Documentation / technical / protocol-capabilities.txton commit Documentation/technical: signed tag format (5f1abfe)
   1Git Protocol Capabilities
   2=========================
   3
   4Servers SHOULD support all capabilities defined in this document.
   5
   6On the very first line of the initial server response of either
   7receive-pack and upload-pack the first reference is followed by
   8a NUL byte and then a list of space delimited server capabilities.
   9These allow the server to declare what it can and cannot support
  10to the client.
  11
  12Client will then send a space separated list of capabilities it wants
  13to be in effect. The client MUST NOT ask for capabilities the server
  14did not say it supports.
  15
  16Server MUST diagnose and abort if capabilities it does not understand
  17was sent.  Server MUST NOT ignore capabilities that client requested
  18and server advertised.  As a consequence of these rules, server MUST
  19NOT advertise capabilities it does not understand.
  20
  21The 'atomic', 'report-status', 'delete-refs', 'quiet', and 'push-cert'
  22capabilities are sent and recognized by the receive-pack (push to server)
  23process.
  24
  25The 'ofs-delta' and 'side-band-64k' capabilities are sent and recognized
  26by both upload-pack and receive-pack protocols.  The 'agent' capability
  27may optionally be sent in both protocols.
  28
  29All other capabilities are only recognized by the upload-pack (fetch
  30from server) process.
  31
  32multi_ack
  33---------
  34
  35The 'multi_ack' capability allows the server to return "ACK obj-id
  36continue" as soon as it finds a commit that it can use as a common
  37base, between the client's wants and the client's have set.
  38
  39By sending this early, the server can potentially head off the client
  40from walking any further down that particular branch of the client's
  41repository history.  The client may still need to walk down other
  42branches, sending have lines for those, until the server has a
  43complete cut across the DAG, or the client has said "done".
  44
  45Without multi_ack, a client sends have lines in --date-order until
  46the server has found a common base.  That means the client will send
  47have lines that are already known by the server to be common, because
  48they overlap in time with another branch that the server hasn't found
  49a common base on yet.
  50
  51For example suppose the client has commits in caps that the server
  52doesn't and the server has commits in lower case that the client
  53doesn't, as in the following diagram:
  54
  55       +---- u ---------------------- x
  56      /              +----- y
  57     /              /
  58    a -- b -- c -- d -- E -- F
  59       \
  60        +--- Q -- R -- S
  61
  62If the client wants x,y and starts out by saying have F,S, the server
  63doesn't know what F,S is.  Eventually the client says "have d" and
  64the server sends "ACK d continue" to let the client know to stop
  65walking down that line (so don't send c-b-a), but it's not done yet,
  66it needs a base for x. The client keeps going with S-R-Q, until a
  67gets reached, at which point the server has a clear base and it all
  68ends.
  69
  70Without multi_ack the client would have sent that c-b-a chain anyway,
  71interleaved with S-R-Q.
  72
  73multi_ack_detailed
  74------------------
  75This is an extension of multi_ack that permits client to better
  76understand the server's in-memory state. See pack-protocol.txt,
  77section "Packfile Negotiation" for more information.
  78
  79no-done
  80-------
  81This capability should only be used with the smart HTTP protocol. If
  82multi_ack_detailed and no-done are both present, then the sender is
  83free to immediately send a pack following its first "ACK obj-id ready"
  84message.
  85
  86Without no-done in the smart HTTP protocol, the server session would
  87end and the client has to make another trip to send "done" before
  88the server can send the pack. no-done removes the last round and
  89thus slightly reduces latency.
  90
  91thin-pack
  92---------
  93
  94A thin pack is one with deltas which reference base objects not
  95contained within the pack (but are known to exist at the receiving
  96end). This can reduce the network traffic significantly, but it
  97requires the receiving end to know how to "thicken" these packs by
  98adding the missing bases to the pack.
  99
 100The upload-pack server advertises 'thin-pack' when it can generate
 101and send a thin pack. A client requests the 'thin-pack' capability
 102when it understands how to "thicken" it, notifying the server that
 103it can receive such a pack. A client MUST NOT request the
 104'thin-pack' capability if it cannot turn a thin pack into a
 105self-contained pack.
 106
 107Receive-pack, on the other hand, is assumed by default to be able to
 108handle thin packs, but can ask the client not to use the feature by
 109advertising the 'no-thin' capability. A client MUST NOT send a thin
 110pack if the server advertises the 'no-thin' capability.
 111
 112The reasons for this asymmetry are historical. The receive-pack
 113program did not exist until after the invention of thin packs, so
 114historically the reference implementation of receive-pack always
 115understood thin packs. Adding 'no-thin' later allowed receive-pack
 116to disable the feature in a backwards-compatible manner.
 117
 118
 119side-band, side-band-64k
 120------------------------
 121
 122This capability means that server can send, and client understand multiplexed
 123progress reports and error info interleaved with the packfile itself.
 124
 125These two options are mutually exclusive. A modern client always
 126favors 'side-band-64k'.
 127
 128Either mode indicates that the packfile data will be streamed broken
 129up into packets of up to either 1000 bytes in the case of 'side_band',
 130or 65520 bytes in the case of 'side_band_64k'. Each packet is made up
 131of a leading 4-byte pkt-line length of how much data is in the packet,
 132followed by a 1-byte stream code, followed by the actual data.
 133
 134The stream code can be one of:
 135
 136 1 - pack data
 137 2 - progress messages
 138 3 - fatal error message just before stream aborts
 139
 140The "side-band-64k" capability came about as a way for newer clients
 141that can handle much larger packets to request packets that are
 142actually crammed nearly full, while maintaining backward compatibility
 143for the older clients.
 144
 145Further, with side-band and its up to 1000-byte messages, it's actually
 146999 bytes of payload and 1 byte for the stream code. With side-band-64k,
 147same deal, you have up to 65519 bytes of data and 1 byte for the stream
 148code.
 149
 150The client MUST send only maximum of one of "side-band" and "side-
 151band-64k".  Server MUST diagnose it as an error if client requests
 152both.
 153
 154ofs-delta
 155---------
 156
 157Server can send, and client understand PACKv2 with delta referring to
 158its base by position in pack rather than by an obj-id.  That is, they can
 159send/read OBJ_OFS_DELTA (aka type 6) in a packfile.
 160
 161agent
 162-----
 163
 164The server may optionally send a capability of the form `agent=X` to
 165notify the client that the server is running version `X`. The client may
 166optionally return its own agent string by responding with an `agent=Y`
 167capability (but it MUST NOT do so if the server did not mention the
 168agent capability). The `X` and `Y` strings may contain any printable
 169ASCII characters except space (i.e., the byte range 32 < x < 127), and
 170are typically of the form "package/version" (e.g., "git/1.8.3.1"). The
 171agent strings are purely informative for statistics and debugging
 172purposes, and MUST NOT be used to programmatically assume the presence
 173or absence of particular features.
 174
 175shallow
 176-------
 177
 178This capability adds "deepen", "shallow" and "unshallow" commands to
 179the  fetch-pack/upload-pack protocol so clients can request shallow
 180clones.
 181
 182no-progress
 183-----------
 184
 185The client was started with "git clone -q" or something, and doesn't
 186want that side band 2.  Basically the client just says "I do not
 187wish to receive stream 2 on sideband, so do not send it to me, and if
 188you did, I will drop it on the floor anyway".  However, the sideband
 189channel 3 is still used for error responses.
 190
 191include-tag
 192-----------
 193
 194The 'include-tag' capability is about sending annotated tags if we are
 195sending objects they point to.  If we pack an object to the client, and
 196a tag object points exactly at that object, we pack the tag object too.
 197In general this allows a client to get all new annotated tags when it
 198fetches a branch, in a single network connection.
 199
 200Clients MAY always send include-tag, hardcoding it into a request when
 201the server advertises this capability. The decision for a client to
 202request include-tag only has to do with the client's desires for tag
 203data, whether or not a server had advertised objects in the
 204refs/tags/* namespace.
 205
 206Servers MUST pack the tags if their referrant is packed and the client
 207has requested include-tags.
 208
 209Clients MUST be prepared for the case where a server has ignored
 210include-tag and has not actually sent tags in the pack.  In such
 211cases the client SHOULD issue a subsequent fetch to acquire the tags
 212that include-tag would have otherwise given the client.
 213
 214The server SHOULD send include-tag, if it supports it, regardless
 215of whether or not there are tags available.
 216
 217report-status
 218-------------
 219
 220The receive-pack process can receive a 'report-status' capability,
 221which tells it that the client wants a report of what happened after
 222a packfile upload and reference update.  If the pushing client requests
 223this capability, after unpacking and updating references the server
 224will respond with whether the packfile unpacked successfully and if
 225each reference was updated successfully.  If any of those were not
 226successful, it will send back an error message.  See pack-protocol.txt
 227for example messages.
 228
 229delete-refs
 230-----------
 231
 232If the server sends back the 'delete-refs' capability, it means that
 233it is capable of accepting a zero-id value as the target
 234value of a reference update.  It is not sent back by the client, it
 235simply informs the client that it can be sent zero-id values
 236to delete references.
 237
 238quiet
 239-----
 240
 241If the receive-pack server advertises the 'quiet' capability, it is
 242capable of silencing human-readable progress output which otherwise may
 243be shown when processing the received pack. A send-pack client should
 244respond with the 'quiet' capability to suppress server-side progress
 245reporting if the local progress reporting is also being suppressed
 246(e.g., via `push -q`, or if stderr does not go to a tty).
 247
 248atomic
 249------
 250
 251If the server sends the 'atomic' capability it is capable of accepting
 252atomic pushes. If the pushing client requests this capability, the server
 253will update the refs in one atomic transaction. Either all refs are
 254updated or none.
 255
 256allow-tip-sha1-in-want
 257----------------------
 258
 259If the upload-pack server advertises this capability, fetch-pack may
 260send "want" lines with SHA-1s that exist at the server but are not
 261advertised by upload-pack.
 262
 263allow-reachable-sha1-in-want
 264----------------------------
 265
 266If the upload-pack server advertises this capability, fetch-pack may
 267send "want" lines with SHA-1s that exist at the server but are not
 268advertised by upload-pack.
 269
 270push-cert=<nonce>
 271-----------------
 272
 273The receive-pack server that advertises this capability is willing
 274to accept a signed push certificate, and asks the <nonce> to be
 275included in the push certificate.  A send-pack client MUST NOT
 276send a push-cert packet unless the receive-pack server advertises
 277this capability.