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git/Documentation/technical/bitmap-format.txt
Taylor Blau 917a54c017 Documentation: describe MIDX-based bitmaps 
Update the technical documentation to describe the multi-pack bitmap
format. This patch merely introduces the new format, and describes its
high-level ideas. Git does not yet know how to read nor write these
multi-pack variants, and so the subsequent patches will:

  - Introduce code to interpret multi-pack bitmaps, according to this
    document.

  - Then, introduce code to write multi-pack bitmaps from the 'git
    multi-pack-index write' sub-command.

Finally, the implementation will gain tests in subsequent patches (as
opposed to inline with the patch teaching Git how to write multi-pack
bitmaps) to avoid a cyclic dependency.

Signed-off-by: Taylor Blau <me@ttaylorr.com>
Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-08-24 13:21:13 -07:00

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GIT bitmap v1 format
====================
== Pack and multi-pack bitmaps
Bitmaps store reachability information about the set of objects in a packfile,
or a multi-pack index (MIDX). The former is defined obviously, and the latter is
defined as the union of objects in packs contained in the MIDX.
A bitmap may belong to either one pack, or the repository's multi-pack index (if
it exists). A repository may have at most one bitmap.
An object is uniquely described by its bit position within a bitmap:
- If the bitmap belongs to a packfile, the __n__th bit corresponds to
the __n__th object in pack order. For a function `offset` which maps
objects to their byte offset within a pack, pack order is defined as
follows:
o1 <= o2 <==> offset(o1) <= offset(o2)
- If the bitmap belongs to a MIDX, the __n__th bit corresponds to the
__n__th object in MIDX order. With an additional function `pack` which
maps objects to the pack they were selected from by the MIDX, MIDX order
is defined as follows:
o1 <= o2 <==> pack(o1) <= pack(o2) /\ offset(o1) <= offset(o2)
The ordering between packs is done according to the MIDX's .rev file.
Notably, the preferred pack sorts ahead of all other packs.
The on-disk representation (described below) of a bitmap is the same regardless
of whether or not that bitmap belongs to a packfile or a MIDX. The only
difference is the interpretation of the bits, which is described above.
Certain bitmap extensions are supported (see: Appendix B). No extensions are
required for bitmaps corresponding to packfiles. For bitmaps that correspond to
MIDXs, both the bit-cache and rev-cache extensions are required.
== On-disk format
- A header appears at the beginning:
4-byte signature: {'B', 'I', 'T', 'M'}
2-byte version number (network byte order)
The current implementation only supports version 1
of the bitmap index (the same one as JGit).
2-byte flags (network byte order)
The following flags are supported:
- BITMAP_OPT_FULL_DAG (0x1) REQUIRED
This flag must always be present. It implies that the
bitmap index has been generated for a packfile or
multi-pack index (MIDX) with full closure (i.e. where
every single object in the packfile/MIDX can find its
parent links inside the same packfile/MIDX). This is a
requirement for the bitmap index format, also present in
JGit, that greatly reduces the complexity of the
implementation.
- BITMAP_OPT_HASH_CACHE (0x4)
If present, the end of the bitmap file contains
`N` 32-bit name-hash values, one per object in the
pack/MIDX. The format and meaning of the name-hash is
described below.
4-byte entry count (network byte order)
The total count of entries (bitmapped commits) in this bitmap index.
20-byte checksum
The SHA1 checksum of the pack/MIDX this bitmap index
belongs to.
- 4 EWAH bitmaps that act as type indexes
Type indexes are serialized after the hash cache in the shape
of four EWAH bitmaps stored consecutively (see Appendix A for
the serialization format of an EWAH bitmap).
There is a bitmap for each Git object type, stored in the following
order:
- Commits
- Trees
- Blobs
- Tags
In each bitmap, the `n`th bit is set to true if the `n`th object
in the packfile or multi-pack index is of that type.
The obvious consequence is that the OR of all 4 bitmaps will result
in a full set (all bits set), and the AND of all 4 bitmaps will
result in an empty bitmap (no bits set).
- N entries with compressed bitmaps, one for each indexed commit
Where `N` is the total amount of entries in this bitmap index.
Each entry contains the following:
- 4-byte object position (network byte order)
The position **in the index for the packfile or
multi-pack index** where the bitmap for this commit is
found.
- 1-byte XOR-offset
The xor offset used to compress this bitmap. For an entry
in position `x`, a XOR offset of `y` means that the actual
bitmap representing this commit is composed by XORing the
bitmap for this entry with the bitmap in entry `x-y` (i.e.
the bitmap `y` entries before this one).
Note that this compression can be recursive. In order to
XOR this entry with a previous one, the previous entry needs
to be decompressed first, and so on.
The hard-limit for this offset is 160 (an entry can only be
xor'ed against one of the 160 entries preceding it). This
number is always positive, and hence entries are always xor'ed
with **previous** bitmaps, not bitmaps that will come afterwards
in the index.
- 1-byte flags for this bitmap
At the moment the only available flag is `0x1`, which hints
that this bitmap can be re-used when rebuilding bitmap indexes
for the repository.
- The compressed bitmap itself, see Appendix A.
== Appendix A: Serialization format for an EWAH bitmap
Ewah bitmaps are serialized in the same protocol as the JAVAEWAH
library, making them backwards compatible with the JGit
implementation:
- 4-byte number of bits of the resulting UNCOMPRESSED bitmap
- 4-byte number of words of the COMPRESSED bitmap, when stored
- N x 8-byte words, as specified by the previous field
This is the actual content of the compressed bitmap.
- 4-byte position of the current RLW for the compressed
bitmap
All words are stored in network byte order for their corresponding
sizes.
The compressed bitmap is stored in a form of run-length encoding, as
follows. It consists of a concatenation of an arbitrary number of
chunks. Each chunk consists of one or more 64-bit words
H L_1 L_2 L_3 .... L_M
H is called RLW (run length word). It consists of (from lower to higher
order bits):
- 1 bit: the repeated bit B
- 32 bits: repetition count K (unsigned)
- 31 bits: literal word count M (unsigned)
The bitstream represented by the above chunk is then:
- K repetitions of B
- The bits stored in `L_1` through `L_M`. Within a word, bits at
lower order come earlier in the stream than those at higher
order.
The next word after `L_M` (if any) must again be a RLW, for the next
chunk. For efficient appending to the bitstream, the EWAH stores a
pointer to the last RLW in the stream.
== Appendix B: Optional Bitmap Sections
These sections may or may not be present in the `.bitmap` file; their
presence is indicated by the header flags section described above.
Name-hash cache
---------------
If the BITMAP_OPT_HASH_CACHE flag is set, the end of the bitmap contains
a cache of 32-bit values, one per object in the pack/MIDX. The value at
position `i` is the hash of the pathname at which the `i`th object
(counting in index or multi-pack index order) in the pack/MIDX can be found.
This can be fed into the delta heuristics to compare objects with similar
pathnames.
The hash algorithm used is:
hash = 0;
while ((c = *name++))
if (!isspace(c))
hash = (hash >> 2) + (c << 24);
Note that this hashing scheme is tied to the BITMAP_OPT_HASH_CACHE flag.
If implementations want to choose a different hashing scheme, they are
free to do so, but MUST allocate a new header flag (because comparing
hashes made under two different schemes would be pointless).
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