blob: 91f73763b4e6a32f5dea5195ed0d3825bed6fd88 [file] [log] [blame]
.. This work is licensed under a Creative Commons Attribution 4.0 International License.
.. SPDX-License-Identifier: CC-BY-4.0
.. CAUTION: this document is generated from source in doc/src/rtd.
.. To make changes edit the source and recompile the document.
.. Do NOT make changes directly to .rst or .md files.
RMR Overview
============================================================================================
RMr Library
============================================================================================
NAME
--------------------------------------------------------------------------------------------
RMr -- Ric Message Router Library
DESCRIPTION
--------------------------------------------------------------------------------------------
RMr is a library which provides a user application with the
ability to send and receive messages to/from other RMr based
applications without having to understand the underlying
messaging transport environment (e.g., SI95) and without
needing to know which other endpoint applications are
currently available and accepting messages. To do this, RMr
depends on a routing table generated by an external source.
This table is used to determine the destination endpoint of
each message sent by mapping the message type T (supplied by
the user application) to an endpoint entry. Once determined,
the message is sent directly to the endpoint. The user
application is unaware of which endpoint actually receives
the message, and in some cases whether that message was sent
to multiple applications.
RMr functions do provide for the ability to respond to the
specific source instance of a message allowing for either a
request response, or call response relationship when needed.
The Route Table
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The library must be given a route table which maps message
numbers to endpoint groups such that each time a message of
type T is sent, the message is delivered to one member of
each group associated with T. For example, message type 2
might route to two different groups where group A consists of
worker1 and worker2, while group B consists only of logger1.
It is the responsibility of the route table generator to know
which endpoints belong to which groups, and which groups
accept which message types. Once understood, the route table
generator publishes a table that is ingested by RMr and used
for mapping messages to end points.
The following is a simple route table which causes message
types 0 through 9 to be routed to specific applications:
::
newrt|start
mse|0|-1| %meid
mse|1|-1|app10:4560,app11:4560
mse|2|-1|app12:4560
mse|3|-1|app14:4560
mse|4|-1|app18:4560
mse|5|-1|app01:4560
mse|6|-1|app02:4560
mse|7|-1|app03:4560
mse|8|-1|app04:4560
mse|9|-1|app05:4560
newrt|end
The special endpoint "%meid" indicates that the message type
(0 in this case) is to be routed to the endpoint which has
been listed as the "owner" for the meid appearing in the
message. MEID ownership is communicated to RMR using the same
Route Table Manager interface and by supplying a "table" such
as the one below:
::
meid_map | start
mme_ar | control1 | meid000 meid001 meid002 meid003 meid004 meid005
mme_ar | control2 | meid100 meid101 meid102 meid103
meid_map | end | 2
This table indicates that the application (endpoint)
*control1* "owns" 6 MEIDs and *control2* owns 4. When message
type 0 is sent, the MEID in the message will be used to
select the endpoint via this table.
The MEID table will update the existing owner relationships,
and add new ones; it is necessary to send only the changes
with the add/replace (mme_ar) entries in the table. When
necessary, MEIDs can be deleted by adding an mme_del record
to the table. The following example illustrates how this
might look:
::
meid_map | start
mme_ar | control1 | meid000 meid001 meid002 meid003 meid004 meid005
mme_ar | control2 | meid100 meid101 meid102 meid103
mme_del| meid200 meid401
meid_map | end | 3
Route Table Syntax
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The following illustrates the syntax for both the route
table.
::
newrt | start
mse | <message-type>[,<sender-endpoint>] | <sub-id> <roud-robin-grp>[;<round-robin-grp>]...
newrt | end
A round robin group is one or more endpoints from which one
will be selected to receive the message. When multiple
endpoints are given in a group, they must be separated with a
comma. An endpoint is the IP address and port (e.g.
192.158.4.30:8219) or DNS name and port of the application
that should receive the message type. If multiple round-robin
groups are given, they must be separated by a semicolon, and
MEID Map Syntax
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The MEID map is similar to the route table. Entries are used
to add or replace the ownership of one or more MEIDs (mme_ar)
or to delete one or more MEIDs (mme_del). The following is
the syntax for the MEID map.
::
meid_map | start
mme_ar | <owner-endpoint> | <meid> [<meid>...]
mme_del | <meid> [<meid>...]
meid_map | end | <count> [| <md5sum>
The <count> on the end record indicates the number of mme_ar
and mme_del records which were sent; if the count does not
match the whole map is refused and dropped. The
<owner-endpoint> is the endpoint which should receive the
message when a message is routed based on the MEID it
contains. A MEID may be "owned" by only one endpoint, and if
supplied multiple times, the last observed relationship is
used. Each of the lists of MEIDs are blank separated.
The optional <md5sum> on the *end* record should be the
computed MD5 hash for all records which appear between the
start and and records. This allows for a tighter verification
that all data was received exactly as the route manager
transmitted them.
Environment
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To enable configuration of the library behaviour outside of
direct user application control, RMr supports a number of
environment variables which provide information to the
library. The following is a list of the various environment
variables, what they control and the defaults which RMr uses
if undefined.
RMR_ASYNC_CONN
Allows the async connection mode to be turned off (by
setting the value to 0). When set to 1, or missing from
the environment, RMR will invoke the connection interface
in the transport mechanism using the non-blocking (async)
mode. This will likely result in many "soft failures"
(retry) until the connection is established, but allows
the application to continue unimpeded should the
connection be slow to set up.
RMR_BIND_IF
This provides the interface that RMR will bind listen
ports to, allowing for a single interface to be used
rather than listening across all interfaces. This should
be the IP address assigned to the interface that RMR
should listen on, and if not defined RMR will listen on
all interfaces.
RMR_CTL_PORT
This variable defines the port that RMR should open for
communications with Route Manager, and other RMR control
applications. If not defined, the port 4561 is assumed.
Previously, the RMR_RTG_SVC (route table generator service
port) was used to define this port. However, a future
version of Route Manager will require RMR to connect and
request tables, thus that variable is now used to supply
the Route Manager's well-known address and port.
To maintain backwards compatibility with the older Route
Manager versions, the presence of this variable in the
environment will shift RMR's behaviour with respect to the
default value used when RMR_RTG_SVC is **not** defined.
When RMR_CTL_PORT is **defined:** RMR assumes that Route
Manager requires RMR to connect and request table updates
is made, and the default well-known address for Route
manager is used (routemgr:4561).
When RMR_CTL_PORT is **undefined:** RMR assumes that Route
Manager will connect and push table updates, thus the
default listen port (4561) is used.
To avoid any possible misinterpretation and/or incorrect
assumptions on the part of RMR, it is recommended that
both the RMR_CTL_PORT and RMR_RTG_SVC be defined. In the
case where both variables are defined, RMR will behave
exactly as is communicated with the variable's values.
RMR_RTG_SVC
The value of this variable depends on the Route Manager in
use.
When the Route Manager is expecting to connect to an xAPP
and push route tables, this variable must indicate the
port which RMR should use to listen for these connections.
When the Route Manager is expecting RMR to connect and
request a table update during initialisation, the variable
should be the host of the Route Manager process.
The RMR_CTL_PORT variable (added with the support of
sending table update requests to Route manager), controls
the behaviour if this variable is not set. See the
description of that variable for details.
RMR_HR_LOG
By default RMR writes messages to standard error
(incorrectly referred to as log messages) in human
readable format. If this environment variable is set to 0,
the format of standard error messages might be written in
some format not easily read by humans. If missing, a value
of 1 is assumed.
RMR_LOG_VLEVEL
This is a numeric value which corresponds to the verbosity
level used to limit messages written to standard error.
The lower the number the less chatty RMR functions are
during execution. The following is the current
relationship between the value set on this variable and
the messages written:
0
Off; no messages of any sort are written.
1
Only critical messages are written (default if this
variable does not exist)
2
Errors and all messages written with a lower value.
3
Warnings and all messages written with a lower value.
4
Informational and all messages written with a lower
value.
5
Debugging mode -- all messages written, however this
requires RMR to have been compiled with debugging
support enabled.
RMR_RTG_ISRAW
**Deprecated.** Should be set to 1 if the route table
generator is sending "plain" messages (not using RMR to
send messages), 0 if the RTG is using RMR to send. The
default is 1 as we don't expect the RTG to use RMR.
This variable is only recognised when using the NNG
transport library as it is not possible to support NNG
"raw" communications with other transport libraries. It is
also necessary to match the value of this variable with
the capabilities of the Route Manager; at some point in
the future RMR will assume that all Route Manager messages
will arrive via an RMR connection and will ignore this
variable.
RMR_SEED_RT
This is used to supply a static route table which can be
used for debugging, testing, or if no route table
generator process is being used to supply the route table.
If not defined, no static table is used and RMR will not
report *ready* until a table is received. The static route
table may contain both the route table (between newrt
start and end records), and the MEID map (between meid_map
start and end records).
RMR_SRC_ID
This is either the name or IP address which is placed into
outbound messages as the message source. This will used
when an RMR based application uses the rmr_rts_msg()
function to return a response to the sender. If not
supplied RMR will use the hostname which in some container
environments might not be routable.
The value of this variable is also used for Route Manager
messages which are sent via an RMR connection.
RMR_VCTL_FILE
This supplies the name of a verbosity control file. The
core RMR functions do not produce messages unless there is
a critical failure. However, the route table collection
thread, not a part of the main message processing
component, can write additional messages to standard
error. If this variable is set, RMR will extract the
verbosity level for these messages (0 is silent) from the
first line of the file. Changes to the file are detected
and thus the level can be changed dynamically, however RMR
will only suss out this variable during initialisation, so
it is impossible to enable verbosity after startup.
RMR_WARNINGS
If set to 1, RMR will write some warnings which are
non-performance impacting. If the variable is not defined,
or set to 0, RMR will not write these additional warnings.
SEE ALSO
--------------------------------------------------------------------------------------------
rmr_alloc_msg(3), rmr_tralloc_msg(3), rmr_call(3),
rmr_free_msg(3), rmr_init(3), rmr_init_trace(3),
rmr_get_meid(3), rmr_get_src(3), rmr_get_srcip(3),
rmr_get_trace(3), rmr_get_trlen(3), rmr_get_xact(3),
rmr_payload_size(3), rmr_rcv_msg(3), rmr_rcv_specific(3),
rmr_rts_msg(3), rmr_ready(3), rmr_fib(3), rmr_has_str(3),
rmr_tokenise(3), rmr_mk_ring(3), rmr_realloc_payload(3),
rmr_ring_free(3), rmr_set_trace(3), rmr_torcv_msg(3),
rmr_wh_open(3), rmr_wh_send_msg(3)