MQ_OVERVIEW(7) Linux Programmer's Manual MQ_OVERVIEW(7)NAMEmq_overview - Overview of POSIX message queues
DESCRIPTION
POSIX message queues allow processes to exchange data in the form of
messages. This API is distinct from that provided by System V message
queues (msgget(2), msgsnd(2), msgrcv(2), etc.), but provides similar
functionality.
Message queues are created and opened using mq_open(3); this function
returns a message queue descriptor (mqd_t), which is used to refer to
the open message queue in later calls. Each message queue is identi‐
fied by a name of the form /somename. Two processes can operate on the
same queue by passing the same name to mq_open().
Messages are transferred to and from a queue using mq_send(3) and
mq_receive(3). When a process has finished using the queue, it closes
it using mq_close(3), and when the queue is no longer required, it can
be deleted using mq_unlink(3). Queue attributes can be retrieved and
(in some cases) modified using mq_getattr(3) and mq_setattr(3). A
process can request asynchronous notification of the arrival of a mes‐
sage on a previously empty queue using mq_notify(3).
A message queue descriptor is a reference to an open message queue
description (cf. open(2)). After a fork(2), a child inherits copies
of its parent's message queue descriptors, and these descriptors refer
to the same open message queue descriptions as the corresponding
descriptors in the parent. Corresponding descriptors in the two pro‐
cesses share the flags (mq_flags) that are associated with the open
message queue description.
Each message has an associated priority, and messages are always deliv‐
ered to the receiving process highest priority first. Message priori‐
ties range from 0 (low) to sysconf(_SC_MQ_PRIO_MAX) - 1 (high). On
Linux, sysconf(_SC_MQ_PRIO_MAX) returns 32768, but POSIX.1-2001 only
requires an implementation to support priorities in the range 0 to 31;
some implementations only provide this range.
Library interfaces and system calls
In most cases the mq_*() library interfaces listed above are imple‐
mented on top of underlying system calls of the same name. Deviations
from this scheme are indicated in the following table:
Library interface System call
mq_close(3)close(2)mq_getattr(3)mq_getsetattr(2)mq_open(3)mq_open(2)mq_receive(3)mq_timedreceive(2)mq_send(3)mq_timedsend(2)mq_setattr(3)mq_getsetattr(2)mq_timedreceive(3)mq_timedreceive(2)mq_timedsend(3)mq_timedsend(2)mq_unlink(3)mq_unlink(2)LINUX SPECIFIC DETAILS
Versions
POSIX message queues have been supported on Linux since kernel 2.6.6.
Glibc support has been provided since version 2.3.4.
Kernel configuration
Support for POSIX message queues is configurable via the CON‐
FIG_POSIX_MQUEUE kernel configuration option. This option is enabled
by default.
Persistence
POSIX message queues have kernel persistence: if not removed by
mq_unlink(), a message queue will exist until the system is shut down.
Linking
Programs using the POSIX message queue API must be compiled with cc
-lrt to link against the real-time library, librt.
/proc interfaces
The following interfaces can be used to limit the amount of kernel mem‐
ory consumed by POSIX message queues:
/proc/sys/fs/mqueue/msg_max
This file can be used to view and change the ceiling value for
the maximum number of messages in a queue. This value acts as a
ceiling on the attr->mq_maxmsg argument given to mq_open(3).
The default and minimum value for msg_max is 10; the upper limit
is HARD_MAX: (131072 / sizeof(void *)) (32768 on Linux/86).
This limit is ignored for privileged processes
(CAP_SYS_RESOURCE), but the HARD_MAX ceiling is nevertheless
imposed.
/proc/sys/fs/mqueue/msgsize_max
This file can be used to view and change the ceiling on the max‐
imum message size. This value acts as a ceiling on the
attr->mq_msgsize argument given to mq_open(3). The default and
minimum value for msgsize_max is 8192 bytes; the upper limit is
INT_MAX (2147483647 on Linux/86). This limit is ignored for
privileged processes (CAP_SYS_RESOURCE).
/proc/sys/fs/mqueue/queues_max
This file can be used to view and change the system-wide limit
on the number of message queues that can be created. Only priv‐
ileged processes (CAP_SYS_RESOURCE) can create new message
queues once this limit has been reached. The default value for
queues_max is 256; it can be changed to any value in the range 0
to INT_MAX.
Resource limit
The RLIMIT_MSGQUEUE resource limit, which places a limit on the amount
of space that can be consumed by all of the message queues belonging to
a process's real user ID, is described in getrlimit(2).
Mounting the message queue file system
On Linux, message queues are created in a virtual file system. (Other
implementations may also provide such a feature, but the details are
likely to differ.) This file system can be mounted using the following
commands:
$ mkdir /dev/mqueue
$ mount -t mqueue none /dev/mqueue
The sticky bit is automatically enabled on the mount directory.
After the file system has been mounted, the message queues on the sys‐
tem can be viewed and manipulated using the commands usually used for
files (e.g., ls(1) and rm(1)).
The contents of each file in the directory consist of a single line
containing information about the queue:
$ ls /dev/mqueue/mymq
QSIZE:129 NOTIFY:2 SIGNO:0 NOTIFY_PID:8260
$ mount -t mqueue none /dev/mqueue
These fields are as follows:
QSIZE Number of bytes of data in all messages in the queue.
NOTIFY_PID
If this is non-zero, then the process with this PID has used
mq_notify(3) to register for asynchronous message notification,
and the remaining fields describe how notification occurs.
NOTIFY Notification method: 0 is SIGEV_SIGNAL; 1 is SIGEV_NONE; and 2
is SIGEV_THREAD.
SIGNO Signal number to be used for SIGEV_SIGNAL.
Polling message queue descriptors
On Linux, a message queue descriptor is actually a file descriptor, and
can be monitored using select(2), poll(2), or epoll(7). This is not
portable.
CONFORMING TO
POSIX.1-2001.
NOTES
System V message queues (msgget(2), msgsnd(2), msgrcv(2), etc.) are an
older API for exchanging messages between processes. POSIX message
queues provide a better designed interface than System V message
queues; on the other hand POSIX message queues are less widely avail‐
able (especially on older systems) than System V message queues.
EXAMPLE
An example of the use of various message queue functions is shown in
mq_notify(3).
SEE ALSOgetrlimit(2), mq_getsetattr(2), mq_close(3), mq_getattr(3),
mq_notify(3), mq_open(3), mq_receive(3), mq_send(3), mq_unlink(3),
poll(2), select(2), epoll(4)Linux 2.6.16 2006-02-25 MQ_OVERVIEW(7)
