Manpages - zmq_socket.3

The client-server pattern is used to allow a single ZMQ_SERVER server talk to one or more ZMQ_CLIENT clients. The client always starts the conversation, after which either peer can send messages asynchronously, to the other.

The client-server pattern is formally defined by http://rfc.zeromq.org/spec:41.

Note

Server-client is still in draft phase.

ZMQ_CLIENT

A ZMQ_CLIENT socket talks to a ZMQ_SERVER socket. Either peer can connect, though the usual and recommended model is to bind the ZMQ_SERVER and connect the ZMQ_CLIENT.

If the ZMQ_CLIENT socket has established a connection, *zmq_send*(3) will accept messages, queue them, and send them as rapidly as the network allows. The outgoing buffer limit is defined by the high water mark for the socket. If the outgoing buffer is full, or, for connection-oriented transports, if the ZMQ_IMMEDIATE option is set and there is no connected peer, *zmq_send*(3) will block. The ZMQ_CLIENT socket will not drop messages.

When a ZMQ_CLIENT socket is connected to multiple ZMQ_SERVER sockets, outgoing messages are distributed between connected peers on a round-robin basis. Likewise, the ZMQ_CLIENT socket receives messages fairly from each connected peer. This usage is sensible only for stateless protocols.

ZMQ_CLIENT sockets are threadsafe and can be used from multiple threads at the same time. Note that replies from a ZMQ_SERVER socket will go to the first client thread that calls *zmq_msg_recv*(3). If you need to get replies back to the originating thread, use one ZMQ_CLIENT socket per thread.

#+begin_quote

Note

ZMQ_CLIENT sockets are threadsafe. They do not accept the ZMQ_SNDMORE option on sends not ZMQ_RCVMORE on receives. This limits them to single part data. The intention is to extend the API to allow scatter/gather of multi-part data.

Table 1. Summary of ZMQ_CLIENT characteristics

#+end_quote

ZMQ_SERVER

A ZMQ_SERVER socket talks to a set of ZMQ_CLIENT sockets. A ZMQ_SERVER socket can only reply to an incoming message: the ZMQ_CLIENT peer must always initiate a conversation.

Each received message has a routing_id that is a 32-bit unsigned integer. The application can fetch this with *zmq_msg_routing_id*(3). To send a message to a given ZMQ_CLIENT peer the application must set the peer’s routing_id on the message, using *zmq_msg_set_routing_id*(3).

If the routing_id is not specified, or does not refer to a connected client peer, the send call will fail with EHOSTUNREACH. If the outgoing buffer for the client peer is full, the send call shall block, unless ZMQ_DONTWAIT is used in the send, in which case it shall fail with EAGAIN. The ZMQ_SERVER socket shall not drop messages in any case.

#+begin_quote

Note

ZMQ_SERVER sockets are threadsafe. They do not accept the ZMQ_SNDMORE option on sends not ZMQ_RCVMORE on receives. This limits them to single part data. The intention is to extend the API to allow scatter/gather of multi-part data.

Table 2. Summary of ZMQ_SERVER characteristics

#+end_quote

The radio-dish pattern is used for one-to-many distribution of data from a single publisher to multiple subscribers in a fan out fashion.

Radio-dish is using groups (vs Pub-sub topics), Dish sockets can join a group and each message sent by Radio sockets belong to a group.

Groups are null terminated strings limited to 16 chars length (including null). The intention is to increase the length to 40 chars (including null). The encoding of groups shall be UTF8.

Groups are matched using exact matching (vs prefix matching of PubSub).

Note

Radio-dish is still in draft phase.

ZMQ_RADIO

A socket of type ZMQ_RADIO is used by a publisher to distribute data. Each message belong to a group, a group is specified with *zmq_msg_set_group*(3). Messages are distributed to all members of a group. The *zmq_recv*(3) function is not implemented for this socket type.

When a ZMQ_RADIO socket enters the mute state due to having reached the high water mark for a subscriber, then any messages that would be sent to the subscriber in question shall instead be dropped until the mute state ends. The zmq_send() function shall never block for this socket type.

#+begin_quote

Note

ZMQ_RADIO sockets are threadsafe. They do not accept the ZMQ_SNDMORE option on sends. This limits them to single part data.

Table 3. Summary of ZMQ_RADIO characteristics

#+end_quote

ZMQ_DISH

A socket of type ZMQ_DISH is used by a subscriber to subscribe to groups distributed by a radio. Initially a ZMQ_DISH socket is not subscribed to any groups, use *zmq_join*(3) to join a group. To get the group the message belong to call *zmq_msg_group*(3). The zmq_send() function is not implemented for this socket type.

#+begin_quote

Note

ZMQ_DISH sockets are threadsafe. They do not accept ZMQ_RCVMORE on receives. This limits them to single part data.

Table 4. Summary of ZMQ_DISH characteristics

#+end_quote

The publish-subscribe pattern is used for one-to-many distribution of data from a single publisher to multiple subscribers in a fan out fashion.

The publish-subscribe pattern is formally defined by http://rfc.zeromq.org/spec:29.

ZMQ_PUB

A socket of type ZMQ_PUB is used by a publisher to distribute data. Messages sent are distributed in a fan out fashion to all connected peers. The *zmq_recv*(3) function is not implemented for this socket type.

When a ZMQ_PUB socket enters the mute state due to having reached the high water mark for a subscriber, then any messages that would be sent to the subscriber in question shall instead be dropped until the mute state ends. The zmq_send() function shall never block for this socket type.

Table 5. Summary of ZMQ_PUB characteristics

Compatible peer sockets	ZMQ_SUB, ZMQ_XSUB
Direction	Unidirectional
Send/receive pattern	Send only
Incoming routing strategy	N/A
Outgoing routing strategy	Fan out
Action in mute state	Drop

ZMQ_SUB

A socket of type ZMQ_SUB is used by a subscriber to subscribe to data distributed by a publisher. Initially a ZMQ_SUB socket is not subscribed to any messages, use the ZMQ_SUBSCRIBE option of *zmq_setsockopt*(3) to specify which messages to subscribe to. The zmq_send() function is not implemented for this socket type.

Table 6. Summary of ZMQ_SUB characteristics

Compatible peer sockets	ZMQ_PUB, ZMQ_XPUB
Direction	Unidirectional
Send/receive pattern	Receive only
Incoming routing strategy	Fair-queued
Outgoing routing strategy	N/A

ZMQ_XPUB

Same as ZMQ_PUB except that you can receive subscriptions from the peers in form of incoming messages. Subscription message is a byte 1 (for subscriptions) or byte 0 (for unsubscriptions) followed by the subscription body. Messages without a sub/unsub prefix are also received, but have no effect on subscription status.

Table 7. Summary of ZMQ_XPUB characteristics

Compatible peer sockets	ZMQ_SUB, ZMQ_XSUB
Direction	Unidirectional
Send/receive pattern	Send messages, receive subscriptions
Incoming routing strategy	N/A
Outgoing routing strategy	Fan out
Action in mute state	Drop

ZMQ_XSUB

Same as ZMQ_SUB except that you subscribe by sending subscription messages to the socket. Subscription message is a byte 1 (for subscriptions) or byte 0 (for unsubscriptions) followed by the subscription body. Messages without a sub/unsub prefix may also be sent, but have no effect on subscription status.

Table 8. Summary of ZMQ_XSUB characteristics

Compatible peer sockets	ZMQ_PUB, ZMQ_XPUB
Direction	Unidirectional
Send/receive pattern	Receive messages, send subscriptions
Incoming routing strategy	Fair-queued
Outgoing routing strategy	N/A
Action in mute state	Drop

The pipeline pattern is used for distributing data to nodes arranged in a pipeline. Data always flows down the pipeline, and each stage of the pipeline is connected to at least one node. When a pipeline stage is connected to multiple nodes data is round-robined among all connected nodes.

The pipeline pattern is formally defined by http://rfc.zeromq.org/spec:30.

ZMQ_PUSH

A socket of type ZMQ_PUSH is used by a pipeline node to send messages to downstream pipeline nodes. Messages are round-robined to all connected downstream nodes. The zmq_recv() function is not implemented for this socket type.

When a ZMQ_PUSH socket enters the mute state due to having reached the high water mark for all downstream nodes, or, for connection-oriented transports, if the ZMQ_IMMEDIATE option is set and there are no downstream nodes at all, then any *zmq_send*(3) operations on the socket shall block until the mute state ends or at least one downstream node becomes available for sending; messages are not discarded.

Table 9. Summary of ZMQ_PUSH characteristics

Compatible peer sockets	ZMQ_PULL
Direction	Unidirectional
Send/receive pattern	Send only
Incoming routing strategy	N/A
Outgoing routing strategy	Round-robin
Action in mute state	Block

ZMQ_PULL

A socket of type ZMQ_PULL is used by a pipeline node to receive messages from upstream pipeline nodes. Messages are fair-queued from among all connected upstream nodes. The zmq_send() function is not implemented for this socket type.

Table 10. Summary of ZMQ_PULL characteristics

Compatible peer sockets	ZMQ_PUSH
Direction	Unidirectional
Send/receive pattern	Receive only
Incoming routing strategy	Fair-queued
Outgoing routing strategy	N/A
Action in mute state	Block

Scatter-gather pattern

#+begin_quote

      The scatter-gather pattern is the thread-safe version of the pipeline pattern.
      The scatter-gather pattern is used for distributing data to _nodes_ arranged in
      a pipeline. Data always flows down the pipeline, and each stage of the pipeline
      is connected to at least one _node_. When a pipeline stage is connected to
      multiple _nodes_ data is round-robined among all connected _nodes_.

      ZMQ_SCATTER
      ^^^^^^^^
      A socket of type ZMQ_SCATTER is used by a scatter-gather _node_ to send messages
      to downstream scatter-gather _nodes_. Messages are round-robined to all connected
      downstream _nodes_. The _zmq_recv()_ function is not implemented for this
      socket type.

      When a ZMQ_SCATTER socket enters the mute state due to having reached the
      high water mark for all downstream _nodes_, or, for connection-oriented transports,
      if the ZMQ_IMMEDIATE option is set and there are no downstream _nodes_ at all,
      then any linkzmq:zmq_send[3] operations on the socket shall block until the mute
      state ends or at least one downstream _node_ becomes available for sending;
      messages are not discarded.

      NOTE: ZMQ_SCATTER sockets are threadsafe. They do not accept ZMQ_RCVMORE on receives.
      This limits them to single part data.

      [horizontal]
      .Summary of ZMQ_SCATTER characteristics
      Compatible peer sockets:: ZMQ_SCATTER
      Direction:: Unidirectional
      Send/receive pattern:: Send only
      Incoming routing strategy:: N/A
      Outgoing routing strategy:: Round-robin
      Action in mute state:: Block


      ZMQ_GATHER
      ^^^^^^^^
      A socket of type ZMQ_GATHER is used by a scatter-gather _node_ to receive messages
      from upstream scatter-gather _nodes_. Messages are fair-queued from among all
      connected upstream _nodes_. The _zmq_send()_ function is not implemented for
      this socket type.

      NOTE: ZMQ_GATHER sockets are threadsafe. They do not accept ZMQ_RCVMORE on receives.
      This limits them to single part data.

      [horizontal]
      .Summary of ZMQ_GATHER characteristics
      Compatible peer sockets:: ZMQ_GATHER
      Direction:: Unidirectional
      Send/receive pattern:: Receive only
      Incoming routing strategy:: Fair-queued
      Outgoing routing strategy:: N/A
      Action in mute state:: Block


      Exclusive pair pattern

The exclusive pair pattern is used to connect a peer to precisely one other peer. This pattern is used for inter-thread communication across the inproc transport.

The exclusive pair pattern is formally defined by http://rfc.zeromq.org/spec:31. #+end_quote

ZMQ_PAIR

A socket of type ZMQ_PAIR can only be connected to a single peer at any one time. No message routing or filtering is performed on messages sent over a ZMQ_PAIR socket.

When a ZMQ_PAIR socket enters the mute state due to having reached the high water mark for the connected peer, or, for connection-oriented transports, if the ZMQ_IMMEDIATE option is set and there is no connected peer, then any *zmq_send*(3) operations on the socket shall block until the peer becomes available for sending; messages are not discarded.

While ZMQ_PAIR sockets can be used over transports other than *zmq_inproc*(7), their inability to auto-reconnect coupled with the fact new incoming connections will be terminated while any previous connections (including ones in a closing state) exist makes them unsuitable for TCP in most cases.

#+begin_quote

Note

ZMQ_PAIR sockets are designed for inter-thread communication across the *zmq_inproc*(7) transport and do not implement functionality such as auto-reconnection.

Table 11. Summary of ZMQ_PAIR characteristics

#+end_quote

The peer-to-peer pattern is used to connect a peer to multiple peers. Peer can both connect and bind and mix both of them with the same socket. The peer-to-peer pattern is useful to build peer-to-peer networks (e.g zyre, bitcoin, torrent) where a peer can both accept connections from other peers or connect to them.

Note

Peer-to-peer is still in draft phase.

ZMQ_PEER

A ZMQ_PEER socket talks to a set of ZMQ_PEER sockets.

To connect and fetch the routing_id of the peer use *zmq_connect_peer*(3).

Each received message has a routing_id that is a 32-bit unsigned integer. The application can fetch this with *zmq_msg_routing_id*(3).

To send a message to a given ZMQ_PEER peer the application must set the peer’s routing_id on the message, using *zmq_msg_set_routing_id*(3).

If the routing_id is not specified, or does not refer to a connected client peer, the send call will fail with EHOSTUNREACH. If the outgoing buffer for the peer is full, the send call shall block, unless ZMQ_DONTWAIT is used in the send, in which case it shall fail with EAGAIN. The ZMQ_PEER socket shall not drop messages in any case.

#+begin_quote

Note

ZMQ_PEER sockets are threadsafe. They do not accept the ZMQ_SNDMORE option on sends not ZMQ_RCVMORE on receives. This limits them to single part data.

Table 12. Summary of ZMQ_PEER characteristics

Channel pattern

      The channel pattern is the thread-safe version of the exclusive pair pattern.
      The channel pattern is used to connect a peer to precisely one other
      peer. This pattern is used for inter-thread communication across the inproc
      transport.

      NOTE: Channel is still in draft phase.

      ZMQ_CHANNEL
      ^^^^^^^^
      A socket of type ZMQ_CHANNEL can only be connected to a single peer at any one
      time.  No message routing or filtering is performed on messages sent over a
      ZMQ_CHANNEL socket.

      When a ZMQ_CHANNEL socket enters the mute state due to having reached the
      high water mark for the connected peer, or, for connection-oriented transports,
      if the ZMQ_IMMEDIATE option is set and there is no connected peer, then
      any linkzmq:zmq_send[3] operations on the socket shall block until the peer
      becomes available for sending; messages are not discarded.

      While ZMQ_CHANNEL sockets can be used over transports other than linkzmq:zmq_inproc[7],
      their inability to auto-reconnect coupled with the fact new incoming connections will
      be terminated while any previous connections (including ones in a closing state)
      exist makes them unsuitable for TCP in most cases.

      NOTE: ZMQ_CHANNEL sockets are designed for inter-thread communication across
      the linkzmq:zmq_inproc[7] transport and do not implement functionality such
      as auto-reconnection.

      NOTE: ZMQ_CHANNEL sockets are threadsafe. They do not accept ZMQ_RCVMORE on receives.
      This limits them to single part data.

      [horizontal]
      .Summary of ZMQ_CHANNEL characteristics
      Compatible peer sockets:: ZMQ_CHANNEL
      Direction:: Bidirectional
      Send/receive pattern:: Unrestricted
      Incoming routing strategy:: N/A
      Outgoing routing strategy:: N/A
      Action in mute state:: Block

      Native Pattern

The native pattern is used for communicating with TCP peers and allows asynchronous requests and replies in either direction. #+end_quote

ZMQ_STREAM

A socket of type ZMQ_STREAM is used to send and receive TCP data from a non-0MQ peer, when using the tcp:// transport. A ZMQ_STREAM socket can act as client and/or server, sending and/or receiving TCP data asynchronously.

When receiving TCP data, a ZMQ_STREAM socket shall prepend a message part containing the routing id of the originating peer to the message before passing it to the application. Messages received are fair-queued from among all connected peers.

When sending TCP data, a ZMQ_STREAM socket shall remove the first part of the message and use it to determine the routing id of the peer the message shall be routed to, and unroutable messages shall cause an EHOSTUNREACH or EAGAIN error.

To open a connection to a server, use the zmq_connect call, and then fetch the socket routing id using the zmq_getsockopt call with the ZMQ_ROUTING_ID option.

To close a specific connection, send the routing id frame followed by a zero-length message (see EXAMPLE section).

When a connection is made, a zero-length message will be received by the application. Similarly, when the peer disconnects (or the connection is lost), a zero-length message will be received by the application.

You must send one routing id frame followed by one data frame. The ZMQ_SNDMORE flag is required for routing id frames but is ignored on data frames.

Table 13. Summary of ZMQ_STREAM characteristics

Compatible peer sockets	none.
Direction	Bidirectional
Send/receive pattern	Unrestricted
Outgoing routing strategy	See text
Incoming routing strategy	Fair-queued
Action in mute state	EAGAIN

The request-reply pattern is used for sending requests from a ZMQ_REQ client to one or more ZMQ_REP services, and receiving subsequent replies to each request sent.

The request-reply pattern is formally defined by http://rfc.zeromq.org/spec:28.

ZMQ_REQ

A socket of type ZMQ_REQ is used by a client to send requests to and receive replies from a service. This socket type allows only an alternating sequence of zmq_send(request) and subsequent zmq_recv(reply) calls. Each request sent is round-robined among all services, and each reply received is matched with the last issued request.

For connection-oriented transports, If the ZMQ_IMMEDIATE option is set and there is no service available, then any send operation on the socket shall block until at least one service becomes available. The REQ socket shall not discard messages.

Table 14. Summary of ZMQ_REQ characteristics

Compatible peer sockets	ZMQ_REP, ZMQ_ROUTER
Direction	Bidirectional
Send/receive pattern	Send, Receive, Send, Receive, …
Outgoing routing strategy	Round-robin
Incoming routing strategy	Last peer
Action in mute state	Block

ZMQ_REP

A socket of type ZMQ_REP is used by a service to receive requests from and send replies to a client. This socket type allows only an alternating sequence of zmq_recv(request) and subsequent zmq_send(reply) calls. Each request received is fair-queued from among all clients, and each reply sent is routed to the client that issued the last request. If the original requester does not exist any more the reply is silently discarded.

Table 15. Summary of ZMQ_REP characteristics

Compatible peer sockets	ZMQ_REQ, ZMQ_DEALER
Direction	Bidirectional
Send/receive pattern	Receive, Send, Receive, Send, …
Incoming routing strategy	Fair-queued
Outgoing routing strategy	Last peer

ZMQ_DEALER

A socket of type ZMQ_DEALER is an advanced pattern used for extending request/reply sockets. Each message sent is round-robined among all connected peers, and each message received is fair-queued from all connected peers.

When a ZMQ_DEALER socket enters the mute state due to having reached the high water mark for all peers, or, for connection-oriented transports, if the ZMQ_IMMEDIATE option is set and there are no peers at all, then any *zmq_send*(3) operations on the socket shall block until the mute state ends or at least one peer becomes available for sending; messages are not discarded.

When a ZMQ_DEALER socket is connected to a ZMQ_REP socket each message sent must consist of an empty message part, the delimiter, followed by one or more body parts.

Table 16. Summary of ZMQ_DEALER characteristics

Compatible peer sockets	ZMQ_ROUTER, ZMQ_REP, ZMQ_DEALER
Direction	Bidirectional
Send/receive pattern	Unrestricted
Outgoing routing strategy	Round-robin
Incoming routing strategy	Fair-queued
Action in mute state	Block

ZMQ_ROUTER

A socket of type ZMQ_ROUTER is an advanced socket type used for extending request/reply sockets. When receiving messages a ZMQ_ROUTER socket shall prepend a message part containing the routing id of the originating peer to the message before passing it to the application. Messages received are fair-queued from among all connected peers. When sending messages a ZMQ_ROUTER socket shall remove the first part of the message and use it to determine the _routing id _ of the peer the message shall be routed to. If the peer does not exist anymore, or has never existed, the message shall be silently discarded. However, if ZMQ_ROUTER_MANDATORY socket option is set to 1, the socket shall fail with EHOSTUNREACH in both cases.

When a ZMQ_ROUTER socket enters the mute state due to having reached the high water mark for all peers, then any messages sent to the socket shall be dropped until the mute state ends. Likewise, any messages routed to a peer for which the individual high water mark has been reached shall also be dropped. If, ZMQ_ROUTER_MANDATORY is set to 1, the socket shall block or return EAGAIN in both cases.

When a ZMQ_ROUTER socket has ZMQ_ROUTER_MANDATORY flag set to 1, the socket shall generate ZMQ_POLLIN events upon reception of messages from one or more peers. Likewise, the socket shall generate ZMQ_POLLOUT events when at least one message can be sent to one or more peers.

When a ZMQ_REQ socket is connected to a ZMQ_ROUTER socket, in addition to the routing id of the originating peer each message received shall contain an empty delimiter message part. Hence, the entire structure of each received message as seen by the application becomes: one or more routing id parts, delimiter part, one or more body parts. When sending replies to a ZMQ_REQ socket the application must include the delimiter part.

Table 17. Summary of ZMQ_ROUTER characteristics

Compatible peer sockets	ZMQ_DEALER, ZMQ_REQ, ZMQ_ROUTER
Direction	Bidirectional
Send/receive pattern	Unrestricted
Outgoing routing strategy	See text
Incoming routing strategy	Fair-queued
Action in mute state	Drop (see text)