Copyright (c) 2014 Basho Technologies, Inc. All Rights Reserved.
Version: Apr 17 2015 14:08:02
Authors: Ulf Wiger (ulf.wiger@feuerlabs.com
), Magnus Feuer (magnus.feuer@feuerlabs.com
).
The Exometer Core package allows for easy and efficient instrumentation of Erlang code, allowing crucial data on system performance to be exported to a wide variety of monitoring systems.
Exometer Core comes with a set of pre-defined monitor components, and can be expanded with custom components to handle new types of Metrics, as well as integration with additional external systems such as databases, load balancers, etc.
This document gives a high level overview of the Exometer system. For
details, please see the documentation for individual modules, starting
with exometer
.
Note the section on Dependency Management for how to deal with optional packages, both users and developers.
- Concept and definitions
- Built-in entries and probes
- Built in Reporters
- Instrumenting Erlang code
- Configuring Exometer Core
- Creating custom exometer entries
- Creating custom probes
- Creating custom reporter plugins
- Dependency management
Exometer Core introduces a number of concepts and definitions used throughout the documentation and the code.
A metric is a specific measurement sampled inside an Erlang system and then reported to the Exometer Core system. An example metric would be "transactions_per_second", or "memory_usage".
Metrics are identified by a list of terms, such as given below:
[ xml_front_end, parser, file_size ]
A metric is created through a call by the code to be instrumented to
exometer:new()
. Once created, the metric can be updated through
exometer:update()
, or on its own initiative through the
exometer_probe:sample
behavior implementation.
Each metric can consist of multiple data points, where each point has a specific value.
A typical example of data points would be a
transactions_per_second
(tps) metric, usually stored as a
histogram covering the last couple of minutes of tps samples. Such a
histogram would host multiple values, such as min
, max
,
median
, mean
, 50_percentile
, 75_percentile
,
etc.
It is up to the type of the metric, and the data probe backing that type (see below), to specify which data points are available under the given metric.
The type of a metric, specified when the metric is created through
exometer:new()
, determines which exometer_entry
callback to use.
The link between the type and the entry to use is configured
through the exometer_admin
module, and its associated exometer
defaults configuration data.
The metric type, in other words, is only used to map a metric to a
configurable exometer_entry
callback.
An exometer entry callback will receive values reported to a metric through the
exometer:update()
call and compile it into one or more data points.
The entry callback can either be a counter (implemented natively
in exometer
), or a more complex statistical analysis such
as a uniform distribution or a regular histogram.
The various outputs from these entries are reported as data points under the given metric.
An entry can also interface external analytics packages.
exometer_folsom
, for example, integrates with the
folsom_metrics
package found at https://github.com/boundary/folsom
.
Probes are a further specialization of exometer entries that run in
their own Erlang processes and have their own state (like a
gen_server). A probe is implemented through the exometer_probe
behavior.
A probe can be used if independent monitoring is needed of,
for example, /proc
trees, network interfaces, and other subsystems
that need periodic sampling. In these cases, the
exometer_probe:probe_sample()
call is invoked regularly by exometer,
in the probe's own process, in order to extract data from
the given subsystem and add it to the metric's data points.
Metric and data point values are read with the exometer:get_value()
function. In the case of counters, this operation is very fast. With probes,
the call results in a synchronous dialog with the probe process, and the
cost of serving the request depends on the probe implementation and the
nature of the metric being served.
If the cost of reading the value is so high that calling the function often
would result in prohibitive load, it is possible to cache the value. This is
done either explicitly from the probe itself (by calling
exometer_cache:write()
), or by specifying the option {cache, Lifetime}
for the entry. If an entry has a non-zero cache lifetime specified, the
get_value()
call will try fetching the cached value before calling the
actual entry and automatically caching the result.
Note that if {cache, Lifetime}
is not specified, exometer:get_value()
will neither read nor write to the cache. It is possible for the probe
to periodically cache a value regardless of how the cache lifetime is set,
and the probe may also explicitly read from the cache if it isn't done
automatically.
The subscription concept, managed by exometer_report
allows metrics
and their data points to be sampled at given intervals and delivered
to one or more recipients, which can be either an arbitrary process
or a Reporter plugin.
Each subscription ties a specific metric-datapoint pair to a reporter
and an interval (given in milliseconds). The reporter system will, at
the given interval, send the current value of the data point to the
subscribing reporter. The subscription, with all its parameters,
is setup through a call to exometer_report:subscribe()
.
In the case of processes, subscribed-to values will be delivered as a
message. Modules, which implement the exometer_report
callback
behavior, will receive the plugins as a callbacks within the
exometer_report
process.
Subscriptions can either be setup at runtime, through
exometer_report:subscribe()
calls, or statically through the
exometer_report
configuration data.
There are a number of built-in entries and probes shipped with the Exometer Core package, as described below:
The counter is implemented directly in exometer
to provide simple
counters. A call to exometer:update()
will add the provided value
to the counter.
The counter can be reset to zero through exometer:reset()
.
The available data points under a metric using the counter entry
are value
and ms_since_reset
.
A fast counter implements the counter functionality, through the
trace_info
system, yielding a speed increase of about 3.5 in
comparison to the regular counter.
The tradeoff is that running tracing and/or debugging may interfere with the counter functionality.
A call to exometer:update()
will add the provided value to the
counter.
The counter can be reset to zero through exometer:reset()
.
The available data points under a metric using the fast_counter
entry are value
and ms_since_reset
.
The gauge is implemented directly in exometer
to provide simple
gauges. A call to exometer:update()
will set the gauge's value
to the provided value. That is, the value of the gauge entry is
always the most recently provided value.
The gauge can be reset to zero through exometer:reset()
.
The available data points under a metric using the gauge entry
are value
and ms_since_reset
.
The histogram probe stores a given number of updates, provided through
exometer:update()
, in a histogram. The histogram maintains a log
derived from all values received during a configurable time span and
provides min, max, median, mean, and percentile analysis data points
for the stored data.
In order to save memory, the histogram is divided into equal-sized time slots, where each slot spans a settable interval. All values received during a time slot will be averaged into a single value to be stored in the histogram once the time slot expires. The averaging function (which can be replaced by the caller), allows for high-frequency update metrics to have their resolution traded against resource consumption.
The uniform probe provides a uniform sample over a pool of values
provided through exometer:update()
. When the pool reaches its configurable
max size, existing values will be replaced at random to make space for
new values. Much like exometer_histogram
, the uniform probe
provides min, max, median, mean, and percentile analysis data points
for the stored data.
The spiral probe maintains the total sum of all values stored in its
histogram. The histogram has a configurable time span, all values
provided to the probe, through exometer:update()
, within that time
span will be summed up and reported. If, for example, the histogram
covers 60 seconds, the spiral probe will report the sum of all
values reported during the last minute.
The grand total of all values received during the lifetime of the probe is also available.
The folsom entry integrates with the folsom metrics package provided by the boundary repo at github. Updated values sent to the folsom entry can be forwarded to folsom's counter, histogram, duration, meter, and spiral.
Folsom integration is provided as a backup. New code using Exometer Core should use the native probes that duplicate folsom.
The function entry allows for a simple caller-supplied function to be
invoked in order to retrieve non-exometer data. The
exometer_function:get_value()
function will invoke a
Module:Function(DataPoints)
call, where Module
and
Function
are provided by the caller.
The function entry provides an easy way of integrating an external system without having to write a complete entry.
Exometer Core ships with some built-in reporters which can be used to forward updated metrics and their data points to external systems. They can also serve as templates for custom-developed reporters.
The exometer_report_tty
reporter is mainly intended for experimentation.
It outputs reports directly to the tty.
The code using Exometer Core needs to be instrumented in order to setup and use metrics reporting.
The system using Exometer Core must start the exometer
application
prior to using it:
application:start(lager),
application:start(exometer_core).
Note that dependent applications need to be started first. On newer OTP versions
(R61B or later), you can use application:ensure_all_started(exometer)
.
For testing, you can also use exometer:start/0
.
If you make use of e.g. folsom metrics, you also need to start folsom
.
Exometer Core will not do that automatically, nor does it contain an
application dependency for it.
See Configuring Exometer Core for details on configuration data format.
A metric, can be created throuh a call to
exometer:new(Name, Type)
Name
is a list of atoms, uniquely identifying the metric created.
The type of the metric, specified by Type
will be mapped
to an exometer entry through the table maintained by
exometer_admin
Please see the Configuring type - entry
maps for details.
The resolved entry to use will determine the data points available under the given metric.
A metric previously created with exometer:new()
can be deleted by
exometer:delete()
.
All subscriptions to the deleted metrics will be cancelled.
A created metric can have its value updated through the
exometer:update()
function:
exometer:update(Name, Value)
The Name
parameter is the same atom list provided to a previous
exometer:new()
call. The Value
is an arbitrarty element that is
forwarded to the exometer:update()
function of the entry/probe that the
metric is mapped to.
The receiving entry/probe will process the provided value and modify its data points accordingly.
Exometer-using code can at any time retrieve the data point values associated with a previously created metric. In order to find out which data points are available for a metric, the following call can be used:
exometer:info(Name, datapoints)
The Name
parameter is the same atom list provided to a previous
exometer:new()
call. The call will return a list of data point
atoms that can then be provided to exometer:get_value()
to
retrieve their actual value:
exometer:get_value(Name, DataPoint)
The Name
paramer identifies the metric, and DataPoints
identifies the data points (returned from the previous info()
call)
to retrieve the value for.
If no DataPoints are provided, the values of a default list of data points, determined by the backing entry / probe, will be returned.
A subscription can either be statically configured, or dynamically setup from within the code using Exometer Core. For details on statically configured subscriptions, please see Configuring static subscriptions.
A dynamic subscription can be setup with the following call:
exometer_report:subscribe(Recipient, Metric, DataPoint, Inteval)
Recipient
is the name of a reporter.
Each created metric can have options setup for it through the following call:
exometer:setopts(Name, Options)
The Name
paramer identifies the metric to set the options for, and
Options is a proplist ([{ Key, Value },...]
) with the options to be
set.
Exometer Core looks up the the backing entry that hosts the metric with
the given Name, and will invoke the entry's setopts/4
function to set
the actual options. Please see the setopts/4
function for the various
entries for details.
Exometer Core defaults can be changed either through OTP application environment
variables or through the use of Basho's cuttlefish
(https://github.com/basho/cuttlefish
).
Note: Exometer Core will check both the exometer
and the exometer_core
application environments. The exometer
environment overrides the
exometer_core
environment. However, if only exometer_core
is used, any
exometer
environment will simply be ignored. This is because of the
application controller: environment data is not loaded until the application
in question is loaded.
The dynamic method of configuring defaults for exometer
entries is:
exometer_admin:set_default(NamePattern, Type, Default)
Where NamePattern
is a list of terms describing what is essentially
a name prefix with optional wildcards ('_'
). A pattern that
matches any legal name is ['_']
.
Type
is an atom defining a type of metric. The types already known to
exometer
, counter
, fast_counter
, ticker
, uniform
, histogram
,
spiral
, netlink
, and probe
may be redefined, but other types can be
described as well.
Default
is either an #exometer_entry{}
record (unlikely), or a list of
{Key, Value}
options, where the keys correspond to #exometer_entry
record
attribute names. The following attributes make sense to preset:
{module, atom()} % the callback module
{status, enabled | disabled} % operational status of the entry
{cache, non_neg_integer()} % cache lifetime (ms)
{options, [{atom(), any()}]} % entry-specific options
Below is an example, from exometer_core/priv/app.config
:
{exometer, [
{defaults, [
{['_'], function , [{module, exometer_function}]},
{['_'], counter , [{module, exometer}]},
{['_'], histogram, [{module, exometer_histogram}]},
{['_'], spiral , [{module, exometer_spiral}]},
{['_'], duration , [{module, exometer_folsom}]},
{['_'], meter , [{module, exometer_folsom}]},
{['_'], gauge , [{module, exometer_folsom}]}
]}
]}
In systems that use CuttleFish, the file exometer/priv/exometer.schema
contains a schema for default settings. The setup corresponding to the above
defaults would be as follows:
exometer.template.function.module = exometer_function
exometer.template.counter.module = exometer
exometer.template.histogram.module = exometer_histogram
exometer.template.spiral.module = exometer_spiral
exometer.template.duration.module = exometer_folsom
exometer.template.meter.module = exometer_folsom
exometer.template.gauge.module = exometer_folsom
Using the exometer
environment variable predefined
, entries can be added
at application startup. The variable should have one of the following values:
-
{script, File}
-File
will be processed usingfile:script/2
. The return value (the result of the last expression in the script) should be a list of{Name, Type, Options}
tuples. -
{apply, M, F, A}
- The result ofapply(M, F, A)
should be{ok, L}
whereL
is a list of{Name, Type, Options}
tuples. -
L
, where L is a list of{Name, Type, Options}
tuples or extended instructions (see below).
The list of instructions may include:
-
{delete, Name}
- deletesName
from the exometer registry. -
{select_delete, Pattern}
- applies a select pattern and deletes all matching entries. -
{re_register, {Name, Type, Options}}
- redefines an entry if present, otherwise creates it.
Exometer Core will also scan all loaded applications for the environment
variables exometer_defaults
and exometer_predefined
, and process
as above. If an application is loaded and started after exometer has started,
it may call the function exometer:register_application()
or
exometer:register_application(App)
. This function will do nothing if
exometer isn't already running, and otherwise process the exometer_defaults
and exometer_predefined
variables as above. The function can also be
called during upgrade, as it will re-apply the settings each time.
Static subscriptions, which are automatically setup at exometer
startup without having to invoke exometer_report:subscribe()
, are
configured through the report sub section under exometer.
Below is an example, from exometer/priv/app.config
:
{exometer, [
{report, [
{subscribers, [
{exometer_report_collectd, [db, cache, hits], mean, 2000, true},
{exometer_report_collectd, [db, cache, hits], max, 5000, false}
]}
]}
]}
The report
section configures static subscriptions and reporter
plugins. See Configuring reporter plugins for details on
how to configure individual plugins.
The subscribers
sub-section contains all static subscriptions to be
setup att exometer applications start. Each tuple in the prop list
should be of one of the following formats:
-
{Reporter, Metric, DataPoint, Interval}
-
{Reporter, Metric, DataPoint, Interval, RetryFailedMetrics}
-
{Reporter, Metric, DataPoint, Interval, RetryFailedMetrics, Extra}
-
{apply, {M, F, A}}
-
{select, {MatchPattern, DataPoint, Interval [, Retry [, Extra] ]}}
In the case of {apply, M, F, A}
, the result of apply(M, F, A)
must
be a list of subscribers
tuples.
In the case of {select, Expr}
, a list of metrics is fetched using
exometer:select(MatchPattern)
, where the result must be on the form
{Key, Type, Status}
(i.e. what corresponds to '$_'
).
The rest of the items will be applied to each of the matching entries.
The meaning of the above tuple elements is:
-
Reporter :: module()
Specifies the reporter plugin module, such asexometer_report_collectd
that is to receive updated metric's data points. -
Metric :: [atoms()]
Specifies the path to a metric previously created with anexometer:new()
call. -
DataPoint
:: atom() | [atom()]'
Specifies the data point within the given metric to send to the receiver. The data point must match one of the data points returned byexometer:info(Name, datapoints)
for the given metrics name. -
Interval
:: integer()' (milliseconds)
Specifies the interval, in milliseconds, between each update of the given metric's data point. At the given interval, the data point will be samples, and the result will be sent to the receiver. -
RetryFailedMetrics :: boolean()
Specifies if the metric should be continued to be reported even if it is not found during a reporting cycle. This would be the case if a metric is not created by the time it is reported for the first time. If the metric will be created at a later time, this value should be set to true. Set this value to false if all attempts to report the metric should stop if when is not found. The default value istrue
. -
Extra :: any()
Provides a means to pass along extra information for a given subscription. An example is thesyntax
option for the SNMP reporter, in which caseExtra
needs to be a property list.
Example configuration in sys.config, using the {select, Expr}
pattern:
[
{exometer, [
{predefined,
[{[a,1], counter, []},
{[a,2], counter, []},
{[b,1], counter, []},
{[c,1], counter, []}]},
{report,
[
{reporters,
[{exometer_report_tty, []}]},
{subscribers,
[{select, {[{ {[a,'_'],'_','_'}, [], ['$_']}],
exometer_report_tty, value, 1000}}]}
]}
]}
].
This will activate a subscription on [a,1]
and [a,2]
in the
exometer_report_tty
reporter, firing once per second.
The various reporter plugins to be loaded by exometer are configured
in the report
section under reporters
Each reporter has an entry named after its module, and the content of that entry is dependent on the reporter itself. The following chapters specifies the configuration parameters for the reporters shipped with exometer.
Please see @see exometer_entry documentation for details.
Please see @see exometer_probe documentation for details.
Please see @see exometer_report documentation for details.
The OS environment variables EXOMETER_CORE_CONFIG_PREPROCESS
and
EXOMETER_CORE_CONFIG_POSTPROCESS
can be used to insert a script, similar to
rebar.config.script
in the processing flow of the exometer build.
As the names imply, the script given by EXOMETER_CONFIG_CONFIG_PREPROCESS
(if any) will be run before exometer does any processing of its own, and the
EXOMETER_CORE_CONFIG_POSTPROCESS
script (if any) will be run after all other
processing is complete.