blob: 6769bd1f6b7e3f0d77ec21cd04b10ea6958dc493 [file] [log] [blame]
// Copyright 2017 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 <errno.h>
#include <fidl/fuchsia.device/cpp/wire.h>
#include <fidl/fuchsia.hardware.block.partition/cpp/wire.h>
#include <fidl/fuchsia.hardware.block.volume/cpp/wire.h>
#include <fidl/fuchsia.hardware.block/cpp/wire.h>
#include <fidl/fuchsia.io/cpp/wire.h>
#include <fuchsia/hardware/block/driver/c/banjo.h>
#include <lib/async-loop/cpp/loop.h>
#include <lib/async-loop/default.h>
#include <lib/component/incoming/cpp/clone.h>
#include <lib/component/incoming/cpp/protocol.h>
#include <lib/device-watcher/cpp/device-watcher.h>
#include <lib/driver-integration-test/fixture.h>
#include <lib/fdio/cpp/caller.h>
#include <lib/fdio/directory.h>
#include <lib/fdio/namespace.h>
#include <lib/fit/function.h>
#include <lib/zircon-internal/thread_annotations.h>
#include <lib/zx/channel.h>
#include <lib/zx/fifo.h>
#include <lib/zx/vmo.h>
#include <poll.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <threads.h>
#include <time.h>
#include <unistd.h>
#include <utime.h>
#include <zircon/errors.h>
#include <zircon/status.h>
#include <zircon/syscalls.h>
#include <algorithm>
#include <climits>
#include <iterator>
#include <limits>
#include <memory>
#include <new>
#include <utility>
#include <fbl/algorithm.h>
#include <fbl/auto_lock.h>
#include <fbl/ref_counted.h>
#include <fbl/ref_ptr.h>
#include <fbl/string.h>
#include <fbl/unique_fd.h>
#include <fbl/vector.h>
#include <ramdevice-client/ramdisk.h>
#include <zxtest/zxtest.h>
#include "lib/fidl/cpp/wire/internal/transport_channel.h"
#include "src/lib/fxl/strings/string_printf.h"
#include "src/storage/blobfs/format.h"
#include "src/storage/fvm/format.h"
#include "src/storage/fvm/fvm_check.h"
#include "src/storage/lib/block_client/cpp/client.h"
#include "src/storage/lib/block_client/cpp/remote_block_device.h"
#include "src/storage/lib/fs_management/cpp/admin.h"
#include "src/storage/lib/fs_management/cpp/fvm.h"
#include "src/storage/lib/fs_management/cpp/mount.h"
#include "src/storage/minfs/format.h"
constexpr char kFvmDriverLib[] = "fvm.cm";
#define STRLEN(s) (sizeof(s) / sizeof((s)[0]))
namespace {
using VolumeManagerInfo = fuchsia_hardware_block_volume::wire::VolumeManagerInfo;
constexpr char kMountPath[] = "/test/minfs_test_mountpath";
constexpr char kTestDevPath[] = "/fake/dev";
// Returns the number of usable slices for a standard layout on a given-sized device.
size_t UsableSlicesCount(size_t disk_size, size_t slice_size) {
return fvm::Header::FromDiskSize(fvm::kMaxUsablePartitions, disk_size, slice_size)
.GetAllocationTableUsedEntryCount();
}
struct PartitionChannel {
fidl::UnownedClientEnd<fuchsia_hardware_block::Block> as_block() {
return fidl::UnownedClientEnd<fuchsia_hardware_block::Block>(partition.channel().borrow());
}
fidl::UnownedClientEnd<fuchsia_hardware_block_volume::Volume> as_volume() {
return fidl::UnownedClientEnd<fuchsia_hardware_block_volume::Volume>(
partition.channel().borrow());
}
static zx::result<PartitionChannel> Create(
fidl::ClientEnd<fuchsia_device::Controller> controller) {
PartitionChannel partition;
partition.controller = std::move(controller);
zx::result partition_server = fidl::CreateEndpoints(&partition.partition);
if (partition_server.is_error()) {
return partition_server.take_error();
}
if (fidl::OneWayStatus status = fidl::WireCall(partition.controller)
->ConnectToDeviceFidl(partition_server->TakeChannel());
!status.ok()) {
return zx::error(status.status());
}
return zx::ok(std::move(partition));
}
fidl::ClientEnd<fuchsia_device::Controller> controller;
fidl::ClientEnd<fuchsia_hardware_block_partition::Partition> partition;
};
using driver_integration_test::IsolatedDevmgr;
class FvmTest : public zxtest::Test {
protected:
void SetUp() override {
IsolatedDevmgr::Args args;
args.disable_block_watcher = true;
ASSERT_OK(IsolatedDevmgr::Create(&args, &devmgr_));
ASSERT_OK(device_watcher::RecursiveWaitForFile(devfs_root_fd().get(),
"sys/platform/00:00:2d/ramctl"));
fdio_ns_t* name_space;
ASSERT_OK(fdio_ns_get_installed(&name_space));
ASSERT_OK(fdio_ns_bind_fd(name_space, kTestDevPath, devmgr_.devfs_root().get()));
}
const fbl::unique_fd& devfs_root_fd() const { return devmgr_.devfs_root(); }
zx::result<fidl::ClientEnd<fuchsia_io::Directory>> devfs_root() const {
fdio_cpp::UnownedFdioCaller caller(devfs_root_fd());
return component::Clone(caller.directory());
}
void TearDown() override {
fdio_ns_t* name_space;
ASSERT_OK(fdio_ns_get_installed(&name_space));
ASSERT_OK(fdio_ns_unbind(name_space, kTestDevPath));
ASSERT_OK(ramdisk_destroy(ramdisk_));
}
fbl::String fvm_path() const { return fxl::StringPrintf("%s/fvm", ramdisk_get_path(ramdisk_)); }
zx::result<fbl::unique_fd> fvm_device_fd() const {
fbl::unique_fd fd;
zx_status_t status =
fdio_open_fd_at(devfs_root_fd().get(), fvm_path().c_str(), 0, fd.reset_and_get_address());
return zx::make_result(status, std::move(fd));
}
zx::result<fidl::ClientEnd<fuchsia_hardware_block_volume::VolumeManager>> fvm_device() const {
zx::result devfs = devfs_root();
if (devfs.is_error()) {
return devfs.take_error();
}
return component::ConnectAt<fuchsia_hardware_block_volume::VolumeManager>(devfs.value(),
fvm_path().c_str());
}
fidl::UnownedClientEnd<fuchsia_device::Controller> ramdisk_controller_interface() const {
return fidl::UnownedClientEnd<fuchsia_device::Controller>(
ramdisk_get_block_controller_interface(ramdisk_));
}
fidl::UnownedClientEnd<fuchsia_hardware_block::Block> ramdisk_block_interface() const {
return fidl::UnownedClientEnd<fuchsia_hardware_block::Block>(
ramdisk_get_block_interface(ramdisk_));
}
const ramdisk_client* ramdisk() const { return ramdisk_; }
void FVMRebind();
void CreateFVM(uint64_t block_size, uint64_t block_count, uint64_t slice_size);
void CreateRamdisk(uint64_t block_size, uint64_t block_count);
zx::result<PartitionChannel> OpenPartition(const fs_management::PartitionMatcher& matcher) const {
zx::result controller =
fs_management::OpenPartitionWithDevfs(devfs_root().value(), matcher, false);
if (controller.is_error()) {
return controller.take_error();
}
return PartitionChannel::Create(std::move(controller.value()));
}
zx::result<PartitionChannel> WaitForPartition(
const fs_management::PartitionMatcher& matcher) const {
zx::result controller =
fs_management::OpenPartitionWithDevfs(devfs_root().value(), matcher, true);
if (controller.is_error()) {
return controller.take_error();
}
return PartitionChannel::Create(std::move(controller.value()));
}
struct AllocatePartitionRequest {
size_t slice_count = 1;
const uuid::Uuid& type;
const uuid::Uuid& guid;
const std::string_view& name;
uint32_t flags = 0;
};
zx::result<PartitionChannel> AllocatePartition(AllocatePartitionRequest request) const {
zx::result fvm = fvm_device();
if (fvm.is_error()) {
return fvm.take_error();
}
zx::result devfs = devfs_root();
if (devfs.is_error()) {
return devfs.take_error();
}
zx::result controller = fs_management::FvmAllocatePartitionWithDevfs(
*devfs, *fvm, request.slice_count, request.type, request.guid, request.name, request.flags);
if (controller.is_error()) {
return controller.take_error();
}
return PartitionChannel::Create(std::move(controller.value()));
}
private:
IsolatedDevmgr devmgr_;
ramdisk_client_t* ramdisk_ = nullptr;
};
void FvmTest::CreateRamdisk(uint64_t block_size, uint64_t block_count) {
if (ramdisk_ != nullptr) {
ramdisk_destroy(ramdisk_);
}
ASSERT_OK(ramdisk_create_at(devfs_root_fd().get(), block_size, block_count, &ramdisk_));
}
void FvmTest::CreateFVM(uint64_t block_size, uint64_t block_count, uint64_t slice_size) {
CreateRamdisk(block_size, block_count);
ASSERT_OK(fs_management::FvmInitPreallocated(ramdisk_block_interface(), block_count * block_size,
block_count * block_size, slice_size));
auto resp = fidl::WireCall(ramdisk_controller_interface())->Bind(kFvmDriverLib);
ASSERT_OK(resp.status());
ASSERT_TRUE(resp->is_ok());
ASSERT_OK(device_watcher::RecursiveWaitForFile(devfs_root_fd().get(), fvm_path().c_str()));
}
void FvmTest::FVMRebind() {
auto resp = fidl::WireCall(ramdisk_controller_interface())->Rebind(kFvmDriverLib);
ASSERT_OK(resp.status());
ASSERT_TRUE(resp->is_ok());
ASSERT_OK(device_watcher::RecursiveWaitForFile(devfs_root_fd().get(), fvm_path().c_str()));
}
void FVMCheckSliceSize(fidl::UnownedClientEnd<fuchsia_hardware_block_volume::VolumeManager> fvm,
size_t expected_slice_size) {
auto volume_info_or = fs_management::FvmQuery(fvm);
ASSERT_EQ(volume_info_or.status_value(), ZX_OK, "Failed to query fvm\n");
ASSERT_EQ(expected_slice_size, volume_info_or->slice_size, "Unexpected slice size\n");
}
void FVMCheckAllocatedCount(
fidl::UnownedClientEnd<fuchsia_hardware_block_volume::VolumeManager> fvm,
size_t expected_allocated, size_t expected_total) {
auto volume_info_or = fs_management::FvmQuery(fvm);
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
ASSERT_EQ(volume_info_or->slice_count, expected_total);
ASSERT_EQ(volume_info_or->assigned_slice_count, expected_allocated);
}
enum class ValidationResult {
Valid,
Corrupted,
};
void ValidateFVM(fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device,
ValidationResult expected_result = ValidationResult::Valid) {
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
fvm::Checker checker(device, block_info.block_size, true);
switch (expected_result) {
case ValidationResult::Valid:
ASSERT_TRUE(checker.Validate());
break;
case ValidationResult::Corrupted:
ASSERT_FALSE(checker.Validate());
break;
}
}
zx::result<std::string> GetPartitionPath(fidl::ClientEnd<fuchsia_device::Controller>& controller) {
auto path = fidl::WireCall(controller)->GetTopologicalPath();
if (!path.ok()) {
return zx::error(path.status());
}
if (path->is_error()) {
return zx::error(path->error_value());
}
// The partition doesn't know that the devmgr it's in is bound at "/fake".
std::string topological_path = std::string("/fake") + path->value()->path.data();
return zx::ok(std::move(topological_path));
}
/////////////////////// Helper functions, definitions
constexpr uuid::Uuid kTestUniqueGuid1 = {0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f};
constexpr uuid::Uuid kTestUniqueGuid2 = {0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17,
0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f};
// Intentionally avoid aligning these GUIDs with
// the actual system GUIDs; otherwise, limited versions
// of Fuchsia may attempt to actually mount these
// partitions automatically.
constexpr std::string_view kTestPartDataName = "data";
constexpr uuid::Uuid kTestPartDataGuid = {
0xAA, 0xFF, 0xBB, 0x00, 0x33, 0x44, 0x88, 0x99, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17,
};
constexpr std::string_view kTestPartBlobName = "blob";
constexpr uuid::Uuid kTestPartBlobGuid = {
0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0xAA, 0xFF, 0xBB, 0x00, 0x33, 0x44, 0x88, 0x99,
};
constexpr std::string_view kTestPartSystemName = "system";
constexpr uuid::Uuid kTestPartSystemGuid = {
0xEE, 0xFF, 0xBB, 0x00, 0x33, 0x44, 0x88, 0x99, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17,
};
const fs_management::PartitionMatcher kPartition1Matcher = {
.type_guids = {kTestPartDataGuid},
.instance_guids = {kTestUniqueGuid1},
};
const fs_management::PartitionMatcher kPartition2Matcher = {
.type_guids = {kTestPartDataGuid},
.instance_guids = {kTestUniqueGuid2},
};
class VmoBuf;
class VmoClient : public fbl::RefCounted<VmoClient> {
public:
explicit VmoClient(fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device);
~VmoClient() = default;
void CheckWrite(VmoBuf& vbuf, size_t buf_off, size_t dev_off, size_t len);
void CheckRead(VmoBuf& vbuf, size_t buf_off, size_t dev_off, size_t len);
void Transaction(block_fifo_request_t* requests, size_t count) {
ASSERT_OK(client_->Transaction(requests, count));
}
zx::result<storage::OwnedVmoid> RegisterVmo(const zx::vmo& vmo) {
return client_->RegisterVmo(vmo);
}
fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device() const { return device_; }
static groupid_t group() { return 0; }
private:
const fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device_;
uint32_t block_size_;
std::unique_ptr<block_client::Client> client_;
};
class VmoBuf {
public:
VmoBuf(fbl::RefPtr<VmoClient> client, size_t size) : client_(std::move(client)) {
buf_ = std::make_unique<uint8_t[]>(size);
ASSERT_EQ(zx::vmo::create(size, 0, &vmo_), ZX_OK);
zx::result vmoid = client_->RegisterVmo(vmo_);
ASSERT_OK(vmoid);
vmoid_ = std::move(vmoid.value());
}
~VmoBuf() {
if (vmo_.is_valid()) {
block_fifo_request_t request = {
.command = {.opcode = BLOCK_OPCODE_CLOSE_VMO, .flags = 0},
.group = client_->group(),
.vmoid = vmoid_.TakeId(),
};
client_->Transaction(&request, 1);
}
}
private:
friend VmoClient;
fbl::RefPtr<VmoClient> client_;
zx::vmo vmo_;
std::unique_ptr<uint8_t[]> buf_;
storage::OwnedVmoid vmoid_;
};
VmoClient::VmoClient(fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device)
: device_(device) {
{
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
block_size_ = response.value()->info.block_size;
}
zx::result endpoints = fidl::CreateEndpoints<fuchsia_hardware_block::Session>();
ASSERT_OK(endpoints);
auto& [session, server] = endpoints.value();
const fidl::Status result = fidl::WireCall(device)->OpenSession(std::move(server));
ASSERT_OK(result.status());
const fidl::WireResult fifo_result = fidl::WireCall(session)->GetFifo();
ASSERT_OK(fifo_result.status());
const fit::result fifo_response = fifo_result.value();
ASSERT_TRUE(fifo_response.is_ok(), "%s", zx_status_get_string(fifo_response.error_value()));
client_ = std::make_unique<block_client::Client>(std::move(session),
std::move(fifo_response.value()->fifo));
}
void VmoClient::CheckWrite(VmoBuf& vbuf, size_t buf_off, size_t dev_off, size_t len) {
// Write to the client-side buffer
for (size_t i = 0; i < len; i++)
vbuf.buf_[i + buf_off] = static_cast<uint8_t>(rand());
// Write to the registered VMO
ASSERT_EQ(vbuf.vmo_.write(&vbuf.buf_[buf_off], buf_off, len), ZX_OK);
ASSERT_EQ(len % block_size_, 0);
ASSERT_EQ(buf_off % block_size_, 0);
ASSERT_EQ(dev_off % block_size_, 0);
// Write to the block device
block_fifo_request_t request = {
.command = {.opcode = BLOCK_OPCODE_WRITE, .flags = 0},
.group = group(),
.vmoid = vbuf.vmoid_.get(),
.length = static_cast<uint32_t>(len / block_size_),
.vmo_offset = buf_off / block_size_,
.dev_offset = dev_off / block_size_,
};
Transaction(&request, 1);
}
void VmoClient::CheckRead(VmoBuf& vbuf, size_t buf_off, size_t dev_off, size_t len) {
// Create a comparison buffer
fbl::AllocChecker ac;
std::unique_ptr<uint8_t[]> out(new (&ac) uint8_t[len]);
ASSERT_TRUE(ac.check());
memset(out.get(), 0, len);
ASSERT_EQ(len % block_size_, 0);
ASSERT_EQ(buf_off % block_size_, 0);
ASSERT_EQ(dev_off % block_size_, 0);
// Read from the block device
block_fifo_request_t request = {
.command = {.opcode = BLOCK_OPCODE_READ, .flags = 0},
.group = group(),
.vmoid = vbuf.vmoid_.get(),
.length = static_cast<uint32_t>(len / block_size_),
.vmo_offset = buf_off / block_size_,
.dev_offset = dev_off / block_size_,
};
Transaction(&request, 1);
// Read from the registered VMO
ASSERT_EQ(vbuf.vmo_.read(out.get(), buf_off, len), ZX_OK);
ASSERT_EQ(memcmp(&vbuf.buf_[buf_off], out.get(), len), 0);
}
void CheckWrite(fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device, size_t off,
size_t len, uint8_t* buf) {
for (size_t i = 0; i < len; i++) {
buf[i] = static_cast<uint8_t>(rand());
}
ASSERT_OK(block_client::SingleWriteBytes(device, buf, len, off));
}
void CheckRead(fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device, size_t off, size_t len,
const uint8_t* in) {
fbl::AllocChecker ac;
std::unique_ptr<uint8_t[]> out(new (&ac) uint8_t[len]);
ASSERT_TRUE(ac.check());
memset(out.get(), 0, len);
ASSERT_OK(block_client::SingleReadBytes(device, out.get(), len, off));
ASSERT_EQ(memcmp(in, out.get(), len), 0);
}
void CheckWriteReadBlock(fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device, size_t block,
size_t count) {
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
size_t len = block_info.block_size * count;
size_t off = block_info.block_size * block;
std::unique_ptr<uint8_t[]> in(new uint8_t[len]);
ASSERT_NO_FATAL_FAILURE(CheckWrite(device, off, len, in.get()));
ASSERT_NO_FATAL_FAILURE(CheckRead(device, off, len, in.get()));
}
void CheckWriteReadBytesFifo(fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device,
size_t off, size_t len) {
std::unique_ptr<uint8_t[]> write_buf(new uint8_t[len]);
memset(write_buf.get(), 0xa3, len);
ASSERT_OK(block_client::SingleWriteBytes(device, write_buf.get(), len, off));
std::unique_ptr<uint8_t[]> read_buf(new uint8_t[len]);
memset(read_buf.get(), 0, len);
ASSERT_OK(block_client::SingleReadBytes(device, read_buf.get(), len, off));
EXPECT_EQ(memcmp(write_buf.get(), read_buf.get(), len), 0);
}
void CheckNoAccessBlock(fidl::UnownedClientEnd<fuchsia_hardware_block::Block> device, size_t block,
size_t count) {
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
size_t len = block_info.block_size * count;
size_t off = block_info.block_size * block;
std::unique_ptr<uint8_t[]> buf(new uint8_t[len]);
for (size_t i = 0; i < len; i++) {
buf[i] = static_cast<uint8_t>(rand());
}
ASSERT_STATUS(block_client::SingleWriteBytes(device, buf.get(), len, off), ZX_ERR_OUT_OF_RANGE);
ASSERT_STATUS(block_client::SingleReadBytes(device, buf.get(), len, off), ZX_ERR_OUT_OF_RANGE);
}
void CheckDeadConnection(zx::channel& chan) {
ASSERT_OK(chan.wait_one(ZX_CHANNEL_PEER_CLOSED, zx::time::infinite(), nullptr));
}
void Upgrade(fidl::UnownedClientEnd<fuchsia_hardware_block_volume::VolumeManager> fvm,
const uuid::Uuid& old_guid, const uuid::Uuid& new_guid, zx_status_t status) {
fuchsia_hardware_block_partition::wire::Guid old_guid_fidl;
std::copy(old_guid.cbegin(), old_guid.cend(), old_guid_fidl.value.begin());
fuchsia_hardware_block_partition::wire::Guid new_guid_fidl;
std::copy(new_guid.cbegin(), new_guid.cend(), new_guid_fidl.value.begin());
const fidl::WireResult result = fidl::WireCall(fvm)->Activate(old_guid_fidl, new_guid_fidl);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, status);
}
/////////////////////// Actual tests:
// Test initializing the FVM on a partition that is smaller than a slice
TEST_F(FvmTest, TestTooSmall) {
uint64_t block_size = 512;
uint64_t block_count = (1 << 15);
CreateRamdisk(block_size, block_count);
size_t slice_size = block_size * block_count;
ASSERT_EQ(fs_management::FvmInit(ramdisk_block_interface(), slice_size), ZX_ERR_NO_SPACE);
ValidateFVM(ramdisk_block_interface(), ValidationResult::Corrupted);
}
// Test initializing the FVM on a large partition, with metadata size > the max transfer size
TEST_F(FvmTest, TestLarge) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount{UINT64_C(8) * (1 << 20)};
CreateRamdisk(kBlockSize, kBlockCount);
constexpr size_t kSliceSize{static_cast<size_t>(16) * (1 << 10)};
fvm::Header fvm_header =
fvm::Header::FromDiskSize(fvm::kMaxUsablePartitions, kBlockSize * kBlockCount, kSliceSize);
const fidl::WireResult result = fidl::WireCall(ramdisk_block_interface())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_LT(block_info.max_transfer_size, fvm_header.GetMetadataAllocatedBytes());
ASSERT_EQ(fs_management::FvmInit(ramdisk_block_interface(), kSliceSize), ZX_OK);
auto resp = fidl::WireCall(ramdisk_controller_interface())->Bind(kFvmDriverLib);
ASSERT_OK(resp.status());
ASSERT_TRUE(resp->is_ok());
ASSERT_OK(device_watcher::RecursiveWaitForFile(devfs_root_fd().get(), fvm_path().c_str()));
ValidateFVM(ramdisk_block_interface());
}
// Load and unload an empty FVM
TEST_F(FvmTest, TestEmpty) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
// Test allocating a single partition
TEST_F(FvmTest, TestAllocateOne) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
// Allocate one VPart
zx::result vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp = std::move(vp_or.value());
// Check that the name matches what we provided
const fidl::WireResult result = fidl::WireCall(vp.partition)->GetName();
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
ASSERT_STREQ(response.name.get(), kTestPartDataName.data());
// Check that we can read from / write to it.
CheckWriteReadBlock(vp.as_block(), 0, 1);
// Try accessing the block again after closing / re-opening it.
vp = {};
vp_or = WaitForPartition(kPartition1Matcher);
ASSERT_EQ(vp_or.status_value(), ZX_OK, "Couldn't re-open Data VPart");
vp = std::move(vp_or.value());
CheckWriteReadBlock(vp.as_block(), 0, 1);
vp = {};
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
// Test Reading and writing with RemoteBlockDevice helpers
TEST_F(FvmTest, TestReadWriteSingle) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
// Allocate one VPart
zx::result vp = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_OK(vp);
// Check that we can read from / write to it.
CheckWriteReadBytesFifo(vp->as_block(), 0, kBlockSize);
// Check with an offset
CheckWriteReadBytesFifo(vp->as_block(), kBlockSize * 7, kBlockSize * 4);
vp = {};
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
// Test allocating a collection of partitions
TEST_F(FvmTest, TestAllocateMany) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
// Test allocation of multiple VPartitions
zx::result data_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(data_or.status_value(), ZX_OK);
PartitionChannel data = *std::move(data_or);
zx::result blob_or = AllocatePartition({
.type = kTestPartBlobGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartBlobName,
});
ASSERT_EQ(blob_or.status_value(), ZX_OK);
PartitionChannel blob = *std::move(blob_or);
zx::result sys_or = AllocatePartition({
.type = kTestPartSystemGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartSystemName,
});
ASSERT_EQ(sys_or.status_value(), ZX_OK);
PartitionChannel sys = *std::move(sys_or);
CheckWriteReadBlock(data.as_block(), 0, 1);
CheckWriteReadBlock(blob.as_block(), 0, 1);
CheckWriteReadBlock(sys.as_block(), 0, 1);
data = {};
blob = {};
sys = {};
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
// Test allocating additional slices to a vpartition.
TEST_F(FvmTest, TestVPartitionExtend) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
size_t slice_size = volume_info_or->slice_size;
constexpr uint64_t kDiskSize = kBlockSize * kBlockCount;
size_t slices_total = UsableSlicesCount(kDiskSize, slice_size);
size_t slices_left = slices_total;
FVMCheckAllocatedCount(volume_manager.value(), slices_total - slices_left, slices_total);
// Allocate one VPart
size_t slice_count = 1;
auto vp_or = AllocatePartition({
.slice_count = slice_count,
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK, "Couldn't open Volume");
PartitionChannel vp = *std::move(vp_or);
slices_left--;
FVMCheckAllocatedCount(volume_manager.value(), slices_total - slices_left, slices_total);
// Confirm that the disk reports the correct number of slices
{
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, slice_size * slice_count);
}
// Try re-allocating an already allocated vslice
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(0, 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_OUT_OF_RANGE);
}
{
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, slice_size * slice_count);
}
// Try again with a portion of the request which is unallocated
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(0, 2);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_OUT_OF_RANGE);
}
// Allocate OBSCENELY too many slices
{
const fidl::WireResult result =
fidl::WireCall(vp.as_volume())->Extend(slice_count, std::numeric_limits<uint64_t>::max());
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_OUT_OF_RANGE);
}
// Allocate slices at a too-large offset
{
const fidl::WireResult result =
fidl::WireCall(vp.as_volume())->Extend(std::numeric_limits<uint64_t>::max(), 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_OUT_OF_RANGE);
}
// Attempt to allocate slightly too many slices
{
const fidl::WireResult result =
fidl::WireCall(vp.as_volume())->Extend(slice_count, slices_left + 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_NO_SPACE);
}
// The number of free slices should be unchanged.
FVMCheckAllocatedCount(volume_manager.value(), slices_total - slices_left, slices_total);
// Allocate exactly the remaining number of slices
{
const fidl::WireResult result =
fidl::WireCall(vp.as_volume())->Extend(slice_count, slices_left);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
slice_count += slices_left;
slices_left = 0;
FVMCheckAllocatedCount(volume_manager.value(), slices_total - slices_left, slices_total);
{
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, slice_size * slice_count);
}
// We can't allocate any more to this VPartition
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(slice_count, 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_NO_SPACE);
}
// We can't allocate a new VPartition
zx::result vp2_or = AllocatePartition({
.type = kTestPartBlobGuid,
.guid = kTestUniqueGuid2,
.name = kTestPartBlobName,
});
ASSERT_NE(vp2_or.status_value(), ZX_OK, "Expected VPart allocation failure");
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
}
// Test allocating very sparse VPartition
TEST_F(FvmTest, TestVPartitionExtendSparse) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp = *std::move(vp_or);
CheckWriteReadBlock(vp.as_block(), 0, 1);
// Double check that we can access a block at this vslice address
// (this isn't always possible; for certain slice sizes, blocks may be
// allocatable / freeable, but not addressable).
size_t bno = (fvm::kMaxVSlices - 1) * (kSliceSize / kBlockSize);
ASSERT_EQ(bno / (kSliceSize / kBlockSize), (fvm::kMaxVSlices - 1), "bno overflowed");
ASSERT_EQ((bno * kBlockSize) / kBlockSize, bno, "block access will overflow");
// Try allocating at a location that's slightly too large
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(fvm::kMaxVSlices, 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_OUT_OF_RANGE);
}
// Try allocating at the largest offset
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(fvm::kMaxVSlices - 1, 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
CheckWriteReadBlock(vp.as_block(), bno, 1);
// Try freeing beyond largest offset
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Shrink(fvm::kMaxVSlices, 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_OUT_OF_RANGE);
}
CheckWriteReadBlock(vp.as_block(), bno, 1);
// Try freeing at the largest offset
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Shrink(fvm::kMaxVSlices - 1, 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
CheckNoAccessBlock(vp.as_block(), bno, 1);
vp = {};
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
// Test removing slices from a VPartition.
TEST_F(FvmTest, TestVPartitionShrink) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
size_t slice_size = volume_info_or->slice_size;
const size_t kDiskSize = kBlockSize * kBlockCount;
size_t slices_total = UsableSlicesCount(kDiskSize, slice_size);
size_t slices_left = slices_total;
FVMCheckAllocatedCount(volume_manager.value(), slices_total - slices_left, slices_total);
// Allocate one VPart
size_t slice_count = 1;
zx::result vp_or = AllocatePartition({
.slice_count = slice_count,
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK, "Couldn't open Volume");
PartitionChannel vp = *std::move(vp_or);
slices_left--;
// Confirm that the disk reports the correct number of slices
{
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, slice_size * slice_count);
CheckWriteReadBlock(vp.as_block(), (slice_size / block_info.block_size) - 1, 1);
CheckNoAccessBlock(vp.as_block(), (slice_size / block_info.block_size) - 1, 2);
FVMCheckAllocatedCount(volume_manager.value(), slices_total - slices_left, slices_total);
}
// Try shrinking the 0th vslice
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Shrink(0, 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_OUT_OF_RANGE);
}
// Try no-op requests (length = 0).
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(1, 0);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Shrink(1, 0);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
{
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, slice_size * slice_count);
}
// Try again with a portion of the request which is unallocated
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Shrink(1, 2);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_INVALID_ARGS);
}
{
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, slice_size * slice_count);
FVMCheckAllocatedCount(volume_manager.value(), slices_total - slices_left, slices_total);
}
// Allocate exactly the remaining number of slices
{
const fidl::WireResult result =
fidl::WireCall(vp.as_volume())->Extend(slice_count, slices_left);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
slice_count += slices_left;
slices_left = 0;
{
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, slice_size * slice_count);
CheckWriteReadBlock(vp.as_block(), (slice_size / block_info.block_size) - 1, 1);
CheckWriteReadBlock(vp.as_block(), (slice_size / block_info.block_size) - 1, 2);
}
FVMCheckAllocatedCount(volume_manager.value(), slices_total - slices_left, slices_total);
// We can't allocate any more to this VPartition
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(slice_count, 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_NO_SPACE);
}
// Try to shrink off the end (okay, since SOME of the slices are allocated)
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Shrink(1, slice_count + 3);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
FVMCheckAllocatedCount(volume_manager.value(), 1, slices_total);
// The same request to shrink should now fail (NONE of the slices are
// allocated)
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Shrink(1, slice_count - 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_INVALID_ARGS);
}
FVMCheckAllocatedCount(volume_manager.value(), 1, slices_total);
// ... unless we re-allocate and try again.
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(1, slice_count - 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Shrink(1, slice_count - 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
}
// Test splitting a contiguous slice extent into multiple parts
TEST_F(FvmTest, TestVPartitionSplit) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
size_t slice_size = volume_info_or->slice_size;
// Allocate one VPart
size_t slice_count = 5;
zx::result vp_or = AllocatePartition({
.slice_count = slice_count,
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp = *std::move(vp_or);
// Confirm that the disk reports the correct number of slices
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, slice_size * slice_count);
size_t reset_offset = 1;
size_t reset_length = slice_count - 1;
size_t mid_offset = 2;
size_t mid_length = 1;
size_t start_offset = 1;
size_t start_length = 1;
size_t end_offset = 3;
size_t end_length = slice_count - 3;
auto verifyExtents = [&](bool start, bool mid, bool end) {
size_t start_block = start_offset * (slice_size / block_info.block_size);
size_t mid_block = mid_offset * (slice_size / block_info.block_size);
size_t end_block = end_offset * (slice_size / block_info.block_size);
if (start) {
CheckWriteReadBlock(vp.as_block(), start_block, 1);
} else {
CheckNoAccessBlock(vp.as_block(), start_block, 1);
}
if (mid) {
CheckWriteReadBlock(vp.as_block(), mid_block, 1);
} else {
CheckNoAccessBlock(vp.as_block(), mid_block, 1);
}
if (end) {
CheckWriteReadBlock(vp.as_block(), end_block, 1);
} else {
CheckNoAccessBlock(vp.as_block(), end_block, 1);
}
return true;
};
auto doExtend = [&vp](size_t offset, size_t length) {
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
};
auto doShrink = [&vp](size_t offset, size_t length) {
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Shrink(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
};
// We should be able to split the extent.
verifyExtents(true, true, true);
doShrink(mid_offset, mid_length);
verifyExtents(true, false, true);
doShrink(start_offset, start_length);
verifyExtents(false, false, true);
doShrink(end_offset, end_length);
verifyExtents(false, false, false);
doExtend(reset_offset, reset_length);
doShrink(start_offset, start_length);
verifyExtents(false, true, true);
doShrink(mid_offset, mid_length);
verifyExtents(false, false, true);
doShrink(end_offset, end_length);
verifyExtents(false, false, false);
doExtend(reset_offset, reset_length);
doShrink(end_offset, end_length);
verifyExtents(true, true, false);
doShrink(mid_offset, mid_length);
verifyExtents(true, false, false);
doShrink(start_offset, start_length);
verifyExtents(false, false, false);
doExtend(reset_offset, reset_length);
doShrink(end_offset, end_length);
verifyExtents(true, true, false);
doShrink(start_offset, start_length);
verifyExtents(false, true, false);
doShrink(mid_offset, mid_length);
verifyExtents(false, false, false);
// We should also be able to combine extents
doExtend(mid_offset, mid_length);
verifyExtents(false, true, false);
doExtend(start_offset, start_length);
verifyExtents(true, true, false);
doExtend(end_offset, end_length);
verifyExtents(true, true, true);
doShrink(reset_offset, reset_length);
doExtend(end_offset, end_length);
verifyExtents(false, false, true);
doExtend(mid_offset, mid_length);
verifyExtents(false, true, true);
doExtend(start_offset, start_length);
verifyExtents(true, true, true);
doShrink(reset_offset, reset_length);
doExtend(end_offset, end_length);
verifyExtents(false, false, true);
doExtend(start_offset, start_length);
verifyExtents(true, false, true);
doExtend(mid_offset, mid_length);
verifyExtents(true, true, true);
vp = {};
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
}
// Test removing VPartitions within an FVM
TEST_F(FvmTest, TestVPartitionDestroy) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
// Test allocation of multiple VPartitions
zx::result data_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(data_or.status_value(), ZX_OK);
PartitionChannel data = *std::move(data_or);
zx::result blob_or = AllocatePartition({
.type = kTestPartBlobGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartBlobName,
});
ASSERT_EQ(blob_or.status_value(), ZX_OK);
PartitionChannel blob = *std::move(blob_or);
zx::result sys_or = AllocatePartition({
.type = kTestPartSystemGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartSystemName,
});
ASSERT_EQ(sys_or.status_value(), ZX_OK);
PartitionChannel sys = *std::move(sys_or);
// We can access all three...
CheckWriteReadBlock(data.as_block(), 0, 1);
CheckWriteReadBlock(blob.as_block(), 0, 1);
CheckWriteReadBlock(sys.as_block(), 0, 1);
// But not after we destroy the blob partition.
{
const fidl::WireResult result = fidl::WireCall(blob.as_volume())->Destroy();
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
CheckWriteReadBlock(data.as_block(), 0, 1);
CheckWriteReadBlock(sys.as_block(), 0, 1);
CheckDeadConnection(blob.partition.channel());
// Destroy the other two VPartitions.
{
const fidl::WireResult result = fidl::WireCall(data.as_volume())->Destroy();
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
CheckWriteReadBlock(sys.as_block(), 0, 1);
CheckDeadConnection(data.partition.channel());
{
const fidl::WireResult result = fidl::WireCall(sys.as_volume())->Destroy();
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
CheckDeadConnection(sys.partition.channel());
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
}
}
TEST_F(FvmTest, TestVPartitionQuery) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
// Allocate partition
zx::result part_or = AllocatePartition({
.slice_count = 10,
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(part_or.status_value(), ZX_OK);
PartitionChannel part = *std::move(part_or);
// Create non-contiguous extent.
uint64_t offset = 20;
uint64_t length = 10;
{
const fidl::WireResult result = fidl::WireCall(part.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
// Query various vslice ranges
uint64_t start_slices[6];
start_slices[0] = 0;
start_slices[1] = 10;
start_slices[2] = 20;
start_slices[3] = 50;
start_slices[4] = 25;
start_slices[5] = 15;
// Check response from partition query
{
const fidl::WireResult result =
fidl::WireCall(part.as_volume())
->QuerySlices(fidl::VectorView<uint64_t>::FromExternal(start_slices));
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
fidl::Array ranges = response.response;
ASSERT_EQ(response.response_count, std::size(start_slices));
ASSERT_TRUE(ranges[0].allocated);
ASSERT_EQ(ranges[0].count, 10);
ASSERT_FALSE(ranges[1].allocated);
ASSERT_EQ(ranges[1].count, 10);
ASSERT_TRUE(ranges[2].allocated);
ASSERT_EQ(ranges[2].count, 10);
ASSERT_FALSE(ranges[3].allocated);
ASSERT_EQ(ranges[3].count, volume_info_or->max_virtual_slice - 50);
ASSERT_TRUE(ranges[4].allocated);
ASSERT_EQ(ranges[4].count, 5);
ASSERT_FALSE(ranges[5].allocated);
ASSERT_EQ(ranges[5].count, 5);
}
// Merge the extents!
offset = 10;
length = 10;
{
const fidl::WireResult result = fidl::WireCall(part.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
// Check partition query response again after extend
{
const fidl::WireResult result =
fidl::WireCall(part.as_volume())
->QuerySlices(fidl::VectorView<uint64_t>::FromExternal(start_slices));
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
fidl::Array ranges = response.response;
ASSERT_EQ(response.response_count, std::size(start_slices));
ASSERT_TRUE(ranges[0].allocated);
ASSERT_EQ(ranges[0].count, 30);
ASSERT_TRUE(ranges[1].allocated);
ASSERT_EQ(ranges[1].count, 20);
ASSERT_TRUE(ranges[2].allocated);
ASSERT_EQ(ranges[2].count, 10);
ASSERT_FALSE(ranges[3].allocated);
ASSERT_EQ(ranges[3].count, volume_info_or->max_virtual_slice - 50);
ASSERT_TRUE(ranges[4].allocated);
ASSERT_EQ(ranges[4].count, 5);
ASSERT_TRUE(ranges[5].allocated);
ASSERT_EQ(ranges[5].count, 15);
}
start_slices[0] = volume_info_or->max_virtual_slice + 1;
const fidl::WireResult result =
fidl::WireCall(part.as_volume())
->QuerySlices(fidl::VectorView<uint64_t>::FromExternal(start_slices));
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_STATUS(response.status, ZX_ERR_OUT_OF_RANGE);
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
}
}
// Test allocating and accessing slices which are allocated contiguously.
TEST_F(FvmTest, TestSliceAccessContiguous) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
size_t slice_size = volume_info_or->slice_size;
// Allocate one VPart
zx::result vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp = *std::move(vp_or);
fidl::UnownedClientEnd device = vp.as_block();
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
// This is the last 'accessible' block.
size_t last_block = (slice_size / block_info.block_size) - 1;
{
auto vc = fbl::MakeRefCounted<VmoClient>(device);
VmoBuf vb(vc, block_info.block_size * static_cast<size_t>(2));
vc->CheckWrite(vb, 0, block_info.block_size * last_block, block_info.block_size);
vc->CheckRead(vb, 0, block_info.block_size * last_block, block_info.block_size);
// Try writing out of bounds -- check that we don't have access.
CheckNoAccessBlock(device, (slice_size / block_info.block_size) - 1, 2);
CheckNoAccessBlock(device, slice_size / block_info.block_size, 1);
// Attempt to access the next contiguous slice
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(1, 1);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
// Now we can access the next slice...
vc->CheckWrite(vb, block_info.block_size, block_info.block_size * (last_block + 1),
block_info.block_size);
vc->CheckRead(vb, block_info.block_size, block_info.block_size * (last_block + 1),
block_info.block_size);
// ... We can still access the previous slice...
vc->CheckRead(vb, 0, block_info.block_size * last_block, block_info.block_size);
// ... And we can cross slices
vc->CheckRead(vb, 0, block_info.block_size * last_block,
block_info.block_size * static_cast<size_t>(2));
}
vp = {};
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
}
}
// Test allocating and accessing multiple (3+) slices at once.
TEST_F(FvmTest, TestSliceAccessMany) {
// The size of a slice must be carefully constructed for this test
// so that we can hold multiple slices in memory without worrying
// about hitting resource limits.
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 20;
constexpr uint64_t kBlocksPerSlice = 256;
constexpr uint64_t kSliceSize = kBlocksPerSlice * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
ASSERT_EQ(volume_info_or->slice_size, kSliceSize);
// Allocate one VPart
auto vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp = *std::move(vp_or);
fidl::UnownedClientEnd device = vp.as_block();
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_size, kBlockSize);
{
auto vc = fbl::MakeRefCounted<VmoClient>(device);
VmoBuf vb(vc, kSliceSize * 3);
// Access the first slice
vc->CheckWrite(vb, 0, 0, kSliceSize);
vc->CheckRead(vb, 0, 0, kSliceSize);
// Try writing out of bounds -- check that we don't have access.
CheckNoAccessBlock(device, kBlocksPerSlice - 1, 2);
CheckNoAccessBlock(device, kBlocksPerSlice, 1);
// Attempt to access the next contiguous slices
uint64_t offset = 1;
uint64_t length = 2;
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
// Now we can access the next slices...
vc->CheckWrite(vb, kSliceSize, kSliceSize, 2 * kSliceSize);
vc->CheckRead(vb, kSliceSize, kSliceSize, 2 * kSliceSize);
// ... We can still access the previous slice...
vc->CheckRead(vb, 0, 0, kSliceSize);
// ... And we can cross slices for reading.
vc->CheckRead(vb, 0, 0, 3 * kSliceSize);
// Also, we can cross slices for writing.
vc->CheckWrite(vb, 0, 0, 3 * kSliceSize);
vc->CheckRead(vb, 0, 0, 3 * kSliceSize);
// Additionally, we can access "parts" of slices in a multi-slice
// operation. Here, read one block into the first slice, and read
// up to the last block in the final slice.
vc->CheckWrite(vb, 0, kBlockSize, 3 * kSliceSize - 2 * kBlockSize);
vc->CheckRead(vb, 0, kBlockSize, 3 * kSliceSize - 2 * kBlockSize);
}
vp = {};
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
}
// Test allocating and accessing slices which are allocated
// virtually contiguously (they appear sequential to the client) but are
// actually noncontiguous on the FVM partition.
TEST_F(FvmTest, TestSliceAccessNonContiguousPhysical) {
constexpr uint64_t kBlockSize{512};
constexpr uint64_t kBlockCount{1 << 16};
constexpr uint64_t kSliceSize{kBlockSize * 64};
constexpr uint64_t kDiskSize{kBlockSize * kBlockCount};
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
ASSERT_EQ(fs_management::FvmQuery(volume_manager.value()).status_value(), ZX_OK);
constexpr size_t kNumVParts = 3;
constexpr size_t kSliceCount = 1;
typedef struct vdata {
PartitionChannel partition;
const uuid::Uuid& guid;
const std::string_view& name;
size_t slices_used;
} vdata_t;
vdata_t vparts[kNumVParts] = {
{{}, kTestPartDataGuid, kTestPartDataName, kSliceCount},
{{}, kTestPartBlobGuid, kTestPartBlobName, kSliceCount},
{{}, kTestPartSystemGuid, kTestPartSystemName, kSliceCount},
};
for (auto& vpart : vparts) {
zx::result part_or = AllocatePartition({
.slice_count = kSliceCount,
.type = vpart.guid,
.guid = kTestUniqueGuid1,
.name = vpart.name,
});
ASSERT_EQ(part_or.status_value(), ZX_OK);
vpart.partition = *std::move(part_or);
}
const fidl::WireResult result = fidl::WireCall(vparts[0].partition.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
size_t usable_slices_per_vpart = UsableSlicesCount(kDiskSize, kSliceSize) / kNumVParts;
size_t i = 0;
while (vparts[i].slices_used < usable_slices_per_vpart) {
// This is the last 'accessible' block.
size_t last_block = (vparts[i].slices_used * (kSliceSize / block_info.block_size)) - 1;
auto vc = fbl::MakeRefCounted<VmoClient>(vparts[i].partition.as_block());
VmoBuf vb(vc, block_info.block_size * static_cast<size_t>(2));
vc->CheckWrite(vb, 0, block_info.block_size * last_block, block_info.block_size);
vc->CheckRead(vb, 0, block_info.block_size * last_block, block_info.block_size);
// Try writing out of bounds -- check that we don't have access.
CheckNoAccessBlock(vparts[i].partition.as_block(), last_block, 2);
CheckNoAccessBlock(vparts[i].partition.as_block(), last_block + 1, 1);
// Attempt to access the next contiguous slice
uint64_t offset = vparts[i].slices_used;
uint64_t length = 1;
{
const fidl::WireResult result =
fidl::WireCall(vparts[i].partition.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
// Now we can access the next slice...
vc->CheckWrite(vb, block_info.block_size, block_info.block_size * (last_block + 1),
block_info.block_size);
vc->CheckRead(vb, block_info.block_size, block_info.block_size * (last_block + 1),
block_info.block_size);
// ... We can still access the previous slice...
vc->CheckRead(vb, 0, block_info.block_size * last_block, block_info.block_size);
// ... And we can cross slices
vc->CheckRead(vb, 0, block_info.block_size * last_block,
block_info.block_size * static_cast<size_t>(2));
vparts[i].slices_used++;
i = (i + 1) % kNumVParts;
}
for (size_t i = 0; i < kNumVParts; i++) {
printf("Testing multi-slice operations on vslice %lu\n", i);
// We need at least five slices, so we can access three "middle"
// slices and jitter to test off-by-one errors.
ASSERT_GE(vparts[i].slices_used, 5);
{
auto vc = fbl::MakeRefCounted<VmoClient>(vparts[i].partition.as_block());
VmoBuf vb(vc, kSliceSize * 4);
// Try accessing 3 noncontiguous slices at once, with the
// addition of "off by one block".
size_t dev_off_start = kSliceSize - block_info.block_size;
size_t dev_off_end = kSliceSize + block_info.block_size;
size_t len_start = kSliceSize * 3 - block_info.block_size;
size_t len_end = kSliceSize * 3 + block_info.block_size;
// Test a variety of:
// Starting device offsets,
size_t bsz = block_info.block_size;
for (size_t dev_off = dev_off_start; dev_off <= dev_off_end; dev_off += bsz) {
printf(" Testing non-contiguous write/read starting at offset: %zu\n", dev_off);
// Operation lengths,
for (size_t len = len_start; len <= len_end; len += bsz) {
printf(" Testing operation of length: %zu\n", len);
// and starting VMO offsets
for (size_t vmo_off = 0; vmo_off < 3 * bsz; vmo_off += bsz) {
// Try writing & reading the entire section (multiple
// slices) at once.
vc->CheckWrite(vb, vmo_off, dev_off, len);
vc->CheckRead(vb, vmo_off, dev_off, len);
// Try reading the section one slice at a time.
// The results should be the same.
size_t sub_off = 0;
size_t sub_len = kSliceSize - (dev_off % kSliceSize);
while (sub_off < len) {
vc->CheckRead(vb, vmo_off + sub_off, dev_off + sub_off, sub_len);
sub_off += sub_len;
sub_len = std::min(kSliceSize, len - sub_off);
}
}
}
}
}
vparts[i].partition = {};
}
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
}
// Test allocating and accessing slices which are
// allocated noncontiguously from the client's perspective.
TEST_F(FvmTest, TestSliceAccessNonContiguousVirtual) {
constexpr uint64_t kBlockSize{512};
constexpr uint64_t kBlockCount{1 << 20};
constexpr uint64_t kSliceSize{UINT64_C(64) * (1 << 20)};
constexpr uint64_t kDiskSize{kBlockSize * kBlockCount};
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
ASSERT_EQ(fs_management::FvmQuery(volume_manager.value()).status_value(), ZX_OK);
constexpr size_t kNumVParts = 3;
constexpr size_t kSliceCount = 1;
typedef struct vdata {
PartitionChannel partition;
const uuid::Uuid& guid;
const std::string_view& name;
size_t slices_used;
size_t last_slice;
} vdata_t;
vdata_t vparts[kNumVParts] = {
{{}, kTestPartDataGuid, kTestPartDataName, kSliceCount, kSliceCount},
{{}, kTestPartBlobGuid, kTestPartBlobName, kSliceCount, kSliceCount},
{{}, kTestPartSystemGuid, kTestPartSystemName, kSliceCount, kSliceCount},
};
for (auto& vpart : vparts) {
zx::result part_or = AllocatePartition({
.slice_count = kSliceCount,
.type = vpart.guid,
.guid = kTestUniqueGuid1,
.name = vpart.name,
});
ASSERT_EQ(part_or.status_value(), ZX_OK);
vpart.partition = *std::move(part_or);
}
const fidl::WireResult result = fidl::WireCall(vparts[0].partition.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
size_t usable_slices_per_vpart = UsableSlicesCount(kDiskSize, kSliceSize) / kNumVParts;
size_t i = 0;
while (vparts[i].slices_used < usable_slices_per_vpart) {
fidl::UnownedClientEnd device = vparts[i].partition.as_block();
// This is the last 'accessible' block.
size_t last_block = (vparts[i].last_slice * (kSliceSize / block_info.block_size)) - 1;
CheckWriteReadBlock(device, last_block, 1);
// Try writing out of bounds -- check that we don't have access.
CheckNoAccessBlock(device, last_block, 2);
CheckNoAccessBlock(device, last_block + 1, 1);
// Attempt to access a non-contiguous slice
uint64_t offset = vparts[i].last_slice + 2;
uint64_t length = 1;
{
const fidl::WireResult result =
fidl::WireCall(vparts[i].partition.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
// We still don't have access to the next slice...
CheckNoAccessBlock(device, last_block, 2);
CheckNoAccessBlock(device, last_block + 1, 1);
// But we have access to the slice we asked for!
size_t requested_block = (offset * kSliceSize) / block_info.block_size;
CheckWriteReadBlock(device, requested_block, 1);
vparts[i].slices_used++;
vparts[i].last_slice = offset;
i = (i + 1) % kNumVParts;
}
for (vdata_t& vpart : vparts) {
vpart.partition = {};
}
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
ValidateFVM(ramdisk_block_interface());
}
}
// Test that the FVM driver actually persists updates.
TEST_F(FvmTest, TestPersistenceSimple) {
constexpr uint64_t kBlockSize{512};
constexpr uint64_t kBlockCount{1 << 20};
constexpr uint64_t kSliceSize{UINT64_C(64) * (1 << 20)};
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
constexpr uint64_t kDiskSize = kBlockSize * kBlockCount;
size_t slices_left = UsableSlicesCount(kDiskSize, kSliceSize);
const uint64_t kSliceCount = slices_left;
ASSERT_EQ(fs_management::FvmQuery(volume_manager.value()).status_value(), ZX_OK);
// Allocate one VPart
auto vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp = *std::move(vp_or);
slices_left--;
fidl::UnownedClientEnd device = vp.as_block();
// Check that the name matches what we provided
{
const fidl::WireResult result = fidl::WireCall(vp.partition)->GetName();
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
ASSERT_STREQ(response.name.get(), kTestPartDataName.data());
}
fuchsia_hardware_block::wire::BlockInfo block_info;
{
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
block_info = response.value()->info;
}
std::unique_ptr<uint8_t[]> buf(new uint8_t[block_info.block_size * static_cast<size_t>(2)]);
// Check that we can read from / write to it
CheckWrite(device, 0, block_info.block_size, buf.get());
CheckRead(device, 0, block_info.block_size, buf.get());
vp = {};
// Check that it still exists after rebinding the driver
FVMRebind();
volume_manager = fvm_device();
ASSERT_OK(volume_manager);
vp_or = WaitForPartition(kPartition1Matcher);
ASSERT_OK(vp_or.status_value());
vp = *std::move(vp_or);
device = vp.as_block();
CheckRead(device, 0, block_info.block_size, buf.get());
// Try extending the vpartition, and checking that the extension persists.
// This is the last 'accessible' block.
size_t last_block = (kSliceSize / block_info.block_size) - 1;
CheckWrite(device, block_info.block_size * last_block, block_info.block_size, buf.get());
CheckRead(device, block_info.block_size * last_block, block_info.block_size, buf.get());
// Try writing out of bounds -- check that we don't have access.
CheckNoAccessBlock(vp.as_block(), (kSliceSize / block_info.block_size) - 1, 2);
CheckNoAccessBlock(vp.as_block(), kSliceSize / block_info.block_size, 1);
uint64_t offset = 1;
uint64_t length = 1;
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
slices_left--;
vp = {};
// FVMRebind will cause the rebind on ramdisk block device. The fvm device is child device
// to ramdisk block device. Before issuing rebind make sure the fd is released.
// Rebind the FVM driver, check the extension has succeeded.
FVMRebind();
volume_manager = fvm_device();
ASSERT_OK(volume_manager);
vp_or = WaitForPartition(kPartition1Matcher);
ASSERT_OK(vp_or.status_value());
vp = *std::move(vp_or);
device = vp.as_block();
// Now we can access the next slice...
CheckWrite(device, block_info.block_size * (last_block + 1), block_info.block_size,
&buf[block_info.block_size]);
CheckRead(device, block_info.block_size * (last_block + 1), block_info.block_size,
&buf[block_info.block_size]);
// ... We can still access the previous slice...
CheckRead(device, block_info.block_size * last_block, block_info.block_size, buf.get());
// ... And we can cross slices
CheckRead(device, block_info.block_size * last_block,
block_info.block_size * static_cast<size_t>(2), buf.get());
// Try allocating the rest of the slices, rebinding, and ensuring
// that the size stays updated.
{
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
block_info = response.value()->info;
}
ASSERT_EQ(block_info.block_count * block_info.block_size, kSliceSize * 2);
offset = 2;
length = slices_left;
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
{
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
block_info = response.value()->info;
}
ASSERT_EQ(block_info.block_count * block_info.block_size, kSliceSize * kSliceCount);
vp = {};
FVMRebind();
volume_manager = fvm_device();
ASSERT_OK(volume_manager);
vp_or = WaitForPartition(kPartition1Matcher);
ASSERT_OK(vp_or.status_value());
vp = *std::move(vp_or);
device = vp.as_block();
{
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
block_info = response.value()->info;
}
ASSERT_EQ(block_info.block_count * block_info.block_size, kSliceSize * kSliceCount);
vp = {};
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), 64lu * (1 << 20));
}
}
void CorruptMountHelper(const fbl::unique_fd& devfs_root, const char* partition_path,
const fs_management::MountOptions& mounting_options,
fs_management::DiskFormat disk_format, const size_t* vslice_start,
size_t vslice_count) {
fdio_cpp::UnownedFdioCaller devfs_caller(devfs_root.get());
auto component = fs_management::FsComponent::FromDiskFormat(disk_format);
// Format the VPart as |disk_format|.
ASSERT_EQ(fs_management::Mkfs(partition_path, component, {}), ZX_OK);
fuchsia_hardware_block_volume::wire::VsliceRange
initial_ranges[fuchsia_hardware_block_volume::wire::kMaxSliceRequests];
// Check initial slice allocation.
{
zx::result controller =
fs_management::OpenPartitionWithDevfs(devfs_caller.directory(), kPartition1Matcher, true);
ASSERT_OK(controller);
zx::result vp = PartitionChannel::Create(std::move(controller.value()));
ASSERT_OK(vp);
const fidl::WireResult result = fidl::WireCall(vp->as_volume())
->QuerySlices(fidl::VectorView<uint64_t>::FromExternal(
const_cast<size_t*>(vslice_start), vslice_count));
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
ASSERT_EQ(vslice_count, response.response_count);
for (unsigned i = 0; i < response.response_count; i++) {
ASSERT_TRUE(response.response[i].allocated);
ASSERT_GT(response.response[i].count, 0);
initial_ranges[i] = response.response[i];
}
// Manually shrink slices so FVM will differ from the partition.
uint64_t offset = vslice_start[0] + response.response[0].count - 1;
uint64_t length = 1;
{
const fidl::WireResult result = fidl::WireCall(vp->as_volume())->Shrink(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
// Check slice allocation after manual grow/shrink
{
const fidl::WireResult result = fidl::WireCall(vp->as_volume())
->QuerySlices(fidl::VectorView<uint64_t>::FromExternal(
const_cast<size_t*>(vslice_start), vslice_count));
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
ASSERT_EQ(vslice_count, response.response_count);
ASSERT_FALSE(response.response[0].allocated);
ASSERT_EQ(response.response[0].count, vslice_start[1] - vslice_start[0]);
}
// Try to mount the VPart. Since this mount call is supposed to fail, we wait for the spawned
// fs process to finish and associated fidl channels to close before continuing to try and
// prevent race conditions with the later mount call.
fidl::ClientEnd device =
fidl::ClientEnd<fuchsia_hardware_block::Block>(vp->partition.TakeChannel());
ASSERT_NE(fs_management::Mount(std::move(device), component, mounting_options).status_value(),
ZX_OK);
// We can't reuse the component.
component = fs_management::FsComponent::FromDiskFormat(disk_format);
}
{
zx::result controller =
fs_management::OpenPartitionWithDevfs(devfs_caller.directory(), kPartition1Matcher, true);
ASSERT_OK(controller);
zx::result vp = PartitionChannel::Create(std::move(controller.value()));
ASSERT_OK(vp);
// Grow back the slice we shrunk earlier.
uint64_t offset = vslice_start[0];
uint64_t length = 1;
{
const fidl::WireResult result = fidl::WireCall(vp->as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
// Verify grow was successful.
const fidl::WireResult result = fidl::WireCall(vp->as_volume())
->QuerySlices(fidl::VectorView<uint64_t>::FromExternal(
const_cast<size_t*>(vslice_start), vslice_count));
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
ASSERT_EQ(vslice_count, response.response_count);
ASSERT_TRUE(response.response[0].allocated);
ASSERT_EQ(response.response[0].count, 1);
// Now extend all extents by some number of additional slices.
fuchsia_hardware_block_volume::wire::VsliceRange
ranges_before_extend[fuchsia_hardware_block_volume::wire::kMaxSliceRequests];
for (unsigned i = 0; i < vslice_count; i++) {
ranges_before_extend[i] = response.response[i];
uint64_t offset = vslice_start[i] + response.response[i].count;
uint64_t length = vslice_count - i;
{
const fidl::WireResult result = fidl::WireCall(vp->as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
}
// Verify that the extensions were successful.
{
const fidl::WireResult result = fidl::WireCall(vp->as_volume())
->QuerySlices(fidl::VectorView<uint64_t>::FromExternal(
const_cast<size_t*>(vslice_start), vslice_count));
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
ASSERT_EQ(vslice_count, response.response_count);
for (unsigned i = 0; i < vslice_count; i++) {
ASSERT_TRUE(response.response[i].allocated);
ASSERT_EQ(response.response[i].count, ranges_before_extend[i].count + vslice_count - i);
}
}
// Try mount again.
fidl::ClientEnd device =
fidl::ClientEnd<fuchsia_hardware_block::Block>(vp->partition.TakeChannel());
ASSERT_EQ(fs_management::Mount(std::move(device), component, mounting_options).status_value(),
ZX_OK);
}
zx::result controller =
fs_management::OpenPartitionWithDevfs(devfs_caller.directory(), kPartition1Matcher, true);
ASSERT_OK(controller);
zx::result vp = PartitionChannel::Create(std::move(controller.value()));
ASSERT_OK(vp);
// Verify that slices were fixed on mount.
const fidl::WireResult result = fidl::WireCall(vp->as_volume())
->QuerySlices(fidl::VectorView<uint64_t>::FromExternal(
const_cast<size_t*>(vslice_start), vslice_count));
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
ASSERT_EQ(vslice_count, response.response_count);
for (unsigned i = 0; i < vslice_count; i++) {
ASSERT_TRUE(response.response[i].allocated);
ASSERT_EQ(response.response[i].count, initial_ranges[i].count);
}
}
TEST_F(FvmTest, TestCorruptMount) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
ASSERT_EQ(kSliceSize, volume_info_or->slice_size);
// Allocate one VPart
zx::result vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_OK(vp_or.status_value());
zx::result partition_path = GetPartitionPath(vp_or.value().controller);
ASSERT_OK(partition_path.status_value());
size_t kMinfsBlocksPerSlice = kSliceSize / minfs::kMinfsBlockSize;
size_t minfs_vslice_count = 4;
size_t minfs_vslice_start[] = {
minfs::kFVMBlockInodeBmStart / kMinfsBlocksPerSlice,
minfs::kFVMBlockDataBmStart / kMinfsBlocksPerSlice,
minfs::kFVMBlockInodeStart / kMinfsBlocksPerSlice,
minfs::kFVMBlockDataStart / kMinfsBlocksPerSlice,
};
// Run the test for Minfs.
fs_management::MountOptions mounting_options;
CorruptMountHelper(devfs_root_fd(), partition_path->c_str(), mounting_options,
fs_management::kDiskFormatMinfs, minfs_vslice_start, minfs_vslice_count);
size_t kBlobfsBlocksPerSlice = kSliceSize / blobfs::kBlobfsBlockSize;
size_t blobfs_vslice_count = 3;
size_t blobfs_vslice_start[] = {
blobfs::kFVMBlockMapStart / kBlobfsBlocksPerSlice,
blobfs::kFVMNodeMapStart / kBlobfsBlocksPerSlice,
blobfs::kFVMDataStart / kBlobfsBlocksPerSlice,
};
// Run the test for Blobfs.
CorruptMountHelper(devfs_root_fd(), partition_path->c_str(), mounting_options,
fs_management::kDiskFormatBlobfs, blobfs_vslice_start, blobfs_vslice_count);
}
TEST_F(FvmTest, TestVPartitionUpgrade) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
// Allocate two VParts, one active, and one inactive.
{
auto vp_fd_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
.flags = fuchsia_hardware_block_volume::wire::kAllocatePartitionFlagInactive,
});
ASSERT_EQ(vp_fd_or.status_value(), ZX_OK, "Couldn't open Volume");
}
{
auto vp_fd_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid2,
.name = kTestPartBlobName,
});
ASSERT_OK(vp_fd_or.status_value(), "Couldn't open volume");
}
// Release FVM device that we opened earlier
FVMRebind();
// The active partition should still exist.
ASSERT_OK(WaitForPartition(kPartition2Matcher).status_value());
// The inactive partition should be gone.
ASSERT_STATUS(OpenPartition(kPartition1Matcher).status_value(), ZX_ERR_NOT_FOUND);
// Reallocate GUID1 as inactive.
{
auto vp_fd_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
.flags = fuchsia_hardware_block_volume::wire::kAllocatePartitionFlagInactive,
});
ASSERT_OK(vp_fd_or.status_value(), "Couldn't open new volume");
}
// Atomically set GUID1 as active and GUID2 as inactive.
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
Upgrade(volume_manager.value(), kTestUniqueGuid2, kTestUniqueGuid1, ZX_OK);
}
// After upgrading, we should be able to open both partitions
ASSERT_OK(WaitForPartition(kPartition1Matcher).status_value());
ASSERT_OK(WaitForPartition(kPartition2Matcher).status_value());
// Rebind the FVM driver, check that the upgrade has succeeded.
// The original (GUID2) should be deleted, and the new partition (GUID)
// should exist.
FVMRebind();
ASSERT_OK(WaitForPartition(kPartition1Matcher).status_value());
ASSERT_STATUS(OpenPartition(kPartition2Matcher).status_value(), ZX_ERR_NOT_FOUND);
// Try upgrading when the "new" version doesn't exist.
// (It should return an error and have no noticeable effect).
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
Upgrade(volume_manager.value(), kTestUniqueGuid1, kTestUniqueGuid2, ZX_ERR_NOT_FOUND);
}
// Release FVM device that we opened earlier
FVMRebind();
ASSERT_OK(WaitForPartition(kPartition1Matcher).status_value());
ASSERT_STATUS(OpenPartition(kPartition2Matcher).status_value(), ZX_ERR_NOT_FOUND);
// Try upgrading when the "old" version doesn't exist.
{
auto vp_fd_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid2,
.name = kTestPartBlobName,
.flags = fuchsia_hardware_block_volume::wire::kAllocatePartitionFlagInactive,
});
ASSERT_EQ(vp_fd_or.status_value(), ZX_OK, "Couldn't open volume");
}
uuid::Uuid fake_guid = {};
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
Upgrade(volume_manager.value(), fake_guid, kTestUniqueGuid2, ZX_OK);
}
FVMRebind();
// We should be able to open both partitions again.
zx::result vp_or = WaitForPartition(kPartition1Matcher);
ASSERT_OK(vp_or.status_value());
ASSERT_OK(WaitForPartition(kPartition2Matcher).status_value());
// Destroy and reallocate the first partition as inactive.
{
const fidl::WireResult result = fidl::WireCall(vp_or.value().as_volume())->Destroy();
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
{
zx::result vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
.flags = fuchsia_hardware_block_volume::wire::kAllocatePartitionFlagInactive,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK, "Couldn't open volume");
}
// Upgrade the partition with old_guid == new_guid.
// This should activate the partition.
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
Upgrade(volume_manager.value(), kTestUniqueGuid1, kTestUniqueGuid1, ZX_OK);
}
FVMRebind();
// We should be able to open both partitions again.
ASSERT_OK(WaitForPartition(kPartition1Matcher).status_value());
ASSERT_OK(WaitForPartition(kPartition2Matcher).status_value());
}
// Test that the FVM driver can mount filesystems.
TEST_F(FvmTest, TestMounting) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
// Allocate one VPart
size_t slice_count = 5;
zx::result vp_or = AllocatePartition({
.slice_count = slice_count,
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp(*std::move(vp_or));
// Format the VPart as minfs
zx::result partition_path = GetPartitionPath(vp.controller);
ASSERT_OK(partition_path.status_value());
auto component = fs_management::FsComponent::FromDiskFormat(fs_management::kDiskFormatMinfs);
ASSERT_EQ(fs_management::Mkfs(partition_path->c_str(), component, fs_management::MkfsOptions()),
ZX_OK);
fidl::ClientEnd device =
fidl::ClientEnd<fuchsia_hardware_block::Block>(vp.partition.TakeChannel());
// Mount the VPart
fs_management::MountOptions mounting_options;
auto mounted_filesystem = fs_management::Mount(std::move(device), component, mounting_options);
ASSERT_EQ(mounted_filesystem.status_value(), ZX_OK);
auto data = mounted_filesystem->DataRoot();
ASSERT_EQ(data.status_value(), ZX_OK);
auto binding = fs_management::NamespaceBinding::Create(kMountPath, std::move(*data));
ASSERT_EQ(binding.status_value(), ZX_OK);
// Verify that the mount was successful.
fbl::unique_fd rootfd;
ASSERT_OK(fdio_open_fd(kMountPath, static_cast<uint32_t>(fuchsia_io::OpenFlags::kDirectory),
rootfd.reset_and_get_address()));
fdio_cpp::FdioCaller caller(std::move(rootfd));
auto result = fidl::WireCall(caller.directory())->QueryFilesystem();
ASSERT_TRUE(result.ok());
const char* kFsName = "minfs";
const char* name = reinterpret_cast<const char*>(result.value().info->name.data());
ASSERT_EQ(strncmp(name, kFsName, strlen(kFsName)), 0, "Unexpected filesystem mounted");
// Verify that MinFS does not try to use more of the VPartition than
// was originally allocated.
ASSERT_LE(result.value().info->total_bytes, kSliceSize * slice_count);
// Clean up.
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
}
}
// Test that FVM-aware filesystem can be reformatted.
TEST_F(FvmTest, TestMkfs) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
// Allocate one VPart.
size_t slice_count = 5;
zx::result vp_or = AllocatePartition({
.slice_count = slice_count,
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp(*std::move(vp_or));
// Format the VPart as minfs.
zx::result partition_path = GetPartitionPath(vp.controller);
ASSERT_OK(partition_path.status_value());
auto minfs_component =
fs_management::FsComponent::FromDiskFormat(fs_management::kDiskFormatMinfs);
ASSERT_EQ(
fs_management::Mkfs(partition_path->c_str(), minfs_component, fs_management::MkfsOptions()),
ZX_OK);
// Format it as MinFS again, even though it is already formatted.
ASSERT_EQ(
fs_management::Mkfs(partition_path->c_str(), minfs_component, fs_management::MkfsOptions()),
ZX_OK);
// Now try reformatting as blobfs.
auto blobfs_component =
fs_management::FsComponent::FromDiskFormat(fs_management::kDiskFormatBlobfs);
ASSERT_EQ(fs_management::Mkfs(partition_path->c_str(), blobfs_component, {}), ZX_OK);
// Demonstrate that mounting as minfs will fail, but mounting as blobfs
// is successful.
{
fidl::ClientEnd device =
fidl::ClientEnd<fuchsia_hardware_block::Block>(vp.partition.TakeChannel());
fs_management::MountOptions mounting_options;
ASSERT_NE(
fs_management::Mount(std::move(device), minfs_component, mounting_options).status_value(),
ZX_OK);
}
// We can't reuse the component.
minfs_component = fs_management::FsComponent::FromDiskFormat(fs_management::kDiskFormatMinfs);
{
zx::result device = component::Connect<fuchsia_hardware_block::Block>(partition_path.value());
ASSERT_OK(device);
ASSERT_EQ(fs_management::Mount(std::move(device.value()), blobfs_component, {}).status_value(),
ZX_OK);
}
// ... and reformat back to MinFS again.
ASSERT_EQ(
fs_management::Mkfs(partition_path->c_str(), minfs_component, fs_management::MkfsOptions()),
ZX_OK);
// Mount the VPart.
zx::result device = component::Connect<fuchsia_hardware_block::Block>(partition_path.value());
ASSERT_OK(device);
fs_management::MountOptions mounting_options;
auto mounted_filesystem =
fs_management::Mount(std::move(device.value()), minfs_component, mounting_options);
ASSERT_EQ(mounted_filesystem.status_value(), ZX_OK);
auto data = mounted_filesystem->DataRoot();
ASSERT_EQ(data.status_value(), ZX_OK);
auto binding = fs_management::NamespaceBinding::Create(kMountPath, std::move(*data));
ASSERT_EQ(binding.status_value(), ZX_OK);
// Verify that the mount was successful.
fbl::unique_fd rootfd;
ASSERT_OK(fdio_open_fd(kMountPath, static_cast<uint32_t>(fuchsia_io::OpenFlags::kDirectory),
rootfd.reset_and_get_address()));
ASSERT_TRUE(rootfd);
fdio_cpp::FdioCaller caller(std::move(rootfd));
auto result = fidl::WireCall(caller.directory())->QueryFilesystem();
ASSERT_TRUE(result.ok());
const char* kFsName = "minfs";
const char* name = reinterpret_cast<const char*>(result.value().info->name.data());
ASSERT_EQ(strncmp(name, kFsName, strlen(kFsName)), 0, "Unexpected filesystem mounted");
// Verify that MinFS does not try to use more of the VPartition than
// was originally allocated.
ASSERT_LE(result.value().info->total_bytes, kSliceSize * slice_count);
// Clean up.
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
}
// Test that the FVM can recover when one copy of
// metadata becomes corrupt.
TEST_F(FvmTest, TestCorruptionOk) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
// Allocate one VPart (writes to backup)
zx::result vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp(*std::move(vp_or));
// Extend the vpart (writes to primary)
uint64_t offset = 1;
uint64_t length = 1;
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, kSliceSize * 2);
// Initial slice access
CheckWriteReadBlock(vp.as_block(), 0, 1);
// Extended slice access
CheckWriteReadBlock(vp.as_block(), kSliceSize / block_info.block_size, 1);
vp = {};
// Corrupt the (backup) metadata and rebind.
// The 'primary' was the last one written, so it'll be used.
fvm::Header header =
fvm::Header::FromDiskSize(fvm::kMaxUsablePartitions, kBlockSize * kBlockCount, kSliceSize);
auto off = static_cast<off_t>(header.GetSuperblockOffset(fvm::SuperblockType::kSecondary));
uint8_t buf[fvm::kBlockSize];
fidl::UnownedClientEnd device = ramdisk_block_interface();
ASSERT_OK(block_client::SingleReadBytes(device, buf, sizeof(buf), off));
// Modify an arbitrary byte (not the magic bits; we still want it to mount!)
buf[128]++;
ASSERT_OK(block_client::SingleWriteBytes(device, buf, sizeof(buf), off));
FVMRebind();
vp_or = WaitForPartition(kPartition1Matcher);
ASSERT_EQ(vp_or.status_value(), ZX_OK, "Couldn't re-open Data VPart");
vp = *std::move(vp_or);
// The slice extension is still accessible.
CheckWriteReadBlock(vp.as_block(), 0, 1);
CheckWriteReadBlock(vp.as_block(), kSliceSize / block_info.block_size, 1);
// Clean up
vp = {};
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
}
}
TEST_F(FvmTest, TestCorruptionRegression) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
auto volume_info_or = fs_management::FvmQuery(volume_manager.value());
ASSERT_EQ(volume_info_or.status_value(), ZX_OK);
size_t slice_size = volume_info_or->slice_size;
// Allocate one VPart (writes to backup)
zx::result vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp(*std::move(vp_or));
// Extend the vpart (writes to primary)
uint64_t offset = 1;
uint64_t length = 1;
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, slice_size * 2);
// Initial slice access
CheckWriteReadBlock(vp.as_block(), 0, 1);
// Extended slice access
CheckWriteReadBlock(vp.as_block(), slice_size / block_info.block_size, 1);
vp = {};
// Corrupt the (primary) metadata and rebind.
// The 'primary' was the last one written, so the backup will be used.
off_t off = 0;
uint8_t buf[fvm::kBlockSize];
fidl::UnownedClientEnd device = ramdisk_block_interface();
ASSERT_OK(block_client::SingleReadBytes(device, buf, sizeof(buf), off));
buf[128]++;
ASSERT_OK(block_client::SingleWriteBytes(device, buf, sizeof(buf), off));
FVMRebind();
vp_or = WaitForPartition(kPartition1Matcher);
ASSERT_EQ(vp_or.status_value(), ZX_OK);
vp = *std::move(vp_or);
// The slice extension is no longer accessible
CheckWriteReadBlock(vp.as_block(), 0, 1);
CheckNoAccessBlock(vp.as_block(), slice_size / block_info.block_size, 1);
// Clean up
vp = {};
{
zx::result volume_manager = fvm_device();
ASSERT_OK(volume_manager);
FVMCheckSliceSize(volume_manager.value(), kSliceSize);
}
}
TEST_F(FvmTest, TestCorruptionUnrecoverable) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
// Allocate one VPart (writes to backup)
zx::result vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_EQ(vp_or.status_value(), ZX_OK);
PartitionChannel vp(*std::move(vp_or));
// Extend the vpart (writes to primary)
uint64_t offset = 1;
uint64_t length = 1;
{
const fidl::WireResult result = fidl::WireCall(vp.as_volume())->Extend(offset, length);
ASSERT_OK(result.status());
const fidl::WireResponse response = result.value();
ASSERT_OK(response.status);
}
const fidl::WireResult result = fidl::WireCall(vp.as_block())->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
ASSERT_EQ(block_info.block_count * block_info.block_size, kSliceSize * 2);
// Initial slice access
CheckWriteReadBlock(vp.as_block(), 0, 1);
// Extended slice access
CheckWriteReadBlock(vp.as_block(), kSliceSize / block_info.block_size, 1);
vp = {};
// Corrupt both copies of the metadata.
// The 'primary' was the last one written, so the backup will be used.
off_t off = 0;
uint8_t buf[fvm::kBlockSize];
fidl::UnownedClientEnd device = ramdisk_block_interface();
ASSERT_OK(block_client::SingleReadBytes(device, buf, sizeof(buf), off));
buf[128]++;
ASSERT_OK(block_client::SingleWriteBytes(device, buf, sizeof(buf), off));
fvm::Header header =
fvm::Header::FromDiskSize(fvm::kMaxUsablePartitions, kBlockSize * kBlockCount, kSliceSize);
off = static_cast<off_t>(header.GetSuperblockOffset(fvm::SuperblockType::kSecondary));
ASSERT_OK(block_client::SingleReadBytes(device, buf, sizeof(buf), off));
buf[128]++;
ASSERT_OK(block_client::SingleWriteBytes(device, buf, sizeof(buf), off));
ValidateFVM(ramdisk_block_interface(), ValidationResult::Corrupted);
}
// Tests the FVM checker against a just-initialized FVM.
TEST_F(FvmTest, TestCheckNewFVM) {
CreateFVM(512, 1 << 20, 64LU * (1 << 20));
fidl::UnownedClientEnd device = ramdisk_block_interface();
const fidl::WireResult result = fidl::WireCall(device)->GetInfo();
ASSERT_OK(result.status());
const fit::result response = result.value();
ASSERT_TRUE(response.is_ok(), "%s", zx_status_get_string(response.error_value()));
const fuchsia_hardware_block::wire::BlockInfo& block_info = response.value()->info;
fvm::Checker checker(device, block_info.block_size, true);
ASSERT_TRUE(checker.Validate());
}
TEST_F(FvmTest, TestAbortDriverLoadSmallDevice) {
constexpr uint64_t kMB = 1 << 20;
constexpr uint64_t kGB = 1 << 30;
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 50 * kMB / kBlockSize;
constexpr uint64_t kSliceSize = kMB;
constexpr uint64_t kFvmPartitionSize = 4 * kGB;
CreateRamdisk(kBlockSize, kBlockCount);
// Init fvm with a partition bigger than the underlying disk.
fs_management::FvmInitWithSize(ramdisk_block_interface(), kFvmPartitionSize, kSliceSize);
// Try to bind an fvm to the disk.
//
// Bind should return ZX_ERR_IO when the load of a driver fails.
auto resp = fidl::WireCall(ramdisk_controller_interface())->Bind(kFvmDriverLib);
ASSERT_OK(resp.status());
ASSERT_FALSE(resp->is_ok());
ASSERT_EQ(resp->error_value(), ZX_ERR_INTERNAL);
CreateRamdisk(kBlockSize, kBlockCount);
fs_management::FvmInitWithSize(ramdisk_block_interface(), kFvmPartitionSize, kSliceSize);
// Grow the ramdisk to the appropiate size and bind should succeed.
ASSERT_OK(ramdisk_grow(ramdisk(), kFvmPartitionSize));
// Use Controller::Call::Rebind because the driver might still be
// when init fails. Driver removes the device and will eventually be
// unloaded but Controller::Bind above does not wait until
// the device is removed. Controller::Rebind ensures nothing is
// bound to the device, before it tries to bind the driver again.
auto resp2 = fidl::WireCall(ramdisk_controller_interface())->Rebind(kFvmDriverLib);
ASSERT_OK(resp2.status());
ASSERT_TRUE(resp2->is_ok());
ASSERT_OK(device_watcher::RecursiveWaitForFile(devfs_root_fd().get(), fvm_path().c_str()));
}
TEST_F(FvmTest, TestPreventDuplicateDeviceNames) {
constexpr uint64_t kBlockSize = 512;
constexpr uint64_t kBlockCount = 1 << 16;
constexpr uint64_t kSliceSize = 64 * kBlockSize;
CreateFVM(kBlockSize, kBlockCount, kSliceSize);
// When a partition is destroyed, the slot in FVM is synchronously freed but the device is
// asynchronously removed. DFv2 prevents multiple child devices with the same name from being
// bound. This test rapidly allocates and destroys the same partition to try and get a race
// between the new device being bound and the old device being removed to try and get FVM to bind
// multiple devices with the same name.
for (int i = 0; i < 10; ++i) {
zx::result vp_or = AllocatePartition({
.type = kTestPartDataGuid,
.guid = kTestUniqueGuid1,
.name = kTestPartDataName,
});
ASSERT_OK(vp_or.status_value());
auto result = fidl::WireCall(vp_or.value().as_volume())->Destroy();
ASSERT_OK(result.status());
ASSERT_OK(result->status);
}
}
} // namespace