|
|
|
|
|
IETF RFC 6486
Last modified on Saturday, February 4th, 2012
Permanent link to RFC 6486
Search GitHub Wiki for RFC 6486
Show other RFCs mentioning RFC 6486
Internet Engineering Task Force (IETF) R. Austein
Request for Comments: 6486 ISC
Category: Standards Track G. Huston
ISSN: 2070-1721 APNIC
S. Kent
M. Lepinski
BBN
February 2012
Manifests for the Resource Public Key Infrastructure (RPKI)
Abstract
This document defines a "manifest" for use in the Resource Public Key
Infrastructure (RPKI). A manifest is a signed object (file) that
contains a listing of all the signed objects (files) in the
repository publication point (directory) associated with an authority
responsible for publishing in the repository. For each certificate,
Certificate Revocation List (CRL), or other type of signed objects
issued by the authority that are published at this repository
publication point, the manifest contains both the name of the file
containing the object and a hash of the file content. Manifests are
intended to enable a relying party (RP) to detect certain forms of
attacks against a repository. Specifically, if an RP checks a
manifest's contents against the signed objects retrieved from a
repository publication point, then the RP can detect "stale" (valid)
data and deletion of signed objects.
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 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/RFC 6486.
Austein, et al. Standards Track PAGE 1
RFC 6486 RPKI Manifests February 2012
Copyright Notice
Copyright (c) 2012 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
(http://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 ....................................................3
1.1. Terminology ................................................3
2. Manifest Scope ..................................................4
3. Manifest Signing ................................................4
4. Manifest Definition .............................................5
4.1. eContentType ...............................................5
4.2. eContent ...................................................5
4.2.1. Manifest ............................................5
4.3. Content-Type Attribute .....................................7
4.4. Manifest Validation ........................................7
5. Manifest Generation .............................................7
5.1. Manifest Generation Procedure ..............................7
5.2. Considerations for Manifest Generation .....................9
6. Relying Party Use of Manifests ..................................9
6.1. Tests for Determining Manifest State ......................10
6.2. Missing Manifests .........................................11
6.3. Invalid Manifests .........................................12
6.4. Stale Manifests ...........................................12
6.5. Mismatch between Manifest and Publication Point ...........13
6.6. Hash Values Not Matching Manifests ........................14
7. Publication Repositories .......................................15
8. Security Considerations ........................................15
9. IANA Considerations ............................................16
10. Acknowledgements ..............................................16
11. References ....................................................16
11.1. Normative References .....................................16
11.2. Informative References ...................................17
Appendix A. ASN.1 Module ..........................................18
Austein, et al. Standards Track PAGE 2
RFC 6486 RPKI Manifests February 2012
1. Introduction
The Resource Public Key Infrastructure (RPKI) [RFC 6480] makes use of
a distributed repository system [RFC 6481] to make available a variety
of objects needed by relying parties (RPs). Because all of the
objects stored in the repository system are digitally signed by the
entities that created them, attacks that modify these published
objects are detectable by RPs. However, digital signatures provide
no protection against attacks that substitute "stale" versions of
signed objects (i.e., objects that were valid and have not expired,
but have since been superseded) or attacks that remove an object that
should be present in the repository. To assist in the detection of
such attacks, the RPKI repository system can make use of a signed
object called a "manifest".
A manifest is a signed object that enumerates all the signed objects
(files) in the repository publication point (directory) that are
associated with an authority responsible for publishing at that
publication point. Each manifest contains both the name of the file
containing the object and a hash of the file content, for every
signed object issued by an authority that is published at the
authority's repository publication point. A manifest is intended to
allow an RP to detect unauthorized object removal or the substitution
of stale versions of objects at a publication point. A manifest also
is intended to allow an RP to detect similar outcomes that may result
from a man-in-the-middle attack on the retrieval of objects from the
repository. Manifests are intended to be used in Certification
Authority (CA) publication points in repositories (directories
containing files that are subordinate certificates and Certificate
Revocation Lists (CRLs) issued by this CA and other signed objects
that are verified by end-entity (EE) certificates issued by this CA).
Manifests are modeled on CRLs, as the issues involved in detecting
stale manifests and potential attacks using manifest replays, etc.,
are similar to those for CRLs. The syntax of the manifest payload
differs from CRLs, since RPKI repositories contain objects not
covered by CRLs, e.g., digitally signed objects, such as Route
Origination Authorizations (ROAs).
1.1. Terminology
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in [RFC 2119].
Austein, et al. Standards Track PAGE 3
RFC 6486 RPKI Manifests February 2012
2. Manifest Scope
A manifest associated with a CA's repository publication point
contains a list of:
* the set of (non-expired, non-revoked) certificates issued and
published by this CA,
* the most recent CRL issued by this CA, and
* all published signed objects that are verifiable using EE
certificates [RFC 6487] issued by this CA.
Every RPKI signed object includes, in the Cryptographic Message
Syntax (CMS) [RFC 3370] wrapper of the object, the EE certificate used
to verify it [RFC 6488]. Thus, there is no requirement to separately
publish that EE certificate at the CA's repository publication point.
Where multiple CA instances share a common publication point, as can
occur when an entity performs a key-rollover operation [RFC 6489], the
repository publication point will contain multiple manifests. In
this case, each manifest describes only the collection of published
products of its associated CA instance.
3. Manifest Signing
A CA's manifest is verified using an EE certificate. The
SubjectInfoAccess (SIA) field of this EE certificate contains the
access method OID of id-ad-signedObject.
The CA MAY choose to sign only one manifest with each generated
private key, and generate a new key pair for each new version of the
manifest. This form of use of the associated EE certificate is
termed a "one-time-use" EE certificate.
Alternatively, the CA MAY elect to use the same private key to sign a
sequence of manifests. Because only a single manifest (issued under
a single CA instance) is current at any point in time, the associated
EE certificate is used to verify only a single object at a time. As
long as the sequence of objects verified by this EE certificate are
published using the same file name, then this sequential, multiple
use of the EE certificate is also valid. This form of use of an EE
certificate is termed a "sequential-use" EE certificate.
Austein, et al. Standards Track PAGE 4
RFC 6486 RPKI Manifests February 2012
4. Manifest Definition
A manifest is an RPKI signed object, as specified in [RFC 6488]. The
RPKI signed object template requires specification of the following
data elements in the context of the manifest structure.
4.1. eContentType
The eContentType for a manifest is defined as id-ct-rpkiManifest and
has the numerical value of 1.2.840.113549.1.9.16.1.26.
id-smime OBJECT IDENTIFIER ::= { iso(1) member-body(2) us(840)
rsadsi(113549) pkcs(1) pkcs9(9) 16 }
id-ct OBJECT IDENTIFIER ::= { id-smime 1 }
id-ct-rpkiManifest OBJECT IDENTIFIER ::= { id-ct 26 }
4.2. eContent
The content of a manifest is ASN.1 encoded using the Distinguished
Encoding Rules (DER) [X.690]. The content of a manifest is defined
as follows:
Manifest ::= SEQUENCE {
version [0] INTEGER DEFAULT 0,
manifestNumber INTEGER (0..MAX),
thisUpdate GeneralizedTime,
nextUpdate GeneralizedTime,
fileHashAlg OBJECT IDENTIFIER,
fileList SEQUENCE SIZE (0..MAX) OF FileAndHash
}
FileAndHash ::= SEQUENCE {
file IA5String,
hash BIT STRING
}
4.2.1. Manifest
The manifestNumber, thisUpdate, and nextUpdate fields are modeled
after the corresponding fields in X.509 CRLs (see [RFC 5280]).
Analogous to CRLs, a manifest is nominally current until the time
specified in nextUpdate or until a manifest is issued with a greater
manifest number, whichever comes first.
If a "one-time-use" EE certificate is employed to verify a manifest,
the EE certificate MUST have a validity period that coincides with
Austein, et al. Standards Track PAGE 5
RFC 6486 RPKI Manifests February 2012
the interval from thisUpdate to nextUpdate, to prevent needless
growth of the CA's CRL.
If a "sequential-use" EE certificate is employed to verify a
manifest, the EE certificate's validity period needs to be no shorter
than the nextUpdate time of the current manifest. The extended
validity time raises the possibility of a substitution attack using a
stale manifest, as described in Section 6.4.
The data elements of the manifest structure are defined as follows:
version:
The version number of this version of the manifest specification
MUST be 0.
manifestNumber:
This field is an integer that is incremented each time a new
manifest is issued for a given publication point. This field
allows an RP to detect gaps in a sequence of published manifests.
As the manifest is modeled on the CRL specification, the
ManifestNumber is analogous to the CRLNumber, and the guidance in
[RFC 5280] for CRLNumber values is appropriate as to the range of
number values that can be used for the manifestNumber. Manifest
numbers can be expected to contain long integers. Manifest
verifiers MUST be able to handle number values up to 20 octets.
Conforming manifest issuers MUST NOT use number values longer than
20 octets.
thisUpdate:
This field contains the time when the manifest was created. This
field has the same format constraints as specified in [RFC 5280]
for the CRL field of the same name.
nextUpdate:
This field contains the time at which the next scheduled manifest
will be issued. The value of nextUpdate MUST be later than the
value of thisUpdate. The specification of the GeneralizedTime
value is the same as required for the thisUpdate field.
If the authority alters any of the items that it has published in
the repository publication point, then the authority MUST issue a
new manifest before the nextUpdate time. If a manifest
encompasses a CRL, the nextUpdate field of the manifest MUST match
that of the CRL's nextUpdate field, as the manifest will be
re-issued when a new CRL is published. If a "one-time-use" EE
certificate is used to verify the manifest, then when a new
manifest is issued before the time specified in nextUpdate of the
Austein, et al. Standards Track PAGE 6
RFC 6486 RPKI Manifests February 2012
current manifest, the CA MUST also issue a new CRL that includes
the EE certificate corresponding to the old manifest.
fileHashAlg:
This field contains the OID of the hash algorithm used to hash the
files that the authority has placed into the repository. The hash
algorithm used MUST conform to the RPKI Algorithms and Key Size
Profile specification [RFC 6485].
fileList:
This field is a sequence of FileAndHash objects. There is one
FileAndHash entry for each currently valid signed object that has
been published by the authority (at this publication point). Each
FileAndHash is an ordered pair consisting of the name of the file
in the repository publication point (directory) that contains the
object in question and a hash of the file's contents.
4.3. Content-Type Attribute
The mandatory content-type attribute MUST have its attrValues field
set to the same OID as eContentType. This OID is id-ct-rpkiManifest
and has the numerical value of 1.2.840.113549.1.9.16.1.26.
4.4. Manifest Validation
To determine whether a manifest is valid, the RP MUST perform the
following checks in addition to those specified in [RFC 6488]:
1. The eContentType in the EncapsulatedContentInfo is
id-ad-rpkiManifest (OID 1.2.840.113549.1.9.16.1.26).
2. The version of the rpkiManifest is 0.
3. In the rpkiManifest, thisUpdate precedes nextUpdate.
If the above procedure indicates that the manifest is invalid, then
the manifest MUST be discarded and treated as though no manifest were
present.
5. Manifest Generation
5.1. Manifest Generation Procedure
For a CA publication point in the RPKI repository system, a CA MUST
perform the following steps to generate a manifest:
1. If no key pair exists, or if using a "one-time-use" EE certificate
with a new key pair, generate a key pair.
Austein, et al. Standards Track PAGE 7
RFC 6486 RPKI Manifests February 2012
2. If using a "one-time-use" EE certificate, or if a key pair was
generated in step 1, or if using a "sequential-use" EE certificate
that will expire before the intended nextUpdate time of this
manifest, issue an EE certificate for this key pair.
This EE certificate MUST have an SIA extension access
description field with an accessMethod OID value of
id-ad-signedobject, where the associated accessLocation
references the publication point of the manifest as an object
URL.
This EE certificate MUST describe its Internet Number Resources
(INRs) using the "inherit" attribute, rather than explicit
description of a resource set (see [RFC 3779]).
In the case of a "one-time-use" EE certificate, the validity
times of the EE certificate MUST exactly match the thisUpdate
and nextUpdate times of the manifest.
In the case of a "sequential-use" EE certificate, the validity
times of the EE certificate MUST encompass the time interval
from thisUpdate to nextUpdate.
3. The EE certificate MUST NOT be published in the authority's
repository publication point.
4. Construct the manifest content.
The manifest content is described in Section 4.2.1. The
manifest's fileList includes the file name and hash pair for each
object issued by this CA that has been published at this
repository publication point (directory). The collection of
objects to be included in the manifest includes all certificates
issued by this CA that are published at the CA's repository
publication point, the most recent CRL issued by the CA, and all
objects verified by EE certificates that were issued by this CA
that are published at this repository publication point.
Note that the manifest does not include a self reference (i.e.,
its own file name and hash), since it would be impossible to
compute the hash of the manifest itself prior to it being signed.
5. Encapsulate the manifest content using the CMS SignedData content
type (as specified Section 4), sign the manifest using the private
key corresponding to the subject key contained in the EE
certificate, and publish the manifest in the repository system
publication point that is described by the manifest.
Austein, et al. Standards Track PAGE 8
RFC 6486 RPKI Manifests February 2012
6. In the case of a key pair that is to be used only once, in
conjunction with a "one-time-use" EE certificate, the private key
associated with this key pair MUST now be destroyed.
5.2. Considerations for Manifest Generation
A new manifest MUST be issued and published on or before the
nextUpdate time.
An authority MUST issue a new manifest in conjunction with the
finalization of changes made to objects in the publication point. An
authority MAY perform a number of object operations on a publication
repository within the scope of a repository change before issuing a
single manifest that covers all the operations within the scope of
this change. Repository operators SHOULD implement some form of
repository update procedure that mitigates, to the extent possible,
the risk that RPs that are performing retrieval operations on the
repository are exposed to inconsistent, transient, intermediate
states during updates to the repository publication point (directory)
and the associated manifest.
Since the manifest object URL is included in the SIA of issued
certificates, a new manifest MUST NOT invalidate the manifest object
URL of previously issued certificates. This implies that the
manifest's publication name in the repository, in the form of an
object URL, is unchanged across manifest generation cycles.
When a CA entity is performing a key rollover, the entity MAY choose
to have two CA instances simultaneously publishing into the same
repository publication point. In this case, there will be one
manifest associated with each active CA instance that is publishing
into the common repository publication point (directory).
6. Relying Party Use of Manifests
The goal of an RP is to determine which signed objects to use for
validating assertions about INRs and their use (e.g., which ROAs to
use in the construction of route filters). Ultimately, this
selection is a matter of local policy. However, in the following
sections, we describe a sequence of tests that the RP SHOULD perform
to determine the manifest state of the given publication point. We
then discuss the risks associated with using signed objects in the
publication point, given the manifest state; we also provide suitable
warning text that SHOULD be placed in a user-accessible log file. It
is the responsibility of the RP to weigh these risks against the risk
of routing failure that could occur if valid data is rejected, and to
implement a suitable local policy. Note that if a certificate is
deemed unfit for use due to local policy, then any signed object that
Austein, et al. Standards Track PAGE 9
RFC 6486 RPKI Manifests February 2012
is validated using this certificate also SHOULD be deemed unfit for
use (regardless of the status of the manifest at its own publication
point).
6.1. Tests for Determining Manifest State
For a given publication point, the RP SHOULD perform the following
tests to determine the manifest state of the publication point:
1. For each CA using this publication point, select the CA's current
manifest (the "current" manifest is the manifest issued by this CA
having the highest manifestNumber among all valid manifests, and
where manifest validity is defined in Section 4.4).
If the publication point does not contain a valid manifest, see
Section 6.2. Lacking a valid manifest, the following tests cannot
be performed.
2. To verify completeness, an RP MAY check that every file at each
publication point appears in one and only one current manifest,
and that every file listed in a current manifest is published at
the same publication point as the manifest.
If there exist files at the publication point that do not appear
on any manifest, or files listed in a manifest that do not appear
at the publication point, then see Section 6.5, but still continue
with the following test.
3. Check that the current time (translated to UTC) is between
thisUpdate and nextUpdate.
If the current time does not lie within this interval, then see
Section 6.4, but still continue with the following tests.
4. Verify that the listed hash value of every file listed in each
manifest matches the value obtained by hashing the file at the
publication point.
If the computed hash value of a file listed on the manifest does
not match the hash value contained in the manifest, then see
Section 6.6.
5. An RP MAY check that the contents of each current manifest
conforms to the manifest's scope constraints, as specified in
Section 2.
6. If a current manifest contains entries for objects that are not
within the scope of the manifest, then the out-of-scope entries
Austein, et al. Standards Track PAGE 10
RFC 6486 RPKI Manifests February 2012
SHOULD be disregarded in the context of this manifest. If there
is no other current manifest that describes these objects within
that other manifest's scope, then see Section 6.2.
For each signed object, if all of the following conditions hold:
* the manifest for its publication and the associated publication
point pass all of the above checks;
* the signed object is valid; and
* the manifests for every certificate on the certification path
used to validate the signed object and the associated
publication points pass all of the above checks;
then the RP can conclude that no attack against the repository system
has compromised the given signed object, and the signed object MUST
be treated as valid (relative to manifest checking).
6.2. Missing Manifests
The absence of a current manifest at a publication point could occur
due to an error by the publisher or due to (malicious or accidental)
deletion or corruption of all valid manifests.
When no valid manifest is available, there is no protection against
attacks that delete signed objects or replay old versions of signed
objects. All signed objects at the publication point, and all
descendant objects that are validated using a certificate at this
publication point, SHOULD be viewed as suspect, but MAY be used by
the RP, as per local policy.
The primary risk in using signed objects at this publication point is
that a superseded (but not stale) CRL would cause an RP to improperly
accept a revoked certificate as valid (and thus rely upon signed
objects that are validated using that certificate). This risk is
somewhat mitigated if the CRL for this publication point has a short
time between thisUpdate and nextUpdate (and the current time is
within this interval). The risk in discarding signed objects at this
publication point is that an RP may incorrectly discard a large
number of valid objects. This gives significant power to an
adversary that is able to delete a manifest at the publication point.
Regardless of whether signed objects from this publication are deemed
fit for use by an RP, this situation SHOULD result in a warning to
the effect that: "No manifest is available for <pub point name>, and
thus there may have been undetected deletions or replay substitutions
from the publication point."
Austein, et al. Standards Track PAGE 11
RFC 6486 RPKI Manifests February 2012
In the case where an RP has access to a local cache of previously
issued manifests that are valid, the RP MAY use the most recently
previously issued valid manifests for this RPKI repository
publication collection for each entity that publishes at this
publication point.
6.3. Invalid Manifests
The presence of an invalid manifest at a publication point could
occur due to an error by the publisher or due to (malicious or
accidental) corruption of a valid manifest. An invalid manifest MUST
never be used, even if the manifestNumber of the invalid manifest is
greater than that of other (valid) manifests.
There are no risks associated with using signed objects at a
publication point containing an invalid manifest, provided that valid
manifests that collectively cover all the signed objects are also
present.
If an invalid manifest is present at a publication point that also
contains one or more valid manifests, this situation SHOULD result in
a warning to the effect that: "An invalid manifest was found at <pub
point name>, this indicates an attack against the publication point
or an error by the publisher. Processing for this publication point
will continue using the most recent valid manifest(s)."
In the case where the RP has access to a local cache of previously
issued (valid) manifests, an RP MAY make use of that locally cached
data. Specifically, the RP MAY use the locally cached, most recent,
previously issued, valid manifest issued by the entity that (appears
to have) issued the invalid manifest.
6.4. Stale Manifests
A manifest is considered stale if the current time is after the
nextUpdate time for the manifest. This could be due to publisher
failure to promptly publish a new manifest, or due to (malicious or
accidental) corruption or suppression of a more recent manifest.
All signed objects at the publication point issued by the entity that
has published the stale manifest, and all descendant signed objects
that are validated using a certificate issued by the entity that has
published the stale manifest at this publication point, SHOULD be
viewed as somewhat suspect, but MAY be used by the RP as per local
policy.
The primary risk in using such signed objects is that a newer
manifest exists that, if present, would indicate that certain objects
Austein, et al. Standards Track PAGE 12
RFC 6486 RPKI Manifests February 2012
have been removed or replaced. (For example, the new manifest might
show the existence of a newer CRL and the removal of one or more
revoked certificates). Thus, the use of objects from a stale
manifest may cause an RP to incorrectly treat invalid objects as
valid. The risk is that the CRL covered by the stale manifest has
been superseded, and thus an RP will improperly treat a revoked
certificate as valid. This risk is somewhat mitigated if the time
between the nextUpdate field of the manifest and the current time is
short. The risk in discarding signed objects at this publication
point is that the RP may incorrectly discard a large number of valid
objects. This gives significant power to an adversary that is able
to prevent the publication of a new manifest at a given publication
point.
Regardless of whether signed objects from this publication are deemed
fit for use by an RP, this situation SHOULD result in a warning to
the effect that: "A manifest found at <pub point name> is no longer
current. It is possible that undetected deletions have occurred at
this publication point."
Note that there is also the potential for the current time to be
before the thisUpdate time for the manifest. This case could be due
to publisher error or a local clock error; in such a case, this
situation SHOULD result in a warning to the effect that: "A manifest
found at <pub point name> has an incorrect thisUpdate field. This
could be due to publisher error, or a local clock error, and
processing for this publication point will continue using this
otherwise valid manifest."
6.5. Mismatch between Manifest and Publication Point
If there exist valid signed objects that do not appear in any
manifest, then, provided the manifest is not stale (see Section 6.4),
it is likely that their omission is an error by the publisher. It is
also possible that this state could be the result of a (malicious or
accidental) replacement of a current manifest with an older, but
still valid, manifest. However, regarding the appropriate
interpretation of such objects, it remains the case that if the
objects were intended to be invalid, then they should have been
revoked using whatever revocation mechanism is appropriate for the
signed object in question. Therefore, there is little risk in using
such signed objects. If the publication point contains a stale
manifest, then there is a greater risk that the objects in question
were revoked, along with a missing Certificate Revocation List (CRL),
the absence of which is undetectable since the manifest is stale. In
any case, the use of signed objects not present on a manifest, or
descendant objects that are validated using such signed objects, is a
matter of local policy.
Austein, et al. Standards Track PAGE 13
RFC 6486 RPKI Manifests February 2012
Regardless of whether objects not appearing on a manifest are deemed
fit for use by the RP, this situation SHOULD result in a warning to
the effect that: "The following files are present in the repository
at <pub point name>, but are not listed on any manifest <file list>
for <pub point name>."
If there exists files listed on the manifest that do not appear in
the repository, then these objects are likely to have been improperly
(via malice or accident) deleted from the repository. A primary
purpose of manifests is to detect such deletions. Therefore, in such
a case, this situation SHOULD result in a warning to the effect that:
"The following files that should have been present in the repository
at <pub point name> are missing <file list>. This indicates an
attack against this publication point, or the repository, or an error
by the publisher."
6.6. Hash Values Not Matching Manifests
A file appearing on a manifest with an incorrect hash value could
occur because of publisher error, but it also may indicate that an
attack has occurred.
If an object appeared on a previous valid manifest with a correct
hash value, and it now appears with an invalid hash value, then it is
likely that the object has been superseded by a new (unavailable)
version of the object. If the object is used, there is a risk that
the RP will be treating a stale object as valid. This risk is more
significant if the object in question is a CRL. If the object can be
validated using the RPKI, the use of these objects is a matter of
local policy.
If an object appears on a manifest with an invalid hash and has never
previously appeared on a manifest, then it is unclear whether the
available version of the object is more or less recent than the
version indicated by the manifest. If the manifest is stale (see
Section 6.4), then it becomes more likely that the available version
is more recent than the version indicated on the manifest, but this
is never certain. Whether to use such objects is a matter of local
policy. However, in general, it is better to use a possibly outdated
version of the object than to discard the object completely.
While it is a matter of local policy, in the case of CRLs, an RP
SHOULD endeavor to use the most recently issued valid CRL, even where
the hash value in the manifest matches an older CRL or does not match
any available CRL for a CA instance. The thisUpdate field of the CRL
can be used to establish the most recent CRL in the case where an RP
has more than one valid CRL for a CA instance.
Austein, et al. Standards Track PAGE 14
RFC 6486 RPKI Manifests February 2012
Regardless of whether objects with incorrect hashes are deemed fit
for use by the RP, this situation SHOULD result in a warning to the
effect that: "The following files at the repository <pub point name>
appear on a manifest with incorrect hash values <file list>. It is
possible that these objects have been superseded by a more recent
version. It is very likely that this problem is due to an attack on
the publication point, although it also could be due to a publisher
error."
7. Publication Repositories
The RPKI publication system model requires that every publication
point be associated with one or more CAs, and be non-empty. Upon
creation of the publication point associated with a CA, the CA MUST
create and publish a manifest as well as a CRL. A CA's manifest will
always contain at least one entry, namely, the CRL issued by the CA
upon repository creation [RFC 6481].
Every published signed object in the RPKI [RFC 6488] is published in
the repository publication point of the CA that issued the EE
certificate, and is listed in the manifest associated with that CA
certificate.
8. Security Considerations
Manifests provide an additional level of protection for RPKI RPs.
Manifests can assist an RP to determine if a repository object has
been deleted, occluded, or otherwise removed from view, or if a
publication of a newer version of an object has been suppressed (and
an older version of the object has been substituted).
Manifests cannot repair the effects of such forms of corruption of
repository retrieval operations. However, a manifest enables an RP
to determine if a locally maintained copy of a repository is a
complete and up-to-date copy, even when the repository retrieval
operation is conducted over an insecure channel. In cases where the
manifest and the retrieved repository contents differ, the manifest
can assist in determining which repository objects form the
difference set in terms of missing, extraneous, or superseded
objects.
The signing structure of a manifest and the use of the nextUpdate
value allows an RP to determine if the manifest itself is the subject
of attempted alteration. The requirement for every repository
publication point to contain at least one manifest allows an RP to
determine if the manifest itself has been occluded from view. Such
attacks against the manifest are detectable within the time frame of
the regular schedule of manifest updates. Forms of replay attack
Austein, et al. Standards Track PAGE 15
RFC 6486 RPKI Manifests February 2012
within finer-grained time frames are not necessarily detectable by
the manifest structure.
9. IANA Considerations
This document registers the following in the "RPKI Signed Object"
registry created by [RFC 6488]:
Name: Manifest
OID: 1.2.840.113549.1.9.16.1.26
Reference: [RFC 6486] (this document)
This document registers the following three-letter filename extension
for "RPKI Repository Name Schemes" registry created by [RFC 6481]:
Filename extension: mft
RPKI Object: Manifest
Reference: [RFC 6481]
10. Acknowledgements
The authors would like to acknowledge the contributions from George
Michelson and Randy Bush in the preparation of the manifest
specification. Additionally, the authors would like to thank Mark
Reynolds and Christopher Small for assistance in clarifying manifest
validation and RP behavior. The authors also wish to thank Sean
Turner for his helpful review of this document.
11. References
11.1. Normative References
[RFC 2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC 5280] Cooper, D., Santesson, S., Farrell, S., Boeyen, S.,
Housley, R., and W. Polk, "Internet X.509 Public Key
Infrastructure Certificate and Certificate Revocation List
(CRL) Profile", RFC 5280, May 2008.
[RFC 6481] Huston, G., Loomans, R., and G. Michaelson, "A Profile for
Resource Certificate Repository Structure", RFC 6481,
February 2012.
[RFC 6485] Huston, G., "A Profile for Algorithms and Key Sizes for Use
in the Resource Public Key Infrastructure (RPKI)", RFC
6485, February 2012.
Austein, et al. Standards Track PAGE 16
RFC 6486 RPKI Manifests February 2012
[RFC 6487] Huston, G., Michaelson, G., and R. Loomans, "A Profile for
X.509 PKIX Resource Certificates", RFC 6487, February 2012.
[RFC 6488] Lepinski, M., Chi, A., and S. Kent, "Signed Object Template
for the Resource Public Key Infrastructure (RPKI)", RFC
6488, February 2012.
[X.690] ITU-T Recommendation X.690 (2002) | ISO/IEC 8825-1:2002,
Information technology - ASN.1 encoding rules:
Specification of Basic Encoding Rules (BER), Canonical
Encoding Rules (CER) and Distinguished Encoding Rules
(DER).
11.2. Informative References
[RFC 3370] Housley, R., "Cryptographic Message Syntax (CMS)
Algorithms", RFC 3370, August 2002.
[RFC 3779] Lynn, C., Kent, S., and K. Seo, "X.509 Extensions for IP
Addresses and AS Identifiers", RFC 3779, June 2004.
[RFC 6480] Lepinski, M. and S. Kent, "An Infrastructure to Support
Secure Internet Routing", RFC 6480, February 2012.
[RFC 6489] Huston, G., Michaelson, G., and S. Kent, "Certification
Authority (CA) Key Rollover in the Resource Public Key
Infrastructure (RPKI)", BCP 174, RFC 6489, February 2012.
Austein, et al. Standards Track PAGE 17
RFC 6486 RPKI Manifests February 2012
Appendix A. ASN.1 Module
RPKIManifest { iso(1) member-body(2) us(840) rsadsi(113549)
pkcs(1) pkcs9(9) smime(16) mod(0) 60 }
DEFINITIONS EXPLICIT TAGS ::=
BEGIN
-- EXPORTS ALL --
-- IMPORTS NOTHING --
-- Manifest Content Type: OID
id-smime OBJECT IDENTIFIER ::= { iso(1) member-body(2)
us(840) rsadsi(113549) pkcs(1) pkcs9(9) 16 }
id-ct OBJECT IDENTIFIER ::= { id-smime 1 }
id-ct-rpkiManifest OBJECT IDENTIFIER ::= { id-ct 26 }
-- Manifest Content Type: eContent
Manifest ::= SEQUENCE {
version [0] INTEGER DEFAULT 0,
manifestNumber INTEGER (0..MAX),
thisUpdate GeneralizedTime,
nextUpdate GeneralizedTime,
fileHashAlg OBJECT IDENTIFIER,
fileList SEQUENCE SIZE (0..MAX) OF FileAndHash
}
FileAndHash ::= SEQUENCE {
file IA5String,
hash BIT STRING
}
END
Austein, et al. Standards Track PAGE 18
RFC 6486 RPKI Manifests February 2012
Authors' Addresses
Rob Austein
Internet Systems Consortium
EMail: sra@hactrn.net
Geoff Huston
APNIC
6 Cordelia St
South Brisbane, QLD 4101
Australia
EMail: gih@apnic.net
URI: http://www.apnic.net
Stephen Kent
BBN Technologies
10 Moulton St.
Cambridge, MA 02138
USA
EMail: kent@bbn.com
Matt Lepinski
BBN Technologies
10 Moulton St.
Cambridge, MA 02138
USA
EMail: mlepinski@bbn.com
Austein, et al. Standards Track PAGE 19
RFC TOTAL SIZE: 42913 bytes
PUBLICATION DATE: Saturday, February 4th, 2012
LEGAL RIGHTS: The IETF Trust (see BCP 78)
|