Use this documentation with care! It describes the outdated version 7, which was actively developed around 2014 and is considered dead by the rsyslog team.

This documentation reflects the latest update of the v7-stable branch. It describes the 7.6.8 version, which was never released. As such, it contains some content that does not apply to any released version.

To obtain the doc that properly matches your installed v7 version, obtain the doc set from your distro. Each version of rsyslog contained the version that exactly matches it.

As general advise, it is strongly suggested to upgrade to the current version supported by the rsyslog project. The current version can always be found on the right-hand side info box on the rsyslog web site.

Note that there is only limited rsyslog community support available for the outdated v7 version (officially we do not support it at all, but we usually are able to answer simple questions). If you need to stick with v7, it probably is best to ask your distribution for support.


Handling a massive syslog database insert rate with Rsyslog

Written by Rainer Gerhards (2008-01-31)


In this paper, I describe how log massive amounts of syslog messages to a database.This HOWTO is currently under development and thus a bit brief. Updates are promised ;).*

The Intention

Database updates are inherently slow when it comes to storing syslog messages. However, there are a number of applications where it is handy to have the message inside a database. Rsyslog supports native database writing via output plugins. As of this writing, there are plugins available for MySQL an PostgreSQL. Maybe additional plugins have become available by the time you read this. Be sure to check.

In order to successfully write messages to a database backend, the backend must be capable to record messages at the expected average arrival rate. This is the rate if you take all messages that can arrive within a day and divide it by 86400 (the number of seconds per day). Let’s say you expect 43,200,000 messages per day. That’s an average rate of 500 messages per second (mps). Your database server MUST be able to handle that amount of message per second on a sustained rate. If it doesn’t, you either need to add an additional server, lower the number of message - or forget about it.

However, this is probably not your peak rate. Let’s simply assume your systems work only half a day, that’s 12 hours (and, yes, I know this is unrealistic, but you’ll get the point soon). So your average rate is actually 1,000 mps during work hours and 0 mps during non-work hours. To make matters worse, workload is not divided evenly during the day. So you may have peaks of up to 10,000mps while at other times the load may go down to maybe just 100mps. Peaks may stay well above 2,000mps for a few minutes.

So how the hack you will be able to handle all of this traffic (including the peaks) with a database server that is just capable of inserting a maximum of 500mps?

The key here is buffering. Messages that the database server is not capable to handle will be buffered until it is. Of course, that means database insert are NOT real-time. If you need real-time inserts, you need to make sure your database server can handle traffic at the actual peak rate. But lets assume you are OK with some delay.

Buffering is fine. But how about these massive amounts of data? That can’t be hold in memory, so don’t we run out of luck with buffering? The key here is that rsyslog can not only buffer in memory but also buffer to disk (this may remind you of “spooling” which gets you the right idea). There are several queuing modes available, offering differnent throughput. In general, the idea is to buffer in memory until the memory buffer is exhausted and switch to disk-buffering when needed (and only as long as needed). All of this is handled automatically and transparently by rsyslog.

With our above scenario, the disk buffer would build up during the day and rsyslog would use the night to drain it. Obviously, this is an extreme example, but it shows what can be done. Please note that queue content survies rsyslogd restarts, so even a reboot of the system will not cause any message loss.

How To Setup

Frankly, it’s quite easy. You just need to do is instruct rsyslog to use a disk queue and then configure your action. There is nothing else to do. With the following simple config file, you log anything you receive to a MySQL database and have buffering applied automatically.

$ModLoad ommysql # load the output driver (use ompgsql for PostgreSQL) $ModLoad imudp # network reception $UDPServerRun 514 # start a udp server at port 514 $ModLoad imuxsock # local message reception $WorkDirectory /rsyslog/work # default location for work (spool) files $MainMsgQueueFileName mainq # set file name, also enables disk mode $ActionResumeRetryCount -1 # infinite retries on insert failure # for PostgreSQL replace :ommysql: by :ompgsql: below: *.* :ommysql:hostname,dbname,userid,password;

The simple setup above has one drawback: the write database action is executed together with all other actions. Typically, local files are also written. These local file writes are now bound to the speed of the database action. So if the database is down, or threre is a large backlog, local files are also not (or late) written.

There is an easy way to avoid this with rsyslog. It involves a slightly more complicated setup. In rsyslog, each action can utilize its own queue. If so, messages are simply pulled over from the main queue and then the action queue handles action processing on its own. This way, main processing and the action are de-coupled. In the above example, this means that local file writes will happen immediately while the database writes are queued. As a side-note, each action can have its own queue, so if you would like to more than a single database or send messages reliably to another host, you can do all of this on their own queues, de-coupling their processing speeds.

The configuration for the de-coupled database write involves just a few more commands:

$ModLoad ommysql # load the output driver (use ompgsql for PostgreSQL) $ModLoad imudp # network reception $UDPServerRun 514 # start a udp server at port 514 $ModLoad imuxsock # local message reception $WorkDirectory /rsyslog/work # default location for work (spool) files $ActionQueueType LinkedList # use asynchronous processing $ActionQueueFileName dbq # set file name, also enables disk mode $ActionResumeRetryCount -1 # infinite retries on insert failure # for PostgreSQL replace :ommysql: by :ompgsql: below: *.* :ommysql:hostname,dbname,userid,password;

This is the recommended configuration for this use case. It requires rsyslog 3.11.0 or above.

In this example, the main message queue is NOT disk-assisted (there is no $MainMsgQueueFileName directive). We still could do that, but have not done it because there seems to be no need. The only slow running action is the database writer and it has its own queue. So there is no real reason to use a large main message queue (except, of course, if you expect *really* heavy traffic bursts).

Note that you can modify a lot of queue performance parameters, but the above config will get you going with default values. If you consider using this on a real busy server, it is strongly recommended to invest some time in setting the tuning parameters to appropriate values.

Feedback requested

I would appreciate feedback on this tutorial. If you have additional ideas, comments or find bugs (I *do* bugs - no way... ;)), please let me know.

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