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GitLab Logs play a critical role for both administrators and GitLab team members to diagnose problems in the field.
Currently Rails.logger
calls all get saved into production.log
, which contains
a mix of Rails' logs and other calls developers have inserted in the codebase.
For example:
Started GET "/gitlabhq/yaml_db/tree/master" for 168.111.56.1 at 2015-02-12 19:34:53 +0200
Processing by Projects::TreeController#show as HTML
Parameters: {"project_id"=>"gitlabhq/yaml_db", "id"=>"master"}
...
Namespaces"."created_at" DESC, "namespaces"."id" DESC LIMIT 1 [["id", 26]]
CACHE (0.0ms) SELECT "members".* FROM "members" WHERE "members"."source_type" = 'Project' AND "members"."type" IN ('ProjectMember') AND "members"."source_id" = $1 AND "members"."source_type" = $2 AND "members"."user_id" = 1 ORDER BY "members"."created_at" DESC, "members"."id" DESC LIMIT 1 [["source_id", 18], ["source_type", "Project"]]
CACHE (0.0ms) SELECT "members".* FROM "members" WHERE "members"."source_type" = 'Project' AND "members".
(1.4ms) SELECT COUNT(*) FROM "merge_requests" WHERE "merge_requests"."target_project_id" = $1 AND ("merge_requests"."state" IN ('opened','reopened')) [["target_project_id", 18]]
Rendered layouts/nav/_project.html.haml (28.0ms)
Rendered layouts/_collapse_button.html.haml (0.2ms)
Rendered layouts/_flash.html.haml (0.1ms)
Rendered layouts/_page.html.haml (32.9ms)
Completed 200 OK in 166ms (Views: 117.4ms | ActiveRecord: 27.2ms)
These logs suffer from a number of problems:
- They often lack timestamps or other contextual information (for example, project ID or user)
- They may span multiple lines, which make them hard to find via Elasticsearch.
- They lack a common structure, which make them hard to parse by log forwarders, such as Logstash or Fluentd. This also makes them hard to search.
Note that currently on GitLab.com, any messages in production.log
aren't
indexed by Elasticsearch due to the sheer volume and noise. They
do end up in Google Stackdriver, but it is still harder to search for
logs there. See the GitLab.com logging documentation
for more details.
Structured logging solves these problems. Consider the example from an API request:
{"time":"2018-10-29T12:49:42.123Z","severity":"INFO","duration":709.08,"db":14.59,"view":694.49,"status":200,"method":"GET","path":"/api/v4/projects","params":[{"key":"action","value":"git-upload-pack"},{"key":"changes","value":"_any"},{"key":"key_id","value":"secret"},{"key":"secret_token","value":"[FILTERED]"}],"host":"localhost","ip":"::1","ua":"Ruby","route":"/api/:version/projects","user_id":1,"username":"root","queue_duration":100.31,"gitaly_calls":30}
In a single line, we've included all the information that a user needs to understand what happened: the timestamp, HTTP method and path, user ID, and so on.
Suppose you want to log the events that happen in a project importer. You want to log issues created, merge requests, and so on, as the importer progresses. Here's what to do:
-
Look at the list of GitLab Logs to see if your log message might belong with one of the existing log files.
-
If there isn't a good place, consider creating a new filename, but check with a maintainer if it makes sense to do so. A log file should make it easy for people to search pertinent logs in one place. For example,
geo.log
contains all logs pertaining to GitLab Geo. To create a new file:-
Choose a filename (for example,
importer_json.log
). -
Create a new subclass of
Gitlab::JsonLogger
:module Gitlab module Import class Logger < ::Gitlab::JsonLogger def self.file_name_noext 'importer' end end end end
Note that by default,
Gitlab::JsonLogger
will include application context metadata in the log entry. If your logger is expected to be called outside of an application request (for example, in arake
task) or by low-level code that may be involved in building the application context (for example, database connection code), you should call the class methodexclude_context!
for your logger class, like so:module Gitlab module Database module LoadBalancing class Logger < ::Gitlab::JsonLogger exclude_context! def self.file_name_noext 'database_load_balancing' end end end end end
-
In your class where you want to log, you might initialize the logger as an instance variable:
attr_accessor :logger def initialize @logger = Gitlab::Import::Logger.build end
Note that it's useful to memoize this because creating a new logger each time you log opens a file, adding unnecessary overhead.
-
-
Now insert log messages into your code. When adding logs, make sure to include all the context as key-value pairs:
# BAD logger.info("Unable to create project #{project.id}")
# GOOD logger.info(message: "Unable to create project", project_id: project.id)
-
Be sure to create a common base structure of your log messages. For example, all messages might have
current_user_id
andproject_id
to make it easier to search for activities by user for a given time.
When using something like Elasticsearch to index structured logs, there is a schema for the types of each log field (even if that schema is implicit / inferred). It's important to be consistent with the types of your field values, otherwise this might break the ability to search/filter on these fields, or even cause whole log events to be dropped. While much of this section is phrased in an Elasticsearch-specific way, the concepts should translate to many systems you might use to index structured logs. GitLab.com uses Elasticsearch to index log data.
Unless a field type is explicitly mapped, Elasticsearch infers the type from the first instance of that field value it sees. Subsequent instances of that field value with different types either fail to be indexed, or in some cases (scalar/object conflict), the whole log line is dropped.
GitLab.com's logging Elasticsearch sets
ignore_malformed
,
which allows documents to be indexed even when there are simpler sorts of
mapping conflict (for example, number / string), although indexing on the affected fields
breaks.
Examples:
# GOOD
logger.info(message: "Import error", error_code: 1, error: "I/O failure")
# BAD
logger.info(message: "Import error", error: 1)
logger.info(message: "Import error", error: "I/O failure")
# WORST
logger.info(message: "Import error", error: "I/O failure")
logger.info(message: "Import error", error: { message: "I/O failure" })
List elements must be the same type:
# GOOD
logger.info(a_list: ["foo", "1", "true"])
# BAD
logger.info(a_list: ["foo", 1, true])
Resources:
Structured logs should always include a class
attribute to make all entries logged from a particular place in the code findable.
To automatically add the class
attribute, you can include the
Gitlab::Loggable
module and use the build_structured_payload
method.
class MyClass
include ::Gitlab::Loggable
def my_method
logger.info(build_structured_payload(message: 'log message', project_id: project_id))
end
private
def logger
@logger ||= Gitlab::AppJsonLogger.build
end
end
Similar to timezones, choosing the right time unit to log can impose avoidable overhead. So, whenever
challenged to choose between seconds, milliseconds or any other unit, lean towards seconds as float
(with microseconds precision, that is, Gitlab::InstrumentationHelper::DURATION_PRECISION
).
In order to make it easier to track timings in the logs, make sure the log key has _s
as
suffix and duration
within its name (for example, view_duration_s
).
GitLab transitioned from structured to JSON logs. However, through multi-destination logging, the logs can be recorded in multiple formats.
Create a new logger class, inheriting from MultiDestinationLogger
and add an
array of loggers to a LOGGERS
constant. The loggers should be classes that
descend from Gitlab::Logger
. For example, the user-defined loggers in the
following examples could be inheriting from Gitlab::Logger
and
Gitlab::JsonLogger
, respectively.
You must specify one of the loggers as the primary_logger
. The
primary_logger
is used when information about this multi-destination logger is
displayed in the application (for example, using the Gitlab::Logger.read_latest
method).
The following example sets one of the defined LOGGERS
as a primary_logger
.
module Gitlab
class FancyMultiLogger < Gitlab::MultiDestinationLogger
LOGGERS = [UnstructuredLogger, StructuredLogger].freeze
def self.loggers
LOGGERS
end
def primary_logger
UnstructuredLogger
end
end
end
You can now call the usual logging methods on this multi-logger. For example:
FancyMultiLogger.info(message: "Information")
This message is logged by each logger registered in FancyMultiLogger.loggers
.
When passing a string or hash to a MultiDestinationLogger
, the log lines could be formatted differently, depending on the kinds of LOGGERS
set.
For example, let's partially define the loggers from the previous example:
module Gitlab
# Similar to AppTextLogger
class UnstructuredLogger < Gitlab::Logger
...
end
# Similar to AppJsonLogger
class StructuredLogger < Gitlab::JsonLogger
...
end
end
Here are some examples of how messages would be handled by both the loggers.
- When passing a string
FancyMultiLogger.info("Information")
# UnstructuredLogger
I, [2020-01-13T18:48:49.201Z #5647] INFO -- : Information
# StructuredLogger
{:severity=>"INFO", :time=>"2020-01-13T11:02:41.559Z", :correlation_id=>"b1701f7ecc4be4bcd4c2d123b214e65a", :message=>"Information"}
- When passing a hash
FancyMultiLogger.info({:message=>"This is my message", :project_id=>123})
# UnstructuredLogger
I, [2020-01-13T19:01:17.091Z #11056] INFO -- : {"message"=>"Message", "project_id"=>"123"}
# StructuredLogger
{:severity=>"INFO", :time=>"2020-01-13T11:06:09.851Z", :correlation_id=>"d7e0886f096db9a8526a4f89da0e45f6", :message=>"This is my message", :project_id=>123}
Gitlab::ApplicationContext
stores metadata in a request
lifecycle, which can then be added to the web request
or Sidekiq logs.
The API, Rails and Sidekiq logs contain fields starting with meta.
with this context information.
Entry points can be seen at:
When adding new attributes, make sure they're exposed within the context of the entry points above and:
- Pass them within the hash to the
with_context
(orpush
) method (make sure to pass a Proc if the method or variable shouldn't be evaluated right away) - Change
Gitlab::ApplicationContext
to accept these new values - Make sure the new attributes are accepted at
Labkit::Context
See our HOWTO: Use Sidekiq metadata logs for further knowledge on creating visualizations in Kibana.
The fields of the context are currently only logged for Sidekiq jobs triggered through web requests. See the follow-up work for more information.
Additional metadata can be attached to a worker through the use of the ApplicationWorker#log_extra_metadata_on_done
method. Using this method adds metadata that is later logged to Kibana with the done job payload.
class MyExampleWorker
include ApplicationWorker
def perform(*args)
# Worker performs work
# ...
# The contents of value will appear in Kibana under `json.extra.my_example_worker.my_key`
log_extra_metadata_on_done(:my_key, value)
end
end
Please see this example
which logs a count of how many artifacts are destroyed per run of the ExpireArtifactsWorker
.
It often happens that you catch the exception and want to track it.
It should be noted that manual logging of exceptions is not allowed, as:
- Manual logged exceptions can leak confidential data,
- Manual logged exception very often require to clean backtrace which reduces the boilerplate,
- Very often manually logged exception needs to be tracked to Sentry as well,
- Manually logged exceptions does not use
correlation_id
, which makes hard to pin them to request, user and context in which this exception was raised, - Manually logged exceptions often end up across multiple files, which increases burden scraping all logging files.
To avoid duplicating and having consistent behavior the Gitlab::ErrorTracking
provides helper methods to track exceptions:
Gitlab::ErrorTracking.track_and_raise_exception
: this method logs, sends exception to Sentry (if configured) and re-raises the exception,Gitlab::ErrorTracking.track_exception
: this method only logs and sends exception to Sentry (if configured),Gitlab::ErrorTracking.log_exception
: this method only logs the exception, and does not send the exception to Sentry,Gitlab::ErrorTracking.track_and_raise_for_dev_exception
: this method logs, sends exception to Sentry (if configured) and re-raises the exception for development and test environments.
It is advised to only use Gitlab::ErrorTracking.track_and_raise_exception
and Gitlab::ErrorTracking.track_exception
as presented on below examples.
Consider adding additional extra parameters to provide more context for each tracked exception.
class MyService < ::BaseService
def execute
project.perform_expensive_operation
success
rescue => e
Gitlab::ErrorTracking.track_exception(e, project_id: project.id)
error('Exception occurred')
end
end
class MyService < ::BaseService
def execute
project.perform_expensive_operation
success
rescue => e
Gitlab::ErrorTracking.track_and_raise_exception(e, project_id: project.id)
end
end
-
Consider log retention settings. By default, Omnibus rotates any logs in
/var/log/gitlab/gitlab-rails/*.log
every hour and keep at most 30 compressed files. On GitLab.com, that setting is only 6 compressed files. These settings should suffice for most users, but you may need to tweak them in Omnibus GitLab. -
On GitLab.com all new JSON log files generated by GitLab Rails are automatically shipped to Elasticsearch (and available in Kibana) on GitLab Rails Kubernetes pods. If you need the file forwarded from Gitaly nodes then submit an issue to the production tracker or a merge request to the
gitlab_fluentd
project. See this example. -
Be sure to update the GitLab CE/EE documentation and the GitLab.com runbooks.
On GitLab.com all new JSON log files generated by GitLab Rails are
automatically shipped to Elasticsearch (and available in Kibana) on GitLab
Rails Kubernetes pods. The json.subcomponent
field in Kibana will allow you
to filter by the different kinds of log files. For example the
json.subcomponent
will be production_json
for entries forwarded from
production_json.log
.
It's also worth noting that log files from Web/API pods go to a different index than log files from Sidekiq pods. Depending on where you log from you will find the logs in a different index pattern.
An increase in the logs can cause a growing backlog of unacknowledged messages. When adding new log messages, make sure they don't increase the overall volume of logging by more than 10%.
If the expected volume of deprecation notices is large:
- Only log them in the development environment.
- If needed, log them in the testing environment.