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plugnpy

A Simple Python Library for creating Opsview Opspack plugins.

Master Build Status Master Coverage Status

Installing the Library

For Opsview versions above 6.1. plugnpy is preinstalled.

For Opsview versions below 6.1, Opsview Python's pip needs to be used to install the library.

/opt/opsview/python/bin/pip install <location of plugnpy-version.tar.gz>

To install the library locally, download the release package and install with pip.

pip install <location of plugnpy-version.tar.gz>

Quick Start

This project includes a Makefile that allows you to test and build the project in a Linux-compatible system with simple commands.

To see all available options:

make help

To create a development environment:

make venv

To run the tests in the development environment:

make test

To build the library in the development environment:

make build

This will create a plugnpy-VERSION.tar.gz file in the dist directory which can be installed in the same way as the prepackaged one above.

The coverage report is available at:

htmlcov/index.html

Writing Checks

The core of a check written using plugnpy is the Check object. A Check object must be instantiated before metrics can be defined.

import plugnpy
check = plugnpy.Check()

To add metrics to this check, simply use the add_metric() method of the Check object. This takes in arguments to add a Metric object to an internal array.

check.add_metric('disk_usage', 30.5, '%', display_name="Disk Usage",
                 display_format='{name} is {value}{unit}')

The Metric objects are then used to create the final output when the final() method is called.

check.final()

This would produce the following output:

METRIC OK - Disk Usage is 30.50% | disk_usage=30.50%;;

You can also specify the precision of the value in the summary and the performance data that you want to output, by using the summary_precision and perf_data_precision parameters when adding metrics (default is 2 decimal places):

check.add_metric('disk_usage', 30.55432, '%', display_name="Disk Usage",
                 display_format='{name} is {value}{unit}', summary_precision=3, perf_data_precision=4)

This would produce the following output:

METRIC OK - Disk Usage is 30.554% | disk_usage=30.5543%;;

Checks with thresholds

To apply thresholds to a metric, simply set the threshold values in the add_metric() call.

check.add_metric('cpu_usage', 70.7, '%', warning_threshold='70', critical_threshold='90',
                 display_name="CPU Usage", display_format="{name} is {value}{unit}")

This would produce the following output:

METRIC WARNING - CPU Usage is 70.70% | cpu_usage=70.70%;70;90

The library supports all Nagios threshold definitions as found here: Nagios Development Guidelines · Nagios Plugins.

As well as being fully compatible with Nagios thresholds, plugnpy allows thresholds to be specified in friendly units.

check.add_metric('mem_swap', 100, 'B', '10MB', '20MB', display_name="Memory Swap")

This would produce the following output:

METRIC OK - Memory Swap is 100.00B | mem_swap=100.00B;10MB;20MB

Writing checks with multiple metrics

Writing service checks with multiple metrics is easy. Simply create the Check object and add multiple metrics using the add_metric() method.

check = plugnpy.Check()
check.add_metric('disk_usage', 30.5, '%', '70', '90', display_name="Disk Usage",
                 display_format='{name} is {value}{unit}')
check.add_metric('cpu_usage', 70.7, '%', '70', '90', display_name="CPU Usage",
                 display_format='{name} is {value}{unit}')
check.final()

This would produce the following output:

METRIC WARNING - Disk Usage is 30.50%, CPU Usage is 70.70% | disk_usage=30.50%;70;90 cpu_usage=70.70%;70;90

When adding multiple metrics, the separator between metrics can be customised. By default this is set to ', ' but can easily be changed or removed by setting the sep field when creating the Check object.

check = plugnpy.Check(sep=' + ')

Adding multiple metrics to the Check object would then produce the following output:

METRIC OK - Disk Usage is 30.50% + CPU Usage is 70.70% | disk_usage=30.5%;70;90 cpu_usage=70.70%;70;90

Checks with automatic conversions

To create a check with automatic value conversions, simply call the add_metric() method with the convert_metric field set to True. The unit passed in should not have any existing prefix - for example, pass your value in B rather than KB or MB.

Setting the convert_metric field to True will override the unit (displayed in the summary) with the best match for the conversion. By default, convert_metric is set to True only for metrics in B, b, Bps and bps.

The supported conversion prefixes are:

Prefix Name Prefix Symbol Base 1000
exa E 10006
peta P 10005
tera T 10004
giga G 10003
mega M 10002
kilo K 10001
milli m 1000-1
micro u 1000-2
nano n 1000-3
pico p 1000-4

The units supporting these prefixes are as follows:

Unit Supported conversion prefixes
s p, n, u, m
B, b, Bps, bps K, M, G, T, P, E
W, Hz p, n, u, m, K, M, G, T, P, E

For example, adding the metric:

check.add_metric('mem_buffer', 1829863424, 'B', '1073741824', '2147483648',
                 display_name="Memory Buffer", convert_metric=True)

Would produce the following output:

METRIC WARNING - Memory Buffer is 1.70GB | mem_buffer=1829904384.00B;1073741824;2147483648

And adding the metric below:

check.add_metric('latency', 0.0002, 's', '0.0004', '0.0007', display_name="Latency",
                 convert_metric=True, summary_precision=1, perf_data_precision=4)

Would produce the following output:

METRIC WARNING - Latency is 0.2ms | latency=0.0002s;0.0004;0.0007

All unit conversions are dealt with inside the library (as long as convert_metric is set to True), allowing values to be entered without having to do any manual conversions.

For metrics with the unit related to bytes (B, b, Bps or bps), conversions are done based on the International Electrotechnical Commission (IEC) standard, using 1024 as the base multiplier. However the library also supports the International System (SI) standard, which uses 1000 as the base multiplier, this can be changed by calling add_metric() with the si_bytes_conversion field set to True (False by default).

check.add_metric('mem_buffer', 1000, 'B', '1GB', '2GB', display_name="Memory Buffer",
                 convert_metric=True, si_bytes_conversion=True, summary_precision=0)

This would produce the following output:

METRIC OK - Memory Buffer is 1KB | mem_buffer=1000.00B;1GB;2GB

For metrics using any other unit, conversions are done using the SI standard (1000 as the base multiplier).

Helper methods

The Metric class includes two helper methods to make developing service checks easier.

The evaluate() method evaluates a metric value against the specified warning and critical thresholds and returns the status code.

status_code = metric.evaluate(15, '10', '20')

The above example would return the value 1, since the value is above the warning threshold but not the critical threshold.

The convert_value() method converts a given value and unit to a more human friendly value and unit.

value, unit = metric.convert_value(2048, 'B')

The above example would return 2.00 as the value and 'KB' as the unit. Both methods support the si_bytes_conversion field. See Checks with automatic conversions above for more details.

Using the Argument Parser

plugnpy comes with its own Argument Parser. This parser inherits from argparse.ArgumentParser but will exit with code 3 when called with the -h/--help flag.

The parser also has the ability to print copyright information when -h/--help is called.

This can either be setup when the Parser object is created.

parser = plugnpy.Parser(description="Monitors Memory Utilisation",
                        copyright="Example Copyright 2017-2018")

Or added after by calling the set_copyright() method.

parser = plugnpy.Parser(description="Monitors Memory Utilisation")
parser.set_copyright("Example Copyright 2017-2018")

To use the parser, create an object of type plugnpy.Parser and use as you would normally use an argparse.ArgumentParser object.

Using the Exceptions

plugnpy comes with its own Exception objects. They have no special implementation beyond their names and can be found in plugnpy.Exceptions. To be consistent, here are the appropriate times to raise each exception:

Exception Usage
ParamError To be thrown when user input causes the issue (i.e, wrong password, invalid input type, etc.)
ParamErrorWithHelp To be thrown when user input causes the issue (i.e, wrong password, invalid input type, etc.) and help text needs to be printed.
ResultError To be thrown when the API/Metric Check returns either no result (when this isn't expected) or returns a result that is essentially unusable.
AssumedOK To be thrown when the status of the check cannot be identified. This is usually used when the check requires the result of a previous run and this is the first run.
InvalidMetricThreshold This shouldn't be thrown in a plugin. It is used internally in checks.py when an invalid metric threshold is passed in.
InvalidMetricName This shouldn't be thrown in a plugin. It is used internally in checks.py when an invalid metric name is passed in.

Cache Manager client

plugnpy comes with an http client which is able to connect to the opsview-cachemanager component. This allows the plugins to use the cache manager to store temporary data into memory which can be consumed by other servicechecks which require the same data.

The module consists of two classes, namely CacheManagerClient and CacheManagerUtils, which provide easy to use interfaces to communicate with the opsview-cachemanager.

CacheManagerClient

A simple client to set or get cached data from the cache manager.

The cache manager client requires the namespace of the plugin and the host ip and port of the cache manager to be supplied. These are provided to the plugin as opsview-executor encrypted environment variables.

host = os.environ.get('OPSVIEW_CACHE_MANAGER_HOST')
port = os.environ.get('OPSVIEW_CACHE_MANAGER_PORT')
namespace = os.environ.get('OPSVIEW_CACHE_MANAGER_NAMESPACE')

A cache manager client can then be created:

client = CacheManagerClient(host, port, namespace)

Items inserted into the cache manager are namespaced, ensuring naming collisions are avoided and potentially sensitive data cannot be read by other unauthorized plugins.

Optionally, when creating the client, the concurrency, connection_timeout and network_timeout parameters can be specified to modify the number of concurrent http connection allowed (default: 1), the number of seconds before the HTTP connection times out (default: 30) and the number of seconds before the data read times out (default: 30), respectively.

client = CacheManagerClient(host, port, namespace, concurrency=1, connection_timeout=30,
                            network_timeout=30)

Once a cache manager client has been created, the get_data and set_data methods can be used to get and set data respectively.

The set_data method can be called with the key and data parameters, this will store the specified data, under the given key. Optionally, the ttl parameter (Time To Live) can be used to specify the number of seconds the data is valid for (default: 900). It is expected that session information and other temporary data will be stored in the cache manager. 15 minutes has been chosen as the default to ensure data does not have to be recreated too often, but in the event of a change in data, the cached information does not persist for too long.

client.set_data(key, data, ttl=900)

The get_data method can be called with the key parameter to retrieve data stored under the specified key. Optionally, the max_wait_time parameter can be used to specify the number of seconds to wait before timing out (default: 30).

client.get_data(key, max_wait_time=30)

Calling the get_data method when the data exists in the cache manager will return the data. However, if the data does not exist in the cache manager, it will return a lock. Obtaining a lock means the cache manager expects the component to make the call to get the data directly and then use the set_data method to set the data in the cache manager, ready to be used by other components. Any concurrent components calling the get_data method will block if they cannot obtain the lock, this ensures that only one component sets the data. Once the data has been set, all blocked components will be unblocked and return the newly cached data. The max_wait_time parameter of the get_data method has a default of 30 seconds, but needs to be large enough for this cycle to be completed.

CacheManagerUtils

get_via_cachemanager

To simplify calls to the cache manager, plugnpy provides a helper utility method get_via_cachemanager, this will create the cache manager client and call the get_data and set_data methods as required.

This method expects the following parameters:

  • no_cachemanager: True if cache manager is not required, False otherwise.
  • key: The key to store the data under.
  • ttl: The Time To Live, number of seconds the data is valid for in the cache manager.
  • func: The function to retrieve the data, if the data is not in the cache manager.
  • args: The arguments to pass to the user's data retrieval function.
  • kwargs: The keyword arguments to pass to the user's data retrieval function.
def api_call(string):
  return string[::-1]

CacheManagerUtils.get_via_cachemanager(no_cachemanager, 'my_key', 300, api_call, 'hello')

In this example, if the data exists in the cache manager under the key 'my_key', the call to get_via_cachemanager will simply return the data. However, if the data does not exist in the cache manager, the call to get_via_cachemanager will call the api_call method with the argument 'hello' and then set the data in the cachemanager, so future calls can use the data from the cache manager. The data is valid for the time specified by the TTL.

set_data

Sometimes data must be inserted or updated in the cache manager, without retrieving the existing data. In these scenarios the set_data method can be used, this will create the cache manager client and call the set_data method of the CacheManagerClient internally.

CachemanagerUtils.set_data(key, data, ttl)

generate_key

CacheManagerUtils also contains a generate_key method which can be used to create a unique key for cache manager based on the arguments that are passed in. All arguments are first escaped if they contain the cache manager delimiter (#), and then joined by the delimiter before a SHA-256 hash is generated.

CacheManagerUtils.generate_key('foo', 'b#ar', 'b\#az')

This would be equivalent to:

hash_string('foo#b\#ar#b\\\#az')

Utils

convert_seconds

utils.py contains a helper method convert_seconds to allow converting seconds to a more human readable format. For values more than 60 seconds, the seconds value will be omitted from the output, for values greater than 60, the value will be returned in seconds. For example passing in the value 90060 to convert_seconds will return 1d 1h 1m, and passing in the value 45 will return 45s.