Internet-Draft | YANG Data Types and Groupings for Crypto | August 2020 |
Watsen | Expires 21 February 2021 | [Page] |
This document presents a YANG 1.1 (RFC 7950) module defining identities, typedefs, and groupings useful to cryptographic applications.¶
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This document presents a YANG 1.1 [RFC7950] module defining identities, typedefs, and groupings useful to cryptographic applications.¶
This document presents one or more YANG modules [RFC7950] that are part of a collection of RFCs that work together to define configuration modules for clients and servers of both the NETCONF [RFC6241] and RESTCONF [RFC8040] protocols.¶
The modules have been defined in a modular fashion to enable their use by other efforts, some of which are known to be in progress at the time of this writing, with many more expected to be defined in time.¶
The normative dependency relationship between the various RFCs in the collection is presented in the below diagram. The labels in the diagram represent the primary purpose provided by each RFC. Hyperlinks to each RFC are provided below the diagram.¶
crypto-types ^ ^ / \ / \ truststore keystore ^ ^ ^ ^ | +---------+ | | | | | | | +------------+ | tcp-client-server | / | | ^ ^ ssh-client-server | | | | ^ tls-client-server | | | ^ ^ http-client-server | | | | | ^ | | | +-----+ +---------+ | | | | | | | | +-----------|--------|--------------+ | | | | | | | | +-----------+ | | | | | | | | | | | | | | | | | netconf-client-server restconf-client-server¶
Label in Diagram | Originating RFC |
---|---|
crypto-types | [I-D.ietf-netconf-crypto-types] |
truststore | [I-D.ietf-netconf-trust-anchors] |
keystore | [I-D.ietf-netconf-keystore] |
tcp-client-server | [I-D.ietf-netconf-tcp-client-server] |
ssh-client-server | [I-D.ietf-netconf-ssh-client-server] |
tls-client-server | [I-D.ietf-netconf-tls-client-server] |
http-client-server | [I-D.ietf-netconf-http-client-server] |
netconf-client-server | [I-D.ietf-netconf-netconf-client-server] |
restconf-client-server | [I-D.ietf-netconf-restconf-client-server] |
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
This document in compliant with the Network Management Datastore Architecture (NMDA) [RFC8342]. It does not define any protocol accessible nodes that are "config false".¶
This section defines a YANG 1.1 [RFC7950] module called "ietf-crypto-types". A high-level overview of the module is provided in Section 2.1. Examples illustatrating the module's use are provided in Examples (Section 2.2). The YANG module itself is defined in Section 2.3.¶
This section provides an overview of the "ietf-crypto-types" module in terms of its features, indentities, typedefs, and groupings.¶
The following diagram lists all the "feature" statements defined in the "ietf-crypt-types" module:¶
Features: +-- one-symmetric-key-format +-- one-asymmetric-key-format +-- encrypted-one-symmetric-key-format +-- encrypted-one-asymmetric-key-format +-- certificate-signing-request-generation +-- certificate-expiration-notification¶
The following diagram illustrates the relationship amongst the "identity" statements defined in the "ietf-crypto-types" module:¶
Identities: +-- public-key-format | +-- subject-public-key-info-format | +-- ssh-public-key-format +-- private-key-format | +-- rsa-private-key-format | +-- ec-private-key-format | +-- one-asymmetric-key-format | | {one-asymmetric-key-format}? | +-- encrypted-one-asymmetric-key-format | {encrypted-one-asymmetric-key-format}? +-- symmetric-key-format +-- octet-string-key-format +-- one-symmetric-key-format | {one-symmetric-key-format}? +-- encrypted-one-symmetric-key-format {encrypted-one-symmetric-key-format}?¶
Comments:¶
The following diagram illustrates the relationship amongst the "typedef" statements defined in the "ietf-crypto-types" module:¶
Typedefs: binary +-- csr-info +-- csr +-- x509 | +-- trust-anchor-cert-x509 | +-- end-entity-cert-x509 +-- crl +-- ocsp-request +-- ocsp-response +-- cms +-- data-content-cms +-- signed-data-cms | +-- trust-anchor-cert-cms | +-- end-entity-cert-cms +-- enveloped-data-cms +-- digested-data-cms +-- encrypted-data-cms +-- authenticated-data-cms¶
Comments:¶
The following diagram lists all the "grouping" statements defined in the "ietf-crypto-types" module:¶
Groupings: +-- encrypted-key-value-grouping +-- password-grouping +-- symmetric-key-grouping +-- public-key-grouping +-- asymmetric-key-pair-grouping +-- trust-anchor-cert-grouping +-- end-entity-cert-grouping +-- generate-csr-grouping +-- asymmetric-key-pair-with-cert-grouping +-- asymmetric-key-pair-with-certs-grouping¶
Each of these groupings are presented in the following subsections.¶
The following tree diagram [RFC8340] illustrates the "encrypted-key-value-grouping" grouping:¶
grouping encrypted-key-value-grouping +-- encrypted-by +-- encrypted-value binary¶
Comments:¶
This section presents two tree diagrams [RFC8340] illustrating the "password-grouping" grouping. The first tree diagram does not expand the internally used grouping statement(s):¶
grouping password-grouping +-- (password-type) +--:(cleartext-password) | +-- cleartext-password? string +--:(encrypted-password) {password-encryption}? +-- encrypted-password +---u encrypted-key-value-grouping¶
The following tree diagram expands the internally used grouping statement(s), enabling the grouping's full structure to be seen:¶
grouping password-grouping +-- (password-type) +--:(cleartext-password) | +-- cleartext-password? string +--:(encrypted-password) {password-encryption}? +-- encrypted-password +-- encrypted-by +-- encrypted-value binary¶
Comments:¶
The "choice" statement enables the password data to be plain-text or encrypted, as follows:¶
This section presents two tree diagrams [RFC8340] illustrating the "symmetric-key-grouping" grouping. The first tree diagram does not expand the internally used grouping statement(s):¶
grouping symmetric-key-grouping +-- key-format? identityref +-- (key-type) +--:(cleartext-key) | +-- cleartext-key? binary +--:(hidden-key) | +-- hidden-key? empty +--:(encrypted-key) {symmetric-key-encryption}? +-- encrypted-key +---u encrypted-key-value-grouping¶
The following tree diagram expands the internally used grouping statement(s), enabling the grouping's full structure to be seen:¶
grouping symmetric-key-grouping +-- key-format? identityref +-- (key-type) +--:(cleartext-key) | +-- cleartext-key? binary +--:(hidden-key) | +-- hidden-key? empty +--:(encrypted-key) {symmetric-key-encryption}? +-- encrypted-key +-- encrypted-by +-- encrypted-value binary¶
Comments:¶
For the referenced grouping statement(s):¶
The "choice" statement enables the private key data to be plain-text, encrypted, or hidden, as follows:¶
The following tree diagram [RFC8340] illustrates the "public-key-grouping" grouping:¶
grouping public-key-grouping +-- public-key-format identityref +-- public-key binary¶
Comments:¶
This section presents two tree diagrams [RFC8340] illustrating the "asymmetric-key-pair-grouping" grouping. The first tree diagram does not expand the internally used grouping statement(s):¶
grouping asymmetric-key-pair-grouping +---u public-key-grouping +-- private-key-format? identityref +-- (private-key-type) +--:(cleartext-private-key) | +-- cleartext-private-key? binary +--:(hidden-private-key) | +-- hidden-private-key? empty +--:(encrypted-private-key) {private-key-encryption}? +-- encrypted-private-key +---u encrypted-key-value-grouping¶
The following tree diagram expands the internally used grouping statement(s), enabling the grouping's full structure to be seen:¶
grouping asymmetric-key-pair-grouping +-- public-key-format identityref +-- public-key binary +-- private-key-format? identityref +-- (private-key-type) +--:(cleartext-private-key) | +-- cleartext-private-key? binary +--:(hidden-private-key) | +-- hidden-private-key? empty +--:(encrypted-private-key) {private-key-encryption}? +-- encrypted-private-key +-- encrypted-by +-- encrypted-value binary¶
Comments:¶
For the referenced grouping statement(s):¶
The "choice" statement enables the private key data to be plain-text, encrypted, or hidden, as follows:¶
The following tree diagram [RFC8340] illustrates the "certificate-expiration-grouping" grouping:¶
grouping certificate-expiration-grouping +---n certificate-expiration {certificate-expiration-notification}? +-- expiration-date yang:date-and-time¶
Comments:¶
This section presents two tree diagrams [RFC8340] illustrating the "trust-anchor-cert-grouping" grouping. The first tree diagram does not expand the internally used grouping statement(s):¶
grouping trust-anchor-cert-grouping +-- cert-data? trust-anchor-cert-cms +---u certificate-expiration-grouping¶
The following tree diagram expands the internally used grouping statement(s), enabling the grouping's full structure to be seen:¶
grouping trust-anchor-cert-grouping +-- cert-data? trust-anchor-cert-cms +---n certificate-expiration {certificate-expiration-notification}? +-- expiration-date yang:date-and-time¶
Comments:¶
For the referenced grouping statement(s):¶
This section presents two tree diagrams [RFC8340] illustrating the "end-entity-cert-grouping" grouping. The first tree diagram does not expand the internally used grouping statement(s):¶
grouping end-entity-cert-grouping +-- cert-data? end-entity-cert-cms +---u certificate-expiration-grouping¶
The following tree diagram expands the internally used grouping statement(s), enabling the grouping's full structure to be seen:¶
grouping end-entity-cert-grouping +-- cert-data? end-entity-cert-cms +---n certificate-expiration {certificate-expiration-notification}? +-- expiration-date yang:date-and-time¶
Comments:¶
For the referenced grouping statement(s):¶
The following tree diagram [RFC8340] illustrates the "generate-csr-grouping" grouping:¶
grouping generate-csr-grouping +---x generate-certificate-signing-request {certificate-signing-request-generation}? +---w input | +---w csr-info ct:csr-info +--ro output +--ro certificate-signing-request ct:csr¶
Comments:¶
This section presents two tree diagrams [RFC8340] illustrating the "asymmetric-key-pair-with-cert-grouping" grouping. The first tree diagram does not expand the internally used grouping statement(s):¶
grouping asymmetric-key-pair-with-cert-grouping +---u asymmetric-key-pair-grouping +---u end-entity-cert-grouping +---u generate-csr-grouping¶
The following tree diagram expands the internally used grouping statement(s), enabling the grouping's full structure to be seen:¶
grouping asymmetric-key-pair-with-cert-grouping +-- public-key-format identityref +-- public-key binary +-- private-key-format? identityref +-- (private-key-type) | +--:(cleartext-private-key) | | +-- cleartext-private-key? binary | +--:(hidden-private-key) | | +-- hidden-private-key? empty | +--:(encrypted-private-key) {private-key-encryption}? | +-- encrypted-private-key | +-- encrypted-by | +-- encrypted-value binary +-- cert-data? end-entity-cert-cms +---n certificate-expiration | {certificate-expiration-notification}? | +-- expiration-date yang:date-and-time +---x generate-certificate-signing-request {certificate-signing-request-generation}? +---w input | +---w csr-info ct:csr-info +--ro output +--ro certificate-signing-request ct:csr¶
Comments:¶
For the referenced grouping statement(s):¶
This section presents two tree diagrams [RFC8340] illustrating the "asymmetric-key-pair-with-certs-grouping" grouping. The first tree diagram does not expand the internally used grouping statement(s):¶
grouping asymmetric-key-pair-with-certs-grouping +---u asymmetric-key-pair-grouping +-- certificates | +-- certificate* [name] | +-- name? string | +---u end-entity-cert-grouping +---u generate-csr-grouping¶
The following tree diagram expands the internally used grouping statement(s), enabling the grouping's full structure to be seen:¶
grouping asymmetric-key-pair-with-certs-grouping +-- public-key-format identityref +-- public-key binary +-- private-key-format? identityref +-- (private-key-type) | +--:(cleartext-private-key) | | +-- cleartext-private-key? binary | +--:(hidden-private-key) | | +-- hidden-private-key? empty | +--:(encrypted-private-key) {private-key-encryption}? | +-- encrypted-private-key | +-- encrypted-by | +-- encrypted-value binary +-- certificates | +-- certificate* [name] | +-- name? string | +-- cert-data end-entity-cert-cms | +---n certificate-expiration | {certificate-expiration-notification}? | +-- expiration-date yang:date-and-time +---x generate-certificate-signing-request {certificate-signing-request-generation}? +---w input | +---w csr-info ct:csr-info +--ro output +--ro certificate-signing-request ct:csr¶
Comments:¶
For the referenced grouping statement(s):¶
The "ietf-crypto-types" module does not contain any protocol-accessible nodes, but the module needs to be "implemented", as described in Section 5.6.5 of [RFC7950], in order for the identities in Section 2.1.2 to be defined.¶
The following non-normative module is constructed in order to illustrate the use of the "symmetric-key-grouping" (Section 2.1.4.3) and the "asymmetric-key-pair-with-certs-grouping" (Section 2.1.4.11) grouping statements:¶
module ex-crypto-types-usage { yang-version 1.1; namespace "http://example.com/ns/example-crypto-types-usage"; prefix "ectu"; import ietf-crypto-types { prefix ct; reference "RFC AAAA: YANG Data Types and Groupings for Cryptography"; } organization "Example Corporation"; contact "YANG Designer <mailto:yang.designer@example.com>"; description "This module illustrates the 'symmetric-key-grouping' and 'asymmetric-key-grouping' groupings defined in the 'ietf-crypto-types' module defined in RFC AAAA."; revision "2020-08-20" { description "Initial version"; reference "RFC AAAA: Common YANG Data Types for Cryptography"; } container symmetric-keys { description "A container of symmetric keys."; list symmetric-key { key name; description "A symmetric key"; leaf name { type string; description "An arbitrary name for this key."; } uses ct:symmetric-key-grouping { augment "key-type/encrypted-key/encrypted-key/" + "encrypted-by" { description "Augments in a choice statement enabling the encrypting key to be any other symmetric or asymmetric key."; uses encrypted-by-choice-grouping; } } } } container asymmetric-keys { description "A container of asymmetric keys."; list asymmetric-key { key name; leaf name { type string; description "An arbitrary name for this key."; } uses ct:asymmetric-key-pair-with-certs-grouping { augment "private-key-type/encrypted-private-key/" + "encrypted-private-key/encrypted-by" { description "Augments in a choice statement enabling the encrypting key to be any other symmetric or asymmetric key."; uses encrypted-by-choice-grouping; } } description "An asymmetric key pair with associated certificates."; } } grouping encrypted-by-choice-grouping { description "A grouping that defines a choice enabling references to other keys."; choice encrypted-by-choice { mandatory true; description "A choice amongst other symmetric or asymmetric keys."; case symmetric-key-ref { leaf symmetric-key-ref { type leafref { path "/ectu:symmetric-keys/ectu:symmetric-key/" + "ectu:name"; } description "Identifies the symmetric key used to encrypt this key."; } } case asymmetric-key-ref { leaf asymmetric-key-ref { type leafref { path "/ectu:asymmetric-keys/ectu:asymmetric-key/" + "ectu:name"; } description "Identifies the asymmetric key used to encrypt this key."; } } } } }¶
The tree diagram [RFC8340] for this example module follows:¶
module: ex-crypto-types-usage +--rw symmetric-keys | +--rw symmetric-key* [name] | +--rw name string | +--rw key-format? identityref | +--rw (key-type) | +--:(cleartext-key) | | +--rw cleartext-key? binary | +--:(hidden-key) | | +--rw hidden-key? empty | +--:(encrypted-key) {symmetric-key-encryption}? | +--rw encrypted-key | +--rw encrypted-by | | +--rw (encrypted-by-choice) | | +--:(symmetric-key-ref) | | | +--rw symmetric-key-ref? leafref | | +--:(asymmetric-key-ref) | | +--rw asymmetric-key-ref? leafref | +--rw encrypted-value binary +--rw asymmetric-keys +--rw asymmetric-key* [name] +--rw name string +--rw public-key-format identityref +--rw public-key binary +--rw private-key-format? identityref +--rw (private-key-type) | +--:(cleartext-private-key) | | +--rw cleartext-private-key? binary | +--:(hidden-private-key) | | +--rw hidden-private-key? empty | +--:(encrypted-private-key) {private-key-encryption}? | +--rw encrypted-private-key | +--rw encrypted-by | | +--rw (encrypted-by-choice) | | +--:(symmetric-key-ref) | | | +--rw symmetric-key-ref? leafref | | +--:(asymmetric-key-ref) | | +--rw asymmetric-key-ref? leafref | +--rw encrypted-value binary +--rw certificates | +--rw certificate* [name] | +--rw name string | +--rw cert-data end-entity-cert-cms | +---n certificate-expiration | {certificate-expiration-notification}? | +-- expiration-date yang:date-and-time +---x generate-certificate-signing-request {certificate-signing-request-generation}? +---w input | +---w csr-info ct:csr-info +--ro output +--ro certificate-signing-request ct:csr grouping encrypted-by-choice-grouping +-- (encrypted-by-choice) +--:(symmetric-key-ref) | +-- symmetric-key-ref? | -> /symmetric-keys/symmetric-key/name +--:(asymmetric-key-ref) +-- asymmetric-key-ref? -> /asymmetric-keys/asymmetric-key/name¶
Finally, the following example illustrates various symmetric and asymmetric keys as they might appear in confugration:¶
=============== NOTE: '\' line wrapping per RFC 8792 ================ <symmetric-keys xmlns="http://example.com/ns/example-crypto-types-usage" xmlns:ct="urn:ietf:params:xml:ns:yang:ietf-crypto-types"> <symmetric-key> <name>ex-hidden-symmetric-key</name> <hidden-key/> </symmetric-key> <symmetric-key> <name>ex-octet-string-based-symmetric-key</name> <key-format>ct:octet-string-key-format</key-format> <cleartext-key>base64encodedvalue==</cleartext-key> </symmetric-key> <symmetric-key> <name>ex-one-symmetric-based-symmetric-key</name> <key-format>ct:one-symmetric-key-format</key-format> <cleartext-key>base64encodedvalue==</cleartext-key> </symmetric-key> <symmetric-key> <name>ex-encrypted-one-symmetric-based-symmetric-key</name> <key-format>ct:encrypted-one-symmetric-key-format</key-format> <encrypted-key> <encrypted-by> <asymmetric-key-ref>ex-hidden-asymmetric-key</asymmetric-key\ -ref> </encrypted-by> <encrypted-value>base64encodedvalue==</encrypted-value> </encrypted-key> </symmetric-key> </symmetric-keys> <asymmetric-keys xmlns="http://example.com/ns/example-crypto-types-usage" xmlns:ct="urn:ietf:params:xml:ns:yang:ietf-crypto-types"> <asymmetric-key> <name>ex-hidden-asymmetric-key</name> <public-key-format> ct:subject-public-key-info-format </public-key-format> <public-key>base64encodedvalue==</public-key> <hidden-private-key/> <certificates> <certificate> <name>ex-hidden-asymmetric-key-cert</name> <cert-data>base64encodedvalue==</cert-data> </certificate> </certificates> </asymmetric-key> <asymmetric-key> <name>ex-subject-public-info-based-asymmetric-key</name> <public-key-format> ct:subject-public-key-info-format </public-key-format> <public-key>base64encodedvalue==</public-key> <private-key-format> ct:rsa-private-key-format </private-key-format> <cleartext-private-key>base64encodedvalue==</cleartext-private-k\ ey> <certificates> <certificate> <name>ex-cert</name> <cert-data>base64encodedvalue==</cert-data> </certificate> </certificates> </asymmetric-key> <asymmetric-key> <name>ex-one-asymmetric-based-symmetric-key</name> <public-key-format> ct:subject-public-key-info-format </public-key-format> <public-key>base64encodedvalue==</public-key> <private-key-format> ct:one-asymmetric-key-format </private-key-format> <cleartext-private-key>base64encodedvalue==</cleartext-private-k\ ey> </asymmetric-key> <asymmetric-key> <name>ex-encrypted-one-asymmetric-based-symmetric-key</name> <public-key-format> ct:subject-public-key-info-format </public-key-format> <public-key>base64encodedvalue==</public-key> <private-key-format> ct:encrypted-one-asymmetric-key-format </private-key-format> <encrypted-private-key> <encrypted-by> <symmetric-key-ref>ex-encrypted-one-symmetric-based-symmetri\ c-key</symmetric-key-ref> </encrypted-by> <encrypted-value>base64encodedvalue==</encrypted-value> </encrypted-private-key> </asymmetric-key> </asymmetric-keys>¶
The following example illustrates the "generate-certificate-signing-request" action, discussed in Section 2.1.4.9, with the NETCONF protocol.¶
REQUEST¶
<rpc message-id="101" xmlns="urn:ietf:params:xml:ns:netconf:base:1.0"> <action xmlns="urn:ietf:params:xml:ns:yang:1"> <asymmetric-keys xmlns="http://example.com/ns/example-crypto-types-usage"> <asymmetric-key> <name>ex-key-sect571r1</name> <generate-certificate-signing-request> <csr-info>base64encodedvalue==</csr-info> </generate-certificate-signing-request> </asymmetric-key> </asymmetric-keys> </action> </rpc>¶
RESPONSE¶
<rpc-reply message-id="101" xmlns="urn:ietf:params:xml:ns:netconf:base:1.0"> <certificate-signing-request xmlns="http://example.com/ns/example-crypto-types-usage"> base64encodedvalue== </certificate-signing-request> </rpc-reply>¶
The following example illustrates the "certificate-expiration" notification, discussed in Section 2.1.4.6, with the NETCONF protocol.¶
=============== NOTE: '\' line wrapping per RFC 8792 ================ <notification xmlns="urn:ietf:params:xml:ns:netconf:notification:1.0"> <eventTime>2018-05-25T00:01:00Z</eventTime> <asymmetric-keys xmlns="http://example.com/ns/example-crypto-types\ -usage"> <asymmetric-key> <name>ex-hidden-asymmetric-key</name> <certificates> <certificate> <name>ex-hidden-asymmetric-key</name> <certificate-expiration> <expiration-date>2018-08-05T14:18:53-05:00</expiration-d\ ate> </certificate-expiration> </certificate> </certificates> </asymmetric-key> </asymmetric-keys> </notification>¶
This module has normative references to [RFC2119], [RFC2986], [RFC3447], [RFC4253], [RFC5280], [RFC5652], [RFC5915], [RFC5958], [RFC6031], [RFC6125], [RFC6991], [RFC8174], [RFC8341], and [ITU.X690.2015].¶
<CODE BEGINS> file "ietf-crypto-types@2020-08-20.yang"¶
module ietf-crypto-types { yang-version 1.1; namespace "urn:ietf:params:xml:ns:yang:ietf-crypto-types"; prefix ct; import ietf-yang-types { prefix yang; reference "RFC 6991: Common YANG Data Types"; } import ietf-netconf-acm { prefix nacm; reference "RFC 8341: Network Configuration Access Control Model"; } organization "IETF NETCONF (Network Configuration) Working Group"; contact "WG Web: <http://datatracker.ietf.org/wg/netconf/> WG List: <mailto:netconf@ietf.org> Author: Kent Watsen <mailto:kent+ietf@watsen.net>"; description "This module defines common YANG types for cryptographic applications. Copyright (c) 2020 IETF Trust and the persons identified as authors of the code. All rights reserved. Redistribution and use in source and binary forms, with or without modification, is permitted pursuant to, and subject to the license terms contained in, the Simplified BSD License set forth in Section 4.c of the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/license-info). This version of this YANG module is part of RFC AAAA (https://www.rfc-editor.org/info/rfcAAAA); see the RFC itself for full legal notices. 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 (RFC 2119) (RFC 8174) when, and only when, they appear in all capitals, as shown here."; revision 2020-08-20 { description "Initial version"; reference "RFC AAAA: YANG Data Types and Groupings for Cryptography"; } /****************/ /* Features */ /****************/ feature one-symmetric-key-format { description "Indicates that the server supports the 'one-symmetric-key-format' identity."; } feature one-asymmetric-key-format { description "Indicates that the server supports the 'one-asymmetric-key-format' identity."; } feature encrypted-one-symmetric-key-format { description "Indicates that the server supports the 'encrypted-one-symmetric-key-format' identity."; } feature encrypted-one-asymmetric-key-format { description "Indicates that the server supports the 'encrypted-one-asymmetric-key-format' identity."; } feature certificate-signing-request-generation { description "Indicates that the server implements the 'generate-certificate-signing-request' action."; } feature certificate-expiration-notification { description "Indicates that the server implements the 'certificate-expiration' notification."; } feature password-encryption { description "Indicates that the server supports password encryption."; } feature symmetric-key-encryption { description "Indicates that the server supports password encryption."; } feature private-key-encryption { description "Indicates that the server supports password encryption."; } /*************************************************/ /* Base Identities for Key Format Structures */ /*************************************************/ identity symmetric-key-format { description "Base key-format identity for symmetric keys."; } identity public-key-format { description "Base key-format identity for public keys."; } identity private-key-format { description "Base key-format identity for private keys."; } /****************************************************/ /* Identities for Private Key Format Structures */ /****************************************************/ identity rsa-private-key-format { base "private-key-format"; description "Indicates that the private key value is encoded as an RSAPrivateKey (from RFC 3447)."; reference "RFC 3447: PKCS #1: RSA Cryptography Specifications Version 2.2"; } identity ec-private-key-format { base "private-key-format"; description "Indicates that the private key value is encoded as an ECPrivateKey (from RFC 5915)"; reference "RFC 5915: Elliptic Curve Private Key Structure"; } identity one-asymmetric-key-format { if-feature "one-asymmetric-key-format"; base "private-key-format"; description "Indicates that the private key value is a CMS OneAsymmetricKey structure, as defined in RFC 5958, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 5958: Asymmetric Key Packages ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } identity encrypted-one-asymmetric-key-format { if-feature "encrypted-one-asymmetric-key-format"; base "private-key-format"; description "Indicates that the private key value is a CMS EnvelopedData structure, per Section 8 in RFC 5652, containing a OneAsymmetricKey structure, as defined in RFC 5958, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 5652: Cryptographic Message Syntax (CMS) RFC 5958: Asymmetric Key Packages ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } /***************************************************/ /* Identities for Public Key Format Structures */ /***************************************************/ identity ssh-public-key-format { base "public-key-format"; description "Indicates that the public key value is an SSH public key, as specified by RFC 4253, Section 6.6, i.e.: string certificate or public key format identifier byte[n] key/certificate data."; reference "RFC 4253: The Secure Shell (SSH) Transport Layer Protocol"; } identity subject-public-key-info-format { base "public-key-format"; description "Indicates that the public key value is a SubjectPublicKeyInfo structure, as described in RFC 5280 encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 5280: Internet X.509 Public Key Infrastructure Certificate and Certificate Revocation List (CRL) Profile ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } /******************************************************/ /* Identities for Symmetric Key Format Structures */ /******************************************************/ identity octet-string-key-format { base "symmetric-key-format"; description "Indicates that the key is encoded as a raw octet string. The length of the octet string MUST be appropriate for the associated algorithm's block size."; } identity one-symmetric-key-format { if-feature "one-symmetric-key-format"; base "symmetric-key-format"; description "Indicates that the private key value is a CMS OneSymmetricKey structure, as defined in RFC 6031, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 6031: Cryptographic Message Syntax (CMS) Symmetric Key Package Content Type ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } identity encrypted-one-symmetric-key-format { if-feature "encrypted-one-symmetric-key-format"; base "symmetric-key-format"; description "Indicates that the private key value is a CMS EnvelopedData structure, per Section 8 in RFC 5652, containing a OneSymmetricKey structure, as defined in RFC 6031, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 5652: Cryptographic Message Syntax (CMS) RFC 6031: Cryptographic Message Syntax (CMS) Symmetric Key Package Content Type ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } /***************************************************/ /* Typedefs for ASN.1 structures from RFC 2986 */ /***************************************************/ typedef csr-info { type binary; description "A CertificationRequestInfo structure, as defined in RFC 2986, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 2986: PKCS #10: Certification Request Syntax Specification Version 1.7 ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } typedef csr { type binary; description "A CertificationRequest structure, as specified in RFC 2986, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 2986: PKCS #10: Certification Request Syntax Specification Version 1.7 ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } /***************************************************/ /* Typedefs for ASN.1 structures from RFC 5280 */ /***************************************************/ typedef x509 { type binary; description "A Certificate structure, as specified in RFC 5280, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 5280: Internet X.509 Public Key Infrastructure Certificate and Certificate Revocation List (CRL) Profile ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } typedef crl { type binary; description "A CertificateList structure, as specified in RFC 5280, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 5280: Internet X.509 Public Key Infrastructure Certificate and Certificate Revocation List (CRL) Profile ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } /***************************************************/ /* Typedefs for ASN.1 structures from RFC 6960 */ /***************************************************/ typedef oscp-request { type binary; description "A OCSPRequest structure, as specified in RFC 6960, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 6960: X.509 Internet Public Key Infrastructure Online Certificate Status Protocol - OCSP ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } typedef oscp-response { type binary; description "A OCSPResponse structure, as specified in RFC 6960, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 6960: X.509 Internet Public Key Infrastructure Online Certificate Status Protocol - OCSP ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } /***********************************************/ /* Typedefs for ASN.1 structures from 5652 */ /***********************************************/ typedef cms { type binary; description "A ContentInfo structure, as specified in RFC 5652, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 5652: Cryptographic Message Syntax (CMS) ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; } typedef data-content-cms { type cms; description "A CMS structure whose top-most content type MUST be the data content type, as described by Section 4 in RFC 5652."; reference "RFC 5652: Cryptographic Message Syntax (CMS)"; } typedef signed-data-cms { type cms; description "A CMS structure whose top-most content type MUST be the signed-data content type, as described by Section 5 in RFC 5652."; reference "RFC 5652: Cryptographic Message Syntax (CMS)"; } typedef enveloped-data-cms { type cms; description "A CMS structure whose top-most content type MUST be the enveloped-data content type, as described by Section 6 in RFC 5652."; reference "RFC 5652: Cryptographic Message Syntax (CMS)"; } typedef digested-data-cms { type cms; description "A CMS structure whose top-most content type MUST be the digested-data content type, as described by Section 7 in RFC 5652."; reference "RFC 5652: Cryptographic Message Syntax (CMS)"; } typedef encrypted-data-cms { type cms; description "A CMS structure whose top-most content type MUST be the encrypted-data content type, as described by Section 8 in RFC 5652."; reference "RFC 5652: Cryptographic Message Syntax (CMS)"; } typedef authenticated-data-cms { type cms; description "A CMS structure whose top-most content type MUST be the authenticated-data content type, as described by Section 9 in RFC 5652."; reference "RFC 5652: Cryptographic Message Syntax (CMS)"; } /*********************************************************/ /* Typedefs for ASN.1 structures related to RFC 5280 */ /*********************************************************/ typedef trust-anchor-cert-x509 { type x509; description "A Certificate structure that MUST encode a self-signed root certificate."; } typedef end-entity-cert-x509 { type x509; description "A Certificate structure that MUST encode a certificate that is neither self-signed nor having Basic constraint CA true."; } /*********************************************************/ /* Typedefs for ASN.1 structures related to RFC 5652 */ /*********************************************************/ typedef trust-anchor-cert-cms { type signed-data-cms; description "A CMS SignedData structure that MUST contain the chain of X.509 certificates needed to authenticate the certificate presented by a client or end-entity. The CMS MUST contain only a single chain of certificates. The client or end-entity certificate MUST only authenticate to last intermediate CA certificate listed in the chain. In all cases, the chain MUST include a self-signed root certificate. In the case where the root certificate is itself the issuer of the client or end-entity certificate, only one certificate is present. This CMS structure MAY (as applicable where this type is used) also contain suitably fresh (as defined by local policy) revocation objects with which the device can verify the revocation status of the certificates. This CMS encodes the degenerate form of the SignedData structure that is commonly used to disseminate X.509 certificates and revocation objects (RFC 5280)."; reference "RFC 5280: Internet X.509 Public Key Infrastructure Certificate and Certificate Revocation List (CRL) Profile."; } typedef end-entity-cert-cms { type signed-data-cms; description "A CMS SignedData structure that MUST contain the end entity certificate itself, and MAY contain any number of intermediate certificates leading up to a trust anchor certificate. The trust anchor certificate MAY be included as well. The CMS MUST contain a single end entity certificate. The CMS MUST NOT contain any spurious certificates. This CMS structure MAY (as applicable where this type is used) also contain suitably fresh (as defined by local policy) revocation objects with which the device can verify the revocation status of the certificates. This CMS encodes the degenerate form of the SignedData structure that is commonly used to disseminate X.509 certificates and revocation objects (RFC 5280)."; reference "RFC 5280: Internet X.509 Public Key Infrastructure Certificate and Certificate Revocation List (CRL) Profile."; } /*****************/ /* Groupings */ /*****************/ grouping encrypted-key-value-grouping { description "A reusable grouping for a value that has been encrypted by a symmetric or asymmetric key in the Keystore."; container encrypted-by { nacm:default-deny-write; description "An empty container enabling references to other keys that encrypt these keys to be augmented in. The referenced key MAY be a symmetric or an asymmetric key."; } leaf encrypted-value { nacm:default-deny-write; type binary; must "../encrypted-by"; mandatory true; description "The value, encrypted using the referenced symmetric or asymmetric key."; } } grouping password-grouping { description "A password that MAY be encrypted."; choice password-type { nacm:default-deny-write; mandatory true; description "Choice between password types."; case cleartext-password { leaf cleartext-password { nacm:default-deny-all; type string; description "The cleartext value of the password."; } } case encrypted-password { if-feature password-encryption; container encrypted-password { description "A container for the encrypted password value. The format of the 'encrypted-value' node is a CMS EnvelopedData structure, per Section 8 in RFC 5652, encoded using ASN.1 distinguished encoding rules (DER), as specified in ITU-T X.690."; reference "RFC 5652: Cryptographic Message Syntax (CMS) ITU-T X.690: Information technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)."; uses encrypted-key-value-grouping; } } } } grouping symmetric-key-grouping { description "A symmetric key."; leaf key-format { nacm:default-deny-write; type identityref { base symmetric-key-format; } description "Identifies the symmetric key's format. Implementations SHOULD ensure that the incoming symmetric key value is encoded in the specified format."; } choice key-type { nacm:default-deny-write; mandatory true; description "Choice between key types."; case cleartext-key { leaf cleartext-key { nacm:default-deny-all; type binary; must "../key-format"; description "The binary value of the key. The interpretation of the value is defined by the 'key-format' field."; } } case hidden-key { leaf hidden-key { type empty; must "not(../key-format)"; description "A hidden key. How such keys are created is outside the scope of this module."; } } case encrypted-key { if-feature symmetric-key-encryption; container encrypted-key { must "../key-format"; description "A container for the encrypted symmetric key value. The interpretation of the 'encrypted-value' node is via the 'key-format' node"; uses encrypted-key-value-grouping; } } } } grouping public-key-grouping { description "A public key."; leaf public-key-format { nacm:default-deny-write; type identityref { base public-key-format; } mandatory true; description "Identifies the public key's format. Implementations SHOULD ensure that the incoming public key value is encoded in the specified format."; } leaf public-key { nacm:default-deny-write; type binary; mandatory true; description "The binary value of the public key. The interpretation of the value is defined by 'public-key-format' field."; } } grouping asymmetric-key-pair-grouping { description "A private key and its associated public key. Implementations SHOULD ensure that the two keys are a matching pair."; uses public-key-grouping; leaf private-key-format { nacm:default-deny-write; type identityref { base private-key-format; } description "Identifies the private key's format. Implementations SHOULD ensure that the incoming private key value is encoded in the specified format."; } choice private-key-type { nacm:default-deny-write; mandatory true; description "Choice between key types."; case cleartext-private-key { leaf cleartext-private-key { nacm:default-deny-all; type binary; must "../private-key-format"; description "The value of the binary key The key's value is interpreted by the 'private-key-format' field."; } } case hidden-private-key { leaf hidden-private-key { type empty; must "not(../private-key-format)"; description "A hidden key. How such keys are created is outside the scope of this module."; } } case encrypted-private-key { if-feature private-key-encryption; container encrypted-private-key { must "../private-key-format"; description "A container for the encrypted asymmetric private key value. The interpretation of the 'encrypted-value' node is via the 'private-key-format' node"; uses encrypted-key-value-grouping; } } } } grouping certificate-expiration-grouping { description "A notification for when a certificate is about to, or already has, expired."; notification certificate-expiration { if-feature certificate-expiration-notification; description "A notification indicating that the configured certificate is either about to expire or has already expired. When to send notifications is an implementation specific decision, but it is RECOMMENDED that a notification be sent once a month for 3 months, then once a week for four weeks, and then once a day thereafter until the issue is resolved."; leaf expiration-date { type yang:date-and-time; mandatory true; description "Identifies the expiration date on the certificate."; } } } grouping trust-anchor-cert-grouping { description "A trust anchor certificate, and a notification for when it is about to (or already has) expire."; leaf cert-data { nacm:default-deny-write; type trust-anchor-cert-cms; description "The binary certificate data for this certificate."; } uses certificate-expiration-grouping; } grouping end-entity-cert-grouping { description "An end entity certificate, and a notification for when it is about to (or already has) expire. Implementations SHOULD assert that, where used, the end entity certificate contains the expected public key."; leaf cert-data { nacm:default-deny-write; type end-entity-cert-cms; description "The binary certificate data for this certificate."; } uses certificate-expiration-grouping; } grouping generate-csr-grouping { description "Defines the 'generate-certificate-signing-request' action."; action generate-certificate-signing-request { if-feature certificate-signing-request-generation; nacm:default-deny-all; description "Generates a certificate signing request structure for the associated asymmetric key using the passed subject and attribute values. This action statement is only available when the associated 'public-key-format' node's value is 'subject-public-key-info-format'."; reference "RFC 6125: Representation and Verification of Domain-Based Application Service Identity within Internet Public Key Infrastructure Using X.509 (PKIX) Certificates in the Context of Transport Layer Security (TLS)"; input { leaf csr-info { type ct:csr-info; mandatory true; description "A CertificationRequestInfo structure, as defined in RFC 2986. Enables the client to provide a fully-populated CertificationRequestInfo structure that the server only needs to sign in order to generate the complete 'CertificationRequest' structure to return in the 'output'. The 'AlgorithmIdentifier' field contained inside the 'SubjectPublicKeyInfo' field MUST be one known to be supported by the device."; reference "RFC 2986: PKCS #10: Certification Request Syntax Specification RFC AAAA: YANG Data Types and Groupings for Cryptography"; } } output { leaf certificate-signing-request { type ct:csr; mandatory true; description "A CertificationRequest structure, as defined in RFC 2986."; reference "RFC 2986: PKCS #10: Certification Request Syntax Specification RFC AAAA: YANG Data Types and Groupings for Cryptography"; } } } } // generate-csr-grouping grouping asymmetric-key-pair-with-cert-grouping { description "A private/public key pair and an associated certificate. Implementations SHOULD assert that certificates contain the matching public key."; uses asymmetric-key-pair-grouping; uses end-entity-cert-grouping; uses generate-csr-grouping; } // asymmetric-key-pair-with-cert-grouping grouping asymmetric-key-pair-with-certs-grouping { description "A private/public key pair and associated certificates. Implementations SHOULD assert that certificates contain the matching public key."; uses asymmetric-key-pair-grouping; container certificates { nacm:default-deny-write; description "Certificates associated with this asymmetric key. More than one certificate supports, for instance, a TPM-protected asymmetric key that has both IDevID and LDevID certificates associated."; list certificate { key "name"; description "A certificate for this asymmetric key."; leaf name { type string; description "An arbitrary name for the certificate. If the name matches the name of a certificate that exists independently in <operational> (i.e., an IDevID), then the 'cert' node MUST NOT be configured."; } uses end-entity-cert-grouping { refine cert-data { mandatory true; } } } } uses generate-csr-grouping; } // asymmetric-key-pair-with-certs-grouping }¶
<CODE ENDS>¶
This document uses PKCS #10 [RFC2986] for the "generate-certificate-signing-request" action. The use of Certificate Request Message Format (CRMF) [RFC4211] was considered, but is was unclear if there was market demand for it. If it is desired to support CRMF in the future, a backwards compatible solution can be defined at that time.¶
Early revisions of this document included "rpc" statements for generating symmetric and asymmetric keys. There statements were removed due to an inability to obtain consensus for how to identify the key-algorithm to use. Thusly, the solution presented in this document only supports keys to be configured via an external client, which does not support Security best practice.¶
When configuring key values, implementations SHOULD ensure that the strength of the key being configured is not greater than the strength of the underlying secure transport connection over which it is communicated. Implementations SHOULD fail the write-request if ever the strength of the private key is greater then the strength of the underlying transport.¶
This module defines storage for cleartext key values that SHOULD be zeroized when deleted, so as to prevent the remnants of their persisted storage locations from being analyzed in any meaningful way.¶
The cleartext key values are the "cleartext-key" node defined in the "symmetric-key-grouping" grouping (Section 2.1.4.3) and the "cleartext-private-key" node defined in the "asymmetric-key-pair-grouping" grouping ("Section 2.1.4.5).¶
The YANG module in this document defines "grouping" statements that are designed to be accessed via YANG based management protocols, such as NETCONF [RFC6241] and RESTCONF [RFC8040]. Both of these protocols have mandatory-to-implement secure transport layers (e.g., SSH, TLS) with mutual authentication.¶
The NETCONF access control model (NACM) [RFC8341] provides the means to restrict access for particular users to a pre-configured subset of all available protocol operations and content.¶
Since the module in this document only define groupings, these considerations are primarily for the designers of other modules that use these groupings.¶
Some of the readable data nodes defined in this YANG module may be considered sensitive or vulnerable in some network environments. It is thus important to control read access (e.g., via get, get-config, or notification) to these data nodes. These are the subtrees and data nodes and their sensitivity/vulnerability:¶
The "cleartext-key" node:¶
The "cleartext-private-key" node:¶
All of the writable data nodes defined by all the groupings defined in this module may be considered sensitive or vulnerable in some network environments. For instance, even the modification of a public key or a certificate can dramatically alter the implemented security policy. For this reason, the NACM extension "default-deny-write" has been applied to all the data nodes defined in the module.¶
Some of the operations in this YANG module may be considered sensitive or vulnerable in some network environments. It is thus important to control access to these operations. These are the operations and their sensitivity/vulnerability:¶
generate-certificate-signing-request:¶
This document registers one URI in the "ns" subregistry of the "IETF XML" registry [RFC3688]. Following the format in [RFC3688], the following registration is requested:¶
URI: urn:ietf:params:xml:ns:yang:ietf-crypto-types Registrant Contact: The NETCONF WG of the IETF. XML: N/A, the requested URI is an XML namespace.¶
This document registers one YANG module in the "YANG Module Names" registry [RFC6020]. Following the format in [RFC6020], the following registration is requested:¶
name: ietf-crypto-types namespace: urn:ietf:params:xml:ns:yang:ietf-crypto-types prefix: ct reference: RFC AAAA¶
This section is to be removed before publishing as an RFC.¶
The authors would like to thank for following for lively discussions on list and in the halls (ordered by first name): Balazs Kovacs, Eric Voit, Juergen Schoenwaelder, Liang Xia, Martin Bjorklund, Nick Hancock, Rich Salz, Rob Wilton, Sandra Murphy, Tom Petch, and Wang Haiguang.¶