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draft-ietf-anima-brski-ae-04.txt
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ANIMA WG D. von Oheimb, Ed.
Internet-Draft S. Fries
Intended status: Standards Track H. Brockhaus
Expires: 14 September 2023 Siemens
13 March 2023
BRSKI-AE: Alternative Enrollment Protocols in BRSKI
draft-ietf-anima-brski-ae-04
Abstract
This document defines an enhancement of Bootstrapping Remote Secure
Key Infrastructure (BRSKI, RFC 8995) that supports alternative
certificate enrollment protocols, such as CMP. This offers the
following advantages.
Using authenticated self-contained signed objects for certification
requests and responses, their origin can be authenticated
independently of message transfer. This supports end-to-end
authentication (proof of origin) also over multiple hops, as well as
asynchronous operation of certificate enrollment. This in turn
provides architectural flexibility where to ultimately authenticate
and authorize certification requests while retaining full-strength
integrity and authenticity of certification requests.
About This Document
This note is to be removed before publishing as an RFC.
Status information for this document may be found at
https://datatracker.ietf.org/doc/draft-ietf-anima-brski-ae/.
Source for this draft and an issue tracker can be found at
https://github.com/anima-wg/anima-brski-ae.
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/.
von Oheimb, et al. Expires 14 September 2023 [Page 1]
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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 14 September 2023.
Copyright Notice
Copyright (c) 2023 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents (https://trustee.ietf.org/
license-info) in effect on the date of publication of this document.
Please review these documents carefully, as they describe your rights
and restrictions with respect to this document. Code Components
extracted from this document must include Revised BSD License text as
described in Section 4.e of the Trust Legal Provisions and are
provided without warranty as described in the Revised BSD License.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Supported Scenarios . . . . . . . . . . . . . . . . . . . 4
1.2. List of Application Examples . . . . . . . . . . . . . . 5
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 5
3. Basic Requirements and Mapping to Solutions . . . . . . . . . 7
3.1. Solution Options for Proof of Possession . . . . . . . . 8
3.2. Solution Options for Proof of Identity . . . . . . . . . 8
4. Adaptations to BRSKI . . . . . . . . . . . . . . . . . . . . 10
4.1. Architecture . . . . . . . . . . . . . . . . . . . . . . 10
4.2. Message Exchange . . . . . . . . . . . . . . . . . . . . 14
4.2.1. Pledge - Registrar Discovery . . . . . . . . . . . . 14
4.2.2. Pledge - Registrar - MASA Voucher Exchange . . . . . 14
4.2.3. Pledge - Registrar - RA/CA Certificate Enrollment . . 14
4.2.4. Pledge - Registrar Enrollment Status Telemetry . . . 17
4.3. Enhancements to the Endpoint Addressing Scheme of
BRSKI . . . . . . . . . . . . . . . . . . . . . . . . . . 18
5. Instantiation to Existing Enrollment Protocols . . . . . . . 19
5.1. BRSKI-CMP: Instantiation to CMP . . . . . . . . . . . . . 19
5.2. Support of Other Enrollment Protocols . . . . . . . . . . 21
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 21
7. Security Considerations . . . . . . . . . . . . . . . . . . . 21
8. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 22
9. References . . . . . . . . . . . . . . . . . . . . . . . . . 23
9.1. Normative References . . . . . . . . . . . . . . . . . . 23
9.2. Informative References . . . . . . . . . . . . . . . . . 24
von Oheimb, et al. Expires 14 September 2023 [Page 2]
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Appendix A. Application Examples . . . . . . . . . . . . . . . . 26
A.1. Rolling Stock . . . . . . . . . . . . . . . . . . . . . . 26
A.2. Building Automation . . . . . . . . . . . . . . . . . . . 27
A.3. Substation Automation . . . . . . . . . . . . . . . . . . 27
A.4. Electric Vehicle Charging Infrastructure . . . . . . . . 28
A.5. Infrastructure Isolation Policy . . . . . . . . . . . . . 28
A.6. Sites with Insufficient Level of Operational Security . . 28
Appendix B. History of Changes TBD RFC Editor: please delete . . 29
Contributors . . . . . . . . . . . . . . . . . . . . . . . . . . 36
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 36
1. Introduction
BRSKI [RFC8995] is typically used with EST as the enrollment protocol
for device certificates employing HTTP over TLS for its message
transfer. BRSKI-AE is a variant using alternative enrollment
protocols with authenticated self-contained objects for device
certificate enrollment.
This specification carries over the main characteristics of BRSKI,
namely:
* The pledge is assumed to have got IDevID credentials during
production, with which it can authenticate itself to domain
components such as the registrar and to the MASA, the Manufacturer
Authorized Signing Authority.
* The pledge first obtains via the voucher exchange a trust anchor
for authenticating the domain registrar and other entities in the
target domain.
* The pledge then obtains for a device private key, called the
LDevID secret, a domain-specific device certificate, called the
LDevID certificate, along with its certificate chain.
The goals of BRSKI-AE are to provide an enhancement of BRSKI for
LDevID certificate enrollment using, alternatively to EST, a protocol
that
* support end-to-end authentication over multiple hops
* enable secure message exchange with any kind of transfer,
including asynchronous delivery.
Note: The BRSKI voucher exchange of the pledge with the registrar and
MASA uses authenticated self-contained objects, so the voucher
exchange already has these properties.
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The well-known URI approach of BRSKI and EST messages is extended
with an additional path element indicating the enrollment protocol
being used.
Based on the definition of the overall approach and specific
endpoints, this specification enables the registrar to offer multiple
enrollment protocols, from which pledges and their developers can
then pick the most suitable one.
Note: BRSKI (RFC 8995) specifies how to use HTTP over TLS, but
further variants are known, such as Constrained BRSKI
[I-D.ietf-anima-constrained-voucher] using CoAP over DTLS. In the
sequel, 'HTTP' and 'TLS' are just references to the most common case,
where variants such as using CoAP and/or DTLS are meant to be
subsumed - the differences are not relevant here.
1.1. Supported Scenarios
BRSKI-AE is intended to be used situations like the following.
* pledges and/or the target domain reusing an already established
certificate enrollment protocol different from EST, such as CMP
* scenarios indirectly excluding the use of EST for certificate
enrollment, such as:
- the RA not being co-located with the registrar while requiring
end-to-end authentication of requesters, which EST does not
support over multiple hops
- the RA or CA operator requiring auditable proof of origin of
CSRs, which is not possible neither with the transient source
authentication provided by TLS.
- certificate requests for types of keys that do not support
signing, such as KEM and key agreement keys, which is not
supported by EST because it uses PKCS#10 CSRs expecting proof-
of-possession via a self-signature
- pledge implementations using security libraries not providing
EST support or a TLS library that does not support providing
the so-called tls-unique value [RFC5929] needed by EST for
strong binding of the source authentication
* no full RA functionality being available on-site in the target
domain, while connectivity to an off-site PKI RA may be
intermittent or entirely offline.
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* authoritative actions of a local RA at the registrar being not
sufficient for fully and reliably authorizing pledge certification
requests, which may be due to missing data access or due to an
insufficient level of security, for instance regarding the local
storage of private keys
1.2. List of Application Examples
Bootstrapping can be handled in various ways, depending on the
application domains. The informative Appendix A provides
illustrative examples from various industrial control system
environments and operational setups. They motivate the support of
alternative enrollment protocols, based on the following examples of
operational environments:
* rolling stock
* building automation
* electrical substation automation
* electric vehicle charging infrastructures
* infrastructure isolation policy
* sites with insufficient level of operational security
2. 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 [RFC2119] [RFC8174] when, and only when, they appear in all
capitals, as shown here.
This document relies on the terminology defined in [RFC8995],
[RFC5280], and [IEEE_802.1AR-2018]. The following terms are defined
partly in addition.
asynchronous communication: time-wise interrupted delivery of
messages, here between a pledge and a registrar or PKI component
authenticated self-contained object: data structure that is
cryptographically bound to the identity of its originator by an
attached digital signature on the actual object, using a private
key of the originator such as the IDevID secret.
backend: placement of a domain component separately from the domain
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registrar; may be on-site or off-site
BRSKI-AE: BRSKI with *A*lternative *E*nrollment, a variation of
BRSKI [RFC8995] in which BRSKI-EST, the enrollment protocol
between pledge and the registrar, is replaced by enrollment
protocols that support end-to-end authentication of the pledge to
the RA, such as Lightweight CMP.
CA: Certification Authority, which is the PKI component that issues
certificates and provides certificate status information
domain: the set of all entities that have a trust anchor in common,
independent of where the entities are deployed. This term is
often used here as a shorthand for the target domain of a pledge.
domain registrar: the access point of the target domain for
onboarding new devices, the pledges. It decides whether pledges
acceptable in the domain and facilitate their communication with
their MASA and with the domain PKI.
IDevID: Initial Device IDentifier of a pledge, provided by the
manufacturer and comprising a private key and the related X.509
certificate with its chain
LDevID: Locally significant Device IDentifier of a pledge, provided
by its target domain and comprising a private key and the related
X.509 certificate with its chain
local RA (LRA): a subordinate RA that is close to entities being
enrolled and separate from a subsequent RA. In BRSKI-AE it is
needed if a backend PKI RA is used, and in this case the LRA is
co-located with the registrar.
MASA: Manufacturer Authorized Signing Authority, providing to pledges
via the registrar a voucher containing a trust anchor for the target
domain
on-site: locality of a component or service or functionality at the
site of the registrar
off-site: locality of component or service or functionality, such as
RA or CA, not at the site of the registrar. This may be a central
site or a cloud service, to which connection may be intermittent.
PKI CA: a CA in the backend of the target domain
PKI RA: an RA in the backend of the target domain
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pledge: device that is to be bootstrapped to a target domain. It
requests an LDevID using an IDevID installed by its manufacturer.
RA: Registration Authority, the PKI component to which a CA
typically delegates certificate management functions such as
authenticating pledges and performing authorization checks on
certification requests
registrar: short for domain registrar
site: the locality where an entity, such as a pledge, registrar, or
PKI component is deployed. The target domain may have multiple
sites.
synchronous communication: time-wise uninterrupted delivery of
messages, here between a pledge and a registrar or PKI component
target domain: the domain that a pledge is going to be bootstrapped
to
3. Basic Requirements and Mapping to Solutions
Based on the intended target scenarios described in Section 1.1 and
the application examples described in Appendix A, the following
requirements are derived to support authenticated self-contained
objects as containers carrying certification requests.
At least the following properties are required for a certification
request:
* Proof of possession: demonstrates access to the private key
corresponding to the public key contained in a certification
request. This is typically achieved by a self-signature using the
corresponding private key but can also be achieved indirectly, see
[RFC4210], Section 4.3.
* Proof of identity, also called proof of origin: provides data
origin authentication of the certification request. Typically
this is achieved by a signature using the pledge IDevID secret
over some data, which needs to include a sufficiently strong
identifier of the pledge, such as the device serial number
typically included in the subject of the IDevID certificate.
The rest of this section gives an non-exhaustive list of solution
examples, based on existing technology described in IETF documents:
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3.1. Solution Options for Proof of Possession
Certificate signing request (CSR) objects: CSRs are data structures
protecting only the integrity of the contained data and providing
proof of possession for a (locally generated) private key. Important
types of CSR data structures are:
* PKCS#10 [RFC2986]. This very common form of CSR is self-signed to
protect its integrity and to prove possession of the private key
that corresponds to the public key included in the request.
* CRMF [RFC4211]. This less common but more general CSR format
supports several ways of integrity protection and proof of
possession- Typically a self-signature is used generated over
(part of) the structure with the private key corresponding to the
included public key. CRMF also supports further proof-of-
possession methods for types of keys that do not have signing
capability. For details see [RFC4211], Section 4.
Note: The integrity protection of CSRs includes the public key
because it is part of the data signed by the corresponding private
key. Yet this signature does not provide data origin authentication,
i.e., proof of identity of the requester because the key pair
involved is fresh.
3.2. Solution Options for Proof of Identity
Binding a certificate signing request (CSR) to an existing
authenticated credential (the BRSKI context, the IDevID certificate)
enables proof of origin, which in turn supports an authorization
decision on the CSR.
The binding of data origin authentication to the CSR is typically
delegated to the protocol used for certificate management. This
binding may be achieved through security options in an underlying
transport protocol such as TLS if the authorization of the
certification request is (sufficiently) done at the next
communication hop. Depending on the key type, the binding can also
be done in a stronger, transport-independent way by wrapping the CSR
with a signature.
This requirement is addressed by existing enrollment protocols in
various ways, such as:
* EST [RFC7030], also its variant EST-coaps [RFC9148], utilizes
PKCS#10 to encode Certificate Signing Requests (CSRs). While such
a CSR was not designed to include a proof of origin, there is a
limited, indirect way of binding it to the source authentication
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of the underlying TLS session. This is achieved by including in
the CSR the tls-unique value [RFC5929] resulting from the TLS
handshake. As this is optionally supported by the EST
"/simpleenroll" endpoint used in BRSKI and the TLS handshake
employed in BRSKI includes certificate-based client authentication
of the pledge with its IDevID, the proof of pledge identity being
an authenticated TLS client can be bound to the CSR.
Yet this binding is only valid in the context of the TLS session
established with the registrar acting as the EST server and
typically also as an RA. So even such a cryptographic binding of
the authenticated pledge identity to the CSR is not visible nor
verifiable to authorization points outside the registrar, such as
a PKI RA in the backend. What the registrar must do is to
authenticate and pre-authorize the pledge and to indicate this to
the PKI RA by signing the forwarded certificate request with its
private key and a related certificate that has the id-kp-cmcRA
extended key usage attribute.
[RFC7030], Section 2.5 sketches wrapping PKCS#10-formatted CSRs
with a Full PKI Request message sent to the "/fullcmc" endpoint.
This would allow for source authentication at message level, such
that the registrar could forward it to external RAs in a
meaningful way. This approach is so far not sufficiently
described and likely has not been implemented.
* SCEP [RFC8894] supports using a shared secret (passphrase) or an
existing certificate to protect CSRs based on SCEP Secure Message
Objects using CMS wrapping ([RFC5652]). Note that the wrapping
using an existing IDevID in SCEP is referred to as 'renewal'.
This way SCEP does not rely on the security of the underlying
message transfer.
* CMP [RFC4210] supports using a shared secret (passphrase) or an
existing certificate, which may be an IDevID credential, to
authenticate certification requests via the PKIProtection
structure in a PKIMessage. The certification request is typically
encoded utilizing CRMF, while PKCS#10 is supported as an
alternative. Thus, CMP does not rely on the security of the
underlying message transfer.
* CMC [RFC5272] also supports utilizing a shared secret (passphrase)
or an existing certificate to protect certification requests,
which can be either in CRMF or PKCS#10 structure. The proof of
identity can be provided as part of a FullCMCRequest, based on CMS
[RFC5652] and signed with an existing IDevID secret. Thus also
CMC does not rely on the security of the underlying message
transfer.
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4. Adaptations to BRSKI
To enable using alternative certificate enrollment protocols
supporting end-to-end authentication, asynchronous enrollment, and
more general system architectures, BRSKI-AE provides some
generalizations on BRSKI [RFC8995]. This way, authenticated self-
contained objects such as those described in Section 3 above can be
used for certificate enrollment, and RA functionality can be
distributed freely in the target domain.
The enhancements needed are kept to a minimum in order to ensure
reuse of already defined architecture elements and interactions. In
general, the communication follows the BRSKI model and utilizes the
existing BRSKI architecture elements. In particular, the pledge
initiates communication with the domain registrar and interacts with
the MASA as usual for voucher request and response processing.
4.1. Architecture
The key element of BRSKI-AE is that the authorization of a
certification request MUST be performed based on an authenticated
self-contained object. The certification request is bound in a self-
contained way to a proof of origin based on the IDevID.
Consequently, the certification request may be transferred using any
mechanism or protocol. Authentication and authorization of the
certification request can be done by the domain registrar and/or by
backend domain components. As mentioned in Section 1.1, these
components may be offline or off-site. The registrar and other on-
site domain components may have no or only temporary (intermittent)
connectivity to them.
This leads to generalizations in the placement and enhancements of
the logical elements as shown in Figure 1.
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+------------------------+
+--------------Drop-Ship------------->| Vendor Service |
| +------------------------+
| | M anufacturer| |
| | A uthorized |Ownership|
| | S igning |Tracker |
| | A uthority | |
| +--------------+---------+
| ^
| |
V |
+--------+ ......................................... |
| | . . | BRSKI-
| | . +-------+ +--------------+ . | MASA
| Pledge | . | Join | | Domain |<----+
| |<------>| Proxy |<-------->| Registrar w/ | .
| | . |.......| | LRA or RA | .
| IDevID | . +-------+ +--------------+ .
| | BRSKI-AE over TLS ^ .
+--------+ using, e.g., [LwCMP] | .
. | .
...............................|.........
on-site (local) domain components |
| e.g., [LwCMP]
|
.............................................|..................
. Public-Key Infrastructure v .
. +---------+ +------------------------------------------+ .
. | |<----+ Registration Authority | .
. | PKI CA +---->| PKI RA (unless part of Domain Registrar) | .
. +---------+ +------------------------------------------+ .
................................................................
backend (central or off-site) domain components
Figure 1: Architecture Overview Using Backend PKI Components
The architecture overview in Figure 1 has the same logical elements
as BRSKI, but with more flexible placement of the authentication and
authorization checks on certification requests. Depending on the
application scenario, the registrar MAY still do all of these checks
(as is the case in BRSKI), or part of them.
The following list describes the on-site components in the target
domain of the pledge shown in Figure 1.
* Join Proxy: same functionality as described in BRSKI [RFC8995],
Section 4
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* Domain Registrar including LRA or RA functionality: in BRSKI-AE,
the domain registrar has mostly the same functionality as in
BRSKI, namely to act as the gatekeeper of the domain for
onboarding new devices and to facilitate the communication of
pledges with their MASA and the domain PKI. Yet there are some
generalizations and specific requirements:
1. The registrar MUST support at least one certificate enrollment
protocol with authenticated self-contained objects for
certification requests. To this end, the URI scheme for
addressing endpoints at the registrar is generalized (see
Section 4.3).
2. Rather than having full RA functionality, the registrar MAY
act as a local registration authority (LRA) and delegate part
of its involvement in certificate enrollment to a backend RA,
called PKI RA. In such scenarios the registrar optionally
checks certification requests it receives from pledges and
forwards them to the PKI RA. The RA performs the remaining
parts of the enrollment request validation and authorization.
On the way back, the registrar forwards responses by the PKI
to the pledge on the same channel.
Note: In order to support end-to-end authentication of the
pledge across the registrar to the PKI RA, the certification
request structure signed by the pledge needs to be retained by
the registrar, and the registrar cannot use for its
communication with the PKI a enrollment protocol different to
the one used by the pledge.
3. The use of a certificate enrollment protocol with
authenticated self-contained objects gives freedom how to
transfer enrollment messages between pledge and RA.
Regardless how this transfer is protected and how messages are
routed, also in case that the RA is not part of the registrar
it MUST be guaranteed, like in BRSKI, that the RA accepts
certification requests for LDevIDs only with the consent of
the registrar. See Section 7} for details how this can be
achieved.
Despite of the above generalizations to the enrollment phase, the
final step of BRSKI, namely the enrollment status telemetry, is kept
as it is.
The following list describes the components provided by the vendor or
manufacturer outside the target domain.
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* MASA: functionality as described in BRSKI [RFC8995]. The voucher
exchange with the MASA via the domain registrar is performed as
described in BRSKI.
Note: From the definition of the interaction with the MASA in
[RFC8995], Section 5 follows that it may be synchronous (using
voucher request with nonces) or asynchronous (using nonceless
voucher requests).
* Ownership tracker: as defined in BRSKI.
The following list describes backend target domain components, which
may be located on-site or off-site in the target domain.
* PKI RA: performs centralized certificate management functions as a
public-key infrastructure for the domain operator. As far as not
already done by the domain registrar, it performs the final
validation and authorization of certification requests.
Otherwise, the RA co-located with the domain registrar directly
connects to the PKI CA.
* PKI CA, also called domain CA: generates domain-specific
certificates according to certification requests that have been
authenticated and authorized by the registrar and/or and an extra
PKI RA.
Based on the diagram in BRSKI [RFC8995], Section 2.1 and the
architectural changes, the original protocol flow is divided into
four phases showing commonalities and differences to the original
approach as follows.
* Discovery phase: same as in BRSKI steps (1) and (2).
* Voucher exchange phase: same as in BRSKI steps (3) and (4).
* Certificate enrollment phase: the use of EST in step (5) is
changed to employing a certificate enrollment protocol that uses
an authenticated self-contained object for requesting the LDevID
certificate.
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For transporting the certificate enrollment request and response
messages, the (D)TLS channel established between pledge and
registrar is RECOMMENDED to use. To this end, the enrollment
protocol, the pledge, and the registrar need to support the usage
of the existing channel for certificate enrollment. Due to this
recommended architecture, typically the pledge does not need to
establish additional connections for certificate enrollment and
the registrar retains full control over the certificate enrollment
traffic.
* Enrollment status telemetry phase: the final exchange of BRSKI
step (5).
4.2. Message Exchange
The behavior of a pledge described in BRSKI [RFC8995], Section 2.1 is
kept, with one major exception. After finishing the Imprint step
(4), the Enroll step (5) MUST be performed with an enrollment
protocol utilizing authenticated self-contained objects, as explained
in Section 3. Section 5 discusses selected suitable enrollment
protocols and options applicable.
An abstract overview of the BRSKI-AE protocol can be found at
[BRSKI-AE-overview].
4.2.1. Pledge - Registrar Discovery
The discovery is done as specified in [RFC8995].
4.2.2. Pledge - Registrar - MASA Voucher Exchange
The voucher exchange is performed as specified in [RFC8995].
4.2.3. Pledge - Registrar - RA/CA Certificate Enrollment
This replaces the EST integration for PKI bootstrapping described in
[RFC8995], Section 5.9 (while [RFC8995], Section 5.9.4 remains as the
final phase, see below).
The certificate enrollment phase may involve transmission of several
messages. Details can depend on the application scenario, the
employed enrollment protocol, and other factors.
The only message exchange REQUIRED is for the actual certificate
request and response. Further message exchanges MAY be performed as
needed.
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Note: The message exchanges marked OPTIONAL in the below Figure 2
cover all those supported by the use of EST in BRSKI. The last
OPTIONAL one, namely certificate confirmation, is not supported by
EST, but by CMP and other enrollment protocols.
+--------+ +------------+ +------------+
| Pledge | | Domain | | Operator |
| | | Registrar | | RA/CA |
| | | (JRC) | | (PKI) |
+--------+ +------------+ +------------+
| | |
| [OPTIONAL request of CA certificates] | |
|--------- CA Certs Request (1) --------->| |
| | [OPTIONAL forwarding] |
| |---CA Certs Request -->|
| |<--CA Certs Response---|
|<-------- CA Certs Response (2) ---------| |
| | |
| [OPTIONAL request of attributes | |
| to include in Certificate Request] | |
|--------- Attribute Request (3) -------->| |
| | [OPTIONAL forwarding] |
| |--- Attribute Req. --->|
| |<-- Attribute Resp. ---|
|<-------- Attribute Response (4) --------| |
| | |
| [REQUIRED certificate request] | |
|--------- Certificate Request (5) ------>| |
| | [OPTIONAL forwarding] |
| |--- Certificate Req.-->|
| |<--Certificate Resp.---|
|<-------- Certificate Response (6) ------| |
| | |
| [OPTIONAL certificate confirmation] | |
|--------- Certificate Confirm (7) ------>| |
| | [OPTIONAL forwarding] |
| |---Certificate Conf.-->|
| |<---- PKI Confirm -----|
|<-------- PKI/Registrar Confirm (8) -----| |
Figure 2: Certificate Enrollment
Note: Connections between the registrar and the PKI components of the
operator (RA, CA, etc.) may be intermittent or off-line. Messages
should be sent as soon as sufficient transfer capacity is available.
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The label [OPTIONAL forwarding] in Figure 2 means that on receiving
from a pledge a request message of the given type, the registrar MAY
answer the request directly itself. In this case, it MUST
authenticate its responses with the same credentials as used for
authenticating itself at TLS level for the voucher exchange.
Otherwise the registrar MUST forward the request to the PKI RA and
forward any resulting response back to the pledge.
Note: The decision whether to forward a request or to answer it
directly can depend on various static and dynamic factors. They
include the application scenario, the capabilities of the registrar
and of the local RA possibly co-located with the registrar, the
enrollment protocol being used, and the specific contents of the
request.
Note: There are several options how the registrar could be able to
directly answer requests for CA certificates or for certificate
request attributes. It could cache responses obtained from the
domain PKI and later use their contents for responding to requests
asking for the same data. The contents could also be explicit
provisioned at the registrar.
Note: Certificate requests typically need to be handled by the
backend PKI, but the registrar can answer them directly with an error
response in case it determines that such a request should be
rejected, for instance because is not properly authenticated or not
authorized.
Also certificate confirmation messages will usually be forwarded to
the backend PKI, but if the registrar knows that they are not needed
or wanted there it can acknowledge such messages directly.
The following list provides an abstract description of the flow
depicted in Figure 2.
* CA Certs Request (1): The pledge optionally requests the latest
relevant CA certificates. This ensures that the pledge has the
complete set of current CA certificates beyond the pinned-domain-
cert (which is contained in the voucher and may be just the domain
registrar certificate).
* CA Certs Response (2): This MUST contain any intermediate CA
certificates that the pledge may need to validate certificates and
MAY contain the LDevID trust anchor.
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* Attribute Request (3): Typically, the automated bootstrapping
occurs without local administrative configuration of the pledge.
Nevertheless, there are cases in which the pledge may also include
additional attributes specific to the target domain into the
certification request. To get these attributes in advance, the
attribute request may be used.
For example, [RFC8994], Section 6.11.7.2 specifies how the
attribute request is used to signal to the pledge the acp-node-
name field required for enrollment into an ACP domain.
* Attribute Response (4): This MUST contain the attributes to be
included in the subsequent certification request.
* Certificate Request (5): This MUST contain the authenticated self-
contained object ensuring both proof of possession of the
corresponding private key and proof of identity of the requester.
* Certificate Response (6): This MUST contain on success the
requested certificate and MAY include further information, like
certificates of intermediate CAs and any additional trust anchors.
* Certificate Confirm (7): An optional confirmation sent after the
requested certificate has been received and validated. If sent,
it MUST contain a positive or negative confirmation by the pledge
to the PKI whether the certificate was successfully enrolled and
fits its needs.
* PKI/Registrar Confirm (8): An acknowledgment by the PKI that MUST
be sent on reception of the Cert Confirm.
The generic messages described above may be implemented using any
certificate enrollment protocol that supports authenticated self-
contained objects for the certificate request as described in
Section 3. Examples are available in Section 5.
Note that the optional certificate confirmation by the pledge to the
PKI described above is independent of the mandatory enrollment status
telemetry done between the pledge and the registrar in the final
phase of BRSKI-AE, described next.
4.2.4. Pledge - Registrar Enrollment Status Telemetry
The enrollment status telemetry is performed as specified in
[RFC8995], Section 5.9.4.
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In BRSKI this is described as part of the certificate enrollment
step, but due to the generalization on the enrollment protocol
described in this document its regarded as a separate phase here.
4.3. Enhancements to the Endpoint Addressing Scheme of BRSKI
BRSKI-AE provides generalizations to the addressing scheme defined in
BRSKI [RFC8995], Section 5 to accommodate alternative enrollment
protocols that use authenticated self-contained objects for
certification requests. As this is supported by various existing
enrollment protocols, they can be employed without modifications to
existing PKI RAs/CAs supporting the respective enrollment protocol
(see also Section 5).
The addressing scheme in BRSKI for certification requests and the
related CA certificates and CSR attributes retrieval functions uses
the definition from EST [RFC7030], here on the example of simple
enrollment: "/.well-known/est/simpleenroll". This approach is
generalized to the following notation: "/.well-known/<enrollment-
protocol>/<request>" in which <enrollment-protocol> refers to a
certificate enrollment protocol. Note that enrollment is considered
here a message sequence that contains at least a certification
request and a certification response. The following conventions are
used to provide maximal compatibility with BRSKI:
* <enrollment-protocol>: MUST reference the protocol being used.
Existing values include 'est' [RFC7030] as in BRSKI and 'cmp' as
in [I-D.ietf-lamps-lightweight-cmp-profile] and Section 5.1 below.
Values for other existing protocols such as CMC and SCEP, or for
newly defined protocols are outside the scope of this document.
For use of the <enrollment-protocol> and <request> URI components,
they would need to specified in a suitable RFC and placed into the
Well-Known URIs registry, like done for EST in [RFC7030].
* <request>: if present, this path component MUST describe,
depending on the enrollment protocol being used, the operation
requested. Enrollment protocols are expected to define their
request endpoints, as done by existing protocols (see also
Section 5).
Well-known URIs for various endpoints on the domain registrar are
already defined as part of the base BRSKI specification or indirectly
by EST. In addition, alternative enrollment endpoints MAY be
supported at the registrar.