Internet Engineering Task Force (IETF) M. Boucadair
Request for Comments:
9177 Orange
Category: Standards Track J. Shallow
ISSN: 2070-1721 March 2022
Constrained Application Protocol (CoAP) Block-Wise Transfer Options
Supporting Robust Transmission
Abstract
This document specifies alternative Constrained Application Protocol
(CoAP) block-wise transfer options: Q-Block1 and Q-Block2.
These options are similar to, but distinct from, the CoAP Block1 and
Block2 options defined in
RFC 7959. The Q-Block1 and Q-Block2
options are not intended to replace the Block1 and Block2 options but
rather have the goal of supporting Non-confirmable (NON) messages for
large amounts of data with fewer packet interchanges. Also, the
Q-Block1 and Q-Block2 options support faster recovery should any of
the blocks get lost in transmission.
Status of This Memo
This is an Internet Standards Track document.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Further information on
Internet Standards is available in
Section 2 of RFC 7841.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
https://www.rfc-editor.org/info/rfc9177.
Copyright Notice
Copyright (c) 2022 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(
https://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
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to this document. Code Components extracted from this document must
include Revised BSD License text as described in Section 4.e of the
Trust Legal Provisions and are provided without warranty as described
in the Revised BSD License.
Table of Contents
1. Introduction
2. Terminology
3. Alternative CoAP Block-Wise Transfer Options
3.1. CoAP Response Code (4.08) Usage
3.2. Applicability Scope
4. The Q-Block1 and Q-Block2 Options
4.1. Properties of the Q-Block1 and Q-Block2 Options
4.2. Structure of the Q-Block1 and Q-Block2 Options
4.3. Using the Q-Block1 Option
4.4. Using the Q-Block2 Option
4.5. Using the Observe Option
4.6. Using the Size1 and Size2 Options
4.7. Using the Q-Block1 and Q-Block2 Options Together
4.8. Using the Q-Block2 Option with Multicast
5. The Use of the 4.08 (Request Entity Incomplete) Response Code
6. The Use of Tokens
7. Congestion Control for Unreliable Transports
7.1. Confirmable (CON)
7.2. Non-confirmable (NON)
8. Caching Considerations
9. HTTP Mapping Considerations
10. Examples with Non-confirmable Messages
10.1. Q-Block1 Option
10.1.1. A Simple Example
10.1.2. Handling MAX_PAYLOADS Limits
10.1.3. Handling MAX_PAYLOADS with Recovery
10.1.4. Handling Recovery if Failure Occurs
10.2. Q-Block2 Option
10.2.1. A Simple Example
10.2.2. Handling MAX_PAYLOADS Limits
10.2.3. Handling MAX_PAYLOADS with Recovery
10.2.4. Handling Recovery by Setting the M Bit
10.3. Q-Block1 and Q-Block2 Options
10.3.1. A Simple Example
10.3.2. Handling MAX_PAYLOADS Limits
10.3.3. Handling Recovery
11. Security Considerations
12. IANA Considerations
12.1. CoAP Option Numbers Registry
12.2. Media Type Registration
12.3. CoAP Content-Formats Registry
13. References
13.1. Normative References
13.2. Informative References
Appendix A. Examples with Confirmable Messages
A.1. Q-Block1 Option
A.2. Q-Block2 Option
Appendix B. Examples with Reliable Transports
B.1. Q-Block1 Option
B.2. Q-Block2 Option
Acknowledgments
Authors' Addresses
1. Introduction
The Constrained Application Protocol (CoAP) [
RFC7252], although
inspired by HTTP, was designed to use UDP instead of TCP. The
message layer of CoAP over UDP includes support for reliable
delivery, simple congestion control, and flow control. CoAP supports
two message types (Section 1.2 of [
RFC7252]): Confirmable (CON) and
Non-confirmable (NON). Unlike NON messages, every CON message will
elicit an acknowledgment or a reset.
The CoAP specification recommends that a CoAP message should fit
within a single IP packet (i.e., avoid IP fragmentation). To handle
data records that cannot fit in a single IP packet, [
RFC7959]
introduced the concept of block-wise transfers and the companion CoAP
Block1 and Block2 options. However, this concept is designed to work
exclusively with Confirmable messages (
Section 1 of [
RFC7959]). Note
that the block-wise transfer was further updated by [
RFC8323] for use
over TCP, TLS, and WebSockets.
The CoAP Block1 and Block2 options work well in environments where
there are no, or minimal, packet losses. These options operate
synchronously, i.e., each individual block has to be requested. A
CoAP endpoint can only ask for (or send) the next block when the
transfer of the previous block has completed. The packet
transmission rate, and hence the block transmission rate, is
controlled by Round-Trip Times (RTTs).
There is a requirement for blocks of data larger than a single IP
datagram to be transmitted under network conditions where there may
be asymmetrical transient packet loss (e.g., acknowledgment responses
may get dropped). An example is when a network is subject to a
Distributed Denial of Service (DDoS) attack and there is a need for
DDoS mitigation agents relying upon CoAP to communicate with each
other (e.g., [
RFC9132] [DOTS-TELEMETRY]). As a reminder, [
RFC7959]
recommends the use of CON responses to handle potential packet loss.
However, such a recommendation does not work with a "flooded pipe"
DDoS situation (e.g., [
RFC9132]).
This document introduces the CoAP Q-Block1 and Q-Block2 options,
which allow block-wise transfers to work with a series of Non-
confirmable messages instead of lock-stepping using Confirmable
messages (
Section 3). In other words, this document provides a
missing piece of [
RFC7959], namely the support of block-wise
transfers using Non-confirmable messages where an entire body of data
can be transmitted without the requirement that intermediate
acknowledgments be received from the peer (but recovery is available
should it be needed).
Similar to [
RFC7959], this specification does not remove any of the
constraints posed by the base CoAP specification [
RFC7252] it is
strictly layered on top of.
2. Terminology
The key words "
MUST", "
MUST NOT", "
REQUIRED", "
SHALL", "
SHALL NOT",
"
SHOULD", "
SHOULD NOT", "
RECOMMENDED", "
NOT RECOMMENDED", "
MAY", and
"
OPTIONAL" in this document are to be interpreted as described in
BCP 14 [
RFC2119] [
RFC8174] when, and only when, they appear in all
capitals, as shown here.
Readers should be familiar with the terms and concepts defined in
[
RFC7252], [
RFC7959], and [
RFC8132]. Particularly, the document uses
the following key concepts:
Token: used to match responses to requests independently from the
underlying messages (Section 5.3.1 of [
RFC7252]).
ETag: used as a resource-local identifier for differentiating
between representations of the same resource that vary over time
(Section 5.10.6 of [
RFC7252]).
The terms "payload" and "body" are defined in [
RFC7959]. The term
"payload" is thus used for the content of a single CoAP message
(i.e., a single block being transferred), while the term "body" is
used for the entire resource representation that is being transferred
in a block-wise fashion.
Request-Tag refers to an option that allows a CoAP server to match
message fragments belonging to the same request [
RFC9175].
MAX_PAYLOADS is the maximum number of payloads that can be
transmitted at any one time.
MAX_PAYLOADS_SET is the set of blocks identified by block numbers
that, when divided by MAX_PAYLOADS, have the same numeric result.
For example, if MAX_PAYLOADS is set to 10, a MAX_PAYLOADS_SET could
be blocks #0 to #9, #10 to #19, etc. Depending on the overall data
size, there could be fewer than MAX_PAYLOADS blocks in the final
MAX_PAYLOADS_SET.
3. Alternative CoAP Block-Wise Transfer Options
This document introduces the CoAP Q-Block1 and Q-Block2 options.
These options are designed to work in particular with NON requests
and responses.
Using NON messages, faster transmissions can occur, as all the blocks
can be transmitted serially (akin to fragmented IP packets) without
having to wait for a response or next request from the remote CoAP
peer. Recovery of missing blocks is faster in that multiple missing
blocks can be requested in a single CoAP message. Even if there is
asymmetrical packet loss, a body can still be sent and received by
the peer whether the body comprises a single payload or multiple
payloads, assuming no recovery is required.
A CoAP endpoint can acknowledge all or a subset of the blocks.
Concretely, the receiving CoAP endpoint either informs the sending
CoAP endpoint of successful reception or reports on all blocks in the
body that have not yet been received. The sending CoAP endpoint will
then retransmit only the blocks that have been lost in transmission.
Note that similar transmission rate benefits can be applied to
Confirmable messages if the value of NSTART is increased from 1
(
Section 4.7 of [
RFC7252]). However, the use of Confirmable messages
will not work effectively if there is asymmetrical packet loss. Some
examples with Confirmable messages are provided in
Appendix A.
There is little, if any, benefit of using these options with CoAP
running over a reliable connection [
RFC8323]. In this case, there is
no differentiation between CON and NON, as they are not used. Some
examples using a reliable transport are provided in
Appendix B.
The Q-Block1 and Q-Block2 options are similar in operation to the
CoAP Block1 and Block2 options, respectively. They are not a
replacement for them but have the following benefits:
* They can operate in environments where packet loss is highly
asymmetrical.
* They enable faster transmissions of sets of blocks of data with
fewer packet interchanges.
* They support faster recovery should any of the blocks get lost in
transmission.
* They support sending an entire body using NON messages without
requiring that an intermediate response be received from the peer.
The disadvantages of using the CoAP Block1 and Block2 options are as
follows:
* There is a loss of lock-stepping, so payloads are not always
received in the correct order (blocks in ascending order).
* Additional congestion control measures need to be put in place for
NON messages (
Section 7.2).
* To reduce the transmission times for CON transmissions of large
bodies, NSTART needs to be increased from 1, but this affects
congestion control and incurs a requirement to retune other
parameters (
Section 4.7 of [
RFC7252]). Such tuning is out of
scope of this document.
* Mixing of NON and CON during an exchange of requests/responses
using Q-Block options is not supported.
* The Q-Block options do not support stateless operation/random
access.
* Proxying of Q-Block options is limited to caching full
representations.
* There is no multicast support.
The Q-Block1 and Q-Block2 options can be used instead of the Block1
and Block2 options when the different transmission properties are
required. If the new options are not supported by a peer, then
transmissions can fall back to using the Block1 and Block2 options
(
Section 4.1).
The deviations from the Block1 and Block2 options are specified in
Section 4. Pointers to the appropriate sections in [
RFC7959] are
provided.
The specification refers to the base CoAP methods defined in
Section 5.8 of [
RFC7252] and the new CoAP methods, FETCH, PATCH, and
iPATCH, which are introduced in [
RFC8132].
The No-Response option [
RFC7967] was considered but was abandoned, as
it does not apply to Q-Block2 responses. A unified solution is
defined in the document.
3.1. CoAP Response Code (4.08) Usage
This document adds a media type for the 4.08 (Request Entity
Incomplete) response defining an additional message format for
reporting on payloads using the Q-Block1 option that are not received
by the server.
See
Section 5 for more details.
3.2. Applicability Scope
The block-wise transfer specified in [
RFC7959] covers the general
case using Confirmable messages but falls short in situations where
packet loss is highly asymmetrical or there is no need for an
acknowledgment. In other words, there is a need for Non-confirmable
support.
The mechanism specified in this document provides roughly similar
features to the Block1/Block2 options. It provides additional
properties that are tailored towards the intended use case of Non-
confirmable transmission. Concretely, this mechanism primarily
targets applications, such as DDoS Open Threat Signaling (DOTS), that
cannot use CON requests/responses because of potential packet loss
and that support application-specific mechanisms to assess whether
the remote peer is not overloaded and thus is able to process the
messages sent by a CoAP endpoint (e.g., DOTS heartbeats in
Section 4.7 of [
RFC9132]). Other use cases are when an application
sends data but has no need for an acknowledgment of receipt and any
data transmission loss is not critical.
The mechanism includes guards to prevent a CoAP agent from
overloading the network by adopting an aggressive sending rate.
These guards
MUST be followed in addition to the existing CoAP
congestion control, as specified in
Section 4.7 of [
RFC7252]. See
Section 7 for more details.
Any usage outside the primary use case of Non-confirmable messages
with block transfers should be carefully weighed against the
potential loss of interoperability with generic CoAP applications
(see the disadvantages listed in
Section 3). It is hoped that the
experience gained with this mechanism can feed future extensions of
the block-wise mechanism that will both be generally applicable and
serve this particular use case.
It is not recommended that these options are used in the "NoSec"
security mode (
Section 9 of [
RFC7252]), as the source endpoint needs
to be trusted. Using Object Security for Constrained RESTful
Environments (OSCORE) [
RFC8613] does provide a security context and
hence a trust of the source endpoint that prepared the inner OSCORE
content. However, even with OSCORE, using the NoSec mode with these
options may still be inadequate, for reasons discussed in
Section 11.
4. The Q-Block1 and Q-Block2 Options
4.1. Properties of the Q-Block1 and Q-Block2 Options
The properties of the Q-Block1 and Q-Block2 options are shown in
Table 1. The formatting of this table follows the one used in
Table 4 of Section 5.10 of [
RFC7252]. The C, U, N, and R columns
indicate the properties Critical, UnSafe, NoCacheKey, and Repeatable,
which are defined in Section 5.4 of [
RFC7252]. Only the Critical and
UnSafe columns are marked for the Q-Block1 option. The Critical,
UnSafe, and Repeatable columns are marked for the Q-Block2 option.
As these options are UnSafe, NoCacheKey has no meaning and so is
marked with a dash.
+=====+===+===+===+===+==========+========+========+=========+
| No. | C | U | N | R | Name | Format | Length | Default |
+=====+===+===+===+===+==========+========+========+=========+
| 19 | x | x | - | | Q-Block1 | uint | 0-3 | (none) |
+-----+---+---+---+---+----------+--------+--------+---------+
| 31 | x | x | - | x | Q-Block2 | uint | 0-3 | (none) |
+-----+---+---+---+---+----------+--------+--------+---------+
Table 1: CoAP Q-Block1 and Q-Block2 Option Properties
The Q-Block1 and Q-Block2 options can be present in both the request
and response messages. The Q-Block1 option pertains to the request
payload, and the Q-Block2 option pertains to the response payload.
When the Content-Format option is present together with the Q-Block1
or Q-Block2 option, the option applies to the body, not to the
payload (i.e., it must be the same for all payloads of the same
body).
The Q-Block1 option is useful with the payload-bearing (e.g., POST,
PUT, FETCH, PATCH, and iPATCH) requests and their responses.
The Q-Block2 option is useful, for example, with GET, POST, PUT,
FETCH, PATCH, and iPATCH requests and their payload-bearing responses
(response codes 2.01, 2.02, 2.04, and 2.05) (Section 5.5 of
[
RFC7252]).
A CoAP endpoint (or proxy)
MUST support either both or neither of the
Q-Block1 and Q-Block2 options.
If the Q-Block1 option is present in a request or the Q-Block2 option
is returned in a response, this indicates a block-wise transfer and
describes how this specific block-wise payload forms part of the
entire body being transferred. If it is present in the opposite
direction, it provides additional control on how that payload will be
formed or was processed.
To indicate support for Q-Block2 responses, the CoAP client
MUST include the Q-Block2 option in a GET or similar request (e.g.,
FETCH), the Q-Block2 option in a PUT or similar request (e.g., POST),
or the Q-Block1 option in a PUT or similar request so that the server
knows that the client supports this Q-Block functionality should it
need to send back a body that spans multiple payloads. Otherwise,
the server would use the Block2 option (if supported) to send back a
message body that is too large to fit into a single IP packet
[
RFC7959].
How a client decides whether it needs to include a Q-Block1 or
Q-Block2 option can be driven by a local configuration parameter,
triggered by an application (e.g., DOTS), etc. Such considerations
are out of the scope of this document.
Implementation of the Q-Block1 and Q-Block2 options is intended to be
optional. However, when a Q-Block1 or Q-Block2 option is present in
a CoAP message, it
MUST be processed (or the message rejected).
Therefore, the Q-Block1 and Q-Block2 options are identified as
critical options.
With CoAP over UDP, the way a request message is rejected for
critical options depends on the message type. A Confirmable message
with an unrecognized critical option is rejected with a 4.02 (Bad
Option) response (Section 5.4.1 of [
RFC7252]). A Non-confirmable
message with an unrecognized critical option is either rejected with
a Reset message or just silently ignored (Sections
5.
4.1 and
4.3 of
[
RFC7252]). To reliably get a rejection message, it is therefore
REQUIRED that clients use a Confirmable message for determining
support for the Q-Block1 and Q-Block2 options. This Confirmable
message can be sent under the base CoAP congestion control setup
specified in
Section 4.7 of [
RFC7252] (that is, NSTART does not need
to be increased (
Section 7.1)).
The Q-Block1 and Q-Block2 options are unsafe to forward. That is, a
CoAP proxy that does not understand the Q-Block1 (or Q-Block2) option
must reject the request or response that uses either option (see
Section 5.7.1 of [
RFC7252]).
The Q-Block2 option is repeatable when requesting retransmission of
missing blocks but not otherwise. Except for that case, any request
carrying multiple Q-Block1 (or Q-Block2) options
MUST be handled
following the procedure specified in Section 5.4.5 of [
RFC7252].
The Q-Block1 and Q-Block2 options, like the Block1 and Block2
options, are of both class E and class U for OSCORE processing
(Table 2). The Q-Block1 (or Q-Block2) option
MAY be an Inner or
Outer option (
Section 4.1 of [
RFC8613]). The Inner and Outer values
are therefore independent of each other. The Inner option is
encrypted and integrity protected between clients and servers and
provides message body identification in case of end-to-end
fragmentation of requests. The Outer option is visible to proxies
and labels message bodies in case of hop-by-hop fragmentation of
requests.
+========+==========+===+===+
| Number | Name | E | U |
+========+==========+===+===+
| 19 | Q-Block1 | x | x |
+--------+----------+---+---+
| 31 | Q-Block2 | x | x |
+--------+----------+---+---+
Table 2: OSCORE
Protection of the
Q-Block1 and Q-Block2
Options
Note that, if the Q-Block1 or Q-Block2 options are included in a
packet as Inner options, the Block1 or Block2 options
MUST NOT be
included as Inner options. Similarly, there
MUST NOT be a mix of
Q-Block and Block options for the Outer options. Messages that do
not adhere to this behavior
MUST be rejected with a 4.02 (Bad
Option). The Q-Block and Block options can be mixed across Inner and
Outer options, as these are handled independently of each other. For
clarity, if OSCORE is not being used, there
MUST NOT be a mix of
Q-Block and Block options in the same packet.
4.2. Structure of the Q-Block1 and Q-Block2 Options
The structure of the Q-Block1 and Q-Block2 options follows the
structure defined in Section 2.2 of [
RFC7959].
There is no default value for the Q-Block1 and Q-Block2 options. The
absence of one of these options is equivalent to an option value of 0
with respect to the value of block number (NUM) and more bit (M) that
could be given in the option, i.e., it indicates that the current
block is the first and only block of the transfer (block number is
set to 0; M is unset). However, in contrast to the explicit value 0,
which would indicate a size of the block (SZX) of 0, and thus a size
value of 16 bytes, there is no specific size implied by the absence
of the option -- the size is left unspecified. (As for any uint, the
explicit value 0 is efficiently indicated by a zero-length option;
therefore, this is semantically different from the absence of the
option.)
4.3. Using the Q-Block1 Option
The Q-Block1 option is used when the client wants to send a large
amount of data to the server using the POST, PUT, FETCH, PATCH, or
iPATCH methods where the data and headers do not fit into a single
packet.
When the Q-Block1 option is used, the client
MUST include a Request-
Tag option [
RFC9175]. The Request-Tag value
MUST be the same for all
of the requests for the body of data that is being transferred. The
Request-Tag is opaque, but the client
MUST ensure that it is unique
for every different body of transmitted data.
Implementation Note: It is suggested that the client treats the
Request-Tag as an unsigned integer of 8 bytes in length. An
implementation may want to consider limiting this to 4 bytes to
reduce packet overhead size. The initial Request-Tag value should
be randomly generated and then subsequently incremented by the
client whenever a new body of data is being transmitted between
peers.
Section 4.6 discusses the use of the Size1 option.
For Confirmable transmission, the server continues to acknowledge
each packet, but a response is not required (whether separate or
piggybacked) until successful receipt of the body by the server. For
Non-confirmable transmission, no response is required until either
the successful receipt of the body by the server or a timer expires
with some of the payloads having not yet arrived. In the latter
case, a "retransmit missing payloads" response is needed. For
reliable transports (e.g., [
RFC8323]), a response is not required
until successful receipt of the body by the server.
Each individual message that carries a block of the body is treated
as a new request (
Section 6).
The client
MUST send the payloads in order of increasing block
number, starting from zero, until the body is complete (subject to
any congestion control (
Section 7)). In addition, any missing
payloads requested by the server must be separately transmitted with
increasing block numbers.
The following response codes are used:
2.01 (Created)
This response code indicates successful receipt of the entire body
and that the resource was created. The token to use
MUST be one
of the tokens that were received in a request for this block-wise
exchange. However, it is desirable to provide the one used in the
last received request, since that will aid any troubleshooting.
The client should then release all of the tokens used for this
body. Note that the last received payload might not be the one
with the highest block number.
2.02 (Deleted)
This response code indicates successful receipt of the entire body
and that the resource was deleted when using POST (Section 5.8.2
of [
RFC7252]). The token to use
MUST be one of the tokens that
were received in a request for this block-wise exchange. However,
it is desirable to provide the one used in the last received
request. The client should then release all of the tokens used
for this body.
2.04 (Changed)
This response code indicates successful receipt of the entire body
and that the resource was updated. The token to use
MUST be one
of the tokens that were received in a request for this block-wise
exchange. However, it is desirable to provide the one used in the
last received request. The client should then release all of the
tokens used for this body.
2.05 (Content)
This response code indicates successful receipt of the entire
FETCH request body (
Section 2 of [
RFC8132]) and that the
appropriate representation of the resource is being returned. The
token to use
MUST be one of the tokens that were received in a
request for this block-wise exchange. However, it is desirable to
provide the one used in the last received request.
If the FETCH request includes the Observe option, then the server
MUST use the same token as used for the 2.05 (Content) response
for returning any triggered Observe responses so that the client
can match them up.
The client should then release all of the tokens used for this
body apart from the one used for tracking an observed resource.
2.31 (Continue)
This response code can be used to indicate that all of the blocks
up to and including the Q-Block1 option block NUM (all having the
M bit set) have been successfully received. The token to use
MUST be one of the tokens that were received in a request for this
latest MAX_PAYLOADS_SET block-wise exchange. However, it is
desirable to provide the one used in the last received request.
The client should then release all of the tokens used for this
MAX_PAYLOADS_SET.
A response using this response code
MUST NOT be generated for
every received Q-Block1 option request. It
SHOULD only be
generated when all the payload requests are Non-confirmable and a
MAX_PAYLOADS_SET has been received by the server. More details
about the motivations for this optimization are discussed in
Section 7.2.
This response code
SHOULD NOT be generated for CON, as this may
cause duplicated payloads to unnecessarily be sent.
4.00 (Bad Request)
This response code
MUST be returned if the request does not
include a Request-Tag option or a Size1 option but does include a
Q-Block1 option.
4.02 (Bad Option)
This response code
MUST be returned for a Confirmable request if
the server does not support the Q-Block options. Note that a
Reset message may be sent in case of a Non-confirmable request.
4.08 (Request Entity Incomplete)
As a reminder, this response code returned without content type
"application/missing-blocks+cbor-seq" (
Section 12.3) is handled as
in Section 2.9.2 of [
RFC7959].
This response code returned with content type "application/
missing-blocks+cbor-seq" indicates that some of the payloads are
missing and need to be resent. The client then retransmits the
individual missing payloads using the same Request-Tag, Size1, and
Q-Block1 options to specify the same NUM, SZX, and M bit values as
those sent initially in the original (but not received) packets.
The Request-Tag value to use is determined by taking the token in
the 4.08 (Request Entity Incomplete) response, locating the
matching client request, and then using its Request-Tag.
The token to use in the 4.08 (Request Entity Incomplete) response
MUST be one of the tokens that were received in a request for this
block-wise body exchange. However, it is desirable to provide the
one used in the last received request. See
Section 5 for further
information.
If the server has not received all the blocks of a body, but one
or more NON payloads have been received, it
SHOULD wait for
NON_RECEIVE_TIMEOUT (
Section 7.2) before sending a 4.08 (Request
Entity Incomplete) response.
4.13 (Request Entity Too Large)
This response code can be returned under conditions similar to
those discussed in Section 2.9.3 of [RFC7959].
This response code can be returned if there is insufficient space
to create a response PDU with a block size of 16 bytes (SZX = 0)
to send back all the response options as appropriate. In this
case, the Size1 option is not included in the response.
Further considerations related to the transmission timings of the
4.08 (Request Entity Incomplete) and 2.31 (Continue) response codes
are discussed in
Section 7.2.
If a server receives payloads with different Request-Tags for the
same resource, it should continue to process all the bodies, as it
has no way of determining which is the latest version or which body,
if any, the client is terminating the transmission for.
If the client elects to stop the transmission of a complete body,
then absent any local policy, the client
MUST "forget" all tracked
tokens associated with the body's Request-Tag so that a Reset message
is generated for the invalid token in the 4.08 (Request Entity
Incomplete) response. On receipt of the Reset message, the server
SHOULD delete the partial body.
If the server receives a duplicate block with the same Request-Tag,
it
MUST ignore the payload of the packet but
MUST still respond as if
the block was received for the first time.
A server
SHOULD maintain a partial body (missing payloads) for
NON_PARTIAL_TIMEOUT (
Section 7.2).
4.4. Using the Q-Block2 Option
In a request for any block number, an unset M bit indicates the
request is just for that block. If the M bit is set, this has
different meanings based on the NUM value:
NUM is zero: This is a request for the entire body.
'NUM modulo MAX_PAYLOADS' is zero, while NUM is not zero: This is
used to confirm that the current MAX_PAYLOADS_SET (the latest
block having block number NUM-1) has been successfully received
and that, upon receipt of this request, the server can continue to
send the next MAX_PAYLOADS_SET (the first block having block
number NUM). This is the 'Continue' Q-Block-2 and conceptually
has the same usage (i.e., continue sending the next set of data)
as the use of 2.31 (Continue) for Q-Block1.
Any other value of NUM: This is a request for that block and for all
of the remaining blocks in the current MAX_PAYLOADS_SET.
If the request includes multiple Q-Block2 options and these options
overlap (e.g., combination of M being set (this and later blocks) and
unset (this individual block)), resulting in an individual block
being requested multiple times, the server
MUST only send back one
instance of that block. This behavior is meant to prevent
amplification attacks.
The payloads sent back from the server as a response
MUST all have
the same ETag (Section 5.10.6 of [
RFC7252]) for the same body. The
server
MUST NOT use the same ETag value for different representations
of a resource.
The ETag is opaque, but the server
MUST ensure that it is unique for
every different body of transmitted data.
Implementation Note: It is suggested that the server treats the
ETag as an unsigned integer of 8 bytes in length. An
implementation may want to consider limiting this to 4 bytes to
reduce packet overhead size. The initial ETag value should be
randomly generated and then subsequently incremented by the server
whenever a new body of data is being transmitted between peers.
Section 4.6 discusses the use of the Size2 option.
The client may elect to request any detected missing blocks or just
ignore the partial body. This decision is implementation specific.
For NON payloads, the client
SHOULD wait for NON_RECEIVE_TIMEOUT
(
Section 7.2) after the last received payload before requesting
retransmission of any missing blocks. Retransmission is requested by
issuing a GET, POST, PUT, FETCH, PATCH, or iPATCH request that
contains one or more Q-Block2 options that define the missing
block(s). Generally, the M bit on the Q-Block2 option(s)
SHOULD be
unset, although the M bit
MAY be set to request this and later blocks
from this MAX_PAYLOADS_SET; see
Section 10.2.4 for an example of this
in operation. Further considerations related to the transmission
timing for missing requests are discussed in
Section 7.2.
The missing block numbers requested by the client
MUST have an
increasing block number in each additional Q-Block2 option with no
duplicates. The server
SHOULD respond with a 4.00 (Bad Request) to
requests not adhering to this behavior. Note that the ordering
constraint is meant to force the client to check for duplicates and
remove them. This also helps with troubleshooting.
If the client receives a duplicate block with the same ETag, it
MUST silently ignore the payload.
A client
SHOULD maintain a partial body (missing payloads) for
NON_PARTIAL_TIMEOUT (
Section 7.2) or as defined by the Max-Age option
(or its default of 60 seconds (Section 5.6.1 of [
RFC7252])),
whichever is less. On release of the partial body, the client should
then release all of the tokens used for this body apart from the
token that is used to track a resource that is being observed.
The ETag option should not be used in the request for missing blocks,
as the server could respond with a 2.03 (Valid) response with no
payload. It can be used in the request if the client wants to check
the freshness of the locally cached body response.
The server
SHOULD maintain a cached copy of the body when using the
Q-Block2 option to facilitate retransmission of any missing payloads.
If the server detects partway through a body transfer that the
resource data has changed and the server is not maintaining a cached
copy of the old data, then the transmission is terminated. Any
subsequent missing block requests
MUST be responded to using the
latest ETag and Size2 option values with the updated data.
If the server responds during a body update with a different ETag
option value (as the resource representation has changed), then the
client should treat the partial body with the old ETag as no longer
being fresh. The client may then request all of the new data by
specifying Q-Block2 with block number '0' and the M bit set.
If the server transmits a new body of data (e.g., a triggered Observe
notification) with a new ETag to the same client as an additional
response, the client should remove any partially received body held
for a previous ETag for that resource, as it is unlikely the missing
blocks can be retrieved.
If there is insufficient space to create a response PDU with a block
size of 16 bytes (SZX = 0) to send back all the response options as
appropriate, a 4.13 (Request Entity Too Large) is returned without
the Size1 option.
For Confirmable traffic, the server typically acknowledges the
initial request using an Acknowledgment (ACK) with a piggybacked
payload and then sends the subsequent payloads of the
MAX_PAYLOADS_SET as CON responses. These CON responses are
individually ACKed by the client. The server will detect failure to
send a packet and
SHOULD terminate the body transfer, but the client
can issue, after a MAX_TRANSMIT_SPAN delay, a separate GET, POST,
PUT, FETCH, PATCH, or iPATCH for any missing blocks as needed.
4.5. Using the Observe Option
For a request that uses Q-Block1, the Observe value [
RFC7641]
MUST be
the same for all the payloads of the same body. This includes any
missing payloads that are retransmitted.
For a response that uses Q-Block2, the Observe value
MUST be the same
for all the payloads of the same body. This is different from Block2
usage where the Observe value is only present in the first block
(Section 3.4 of [
RFC7959]). This includes payloads transmitted
following receipt of the 'Continue' Q-Block2 option (
Section 4.4) by
the server. If a missing payload is requested by a client, then both
the request and response
MUST NOT include the Observe option.
4.6. Using the Size1 and Size2 Options
Section 4 of [
RFC7959] defines two CoAP options: Size1 for indicating
the size of the representation transferred in requests and Size2 for
indicating the size of the representation transferred in responses.
For the Q-Block1 and Q-Block2 options, the Size1 or Size2 option
values
MUST exactly represent the size of the data on the body so
that any missing data can easily be determined.
The Size1 option
MUST be used with the Q-Block1 option when used in a
request and
MUST be present in all payloads of the request,
preserving the same value. The Size2 option
MUST be used with the
Q-Block2 option when used in a response and
MUST be present in all
payloads of the response, preserving the same value.
4.7. Using the Q-Block1 and Q-Block2 Options Together
The behavior is similar to the one defined in Section 3.3 of
[
RFC7959] with Q-Block1 substituted for Block1 and Q-Block2
substituted for Block2.
4.8. Using the Q-Block2 Option with Multicast
Servers
MUST ignore multicast requests that contain the Q-Block2
option. As a reminder, the Block2 option can be used as stated in
Section 2.8 of [
RFC7959].
5. The Use of the 4.08 (Request Entity Incomplete) Response Code
The 4.08 (Request Entity Incomplete) response code has a new content
type "application/missing-blocks+cbor-seq" used to indicate that the
server has not received all of the blocks of the request body that it
needs to proceed. Such messages must not be treated by the client as
a fatal error.
Likely causes are the client has not sent all blocks, some blocks
were dropped during transmission, or the client sent them a long
enough time ago that the server has already discarded them.
The new data payload of the 4.08 (Request Entity Incomplete) response
with content type "application/missing-blocks+cbor-seq" is encoded as
a Concise Binary Object Representation (CBOR) Sequence [
RFC8742]. It
comprises one or more missing block numbers encoded as CBOR unsigned
integers [
RFC8949]. The missing block numbers
MUST be unique in each
4.08 (Request Entity Incomplete) response when created by the server;
the client
MUST ignore any duplicates in the same 4.08 (Request
Entity Incomplete) response.
The Content-Format option (Section 5.10.3 of [
RFC7252])
MUST be used
in the 4.08 (Request Entity Incomplete) response. It
MUST be set to
"application/missing-blocks+cbor-seq" (
Section 12.3).
The Concise Data Definition Language (CDDL) [
RFC8610] (and see
Section 4.1 of [
RFC8742]) for the data describing these missing
blocks is as follows:
; This defines an array, the elements of which are to be used
; in a CBOR Sequence:
payload = [+ missing-block-number]
; A unique block number not received:
missing-block-number = uint
Figure 1: Structure of the Missing Blocks Payload
This CDDL syntax
MUST be followed.
It is desirable that the token to use for the response is the token
that was used in the last block number received so far with the same
Request-Tag value. Note that the use of any received token with the
same Request-Tag would be acceptable, but providing the one used in
the last received payload will aid any troubleshooting. The client
will use the token to determine what was the previously sent request
to obtain the Request-Tag value that was used.
If the size of the 4.08 (Request Entity Incomplete) response packet
is larger than that defined by
Section 4.6 of [
RFC7252], then the
number of reported missing blocks
MUST be limited so that the
response can fit into a single packet. If this is the case, then the
server can send subsequent 4.08 (Request Entity Incomplete) responses
containing those additional missing blocks on receipt of a new
request providing a missing payload with the same Request-Tag.
The missing blocks
MUST be reported in ascending order without any
duplicates. The client
SHOULD silently drop 4.08 (Request Entity
Incomplete) responses not adhering to this behavior.
Implementation Note: Consider limiting the number of missing
payloads to MAX_PAYLOADS to minimize the need for congestion
control. The CBOR Sequence does not include any array wrapper.
A 4.08 (Request Entity Incomplete) response with content type
"application/missing-blocks+cbor-seq"
SHOULD NOT be used when using
Confirmable requests or a reliable connection [
RFC8323], as the
client will be able to determine that there is a transmission failure
of a particular payload and hence that the server is missing that
payload.
6. The Use of Tokens
Each new request generally uses a new Token (and sometimes must; see
Section 4 of [
RFC9175]). Additional responses to a request all use
the token of the request they respond to.
Implementation Note: By using 8-byte tokens, it is possible to
easily minimize the number of tokens that have to be tracked by
clients, by keeping the bottom 32 bits the same for the same body
and the upper 32 bits containing the current body's request number
(incrementing every request, including every retransmit). This
alleviates the client's need to keep all the per-request state,
e.g., per
Section 3 of [
RFC8974]. However, if using NoSec,
Section 5.2 of [
RFC8974] needs to be considered for security
implications.
7. Congestion Control for Unreliable Transports
The transmission of all the blocks of a single body over an
unreliable transport
MUST either all be Confirmable or all be Non-
confirmable. This is meant to simplify the congestion control
procedure.
As a reminder, there is no need for CoAP-specific congestion control
for reliable transports [
RFC8323].
7.1. Confirmable (CON)
Congestion control for CON requests and responses is specified in
Section 4.7 of [
RFC7252]. In order to benefit from faster
transmission rates, NSTART will need to be increased from 1.
However, the other CON congestion control parameters will need to be
tuned to cover this change. This tuning is not specified in this
document, given that the applicability scope of the current
specification assumes that all requests and responses using Q-Block1
and Q-Block2 will be Non-confirmable (
Section 3.2) apart from the
initial Q-Block functionality negotiation.
Following the failure to transmit a packet due to packet loss after
MAX_TRANSMIT_SPAN time (Section 4.8.2 of [
RFC7252]), it is
implementation specific as to whether there should be any further
requests for missing data.
7.2. Non-confirmable (NON)
This document introduces the new parameters MAX_PAYLOADS,
NON_TIMEOUT, NON_TIMEOUT_RANDOM, NON_RECEIVE_TIMEOUT,
NON_MAX_RETRANSMIT, NON_PROBING_WAIT, and NON_PARTIAL_TIMEOUT
primarily for use with NON (Table 3).
Note: Randomness may naturally be provided based on the traffic
profile, how PROBING_RATE is computed (as this is an average), and
when the peer responds. Randomness is explicitly added for some
of the congestion control parameters to handle situations where
everything is in sync when retrying.
MAX_PAYLOADS should be configurable with a default value of 10. Both
CoAP endpoints
MUST have the same value (otherwise, there will be
transmission delays in one direction), and the value
MAY be
negotiated between the endpoints to a common value by using a higher-
level protocol (out of scope of this document). This is the maximum
number of payloads that can be transmitted at any one time.
Note: The default value of 10 is chosen for reasons similar to
those discussed in
Section 5 of [
RFC6928], especially given the
target application discussed in
Section 3.2.
NON_TIMEOUT is used to compute the delay between sending
MAX_PAYLOADS_SET for the same body. By default, NON_TIMEOUT has the
same value as ACK_TIMEOUT (
Section 4.8 of [
RFC7252]).
NON_TIMEOUT_RANDOM is the initial actual delay between sending the
first two MAX_PAYLOADS_SETs of the same body. The same delay is then
used between the subsequent MAX_PAYLOADS_SETs. It is a random
duration (not an integral number of seconds) between NON_TIMEOUT and
(NON_TIMEOUT * ACK_RANDOM_FACTOR). ACK_RANDOM_FACTOR is set to 1.5,
as discussed in
Section 4.8 of [
RFC7252].
NON_RECEIVE_TIMEOUT is the initial time to wait for a missing payload
before requesting retransmission for the first time. Every time the
missing payload is re-requested, the Time-to-Wait value doubles. The
time to wait is calculated as:
Time-to-Wait = NON_RECEIVE_TIMEOUT * (2 ** (Re-Request-Count - 1))
NON_RECEIVE_TIMEOUT has a default value of twice NON_TIMEOUT.
NON_RECEIVE_TIMEOUT
MUST always be greater than NON_TIMEOUT_RANDOM by
at least one second so that the sender of the payloads has the
opportunity to start sending the next MAX_PAYLOADS_SET before the
receiver times out.
NON_MAX_RETRANSMIT is the maximum number of times a request for the
retransmission of missing payloads can occur without a response from
the remote peer. After this occurs, the local endpoint
SHOULD consider the body stale, remove any body, and release the tokens and
Request-Tag on the client (or the ETag on the server). By default,
NON_MAX_RETRANSMIT has the same value as MAX_RETRANSMIT (
Section 4.8 of [
RFC7252]).
NON_PROBING_WAIT is used to limit the potential wait needed when
using PROBING_RATE. By default, NON_PROBING_WAIT is computed in a
way similar to EXCHANGE_LIFETIME (Section 4.8.2 of [
RFC7252]) but
with ACK_TIMEOUT, MAX_RETRANSMIT, and PROCESSING_DELAY substituted
with NON_TIMEOUT, NON_MAX_RETRANSMIT, and NON_TIMEOUT_RANDOM,
respectively:
NON_PROBING_WAIT = NON_TIMEOUT * ((2 ** NON_MAX_RETRANSMIT) - 1) *
ACK_RANDOM_FACTOR + (2 * MAX_LATENCY) + NON_TIMEOUT_RANDOM
NON_PARTIAL_TIMEOUT is used for expiring partially received bodies.
By default, NON_PARTIAL_TIMEOUT is computed in the same way as
EXCHANGE_LIFETIME (Section 4.8.2 of [
RFC7252]) but with ACK_TIMEOUT
and MAX_RETRANSMIT substituted with NON_TIMEOUT and
NON_MAX_RETRANSMIT, respectively:
NON_PARTIAL_TIMEOUT = NON_TIMEOUT * ((2 ** NON_MAX_RETRANSMIT) -
1) * ACK_RANDOM_FACTOR + (2 * MAX_LATENCY) + NON_TIMEOUT
+=====================+===================+
| Parameter Name | Default Value |
+=====================+===================+
| MAX_PAYLOADS | 10 |
+---------------------+-------------------+
| NON_MAX_RETRANSMIT | 4 |
+---------------------+-------------------+
| NON_TIMEOUT | 2 s |
+---------------------+-------------------+
| NON_TIMEOUT_RANDOM | between 2-3 s |
+---------------------+-------------------+
| NON_RECEIVE_TIMEOUT | 4 s |
+---------------------+-------------------+
| NON_PROBING_WAIT | between 247-248 s |
+---------------------+-------------------+
| NON_PARTIAL_TIMEOUT | 247 s |
+---------------------+-------------------+
Table 3: Congestion Control Parameters
The PROBING_RATE parameter in CoAP indicates the average data rate
that must not be exceeded by a CoAP endpoint in sending to a peer
endpoint that does not respond. A single body will be subjected to
PROBING_RATE (
Section 4.7 of [
RFC7252]), not the individual packets.
If the wait time between sending bodies that are not being responded
to based on PROBING_RATE exceeds NON_PROBING_WAIT, then the wait time
is limited to NON_PROBING_WAIT.
| Note: For the particular DOTS application, PROBING_RATE and
| other transmission parameters are negotiated between peers.
| Even when not negotiated, the DOTS application uses customized
| defaults, as discussed in Section 4.5.2 of [
RFC9132]. Note
| that MAX_PAYLOADS, NON_MAX_RETRANSMIT, NON_TIMEOUT,
| NON_PROBING_WAIT, and NON_PARTIAL_TIMEOUT can be negotiated
| between DOTS peers, e.g., as per [DOTS-QUICK-BLOCKS]. When
| explicit values are configured for NON_PROBING_WAIT and
| NON_PARTIAL_TIMEOUT, these values are used without applying any
| jitter.
Each NON 4.08 (Request Entity Incomplete) response is subject to
PROBING_RATE.
Each NON GET or FETCH request using a Q-Block2 option is subject to
PROBING_RATE.
As the sending of many payloads of a single body may itself cause
congestion, after transmission of every MAX_PAYLOADS_SET of a single
body, a delay of NON_TIMEOUT_RANDOM
MUST be introduced before sending
the next MAX_PAYLOADS_SET, unless a 'Continue' is received from the
peer for the current MAX_PAYLOADS_SET, in which case the next
MAX_PAYLOADS_SET
MAY start transmission immediately.
Note: Assuming 1500-byte packets and the MAX_PAYLOADS_SET having
10 payloads, this corresponds to 1500 * 10 * 8 = 120 kbits. With
a delay of 2 seconds between MAX_PAYLOADS_SET, this indicates an
average speed requirement of 60 kbps for a single body should
there be no responses. This transmission rate is further reduced
by being subject to PROBING_RATE.
The sending of a set of missing blocks of a body is restricted to
those in a MAX_PAYLOADS_SET at a time. In other words, a
NON_TIMEOUT_RANDOM delay is still observed between each
MAX_PAYLOADS_SET.
For the Q-Block1 option, if the server responds with a 2.31
(Continue) response code for the latest payload sent, then the client
can continue to send the next MAX_PAYLOADS_SET without any further
delay. If the server responds with a 4.08 (Request Entity
Incomplete) response code, then the missing payloads
SHOULD be
retransmitted before going into another NON_TIMEOUT_RANDOM delay
prior to sending the next set of payloads.
For the server receiving NON Q-Block1 requests, it
SHOULD send back a
2.31 (Continue) response code on receipt of all of the
MAX_PAYLOADS_SET to prevent the client unnecessarily delaying the
transfer of remaining blocks. If not all of the MAX_PAYLOADS_SET
were received, the server
SHOULD delay for NON_RECEIVE_TIMEOUT
(exponentially scaled based on the repeat request count for a
payload) before sending the 4.08 (Request Entity Incomplete) response
code for the missing payload(s). If all of the MAX_PAYLOADS_SET were
received and a 2.31 (Continue) response code had been sent, but no
more payloads were received for NON_RECEIVE_TIMEOUT (exponentially
scaled), the server
SHOULD send a 4.08 (Request Entity Incomplete)
response detailing the missing payloads after the block number that
was indicated in the sent 2.31 (Continue) response code. If the
repeat response count of the 4.08 (Request Entity Incomplete) exceeds
NON_MAX_RETRANSMIT, the server
SHOULD discard the partial body and
stop requesting the missing payloads.
It is likely that the client will start transmitting the next
MAX_PAYLOADS_SET before the server times out on waiting for the last
block of the previous MAX_PAYLOADS_SET. On receipt of a payload from
the next MAX_PAYLOADS_SET, the server
SHOULD send a 4.08 (Request
Entity Incomplete) response code indicating any missing payloads from
any previous MAX_PAYLOADS_SET. Upon receipt of the 4.08 (Request
Entity Incomplete) response code, the client
SHOULD send the missing
payloads before continuing to send the remainder of the
MAX_PAYLOADS_SET and then go into another NON_TIMEOUT_RANDOM delay
prior to sending the next MAX_PAYLOADS_SET.
For the client receiving NON Q-Block2 responses, it
SHOULD send a
'Continue' Q-Block2 request (
Section 4.4) for the next
MAX_PAYLOADS_SET on receipt of all of the MAX_PAYLOADS_SET to prevent
the server unnecessarily delaying the transfer of remaining blocks.
Otherwise, the client
SHOULD delay for NON_RECEIVE_TIMEOUT
(exponentially scaled based on the repeat request count for a
payload) before sending the request for the missing payload(s). If
the repeat request count for a missing payload exceeds
NON_MAX_RETRANSMIT, the client
SHOULD discard the partial body and
stop requesting the missing payloads.
The server
SHOULD recognize the 'Continue' Q-Block2 request per the
definition in
Section 4.4 and just continue the transmission of the
body (including the Observe option, if appropriate for an unsolicited
response) rather than treat 'Continue' as a request for the remaining
missing blocks.
It is likely that the server will start transmitting the next
MAX_PAYLOADS_SET before the client times out on waiting for the last
block of the previous MAX_PAYLOADS_SET. Upon receipt of a payload
from the new MAX_PAYLOADS_SET, the client
SHOULD send a request
indicating any missing payloads from any previous MAX_PAYLOADS_SET.
Upon receipt of such a request, the server
SHOULD send the missing
payloads before continuing to send the remainder of the
MAX_PAYLOADS_SET and then go into another NON_TIMEOUT_RANDOM delay
prior to sending the next MAX_PAYLOADS_SET.
The client does not need to acknowledge the receipt of the entire
body.
Note: If there is asymmetric traffic loss causing responses to
never get received, a delay of NON_TIMEOUT_RANDOM after every
transmission of MAX_PAYLOADS_SET will be observed. The endpoint
receiving the body is still likely to receive the entire body.
8. Caching Considerations
Caching block-based information is not straightforward in a proxy.
For the Q-Block1 and Q-Block2 options, for simplicity, it is expected
that the proxy will reassemble the body (using any appropriate
recovery options for packet loss) before passing the body onward to
the appropriate CoAP endpoint. This does not preclude an
implementation doing a more complex per-payload caching, but how to
do this is out of the scope of this document. The onward
transmission of the body does not require the use of the Q-Block1 or
Q-Block2 options, as these options may not be supported in that link.
This means that the proxy must fully support the Q-Block1 and
Q-Block2 options.
How the body is cached in the CoAP client (for Q-Block1
transmissions) or the CoAP server (for Q-Block2 transmissions) is
implementation specific.
As the entire body is being cached in the proxy, the Q-Block1 and
Q-Block2 options are removed as part of the block assembly and thus
do not reach the cache.
For Q-Block2 responses, the ETag option value is associated with the
data (and transmitted onward to the CoAP client) but is not part of
the cache key.
For requests with the Q-Block1 option, the Request-Tag option is
associated with building the body from successive payloads but is not
part of the cache key. For the onward transmission of the body using
CoAP, a new Request-Tag
SHOULD be generated and used. Ideally, this
new Request-Tag should replace the Request-Tag used by the client.
It is possible that two or more CoAP clients are concurrently
updating the same resource through a common proxy to the same CoAP
server using the Q-Block1 (or Block1) option. If this is the case,
the first client to complete building the body causes that body to
start transmitting to the CoAP server with an appropriate Request-Tag
value. When the next client completes building the body, any
existing partial body transmission to the CoAP server is terminated,
and the transmission of the new body representation starts with a new
Request-Tag value. Note that it cannot be assumed that the proxy
will always receive a complete body from a client.
A proxy that supports the Q-Block2 option
MUST be prepared to receive
a GET or similar request indicating one or more missing blocks. From
its cache, the proxy will serve the missing blocks that are available
in its cache in the same way a server would send all the appropriate
Q-Block2 responses. If a body matching the cache key is not
available in the cache, the proxy
MUST request the entire body from
the CoAP server using the information in the cache key.
How long a CoAP endpoint (or proxy) keeps the body in its cache is
implementation specific (e.g., it may be based on Max-Age).
9. HTTP Mapping Considerations
As a reminder, the basic normative requirements on HTTP/CoAP mappings
are defined in
Section 10 of [
RFC7252]. The implementation
guidelines for HTTP/CoAP mappings are elaborated in [
RFC8075].
The rules defined in
Section 5 of [
RFC7959] are to be followed.
10. Examples with Non-confirmable Messages
This section provides some sample flows to illustrate the use of the
Q-Block1 and Q-Block2 options with NON. Examples with CON are
provided in
Appendix A.
The examples in the following subsections assume MAX_PAYLOADS is set
to 10 and NON_MAX_RETRANSMIT is set to 4.
The list below contains the conventions that are used in the figures
in the following subsections.
T: Token value
O: Observe option value
M: Message ID
RT: Request-Tag
ET: ETag
QB1: Q-Block1 option values NUM/More/Size
QB2: Q-Block2 option values NUM/More/Size
Size: Actual block size encoded in SZX
\: Trimming long lines
[[]]: Comments
-->X: Message loss (request)
X<--: Message loss (response)
...: Passage of time
Payload N: Corresponds to the CoAP message that conveys a block
number (N-1) of a given block-wise exchange.
10.1. Q-Block1 Option
10.1.1. A Simple Example
Figure 2 depicts an example of a NON PUT request conveying the
Q-Block1 option. All the blocks are received by the server.
CoAP CoAP
Client Server
| |
+--------->| NON PUT /path M:0x81 T:0xc0 RT=9 QB1:0/1/1024
+--------->| NON PUT /path M:0x82 T:0xc1 RT=9 QB1:1/1/1024
+--------->| NON PUT /path M:0x83 T:0xc2 RT=9 QB1:2/1/1024
+--------->| NON PUT /path M:0x84 T:0xc3 RT=9 QB1:3/0/1024
|<---------+ NON 2.04 M:0xf1 T:0xc3
| ... |
Figure 2: Example of a NON Request with the Q-Block1 option
(without Loss)
10.1.2. Handling MAX_PAYLOADS Limits
Figure 3 depicts an example of a NON PUT request conveying the
Q-Block1 option. The number of payloads exceeds MAX_PAYLOADS. All
the blocks are received by the server.
CoAP CoAP
Client Server
| |
+--------->| NON PUT /path M:0x01 T:0xf1 RT=10 QB1:0/1/1024
+--------->| NON PUT /path M:0x02 T:0xf2 RT=10 QB1:1/1/1024
+--------->| [[Payloads 3 - 9 not detailed]]
+--------->| NON PUT /path M:0x0a T:0xfa RT=10 QB1:9/1/1024
[[MAX_PAYLOADS_SET has been received]]
| [[MAX_PAYLOADS_SET receipt acknowledged by server]]
|<---------+ NON 2.31 M:0x81 T:0xfa
+--------->| NON PUT /path M:0x0b T:0xfb RT=10 QB1:10/0/1024
|<---------+ NON 2.04 M:0x82 T:0xfb
| ... |
Figure 3: Example of a MAX_PAYLOADS NON Request with the Q-Block1
Option (without Loss)
10.1.3. Handling MAX_PAYLOADS with Recovery
Consider now a scenario where a new body of data is to be sent by the
client, but some blocks are dropped in transmission, as illustrated
in Figure 4.
CoAP CoAP
Client Server
| |
+--------->| NON PUT /path M:0x11 T:0xe1 RT=11 QB1:0/1/1024
+--->X | NON PUT /path M:0x12 T:0xe2 RT=11 QB1:1/1/1024
+--------->| [[Payloads 3 - 8 not detailed]]
+--------->| NON PUT /path M:0x19 T:0xe9 RT=11 QB1:8/1/1024
+--->X | NON PUT /path M:0x1a T:0xea RT=11 QB1:9/1/1024
[[Some of the MAX_PAYLOADS_SET has been received]]
| ... |
[[NON_TIMEOUT_RANDOM (client) delay expires]]
| [[Client starts sending next MAX_PAYLOADS_SET]]
+--->X | NON PUT /path M:0x1b T:0xeb RT=11 QB1:10/1/1024
+--------->| NON PUT /path M:0x1c T:0xec RT=11 QB1:11/1/1024
| |
Figure 4: Example of a MAX_PAYLOADS NON Request with the Q-Block1
Option (with Loss)
On seeing a payload from the next MAX_PAYLOADS_SET, the server
realizes that some blocks are missing from the previous
MAX_PAYLOADS_SET and asks for the missing blocks in one go
(Figure 5). It does so by indicating which blocks from the previous
MAX_PAYLOADS_SET have not been received in the data portion of the
response (
Section 5). The token used in the response should be the
token that was used in the last received payload. The client can
then derive the Request-Tag by matching the token with the sent
request.
CoAP CoAP
Client Server
| |
|<---------+ NON 4.08 M:0x91 T:0xec [Missing 1,9]
| [[Client responds with missing payloads]]
+--------->| NON PUT /path M:0x1d T:0xed RT=11 QB1:1/1/1024
+--------->| NON PUT /path M:0x1e T:0xee RT=11 QB1:9/1/1024
| [[Client continues sending next MAX_PAYLOADS_SET]]
+--------->| NON PUT /path M:0x1f T:0xef RT=11 QB1:12/0/1024
| ... |
[[NON_RECEIVE_TIMEOUT (server) delay expires]]
| [[The server realizes a block is still missing and asks
| for the missing one]]
|<---------+ NON 4.08 M:0x92 T:0xef [Missing 10]
+--------->| NON PUT /path M:0x20 T:0xf0 RT=11 QB1:10/1/1024
|<---------+ NON 2.04 M:0x93 T:0xf0
| ... |
Figure 5: Example of a NON Request with the Q-Block1 Option
(Block Recovery)
10.1.4. Handling Recovery if Failure Occurs
Figure 6 depicts an example of a NON PUT request conveying the
Q-Block1 option where recovery takes place but eventually fails.
CoAP CoAP
Client Server
| |
+--------->| NON PUT /path M:0x91 T:0xd0 RT=12 QB1:0/1/1024
+--->X | NON PUT /path M:0x92 T:0xd1 RT=12 QB1:1/1/1024
+--------->| NON PUT /path M:0x93 T:0xd2 RT=12 QB1:2/0/1024
| ... |
[[NON_RECEIVE_TIMEOUT (server) delay expires]]
| [[The server realizes a block is missing and asks
| for the missing one. Retry #1]]
|<---------+ NON 4.08 M:0x01 T:0xd2 [Missing 1]
| ... |
[[2 * NON_RECEIVE_TIMEOUT (server) delay expires]]
| [[The server realizes a block is still missing and asks
| for the missing one. Retry #2]]
|<---------+ NON 4.08 M:0x02 T:0xd2 [Missing 1]
| ... |
[[4 * NON_RECEIVE_TIMEOUT (server) delay expires]]
| [[The server realizes a block is still missing and asks
| for the missing one. Retry #3]]
|<---------+ NON 4.08 M:0x03 T:0xd2 [Missing 1]
| ... |
[[8 * NON_RECEIVE_TIMEOUT (server) delay expires]]
| [[The server realizes a block is still missing and asks
| for the missing one. Retry #4]]
|<---------+ NON 4.08 M:0x04 T:0xd2 [Missing 1]
| ... |
[[16 * NON_RECEIVE_TIMEOUT (server) delay expires]]
| [[NON_MAX_RETRANSMIT exceeded. Server stops requesting
| the missing blocks and releases partial body]]
| ... |
Figure 6: Example of a NON Request with the Q-Block1 Option (with
Eventual Failure)
10.2. Q-Block2 Option
These examples include the Observe option to demonstrate how that
option is used. Note that the Observe option is not required for
Q-Block2.
10.2.1. A Simple Example
Figure 7 illustrates an example of the Q-Block2 option. The client
sends a NON GET carrying the Observe and Q-Block2 options. The
Q-Block2 option indicates a block size hint (1024 bytes). The server
replies to this request using four (4) blocks that are transmitted to
the client without any loss. Each of these blocks carries a Q-Block2
option. The same process is repeated when an Observe is triggered,
but no loss is experienced by any of the notification blocks.
CoAP CoAP
Client Server
| |
+--------->| NON GET /path M:0x01 T:0xc0 O:0 QB2:0/1/1024
|<---------+ NON 2.05 M:0xf1 T:0xc0 O:1220 ET=19 QB2:0/1/1024
|<---------+ NON 2.05 M:0xf2 T:0xc0 O:1220 ET=19 QB2:1/1/1024
|<---------+ NON 2.05 M:0xf3 T:0xc0 O:1220 ET=19 QB2:2/1/1024
|<---------+ NON 2.05 M:0xf4 T:0xc0 O:1220 ET=19 QB2:3/0/1024
| ... |
| [[Observe triggered]]
|<---------+ NON 2.05 M:0xf5 T:0xc0 O:1221 ET=20 QB2:0/1/1024
|<---------+ NON 2.05 M:0xf6 T:0xc0 O:1221 ET=20 QB2:1/1/1024
|<---------+ NON 2.05 M:0xf7 T:0xc0 O:1221 ET=20 QB2:2/1/1024
|<---------+ NON 2.05 M:0xf8 T:0xc0 O:1221 ET=20 QB2:3/0/1024
| ... |
Figure 7: Example of NON Notifications with the Q-Block2 Option
(without Loss)
10.2.2. Handling MAX_PAYLOADS Limits
Figure 8 illustrates the same scenario as Figure 7, but this time
with eleven (11) payloads, which exceeds MAX_PAYLOADS. There is no
loss experienced.
CoAP CoAP
Client Server
| |
+--------->| NON GET /path M:0x01 T:0xf0 O:0 QB2:0/1/1024
|<---------+ NON 2.05 M:0x81 T:0xf0 O:1234 ET=21 QB2:0/1/1024
|<---------+ NON 2.05 M:0x82 T:0xf0 O:1234 ET=21 QB2:1/1/1024
|<---------+ [[Payloads 3 - 9 not detailed]]
|<---------+ NON 2.05 M:0x8a T:0xf0 O:1234 ET=21 QB2:9/1/1024
[[MAX_PAYLOADS_SET has been received]]
| [[MAX_PAYLOADS_SET acknowledged by client using
| 'Continue' Q-Block2]]
+--------->| NON GET /path M:0x02 T:0xf1 QB2:10/1/1024
|<---------+ NON 2.05 M:0x8b T:0xf0 O:1234 ET=21 QB2:10/0/1024
| ... |
| [[Observe triggered]]
|<---------+ NON 2.05 M:0x91 T:0xf0 O:1235 ET=22 QB2:0/1/1024
|<---------+ NON 2.05 M:0x92 T:0xf0 O:1235 ET=22 QB2:1/1/1024
|<---------+ [[Payloads 3 - 9 not detailed]]
|<---------+ NON 2.05 M:0x9a T:0xf0 O:1235 ET=22 QB2:9/1/1024
[[MAX_PAYLOADS_SET has been received]]
| [[MAX_PAYLOADS_SET acknowledged by client using
| 'Continue' Q-Block2]]
+--------->| NON GET /path M:0x03 T:0xf2 QB2:10/1/1024
|<---------+ NON 2.05 M:0x9b T:0xf0 O:1235 ET=22 QB2:10/0/1024
[[Body has been received]]
| ... |
Figure 8: Example of NON Notifications with the Q-Block2 Option
(without Loss)
10.2.3. Handling MAX_PAYLOADS with Recovery
Figure 9 shows an example of an Observe that is triggered but for
which some notification blocks are lost. The client detects the
missing blocks and requests their retransmission. It does so by
indicating the blocks that are missing as one or more Q-Block2
options.
CoAP CoAP
Client Server
| ... |
| [[Observe triggered]]
|<---------+ NON 2.05 M:0xa1 T:0xf0 O:1236 ET=23 QB2:0/1/1024
| X<---+ NON 2.05 M:0xa2 T:0xf0 O:1236 ET=23 QB2:1/1/1024
|<---------+ [[Payloads 3 - 9 not detailed]]
| X<---+ NON 2.05 M:0xaa T:0xf0 O:1236 ET=23 QB2:9/1/1024
[[Some of the MAX_PAYLOADS_SET has been received]]
| ... |
[[NON_TIMEOUT_RANDOM (server) delay expires]]
| [[Server sends next MAX_PAYLOADS_SET]]
|<---------+ NON 2.05 M:0xab T:0xf0 O:1236 ET=23 QB2:10/0/1024
| [[On seeing a payload from the next MAX_PAYLOADS_SET,
| client realizes blocks are missing and asks for the
| missing ones in one go]]
+--------->| NON GET /path M:0x04 T:0xf3 QB2:1/0/1024\
| | QB2:9/0/1024
| X<---+ NON 2.05 M:0xac T:0xf3 ET=23 QB2:1/1/1024
|<---------+ NON 2.05 M:0xad T:0xf3 ET=23 QB2:9/1/1024
| ... |
[[NON_RECEIVE_TIMEOUT (client) delay expires]]
| [[Client realizes block is still missing and asks for
| missing block]]
+--------->| NON GET /path M:0x05 T:0xf4 QB2:1/0/1024
|<---------+ NON 2.05 M:0xae T:0xf4 ET=23 QB2:1/1/1024
[[Body has been received]]
| ... |
Figure 9: Example of NON Notifications with the Q-Block2 Option
(Block Recovery)
10.2.4. Handling Recovery by Setting the M Bit
Figure 10 shows an example where an Observe is triggered but only the
first two notification blocks reach the client. In order to retrieve
the missing blocks, the client sends a request with a single Q-Block2
option with the M bit set.
CoAP CoAP
Client Server
| ... |
| [[Observe triggered]]
|<---------+ NON 2.05 M:0xb1 T:0xf0 O:1237 ET=24 QB2:0/1/1024
|<---------+ NON 2.05 M:0xb2 T:0xf0 O:1237 ET=24 QB2:1/1/1024
| X<---+ NON 2.05 M:0xb3 T:0xf0 O:1237 ET=24 QB2:2/1/1024
| X<---+ [[Payloads 4 - 9 not detailed]]
| X<---+ NON 2.05 M:0xb9 T:0xf0 O:1237 ET=24 QB2:9/1/1024
[[Some of the MAX_PAYLOADS_SET has been received]]
| ... |
[[NON_TIMEOUT_RANDOM (server) delay expires]]
| [[Server sends next MAX_PAYLOADS_SET]]
| X<---+ NON 2.05 M:0xba T:0xf0 O:1237 ET=24 QB2:10/0/1024
| ... |
[[NON_RECEIVE_TIMEOUT (client) delay expires]]
| [[Client realizes blocks are missing and asks for the
| missing ones in one go by setting the M bit]]
+--------->| NON GET /path M:0x06 T:0xf5 QB2:2/1/1024
|<---------+ NON 2.05 M:0xbb T:0xf5 ET=24 QB2:2/1/1024
|<---------+ [[Payloads 3 - 9 not detailed]]
|<---------+ NON 2.05 M:0xc2 T:0xf5 ET=24 QB2:9/1/1024
[[MAX_PAYLOADS_SET has been received]]
| [[MAX_PAYLOADS_SET acknowledged by client using 'Continue'
| Q-Block2]]
+--------->| NON GET /path M:0x87 T:0xf6 QB2:10/1/1024
|<---------+ NON 2.05 M:0xc3 T:0xf0 O:1237 ET=24 QB2:10/0/1024
[[Body has been received]]
| ... |
Figure 10: Example of NON Notifications with the Q-Block2 Option
(Block Recovery with the M Bit Set)
10.3. Q-Block1 and Q-Block2 Options
10.3.1. A Simple Example
Figure 11 illustrates an example of a FETCH using both the Q-Block1
and Q-Block2 options along with an Observe option. No loss is
experienced.
CoAP CoAP
Client Server
| |
+--------->| NON FETCH /path M:0x10 T:0x90 O:0 RT=30 QB1:0/1/1024
+--------->| NON FETCH /path M:0x11 T:0x91 O:0 RT=30 QB1:1/1/1024
+--------->| NON FETCH /path M:0x12 T:0x93 O:0 RT=30 QB1:2/0/1024
|<---------+ NON 2.05 M:0x60 T:0x93 O:1320 ET=90 QB2:0/1/1024
|<---------+ NON 2.05 M:0x61 T:0x93 O:1320 ET=90 QB2:1/1/1024
|<---------+ NON 2.05 M:0x62 T:0x93 O:1320 ET=90 QB2:2/1/1024
|<---------+ NON 2.05 M:0x63 T:0x93 O:1320 ET=90 QB2:3/0/1024
| ... |
| [[Observe triggered]]
|<---------+ NON 2.05 M:0x64 T:0x93 O:1321 ET=91 QB2:0/1/1024
|<---------+ NON 2.05 M:0x65 T:0x93 O:1321 ET=91 QB2:1/1/1024
|<---------+ NON 2.05 M:0x66 T:0x93 O:1321 ET=91 QB2:2/1/1024
|<---------+ NON 2.05 M:0x67 T:0x93 O:1321 ET=91 QB2:3/0/1024
| ... |
Figure 11: Example of a NON FETCH with the Q-Block1 and Q-Block2
Options (without Loss)
10.3.2. Handling MAX_PAYLOADS Limits
Figure 12 illustrates the same scenario as Figure 11, but this time
with eleven (11) payloads in both directions, which exceeds
MAX_PAYLOADS. There is no loss experienced.
CoAP CoAP
Client Server
| |
+--------->| NON FETCH /path M:0x30 T:0xa0 O:0 RT=10 QB1:0/1/1024
+--------->| NON FETCH /path M:0x31 T:0xa1 O:0 RT=10 QB1:1/1/1024
+--------->| [[Payloads 3 - 9 not detailed]]
+--------->| NON FETCH /path M:0x39 T:0xa9 O:0 RT=10 QB1:9/1/1024
[[MAX_PAYLOADS_SET has been received]]
| [[MAX_PAYLOADS_SET acknowledged by server]]
|<---------+ NON 2.31 M:0x80 T:0xa9
+--------->| NON FETCH /path M:0x3a T:0xaa O:0 RT=10 QB1:10/0/1024
|<---------+ NON 2.05 M:0x81 T:0xaa O:1334 ET=21 QB2:0/1/1024
|<---------+ NON 2.05 M:0x82 T:0xaa O:1334 ET=21 QB2:1/1/1024
|<---------+ [[Payloads 3 - 9 not detailed]]
|<---------+ NON 2.05 M:0x8a T:0xaa O:1334 ET=21 QB2:9/1/1024
[[MAX_PAYLOADS_SET has been received]]
| [[MAX_PAYLOADS_SET acknowledged by client using
| 'Continue' Q-Block2]]
+--------->| NON FETCH /path M:0x3b T:0xab QB2:10/1/1024
|<---------+ NON 2.05 M:0x8b T:0xaa O:1334 ET=21 QB2:10/0/1024
| ... |
| [[Observe triggered]]
|<---------+ NON 2.05 M:0x8c T:0xaa O:1335 ET=22 QB2:0/1/1024
|<---------+ NON 2.05 M:0x8d T:0xaa O:1335 ET=22 QB2:1/1/1024
|<---------+ [[Payloads 3 - 9 not detailed]]
|<---------+ NON 2.05 M:0x95 T:0xaa O:1335 ET=22 QB2:9/1/1024
[[MAX_PAYLOADS_SET has been received]]
| [[MAX_PAYLOADS_SET acknowledged by client using
| 'Continue' Q-Block2]]
+--------->| NON FETCH /path M:0x3c T:0xac QB2:10/1/1024
|<---------+ NON 2.05 M:0x96 T:0xaa O:1335 ET=22 QB2:10/0/1024
[[Body has been received]]
| ... |
Figure 12: Example of a NON FETCH with the Q-Block1 and Q-Block2
Options (without Loss)
Note that, as 'Continue' was used, the server continues to use the
same token (0xaa), since the 'Continue' is not being used as a
request for a new set of packets but rather is being used to instruct
the server to continue its transmission (
Section 7.2).
10.3.3. Handling Recovery
Consider now a scenario where some blocks are lost in transmission,
as illustrated in Figure 13.
CoAP CoAP
Client Server
| |
+--------->| NON FETCH /path M:0x50 T:0xc0 O:0 RT=31 QB1:0/1/1024
+--->X | NON FETCH /path M:0x51 T:0xc1 O:0 RT=31 QB1:1/1/1024
+--->X | NON FETCH /path M:0x52 T:0xc2 O:0 RT=31 QB1:2/1/1024
+--------->| NON FETCH /path M:0x53 T:0xc3 O:0 RT=31 QB1:3/0/1024
| ... |
[[NON_RECEIVE_TIMEOUT (server) delay expires]]
Figure 13: Example of a NON FETCH with the Q-Block1 and Q-Block2
Options (with Loss)
The server realizes that some blocks are missing and asks for the
missing blocks in one go (Figure 14). It does so by indicating which
blocks have not been received in the data portion of the response.
The token used in the response is the token that was used in the last
received payload. The client can then derive the Request-Tag by
matching the token with the sent request.
CoAP CoAP
Client Server
| |
|<---------+ NON 4.08 M:0xa0 T:0xc3 [Missing 1,2]
| [[Client responds with missing payloads]]
+--------->| NON FETCH /path M:0x54 T:0xc4 O:0 RT=31 QB1:1/1/1024
+--------->| NON FETCH /path M:0x55 T:0xc5 O:0 RT=31 QB1:2/1/1024
| [[Server received FETCH body,
| starts transmitting response body]]
|<---------+ NON 2.05 M:0xa1 T:0xc3 O:1236 ET=23 QB2:0/1/1024
| X<---+ NON 2.05 M:0xa2 T:0xc3 O:1236 ET=23 QB2:1/1/1024
|<---------+ NON 2.05 M:0xa3 T:0xc3 O:1236 ET=23 QB2:2/1/1024
| X<---+ NON 2.05 M:0xa4 T:0xc3 O:1236 ET=23 QB2:3/0/1024
| ... |
[[NON_RECEIVE_TIMEOUT (client) delay expires]]
| |
Figure 14: Example of a NON Request with the Q-Block1 Option
(Server Recovery)
The client realizes that not all the payloads of the response have
been returned. The client then asks for the missing blocks in one go
(Figure 15). Note that, following Section 2.7 of [
RFC7959], the
FETCH request does not include the Q-Block1 or any payload.
CoAP CoAP
Client Server
| |
+--------->| NON FETCH /path M:0x56 T:0xc6 RT=31 QB2:1/0/1024\
| | QB2:3/0/1024
| [[Server receives FETCH request for missing payloads,
| starts transmitting missing blocks]]
| X<---+ NON 2.05 M:0xa5 T:0xc6 ET=23 QB2:1/1/1024
|<---------+ NON 2.05 M:0xa6 T:0xc6 ET=23 QB2:3/0/1024
| ... |
[[NON_RECEIVE_TIMEOUT (client) delay expires]]
| [[Client realizes block is still missing and asks for
| missing block]]
+--------->| NON FETCH /path M:0x57 T:0xc7 RT=31 QB2:1/0/1024
| [[Server receives FETCH request for missing payload,
| starts transmitting missing block]]
|<---------+ NON 2.05 M:0xa7 T:0xc7 ET=23 QB2:1/1/1024
[[Body has been received]]
| ... |
| [[Observe triggered]]
|<---------+ NON 2.05 M:0xa8 T:0xc3 O:1337 ET=24 QB2:0/1/1024
| X<---+ NON 2.05 M:0xa9 T:0xc3 O:1337 ET=24 QB2:1/1/1024
|<---------+ NON 2.05 M:0xaa T:0xc3 O:1337 ET=24 QB2:2/0/1024
[[NON_RECEIVE_TIMEOUT (client) delay expires]]
| [[Client realizes block is still missing and asks for
| missing block]]
+--------->| NON FETCH /path M:0x58 T:0xc8 RT=31 QB2:1/0/1024
| [[Server receives FETCH request for missing payload,
| starts transmitting missing block]]
|<---------+ NON 2.05 M:0xa7 T:0xc8 ET=24 QB2:1/1/1024
[[Body has been received]]
| ... |
Figure 15: Example of a NON Request with the Q-Block1 Option
(Client Recovery)
11. Security Considerations
Security considerations discussed in
Section 7 of [
RFC7959] should be
taken into account.
Security considerations discussed in Sections
11.
3 and
11.4 of
[
RFC7252] should also be taken into account.
OSCORE provides end-to-end protection of all information that is not
required for proxy operations and requires that a security context is
set up (
Section 3.1 of [
RFC8613]). It can be trusted that the source
endpoint is legitimate even if the NoSec mode is used. However, an
intermediary node can modify the unprotected Outer Q-Block1 and/or
Q-Block2 options to cause a Q-Block transfer to fail or keep
requesting all the blocks by setting the M bit and thus causing
attack amplification. As discussed in
Section 12.1 of [
RFC8613],
applications need to consider that certain message fields and message
types are not protected end to end and may be spoofed or manipulated.
Therefore, it is
NOT RECOMMENDED to use the NoSec mode if either the
Q-Block1 or Q-Block2 option is used.
If OSCORE is not used, it is also
NOT RECOMMENDED to use the NoSec
mode if either the Q-Block1 or Q-Block2 option is used.
If NoSec is being used, Appendix D.5 of [
RFC8613] discusses the
security analysis and considerations for unprotected message fields
even if OSCORE is not being used.
Security considerations related to the use of Request-Tag are
discussed in
Section 5 of [
RFC9175].
12. IANA Considerations
12.1. CoAP Option Numbers Registry
IANA has added the following entries to the "CoAP Option Numbers"
subregistry [IANA-Options] defined in [
RFC7252] within the
"Constrained RESTful Environments (CoRE) Parameters" registry:
+========+==========+===========+
| Number | Name | Reference |
+========+==========+===========+
| 19 | Q-Block1 |
RFC 9177 |
+--------+----------+-----------+
| 31 | Q-Block2 |
RFC 9177 |
+--------+----------+-----------+
Table 4: Additions to CoAP
Option Numbers Registry
12.2. Media Type Registration
IANA has registered the "application/missing-blocks+cbor-seq" media
type in the "Media Types" registry [IANA-MediaTypes]. This
registration follows the procedures specified in [
RFC6838].
Type name: application
Subtype name: missing-blocks+cbor-seq
Required parameters: N/A
Optional parameters: N/A
Encoding considerations: Must be encoded as a CBOR Sequence
[
RFC8742], as defined in
Section 5 of RFC 9177.
Security considerations: See
Section 11 of RFC 9177.
Interoperability considerations: N/A
Published specification:
RFC 9177 Applications that use this media type: Data serialization and
deserialization. In particular, the type is used by applications
relying upon block-wise transfers, allowing a server to specify
non-received blocks and request their retransmission, as defined
in
Section 4 of RFC 9177.
Fragment identifier considerations: N/A
Additional information: N/A
Person & email address to contact for further information: IETF,
iesg@ietf.org
Intended usage: COMMON
Restrictions on usage: none
Author: See Authors' Addresses section of
RFC 9177.
Change controller: IESG
Provisional registration? No
12.3. CoAP Content-Formats Registry
IANA has registered the following CoAP Content-Format for the
"application/missing-blocks+cbor-seq" media type in the "CoAP
Content-Formats" registry [IANA-Format] defined in [
RFC7252] within
the "Constrained RESTful Environments (CoRE) Parameters" registry:
+=====================================+==========+=====+===========+
| Media Type | Encoding | ID | Reference |
+=====================================+==========+=====+===========+
| application/missing-blocks+cbor-seq | - | 272 |
RFC 9177 |
+-------------------------------------+----------+-----+-----------+
Table 5: Addition to CoAP Content-Format Registry
13. References
13.1. Normative References
[
RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14,
RFC 2119,
DOI 10.17487/
RFC2119, March 1997,
<
https://www.rfc-editor.org/info/rfc2119>.
[
RFC6838] Freed, N., Klensin, J., and T. Hansen, "Media Type
Specifications and Registration Procedures", BCP 13,
RFC 6838, DOI 10.17487/
RFC6838, January 2013,
<
https://www.rfc-editor.org/info/rfc6838>.
[
RFC7252] Shelby, Z., Hartke, K., and C. Bormann, "The Constrained
Application Protocol (CoAP)",
RFC 7252,
DOI 10.17487/
RFC7252, June 2014,
<
https://www.rfc-editor.org/info/rfc7252>.
[
RFC7641] Hartke, K., "Observing Resources in the Constrained
Application Protocol (CoAP)",
RFC 7641,
DOI 10.17487/
RFC7641, September 2015,
<
https://www.rfc-editor.org/info/rfc7641>.
[
RFC7959] Bormann, C. and Z. Shelby, Ed., "Block-Wise Transfers in
the Constrained Application Protocol (CoAP)",
RFC 7959,
DOI 10.17487/
RFC7959, August 2016,
<
https://www.rfc-editor.org/info/rfc7959>.
[
RFC8075] Castellani, A., Loreto, S., Rahman, A., Fossati, T., and
E. Dijk, "Guidelines for Mapping Implementations: HTTP to
the Constrained Application Protocol (CoAP)",
RFC 8075,
DOI 10.17487/
RFC8075, February 2017,
<
https://www.rfc-editor.org/info/rfc8075>.
[
RFC8132] van der Stok, P., Bormann, C., and A. Sehgal, "PATCH and
FETCH Methods for the Constrained Application Protocol
(CoAP)",
RFC 8132, DOI 10.17487/
RFC8132, April 2017,
<
https://www.rfc-editor.org/info/rfc8132>.
[
RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in
RFC 2119 Key Words", BCP 14,
RFC 8174, DOI 10.17487/
RFC8174,
May 2017, <
https://www.rfc-editor.org/info/rfc8174>.
[
RFC8323] Bormann, C., Lemay, S., Tschofenig, H., Hartke, K.,
Silverajan, B., and B. Raymor, Ed., "CoAP (Constrained
Application Protocol) over TCP, TLS, and WebSockets",
RFC 8323, DOI 10.17487/
RFC8323, February 2018,
<
https://www.rfc-editor.org/info/rfc8323>.
[
RFC8610] Birkholz, H., Vigano, C., and C. Bormann, "Concise Data
Definition Language (CDDL): A Notational Convention to
Express Concise Binary Object Representation (CBOR) and
JSON Data Structures",
RFC 8610, DOI 10.17487/
RFC8610,
June 2019, <
https://www.rfc-editor.org/info/rfc8610>.
[
RFC8613] Selander, G., Mattsson, J., Palombini, F., and L. Seitz,
"Object Security for Constrained RESTful Environments
(OSCORE)",
RFC 8613, DOI 10.17487/
RFC8613, July 2019,
<
https://www.rfc-editor.org/info/rfc8613>.
[
RFC8742] Bormann, C., "Concise Binary Object Representation (CBOR)
Sequences",
RFC 8742, DOI 10.17487/
RFC8742, February 2020,
<
https://www.rfc-editor.org/info/rfc8742>.
[
RFC8949] Bormann, C. and P. Hoffman, "Concise Binary Object
Representation (CBOR)", STD 94,
RFC 8949,
DOI 10.17487/
RFC8949, December 2020,
<
https://www.rfc-editor.org/info/rfc8949>.
[
RFC9175] Amsüss, C., Preuß Mattsson, J., and G. Selander,
"Constrained Application Protocol (CoAP): Echo, Request-
Tag, and Token Processing",
RFC 9175,
DOI 10.17487/
RFC9175, February 2022,
<
https://www.rfc-editor.org/info/rfc9175>.
13.2. Informative References
[DOTS-QUICK-BLOCKS]
Boucadair, M. and J. Shallow, "Distributed Denial-of-
Service Open Threat Signaling (DOTS) Signal Channel
Configuration Attributes for Robust Block Transmission",
Work in Progress, Internet-Draft, draft-bosh-dots-quick-
blocks-03, 29 June 2021,
<
https://datatracker.ietf.org/doc/html/draft-bosh-dots- quick-blocks-03>.
[DOTS-TELEMETRY]
Boucadair, M., Ed., Reddy.K, T., Ed., Doron, E., Chen, M.,
and J. Shallow, "Distributed Denial-of-Service Open Threat
Signaling (DOTS) Telemetry", Work in Progress, Internet-
Draft, draft-ietf-dots-telemetry-19, 4 January 2022,
<
https://datatracker.ietf.org/doc/html/draft-ietf-dots- telemetry-19>.
[IANA-Format]
IANA, "CoAP Content-Formats",
<
https://www.iana.org/assignments/core-parameters/>.
[IANA-MediaTypes]
IANA, "Media Types",
<
https://www.iana.org/assignments/media-types/>.
[IANA-Options]
IANA, "CoAP Option Numbers",
<
https://www.iana.org/assignments/core-parameters/>.
[
RFC6928] Chu, J., Dukkipati, N., Cheng, Y., and M. Mathis,
"Increasing TCP's Initial Window",
RFC 6928,
DOI 10.17487/
RFC6928, April 2013,
<
https://www.rfc-editor.org/info/rfc6928>.
[
RFC7967] Bhattacharyya, A., Bandyopadhyay, S., Pal, A., and T.
Bose, "Constrained Application Protocol (CoAP) Option for
No Server Response",
RFC 7967, DOI 10.17487/
RFC7967,
August 2016, <
https://www.rfc-editor.org/info/rfc7967>.
[
RFC8974] Hartke, K. and M. Richardson, "Extended Tokens and
Stateless Clients in the Constrained Application Protocol
(CoAP)",
RFC 8974, DOI 10.17487/
RFC8974, January 2021,
<
https://www.rfc-editor.org/info/rfc8974>.
[
RFC9132] Boucadair, M., Ed., Shallow, J., and T. Reddy.K,
"Distributed Denial-of-Service Open Threat Signaling
(DOTS) Signal Channel Specification",
RFC 9132,
DOI 10.17487/
RFC9132, September 2021,
<
https://www.rfc-editor.org/info/rfc9132>.
Appendix A. Examples with Confirmable Messages
The following examples assume NSTART has been increased to 3.
The conventions provided in
Section 10 are used in the following
subsections.
A.1. Q-Block1 Option
Let's now consider the use of the Q-Block1 option with a CON request,
as shown in Figure 16. All the blocks are acknowledged (as noted
with "ACK").
CoAP CoAP
Client Server
| |
+--------->| CON PUT /path M:0x01 T:0xf0 RT=10 QB1:0/1/1024
+--------->| CON PUT /path M:0x02 T:0xf1 RT=10 QB1:1/1/1024
+--------->| CON PUT /path M:0x03 T:0xf2 RT=10 QB1:2/1/1024
[[NSTART(3) limit reached]]
|<---------+ ACK 0.00 M:0x01
+--------->| CON PUT /path M:0x04 T:0xf3 RT=10 QB1:3/0/1024
|<---------+ ACK 0.00 M:0x02
|<---------+ ACK 0.00 M:0x03
|<---------+ ACK 2.04 M:0x04
| |
Figure 16: Example of a CON Request with the Q-Block1 Option
(without Loss)
Now, suppose that a new body of data is to be sent but with some
blocks dropped in transmission, as illustrated in Figure 17. The
client will retry sending blocks for which no ACK was received.
CoAP CoAP
Client Server
| |
+--------->| CON PUT /path M:0x05 T:0xf4 RT=11 QB1:0/1/1024
+--->X | CON PUT /path M:0x06 T:0xf5 RT=11 QB1:1/1/1024
+--->X | CON PUT /path M:0x07 T:0xf6 RT=11 QB1:2/1/1024
[[NSTART(3) limit reached]]
|<---------+ ACK 0.00 M:0x05
+--------->| CON PUT /path M:0x08 T:0xf7 RT=11 QB1:3/1/1024
|<---------+ ACK 0.00 M:0x08
| ... |
[[ACK TIMEOUT (client) for M:0x06 delay expires]]
| [[Client retransmits packet]]
+--------->| CON PUT /path M:0x06 T:0xf5 RT=11 QB1:1/1/1024
[[ACK TIMEOUT (client) for M:0x07 delay expires]]
| [[Client retransmits packet]]
+--->X | CON PUT /path M:0x07 T:0xf6 RT=11 QB1:2/1/1024
|<---------+ ACK 0.00 M:0x06
| ... |
[[ACK TIMEOUT exponential backoff (client) delay expires]]
| [[Client retransmits packet]]
+--->X | CON PUT /path M:0x07 T:0xf6 RT=11 QB1:2/1/1024
| ... |
[[Either body transmission failure (acknowledge retry timeout)
or successfully transmitted]]
Figure 17: Example of a CON Request with the Q-Block1 Option
(Block Recovery)
It is up to the implementation as to whether the application process
stops trying to send this particular body of data on reaching
MAX_RETRANSMIT for any payload or separately tries to initiate the
new transmission of the payloads that have not been acknowledged
under these adverse traffic conditions.
If transient network losses are possible, then the use of NON should
be considered.
A.2. Q-Block2 Option
An example of the use of the Q-Block2 option with Confirmable
messages is shown in Figure 18.
Client Server
| |
+--------->| CON GET /path M:0x01 T:0xf0 O:0 QB2:0/1/1024
|<---------+ ACK 2.05 M:0x01 T:0xf0 O:1234 ET=21 QB2:0/1/1024
|<---------+ CON 2.05 M:0xe1 T:0xf0 O:1234 ET=21 QB2:1/1/1024
|<---------+ CON 2.05 M:0xe2 T:0xf0 O:1234 ET=21 QB2:2/1/1024
|<---------+ CON 2.05 M:0xe3 T:0xf0 O:1234 ET=21 QB2:3/0/1024
|--------->+ ACK 0.00 M:0xe1
|--------->+ ACK 0.00 M:0xe2
|--------->+ ACK 0.00 M:0xe3
| ... |
| [[Observe triggered]]
|<---------+ CON 2.05 M:0xe4 T:0xf0 O:1235 ET=22 QB2:0/1/1024
|<---------+ CON 2.05 M:0xe5 T:0xf0 O:1235 ET=22 QB2:1/1/1024
|<---------+ CON 2.05 M:0xe6 T:0xf0 O:1235 ET=22 QB2:2/1/1024
[[NSTART(3) limit reached]]
|--------->+ ACK 0.00 M:0xe4
|<---------+ CON 2.05 M:0xe7 T:0xf0 O:1235 ET=22 QB2:3/0/1024
|--------->+ ACK 0.00 M:0xe5
|--------->+ ACK 0.00 M:0xe6
|--------->+ ACK 0.00 M:0xe7
| ... |
| [[Observe triggered]]
|<---------+ CON 2.05 M:0xe8 T:0xf0 O:1236 ET=23 QB2:0/1/1024
| X<---+ CON 2.05 M:0xe9 T:0xf0 O:1236 ET=23 QB2:1/1/1024
| X<---+ CON 2.05 M:0xea T:0xf0 O:1236 ET=23 QB2:2/1/1024
[[NSTART(3) limit reached]]
|--------->+ ACK 0.00 M:0xe8
|<---------+ CON 2.05 M:0xeb T:0xf0 O:1236 ET=23 QB2:3/0/1024
|--------->+ ACK 0.00 M:0xeb
| ... |
[[ACK TIMEOUT (server) for M:0xe9 delay expires]]
| [[Server retransmits packet]]
|<---------+ CON 2.05 M:0xe9 T:0xf0 O:1236 ET=23 QB2:1/1/1024
[[ACK TIMEOUT (server) for M:0xea delay expires]]
| [[Server retransmits packet]]
| X<---+ CON 2.05 M:0xea T:0xf0 O:1236 ET=23 QB2:2/1/1024
|--------->+ ACK 0.00 M:0xe9
| ... |
[[ACK TIMEOUT exponential backoff (server) delay expires]]
| [[Server retransmits packet]]
| X<---+ CON 2.05 M:0xea T:0xf0 O:1236 ET=23 QB2:2/1/1024
| ... |
[[Either body transmission failure (acknowledge retry timeout)
or successfully transmitted]]
Figure 18: Example of CON Notifications with the Q-Block2 Option
It is up to the implementation as to whether the application process
stops trying to send this particular body of data on reaching
MAX_RETRANSMIT for any payload or separately tries to initiate the
new transmission of the payloads that have not been acknowledged
under these adverse traffic conditions.
If transient network losses are possible, then the use of NON should
be considered.
Appendix B. Examples with Reliable Transports
The conventions provided in
Section 10 are used in the following
subsections.
B.1. Q-Block1 Option
Let's now consider the use of the Q-Block1 option with a reliable
transport, as shown in Figure 19. There is no acknowledgment of
packets at the CoAP layer, just the final result.
CoAP CoAP
Client Server
| |
+--------->| PUT /path T:0xf0 RT=10 QB1:0/1/1024
+--------->| PUT /path T:0xf1 RT=10 QB1:1/1/1024
+--------->| PUT /path T:0xf2 RT=10 QB1:2/1/1024
+--------->| PUT /path T:0xf3 RT=10 QB1:3/0/1024
|<---------+ 2.04
| |
Figure 19: Example of a Reliable Request with the Q-Block1 Option
If transient network losses are possible, then the use of unreliable
transport with NON should be considered.
B.2. Q-Block2 Option
An example of the use of the Q-Block2 option with a reliable
transport is shown in Figure 20.
Client Server
| |
+--------->| GET /path T:0xf0 O:0 QB2:0/1/1024
|<---------+ 2.05 T:0xf0 O:1234 ET=21 QB2:0/1/1024
|<---------+ 2.05 T:0xf0 O:1234 ET=21 QB2:1/1/1024
|<---------+ 2.05 T:0xf0 O:1234 ET=21 QB2:2/1/1024
|<---------+ 2.05 T:0xf0 O:1234 ET=21 QB2:3/0/1024
| ... |
| [[Observe triggered]]
|<---------+ 2.05 T:0xf0 O:1235 ET=22 QB2:0/1/1024
|<---------+ 2.05 T:0xf0 O:1235 ET=22 QB2:1/1/1024
|<---------+ 2.05 T:0xf0 O:1235 ET=22 QB2:2/1/1024
|<---------+ 2.05 T:0xf0 O:1235 ET=22 QB2:3/0/1024
| ... |
Figure 20: Example of Notifications with the Q-Block2 Option
If transient network losses are possible, then the use of unreliable
transport with NON should be considered.
Acknowledgments
Thanks to Achim Kraus, Jim Schaad, and Michael Richardson for their
comments.
Special thanks to Christian Amsüss, Carsten Bormann, and Marco Tiloca
for their suggestions and several reviews, which improved this
specification significantly. Thanks to Francesca Palombini for the
AD review. Thanks to Pete Resnick for the Gen-ART review, Colin
Perkins for the TSVART review, and Emmanuel Baccelli for the IOT-DIR
review. Thanks to Martin Duke, Éric Vyncke, Benjamin Kaduk, Roman
Danyliw, John Scudder, and Lars Eggert for the IESG review.
Some text from [
RFC7959] is reused for the readers' convenience.
Authors' Addresses
Mohamed Boucadair
Orange
35000 Rennes
France
Email: mohamed.boucadair@orange.com
Jon Shallow
United Kingdom