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-<p><a name="__index__"></a></p>
+
<!-- INDEX BEGIN -->
<!-- INDEX BEGIN -->
+<div name="index">
+<p><a name="__index__"></a></p>
<!--
<ul>
<!--
<ul>
<ul>
<li><a href="#filename"><em>filename</em></a></li>
<ul>
<li><a href="#filename"><em>filename</em></a></li>
- <li><a href="#start_b_start_time__default__now__10s_"><strong>-start</strong>|<strong>-b</strong> <em>start time</em> (default: now - 10s)</a></li>
- <li><a href="#step_s_step__default__300_seconds_"><strong>-step</strong>|<strong>-s</strong> <em>step</em> (default: 300 seconds)</a></li>
- <li><a href="#ds_dsname_dst_dst_arguments"><strong>DS:</strong><em>ds-name</em><strong>:</strong><em>DST</em><strong>:</strong><em>dst arguments</em></a></li>
+ <li><a href="#__start__b_start_time__default__now___10s_"><strong>-start</strong>|<strong>-b</strong> <em>start time</em> (default: now - 10s)</a></li>
+ <li><a href="#__step__s_step__default__300_seconds_"><strong>-step</strong>|<strong>-s</strong> <em>step</em> (default: 300 seconds)</a></li>
+ <li><a href="#ds_ds_name_dst_dst_arguments"><strong>DS:</strong><em>ds-name</em><strong>:</strong><em>DST</em><strong>:</strong><em>dst arguments</em></a></li>
<li><a href="#rra_cf_cf_arguments"><strong>RRA:</strong><em>CF</em><strong>:</strong><em>cf arguments</em></a></li>
</ul>
<li><a href="#rra_cf_cf_arguments"><strong>RRA:</strong><em>CF</em><strong>:</strong><em>cf arguments</em></a></li>
</ul>
- <li><a href="#aberrant_behavior_detection_with_holtwinters_forecasting">Aberrant Behavior Detection with Holt-Winters Forecasting</a></li>
+ <li><a href="#aberrant_behavior_detection_with_holt_winters_forecasting">Aberrant Behavior Detection with Holt-Winters Forecasting</a></li>
<li><a href="#the_heartbeat_and_the_step">The HEARTBEAT and the STEP</a></li>
<li><a href="#how_to_measure">HOW TO MEASURE</a></li>
<li><a href="#example">EXAMPLE</a></li>
<li><a href="#the_heartbeat_and_the_step">The HEARTBEAT and the STEP</a></li>
<li><a href="#how_to_measure">HOW TO MEASURE</a></li>
<li><a href="#example">EXAMPLE</a></li>
<li><a href="#example_3">EXAMPLE 3</a></li>
<li><a href="#author">AUTHOR</a></li>
</ul>
<li><a href="#example_3">EXAMPLE 3</a></li>
<li><a href="#author">AUTHOR</a></li>
</ul>
+
-->
-->
+
+
+</div>
<!-- INDEX END -->
<p>
<!-- INDEX END -->
<p>
</p>
<h2><a name="filename"><em>filename</em></a></h2>
<p>The name of the <strong>RRD</strong> you want to create. <strong>RRD</strong> files should end
</p>
<h2><a name="filename"><em>filename</em></a></h2>
<p>The name of the <strong>RRD</strong> you want to create. <strong>RRD</strong> files should end
-with the extension <em>.rrd</em>. However, <strong>RRDtool</strong> will accept any
+with the extension <em class="file">.rrd</em>. However, <strong>RRDtool</strong> will accept any
filename.</p>
<p>
</p>
filename.</p>
<p>
</p>
-<h2><a name="start_b_start_time__default__now__10s_"><strong>--start</strong>|<strong>-b</strong> <em>start time</em> (default: now - 10s)</a></h2>
+<h2><a name="__start__b_start_time__default__now___10s_"><strong>--start</strong>|<strong>-b</strong> <em>start time</em> (default: now - 10s)</a></h2>
<p>Specifies the time in seconds since 1970-01-01 UTC when the first
value should be added to the <strong>RRD</strong>. <strong>RRDtool</strong> will not accept
any data timed before or at the time specified.</p>
<p>Specifies the time in seconds since 1970-01-01 UTC when the first
value should be added to the <strong>RRD</strong>. <strong>RRDtool</strong> will not accept
any data timed before or at the time specified.</p>
<em>rrdfetch</em> documentation for other ways to specify time.</p>
<p>
</p>
<em>rrdfetch</em> documentation for other ways to specify time.</p>
<p>
</p>
-<h2><a name="step_s_step__default__300_seconds_"><strong>--step</strong>|<strong>-s</strong> <em>step</em> (default: 300 seconds)</a></h2>
+<h2><a name="__step__s_step__default__300_seconds_"><strong>--step</strong>|<strong>-s</strong> <em>step</em> (default: 300 seconds)</a></h2>
<p>Specifies the base interval in seconds with which data will be fed
into the <strong>RRD</strong>.</p>
<p>
</p>
<p>Specifies the base interval in seconds with which data will be fed
into the <strong>RRD</strong>.</p>
<p>
</p>
-<h2><a name="ds_dsname_dst_dst_arguments"><strong>DS:</strong><em>ds-name</em><strong>:</strong><em>DST</em><strong>:</strong><em>dst arguments</em></a></h2>
+<h2><a name="ds_ds_name_dst_dst_arguments"><strong>DS:</strong><em>ds-name</em><strong>:</strong><em>DST</em><strong>:</strong><em>dst arguments</em></a></h2>
<p>A single <strong>RRD</strong> can accept input from several data sources (<strong>DS</strong>),
for example incoming and outgoing traffic on a specific communication
line. With the <strong>DS</strong> configuration option you must define some basic
<p>A single <strong>RRD</strong> can accept input from several data sources (<strong>DS</strong>),
for example incoming and outgoing traffic on a specific communication
line. With the <strong>DS</strong> configuration option you must define some basic
<p>For COMPUTE data sources, the format is:</p>
<p><strong>DS:</strong><em>ds-name</em><strong>:</strong><em>COMPUTE</em><strong>:</strong><em>rpn-expression</em></p>
<p>In order to decide which data source type to use, review the
<p>For COMPUTE data sources, the format is:</p>
<p><strong>DS:</strong><em>ds-name</em><strong>:</strong><em>COMPUTE</em><strong>:</strong><em>rpn-expression</em></p>
<p>In order to decide which data source type to use, review the
-definitions that follow. Also consult the section on ``HOW TO MEASURE''
+definitions that follow. Also consult the section on "HOW TO MEASURE"
for further insight.</p>
<dl>
for further insight.</p>
<dl>
-<dt><strong><a name="item_gauge"><strong>GAUGE</strong></a></strong><br />
-</dt>
+<dt><strong><a name="gauge" class="item"><strong>GAUGE</strong></a></strong></dt>
+
<dd>
<dd>
-is for things like temperatures or number of people in a room or the
-value of a RedHat share.
+<p>is for things like temperatures or number of people in a room or the
+value of a RedHat share.</p>
</dd>
</dd>
-<p></p>
-<dt><strong><a name="item_counter"><strong>COUNTER</strong></a></strong><br />
-</dt>
+<dt><strong><a name="counter" class="item"><strong>COUNTER</strong></a></strong></dt>
+
<dd>
<dd>
-is for continuous incrementing counters like the ifInOctets counter in
+<p>is for continuous incrementing counters like the ifInOctets counter in
a router. The <strong>COUNTER</strong> data source assumes that the counter never
decreases, except when a counter overflows. The update function takes
the overflow into account. The counter is stored as a per-second
rate. When the counter overflows, RRDtool checks if the overflow
happened at the 32bit or 64bit border and acts accordingly by adding
a router. The <strong>COUNTER</strong> data source assumes that the counter never
decreases, except when a counter overflows. The update function takes
the overflow into account. The counter is stored as a per-second
rate. When the counter overflows, RRDtool checks if the overflow
happened at the 32bit or 64bit border and acts accordingly by adding
-an appropriate value to the result.
+an appropriate value to the result.</p>
</dd>
</dd>
-<p></p>
-<dt><strong><a name="item_derive"><strong>DERIVE</strong></a></strong><br />
-</dt>
+<dt><strong><a name="derive" class="item"><strong>DERIVE</strong></a></strong></dt>
+
<dd>
<dd>
-will store the derivative of the line going from the last to the
+<p>will store the derivative of the line going from the last to the
current value of the data source. This can be useful for gauges, for
example, to measure the rate of people entering or leaving a
room. Internally, derive works exactly like COUNTER but without
overflow checks. So if your counter does not reset at 32 or 64 bit you
current value of the data source. This can be useful for gauges, for
example, to measure the rate of people entering or leaving a
room. Internally, derive works exactly like COUNTER but without
overflow checks. So if your counter does not reset at 32 or 64 bit you
-might want to use DERIVE and combine it with a MIN value of 0.
-</dd>
-<dd>
+might want to use DERIVE and combine it with a MIN value of 0.</p>
<p><strong>NOTE on COUNTER vs DERIVE</strong></p>
<p><strong>NOTE on COUNTER vs DERIVE</strong></p>
-</dd>
-<dd>
<p>by Don Baarda <<a href="mailto:don.baarda@baesystems.com">don.baarda@baesystems.com</a>></p>
<p>by Don Baarda <<a href="mailto:don.baarda@baesystems.com">don.baarda@baesystems.com</a>></p>
-</dd>
-<dd>
<p>If you cannot tolerate ever mistaking the occasional counter reset for a
<p>If you cannot tolerate ever mistaking the occasional counter reset for a
-legitimate counter wrap, and would prefer ``Unknowns'' for all legitimate
+legitimate counter wrap, and would prefer "Unknowns" for all legitimate
counter wraps and resets, always use DERIVE with min=0. Otherwise, using
COUNTER with a suitable max will return correct values for all legitimate
counter wraps and resets, always use DERIVE with min=0. Otherwise, using
COUNTER with a suitable max will return correct values for all legitimate
-counter wraps, mark some counter resets as ``Unknown'', but can mistake some
+counter wraps, mark some counter resets as "Unknown", but can mistake some
counter resets for a legitimate counter wrap.</p>
counter resets for a legitimate counter wrap.</p>
-</dd>
-<dd>
<p>For a 5 minute step and 32-bit counter, the probability of mistaking a
counter reset for a legitimate wrap is arguably about 0.8% per 1Mbps of
maximum bandwidth. Note that this equates to 80% for 100Mbps interfaces, so
<p>For a 5 minute step and 32-bit counter, the probability of mistaking a
counter reset for a legitimate wrap is arguably about 0.8% per 1Mbps of
maximum bandwidth. Note that this equates to 80% for 100Mbps interfaces, so
setting will eliminate the possibility of mistaking a reset for a counter
wrap.</p>
</dd>
setting will eliminate the possibility of mistaking a reset for a counter
wrap.</p>
</dd>
-<p></p>
-<dt><strong><a name="item_absolute"><strong>ABSOLUTE</strong></a></strong><br />
-</dt>
+<dt><strong><a name="absolute" class="item"><strong>ABSOLUTE</strong></a></strong></dt>
+
<dd>
<dd>
-is for counters which get reset upon reading. This is used for fast counters
+<p>is for counters which get reset upon reading. This is used for fast counters
which tend to overflow. So instead of reading them normally you reset them
after every read to make sure you have a maximum time available before the
next overflow. Another usage is for things you count like number of messages
which tend to overflow. So instead of reading them normally you reset them
after every read to make sure you have a maximum time available before the
next overflow. Another usage is for things you count like number of messages
-since the last update.
+since the last update.</p>
</dd>
</dd>
-<p></p>
-<dt><strong><a name="item_compute"><strong>COMPUTE</strong></a></strong><br />
-</dt>
+<dt><strong><a name="compute" class="item"><strong>COMPUTE</strong></a></strong></dt>
+
<dd>
<dd>
-is for storing the result of a formula applied to other data sources
+<p>is for storing the result of a formula applied to other data sources
in the <strong>RRD</strong>. This data source is not supplied a value on update, but
rather its Primary Data Points (PDPs) are computed from the PDPs of
the data sources according to the rpn-expression that defines the
formula. Consolidation functions are then applied normally to the PDPs
of the COMPUTE data source (that is the rpn-expression is only applied
to generate PDPs). In database software, such data sets are referred
in the <strong>RRD</strong>. This data source is not supplied a value on update, but
rather its Primary Data Points (PDPs) are computed from the PDPs of
the data sources according to the rpn-expression that defines the
formula. Consolidation functions are then applied normally to the PDPs
of the COMPUTE data source (that is the rpn-expression is only applied
to generate PDPs). In database software, such data sets are referred
-to as ``virtual'' or ``computed'' columns.
+to as "virtual" or "computed" columns.</p>
</dd>
</dd>
-<p></p></dl>
+</dl>
<p><em>heartbeat</em> defines the maximum number of seconds that may pass
between two updates of this data source before the value of the
data source is assumed to be <em>*UNKNOWN*</em>.</p>
<p><em>heartbeat</em> defines the maximum number of seconds that may pass
between two updates of this data source before the value of the
data source is assumed to be <em>*UNKNOWN*</em>.</p>
consolidate primary data points via an aggregate function: <strong>AVERAGE</strong>,
<strong>MIN</strong>, <strong>MAX</strong>, <strong>LAST</strong>.</p>
<dl>
consolidate primary data points via an aggregate function: <strong>AVERAGE</strong>,
<strong>MIN</strong>, <strong>MAX</strong>, <strong>LAST</strong>.</p>
<dl>
-<dt><strong><a name="item_average">AVERAGE</a></strong><br />
-</dt>
+<dt><strong><a name="average" class="item">AVERAGE</a></strong></dt>
+
<dd>
<dd>
-the average of the data points is stored.
+<p>the average of the data points is stored.</p>
</dd>
</dd>
-<p></p>
-<dt><strong><a name="item_min">MIN</a></strong><br />
-</dt>
+<dt><strong><a name="min" class="item">MIN</a></strong></dt>
+
<dd>
<dd>
-the smallest of the data points is stored.
+<p>the smallest of the data points is stored.</p>
</dd>
</dd>
-<p></p>
-<dt><strong><a name="item_max">MAX</a></strong><br />
-</dt>
+<dt><strong><a name="max" class="item">MAX</a></strong></dt>
+
<dd>
<dd>
-the largest of the data points is stored.
+<p>the largest of the data points is stored.</p>
</dd>
</dd>
-<p></p>
-<dt><strong><a name="item_last">LAST</a></strong><br />
-</dt>
+<dt><strong><a name="last" class="item">LAST</a></strong></dt>
+
<dd>
<dd>
-the last data points is used.
+<p>the last data points is used.</p>
</dd>
</dd>
-<p></p></dl>
+</dl>
<p>Note that data aggregation inevitably leads to loss of precision and
information. The trick is to pick the aggregate function such that the
<em>interesting</em> properties of your data is kept across the aggregation
<p>Note that data aggregation inevitably leads to loss of precision and
information. The trick is to pick the aggregate function such that the
<em>interesting</em> properties of your data is kept across the aggregation
<p>
</p>
<hr />
<p>
</p>
<hr />
-<h1><a name="aberrant_behavior_detection_with_holtwinters_forecasting">Aberrant Behavior Detection with Holt-Winters Forecasting</a></h1>
+<h1><a name="aberrant_behavior_detection_with_holt_winters_forecasting">Aberrant Behavior Detection with Holt-Winters Forecasting</a></h1>
<p>In addition to the aggregate functions, there are a set of specialized
functions that enable <strong>RRDtool</strong> to provide data smoothing (via the
Holt-Winters forecasting algorithm), confidence bands, and the
flagging aberrant behavior in the data source time series:</p>
<ul>
<p>In addition to the aggregate functions, there are a set of specialized
functions that enable <strong>RRDtool</strong> to provide data smoothing (via the
Holt-Winters forecasting algorithm), confidence bands, and the
flagging aberrant behavior in the data source time series:</p>
<ul>
-<li></li>
-<strong>RRA:</strong><em>HWPREDICT</em><strong>:</strong><em>rows</em><strong>:</strong><em>alpha</em><strong>:</strong><em>beta</em><strong>:</strong><em>seasonal period</em>[<strong>:</strong><em>rra-num</em>]
-<p></p>
-<li></li>
-<strong>RRA:</strong><em>MHWPREDICT</em><strong>:</strong><em>rows</em><strong>:</strong><em>alpha</em><strong>:</strong><em>beta</em><strong>:</strong><em>seasonal period</em>[<strong>:</strong><em>rra-num</em>]
-<p></p>
-<li></li>
-<strong>RRA:</strong><em>SEASONAL</em><strong>:</strong><em>seasonal period</em><strong>:</strong><em>gamma</em><strong>:</strong><em>rra-num</em>[<strong>:smoothing-window=</strong><em>fraction</em>]
-<p></p>
-<li></li>
-<strong>RRA:</strong><em>DEVSEASONAL</em><strong>:</strong><em>seasonal period</em><strong>:</strong><em>gamma</em><strong>:</strong><em>rra-num</em>[<strong>:smoothing-window=</strong><em>fraction</em>]
-<p></p>
-<li></li>
-<strong>RRA:</strong><em>DEVPREDICT</em><strong>:</strong><em>rows</em><strong>:</strong><em>rra-num</em>
-<p></p>
-<li></li>
-<strong>RRA:</strong><em>FAILURES</em><strong>:</strong><em>rows</em><strong>:</strong><em>threshold</em><strong>:</strong><em>window length</em><strong>:</strong><em>rra-num</em>
-<p></p></ul>
+<li>
+<p><strong>RRA:</strong><em>HWPREDICT</em><strong>:</strong><em>rows</em><strong>:</strong><em>alpha</em><strong>:</strong><em>beta</em><strong>:</strong><em>seasonal period</em>[<strong>:</strong><em>rra-num</em>]</p>
+</li>
+<li>
+<p><strong>RRA:</strong><em>MHWPREDICT</em><strong>:</strong><em>rows</em><strong>:</strong><em>alpha</em><strong>:</strong><em>beta</em><strong>:</strong><em>seasonal period</em>[<strong>:</strong><em>rra-num</em>]</p>
+</li>
+<li>
+<p><strong>RRA:</strong><em>SEASONAL</em><strong>:</strong><em>seasonal period</em><strong>:</strong><em>gamma</em><strong>:</strong><em>rra-num</em>[<strong>:smoothing-window=</strong><em>fraction</em>]</p>
+</li>
+<li>
+<p><strong>RRA:</strong><em>DEVSEASONAL</em><strong>:</strong><em>seasonal period</em><strong>:</strong><em>gamma</em><strong>:</strong><em>rra-num</em>[<strong>:smoothing-window=</strong><em>fraction</em>]</p>
+</li>
+<li>
+<p><strong>RRA:</strong><em>DEVPREDICT</em><strong>:</strong><em>rows</em><strong>:</strong><em>rra-num</em></p>
+</li>
+<li>
+<p><strong>RRA:</strong><em>FAILURES</em><strong>:</strong><em>rows</em><strong>:</strong><em>threshold</em><strong>:</strong><em>window length</em><strong>:</strong><em>rra-num</em></p>
+</li>
+</ul>
<p>These <strong>RRAs</strong> differ from the true consolidation functions in several ways.
First, each of the <strong>RRA</strong>s is updated once for every primary data point.
Second, these <strong>RRAs</strong> are interdependent. To generate real-time confidence
<p>These <strong>RRAs</strong> differ from the true consolidation functions in several ways.
First, each of the <strong>RRA</strong>s is updated once for every primary data point.
Second, these <strong>RRAs</strong> are interdependent. To generate real-time confidence
@@ -366,21 +360,22 @@ index in the order of <strong>RRA</strong> creation (that is, the order they app
in the <em>create</em> command). The dependent <strong>RRA</strong> for each <strong>RRA</strong>
requiring the <em>rra-num</em> argument is listed here:</p>
<ul>
in the <em>create</em> command). The dependent <strong>RRA</strong> for each <strong>RRA</strong>
requiring the <em>rra-num</em> argument is listed here:</p>
<ul>
-<li></li>
-HWPREDICT <em>rra-num</em> is the index of the SEASONAL <strong>RRA</strong>.
-<p></p>
-<li></li>
-SEASONAL <em>rra-num</em> is the index of the HWPREDICT <strong>RRA</strong>.
-<p></p>
-<li></li>
-DEVPREDICT <em>rra-num</em> is the index of the DEVSEASONAL <strong>RRA</strong>.
-<p></p>
-<li></li>
-DEVSEASONAL <em>rra-num</em> is the index of the HWPREDICT <strong>RRA</strong>.
-<p></p>
-<li></li>
-FAILURES <em>rra-num</em> is the index of the DEVSEASONAL <strong>RRA</strong>.
-<p></p></ul>
+<li>
+<p>HWPREDICT <em>rra-num</em> is the index of the SEASONAL <strong>RRA</strong>.</p>
+</li>
+<li>
+<p>SEASONAL <em>rra-num</em> is the index of the HWPREDICT <strong>RRA</strong>.</p>
+</li>
+<li>
+<p>DEVPREDICT <em>rra-num</em> is the index of the DEVSEASONAL <strong>RRA</strong>.</p>
+</li>
+<li>
+<p>DEVSEASONAL <em>rra-num</em> is the index of the HWPREDICT <strong>RRA</strong>.</p>
+</li>
+<li>
+<p>FAILURES <em>rra-num</em> is the index of the DEVSEASONAL <strong>RRA</strong>.</p>
+</li>
+</ul>
<p><em>threshold</em> is the minimum number of violations (observed values outside
the confidence bounds) within a window that constitutes a failure. If the
FAILURES <strong>RRA</strong> is implicitly created, the default value is 7.</p>
<p><em>threshold</em> is the minimum number of violations (observed values outside
the confidence bounds) within a window that constitutes a failure. If the
FAILURES <strong>RRA</strong> is implicitly created, the default value is 7.</p>
It may help you to sort out why all this *UNKNOWN* data is popping
up in your databases:</p>
<p>RRDtool gets fed samples/updates at arbitrary times. From these it builds Primary
It may help you to sort out why all this *UNKNOWN* data is popping
up in your databases:</p>
<p>RRDtool gets fed samples/updates at arbitrary times. From these it builds Primary
-Data Points (PDPs) on every ``step'' interval. The PDPs are
+Data Points (PDPs) on every "step" interval. The PDPs are
then accumulated into the RRAs.</p>
then accumulated into the RRAs.</p>
-<p>The ``heartbeat'' defines the maximum acceptable interval between
-samples/updates. If the interval between samples is less than ``heartbeat'',
+<p>The "heartbeat" defines the maximum acceptable interval between
+samples/updates. If the interval between samples is less than "heartbeat",
then an average rate is calculated and applied for that interval. If
then an average rate is calculated and applied for that interval. If
-the interval between samples is longer than ``heartbeat'', then that
-entire interval is considered ``unknown''. Note that there are other
-things that can make a sample interval ``unknown'', such as the rate
+the interval between samples is longer than "heartbeat", then that
+entire interval is considered "unknown". Note that there are other
+things that can make a sample interval "unknown", such as the rate
exceeding limits, or a sample that was explicitly marked as unknown.</p>
exceeding limits, or a sample that was explicitly marked as unknown.</p>
-<p>The known rates during a PDP's ``step'' interval are used to calculate
-an average rate for that PDP. If the total ``unknown'' time accounts for
-more than <strong>half</strong> the ``step'', the entire PDP is marked
-as ``unknown''. This means that a mixture of known and ``unknown'' sample
-times in a single PDP ``step'' may or may not add up to enough ``known''
-time to warrent for a known PDP.</p>
-<p>The ``heartbeat'' can be short (unusual) or long (typical) relative to
-the ``step'' interval between PDPs. A short ``heartbeat'' means you
+<p>The known rates during a PDP's "step" interval are used to calculate
+an average rate for that PDP. If the total "unknown" time accounts for
+more than <strong>half</strong> the "step", the entire PDP is marked
+as "unknown". This means that a mixture of known and "unknown" sample
+times in a single PDP "step" may or may not add up to enough "known"
+time to warrant a known PDP.</p>
+<p>The "heartbeat" can be short (unusual) or long (typical) relative to
+the "step" interval between PDPs. A short "heartbeat" means you
require multiple samples per PDP, and if you don't get them mark the
require multiple samples per PDP, and if you don't get them mark the
-PDP unknown. A long heartbeat can span multiple ``steps'', which means
+PDP unknown. A long heartbeat can span multiple "steps", which means
it is acceptable to have multiple PDPs calculated from a single
it is acceptable to have multiple PDPs calculated from a single
-sample. An extreme example of this might be a ``step'' of 5 minutes and a
-``heartbeat'' of one day, in which case a single sample every day will
+sample. An extreme example of this might be a "step" of 5 minutes and a
+"heartbeat" of one day, in which case a single sample every day will
result in all the PDPs for that entire day period being set to the
same average rate. <em>-- Don Baarda <<a href="mailto:don.baarda@baesystems.com">don.baarda@baesystems.com</a>></em></p>
<pre>
result in all the PDPs for that entire day period being set to the
same average rate. <em>-- Don Baarda <<a href="mailto:don.baarda@baesystems.com">don.baarda@baesystems.com</a>></em></p>
<pre>
@@ -464,21 +459,20 @@ same average rate. <em>-- Don Baarda <<a href="mailto:don.baarda@baesystems.c
<h1><a name="how_to_measure">HOW TO MEASURE</a></h1>
<p>Here are a few hints on how to measure:</p>
<dl>
<h1><a name="how_to_measure">HOW TO MEASURE</a></h1>
<p>Here are a few hints on how to measure:</p>
<dl>
-<dt><strong><a name="item_temperature">Temperature</a></strong><br />
-</dt>
+<dt><strong><a name="temperature" class="item">Temperature</a></strong></dt>
+
<dd>
<dd>
-Usually you have some type of meter you can read to get the temperature.
+<p>Usually you have some type of meter you can read to get the temperature.
The temperature is not really connected with a time. The only connection is
that the temperature reading happened at a certain time. You can use the
<strong>GAUGE</strong> data source type for this. RRDtool will then record your reading
The temperature is not really connected with a time. The only connection is
that the temperature reading happened at a certain time. You can use the
<strong>GAUGE</strong> data source type for this. RRDtool will then record your reading
-together with the time.
+together with the time.</p>
</dd>
</dd>
-<p></p>
-<dt><strong><a name="item_mail_messages">Mail Messages</a></strong><br />
-</dt>
+<dt><strong><a name="mail_messages" class="item">Mail Messages</a></strong></dt>
+
<dd>
<dd>
-Assume you have a method to count the number of messages transported by
-your mailserver in a certain amount of time, giving you data like '5
+<p>Assume you have a method to count the number of messages transported by
+your mail server in a certain amount of time, giving you data like '5
messages in the last 65 seconds'. If you look at the count of 5 like an
<strong>ABSOLUTE</strong> data type you can simply update the RRD with the number 5 and the
end time of your monitoring period. RRDtool will then record the number of
messages in the last 65 seconds'. If you look at the count of 5 like an
<strong>ABSOLUTE</strong> data type you can simply update the RRD with the number 5 and the
end time of your monitoring period. RRDtool will then record the number of
messages transported in a day, you can get the average messages per second
from RRDtool for the day in question and multiply this number with the
number of seconds in a day. Because all math is run with Doubles, the
messages transported in a day, you can get the average messages per second
from RRDtool for the day in question and multiply this number with the
number of seconds in a day. Because all math is run with Doubles, the
-precision should be acceptable.
+precision should be acceptable.</p>
</dd>
</dd>
-<p></p>
-<dt><strong><a name="item_it_27s_always_a_rate">It's always a Rate</a></strong><br />
-</dt>
+<dt><strong><a name="it_s_always_a_rate" class="item">It's always a Rate</a></strong></dt>
+
<dd>
<dd>
-RRDtool stores rates in amount/second for COUNTER, DERIVE and ABSOLUTE
+<p>RRDtool stores rates in amount/second for COUNTER, DERIVE and ABSOLUTE
data. When you plot the data, you will get on the y axis
amount/second which you might be tempted to convert to an absolute
amount by multiplying by the delta-time between the points. RRDtool
plots continuous data, and as such is not appropriate for plotting
data. When you plot the data, you will get on the y axis
amount/second which you might be tempted to convert to an absolute
amount by multiplying by the delta-time between the points. RRDtool
plots continuous data, and as such is not appropriate for plotting
-absolute amounts as for example ``total bytes'' sent and received in a
+absolute amounts as for example "total bytes" sent and received in a
router. What you probably want is plot rates that you can scale to
bytes/hour, for example, or plot absolute amounts with another tool
that draws bar-plots, where the delta-time is clear on the plot for
each point (such that when you read the graph you see for example GB
router. What you probably want is plot rates that you can scale to
bytes/hour, for example, or plot absolute amounts with another tool
that draws bar-plots, where the delta-time is clear on the plot for
each point (such that when you read the graph you see for example GB
-on the y axis, days on the x axis and one bar for each day).
+on the y axis, days on the x axis and one bar for each day).</p>
</dd>
</dd>
-<p></p></dl>
+</dl>
<p>
</p>
<hr />
<p>
</p>
<hr />
RRA:MIN:0.5:12:2400 \
RRA:MAX:0.5:12:2400 \
RRA:AVERAGE:0.5:12:2400</pre>
RRA:MIN:0.5:12:2400 \
RRA:MAX:0.5:12:2400 \
RRA:AVERAGE:0.5:12:2400</pre>
-<p>This sets up an <strong>RRD</strong> called <em>temperature.rrd</em> which accepts one
+<p>This sets up an <strong>RRD</strong> called <em class="file">temperature.rrd</em> which accepts one
temperature value every 300 seconds. If no new data is supplied for
more than 600 seconds, the temperature becomes <em>*UNKNOWN*</em>. The
minimum acceptable value is -273 and the maximum is 5'000.</p>
temperature value every 300 seconds. If no new data is supplied for
more than 600 seconds, the temperature becomes <em>*UNKNOWN*</em>. The
minimum acceptable value is -273 and the maximum is 5'000.</p>