naiveproxy/net/disk_cache/simple/simple_synchronous_entry.h
2018-01-29 00:30:36 +08:00

443 lines
16 KiB
C++

// 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.
#ifndef NET_DISK_CACHE_SIMPLE_SIMPLE_SYNCHRONOUS_ENTRY_H_
#define NET_DISK_CACHE_SIMPLE_SIMPLE_SYNCHRONOUS_ENTRY_H_
#include <stdint.h>
#include <algorithm>
#include <map>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "base/feature_list.h"
#include "base/files/file.h"
#include "base/files/file_path.h"
#include "base/gtest_prod_util.h"
#include "base/memory/ref_counted.h"
#include "base/strings/string_piece_forward.h"
#include "base/time/time.h"
#include "net/base/cache_type.h"
#include "net/base/net_export.h"
#include "net/disk_cache/simple/simple_entry_format.h"
namespace net {
class GrowableIOBuffer;
class IOBuffer;
}
FORWARD_DECLARE_TEST(DiskCacheBackendTest, SimpleCacheEnumerationLongKeys);
namespace disk_cache {
NET_EXPORT_PRIVATE extern const base::Feature kSimpleCachePrefetchExperiment;
NET_EXPORT_PRIVATE extern const char kSimplePrefetchBytesParam[];
// Returns how large a file would get prefetched on reading the entry.
// If the experiment is disabled, returns 0.
NET_EXPORT_PRIVATE int GetSimpleCachePrefetchSize();
class SimpleSynchronousEntry;
// This class handles the passing of data about the entry between
// SimpleEntryImplementation and SimpleSynchronousEntry and the computation of
// file offsets based on the data size for all streams.
class NET_EXPORT_PRIVATE SimpleEntryStat {
public:
SimpleEntryStat(base::Time last_used,
base::Time last_modified,
const int32_t data_size[],
const int32_t sparse_data_size);
int GetOffsetInFile(size_t key_length, int offset, int stream_index) const;
int GetEOFOffsetInFile(size_t key_length, int stream_index) const;
int GetLastEOFOffsetInFile(size_t key_length, int file_index) const;
int64_t GetFileSize(size_t key_length, int file_index) const;
base::Time last_used() const { return last_used_; }
base::Time last_modified() const { return last_modified_; }
void set_last_used(base::Time last_used) { last_used_ = last_used; }
void set_last_modified(base::Time last_modified) {
last_modified_ = last_modified;
}
int32_t data_size(int stream_index) const { return data_size_[stream_index]; }
void set_data_size(int stream_index, int data_size) {
data_size_[stream_index] = data_size;
}
int32_t sparse_data_size() const { return sparse_data_size_; }
void set_sparse_data_size(int32_t sparse_data_size) {
sparse_data_size_ = sparse_data_size;
}
private:
base::Time last_used_;
base::Time last_modified_;
int32_t data_size_[kSimpleEntryStreamCount];
int32_t sparse_data_size_;
};
struct SimpleStreamPrefetchData {
SimpleStreamPrefetchData();
~SimpleStreamPrefetchData();
scoped_refptr<net::GrowableIOBuffer> data;
uint32_t stream_crc32;
};
struct SimpleEntryCreationResults {
explicit SimpleEntryCreationResults(SimpleEntryStat entry_stat);
~SimpleEntryCreationResults();
SimpleSynchronousEntry* sync_entry;
// Expectation is that [0] will always be filled in, but [1] might not be.
SimpleStreamPrefetchData stream_prefetch_data[2];
SimpleEntryStat entry_stat;
int result;
};
// Worker thread interface to the very simple cache. This interface is not
// thread safe, and callers must ensure that it is only ever accessed from
// a single thread between synchronization points.
class SimpleSynchronousEntry {
public:
struct CRCRecord {
CRCRecord();
CRCRecord(int index_p, bool has_crc32_p, uint32_t data_crc32_p);
int index;
bool has_crc32;
uint32_t data_crc32;
};
struct CRCRequest {
CRCRequest()
: data_crc32(0),
request_verify(false),
performed_verify(false),
verify_ok(false) {}
// Initial CRC, to be updated with CRC of block.
uint32_t data_crc32;
// If true, CRC should be verified if at end of stream.
bool request_verify;
// If true, CRC was actually checked.
bool performed_verify;
bool verify_ok;
};
struct EntryOperationData {
EntryOperationData(int index_p, int offset_p, int buf_len_p);
EntryOperationData(int index_p,
int offset_p,
int buf_len_p,
bool truncate_p,
bool doomed_p);
EntryOperationData(int64_t sparse_offset_p, int buf_len_p);
int index;
int offset;
int64_t sparse_offset;
int buf_len;
bool truncate;
bool doomed;
};
// Opens a disk cache entry on disk. The |key| parameter is optional, if empty
// the operation may be slower. The |entry_hash| parameter is required.
// |had_index| is provided only for histograms.
// |time_enqueued| is when this operation was added to the I/O thread pool,
// and is provided only for histograms.
static void OpenEntry(net::CacheType cache_type,
const base::FilePath& path,
const std::string& key,
uint64_t entry_hash,
bool had_index,
const base::TimeTicks& time_enqueued,
SimpleEntryCreationResults* out_results);
static void CreateEntry(net::CacheType cache_type,
const base::FilePath& path,
const std::string& key,
uint64_t entry_hash,
bool had_index,
const base::TimeTicks& time_enqueued,
SimpleEntryCreationResults* out_results);
// Deletes an entry from the file system without affecting the state of the
// corresponding instance, if any (allowing operations to continue to be
// executed through that instance). Returns a net error code.
static int DoomEntry(const base::FilePath& path, uint64_t entry_hash);
// Like |DoomEntry()| above, except that it truncates the entry files rather
// than deleting them. Used when dooming entries after the backend has
// shutdown. See implementation of |SimpleEntryImpl::DoomEntryInternal()| for
// more.
static int TruncateEntryFiles(const base::FilePath& path,
uint64_t entry_hash);
// Like |DoomEntry()| above. Deletes all entries corresponding to the
// |key_hashes|. Succeeds only when all entries are deleted. Returns a net
// error code.
static int DoomEntrySet(const std::vector<uint64_t>* key_hashes,
const base::FilePath& path);
// N.B. ReadData(), WriteData(), CheckEOFRecord(), ReadSparseData(),
// WriteSparseData() and Close() may block on IO.
//
// All of these methods will put the //net return value into |*out_result|.
// |crc_request| can be nullptr here, to denote that no CRC computation is
// requested.
void ReadData(const EntryOperationData& in_entry_op,
CRCRequest* crc_request,
SimpleEntryStat* entry_stat,
net::IOBuffer* out_buf,
int* out_result);
void WriteData(const EntryOperationData& in_entry_op,
net::IOBuffer* in_buf,
SimpleEntryStat* out_entry_stat,
int* out_result);
int CheckEOFRecord(int stream_index,
const SimpleEntryStat& entry_stat,
uint32_t expected_crc32);
void ReadSparseData(const EntryOperationData& in_entry_op,
net::IOBuffer* out_buf,
base::Time* out_last_used,
int* out_result);
void WriteSparseData(const EntryOperationData& in_entry_op,
net::IOBuffer* in_buf,
uint64_t max_sparse_data_size,
SimpleEntryStat* out_entry_stat,
int* out_result);
void GetAvailableRange(const EntryOperationData& in_entry_op,
int64_t* out_start,
int* out_result);
// Close all streams, and add write EOF records to streams indicated by the
// CRCRecord entries in |crc32s_to_write|.
void Close(const SimpleEntryStat& entry_stat,
std::unique_ptr<std::vector<CRCRecord>> crc32s_to_write,
net::GrowableIOBuffer* stream_0_data);
const base::FilePath& path() const { return path_; }
std::string key() const { return key_; }
private:
FRIEND_TEST_ALL_PREFIXES(::DiskCacheBackendTest,
SimpleCacheEnumerationLongKeys);
enum CreateEntryResult {
CREATE_ENTRY_SUCCESS = 0,
CREATE_ENTRY_PLATFORM_FILE_ERROR = 1,
CREATE_ENTRY_CANT_WRITE_HEADER = 2,
CREATE_ENTRY_CANT_WRITE_KEY = 3,
CREATE_ENTRY_MAX = 4,
};
enum FileRequired {
FILE_NOT_REQUIRED,
FILE_REQUIRED
};
struct SparseRange {
int64_t offset;
int64_t length;
uint32_t data_crc32;
int64_t file_offset;
bool operator<(const SparseRange& other) const {
return offset < other.offset;
}
};
// When opening an entry without knowing the key, the header must be read
// without knowing the size of the key. This is how much to read initially, to
// make it likely the entire key is read.
static const size_t kInitialHeaderRead = 64 * 1024;
SimpleSynchronousEntry(net::CacheType cache_type,
const base::FilePath& path,
const std::string& key,
uint64_t entry_hash,
bool had_index);
// Like Entry, the SimpleSynchronousEntry self releases when Close() is
// called.
~SimpleSynchronousEntry();
// Tries to open one of the cache entry files. Succeeds if the open succeeds
// or if the file was not found and is allowed to be omitted if the
// corresponding stream is empty.
bool MaybeOpenFile(int file_index,
base::File::Error* out_error);
// Creates one of the cache entry files if necessary. If the file is allowed
// to be omitted if the corresponding stream is empty, and if |file_required|
// is FILE_NOT_REQUIRED, then the file is not created; otherwise, it is.
bool MaybeCreateFile(int file_index,
FileRequired file_required,
base::File::Error* out_error);
bool OpenFiles(SimpleEntryStat* out_entry_stat);
bool CreateFiles(SimpleEntryStat* out_entry_stat);
void CloseFile(int index);
void CloseFiles();
// Read the header and key at the beginning of the file, and validate that
// they are correct. If this entry was opened with a key, the key is checked
// for a match. If not, then the |key_| member is set based on the value in
// this header. Records histograms if any check is failed.
bool CheckHeaderAndKey(int file_index);
// Returns a net error, i.e. net::OK on success.
int InitializeForOpen(SimpleEntryStat* out_entry_stat,
SimpleStreamPrefetchData stream_prefetch_data[2]);
// Writes the header and key to a newly-created stream file. |index| is the
// index of the stream. Returns true on success; returns false and sets
// |*out_result| on failure.
bool InitializeCreatedFile(int index, CreateEntryResult* out_result);
// Returns a net error, including net::OK on success and net::FILE_EXISTS
// when the entry already exists.
int InitializeForCreate(SimpleEntryStat* out_entry_stat);
// Allocates and fills a buffer with stream 0 data in |stream_0_data|, then
// checks its crc32. May also optionally read in |stream_1_data| and its
// crc, but might decide not to.
int ReadAndValidateStream0AndMaybe1(
int file_size,
SimpleEntryStat* out_entry_stat,
SimpleStreamPrefetchData stream_prefetch_data[2]);
// Reads the EOF record located at |file_offset| in file |file_index|,
// with |file_0_prefetch| ptentially having prefetched file 0 content.
// Puts the result into |*eof_record| and sanity-checks it.
// Returns net status, and records any failures to UMA.
int GetEOFRecordData(base::StringPiece file_0_prefetch,
int file_index,
int file_offset,
SimpleFileEOF* eof_record);
// Reads either from |file_0_prefetch| or files_[file_index].
// Range-checks all the in-memory reads.
bool ReadFromFileOrPrefetched(base::StringPiece file_0_prefetch,
int file_index,
int offset,
int size,
char* dest);
// Extracts out the payload of stream |stream_index|, reading either from
// |file_0_prefetch|, if available, or the file. |entry_stat| will be used to
// determine file layout, though |extra_size| additional bytes will be read
// past the stream payload end.
//
// |*stream_data| will be pointed to a fresh buffer with the results,
// and |*out_crc32| will get the checksum, which will be verified against
// |eof_record|.
int PreReadStreamPayload(base::StringPiece file_0_prefetch,
int stream_index,
int extra_size,
const SimpleEntryStat& entry_stat,
const SimpleFileEOF& eof_record,
SimpleStreamPrefetchData* out);
void Doom() const;
// Opens the sparse data file and scans it if it exists.
bool OpenSparseFileIfExists(int32_t* out_sparse_data_size);
// Creates and initializes the sparse data file.
bool CreateSparseFile();
// Closes the sparse data file.
void CloseSparseFile();
// Writes the header to the (newly-created) sparse file.
bool InitializeSparseFile();
// Removes all but the header of the sparse file.
bool TruncateSparseFile();
// Scans the existing ranges in the sparse file. Populates |sparse_ranges_|
// and sets |*out_sparse_data_size| to the total size of all the ranges (not
// including headers).
bool ScanSparseFile(int32_t* out_sparse_data_size);
// Reads from a single sparse range. If asked to read the entire range, also
// verifies the CRC32.
bool ReadSparseRange(const SparseRange* range,
int offset, int len, char* buf);
// Writes to a single (existing) sparse range. If asked to write the entire
// range, also updates the CRC32; otherwise, invalidates it.
bool WriteSparseRange(SparseRange* range,
int offset, int len, const char* buf);
// Appends a new sparse range to the sparse data file.
bool AppendSparseRange(int64_t offset, int len, const char* buf);
static bool DeleteFileForEntryHash(const base::FilePath& path,
uint64_t entry_hash,
int file_index);
static bool DeleteFilesForEntryHash(const base::FilePath& path,
uint64_t entry_hash);
static bool TruncateFilesForEntryHash(const base::FilePath& path,
uint64_t entry_hash);
void RecordSyncCreateResult(CreateEntryResult result, bool had_index);
base::FilePath GetFilenameFromFileIndex(int file_index);
bool sparse_file_open() const {
return sparse_file_.IsValid();
}
const net::CacheType cache_type_;
const base::FilePath path_;
const uint64_t entry_hash_;
const bool had_index_;
std::string key_;
bool have_open_files_;
bool initialized_;
// Normally false. This is set to true when an entry is opened without
// checking the file headers. Any subsequent read will perform the check
// before completing.
bool header_and_key_check_needed_[kSimpleEntryNormalFileCount] = {
false,
};
base::File files_[kSimpleEntryNormalFileCount];
// True if the corresponding stream is empty and therefore no on-disk file
// was created to store it.
bool empty_file_omitted_[kSimpleEntryNormalFileCount];
typedef std::map<int64_t, SparseRange> SparseRangeOffsetMap;
typedef SparseRangeOffsetMap::iterator SparseRangeIterator;
SparseRangeOffsetMap sparse_ranges_;
base::File sparse_file_;
// Offset of the end of the sparse file (where the next sparse range will be
// written).
int64_t sparse_tail_offset_;
// True if the entry was created, or false if it was opened. Used to log
// SimpleCache.*.EntryCreatedWithStream2Omitted only for created entries.
bool files_created_;
};
} // namespace disk_cache
#endif // NET_DISK_CACHE_SIMPLE_SIMPLE_SYNCHRONOUS_ENTRY_H_