The following security review of the Geo feature set focuses on security aspects of
the feature as they apply to customers running their own GitLab instances. The review
questions are based in part on the [OWASP Application Security Verification Standard Project](https://www.owasp.org/index.php/Category:OWASP_Application_Security_Verification_Standard_Project)
from [owasp.org](https://www.owasp.org/index.php/Main_Page).
- There are significant dependencies on the system-installed OpenSSH daemon (Geo
requires users to set up custom authentication methods) and the omnibus or
system-provided PostgreSQL daemon (it must be configured to listen on TCP,
additional users and replication slots must be added, etc).
- The process for dealing with security updates (for example, if there is a
significant vulnerability in OpenSSH or other services, and the customer
wants to patch those services on the OS) is identical to the non-Geo
situation: security updates to OpenSSH would be provided to the user via the
usual distribution channels. Geo introduces no delay there.
## Infrastructure Monitoring
### What network and system performance monitoring requirements have been defined?
- None specific to Geo.
### What mechanisms exist to detect malicious code or compromised application components?
- None specific to Geo.
### What network and system security monitoring requirements have been defined?
- None specific to Geo.
## Virtualization and Externalization
### What aspects of the application lend themselves to virtualization?
- All.
## What virtualization requirements have been defined for the application?
- Nothing Geo-specific, but everything in GitLab needs to have full
functionality in such an environment.
### What aspects of the product may or may not be hosted via the cloud computing model?
- GitLab is “cloud native” and this applies to Geo as much as to the rest of the
product. Deployment in clouds is a common and supported scenario.
## If applicable, what approach(es) to cloud computing will be taken (Managed Hosting versus "Pure" Cloud, a "full machine" approach such as AWS-EC2 versus a "hosted database" approach such as AWS-RDS and Azure, etc)?
- To be decided by our customers, according to their operational needs.
## Environment
### What frameworks and programming languages have been used to create the application?
- Ruby on Rails, Ruby.
### What process, code, or infrastructure dependencies have been defined for the application?
- Nothing specific to Geo.
### What databases and application servers support the application?
- PostgreSQL >= 9.6, Redis, Sidekiq, Unicorn.
### How will database connection strings, encryption keys, and other sensitive components be stored, accessed, and protected from unauthorized detection?
- There are some Geo-specific values. Some are shared secrets which must be
securely transmitted from the **primary** node to the **secondary** node at setup time. Our
documentation recommends transmitting them from the **primary** node to the system
administrator via SSH, and then back out to the **secondary** node in the same manner.
In particular, this includes the PostgreSQL replication credentials and a secret
key (`db_key_base`) which is used to decrypt certain columns in the database.
The `db_key_base` secret is stored unencrypted on the filesystem, in
`/etc/gitlab/gitlab-secrets.json`, along with a number of other secrets. There is
no at-rest protection for them.
## Data Processing
### What data entry paths does the application support?
- Data is entered via the web application exposed by GitLab itself. Some data is
also entered using system administration commands on the GitLab servers (e.g.,
`gitlab-ctl set-primary-node`).
- **Secondary** nodes also receive inputs via PostgreSQL streaming replication from the **primary** node.
### What data output paths does the application support?
- **Primary** nodes output via PostgreSQL streaming replication to the **secondary** node.
Otherwise, principally via the web application exposed by GitLab itself, and via
SSH `git clone` operations initiated by the end-user.
### How does data flow across the application's internal components?
- **Secondary** nodes and **primary** nodes interact via HTTP/HTTPS (secured with JSON web
tokens) and via PostgreSQL streaming replication.
- Within a **primary** node or **secondary** node, the SSOT is the filesystem and the database
(including Geo tracking database on **secondary** node). The various internal components
are orchestrated to make alterations to these stores.
### What data input validation requirements have been defined?
- **Secondary** nodes must have a faithful replication of the **primary** node’s data.
### What data does the application store and how?
- Git repositories and files, tracking information related to the them, and the GitLab database contents.
### What data is or may need to be encrypted and what key management requirements have been defined?
- Neither **primary** nodes or **secondary** nodes encrypt Git repository or filesystem data at
rest. A subset of database columns are encrypted at rest using the `db_otp_key`.
- A static secret shared across all hosts in a GitLab deployment.
- In transit, data should be encrypted, although the application does permit
communication to proceed unencrypted. The two main transits are the **secondary** node’s
be protected using TLS, with the keys for that managed via Omnibus per existing
configuration for end-user access to GitLab.
### What capabilities exist to detect the leakage of sensitive data?
- Comprehensive system logs exist, tracking every connection to GitLab and PostgreSQL.
### What encryption requirements have been defined for data in transit - including transmission over WAN, LAN, SecureFTP, or publicly accessible protocols such as http: and https:?
- Data must have the option to be encrypted in transit, and be secure against
both passive and active attack (e.g., MITM attacks should not be possible).
## Access
### What user privilege levels does the application support?
- Geo adds one type of privilege: **secondary** nodes can access a special Geo API to
download files over HTTP/HTTPS, and to clone repositories using HTTP/HTTPS.
### What user identification and authentication requirements have been defined?
- **Secondary** nodes identify to Geo **primary** nodes via OAuth or JWT authentication
based on the shared database (HTTP access) or a PostgreSQL replication user (for
database replication). The database replication also requires IP-based access
controls to be defined.
### What user authorization requirements have been defined?
- **Secondary** nodes must only be able to *read* data. They are not currently able to mutate data on the **primary** node.
### What session management requirements have been defined?
- Geo JWTs are defined to last for only two minutes before needing to be regenerated.
- Geo JWTs are generated for one of the following specific scopes:
- Geo API access.
- Git access.
- LFS and File ID.
- Upload and File ID.
- Job Artifact and File ID.
### What access requirements have been defined for URI and Service calls?
- **Secondary** nodes make many calls to the **primary** node's API. This is how file
replication proceeds, for instance. This endpoint is only accessible with a JWT token.
- The **primary** node also makes calls to the **secondary** node to get status information.
## Application Monitoring
### What application auditing requirements have been defined? How are audit and debug logs accessed, stored, and secured?
- Structured JSON log is written to the filesystem, and can also be ingested