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matrix-spec/specification/server_server_api.rst

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.. Copyright 2016 OpenMarket Ltd
..
.. Licensed under the Apache License, Version 2.0 (the "License");
.. you may not use this file except in compliance with the License.
.. You may obtain a copy of the License at
..
.. http://www.apache.org/licenses/LICENSE-2.0
..
.. Unless required by applicable law or agreed to in writing, software
.. distributed under the License is distributed on an "AS IS" BASIS,
.. WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
.. See the License for the specific language governing permissions and
.. limitations under the License.
Federation API
==============
Matrix homeservers use the Federation APIs (also known as server-server APIs)
to communicate with each other. Homeservers use these APIs to push messages to
each other in real-time, to request historic messages from each other, and to
query profile and presence information about users on each other's servers.
The APIs are implemented using HTTPS GETs and PUTs between each of the
servers. These HTTPS requests are strongly authenticated using public key
signatures at the TLS transport layer and using public key signatures in
HTTP Authorization headers at the HTTP layer.
There are three main kinds of communication that occur between homeservers:
Persisted Data Units (PDUs):
These events are broadcast from one homeserver to any others that have
joined the same room (identified by Room ID). They are persisted in
long-term storage and record the history of messages and state for a
room.
Like email, it is the responsibility of the originating server of a PDU
to deliver that event to its recipient servers. However PDUs are signed
using the originating server's private key so that it is possible to
deliver them through third-party servers.
Ephemeral Data Units (EDUs):
These events are pushed between pairs of homeservers. They are not
persisted and are not part of the history of a room, nor does the
receiving homeserver have to reply to them.
Queries:
These are single request/response interactions between a given pair of
servers, initiated by one side sending an HTTPS GET request to obtain some
information, and responded by the other. They are not persisted and contain
no long-term significant history. They simply request a snapshot state at
the instant the query is made.
EDUs and PDUs are further wrapped in an envelope called a Transaction, which is
transferred from the origin to the destination homeserver using an HTTPS PUT
request.
.. contents:: Table of Contents
.. sectnum::
Specification version
---------------------
This version of the specification is generated from
`matrix-doc <https://github.com/matrix-org/matrix-doc>`_ as of Git commit
`{{git_version}} <https://github.com/matrix-org/matrix-doc/tree/{{git_rev}}>`_.
Server Discovery
----------------
Resolving Server Names
~~~~~~~~~~~~~~~~~~~~~~
Each matrix homeserver is identified by a server name consisting of a DNS name
and an optional TLS port.
.. code::
server_name = dns_name [ ":" tls_port]
dns_name = <host, see [RFC 3986], Section 3.2.2>
tls_port = *DIGIT
.. **
If the port is present then the server is discovered by looking up an AAAA or
A record for the DNS name and connecting to the specified TLS port. If the port
is absent then the server is discovered by looking up a ``_matrix._tcp`` SRV
record for the DNS name. If this record does not exist then the server is
discovered by looking up an AAAA or A record on the DNS name and taking the
default fallback port number of 8448.
Homeservers may use SRV records to load balance requests between multiple TLS
endpoints or to failover to another endpoint if an endpoint fails.
Retrieving Server Keys
~~~~~~~~~~~~~~~~~~~~~~
Version 2
+++++++++
Each homeserver publishes its public keys under ``/_matrix/key/v2/server/``.
Homeservers query for keys by either getting ``/_matrix/key/v2/server/``
directly or by querying an intermediate notary server using a
``/_matrix/key/v2/query`` API. Intermediate notary servers query the
``/_matrix/key/v2/server/`` API on behalf of another server and sign the
response with their own key. A server may query multiple notary servers to
ensure that they all report the same public keys.
This approach is borrowed from the `Perspectives Project`_, but modified to
include the NACL keys and to use JSON instead of XML. It has the advantage of
avoiding a single trust-root since each server is free to pick which notary
servers they trust and can corroborate the keys returned by a given notary
server by querying other servers.
.. _Perspectives Project: http://perspectives-project.org/
Publishing Keys
^^^^^^^^^^^^^^^
Homeservers publish the allowed TLS fingerprints and signing keys in a JSON
object at ``/_matrix/key/v2/server/{key_id}``. The response contains a list of
``verify_keys`` that are valid for signing federation requests made by the
server and for signing events. It contains a list of ``old_verify_keys``
which are only valid for signing events. Finally the response contains a list
of TLS certificate fingerprints to validate any connection made to the server.
A server may have multiple keys active at a given time. A server may have any
number of old keys. It is recommended that servers return a single JSON
response listing all of its keys whenever any ``key_id`` is requested to reduce
the number of round trips needed to discover the relevant keys for a server.
However a server may return a different responses for a different ``key_id``.
The ``tls_certificates`` contain a list of hashes of the X.509 TLS certificates
currently used by the server. The list must include SHA-256 hashes for every
certificate currently in use by the server. These fingerprints are valid until
the millisecond POSIX timestamp in ``valid_until_ts``.
The ``verify_keys`` can be used to sign requests and events made by the server
until the millisecond POSIX timestamp in ``valid_until_ts``. If a homeserver
receives an event with a ``origin_server_ts`` after the ``valid_until_ts`` then
it should request that ``key_id`` for the originating server to check whether
the key has expired.
The ``old_verify_keys`` can be used to sign events with an ``origin_server_ts``
before the ``expired_ts``. The ``expired_ts`` is a millisecond POSIX timestamp
of when the originating server stopped using that key.
Intermediate notary servers should cache a response for half of its remaining
life time to avoid serving a stale response. Originating servers should avoid
returning responses that expire in less than an hour to avoid repeated requests
for an about to expire certificate. Requesting servers should limit how
frequently they query for certificates to avoid flooding a server with requests.
If a server goes offline intermediate notary servers should continue to return
the last response they received from that server so that the signatures of old
events sent by that server can still be checked.
==================== =================== ======================================
Key Type Description
==================== =================== ======================================
``server_name`` String DNS name of the homeserver.
``verify_keys`` Object Public keys of the homeserver for
verifying digital signatures.
``old_verify_keys`` Object The public keys that the server used
to use and when it stopped using them.
``signatures`` Object Digital signatures for this object
signed using the ``verify_keys``.
``tls_fingerprints`` Array of Objects Hashes of X.509 TLS certificates used
by this this server encoded as `Unpadded Base64`_.
``valid_until_ts`` Integer POSIX timestamp when the list of valid
keys should be refreshed.
==================== =================== ======================================
.. code:: json
{
"old_verify_keys": {
"ed25519:auto1": {
"expired_ts": 922834800000,
"key": "Base+64+Encoded+Old+Verify+Key"
}
},
"server_name": "example.org",
"signatures": {
"example.org": {
"ed25519:auto2": "Base+64+Encoded+Signature"
}
},
"tls_fingerprints": [
{
"sha256": "Base+64+Encoded+SHA-256-Fingerprint"
}
],
"valid_until_ts": 1052262000000,
"verify_keys": {
"ed25519:auto2": {
"key": "Base+64+Encoded+Signature+Verification+Key"
}
}
}
Querying Keys Through Another Server
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Servers may offer a query API ``_matrix/key/v2/query/`` for getting the keys
for another server. This API can be used to GET at list of JSON objects for a
given server or to POST a bulk query for a number of keys from a number of
servers. Either way the response is a list of JSON objects containing the
JSON published by the server under ``_matrix/key/v2/server/`` signed by
both the originating server and by this server.
The ``minimum_valid_until_ts`` is a millisecond POSIX timestamp indicating
when the returned certificate will need to be valid until to be useful to the
requesting server. This can be set using the maximum ``origin_server_ts`` of
an batch of events that a requesting server is trying to validate. This allows
an intermediate notary server to give a prompt cached response even if the
originating server is offline.
This API can return keys for servers that are offline be using cached responses
taken from when the server was online. Keys can be queried from multiple
servers to mitigate against DNS spoofing.
Requests:
.. code::
GET /_matrix/key/v2/query/${server_name}/${key_id}/?minimum_valid_until_ts=${minimum_valid_until_ts} HTTP/1.1
POST /_matrix/key/v2/query HTTP/1.1
Content-Type: application/json
{
"server_keys": {
"$server_name": {
"$key_id": {
"minimum_valid_until_ts": $posix_timestamp
}
}
}
}
Response:
.. code::
HTTP/1.1 200 OK
Content-Type: application/json
{
"server_keys": [
# List of responses with same format as /_matrix/key/v2/server
# signed by both the originating server and this server.
]
}
Version 1
+++++++++
.. WARNING::
Version 1 of key distribution is obsolete
Homeservers publish their TLS certificates and signing keys in a JSON object
at ``/_matrix/key/v1``.
==================== =================== ======================================
Key Type Description
==================== =================== ======================================
``server_name`` String DNS name of the homeserver.
``verify_keys`` Object Public keys of the homeserver for
verifying digital signatures.
``signatures`` Object Digital signatures for this object
signed using the ``verify_keys``.
``tls_certificate`` String The X.509 TLS certificate used by this
this server encoded as `Unpadded Base64`_.
==================== =================== ======================================
.. code:: json
{
"server_name": "example.org",
"signatures": {
"example.org": {
"ed25519:auto": "Base+64+Encoded+Signature"
}
},
"tls_certificate": "Base+64+Encoded+DER+Encoded+X509+TLS+Certificate"
"verify_keys": {
"ed25519:auto": "Base+64+Encoded+Signature+Verification+Key"
}
}
When fetching the keys for a server the client should check that the TLS
certificate in the JSON matches the TLS server certificate for the connection
and should check that the JSON signatures are correct for the supplied
``verify_keys``
Transactions
------------
.. WARNING::
This section may be misleading or inaccurate.
The transfer of EDUs and PDUs between homeservers is performed by an exchange
of Transaction messages, which are encoded as JSON objects, passed over an HTTP
PUT request. A Transaction is meaningful only to the pair of homeservers that
exchanged it; they are not globally-meaningful.
Each transaction has:
- An opaque transaction ID.
- A timestamp (UNIX epoch time in milliseconds) generated by its origin
server.
- An origin and destination server name.
- A list of "previous IDs".
- A list of PDUs and EDUs - the actual message payload that the Transaction
carries.
Transaction Fields
~~~~~~~~~~~~~~~~~~
==================== =================== ======================================
Key Type Description
==================== =================== ======================================
``origin`` String DNS name of homeserver making this
transaction.
``origin_server_ts`` Integer Timestamp in milliseconds on
originating homeserver when this
transaction started.
``previous_ids`` List of Strings List of transactions that were sent
immediately prior to this transaction.
``pdus`` List of Objects List of persistent updates to rooms.
``edus`` List of Objects List of ephemeral messages.
==================== =================== ======================================
.. code:: json
{
"transaction_id":"916d630ea616342b42e98a3be0b74113",
"ts":1404835423000,
"origin":"red",
"prev_ids":["e1da392e61898be4d2009b9fecce5325"],
"pdus":[...],
"edus":[...]
}
The ``prev_ids`` field contains a list of previous transaction IDs that the
``origin`` server has sent to this ``destination``. Its purpose is to act as a
sequence checking mechanism - the destination server can check whether it has
successfully received that Transaction, or ask for a re-transmission if not.
The ``pdus`` field of a transaction is a list, containing zero or more PDUs.[*]
Each PDU is itself a JSON object containing a number of keys, the exact details
of which will vary depending on the type of PDU. Similarly, the ``edus`` field
is another list containing the EDUs. This key may be entirely absent if there
are no EDUs to transfer.
(* Normally the PDU list will be non-empty, but the server should cope with
receiving an "empty" transaction, as this is useful for informing peers of other
transaction IDs they should be aware of. This effectively acts as a push
mechanism to encourage peers to continue to replicate content.)
PDUs
----
All PDUs have:
- An ID to identify the PDU itself
- A room ID that it relates to
- A declaration of their type
- A list of other PDU IDs that have been seen recently in that room (regardless
of which origin sent them)
Required PDU Fields
~~~~~~~~~~~~~~~~~~~
==================== ================== =======================================
Key Type Description
==================== ================== =======================================
``context`` String Room identifier
``user_id`` String The ID of the user sending the PDU
``origin`` String DNS name of homeserver that created
this PDU
``pdu_id`` String Unique identifier for PDU on the
originating homeserver
``origin_server_ts`` Integer Timestamp in milliseconds on origin
homeserver when this PDU was created.
``pdu_type`` String PDU event type
``content`` Object The content of the PDU.
``prev_pdus`` List of (String, The originating homeserver, PDU ids and
String, Object) hashes of the most recent PDUs the
Triplets homeserver was aware of for the room
when it made this PDU
``depth`` Integer The maximum depth of the previous PDUs
plus one
``is_state`` Boolean True if this PDU is updating room state
==================== ================== =======================================
.. code:: json
{
"context":"#example:green.example.com",
"origin":"green.example.com",
"pdu_id":"a4ecee13e2accdadf56c1025af232176",
"origin_server_ts":1404838188000,
"pdu_type":"m.room.message",
"prev_pdus":[
["blue.example.com","99d16afbc8",
{"sha256":"abase64encodedsha256hashshouldbe43byteslong"}]
],
"hashes":{"sha256":"thishashcoversallfieldsincasethisisredacted"},
"signatures":{
"green.example.com":{
"ed25519:key_version:":"these86bytesofbase64signaturecoveressentialfieldsincludinghashessocancheckredactedpdus"
}
},
"is_state":false,
"content": {...}
}
In contrast to Transactions, it is important to note that the ``prev_pdus``
field of a PDU refers to PDUs that any origin server has sent, rather than
previous IDs that this ``origin`` has sent. This list may refer to other PDUs
sent by the same origin as the current one, or other origins.
Because of the distributed nature of participants in a Matrix conversation, it
is impossible to establish a globally-consistent total ordering on the events.
However, by annotating each outbound PDU at its origin with IDs of other PDUs
it has received, a partial ordering can be constructed allowing causality
relationships to be preserved. A client can then display these messages to the
end-user in some order consistent with their content and ensure that no message
that is semantically in reply of an earlier one is ever displayed before it.
State Update PDU Fields
~~~~~~~~~~~~~~~~~~~~~~~
PDUs fall into two main categories: those that deliver Events, and those that
synchronise State. For PDUs that relate to State synchronisation, additional
keys exist to support this:
======================== ============ =========================================
Key Type Description
======================== ============ =========================================
``state_key`` String Combined with the ``pdu_type`` this
identifies the which part of the room
state is updated
``required_power_level`` Integer The required power level needed to
replace this update.
``prev_state_id`` String The PDU id of the update this replaces.
``prev_state_origin`` String The homeserver of the update this
replaces.
``user_id`` String The user updating the state.
======================== ============ =========================================
.. code:: json
{...,
"is_state":true,
"state_key":TODO-doc
"required_power_level":TODO-doc
"prev_state_id":TODO-doc
"prev_state_origin":TODO-doc
}
EDUs
----
EDUs, by comparison to PDUs, do not have an ID, a room ID, or a list of
"previous" IDs. The only mandatory fields for these are the type, origin and
destination homeserver names, and the actual nested content.
======================== ============ =========================================
Key Type Description
======================== ============ =========================================
``edu_type`` String The type of the ephemeral message.
``content`` Object Content of the ephemeral message.
======================== ============ =========================================
.. code:: json
{
"edu_type":"m.presence",
"origin":"blue",
"destination":"orange",
"content":{...}
}
Protocol URLs
-------------
.. WARNING::
This section may be misleading or inaccurate.
All these URLs are name-spaced within a prefix of::
/_matrix/federation/v1/...
For active pushing of messages representing live activity "as it happens"::
PUT .../send/<transaction_id>/
Body: JSON encoding of a single Transaction
Response: TODO-doc
The transaction_id path argument will override any ID given in the JSON body.
The destination name will be set to that of the receiving server itself. Each
embedded PDU in the transaction body will be processed.
To fetch all the state of a given room::
GET .../state/<room_id>/
Response: JSON encoding of a single Transaction containing multiple PDUs
Retrieves a snapshot of the entire current state of the given room. The
response will contain a single Transaction, inside which will be a list of PDUs
that encode the state.
To fetch a particular event::
GET .../event/<event_id>/
Response: JSON encoding of a partial Transaction containing the event
Retrieves a single event. The response will contain a partial Transaction,
having just the ``origin``, ``origin_server_ts`` and ``pdus`` fields; the
event will be encoded as the only PDU in the ``pdus`` list.
To backfill events on a given room::
GET .../backfill/<room_id>/
Query args: v, limit
Response: JSON encoding of a single Transaction containing multiple PDUs
Retrieves a sliding-window history of previous PDUs that occurred on the given
room. Starting from the PDU ID(s) given in the "v" argument, the PDUs that
preceded it are retrieved, up to a total number given by the "limit" argument.
To stream events all the events::
GET .../pull/
Query args: origin, v
Response: JSON encoding of a single Transaction consisting of multiple PDUs
Retrieves all of the transactions later than any version given by the "v"
arguments.
To make a query::
GET .../query/<query_type>
Query args: as specified by the individual query types
Response: JSON encoding of a response object
Performs a single query request on the receiving homeserver. The Query Type
part of the path specifies the kind of query being made, and its query
arguments have a meaning specific to that kind of query. The response is a
JSON-encoded object whose meaning also depends on the kind of query.
To join a room::
GET .../make_join/<room_id>/<user_id>
Response: JSON encoding of a join proto-event
PUT .../send_join/<room_id>/<event_id>
Response: JSON encoding of the state of the room at the time of the event
Performs the room join handshake. For more information, see "Joining Rooms"
below.
Joining Rooms
-------------
When a new user wishes to join room that the user's homeserver already knows
about, the homeserver can immediately determine if this is allowable by
inspecting the state of the room, and if it is acceptable, it can generate,
sign, and emit a new ``m.room.member`` state event adding the user into that
room. When the homeserver does not yet know about the room it cannot do this
directly. Instead, it must take a longer multi-stage handshaking process by
which it first selects a remote homeserver which is already participating in
that room, and uses it to assist in the joining process. This is the remote
join handshake.
This handshake involves the homeserver of the new member wishing to join
(referred to here as the "joining" server), the directory server hosting the
room alias the user is requesting to join with, and a homeserver where existing
room members are already present (referred to as the "resident" server).
In summary, the remote join handshake consists of the joining server querying
the directory server for information about the room alias; receiving a room ID
and a list of join candidates. The joining server then requests information
about the room from one of the residents. It uses this information to construct
a ``m.room.member`` event which it finally sends to a resident server.
Conceptually these are three different roles of homeserver. In practice the
directory server is likely to be resident in the room, and so may be selected
by the joining server to be the assisting resident. Likewise, it is likely that
the joining server picks the same candidate resident for both phases of event
construction, though in principle any valid candidate may be used at each time.
Thus, any join handshake can potentially involve anywhere from two to four
homeservers, though most in practice will use just two.
::
Client Joining Directory Resident
Server Server Server
join request -->
|
directory request ------->
<---------- directory response
|
make_join request ----------------------->
<------------------------------- make_join response
|
send_join request ----------------------->
<------------------------------- send_join response
|
<---------- join response
The first part of the handshake usually involves using the directory server to
request the room ID and join candidates. This is covered in more detail on the
directory server documentation, below. In the case of a new user joining a
room as a result of a received invite, the joining user's homeserver could
optimise this step away by picking the origin server of that invite message as
the join candidate. However, the joining server should be aware that the origin
server of the invite might since have left the room, so should be prepared to
fall back on the regular join flow if this optimisation fails.
Once the joining server has the room ID and the join candidates, it then needs
to obtain enough information about the room to fill in the required fields of
the ``m.room.member`` event. It obtains this by selecting a resident from the
candidate list, and requesting the ``make_join`` endpoint using a ``GET``
request, specifying the room ID and the user ID of the new member who is
attempting to join.
The resident server replies to this request with a JSON-encoded object having a
single key called ``event``; within this is an object whose fields contain some
of the information that the joining server will need. Despite its name, this
object is not a full event; notably it does not need to be hashed or signed by
the resident homeserver. The required fields are:
==================== ======== ============
Key Type Description
==================== ======== ============
``type`` String The value ``m.room.member``
``auth_events`` List An event-reference list containing the
authorization events that would allow this member
to join
``content`` Object The event content
``depth`` Integer (this field must be present but is ignored; it
may be 0)
``origin`` String The name of the resident homeserver
``origin_server_ts`` Integer A timestamp added by the resident homeserver
``prev_events`` List An event-reference list containing the immediate
predecessor events
``room_id`` String The room ID of the room
``sender`` String The user ID of the joining member
``state_key`` String The user ID of the joining member
==================== ======== ============
The ``content`` field itself must be an object, containing:
============== ====== ============
Key Type Description
============== ====== ============
``membership`` String The value ``join``
============== ====== ============
The joining server now has sufficient information to construct the real join
event from these protoevent fields. It copies the values of most of them,
adding (or replacing) the following fields:
==================== ======= ============
Key Type Description
==================== ======= ============
``event_id`` String A new event ID specified by the joining homeserver
``origin`` String The name of the joining homeserver
``origin_server_ts`` Integer A timestamp added by the joining homeserver
==================== ======= ============
This will be a true event, so the joining server should apply the event-signing
algorithm to it, resulting in the addition of the ``hashes`` and ``signatures``
fields.
To complete the join handshake, the joining server must now submit this new
event to an resident homeserver, by using the ``send_join`` endpoint. This is
invoked using the room ID and the event ID of the new member event.
The resident homeserver then accepts this event into the room's event graph,
and responds to the joining server with the full set of state for the newly-
joined room. This is returned as a two-element list, whose first element is the
integer 200, and whose second element is an object which contains the
following keys:
============== ===== ============
Key Type Description
============== ===== ============
``auth_chain`` List A list of events giving the authorization chain for this
join event
``state`` List A complete list of the prevailing state events at the
instant just before accepting the new ``m.room.member``
event
============== ===== ============
.. TODO-spec
- (paul) I don't really understand why the full auth_chain events are given
here. What purpose does it serve expanding them out in full, when surely
they'll appear in the state anyway?
Backfilling
-----------
Once a homeserver has joined a room, it receives all the events emitted by
other homeservers in that room, and is thus aware of the entire history of the
room from that moment onwards. Since users in that room are able to request the
history by the ``/messages`` client API endpoint, it's possible that they might
step backwards far enough into history before the homeserver itself was a
member of that room.
To cover this case, the federation API provides a server-to-server analog of
the ``/messages`` client API, allowing one homeserver to fetch history from
another. This is the ``/backfill`` API.
To request more history, the requesting homeserver picks another homeserver
that it thinks may have more (most likely this should be a homeserver for some
of the existing users in the room at the earliest point in history it has
currently), and makes a ``/backfill`` request. The parameters of this request
give an event ID that the requesting homeserver wishes to obtain, and a number
specifying how many more events of history before that one to return at most.
The response to this request is an object with the following keys:
==================== ======== ============
Key Type Description
==================== ======== ============
``pdus`` List A list of events
``origin`` String The name of the resident homeserver
``origin_server_ts`` Integer A timestamp added by the resident homeserver
==================== ======== ============
The list of events given in ``pdus`` is returned in reverse chronological
order; having the most recent event first (i.e. the event whose event ID is
that requested by the requestor in the ``v`` parameter).
.. TODO-spec
Specify (or remark that it is unspecified) how the server handles divergent
history. DFS? BFS? Anything weirder?
Inviting to a room
------------------
When a user wishes to invite an other user to a local room and the other user
is on a different server, the inviting server will send a request to the invited
server::
PUT .../invite/{roomId}/{eventId}
The required fields in the JSON body are:
==================== ======== ============
Key Type Description
==================== ======== ============
``room_id`` String The room ID of the room. Must be the same as the
room ID specified in the path.
``event_id`` String The ID of the event. Must be the same as the event
ID specified in the path.
``type`` String The value ``m.room.member``.
``auth_events`` List An event-reference list containing the IDs of the
authorization events that would allow this member
to be invited in the room.
``content`` Object The content of the event.
``depth`` Integer The depth of the event.
``origin`` String The name of the inviting homeserver.
``origin_server_ts`` Integer A timestamp added by the inviting homeserver.
``prev_events`` List An event-reference list containing the IDs of the
immediate predecessor events.
``sender`` String The Matrix ID of the user who sent the original
`m.room.third_party_invite`.
``state_key`` String The Matrix ID of the invited user.
``signatures`` Object The signature of the event from the origin server.
``unsigned`` Object An object containing the properties that aren't
part of the signature's computation.
==================== ======== ============
Where the ``content`` key contains the content for the ``m.room.member`` event
specified in the `Client-Server API`_. Note that the ``membership`` property of
the content must be ``invite``.
Upon receiving this request, the invited homeserver will append its signature to
the event and respond to the request with the following JSON body::
[
200,
"event": {...}
]
Where ``event`` contains the event signed by both homeservers, using the same
JSON keys as the initial request on ``/invite/{roomId}/{eventId}``. Note that,
except for the ``signatures`` object (which now contains an additional signature),
all of the event's keys remain the same as in the event initially provided.
This response format is due to a typo in Synapse, the first implementation of
Matrix's APIs, and is preserved to maintain compatibility.
Now that the event has been signed by both the inviting homeserver and the
invited homeserver, it can be sent to all of the users in the room.
Third-party invites
-------------------
When an user wants to invite another user in a room but doesn't know the Matrix
ID to invite, they can do so using a third-party identifier (e.g. an e-mail or a
phone number).
This identifier and its bindings to Matrix IDs are verified by an identity server
implementing the `Identity Service API`_.
Cases where an association exists for a third-party identifier
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
If the third-party identifier is already bound to a Matrix ID, a lookup request
on the identity server will return it. The invite is then processed by the inviting
homeserver as a standard ``m.room.member`` invite event. This is the simplest case.
Cases where an association doesn't exist for a third-party identifier
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
If the third-party identifier isn't bound to any Matrix ID, the inviting
homeserver will request the identity server to store an invite for this identifier
and to deliver it to whoever binds it to its Matrix ID. It will also send a
``m.room.third_party_invite`` event in the room to specify a display name, a token
and public keys the identity server provided as a response to the invite storage
request.
When a third-party identifier with pending invites gets bound to a Matrix ID,
the identity server will send a ``POST`` request to the ID's homeserver as described
in the `Invitation Storage`_ section of the Identity Service API.
The following process applies for each invite sent by the identity server:
The invited homeserver will create a ``m.room.member`` invite event containing
a special ``third_party_invite`` section containing the token and a signed object,
both provided by the identity server.
If the invited homeserver is in the room the invite came from, it can auth the
event and send it.
However, if the invited homeserver isn't in the room the invite came from, it
will need to request the room's homeserver to auth the event::
PUT .../exchange_third_party_invite/{roomId}
Where ``roomId`` is the ID of the room the invite is for.
The required fields in the JSON body are:
==================== ======= ==================================================
Key Type Description
==================== ======= ==================================================
``type`` String The event type. Must be `m.room.member`.
``room_id`` String The ID of the room the event is for. Must be the
same as the ID specified in the path.
``sender`` String The Matrix ID of the user who sent the original
`m.room.third_party_invite`.
``state_key`` String The Matrix ID of the invited user.
``content`` Object The content of the event.
==================== ======= ==================================================
Where the ``content`` key contains the content for the ``m.room.member`` event
as described in the `Client-Server API`_. Its ``membership`` key must be
``invite`` and its content must include the ``third_party_invite`` object.
The inviting homeserver will then be able to authenticate the event. It will send
a fully authenticated event to the invited homeserver as described in the `Inviting
to a room`_ section above.
Once the invited homeserver responded with the event to which it appended its
signature, the inviting homeserver will respond with ``200 OK`` and an empty body
(``{}``) to the initial request on ``/exchange_third_party_invite/{roomId}`` and
send the now verified ``m.room.member`` invite event to the room's members.
Verifying the invite
++++++++++++++++++++
When a homeserver receives a ``m.room.member`` invite event for a room it's in
with a ``third_party_invite`` object, it must verify that the association between
the third-party identifier initially invited to the room and the Matrix ID that
claims to be bound to it has been verified without having to rely on a third-party
server.
To do so, it will fetch from the room's state events the ``m.room.third_party_invite``
event for which the state key matches with the value for the ``token`` key in the
``third_party_invite`` object from the ``m.room.member`` event's content to fetch the
public keys initially delivered by the identity server that stored the invite.
It will then use these keys to verify that the ``signed`` object (in the
``third_party_invite`` object from the ``m.room.member`` event's content) was
signed by the same identity server.
Since this ``signed`` object can only be delivered once in the ``POST`` request
emitted by the identity server upon binding between the third-party identifier
and the Matrix ID, and contains the invited user's Matrix ID and the token
delivered when the invite was stored, this verification will prove that the
``m.room.member`` invite event comes from the user owning the invited third-party
identifier.
Authentication
--------------
Request Authentication
~~~~~~~~~~~~~~~~~~~~~~
Every HTTP request made by a homeserver is authenticated using public key
digital signatures. The request method, target and body are signed by wrapping
them in a JSON object and signing it using the JSON signing algorithm. The
resulting signatures are added as an Authorization header with an auth scheme
of X-Matrix. Note that the target field should include the full path starting with
``/_matrix/...``, including the ``?`` and any query parameters if present, but
should not include the leading ``https:``, nor the destination server's
hostname.
Step 1 sign JSON:
.. code::
{
"method": "GET",
"uri": "/target",
"origin": "origin.hs.example.com",
"destintation": "destination.hs.example.com",
"content": { JSON content ... },
"signatures": {
"origin.hs.example.com": {
"ed25519:key1": "ABCDEF..."
}
}
}
Step 2 add Authorization header:
.. code::
GET /target HTTP/1.1
Authorization: X-Matrix origin=origin.example.com,key="ed25519:key1",sig="ABCDEF..."
Content-Type: application/json
{ JSON content ... }
Example python code:
.. code:: python
def authorization_headers(origin_name, origin_signing_key,
destination_name, request_method, request_target,
content_json=None):
request_json = {
"method": request_method,
"uri": request_target,
"origin": origin_name,
"destination": destination_name,
}
if content_json is not None:
request["content"] = content_json
signed_json = sign_json(request_json, origin_name, origin_signing_key)
authorization_headers = []
for key, sig in signed_json["signatures"][origin_name].items():
authorization_headers.append(bytes(
"X-Matrix origin=%s,key=\"%s\",sig=\"%s\"" % (
origin_name, key, sig,
)
))
return ("Authorization", authorization_headers)
Response Authentication
~~~~~~~~~~~~~~~~~~~~~~~
Responses are authenticated by the TLS server certificate. A homeserver should
not send a request until it has authenticated the connected server to avoid
leaking messages to eavesdroppers.
Client TLS Certificates
~~~~~~~~~~~~~~~~~~~~~~~
Requests are authenticated at the HTTP layer rather than at the TLS layer
because HTTP services like Matrix are often deployed behind load balancers that
handle the TLS and these load balancers make it difficult to check TLS client
certificates.
A homeserver may provide a TLS client certificate and the receiving homeserver
may check that the client certificate matches the certificate of the origin
homeserver.
Server-Server Authorization
---------------------------
.. TODO-doc
- PDU signing (see the Event signing section earlier)
- State conflict resolution (see below)
State Conflict Resolution
-------------------------
.. NOTE::
This section is a work in progress.
.. TODO-doc
- How do conflicts arise (diagrams?)
- How are they resolved (incl tie breaks)
- How does this work with deleting current state
- How do we reject invalid federation traffic?
[[TODO(paul): At this point we should probably have a long description of how
State management works, with descriptions of clobbering rules, power levels, etc
etc... But some of that detail is rather up-in-the-air, on the whiteboard, and
so on. This part needs refining. And writing in its own document as the details
relate to the server/system as a whole, not specifically to server-server
federation.]]
Presence
--------
The server API for presence is based entirely on exchange of the following
EDUs. There are no PDUs or Federation Queries involved.
Performing a presence update and poll subscription request::
EDU type: m.presence
Content keys:
push: (optional): list of push operations.
Each should be an object with the following keys:
user_id: string containing a User ID
presence: "offline"|"unavailable"|"online"|"free_for_chat"
status_msg: (optional) string of free-form text
last_active_ago: milliseconds since the last activity by the user
poll: (optional): list of strings giving User IDs
unpoll: (optional): list of strings giving User IDs
The presence of this combined message is two-fold: it informs the recipient
server of the current status of one or more users on the sending server (by the
``push`` key), and it maintains the list of users on the recipient server that
the sending server is interested in receiving updates for, by adding (by the
``poll`` key) or removing them (by the ``unpoll`` key). The ``poll`` and
``unpoll`` lists apply *changes* to the implied list of users; any existing IDs
that the server sent as ``poll`` operations in a previous message are not
removed until explicitly requested by a later ``unpoll``.
On receipt of a message containing a non-empty ``poll`` list, the receiving
server should immediately send the sending server a presence update EDU of its
own, containing in a ``push`` list the current state of every user that was in
the original EDU's ``poll`` list.
Sending a presence invite::
EDU type: m.presence_invite
Content keys:
observed_user: string giving the User ID of the user whose presence is
requested (i.e. the recipient of the invite)
observer_user: string giving the User ID of the user who is requesting to
observe the presence (i.e. the sender of the invite)
Accepting a presence invite::
EDU type: m.presence_accept
Content keys - as for m.presence_invite
Rejecting a presence invite::
EDU type: m.presence_deny
Content keys - as for m.presence_invite
.. TODO-doc
- Explain the timing-based round-trip reduction mechanism for presence
messages
- Explain the zero-byte presence inference logic
See also: docs/client-server/model/presence
Profiles
--------
The server API for profiles is based entirely on the following Federation
Queries. There are no additional EDU or PDU types involved, other than the
implicit ``m.presence`` and ``m.room.member`` events (see section below).
Querying profile information::
Query type: profile
Arguments:
user_id: the ID of the user whose profile to return
field: (optional) string giving a field name
Returns: JSON object containing the following keys:
displayname: string of free-form text
avatar_url: string containing an HTTP-scheme URL
If the query contains the optional ``field`` key, it should give the name of a
result field. If such is present, then the result should contain only a field
of that name, with no others present. If not, the result should contain as much
of the user's profile as the homeserver has available and can make public.
Directory
---------
The server API for directory queries is also based on Federation Queries.
Querying directory information::
Query type: directory
Arguments:
room_alias: the room alias to query
Returns: JSON object containing the following keys:
room_id: string giving the underlying room ID the alias maps to
servers: list of strings giving the join candidates
The list of join candidates is a list of server names that are likely to hold
the given room; these are servers that the requesting server may wish to use as
resident servers as part of the remote join handshake. This list may or may not
include the server answering the query.
Send-to-device messaging
------------------------
.. TODO: add modules to the federation spec and make this a module
The server API for send-to-device messaging is based on the following
EDU. There are no PDUs or Federation Queries involved.
Each send-to-device message should be sent to the destination server using
the following EDU::
EDU type: m.direct_to_device
Content keys:
sender: user ID of the sender
type: event type for the message
message_id: unique id for the message: used for idempotence
messages: The messages to send. A map from user ID, to a map from device ID
to message body. The device ID may also be *, meaning all known devices
for the user.
Signing Events
--------------
Signing events is complicated by the fact that servers can choose to redact
non-essential parts of an event.
Before signing the event, the ``unsigned`` and ``signature`` members are
removed, it is encoded as `Canonical JSON`_, and then hashed using SHA-256. The
resulting hash is then stored in the event JSON in a ``hash`` object under a
``sha256`` key.
.. code:: python
def hash_event(event_json_object):
# Keys under "unsigned" can be modified by other servers.
# They are useful for conveying information like the age of an
# event that will change in transit.
# Since they can be modifed we need to exclude them from the hash.
unsigned = event_json_object.pop("unsigned", None)
# Signatures will depend on the current value of the "hashes" key.
# We cannot add new hashes without invalidating existing signatures.
signatures = event_json_object.pop("signatures", None)
# The "hashes" key might contain multiple algorithms if we decide to
# migrate away from SHA-2. We don't want to include an existing hash
# output in our hash so we exclude the "hashes" dict from the hash.
hashes = event_json_object.pop("hashes", {})
# Encode the JSON using a canonical encoding so that we get the same
# bytes on every server for the same JSON object.
event_json_bytes = encode_canonical_json(event_json_bytes)
# Add the base64 encoded bytes of the hash to the "hashes" dict.
hashes["sha256"] = encode_base64(sha256(event_json_bytes).digest())
# Add the "hashes" dict back the event JSON under a "hashes" key.
event_json_object["hashes"] = hashes
if unsigned is not None:
event_json_object["unsigned"] = unsigned
return event_json_object
The event is then stripped of all non-essential keys both at the top level and
within the ``content`` object. Any top-level keys not in the following list
MUST be removed:
.. code::
auth_events
depth
event_id
hashes
membership
origin
origin_server_ts
prev_events
prev_state
room_id
sender
signatures
state_key
type
A new ``content`` object is constructed for the resulting event that contains
only the essential keys of the original ``content`` object. If the original
event lacked a ``content`` object at all, a new empty JSON object is created
for it.
The keys that are considered essential for the ``content`` object depend on the
the ``type`` of the event. These are:
.. code::
type is "m.room.aliases":
aliases
type is "m.room.create":
creator
type is "m.room.history_visibility":
history_visibility
type is "m.room.join_rules":
join_rule
type is "m.room.member":
membership
type is "m.room.power_levels":
ban
events
events_default
kick
redact
state_default
users
users_default
The resulting stripped object with the new ``content`` object and the original
``hashes`` key is then signed using the JSON signing algorithm outlined below:
.. code:: python
def sign_event(event_json_object, name, key):
# Make sure the event has a "hashes" key.
if "hashes" not in event_json_object:
event_json_object = hash_event(event_json_object)
# Strip all the keys that would be removed if the event was redacted.
# The hashes are not stripped and cover all the keys in the event.
# This means that we can tell if any of the non-essential keys are
# modified or removed.
stripped_json_object = strip_non_essential_keys(event_json_object)
# Sign the stripped JSON object. The signature only covers the
# essential keys and the hashes. This means that we can check the
# signature even if the event is redacted.
signed_json_object = sign_json(stripped_json_object)
# Copy the signatures from the stripped event to the original event.
event_json_object["signatures"] = signed_json_oject["signatures"]
return event_json_object
Servers can then transmit the entire event or the event with the non-essential
keys removed. If the entire event is present, receiving servers can then check
the event by computing the SHA-256 of the event, excluding the ``hash`` object.
If the keys have been redacted, then the ``hash`` object is included when
calculating the SHA-256 instead.
New hash functions can be introduced by adding additional keys to the ``hash``
object. Since the ``hash`` object cannot be redacted a server shouldn't allow
too many hashes to be listed, otherwise a server might embed illict data within
the ``hash`` object. For similar reasons a server shouldn't allow hash values
that are too long.
.. TODO
[[TODO(markjh): We might want to specify a maximum number of keys for the
``hash`` and we might want to specify the maximum output size of a hash]]
[[TODO(markjh) We might want to allow the server to omit the output of well
known hash functions like SHA-256 when none of the keys have been redacted]]
.. _`Invitation storage`: ../identity_service/unstable.html#invitation-storage
.. _`Identity Service API`: ../identity_service/unstable.html
.. _`Client-Server API`: ../client_server/unstable.html#m-room-member
.. _`Inviting to a room`: #inviting-to-a-room
.. _`Canonical JSON`: ../appendices.html#canonical-json
.. _`Unpadded Base64`: ../appendices.html#unpadded-base64