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This document describes a fully-specified simple FEC scheme for Reed-Solomon codes over GF(2^^m), with 2 ≤ m ≤ 16, that can be used to protect arbitrary media streams along the lines defined by the FECFRAME framework. Reed-Solomon codes belong to the class of Maximum Distance Separable (MDS) codes which means they offer optimal protection against packet erasures. They are also systematic codes, which means that the source symbols are part of the encoding symbols. The price to pay is a limit on the maximum source block size, on the maximum number of encoding symbols, and a computational complexity higher than that of LDPC codes for instance.
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Copyright (c) 2010 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.
1.
Introduction
2.
Terminology
3.
Definitions Notations and Abbreviations
3.1.
Definitions
3.2.
Notations
3.3.
Abbreviations
4.
Common Procedures Related to the ADU Block and
Source Block Creation
4.1.
Restrictions
4.2.
ADU Block Creation
4.3.
Source Block Creation
5.
Simple Reed-Solomon FEC Scheme over GF(2^^m) for Arbitrary ADU Flows
5.1.
Formats and Codes
5.1.1.
FEC Framework Configuration Information
5.1.2.
Explicit Source FEC Payload ID
5.1.3.
Repair FEC Payload ID
5.2.
Procedures
5.3.
FEC Code Specification
6.
Security Considerations
6.1.
Problem Statement
6.2.
Attacks Against the Data Flow
6.2.1.
Access to Confidential Contents
6.2.2.
Content Corruption
6.3.
Attacks Against the FEC Parameters
7.
IANA Considerations
8.
Acknowledgments
9.
References
9.1.
Normative References
9.2.
Informative References
§
Authors' Addresses
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The use of Forward Error Correction (FEC) codes is a classic solution to improve the reliability of unicast, multicast and broadcast Content Delivery Protocols (CDP) and applications. The [FECFRAME‑FRAMEWORK] (Watson, M., “Forward Error Correction (FEC) Framework,” September 2010.) document 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 the [RFC5052] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.) document describes a generic framework to use FEC schemes with with objects (e.g., files) delivery applications based on the ALC [RFC5775] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” April 2010.) and NORM [RFC5740] (Adamson, B., Bormann, C., Handley, M., and J. Macker, “Negative-acknowledgment (NACK)-Oriented Reliable Multicast (NORM) Protocol,” November 2009.) reliable multicast transport protocols.
More specifically, the [RFC5053] (Luby, M., Shokrollahi, A., Watson, M., and T. Stockhammer, “Raptor Forward Error Correction Scheme,” June 2007.) and [RFC5170] (Roca, V., Neumann, C., and D. Furodet, “Low Density Parity Check (LDPC) Forward Error Correction,” June 2008.) FEC schemes introduce erasure codes based on sparse parity check matrices for object delivery protocols like ALC and NORM. These codes are efficient in terms of processing but not optimal in terms of erasure recovery capabilities when dealing with "small" objects.
The Reed-Solomon FEC codes described in this document belong to the class of Maximum Distance Separable (MDS) codes that are optimal in terms of erasure recovery capability. It means that a receiver can recover the k source symbols from any set of exactly k encoding symbols. These codes are also systematic codes, which means that the k source symbols are part of the encoding symbols. However they are limited in terms of maximum source block size and number of encoding symbols. Since the real-time constraints of media delivery applications usually limit the maximum source block size, this is not considered to be a major issue in the context of the FEC Framework for many (but not necessarily all) use-cases. Additionally, if the encoding/decoding complexity is higher with Reed-Solomon codes than it is with [RFC5053] (Luby, M., Shokrollahi, A., Watson, M., and T. Stockhammer, “Raptor Forward Error Correction Scheme,” June 2007.) or [RFC5170] (Roca, V., Neumann, C., and D. Furodet, “Low Density Parity Check (LDPC) Forward Error Correction,” June 2008.) codes, it remains reasonable for most use-cases, even in case of a software codec.
Many applications dealing with reliable content transmission or content storage already rely on packet-based Reed-Solomon erasure recovery codes. In particular, many of them use the Reed-Solomon codec of Luigi Rizzo [RS‑codec] (Rizzo, L., “Reed-Solomon FEC codec (revised version of July 2nd, 1998), available at http://info.iet.unipi.it/~luigi/vdm98/vdm980702.tgz and mirrored at http://planete-bcast.inrialpes.fr/,” July 1998.) [Rizzo97] (Rizzo, L., “Effective Erasure Codes for Reliable Computer Communication Protocols,” April 1997.). The goal of the present document is to specify a simple Reed-Solomon scheme that is compatible with this codec.
More specifically, the [RFC5510] (Lacan, J., Roca, V., Peltotalo, J., and S. Peltotalo, “Reed-Solomon Forward Error Correction (FEC) Schemes,” April 2009.) document introduced such Reed-Solomon codes and several associated FEC schemes that are compatible with the [RFC5052] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.) framework. The present document inherits from [RFC5510] (Lacan, J., Roca, V., Peltotalo, J., and S. Peltotalo, “Reed-Solomon Forward Error Correction (FEC) Schemes,” April 2009.) the specification of the core Reed-Solomon codes based on Vandermonde matrices, and specifies a simple FEC scheme that is compatible with the FECFRAME framework [FECFRAME‑FRAMEWORK] (Watson, M., “Forward Error Correction (FEC) Framework,” September 2010.). Therefore this document specifies only the information specific to the FECFRAME context and refers to [RFC5510] (Lacan, J., Roca, V., Peltotalo, J., and S. Peltotalo, “Reed-Solomon Forward Error Correction (FEC) Schemes,” April 2009.) for the core specifications of the codes. To that purpose, the present document introduces:
For instance, with this scheme, a set of Application Data Units (or ADUs) coming from one or several (resp. one) media delivery applications (e.g., a set of RTP packets), are grouped in an ADU block and FEC encoded as a whole. With Reed-Solomon codes over GF(2^^8), there is a strict limit over the number of ADUs that can be protected together, since the number of encoded symbols, n, must be inferior or equal to 255. This constraint is relaxed when using a higher finite field size (m > 8), at the price of an increased computational complexity.
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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] (Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” .).
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This document uses the following terms and definitions. Some of them are FEC scheme specific and are in line with [RFC5052] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.):
- 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 Reed-Solomon codes introduced in this document are systematic.
- 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.
Some of them are FECFRAME framework specific and are in line with [FECFRAME‑FRAMEWORK] (Watson, M., “Forward Error Correction (FEC) Framework,” September 2010.):
- Application Data Unit (ADU):
- a unit of data coming from (sender) or given to (receiver) the media delivery application. Depending on the use-case, an ADU can use an RTP encapsulation. In this specification, there is always one source symbol per ADU.
- (Source) ADU Flow:
- a flow of ADUs from a media delivery application and to which FEC protection is applied. Depending on the use-case, several ADU flows can be protected together by the FECFRAME framework.
- ADU Block:
- a set of ADUs that are considered together by the FECFRAME instance for the purpose of the FEC scheme. Along with the F[], L[], and 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 (Source Block Creation)). This is the unit of data that is used as source symbol.
- FEC Framework Configuration Information:
- the FEC scheme specific information that enables the synchronization of the FECFRAME sender and receiver instances.
- FEC Source Packet:
- a data packet submitted to (sender) or received from (receiver) the transport protocol. It contains an ADU along with its optional Explicit Source FEC Payload ID.
- FEC Repair Packet:
- a repair packet submitted to (sender) or received from (receiver) the transport protocol. It contains a repair symbol along with its Repair FEC Payload ID.
The above terminology is illustrated in Figure 1 (Terminology used in this document (sender).) (sender's point of view):
+----------------------+ | Application | +----------------------+ | ADU flow | (1) Application Data Unit (ADU) v +----------------------+ +----------------+ | FEC Framework | | | | |------------------------- >| FEC Scheme | |(2) Construct an ADU | (4) Source Symbols for | | | block | this Source Block |(5) Perform FEC | |(3) Construct ADU Info| | Encoding | |(7) Construct FEC Src |< -------------------------| | | Packets and FEC |(6) Ex src FEC Payload Ids,| | | Repair Packets | Repair FEC Payload Ids,| | +----------------------+ Repair Symbols +----------------+ | | |(8) FEC Src |(8') FEC Repair | packets | packets v v +----------------------+ | Transport Layer | | (e.g., UDP ) | +----------------------+
Figure 1: Terminology used in this document (sender). |
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This document uses the following notations: Some of them 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.
- GF(q)
- denotes a finite field (also known as Galois Field) with q elements. We assume that q = 2^^m in this document.
- m
- defines the length of the elements in the finite field, in bits. In this document, m is such that 2 ≤ m ≤ 16.
- q
- defines the number of elements in the finite field. We have: q = 2^^m in this specification.
- CR
- denotes the "code rate", i.e., the k/n ratio.
- a^^b
- denotes a raised to the power b.
Some of them are FECFRAME framework specific:
- B
- denotes the number of ADUs per ADU block.
- max_B
- denotes the maximum number of ADUs for any ADU block.
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This document uses the following abbreviations:
- ADU
- stands for Application Data Unit.
- ESI
- stands for Encoding Symbol ID.
- FEC
- stands for Forward Error (or Erasure) Correction code.
- FFCI
- stands for FEC Framework Configuration Information.
- RS
- stands for Reed-Solomon.
- MDS
- stands for Maximum Distance Separable code.
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This section introduces the procedures that are used during the ADU block and the related source block creation, for the FEC scheme considered.
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This specification has the following restrictions:
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Several aspects must be considered, that impact the ADU block creation:
We now detail each of these aspects.
The finite field size parameter, m, defines the number of non zero elements in this field which is equal to: q - 1 = 2^^m - 1. This q - 1 value is also the theoretical maximum number of encoding symbols that can be produced for a source block. For instance, when m = 8 (default) there is a maximum of 2^^8 - 1 = 255 encoding symbols. So: k < n ≤ 255. Given the target FEC code rate (e.g., provided by the end-user or upper application when starting the FECFRAME framework, and taking into account the (known or estimated) packet loss rate), the sender calculates:
max_k = floor((2^^m - 1) * CR)
This max_k value leaves enough room for the sender to produce the desired number of repair symbols. Since there is one source symbol per ADU, max_k is also an upper bound to the maximum number of ADUs per ADU block.
The source ADU flows usually have real-time constraints. It means that the maximum number of ADUs of an ADU block must not exceed a certain threshold since it directly impacts the decoding delay. It is the role of the developer, who knows the flow real-time features, to define an appropriate upper bound to the ADU block size, max_rt.
If we take into account these constraints, we find: max_B = min(max_k, max_rt). Then max_B gives an upper bound to the number of ADUs that can constitute an ADU block.
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In its most general form the FECFRAME framework and the RS 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 RS FEC scheme requires a constant encoding symbol size (E parameter) per source block. Since this specification requires that there is 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 FCCI/FSSI with S = 0, Section 5.1.1.2 (FEC Scheme-Specific Information)), 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 (Repair FEC Payload ID)), a receiver determines the E parameter used for this source block.
In situations where E is fixed (specified by the FCCI/FSSI with S = 1, Section 5.1.1.2 (FEC Scheme-Specific Information)), 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 (Source block creation, for code rate 1/2 (equal number of source and repair symbols, 4 in this example), and S = 0.)):
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 to 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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This Fully-Specified FEC Scheme specifies the use of Reed-Solomon codes over GF(2^^m), with 2 ≤ m ≤ 16, with a simple FEC encoding for arbitrary packet flows.
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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.
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- FEC Encoding ID:
- the value assigned to this fully-specified FEC scheme MUST be XXX, as assigned by IANA (Section 7 (IANA Considerations)).
When SDP is used to communicate the FFCI, this FEC Encoding ID is carried in the 'encoding-id' parameter.
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The FEC Scheme Specific Information (FSSI) includes elements that are specific to the present FEC scheme. More precisely:
- 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).
- Strict (S) flag:
- when set to 1 this flag indicates that the E parameter is valid for the whole session, unless otherwise notified. When set to 0 this flag indicates that the E parameter is only the maximum length of each encoding symbol, for the whole session, unless otherwise notified.
- m parameter (m):
- an integer that defines the length of the elements in the finite field, in bits. We have: 2 ≤ m ≤ 16.
These elements are required both by the sender (RS encoder) and the receiver(s) (RS 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 [SDP_ELEMENTS] (Begen, A., “SDP Elements for FEC Framework,” October 2010.). For instance:
fssi = E:1400,S:0,m:8
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 3 octets:
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Encoding Symbol Length (E) |S| m | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 3: FSSI encoding format. |
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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 (Structure of a FEC Source Packet with the Explicit Source FEC Payload ID.).
+--------------------------------+ | 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 Source Block Number, the Encoding Symbol ID, and the Source Block Length. The length of the first two fields depends on the m parameter (transmitted separately in the FFCI, Section 5.1.1.2 (FEC Scheme-Specific Information)):
- Source Block Number (SBN) (32-m bit field):
- this field identifies the source block to which this FEC source packet belongs.
- Encoding Symbol ID (ESI) (m 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.
- Source Block Length (k) (16 bit field):
- this field provides the number of source symbols for this source block, i.e., the k parameter. If 16 bits are too much when m ≤ 8, it is needed when 8 < m ≤ 16. Therefore we provide a single common format regardless of m.
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 (24 bits) | Enc. Symb. ID | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Source Block Length (k) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 5: Source FEC Payload ID encoding format for m = 8 (default). |
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 Nb (16 bits) | Enc. Symbol ID (16 bits) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Source Block Length (k) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 6: Source FEC Payload ID encoding format for m = 16. |
The format of the Source FEC Payload ID for m = 8 and m = 16 are illustrated in Figure 5 (Source FEC Payload ID encoding format for m = 8 (default).) and Figure 6 (Source FEC Payload ID encoding format for m = 16.) respectively.
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A FEC repair packet MUST contain a Repair FEC Payload ID that is prepended to the repair symbol(s) as illustrated in Figure 7 (Structure of a FEC Repair Packet with the Repair FEC Payload ID.). There MUST be a single repair symbol per FEC repair packet.
+--------------------------------+ | IP Header | +--------------------------------+ | Transport Header | +--------------------------------+ | Repair FEC Payload ID | +--------------------------------+ | Repair Symbol | +--------------------------------+
Figure 7: Structure of a FEC Repair Packet with the
Repair FEC Payload ID. |
More precisely, the Repair FEC Payload ID is composed of the Source Block Number, the Encoding Symbol ID, and the Source Block Length. The length of the first two fields depends on the m parameter (transmitted separately in the FFCI, Section 5.1.1.2 (FEC Scheme-Specific Information)):
- Source Block Number (SBN) (32-m bit field):
- this field identifies the source block to which the FEC repair packet belongs.
- Encoding Symbol ID (ESI) (m 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.
- Source Block Length (k) (16 bit field):
- this field provides the number of source symbols for this source block, i.e., the k parameter. If 16 bits are too much when m ≤ 8, it is needed when 8 < m ≤ 16. Therefore we provide a single common format regardless of m.
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 (24 bits) | Enc. Symb. ID | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Source Block Length (k) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 8: Repair FEC Payload ID encoding format for m = 8 (default). |
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 Nb (16 bits) | Enc. Symbol ID (16 bits) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Source Block Length (k) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 9: Repair FEC Payload ID encoding format for m = 16. |
The format of the Repair FEC Payload ID for m = 8 and m = 16 are illustrated in Figure 8 (Repair FEC Payload ID encoding format for m = 8 (default).) and Figure 9 (Repair FEC Payload ID encoding format for m = 16.) respectively.
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The following procedures apply:
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The present document inherits from [RFC5510] (Lacan, J., Roca, V., Peltotalo, J., and S. Peltotalo, “Reed-Solomon Forward Error Correction (FEC) Schemes,” April 2009.) the specification of the core Reed-Solomon codes based on Vandermonde matrices for a packet transmission channel.
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A content delivery system is potentially subject to many attacks. Some of them target the network (e.g., to compromise the routing infrastructure, by compromising the congestion control component), others target the Content Delivery Protocol (CDP) (e.g., to compromise its normal behavior), and finally some attacks target the content itself. Since this document focuses on various FEC schemes, this section only discusses the additional threats that their use within the FECFRAME framework can create to an arbitrary CDP.
More specifically, these attacks may have several goals:
These attacks can be launched either against the data flow itself (e.g., by sending forged FEC Source/Repair Packets) or against the FEC parameters that are sent either in-band (e.g., in the Repair FEC Payload ID) or out-of-band (e.g., in a session description).
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First of all, let us consider the attacks against the data flow.
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Access control to the ADU Flow being transmitted is typically provided by means of encryption. This encryption can be done within the content provider itself, by the application (for instance by using the Secure Real-time Transport Protocol (SRTP) [RFC3711] (Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, “The Secure Real-time Transport Protocol (SRTP),” March 2004.)), or at the Network Layer, on a packet per packet basis when IPSec/ESP is used [RFC4303] (Kent, S., “IP Encapsulating Security Payload (ESP),” December 2005.). If confidentiality is a concern, it is RECOMMENDED that one of these solutions be used. Even if we mention these attacks here, they are not related nor facilitated by the use of FEC.
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Protection against corruptions (e.g., after sending forged FEC Source/Repair Packets) is achieved by means of a content integrity verification/sender authentication scheme. This service is usually provided at the packet level. In this case, after removing all forged packets, the ADU Flow may be sometimes recovered. Several techniques can provide this source authentication/content integrity service:
It is up to the developer and the person in charge of deployment, who know the security requirements and features of the target application area, to define which solution is the most appropriate. Nonetheless it is RECOMMENDED that at least one of these techniques be used.
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Let us now consider attacks against the FEC parameters included in the FFCI that are usually sent out-of-band (e.g., in a session description). Attacks on these FEC parameters can prevent the decoding of the associated object. For instance modifying the m field (when applicable) will lead a receiver to consider a different code. Modifying the E parameter will lead a receiver to consider bad Repair Symbols for a received FEC Repair Packet.
It is therefore RECOMMENDED that security measures be taken to guarantee the FFCI integrity. When the FFCI is sent out-of-band in a session description, this latter SHOULD be protected, for instance by digitally signing it.
Attacks are also possible against some FEC parameters included in the Explicit Source FEC Payload ID and Repair FEC Payload ID. For instance modifying the Source Block Number of a FEC Source of Repair Packet will lead a receiver to assign this packet to a wrong block.
It is therefore RECOMMENDED that security measures be taken to guarantee the Explicit Source FEC Payload ID and Repair FEC Payload ID integrity. To that purpose, one of the packet-level source authentication/content integrity techniques of Section 6.2.2 (Content Corruption) can be used.
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The FEC Encoding ID value is subject to IANA registration.
TBD
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The authors want to thank Hitoshi Asaeda for his valuable comments.
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[RFC2119] | Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” RFC 2119. |
[RFC5052] | Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” RFC 5052, August 2007. |
[RFC5510] | Lacan, J., Roca, V., Peltotalo, J., and S. Peltotalo, “Reed-Solomon Forward Error Correction (FEC) Schemes,” RFC 5510, April 2009. |
[FECFRAME-FRAMEWORK] | Watson, M., “Forward Error Correction (FEC) Framework,” draft-ietf-fecframe-framework-10 (Work in Progress), September 2010. |
[SDP_ELEMENTS] | Begen, A., “SDP Elements for FEC Framework,” draft-ietf-fecframe-sdp-elements-10 (Work in Progress), October 2010. |
TOC |
[RS-codec] | Rizzo, L., “Reed-Solomon FEC codec (revised version of July 2nd, 1998), available at http://info.iet.unipi.it/~luigi/vdm98/vdm980702.tgz and mirrored at http://planete-bcast.inrialpes.fr/,” July 1998. |
[Rizzo97] | Rizzo, L., “Effective Erasure Codes for Reliable Computer Communication Protocols,” ACM SIGCOMM Computer Communication Review Vol.27, No.2, pp.24-36, April 1997. |
[RFC5170] | Roca, V., Neumann, C., and D. Furodet, “Low Density Parity Check (LDPC) Forward Error Correction,” RFC 5170, June 2008. |
[RFC5053] | Luby, M., Shokrollahi, A., Watson, M., and T. Stockhammer, “Raptor Forward Error Correction Scheme,” RFC 5053, June 2007. |
[RFC5775] | Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” RFC 5775, April 2010 (TXT). |
[RFC5740] | Adamson, B., Bormann, C., Handley, M., and J. Macker, “Negative-acknowledgment (NACK)-Oriented Reliable Multicast (NORM) Protocol,” RFC 5740, November 2009. |
[RFC4303] | Kent, S., “IP Encapsulating Security Payload (ESP),” RFC 4303, December 2005 (TXT). |
[RFC3711] | Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, “The Secure Real-time Transport Protocol (SRTP),” RFC 3711, March 2004 (TXT). |
[RFC4383] | Baugher, M. and E. Carrara, “The Use of Timed Efficient Stream Loss-Tolerant Authentication (TESLA) in the Secure Real-time Transport Protocol (SRTP),” RFC 4383, February 2006 (TXT). |
TOC |
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 | |
NICTA | |
Australia | |
Email: | mathieu.cunche@nicta.com.au |
URI: | http://mathieu.cunche.free.fr/ |
Jerome Lacan | |
ISAE/LAAS-CNRS | |
1, place Emile Blouin | |
Toulouse 31056 | |
France | |
Email: | jerome.lacan@isae.fr |
URI: | http://dmi.ensica.fr/auteur.php3?id_auteur=5 |
Amine Bouabdallah | |
ISAE/LAAS-CNRS | |
1, place Emile Blouin | |
Toulouse 31056 | |
France | |
Email: | Amine.Bouabdallah@isae.fr |
URI: | http://dmi.ensica.fr/ |
Kazuhisa Matsuzono | |
Keio University | |
Graduate School of Media and Governance | |
5322 Endo | |
Fujisawa, Kanagawa 252-8520 | |
Japan | |
Email: | kazuhisa@sfc.wide.ad.jp |