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New upstream version 12.8.6
2020-03-13 15:44:24 +05:30
# Geo self-service framework (alpha)
NOTE: **Note:** This document might be subjected to change. It's a
proposal we're working on and once the implementation is complete this
documentation will be updated. Follow progress in the
[epic](https://gitlab.com/groups/gitlab-org/-/epics/2161).
NOTE: **Note:** The Geo self-service framework is currently in
alpha. If you need to replicate a new data type, reach out to the Geo
team to discuss the options. You can contact them in `#g_geo` on Slack
or mention `@geo-team` in the issue or merge request.
Geo provides an API to make it possible to easily replicate data types
across Geo nodes. This API is presented as a Ruby Domain-Specific
Language (DSL) and aims to make it possible to replicate data with
minimal effort of the engineer who created a data type.
## Nomenclature
Before digging into the API, developers need to know some Geo-specific
naming conventions.
Model
: A model is an Active Model, which is how it is known in the entire
Rails codebase. It usually is tied to a database table. From Geo
perspective, a model can have one or more resources.
Resource
: A resource is a piece of data that belongs to a model and is
produced by a GitLab feature. It is persisted using a storage
mechanism. By default, a resource is not a replicable.
Data type
: Data type is how a resource is stored. Each resource should
fit in one of the data types Geo supports:
:- Git repository
:- Blob
:- Database
: For more detail, see [Data types](../../administration/geo/replication/datatypes.md).
Geo Replicable
: A Replicable is a resource Geo wants to sync across Geo nodes. There
is a limited set of supported data types of replicables. The effort
required to implement replication of a resource that belongs to one
of the known data types is minimal.
Geo Replicator
: A Geo Replicator is the object that knows how to replicate a
replicable. It's responsible for:
:- Firing events (producer)
:- Consuming events (consumer)
: It's tied to the Geo Replicable data type. All replicators have a
common interface that can be used to process (that is, produce and
consume) events. It takes care of the communication between the
primary node (where events are produced) and the secondary node
(where events are consumed). The engineer who wants to incorporate
Geo in their feature will use the API of replicators to make this
happen.
Geo Domain-Specific Language
: The syntactic sugar that allows engineers to easily specify which
resources should be replicated and how.
## Geo Domain-Specific Language
### The replicator
First of all, you need to write a replicator. The replicators live in
[`ee/app/replicators/geo`](https://gitlab.com/gitlab-org/gitlab/-/tree/master/ee/app/replicators/geo).
For each resource that needs to be replicated, there should be a
separate replicator specified, even if multiple resources are tied to
the same model.
For example, the following replicator replicates a package file:
```ruby
module Geo
class PackageFileReplicator < Gitlab::Geo::Replicator
# Include one of the strategies your resource needs
include ::Geo::BlobReplicatorStrategy
# Specify the CarrierWave uploader needed by the used strategy
def carrierwave_uploader
model_record.file
end
private
# Specify the model this replicator belongs to
def model
::Packages::PackageFile
end
end
end
```
The class name should be unique. It also is tightly coupled to the
table name for the registry, so for this example the registry table
will be `package_file_registry`.
For the different data types Geo supports there are different
strategies to include. Pick one that fits your needs.
### Linking to a model
To tie this replicator to the model, you need to add the following to
the model code:
```ruby
class Packages::PackageFile < ApplicationRecord
include ::Gitlab::Geo::ReplicableModel
with_replicator Geo::PackageFileReplicator
end
```
### API
When this is set in place, it's easy to access the replicator through
the model:
```ruby
package_file = Packages::PackageFile.find(4) # just a random id as example
replicator = package_file.replicator
```
Or get the model back from the replicator:
```ruby
replicator.model_record
=> <Packages::PackageFile id:4>
```
The replicator can be used to generate events, for example in
ActiveRecord hooks:
```ruby
after_create_commit -> { replicator.publish_created_event }
```
#### Library
The framework behind all this is located in
[`ee/lib/gitlab/geo/`](https://gitlab.com/gitlab-org/gitlab/-/tree/master/ee/lib/gitlab/geo).
New upstream version 12.9.2
2020-04-08 14:13:33 +05:30
## Existing Replicator Strategies
Before writing a new kind of Replicator Strategy, check below to see if your
resource can already be handled by one of the existing strategies. Consult with
the Geo team if you are unsure.
### Blob Replicator Strategy
Models that use
[CarrierWave's](https://github.com/carrierwaveuploader/carrierwave) `Uploader::Base`
can be easily supported by Geo with the `Geo::BlobReplicatorStrategy` module.
First, each file should have its own primary ID and model. Geo strongly
recommends treating *every single file* as a first-class citizen, because in
our experience this greatly simplifies tracking replication and verification
state.
For example, to add support for files referenced by a `Widget` model with a
`widgets` table, you would perform the following steps:
1. Add verification state fields to the `widgets` table so the Geo primary can
track verification state:
```ruby
# frozen_string_literal: true
class AddVerificationStateToWidgets < ActiveRecord::Migration[6.0]
DOWNTIME = false
def change
add_column :widgets, :verification_retry_at, :datetime_with_timezone
add_column :widgets, :last_verification_ran_at, :datetime_with_timezone
add_column :widgets, :verification_checksum, :string
add_column :widgets, :verification_failure, :string
add_column :widgets, :verification_retry_count, :integer
end
end
```
1. Add a partial index on `verification_failure` to ensure re-verification can
be performed efficiently:
```ruby
# frozen_string_literal: true
class AddVerificationFailureIndexToWidgets < ActiveRecord::Migration[6.0]
include Gitlab::Database::MigrationHelpers
DOWNTIME = false
disable_ddl_transaction!
def up
add_concurrent_index :widgets, :verification_failure, where: "(verification_failure IS NOT NULL)", name: "widgets_verification_failure_partial"
end
def down
remove_concurrent_index :widgets, :verification_failure
end
end
```
1. Include `Gitlab::Geo::ReplicableModel` in the `Widget` class, and specify
the Replicator class `with_replicator Geo::WidgetReplicator`.
At this point the `Widget` class should look like this:
```ruby
# frozen_string_literal: true
class Widget < ApplicationRecord
include ::Gitlab::Geo::ReplicableModel
with_replicator Geo::WidgetReplicator
mount_uploader :file, WidgetUploader
...
end
```
1. Create `ee/app/replicators/geo/widget_replicator.rb`. Implement the
`#carrierwave_uploader` method which should return a `CarrierWave::Uploader`.
And implement the private `#model` method to return the `Widget` class.
```ruby
# frozen_string_literal: true
module Geo
class WidgetReplicator < Gitlab::Geo::Replicator
include ::Geo::BlobReplicatorStrategy
def carrierwave_uploader
model_record.file
end
private
def model
::Widget
end
end
end
```
1. Create `ee/spec/replicators/geo/widget_replicator_spec.rb` and perform
the setup necessary to define the `model_record` variable for the shared
examples.
```ruby
# frozen_string_literal: true
require 'spec_helper'
describe Geo::WidgetReplicator do
let(:model_record) { build(:widget) }
it_behaves_like 'a blob replicator'
end
```
1. Create the `widget_registry` table so Geo secondaries can track the sync and
verification state of each Widget's file:
```ruby
# frozen_string_literal: true
class CreateWidgetRegistry < ActiveRecord::Migration[5.2]
DOWNTIME = false
def change
create_table :widget_registry, id: :serial, force: :cascade do |t|
t.integer :widget_id, null: false
t.integer :state, default: 0, null: false
t.integer :retry_count, default: 0
t.string :last_sync_failure, limit: 255
t.datetime_with_timezone :retry_at
t.datetime_with_timezone :last_synced_at
t.datetime_with_timezone :created_at, null: false
t.index :widget_id, name: :index_widget_registry_on_repository_id, using: :btree
t.index :retry_at, name: :index_widget_registry_on_retry_at, using: :btree
t.index :state, name: :index_widget_registry_on_state, using: :btree
end
end
end
```
1. Create `ee/app/models/geo/widget_registry.rb`:
```ruby
# frozen_string_literal: true
class Geo::WidgetRegistry < Geo::BaseRegistry
include Geo::StateMachineRegistry
belongs_to :widget, class_name: 'Widget'
end
```
1. Create `ee/spec/factories/geo/widget_registry.rb`:
```ruby
# frozen_string_literal: true
FactoryBot.define do
factory :widget_registry, class: 'Geo::WidgetRegistry' do
widget
state { Geo::WidgetRegistry.state_value(:pending) }
trait :synced do
state { Geo::WidgetRegistry.state_value(:synced) }
last_synced_at { 5.days.ago }
end
trait :failed do
state { Geo::WidgetRegistry.state_value(:failed) }
last_synced_at { 1.day.ago }
retry_count { 2 }
last_sync_failure { 'Random error' }
end
trait :started do
state { Geo::WidgetRegistry.state_value(:started) }
last_synced_at { 1.day.ago }
retry_count { 0 }
end
end
end
```
1. Create `ee/spec/models/geo/widget_registry.rb`:
```ruby
# frozen_string_literal: true
require 'spec_helper'
describe Geo::WidgetRegistry, :geo, type: :model do
let_it_be(:registry) { create(:widget_registry) }
specify 'factory is valid' do
expect(registry).to be_valid
end
end
```
Widget files should now be replicated and verified by Geo!
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