naiveproxy/net/disk_cache/simple/simple_index_file.cc

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2018-02-02 13:49:39 +03:00
// Copyright (c) 2013 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 "net/disk_cache/simple/simple_index_file.h"
#include <utility>
#include <vector>
#include "base/files/file.h"
#include "base/files/file_util.h"
#include "base/files/memory_mapped_file.h"
#include "base/hash.h"
#include "base/logging.h"
#include "base/numerics/safe_conversions.h"
#include "base/pickle.h"
#include "base/single_thread_task_runner.h"
#include "base/task_runner_util.h"
#include "base/threading/thread_restrictions.h"
#include "net/disk_cache/simple/simple_backend_version.h"
#include "net/disk_cache/simple/simple_entry_format.h"
#include "net/disk_cache/simple/simple_histogram_macros.h"
#include "net/disk_cache/simple/simple_index.h"
#include "net/disk_cache/simple/simple_synchronous_entry.h"
#include "net/disk_cache/simple/simple_util.h"
using base::File;
namespace disk_cache {
namespace {
const int kEntryFilesHashLength = 16;
const int kEntryFilesSuffixLength = 2;
// Limit on how big a file we are willing to work with, to avoid crashes
// when its corrupt.
const int kMaxEntriesInIndex = 1000000;
// Here 8 comes from the key size.
const int64_t kMaxIndexFileSizeBytes =
kMaxEntriesInIndex * (8 + EntryMetadata::kOnDiskSizeBytes);
uint32_t CalculatePickleCRC(const base::Pickle& pickle) {
return simple_util::Crc32(pickle.payload(), pickle.payload_size());
}
// Used in histograms. Please only add new values at the end.
enum IndexFileState {
INDEX_STATE_CORRUPT = 0,
INDEX_STATE_STALE = 1,
INDEX_STATE_FRESH = 2,
INDEX_STATE_FRESH_CONCURRENT_UPDATES = 3,
INDEX_STATE_MAX = 4,
};
enum StaleIndexQuality {
STALE_INDEX_OK = 0,
STALE_INDEX_MISSED_ENTRIES = 1,
STALE_INDEX_EXTRA_ENTRIES = 2,
STALE_INDEX_BOTH_MISSED_AND_EXTRA_ENTRIES = 3,
STALE_INDEX_MAX = 4,
};
void UmaRecordIndexFileState(IndexFileState state, net::CacheType cache_type) {
SIMPLE_CACHE_UMA(ENUMERATION,
"IndexFileStateOnLoad", cache_type, state, INDEX_STATE_MAX);
}
void UmaRecordIndexInitMethod(SimpleIndex::IndexInitMethod method,
net::CacheType cache_type) {
SIMPLE_CACHE_UMA(ENUMERATION, "IndexInitializeMethod", cache_type, method,
SimpleIndex::INITIALIZE_METHOD_MAX);
}
void UmaRecordIndexWriteReason(SimpleIndex::IndexWriteToDiskReason reason,
net::CacheType cache_type) {
SIMPLE_CACHE_UMA(ENUMERATION, "IndexWriteReason", cache_type, reason,
SimpleIndex::INDEX_WRITE_REASON_MAX);
}
void UmaRecordIndexWriteReasonAtLoad(SimpleIndex::IndexWriteToDiskReason reason,
net::CacheType cache_type) {
SIMPLE_CACHE_UMA(ENUMERATION, "IndexWriteReasonAtLoad", cache_type, reason,
SimpleIndex::INDEX_WRITE_REASON_MAX);
}
void UmaRecordStaleIndexQuality(int missed_entry_count,
int extra_entry_count,
net::CacheType cache_type) {
SIMPLE_CACHE_UMA(CUSTOM_COUNTS, "StaleIndexMissedEntryCount", cache_type,
missed_entry_count, 1, 100, 5);
SIMPLE_CACHE_UMA(CUSTOM_COUNTS, "StaleIndexExtraEntryCount", cache_type,
extra_entry_count, 1, 100, 5);
StaleIndexQuality quality;
if (missed_entry_count > 0 && extra_entry_count > 0)
quality = STALE_INDEX_BOTH_MISSED_AND_EXTRA_ENTRIES;
else if (missed_entry_count > 0)
quality = STALE_INDEX_MISSED_ENTRIES;
else if (extra_entry_count > 0)
quality = STALE_INDEX_EXTRA_ENTRIES;
else
quality = STALE_INDEX_OK;
SIMPLE_CACHE_UMA(ENUMERATION, "StaleIndexQuality", cache_type, quality,
STALE_INDEX_MAX);
}
bool WritePickleFile(base::Pickle* pickle, const base::FilePath& file_name) {
File file(
file_name,
File::FLAG_CREATE_ALWAYS | File::FLAG_WRITE | File::FLAG_SHARE_DELETE);
if (!file.IsValid())
return false;
int bytes_written =
file.Write(0, static_cast<const char*>(pickle->data()), pickle->size());
if (bytes_written != base::checked_cast<int>(pickle->size())) {
simple_util::SimpleCacheDeleteFile(file_name);
return false;
}
return true;
}
// Called for each cache directory traversal iteration.
void ProcessEntryFile(SimpleIndex::EntrySet* entries,
const base::FilePath& file_path,
base::Time last_accessed,
base::Time last_modified,
int64_t size) {
static const size_t kEntryFilesLength =
kEntryFilesHashLength + kEntryFilesSuffixLength;
// Converting to std::string is OK since we never use UTF8 wide chars in our
// file names.
const base::FilePath::StringType base_name = file_path.BaseName().value();
const std::string file_name(base_name.begin(), base_name.end());
if (file_name.size() != kEntryFilesLength)
return;
const base::StringPiece hash_string(
file_name.begin(), file_name.begin() + kEntryFilesHashLength);
uint64_t hash_key = 0;
if (!simple_util::GetEntryHashKeyFromHexString(hash_string, &hash_key)) {
LOG(WARNING) << "Invalid entry hash key filename while restoring index from"
<< " disk: " << file_name;
return;
}
base::Time last_used_time;
#if defined(OS_POSIX)
// For POSIX systems, a last access time is available. However, it's not
// guaranteed to be more accurate than mtime. It is no worse though.
last_used_time = last_accessed;
#endif
if (last_used_time.is_null())
last_used_time = last_modified;
SimpleIndex::EntrySet::iterator it = entries->find(hash_key);
base::CheckedNumeric<uint32_t> total_entry_size = size;
// Sometimes we see entry sizes here which are nonsense. We can't use them
// as-is, as they simply won't fit the type. The options that come to mind
// are:
// 1) Ignore the file.
// 2) Make something up.
// 3) Delete the files for the hash.
// ("crash the browser" isn't considered a serious alternative).
//
// The problem with doing (1) is that we are recovering the index here, so if
// we don't include the info on the file here, we may completely lose track of
// the entry and never clean the file up.
//
// (2) is actually mostly fine: we may trigger eviction too soon or too late,
// but we can't really do better since we can't trust the size. If the entry
// is never opened, it will eventually get evicted. If it is opened, we will
// re-check the file size, and if it's nonsense delete it there, and if it's
// fine we will fix up the index via a UpdateDataFromEntryStat to have the
// correct size.
//
// (3) does the best thing except when the wrong size is some weird interim
// thing just on directory listing (in which case it may evict an entry
// prematurely). It's a little harder to think about since it involves
// mutating the disk while there are other mutations going on, however,
// while (2) is single-threaded.
//
// Hence this picks (2).
const int kPlaceHolderSizeWhenInvalid = 32768;
if (!total_entry_size.IsValid()) {
LOG(WARNING) << "Invalid file size while restoring index from disk: "
<< size << " on file:" << file_name;
}
if (it == entries->end()) {
SimpleIndex::InsertInEntrySet(
hash_key,
EntryMetadata(last_used_time, total_entry_size.ValueOrDefault(
kPlaceHolderSizeWhenInvalid)),
entries);
} else {
// Summing up the total size of the entry through all the *_[0-1] files
total_entry_size += it->second.GetEntrySize();
it->second.SetEntrySize(
total_entry_size.ValueOrDefault(kPlaceHolderSizeWhenInvalid));
}
}
} // namespace
SimpleIndexLoadResult::SimpleIndexLoadResult()
: did_load(false),
index_write_reason(SimpleIndex::INDEX_WRITE_REASON_MAX),
flush_required(false) {}
SimpleIndexLoadResult::~SimpleIndexLoadResult() = default;
void SimpleIndexLoadResult::Reset() {
did_load = false;
index_write_reason = SimpleIndex::INDEX_WRITE_REASON_MAX;
flush_required = false;
entries.clear();
}
// static
const char SimpleIndexFile::kIndexFileName[] = "the-real-index";
// static
const char SimpleIndexFile::kIndexDirectory[] = "index-dir";
// static
const char SimpleIndexFile::kTempIndexFileName[] = "temp-index";
SimpleIndexFile::IndexMetadata::IndexMetadata()
: magic_number_(kSimpleIndexMagicNumber),
version_(kSimpleVersion),
reason_(SimpleIndex::INDEX_WRITE_REASON_MAX),
entry_count_(0),
cache_size_(0) {}
SimpleIndexFile::IndexMetadata::IndexMetadata(
SimpleIndex::IndexWriteToDiskReason reason,
uint64_t entry_count,
uint64_t cache_size)
: magic_number_(kSimpleIndexMagicNumber),
version_(kSimpleVersion),
reason_(reason),
entry_count_(entry_count),
cache_size_(cache_size) {}
void SimpleIndexFile::IndexMetadata::Serialize(base::Pickle* pickle) const {
DCHECK(pickle);
pickle->WriteUInt64(magic_number_);
pickle->WriteUInt32(version_);
pickle->WriteUInt64(entry_count_);
pickle->WriteUInt64(cache_size_);
pickle->WriteUInt32(static_cast<uint32_t>(reason_));
}
// static
void SimpleIndexFile::SerializeFinalData(base::Time cache_modified,
base::Pickle* pickle) {
pickle->WriteInt64(cache_modified.ToInternalValue());
SimpleIndexFile::PickleHeader* header_p = pickle->headerT<PickleHeader>();
header_p->crc = CalculatePickleCRC(*pickle);
}
bool SimpleIndexFile::IndexMetadata::Deserialize(base::PickleIterator* it) {
DCHECK(it);
bool v6_format_index_read_results =
it->ReadUInt64(&magic_number_) && it->ReadUInt32(&version_) &&
it->ReadUInt64(&entry_count_) && it->ReadUInt64(&cache_size_);
if (!v6_format_index_read_results)
return false;
if (version_ >= 7) {
uint32_t tmp_reason;
if (!it->ReadUInt32(&tmp_reason))
return false;
reason_ = static_cast<SimpleIndex::IndexWriteToDiskReason>(tmp_reason);
}
return true;
}
void SimpleIndexFile::SyncWriteToDisk(net::CacheType cache_type,
const base::FilePath& cache_directory,
const base::FilePath& index_filename,
const base::FilePath& temp_index_filename,
std::unique_ptr<base::Pickle> pickle,
const base::TimeTicks& start_time,
bool app_on_background) {
DCHECK_EQ(index_filename.DirName().value(),
temp_index_filename.DirName().value());
base::FilePath index_file_directory = temp_index_filename.DirName();
if (!base::DirectoryExists(index_file_directory) &&
!base::CreateDirectory(index_file_directory)) {
LOG(ERROR) << "Could not create a directory to hold the index file";
return;
}
// There is a chance that the index containing all the necessary data about
// newly created entries will appear to be stale. This can happen if on-disk
// part of a Create operation does not fit into the time budget for the index
// flush delay. This simple approach will be reconsidered if it does not allow
// for maintaining freshness.
base::Time cache_dir_mtime;
if (!simple_util::GetMTime(cache_directory, &cache_dir_mtime)) {
LOG(ERROR) << "Could obtain information about cache age";
return;
}
SerializeFinalData(cache_dir_mtime, pickle.get());
if (!WritePickleFile(pickle.get(), temp_index_filename)) {
LOG(ERROR) << "Failed to write the temporary index file";
return;
}
// Atomically rename the temporary index file to become the real one.
if (!base::ReplaceFile(temp_index_filename, index_filename, NULL))
return;
if (app_on_background) {
SIMPLE_CACHE_UMA(TIMES,
"IndexWriteToDiskTime.Background", cache_type,
(base::TimeTicks::Now() - start_time));
} else {
SIMPLE_CACHE_UMA(TIMES,
"IndexWriteToDiskTime.Foreground", cache_type,
(base::TimeTicks::Now() - start_time));
}
}
bool SimpleIndexFile::IndexMetadata::CheckIndexMetadata() {
if (entry_count_ > kMaxEntriesInIndex ||
magic_number_ != kSimpleIndexMagicNumber) {
return false;
}
static_assert(kSimpleVersion == 8, "index metadata reader out of date");
// No |reason_| is saved in the version 6 file format.
if (version_ == 6)
return reason_ == SimpleIndex::INDEX_WRITE_REASON_MAX;
return (version_ == 7 || version_ == 8) &&
reason_ < SimpleIndex::INDEX_WRITE_REASON_MAX;
}
SimpleIndexFile::SimpleIndexFile(
const scoped_refptr<base::SequencedTaskRunner>& cache_runner,
const scoped_refptr<base::TaskRunner>& worker_pool,
net::CacheType cache_type,
const base::FilePath& cache_directory)
: cache_runner_(cache_runner),
worker_pool_(worker_pool),
cache_type_(cache_type),
cache_directory_(cache_directory),
index_file_(cache_directory_.AppendASCII(kIndexDirectory)
.AppendASCII(kIndexFileName)),
temp_index_file_(cache_directory_.AppendASCII(kIndexDirectory)
.AppendASCII(kTempIndexFileName)) {}
SimpleIndexFile::~SimpleIndexFile() = default;
void SimpleIndexFile::LoadIndexEntries(base::Time cache_last_modified,
const base::Closure& callback,
SimpleIndexLoadResult* out_result) {
base::Closure task = base::Bind(&SimpleIndexFile::SyncLoadIndexEntries,
cache_type_,
cache_last_modified, cache_directory_,
index_file_, out_result);
worker_pool_->PostTaskAndReply(FROM_HERE, task, callback);
}
void SimpleIndexFile::WriteToDisk(SimpleIndex::IndexWriteToDiskReason reason,
const SimpleIndex::EntrySet& entry_set,
uint64_t cache_size,
const base::TimeTicks& start,
bool app_on_background,
const base::Closure& callback) {
UmaRecordIndexWriteReason(reason, cache_type_);
IndexMetadata index_metadata(reason, entry_set.size(), cache_size);
std::unique_ptr<base::Pickle> pickle = Serialize(index_metadata, entry_set);
base::Closure task =
base::Bind(&SimpleIndexFile::SyncWriteToDisk,
cache_type_, cache_directory_, index_file_, temp_index_file_,
base::Passed(&pickle), start, app_on_background);
if (callback.is_null())
cache_runner_->PostTask(FROM_HERE, task);
else
cache_runner_->PostTaskAndReply(FROM_HERE, task, callback);
}
// static
void SimpleIndexFile::SyncLoadIndexEntries(
net::CacheType cache_type,
base::Time cache_last_modified,
const base::FilePath& cache_directory,
const base::FilePath& index_file_path,
SimpleIndexLoadResult* out_result) {
// Load the index and find its age.
base::Time last_cache_seen_by_index;
SyncLoadFromDisk(index_file_path, &last_cache_seen_by_index, out_result);
// Consider the index loaded if it is fresh.
const bool index_file_existed = base::PathExists(index_file_path);
if (!out_result->did_load) {
if (index_file_existed)
UmaRecordIndexFileState(INDEX_STATE_CORRUPT, cache_type);
} else {
if (cache_last_modified <= last_cache_seen_by_index) {
if (out_result->index_write_reason !=
SimpleIndex::INDEX_WRITE_REASON_MAX) {
UmaRecordIndexWriteReasonAtLoad(out_result->index_write_reason,
cache_type);
}
base::Time latest_dir_mtime;
simple_util::GetMTime(cache_directory, &latest_dir_mtime);
if (LegacyIsIndexFileStale(latest_dir_mtime, index_file_path)) {
UmaRecordIndexFileState(INDEX_STATE_FRESH_CONCURRENT_UPDATES,
cache_type);
} else {
UmaRecordIndexFileState(INDEX_STATE_FRESH, cache_type);
}
out_result->init_method = SimpleIndex::INITIALIZE_METHOD_LOADED;
UmaRecordIndexInitMethod(out_result->init_method, cache_type);
return;
}
UmaRecordIndexFileState(INDEX_STATE_STALE, cache_type);
}
// Reconstruct the index by scanning the disk for entries.
SimpleIndex::EntrySet entries_from_stale_index;
entries_from_stale_index.swap(out_result->entries);
const base::TimeTicks start = base::TimeTicks::Now();
SyncRestoreFromDisk(cache_directory, index_file_path, out_result);
SIMPLE_CACHE_UMA(MEDIUM_TIMES, "IndexRestoreTime", cache_type,
base::TimeTicks::Now() - start);
SIMPLE_CACHE_UMA(COUNTS_1M, "IndexEntriesRestored", cache_type,
out_result->entries.size());
if (index_file_existed) {
out_result->init_method = SimpleIndex::INITIALIZE_METHOD_RECOVERED;
int missed_entry_count = 0;
for (const auto& i : out_result->entries) {
if (entries_from_stale_index.count(i.first) == 0)
++missed_entry_count;
}
int extra_entry_count = 0;
for (const auto& i : entries_from_stale_index) {
if (out_result->entries.count(i.first) == 0)
++extra_entry_count;
}
UmaRecordStaleIndexQuality(missed_entry_count, extra_entry_count,
cache_type);
} else {
out_result->init_method = SimpleIndex::INITIALIZE_METHOD_NEWCACHE;
SIMPLE_CACHE_UMA(COUNTS_1M,
"IndexCreatedEntryCount", cache_type,
out_result->entries.size());
}
UmaRecordIndexInitMethod(out_result->init_method, cache_type);
}
// static
void SimpleIndexFile::SyncLoadFromDisk(const base::FilePath& index_filename,
base::Time* out_last_cache_seen_by_index,
SimpleIndexLoadResult* out_result) {
out_result->Reset();
File file(index_filename, File::FLAG_OPEN | File::FLAG_READ |
File::FLAG_SHARE_DELETE |
File::FLAG_SEQUENTIAL_SCAN);
if (!file.IsValid())
return;
// Sanity-check the length. We don't want to crash trying to read some corrupt
// 10GiB file or such.
int64_t file_length = file.GetLength();
if (file_length < 0 || file_length > kMaxIndexFileSizeBytes) {
simple_util::SimpleCacheDeleteFile(index_filename);
return;
}
// Make sure to preallocate in one chunk, so we don't induce fragmentation
// reallocating a growing buffer.
auto buffer = std::make_unique<char[]>(file_length);
int read = file.Read(0, buffer.get(), file_length);
if (read < file_length) {
simple_util::SimpleCacheDeleteFile(index_filename);
return;
}
SimpleIndexFile::Deserialize(buffer.get(), read, out_last_cache_seen_by_index,
out_result);
if (!out_result->did_load)
simple_util::SimpleCacheDeleteFile(index_filename);
}
// static
std::unique_ptr<base::Pickle> SimpleIndexFile::Serialize(
const SimpleIndexFile::IndexMetadata& index_metadata,
const SimpleIndex::EntrySet& entries) {
std::unique_ptr<base::Pickle> pickle(
new base::Pickle(sizeof(SimpleIndexFile::PickleHeader)));
index_metadata.Serialize(pickle.get());
for (SimpleIndex::EntrySet::const_iterator it = entries.begin();
it != entries.end(); ++it) {
pickle->WriteUInt64(it->first);
it->second.Serialize(pickle.get());
}
return pickle;
}
// static
void SimpleIndexFile::Deserialize(const char* data, int data_len,
base::Time* out_cache_last_modified,
SimpleIndexLoadResult* out_result) {
DCHECK(data);
out_result->Reset();
SimpleIndex::EntrySet* entries = &out_result->entries;
base::Pickle pickle(data, data_len);
if (!pickle.data()) {
LOG(WARNING) << "Corrupt Simple Index File.";
return;
}
base::PickleIterator pickle_it(pickle);
SimpleIndexFile::PickleHeader* header_p =
pickle.headerT<SimpleIndexFile::PickleHeader>();
const uint32_t crc_read = header_p->crc;
const uint32_t crc_calculated = CalculatePickleCRC(pickle);
if (crc_read != crc_calculated) {
LOG(WARNING) << "Invalid CRC in Simple Index file.";
return;
}
SimpleIndexFile::IndexMetadata index_metadata;
if (!index_metadata.Deserialize(&pickle_it)) {
LOG(ERROR) << "Invalid index_metadata on Simple Cache Index.";
return;
}
if (!index_metadata.CheckIndexMetadata()) {
LOG(ERROR) << "Invalid index_metadata on Simple Cache Index.";
return;
}
entries->reserve(index_metadata.entry_count() + kExtraSizeForMerge);
while (entries->size() < index_metadata.entry_count()) {
uint64_t hash_key;
EntryMetadata entry_metadata;
if (!pickle_it.ReadUInt64(&hash_key) ||
!entry_metadata.Deserialize(
&pickle_it, index_metadata.has_entry_in_memory_data())) {
LOG(WARNING) << "Invalid EntryMetadata in Simple Index file.";
entries->clear();
return;
}
SimpleIndex::InsertInEntrySet(hash_key, entry_metadata, entries);
}
int64_t cache_last_modified;
if (!pickle_it.ReadInt64(&cache_last_modified)) {
entries->clear();
return;
}
DCHECK(out_cache_last_modified);
*out_cache_last_modified = base::Time::FromInternalValue(cache_last_modified);
out_result->index_write_reason = index_metadata.reason();
out_result->did_load = true;
}
// static
void SimpleIndexFile::SyncRestoreFromDisk(
const base::FilePath& cache_directory,
const base::FilePath& index_file_path,
SimpleIndexLoadResult* out_result) {
VLOG(1) << "Simple Cache Index is being restored from disk.";
simple_util::SimpleCacheDeleteFile(index_file_path);
out_result->Reset();
SimpleIndex::EntrySet* entries = &out_result->entries;
const bool did_succeed = TraverseCacheDirectory(
cache_directory, base::Bind(&ProcessEntryFile, entries));
if (!did_succeed) {
LOG(ERROR) << "Could not reconstruct index from disk";
return;
}
out_result->did_load = true;
// When we restore from disk we write the merged index file to disk right
// away, this might save us from having to restore again next time.
out_result->flush_required = true;
}
// static
bool SimpleIndexFile::LegacyIsIndexFileStale(
base::Time cache_last_modified,
const base::FilePath& index_file_path) {
base::Time index_mtime;
if (!simple_util::GetMTime(index_file_path, &index_mtime))
return true;
return index_mtime < cache_last_modified;
}
} // namespace disk_cache