| lpwan Working Group | A. Minaburo |
| Internet-Draft | Acklio |
| Intended status: Informational | L. Toutain |
| Expires: March 16, 2018 | IMT-Atlantique |
| C. Gomez | |
| Universitat Politècnica de Catalunya | |
| September 12, 2017 |
LPWAN Static Context Header Compression (SCHC) and fragmentation for IPv6 and UDP
draft-ietf-lpwan-ipv6-static-context-hc-06
This document describes a header compression scheme and fragmentation functionality for very low bandwidth networks. These techniques are especially tailored for LPWAN (Low Power Wide Area Network) networks.
The Static Context Header Compression (SCHC) offers a great level of flexibility when processing the header fields and must be used for these kind of networks. A common context stored in a LPWAN device and in the network is used. This context keeps information that will not be transmitted in the constrained network. Static context means that information stored in the context, which describes field values, does not change during packet transmission. This avoids complex resynchronization mechanisms, which are incompatible with LPWAN characteristics. In most cases, IPv6/UDP headers are reduced to a small identifier called Rule ID. But sometimes, a packet will not be compressed enough by SCHC to fit in one L2 PDU, and the SCHC fragmentation protocol will be used.
This document describes the SCHC compression/decompression framework and applies it to IPv6/UDP headers. Similar solutions for other protocols such as CoAP will be described in separate documents. Moreover, this document specifies a fragmentation and reassembly mechanism that is used in two situations: for SCHC-compressed packets that still exceed the L2 PDU size; and for the case where the SCHC compression cannot be performed.
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Header compression is mandatory to efficiently bring Internet connectivity to the node within a LPWAN network. Some LPWAN networks properties can be exploited to get an efficient header compression:
The Static Context Header Compression (SCHC) is defined for this environment. SCHC uses a context where header information is kept in the header format order. This context is static (the values on the header fields do not change over time) avoiding complex resynchronization mechanisms, incompatible with LPWAN characteristics. In most of the cases, IPv6/UDP headers are reduced to a small context identifier.
The SCHC header compression mechanism is independent from the specific LPWAN technology over which it will be used.
LPWAN technologies are also characterized, among others, by a very reduced data unit and/or payload size [I-D.ietf-lpwan-overview]. However, some of these technologies do not support layer two fragmentation, therefore the only option for them to support the IPv6 MTU requirement of 1280 bytes [RFC2460] is the use of a fragmentation protocol at the adaptation layer below IPv6. This draft defines also a fragmentation functionality to support the IPv6 MTU requirements over LPWAN technologies. Such functionality has been designed under the assumption that data unit reordering will not happen between the entity performing fragmentation and the entity performing reassembly.
LPWAN technologies have similar architectures but different terminology. We can identify different types of entities in a typical LPWAN network, see Figure 1:
o Devices (Dev) are the end-devices or hosts (e.g. sensors, actuators, etc.). There can be a high density of devices per radio gateway.
o The Radio Gateway (RG), which is the end point of the constrained link.
o The Network Gateway (NGW) is the interconnection node between the Radio Gateway and the Internet.
o LPWAN-AAA Server, which controls the user authentication and the applications. We use the term LPWAN-AAA server because we are not assuming that this entity speaks RADIUS or Diameter as many/most AAA servers do, but equally we don’t want to rule that out, as the functionality will be similar.
o Application Server (App)
+------+
() () () | |LPWAN-|
() () () () / \ +---------+ | AAA |
() () () () () () / \=====| ^ |===|Server| +-----------+
() () () | | <--|--> | +------+ |APPLICATION|
() () () () / \==========| v |=============| (App) |
() () () / \ +---------+ +-----------+
Dev Radio Gateways NGW
Figure 1: LPWAN Architecture
This section defines the terminology and acronyms used in this document.
Static Context Header Compression (SCHC) avoids context synchronization, which is the most bandwidth-consuming operation in other header compression mechanisms such as RoHC [RFC5795]. Based on the fact that the nature of data flows is highly predictable in LPWAN networks, some static contexts may be stored on the Device (Dev). The contexts must be stored in both ends, and it can either be learned by a provisioning protocol or by out of band means or it can be pre-provisioned, etc. The way the context is learned on both sides is out of the scope of this document.
Dev App
+--------------+ +--------------+
|APP1 APP2 APP3| |APP1 APP2 APP3|
| | | |
| UDP | | UDP |
| IPv6 | | IPv6 |
| | | |
| SCHC C/D | | |
| (context) | | |
+-------+------+ +-------+------+
| +--+ +----+ +---------+ .
+~~ |RG| === |NGW | === |SCHC C/D |... Internet ..
+--+ +----+ |(context)|
+---------+
Figure 2: Architecture
Figure 2 represents the architecture for compression/decompression, it is based on [I-D.ietf-lpwan-overview] terminology. The Device is sending applications flows using IPv6 or IPv6/UDP protocols. These flows are compressed by an Static Context Header Compression Compressor/Decompressor (SCHC C/D) to reduce headers size. Resulting information is sent on a layer two (L2) frame to a LPWAN Radio Network (RG) which forwards the frame to a Network Gateway (NGW). The NGW sends the data to a SCHC C/D for decompression which shares the same rules with the Dev. The SCHC C/D can be located on the Network Gateway (NGW) or in another place as long as a tunnel is established between the NGW and the SCHC C/D. The SCHC C/D in both sides must share the same set of Rules. After decompression, the packet can be sent on the Internet to one or several LPWAN Application Servers (App).
The SCHC C/D process is bidirectional, so the same principles can be applied in the other direction.
The main idea of the SCHC compression scheme is to send the Rule id to the other end instead of sending known field values. This Rule id identifies a rule that match as much as possible the original packet values. When a value is known by both ends, it is not necessary sent through the LPWAN network.
The context contains a list of rules (cf. Figure 3). Each Rule contains itself a list of fields descriptions composed of a field identifier (FID), a field position (FP), a direction indicator (DI), a target value (TV), a matching operator (MO) and a Compression/Decompression Action (CDA).
/--------------------------------------------------------------\ | Rule N | /--------------------------------------------------------------\| | Rule i || /--------------------------------------------------------------\|| | (FID) Rule 1 ||| |+-------+--+--+------------+-----------------+---------------+||| ||Field 1|FP|DI|Target Value|Matching Operator|Comp/Decomp Act|||| |+-------+--+--+------------+-----------------+---------------+||| ||Field 2|FP|DI|Target Value|Matching Operator|Comp/Decomp Act|||| |+-------+--+--+------------+-----------------+---------------+||| ||... |..|..| ... | ... | ... |||| |+-------+--+--+------------+-----------------+---------------+||/ ||Field N|FP|DI|Target Value|Matching Operator|Comp/Decomp Act||| |+-------+--+--+------------+-----------------+---------------+|/ | | \--------------------------------------------------------------/
Figure 3: Compression/Decompression Context
The Rule does not describe the original packet format which must be known from the compressor/decompressor. The rule just describes the compression/decompression behavior for the header fields. In the rule, the description of the header field must be performed in the format packet order.
The Rule also describes the compressed header fields which are transmitted regarding their position in the rule which is used for data serialization on the compressor side and data deserialization on the decompressor side.
The Context describes the header fields and its values with the following entries:
Rule IDs are sent between both compression/decompression elements. The size of the Rule ID is not specified in this document, it is implementation-specific and can vary regarding the LPWAN technology, the number of flows, among others.
Some values in the Rule ID space may be reserved for goals other than header compression as fragmentation. (See Section 5).
Rule IDs are specific to a Dev. Two Devs may use the same Rule ID for different header compression. To identify the correct Rule ID, the SCHC C/D needs to combine the Rule ID with the Dev L2 identifier to find the appropriate Rule.
The compression/decompression process follows several steps:
+--- ... --+-------------- ... --------------+-----------+--...--+ | Rule ID |Compressed Hdr Fields information| payload |padding| +--- ... --+-------------- ... --------------+-----------+--...--+
Figure 4: LPWAN Compressed Format Packet
Matching Operators (MOs) are functions used by both SCHC C/D endpoints involved in the header compression/decompression. They are not typed and can be applied indifferently to integer, string or any other data type. The result of the operation can either be True or False. MOs are defined as follows:
The Compression Decompression Action (CDA) describes the actions taken during the compression of headers fields, and inversely, the action taken by the decompressor to restore the original value.
/--------------------+-------------+----------------------------\ | Action | Compression | Decompression | | | | | +--------------------+-------------+----------------------------+ |not-sent |elided |use value stored in ctxt | |value-sent |send |build from received value | |mapping-sent |send index |value from index on a table | |LSB(length) |send LSB |TV OR received value | |compute-length |elided |compute length | |compute-checksum |elided |compute UDP checksum | |Deviid |elided |build IID from L2 Dev addr | |Appiid |elided |build IID from L2 App addr | \--------------------+-------------+----------------------------/
Figure 5: Compression and Decompression Functions
Figure 5 sumarizes the basics functions defined to compress and decompress a field. The first column gives the action’s name. The second and third columns outlines the compression/decompression behavior.
Compression is done in the rule order and compressed values are sent in that order in the compressed message. The receiver must be able to find the size of each compressed field which can be given by the rule or may be sent with the compressed header.
If the field is identified as variable, then its size must be sent first using the following coding:
Not-sent function is generally used when the field value is specified in the rule and therefore known by the both Compressor and Decompressor. This action is generally used with the “equal” MO. If MO is “ignore”, there is a risk to have a decompressed field value different from the compressed field.
The compressor does not send any value on the compressed header for the field on which compression is applied.
The decompressor restores the field value with the target value stored in the matched rule.
The value-sent action is generally used when the field value is not known by both Compressor and Decompressor. The value is sent in the compressed message header. Both Compressor and Decompressor must know the size of the field, either implicitly (the size is known by both sides) or explicitly in the compressed header field by indicating the length. This function is generally used with the “ignore” MO.
mapping-sent is used to send a smaller index associated to the list of values in the Target Value. This function is used together with the “match-mapping” MO.
The compressor looks in the TV to find the field value and send the corresponding index. The decompressor uses this index to restore the field value.
The number of bits sent is the minimal size to code all the possible indexes.
LSB action is used to avoid sending the known part of the packet field header to the other end. This action is used together with the “MSB” MO. A length can be specified in the rule to indicate how many bits have to be sent. If not length is specified, the number of bits sent are the field length minus the bits length specified in the MSB MO.
The compressor sends the “length” Least Significant Bits. The decompressor combines the value received with the Target Value.
If this action is made on a variable length field, the remaining size in byte has to be sent before.
These functions are used to process respectively the Dev and the App Interface Identifiers (Deviid and Appiid) of the IPv6 addresses. Appiid CDA is less common, since current LPWAN technologies frames contain a single address.
The IID value may be computed from the Device ID present in the Layer 2 header. The computation is specific for each LPWAN technology and may depend on the Device ID size.
In the downstream direction, these CDA may be used to determine the L2 addresses used by the LPWAN.
These classes of functions are used by the decompressor to compute the compressed field value based on received information. Compressed fields are elided during compression and reconstructed during decompression.
Fragmentation supported in LPWAN is mandatory when the underlying LPWAN technology is not capable of fulfilling the IPv6 MTU requirement. Fragmentation is used after SCHC header compression when the size of the resulting compressed packet is larger than the L2 data unit maximum payload. In LPWAN technologies, the L2 data unit size typically varies from tens to hundreds of bytes. If the entire datagram fits within a single L2 data unit, the fragmentation mechanism is not used and the packet is sent unfragmented. Otherwise, the datagram does not fit a single L2 data unit, it SHALL be broken into fragments.
Moreover, LPWAN technologies impose some strict limitations on traffic; therefore it is desirable to enable optional fragment retransmission, while a single fragment loss should not lead to retransmitting the full datagram. On the other hand, in order to preserve energy, Devices are sleeping most of the time and may receive data during a short period of time after transmission. In order to adapt to the capabilities of various LPWAN technologies, this specification allows a gradation of fragment delivery reliability. This document does not make any decision with regard to which fragment delivery reliability option was used over a specific LPWAN technology.
An important consideration is that LPWAN networks typically follow the star topology, and therefore data unit reordering is not expected in such networks. This specification assumes that reordering will not happen between the entity performing fragmentation and the entity performing reassembly. This assumption allows to reduce complexity and overhead of the fragmentation mechanism.
This specification defines the following three fragment delivery reliability options:
o No ACK
o Window mode - ACK “always”
o Window mode - ACK on error
The same reliability option MUST be used for all fragments of a packet. It is up to implementers and/or representatives of the underlying LPWAN technology to decide which reliability option to use and whether the same reliability option applies to all IPv6 packets or not. Note that the reliability option to be used is not necessarily tied to the particular characteristics of the underlying L2 LPWAN technology (e.g. the No ACK reliability option may be used on top of an L2 LPWAN technology with symmetric characteristics for uplink and downlink).
In the No ACK option, the receiver MUST NOT issue acknowledgments (ACK).
In Window mode – ACK “always”, an ACK is transmitted by the fragment receiver after a window of fragments have been sent. A window of fragments is a subset of the full set of fragments needed to carry an IPv6 packet. In this mode, the ACK informs the sender about received and/or missed fragments from the window of fragments. Upon receipt of an ACK that informs about any lost fragments, the sender retransmits the lost fragments. When an ACK is not received by the fragment sender, the latter retransmits a fragment, which serves as an ACK request. The maximum number of ACK requests is MAX_ACK_REQUESTS. The default value of MAX_ACK_REQUESTS is not stated in this document, and it is expected to be defined in other documents (e.g. technology- specific profiles).
In Window mode – ACK on error, an ACK is transmitted by the fragment receiver after a window of fragments have been sent, only if at least one of the fragments in the window has been lost. In this mode, the ACK informs the sender about received and/or missed fragments from the window of fragments. Upon receipt of an ACK that informs about any lost fragments, the sender retransmits the lost fragments. The maximum number of ACKs to be sent by the receiver for a specific window, denoted MAX_ACKS_PER_WINDOW, is not stated in this document, and it is expected to be defined in other documents (e.g. technology- specific profiles).
This document does not make any decision as to which fragment delivery reliability option(s) are supported by a specific LPWAN technology.
Examples of the different reliability options described are provided in Appendix A.
This section discusses the properties of each fragment delivery reliability option defined in the previous section.
No ACK is the most simple fragment delivery reliability option. With this option, the receiver does not generate overhead in the form of ACKs. However, this option does not enhance delivery reliability beyond that offered by the underlying LPWAN technology.
The Window mode - ACK on error option is based on the optimistic expectation that the underlying links will offer relatively low L2 data unit loss probability. This option reduces the number of ACKs transmitted by the fragment receiver compared to the Window mode - ACK “always” option. This may be specially beneficial in asymmetric scenarios, e.g. where fragmented data are sent uplink and the underlying LPWAN technology downlink capacity or message rate is lower than the uplink one. However, if an ACK is lost, the sender assumes that all fragments covered by the ACK have been successfully delivered. In contrast, the Window mode - ACK “always” option does not suffer that issue, at the expense of an ACK overhead increase.
The Window mode – ACK “always” option provides flow control. In addition, it is able to handle long bursts of lost fragments, since detection of such events can be done before end of the IPv6 packet transmission, as long as the window size is short enough. However, such benefit comes at the expense of higher ACK overhead.
This subsection describes the different tools that are used to enable the described fragmentation functionality and the different reliability options supported. Each tool has a corresponding header field format that is defined in the next subsection. The list of tools follows:
o Rule ID. The Rule ID is used in fragments and in ACKs. The Rule ID in a fragment is set to a value that indicates that the data unit being carried is a fragment. This also allows to interleave non-fragmented IPv6 datagrams with fragments that carry a larger IPv6 datagram. Rule ID may also be used to signal which reliability option is in use for the IPv6 packet being carried. Rule ID may also be used to signal the window size if multiple sizes are supported (see 9.7). In an ACK, the Rule ID signals that the message this Rule ID is prepended to is an ACK.
o Fragment Compressed Number (FCN). The FCN is included in all fragments. This field can be understood as a truncated, efficient representation of a larger-sized fragment number, and does not carry an absolute fragment number. A special FCN value denotes the last fragment that carries a fragmented IPv6 packet. In Window mode, the FCN is augmented with the W bit, which has the purpose of avoiding possible ambiguity for the receiver that might arise under certain conditions.
o Datagram Tag (DTag). The DTag field, if present, is set to the same value for all fragments carrying the same IPv6 datagram, allows to interleave fragments that correspond to different IPv6 datagrams.
o Message Integrity Check (MIC). It is computed by the sender over the complete IPv6 packet before fragmentation by using the TBD algorithm. The MIC allows the receiver to check for errors in the reassembled IPv6 packet, while it also enables compressing the UDP checksum by use of SCHC.
o Bitmap. The bitmap is a sequence of bits included in the ACK for a given window, that provides feedback on whether each fragment of the current window has been received or not.
This section defines the fragment format, the fragmentation header formats, and the ACK format.
A fragment comprises a fragmentation header and a fragment payload, and conforms to the format shown in Figure 6. The fragment payload carries a subset of either an IPv6 packet after header compression or an IPv6 packet which could not be compressed. A fragment is the payload in the L2 protocol data unit (PDU).
+---------------+-----------------------+
| Fragm. Header | Fragment payload |
+---------------+-----------------------+
Figure 6: Fragment format.
In the No ACK option, fragments except the last one SHALL contain the fragmentation header as defined in Figure 7. The total size of this fragmentation header is R bits.
<------------ R ---------->
<--T--> <--N-->
+-- ... --+- ... -+- ... -+
| Rule ID | DTag | FCN |
+-- ... --+- ... -+- ... -+
Figure 7: Fragmentation Header for Fragments except the Last One, No ACK option
In any of the Window mode options, fragments except the last one SHALL
contain the fragmentation header as defined in Figure 8. The total size of this fragmentation header is R bits.
<------------ R ---------->
<--T--> 1 <--N-->
+-- ... --+- ... -+-+- ... -+
| Rule ID | DTag |W| FCN |
+-- ... --+- ... -+-+- ... -+
Figure 8: Fragmentation Header for Fragments except the Last One, Window mode
In the No ACK option, the last fragment of an IPv6 datagram SHALL contain a fragmentation header that conforms to the format shown in Figure 9. The total size of this fragmentation header is R+M bits.
<------------- R ------------>
<- T -> <- N -> <---- M ----->
+---- ... ---+- ... -+- ... -+---- ... ----+
| Rule ID | DTag | 11..1 | MIC |
+---- ... ---+- ... -+- ... -+---- ... ----+
Figure 9: Fragmentation Header for the Last Fragment, No ACK option
In any of the Window modes, the last fragment of an IPv6 datagram SHALL contain a fragmentation header that conforms to the format shown in Figure 10. The total size of this fragmentation header is R+M bits.
<------------ R ------------>
<- T -> 1 <- N -> <---- M ----->
+-- ... --+- ... -+-+- ... -+---- ... ----+
| Rule ID | DTag |W| 11..1 | MIC |
+-- ... --+- ... -+-+- ... -+---- ... ----+
Figure 10: Fragmentation Header for the Last Fragment, Window mode
The values for R, N, MAX_WIND_FCN, T and M are not specified in this document, and have to be determined in other documents (e.g. technology-specific profile documents).
The format of an ACK is shown in Figure 11:
<-------- R ------->
<- T -> 1
+---- ... --+-... -+-+----- ... ---+
| Rule ID | DTag |W| bitmap |
+---- ... --+-... -+-+----- ... ---+
Figure 11: Format of an ACK
Rule ID: In all ACKs, Rule ID has a size of R - T - 1 bits.
DTag: DTag has a size of T bits. DTag carries the same value as the DTag field in the fragments carrying the IPv6 datagram for which this ACK is intended.
W: This field has a size of 1 bit. In all ACKs, the W bit carries the same value as the W bit carried by the fragments whose reception is being positively or negatively acknowledged by the ACK.
bitmap: This field carries the bitmap sent by the receiver to inform the sender about whether fragments in the current window have been received or not. Size of the bitmap field of an ACK can be equal to 0 or Ceiling(Number_of_Fragments/8) octets, where Number_of_Fragments denotes the number of fragments of a window. The bitmap is a sequence of bits, where the n-th bit signals whether the n-th fragment transmitted in the current window has been correctly received (n-th bit set to 1) or not (n-th bit set to 0). Remaining bits with bit order greater than the number of fragments sent (as determined by the receiver) are set to 0, except for the last bit in the bitmap, which is set to 1 if the last fragment of the window has been correctly received, and 0 otherwise. Feedback on reception of the fragment with FCN = 2^N - 1 (last fragment carrying an IPv6 packet) is only given by the last bit of the corresponding bitmap. Absence of the bitmap in an ACK confirms correct reception of all fragments to be acknowledged by means of the ACK. Note that absence of the bitmap in an ACK may be determined based on the size of the L2 payload.
Figure 12 shows an example of an ACK (N=3), where the bitmap indicates that the second and the fifth fragments have not been correctly received.
<------- R ------->
<- T -> 0 1 2 3 4 5 6 7
+---- ... --+-... -+-+-+-+-+-+-+-+-+-+
| Rule ID | DTag |W|1|0|1|1|0|1|1|1|
+---- ... --+-... -+-+-+-+-+-+-+-+-+-+
Figure 12: Example of the bitmap in an ACK (in Window mode, for N=3)
Figure 13 illustrates an ACK without a bitmap.
<------- R ------->
<- T ->
+---- ... --+-... -+-+
| Rule ID | DTag |W|
+---- ... --+-... -+-+
Figure 13: Example of an ACK without a bitmap
Note that, in order to exploit the available L2 payload space to the fullest, a bitmap may have a size smaller than 2^N bits. In that case, the window in use will have a size lower than 2^N-1 fragments. For example, if the maximum available space for a bitmap is 56 bits, N can be set to 6, and the window size can be set to a maximum of 56 fragments, thus MAX_WIND_FCN will be equal to 55 in this example.
The receiver of link fragments SHALL use (1) the sender’s L2 source address (if present), (2) the destination’s L2 address (if present), (3) Rule ID and (4) DTag (the latter, if present) to identify all the fragments that belong to a given IPv6 datagram. The fragment receiver may determine the fragment delivery reliability option in use for the fragment based on the Rule ID field in that fragment.
Upon receipt of a link fragment, the receiver starts constructing the original unfragmented packet. It uses the FCN and the order of arrival of each fragment to determine the location of the individual fragments within the original unfragmented packet. For example, it may place the data payload of the fragments within a payload datagram reassembly buffer at the location determined from the FCN and order of arrival of the fragments, and the fragment payload sizes. In Window mode, the fragment receiver also uses the W bit in the received fragments. Note that the size of the original, unfragmented IPv6 packet cannot be determined from fragmentation headers.
When Window mode - ACK on error is used, the fragment receiver starts a timer (denoted “ACK on Error Timer”) upon reception of the first fragment for an IPv6 datagram. The initial value for this timer is not provided by this specification, and is expected to be defined in additional documents. This timer is reset and restarted every time that a new fragment carrying data from the same IPv6 datagram is received. In Window mode – ACK on error, after reception of the last fragment of a window (i.e. the fragment with FCN=0 or FCN=2^N-1), if fragment losses have been detected by the fragment receiver in the current window, the fragment receiver MUST transmit an ACK reporting its available information with regard to successfully received and missing fragments from the current window. Upon expiration of the “ACK on Error Timer”, an ACK MUST be transmitted by the fragment receiver to report received and not received fragments for the current window. The “ACK on Error Timer” is then reset and restarted. When the last fragment of the IPv6 datagram is received, if all fragments of that last window of the packet have been received, the “ACK on Error Timer” is stopped. In Window mode – ACK on error, the fragment sender retransmits any lost fragments reported in an ACK. The maximum number of ACKs to be sent by the receiver for a specific window, denoted MAX_ACKS_PER_WINDOW, is not stated in this document, and it is expected to be defined in other documents (e.g. technology-specific profiles). In Window mode – ACK on error, when a fragment sender has transmitted the last fragment of a window, or it has retransmitted the last fragment within the set of lost fragments reported in an ACK, it is assumed that the time the fragment sender will wait to receive an ACK is smaller than the transmission time of MAX_WIND_FCN + 1 fragments (i.e. the time required to transmit a complete window of fragments). This aspect must be carefully considered if Window mode – ACK on error is used, in particular taking into account the latency characteristics of the underlying L2 technology.
Note that, in Window mode, the first fragment of the window is the one with FCN set to MAX_WIND_FCN. Also note that, in Window mode, the fragment with FCN=0 is considered the last fragment of its window, except for the last fragment of the whole packet (with all FCN bits set to 1, i.e. FCN=2^N-1), which is also the last fragment of the last window.
If Window mode - ACK “always” is used, upon receipt of the last fragment of a window (i.e. the fragment with CFN=0 or CFN=2^N-1), or upon receipt of the last retransmitted fragment from the set of lost fragments reported by the last ACK sent by the fragment receiver (if any), the fragment receiver MUST send an ACK to the fragment sender. The ACK provides feedback on the fragments received and those not received that correspond to the last window. Once all fragments of a window have been received by the fragment receiver (including retransmitted fragments, if any), the latter sends an ACK without a bitmap to the sender, in order to report successful reception of all fragments of the window to the fragment sender.
When Window mode - ACK “always” is used, the fragment sender starts a timer (denoted “ACK Always Timer”) after the first transmission attempt of the last fragment of a window (i.e. the fragment with FCN=0 or FCN=2^N-1). In the same reliability option, if one or more fragments are reported by an ACK to be lost, the sender retransmits those fragments and starts the “ACK Always Timer” after the last retransmitted fragment (i.e. the fragment with the lowest FCN) among the set of lost fragments reported by the ACK. The initial value for the “ACK Always Timer” is not provided by this specification, and it is expected to be defined in additional documents. Upon expiration of the timer, if no ACK has been received since the timer start, the next action to be performed by the fragment sender depends on whether the current window is the last window of the IPv6 packet or not. If the current window is not the last one, the sender retransmits the last fragment sent at the moment of timer expiration (which may or may not be the fragment with FCN=0), and it reinitializes and restarts the timer. Otherwise (i.e. the current window is the last one), the sender retransmits the fragment with FCN=2^N-1; if the fragment sender knows that the fragment with FCN=2^N-1 has already been successfully received, the fragment sender MAY opt to send a fragment with FCN=2^N-1 and without a data payload. Note that retransmitting a fragment sent as described serves as an ACK request. The maximum number of requests for a specific ACK, denoted MAX_ACK_REQUESTS, is not stated in this document, and it is expected to be defined in other documents (e.g. technology-specific profiles). In Window mode – ACK “Always”, the fragment sender retransmits any lost fragments reported in an ACK. When the fragment sender receives an ACK that confirms correct reception of all fragments of a window, if there are further fragments to be sent for the same IPv6 datagram, the fragment sender proceeds to transmitting subsequent fragments of the next window.
If the recipient receives the last fragment of an IPv6 datagram (i.e. the fragment with FCN=2^N-1), it checks for the integrity of the reassembled IPv6 datagram, based on the MIC received. In No ACK, if the integrity check indicates that the reassembled IPv6 datagram does not match the original IPv6 datagram (prior to fragmentation), the reassembled IPv6 datagram MUST be discarded. In Window mode, a MIC check is also performed by the fragment receiver after reception of each subsequent fragment retransmitted after the first MIC check. In Window mode – ACK “always”, if a MIC check indicates that the IPv6 datagram has been successfully reassembled, the fragment receiver sends an ACK without a bitmap to the fragment sender. In the same reliability option, after receiving a fragment with FCN=2^N-1, the fragment receiver sends an ACK to the fragment sender, even if it is not the first fragment with FCN=2^N-1 received by the fragment receiver.
If a fragment recipient disassociates from its L2 network, the recipient MUST discard all link fragments of all partially reassembled payload datagrams, and fragment senders MUST discard all not yet transmitted link fragments of all partially transmitted payload (e.g., IPv6) datagrams. Similarly, when either end of the LPWAN link first receives a fragment of a packet, it starts a reassembly timer. When this time expires, if the entire packet has not been reassembled, the existing fragments MUST be discarded and the reassembly state MUST be flushed. The value for this timer is not provided by this specification, and is expected to be defined in technology-specific profile documents.
For Window mode operation, implementers may opt to support a single window size or multiple window sizes. The latter, when feasible, may provide performance optimizations. For example, a large window size may be used for IPv6 packets that need to be carried by a large number of fragments. However, when the number of fragments required to carry an IPv6 packet is low, a smaller window size, and thus a shorter bitmap, may be sufficient to provide feedback on all fragments. If multiple window sizes are supported, the Rule ID may be used to signal the window size in use for a specific IPv6 packet transmission.
For several reasons, a fragment sender or a fragment receiver may want to abort the on-going transmission of one or several fragmented IPv6 datagrams. The entity (either the fragment sender or the fragment receiver) that triggers abortion transmits to the other endpoint a data unit with an L2 payload that only comprises a Rule ID (of size R bits), which signals abortion of all on-going fragmented IPv6 packet transmissions. The specific value to be used for the Rule ID of this abortion signal is not defined in this document, and is expected to be defined in future documents.
Upon transmission or reception of the abortion signal, both entities MUST release any resources allocated for the fragmented IPv6 datagram transmissions being aborted.
In some LPWAN technologies, as part of energy-saving techniques, downlink transmission is only possible immediately after an uplink transmission. In order to avoid potentially high delay for fragmented IPv6 datagram transmission in the downlink, the fragment receiver MAY perform an uplink transmission as soon as possible after reception of a fragment that is not the last one. Such uplink transmission may be triggered by the L2 (e.g. an L2 ACK sent in response to a fragment encapsulated in a L2 frame that requires an L2 ACK) or it may be triggered from an upper layer.
This section lists the different IPv6 and UDP header fields and how they can be compressed.
This field always holds the same value, therefore the TV is 6, the MO is “equal” and the “CDA “not-sent””.
If the DiffServ field identified by the rest of the rule do not vary and is known by both sides, the TV should contain this well-known value, the MO should be “equal” and the CDA must be “not-sent.
If the DiffServ field identified by the rest of the rule varies over time or is not known by both sides, then there are two possibilities depending on the variability of the value, the first one is to do not compressed the field and sends the original value, or the second where the values can be computed by sending only the LSB bits:
If the Flow Label field identified by the rest of the rule does not vary and is known by both sides, the TV should contain this well-known value, the MO should be “equal” and the CDA should be “not-sent”.
If the Flow Label field identified by the rest of the rule varies during time or is not known by both sides, there are two possibilities depending on the variability of the value, the first one is without compression and then the value is sent and the second where only part of the value is sent and the decompressor needs to compute the original value:
If the LPWAN technology does not add padding, this field can be elided for the transmission on the LPWAN network. The SCHC C/D recomputes the original payload length value. The TV is not set, the MO is set to “ignore” and the CDA is “compute-IPv6-length”.
If the payload length needs to be sent and does not need to be coded in 16 bits, the TV can be set to 0x0000, the MO set to “MSB (16-s)” and the CDA to “LSB”. The ‘s’ parameter depends on the expected maximum packet length.
On other cases, the payload length field must be sent and the CDA is replaced by “value-sent”.
If the Next Header field identified by the rest of the rule does not vary and is known by both sides, the TV should contain this Next Header value, the MO should be “equal” and the CDA should be “not-sent”.
If the Next header field identified by the rest of the rule varies during time or is not known by both sides, then TV is not set, MO is set to “ignore” and CDA is set to “value-sent”. A matching-list may also be used.
The End System is generally a device and does not forward packets, therefore the Hop Limit value is constant. So the TV is set with a default value, the MO is set to “equal” and the CDA is set to “not-sent”.
Otherwise the value is sent on the LPWAN: TV is not set, MO is set to ignore and CDA is set to “value-sent”.
Note that the field behavior differs in upstream and downstream. In upstream, since there is no IP forwarding between the Dev and the SCHC C/D, the value is relatively constant. On the other hand, the downstream value depends of Internet routing and may change more frequently. One solution could be to use the Direction Indicator (DI) to distinguish both directions to elide the field in the upstream direction and send the value in the downstream direction.
As in 6LoWPAN [RFC4944], IPv6 addresses are split into two 64-bit long fields; one for the prefix and one for the Interface Identifier (IID). These fields should be compressed. To allow a single rule, these values are identified by their role (DEV or APP) and not by their position in the frame (source or destination). The SCHC C/D must be aware of the traffic direction (upstream, downstream) to select the appropriate field.
Both ends must be synchronized with the appropriate prefixes. For a specific flow, the source and destination prefix can be unique and stored in the context. It can be either a link-local prefix or a global prefix. In that case, the TV for the source and destination prefixes contains the values, the MO is set to “equal” and the CDA is set to “not-sent”.
In case the rule allows several prefixes, mapping-list must be used. The different prefixes are listed in the TV associated with a short ID. The MO is set to “match-mapping” and the CDA is set to “mapping-sent”.
Otherwise the TV contains the prefix, the MO is set to “equal” and the CDA is set to value-sent.
If the DEV or APP IID are based on an LPWAN address, then the IID can be reconstructed with information coming from the LPWAN header. In that case, the TV is not set, the MO is set to “ignore” and the CDA is set to “DEViid” or “APPiid”. Note that the LPWAN technology is generally carrying a single device identifier corresponding to the DEV. The SCHC C/D may also not be aware of these values.
If the DEV address has a static value that is not derived from an IEEE EUI-64, then TV contains the actual Dev address value, the MO operator is set to “equal” and the CDA is set to “not-sent”.
If several IIDs are possible, then the TV contains the list of possible IIDs, the MO is set to “match-mapping” and the CDA is set to “mapping-sent”.
Otherwise the value variation of the IID may be reduced to few bytes. In that case, the TV is set to the stable part of the IID, the MO is set to MSB and the CDA is set to LSB.
Finally, the IID can be sent on the LPWAN. In that case, the TV is not set, the MO is set to “ignore” and the CDA is set to “value-sent”.
No extension rules are currently defined. They can be based on the MOs and CDAs described above.
To allow a single rule, the UDP port values are identified by their role (DEV or APP) and not by their position in the frame (source or destination). The SCHC C/D must be aware of the traffic direction (upstream, downstream) to select the appropriate field. The following rules apply for DEV and APP port numbers.
If both ends know the port number, it can be elided. The TV contains the port number, the MO is set to “equal” and the CDA is set to “not-sent”.
If the port variation is on few bits, the TV contains the stable part of the port number, the MO is set to “MSB” and the CDA is set to “LSB”.
If some well-known values are used, the TV can contain the list of this values, the MO is set to “match-mapping” and the CDA is set to “mapping-sent”.
Otherwise the port numbers are sent on the LPWAN. The TV is not set, the MO is set to “ignore” and the CDA is set to “value-sent”.
If the LPWAN technology does not introduce padding, the UDP length can be computed from the received data. In that case the TV is not set, the MO is set to “ignore” and the CDA is set to “compute-UDP-length”.
If the payload is small, the TV can be set to 0x0000, the MO set to “MSB” and the CDA to “LSB”.
On other cases, the length must be sent and the CDA is replaced by “value-sent”.
IPv6 mandates a checksum in the protocol above IP. Nevertheless, if a more efficient mechanism such as L2 CRC or MIC is carried by or over the L2 (such as in the LPWAN fragmentation process (see section Section 5)), the UDP checksum transmission can be avoided. In that case, the TV is not set, the MO is set to “ignore” and the CDA is set to “compute-UDP-checksum”.
In other cases the checksum must be explicitly sent. The TV is not set, the MO is set to “ignore” and the CDF is set to “value-sent”.
A malicious header compression could cause the reconstruction of a wrong packet that does not match with the original one, such corruption may be detected with end-to-end authentication and integrity mechanisms. Denial of Service may be produced but its arise other security problems that may be solved with or without header compression.
This subsection describes potential attacks to LPWAN fragmentation and suggests possible countermeasures.
A node can perform a buffer reservation attack by sending a first fragment to a target. Then, the receiver will reserve buffer space for the IPv6 packet. Other incoming fragmented packets will be dropped while the reassembly buffer is occupied during the reassembly timeout. Once that timeout expires, the attacker can repeat the same procedure, and iterate, thus creating a denial of service attack. The (low) cost to mount this attack is linear with the number of buffers at the target node. However, the cost for an attacker can be increased if individual fragments of multiple packets can be stored in the reassembly buffer. To further increase the attack cost, the reassembly buffer can be split into fragment-sized buffer slots. Once a packet is complete, it is processed normally. If buffer overload occurs, a receiver can discard packets based on the sender behavior, which may help identify which fragments have been sent by an attacker.
In another type of attack, the malicious node is required to have overhearing capabilities. If an attacker can overhear a fragment, it can send a spoofed duplicate (e.g. with random payload) to the destination. If the LPWAN technology does not support suitable protection (e.g. source authentication and frame counters to prevent replay attacks), a receiver cannot distinguish legitimate from spoofed fragments. Therefore, the original IPv6 packet will be considered corrupt and will be dropped. To protect resource-constrained nodes from this attack, it has been proposed to establish a binding among the fragments to be transmitted by a node, by applying content-chaining to the different fragments, based on cryptographic hash functionality. The aim of this technique is to allow a receiver to identify illegitimate fragments.
Further attacks may involve sending overlapped fragments (i.e. comprising some overlapping parts of the original IPv6 datagram). Implementers should make sure that correct operation is not affected by such event.
Thanks to Dominique Barthel, Carsten Bormann, Philippe Clavier, Arunprabhu Kandasamy, Antony Markovski, Alexander Pelov, Pascal Thubert, Juan Carlos Zuniga and Diego Dujovne for useful design consideration and comments.
| [RFC2460] | Deering, S. and R. Hinden, "Internet Protocol, Version 6 (IPv6) Specification", RFC 2460, DOI 10.17487/RFC2460, December 1998. |
| [RFC4944] | Montenegro, G., Kushalnagar, N., Hui, J. and D. Culler, "Transmission of IPv6 Packets over IEEE 802.15.4 Networks", RFC 4944, DOI 10.17487/RFC4944, September 2007. |
| [RFC5795] | Sandlund, K., Pelletier, G. and L-E. Jonsson, "The RObust Header Compression (ROHC) Framework", RFC 5795, DOI 10.17487/RFC5795, March 2010. |
| [RFC7136] | Carpenter, B. and S. Jiang, "Significance of IPv6 Interface Identifiers", RFC 7136, DOI 10.17487/RFC7136, February 2014. |
| [I-D.ietf-lpwan-overview] | Farrell, S., "LPWAN Overview", Internet-Draft draft-ietf-lpwan-overview-06, July 2017. |
This section gives some scenarios of the compression mechanism for IPv6/UDP. The goal is to illustrate the SCHC behavior.
The most common case using the mechanisms defined in this document will be a LPWAN Dev that embeds some applications running over CoAP. In this example, three flows are considered. The first flow is for the device management based on CoAP using Link Local IPv6 addresses and UDP ports 123 and 124 for Dev and App, respectively. The second flow will be a CoAP server for measurements done by the Device (using ports 5683) and Global IPv6 Address prefixes alpha::IID/64 to beta::1/64. The last flow is for legacy applications using different ports numbers, the destination IPv6 address prefix is gamma::1/64.
Figure 14 presents the protocol stack for this Device. IPv6 and UDP are represented with dotted lines since these protocols are compressed on the radio link.
Management Data
+----------+---------+---------+
| CoAP | CoAP | legacy |
+----||----+---||----+---||----+
. UDP . UDP | UDP |
................................
. IPv6 . IPv6 . IPv6 .
+------------------------------+
| SCHC Header compression |
| and fragmentation |
+------------------------------+
| LPWAN L2 technologies |
+------------------------------+
DEV or NGW
Figure 14: Simplified Protocol Stack for LP-WAN
Note that in some LPWAN technologies, only the Devs have a device ID. Therefore, when such technologies are used, it is necessary to define statically an IID for the Link Local address for the SCHC C/D.
Rule 0 +----------------+--+--+---------+--------+-------------++------+ | Field |FP|DI| Value | Match | Comp Decomp || Sent | | | | | | Opera. | Action ||[bits]| +----------------+--+--+---------+----------------------++------+ |IPv6 version |1 |Bi|6 | equal | not-sent || | |IPv6 DiffServ |1 |Bi|0 | equal | not-sent || | |IPv6 Flow Label |1 |Bi|0 | equal | not-sent || | |IPv6 Length |1 |Bi| | ignore | comp-length || | |IPv6 Next Header|1 |Bi|17 | equal | not-sent || | |IPv6 Hop Limit |1 |Bi|255 | ignore | not-sent || | |IPv6 DEVprefix |1 |Bi|FE80::/64| equal | not-sent || | |IPv6 DEViid |1 |Bi| | ignore | DEViid || | |IPv6 APPprefix |1 |Bi|FE80::/64| equal | not-sent || | |IPv6 APPiid |1 |Bi|::1 | equal | not-sent || | +================+==+==+=========+========+=============++======+ |UDP DEVport |1 |Bi|123 | equal | not-sent || | |UDP APPport |1 |Bi|124 | equal | not-sent || | |UDP Length |1 |Bi| | ignore | comp-length || | |UDP checksum |1 |Bi| | ignore | comp-chk || | +================+==+==+=========+========+=============++======+ Rule 1 +----------------+--+--+---------+--------+-------------++------+ | Field |FP|DI| Value | Match | Action || Sent | | | | | | Opera. | Action ||[bits]| +----------------+--+--+---------+--------+-------------++------+ |IPv6 version |1 |Bi|6 | equal | not-sent || | |IPv6 DiffServ |1 |Bi|0 | equal | not-sent || | |IPv6 Flow Label |1 |Bi|0 | equal | not-sent || | |IPv6 Length |1 |Bi| | ignore | comp-length || | |IPv6 Next Header|1 |Bi|17 | equal | not-sent || | |IPv6 Hop Limit |1 |Bi|255 | ignore | not-sent || | |IPv6 DEVprefix |1 |Bi|[alpha/64, match- | mapping-sent|| [1] | | |1 |Bi|fe80::/64] mapping| || | |IPv6 DEViid |1 |Bi| | ignore | DEViid || | |IPv6 APPprefix |1 |Bi|[beta/64,| match- | mapping-sent|| [2] | | | | |alpha/64,| mapping| || | | | | |fe80::64]| | || | |IPv6 APPiid |1 |Bi|::1000 | equal | not-sent || | +================+==+==+=========+========+=============++======+ |UDP DEVport |1 |Bi|5683 | equal | not-sent || | |UDP APPport |1 |Bi|5683 | equal | not-sent || | |UDP Length |1 |Bi| | ignore | comp-length || | |UDP checksum |1 |Bi| | ignore | comp-chk || | +================+==+==+=========+========+=============++======+ Rule 2 +----------------+--+--+---------+--------+-------------++------+ | Field |FP|DI| Value | Match | Action || Sent | | | | | | Opera. | Action ||[bits]| +----------------+--+--+---------+--------+-------------++------+ |IPv6 version |1 |Bi|6 | equal | not-sent || | |IPv6 DiffServ |1 |Bi|0 | equal | not-sent || | |IPv6 Flow Label |1 |Bi|0 | equal | not-sent || | |IPv6 Length |1 |Bi| | ignore | comp-length || | |IPv6 Next Header|1 |Bi|17 | equal | not-sent || | |IPv6 Hop Limit |1 |Up|255 | ignore | not-sent || | |IPv6 Hop Limit |1 |Dw| | ignore | value-sent || [8] | |IPv6 DEVprefix |1 |Bi|alpha/64 | equal | not-sent || | |IPv6 DEViid |1 |Bi| | ignore | DEViid || | |IPv6 APPprefix |1 |Bi|gamma/64 | equal | not-sent || | |IPv6 APPiid |1 |Bi|::1000 | equal | not-sent || | +================+==+==+=========+========+=============++======+ |UDP DEVport |1 |Bi|8720 | MSB(12)| LSB(4) || [4] | |UDP APPport |1 |Bi|8720 | MSB(12)| LSB(4) || [4] | |UDP Length |1 |Bi| | ignore | comp-length || | |UDP checksum |1 |Bi| | ignore | comp-chk || | +================+==+==+=========+========+=============++======+
Figure 15: Context rules
All the fields described in the three rules depicted on Figure 15 are present in the IPv6 and UDP headers. The DEViid-DID value is found in the L2 header.
The second and third rules use global addresses. The way the Dev learns the prefix is not in the scope of the document.
The third rule compresses port numbers to 4 bits.
This section provides examples of different fragment delivery reliability options possible on the basis of this specification.
Figure 16 illustrates the transmission of an IPv6 packet that needs 11 fragments in the No ACK option.
Sender Receiver
|-------FCN=0-------->|
|-------FCN=0-------->|
|-------FCN=0-------->|
|-------FCN=0-------->|
|-------FCN=0-------->|
|-------FCN=0-------->|
|-------FCN=0-------->|
|-------FCN=0-------->|
|-------FCN=0-------->|
|-------FCN=0-------->|
|-------FCN=1-------->|MIC checked =>
Figure 16: Transmission of an IPv6 packet carried by 11 fragments in the No ACK option
Figure 17 illustrates the transmission of an IPv6 packet that needs 11 fragments in Window mode - ACK on error, for N=3, without losses.
Sender Receiver
|-----W=1, FCN=6----->|
|-----W=1, FCN=5----->|
|-----W=1, FCN=4----->|
|-----W=1, FCN=3----->|
|-----W=1, FCN=2----->|
|-----W=1, FCN=1----->|
|-----W=1, FCN=0----->|
(no ACK)
|-----W=0, FCN=6----->|
|-----W=0, FCN=5----->|
|-----W=0, FCN=4----->|
|-----W=0, FCN=7----->|MIC checked =>
(no ACK)
Figure 17: Transmission of an IPv6 packet carried by 11 fragments in Window mode - ACK on error, for N=3 and MAX_WIND_FCN=6, without losses.
Figure 18 illustrates the transmission of an IPv6 packet that needs 11 fragments in Window mode - ACK on error, for N=3, with three losses.
Sender Receiver
|-----W=1, FCN=6----->|
|-----W=1, FCN=5----->|
|-----W=1, FCN=4--X-->|
|-----W=1, FCN=3----->|
|-----W=1, FCN=2--X-->|
|-----W=1, FCN=1----->|
|-----W=1, FCN=0----->|
|<-----ACK, W=1-------|Bitmap:11010111
|-----W=1, FCN=4----->|
|-----W=1, FCN=2----->|
(no ACK)
|-----W=0, FCN=6----->|
|-----W=0, FCN=5----->|
|-----W=0, FCN=4--X-->|
|-----W=0, FCN=7----->|MIC checked
|<-----ACK, W=0-------|Bitmap:11000001
|-----W=0, FCN=4----->|MIC checked =>
(no ACK)
Figure 18: Transmission of an IPv6 packet carried by 11 fragments in Window mode - ACK on error, for N=3 and MAX_WIND_FCN=6, three losses.
Figure 19 illustrates the transmission of an IPv6 packet that needs 11 fragments in Window mode - ACK “always”, for N=3 and MAX_WIND_FCN=6, without losses. Note: in Window mode, an additional bit will be needed to number windows.
Sender Receiver
|-----W=1, FCN=6----->|
|-----W=1, FCN=5----->|
|-----W=1, FCN=4----->|
|-----W=1, FCN=3----->|
|-----W=1, FCN=2----->|
|-----W=1, FCN=1----->|
|-----W=1, FCN=0----->|
|<-----ACK, W=1-------|no bitmap
|-----W=0, FCN=6----->|
|-----W=0, FCN=5----->|
|-----W=0, FCN=4----->|
|-----W=0, FCN=7----->|MIC checked =>
|<-----ACK, W=0-------|no bitmap
(End)
Figure 19: Transmission of an IPv6 packet carried by 11 fragments in Window mode - ACK "always", for N=3 and MAX_WIND_FCN=6, no losses.
Figure 20 illustrates the transmission of an IPv6 packet that needs 11 fragments in Window mode - ACK “always”, for N=3 and MAX_WIND_FCN=6, with three losses.
Sender Receiver
|-----W=1, FCN=6----->|
|-----W=1, FCN=5----->|
|-----W=1, FCN=4--X-->|
|-----W=1, FCN=3----->|
|-----W=1, FCN=2--X-->|
|-----W=1, FCN=1----->|
|-----W=1, FCN=0----->|
|<-----ACK, W=1-------|bitmap:11010111
|-----W=1, FCN=4----->|
|-----W=1, FCN=2----->|
|<-----ACK, W=1-------|no bitmap
|-----W=0, FCN=6----->|
|-----W=0, FCN=5----->|
|-----W=0, FCN=4--X-->|
|-----W=0, FCN=7----->|MIC checked
|<-----ACK, W=0-------|bitmap:11000001
|-----W=0, FCN=4----->|MIC checked =>
|<-----ACK, W=0-------|no bitmap
(End)
Figure 20: Transmission of an IPv6 packet carried by 11 fragments in Window mode - ACK "Always", for N=3, and MAX_WIND_FCN=6, with three losses.
Appendix C illustrates the transmission of an IPv6 packet that needs 28 fragments in Window mode - ACK “always”, for N=5 and MAX_WIND_FCN=23, with two losses. Note that MAX_WIND_FCN=23 may be useful when the maximum possible bitmap size, considering the maximum lower layer technology payload size and the value of R, is 3 bytes. Note also that the FCN of the last fragment of the packet is the one with FCN=31 (i.e. FCN=2^N-1 for N=5, or equivalently, all FCN bits set to 1).
Sender Receiver
|-----W=1, CFN=23----->|
|-----W=1, CFN=22----->|
|-----W=1, CFN=21--X-->|
|-----W=1, CFN=20----->|
|-----W=1, CFN=19----->|
|-----W=1, CFN=18----->|
|-----W=1, CFN=17----->|
|-----W=1, CFN=16----->|
|-----W=1, CFN=15----->|
|-----W=1, CFN=14----->|
|-----W=1, CFN=13----->|
|-----W=1, CFN=12----->|
|-----W=1, CFN=11----->|
|-----W=1, CFN=10--X-->|
|-----W=1, CFN=9 ----->|
|-----W=1, CFN=8 ----->|
|-----W=1, CFN=7 ----->|
|-----W=1, CFN=6 ----->|
|-----W=1, CFN=5 ----->|
|-----W=1, CFN=4 ----->|
|-----W=1, CFN=3 ----->|
|-----W=1, CFN=2 ----->|
|-----W=1, CFN=1 ----->|
|-----W=1, CFN=0 ----->|
|<------ACK, W=1-------|bitmap:110111111111101111111111
|-----W=1, CFN=21----->|
|-----W=1, CFN=10----->|
|<------ACK, W=1-------|no bitmap
|-----W=0, CFN=23----->|
|-----W=0, CFN=22----->|
|-----W=0, CFN=21----->|
|-----W=0, CFN=31----->|MIC checked =>
|<------ACK, W=0-------|no bitmap
(End)
A set of Rule IDs are allocated to support different aspects of fragmentation functionality as per this document. The allocation of IDs is to be defined in other documents. The set MAY include:
Carles Gomez has been funded in part by the Spanish Government (Ministerio de Educacion, Cultura y Deporte) through the Jose Castillejo grant CAS15/00336, and by the ERDF and the Spanish Government through project TEC2016-79988-P. Part of his contribution to this work has been carried out during his stay as a visiting scholar at the Computer Laboratory of the University of Cambridge.