]> Cisco

ofriel@cisco.com

Hewlett-Packard Enterprise

daniel.harkins@hpe.com

This document defines a mechanism that enables a bootstrapping device to establish trust and mutually authenticate against a network. Bootstrapping devices have a public private key pair, and this mechanism enables a network server to prove to the device that it knows the public key, and the device to prove to the server that it knows the private key. The mechanism leverages existing DPP and TLS standards and can be used in an EAP exchange.

Introduction On-boarding of devices with no, or limited, user interface can be difficult. Typically, a credential is needed to access the network, and network connectivity is needed to obtain a credential. This poses a catch-22. If a device has a public / private keypair, and trust in the integrity of a device's public key can be obtained in an out-of-band fashion, a device can be authenticated and provisioned with a usable credential for network access. While this authentication can be strong, the device's authentication of the network is somewhat weaker. presents a functional security model to address this asymmetry. Device on-boarding protocols such as the Device Provisioning Profile , also referred to as Wi-Fi Easy Connect, address this use case but they have drawbacks. for instance does not support wired network access, and does not specify how the device's DPP keypair can be used in a TLS handshake. This document describes an on-boarding protocol that can be used for wired network access, which we refer to as TLS Proof of Knowledge or TLS-POK. This document does not address the problem of Wi-Fi network discovery, where a bootstrapping device detects multiple different Wi-Fi networks and needs a more robust and scalable mechanism than simple round-robin to determine the correct network to attach to. DPP addresses this issue. Thus, the intention is that DPP is the recommended mechanism for bootstrapping against Wi-Fi networks, and TLS-POK is the recommended mechanism for bootstrapping against wired networks.

Terminology 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 when, and only when, they appear in all capitals, as shown here. The following terminology is used throughout this document. 802.1X: IEEE Port-Based Network Access Control BSK: Bootstrap Key which is an elliptic curve public private key pair from a cryptosystem suitable for doing ECDSA DPP: Device Provisioning Protocol EAP: Extensible Authentication Protocol EC: Elliptic Curve ECDSA: Elliptic Curve Digital Signature Algorithm EPSK: External Pre-Shared Key EST: Enrollment over Secure Transport PSK: Pre-Shared Key TEAP: Tunnel Extensible Authentication Protocol

Bootstrapping Overview A bootstrapping device holds a public / private elliptic curve (EC) key pair which we refer to as a Bootstrap Key (BSK). The private key of the BSK is known only by the device. The public key of the BSK is known by the device, is known by the owner or holder of the device, and is provisioned on the network by the network operator. In order to establish trust and mutually authenticate, the network proves to the device that it knows the public part of the BSK, and the device proves to the network that it knows the private part of the BSK. Once this trust has been established during bootstrapping, the network can provision the device with a credential that it uses for subsequent network access. More details on the BSK are given in .

EAP Network Access Enterprise deployments typically require an /EAP-based authentication to obtain network access. Protocols like Enrollment over Secure Transport (EST) can be used to enroll devices into a Certification Authority to allow them to authenticate using 802.1X/EAP. This creates a Catch-22 where a certificate is needed for network access and network access is needed to obtain certificate. Devices whose BSK public key can been obtained in an out-of-band fashion and provisioned on the network can perform an EAP-TLS-based exchange, for instance Tunnel Extensible Authentication Protocol (TEAP) , and authenticate the TLS exchange using the bootstrapping mechanisms defined in . This network connectivity can then be used to perform an enrollment protocol (such as provided by ) to obtain a credential for subsequent network connectivity and certificate lifecycle maintenance.

Bootstrap Key The mechanism for on-boarding of devices defined in this document relies on an elliptic curve (EC) bootstrap key (BSK). This BSK MUST be from a cryptosystem suitable for doing ECDSA. A bootstrapping client device has an associated EC BSK. The BSK may be static and baked into device firmware at manufacturing time, or may be dynamic and generated at on-boarding time by the device. The BSK public key MUST be encoded as the ASN.1 SEQUENCE SubjectPublicKeyInfo from . If the BSK public key can be shared in a trustworthy manner with a TLS server, a form of "entity authentication" (the step from which all subsequent authentication proceeds) can be obtained. The exact mechanism by which the server gains knowledge of the BSK public key is out of scope of this specification, but possible mechanisms include scanning a QR code to obtain a base64 encoding of the ASN.1-formatted public key or uploading of a Bill of Materials (BOM) which includes the public key. If the QR code is physically attached to the client device, or the BOM is associated with the device, the assumption is that the public key obtained in this bootstrapping method belongs to the client. In this model, physical possession of the device implies legitimate ownership. The server may have knowledge of multiple BSK public keys corresponding to multiple devices, and existing TLS mechanisms are leveraged that enable the server to identity a specific bootstrap public key corresponding to a specific device. Using the process defined herein, the client proves to the server that it has possession of the private key of its BSK. Provided that the mechanism in which the server obtained the BSK public key is trustworthy, a commensurate amount of authenticity of the resulting connection can be obtained. The server also proves that it knows the client's BSK public key which, if the client does not gratuitously expose its public key, can be used to obtain a modicum of correctness, that the client is connecting to the correct network (see ).

Alignment with Wi-Fi Alliance Device Provisioning Profile The definition of the BSK public key aligns with that given in . This, for example, enables the QR code format as defined in to be reused for TLS-POK. Therefore, a device that supports both wired LAN and Wi-Fi LAN connections can have a single QR code printed on its label, or dynamically display a single QR code on a display, and the bootstrap key can be used for DPP if the device bootstraps against a Wi-Fi network, or TLS-POK if the device bootstraps against a wired network. Similarly, a common bootstrap public key format could be imported into a BOM into a server that handles devices connecting over both wired and Wi-Fi networks. Any bootstrapping method defined for, or used by, is compatible with TLS-POK.

Bootstrapping in TLS 1.3 Bootstrapping in TLS 1.3 leverages Certificate-Based Authentication with an External Pre-Shared Key. The External PSK (EPSK) is derived from the BSK public key as described in , and the EPSK is imported using Importing External Pre-Shared Keys (PSKs) for TLS 1.3. As the BSK public key is an ASN.1 SEQUENCE SubjectPublicKeyInfo, the client presents a raw public key certificate as specified in Using Raw Public Keys in TLS and DTLS. The TLS PSK handshake gives the client proof that the server knows the BSK public key. Certificate based authentication of the client to the server using the BSK gives the server proof that the client knows the BSK private key. This satisfies the proof of ownership requirements outlined in .

External PSK Derivation An EPSK is made up of the tuple of (Base Key, External Identity, Hash). The Base Key is the DER-encoded ASN.1 subjectPublicKeyInfo representation of the BSK public key. The External Identity is derived from the BSK public key using with the hash algorithm from the ciphersuite as follows:

, Base Key), "tls13-bspsk-identity", L) where: - epskid is the EPSK External Identity - <> is a NULL salt - Base Key is the DER-encoded ASN.1 subjectPublicKeyInfo representation of the BSK public key - L is the length of the digest of the underlying hash algorithm ]]>

The ImportedIdentity structure is defined as:

; opaque context<0..2^16-1>; uint16 target_protocol; uint16 target_kdf; } ImportedIdentity; ]]>

and is created using the following values:

The ImportedIdentity context value MUST be "tls13-bsk". This informs the server that the mechanisms specified in this document for deriving the EPSK and executing the TLS handshake MUST be used. The EPSK and ImportedIdentity are used in the TLS handshake as specified in . A performance versus storage tradeoff a server can choose is to precompute the identity of every bootstrapped key with every hash algorithm that it uses in TLS and use that to quickly lookup the bootstrap key and generate the PSK. Servers that choose not to employ this optimization will have to do a runtime check with every bootstrap key it holds against the identity the client provides.

TLS 1.3 Handshake Details The client includes the "tls_cert_with_extern_psk" extension in the ClientHello, per . The client identifies the BSK public key by inserting the serialized content of ImportedIdentity into the PskIdentity.identity in the PSK extension, per . The client MUST also include the "client_certificate_type" extension in the ClientHello and MUST specify type of RawPublicKey. Upon receipt of the ClientHello, the server looks up the client's EPSK key in its database using the mechanisms documented in . If no match is found, the server MUST terminate the TLS handshake with an alert. If the server found the matching BSK public key, it includes the "tls_cert_with_extern_psk" extension in the ServerHello message, and the corresponding EPSK identity in the "pre_shared_key" extension. When these extensions have been successfully negotiated, the TLS 1.3 key schedule MUST include both the EPSK in the Early Secret derivation and an (EC)DHE shared secret value in the Handshake Secret derivation. After successful negotiation of these extensions, the full TLS 1.3 handshake is performed with the additional caveat that the server MUST send a CertificateRequest message and client MUST authenticate with a raw public key (its BSK) per . The BSK is always an elliptic curve key pair, therefore the type of the client's Certificate MUST be ECDSA and MUST contain the client's BSK public key as a DER-encoded ASN.1 subjectPublicKeyInfo SEQUENCE. Note that the client MUST NOT share its BSK public key with the server until after the client has completed processing of the ServerHello and verified the TLS key schedule. The PSK proof has completed at this stage, and the server has proven to the client that is knows the BSK public key, and it is therefore safe for the client to send the BSK public key to the server in the Certificate message. If the PSK verification step fails when processing the ServerHello, the client terminates the TLS handshake and the BSK public key MUST NOT be shared with the server. When the server processes the client's Certificate it MUST ensure that it is identical to the BSK public key that it used to generate the EPSK and ImportedIdentity for this handshake. When clients use the form of authentication, they MAY forgo the checking of the server's certificate in the CertificateVerify and rely on the integrity of the bootstrapping method employed to distribute its key in order to validate trust in the authenticated TLS connection. The handshake is shown in Figure 1.

ServerHello + cert_with_extern_psk + client_cert_type=RawPublicKey + key_share + pre_shared_key {EncryptedExtensions} {CertificateRequest} {Certificate} {CertificateVerify} <-------- {Finished} {Certificate} {CertificateVerify} {Finished} --------> [Application Data] <-------> [Application Data] ]]>

Using TLS Bootstrapping in EAP Upon "link up", an Authenticator on an 802.1X-protected port will issue an EAP Identity request to the newly connected peer. For unprovisioned devices that desire to take advantage of TLS-POK, there is no initial realm in which to construct an NAI (see ) so the initial EAP Identity response SHOULD contain simply the name "tls-pok@eap-dpp.arpa" in order to indicate to the Authenticator that an EAP method that supports TLS-POK SHOULD be started.

<- EAP-Request/ EAP-Type=TEAP (TLS Start) EAP-Response/ EAP-Type=TEAP (TLS client_hello with tls_cert_with_extern_psk and pre_shared_key) -> . . . ]]>

Both client and server have derived the EPSK and associated ImportedIdentity from the BSK public key as described in . When the client starts the TLS exchange in the EAP transaction, it includes the ImportedIdentity structure in the pre_shared_key extension in the ClientHello. When the server received the ClientHello, it extracts the ImportedIdentity and looks up the EPSK and BSK public key. As previously mentioned in , the exact mechanism by which the server has gained knowledge of or been provisioned with the BSK public key is outside the scope of this document. The server continues with the TLS handshake and uses the EPSK to prove that it knows the BSK public key. When the client replies with its Certificate, CertificateVerify and Finished messages, the server MUST ensure that the public key in the Certificate message matches the BSK public key. Once the TLS handshake completes, the client and server have established mutual trust. The server can then proceed to provision a credential onto the client using, for example, the mechanisms outlined in . The client can then use this provisioned credential for subsequent network authentication. The BSK is only used during bootstrap, and it not used for any subsequent network access.

IANA Considerations This document registers the following arpa domain: eap-dpp.arpa

Security Considerations Bootstrap and trust establishment by the TLS server is based on proof of knowledge of the client's bootstrap public key, a non-public datum. The TLS server obtains proof that the client knows its bootstrap public key and, in addition, also possesses its corresponding private key. Trust on the part of the client is based on successful completion of the TLS 1.3 handshake using the EPSK derived from the BSK. This proves to the client that the server knows its BSK public key. In addition, the client assumes that knowledge of its BSK public key is not widely disseminated and therefore any server that proves knowledge of its BSK public key is the appropriate server from which to receive provisioning, for instance via . describes a security model for this type of "imprinting". An attack on the bootstrapping method which substitutes the public key of a corrupted device for the public key of an honest device can result in the TLS sever on-boarding and trusting the corrupted device. If an adversary has knowledge of the bootstrap public key, the adversary may be able to make the client bootstrap against the adversary's network. For example, if an adversary intercepts and scans QR labels on clients, and the adversary can force the client to connect to its server, then the adversary can complete the TLS-POK handshake with the client and the client will connect to the adversary's server. Since physical possession implies ownership, there is nothing to prevent a stolen device from being on-boarded.

In many standards track documents several words are used to signify the requirements in the specification. These words are often capitalized. This document defines these words as they should be interpreted in IETF documents. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements. RFC 2119 specifies common key words that may be used in protocol specifications. This document aims to reduce the ambiguity by clarifying that only UPPERCASE usage of the key words have the defined special meanings. This memo profiles the X.509 v3 certificate and X.509 v2 certificate revocation list (CRL) for use in the Internet. An overview of this approach and model is provided as an introduction. The X.509 v3 certificate format is described in detail, with additional information regarding the format and semantics of Internet name forms. Standard certificate extensions are described and two Internet-specific extensions are defined. A set of required certificate extensions is specified. The X.509 v2 CRL format is described in detail along with standard and Internet-specific extensions. An algorithm for X.509 certification path validation is described. An ASN.1 module and examples are provided in the appendices. [STANDARDS-TRACK] This document specifies a TLS 1.3 extension that allows a server to authenticate with a combination of a certificate and an external pre-shared key (PSK). This document describes an interface for importing external Pre-Shared Keys (PSKs) into TLS 1.3. This document specifies a new certificate type and two TLS extensions for exchanging raw public keys in Transport Layer Security (TLS) and Datagram Transport Layer Security (DTLS). The new certificate type allows raw public keys to be used for authentication. IEEE Wi-Fi Alliance This document defines the Extensible Authentication Protocol (EAP), an authentication framework which supports multiple authentication methods. EAP typically runs directly over data link layers such as Point-to-Point Protocol (PPP) or IEEE 802, without requiring IP. EAP provides its own support for duplicate elimination and retransmission, but is reliant on lower layer ordering guarantees. Fragmentation is not supported within EAP itself; however, individual EAP methods may support this. This document obsoletes RFC 2284. A summary of the changes between this document and RFC 2284 is available in Appendix A. [STANDARDS-TRACK] This document profiles certificate enrollment for clients using Certificate Management over CMS (CMC) messages over a secure transport. This profile, called Enrollment over Secure Transport (EST), describes a simple, yet functional, certificate management protocol targeting Public Key Infrastructure (PKI) clients that need to acquire client certificates and associated Certification Authority (CA) certificates. It also supports client-generated public/private key pairs as well as key pairs generated by the CA. This document defines the Tunnel Extensible Authentication Protocol (TEAP) version 1. TEAP is a tunnel-based EAP method that enables secure communication between a peer and a server by using the Transport Layer Security (TLS) protocol to establish a mutually authenticated tunnel. Within the tunnel, TLV objects are used to convey authentication-related data between the EAP peer and the EAP server. This document specifies a simple Hashed Message Authentication Code (HMAC)-based key derivation function (HKDF), which can be used as a building block in various protocols and applications. The key derivation function (KDF) is intended to support a wide range of applications and requirements, and is conservative in its use of cryptographic hash functions. This document is not an Internet Standards Track specification; it is published for informational purposes. In order to provide inter-domain authentication services, it is necessary to have a standardized method that domains can use to identify each other's users. This document defines the syntax for the Network Access Identifier (NAI), the user identifier submitted by the client prior to accessing resources. This document is a revised version of RFC 4282. It addresses issues with international character sets and makes a number of other corrections to RFC 4282.