Rfc | 4326 |
Title | Unidirectional Lightweight Encapsulation (ULE) for Transmission of
IP Datagrams over an MPEG-2 Transport Stream (TS) |
Author | G. Fairhurst, B.
Collini-Nocker |
Date | December 2005 |
Format: | TXT, HTML |
Updated by | RFC7280 |
Status: | PROPOSED STANDARD |
|
Network Working Group G. Fairhurst
Request for Comments: 4326 University of Aberdeen
Category: Standards Track B. Collini-Nocker
University of Salzburg
December 2005
Unidirectional Lightweight Encapsulation (ULE) for
Transmission of IP Datagrams over an MPEG-2 Transport Stream (TS)
Status of This Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2005).
Abstract
The MPEG-2 Transport Stream (TS) has been widely accepted not only
for providing digital TV services, but also as a subnetwork
technology for building IP networks.
This document describes a Unidirectional Lightweight Encapsulation
(ULE) mechanism for the transport of IPv4 and IPv6 Datagrams and
other network protocol packets directly over the ISO MPEG-2 Transport
Stream as TS Private Data. ULE specifies a base encapsulation format
and supports an extension format that allows it to carry additional
header information to assist in network/Receiver processing.
Table of Contents
1. Introduction ....................................................3
2. Conventions Used in This Document ...............................4
3. Description of the Method .......................................8
4. SNDU Format .....................................................9
4.1. Destination Address Absent (D) Field ......................10
4.2. Length Field ..............................................10
4.3. End Indicator .............................................10
4.4. Type Field ................................................10
4.4.1. Type 1: Next-Header Type Fields ....................11
4.4.2. Type 2: EtherType Compatible Type Fields ...........11
4.5. SNDU Destination Address Field ............................12
4.6. SNDU Trailer CRC ..........................................12
4.7. Description of SNDU Formats ...............................13
4.7.1. End Indicator ......................................14
4.7.2. IPv4 SNDU Encapsulation ............................14
4.7.3. IPv6 SNDU Encapsulation ............................15
5. Extension Headers ..............................................16
5.1. Test SNDU .................................................18
5.2. Bridged Frame SNDU Encapsulation ..........................18
5.3. Extension-Padding Optional Extension Header ...............21
6. Processing at the Encapsulator .................................22
6.1. SNDU Encapsulation ........................................22
6.2. Procedure for Padding and Packing .........................24
7. Receiver Processing ............................................25
7.1. Idle State ................................................26
7.1.1. Idle State Payload Pointer Checking ................26
7.2. Processing of a Received SNDU .............................26
7.2.1. Reassembly Payload Pointer Checking ................28
7.3. Other Error Conditions ....................................28
8. Summary ........................................................29
9. Acknowledgements ...............................................29
10. Security Considerations .......................................29
11. IANA Considerations ...........................................30
11.1. IANA Guidelines ..........................................30
12. References ....................................................31
12.1. Normative References .....................................31
12.2. Informative References ...................................32
Appendix A. SNDU Packing Examples .................................35
Appendix B. SNDU Encapsulation ....................................40
1. Introduction
This document describes an encapsulation for the transport of IP
datagrams, or other network-layer packets, over ISO MPEG-2 Transport
Streams [ISO-MPEG2, RFC4259]. The encapsulation satisfies the
requirement for a lightweight encapsulation defined in section 4 of
[RFC4259]. The basic header provides the required set of protocol
fields. Extension headers may also be defined. This header
structure is significantly simpler to parse and process [SOOR05] than
current alternative methods (e.g., MPE [ETSI-DAT], which builds upon
the DSM-CC Table Section syntax [ISO-DSMCC]).
The encapsulation is suited to services based on MPEG-2; for example,
the Digital Video Broadcast (DVB) architecture, the Advanced
Television Systems Committee (ATSC) system [ATSC, ATSC-G], and other
similar MPEG-2-based transmission systems. Such systems provide
unidirectional (simplex) physical and link-layer standards. Support
has been defined for a wide range of physical media (e.g.,
Terrestrial TV [ETSI-DVBT, ATSC-PSIP-TC], Satellite TV [ETSI-DVBS,
ATSC-S], and Cable Transmission [ETSI-DVBC, ATSC-PSIP-TC]).
Bi-directional (duplex) links may also be established using these
standards (e.g., DVB defines a range of return channel technologies,
including the use of two-way satellite links [ETSI-RCS]) and dial-up
modem links [RFC3077].
Protocol Data Units (PDUs), such as Ethernet Frames, IP datagrams, or
other network-layer packets, used for transmission over an MPEG-2
Transport Multiplex are passed to an Encapsulator. This formats each
PDU into a SubNetwork Data Unit (SNDU) by adding an encapsulation
header and an integrity check trailer. The SNDU is fragmented into a
series of one or more MPEG-2 Transport Stream (TS) Packets that are
sent over a single TS Logical Channel.
The MPEG-2 specification [ISO-MPEG2] requires that conformant TS
Multiplexes provide Program Specific Information (PSI) for each
stream in the TS Multiplex. Other MPEG-2-based transmission
standards may also define Service Information (SI).
A format_identifier value has been registered for ULE [ULE1]. This
32 bit number has a hexadecimal value of 0x554C4531. Transport
Streams that utilise the Programme Map Table (PMT) defined in ISO
13818-1 [ISO-MPEG2] and that use the ULE format defined in this
document, SHOULD insert a descriptor with this value in the PMT
ES_info descriptor loop. ULE Streams may also be identified by the
stream_type value of 0x91 [ATSC-REG] in a SI/PSI Table [ISO_MPEG2].
This information may allow Receivers and Re-multiplexors [RFC4259] to
locate a specific ULE Stream (i.e., the PID value of the TS Logical
Channel that carries a ULE Stream). The conditions under which this
information is required and the format in which it is to be provided
are beyond the scope of this document. Addressing and mapping issues
for ULE over MPEG-2 are also described in [IPDVB-AR].
2. Conventions Used in This Document
The capitalized key words "MUST", "MUST NOT", "REQUIRED", "SHALL",
"SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in
[RFC2119].
Other terms used in this document are defined below:
Adaptation Field: An optional variable-length extension field of the
fixed-length TS Packet header, intended to convey clock references
and timing and synchronization information as well as stuffing over
an MPEG-2 Multiplex [ISO-MPEG2].
AFC: Adaptation Field Control [ISO-MPEG2]. A pair of bits carried in
the TS Packet header that signal the presence of the Adaptation Field
and/or TS Packet payload.
ATSC: Advanced Television Systems Committee [ATSC]. A framework and
a set of associated standards for the transmission of video, audio,
and data using the ISO MPEG-2 standard.
b: bit. For example, one byte consists of 8b.
B: Byte. Groups of bytes are represented in Internet byte order.
DSM-CC: Digital Storage Media Command and Control [ISO-DSMCC]. A
format for transmission of data and control information in an MPEG-2
Private Section, defined by the ISO MPEG-2 standard.
DVB: Digital Video Broadcast. A framework and set of associated
standards published by the European Telecommunications Standards
Institute (ETSI) (e.g., [ETSI-DVBC, ETSI-DVBS, ETSI-DVBT]) for the
transmission of video, audio, and data using the ISO MPEG-2 Standard
[ISO-MPEG2].
Encapsulator: A network device that receives PDUs and formats these
into Payload Units (known here as SNDUs) for output as a stream of TS
Packets.
End Indicator: A value that indicates to the Receiver that there are
no further SNDUs present within the current TS Packet.
LLC: Logical Link Control [ISO-8802-2, IEEE-802.2]. A link-layer
protocol defined by the IEEE 802 standard, which follows the Ethernet
MAC Header.
MAC: Medium Access Control [IEEE-802.3]. A link-layer protocol
defined by the IEEE 802.3 standard (or by Ethernet v2 [DIX]).
MAC Header: The link-layer header of the IEEE 802.3 standard
[IEEE-802.3] or Ethernet v2 [DIX]. It consists of a 6B destination
address, 6B source address, and 2B Type field (see also NPA, LLC).
MPE: Multiprotocol Encapsulation [ETSI-DAT, ATSC-DAT, ATSC-DATG]. A
scheme that encapsulates PDUs, forming a DSM-CC Table Section. Each
Section is sent in a series of TS Packets using a single TS Logical
Channel.
MPEG-2: A set of standards specified by the Motion Picture Experts
Group (MPEG) and standardized by the International Standards
Organisation (ISO/IEC 13818-1) [ISO-MPEG2], and ITU-T (in H.222
[ITU-H222]).
Next-Header: A Type value indicating an Extension Header.
NPA: Network Point of Attachment. In this document, refers to a
6-byte destination address (resembling an IEEE MAC address) within
the MPEG-2 transmission network that is used to identify individual
Receivers or groups of Receivers.
Packing Threshold: A period of time an Encapsulator is willing to
defer transmission of a partially filled TS-Packet to accumulate more
SNDUs, rather than use Padding. After the Packet Threshold period,
the Encapsulator uses Padding to send the partially filled TS-Packet.
Padding: A method that fills the remaining unused bytes in a TS
Packet payload using the specific pattern of 0xFF.
Payload Unit, PU. A sequence of bytes sent using a TS. Examples of
Payload Units include: an MPEG-2 Table Section or a ULE SNDU.
PDU: Protocol Data Unit. Examples of a PDU include Ethernet frames,
IPv4 or IPv6 datagrams, and other network packets.
PES: Packetized Elementary Steam [ISO-MPEG2]. A format of MPEG-2 TS
packet payload usually used for video or audio information.
PID: Packet Identifier [ISO-MPEG2]. A 13-bit field carried in the
header of TS Packets. This is used to identify the TS Logical
Channel to which a TS Packet belongs [ISO-MPEG2]. The TS Packets
forming the parts of a Table Section, PES, or other Payload Unit must
all carry the same PID value. The all-zeros PID 0x0000 as well as
other PID values are reserved for specific PSI/SI Tables [ISO-MPEG2].
The all-ones PID value 0x1FFF indicates a Null TS Packet introduced
to maintain a constant bit rate of a TS Multiplex. There is no
required relationship between the PID values used for TS Logical
Channels transmitted using different TS Multiplexes.
PP: Payload Pointer [ISO-MPEG2]. An optional one-byte pointer that
directly follows the 4-byte TS Packet header. It contains the number
of bytes that follow the Payload Pointer, up to the start of the
first Payload Unit (counted from the first byte of the TS Packet
payload field, and excluding the PP field itself). The presence of
the Payload Pointer is indicated by the value of the PUSI bit in the
TS Packet header. The Payload Pointer is present in DSM-CC, Table
Sections, and ULE. It is not present in TS Logical Channels that use
the PES-format.
Private Section: A syntactic structure constructed in accordance with
Table 2-30 of [ISO-MPEG2]. The structure may be used to identify
private information (i.e., not defined by [ISO-MPEG2]) relating to
one or more elementary streams, or a specific MPEG-2 program, or the
entire Transport Stream. Other Standards bodies, e.g., ETSI, ATSC,
have defined sets of table structures using the private_section
structure. A Private Section is transmitted as a sequence of TS
Packets using a TS Logical Channel. A TS Logical Channel may carry
sections from more than one set of tables.
PSI: Program Specific Information [ISO-MPEG2]. Tables used to convey
information about the service carried in a TS Multiplex. The
information is carried in one of four specifically identified Table
Sections defined by MPEG-2 [ISO-MPEG2]. See also SI Table.
PU: Payload Unit.
PUSI: Payload_Unit_Start_Indicator [ISO-MPEG2]. A single-bit flag
carried in the TS Packet header. A PUSI value of zero indicates that
the TS Packet does not carry the start of a new Payload Unit. A PUSI
value of one indicates that the TS Packet does carry the start of a
new Payload Unit. In ULE, a PUSI bit set to 1 also indicates the
presence of a one-byte Payload Pointer (PP).
Receiver: Equipment that processes the signal from a TS Multiplex and
performs filtering and forwarding of encapsulated PDUs to the
network-layer service (or bridging module when operating at the link
layer).
SI Table: Service Information Table [ISO-MPEG2]. In this document,
this term describes a table that is defined by another standards body
to convey information about the services carried in a TS Multiplex.
A Table may consist of one or more Table Sections; however, all
sections of a particular SI Table must be carried over a single TS
Logical Channel [ISO-MPEG2].
SNDU: SubNetwork Data Unit. An encapsulated PDU sent as an MPEG-2
Payload Unit.
Table Section: A Payload Unit carrying all or part of an SI or PSI
Table [ISO-MPEG2].
TS: Transport Stream [ISO-MPEG2], a method of transmission at the
MPEG-2 level using TS Packets; it represents layer 2 of the ISO/OSI
reference model. See also TS Logical Channel and TS Multiplex.
TS Header: The 4-byte header of a TS Packet [ISO-MPEG2]. Each 188B
TS Packet incorporates a 4B header with the following fields (those
referenced within this document are marked with *):
Field Length Name/Purpose
(in bits)
8b Synchronisation pattern equal to 0x47
*1b Transport Error Indicator
*1b Payload Unit Start Indicator (PUSI)
1b Transport Priority
*13b Packet IDentifier (PID)
2b Transport Scrambling Control
*2b Adaptation Field Control (AFC)
*4b Continuity Counter (CC)
If the PUSI bit is set to a value of 1, there is one
additional field following the TS packet header:
*8b Payload Pointer (PP)
TS Logical Channel: Transport Stream Logical Channel. In this
document, this term identifies a channel at the MPEG-2 level
[ISO-MPEG2]. It exists at level 2 of the ISO/OSI reference model.
All packets sent over a TS Logical Channel carry the same PID value
(this value is unique within a specific TS Multiplex). The term
"Stream" is defined in MPEG-2 [ISO-MPEG2] to describe the content
carried by a specific TS Logical Channel (see ULE Stream). Some PID
values are reserved (by MPEG-2) for specific signalling. Other
standards (e.g., ATSC, DVB) also reserve specific PID values.
TS Multiplex: In this document, this term defines a set of MPEG-2 TS
Logical Channels sent over a single lower-layer connection. This may
be a common physical link (i.e., a transmission at a specified symbol
rate, FEC setting, and transmission frequency) or an encapsulation
provided by another protocol layer (e.g., Ethernet, or RTP over IP).
The same TS Logical Channel may be repeated over more than one TS
Multiplex (possibly associated with a different PID value) [RFC4259];
for example, to redistribute the same multicast content to two
terrestrial TV transmission cells.
TS Packet: A fixed-length 188B unit of data sent over a TS Multiplex
[ISO-MPEG2]. Each TS Packet carries a 4B header, plus optional
overhead including an Adaptation Field, encryption details, and time
stamp information to synchronise a set of related TS Logical
Channels.
ULE Stream: An MPEG-2 TS Logical Channel that carries only ULE
encapsulated PDUs. ULE Streams may be identified by definition of a
stream_type in SI/PSI [ISO-MPEG2].
3. Description of the Method
PDUs (IP packets, Ethernet frames or packets from other network
protocols) are encapsulated to form a Subnetwork Data Unit (SNDU).
The SNDU is transmitted over an MPEG-2 transmission network either by
being placed in the payload of a single TS Packet, or, if required,
by being fragmented into a series of TS Packets. Where there is
sufficient space, the method permits a single TS Packet to carry more
than one SNDU (or part thereof), a practice sometimes known as
Packing. All TS Packets comprising an SNDU MUST be assigned the same
PID, and therefore form a part of the same TS Logical Channel.
The ULE encapsulation is limited to TS private streams only. The
header of each TS Packet carries a one-bit Payload Unit Start
Indicator (PUSI) field. A PUSI field with a value of 1 indicates the
start of at least one Payload Unit (SNDU) within the TS Packet
payload. The semantics of the PUSI bit are defined for PES and PSI
packets [ISO-MPEG2]; for private data, its use is not defined in the
MPEG-2 Standard. Although ULE uses private data, the operation
follows that of PSI packets. Hence, the following PUSI values are
defined:
0: The TS Packet does NOT contain the start of an SNDU, but
contains the continuation, or end, of an SNDU;
1: The TS Packet contains the start of an SNDU, and a one byte
Payload Pointer follows the last byte of the TS Packet header.
If a Payload Unit (SNDU) finishes before the end of a TS Packet
payload, but it is not intended to start another Payload Unit, a
stuffing procedure (known as Padding) fills the remainder of the TS
Packet payload with bytes with a value 0xFF [ISO-MPEG2].
A Receiver processing MPEG-2 Table Sections that receives a value of
0xFF in the first byte of a Table Section (table_Id) interprets this
as Padding/Stuffing and silently discards the remainder of the TS
Packet payload. The payload of the next TS Packet for the same TS
Logical Channel will begin with a Payload Pointer of value 0x00,
indicating that the next Payload Unit immediately follows the TS
Packet header. The ULE protocol resembles this, but differs in the
exact procedure (see the following sections).
The TS Packet Header also carries a two-bit Adaptation Field Control
(AFC) value. This adaptation field may extend the TS Packet Header
to carry timing and synchronisation information and may also be used
to include stuffing bytes before a TS Packet payload. Adaptation
Field stuffing is NOT used in this encapsulation method, and TS
Packets from a ULE Encapsulator MUST be sent with an AFC value of
'01'. For TS Logical Channels supporting ULE, Receivers MUST discard
TS Packets that carry other AFC values.
4. SNDU Format
PDUs are encapsulated using ULE to form an SNDU. (Each SNDU is an
MPEG-2 Payload Unit.) The encapsulation format to be used for PDUs is
illustrated below:
< ----------------------------- SNDU ----------------------------- >
+-+-------------------------------------------------------+--------+
|D| Length | Type | Dest Address* | PDU | CRC-32 |
+-+-------------------------------------------------------+--------+
Figure 1: SNDU Encapsulation (* optional Destination Address)
All multi-byte values in ULE (including the Length/End Indicator
(4.2,4.3), Type (4.4), Destination Address (4.5), and Extension
Headers (5)) are transmitted in network byte order (most significant
byte first). The most significant bit of each byte is placed in the
left-most position of the 8-bit field. Appendix A provides
informative examples of usage.
4.1. Destination Address Absent (D) Field
The most significant bit of the Length field carries the value of the
Destination Address Absent Field, the D-bit. A value of 0 indicates
the presence of the Destination Address Field (see section 4.5). A
value of 1 indicates that a Destination Address Field is not present.
An End Indicator (4.3) MUST be sent with a D-bit value of 1. Other
SNDUs MAY be sent with a D-bit value of 0 or 1. The default method
SHOULD use a D-bit value of 0 (see section 4.5).
4.2. Length Field
A 15-bit value that indicates the length, in bytes, of the SNDU
counted from the byte following the Type field of the SNDU base
header (figure 9) up to and including the CRC. This Length includes
the size of any extension headers that may be present (section 5).
Note the special case described in section 4.3.
4.3. End Indicator
When the first two bytes following an SNDU have the value 0xFFFF,
this denotes an End Indicator (i.e., all ones length combined with a
D-bit value of 1). This indicates to the Receiver that there are no
further SNDUs present within the current TS Packet (see section 6),
and that no Destination Address Field is present. The value 0xFF has
specific semantics in MPEG-2 framing, where it is used to indicate
the presence of Padding. This use resembles [ISO-DSMCC].
4.4. Type Field
The 16-bit Type field indicates the type of payload carried in an
SNDU, or the presence of a Next-Header. The set of values that may
be assigned to this field is divided into two parts, similar to the
allocations for Ethernet.
EtherTypes were originally specified by Xerox under the Ethernet v2
Specification [DIX]. After specification of IEEE 802.3 [IEEE-802.3,
ISO-8802-2], the set of EtherTypes less than 1536 (0x0600) assumed
the role of a length indicator. Ethernet receivers use this feature
to discriminate LLC format frames. Hence, any IEEE EtherType < 1536
indicates an LLC frame, and the actual value indicates the length of
the LLC frame.
There is a potential ambiguous case when a Receiver receives a PDU
with two Length fields: The Receiver would need to validate the
actual length and the Length field and ensure that inconsistent
values are not propagated by the network. Specification of two
independent Length fields is therefore undesirable. In the ULE
header, this is avoided in the SNDU header by including only one
length value, but bridging of LLC frames re-introduces this
consideration (section 5.2).
The Ethernet LLC mode of identification is not required in ULE, since
the SNDU format always carries an explicit Length field, and
therefore the procedure in ULE is modified, as below:
The first set of ULE Type field values comprise the set of values
less than 1536 in decimal. These Type field values are IANA assigned
(see section 4.4.1) and indicate the Next-Header.
The second set of ULE Type field values comprise the set of values
greater than or equal to 1536 in decimal. In ULE, this value is
identical to the corresponding type codes specified by the IEEE/DIX
type assignments for Ethernet and recorded in the IANA EtherType
registry.
4.4.1. Type 1: Next-Header Type Fields
The first part of the Type space corresponds to the values 0 to 1535
decimal. These values may be used to identify link-specific
protocols and/or to indicate the presence of Extension Headers that
carry additional optional protocol fields (e.g., a bridging
encapsulation). Use of these values is co-ordinated by an IANA
registry. The following types are defined in this document:
0x0000: Test SNDU (see section 5.1)
0x0001: Bridged Frame (see section 5.2)
0x0100: Extension-Padding (see section 5.3)
The remaining values within the first part of the Type space are
reserved for Next-Header values allocated by the IANA.
4.4.2. Type 2: EtherType Compatible Type Fields
The second part of the Type space corresponds to the values between
0x600 (1536 decimal) and 0xFFFF. This set of type assignments
follows DIX/IEEE assignments (but excludes use of this field as a
frame length indicator). All assignments in this space MUST use the
values defined for IANA EtherType. The following two Type values are
used as examples (taken from the IANA EtherTypes registry):
0x0800: IPv4 Payload (see section 4.7.2)
0x86DD: IPv6 Payload (see section 4.7.3)
4.5. SNDU Destination Address Field
The SNDU Destination Address Field is optional (see section 4.1).
This field MUST be carried (i.e., D=0) for IP unicast packets
destined to routers that are sent using shared links (i.e., where the
same link connects multiple Receivers). A sender MAY omit this field
(D=1) for an IP unicast packet and/or multicast packets delivered to
Receivers that are able to utilise a discriminator field (e.g., the
IPv4/IPv6 destination address, or a bridged MAC destination address),
which, in combination with the PID value, could be interpreted as a
Link-Level address.
When the SNDU header indicates the presence of an SNDU Destination
Address field (i.e., D=0), a Network Point of Attachment (NPA) field
directly follows the fourth byte of the SNDU header. NPA destination
addresses are 6 Byte numbers, normally expressed in hexadecimal, used
to identify the Receiver(s) in a MPEG-2 transmission network that
should process a received SNDU. The value 0x00:00:00:00:00:00 MUST
NOT be used as a destination address in an SNDU. The least
significant bit of the first byte of the address is set to 1 for
multicast frames, and the remaining bytes specify the link-layer
multicast address. The specific value 0xFF:FF:FF:FF:FF:FF is the
link broadcast address, indicating that this SNDU is to be delivered
to all Receivers.
IPv4 packets carrying an IPv4 subnetwork broadcast address need to be
delivered to all systems with the same network prefix. When a SNDU
Destination Address is present (D=0), the value MUST be set to the
NPA link broadcast address (0xFF:FF:FF:FF:FF:FF).
When the PDU is an IP multicast packet and an SNDU Destination
Address is present (D=0), the IP group destination address of the
multicast packet MUST be mapped to the multicast SNDU Destination
Address (following the method used to generate a destination MAC
address in Ethernet). The method for mapping IPv4 multicast
addresses is specified in [RFC1112]. The method for mapping IPv6
multicast addresses is specified in [RFC2464].
4.6. SNDU Trailer CRC
Each SNDU MUST carry a 32-bit CRC field in the last four bytes of the
SNDU. This position eases CRC computation by hardware. The CRC-32
polynomial is to be used. Examples where this polynomial is also
employed include Ethernet, DSM-CC section syntax [ISO-DSMCC], and
AAL5 [ITU-3563]. This is a 32-bit value calculated according to the
generator polynomial represented 0x104C11DB7 in hexadecimal:
x^32+x^26+x^23+x^22+x^16+x^12+x^11+x^10+x^8+x^7+x^5+x^4+x^2+x^1+x^0.
The Encapsulator initialises the CRC-32 accumulator register to the
value 0xFFFF FFFF. It then accumulates a transmit value for the
CRC32 that includes all bytes from the start of the SNDU header to
the end of the SNDU (excluding the 32-bit trailer holding the
CRC-32), and places this in the CRC Field. In ULE, the bytes are
processed in order of increasing position within the SNDU; the order
of processing bits is NOT reversed. This use resembles, but is
different from that in SCTP [RFC3309].
The Receiver performs an integrity check by independently calculating
the same CRC value and comparing this with the transmitted value in
the SNDU trailer. SNDUs that do not have a valid CRC are discarded,
causing the Receiver to enter the Idle State.
This description may be suited for hardware implementation, but this
document does not imply any specific implementation. Software-based
table-lookup or hardware-assisted software-based implementations are
also possible. Appendix B provides an example of an Encapsulated PDU
that includes the computed CRC-32 value.
The primary purpose of this CRC is to protect the SNDU (header and
payload) from undetected reassembly errors and errors introduced by
unexpected software/hardware operation while the SNDU is in transit
across the MPEG-2 subnetwork and during processing at the
Encapsulator and/or the Receiver. It may also detect the presence of
uncorrected errors from the physical link (however, these may also be
detected by other means, e.g., section 7.3).
4.7. Description of SNDU Formats
The format of an SNDU is determined by the combination of the
Destination Address Absent bit (D) and the SNDU Type field. The
simplest encapsulation places a PDU directly into an SNDU payload.
Some Type 1 encapsulations may require additional header fields.
These are inserted in the SNDU following the NPA destination address
and directly preceding the PDU.
The following SNDU Formats are defined here:
End Indicator: The Receiver should enter the Idle State (4.7.1).
IPv4 SNDU: The payload is a complete IPv4 datagram (4.7.2).
IPv6 SNDU: The payload is a complete IPv6 datagram (4.7.3).
Test SNDU: The payload will be discarded by the Receiver (5.1).
Bridged SNDU: The payload carries a bridged MAC frame (5.2).
Other formats may be defined through relevant assignments in the IEEE
and IANA registries.
4.7.1. End Indicator
The format of the End Indicator is shown in figure 2. This format
MUST carry a D-bit value of 1.
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|1| 0x7FFF | |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +
| |
= A sequence of zero or more bytes with a value 0xFF filling =
| the remainder of the TS Packet Payload |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 2: Format for a ULE End Indicator
4.7.2. IPv4 SNDU Encapsulation
IPv4 datagrams are directly transported using one of the two standard
SNDU structures, in which the PDU is placed directly in the SNDU
payload. The two encapsulations are shown in Figures 3 and 4. (Note
that in this, and the following figures, the IP datagram payload is
of variable size and is directly followed by the CRC-32).
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|0| Length (15b) | Type = 0x0800 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Receiver Destination NPA Address (6B) |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| | |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +
| |
= IPv4 datagram =
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| (CRC-32) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 3: SNDU Format for an IPv4 Datagram using L2 filtering (D=0)
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|1| Length (15b) | Type = 0x0800 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
= IPv4 datagram =
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| (CRC-32) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 4: SNDU Format for an IPv4 Datagram using L3 filtering (D=1)
4.7.3. IPv6 SNDU Encapsulation
IPv6 datagrams are directly transported using one of the two standard
SNDU structures, in which the PDU is placed directly in the SNDU
payload. The two encapsulations are shown in Figures 5 and 6.
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|0| Length (15b) | Type = 0x86DD |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Receiver Destination NPA Address (6B) |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| | |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +
| |
= IPv6 datagram =
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| (CRC-32) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 5: SNDU Format for an IPv6 Datagram using L2 filtering (D=0)
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|1| Length (15b) | Type = 0x86DD |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
= IPv6 datagram =
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| (CRC-32) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 6: SNDU Format for an IPv6 Datagram using L3 filtering (D=1)
5. Extension Headers
This section describes an extension format for the ULE encapsulation.
In ULE, a Type field value less than 1536 decimal indicates an
Extension Header. These values are assigned from a separate IANA
registry defined for ULE.
The use of a single Type/Next-Header field simplifies processing and
eliminates the need to maintain multiple IANA registries. The cost
is that each Extension Header requires at least 2 bytes. This is
justified, on the basis of simplified processing and maintaining a
simple lightweight header for the common case when no extensions are
present.
A ULE Extension Header is identified by a 16-bit value in the Type
field. This field is organised as a 5-bit zero prefix, a 3-bit H-LEN
field, and an 8-bit H-Type field, as follows:
0 1
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|0 0 0 0 0|H-LEN| H-Type |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 7: Structure of ULE Next-Header Field
The H-LEN Assignment is described below:
0 Indicates a Mandatory Extension Header
1 Indicates an Optional Extension Header of length 2B (Type only)
2 Indicates an Optional Extension Header of length 4B (Type + 2B)
3 Indicates an Optional Extension Header of length 6B (Type + 4B)
4 Indicates an Optional Extension Header of length 8B (Type + 6B)
5 Indicates an Optional Extension Header of length 10B (Type + 8B)
>=6 The combined H-LEN and H-TYPE values indicate the EtherType
of a PDU that directly follows this Type field.
The H-LEN value indicates the total number of bytes in an Optional
Extension Header (including the 2B Type field).
An H-LEN value of zero indicates a Mandatory Extension Header. Each
Mandatory Extension Header has a pre-defined length that is not
communicated in the H-LEN field. No additional limit is placed on
the maximum length of a Mandatory Extension Header. A Mandatory
Extension Header MAY modify the format or encoding of the enclosed
PDU (e.g., to perform encryption and/or compression).
The H-Type is a one-byte field that is either one of 256 Mandatory
Header Extensions or one of 256 Optional Header Extensions. The set
of currently permitted values for both types of Extension Headers are
defined by an IANA Registry (section 15). Registry values for
Optional Extensions are specified in the form H=1 (i.e., a decimal
number in the range 256-511), but may be used with an H-Length value
in the range 1-5 (see example in section 5.3).
Two examples of Extension Headers are the Test SNDU and the use of
Extension-Padding. The Test SNDU Mandatory Extension Header results
in the entire PDU's being discarded. The Extension-Padding Optional
Extension Header results in the following (if any) option header
being ignored (i.e., a total of H-LEN 16-bit words).
The general format for an SNDU with Extension Headers is:
< -------------------------- SNDU ------------------------- >
+---+--------------------------------------------------+--------+
|D=0| Length | T1 | NPA Address | H1 | T2 | PDU | CRC-32 |
+---+--------------------------------------------------+--------+
< ULE base header > < ext 1 >
Figure 8: SNDU Encapsulation with one Extension Header (for D=0)
Where:
D is the ULE D_bit (in this example D=0; however, NPA addresses may
also be omitted when using Extension Headers).
T1 is the base header Type field. In this case, specifying a
Next-Header value.
H1 is a set of fields defined for header type T1. There may be 0
or more bytes of information for a specific ULE Extension Header.
T2 is the Type field of the next header, or an EtherType > 1535 B
indicating the type of the PDU being carried.
< -------------------------- SNDU ------------------------- >
+---+---------------------------------------------------+--------+
|D=1| Length | T1 | H1 | T2 | H2 | T3 | PDU | CRC-32 |
+---+---------------------------------------------------+--------+
< ULE base header >< ext 1 >< ext 2 >
Figure 9: SNDU Encapsulation with two Extension Headers (D=1)
Using this method, several Extension Headers MAY be chained in
series. Figure 12 shows an SNDU including two Extension Headers. In
the example, the values of T1 and T2 are both less than 1536 decimal.
Each indicates the presence of an Extension Header, rather than a
directly following PDU. T3 has a value > 1535 indicating the
EtherType of the PDU being carried. Although an SNDU may contain an
arbitrary number of consecutive Extension Headers, it is not expected
that SNDUs will generally carry a large number of extensions.
5.1. Test SNDU
A Test SNDU (Figure 10) is a Mandatory Extension Header of Type 1.
This header must be the final (or only) extension header specified in
the header chain of an SNDU. The structure of the Data portion of
this SNDU is not defined by this document. Receivers MAY record
reception in a log file, but MUST then discard any Test SNDUs. The
D-bit MAY be set in a TEST SNDU.
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|D| Length (15b) | Type = 0x0000 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
= Data (not forwarded by a Receiver) =
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| (CRC-32) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 10: SNDU Format for a Test SNDU
5.2. Bridged Frame SNDU Encapsulation
A bridged SNDU is a Mandatory Extension Header of Type 1. It MUST be
the final (or only) extension header specified in the header chain of
an SNDU. The payload includes MAC address and EtherType [DIX] or LLC
Length [ISO-8802-2] fields together with the contents of a bridged
MAC frame. The SNDU has the format shown in Figures 11 and 12.
When an NPA address is specified (D=0), Receivers MUST discard all
SNDUs that carry an NPA destination address that does NOT match their
own NPA address (or a broadcast/multicast address); the payload of
the remaining SNDUs are processed by the bridging rules that follow.
An SNDU without an NPA address (D=1) results in a Receiver performing
bridging processing on the payload of all received SNDUs.
An Encapsulator MAY also use this encapsulation format to directly
communicate network protocol packets that require the LLC
encapsulation [IEEE-802.2, ISO-8802-2]. To do this, it constructs an
SNDU with a Bridge Extension Header containing the intended
destination MAC address, the MAC source address of the Encapsulator,
and the LLC-Length. The PDU comprises an LLC header followed by the
required payload. The Encapsulator MAY choose to suppress the NPA
address (see 4.5).
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|0| Length (15b) | Type = 0x0001 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Receiver Destination NPA Address (6B) |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| | |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +
| MAC Destination Address (6B) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| MAC Source Address (6B) |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| | EtherType/LLC-Length (2B) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
= (Contents of bridged MAC frame) =
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| (CRC-32) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 11: SNDU Format for a Bridged Payload (D=0)
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|1| Length (15b) | Type = 0x0001 |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| MAC Destination Address (6B) |
+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| | |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +
| MAC Source Address (6B) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| EtherType/LLC-Length (2B) | |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +
| |
= (Contents of bridged MAC frame) =
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| (CRC-32) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 12: SNDU Format for a Bridged Payload (D=1)
The EtherType/LLC-Length field of a frame is defined according to
IEEE 802.3 [IEEE-802.2] (see section 5).
In this special case, the Mandatory Extension Header format may be
interpreted as either an EtherType [DIX] or an LLC Length field,
specified by IEEE 802 [IEEE-802.3] rather than as a value assigned in
the ULE Next-Header Registry maintained by the IANA.
The MAC addresses in the frame being bridged SHOULD be assigned
according to the rules specified by the IEEE and denote unknown,
unicast, broadcast, and multicast link addresses. These MAC
addresses denote the intended recipient in the destination LAN, and
therefore have a different function from the NPA addresses carried in
the SNDU header.
A frame Type < 1536 for a bridged frame introduces a LLC Length
field. The Receiver MUST check this length and discard any frame
with a length greater than permitted by the SNDU payload size.
In normal operation, it is expected that any padding appended to the
Ethernet frame SHOULD be removed prior to forwarding. This requires
the sender to be aware of such Ethernet padding (e.g., [DIX,
IEEE-802.3]).
Ethernet frames received at the Encapsulator for onward transmission
over ULE carry a Local Area Network Frame Check sequence (LAN FCS)
field (e.g., CRC-32 for Ethernet [DIX, IEEE-802.3]). The
Encapsulator MUST check the LAN-FCS value of all frames received,
prior to further processing. Frames received with an invalid LAN FCS
MUST be discarded. After checking, the LAN FCS is then removed
(i.e., it is NOT forwarded in the bridged SNDU). As in other ULE
frames, the Encapsulator appends a CRC-32 to the transmitted SNDU.
At the Receiver, an appropriate LAN-FCS field will be appended to the
bridged frame prior to onward transmission on the Ethernet interface.
This design is readily implemented using existing network interface
cards and does not introduce an efficiency cost by
calculating/verifying two integrity check fields for bridged frames.
However, it also introduces the possibility that a frame corrupted
within the processing performed at an Encapsulator and/or Receiver
may not be detected by the final recipient(s) (i.e., such corruption
would not normally result in an invalid LAN FCS).
5.3. Extension-Padding Optional Extension Header
The Extension-Padding Optional Extension Header is specified by an
IANA-assigned H-Type value of 0x100. As in other Optional
Extensions, the total length of the extension is indicated by the
H-LEN field (specified in 16-bit words). The extension field is
formed of a group of one to five 16-bit fields.
For this specific option, only the last 16-bit word has an assigned
value; the sender SHOULD set the remaining values to 0x0000. The
last 16-bit field forms the Next-Header Type field. A Receiver MUST
interpret the Type field, but MUST ignore any other fields of this
Extension Header.
6. Processing at the Encapsulator
The Encapsulator forms the PDUs queued for transmission into SNDUs by
adding a header and trailer to each PDU (section 4). It then
segments the SNDU into a series of TS Packet payloads (Figure 13).
These are transmitted using a single TS Logical Channel over a TS
Multiplex. The TS Multiplex may be processed by a number of MPEG-2
(re)multiplexors before it is finally delivered to a Receiver
[RFC4259].
+------+--------------------------------+------+
| ULE | Protocol Data Unit | ULE |
|Header| |CRC-32|
+------+--------------------------------+------+
/ / \ \
/ / \ \
/ / \ \
+--------+---------+ +--------+---------+ +--------+---------+
|MPEG-2TS| MPEG-2 |...|MPEG-2TS| MPEG-2 |...|MPEG-2TS| MPEG-2 |
| Header | Payload | | Header | Payload | | Header | Payload |
+--------+---------+ +--------+---------+ +--------+---------+
Figure 13: Encapsulation of an SNDU into a series of TS Packets
6.1. SNDU Encapsulation
When an Encapsulator has not previously sent a TS Packet for a
specific TS Logical Channel, or after an Idle period, it starts to
send an SNDU in the first available TS Packet. This first TS Packet
generated MUST carry a PUSI value of 1. It MUST also carry a Payload
Pointer value of zero, indicating that the SNDU starts immediately
after the Payload Pointer in the TS Packet payload.
The Encapsulation MUST ensure that all TS Packets set the MPEG-2
Continuity Counter carried in the TS Packet header, according to
[ISO-MPEG2]. This value MUST be incremented by one (modulo 16) for
each successive TS Packet containing a fragment/complete SNDU sent
using the same TS Logical Channel.
An Encapsulator MAY decide not to send another SNDU immediately, even
if space is available in a partially filled TS Packet. This
procedure is known as Padding (Figure 14). The End Indicator informs
the Receiver that there are no more SNDUs in this TS Packet payload.
The End Indicator is followed by zero or more unused bytes until the
end of the TS Packet payload. All unused bytes MUST be set to the
value of 0xFF, following current practice in MPEG-2 [ISO-DSMCC]. The
Padding procedure trades decreased efficiency against improved
latency.
+-/------------+
| SubNetwork |
| DU 1 |
+-/------------+
\ \
\ \
\ \
+--------+--------+--------+----------+
|MPEG-2TS| End of | 0xFFFF | Unused |
| Header | SNDU 1 | | Bytes |
+--------+--------+--------+----------+
PUSI=0 ULE
End
Indicator
Figure 14: A TS Packet carrying the end of SNDU 1, followed by an
End Indicator
Alternatively, when more packets are waiting at an Encapsulator, and
a TS Packet has sufficient space remaining in the payload, the
Encapsulator can follow a previously encapsulated SNDU with another
SNDU using the next available byte of the TS Packet payload (see
6.2). This is called Packing (Figure 15).
+-/----------------+ +----------------/-+
| Subnetwork | | Subnetwork |
| DU 2 | | DU 3 |
+-/----------------+ +----------------/-+
\ \ / /\
\ \ / / \
\ \ / / \. . .
+--------+--------+--------+----------+
|MPEG-2TS| Payload| end of | start of |
| Header | Pointer| SNDU 2 | SNDU 3 |
+--------+--------+--------+----------+
PUSI=1 | ^
| |
+--------------+
Figure 15: A TS Packet with the end of SNDU 2, followed by SNDU 3
6.2. Procedure for Padding and Packing
Five possible actions may occur when an Encapsulator has completed
encapsulation of an SNDU:
(i) If the TS Packet has no remaining space, the Encapsulator
transmits this TS Packet. It starts transmission of the next SNDU in
a new TS Packet. (The standard rules [ISO-MPEG2] require that the
header of this new TS Packet carry a PUSI value of 1 followed by a
Payload Pointer value of 0x00.)
(ii) If the TS Packet carrying the final part of an SNDU has one byte
of unused payload, the Encapsulator MUST place the value 0xFF in this
final byte and transmit the TS Packet. This rule provides a simple
mechanism to resolve the complex behaviour that may arise when the TS
Packet has no PUSI set. To send another SNDU in the current TS
Packet would otherwise require the addition of a Payload Pointer that
would consume the last remaining byte of TS Packet payload. The
behaviour follows similar practice for other MPEG-2 payload types
[ISO-DSMCC]. The Encapsulator MUST start transmission of the next
SNDU in a new TS Packet. (The standard rules require the header of
this new TS Packet to carry a PUSI value of 1 followed by a Payload
Pointer value of 0x00.)
(iii) If the TS Packet carrying the final part of an SNDU has exactly
two bytes of unused payload, and the PUSI was NOT already set, the
Encapsulator MUST place the value 0xFFFF in these final two bytes,
providing an End Indicator (section 4.3), and transmit the TS Packet.
This rule prevents fragmentation of the SNDU Length field over two TS
Packets. The Encapsulator MUST start transmission of the next SNDU
in a new TS Packet. (The standard rules require the header of this
new TS Packet to carry a PUSI value of 1 followed by a Payload
Pointer value of 0x00.)
(iv) If the TS Packet has more than two bytes of unused payload, the
Encapsulator MAY transmit this partially full TS Packet but MUST
first place the value 0xFF in all remaining unused bytes (i.e.,
setting an End Indicator followed by Padding). The Encapsulator MUST
then start transmission of the next SNDU in a new TS Packet. (The
standard rules [ISO-MPEG2] require that the header of this new TS
Packet carry a PUSI value of 1 and a Payload Pointer value of 0x00.)
(v) If at least two bytes are available for SNDU data in the TS
Packet payload (i.e., three bytes if the PUSI was NOT previously set,
and two bytes if it was previously set), the Encapsulator MAY
encapsulate further queued PDUs, by starting the next SNDU in the
next available byte of the current TS Packet payload. When the
Encapsulator packs further SNDUs into a TS Packet where the PUSI has
NOT already been set, the PUSI MUST be updated (set to 1), and an
8-bit Payload Pointer MUST be inserted in the first byte directly
following the TS Packet header. (This reduces the size of the TS
Packet payload field that is available for data by one byte.) The
value of the Payload Pointer MUST be set to the position of the byte
following the end of the first SNDU in the TS Packet payload. If no
further PDUs are available, an Encapsulator MAY wait for additional
PDUs to fill the incomplete TS Packet. The maximum period of time an
Encapsulator can wait, known as the Packing Threshold, MUST be
bounded and SHOULD be configurable in the Encapsulator. If
sufficient additional PDUs are NOT received to complete the TS Packet
within the Packing Threshold, the Encapsulator MUST insert an End
Indicator (using rule iv).
Use of the Packing method (v) by an Encapsulator is optional and may
be determined on a per-session, per-packet, or per-SNDU basis.
When an SNDU is less than the size of a TS Packet payload, a TS
Packet may be formed that carries a PUSI value of one and also an End
Indicator (using rule iv).
7. Receiver Processing
A Receiver tunes to a specific TS Multiplex carrying a ULE Stream and
sets a receive filter to accept all TS Packets with a specific PID.
These TS Packets are associated with a specific TS Logical Channel
and are reassembled to form a stream of SNDUs. A single Receiver may
be able to receive multiple TS Logical Channels, possibly using a
range of TS Multiplexes. In each case, reassembly MUST be performed
independently for each TS Logical Channel. To perform this
reassembly, the Receiver may use a buffer to hold the partially
assembled SNDU, referred to here as the Current SNDU buffer. Other
implementations may choose to use other data structures, but MUST
provide equivalent operations.
Receipt of a TS Packet with a PUSI value of 1 indicates that the TS
Packet contains the start of a new SNDU. It also indicates the
presence of the Payload Pointer (indicating the number of bytes to
the start of the first SNDU in the TS-Packet currently being
reassembled). It is illegal to receive a Payload Pointer value
greater than 181, and this MUST cause the SNDU reassembly to be
aborted and the Receiver to enter the Idle State. This event SHOULD
be recorded as a payload pointer error.
A Receiver MUST support the use of both the Packing and Padding
method for any received SNDU and MUST support reception of SNDUs with
or without a Destination Address Field (i.e., D=0 and D=1).
7.1. Idle State
After initialisation or errors, or on receipt of an End Indicator,
the Receiver enters the Idle State. In this state, the Receiver
discards all TS Packets until it discovers the start of a new SNDU,
upon which it then enters the Reassembly State. Figure 16 outlines
these state transitions:
+-------+
| START |
+---+---+
|
\/
+----------+
\| Idle |/
+-------/| State |\-------+
Insufficient | +----+-----+ |
unused space | | PUSI set | MPEG-2 TS Error
or | \/ | or
End Indicator| +----------+ | SNDU Error
| |Reassembly| |
+--------| State |--------+
+----------+
Figure 16: Receiver state transitions
7.1.1. Idle State Payload Pointer Checking
A Receiver in the Idle State MUST check the PUSI value in the header
of all received TS Packets. A PUSI value of 1 indicates the presence
of a Payload Pointer. Following a loss of synchronisation, values
between 0 and 181 are permitted, in which case the Receiver MUST
discard the number of bytes indicated by the Payload Pointer (counted
from the first byte of the TS Packet payload field, and excluding the
PP field itself), before leaving the Idle State. It then enters the
Reassembly State, and starts reassembly of a new SNDU at this point.
7.2. Processing of a Received SNDU
When in the Reassembly State, the Receiver reads a 2-byte SNDU Length
field from the TS Packet payload. If the value is less than or equal
to 4, or equal to 0xFFFF, the Receiver discards the Current SNDU and
the remaining TS Packet payload and returns to the Idle State.
Receipt of an invalid Length field is an error event and SHOULD be
recorded as an SNDU length error.
If the Length of the Current SNDU is greater than 4, the Receiver
accepts bytes from the TS Packet payload to the Current SNDU buffer
until either Length bytes in total are received, or the end of the TS
Packet is reached (see also 7.2.1). When the Current SNDU length
equals the value of the Length field, the Receiver MUST calculate and
verify the CRC value (see 4.6). SNDUs that contain an invalid CRC
value MUST be discarded. Mismatch of the CRC is an error event and
SHOULD be recorded as a CRC error. The underlying physical-layer
processing (e.g., forward error correction coding) often results in
patterns of errors, rather than single bit errors, so the Receiver
needs to be robust to arbitrary patterns of corruption to the TS
Packet and payload, including potential corruption of the PUSI, PP,
and SNDU Length fields. Therefore, a Receiver SHOULD discard the
remaining TS Packet payload (if any) following a CRC mismatch and
return to the Idle State.
When the Destination Address is present (D=0), the Receiver accepts
SNDUs that match one of a set of addresses specified by the Receiver
(this includes the NPA address of the Receiver, the NPA broadcast
address, and any required multicast NPA addresses). The Receiver
MUST silently discard an SNDU with an unmatched address.
After receiving a valid SNDU, the Receiver MUST check the Type field
(and process any Type 1 Extension Headers). The SNDU payload is then
passed to the next protocol layer specified. An SNDU with an unknown
Type value < 1536 MUST be discarded. This error event SHOULD be
recorded as an SNDU type error.
The Receiver then starts reassembly of the next SNDU. This MAY
directly follow the previously reassembled SNDU within the TS Packet
payload.
(i) If the Current SNDU finishes at the end of a TS Packet payload,
the Receiver MUST enter the Idle State.
(ii) If only one byte remains unprocessed in the TS Packet payload
after completion of the Current SNDU, the Receiver MUST discard this
final byte of TS Packet payload. It then enters the Idle State. It
MUST NOT record an error when the value of the remaining byte is
identical to 0xFF.
(iii) If two or more bytes of TS Packet payload data remain after
completion of the Current SNDU, the Receiver accepts the next 2 bytes
and examines whether this is an End Indicator. When an End Indicator
is received, a Receiver MUST silently discard the remainder of the TS
Packet payload and transition to the Idle State. Otherwise, this is
the start of the next Packed SNDU, and the Receiver continues by
processing this SNDU. (This is provided that the TS Packet has a
PUSI value of 1, see 7.2.1; otherwise, the Receiver has detected a
delimiting error and MUST discard all remaining bytes in the TS
Packet payload and transitions to the Idle State.)
7.2.1. Reassembly Payload Pointer Checking
A Receiver that has partially received an SNDU (in the Current SNDU
buffer) MUST check the PUSI value in the header of all subsequent TS
Packets with the same PID (i.e., same TS Logical Channel). If it
receives a TS Packet with a PUSI value of 1, it MUST then verify the
Payload Pointer. If the Payload Pointer does NOT equal the number of
bytes remaining to complete the Current SNDU (i.e., the difference
between the SNDU Length field and the number of reassembled bytes),
the Receiver has detected a delimiting error.
Following a delimiting error, the Receiver MUST discard the partially
assembled SNDU (in the Current SNDU buffer) and SHOULD record a
reassembly error. It MUST then re-enter the Idle State.
7.3. Other Error Conditions
The Receiver SHOULD check the MPEG-2 Transport Error Indicator
carried in the TS Packet header [ISO-MPEG2]. This flag indicates a
transmission error for a TS Logical Channel. If the flag is set to a
value of one, a transmission error event SHOULD be recorded. Any
partially received SNDU MUST be discarded. The Receiver then enters
the Idle State.
The Receiver MUST check the MPEG-2 Continuity Counter carried in the
TS Packet header [ISO-MPEG2]. If two (or more) successive TS Packets
within the same TS Logical Channel carry the same Continuity Counter
value, the duplicate TS Packets MUST be silently discarded. If the
received value is NOT identical to that in the previous TS Packet,
and it does NOT increment by one for successive TS Packets (modulo
16), the Receiver has detected a continuity error. Any partially
received SNDU MUST be discarded. A continuity counter error event
SHOULD be recorded. The Receiver then enters the Idle State.
Note that an MPEG2-2 Transmission network is permitted to carry
duplicate TS Packets [ISO-MPEG2], which are normally detected by the
MPEG-2 Continuity Counter. A Receiver that does not perform the
above Continuity Counter check would accept duplicate copies of TS
Packets to the reassembly procedure. In most cases, the SNDU CRC-32
integrity check will result in discard of these SNDUs, leading to
unexpected PDU loss; however, in some cases, duplicate PDUs (fitting
into one TS Packet) could pass undetected to the next layer protocol.
8. Summary
This document defines a Unidirectional Lightweight Encapsulation
(ULE) that performs efficient and flexible support for IPv4 and IPv6
network services over networks built upon the MPEG-2 Transport Stream
(TS). The encapsulation is also suited to transport of other
protocol packets and bridged Ethernet frames.
ULE also provides an Extension Header format and defines an
associated IANA registry for efficient and flexible support of both
mandatory and optional SNDU headers. This allows for future
extension of the protocol, while providing backwards compatibility
with existing implementations. In particular, Optional Extension
Headers may safely be ignored by Receivers that do not implement
them, or choose not to process them.
9. Acknowledgements
This document is based on a previous document authored by: Horst D.
Clausen, Bernhard Collini-Nocker, Hilmar Linder, and Gorry Fairhurst.
The authors wish to thank the members of the ip-dvb mailing list for
their input; in particular, the many comments received from Art
Allison, Carstsen Borman, Patrick Cipiere, Wolgang Fritsche, Hilmar
Linder, Alain Ritoux, and William Stanislaus. Alain also provided
the original examples of usage.
10. Security Considerations
The security considerations for ULE resemble those that arise when
the existing Multi-Protocol Encapsulation (MPE) is used. ULE does
not add specific new threats that will impact the security of the
general Internet.
There is a known security issue with un-initialised stuffing bytes.
In ULE, these bytes are set to 0xFF (normal practice in MPEG-2).
There are known integrity issues with the removal of the LAN FCS in a
bridged networking environment. The removal for bridged frames
exposes the traffic to potentially undetected corruption while being
processed by the Encapsulator and/or Receiver.
There is a potential security issue when a Receiver receives a PDU
with two Length fields: The Receiver would need to validate the
actual length and the Length field and ensure that inconsistent
values are not propagated by the network. In direct encapsulation of
IPv4/IPv6 in ULE, this is avoided by including only one SNDU Length
Field. However, this issue still arises in bridged LLC frames, and
frames with a LLC Length greater than the SNDU payload size MUST be
discarded, and an SNDU payload length error SHOULD be recorded.
In the future, a ULE Mandatory Extension Header may be used to define
a method to perform link encryption of the SNDU payload. This is as
an additional security mechanism to IP-, transport-, or application-
layer security, not a replacement [RFC4259]. The approach is generic
and decouples the encapsulation from future security extensions. The
operation provides functions that resemble those currently used with
the MPE encapsulation.
Additional security control fields may be provided as part of this
link encryption Extension Header, e.g., to associate an SNDU with one
of a set of Security Association (SA) parameters. As a part of the
encryption process, it may also be desirable to authenticate some or
all of the SNDU headers. The method of encryption and the way in
which keys are exchanged is beyond the scope of this specification,
as are the definition of the SA format and that of the related
encryption keys.
11. IANA Considerations
The IANA has created the ULE Next-Header Type field registry as
defined in this document.
ULE Next-Header registry
This registry allocates Next-Header values within the range 0-511
(decimal). For each allocated value, it also specifies the set of
allowed H-LEN values (see section 5). In combination, these
define a set of allowed values in the range 0-1535 for the first
part of the ULE Type space (see section 4.4.1).
11.1. IANA Guidelines
The following contains the IANA guidelines for management of the ULE
Next-Header registry. This registry allocates values 0-511 decimal
(0x0000-0x01FF, hexadecimal). It MUST NOT allocate values greater
than 0x01FF (decimal).
It subdivides the Next-Header registry in the following way:
1) 0-255 (decimal) IANA-assigned values, indicating Mandatory
Extension Headers (or link-dependent Type fields) for ULE,
requiring expert review leading to prior issue of an IETF RFC.
This specification MUST define the value and the name associated
with the Extension Header, together with the procedure for
processing the Extension Header. It MUST also define the need for
the Mandatory Extension and the intended use. The size of the
Extension Header MUST be specified.
Assignments have been made in this document, and registered by
IANA:
Type Name Reference
0: Test-SNDU Section 5.1
1: Bridged-SNDU Section 5.2
2) 256-511 (decimal) IANA-assigned values, indicating Optional
Extension Headers for ULE, requiring expert review leading to
prior issue of an IETF RFC. This specification MUST define the
value and the name associated with the Extension Header, together
with the procedure for processing the Extension Header. The entry
MUST specify the range of allowable H-LEN values that are
permitted (in the range 1-5). It MUST also define the need for
the Optional Extension and the intended use.
Assignments have been made in this document, and registered by
IANA:
Type Name H-LEN Reference
256: Extension-Padding 1-5 Section 5.3
12. References
12.1. Normative References
[ISO-MPEG2] IS 13818-1, "Information technology -- Generic coding
of moving pictures and associated audio information --
Part 1: Systems", International Standards Organisation
(ISO), 2000.
[RFC2119] Bradner, S., "Key Words for Use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, 1997.
[RFC1112] Deering, S., "Host extensions for IP multicasting",
STD 5, RFC 1112, August 1989.
[RFC2464] Crawford, M., "Transmission of IPv6 Packets over
Ethernet Networks", RFC 2464, December 1998.
[ULE1] Registration for format_identifier ULE1, SMPTE
Registration Authority, LLC,
http://www.smpte-ra.org/ule1.html.
12.2. Informative References
[IPDVB-AR] Fairhurst, G. and M-J. Montpetit, "Address Resolution
for IP datagrams over MPEG-2 Networks", Work in
Progress, September 2005.
[ATSC] A/53, "ATSC Digital Television Standard", Advanced
Television Systems Committee (ATSC), Doc. A/53 Rev.C,
2004
[ATSC-DAT] A/90, "ATSC Data Broadcast Standard", Advanced
Television Systems Committee (ATSC), Doc. A/090, 2000.
[ATSC-DATG] A/91, "Recommended Practice: Implementation Guidelines
for the ATSC Data Broadcast Standard", Advanced
Television Systems Committee (ATSC), Doc. A/91, 2001.
[ATSC-G] A/54, "Guide to the use of the ATSC Digital Television
Standard", Advanced Television Systems Committee
(ATSC), Doc. A/54, 1995.
[ATSC-PSIP-TC] A/65B, "Program and System Information Protocol for
Terrestrial Broadcast and Cable", Advanced Television
Systems Committee (ATSC), Doc. A/65B, 2003.
[ATSC-REG] ATSC "Code Point Registry"
www.atsc.org/standards/Code_Point_Registry.pdf.
[ATSC-S] A/80, "Modulation and Coding Requirements for Digital
TV (DTV) Applications over Satellite", Advanced
Television Systems Committee (ATSC), Doc. A/80, 1999.
[DIX] Digital Equipment Corp, Intel Corp, Xerox Corp,
"Ethernet Local Area Network Specification" Version
2.0, November 1982.
[ETSI-DAT] EN 301 192, "Specifications for Data Broadcasting",
European Telecommunications Standards Institute
(ETSI), 2004.
[ETSI-DVBC] EN 300 800, "Digital Video Broadcasting (DVB); DVB
interaction channel for Cable TV distribution systems
(CATV)", European Telecommunications Standards
Institute (ETSI), 1998.
[ETSI-DVBS] EN 300 421, "Digital Video Broadcasting (DVB);
Modulation and Coding for DBS satellite systems at
11/12 GHz", European Telecommunications Standards
Institute (ETSI), 1997.
[ETSI-DVBT] EN 300 744, "Digital Video Broadcasting (DVB); Framing
structure, channel coding and modulation for digital
terrestrial television (DVB-T)", European
Telecommunications Standards Institute (ETSI), 2004.
[ETSI-RCS] ETSI 301 790, "Digital Video Broadcasting (DVB);
Interaction Channel for Satellite Distribution
Systems", European Telecommunications Standards
Institute (ETSI), 2005.
[IEEE-802.2] IEEE 802.2, "Local and metropolitan area networks-
Specific requirements Part 2: Logical Link Control",
IEEE Computer Society, (also ISO/IEC 8802-2), 1998.
[IEEE-802.3] IEEE 802.3, "Local and metropolitan area networks-
Specific requirements Part 3: Carrier sense multiple
access with collision detection (CSMA/CD) access
method and physical layer specifications", IEEE
Computer Society, (also ISO/IEC 8802-3), 2002.
[ISO-DSMCC] IS 13818-6, "Information technology -- Generic coding
of moving pictures and associated audio information --
Part 6: Extensions for DSM-CC", International
Standards Organisation (ISO), 1998.
[ITU-H222] H.222.0, "Information technology - Generic coding of
moving pictures and associated audio information:
Systems", International Telecommunication Union,
(ITU-T), 1995.
[ITU-3563] I.363.5, "B-ISDN ATM Adaptation Layer specification:
Type 5 AAL", International Telecommunication Union,
(ITU-T), 1996.
[ISO-8802-2] ISO/IEC 8802.2, "Logical Link Control", International
Standards Organisation (ISO), 1998.
[RFC3077] Duros, E., Dabbous, W., Izumiyama, H., Fujii, N., and
Y. Zhang, "A Link-Layer Tunneling Mechanism for
Unidirectional Links", RFC 3077, March 2001.
[RFC3309] Stone, J., Stewart, R., and D. Otis, "Stream Control
Transmission Protocol (SCTP) Checksum Change", RFC
3309, September 2002.
[RFC4259] Montpetit, M.-J., Fairhurst, G., Clausen, H.,
Collini-Nocker, B., and H. Linder, "A Framework for
Transmission of IP Datagrams over MPEG-2 Networks",
RFC 4259, November 2005.
[SOOR05] M. Sooriyabandara, G. Fairhurst, A. Ang, B. Collini-
Nocker, H. Linder, W. Stering "A Lightweight
Encapsulation Protocol for IP over MPEG-2 Networks:
Design, Implementation and Analysis", Computer
Networks 48 p5-19, 2005.
Appendix A: SNDU Packing Examples
This appendix provides some examples of use. The appendix is
informative. It does not provide a description of the protocol. The
examples provide the complete TS Packet sequence for some sample
encapsulated IP packets.
The specification of the TS Packet header operation and field values
is provided in [ISO-MPEG2]. The specification of ULE is provided in
the body of this document.
The key below is provided for the following examples.
HDR 4B TS Packet Header
PUSI Payload Unit Start Indicator
PP Payload Pointer
*** TS Packet Payload Pointer (PP)
Example A.1: Two 186B PDUs.
SNDU A is 200 bytes (including the ULE destination NPA address)
SNDU B is 200 bytes (including the ULE destination NPA address)
The sequence comprises 3 TS Packets:
SNDU
PP=0 Length
+-----+------+------+------+- -+------+
| HDR | 0x00 | 0x00 | 0xC4 | ... | A182 |
+-----+----*-+-*----+------+- -+------+
PUSI=1 * *
*****
SNDU
PP=17 CRC for A Length
+-----+------+------+- -+--- --+------+------+- -+------+
| HDR | 0x11 | A183 | ... | A199 | 0x00 | 0xC4 | ... | B165 |
+-----+----*-+------+- -+------+-*----+------+- -+------+
PUSI=1 * *
*************************
End Stuffing
CRC for A Indicator Bytes
+-----+------+- -+------+----+----+- -+----+
| HDR | B166 | ... | B199 |0xFF|0xFF| ... |0xFF|
+-----+------+- -+------+----+----+- -+----+
PUSI=0
Example A.2: Usage of last byte in a TS-Packet
SNDU A is 183 bytes
SNDU B is 182 bytes
SNDU C is 181 bytes
SNDU D is 185 bytes
The sequence comprises 4 TS Packets:
SNDU
PP=0 Length CRC for A
+-----+------+------+------+- -+------+
| HDR | 0x00 | 0x00 | 0xB3 | ... | A182 |
+-----+----*-+-*----+------+- -+------+
PUSI=1 * *
*****
SNDU Unused
PP=0 Length CRC for B byte
+-----+------+------+------+- -+------+------+
| HDR | 0x00 | 0x00 | 0xB2 | ... | B181 | 0xFF |
+-----+---*--+-*----+------+- -+------+------+
PUSI=1 * *
******
SNDU SNDU
PP=0 Length CRC for C Length
+-----+------+------+------+- -+------+------+------+
| HDR | 0x00 | 0x00 | 0xB1 | ... | C180 | 0x00 | 0x65 |
+-----+---*--+-*----+------+- -+------+------+------+
PUSI=1 * *
****** Unused
byte
+-----+------+- -+------+------+
| HDR | D002 | ... | D184 | 0xFF |
+-----+------+- -+------+------+
PUSI=0
Example A.3: Large SNDUs
SNDU A is 732 bytes
SNDU B is 284 bytes
The sequence comprises 6 TS Packets:
SNDU
PP=0 Length
+-----+------+------+------+- -+------+
| HDR | 0x00 | 0x02 | 0xD8 | ... | A182 |
+-----+---*--+-*----+------+- -+------+
PUSI=1 * *
******
+-----+------+- -+------+
| HDR | A183 | ... | A366 |
+-----+------+- -+------+
PUSI=0
+-----+------+- -+------+
| HDR | A367 | ... | A550 |
+-----+------+- -+------+
PUSI=0
SNDU
PP=181 CRC for A Length
+-----+------+------+- -+------+------+------+
| HDR | 0xB5 | A551 | ... | A731 | 0x01 | 0x18 |
+-----+---*--+------+- -+------+*-----+------+
PUSI=1 * *
*************************
+-----+------+- -+------+
| HDR | B002 | ... | B185 |
+-----+------+- -+------+
PUSI=0
End Stuffing
Indicator Bytes
+-----+------+- -+------+------+------+- -+------+
| HDR | B186 | ... | B283 | 0xFF | 0xFF | ... | 0xFF |
+-----+------+- -+------+------+------+- -+------+
PUSI=0
Example A.4: Illustration of SNDU Length field
SNDU A is 200 bytes
SNDU B is 60 bytes
SNDU C is 60 bytes
The sequence comprises two TS Packets:
SNDU
PP=0 Length
+-----+------+------+------+- -+------+
| HDR | 0x00 | 0x00 | 0xC4 | ... | A182 |
+-----+----*-+-*----+------+- -+------+
PUSI=1 * * + +
***** ++++++++
+
+++++++++++++++++
+ SNDU
PP=17 CRC for A + Length
+-----+------+------+- -+------+-+----+------+-
| HDR | 0x11 | A183 | ... | A199 | 0x00 | 0x38 | ...
+-----+----*-+------+- -+------+*-----+------+-
PUSI=1 * * + +
************************ +++++++++
+
+++++++++++++++++++++++++++++++++++++++
+
+ SNDU End Stuffing
+ Length Indicator bytes
+ -+------+------+------+ -+------+------+------+- -+------+
+ ... | B59 | 0x00 | 0x38 |...| C59 | 0xFF | 0xFF |...| 0xFF |
+ -+------+-+----+------+ -+------+-+----+------+- -+------+
+ + + + +
+ + ++++++++ +
+ + + +
++++++++++++++++ ++++++++++++++++++++++
*** TS Packet Payload Pointer (PP)
+++ ULE Length Indicator
Example A.5: Three 44B PDUs.
SNDU A is 52 bytes (no ULE destination NPA address) SNDU B is 52
bytes (no ULE destination NPA address) SNDU C is 52 bytes (no ULE
destination NPA address)
The sequence comprises 1 TS Packet:
SNDU
PP=0 Length
+-----+------+------+------+- -+-----+------+------+- -+-----+-
| HDR | 0x00 | 0x80 | 0x30 | ... | A51 | 0x80 | 0x30 | ... | B51 | ..
+-----+----*-+-*----+------+- -+-----+------+------+- -+-----+-
PUSI=1 * *
*****
End Stuffing
Indicator bytes
-----+------+- -+-----+---------+- -+------+
... 0x80 | 0x30 | ... | C51 |0xFF|0xFF| | 0xFF |
-----+------+- -+-----+---------+- -+------+
Appendix B: SNDU Encapsulation
An example of ULE encapsulation carrying an ICMPv6 packet generated
by ping6.
ULE SNDU Length : 63 decimal
D-bit value : 0 (NPA destination address present)
ULE Protocol Type : 0x86dd (IPv6)
Destination ULE NPA Address : 00:01:02:03:04:05
ULE CRC32 : 0x7c171763
Source IPv6 : 2001:DB8:3008:1965::1
Destination IPv6 : 2001:DB8:2509:1962::2
SNDU contents (including CRC-32):
0000: 00 3f 86 dd 00 01 02 03 04 05 60 00 00 00 00 0d
0016: 3a 40 20 01 0d b8 30 08 19 65 00 00 00 00 00 00
0032: 00 01 20 01 0d b8 25 09 19 62 00 00 00 00 00 00
0048: 00 02 80 00 9d 8c 06 38 00 04 00 00 00 00 00 7c
0064: 17 17 63
Authors' Addresses
Godred Fairhurst
Department of Engineering
University of Aberdeen
Aberdeen, AB24 3UE
UK
EMail: gorry@erg.abdn.ac.uk
Web: http://www.erg.abdn.ac.uk/users/Gorry
Bernhard Collini-Nocker
Department of Scientific Computing
University of Salzburg
Jakob Haringer Str. 2
5020 Salzburg
Austria
EMail: bnocker@cosy.sbg.ac.at
Web: http://www.scicomp.sbg.ac.at/
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