| ANIMA WG | M. Pritikin |
| Internet-Draft | Cisco |
| Intended status: Standards Track | M. Richardson |
| Expires: December 19, 2019 | Sandelman |
| M. Behringer | |
| S. Bjarnason | |
| Arbor Networks | |
| K. Watsen | |
| Watsen Networks | |
| June 17, 2019 |
Bootstrapping Remote Secure Key Infrastructures (BRSKI)
draft-ietf-anima-bootstrapping-keyinfra-22
This document specifies automated bootstrapping of an Autonomic Control Plane. To do this a remote secure key infrastructure (BRSKI) is created using manufacturer installed X.509 certificate, in combination with a manufacturer's authorizing service, both online and offline. Bootstrapping a new device can occur using a routable address and a cloud service, or using only link-local connectivity, or on limited/disconnected networks. Support for lower security models, including devices with minimal identity, is described for legacy reasons but not encouraged. Bootstrapping is complete when the cryptographic identity of the new key infrastructure is successfully deployed to the device but the established secure connection can be used to deploy a locally issued certificate to the device as well.
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 December 19, 2019.
Copyright (c) 2019 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 Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.
BRSKI provides a solution for secure zero-touch (automated) bootstrap of new (unconfigured) devices that are called pledges in this document.
This document primarily provides for the needs of the ISP and Enterprise focused ANIMA Autonomic Control Plane (ACP). Other users of the BRSKI protocol will need to provide separate applicability statements that include privacy and security considerations appropriate to that deployment. Section Section 9 explains the details applicability for this the ACP usage.
This document describes how pledges discover (or be discovered by) an element of the network domain to which the pledge belongs to perform the bootstrap. This element (device) is called the registrar. Before any other operation, pledge and registrar need to establish mutual trust:
This document details protocols and messages to answer the above questions. It uses a TLS connection and an PKIX (X.509v3) certificate (an IEEE 802.1AR [IDevID] LDevID) of the pledge to answer points 1 and 2. It uses a new artifact called a "voucher" that the registrar receives from a "Manufacturer Authorized Signing Authority" and passes to the pledge to answer points 3 and 4.
A proxy provides very limited connectivity between the pledge and the registrar.
The syntactic details of vouchers are described in detail in [RFC8366]. This document details automated protocol mechanisms to obtain vouchers, including the definition of a 'voucher-request' message that is a minor extension to the voucher format (see Section 3) defined by [RFC8366].
BRSKI results in the pledge storing an X.509 root certificate sufficient for verifying the registrar identity. In the process a TLS connection is established that can be directly used for Enrollment over Secure Transport (EST). In effect BRSKI provides an automated mechanism for the "Bootstrap Distribution of CA Certificates" described in [RFC7030] Section 4.1.1 wherein the pledge "MUST [...] engage a human user to authorize the CA certificate using out-of-band" information". With BRSKI the pledge now can automate this process using the voucher. Integration with a complete EST enrollment is optional but trivial.
BRSKI is agile enough to support bootstrapping alternative key infrastructures, such as a symmetric key solutions, but no such system is described in this document.
To literally "pull yourself up by the bootstraps" is an impossible action. Similarly the secure establishment of a key infrastructure without external help is also an impossibility. Today it is commonly accepted that the initial connections between nodes are insecure, until key distribution is complete, or that domain-specific keying material (often pre-shared keys, including mechanisms like SIM cards) is pre-provisioned on each new device in a costly and non-scalable manner. Existing automated mechanisms are known as non-secured 'Trust on First Use' (TOFU) [RFC7435], 'resurrecting duckling' [Stajano99theresurrecting] or 'pre-staging'.
Another prior approach has been to try and minimize user actions during bootstrapping, but not eliminate all user-actions. The original EST protocol [RFC7030] does reduce user actions during bootstrap but does not provide solutions for how the following protocol steps can be made autonomic (not involving user actions):
These "touch" methods do not meet the requirements for zero-touch.
There are "call home" technologies where the pledge first establishes a connection to a well known manufacturer service using a common client-server authentication model. After mutual authentication, appropriate credentials to authenticate the target domain are transfered to the pledge. This creates serveral problems and limitations:
BRSKI addresses these issues by defining extensions to the EST protocol for the automated distribution of vouchers.
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 [RFC2119].
The following terms are defined for clarity:
This solution (BRSKI) can support large router platforms with multi-gigabit inter-connections, mounted in controlled access data centers. But this solution is not exclusive to large equipment: it is intended to scale to thousands of devices located in hostile environments, such as ISP provided CPE devices which are drop-shipped to the end user. The situation where an order is fulfilled from distributed warehouse from a common stock and shipped directly to the target location at the request of a domain owner is explicitly supported. That stock ("SKU") could be provided to a number of potential domain owners, and the eventual domain owner will not know a-priori which device will go to which location.
The bootstrapping process can take minutes to complete depending on the network infrastructure and device processing speed. The network communication itself is not optimized for speed; for privacy reasons, the discovery process allows for the pledge to avoid announcing its presence through broadcasting.
Nomadic or mobile devices often need to aquire credentials to access the network at the new location. An example of this is mobile phone roaming among network operators, or even between cell towers. This is usually called handoff. BRSKI does not provide a low-latency handoff which is usually a requirement in such situations. For these solutions BRSKI can be used to create a relationship (an LDevID) with the "home" domain owner. The resulting credentials are then used to provide credentials more appropriate for a low-latency handoff.
Questions have been posed as to whether this solution is suitable in general for Internet of Things (IoT) networks. This depends on the capabilities of the devices in question. The terminology of [RFC7228] is best used to describe the boundaries.
The solution described in this document is aimed in general at non-constrained (i.e., class 2+) devices operating on a non-Challenged network. The entire solution as described here is not intended to be useable as-is by constrained devices operating on challenged networks (such as 802.15.4 LLNs).
Specifically, there are protocol aspects described here that might result in congestion collapse or energy-exhaustion of intermediate battery powered routers in an LLN. Those types of networks SHOULD NOT use this solution. These limitations are predominately related to the large credential and key sizes required for device authentication. Defining symmetric key techniques that meet the operational requirements is out-of-scope but the underlying protocol operations (TLS handshake and signing structures) have sufficient algorithm agility to support such techniques when defined.
The imprint protocol described here could, however, be used by non-energy constrained devices joining a non-constrained network (for instance, smart light bulbs are usually mains powered, and speak 802.11). It could also be used by non-constrained devices across a non-energy constrained, but challenged network (such as 802.15.4). The certificate contents, and the process by which the four questions above are resolved do apply to constrained devices. It is simply the actual on-the-wire imprint protocol that could be inappropriate.
This document presumes that network access control has either already occurred, is not required, or is integrated by the proxy and registrar in such a way that the device itself does not need to be aware of the details. Although the use of an X.509 Initial Device Identity is consistant with IEEE 802.1AR [IDevID], and allows for alignment with 802.1X network access control methods, its use here is for pledge authentication rather than network access control. Integrating this protocol with network access control, perhaps as an Extensible Authentication Protocol (EAP) method (see [RFC3748]), is out-of-scope.
This document describes "bootstrapping" as the protocol used to obtain a local trust anchor. It is expected that this trust anchor, along with any additional configuration information subsequently installed, is persisted on the device across system restarts ("booting"). Bootstrapping occurs only infrequently such as when a device is transfered to a new owner or has been reset to factory default settings.
As a result of the protocol described herein, the bootstrapped devices have the Domain CA trust anchor in common. An end entity certificate has optionally been issued from the Domain CA. This makes it possible to securely deploy functionalities across the domain, e.g:
The major beneficiary is that it possible to use the credentials deployed by this protocol to secure the Autonomic Control Plane (ACP) ([I-D.ietf-anima-autonomic-control-plane]).
The BRSKI protocol can be used in a number of environments. Some of the options in this document is the result of requirements that are out of the ANI scope. This section defines the base requirements for ANI devices.
For devices that intend to become part of an Autonomic Network Infrastructure (ANI) ([I-D.ietf-anima-reference-model]) that includes an Autonomic Control Plane ([I-D.ietf-anima-autonomic-control-plane]), the BRSKI protocol MUST be implemented.
The pledge must perform discovery of the proxy as described in Section 4.1 using GRASP M_FLOOD announcements.
Upon successfully validating a voucher artiface, a status telemetry MUST be returned. See Section 5.7.
An ANIMA ANI pledge MUST implement the EST automation extensions described in Section 5.9. They supplement the [RFC7030] EST to better support automated devices that do not have an end user.
The ANI Join Registrar ASA MUST support all the BRSKI and above listed EST operations.
All ANI devices SHOULD support the BRSKI proxy function, using circuit proxies over the ACP. (See Section 4.3)
The logical elements of the bootstrapping framework are described in this section. Figure 1 provides a simplified overview of the components.
+------------------------+
+--------------Drop Ship--------------->| Vendor Service |
| +------------------------+
| | M anufacturer| |
| | A uthorized |Ownership|
| | S igning |Tracker |
| | A uthority | |
| +--------------+---------+
| ^
| | BRSKI-
V | MASA
+-------+ ............................................|...
| | . | .
| | . +------------+ +-----------+ | .
| | . | | | | | .
|Pledge | . | Join | | Domain <-------+ .
| | . | Proxy | | Registrar | .
| <-------->............<-------> (PKI RA) | .
| | | BRSKI-EST | | .
| | . | | +-----+-----+ .
|IDevID | . +------------+ | e.g. RFC7030 .
| | . +-----------------+----------+ .
| | . | Key Infrastructure | .
| | . | (e.g., PKI Certificate | .
+-------+ . | Authority) | .
. +----------------------------+ .
. .
................................................
"Domain" components
Figure 1
We assume a multi-vendor network. In such an environment there could be a Manufacturer Service for each manufacturer that supports devices following this document's specification, or an integrator could provide a generic service authorized by multiple manufacturers. It is unlikely that an integrator could provide Ownership Tracking services for multiple manufacturers due to the required sales channel integrations necessary to track ownership.
The domain is the managed network infrastructure with a Key Infrastructure the pledge is joining. The domain provides initial device connectivity sufficient for bootstrapping through a proxy. The domain registrar authenticates the pledge, makes authorization decisions, and distributes vouchers obtained from the Manufacturer Service. Optionally the registrar also acts as a PKI Registration Authority.
The pledge goes through a series of steps, which are outlined here at a high level.
------------
/ Factory \
\ default /
-----+------
|
+------v-------+
| (1) Discover |
+------------> |
| +------+-------+
| |
| +------v-------+
| | (2) Identity |
^------------+ |
| rejected +------+-------+
| |
| +------v-------+
| | (3) Request |
| | Join |
| +------+-------+
| |
| +------v-------+
| | (4) Imprint |
^------------+ |
| Bad MASA +------+-------+
| response | send Voucher Status Telemetry
| +------v-------+
| | (5) Enroll |<---+ (non-error HTTP codes )
^------------+ |\___/ (e.g. 201 'Retry-After')
| Enroll +------+-------+
| Failure |
| -----v------
| / Enrolled \
^------------+ |
Factory \------------/
reset
Figure 2: pledge state diagram
State descriptions for the pledge are as follows:
The pledge is now a member of, and can be managed by, the domain and will only repeat the discovery aspects of bootstrapping if it is returned to factory default settings.
This specification details integration with EST enrollment so that pledges can optionally obtain a locally issued certificate, although any REST interface could be integrated in future work.
A voucher is a cryptographically protected artifact (a digital signature) to the pledge device authorizing a zero-touch imprint on the registrar domain.
The format and cryptographic mechanism of vouchers is described in detail in [RFC8366].
Vouchers provide a flexible mechanism to secure imprinting: the pledge device only imprints when a voucher can be validated. At the lowest security levels the MASA can indiscriminately issue vouchers and log claims of ownership by domains. At the highest security levels issuance of vouchers can be integrated with complex sales channel integrations that are beyond the scope of this document. The sales channel integration would verify actual (legal) ownership of the pledge by the domain. This provides the flexibility for a number of use cases via a single common protocol mechanism on the pledge and registrar devices that are to be widely deployed in the field. The MASA services have the flexibility to leverage either the currently defined claim mechanisms or to experiment with higher or lower security levels.
Vouchers provide a signed but non-encrypted communication channel among the pledge, the MASA, and the registrar. The registrar maintains control over the transport and policy decisions allowing the local security policy of the domain network to be enforced.
Pledge authentication and pledge voucher-request signing is via a PKIX certificate installed during the manufacturing process. This is the 802.1AR Initial Device Identifier (IDevID), and it provides a basis for authenticating the pledge during the protocol exchanges described here. There is no requirement for a common root PKI hierarchy. Each device manufacturer can generate its own root certificate. Specifically, the IDevID enables:
Section 7.2.13 of [IDevID] discusses keyUsage and extendedKeyUsage extensions in the IDevID certificate. Any restrictions included reduce the utility of the IDevID and so this specification RECOMMENDS that no key usage restrictions be included. Additionally, [RFC5280] section 4.2.1.3 does not require key usage restrictions for end entity certificates.
In the context of BRSKI, pledges are uniquely identified by a "serial-number". This serial-number is used both in the "serial-number" field of voucher or voucher-requests (see Section 3) and in local policies on registrar or MASA (see Section 5).
The following fields are defined in [IDevID] and [RFC5280]:
and they are used as follows by the pledge to build the "serial-number" that is placed in the voucher-request. In order to build it, the fields need to be converted into a serial-number of "type string". The following methods are used depending on the first available IDevID certificate field (attempted in this order):
The above process to locate the serial-number MUST be performed by the pledge when filling out the voucher-request. Signed voucher-requests are always passed up to the MASA.
As explained in Section 5.5 the Registrar MUST extract the serial-number again itself from the pledge's TLS certificate. It can consult the serial-number in the pledge-request if there are any possible confusion about the source of the serial-number (hwSerialNum vs serialNumber).
This docucment defines a new PKIX non-critical certificate extension to carry the MASA URI. This extension is intended to be used in the IDevID certificate. The URI is represented as described in Section 7.4 of [RFC5280].
Any Internationalized Resource Identifiers (IRIs) MUST be mapped to URIs as specified in Section 3.1 of [RFC3987] before they are placed in the certificate extension. The IRI provides the authority information. The BRSKI "/.well-known" tree ([RFC5785]) is described in Section 5.
As explained in [RFC5280] section 7.4, a complete IRI SHOULD be in this extension, including the scheme, iauthority, and ipath. As a consideration to constrained systems, this MAY be reduced to only the iauthority, in which case a scheme of "https://" and ipath of "/.well-known/est" is to be assumed, as explained in section Section 5.
The registrary can assume that only the iauthority is present in the extension, if there are no slash ("/") characters in the extension.
Section 7.4 of [RFC5280] calls out various schemes that MUST be supported, including ldap, http and ftp. However, the registrar MUST use https for the BRSKI-MASA connection.
The new extension is identified as follows:
<CODE BEGINS>
MASAURLExtnModule-2016 { iso(1) identified-organization(3) dod(6)
internet(1) security(5) mechanisms(5) pkix(7)
id-mod(0) id-mod-MASAURLExtn2016(TBD) }
DEFINITIONS IMPLICIT TAGS ::= BEGIN
-- EXPORTS ALL --
IMPORTS
EXTENSION
FROM PKIX-CommonTypes-2009
{ iso(1) identified-organization(3) dod(6) internet(1)
security(5) mechanisms(5) pkix(7) id-mod(0)
id-mod-pkixCommon-02(57) }
id-pe
FROM PKIX1Explicit-2009
{ iso(1) identified-organization(3) dod(6) internet(1)
security(5) mechanisms(5) pkix(7) id-mod(0)
id-mod-pkix1-explicit-02(51) } ;
MASACertExtensions EXTENSION ::= { ext-MASAURL, ... }
ext-MASAURL EXTENSION ::= { SYNTAX MASAURLSyntax
IDENTIFIED BY id-pe-masa-url }
id-pe-masa-url OBJECT IDENTIFIER ::= { id-pe TBD }
MASAURLSyntax ::= IA5String
END
<CODE ENDS>
The choice of id-pe is based on guidance found in Section 4.2.2 of [RFC5280], "These extensions may be used to direct applications to on-line information about the issuer or the subject". The MASA URL is precisely that: online information about the particular subject.
A representative flow is shown in Figure 3:
+--------+ +---------+ +------------+ +------------+ | Pledge | | Circuit | | Domain | | Vendor | | | | Join | | Registrar | | Service | | | | Proxy | | (JRC) | | (MASA) | +--------+ +---------+ +------------+ +------------+ | | | Internet | [discover] | | | |<-RFC4862 IPv6 addr | | | |<-RFC3927 IPv4 addr | Appendix A | Legend | |-------------------->| | C - circuit | | optional: mDNS query| Appendix B | join proxy | | RFC6763/RFC6762 | | P - provisional | |<--------------------| | TLS connection | | GRASP M_FLOOD | | | | periodic broadcast| | | [identity] | | | |<------------------->C<----------------->| | | TLS via the Join Proxy | | |<--Registrar TLS server authentication---| | [PROVISIONAL accept of server cert] | | P---X.509 client authentication---------->| | [request join] | | P---Voucher Request(w/nonce for voucher)->| | P /------------------- | | P | [accept device?] | P | [contact Vendor] | P | |--Pledge ID-------->| P | |--Domain ID-------->| P | |--optional:nonce--->| P optional: | [extract DomainID] P can occur in advance | [update audit log] P if nonceleess | | P | |<- voucher ---------| P \------------------- | w/nonce if provided| P<------voucher---------------------------| | [imprint] | | |-------voucher status telemetry--------->| | | |<-device audit log--| | [verify audit log and voucher] | |<--------------------------------------->| | [enroll] | | | Continue with RFC7030 enrollment | | | using now bidirectionally authenticated | | | TLS session. | | [enrolled] | |
Figure 3
The pledge is the device that is attempting to join. Until the pledge completes the enrollment process, it has link-local network connectivity only to the proxy.
The join proxy provides HTTPS connectivity between the pledge and the registrar. A circuit proxy mechanism is described in Section 4. Additional mechanisms, including a CoAP mechanism and a stateless IPIP mechanism are the subject of future work.
The domain's registrar operates as the BRSKI-MASA client when requesting vouchers from the MASA (see Section 5.4). The registrar operates as the BRSKI-EST server when pledges request vouchers (see Section 5.1). The registrar operates as the BRSKI-EST server "Registration Authority" if the pledge requests an end entity certificate over the BRSKI-EST connection (see Section 5.9).
The registrar uses an Implicit Trust Anchor database for authenticating the BRSKI-MASA TLS connection MASA certificate. The registrar uses a different Implicit Trust Anchor database for authenticating the BRSKI-EST TLS connection pledge client certificate. Configuration or distribution of these trust anchor databases is out-of-scope of this specification.
The Manufacturer Service provides two logically seperate functions: the Manufacturer Authorized Signing Authority (MASA) described in Section 5.5 and Section 5.6, and an ownership tracking/auditing function described in Section 5.7 and Section 5.8.
The Public Key Infrastructure (PKI) administers certificates for the domain of concerns, providing the trust anchor(s) for it and allowing enrollment of pledges with domain certificates.
The voucher provides a method for the distribution of a single PKI trust anchor (as the "pinned-domain-cert"). A distribution of the full set of current trust anchors is possible using the optional EST integration.
The domain's registrar acts as an [RFC5272] Registration Authority, requesting certificates for pledges from the Key Infrastructure.
The expectations of the PKI are unchanged from EST [[RFC7030]]. This document does not place any additional architectural requirements on the Public Key Infrastructure.
Many devices when bootstrapping do not have knowledge of the current time. Mechanisms such as Network Time Protocols cannot be secured until bootstrapping is complete. Therefore bootstrapping is defined in a method that does not require knowledge of the current time. A pledge MAY ignore all time stamps in the voucher and in the certificate validity periods if it does not know the current time.
The pledge is exposed to dates in the following five places: registrar certificate notBefore, registrar certificiate notAfter, voucher created-on, and voucher expires-on. Additionally, CMS signatures contain a signingTime.
If the voucher contains a nonce then the pledge MUST confirm the nonce matches the original pledge voucher-request. This ensures the voucher is fresh. See Section 5.2.
[RFC5280] explains that long lived pledge certificates "SHOULD be assigned the GeneralizedTime value of 99991231235959Z". Registrars MUST support such lifetimes and SHOULD support ignoring pledge lifetimes if they did not follow the RFC5280 recommendations.
For example, IDevID may have incorrect lifetime of N <= 3 years, rendering replacement pledges from storage useless after N years unless registrars support ignoring such a lifetime.
There exist operationally open network wherein devices gain unauthenticated access to the internet at large. In these use cases the management domain for the device needs to be discovered within the larger internet. These are less likely within the anima scope but may be more important in the future.
There are additionally some greenfield situations involving an entirely new installation where a device may have some kind of management uplink that it can use (such as via 3G network for instance). In such a future situation, the device might use this management interface to learn that it should configure itself to become the local registrar.
In order to support these scenarios, the pledge MAY contact a well known URI of a cloud registrar if a local registrar cannot be discovered or if the pledge's target use cases do not include a local registrar.
If the pledge uses a well known URI for contacting a cloud registrar an Implicit Trust Anchor database (see [RFC7030]) MUST be used to authenticate service as described in [RFC6125]. This is consistent with the human user configuration of an EST server URI in [RFC7030] which also depends on RFC6125.
The registrar needs to be able to contact a MASA that is trusted by the pledge in order to obtain vouchers. There are three mechanisms described:
The device's Initial Device Identifier (IDevID) will normally contain the MASA URL as detailed in Section 2.3. This is the RECOMMENDED mechanism.
If the registrar is integrated with [I-D.ietf-opsawg-mud] and the pledge IDevID contains the id-pe-mud-url then the registrar MAY attempt to obtain the MASA URL from the MUD file. The MUD file extension for the MASA URL is defined in Appendix C.
It can be operationally difficult to ensure the necessary X.509 extensions are in the pledge's IDevID due to the difficulty of aligning current pledge manufacturing with software releases and development. As a final fallback the registrar MAY be manually configured or distributed with a MASA URL for each manufacturer. Note that the registrar can only select the configured MASA URL based on the trust anchor -- so manufacturers can only leverage this approach if they ensure a single MASA URL works for all pledge's associated with each trust anchor.
Voucher-requests are how vouchers are requested. The semantics of the vouchers are described below, in the YANG model.
A pledge forms the "pledge voucher-request" and submits it to the registrar.
The registrar in turn forms the "registrar voucher-request", and submits it to the MASA.
The "proximity-registrar-cert" leaf is used in the pledge voucher-requests. This provides a method for the pledge to assert the registrar's proximity.
The "prior-signed-voucher-request" leaf is used in registrar voucher-requests. If present, it is the signed pledge voucher-request. This provides a method for the registrar to forward the pledge's signed request to the MASA. This completes transmission of the signed "proximity-registrar-cert" leaf.
Unless otherwise signaled (outside the voucher-request artifact), the signing structure is as defined for vouchers, see [RFC8366].
A registrar MAY also retrieve nonceless vouchers by sending nonceless voucher-requests to the MASA in order to obtain vouchers for use when the registrar does not have connectivity to the MASA. No "prior-signed-voucher-request" leaf would be included. The registrar will also need to know the serial number of the pledge. This document does not provide a mechanism for the registrar to learn that in an automated fashion. Typically this will be done via scanning of bar-code or QR-code on packaging, or via some sales channel integration.
The following tree diagram illustrates a high-level view of a voucher-request document. The voucher-request builds upon the voucher artifact described in [RFC8366]. The tree diagram is described in [RFC8340]. Each node in the diagram is fully described by the YANG module in Section 3.4. Please review the YANG module for a detailed description of the voucher-request format.
module: ietf-voucher-request
grouping voucher-request-grouping
+-- voucher
+-- created-on? yang:date-and-time
+-- expires-on? yang:date-and-time
+-- assertion? enumeration
+-- serial-number string
+-- idevid-issuer? binary
+-- pinned-domain-cert? binary
+-- domain-cert-revocation-checks? boolean
+-- nonce? binary
+-- last-renewal-date? yang:date-and-time
+-- prior-signed-voucher-request? binary
+-- proximity-registrar-cert? binary
This section provides voucher-request examples for illustration purposes. For detailed examples, see Appendix D.2. These examples conform to the encoding rules defined in [RFC7951].
{
"ietf-voucher-request:voucher": {
"nonce": "62a2e7693d82fcda2624de58fb6722e5",
"created-on": "2017-01-01T00:00:00.000Z",
"proximity-registrar-cert": "base64encodedvalue=="
}
}
{
"ietf-voucher-request:voucher": {
"nonce": "62a2e7693d82fcda2624de58fb6722e5",
"created-on": "2017-01-01T00:00:02.000Z",
"idevid-issuer": "base64encodedvalue=="
"serial-number": "JADA123456789"
"prior-signed-voucher-request": "base64encodedvalue=="
}
}
{
"ietf-voucher-request:voucher": {
"created-on": "2017-01-01T00:00:02.000Z",
"idevid-issuer": "base64encodedvalue=="
"serial-number": "JADA123456789"
}
}
Following is a YANG [RFC7950] module formally extending the [RFC8366] voucher into a voucher-request.
<CODE BEGINS> file "ietf-voucher-request@2018-02-14.yang"
module ietf-voucher-request {
yang-version 1.1;
namespace
"urn:ietf:params:xml:ns:yang:ietf-voucher-request";
prefix "vch";
import ietf-restconf {
prefix rc;
description "This import statement is only present to access
the yang-data extension defined in RFC 8040.";
reference "RFC 8040: RESTCONF Protocol";
}
import ietf-voucher {
prefix v;
description "This module defines the format for a voucher,
which is produced by a pledge's manufacturer or
delegate (MASA) to securely assign a pledge to
an 'owner', so that the pledge may establish a secure
conn ection to the owner's network infrastructure";
reference "RFC YYYY: Voucher Profile for Bootstrapping Protocols";
}
organization
"IETF ANIMA Working Group";
contact
"WG Web: <http://tools.ietf.org/wg/anima/>
WG List: <mailto:anima@ietf.org>
Author: Kent Watsen
<mailto:kwatsen@juniper.net>
Author: Max Pritikin
<mailto:pritikin@cisco.com>
Author: Michael Richardson
<mailto:mcr+ietf@sandelman.ca>
Author: Toerless Eckert
<mailto:tte+ietf@cs.fau.de>";
description
"This module defines the format for a voucher request.
It is a superset of the voucher itself.
It provides content to the MASA for consideration
during a voucher request.
The key words 'MUST', 'MUST NOT', 'REQUIRED', 'SHALL', 'SHALL NOT',
'SHOULD', 'SHOULD NOT', 'RECOMMENDED', 'MAY', and 'OPTIONAL' in
the module text are to be interpreted as described in RFC 2119.
Copyright (c) 2017 IETF Trust and the persons identified as
authors of the code. All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, is permitted pursuant to, and subject to the license
terms contained in, the Simplified BSD License set forth in Section
4.c of the IETF Trust's Legal Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info).
This version of this YANG module is part of RFC XXXX; see the RFC
itself for full legal notices.";
revision "2018-02-14" {
description
"Initial version";
reference
"RFC XXXX: Voucher Profile for Bootstrapping Protocols";
}
// Top-level statement
rc:yang-data voucher-request-artifact {
uses voucher-request-grouping;
}
// Grouping defined for future usage
grouping voucher-request-grouping {
description
"Grouping to allow reuse/extensions in future work.";
uses v:voucher-artifact-grouping {
refine "voucher/created-on" {
mandatory false;
}
refine "voucher/pinned-domain-cert" {
mandatory false;
}
refine "voucher/domain-cert-revocation-checks" {
description "The domain-cert-revocation-checks field
is not valid in a voucher request, and
any occurance MUST be ignored";
}
refine "voucher/assertion" {
mandatory false;
description "Any assertion included in voucher
requests SHOULD be ignored by the MASA.";
}
augment "voucher" {
description
"Adds leaf nodes appropriate for requesting vouchers.";
leaf prior-signed-voucher-request {
type binary;
description
"If it is necessary to change a voucher, or re-sign and
forward a voucher that was previously provided along a
protocol path, then the previously signed voucher SHOULD be
included in this field.
For example, a pledge might sign a voucher request
with a proximity-registrar-cert, and the registrar
then includes it in the prior-signed-voucher-request field.
This is a simple mechanism for a chain of trusted
parties to change a voucher request, while
maintaining the prior signature information.
The Registrar and MASA MAY examine the prior signed
voucher information for the
purposes of policy decisions. For example this information
could be useful to a MASA to determine that both pledge and
registrar agree on proximity assertions. The MASA SHOULD
remove all prior-signed-voucher-request information when
signing a voucher for imprinting so as to minimize the
final voucher size.";
}
leaf proximity-registrar-cert {
type binary;
description
"An X.509 v3 certificate structure as specified by RFC 5280,
Section 4 encoded using the ASN.1 distinguished encoding
rules (DER), as specified in ITU-T X.690.
The first certificate in the Registrar TLS server
certificate_list sequence (see [RFC5246]) presented by
the Registrar to the Pledge. This MUST be populated in a
Pledge's voucher request if a proximity assertion is
requested.";
}
}
}
}
}
<CODE ENDS>
The role of the proxy is to facilitate communications. The proxy forwards packets between the pledge and a registrar that has been provisioned to the proxy via GRASP discovery.
This section defines a stateful proxy mechanism which is refered to as a "circuit" proxy.
The proxy does not terminate the TLS handshake: it passes streams of bytes onward without examination. A proxy MUST NOT assume any specific TLS version.
A Registrar can directly provide the proxy announcements described below, in which case the announced port can point directly to the Registrar itself. In this scenario the pledge is unaware that there is no proxing occuring. This is useful for Registrars servicing pledges on directly connected networks.
As a result of the proxy Discovery process in Section 4.1.1, the port number exposed by the proxy does not need to be well known, or require an IANA allocation.
During the discovery of the Registrar by the Join Proxy, the Join Proxy will also learn which kinds of proxy mechanisms are available. This will allow the Join Proxy to use the lowest impact mechanism which the Join Proxy and Registrar have in common.
In order to permit the proxy functionality to be implemented on the maximum variety of devices the chosen mechanism SHOULD use the minimum amount of state on the proxy device. While many devices in the ANIMA target space will be rather large routers, the proxy function is likely to be implemented in the control plane CPU of such a device, with available capabilities for the proxy function similar to many class 2 IoT devices.
The document [I-D.richardson-anima-state-for-joinrouter] provides a more extensive analysis and background of the alternative proxy methods.
The result of discovery is a logical communication with a registrar, through a proxy. The proxy is transparent to the pledge. The communication between the pledge is over IPv6 Link-Local addresses.
To discover the proxy the pledge performs the following actions:
Once a proxy is discovered the pledge communicates with a registrar through the proxy using the bootstrapping protocol defined in
While the GRASP M_FLOOD mechanism is passive for the pledge, the optional other methods (mDNS, and IPv4 methods) are active. The pledge SHOULD run those methods in parallel with listening to for the M_FLOOD. The active methods SHOULD exponentially back-off to a maximum of one hour to avoid overloading the network with discovery attempts. Detection of change of physical link status (ethernet carrier for instance) SHOULD reset the exponential back off.
The pledge could discover more than one proxy on a given physical interface. The pledge can have a multitude of physical interfaces as well: a layer-2/3 ethernet switch may have hundreds of physical ports.
Each possible proxy offer SHOULD be attempted up to the point where a voucher is received: while there are many ways in which the attempt may fail, it does not succeed until the voucher has been validated.
The connection attempts via a single proxy SHOULD exponentially back-off to a maximum of one hour to avoid overloading the network infrastructure. The back-off timer for each MUST be independent of other connection attempts.
Connection attempts SHOULD be run in parallel to avoid head of queue problems wherein an attacker running a fake proxy or registrar could perform protocol actions intentionally slowly. The pledge SHOULD continue to listen to for additional GRASP M_FLOOD messages during the connection attempts.
Once a connection to a registrar is established (e.g. establishment of a TLS session key) there are expectations of more timely responses, see Section 5.2.
Once all discovered services are attempted (assuming that none succeeded) the device MUST return to listening for GRASP M_FLOOD. It SHOULD periodically retry the manufacturer specific mechanisms. The pledge MAY prioritize selection order as appropriate for the anticipated environment.
[M_FLOOD, 12340815, h'fe800000000000000000000000000001', 180000,
["AN_Proxy", 4, 1, ""],
[O_IPv6_LOCATOR,
h'fe800000000000000000000000000001', IPPROTO_TCP, 4443]]
A proxy uses the DULL GRASP M_FLOOD mechanism to announce itself. This announcement can be within the same message as the ACP announcement detailed in [I-D.ietf-anima-autonomic-control-plane]. The M_FLOOD is formatted as follows:
Figure 6b: Proxy Discovery
flood-message = [M_FLOOD, session-id, initiator, ttl,
+[objective, (locator-option / [])]]
objective = ["AN_Proxy", objective-flags, loop-count,
objective-value]
ttl = 180000 ; 180,000 ms (3 minutes)
initiator = ACP address to contact Registrar
objective-flags = sync-only ; as in GRASP spec
sync-only = 4 ; M_FLOOD only requires synchronization
loop-count = 1 ; one hop only
objective-value = any ; none
locator-option = [ O_IPv6_LOCATOR, ipv6-address,
transport-proto, port-number ]
ipv6-address = the v6 LL of the Proxy
$transport-proto /= IPPROTO_TCP ; note this can be any value from the
; IANA protocol registry, as per
; [GRASP] section 2.9.5.1, note 3.
port-number = selected by Proxy
The formal CDDL [I-D.ietf-cbor-cddl] definition is:
Figure 6c: AN_Proxy CDDL
On a small network the Registrar MAY include the GRASP M_FLOOD announcements to locally connected networks.
The $transport-proto above indicates the method that the pledge-proxy-registrar will use. The TCP method described here is mandatory, and other proxy methods, such as CoAP methods not defined in this document are optional. Other methods MUST NOT be enabled unless the Join Registrar ASA indicates support for them in it's own announcement.
The use of CoAP to connect from pledge to registrar is out of scope for this document, and is described in future work. See [I-D.ietf-anima-constrained-voucher].
The registrar SHOULD announce itself so that proxies can find it and determine what kind of connections can be terminated.
The registrar announces itself using ACP instance of GRASP using M_FLOOD messages. ANI proxies MUST support GRASP discovery of registrars.
[M_FLOOD, 12340815, h'fda379a6f6ee00000200000064000001', 180000,
["AN_join_registrar", 4, 255, "EST-TLS"],
[O_IPv6_LOCATOR,
h'fda379a6f6ee00000200000064000001', IPPROTO_TCP, 80]]
The M_FLOOD is formatted as follows:
Figure 7a: Registrar Discovery
flood-message = [M_FLOOD, session-id, initiator, ttl,
+[objective, (locator-option / [])]]
objective = ["AN_join_registrar", objective-flags, loop-count,
objective-value]
initiator = ACP address to contact Registrar
objective-flags = sync-only ; as in GRASP spec
sync-only = 4 ; M_FLOOD only requires synchronization
loop-count = 255 ; mandatory maximum
objective-value = text ; name of the (list of) of supported
; protocols: "EST-TLS" for RFC7030.
The formal CDDL definition is:
Figure 7: AN_join_registrar CDDL
The M_FLOOD message MUST be sent periodically. The period is subject to network administrator policy (EST server configuration). It must be sufficiently low that the aggregate amount of periodic M_FLOODs from all EST servers causes negligible traffic across the ACP.
locator1 = [O_IPv6_LOCATOR, fd45:1345::6789, 6, 443] locator2 = [O_IPv6_LOCATOR, fd45:1345::6789, 17, 5683] locator3 = [O_IPv6_LOCATOR, fe80::1234, 41, nil]
Here are some examples of locators for illustrative purposes. Only the first one ($transport-protocol = 6, TCP) is defined in this document and is mandatory to implement.
A protocol of 6 indicates that TCP proxying on the indicated port is desired.
Registrars MUST announce the set of protocols that they support. They MUST support TCP traffic.
Registrars MUST accept HTTPS/EST traffic on the TCP ports indicated.
Registrars MUST support ANI TLS circuit proxy and therefore BRSKI across HTTPS/TLS native across the ACP.
In the ANI, the Autonomic Control Plane (ACP) secured instance of GRASP ([I-D.ietf-anima-grasp]) MUST be used for discovery of ANI registrar ACP addresses and ports by ANI proxies. The TCP leg of the proxy connection between ANI proxy and ANI registrar therefore also runs across the ACP.
The pledge MUST initiate BRSKI after boot if it is unconfigured. The pledge MUST NOT automatically initiate BRSKI if it has been configured or is in the process of being configured.
BRSKI is described as extensions to EST [RFC7030]. The goal of these extensions is to reduce the number of TLS connections and crypto operations required on the pledge. The registrar implements the BRSKI REST interface within the same "/.well-known" URI tree as the existing EST URIs as described in EST [RFC7030] section 3.2.2. The communication channel between the pledge and the registrar is referred to as "BRSKI-EST" (see Figure 1).
The communication channel between the registrar and MASA is similarly described as extensions to EST within the same "/.well-known" tree. For clarity this channel is referred to as "BRSKI-MASA". (See Figure 1).
MASA URI is "https://" iauthority "/.well-known/est".
BRSKI uses existing CMS message formats for existing EST operations. BRSKI uses JSON [RFC7159] for all new operations defined here, and voucher formats.
While EST section 3.2 does not insist upon use of HTTP 1.1 persistent connections, BRSKI-EST connections SHOULD use persistent connections. The intention of this guidance is to ensure the provisional TLS state occurs only once, and that the subsequent resolution of the provision state is not subject to a MITM attack during a critical phase.
Summarized automation extensions for the BRSKI-EST flow are:
The BRSKI-EST TLS connection can now be used for EST enrollment.
The extensions for a registrar (equivalent to EST server) are:
The pledge establishes the TLS connection with the registrar through the circuit proxy (see Section 4) but the TLS handshake is with the registrar. The BRSKI-EST pledge is the TLS client and the BRSKI-EST registrar is the TLS server. All security associations established are between the pledge and the registrar regardless of proxy operations.
Establishment of the BRSKI-EST TLS connection is as specified in EST [RFC7030] section 4.1.1 "Bootstrap Distribution of CA Certificates" [RFC7030] wherein the client is authenticated with the IDevID certificate, and the EST server (the registrar) is provisionally authenticated with an unverified server certificate.
The pledge maintains a security paranoia concerning the provisional state, and all data received, until a voucher is received and verified as specified in Section 5.6.1
A Pledge that can connect to multiple registries concurrently, SHOULD do so. Some devices may be unable to do so for lack of threading, or resource issues. Concurrent connections defeat atttempts by a malicious proxy from causing a TCP Slowloris-like attack (see [slowloris]).
A pledge that can not maintain as many connections as there are eligible proxies. If no connection is making process after 5 seconds then the pledge SHOULD drop the oldest connection and go on to a different proxy: the proxy that has been communicated with least recently. If there were no other proxies discovered, the pledge MAY continue to wait, as long as it is concurrently listening for new proxy announcements.
When the pledge bootstraps it makes a request for a voucher from a registrar.
This is done with an HTTPS POST using the operation path value of "/.well-known/est/requestvoucher".
The pledge voucher-request Content-Type is:
Registrar impementations SHOULD anticipate future media types but of course will simply fail the request if those types are not yet known.
The pledge SHOULD include an [RFC7231] section 5.3.2 "Accept" header indicating the acceptable media type for the voucher response. The "application/voucher-cms+json" media type is defined in [RFC8366] but constrained voucher formats are expected in the future. Registrar's and MASA's are expected to be flexible in what they accept.
The pledge populates the voucher-request fields as follows:
All other fields MAY be omitted in the pledge voucher-request.
An example JSON payload of a pledge voucher-request is in Section 3.3 Example 1.
The registrar validates the client identity as described in EST [RFC7030] section 3.3.2. The registrar confirms that the 'proximity' assertion and associated 'proximity-registrar-cert' are correct.
In a fully automated network all devices must be securely identified and authorized to join the domain.
A Registrar accepts or declines a request to join the domain, based on the authenticated identity presented. Automated acceptance criteria include:
If these validations fail the registrar SHOULD respond with an appropriate HTTP error code.
If authorization is successful the registrar obtains a voucher from the MASA service (see Section 5.5) and returns that MASA signed voucher to the pledge as described in Section 5.6.
The BRSKI-MASA TLS connection is a 'normal' TLS connection appropriate for HTTPS REST interfaces. The registrar initiates the connection and uses the MASA URL obtained as described in Section 2.8 for [RFC6125] authentication of the MASA.
The primary method of registrar "authentication" by the MASA is detailed in Section 5.5. As detailed in Section 11 the MASA might find it necessary to request additional registrar authentication.
The MASA and the registrars SHOULD be prepared to support TLS client certificate authentication and/or HTTP Basic or Digest authentication as described in [RFC7030] for EST clients. This connection MAY also have no client authentication at all (Section 7.4)
The authentication of the BRSKI-MASA connection does not affect the voucher-request process, as voucher-requests are already signed by the registrar. Instead, this authentication provides access control to the audit log.
Implementors are advised that contacting the MASA is to establish a secured REST connection with a web service and that there are a number of authentication models being explored within the industry. Registrars are RECOMMENDED to fail gracefully and generate useful administrative notifications or logs in the advent of unexpected HTTP 401 (Unauthorized) responses from the MASA.
When a registrar receives a pledge voucher-request it in turn submits a registrar voucher-request to the MASA service via an HTTPS RESTful interface ([RFC7231]).
This is done with an HTTP POST using the operation path value of "/.well-known/est/requestvoucher".
The voucher media type "application/voucher-cms+json" is defined in [RFC8366] and is also used for the registrar voucher-request. It is a JSON document that has been signed using a CMS structure. The registrar MUST sign the registrar voucher-request. The entire registrar certificate chain, up to and including the Domain CA, MUST be included in the CMS structure.
MASA impementations SHOULD anticipate future media types but of course will simply fail the request if those types are not yet known.
The Registrar SHOULD include an [RFC7231] section 5.3.2 "Accept" header indicating the response media types that are acceptable. This list SHOULD be the entire list presented to the Registrar in the Pledge's original request (see Section 5.2) but MAY be a subset. MASA's are expected to be flexible in what they accept.
The registrar populates the voucher-request fields as follows:
A nonceless registrar voucher-request MAY be submitted to the MASA. Doing so allows the registrar to request a voucher when the pledge is offline, or when the registrar anticipates not being able to connect to the MASA while the pledge is being deployed. Some use cases require the registrar to learn the appropriate IDevID SerialNumber field and appropriate 'Accept header' field values from the physical device labeling or from the sales channel (out-of-scope for this document).
All other fields MAY be omitted in the registrar voucher-request.
Example JSON payloads of registrar voucher-requests are in Section 3.3 Examples 2 through 4.
The MASA verifies that the registrar voucher-request is internally consistent but does not necessarily authenticate the registrar certificate since the registrar is not known to the MASA in advance. The MASA performs the actions and validation checks described in the following sub-sections before issuing a voucher.
As described in [RFC8366] vouchers are normally short lived to avoid revocation issues. If the request is for a previous (expired) voucher using the same registrar then the request for a renewed voucher SHOULD be automatically authorized. The MASA has sufficient information to determine this by examining the request, the registrar authentication, and the existing audit log. The issuance of a renewed voucher is logged as detailed in Section 5.6.
To inform the MASA that existing vouchers are not to be renewed one can update or revoke the registrar credentials used to authorize the request (see Section 5.5.3 and Section 5.5.4). More flexible methods will likely involve sales channel integration and authorizations (details are out-of-scope of this document).
The MASA MUST verify that the registrar voucher-request is signed by a registrar. This is confirmed by verifying that the id-kp-cmcRA extended key usage extension field (as detailed in EST RFC7030 section 3.6.1) exists in the certificate of the entity that signed the registrar voucher-request. This verification is only a consistency check that the unauthenticated domain CA intended the voucher-request signer to be a registrar. Performing this check provides value to the domain PKI by assuring the domain administrator that the MASA service will only respect claims from authorized Registration Authorities of the domain.
The MASA verifies that the domain CA certificate is included in the CMS structure as detailed in Section 5.5.
If a nonceless voucher-request is submitted the MASA MUST authenticate the registrar as described in either EST [RFC7030] section 3.2, section 3.3, or by validating the registrar's certificate used to sign the registrar voucher-request. Any of these methods reduce the risk of DDoS attacks and provide an authenticated identity as an input to sales channel integration and authorizations (details are out-of-scope of this document).
In the nonced case, validation of the registrar MAY be omitted if the device policy is to accept audit-only vouchers.
As noted in Section 5.5.3 the MASA performs registrar authentication in a subset of situations (e.g. nonceless voucher requests). Normal PKIX revocation checking is assumed during either EST client authentication or voucher-request signature validation. Similarly, as noted in Section 5.5.2, the MASA performs normal PKIX revocation checking during signature consistency checks (a signature by a registrar certificate that has been revoked is an inconsistency).
The MASA MAY verify that the registrar voucher-request includes the 'prior-signed-voucher-request' field. If so the prior-signed-voucher-request MUST include a 'proximity-registrar-cert' that is consistent with the certificate used to sign the registrar voucher-request. Additionally the voucher-request serial-number leaf MUST match the pledge serial-number that the MASA extracts from the signing certificate of the prior-signed-voucher-request. The MASA is aware of which pledges support signing of their voucher requests and can use this information to confirm proximity of the pledge with the registrar, thus ensuring that the BRSKI-EST TLS connection has no man-in-the-middle.
If these checks succeed the MASA updates the voucher and audit log assertion leafs with the "proximity" assertion.
The registrar's certificate chain is extracted from the signature method. The chain includes the domain CA certificate as specified in Section 5.5. This certificate is used to populate the "pinned-domain-cert" of the voucher being issued. The domainID (e.g., hash of the root public key) is determined from the pinned-domain-cert and is used to update the audit log.
The MASA does not verify the nonce itself. If the registrar voucher-request contains a nonce, and the prior-signed-voucher-request is exist, then the MASA MUST verify that the nonce is consistent. (Recall from above that the voucher-request might not contain a nonce, see Section 5.5 and Section 5.5.3).
The MASA MUST use the nonce from the registrar voucher-request for the resulting voucher and audit log. The prior-signed-voucher-request nonce is ignored during this operation.
The MASA voucher response to the registrar is forwarded without changes to the pledge; therefore this section applies to both the MASA and the registrar. The HTTP signaling described applies to both the MASA and registrar responses. A registrar either caches prior MASA responses or dynamically requests a new voucher based on local policy (it does not generate or sign a voucher). Registrar evaluation of the voucher itself is purely for transparency and audit purposes to further inform log verification (see Section 5.8.2) and therefore a registrar could accept future voucher formats that are opaque to the registrar.
If the voucher-request is successful, the server (MASA responding to registrar or registrar responding to pledge) response MUST contain an HTTP 200 response code. The server MUST answer with a suitable 4xx or 5xx HTTP [RFC2616] error code when a problem occurs. In this case, the response data from the MASA MUST be a plaintext human-readable (ASCII, English) error message containing explanatory information describing why the request was rejected.
The registrar MAY respond with an HTTP 202 ("the request has been accepted for processing, but the processing has not been completed") as described in EST [RFC7030] section 4.2.3 wherein the client "MUST wait at least the specified 'Retry-After' time before repeating the same request". (see [RFC7231] section 6.6.4) The pledge is RECOMMENDED to provide local feedback (blinked LED etc) during this wait cycle if mechanisms for this are available. To prevent an attacker registrar from significantly delaying bootstrapping the pledge MUST limit the 'Retry-After' time to 60 seconds. Ideally the pledge would keep track of the appropriate Retry-After header values for any number of outstanding registrars but this would involve a state table on the pledge. Instead the pledge MAY ignore the exact Retry-After value in favor of a single hard coded value (a registrar that is unable to complete the transaction after the first 60 seconds has another chance a minute later). A pledge SHOULD only maintain a 202 retry-state for up to 4 days, which is longer than a long weekend, after which time the enrollment attempt fails and the pledge returns to discovery state.
In order to avoid infinite redirect loops, which a malicious registrar might do in order to keep the pledge from discovering the correct registrar, the pledge MUST NOT follow more than one redirection (3xx code) to another web origins. EST supports redirection but requires user input; this change allows the pledge to follow a single redirection without a user interaction.
A 403 (Forbidden) response is appropriate if the voucher-request is not signed correctly, stale, or if the pledge has another outstanding voucher that cannot be overridden.
A 404 (Not Found) response is appropriate when the request is for a device that is not known to the MASA.
A 406 (Not Acceptable) response is appropriate if a voucher of the desired type or using the desired algorithms (as indicated by the Accept: headers, and algorithms used in the signature) cannot be issued such as because the MASA knows the pledge cannot process that type. The registrar SHOULD use this response if it determines the pledge is unacceptable due to inventory control, MASA audit logs, or any other reason.
A 415 (Unsupported Media Type) response is approriate for a request that has a voucher-request or accept encoding that is not understood.
The voucher response format is as indicated in the submitted accept header or based on the MASA's prior understanding of proper format for this Pledge. Only the [RFC8366] "application/voucher-cms+json" media type is defined at this time. The syntactic details of vouchers are described in detail in [RFC8366]. For example, the voucher consists of:
{
"ietf-voucher:voucher": {
"nonce": "62a2e7693d82fcda2624de58fb6722e5",
"assertion": "logging"
"pinned-domain-cert": "base64encodedvalue=="
"serial-number": "JADA123456789"
}
}
The MASA populates the voucher fields as follows:
Whenever a voucher is issued the MASA MUST update the audit log appropriately. The internal state requirements to maintain the audit log are out-of-scope. See Section 5.8.1 for a discussion of reporting the log to a registrar.
The pledge MUST verify the voucher signature using the manufacturer installed trust anchor(s) associated with the manufacturer's MASA (this is likely included in the pledge's firmware). Management of the manufacter installed trust anchor(s) is out-of-scope of this document; this protocol does not update these trust anchor(s).
The pledge MUST verify the serial-number field of the signed voucher matches the pledge's own serial-number.
The pledge MUST verify that the voucher nonce field is accurate and matches the nonce the pledge submitted to this registrar, or that the voucher is nonceless (see Section 7.2).
The pledge MUST be prepared to parse and fail gracefully from a voucher response that does not contain a 'pinned-domain-cert' field. The pledge MUST be prepared to ignore additional fields that it does not recognize.
The 'pinned-domain-cert' element of the voucher contains the domain CA's public key. The pledge MUST use the 'pinned-domain-cert' trust anchor to immediately complete authentication of the provisional TLS connection.
If a registrar's credentials cannot be verified using the pinned-domain-cert trust anchor from the voucher then the TLS connection is immediately discarded and the pledge abandons attempts to bootstrap with this discovered registrar. The pledge SHOULD send voucher status telemetry (described below) before closing the TLS connection. The pledge MUST attempt to enroll using any other proxies it has found. It SHOULD return to the same proxy again after attempting with other proxies. Attempts should be attempted in the exponential backoff described earlier. Attempts SHOULD be repeated as failure may be the result of a temporary inconsistently (an inconsistently rolled registrar key, or some other mis-configuration). The inconsistently could also be the result an active MITM attack on the EST connection.
The registrar MUST use a certificate that chains to the pinned-domain-cert as its TLS server certificate.
The pledge's PKIX path validation of a registrar certificate's validity period information is as described in Section 2.6.1. Once the PKIX path validation is successful the TLS connection is no longer provisional.
The pinned-domain-cert MAY be installed as an trust anchor for future operations such as enrollment (e.g. [RFC7030] as recommended) or trust anchor management or raw protocols that do not need full PKI based key management. It can be used to authenticate any dynamically discovered EST server that contain the id-kp-cmcRA extended key usage extension as detailed in EST RFC7030 section 3.6.1; but to reduce system complexity the pledge SHOULD avoid additional discovery operations. Instead the pledge SHOULD communicate directly with the registrar as the EST server. The 'pinned-domain-cert' is not a complete distribution of the [RFC7030] section 4.1.3 CA Certificate Response, which is an additional justification for the recommendation to proceed with EST key management operations. Once a full CA Certificate Response is obtained it is more authoritative for the domain than the limited 'pinned-domain-cert' response.
The domain is expected to provide indications to the system administrators concerning device lifecycle status. To facilitate this it needs telemetry information concerning the device's status.
To indicate pledge status regarding the voucher, the pledge MUST post a status message.
The posted data media type: application/json
The client HTTP POSTs the following to the server at the EST well known URI "/voucher_status". The Status field indicates if the voucher was acceptable. If it was not acceptable the Reason string indicates why. In the failure case this message may be sent to an unauthenticated, potentially malicious registrar and therefore the Reason string SHOULD NOT provide information beneficial to an attacker. The operational benefit of this telemetry information is balanced against the operational costs of not recording that an voucher was ignored by a client the registrar expected to continue joining the domain.
{
"version":"1",
"Status":FALSE /* TRUE=Success, FALSE=Fail"
"Reason":"Informative human readable message"
"reason-context": { additional JSON }
}
The reason-context attribute is an arbitrary JSON object (literal value or hash of values) which provides additional information specific to this pledge. The contents of this field are not subject to standardization.
Additional standard JSON fields in this POST MAY be added, see Section 8.3.
After receiving the pledge status telemetry Section 5.7, the registrar SHOULD request the MASA audit log from the MASA service.
This is done with an HTTP GET using the operation path value of "/.well-known/est/requestauditlog".
The registrar SHOULD HTTP POST the same registrar voucher-request as it did when requesting a voucher (using the same Content-Type). It is posted to the /requestauditlog URI instead. The "idevid-issuer" and "serial-number" informs the MASA which log is requested so the appropriate log can be prepared for the response. Using the same media type and message minimizes cryptographic and message operations although it results in additional network traffic. The relying MASA implementation MAY leverage internal state to associate this request with the original, and by now already validated, voucher-request so as to avoid an extra crypto validation.
A registrar MAY request logs at future times. If the registrar generates a new request then the MASA is forced to perform the additional cryptographic operations to verify the new request.
A MASA that receives a request for a device that does not exist, or for which the requesting owner was never an owner returns an HTTP 404 ("Not found") code.
Rather than returning the audit log as a response to the POST (with a return code 200), the MASA MAY instead return a 201 ("Created") RESTful response ([RFC7231] section 7.1) containing a URL to the prepared (and easily cachable) audit response.
In order to avoid enumeration of device audit logs, MASA that return URLs SHOULD take care to make the returned URL unguessable. For instance, rather than returning URLs containing a database number such as https://example.com/auditlog/1234 or the EUI of the device such https://example.com/auditlog/10-00-00-11-22-33, the MASA SHOULD return a randomly generated value (a "slug" in web parlance). The value is used to find the relevant database entry.
A MASA that returns a code 200 MAY also include a Location: header for future reference by the registrar.
A log data file is returned consisting of all log entries associated with the the device selected by the IDevID presented in the request. The audit log may be truncated of old or repeated values as explained below. The returned data is in JSON format ([RFC7951]), and the Content-Type SHOULD be "application/json". For example:
{
"version":"1",
"events":[
{
"date":"<date/time of the entry>",
"domainID":"<domainID extracted from voucher-request>",
"nonce":"<any nonce if supplied (or the exact string 'NULL')>"
"assertion":"<the value from the voucher assertion leaf>"
"truncated":"<the number of domainID entries truncated>"
},
{
"date":"<date/time of the entry>",
"domainID":"<anotherDomainID extracted from voucher-request>",
"nonce":"<any nonce if supplied (or the exact string 'NULL')>"
"assertion":"<the value from the voucher assertion leaf>"
}
],
"truncation": {
"nonced duplicates": "<total number of entries truncated>",
"nonceless duplicates": "<total number of entries truncated>",
"arbitrary": "<number of domainID entries removed entirely>"
}
}
Distribution of a large log is less than ideal. This structure can be optimized as follows: Nonced or Nonceless entries for the same domainID MAY be truncated from the log leaving only the single most recent nonced or nonceless entry for that domainID. In the case of truncation the 'event' truncation value SHOULD contain a count of the number of events for this domainID that were truncated. The log SHOULD NOT be further reduced but there could exist operational situation where maintaining the full log is not possible. In such situations the log MAY be arbitrarily truncated for length, with the number of removed entries indicated as 'arbitrary'.
If the truncation count exceeds 1024 then the MASA MAY use this value without further incrementing it.
A log where duplicate entries for the same domain have been truncated ("nonced duplicates" and/or "nonceless duplicates) could still be acceptable for informed decisions. A log that has had "arbitrary" truncations is less acceptable but manufacturer transparency is better than hidden truncations.
This document specifies a simple log format as provided by the MASA service to the registrar. This format could be improved by distributed consensus technologies that integrate vouchers with technologies such as block-chain or hash trees or optimized logging approaches. Doing so is out of the scope of this document but is an anticipated improvement for future work. As such, the registrar client SHOULD anticipate new kinds of responses, and SHOULD provide operator controls to indicate how to process unknown responses.
Each time the Manufacturer Authorized Signing Authority (MASA) issues a voucher, it places it into the audit log for that device. The details are described in Section 5.8. The contents of the audit log can express a variety of trust levels, and this section explains what kind of trust a registrar can derive from the entries.
While the audit log provides a list of vouchers that were issued by the MASA, the vouchers are issued in response to voucher-requests, and it is the contents of the voucher-requests which determines how meaningful the audit log entries are.
A registrar SHOULD use the log information to make an informed decision regarding the continued bootstrapping of the pledge. The exact policy is out of scope of this document as it depends on the security requirements within the registrar domain. Equipment that is purchased pre-owned can be expected to have an extensive history. The following dicussion is provided to help explain the value of each log element:
A relatively simple policy is to white list known (internal or external) domainIDs and to require all vouchers to have a nonce and/or require that all nonceless vouchers be from a subset (e.g. only internal) domainIDs. A simple action is to revoke any locally issued credentials for the pledge in question or to refuse to forward the voucher. A registrar MAY be configured to ignore the history of the device but it is RECOMMENDED that this only be configured if hardware assisted NEA [RFC5209] is supported.
The pledge SHOULD follow the BRSKI operations with EST enrollment operations including "CA Certificates Request", "CSR Attributes" and "Client Certificate Request" or "Server-Side Key Generation", etc. This is a relatively seamless integration since BRSKI REST calls provide an automated alternative to the manual bootstrapping method described in [RFC7030]. As noted above, use of HTTP 1.1 persistent connections simplifies the pledge state machine.
Although EST allows clients to obtain multiple certificates by sending multiple CSR requests BRSKI mandates use of the CSR Attributes request and mandates that the registrar validate the CSR against the expected attributes. This implies that client requests will "look the same" and therefore result in a single logical certificate being issued even if the client were to make multiple requests. Registrars MAY contain more complex logic but doing so is out-of-scope of this specification. BRSKI does not signal any enhancement or restriction to this capability.
The pledge SHOULD request the full EST Distribution of CA Certificates message. See RFC7030, section 4.1.
This ensures that the pledge has the complete set of current CA certificates beyond the pinned-domain-cert (see Section 5.6.1 for a discussion of the limitations inherent in having a single certificate instead of a full CA Certificates response.) Although these limitations are acceptable during initial bootstrapping, they are not appropriate for ongoing PKIX end entity certificate validation.
Automated bootstrapping occurs without local administrative configuration of the pledge. In some deployments it is plausible that the pledge generates a certificate request containing only identity information known to the pledge (essentially the X.509 IDevID information) and ultimately receives a certificate containing domain specific identity information. Conceptually the CA has complete control over all fields issued in the end entity certificate. Realistically this is operationally difficult with the current status of PKI certificate authority deployments, where the CSR is submitted to the CA via a number of non-standard protocols. Even with all standardized protocols used, it could operationally be problematic to expect that service specific certificate fields can be created by a CA that is likely operated by a group that has no insight into different network services/protocols used. For example, the CA could even be outsourced.
To alleviate these operational difficulties, the pledge MUST request the EST "CSR Attributes" from the EST server and the EST server needs to be able to reply with the attributes necessary for use of the certificate in its intended protocols/services. This approach allows for minimal CA integrations and instead the local infrastructure (EST server) informs the pledge of the proper fields to include in the generated CSR. This approach is beneficial to automated boostrapping in the widest number of environments.
If the hardwareModuleName in the X.509 IDevID is populated then it SHOULD by default be propagated to the LDevID along with the hwSerialNum. The EST server SHOULD support local policy concerning this functionality.
In networks using the BRSKI enrolled certificate to authenticate the ACP (Autonomic Control Plane), the EST attributes MUST include the "ACP information" field. See [I-D.ietf-anima-autonomic-control-plane] for more details.
The registrar MUST also confirm that the resulting CSR is formatted as indicated before forwarding the request to a CA. If the registrar is communicating with the CA using a protocol such as full CMC, which provides mechanisms to override the CSR attributes, then these mechanisms MAY be used even if the client ignores CSR Attribute guidance.
The pledge MUST request a new client certificate. See RFC7030, section 4.2.
For automated bootstrapping of devices, the adminstrative elements providing bootstrapping also provide indications to the system administrators concerning device lifecycle status. This might include information concerning attempted bootstrapping messages seen by the client, MASA provides logs and status of credential enrollment. [RFC7030] assumes an end user and therefore does not include a final success indication back to the server. This is insufficient for automated use cases.
To indicate successful enrollment the client SHOULD re-negotiate the EST TLS session using the newly obtained credentials. This occurs by the client initiating a new TLS ClientHello message on the existing TLS connection. The client MAY simply close the old TLS session and start a new one. The server MUST support either model.
In the case of a FAIL, the Reason string indicates why the most recent enrollment failed. The SubjectKeyIdentifier field MUST be included if the enrollment attempt was for a keypair that is locally known to the client. If EST /serverkeygen was used and failed then the field is omitted from the status telemetry.
In the case of a SUCCESS the Reason string is omitted. The SubjectKeyIdentifier is included so that the server can record the successful certificate distribution.
Status media type: application/json
The client HTTP POSTs the following to the server at the new EST well known URI /enrollstatus.
{
"version":"1",
"Status":TRUE /* TRUE=Success, FALSE=Fail"
"Reason":"Informative human readable message"
"reason-context": "Additional information"
}
The server SHOULD respond with an HTTP 200 but MAY simply fail with an HTTP 404 error.
Within the server logs the server MUST capture if this message was received over an TLS session with a matching client certificate. This allows for clients that wish to minimize their crypto operations to simply POST this response without renegotiating the TLS session - at the cost of the server not being able to accurately verify that enrollment was truly successful.
Pledges that require multiple certificates could establish direct EST connections to the registrar.
This document describes extensions to EST for the purposes of bootstrapping of remote key infrastructures. Bootstrapping is relevant for CoAP enrollment discussions as well. The defintion of EST and BRSKI over CoAP is not discussed within this document beyond ensuring proxy support for CoAP operations. Instead it is anticipated that a definition of CoAP mappings will occur in subsequent documents such as [I-D.ietf-ace-coap-est] and that CoAP mappings for BRSKI will be discussed either there or in future work.
[RFC7030] defines it's endpoints to include a "Content-Transfer-Encoding" heading, and the payloads to be [RFC4648] Base64 encoded DER.
When used within BRSKI, the original RFC7030 EST endpoints remain Base64 encoded, but the new BRSKI end points which send and receive binary artifacts (specifically, ../voucherrequest) are binary. That is, no encoding is used.
In the BRSKI context, the EST "Content-Transfer-Encoding" header if present, SHOULD be ignored. This header does not need to included.
A common requirement of bootstrapping is to support less secure operational modes for support specific use cases. The following sections detail specific ways that the pledge, registrar and MASA can be configured to run in a less secure mode for the indicated reasons.
This section is considered non-normative: use suggested methods MUST be detailed in specific profiles of BRSKI. This is the subject for future work.
This section explains the trust relationships detailed in Section 2.4:
+--------+ +---------+ +------------+ +------------+
| Pledge | | Join | | Domain | |Manufacturer|
| | | Proxy | | Registrar | | Service |
| | | | | | | (Internet) |
+--------+ +---------+ +------------+ +------------+
Figure 10
The pledge can choose to accept vouchers using less secure methods. These methods enable offline and emergency (touch based) deployment use cases:
It is RECOMMENDED that "trust on first use" or any method of skipping voucher validation (including use of craft serial console) only be available if hardware assisted Network Endpoint Assessment [RFC5209] is supported. This recommendation ensures that domain network monitoring can detect innappropriate use of offline or emergency deployment procedures when voucher-based bootstrapping is not used.
A registrar can choose to accept devices using less secure methods. These methods are acceptable when low security models are needed, as the security decisions are being made by the local administrator, but they MUST NOT be the default behavior:
Lower security modes chosen by the MASA service affect all device deployments unless bound to the specific device identities. In which case these modes can be provided as additional features for specific customers. The MASA service can choose to run in less secure modes by:
This document requires the following IANA actions:
This document extends the definitions of "est" (so far defined via RFC7030) in the "https://www.iana.org/assignments/well-known-uris/well-known-uris.xhtml" registry as follows:
IANA is requested to register the following:
This document requests a number for id-mod-MASAURLExtn2016(TBD) from the pkix(7) id-mod(0) Registry.
This document has received an early allocation from the id-pe registry (SMI Security for PKIX Certificate Extension) for id-pe-masa-url with the value 32, resulting in an OID of 1.3.6.1.5.5.7.1.32.
IANA is requested to create a new Registry entitled: "BRSKI Parameters", and within that Registry to create a table called: "Pledge BRSKI Status Telemetry Attributes". New items can be added using the Specification Required. The following items are to be in the initial registration, with this document (Section 5.7) as the reference:
IANA is requested to register the following Service Names:
Service Name: _brski-proxy
Transport Protocol(s): tcp
Assignee: IESG <iesg@ietf.org>.
Contact: IESG <iesg@ietf.org>
Description: The Bootstrapping Remote Secure Key
Infrastructures Proxy
Reference: [This document]
Service Name: _brski-registrar
Transport Protocol(s): tcp
Assignee: IESG <iesg@ietf.org>.
Contact: IESG <iesg@ietf.org>
Description: The Bootstrapping Remote Secure Key
Infrastructures Registrar
Reference: [This document]
The IANA is requested to list the name "masa" in the MUD extensions registry defined in [I-D.ietf-opsawg-mud]. Its use is documented in Appendix C.
This document provides a solution to the requirements for secure bootstrap set out in Using an Autonomic Control Plane for Stable Connectivity of Network Operations, Administration, and Maintenance, A Reference Model for Autonomic Networking and specifically the An Autonomic Control Plane (ACP), section 3.2 (Secure Bootstrap), and section 6.1 (ACP Domain, Certificate and Network).
The protocol described in this document has appeal in a number of other non-ANIMA use cases. Such uses of the protocol will be deploying into other environments with different tradeoffs of privacy, security, reliability and autonomy from manufacturers. As such those use cases will need to provide their own applicability statements, and will need to address unique privacy and security considerations for the environments in which they are used.
The autonomic control plane that this document provides bootstrap for is typically a medium to large Internet Service Provider organization, or an equivalent Enterprise that has signficant layer-3 router connectivity. (A network consistenting of primarily layer-2 is not excluded, but the adjacencies that the ACP will create and maintain will not reflect the topology until all devices participate in the ACP).
As specified in the ANIMA charter, this work "..focuses on professionally-managed networks." Such a network has an operator and can do things like like install, configure and operate the Registrar function. The operator makes purchasing decisions and is aware of what manufacturers it expects to see on it's network.
Such an operator also is capable of performing the traditional (craft serial-console) based bootstrap of devices. The zero-touch mechanism presented in this and the ACP document represents a signficiant efficiency: in particular it reduces the need to put senior experts on airplanes to configure devices in person. There is a recognition as the technology evolves that not every situation may work out, and occasionally a human still still have to visit.
The BRSKI protocol is going into environments where there have already been quite a number of vendor proprietary management systems. Those are not expected to go away quickly, but rather to leverage the secure credentials that are provisioned by BRSKI. The connectivity requirements of said management systems are provided by the ACP.
The MASA audit log includes a hash of the domainID for each Registrar a voucher has been issued to. This information is closely related to the actual domain identity, especially when paired with the anti-DDoS authentication information the MASA might collect. This could provide sufficient information for the MASA service to build a detailed understanding the devices that have been provisioned within a domain.
There are a number of design choices that mitigate this risk. The domain can maintain some privacy since it has not necessarily been authenticated and is not authoritatively bound to the supply chain.
Additionally the domainID captures only the unauthenticated subject key identifier of the domain. A privacy sensitive domain could theoretically generate a new domainID for each device being deployed. Similarly a privacy sensitive domain would likely purchase devices that support proximity assertions from a manufacturer that does not require sales channel integrations. This would result in a significant level of privacy while maintaining the security characteristics provided by Registrar based audit log inspection.
The so-called "call-home" mechanism that occurs as part of the BRSKI-MASA connection standardizes what has been deemed by some as a sinister mechanism for corporate oversight of individuals. ([livingwithIoT] and [IoTstrangeThings] for a small sample).
As the Autonomic Control Plane (ACP) usage of BRSKI is not targetted at individual usage of IoT devices, but rather at the Enterprise and ISP creation of networks in a zero-touch fashion, the "call-home" represents a different kind of concern.
It needs to be re-iterated that the BRSKI-MASA mechanism only occurs once during the comissioning of the device. It is well defined, and although encrypted with TLS, it could in theory be made auditable as the contents are well defined. This connection does not occur when the device powers on or is restarted for normal routines. It is conceivable that a device could be forced to go through a full factory reset during an exceptional firmware update situation, after which enrollment would have be repeated.
The BRSKI call-home mechanism is mediated via the owner's Registrar, and the information that is transmitted is directly auditable by the device owner. This is in stark constrast to many "call-home" protocols where the device autonomously calls home and uses an undocumented protocol.
While the contents of the signed part of the pledge voucher request can not be changed, they are not encrypted at the registrar. The ability to audit the messages by the owner of the network prevents exfiltration of data by a nefarious pledge. The contents of an unsigned voucher request are, however, completely changeable by the Registrar. Both are, to re-iterate, encrypted by TLS while in transit.
The BRSKI-MASA exchange reveals the following information to the manufacturer:
The above situation is to be distinguished from a residential/individual person who registers a device from a manufacturer: that an enterprise/ISP purchases routing products is hardly worth mentioning. Deviations would, however, be notable.
The situation is not improved by the enterprise/ISP using anonymization services such as ToR, as a TLS 1.2 connection will reveal the ClientCertificate used, clearly identifying the enterprise/ISP involved. TLS 1.3 is better in this regard, but an active attacker can still discover the parties involved by performing a Man-In-The-Middle-Attack on the first attempt (breaking/killing it with a TCP RST), and then letting subsequent connection pass through.
A manufacturer could attempt to mix the BRSKI-MASA traffic in with general traffic their site by hosting the MASA behind the same (set) of load balancers that the companies normal marketing site is hosted behind. This makes lots of sense from a straight capacity planning point of view as the same set of services (and the same set of Distributed Denial of Service mitigations) may be used. Unfortunately, as the BRSKI-MASA connections include TLS ClientCertificate exchanges, this may easily be observed in TLS 1.2, and a traffic analysis may reveal it even in TLS 1.3. This does not make such a plan irrelevant. There may be other organizational reasons to keep the marketing site (which is often subject to frequent redesigs, outsourcing, etc.) seperate from the MASA, which may need to operate reliably for decades.
As explained above, the manufacturer receives information each time that a device which is in factory-default mode does a zero-touch bootstrap, and attempts to enroll into a domain owner's registrar.
The manufacturer is therefore in a position to decline to issue a voucher if it detects that the new owner is not the same as the previous owner.
This section has outlined five situations in which a manufacturer could use the voucher system to enforce what are clearly license terms. A manufacturer that attempted to enforce license terms via vouchers would find it rather ineffective as the terms would only be enforced when the device is enrolled, and this is not (to repeat), a daily or even monthly occurrance.
Manufacturers of devices often sell different products into different regional markets. Which product is available in which market can be driven by price differentials, support issues (some markets may require manuals and tech-support to be done in the local language), government export regulation (such as whether strong crypto is permitted to be exported, or permitted to be used in a particular market). When an domain owner obtains a device from a different market (they can be new) and transfers it to a different location, this is called a Grey Market.
A manufacturer could decide not to issue a voucher to an enterprise/ISP based upon their location. There are a number of ways which this could be determined: from the geolocation of the registrar, from sales channel knowledge about the customer, and what products are (un-)available in that market. If the device has a GPS the coordinates of the device could even be placed into an extension of the voucher.
The above actions are not illegal, and not new. Many manufacturers have shipped crypto-weak (exportable) versions of firmware as the default on equipment for decades. The first task of an enterprise/ISP has always been to login to a manufacturer system, show one's "entitlement" (country informatin, proof that support payments have been made), and receive either a new updated firmware, or a license key that will activate the correct firmware.
BRSKI permits the above process to automated (in an autonomic fashion), and therefore perhaps encourages this kind of differentiation by reducing the cost of doing it.
An issue that manufacturers will need to deal with in the above automated process is when a device is shipped to one country with one set of rules (or laws or entitlements), but the domain registry is in another one. Which rules apply is something will have to be worked out: the manufacturer could come to believe they are dealing with Grey market equipment, when it is simply dealing with a global enterprise.
The most obvious mitigation is not to buy the product. Pick manufacturers that are up-front about their policies, who do not change them gratutiously.
A manufacturer could provide a mechanism to manage the trust anchors and built-in certificates (IDevID) as an extension. This is a substantial amount of work, and may be an area for future standardization work.
Replacement of the voucher validation anchors (usually pointing to the original manufacturer's MASA) with those of the new owner permits the new owner to issue vouchers to subsequent owners. This would be done by having the selling (old) owner to run a MASA.
In order to automatically find the new MASA, the mechanism describe in this document is to look for the MASA URL extension in the IDevID. A new owner could override this in their Registrar, or the manufacturer could provide a mechanism to update or replace the IDevID prior to sale.
Once the voucher trust anchor and the IDevID is replaced, then the device will no longer trust the manufacturer in any way. When a new owner performs a bootstrap, the device will point to a MASA that has been chosen, and will validate vouchers from this new entity.
The BRSKI protocol depends upon a trust anchor on the device and an identity on the device. Management of these these entities facilitiates a few new operatonal modes without making any changes to the BRSKI protocol. Those modes include: offline modes where the domain owner operates an internal MASA for all devices, resell modes where the first domain owner becomes the MASA for the next (resold-to) domain owner, and services where an aggregator acquires a large variety of devices, and then acts as a pseudonymized MASA for a variety of devices from a variety of manufacturers.
Some manufacturers may wish to consider replacement of the IDevID as an indication that the device's warantee is terminated. For others, the privacy requiments of some deployments might consider this a standard operating practice.
As discussed at the end of Section 5.8.1, new work could be done to use a distributed consensus technology for the audit log. This would permit the audit log to continue to be useful, even when there is a chain of MASA due to changes of ownership.
This document details a protocol for bootstrapping that balances operational concerns against security concerns. As detailed in the introduction, and touched on again in Section 7, the protocol allows for reduced security modes. These attempt to deliver additional control to the local administrator and owner in cases where less security provides operational benefits. This section goes into more detail about a variety of specific considerations.
To facilitate logging and administrative oversight, in addition to triggering Registration verification of MASA logs, the pledge reports on voucher parsing status to the registrar. In the case of a failure, this information is informative to a potentially malicious registrar. This is mandated anyway because of the operational benefits of an informed administrator in cases where the failure is indicative of a problem. The registrar is RECOMMENDED to verify MASA logs if voucher status telemetry is not received.
To facilitate truely limited clients EST RFC7030 section 3.3.2 requirements that the client MUST support a client authentication model have been reduced in Section 7 to a statement that the registrar "MAY" choose to accept devices that fail cryptographic authentication. This reflects current (poor) practices in shipping devices without a cryptographic identity that are NOT RECOMMENDED.
During the provisional period of the connection the pledge MUST treat all HTTP header and content data as untrusted data. HTTP libraries are regularly exposed to non-secured HTTP traffic: mature libraries should not have any problems.
Pledges might chose to engage in protocol operations with multiple discovered registrars in parallel. As noted above they will only do so with distinct nonce values, but the end result could be multiple vouchers issued from the MASA if all registrars attempt to claim the device. This is not a failure and the pledge choses whichever voucher to accept based on internal logic. The registrars verifying log information will see multiple entries and take this into account for their analytics purposes.
There are uses cases where the MASA could be unavailable or uncooperative to the Registrar. They include active DoS attacks, planned and unplanned network partitions, changes to MASA policy, or other instances where MASA policy rejects a claim. These introduce an operational risk to the Registrar owner in that MASA behavior might limit the ability to bootstrap a pledge device. For example this might be an issue during disaster recovery. This risk can be mitigated by Registrars that request and maintain long term copies of "nonceless" vouchers. In that way they are guaranteed to be able to bootstrap their devices.
The issuance of nonceless vouchers themselves creates a security concern. If the Registrar of a previous domain can intercept protocol communications then it can use a previously issued nonceless voucher to establish management control of a pledge device even after having sold it. This risk is mitigated by recording the issuance of such vouchers in the MASA audit log that is verified by the subsequent Registrar and by Pledges only bootstrapping when in a factory default state. This reflects a balance between enabling MASA independence during future bootstrapping and the security of bootstrapping itself. Registrar control over requesting and auditing nonceless vouchers allows device owners to choose an appropriate balance.
The MASA is exposed to DoS attacks wherein attackers claim an unbounded number of devices. Ensuring a registrar is representative of a valid manufacturer customer, even without validating ownership of specific pledge devices, helps to mitigate this. Pledge signatures on the pledge voucher-request, as forwarded by the registrar in the prior-signed-voucher-request field of the registrar voucher-request, significantly reduce this risk by ensuring the MASA can confirm proximity between the pledge and the registrar making the request. This mechanism is optional to allow for constrained devices. Supply chain integration ("know your customer") is an additional step that MASA providers and device vendors can explore.
A concern has been raised that the pledge voucher-request should contain some content (a nonce) provided by the registrar and/or MASA in order for those actors to verify that the pledge voucher-request is fresh.
There are a number of operational problems with getting a nonce from the MASA to the pledge. It is somewhat easier to collect a random value from the registrar, but as the registrar is not yet vouched for, such a registrar nonce has little value. There are privacy and logistical challenges to addressing these operational issues, so if such a thing were to be considered, it would have to provide some clear value. This section examines the impacts of not having a fresh pledge voucher-request.
Because the registrar authenticates the pledge, a full Man-in-the-Middle attack is not possible, despite the provisional TLS authentication by the pledge (see Section 5.) Instead we examine the case of a fake registrar (Rm) that communicates with the pledge in parallel or in close time proximity with the intended registrar. (This scenario is intentionally supported as described in Section 4.1.)
The fake registrar (Rm) can obtain a voucher signed by the MASA either directly or through arbitrary intermediaries. Assuming that the MASA accepts the registrar voucher-request (either because Rm is collaborating with a legitimate registrar according to supply chain information, or because the MASA is in audit-log only mode), then a voucher linking the pledge to the registrar Rm is issued.
Such a voucher, when passed back to the pledge, would link the pledge to registrar Rm, and would permit the pledge to end the provisional state. It now trusts Rm and, if it has any security vulnerabilities leveragable by an Rm with full administrative control, can be assumed to be a threat against the intended registrar.
This flow is mitigated by the intended registrar verifying the audit logs available from the MASA as described in Section 5.8. Rm might chose to collect a voucher-request but wait until after the intended registrar completes the authorization process before submitting it. This pledge voucher-request would be 'stale' in that it has a nonce that no longer matches the internal state of the pledge. In order to successfully use any resulting voucher the Rm would need to remove the stale nonce or anticipate the pledge's future nonce state. Reducing the possibility of this is why the pledge is mandated to generate a strong random or pseudo-random number nonce.
Additionally, in order to successfully use the resulting voucher the Rm would have to attack the pledge and return it to a bootstrapping enabled state. This would require wiping the pledge of current configuration and triggering a re-bootstrapping of the pledge. This is no more likely than simply taking control of the pledge directly but if this is a consideration the target network is RECOMMENDED to take the following steps:
The BRSKI extensions to EST permit a new pledge to be completely configured with domain specific trust anchors. The link from built-in manufacturer-provided trust anchors to domain-specific trust anchors is mediated by the signed voucher artifact.
If the manufacturer's IDevID signing key is not properly validated, then there is a risk that the network will accept a pledge that should not be a member of the network. As the address of the manufacturer's MASA is provided in the IDevID using the extension from Section 2.3, the malicious pledge will have no problem collaborating with it's MASA to produce a completely valid voucher.
BRSKI does not, however, fundamentally change the trust model from domain owner to manufacturer. Assuming that the pledge used its IDevID with RFC7030 EST and BRSKI, the domain (registrar) still needs to trust the manufacturer.
Establishing this trust between domain and manufacturer is outside the scope of BRSKI. There are a number of mechanisms that can adopted including:
The existing WebPKI provides a reasonable anchor between manufacturer name and public key. It authenticates the key. It does not provide a reasonable authorization for the manufacturer, so it is not directly useable on it's own.
BRSKI depends upon the manufacturer building in trust anchors to the pledge device. The voucher artifact which is signed by the MASA will be validated by the pledge using that anchor. This implies that the manufacturer needs to maintain access to a signing key that the pledge can validate.
The manufacturer will need to maintain the ability to make signatures that can be validated for the lifetime that the device could be onboarded. Whether this onboarding lifetime is less than the device lifetime depends upon how the device is used. An inventory of devices kept in a warehouse as spares might not be onboarded for many decades.
There are good cryptographic hygiene reasons why a manufacturer would not want to maintain access to a private key for many decades. A manufacturer in that situation can leverage a long-term certificate authority anchor, built-in to the pledge, and then a certificate chain may be incorporated using the normal CMS certificate set. This may increase the size of the voucher artifacts, but that is not a significant issues in non-constrained environements.
There are a few other operational variations that manufacturers could consider. For instance, there is no reason that every device need have the same set of trust anchors pre-installed. Devices built in different factories, or on different days, or any other consideration could have different trust anchors built in, and the record of which batch the device is in would be recorded in the asset database. The manufacturer would then know which anchor to sign an artifact against.
Aside from the concern about long-term access to private keys, a major limiting factor for the shelf-life of many devices will be the age of the cryptographic algorithms included. A device produced in 2019 will have hardware and software capable of validating algorithms common in 2019, and will have no defense against attacks (both quantum and von-neuman brute force attacks) which have not yet been invented. This concern is orthogonal to the concern about access to private keys, but this concern likely dominates and limits the lifespan of a device in a warehouse. If any update to firmware to support new cryptographic mechanism were possible (while the device was in a warehouse), updates to trust anchors would also be done at the same time.
We would like to thank the various reviewers for their input, in particular William Atwood, Brian Carpenter, Toerless Eckert, Fuyu Eleven, Eliot Lear, Sergey Kasatkin, Anoop Kumar, Markus Stenberg, Peter van der Stok, and Thomas Werner
Significant reviews were done by Jari Arko, Christian Huitema and Russ Housley.
The secification of BRSKI in Section 4 intentionally only covers the mechanisms for an IPv6 pledge using Link-Local addresses. This section describes non-normative extensions that can be used in other environments.
Instead of an IPv6 link-local address, an IPv4 address may be generated using [RFC3927] Dynamic Configuration of IPv4 Link-Local Addresses.
In the case that an IPv4 Link-Local address is formed, then the bootstrap process would continue as in the IPv6 case by looking for a (circuit) proxy.
The Plege MAY obtain an IP address via DHCP [RFC2131]. The DHCP provided parameters for the Domain Name System can be used to perform DNS operations if all local discovery attempts fail.
Pledge discovery of the proxy (Section 4.1) MAY be performed with DNS-based Service Discovery [RFC6763] over Multicast DNS [RFC6762] to discover the proxy at "_brski-proxy._tcp.local.".
Proxy discovery of the registrar (Section 4.3) MAY be performed with DNS-based Service Discovery over Multicast DNS to discover registrars by searching for the service "_brski-registrar._tcp.local.".
To prevent unaccceptable levels of network traffic, when using mDNS, the congestion avoidance mechanisms specified in [RFC6762] section 7 MUST be followed. The pledge SHOULD listen for an unsolicited broadcast response as described in [RFC6762]. This allows devices to avoid announcing their presence via mDNS broadcasts and instead silently join a network by watching for periodic unsolicited broadcast responses.
Discovery of registrar MAY also be performed with DNS-based service discovery by searching for the service "_brski-registrar._tcp.example.com". In this case the domain "example.com" is discovered as described in [RFC6763] section 11 (Appendix A.2 suggests the use of DHCP parameters).
If no local proxy or registrar service is located using the GRASP mechanisms or the above mentioned DNS-based Service Discovery methods the pledge MAY contact a well known manufacturer provided bootstrapping server by performing a DNS lookup using a well known URI such as "brski-registrar.manufacturer.example.com". The details of the URI are manufacturer specific. Manufacturers that leverage this method on the pledge are responsible for providing the registrar service. Also see Section 2.7.
The current DNS services returned during each query are maintained until bootstrapping is completed. If bootstrapping fails and the pledge returns to the Discovery state, it picks up where it left off and continues attempting bootstrapping. For example, if the first Multicast DNS _bootstrapks._tcp.local response doesn't work then the second and third responses are tried. If these fail the pledge moves on to normal DNS-based Service Discovery.
module: ietf-mud-brski-masa augment /ietf-mud:mud: +--rw masa-server? inet:uri
The following extension augments the MUD model to include a single node, as described in [I-D.ietf-opsawg-mud] section 3.6, using the following sample module that has the following tree structure:
<CODE BEGINS> file "ietf-mud-extension@2018-02-14.yang"
module ietf-mud-brski-masa {
yang-version 1.1;
namespace "urn:ietf:params:xml:ns:yang:ietf-mud-brski-masa";
prefix ietf-mud-brski-masa;
import ietf-mud {
prefix ietf-mud;
}
import ietf-inet-types {
prefix inet;
}
organization
"IETF ANIMA (Autonomic Networking Integrated Model and
Approach) Working Group";
contact
"WG Web: http://tools.ietf.org/wg/anima/
WG List: anima@ietf.org
";
description
"BRSKI extension to a MUD file to indicate the
MASA URL.";
revision 2018-02-14 {
description
"Initial revision.";
reference
"RFC XXXX: Manufacturer Usage Description
Specification";
}
augment "/ietf-mud:mud" {
description
"BRSKI extension to a MUD file to indicate the
MASA URL.";
leaf masa-server {
type inet:uri;
description
"This value is the URI of the MASA server";
}
}
}
<CODE ENDS>
The model is defined as follows:
The MUD extensions string "masa" is defined, and MUST be included in the extensions array of the mud container of a MUD file when this extension is used.
Three entities are involved in a voucher: the MASA issues (signs) it, the registrar's public key is mentioned in the voucher, and the pledge validates it. In order to provide reproduceable examples the public and private keys for an example MASA and registrar are first listed.
The Manufacturer has a Certificate Authority that signs the pledge's IDevID. In addition the Manufacturer's signing authority (the MASA) signs the vouchers, and that certificate must distributed to the devices at manufacturing time so that vouchers can be validated.
-----BEGIN EC PRIVATE KEY----- MIGkAgEBBDAgiRoYqKoEcfOfvRvmZ5P5Azn58tuI7nSnIy7OgFnCeiNo+BmbgMho r6lcU60gwVagBwYFK4EEACKhZANiAATZAH3Rb2FvIJOnts+vXuWW35ofyNbCHzjA zOi2kWZFE1ByurKImNcNMFGirGnRXIXGqWCfw5ICgJ8CuM3vV5ty9bf7KUlOkejz Tvv+5PV++elkP9HQ83vqTAws2WwWTxI= -----END EC PRIVATE KEY-----
-----BEGIN CERTIFICATE----- MIIBzzCCAVagAwIBAgIBATAKBggqhkjOPQQDAjBNMRIwEAYKCZImiZPyLGQBGRYC Y2ExGTAXBgoJkiaJk/IsZAEZFglzYW5kZWxtYW4xHDAaBgNVBAMME1Vuc3RydW5n IEhpZ2h3YXkgQ0EwHhcNMTcwMzI2MTYxOTQwWhcNMTkwMzI2MTYxOTQwWjBHMRIw EAYKCZImiZPyLGQBGRYCY2ExGTAXBgoJkiaJk/IsZAEZFglzYW5kZWxtYW4xFjAU BgNVBAMMDVVuc3RydW5nIE1BU0EwdjAQBgcqhkjOPQIBBgUrgQQAIgNiAATZAH3R b2FvIJOnts+vXuWW35ofyNbCHzjAzOi2kWZFE1ByurKImNcNMFGirGnRXIXGqWCf w5ICgJ8CuM3vV5ty9bf7KUlOkejzTvv+5PV++elkP9HQ83vqTAws2WwWTxKjEDAO MAwGA1UdEwEB/wQCMAAwCgYIKoZIzj0EAwIDZwAwZAIwGb0oyM0doP6t3/LSPL5O DuatEwMYh7WGO+IYTHC8K7EyHBOmCYReKT2+GhV/CLWzAjBNy6UMJTt1tsxJsJqd MPUIFj+4wZg1AOIb/JoA6M7r33pwLQTrHRxEzVMGfWOkYUw= -----END CERTIFICATE-----
This private key signs vouchers:
-----BEGIN EC PRIVATE KEY----- MIGkAgEBBDAgiRoYqKoEcfOfvRvmZ5P5Azn58tuI7nSnIy7OgFnCeiNo+BmbgMho r6lcU60gwVagBwYFK4EEACKhZANiAATZAH3Rb2FvIJOnts+vXuWW35ofyNbCHzjA zOi2kWZFE1ByurKImNcNMFGirGnRXIXGqWCfw5ICgJ8CuM3vV5ty9bf7KUlOkejz Tvv+5PV++elkP9HQ83vqTAws2WwWTxI= -----END EC PRIVATE KEY-----
-----BEGIN CERTIFICATE----- MIIBzzCCAVagAwIBAgIBATAKBggqhkjOPQQDAjBNMRIwEAYKCZImiZPyLGQBGRYC Y2ExGTAXBgoJkiaJk/IsZAEZFglzYW5kZWxtYW4xHDAaBgNVBAMME1Vuc3RydW5n IEhpZ2h3YXkgQ0EwHhcNMTcwMzI2MTYxOTQwWhcNMTkwMzI2MTYxOTQwWjBHMRIw EAYKCZImiZPyLGQBGRYCY2ExGTAXBgoJkiaJk/IsZAEZFglzYW5kZWxtYW4xFjAU BgNVBAMMDVVuc3RydW5nIE1BU0EwdjAQBgcqhkjOPQIBBgUrgQQAIgNiAATZAH3R b2FvIJOnts+vXuWW35ofyNbCHzjAzOi2kWZFE1ByurKImNcNMFGirGnRXIXGqWCf w5ICgJ8CuM3vV5ty9bf7KUlOkejzTvv+5PV++elkP9HQ83vqTAws2WwWTxKjEDAO MAwGA1UdEwEB/wQCMAAwCgYIKoZIzj0EAwIDZwAwZAIwGb0oyM0doP6t3/LSPL5O DuatEwMYh7WGO+IYTHC8K7EyHBOmCYReKT2+GhV/CLWzAjBNy6UMJTt1tsxJsJqd MPUIFj+4wZg1AOIb/JoA6M7r33pwLQTrHRxEzVMGfWOkYUw= -----END CERTIFICATE-----
This private key signs IDevID certificates:
-----BEGIN EC PRIVATE KEY----- MHcCAQEEIF+obiToYYYeMifPsZvrjWJ0yFsCJwIFhpokmT/TULmXoAoGCCqGSM49 AwEHoUQDQgAENWQOzcNMUjP0NrtfeBc0DJLWfeMGgCFdIv6FUz4DifM1ujMBec/g 6W/P6boTmyTGdFOh/8HwKUerL5bpneK8sg== -----END EC PRIVATE KEY-----
-----BEGIN CERTIFICATE----- MIIBrjCCATOgAwIBAgIBAzAKBggqhkjOPQQDAzBOMRIwEAYKCZImiZPyLGQBGRYC Y2ExGTAXBgoJkiaJk/IsZAEZFglzYW5kZWxtYW4xHTAbBgNVBAMMFFVuc3RydW5n IEZvdW50YWluIENBMB4XDTE3MDkwNTAxMTI0NVoXDTE5MDkwNTAxMTI0NVowQzES MBAGCgmSJomT8ixkARkWAmNhMRkwFwYKCZImiZPyLGQBGRYJc2FuZGVsbWFuMRIw EAYDVQQDDAlsb2NhbGhvc3QwWTATBgcqhkjOPQIBBggqhkjOPQMBBwNCAAQ1ZA7N w0xSM/Q2u194FzQMktZ94waAIV0i/oVTPgOJ8zW6MwF5z+Dpb8/puhObJMZ0U6H/ wfApR6svlumd4ryyow0wCzAJBgNVHRMEAjAAMAoGCCqGSM49BAMDA2kAMGYCMQC3 /iTQJ3evYYcgbXhbmzrp64t3QC6qjIeY2jkDx062nuNifVKtyaara3F30AIkKSEC MQDi29efbTLbdtDk3tecY/rD7V77XaJ6nYCmdDCR54TrSFNLgxvt1lyFM+0fYpYR c3o= -----END CERTIFICATE-----
Certificate:
Data:
Version: 3 (0x2)
Serial Number: 3 (0x3)
Signature Algorithm: ecdsa-with-SHA384
Issuer: DC = ca, DC = sandelman, CN = Unstrung Fount
ain CA
Validity
Not Before: Sep 5 01:12:45 2017 GMT
Not After : Sep 5 01:12:45 2019 GMT
Subject: DC = ca, DC = sandelman, CN = localhost
Subject Public Key Info:
Public Key Algorithm: id-ecPublicKey
Public-Key: (256 bit)
pub:
04:35:64:0e:cd:c3:4c:52:33:f4:36:bb:5f:7
8:17:
34:0c:92:d6:7d:e3:06:80:21:5d:22:fe:85:5
3:3e:
03:89:f3:35:ba:33:01:79:cf:e0:e9:6f:cf:e
9:ba:
13:9b:24:c6:74:53:a1:ff:c1:f0:29:47:ab:2
f:96:
e9:9d:e2:bc:b2
ASN1 OID: prime256v1
NIST CURVE: P-256
X509v3 extensions:
X509v3 Basic Constraints:
CA:FALSE
Signature Algorithm: ecdsa-with-SHA384
30:66:02:31:00:b7:fe:24:d0:27:77:af:61:87:20:6d:78:
5b:
9b:3a:e9:eb:8b:77:40:2e:aa:8c:87:98:da:39:03:c7:4e:
b6:
9e:e3:62:7d:52:ad:c9:a6:ab:6b:71:77:d0:02:24:29:21:
02:
31:00:e2:db:d7:9f:6d:32:db:76:d0:e4:de:d7:9c:63:fa:
c3:
ed:5e:fb:5d:a2:7a:9d:80:a6:74:30:91:e7:84:eb:48:53:
4b:
83:1b:ed:d6:5c:85:33:ed:1f:62:96:11:73:7a
The registrar key (or chain) is the representative of the domain owner. This key signs registrar voucher-requests:
-----BEGIN EC PRIVATE KEY----- MHcCAQEEIBgR6SV+uEvWfl5zCQWZxWjYbMhXPyNqdHJ3KPh11mm4oAoGCCqGSM49 AwEHoUQDQgAEWi/jqPpRJ0JgWghZRgeZlLKutbXVjmnHb+1AYaEF/YQjE2g5FZV8 KjiR/bkEl+l8M4onIC7KHaXKKkuag9S6Tw== -----END EC PRIVATE KEY-----
-----BEGIN CERTIFICATE----- MIICBDCCAYugAwIBAgIECe20qTAKBggqhkjOPQQDAjBNMRIwEAYKCZImiZPyLGQB GRYCY2ExGTAXBgoJkiaJk/IsZAEZFglzYW5kZWxtYW4xHDAaBgNVBAMME1Vuc3Ry dW5nIEhpZ2h3YXkgQ0EwIBcNMTkwNDI0MDIxNjU4WhgPMjk5OTEyMzEwMDAwMDBa MBwxGjAYBgNVBAUMETAwLWQwLWU1LTAyLTAwLTJkMFkwEwYHKoZIzj0CAQYIKoZI zj0DAQcDQgAEWi/jqPpRJ0JgWghZRgeZlLKutbXVjmnHb+1AYaEF/YQjE2g5FZV8 KjiR/bkEl+l8M4onIC7KHaXKKkuag9S6T6OBhzCBhDAdBgNVHQ4EFgQUj8KYdUoE OvJ0kcOIbjEWwgWdDYkwCQYDVR0TBAIwADArBgNVHREEJDAioCAGCSsGAQQBgu5S AaATDBEwMC1EMC1FNS0wMi0wMC0yRDArBgkrBgEEAYLuUgIEHgwcbWFzYS5ob25l eWR1a2VzLnNhbmRlbG1hbi5jYTAKBggqhkjOPQQDAgNnADBkAjAmvMjmNgjypDhc fynMV3kMuIpSKrYzRWr4g3PtTwXDsAe0oitTTj4QtU1bajhOfTkCMGMNbsW2Q41F z9t6PDVdtOKabBbAP1RVoFTlDQuO9nmLzb5kU+cUqCtPRFZBUXP3kg== -----END CERTIFICATE-----
Certificate:
Data:
Version: 3 (0x2)
Serial Number: 166573225 (0x9edb4a9)
Signature Algorithm: ecdsa-with-SHA256
Issuer: DC = ca, DC = sandelman, CN = Unstrung Highway CA
Validity
Not Before: Apr 24 02:16:58 2019 GMT
Not After : Dec 31 00:00:00 2999 GMT
Subject: serialNumber = 00-d0-e5-02-00-2d
Subject Public Key Info:
Public Key Algorithm: id-ecPublicKey
Public-Key: (256 bit)
pub:
04:5a:2f:e3:a8:fa:51:27:42:60:5a:08:59:46:07:
99:94:b2:ae:b5:b5:d5:8e:69:c7:6f:ed:40:61:a1:
05:fd:84:23:13:68:39:15:95:7c:2a:38:91:fd:b9:
04:97:e9:7c:33:8a:27:20:2e:ca:1d:a5:ca:2a:4b:
9a:83:d4:ba:4f
ASN1 OID: prime256v1
NIST CURVE: P-256
X509v3 extensions:
X509v3 Subject Key Identifier:
8F:C2:98:75:4A:04:3A:F2:74:91:C3:88:6E:31:16:C2:05:9D:0D:89
X509v3 Basic Constraints:
CA:FALSE
X509v3 Subject Alternative Name:
othername:<unsupported>
1.3.6.1.4.1.46930.2:
..masa.honeydukes.sandelman.ca
Signature Algorithm: ecdsa-with-SHA256
30:64:02:30:26:bc:c8:e6:36:08:f2:a4:38:5c:7f:29:cc:57:
79:0c:b8:8a:52:2a:b6:33:45:6a:f8:83:73:ed:4f:05:c3:b0:
07:b4:a2:2b:53:4e:3e:10:b5:4d:5b:6a:38:4e:7d:39:02:30:
63:0d:6e:c5:b6:43:8d:45:cf:db:7a:3c:35:5d:b4:e2:9a:6c:
16:c0:3f:54:55:a0:54:e5:0d:0b:8e:f6:79:8b:cd:be:64:53:
e7:14:a8:2b:4f:44:56:41:51:73:f7:92
The pledge has an IDevID key pair built in at manufacturing time: Section 2.3.
RFC-EDITOR: these examples will need to be replaced with CMS versions once IANA has assigned the eContentType in [RFC8366].
-----BEGIN CMS----- MIIGtQYJKoZIhvcNAQcCoIIGpjCCBqICAQExDTALBglghkgBZQMEAgEwggNRBgkq hkiG9w0BBwGgggNCBIIDPnsiaWV0Zi12b3VjaGVyLXJlcXVlc3Q6dm91Y2hlciI6 eyJhc3NlcnRpb24iOiJwcm94aW1pdHkiLCJjcmVhdGVkLW9uIjoiMjAxOS0wNS0x NVQxNzoyNTo1NS42NDQtMDQ6MDAiLCJzZXJpYWwtbnVtYmVyIjoiMDAtZDAtZTUt MDItMDAtMmQiLCJub25jZSI6IlZPVUZULVd3ckV2ME51QVFFSG9WN1EiLCJwcm94 aW1pdHktcmVnaXN0cmFyLWNlcnQiOiJNSUlCMFRDQ0FWYWdBd0lCQWdJQkFqQUtC Z2dxaGtqT1BRUURBekJ4TVJJd0VBWUtDWkltaVpQeUxHUUJHUllDWTJFeEdUQVhC Z29Ka2lhSmsvSXNaQUVaRmdsellXNWtaV3h0WVc0eFFEQStCZ05WQkFNTU55TThV M2x6ZEdWdFZtRnlhV0ZpYkdVNk1IZ3dNREF3TURBd05HWTVNVEZoTUQ0Z1ZXNXpk SEoxYm1jZ1JtOTFiblJoYVc0Z1EwRXdIaGNOTVRjeE1UQTNNak0wTlRJNFdoY05N VGt4TVRBM01qTTBOVEk0V2pCRE1SSXdFQVlLQ1pJbWlaUHlMR1FCR1JZQ1kyRXhH VEFYQmdvSmtpYUprL0lzWkFFWkZnbHpZVzVrWld4dFlXNHhFakFRQmdOVkJBTU1D V3h2WTJGc2FHOXpkREJaTUJNR0J5cUdTTTQ5QWdFR0NDcUdTTTQ5QXdFSEEwSUFC SlpsVUhJMHVwL2wzZVpmOXZDQmIrbElub0VNRWdjN1JvK1haQ3RqQUkwQ0QxZkpm SlIvaEl5eURtSFd5WWlORmJSQ0g5ZnlhcmZremdYNHAwelRpenFqRFRBTE1Ba0dB MVVkRXdRQ01BQXdDZ1lJS29aSXpqMEVBd01EYVFBd1pnSXhBTFFNTnVyZjh0djUw bFJPRDVEUVhIRU9KSk5XM1FWMmc5UUVkRFNrMk1ZK0FvU3JCU21HU05qaDRvbEVP aEV1TGdJeEFKNG5XZk53K0JqYlptS2lJaVVFY1R3SE1oR1ZYYU1IWS9GN24zOXd3 S2NCQlNPbmROUHFDcE9FTGw2YnEzQ1pxUT09In19oIICCDCCAgQwggGLoAMCAQIC BAnttKkwCgYIKoZIzj0EAwIwTTESMBAGCgmSJomT8ixkARkWAmNhMRkwFwYKCZIm iZPyLGQBGRYJc2FuZGVsbWFuMRwwGgYDVQQDDBNVbnN0cnVuZyBIaWdod2F5IENB MCAXDTE5MDQyNDAyMTY1OFoYDzI5OTkxMjMxMDAwMDAwWjAcMRowGAYDVQQFDBEw MC1kMC1lNS0wMi0wMC0yZDBZMBMGByqGSM49AgEGCCqGSM49AwEHA0IABFov46j6 USdCYFoIWUYHmZSyrrW11Y5px2/tQGGhBf2EIxNoORWVfCo4kf25BJfpfDOKJyAu yh2lyipLmoPUuk+jgYcwgYQwHQYDVR0OBBYEFI/CmHVKBDrydJHDiG4xFsIFnQ2J MAkGA1UdEwQCMAAwKwYDVR0RBCQwIqAgBgkrBgEEAYLuUgGgEwwRMDAtRDAtRTUt MDItMDAtMkQwKwYJKwYBBAGC7lICBB4MHG1hc2EuaG9uZXlkdWtlcy5zYW5kZWxt YW4uY2EwCgYIKoZIzj0EAwIDZwAwZAIwJrzI5jYI8qQ4XH8pzFd5DLiKUiq2M0Vq +INz7U8Fw7AHtKIrU04+ELVNW2o4Tn05AjBjDW7FtkONRc/bejw1XbTimmwWwD9U VaBU5Q0LjvZ5i82+ZFPnFKgrT0RWQVFz95IxggErMIIBJwIBATBVME0xEjAQBgoJ kiaJk/IsZAEZFgJjYTEZMBcGCgmSJomT8ixkARkWCXNhbmRlbG1hbjEcMBoGA1UE AwwTVW5zdHJ1bmcgSGlnaHdheSBDQQIECe20qTALBglghkgBZQMEAgGgaTAYBgkq hkiG9w0BCQMxCwYJKoZIhvcNAQcBMBwGCSqGSIb3DQEJBTEPFw0xOTA1MTUyMTI1 NTVaMC8GCSqGSIb3DQEJBDEiBCAQN2lP7aqwyhmj9qUHt6Qk/SbOTOPXFOwn1wv2 5YGYgDAKBggqhkjOPQQDAgRHMEUCIEYQhHToU0rrhPyQv2fR0TwWePTx2Z1DEhR4 tTl/Dr/ZAiEA47u9+bIz/p6nFJ+wctKHER+ycUzYQF56h9odMo+Ilkc= -----END CMS-----
As described in Section 5.2, the pledge will sign a pledge voucher-request containing the registrar's public key in the proximity-registrar-cert field. The base64 has been wrapped at 60 characters for presentation reasons.
file: examples/vr_00-D0-E5-02-00-2D.pkcs
0:d=0 hl=4 l=1717 cons: SEQUENCE
4:d=1 hl=2 l= 9 prim: OBJECT :pkcs7-signedData
15:d=1 hl=4 l=1702 cons: cont [ 0 ]
19:d=2 hl=4 l=1698 cons: SEQUENCE
23:d=3 hl=2 l= 1 prim: INTEGER :01
26:d=3 hl=2 l= 13 cons: SET
28:d=4 hl=2 l= 11 cons: SEQUENCE
30:d=5 hl=2 l= 9 prim: OBJECT :sha256
41:d=3 hl=4 l= 849 cons: SEQUENCE
45:d=4 hl=2 l= 9 prim: OBJECT :pkcs7-data
56:d=4 hl=4 l= 834 cons: cont [ 0 ]
60:d=5 hl=4 l= 830 prim: OCTET STRING :{"ietf-voucher-request:v
894:d=3 hl=4 l= 520 cons: cont [ 0 ]
898:d=4 hl=4 l= 516 cons: SEQUENCE
902:d=5 hl=4 l= 395 cons: SEQUENCE
906:d=6 hl=2 l= 3 cons: cont [ 0 ]
908:d=7 hl=2 l= 1 prim: INTEGER :02
911:d=6 hl=2 l= 4 prim: INTEGER :09EDB4A9
917:d=6 hl=2 l= 10 cons: SEQUENCE
919:d=7 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA256
929:d=6 hl=2 l= 77 cons: SEQUENCE
931:d=7 hl=2 l= 18 cons: SET
933:d=8 hl=2 l= 16 cons: SEQUENCE
935:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
947:d=9 hl=2 l= 2 prim: IA5STRING :ca
951:d=7 hl=2 l= 25 cons: SET
953:d=8 hl=2 l= 23 cons: SEQUENCE
955:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
967:d=9 hl=2 l= 9 prim: IA5STRING :sandelman
978:d=7 hl=2 l= 28 cons: SET
980:d=8 hl=2 l= 26 cons: SEQUENCE
982:d=9 hl=2 l= 3 prim: OBJECT :commonName
987:d=9 hl=2 l= 19 prim: UTF8STRING :Unstrung Highway CA
1008:d=6 hl=2 l= 32 cons: SEQUENCE
1010:d=7 hl=2 l= 13 prim: UTCTIME :190424021658Z
1025:d=7 hl=2 l= 15 prim: GENERALIZEDTIME :29991231000000Z
1042:d=6 hl=2 l= 28 cons: SEQUENCE
1044:d=7 hl=2 l= 26 cons: SET
1046:d=8 hl=2 l= 24 cons: SEQUENCE
1048:d=9 hl=2 l= 3 prim: OBJECT :serialNumber
1053:d=9 hl=2 l= 17 prim: UTF8STRING :00-d0-e5-02-00-2d
1072:d=6 hl=2 l= 89 cons: SEQUENCE
1074:d=7 hl=2 l= 19 cons: SEQUENCE
1076:d=8 hl=2 l= 7 prim: OBJECT :id-ecPublicKey
1085:d=8 hl=2 l= 8 prim: OBJECT :prime256v1
1095:d=7 hl=2 l= 66 prim: BIT STRING
1163:d=6 hl=3 l= 135 cons: cont [ 3 ]
1166:d=7 hl=3 l= 132 cons: SEQUENCE
1169:d=8 hl=2 l= 29 cons: SEQUENCE
1171:d=9 hl=2 l= 3 prim: OBJECT :X509v3 Subject Key Ident
1176:d=9 hl=2 l= 22 prim: OCTET STRING [HEX DUMP]:04148FC298754A
1200:d=8 hl=2 l= 9 cons: SEQUENCE
1202:d=9 hl=2 l= 3 prim: OBJECT :X509v3 Basic Constraints
1207:d=9 hl=2 l= 2 prim: OCTET STRING [HEX DUMP]:3000
1211:d=8 hl=2 l= 43 cons: SEQUENCE
1213:d=9 hl=2 l= 3 prim: OBJECT :X509v3 Subject Alternati
1218:d=9 hl=2 l= 36 prim: OCTET STRING [HEX DUMP]:3022A02006092B
1256:d=8 hl=2 l= 43 cons: SEQUENCE
1258:d=9 hl=2 l= 9 prim: OBJECT :1.3.6.1.4.1.46930.2
1269:d=9 hl=2 l= 30 prim: OCTET STRING [HEX DUMP]:0C1C6D6173612E
1301:d=5 hl=2 l= 10 cons: SEQUENCE
1303:d=6 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA256
1313:d=5 hl=2 l= 103 prim: BIT STRING
1418:d=3 hl=4 l= 299 cons: SET
1422:d=4 hl=4 l= 295 cons: SEQUENCE
1426:d=5 hl=2 l= 1 prim: INTEGER :01
1429:d=5 hl=2 l= 85 cons: SEQUENCE
1431:d=6 hl=2 l= 77 cons: SEQUENCE
1433:d=7 hl=2 l= 18 cons: SET
1435:d=8 hl=2 l= 16 cons: SEQUENCE
1437:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
1449:d=9 hl=2 l= 2 prim: IA5STRING :ca
1453:d=7 hl=2 l= 25 cons: SET
1455:d=8 hl=2 l= 23 cons: SEQUENCE
1457:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
1469:d=9 hl=2 l= 9 prim: IA5STRING :sandelman
1480:d=7 hl=2 l= 28 cons: SET
1482:d=8 hl=2 l= 26 cons: SEQUENCE
1484:d=9 hl=2 l= 3 prim: OBJECT :commonName
1489:d=9 hl=2 l= 19 prim: UTF8STRING :Unstrung Highway CA
1510:d=6 hl=2 l= 4 prim: INTEGER :09EDB4A9
1516:d=5 hl=2 l= 11 cons: SEQUENCE
1518:d=6 hl=2 l= 9 prim: OBJECT :sha256
1529:d=5 hl=2 l= 105 cons: cont [ 0 ]
1531:d=6 hl=2 l= 24 cons: SEQUENCE
1533:d=7 hl=2 l= 9 prim: OBJECT :contentType
1544:d=7 hl=2 l= 11 cons: SET
1546:d=8 hl=2 l= 9 prim: OBJECT :pkcs7-data
1557:d=6 hl=2 l= 28 cons: SEQUENCE
1559:d=7 hl=2 l= 9 prim: OBJECT :signingTime
1570:d=7 hl=2 l= 15 cons: SET
1572:d=8 hl=2 l= 13 prim: UTCTIME :190515212555Z
1587:d=6 hl=2 l= 47 cons: SEQUENCE
1589:d=7 hl=2 l= 9 prim: OBJECT :messageDigest
1600:d=7 hl=2 l= 34 cons: SET
1602:d=8 hl=2 l= 32 prim: OCTET STRING [HEX DUMP]:1037694FEDAAB0
1636:d=5 hl=2 l= 10 cons: SEQUENCE
1638:d=6 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA256
1648:d=5 hl=2 l= 71 prim: OCTET STRING [HEX DUMP]:30450220461084
{"ietf-voucher-request:voucher":{"assertion":"proximity","created-on":"2019-05-15T17:25:55.644-04:00","serial-number":"00-d0-e5-02-00-2d","nonce":"VOUFT-WwrEv0NuAQEHoV7Q","proximity-registrar-cert":"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"}}
-----BEGIN CMS----- MIIPkwYJKoZIhvcNAQcCoIIPhDCCD4ACAQExDTALBglghkgBZQMEAgEwggnUBgkq hkiG9w0BBwGgggnFBIIJwXsiaWV0Zi12b3VjaGVyLXJlcXVlc3Q6dm91Y2hlciI6 eyJhc3NlcnRpb24iOiJwcm94aW1pdHkiLCJjcmVhdGVkLW9uIjoiMjAxOS0wNS0x NVQyMToyNTo1NS43NThaIiwic2VyaWFsLW51bWJlciI6IjAwLWQwLWU1LTAyLTAw LTJkIiwibm9uY2UiOiJWT1VGVC1Xd3JFdjBOdUFRRUhvVjdRIiwicHJpb3Itc2ln bmVkLXZvdWNoZXItcmVxdWVzdCI6Ik1JSUd0UVlKS29aSWh2Y05BUWNDb0lJR3Bq Q0NCcUlDQVFFeERUQUxCZ2xnaGtnQlpRTUVBZ0V3Z2dOUkJna3Foa2lHOXcwQkJ3 R2dnZ05DQklJRFBuc2lhV1YwWmkxMmIzVmphR1Z5TFhKbGNYVmxjM1E2ZG05MVky aGxjaUk2ZXlKaGMzTmxjblJwYjI0aU9pSndjbTk0YVcxcGRIa2lMQ0pqY21WaGRH VmtMVzl1SWpvaU1qQXhPUzB3TlMweE5WUXhOem95TlRvMU5TNDJORFF0TURRNk1E QWlMQ0p6WlhKcFlXd3RiblZ0WW1WeUlqb2lNREF0WkRBdFpUVXRNREl0TURBdE1t UWlMQ0p1YjI1alpTSTZJbFpQVlVaVUxWZDNja1YyTUU1MVFWRkZTRzlXTjFFaUxD SndjbTk0YVcxcGRIa3RjbVZuYVhOMGNtRnlMV05sY25RaU9pSk5TVWxDTUZSRFEw RldZV2RCZDBsQ1FXZEpRa0ZxUVV0Q1oyZHhhR3RxVDFCUlVVUkJla0o0VFZKSmQw VkJXVXREV2tsdGFWcFFlVXhIVVVKSFVsbERXVEpGZUVkVVFWaENaMjlLYTJsaFNt c3ZTWE5hUVVWYVJtZHNlbGxYTld0YVYzaDBXVmMwZUZGRVFTdENaMDVXUWtGTlRV NTVUVGhWTTJ4NlpFZFdkRlp0Um5saFYwWnBZa2RWTmsxSVozZE5SRUYzVFVSQmQw NUhXVFZOVkVab1RVUTBaMVpYTlhwa1NFb3hZbTFqWjFKdE9URmlibEpvWVZjMFox RXdSWGRJYUdOT1RWUmplRTFVUVROTmFrMHdUbFJKTkZkb1kwNU5WR3Q0VFZSQk0w MXFUVEJPVkVrMFYycENSRTFTU1hkRlFWbExRMXBKYldsYVVIbE1SMUZDUjFKWlEx a3lSWGhIVkVGWVFtZHZTbXRwWVVwckwwbHpXa0ZGV2tabmJIcFpWelZyV2xkNGRG bFhOSGhGYWtGUlFtZE9Wa0pCVFUxRFYzaDJXVEpHYzJGSE9YcGtSRUphVFVKTlIw SjVjVWRUVFRRNVFXZEZSME5EY1VkVFRUUTVRWGRGU0VFd1NVRkNTbHBzVlVoSk1I VndMMnd6WlZwbU9YWkRRbUlyYkVsdWIwVk5SV2RqTjFKdksxaGFRM1JxUVVrd1Ew UXhaa3BtU2xJdmFFbDVlVVJ0U0ZkNVdXbE9SbUpTUTBnNVpubGhjbVpyZW1kWU5I QXdlbFJwZW5GcVJGUkJURTFCYTBkQk1WVmtSWGRSUTAxQlFYZERaMWxKUzI5YVNY cHFNRVZCZDAxRVlWRkJkMXBuU1hoQlRGRk5UblZ5WmpoMGRqVXdiRkpQUkRWRVVW aElSVTlLU2s1WE0xRldNbWM1VVVWa1JGTnJNazFaSzBGdlUzSkNVMjFIVTA1cWFE UnZiRVZQYUVWMVRHZEplRUZLTkc1WFprNTNLMEpxWWxwdFMybEphVlZGWTFSM1NF MW9SMVpZWVUxSVdTOUdOMjR6T1hkM1MyTkNRbE5QYm1ST1VIRkRjRTlGVEd3Mllu 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SUJKd0lCQVRCVk1FMHhFakFRQmdvSmtpYUprL0lzWkFFWkZnSmpZVEVaTUJjR0Nn bVNKb21UOGl4a0FSa1dDWE5oYm1SbGJHMWhiakVjTUJvR0ExVUVBd3dUVlc1emRI SjFibWNnU0dsbmFIZGhlU0JEUVFJRUNlMjBxVEFMQmdsZ2hrZ0JaUU1FQWdHZ2FU QVlCZ2txaGtpRzl3MEJDUU14Q3dZSktvWklodmNOQVFjQk1Cd0dDU3FHU0liM0RR RUpCVEVQRncweE9UQTFNVFV5TVRJMU5UVmFNQzhHQ1NxR1NJYjNEUUVKQkRFaUJD QVFOMmxQN2Fxd3lobWo5cVVIdDZRay9TYk9UT1BYRk93bjF3djI1WUdZZ0RBS0Jn Z3Foa2pPUFFRREFnUkhNRVVDSUVZUWhIVG9VMHJyaFB5UXYyZlIwVHdXZVBUeDJa MURFaFI0dFRsL0RyL1pBaUVBNDd1OStiSXovcDZuRkord2N0S0hFUit5Y1V6WVFG NTZoOW9kTW8rSWxrYz0ifX2gggRCMIIB0TCCAVagAwIBAgIBAjAKBggqhkjOPQQD AzBxMRIwEAYKCZImiZPyLGQBGRYCY2ExGTAXBgoJkiaJk/IsZAEZFglzYW5kZWxt YW4xQDA+BgNVBAMMNyM8U3lzdGVtVmFyaWFibGU6MHgwMDAwMDAwNGY5MTFhMD4g VW5zdHJ1bmcgRm91bnRhaW4gQ0EwHhcNMTcxMTA3MjM0NTI4WhcNMTkxMTA3MjM0 NTI4WjBDMRIwEAYKCZImiZPyLGQBGRYCY2ExGTAXBgoJkiaJk/IsZAEZFglzYW5k ZWxtYW4xEjAQBgNVBAMMCWxvY2FsaG9zdDBZMBMGByqGSM49AgEGCCqGSM49AwEH A0IABJZlUHI0up/l3eZf9vCBb+lInoEMEgc7Ro+XZCtjAI0CD1fJfJR/hIyyDmHW yYiNFbRCH9fyarfkzgX4p0zTizqjDTALMAkGA1UdEwQCMAAwCgYIKoZIzj0EAwMD aQAwZgIxALQMNurf8tv50lROD5DQXHEOJJNW3QV2g9QEdDSk2MY+AoSrBSmGSNjh 4olEOhEuLgIxAJ4nWfNw+BjbZmKiIiUEcTwHMhGVXaMHY/F7n39wwKcBBSOndNPq CpOELl6bq3CZqTCCAmkwggHvoAMCAQICAQMwCgYIKoZIzj0EAwIwbTESMBAGCgmS JomT8ixkARkWAmNhMRkwFwYKCZImiZPyLGQBGRYJc2FuZGVsbWFuMTwwOgYDVQQD DDNmb3VudGFpbi10ZXN0LmV4YW1wbGUuY29tIFVuc3RydW5nIEZvdW50YWluIFJv b3QgQ0EwHhcNMTkwMTEzMjI1NDQ0WhcNMjEwMTEyMjI1NDQ0WjBtMRIwEAYKCZIm iZPyLGQBGRYCY2ExGTAXBgoJkiaJk/IsZAEZFglzYW5kZWxtYW4xPDA6BgNVBAMM M2ZvdW50YWluLXRlc3QuZXhhbXBsZS5jb20gVW5zdHJ1bmcgRm91bnRhaW4gUm9v dCBDQTB2MBAGByqGSM49AgEGBSuBBAAiA2IABBt/WboXwxq8Zo2MbODD+jFxD2X2 IpG9t1aAB9vfuHqlRU15ikaXGVmWMbGPaX0yvjzIPltjtUb2qNVvm/nA89O5FD9y R1Gkdt3S8L/1yo8wAX/4wl/T9SADRIuL8gdstKNjMGEwDwYDVR0TAQH/BAUwAwEB /zAOBgNVHQ8BAf8EBAMCAQYwHQYDVR0OBBYEFLml9ssR4QekSSynCMZ8ELyHs3Qm MB8GA1UdIwQYMBaAFLml9ssR4QekSSynCMZ8ELyHs3QmMAoGCCqGSM49BAMCA2gA MGUCMAviLdbfd6AZdsOxNgf7D15WFmGC1JkHeEbT/0w4UXz6q/48S71/IMbSXRWH aNxiJwIxAOCRjtlN+VSmCLTvWwMTxnSpIuqMr/O1y2Z8rl459VRFphWPdbf4i0qE cwu0u4JzpDGCAUwwggFIAgEBMHYwcTESMBAGCgmSJomT8ixkARkWAmNhMRkwFwYK CZImiZPyLGQBGRYJc2FuZGVsbWFuMUAwPgYDVQQDDDcjPFN5c3RlbVZhcmlhYmxl OjB4MDAwMDAwMDRmOTExYTA+IFVuc3RydW5nIEZvdW50YWluIENBAgECMAsGCWCG SAFlAwQCAaBpMBgGCSqGSIb3DQEJAzELBgkqhkiG9w0BBwEwHAYJKoZIhvcNAQkF MQ8XDTE5MDUxNTIxMjU1NVowLwYJKoZIhvcNAQkEMSIEIFBQjMmWzZOEkRHXrVAS snJwgQ26goyvOAtUFYs3MstMMAoGCCqGSM49BAMCBEcwRQIgBthbhEmgbqZbYDkD zxHXLzJ5eusWplzHKqZyxNpzaR8CIQC3UtMu0QsXoUpYL016iTsbd7Eedi8IfnwQ akExfhh0ew== -----END CMS-----
As described in Section 5.5 the registrar will sign a registrar voucher-request, and will include pledge's voucher request in the prior-signed-voucher-request.
file: examples/parboiled_vr_00_D0-E5-02-00-2D.pkcs
0:d=0 hl=4 l=3987 cons: SEQUENCE
4:d=1 hl=2 l= 9 prim: OBJECT :pkcs7-signedData
15:d=1 hl=4 l=3972 cons: cont [ 0 ]
19:d=2 hl=4 l=3968 cons: SEQUENCE
23:d=3 hl=2 l= 1 prim: INTEGER :01
26:d=3 hl=2 l= 13 cons: SET
28:d=4 hl=2 l= 11 cons: SEQUENCE
30:d=5 hl=2 l= 9 prim: OBJECT :sha256
41:d=3 hl=4 l=2516 cons: SEQUENCE
45:d=4 hl=2 l= 9 prim: OBJECT :pkcs7-data
56:d=4 hl=4 l=2501 cons: cont [ 0 ]
60:d=5 hl=4 l=2497 prim: OCTET STRING :{"ietf-voucher-request:v
2561:d=3 hl=4 l=1090 cons: cont [ 0 ]
2565:d=4 hl=4 l= 465 cons: SEQUENCE
2569:d=5 hl=4 l= 342 cons: SEQUENCE
2573:d=6 hl=2 l= 3 cons: cont [ 0 ]
2575:d=7 hl=2 l= 1 prim: INTEGER :02
2578:d=6 hl=2 l= 1 prim: INTEGER :02
2581:d=6 hl=2 l= 10 cons: SEQUENCE
2583:d=7 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA384
2593:d=6 hl=2 l= 113 cons: SEQUENCE
2595:d=7 hl=2 l= 18 cons: SET
2597:d=8 hl=2 l= 16 cons: SEQUENCE
2599:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
2611:d=9 hl=2 l= 2 prim: IA5STRING :ca
2615:d=7 hl=2 l= 25 cons: SET
2617:d=8 hl=2 l= 23 cons: SEQUENCE
2619:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
2631:d=9 hl=2 l= 9 prim: IA5STRING :sandelman
2642:d=7 hl=2 l= 64 cons: SET
2644:d=8 hl=2 l= 62 cons: SEQUENCE
2646:d=9 hl=2 l= 3 prim: OBJECT :commonName
2651:d=9 hl=2 l= 55 prim: UTF8STRING :#<SystemVariable:0x00000
2708:d=6 hl=2 l= 30 cons: SEQUENCE
2710:d=7 hl=2 l= 13 prim: UTCTIME :171107234528Z
2725:d=7 hl=2 l= 13 prim: UTCTIME :191107234528Z
2740:d=6 hl=2 l= 67 cons: SEQUENCE
2742:d=7 hl=2 l= 18 cons: SET
2744:d=8 hl=2 l= 16 cons: SEQUENCE
2746:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
2758:d=9 hl=2 l= 2 prim: IA5STRING :ca
2762:d=7 hl=2 l= 25 cons: SET
2764:d=8 hl=2 l= 23 cons: SEQUENCE
2766:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
2778:d=9 hl=2 l= 9 prim: IA5STRING :sandelman
2789:d=7 hl=2 l= 18 cons: SET
2791:d=8 hl=2 l= 16 cons: SEQUENCE
2793:d=9 hl=2 l= 3 prim: OBJECT :commonName
2798:d=9 hl=2 l= 9 prim: UTF8STRING :localhost
2809:d=6 hl=2 l= 89 cons: SEQUENCE
2811:d=7 hl=2 l= 19 cons: SEQUENCE
2813:d=8 hl=2 l= 7 prim: OBJECT :id-ecPublicKey
2822:d=8 hl=2 l= 8 prim: OBJECT :prime256v1
2832:d=7 hl=2 l= 66 prim: BIT STRING
2900:d=6 hl=2 l= 13 cons: cont [ 3 ]
2902:d=7 hl=2 l= 11 cons: SEQUENCE
2904:d=8 hl=2 l= 9 cons: SEQUENCE
2906:d=9 hl=2 l= 3 prim: OBJECT :X509v3 Basic Constraints
2911:d=9 hl=2 l= 2 prim: OCTET STRING [HEX DUMP]:3000
2915:d=5 hl=2 l= 10 cons: SEQUENCE
2917:d=6 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA384
2927:d=5 hl=2 l= 105 prim: BIT STRING
3034:d=4 hl=4 l= 617 cons: SEQUENCE
3038:d=5 hl=4 l= 495 cons: SEQUENCE
3042:d=6 hl=2 l= 3 cons: cont [ 0 ]
3044:d=7 hl=2 l= 1 prim: INTEGER :02
3047:d=6 hl=2 l= 1 prim: INTEGER :03
3050:d=6 hl=2 l= 10 cons: SEQUENCE
3052:d=7 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA256
3062:d=6 hl=2 l= 109 cons: SEQUENCE
3064:d=7 hl=2 l= 18 cons: SET
3066:d=8 hl=2 l= 16 cons: SEQUENCE
3068:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
3080:d=9 hl=2 l= 2 prim: IA5STRING :ca
3084:d=7 hl=2 l= 25 cons: SET
3086:d=8 hl=2 l= 23 cons: SEQUENCE
3088:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
3100:d=9 hl=2 l= 9 prim: IA5STRING :sandelman
3111:d=7 hl=2 l= 60 cons: SET
3113:d=8 hl=2 l= 58 cons: SEQUENCE
3115:d=9 hl=2 l= 3 prim: OBJECT :commonName
3120:d=9 hl=2 l= 51 prim: UTF8STRING :fountain-test.example.co
3173:d=6 hl=2 l= 30 cons: SEQUENCE
3175:d=7 hl=2 l= 13 prim: UTCTIME :190113225444Z
3190:d=7 hl=2 l= 13 prim: UTCTIME :210112225444Z
3205:d=6 hl=2 l= 109 cons: SEQUENCE
3207:d=7 hl=2 l= 18 cons: SET
3209:d=8 hl=2 l= 16 cons: SEQUENCE
3211:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
3223:d=9 hl=2 l= 2 prim: IA5STRING :ca
3227:d=7 hl=2 l= 25 cons: SET
3229:d=8 hl=2 l= 23 cons: SEQUENCE
3231:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
3243:d=9 hl=2 l= 9 prim: IA5STRING :sandelman
3254:d=7 hl=2 l= 60 cons: SET
3256:d=8 hl=2 l= 58 cons: SEQUENCE
3258:d=9 hl=2 l= 3 prim: OBJECT :commonName
3263:d=9 hl=2 l= 51 prim: UTF8STRING :fountain-test.example.co
3316:d=6 hl=2 l= 118 cons: SEQUENCE
3318:d=7 hl=2 l= 16 cons: SEQUENCE
3320:d=8 hl=2 l= 7 prim: OBJECT :id-ecPublicKey
3329:d=8 hl=2 l= 5 prim: OBJECT :secp384r1
3336:d=7 hl=2 l= 98 prim: BIT STRING
3436:d=6 hl=2 l= 99 cons: cont [ 3 ]
3438:d=7 hl=2 l= 97 cons: SEQUENCE
3440:d=8 hl=2 l= 15 cons: SEQUENCE
3442:d=9 hl=2 l= 3 prim: OBJECT :X509v3 Basic Constraints
3447:d=9 hl=2 l= 1 prim: BOOLEAN :255
3450:d=9 hl=2 l= 5 prim: OCTET STRING [HEX DUMP]:30030101FF
3457:d=8 hl=2 l= 14 cons: SEQUENCE
3459:d=9 hl=2 l= 3 prim: OBJECT :X509v3 Key Usage
3464:d=9 hl=2 l= 1 prim: BOOLEAN :255
3467:d=9 hl=2 l= 4 prim: OCTET STRING [HEX DUMP]:03020106
3473:d=8 hl=2 l= 29 cons: SEQUENCE
3475:d=9 hl=2 l= 3 prim: OBJECT :X509v3 Subject Key Ident
3480:d=9 hl=2 l= 22 prim: OCTET STRING [HEX DUMP]:0414B9A5F6CB11
3504:d=8 hl=2 l= 31 cons: SEQUENCE
3506:d=9 hl=2 l= 3 prim: OBJECT :X509v3 Authority Key Ide
3511:d=9 hl=2 l= 24 prim: OCTET STRING [HEX DUMP]:30168014B9A5F6
3537:d=5 hl=2 l= 10 cons: SEQUENCE
3539:d=6 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA256
3549:d=5 hl=2 l= 104 prim: BIT STRING
3655:d=3 hl=4 l= 332 cons: SET
3659:d=4 hl=4 l= 328 cons: SEQUENCE
3663:d=5 hl=2 l= 1 prim: INTEGER :01
3666:d=5 hl=2 l= 118 cons: SEQUENCE
3668:d=6 hl=2 l= 113 cons: SEQUENCE
3670:d=7 hl=2 l= 18 cons: SET
3672:d=8 hl=2 l= 16 cons: SEQUENCE
3674:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
3686:d=9 hl=2 l= 2 prim: IA5STRING :ca
3690:d=7 hl=2 l= 25 cons: SET
3692:d=8 hl=2 l= 23 cons: SEQUENCE
3694:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
3706:d=9 hl=2 l= 9 prim: IA5STRING :sandelman
3717:d=7 hl=2 l= 64 cons: SET
3719:d=8 hl=2 l= 62 cons: SEQUENCE
3721:d=9 hl=2 l= 3 prim: OBJECT :commonName
3726:d=9 hl=2 l= 55 prim: UTF8STRING :#<SystemVariable:0x00000
3783:d=6 hl=2 l= 1 prim: INTEGER :02
3786:d=5 hl=2 l= 11 cons: SEQUENCE
3788:d=6 hl=2 l= 9 prim: OBJECT :sha256
3799:d=5 hl=2 l= 105 cons: cont [ 0 ]
3801:d=6 hl=2 l= 24 cons: SEQUENCE
3803:d=7 hl=2 l= 9 prim: OBJECT :contentType
3814:d=7 hl=2 l= 11 cons: SET
3816:d=8 hl=2 l= 9 prim: OBJECT :pkcs7-data
3827:d=6 hl=2 l= 28 cons: SEQUENCE
3829:d=7 hl=2 l= 9 prim: OBJECT :signingTime
3840:d=7 hl=2 l= 15 cons: SET
3842:d=8 hl=2 l= 13 prim: UTCTIME :190515212555Z
3857:d=6 hl=2 l= 47 cons: SEQUENCE
3859:d=7 hl=2 l= 9 prim: OBJECT :messageDigest
3870:d=7 hl=2 l= 34 cons: SET
3872:d=8 hl=2 l= 32 prim: OCTET STRING [HEX DUMP]:50508CC996CD93
3906:d=5 hl=2 l= 10 cons: SEQUENCE
3908:d=6 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA256
3918:d=5 hl=2 l= 71 prim: OCTET STRING [HEX DUMP]:3045022006D85B
-----BEGIN CMS----- MIIGsgYJKoZIhvcNAQcCoIIGozCCBp8CAQExDTALBglghkgBZQMEAgEwggNABgkq hkiG9w0BBwGgggMxBIIDLXsiaWV0Zi12b3VjaGVyOnZvdWNoZXIiOnsiYXNzZXJ0 aW9uIjoibG9nZ2VkIiwiY3JlYXRlZC1vbiI6IjIwMTktMDUtMTZUMDI6NTE6NDIu Njk3KzAwOjAwIiwic2VyaWFsLW51bWJlciI6IjAwLWQwLWU1LTAyLTAwLTJkIiwi bm9uY2UiOiJHWmUtT2pvZXJwS0VNNFNNN1N6UzlnIiwicGlubmVkLWRvbWFpbi1j ZXJ0IjoiTUlJQjBUQ0NBVmFnQXdJQkFnSUJBakFLQmdncWhrak9QUVFEQXpCeE1S SXdFQVlLQ1pJbWlaUHlMR1FCR1JZQ1kyRXhHVEFYQmdvSmtpYUprL0lzWkFFWkZn bHpZVzVrWld4dFlXNHhRREErQmdOVkJBTU1OeU04VTNsemRHVnRWbUZ5YVdGaWJH VTZNSGd3TURBd01EQXdOR1k1TVRGaE1ENGdWVzV6ZEhKMWJtY2dSbTkxYm5SaGFX NGdRMEV3SGhjTk1UY3hNVEEzTWpNME5USTRXaGNOTVRreE1UQTNNak0wTlRJNFdq QkRNUkl3RUFZS0NaSW1pWlB5TEdRQkdSWUNZMkV4R1RBWEJnb0praWFKay9Jc1pB RVpGZ2x6WVc1a1pXeHRZVzR4RWpBUUJnTlZCQU1NQ1d4dlkyRnNhRzl6ZERCWk1C TUdCeXFHU000OUFnRUdDQ3FHU000OUF3RUhBMElBQkpabFVISTB1cC9sM2VaZjl2 Q0JiK2xJbm9FTUVnYzdSbytYWkN0akFJMENEMWZKZkpSL2hJeXlEbUhXeVlpTkZi UkNIOWZ5YXJma3pnWDRwMHpUaXpxakRUQUxNQWtHQTFVZEV3UUNNQUF3Q2dZSUtv Wkl6ajBFQXdNRGFRQXdaZ0l4QUxRTU51cmY4dHY1MGxST0Q1RFFYSEVPSkpOVzNR VjJnOVFFZERTazJNWStBb1NyQlNtR1NOamg0b2xFT2hFdUxnSXhBSjRuV2ZOdytC amJabUtpSWlVRWNUd0hNaEdWWGFNSFkvRjduMzl3d0tjQkJTT25kTlBxQ3BPRUxs NmJxM0NacVE9PSJ9faCCAfUwggHxMIIBeKADAgECAgQjzIkTMAoGCCqGSM49BAMC ME0xEjAQBgoJkiaJk/IsZAEZFgJjYTEZMBcGCgmSJomT8ixkARkWCXNhbmRlbG1h bjEcMBoGA1UEAwwTVW5zdHJ1bmcgSGlnaHdheSBDQTAeFw0xOTA0MjMyMzIxMDda Fw0xOTA1MjQwOTIxMDdaMGYxDzANBgNVBAYTBkNhbmFkYTESMBAGA1UECgwJU2Fu ZGVsbWFuMRMwEQYDVQQLDApob25leWR1a2VzMSowKAYDVQQDDCFtYXNhLmhvbmV5 ZHVrZXMuc2FuZGVsbWFuLmNhIE1BU0EwdjAQBgcqhkjOPQIBBgUrgQQAIgNiAAQ1 /2UdVp8zVmgADoBNql7LcPlJsEaaVAogYEqABikNOkoTO3oPjIQfNBxtGfRFzBXx gihzkTH58r8SW1L/Mej8AFqhB4SZyyjmWURdzD71Ju0M+tRritWf7T+QGaE+fcWj EDAOMAwGA1UdEwEB/wQCMAAwCgYIKoZIzj0EAwIDZwAwZAIwOMlNOMNYEZo4yLW4 iRltDL8uirmjMdtVmmVYzqYHSindjP0a3pXQkQZ5LLARoSRWAjBTxsnv6ya5HpZI IWcspDPZGlOSDPm7nuRJSDkgWqevxLI4+9nmIhsfMBsDvz1DJhAxggFMMIIBSAIB ATBVME0xEjAQBgoJkiaJk/IsZAEZFgJjYTEZMBcGCgmSJomT8ixkARkWCXNhbmRl bG1hbjEcMBoGA1UEAwwTVW5zdHJ1bmcgSGlnaHdheSBDQQIEI8yJEzALBglghkgB ZQMEAgGgaTAYBgkqhkiG9w0BCQMxCwYJKoZIhvcNAQcBMBwGCSqGSIb3DQEJBTEP Fw0xOTA1MTYwMjUxNDJaMC8GCSqGSIb3DQEJBDEiBCCYRh4i21QjEjEk8leRLSVA x/EVY5g1bM40QM21oR4c2DAKBggqhkjOPQQDAgRoMGYCMQCYYOiSbIlED4nAN0iL e4S8ixWAZ9SXpGv77bB/G4fTTVTN35mnAeYBfeNfhC6/kOECMQDqlkCmwQJQDdEL asj1ISinJ/FnZjjgOMz9MXOmGNGIfw9v2VBb9mVyhsOSMcqlVig= -----END CMS-----
The MASA will return a voucher to the registrar, to be relayed to the pledge.
file: examples/voucher_00-D0-E5-02-00-2D.pkcs
0:d=0 hl=4 l=1714 cons: SEQUENCE
4:d=1 hl=2 l= 9 prim: OBJECT :pkcs7-signedData
15:d=1 hl=4 l=1699 cons: cont [ 0 ]
19:d=2 hl=4 l=1695 cons: SEQUENCE
23:d=3 hl=2 l= 1 prim: INTEGER :01
26:d=3 hl=2 l= 13 cons: SET
28:d=4 hl=2 l= 11 cons: SEQUENCE
30:d=5 hl=2 l= 9 prim: OBJECT :sha256
41:d=3 hl=4 l= 832 cons: SEQUENCE
45:d=4 hl=2 l= 9 prim: OBJECT :pkcs7-data
56:d=4 hl=4 l= 817 cons: cont [ 0 ]
60:d=5 hl=4 l= 813 prim: OCTET STRING :{"ietf-voucher:voucher":
877:d=3 hl=4 l= 501 cons: cont [ 0 ]
881:d=4 hl=4 l= 497 cons: SEQUENCE
885:d=5 hl=4 l= 376 cons: SEQUENCE
889:d=6 hl=2 l= 3 cons: cont [ 0 ]
891:d=7 hl=2 l= 1 prim: INTEGER :02
894:d=6 hl=2 l= 4 prim: INTEGER :23CC8913
900:d=6 hl=2 l= 10 cons: SEQUENCE
902:d=7 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA256
912:d=6 hl=2 l= 77 cons: SEQUENCE
914:d=7 hl=2 l= 18 cons: SET
916:d=8 hl=2 l= 16 cons: SEQUENCE
918:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
930:d=9 hl=2 l= 2 prim: IA5STRING :ca
934:d=7 hl=2 l= 25 cons: SET
936:d=8 hl=2 l= 23 cons: SEQUENCE
938:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
950:d=9 hl=2 l= 9 prim: IA5STRING :sandelman
961:d=7 hl=2 l= 28 cons: SET
963:d=8 hl=2 l= 26 cons: SEQUENCE
965:d=9 hl=2 l= 3 prim: OBJECT :commonName
970:d=9 hl=2 l= 19 prim: UTF8STRING :Unstrung Highway CA
991:d=6 hl=2 l= 30 cons: SEQUENCE
993:d=7 hl=2 l= 13 prim: UTCTIME :190423232107Z
1008:d=7 hl=2 l= 13 prim: UTCTIME :190524092107Z
1023:d=6 hl=2 l= 102 cons: SEQUENCE
1025:d=7 hl=2 l= 15 cons: SET
1027:d=8 hl=2 l= 13 cons: SEQUENCE
1029:d=9 hl=2 l= 3 prim: OBJECT :countryName
1034:d=9 hl=2 l= 6 prim: PRINTABLESTRING :Canada
1042:d=7 hl=2 l= 18 cons: SET
1044:d=8 hl=2 l= 16 cons: SEQUENCE
1046:d=9 hl=2 l= 3 prim: OBJECT :organizationName
1051:d=9 hl=2 l= 9 prim: UTF8STRING :Sandelman
1062:d=7 hl=2 l= 19 cons: SET
1064:d=8 hl=2 l= 17 cons: SEQUENCE
1066:d=9 hl=2 l= 3 prim: OBJECT :organizationalUnitName
1071:d=9 hl=2 l= 10 prim: UTF8STRING :honeydukes
1083:d=7 hl=2 l= 42 cons: SET
1085:d=8 hl=2 l= 40 cons: SEQUENCE
1087:d=9 hl=2 l= 3 prim: OBJECT :commonName
1092:d=9 hl=2 l= 33 prim: UTF8STRING :masa.honeydukes.sandelma
1127:d=6 hl=2 l= 118 cons: SEQUENCE
1129:d=7 hl=2 l= 16 cons: SEQUENCE
1131:d=8 hl=2 l= 7 prim: OBJECT :id-ecPublicKey
1140:d=8 hl=2 l= 5 prim: OBJECT :secp384r1
1147:d=7 hl=2 l= 98 prim: BIT STRING
1247:d=6 hl=2 l= 16 cons: cont [ 3 ]
1249:d=7 hl=2 l= 14 cons: SEQUENCE
1251:d=8 hl=2 l= 12 cons: SEQUENCE
1253:d=9 hl=2 l= 3 prim: OBJECT :X509v3 Basic Constraints
1258:d=9 hl=2 l= 1 prim: BOOLEAN :255
1261:d=9 hl=2 l= 2 prim: OCTET STRING [HEX DUMP]:3000
1265:d=5 hl=2 l= 10 cons: SEQUENCE
1267:d=6 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA256
1277:d=5 hl=2 l= 103 prim: BIT STRING
1382:d=3 hl=4 l= 332 cons: SET
1386:d=4 hl=4 l= 328 cons: SEQUENCE
1390:d=5 hl=2 l= 1 prim: INTEGER :01
1393:d=5 hl=2 l= 85 cons: SEQUENCE
1395:d=6 hl=2 l= 77 cons: SEQUENCE
1397:d=7 hl=2 l= 18 cons: SET
1399:d=8 hl=2 l= 16 cons: SEQUENCE
1401:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
1413:d=9 hl=2 l= 2 prim: IA5STRING :ca
1417:d=7 hl=2 l= 25 cons: SET
1419:d=8 hl=2 l= 23 cons: SEQUENCE
1421:d=9 hl=2 l= 10 prim: OBJECT :domainComponent
1433:d=9 hl=2 l= 9 prim: IA5STRING :sandelman
1444:d=7 hl=2 l= 28 cons: SET
1446:d=8 hl=2 l= 26 cons: SEQUENCE
1448:d=9 hl=2 l= 3 prim: OBJECT :commonName
1453:d=9 hl=2 l= 19 prim: UTF8STRING :Unstrung Highway CA
1474:d=6 hl=2 l= 4 prim: INTEGER :23CC8913
1480:d=5 hl=2 l= 11 cons: SEQUENCE
1482:d=6 hl=2 l= 9 prim: OBJECT :sha256
1493:d=5 hl=2 l= 105 cons: cont [ 0 ]
1495:d=6 hl=2 l= 24 cons: SEQUENCE
1497:d=7 hl=2 l= 9 prim: OBJECT :contentType
1508:d=7 hl=2 l= 11 cons: SET
1510:d=8 hl=2 l= 9 prim: OBJECT :pkcs7-data
1521:d=6 hl=2 l= 28 cons: SEQUENCE
1523:d=7 hl=2 l= 9 prim: OBJECT :signingTime
1534:d=7 hl=2 l= 15 cons: SET
1536:d=8 hl=2 l= 13 prim: UTCTIME :190516025142Z
1551:d=6 hl=2 l= 47 cons: SEQUENCE
1553:d=7 hl=2 l= 9 prim: OBJECT :messageDigest
1564:d=7 hl=2 l= 34 cons: SET
1566:d=8 hl=2 l= 32 prim: OCTET STRING [HEX DUMP]:98461E22DB5423
1600:d=5 hl=2 l= 10 cons: SEQUENCE
1602:d=6 hl=2 l= 8 prim: OBJECT :ecdsa-with-SHA256
1612:d=5 hl=2 l= 104 prim: OCTET STRING [HEX DUMP]:30660231009860