Use Docker Swarm with TLS
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You are viewing docs for legacy standalone Swarm. These topics describe standalone Docker Swarm. In Docker 1.12 and higher, Swarm mode is integrated with Docker Engine. Most users should use integrated Swarm mode — a good place to start is Getting started with swarm mode, Swarm mode CLI commands, and the Get started with Docker walkthrough). Standalone Docker Swarm is not integrated into the Docker Engine API and CLI commands.
All nodes in a Swarm cluster must bind their Docker daemons to a network port. This has obvious security implications. These implications are compounded when the network in question is untrusted such as the internet. To mitigate these risks, Docker Swarm and the Docker Engine daemon support Transport Layer Security (TLS).
Note: TLS is the successor to SSL (Secure Sockets Layer) and the two terms are often used interchangeably. Docker uses TLS, this term is used throughout this article.
Learn the TLS concepts
Before going further, it is important to understand the basic concepts of TLS and public key infrastructure (PKI).
Public key infrastructure is a combination of security related technologies, policies, and procedures, that are used to create and manage digital certificates. These certificates and infrastructure secure digital communication using mechanisms such as authentication and encryption.
The following analogy may be useful. It is common practice that passports are used to verify an individual’s identity. Passports usually contain a photograph and biometric information that identify the owner. A passport also lists the country that issued it, as well as valid from and valid to dates. Digital certificates are very similar. The text below is an extract from a digital certificate:
Certificate: Data: Version: 3 (0x2) Serial Number: 9590646456311914051 (0x8518d2237ad49e43) Signature Algorithm: sha256WithRSAEncryption Issuer: C=US, ST=CA, L=Sanfrancisco, O=Docker Inc Validity Not Before: Jan 18 09:42:16 2016 GMT Not After : Jan 15 09:42:16 2026 GMT Subject: CN=swarm
This certificate identifies a computer called swarm. The certificate is valid between January 2016 and January 2026 and was issued by Docker Inc. based in the state of California in the US.
Just as passports authenticate individuals as they board flights and clear customs, digital certificates authenticate computers on a network.
Public key infrastructure (PKI) is the combination of technologies, policies, and procedures that work behind the scenes to enable digital certificates. Some of the technologies, policies and procedures provided by PKI include:
- Services to securely request certificates
- Procedures to authenticate the entity requesting the certificate
- Procedures to determine the entity’s eligibility for the certificate
- Technologies and processes to issue certificates
- Technologies and processes to revoke certificates
How does Docker Engine authenticate using TLS
In this section, you’ll learn how Docker Engine and Swarm use PKI and certificates to increase security.
You can configure both the Docker Engine CLI and the Docker Engine daemon to require TLS for authentication. Configuring TLS means that all communications between the Docker Engine CLI and the Docker Engine daemon must be accompanied with, and signed by a trusted digital certificate. The Docker Engine CLI must provide its digital certificate before the Docker Engine daemon will accept incoming commands from it.
The Docker Engine daemon must also trust the certificate that the Docker Engine CLI uses. This trust is usually established by way of a trusted third party. The Docker Engine CLI and Docker Engine daemon in the diagram below are configured to require TLS authentication.
The trusted third party in this diagram is the Certificate Authority (CA) server. Like the country in the passport example, a CA creates, signs, issues, revokes certificates. Trust is established by installing the CA’s root certificate on the host running the Docker Engine daemon. The Docker Engine CLI then requests its own certificate from the CA server, which the CA server signs and issues to the client.
The Docker Engine CLI sends its certificate to the Docker Engine daemon before issuing commands. The Docker Engine daemon inspects the certificate, and because the Docker Engine daemon trusts the CA, the Docker Engine daemon automatically trusts any certificates signed by the CA. Assuming the certificate is in order (the certificate has not expired or been revoked etc.) the Docker Engine daemon accepts commands from this trusted Docker Engine CLI.
The Docker Engine CLI is simply a client that uses the Docker Engine API to communicate with the Docker Engine daemon. Any client that uses this Docker Engine API can use TLS. For example, Docker Engine clients such as ‘Docker Universal Control Plane’ (UCP) have TLS support built-in. Other, third party products, that use Docker Engine API, can also be configured this way.
TLS modes with Docker and Swarm
Now that you know how certificates are used by the Docker Engine daemon for authentication, it’s important to be aware of the three TLS configurations possible with Docker Engine daemon and its clients:
- External 3rd party CA
- Internal corporate CA
- Self-signed certificates
These configurations are differentiated by the type of entity acting as the Certificate Authority (CA).
External 3rd party CA
An external CA is a trusted 3rd party company that provides a means of creating, issuing, revoking, and otherwise managing certificates. They are trusted in the sense that they have to fulfill specific conditions and maintain high levels of security and business practices to win your business. You also have to install the external CA’s root certificates for you computers and services to trust them.
When you use an external 3rd party CA, they create, sign, issue, revoke and otherwise manage your certificates. They normally charge a fee for these services, but are considered an enterprise-class scalable solution that provides a high degree of trust.
Internal corporate CA
Many organizations choose to implement their own Certificate Authorities and PKI. Common examples are using OpenSSL and Microsoft Active Directory. In this case, your company is its own Certificate Authority with all the work it entails. The benefit is, as your own CA, you have more control over your PKI.
Running your own CA and PKI requires you to provide all of the services offered by external 3rd party CAs. These include creating, issuing, revoking, and otherwise managing certificates. Doing all of this yourself has its own costs and overheads. However, for a large corporation, it still may reduce costs in comparison to using an external 3rd party service.
Assuming you operate and manage your own internal CAs and PKI properly, an internal, corporate CA can be a highly scalable and highly secure option.
As the name suggests, self-signed certificates are certificates that are signed with their own private key rather than a trusted CA. This is a low cost and simple to use option. If you implement and manage self-signed certificates correctly, they can be better than using no certificates.
Because self-signed certificates lack of a full-blown PKI, they do not scale well and lack many of the advantages offered by the other options. One of their disadvantages is that you cannot revoke self-signed certificates. Due to this, and other limitations, self-signed certificates are considered the least secure of the three options. Self-signed certificates are not recommended for public facing production workloads exposed to untrusted networks.