Internet Engineering Task Force (IETF) V. Roca
Request for Comments: 6816 INRIA
Category: Standards Track M. Cunche
ISSN: 2070-1721 INSA-Lyon/INRIA
J. Lacan
ISAE, Univ. of Toulouse
December 2012
Simple Low-Density Parity Check (LDPC) Staircase
Forward Error Correction (FEC) Scheme for FECFRAME
Abstract
This document describes a fully specified simple Forward Error
Correction (FEC) scheme for Low-Density Parity Check (LDPC) Staircase
codes that can be used to protect media streams along the lines
defined by FECFRAME. These codes have many interesting properties:
they are systematic codes, they perform close to ideal codes in many
use-cases, and they also feature very high encoding and decoding
throughputs. LDPC-Staircase codes are therefore a good solution to
protect a single high bitrate source flow or to protect globally
several mid-rate flows within a single FECFRAME instance. They are
also a good solution whenever the processing load of a software
encoder or decoder must be kept to a minimum.
Status of This Memo
This is an Internet Standards Track document.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Further information on
Internet Standards is available in Section 2 of RFC 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/rfc6816.
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RFC 6816 Simple LDPC-Staircase FEC Scheme December 2012
Copyright Notice
Copyright (c) 2012 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
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RFC 6816 Simple LDPC-Staircase FEC Scheme December 2012
Table of Contents
1. Introduction ....................................................4
2. Terminology .....................................................5
3. Definitions Notations and Abbreviations .........................5
3.1. Definitions ................................................5
3.2. Notations ..................................................7
3.3. Abbreviations ..............................................8
4. Common Procedures Related to the ADU Block and Source
Block Creation ..................................................8
4.1. Restrictions ...............................................9
4.2. ADU Block Creation .........................................9
4.3. Source Block Creation .....................................11
5. LDPC-Staircase FEC Scheme for Arbitrary ADU Flows ..............13
5.1. Formats and Codes .........................................13
5.1.1. FEC Framework Configuration Information ............13
5.1.2. Explicit Source FEC Payload ID .....................14
5.1.3. Repair FEC Payload ID ..............................16
5.2. Procedures ................................................17
5.3. FEC Code Specification ....................................17
6. Security Considerations ........................................17
6.1. Attacks against the Data Flow .............................17
6.1.1. Access to Confidential Content .....................17
6.1.2. Content Corruption .................................18
6.2. Attacks against the FEC Parameters ........................18
6.3. When Several Source Flows Are to Be Protected Together ....19
6.4. Baseline Secure FEC Framework Operation ...................19
7. Operations and Management Considerations .......................19
7.1. Operational Recommendations ...............................19
8. IANA Considerations ............................................21
9. Acknowledgments ................................................21
10. References ....................................................21
10.1. Normative References .....................................21
10.2. Informative References ...................................22
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1. Introduction
The use of Forward Error Correction (FEC) codes is a classic solution
to improve the reliability of unicast, multicast, and broadcast
Content Delivery Protocols (CDPs) and applications [RFC3453].
"Forward Error Correction (FEC) Framework" [RFC6363] describes a
generic framework to use FEC schemes with media delivery applications
and, for instance, with real-time streaming media applications based
on the RTP real-time protocol. Similarly, "Forward Error Correction
(FEC) Building Block" [RFC5052] describes a generic framework to use
FEC schemes with objects (e.g., files) delivery applications based on
either the Asynchronous Layered Coding (ALC) [RFC5775] or the NACK-
Oriented Reliable Multicast (NORM) [RFC5740] protocols.
More specifically, the [RFC5053] (Raptor) and [RFC5170] (LDPC-
Staircase and LDPC-Triangle) FEC schemes introduce erasure codes
based on sparse parity check matrices for object delivery protocols
like ALC and NORM. Similarly, "Reed-Solomon Forward Error Correction
(FEC) Schemes" [RFC5510] introduces Reed-Solomon codes based on
Vandermonde matrices for the same object delivery protocols. All
these codes are systematic codes, meaning that the k source symbols
are part of the n encoding symbols. Additionally, the Reed-Solomon
FEC codes belong to the class of Maximum Distance Separable (MDS)
codes that are optimal in terms of erasure recovery capabilities. It
means that a receiver can recover the k source symbols from any set
of exactly k encoding symbols out of n. This is not the case with
either Raptor or LDPC-Staircase codes, and these codes require a
certain number of encoding symbols in excess to k. However, this
number is small in practice when an appropriate decoding scheme is
used at the receiver [Cunche08]. Another key difference is the high
encoding/decoding complexity of Reed-Solomon codecs compared to
Raptor or LDPC-Staircase codes. A difference of one or more orders
of magnitude in terms of encoding/decoding speed exists between the
Reed-Solomon and LDPC-Staircase software codecs
[Cunche08][CunchePHD10]. Finally, Raptor and LDPC-Staircase codes
are large block FEC codes, in the sense of [RFC3453], since they can
efficiently deal with a large number of source symbols.
The present document focuses on LDPC-Staircase codes that belong to
the well-known class of "Low Density Parity Check" codes. Because of
their key features, these codes are a good solution in many
situations, as detailed in Section 7.
This document inherits from [RFC5170], Section 6 "Full Specification
of the LDPC-Staircase Scheme", the specifications of the core LDPC-
Staircase codes, and from Section 5.7 "Pseudo-Random Number
Generator", the specifications of the PRNG used by these codes.
Therefore, this document specifies only the information specific to
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the FECFRAME context and refers to [RFC5170] for the core
specifications of the codes. To that purpose, the present document
introduces:
o the Fully Specified FEC Scheme with FEC Encoding ID 7 that
specifies a simple way of using LDPC-Staircase codes in order to
protect arbitrary Application Data Unit (ADU) flows.
Therefore Sections 4 and 5 (except Section 5.7, see above) of
[RFC5170], that define [RFC5052] specific Formats and Procedures, are
not considered and are replaced by FECFRAME specific Formats and
Procedures.
Finally, publicly available reference implementations of these codes
are available [LDPC-codec] [LDPC-codec-OpenFEC].
2. Terminology
The 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 RFC 2119 [RFC2119].
3. Definitions Notations and Abbreviations
3.1. Definitions
This document uses the following terms and definitions. Those in the
list below are FEC scheme specific and are in line with [RFC5052]:
Source symbol: unit of data used during the encoding process. In
this specification, there is always one source symbol per ADU.
Encoding symbol: unit of data generated by the encoding process.
With systematic codes, source symbols are part of the encoding
symbols.
Repair symbol: encoding symbol that is not a source symbol.
Code rate: the k/n ratio, i.e., the ratio between the number of
source symbols and the number of encoding symbols. By definition,
the code rate is such that: 0 < code rate <= 1. A code rate close
to 1 indicates that a small number of repair symbols have been
produced during the encoding process.
Systematic code: FEC code in which the source symbols are part of
the encoding symbols. The LDPC-Staircase codes introduced in this
document are systematic.
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Source block: a block of k source symbols that are considered
together for the encoding.
Packet erasure channel: a communication path where packets are
either dropped (e.g., by a congested router, or because the number
of transmission errors exceeds the correction capabilities of the
physical layer codes) or received. When a packet is received, it
is assumed that this packet is not corrupted.
The following are FECFRAME specific and are in line with [RFC6363]:
Application Data Unit (ADU): the unit of source data provided as
payload to the transport layer. Depending on the use-case, an ADU
may use an RTP encapsulation.
(Source) ADU Flow: a sequence of ADUs associated with a transport-
layer flow identifier (such as the standard 5-tuple {Source IP
address, source port, destination IP address, destination port,
transport protocol}). Depending on the use-case, several ADU
flows may be protected together by FECFRAME.
ADU Block: a set of ADUs that are considered together by the
FECFRAME instance for the purpose of the FEC scheme. Along with
the flow ID (F[]), length (L[]), and padding (Pad[]) fields, they
form the set of source symbols over which FEC encoding will be
performed.
ADU Information (ADUI): a unit of data constituted by the ADU and
the associated Flow ID, Length, and Padding fields (Section 4.3).
This is the unit of data that is used as source symbol.
FEC Framework Configuration Information (FFCI): information that
controls the operation of the FEC Framework. The FFCI enables the
synchronization of the FECFRAME sender and receiver instances.
FEC Source Packet: at a sender (respectively, at a receiver) a
payload submitted to (respectively, received from) the transport
protocol containing an ADU along with an optional Explicit Source
FEC Payload ID.
FEC Repair Packet: at a sender (respectively, at a receiver) a
payload submitted to (respectively, received from) the transport
protocol containing one repair symbol along with a Repair FEC
Payload ID and possibly an RTP header.
The above terminology is illustrated in Figure 1 (sender's point of
view):
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+----------------------+
| Application |
+----------------------+
|
| (1) Application Data Units (ADUs)
|
v
+----------------------+ +----------------+
| FEC Framework | | |
| |-------------------------->| FEC Scheme |
|(2) Construct source |(3) Source Block | |
| blocks | |(4) FEC Encoding|
|(6) Construct FEC |<--------------------------| |
| source and repair | | |
| packets |(5) Explicit Source FEC | |
+----------------------+ Payload IDs +----------------+
| Repair FEC Payload IDs
| Repair symbols
|
|(7) FEC source and repair packets
v
+----------------------+
| Transport Layer |
| (e.g., UDP) |
+----------------------+
Figure 1: Terminology Used in This Document (Sender)
3.2. Notations
This document uses the following notations. Those in the list below
are FEC scheme specific:
k denotes the number of source symbols in a source block.
max_k denotes the maximum number of source symbols for any source
block.
n denotes the number of encoding symbols generated for a source
block.
E denotes the encoding symbol length in bytes.
CR denotes the "code rate", i.e., the k/n ratio.
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N1 denotes the target number of "1s" per column in the left side
of the parity check matrix.
N1m3 denotes the value N1 - 3.
G G denotes the number of encoding symbols per group, i.e., the
number of symbols sent in the same packet.
a^^b denotes a raised to the power b.
The following are FECFRAME specific:
B denotes the number of ADUs per ADU block.
max_B denotes the maximum number of ADUs for any ADU block.
3.3. Abbreviations
This document uses the following abbreviations:
ADU Application Data Unit
ESI Encoding Symbol ID
FEC Forward Error (or Erasure) Correction
FFCI FEC Framework Configuration Information
FSSI FEC Scheme-Specific Information
LDPC Low-Density Parity Check
MDS Maximum Distance Separable
PRNG Pseudo-Random Number Generator
SDP Session Description Protocol
4. Common Procedures Related to the ADU Block and Source Block Creation
This section introduces the procedures that are used during the ADU
block and related source block creation, for the FEC scheme
considered.
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4.1. Restrictions
This specification has the following restrictions:
o there MUST be exactly one source symbol per ADUI, and therefore
per ADU;
o there MUST be exactly one repair symbol per FEC repair packet;
o there MUST be exactly one source block per ADU block;
o the use of the LDPC-Staircase scheme is such that there MUST be
exactly one encoding symbol per group; i.e., G MUST be equal to 1
[RFC5170];
4.2. ADU Block Creation
Two kinds of limitations exist that impact the ADU block creation:
o at the FEC scheme level: the FEC scheme and the FEC codec have
limitations that define a maximum source block size;
o at the FECFRAME instance level: the target use-case can have real-
time constraints that can/will define a maximum ADU block size;
Note that the use of the terminology "maximum source block size" and
"maximum ADU block size" depends on the point of view that is adopted
(FEC scheme versus FECFRAME instance). However, in this document,
both refer to the same value since Section 4.1 requires there be
exactly one source symbol per ADU. We now detail each of these
aspects.
The maximum source block size in symbols, max_k, depends on several
parameters: the code rate (CR) and the Encoding Symbol ID (ESI) field
length in the Explicit Source/Repair FEC Payload ID (16 bits), as
well as possible internal codec limitations. More specifically,
max_k cannot be larger than the following values, derived from the
ESI field size limitation, for a given code rate:
max1_k = 2^^(16 - ceil(Log2(1/CR)))
Some common max1_k values are:
o CR == 1 (no repair symbol): max1_k = 2^^16 = 65536 symbols
o 1/2 <= CR < 1: max1_k = 2^^15 = 32,768 symbols
o 1/4 <= CR < 1/2: max1_k = 2^^14 = 16,384 symbols
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Additionally, a codec can impose other limitations on the maximum
source block size, for instance, because of a limited working memory
size. This decision MUST be clarified at implementation time, when
the target use-case is known. This results in a max2_k limitation.
Then, max_k is given by:
max_k = min(max1_k, max2_k)
Note that this calculation is only required at the encoder (sender),
since the actual k parameter (k <= max_k) is communicated to the
decoder (receiver) through the Explicit Source/Repair FEC Payload ID.
The source ADU flows can have real-time constraints. When there are
multiple flows, with different real-time constraints, let us consider
the most stringent constraints (see [RFC6363], Section 10.2, item 6,
for recommendations when several flows are globally protected). In
that case the maximum number of ADUs of an ADU block must not exceed
a certain threshold since it directly impacts the decoding delay.
The larger the ADU block size, the longer a decoder may have to wait
until it has received a sufficient number of encoding symbols for
decoding to succeed, and therefore the larger the decoding delay.
When the target use-case is known, these real-time constraints result
in an upper bound to the ADU block size, max_rt.
For instance, if the use-case specifies a maximum decoding latency,
l, and if each source ADU covers a duration d of a continuous media
(we assume here the simple case of a constant bit rate ADU flow),
then the ADU block size must not exceed:
max_rt = floor(l / d)
After encoding, this block will produce a set of at most n = max_rt /
CR encoding symbols. These n encoding symbols will have to be sent
at a rate of n / l packets per second. For instance, with d = 10 ms,
l = 1 s, max_rt = 100 ADUs.
If we take into account all these constraints, we find:
max_B = min(max_k, max_rt)
This max_B parameter is an upper bound to the number of ADUs that can
constitute an ADU block.
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4.3. Source Block Creation
In its most general form, FECFRAME and the LDPC-Staircase FEC Scheme
are meant to protect a set of independent flows. Since the flows
have no relationship to one another, the ADU size of each flow can
potentially vary significantly. Even in the special case of a single
flow, the ADU sizes can largely vary (e.g., the various frames of a
Group of Pictures (GOP) of an H.264 flow). This diversity must be
addressed since the LDPC-Staircase FEC Scheme requires a constant
encoding symbol size (E parameter) per source block. Since this
specification requires that there be only one source symbol per ADU,
E must be large enough to contain all the ADUs of an ADU block along
with their prepended 3 bytes (see below).
In situations where E is determined per source block (default,
specified by the FFCI/FSSI with S = 0, Section 5.1.1.2), E is equal
to the size of the largest ADU of this source block plus three (for
the prepended 3 bytes, see below). In this case, upon receiving the
first FEC repair packet for this source block, since this packet MUST
contain a single repair symbol (Section 5.1.3), a receiver determines
the E parameter used for this source block.
In situations where E is fixed (specified by the FFCI/FSSI with S =
1, Section 5.1.1.2), then E must be greater or equal to the size of
the largest ADU of this source block plus three (for the prepended 3
bytes, see below). If this is not the case, an error is returned.
How to handle this error is use-case specific (e.g., a larger E
parameter may be communicated to the receivers in an updated FFCI
message, using an appropriate mechanism) and is not considered by
this specification.
The ADU block is always encoded as a single source block. There are
a total of B <= max_B ADUs in this ADU block. For the ADU i, with 0
<= i <= B-1, 3 bytes are prepended (Figure 2):
o The first byte, F[i] (Flow ID), contains the integer identifier
associated to the source ADU flow to which this ADU belongs. It
is assumed that a single byte is sufficient, or said differently,
that no more than 256 flows will be protected by a single instance
of FECFRAME.
o The following two bytes, L[i] (Length), contain the length of this
ADU, in network byte order (i.e., big endian). This length is for
the ADU itself and does not include the F[i], L[i], or Pad[i]
fields.
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Then, zero padding is added to ADU i (if needed) in field Pad[i], for
alignment purposes up to a size of exactly E bytes. The data unit
resulting from the ADU i and the F[i], L[i], and Pad[i] fields is
called ADU Information (or ADUI). Each ADUI contributes to exactly
one source symbol of the source block.
Encoding Symbol Length (E)
< -------------------------------------------------------------- >
+----+----+-----------------------+------------------------------+
|F[0]|L[0]| ADU[0] | Pad[0] |
+----+----+----------+------------+------------------------------+
|F[1]|L[1]| ADU[1] | Pad[1] |
+----+----+----------+-------------------------------------------+
|F[2]|L[2]| ADU[2] |
+----+----+------+-----------------------------------------------+
|F[3]|L[3]|ADU[3]| Pad[3] |
+----+----+------+-----------------------------------------------+
\_______________________________ _______________________________/
\/
simple FEC encoding
+----------------------------------------------------------------+
| Repair 4 |
+----------------------------------------------------------------+
. .
. .
+----------------------------------------------------------------+
| Repair 7 |
+----------------------------------------------------------------+
Figure 2: Source Block Creation, for Code Rate 1/2 (Equal Number of
Source and Repair Symbols, 4 in This Example), and S = 0
Note that neither the initial 3 bytes nor the optional padding are
sent over the network. However, they are considered during FEC
encoding. It means that a receiver who lost a certain FEC source
packet (e.g., the UDP datagram containing this FEC source packet)
will be able to recover the ADUI if FEC decoding succeeds. Thanks to
the initial 3 bytes, this receiver will get rid of the padding (if
any) and identify the corresponding ADU flow.
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5. LDPC-Staircase FEC Scheme for Arbitrary ADU Flows
5.1. Formats and Codes
5.1.1. FEC Framework Configuration Information
The FEC Framework Configuration Information (or FFCI) includes
information that MUST be communicated between the sender and
receiver(s). More specifically, it enables the synchronization of
the FECFRAME sender and receiver instances. It includes both
mandatory elements and scheme-specific elements, as detailed below.
5.1.1.1. Mandatory Information
o FEC Encoding ID: the value assigned to this fully specified FEC
scheme MUST be 7, as assigned by IANA (Section 8).
When SDP is used to communicate the FFCI, this FEC Encoding ID is
carried in the 'encoding-id' parameter.
5.1.1.2. FEC Scheme-Specific Information
The FEC Scheme-Specific Information (FSSI) includes elements that are
specific to the present FEC scheme. More precisely:
o PRNG seed (seed): a non-negative 32-bit integer used as the seed
of the Pseudo-Random Number Generator, as defined in [RFC5170].
o Encoding symbol length (E): a non-negative integer that indicates
either the length of each encoding symbol in bytes (strict mode,
i.e., if S = 1) or the maximum length of any encoding symbol
(i.e., if S = 0).
o Strict (S) flag: when set to 1, this flag indicates that the E
parameter is the actual encoding symbol length value for each
block of the session (unless otherwise notified by an updated FFCI
if this possibility is considered by the use-case or CDP). When
set to 0, this flag indicates that the E parameter is the maximum
encoding symbol length value for each block of the session (unless
otherwise notified by an updated FFCI if this possibility is
considered by the use-case or CDP).
o N1 minus 3 (n1m3): an integer between 0 (default) and 7,
inclusive. The number of "1s" per column in the left side of the
parity check matrix, N1, is then equal to N1m3 + 3, as specified
in [RFC5170].
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These elements are required both by the sender (LDPC-Staircase
encoder) and the receiver(s) (LDPC-Staircase decoder).
When SDP is used to communicate the FFCI, this FEC scheme-specific
information is carried in the 'fssi' parameter in textual
representation as specified in [RFC6364]. For instance:
fssi=seed:1234,E:1400,S:0,n1m3:0
If another mechanism requires the FSSI to be carried as an opaque
octet string (for instance, after a Base64 encoding), the encoding
format consists of the following 7 octets:
o PRNG seed (seed): 32-bit field.
o Encoding symbol length (E): 16-bit field.
o Strict (S) flag: 1-bit field.
o Reserved: a 4-bit field that MUST be set to zero.
o N1m3 parameter (n1m3): 3-bit field.
0 1 2
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| PRNG seed (seed) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Encoding Symbol Length (E) |S| resvd | n1m3|
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 3: FSSI Encoding Format
5.1.2. Explicit Source FEC Payload ID
A FEC source packet MUST contain an Explicit Source FEC Payload ID
that is appended to the end of the packet as illustrated in Figure 4.
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+--------------------------------+
| IP Header |
+--------------------------------+
| Transport Header |
+--------------------------------+
| ADU |
+--------------------------------+
| Explicit Source FEC Payload ID |
+--------------------------------+
Figure 4: Structure of a FEC Source Packet with the
Explicit Source FEC Payload ID
More precisely, the Explicit Source FEC Payload ID is composed of the
following fields (Figure 5):
o Source Block Number (SBN) (16-bit field): this field identifies
the source block to which this FEC source packet belongs.
o Encoding Symbol ID (ESI) (16-bit field): this field identifies the
source symbol contained in this FEC source packet. This value is
such that 0 <= ESI <= k - 1 for source symbols.
o Source Block Length (k) (16-bit field): this field provides the
number of source symbols for this source block, i.e., the k
parameter.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Source Block Number (SBN) | Encoding Symbol ID (ESI) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Source Block Length (k) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 5: Source FEC Payload ID Encoding Format
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5.1.3. Repair FEC Payload ID
A FEC repair packet MUST contain a Repair FEC Payload ID that is
prepended to the repair symbol(s) as illustrated in Figure 6. There
MUST be a single repair symbol per FEC repair packet.
+--------------------------------+
| IP Header |
+--------------------------------+
| Transport Header |
+--------------------------------+
| Repair FEC Payload ID |
+--------------------------------+
| Repair Symbol |
+--------------------------------+
Figure 6: Structure of a FEC Repair Packet with
the Repair Payload ID
More precisely, the Repair FEC Payload ID is composed of the
following fields (Figure 7):
o Source Block Number (SBN) (16-bit field): this field identifies
the source block to which the FEC repair packet belongs.
o Encoding Symbol ID (ESI) (16-bit field): this field identifies the
repair symbol contained in this FEC repair packet. This value is
such that k <= ESI <= n - 1 for repair symbols.
o Source Block Length (k) (16-bit field): this field provides the
number of source symbols for this source block, i.e., the k
parameter.
o Number of Encoding Symbols (n) (16-bit field): this field provides
the number of encoding symbols for this source block, i.e., the n
parameter.
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Source Block Number (SBN) | Encoding Symbol ID (ESI) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Source Block Length (k) | Number Encoding Symbols (n) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 7: Repair FEC Payload ID Encoding Format
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5.2. Procedures
The following procedures apply:
o The source block creation MUST follow the procedures specified in
Section 4.3.
o The SBN value MUST start with value 0 for the first block of the
ADU flow and MUST be incremented by 1 for each new source block.
Wrapping to zero will happen for long sessions, after value 2^^16
- 1.
o The ESI of encoding symbols MUST start with value 0 for the first
symbol and MUST be managed sequentially. The first k values (0 <=
ESI <= k - 1) identify source symbols whereas the last n-k values
(k <= ESI <= n - 1) identify repair symbols.
o The FEC repair packet creation MUST follow the procedures
specified in Section 5.1.3.
5.3. FEC Code Specification
The present document inherits from [RFC5170] the specification of the
core LDPC-Staircase codes for a packet erasure transmission channel
(see Section 1).
Because of the requirement to have exactly one encoding symbol per
group, i.e., because G MUST be equal to 1 (Section 4.1), several
parts of [RFC5170] are not of use. In particular, this is the case
of Section 5.6, "Identifying the G Symbols of an Encoding Symbol
Group".
6. Security Considerations
The FEC Framework document [RFC6363] provides a comprehensive
analysis of security considerations applicable to FEC schemes.
Therefore, the present section follows the security considerations
section of [RFC6363] and only discusses topics that are specific to
the use of LDPC-Staircase codes.
6.1. Attacks against the Data Flow
6.1.1. Access to Confidential Content
The LDPC-Staircase FEC Scheme specified in this document does not
change the recommendations of [RFC6363]. To summarize, if
confidentiality is a concern, it is RECOMMENDED that one of the
solutions mentioned in [RFC6363] be used, with special considerations
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to the way this solution is applied (e.g., Is encryption applied
before or after FEC protection? Is it within the end-system or in a
middlebox?), to the operational constraints (e.g., performing FEC
decoding in a protected environment may be complicated or even
impossible) and to the threat model.
6.1.2. Content Corruption
The LDPC-Staircase FEC Scheme specified in this document does not
change the recommendations of [RFC6363]. To summarize, it is
RECOMMENDED that one of the solutions mentioned in [RFC6363] be used
on both the FEC source and repair packets.
6.2. Attacks against the FEC Parameters
The FEC scheme specified in this document defines parameters that can
be the basis of several attacks. More specifically, the following
parameters of the FFCI may be modified by an attacker
(Section 5.1.1.2):
o FEC Encoding ID: changing this parameter leads the receiver to
consider a different FEC scheme, which enables an attacker to
create a Denial of Service (DoS).
o Encoding symbol length (E): setting this E parameter to a value
smaller than the valid one enables an attacker to create a DoS
since the repair symbols and certain source symbols will be larger
than E, which is an incoherency for the receiver. Setting this E
parameter to a value larger than the valid one has similar impacts
when S=1 since the received repair symbol size will be smaller
than expected. Contrarily, it will not lead to any incoherency
when S=0 since the actual symbol length value for the block is
determined by the size of any received repair symbol, as long as
this value is smaller than E. However, setting this E parameter
to a larger value may have impacts on receivers that pre-allocate
memory space in advance to store incoming symbols.
o Strict (S) flag: flipping this S flag from 0 to 1 (i.e., E is now
considered as a strict value) enables an attacker to mislead the
receiver if the actual symbol size varies over different source
blocks. Flipping this S flag from 1 to 0 has no major
consequences unless the receiver requires to have a fixed E value
(e.g., because the receiver pre-allocates memory space).
o N1 minus 3 (n1m3): changing this parameter leads the receiver to
consider a different code, which enables an attacker to create a
DoS.
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Therefore, it is RECOMMENDED that security measures be taken to
guarantee the FFCI integrity, as specified in [RFC6363]. How to
achieve this depends on the way the FFCI is communicated from the
sender to the receiver, which is not specified in this document.
Similarly, attacks are possible against the Explicit Source FEC
Payload ID and Repair FEC Payload ID: by modifying the Source Block
Number (SBN), or the Encoding Symbol ID (ESI), or the Source Block
Length (k), or the Number Encoding Symbols (n), an attacker can
easily corrupt the block identified by the SBN. Other consequences,
that are use-case and/or CDP dependent, may also happen. It is
therefore RECOMMENDED that security measures be taken to guarantee
the FEC source and repair packets as stated in [RFC6363].
6.3. When Several Source Flows Are to Be Protected Together
The LDPC-Staircase FEC Scheme specified in this document does not
change the recommendations of [RFC6363].
6.4. Baseline Secure FEC Framework Operation
The LDPC-Staircase FEC Scheme specified in this document does not
change the recommendations of [RFC6363] concerning the use of the
IPsec/ESP security protocol as a mandatory to implement (but not
mandatory to use) security scheme. This is well suited to situations
where the only insecure domain is the one over which the FEC
Framework operates.
7. Operations and Management Considerations
The FEC Framework document [RFC6363] provides a comprehensive
analysis of operations and management considerations applicable to
FEC schemes. Therefore, the present section only discusses topics
that are specific to the use of LDPC-Staircase codes as specified in
this document.
7.1. Operational Recommendations
LDPC-Staircase codes have excellent erasure recovery capabilities
with large source blocks, close to ideal MDS codes. For instance,
independently of FECFRAME, let us consider a source block of size
k=1024 symbols, CR=2/3 (i.e., 512 repair symbols are added), N1=7,
G=1, a transmission scheme where all the symbols are sent in a random
order, and a hybrid ITerative/Maximum Likelihood (IT/ML) decoder (see
below). An ideal MDS code with code rate 2/3 can recover from
erasures up to a 33.33% channel loss rate. With LDPC-Staircase
codes, the average overhead amounts to 0.237% (i.e., receiving 2.43
symbols in addition to k, which corresponds to a 33.18% channel loss
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rate, enables a successful decoding with a probability 0.5), and an
overhead of 1.46% (i.e., receiving 15 symbols in addition to k, which
corresponds to a 32.36% channel loss rate) is sufficient to reduce
the probability that decoding fails down to 8.2*10^^-5. This is why
these codes are a good solution to protect a single high bitrate
source flow as in [Matsuzono10] or to protect globally several mid-
rate source flows within a single FECFRAME instance: in both cases,
the source block size can be assumed to be equal to a few hundred (or
more) source symbols.
LDPC-Staircase codes are also a good solution whenever the processing
load at a software encoder or decoder must be kept to a minimum.
This is true when the decoder uses an IT decoding algorithm, an ML
algorithm (we use a Gaussian Elimination as the ML algorithm) when
carefully implemented, or a mixture of both techniques, which is the
recommended solution [Cunche08][CunchePHD10][LDPC-codec-OpenFEC].
Let us consider the same conditions as above (k=1024 source symbols,
CR=2/3, N1=7, G=1), with encoding symbols of size 1024 bytes. With
an Intel Xeon 5120/1.86 GHz workstation running Linux/64 bits, the
average decoding speed is between 1.78 Gbps (overhead of 2 symbols in
addition to k, corresponding to a very bad channel with a 33.20% loss
rate, close to the theoretical decoding limit, where ML decoding is
required) and 3.91 Gbps (corresponding to a good channel with a 5%
loss rate only, where IT decoding is sufficient). Under the same
conditions, on a Samsung Galaxy SII smartphone (GT-I9100P model,
featuring an ARM Cortex-A9/1.2 GHz processor and running Android
2.3.4), the decoding speed is between 397 Mbps (bad channel with a
33.20% loss rate, close to the theoretical decoding limit) and 813
Mbps (good channel with a 5% loss rate only).
As the source block size decreases, the erasure recovery capabilities
of LDPC codes in general also decrease. In the case of LDPC-
Staircase codes, in order to limit this phenomenon, it is recommended
to use a value of the N1 parameter at least equal to 7 (e.g.,
experiments carried out in [Matsuzono10] use N1=7 if k=170 symbols,
and N1=5 otherwise). For instance, independently of FECFRAME, with a
source block of size k=256 symbols, CR=2/3 (i.e., 128 repair symbols
are added), N1=7, and G=1, the average overhead amounts to 0.706%
(i.e., receiving 1.8 symbols in addition to k enables a successful
decoding with a probability 0.5), and an overhead of 5.86% (i.e.,
receiving 15 symbols in addition to k) is sufficient to reduce the
decoding failure probability to 5.9*10^^-5.
The processing load also decreases with the source block size. For
instance, under these conditions (k=256 source symbols, CR=2/3, N1=7,
and G=1), with encoding symbols of size 1024 bytes, on a Samsung
Galaxy SII smartphone, the decoding speed is between 518 Mbps (bad
channel) and 863 Mbps (good channel with a 5% loss rate only).
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With very small source blocks (e.g., a few tens of symbols), using
for instance Reed-Solomon codes [SIMPLE_RS] or 2D parity check codes
may be more appropriate.
The way the FEC repair packets are transmitted is of high importance.
A good strategy, that works well for any kind of channel loss model,
consists in sending FEC repair packets in random order (rather than
in sequence) while FEC source packets are sent first and in sequence.
Sending all packets in a random order is another possibility, but it
requires that all repair symbols for a source block be produced
first, which adds some extra delay at a sender.
8. IANA Considerations
This document registers one value in the "FEC Framework (FECFRAME)
FEC Encoding IDs" registry [RFC6363] as follows:
o 7 refers to the Simple LDPC-Staircase FEC Scheme for Arbitrary
Packet Flows, as defined in Section 5 of this document.
9. Acknowledgments
The authors want to thank K. Matsuzono, J. Detchart, and H. Asaeda
for their contributions in evaluating the use of LDPC-Staircase codes
in the context of FECFRAME [Matsuzono10].
10. References
10.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC5170] Roca, V., Neumann, C., and D. Furodet, "Low Density
Parity Check (LDPC) Staircase and Triangle Forward Error
Correction (FEC) Schemes", RFC 5170, June 2008.
[RFC6363] Watson, M., Begen, A., and V. Roca, "Forward Error
Correction (FEC) Framework", RFC 6363, October 2011.
[RFC6364] Begen, A., "Session Description Protocol Elements for
the Forward Error Correction (FEC) Framework", RFC 6364,
October 2011.
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10.2. Informative References
[Cunche08] Cunche, M. and V. Roca, "Optimizing the Error Recovery
Capabilities of LDPC-Staircase Codes Featuring a
Gaussian Elimination Decoding Scheme", 10th IEEE
International Workshop on Signal Processing for Space
Communications (SPSC'08), October 2008.
[CunchePHD10]
Cunche, M., "High performances AL-FEC codes for the
erasure channel : variation around LDPC codes", PhD
dissertation (in French) (http://
tel.archives-ouvertes.fr/tel-00451336/en/), June 2010.
[LDPC-codec]
Cunche, M., Roca, V., Neumann, C., and J. Laboure,
"LDPC-Staircase/LDPC-Triangle Codec Reference
Implementation", INRIA Rhone-Alpes and
STMicroelectronics,
.
[LDPC-codec-OpenFEC]
"The OpenFEC project", .
[Matsuzono10]
Matsuzono, K., Detchart, J., Cunche, M., Roca, V., and
H. Asaeda, "Performance Analysis of a High-Performance
Real-Time Application with Several AL-FEC Schemes", 35th
Annual IEEE Conference on Local Computer Networks (LCN
2010), October 2010.
[RFC3453] Luby, M., Vicisano, L., Gemmell, J., Rizzo, L., Handley,
M., and J. Crowcroft, "The Use of Forward Error
Correction (FEC) in Reliable Multicast", RFC 3453,
December 2002.
[RFC5052] Watson, M., Luby, M., and L. Vicisano, "Forward Error
Correction (FEC) Building Block", RFC 5052, August 2007.
[RFC5053] Luby, M., Shokrollahi, A., Watson, M., and T.
Stockhammer, "Raptor Forward Error Correction Scheme for
Object Delivery", RFC 5053, October 2007.
[RFC5510] Lacan, J., Roca, V., Peltotalo, J., and S. Peltotalo,
"Reed-Solomon Forward Error Correction (FEC) Schemes",
RFC 5510, April 2009.
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[RFC5740] Adamson, B., Bormann, C., Handley, M., and J. Macker,
"NACK-Oriented Reliable Multicast (NORM) Transport
Protocol", RFC 5740, November 2009.
[RFC5775] Luby, M., Watson, M., and L. Vicisano, "Asynchronous
Layered Coding (ALC) Protocol Instantiation", RFC 5775,
April 2010.
[SIMPLE_RS] Roca, V., Cunche, M., Lacan, J., Bouabdallah, A., and K.
Matsuzono, "Simple Reed-Solomon Forward Error Correction
(FEC) Scheme for FECFRAME", Work in Progress, October
2012.
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Authors' Addresses
Vincent Roca
INRIA
655, av. de l'Europe
Inovallee; Montbonnot
ST ISMIER cedex 38334
France
EMail: vincent.roca@inria.fr
URI: http://planete.inrialpes.fr/people/roca/
Mathieu Cunche
INSA-Lyon/INRIA
Laboratoire CITI
6 av. des Arts
Villeurbanne cedex 69621
France
EMail: mathieu.cunche@inria.fr
URI: http://mathieu.cunche.free.fr/
Jerome Lacan
ISAE, Univ. of Toulouse
10 av. Edouard Belin; BP 54032
Toulouse cedex 4 31055
France
EMail: jerome.lacan@isae.fr
URI: http://personnel.isae.fr/jerome-lacan/
Roca, et al. Standards Track [Page 24]