Git’s pack files are carefully constructed to effectively use disk caches and
provide “nice” access patterns for common commands and for reading recently referenced
Git’s pack file
format is quite flexible (see Documentation/technical/pack-format.txt,
or The Packfile in The Git Community Book).
The pack files store objects in two main
ways: “undeltified” (take the raw object data and deflate-compress
it), or “deltified” (form a delta against some other object then
deflate-compress the resulting delta data). The objects stored in
a pack can be in any order (they do not (necessarily) have to be
sorted by object type, object name, or any other attribute) and
deltified objects can be made against any other suitable object of the same type.
Git’s pack-objects command uses several heuristics to
provide excellent locality of reference for common
commands. These heuristics control both the selection of base
objects for deltified objects and the order of the objects. Each
mechanism is mostly independent, but they share some goals.
Git does form long chains of delta compressed objects, but the
heuristics try to make sure that only “old” objects are at the ends of
the long chains. The delta base cache (who’s size is controlled by the
core.deltaBaseCacheLimit configuration variable) is automatically
used and can greatly reduce the number of “rebuilds” required for
commands that need to read a large number of objects (e.g.
Delta Compression Heuristic
A typical Git repository stores a very large number of objects, so
it can not reasonably compare them all to find the pairs (and
chains) that will yield the smallest delta representations.
The delta base selection heuristic is based on the idea that the
good delta bases will be found among objects with similar filenames
and sizes. Each type of object is processed separately (i.e. an
object of one type will never be used as the delta base for an
object of another type).
For the purposes of delta base selection, the objects are sorted (primarily) by
filename and then size. A window into this sorted list is used to limit
the number of objects that are considered as potential delta bases.
If a “good enough”1 delta representation is not found for an object
among the objects in its window, then the object will not be delta
The size of the window is controlled by the
--window= option of
git pack-objects, or the
pack.window configuration variable. The
maximum depth of a delta chain is controlled by the
git pack-objects, or the
--aggressive option of
git gc greatly enlarges
both the window size and the maximum depth to attempt to create
a smaller pack file.
The filename sort clumps together the objects for entries with with
identical names (or at least similar endings (e.g.
.c)). The size
sort is from largest to smallest so that deltas that remove data are
preferred to deltas that add data (since removal deltas have shorter
representations) and so that the earlier, larger objects (usually
newer) tend to be represented with plain compression.
What qualifies as “good enough” depends on the size of the object in question and its potential delta base as well as how deep its resulting delta chain would be.
Object Ordering Heuristic
Objects are stored in the pack files in a “most recently referenced”
order. The objects needed to reconstruct the most recent history are
placed earlier in the pack and they will be close together. This
usually works well for OS disk caches.
All the commit objects are sorted by commit date (most recent first)
and stored together. This placement and ordering optimizes the disk
accesses needed to walk the history graph and extract basic commit
The tree and blob objects are stored starting with the tree from the
first stored (most recent) commit. Each tree is processed in a depth
first fashion, storing any objects that have not already been
stored. This puts all the trees and blobs required to reconstruct
the most recent commit together in one place. Any trees and blobs that
have not yet been saved but that are required for later commits are
stored next, in the sorted commit order.
The final object ordering is slightly affected by the delta base selection
in that if an object is selected for delta representation and its base object
has not been stored yet, then its base object is stored immediately before the
deltified object itself. This prevents likely disk cache misses due to the
non-linear access required to read a base object that would have “naturally” been
stored later in the pack file.