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author | Igor Pashev <pashev.igor@gmail.com> | 2014-10-01 17:56:20 +0400 |
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committer | Igor Pashev <pashev.igor@gmail.com> | 2014-10-01 17:56:20 +0400 |
commit | c046f7bcc92281465917e026f83fd0d38569cb06 (patch) | |
tree | 711f61cf319e171a5f41c469ef30e3298c8917f8 /doc/queues.html | |
parent | 17262528e2277c3d069c4a29ed098830d4fdbc08 (diff) | |
parent | 7ec8c6d6f9114765775ea5100af5b0b20af4502e (diff) | |
download | rsyslog-c046f7bcc92281465917e026f83fd0d38569cb06.tar.gz |
Merge branch 'master' of git://anonscm.debian.org/collab-maint/rsyslog
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debian/changelog
debian/patches/series
debian/rules
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diff --git a/doc/queues.html b/doc/queues.html deleted file mode 100644 index 75b70fb..0000000 --- a/doc/queues.html +++ /dev/null @@ -1,398 +0,0 @@ -<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.01 Transitional//EN"> -<html><head> -<title>Understanding rsyslog queues</title></head> -<body> -<a href="rsyslog_conf_global.html">back</a> - -<h1>Understanding rsyslog Queues</h1> -<p>Rsyslog uses queues whenever two activities need to be loosely coupled. With a -queue, one part of the system "produces" something while another part "consumes" -this something. The "something" is most often syslog messages, but queues may -also be used for other purposes.</p> -<p>This document provides a good insight into technical details, operation modes -and implications. In addition to it, an -<a href="queues_analogy.html">rsyslog queue concepts overview</a> document -exists which tries to explain queues with the help of some analogies. This may -probably be a better place to start reading about queues. I assume that once you -have understood that document, the material here will be much easier to grasp -and look much more natural. -<p>The most prominent example is the main message queue. Whenever rsyslog -receives a message (e.g. locally, via UDP, TCP or in whatever else way), it -places these messages into the main message queue. Later, it is dequeued by the -rule processor, which then evaluates which actions are to be carried out. In -front of each action, there is also a queue, which potentially de-couples the -filter processing from the actual action (e.g. writing to file, database or -forwarding to another host).</p> -<h1>Where are Queues Used?</h1> -<p>Currently, queues are used for the main message queue and for the -actions.</p> -<p>There is a single main message queue inside rsyslog. Each input module -delivers messages to it. The main message queue worker filters messages based on -rules specified in rsyslog.conf and dispatches them to the individual action -queues. Once a message is in an action queue, it is deleted from the main -message queue.</p> -<p>There are multiple action queues, one for each configured action. By default, -these queues operate in direct (non-queueing) mode. Action queues are fully -configurable and thus can be changed to whatever is best for the given use case.</p> -<p>Future versions of rsyslog will most probably utilize queues at other places, -too.</p> -<p> Wherever "<i><object></i>" is used in the config file -statements, substitute "<i><object></i>" with either "MainMsg" or "Action". The -former will set main message queue -parameters, the later parameters for the next action that will be -created. Action queue parameters can not be modified once the action has been -specified. For example, to tell the main message queue to save its content on -shutdown, use <i>$MainMsgQueueSaveOnShutdown on</i>".</p> -<p>If the same parameter is specified multiple times before a queue is created, -the last one specified takes precedence. The main message queue is created after -parsing the config file and all of its potential includes. An action queue is -created each time an action selector is specified. Action queue parameters are -reset to default after an action queue has been created (to provide a clean -environment for the next action).</p> -<p>Not all queues necessarily support the full set of queue configuration -parameters, because not all are applicable. For example, in current output -module design, actions do not support multi-threading. Consequently, the number -of worker threads is fixed to one for action queues and can not be changed.</p> -<h1>Queue Modes</h1> -<p>Rsyslog supports different queue modes, some with submodes. Each of them has -specific advantages and disadvantages. Selecting the right queue mode is quite -important when tuning rsyslogd. The queue mode (aka "type") is set via the "<i>$<object>QueueType</i>" -config directive.</p> -<h2>Direct Queues</h2> -<p>Direct queues are <b>non</b>-queuing queues. A queue in direct mode does -neither queue nor buffer any of the queue elements but rather passes the element -directly (and immediately) from the producer to the consumer. This sounds strange, -but there is a good reason for this queue type.</p> -<p>Direct mode queues allow to use queues generically, even in places where -queuing is not always desired. A good example is the queue in front of output -actions. While it makes perfect sense to buffer forwarding actions or database -writes, it makes only limited sense to build up a queue in front of simple local -file writes. Yet, rsyslog still has a queue in front of every action. So for -file writes, the queue mode can simply be set to "direct", in which case no -queuing happens.</p> -<p>Please note that a direct queue also is the only queue type that passes back -the execution return code (success/failure) from the consumer to the producer. -This, for example, is needed for the backup action logic. Consequently, backup -actions require the to-be-checked action to use a "direct" mode queue.</p> -<p>To create a direct queue, use the "<i>$<object>QueueType Direct</i>" config -directive.</p> -<h2>Disk Queues</h2> -<p>Disk queues use disk drives for buffering. The important fact is that the -always use the disk and do not buffer anything in memory. Thus, the queue is -ultra-reliable, but by far the slowest mode. For regular use cases, this queue -mode is not recommended. It is useful if log data is so important that it must -not be lost, even in extreme cases.</p> -<p>When a disk queue is written, it is done in chunks. Each chunk receives its -individual file. Files are named with a prefix (set via the "<i>$<object>QueueFilename</i>" -config directive) and followed by a 7-digit number (starting at one and -incremented for each file). Chunks are 10mb by default, a different size can be -set via the"<i>$<object>QueueMaxFileSize</i>" config directive. Note that -the size limit is not a sharp one: rsyslog always writes one complete queue -entry, even if it violates the size limit. So chunks are actually a little but -(usually less than 1k) larger then the configured size. Each chunk also has a -different size for the same reason. If you observe different chunk sizes, you -can relax: this is not a problem.</p> -<p>Writing in chunks is used so that processed data can quickly be deleted and -is free for other uses - while at the same time keeping no artificial upper -limit on disk space used. If a disk quota is set (instructions further below), -be sure that the quota/chunk size allows at least two chunks to be written. -Rsyslog currently does not check that and will fail miserably if a single chunk -is over the quota.</p> -<p>Creating new chunks costs performance but provides quicker ability to free -disk space. The 10mb default is considered a good compromise between these two. -However, it may make sense to adapt these settings to local policies. For -example, if a disk queue is written on a dedicated 200gb disk, it may make sense -to use a 2gb (or even larger) chunk size.</p> -<p>Please note, however, that the disk queue by default does not update its -housekeeping structures every time it writes to disk. This is for performance -reasons. In the event of failure, data will still be lost (except when manually -is mangled with the file structures). However, disk queues can be set to write -bookkeeping information on checkpoints (every n records), so that this can be -made ultra-reliable, too. If the checkpoint interval is set to one, no data can -be lost, but the queue is exceptionally slow.</p> -<p>Each queue can be placed on a different disk for best performance and/or -isolation. This is currently selected by specifying different <i>$WorkDirectory</i> -config directives before the queue creation statement.</p> -<p>To create a disk queue, use the "<i>$<object>QueueType Disk</i>" config -directive. Checkpoint intervals can be specified via "<i>$<object>QueueCheckpointInterval</i>", -with 0 meaning no checkpoints. Note that disk-based queues can be made very reliable -by issuing a (f)sync after each write operation. Starting with version 4.3.2, this can -be requested via "<i><object>QueueSyncQueueFiles on/off</i> with the -default being off. Activating this option has a performance penalty, so it should -not be turned on without reason.</p> -<h2>In-Memory Queues</h2> -<p>In-memory queue mode is what most people have on their mind when they think -about computing queues. Here, the enqueued data elements are held in memory. -Consequently, in-memory queues are very fast. But of course, they do not survive -any program or operating system abort (what usually is tolerable and unlikely). -Be sure to use an UPS if you use in-memory mode and your log data is important -to you. Note that even in-memory queues may hold data for an infinite amount of -time when e.g. an output destination system is down and there is no reason to move -the data out of memory (lying around in memory for an extended period of time is -NOT a reason). Pure in-memory queues can't even store queue elements anywhere -else than in core memory. </p> -<p>There exist two different in-memory queue modes: LinkedList and FixedArray. -Both are quite similar from the user's point of view, but utilize different -algorithms. </p> -<p>A FixedArray queue uses a fixed, pre-allocated array that holds pointers to -queue elements. The majority of space is taken up by the actual user data -elements, to which the pointers in the array point. The pointer array itself is -comparatively small. However, it has a certain memory footprint even if the -queue is empty. As there is no need to dynamically allocate any housekeeping -structures, FixedArray offers the best run time performance (uses the least CPU -cycle). FixedArray is best if there is a relatively low number of queue elements -expected and performance is desired. It is the default mode for the main message -queue (with a limit of 10,000 elements).</p> -<p>A LinkedList queue is quite the opposite. All housekeeping structures are -dynamically allocated (in a linked list, as its name implies). This requires -somewhat more runtime processing overhead, but ensures that memory is only -allocated in cases where it is needed. LinkedList queues are especially -well-suited for queues where only occasionally a than-high number of elements -need to be queued. A use case may be occasional message burst. Memory -permitting, it could be limited to e.g. 200,000 elements which would take up -only memory if in use. A FixedArray queue may have a too large static memory -footprint in such cases.</p> -<p><b>In general, it is advised to use LinkedList mode if in doubt</b>. The -processing overhead compared to FixedArray is low and may be -outweigh by the reduction in memory use. Paging in most-often-unused -pointer array pages can be much slower than dynamically allocating them.</p> -<p>To create an in-memory queue, use the "<i>$<object>QueueType LinkedList</i>" -or "<i>$<object>QueueType FixedArray</i>" config directive.</p> -<h3>Disk-Assisted Memory Queues</h3> -<p>If a disk queue name is defined for in-memory queues (via <i> -$<object>QueueFileName</i>), they automatically -become "disk-assisted" (DA). In that mode, data is written to disk (and read -back) on an as-needed basis.</p> -<p>Actually, the regular memory queue (called the -"primary queue") and a disk queue (called the "DA queue") work in tandem in this -mode. Most importantly, the disk queue is activated if the primary queue is full -or needs to be persisted on shutdown. Disk-assisted queues combine the -advantages of pure memory queues with those of pure disk queues. Under normal -operations, they are very fast and messages will never touch the disk. But if -there is need to, an unlimited amount of messages can be buffered (actually -limited by free disk space only) and data can be persisted between rsyslogd runs.</p> -<p>With a DA-queue, both disk-specific and in-memory specific configuration -parameters can be set. From the user's point of view, think of a DA queue like a -"super-queue" which does all within a single queue [from the code perspective, -there is some specific handling for this case, so it is actually much like a -single object].</p> -<p>DA queues are typically used to de-couple potentially long-running and -unreliable actions (to make them reliable). For example, it is recommended to -use a disk-assisted linked list in-memory queue in front of each database and -"send via tcp" action. Doing so makes these actions reliable and de-couples -their potential low execution speed from the rest of your rules (e.g. the local -file writes). There is a howto on <a href="rsyslog_high_database_rate.html"> -massive database inserts</a> which nicely describes this use case. It may even -be a good read if you do not intend to use databases.</p> -<p>With DA queues, we do not simply write out everything to disk and then run as -a disk queue once the in-memory queue is full. A much smarter algorithm is used, -which involves a "high watermark" and a "low watermark". Both specify numbers of -queued items. If the queue size reaches high watermark elements, the queue -begins to write data elements to disk. It does so until it reaches the low water -mark elements. At this point, it stops writing until either high water mark is -reached again or the on-disk queue becomes empty, in which case the queue -reverts back to in-memory mode, only. While holding at the low watermark, new -elements are actually enqueued in memory. They are eventually written to disk, -but only if the high water mark is ever reached again. If it isn't, these items -never touch the disk. So even when a queue runs disk-assisted, there is -in-memory data present (this is a big difference to pure disk queues!).</p> -<p>This algorithm prevents unnecessary disk writes, but also leaves some -additional buffer space for message bursts. Remember that creating disk files -and writing to them is a lengthy operation. It is too lengthy to e.g. block -receiving UDP messages. Doing so would result in message loss. Thus, the queue -initiates DA mode, but still is able to receive messages and enqueue them - as -long as the maximum queue size is not reached. The number of elements between -the high water mark and the maximum queue size serves as this "emergency -buffer". Size it according to your needs, if traffic is very bursty you will -probably need a large buffer here. Keep in mind, though, that under normal -operations these queue elements will probably never be used. Setting the high -water mark too low will cause disk-assistance to be turned on more often than -actually needed.</p> -<p>The water marks can be set via the "<i>$<object>QueueHighWatermark</i>" and -"<i>$<object>QueueHighWatermark</i>" configuration file directives. Note that -these are actual numbers, not precentages. Be sure they make sense (also in -respect to "<i>$<object>QueueSize</i>"), as rsyslodg does currently not perform -any checks on the numbers provided. It is easy to screw up the system here (yes, -a feature enhancement request is filed ;)).</p> -<h1>Limiting the Queue Size</h1> -<p>All queues, including disk queues, have a limit of the number of elements -they can enqueue. This is set via the "<i>$<object>QueueSize</i>" config -parameter. Note that the size is specified in number of enqueued elements, not -their actual memory size. Memory size limits can not be set. A conservative -assumption is that a single syslog messages takes up 512 bytes on average -(in-memory, NOT on the wire, this *is* a difference).</p> -<p>Disk assisted queues are special in that they do <b>not</b> have any size -limit. The enqueue an unlimited amount of elements. To prevent running out of -space, disk and disk-assisted queues can be size-limited via the "<i>$<object>QueueMaxDiskSpace</i>" -configuration parameter. If it is not set, the limit is only available free -space (and reaching this limit is currently not very gracefully handled, so -avoid running into it!). If a limit is set, the queue can not grow larger than -it. Note, however, that the limit is approximate. The engine always writes -complete records. As such, it is possible that slightly more than the set limit -is used (usually less than 1k, given the average message size). Keeping strictly -on the limit would be a performance hurt, and thus the design decision was to -favour performance. If you don't like that policy, simply specify a slightly -lower limit (e.g. 999,999K instead of 1G).</p> -<p>In general, it is a good idea to limit the pysical disk space even if you -dedicate a whole disk to rsyslog. That way, you prevent it from running out of -space (future version will have an auto-size-limit logic, that then kicks in in -such situations).</p> -<h1>Worker Thread Pools</h1> -<p>Each queue (except in "direct" mode) has an associated pool of worker -threads. Worker threads carry out the action to be performed on the data -elements enqueued. As an actual sample, the main message queue's worker task is -to apply filter logic to each incoming message and enqueue them to the relevant -output queues (actions).</p> -<p>Worker threads are started and stopped on an as-needed basis. On a system -without activity, there may be no worker at all running. One is automatically -started when a message comes in. Similarily, additional workers are started if -the queue grows above a specific size. The "<i>$<object>QueueWorkerThreadMinimumMessages</i>" -config parameter controls worker startup. If it is set to the minimum number of -elements that must be enqueued in order to justify a new worker startup. For -example, let's assume it is set to 100. As long as no more than 100 messages are -in the queue, a single worker will be used. When more than 100 messages arrive, -a new worker thread is automatically started. Similarily, a third worker will be -started when there are at least 300 messages, a forth when reaching 400 and so -on.</p> -<p>It, however, does not make sense to have too many worker threads running in -parall. Thus, the upper limit ca be set via "<i>$<object>QueueWorkerThreads</i>". -If it, for example, is set to four, no more than four workers will ever be -started, no matter how many elements are enqueued. </p> -<p>Worker threads that have been started are kept running until an inactivity -timeout happens. The timeout can be set via "<i>$<object>QueueWorkerTimeoutThreadShutdown</i>" -and is specified in milliseconds. If you do not like to keep the workers -running, simply set it to 0, which means immediate timeout and thus immediate -shutdown. But consider that creating threads involves some overhead, and this is -why we keep them running. If you would like to never shutdown any worker -threads, specify -1 for this parameter.</p> -<h2>Discarding Messages</h2> -<p>If the queue reaches the so called "discard watermark" (a number of queued -elements), less important messages can automatically be discarded. This is in an -effort to save queue space for more important messages, which you even less like -to loose. Please note that whenever there are more than "discard watermark" -messages, both newly incoming as well as already enqueued low-priority messages -are discarded. The algorithm discards messages newly coming in and those at the -front of the queue.</p> -<p>The discard watermark is a last resort setting. It should be set sufficiently -high, but low enough to allow for large message burst. Please note that it take -effect immediately and thus shows effect promptly - but that doesn't help if the -burst mainly consist of high-priority messages...</p> -<p>The discard watermark is set via the "<i>$<object>QueueDiscardMark</i>" -directive. The priority of messages to be discarded is set via "<i>$<object>QueueDiscardSeverity</i>". -This directive accepts both the usual textual severity as well as a -numerical one. To understand it, you must be aware of the numerical -severity values. They are defined in RFC 3164:</p> -<pre> Numerical Severity<br> Code<br><br> 0 Emergency: system is unusable<br> 1 Alert: action must be taken immediately<br> 2 Critical: critical conditions<br> 3 Error: error conditions<br> 4 Warning: warning conditions<br> 5 Notice: normal but significant condition<br> 6 Informational: informational messages<br> 7 Debug: debug-level messages</pre> -<p>Anything of the specified severity and (numerically) above it is -discarded. To turn message discarding off, simply specify the discard -watermark to be higher than the queue size. An alternative is to -specify the numerical value 8 as DiscardSeverity. This is also the -default setting to prevent unintentional message loss. So if you would -like to use message discarding, you need to set" <i>$<object>QueueDiscardSeverity</i>" to an actual value.</p> -<p>An interesting application is with disk-assisted queues: if the discard -watermark is set lower than the high watermark, message discarding will start -before the queue becomes disk-assisted. This may be a good thing if you would -like to switch to disk-assisted mode only in cases where it is absolutely -unavoidable and you prefer to discard less important messages first.</p> -<h1>Filled-Up Queues</h1> -<p>If the queue has either reached its configured maximum number of entries or -disk space, it is finally full. If so, rsyslogd throttles the data element -submitter. If that, for example, is a reliable input (TCP, local log socket), -that will slow down the message originator which is a good -resolution for this scenario.</p> -<p>During throtteling, a disk-assisted queue continues to write to disk and -messages are also discarded based on severity as well as regular dequeuing and -processing continues. So chances are good the situation will be resolved by -simply throttling. Note, though, that throtteling is highly undesirable for -unreliable sources, like UDP message reception. So it is not a good thing to run -into throtteling mode at all.</p> -<p>We can not hold processing -infinitely, not even when throtteling. For example, throtteling the local -log socket too long would cause the system at whole come to a standstill. To -prevent this, rsyslogd times out after a configured period ("<i>$<object>QueueTimeoutEnqueue</i>", -specified in milliseconds) if no space becomes available. As a last resort, it -then discards the newly arrived message.</p> -<p>If you do not like throtteling, set the timeout to 0 - the message will then -immediately be discarded. If you use a high timeout, be sure you know what you -do. If a high main message queue enqueue timeout is set, it can lead to -something like a complete hang of the system. The same problem does not apply to -action queues.</p> -<h2>Rate Limiting</h2> -<p>Rate limiting provides a way to prevent rsyslogd from processing things too -fast. It can, for example, prevent overruning a receiver system.</p> -<p>Currently, there are only limited rate-limiting features available. The "<i>$<object>QueueDequeueSlowdown</i>" -directive allows to specify how long (in microseconds) dequeueing should be -delayed. While simple, it still is powerful. For example, using a -DequeueSlowdown delay of 1,000 microseconds on a UDP send action ensures that no -more than 1,000 messages can be sent within a second (actually less, as there is -also some time needed for the processing itself).</p><h2>Processing Timeframes</h2><p>Queues -can be set to dequeue (process) messages only during certain -timeframes. This is useful if you, for example, would like to transfer -the bulk of messages only during off-peak hours, e.g. when you have -only limited bandwidth on the network path the the central server.</p><p>Currently, -only a single timeframe is supported and, even worse, it can only be -specified by the hour. It is not hard to extend rsyslog's capabilities -in this regard - it was just not requested so far. So if you need more -fine-grained control, let us know and we'll probably implement it. -There are two configuration directives, both should be used together or -results are unpredictable:" <i>$<object>QueueDequeueTimeBegin <hour></i>" and "<i>$<object>QueueDequeueTimeEnd <hour></i>". The hour parameter must be specified in 24-hour format (so 10pm is 22). A use case for this parameter can be found in the <a href="http://wiki.rsyslog.com/index.php/OffPeakHours">rsyslog wiki</a>. </p> -<h2>Performance</h2> -<p>The locking involved with maintaining the queue has a potentially large -performance impact. How large this is, and if it exists at all, depends much on -the configuration and actual use case. However, the queue is able to work on -so-called "batches" when dequeueing data elements. With batches, -multiple data elements are dequeued at once (with a single locking call). -The queue dequeues all available elements up to a configured upper -limit (<i><object>DequeueBatchSize <number></i>). It is important -to note that the actual upper limit is dictated by availability. The queue engine -will never wait for a batch to fill. So even if a high upper limit is configured, -batches may consist of fewer elements, even just one, if there are no more elements -waiting in the queue. -<p>Batching -can improve performance considerably. Note, however, that it affects the -order in which messages are passed to the queue worker threads, as each worker -now receive as batch of messages. Also, the larger the batch size and the higher -the maximum number of permitted worker threads, the more main memory is needed. -For a busy server, large batch sizes (around 1,000 or even more elements) may be useful. -Please note that with batching, the main memory must hold BatchSize * NumOfWorkers -objects in memory (worst-case scenario), even if running in disk-only mode. So if you -use the default 5 workers at the main message queue and set the batch size to 1,000, you need -to be prepared that the main message queue holds up to 5,000 messages in main memory -<b>in addition</b> to the configured queue size limits! -<p>The queue object's default maximum batch size -is eight, but there exists different defaults for the actual parts of -rsyslog processing that utilize queues. So you need to check these object's -defaults. -<h2>Terminating Queues</h2> -<p>Terminating a process sounds easy, but can be complex. -Terminating a running queue is in fact the most complex operation a queue -object can perform. You don't see that from a user's point of view, but its -quite hard work for the developer to do everything in the right order.</p> -<p>The complexity arises when the queue has still data enqueued when it -finishes. Rsyslog tries to preserve as much of it as possible. As a first -measure, there is a regular queue time out ("<i>$<object>QueueTimeoutShutdown</i>", -specified in milliseconds): the queue workers are given that time period to -finish processing the queue.</p> -<p>If after that period there is still data in the queue, workers are instructed -to finish the current data element and then terminate. This essentially means -any other data is lost. There is another timeout ("<i>$<object>QueueTimeoutActionCompletion</i>", -also specified in milliseconds) that specifies how long the workers have to -finish the current element. If that timeout expires, any remaining workers are -cancelled and the queue is brought down.</p> -<p>If you do not like to lose data on shutdown, the "<i>$<object>QueueSaveOnShutdown</i>" -parameter can be set to "on". This requires either a disk or disk-assisted -queue. If set, rsyslogd ensures that any queue elements are saved to disk before -it terminates. This includes data elements there were begun being processed by -workers that needed to be cancelled due to too-long processing. For a large -queue, this operation may be lengthy. No timeout applies to a required shutdown -save.</p> -[<a href="manual.html">manual index</a>] -[<a href="rsyslog_conf.html">rsyslog.conf</a>] -[<a href="http://www.rsyslog.com/">rsyslog site</a>]</p> -<p><font size="2">This documentation is part of the -<a href="http://www.rsyslog.com/">rsyslog</a> project.<br> -Copyright © 2008, 2009 by <a href="http://www.gerhards.net/rainer">Rainer Gerhards</a> and -<a href="http://www.adiscon.com/">Adiscon</a>. Released under the GNU GPL -version 3 or higher.</font></p> - -</body></html> |