Internet-Draft	keyshare	April 2025
Wagner & Wang	Expires 6 October 2025	[Page]

Workgroup:: Transport Layer Security
Internet-Draft:: draft-wagner-tls-keysharepqc-00
Published:: 4 April 2025
Intended Status:: Standards Track
Expires:: 6 October 2025
Authors:: J. Wagner

UNC Charlotte

Y. Wang

UNC Charlotte

New Key Share Extension for Classic McEliece Algorithms

Abstract

[RFC8446] is modified to where another key share extension is introduced to accommodate both public keys and ciphertexts in ClientHello and ServerHello messages for post-quantum algorithms that have large public keys, including the code-based cryptographic schemes the Classic McEliece family and the RLCE algorithm group.¶

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://jwagrunner.github.io/internet-draft/draft-wagner-tls-keysharepqc.html. Status information for this document may be found at https://datatracker.ietf.org/doc/draft-wagner-tls-keysharepqc/.¶

Discussion of this document takes place on the Transport Layer Security mailing list (mailto:tls@ietf.org), which is archived at https://mailarchive.ietf.org/arch/browse/tls/. Subscribe at https://www.ietf.org/mailman/listinfo/tls/.¶

Source for this draft and an issue tracker can be found at https://github.com/jwagrunner/internet-draft.¶

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 6 October 2025.¶

Copyright Notice

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.¶

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1. Introduction

Large public key algorithms, including the code-based cryptographic algorithm family Classic McEliece (see [RJM78], [DJB25], and [OQS24] and the Random Linear Code-based Encryption (RLCE) algorithm group (see [RLCE17]), cannot be easily implemented in TLS 1.3 due to the current key share limitations of 65535 bytes. It is important to consider such uses of algorithms given that Classic McEliece is a Round 4 algorithm submitted in the NIST standardization process (see [PQC25]). Therefore, this document proposes a new key share that has a higher limit and is utilized in ClientHello and ServerHello messages, which is a modification of [RFC8446]. For example, if a large post-quantum algorithm is requested in a TLS 1.3 key exchange, this new key share extension will be constructed but the original key share extension will not be constructed. However, if a classical algorithm is requested for key exchange, a normal key share extension is constructed and this new key share extension will not be constructed. Thus enabling the use of large public key post-quantum algorithms to be used in TLS 1.3 key exchanges, and also presenting them as an alternative option to replace classical algorithms for future protection against the threat of attackers in possession of powerful quantum computers that will break classical encryption.¶

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.¶

Based on the key share extension from [RFC8446] is introduced a new key share extension in this document, "key_share_pqc". This is reflected in this document and is represented as KeyShareEntryPQC below, based off of the existing KeyShareEntry from [RFC8446]. However this is modified along with the existing KeyShareEntry structure to include case statements to test if the key exchange algorithm chosen in a TLS 1.3 connection belongs to either the Classic McEliece family or RLCE algorithm group, and if it is, then KeyShareEntryPQC is constructed and KeyShareEntry is not constructed. If the opposite is true, where the key exchange algorithm does not belong to either group, then KeyShareEntryPQC is not constructed but KeyShareEntry is constructed. Note that the "key_exchange" field is expanded in KeyShareEntryPQC to accomodate a large public key that is greater than 65535 bytes:¶


    struct {
       NamedGroup group;
       select (NameGroup.group) {
       case classicmceliece348864 | classicmceliece348864f | classicmceliece460896
       | classicmceliece460896f | classicmceliece6688128 | classicmceliece6688128f
       | classicmceliece6960119 | classicmceliece6960119f | classicmceliece8192128
       | classicmceliece8192128f
       | rlcel1 | rlcel3 | rlcel5 :
             break;
       default :
             opaque key_exchange<1..2^16-1>;
       }
    } KeyShareEntry;

    struct {
       NamedGroup group;
       select (NamedGroup.group) {
       case classicmceliece348864 | classicmceliece348864f | classicmceliece460896
       | classicmceliece460896f | classicmceliece6688128 | classicmceliece6688128f
       | classicmceliece6960119 | classicmceliece6960119f | classicmceliece8192128
       | classicmceliece8192128f
       | rlcel1 | rlcel3 | rlcel5 :
             opaque key_exchange<1..2^24-1>;
       default :
             break;
       }
    } KeyShareEntryPQC

This is then applied to the existing KeyShareClientHello structure, which originates from [RFC8446], that now contains an additional field for KeyShareEntryPQC:¶


    struct {
       KeyShareEntry client_shares<0..2^16-1>;
       KeyShareEntryPQC client_shares<0..2^24-1>;
    } KeyShareClientHello;

Since the KeyShareClientHello needs to be expanded to accomodate for the KeyShareEntryPQC struct, the same applies to the existing Extension struct, originated as well from [RFC8446] but "extension_data" is now expanded:¶


    struct {
      ExtensionType extension_type;
      opaque extension_data<0..2^24-1>;
    } Extension;

Since there is a new key share extension to accomodate keys larger than the 65535 Byte limit (KeyShareEntryPQC), this is reflected in the existing ExtensionType structure from [RFC8446] where this is the new type that holds a value of 63, "key_share_pqc":¶


    enum {
            server_name(0),                             /* RFC 6066 */
            max_fragment_length(1),                     /* RFC 6066 */
            status_request(5),                          /* RFC 6066 */
            supported_groups(10),                       /* RFC 8422, 7919 */
            signature_algorithms(13),                   /* RFC 8446 */
            use_srtp(14),                               /* RFC 5764 */
            heartbeat(15),                              /* RFC 6520 */
            application_layer_protocol_negotiation(16), /* RFC 7301 */
            signed_certificate_timestamp(18),           /* RFC 6962 */
            client_certificate_type(19),                /* RFC 7250 */
            server_certificate_type(20),                /* RFC 7250 */
            padding(21),                                /* RFC 7685 */
            pre_shared_key(41),                         /* RFC 8446 */
            early_data(42),                             /* RFC 8446 */
            supported_versions(43),                     /* RFC 8446 */
            cookie(44),                                 /* RFC 8446 */
            psk_key_exchange_modes(45),                 /* RFC 8446 */
            certificate_authorities(47),                /* RFC 8446 */
            oid_filters(48),                            /* RFC 8446 */
            post_handshake_auth(49),                    /* RFC 8446 */
            signature_algorithms_cert(50),              /* RFC 8446 */
            key_share(51),                              /* RFC 8446 */
            key_share_pqc(63),
            (65535)
        } ExtensionType;

Since the "extension_data" field will be much larger for a KeyShareClientHello that contains a large public key that is greater than the previously defined 65535 byte limit, an example being a Classic McEliece public key, the server must be able to handle this circumstance when receiving the ClientHello message. One way is to compare the value for a packet that contains extensions including a large public key from the ClientHello message to a macro constant (for example, "CLIENT_HELLO_MIN_EXT_LENGTH" as defined in this introduced TLS implementation in this paper, see [SRVR1650] and [SRVR1211]) and if this packet value is longer than this constant, the server will change the way it normally handles all of the extensions. This constant could be easily modified in the aformentioned TLS OpenSSL implementation. The process of how the server collects the extensions from a ClientHello message must also be modified, as the server must be able to process the new key share extension of Type 63 differently than the other extensions, should the server see this inside a ClientHello message. For example, see [EXT652].¶

The ServerHello message is modified as well where the KeyShareServerHello structure originates from [RFC8446]:¶


struct {
    KeyShareEntry server_share;
    KeyShareEntryPQC server_sharePQC;
} KeyShareServerHello;

This new "key_share_pqc" extension is therefore can be implemented in the full TLS handshake, where Figure 1 from [RFC8446] is modified to be the following:¶


       Client                                           Server

Key  ^ ClientHello
Exch | + key_share*
     | + key_share_pqc*
     | + signature_algorithms*
     | + psk_key_exchange_modes*
     v + pre_shared_key*       -------->
                                                  ServerHello  ^ Key
                                                 + key_share*  | Exch
                                             + key_share_pqc*  |
                                            + pre_shared_key*  v
                                        {EncryptedExtensions}  ^  Server
                                        {CertificateRequest*}  v  Params
                                               {Certificate*}  ^
                                         {CertificateVerify*}  | Auth
                                                   {Finished}  v
                               <--------  [Application Data*]
     ^ {Certificate*}
Auth | {CertificateVerify*}
     v {Finished}              -------->
       [Application Data]      <------->  [Application Data]

              +  Indicates noteworthy extensions sent in the
                 previously noted message.

              *  Indicates optional or situation-dependent
                 messages/extensions that are not always sent.

              {} Indicates messages protected using keys
                 derived from a [sender]_handshake_traffic_secret.

              [] Indicates messages protected using keys
                 derived from [sender]_application_traffic_secret_N.

Figure 1: Full TLS Handshake with "key_share_pqc" extension

4. NamedGroup Addition for Classic McEliece and RLCE

The values for Classic McEliece and RLCE algorithms are added below in the NamedGroup struct that originates from [RFC8446]:¶


    enum {

              /* Elliptic Curve Groups (ECDHE) */
              secp256r1(0x0017), secp384r1(0x0018), secp521r1(0x0019),
              x25519(0x001D), x448(0x001E),

              /* Finite Field Groups (DHE) */
              ffdhe2048(0x0100), ffdhe3072(0x0101), ffdhe4096(0x0102),
              ffdhe6144(0x0103), ffdhe8192(0x0104),

              /* Reserved Code Points */
              ffdhe_private_use(0x01FC..0x01FF),
              ecdhe_private_use(0xFE00..0xFEFF),
              (0xFFFF)

              /* Classic McEliece family */
              classicmceliece348864(0x002A), classicmceliece348864f(0x002B), classicmceliece460896(0x002C),
              classicmceliece460896f(0x002D), classicmceliece6688128(0x002E), classicmceliece6688128f(0x002F),
              classicmceliece6960119(0x0030), classicmceliece6960119f(0x0031), classicmceliece8192128(0x0032),
              classicmceliece8192128f(0x0033)

              /* RLCE algorithm group */
              rlcel1(0x0034), rlcel3(0x0035), rlcel5(0x0036)
          } NamedGroup;

5. Modification to PskKeyExchangeMode structure

There are two key establishments that are considered when examining the structure of PskKeyExchangeMode from [RFC8446]. Since there is no Diffie Hellman algorithm in use with a pre-shared key (PSK) when considering the use of a Classic McEliece algorithm for key exchange, then there must be another key exchange mode to utilize to taken into account this case. Therefore, this is reflected in the existing [RFC8446] PskKeyExchangeMode structure below where "psk_pqc_ke(2)" is added:¶


enum {
 psk_ke(0), psk_dhe_ke(1), psk_pqc_ke(2), (255)
} PskKeyExchangeMode;

When selecting a Classic McEliece algorithm and using an external PSK or a resumption PSK (using the cipher suites "TLS_AES_128_GCM_SHA256:TLS_AES_256_GCM_SHA384:TLS_CHACHA20_POLY1305_SHA256" listed from [MOZ25] for TLS 1.3 "Modern Compatibility" configuration), "02" will then be listed for the "psk_key_exchange_modes" extension along with the new "key_share_pqc" extension in the ClientHello message. At the end of this ClientHello message is printed the "00 29" extension (pre-shared key extension), where the PSK identity should be printed and is mapped to the binder that should proceed it in this pre-shared key extension. The ServerHello message will also contain the new "key_share_pqc" extension, and will as well contain the pre-shared key extension, where it should contain "00 00" at the end which represents the server selecting the PSK identity of 0 (for example: the Selected Identity of 0 shown in the pre-shared key extension in a ServerHello message in this Wireshark example: [RASHOK20]). Overall, this is a new key exchange selecting a Classic McEliece algorithm using a PSK, whether its external or resumption, and this is can be demonstrated in the TLS Implementation below.¶

For the situation where a Classic McEliece is used for key exchange and a PSK is not chosen, then the value of "02" is printed for the "psk_key_exchange_modes" extension. But when choosing a Kyber post-quantum algorithm or X25519 and PSK is not chosen, then a value of "01" will be printed in this same extension (see TLS Implementation below), just as it is shown for the "psk_key_exchange_modes" extension listing "PSK with DHE" here: [JD19].¶

As stated above, resumption PSK with a Classic McEliece algorithm chosen as a key exchange algorithm involves the use of the new "key_share_pqc" extension for both the ClientHello and ServerHello messages. Thus the Resumption and PSK Message Flow diagram, which originates from Figure 3 of [RFC8446], is derived for this situation and has been tested with the TLS Implementation mentioned in this document:¶


      Client                                 Server

Initial Handshake
      ClientHello
         key_share_pqc         --------->
                                             ServerHello
                                               key_share_pqc
                                               EncryptedExtensions
                                             Certificate
                                             CertificateVerify
                              <---------     Finished
      Finished                ---------->
                              <---------     NewSessionTicket
                              <---------     NewSessionTicket


Subsequent Handshake
       ClientHello
          key_share_pqc
          pre_shared_key       --------->
                                               ServerHello
                                                  key_share_pqc
                                                  pre_shared_key
                                               EncryptedExtensions
                              <---------       Finished
       Finished               ---------->
                              <---------       NewSessionTicket


Figure 2: A Classic McEliece algorithm used with Resumption PSK

6. Hello Retry Request using New Key Share Extension

In a Hello Retry Request scenario, the first ClientHello message will have two algorithms listed in its "supported_groups" extension, where the NID for the algorithm that is no longer recognized by the server as an acceptable algorithm (X448 for example as proven in the TLS implementation), will first be listed in this extension, followed by the NID for a Classic McEliece algorithm. In this same ClientHello message is where "02" will be listed in the "psk_key_exchange_modes" extension, and the original "key_share" extension (value 51) is also shown with its public key for the unacceptable algorithm.¶

When the server responds with the HelloRetryRequest message, the random is the same special value for SHA-256 as indicated in Section 4.1.3 of [RFC8446], and all this has the same exact fields ("legacy_version", "random", "legacy_session_id_echo", "cipher_suite", "legacy_compression_method", and "extensions") as in the ServerHello structure indicated in [RFC8446] (see section 4.1.3). The extensions field consists of the "supported_versions" extension, but also the new "key_share_pqc" extension where the server offers the client the Classic McEliece algorithm NID it shares with the client. There is no "cookie" extension present in this same HelloRetryRequest.¶

When the client sends a second ClientHello in response to the HelloRetryRequest, this will be the same message as the firstClientHello with one exception: the original "key_share" extension is replaced with the new "key_share_pqc" extension which contains the large public key of a Classic McEliece algorithm. Then ServerHello message will then respond containing the new "key_share_pqc" extension and not the original "key_share" extension.¶

Therefore, this Hello Retry Request scenario is reflected in Figure 3 below, which is a modification of Figure 2 in [RFC8446], and this can be demonstrated in the TLS Implementation mentioned in this documentation:¶


        Client                                    Server

        ClientHello
          key_share             -------->
                                                  HelloRetryRequest
                                <--------           key_share_pqc
        ClientHello
          key_share_pqc         -------->
                                                  ServerHello
                                                    key_share_pqc
                                                  EncryptedExtensions
                                                  Certificate
                                                  CertificateVerify
                                <--------         Finished
         Finished               -------->
                                <--------         NewSessionTicket
                                <--------         NewSessionTicket

Figure 3: A Classic McEliece algorithm used in a Hello Retry Request scenario.

Note: When the client processes the HelloRetryRequest message, it must mark the new "key_share_pqc" extension as an unsolicited extension, which would be an additional exception to the rule noted in [RFC8446] regarding extension responses MUST NOT be sent if the corresponding extension requests were not sent by a remote endpoint (see section 4.2 in [RFC8446].¶

The following structure would remain intact from [RFC8446], since support would already be provided for a Classic McEliece algorithm being in NamedGroup (see Section 4):¶


struct {
    NamedGroup selected_group;
} KeyShareHelloRetryRequest;

When a Hello Retry Request involves either a resumption PSK or an external PSK in use with a Classic McEliece algorithm, both the first and second ClientHello messages (the second one being sent after a HelloRetryRequest message) will contain the exact same content except the first ClientHello will have the original "key_share" extension and the second ClientHello will have the new "key_share_pqc" extension. Another exception includes different binders in both ClientHello messages' pre-shared key extensions. This pre-shared key extension appears as the last extension in both ClientHello messages as well in the ServerHello message. However, this pre-shared key extension is not present in the HelloRetryRequest message.¶

7. TLS Implementation

A TLS implementation exists that tests the use of a new key share extension for both the ClientHello and ServerHello messages that is implemented for OpenSSL, and also where the Classic McEliece algorithm family and the RLCE algorithm group can be chosen for key exchange when initiating TLS connections. It can be accessed here: [JWYW25].¶

8. Summary of Changes from RFC 8446

A new structure is introduced of KeyShareEntryPQC along with modifications of existing structures including KeyShareEntry, NamedGroup, Extension, ExtensionType, KeyShareClientHello, and KeyShareServerHello. Adding a new ExtensionType of "key_share_pqc" allows for the addition of this new structure of KeyShareEntryPQC, which is based on the existing KeyShareEntry, but "key_exchange" has been expanded and select statements are added to both structures which depend on the NamedGroup.group being called in a TLS connection for key exchange. This new KeyShareEntryPQC will now also appear in existing structures of KeyShareClientHello and KeyShareServerHello. Thus the "extension_data" is expanded in the existing Extension structure.¶

9. Security Considerations

The new "key_share_pqc" extension MUST NOT be used with 0-RTT, as this subjects the server to replay attacks of multiple large ClientHello messages (see [RFC8446] and an example of a replay attack of several ClientHello messages in [HN23]). If this extension were to be used with 0-RTT, the server may receive duplicated ClientHello messages where each of them contain a large public key of a Classic McEliece algorithm in each ClientHello's "key_share_pqc" extension, which will not only cause resource exhaustion on the server (see Section 8.2 in [RFC8446]), but memory utlization will rise quickly than noted in [MEA23] and will cause the client-hello recording defense mechanism (see Section 8.2 in [RFC8446] and [MEA23]) to be used as a Denial-of-Service attack on the server. Therefore, 0-RTT and the use of the "early_data" extension MUST NOT be used with the "key_share_pqc" extension.¶

Larger ClientHello messages can cause TLS connections to be dropped and for TLS handshakes to be broken, as evidenced by the inclusion of post-quantum cryptography in applications of Google Chrome 124 and Microsoft Edge 124, specifically the use of Kyber768 for key agreement. See [SG24]. A possible workaround includes updating web servers if receiving an error with TLS/SSL if Kyber is utlized through Chrome or Firefox. See [SK24].¶

10. IANA Considerations

The new key share proposed in this document "key_share_pqc", along with its value of 63, needs to be updated in the registry specified for TLS ExtensionType Values. See [TLSE24]. The registry for TLS Supported Groups will need to have the proper values assigned to the Classic McEliece family with the entries of 42-51 and the RLCE algorithm group with 52-54. See [TLSP25].¶

Acknowledgements

Thank you to Martin Thomson and David Schinazi, as their Internet Draft template was used to generate this document, before the authors' information was added. The authors also want to thank the contributers of the kramdown-rfc GitHub repository, as their examples helped with the format of the figures, references, and authors' information presented in this document. Thank you also to Joyce Reynolds and Robert Braden, as their Internet Draft [JR04] was helpful as a guide on how to write the citations in this document (i.e., using citation brackets with author's initials, year, etc.).¶

References

Normative References

[RFC2119]: Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997, <https://www.rfc-editor.org/rfc/rfc2119>.
[RFC8174]: Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, May 2017, <https://www.rfc-editor.org/rfc/rfc8174>.
[RFC8446]: Rescorla, E., "The Transport Layer Security (TLS) Protocol Version 1.3", 2018, <https://datatracker.ietf.org/doc/html/rfc8446>.
[TLSE24]: Internet Assigned Numbers Authority, "Transport Layer Security (TLS) Extensions", 2024, <https://www.iana.org/assignments/tls-extensiontype-values/tls-extensiontype-values.xhtml>.
[TLSP25]: Internet Assigned Numbers Authority, "Transport Layer Security (TLS) Parameters", 2025, <https://www.iana.org/assignments/tls-parameters/tls-parameters.xhtml>.