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Docker Registry v2 authentication via central service
Today a Docker Registry can run in standalone mode in which there are no
authorization checks. While adding your own HTTP authorization requirements in
a proxy placed between the client and the registry can give you greater access
control, we'd like a native authorization mechanism that's public key based
with access control lists managed separately with the ability to have fine
granularity in access control on a by-key, by-user, by-namespace, and
by-repository basis. In v1 this can be configured by specifying an
index_endpoint
in the registry's config. Clients present tokens generated by
the index and tokens are validated on-line by the registry with every request.
This results in a complex authentication and authorization loop that occurs
with every registry operation. Some people are very familiar with this image:
The above image outlines the 6-step process in accessing the Official Docker Registry.
- Contact the Docker Hub to know where I should download “samalba/busybox”
- Docker Hub replies: a. samalba/busybox is on Registry A b. here are the checksums for samalba/busybox (for all layers) c. token
- Contact Registry A to receive the layers for samalba/busybox (all of them to the base image). Registry A is authoritative for “samalba/busybox” but keeps a copy of all inherited layers and serve them all from the same location.
- Registry contacts Docker Hub to verify if token/user is allowed to download images.
- Docker Hub returns true/false lettings registry know if it should proceed or error out.
- Get the payload for all layers.
The goal of this document is to outline a way to eliminate steps 4 and 5 from the above process by using cryptographically signed tokens and no longer require the client to authenticate each request with a username and password stored locally in plain text.
The new registry workflow is more like this:
- Attempt to begin a push/pull operation with the registry.
- If the registry requires authorization it will return a
401 Unauthorized
HTTP response with information on how to authenticate. - The registry client makes a request to the authorization service for a signed JSON Web Token.
- The authorization service returns a token.
- The client retries the original request with the token embedded in the request header.
- The Registry authorizes the client and begins the push/pull session as usual.
Requirements
- Registry Clients capable of generating key pairs which can be used to authenticate to an authorization server.
- An authorization server capable of managing user accounts, their public keys, and access controls to their resources hosted by any given service (such as repositories in a Docker Registry).
- A Docker Registry capable of trusting the authorization server to sign tokens which clients can use for authorization and the ability to verify these tokens for single use or for use during a sufficiently short period of time.
Authorization Server Endpoint Descriptions
This document borrows heavily from the JSON Web Token Draft Spec
The described server is meant to serve as a user account and key manager and a centralized access control list for resources hosted by other services which wish to authenticate and manage authorizations using this services accounts and their public keys.
Such a service could be used by the official docker registry to authenticate clients and verify their authorization to docker image repositories.
Docker will need to be updated to interact with an authorization server to get an authorization token.
How to authenticate
Today, registry clients first contact the index to initiate a push or pull.
For v2, clients should contact the registry first. If the registry server
requires authentication it will return a 401 Unauthorized
response with a
WWW-Authenticate
header detailing how to authenticate to this registry.
For example, say I (username jlhawn
) am attempting to push an image to the
repository samalba/my-app
. For the registry to authorize this, I either need
push
access to the samalba/my-app
repository or push
access to the whole
samalba
namespace in general. The registry will first return this response:
HTTP/1.1 401 Unauthorized
WWW-Authenticate: Bearer realm="https://auth.docker.com/v2/token/",service="registry.docker.com",scope="repository:samalba/my-app:push"
This format is documented in Section 3 of RFC 6750: The OAuth 2.0 Authorization Framework: Bearer Token Usage
The client will then know to make a GET
request to the URL
https://auth.docker.com/v2/token/
using the service
and scope
values from
the WWW-Authenticate
header.
Requesting a Token
Query Parameters
-
service
- The name of the service which hosts the resource.
-
scope
-
The resource in question, formatted as one of the space-delimited
entries from the
scope
parameters from theWWW-Authenticate
header shown above. This query parameter should be specified multiple times if there is more than onescope
entry from theWWW-Authenticate
header. The above example would be specified as:scope=repository:samalba/my-app:push
. -
account
- The name of the account which the client is acting as. Optional if it can be inferred from client authentication.
Description
Requests an authorization token for access to a specific resource hosted by a
specific service provider. Requires the client to authenticate either using a
TLS client certificate or using basic authentication (or any other kind of
digest/challenge/response authentication scheme if the client doesn't support
TLS client certs). If the key in the client certificate is linked to an account
then the token is issued for that account key. If the key in the certificate is
linked to multiple accounts then the client must specify the account
query
parameter. The returned token is in JWT (JSON Web Token) format, signed using
the authorization server's private key.
Example
For this example, the client makes an HTTP request to the following endpoint over TLS using a client certificate with the server being configured to allow a non-verified issuer during the handshake (i.e., a self-signed client cert is okay).
GET /v2/token/?service=registry.docker.com&scope=repository:samalba/my-app:push&account=jlhawn HTTP/1.1
Host: auth.docker.com
The server first inspects the client certificate to extract the subject key and lookup which account it is associated with. The client is now authenticated using that account.
The server next searches its access control list for the account's access to
the repository samalba/my-app
hosted by the service registry.docker.com
.
The server will now construct a JSON Web Token to sign and return. A JSON Web Token has 3 main parts:
-
Headers
The header of a JSON Web Token is a standard JOSE header. The "typ" field will be "JWT" and it will also contain the "alg" which identifies the signing algorithm used to produce the signature. It will also usually have a "kid" field, the ID of the key which was used to sign the token.
Here is an example JOSE Header for a JSON Web Token (formatted with whitespace for readability):
{ "typ": "JWT", "alg": "ES256", "kid": "PYYO:TEWU:V7JH:26JV:AQTZ:LJC3:SXVJ:XGHA:34F2:2LAQ:ZRMK:Z7Q6" }
It specifies that this object is going to be a JSON Web token signed using the key with the given ID using the Elliptic Curve signature algorithm using a SHA256 hash.
-
Claim Set
The Claim Set is a JSON struct containing these standard registered claim name fields:
-
iss
(Issuer) - The issuer of the token, typically the fqdn of the authorization server.
-
sub
(Subject) - The subject of the token; the id of the client which requested it.
-
aud
(Audience) - The intended audience of the token; the id of the service which will verify the token to authorize the client/subject.
-
exp
(Expiration) - The token should only be considered valid up to this specified date and time.
-
nbf
(Not Before) - The token should not be considered valid before this specified date and time.
-
iat
(Issued At) - Specifies the date and time which the Authorization server generated this token.
-
jti
(JWT ID) - A unique identifier for this token. Can be used by the intended audience to prevent replays of the token.
The Claim Set will also contain a private claim name unique to this authorization server specification:
-
access
-
An array of access entry objects with the following fields:
<dl> <dt> <code>type</code> </dt> <dd> The type of resource hosted by the service. </dd> <dt> <code>name</code> </dt> <dd> The name of the recource of the given type hosted by the service. </dd> <dt> <code>actions</code> </dt> <dd> An array of strings which give the actions authorized on this resource. </dd> </dl> </dd>
Here is an example of such a JWT Claim Set (formatted with whitespace for readability):
{ "iss": "auth.docker.com", "sub": "jlhawn", "aud": "registry.docker.com", "exp": 1415387315, "nbf": 1415387015, "iat": 1415387015, "jti": "tYJCO1c6cnyy7kAn0c7rKPgbV1H1bFws", "access": [ { "type": "repository", "name": "samalba/my-app", "actions": [ "push" ] } ] }
-
-
Signature
The authorization server will produce a JOSE header and Claim Set with no extraneous whitespace, i.e., the JOSE Header from above would be
{"typ":"JWT","alg":"ES256","kid":"PYYO:TEWU:V7JH:26JV:AQTZ:LJC3:SXVJ:XGHA:34F2:2LAQ:ZRMK:Z7Q6"}
and the Claim Set from above would be
{"iss":"auth.docker.com","sub":"jlhawn","aud":"registry.docker.com","exp":1415387315,"nbf":1415387015,"iat":1415387015,"jti":"tYJCO1c6cnyy7kAn0c7rKPgbV1H1bFws","access":[{"type":"repository","name":"samalba/my-app","actions":["push"]}]}
The utf-8 representation of this JOSE header and Claim Set are then url-safe base64 encoded (sans trailing '=' buffer), producing:
eyJ0eXAiOiJKV1QiLCJhbGciOiJFUzI1NiIsImtpZCI6IlBZWU86VEVXVTpWN0pIOjI2SlY6QVFUWjpMSkMzOlNYVko6WEdIQTozNEYyOjJMQVE6WlJNSzpaN1E2In0
for the JOSE Header and
eyJpc3MiOiJhdXRoLmRvY2tlci5jb20iLCJzdWIiOiJqbGhhd24iLCJhdWQiOiJyZWdpc3RyeS5kb2NrZXIuY29tIiwiZXhwIjoxNDE1Mzg3MzE1LCJuYmYiOjE0MTUzODcwMTUsImlhdCI6MTQxNTM4NzAxNSwianRpIjoidFlKQ08xYzZjbnl5N2tBbjBjN3JLUGdiVjFIMWJGd3MiLCJhY2Nlc3MiOlt7InR5cGUiOiJyZXBvc2l0b3J5IiwibmFtZSI6InNhbWFsYmEvbXktYXBwIiwiYWN0aW9ucyI6WyJwdXNoIl19XX0
for the Claim Set. These two are concatenated using a '.' character, yielding the string:
eyJ0eXAiOiJKV1QiLCJhbGciOiJFUzI1NiIsImtpZCI6IlBZWU86VEVXVTpWN0pIOjI2SlY6QVFUWjpMSkMzOlNYVko6WEdIQTozNEYyOjJMQVE6WlJNSzpaN1E2In0.eyJpc3MiOiJhdXRoLmRvY2tlci5jb20iLCJzdWIiOiJqbGhhd24iLCJhdWQiOiJyZWdpc3RyeS5kb2NrZXIuY29tIiwiZXhwIjoxNDE1Mzg3MzE1LCJuYmYiOjE0MTUzODcwMTUsImlhdCI6MTQxNTM4NzAxNSwianRpIjoidFlKQ08xYzZjbnl5N2tBbjBjN3JLUGdiVjFIMWJGd3MiLCJhY2Nlc3MiOlt7InR5cGUiOiJyZXBvc2l0b3J5IiwibmFtZSI6InNhbWFsYmEvbXktYXBwIiwiYWN0aW9ucyI6WyJwdXNoIl19XX0
This is then used as the payload to a the
ES256
signature algorithm specified in the JOSE header and specified fully in Section 3.4 of the JSON Web Algorithms (JWA) draft specificationThis example signature will use the following ECDSA key for the server:
{ "kty": "EC", "crv": "P-256", "kid": "PYYO:TEWU:V7JH:26JV:AQTZ:LJC3:SXVJ:XGHA:34F2:2LAQ:ZRMK:Z7Q6", "d": "R7OnbfMaD5J2jl7GeE8ESo7CnHSBm_1N2k9IXYFrKJA", "x": "m7zUpx3b-zmVE5cymSs64POG9QcyEpJaYCD82-549_Q", "y": "dU3biz8sZ_8GPB-odm8Wxz3lNDr1xcAQQPQaOcr1fmc" }
A resulting signature of the above payload using this key is:
QhflHPfbd6eVF4lM9bwYpFZIV0PfikbyXuLx959ykRTBpe3CYnzs6YBK8FToVb5R47920PVLrh8zuLzdCr9t3w
Concatenating all of these together with a
.
character gives the resulting JWT:eyJ0eXAiOiJKV1QiLCJhbGciOiJFUzI1NiIsImtpZCI6IlBZWU86VEVXVTpWN0pIOjI2SlY6QVFUWjpMSkMzOlNYVko6WEdIQTozNEYyOjJMQVE6WlJNSzpaN1E2In0.eyJpc3MiOiJhdXRoLmRvY2tlci5jb20iLCJzdWIiOiJqbGhhd24iLCJhdWQiOiJyZWdpc3RyeS5kb2NrZXIuY29tIiwiZXhwIjoxNDE1Mzg3MzE1LCJuYmYiOjE0MTUzODcwMTUsImlhdCI6MTQxNTM4NzAxNSwianRpIjoidFlKQ08xYzZjbnl5N2tBbjBjN3JLUGdiVjFIMWJGd3MiLCJhY2Nlc3MiOlt7InR5cGUiOiJyZXBvc2l0b3J5IiwibmFtZSI6InNhbWFsYmEvbXktYXBwIiwiYWN0aW9ucyI6WyJwdXNoIl19XX0.QhflHPfbd6eVF4lM9bwYpFZIV0PfikbyXuLx959ykRTBpe3CYnzs6YBK8FToVb5R47920PVLrh8zuLzdCr9t3w
This can now be placed in an HTTP response and returned to the client to use to authenticate to the audience service:
HTTP/1.1 200 OK
Content-Type: application/json
{"token": "eyJ0eXAiOiJKV1QiLCJhbGciOiJFUzI1NiIsImtpZCI6IlBZWU86VEVXVTpWN0pIOjI2SlY6QVFUWjpMSkMzOlNYVko6WEdIQTozNEYyOjJMQVE6WlJNSzpaN1E2In0.eyJpc3MiOiJhdXRoLmRvY2tlci5jb20iLCJzdWIiOiJqbGhhd24iLCJhdWQiOiJyZWdpc3RyeS5kb2NrZXIuY29tIiwiZXhwIjoxNDE1Mzg3MzE1LCJuYmYiOjE0MTUzODcwMTUsImlhdCI6MTQxNTM4NzAxNSwianRpIjoidFlKQ08xYzZjbnl5N2tBbjBjN3JLUGdiVjFIMWJGd3MiLCJhY2Nlc3MiOlt7InR5cGUiOiJyZXBvc2l0b3J5IiwibmFtZSI6InNhbWFsYmEvbXktYXBwIiwiYWN0aW9ucyI6WyJwdXNoIl19XX0.QhflHPfbd6eVF4lM9bwYpFZIV0PfikbyXuLx959ykRTBpe3CYnzs6YBK8FToVb5R47920PVLrh8zuLzdCr9t3w"}
Using the signed token
Once the client has a token, it will try the registry request again with the
token placed in the HTTP Authorization
header like so:
Authorization: Bearer eyJ0eXAiOiJKV1QiLCJhbGciOiJFUzI1NiIsImtpZCI6IkJWM0Q6MkFWWjpVQjVaOktJQVA6SU5QTDo1RU42Ok40SjQ6Nk1XTzpEUktFOkJWUUs6M0ZKTDpQT1RMIn0.eyJpc3MiOiJhdXRoLmRvY2tlci5jb20iLCJzdWIiOiJCQ0NZOk9VNlo6UUVKNTpXTjJDOjJBVkM6WTdZRDpBM0xZOjQ1VVc6NE9HRDpLQUxMOkNOSjU6NUlVTCIsImF1ZCI6InJlZ2lzdHJ5LmRvY2tlci5jb20iLCJleHAiOjE0MTUzODczMTUsIm5iZiI6MTQxNTM4NzAxNSwiaWF0IjoxNDE1Mzg3MDE1LCJqdGkiOiJ0WUpDTzFjNmNueXk3a0FuMGM3cktQZ2JWMUgxYkZ3cyIsInNjb3BlIjoiamxoYXduOnJlcG9zaXRvcnk6c2FtYWxiYS9teS1hcHA6cHVzaCxwdWxsIGpsaGF3bjpuYW1lc3BhY2U6c2FtYWxiYTpwdWxsIn0.Y3zZSwaZPqy4y9oRBVRImZyv3m_S9XDHF1tWwN7mL52C_IiA73SJkWVNsvNqpJIn5h7A2F8biv_S2ppQ1lgkbw
This is also described in Section 2.1 of RFC 6750: The OAuth 2.0 Authorization Framework: Bearer Token Usage
Verifying the token
The registry must now verify the token presented by the user by inspecting the claim set within. The registry will:
- Ensure that the issuer (
iss
claim) is an authority it trusts. - Ensure that the registry identifies as the audience (
aud
claim). - Check that the current time is between the
nbf
andexp
claim times. - If enforcing single-use tokens, check that the JWT ID (
jti
claim) value has not been seen before.- To enforce this, the registry may keep a record of
jti
s it has seen for up to theexp
time of the token to prevent token replays.
- To enforce this, the registry may keep a record of
- Check the
access
claim value and use the identified resources and the list of actions authorized to determine whether the token grants the required level of access for the operation the client is attempting to perform. - Verify that the signature of the token is valid.
At no point in this process should the registry need to call back to the authorization server. If anything, it would only need to update a list of trusted public keys for verifying token signatures or use a separate API (still to be spec'd) to add/update resource records on the authorization server.