MOQ C. Jennings Internet-Draft R. L. Barnes Intended status: Informational S. Nandakumar Expires: 5 September 2024 Cisco 4 March 2024 Secure Group Key Agreement with MLS over MoQ draft-jennings-moq-e2ee-mls-00 Abstract This specification defines a mechanism to use Message Layer Security (MLS) to provide end-to-end group key agreement for Media over QUIC (MOQ) applications. Almost all communications are done via the MOQ transport. MLS requires a small degree of synchronization, which is provided by a simple counter service. About This Document This note is to be removed before publishing as an RFC. The latest revision of this draft can be found at https://suhashere.github.io/moq-e2ee-mls. Status information for this document may be found at https://datatracker.ietf.org/doc/draft- jennings-moq-e2ee-mls/. Discussion of this document takes place on the Media over QUIC Working Group mailing list (mailto:moq@ietf.org), which is archived at https://mailarchive.ietf.org/arch/browse/moq/. Subscribe at https://www.ietf.org/mailman/listinfo/moq/. Source for this draft and an issue tracker can be found at https://github.com/suhasHere/moq-e2ee-mls. Status of This Memo This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet- Drafts is at https://datatracker.ietf.org/drafts/current/. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." This Internet-Draft will expire on 5 September 2024. Copyright Notice Copyright (c) 2024 IETF Trust and the persons identified as the document authors. All rights reserved. This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/ license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Revised BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Revised BSD License. Table of Contents 1. Introduction 2. Conventions and Definitions 3. MLS Overview 3.1. Critical Invariants 4. MOQ Overview 4.1. Simple Callflow 4.2. TrackNamespace Subscription 4.2.1. SUBSCRIBE_NAMESPACE 4.2.2. SUBSCRIBE_NAMESPACE_RESPONSE 4.2.3. NAMESPACE_INFO 5. MLS and MOQ 5.1. High-level Design 5.1.1. KeyPackage Distribution 5.1.2. Welcoming New Member 5.1.3. Updating MLS Group State 6. MLS Group Key Exchange over MOQT 6.1. Bootstrapping MLS Session 6.2. Creating/Joining a MLS Group 6.3. Updating Group State 6.3.1. Processing MLS Welcome Message 6.3.2. Processing MLS Commit Messages 7. Epoch Counter Service 7.1. Lock API 7.2. Increment API 8. Interactions with MOQ Secure Objects 9. Security Considerations 10. IANA Considerations 11. Normative References Acknowledgments Authors' Addresses 1. Introduction Media Over QUIC Transport (MOQT) is a protocol that is optimized for the QUIC protocol, either directly or via WebTransport, for the dissemination of delivery of low latency media. MOQT defines a publish/subscribe media delivery layer across set of participating relays for supporting wide range of use-cases with different resiliency and latency (live, interactive) needs without compromising the scalability and cost effectiveness associated with content delivery networks. It supports sending media objects through sets of relays nodes. MLS is a key establishment protocol that provides efficient asynchronous group key establishment with forward secrecy (FS) and post-compromise security (PCS) for groups in size ranging from two to thousands. This document defines procedures for MOQ endpoints to engage in secure E2EE key establishment protocol using MLS over MOQT. More specifically, this document provides * Design for using MOQT data model to carrying out MLS protocol exchange * Simple counter service interface enabling synchronization of MLS protocol messages. * Procedures to derive keys for MOQT object protection when using [SecureObjects]. 2. Conventions and Definitions The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here. The "|" operator is is used to indicate concatenation of two strings or bytes arrays. 3. MLS Overview MLS protocol provides continuous group authenticated key exchange. MLS provides several important security properties * Group Key Exchange: All members of the group at a given time know a secret key that is inaccessible to parties outside the group. * Authentication of group members: Each member of the group can authenticate the other members of the group. * Group Agreement: The members of the group all agree on the identities of the participants in the group. * Forward Secrecy: There are protocol events such that if a member's state is compromised after the event, group secrets created before the event are safe. * Post-compromise Security: There are protocol events such that if a member's state is compromised before the event, the group secrets created after the event are safe. At a very high level, MLS protocol operates by participants sending proposals to add/remove/update the group state and an active member of the group commit the proposals to move the group’s cryptographic state from one epoch to the next (see section 3.2 of [RFC9420]). In order to setup end to end encryption of media delivered over MOQT delivery network, producers and consumers participate in the MLS exchange to setup group secret through which are used to derive the keys needed for encrypting the media/data published by the members of the MLS group. 3.1. Critical Invariants MLS requires a linear sequence of MLS Commits in that each MLS Commit has exactly one successor. This is achieved by using a centralized server that hands out a token to the client that is allowed to make the next commit. 4. MOQ Overview MOQT [MoQTransport] defines a publish/subscribe based media delivery protocol, where in endpoints, called producers, publish objects which are delivered via participating relays to receiving endpoints, called consumers. Section 2 of MoQ Transport defines hierarchical object model for application data, comprised of objects, groups and tracks. Objects defines the basic data element, an addressable unit whose payload is sequence of bytes. All objects belong to a group, indicating ordering and potential dependencies. A track contains a sequence of groups and serves as the entity against which a consumer issues a subscription request. Media Over QUIC Application | time | TrackA +-+---------+-----+---------+--------------+---------+----> | | Group1 | | Group2 | . . . . . . | GroupN | | +----+----+ +----+----+ +---------+ | | | | | | | +----+----+ +----+----+ | | Object0 | | Object0 | | +---------+ +---------+ | | Object1 | | Object1 | | +---------+ +---------+ | | Object2 | | Object2 | | +---------+ +---------+ | . | . | . | +---------+ | | ObjectN | | +---------+ | | time | TrackB +-+---------+-----+---------+--------------+---------+----> | | Group1 | | Group2 | . . .. .. .. | GroupN | | +---+-----+ +----+----+ +----+----+ | | | | | | | | |+----+----+ +----+----+ +----+----+ || Object0 | | Object0 | | Object0 | |+---------+ +---------+ +---------+ | v Objects are comprised of two parts: envelope and a payload. The envelope is never end to end encrypted and is always visible to relays. The payload portion may be end to end encrypted, in which case it is only visible to the producer and consumer. The application is solely responsible for the content of the object payload. Tracks are identified by a combination of its TrackNamespace and TrackName. TrackNamespace and TrackName are treated as a sequence of binary bytes. Group and Objects are represented as variable length integers called GroupId and ObjectId respectively. 4.1. Simple Callflow Below is a simple callflow that shows the message exchange between, Alice (the producer) , Bob (the consumer) and Relay. The MOQT protocol exchange starts with Alice sending MOQT Announce message with TrackNamespace under which she is going to publish media tracks. Then Bob issues a MOQT Subscribe message to the relay for a FullTrackName (identified by its TrackNamespace and TrackName) expressing his interest to receive media. Relay makes downstream subscription to Alice since the track namespace in the subscription matches the track namespace in the announcement from Alice. This is followed by Alice publishing media over the requested track, which is eventually forwarded to Bob via the Relay. ┌──────────┐ ┌─────┐ ┌────────┐ │Alice(Pub)│ │Relay│ │Bob(Sub)│ └────┬─────┘ └──┬──┘ └───┬────┘ │ │ │ │Announce(id=1,TrackNamespace)│ │ │────────────────────────────>│ │ │ │ │ │ AnnounceOk(id=1) │ │ │<────────────────────────────│ │ │ │ │ │ │Subscribe(id=1, TrackName)│ │ │<─────────────────────────│ │ │ │ │ │ SubscribeOk(id=1) │ │ │─────────────────────────>│ │ │ │ │ Subscribe(id=2, TrackName) │ │ │<────────────────────────────│ │ │ │ │ │ SubscribeOk(id=2) │ │ │────────────────────────────>│ │ │ │ │ │ Object Flow │ │ │────────────────────────────>│ │ │ │ │ │ │ Object Flow │ │ │─────────────────────────>│ │ │ │ │ │ Unsubscribe(id=1) │ │ │<─────────────────────────│ │ │ │ │ Unsubscribe(id=1) │ │ │<────────────────────────────│ │ ┌────┴─────┐ ┌──┴──┐ ┌───┴────┐ │Alice(Pub)│ │Relay│ │Bob(Sub)│ └──────────┘ └─────┘ └────────┘ 4.2. TrackNamespace Subscription In order to realize the MLS key exchange over MOQ, this specification proposes MOQT endpoints and Relays to be able to subscribe to TrackNamespace. A sketch of the proposal is here but this would be moved out of this draft. Following additions is proposed to the core MOQT protocol. 4.2.1. SUBSCRIBE_NAMESPACE A subscriber sends SUBSCRIBE_NAMESPACE to express its interest in all the tracks that will eventually be produced under the requested namespace. SUBSCRIBE_NAMESPACE { Track Namespace (b), Subscribe Namespace ID (i) } 4.2.2. SUBSCRIBE_NAMESPACE_RESPONSE Publishers sends SUBSCRIBE_NAMESPACE_RESPONSE indicating the status of the request for subscribing to the track namespace. SUBSCRIBE_NAMESPACE_RESPONSE { Subscribe Namespace ID (i), Status Code (i), [Reason Phrase (b)] } 4.2.3. NAMESPACE_INFO Publisher sends NAMESPACE_INFO message whenever it is ready to publish on new track under a track namespace Section 4.2.1 message. The NAMESPACE_INFO message is a implicit subscription to the track, unless it is explicitly unsubscribed by the subscriber by sending UNSUBSCRIBE message. This message provides necessary mapping between Track Alias, Subscribe Id to the namespace requested in the SUBSCRIBE NAMESPACE message. NAMESPACE_INFO { Track Alias (i), Subscribe ID (i), Mapped Track Namespace (b), Mapped Track Name (b), Mapped Request Id (i) } Section 6.1 provides one of the applications of namespace subscription for MLS KeyPackage distribution. 5. MLS and MOQ This specification defines procedures for participants engaging in MLS key exchange to happen over MOQT protocol, thus enabling following 2 goals: 1. Use MOQT as delivery transport for MLS protocol messages. 2. Allow MOQT endpoints (producers/consumers) to use MLS as secure key exchange protocol for end to end secure communications across range of use-cases. 5.1. High-level Design MLS [RFC9420] achieves group key agreement by participants/members engaging in MLS protocol message exchange that allows: * New members to express their interest to join a MLS group * Existing members to commit a new members to a MLS group * Existing members to commit removal of existing members from a MLS group The central unit of functionality in MLS is a group, where at any given time, a group represents a secret known only to its members. Membership to the group can change over time. Each time membership changes (batch of joins or leaves), the shared secret is changed to one known only by the current members. Each period of time with stable membership/secret is an epoch. At a high level, one can envision MLS protocol operation in the form multiple queue abstractions to achieve the above functionality. 5.1.1. KeyPackage Distribution All participants interested in joining a MLS group share their MLS KeyPackage(s) with the group, thus enabling an existing member to add new members to the MLS group. In this context, KeyPackages distribution/processing can be modeled a "queue of KeyPackages". Such a queue provides following properties: * Multiple parties to write to it, when participants submit their KeyPackages. * Multiple parties to read/process from the queue, to process the KeyPackage for updating the MLS group state. +---------------------------+ +---> Multiple ---+ | | | Multiple Simultaneous +---> | MLS KeyPackage Queue | --+ Simultaneous Writers +---> | | | Readers ---+ +---------------------------+ +---> 5.1.2. Welcoming New Member Once a MLS KeyPackage is verified, an existing member can add a new member to the MLS group and send MLS Welcome message to invite the new member to join the group. This procedure can be abstracted via message queues for each joiner to receive MLS Welcome messages with the following properties: * Accessible by multiple parties to write, but constrained so that only one party is allowed to write for a given epoch. * One party, the recipient of the welcome message, is be able to read the MLS Welcome message. +--------------------------+ +---> ---+ | | | 1 writer per +---> | MLS Welcome Queues | --+ Single epoch +---> | (1 queue per joiner) | --+ Reader ---+ +--------------------------+ | +---> 5.1.3. Updating MLS Group State Members can update group's state when adding a new member, removing an existing member or updating group's entropy at any time during a MLS session. Group updates are performed via MLS Commit messages and successful commits result in moving the MLS epoch further. MLS Commit message needs to be processed by all the members to compute the shared group secret for that epoch. The distribution of commit messages can be modeled with a message queue for MLS Commit messages with the following properties: * Any member can access the commit queue for writing MLS Commit messages, but only one member is allowed to write per epoch. * All the members can read and process MLS Commit message from the commit queue to update their group state. ---+ +--------------------------+ +---> 1 writer per +--->| |--+ Multiple epoch +--->| MLS Commit Queue |--+ Simultaneous ---+ | | | Readers +--------------------------+ +---> 6. MLS Group Key Exchange over MOQT Section Section 5.1 provided an non-normative abstracted view (via Queue metaphor) to illustrate various MLS operations. Subsections below provide further normative details on realizing those abstractions via concepts from the MOQT data model (see Section 4). 6.1. Bootstrapping MLS Session Each participant is provisioned, out of band, the MLS Group Name for a given MOQ application instance. As part of bootstrapping a MLS Session, participating MOQT endpoints needs to perform the following 2 actions: 1. Subscribe to receive published MLS KeyPackages over MOQT Track for an MLS group. 2. Publishing MLS KeyPackages over a MOQT Track. To enable the above, following MOQT track definition is specified: The TrackNamespace, termed "KeyPackage Namespace" is made up of 2 parts as shown below: KeyPackage Namespace := | "keypackages" Note: The MLS group name chosen should be unique within a MOQ relay network. All the members subscribe to the "KeyPackage Namespace" to receive KeyPackages published over sender specific "KeyPackage Track"s as shown below, where the Trackname identifies the sender of the the KeyPackage. KeyPackage Track Tracknamespace := KeyPackage Namespace Trackname := SenderId The SenderId value chosen MUST be unique within the MOQ application. The RECOMMENDED way to ensure uniques would be to use certificate fingerprint of the sender's public key. There is one MOQT Group within the KeyPackage Track and objects within that group identify different updates to the KeyPackage from a given publisher. KeyPackage published at Object ID of '0' is used to initiate joining a MLS group. Below figure depicts a sample call flow on how the MOQT Namespace subscribe is used to enable 2 participants (joiner1 and joiner2) to publish their KeyPackages and have the member is able to process both of them ┌───────┐ ┌─────┐ ┌───────┐┌──────┐ │Joiner1│ │Relay│ │Joiner2││Member│ └───┬───┘ └──┬──┘ └───┬───┘└──┬───┘ │ │ │ │ │ Announce(mls-grp1|keypackages) │ │ │ │─────────────────────────────────────────────>│ │ │ │ │ │ │ │ │ Announce(mls-grp1|keypackages) │ │ │ │<─────────────────────────────────────────────│ │ │ │ │ │ │ │ Subscribe_Namespace(mls-grp1|keypackages) │ │ │<─────────────────────────────────────────────────────│ │ │ │ │ │ Subscribe_Namespace(mls-grp1|keypackages) │ │ │ │<─────────────────────────────────────────────│ │ │ │ │ │ │ │ │ Subscribe_Namespace(mls-grp1|keypackages) │ │ │ │─────────────────────────────────────────────>│ │ │ │ │ │ │Namespace_Info(namespace=mls-grp1|keypackages,│ │ │ │name=joiner1,alias=j1) │ │ │ │─────────────────────────────────────────────>│ │ │ │ │ │ │ │ │ Namespace_Info(namespace=mls-grp1|keypackages, │ │ │ name=joiner1,alias=j1) │ │ │ │─────────────────────────────────────────────────────>│ │ │ │ │ │ │Namespace_Info(namespace=mls-grp1|keypackages,│ │ │ │name=joiner2,alias=j2) │ │ │ │<─────────────────────────────────────────────│ │ │ │ │ │ │ │ Namespace_Info(namespace=mls-grp1|keypackages, │ │ │ name=joiner2,alias=j2) │ │ │ │─────────────────────────────────────────────────────>│ │ │ │ │ │ Object(alias=j1,.., payload=KeyPackage) │ │ │ │─────────────────────────────────────────────>│ │ │ │ │ │ │ │ │ Object(alias=j1,.., payload=KeyPackage)│ │ │ │─────────────────────────────────────────────────────>│ │ │ │ │ │ │ Object(alias=j2,.., payload=KeyPackage) │ │ │ │<─────────────────────────────────────────────│ │ │ │ │ │ │ │ Object(alias=j2,.., payload=KeyPackage)│ │ │ │─────────────────────────────────────────────────────>│ ┌───┴───┐ ┌──┴──┐ ┌───┴───┐┌──┴───┐ │Joiner1│ │Relay│ │Joiner2││Member│ └───────┘ └─────┘ └───────┘└──────┘ 6.2. Creating/Joining a MLS Group Creating or Joining an MLS group requires a way for boostraping the group when the first member joins and a way to decide an existing member for processing the MLS KeyPackage to add the new member. In order to realize the above functionalities and ensure the critical invariants Section 3.1, a centralized "Epoch Counter Service" (see epoch-svc) is required to address/resolve contention issues when multiple participants carryout the create/join procedures. Participants intending to join/create a MLS grooup, try to acquire lock from the counter service. The request identifies the MLS Group identified by its GroupId and epoch '0' as the counter to obtain the lock. The response can be one of the following: * Ok: A response of OK implies that there doesn't exist an MLS Group. In this scenario, the participant is the first participant and thus creates the group unilaterally and generates the initial secret for the group. Following which the participant releases the acquired lock by performing the increment operation for the obtained lock, on the counter service. * Locked: A response of "Locked" implies a conflicting request and the requestor has to retry acquiring the lock, after the lock expiry timeout provided in the response. * CounterError: A response of CounterError implies that the service has a different value of the current counter than the one requested (epoch 0). This happens when the requested MLS Group has already been created. In such situations, the participant awaits for an existing member to add the participant and publish the MLS Welcome message (see Section 6.3) 6.3. Updating Group State Updating MLS group state requires Section 3.1 to be satisfied. This means that the changes have to be done linearly and changes to the group state MUST be performed by a single member within a MLS group for a given epoch. The process of updating the group state is described below: 1. Acquire lock for the current epoch from the counter service. 2.a If the lock was successfully acquired and member is attempting to add a new member, process the MLS KeyPackage(s) available over per joiner's KeyPackage track, generate set of MLS Welcome messages per joiner and a single MLS Commit message for the group. Publish individual MLS Welcome messages to the intended recipeints on per recipient welcome track (see Section 6.3.1) and Publish MLS Commit message to all the participants (see Section 6.3.2). 2.b If the lock was successfully acquired and the operation is to remove a member, update the MLS state to remove the member, generate MLS Commit message and publish the generated MLS Commit message to all the participants (see Section 6.3.2). 1. If the response was "Locked", following the procedures for retrying as defined in (locked). 2. A lock response of "CounterError" implies the member attempting to update the MLS group state is behind and MUST await until it catches up with all the MLS Commit messages in transit. It is important to note, this situation MAY also imply that another member won the contention to update the group state before this member can make the change. 6.3.1. Processing MLS Welcome Message In order to be able to publish MLS Welcome message and process the same over MOQT, following track naming scheme is specified. The TrackNamespace, termed "Welcome Namespace" is divided into 2 parts as shown below: Welcome Namespace := | "welcome" Note: The MLS group name chosen should be unique within a MOQ relay network. MLS Welcome message is published over a track that is specific to individual recipient. Joining participants subscribe to the "Welcome Track" as part of MLS session bootstrapping, which has the following structure: Welcome Track Tracknamespace := Welcome Namespace Trackname := RecipientId The RecipientId value chosen MUST be unique within the MOQ application. The RECOMMENDED way to ensure uniques would be to use certificate fingerprint of the recipients's public key. The group member publishing the MLS Welcome message can obtain the RecipientId while processing the KeyPackage of the member being added. On receipt of the Welcome message, local MLS state is updated with the received MLS Welcome message to obtain the group secret for the current epoch. When publishing on the "Welcome Track", there is one MOQT group per MLS epoch and objectId 0 carries the MLS Welcome message. 6.3.2. Processing MLS Commit Messages All the members subscribe to receive MLS Commit message and they do so by subscribing to the "Commit Track" as shown: Commit Track Tracknamespace := Trackname := commits MLS Commit message updates the existing member about group changes, such as adds/removes and entropy updates. Publish to the "Commit Track" happens with one MOQT group per MLS epoch and objectId 0 carries the MLS Commit message. 7. Epoch Counter Service A counter service tracks a collection of counters with unique identifiers. In an MLS context, the counter value is equal to the MLS epoch, and the counter identifier is the MLS group identifier/MLS group name. Before a counter can be incremented, it must be locked. As part of the lock operation, the caller states what their expected next counter value, which much match the service's expectation in order for the caller to acquire the lock. Since the actual updates to the counter are out of band, this ensures that the caller has the correct current value before incrementing. There is no explicit initialization of counters. The first call to lock for a counter must have expected_next_value set to 0. There is no method provided to clean up counters. A service may clean up a counter if it has some out-of-band mechanism to find out that the counter is no longer needed. For example, in an MLS context, once the MLS group is no longer in use, its counter can be discarded. 7.1. Lock API This is a simple REST style API over HTTPS used to request lock for a counter for a provided Counter ID. GET /lock/?val= Returns "Ok" if lock acquisition succeeded, a "Confict" response when lock is already held with a retry_later time for retrying the lock acquisition or a "CounterError" with the current value of the counter when the requested counter doesn't match the expected_next_value. 7.2. Increment API The increment HTTPS API allows the counter value stored in expected_next_value to be incremented for the provided Counter ID. POST /increment/ Returns "Ok" if the counter value was successfully incremented, a "Error" responses if the provider "Counter ID" hasn't been locked yet. TODO: Define Error responses and codes for authorization failures. 8. Interactions with MOQ Secure Objects MLS Key agreement generates a group shared secret, called "MLS Mater Key", per MLS Epoch. Epochs in MLS are incremented whenever there is changed in the group state due to an existing member commit the changes to the group. MLS generated shared group secret per epoch can be used to derive track_base_key when using SecureObjects (see Section 5 ) for protecting the objects within a MOQT track. The procedure for the same is as defined below: For each combination of (MLS Epoch, MLS Master Key) an 'Epoch Secret' is derived: Epoch Secret = HKDF.Extract("SecureObject Epoch Master Key " | MLS Epoch, MLS Master Key) 'Epoch Secret' is used to derive track_base_key per FullTrackName (see Section 3 of [SecureObjects]): track_base_key = HKDF.Expand("SecureObject Track Base Key " | FullTrackName, Epoch Secret) When encrypting/decrypting objects using SecureObject, the epoch under which the track_base_key was computed is used as KID in the SecureObject Header. The track_base_key computed is used to derive per object keys and nonce as defined in Section 5 of [SecureObjects]. All the objects within a given epoch are encrypted/decrypted with the keys derived from the Epoch Secret for that epoch. 9. Security Considerations TODO Security 10. IANA Considerations This document has no IANA actions. 11. Normative References [MoQTransport] Curley, L., Pugin, K., Nandakumar, S., Vasiliev, V., and I. Swett, "Media over QUIC Transport", Work in Progress, Internet-Draft, draft-ietf-moq-transport-03, 4 March 2024, . [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997, . [RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, May 2017, . [RFC9420] Barnes, R., Beurdouche, B., Robert, R., Millican, J., Omara, E., and K. Cohn-Gordon, "The Messaging Layer Security (MLS) Protocol", RFC 9420, DOI 10.17487/RFC9420, July 2023, . [SecureObjects] "Secure Objects for Media over QUIC", n.d., . Acknowledgments TODO acknowledge. Authors' Addresses Cullen Jennings Cisco Email: fluffy@cisco.com Richard L. Barnes Cisco Email: rlb@ipv.sx Suhas Nandakumar Cisco Email: snandaku@cisco.com