Internet Engineering Task Force (IETF)                         J. Schaad
Request for Comments: 9052                                August Cellars
STD: 96                                                        July 2021
Obsoletes: 8152
Category: Standards Track
ISSN: 2070-1721

   CBOR Object Signing and Encryption (COSE): Structures and Process

Abstract

   Concise Binary Object Representation (CBOR) is a data format designed
   for small code size and small message size.  There is a need for the
   ability to have basic security services defined for this data format.
   This document defines the CBOR Object Signing and Encryption (COSE)
   protocol.  This specification describes how to create and process
   signatures, message authentication codes, and encryption using CBOR
   for serialization.  This specification additionally describes how to
   represent cryptographic keys using CBOR.

   This document, along with RFC 9053, obsoletes RFC 8152.

Status of This Memo

   This is an Internet Standards Track document.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Further information on
   Internet Standards is available in Section 2 of RFC 7841.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   https://www.rfc-editor.org/info/rfc9052.

Copyright Notice

   Copyright (c) 2021 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.

Table of Contents

   1.  Introduction
     1.1.  Requirements Terminology
     1.2.  Changes from RFC 8152
     1.3.  Design Changes from JOSE
     1.4.  CBOR Grammar
     1.5.  CBOR-Related Terminology
     1.6.  Document Terminology
   2.  Basic COSE Structure
   3.  Header Parameters
     3.1.  Common COSE Header Parameters
   4.  Signing Objects
     4.1.  Signing with One or More Signers
     4.2.  Signing with One Signer
     4.3.  Externally Supplied Data
     4.4.  Signing and Verification Process
   5.  Encryption Objects
     5.1.  Enveloped COSE Structure
       5.1.1.  Content Key Distribution Methods
     5.2.  Single Recipient Encrypted
     5.3.  How to Encrypt and Decrypt for AEAD Algorithms
     5.4.  How to Encrypt and Decrypt for AE Algorithms
   6.  MAC Objects
     6.1.  MACed Message with Recipients
     6.2.  MACed Messages with Implicit Key
     6.3.  How to Compute and Verify a MAC
   7.  Key Objects
     7.1.  COSE Key Common Parameters
   8.  Taxonomy of Algorithms Used by COSE
     8.1.  Signature Algorithms
     8.2.  Message Authentication Code (MAC) Algorithms
     8.3.  Content Encryption Algorithms
     8.4.  Key Derivation Functions (KDFs)
     8.5.  Content Key Distribution Methods
       8.5.1.  Direct Encryption
       8.5.2.  Key Wrap
       8.5.3.  Key Transport
       8.5.4.  Direct Key Agreement
       8.5.5.  Key Agreement with Key Wrap
   9.  CBOR Encoding Restrictions
   10. Application Profiling Considerations
   11. IANA Considerations
     11.1.  COSE Header Parameters Registry
     11.2.  COSE Key Common Parameters Registry
     11.3.  Media Type Registrations
       11.3.1.  COSE Security Message
       11.3.2.  COSE Key Media Type
     11.4.  CoAP Content-Formats Registry
     11.5.  CBOR Tags Registry
     11.6.  Expert Review Instructions
   12. Security Considerations
   13. References
     13.1.  Normative References
     13.2.  Informative References
   Appendix A.  Guidelines for External Data Authentication of
           Algorithms
   Appendix B.  Two Layers of Recipient Information
   Appendix C.  Examples
     C.1.  Examples of Signed Messages
       C.1.1.  Single Signature
       C.1.2.  Multiple Signers
       C.1.3.  Signature with Criticality
     C.2.  Single Signer Examples
       C.2.1.  Single ECDSA Signature
     C.3.  Examples of Enveloped Messages
       C.3.1.  Direct ECDH
       C.3.2.  Direct Plus Key Derivation
       C.3.3.  Encrypted Content with External Data
     C.4.  Examples of Encrypted Messages
       C.4.1.  Simple Encrypted Message
       C.4.2.  Encrypted Message with a Partial IV
     C.5.  Examples of MACed Messages
       C.5.1.  Shared Secret Direct MAC
       C.5.2.  ECDH Direct MAC
       C.5.3.  Wrapped MAC
       C.5.4.  Multi-Recipient MACed Message
     C.6.  Examples of MAC0 Messages
       C.6.1.  Shared-Secret Direct MAC
     C.7.  COSE Keys
       C.7.1.  Public Keys
       C.7.2.  Private Keys
   Acknowledgments
   Author's Address

1.  Introduction

   There has been an increased focus on small, constrained devices that
   make up the Internet of Things (IoT).  One of the standards that has
   come out of this process is "Concise Binary Object Representation
   (CBOR)" [RFC8949]. [STD94].  CBOR extended the data model of the JavaScript
   Object Notation (JSON) [STD90] by allowing for binary data, among
   other changes.  CBOR has been adopted by several of the IETF working
   groups dealing with the IoT world as their encoding of data
   structures.  CBOR was designed specifically to be small in terms of
   both messages transported and implementation size and to be a schema-
   free decoder.  A need exists to provide message security services for
   IoT, and using CBOR as the message-encoding format makes sense.

   The JOSE Working Group produced a set of documents [RFC7515]
   [RFC7516] [RFC7517] [RFC7518] that specified how to process
   encryption, signatures, and Message Authentication Code (MAC)
   operations and how to encode keys using JSON.  This document defines
   the CBOR Object Signing and Encryption (COSE) standard, which does
   the same thing for the CBOR encoding format.  This document is
   combined with [RFC9053], which provides an initial set of algorithms.
   While there is a strong attempt to keep the flavor of the original
   JSON Object Signing and Encryption (JOSE) documents, two
   considerations are taken into account:

   *  CBOR has capabilities that are not present in JSON and are
      appropriate to use.  One example of this is the fact that CBOR has
      a method of encoding binary directly without first converting it
      into a base64-encoded text string.

   *  COSE is not a direct copy of the JOSE specification.  In the
      process of creating COSE, decisions that were made for JOSE were
      re-examined.  In many cases, different results were decided on, as
      the criteria were not always the same.

   This document contains:

   *  The description of the structure for the CBOR objects that are
      transmitted over the wire.  Two objects each are defined for
      encryption, signing, and message authentication.  One object is
      defined for transporting keys and one for transporting groups of
      keys.

   *  The procedures used to build the inputs to the cryptographic
      functions required for each of the structures.

   *  A set of attributes that apply to the different security objects.

   This document does not contain the rules and procedures for using
   specific cryptographic algorithms.  Details on specific algorithms
   can be found in [RFC9053] and [RFC8230].  Details for additional
   algorithms are expected to be defined in future documents.

   COSE was initially designed as part of a solution to provide security
   to Constrained RESTful Environments (CoRE), and this is done using
   [RFC8613] and [CORE-GROUPCOMM].  However, COSE is not restricted to
   just these cases and can be used in any place where one would
   consider either JOSE or Cryptographic Message Syntax (CMS) [RFC5652]
   for the purpose of providing security services.  COSE, like JOSE and
   CMS, is only for use in store-and-forward or offline protocols.  The
   use of COSE in online protocols needing encryption requires that an
   online key establishment process be done before sending objects back
   and forth.  Any application that uses COSE for security services
   first needs to determine what security services are required and then
   select the appropriate COSE structures and cryptographic algorithms
   based on those needs.  Section 10 provides additional information on
   what applications need to specify when using COSE.

   One feature that is present in CMS that is not present in this
   standard is a digest structure.  This omission is deliberate.  It is
   better for the structure to be defined in each protocol as different
   protocols will want to include a different set of fields as part of
   the structure.  While an algorithm identifier and the digest value
   are going to be common to all applications, the two values may not
   always be adjacent, as the algorithm could be defined once with
   multiple values.  Applications may additionally want to define
   additional data fields as part of the structure.  One such
   application-specific element would be to include a URI or other
   pointer to where the data that is being hashed can be obtained.
   [RFC9054] contains one such possible structure and defines a set of
   digest algorithms.

   During the process of advancing COSE to Internet Standard, it was
   noticed that the description of the security properties of
   countersignatures was incorrect for the COSE_Sign1 structure.  Since
   the security properties that were described -- those of a true
   countersignature -- were those that the working group desired, the
   decision was made to remove all of the countersignature text from
   this document and create a new document [COSE-COUNTERSIGN] to both
   deprecate the old countersignature algorithm and header parameters
   and define a new algorithm and header parameters with the desired
   security properties.

1.1.  Requirements Terminology

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
   "OPTIONAL" in this document are to be interpreted as described in
   BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all
   capitals, as shown here.

1.2.  Changes from RFC 8152

   *  Split the original document into this document and [RFC9053].

   *  Added some text describing why there is no digest structure
      defined by COSE.

   *  Made text clarifications and changes in terminology.

   *  Removed all of the details relating to countersignatures and
      placed in [COSE-COUNTERSIGN].

1.3.  Design Changes from JOSE

   *  A single overall message structure has been defined so that
      encrypted, signed, and MACed messages can easily be identified and
      still have a consistent view.

   *  Signed messages distinguish between the protected and unprotected
      header parameters that relate to the content and those that relate
      to the signature.

   *  MACed messages are separated from signed messages.

   *  MACed messages have the ability to use the same set of recipient
      algorithms as enveloped messages for obtaining the MAC
      authentication key.

   *  Binary encodings are used, rather than base64url encodings, to
      encode binary data.

   *  The authentication tag for encryption algorithms has been combined
      with the ciphertext.

   *  The set of cryptographic algorithms has been expanded in some
      directions and trimmed in others.

1.4.  CBOR Grammar

   There was not a standard CBOR grammar available when COSE was
   originally written.  For that reason, the CBOR data objects defined
   here are described in prose.  Since that time, Concise Data
   Definition Language (CDDL) [RFC8610] has been published as an RFC. RFC,
   providing such a data description grammar to describe CBOR.  The CBOR
   grammar presented in this document is compatible with CDDL.

   This document was developed by first working on the grammar and then
   developing the prose to go with it.  An artifact of this is that the
   prose was written using the primitive-type strings defined by Concise
   Data Definition Language (CDDL) [RFC8610].  In this specification,
   the following primitive types are used:

   any:  A nonspecific value that permits all CBOR values to be placed
      here.

   bool:  A boolean value (true: major type 7, value 21; false: major
      type 7, value 20).

   bstr:  Byte string (major type 2).

   int:  An unsigned integer or a negative integer.

   nil:  A null value (major type 7, value 22).

   nint:  A negative integer (major type 1).

   tstr:  A UTF-8 text string (major type 3).

   uint:  An unsigned integer (major type 0).

   Two syntaxes from CDDL appear in this document as shorthand.  These
   are:

   FOO / BAR:  Indicates that either FOO or BAR can appear here.

   [+ FOO]:  Indicates that the type FOO appears one or more times in an
      array.

   * FOO:  Indicates that the type FOO appears zero or more times.

   Two of the constraints defined by CDDL are also used in this
   document.  These are:

   type1 .cbor type2:  Indicates that the contents of type1, usually
      bstr, contains a value of type2.

   type1 .size integer:  Indicates that the contents of type1 is integer
      bytes long.

   As well as the prose description, a version of a CBOR grammar is
   presented in CDDL.  The CDDL grammar is informational; the prose
   description is normative.

   The collected CDDL can be extracted from the XML version of this
   document via the XPath expression below.  (Depending on the XPath
   evaluator one is using, it may be necessary to deal with > as an
   entity.)

   //sourcecode[@type='CDDL']/text()

   CDDL expects the initial nonterminal symbol to be the first symbol in
   the file.  For this reason, the first fragment of CDDL is presented
   here.

   start = COSE_Messages / COSE_Key / COSE_KeySet / Internal_Types

   ; This is defined to make the tool quieter:
   Internal_Types = Sig_structure / Enc_structure / MAC_structure

   The nonterminal Internal_Types is defined for dealing with the
   automated validation tools used during the writing of this document.
   It references those nonterminals that are used for security
   computations but are not emitted for transport.

1.5.  CBOR-Related Terminology

   In JSON, maps are called objects and only have one kind of map key: a
   text string.  In COSE, we use text strings, negative integers, and
   unsigned integers as map keys.  The integers are used for compactness
   of encoding and easy comparison.  The inclusion of text strings
   allows for an additional range of short encoded values to be used as
   well.  Since the word "key" is mainly used in its other meaning, as a
   cryptographic key, we use the term "label" for this usage as a map
   key.

   In a CBOR map, the presence a label that is neither a text string nor
   an integer is an error.  Applications can either fail processing or
   process messages by ignoring incorrect labels; however, they MUST NOT
   create messages with incorrect labels.

   A CDDL grammar fragment defines the nonterminal "label", as in the
   previous paragraph, and "values", which permits any value to be used.

   label = int / tstr
   values = any

1.6.  Document Terminology

   In this document, we use the following terminology:

   Byte is a synonym for octet.

   Constrained Application Protocol (CoAP) is a specialized web transfer
   protocol for use in constrained systems.  It is defined in [RFC7252].

   Authenticated Encryption (AE) [RFC5116] algorithms are encryption
   algorithms that provide an authentication check of the contents with
   the encryption service.  An example of an AE algorithm used in COSE
   is Advanced Encryption Standard (AES) Key Wrap [RFC3394].  These
   algorithms are used for key encryption algorithms, but Authenticated
   Encryption with Associated Data (AEAD) algorithms would be preferred.

   AEAD [RFC5116] algorithms provide the same authentication service of
   the content as AE algorithms do.  They also allow associated data
   that is not part of the encrypted body to be included in the
   authentication service.  An example of an AEAD algorithm used in COSE
   is AES in Galois/Counter Mode (GCM) [RFC5116].  These algorithms are
   used for content encryption and can be used for key encryption as
   well.

   "Context" is used throughout the document to represent information
   that is not part of the COSE message.  Information that is part of
   the context can come from several different sources, including
   protocol interactions, associated key structures, and program
   configuration.  The context to use can be implicit, identified using
   the "kid context" header parameter defined in [RFC8613], or
   identified by a protocol-specific identifier.  Context should
   generally be included in the cryptographic construction; for more
   details, see Section 4.3.

   The term "byte string" is used for sequences of bytes, while the term
   "text string" is used for sequences of characters.

2.  Basic COSE Structure

   The COSE object structure is designed so that there can be a large
   amount of common code when parsing and processing the different types
   of security messages.  All of the message structures are built on the
   CBOR array type.  The first three elements of the array always
   contain the same information:

   1.  The protected header parameters, encoded and wrapped in a bstr.

   2.  The unprotected header parameters as a map.

   3.  The content of the message.  The content is either the plaintext
       or the ciphertext, as appropriate.  The content may be detached
       (i.e., transported separately from the COSE structure), but the
       location is still used.  The content is wrapped in a bstr when
       present and is a nil value when detached.

   Elements after this point are dependent on the specific message type.

   COSE messages are built using the concept of layers to separate
   different types of cryptographic concepts.  As an example of how this
   works, consider the COSE_Encrypt message (Section 5.1).  This message
   type is broken into two layers: the content layer and the recipient
   layer.  The content layer contains the encrypted plaintext and
   information about the encrypted message.  The recipient layer
   contains the encrypted content encryption key (CEK) and information
   about how it is encrypted for each recipient.  A single-layer version
   of the encryption message COSE_Encrypt0 (Section 5.2) is provided for
   cases where the CEK is preshared.

   Identification of which type of message has been presented is done by
   the following methods:

   1.  The specific message type is known from the context.  This may be
       defined by a marker in the containing structure or by
       restrictions specified by the application protocol.

   2.  The message type is identified by a CBOR tag.  Messages with a
       CBOR tag are known in this specification as tagged messages,
       while those without the CBOR tag are known as untagged messages.
       This document defines a CBOR tag for each of the message
       structures.  These tags can be found in Table 1.

   3.  When a COSE object is carried in a media type of "application/
       cose", the optional parameter "cose-type" can be used to identify
       the embedded object.  The parameter is OPTIONAL if the tagged
       version of the structure is used.  The parameter is REQUIRED if
       the untagged version of the structure is used.  The value to use
       with the parameter for each of the structures can be found in
       Table 1.

   4.  When a COSE object is carried as a CoAP payload, the CoAP
       Content-Format Option can be used to identify the message
       content.  The CoAP Content-Format values can be found in Table 2.
       The CBOR tag for the message structure is not required, as each
       security message is uniquely identified.

   +==========+===============+===============+=======================+
   | CBOR Tag | cose-type     | Data Item     | Semantics             |
   +==========+===============+===============+=======================+
   | 98       | cose-sign     | COSE_Sign     | COSE Signed Data      |
   |          |               |               | Object                |
   +----------+---------------+---------------+-----------------------+
   | 18       | cose-sign1    | COSE_Sign1    | COSE Single Signer    |
   |          |               |               | Data Object           |
   +----------+---------------+---------------+-----------------------+
   | 96       | cose-encrypt  | COSE_Encrypt  | COSE Encrypted Data   |
   |          |               |               | Object                |
   +----------+---------------+---------------+-----------------------+
   | 16       | cose-encrypt0 | COSE_Encrypt0 | COSE Single Recipient |
   |          |               |               | Encrypted Data Object |
   +----------+---------------+---------------+-----------------------+
   | 97       | cose-mac      | COSE_Mac      | COSE MACed Data       |
   |          |               |               | Object                |
   +----------+---------------+---------------+-----------------------+
   | 17       | cose-mac0     | COSE_Mac0     | COSE Mac w/o          |
   |          |               |               | Recipients Object     |
   +----------+---------------+---------------+-----------------------+

                   Table 1: COSE Message Identification

        +===========================+==========+=====+===========+
        | Media Type                | Encoding | ID  | Reference |
        +===========================+==========+=====+===========+
        | application/cose; cose-   |          | 98  | RFC 9052  |
        | type="cose-sign"          |          |     |           |
        +---------------------------+----------+-----+-----------+
        | application/cose; cose-   |          | 18  | RFC 9052  |
        | type="cose-sign1"         |          |     |           |
        +---------------------------+----------+-----+-----------+
        | application/cose; cose-   |          | 96  | RFC 9052  |
        | type="cose-encrypt"       |          |     |           |
        +---------------------------+----------+-----+-----------+
        | application/cose; cose-   |          | 16  | RFC 9052  |
        | type="cose-encrypt0"      |          |     |           |
        +---------------------------+----------+-----+-----------+
        | application/cose; cose-   |          | 97  | RFC 9052  |
        | type="cose-mac"           |          |     |           |
        +---------------------------+----------+-----+-----------+
        | application/cose; cose-   |          | 17  | RFC 9052  |
        | type="cose-mac0"          |          |     |           |
        +---------------------------+----------+-----+-----------+
        | application/cose-key      |          | 101 | RFC 9052  |
        +---------------------------+----------+-----+-----------+
        | application/cose-key-set  |          | 102 | RFC 9052  |
        +---------------------------+----------+-----+-----------+

                  Table 2: CoAP Content-Formats for COSE

   The following CDDL fragment identifies all of the top messages
   defined in this document.  Separate nonterminals are defined for the
   tagged and untagged versions of the messages.

   COSE_Messages = COSE_Untagged_Message / COSE_Tagged_Message

   COSE_Untagged_Message = COSE_Sign / COSE_Sign1 /
       COSE_Encrypt / COSE_Encrypt0 /
       COSE_Mac / COSE_Mac0

   COSE_Tagged_Message = COSE_Sign_Tagged / COSE_Sign1_Tagged /
       COSE_Encrypt_Tagged / COSE_Encrypt0_Tagged /
       COSE_Mac_Tagged / COSE_Mac0_Tagged

3.  Header Parameters

   The structure of COSE has been designed to have two buckets of
   information that are not considered to be part of the payload itself,
   but are used for holding information about content, algorithms, keys,
   or evaluation hints for the processing of the layer.  These two
   buckets are available for use in all of the structures except for
   keys.  While these buckets are present, they may not always be usable
   in all instances.  For example, while the protected bucket is defined
   as part of the recipient structure, some of the algorithms used for
   recipient structures do not provide for authenticated data.  If this
   is the case, the protected bucket is left empty.

   Both buckets are implemented as CBOR maps.  The map key is a "label"
   (Section 1.5).  The value portion is dependent on the definition for
   the label.  Both maps use the same set of label/value pairs.  The
   integer and text-string values for labels have been divided into
   several sections, including a standard range, a private range, and a
   range that is dependent on the algorithm selected.  The defined
   labels can be found in the "COSE Header Parameters" IANA registry
   (Section 11.1).

   The two buckets are:

   protected:  Contains parameters about the current layer that are
      cryptographically protected.  This bucket MUST be empty if it is
      not going to be included in a cryptographic computation.  This
      bucket is encoded in the message as a binary object.  This value
      is obtained by CBOR encoding the protected map and wrapping it in
      a bstr object.  Senders SHOULD encode a zero-length map as a zero-
      length byte string rather than as a zero-length map (encoded as
      h'a0').  The zero-length binary encoding is preferred, because it
      is both shorter and the version used in the serialization
      structures for cryptographic computation.  Recipients MUST accept
      both a zero-length byte string and a zero-length map encoded in a
      byte string.

      Wrapping the encoding with a byte string allows the protected map
      to be transported with a greater chance that it will not be
      altered accidentally in transit.  (Badly behaved intermediates
      could decode and re-encode, but this will result in a failure to
      verify unless the re-encoded byte string is identical to the
      decoded byte string.)  This avoids the problem of all parties
      needing to be able to do a common canonical encoding of the map
      for input to crytographic operations.

   unprotected:  Contains parameters about the current layer that are
      not cryptographically protected.

   Only header parameters that deal with the current layer are to be
   placed at that layer.  As an example of this, the header parameter
   "content type" describes the content of the message being carried in
   the message.  As such, this header parameter is placed only in the
   content layer and is not placed in the recipient or signature layers.
   In principle, one should be able to process any given layer without
   reference to any other layer.  With the exception of the COSE_Sign
   structure, the only data that needs to cross layers is the
   cryptographic key.

   The buckets are present in all of the security objects defined in
   this document.  The fields, in order, are the "protected" bucket (as
   a CBOR "bstr" type) and then the "unprotected" bucket (as a CBOR
   "map" type).  The presence of both buckets is required.  The header
   parameters that go into the buckets come from the IANA "COSE Header
   Parameters" registry (Section 11.1).  Some header parameters are
   defined in the next section.

   Labels in each of the maps MUST be unique.  When processing messages,
   if a label appears multiple times, the message MUST be rejected as
   malformed.  Applications SHOULD verify that the same label does not
   occur in both the protected and unprotected header parameters.  If
   the message is not rejected as malformed, attributes MUST be obtained
   from the protected bucket, and only if not found are attributes
   obtained from the unprotected bucket.

   The following CDDL fragment represents the two header-parameter
   buckets.  A group "Headers" is defined in CDDL that represents the
   two buckets in which attributes are placed.  This group is used to
   provide these two fields consistently in all locations.  A type is
   also defined that represents the map of common header parameters.

   Headers = (
       protected : empty_or_serialized_map,
       unprotected : header_map
   )

   header_map = {
       Generic_Headers,
       * label => values
   }

   empty_or_serialized_map = bstr .cbor header_map / bstr .size 0

3.1.  Common COSE Header Parameters

   This section defines a set of common header parameters.  A summary of
   these header parameters can be found in Table 3.  This table should
   be consulted to determine the value of the label and the type of the
   value.

   The set of header parameters defined in this section is as follows:

   alg:  This header parameter is used to indicate the algorithm used
      for the security processing.  This header parameter MUST be
      authenticated where the ability to do so exists.  This support is
      provided by AEAD algorithms or construction (e.g., COSE_Sign and
      COSE_Mac0).  This authentication can be done either by placing the
      header parameter in the protected-header-parameter protected-header-parameters bucket or as
      part of the externally supplied data (Section 4.3).  The value is
      taken from the "COSE Algorithms" registry (see [COSE.Algorithms]).

   crit:  This header parameter is used to indicate which protected
      header parameters an application that is processing a message is
      required to understand.  Header parameters defined in this
      document do not need to be included, as they should be understood
      by all implementations.  When present, the "crit" header parameter
      MUST be placed in the protected-header-parameter protected-header-parameters bucket.  The
      array MUST have at least one value in it.

      Not all header-parameter labels need to be included in the "crit"
      header parameter.  The rules for deciding which header parameters
      are placed in the array are:

      *  Integer labels in the range of 0 to 7 SHOULD be omitted.

      *  Integer labels in the range -1 to -128 can be omitted.
         Algorithms can assign labels in this range where the ability to
         process the content of the label is considered to be core to
         implementing the algorithm.  Algorithms can assign labels
         outside of this range where the ability to process the content
         of the label is not considered to be core but needs to be
         understood to correctly process this instance.  Integer labels
         in the range -129 to -65536 SHOULD be included, as these would
         be less common header parameters that might not be generally
         supported.

      *  Labels for header parameters required for an application MAY be
         omitted.  Applications should have a statement if declaring
         whether or not the label can be omitted.

      The header parameters indicated by "crit" can be processed by
      either the security-library code or an application using a
      security library; the only requirement is that the header
      parameter is processed.  If the "crit" value list includes a label
      for which the header parameter is not in the protected-header-
      parameters bucket, this is a fatal error in processing the
      message.

   content type:  This header parameter is used to indicate the content
      type of the data in the "payload" or "ciphertext" fields.
      Integers are from the "CoAP Content-Formats" IANA registry table
      [COAP.Formats].  Text values follow the syntax of "<type-
      name>/<subtype-name>", where <type-name> and <subtype-name> are
      defined in Section 4.2 of [RFC6838].  Leading and trailing
      whitespace is also omitted.  Textual content values, along with
      parameters and subparameters, can be located using the IANA "Media
      Types" registry.  Applications SHOULD provide this header
      parameter if the content structure is potentially ambiguous.

   kid:  This header parameter identifies one piece of data that can be
      used as input to find the needed cryptographic key.  The value of
      this header parameter can be matched against the "kid" member in a
      COSE_Key structure.  Other methods of key distribution can define
      an equivalent field to be matched.  Applications MUST NOT assume
      that "kid" values are unique.  There may be more than one key with
      the same "kid" value, so all of the keys associated with this
      "kid" may need to be checked.  The internal structure of "kid"
      values is not defined and cannot be relied on by applications.
      Key identifier values are hints about which key to use.  This is
      not a security-critical field.  For this reason, it can be placed
      in the unprotected-header-parameters bucket.

   IV:  This header parameter holds the Initialization Vector (IV)
      value.  For some symmetric encryption algorithms, this may be
      referred to as a nonce.  The IV can be placed in the unprotected
      bucket, as modifying the IV will cause the decryption to yield
      plaintext that is readily detectable as garbled.

   Partial IV:  This header parameter holds a part of the IV value.
      When using the COSE_Encrypt0 structure, a portion of the IV can be
      part of the context associated with the key (Context IV), while a
      portion can be changed with each message (Partial IV).  This field
      is used to carry a value that causes the IV to be changed for each
      message.  The Partial IV can be placed in the unprotected bucket,
      as modifying the value will cause the decryption to yield
      plaintext that is readily detectable as garbled.  The
      "Initialization Vector" and "Partial Initialization Vector" header
      parameters MUST NOT both be present in the same security layer.

      The message IV is generated by the following steps:

      1.  Left-pad the Partial IV with zeros to the length of IV
          (determined by the algorithm).

      2.  XOR the padded Partial IV with the Context IV.

   +=========+=======+========+=====================+==================+
   | Name    | Label | Value  | Value Registry      | Description      |
   |         |       | Type   |                     |                  |
   +=========+=======+========+=====================+==================+
   | alg     | 1     | int /  | COSE Algorithms     | Cryptographic    |
   |         |       | tstr   | registry            | algorithm to use |
   +---------+-------+--------+---------------------+------------------+
   | crit    | 2     | [+     | COSE Header         | Critical header  |
   |         |       | label] | Parameters          | parameters to be |
   |         |       |        | registry            | understood       |
   +---------+-------+--------+---------------------+------------------+
   | content | 3     | tstr / | CoAP Content-       | Content type of  |
   | type    |       | uint   | Formats or Media    | the payload      |
   |         |       |        | Types registries    |                  |
   +---------+-------+--------+---------------------+------------------+
   | kid     | 4     | bstr   |                     | Key identifier   |
   +---------+-------+--------+---------------------+------------------+
   | IV      | 5     | bstr   |                     | Full             |
   |         |       |        |                     | Initialization   |
   |         |       |        |                     | Vector           |
   +---------+-------+--------+---------------------+------------------+
   | Partial | 6     | bstr   |                     | Partial          |
   | IV      |       |        |                     | Initialization   |
   |         |       |        |                     | Vector           |
   +---------+-------+--------+---------------------+------------------+

                     Table 3: Common Header Parameters

   The CDDL fragment that represents the set of header parameters
   defined in this section is given below.  Each of the header
   parameters is tagged as optional, because they do not need to be in
   every map; header parameters required in specific maps are discussed
   above.

   Generic_Headers = (
       ? 1 => int / tstr,  ; algorithm identifier
       ? 2 => [+label],    ; criticality
       ? 3 => tstr / int,  ; content type
       ? 4 => bstr,        ; key identifier
       ? 5 => bstr,        ; IV
       ? 6 => bstr         ; Partial IV
   )

4.  Signing Objects

   COSE supports two different signature structures.  COSE_Sign allows
   for one or more signatures to be applied to the same content.
   COSE_Sign1 is restricted to a single signer.  The structures cannot
   be converted between each other; as the signature computation
   includes a parameter identifying which structure is being used, the
   converted structure will fail signature validation.

4.1.  Signing with One or More Signers

   The COSE_Sign structure allows for one or more signatures to be
   applied to a message payload.  Header parameters relating to the
   content and header parameters relating to the signature are carried
   along with the signature itself.  These header parameters may be
   authenticated by the signature, or just be present.  An example of a
   header parameter about the content is the content type header
   parameter.  An example of a header parameter about the signature
   would be the algorithm and key used to create the signature.

   RFC 5652 indicates that:

   |  When more than one signature is present, the successful validation
   |  of one signature associated with a given signer is usually treated
   |  as a successful signature by that signer.  However, there are some
   |  application environments where other rules are needed.  An
   |  application that employs a rule other than one valid signature for
   |  each signer must specify those rules.  Also, where simple matching
   |  of the signer identifier is not sufficient to determine whether
   |  the signatures were generated by the same signer, the application
   |  specification must describe how to determine which signatures were
   |  generated by the same signer.  Support of different communities of
   |  recipients is the primary reason that signers choose to include
   |  more than one signature.

   For example, the COSE_Sign structure might include signatures
   generated with the Edwards-curve Digital Signature Algorithm (EdDSA)
   [RFC8032] and the Elliptic Curve Digital Signature Algorithm (ECDSA)
   [DSS].  This allows recipients to verify the signature associated
   with one algorithm or the other.  More detailed information on
   multiple signature evaluations can be found in [RFC5752].

   The signature structure can be encoded as either tagged or untagged,
   depending on the context it will be used in.  A tagged COSE_Sign
   structure is identified by the CBOR tag 98.  The CDDL fragment that
   represents this is:

   COSE_Sign_Tagged = #6.98(COSE_Sign)

   A COSE Signed Message is defined in two parts.  The CBOR object that
   carries the body and information about the body is called the
   COSE_Sign structure.  The CBOR object that carries the signature and
   information about the signature is called the COSE_Signature
   structure.  Examples of COSE Signed Messages can be found in
   Appendix C.1.

   The COSE_Sign structure is a CBOR array.  The fields of the array, in
   order, are:

   protected:  This is as described in Section 3.

   unprotected:  This is as described in Section 3.

   payload:  This field contains the serialized content to be signed.
      If the payload is not present in the message, the application is
      required to supply the payload separately.  The payload is wrapped
      in a bstr to ensure that it is transported without changes.  If
      the payload is transported separately ("detached content"), then a
      nil CBOR object is placed in this location, and it is the
      responsibility of the application to ensure that it will be
      transported without changes.

      Note: When a signature with a message recovery algorithm is used
      (Section 8.1), the maximum number of bytes that can be recovered
      is the length of the original payload.  The size of the encoded
      payload is reduced by the number of bytes that will be recovered.
      If all of the bytes of the original payload are consumed, then the
      transmitted payload is encoded as a zero-length byte string rather
      than as being absent.

   signatures:  This field is an array of signatures.  Each signature is
      represented as a COSE_Signature structure.

   The CDDL fragment that represents the above text for COSE_Sign
   follows.

   COSE_Sign = [
       Headers,
       payload : bstr / nil,
       signatures : [+ COSE_Signature]
   ]

   The COSE_Signature structure is a CBOR array.  The fields of the
   array, in order, are:

   protected:  This is as described in Section 3.

   unprotected:  This is as described in Section 3.

   signature:  This field contains the computed signature value.  The
      type of the field is a bstr.  Algorithms MUST specify padding if
      the signature value is not a multiple of 8 bits.

   The CDDL fragment that represents the above text for COSE_Signature
   follows.

   COSE_Signature =  [
       Headers,
       signature : bstr
   ]

4.2.  Signing with One Signer

   The COSE_Sign1 signature structure is used when only one signature is
   going to be placed on a message.  The header parameters dealing with
   the content and the signature are placed in the same pair of buckets,
   rather than having the separation of COSE_Sign.

   The structure can be encoded as either tagged or untagged depending
   on the context it will be used in.  A tagged COSE_Sign1 structure is
   identified by the CBOR tag 18.  The CDDL fragment that represents
   this is:

   COSE_Sign1_Tagged = #6.18(COSE_Sign1)

   The CBOR object that carries the body, the signature, and the
   information about the body and signature is called the COSE_Sign1
   structure.  Examples of COSE_Sign1 messages can be found in
   Appendix C.2.

   The COSE_Sign1 structure is a CBOR array.  The fields of the array,
   in order, are:

   protected:  This is as described in Section 3.

   unprotected:  This is as described in Section 3.

   payload:  This is as described in Section 4.1.

   signature:  This field contains the computed signature value.  The
      type of the field is a bstr.

   The CDDL fragment that represents the above text for COSE_Sign1
   follows.

   COSE_Sign1 = [
       Headers,
       payload : bstr / nil,
       signature : bstr
   ]

4.3.  Externally Supplied Data

   One of the features offered in the COSE document is the ability for
   applications to provide additional data that is to be authenticated
   but is not carried as part of the COSE object.  The primary reason
   for supporting this can be seen by looking at the CoAP message
   structure [RFC7252], where the facility exists for options to be
   carried before the payload.  Examples of data that can be placed in
   this location would be the CoAP code or CoAP options.  If the data is
   in the headers of the CoAP message, then it is available for proxies
   to help in performing its proxying operations.  For example, the Accept
   option can be used by a proxy to determine if an appropriate value is
   in the proxy's cache.  But the sender can cause a failure at the
   server if a proxy, or an attacker, changes the set of Accept values
   by including the field in the externally supplied data.

   This document describes the process for using a byte array of
   externally supplied authenticated data; the method of constructing
   the byte array is a function of the application.  Applications that
   use this feature need to define how the externally supplied
   authenticated data is to be constructed.  Such a construction needs
   to take into account the following issues:

   *  If multiple items are included, applications need to ensure that
      the same byte string cannot be produced if there are different
      inputs.  This would occur by concatenating the text strings "AB"
      and "CDE" or by concatenating the text strings "ABC" and "DE".
      This is usually addressed by making fields a fixed width and/or
      encoding the length of the field as part of the output.  Using
      options from CoAP [RFC7252] as an example, these fields use a TLV
      structure so they can be concatenated without any problems.

   *  If multiple items are included, an order for the items needs to be
      defined.  Using options from CoAP as an example, an application
      could state that the fields are to be ordered by the option
      number.

   *  Applications need to ensure that the byte string is going to be
      the same on both sides.  Using options from CoAP might give a
      problem if the same relative numbering is kept.  An intermediate
      node could insert or remove an option, changing how the relative
      numbering is done.  An application would need to specify that the
      relative number must be re-encoded to be relative only to the
      options that are in the external data.

4.4.  Signing and Verification Process

   In order to create a signature, a well-defined byte string is needed.
   The Sig_structure is used to create the canonical form.  This signing
   and verification process takes in the body information (COSE_Sign or
   COSE_Sign1), the signer information (COSE_Signature), and the
   application data (external source).  A Sig_structure is a CBOR array.
   The fields of the Sig_structure, in order, are:

   1.  A context text string identifying the context of the signature.
       The context text string is:

          "Signature" for signatures using the COSE_Signature structure.

          "Signature1" for signatures using the COSE_Sign1 structure.

   2.  The protected attributes from the body structure, encoded in a
       bstr type.  If there are no protected attributes, a zero-length
       byte string is used.

   3.  The protected attributes from the signer structure, encoded in a
       bstr type.  If there are no protected attributes, a zero-length
       byte string is used.  This field is omitted for the COSE_Sign1
       signature structure.

   4.  The externally supplied data from the application, encoded in a
       bstr type.  If this field is not supplied, it defaults to a zero-
       length byte string.  (See Section 4.3 for application guidance on
       constructing this field.)

   5.  The payload to be signed, encoded in a bstr type.  The payload is
       placed here, independent of how it is transported.

   The CDDL fragment that describes the above text is:

   Sig_structure = [
       context : "Signature" / "Signature1",
       body_protected : empty_or_serialized_map,
       ? sign_protected : empty_or_serialized_map,
       external_aad : bstr,
       payload : bstr
   ]

   How to compute a signature:

   1.  Create a Sig_structure and populate it with the appropriate
       fields.

   2.  Create the value ToBeSigned by encoding the Sig_structure to a
       byte string, using the encoding described in Section 9.

   3.  Call the signature creation algorithm, passing in K (the key to
       sign with), alg (the algorithm to sign with), and ToBeSigned (the
       value to sign).

   4.  Place the resulting signature value in the correct location.
       This is the "signature" field of the COSE_Signature or COSE_Sign1
       structure.

   The steps for verifying a signature are:

   1.  Create a Sig_structure and populate it with the appropriate
       fields.

   2.  Create the value ToBeSigned by encoding the Sig_structure to a
       byte string, using the encoding described in Section 9.

   3.  Call the signature verification algorithm, passing in K (the key
       to verify with), alg (the algorithm used to sign with),
       ToBeSigned (the value to sign), and sig (the signature to be
       verified).

   In addition to performing the signature verification, the application
   performs the appropriate checks to ensure that the key is correctly
   paired with the signing identity and that the signing identity is
   authorized before performing actions.

5.  Encryption Objects

   COSE supports two different encryption structures.  COSE_Encrypt0 is
   used when a recipient structure is not needed because the key to be
   used is known implicitly.  COSE_Encrypt is used the rest of the time.
   This includes cases where there are multiple recipients or a
   recipient algorithm other than direct (i.e., preshared secret) is
   used.

5.1.  Enveloped COSE Structure

   The enveloped structure allows for one or more recipients of a
   message.  There are provisions for header parameters about the
   content and header parameters about the recipient information to be
   carried in the message.  The protected header parameters associated
   with the content are authenticated by the content encryption
   algorithm.  The protected header parameters associated with the
   recipient are authenticated by the recipient algorithm (when the
   algorithm supports it).  Examples of header parameters about the
   content are the type of the content and the content encryption
   algorithm.  Examples of header parameters about the recipient are the
   recipient's key identifier and the recipient's encryption algorithm.

   The same techniques and nearly the same structure are used for
   encrypting both the plaintext and the keys.  This is different from
   the approach used by both "Cryptographic Message Syntax (CMS)"
   [RFC5652] and "JSON Web Encryption (JWE)" [RFC7516], where different
   structures are used for the content layer and the recipient layer.
   Two structures are defined: COSE_Encrypt to hold the encrypted
   content and COSE_recipient to hold the encrypted keys for recipients.
   Examples of encrypted messages can be found in Appendix C.3.

   The COSE_Encrypt structure can be encoded as either tagged or
   untagged, depending on the context it will be used in.  A tagged
   COSE_Encrypt structure is identified by the CBOR tag 96.  The CDDL
   fragment that represents this is:

   COSE_Encrypt_Tagged = #6.96(COSE_Encrypt)

   The COSE_Encrypt structure is a CBOR array.  The fields of the array,
   in order, are:

   protected:  This is as described in Section 3.

   unprotected:  This is as described in Section 3.

   ciphertext:  This field contains the ciphertext, encoded as a bstr.
      If the ciphertext is to be transported independently of the
      control information about the encryption process (i.e., detached
      content), then the field is encoded as a nil value.

   recipients:  This field contains an array of recipient information
      structures.  The type for the recipient information structure is a
      COSE_recipient.

   The CDDL fragment that corresponds to the above text is:

   COSE_Encrypt = [
       Headers,
       ciphertext : bstr / nil,
       recipients : [+COSE_recipient]
   ]

   The COSE_recipient structure is a CBOR array.  The fields of the
   array, in order, are:

   protected:  This is as described in Section 3.

   unprotected:  This is as described in Section 3.

   ciphertext:  This field contains the encrypted key, encoded as a
      bstr.  All encoded keys are symmetric keys; the binary value of
      the key is the content.  If there is not an encrypted key, then
      this field is encoded as a nil value.

   recipients:  This field contains an array of recipient information
      structures.  The type for the recipient information structure is a
      COSE_recipient (an example of this can be found in Appendix B).
      If there are no recipient information structures, this element is
      absent.

   The CDDL fragment that corresponds to the above text for
   COSE_recipient is:

   COSE_recipient = [
       Headers,
       ciphertext : bstr / nil,
       ? recipients : [+COSE_recipient]
   ]

5.1.1.  Content Key Distribution Methods

   An encrypted message consists of an encrypted content and an
   encrypted CEK for one or more recipients.  The CEK is encrypted for
   each recipient, using a key specific to that recipient.  The details
   of this encryption depend on which class the recipient algorithm
   falls into.  Specific details on each of the classes can be found in
   Section 8.5.  A short summary of the five content key distribution
   methods is:

   direct:  The CEK is the same as the identified previously distributed
      symmetric key or is derived from a previously distributed secret.
      No CEK is transported in the message.

   symmetric key-encryption keys (KEKs):  The CEK is encrypted using a
      previously distributed symmetric KEK.  Also known as key wrap.

   key agreement:  The recipient's public key and a sender's private key
      are used to generate a pairwise secret, a Key Derivation Function
      (KDF) is applied to derive a key, and then the CEK is either the
      derived key or encrypted by the derived key.

   key transport:  The CEK is encrypted with the recipient's public key.

   passwords:  The CEK is encrypted in a KEK that is derived from a
      password.  As of when this document was published, no password
      algorithms have been defined.

5.2.  Single Recipient Encrypted

   The COSE_Encrypt0 encrypted structure does not have the ability to
   specify recipients of the message.  The structure assumes that the
   recipient of the object will already know the identity of the key to
   be used in order to decrypt the message.  If a key needs to be
   identified to the recipient, the enveloped structure ought to be
   used.

   Examples of encrypted messages can be found in Appendix C.3.

   The COSE_Encrypt0 structure can be encoded as either tagged or
   untagged, depending on the context it will be used in.  A tagged
   COSE_Encrypt0 structure is identified by the CBOR tag 16.  The CDDL
   fragment that represents this is:

   COSE_Encrypt0_Tagged = #6.16(COSE_Encrypt0)

   The COSE_Encrypt0 structure is a CBOR array.  The fields of the
   array, in order, are:

   protected:  This is as described in Section 3.

   unprotected:  This is as described in Section 3.

   ciphertext:  This is as described in Section 5.1.

   The CDDL fragment for COSE_Encrypt0 that corresponds to the above
   text is:

   COSE_Encrypt0 = [
       Headers,
       ciphertext : bstr / nil,
   ]

5.3.  How to Encrypt and Decrypt for AEAD Algorithms

   The encryption algorithm for AEAD algorithms is fairly simple.  The
   first step is to create a consistent byte string for the
   authenticated data structure.  For this purpose, we use an
   Enc_structure.  The Enc_structure is a CBOR array.  The fields of the
   Enc_structure, in order, are:

   1.  A context text string identifying the context of the
       authenticated data structure.  The context text string is:

          "Encrypt0" for the content encryption of a COSE_Encrypt0 data
          structure.

          "Encrypt" for the first layer of a COSE_Encrypt data structure
          (i.e., for content encryption).

          "Enc_Recipient" for a recipient encoding to be placed in a
          COSE_Encrypt data structure.

          "Mac_Recipient" for a recipient encoding to be placed in a
          MACed message structure.

          "Rec_Recipient" for a recipient encoding to be placed in a
          recipient structure.

   2.  The protected attributes from the body structure, encoded in a
       bstr type.  If there are no protected attributes, a zero-length
       byte string is used.

   3.  The externally supplied data from the application encoded in a
       bstr type.  If this field is not supplied, it defaults to a zero-
       length byte string.  (See Section 4.3 for application guidance on
       constructing this field.)

   The CDDL fragment that describes the above text is:

   Enc_structure = [
       context : "Encrypt" / "Encrypt0" / "Enc_Recipient" /
           "Mac_Recipient" / "Rec_Recipient",
       protected : empty_or_serialized_map,
       external_aad : bstr
   ]

   How to encrypt a message:

   1.  Create an Enc_structure and populate it with the appropriate
       fields.

   2.  Encode the Enc_structure to a byte string (Additional
       Authenticated Data (AAD)), using the encoding described in
       Section 9.

   3.  Determine the encryption key (K).  This step is dependent on the
       class of recipient algorithm being used.  For:

       No Recipients:  The key to be used is determined by the algorithm
          and key at the current layer.  Examples are key transport keys
          (Section 8.5.3), key wrap keys (Section 8.5.2), and preshared
          secrets.

       Direct Encryption and Direct Key Agreement:  The key is
          determined by the key and algorithm in the recipient
          structure.  The encryption algorithm and size of the key to be
          used are inputs into the KDF used for the recipient.  (For
          direct, the KDF can be thought of as the identity operation.)
          Examples of these algorithms are found in Sections 6.1.2 and
          6.3 of [RFC9053].

       Other:  The key is randomly or pseudorandomly generated.

   4.  Call the encryption algorithm with K (the encryption key), P (the
       plaintext), and AAD.  Place the returned ciphertext into the
       "ciphertext" field of the structure.

   5.  For recipients of the message, recursively perform the encryption
       algorithm for that recipient, using K (the encryption key) as the
       plaintext.

   How to decrypt a message:

   1.  Create an Enc_structure and populate it with the appropriate
       fields.

   2.  Encode the Enc_structure to a byte string (AAD), using the
       encoding described in Section 9.

   3.  Determine the decryption key.  This step is dependent on the
       class of recipient algorithm being used.  For:

       No Recipients:  The key to be used is determined by the algorithm
          and key at the current layer.  Examples are key transport keys
          (Section 8.5.3), key wrap keys (Section 8.5.2), and preshared
          secrets.

       Direct Encryption and Direct Key Agreement:  The key is
          determined by the key and algorithm in the recipient
          structure.  The encryption algorithm and size of the key to be
          used are inputs into the KDF used for the recipient.  (For
          direct, the KDF can be thought of as the identity operation.)

       Other:  The key is determined by decoding and decrypting one of
          the recipient structures.

   4.  Call the decryption algorithm with K (the decryption key to use),
       C (the ciphertext), and AAD.

5.4.  How to Encrypt and Decrypt for AE Algorithms

   How to encrypt a message:

   1.  Verify that the "protected" field is empty.

   2.  Verify that there was no external additional authenticated data
       supplied for this operation.

   3.  Determine the encryption key.  This step is dependent on the
       class of recipient algorithm being used.  For:

       No Recipients:  The key to be used is determined by the algorithm
          and key at the current layer.  Examples are key transport keys
          (Section 8.5.3), key wrap keys (Section 8.5.2), and preshared
          secrets.

       Direct Encryption and Direct Key Agreement:  The key is
          determined by the key and algorithm in the recipient
          structure.  The encryption algorithm and size of the key to be
          used are inputs into the KDF used for the recipient.  (For
          direct, the KDF can be thought of as the identity operation.)
          Examples of these algorithms are found in Sections 6.1.2 and
          6.3 of [RFC9053].

       Other:  The key is randomly generated.

   4.  Call the encryption algorithm with K (the encryption key to use)
       and P (the plaintext).  Place the returned ciphertext into the
       "ciphertext" field of the structure.

   5.  For recipients of the message, recursively perform the encryption
       algorithm for that recipient, using K (the encryption key) as the
       plaintext.

   How to decrypt a message:

   1.  Verify that the "protected" field is empty.

   2.  Verify that there was no external additional authenticated data
       supplied for this operation.

   3.  Determine the decryption key.  This step is dependent on the
       class of recipient algorithm being used.  For:

       No Recipients:  The key to be used is determined by the algorithm
          and key at the current layer.  Examples are key transport keys
          (Section 8.5.3), key wrap keys (Section 8.5.2), and preshared
          secrets.

       Direct Encryption and Direct Key Agreement:  The key is
          determined by the key and algorithm in the recipient
          structure.  The encryption algorithm and size of the key to be
          used are inputs into the KDF used for the recipient.  (For
          direct, the KDF can be thought of as the identity operation.)
          Examples of these algorithms are found in Sections 6.1.2 and
          6.3 of [RFC9053].

       Other:  The key is determined by decoding and decrypting one of
          the recipient structures.

   4.  Call the decryption algorithm with K (the decryption key to use)
       and C (the ciphertext).

6.  MAC Objects

   COSE supports two different MAC structures.  COSE_MAC0 is used when a
   recipient structure is not needed because the key to be used is
   implicitly known.  COSE_MAC is used for all other cases.  These
   include a requirement for multiple recipients, the key being unknown,
   or a recipient algorithm other than direct.

   In this section, we describe the structure and methods to be used
   when doing MAC authentication in COSE.  This document allows for the
   use of all of the same classes of recipient algorithms as are allowed
   for encryption.

   There are two modes in which MAC operations can be used.  The first
   is just a check that the content has not been changed since the MAC
   was computed.  Any class of recipient algorithm can be used for this
   purpose.  The second mode is to both check that the content has not
   been changed since the MAC was computed and use the recipient
   algorithm to verify who sent it.  The classes of recipient algorithms
   that support this are those that use a preshared secret or do static-
   static Static-
   Static (SS) key agreement (without the key wrap step).  In both of
   these cases, the entity that created and sent the message MAC can be
   validated.  (This knowledge of the sender assumes that there are only
   two parties involved and that you did not send the message to
   yourself.)  The origination property can be obtained with both of the
   MAC message structures.

6.1.  MACed Message with Recipients

   A multiple-recipient MACed message uses two structures: the COSE_Mac
   structure defined in this section for carrying the body and the
   COSE_recipient structure (Section 5.1) to hold the key used for the
   MAC computation.  Examples of MACed messages can be found in
   Appendix C.5.

   The MAC structure can be encoded as either tagged or untagged
   depending on the context it will be used in.  A tagged COSE_Mac
   structure is identified by the CBOR tag 97.  The CDDL fragment that
   represents this is:

   COSE_Mac_Tagged = #6.97(COSE_Mac)

   The COSE_Mac structure is a CBOR array.  The fields of the array, in
   order, are:

   protected:  This is as described in Section 3.

   unprotected:  This is as described in Section 3.

   payload:  This field contains the serialized content to be MACed.  If
      the payload is not present in the message, the application is
      required to supply the payload separately.  The payload is wrapped
      in a bstr to ensure that it is transported without changes.  If
      the payload is transported separately (i.e., detached content),
      then a nil CBOR value is placed in this location, and it is the
      responsibility of the application to ensure that it will be
      transported without changes.

   tag:  This field contains the MAC value.

   recipients:  This is as described in Section 5.1.

   The CDDL fragment that represents the above text for COSE_Mac
   follows.

   COSE_Mac = [
      Headers,
      payload : bstr / nil,
      tag : bstr,
      recipients :[+COSE_recipient]
   ]

6.2.  MACed Messages with Implicit Key

   In this section, we describe the structure and methods to be used
   when doing MAC authentication for those cases where the recipient is
   implicitly known.

   The MACed message uses the COSE_Mac0 structure defined in this
   section for carrying the body.  Examples of MACed messages with an
   implicit key can be found in Appendix C.6.

   The MAC structure can be encoded as either tagged or untagged,
   depending on the context it will be used in.  A tagged COSE_Mac0
   structure is identified by the CBOR tag 17.  The CDDL fragment that
   represents this is:

   COSE_Mac0_Tagged = #6.17(COSE_Mac0)

   The COSE_Mac0 structure is a CBOR array.  The fields of the array, in
   order, are:

   protected:  This is as described in Section 3.

   unprotected:  This is as described in Section 3.

   payload:  This is as described in Section 6.1.

   tag:  This field contains the MAC value.

   The CDDL fragment that corresponds to the above text is:

   COSE_Mac0 = [
      Headers,
      payload : bstr / nil,
      tag : bstr,
   ]

6.3.  How to Compute and Verify a MAC

   In order to get a consistent encoding of the data to be
   authenticated, the MAC_structure is used to have a canonical form.
   The MAC_structure is a CBOR array.  The fields of the MAC_structure,
   in order, are:

   1.  A context text string that identifies the structure that is being
       encoded.  This context text string is "MAC" for the COSE_Mac
       structure.  This context text string is "MAC0" for the COSE_Mac0
       structure.

   2.  The protected attributes from the COSE_MAC structure.  If there
       are no protected attributes, a zero-length bstr is used.

   3.  The externally supplied data from the application, encoded as a
       bstr type.  If this field is not supplied, it defaults to a zero-
       length byte string.  (See Section 4.3 for application guidance on
       constructing this field.)

   4.  The payload to be MACed, encoded in a bstr type.  The payload is
       placed here, independent of how it is transported.

   The CDDL fragment that corresponds to the above text is:

   MAC_structure = [
        context : "MAC" / "MAC0",
        protected : empty_or_serialized_map,
        external_aad : bstr,
        payload : bstr
   ]

   The steps to compute a MAC are:

   1.  Create a MAC_structure and populate it with the appropriate
       fields.

   2.  Create the value ToBeMaced by encoding the MAC_structure to a
       byte string, using the encoding described in Section 9.

   3.  Call the MAC creation algorithm, passing in K (the key to use),
       alg (the algorithm to MAC with), and ToBeMaced (the value to
       compute the MAC on).

   4.  Place the resulting MAC in the "tag" field of the COSE_Mac or
       COSE_Mac0 structure.

   5.  For COSE_Mac structures, encrypt and encode the MAC key for each
       recipient of the message.

   The steps to verify a MAC are:

   1.  Create a MAC_structure and populate it with the appropriate
       fields.

   2.  Create the value ToBeMaced by encoding the MAC_structure to a
       byte string, using the encoding described in Section 9.

   3.  For COSE_Mac structures, obtain the cryptographic key from one of
       the recipients of the message.

   4.  Call the MAC creation algorithm, passing in K (the key to use),
       alg (the algorithm to MAC with), and ToBeMaced (the value to
       compute the MAC on).

   5.  Compare the MAC value to the "tag" field of the COSE_Mac or
       COSE_Mac0 structure.

7.  Key Objects

   A COSE Key structure is built on a CBOR map.  The set of common
   parameters that can appear in a COSE Key can be found in the IANA
   "COSE Key Common Parameters" registry (Section [COSE.KeyParameters] (see
   Section 11.2).  Additional parameters defined for specific key types
   can be found in the IANA "COSE Key Type Parameters" registry
   [COSE.KeyTypes].

   A COSE Key Set uses a CBOR array object as its underlying type.  The
   values of the array elements are COSE Keys.  A COSE Key Set MUST have
   at least one element in the array.  Examples of COSE Key Sets can be
   found in Appendix C.7.

   Each element in a COSE Key Set MUST be processed independently.  If
   one element in a COSE Key Set is either malformed or uses a key that
   is not understood by an application, that key is ignored, and the
   other keys are processed normally.

   The element "kty" is a required element in a COSE_Key map.

   The CDDL grammar describing COSE_Key and COSE_KeySet is:

   COSE_Key = {
       1 => tstr / int,          ; kty
       ? 2 => bstr,              ; kid
       ? 3 => tstr / int,        ; alg
       ? 4 => [+ (tstr / int) ], ; key_ops
       ? 5 => bstr,              ; Base IV
       * label => values
   }

   COSE_KeySet = [+COSE_Key]

7.1.  COSE Key Common Parameters

   This document defines a set of common parameters for a COSE Key
   object.  Table 4 provides a summary of the parameters defined in this
   section.  There are also parameters that are defined for specific key
   types.  Key-type-specific parameters can be found in [RFC9053].

      +=========+=======+========+============+====================+
      | Name    | Label | CBOR   | Value      | Description        |
      |         |       | Type   | Registry   |                    |
      +=========+=======+========+============+====================+
      | kty     | 1     | tstr / | COSE Key   | Identification of  |
      |         |       | int    | Types      | the key type       |
      +---------+-------+--------+------------+--------------------+
      | kid     | 2     | bstr   |            | Key identification |
      |         |       |        |            | value -- match to  |
      |         |       |        |            | "kid" in message   |
      +---------+-------+--------+------------+--------------------+
      | alg     | 3     | tstr / | COSE       | Key usage          |
      |         |       | int    | Algorithms | restriction to     |
      |         |       |        |            | this algorithm     |
      +---------+-------+--------+------------+--------------------+
      | key_ops | 4     | [+     |            | Restrict set of    |
      |         |       | (tstr/ |            | permissible        |
      |         |       | int)]  |            | operations         |
      +---------+-------+--------+------------+--------------------+
      | Base IV | 5     | bstr   |            | Base IV to be xor- |
      |         |       |        |            | ed with Partial    |
      |         |       |        |            | IVs                |
      +---------+-------+--------+------------+--------------------+

                         Table 4: Key Map Labels

   kty:  This parameter is used to identify the family of keys for this
      structure and, thus, the set of key-type-specific parameters to be
      found.  The set of values defined in this document can be found in
      [COSE.KeyTypes].  This parameter MUST be present in a key object.
      Implementations MUST verify that the key type is appropriate for
      the algorithm being processed.  The key type MUST be included as
      part of the trust-decision process.

   alg:  This parameter is used to restrict the algorithm that is used
      with the key.  If this parameter is present in the key structure,
      the application MUST verify that this algorithm matches the
      algorithm for which the key is being used.  If the algorithms do
      not match, then this key object MUST NOT be used to perform the
      cryptographic operation.  Note that the same key can be in a
      different key structure with a different or no algorithm
      specified; however, this is considered to be a poor security
      practice.

   kid:  This parameter is used to give an identifier for a key.  The
      identifier is not structured and can be anything from a user-
      provided byte string to a value computed on the public portion of
      the key.  This field is intended for matching against a "kid"
      parameter in a message in order to filter down the set of keys
      that need to be checked.  The value of the identifier is not a
      unique value and can occur in other key objects, even for
      different keys.

   key_ops:  This parameter is defined to restrict the set of operations
      that a key is to be used for.  The value of the field is an array
      of values from Table 5.  Algorithms define the values of key ops
      that are permitted to appear and are required for specific
      operations.  The set of values matches that in [RFC7517] and
      [W3C.WebCrypto].

   Base IV:  This parameter is defined to carry the base portion of an
      IV.  It is designed to be used with the Partial IV header
      parameter defined in Section 3.1.  This field provides the ability
      to associate a Base IV with a key that is then modified on a per-
      message basis with the Partial IV.

      Extreme care needs to be taken when using a Base IV in an
      application.  Many encryption algorithms lose security if the same
      IV is used twice.

      If different keys are derived for each sender, starting at the
      same Base IV is likely to satisfy this condition.  If the same key
      is used for multiple senders, then the application needs to
      provide for a method of dividing the IV space up between the
      senders.  This could be done by providing a different base point
      to start from or a different Partial IV to start with and
      restricting the number of messages to be sent before rekeying.

    +=========+=======+==============================================+
    | Name    | Value | Description                                  |
    +=========+=======+==============================================+
    | sign    | 1     | The key is used to create signatures.        |
    |         |       | Requires private key fields.                 |
    +---------+-------+----------------------------------------------+
    | verify  | 2     | The key is used for verification of          |
    |         |       | signatures.                                  |
    +---------+-------+----------------------------------------------+
    | encrypt | 3     | The key is used for key transport            |
    |         |       | encryption.                                  |
    +---------+-------+----------------------------------------------+
    | decrypt | 4     | The key is used for key transport            |
    |         |       | decryption.  Requires private key fields.    |
    +---------+-------+----------------------------------------------+
    | wrap    | 5     | The key is used for key wrap encryption.     |
    | key     |       |                                              |
    +---------+-------+----------------------------------------------+
    | unwrap  | 6     | The key is used for key wrap decryption.     |
    | key     |       | Requires private key fields.                 |
    +---------+-------+----------------------------------------------+
    | derive  | 7     | The key is used for deriving keys.  Requires |
    | key     |       | private key fields.                          |
    +---------+-------+----------------------------------------------+
    | derive  | 8     | The key is used for deriving bits not to be  |
    | bits    |       | used as a key.  Requires private key fields. |
    +---------+-------+----------------------------------------------+
    | MAC     | 9     | The key is used for creating MACs.           |
    | create  |       |                                              |
    +---------+-------+----------------------------------------------+
    | MAC     | 10    | The key is used for validating MACs.         |
    | verify  |       |                                              |
    +---------+-------+----------------------------------------------+

                      Table 5: Key Operation Values

8.  Taxonomy of Algorithms Used by COSE

   In this section, a taxonomy of the different algorithm types that can
   be used in COSE is laid out.  This taxonomy should not be considered
   to be exhaustive.  New algorithms will be created that will not fit
   into this taxonomy.

8.1.  Signature Algorithms

   Signature algorithms provide data-origination and data-integrity
   services.  Data origination provides the ability to infer who
   originated the data based on who signed the data.  Data integrity
   provides the ability to verify that the data has not been modified
   since it was signed.

   There are two general signature algorithm schemes.  The first is
   signature with appendix.  In this scheme, the message content is
   processed and a signature is produced; the signature is called the
   appendix.  This is the scheme used by algorithms such as ECDSA and
   the RSA Probabilistic Signature Scheme (RSASSA-PSS).  (In fact, the
   SSA in RSASSA-PSS stands for Signature Scheme with Appendix.)

   The signature functions for this scheme are:

   signature = Sign(message content, key)

   valid = Verification(message content, key, signature)

   The second scheme is signature with message recovery; an example of
   such an algorithm is [PVSig].  In this scheme, the message content is
   processed, but part of it is included in the signature.  Moving bytes
   of the message content into the signature allows for smaller
   signatures; the signature size is still potentially large, but the
   message content has shrunk.  This has implications for systems
   implementing these algorithms and applications that use them.  The
   first is that the message content is not fully available until after
   a signature has been validated.  Until that point, the part of the
   message contained inside of the signature is unrecoverable.  The
   second implication is that the security analysis of the strength of
   the signature can be very much dependent on the structure of the
   message content.  Finally, in the event that multiple signatures are
   applied to a message, all of the signature algorithms are going to be
   required to consume the same bytes of message content.  This means
   that the mixing of the signature-with-message-recovery and signature-
   with-appendix schemes in a single message is not supported.

   The signature functions for this scheme are:

   signature, message sent = Sign(message content, key)

   valid, message content = Verification(message sent, key, signature)

   No message recovery signature algorithms have been formally defined
   for COSE yet.  Given the new constraints arising from this scheme,
   while some of these issues have already been identified, there is a
   high probability that additional issues will arise when integrating
   message recovery signature algorithms.  The first algorithm defined
   is going to need to make decisions about these issues, and those
   decisions are likely to be binding on any further algorithms defined.

   We use the following terms below:

   message content bytes:  The byte provided by the application to be
      signed.

   to-be-signed bytes:  The byte string passed into the signature
      algorithm.

   recovered bytes:  The bytes recovered during the signature
      verification process.

   Some of the issues that have already been identified are:

   *  The to-be-signed bytes are not the same as the message content
      bytes.  This is because we build a larger to-be-signed message
      during the signature processing.  The length of the recovered
      bytes may exceed the length of the message content, but not the
      length of the to-be-signed bytes.  This may lead to privacy
      considerations if, for example, the externally supplied data
      contains confidential information.

   *  There may be difficulties in determining where the recovered bytes
      match up with the to-be-signed bytes, because the recovered bytes
      contain data not in the message content bytes.  One possible
      option would be to create a padding scheme to prevent that.

   *  Not all message recovery signature algorithms take the recovered
      bytes from the end of the to-be-signed bytes.  This is a problem,
      because the message content bytes are at the end of the to-be-
      signed bytes.  If the bytes to be recovered are taken from the
      start of the to-be-signed bytes, then, by default, none of the
      message content bytes may be included in the recovered bytes.  One
      possible option to deal with this is to reverse the to-be-signed
      data in the event that recovered bytes are taken from the start
      rather than the end of the to-be-signed bytes.

   Signature algorithms are used with the COSE_Signature and COSE_Sign1
   structures.  At the time of this writing, only signatures with
   appendices are defined for use with COSE; however, considerable
   interest has been expressed in using a signature-with-message-
   recovery algorithm, due to the effective size reduction that is
   possible.

8.2.  Message Authentication Code (MAC) Algorithms

   Message Authentication Codes (MACs) provide data authentication and
   integrity protection.  They provide either no or very limited data
   origination.  A MAC, for example, cannot be used to prove the
   identity of the sender to a third party.

   MACs use the same scheme as signature-with-appendix algorithms.  The
   message content is processed, and an authentication code is produced.
   The authentication code is frequently called a tag.

   The MAC functions are:

   tag = MAC_Create(message content, key)

   valid = MAC_Verify(message content, key, tag)

   MAC algorithms can be based on either a block cipher algorithm (i.e.,
   AES-MAC) or a hash algorithm (i.e., a Hash-based Message
   Authentication Code (HMAC)).  [RFC9053] defines a MAC algorithm using
   each of these constructions.

   MAC algorithms are used in the COSE_Mac and COSE_Mac0 structures.

8.3.  Content Encryption Algorithms

   Content encryption algorithms provide data confidentiality for
   potentially large blocks of data using a symmetric key.  They provide
   integrity on the data that was encrypted; however, they provide
   either no or very limited data origination.  (One cannot, for
   example, be used to prove the identity of the sender to a third
   party.)  The ability to provide data origination is linked to how the
   CEK is obtained.

   COSE restricts the set of legal content encryption algorithms to
   those that support authentication both of the content and additional
   data.  The encryption process will generate some type of
   authentication value, but that value may be either explicit or
   implicit in terms of the algorithm definition.  For simplicity's
   sake, the authentication code will normally be defined as being
   appended to the ciphertext stream.  The encryption functions are:

   ciphertext = Encrypt(message content, key, additional data)

   valid, message content = Decrypt(ciphertext, key, additional data)

   Most AEAD algorithms are logically defined as returning the message
   content only if the decryption is valid.  Many, but not all,
   implementations will follow this convention.  The message content
   MUST NOT be used if the decryption does not validate.

   These algorithms are used in COSE_Encrypt and COSE_Encrypt0.

8.4.  Key Derivation Functions (KDFs)

   KDFs are used to take some secret value and generate a different one.
   The secret value comes in three flavors:

   *  Secrets that are uniformly random.  This is the type of secret
      that is created by a good random number generator.

   *  Secrets that are not uniformly random.  This is the type of secret
      that is created by operations like key agreement.

   *  Secrets that are not random.  This is the type of secret that
      people generate for things like passwords.

   General KDFs work well with the first type of secret, can do
   reasonably well with the second type of secret, and generally do
   poorly with the last type of secret.  Functions like Argon2
   [CFRG-ARGON2] need to be used for nonrandom secrets.

   The same KDF can be set up to deal with the first two types of
   secrets in different ways.  The KDF defined in Section 5.1 of
   [RFC9053] is such a function.  This is reflected in the set of
   algorithms defined around the HMAC-based Extract-and-Expand Key
   Derivation Function (HKDF).

   When using KDFs, one component that is included is context
   information.  Context information is used to allow for different
   keying information to be derived from the same secret.  The use of
   context-based keying material is considered to be a good security
   practice.

8.5.  Content Key Distribution Methods

   Content key distribution methods (recipient algorithms) can be
   defined into a number of different classes.  COSE has the ability to
   support many classes of recipient algorithms.  In this section, a
   number of classes are listed.  The names of  For the recipient algorithm classes used here are the same as those
   defined in [RFC7516]. [RFC7516], the same names are used.  Other specifications
   use different terms for the recipient algorithm classes or do not
   support some of the recipient algorithm classes.

8.5.1.  Direct Encryption

   The Direct Encryption class of algorithms share a secret between the
   sender and the recipient that is used either directly or after
   manipulation as the CEK.  When direct-encryption mode is used, it
   MUST be the only mode used on the message.

   The COSE_Recipient structure for the recipient is organized as
   follows:

   *  The "protected" field MUST be a zero-length byte string unless it
      is used in the computation of the content key.

   *  The "alg" header parameter MUST be present.

   *  A header parameter identifying the shared secret SHOULD be
      present.

   *  The "ciphertext" field MUST be a zero-length byte string.

   *  The "recipients" field MUST be absent.

8.5.2.  Key Wrap

   In key wrap mode, the CEK is randomly generated, and that key is then
   encrypted by a shared secret between the sender and the recipient.
   All of the currently defined key wrap algorithms for COSE are AE
   algorithms.  Key wrap mode is considered to be superior to Direct
   Encryption if the system has any capability for doing random-key
   generation.  This is because the shared key is used to wrap random
   data rather than data that has some degree of organization and may in
   fact be repeating the same content.  The use of key wrap loses the
   weak data origination that is provided by the direct-encryption
   algorithms.

   The COSE_Recipient structure for the recipient is organized as
   follows:

   *  The "protected" field MUST be absent if the key wrap algorithm is
      an AE algorithm.

   *  The "recipients" field is normally absent but can be used.
      Applications MUST deal with a recipient field being present that
      has an unsupported algorithm.  Failing to decrypt that specific
      recipient is an acceptable way of dealing with it.  Failing to
      process the message is not an acceptable way of dealing with it.

   *  The plaintext to be encrypted is the key from the next layer down
      (usually the content layer).

   *  At a minimum, the "unprotected" field MUST contain the "alg"
      header parameter and SHOULD contain a header parameter identifying
      the shared secret.

8.5.3.  Key Transport

   Key transport mode is also called key encryption mode in some
   standards.  Key transport mode differs from key wrap mode in that it
   uses an asymmetric encryption algorithm rather than a symmetric
   encryption algorithm to protect the key.  A set of key transport
   algorithms is defined in [RFC8230].

   When using a key transport algorithm, the COSE_Recipient structure
   for the recipient is organized as follows:

   *  The "protected" field MUST be absent.

   *  The plaintext to be encrypted is the key from the next layer down
      (usually the content layer).

   *  At a minimum, the "unprotected" field MUST contain the "alg"
      header parameter and SHOULD contain a parameter identifying the
      asymmetric key.

8.5.4.  Direct Key Agreement

   The Direct Key Agreement class of recipient algorithms uses a key
   agreement method to create a shared secret.  A KDF is then applied to
   the shared secret to derive a key to be used in protecting the data.
   This key is normally used as a CEK or MAC key but could be used for
   other purposes if more than two layers are in use (see Appendix B).

   The most commonly used key agreement algorithm is Diffie-Hellman, but
   other variants exist.  Since COSE is designed for a store-and-forward
   environment rather than an online environment, many of the DH
   variants cannot be used, as the receiver of the message cannot
   provide any dynamic key material.  One side effect of this is that
   forward secrecy (see [RFC4949]) is not achievable.  A static key will
   always be used for the receiver of the COSE object.

   Two variants of DH that are supported are:

   Ephemeral-Static (ES) DH:  The sender of the message creates a one-
      time DH key and uses a static key for the recipient.  The use of
      the ephemeral sender key means that no additional random input is
      needed, as this is randomly generated for each message.

   Static-Static (SS) DH:  A static key is used for both the sender and
      the recipient.  The use of static keys allows for the recipient to
      get a weak version of data origination for the message.  When
      static-static
      Static-Static key agreement is used, then some piece of unique
      data for the KDF is required to ensure that a different key is
      created for each message.

   When direct key agreement mode is used, there MUST be only one
   recipient in the message.  This method creates the key directly, and
   that makes it difficult to mix with additional recipients.  If
   multiple recipients are needed, then the version with key wrap needs
   to be used.

   The COSE_Recipient structure for the recipient is organized as
   follows:

   *  At a minimum, headers MUST contain the "alg" header parameter and
      SHOULD contain a header parameter identifying the recipient's
      asymmetric key.

   *  The headers SHOULD identify the sender's key for the static-static Static-Static
      versions and MUST contain the sender's ephemeral key for the
      ephemeral-static versions.

8.5.5.  Key Agreement with Key Wrap

   Key Agreement with Key Wrap uses a randomly generated CEK.  The CEK
   is then encrypted using a key wrap algorithm and a key derived from
   the shared secret computed by the key agreement algorithm.  The
   function for this would be:

   encryptedKey = KeyWrap(KDF(DH-Shared, context), CEK)

   The COSE_Recipient structure for the recipient is organized as
   follows:

   *  The "protected" field is fed into the KDF context structure.

   *  The plaintext to be encrypted is the key from the next layer down
      (usually the content layer).

   *  The "alg" header parameter MUST be present in the layer.

   *  A header parameter identifying the recipient's key SHOULD be
      present.  A header parameter identifying the sender's key SHOULD
      be present.

9.  CBOR Encoding Restrictions

   This document limits the restrictions it imposes on how the CBOR
   encoder
   Encoder needs to work.  The new encoding restrictions are aligned
   with the deterministically encoded CBOR requirements specified in
   [STD94].  It has been narrowed down to the following restrictions:

   *  The restriction applies to the encoding of the COSE_KDF_Context, the Sig_structure,
      the Enc_structure, and the MAC_structure.

   *  Encoding MUST be done using definite lengths, and the value's
      length MUST be the minimum possible length.  This means that the
      integer 1 is encoded as "0x01" and not "0x1801".

   *  Applications MUST NOT generate messages with the same label used
      twice as a key in a single map.  Applications MUST NOT parse and
      process messages with the same label used twice as a key in a
      single map.  Applications can enforce the parse and process
      requirement by using parsers that will fail the parse step or by
      using parsers that will pass all keys to the application, and the
      application can perform the check for duplicate keys.

10.  Application Profiling Considerations

   This document is designed to provide a set of security services but
   not impose algorithm implementation requirements for specific usage.
   The interoperability requirements are provided for how each of the
   individual services are used and how the algorithms are to be used
   for interoperability.  The requirements about which algorithms and
   which services are needed are deferred to each application.

   An example of a profile can be found in [RFC8613], where one was
   developed for carrying content in combination with CoAP headers.

   It is intended that a profile of this document be created that
   defines the interoperability requirements for that specific
   application.  This section provides a set of guidelines and topics
   that need to be considered when profiling this document.

   *  Applications need to determine the set of messages defined in this
      document that they will be using.  The set of messages corresponds
      fairly directly to the needed set of security services security
      levels.

   *  Applications may define new header parameters for a specific
      purpose.  Applications will oftentimes select specific header
      parameters to use or not to use.  For example, an application
      would normally state a preference for using either the IV or the
      Partial IV header parameter.  If the Partial IV header parameter
      is specified, then the application also needs to define how the
      fixed portion of the IV is determined.

   *  When applications use externally defined authenticated data, they
      need to define how that data is encoded.  This document assumes
      that the data will be provided as a byte string.  More information
      can be found in Section 4.3.

   *  Applications need to determine the set of security algorithms that
      is to be used.  When selecting the algorithms to be used as the
      mandatory-to-implement set, consideration should be given to
      choosing different types of algorithms when two are chosen for a
      specific purpose.  An example of this would be choosing HMAC-
      SHA512 and AES-CMAC (Cipher-Based Message Authentication Code) as
      different MAC algorithms; the construction is vastly different
      between these two algorithms.  This means that a weakening of one
      algorithm would be unlikely to lead to a weakening of the other
      algorithms.  Of course, these algorithms do not provide the same
      level of security and thus may not be comparable for the desired
      security functionality.  Additional guidance can be found in
      [BCP201].

   *  Applications may need to provide some type of negotiation or
      discovery method if multiple algorithms or message structures are
      permitted.  The method can be as simple as requiring
      preconfiguration of the set of algorithms to providing a discovery
      method built into the protocol.  S/MIME provided a number of
      different ways to approach the problem that applications could
      follow:

      -  Advertising in the message (S/MIME capabilities) [RFC8551].

      -  Advertising in the certificate (capabilities extension)
         [RFC4262].

      -  Minimum requirements for the S/MIME, which have been updated
         over time [RFC2633] [RFC5751] [RFC8551].  (Note that [RFC2633]
         was obsoleted by [RFC3851], which was obsoleted by [RFC5751],
         which was obsoleted by [RFC8551].)

11.  IANA Considerations

   The registries and registrations listed below were defined by RFC
   8152 [RFC8152].  The majority of the following actions are to update
   the references to point to this document.

   Note that while [RFC9053] also updates the registries and
   registrations originally established by [RFC8152], the requested
   updates are mutually exclusive.  The updates requested in this
   document do not conflict or overlap with the updates requested in
   [RFC9053], and vice versa.

11.1.  COSE Header Parameters Registry

   The "COSE Header Parameters" registry was defined by [RFC8152].  IANA
   has updated the reference for this registry to point to this document
   instead of [RFC8152].  IANA has also updated all entries that
   referenced [RFC8152], except "counter signature" and
   "CounterSignature0", to refer to this document.  The references for
   "counter signature" and "CounterSignature0" continue to reference
   [RFC8152].

11.2.  COSE Key Common Parameters Registry

   The "COSE Key Common Parameters" registry [COSE.KeyParameters] was
   defined in [RFC8152].  IANA has updated the reference for this
   registry to point to this document instead of [RFC8152].  IANA has
   also updated the entries that referenced [RFC8152] to refer to this
   document.

11.3.  Media Type Registrations

11.3.1.  COSE Security Message

   IANA has registered the "application/cose" media type in the "Media
   Types" registry.  These media types are used to indicate that the
   content is a COSE message.

   Type name:  application

   Subtype name:  cose

   Required parameters:  N/A

   Optional parameters:  cose-type

   Encoding considerations:  binary

   Security considerations:  See the Security Considerations section of
      RFC 9052.

   Interoperability considerations:  N/A

   Published specification:  RFC 9052

   Applications that use this media type:  IoT applications sending
      security content over HTTP(S) transports.

   Fragment identifier considerations:  N/A

   Additional information:
      *  Deprecated alias names for this type: N/A

      *  Magic number(s): N/A

      *  File extension(s): cbor

      *  Macintosh file type code(s): N/A

   Person & email address to contact for further information:  iesg@ietf
      .org

   Intended usage:  COMMON

   Restrictions on usage:  N/A

   Author:  Jim Schaad, ietf@augustcellars.com

   Change Controller:  IESG

   Provisional registration?  No

11.3.2.  COSE Key Media Type

   IANA has registered the "application/cose-key" and "application/cose-
   key-set" media types in the "Media Types" registry.  These media
   types are used to indicate, respectively, that content is a COSE_Key
   or COSE_KeySet object.

   The template for "application/cose-key" is as follows:

   Type name:  application

   Subtype name:  cose-key

   Required parameters:  N/A

   Optional parameters:  N/A

   Encoding considerations:  binary

   Security considerations:  See the Security Considerations section of
      RFC 9052.

   Interoperability considerations:  N/A

   Published specification:  RFC 9052

   Applications that use this media type:  Distribution of COSE-based
      keys for IoT applications.

   Fragment identifier considerations:  N/A

   Additional information:
      *  Deprecated alias names for this type: N/A

      *  Magic number(s): N/A

      *  File extension(s): cbor

      *  Macintosh file type code(s): N/A

   Person & email address to contact for further information:  iesg@ietf
      .org

   Intended usage:  COMMON

   Restrictions on usage:  N/A

   Author:  Jim Schaad, ietf@augustcellars.com

   Change Controller:  IESG

   Provisional registration?  No

   The template for registering "application/cose-key-set" is:

   Type name:  application

   Subtype name:  cose-key-set

   Required parameters:  N/A

   Optional parameters:  N/A

   Encoding considerations:  binary

   Security considerations:  See the Security Considerations section of
      RFC 9052.

   Interoperability considerations:  N/A

   Published specification:  RFC 9052

   Applications that use this media type:  Distribution of COSE-based
      keys for IoT applications.

   Fragment identifier considerations:  N/A

   Additional information:
      *  Deprecated alias names for this type: N/A

      *  Magic number(s): N/A

      *  File extension(s): cbor

      *  Macintosh file type code(s): N/A

   Person & email address to contact for further information:  iesg@ietf
      .org

   Intended usage:  COMMON

   Restrictions on usage:  N/A

   Author:  Jim Schaad, ietf@augustcellars.com

   Change Controller:  IESG

   Provisional registration?  No

11.4.  CoAP Content-Formats Registry

   IANA added entries to the "CoAP Content-Formats" registry as defined
   in [RFC8152].  IANA has updated the reference to point to this
   document instead of [RFC8152].

11.5.  CBOR Tags Registry

   IANA has updated the references to point to this document instead of
   [RFC8152].

11.6.  Expert Review Instructions

   All of the IANA registries established by [RFC8152] are, at least in
   part, defined as expert review.  This section gives some general
   guidelines for what the experts should be looking for, but they are
   being designated as experts for a reason, so they should be given
   substantial latitude.

   Expert reviewers should take the following into consideration:

   *  Point squatting should be discouraged.  Reviewers are encouraged
      to get sufficient information for registration requests to ensure
      that the usage is not going to duplicate an existing registration
      and that the code point is likely to be used in deployments.  The
      zones tagged as private use are intended for testing purposes and
      closed environments; code points in other ranges should not be
      assigned for testing.

   *  Specifications are required for the  Standards Track range of or BCP RFCs are required to register a code point assignment.
      in the Standards Action range.  Specifications should exist for
      specification required ranges, but early assignment before a specification an RFC
      is available is considered to be permissible.  Specifications are
      needed for the first-come, first-serve range if the points are
      expected to be used outside of closed environments in an
      interoperable way.  When specifications are not provided, the
      description provided needs to have sufficient information to
      identify what the point is being used for.

   *  Experts should take into account the expected usage of fields when
      approving code point assignment.  The fact that there is a the Standards
      Action range
      for is only available to Standards Track documents does
      not mean that a Standards Track document cannot have code points
      assigned outside of that range.  The length of the encoded value
      should be weighed against how many code points of that length are
      left, the size of device it will be used on, and the number of
      code points left that encode to that size.

   *  When algorithms are registered, vanity registrations should be
      discouraged.  One way to do this is to require registrations to
      provide additional documentation on security analysis of the
      algorithm.  Another thing that should be considered is requesting
      an opinion on the algorithm from the Crypto Forum Research Group
      (CFRG).  Algorithms that do not meet the security requirements of
      the community and the requirements of the message structures
      should not be registered.

12.  Security Considerations

   There are a number of security considerations that need to be taken
   into account by implementers of this specification.  While some
   considerations have been highlighted here, additional considerations
   may be found in the documents listed in the references.

   Implementations need to protect the private key material for all
   individuals.  There are some cases that need to be highlighted on
   this issue.

   *  Use of the same key for two different algorithms can leak
      information about the key.  It is therefore recommended that keys
      be restricted to a single algorithm.

   *  Use of "direct" as a recipient algorithm combined with a second
      recipient algorithm exposes the direct key to the second
      recipient.

   *  Several of the algorithms in [RFC9053] have limits on the number
      of times that a key can be used without leaking information about
      the key.

   The use of Elliptic Curve Diffie-Hellman (ECDH) and direct plus KDF
   (with no key wrap) will not directly lead to the private key being
   leaked; the one-way function of the KDF will prevent that.  There is,
   however, a different issue that needs to be addressed.  Having two
   recipients requires that the CEK be shared between two recipients.
   The second recipient therefore has a CEK that was derived from
   material that can be used for the weak proof of origin.  The second
   recipient could create a message using the same CEK and send it to
   the first recipient; the first recipient would, for either static-
   static Static-
   Static ECDH or direct plus KDF, make an assumption that the CEK could
   be used for proof of origin, even though it is from the wrong entity.
   If the key wrap step is added, then no proof of origin is implied and
   this is not an issue.

   Although it has been mentioned before, the use of a single key for
   multiple algorithms has been demonstrated in some cases to leak
   information about that key, providing the opportunity for attackers
   to forge integrity tags or gain information about encrypted content.
   Binding a key to a single algorithm prevents these problems.  Key
   creators and key consumers are strongly encouraged not only to create
   new keys for each different algorithm, but to include that selection
   of algorithm in any distribution of key material and strictly enforce
   the matching of algorithms in the key structure to algorithms in the
   message structure.  In addition to checking that algorithms are
   correct, the key form needs to be checked as well.  Do not use an
   "EC2" key where an "OKP" key is expected.

   Before using a key for transmission, or before acting on information
   received, a trust decision on a key needs to be made.  Is the data or
   action something that the entity associated with the key has a right
   to see or a right to request?  A number of factors are associated
   with this trust decision.  Some of the ones that are highlighted here
   are:

   *  What are the permissions associated with the key owner?

   *  Is the cryptographic algorithm acceptable in the current context?

   *  Have the restrictions associated with the key, such as algorithm
      or freshness, been checked, and are they correct?

   *  Is the request something that is reasonable, given the current
      state of the application?

   *  Have any security considerations that are part of the message been
      enforced (as specified by the application or "crit" header
      parameter)?

   One area that has been getting exposure is traffic analysis of
   encrypted messages based on the length of the message.  This
   specification does not provide for a uniform method of providing
   padding as part of the message structure.  An observer can
   distinguish between two different messages (for example, "YES" and
   "NO") based on the length for all of the content encryption
   algorithms that are defined in [RFC9053].  This means that it is up
   to the applications to document how content padding is to be done in
   order to prevent or discourage such analysis.  (For example, the text
   strings could be defined as "YES" and "NO".)

13.  References

13.1.  Normative References

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119,
              DOI 10.17487/RFC2119, March 1997,
              <https://www.rfc-editor.org/info/rfc2119>.

   [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>.

   [RFC8949]  Bormann, C. and P. Hoffman, "Concise Binary Object
              Representation (CBOR)", STD 94, RFC 8949,
              DOI 10.17487/RFC8949, December 2020,
              <https://www.rfc-editor.org/info/rfc8949>.

   [RFC9053]  Schaad, J., "CBOR Object Signing and Encryption (COSE):
              Initial Algorithms", RFC 9053, DOI 10.17487/RFC9053, July
              2021, <https://www.rfc-editor.org/info/rfc9053>.

   [STD94]    Bormann, C. and P. Hoffman, "Concise Binary Object
              Representation (CBOR)", STD 94, RFC 8949, December 2020,
              <https://www.rfc-editor.org/info/std94>.

13.2.  Informative References

   [BCP201]   Housley, R., "Guidelines for Cryptographic Algorithm
              Agility and Selecting Mandatory-to-Implement Algorithms",
              BCP 201, RFC 7696, November 2015,
              <https://www.rfc-editor.org/info/bcp201>.

   [CFRG-ARGON2]
              Biryukov, A., Dinu, D., Khovratovich, D., and S.
              Josefsson, "The memory-hard Argon2 password hash "Argon2 Memory-Hard Function for Password
              Hashing and
              proof-of-work function", Proof-of-Work Applications", Work in Progress,
              Internet-Draft, draft-irtf-cfrg-argon2-13, 11 March 2021,
              <https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-
              argon2-13>.

   [COAP.Formats]
              IANA, "CoAP Content-Formats",
              <https://www.iana.org/assignments/core-parameters/>.

   [CORE-GROUPCOMM]
              Dijk, E., Wang, C., and M. Tiloca, "Group Communication
              for the Constrained Application Protocol (CoAP)", Work in
              Progress, Internet-Draft, draft-ietf-core-groupcomm-bis-
              03, 22 February
              04, 12 July 2021,
              <https://datatracker.ietf.org/doc/html/draft-ietf-core-
              groupcomm-bis-03>. <https://datatracker.ietf.org/doc/html/
              draft-ietf-core-groupcomm-bis-04>.

   [COSE-COUNTERSIGN]
              Schaad, J. and R. Housley, "CBOR Object Signing and
              Encryption (COSE): Countersignatures", Work in Progress,
              Internet-Draft, draft-ietf-cose-countersign-05, 23 June
              2021, <https://datatracker.ietf.org/doc/html/draft-ietf-
              cose-countersign-05>.

   [COSE.Algorithms]
              IANA, "COSE Algorithms",
              <https://www.iana.org/assignments/cose/>.

   [COSE.KeyParameters]
              IANA, "COSE Key Common Parameters",
              <https://www.iana.org/assignments/cose/>.

   [COSE.KeyTypes]
              IANA, "COSE Key Types",
              <https://www.iana.org/assignments/cose/>.

   [DSS]      National Institute of Standards and Technology, "Digital
              Signature Standard (DSS)", FIPS 186-4,
              DOI 10.6028/NIST.FIPS.186-4, July 2013,
              <https://nvlpubs.nist.gov/nistpubs/FIPS/
              NIST.FIPS.186-4.pdf>.

   [PVSig]    Brown, D.R.L. and D.B. Johnson, "Formal Security Proofs
              for a Signature Scheme with Partial Message Recovery",
              LNCS Volume 2020, DOI 10.1007/3-540-45353-9_11, June 2000,
              <https://www.certicom.com/content/dam/certicom/images/
              pdfs/CerticomWP-PVSigSec_login.pdf>.

   [RFC2633]  Ramsdell, B., Ed., "S/MIME Version 3 Message
              Specification", RFC 2633, DOI 10.17487/RFC2633, June 1999,
              <https://www.rfc-editor.org/info/rfc2633>.

   [RFC3394]  Schaad, J. and R. Housley, "Advanced Encryption Standard
              (AES) Key Wrap Algorithm", RFC 3394, DOI 10.17487/RFC3394,
              September 2002, <https://www.rfc-editor.org/info/rfc3394>.

   [RFC3851]  Ramsdell, B., Ed., "Secure/Multipurpose Internet Mail
              Extensions (S/MIME) Version 3.1 Message Specification",
              RFC 3851, DOI 10.17487/RFC3851, July 2004,
              <https://www.rfc-editor.org/info/rfc3851>.

   [RFC4262]  Santesson, S., "X.509 Certificate Extension for Secure/
              Multipurpose Internet Mail Extensions (S/MIME)
              Capabilities", RFC 4262, DOI 10.17487/RFC4262, December
              2005, <https://www.rfc-editor.org/info/rfc4262>.

   [RFC4949]  Shirey, R., "Internet Security Glossary, Version 2",
              FYI 36, RFC 4949, DOI 10.17487/RFC4949, August 2007,
              <https://www.rfc-editor.org/info/rfc4949>.

   [RFC5116]  McGrew, D., "An Interface and Algorithms for Authenticated
              Encryption", RFC 5116, DOI 10.17487/RFC5116, January 2008,
              <https://www.rfc-editor.org/info/rfc5116>.

   [RFC5652]  Housley, R., "Cryptographic Message Syntax (CMS)", STD 70,
              RFC 5652, DOI 10.17487/RFC5652, September 2009,
              <https://www.rfc-editor.org/info/rfc5652>.

   [RFC5751]  Ramsdell, B. and S. Turner, "Secure/Multipurpose Internet
              Mail Extensions (S/MIME) Version 3.2 Message
              Specification", RFC 5751, DOI 10.17487/RFC5751, January
              2010, <https://www.rfc-editor.org/info/rfc5751>.

   [RFC5752]  Turner, S. and J. Schaad, "Multiple Signatures in
              Cryptographic Message Syntax (CMS)", RFC 5752,
              DOI 10.17487/RFC5752, January 2010,
              <https://www.rfc-editor.org/info/rfc5752>.

   [RFC5990]  Randall, J., Kaliski, B., Brainard, J., and S. Turner,
              "Use of the RSA-KEM Key Transport Algorithm in the
              Cryptographic Message Syntax (CMS)", RFC 5990,
              DOI 10.17487/RFC5990, September 2010,
              <https://www.rfc-editor.org/info/rfc5990>.

   [RFC6838]  Freed, N., Klensin, J., and T. Hansen, "Media Type
              Specifications and Registration Procedures", BCP 13,
              RFC 6838, DOI 10.17487/RFC6838, January 2013,
              <https://www.rfc-editor.org/info/rfc6838>.

   [RFC7252]  Shelby, Z., Hartke, K., and C. Bormann, "The Constrained
              Application Protocol (CoAP)", RFC 7252,
              DOI 10.17487/RFC7252, June 2014,
              <https://www.rfc-editor.org/info/rfc7252>.

   [RFC7515]  Jones, M., Bradley, J., and N. Sakimura, "JSON Web
              Signature (JWS)", RFC 7515, DOI 10.17487/RFC7515, May
              2015, <https://www.rfc-editor.org/info/rfc7515>.

   [RFC7516]  Jones, M. and J. Hildebrand, "JSON Web Encryption (JWE)",
              RFC 7516, DOI 10.17487/RFC7516, May 2015,
              <https://www.rfc-editor.org/info/rfc7516>.

   [RFC7517]  Jones, M., "JSON Web Key (JWK)", RFC 7517,
              DOI 10.17487/RFC7517, May 2015,
              <https://www.rfc-editor.org/info/rfc7517>.

   [RFC7518]  Jones, M., "JSON Web Algorithms (JWA)", RFC 7518,
              DOI 10.17487/RFC7518, May 2015,
              <https://www.rfc-editor.org/info/rfc7518>.

   [RFC8032]  Josefsson, S. and I. Liusvaara, "Edwards-Curve Digital
              Signature Algorithm (EdDSA)", RFC 8032,
              DOI 10.17487/RFC8032, January 2017,
              <https://www.rfc-editor.org/info/rfc8032>.

   [RFC8152]  Schaad, J., "CBOR Object Signing and Encryption (COSE)",
              RFC 8152, DOI 10.17487/RFC8152, July 2017,
              <https://www.rfc-editor.org/info/rfc8152>.

   [RFC8230]  Jones, M., "Using RSA Algorithms with CBOR Object Signing
              and Encryption (COSE) Messages", RFC 8230,
              DOI 10.17487/RFC8230, September 2017,
              <https://www.rfc-editor.org/info/rfc8230>.

   [RFC8551]  Schaad, J., Ramsdell, B., and S. Turner, "Secure/
              Multipurpose Internet Mail Extensions (S/MIME) Version 4.0
              Message Specification", RFC 8551, DOI 10.17487/RFC8551,
              April 2019, <https://www.rfc-editor.org/info/rfc8551>.

   [RFC8610]  Birkholz, H., Vigano, C., and C. Bormann, "Concise Data
              Definition Language (CDDL): A Notational Convention to
              Express Concise Binary Object Representation (CBOR) and
              JSON Data Structures", RFC 8610, DOI 10.17487/RFC8610,
              June 2019, <https://www.rfc-editor.org/info/rfc8610>.

   [RFC8613]  Selander, G., Mattsson, J., Palombini, F., and L. Seitz,
              "Object Security for Constrained RESTful Environments
              (OSCORE)", RFC 8613, DOI 10.17487/RFC8613, July 2019,
              <https://www.rfc-editor.org/info/rfc8613>.

   [RFC9054]  Schaad, J., "CBOR Object Signing and Encryption (COSE):
              Hash Algorithms", RFC 9054, DOI 10.17487/RFC9054, July
              2021, <https://www.rfc-editor.org/info/rfc9054>.

   [STD90]    Bray, T., Ed., "The JavaScript Object Notation (JSON) Data
              Interchange Format", STD 90, RFC 8259, December 2017,
              <https://www.rfc-editor.org/info/std90>.

   [W3C.WebCrypto]
              Watson, M., Ed., "Web Cryptography API", W3C
              Recommendation, 26 January 2017,
              <https://www.w3.org/TR/WebCryptoAPI/>.

Appendix A.  Guidelines for External Data Authentication of Algorithms

   During development of COSE, the requirement that the algorithm
   identifier be located in the protected attributes was relaxed from a
   must to a should.  Two basic reasons have been advanced to support
   this position.  First, the resulting message will be smaller if the
   algorithm identifier is omitted from the most common messages in a
   CoAP environment.  Second, there is a potential bug that will arise
   if full checking is not done correctly between the different places
   that an algorithm identifier could be placed (the message itself, an
   application statement, the key structure that the sender possesses,
   and the key structure the recipient possesses).

   This appendix lays out how such a change can be made and the details
   that an application needs to specify in order to use this option.
   Two different sets of details are specified: those needed to omit an
   algorithm identifier and those needed to use the variant on the
   countersignature attribute that contains no attributes about itself.

   Three sets of recommendations are laid out.  The first set of
   recommendations applies to having an implicit algorithm identified
   for a single layer of a COSE object.  The second set of
   recommendations applies to having multiple implicit algorithms
   identified for multiple layers of a COSE object.  The third set of
   recommendations applies to having implicit algorithms for multiple
   COSE object constructs.

   The key words from [RFC2119] are deliberately not used here.  This
   specification can provide recommendations, but it cannot enforce
   them.

   This set of recommendations applies to the case where an application
   is distributing a fixed algorithm along with the key information for
   use in a single COSE object.  This normally applies to the smallest
   of the COSE objects -- specifically, COSE_Sign1, COSE_Mac0, and
   COSE_Encrypt0 -- but could apply to the other structures as well.

   The following items should be taken into account:

   *  Applications need to list the set of COSE structures that implicit
      algorithms are to be used in.  Applications need to require that
      the receipt of an explicit algorithm identifier in one of these
      structures will lead to the message being rejected.  This
      requirement is stated so that there will never be a case where
      there is any ambiguity about the question of which algorithm
      should be used, the implicit or the explicit one.  This applies
      even if the transported algorithm identifier is a protected
      attribute.  This applies even if the transported algorithm is the
      same as the implicit algorithm.

   *  Applications need to define the set of information that is to be
      considered to be part of a context when omitting algorithm
      identifiers.  At a minimum, this would be the key identifier (if
      needed), the key, the algorithm, and the COSE structure it is used
      with.  Applications should restrict the use of a single key to a
      single algorithm.  As noted for some of the algorithms in
      [RFC9053], the use of the same key in different, related
      algorithms can lead to leakage of information about the key,
      leakage about the data, or the ability to perform forgeries.

   *  In many cases, applications that make the algorithm identifier
      implicit will also want to make the context identifier implicit
      for the same reason.  That is, omitting the context identifier
      will decrease the message size (potentially significantly,
      depending on the length of the identifier).  Applications that do
      this will need to describe the circumstances where the context
      identifier is to be omitted and how the context identifier is to
      be inferred in these cases.  (An exhaustive search over all of the
      keys would normally not be considered to be acceptable.)  An
      example of how this can be done is to tie the context to a
      transaction identifier.  Both would be sent on the original
      message, but only the transaction identifier would need to be sent
      after that point, as the context is tied into the transaction
      identifier.  Another way would be to associate a context with a
      network address.  All messages coming from a single network
      address can be assumed to be associated with a specific context.
      (In this case, the address would normally be distributed as part
      of the context.)

   *  Applications cannot rely on key identifiers being unique unless
      they take significant efforts to ensure that they are computed in
      such a way as to create this guarantee.  Even when an application
      does this, the uniqueness might be violated if the application is
      run in different contexts (i.e., with a different context
      provider) or if the system combines the security contexts from
      different applications together into a single store.

   *  Applications should continue the practice of protecting the
      algorithm identifier.  Since this is not done by placing it in the
      protected attributes field, applications should define an
      application-specific external data structure that includes this
      value.  This external data field can be used as such for content
      encryption, MAC, and signature algorithms.  It can be used in the
      SuppPrivInfo field for those algorithms that use a KDF to derive a
      key value.  Applications may also want to protect other
      information that is part of the context structure as well.  It
      should be noted that those fields, such as the key or a Base IV,
      are protected by virtue of being used in the cryptographic
      computation and do not need to be included in the external data
      field.

   The second case is having multiple implicit algorithm identifiers
   specified for a multiple-layer COSE object.  An example of how this
   would work is the encryption context that an application specifies,
   which contains a content encryption algorithm, a key wrap algorithm,
   a key identifier, and a shared secret.  The sender omits sending the
   algorithm identifier for both the content layer and the recipient
   layer, leaving only the key identifier.  The receiver then uses the
   key identifier to get the implicit algorithm identifiers.

   The following additional items need to be taken into consideration:

   *  Applications that want to support this will need to define a
      structure that allows for, and clearly identifies, both the COSE
      structure to be used with a given key and the structure and
      algorithm to be used for the secondary layer.  The key for the
      secondary layer is computed as normal from the recipient layer.

   The third case is having multiple implicit algorithm identifiers, but
   targeted at potentially unrelated layers or different COSE objects.
   There are a number of different scenarios where this might be
   applicable.  Some of these scenarios are:

   *  Two contexts are distributed as a pair.  Each of the contexts is
      for use with a COSE_Encrypt message.  Each context will consist of
      distinct secret keys and IVs and potentially even different
      algorithms.  One context is for sending messages from party A to
      party B, and the second context is for sending messages from party
      B to party A.  This means that there is no chance for a reflection
      attack to occur, as each party uses different secret keys to send
      its messages; a message that is reflected back to it would fail to
      decrypt.

   *  Two contexts are distributed as a pair.  The first context is used
      for encryption of the message, and the second context is used to
      place a countersignature on the message.  The intention is that
      the second context can be distributed to other entities
      independently of the first context.  This allows these entities to
      validate that the message came from an individual without being
      able to decrypt the message and see the content.

   *  Two contexts are distributed as a pair.  The first context
      contains a key for dealing with MACed messages, and the second
      context contains a different key for dealing with encrypted
      messages.  This allows for a unified distribution of keys to
      participants for different types of messages that have different
      keys, but where the keys may be used in a coordinated manner.

   For these cases, the following additional items need to be
   considered:

   *  Applications need to ensure that the multiple contexts stay
      associated.  If one of the contexts is invalidated for any reason,
      all of the contexts associated with it should also be invalidated.

Appendix B.  Two Layers of Recipient Information

   All of the currently defined recipient algorithm classes only use two
   layers of the COSE structure.  The first layer (COSE_Encrypt) is the
   message content, and the second layer (COSE_Recipient) is the content
   key encryption.  However, if one uses a recipient algorithm such as
   the RSA Key Encapsulation Mechanism (RSA-KEM) (see Appendix A of RSA-
   KEM [RFC5990]), then it makes sense to have two layers of the
   COSE_Recipient structure.

   These layers would be:

   *  Layer 0: The content encryption layer.  This layer contains the
      payload of the message.

   *  Layer 1: The encryption of the CEK by a KEK.

   *  Layer 2: The encryption of a long random secret using an RSA key
      and a key derivation function to convert that secret into the KEK.

   This is an example of what a triple-layer message would look like.
   The message has the following layers:

   *  Layer 0: Has content encrypted with AES-GCM using a 128-bit key.

   *  Layer 1: Uses the AES Key Wrap algorithm with a 128-bit key.

   *  Layer 2: Uses ECDH Ephemeral-Static direct to generate the Layer 1
      key.

   In effect, this example is a decomposed version of using the ECDH-
   ES+A128KW algorithm.

   Size of binary file is 183 bytes

   96(
     [ / COSE_Encrypt /
       / protected  h'a10101' / << {
           / alg / 1:1 / AES-GCM 128 /
         } >>,
       / unprotected / {
         / iv / 5:h'02d1f7e6f26c43d4868d87ce'
       },
       / ciphertext / h'64f84d913ba60a76070a9a48f26e97e863e2852948658f0
   811139868826e89218a75715b',
       / recipients / [
         [ / COSE_Recipient /
           / protected / h'',
           / unprotected / {
             / alg / 1:-3 / A128KW /
           },
           / ciphertext / h'dbd43c4e9d719c27c6275c67d628d493f090593db82
   18f11',
           / recipients / [
             [ / COSE_Recipient /
               / protected  h'a1013818' / << {
                   / alg / 1:-25 / ECDH-ES + HKDF-256 /
                 } >> ,
               / unprotected / {
                 / ephemeral / -1:{
                   / kty / 1:2,
                   / crv / -1:1,
                   / x / -2:h'b2add44368ea6d641f9ca9af308b4079aeb519f11
   e9b8a55a600b21233e86e68',
                   / y / -3:false
                 },
                 / kid / 4:'meriadoc.brandybuck@buckland.example'
               },
               / ciphertext / h''
             ]
           ]
         ]
       ]
     ]
   )

Appendix C.  Examples

   This appendix includes a set of examples that show the different
   features and message types that have been defined in this document.
   To make the examples easier to read, they are presented using the
   extended CBOR diagnostic notation (defined in [RFC8610]) rather than
   as a binary dump.

   A GitHub project has been created at <https://github.com/cose-wg/
   Examples> that contains not only the examples presented in this
   document, but a more complete set of testing examples as well.  Each
   example is found in a JSON file that contains the inputs used to
   create the example, some of the intermediate values that can be used
   in debugging the example, and the output of the example presented
   both as a hex dump and in CBOR diagnostic notation format.  Some of
   the examples at the site are designed failure-testing cases; these
   are clearly marked as such in the JSON file.  If errors in the
   examples in this document are found, the examples on GitHub will be
   updated, and a note to that effect will be placed in the JSON file.

   As noted, the examples are presented using CBOR's diagnostic
   notation.  A Ruby-based tool exists that can convert between the
   diagnostic notation and binary.  This tool can be installed with the
   command line:

   gem install cbor-diag

   The diagnostic notation can be converted into binary files using the
   following command line:

   diag2cbor.rb < inputfile > outputfile

   The examples can be extracted from the XML version of this document
   via an XPath expression, as all of the source code is tagged with the
   attribute type='cbor-diag'.  (Depending on the XPath evaluator one is
   using, it may be necessary to deal with &gt; as an entity.)

   //sourcecode[@type='CDDL']/text()

C.1.  Examples of Signed Messages

C.1.1.  Single Signature

   This example uses the following:

   *  Signature Algorithm: ECDSA w/ SHA-256, Curve P-256

   Size of binary file is 103 bytes

   98(
     [
       / protected / h'',
       / unprotected / {},
       / payload / 'This is the content.',
       / signatures / [
         [
           / protected h'a10126' / << {
               / alg / 1:-7 / ECDSA 256 /
             } >>,
           / unprotected / {
             / kid / 4:'11'
           },
           / signature / h'e2aeafd40d69d19dfe6e52077c5d7ff4e408282cbefb
   5d06cbf414af2e19d982ac45ac98b8544c908b4507de1e90b717c3d34816fe926a2b
   98f53afd2fa0f30a'
         ]
       ]
     ]
   )

C.1.2.  Multiple Signers

   This example uses the following:

   *  Signature Algorithm: ECDSA w/ SHA-256, Curve P-256

   *  Signature Algorithm: ECDSA w/ SHA-512, Curve P-521

   Size of binary file is 277 bytes

   98(
     [
       / protected / h'',
       / unprotected / {},
       / payload / 'This is the content.',
       / signatures / [
         [
           / protected h'a10126' / << {
               / alg / 1:-7 / ECDSA 256 /
             } >>,
           / unprotected / {
             / kid / 4:'11'
           },
           / signature / h'e2aeafd40d69d19dfe6e52077c5d7ff4e408282cbefb
   5d06cbf414af2e19d982ac45ac98b8544c908b4507de1e90b717c3d34816fe926a2b
   98f53afd2fa0f30a'
         ],
         [
           / protected h'a1013823' / << {
               / alg / 1:-36 / ECDSA 521 /
             } >> ,
           / unprotected / {
             / kid / 4:'bilbo.baggins@hobbiton.example'
           },
           / signature / h'00a2d28a7c2bdb1587877420f65adf7d0b9a06635dd1
   de64bb62974c863f0b160dd2163734034e6ac003b01e8705524c5c4ca479a952f024
   7ee8cb0b4fb7397ba08d009e0c8bf482270cc5771aa143966e5a469a09f613488030
   c5b07ec6d722e3835adb5b2d8c44e95ffb13877dd2582866883535de3bb03d01753f
   83ab87bb4f7a0297'
         ]
       ]
     ]
   )

C.1.3.  Signature with Criticality

   This example uses the following:

   *  Signature Algorithm: ECDSA w/ SHA-256, Curve P-256

   *  There is a criticality marker on the "reserved" header parameter.

   Size of binary file is 125 bytes

   98(
     [
       / protected h'a2687265736572766564f40281687265736572766564' /
       << {
           "reserved":false,
           / crit / 2:[
             "reserved"
           ]
         } >>,
       / unprotected / {},
       / payload / 'This is the content.',
       / signatures / [
         [
           / protected h'a10126' / << {
               / alg / 1:-7 / ECDSA 256 /
             } >>,
           / unprotected / {
             / kid / 4:'11'
           },
           / signature / h'3fc54702aa56e1b2cb20284294c9106a63f91bac658d
   69351210a031d8fc7c5ff3e4be39445b1a3e83e1510d1aca2f2e8a7c081c7645042b
   18aba9d1fad1bd9c'
         ]
       ]
     ]
   )

C.2.  Single Signer Examples

C.2.1.  Single ECDSA Signature

   This example uses the following:

   *  Signature Algorithm: ECDSA w/ SHA-256, Curve P-256

   Size of binary file is 98 bytes

   18(
     [
       / protected h'a10126' / << {
           / alg / 1:-7 / ECDSA 256 /
         } >>,
       / unprotected / {
         / kid / 4:'11'
       },
       / payload / 'This is the content.',
       / signature / h'8eb33e4ca31d1c465ab05aac34cc6b23d58fef5c083106c4
   d25a91aef0b0117e2af9a291aa32e14ab834dc56ed2a223444547e01f11d3b0916e5
   a4c345cacb36'
     ]
   )

C.3.  Examples of Enveloped Messages

C.3.1.  Direct ECDH

   This example uses the following:

   *  CEK: AES-GCM w/ 128-bit key

   *  Recipient class: ECDH Ephemeral-Static, Curve P-256

   Size of binary file is 151 bytes

   96(
     [
       / protected h'a10101' / << {
           / alg / 1:1 / AES-GCM 128 /
         } >>,
       / unprotected / {
         / iv / 5:h'c9cf4df2fe6c632bf7886413'
       },
       / ciphertext / h'7adbe2709ca818fb415f1e5df66f4e1a51053ba6d65a1a0
   c52a357da7a644b8070a151b0',
       / recipients / [
         [
           / protected h'a1013818' / << {
               / alg / 1:-25 / ECDH-ES + HKDF-256 /
             } >>,
           / unprotected / {
             / ephemeral / -1:{
               / kty / 1:2,
               / crv / -1:1,
               / x / -2:h'98f50a4ff6c05861c8860d13a638ea56c3f5ad7590bbf
   bf054e1c7b4d91d6280',
               / y / -3:true
             },
             / kid / 4:'meriadoc.brandybuck@buckland.example'
           },
           / ciphertext / h''
         ]
       ]
     ]
   )

C.3.2.  Direct Plus Key Derivation

   This example uses the following:

   *  CEK: AES-CCM w/ 128-bit key, truncate the tag to 64 bits

   *  Recipient class: Use HKDF on a shared secret with the following
      implicit fields as part of the context.

      -  salt: "aabbccddeeffgghh"

      -  PartyU identity: "lighting-client"

      -  PartyV identity: "lighting-server"

      -  Supplementary Public Other: "Encryption Example 02"

   Size of binary file is 91 bytes

   96(
     [
       / protected h'a1010a' / << {
           / alg / 1:10 / AES-CCM-16-64-128 /
         } >>,
       / unprotected / {
         / iv / 5:h'89f52f65a1c580933b5261a76c'
       },
       / ciphertext / h'753548a19b1307084ca7b2056924ed95f2e3b17006dfe93
   1b687b847',
       / recipients / [
         [
           / protected  h'a10129' / << {
               / alg / 1:-10
             } >>,
           / unprotected / {
             / salt / -20:'aabbccddeeffgghh',
             / kid / 4:'our-secret'
           },
           / ciphertext / h''
         ]
       ]
     ]
   )

C.3.3.  Encrypted Content with External Data

   This example uses the following:

   *  CEK: AES-GCM w/ 128-bit key

   *  Recipient class: ECDH static-Static, Static-Static, Curve P-256 with AES Key Wrap

   *  Externally Supplied AAD: h'0011bbcc22dd44ee55ff660077'

   Size of binary file is 173 bytes

   96(
     [
       / protected h'a10101' / << {
           / alg / 1:1 / AES-GCM 128 /
         } >> ,
       / unprotected / {
         / iv / 5:h'02d1f7e6f26c43d4868d87ce'
       },
       / ciphertext / h'64f84d913ba60a76070a9a48f26e97e863e28529d8f5335
   e5f0165eee976b4a5f6c6f09d',
       / recipients / [
         [
           / protected / h'a101381f' / {
               \ alg \ 1:-32 \ ECHD-SS+A128KW \
             } / ,
           / unprotected / {
             / static kid / -3:'peregrin.took@tuckborough.example',
             / kid / 4:'meriadoc.brandybuck@buckland.example',
             / U nonce / -22:h'0101'
           },
           / ciphertext / h'41e0d76f579dbd0d936a662d54d8582037de2e366fd
   e1c62'
         ]
       ]
     ]
   )

C.4.  Examples of Encrypted Messages

C.4.1.  Simple Encrypted Message

   This example uses the following:

   *  CEK: AES-CCM w/ 128-bit key and a 64-bit tag

   Size of binary file is 52 bytes

   16(
     [
       / protected h'a1010a' / << {
           / alg / 1:10 / AES-CCM-16-64-128 /
         } >> ,
       / unprotected / {
         / iv / 5:h'89f52f65a1c580933b5261a78c'
       },
       / ciphertext / h'5974e1b99a3a4cc09a659aa2e9e7fff161d38ce71cb45ce
   460ffb569'
     ]
   )

C.4.2.  Encrypted Message with a Partial IV

   This example uses the following:

   *  CEK: AES-CCM w/ 128-bit key and a 64-bit tag

   *  Prefix for IV is 89F52F65A1C580933B52

   Size of binary file is 41 bytes

   16(
     [
       / protected  h'a1010a' / << {
           / alg / 1:10 / AES-CCM-16-64-128 /
         } >> ,
       / unprotected / {
         / partial iv / 6:h'61a7'
       },
       / ciphertext / h'252a8911d465c125b6764739700f0141ed09192de139e05
   3bd09abca'
     ]
   )

C.5.  Examples of MACed Messages

C.5.1.  Shared Secret Direct MAC

   This example uses the following:

   *  MAC: AES-CMAC, 256-bit key, truncated to 64 bits

   *  Recipient class: direct shared secret

   Size of binary file is 57 bytes

   97(
     [
       / protected  h'a1010f' / << {
           / alg / 1:15 / AES-CBC-MAC-256//64 /
         } >> ,
       / unprotected / {},
       / payload / 'This is the content.',
       / tag / h'9e1226ba1f81b848',
       / recipients / [
         [
           / protected / h'',
           / unprotected / {
             / alg / 1:-6 / direct /,
             / kid / 4:'our-secret'
           },
           / ciphertext / h''
         ]
       ]
     ]
   )

C.5.2.  ECDH Direct MAC

   This example uses the following:

   *  MAC: HMAC w/SHA-256, 256-bit key

   *  Recipient class: ECDH key agreement, two static keys, HKDF w/
      context structure

   Size of binary file is 214 bytes

   97(
     [
       / protected  h'a10105' / << {
           / alg / 1:5 / HMAC 256//256 /
         } >> ,
       / unprotected / {},
       / payload / 'This is the content.',
       / tag / h'81a03448acd3d305376eaa11fb3fe416a955be2cbe7ec96f012c99
   4bc3f16a41',
       / recipients / [
         [
           / protected  h'a101381a' / << {
               / alg / 1:-27 / ECDH-SS + HKDF-256 /
             } >> ,
           / unprotected / {
             / static kid / -3:'peregrin.took@tuckborough.example',
             / kid / 4:'meriadoc.brandybuck@buckland.example',
             / U nonce / -22:h'4d8553e7e74f3c6a3a9dd3ef286a8195cbf8a23d
   19558ccfec7d34b824f42d92bd06bd2c7f0271f0214e141fb779ae2856abf585a583
   68b017e7f2a9e5ce4db5'
           },
           / ciphertext / h''
         ]
       ]
     ]
   )

C.5.3.  Wrapped MAC

   This example uses the following:

   *  MAC: AES-MAC, 128-bit key, truncated to 64 bits

   *  Recipient class: AES Key Wrap w/ a preshared 256-bit key

   Size of binary file is 109 bytes

   97(
     [
       / protected  h'a1010e' / << {
           / alg / 1:14 / AES-CBC-MAC-128//64 /
         } >> ,
       / unprotected / {},
       / payload / 'This is the content.',
       / tag / h'36f5afaf0bab5d43',
       / recipients / [
         [
           / protected / h'',
           / unprotected / {
             / alg / 1:-5 / A256KW /,
             / kid / 4:'018c0ae5-4d9b-471b-bfd6-eef314bc7037'
           },
           / ciphertext / h'711ab0dc2fc4585dce27effa6781c8093eba906f227
   b6eb0'
         ]
       ]
     ]
   )

C.5.4.  Multi-Recipient MACed Message

   This example uses the following:

   *  MAC: HMAC w/ SHA-256, 128-bit key

   *  Recipient class: Uses three different methods.

      1.  ECDH Ephemeral-Static, Curve P-521, AES Key Wrap w/ 128-bit
          key

      2.  AES Key Wrap w/ 256-bit key

   Size of binary file is 309 bytes

   97(
     [
       / protected h'a10105' / << {
           / alg / 1:5 / HMAC 256//256 /
         } >> ,
       / unprotected / {},
       / payload / 'This is the content.',
       / tag / h'bf48235e809b5c42e995f2b7d5fa13620e7ed834e337f6aa43df16
   1e49e9323e',
       / recipients / [
         [
           / protected h'a101381c' / << {
               / alg / 1:-29 / ECHD-ES+A128KW /
             } >> ,
           / unprotected / {
             / ephemeral / -1:{
               / kty / 1:2,
               / crv / -1:3,
               / x / -2:h'0043b12669acac3fd27898ffba0bcd2e6c366d53bc4db
   71f909a759304acfb5e18cdc7ba0b13ff8c7636271a6924b1ac63c02688075b55ef2
   d613574e7dc242f79c3',
               / y / -3:true
             },
             / kid / 4:'bilbo.baggins@hobbiton.example'
           },
           / ciphertext / h'339bc4f79984cdc6b3e6ce5f315a4c7d2b0ac466fce
   a69e8c07dfbca5bb1f661bc5f8e0df9e3eff5'
         ],
         [
           / protected / h'',
           / unprotected / {
             / alg / 1:-5 / A256KW /,
             / kid / 4:'018c0ae5-4d9b-471b-bfd6-eef314bc7037'
           },
           / ciphertext / h'0b2c7cfce04e98276342d6476a7723c090dfdd15f9a
   518e7736549e998370695e6d6a83b4ae507bb'
         ]
       ]
     ]
   )

C.6.  Examples of MAC0 Messages

C.6.1.  Shared-Secret Direct MAC

   This example uses the following:

   *  MAC: AES-CMAC, 256-bit key, truncated to 64 bits

   *  Recipient class: direct shared secret

   Size of binary file is 37 bytes

   17(
     [
       / protected h'a1010f' / << {
           / alg / 1:15 / AES-CBC-MAC-256//64 /
         } >> ,
       / unprotected / {},
       / payload / 'This is the content.',
       / tag / h'726043745027214f'
     ]
   )

   Note that this example uses the same inputs as Appendix C.5.1.

C.7.  COSE Keys

C.7.1.  Public Keys

   This is an example of a COSE Key Set.  This example includes the
   public keys for all of the previous examples.

   In order, the keys are:

   *  An EC key with a kid of "meriadoc.brandybuck@buckland.example"

   *  An EC key with a kid of "11"

   *  An EC key with a kid of "bilbo.baggins@hobbiton.example"

   *  An EC key with a kid of "peregrin.took@tuckborough.example"

   Size of binary file is 481 bytes

   [
     {
       -1:1,
       -2:h'65eda5a12577c2bae829437fe338701a10aaa375e1bb5b5de108de439c0
   8551d',
       -3:h'1e52ed75701163f7f9e40ddf9f341b3dc9ba860af7e0ca7ca7e9eecd008
   4d19c',
       1:2,
       2:'meriadoc.brandybuck@buckland.example'
     },
     {
       -1:1,
       -2:h'bac5b11cad8f99f9c72b05cf4b9e26d244dc189f745228255a219a86d6a
   09eff',
       -3:h'20138bf82dc1b6d562be0fa54ab7804a3a64b6d72ccfed6b6fb6ed28bbf
   c117e',
       1:2,
       2:'11'
     },
     {
       -1:3,
       -2:h'0072992cb3ac08ecf3e5c63dedec0d51a8c1f79ef2f82f94f3c737bf5de
   7986671eac625fe8257bbd0394644caaa3aaf8f27a4585fbbcad0f2457620085e5c8
   f42ad',
       -3:h'01dca6947bce88bc5790485ac97427342bc35f887d86d65a089377e247e
   60baa55e4e8501e2ada5724ac51d6909008033ebc10ac999b9d7f5cc2519f3fe1ea1
   d9475',
       1:2,
       2:'bilbo.baggins@hobbiton.example'
     },
     {
       -1:1,
       -2:h'98f50a4ff6c05861c8860d13a638ea56c3f5ad7590bbfbf054e1c7b4d91
   d6280',
       -3:h'f01400b089867804b8e9fc96c3932161f1934f4223069170d924b7e03bf
   822bb',
       1:2,
       2:'peregrin.took@tuckborough.example'
     }
   ]

C.7.2.  Private Keys

   This is an example of a COSE Key Set.  This example includes the
   private keys for all of the previous examples.

   In order the keys are:

   *  An EC key with a kid of "meriadoc.brandybuck@buckland.example"

   *  A shared-secret key with a kid of "our-secret"

   *  An EC key with a kid of "peregrin.took@tuckborough.example"

   *  A shared-secret key with a kid of "018c0ae5-4d9b-471b-
      bfd6-eef314bc7037"

   *  An EC key with a kid of "bilbo.baggins@hobbiton.example"

   *  An EC key with a kid of "11"

   Size of binary file is 816 bytes

   [
     {
       1:2,
       2:'meriadoc.brandybuck@buckland.example',
       -1:1,
       -2:h'65eda5a12577c2bae829437fe338701a10aaa375e1bb5b5de108de439c0
   8551d',
       -3:h'1e52ed75701163f7f9e40ddf9f341b3dc9ba860af7e0ca7ca7e9eecd008
   4d19c',
       -4:h'aff907c99f9ad3aae6c4cdf21122bce2bd68b5283e6907154ad911840fa
   208cf'
     },
     {
       1:2,
       2:'11',
       -1:1,
       -2:h'bac5b11cad8f99f9c72b05cf4b9e26d244dc189f745228255a219a86d6a
   09eff',
       -3:h'20138bf82dc1b6d562be0fa54ab7804a3a64b6d72ccfed6b6fb6ed28bbf
   c117e',
       -4:h'57c92077664146e876760c9520d054aa93c3afb04e306705db609030850
   7b4d3'
     },
     {
       1:2,
       2:'bilbo.baggins@hobbiton.example',
       -1:3,
       -2:h'0072992cb3ac08ecf3e5c63dedec0d51a8c1f79ef2f82f94f3c737bf5de
   7986671eac625fe8257bbd0394644caaa3aaf8f27a4585fbbcad0f2457620085e5c8
   f42ad',
       -3:h'01dca6947bce88bc5790485ac97427342bc35f887d86d65a089377e247e
   60baa55e4e8501e2ada5724ac51d6909008033ebc10ac999b9d7f5cc2519f3fe1ea1
   d9475',
       -4:h'00085138ddabf5ca975f5860f91a08e91d6d5f9a76ad4018766a476680b
   55cd339e8ab6c72b5facdb2a2a50ac25bd086647dd3e2e6e99e84ca2c3609fdf177f
   eb26d'
     },
     {
       1:4,
       2:'our-secret',
       -1:h'849b57219dae48de646d07dbb533566e976686457c1491be3a76dcea6c4
   27188'
     },
     {
       1:2,
       -1:1,
       2:'peregrin.took@tuckborough.example',
       -2:h'98f50a4ff6c05861c8860d13a638ea56c3f5ad7590bbfbf054e1c7b4d91
   d6280',
       -3:h'f01400b089867804b8e9fc96c3932161f1934f4223069170d924b7e03bf
   822bb',
       -4:h'02d1f7e6f26c43d4868d87ceb2353161740aacf1f7163647984b522a848
   df1c3'
     },
     {
       1:4,
       2:'our-secret2',
       -1:h'849b5786457c1491be3a76dcea6c4271'
     },
     {
       1:4,
       2:'018c0ae5-4d9b-471b-bfd6-eef314bc7037',
       -1:h'849b57219dae48de646d07dbb533566e976686457c1491be3a76dcea6c4
   27188'
     }
   ]

Acknowledgments

   This document is a product of the COSE Working Group of the IETF.

   The following individuals are to blame for getting me started on this
   project in the first place: Richard Barnes, Matt Miller, and Martin
   Thomson.

   The initial draft version of the specification was based to some
   degree on the outputs of the JOSE and S/MIME Working Groups.

   The following individuals provided input into the final form of the
   document: Carsten Bormann, John Bradley, Brian Campbell, Michael
   B. Jones, Ilari Liusvaara, Francesca Palombini, Ludwig Seitz, and
   Göran Selander.

Author's Address

   Jim Schaad
   August Cellars

   Email: ietf@augustcellars.com

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