Hi,
Reviewer: Daniel Migault
Review result: Has Issues
I have reviewed this document as part of the security directorate's ongoing
effort to review all IETF documents being processed by the IESG. These
comments were written primarily for the benefit of the security area directors.
Document editors and WG chairs should treat these comments just like any
other last call comments.
The summary of the review is Has (small) Issues.
I am not an expert in CoAP. The document is well written, and I believe securing objects is important. I had comments regarding the description of security contexts. I hesitated between Nits and Issues. I do not believe these are major design issues, and some clarifications may be sufficient. Other comments are mostly editorial nits. Please find above my comments. I am happy to follow up the updates.
Object Security for Constrained RESTful Environments (OSCORE)
draft-ietf-core-object-security-14
1. Introduction
The Constrained Application Protocol (CoAP) [RFC7252] is a web
transfer protocol, designed for constrained nodes and networks
[RFC7228], and may be mapped from HTTP [RFC8075]. CoAP specifies the
use of proxies for scalability and efficiency and references DTLS
[RFC6347] for security. CoAP-to-CoAP, HTTP-to-CoAP, and CoAP-to-HTTP
proxies require DTLS or TLS [RFC5246] to be terminated at the proxy.
The proxy therefore not only has access to the data required for
performing the intended proxy functionality, but is also able to
eavesdrop on, or manipulate any part of, the message payload and
metadata in transit between the endpoints. The proxy can also
inject, delete, or reorder packets since they are no longer protected
by (D)TLS.
The proxy can almost do whatever it wants as mentioned in the second sentence. Accessing the data enables it to passively monitor the communication. I would thus propose some text around these lines:
OLD:
The proxy therefore not only has access to the data required for
performing the intended proxy functionality, but is also able to
eavesdrop on, or manipulate any part of, the message payload and
metadata in transit between the endpoints. The proxy can also
inject, delete, or reorder packets since they are no longer protected
by (D)TLS.
NEW:
The proxy therefore has access to the data required for
performing the intended proxy functionality, and so can passively monitor the communications. In addition, the proxy can also
inject, delete, or reorder packets since they are no longer protected
by (D)TLS.
This document defines the Object Security for Constrained RESTful
Environments (OSCORE) security protocol, protecting CoAP and CoAP-
mappable HTTP requests and responses end-to-end across intermediary
nodes such as CoAP forward proxies and cross-protocol translators
including HTTP-to-CoAP proxies [RFC8075]. In addition to the core
CoAP features defined in [RFC7252], OSCORE supports Observe
[RFC7641], Block-wise [RFC7959], No-Response [RFC7967], and PATCH and
FETCH [RFC8132].
Maybe too many "and".
An analysis of end-to-end security for CoAP
messages through some types of intermediary nodes is performed in
[I-D.hartke-core-e2e-security-reqs]. OSCORE essentially protects the
RESTful interactions; the request method, the requested resource, the
message payload, etc. (see Section 4). OSCORE protects neither the
CoAP Messaging Layer nor the CoAP Token which may change between the
endpoints, and those are therefore processed as defined in [RFC7252].
Additionally, since the message formats for CoAP over unreliable
transport [RFC7252] and for CoAP over reliable transport [RFC8323]
differ only in terms of CoAP Messaging Layer, OSCORE can be applied
to both unreliable and reliable transports (see Figure 1).
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+-----------------------------------+
| Application |
+-----------------------------------+
+-----------------------------------+ \
| Requests / Responses / Signaling | |
|-----------------------------------| |
| OSCORE | | CoAP
|-----------------------------------| |
| Messaging Layer / Message Framing | |
+-----------------------------------+ /
+-----------------------------------+
| UDP / TCP / ... |
+-----------------------------------+
Figure 1: Abstract Layering of CoAP with OSCORE
OSCORE works in very constrained nodes and networks, thanks to its
small message size and the restricted code and memory requirements in
addition to what is required by CoAP. Examples of the use of OSCORE
are given in Appendix A. OSCORE does not depend on underlying
layers, and can be used with non-IP transports (e.g.,
[I-D.bormann-6lo-coap-802-15-ie]). OSCORE may also be used in
different ways with HTTP. OSCORE messages may be transported in
HTTP, and OSCORE may also be used to protect CoAP-mappable HTTP
messages, as described below.
I believe that "underlying layers" should be specified. My understanding is that OSCORE requires CoAP or HTTP. If that is correct, I believe that should be clarified in the paragraph above.
OSCORE is designed to protect as much information as possible while
still allowing CoAP proxy operations (Section 10). It works with
existing CoAP-to-CoAP forward proxies [RFC7252], but an OSCORE-aware
proxy will be more efficient. HTTP-to-CoAP proxies [RFC8075] and
CoAP-to-HTTP proxies can also be used with OSCORE, as specified in
Section 11. OSCORE may be used together with TLS or DTLS over one or
more hops in the end-to-end path, e.g. transported with HTTPS in one
hop and with plain CoAP in another hop. The use of OSCORE does not
affect the URI scheme and OSCORE can therefore be used with any URI
scheme defined for CoAP or HTTP. The application decides the
conditions for which OSCORE is required.
OSCORE uses pre-shared keys which may have been established out-of-
band or with a key establishment protocol (see Section 3.2). The
technical solution builds on CBOR Object Signing and Encryption
(COSE) [RFC8152], providing end-to-end encryption, integrity, replay
protection, and binding of response to request. A compressed version
of COSE is used, as specified in Section 6. The use of OSCORE is
signaled in CoAP with a new option (Section 2), and in HTTP with a
new header field (Section 11.1) and content type (Section 13.5). The
solution transforms a CoAP/HTTP message into an "OSCORE message"
before sending, and vice versa after receiving. The OSCORE message
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is a CoAP/HTTP message related to the original message in the
following way: the original CoAP/HTTP message is translated to CoAP
(if not already in CoAP) and protected in a COSE object. The
encrypted message fields of this COSE object are transported in the
CoAP payload/HTTP body of the OSCORE message, and the OSCORE option/
header field is included in the message. A sketch of an exchange of
OSCORE messages, in the case of the original message being CoAP, is
provided in Figure 2.
Client Server
| OSCORE request - POST example.com: |
| Header, Token, |
| Options: {OSCORE, ...}, |
| Payload: COSE ciphertext |
+--------------------------------------------->|
| |
|<---------------------------------------------+
| OSCORE response - 2.04 (Changed): |
| Header, Token, |
| Options: {OSCORE, ...}, |
| Payload: COSE ciphertext |
| |
Figure 2: Sketch of CoAP with OSCORE
Options are mentioned in {}. How these "{}" should be interpreted may be specified in the figure.
The paragraph above mentions that OSCORE can be used both with CoAP or HTTP. It might be helpful to split Figure 2 in to two sub figures Figure 2a) that illustrates the use of OCSORE with CoAP and figure 2b) that illustrates the use of OSCORE with HTTP.
My understanding is that CoAP and HTTP can easily be translated. As such it might also be able to consider OSCORE only with CoAP and having a specific section that deals with HTTP. Such split may avoid to deal in parallel with HTTP and CoAP.
An implementation supporting this specification MAY implement only
the client part, MAY implement only the server part, or MAY implement
only one of the proxy parts.
1.1. Terminology
2. The OSCORE Option
The OSCORE option (see Figure 3, which extends Table 4 of [RFC7252])
indicates that the CoAP message is an OSCORE message and that it
contains a compressed COSE object (see Sections 5 and 6). The OSCORE
option is critical, safe to forward, part of the cache key, and not
repeatable.
I believe it would be clearer to specify that this section defines the OSCORE option which is a new CoAP option. Similarly Table 4 may also be designated by CoAP Options or something similar.
+------+---+---+---+---+----------------+--------+--------+---------+
| No. | C | U | N | R | Name | Format | Length | Default |
+------+---+---+---+---+----------------+--------+--------+---------+
| TBD1 | x | | | | OSCORE | (*) | 0-255 | (none) |
+------+---+---+---+---+----------------+--------+--------+---------+
C = Critical, U = Unsafe, N = NoCacheKey, R = Repeatable
(*) See below.
Figure 3: The OSCORE Option
The OSCORE option includes the OSCORE flag bits (Section 6), the
Sender Sequence Number, the Sender ID, and the ID Context when these
fields are present (Section 3). The detailed format and length is
specified in Section 6. If the OSCORE flag bits are all zero (0x00)
the Option value SHALL be empty (Option Length = 0). An endpoint
receiving a CoAP message without payload, that also contains an
OSCORE option SHALL treat it as malformed and reject it.
I believe the logic for the OSCORE option is the other way around, that is: an CoAP message with an OSCORE option with an empty CoAP payload MUST be rejected as malformed and reject it.
A successful response to a request with the OSCORE option SHALL
contain the OSCORE option. Whether error responses contain the
OSCORE option depends on the error type (see Section 8).
For CoAP proxy operations, see Section 10.
3. The Security Context
OSCORE requires that client and server establish a shared security
context used to process the COSE objects. OSCORE uses COSE with an
Authenticated Encryption with Additional Data (AEAD, [RFC5116])
algorithm for protecting message data between a client and a server.
In this section, we define the security context and how it is derived
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in client and server based on a shared secret and a key derivation
function (KDF).
3.1. Security Context Definition
The security context is the set of information elements necessary to
carry out the cryptographic operations in OSCORE. For each endpoint,
the security context is composed of a "Common Context", a "Sender
Context", and a "Recipient Context".
The endpoints protect messages to send using the Sender Context and
verify messages received using the Recipient Context, both contexts
being derived from the Common Context and other data. Clients and
servers need to be able to retrieve the correct security context to
use.
I believe it might be clarifying to specify that CoAP endpoints have always bidirectional communications. If that is correct, then for each communication each end point is both a "Sender" and a "Recipient" for its respective outbound and inbound traffic. The 4 context are derived from a Common Context.
As security context are established to secure unidirectional communications, maybe that would be easier to base the description on the unidirectional communications rather than the end points.
An endpoint uses its Sender ID (SID) to derive its Sender Context,
and the other endpoint uses the same ID, now called Recipient ID
(RID), to derive its Recipient Context. In communication between two
endpoints, the Sender Context of one endpoint matches the Recipient
Context of the other endpoint, and vice versa. Thus, the two
security contexts identified by the same IDs in the two endpoints are
not the same, but they are partly mirrored. Retrieval and use of the
security context are shown in Figure 4.
"An endpoint uses its Sender ID (SID) to derive its Sender Context,"
I see the ID as mostly useful to the recipient in order to retrieve the appropriated security context and decrypt the message. In other words, the sender should know who it sends the message to and does not really need the SID to match the security context.
I believe this should be clarified as the current text prevents Sender ID collision, while collision should only be avoided on the receiver's side.
.-------------. .-------------.
| Common, | | Common, |
| Sender, | | Recipient, |
| Recipient | | Sender |
'-------------' '-------------'
Client Server
| |
Retrieve context for | OSCORE request: |
target resource | Token = Token1, |
Protect request with | kid = SID, ... |
Sender Context +---------------------->| Retrieve context with
| | RID = kid
| | Verify request with
| | Recipient Context
| OSCORE response: | Protect response with
| Token = Token1, ... | Sender Context
Retrieve context with |<----------------------+
Token = Token1 | |
Verify request with | |
Recipient Context | |
Figure 4: Retrieval and Use of the Security Context
I might be helpful to clarify that Sender Context on both sides are not the same context.
Security Context seems to be missing in the box.
It would also help to have in the figure, the relation between the Common Security Context, the Sender Context and Recipient Context on both sides.
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The Common Context contains the following parameters:
o AEAD Algorithm. The COSE AEAD algorithm to use for encryption.
o Key Derivation Function. The HMAC based HKDF [RFC5869] used to
derive Sender Key, Recipient Key, and Common IV.
This is confusing to have a generic term such as KDF defined by a sup set of it (HKDF). I believe that either the KDF is defined generic enough and later the default value is set to HKDF with a specific hash function. Another alternative could be to limited the scope of this parameter to HKDF Hash Function.
o Master Secret. Variable length, random byte string (see
Section 12.3) used to derive traffic keys and IVs.
I believe that IVs is the Common IV.
o Master Salt. Optional variable length byte string containing the
salt used to derive traffic keys and IVs.
I believe that IVs is the Common IV.
o ID Context. Optional variable length byte string providing
additional information to identify the Common Context and to
derive traffic keys and IVs.
o Common IV. Byte string derived from Master Secret, Master Salt,
and ID Context. Length is determined by the AEAD Algorithm.
RFC8152 uses context IV. It is not clear to me how these two differ. I believe some text should be added to explain how Common IV differs from the context IV.
It is unclear to me whether the Common Context is used for the two bidirectional communications. If that is the case, I am reading that Common IV and Sequence Number in the two directions will end up in IV collision. So Keys needs to be unidirectional and different.
The Sender Context contains the following parameters:
o Sender ID. Byte string used to identify the Sender Context, to
derive traffic keys and IVs, and to assure unique nonces. Maximum
length is determined by the AEAD Algorithm.
o Sender Key. Byte string containing the symmetric key to protect
messages to send. Derived from Common Context and Sender ID.
Length is determined by the AEAD Algorithm.
o Sender Sequence Number. Non-negative integer used by the sender
to protect requests and certain responses, e.g. Observe
notifications. Used as 'Partial IV' [RFC8152] to generate unique
nonces for the AEAD. Maximum value is determined by the AEAD
Algorithm.
The Recipient Context contains the following parameters:
o Recipient ID. Byte string used to identify the Recipient Context,
to derive traffic keys and IVs, and to assure unique nonces.
Maximum length is determined by the AEAD Algorithm.
o Recipient Key. Byte string containing the symmetric key to verify
messages received. Derived from Common Context and Recipient ID.
Length is determined by the AEAD Algorithm.
o Replay Window (Server only). The replay window to verify requests
received.
Looking at the different contexts, maybe some text should be added to specify that Sender ID and Recipient ID are equal for a given unidirectional communication. The same occurs for Sender Key and Recipient Key.
I believe that Sender Sequence Number also needs to be present in the Recipient Context in order to implement anti replay mechanism.
Sequence Number May be interpreted differently. I believe that interpretation should also be part of the Common Security Context.
As mentioned above the contexts may probably be refactored with one Context per unidirectional communication.
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All parameters except Sender Sequence Number and Replay Window are
immutable once the security context is established. An endpoint may
free up memory by not storing the Common IV, Sender Key, and
Recipient Key, deriving them when needed. Alternatively, an endpoint
may free up memory by not storing the Master Secret and Master Salt
after the other parameters have been derived.
Endpoints MAY operate as both client and server and use the same
security context for those roles. Independent of being client or
server, the endpoint protects messages to send using its Sender
Context, and verifies messages received using its Recipient Context.
The endpoints MUST NOT change the Sender/Recipient ID when changing
roles. In other words, changing the roles does not change the set of
keys to be used.
3.2. Establishment of Security Context Parameters
The parameters in the security context are derived from a small set
of input parameters. The following input parameters SHALL be pre-
established:
o Master Secret
o Sender ID
o Recipient ID
I believe that Sender ID and Recipient ID could be the same value for a given unidirectional communication. I believe that what is required her is the two IDs used by the sessions.
The following input parameters MAY be pre-established. In case any
of these parameters is not pre-established, the default value
indicated below is used:
o AEAD Algorithm
* Default is AES-CCM-16-64-128 (COSE algorithm encoding: 10)
o Master Salt
* Default is the empty byte string
I believe explicitly providing the string could help. There is always the confusion with "\0" versus "".
o Key Derivation Function (KDF)
* Default is HKDF SHA-256
o Replay Window Type and Size
* Default is DTLS-type replay protection with a window size of 32
[RFC6347]
This section specifies Type and windows for the anti replay mechanism. This was described as Replay Windows in the context description.
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All input parameters need to be known to and agreed on by both
endpoints, but the replay window may be different in the two
endpoints. The way the input parameters are pre-established, is
application specific. Considerations of security context
establishment are given in Section 12.2 and examples of deploying
OSCORE in Appendix B.
3.2.1. Derivation of Sender Key, Recipient Key, and Common IV
The KDF MUST be one of the HMAC based HKDF [RFC5869] algorithms
defined for COSE [RFC8152].
It might be better to consider HKDF instead of KDF and then just specify the Hash function
HKDF SHA-256 is mandatory to implement.
The security context parameters Sender Key, Recipient Key, and Common
IV SHALL be derived from the input parameters using the HKDF, which
consists of the composition of the HKDF-Extract and HKDF-Expand steps
[RFC5869]:
output parameter = HKDF(salt, IKM, info, L)
where:
o salt is the Master Salt as defined above
o IKM is the Master Secret as defined above
o info is the serialization of a CBOR array consisting of:
info = [
id : bstr,
id_context : bstr / nil,
alg_aead : int / tstr,
type : tstr,
L : uint
]
bstr, nil, tstr are used for the first time here. Maybe a reference to 8152 may be clarifying.
where:
o id is the Sender ID or Recipient ID when deriving keys and the
empty byte string when deriving the Common IV. The encoding is
described in Section 5.
o id_context is the ID Context, or nil if ID Context is not
provided.
o alg_aead is the AEAD Algorithm, encoded as defined in [RFC8152].
o type is "Key" or "IV". The label is an ASCII string, and does not
include a trailing NUL byte.
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o L is the size of the key/IV for the AEAD algorithm used, in bytes.
For example, if the algorithm AES-CCM-16-64-128 (see Section 10.2 in
[RFC8152]) is used, the integer value for alg_aead is 10, the value
for L is 16 for keys and 13 for the Common IV.
Note that [RFC5869] specifies that if the salt is not provided, it is
set to a string of zeros. For implementation purposes, not providing
the salt is the same as setting the salt to the empty byte string.
OSCORE sets the salt default value to empty byte string, which in
[RFC5869] is converted to a string of zeroes (see Section 2.2 of
[RFC5869]).
I believe that how Sender Key, Recipient Key, and Common IV are derived from the output_parameters should be described as well.
Note that in this case I believe that Sender Key and Recipient Key are used for the two unidirectional communications. In other words, the same key should be used by the sender and the recipient of the same communication. The same Common IV is used in both communications.
3.2.2. Initial Sequence Numbers and Replay Window
The Sender Sequence Number is initialized to 0. The supported types
of replay protection and replay window length is application specific
and depends on how OSCORE is transported, see Section 7.4. The
default is DTLS-type replay protection with a window size of 32
initiated as described in Section 4.1.2.6 of [RFC6347].
This should be specified the same in the Context.
3.3. Requirements on the Security Context Parameters
To ensure unique Sender Keys, the quartet (Master Secret, Master
Salt, ID Context, Sender ID) MUST be unique, i.e. the pair (ID
Context, Sender ID) SHALL be unique in the set of all security
contexts using the same Master Secret and Master Salt. This means
that Sender ID SHALL be unique in the set of all security contexts
using the same Master Secret, Master Salt, and ID Context; such a
requirement guarantees unique (key, nonce) pairs, which avoids nonce
reuse.
I understand the use of SHALL and MUST as similar. If that is correct, It may be better to use the same term throughout the document.
I believe that we would like to avoid that the same IV is being reused with the same key. Any change in the inputs of the HMAC based KDF will result in a different output. As such any change in the output will result in that property. I suspect we would like to some parameters to remain wit the same value, while some could be changed, and for that reason, we chose the Sender ID. I believe the text could be clarified either on the reasoning behind or how this should be operated.
Different methods can be used to assign Sender IDs: a protocol that
allows the parties to negotiate locally unique identifiers, a trusted
third party (e.g., [I-D.ietf-ace-oauth-authz]), or the identifiers
can be assigned out-of-band. The Sender IDs can be very short (note
that the empty string is a legitimate value). The maximum length of
Sender ID in bytes equals the length of AEAD nonce minus 6. For AES-
CCM-16-64-128 the maximum length of Sender ID is 7 bytes.
I suspect those restriction coming from the COSE specification. If that is correct, I believe it would be helpful to have a reference to that document.
To simplify retrieval of the right Recipient Context, the Recipient
ID SHOULD be unique in the sets of all Recipient Contexts used by an
endpoint. If an endpoint has the same Recipient ID with different
Recipient Contexts, i.e. the Recipient Contexts are derived from
different Common Contexts, then the endpoint may need to try multiple
times before verifying the right security context associated to the
Recipient ID.
Such collision could represent an attack where the attacker could in case a collision is observed craft a packet that costs two time more computation than a regular packet.
I might be wrong, but it seems that the ID is more important for the recipient. Typically the sender can easily address Sender ID collision. On the other hand the cryptographic properties are based on the uniqueness of the Sender ID. Maybe these could be considered with the Recipient ID in mind.
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The ID Context is used to distinguish between security contexts. The
methods used for assigning Sender ID can also be used for assigning
the ID Context. Additionally, the ID Context can be generated by the
client (see Appendix B.2). ID Context can be arbitrarily long.
4. Protected Message Fields
4.1. CoAP Options
4.1.1. Inner Options
4.1.2. Outer Options
4.1.3. Special Options
4.1.3.1. Max-Age
4.1.3.2. Uri-Host and Uri-Port
4.1.3.3. Proxy-Uri
4.1.3.4. The Block Options
4.1.3.4.1. Inner Block Options
4.1.3.4.2. Outer Block Options
4.1.3.5. Observe
4.1.3.5.1. Registrations and Cancellations
4.1.3.5.2. Notifications
If the server accepts an Observe registration, a Partial IV MUST be
included in all notifications (both successful and error), except for
the first one where Partial IV MAY be omitted. To protect against
replay, the client SHALL maintain a Notification Number for each
Observation it registers. The Notification Number is a non-negative
integer containing the largest Partial IV of the received
notifications for the associated Observe registration. Further
details of replay protection of notifications are specified in
Section 7.4.1.
For notifications, the Inner Observe value MUST be empty (see
Section 3.2 of [RFC7252]). The Outer Observe in a notification is
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needed for intermediary nodes to allow multiple responses to one
request, and may be set to the value of Observe in the original CoAP
message. The client performs ordering of notifications and replay
protection by comparing their Partial IVs and SHALL ignore the outer
Observe value.
If the client receives a response to an Observe request without an
Inner Observe option, then it verifies the response as a non-Observe
response, as specified in Section 8.4. If the client receives a
response to a non-Observe request with an Inner Observe option, then
it stops processing the message, as specified in Section 8.4.
A client MUST consider the notification with the highest Partial IV
as the freshest, regardless of the order of arrival. In order to
support existing Observe implementations the OSCORE client
implementation MAY set the Observe value to the three least
significant bytes of the Partial IV; such an implementation needs to
make sure that the Observe value for an observe notification without
Partial IV is smaller than a notification with Partial IV.
This section discuss the behavior regarding the sequence number. While the sequence number and the partial IV have the same value, I am wondering if it would not be more appropriated to mention the sequence number value is provided by the partial IV, and then use the sequence number variable to describe anti replay.
4.1.3.6. No-Response
4.1.3.7. OSCORE
4.2. CoAP Header Fields and Payload
4.3. Signaling Messages
5. The COSE Object
5.1. Kid Context
5.2. Nonce
5.3. Plaintext
5.4. Additional Authenticated Data
6. OSCORE Header Compression
6.1. Encoding of the OSCORE Option Value
6.2. Encoding of the OSCORE Payload
6.3. Examples of Compressed COSE Objects
7.2. Sequence Numbers
7.2.1. Maximum Sequence Number
7.3. Freshness
7.4. Replay Protection
In order to protect from replay of requests, the server's Recipient
Context includes a Replay Window. A server SHALL verify that a
Partial IV received in the COSE object has not been received before.
If this verification fails the server SHALL stop processing the
message, and MAY optionally respond with a 4.01 Unauthorized error
message. Also, the server MAY set an Outer Max-Age option with value
zero, to inform any intermediary that the response is not to be
cached. The diagnostic payload MAY contain the "Replay detected"
string. The size and type of the Replay Window depends on the use
case and the protocol with which the OSCORE message is transported.
In case of reliable and ordered transport from endpoint to endpoint,
e.g. TCP, the server MAY just store the last received Partial IV and
require that newly received Partial IVs equals the last received
Partial IV + 1. However, in case of mixed reliable and unreliable
transports and where messages may be lost, such a replay mechanism
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may be too restrictive and the default replay window be more suitable
(see Section 3.2.2).
I am reading the anti replay mechanism used as very specific. Incrementing Partial IV is one way to perform anti-replay protection. It could be the way OSCORE performs anti replay protection but this is not the only way to do. In addition, incrementing the Partial IV result in the IV being predictible. This condition may not be sufficient as some algorithm may require the IV being unpredictable. I believe Anti-Replay Type shoudl be configurable, and some note shoudl be added to comply with the encryption being used.
Responses (with or without Partial IV) are protected against replay
as they are bound to the request and the fact that only a single
response is accepted. Note that the Partial IV is not used for
replay protection in this case.
The operation of validating the Partial IV and updating the replay
protection MUST be atomic.
7.4.1. Replay Protection of Notifications
7.5. Losing Part of the Context State
To prevent reuse of an AEAD nonce with the same key, or from
accepting replayed messages, an endpoint needs to handle the
situation of losing rapidly changing parts of the context, such as
the request Token, Sender Sequence Number, Replay Window, and
Notification Numbers. These are typically stored in RAM and
therefore lost in the case of an unplanned reboot.
After boot, an endpoint can either use a persistently stored complete
or partial security context, or establish a new security context with
each endpoint it communicates with. However, establishing a fresh
security context may have a non-negligible cost in terms of, e.g.,
power consumption.
If the endpoint uses a persistently stored partial security context,
it MUST NOT reuse a previous Sender Sequence Number and MUST NOT
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accept previously received messages. Some ways to achieve this are
described in the following sections.
7.5.1. Sequence Number
To prevent reuse of Sender Sequence Numbers, an endpoint may perform
the following procedure during normal operations:
o Before using a Sender Sequence Number that is evenly divisible by
K, where K is a positive integer, store the Sender Sequence Number
in persistent memory. After boot, the endpoint initiates the
Sender Sequence Number to the value stored in persistent memory +
K. Storing to persistent memory can be costly. The value K gives
a trade-off between the number of storage operations and efficient
use of Sender Sequence Numbers.
I have hard time reading the section above. I guess K is a parameter known by OSCORE. My understanding is that SSN=0 ... K-1 are stored in persistent memory. After boot SSN = SSN + K.
I might be wrong but as storage in persistent memory is costly. Given K a parameter defined by the implementation. I would rather store F = floor(SSN / K ). SSN = F.K + ssn with ssn = 0... K-1, so a storage operation happens every K. In case of reboot, SSN = (F + 1).K + ssn.
This ends in a jump of maximum K and anti replay must be able to handle this.
7.5.2. Replay Window
7.5.3. Replay of Notifications
8. Processing
This section describes the OSCORE message processing. Additional
processing for Observe or Block-wise are described in subsections.
Note that, analogously to [RFC7252] where the Token and source/
destination pair are used to match a response with a request, both
endpoints MUST keep the association (Token, {Security Context,
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Partial IV of the request}), in order to be able to find the Security
Context and compute the AAD to protect or verify the response. The
association MAY be forgotten after it has been used to successfully
protect or verify the response, with the exception of Observe
processing, where the association MUST be kept as long as the
Observation is active.
8.1. Protecting the Request
Given a CoAP request, the client SHALL perform the following steps to
create an OSCORE request:
1. Retrieve the Sender Context associated with the target resource.
2. Compose the Additional Authenticated Data and the plaintext, as
described in Sections 5.3 and 5.4.
3. Encode the Partial IV (Sender Sequence Number in network byte
order) and increment the Sender Sequence Number by one.
I believe this depends on the Anti-replay type.
Compute
the AEAD nonce from the Sender ID, Common IV, and Partial IV as
described in Section 5.2.
4. Encrypt the COSE object using the Sender Key. Compress the COSE
Object as specified in Section 6.
5. Format the OSCORE message according to Section 4. The OSCORE
option is added (see Section 4.1.2).
8.2. Verifying the Request
A server receiving a request containing the OSCORE option SHALL
perform the following steps:
1. Discard Code and all class E options (marked in Figure 5 with 'x'
in column E) present in the received message. For example, an
If-Match Outer option is discarded, but an Uri-Host Outer option
is not discarded.
2. Decompress the COSE Object (Section 6) and retrieve the Recipient
Context associated with the Recipient ID in the 'kid' parameter,
additionally using the 'kid context', if present. If either the
decompression or the COSE message fails to decode, or the server
fails to retrieve a Recipient Context with Recipient ID
corresponding to the 'kid' parameter received, then the server
SHALL stop processing the request.
* If either the decompression or the COSE message fails to
decode, the server MAY respond with a 4.02 Bad Option error
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message. The server MAY set an Outer Max-Age option with
value zero. The diagnostic payload SHOULD contain the string
"Failed to decode COSE".
* If the server fails to retrieve a Recipient Context with
Recipient ID corresponding to the 'kid' parameter received,
the server MAY respond with a 4.01 Unauthorized error message.
The server MAY set an Outer Max-Age option with value zero.
The diagnostic payload SHOULD contain the string "Security
context not found".
3. Verify the 'Partial IV' parameter using the Replay Window, as
described in Section 7.4.
My understanding is that the Partial IV value has not been authenticated. Thus I believe this step mostly consists in discarding packets with irrelevant Partial IV values. Here irrelevant are limited to repeated sequence numbers that is too say known replayed packets.
4. Compose the Additional Authenticated Data, as described in
Section 5.4.
5. Compute the AEAD nonce from the Recipient ID, Common IV, and the
'Partial IV' parameter, received in the COSE Object.
6. Decrypt the COSE object using the Recipient Key, as per [RFC8152]
Section 5.3. (The decrypt operation includes the verification of
the integrity.)
* If decryption fails, the server MUST stop processing the
request and MAY respond with a 4.00 Bad Request error message.
The server MAY set an Outer Max-Age option with value zero.
The diagnostic payload MAY contain the "Decryption failed"
string.
* If decryption succeeds, update the Replay Window, as described
in Section 7.
7. Add decrypted Code, options, and payload to the decrypted
request. The OSCORE option is removed.
8. The decrypted CoAP request is processed according to [RFC7252].
8.2.1. Supporting Block-wise
8.3. Protecting the Response
If a CoAP response is generated in response to an OSCORE request, the
server SHALL perform the following steps to create an OSCORE
response. Note that CoAP error responses derived from CoAP
processing (step 8 in Section 8.2) are protected, as well as
successful CoAP responses, while the OSCORE errors (steps 2, 3, and 6
in Section 8.2) do not follow the processing below, but are sent as
simple CoAP responses, without OSCORE processing.
1. Retrieve the Sender Context in the Security Context associated
with the Token.
2. Compose the Additional Authenticated Data and the plaintext, as
described in Sections 5.3 and 5.4.
3. Compute the AEAD nonce as described in Section 5.2:
* Either use the nonce from the request, or
* Encode the Partial IV (Sender Sequence Number in network byte
order) and increment the Sender Sequence Number by one.
Again this is very specific.
I am reading that SSN is incremented after the Partial IV is generated. It seems to me that the Partial IV should reflect the SSN, and as such being encoded after the incrementation of the SSN.
Compute the AEAD nonce from the Sender ID, Common IV, and
Partial IV.
4. Encrypt the COSE object using the Sender Key. Compress the COSE
Object as specified in Section 6. If the AEAD nonce was
constructed from a new Partial IV, this Partial IV MUST be
included in the message. If the AEAD nonce from the request was
used, the Partial IV MUST NOT be included in the message.
5. Format the OSCORE message according to Section 4. The OSCORE
option is added (see Section 4.1.2).
8.3.1. Supporting Observe
8.4. Verifying the Response
9. Web Linking
10. CoAP-to-CoAP Forwarding Proxy
11. HTTP Operations
11.2. CoAP-to-HTTP Mapping
11.3. HTTP-to-CoAP Mapping
11.4. HTTP Endpoints
11.5. Example: HTTP Client and CoAP Server
11.6. Example: CoAP Client and HTTP Server
12. Security Considerations
An overview of the security properties is given in Appendix D.
12.1. End-to-end Protection
In scenarios with intermediary nodes such as proxies or gateways,
transport layer security such as (D)TLS only protects data hop-by-
hop. As a consequence, the intermediary nodes can read and modify
any information. The trust model where all intermediary nodes are
considered trustworthy is problematic, not only from a privacy
perspective, but also from a security perspective, as the
intermediaries are free to delete resources on sensors and falsify
commands to actuators (such as "unlock door", "start fire alarm",
"raise bridge"). Even in the rare cases where all the owners of the
intermediary nodes are fully trusted, attacks and data breaches make
such an architecture brittle.
(D)TLS protects hop-by-hop the entire message. OSCORE protects end-
to-end all information that is not required for proxy operations (see
Section 4). (D)TLS and OSCORE can be combined, thereby enabling end-
to-end security of the message payload, in combination with hop-by-
hop protection of the entire message, during transport between end-
point and intermediary node. In particular when OSCORE is used with
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HTTP, the additional TLS protection of HTTP hops is recommended, e.g.
between an HTTP endpoint and a proxy translating between HTTP and
CoAP.
I see that (D)TLS provides privacy to OSCORE communication, while OSCORE protects the data.
Applications need to consider that certain message fields and
messages types are not protected end-to-end and may be spoofed or
manipulated. The consequences of unprotected message fields are
analyzed in Appendix D.4.
12.2. Security Context Establishment
Wouldn't agreement preferred to established ?
The use of COSE_Encrypt0 and AEAD to protect messages as specified in
this document requires an established security context. The method
to establish the security context described in Section 3.2 is based
on a common Master Secret and unique Sender IDs. The necessary input
parameters may be pre-established or obtained using a key
establishment protocol augmented with establishment of Sender/
Recipient ID such as the OSCORE profile of the ACE framework
[I-D.ietf-ace-oscore-profile]. Such a procedure must ensure that the
requirements of the security context parameters for the intended use
are complied with (see Section 3.3) and also in error situations. It
is recommended to use a key establishment protocol which provides
forward secrecy whenever possible. Considerations for deploying
OSCORE with a fixed Master Secret are given in Appendix B.
12.3. Master Secret
OSCORE uses HKDF [RFC5869] and the established input parameters to
derive the security context. The required properties of the security
context parameters are discussed in Section 3.3, in this section we
focus on the Master Secret. HKDF denotes in this specification the
composition of the expand and extract functions as defined in
[RFC5869] and the Master Secret is used as Input Key Material (IKM).
Informally, HKDF takes as source an IKM containing some good amount
of randomness but not necessarily distributed uniformly (or for which
an attacker has some partial knowledge) and derive from it one or
more cryptographically strong secret keys [RFC5869].
rfc4086 may be a usefull reference.
Therefore, the main requirement for the OSCORE Master Secret, in
addition to being secret, is that it is has a good amount of
randomness. The selected key establishment schemes must ensure that
the necessary properties for the Master Secret are fulfilled. For
pre-shared key deployments and key transport solutions such as
[I-D.ietf-ace-oscore-profile], the Master Secret can be generated
offline using a good random number generator.
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12.4. Replay Protection
Replay attacks need to be considered in different parts of the
implementation. Most AEAD algorithms require a unique nonce for each
message, for which the sender sequence numbers in the COSE message
field 'Partial IV' is used. If the recipient accepts any sequence
number larger than the one previously received, then the problem of
sequence number synchronization is avoided.
Do we have cases where the Partial IV represents the LSB of the SSN ? If that is the case, if more then len(Partial IV) packet have been dropped. The two peers may have hard time to resynchronize their SSN. This may happen in a communication with a lot of notifications. In a query-response paradigm, the sender may have some hints when the packet has been receieved or not.
With reliable transport,
it may be defined that only messages with sequence number which are
equal to previous sequence number + 1 are accepted. An adversary may
try to induce a device reboot for the purpose of replaying a message
(see Section 7.5).
Note that sharing a security context between servers may open up for
replay attacks, for example if the replay windows are not
synchronized.
12.5. Client Aliveness
A verified OSCORE request enables the server to verify the identity
of the entity who generated the message. However, it does not verify
that the client is currently involved in the communication, since the
message may be a delayed delivery of a previously generated request
which now reaches the server. To verify the aliveness of the client
the server may use the Echo option in the response to a request from
the client (see [I-D.ietf-core-echo-request-tag]).
12.6. Cryptographic Considerations
The maximum sender sequence number is dependent on the AEAD
algorithm. The maximum sender sequence number is 2^40 - 1, or any
algorithm specific lower limit, after which a new security context
must be generated. The mechanism to build the nonce (Section 5.2)
assumes that the nonce is at least 56 bits, and the Partial IV is at
most 40 bits. The mandatory-to-implement AEAD algorithm AES-CCM-
16-64-128 is selected for compatibility with CCM*.
In order to prevent cryptanalysis when the same plaintext is
repeatedly encrypted by many different users with distinct keys, the
nonce is formed by mixing the sequence number with a secret per-
context initialization vector (Common IV) derived along with the keys
(see Section 3.1 of [RFC8152]), and by using a Master Salt in the key
derivation (see [MF00] for an overview). The Master Secret, Sender
Key, Recipient Key, and Common IV must be secret, the rest of the
parameters may be public. The Master Secret must have a good amount
of randomness (see Section 12.3).
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12.7. Message Segmentation
The Inner Block options enable the sender to split large messages
into OSCORE-protected blocks such that the receiving endpoint can
verify blocks before having received the complete message. The Outer
Block options allow for arbitrary proxy fragmentation operations that
cannot be verified by the endpoints, but can by policy be restricted
in size since the Inner Block options allow for secure fragmentation
of very large messages. A maximum message size (above which the
sending endpoint fragments the message and the receiving endpoint
discards the message, if complying to the policy) may be obtained as
part of normal resource discovery.
12.8. Privacy Considerations
Privacy threats executed through intermediary nodes are considerably
reduced by means of OSCORE. End-to-end integrity protection and
encryption of the message payload and all options that are not used
for proxy operations, provide mitigation against attacks on sensor
and actuator communication, which may have a direct impact on the
personal sphere.
The unprotected options (Figure 5) may reveal privacy sensitive
information, see Appendix D.4. CoAP headers sent in plaintext allow,
for example, matching of CON and ACK (CoAP Message Identifier),
matching of request and responses (Token) and traffic analysis.
OSCORE does not provide protection for HTTP header fields which are
not both CoAP-mappable and class E. The HTTP message fields which
are visible to on-path entity are only used for the purpose of
transporting the OSCORE message, whereas the application layer
message is encoded in CoAP and encrypted.
COSE message fields, i.e. the OSCORE option, may reveal information
about the communicating endpoints. E.g. 'kid' and 'kid context',
which are intended to help the server find the right context, may
reveal information about the client. Tracking 'kid' and 'kid
context' to one server may be used for correlating requests from one
client.
Unprotected error messages reveal information about the security
state in the communication between the endpoints. Unprotected
signaling messages reveal information about the reliable transport
used on a leg of the path. Using the mechanisms described in
Section 7.5 may reveal when a device goes through a reboot. This can
be mitigated by the device storing the precise state of sender
sequence number and replay window on a clean shutdown.
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The length of message fields can reveal information about the
message. Applications may use a padding scheme to protect against
traffic analysis.
13. IANA Considerations
14. References
Appendix A. Scenario Examples
Appendix B. Deployment Examples
B.1. Master Secret Used Once
An application may derive a security context once and use it for the
lifetime of a device. For many IoT deployments, a 128 bit uniformly
random Master Key is sufficient for encrypting all data exchanged
with the IoT device. This specification describes techniques for
persistent storage of the security context and synchronization of
sequence numbers (see Section 7.5) to ensure that security is
maintained with the existing security context.
B.2. Master Secret Used Multiple Times
Section 12.2 recommends the use of a key establishment protocol
providing forward secrecy of the Master Secret.
I believe that forward secrecy is a property associated to the kex. I am reading it as associated to the Master Secret. That said, English is not my native language.
An application which does not require forward secrecy may allow
multiple security contexts to be derived from one Master Secret. The
requirements on the security context parameters must be fulfilled
(Section 3.3) even if the client or server is rebooted,
recommissioned or in error cases.
This section gives an example of an application allowing new security
contexts to be derived from input parameters pre-established between
client and server for this purpose: in particular Master Secret,
Master Salt and Sender/Recipient ID (see Section 3.2):
o The client generates an ID Context which has previously not been
used with the pre-established input parameters and derives a new
security context. ID context may be pseudo-random and large for
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stochastic uniqueness, but care must be taken e.g. to avoid re-use
of the same seed for random number generation. Using this new
security context, the client generates an OSCORE request with (kid
context, kid) = (ID Context, Sender ID) in the OSCORE option.
o The server receiving such an OSCORE request with kid matching the
Recipient ID of pre-established input parameters, but with a new
kid context, derives the security context using ID Context = kid
context. If the message verifies then a new security context with
this ID Context is stored in the server, and used in the response.
Further requests with the same (kid context, kid) are verified
with this security context.
As an alternative procedure to reduce the subsequent overhead in
requests due to kid context, the verification of a message with a new
ID Context may trigger the server to generate a new kid to replace
the Client Sender ID in future requests. A client may e.g. indicate
support for such a procedure by requesting a special well-known URI
and receive the new kid in the response, which together with the
input parameters and the ID context is used to derive the new
security context which may be identified only by its kid. The
details are out of scope for this specification.
The procedures may be complemented with the use of the Echo option
for verifying the aliveness of the client requesting a new security
context.
Appendix C. Test Vectors
Appendix D. Overview of Security Properties
D.1. Supporting Proxy Operations
CoAP is designed to work with intermediaries reading and/or changing
CoAP message fields to perform supporting operations in constrained
environments, e.g. forwarding and cross-protocol translations.
Securing CoAP on transport layer protects the entire message between
the endpoints in which case CoAP proxy operations are not possible.
In order to enable proxy operations, security on transport layer
needs to be terminated at the proxy in which case the CoAP message in
its entirety is unprotected in the proxy.
Requirements for CoAP end-to-end security are specified in
[I-D.hartke-core-e2e-security-reqs]. The client and server are
assumed to be honest, but proxies and gateways are only trusted to
perform their intended operations.
I expected after 'but' something saying the proxies are not trusted, but t seems that everyone is honest here. maybe we should replace:
OLD
but proxies and gateways are only trusted to
perform their intended operations.
NEW:
and proxies and gateways are trusted to
perform their intended operations.
That the server is honest does not means that the node terminating the session is the server....
Forwarding is specified in
Section 2.2.1 of [I-D.hartke-core-e2e-security-reqs]. HTTP-CoAP
translation is specified in [RFC8075]. Intermediaries translating
between different transport layers are intended to perform just that.
By working at the CoAP layer, OSCORE enables different CoAP message
fields to be protected differently, which allows message fields
required for proxy operations to be available to the proxy while
message fields intended for the other endpoint remain protected. In
the remainder of this section we analyze how OSCORE protects the
protected message fields and the consequences of message fields
intended for proxy operation being unprotected.
This text seems clear to me. Maybe the last paragraph could be sufficient.
D.2. Protected Message Fields
Protected message fields are included in the Plaintext (Section 5.3)
and the Additional Authenticated Data (Section 5.4) of the
COSE_Encrypt0 object and encrypted using an AEAD algorithm.
OSCORE depends on a pre-established random Master Secret
(Section 12.3) used to derive encryption keys, and a construction for
making (key, nonce) pairs unique (Appendix D.3). Assuming this is
true, and the keys are used for no more data than indicated in
Section 7.2.1, OSCORE should provide the following guarantees:
o Confidentiality: An attacker should not be able to determine the
plaintext contents of a given OSCORE message or determine that
different plaintexts are related (Section 5.3).
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o Integrity: An attacker should not be able to craft a new OSCORE
message with protected message fields different from an existing
OSCORE message which will be accepted by the receiver.
o Request-response binding: An attacker should not be able to make a
client match a response to the wrong request.
o Non-replayability: An attacker should not be able to cause the
receiver to accept a message which it has previously received and
accepted.
In the above, the attacker is anyone except the endpoints, e.g. a
compromised intermediary. Informally, OSCORE provides these
properties by AEAD-protecting the plaintext with a strong key and
uniqueness of (key, nonce) pairs. AEAD encryption [RFC5116] provides
confidentiality and integrity for the data. Response-request binding
is provided by including the kid and Partial IV of the request in the
AAD of the response. Non-replayability of requests and notifications
is provided by using unique (key, nonce) pairs and a replay
protection mechanism (application dependent, see Section 7.4).
OSCORE is susceptible to a variety of traffic analysis attacks based
on observing the length and timing of encrypted packets. OSCORE does
not provide any specific defenses against this form of attack but the
application may use a padding mechanism to prevent an attacker from
directly determine the length of the padding. However, information
about padding may still be revealed by side-channel attacks observing
differences in timing.
D.3. Uniqueness of (key, nonce)
In this section we show that (key, nonce) pairs are unique as long as
the requirements in Sections 3.3 and 7.2.1 are followed.
Fix a Common Context (Section 3.1) and an endpoint, called the
encrypting endpoint. An endpoint may alternate between client and
server roles, but each endpoint always encrypts with the Sender Key
of its Sender Context. Sender Keys are (stochastically) unique since
they are derived with HKDF using unique Sender IDs, so messages
encrypted by different endpoints use different keys. It remains to
prove that the nonces used by the fixed endpoint are unique.
Since the Common IV is fixed, the nonces are determined by a Partial
IV (PIV) and the Sender ID of the endpoint generating that Partial IV
(ID_PIV). The nonce construction (Section 5.2) with the size of the
ID_PIV (S) creates unique nonces for different (ID_PIV, PIV) pairs.
There are two cases:
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A. For requests, and responses with Partial IV (e.g. Observe
notifications):
o ID_PIV = Sender ID of the encrypting endpoint
o PIV = current Partial IV of the encrypting endpoint
Since the encrypting endpoint steps the Partial IV for each use, the
nonces used in case A are all unique as long as the number of
encrypted messages is kept within the required range (Section 7.2.1).
B. For responses without Partial IV (e.g. single response to a
request):
o ID_PIV = Sender ID of the endpoint generating the request
o PIV = Partial IV of the request
Since the Sender IDs are unique, ID_PIV is different from the Sender
ID of the encrypting endpoint. Therefore, the nonces in case B are
different compared to nonces in case A, where the encrypting endpoint
generated the Partial IV. Since the Partial IV of the request is
verified for replay (Section 7.4) associated to this Recipient
Context, PIV is unique for this ID_PIV, which makes all nonces in
case B distinct.
D.4. Unprotected Message Fields
This section lists and discusses issues with unprotected message
fields.
D.4.1. CoAP Header Fields
o Version. The CoAP version [RFC7252] is not expected to be
sensitive to disclose. Currently there is only one CoAP version
defined. A change of this parameter is potentially a denial-of-
service attack. Future versions of CoAP need to analyze attacks
to OSCORE protected messages due to an adversary changing the CoAP
version.
o Token/Token Length. The Token field is a client-local identifier
for differentiating between concurrent requests [RFC7252]. An
eavesdropper reading the token can match requests to responses
which can be used in traffic analysis. In particular this is true
for notifications, where multiple responses are matched with one
request. CoAP proxies are allowed to change Token and Token
Length between UDP hops. However, modifications of Token and
Token Length during a UDP hop may become a denial-of-service
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attack, since it may prevent the client to identify to which
request the response belongs or to find the correct information to
verify integrity of the response.
I am reading the text as. When the attacker is on-path, a long Token does not prevents the attack based on a spoofed response. However, for an attacker that is not on path, the attacker needs to guess the Token, and this can be mitigated (partially) by increasing the Token size. Note that in the latest case, a long Token should not be seen as a replacement for cryptographic protection of the message.
o Code. The Outer CoAP Code of an OSCORE message is POST or FETCH
for requests with corresponding response codes. The use of FETCH
reveals no more than what is revealed by the Outer Observe option.
Changing the Outer Code may be a denial-of-service attack by
causing errors in the proxy processing.
o Type/Message ID. The Type/Message ID fields [RFC7252] reveal
information about the UDP transport binding, e.g. an eavesdropper
reading the Type or Message ID gain information about how UDP
messages are related to each other. CoAP proxies are allowed to
change Type and Message ID. These message fields are not present
in CoAP over TCP [RFC8323], and does not impact the request/
response message. A change of these fields in a UDP hop is a
denial-of-service attack. By sending an ACK, an attacker can make
the endpoint believe that the other endpoint received the previous
message. By sending a RST, an attacker may be able to cancel an
observation, make one endpoint believe the other endpoint is
alive, or make one endpoint endpoint believe that the other
endpoint is missing some context. By changing a NON to a CON, the
attacker can cause the receiving endpoint to respond to messages
for which no response was requested.
o Length. This field contain the length of the message [RFC8323]
which may be used for traffic analysis. These message fields are
not present in CoAP over UDP, and does not impact the request/
response message. A change of Length is a denial-of-service
attack similar to changing TCP header fields.
D.4.2. CoAP Options
o Max-Age. The Outer Max-Age is set to zero to avoid unnecessary
caching of OSCORE error responses. Changing this value thus may
cause unnecessary caching. No additional information is carried
with this option.
o Proxy-Uri/Proxy-Scheme. These options are used in forward proxy
deployments. With OSCORE, the Proxy-Uri option does not contain
the Uri-Path/Uri-Query parts of the URI. The other parts of
Proxy-Uri cannot be protected since they are allowed to be changed
by a forward proxy. The server can verify what scheme is used in
the last hop, but not what was requested by the client or what was
used in previous hops.
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o Uri-Host/Uri-Port. In forward proxy deployments, the Uri-Host/
Uri-Port may be changed by an adversary, and the application needs
to handle the consequences of that (see Section 4.1.3.2). The
Uri-Host may either be omitted, reveal information equivalent to
that of the IP address or more privacy-sensitive information,
which is discouraged.
o Observe. The Outer Observe option is intended for a proxy to
support forwarding of Observe messages, but is ignored by the
endpoints since the Inner Observe determines the processing in the
endpoints. Since the Partial IV provides absolute ordering of
notifications it is not possible for an intermediary to spoof
reordering (see Section 4.1.3.5). The absence of Partial IV,
since only allowed for the first notification, does not prevent
correct ordering of notifications. The size and distributions of
notifications over time may reveal information about the content
or nature of the notifications. Cancellations (Section 4.1.3.5.1)
are not bound to the corresponding registrations in the same way
responses are bound to requests in OSCORE (see Appendix D.2), but
that does not open up for attacks based on mismatched
cancellations, since [RFC7641] specifies that for cancellations to
be accepted, all options except for ETags MUST be the same (see
Section 3.6 of [RFC7641]). For different target resources, the
OSCORE option is different, and even if the Token is modified to
match a different observation, such a cancellation would not be
accepted.
o Block1/Block2/Size1/Size2. The Outer Block options enables
fragmentation of OSCORE messages in addition to segmentation
performed by the Inner Block options. The presence of these
options indicates a large message being sent and the message size
can be estimated and used for traffic analysis. Manipulating
these options is a potential denial-of-service attack, e.g.
injection of alleged Block fragments. The specification of a
maximum size of message, MAX_UNFRAGMENTED_SIZE
(Section 4.1.3.4.2), above which messages will be dropped, is
intended as one measure to mitigate this kind of attack.
o No-Response. The Outer No-Response option is used to support
proxy functionality, specifically to avoid error transmissions
from proxies to clients, and to avoid bandwidth reduction to
servers by proxies applying congestion control when not receiving
responses. Modifying or introducing this option is a potential
denial-of-service attack against the proxy operations, but since
the option has an Inner value its use can be securely agreed
between the endpoints. The presence of this option is not
expected to reveal any sensitive information about the message
exchange.
Selander, et al. Expires January 27, 2019 [Page 78]
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o OSCORE. The OSCORE option contains information about the
compressed COSE header. Changing this field may cause OSCORE
verification to fail.
D.4.3. Error and Signaling Messages
Error messages occurring during CoAP processing are protected end-to-
end. Error messages occurring during OSCORE processing are not
always possible to protect, e.g. if the receiving endpoint cannot
locate the right security context. For this setting, unprotected
error messages are allowed as specified to prevent extensive
retransmissions. Those error messages can be spoofed or manipulated,
which is a potential denial-of-service attack.
Signaling messages used in CoAP over TCP [RFC8323] are intended to be
hop-by-hop; spoofing signaling messages can be used as a denial-of-
service attack of a TCP connection.
D.4.4. HTTP Message Fields
In contrast to CoAP, where OSCORE does not protect header fields to
enable CoAP-CoAP proxy operations, the use of OSCORE with HTTP is
restricted to transporting a protected CoAP message over an HTTP hop.
Any unprotected HTTP message fields may reveal information about the
transport of the OSCORE message and enable various denial-of-service
attacks. It is recommended to additionally use TLS [RFC5246] for
HTTP hops, which enables encryption and integrity protection of
headers, but still leaves some information for traffic analysis.
Appendix E. CDDL Summary