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-rw-r--r--Documentation/technical/chunk-format.txt116
-rw-r--r--Documentation/technical/commit-graph-format.txt31
-rw-r--r--Documentation/technical/commit-graph.txt77
-rw-r--r--Documentation/technical/hash-function-transition.txt293
-rw-r--r--Documentation/technical/index-format.txt46
-rw-r--r--Documentation/technical/pack-format.txt23
-rw-r--r--Documentation/technical/protocol-v2.txt15
-rw-r--r--Documentation/technical/reftable.txt42
8 files changed, 448 insertions, 195 deletions
diff --git a/Documentation/technical/chunk-format.txt b/Documentation/technical/chunk-format.txt
new file mode 100644
index 0000000000..593614fced
--- /dev/null
+++ b/Documentation/technical/chunk-format.txt
@@ -0,0 +1,116 @@
+Chunk-based file formats
+========================
+
+Some file formats in Git use a common concept of "chunks" to describe
+sections of the file. This allows structured access to a large file by
+scanning a small "table of contents" for the remaining data. This common
+format is used by the `commit-graph` and `multi-pack-index` files. See
+link:technical/pack-format.html[the `multi-pack-index` format] and
+link:technical/commit-graph-format.html[the `commit-graph` format] for
+how they use the chunks to describe structured data.
+
+A chunk-based file format begins with some header information custom to
+that format. That header should include enough information to identify
+the file type, format version, and number of chunks in the file. From this
+information, that file can determine the start of the chunk-based region.
+
+The chunk-based region starts with a table of contents describing where
+each chunk starts and ends. This consists of (C+1) rows of 12 bytes each,
+where C is the number of chunks. Consider the following table:
+
+ | Chunk ID (4 bytes) | Chunk Offset (8 bytes) |
+ |--------------------|------------------------|
+ | ID[0] | OFFSET[0] |
+ | ... | ... |
+ | ID[C] | OFFSET[C] |
+ | 0x0000 | OFFSET[C+1] |
+
+Each row consists of a 4-byte chunk identifier (ID) and an 8-byte offset.
+Each integer is stored in network-byte order.
+
+The chunk identifier `ID[i]` is a label for the data stored within this
+fill from `OFFSET[i]` (inclusive) to `OFFSET[i+1]` (exclusive). Thus, the
+size of the `i`th chunk is equal to the difference between `OFFSET[i+1]`
+and `OFFSET[i]`. This requires that the chunk data appears contiguously
+in the same order as the table of contents.
+
+The final entry in the table of contents must be four zero bytes. This
+confirms that the table of contents is ending and provides the offset for
+the end of the chunk-based data.
+
+Note: The chunk-based format expects that the file contains _at least_ a
+trailing hash after `OFFSET[C+1]`.
+
+Functions for working with chunk-based file formats are declared in
+`chunk-format.h`. Using these methods provide extra checks that assist
+developers when creating new file formats.
+
+Writing chunk-based file formats
+--------------------------------
+
+To write a chunk-based file format, create a `struct chunkfile` by
+calling `init_chunkfile()` and pass a `struct hashfile` pointer. The
+caller is responsible for opening the `hashfile` and writing header
+information so the file format is identifiable before the chunk-based
+format begins.
+
+Then, call `add_chunk()` for each chunk that is intended for write. This
+populates the `chunkfile` with information about the order and size of
+each chunk to write. Provide a `chunk_write_fn` function pointer to
+perform the write of the chunk data upon request.
+
+Call `write_chunkfile()` to write the table of contents to the `hashfile`
+followed by each of the chunks. This will verify that each chunk wrote
+the expected amount of data so the table of contents is correct.
+
+Finally, call `free_chunkfile()` to clear the `struct chunkfile` data. The
+caller is responsible for finalizing the `hashfile` by writing the trailing
+hash and closing the file.
+
+Reading chunk-based file formats
+--------------------------------
+
+To read a chunk-based file format, the file must be opened as a
+memory-mapped region. The chunk-format API expects that the entire file
+is mapped as a contiguous memory region.
+
+Initialize a `struct chunkfile` pointer with `init_chunkfile(NULL)`.
+
+After reading the header information from the beginning of the file,
+including the chunk count, call `read_table_of_contents()` to populate
+the `struct chunkfile` with the list of chunks, their offsets, and their
+sizes.
+
+Extract the data information for each chunk using `pair_chunk()` or
+`read_chunk()`:
+
+* `pair_chunk()` assigns a given pointer with the location inside the
+ memory-mapped file corresponding to that chunk's offset. If the chunk
+ does not exist, then the pointer is not modified.
+
+* `read_chunk()` takes a `chunk_read_fn` function pointer and calls it
+ with the appropriate initial pointer and size information. The function
+ is not called if the chunk does not exist. Use this method to read chunks
+ if you need to perform immediate parsing or if you need to execute logic
+ based on the size of the chunk.
+
+After calling these methods, call `free_chunkfile()` to clear the
+`struct chunkfile` data. This will not close the memory-mapped region.
+Callers are expected to own that data for the timeframe the pointers into
+the region are needed.
+
+Examples
+--------
+
+These file formats use the chunk-format API, and can be used as examples
+for future formats:
+
+* *commit-graph:* see `write_commit_graph_file()` and `parse_commit_graph()`
+ in `commit-graph.c` for how the chunk-format API is used to write and
+ parse the commit-graph file format documented in
+ link:technical/commit-graph-format.html[the commit-graph file format].
+
+* *multi-pack-index:* see `write_midx_internal()` and `load_multi_pack_index()`
+ in `midx.c` for how the chunk-format API is used to write and
+ parse the multi-pack-index file format documented in
+ link:technical/pack-format.html[the multi-pack-index file format].
diff --git a/Documentation/technical/commit-graph-format.txt b/Documentation/technical/commit-graph-format.txt
index b3b58880b9..87971c27dd 100644
--- a/Documentation/technical/commit-graph-format.txt
+++ b/Documentation/technical/commit-graph-format.txt
@@ -4,11 +4,7 @@ Git commit graph format
The Git commit graph stores a list of commit OIDs and some associated
metadata, including:
-- The generation number of the commit. Commits with no parents have
- generation number 1; commits with parents have generation number
- one more than the maximum generation number of its parents. We
- reserve zero as special, and can be used to mark a generation
- number invalid or as "not computed".
+- The generation number of the commit.
- The root tree OID.
@@ -65,6 +61,9 @@ CHUNK LOOKUP:
the length using the next chunk position if necessary.) Each chunk
ID appears at most once.
+ The CHUNK LOOKUP matches the table of contents from
+ link:technical/chunk-format.html[the chunk-based file format].
+
The remaining data in the body is described one chunk at a time, and
these chunks may be given in any order. Chunks are required unless
otherwise specified.
@@ -86,13 +85,33 @@ CHUNK DATA:
position. If there are more than two parents, the second value
has its most-significant bit on and the other bits store an array
position into the Extra Edge List chunk.
- * The next 8 bytes store the generation number of the commit and
+ * The next 8 bytes store the topological level (generation number v1)
+ of the commit and
the commit time in seconds since EPOCH. The generation number
uses the higher 30 bits of the first 4 bytes, while the commit
time uses the 32 bits of the second 4 bytes, along with the lowest
2 bits of the lowest byte, storing the 33rd and 34th bit of the
commit time.
+ Generation Data (ID: {'G', 'D', 'A', 'T' }) (N * 4 bytes) [Optional]
+ * This list of 4-byte values store corrected commit date offsets for the
+ commits, arranged in the same order as commit data chunk.
+ * If the corrected commit date offset cannot be stored within 31 bits,
+ the value has its most-significant bit on and the other bits store
+ the position of corrected commit date into the Generation Data Overflow
+ chunk.
+ * Generation Data chunk is present only when commit-graph file is written
+ by compatible versions of Git and in case of split commit-graph chains,
+ the topmost layer also has Generation Data chunk.
+
+ Generation Data Overflow (ID: {'G', 'D', 'O', 'V' }) [Optional]
+ * This list of 8-byte values stores the corrected commit date offsets
+ for commits with corrected commit date offsets that cannot be
+ stored within 31 bits.
+ * Generation Data Overflow chunk is present only when Generation Data
+ chunk is present and atleast one corrected commit date offset cannot
+ be stored within 31 bits.
+
Extra Edge List (ID: {'E', 'D', 'G', 'E'}) [Optional]
This list of 4-byte values store the second through nth parents for
all octopus merges. The second parent value in the commit data stores
diff --git a/Documentation/technical/commit-graph.txt b/Documentation/technical/commit-graph.txt
index f14a7659aa..f05e7bda1a 100644
--- a/Documentation/technical/commit-graph.txt
+++ b/Documentation/technical/commit-graph.txt
@@ -38,14 +38,31 @@ A consumer may load the following info for a commit from the graph:
Values 1-4 satisfy the requirements of parse_commit_gently().
-Define the "generation number" of a commit recursively as follows:
+There are two definitions of generation number:
+1. Corrected committer dates (generation number v2)
+2. Topological levels (generation nummber v1)
- * A commit with no parents (a root commit) has generation number one.
+Define "corrected committer date" of a commit recursively as follows:
- * A commit with at least one parent has generation number one more than
- the largest generation number among its parents.
+ * A commit with no parents (a root commit) has corrected committer date
+ equal to its committer date.
-Equivalently, the generation number of a commit A is one more than the
+ * A commit with at least one parent has corrected committer date equal to
+ the maximum of its commiter date and one more than the largest corrected
+ committer date among its parents.
+
+ * As a special case, a root commit with timestamp zero has corrected commit
+ date of 1, to be able to distinguish it from GENERATION_NUMBER_ZERO
+ (that is, an uncomputed corrected commit date).
+
+Define the "topological level" of a commit recursively as follows:
+
+ * A commit with no parents (a root commit) has topological level of one.
+
+ * A commit with at least one parent has topological level one more than
+ the largest topological level among its parents.
+
+Equivalently, the topological level of a commit A is one more than the
length of a longest path from A to a root commit. The recursive definition
is easier to use for computation and observing the following property:
@@ -60,6 +77,9 @@ is easier to use for computation and observing the following property:
generation numbers, then we always expand the boundary commit with highest
generation number and can easily detect the stopping condition.
+The property applies to both versions of generation number, that is both
+corrected committer dates and topological levels.
+
This property can be used to significantly reduce the time it takes to
walk commits and determine topological relationships. Without generation
numbers, the general heuristic is the following:
@@ -67,7 +87,9 @@ numbers, the general heuristic is the following:
If A and B are commits with commit time X and Y, respectively, and
X < Y, then A _probably_ cannot reach B.
-This heuristic is currently used whenever the computation is allowed to
+In absence of corrected commit dates (for example, old versions of Git or
+mixed generation graph chains),
+this heuristic is currently used whenever the computation is allowed to
violate topological relationships due to clock skew (such as "git log"
with default order), but is not used when the topological order is
required (such as merge base calculations, "git log --graph").
@@ -77,7 +99,7 @@ in the commit graph. We can treat these commits as having "infinite"
generation number and walk until reaching commits with known generation
number.
-We use the macro GENERATION_NUMBER_INFINITY = 0xFFFFFFFF to mark commits not
+We use the macro GENERATION_NUMBER_INFINITY to mark commits not
in the commit-graph file. If a commit-graph file was written by a version
of Git that did not compute generation numbers, then those commits will
have generation number represented by the macro GENERATION_NUMBER_ZERO = 0.
@@ -93,12 +115,12 @@ fully-computed generation numbers. Using strict inequality may result in
walking a few extra commits, but the simplicity in dealing with commits
with generation number *_INFINITY or *_ZERO is valuable.
-We use the macro GENERATION_NUMBER_MAX = 0x3FFFFFFF to for commits whose
-generation numbers are computed to be at least this value. We limit at
-this value since it is the largest value that can be stored in the
-commit-graph file using the 30 bits available to generation numbers. This
-presents another case where a commit can have generation number equal to
-that of a parent.
+We use the macro GENERATION_NUMBER_V1_MAX = 0x3FFFFFFF for commits whose
+topological levels (generation number v1) are computed to be at least
+this value. We limit at this value since it is the largest value that
+can be stored in the commit-graph file using the 30 bits available
+to topological levels. This presents another case where a commit can
+have generation number equal to that of a parent.
Design Details
--------------
@@ -267,6 +289,35 @@ The merge strategy values (2 for the size multiple, 64,000 for the maximum
number of commits) could be extracted into config settings for full
flexibility.
+## Handling Mixed Generation Number Chains
+
+With the introduction of generation number v2 and generation data chunk, the
+following scenario is possible:
+
+1. "New" Git writes a commit-graph with the corrected commit dates.
+2. "Old" Git writes a split commit-graph on top without corrected commit dates.
+
+A naive approach of using the newest available generation number from
+each layer would lead to violated expectations: the lower layer would
+use corrected commit dates which are much larger than the topological
+levels of the higher layer. For this reason, Git inspects the topmost
+layer to see if the layer is missing corrected commit dates. In such a case
+Git only uses topological level for generation numbers.
+
+When writing a new layer in split commit-graph, we write corrected commit
+dates if the topmost layer has corrected commit dates written. This
+guarantees that if a layer has corrected commit dates, all lower layers
+must have corrected commit dates as well.
+
+When merging layers, we do not consider whether the merged layers had corrected
+commit dates. Instead, the new layer will have corrected commit dates if the
+layer below the new layer has corrected commit dates.
+
+While writing or merging layers, if the new layer is the only layer, it will
+have corrected commit dates when written by compatible versions of Git. Thus,
+rewriting split commit-graph as a single file (`--split=replace`) creates a
+single layer with corrected commit dates.
+
## Deleting graph-{hash} files
After a new tip file is written, some `graph-{hash}` files may no longer
diff --git a/Documentation/technical/hash-function-transition.txt b/Documentation/technical/hash-function-transition.txt
index 6fd20ebbc2..7c1630bf83 100644
--- a/Documentation/technical/hash-function-transition.txt
+++ b/Documentation/technical/hash-function-transition.txt
@@ -33,16 +33,9 @@ researchers. On 23 February 2017 the SHAttered attack
Git v2.13.0 and later subsequently moved to a hardened SHA-1
implementation by default, which isn't vulnerable to the SHAttered
-attack.
+attack, but SHA-1 is still weak.
-Thus Git has in effect already migrated to a new hash that isn't SHA-1
-and doesn't share its vulnerabilities, its new hash function just
-happens to produce exactly the same output for all known inputs,
-except two PDFs published by the SHAttered researchers, and the new
-implementation (written by those researchers) claims to detect future
-cryptanalytic collision attacks.
-
-Regardless, it's considered prudent to move past any variant of SHA-1
+Thus it's considered prudent to move past any variant of SHA-1
to a new hash. There's no guarantee that future attacks on SHA-1 won't
be published in the future, and those attacks may not have viable
mitigations.
@@ -57,6 +50,38 @@ SHA-1 still possesses the other properties such as fast object lookup
and safe error checking, but other hash functions are equally suitable
that are believed to be cryptographically secure.
+Choice of Hash
+--------------
+The hash to replace the hardened SHA-1 should be stronger than SHA-1
+was: we would like it to be trustworthy and useful in practice for at
+least 10 years.
+
+Some other relevant properties:
+
+1. A 256-bit hash (long enough to match common security practice; not
+ excessively long to hurt performance and disk usage).
+
+2. High quality implementations should be widely available (e.g., in
+ OpenSSL and Apple CommonCrypto).
+
+3. The hash function's properties should match Git's needs (e.g. Git
+ requires collision and 2nd preimage resistance and does not require
+ length extension resistance).
+
+4. As a tiebreaker, the hash should be fast to compute (fortunately
+ many contenders are faster than SHA-1).
+
+There were several contenders for a successor hash to SHA-1, including
+SHA-256, SHA-512/256, SHA-256x16, K12, and BLAKE2bp-256.
+
+In late 2018 the project picked SHA-256 as its successor hash.
+
+See 0ed8d8da374 (doc hash-function-transition: pick SHA-256 as
+NewHash, 2018-08-04) and numerous mailing list threads at the time,
+particularly the one starting at
+https://lore.kernel.org/git/20180609224913.GC38834@genre.crustytoothpaste.net/
+for more information.
+
Goals
-----
1. The transition to SHA-256 can be done one local repository at a time.
@@ -94,7 +119,7 @@ Overview
--------
We introduce a new repository format extension. Repositories with this
extension enabled use SHA-256 instead of SHA-1 to name their objects.
-This affects both object names and object content --- both the names
+This affects both object names and object content -- both the names
of objects and all references to other objects within an object are
switched to the new hash function.
@@ -107,7 +132,7 @@ mapping to allow naming objects using either their SHA-1 and SHA-256 names
interchangeably.
"git cat-file" and "git hash-object" gain options to display an object
-in its sha1 form and write an object given its sha1 form. This
+in its SHA-1 form and write an object given its SHA-1 form. This
requires all objects referenced by that object to be present in the
object database so that they can be named using the appropriate name
(using the bidirectional hash mapping).
@@ -115,7 +140,7 @@ object database so that they can be named using the appropriate name
Fetches from a SHA-1 based server convert the fetched objects into
SHA-256 form and record the mapping in the bidirectional mapping table
(see below for details). Pushes to a SHA-1 based server convert the
-objects being pushed into sha1 form so the server does not have to be
+objects being pushed into SHA-1 form so the server does not have to be
aware of the hash function the client is using.
Detailed Design
@@ -151,38 +176,38 @@ repository extensions.
Object names
~~~~~~~~~~~~
-Objects can be named by their 40 hexadecimal digit sha1-name or 64
-hexadecimal digit sha256-name, plus names derived from those (see
+Objects can be named by their 40 hexadecimal digit SHA-1 name or 64
+hexadecimal digit SHA-256 name, plus names derived from those (see
gitrevisions(7)).
-The sha1-name of an object is the SHA-1 of the concatenation of its
-type, length, a nul byte, and the object's sha1-content. This is the
+The SHA-1 name of an object is the SHA-1 of the concatenation of its
+type, length, a nul byte, and the object's SHA-1 content. This is the
traditional <sha1> used in Git to name objects.
-The sha256-name of an object is the SHA-256 of the concatenation of its
-type, length, a nul byte, and the object's sha256-content.
+The SHA-256 name of an object is the SHA-256 of the concatenation of its
+type, length, a nul byte, and the object's SHA-256 content.
Object format
~~~~~~~~~~~~~
The content as a byte sequence of a tag, commit, or tree object named
-by sha1 and sha256 differ because an object named by sha256-name refers to
-other objects by their sha256-names and an object named by sha1-name
-refers to other objects by their sha1-names.
+by SHA-1 and SHA-256 differ because an object named by SHA-256 name refers to
+other objects by their SHA-256 names and an object named by SHA-1 name
+refers to other objects by their SHA-1 names.
-The sha256-content of an object is the same as its sha1-content, except
-that objects referenced by the object are named using their sha256-names
-instead of sha1-names. Because a blob object does not refer to any
-other object, its sha1-content and sha256-content are the same.
+The SHA-256 content of an object is the same as its SHA-1 content, except
+that objects referenced by the object are named using their SHA-256 names
+instead of SHA-1 names. Because a blob object does not refer to any
+other object, its SHA-1 content and SHA-256 content are the same.
-The format allows round-trip conversion between sha256-content and
-sha1-content.
+The format allows round-trip conversion between SHA-256 content and
+SHA-1 content.
Object storage
~~~~~~~~~~~~~~
Loose objects use zlib compression and packed objects use the packed
format described in Documentation/technical/pack-format.txt, just like
-today. The content that is compressed and stored uses sha256-content
-instead of sha1-content.
+today. The content that is compressed and stored uses SHA-256 content
+instead of SHA-1 content.
Pack index
~~~~~~~~~~
@@ -191,21 +216,21 @@ hash functions. They have the following format (all integers are in
network byte order):
- A header appears at the beginning and consists of the following:
- - The 4-byte pack index signature: '\377t0c'
- - 4-byte version number: 3
- - 4-byte length of the header section, including the signature and
+ * The 4-byte pack index signature: '\377t0c'
+ * 4-byte version number: 3
+ * 4-byte length of the header section, including the signature and
version number
- - 4-byte number of objects contained in the pack
- - 4-byte number of object formats in this pack index: 2
- - For each object format:
- - 4-byte format identifier (e.g., 'sha1' for SHA-1)
- - 4-byte length in bytes of shortened object names. This is the
+ * 4-byte number of objects contained in the pack
+ * 4-byte number of object formats in this pack index: 2
+ * For each object format:
+ ** 4-byte format identifier (e.g., 'sha1' for SHA-1)
+ ** 4-byte length in bytes of shortened object names. This is the
shortest possible length needed to make names in the shortened
object name table unambiguous.
- - 4-byte integer, recording where tables relating to this format
+ ** 4-byte integer, recording where tables relating to this format
are stored in this index file, as an offset from the beginning.
- - 4-byte offset to the trailer from the beginning of this file.
- - Zero or more additional key/value pairs (4-byte key, 4-byte
+ * 4-byte offset to the trailer from the beginning of this file.
+ * Zero or more additional key/value pairs (4-byte key, 4-byte
value). Only one key is supported: 'PSRC'. See the "Loose objects
and unreachable objects" section for supported values and how this
is used. All other keys are reserved. Readers must ignore
@@ -213,37 +238,36 @@ network byte order):
- Zero or more NUL bytes. This can optionally be used to improve the
alignment of the full object name table below.
- Tables for the first object format:
- - A sorted table of shortened object names. These are prefixes of
+ * A sorted table of shortened object names. These are prefixes of
the names of all objects in this pack file, packed together
without offset values to reduce the cache footprint of the binary
search for a specific object name.
- - A table of full object names in pack order. This allows resolving
+ * A table of full object names in pack order. This allows resolving
a reference to "the nth object in the pack file" (from a
reachability bitmap or from the next table of another object
format) to its object name.
- - A table of 4-byte values mapping object name order to pack order.
+ * A table of 4-byte values mapping object name order to pack order.
For an object in the table of sorted shortened object names, the
value at the corresponding index in this table is the index in the
previous table for that same object.
-
This can be used to look up the object in reachability bitmaps or
to look up its name in another object format.
- - A table of 4-byte CRC32 values of the packed object data, in the
+ * A table of 4-byte CRC32 values of the packed object data, in the
order that the objects appear in the pack file. This is to allow
compressed data to be copied directly from pack to pack during
repacking without undetected data corruption.
- - A table of 4-byte offset values. For an object in the table of
+ * A table of 4-byte offset values. For an object in the table of
sorted shortened object names, the value at the corresponding
index in this table indicates where that object can be found in
the pack file. These are usually 31-bit pack file offsets, but
large offsets are encoded as an index into the next table with the
most significant bit set.
- - A table of 8-byte offset entries (empty for pack files less than
+ * A table of 8-byte offset entries (empty for pack files less than
2 GiB). Pack files are organized with heavily used objects toward
the front, so most object references should not need to refer to
this table.
@@ -252,10 +276,10 @@ network byte order):
up to and not including the table of CRC32 values.
- Zero or more NUL bytes.
- The trailer consists of the following:
- - A copy of the 20-byte SHA-256 checksum at the end of the
+ * A copy of the 20-byte SHA-256 checksum at the end of the
corresponding packfile.
- - 20-byte SHA-256 checksum of all of the above.
+ * 20-byte SHA-256 checksum of all of the above.
Loose object index
~~~~~~~~~~~~~~~~~~
@@ -288,18 +312,18 @@ To remove entries (e.g. in "git pack-refs" or "git-prune"):
Translation table
~~~~~~~~~~~~~~~~~
-The index files support a bidirectional mapping between sha1-names
-and sha256-names. The lookup proceeds similarly to ordinary object
-lookups. For example, to convert a sha1-name to a sha256-name:
+The index files support a bidirectional mapping between SHA-1 names
+and SHA-256 names. The lookup proceeds similarly to ordinary object
+lookups. For example, to convert a SHA-1 name to a SHA-256 name:
1. Look for the object in idx files. If a match is present in the
- idx's sorted list of truncated sha1-names, then:
- a. Read the corresponding entry in the sha1-name order to pack
+ idx's sorted list of truncated SHA-1 names, then:
+ a. Read the corresponding entry in the SHA-1 name order to pack
name order mapping.
- b. Read the corresponding entry in the full sha1-name table to
+ b. Read the corresponding entry in the full SHA-1 name table to
verify we found the right object. If it is, then
- c. Read the corresponding entry in the full sha256-name table.
- That is the object's sha256-name.
+ c. Read the corresponding entry in the full SHA-256 name table.
+ That is the object's SHA-256 name.
2. Check for a loose object. Read lines from loose-object-idx until
we find a match.
@@ -313,10 +337,10 @@ Since all operations that make new objects (e.g., "git commit") add
the new objects to the corresponding index, this mapping is possible
for all objects in the object store.
-Reading an object's sha1-content
-~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-The sha1-content of an object can be read by converting all sha256-names
-its sha256-content references to sha1-names using the translation table.
+Reading an object's SHA-1 content
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+The SHA-1 content of an object can be read by converting all SHA-256 names
+of its SHA-256 content references to SHA-1 names using the translation table.
Fetch
~~~~~
@@ -339,7 +363,7 @@ the following steps:
1. index-pack: inflate each object in the packfile and compute its
SHA-1. Objects can contain deltas in OBJ_REF_DELTA format against
objects the client has locally. These objects can be looked up
- using the translation table and their sha1-content read as
+ using the translation table and their SHA-1 content read as
described above to resolve the deltas.
2. topological sort: starting at the "want"s from the negotiation
phase, walk through objects in the pack and emit a list of them,
@@ -348,12 +372,12 @@ the following steps:
(This list only contains objects reachable from the "wants". If the
pack from the server contained additional extraneous objects, then
they will be discarded.)
-3. convert to sha256: open a new (sha256) packfile. Read the topologically
+3. convert to SHA-256: open a new SHA-256 packfile. Read the topologically
sorted list just generated. For each object, inflate its
- sha1-content, convert to sha256-content, and write it to the sha256
- pack. Record the new sha1<->sha256 mapping entry for use in the idx.
+ SHA-1 content, convert to SHA-256 content, and write it to the SHA-256
+ pack. Record the new SHA-1<-->SHA-256 mapping entry for use in the idx.
4. sort: reorder entries in the new pack to match the order of objects
- in the pack the server generated and include blobs. Write a sha256 idx
+ in the pack the server generated and include blobs. Write a SHA-256 idx
file
5. clean up: remove the SHA-1 based pack file, index, and
topologically sorted list obtained from the server in steps 1
@@ -378,19 +402,20 @@ experimenting to get this to perform well.
Push
~~~~
Push is simpler than fetch because the objects referenced by the
-pushed objects are already in the translation table. The sha1-content
+pushed objects are already in the translation table. The SHA-1 content
of each object being pushed can be read as described in the "Reading
-an object's sha1-content" section to generate the pack written by git
+an object's SHA-1 content" section to generate the pack written by git
send-pack.
Signed Commits
~~~~~~~~~~~~~~
We add a new field "gpgsig-sha256" to the commit object format to allow
signing commits without relying on SHA-1. It is similar to the
-existing "gpgsig" field. Its signed payload is the sha256-content of the
+existing "gpgsig" field. Its signed payload is the SHA-256 content of the
commit object with any "gpgsig" and "gpgsig-sha256" fields removed.
This means commits can be signed
+
1. using SHA-1 only, as in existing signed commit objects
2. using both SHA-1 and SHA-256, by using both gpgsig-sha256 and gpgsig
fields.
@@ -404,10 +429,11 @@ Signed Tags
~~~~~~~~~~~
We add a new field "gpgsig-sha256" to the tag object format to allow
signing tags without relying on SHA-1. Its signed payload is the
-sha256-content of the tag with its gpgsig-sha256 field and "-----BEGIN PGP
+SHA-256 content of the tag with its gpgsig-sha256 field and "-----BEGIN PGP
SIGNATURE-----" delimited in-body signature removed.
This means tags can be signed
+
1. using SHA-1 only, as in existing signed tag objects
2. using both SHA-1 and SHA-256, by using gpgsig-sha256 and an in-body
signature.
@@ -415,11 +441,11 @@ This means tags can be signed
Mergetag embedding
~~~~~~~~~~~~~~~~~~
-The mergetag field in the sha1-content of a commit contains the
-sha1-content of a tag that was merged by that commit.
+The mergetag field in the SHA-1 content of a commit contains the
+SHA-1 content of a tag that was merged by that commit.
-The mergetag field in the sha256-content of the same commit contains the
-sha256-content of the same tag.
+The mergetag field in the SHA-256 content of the same commit contains the
+SHA-256 content of the same tag.
Submodules
~~~~~~~~~~
@@ -494,7 +520,7 @@ Caveats
-------
Invalid objects
~~~~~~~~~~~~~~~
-The conversion from sha1-content to sha256-content retains any
+The conversion from SHA-1 content to SHA-256 content retains any
brokenness in the original object (e.g., tree entry modes encoded with
leading 0, tree objects whose paths are not sorted correctly, and
commit objects without an author or committer). This is a deliberate
@@ -513,15 +539,15 @@ allow lifting this restriction.
Alternates
~~~~~~~~~~
-For the same reason, a sha256 repository cannot borrow objects from a
-sha1 repository using objects/info/alternates or
+For the same reason, a SHA-256 repository cannot borrow objects from a
+SHA-1 repository using objects/info/alternates or
$GIT_ALTERNATE_OBJECT_REPOSITORIES.
git notes
~~~~~~~~~
-The "git notes" tool annotates objects using their sha1-name as key.
+The "git notes" tool annotates objects using their SHA-1 name as key.
This design does not describe a way to migrate notes trees to use
-sha256-names. That migration is expected to happen separately (for
+SHA-256 names. That migration is expected to happen separately (for
example using a file at the root of the notes tree to describe which
hash it uses).
@@ -555,7 +581,7 @@ unclear:
Git 2.12
-Does this mean Git v2.12.0 is the commit with sha1-name
+Does this mean Git v2.12.0 is the commit with SHA-1 name
e7e07d5a4fcc2a203d9873968ad3e6bd4d7419d7 or the commit with
new-40-digit-hash-name e7e07d5a4fcc2a203d9873968ad3e6bd4d7419d7?
@@ -598,44 +624,12 @@ The user can also explicitly specify which format to use for a
particular revision specifier and for output, overriding the mode. For
example:
-git --output-format=sha1 log abac87a^{sha1}..f787cac^{sha256}
-
-Choice of Hash
---------------
-In early 2005, around the time that Git was written, Xiaoyun Wang,
-Yiqun Lisa Yin, and Hongbo Yu announced an attack finding SHA-1
-collisions in 2^69 operations. In August they published details.
-Luckily, no practical demonstrations of a collision in full SHA-1 were
-published until 10 years later, in 2017.
-
-Git v2.13.0 and later subsequently moved to a hardened SHA-1
-implementation by default that mitigates the SHAttered attack, but
-SHA-1 is still believed to be weak.
-
-The hash to replace this hardened SHA-1 should be stronger than SHA-1
-was: we would like it to be trustworthy and useful in practice for at
-least 10 years.
-
-Some other relevant properties:
-
-1. A 256-bit hash (long enough to match common security practice; not
- excessively long to hurt performance and disk usage).
-
-2. High quality implementations should be widely available (e.g., in
- OpenSSL and Apple CommonCrypto).
-
-3. The hash function's properties should match Git's needs (e.g. Git
- requires collision and 2nd preimage resistance and does not require
- length extension resistance).
-
-4. As a tiebreaker, the hash should be fast to compute (fortunately
- many contenders are faster than SHA-1).
-
-We choose SHA-256.
+ git --output-format=sha1 log abac87a^{sha1}..f787cac^{sha256}
Transition plan
---------------
Some initial steps can be implemented independently of one another:
+
- adding a hash function API (vtable)
- teaching fsck to tolerate the gpgsig-sha256 field
- excluding gpgsig-* from the fields copied by "git commit --amend"
@@ -647,9 +641,9 @@ Some initial steps can be implemented independently of one another:
- introducing index v3
- adding support for the PSRC field and safer object pruning
-
The first user-visible change is the introduction of the objectFormat
extension (without compatObjectFormat). This requires:
+
- teaching fsck about this mode of operation
- using the hash function API (vtable) when computing object names
- signing objects and verifying signatures
@@ -657,6 +651,7 @@ extension (without compatObjectFormat). This requires:
repository
Next comes introduction of compatObjectFormat:
+
- implementing the loose-object-idx
- translating object names between object formats
- translating object content between object formats
@@ -669,10 +664,11 @@ Next comes introduction of compatObjectFormat:
"Object names on the command line" above)
The next step is supporting fetches and pushes to SHA-1 repositories:
+
- allow pushes to a repository using the compat format
- generate a topologically sorted list of the SHA-1 names of fetched
objects
-- convert the fetched packfile to sha256 format and generate an idx
+- convert the fetched packfile to SHA-256 format and generate an idx
file
- re-sort to match the order of objects in the fetched packfile
@@ -734,6 +730,7 @@ Using hash functions in parallel
Objects newly created would be addressed by the new hash, but inside
such an object (e.g. commit) it is still possible to address objects
using the old hash function.
+
* You cannot trust its history (needed for bisectability) in the
future without further work
* Maintenance burden as the number of supported hash functions grows
@@ -743,36 +740,38 @@ using the old hash function.
Signed objects with multiple hashes
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Instead of introducing the gpgsig-sha256 field in commit and tag objects
-for sha256-content based signatures, an earlier version of this design
-added "hash sha256 <sha256-name>" fields to strengthen the existing
-sha1-content based signatures.
+for SHA-256 content based signatures, an earlier version of this design
+added "hash sha256 <SHA-256 name>" fields to strengthen the existing
+SHA-1 content based signatures.
In other words, a single signature was used to attest to the object
content using both hash functions. This had some advantages:
+
* Using one signature instead of two speeds up the signing process.
* Having one signed payload with both hashes allows the signer to
- attest to the sha1-name and sha256-name referring to the same object.
+ attest to the SHA-1 name and SHA-256 name referring to the same object.
* All users consume the same signature. Broken signatures are likely
to be detected quickly using current versions of git.
However, it also came with disadvantages:
-* Verifying a signed object requires access to the sha1-names of all
+
+* Verifying a signed object requires access to the SHA-1 names of all
objects it references, even after the transition is complete and
translation table is no longer needed for anything else. To support
- this, the design added fields such as "hash sha1 tree <sha1-name>"
- and "hash sha1 parent <sha1-name>" to the sha256-content of a signed
+ this, the design added fields such as "hash sha1 tree <SHA-1 name>"
+ and "hash sha1 parent <SHA-1 name>" to the SHA-256 content of a signed
commit, complicating the conversion process.
-* Allowing signed objects without a sha1 (for after the transition is
+* Allowing signed objects without a SHA-1 (for after the transition is
complete) complicated the design further, requiring a "nohash sha1"
- field to suppress including "hash sha1" fields in the sha256-content
+ field to suppress including "hash sha1" fields in the SHA-256 content
and signed payload.
Lazily populated translation table
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Some of the work of building the translation table could be deferred to
push time, but that would significantly complicate and slow down pushes.
-Calculating the sha1-name at object creation time at the same time it is
-being streamed to disk and having its sha256-name calculated should be
+Calculating the SHA-1 name at object creation time at the same time it is
+being streamed to disk and having its SHA-256 name calculated should be
an acceptable cost.
Document History
@@ -782,18 +781,19 @@ Document History
bmwill@google.com, jonathantanmy@google.com, jrnieder@gmail.com,
sbeller@google.com
-Initial version sent to
-http://lore.kernel.org/git/20170304011251.GA26789@aiede.mtv.corp.google.com
+* Initial version sent to https://lore.kernel.org/git/20170304011251.GA26789@aiede.mtv.corp.google.com
2017-03-03 jrnieder@gmail.com
Incorporated suggestions from jonathantanmy and sbeller:
-* describe purpose of signed objects with each hash type
-* redefine signed object verification using object content under the
+
+* Describe purpose of signed objects with each hash type
+* Redefine signed object verification using object content under the
first hash function
2017-03-06 jrnieder@gmail.com
+
* Use SHA3-256 instead of SHA2 (thanks, Linus and brian m. carlson).[1][2]
-* Make sha3-based signatures a separate field, avoiding the need for
+* Make SHA3-based signatures a separate field, avoiding the need for
"hash" and "nohash" fields (thanks to peff[3]).
* Add a sorting phase to fetch (thanks to Junio for noticing the need
for this).
@@ -805,23 +805,26 @@ Incorporated suggestions from jonathantanmy and sbeller:
especially Junio).
2017-09-27 jrnieder@gmail.com, sbeller@google.com
-* use placeholder NewHash instead of SHA3-256
-* describe criteria for picking a hash function.
-* include a transition plan (thanks especially to Brandon Williams
+
+* Use placeholder NewHash instead of SHA3-256
+* Describe criteria for picking a hash function.
+* Include a transition plan (thanks especially to Brandon Williams
for fleshing these ideas out)
-* define the translation table (thanks, Shawn Pearce[5], Jonathan
+* Define the translation table (thanks, Shawn Pearce[5], Jonathan
Tan, and Masaya Suzuki)
-* avoid loose object overhead by packing more aggressively in
+* Avoid loose object overhead by packing more aggressively in
"git gc --auto"
Later history:
- See the history of this file in git.git for the history of subsequent
- edits. This document history is no longer being maintained as it
- would now be superfluous to the commit log
+* See the history of this file in git.git for the history of subsequent
+ edits. This document history is no longer being maintained as it
+ would now be superfluous to the commit log
+
+References:
-[1] http://lore.kernel.org/git/CA+55aFzJtejiCjV0e43+9oR3QuJK2PiFiLQemytoLpyJWe6P9w@mail.gmail.com/
-[2] http://lore.kernel.org/git/CA+55aFz+gkAsDZ24zmePQuEs1XPS9BP_s8O7Q4wQ7LV7X5-oDA@mail.gmail.com/
-[3] http://lore.kernel.org/git/20170306084353.nrns455dvkdsfgo5@sigill.intra.peff.net/
-[4] http://lore.kernel.org/git/20170304224936.rqqtkdvfjgyezsht@genre.crustytoothpaste.net
-[5] https://lore.kernel.org/git/CAJo=hJtoX9=AyLHHpUJS7fueV9ciZ_MNpnEPHUz8Whui6g9F0A@mail.gmail.com/
+ [1] https://lore.kernel.org/git/CA+55aFzJtejiCjV0e43+9oR3QuJK2PiFiLQemytoLpyJWe6P9w@mail.gmail.com/
+ [2] https://lore.kernel.org/git/CA+55aFz+gkAsDZ24zmePQuEs1XPS9BP_s8O7Q4wQ7LV7X5-oDA@mail.gmail.com/
+ [3] https://lore.kernel.org/git/20170306084353.nrns455dvkdsfgo5@sigill.intra.peff.net/
+ [4] https://lore.kernel.org/git/20170304224936.rqqtkdvfjgyezsht@genre.crustytoothpaste.net
+ [5] https://lore.kernel.org/git/CAJo=hJtoX9=AyLHHpUJS7fueV9ciZ_MNpnEPHUz8Whui6g9F0A@mail.gmail.com/
diff --git a/Documentation/technical/index-format.txt b/Documentation/technical/index-format.txt
index 69edf46c03..d363a71c37 100644
--- a/Documentation/technical/index-format.txt
+++ b/Documentation/technical/index-format.txt
@@ -26,7 +26,7 @@ Git index format
Extensions are identified by signature. Optional extensions can
be ignored if Git does not understand them.
- Git currently supports cached tree and resolve undo extensions.
+ Git currently supports cache tree and resolve undo extensions.
4-byte extension signature. If the first byte is 'A'..'Z' the
extension is optional and can be ignored.
@@ -136,14 +136,35 @@ Git index format
== Extensions
-=== Cached tree
-
- Cached tree extension contains pre-computed hashes for trees that can
- be derived from the index. It helps speed up tree object generation
- from index for a new commit.
-
- When a path is updated in index, the path must be invalidated and
- removed from tree cache.
+=== Cache tree
+
+ Since the index does not record entries for directories, the cache
+ entries cannot describe tree objects that already exist in the object
+ database for regions of the index that are unchanged from an existing
+ commit. The cache tree extension stores a recursive tree structure that
+ describes the trees that already exist and completely match sections of
+ the cache entries. This speeds up tree object generation from the index
+ for a new commit by only computing the trees that are "new" to that
+ commit. It also assists when comparing the index to another tree, such
+ as `HEAD^{tree}`, since sections of the index can be skipped when a tree
+ comparison demonstrates equality.
+
+ The recursive tree structure uses nodes that store a number of cache
+ entries, a list of subnodes, and an object ID (OID). The OID references
+ the existing tree for that node, if it is known to exist. The subnodes
+ correspond to subdirectories that themselves have cache tree nodes. The
+ number of cache entries corresponds to the number of cache entries in
+ the index that describe paths within that tree's directory.
+
+ The extension tracks the full directory structure in the cache tree
+ extension, but this is generally smaller than the full cache entry list.
+
+ When a path is updated in index, Git invalidates all nodes of the
+ recursive cache tree corresponding to the parent directories of that
+ path. We store these tree nodes as being "invalid" by using "-1" as the
+ number of cache entries. Invalid nodes still store a span of index
+ entries, allowing Git to focus its efforts when reconstructing a full
+ cache tree.
The signature for this extension is { 'T', 'R', 'E', 'E' }.
@@ -174,7 +195,8 @@ Git index format
first entry represents the root level of the repository, followed by the
first subtree--let's call this A--of the root level (with its name
relative to the root level), followed by the first subtree of A (with
- its name relative to A), ...
+ its name relative to A), and so on. The specified number of subtrees
+ indicates when the current level of the recursive stack is complete.
=== Resolve undo
@@ -251,14 +273,14 @@ Git index format
- Stat data of $GIT_DIR/info/exclude. See "Index entry" section from
ctime field until "file size".
- - Stat data of core.excludesfile
+ - Stat data of core.excludesFile
- 32-bit dir_flags (see struct dir_struct)
- Hash of $GIT_DIR/info/exclude. A null hash means the file
does not exist.
- - Hash of core.excludesfile. A null hash means the file does
+ - Hash of core.excludesFile. A null hash means the file does
not exist.
- NUL-terminated string of per-dir exclude file name. This usually
diff --git a/Documentation/technical/pack-format.txt b/Documentation/technical/pack-format.txt
index 96d2fc589f..1faa949bf6 100644
--- a/Documentation/technical/pack-format.txt
+++ b/Documentation/technical/pack-format.txt
@@ -274,6 +274,26 @@ Pack file entry: <+
Index checksum of all of the above.
+== pack-*.rev files have the format:
+
+ - A 4-byte magic number '0x52494458' ('RIDX').
+
+ - A 4-byte version identifier (= 1).
+
+ - A 4-byte hash function identifier (= 1 for SHA-1, 2 for SHA-256).
+
+ - A table of index positions (one per packed object, num_objects in
+ total, each a 4-byte unsigned integer in network order), sorted by
+ their corresponding offsets in the packfile.
+
+ - A trailer, containing a:
+
+ checksum of the corresponding packfile, and
+
+ a checksum of all of the above.
+
+All 4-byte numbers are in network order.
+
== multi-pack-index (MIDX) files have the following format:
The multi-pack-index files refer to multiple pack-files and loose objects.
@@ -316,6 +336,9 @@ CHUNK LOOKUP:
(Chunks are provided in file-order, so you can infer the length
using the next chunk position if necessary.)
+ The CHUNK LOOKUP matches the table of contents from
+ link:technical/chunk-format.html[the chunk-based file format].
+
The remaining data in the body is described one chunk at a time, and
these chunks may be given in any order. Chunks are required unless
otherwise specified.
diff --git a/Documentation/technical/protocol-v2.txt b/Documentation/technical/protocol-v2.txt
index 85daeb5d9e..a7c806a73e 100644
--- a/Documentation/technical/protocol-v2.txt
+++ b/Documentation/technical/protocol-v2.txt
@@ -33,8 +33,8 @@ In protocol v2 these special packets will have the following semantics:
* '0000' Flush Packet (flush-pkt) - indicates the end of a message
* '0001' Delimiter Packet (delim-pkt) - separates sections of a message
- * '0002' Message Packet (response-end-pkt) - indicates the end of a response
- for stateless connections
+ * '0002' Response End Packet (response-end-pkt) - indicates the end of a
+ response for stateless connections
Initial Client Request
----------------------
@@ -192,11 +192,20 @@ ls-refs takes in the following arguments:
When specified, only references having a prefix matching one of
the provided prefixes are displayed.
+If the 'unborn' feature is advertised the following argument can be
+included in the client's request.
+
+ unborn
+ The server will send information about HEAD even if it is a symref
+ pointing to an unborn branch in the form "unborn HEAD
+ symref-target:<target>".
+
The output of ls-refs is as follows:
output = *ref
flush-pkt
- ref = PKT-LINE(obj-id SP refname *(SP ref-attribute) LF)
+ obj-id-or-unborn = (obj-id | "unborn")
+ ref = PKT-LINE(obj-id-or-unborn SP refname *(SP ref-attribute) LF)
ref-attribute = (symref | peeled)
symref = "symref-target:" symref-target
peeled = "peeled:" obj-id
diff --git a/Documentation/technical/reftable.txt b/Documentation/technical/reftable.txt
index 8095ab2590..3ef169af27 100644
--- a/Documentation/technical/reftable.txt
+++ b/Documentation/technical/reftable.txt
@@ -872,17 +872,11 @@ A repository must set its `$GIT_DIR/config` to configure reftable:
Layout
^^^^^^
-A collection of reftable files are stored in the `$GIT_DIR/reftable/`
-directory:
-
-....
-00000001-00000001.log
-00000002-00000002.ref
-00000003-00000003.ref
-....
-
-where reftable files are named by a unique name such as produced by the
-function `${min_update_index}-${max_update_index}.ref`.
+A collection of reftable files are stored in the `$GIT_DIR/reftable/` directory.
+Their names should have a random element, such that each filename is globally
+unique; this helps avoid spurious failures on Windows, where open files cannot
+be removed or overwritten. It suggested to use
+`${min_update_index}-${max_update_index}-${random}.ref` as a naming convention.
Log-only files use the `.log` extension, while ref-only and mixed ref
and log files use `.ref`. extension.
@@ -893,9 +887,9 @@ current files, one per line, in order, from oldest (base) to newest
....
$ cat .git/reftable/tables.list
-00000001-00000001.log
-00000002-00000002.ref
-00000003-00000003.ref
+00000001-00000001-RANDOM1.log
+00000002-00000002-RANDOM2.ref
+00000003-00000003-RANDOM3.ref
....
Readers must read `$GIT_DIR/reftable/tables.list` to determine which
@@ -940,7 +934,7 @@ new reftable and atomically appending it to the stack:
3. Select `update_index` to be most recent file's
`max_update_index + 1`.
4. Prepare temp reftable `tmp_XXXXXX`, including log entries.
-5. Rename `tmp_XXXXXX` to `${update_index}-${update_index}.ref`.
+5. Rename `tmp_XXXXXX` to `${update_index}-${update_index}-${random}.ref`.
6. Copy `tables.list` to `tables.list.lock`, appending file from (5).
7. Rename `tables.list.lock` to `tables.list`.
@@ -993,7 +987,7 @@ prevents other processes from trying to compact these files.
should always be the case, assuming that other processes are adhering to
the locking protocol.
7. Rename `${min_update_index}-${max_update_index}_XXXXXX` to
-`${min_update_index}-${max_update_index}.ref`.
+`${min_update_index}-${max_update_index}-${random}.ref`.
8. Write the new stack to `tables.list.lock`, replacing `B` and `C`
with the file from (4).
9. Rename `tables.list.lock` to `tables.list`.
@@ -1005,6 +999,22 @@ This strategy permits compactions to proceed independently of updates.
Each reftable (compacted or not) is uniquely identified by its name, so
open reftables can be cached by their name.
+Windows
+^^^^^^^
+
+On windows, and other systems that do not allow deleting or renaming to open
+files, compaction may succeed, but other readers may prevent obsolete tables
+from being deleted.
+
+On these platforms, the following strategy can be followed: on closing a
+reftable stack, reload `tables.list`, and delete any tables no longer mentioned
+in `tables.list`.
+
+Irregular program exit may still leave about unused files. In this case, a
+cleanup operation can read `tables.list`, note its modification timestamp, and
+delete any unreferenced `*.ref` files that are older.
+
+
Alternatives considered
~~~~~~~~~~~~~~~~~~~~~~~