- Secretless Broker
- Quick Start
- Additional demos
- Using Secretless
- Community
- Performance
- Development
- License
Secretless Broker is a connection broker which relieves client applications of the need to directly handle secrets to target services such as databases, web services, SSH connections, or any other TCP-based service.
Secretless is designed to solve two problems. The first is loss or theft of credentials from applications and services, which can occur by:
- Accidental credential leakage (e.g. credential checked into source control, etc)
- An attack on a privileged user (e.g. phishing, developer machine compromises, etc)
- A vulnerability in an application (e.g. remote code execution, environment variable dump, etc)
The second is downtime caused when applications or services do not respond to credential rotation and crash or get locked out of target services as a result.
When the client connects to a target service through the Secretless Broker:
-
The client is not part of the threat surface
The client/app no longer has direct access to the password, and therefore cannot reveal it.
-
The client doesn’t have to know how to properly manage secrets
Handling secrets safely involves some complexities, and when every application needs to know how to handle secrets, accidents happen. The Secretless Broker centralizes the client-side management of secrets into one code base, making it easier for developers to focus on delivering features.
-
The client doesn’t have to manage secret rotation
Secretless is responsible for establishing connections to the backend, and can handle secret rotation in a way that’s transparent to the client.
To provide Secretless access to a target service, a Service Connector implements the protocol of the service, replacing the authentication handshake. The client does not need to know or use a real password to the service. Instead, it proxies its connection to the service through a local connection to Secretless. Secretless obtains credentials to the target service from a secrets vault (such as Conjur, a keychain service, text files, or other sources) via a Credential Provider. The credentials are used to establish a connection to the actual service, and Secretless then rapidly shuttles data back and forth between the client and the service.
Secretless Broker is currently licensed under ASL 2.0
Secretless supports several target services out of the box, and these include:
- MySQL (Socket and TCP)
- PostgreSQL (Socket and TCP)
- SSH / SSH-Agent (Beta)
- HTTP with Basic auth, Conjur, and AWS authorization strategies (Beta)
Support for these services is provided via internal plugins (also referred to as "Service Connectors") that are part of the Secretless binary distribution.
If you want to use Secretless with a target service that is not currently supported, you can use the Secretless Plugin Interface to create Connector Plugins to extend Secretless to support virtually any target service. These external plugins can be integrated in environments using a standard Secretless Broker implementation.
For more information on building a Secretless Connector Plugin please see our documentation, which will walk you through creating a new Connector Plugin using our templates.
Are we missing an internal service connector that you think is important? Are you curious if anyone else has thought of building the service connector you're interested in? Please open a GitHub issue with more information on the connector you'd like, and start the conversation.
For specific guidelines about using a particular service, please see our documentation.
Running the quick start demo requires Docker.
To see the Secretless Broker in action, pull the quick start image:
docker pull cyberark/secretless-broker-quickstart
The quick start image runs the Secretless Broker binary and a few sample target services. The Secretless Broker is configured to retrieve the credentials required to access the services from the process environment. All services are configured to require authentication to access, but we don't know what those credentials are. We can try to access the services, but since we don't know the password our access attempts will fail. But when we try to connect via the Secretless Broker, we will be granted access.
Let's try this with the PostgreSQL server running in the quick start image. We know that the server has been configured with a quickstart
database, so let's try to access it.
You can run the Secretless Broker quick start as a Docker container:
$ docker run \
--rm \
-p 5432:5432 \
-p 5454:5454 \
secretless-broker-quickstart:latest
In a new window, if we try to connect to PostgreSQL directly via port 5432 (guessing at the postgres
username), our attempt will fail:
$ psql "host=localhost port=5432 user=postgres dbname=quickstart sslmode=disable"
Password for user postgres:
psql: FATAL: password authentication failed for user "postgres"
But the Secretless Broker is listening on port 5454, and will add authentication credentials (both username and password) to our connection request and proxy our connection to the PostgreSQL server:
$ psql "host=localhost port=5454 user=postgres dbname=quickstart sslmode=disable"
psql (10.3, server 9.6.9)
Type "help" for help.
quickstart=> \d
List of relations
Schema | Name | Type | Owner
--------+-----------------+----------+------------
public | counties | table | secretless
public | counties_id_seq | sequence | secretless
(2 rows)
quickstart=> select * from counties limit 1;
id | name
----+-----------
1 | Middlesex
(1 row)
quickstart=>
Success! Smile and grab a 🍪 because it was too easy!
You have just delegated responsibility for managing credentials to a secure process isolated from your app!
If the PostgreSQL quick start demo piqued your interest, please check out our additional demos where you can try the Secretless Broker with SSH and HTTP Basic Auth.
For an even more in-depth demo, check out our Deploying to Kubernetes demo, which walks you through deploying a sample app to Kubernetes with the Secretless Broker.
For complete documentation on using Secretless, please see our documentation. The documentation includes comprehensive guides for how to get up and running with Secretless.
Are you using this project with Conjur OSS? Then we strongly recommend choosing the version of this project to use from the latest Conjur OSS suite release. Conjur maintainers perform additional testing on the suite release versions to ensure compatibility. When possible, upgrade your Conjur version to match the latest suite release; when using integrations, choose the latest suite release that matches your Conjur version. For any questions, please contact us on Discourse.
The primary source of Secretless Broker releases is our DockerHub.
Every new GitHub tag (x.y.z
) added to the project produces a set of Docker images in DockerHub: (x.y.z
, x.y
, x
, latest
). The latest
image tag therefore always corresponds to the latest GitHub tag, and the x.y
and x
tags alway correspond to the latest matching x.y.z
image.
Post-1.0, GitHub releases are created for GitHub tagged versions that have undergone additional quality activities to ensure that Secretless continues to meet its stability requirements. When a GitHub release is created (indicating a new stable Secretless version), an additional Docker image is pushed to DockerHub with the stable
tag.
At any given time there is only one Docker image with the stable
tag - that of the latest stable
release. Older stable versions (v1.0+) can be found on the official GitHub releases page.
Note: the GitHub releases page will also show pre-releases
, which have not yet been promoted to stable.
The code on master
in the project's GitHub repository represents the development work done since the previous GitHub tag. It is possible to build Secretless from source (see our contributing guidelines for more info), but for regular use we recommend using the stable
Docker image from DockerHub or an official GitHub release.
Stable components (eg service connectors, credential providers, etc.) of Secretless meet the core acceptance criteria:
- The component should perform its functionality transparently to the underlying application
- The component must guard against threats from all parts of the STRIDE threat model
- Documentation exists that clearly explains how to set up and use the component as well as providing troubleshooting information for anticipated common failure cases
- A suite of automated tests that exercise the component exists and provides excellent code coverage
In addition, the following must be true for any stable release:
- Secretless has had security review (including static code analysis), and all known high and critical issues have been addressed. Any low or medium issues that have not been addressed have been logged in the GitHub issue backlog with a label of the form
security/X
- Secretless has undergone STRIDE threat modeling
- For use cases involving stable components of Secretless (eg service connectors, credential providers, etc.):
- Secretless is stable while running
- It does not drop connections while running
- It can run without failure (eg it can consistently open connections, it maintains existing open connections, etc) for an extended period of time (~4 days)
- When the Secretless process dies in Kubernetes / OpenShift, the pod is destroyed and rescheduled
- Secretless has minimal impact on connection speeds
- Request throughput is within 20% of direct-to-DB speed
- Secretless performs under load in a realistic environment (eg deployed to the same pod as an application in Kubernetes or OpenShift)
- Secretless handles connections transparently, so that requests from the client are appropriately transmitted to the server and messages from the server are propagated back to the client
- Secretless is stable while running
- Secretless is easy to set up, and adding the configured Secretless Broker sidecar to your application takes less than 30 minutes
- Secretless is clear about known limitations
Our primary channel for support is through our Secretless Broker Discourse. More info here: community support
Using the Secretless Broker reduces the transaction throughput by about 25% on Postgresql. Once the connection to the backend database is established, the Secretless Broker runs 2 goroutines - one reads from the client and writes to the server, the other reads from the server and writes to the client. It's as simple as this:
go stream(self.Client, self.Backend)
go stream(self.Backend, self.Client)
Here is some performance data created by running pgbench with the client, the Secretless Broker and database running on a single machine (2017 MacBook Pro with 2.3 GHz Intel Core i5) where the database is running in Docker.
Directly to the database:
$ PGPASSWORD=mysecretpassword PGSSLMODE=disable pgbench -h localhost -U postgres -p 5432 -T 10 -c 12 -j 12 postgres
starting vacuum...end.
transaction type: <builtin: TPC-B (sort of)>
scaling factor: 1
query mode: simple
number of clients: 12
number of threads: 12
duration: 10 s
number of transactions actually processed: 2733
latency average = 44.167 ms
tps = 271.696057 (including connections establishing)
tps = 272.924176 (excluding connections establishing)
Through the secretless-broker
proxy:
$ PGSSLMODE=disable pgbench -h localhost -U postgres -p 4321 -T 10 -c 12 -j 12 postgres
starting vacuum...end.
transaction type: <builtin: TPC-B (sort of)>
scaling factor: 1
query mode: simple
number of clients: 12
number of threads: 12
duration: 10 s
number of transactions actually processed: 2459
latency average = 49.034 ms
tps = 244.727719 (including connections establishing)
tps = 248.327635 (excluding connections establishing)
From the results above, you can see 9% fewer tps (even including establishing connections) via the Secretless Broker.
To run this test yourself, you can start PostgreSQL by running
docker run --name some-postgres -e POSTGRES_PASSWORD=mysecretpassword -d -p 5432:5432 postgres:9.3
Write a secretless.yml
file that includes:
version: "2"
services:
pg-db:
connector: pg
listenOn: tcp://0.0.0.0:4321
credentials:
host: localhost
username: postgres
password: mysecretpassword
sslmode: disable
and run Secretless:
$ ./bin/build_darwin # to build the OSX binary
$ ./dist/darwin/amd64/secretless-broker -f secretless.yml
Initialize pgbench
by running
PGPASSWORD=mysecretpassword pgbench -i -h localhost -U postgres -p 5432
and run the tests as above.
We welcome contributions of all kinds to Secretless Broker. For instructions on how to get started and descriptions of our development workflows, please see our contributing guide. This document includes guidelines for writing plugins to extend the functionality of Secretless Broker.
The Secretless Broker is licensed under Apache License 2.0 - see LICENSE
for more details.