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ladybird/Kernel/Storage/StorageManagement.cpp
Liav A 4744ccbff0 Kernel/Storage: Add LUN address to each StorageDevice 
LUN address is essentially how people used to address SCSI devices back
in the day we had these devices more in use. However, SCSI was taken as
an abstraction layer for many Unix and Unix-like systems, so it still
common to see LUN addresses in use. In Serenity, we don't really provide
such abstraction layer, and therefore until now, we didn't use LUNs too.
However (again), this changes, as we want to let users to address their
devices under SysFS easily. LUNs make sense in that regard, because they
can be easily adapted to different interfaces besides SCSI.
For example, for legacy ATA hard drive being connected to the first IDE
controller which was enumerated on the PCI bus, and then to the primary
channel as slave device, the LUN address would be 0:0:1.

To make this happen, we add unique ID number to each StorageController,
which increments by 1 for each new instance of StorageController. Then,
we adapt the ATA and NVMe devices to use these numbers and generate LUN
in the construction time.
2022-07-15 12:29:23 +02:00

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/*
* Copyright (c) 2020-2022, Liav A. <liavalb@hotmail.co.il>
* Copyright (c) 2022, the SerenityOS developers.
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/IterationDecision.h>
#include <AK/Singleton.h>
#include <AK/StringView.h>
#include <AK/UUID.h>
#include <Kernel/Bus/PCI/API.h>
#include <Kernel/Bus/PCI/Access.h>
#include <Kernel/Bus/PCI/Controller/VolumeManagementDevice.h>
#include <Kernel/CommandLine.h>
#include <Kernel/Devices/BlockDevice.h>
#include <Kernel/FileSystem/Ext2FileSystem.h>
#include <Kernel/Panic.h>
#include <Kernel/Storage/ATA/AHCIController.h>
#include <Kernel/Storage/ATA/ISAIDEController.h>
#include <Kernel/Storage/ATA/PCIIDEController.h>
#include <Kernel/Storage/NVMe/NVMeController.h>
#include <Kernel/Storage/Partition/EBRPartitionTable.h>
#include <Kernel/Storage/Partition/GUIDPartitionTable.h>
#include <Kernel/Storage/Partition/MBRPartitionTable.h>
#include <Kernel/Storage/Ramdisk/Controller.h>
#include <Kernel/Storage/StorageManagement.h>
namespace Kernel {
static Singleton<StorageManagement> s_the;
static Atomic<u32> s_device_minor_number;
static Atomic<u32> s_controller_id;
static constexpr StringView partition_uuid_prefix = "PARTUUID:"sv;
UNMAP_AFTER_INIT StorageManagement::StorageManagement()
{
}
void StorageManagement::remove_device(StorageDevice& device)
{
m_storage_devices.remove(device);
}
bool StorageManagement::boot_argument_contains_partition_uuid()
{
return m_boot_argument.starts_with(partition_uuid_prefix);
}
UNMAP_AFTER_INIT void StorageManagement::enumerate_pci_controllers(bool force_pio, bool nvme_poll)
{
VERIFY(m_controllers.is_empty());
using SubclassID = PCI::MassStorage::SubclassID;
if (!kernel_command_line().disable_physical_storage()) {
MUST(PCI::enumerate([&](PCI::DeviceIdentifier const& device_identifier) -> void {
if (device_identifier.class_code().value() != to_underlying(PCI::ClassID::MassStorage)) {
return;
}
{
constexpr PCI::HardwareID vmd_device = { 0x8086, 0x9a0b };
if (device_identifier.hardware_id() == vmd_device) {
auto controller = PCI::VolumeManagementDevice::must_create(device_identifier);
MUST(PCI::Access::the().add_host_controller_and_enumerate_attached_devices(move(controller), [this, nvme_poll](PCI::DeviceIdentifier const& device_identifier) -> void {
auto subclass_code = static_cast<SubclassID>(device_identifier.subclass_code().value());
if (subclass_code == SubclassID::NVMeController) {
auto controller = NVMeController::try_initialize(device_identifier, nvme_poll);
if (controller.is_error()) {
dmesgln("Unable to initialize NVMe controller: {}", controller.error());
} else {
m_controllers.append(controller.release_value());
}
}
}));
}
}
auto subclass_code = static_cast<SubclassID>(device_identifier.subclass_code().value());
if (subclass_code == SubclassID::IDEController && kernel_command_line().is_ide_enabled()) {
m_controllers.append(PCIIDEController::initialize(device_identifier, force_pio));
}
if (subclass_code == SubclassID::SATAController
&& device_identifier.prog_if().value() == to_underlying(PCI::MassStorage::SATAProgIF::AHCI)) {
m_controllers.append(AHCIController::initialize(device_identifier));
}
if (subclass_code == SubclassID::NVMeController) {
auto controller = NVMeController::try_initialize(device_identifier, nvme_poll);
if (controller.is_error()) {
dmesgln("Unable to initialize NVMe controller: {}", controller.error());
} else {
m_controllers.append(controller.release_value());
}
}
}));
}
}
UNMAP_AFTER_INIT void StorageManagement::enumerate_storage_devices()
{
VERIFY(!m_controllers.is_empty());
for (auto& controller : m_controllers) {
for (size_t device_index = 0; device_index < controller.devices_count(); device_index++) {
auto device = controller.device(device_index);
if (device.is_null())
continue;
m_storage_devices.append(device.release_nonnull());
}
}
}
UNMAP_AFTER_INIT void StorageManagement::dump_storage_devices_and_partitions() const
{
dbgln("StorageManagement: Detected {} storage devices", m_storage_devices.size_slow());
for (auto const& storage_device : m_storage_devices) {
auto const& partitions = storage_device.partitions();
if (partitions.is_empty()) {
dbgln(" Device: {} (no partitions)", storage_device.early_storage_name());
} else {
dbgln(" Device: {} ({} partitions)", storage_device.early_storage_name(), partitions.size());
unsigned partition_number = 1;
for (auto const& partition : partitions) {
dbgln(" Partition: {} (UUID {})", partition_number, partition.metadata().unique_guid().to_string());
partition_number++;
}
}
}
}
UNMAP_AFTER_INIT ErrorOr<NonnullOwnPtr<PartitionTable>> StorageManagement::try_to_initialize_partition_table(StorageDevice const& device) const
{
auto mbr_table_or_error = MBRPartitionTable::try_to_initialize(device);
if (!mbr_table_or_error.is_error())
return mbr_table_or_error.release_value();
auto ebr_table_or_error = EBRPartitionTable::try_to_initialize(device);
if (!ebr_table_or_error.is_error()) {
return ebr_table_or_error.release_value();
}
return TRY(GUIDPartitionTable::try_to_initialize(device));
}
UNMAP_AFTER_INIT void StorageManagement::enumerate_disk_partitions()
{
VERIFY(!m_storage_devices.is_empty());
size_t device_index = 0;
for (auto& device : m_storage_devices) {
auto partition_table_or_error = try_to_initialize_partition_table(device);
if (partition_table_or_error.is_error())
continue;
auto partition_table = partition_table_or_error.release_value();
for (size_t partition_index = 0; partition_index < partition_table->partitions_count(); partition_index++) {
auto partition_metadata = partition_table->partition(partition_index);
if (!partition_metadata.has_value())
continue;
// FIXME: Try to not hardcode a maximum of 16 partitions per drive!
auto disk_partition = DiskPartition::create(device, (partition_index + (16 * device_index)), partition_metadata.value());
device.add_partition(disk_partition);
}
device_index++;
}
}
UNMAP_AFTER_INIT void StorageManagement::determine_boot_device()
{
VERIFY(!m_controllers.is_empty());
if (m_boot_argument.starts_with("/dev/"sv)) {
StringView storage_name = m_boot_argument.substring_view(5);
for (auto& storage_device : m_storage_devices) {
if (storage_device.early_storage_name() == storage_name) {
m_boot_block_device = storage_device;
break;
}
// If the early storage name's last character is a digit (e.g. in the case of NVMe where the last
// number in the device name indicates the node, e.g. /dev/nvme0n1 we need to append a "p" character
// so that we can properly distinguish the partition index from the device itself
char storage_name_last_char = *(storage_device.early_storage_name().end() - 1);
OwnPtr<KString> normalized_name;
StringView early_storage_name;
if (storage_name_last_char >= '0' && storage_name_last_char <= '9') {
normalized_name = MUST(KString::formatted("{}p", storage_device.early_storage_name()));
early_storage_name = normalized_name->view();
} else {
early_storage_name = storage_device.early_storage_name();
}
auto start_storage_name = storage_name.substring_view(0, min(early_storage_name.length(), storage_name.length()));
if (early_storage_name.starts_with(start_storage_name)) {
StringView partition_sign = storage_name.substring_view(start_storage_name.length());
auto possible_partition_number = partition_sign.to_uint<size_t>();
if (!possible_partition_number.has_value())
break;
if (possible_partition_number.value() == 0)
break;
if (storage_device.partitions().size() < possible_partition_number.value())
break;
m_boot_block_device = storage_device.partitions()[possible_partition_number.value() - 1];
break;
}
}
}
if (m_boot_block_device.is_null()) {
dump_storage_devices_and_partitions();
PANIC("StorageManagement: boot device {} not found", m_boot_argument);
}
}
UNMAP_AFTER_INIT void StorageManagement::determine_boot_device_with_partition_uuid()
{
VERIFY(!m_storage_devices.is_empty());
VERIFY(m_boot_argument.starts_with(partition_uuid_prefix));
auto partition_uuid = UUID(m_boot_argument.substring_view(partition_uuid_prefix.length()), UUID::Endianness::Mixed);
for (auto& storage_device : m_storage_devices) {
for (auto& partition : storage_device.partitions()) {
if (partition.metadata().unique_guid().is_zero())
continue;
if (partition.metadata().unique_guid() == partition_uuid) {
m_boot_block_device = partition;
break;
}
}
}
}
RefPtr<BlockDevice> StorageManagement::boot_block_device() const
{
return m_boot_block_device.strong_ref();
}
MajorNumber StorageManagement::storage_type_major_number()
{
return 3;
}
MinorNumber StorageManagement::generate_storage_minor_number()
{
auto minor_number = s_device_minor_number.load();
s_device_minor_number++;
return minor_number;
}
u32 StorageManagement::generate_controller_id()
{
auto controller_id = s_controller_id.load();
s_controller_id++;
return controller_id;
}
NonnullRefPtr<FileSystem> StorageManagement::root_filesystem() const
{
auto boot_device_description = boot_block_device();
if (!boot_device_description) {
dump_storage_devices_and_partitions();
PANIC("StorageManagement: Couldn't find a suitable device to boot from");
}
auto description_or_error = OpenFileDescription::try_create(boot_device_description.release_nonnull());
VERIFY(!description_or_error.is_error());
auto file_system = Ext2FS::try_create(description_or_error.release_value()).release_value();
if (auto result = file_system->initialize(); result.is_error()) {
dump_storage_devices_and_partitions();
PANIC("StorageManagement: Couldn't open root filesystem: {}", result.error());
}
return file_system;
}
UNMAP_AFTER_INIT void StorageManagement::initialize(StringView root_device, bool force_pio, bool poll)
{
VERIFY(s_device_minor_number == 0);
m_boot_argument = root_device;
if (PCI::Access::is_disabled()) {
// Note: If PCI is disabled, we assume that at least we have an ISA IDE controller
// to probe and use
m_controllers.append(ISAIDEController::initialize());
} else {
enumerate_pci_controllers(force_pio, poll);
}
// Note: Whether PCI bus is present on the system or not, always try to attach
// a given ramdisk.
m_controllers.append(RamdiskController::initialize());
enumerate_storage_devices();
enumerate_disk_partitions();
if (!boot_argument_contains_partition_uuid()) {
determine_boot_device();
return;
}
determine_boot_device_with_partition_uuid();
}
StorageManagement& StorageManagement::the()
{
return *s_the;
}
}
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