Prometheus Exporter allows you to aggregate custom metrics from multiple processes and export to Prometheus. It provides a very flexible framework for handling Prometheus metrics and can operate in a single and multiprocess mode.
To learn more see Instrumenting Rails with Prometheus (it has pretty pictures!)
- Requirements
- Migrating from v0.x
- Installation
- Usage
- Single process mode
- Multi process mode
- Rails integration
- Puma metrics
- Unicorn metrics
- Resque metrics
- GoodJob metrics
- Custom type collectors
- Multi process mode with custom collector
- GraphQL support
- Metrics default prefix / labels
- Client default labels
- Client default host
- Histogram mode
- Histogram - custom buckets
- Transport concerns
- JSON generation and parsing
- Logging
- Docker Usage
- Contributing
- License
- Code of Conduct
Minimum Ruby of version 3.0.0 is required, Ruby 2.7 is EOL as of March 31st 2023.
There are some major changes in v1.x from v0.x.
- Some of metrics are renamed to match prometheus official guide for metric names. (#184)
Add this line to your application's Gemfile:
gem 'prometheus_exporter'
And then execute:
$ bundle
Or install it yourself as:
$ gem install prometheus_exporter
Simplest way of consuming Prometheus exporter is in a single process mode.
require 'prometheus_exporter/server'
# client allows instrumentation to send info to server
require 'prometheus_exporter/client'
require 'prometheus_exporter/instrumentation'
# bind is the address, on which the webserver will listen
# port is the port that will provide the /metrics route
server = PrometheusExporter::Server::WebServer.new bind: 'localhost', port: 12345
server.start
# wire up a default local client
PrometheusExporter::Client.default = PrometheusExporter::LocalClient.new(collector: server.collector)
# this ensures basic process instrumentation metrics are added such as RSS and Ruby metrics
PrometheusExporter::Instrumentation::Process.start(type: "my program", labels: {my_custom: "label for all process metrics"})
gauge = PrometheusExporter::Metric::Gauge.new("rss", "used RSS for process")
counter = PrometheusExporter::Metric::Counter.new("web_requests", "number of web requests")
summary = PrometheusExporter::Metric::Summary.new("page_load_time", "time it took to load page")
histogram = PrometheusExporter::Metric::Histogram.new("api_access_time", "time it took to call api")
server.collector.register_metric(gauge)
server.collector.register_metric(counter)
server.collector.register_metric(summary)
server.collector.register_metric(histogram)
gauge.observe(get_rss)
gauge.observe(get_rss)
counter.observe(1, route: 'test/route')
counter.observe(1, route: 'another/route')
summary.observe(1.1)
summary.observe(1.12)
summary.observe(0.12)
histogram.observe(0.2, api: 'twitter')
# http://localhost:12345/metrics now returns all your metrics
You can also choose custom quantiles for summaries and custom buckets for histograms.
summary = PrometheusExporter::Metric::Summary.new("load_time", "time to load page", quantiles: [0.99, 0.75, 0.5, 0.25])
histogram = PrometheusExporter::Metric::Histogram.new("api_time", "time to call api", buckets: [0.1, 0.5, 1])
In some cases (for example, unicorn or puma clusters) you may want to aggregate metrics across multiple processes.
Simplest way to achieve this is to use the built-in collector.
First, run an exporter on your desired port (we use the default bind to localhost and port of 9394):
$ prometheus_exporter
And in your application:
require 'prometheus_exporter/client'
client = PrometheusExporter::Client.default
gauge = client.register(:gauge, "awesome", "amount of awesome")
gauge.observe(10)
gauge.observe(99, day: "friday")
Then you will get the metrics:
$ curl localhost:9394/metrics
# HELP collector_working Is the master process collector able to collect metrics
# TYPE collector_working gauge
collector_working 1
# HELP awesome amount of awesome
# TYPE awesome gauge
awesome{day="friday"} 99
awesome 10
Custom quantiles for summaries and buckets for histograms can also be passed in.
require 'prometheus_exporter/client'
client = PrometheusExporter::Client.default
histogram = client.register(:histogram, "api_time", "time to call api", buckets: [0.1, 0.5, 1])
histogram.observe(0.2, api: 'twitter')
You can easily integrate into any Rack application.
In your Gemfile:
gem 'prometheus_exporter'
In an initializer:
unless Rails.env.test?
require 'prometheus_exporter/middleware'
# This reports stats per request like HTTP status and timings
Rails.application.middleware.unshift PrometheusExporter::Middleware
end
Ensure you run the exporter in a monitored background process:
$ bundle exec prometheus_exporter
By default, prometheus_exporter
uses alias_method
to instrument methods used by SQL and Redis as it is the fastest approach (see this article). You may desire to add additional instrumentation libraries beyond prometheus_exporter
to your app. This can become problematic if these other libraries instead use prepend
to instrument methods. To resolve this, you can tell the middleware to instrument using prepend
by passing an instrument
option like so:
Rails.application.middleware.unshift PrometheusExporter::Middleware, instrument: :prepend
Type | Name | Description |
---|---|---|
Counter | http_requests_total |
Total HTTP requests from web app |
Summary | http_request_duration_seconds |
Time spent in HTTP reqs in seconds |
Summary | http_request_redis_duration_seconds ¹ |
Time spent in HTTP reqs in Redis, in seconds |
Summary | http_request_sql_duration_seconds ² |
Time spent in HTTP reqs in SQL in seconds |
Summary | http_request_queue_duration_seconds ³ |
Time spent queueing the request in load balancer in seconds |
Summary | http_request_memcache_duration_seconds ⁴ |
Time spent in HTTP reqs in Memcache in seconds |
All metrics have a controller
and an action
label.
http_requests_total
additionally has a (HTTP response) status
label.
To add your own labels to the default metrics, create a subclass of PrometheusExporter::Middleware
, override custom_labels
, and use it in your initializer.
class MyMiddleware < PrometheusExporter::Middleware
def custom_labels(env)
labels = {}
if env['HTTP_X_PLATFORM']
labels['platform'] = env['HTTP_X_PLATFORM']
end
labels
end
end
If you're not using Rails like framework, you can extend PrometheusExporter::Middleware#default_labels
in a way to add more relevant labels.
For example you can mimic prometheus-client labels with code like this:
class MyMiddleware < PrometheusExporter::Middleware
def default_labels(env, result)
status = (result && result[0]) || -1
path = [env["SCRIPT_NAME"], env["PATH_INFO"]].join
{
path: strip_ids_from_path(path),
method: env["REQUEST_METHOD"],
status: status
}
end
def strip_ids_from_path(path)
path
.gsub(%r{/[0-9a-f]{8}-[0-9a-f]{4}-[0-9a-f]{4}-[0-9a-f]{4}-[0-9a-f]{12}(/|$)}, '/:uuid\\1')
.gsub(%r{/\d+(/|$)}, '/:id\\1')
end
end
That way you won't have all metrics labeled with controller=other
and action=other
, but have labels such as
ruby_http_request_duration_seconds{path="/api/v1/teams/:id",method="GET",status="200",quantile="0.99"} 0.009880661998977303
¹) Only available when Redis is used. ²) Only available when Mysql or PostgreSQL are used. ³) Only available when Instrumenting Request Queueing Time is set up. ⁴) Only available when Dalli is used.
This collects activerecord connection pool metrics.
It supports injection of custom labels and the connection config options (username
, database
, host
, port
) as labels.
For Puma single mode
#in puma.rb
require 'prometheus_exporter/instrumentation'
PrometheusExporter::Instrumentation::ActiveRecord.start(
custom_labels: { type: "puma_single_mode" }, #optional params
config_labels: [:database, :host] #optional params
)
For Puma cluster mode
# in puma.rb
on_worker_boot do
require 'prometheus_exporter/instrumentation'
PrometheusExporter::Instrumentation::ActiveRecord.start(
custom_labels: { type: "puma_worker" }, #optional params
config_labels: [:database, :host] #optional params
)
end
For Unicorn / Passenger
after_fork do |_server, _worker|
require 'prometheus_exporter/instrumentation'
PrometheusExporter::Instrumentation::ActiveRecord.start(
custom_labels: { type: "unicorn_worker" }, #optional params
config_labels: [:database, :host] #optional params
)
end
For Sidekiq
Sidekiq.configure_server do |config|
config.on :startup do
require 'prometheus_exporter/instrumentation'
PrometheusExporter::Instrumentation::ActiveRecord.start(
custom_labels: { type: "sidekiq" }, #optional params
config_labels: [:database, :host] #optional params
)
end
end
Type | Name | Description |
---|---|---|
Gauge | active_record_connection_pool_connections |
Total connections in pool |
Gauge | active_record_connection_pool_busy |
Connections in use in pool |
Gauge | active_record_connection_pool_dead |
Dead connections in pool |
Gauge | active_record_connection_pool_idle |
Idle connections in pool |
Gauge | active_record_connection_pool_waiting |
Connection requests waiting |
Gauge | active_record_connection_pool_size |
Maximum allowed connection pool size |
All metrics collected by the ActiveRecord integration include at least the following labels: pid
(of the process the stats where collected in), pool_name
, any labels included in the config_labels
option (prefixed with dbconfig_
, example: dbconfig_host
), and all custom labels provided with the custom_labels
option.
You may also be interested in per-process stats. This collects memory and GC stats:
# in an initializer
unless Rails.env.test?
require 'prometheus_exporter/instrumentation'
# this reports basic process stats like RSS and GC info
PrometheusExporter::Instrumentation::Process.start(type: "master")
end
# in unicorn/puma/passenger be sure to run a new process instrumenter after fork
after_fork do
require 'prometheus_exporter/instrumentation'
PrometheusExporter::Instrumentation::Process.start(type: "web")
end
Type | Name | Description |
---|---|---|
Gauge | heap_free_slots |
Free ruby heap slots |
Gauge | heap_live_slots |
Used ruby heap slots |
Gauge | v8_heap_size * |
Total JavaScript V8 heap size (bytes) |
Gauge | v8_used_heap_size * |
Total used JavaScript V8 heap size (bytes) |
Gauge | v8_physical_size * |
Physical size consumed by V8 heaps |
Gauge | v8_heap_count * |
Number of V8 contexts running |
Gauge | rss |
Total RSS used by process |
Counter | major_gc_ops_total |
Major GC operations by process |
Counter | minor_gc_ops_total |
Minor GC operations by process |
Counter | allocated_objects_total |
Total number of allocated objects by process |
Metrics marked with * are only collected when MiniRacer
is defined.
Metrics collected by Process instrumentation include labels type
(as given with the type
option), pid
(of the process the stats where collected in), and any custom labels given to Process.start
with the labels
option.
There are different kinds of Sidekiq metrics that can be collected. A recommended setup looks like this:
Sidekiq.configure_server do |config|
require 'prometheus_exporter/instrumentation'
config.server_middleware do |chain|
chain.add PrometheusExporter::Instrumentation::Sidekiq
end
config.death_handlers << PrometheusExporter::Instrumentation::Sidekiq.death_handler
config.on :startup do
PrometheusExporter::Instrumentation::Process.start type: 'sidekiq'
PrometheusExporter::Instrumentation::SidekiqProcess.start
PrometheusExporter::Instrumentation::SidekiqQueue.start
PrometheusExporter::Instrumentation::SidekiqStats.start
end
end
- The middleware and death handler will generate job specific metrics (how many jobs ran? how many failed? how long did they take? how many are dead? how many were restarted?).
- The
Process
metrics provide basic ruby metrics. - The
SidekiqProcess
metrics provide the concurrency and busy metrics for this process. - The
SidekiqQueue
metrics provides size and latency for the queues run by this process. - The
SidekiqStats
metrics provide general, global Sidekiq stats (size of Scheduled, Retries, Dead queues, total number of jobs, etc).
For SidekiqQueue
, if you run more than one process for the same queues, note that the same metrics will be exposed by all the processes, just like the SidekiqStats
will if you run more than one process of any kind. You might want use avg
or max
when consuming their metrics.
An alternative would be to expose these metrics in lone, long-lived process. Using a rake task, for example:
task :sidekiq_metrics do
server = PrometheusExporter::Server::WebServer.new
server.start
PrometheusExporter::Client.default = PrometheusExporter::LocalClient.new(collector: server.collector)
PrometheusExporter::Instrumentation::SidekiqQueue.start(all_queues: true)
PrometheusExporter::Instrumentation::SidekiqStats.start
sleep
end
The all_queues
parameter for SidekiqQueue
will expose metrics for all queues.
Sometimes the Sidekiq server shuts down before it can send metrics, that were generated right before the shutdown, to the collector. Especially if you care about the sidekiq_restarted_jobs_total
metric, it is a good idea to explicitly stop the client:
Sidekiq.configure_server do |config|
at_exit do
PrometheusExporter::Client.default.stop(wait_timeout_seconds: 10)
end
end
Custom labels can be added for individual jobs by defining a class method on the job class. These labels will be added to all Sidekiq metrics written by the job:
class WorkerWithCustomLabels
def self.custom_labels
{ my_label: 'value-here', other_label: 'second-val' }
end
def perform; end
end
PrometheusExporter::Instrumentation::Sidekiq
Type | Name | Description |
---|---|---|
Summary | sidekiq_job_duration_seconds |
Time spent in sidekiq jobs |
Counter | sidekiq_jobs_total |
Total number of sidekiq jobs executed |
Counter | sidekiq_restarted_jobs_total |
Total number of sidekiq jobs that we restarted because of a sidekiq shutdown |
Counter | sidekiq_failed_jobs_total |
Total number of failed sidekiq jobs |
All metrics have a job_name
label and a queue
label.
PrometheusExporter::Instrumentation::Sidekiq.death_handler
Type | Name | Description |
---|---|---|
Counter | sidekiq_dead_jobs_total |
Total number of dead sidekiq jobs |
This metric has a job_name
label and a queue
label.
PrometheusExporter::Instrumentation::SidekiqQueue
Type | Name | Description |
---|---|---|
Gauge | sidekiq_queue_backlog |
Size of the sidekiq queue |
Gauge | sidekiq_queue_latency_seconds |
Latency of the sidekiq queue |
Both metrics will have a queue
label with the name of the queue.
PrometheusExporter::Instrumentation::SidekiqProcess
Type | Name | Description |
---|---|---|
Gauge | sidekiq_process_busy |
Number of busy workers for this process |
Gauge | sidekiq_process_concurrency |
Concurrency for this process |
Both metrics will include the labels labels
, queues
, quiet
, tag
, hostname
and identity
, as returned by the Sidekiq Processes API.
PrometheusExporter::Instrumentation::SidekiqStats
Type | Name | Description |
---|---|---|
Gauge | sidekiq_stats_dead_size |
Size of the dead queue |
Gauge | sidekiq_stats_enqueued |
Number of enqueued jobs |
Gauge | sidekiq_stats_failed |
Number of failed jobs |
Gauge | sidekiq_stats_processed |
Total number of processed jobs |
Gauge | sidekiq_stats_processes_size |
Number of processes |
Gauge | sidekiq_stats_retry_size |
Size of the retries queue |
Gauge | sidekiq_stats_scheduled_size |
Size of the scheduled queue |
Gauge | sidekiq_stats_workers_size |
Number of jobs actively being processed |
Based on the Sidekiq Stats API.
See Metrics collected by Process Instrumentation for a list of metrics the Process instrumentation will produce.
For Shoryuken metrics (how many jobs ran? how many failed? how long did they take? how many were restarted?)
Shoryuken.configure_server do |config|
config.server_middleware do |chain|
require 'prometheus_exporter/instrumentation'
chain.add PrometheusExporter::Instrumentation::Shoryuken
end
end
Type | Name | Description |
---|---|---|
Counter | shoryuken_job_duration_seconds |
Total time spent in shoryuken jobs |
Counter | shoryuken_jobs_total |
Total number of shoryuken jobs executed |
Counter | shoryuken_restarted_jobs_total |
Total number of shoryuken jobs that we restarted because of a shoryuken shutdown |
Counter | shoryuken_failed_jobs_total |
Total number of failed shoryuken jobs |
All metrics have labels for job_name
and queue_name
.
In an initializer:
unless Rails.env.test?
require 'prometheus_exporter/instrumentation'
PrometheusExporter::Instrumentation::DelayedJob.register_plugin
end
Type | Name | Description | Labels |
---|---|---|---|
Counter | delayed_job_duration_seconds |
Total time spent in delayed jobs | job_name |
Counter | delayed_job_latency_seconds_total |
Total delayed jobs latency | job_name |
Counter | delayed_jobs_total |
Total number of delayed jobs executed | job_name |
Gauge | delayed_jobs_enqueued |
Number of enqueued delayed jobs | - |
Gauge | delayed_jobs_pending |
Number of pending delayed jobs | - |
Counter | delayed_failed_jobs_total |
Total number failed delayed jobs executed | job_name |
Counter | delayed_jobs_max_attempts_reached_total |
Total number of delayed jobs that reached max attempts | - |
Summary | delayed_job_duration_seconds_summary |
Summary of the time it takes jobs to execute | status |
Summary | delayed_job_attempts_summary |
Summary of the amount of attempts it takes delayed jobs to succeed | - |
All metrics have labels for job_name
and queue_name
.
delayed_job_latency_seconds_total
is considering delayed job's sleep_delay parameter, so please be aware of this in case you are looking for high latency precision.
Capture Hutch metrics (how many jobs ran? how many failed? how long did they take?)
unless Rails.env.test?
require 'prometheus_exporter/instrumentation'
Hutch::Config.set(:tracer, PrometheusExporter::Instrumentation::Hutch)
end
Type | Name | Description |
---|---|---|
Counter | hutch_job_duration_seconds |
Total time spent in hutch jobs |
Counter | hutch_jobs_total |
Total number of hutch jobs executed |
Counter | hutch_failed_jobs_total |
Total number failed hutch jobs executed |
All metrics have a job_name
label.
Request Queueing is defined as the time it takes for a request to reach your application (instrumented by this prometheus_exporter
) from farther upstream (as your load balancer). A high queueing time usually means that your backend cannot handle all the incoming requests in time, so they queue up (= you should see if you need to add more capacity).
As this metric starts before prometheus_exporter
can handle the request, you must add a specific HTTP header as early in your infrastructure as possible (we recommend your load balancer or reverse proxy).
The Amazon Application Load Balancer request tracing header is natively supported. If you are using another upstream entrypoint, you may configure your HTTP server / load balancer to add a header X-Request-Start: t=<MSEC>
when passing the request upstream. Please keep in mind request time start is reported as epoch time (in seconds) and lacks precision, which may introduce additional latency in reported metrics. For more information, please consult your software manual.
Hint: we aim to be API-compatible with the big APM solutions, so if you've got requests queueing time configured for them, it should be expected to also work with prometheus_exporter
.
The puma metrics are using the Puma.stats
method and hence need to be started after the
workers has been booted and from a Puma thread otherwise the metrics won't be accessible.
The easiest way to gather this metrics is to put the following in your puma.rb
config:
For Puma single mode
# puma.rb config
require 'prometheus_exporter/instrumentation'
# optional check, avoids spinning up and down threads per worker
if !PrometheusExporter::Instrumentation::Puma.started?
PrometheusExporter::Instrumentation::Puma.start
end
For Puma clustered mode
# puma.rb config
after_worker_boot do
require 'prometheus_exporter/instrumentation'
# optional check, avoids spinning up and down threads per worker
if !PrometheusExporter::Instrumentation::Puma.started?
PrometheusExporter::Instrumentation::Puma.start
end
end
Type | Name | Description |
---|---|---|
Gauge | puma_workers |
Number of puma workers |
Gauge | puma_booted_workers |
Number of puma workers booted |
Gauge | puma_old_workers |
Number of old puma workers |
Gauge | puma_running_threads |
Number of puma threads currently running |
Gauge | puma_request_backlog |
Number of requests waiting to be processed by a puma thread |
Gauge | puma_thread_pool_capacity |
Number of puma threads available at current scale |
Gauge | puma_max_threads |
Number of puma threads at available at max scale |
All metrics may have a phase
label and all custom labels provided with the labels
option.
The resque metrics are using the Resque.info
method, which queries Redis internally. To start monitoring your resque
installation, you'll need to start the instrumentation:
# e.g. config/initializers/resque.rb
require 'prometheus_exporter/instrumentation'
PrometheusExporter::Instrumentation::Resque.start
Type | Name | Description |
---|---|---|
Gauge | resque_processed_jobs |
Total number of processed Resque jobs |
Gauge | resque_failed_jobs |
Total number of failed Resque jobs |
Gauge | resque_pending_jobs |
Total number of pending Resque jobs |
Gauge | resque_queues |
Total number of Resque queues |
Gauge | resque_workers |
Total number of Resque workers running |
Gauge | resque_working |
Total number of Resque workers working |
The metrics are generated from the database using the relevant scopes. To start monitoring your GoodJob installation, you'll need to start the instrumentation:
# e.g. config/initializers/good_job.rb
require 'prometheus_exporter/instrumentation'
PrometheusExporter::Instrumentation::GoodJob.start
Type | Name | Description |
---|---|---|
Gauge | good_job_scheduled |
Total number of scheduled GoodJob jobs. |
Gauge | good_job_retried |
Total number of retried GoodJob jobs. |
Gauge | good_job_queued |
Total number of queued GoodJob jobs. |
Gauge | good_job_running |
Total number of running GoodJob jobs. |
Gauge | good_job_finished |
Total number of finished GoodJob jobs. |
Gauge | good_job_succeeded |
Total number of succeeded GoodJob jobs. |
Gauge | good_job_discarded |
Total number of discarded GoodJob jobs |
In order to gather metrics from unicorn processes, we use rainbows
, which exposes Rainbows::Linux.tcp_listener_stats
to gather information about active workers and queued requests. To start monitoring your unicorn processes, you'll need to know both the path to unicorn PID file and the listen address (pid_file
and listen
in your unicorn config file)
Then, run prometheus_exporter
with --unicorn-master
and --unicorn-listen-address
options:
prometheus_exporter --unicorn-master /var/run/unicorn.pid --unicorn-listen-address 127.0.0.1:3000
# alternatively, if you're using unix sockets:
prometheus_exporter --unicorn-master /var/run/unicorn.pid --unicorn-listen-address /var/run/unicorn.sock
Note: You must install the raindrops
gem in your Gemfile
or locally.
Type | Name | Description |
---|---|---|
Gauge | unicorn_workers |
Number of unicorn workers |
Gauge | unicorn_active_workers |
Number of active unicorn workers |
Gauge | unicorn_request_backlog |
Number of requests waiting to be processed by a unicorn worker |
In some cases you may have custom metrics you want to ship the collector in a batch. In this case you may still be interested in the base collector behavior, but would like to add your own special messages.
# person_collector.rb
class PersonCollector < PrometheusExporter::Server::TypeCollector
def initialize
@oldies = PrometheusExporter::Metric::Counter.new("oldies", "old people")
@youngies = PrometheusExporter::Metric::Counter.new("youngies", "young people")
end
def type
"person"
end
def collect(obj)
if obj["age"] > 21
@oldies.observe(1)
else
@youngies.observe(1)
end
end
def metrics
[@oldies, @youngies]
end
end
Shipping metrics then is done via:
PrometheusExporter::Client.default.send_json(type: "person", age: 40)
To load the custom collector run:
$ bundle exec prometheus_exporter -a person_collector.rb
Custom type collectors are the ideal place to collect global metrics, such as user/article counts and connection counts. The custom type collector runs in the collector, which usually runs in the prometheus exporter process.
Out-of-the-box we try to keep the prometheus exporter as lean as possible. We do not load all Rails dependencies, so you won't have access to your models. You can always ensure it is loaded in your custom type collector with:
unless defined? Rails
require File.expand_path("../../config/environment", __FILE__)
end
Then you can collect the metrics you need on demand:
def metrics
user_count_gauge = PrometheusExporter::Metric::Gauge.new('user_count', 'number of users in the app')
user_count_gauge.observe User.count
[user_count_gauge]
end
The metrics endpoint is called whenever prometheus calls the /metrics
HTTP endpoint, so it may make sense to introduce some type of caching. lru_redux is the perfect gem for this job: you can use LruRedux::TTL::Cache
, which will expire automatically after N seconds, thus saving multiple database queries.
You can opt for custom collector logic in a multi process environment.
This allows you to completely replace the collector logic.
First, define a custom collector. It is important that you inherit off PrometheusExporter::Server::CollectorBase
and have custom implementations for #process
and #prometheus_metrics_text
methods.
class MyCustomCollector < PrometheusExporter::Server::CollectorBase
def initialize
@gauge1 = PrometheusExporter::Metric::Gauge.new("thing1", "I am thing 1")
@gauge2 = PrometheusExporter::Metric::Gauge.new("thing2", "I am thing 2")
@mutex = Mutex.new
end
def process(str)
obj = JSON.parse(str)
@mutex.synchronize do
if thing1 = obj["thing1"]
@gauge1.observe(thing1)
end
if thing2 = obj["thing2"]
@gauge2.observe(thing2)
end
end
end
def prometheus_metrics_text
@mutex.synchronize do
"#{@gauge1.to_prometheus_text}\n#{@gauge2.to_prometheus_text}"
end
end
end
Next, launch the exporter process:
$ bin/prometheus_exporter --collector examples/custom_collector.rb
In your application send metrics you want:
require 'prometheus_exporter/client'
client = PrometheusExporter::Client.new(host: 'localhost', port: 12345)
client.send_json(thing1: 122)
client.send_json(thing2: 12)
Now your exporter will echo the metrics:
$ curl localhost:12345/metrics
# HELP collector_working Is the master process collector able to collect metrics
# TYPE collector_working gauge
collector_working 1
# HELP thing1 I am thing 1
# TYPE thing1 gauge
thing1 122
# HELP thing2 I am thing 2
# TYPE thing2 gauge
thing2 12
GraphQL execution metrics are supported and can be collected via the GraphQL collector, included in graphql-ruby.
This only works in single process mode.
You can specify default prefix or labels for metrics. For example:
# Specify prefix for metric names
PrometheusExporter::Metric::Base.default_prefix = "ruby"
# Specify default labels for metrics
PrometheusExporter::Metric::Base.default_labels = { "hostname" => "app-server-01" }
counter = PrometheusExporter::Metric::Counter.new("web_requests", "number of web requests")
counter.observe(1, route: 'test/route')
counter.observe
Will result in:
# HELP web_requests number of web requests
# TYPE web_requests counter
ruby_web_requests{hostname="app-server-01",route="test/route"} 1
ruby_web_requests{hostname="app-server-01"} 1
When running the process for prometheus_exporter
using bin/prometheus_exporter
, there are several configurations that
can be passed in:
Usage: prometheus_exporter [options]
-p, --port INTEGER Port exporter should listen on (default: 9394)
-b, --bind STRING IP address exporter should listen on (default: localhost)
-t, --timeout INTEGER Timeout in seconds for metrics endpoint (default: 2)
--prefix METRIC_PREFIX Prefix to apply to all metrics (default: ruby_)
--label METRIC_LABEL Label to apply to all metrics (default: {})
-c, --collector FILE (optional) Custom collector to run
-a, --type-collector FILE (optional) Custom type collectors to run in main collector
-v, --verbose
-g, --histogram Use histogram instead of summary for aggregations
--auth FILE (optional) enable basic authentication using a htpasswd FILE
--realm REALM (optional) Use REALM for basic authentication (default: "Prometheus Exporter")
--unicorn-listen-address ADDRESS
(optional) Address where unicorn listens on (unix or TCP address)
--unicorn-master PID_FILE (optional) PID file of unicorn master process to monitor unicorn
The following will run the process at
- Port
8080
(default9394
) - Bind to
0.0.0.0
(defaultlocalhost
) - Timeout in
1 second
for metrics endpoint (default2 seconds
) - Metric prefix as
foo_
(defaultruby_
) - Default labels as
{environment: "integration", foo: "bar"}
prometheus_exporter -p 8080 \
-b 0.0.0.0 \
-t 1 \
--label '{"environment": "integration", "foo": "bar"}' \
--prefix 'foo_'
You can use -b
option to bind the prometheus_exporter
web server to any IPv4 interface with -b 0.0.0.0
,
any IPv6 interface with -b ::
, or -b ANY
to any IPv4/IPv6 interfaces available on your host system.
If you desire authentication on your /metrics
route, you can enable basic authentication with the --auth
option.
$ prometheus_exporter --auth my-htpasswd-file
Additionally, the --realm
option may be used to provide a customized realm for the challenge request.
Notes:
- You will need to create a
htpasswd
formatted file before hand which contains one or more user:password entries - Only the basic
crypt
encryption is currently supported
A simple htpasswd
file can be created with the Apache htpasswd
utility; e.g:
$ htpasswd -cdb my-htpasswd-file my-user my-unencrypted-password
This will create a file named my-htpasswd-file
which is suitable for use the --auth
option.
You can specify a default label for instrumentation metrics sent by a specific client. For example:
# Specify on intializing PrometheusExporter::Client
PrometheusExporter::Client.new(custom_labels: { hostname: 'app-server-01', app_name: 'app-01' })
# Specify on an instance of PrometheusExporter::Client
client = PrometheusExporter::Client.new
client.custom_labels = { hostname: 'app-server-01', app_name: 'app-01' }
Will result in:
http_requests_total{controller="home","action"="index",service="app-server-01",app_name="app-01"} 2
http_requests_total{service="app-server-01",app_name="app-01"} 1
By default, PrometheusExporter::Client.default
connects to localhost:9394
. If your setup requires this (e.g. when using docker-compose
), you can change the default host and port by setting the environment variables PROMETHEUS_EXPORTER_HOST
and PROMETHEUS_EXPORTER_PORT
.
By default, the built-in collectors will report aggregations as summaries. If you need to aggregate metrics across labels, you can switch from summaries to histograms:
$ prometheus_exporter --histogram
In histogram mode, the same metrics will be collected but will be reported as histograms rather than summaries. This sacrifices some precision but allows aggregating metrics across actions and nodes using histogram_quantile
.
By default these buckets will be used:
[0.005, 0.01, 0.025, 0.05, 0.1, 0.25, 0.5, 1, 2.5, 5.0, 10.0].freeze
if this is not enough you can specify default_buckets
like this:
Histogram.default_buckets = [0.005, 0.01, 0.025, 0.05, 0.1, 0.25, 0.5, 1, 2, 2.5, 3, 4, 5.0, 10.0, 12, 14, 15, 20, 25].freeze
Specfied buckets on the instance takes precedence over default:
Histogram.default_buckets = [0.005, 0.01, 0,5].freeze
buckets = [0.1, 0.2, 0.3]
histogram = Histogram.new('test_bucktets', 'I have specified buckets', buckets: buckets)
histogram.buckets => [0.1, 0.2, 0.3]
Prometheus Exporter handles transport using a simple HTTP protocol. In multi process mode we avoid needing a large number of HTTP request by using chunked encoding to send metrics. This means that a single HTTP channel can deliver 100s or even 1000s of metrics over a single HTTP session to the /send-metrics
endpoint. All calls to send
and send_json
on the PrometheusExporter::Client
class are non-blocking and batched.
The /bench
directory has simple benchmark, which is able to send through 10k messages in 500ms.
The PrometheusExporter::Client
class has the method #send-json
. This method, by default, will call JSON.dump
on the Object it recieves. You may opt in for oj
mode where it can use the faster Oj.dump(obj, mode: :compat)
for JSON serialization. But be warned that if you have custom objects that implement own to_json
methods this may not work as expected. You can opt for oj serialization with json_serializer: :oj
.
When PrometheusExporter::Server::Collector
parses your JSON, by default it will use the faster Oj deserializer if available. This happens cause it only expects a simple Hash out of the box. You can opt in for the default JSON deserializer with json_serializer: :json
.
PrometheusExporter::Client.default
will export to STDERR
. To change this, you can pass your own logger:
PrometheusExporter::Client.new(logger: Rails.logger)
PrometheusExporter::Client.new(logger: Logger.new(STDOUT))
You can also pass a log level (default is Logger::WARN
):
PrometheusExporter::Client.new(log_level: Logger::DEBUG)
You can run prometheus_exporter
project using an official Docker image:
docker pull discourse/prometheus_exporter:latest
# or use specific version
docker pull discourse/prometheus_exporter:x.x.x
The start the container:
docker run -p 9394:9394 discourse/prometheus_exporter
Additional flags could be included:
docker run -p 9394:9394 discourse/prometheus_exporter --verbose --prefix=myapp
A /ping
endpoint which only returns PONG
is available so you can run container healthchecks :
Example:
services:
rails-exporter:
command:
- bin/prometheus_exporter
- -b
- 0.0.0.0
healthcheck:
test: ["CMD", "curl", "--silent", "--show-error", "--fail", "--max-time", "3", "http://0.0.0.0:9394/ping"]
timeout: 3s
interval: 10s
retries: 5
Bug reports and pull requests are welcome on GitHub at https://github.com/discourse/prometheus_exporter. This project is intended to be a safe, welcoming space for collaboration, and contributors are expected to adhere to the Contributor Covenant code of conduct.
The gem is available as open source under the terms of the MIT License.
Everyone interacting in the PrometheusExporter project’s codebases, issue trackers, chat rooms and mailing lists is expected to follow the code of conduct.