Internet-Draft | CoRIM | July 2022 |
Birkholz, et al. | Expires 12 January 2023 | [Page] |
Remote Attestation Procedures (RATS) enable Relying Parties to assess the trustworthiness of a remote Attester and therefore to decide whether to engage in secure interactions with it. Evidence about trustworthiness can be rather complex and it is deemed unrealistic that every Relying Party is capable of the appraisal of Evidence. Therefore that burden is typically offloaded to a Verifier. In order to conduct Evidence appraisal, a Verifier requires not only fresh Evidence from an Attester, but also trusted Endorsements and Reference Values from Endorsers and Reference Value Providers, such as manufacturers, distributors, or device owners. This document specifies Concise Reference Integrity Manifests (CoRIM) that represent Endorsements and Reference Values in CBOR format. Composite devices or systems are represented by a collection of Concise Module Identifiers (CoMID) and Concise Software Identifiers (CoSWID) bundled in a CoRIM document.¶
This note is to be removed before publishing as an RFC.¶
Discussion of this document takes place on the RATS Working Group mailing list (rats@ietf.org), which is archived at https://mailarchive.ietf.org/arch/browse/rats/.¶
Source for this draft and an issue tracker can be found at https://github.com/ietf-rats/draft-birkholz-rats-corim.¶
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 12 January 2023.¶
Copyright (c) 2022 IETF Trust and the persons identified as the document authors. All rights reserved.¶
This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Revised BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Revised BSD License.¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/86¶
This document uses terms and concepts defined by the RATS architecture. For a complete glossary see Section 4 of [I-D.ietf-rats-architecture].¶
The terminology from CBOR [STD94], CDDL [RFC8610] and COSE [RFC8152] applies; in particular, CBOR diagnostic notation is defined in Section 8 of [STD94] and Appendix G of [RFC8610].¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
The CDDL definitions in this document follow the naming conventions illustrated in Table 1.¶
Type trait | Example | Typographical convention |
---|---|---|
extensible type choice |
int / text / ...
|
$ NAME-type-choice
|
closed type choice |
int / text
|
NAME-type-choice
|
group choice |
( 1 => int // 2 => text )
|
$$ NAME-group-choice
|
group |
( 1 => int, 2 => text )
|
NAME-group
|
type |
int
|
NAME-type
|
tagged type |
#6.123(int)
|
tagged- NAME-type
|
map |
{ 1 => int, 2 => text }
|
NAME-map
|
flags |
&( a: 1, b: 2 )
|
NAME-flags
|
The following CDDL types are used in both CoRIM and CoMID.¶
The non-empty
generic type is used to express that a map with only optional
members MUST at least include one of the members.¶
non-empty<M> = (M) .and ({ + any => any })¶
The entity-map
is a generic type describing an organization responsible for
the contents of a manifest. It is instantiated by supplying two parameters:¶
role-type-choice
, i.e., a selection of roles that entities of the
instantiated type can claim¶
extension-socket
, i.e., a CDDL socket that can be used to extend
the attributes associated with entities of the instantiated type¶
entity-map<role-type-choice, extension-socket> = { &(entity-name: 0) => $entity-name-type-choice ? &(reg-id: 1) => uri &(role: 2) => [ + role-type-choice ] * extension-socket } $entity-name-type-choice /= text¶
The following describes each member of the entity-map
.¶
entity-name
(index 0): The name of entity which is responsible for the
action(s) as defined by the role. $entity-name-type-choice
can only be
Other specifications can extend the $entity-name-type-choice
(see
Section 6.4).¶
reg-id
(index 1): A URI associated with the organization that owns the
entity name¶
role
(index 2): A type choice defining the roles that the entity is
claiming. The role is supplied as a parameter at the time the entity-map
generic is instantiated.¶
extension-socket
: A CDDL socket used to add new information structures to
the entity-map
.¶
Examples of how the entity-map
generic is instantiated can be found in
Section 2.1.5 and Section 3.1.2.¶
A validity-map
represents the time interval during which the signer
warrants that it will maintain information about the status of the signed
object (e.g., a manifest).¶
In a validity-map
, both ends of the interval are encoded as epoch-based
date/time as per Section 3.4.2 of [STD94].¶
validity-map = { ? &(not-before: 0) => time &(not-after: 1) => time }¶
Used to tag a byte string as a binary UUID defined in Section 4.1.2. of [RFC4122].¶
uuid-type = bytes .size 16 tagged-uuid-type = #6.37(uuid-type)¶
Used to tag a byte string as Universal Entity ID Claim (UUID) defined in Section 4.2.1 of [I-D.ietf-rats-eat].¶
ueid-type = bytes .size 33 tagged-ueid-type = #6.550(ueid-type)¶
Used to tag a byte string as the BER encoding [X.690] of an absolute object identifier [RFC9090].¶
oid-type = bytes tagged-oid-type = #6.111(oid-type)¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/87¶
tagged-int-type = #6.551(int)¶
A hash entry represents the value of a hashing operation together with the hash algorithm used. Defined in Section 2.9.1 of [I-D.ietf-sacm-coswid]. The CDDL is copied below for convenience.¶
hash-entry = [ hash-alg-id: int hash-value: bytes ]¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/98¶
At the top-level, a CoRIM can either be a CBOR-tagged corim-map
(Section 2.1) or a COSE signed corim-map
(Section 2.2).¶
corim = #6.500(concise-rim-type-choice) $concise-rim-type-choice /= #6.501(corim-map) $concise-rim-type-choice /= #6.502(signed-corim)¶
The CDDL specification for the corim-map
is as follows and this rule and its
constraints must be followed when creating or validating a CoRIM map.¶
corim-map = { &(id: 0) => $corim-id-type-choice &(tags: 1) => [ + $concise-tag-type-choice ] ? &(dependent-rims: 2) => [ + corim-locator-map ] ? &(profile: 3) => [ + profile-type-choice ] ? &(rim-validity: 4) => validity-map ? &(entities: 5) => [ + corim-entity-map ] * $$corim-map-extension }¶
The following describes each child item of this map.¶
id
(index 0): A globally unique identifier to identify a CoRIM. Described
in Section 2.1.1¶
tags
(index 1): An array of one or more CoMID or CoSWID tags. Described
in Section 2.1.2¶
dependent-rims
(index 2): One or more services supplying additional,
possibly dependent, manifests or related files. Described in
Section 2.1.3¶
profile
(index 3): One or more unique identifiers for the profiles of the
tags contained in this CoRIM. All the listed profiles MUST be understood.
Failure to recognize a profile identifier MUST result in the rejection of the
entire processing. Described in Section 2.1.4¶
rim-validity
(index 4): Specifies the validity period of the CoRIM.
Described in Section 1.3.3¶
entities
(index 5): A list of entities involved in a CoRIM life-cycle.
Described in Section 2.1.5¶
$$corim-map-extension
: This CDDL socket is used to add new information
structures to the corim-map
. See Section 6.3.¶
A CoRIM id can be either a text string or a UUID type that uniquely identifies a CoRIM.¶
$corim-id-type-choice /= tstr $corim-id-type-choice /= uuid-type¶
The locator map contains pointers to repositories where dependent manifests, certificates, or other relevant information can be retrieved by the Verifier.¶
corim-locator-map = { &(href: 0) => uri ? &(thumbprint: 1) => hash-entry }¶
The following describes each child element of this type.¶
href
(index 0): URI identifying the additional resource that can be fetched¶
thumbprint
(index 1): expected digest of the resource referenced by href
.
See Section 1.3.8.¶
A profile specifies which of the optional parts of a CoRIM are required, which are prohibited and which extension points are exercised and how.¶
profile-type-choice = uri / tagged-oid-type¶
The CoRIM Entity is an instantiation of the Entity generic
(Section 1.3.2) using a $corim-role-type-choice
.¶
The only role defined in this specification for a CoRIM Entity is
manifest-creator
.¶
The $$corim-entity-map-extension
extension socket is empty in this
specification.¶
corim-entity-map = entity-map<$corim-role-type-choice, $$corim-entity-map-extension> $corim-role-type-choice /= &(manifest-creator: 1)¶
Signing a CoRIM follows the procedures defined in CBOR Object Signing and Encryption [RFC8152]. A CoRIM tag MUST be wrapped in a COSE_Sign1 structure. The CoRIM MUST be signed by the CoRIM creator.¶
The following CDDL specification defines a restrictive subset of COSE header
parameters that MUST be used in the protected header alongside additional
information about the CoRIM encoded in a corim-meta-map
(Section 2.2.2).¶
COSE-Sign1-corim = [ protected: bstr .cbor protected-corim-header-map unprotected: unprotected-corim-header-map payload: bstr .cbor tagged-corim-map signature: bstr ]¶
The following describes each child element of this type.¶
protected
: A CBOR Encoded protected header which is protected by the COSE
signature. Contains information as given by Protected Header Map below.¶
unprotected
: A COSE header that is not protected by COSE signature.¶
payload
: A CBOR encoded tagged CoRIM.¶
signature
: A COSE signature block which is the signature over the protected
and payload components of the signed CoRIM.¶
protected-corim-header-map = { &(alg-id: 1) => int &(content-type: 3) => "application/corim-unsigned+cbor" &(issuer-key-id: 4) => bstr &(corim-meta: 8) => bstr .cbor corim-meta-map * cose-label => cose-value }¶
The following describes each child item of this map.¶
alg-id
(index 1): An integer that identifies a signature algorithm.¶
content-type
(index 3): A string that represents the "MIME Content type"
carried in the CoRIM payload.¶
issuer-key-id
(index 4): A bit string which is a key identity pertaining to
the CoRIM Issuer.¶
corim-meta
(index 8): A map that contains metadata associated with a
signed CoRIM. Described in Section 2.2.2.¶
Additional data can be included in the COSE header map as per Section 3 of [RFC8152].¶
The CoRIM meta map identifies the entity or entities that create and sign the CoRIM. This ensures the consumer is able to identify credentials used to authenticate its signer.¶
corim-meta-map = { &(signer: 0) => corim-signer-map ? &(signature-validity: 1) => validity-map }¶
The following describes each child item of this group.¶
signer
(index 0): Information about the entity that signs the CoRIM.
Described in Section 2.2.2.1¶
signature-validity
(index 1): Validity period for the CoRIM. Described in
Section 1.3.3¶
corim-signer-map = { &(signer-name: 0) => $entity-name-type-choice ? &(signer-uri: 1) => uri * $$corim-signer-map-extension }¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/88¶
The CDDL specification for the concise-mid-tag
map is as follows and this
rule and its constraints MUST be followed when creating or validating a CoMID
tag:¶
concise-mid-tag = { ? &(language: 0) => text &(tag-identity: 1) => tag-identity-map ? &(entities: 2) => [ + entity-map ] ? &(linked-tags: 3) => [ + linked-tag-map ] &(triples: 4) => triples-map * $$concise-mid-tag-extension }¶
The following describes each member of the concise-mid-tag
map.¶
lang
(index 0): A textual language tag that conforms with IANA "Language
Subtag Registry" [IANA.language-subtag-registry]. The context of the specified language
applies to all sibling and descendant textual values, unless a descendant
object has defined a different language tag. Thus, a new context is
established when a descendant object redefines a new language tag. All
textual values within a given context MUST be considered expressed in the
specified language.¶
tag-identity
(index 1): A tag-identity-map
containing unique
identification information for the CoMID. Described in Section 3.1.1.¶
entities
(index 2): Provides information about one or more organizations
responsible for producing the CoMID tag. Described in Section 3.1.2.¶
linked-tags
(index 3): A list of one or more linked-tag-map
(described in
Section 3.1.3), providing typed relationships between this and
other CoMIDs.¶
triples
(index 4): One or more triples providing information specific to
the described module, e.g.: reference or endorsed values, cryptographic
material, or structural relationship between the described module and other
modules. Described in (Section 3.1.4).¶
tag-identity-map = { &(tag-id: 0) => $tag-id-type-choice ? &(tag-version: 1) => tag-version-type }¶
The following describes each member of the tag-identity-map
.¶
tag-id
(index 0): A universally unique identifier for the CoMID. Described
in Section 3.1.1.1.¶
tag-version
(index 1): Optional versioning information for the tag-id
.
Described in Section 3.1.1.2.¶
$tag-id-type-choice /= tstr $tag-id-type-choice /= uuid-type¶
A Tag ID is either a 16-byte binary string, or a textual identifier, uniquely referencing the CoMID. The tag identifier MUST be globally unique. Failure to ensure global uniqueness can create ambiguity in tag use since the tag-id serves as the global key for matching, lookups and linking. If represented as a 16-byte binary string, the identifier MUST be a valid universally unique identifier as defined by [RFC4122]. There are no strict guidelines on how the identifier is structured, but examples include a 16-byte GUID (e.g., class 4 UUID) [RFC4122], or a URI [STD66].¶
tag-version-type = uint .default 0¶
Tag Version is an integer value that indicates the specific release revision of the tag. Typically, the initial value of this field is set to 0 and the value is increased for subsequent tags produced for the same module release. This value allows a CoMID tag producer to correct an incorrect tag previously released without indicating a change to the underlying module the tag represents. For example, the tag version could be changed to add new metadata, to correct a broken link, to add a missing reference value, etc. When producing a revised tag, the new tag-version value MUST be greater than the old tag-version value.¶
comid-entity-map = entity-map<$comid-role-type-choice, $$comid-entity-map-extension>¶
The CoMID Entity is an instantiation of the Entity generic
(Section 1.3.2) using a $comid-role-type-choice
.¶
The $$comid-entity-map-extension
extension socket is empty in this
specification.¶
$comid-role-type-choice /= &(tag-creator: 0) $comid-role-type-choice /= &(creator: 1) $comid-role-type-choice /= &(maintainer: 2)¶
The roles defined for a CoMID entity are:¶
The linked tag map represents a typed relationship between the embedding CoMID tag (the source) and another CoMID tag (the target).¶
linked-tag-map = { &(linked-tag-id: 0) => $tag-id-type-choice &(tag-rel: 1) => $tag-rel-type-choice }¶
The following describes each member of the tag-identity-map
.¶
linked-tag-id
(index 0): Unique identifier for the target tag. For the
definition see Section 3.1.1.1.¶
tag-rel
(index 1): the kind of relation linking the source tag to the
target identified by linked-tag-id
.¶
$tag-rel-type-choice /= &(supplements: 0) $tag-rel-type-choice /= &(replaces: 1)¶
The relations defined in this specification are:¶
The triples-map
contains all the CoMID triples broken down per category. Not
all category need to be present but at least one category MUST be present and
contain at least one entry.¶
triples-map = non-empty<{ ? &(reference-triples: 0) => [ + reference-triple-record ] ? &(endorsed-triples: 1) => [ + endorsed-triple-record ] ? &(identity-triples: 2) => [ + identity-triple-record ] ? &(attest-key-triples: 3) => [ + attest-key-triple-record ] ? &(dependency-triples: 4) => [ + domain-dependency-triple-record ] ? &(membership-triples: 5) => [ + domain-membership-triple-record ] ? &(coswid-triples: 6) => [ + coswid-triple-record ] * $$triples-map-extension }>¶
The following describes each member of the triples-map
:¶
reference-triples
(index 0): Triples containing reference values. Described
in Section 3.1.4.2.¶
endorsed-triples
(index 1): Triples containing endorsed values. Described
in Section 3.1.4.3.¶
identity-triples
(index 2): Triples containing identity credentials.
Described in Section 3.1.4.4.¶
attest-key-triples
(index 3): Triples containing verification keys
associated with attesting environments. Described in
Section 3.1.4.5.¶
dependency-triples
(index 4): Triples describing trust relationships
between domains. Described in Section 3.1.4.6.¶
membership-triples
(index 5): Triples describing topological relationships
between (sub-)modules. Described in Section 3.1.4.7.¶
coswid-triples
(index 6): Triples associating modules with existing CoSWID
tags. Described in Section 3.1.4.8.¶
An environment-map
may be used to represent a whole attester, an attesting
environment, or a target environment. The exact semantic depends on the
context (triple) in which the environment is used.¶
An environment is named after a class, instance or group identifier (or a combination thereof).¶
environment-map = non-empty<{ ? &(class: 0) => class-map ? &(instance: 1) => $instance-id-type-choice ? &(group: 2) => $group-id-type-choice }>¶
The following describes each member of the environment-map
:¶
class
(index 0): Contains "class" attributes associated with the module.
Described in Section 3.1.4.1.2.¶
instance
(index 1): Contains a unique identifier of a module's instance.
See Section 3.1.4.1.3.¶
group
(index 2): identifier for a group of instances, e.g., if an
anonymization scheme is used.¶
The Class name consists of class attributes that distinguish the class of environment from other classes. The class attributes include class-id, vendor, model, layer, and index. The CoMID author determines which attributes are needed.¶
class-map = non-empty<{ ? &(class-id: 0) => $class-id-type-choice ? &(vendor: 1) => tstr ? &(model: 2) => tstr ? &(layer: 3) => uint ? &(index: 4) => uint }> $class-id-type-choice /= tagged-oid-type $class-id-type-choice /= tagged-uuid-type $class-id-type-choice /= tagged-int-type¶
The following describes each member of the class-map
:¶
class-id
(index 0): Identifies the environment via a well-known identifier.
Typically, class-id
is an object identifier (OID) or universally unique
identifier (UUID). Use of this attribute is preferred.¶
vendor
(index 1): Identifies the entity responsible for choosing values for
the other class attributes that do not already have naming authority.¶
model
(index 2): Describes a product, generation, and family. If
populated, vendor MUST also be populated.¶
layer
(index 3): Is used to capture where in a sequence the environment
exists. For example, the order in which bootstrap code is executed may have
security relevance.¶
index
(index 4): Is used when there are clones (i.e., multiple instances)
of the same class of environment. Each clone is given a different index
value to disambiguate it from the other clones. For example, given a chassis
with several network interface controllers (NIC), each NIC can be given a
different index value.¶
An instance carries a unique identifier that is reliably bound to an instance of the attester.¶
The types defined for an instance identifier are UEID or UUID.¶
$instance-id-type-choice /= tagged-ueid-type $instance-id-type-choice /= tagged-uuid-type¶
A group carries a unique identifier that is reliably bound to a group of attesters, for example when a number of attester are hidden in the same anonymity set.¶
The type defined for a group identified is UUID.¶
$group-id-type-choice /= tagged-uuid-type¶
Measurements can be of a variety of things including software, firmware, configuration files, read-only memory, fuses, IO ring configuration, partial reconfiguration regions, etc. Measurements comprise raw values, digests, or status information.¶
An environment has one or more measurable elements. Each element can have a dedicated measurement or multiple elements could be combined into a single measurement. Measurements can have class, instance or group scope. This is typically determined by the triple's environment.¶
Class measurements apply generally to all the attesters in the given class. Instance measurements apply to a specific attester instances. Environments identified by a class identifier have measurements that are common to the class. Environments identified by an instance identifier have measurements that are specific to that instance.¶
measurement-map = { ? &(mkey: 0) => $measured-element-type-choice &(mval: 1) => measurement-values-map }¶
The following describes each member of the measurement-map
:¶
mkey
(index 0): An optional unique identifier of the measured
(sub-)environment. See Section 3.1.4.1.5.1.¶
mval
(index 1): The measurements associated with the (sub-)environment.
Described in Section 3.1.4.1.5.2.¶
The types defined for a measurement identifier are OID, UUID or uint.¶
$measured-element-type-choice /= tagged-oid-type $measured-element-type-choice /= tagged-uuid-type $measured-element-type-choice /= uint¶
A measurement-values-map
contains measurements associated with a certain
environment. Depending on the context (triple) in which they are found,
elements in a measurement-values-map
can represent class or instance
measurements. Note that some of the elements have instance scope only.¶
measurement-values-map = non-empty<{ ? &(version: 0) => version-map ? &(svn: 1) => svn-type-choice ? &(digests: 2) => [ + hash-entry ] ? &(flags: 3) => flags-map ? ( &(raw-value: 4) => $raw-value-type-choice, ? &(raw-value-mask: 5) => raw-value-mask-type ) ? &(mac-addr: 6) => mac-addr-type-choice ? &(ip-addr: 7) => ip-addr-type-choice ? &(serial-number: 8) => text ? &(ueid: 9) => ueid-type ? &(uuid: 10) => uuid-type ? &(name: 11) => text * $$measurement-values-map-extension }>¶
The following describes each member of the measurement-values-map
.¶
version
(index 0): Typically changes whenever the measured environment is
updated. Described in Section 3.1.4.1.5.3.¶
svn
(index 1): The security version number typically changes only when a
security relevant change is made to the measured environment. Described in
Section 3.1.4.1.5.4.¶
digests
(index 2): Contains the digest(s) of the measured environment
together with the respective hash algorithm used in the process. See
Section 1.3.8.¶
flags
(index 3): Describes security relevant operational modes. For
example, whether the environment is in a debug mode, recovery mode, not fully
configured, not secure, not replay protected or not integrity protected. The
flags
field indicates which operational modes are currently associated with
measured environment. Described in Section 3.1.4.1.5.5.¶
raw-value
(index 4): Contains the actual (not hashed) value of the element.
An optional raw-value-mask
(index 5) indicates which bits in the
raw-value
field are relevant for verification. A mask of all ones ("1")
means all bits in the raw-value
field are relevant. Multiple values could
be combined to create a single raw-value
attribute. The vendor determines
how to pack multiple values into a single raw-value
structure. The same
packing format is used when collecting Evidence so that Reference Values and
collected values are bit-wise comparable. The vendor determines the encoding
of raw-value
and the corresponding raw-value-mask
.¶
mac-addr
(index 6): A EUI-48 or EUI-64 MAC address associated with the
measured environment. Described in Section 3.1.4.1.5.7.¶
ip-addr
(index 7): An IPv4 or IPv6 address associated with the measured
environment. Described in Section 3.1.4.1.5.7.¶
serial-number
(index 8): A text string representing the product serial
number.¶
ueid
(index 9): UEID associated with the measured environment. See
Section 1.3.5.¶
uuid
(index 10): UUID associated with the measured environment. See
Section 1.3.4.¶
name
(index 11): a name associated with the measured environment.¶
A version-map
contains details about the versioning of a measured
environment.¶
version-map = { &(version: 0) => text ? &(version-scheme: 1) => $version-scheme }¶
The following describes each member of the version-map
:¶
version
(index 0): the version string¶
version-scheme
(index 1): an optional indicator of the versioning
convention used in the version
attribute. Defined in Section 4.1 of [I-D.ietf-sacm-coswid]. The CDDL is copied below for convenience.¶
$version-scheme /= &(multipartnumeric: 1) $version-scheme /= &(multipartnumeric-suffix: 2) $version-scheme /= &(alphanumeric: 3) $version-scheme /= &(decimal: 4) $version-scheme /= &(semver: 16384) $version-scheme /= int / text¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/89¶
svn-type = uint svn = svn-type min-svn = svn-type tagged-svn = #6.552(svn) tagged-min-svn = #6.553(min-svn) svn-type-choice = tagged-svn / tagged-min-svn¶
The flags-map
measurement describes a number of boolean operational modes.
If a flags-map
value is not specified, then the operational mode is unknown.¶
flags-map = { ? &(configured: 0) => bool ? &(secure: 1) => bool ? &(recovery: 2) => bool ? &(debug: 3) => bool ? &(replay-protected: 4) => bool ? &(integrity-protected: 5) => bool * $$flags-map-extension }¶
The following describes each member of the flags-map
:¶
configured
(index 0): The measured environment is fully configured for
normal operation if the flag is true.¶
secure
(index 1): The measured environment's configurable security settings
are fully enabled if the flag is true.¶
recovery
(index 2): The measured environment is NOT in a recovery state if
the flag is true.¶
debug
(index 3): The measured environment is in a debug enabled state if
the flag is true.¶
replay-protected
(index 4): The measured environment is protected from
replay by a previous image that differs from the current image if the flag is
true.¶
integrity-protected
(index 5): The measured environment is protected from
unauthorized update if the flag is true.¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/90¶
$raw-value-type-choice /= #6.560(bytes) raw-value-mask-type = bytes¶
The types or associating addressing information to a measured environment are:¶
ip-addr-type-choice = ip4-addr-type / ip6-addr-type ip4-addr-type = bytes .size 4 ip6-addr-type = bytes .size 16 mac-addr-type-choice = eui48-addr-type / eui64-addr-type eui48-addr-type = bytes .size 6 eui64-addr-type = bytes .size 8¶
A cryptographic key can be one of the following formats:¶
tagged-pkix-base64-key-type
: PEM encoded SubjectPublicKeyInfo.
Defined in Section 13 of [RFC7468].¶
tagged-pkix-base64-cert-type
: PEM encoded X.509 public key certificate.
Defined in Section 5 of [RFC7468].¶
tagged-pkix-base64-cert-path-type
: X.509 certificate chain created by the
concatenation of as many PEM encoded X.509 certificates as needed. The
certificates MUST be concatenated in order so that each directly certifies
the one preceding.¶
$crypto-key-type-choice /= tagged-pkix-base64-key-type $crypto-key-type-choice /= tagged-pkix-base64-cert-type $crypto-key-type-choice /= tagged-pkix-base64-cert-path-type tagged-pkix-base64-key-type = #6.554(tstr) tagged-pkix-base64-cert-type = #6.555(tstr) tagged-pkix-base64-cert-path-type = #6.556(tstr)¶
A domain is a context for bundling a collection of related environments and their measurements.¶
Three types are defined: uint and text for local scope, UUID for global scope.¶
$domain-type-choice /= uint $domain-type-choice /= text $domain-type-choice /= tagged-uuid-type¶
A Reference Values triple relates reference measurements to a Target Environment. For Reference Value Claims, the subject identifies a Target Environment, the object contains measurements, and the predicate asserts that these are the expected (i.e., reference) measurements for the Target Environment.¶
reference-triple-record = [ environment-map [ + measurement-map ] ]¶
An Endorsed Values triple declares additional measurements that are valid when a Target Environment has been verified against reference measurements. For Endorsed Value Claims, the subject is either a Target or Attesting Environment, the object contains measurements, and the predicate defines semantics for how the object relates to the subject.¶
endorsed-triple-record = [ environment-map [ + measurement-map ] ]¶
A Device Identity triple relates one or more cryptographic keys to a device. The subject of an Identity triple uses an instance or class identifier to refer to a device, and a cryptographic key is the object. The predicate asserts that the identity is authenticated by the key. A common application for this triple is device identity.¶
identity-triple-record = [ environment-map [ + $crypto-key-type-choice ] ]¶
An Attestation Keys triple relates one or more cryptographic keys to an Attesting Environment. The Attestation Key triple subject is an Attesting Environment whose object is a cryptographic key. The predicate asserts that the Attesting Environment signs Evidence that can be verified using the key.¶
attest-key-triple-record = [ environment-map [ + $crypto-key-type-choice ] ]¶
A Domain Dependency triple defines trust dependencies between measurement sources. The subject identifies a domain (Section 3.1.4.1.7) that has a predicate relationship to the object containing one or more dependent domains. Dependency means the subject domain's trustworthiness properties rely on the object domain(s) trustworthiness having been established before the trustworthiness properties of the subject domain exists.¶
domain-dependency-triple-record = [ $domain-type-choice [ + $domain-type-choice ] ]¶
A Domain Membership triple assigns domain membership to environments. The subject identifies a domain (Section 3.1.4.1.7) that has a predicate relationship to the object containing one or more environments. Endorsed environments (Section 3.1.4.3) membership is conditional upon successful matching of Reference Values (Section 3.1.4.2) to Evidence.¶
domain-membership-triple-record = [ $domain-type-choice [ + environment-map ] ]¶
A CoSWID triple relates reference measurements contained in one or more CoSWIDs to a Target Environment. The subject identifies a Target Environment, the object one or more unique tag identifiers of existing CoSWIDs, and the predicate asserts that these contain the expected (i.e., reference) measurements for the Target Environment.¶
coswid-triple-record = [ environment-map [ + concise-swid-tag-id ] ] concise-swid-tag-id = text / bstr .size 16¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/91¶
This section records the status of known implementations of the protocol defined by this specification at the time of posting of this Internet-Draft, and is based on a proposal described in [RFC7942]. The description of implementations in this section is intended to assist the IETF in its decision processes in progressing drafts to RFCs. Please note that the listing of any individual implementation here does not imply endorsement by the IETF. Furthermore, no effort has been spent to verify the information presented here that was supplied by IETF contributors. This is not intended as, and must not be construed to be, a catalog of available implementations or their features. Readers are advised to note that other implementations may exist.¶
According to [RFC7942], "this will allow reviewers and working groups to assign due consideration to documents that have the benefit of running code, which may serve as evidence of valuable experimentation and feedback that have made the implemented protocols more mature. It is up to the individual working groups to use this information as they see fit".¶
corim/corim
and corim/comid
packages
provide a golang API for low-level manipulation of Concise Reference
Integrity Manifest (CoRIM) and Concise Module Identifier (CoMID) tags
respectively. The corim/cocli
package uses the API above (as well as the
API from the veraison/swid
package) to provide a user command line
interface for working with CoRIM, CoMID and CoSWID. Specifically, it allows
creating, signing, verifying, displaying, uploading, and more. See
https://github.com/cocli/README.md for
further details.¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/92¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/96¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/94¶
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/95¶
IANA is requested to add the following media types to the "Media Types" registry [IANA.media-types].¶
Name | Template | Reference |
---|---|---|
corim-signed+cbor | application/corim-signed+cbor | RFCthis, Section 6.5.1 |
corim-unsigned+cbor | application/corim-unsigned+cbor | RFCthis, Section 6.5.2 |
application
¶
corim-signed+cbor
¶
n/a¶
"profile" (CoRIM profile in string format. OIDs MUST use the dotted-decimal notation.)¶
binary¶
n/a¶
RFCthis¶
Attestation Verifiers, Endorsers and Reference-Value providers that need to transfer COSE Sign1 wrapped CoRIM payloads over HTTP(S), CoAP(S), and other transports.¶
n/a¶
D9 01 F6 D2
, D9 01 F4 D9 01 F6 D2
¶
n/a¶
n/a¶
RATS WG mailing list (rats@ietf.org)¶
COMMON¶
none¶
IETF¶
Maybe¶
application
¶
corim-unsigned+cbor
¶
n/a¶
"profile" (CoRIM profile in string format. OIDs MUST use the dotted-decimal notation.)¶
binary¶
n/a¶
RFCthis¶
Attestation Verifiers, Endorsers and Reference-Value providers that need to transfer unprotected CoRIM payloads over HTTP(S), CoAP(S), and other transports.¶
n/a¶
D9 01 F5
, D9 01 F4 D9 01 F5
¶
n/a¶
n/a¶
RATS WG mailing list (rats@ietf.org)¶
COMMON¶
none¶
IETF¶
Maybe¶
IANA is requested to register the two following Content-Format numbers in the "CoAP Content-Formats" sub-registry, within the "Constrained RESTful Environments (CoRE) Parameters" Registry [IANA.core-parameters]:¶
Content-Type | Content Coding | ID | Reference |
---|---|---|---|
application/corim-signed+cbor | - | TBD1 | RFCthis |
application/corim-unsigned+cbor | - | TBD2 | RFCthis |
Content missing. Tracked at: https://github.com/ietf-rats/draft-birkholz-rats-corim/issues/80¶
corim = []¶
Carl Wallace for review and comments on this document.¶