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Version: 2.4.x.x Java 8 ELS

Dispatch Target Management

Experimental feature

Dispatch target management is currently considered as an experimental feature. The implementation and public interfaces are likely to change in the future.

Description

Dispatch targets serve as receivers of out-of-band messages, as described in Out-of-Band Message Transmission. Dispatch target management deals with the administration and maintenance of such message receivers. The concept of dispatch targets is not part of the FIDO UAF specification but represents a Nevis proprietary concept. As dispatch targets only play a role in out-of-band scenarios, the whole concept can be disregarded in in-band only scenarios.

Dispatch target management is important for any Nevis Mobile Authentication client application that contains a FIDO UAF client and wants to be able to receive and handle out-of-band messages. The client application is responsible for administering the dispatch target represented by the application or the corresponding device. Administering dispatch targets includes the creation, modification as well as eventual deletion of dispatch targets.

If the dispatching takes place in the form of (mobile) push messages, the mobile client application is responsible for:

  1. Registering itself as a dispatch target with the Nevis Mobile Authentication backend.
  2. Updating the dispatch target information in the backend upon change (for example, if the push identifier on the mobile device changes).
  3. Removing the dispatch target information upon deregistration.

As dispatch target management is independent of the UAF protocol, the responsible user must not have active UAF credentials or authenticators present when managing dispatch targets.

info

Note that the QR codes used in Nevis Mobile Authentication flows have no relation to dispatch targets (although technically QR codes could be considered as an out-of-band channel).

Prerequisites

  • The user owns a device that is able to serve as dispatch target. Such a device could be, for example, a smartphone.
  • The relying party mobile client application is able to generate additional key material, for encrypting the dispatch channel and certifying dispatch target updates.
  • Nevis is configured to allow out-of-band dispatching of Nevis Mobile Authentication messages. (see Nevis Component Configuration Examples)

The following examples assumes the usage of push message dispatching to the Nevis Mobile Authentication client application.

Examples

Dispatch Target Registration

The numbers in the description below correspond with the numbers in the next figure.

  1. The user performs and completes an in-band registration.

  2. The mobile application creates two certificates:

    • One certificate is for decrypting the encrypted dispatch message.
    • Another certificate is for signing future updates regarding the dispatch target information.
  3. The mobile application registers itself or the corresponding device as a dispatch target with the backend. Additionally, the application sends the public keys of the certificates generated in step 2.

Dispatch Target Registration

Technical Flow

The technical flow in the next figure explains the component interaction in detail. The step numbers in the figure do not correlate with the simplified example above.

A client application must authenticate itself before it can access the (protected) Create Dispatch Target endpoint. But the client application must also be able to update dispatch target information at any given point in time, without the need for explicit user authentication. To support both scenarios, Nevis uses signature keys for the verification of the client against the backend - authentication credentials of the user are not required. This concept is necessary because third party push providers may change the push identifier of the mobile device/application at anytime during the life cycle of an application. An example of a third party push provider is Google Firebase Cloud Messaging.

title="Dispatch Target Registration"

The numbers in the list correlate with the step numbers in the previous figure.

  1. The client application generates signature keys. These keys will be used to access the Update Dispatch Target endpoint, by signing the payload with the private key.

  2. The client generates encryption keys. These keys will be used to decrypt encrypted out-of-band messages.

  3. The client posts the dispatch target information to the Nevis backend. nevisProxy forwards the request to nevisFIDO. The signature and encryption public keys are part of the payload.

    info

    The Create Dispatch Target endpoint requires authentication. Currently, this is done by executing an in-band authentication. For more information, see In-Band Authentication.

    Endpoint: https://<nevisProxy-host>:<nevisProxy-port>/nevisfido/dispatch/targets

    References:

  4. nevisFIDO stores the dispatch target in nevisIDM.

  5. nevisFIDO informs the client about the successful creation of the dispatch target.

Dispatch Target Modification

The numbers in the description below correspond with the numbers in the next figure.

  1. The push identifier of the mobile phone/application changes. The mobile application is informed about the change.
  2. The mobile application updates the dispatch target information on the Nevis backend.
Dispatch Target Modification

Technical Flow

info

The technical flow in the next figure explains the component interaction in detail. The step numbers in the figure do not correlate with the simplified example above.

Dispatch target modification uses a special concept regarding endpoint protection and authentication, as previously outlined without any user interaction.

caution

Using JWS (JSON Web Signature) to verify a client means that the HTTP PATCH operation on the specific dispatch target endpoint is not protected by nevisAuth and is accessible without prior authentication!For more information on JWS, see "`http://tools.ietf.org/html/rfc7515".

title="Dispatch Target Modification"

The numbers in the list correlate with the step numbers in the previous figure.

  1. The client creates a JSON structure containing the changed data.

    References:

  2. The client signs the structure using the locally stored signature private key.

  3. The client sends the JSON as payload to the Nevis backend. nevisProxy forwards the request to nevisFIDO.

    info

    The backend expects the payload to be signed using JWS compact serialisation. For details, refer to RFC 7515: https://tools.ietf.org/html/rfc7515#section-4.1.9.

    Endpoint: https://<nevisProxy-host>:<nevisProxy-port>/nevisfido/dispatch/targets/<id>

    References:

  4. nevisFIDO loads the dispatch target information based on the dispatch target ID.

  5. nevisFIDO uses the signature public key to verify that the payload was signed by the correct mobile client.

  6. If the verification was successful, nevisFIDO updates the information in nevisIDM.

  7. The result of the operation is reported back to the client.

Dispatch Target Deletion

The numbers in the description below correspond with the numbers in the next figure.

  1. The user starts the Deregistration process on the mobile device.
  2. The mobile application performs the UAF credential Deregistration. For more information, see FIDO UAF Credential Deregistration.
  3. The mobile application removes the current device as dispatch target. Note that the removal order is not relevant, for example, the FIDO UAF credentials can be also removed after the dispatch target.
Dispatch Target Deletion
caution

The deletion operation described in this section only affects the dispatch targets. The registered FIDO UAF credentials will stay in place and are not removed. To remove the registered FIDO UAF credentials, perform a Deregistration operation. Refer to the chapter FIDO UAF Credential Deregistration for additional details.

To find the FIDO UAF credentials that are associated with the dispatch target, you can use the deviceId attribute. The dispatch targets and FIDO UAF credentials that have the same deviceIdvalue are stored on the same device. So if you want to remove all dispatch targets and corresponding FIDO UAF credentials on a given device, remove all elements with the same deviceId. For details, see the nevisFIDO Reference Guide, sections Registration Response Service and Dispatch Target Service .

Technical Flow

info

The technical flow in the next figure explains the component interaction in detail. The step numbers in the figure do not correlate with the simplified example above.

Dispatch target deletion is an important step in deregistration scenarios. As described in FIDO UAF Credential Deregistration, there is no direct relation between dispatch targets and UAF credentials. This means that the respective mobile client application must fully support and handle the deregistration procedure.

The following is only relevant if FIDO UAF authentication is used to protect the Delete Dispatch Target endpoint: As deleting dispatch targets requires authentication, the dispatch target deregistration must take place before the last authenticator has been removed from the client application. This impacts the complexity of the implementation on the client side: The client must be aware of its currently registered authenticators.

title="Dispatch Target Deletion"

The numbers in the list correlate with the step numbers in the previous figure.

  1. The client calls the Delete Dispatch Target endpoint with the HTTP DELETE method. nevisProxy forwards the request to nevisFIDO.

    info

    The Delete Dispatch Target endpoint requires authentication. Currently, this happens by executing an in-band authentication. For more information, see nevisFIDO Reference Guide

    Endpoint: https://<nevisProxy-host>:<nevisProxy-port>/nevisfido/dispatch/targets/<id>

    References:

  2. nevisFIDO deletes the dispatch target in nevisIDM identified. The target-to-be-deleted is identified by its ID.

  3. nevisFIDO informs the client about the result of the operation.

    When the dispatch target deletion was successful, the client can proceed with the deregistration of its authenticators.

    References:

Configuration Snippets

You will find example configuration snippets for all involved components in Nevis Component Configuration Examples.

info

In the configuration examples, it is assumed that the dispatch target endpoints are protected by using FIDO UAF in-band authentication.