gitlab-org--gitlab-foss/lib/gitlab/metrics/system.rb

module Gitlab
  module Metrics
    # Module for gathering system/process statistics such as the memory usage.
    #
    # This module relies on the /proc filesystem being available. If /proc is
    # not available the methods of this module will be stubbed.
    module System
      if File.exist?('/proc')
        # Returns the current process' memory usage in bytes.
        def self.memory_usage
          mem   = 0
          match = File.read('/proc/self/status').match(/VmRSS:\s+(\d+)/)

          if match and match[1]
            mem = match[1].to_f * 1024
          end

          mem
        end

        def self.file_descriptor_count
          Dir.glob('/proc/self/fd/*').length
        end
      else
        def self.memory_usage
          0.0
        end

        def self.file_descriptor_count
          0
        end
      end

      # THREAD_CPUTIME is not supported on OS X
      if Process.const_defined?(:CLOCK_THREAD_CPUTIME_ID)
        def self.cpu_time
          Process.
            clock_gettime(Process::CLOCK_THREAD_CPUTIME_ID, :millisecond)
        end
      else
        def self.cpu_time
          Process.
            clock_gettime(Process::CLOCK_PROCESS_CPUTIME_ID, :millisecond)
        end
      end

      # Returns the current real time in a given precision.
      #
      # Returns the time as a Float.
      def self.real_time(precision = :millisecond)
        Process.clock_gettime(Process::CLOCK_REALTIME, precision)
      end

      # Returns the current monotonic clock time in a given precision.
      #
      # Returns the time as a Float.
      def self.monotonic_time(precision = :millisecond)
        Process.clock_gettime(Process::CLOCK_MONOTONIC, precision)
      end
    end
  end
end
Storing of application metrics in InfluxDB This adds the ability to write application metrics (e.g. SQL timings) to InfluxDB. These metrics can in turn be visualized using Grafana, or really anything else that can read from InfluxDB. These metrics can be used to track application performance over time, between different Ruby versions, different GitLab versions, etc. == Transaction Metrics Currently the following is tracked on a per transaction basis (a transaction is a Rails request or a single Sidekiq job): * Timings per query along with the raw (obfuscated) SQL and information about what file the query originated from. * Timings per view along with the path of the view and information about what file triggered the rendering process. * The duration of a request itself along with the controller/worker class and method name. * The duration of any instrumented method calls (more below). == Sampled Metrics Certain metrics can't be directly associated with a transaction. For example, a process' total memory usage is unrelated to any running transactions. While a transaction can result in the memory usage going up there's no accurate way to determine what transaction is to blame, this becomes especially problematic in multi-threaded environments. To solve this problem there's a separate thread that takes samples at a fixed interval. This thread (using the class Gitlab::Metrics::Sampler) currently tracks the following: * The process' total memory usage. * The number of file descriptors opened by the process. * The amount of Ruby objects (using ObjectSpace.count_objects). * GC statistics such as timings, heap slots, etc. The default/current interval is 15 seconds, any smaller interval might put too much pressure on InfluxDB (especially when running dozens of processes). == Method Instrumentation While currently not yet used methods can be instrumented to track how long they take to run. Unlike the likes of New Relic this doesn't require modifying the source code (e.g. including modules), it all happens from the outside. For example, to track `User.by_login` we'd add the following code somewhere in an initializer: Gitlab::Metrics::Instrumentation. instrument_method(User, :by_login) to instead instrument an instance method: Gitlab::Metrics::Instrumentation. instrument_instance_method(User, :save) Instrumentation for either all public model methods or a few crucial ones will be added in the near future, I simply haven't gotten to doing so just yet. == Configuration By default metrics are disabled. This means users don't have to bother setting anything up if they don't want to. Metrics can be enabled by editing one's gitlab.yml configuration file (see config/gitlab.yml.example for example settings). == Writing Data To InfluxDB Because InfluxDB is still a fairly young product I expect the worse. Data loss, unexpected reboots, the database not responding, you name it. Because of this data is _not_ written to InfluxDB directly, instead it's queued and processed by Sidekiq. This ensures that users won't notice anything when InfluxDB is giving trouble. The metrics worker can be started in a standalone manner as following: bundle exec sidekiq -q metrics The corresponding class is called MetricsWorker. 2015-12-09 15:45:51 +00:00			`module Gitlab`
			`module Metrics`
			`# Module for gathering system/process statistics such as the memory usage.`
			`#`
			`# This module relies on the /proc filesystem being available. If /proc is`
			`# not available the methods of this module will be stubbed.`
			`module System`
			`if File.exist?('/proc')`
			`# Returns the current process' memory usage in bytes.`
			`def self.memory_usage`
			`mem = 0`
			`match = File.read('/proc/self/status').match(/VmRSS:\s+(\d+)/)`

			`if match and match[1]`
			`mem = match[1].to_f * 1024`
			`end`

			`mem`
			`end`

			`def self.file_descriptor_count`
			`Dir.glob('/proc/self/fd/*').length`
			`end`
			`else`
			`def self.memory_usage`
			`0.0`
			`end`

			`def self.file_descriptor_count`
			`0`
			`end`
			`end`
Store block timings as transaction values This makes it easier to query, simplifies the code, and makes it possible to figure out what transaction the data belongs to (simply because it's now stored _in_ the transaction). This new setup keeps track of both the real/wall time _and_ CPU time spent in a block, both measured using milliseconds (to keep all units the same). 2016-04-11 10:23:37 +00:00
			`# THREAD_CPUTIME is not supported on OS X`
			`if Process.const_defined?(:CLOCK_THREAD_CPUTIME_ID)`
			`def self.cpu_time`
Use clock_gettime for all performance timestamps Process.clock_gettime allows getting the real time in nanoseconds as well as allowing one to get a monotonic timestamp. This offers greater accuracy without the overhead of having to allocate a Time instance. In general using Time.now/Time.new is about 2x slower than using Process.clock_gettime(). For example: require 'benchmark/ips' Benchmark.ips do \|bench\| bench.report 'Time.now' do Time.now.to_f end bench.report 'clock_gettime' do Process.clock_gettime(Process::CLOCK_MONOTONIC, :millisecond) end bench.compare! end Running this benchmark gives: Calculating ------------------------------------- Time.now 108.052k i/100ms clock_gettime 125.984k i/100ms ------------------------------------------------- Time.now 2.343M (± 7.1%) i/s - 11.670M clock_gettime 4.979M (± 0.8%) i/s - 24.945M Comparison: clock_gettime: 4979393.8 i/s Time.now: 2342986.8 i/s - 2.13x slower Another benefit of using Process.clock_gettime() is that we can simplify the code a bit since it can give timestamps in nanoseconds out of the box. 2016-06-24 11:44:50 +00:00			`Process.`
Reduce instrumentation overhead This reduces the overhead of the method instrumentation code primarily by reducing the number of method calls. There are also some other small optimisations such as not casting timing values to Floats (there's no particular need for this), using Symbols for method call metric names, and reducing the number of Hash lookups for instrumented methods. The exact impact depends on the code being executed. For example, for a method that's only called once the difference won't be very noticeable. However, for methods that are called many times the difference can be more significant. For example, the loading time of a large commit (nrclark/dummy_project@81ebdea5df2fb42e59257cb3eaad671a5c53ca36) was reduced from around 19 seconds to around 15 seconds using these changes. 2016-07-28 13:08:57 +00:00			`clock_gettime(Process::CLOCK_THREAD_CPUTIME_ID, :millisecond)`
Store block timings as transaction values This makes it easier to query, simplifies the code, and makes it possible to figure out what transaction the data belongs to (simply because it's now stored _in_ the transaction). This new setup keeps track of both the real/wall time _and_ CPU time spent in a block, both measured using milliseconds (to keep all units the same). 2016-04-11 10:23:37 +00:00			`end`
			`else`
			`def self.cpu_time`
Use clock_gettime for all performance timestamps Process.clock_gettime allows getting the real time in nanoseconds as well as allowing one to get a monotonic timestamp. This offers greater accuracy without the overhead of having to allocate a Time instance. In general using Time.now/Time.new is about 2x slower than using Process.clock_gettime(). For example: require 'benchmark/ips' Benchmark.ips do \|bench\| bench.report 'Time.now' do Time.now.to_f end bench.report 'clock_gettime' do Process.clock_gettime(Process::CLOCK_MONOTONIC, :millisecond) end bench.compare! end Running this benchmark gives: Calculating ------------------------------------- Time.now 108.052k i/100ms clock_gettime 125.984k i/100ms ------------------------------------------------- Time.now 2.343M (± 7.1%) i/s - 11.670M clock_gettime 4.979M (± 0.8%) i/s - 24.945M Comparison: clock_gettime: 4979393.8 i/s Time.now: 2342986.8 i/s - 2.13x slower Another benefit of using Process.clock_gettime() is that we can simplify the code a bit since it can give timestamps in nanoseconds out of the box. 2016-06-24 11:44:50 +00:00			`Process.`
Reduce instrumentation overhead This reduces the overhead of the method instrumentation code primarily by reducing the number of method calls. There are also some other small optimisations such as not casting timing values to Floats (there's no particular need for this), using Symbols for method call metric names, and reducing the number of Hash lookups for instrumented methods. The exact impact depends on the code being executed. For example, for a method that's only called once the difference won't be very noticeable. However, for methods that are called many times the difference can be more significant. For example, the loading time of a large commit (nrclark/dummy_project@81ebdea5df2fb42e59257cb3eaad671a5c53ca36) was reduced from around 19 seconds to around 15 seconds using these changes. 2016-07-28 13:08:57 +00:00			`clock_gettime(Process::CLOCK_PROCESS_CPUTIME_ID, :millisecond)`
Store block timings as transaction values This makes it easier to query, simplifies the code, and makes it possible to figure out what transaction the data belongs to (simply because it's now stored _in_ the transaction). This new setup keeps track of both the real/wall time _and_ CPU time spent in a block, both measured using milliseconds (to keep all units the same). 2016-04-11 10:23:37 +00:00			`end`
			`end`
Use clock_gettime for all performance timestamps Process.clock_gettime allows getting the real time in nanoseconds as well as allowing one to get a monotonic timestamp. This offers greater accuracy without the overhead of having to allocate a Time instance. In general using Time.now/Time.new is about 2x slower than using Process.clock_gettime(). For example: require 'benchmark/ips' Benchmark.ips do \|bench\| bench.report 'Time.now' do Time.now.to_f end bench.report 'clock_gettime' do Process.clock_gettime(Process::CLOCK_MONOTONIC, :millisecond) end bench.compare! end Running this benchmark gives: Calculating ------------------------------------- Time.now 108.052k i/100ms clock_gettime 125.984k i/100ms ------------------------------------------------- Time.now 2.343M (± 7.1%) i/s - 11.670M clock_gettime 4.979M (± 0.8%) i/s - 24.945M Comparison: clock_gettime: 4979393.8 i/s Time.now: 2342986.8 i/s - 2.13x slower Another benefit of using Process.clock_gettime() is that we can simplify the code a bit since it can give timestamps in nanoseconds out of the box. 2016-06-24 11:44:50 +00:00
			`# Returns the current real time in a given precision.`
			`#`
			`# Returns the time as a Float.`
			`def self.real_time(precision = :millisecond)`
Reduce instrumentation overhead This reduces the overhead of the method instrumentation code primarily by reducing the number of method calls. There are also some other small optimisations such as not casting timing values to Floats (there's no particular need for this), using Symbols for method call metric names, and reducing the number of Hash lookups for instrumented methods. The exact impact depends on the code being executed. For example, for a method that's only called once the difference won't be very noticeable. However, for methods that are called many times the difference can be more significant. For example, the loading time of a large commit (nrclark/dummy_project@81ebdea5df2fb42e59257cb3eaad671a5c53ca36) was reduced from around 19 seconds to around 15 seconds using these changes. 2016-07-28 13:08:57 +00:00			`Process.clock_gettime(Process::CLOCK_REALTIME, precision)`
Use clock_gettime for all performance timestamps Process.clock_gettime allows getting the real time in nanoseconds as well as allowing one to get a monotonic timestamp. This offers greater accuracy without the overhead of having to allocate a Time instance. In general using Time.now/Time.new is about 2x slower than using Process.clock_gettime(). For example: require 'benchmark/ips' Benchmark.ips do \|bench\| bench.report 'Time.now' do Time.now.to_f end bench.report 'clock_gettime' do Process.clock_gettime(Process::CLOCK_MONOTONIC, :millisecond) end bench.compare! end Running this benchmark gives: Calculating ------------------------------------- Time.now 108.052k i/100ms clock_gettime 125.984k i/100ms ------------------------------------------------- Time.now 2.343M (± 7.1%) i/s - 11.670M clock_gettime 4.979M (± 0.8%) i/s - 24.945M Comparison: clock_gettime: 4979393.8 i/s Time.now: 2342986.8 i/s - 2.13x slower Another benefit of using Process.clock_gettime() is that we can simplify the code a bit since it can give timestamps in nanoseconds out of the box. 2016-06-24 11:44:50 +00:00			`end`

			`# Returns the current monotonic clock time in a given precision.`
			`#`
			`# Returns the time as a Float.`
			`def self.monotonic_time(precision = :millisecond)`
Reduce instrumentation overhead This reduces the overhead of the method instrumentation code primarily by reducing the number of method calls. There are also some other small optimisations such as not casting timing values to Floats (there's no particular need for this), using Symbols for method call metric names, and reducing the number of Hash lookups for instrumented methods. The exact impact depends on the code being executed. For example, for a method that's only called once the difference won't be very noticeable. However, for methods that are called many times the difference can be more significant. For example, the loading time of a large commit (nrclark/dummy_project@81ebdea5df2fb42e59257cb3eaad671a5c53ca36) was reduced from around 19 seconds to around 15 seconds using these changes. 2016-07-28 13:08:57 +00:00			`Process.clock_gettime(Process::CLOCK_MONOTONIC, precision)`
Use clock_gettime for all performance timestamps Process.clock_gettime allows getting the real time in nanoseconds as well as allowing one to get a monotonic timestamp. This offers greater accuracy without the overhead of having to allocate a Time instance. In general using Time.now/Time.new is about 2x slower than using Process.clock_gettime(). For example: require 'benchmark/ips' Benchmark.ips do \|bench\| bench.report 'Time.now' do Time.now.to_f end bench.report 'clock_gettime' do Process.clock_gettime(Process::CLOCK_MONOTONIC, :millisecond) end bench.compare! end Running this benchmark gives: Calculating ------------------------------------- Time.now 108.052k i/100ms clock_gettime 125.984k i/100ms ------------------------------------------------- Time.now 2.343M (± 7.1%) i/s - 11.670M clock_gettime 4.979M (± 0.8%) i/s - 24.945M Comparison: clock_gettime: 4979393.8 i/s Time.now: 2342986.8 i/s - 2.13x slower Another benefit of using Process.clock_gettime() is that we can simplify the code a bit since it can give timestamps in nanoseconds out of the box. 2016-06-24 11:44:50 +00:00			`end`
Storing of application metrics in InfluxDB This adds the ability to write application metrics (e.g. SQL timings) to InfluxDB. These metrics can in turn be visualized using Grafana, or really anything else that can read from InfluxDB. These metrics can be used to track application performance over time, between different Ruby versions, different GitLab versions, etc. == Transaction Metrics Currently the following is tracked on a per transaction basis (a transaction is a Rails request or a single Sidekiq job): * Timings per query along with the raw (obfuscated) SQL and information about what file the query originated from. * Timings per view along with the path of the view and information about what file triggered the rendering process. * The duration of a request itself along with the controller/worker class and method name. * The duration of any instrumented method calls (more below). == Sampled Metrics Certain metrics can't be directly associated with a transaction. For example, a process' total memory usage is unrelated to any running transactions. While a transaction can result in the memory usage going up there's no accurate way to determine what transaction is to blame, this becomes especially problematic in multi-threaded environments. To solve this problem there's a separate thread that takes samples at a fixed interval. This thread (using the class Gitlab::Metrics::Sampler) currently tracks the following: * The process' total memory usage. * The number of file descriptors opened by the process. * The amount of Ruby objects (using ObjectSpace.count_objects). * GC statistics such as timings, heap slots, etc. The default/current interval is 15 seconds, any smaller interval might put too much pressure on InfluxDB (especially when running dozens of processes). == Method Instrumentation While currently not yet used methods can be instrumented to track how long they take to run. Unlike the likes of New Relic this doesn't require modifying the source code (e.g. including modules), it all happens from the outside. For example, to track `User.by_login` we'd add the following code somewhere in an initializer: Gitlab::Metrics::Instrumentation. instrument_method(User, :by_login) to instead instrument an instance method: Gitlab::Metrics::Instrumentation. instrument_instance_method(User, :save) Instrumentation for either all public model methods or a few crucial ones will be added in the near future, I simply haven't gotten to doing so just yet. == Configuration By default metrics are disabled. This means users don't have to bother setting anything up if they don't want to. Metrics can be enabled by editing one's gitlab.yml configuration file (see config/gitlab.yml.example for example settings). == Writing Data To InfluxDB Because InfluxDB is still a fairly young product I expect the worse. Data loss, unexpected reboots, the database not responding, you name it. Because of this data is _not_ written to InfluxDB directly, instead it's queued and processed by Sidekiq. This ensures that users won't notice anything when InfluxDB is giving trouble. The metrics worker can be started in a standalone manner as following: bundle exec sidekiq -q metrics The corresponding class is called MetricsWorker. 2015-12-09 15:45:51 +00:00			`end`
			`end`
			`end`