- Examples of CI/CD usage
- CI Architecture overview
- Job scheduling
- The definition of “Job” in GitLab CI/CD
- Compute quota
CI/CD development guidelines
Development guides that are specific to CI/CD are listed here:
- If you are creating new CI/CD templates, please read the development guide for GitLab CI/CD templates.
- If you are adding a new keyword or changing the CI schema, check the CI schema guide
See the CI/CD YAML reference documentation guide to learn how to update the reference page.
Examples of CI/CD usage
We maintain a ci-sample-projects
group, with projects that showcase
examples of .gitlab-ci.yml
for different use cases of GitLab CI/CD. They also cover specific syntax that could
be used for different scenarios.
CI Architecture overview
The following is a simplified diagram of the CI architecture. Some details are left out to focus on the main components.
On the left side we have the events that can trigger a pipeline based on various events (triggered by a user or automation):
- A
git push
is the most common event that triggers a pipeline. - The Web API.
- A user selecting the “Run pipeline” button in the UI.
- When a merge request is created or updated.
- When an MR is added to a Merge Train.
- A scheduled pipeline.
- When project is subscribed to an upstream project.
- When Auto DevOps is enabled.
- When GitHub integration is used with external pull requests.
- When an upstream pipeline contains a bridge job which triggers a downstream pipeline.
Triggering any of these events invokes the CreatePipelineService
which takes as input event data and the user triggering it, then attempts to create a pipeline.
The CreatePipelineService
relies heavily on the YAML Processor
component, which is responsible for taking in a YAML blob as input and returns the abstract data structure of a
pipeline (including stages and all jobs). This component also validates the structure of the YAML while
processing it, and returns any syntax or semantic errors. The YAML Processor
component is where we define
all the keywords available to structure a pipeline.
The CreatePipelineService
receives the abstract data structure returned by the YAML Processor
,
which then converts it to persisted models (like pipeline, stages, and jobs). After that, the pipeline is ready
to be processed. Processing a pipeline means running the jobs in order of execution (stage or DAG)
until either one of the following:
- All expected jobs have been executed.
- Failures interrupt the pipeline execution.
The component that processes a pipeline is ProcessPipelineService
,
which is responsible for moving all the pipeline’s jobs to a completed state. When a pipeline is created, all its
jobs are initially in created
state. This services looks at what jobs in created
stage are eligible
to be processed based on the pipeline structure. Then it moves them into the pending
state, which means
they can now be picked up by a runner. After a job has been executed it can complete
successfully or fail. Each status transition for job within a pipeline triggers this service again, which
looks for the next jobs to be transitioned towards completion. While doing that, ProcessPipelineService
updates the status of jobs, stages and the overall pipeline.
On the right side of the diagram we have a list of runners
connected to the GitLab instance. These can be shared runners, group runners, or project runners.
The communication between runners and the Rails server occurs through a set of API endpoints, grouped as
the Runner API Gateway
.
We can register, delete, and verify runners, which also causes read/write queries to the database. After a runner is connected,
it keeps asking for the next job to execute. This invokes the RegisterJobService
which picks the next job and assigns it to the runner. At this point the job transitions to a
running
state, which again triggers ProcessPipelineService
due to the status change.
For more details read Job scheduling).
While a job is being executed, the runner sends logs back to the server as well any possible artifacts that must be stored. Also, a job may depend on artifacts from previous jobs to run. In this case the runner downloads them using a dedicated API endpoint.
Artifacts are stored in object storage, while metadata is kept in the database. An important example of artifacts are reports (like JUnit, SAST, and DAST) which are parsed and rendered in the merge request.
Job status transitions are not all automated. A user may run manual jobs, cancel a pipeline, retry
specific failed jobs or the entire pipeline. Anything that
causes a job to change status triggers ProcessPipelineService
, as it’s responsible for
tracking the status of the entire pipeline.
A special type of job is the bridge job which is executed server-side
when transitioning to the pending
state. This job is responsible for creating a downstream pipeline, such as
a multi-project or child pipeline. The workflow loop starts again
from the CreatePipelineService
every time a downstream pipeline is triggered.
You can watch a walkthrough of the architecture in CI Backend Architectural Walkthrough.
Job scheduling
When a Pipeline is created all its jobs are created at once for all stages, with an initial state of created
. This makes it possible to visualize the full content of a pipeline.
A job with the created
state isn’t seen by the runner yet. To make it possible to assign a job to a runner, the job must transition first into the pending
state, which can happen if:
- The job is created in the very first stage of the pipeline.
- The job required a manual start and it has been triggered.
- All jobs from the previous stage have completed successfully. In this case we transition all jobs from the next stage to
pending
. - The job specifies DAG dependencies using
needs:
and all the dependent jobs are completed. - The job has not been dropped because of its not-runnable state by
Ci::PipelineCreation::DropNotRunnableBuildsService
.
When the runner is connected, it requests the next pending
job to run by polling the server continuously.
lib/api/ci/runner.rb
After the server receives the request it selects a pending
job based on the Ci::RegisterJobService
algorithm, then assigns and sends the job to the runner.
Once all jobs are completed for the current stage, the server “unlocks” all the jobs from the next stage by changing their state to pending
. These can now be picked by the scheduling algorithm when the runner requests new jobs, and continues like this until all stages are completed.
Communication between runner and GitLab server
After the runner is registered using the registration token, the server knows what type of jobs it can execute. This depends on:
- The type of runner it is registered as:
- a shared runner
- a group runner
- a project runner
- Any associated tags.
The runner initiates the communication by requesting jobs to execute with POST /api/v4/jobs/request
. Although polling happens every few seconds, we leverage caching through HTTP headers to reduce the server-side work load if the job queue doesn’t change.
This API endpoint runs Ci::RegisterJobService
, which:
- Picks the next job to run from the pool of
pending
jobs - Assigns it to the runner
- Presents it to the runner via the API response
Ci::RegisterJobService
There are 3 top level queries that this service uses to gather the majority of the jobs and they are selected based on the level where the runner is registered to:
- Select jobs for shared runner (instance level)
- Utilizes a fair scheduling algorithm which prioritizes projects with fewer running builds
- Select jobs for group runner
- Select jobs for project runner
This list of jobs is then filtered further by matching tags between job and runner tags.
Finally if the runner can only pick jobs that are tagged, all untagged jobs are filtered out.
At this point we loop through remaining pending
jobs and we try to assign the first job that the runner “can pick” based on additional policies. For example, runners marked as protected
can only pick jobs that run against protected branches (such as production deployments).
As we increase the number of runners in the pool we also increase the chances of conflicts which would arise if assigning the same job to different runners. To prevent that we gracefully rescue conflict errors and assign the next job in the list.
Dropping stuck builds
There are two ways of marking builds as “stuck” and drop them.
- When a build is created,
Ci::PipelineCreation::DropNotRunnableBuildsService
checks for upfront known conditions that would make jobs not executable:- If there is not enough CI/CD Minutes to run the build, then the build is immediately dropped with
ci_quota_exceeded
. -
In the future, if the project is not on the plan that available runners for the build require via
allowed_plans
, then the build is immediately dropped withno_matching_runner
.
- If there is not enough CI/CD Minutes to run the build, then the build is immediately dropped with
- If there is no available Runner to pick up a build, it is dropped after 1 hour by
Ci::StuckBuilds::DropPendingService
.- If a job is not picked up by a runner in 24 hours it is automatically removed from the processing queue after that time.
- If a pending job is stuck, when there is no runner available that can process it, it is removed from the queue after 1 hour.
- In both cases the job’s status is changed to
failed
with an appropriate failure reason.
The reason behind this difference
CI Minutes quota mechanism is handled early when the job is created because it is a constant decision for most of the time. Once a project exceeds the limit, every next job matching it will be applicable for it until next month starts. Of course, the project owner can buy additional minutes, but that is a manual action that the project need to take.
The same mechanism will be used for allowed_plans
soon.
If the project is not on the required plan and a job is targeting such runner,
it will be failing constantly until the project owner changes the configuration or upgrades the namespace to the required plan.
These two mechanisms are also very SaaS specific and at the same time are quite compute expensive when we consider SaaS’ scale. Doing the check before the job is even transitioned to pending and failing early makes a lot of sense here.
Why we don’t handle other cases for pending and drop jobs early? In some cases, a job is in pending only because the runner is slow on taking up jobs. This is not something that you can know at GitLab level. Depending on the runner’s configuration and capacity and the size of the queue in GitLab, a job may be taken immediately, or may need to wait.
There may be also other reasons:
- you are handling runner maintenance and it’s not available for a while at all,
- you are updating configuration and by mistake, you’ve messed up the tagging and/or protected flag (or in the case of our SaaS instance runners; you’ve assigned a wrong cost factor or
allowed_plans
configuration).
All of that are problems that may be temporary and mostly are not expected to happen and are expected to be detected and fixed early. We definitely don’t want to drop jobs immediately when one of these conditions is happening. Dropping a job only because a runner is at capacity or because there is a temporary unavailability/configuration mistake would be very harmful to users.
The definition of “Job” in GitLab CI/CD
“Job” in GitLab CI context refers a task to drive Continuous Integration, Delivery and Deployment. Typically, a pipeline contains multiple stages, and a stage contains multiple jobs.
In Active Record modeling, Job is defined as CommitStatus
class.
On top of that, we have the following types of jobs:
-
Ci::Build
… The job to be executed by runners. -
Ci::Bridge
… The job to trigger a downstream pipeline. -
GenericCommitStatus
… The job to be executed in an external CI/CD system, for example Jenkins.
When you use the “Job” terminology in codebase, readers would
assume that the class/object is any type of above.
If you specifically refer Ci::Build
class, you should not name the object/class
as “job” as this could cause some confusions. In documentation,
we should use “Job” in general, instead of “Build”.
We have a few inconsistencies in our codebase that should be refactored.
For example, CommitStatus
should be Ci::Job
and Ci::JobArtifact
should be Ci::BuildArtifact
.
See this issue for the full refactoring plan.
Compute quota
Renamed from “CI/CD minutes” to “compute quota” and “compute minutes” in GitLab 16.1.
This diagram shows how the Compute quota feature and its components work.
Watch a walkthrough of this feature in details in the video below.