ARMWARE RFC Archive <- RFC Index (9601..9700)

RFC 9614




Internet Architecture Board (IAB)                           M. Kühlewind
Request for Comments: 9614                                              
Category: Informational                                         T. Pauly
ISSN: 2070-1721                                                         
                                                              C. A. Wood
                                                               July 2024

              Partitioning as an Architecture for Privacy

Abstract

   This document describes the principle of privacy partitioning, which
   selectively spreads data and communication across multiple parties as
   a means to improve privacy by separating user identity from user
   data.  This document describes emerging patterns in protocols to
   partition what data and metadata is revealed through protocol
   interactions, provides common terminology, and discusses how to
   analyze such models.

Status of This Memo

   This document is not an Internet Standards Track specification; it is
   published for informational purposes.

   This document is a product of the Internet Architecture Board (IAB)
   and represents information that the IAB has deemed valuable to
   provide for permanent record.  It represents the consensus of the
   Internet Architecture Board (IAB).  Documents approved for
   publication by the IAB are not candidates for any level of Internet
   Standard; see Section 2 of RFC 7841.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   https://www.rfc-editor.org/info/rfc9614.

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.

Table of Contents

   1.  Introduction
   2.  Privacy Partitioning
     2.1.  Privacy Contexts
     2.2.  Context Separation
     2.3.  Approaches to Partitioning
   3.  A Survey of Protocols Using Partitioning
     3.1.  CONNECT Proxying and MASQUE
     3.2.  Oblivious HTTP and DNS
     3.3.  Privacy Pass
     3.4.  Privacy Preserving Measurement
   4.  Applying Privacy Partitioning
     4.1.  User-Identifying Information
     4.2.  Selecting Client Identifiers
     4.3.  Incorrect or Incomplete Partitioning
     4.4.  Selecting Information within a Context
   5.  Limits of Privacy Partitioning
     5.1.  Violations by Collusion
     5.2.  Violations by Insufficient or Incorrect Partitioning
       5.2.1.  Violations from Application Information
       5.2.2.  Violations from Network Information
       5.2.3.  Violations from Side Channels
       5.2.4.  Identifying Partitions
   6.  Partitioning Impacts
   7.  Security Considerations
   8.  IANA Considerations
   9.  Informative References
   IAB Members at the Time of Approval
   Acknowledgments
   Authors' Addresses

1.  Introduction

   Protocols such as TLS and IPsec provide a secure (authenticated and
   encrypted) channel between two endpoints over which endpoints
   transfer information.  Encryption and authentication of data in
   transit are necessary to protect information from being seen or
   modified by parties other than the intended protocol participants.
   As such, this kind of security is necessary for ensuring that
   information transferred over these channels remains private.

   However, a secure channel between two endpoints is insufficient for
   the privacy of the endpoints themselves.  In recent years, privacy
   requirements have expanded beyond the need to protect data in transit
   between two endpoints.  Some examples of this expansion include:

   *  A user accessing a service on a website might not consent to
      reveal their location, but if that service is able to observe the
      client's IP address, it can learn something about the user's
      location.  This is problematic for privacy since the service can
      link user data to the user's location.

   *  A user might want to be able to access content for which they are
      authorized, such as a news article; but the news service might
      track which users access which articles, even if the user doesn't
      want their activity to be tracked.  This is problematic for
      privacy since the service can link user activity to the user's
      account.

   *  A client device might need to upload metrics to an aggregation
      service and in doing so allow the service to attribute the
      specific metrics contributions to that client device.  This is
      problematic for privacy since the service can link client
      contributions to the specific client.

   The commonality in these examples is that clients want to interact
   with or use a service without exposing too much user-specific or
   identifying information to that service.  In particular, separating
   the user-specific identity information from user-specific data is
   necessary for privacy.  Thus, in order to protect user privacy, it is
   important to keep identity (who) and data (what) separate.

   This document defines "privacy partitioning," sometimes also referred
   to as the "decoupling principle" [DECOUPLING], as the general
   technique used to separate the data and metadata visible to various
   parties in network communication, with the aim of improving user
   privacy.  Although privacy partitioning cannot guarantee there is no
   link between user-specific identity and user-specific data, when
   applied properly it helps ensure that user privacy violations become
   more technically difficult to achieve over time.

   Several IETF working groups are working on protocols or systems that
   adhere to the principle of privacy partitioning, including Oblivious
   HTTP Application Intermediation (OHAI), Multiplexed Application
   Substrate over QUIC Encryption (MASQUE), Privacy Pass, and Privacy
   Preserving Measurement (PPM).  This document summarizes work in those
   groups and describes a framework for thinking about the resulting
   privacy posture of different endpoints in practice.

   Privacy partitioning is particularly relevant as a tool for data
   minimization, which is described in Section 6.1 of [RFC6973].
   [RFC6973] provides guidance for privacy considerations in Internet
   protocols, along with a set of questions on how to evaluate the data
   minimization of a protocol in Section 7.1 of [RFC6973].  Protocols
   that employ privacy partitioning ought to consider the questions in
   that section when evaluating their design, particularly with regard
   to how identifiers and data can be correlated by protocol
   participants and observers in each context that has been partitioned.
   Privacy partitioning can also be used as a way to separate identity
   providers from relying parties (see Section 6.1.4 of [RFC6973]), as
   in the case of Privacy Pass (see Section 3.3).

   Privacy partitioning is not a panacea; applying it well requires
   holistic analysis of the system in question to determine whether or
   not partitioning as a tool, and as implemented, offers meaningful
   privacy improvements.  See Section 5 for more information.

2.  Privacy Partitioning

   For the purposes of user privacy, this document focuses on user-
   specific information.  This might include any identifying information
   that is specific to a user, such as their email address or IP
   address, or any data about the user, such as their date of birth.
   Informally, the goal of privacy partitioning is to ensure that each
   party in a system beyond the user themselves only has access to one
   type of user-specific information.

   This is a simple application of the principle of least privilege,
   wherein every party in a system only has access to the minimum amount
   of information needed to fulfill their function.  Privacy
   partitioning advocates for this minimization by ensuring that
   protocols, applications, and systems only reveal user-specific
   information to parties that need access to the information for their
   intended purpose.

   Put simply, privacy partitioning aims to separate _who_ someone is
   from _what_ they do.  In the rest of this section, we describe how
   privacy partitioning can be used to achieve this goal.

2.1.  Privacy Contexts

   Each piece of user-specific information exists within some context,
   where a context is abstractly defined as a set of data, metadata, and
   the entities that share access to that information.  In order to
   prevent the correlation of user-specific information across contexts,
   partitions need to ensure that any single entity (other than the
   client itself) does not participate in more than one context where
   the information is visible.

   [RFC6973] discusses the importance of identifiers in reducing
   correlation as a way of improving privacy:

   |  Correlation is the combination of various pieces of information
   |  related to an individual or that obtain that characteristic when
   |  combined....
   |  
   |  Correlation is closely related to identification.  Internet
   |  protocols can facilitate correlation by allowing individuals'
   |  activities to be tracked and combined over time....
   |  
   |  Pseudonymity is strengthened when less personal data can be linked
   |  to the pseudonym; when the same pseudonym is used less often and
   |  across fewer contexts; and when independently chosen pseudonyms
   |  are more frequently used for new actions (making them, from an
   |  observer's or attacker's perspective, unlinkable).

   Context separation is foundational to privacy partitioning and
   reducing correlation.  As an example, consider an unencrypted HTTP
   session over TCP, wherein the context includes both the content of
   the transaction as well as any metadata from the transport and IP
   headers; and the participants include the client, routers, other
   network middleboxes, intermediaries, and the server.  Middleboxes or
   intermediaries might simply forward traffic or might terminate the
   traffic at any layer (such as terminating the TCP connection from the
   client and creating another TCP connection to the server).
   Regardless of how the middlebox interacts with the traffic, for the
   purposes of privacy partitioning, it is able to observe all of the
   data in the context.

   +-------------------------------------------------------------------+
   | Context A                                                         |
   |  +--------+                +-----------+              +--------+  |
   |  |        +------HTTP------+           +--------------+        |  |
   |  | Client |                | Middlebox |              | Server |  |
   |  |        +------TCP-------+           +--------------+        |  |
   |  +--------+      flow      +-----------+              +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+

         Figure 1: Diagram of a Basic Unencrypted Client-to-Server
                        Connection with Middleboxes

   Adding TLS encryption to the HTTP session is a simple partitioning
   technique that splits the previous context into two separate
   contexts.  The content of the transaction is now only visible to the
   client, TLS-terminating intermediaries, and server, while the
   metadata in transport and IP headers remain in the original context.
   In this scenario, without any further partitioning, the entities that
   participate in both contexts can allow the data in both contexts to
   be correlated.

   +-------------------------------------------------------------------+
   | Context A                                                         |
   |  +--------+                                           +--------+  |
   |  |        |                                           |        |  |
   |  | Client +-------------------HTTPS-------------------+ Server |  |
   |  |        |                                           |        |  |
   |  +--------+                                           +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Context B                                                         |
   |  +--------+                +-----------+              +--------+  |
   |  |        |                |           |              |        |  |
   |  | Client +-------TCP------+ Middlebox +--------------+ Server |  |
   |  |        |       flow     |           |              |        |  |
   |  +--------+                +-----------+              +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+

       Figure 2: Diagram of How Adding Encryption Splits the Context
                                  into Two

   Another way to create a partition is to simply use separate
   connections.  For example, to split two separate HTTP requests from
   one another, a client could issue the requests on separate TCP
   connections, each on a different network and at different times, and
   avoid including obvious identifiers like HTTP cookies across the
   requests.

   +-------------------------------------------------------------------+
   | Context A                                                         |
   |  +--------+                +-----------+              +--------+  |
   |  |        | IP A           |           |              |        |  |
   |  | Client +-------TCP------+ Middlebox +--------------+ Server |  |
   |  |        |      flow A    |     A     |              |        |  |
   |  +--------+                +-----------+              +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Context B                                                         |
   |  +--------+                +-----------+              +--------+  |
   |  |        | IP B           |           |              |        |  |
   |  | Client +-------TCP------+ Middlebox +--------------+ Server |  |
   |  |        |      flow B    |     B     |              |        |  |
   |  +--------+                +-----------+              +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+

        Figure 3: Diagram of Making Separate Connections to Generate
                             Separate Contexts

   Using separate connections to create separate contexts can reduce or
   eliminate the ability of specific parties to correlate activity
   across contexts.  However, any identifier at any layer that is common
   across different contexts can be used as a way to correlate activity.
   Beyond IP addresses, many other factors can be used together to
   create a fingerprint of a specific device (such as Media Access
   Control (MAC) addresses, device properties, software properties and
   behavior, application state, etc.).

2.2.  Context Separation

   In order to define and analyze how various partitioning techniques
   work, the boundaries of what is being partitioned need to be
   established.  This is the role of context separation.  In particular,
   in order to prevent the correlation of user-specific information
   across contexts, partitions need to ensure that any single entity
   (other than the client itself) does not participate in contexts where
   both identifiers are visible.

   Context separation can be achieved in different ways, for example,
   over time, across network paths, based on (en)coding, etc.  The
   privacy-oriented protocols described in this document generally
   involve more complex partitioning, but the techniques to partition
   communication contexts still employ the same techniques:

   *  Cryptographic protection, such as the use of encryption to
      specific parties, allows partitioning of contexts between
      different parties (those with the ability to remove cryptographic
      protections, and those without).

   *  Connection separation across time or space to allow partitioning
      of contexts for different application transactions over the
      network.

   These techniques are frequently used in conjunction for context
   separation.  For example, encrypting an HTTP exchange using TLS
   between the client and TLS-terminating server might prevent a network
   middlebox that sees a client IP address from seeing the user account
   identifier, but it doesn't prevent the TLS-terminating server from
   observing both identifiers and correlating them.  As such, preventing
   correlation requires separating contexts, such as by using proxying
   to conceal a client's IP address that would otherwise be used as an
   identifier.

2.3.  Approaches to Partitioning

   While all of the partitioning protocols described in this document
   create separate contexts using cryptographic protection and/or
   connection separation, each one has a unique approach that results in
   different sets of contexts.  Since many of these protocols are new,
   it is yet to be seen how each approach will be used at scale across
   the Internet and what new models will emerge in the future.

   There are multiple factors that lead to a diversity in approaches to
   partitioning, including:

   *  Adding privacy partitioning to existing protocol ecosystems places
      requirements and constraints on how contexts are constructed.
      CONNECT-style proxying is intended to work with servers that are
      unaware of privacy contexts, requiring more intermediaries to
      provide strong separation guarantees.  On the other hand,
      Oblivious HTTP assumes servers that cooperate with context
      separation and, thus, reduces the overall number of elements in
      the solution.

   *  Whether or not information exchange needs to happen
      bidirectionally in an interactive fashion determines how contexts
      can be separated.  Some use cases, like metrics collection for
      PPM, can occur whereby information only flows from clients to
      servers and can function even when clients are no longer
      connected.  Privacy Pass is an example of a case that can be
      either interactive or not, depending on whether tokens can be
      cached and reused.  CONNECT-style proxying and Oblivious HTTP
      often require bidirectional and interactive communication.

   *  The degree to which contexts need to be partitioned depends in
      part on the client's threat models and level of trust in various
      protocol participants.  For example, in Oblivious HTTP, clients
      allow relays to learn that clients are accessing a particular
      application-specific gateway.  If clients do not trust relays with
      this information, they can instead use a multi-hop CONNECT-style
      proxy approach wherein no single party learns whether specific
      clients are accessing a specific application.  This is the default
      trust model for systems like Tor, where multiple hops are used to
      drive down the probability of privacy violations due to collusion
      or related attacks.

3.  A Survey of Protocols Using Partitioning

   The following section discusses current on-going work in the IETF
   that is applying privacy partitioning.

3.1.  CONNECT Proxying and MASQUE

   When using encryption on the connection between the client and the
   proxy, HTTP forward proxies provide privacy partitioning by
   separating a connection into multiple segments.  When connections to
   targets via the proxy themselves are encrypted, the proxy cannot see
   the end-to-end content.  HTTP has historically supported forward
   proxying for TCP-like streams via the CONNECT method.  More recently,
   the Multiplexed Application Substrate over QUIC Encryption (MASQUE)
   Working Group has developed protocols to similarly proxy UDP
   [CONNECT-UDP] and IP packets [CONNECT-IP] based on tunneling.

   In a single-proxy setup, there is a tunnel connection between the
   client and proxy and an end-to-end connection that is tunneled
   between the client and target.  This setup, as shown in Figure 4,
   partitions communication into:

   *  a Client-to-Target encrypted context, which contains the end-to-
      end content within the TLS session to the target, such as HTTP
      content;

   *  a Client-to-Target proxied context, which is the end-to-end data
      exchanged with the target that is also visible to the proxy, such
      as a TLS session;

   *  a Client-to-Proxy context, which contains the transport metadata
      between the client and the target, and the request to the proxy to
      open a connection to the target; and

   *  a Proxy-to-Target context, which for TCP and UDP proxying contains
      any packet header information that is added or modified by the
      proxy, e.g., the IP and TCP/UDP headers.

   +-------------------------------------------------------------------+
   | Client-to-Target Encrypted Context                                |
   |  +--------+                                           +--------+  |
   |  |        |                                           |        |  |
   |  | Client +------------------HTTPS--------------------+ Target |  |
   |  |        |                 content                   |        |  |
   |  +--------+                                           +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Client-to-Target Proxied Context                                  |
   |  +--------+                +-----------+              +--------+  |
   |  |        |                |           |              |        |  |
   |  | Client +----Proxied-----+   Proxy   +--------------+ Target |  |
   |  |        |    TLS flow    |           |              |        |  |
   |  +--------+                +-----------+              +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Client-to-Proxy Context                                           |
   |  +--------+                +-----------+                          |
   |  |        |                |           |                          |
   |  | Client +---Transport----+   Proxy   |                          |
   |  |        |     flow       |           |                          |
   |  +--------+                +-----------+                          |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Proxy-to-Target Context                                           |
   |                            +-----------+              +--------+  |
   |                            |           |              |        |  |
   |                            |   Proxy   +--Transport---+ Target |  |
   |                            |           |    flow      |        |  |
   |                            +-----------+              +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+

                Figure 4: Diagram of One-Hop Proxy Contexts

   Using two (or more) proxies provides better privacy partitioning.  In
   particular, with two proxies, each proxy sees the Client metadata but
   not the Target, the Target but not the Client metadata, or neither.

   In addition to the contexts described above for the single proxy
   case, the two-hop proxy case shown in Figure 5 changes the contexts
   in several ways:

   *  the Client-to-Target proxied context only includes the second
      proxy (referred to here as "Proxy B");

   *  a new Client-to-Proxy B context is added, which is the TLS session
      from the client to Proxy B that is also visible to the first proxy
      (referred to here as "Proxy A");

   *  the contexts that see transport data only (TCP or UDP over IP) are
      separated out into three separate contexts, a Client-to-Proxy A
      context, a Proxy A-to-Proxy B context, and a Proxy B-to-Target
      context.

   +-------------------------------------------------------------------+
   | Client-to-Target Encrypted Context                                |
   |  +--------+                                           +--------+  |
   |  |        |                                           |        |  |
   |  | Client +------------------HTTPS--------------------+ Target |  |
   |  |        |                 content                   |        |  |
   |  +--------+                                           +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Client-to-Target Proxied Context                                  |
   |  +--------+                           +-------+       +--------+  |
   |  |        |                           |       |       |        |  |
   |  | Client +----------Proxied----------+ Proxy +-------+ Target |  |
   |  |        |          TLS flow         |   B   |       |        |  |
   |  +--------+                           +-------+       +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Client-to-Proxy B Context                                         |
   |  +--------+         +-------+         +-------+                   |
   |  |        |         |       |         |       |                   |
   |  | Client +---------+ Proxy +---------+ Proxy |                   |
   |  |        |         |   A   |         |   B   |                   |
   |  +--------+         +-------+         +-------+                   |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Client-to-Proxy A Context                                         |
   |  +--------+         +-------+                                     |
   |  |        |         |       |                                     |
   |  | Client +---------+ Proxy |                                     |
   |  |        |         |   A   |                                     |
   |  +--------+         +-------+                                     |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Proxy A-to-Proxy B Context                                        |
   |                     +-------+         +-------+                   |
   |                     |       |         |       |                   |
   |                     | Proxy +---------+ Proxy |                   |
   |                     |   A   |         |   B   |                   |
   |                     +-------+         +-------+                   |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Proxy B-to-Target Context                                         |
   |                                       +-------+       +--------+  |
   |                                       |       |       |        |  |
   |                                       | Proxy +-------+ Target |  |
   |                                       |   B   |       |        |  |
   |                                       +-------+       +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+

                Figure 5: Diagram of Two-Hop Proxy Contexts

   Forward proxying, such as the modes of proxying in the protocols
   developed in MASQUE, uses both encryption (via TLS) and separation of
   connections (via proxy hops that see only the next hop) to achieve
   privacy partitioning.

3.2.  Oblivious HTTP and DNS

   Oblivious HTTP [OHTTP], developed in the Oblivious HTTP Application
   Intermediation (OHAI) Working Group, adds per-message encryption to
   HTTP exchanges through a relay system.  Clients send requests through
   an Oblivious Relay, which cannot read message contents, to an
   Oblivious Gateway, which can decrypt the messages but cannot
   communicate directly with the client or observe client metadata like
   an IP address.  Oblivious HTTP relies on Hybrid Public Key Encryption
   [HPKE] to perform encryption.

   Oblivious HTTP uses both encryption and separation of connections to
   achieve privacy partitioning.

   *  End-to-end messages are encrypted between the Client and Gateway.
      The content of these inner messages are visible to the Client,
      Gateway, and Target.  This is the Client-to-Target context.

   *  The encrypted messages exchanged between the Client and Gateway
      are visible to the Relay, but the Relay cannot decrypt the
      messages.  This is the Client-to-Gateway context.

   *  The transport (such as TCP and TLS) connections between the
      Client, Relay, and Gateway form two separate contexts: a Client-
      to-Relay context and a Relay-to-Gateway context.  It is important
      to note that the Relay-to-Gateway connection can be a single
      connection, even if the Relay has many separate Clients.  This
      provides better anonymity by making the pseudonym presented by the
      Relay to be shared across many Clients.

   +-------------------------------------------------------------------+
   | Client-to-Target Context                                          |
   |  +--------+                           +---------+     +--------+  |
   |  |        |                           |         |     |        |  |
   |  | Client +---------------------------+ Gateway +-----+ Target |  |
   |  |        |                           |         |     |        |  |
   |  +--------+                           +---------+     +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Client-to-Gateway Context                                         |
   |  +--------+         +-------+         +---------+                 |
   |  |        |         |       |         |         |                 |
   |  | Client +---------+ Relay +---------+ Gateway |                 |
   |  |        |         |       |         |         |                 |
   |  +--------+         +-------+         +---------+                 |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Client-to-Relay Context                                           |
   |  +--------+         +-------+                                     |
   |  |        |         |       |                                     |
   |  | Client +---------+ Relay |                                     |
   |  |        |         |       |                                     |
   |  +--------+         +-------+                                     |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Relay-to-Gateway Context                                          |
   |                     +-------+         +---------+                 |
   |                     |       |         |         |                 |
   |                     + Relay +---------+ Gateway |                 |
   |                     |       |         |         |                 |
   |                     +-------+         +---------+                 |
   |                                                                   |
   +-------------------------------------------------------------------+

                Figure 6: Diagram of Oblivious HTTP Contexts

   Oblivious DNS over HTTPS (ODoH) [ODOH] applies the same principle as
   Oblivious HTTP but operates on DNS messages only.  As a precursor to
   the more generalized Oblivious HTTP, it relies on the same HPKE
   cryptographic primitives and can be analyzed in the same way.

3.3.  Privacy Pass

   Privacy Pass is an architecture [RFC9576] and a set of protocols
   being developed in the Privacy Pass Working Group that allows clients
   to present proof of verification in an anonymous and unlinkable
   fashion via tokens.  These tokens were originally designed as a way
   to prove that a client had solved a CAPTCHA, but they can be applied
   to other types of user or device attestation checks as well.  In
   Privacy Pass, clients interact with an attester and issuer for the
   purposes of issuing a token, and clients then interact with an origin
   server to redeem said token.

   In Privacy Pass, privacy partitioning is achieved with cryptographic
   protection (in the form of blind signature protocols or similar) and
   separation of connections across two contexts: a "redemption context"
   between clients and origins (servers that request and receive
   tokens), and an "issuance context" between clients, attestation
   servers, and token issuance servers.  The cryptographic protection
   ensures that information revealed during the issuance context is
   separated from information revealed during the redemption context.

   +-------------------------------------------------------------------+
   | Redemption Context                                                |
   |  +--------+         +--------+                                    |
   |  |        |         |        |                                    |
   |  | Origin +---------+ Client |                                    |
   |  |        |         |        |                                    |
   |  +--------+         +--------+                                    |
   |                                                                   |
   +-------------------------------------------------------------------+
   | Issuance Context                                                  |
   |                     +--------+      +----------+      +--------+  |
   |                     |        |      |          |      |        |  |
   |                     | Client +------+ Attester +------+ Issuer |  |
   |                     |        |      |          |      |        |  |
   |                     +--------+      +----------+      +--------+  |
   |                                                                   |
   +-------------------------------------------------------------------+

               Figure 7: Diagram of Contexts in Privacy Pass

   Since the redemption context and issuance context are separate
   connections that involve separate entities, they can also be further
   decoupled by running those parts of the protocols at different times.
   Clients can fetch tokens through the issuance context early and cache
   the tokens for later use in redemption contexts.  This can aid in
   partitioning identifiers and data.

   [RFC9576] describes different deployment models for which entities
   operate origins, attesters, and issuers; in some models, they are all
   separate entities, and in others they can be operated by the same
   entity.  The model impacts the effectiveness of partitioning, and
   some models (such as when all three are operated by the same entity)
   only provide effective partitioning when the timing of connections on
   the two contexts are not correlated and when the client uses
   different identifiers (such as different IP addresses) on each
   context.

3.4.  Privacy Preserving Measurement

   The Privacy Preserving Measurement (PPM) Working Group is chartered
   to develop protocols and systems that help a data aggregation or
   collection server (or multiple non-colluding servers) compute
   aggregate values without learning the value of any one client's
   individual measurement.  The Distributed Aggregation Protocol (DAP)
   is the primary working item of the group.

   At a high level, DAP uses a combination of cryptographic protection
   (in the form of secret sharing amongst non-colluding servers) to
   establish two contexts:

   *  an "upload context" between clients and non-colluding aggregation
      servers (in which the servers are separated into "Helper" and
      "Leader" roles) wherein aggregation servers possibly learn client
      identity but nothing about their individual measurement reports;
      and

   *  a "collect context" wherein a collector learns aggregate
      measurement results and nothing about individual client data.

   +-------------------------------------+--------------------+
   | Upload Context                      | Collect Context    |
   |                     +------------+  |                    |
   |              +----->|   Helper   |  |                    |
   | +--------+   |      +------------+  |                    |
   | |        +---+             ^        |   +-----------+    |
   | | Client |                 |        |   | Collector |    |
   | |        +---+             v        |   +-----+-----+    |
   | +--------+   |      +------------+  |         |          |
   |              +----->|   Leader   |<-----------+          |
   |                     +------------+  |                    |
   +-------------------------------------+--------------------+

                    Figure 8: Diagram of Contexts in DAP

4.  Applying Privacy Partitioning

   Applying privacy partitioning to an existing or new system or
   protocol requires the following steps:

   1.  Identify the types of information used or exposed in a system or
       protocol, some of which can be used to identify a user or
       correlate to other contexts.

   2.  Partition data to minimize the amount of user-identifying or
       correlatable information in any given context to only include
       what is necessary for that context and prevent the sharing of
       data across contexts wherever possible.

   The most impactful types of information to partition are (a) user-
   identifying information, such as user identifiers (including account
   names or IP addresses) that can be linked and (b) non-user-
   identifying information (including content a user generates or
   accesses), which can be often sensitive when combined with a user
   identifier.

   In this section, we discuss considerations for partitioning these
   types of information.

4.1.  User-Identifying Information

   User data can itself be user-identifying, in which case it should be
   treated as an identifier.  For example, Oblivious DoH and Oblivious
   HTTP partition the client IP address and client request data into
   separate contexts, thereby ensuring that no entity beyond the client
   can observe both.  Collusion across contexts could reverse this
   partitioning and cause non-user-identifying information to become
   user-identifying information.  For example, in CONNECT proxy systems
   that use QUIC, the QUIC connection ID is inherently non-user-
   identifying since it is generated randomly (Section 5.1 of [QUIC]).
   However, if combined with another context that has user-identifying
   information such as the client IP address, the QUIC connection ID can
   become user-identifying information.

   Some information is innate to client user-agents, including details
   of the network location and implementation of protocols in hardware
   and software.  This information can be used to construct user-
   identifying information, which is a process sometimes referred to as
   "fingerprinting".  Depending on the application and system
   constraints, users may not be able to prevent fingerprinting in
   privacy contexts.  As a result, fingerprinting information, when
   combined with non-user-identifying user data, could turn that
   otherwise innocuous user data into user-identifying information.

4.2.  Selecting Client Identifiers

   The selection of client identifiers used in the contexts used for
   privacy partitioning has a large impact on the effectiveness of
   partitioning.  Identifier selection can either undermine or improve
   the value of partitioning.  Generally, each context involves some
   form of client identifier, which might be directly associated with a
   client identity but can also be a pseudonym or a random one-time
   identifier.

   Using the same client identifier across multiple contexts can partly
   or wholly undermine the effectiveness of partitioning by allowing the
   various contexts to be linked back to the same client.  For example,
   if a client uses proxies as described in Section 3.1 to separate
   connections but uses the same email address to authenticate to two
   servers in different contexts, those actions can be linked back to
   the same client.  While this does not undermine all of the
   partitioning achieved through proxying (the contexts along the
   network path still cannot correlate the client identity and what
   servers are being accessed), the overall effect of partitioning is
   diminished.

   When possible, using per-context unique client identifiers provides
   better partitioning properties.  For example, a client can use a
   unique email address as an account identifier with each different
   server it needs to log into.  The same approach can apply across many
   layers, as seen with per-network MAC address randomization
   [RANDOM-MAC], use of multiple temporary IP addresses across
   connections and over time [RFC8981], and use of unique per-
   subscription identifiers for HTTP Web Push [RFC8030].

4.3.  Incorrect or Incomplete Partitioning

   Privacy partitioning can be applied incorrectly or incompletely.
   Contexts may contain more user-identifying information than desired,
   or some information in a context may be more user-identifying than
   intended.  Moreover, splitting user-identifying information over
   multiple contexts has to be done with care, as creating more contexts
   can increase the number of entities that need to be trusted to not
   collude.  Nevertheless, partitions can help improve the client's
   privacy posture when applied carefully.

   Evaluating and qualifying the resulting privacy of a system or
   protocol that applies privacy partitioning depends on the contexts
   that exist and the types of user-identifying information in each
   context.  Such evaluation is helpful for identifying ways in which
   systems or protocols can improve their privacy posture.  For example,
   consider DNS over HTTPS [DOH], which produces a single context that
   contains both the client IP address and client query.  One
   application of privacy partitioning results in ODoH, which produces
   two contexts, one with the client IP address and the other with the
   client query.

4.4.  Selecting Information within a Context

   Recognizing potential applications of privacy partitioning requires
   identifying the contexts in use, the information exposed in a
   context, and the intent of information exposed in a context.
   Unfortunately, determining what information to include in a given
   context is a non-trivial task.  In principle, the information
   contained in a context should be fit for purpose.  As such, new
   systems or protocols developed should aim to ensure that all
   information exposed in a context serves as few purposes as possible.
   Designing with this principle from the start helps mitigate issues
   that arise if users of the system or protocol inadvertently ossify on
   the information available in contexts.  Legacy systems that have
   ossified on information available in contexts may be difficult to
   change in practice.  As an example, many existing anti-abuse systems
   depend on some client identifier, such as the client IP address,
   coupled with client data to provide value.  Partitioning contexts in
   these systems such that they no longer determine the client identity
   requires new solutions to the anti-abuse problem.

5.  Limits of Privacy Partitioning

   Privacy partitioning aims to increase user privacy, though, as
   stated, it is merely one of possibly many architectural tools that
   help manage privacy risks.  Understanding the limits of its benefits
   requires a more comprehensive analysis of the system in question.
   Such analysis also helps determine whether or not the tool has been
   applied correctly.  In particular, the value of privacy partitioning
   depends on numerous factors, including, though not limited to, the
   following:

   *  non-collusion across contexts and

   *  the type of information exposed in each context.

   We elaborate on each in the following sections.

5.1.  Violations by Collusion

   Privacy partitions ensure that only the client, i.e., the entity that
   is responsible for partitioning, can independently link all user-
   specific information.  No other entity individually knows how to link
   all the user-specific information as long as they do not collude with
   each other across contexts.  Thus, non-collusion is a fundamental
   requirement for privacy partitioning to offer meaningful privacy for
   end users.  In particular, the trust relationships that users have
   with different parties affect the resulting impact on the user's
   privacy.

   As an example, consider Oblivious HTTP (OHTTP), wherein the Oblivious
   Relay knows the client identity but not the client data, and the
   Oblivious Gateway knows the client data but not the client identity.
   If the Oblivious Relay and Gateway collude, they can link client
   identity and data together for each request and response transaction
   by simply observing requests in transit.

   It is not currently possible to guarantee with technical protocol
   measures that two entities are not colluding.  Even if two entities
   do not collude directly, if both entities reveal information to other
   parties, it will not be possible to guarantee that the information
   won't be combined.  However, there are some mitigations that can be
   applied to reduce the risk of collusion happening in practice:

   *  Policy and contractual agreements between entities involved in
      partitioning to disallow logging or sharing of data, along with
      auditing to validate that the policies are being followed.  For
      cases where logging is required (such as for service operation),
      such logged data should be minimized and anonymized to prevent it
      from being useful for collusion.

   *  Protocol requirements to make collusion or data sharing more
      difficult.

   *  Adding more partitions and contexts to make it increasingly
      difficult to collude with enough parties to recover identities.

5.2.  Violations by Insufficient or Incorrect Partitioning

   Insufficient or incorrect application of privacy partitioning can
   lessen or negate benefits to users.  In particular, it is possible to
   apply partitioning in a way that is either insufficient or incorrect
   for meaningful privacy.  For example, partitioning at one layer in
   the stack can fail to account for linkable information at different
   layers in the stack.  Privacy violations can stem from partitioning
   failures in a multitude of ways, some of which are described in the
   following sections.

5.2.1.  Violations from Application Information

   Partitioning at the network layer can be insufficient when the
   application layer fails to properly partition.  As an example,
   consider OHTTP used for the purposes of hiding client-identifying
   information for a browser telemetry system.  It is entirely possible
   for reports in such a telemetry system to contain both client-
   specific telemetry data, such as information about their specific
   browser instance, as well as client-identifying information, such as
   the client's email address, location, or IP address.  Even though
   OHTTP separates the client IP address from the server via a relay,
   the server can still learn this directly from the client's telemetry
   report.

5.2.2.  Violations from Network Information

   It is also possible to inadequately partition at the network layer.
   As an example, consider both TLS Encrypted Client Hello (ECH)
   [TLS-ESNI] and VPNs.  ECH uses cryptographic protection (encryption)
   to hide information from unauthorized parties, but both clients and
   servers (two entities) can link user-specific data to a user-specific
   identifier (IP address).  Similarly, while VPNs hide identifiers from
   end servers, the VPN server can still see the identifiers of both the
   client and server.  Applying privacy partitioning would advocate for
   at least two additional entities to avoid revealing both identity
   (who) and user actions (what) from each involved party.

5.2.3.  Violations from Side Channels

   Beyond the information that is intentionally revealed by applying
   privacy partitioning, it is also possible for the information to be
   unintentionally revealed through side channels.  For example, in the
   two-hop proxy arrangement described in Section 3.1, Proxy A sees and
   proxies TLS data between the client and Proxy B.  While it does not
   directly learn information that Proxy B sees, it does learn
   information through metadata, such as the timing and size of
   encrypted data being proxied.  Traffic analysis could be exploited to
   learn more information from such metadata, including, in some cases,
   application data that Proxy A was never meant to see.  Although
   privacy partitioning does not obviate such attacks, it does increase
   the cost necessary to carry them out in practice.  See Section 7 for
   more discussion on this topic.

5.2.4.  Identifying Partitions

   While straightforward violations of user privacy that stem from
   insufficient partitioning may seem straightforward to mitigate, it
   remains an open problem to rigorously determine what information
   needs to be partitioned for meaningful privacy and to implement it in
   a way that achieves the desired properties.  In essence, it is
   difficult to determine whether a certain set of information reveals
   "too much" about a specific user, and it is similarly challenging to
   determine whether or not an implementation of partitioning works as
   intended.  There is ample evidence of data being assumed "private" or
   "anonymous" but, in hindsight, winds up revealing too much
   information such that it allows one to link back to individual
   clients; see [DataSetReconstruction] and [CensusReconstruction] for
   more examples of this in the real world.

6.  Partitioning Impacts

   Applying privacy partitioning to communication protocols leads to a
   substantial change in communication patterns.  For example, instead
   of sending traffic directly to a service, essentially all user
   traffic is routed through a set of intermediaries, possibly adding
   more end-to-end round trips in the process (depending on the system
   and protocol).  This has a number of practical implications,
   described below.

   1.  Service operational or management challenges: Information that is
       usually passively observed in the network or metadata that has
       been unintentionally revealed to the service provider will no
       longer be available; for example, this can impact existing
       security procedures such as application rate limiting or DDoS
       mitigation.  Current network management techniques deployed often
       rely on information that is exposed by typical traffic that lacks
       guarantees or accuracy.

       Privacy partitioning provides an opportunity for improvements in
       these management techniques by enabling active exchange of
       information with each entity in a privacy-preserving way and
       requesting exactly the information needed for a specific task or
       function rather than relying on information derived from a
       limited set of unintentionally revealed information that cannot
       be guaranteed to be available and may be removed in the future.

   2.  Varying performance effects and costs: Depending on how context
       separation is done, privacy partitioning may affect application
       performance.  As an example, Privacy Pass introduces an entire
       end-to-end round trip to issue a token before it can be redeemed,
       thereby decreasing performance.  In contrast, while systems like
       CONNECT proxying may seem like they would reduce performance,
       oftentimes the highly optimized nature of proxy-to-proxy paths
       leads to improved performance.

       Reduced performance can be a reason that protocols and
       deployments will not apply privacy partitioning.  For example,
       HTTPS connection reuse (Section 9.1.1 of [HTTP2]) allows clients
       to use an existing HTTPS session created for one origin to
       interact with different origins (provided that the original
       origin is authoritative for these alternative origins).  Reusing
       connections saves the cost of connection establishment but means
       that the server can now link the client's activity with these two
       or more origins together.  Applying privacy partitioning would
       prevent this, but typically at the cost of performance.

       In general, while performance and privacy trade-offs are often
       cast as a zero-sum game, in practice this is often not the case.
       The relationship between privacy and performance varies depending
       on a number of related factors, such as application
       characteristics, network path properties, and so on.

   3.  Increased attack surface: Even in the event that information is
       adequately partitioned across non-colluding parties, the
       resulting effects on the end user may not always be positive.
       For example, using OHTTP as a basis for illustration, consider a
       hypothetical scenario where the Oblivious Gateway has an
       implementation flaw that causes all of its decrypt requests to be
       inappropriately logged in a public or otherwise compromised
       location.  Moreover, assume that the Target Resource for which
       these requests are destined does not have such an implementation
       flaw.  Applications that use OHTTP with this flawed Oblivious
       Gateway to interact with the Target Resource risk their user
       request information being made public, albeit in a way that is
       decoupled from user identifying information, whereas applications
       that do not use OHTTP to interact with the Target Resource do not
       risk this type of disclosure.

   4.  Centralization: Depending on the protocol and system, as well as
       the desired privacy properties, the use of partitioning may
       inherently force centralization to a selected set of trusted
       participants.  As an example, the impact of OHTTP on end-user
       privacy generally increases proportionally to the number of users
       that exist behind a given Oblivious Relay.  That is, the
       probability of an Oblivious Gateway determining the client
       associated with a request forwarded through an Oblivious Relay
       decreases as the number of possible clients behind the Oblivious
       Relay increases.  This trade-off encourages the centralization of
       the Oblivious Relays.

7.  Security Considerations

   Section 5 discusses some of the limitations of privacy partitioning
   in practice and advocates for holistic analysis to understand the
   extent to which privacy partitioning offers meaningful privacy
   improvements.  Applied correctly, partitioning helps improve an end-
   user's privacy posture, thereby making violations harder to do via
   technical, social, or policy means.  For example, side channels such
   as traffic analysis [FINGERPINT] or timing analysis are still
   possible and can allow an unauthorized entity to learn information
   about a context they are not a participant of.  Proposed mitigations
   for these types of attacks, e.g., padding application traffic or
   generating fake traffic, can be very expensive and are therefore not
   typically applied in practice.  Nevertheless, privacy partitioning
   moves the threat vector from one that has direct access to user-
   specific information to one that requires more effort, e.g.,
   computational resources, to violate end-user privacy.

8.  IANA Considerations

   This document has no IANA actions.

9.  Informative References

   [CensusReconstruction]
              United States Consensus Bureau, "The Census Bureau's
              Simulated Reconstruction-Abetted Re-identification Attack
              on the 2010 Census", May 2021,
              <https://www.census.gov/data/academy/webinars/2021/
              disclosure-avoidance-series/simulated-reconstruction-
              abetted-re-identification-attack-on-the-2010-census.html>.

   [CONNECT-IP]
              Pauly, T., Ed., Schinazi, D., Chernyakhovsky, A.,
              Kühlewind, M., and M. Westerlund, "Proxying IP in HTTP",
              RFC 9484, DOI 10.17487/RFC9484, October 2023,
              <https://www.rfc-editor.org/info/rfc9484>.

   [CONNECT-UDP]
              Schinazi, D. and L. Pardue, "HTTP Datagrams and the
              Capsule Protocol", RFC 9297, DOI 10.17487/RFC9297, August
              2022, <https://www.rfc-editor.org/info/rfc9297>.

   [DataSetReconstruction]
              Narayanan, A. and V. Shmatikov, "Robust De-anonymization
              of Large Sparse Datasets", IEEE Symposium on Security and
              Privacy, DOI 10.1109/sp.2008.33, May 2008,
              <https://doi.org/10.1109/sp.2008.33>.

   [DECOUPLING]
              Schmitt, P., Iyengar, J., Wood, C., and B. Raghavan, "The
              decoupling principle: a practical privacy framework",
              Proceedings of the 21st ACM Workshop on Hot Topics in
              Networks, DOI 10.1145/3563766.3564112, November 2022,
              <https://doi.org/10.1145/3563766.3564112>.

   [DOH]      Hoffman, P. and P. McManus, "DNS Queries over HTTPS
              (DoH)", RFC 8484, DOI 10.17487/RFC8484, October 2018,
              <https://www.rfc-editor.org/info/rfc8484>.

   [FINGERPINT]
              Goldberg, I., Wang, T., and C. A. Wood, "Network-Based
              Website Fingerprinting", Work in Progress, Internet-Draft,
              draft-irtf-pearg-website-fingerprinting-01, 8 September
              2020, <https://datatracker.ietf.org/doc/html/draft-irtf-
              pearg-website-fingerprinting-01>.

   [HPKE]     Barnes, R., Bhargavan, K., Lipp, B., and C. Wood, "Hybrid
              Public Key Encryption", RFC 9180, DOI 10.17487/RFC9180,
              February 2022, <https://www.rfc-editor.org/info/rfc9180>.

   [HTTP2]    Thomson, M., Ed. and C. Benfield, Ed., "HTTP/2", RFC 9113,
              DOI 10.17487/RFC9113, June 2022,
              <https://www.rfc-editor.org/info/rfc9113>.

   [ODOH]     Kinnear, E., McManus, P., Pauly, T., Verma, T., and C.A.
              Wood, "Oblivious DNS over HTTPS", RFC 9230,
              DOI 10.17487/RFC9230, June 2022,
              <https://www.rfc-editor.org/info/rfc9230>.

   [OHTTP]    Thomson, M. and C. A. Wood, "Oblivious HTTP", RFC 9458,
              DOI 10.17487/RFC9458, January 2024,
              <https://www.rfc-editor.org/info/rfc9458>.

   [QUIC]     Iyengar, J., Ed. and M. Thomson, Ed., "QUIC: A UDP-Based
              Multiplexed and Secure Transport", RFC 9000,
              DOI 10.17487/RFC9000, May 2021,
              <https://www.rfc-editor.org/info/rfc9000>.

   [RANDOM-MAC]
              Zuniga, JC., Bernardos, CJ., Ed., and A. Andersdotter,
              "Randomized and Changing MAC Address state of affairs",
              Work in Progress, Internet-Draft, draft-ietf-madinas-mac-
              address-randomization-12, 28 February 2024,
              <https://datatracker.ietf.org/doc/html/draft-ietf-madinas-
              mac-address-randomization-12>.

   [RFC6973]  Cooper, A., Tschofenig, H., Aboba, B., Peterson, J.,
              Morris, J., Hansen, M., and R. Smith, "Privacy
              Considerations for Internet Protocols", RFC 6973,
              DOI 10.17487/RFC6973, July 2013,
              <https://www.rfc-editor.org/info/rfc6973>.

   [RFC8030]  Thomson, M., Damaggio, E., and B. Raymor, Ed., "Generic
              Event Delivery Using HTTP Push", RFC 8030,
              DOI 10.17487/RFC8030, December 2016,
              <https://www.rfc-editor.org/info/rfc8030>.

   [RFC8981]  Gont, F., Krishnan, S., Narten, T., and R. Draves,
              "Temporary Address Extensions for Stateless Address
              Autoconfiguration in IPv6", RFC 8981,
              DOI 10.17487/RFC8981, February 2021,
              <https://www.rfc-editor.org/info/rfc8981>.

   [RFC9576]  Davidson, A., Iyengar, J., and C. A. Wood, "The Privacy
              Pass Architecture", RFC 9576, DOI 10.17487/RFC9576, June
              2024, <https://www.rfc-editor.org/info/rfc9576>.

   [TLS-ESNI] Rescorla, E., Oku, K., Sullivan, N., and C. A. Wood, "TLS
              Encrypted Client Hello", Work in Progress, Internet-Draft,
              draft-ietf-tls-esni-18, 4 March 2024,
              <https://datatracker.ietf.org/doc/html/draft-ietf-tls-
              esni-18>.

IAB Members at the Time of Approval

   Internet Architecture Board members at the time this document was
   approved for publication were:

      Dhruv Dhody
      Lars Eggert
      Wes Hardaker
      Cullen Jennings
      Mallory Knodel
      Suresh Krishnan
      Mirja Kühlewind
      Tommy Pauly
      Alvaro Retana
      David Schinazi
      Christopher A. Wood
      Qin Wu
      Jiankang Yao

Acknowledgments

   We would like to thank Martin Thomson, Eliot Lear, Mark Nottingham,
   Niels ten Oever, Vittorio Bertola, Antoine Fressancourt, Cullen
   Jennings, and Dhruv Dhody for their reviews and feedback.

Authors' Addresses

   Mirja Kühlewind
   Email: mirja.kuehlewind@ericsson.com

   Tommy Pauly
   Email: tpauly@apple.com

   Christopher A. Wood
   Email: caw@heapingbits.net