Roll src/third_party/WebKit d9c6159:8139f33 (svn 201974:201975)
[chromium-blink-merge.git] / net / disk_cache / blockfile / disk_format_base.h
blob1c49a48e737f7f5ee93cf75dc612f2010db89f1a
1 // Copyright (c) 2011 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
5 // For a general description of the files used by the cache see file_format.h.
6 //
7 // A block file is a file designed to store blocks of data of a given size. It
8 // is able to store data that spans from one to four consecutive "blocks", and
9 // it grows as needed to store up to approximately 65000 blocks. It has a fixed
10 // size header used for book keeping such as tracking free of blocks on the
11 // file. For example, a block-file for 1KB blocks will grow from 8KB when
12 // totally empty to about 64MB when completely full. At that point, data blocks
13 // of 1KB will be stored on a second block file that will store the next set of
14 // 65000 blocks. The first file contains the number of the second file, and the
15 // second file contains the number of a third file, created when the second file
16 // reaches its limit. It is important to remember that no matter how long the
17 // chain of files is, any given block can be located directly by its address,
18 // which contains the file number and starting block inside the file.
20 #ifndef NET_DISK_CACHE_BLOCKFILE_DISK_FORMAT_BASE_H_
21 #define NET_DISK_CACHE_BLOCKFILE_DISK_FORMAT_BASE_H_
23 #include "base/basictypes.h"
24 #include "net/base/net_export.h"
26 namespace disk_cache {
28 typedef uint32 CacheAddr;
30 const uint32 kBlockVersion2 = 0x20000; // Version 2.0.
31 const uint32 kBlockCurrentVersion = 0x30000; // Version 3.0.
33 const uint32 kBlockMagic = 0xC104CAC3;
34 const int kBlockHeaderSize = 8192; // Two pages: almost 64k entries
35 const int kMaxBlocks = (kBlockHeaderSize - 80) * 8;
36 const int kNumExtraBlocks = 1024; // How fast files grow.
38 // Bitmap to track used blocks on a block-file.
39 typedef uint32 AllocBitmap[kMaxBlocks / 32];
41 // A block-file is the file used to store information in blocks (could be
42 // EntryStore blocks, RankingsNode blocks or user-data blocks).
43 // We store entries that can expand for up to 4 consecutive blocks, and keep
44 // counters of the number of blocks available for each type of entry. For
45 // instance, an entry of 3 blocks is an entry of type 3. We also keep track of
46 // where did we find the last entry of that type (to avoid searching the bitmap
47 // from the beginning every time).
48 // This Structure is the header of a block-file:
49 struct BlockFileHeader {
50 uint32 magic;
51 uint32 version;
52 int16 this_file; // Index of this file.
53 int16 next_file; // Next file when this one is full.
54 int32 entry_size; // Size of the blocks of this file.
55 int32 num_entries; // Number of stored entries.
56 int32 max_entries; // Current maximum number of entries.
57 int32 empty[4]; // Counters of empty entries for each type.
58 int32 hints[4]; // Last used position for each entry type.
59 volatile int32 updating; // Keep track of updates to the header.
60 int32 user[5];
61 AllocBitmap allocation_map;
64 static_assert(sizeof(BlockFileHeader) == kBlockHeaderSize, "bad header");
66 // Sparse data support:
67 // We keep a two level hierarchy to enable sparse data for an entry: the first
68 // level consists of using separate "child" entries to store ranges of 1 MB,
69 // and the second level stores blocks of 1 KB inside each child entry.
71 // Whenever we need to access a particular sparse offset, we first locate the
72 // child entry that stores that offset, so we discard the 20 least significant
73 // bits of the offset, and end up with the child id. For instance, the child id
74 // to store the first megabyte is 0, and the child that should store offset
75 // 0x410000 has an id of 4.
77 // The child entry is stored the same way as any other entry, so it also has a
78 // name (key). The key includes a signature to be able to identify children
79 // created for different generations of the same resource. In other words, given
80 // that a given sparse entry can have a large number of child entries, and the
81 // resource can be invalidated and replaced with a new version at any time, it
82 // is important to be sure that a given child actually belongs to certain entry.
84 // The full name of a child entry is composed with a prefix ("Range_"), and two
85 // hexadecimal 64-bit numbers at the end, separated by semicolons. The first
86 // number is the signature of the parent key, and the second number is the child
87 // id as described previously. The signature itself is also stored internally by
88 // the child and the parent entries. For example, a sparse entry with a key of
89 // "sparse entry name", and a signature of 0x052AF76, may have a child entry
90 // named "Range_sparse entry name:052af76:4", which stores data in the range
91 // 0x400000 to 0x4FFFFF.
93 // Each child entry keeps track of all the 1 KB blocks that have been written
94 // to the entry, but being a regular entry, it will happily return zeros for any
95 // read that spans data not written before. The actual sparse data is stored in
96 // one of the data streams of the child entry (at index 1), while the control
97 // information is stored in another stream (at index 2), both by parents and
98 // the children.
100 // This structure contains the control information for parent and child entries.
101 // It is stored at offset 0 of the data stream with index 2.
102 // It is possible to write to a child entry in a way that causes the last block
103 // to be only partialy filled. In that case, last_block and last_block_len will
104 // keep track of that block.
105 struct SparseHeader {
106 int64 signature; // The parent and children signature.
107 uint32 magic; // Structure identifier (equal to kIndexMagic).
108 int32 parent_key_len; // Key length for the parent entry.
109 int32 last_block; // Index of the last written block.
110 int32 last_block_len; // Lenght of the last written block.
111 int32 dummy[10];
114 // The SparseHeader will be followed by a bitmap, as described by this
115 // structure.
116 struct SparseData {
117 SparseHeader header;
118 uint32 bitmap[32]; // Bitmap representation of known children (if this
119 // is a parent entry), or used blocks (for child
120 // entries. The size is fixed for child entries but
121 // not for parents; it can be as small as 4 bytes
122 // and as large as 8 KB.
125 // The number of blocks stored by a child entry.
126 const int kNumSparseBits = 1024;
127 static_assert(sizeof(SparseData) == sizeof(SparseHeader) + kNumSparseBits / 8,
128 "invalid SparseData bitmap");
130 } // namespace disk_cache
132 #endif // NET_DISK_CACHE_BLOCKFILE_DISK_FORMAT_BASE_H_