1 Git commit graph format
2 =======================
4 The Git commit graph stores a list of commit OIDs and some associated
7 - The generation number of the commit. Commits with no parents have
8 generation number 1; commits with parents have generation number
9 one more than the maximum generation number of its parents. We
10 reserve zero as special, and can be used to mark a generation
11 number invalid or as "not computed".
17 - The parents of the commit, stored using positional references within
20 - The Bloom filter of the commit carrying the paths that were changed between
21 the commit and its first parent, if requested.
23 These positional references are stored as unsigned 32-bit integers
24 corresponding to the array position within the list of commit OIDs. Due
25 to some special constants we use to track parents, we can store at most
26 (1 << 30) + (1 << 29) + (1 << 28) - 1 (around 1.8 billion) commits.
28 == Commit graph files have the following format:
30 In order to allow extensions that add extra data to the graph, we organize
31 the body into "chunks" and provide a binary lookup table at the beginning
32 of the body. The header includes certain values, such as number of chunks
35 All multi-byte numbers are in network byte order.
40 The signature is: {'C', 'G', 'P', 'H'}
42 1-byte version number:
43 Currently, the only valid version is 1.
46 We infer the hash length (H) from this value:
49 If the hash type does not match the repository's hash algorithm, the
50 commit-graph file should be ignored with a warning presented to the
53 1-byte number (C) of "chunks"
55 1-byte number (B) of base commit-graphs
56 We infer the length (H*B) of the Base Graphs chunk
61 (C + 1) * 12 bytes listing the table of contents for the chunks:
62 First 4 bytes describe the chunk id. Value 0 is a terminating label.
63 Other 8 bytes provide the byte-offset in current file for chunk to
64 start. (Chunks are ordered contiguously in the file, so you can infer
65 the length using the next chunk position if necessary.) Each chunk
66 ID appears at most once.
68 The remaining data in the body is described one chunk at a time, and
69 these chunks may be given in any order. Chunks are required unless
74 OID Fanout (ID: {'O', 'I', 'D', 'F'}) (256 * 4 bytes)
75 The ith entry, F[i], stores the number of OIDs with first
76 byte at most i. Thus F[255] stores the total
77 number of commits (N).
79 OID Lookup (ID: {'O', 'I', 'D', 'L'}) (N * H bytes)
80 The OIDs for all commits in the graph, sorted in ascending order.
82 Commit Data (ID: {'C', 'D', 'A', 'T' }) (N * (H + 16) bytes)
83 * The first H bytes are for the OID of the root tree.
84 * The next 8 bytes are for the positions of the first two parents
85 of the ith commit. Stores value 0x7000000 if no parent in that
86 position. If there are more than two parents, the second value
87 has its most-significant bit on and the other bits store an array
88 position into the Extra Edge List chunk.
89 * The next 8 bytes store the generation number of the commit and
90 the commit time in seconds since EPOCH. The generation number
91 uses the higher 30 bits of the first 4 bytes, while the commit
92 time uses the 32 bits of the second 4 bytes, along with the lowest
93 2 bits of the lowest byte, storing the 33rd and 34th bit of the
96 Extra Edge List (ID: {'E', 'D', 'G', 'E'}) [Optional]
97 This list of 4-byte values store the second through nth parents for
98 all octopus merges. The second parent value in the commit data stores
99 an array position within this list along with the most-significant bit
100 on. Starting at that array position, iterate through this list of commit
101 positions for the parents until reaching a value with the most-significant
102 bit on. The other bits correspond to the position of the last parent.
104 Bloom Filter Index (ID: {'B', 'I', 'D', 'X'}) (N * 4 bytes) [Optional]
105 * The ith entry, BIDX[i], stores the number of bytes in all Bloom filters
106 from commit 0 to commit i (inclusive) in lexicographic order. The Bloom
107 filter for the i-th commit spans from BIDX[i-1] to BIDX[i] (plus header
108 length), where BIDX[-1] is 0.
109 * The BIDX chunk is ignored if the BDAT chunk is not present.
111 Bloom Filter Data (ID: {'B', 'D', 'A', 'T'}) [Optional]
112 * It starts with header consisting of three unsigned 32-bit integers:
113 - Version of the hash algorithm being used. We currently only support
114 value 1 which corresponds to the 32-bit version of the murmur3 hash
115 implemented exactly as described in
116 https://en.wikipedia.org/wiki/MurmurHash#Algorithm and the double
117 hashing technique using seed values 0x293ae76f and 0x7e646e2 as
118 described in https://doi.org/10.1007/978-3-540-30494-4_26 "Bloom Filters
119 in Probabilistic Verification"
120 - The number of times a path is hashed and hence the number of bit positions
121 that cumulatively determine whether a file is present in the commit.
122 - The minimum number of bits 'b' per entry in the Bloom filter. If the filter
123 contains 'n' entries, then the filter size is the minimum number of 64-bit
124 words that contain n*b bits.
125 * The rest of the chunk is the concatenation of all the computed Bloom
126 filters for the commits in lexicographic order.
127 * Note: Commits with no changes or more than 512 changes have Bloom filters
129 * The BDAT chunk is present if and only if BIDX is present.
131 Base Graphs List (ID: {'B', 'A', 'S', 'E'}) [Optional]
132 This list of H-byte hashes describe a set of B commit-graph files that
133 form a commit-graph chain. The graph position for the ith commit in this
134 file's OID Lookup chunk is equal to i plus the number of commits in all
135 base graphs. If B is non-zero, this chunk must exist.
139 H-byte HASH-checksum of all of the above.
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