition(i);
if (!p) {
continue;
}
if (!check_cb(*p)) {
continue;
}
modify = true;
// Ignore the return status; wiping is a best-effort approach anyway.
WipeBlockPartition(devfs_root_, p->guid, p->type);
if (gpt_->RemovePartition(p->guid) != ZX_OK) {
ERROR("Warning: Could not remove partition\n");
} else {
// If we successfully clear the partition, then all subsequent
// partitions get shifted down. If we just deleted partition 'i',
// we now need to look at partition 'i' again, since it's now
// occupied by what was in 'i+1'.
i--;
}
}
if (modify) {
gpt_->Sync();
LOG("Immediate reboot strongly recommended\n");
}
block::Block::Call::RebindDevice(Channel());
return ZX_OK;
}
zx_status_t GptDevicePartitioner::WipeFvm() const { return WipePartitions(IsFvmPartition); }
zx_status_t GptDevicePartitioner::WipePartitionTables() const {
return WipePartitions([](const gpt_partition_t&) { return true; });
}
/*====================================================*
* EFI SPECIFIC *
*====================================================*/
zx_status_t EfiDevicePartitioner::Initialize(fbl::unique_fd devfs_root, Arch arch,
std::optional<fbl::unique_fd> block_device,
fbl::unique_ptr<DevicePartitioner>* partitioner) {
fbl::unique_ptr<GptDevicePartitioner> gpt;
zx_status_t status = GptDevicePartitioner::InitializeGpt(std::move(devfs_root), arch,
std::move(block_device), &gpt);
if (status != ZX_OK) {
return status;
}
if (is_cros(gpt->GetGpt())) {
ERROR("Use CrOS Device Partitioner.");
return ZX_ERR_NOT_SUPPORTED;
}
LOG("Successfully initialized EFI Device Partitioner\n");
*partitioner = WrapUnique(new EfiDevicePartitioner(std::move(gpt)));
return ZX_OK;
}
zx_status_t EfiDevicePartitioner::AddPartition(
Partition partition_type, std::unique_ptr<PartitionClient>* out_partition) const {
const char* name;
uint8_t type[GPT_GUID_LEN];
size_t minimum_size_bytes = 0;
size_t optional_reserve_bytes = 0;
switch (partition_type) {
case Partition::kBootloader: {
const uint8_t efi_type[GPT_GUID_LEN] = GUID_EFI_VALUE;
memcpy(type, efi_type, GPT_GUID_LEN);
minimum_size_bytes = 20LU * (1 << 20);
name = kEfiName;
break;
}
case Partition::kZirconA: {
const uint8_t zircon_a_type[GPT_GUID_LEN] = GUID_ZIRCON_A_VALUE;
memcpy(type, zircon_a_type, GPT_GUID_LEN);
minimum_size_bytes = 32LU * (1 << 20);
name = kZirconAName;
break;
}
case Partition::kZirconB: {
const uint8_t zircon_b_type[GPT_GUID_LEN] = GUID_ZIRCON_B_VALUE;
memcpy(type, zircon_b_type, GPT_GUID_LEN);
minimum_size_bytes = 32LU * (1 << 20);
name = kZirconBName;
break;
}
case Partition::kZirconR: {
const uint8_t zircon_r_type[GPT_GUID_LEN] = GUID_ZIRCON_R_VALUE;
memcpy(type, zircon_r_type, GPT_GUID_LEN);
minimum_size_bytes = 48LU * (1 << 20);
name = kZirconRName;
break;
}
case Partition::kFuchsiaVolumeManager: {
const uint8_t fvm_type[GPT_GUID_LEN] = GUID_FVM_VALUE;
memcpy(type, fvm_type, GPT_GUID_LEN);
minimum_size_bytes = 8LU * (1 << 30);
name = kFvmPartitionName;
break;
}
default:
ERROR("EFI partitioner cannot add unknown partition type\n");
return ZX_ERR_NOT_SUPPORTED;
}
return gpt_->AddPartition(name, type, minimum_size_bytes, optional_reserve_bytes, out_partition);
}
zx_status_t EfiDevicePartitioner::FindPartition(
Partition partition_type, std::unique_ptr<PartitionClient>* out_partition) const {
switch (partition_type) {
case Partition::kBootloader: {
return gpt_->FindPartition(IsGigabootPartition, out_partition);
}
case Partition::kZirconA: {
const auto filter = [](const gpt_partition_t& part) {
const uint8_t guid[GPT_GUID_LEN] = GUID_ZIRCON_A_VALUE;
return KernelFilterCallback(part, guid, kZirconAName);
};
return gpt_->FindPartition(filter, out_partition);
}
case Partition::kZirconB: {
const auto filter = [](const gpt_partition_t& part) {
const uint8_t guid[GPT_GUID_LEN] = GUID_ZIRCON_B_VALUE;
return KernelFilterCallback(part, guid, kZirconBName);
};
return gpt_->FindPartition(filter, out_partition);
}
case Partition::kZirconR: {
const auto filter = [](const gpt_partition_t& part) {
const uint8_t guid[GPT_GUID_LEN] = GUID_ZIRCON_R_VALUE;
return KernelFilterCallback(part, guid, kZirconRName);
};
return gpt_->FindPartition(filter, out_partition);
}
case Partition::kFuchsiaVolumeManager:
return gpt_->FindPartition(IsFvmPartition, out_partition);
default:
ERROR("EFI partitioner cannot find unknown partition type\n");
return ZX_ERR_NOT_SUPPORTED;
}
}
zx_status_t EfiDevicePartitioner::WipeFvm() const { return gpt_->WipeFvm(); }
zx_status_t EfiDevicePartitioner::WipePartitionTables() const {
return gpt_->WipePartitionTables();
}
/*====================================================*
* CROS SPECIFIC *
*====================================================*/
zx_status_t CrosDevicePartitioner::Initialize(fbl::unique_fd devfs_root, Arch arch,
std::optional<fbl::unique_fd> block_device,
fbl::unique_ptr<DevicePartitioner>* partitioner) {
fbl::unique_ptr<GptDevicePartitioner> gpt_partitioner;
zx_status_t status = GptDevicePartitioner::InitializeGpt(
std::move(devfs_root), arch, std::move(block_device), &gpt_partitioner);
if (status != ZX_OK) {
return status;
}
GptDevice* gpt = gpt_partitioner->GetGpt();
if (!is_cros(gpt)) {
return ZX_ERR_NOT_FOUND;
}
block::BlockInfo info;
gpt_partitioner->GetBlockInfo(&info);
if (!is_ready_to_pave(gpt, reinterpret_cast<fuchsia_hardware_block_BlockInfo*>(&info),
SZ_ZX_PART)) {
status = config_cros_for_fuchsia(
gpt, reinterpret_cast<fuchsia_hardware_block_BlockInfo*>(&info), SZ_ZX_PART);
if (status != ZX_OK) {
ERROR("Failed to configure CrOS for Fuchsia.\n");
return status;
}
if ((status = gpt->Sync()) != ZX_OK) {
ERROR("Failed to sync CrOS for Fuchsia.\n");
return status;
}
block::Block::Call::RebindDevice(gpt_partitioner->Channel());
}
LOG("Successfully initialized CrOS Device Partitioner\n");
*partitioner = WrapUnique(new CrosDevicePartitioner(std::move(gpt_partitioner)));
return ZX_OK;
}
zx_status_t CrosDevicePartitioner::AddPartition(
Partition partition_type, std::unique_ptr<PartitionClient>* out_partition) const {
const char* name;
uint8_t type[GPT_GUID_LEN];
size_t minimum_size_bytes = 0;
size_t optional_reserve_bytes = 0;
switch (partition_type) {
case Partition::kZirconA: {
const uint8_t kernc_type[GPT_GUID_LEN] = GUID_CROS_KERNEL_VALUE;
memcpy(type, kernc_type, GPT_GUID_LEN);
minimum_size_bytes = 64LU * (1 << 20);
name = kZirconAName;
break;
}
case Partition::kZirconR: {
const uint8_t zircon_r_type[GPT_GUID_LEN] = GUID_ZIRCON_R_VALUE;
memcpy(type, zircon_r_type, GPT_GUID_LEN);
minimum_size_bytes = 24LU * (1 << 20);
name = kZirconRName;
break;
}
case Partition::kFuchsiaVolumeManager: {
const uint8_t fvm_type[GPT_GUID_LEN] = GUID_FVM_VALUE;
memcpy(type, fvm_type, GPT_GUID_LEN);
minimum_size_bytes = 8LU * (1 << 30);
name = kFvmPartitionName;
break;
}
default:
ERROR("Cros partitioner cannot add unknown partition type\n");
return ZX_ERR_NOT_SUPPORTED;
}
return gpt_->AddPartition(name, type, minimum_size_bytes, optional_reserve_bytes, out_partition);
}
zx_status_t CrosDevicePartitioner::FindPartition(
Partition partition_type, std::unique_ptr<PartitionClient>* out_partition) const {
switch (partition_type) {
case Partition::kZirconA: {
const auto filter = [](const gpt_partition_t& part) {
const uint8_t guid[GPT_GUID_LEN] = GUID_CROS_KERNEL_VALUE;
return KernelFilterCallback(part, guid, kZirconAName);
};
return gpt_->FindPartition(filter, out_partition);
}
case Partition::kZirconR: {
const auto filter = [](const gpt_partition_t& part) {
const uint8_t guid[GPT_GUID_LEN] = GUID_ZIRCON_R_VALUE;
return KernelFilterCallback(part, guid, kZirconRName);
};
return gpt_->FindPartition(filter, out_partition);
}
case Partition::kFuchsiaVolumeManager:
return gpt_->FindPartition(IsFvmPartition, out_partition);
default:
ERROR("Cros partitioner cannot find unknown partition type\n");
return ZX_ERR_NOT_SUPPORTED;
}
}
zx_status_t CrosDevicePartitioner::FinalizePartition(Partition partition_type) const {
// Special partition finalization is only necessary for Zircon partitions.
if (partition_type != Partition::kZirconA) {
return ZX_OK;
}
uint8_t top_priority = 0;
const uint8_t kern_type[GPT_GUID_LEN] = GUID_CROS_KERNEL_VALUE;
constexpr char kPrefix[] = "ZIRCON-";
uint16_t zircon_prefix[strlen(kPrefix) * 2];
cstring_to_utf16(&zircon_prefix[0], kPrefix, strlen(kPrefix));
for (uint32_t i = 0; i < gpt::kPartitionCount; ++i) {
const gpt_partition_t* part = gpt_->GetGpt()->GetPartition(i);
if (part == NULL) {
continue;
}
if (memcmp(part->type, kern_type, GPT_GUID_LEN)) {
continue;
}
if (memcmp(part->name, zircon_prefix, strlen(kPrefix) * 2)) {
const uint8_t priority = gpt_cros_attr_get_priority(part->flags);
if (priority > top_priority) {
top_priority = priority;
}
}
}
const auto filter_zircona = [](const gpt_partition_t& part) {
const uint8_t guid[GPT_GUID_LEN] = GUID_CROS_KERNEL_VALUE;
return KernelFilterCallback(part, guid, kZirconAName);
};
zx_status_t status;
gpt_partition_t* partition;
if ((status = gpt_->FindPartition(filter_zircona, nullptr, &partition)) != ZX_OK) {
ERROR("Cannot find %s partition\n", kZirconAName);
return status;
}
// Priority for Zircon A set to higher priority than all other kernels.
if (top_priority == UINT8_MAX) {
ERROR("Cannot set CrOS partition priority higher than other kernels\n");
return ZX_ERR_OUT_OF_RANGE;
}
// TODO(raggi): when other (B/R) partitions are paved, set their priority
// appropriately as well.
if (gpt_cros_attr_set_priority(&partition->flags, ++top_priority) != 0) {
ERROR("Cannot set CrOS partition priority for ZIRCON-A\n");
return ZX_ERR_OUT_OF_RANGE;
}
// Successful set to 'true' to encourage the bootloader to
// use this partition.
gpt_cros_attr_set_successful(&partition->flags, true);
// Maximize the number of attempts to boot this partition before
// we fall back to a different kernel.
if (gpt_cros_attr_set_tries(&partition->flags, 15) != 0) {
ERROR("Cannot set CrOS partition 'tries' for KERN-C\n");
return ZX_ERR_OUT_OF_RANGE;
}
if ((status = gpt_->GetGpt()->Sync()) == ZX_OK) {
ERROR("Failed to sync CrOS partition 'tries' for KERN-C.\n");
return status;
}
return ZX_OK;
}
zx_status_t CrosDevicePartitioner::WipeFvm() const { return gpt_->WipeFvm(); }
zx_status_t CrosDevicePartitioner::WipePartitionTables() const {
return gpt_->WipePartitionTables();
}
/*====================================================*
* FIXED PARTITION MAP *
*====================================================*/
zx_status_t FixedDevicePartitioner::Initialize(fbl::unique_fd devfs_root,
fbl::unique_ptr<DevicePartitioner>* partitioner) {
if (HasSkipBlockDevice(devfs_root)) {
return ZX_ERR_NOT_SUPPORTED;
}
LOG("Successfully initialized FixedDevicePartitioner Device Partitioner\n");
*partitioner = WrapUnique(new FixedDevicePartitioner(std::move(devfs_root)));
return ZX_OK;
}
zx_status_t FixedDevicePartitioner::AddPartition(
Partition partition_type, std::unique_ptr<PartitionClient>* out_partition) const {
ERROR("Cannot add partitions to a fixed-map partition device\n");
return ZX_ERR_NOT_SUPPORTED;
}
zx_status_t FixedDevicePartitioner::FindPartition(
Partition partition_type, std::unique_ptr<PartitionClient>* out_partition) const {
uint8_t type[GPT_GUID_LEN];
switch (partition_type) {
case Partition::kZirconA: {
const uint8_t zircon_a_type[GPT_GUID_LEN] = GUID_ZIRCON_A_VALUE;
memcpy(type, zircon_a_type, GPT_GUID_LEN);
break;
}
case Partition::kZirconB: {
const uint8_t zircon_b_type[GPT_GUID_LEN] = GUID_ZIRCON_B_VALUE;
memcpy(type, zircon_b_type, GPT_GUID_LEN);
break;
}
case Partition::kZirconR: {
const uint8_t zircon_r_type[GPT_GUID_LEN] = GUID_ZIRCON_R_VALUE;
memcpy(type, zircon_r_type, GPT_GUID_LEN);
break;
}
case Partition::kVbMetaA: {
const uint8_t vbmeta_a_type[GPT_GUID_LEN] = GUID_VBMETA_A_VALUE;
memcpy(type, vbmeta_a_type, GPT_GUID_LEN);
break;
}
case Partition::kVbMetaB: {
const uint8_t vbmeta_b_type[GPT_GUID_LEN] = GUID_VBMETA_B_VALUE;
memcpy(type, vbmeta_b_type, GPT_GUID_LEN);
break;
}
case Partition::kVbMetaR: {
const uint8_t vbmeta_r_type[GPT_GUID_LEN] = GUID_VBMETA_R_VALUE;
memcpy(type, vbmeta_r_type, GPT_GUID_LEN);
break;
}
case Partition::kFuchsiaVolumeManager: {
const uint8_t fvm_type[GPT_GUID_LEN] = GUID_FVM_VALUE;
memcpy(type, fvm_type, GPT_GUID_LEN);
break;
}
default:
ERROR("partition_type is invalid!\n");
return ZX_ERR_NOT_SUPPORTED;
}
zx::channel chan;
zx_status_t status = OpenBlockPartition(devfs_root_, nullptr, type, ZX_SEC(5), &chan);
if (status != ZX_OK) {
return status;
}
out_partition->reset(new BlockPartitionClient(std::move(chan)));
return ZX_OK;
}
zx_status_t FixedDevicePartitioner::WipeFvm() const {
const uint8_t fvm_type[GPT_GUID_LEN] = GUID_FVM_VALUE;
zx_status_t status;
if ((status = WipeBlockPartition(devfs_root_, nullptr, fvm_type)) != ZX_OK) {
ERROR("Failed to wipe FVM.\n");
} else {
LOG("Wiped FVM successfully.\n");
}
LOG("Immediate reboot strongly recommended\n");
return ZX_OK;
}
zx_status_t FixedDevicePartitioner::WipePartitionTables() const { return ZX_ERR_NOT_SUPPORTED; }
/*====================================================*
* SKIP BLOCK SPECIFIC *
*====================================================*/
zx_status_t SkipBlockDevicePartitioner::Initialize(
fbl::unique_fd devfs_root, zx::channel svc_root,
fbl::unique_ptr<DevicePartitioner>* partitioner) {
if (!HasSkipBlockDevice(devfs_root)) {
return ZX_ERR_NOT_SUPPORTED;
}
LOG("Successfully initialized SkipBlockDevicePartitioner Device Partitioner\n");
*partitioner =
WrapUnique(new SkipBlockDevicePartitioner(std::move(devfs_root), std::move(svc_root)));
return ZX_OK;
}
zx_status_t SkipBlockDevicePartitioner::AddPartition(
Partition partition_type, std::unique_ptr<PartitionClient>* out_partition) const {
ERROR("Cannot add partitions to a skip-block, fixed partition device\n");
return ZX_ERR_NOT_SUPPORTED;
}
zx_status_t SkipBlockDevicePartitioner::FindPartition(
Partition partition_type, std::unique_ptr<PartitionClient>* out_partition) const {
uint8_t type[GPT_GUID_LEN];
switch (partition_type) {
case Partition::kBootloader: {
const uint8_t bootloader_type[GPT_GUID_LEN] = GUID_BOOTLOADER_VALUE;
memcpy(type, bootloader_type, GPT_GUID_LEN);
break;
}
case Partition::kZirconA: {
const uint8_t zircon_a_type[GPT_GUID_LEN] = GUID_ZIRCON_A_VALUE;
memcpy(type, zircon_a_type, GPT_GUID_LEN);
break;
}
case Partition::kZirconB: {
const uint8_t zircon_b_type[GPT_GUID_LEN] = GUID_ZIRCON_B_VALUE;
memcpy(type, zircon_b_type, GPT_GUID_LEN);
break;
}
case Partition::kZirconR: {
const uint8_t zircon_r_type[GPT_GUID_LEN] = GUID_ZIRCON_R_VALUE;
memcpy(type, zircon_r_type, GPT_GUID_LEN);
break;
}
case Partition::kVbMetaA:
case Partition::kVbMetaB:
case Partition::kVbMetaR:
case Partition::kABRMeta: {
const auto type = [&]() {
switch (partition_type) {
case Partition::kVbMetaA:
return sysconfig::SyncClient::PartitionType::kVerifiedBootMetadataA;
case Partition::kVbMetaB:
return sysconfig::SyncClient::PartitionType::kVerifiedBootMetadataB;
case Partition::kVbMetaR:
return sysconfig::SyncClient::PartitionType::kVerifiedBootMetadataR;
case Partition::kABRMeta:
return sysconfig::SyncClient::PartitionType::kABRMetadata;
default:
break;
}
ZX_ASSERT(false);
}();
std::optional<sysconfig::SyncClient> client;
zx_status_t status = sysconfig::SyncClient::Create(devfs_root_, &client);
if (status != ZX_OK) {
return status;
}
out_partition->reset(new SysconfigPartitionClient(*std::move(client), type));
return ZX_OK;
}
case Partition::kFuchsiaVolumeManager: {
const uint8_t fvm_type[GPT_GUID_LEN] = GUID_FVM_VALUE;
memcpy(type, fvm_type, GPT_GUID_LEN);
// FVM partition is managed so it should expose a normal block device.
zx::channel chan;
zx_status_t status = OpenBlockPartition(devfs_root_, nullptr, type, ZX_SEC(5), &chan);
if (status != ZX_OK) {
return status;
}
out_partition->reset(new BlockPartitionClient(std::move(chan)));
return ZX_OK;
}
default:
ERROR("partition_type is invalid!\n");
return ZX_ERR_NOT_SUPPORTED;
}
zx::channel chan;
zx_status_t status = OpenSkipBlockPartition(devfs_root_, type, ZX_SEC(5), &chan);
if (status != ZX_OK) {
return status;
}
out_partition->reset(new SkipBlockPartitionClient(std::move(chan)));
return ZX_OK;
}
zx_status_t SkipBlockDevicePartitioner::WipeFvm() const {
const uint8_t fvm_type[GPT_GUID_LEN] = GUID_FVM_VALUE;
zx::channel chan;
zx_status_t status = OpenBlockPartition(devfs_root_, nullptr, fvm_type, ZX_SEC(3), &chan);
if (status != ZX_OK) {
ERROR("Warning: Could not open partition to wipe: %s\n", zx_status_get_string(status));
return ZX_OK;
}
::llcpp::fuchsia::device::Controller::SyncClient block_client(std::move(chan));
auto result = block_client.GetTopologicalPath();
if (!result.ok()) {
ERROR("Warning: Could not get name for partition: %s\n", zx_status_get_string(result.status()));
return result.status();
}
const auto& response = result.value();
if (response.status != ZX_OK) {
ERROR("Warning: Could not get name for partition: %s\n", zx_status_get_string(response.status));
return response.status;
}
fbl::StringBuffer<PATH_MAX> name_buffer;
name_buffer.Append(response.path.data(), static_cast<size_t>(response.path.size()));
const char* parent = dirname(name_buffer.data());
zx::channel local, remote;
status = zx::channel::create(0, &local, &remote);
if (status != ZX_OK) {
ERROR("Warning: Failed to create channel pair: %s\n", zx_status_get_string(status));
return status;
}
status = fdio_service_connect(parent, remote.release());
if (status != ZX_OK) {
ERROR("Warning: Unable to open block parent device: %s\n", zx_status_get_string(status));
return status;
}
block::Ftl::SyncClient client(std::move(local));
auto result2 = client.Format();
return result2.ok() ? result2.value().status : result2.status();
}
zx_status_t SkipBlockDevicePartitioner::WipePartitionTables() const { return ZX_ERR_NOT_SUPPORTED; }
zx_status_t SkipBlockDevicePartitioner::QueryBootConfig(Configuration* out) {
if (boot_config_.has_value()) {
*out = *boot_config_;
return ZX_OK;
}
zx::channel local, remote;
if (zx_status_t status = zx::channel::create(0, &local, &remote); status != ZX_OK) {
return status;
}
auto status = fdio_service_connect_at(svc_root_.get(), ::llcpp::fuchsia::boot::Arguments::Name,
remote.release());
if (status != ZX_OK) {
return status;
}
::llcpp::fuchsia::boot::Arguments::SyncClient client(std::move(local));
auto result = client.Get();
if (!result.ok()) {
return result.status();
}
const size_t size = result->size;
if (size == 0) {
ERROR("Kernel cmdline param zvb.current_slot not found!\n");
return ZX_ERR_NOT_SUPPORTED;
}
const auto args_buf = std::make_unique<char[]>(size);
if (zx_status_t status = result->vmo.read(args_buf.get(), 0, size); status != ZX_OK) {
return status;
}
const auto slot = GetBootSlot(std::string_view(args_buf.get(), size));
if (!slot.has_value()) {
ERROR("Kernel cmdline param zvb.current_slot not found!\n");
return ZX_ERR_NOT_SUPPORTED;
}
if (slot->compare("-a") == 0) {
*boot_config_ = Configuration::A;
} else if (slot->compare("-b") == 0) {
*boot_config_ = Configuration::B;
} else if (slot->compare("-r") == 0) {
*boot_config_ = Configuration::RECOVERY;
} else {
ERROR("Invalid value `%.*s` found in zvb.current_slot!\n", static_cast<int>(slot->size()),
slot->data());
return ZX_ERR_NOT_SUPPORTED;
}
*out = *boot_config_;
return ZX_OK;
}
zx_status_t SkipBlockDevicePartitioner::SupportsVerfiedBoot() {
Configuration config;
if (zx_status_t status = QueryBootConfig(&config); status != ZX_OK) {
return status;
}
return ZX_OK;
}
zx_status_t SkipBlockDevicePartitioner::GetAbrClient(std::unique_ptr<abr::Client>* client) {
if (zx_status_t status = SupportsVerfiedBoot(); status != ZX_OK) {
return status;
}
std::unique_ptr<PartitionClient> partition;
if (zx_status_t status = FindPartition(Partition::kABRMeta, &partition); status != ZX_OK) {
return status;
}
return AbrPartitionClient::Create(std::move(partition), client);
}
} // namespace paver