StatsD is a system to collect data from any application. Applications send metrics to it, usually via non-blocking UDP communication, and StatsD servers collect these metrics, perform a few simple calculations on them and push them to backend time-series databases. If you want to learn more about the StatsD protocol, we have written a [blog post](https://www.netdata.cloud/blog/introduction-to-statsd/) about it! Netdata is a fully featured statsd server. It can collect statsd formatted metrics, visualize them on its dashboards and store them in it's database for long-term retention. Netdata statsd is inside Netdata (an internal plugin, running inside the Netdata daemon), it is configured via `netdata.conf` and by-default listens on standard statsd port 8125. Netdata supports both TCP and UDP packets at the same time. Since statsd is embedded in Netdata, it means you now have a statsd server embedded on all your servers. Netdata statsd is fast. It can collect several millions of metrics per second on modern hardware, using just 1 CPU core. The implementation uses two threads: one thread collects metrics, another thread updates the charts from the collected data. ## Available StatsD synthetic application charts Netdata ships with a few synthetic chart definitions to automatically present application metrics into a more uniform way. These synthetic charts are configuration files (you can create your own) that re-arrange statsd metrics into a more meaningful way. On synthetic charts, we can have alarms as with any metric and chart. - [K6 load testing tool](https://k6.io) - **Description:** k6 is a developer-centric, free and open-source load testing tool built for making performance testing a productive and enjoyable experience. - [Documentation](/collectors/statsd.plugin/k6.md) - [Configuration](https://github.com/netdata/netdata/blob/master/collectors/statsd.plugin/k6.conf) - [Asterisk](https://www.asterisk.org/) - **Description:** Asterisk is an Open Source PBX and telephony toolkit. - [Documentation](/collectors/statsd.plugin/asterisk.md) - [Configuration](https://github.com/netdata/netdata/blob/master/collectors/statsd.plugin/asterisk.conf) ## Metrics supported by Netdata Netdata fully supports the StatsD protocol and also extends it to support more advanced Netdata specific use cases. All StatsD client libraries can be used with Netdata too. - **Gauges** The application sends `name:value|g`, where `value` is any **decimal/fractional** number, StatsD reports the latest value collected and the number of times it was updated (events). The application may increment or decrement a previous value, by setting the first character of the value to `+` or `-` (so, the only way to set a gauge to an absolute negative value, is to first set it to zero). [Sampling rate](#sampling-rates) is supported. [Tags](#tags) are supported for changing chart units, family and dimension name. When a gauge is not collected and the setting is not to show gaps on the charts (the default), the last value will be shown, until a data collection event changes it. - **Counters** and **Meters** The application sends `name:value|c`, `name:value|C` or `name:value|m`, where `value` is a positive or negative **integer** number of events occurred, StatsD reports the **rate** and the number of times it was updated (events). `:value` can be omitted and StatsD will assume it is `1`. `|c`, `|C` and `|m` can be omitted and StatsD will assume it is `|m`. So, the application may send just `name` and StatsD will parse it as `name:1|m`. - Counters use `|c` (etsy/StatsD compatible) or `|C` (brubeck compatible) - Meters use `|m` [Sampling rate](#sampling-rates) is supported. [Tags](#tags) are supported for changing chart units, family and dimension name. When a counter or meter is not collected, StatsD **defaults** to showing a zero value, until a data collection event changes the value. - **Timers** and **Histograms** The application sends `name:value|ms` or `name:value|h`, where `value` is any **decimal/fractional** number, StatsD reports **min**, **max**, **average**, **95th percentile**, **median** and **standard deviation** and the total number of times it was updated (events). Internally it also calculates the **sum**, which is available for synthetic charts. - Timers use `|ms` - Histograms use `|h` The only difference between the two, is the `units` of the charts, as timers report *milliseconds*. [Sampling rate](#sampling-rates) is supported. [Tags](#tags) are supported for changing chart units and family. When a counter or meter is not collected, StatsD **defaults** to showing a zero value, until a data collection event changes the value. - **Sets** The application sends `name:value|s`, where `value` is anything (**number or text**, leading and trailing spaces are removed), StatsD reports the number of unique values sent and the number of times it was updated (events). Sampling rate is **not** supported for Sets. `value` is always considered text (so `01` and `1` are considered different). [Tags](#tags) are supported for changing chart units and family. When a set is not collected, Netdata **defaults** to showing a zero value, until a data collection event changes the value. - **Dictionaries** The application sends `name:value|d`, where `value` is anything (**number or text**, leading and trailing spaces are removed), StatsD reports the number of events sent for each `value` and the total times `name` was updated (events). Sampling rate is **not** supported for Dictionaries. `value` is always considered text (so `01` and `1` are considered different). [Tags](#tags) are supported for changing chart units and family. When a set is not collected, Netdata **defaults** to showing a zero value, until a data collection event changes the value. #### Sampling Rates The application may append `|@sampling_rate`, where `sampling_rate` is a number from `0.0` to `1.0` in order for StatD to extrapolate the value and predict the total for the entire period. If the application reports to StatsD a value for 1/10th of the time, it can append `|@0.1` to the metrics it sends to statsd. #### Tags The application may append `|#tag1:value1,tag2:value2,tag3:value3` etc, where `tagX` and `valueX` are strings. `:valueX` can be omitted. Currently, Netdata uses only 2 tags: * `units=string` which sets the units of the chart that is automatically generated * `family=string` which sets the family of the chart that is automatically generated (the family is the submenu of the dashboard) * `name=string` which sets the name of the dimension of the chart that is automatically generated (only for counters, meters, gauges) Other tags are parsed, but currently are ignored. Charts are not updated to change units or dimension names once they are created. So, either send the tags on every event, or use the special `zinit` value to initiaze the charts at the beginning. `zinit` is a special value that can be used on any chart, to have netdata initialize the charts, without actually setting any values to them. So, instead of sending `my.metric:VALUE|c|#units=bytes,name=size` every time, the application can send at the beginning `my.metric:zinit|c|#units=bytes,name=size` and then `my.metric:VALUE|c`. #### Overlapping metrics Netdata's StatsD server maintains different indexes for each of the metric types supported. This means the same metric `name` may exist under different types concurrently. #### How to name your metrics A good practice is to name your metrics like `application.operation.metric`, where: - `application` is the application name - Netdata will automatically create a dashboard section based on the first keyword of the metrics, so you can have all your applications in different sections. - `operation` is the operation your application is executing, like `dbquery`, `request`, `response`, etc. - `metric` is anything you want to name your metric as. Netdata will automatically append the metric type (meter, counter, gauge, set, dictionary, timer, histogram) to the generated chart. Using [Tags](#tags) you can also change the submenus of the dashboard, the units of the charts and for meters, counters and gauges, the name of dimension. So, you can have a usable default view without using [Synthetic StatsD charts](#synthetic-statsd-charts) #### Multiple metrics per packet Netdata accepts multiple metrics per packet if each is terminated with a newline (`\n`) at the end. #### TCP packets Netdata listens for both TCP and UDP packets. For TCP, is it important to always append `\n` on each metric, as Netdata will use the newline character to detect if a metric is split into multiple TCP packets. #### UDP packets When sending multiple metrics over a single UDP message, it is important not to exceed the network MTU, which is usually 1500 bytes. Netdata will accept UDP packets up to 9000 bytes, but the underlying network will not exceed MTU. > You can read more about the network maximum transmission unit(MTU) in this cloudflare [article](https://www.cloudflare.com/en-gb/learning/network-layer/what-is-mtu/). ## Configuration You can find the configuration at `/etc/netdata/netdata.conf`: ``` [statsd] # enabled = yes # decimal detail = 1000 # update every (flushInterval) = 1 # udp messages to process at once = 10 # create private charts for metrics matching = * # max private charts allowed = 200 # max private charts hard limit = 1000 # private charts memory mode = save # private charts history = 3996 # histograms and timers percentile (percentThreshold) = 95.00000 # add dimension for number of events received = no # gaps on gauges (deleteGauges) = no # gaps on counters (deleteCounters) = no # gaps on meters (deleteMeters) = no # gaps on sets (deleteSets) = no # gaps on histograms (deleteHistograms) = no # gaps on timers (deleteTimers) = no # listen backlog = 4096 # default port = 8125 # bind to = udp:localhost:8125 tcp:localhost:8125 ``` ### StatsD main config options - `enabled = yes|no` controls if StatsD will be enabled for this Netdata. The default is enabled. - `default port = 8125` controls the default port StatsD will use if no port is defined in the following setting. - `bind to = udp:localhost tcp:localhost` is a space separated list of IPs and ports to listen to. The format is `PROTOCOL:IP:PORT` - if `PORT` is omitted, the `default port` will be used. If `IP` is IPv6, it needs to be enclosed in `[]`. `IP` can also be `*` (to listen on all IPs) or even a hostname. - `update every (flushInterval) = 1` seconds, controls the frequency StatsD will push the collected metrics to Netdata charts. - `decimal detail = 1000` controls the number of fractional digits in gauges and histograms. Netdata collects metrics using signed 64-bit integers and their fractional detail is controlled using multipliers and divisors. This setting is used to multiply all collected values to convert them to integers and is also set as the divisors, so that the final data will be a floating point number with this fractional detail (1000 = X.0 - X.999, 10000 = X.0 - X.9999, etc). The rest of the settings are discussed below. ## StatsD charts Netdata can visualize StatsD collected metrics in 2 ways: 1. Each metric gets its own **private chart**. This is the default and does not require any configuration. You can adjust the default parameters. 2. **Synthetic charts** can be created, combining multiple metrics, independently of their metric types. For this type of charts, special configuration is required, to define the chart title, type, units, its dimensions, etc. ### Private metric charts Private charts are controlled with `create private charts for metrics matching = *`. This setting accepts a space-separated list of [simple patterns](/libnetdata/simple_pattern/README.md). Netdata will create private charts for all metrics **by default**. For example, to render charts for all `myapp.*` metrics, except `myapp.*.badmetric`, use: ``` create private charts for metrics matching = !myapp.*.badmetric myapp.* ``` You can specify Netdata StatsD to have a different `memory mode` than the rest of the Netdata Agent. You can read more about `memory mode` in the [documentation](/database/README.md). The default behavior is to use the same settings as the rest of the Netdata Agent. If you wish to change them, edit the following settings: - `private charts memory mode` - `private charts history` ### Optimize private metric charts visualization and storage If you have thousands of metrics, each with its own private chart, you may notice that your web browser becomes slow when you view the Netdata dashboard (this is a web browser issue we need to address at the Netdata UI). So, Netdata has a protection to stop creating charts when `max private charts allowed = 200` (soft limit) is reached. The metrics above this soft limit are still processed by Netdata, can be used in synthetic charts and will be available to be sent to backend time-series databases, up to `max private charts hard limit = 1000`. So, between 200 and 1000 charts, Netdata will still generate charts, but they will automatically be created with `memory mode = none` (Netdata will not maintain a database for them). These metrics will be sent to backend time series databases, if the backend configuration is set to `as collected`. Metrics above the hard limit are still collected, but they can only be used in synthetic charts (once a metric is added to chart, it will be sent to backend servers too). Example private charts (automatically generated without any configuration): #### Counters - Scope: **count the events of something** (e.g. number of file downloads) - Format: `name:INTEGER|c` or `name:INTEGER|C` or `name|c` - StatsD increments the counter by the `INTEGER` number supplied (positive, or negative). ![image](https://cloud.githubusercontent.com/assets/2662304/26131553/4a26d19c-3aa3-11e7-94e8-c53b5ed6ebc3.png) #### Gauges - Scope: **report the value of something** (e.g. cache memory used by the application server) - Format: `name:FLOAT|g` - StatsD remembers the last value supplied, and can increment or decrement the latest value if `FLOAT` begins with `+` or `-`. ![image](https://cloud.githubusercontent.com/assets/2662304/26131575/5d54e6f0-3aa3-11e7-9099-bc4440cd4592.png) #### histograms - Scope: **statistics on a size of events** (e.g. statistics on the sizes of files downloaded) - Format: `name:FLOAT|h` - StatsD maintains a list of all the values supplied and provides statistics on them. ![image](https://cloud.githubusercontent.com/assets/2662304/26131587/704de72a-3aa3-11e7-9ea9-0d2bb778c150.png) The same chart with `sum` unselected, to show the detail of the dimensions supported: ![image](https://cloud.githubusercontent.com/assets/2662304/26131598/8076443a-3aa3-11e7-9ffa-ea535aee9c9f.png) #### Meters This is identical to `counter`. - Scope: **count the events of something** (e.g. number of file downloads) - Format: `name:INTEGER|m` or `name|m` or just `name` - StatsD increments the counter by the `INTEGER` number supplied (positive, or negative). ![image](https://cloud.githubusercontent.com/assets/2662304/26131605/8fdf5a06-3aa3-11e7-963f-7ecf207d1dbc.png) #### Sets - Scope: **count the unique occurrences of something** (e.g. unique filenames downloaded, or unique users that downloaded files) - Format: `name:TEXT|s` - StatsD maintains a unique index of all values supplied, and reports the unique entries in it. ![image](https://cloud.githubusercontent.com/assets/2662304/26131612/9eaa7b1a-3aa3-11e7-903b-d881e9a35be2.png) #### Timers - Scope: **statistics on the duration of events** (e.g. statistics for the duration of file downloads) - Format: `name:FLOAT|ms` - StatsD maintains a list of all the values supplied and provides statistics on them. ![image](https://cloud.githubusercontent.com/assets/2662304/26131629/bc34f2d2-3aa3-11e7-8a07-f2fc94ba4352.png) ### Synthetic StatsD charts Use synthetic charts to create dedicated sections on the dashboard to render your StatsD charts. Synthetic charts are organized in - **application** aka section in Netdata Dashboard. - **charts for each application** aka family in Netdata Dashboard. - **StatsD metrics for each chart** /aka charts and context Netdata Dashboard. > You can read more about how the Netdata Agent organizes information in the relevant [documentation](/web/README.md) For each application you need to create a `.conf` file in `/etc/netdata/statsd.d`. For example, if you want to monitor the application `myapp` using StatsD and Netdata, create the file `/etc/netdata/statsd.d/myapp.conf`, with this content: ``` [app] name = myapp metrics = myapp.* private charts = no gaps when not collected = no history = 60 # memory mode = ram [dictionary] m1 = metric1 m2 = metric2 # replace 'mychart' with the chart id # the chart will be named: myapp.mychart [mychart] name = mychart title = my chart title family = my family context = chart.context units = tests/s priority = 91000 type = area dimension = myapp.metric1 m1 dimension = myapp.metric2 m2 ``` Using the above configuration `myapp` should get its own section on the dashboard, having one chart with 2 dimensions. `[app]` starts a new application definition. The supported settings in this section are: - `name` defines the name of the app. - `metrics` is a Netdata [simple pattern](/libnetdata/simple_pattern/README.md). This pattern should match all the possible StatsD metrics that will be participating in the application `myapp`. - `private charts = yes|no`, enables or disables private charts for the metrics matched. - `gaps when not collected = yes|no`, enables or disables gaps on the charts of the application in case that no metrics are collected. - `memory mode` sets the memory mode for all charts of the application. The default is the global default for Netdata (not the global default for StatsD private charts). We suggest not to use this (we have commented it out in the example) and let your app use the global default for Netdata, which is our dbengine. - `history` sets the size of the round robin database for this application. The default is the global default for Netdata (not the global default for StatsD private charts). This is only relevant if you use `memory mode = save`. Read more on our [metrics storage(]/docs/store/change-metrics-storage.md) doc. `[dictionary]` defines name-value associations. These are used to renaming metrics, when added to synthetic charts. Metric names are also defined at each `dimension` line. However, using the dictionary dimension names can be declared globally, for each app and is the only way to rename dimensions when using patterns. Of course the dictionary can be empty or missing. Then, add any number of charts. Each chart should start with `[id]`. The chart will be called `app_name.id`. `family` controls the submenu on the dashboard. `context` controls the alarm templates. `priority` controls the ordering of the charts on the dashboard. The rest of the settings are informational. Add any number of metrics to a chart, using `dimension` lines. These lines accept 5 space separated parameters: 1. the metric name, as it is collected (it has to be matched by the `metrics =` pattern of the app) 2. the dimension name, as it should be shown on the chart 3. an optional selector (type) of the value to shown (see below) 4. an optional multiplier 5. an optional divider 6. optional flags, space separated and enclosed in quotes. All the external plugins `DIMENSION` flags can be used. Currently the only usable flag is `hidden`, to add the dimension, but not show it on the dashboard. This is usually needed to have the values available for percentage calculation, or use them in alarms. So, the format is this: ``` dimension = [pattern] METRIC NAME TYPE MULTIPLIER DIVIDER OPTIONS ``` `pattern` is a keyword. When set, `METRIC` is expected to be a Netdata [simple pattern](/libnetdata/simple_pattern/README.md) that will be used to match all the StatsD metrics to be added to the chart. So, `pattern` automatically matches any number of StatsD metrics, all of which will be added as separate chart dimensions. `TYPE`, `MULTIPLIER`, `DIVIDER` and `OPTIONS` are optional. `TYPE` can be: - `events` to show the number of events received by StatsD for this metric - `last` to show the last value, as calculated at the flush interval of the metric (the default) Then for histograms and timers the following types are also supported: - `min`, show the minimum value - `max`, show the maximum value - `sum`, show the sum of all values - `average` (same as `last`) - `percentile`, show the 95th percentile (or any other percentile, as configured at StatsD global config) - `median`, show the median of all values (i.e. sort all values and get the middle value) - `stddev`, show the standard deviation of the values #### Example synthetic charts StatsD metrics: `foo` and `bar`. Contents of file `/etc/netdata/stats.d/foobar.conf`: ``` [app] name = foobarapp metrics = foo bar private charts = yes [foobar_chart1] title = Hey, foo and bar together family = foobar_family context = foobarapp.foobars units = foobars type = area dimension = foo 'foo me' last 1 1 dimension = bar 'bar me' last 1 1 ``` Metrics sent to statsd: `foo:10|g` and `bar:20|g`. Private charts: ![screenshot from 2017-08-03 23-28-19](https://user-images.githubusercontent.com/2662304/28942295-7c3a73a8-78a3-11e7-88e5-a9a006bb7465.png) Synthetic chart: ![screenshot from 2017-08-03 23-29-14](https://user-images.githubusercontent.com/2662304/28942317-958a2c68-78a3-11e7-853f-32850141dd36.png) #### Renaming StatsD synthetic charts' metrics You can define a dictionary to rename metrics sent by StatsD clients. This enables you to send response `"200"` and Netdata visualize it as `succesful connection` The `[dictionary]` section accepts any number of `name = value` pairs. Netdata uses this dictionary as follows: 1. When a `dimension` has a non-empty `NAME`, that name is looked up at the dictionary. 2. If the above lookup gives nothing, or the `dimension` has an empty `NAME`, the original StatsD metric name is looked up at the dictionary. 3. If any of the above succeeds, Netdata uses the `value` of the dictionary, to set the name of the dimension. The dimensions will have as ID the original StatsD metric name, and as name, the dictionary value. Use the dictionary in 2 ways: 1. set `dimension = myapp.metric1 ''` and have at the dictionary `myapp.metric1 = metric1 name` 2. set `dimension = myapp.metric1 'm1'` and have at the dictionary `m1 = metric1 name` In both cases, the dimension will be added with ID `myapp.metric1` and will be named `metric1 name`. So, in alarms use either of the 2 as `${myapp.metric1}` or `${metric1 name}`. > keep in mind that if you add multiple times the same StatsD metric to a chart, Netdata will append `TYPE` to the dimension ID, so `myapp.metric1` will be added as `myapp.metric1_last` or `myapp.metric1_events`, etc. If you add multiple times the same metric with the same `TYPE` to a chart, Netdata will also append an incremental counter to the dimension ID, i.e. `myapp.metric1_last1`, `myapp.metric1_last2`, etc. #### Dimension patterns Netdata allows adding multiple dimensions to a chart, by matching the StatsD metrics with a Netdata simple pattern. Assume we have an API that provides StatsD metrics for each response code per method it supports, like these: ``` myapp.api.get.200 myapp.api.get.400 myapp.api.get.500 myapp.api.del.200 myapp.api.del.400 myapp.api.del.500 myapp.api.post.200 myapp.api.post.400 myapp.api.post.500 myapp.api.all.200 myapp.api.all.400 myapp.api.all.500 ``` In order to add all the response codes of `myapp.api.get` to a chart, we simply make the following configuration: ``` [api_get_responses] ... dimension = pattern 'myapp.api.get.* '' last 1 1 ``` The above will add dimension named `200`, `400` and `500`. Netdata extracts the wildcard part of the metric name - so the dimensions will be named with whatever the `*` matched. You can rename the dimensions with this: ``` [dictionary] get.200 = 200 ok get.400 = 400 bad request get.500 = 500 cannot connect to db [api_get_responses] ... dimension = pattern 'myapp.api.get.* 'get.' last 1 1 ``` Note that we added a `NAME` to the dimension line with `get.`. This is prefixed to the wildcarded part of the metric name, to compose the key for looking up the dictionary. So `500` became `get.500` which was looked up to the dictionary to find value `500 cannot connect to db`. This way we can have different dimension names, for each of the API methods (i.e. `get.500 = 500 cannot connect to db` while `post.500 = 500 cannot write to disk`). To add all 200s across all API methods to a chart, you can do this: ``` [ok_by_method] ... dimension = pattern 'myapp.api.*.200 '' last 1 1 ``` The above will add `get`, `post`, `del` and `all` to the chart. If `all` is not wanted (a `stacked` chart does not need the `all` dimension, since the sum of the dimensions provides the total), the line should be: ``` [ok_by_method] ... dimension = pattern '!myapp.api.all.* myapp.api.*.200 '' last 1 1 ``` With the above, all methods except `all` will be added to the chart. To automatically rename the methods, you can use this: ``` [dictionary] method.get = GET method.post = ADD method.del = DELETE [ok_by_method] ... dimension = pattern '!myapp.api.all.* myapp.api.*.200 'method.' last 1 1 ``` Using the above, the dimensions will be added as `GET`, `ADD` and `DELETE`. ## StatsD examples ### Python It's really easy to instrument your python application with StatsD, for example using [jsocol/pystatsd](https://github.com/jsocol/pystatsd). ```python import statsd c = statsd.StatsClient('localhost', 8125) c.incr('foo') # Increment the 'foo' counter. for i in range(100000000): c.incr('bar') c.incr('foo') if i % 3: c.decr('bar') c.timing('stats.timed', 320) # Record a 320ms 'stats.timed'. ``` You can find detailed documentation in their [documentation page](https://statsd.readthedocs.io/en/v3.3/). ### Javascript and Node.js Using the client library by [sivy/node-statsd](https://github.com/sivy/node-statsd), you can easily embed StatsD into your Node.js project. ```javascript var StatsD = require('node-statsd'), client = new StatsD(); // Timing: sends a timing command with the specified milliseconds client.timing('response_time', 42); // Increment: Increments a stat by a value (default is 1) client.increment('my_counter'); // Decrement: Decrements a stat by a value (default is -1) client.decrement('my_counter'); // Using the callback client.set(['foo', 'bar'], 42, function(error, bytes){ //this only gets called once after all messages have been sent if(error){ console.error('Oh noes! There was an error:', error); } else { console.log('Successfully sent', bytes, 'bytes'); } }); // Sampling, tags and callback are optional and could be used in any combination client.histogram('my_histogram', 42, 0.25); // 25% Sample Rate client.histogram('my_histogram', 42, ['tag']); // User-defined tag client.histogram('my_histogram', 42, next); // Callback client.histogram('my_histogram', 42, 0.25, ['tag']); client.histogram('my_histogram', 42, 0.25, next); client.histogram('my_histogram', 42, ['tag'], next); client.histogram('my_histogram', 42, 0.25, ['tag'], next); ``` ### Other languages You can also use StatsD with: - Golang, thanks to [alexcesaro/statsd](https://github.com/alexcesaro/statsd) - Ruby, thanks to [reinh/statsd](https://github.com/reinh/statsd) - Java, thanks to [DataDog/java-dogstatsd-client](https://github.com/DataDog/java-dogstatsd-client) ### Shell Getting the proper support for a programming language is not always easy, but the Unix shell is available on most Unix systems. You can use shell and `nc` to instrument your systems and send metric data to Netdata's StatsD implementation. Using the method you can send metrics from any script. You can generate events like: backup.started, backup.ended, backup.time, or even tail logs and convert them to metrics. > **IMPORTANT**: > > To send StatsD messages you need from the `netcat` package, the `nc` command. > There are multiple versions of this package. Please try to experiment with the `nc` command you have available on your right system, to find the right parameters. > > In the examples below, we assume the `openbsd-netcat` is installed. If you plan to send short StatsD events at sporadic occasions, use UDP. The messages should not be too long (remember, most networks support up to 1500 bytes MTU, which is also the limit for StatsD messages over UDP). The good thing is that using UDP will not block your script, even if the StatsD server is not there (UDP messages are "fire-and-forget"). For UDP use this: ```sh echo "APPLICATION.METRIC:VALUE|TYPE" | nc -u -w 0 localhost 8125 ``` `-u` turns on UDP, `-w 0` tells `nc` not to wait for a response from StatsD (idle time to close the connection). where: - `APPLICATION` is any name for your application - `METRIC` is the name for the specific metric - `VALUE` is the value for that metric (**meters**, **counters**, **gauges**, **timers** and **histograms** accept integer/decimal/fractional numbers, **sets** and **dictionaries** accept strings) - `TYPE` is one of `m`, `c`, `g`, `ms`, `h`, `s`, `d` to define the metric type. For tailing a log and converting it to metrics, do something like this: ```sh tail -f some.log | awk 'awk commands to parse the log and format statsd metrics' | nc -N -w 120 localhost 8125 ``` `-N` tells `nc` to close the socket once it receives EOF on its input. `-w 120` tells `nc` to stop if the connection is idle for 120 seconds. The timeout is needed to stop the `nc` command if you restart Netdata while `nc` is connected to it. Without it, `nc` will sit idle forever. When you embed the above commands to a script, you may notice that all the metrics are sent to StatsD with a delay. They are buffered in the pipes `|`. You can turn them to real-time by prepending each command with `stdbuf -i0 -oL -eL command to be run`, like this: ```sh stdbuf -i0 -oL -eL tail -f some.log |\ stdbuf -i0 -oL -eL awk 'awk commands to parse the log and format statsd metrics' |\ stdbuf -i0 -oL -eL nc -N -w 120 localhost 8125 ``` If you use `mawk` you also need to run awk with `-W interactive`. Examples: To set `myapp.used_memory` as gauge to value `123456`, use: ```sh echo "myapp.used_memory:123456|g|#units:bytes" | nc -u -w 0 localhost 8125 ``` To increment `myapp.files_sent` by `10`, as a counter, use: ```sh echo "myapp.files_sent:10|c|#units:files" | nc -u -w 0 localhost 8125 ``` You can send multiple metrics like this: ```sh # send multiple metrics via UDP printf "myapp.used_memory:123456|g|#units:bytes\nmyapp.files_sent:10|c|#units:files\n" | nc -u -w 0 localhost 8125 ``` Remember, for UDP communication each packet should not exceed the MTU. So, if you plan to push too many metrics at once, prefer TCP communication: ```sh # send multiple metrics via TCP cat /tmp/statsd.metrics.txt | nc -N -w 120 localhost 8125 ``` You can also use this little function to take care of all the details: ```sh #!/usr/bin/env bash # we assume nc is from the openbsd-netcat package STATSD_HOST="localhost" STATSD_PORT="8125" statsd() { local options="-u -w 0" all="${*}" # replace all spaces with newlines all="${all// /\\n}" # if the string length of all parameters given is above 1000, use TCP [ "${#all}" -gt 1000 ] && options="-N -w 0" # send the metrics to statsd printf "${all}\n" | nc ${options} ${STATSD_HOST} ${STATSD_PORT} || return 1 return 0 } if [ ! -z "${*}" ] then statsd "${@}" fi ``` You can use it like this: ```sh # first, source it in your script source statsd.sh # then, at any point: statsd "myapp.used_memory:123456|g|#units:bytes" "myapp.files_sent:10|c|#units:files" ... ``` or even at a terminal prompt, like this: ```sh ./statsd.sh "myapp.used_memory:123456|g|#units:bytes" "myapp.files_sent:10|c|#units:files" ... ``` The function is smart enough to call `nc` just once and pass all the metrics to it. It will also automatically switch to TCP if the metrics to send are above 1000 bytes. If you have gotten thus far, make sure to check out our [community forums](https://community.netdata.cloud) to share your experience using Netdata with StatsD.