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Object Storage
GitLab supports using an object storage service for holding numerous types of data. It's recommended over NFS and in general it's better in larger setups as object storage is typically much more performant, reliable, and scalable.
Options
GitLab has been tested on a number of object storage providers:
- Amazon S3
- Google Cloud Storage
- Digital Ocean Spaces
- Oracle Cloud Infrastructure
- Openstack Swift
- Azure Blob storage
- On-premises hardware and appliances from various storage vendors.
- MinIO. We have a guide to deploying this within our Helm Chart documentation.
Known compatibility issues
- Dell EMC ECS: Prior to GitLab 13.3, there is a known bug in GitLab Workhorse that prevents HTTP Range Requests from working with CI job artifacts. Be sure to upgrade to GitLab v13.3.0 or above if you use S3 storage with this hardware.
Configuration guides
There are two ways of specifying object storage configuration in GitLab:
- Consolidated form: A single credential is shared by all supported object types.
- Storage-specific form: Every object defines its own object storage connection and configuration.
For more information on the differences and to transition from one form to another, see Transition to consolidated form.
Consolidated object storage configuration
Introduced in GitLab 13.2.
Using the consolidated object storage configuration has a number of advantages:
- It can simplify your GitLab configuration since the connection details are shared across object types.
- It enables the use of encrypted S3 buckets.
- It uploads files to S3 with proper
Content-MD5
headers.
Because direct upload mode must be enabled, only the following providers can be used:
Background upload is not supported with the consolidated object storage configuration. We recommend enabling direct upload mode because it does not require a shared folder, and this setting may become the default.
NOTE: Note: Consolidated object storage configuration cannot be used for backups or Mattermost. See the full table for a complete list.
NOTE: Note: Enabling consolidated object storage will enable object storage for all object types. If you wish to use local storage for specific object types, you can selectively disable object storages.
Most types of objects, such as CI artifacts, LFS files, upload attachments, and so on can be saved in object storage by specifying a single credential for object storage with multiple buckets. A different bucket for each type must be used.
When the consolidated form is:
- Used with an S3-compatible object storage, Workhorse uses its internal S3 client to upload files.
- Not used with an S3-compatible object storage, Workhorse falls back to using pre-signed URLs.
See the section on ETag mismatch errors for more details.
In Omnibus installations:
-
Edit
/etc/gitlab/gitlab.rb
and add the following lines, substituting the values you want:# Consolidated object storage configuration gitlab_rails['object_store']['enabled'] = true gitlab_rails['object_store']['proxy_download'] = true gitlab_rails['object_store']['connection'] = { 'provider' => 'AWS', 'region' => '<eu-central-1>', 'aws_access_key_id' => '<AWS_ACCESS_KEY_ID>', 'aws_secret_access_key' => '<AWS_SECRET_ACCESS_KEY>' } # OPTIONAL: The following lines are only needed if server side encryption is required gitlab_rails['object_store']['storage_options'] = { 'server_side_encryption' => '<AES256 or aws:kms>', 'server_side_encryption_kms_key_id' => '<arn:s3:aws:xxx>' } gitlab_rails['object_store']['objects']['artifacts']['bucket'] = '<artifacts>' gitlab_rails['object_store']['objects']['external_diffs']['bucket'] = '<external-diffs>' gitlab_rails['object_store']['objects']['lfs']['bucket'] = '<lfs-objects>' gitlab_rails['object_store']['objects']['uploads']['bucket'] = '<uploads>' gitlab_rails['object_store']['objects']['packages']['bucket'] = '<packages>' gitlab_rails['object_store']['objects']['dependency_proxy']['bucket'] = '<dependency-proxy>' gitlab_rails['object_store']['objects']['terraform_state']['bucket'] = '<terraform-state>'
NOTE: For GitLab 9.4 or later, if you're using AWS IAM profiles, be sure to omit the AWS access key and secret access key/value pairs. For example:
gitlab_rails['object_store']['connection'] = { 'provider' => 'AWS', 'region' => '<eu-central-1>', 'use_iam_profile' => true }
-
Save the file and reconfigure GitLab for the changes to take effect.
In installations from source:
-
Edit
/home/git/gitlab/config/gitlab.yml
and add or amend the following lines:object_store: enabled: true proxy_download: true connection: provider: AWS aws_access_key_id: <AWS_ACCESS_KEY_ID> aws_secret_access_key: <AWS_SECRET_ACCESS_KEY> region: <eu-central-1> storage_options: server_side_encryption: <AES256 or aws:kms> server_side_encryption_key_kms_id: <arn:s3:aws:xxx> objects: artifacts: bucket: <artifacts> external_diffs: bucket: <external-diffs> lfs: bucket: <lfs-objects> uploads: bucket: <uploads> packages: bucket: <packages> dependency_proxy: bucket: <dependency_proxy> terraform_state: bucket: <terraform>
-
Edit
/home/git/gitlab-workhorse/config.toml
and add or amend the following lines:[object_storage] provider = "AWS" [object_storage.s3] aws_access_key_id = "<AWS_ACCESS_KEY_ID>" aws_secret_access_key = "<AWS_SECRET_ACCESS_KEY>"
-
Save the file and restart GitLab for the changes to take effect.
Common parameters
In the consolidated configuration, the object_store
section defines a
common set of parameters. Here we use the YAML from the source
installation because it's easier to see the inheritance:
object_store:
enabled: true
proxy_download: true
connection:
provider: AWS
aws_access_key_id: <AWS_ACCESS_KEY_ID>
aws_secret_access_key: <AWS_SECRET_ACCESS_KEY>
objects:
...
The Omnibus configuration maps directly to this:
gitlab_rails['object_store']['enabled'] = true
gitlab_rails['object_store']['proxy_download'] = true
gitlab_rails['object_store']['connection'] = {
'provider' => 'AWS',
'aws_access_key_id' => '<AWS_ACCESS_KEY_ID',
'aws_secret_access_key' => '<AWS_SECRET_ACCESS_KEY>'
}
Setting | Description |
---|---|
enabled |
Enable/disable object storage |
proxy_download |
Set to true to enable proxying all files served. Option allows to reduce egress traffic as this allows clients to download directly from remote storage instead of proxying all data |
connection |
Various connection options described below |
storage_options |
Options to use when saving new objects, such as server side encryption. Introduced in GitLab 13.3 |
objects |
Object-specific configuration |
Connection settings
Both consolidated configuration form and storage-specific configuration form must configure a connection. The following sections describe parameters that can be used
in the connection
setting.
S3-compatible connection settings
The connection settings match those provided by fog-aws:
Setting | Description | Default |
---|---|---|
provider |
Always AWS for compatible hosts |
AWS |
aws_access_key_id |
AWS credentials, or compatible | |
aws_secret_access_key |
AWS credentials, or compatible | |
aws_signature_version |
AWS signature version to use. 2 or 4 are valid options. Digital Ocean Spaces and other providers may need 2 . |
4 |
enable_signature_v4_streaming |
Set to true to enable HTTP chunked transfers with AWS v4 signatures. Oracle Cloud S3 needs this to be false . |
true |
region |
AWS region | us-east-1 |
host |
S3 compatible host for when not using AWS, e.g. localhost or storage.example.com . HTTPS and port 443 is assumed. |
s3.amazonaws.com |
endpoint |
Can be used when configuring an S3 compatible service such as MinIO, by entering a URL such as http://127.0.0.1:9000 . This takes precedence over host . |
(optional) |
path_style |
Set to true to use host/bucket_name/object style paths instead of bucket_name.host/object . Leave as false for AWS S3. |
false |
use_iam_profile |
Set to true to use IAM profile instead of access keys |
false |
Oracle Cloud S3 connection settings
Note that Oracle Cloud S3 must be sure to use the following settings:
Setting | Value |
---|---|
enable_signature_v4_streaming |
false |
path_style |
true |
If enable_signature_v4_streaming
is set to true
, you may see the
following error in production.log
:
STREAMING-AWS4-HMAC-SHA256-PAYLOAD is not supported
Google Cloud Storage (GCS)
Here are the valid connection parameters for GCS:
Setting | Description | example |
---|---|---|
provider |
The provider name | Google |
google_project |
GCP project name | gcp-project-12345 |
google_client_email |
The email address of the service account | foo@gcp-project-12345.iam.gserviceaccount.com |
google_json_key_location |
The JSON key path | /path/to/gcp-project-12345-abcde.json |
NOTE: Note: The service account must have permission to access the bucket. See more
Google example (consolidated form)
For Omnibus installations, this is an example of the connection
setting:
gitlab_rails['object_store']['connection'] = {
'provider' => 'Google',
'google_project' => '<GOOGLE PROJECT>',
'google_client_email' => '<GOOGLE CLIENT EMAIL>',
'google_json_key_location' => '<FILENAME>'
}
Azure Blob storage
Introduced in GitLab 13.4.
Although Azure uses the word container
to denote a collection of
blobs, GitLab standardizes on the term bucket
. Be sure to configure
Azure container names in the bucket
settings.
The following are the valid connection parameters for Azure. Read the Azure Blob storage documentation to learn more.
Setting | Description | Example |
---|---|---|
provider |
Provider name | AzureRM |
azure_storage_account_name |
Name of the Azure Blob Storage account used to access the storage | azuretest |
azure_storage_access_key |
Storage account access key used to access the container. This is typically a secret, 512-bit encryption key encoded in base64. | czV2OHkvQj9FKEgrTWJRZVRoV21ZcTN0Nnc5eiRDJkYpSkBOY1JmVWpYbjJy\nNHU3eCFBJUQqRy1LYVBkU2dWaw==\n |
azure_storage_domain |
Domain name used to contact the Azure Blob Storage API (optional). Defaults to blob.core.windows.net . Set this if you are using Azure China, Azure Germany, Azure US Government, or some other custom Azure domain. |
blob.core.windows.net |
Azure example (consolidated form)
For Omnibus installations, this is an example of the connection
setting:
gitlab_rails['object_store']['connection'] = {
'provider' => 'AzureRM',
'azure_storage_account_name' => '<AZURE STORAGE ACCOUNT NAME>',
'azure_storage_access_key' => '<AZURE STORAGE ACCESS KEY>',
'azure_storage_domain' => '<AZURE STORAGE DOMAIN>',
}
Azure Workhorse settings (source installs only)
NOTE: Note: For source installations, Workhorse needs to be configured with the Azure credentials as well. This is not needed in Omnibus installs because the Workhorse settings are populated from the settings above.
-
Edit
/home/git/gitlab-workhorse/config.toml
and add or amend the following lines:[object_storage] provider = "AzureRM" [object_storage.azurerm] azure_storage_account_name = "<AZURE STORAGE ACCOUNT NAME>" azure_storage_access_key = "<AZURE STORAGE ACCESS KEY>"
If you are using a custom Azure storage domain, note that
azure_storage_domain
does not have to be set in the Workhorse
configuration. This information is exchanged in an API call between
GitLab Rails and Workhorse.
OpenStack-compatible connection settings
NOTE: Note: This is not compatible with the consolidated object storage form. OpenStack Swift is only supported with the storage-specific form. See the S3 settings if you want to use the consolidated form.
While OpenStack Swift provides S3 compatibility, some users may want to use the Swift API. Here are the valid connection settings below for the Swift API, provided by fog-openstack:
Setting | Description | Default |
---|---|---|
provider |
Always OpenStack for compatible hosts |
OpenStack |
openstack_username |
OpenStack username | |
openstack_api_key |
OpenStack API key | |
openstack_temp_url_key |
OpenStack key for generating temporary URLs | |
openstack_auth_url |
OpenStack authentication endpoint | |
openstack_region |
OpenStack region | |
openstack_tenant |
OpenStack tenant ID |
Rackspace Cloud Files
NOTE: Note: This is not compatible with the consolidated object storage form. Rackspace Cloud is only supported with the storage-specific form.
Here are the valid connection parameters for Rackspace Cloud, provided by fog-rackspace:
Setting | Description | example |
---|---|---|
provider |
The provider name | Rackspace |
rackspace_username |
The username of the Rackspace account with access to the container | joe.smith |
rackspace_api_key |
The API key of the Rackspace account with access to the container | ABC123DEF456ABC123DEF456ABC123DE |
rackspace_region |
The Rackspace storage region to use, a three letter code from the list of service access endpoints | iad |
rackspace_temp_url_key |
The private key you have set in the Rackspace API for temporary URLs. | ABC123DEF456ABC123DEF456ABC123DE |
NOTE: Note:
Regardless of whether the container has public access enabled or disabled, Fog will
use the TempURL method to grant access to LFS objects. If you see errors in logs referencing
instantiating storage with a temp-url-key
, ensure that you have set the key properly
on the Rackspace API and in gitlab.rb
. You can verify the value of the key Rackspace
has set by sending a GET request with token header to the service access endpoint URL
and comparing the output of the returned headers.
Object-specific configuration
The following YAML shows how the object_store
section defines
object-specific configuration block and how the enabled
and
proxy_download
flags can be overriden. The bucket
is the only
required parameter within each type:
object_store:
connection:
...
objects:
artifacts:
bucket: artifacts
proxy_download: false
external_diffs:
bucket: external-diffs
lfs:
bucket: lfs-objects
uploads:
bucket: uploads
packages:
bucket: packages
dependency_proxy:
enabled: false
bucket: dependency_proxy
terraform_state:
bucket: terraform
This maps to this Omnibus GitLab configuration:
gitlab_rails['object_store']['objects']['artifacts']['bucket'] = 'artifacts'
gitlab_rails['object_store']['objects']['artifacts']['proxy_download'] = false
gitlab_rails['object_store']['objects']['external_diffs']['bucket'] = 'external-diffs'
gitlab_rails['object_store']['objects']['lfs']['bucket'] = 'lfs-objects'
gitlab_rails['object_store']['objects']['uploads']['bucket'] = 'uploads'
gitlab_rails['object_store']['objects']['packages']['bucket'] = 'packages'
gitlab_rails['object_store']['objects']['dependency_proxy']['enabled'] = false
gitlab_rails['object_store']['objects']['dependency_proxy']['bucket'] = 'dependency-proxy'
gitlab_rails['object_store']['objects']['terraform_state']['bucket'] = 'terraform-state'
This is the list of valid objects
that can be used:
Type | Description |
---|---|
artifacts |
CI artifacts |
external_diffs |
Merge request diffs |
uploads |
User uploads |
lfs |
Git Large File Storage objects |
packages |
Project packages (e.g. PyPI, Maven, NuGet, etc.) |
dependency_proxy |
GitLab Dependency Proxy |
terraform_state |
Terraform state files |
Within each object type, three parameters can be defined:
Setting | Required? | Description |
---|---|---|
bucket |
Yes | The bucket name for the object storage. |
enabled |
No | Overrides the common parameter |
proxy_download |
No | Overrides the common parameter |
Selectively disabling object storage
As seen above, object storage can be disabled for specific types by
setting the enabled
flag to false
. For example, to disable object
storage for CI artifacts:
gitlab_rails['object_store']['objects']['artifacts']['enabled'] = false
A bucket is not needed if the feature is disabled entirely. For example, no bucket is needed if CI artifacts are disabled with this setting:
gitlab_rails['artifacts_enabled'] = false
Transition to consolidated form
Prior to GitLab 13.2:
- Object storage configuration for all types of objects such as CI/CD artifacts, LFS files, upload attachments, and so on had to be configured independently.
- Object store connection parameters such as passwords and endpoint URLs had to be duplicated for each type.
For example, an Omnibus GitLab install might have the following configuration:
# Original object storage configuration
gitlab_rails['artifacts_object_store_enabled'] = true
gitlab_rails['artifacts_object_store_direct_upload'] = true
gitlab_rails['artifacts_object_store_proxy_download'] = true
gitlab_rails['artifacts_object_store_remote_directory'] = 'artifacts'
gitlab_rails['artifacts_object_store_connection'] = { 'provider' => 'AWS', 'aws_access_key_id' => 'access_key', 'aws_secret_access_key' => 'secret' }
gitlab_rails['uploads_object_store_enabled'] = true
gitlab_rails['uploads_object_store_direct_upload'] = true
gitlab_rails['uploads_object_store_proxy_download'] = true
gitlab_rails['uploads_object_store_remote_directory'] = 'uploads'
gitlab_rails['uploads_object_store_connection'] = { 'provider' => 'AWS', 'aws_access_key_id' => 'access_key', 'aws_secret_access_key' => 'secret' }
While this provides flexibility in that it makes it possible for GitLab to store objects across different cloud providers, it also creates additional complexity and unnecessary redundancy. Since both GitLab Rails and Workhorse components need access to object storage, the consolidated form avoids excessive duplication of credentials.
NOTE: Note:
The consolidated object storage configuration is only used if all
lines from the original form is omitted. To move to the consolidated form, remove the original configuration (for example, artifacts_object_store_enabled
, uploads_object_store_connection
, and so on.)
Storage-specific configuration
For configuring object storage in GitLab 13.1 and earlier, or for storage types not supported by consolidated configuration form, refer to the following guides:
Object storage type | Supported by consolidated configuration? |
---|---|
Backups | No |
Job artifacts including archived job logs | Yes |
LFS objects | Yes |
Uploads | Yes |
Container Registry (optional feature) | No |
Merge request diffs | Yes |
Mattermost | No |
Packages (optional feature) | Yes |
Dependency Proxy (optional feature) (PREMIUM ONLY) | Yes |
Pseudonymizer (optional feature) (ULTIMATE ONLY) | No |
Autoscale runner caching (optional for improved performance) | No |
Terraform state files | Yes |
Other alternatives to filesystem storage
If you're working to scale out your GitLab implementation, or add fault tolerance and redundancy, you may be looking at removing dependencies on block or network filesystems. See the following additional guides and note that Pages requires disk storage:
- Make sure the
git
user home directory is on local disk. - Configure database lookup of SSH keys
to eliminate the need for a shared
authorized_keys
file. - Prevent local disk usage for job logs.
Warnings, limitations, and known issues
Use separate buckets
Using separate buckets for each data type is the recommended approach for GitLab.
A limitation of our configuration is that each use of object storage is separately configured. We have an issue for improving this and easily using one bucket with separate folders is one improvement that this might bring.
There is at least one specific issue with using the same bucket: when GitLab is deployed with the Helm chart restore from backup will not properly function unless separate buckets are used.
One risk of using a single bucket would be that if your organisation decided to migrate GitLab to the Helm deployment in the future. GitLab would run, but the situation with backups might not be realised until the organisation had a critical requirement for the backups to work.
S3 API compatibility issues
Not all S3 providers are fully compatible
with the Fog library that GitLab uses. Symptoms include an error in production.log
:
411 Length Required
GitLab Pages requires NFS
If you're working to add more GitLab servers for scaling or fault tolerance and one of your requirements is GitLab Pages this currently requires NFS. There is work in progress to remove this dependency. In the future, GitLab Pages may use object storage.
The dependency on disk storage also prevents Pages being deployed using the GitLab Helm chart.
Incremental logging is required for CI to use object storage
If you configure GitLab to use object storage for CI logs and artifacts, you can avoid local disk usage for job logs by enabling beta incremental logging.
Proxy Download
Clients can download files in object storage by receiving a pre-signed, time-limited URL, or by GitLab proxying the data from object storage to the client. Downloading files from object storage directly helps reduce the amount of egress traffic GitLab needs to process.
When the files are stored on local block storage or NFS, GitLab has to act as a proxy. This is not the default behavior with object storage.
The proxy_download
setting controls this behavior: the default is generally false
.
Verify this in the documentation for each use case. Set it to true
if you want
GitLab to proxy the files.
When not proxying files, GitLab returns an HTTP 302 redirect with a pre-signed, time-limited object storage URL. This can result in some of the following problems:
-
If GitLab is using non-secure HTTP to access the object storage, clients may generate
https->http
downgrade errors and refuse to process the redirect. The solution to this is for GitLab to use HTTPS. LFS, for example, will generate this error:LFS: lfsapi/client: refusing insecure redirect, https->http
-
Clients will need to trust the certificate authority that issued the object storage certificate, or may return common TLS errors such as:
x509: certificate signed by unknown authority
-
Clients will need network access to the object storage. Network firewalls could block access. Errors that might result if this access is not in place include:
Received status code 403 from server: Forbidden
Getting a 403 Forbidden
response is specifically called out on the
package repository documentation
as a side effect of how some build tools work.
Additionally for a short time period users could share pre-signed, time-limited object storage URLs with others without authentication. Also bandwidth charges may be incurred between the object storage provider and the client.
ETag mismatch
Using the default GitLab settings, some object storage back-ends such as
MinIO
and Alibaba
might generate ETag mismatch
errors.
If you are seeing this ETag mismatch error with Amazon Web Services S3, it's likely this is due to encryption settings on your bucket. To fix this issue, you have two options:
The first option is recommended for MinIO. Otherwise, the
workaround for MinIO
is to use the --compat
parameter on the server.
Without consolidated object store configuration or instance profiles enabled,
GitLab Workhorse will upload files to S3 using pre-signed URLs that do
not have a Content-MD5
HTTP header computed for them. To ensure data
is not corrupted, Workhorse checks that the MD5 hash of the data sent
equals the ETag header returned from the S3 server. When encryption is
enabled, this is not the case, which causes Workhorse to report an ETag mismatch
error during an upload.
With the consolidated object configuration and instance profile, Workhorse has
S3 credentials so that it can compute the Content-MD5
header. This
eliminates the need to compare ETag headers returned from the S3 server.
Using Amazon instance profiles
Instead of supplying AWS access and secret keys in object storage configuration, GitLab can be configured to use IAM roles to set up an Amazon instance profile. When this is used, GitLab will fetch temporary credentials each time an S3 bucket is accessed, so no hard-coded values are needed in the configuration.
Encrypted S3 buckets
- Introduced in GitLab 13.1 for instance profiles only and S3 default encryption.
- Introduced in GitLab 13.2 for static credentials when consolidated object storage configuration and S3 default encryption are used.
When configured either with an instance profile or with the consolidated object configuration, GitLab Workhorse properly uploads files to S3 buckets that have SSE-S3 or SSE-KMS encryption enabled by default. Note that customer master keys (CMKs) and SSE-C encryption are not supported since this requires sending the encryption keys in every request.
Server-side encryption headers
Introduced in GitLab 13.3.
Setting a default encryption on an S3 bucket is the easiest way to
enable encryption, but you may want to set a bucket policy to ensure
only encrypted objects are uploaded.
To do this, you must configure GitLab to send the proper encryption headers
in the storage_options
configuration section:
Setting | Description |
---|---|
server_side_encryption |
Encryption mode (AES256 or aws:kms) |
server_side_encryption_kms_key_id |
Amazon Resource Name. Only needed when aws:kms is used in server_side_encryption . See the Amazon documentation on using KMS encryption |
As with the case for default encryption, these options only work when the Workhorse S3 client is enabled. One of the following two conditions must be fulfilled:
use_iam_profile
istrue
in the connection settings.- Consolidated object storage settings are in use.
ETag mismatch errors will occur if server side encryption headers are used without enabling the Workhorse S3 client.
Disabling the feature
The Workhorse S3 client is enabled by default when the
use_iam_profile
configuration option is set to true
or consolidated
object storage settings are configured.
The feature can be disabled using the :use_workhorse_s3_client
feature flag. To disable the
feature, ask a GitLab administrator with
Rails console access to run the
following command:
Feature.disable(:use_workhorse_s3_client)
IAM Permissions
To set up an instance profile:
-
Create an Amazon Identity Access and Management (IAM) role with the necessary permissions. The following example is a role for an S3 bucket named
test-bucket
:{ "Version": "2012-10-17", "Statement": [ { "Sid": "VisualEditor0", "Effect": "Allow", "Action": [ "s3:PutObject", "s3:GetObject", "s3:AbortMultipartUpload", "s3:DeleteObject" ], "Resource": "arn:aws:s3:::test-bucket/*" } ] }
-
Attach this role to the EC2 instance hosting your GitLab instance.
-
Configure GitLab to use it via the
use_iam_profile
configuration option.