// Copyright (c) 2012 The Chromium 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 "chrome/browser/chromeos/drive/file_cache.h"
#include <vector>
#include "base/file_util.h"
#include "base/files/file_enumerator.h"
#include "base/logging.h"
#include "base/metrics/histogram.h"
#include "base/strings/string_util.h"
#include "base/strings/stringprintf.h"
#include "base/sys_info.h"
#include "chrome/browser/chromeos/drive/drive.pb.h"
#include "chrome/browser/chromeos/drive/file_system_util.h"
#include "chrome/browser/chromeos/drive/resource_metadata_storage.h"
#include "chrome/browser/drive/drive_api_util.h"
#include "chromeos/chromeos_constants.h"
#include "content/public/browser/browser_thread.h"
#include "net/base/mime_sniffer.h"
#include "net/base/mime_util.h"
#include "net/base/net_util.h"
#include "third_party/cros_system_api/constants/cryptohome.h"
using content::BrowserThread;
namespace drive {
namespace internal {
namespace {
// Returns ID extracted from the path.
std::string GetIdFromPath(const base::FilePath& path) {
return util::UnescapeCacheFileName(path.BaseName().AsUTF8Unsafe());
}
} // namespace
FileCache::FileCache(ResourceMetadataStorage* storage,
const base::FilePath& cache_file_directory,
base::SequencedTaskRunner* blocking_task_runner,
FreeDiskSpaceGetterInterface* free_disk_space_getter)
: cache_file_directory_(cache_file_directory),
blocking_task_runner_(blocking_task_runner),
storage_(storage),
free_disk_space_getter_(free_disk_space_getter),
weak_ptr_factory_(this) {
DCHECK(blocking_task_runner_.get());
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
}
FileCache::~FileCache() {
// Must be on the sequenced worker pool, as |metadata_| must be deleted on
// the sequenced worker pool.
AssertOnSequencedWorkerPool();
}
base::FilePath FileCache::GetCacheFilePath(const std::string& id) const {
return cache_file_directory_.Append(
base::FilePath::FromUTF8Unsafe(util::EscapeCacheFileName(id)));
}
void FileCache::AssertOnSequencedWorkerPool() {
DCHECK(blocking_task_runner_->RunsTasksOnCurrentThread());
}
bool FileCache::IsUnderFileCacheDirectory(const base::FilePath& path) const {
return cache_file_directory_.IsParent(path);
}
bool FileCache::GetCacheEntry(const std::string& id, FileCacheEntry* entry) {
DCHECK(entry);
AssertOnSequencedWorkerPool();
return storage_->GetCacheEntry(id, entry);
}
scoped_ptr<FileCache::Iterator> FileCache::GetIterator() {
AssertOnSequencedWorkerPool();
return storage_->GetCacheEntryIterator();
}
bool FileCache::FreeDiskSpaceIfNeededFor(int64 num_bytes) {
AssertOnSequencedWorkerPool();
// Do nothing and return if we have enough space.
if (HasEnoughSpaceFor(num_bytes, cache_file_directory_))
return true;
// Otherwise, try to free up the disk space.
DVLOG(1) << "Freeing up disk space for " << num_bytes;
// Remove all entries unless specially marked.
scoped_ptr<ResourceMetadataStorage::CacheEntryIterator> it =
storage_->GetCacheEntryIterator();
for (; !it->IsAtEnd(); it->Advance()) {
const FileCacheEntry& entry = it->GetValue();
if (!entry.is_pinned() &&
!entry.is_dirty() &&
!mounted_files_.count(it->GetID()))
storage_->RemoveCacheEntry(it->GetID());
}
DCHECK(!it->HasError());
// Remove all files which have no corresponding cache entries.
base::FileEnumerator enumerator(cache_file_directory_,
false, // not recursive
base::FileEnumerator::FILES);
FileCacheEntry entry;
for (base::FilePath current = enumerator.Next(); !current.empty();
current = enumerator.Next()) {
std::string id = GetIdFromPath(current);
if (!storage_->GetCacheEntry(id, &entry))
base::DeleteFile(current, false /* recursive */);
}
// Check the disk space again.
return HasEnoughSpaceFor(num_bytes, cache_file_directory_);
}
FileError FileCache::GetFile(const std::string& id,
base::FilePath* cache_file_path) {
AssertOnSequencedWorkerPool();
DCHECK(cache_file_path);
FileCacheEntry cache_entry;
if (!storage_->GetCacheEntry(id, &cache_entry) ||
!cache_entry.is_present())
return FILE_ERROR_NOT_FOUND;
*cache_file_path = GetCacheFilePath(id);
return FILE_ERROR_OK;
}
FileError FileCache::Store(const std::string& id,
const std::string& md5,
const base::FilePath& source_path,
FileOperationType file_operation_type) {
AssertOnSequencedWorkerPool();
int64 file_size = 0;
if (file_operation_type == FILE_OPERATION_COPY) {
if (!base::GetFileSize(source_path, &file_size)) {
LOG(WARNING) << "Couldn't get file size for: " << source_path.value();
return FILE_ERROR_FAILED;
}
}
if (!FreeDiskSpaceIfNeededFor(file_size))
return FILE_ERROR_NO_LOCAL_SPACE;
FileCacheEntry cache_entry;
storage_->GetCacheEntry(id, &cache_entry);
// If file is dirty or mounted, return error.
if (cache_entry.is_dirty() || mounted_files_.count(id))
return FILE_ERROR_IN_USE;
base::FilePath dest_path = GetCacheFilePath(id);
bool success = false;
switch (file_operation_type) {
case FILE_OPERATION_MOVE:
success = base::Move(source_path, dest_path);
break;
case FILE_OPERATION_COPY:
success = base::CopyFile(source_path, dest_path);
break;
default:
NOTREACHED();
}
if (!success) {
LOG(ERROR) << "Failed to store: "
<< "source_path = " << source_path.value() << ", "
<< "dest_path = " << dest_path.value() << ", "
<< "file_operation_type = " << file_operation_type;
return FILE_ERROR_FAILED;
}
// Now that file operations have completed, update metadata.
cache_entry.set_md5(md5);
cache_entry.set_is_present(true);
cache_entry.set_is_dirty(false);
return storage_->PutCacheEntry(id, cache_entry) ?
FILE_ERROR_OK : FILE_ERROR_FAILED;
}
FileError FileCache::Pin(const std::string& id) {
AssertOnSequencedWorkerPool();
FileCacheEntry cache_entry;
storage_->GetCacheEntry(id, &cache_entry);
cache_entry.set_is_pinned(true);
return storage_->PutCacheEntry(id, cache_entry) ?
FILE_ERROR_OK : FILE_ERROR_FAILED;
}
FileError FileCache::Unpin(const std::string& id) {
AssertOnSequencedWorkerPool();
// Unpinning a file means its entry must exist in cache.
FileCacheEntry cache_entry;
if (!storage_->GetCacheEntry(id, &cache_entry))
return FILE_ERROR_NOT_FOUND;
// Now that file operations have completed, update metadata.
if (cache_entry.is_present()) {
cache_entry.set_is_pinned(false);
if (!storage_->PutCacheEntry(id, cache_entry))
return FILE_ERROR_FAILED;
} else {
// Remove the existing entry if we are unpinning a non-present file.
if (!storage_->RemoveCacheEntry(id))
return FILE_ERROR_FAILED;
}
// Now it's a chance to free up space if needed.
FreeDiskSpaceIfNeededFor(0);
return FILE_ERROR_OK;
}
FileError FileCache::MarkAsMounted(const std::string& id,
base::FilePath* cache_file_path) {
AssertOnSequencedWorkerPool();
DCHECK(cache_file_path);
// Get cache entry associated with the id and md5
FileCacheEntry cache_entry;
if (!storage_->GetCacheEntry(id, &cache_entry))
return FILE_ERROR_NOT_FOUND;
if (mounted_files_.count(id))
return FILE_ERROR_INVALID_OPERATION;
// Ensure the file is readable to cros_disks. See crbug.com/236994.
base::FilePath path = GetCacheFilePath(id);
if (!base::SetPosixFilePermissions(
path,
base::FILE_PERMISSION_READ_BY_USER |
base::FILE_PERMISSION_WRITE_BY_USER |
base::FILE_PERMISSION_READ_BY_GROUP |
base::FILE_PERMISSION_READ_BY_OTHERS))
return FILE_ERROR_FAILED;
mounted_files_.insert(id);
*cache_file_path = path;
return FILE_ERROR_OK;
}
FileError FileCache::MarkDirty(const std::string& id) {
AssertOnSequencedWorkerPool();
// Marking a file dirty means its entry and actual file blob must exist in
// cache.
FileCacheEntry cache_entry;
if (!storage_->GetCacheEntry(id, &cache_entry) ||
!cache_entry.is_present()) {
LOG(WARNING) << "Can't mark dirty a file that wasn't cached: " << id;
return FILE_ERROR_NOT_FOUND;
}
if (cache_entry.is_dirty())
return FILE_ERROR_OK;
cache_entry.set_is_dirty(true);
return storage_->PutCacheEntry(id, cache_entry) ?
FILE_ERROR_OK : FILE_ERROR_FAILED;
}
FileError FileCache::ClearDirty(const std::string& id, const std::string& md5) {
AssertOnSequencedWorkerPool();
// Clearing a dirty file means its entry and actual file blob must exist in
// cache.
FileCacheEntry cache_entry;
if (!storage_->GetCacheEntry(id, &cache_entry) ||
!cache_entry.is_present()) {
LOG(WARNING) << "Can't clear dirty state of a file that wasn't cached: "
<< id;
return FILE_ERROR_NOT_FOUND;
}
// If a file is not dirty (it should have been marked dirty via
// MarkDirtyInCache), clearing its dirty state is an invalid operation.
if (!cache_entry.is_dirty()) {
LOG(WARNING) << "Can't clear dirty state of a non-dirty file: " << id;
return FILE_ERROR_INVALID_OPERATION;
}
cache_entry.set_md5(md5);
cache_entry.set_is_dirty(false);
return storage_->PutCacheEntry(id, cache_entry) ?
FILE_ERROR_OK : FILE_ERROR_FAILED;
}
FileError FileCache::Remove(const std::string& id) {
AssertOnSequencedWorkerPool();
FileCacheEntry cache_entry;
// If entry doesn't exist, nothing to do.
if (!storage_->GetCacheEntry(id, &cache_entry))
return FILE_ERROR_OK;
// Cannot delete a mounted file.
if (mounted_files_.count(id))
return FILE_ERROR_IN_USE;
// Delete the file.
base::FilePath path = GetCacheFilePath(id);
if (!base::DeleteFile(path, false /* recursive */))
return FILE_ERROR_FAILED;
// Now that all file operations have completed, remove from metadata.
return storage_->RemoveCacheEntry(id) ? FILE_ERROR_OK : FILE_ERROR_FAILED;
}
bool FileCache::ClearAll() {
AssertOnSequencedWorkerPool();
// Remove entries on the metadata.
scoped_ptr<ResourceMetadataStorage::CacheEntryIterator> it =
storage_->GetCacheEntryIterator();
for (; !it->IsAtEnd(); it->Advance()) {
if (!storage_->RemoveCacheEntry(it->GetID()))
return false;
}
if (it->HasError())
return false;
// Remove files.
base::FileEnumerator enumerator(cache_file_directory_,
false, // not recursive
base::FileEnumerator::FILES);
for (base::FilePath file = enumerator.Next(); !file.empty();
file = enumerator.Next())
base::DeleteFile(file, false /* recursive */);
return true;
}
bool FileCache::Initialize() {
AssertOnSequencedWorkerPool();
if (!RenameCacheFilesToNewFormat())
return false;
return true;
}
void FileCache::Destroy() {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
// Invalidate the weak pointer.
weak_ptr_factory_.InvalidateWeakPtrs();
// Destroy myself on the blocking pool.
// Note that base::DeletePointer<> cannot be used as the destructor of this
// class is private.
blocking_task_runner_->PostTask(
FROM_HERE,
base::Bind(&FileCache::DestroyOnBlockingPool, base::Unretained(this)));
}
void FileCache::DestroyOnBlockingPool() {
AssertOnSequencedWorkerPool();
delete this;
}
bool FileCache::RecoverFilesFromCacheDirectory(
const base::FilePath& dest_directory,
const ResourceMetadataStorage::RecoveredCacheInfoMap&
recovered_cache_info) {
int file_number = 1;
base::FileEnumerator enumerator(cache_file_directory_,
false, // not recursive
base::FileEnumerator::FILES);
for (base::FilePath current = enumerator.Next(); !current.empty();
current = enumerator.Next()) {
const std::string& id = GetIdFromPath(current);
FileCacheEntry entry;
if (storage_->GetCacheEntry(id, &entry)) {
// This file is managed by FileCache, no need to recover it.
continue;
}
// If a cache entry which is non-dirty and has matching MD5 is found in
// |recovered_cache_entries|, it means the current file is already uploaded
// to the server. Just delete it instead of recovering it.
ResourceMetadataStorage::RecoveredCacheInfoMap::const_iterator it =
recovered_cache_info.find(id);
if (it != recovered_cache_info.end()) {
// Due to the DB corruption, cache info might be recovered from old
// revision. Perform MD5 check even when is_dirty is false just in case.
if (!it->second.is_dirty &&
it->second.md5 == util::GetMd5Digest(current)) {
base::DeleteFile(current, false /* recursive */);
continue;
}
}
// Read file contents to sniff mime type.
std::vector<char> content(net::kMaxBytesToSniff);
const int read_result =
base::ReadFile(current, &content[0], content.size());
if (read_result < 0) {
LOG(WARNING) << "Cannot read: " << current.value();
return false;
}
if (read_result == 0) // Skip empty files.
continue;
// Use recovered file name if available, otherwise decide file name with
// sniffed mime type.
base::FilePath dest_base_name(FILE_PATH_LITERAL("file"));
std::string mime_type;
if (it != recovered_cache_info.end() && !it->second.title.empty()) {
// We can use a file name recovered from the trashed DB.
dest_base_name = base::FilePath::FromUTF8Unsafe(it->second.title);
} else if (net::SniffMimeType(&content[0], read_result,
net::FilePathToFileURL(current),
std::string(), &mime_type) ||
net::SniffMimeTypeFromLocalData(&content[0], read_result,
&mime_type)) {
// Change base name for common mime types.
if (net::MatchesMimeType("image/*", mime_type)) {
dest_base_name = base::FilePath(FILE_PATH_LITERAL("image"));
} else if (net::MatchesMimeType("video/*", mime_type)) {
dest_base_name = base::FilePath(FILE_PATH_LITERAL("video"));
} else if (net::MatchesMimeType("audio/*", mime_type)) {
dest_base_name = base::FilePath(FILE_PATH_LITERAL("audio"));
}
// Estimate extension from mime type.
std::vector<base::FilePath::StringType> extensions;
base::FilePath::StringType extension;
if (net::GetPreferredExtensionForMimeType(mime_type, &extension))
extensions.push_back(extension);
else
net::GetExtensionsForMimeType(mime_type, &extensions);
// Add extension if possible.
if (!extensions.empty())
dest_base_name = dest_base_name.AddExtension(extensions[0]);
}
// Add file number to the file name and move.
const base::FilePath& dest_path = dest_directory.Append(dest_base_name)
.InsertBeforeExtensionASCII(base::StringPrintf("%08d", file_number++));
if (!base::CreateDirectory(dest_directory) ||
!base::Move(current, dest_path)) {
LOG(WARNING) << "Failed to move: " << current.value()
<< " to " << dest_path.value();
return false;
}
}
UMA_HISTOGRAM_COUNTS("Drive.NumberOfCacheFilesRecoveredAfterDBCorruption",
file_number - 1);
return true;
}
FileError FileCache::MarkAsUnmounted(const base::FilePath& file_path) {
AssertOnSequencedWorkerPool();
DCHECK(IsUnderFileCacheDirectory(file_path));
std::string id = GetIdFromPath(file_path);
// Get cache entry associated with the id and md5
FileCacheEntry cache_entry;
if (!storage_->GetCacheEntry(id, &cache_entry))
return FILE_ERROR_NOT_FOUND;
std::set<std::string>::iterator it = mounted_files_.find(id);
if (it == mounted_files_.end())
return FILE_ERROR_INVALID_OPERATION;
mounted_files_.erase(it);
return FILE_ERROR_OK;
}
bool FileCache::HasEnoughSpaceFor(int64 num_bytes,
const base::FilePath& path) {
int64 free_space = 0;
if (free_disk_space_getter_)
free_space = free_disk_space_getter_->AmountOfFreeDiskSpace();
else
free_space = base::SysInfo::AmountOfFreeDiskSpace(path);
// Subtract this as if this portion does not exist.
free_space -= cryptohome::kMinFreeSpaceInBytes;
return (free_space >= num_bytes);
}
bool FileCache::RenameCacheFilesToNewFormat() {
base::FileEnumerator enumerator(cache_file_directory_,
false, // not recursive
base::FileEnumerator::FILES);
for (base::FilePath current = enumerator.Next(); !current.empty();
current = enumerator.Next()) {
base::FilePath new_path = current.RemoveExtension();
if (!new_path.Extension().empty()) {
// Delete files with multiple extensions.
if (!base::DeleteFile(current, false /* recursive */))
return false;
continue;
}
const std::string& id = GetIdFromPath(new_path);
new_path = GetCacheFilePath(util::CanonicalizeResourceId(id));
if (new_path != current && !base::Move(current, new_path))
return false;
}
return true;
}
} // namespace internal
} // namespace drive