SYNOPSIS

#include <zmq.h>

cc [flags] files -lzmq [libraries]

DESCRIPTION

The ØMQ lightweight messaging kernel is a library which extends the standard socket interfaces with features traditionally provided by specialised messaging middleware products. ØMQ sockets provide an abstraction of asynchronous message queues, multiple messaging patterns, message filtering (subscriptions), seamless access to multiple transport protocols and more.

This documentation presents an overview of ØMQ concepts, describes how ØMQ abstracts standard sockets and provides a reference manual for the functions provided by the ØMQ library.

Context

Before using any ØMQ library functions you must create a ØMQ context. When you exit your application you must destroy the context. These functions let you work with contexts:

Create a new ØMQ context

zmq_ctx_new(3)

Work with context properties

zmq_ctx_set(3) zmq_ctx_get(3)

Destroy a ØMQ context

zmq_ctx_destroy(3)

Monitor a ØMQ context

zmq_ctx_set_monitor(3)

These deprecated functions let you create and destroy contexts:

Initialise ØMQ context

zmq_init(3)

Terminate ØMQ context

zmq_term(3)

Thread safety

A ØMQ context is thread safe and may be shared among as many application threads as necessary, without any additional locking required on the part of the caller.

Individual ØMQ sockets are not thread safe except in the case where full memory barriers are issued when migrating a socket from one thread to another. In practice this means applications can create a socket in one thread with zmq_socket() and then pass it to a newly created thread as part of thread initialization, for example via a structure passed as an argument to pthread_create().

Multiple contexts

Multiple contexts may coexist within a single application. Thus, an application can use ØMQ directly and at the same time make use of any number of additional libraries or components which themselves make use of ØMQ as long as the above guidelines regarding thread safety are adhered to.

Messages

A ØMQ message is a discrete unit of data passed between applications or components of the same application. ØMQ messages have no internal structure and from the point of view of ØMQ itself they are considered to be opaque binary data.

The following functions are provided to work with messages:

Initialise a message

zmq_msg_init(3) zmq_msg_init_size(3) zmq_msg_init_data(3)

Sending and receiving a message

zmq_msg_send(3) zmq_msg_recv(3)

Release a message

zmq_msg_close(3)

Access message content

zmq_msg_data(3) zmq_msg_size(3) zmq_msg_more(3)

Work with message properties

zmq_msg_get(3) zmq_msg_set(3)

Message manipulation

zmq_msg_copy(3) zmq_msg_move(3)

Sockets

ØMQ sockets present an abstraction of a asynchronous message queue, with the exact queueing semantics depending on the socket type in use. See zmq_socket(3) for the socket types provided.

The following functions are provided to work with sockets:

Creating a socket

zmq_socket(3)

Closing a socket

zmq_close(3)

Manipulating socket options

zmq_getsockopt(3) zmq_setsockopt(3)

Establishing a message flow

zmq_bind(3) zmq_connect(3)

Sending and receiving messages

zmq_msg_send(3) zmq_msg_recv(3) zmq_send(3) zmq_recv(3)

Input/output multiplexing

ØMQ provides a mechanism for applications to multiplex input/output events over a set containing both ØMQ sockets and standard sockets. This mechanism mirrors the standard poll() system call, and is described in detail in zmq_poll(3).

Transports

A ØMQ socket can use multiple different underlying transport mechanisms. Each transport mechanism is suited to a particular purpose and has its own advantages and drawbacks.

The following transport mechanisms are provided:

Unicast transport using TCP

zmq_tcp(7)

Reliable multicast transport using PGM

zmq_pgm(7)

Local inter-process communication transport

zmq_ipc(7)

Local in-process (inter-thread) communication transport

zmq_inproc(7)

Proxies

ØMQ provides proxies to create fanout and fan-in topologies. A proxy connects a frontend socket to a backend socket and switches all messages between the two sockets, opaquely. A proxy may optionally capture all traffic to a third socket. To start a proxy in an application thread, use zmq_proxy(3).

ERROR HANDLING

The ØMQ library functions handle errors using the standard conventions found on POSIX systems. Generally, this means that upon failure a ØMQ library function shall return either a NULL value (if returning a pointer) or a negative value (if returning an integer), and the actual error code shall be stored in the errno variable.

On non-POSIX systems some users may experience issues with retrieving the correct value of the errno variable. The zmq_errno() function is provided to assist in these cases; for details refer to zmq_errno(3).

The zmq_strerror() function is provided to translate ØMQ-specific error codes into error message strings; for details refer to zmq_strerror(3).

MISCELLANEOUS

The following miscellaneous functions are provided:

Report ØMQ library version

zmq_version(3)

LANGUAGE BINDINGS

The ØMQ library provides interfaces suitable for calling from programs in any language; this documentation documents those interfaces as they would be used by C programmers. The intent is that programmers using ØMQ from other languages shall refer to this documentation alongside any documentation provided by the vendor of their language binding.

Language bindings (C++, Python, PHP, Ruby, Java and more) are provided by members of the ØMQ community and pointers can be found on the ØMQ website.

AUTHORS

This ØMQ manual page was written by Martin Sustrik <sustrik@250bpm.com>, Martin Lucina <martin@lucina.net>, and Pieter Hintjens <ph@imatix.com>.

RESOURCES

Main web site: http://www.zeromq.org/

Report bugs to the ØMQ development mailing list: <zeromq-dev@lists.zeromq.org>

COPYING

Free use of this software is granted under the terms of the GNU Lesser General Public License (LGPL). For details see the files COPYING and COPYING.LESSER included with the ØMQ distribution.