'\" t
.\"     Title: zmq_tcp
.\"    Author: [see the "AUTHORS" section]
.\" Generator: DocBook XSL Stylesheets v1.75.2 <http://docbook.sf.net/>
.\"      Date: 11/22/2011
.\"    Manual: 0MQ Manual
.\"    Source: 0MQ 2.1.10
.\"  Language: English
.\"
.TH "ZMQ_TCP" "7" "11/22/2011" "0MQ 2\&.1\&.10" "0MQ Manual"
.\" -----------------------------------------------------------------
.\" * Define some portability stuff
.\" -----------------------------------------------------------------
.\" ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
.\" http://bugs.debian.org/507673
.\" http://lists.gnu.org/archive/html/groff/2009-02/msg00013.html
.\" ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
.ie \n(.g .ds Aq \(aq
.el       .ds Aq '
.\" -----------------------------------------------------------------
.\" * set default formatting
.\" -----------------------------------------------------------------
.\" disable hyphenation
.nh
.\" disable justification (adjust text to left margin only)
.ad l
.\" -----------------------------------------------------------------
.\" * MAIN CONTENT STARTS HERE *
.\" -----------------------------------------------------------------
.SH "NAME"
zmq_tcp \- 0MQ unicast transport using TCP
.SH "SYNOPSIS"
.sp
TCP is an ubiquitous, reliable, unicast transport\&. When connecting distributed applications over a network with 0MQ, using the TCP transport will likely be your first choice\&.
.SH "ADDRESSING"
.sp
A 0MQ address string consists of two parts as follows: \fItransport\fR://\fIendpoint\fR\&. The \fItransport\fR part specifies the underlying transport protocol to use, and for the TCP transport shall be set to tcp\&. The meaning of the \fIendpoint\fR part for the TCP transport is defined below\&.
.SS "Assigning a local address to a socket"
.sp
When assigning a local address to a socket using \fIzmq_bind()\fR with the \fItcp\fR transport, the \fIendpoint\fR shall be interpreted as an \fIinterface\fR followed by a colon and the TCP port number to use\&.
.sp
An \fIinterface\fR may be specified by either of the following:
.sp
.RS 4
.ie n \{\
\h'-04'\(bu\h'+03'\c
.\}
.el \{\
.sp -1
.IP \(bu 2.3
.\}
The wild\-card
*, meaning all available interfaces\&.
.RE
.sp
.RS 4
.ie n \{\
\h'-04'\(bu\h'+03'\c
.\}
.el \{\
.sp -1
.IP \(bu 2.3
.\}
The primary IPv4 address assigned to the interface, in its numeric representation\&.
.RE
.sp
.RS 4
.ie n \{\
\h'-04'\(bu\h'+03'\c
.\}
.el \{\
.sp -1
.IP \(bu 2.3
.\}
The interface name as defined by the operating system\&.
.RE
.if n \{\
.sp
.\}
.RS 4
.it 1 an-trap
.nr an-no-space-flag 1
.nr an-break-flag 1
.br
.ps +1
\fBNote\fR
.ps -1
.br
.sp
Interface names are not standardised in any way and should be assumed to be arbitrary and platform dependent\&. On Win32 platforms no short interface names exist, thus only the primary IPv4 address may be used to specify an \fIinterface\fR\&.
.sp .5v
.RE
.SS "Connecting a socket"
.sp
When connecting a socket to a peer address using \fIzmq_connect()\fR with the \fItcp\fR transport, the \fIendpoint\fR shall be interpreted as a \fIpeer address\fR followed by a colon and the TCP port number to use\&.
.sp
A \fIpeer address\fR may be specified by either of the following:
.sp
.RS 4
.ie n \{\
\h'-04'\(bu\h'+03'\c
.\}
.el \{\
.sp -1
.IP \(bu 2.3
.\}
The DNS name of the peer\&.
.RE
.sp
.RS 4
.ie n \{\
\h'-04'\(bu\h'+03'\c
.\}
.el \{\
.sp -1
.IP \(bu 2.3
.\}
The IPv4 address of the peer, in its numeric representation\&.
.RE
.SH "WIRE FORMAT"
.sp
0MQ messages are transmitted over TCP in frames consisting of an encoded \fIpayload length\fR, followed by a \fIflags\fR field and the message body\&. The \fIpayload length\fR is defined as the combined length in octets of the message body and the \fIflags\fR field\&.
.sp
For frames with a \fIpayload length\fR not exceeding 254 octets, the \fIpayload length\fR shall be encoded as a single octet\&. The minimum valid \fIpayload length\fR of a frame is 1 octet, thus a \fIpayload length\fR of 0 octets is invalid and such frames SHOULD be ignored\&.
.sp
For frames with a \fIpayload length\fR exceeding 254 octets, the \fIpayload length\fR shall be encoded as a single octet with the value 255 followed by the \fIpayload length\fR represented as a 64\-bit unsigned integer in network byte order\&.
.sp
The \fIflags\fR field consists of a single octet containing various control flags:
.sp
Bit 0 (MORE): \fIMore message parts to follow\fR\&. A value of 0 indicates that there are no more message parts to follow; or that the message being sent is not a multi\-part message\&. A value of 1 indicates that the message being sent is a multi\-part message and more message parts are to follow\&.
.sp
Bits 1\-7: \fIReserved\fR\&. Bits 1\-7 are reserved for future expansion and MUST be set to zero\&.
.sp
The following ABNF grammar represents a single \fIframe\fR:
.sp
.if n \{\
.RS 4
.\}
.nf
    frame           = (length flags data)
    length          = OCTET / (escape 8OCTET)
    flags           = OCTET
    escape          = %xFF
    data            = *OCTET
.fi
.if n \{\
.RE
.\}
.sp
The following diagram illustrates the layout of a frame with a \fIpayload length\fR not exceeding 254 octets:
.sp
.if n \{\
.RS 4
.\}
.nf
0                   1                   2                   3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+
| Payload length|     Flags     |       Message body        \&.\&.\&. |
+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+
| Message body \&.\&.\&.
+\-+\-+\-+\-+\-+\-+\- \&.\&.\&.
.fi
.if n \{\
.RE
.\}
.sp
The following diagram illustrates the layout of a frame with a \fIpayload length\fR exceeding 254 octets:
.sp
.if n \{\
.RS 4
.\}
.nf
0                   1                   2                   3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+
|     0xff      |               Payload length              \&.\&.\&. |
+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+
|                       Payload length                      \&.\&.\&. |
+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+
| Payload length|     Flags     |        Message body       \&.\&.\&. |
+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+\-+
|  Message body \&.\&.\&.
+\-+\-+\-+\-+\-+\-+\-+ \&.\&.\&.
.fi
.if n \{\
.RE
.\}
.SH "EXAMPLES"
.PP
\fBAssigning a local address to a socket\fR. 
.sp
.if n \{\
.RS 4
.\}
.nf
/* TCP port 5555 on all available interfaces */
rc = zmq_bind(socket, "tcp://*:5555");
assert (rc == 0);
/* TCP port 5555 on the local loop\-back interface on all platforms */
rc = zmq_bind(socket, "tcp://127\&.0\&.0\&.1:5555");
assert (rc == 0);
/* TCP port 5555 on the first Ethernet network interface on Linux */
rc = zmq_bind(socket, "tcp://eth0:5555");
assert (rc == 0);
.fi
.if n \{\
.RE
.\}
.PP
\fBConnecting a socket\fR. 
.sp
.if n \{\
.RS 4
.\}
.nf
/* Connecting using an IP address */
rc = zmq_connect(socket, "tcp://192\&.168\&.1\&.1:5555");
assert (rc == 0);
/* Connecting using a DNS name */
rc = zmq_connect(socket, "tcp://server1:5555");
assert (rc == 0);
.fi
.if n \{\
.RE
.\}
.sp
.SH "SEE ALSO"
.sp
\fBzmq_bind\fR(3) \fBzmq_connect\fR(3) \fBzmq_pgm\fR(7) \fBzmq_ipc\fR(7) \fBzmq_inproc\fR(7) \fBzmq\fR(7)
.SH "AUTHORS"
.sp
This 0MQ manual page was written by Martin Sustrik <\m[blue]\fBsustrik@250bpm\&.com\fR\m[]\&\s-2\u[1]\d\s+2> and Martin Lucina <\m[blue]\fBmato@kotelna\&.sk\fR\m[]\&\s-2\u[2]\d\s+2>\&.
.SH "NOTES"
.IP " 1." 4
sustrik@250bpm.com
.RS 4
\%mailto:sustrik@250bpm.com
.RE
.IP " 2." 4
mato@kotelna.sk
.RS 4
\%mailto:mato@kotelna.sk
.RE