TOC 
CoRE Working GroupC. Bormann
Internet-DraftK. Hartke
Intended status: InformationalUniversität Bremen TZI
Expires: January 2, 2011July 01, 2010


Miscellaneous additions to CoAP
draft-bormann-coap-misc-03

Abstract

This short I-D makes a number of partially interrelated proposals how to solve certain problems in the CoRE WG's main protocol, CoAP.

Status of this Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at http://datatracker.ietf.org/drafts/current/.

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Table of Contents

1.  Introduction
2.  A Compact Accept Option
3.  Representing Durations
    3.1.  Pseudo-Floating Point
    3.2.  A Duration Type for CoAP
4.  URI encoding
    4.1.  An efficient stateless URI encoding
    4.2.  Stateful URI compression
5.  Block-wise transfers
    5.1.  The Block Option
6.  Option Encoding
    6.1.  A More Efficient Option Encoding
    6.2.  Critical Options
    6.3.  Payload-Length Option
    6.4.  Problems with specific options
7.  Experimental Options
    7.1.  Options indicating absolute time
8.  IANA Considerations
9.  Security Considerations
    9.1.  Amplification Attacks
10.  References
    10.1.  Normative References
    10.2.  Informative References
§  Authors' Addresses




 TOC 

1.  Introduction

The CoRE WG is tasked with standardizing an Application Protocol for Constrained Networks/Nodes, CoAP. This protocol is intended to provide RESTful [REST] (Fielding, R., “Architectural Styles and the Design of Network-based Software Architectures,” 2000.) services not unlike HTTP [RFC2616] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.), while reducing the complexity of implementation as well as the size of packets exchanged in order to make these services useful in a highly constrained network of themselves highly constrained nodes.

This objective requires restraint in a number of sometimes conflicting ways:

This draft attempts to address a number of problems not yet adequately solved in [I‑D.ietf‑core‑coap] (Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” June 2010.). The solutions proposed to these problems are somewhat interrelated and are therefore presented in one draft.

In this document, the key words “MUST”, “MUST NOT”, “REQUIRED”, “SHALL”, “SHALL NOT”, “SHOULD”, “SHOULD NOT”, “RECOMMENDED”, “MAY”, and “OPTIONAL” are to be interpreted as described in BCP 14 [RFC2119] (Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” March 1997.) and indicate requirement levels for compliant CoAP implementations.



 TOC 

2.  A Compact Accept Option

A resource may be available in a number of representations. Without some information from the client, a server has no easy way to decide which of these would be best served. HTTP has an Accept: request header that a client can use to indicate the media types supported, allowing the server to decide. This header is somewhat unpopular as, for a web browser, there are too many media types to choose from, so — even with wildcards — there is no meaningful information to put there. (This has changed a bit for AJAX calls, which may indeed have a specific media type preference.) It is unlikely that machine-to-machine communication would have the same problem.

A similar function to the HTTP Accept: header could be added to CoAP as an option in a much simpler way. The CoAP Accept option would simple carry a value that is a sequence of octets, each of which is an acceptable media type for the client, in the order of preference (see Figure 1 (Accept option value: A sequence of media types)). If no Accept option is given, the client does not express a preference.



        0
        0 1 2 3 4 5 6 7
       +-+-+-+-+-+-+-+-+
       |   mediatype   |
       +-+-+-+-+-+-+-+-+

        0                   1
        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |   mediatype1  |   mediatype2  |    etc.
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 Figure 1: Accept option value: A sequence of media types 

Accept also has to be given an option type code, e.g. 7, in Table 2 of [I‑D.ietf‑core‑coap] (Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” June 2010.).

The other addition that would be required is an error code that mirrors HTTP’s “415 Unsupported Media Type”. This is indeed already listed as CoAP Code 35 in Table 3 of [I‑D.ietf‑core‑coap] (Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” June 2010.).

Proposal:
Add an Accept Option.
Benefits:
A Server does not need to specify one URI each for every possible media type that it wants to serve a resource under.
Open Issues:
For coap-00, this would have needed a way to handle two-byte media types (easiest if these can be made self-describing, at the cost of about 3 bits in the sub-type field; Figure 2 (A self-describing media type representation)).

An self-describing representation for long mediatypes could look like this:



        0
        0 1 2 3 4 5 6 7
       +-+-+-+-+-+-+-+-+
       | top |   sub   |  (1-byte: unchanged)
       +-+-+-+-+-+-+-+-+

        0                   1
        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       | 000 | top |       sub         |  (2-byte)
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 Figure 2: A self-describing media type representation 



 TOC 

3.  Representing Durations

Various message types used in CoAP need the representation of durations, i.e. of the length of a timespan. In SI units, these are measured in seconds. Where CPU power and memory is abundant, a duration can almost always be adequately represented by a non-negative floating-point number representing that number of seconds. Historically, many APIs have also used an integer representation, which limits both the resolution (e.g., if the integer represents the duration in seconds) and often the range (integer machine types have range limits that may become relevant). UNIX’s time_t (which is used for both absolute time and durations) originally was a signed 32-bit value of seconds, but was later complemented by an additional integer to add microsecond (struct timeval) and then later nanosecond (struct timespec) resolution.

Three decisions need to be made for each application of the concept of duration:

Obviously, these decisions are interrelated. Typically, a large range needs a large number of bits, unless resolution is traded. For most applications, the actual requirement for resolution are limited for longer durations, but can be more acute for shorter durations.



 TOC 

3.1.  Pseudo-Floating Point

Constrained systems typically avoid the use of floating-point (FP) values, as

In addition, floating-point datatypes used to be a significant element of market differentiation in CPU design; it has taken the industry a long time to agree on a standard floating point representation.

These issues have led to protocols that try to constrain themselves to integer representation even where the ability of a floating point representation to trade range for resolution would be beneficial.

The idea of introducing pseudo-FP is to obtain the increased range provided by embedding an exponent, without necessarily getting stuck with hardware datatypes or inefficient software floating-point libraries.

For the purposes of this draft, we define an (n,e)-pseudo-FP as a fixed-length value of n bits, e of which may be used for an exponent. Figure 3 (An (8,4) pseudo-FP representation) illustrates an (8,4)-pseudo-FP value.



  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| 0...          value           |
+---+---+---+---+---+---+---+---+

+---+---+---+---+---+---+---+---+
| 1... mantissa |    exponent   |
+---+---+---+---+---+---+---+---+

 Figure 3: An (8,4) pseudo-FP representation 

If the high bit is clear, the entire n-bit value (including the high bit) is the decoded value. If the high bit is set, the mantissa (including the high bit, but with the exponent field cleared out) is shifted left by the exponent to yield the decoded value.

The (n,e)-pseudo-FP format can be decoded with a single line of code (plus a couple of constant definition), as demonstrated in Figure 4 (Decoding an (8,4) pseudo-FP value).



#define N 8
#define E 4
#define HIBIT (1 << (N - 1))
#define EMASK ((1 << E) - 1)
#define MMASK ((1 << N) - 1 - EMASK)

#define DECODE_8_4(r) (r < HIBIT ? r : (r & MMASK) << (r & EMASK))

 Figure 4: Decoding an (8,4) pseudo-FP value 

Only non-negative numbers can be represented by this format. It is designed to provide full integer resolution for values from 0 to 2^(n-1)-1, i.e., 0 to 127 in the (8,4) case, and a mantissa of n-e bits from 2^(n-1) to (2^n-2^e)*2^(2^e-1), i.e., 128 to 7864320 in the (8,4) case. By choosing e carefully, resolution can be traded against range.

Note that a pseudo-FP encoder needs to consider rounding; different applications of durations may favor rounding up or rounding down the value encoded in the message. This requires a little more than a single line of code (which is left as an exercise to the reader, as the most efficient expression depends on hardware details).



 TOC 

3.2.  A Duration Type for CoAP

CoAP needs durations in a number of places. In [I‑D.ietf‑core‑coap] (Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” June 2010.), durations occur in the option Subscription-lifetime as well as in the option Max-age. (Note that the option Date is not a duration, but a point in time.) Other durations of this kind may be added later.

Most durations relevant to CoAP are best expressed with a minimum resolution of one second. More detailed resolutions are unlikely to provide much benefit.

The range of lifetimes and caching ages are probably best kept below the order of magnitude of months. An (8,4)-pseudo-FP has the maximum value of 7864320, which is about 91 days; this appears to be adequate for a subscription lifetime and probably even for a maximum cache age. (If a larger range for the latter is indeed desired, an (8,5)-pseudo-FP could be used; this would last 15 milleniums, at the cost of having only 3 bits of accuracy for values larger than 127 seconds.)

Proposal:
A single duration type is used throughout CoAP, based on an (8,4)-pseudo-FP giving a duration in seconds.
Benefits:
Implementations can use a single piece of code for managing all CoAP-related durations.
In addition, length information never needs to be managed for durations that are embedded in other data structures: All durations are expressed by a single byte.
Open Issues:
It might be worthwhile to reserve one duration value, e.g. 0xFF, for an indefinite duration.


 TOC 

4.  URI encoding

In HTTP-based systems, URIs can reach significant lengths. While CoAP-based systems may be able to sidestep the most egregious excesses (mostly by simply applying REST principles), a URI such as

/.well-known/resources

can use up one third of the available payload in a CoAP message transported in a single 6LoWPAN packet. Is there a way to encode these URIs in a more efficient way?

Several proposals have been made on the CoRE mailing list, e.g. applying the principle of base64-encoding [RFC4648] (Josefsson, S., “The Base16, Base32, and Base64 Data Encodings,” October 2006.) in reverse and using only 6 bits per character. However, due to rounding errors and occasional characters that are not in the 64-character subset chosen to be efficiently encodable, the actual gains are limited. Similarly, using 7 bits per character (assuming URIs contain only ASCII characters) only gives a best-case gain of 12.5 %, and that only in the case the URI is a multiple of 8 characters long. On the other hand, the complexity (and danger of subtle interoperability problems) is not entirely trivial.

We will proceed by first proposing an URI encoding that is slightly more efficient than the abovementioned ones, then rejecting even that for its unconvincing cost-benefit ratio, and finally taking up Henning Schulzrinne’s proposal to add state.



 TOC 

4.1.  An efficient stateless URI encoding

There is very little redundancy by repetition in a typical URI, rendering popular compression methods such as LZ77 (as implemented in in the widely used DEFLATE algorithm [RFC1951] (Deutsch, P., “DEFLATE Compressed Data Format Specification version 1.3,” May 1996.)) rather ineffective.

For the short, non-repetitive data structures that URIs tend to be, efficient stateless compression is pretty much confined to Huffman (or, for even more complexity, arithmetic) coding. The complexity can be reduced significantly by moving to n-ary Huffman coding, i.e., optimizing not to the bit level, but to a larger level of granularity. Informal experiments by the author show that a 16ary Huffman coding is close to optimal for reasonable URI lengths. In other words, basing the encoding on nibbles (4-bit half-bytes) is both nearly optimal and relatively inexpensive to implement.

The actual letter frequencies that will occur in CoAP URIs are hard to predict. As a stopgap, the author has analyzed an HTTP-based URI corpus and found the following characters to occur with high frequency:

%.aeinorst

In the encoding proposed, each of these ten highly-compressed characters is represented by a single 4-bit nibble. As the % character is used for hexadecimal encoding in URIs, two additional nibbles are used to provide the numeric value of the two hexadecimal numbers following the % character (the original URI will only be properly reconstituted if these are upper-case as they should be according to section 2.1 of the URI specification [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.); the encoder can choose to send all three characters in dual-nibble format if that matters). An encoder could also map non-ASCII characters to this three-nibble form, even though they are not allowed in URIs. This gives compatibility with the %-encoding required by [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.).

All other characters are represented by both of their nibbles. The resulting sequence of nibbles is reconstituted into a sequence of bytes in most-significant-nibble-first order. Any unused nibble in the last byte of an encoding is set to 0. (Upon decoding, this padding can be readily distinguished from another % combination as this would require another byte after the last byte.) The encoding is summarized in Figure 5 (A nibble-based URI encoding).



  0                                       1
  0   1   2   3   4   5   6   7   8   9   0   1
+---+---+---+---+
|    1, 8-F     |   .aeinorst
+---+---+---+---+   189ABCDEF

+---+---+---+---+---+---+---+---+
|      2-7      |      0-F      |   other ASCII
+---+---+---+---+---+---+---+---+

+---+---+---+---+---+---+---+---+---+---+---+---+
|       0       |      0-F      |      0-F      |   %HH
+---+---+---+---+---+---+---+---+---+---+---+---+

 Figure 5: A nibble-based URI encoding 

An example encoding for /.well-known/resources (where the initial slash is left out, as proposed for abs-path URIs) is given in Figure 6 (Nibble-based URI encoding: 21 -> 15 bytes). While the more than 28 % savings in this example may seem just an accident, the HTTP-based corpus indeed shows an average savings of about 21.8 %, i.e. the sum of the lengths of the encoded version of all URIs in the corpus is about 78.2 % of the sum of the length of all URIs. (The savings should be noticeably higher with a more RESTful selection of URIs than was available for this experiment.)



     0                          1                             2
     1  2  3  4  5  6  7  8  9  0  1  2  3  4  5  6  7  8  9  0  1
  /  .  w  e  l  l  -  k  n  o  w  n  /  r  e  s  o  u  r  c  e  s

    2e 77 65 6c 6c 2d 6b 6e 6f 77 6e 2f 72 65 73 6f 75 72 63 65 73
->
    1  77 9  6c 6c 2d 6b b  c  77 b  2f d  9  e  c  75 d  63 9  e
  = 17 79 6c 6c 2d 6b bc 77 b2 fd 9e c7 5d 63 9e
 Figure 6: Nibble-based URI encoding: 21 -> 15 bytes 



 TOC 

4.2.  Stateful URI compression

Is the approximately 25 % average saving achievable with Huffman-based URI compression schemes worth the complexity? Probably not, because much higher average savings can be achieved by introducing state.

Henning Schulzrinne has proposed for a server to be able to supply a shortened URI once a resource has been requested using the full-length URI. Let’s call such a shortened referent a Temporary Resource Identifier, TeRI for short. This could be expressed by a response option as shown in Figure 7 (Option for offering a TeRI in a response).



        0
        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |    duration   |    TeRI...
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 Figure 7: Option for offering a TeRI in a response 

The TeRI offer option indicates that the server promises to offer this resources under the TeRI given for at least the time given as the duration. Another TeRI offer can be made later to extend the duration.

Once a TeRI for a URI is known (and still within its lifetime), the client can supply a TeRI instead of a URI in its requests. The same option format as an offer could be used to allow the client to indicate how long it believes the TeRI will still be valid (so that the server can decide when to update the lifetime duration). TeRIs in requests could be distinguished from URIs e.g. by using a different option number.

Proposal:
Add a TeRI option (e.g., number 2) that can be used in CoAP requests and responses.
Add a way to indicate a TeRI and its duration in a link-value.
Do not add any form of stateless URI encoding.
Benefits:
Much higher reduction of message size than any stateless URI encoding could achieve.
As the use of TeRIs is entirely optional, minimal complexity nodes can get by without implementing them.


 TOC 

5.  Block-wise transfers

Not all resource representations will fit into a single link layer packet of a constrained network. Using fragmentation (either at the adaptation layer or at the IP layer) to enable the transport of larger representations is possible up to the maximum size of a UDP datagram, but the fragmentation/reassembly process loads the lower layers with conversation state that is better managed in the application layer.

This section proposes options to enable block-wise access to resource representations. The overriding objective is to avoid creating conversation state at the server for block-wise GET requests. (It is impossible to fully avoid creating conversation state for POST/PUT, if the creation/replacement of resources is to be atomic; where that property is not needed, there is no need to create server conversation state in this case, either.) Also, implementation of these options is intended to be optional. (The details of which parts of the behavior need to be mandatory to enable that optionality still are TBD, see below.)

The size of the blocks should not be fixed by the protocol. On the other hand, implementation should be as simple as possible. We therefore propose a small range of power-of-two block sizes, from 2^4 (16) to 2^11 (2048) bytes. One of these eight values can be encoded in three bits (0 for 2^4 to 7 for 2^11 bytes), the szx (size exponent); the actual block size is then 1 << (szx + 4).



 TOC 

5.1.  The Block Option

When a representation is larger than can be comfortably transferred in a single UDP datagram, the Block option can be used to indicate a block-wise transfer. Block is a 1-, 2- or 3-byte integer, the four least significant bits of which indicate the size and whether the current block-wise transfer is the last block being transferred (M or “more” bit). The value divided by sixteen is the number of the block currently being transferred, starting from zero, i.e., the current transfer is about the size bytes starting at blocknr << (szx + 4). The default value of the Block option is zero, indicating that the current block is the first (block number 0) and only (M bit not set) block of the transfer; however, there is no explicit size implied by this default value.



        0
        0 1 2 3 4 5 6 7
       +-+-+-+-+-+-+-+-+
       |blocknr|M| szx |
       +-+-+-+-+-+-+-+-+

        0                   1
        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |        block nr       |M| szx |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

        0                   1                   2
        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
       |                block nr               |M| szx |
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 Figure 8: Block option 

(Note that the option with the last 4 bits masked out, shifted to the left by the value of szx, gives the byte position of the block. The author is not too sure whether that particularly is a feature.)

The block option is used in one of three roles:

In all cases, the block number logically extends the transaction ID, i.e. the same transaction ID can be used for all exchanges for a block-wise transfer. (For GET, and for PUT/POST where atomic semantics are not needed, the requester is free to use different transactions IDs for each block if desired.)

When a GET is answered with a response carrying a Block option with the M bit set, the requestor may retrieve additional blocks by sending requests with a Block option giving the block number desired. In such a Block option, the M bit MUST be sent as zero and ignored on reception.

To influence the block size used in response to a GET request, the requestor uses the Block option, giving the desired size, a block number of zero and an M bit of zero. A server SHOULD use the block size indicated or a smaller size. Any further block-wise requests for blocks beyond the first one MUST indicate the block size used in the response for the first one.

If the Block option is used by the requestor, all GET requests in a single transaction MUST use the same size. The server SHOULD use the block size indicated in the request option, but the requestor MUST take note of the actual block size used in the response; the server MUST ensure that it uses the same block size for all responses in a transaction (except for the last one with the M bit not set). [TBD: decide whether the Block option can only be used in a response if a Block option was in the request. Such a minimal block option could be of length zero, i.e., would occupy just one byte for the type/length information, but is a bit redundant, so it would be nice to leave this requirement out, but then every GET requestor has the burden of having to cope with receiving Block options.]

Block-wise transfers SHOULD be used in conjunction with the Etag option, unless the representation being exchanged is entirely static (not changing over time at all, such as in a schema describing a device). When reassembling the representation from the blocks being exchanged, the reassembler MUST compare Etag options. If the Etag options do not match in a GET transfer, the requestor has the option of attempting to retrieve fresh values for the blocks it retrieved first. To minimize the resulting inefficiency, the server MAY cache the current value of a representation for an ongoing transaction, but there is no requirement for the server to establish any state. The server may offer a TeRI with the initial block to reduce the size of further block-wise GET requests; this TeRI MAY be short-lived and specific to the version of the representation being retrieved (which would in effect freeze the representation of the resource specifically for the purposes of this block-wise transfer).

In a PUT or POST transfer, the block option refers to the body in the request, i.e., there is no way to perform a block-wise retrieval of the body of the response. Servers that do need to supply large bodies in response to PUT/POST SHOULD therefore be employing redirects, possibly offering a TeRI.

In a PUT or POST transfer that is intended to be implemented in an atomic fashion at the server, the actual creation/replacement takes place at the time a block with the M bit unset is received. If not all previous blocks are available at the server at this time, the transfer fails and error code 4__ (TBD) MUST be returned. The error code 4__ can also be returned at any time by a server that does not currently have the resources to store blocks for a block-wise PUT or POST transfer that it would intend to implement in an atomic fashion. [TBD: a way for a server to derive the equivalent of an Etag for the request body, so that when these do not match in a PUT or POST transfer, the reassembler MUST discard older blocks. For now, the transaction ID will have to suffice.]

Proposal:
Add a Block option (e.g., number 8) that can be used for block-wise transfers.
Benefits:
Transfers larger than can be accommodated in constrained-network link-layer packets can be performed in smaller blocks.
No hard-to-manage conversation state is created at the adaptation layer or IP layer for fragmentation.
The transfer of each block is acknowledged, enabling retransmission if required.
Both sides have a say in the block size that actually will be used.


 TOC 

6.  Option Encoding

The option encoding in [I‑D.ietf‑core‑coap] (Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” June 2010.) is neither particularly flexible nor particularly efficient. One important, easily overlooked disadvantage of the encoding is the large number of ways in which the same information can be encoded. This unneeded variability causes problems in interoperability and increases both coding and testing efforts required.



 TOC 

6.1.  A More Efficient Option Encoding

The basic idea of the proposed encoding is to reduce the number of ways the same information can be encoded as far as possible (but not further). This both simplifies decoding (e.g., an implementation that only ever uses short URIs never has to implement long options, because these can only be used with long lengths) and interoperability testing (there is only one way to say a specific thing, so there aren’t multiple ways that need testing).

One of the undesired variations in packets is the ordering of the options. In this draft, we therefore mandate a total ordering of options, ordered by the option number.

As an interesting consequence, the option numbers can now be expressed in delta coding, in turn requiring fewer bits to encode the option number. This frees a number of bits for the length, making the likelihood of actually needing the two-byte form of the option header much smaller.

To further reduce variation, the length of the value (as always, not including the option header) is now encoded in such a way that there is only one way to express a given length: The short form (one-byte option tag) can express length values from 0 to 14, and the long form is used for values of 15 to 15+255=270, inclusively (Figure 9 (Option delta/length representation with small range)).



      0   1   2   3   4   5   6   7
    +---+---+---+---+---+---+---+---+
    | option delta  |    length     | for 0..14
    +---+---+---+---+---+---+---+---+
                                               for 15..270:
    +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+
    | option delta  | 1   1   1   1 |          length - 15          |
    +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+
 Figure 9: Option delta/length representation with small range 

The small option delta of 0..15 in this encoding limits the difference in option value between two adjacent options (or the value of the option number of the first option). While realistic sequences of options rarely will have a problem here, option numbers 14, 28, … are reserved for no-op options with no body (implementations will automatically ignore these with zero additional code; see Section 6.2 (Critical Options) why the reserved values are not 15, 30, …). Note that the resulting delta that reaches the interim nop option may have any number, e.g., for including option 2 and 27 in one message, the sequence would be:

In the unlikely case that only option 40 is needed, the sequence would be:



 TOC 

6.2.  Critical Options

CoAP is designed to enable the definition of additional options by later extensions. Typically, new options are designed in such a way that they can simply be ignored if not understood, i.e. new options are elective. However, some new options may be critical, i.e., there is no good way to process the message if the option is not understood. (Actually, half of the options currently on the table are critical in nature.)

In the option encoding proposed, odd-numbered options indicate a critical option; even-numbered options indicate elective options. (Note that, again, the even/odd distinction is on the option number resulting from the decoding, not the delta value actually embedded in the packet.)

Implementing this proposal requires some renumbering of options from [I‑D.ietf‑core‑coap] (Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” June 2010.).



 TOC 

6.3.  Payload-Length Option

Not all transport mappings may provide an unambiguous length of the CoAP message. For UDP, it may also be desirable to pack more than one CoAP message into one UDP payload (aggregation); in that case, for all but the last message there needs to be a way to delimit the payload of that message.

We propose a new option, the Payload-Length option. If this option is present, the value of this option is an unsigned integer giving the length of the payload of the message (note that this integer can be zero for a zero-length payload, which can in turn be represented by a zero-length option value). (In the UDP aggregation case, what would have been in the payload of this message after payload-length bytes is then actually one or more additional messages.)



 TOC 

6.4.  Problems with specific options

Problem:
The Uri option currently does not provide a way to distinguish an absolute-URI from an absolute-path [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.), as the leading slash is omitted from the latter. (Ticket #12.)
Proposal:
Split the option into two variants: Uri-Full and Uri-Path. None (= Uri-Path with option value ‘’), one of these, but never both can be present.


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7.  Experimental Options



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7.1.  Options indicating absolute time

HTTP has a number of headers that may indicate absolute time:

[I‑D.ietf‑core‑coap] (Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” June 2010.) defines a single Date option, which however “indicates the creation time and date of a given resource representation”, i.e., is closer to a “Last-Modified” HTTP header. HTTP’s caching rules [I‑D.ietf‑httpbis‑p6‑cache] (Fielding, R., Gettys, J., Mogul, J., Nielsen, H., Masinter, L., Leach, P., Berners-Lee, T., and J. Reschke, “HTTP/1.1, part 6: Caching,” March 2010.) make use of both Date and Last-Modified, combined with Expires. The specific semantics required for CoAP needs further consideration.

In addition to the definition of the semantics, an encoding for absolute times needs to be specified.

In UNIX-related systems, it is customary to indicate absolute time as an integer number of seconds, after midnight UTC, January 1, 1970. Unless negative numbers are employed, this time format cannot represent time values prior to January 1, 1970, which probably is not required for the uses ob absolute time in CoAP.

If a 32-bit integer is used and allowance is made for a sign-bit in a local implementation, the latest UTC time value that can be represented by the resulting 31 bit integer value is 03:14:07 on January 19, 2038. If the 32-bit integer is used as an unsigned value, the last date is 2106-02-07, 06:28:15.

The reach can be extended by: - moving the epoch forward, e.g. by 40 years (= 1262304000 seconds) to 2010-01-01. This makes it impossible to represent Last-Modified times in that past (such as could be gatewayed in from HTTP). - extending the number of bits, e.g. by one more byte, either always or as one of two formats, keeping the 32-bit variant as well.

Also, the resolution can be extended by expressing time in milliseconds etc., requiring even more bits (e.g., a 48-bit unsigned integer of milliseconds would last well after year 9999.)

For experiments, an experimental Date option is defined with the semantics of HTTP’s Last-Modified. It can carry an unsigned integer of 32, 40, or 48 bits; 32- and 40-bit integers indicate the absolute time in seconds since 1970-01-01 00:00 UTC, while 48-bit integers indicate the absolute time in milliseconds since 1970-01-01 00:00 UTC.



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8.  IANA Considerations

This draft adds the following option numbers to Table 2 of [I‑D.ietf‑core‑coap] (Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” June 2010.):

TypeC/ENameData typeLengthRules
2 E TeRI Duration + Sequence of Bytes 2-n B  
7 E Accept Sequence of bytes 1-n B  
8 C Block Unsigned Integer 1-3 B  

With the new option encoding and the proposal for essential options, the total list becomes:

TypeC/ENameData typeLengthRules
0 E TeRI Duration + Sequence of Bytes 2-n B  
1 C Uri-Path String 1-n B  
2 E Accept Sequence of Bytes 1-n B  
3 C Uri-Full String 1-n B  
4 E Max-age Duration 1 B  
5 C Content-type Unsigned Integer 1-2 B  
6 E Etag Sequence of Bytes 1-4 B  
8 E Date Unsigned Integer (?) 4-6 B (with body)
13 C Block Unsigned Integer 1-3 B  
14.. E Nop None 0 B  
15 C Payload-length Unsigned Integer 0-2 B  

(The upper limit of n indicates that the size is limited only by the options encoding.) Odd option numbers indicate critical options, even option numbers indicate elective options. Option numbers 14, 28, 42, … (any number divisible by 14) are reserved (they are elective and therefore ignored by all implementations).

(Subscription-related options are discussed in [I‑D.hartke‑coap‑observe] (Hartke, K. and C. Bormann, “Observing Resources in CoAP,” June 2010.), so the following option from [I‑D.ietf‑core‑coap] (Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” June 2010.) is not further discussed here:

TypeC/ENameData typeLengthRules
6 E Subscription-lifetime Duration 1 B With SUBSCRIBE or its response



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9.  Security Considerations

TBD. (Weigh the security implications of application layer block-wise transfer against those of adaptation-layer or IP-layer fragmentation. Discuss the implications of TeRIs. Also: Discuss nodes without clocks.)



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9.1.  Amplification Attacks

TBD. (This section discusses how CoAP nodes could become implicated in DoS attacks by using the amplifying properties of the protocol, as well as mitigations for this threat.)



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10.  References



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10.1. Normative References

[I-D.hartke-coap-observe] Hartke, K. and C. Bormann, “Observing Resources in CoAP,” draft-hartke-coap-observe-00 (work in progress), June 2010 (TXT).
[I-D.ietf-core-coap] Shelby, Z., Frank, B., and D. Sturek, “Constrained Application Protocol (CoAP),” draft-ietf-core-coap-00 (work in progress), June 2010 (TXT).
[I-D.ietf-httpbis-p1-messaging] Fielding, R., Gettys, J., Mogul, J., Nielsen, H., Masinter, L., Leach, P., Berners-Lee, T., and J. Reschke, “HTTP/1.1, part 1: URIs, Connections, and Message Parsing,” draft-ietf-httpbis-p1-messaging-09 (work in progress), March 2010 (TXT).
[I-D.ietf-httpbis-p4-conditional] Fielding, R., Gettys, J., Mogul, J., Nielsen, H., Masinter, L., Leach, P., Berners-Lee, T., and J. Reschke, “HTTP/1.1, part 4: Conditional Requests,” draft-ietf-httpbis-p4-conditional-09 (work in progress), March 2010 (TXT).
[I-D.ietf-httpbis-p6-cache] Fielding, R., Gettys, J., Mogul, J., Nielsen, H., Masinter, L., Leach, P., Berners-Lee, T., and J. Reschke, “HTTP/1.1, part 6: Caching,” draft-ietf-httpbis-p6-cache-09 (work in progress), March 2010 (TXT).
[RFC2119] Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” BCP 14, RFC 2119, March 1997 (TXT, HTML, XML).
[RFC2616] Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” RFC 2616, June 1999 (TXT, PS, PDF, HTML, XML).
[RFC3986] Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” STD 66, RFC 3986, January 2005 (TXT, HTML, XML).


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10.2. Informative References

[REST] Fielding, R., “Architectural Styles and the Design of Network-based Software Architectures,” 2000.
[RFC1951] Deutsch, P., “DEFLATE Compressed Data Format Specification version 1.3,” RFC 1951, May 1996 (TXT, PS, PDF).
[RFC4648] Josefsson, S., “The Base16, Base32, and Base64 Data Encodings,” RFC 4648, October 2006 (TXT).


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Authors' Addresses

  Carsten Bormann
  Universität Bremen TZI
  Postfach 330440
  Bremen D-28359
  Germany
Phone:  +49-421-218-63921
Fax:  +49-421-218-7000
Email:  cabo@tzi.org
  
  Klaus Hartke
  Universität Bremen TZI
  Postfach 330440
  Bremen D-28359
  Germany
Phone:  +49-421-218-63908
Fax:  +49-421-218-7000
Email:  hartke@tzi.org