Taxonomy of Composite Attesters
draft-richardson-rats-composite-attesters-04
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| Document | Type | Active Internet-Draft (individual) | |
|---|---|---|---|
| Authors | Michael Richardson , Henk Birkholz , Yogesh Deshpande , Thomas Fossati | ||
| Last updated | 2026-03-02 | ||
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| Intended RFC status | (None) | ||
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draft-richardson-rats-composite-attesters-04
RATS Working Group M. Richardson
Internet-Draft Sandelman Software Works
Intended status: Informational H. Birkholz
Expires: 3 September 2026 Fraunhofer SIT
Y. Deshpande
Arm
T. Fossati
Linaro
2 March 2026
Taxonomy of Composite Attesters
draft-richardson-rats-composite-attesters-04
Abstract
This document clarifies and extends the meaning of Composite Attester
from RFC9334. A system of annotated diagram components is defined as
a small language to explain the different ways that components can
interact to form composites. These diagram components are then used
to define a few popular classes of composites.
About This Document
This note is to be removed before publishing as an RFC.
Status information for this document may be found at
https://datatracker.ietf.org/doc/draft-richardson-rats-composite-
attesters/.
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Source for this draft and an issue tracker can be found at
https://github.com/mcr/composite-attesters.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Caveats of Current Definition . . . . . . . . . . . . . . 3
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4
3. Notation System . . . . . . . . . . . . . . . . . . . . . . . 5
3.1. Nodes . . . . . . . . . . . . . . . . . . . . . . . . . . 5
3.1.1. Conveyer . . . . . . . . . . . . . . . . . . . . . . 5
3.1.2. Attester . . . . . . . . . . . . . . . . . . . . . . 5
3.2. Connectors . . . . . . . . . . . . . . . . . . . . . . . 7
3.2.1. Interface . . . . . . . . . . . . . . . . . . . . . . 7
3.2.2. Depends-on . . . . . . . . . . . . . . . . . . . . . 7
3.2.3. Router . . . . . . . . . . . . . . . . . . . . . . . 8
3.2.4. Trusted HW path . . . . . . . . . . . . . . . . . . . 8
3.2.5. Collection (Bus) . . . . . . . . . . . . . . . . . . 8
3.3. Example of Notation System . . . . . . . . . . . . . . . 8
3.3.1. CCA Delegated . . . . . . . . . . . . . . . . . . . . 8
3.3.2. Class 0 . . . . . . . . . . . . . . . . . . . . . . . 9
3.3.3. Class 1 . . . . . . . . . . . . . . . . . . . . . . . 9
3.3.4. Class 2 . . . . . . . . . . . . . . . . . . . . . . . 10
4. Composite Attesters Examples . . . . . . . . . . . . . . . . 11
4.1. Class 0 Composite Attester . . . . . . . . . . . . . . . 12
4.2. Class 1 Composite Attester . . . . . . . . . . . . . . . 13
4.3. Class 2 Composite/Hybrid Attester . . . . . . . . . . . . 15
4.4. Class 3B Composite Background-Check Attester . . . . . . 16
4.5. Class 3P Composite Passport-Model Attester . . . . . . . 17
4.6. Class 4 Dual Composite Attester . . . . . . . . . . . . . 19
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4.7. Class 5 Mixed Composite Attester . . . . . . . . . . . . 20
5. Attestation Results as Evidence . . . . . . . . . . . . . . . 20
6. Privacy Considerations . . . . . . . . . . . . . . . . . . . 21
7. Security Considerations . . . . . . . . . . . . . . . . . . . 21
8. Nonce Architecture . . . . . . . . . . . . . . . . . . . . . 21
9. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 21
10. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 21
11. Changelog . . . . . . . . . . . . . . . . . . . . . . . . . . 21
12. References . . . . . . . . . . . . . . . . . . . . . . . . . 21
12.1. Normative References . . . . . . . . . . . . . . . . . . 21
12.2. Informative References . . . . . . . . . . . . . . . . . 22
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 22
1. Introduction
This document clarifies and extends the meaning of Composite Attester
from [RFC9334], Section 3.3.
A system of anotated diagram components are defined to allow
relationships to be expressed consistently.
These diagram components are then used to describe a number of
classes of Composite Attester which are being seen in the nascent
Remote Attestation industry. These classes are representative, but
are not intended to be complete: more complexity, more layers and
more sub-components are always possible.
The aim is to describe the Composite Attester topology in a way that
helps understanding the resulting Evidence composition that flows
from the Attesting Environment(s), to the Verifier(s).
Additionally, there is a need for freshness artifacts is flow in the
opposite direction, and in Composite Remote Attestation, the amount
of freshness and origin of the freshness needs to be understood.
1.1. Caveats of Current Definition
[RFC9334], Section 3.3 says:
| A composite device is an entity composed of multiple sub-entities
| such that its trustworthiness has to be determined by the
| appraisal of all these sub-entities.
|
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| Each sub-entity has at least one Attesting Environment collecting
| the Claims from at least one Target Environment. Then, this sub-
| entity generates Evidence about its trustworthiness; therefore,
| each sub- entity can be called an "Attester". Among all the
| Attesters, there may be only some that have the ability to
| communicate with the Verifier while others do not.
In this description, it was left vague as to whether or not each
Attesting Environment signs the Evidence that it generates, and
whether or not the Evidence is evaluated by a Verifier operated by
the Lead Attester, or if it's passed by the Lead Attester along with
the Evidence from the Lead Target Environment.
2. Terminology
Lead Attester: This term is from RFC9334, and includes the (Lead)
Attesting Environment, and the (Lead) Target Environment.
Target Environment: This term is from RFC9334, this refers to the
environment for which Evidence is gathered.
Attesting Environment: This term is from RFC9334, this refers to the
thing which gathers the Evidence.
Component: This is the pieces which are attached to the Lead
Attester. There are one to many of these, typically each with
their own application specific processor.
Component Evidence: This is the Evidence that is collected by the
Component Attesting Environment about the Component Target
Environment.
Component Attesting Environment: This term is new, and refers to an
Attesting Environment residing inside a component of the whole.
Component Target Environment: This term is new, and refers to an
environment for which Evidence is collected.
Local Verifier: When an Attesting Environment _appraises_ Evidence
from another Attesting Environment, then it operates as a Local
Verifier. Mere examination of the signature on the Evidence
(perhaps using a local credential) is not appraisal.
Local Validation: in some classes, Evidence is passed around, and
must remain integral. Local Validation involves checking the
authenticity of the end-point. This could involve a signature, or
require physical security of that end-point.
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Verifier le petit: (Or, "Le Petit Verificateur"). This is the
Verifier that examines the Component Evidence. This may treat the
Lead Attester as a component.
Verifier le grand: (Or, "Le Grand Verificateur"). This is the
Verifier that examines the arrangement and relationships between
Components.
3. Notation System
This notation system is used in subsequent examples to compose more
complex system. The notations presented here should be considered in
analogy to atoms in Chemistry, with the composed class examples
below, to be molecules. (Alternatively, the notations here are
Baryons and Leptons in the Standard Model of Physics, with examples
being atoms of the periodic table)
This process was developed when it was realized that the set of
classes that could be formed via Composition was unbounded, and so
any attempt to enumerate them all would never end.
3.1. Nodes
3.1.1. Conveyer
A Conveyer is a system component that produces or relays Conceptual
Messages.
.---.
| |
'---'
It is represented by a rectangular shape with rounded corners.
The following sections describe specialised types of Conveyors.
3.1.2. Attester
An Attester is a special kind of Conveyer which produces Evidence.
.------.
| TE |
+------+
| AK |
'------'
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Internally, it is composed of an Attesting Environment, identified by
the attestation key (AK), and a Target Environment (TE), i.e., the
Trusted Computing Base (TCB) measured by the Attester.
An Attester exposes the following Interface (see Section 3.2.1):
+===========+=================+========================+===========+
| Direction | Name | Description | Mandatory |
+===========+=================+========================+===========+
| IN | Nonce | Fixed size parameter | Y |
| | | (typically 32 or 64 | |
| | | bytes) used to bind | |
| | | the produced Evidence | |
| | | to a randomly selected | |
| | | parameter chosen by | |
| | | the caller. | |
+-----------+-----------------+------------------------+-----------+
| IN | UserData | Typically a variable- | N |
| | | size parameter that | |
| | | allows the binding of | |
| | | arbitrary application | |
| | | data (e.g., an | |
| | | authentication key | |
| | | held by a confidential | |
| | | computing workload) to | |
| | | the attestation | |
| | | Evidence. | |
+-----------+-----------------+------------------------+-----------+
| IN | ClaimsSelection | A parameter that | N |
| | | allows the user to | |
| | | select which claims | |
| | | should appear in the | |
| | | Evidence. The format | |
| | | is attester-specific | |
| | | (e.g., PCR selection | |
| | | for TPM-like | |
| | | attesters) | |
+-----------+-----------------+------------------------+-----------+
| OUT | Evidence | The Evidence signed by | Y |
| | | the AK. It contains | |
| | | either the full set of | |
| | | claims or a subset | |
| | | thereof, as well as | |
| | | the nonce supplied by | |
| | | the caller and any | |
| | | user data. | |
+-----------+-----------------+------------------------+-----------+
| OUT | OtherData | Related Conceptual | N |
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| | | Messages, such as | |
| | | Attestation Results, | |
| | | Endorsement, etc. | |
+-----------+-----------------+------------------------+-----------+
Table 1
3.2. Connectors
3.2.1. Interface
An Interface is connected to a Node (such as an Attester) and outputs
a RATS Conceptual Messages.
It is represented by a T-shaped connector.
-+-
|
An Interface has a name and some input and output parameters.
Input and output parameters are defined by their name and type.
A ? signals an optional parameter.
// TODO: align this with Attester's interface description.
3.2.2. Depends-on
The Depends-on connector describes a chain of trust between two
adjacent Attesters within a layered attester arrangement. Examples
of such an arrangement include DICE [TCG-DICE] and Arm CCA
[I-D.ffm-rats-cca-token] in delegated mode.
It is represented by an arrow connector pointing from the dependent
node to the dependent node, i.e. from the "higher" to the "lower"
component in the chain of trust.
.---.
| B |
'-+-'
| depends-on
v
.-+-.
| A |
'---'
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3.2.3. Router
TBD
3.2.4. Trusted HW path
TBD - it may be an implementation detail rather than a conceptual
relation between attesters.
3.2.5. Collection (Bus)
A Collection connector describes the collection of Conceptual
Messages.
.------------.
| Binder |
'-+--------+-'
| |
v v
-+- -+-
| |
.-+-. .-+-.
| A | | B |
'---' '---'
A lead Attester is responsible for the binding function.
A binder is one of:
* Signature of the lead Attester
* Projection
The signature of the lead Attester can bind over a broadcast nonce.
A Projection is described as a topo-sorted set of (src, dst) tuples.
3.3. Example of Notation System
3.3.1. CCA Delegated
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-+- RSI ABI (nonce[64])
|
.---+------.
| TE: wkl |
+----------+ Realm
| AK: RAK |
'---+------'
| depends-on
v
.---+------.
| TE: RMM |
+----------+ Platform
| AK: CPAK |
'----------'
3.3.2. Class 0
-+- API
|
.---+-----.
| TE: TE |
+---------+
| AK: LAK |
'---------'
Or
-+- API
|
.---+-----.
| TE: <> | .---------------.
+---------+----->| <> |
| AK: LAK | '-+-----------+-'
'---------' | |
.--+------. .--+-------.
| TE: VGA | | TE: SCSI |
+---------+ +----------+
| AK: <> | | AK: <> |
'---------' '----------'
3.3.3. Class 1
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-+- API
|
.---+-----.
| TE: A | .---------------.
+---------+----->| Binding=? |
| AK: LAK | '-+-----------+-'
'---------' | |
.--+------. .--+-------.
| TE: B | | TE: C |
+---------+ +----------+
| AK: BK | | AK: CK |
'---------' '----------'
Notes:
1. A seems to have both lead and "normal" attester functionality
2. Binding between collection entries is unspecified
3. is CMW signed or not?
Questions:
1. scope of LAK: the signing key over the collection CMW, or signing
key over Target A, or both?
3.3.4. Class 2
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.-----------.
| Verifier |
'-+---------'
| ^ | .-.
v | .---->+--+ B |
.---------+-. | | '-'
| RP +----+
+-----------+ | | .-.
| Conveyer | '---->+--+ C |
'-----+-----' .-. | '-'
| | A |
| '+'
| |
-+- -+-
^ ^
| |
.-+-----------+-.
| Binding=? |
'------+--------'
|
.--+-------.
| TE: <> |
+----------+
| AK: LAK |
'--+-------'
|
-+-
Questions and notes are the same as Class 1.
Besides, there are further questions:
1. a question whether a lead attester is in front of B and C
2. a question about unnecessary conflation of RP/Verifier and Lead
attester -- they probably need to be modelled as separate
entities
4. Composite Attesters Examples
(EDNOTE: the diagrams in this section will get rewritten using the
notation system abover)
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4.1. Class 0 Composite Attester
In this first, somewhat degenerate scenario, the Lead Attester has
access to the entire memory/environment of all of the components.
Examples of situations like this include classic PCI-buses, ISA-
buses, VME, S100/IEEE 696-1983. In these situations, secondary
components might not boot on their own. (It might even be that the
lead environment (the chassis) will place code into RAM for these
systems, with no ROM at all)
In this case, it is possible for the Lead Attesting Environment to
collect Claims about each of the components without the components
having to have their own Attesting Environment.
There is no Verifier le petit, since there are no components that can
create Evidence other than the Lead Attester.
At this Class, all of these components can be considered part of the
same system. In the classic PCI or ISA environment, the components
are hard drive interfaces, video interfaces, and network interfaces.
For many such systems considering the system to be a composite is
unncessary additional complexity.
The benefit of applying the composite mechanism in this case is that
it is no longer necessary to consider the exhaustive combinatorics of
all possible components being attached to the lead attester. It is,
for instance, already the case the reference values for a target
environment may change depending upon how much memory is installed in
the target environment.
In this degenerate, or Class _0_ Composite Attester, the Claims
gathered about the components would be included in the Lead
Attester's signed Evidence (such as an EAT), as sub-components in
UCCS form [RFC9781]. The signature from the Lead Attester applies to
all the Claims, but the Verifier can evaluate each component
separately.
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.----------.
| Verifier |
'----------'
^
.---------------------------|---------------------.
| .---------------------. | |
| | Target | | |
| | Environ | | |
| | | | |
| | .------. .------. | |Evidence includes: |
| | | VGA | | SCSI | | | - SHA256(VGArom) |
| | | rom | | rom | | | - SHA256(SCSIrom) |
| | | | | | | | - SHA256(boot rom) |
| | '------' '------' | | |
| | Claims | | |
| | | | |
| '---------------------' | |
| | | |
| | Collect | |
| | Claims | |
| | | |
| | .-------------. |
| | | Attesting | |
| '----->| Environment | |
| '-------------' |
| |
'----------------------Chassis--------------------'
Figure 1: Class 0 Composite Attester
However, more modern buses like PCIe, InfiniBand, Thunderbolt,
DisplayPort, USB, Firewire and others do not provided direct
electrical access to target component system memory. While some seem
to be very high speed serialized versions of the old I/O buses, there
is a network-like protocol, and non-trivial deserialization occurs at
each end. That implies that there can be mutable firmware in each
component which mitigates access. That firmware itself might not be
trustworthy. If it can even be seen by the Lead Attester, the
mitigation mechanism can present whatever view the Lead Attester
expects to see. So, a system with such interfaces would be a Class
1.
4.2. Class 1 Composite Attester
In this Class, each component or slot has its own Attesting
Environment and hence produces its own signed Evidence.
RFC 9334 gives the following example:
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| For example, a carrier-grade router consists of a chassis and
| multiple slots. The trustworthiness of the router depends on all
| its slots' trustworthiness. Each slot has an Attesting
| Environment, such as a TEE, collecting the Claims of its boot
| process, after which it generates Evidence from the Claims.
The Lead Attester simply relays the Evidence along with its own:
| Among these slots, only a "main" slot can communicate with the
| Verifier while other slots cannot. However, other slots can
| communicate with the main slot by the links between them inside
| the router. The main slot collects the Evidence of other slots,
| produces the final Evidence of the whole router, and conveys the
| final Evidence to the Verifier. Therefore, the router is a
| composite device, each slot is an Attester, and the main slot is
| the lead Attester.
Note that the Lead Attester does _not_ evaluate the Evidence, and
does not run its own Verifier.
.----------.
| Verifier |
'----------'
^
.----------------------------|-----------------------------------------.
| .-------------------------|--------. |
| | .----------. | Evidence-Collection CMW |
| | | Target A | | 1: CMW(Evidence(Attester A) |
| | | Environ | | 2: Evidence(Attester B) |
| | '----------' | 3: Evidence(Attester C)) |
| | | | | |
| | |Collect | | .--------------. |
| | |Claims | | Evidence B | Attester B | |
| | | | |<------------| | |
| | | .-------------. | '--------------' |
| | | | Attesting | | |
| | '--------->| Environment | | .--------------. |
| | '-------------' |<------------| Attester C | |
| | Attester A | Evidence C | | |
| '-----------Lead Attester----------' '--------------' |
| |
.---------------------------Composite Device---------------------------.
Figure 2: Class 1 Composite Attester
This diagram is intended to be identical to Figure 4 of [RFC9334],
but has been stretched out to allow the relationship to other classes
to be clearer.
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4.3. Class 2 Composite/Hybrid Attester
In this scenario, the Components relay their Evidence to the Lead
Attester. The Lead Attester operates a Verifier itself. It
evaluates the Components' Evidence against Reference Values,
Endorsements, etc. producing _Attestation Results_ These Attestation
Results (or their selectively disclosed version: SD-CWT/SD-JWT) are
then included as part of the Lead Attester's Evidence to it's remote
Verifier, using the RATS Concise Message Wrapper (CMW)
[I-D.ietf-rats-msg-wrap] Also the Lead Attester's Verifier can be a
target environment, whose claims can be reported in Lead Attester
Evidence. This ensures that the remote Verifier can fully trust the
verification done by Lead Attester.
.----------.
| Lead |
| Verifier |
'----------'
|
|
.----------------------------|------------------------------------------.
| .-------------------------|---------. |
| | .----------. | Evidence-Collection CMW |
| | | Target A | | 1: CMW(Evidence(Attester A), |
| | | Environ | | 2: AR(Attester B), |
| | '----------' | 3: AR(Attester C)) |
| | | | | |
| | |Collect | | |
| | |Claims | | |
| | | | | |
| | | .-------------. | |
| | | | Attesting | | |
| | '--------->| Environment | | |
| | | + RP | | |
| | Attester A '-------------' | Evidence B .------------. |
| | ^ | .------------| Attester B | |
| | | | | '------------' |
| | | | | |
| | AR(Attester B)| | | |
| | AR(Attester C)| | |<---. |
| | .-------------. | | | .------------. |
| | | Chassis | | | '-------| Attester C | |
| | | Component |<----'Evidence C '------------' |
| | | Verifier | | |
| | '-------------' | |
| '-----------------------------------' |
'-----------------------------Chassis A---------------------------------'
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Figure 3: Class 2 Composite Attester
The Verifier's signing credentials may be part of the same Attesting
Environment as the Evidence signing credential used by the Lead
Attesting environment. Or they could be in a different environment,
such as in a different TEE.
4.4. Class 3B Composite Background-Check Attester
In this scenario, the Components relay their Evidence to the Lead
Attester. The Lead Attester does _not_ operates a Verifier itself.
Instead, the Lead Attester, conveys the Evidence to the Lead Verifier
along with it's own Evidence. The Component Evidence is not placed
within the Lead Attester's Evidence (DEBATE). The Lead Attester
needs to communicate how each component is attached, and that would
be within its Evidence.
.----------. .-------------.
| Lead | | Component |
| Verifier |<---------| Verifier |
'----------' '-------------'
|
.----------------------------|------------------------------------------.
| .-------------------------|----------. |
| | | | |
| | .----------. | Evidence-Collection CMW |
| | | Target A | | 1: CMW(Evidence(Attester A), |
| | | Environ | | 2. Evidence(Attester B), |
| | '----------' | 3: Evidence(Attester C)) |
| | | | | |
| | |Collect | | |
| | |Claims | | |
| | | | | |
| | | .-------------. | |
| | | | Attesting | | Evidence B .------------. |
| | '--------->| Environment | |<--------------| Attester B | |
| | '-------------' | '------------' |
| | | |
| | Attester A | Evidence C .------------. |
| | |<--------------| Attester C | |
| '------------------------------------' '------------' |
'-----------------------------Chassis A---------------------------------'
Figure 4: Class 3B Composite Background-check Attester
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The Lead Verifier, acting a Relying Party, connects to Component
Verifiers capable of evaluating the Component Evidence, retrieving
Attestation Results from those Verifiers as part of evaluating the
Lead Attester.
This case is similar to Class 1, however the integration of the
component attestation results in Class 1 is not included in the
Evidence, while in this case, it is.
4.5. Class 3P Composite Passport-Model Attester
In this scenario, the Components relay their Evidence to the Lead
Attester. The Lead Attester does _not_ operates a Verifier itself.
Instead, the Lead Attester, acting as a Presenter (term To-Be-
Defined), connects to an appropriate Verifier, in passport mode. It
retrieves an Attestation Result from the Verifier, which it then
includes within the Evidence that the Lead Attester produces.
The Lead Attester's Verifier considers the Components during it's
assessment. It needs to consider if the component has been assessed
by a Verifier it trusts, if the component is appropriately connected
to the Lead Attester, and if there are an appropriate number of such
components.
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.----------.
| Lead |
| Verifier |
'----------'
.---------------------------|------------------------------------------.
| .-------------------------|----------. |
| | | Evidence-Collection CMW |
| | .----------. | 1: CMW(Evidence(Attester A), |
| | | Target A | | 2: AR(Attester B), |
| | | Environ | | 3: AR(Attester C)) |
| | '----------' | | |
| | | | | |
| | |Collect | | |
| | |Claims | | Evidence B .------------. |
| | | | |<---------------| Attester B | |
| | | .-------------. | '------------' |
| | | | Attesting | | |
| | '--------->| Environment | | Evidence C .------------. |
| | '-------------' |<---------------| Attester C | |
| | | '------------' |
| | Attester A | |
| '------------------------------------' |
'-------------------------------Chassis A------------------------------'
^
|
|
|
| Evidence->
| <- Results
.---------------.
| Component B,C |
| Verifier(s) |
'---------------'
Figure 5: Class 3P Composite Password Attester
For instance, when accessing a vehicle such as a car, where each tire
is it's own component, then a car with three wheels is not
trusthworthy. Most cars should have four wheels. A car with five
wheels might be acceptable, if at least one wheel is installed into
the "spare" holder. (And, it may be of concern if the spare is flat,
but the car can still be operated)
A more typical digital use case would involve a main CPU with a
number of attached specialized intelligent components that contain
their own firmware, such as Graphical Processors (GPU), Network
Processors (NPU).
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4.6. Class 4 Dual Composite Attester
In certain systems, it is possible to have two independent Attesting
Environments in an Attester to collect claims about a single Target
Environment. In such cases, one of the Attesting Environment, acts
as a Primary, while the other acts as a Secondary Attesting
Environment.
The two Attesting Environments will have a fixed and collaborative
structure where each can be responsible for a subset of Evidence.
Because of the collaborative structure it may be arranged that either
of the Attesting Environment can present Evidence collected by the
other (but this is deployment specific).
.----------.
| Verifier |
'----------'
^
|
-----.
|
.--------------------------------------------|----------.
| | |
| .----------. Evidence-Collection CMW| |
| | Target A | 1: CMW(EAT(Target A)) | |
| | Environ | | |
| '----------' | |
| | | |
| |Collect | |
| |Claims | |
| | .-------------. |
| | .-------------. | Attesting 2 | |
| | | Attesting 1 | | Environment | |
| '--------->| Environment | '-------------' |
| '-------------' ^ |
| | | |
| | | |
| '-----Partial -----' |
| Evidence |
| (signed) |
| |
| |
'-------------------------------------------------------'
Figure 6: Class 4 Composite (Dual) Attester
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Example of one such system is a CPU system of a desktop from a Vendor
X, which has its built in Attesting Environment, integrated into a
product Y which requires a mandatory TPM support. (EDIT: This
example to be clarified)
There is an assumption that the Attesting Environment 1 (AE1)
"trusts" Attesting Environment 2 (AE2), which means that AE2 has to
verify the signature from AE1, otherwise AE2 can become a "signing
fool". This verification can be based upon a local credential.
In such situations one can anchor the Roots of Trust of Vendor X's
CPU Attestation using a secondary Attesting Environment with the TPM
Attestation. Alternatively, generate a TPM Quote and anchor it to
Root of Trust of CPU Attestation based of Vendor X's Attesting
Environment.
A Verifier/RP may decide to direct the Attestation Request to an AE
of choice to reflect the relevant subset of Evidence required for
trust asssessment.
4.7. Class 5 Mixed Composite Attester
As soon as there is more than one Component, it is reasonable that
the different Components interact with the Lead Attester in different
ways. A Mixed Composite Attester would have a components that come
from different classes. This is not a class itself, but a class of
classes.
Degenerately, all previous classes can be considered mixes of one,
but such a trivial category does not help discussionn. Except that
adding/moving/replacing Components in the field can change things, so
some system architectures will need to always consider themselves to
be Mixed Composite Attesters, even if when shipped, they might be
degenerate instances.
5. Attestation Results as Evidence
In cases 2, 3B and 3P Attestation Results are included as Evidence.
This results in a Verifier that must evaluate these results. It must
be able to validate the signatures on the Evidence.
This creates _stacked_ Remote Attestation. This is very much
different and _distinct_ from [RFC9334], Section 3.2 Layered
Attestation.
Layered Attestion produces a _single_ set of Evidence, with claims
about different layers.
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6. Privacy Considerations
YYY
7. Security Considerations
ZZZ
8. Nonce Architecture
In all classes other than the class 0 and class 1, there are cases
that multiple (local or external) Verifiers exist in the system. To
address the conflict between different nonces generated by different
Verifiers, there are possible candidate solutions as follows
* Using one unique nonce from one external Verifier: This Verifier
initiates the attestation progress and other Verifiers use the
same nonce to challenge their corresponding Attesters. To ensure
the integrity of the nonce, this nonce SHOULD be signed by this
initial Verifier.
* Each Verifier uses their own nonce: The Evidence in such a case is
the mixing of certain Evidences and Attestation Result-as-
Evidences. The receiver of the Attestation Results (the Attester)
can apply the technique in [RFC9334], Appendix A.2 to ensure the
freshness of the Attestation Result-as-Evidences.
9. IANA Considerations
10. Acknowledgements
Jun Zhang contributed the terms "Le Petit" and "Le Grand" to qualify
Verifier, the original thought for Class 5 Composite Atteser and the
description of the Nonce architecture.
11. Changelog
12. References
12.1. Normative References
[I-D.ietf-rats-msg-wrap]
Birkholz, H., Smith, N., Fossati, T., Tschofenig, H., and
D. Glaze, "RATS Conceptual Messages Wrapper (CMW)", Work
in Progress, Internet-Draft, draft-ietf-rats-msg-wrap-23,
11 December 2025, <https://datatracker.ietf.org/doc/html/
draft-ietf-rats-msg-wrap-23>.
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[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
May 2017, <https://www.rfc-editor.org/info/rfc8174>.
[RFC9334] Birkholz, H., Thaler, D., Richardson, M., Smith, N., and
W. Pan, "Remote ATtestation procedureS (RATS)
Architecture", RFC 9334, DOI 10.17487/RFC9334, January
2023, <https://www.rfc-editor.org/info/rfc9334>.
12.2. Informative References
[I-D.ffm-rats-cca-token]
Frost, S., Fossati, T., and G. Mandyam, "Arm's
Confidential Compute Architecture Reference Attestation
Token", Work in Progress, Internet-Draft, draft-ffm-rats-
cca-token-02, 2 September 2025,
<https://datatracker.ietf.org/doc/html/draft-ffm-rats-cca-
token-02>.
[RFC9781] Birkholz, H., O'Donoghue, J., Cam-Winget, N., and C.
Bormann, "A Concise Binary Object Representation (CBOR)
Tag for Unprotected CBOR Web Token Claims Sets (UCCS)",
RFC 9781, DOI 10.17487/RFC9781, May 2025,
<https://www.rfc-editor.org/info/rfc9781>.
[TCG-DICE] Trusted Computing Group, "DICE Layering Architecture",
Version 1.0, Revision 0.19 , July 2020,
<https://trustedcomputinggroup.org/wp-content/uploads/
DICE-Layering-Architecture-r19_pub.pdf>.
Authors' Addresses
Michael Richardson
Sandelman Software Works
Email: mcr+ietf@sandelman.ca
Henk Birkholz
Fraunhofer SIT
Email: henk.birkholz@ietf.contact
Yogesh Deshpande
Arm
Email: yogesh.deshpande@arm.com
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Thomas Fossati
Linaro
Email: thomas.fossati@linaro.org
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