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This document describes a Fully-Specified Forward Error Correction (FEC) Scheme for the Reed-Solomon FEC codes over GF(2^^m), with m in {2..16}, and its application to the reliable delivery of data objects on the packet erasure channel.
This document also describes a Fully-Specified FEC Scheme for the special case of Reed-Solomon codes over GF(2^^8) when there is no encoding symbol group.
Finally, in the context of the Under-Specified Small Block Systematic FEC Scheme (FEC Encoding ID 129), this document assigns an FEC Instance ID to the special case of Reed-Solomon codes over GF(2^^8).
Reed-Solomon codes belong to the class of Maximum Distance Separable (MDS) codes, i.e., they enable a receiver to recover the k source symbols from any set of k received symbols. The schemes described here are compatible with the implementation from Luigi Rizzo.
1.
Introduction
2.
Terminology
3.
Definitions Notations and Abbreviations
3.1.
Definitions
3.2.
Notations
3.3.
Abbreviations
4.
Formats and Codes with FEC Encoding ID 2
4.1.
FEC Payload ID
4.2.
FEC Object Transmission Information
4.2.1.
Mandatory Elements
4.2.2.
Common Elements
4.2.3.
Scheme-Specific Elements
4.2.4.
Encoding Format
5.
Formats and Codes with FEC Encoding ID 5
5.1.
FEC Payload ID
5.2.
FEC Object Transmission Information
5.2.1.
Mandatory Elements
5.2.2.
Common Elements
5.2.3.
Scheme-Specific Elements
5.2.4.
Encoding Format
6.
Procedures with FEC Encoding IDs 2 and 5
6.1.
Determining the Maximum Source Block Length (B)
6.2.
Determining the Number of Encoding Symbols of a Block
7.
Small Block Systematic FEC Scheme (FEC Encoding ID 129) and Reed-Solomon Codes over GF(2^^8)
8.
Reed-Solomon Codes Specification for the Erasure Channel
8.1.
Finite Field
8.2.
Reed-Solomon Encoding Algorithm
8.2.1.
Encoding Principles
8.2.2.
Encoding Complexity
8.3.
Reed-Solomon Decoding Algorithm
8.3.1.
Decoding Principles
8.3.2.
Decoding Complexity
8.4.
Implementation for the Packet Erasure Channel
9.
Security Considerations
9.1.
Problem Statement
9.2.
Attacks Against the Data Flow
9.3.
Attacks against the FEC parameters
10.
IANA Considerations
11.
Acknowledgments
12.
References
12.1.
Normative References
12.2.
Informative References
§
Authors' Addresses
§
Intellectual Property and Copyright Statements
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The use of Forward Error Correction (FEC) codes is a classical solution to improve the reliability of multicast and broadcast transmissions. The [2] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.) document describes a general framework to use FEC in Content Delivery Protocols (CDP). The companion document [4] (Luby, M., Vicisano, L., Gemmell, J., Rizzo, L., Handley, M., and J. Crowcroft, “The Use of Forward Error Correction (FEC) in Reliable Multicast,” December 2002.) describes some applications of FEC codes for content delivery.
Recent FEC schemes like [9] (Luby, M., Shokrollahi, A., Watson, M., and T. Stockhammer, “Raptor Forward Error Correction Scheme,” June 2007.) and [8] (Roca, V., Neumann, C., and D. Furodet, “Low Density Parity Check (LDPC) Forward Error Correction,” May 2007.) proposed erasure codes based on sparse graphs/matrices. These codes are efficient in terms of processing but not optimal in terms of correction capabilities when dealing with "small" objects.
The FEC scheme described in this document belongs to the class of Maximum Distance Separable codes that are optimal in terms of erasure correction capability. In others words, it enables a receiver to recover the k source symbols from any set of exactly k encoding symbols. Even if the encoding/decoding complexity is larger than that of [9] (Luby, M., Shokrollahi, A., Watson, M., and T. Stockhammer, “Raptor Forward Error Correction Scheme,” June 2007.) or [8] (Roca, V., Neumann, C., and D. Furodet, “Low Density Parity Check (LDPC) Forward Error Correction,” May 2007.), this family of codes is very useful.
Many applications dealing with content transmission or content storage already rely on packet-based Reed-Solomon codes. In particular, many of them use the Reed-Solomon codec of Luigi Rizzo [5] (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.). The goal of the present document to specify an implementation of Reed-Solomon codes that is compatible with this codec.
The present document:
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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 [1] (Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” .).
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This document uses the same terms and definitions as those specified in [2] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.). Additionally, it uses the following definitions:
Source symbol: unit of data used during the encoding process.
Encoding symbol: unit of data generated by the encoding process.
Repair symbol: encoding symbol that is not a source symbol.
Systematic code: FEC code in which the source symbols are part of the encoding symbols.
Source block: a block of k source symbols that are considered together for the encoding.
Encoding Symbol Group: a group of encoding symbols that are sent together within the same packet, and whose relationships to the source block can be derived from a single Encoding Symbol ID.
Source Packet: a data packet containing only source symbols.
Repair Packet: a data packet containing only repair symbols.
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This document uses the following notations:
L denotes the object transfer length in bytes.
k denotes the number of source symbols in a source block.
n_r denotes the number of repair symbols generated for a source block.
n denotes the encoding block length, i.e., the number of encoding symbols generated for a source block. Therefore: n = k + n_r.
max_n denotes the maximum number of encoding symbols generated for any source block.
B denotes the maximum source block length in symbols, i.e., the maximum number of source symbols per source block.
N denotes the number of source blocks into which the object shall be partitioned.
E denotes the encoding symbol length in bytes.
S denotes the symbol size in units of m-bit elements. When m = 8, then S and E are equal.
m defines the length of the elements in the finite field, in bits. In this document, m belongs to {2..16}.
q defines the number of elements in the finite field. We have: q = 2^^m in this specification.
G denotes the number of encoding symbols per group, i.e. the number of symbols sent in the same packet.
GM denotes the Generator Matrix of a Reed-Solomon code.
rate denotes the "code rate", i.e., the k/n ratio.
a^^b denotes a raised to the power b.
a^^-1 denotes the inverse of a.
I_k denotes the k*k identity matrix.
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This document uses the following abbreviations:
ESI stands for Encoding Symbol ID.
FEC OTI stands for FEC Object Transmission Information.
RS stands for Reed-Solomon.
MDS stands for Maximum Distance Separable code.
GF(q) denotes a finite field (also known as Galois Field) with q elements. We assume that q = 2^^m in this document.
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This section introduces the formats and codes associated to the Fully-Specified FEC Scheme with FEC Encoding ID 2 that specifies the use of Reed-Solomon codes over GF(2^^m).
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The FEC Payload ID is composed of the Source Block Number and the Encoding Symbol ID. The length of these two fields depends on the parameter m (which is transmitted in the FEC OTI) as follows:
There MUST be exactly one FEC Payload ID per source or repair packet. In case of an Encoding Symbol Group, when multiple encoding symbols are sent in the same packet, the FEC Payload ID refers to the first symbol of the packet. The other symbols can be deduced from the ESI of the first symbol by incrementing sequentially the ESI.
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 (32-8=24 bits) | Enc. Symb. ID | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 1: 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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Src Block Nb (32-16=16 bits) | Enc. Symbol ID (m=16 bits) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 2: FEC Payload ID encoding format for m = 16 |
The format of the FEC Payload ID for m = 8 and m = 16 is illustrated in Figure 1 (FEC Payload ID encoding format for m = 8 (default)) and Figure 2 (FEC Payload ID encoding format for m = 16) respectively.
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The following elements MUST be defined with the present FEC scheme:
For instance, for m = 8, for B = 2^^8 - 1 (because the codec operates on a finite field with 2^^8 elements) and if E = 1024 bytes, then the maximum transfer length is approximately equal to 2^^42 bytes (i.e., 4 Tera Bytes). Similarly, for m = 16, for B = 2^^16 - 1 and if E = 1024 bytes, then the maximum transfer length is also approximately equal to 2^^42 bytes. For larger objects, another FEC scheme, with a larger Source Block Number field in the FEC Payload ID, could be defined. Another solution consists in fragmenting large objects into smaller objects, each of them complying with the above limits.max_transfer_length = 2^^(32-m) * B * E
Section 6 (Procedures with FEC Encoding IDs 2 and 5) explains how to derive the values of each of these elements.
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The following element MUST be defined with the present FEC Scheme. It contains two distinct pieces of information:
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This section shows the two possible encoding formats of the above FEC OTI. The present document does not specify when one encoding format or the other should be used.
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The FEC OTI binary format is the following, when the EXT_FTI mechanism is used (e.g., within the ALC [10] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” February 2007.) or NORM [11] (Adamson, B., Bormann, C., Handley, M., and J. Macker, “Negative-acknowledgment (NACK)-Oriented Reliable Multicast (NORM) Protocol,” March 2007.) protocols).
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | HET = 64 | HEL = 4 | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Transfer-Length (L) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | m | G | Encoding Symbol Length (E) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Max Source Block Length (B) | Max Nb Enc. Symbols (max_n) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 3: EXT_FTI Header Format |
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When it is desired that the FEC OTI be carried in the FDT (File Delivery Table) Instance of a FLUTE session [12] (Paila, T., Walsh, R., Luby, M., Lehtonen, R., and V. Roca, “FLUTE - File Delivery over Unidirectional Transport,” October 2007.), the following XML attributes must be described for the associated object:
The FEC-OTI-Scheme-Specific-Info contains the string resulting from the Base64 encoding (in the XML Schema xs:base64Binary sense) of the following value:
0 1 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | m | G | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 4: FEC OTI Scheme Specific Information to be included in the FDT Instance |
When no m parameter is to be carried in the FEC OTI, the m field is set to 0 (which is not a valid seed value). Otherwise the m field contains a valid value as explained in Section 4.2.3 (Scheme-Specific Elements). Similarly, when no G parameter is to be carried in the FEC OTI, the G field is set to 0 (which is not a valid seed value). Otherwise the G field contains a valid value as explained in Section 4.2.3 (Scheme-Specific Elements). When neither m nor G are to be carried in the FEC OTI, then the sender simply omits the FEC-OTI-Scheme-Specific-Info attribute.
After Base64 encoding, the 2 bytes of the FEC OTI Scheme Specific Information are transformed into a string of 4 printable characters (in the 64-character alphabet) and added to the FEC-OTI-Scheme-Specific-Info attribute.
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This section introduces the formats and codes associated to the Fully-Specified FEC Scheme with FEC Encoding ID 5 that focuses on the special case of Reed-Solomon codes over GF(2^^8) and no encoding symbol group.
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The FEC Payload ID is composed of the Source Block Number and the Encoding Symbol ID:
There MUST be exactly one FEC Payload ID per source or repair packet. This FEC Payload ID refer to the one and only symbol of the packet.
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 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 5: FEC Payload ID encoding format with FEC Encoding ID 5 |
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The Common Elements are the same as those specified in Section 4.2.2 (Common Elements) when m = 8 and G = 1.
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No Scheme-Specific elements are defined by this FEC Scheme.
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This section shows the two possible encoding formats of the above FEC OTI. The present document does not specify when one encoding format or the other should be used.
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The FEC OTI binary format is the following, when the EXT_FTI mechanism is used (e.g., within the ALC [10] (Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” February 2007.) or NORM [11] (Adamson, B., Bormann, C., Handley, M., and J. Macker, “Negative-acknowledgment (NACK)-Oriented Reliable Multicast (NORM) Protocol,” March 2007.) protocols).
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | HET = 64 | HEL = 3 | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Transfer-Length (L) | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Encoding Symbol Length (E) | MaxBlkLen (B) | max_n | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 6: EXT_FTI Header Format with FEC Encoding ID 5 |
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When it is desired that the FEC OTI be carried in the FDT Instance of a FLUTE session [12] (Paila, T., Walsh, R., Luby, M., Lehtonen, R., and V. Roca, “FLUTE - File Delivery over Unidirectional Transport,” October 2007.), the following XML attributes must be described for the associated object:
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This section defines procedures that are common to FEC Encoding IDs 2 and 5. In case of FEC Encoding ID 5, m = 8 and G = 1. Note that the block partitioning algorithm is defined in [2] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.).
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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. Note that q - 1 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.
Given the target FEC code rate (e.g., provided by the user when starting a FLUTE sending application), the sender calculates:
max1_B = floor((2^^m - 1) * rate)
This max1_B value leaves enough room for the sender to produce the desired number of parity symbols.
Additionally, a codec MAY impose other limitations on the maximum block size. Yet it is not expected that such limits exist when using the default m = 8 value. This decision MUST be clarified at implementation time, when the target use case is known. This results in a max2_B limitation.
Then, B is given by:
B = min(max1_B, max2_B)
Note that this calculation is only required at the coder, since the B parameter is communicated to the decoder through the FEC OTI.
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The following algorithm, also called "n-algorithm", explains how to determine the actual number of encoding symbols for a given block.
AT A SENDER:
Input:
B: Maximum source block length, for any source block. Section 6.1 (Determining the Maximum Source Block Length (B)) explains how to determine its value.
k: Current source block length. This parameter is given by the block partitioning algorithm.
rate: FEC code rate, which is given by the user (e.g., when starting a FLUTE sending application). It is expressed as a floating point value.
Output:
max_n: Maximum number of encoding symbols generated for any source block.
n: Number of encoding symbols generated for this source block.
Algorithm:
max_n = ceil(B / rate);
if (max_n > 2^^m - 1) then return an error ("invalid code rate");
n = floor(k * max_n / B);
AT A RECEIVER:
Input:
B: Extracted from the received FEC OTI.
max_n: Extracted from the received FEC OTI.
k: Given by the block partitioning algorithm.
Output:
n
Algorithm:
n = floor(k * max_n / B);
Note that a Reed-Solomon decoder does not need to know the n value. Therefore the receiver part of the "n-algorithm" is not necessary from the Reed-Solomon decoder point of view. Yet a receiving application using the Reed-Solomon FEC scheme will sometimes need to know the n value used by the sender, for instance for memory management optimizations. To that purpose, the FEC OTI carries all the parameters needed for a receiver to execute the above algorithm.
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In the context of the Under-Specified Small Block Systematic FEC Scheme (FEC Encoding ID 129) [3] (Watson, M., “Basic Forward Error Correction (FEC) Schemes,” February 2007.), this document assigns the FEC Instance ID 0 to the special case of Reed-Solomon codes over GF(2^^8) and no encoding symbol group.
The FEC Instance ID 0 uses the Formats and Codes specified in [3] (Watson, M., “Basic Forward Error Correction (FEC) Schemes,” February 2007.).
The FEC Scheme with FEC Instance ID 0 MAY use the algorithm defined in Section 9.1. of [2] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.) to partition the file into source blocks. This FEC Scheme MAY also use another algorithm. For instance the CDP sender may change the length of each source block dynamically, depending on some external criteria (e.g., to adjust the FEC coding rate to the current loss rate experienced by NORM receivers) and inform the CDP receivers of the current block length by means of the EXT_FTI mechanism. This choice is out of the scope of the current document.
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Reed-Solomon (RS) codes are linear block codes. They also belong to the class of MDS codes. A [n,k]-RS code encodes a sequence of k source elements defined over a finite field GF(q) into a sequence of n encoding elements, where n is upper bounded by q - 1. The implementation described in this document is based on a generator matrix built from a Vandermonde matrix put into systematic form.
Section 8.1 (Finite Field) to Section 8.3 (Reed-Solomon Decoding Algorithm) specify the [n,k]-RS codes when applied to m-bit elements, and Section 8.4 (Implementation for the Packet Erasure Channel) the use of [n,k]-RS codes when applied to symbols composed of several m-bit elements, which is the target of this specification.
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A finite field GF(q) is defined as a finite set of q elements which has a structure of field. It contains necessarily q = p^^m elements, where p is a prime number. With packet erasure channels, p is always set to 2. The elements of the field GF(2^^m) can be represented by polynomials with binary coefficients (i.e., over GF(2)) of degree lower or equal than m-1. The polynomials can be associated to binary vectors of length m. For example, the vector (11001) represents the polynomial 1 + x + x^^4. This representation is often called polynomial representation. The addition between two elements is defined as the addition of binary polynomials in GF(2) and the multiplication is the multiplication modulo a given irreducible polynomial over GF(2) of degree m with coefficients in GF(2). Note that all the roots of this polynomial are in GF(2^^m) but not in GF(2).
A finite field GF(2^^m) is completely characterized by the irreducible polynomial. The following polynomials are chosen to represent the field GF(2^^m), for m varying from 2 to 16:
m = 2, "111" (1+x+x^^2)
m = 3, "1101", (1+x+x^^3)
m = 4, "11001", (1+x+x^^4)
m = 5, "101001", (1+x^^2+x^^5)
m = 6, "1100001", (1+x+x^^6)
m = 7, "10010001", (1+x^^3+x^^7)
m = 8, "101110001", (1+x^^2+x^^3+x^^4+x^^8)
m = 9, "1000100001", (1+x^^4+x^^9)
m = 10, "10010000001", (1+x^^3+x^^10)
m = 11, "101000000001", (1+x^^2+x^^11)
m = 12, "1100101000001", (1+x+x^^4+x^^6+x^^12)
m = 13, "11011000000001", (1+x+x^^3+x^^4+x^^13)
m = 14, "110000100010001", (1+x+x^^6+x^^10+x^^14)
m = 15, "1100000000000001", (1+x+x^^15)
m = 16, "11010000000010001", (1+x+x^^3+x^^12+x^^16)
In order to facilitate the implementation, these polynomials are also primitive. This means that any element of GF(2^^m) can be expressed as a power of a given root of this polynomial. These polynomials are also chosen so that they contain the minimum number of monomials.
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Let s = (s_0, ..., s_{k-1}) be a source vector of k elements over GF(2^^m). Let e = (e_0, ..., e_{n-1}) be the corresponding encoding vector of n elements over GF(2^^m). Being a linear code, encoding is performed by multiplying the source vector by a generator matrix, GM, of k rows and n columns over GF(2^^m). Thus:
e = s * GM.
The definition of the generator matrix completely characterizes the RS code.
Let us consider that: n = 2^^m - 1 and: 0 < k ≤ n. Let us denote by alpha the root of the primitive polynomial of degree m chosen in the list of Section 8.1 (Finite Field) for the corresponding value of m. Let us consider a Vandermonde matrix of k rows and n columns, denoted by V_{k,n}, and built as follows: the {i, j} entry of V_{k,n} is v_{i,j} = alpha^^(i*j), where 0 ≤ i ≤ k - 1 and 0 ≤ j ≤ n - 1. This matrix generates a MDS code. However, this MDS code is not systematic, which is a problem for many networking applications. To obtain a systematic matrix (and code), the simplest solution consists in considering the matrix V_{k,k} formed by the first k columns of V_{k,n}, then to invert it and to multiply this inverse by V_{k,n}. Clearly, the product V_{k,k}^^-1 * V_{k,n} contains the identity matrix I_k on its first k columns, meaning that the first k encoding elements are equal to source elements. Besides the associated code keeps the MDS property.
Therefore, the generator matrix of the code considered in this document is:
GM = (V_{k,k}^^-1) * V_{k,n}
Note that, in practice, the [n,k]-RS code can be shortened to a [n',k]-RS code, where k ≤ n' < n, by considering the sub-matrix formed by the n' first columns of GM.
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Encoding can be performed by first pre-computing GM and by multiplying the source vector (k elements) by GM (k rows and n columns). The complexity of the pre-computation of the generator matrix can be estimated as the complexity of the multiplication of the inverse of a Vandermonde matrix by n-k vectors (i.e., the last n-k columns of V_{k,n}). Since the complexity of the inverse of a k*k-Vandermonde matrix by a vector is O(k * log^^2(k)), the generator matrix can be computed in 0((n-k)* k * log^^2(k)) operations. When the generator matrix is pre-computed, the encoding needs k operations per repair element (vector-matrix multiplication).
Encoding can also be performed by first computing the product s * V_{k,k}^^-1 and then by multiplying the result with V_{k,n}. The multiplication by the inverse of a square Vandermonde matrix is known as the interpolation problem and its complexity is O(k * log^^2 (k)). The multiplication by a Vandermonde matrix, known as the multipoint evaluation problem, requires O((n-k) * log(k)) by using Fast Fourier Transform, as explained in [7] (Gohberg, I. and V. Olshevsky, “Fast algorithms with preprocessing for matrix-vector multiplication problems,” .). The total complexity of this encoding algorithm is then O((k/(n-k)) * log^^2(k) + log(k)) operations per repair element.
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The Reed-Solomon decoding algorithm for the erasure channel allows the recovery of the k source elements from any set of k received elements. It is based on the fundamental property of the generator matrix which is such that any k*k-submatrix is invertible (see [6] (Mac Williams, F. and N. Sloane, “The Theory of Error Correcting Codes,” .)). The first step of the decoding consists in extracting the k*k submatrix of the generator matrix obtained by considering the columns corresponding to the received elements. Indeed, since any encoding element is obtained by multiplying the source vector by one column of the generator matrix, the received vector of k encoding elements can be considered as the result of the multiplication of the source vector by a k*k submatrix of the generator matrix. Since this submatrix is invertible, the second step of the algorithm is to invert this matrix and to multiply the received vector by the obtained matrix to recover the source vector.
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The decoding algorithm described previously includes the matrix inversion and the vector-matrix multiplication. With the classical Gauss-Jordan algorithm, the matrix inversion requires O(k^^3) operations and the vector-matrix multiplication is performed in O(k^^2) operations.
This complexity can be improved by considering that the received submatrix of GM is the product between the inverse of a Vandermonde matrix (V_(k,k)^^-1) and another Vandermonde matrix (denoted by V' which is a submatrix of V_(k,n)). The decoding can be done by multiplying the received vector by V'^^-1 (interpolation problem with complexity O( k * log^^2(k)) ) then by V_{k,k} (multipoint evaluation with complexity O(k * log(k))). The global decoding complexity is then O(log^^2(k)) operations per source element.
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In a packet erasure channel, each packet (and symbol(s) since packets contain G ≥ 1 symbols) is either correctly received or erased. The location of the erased symbols in the sequence of symbols MUST be known. The following specification describes the use of Reed-Solomon codes for generating redundant symbols from the k source symbols and for recovering the source symbols from any set of k received symbols.
The k source symbols of a source block are assumed to be composed of S m-bit elements. Each m-bit element corresponds to an element of the finite field GF(2^^m) through the polynomial representation (Section 8.1 (Finite Field)). If some of the source symbols contain less than S elements, they MUST be virtually padded with zero elements (it can be the case for the last symbol of the last block of the object). However, this padding does not need to be actually sent with the data to the receivers.
The encoding process produces n encoding symbols of size S m-bit elements, of which k are source symbols (this is a systematic code) and n-k are repair symbols (Figure 7 (Packet encoding scheme)). The m-bit elements of the repair symbols are calculated using the corresponding m-bit elements of the source symbol set. A logical j-th source vector, comprised of the j-th elements from the set of source symbols, is used to calculate a j-th encoding vector. This j-th encoding vector then provides the j-th elements for the set encoding symbols calculated for the block. As a systematic code, the first k encoding symbols are the same as the k source symbols and the last n-k repair symbols are the result of the Reed-Solomon encoding.
Input: k source symbols 0 j S-1 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | |X| | source symbol 0 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | |X| | source symbol 1 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | |X| | source symbol k-1 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ * +--------------------+ | generator matrix | | GM | | (k x n) | +--------------------+ | V Output: n encoding symbols (source + repair) 0 j S-1 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | |X| | enc. symbol 0 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | |X| | enc. symbol 1 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ . . . +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | |Y| | enc. symbol n-1 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 7: Packet encoding scheme |
An asset of this scheme is that the loss of some encoding symbols produces the same erasure pattern for each of the S encoding vectors. It follows that the matrix inversion must be done only once and will be used by all the S encoding vectors. For large S, this matrix inversion cost becomes negligible in front of the S matrix-vector multiplications.
Another asset is that the n-k repair symbols can be produced on demand. For instance, a sender can start by producing a limited number of repair symbols and later on, depending on the observed erasures on the channel, decide to produce additional repair symbols, up to the n-k upper limit. Indeed, to produce the repair symbol e_j, where k ≤ j < n, it is sufficient to multiply the S source vectors with column j of GM.
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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 a FEC building block independently of any particular CDP (even if ALC and NORM are two natural candidates), this section only discusses the additional threats that an arbitrary CDP may be exposed to when using this building block.
More specifically, several kinds of attacks exist:
These attacks can be launched either against the data flow itself (e.g. by sending forged symbols) or against the FEC parameters that are sent either in-band (e.g., in an EXT_FTI or FDT Instance) 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. Access control is typically provided by means of encryption. This encryption can be done over the whole object (e.g., by the content provider, before the FEC encoding process), or be done on a packet per packet basis (e.g., when IPSec/ESP is used [14] (Kent, S., “IP Encapsulating Security Payload (ESP),” December 2005.)). If access control 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.
Protection against corruptions (forged packets) is achieved by means of a content integrity verification/sender authentication scheme. This service can be provided at the object level, but in that case a receiver has no way to identify which symbol(s) is(are) corrupted if the object is detected as corrupted. This service can also be provided at the packet level, and after having removed all forged packets, the object can be recovered if the number of symbols remaining is sufficient. Several techniques can provide this source authentication/content integrity service:
It is up to the developer, who knows the security requirements of the target use-case, to define which solution is the most appropriate. Nonetheless, it is RECOMMENDED that at least one of these techniques be used.
Techniques relying on public key cryptography (digital signatures and TESLA during the bootstrap process) require that public keys be securely associated to the entities. This can be achieved by a Public Key Infrastructure (PKI), or by a PGP Web of Trust, or by pre-distributing the public keys of each group member. It is up to the developer, who knows the features of the target use-case, to define which solution to use.
Techniques relying on symmetric key cryptography (group MAC) require that a secret key be shared by all group members. This can be achieved by means of a group key management protocol, or simply by pre-distributing the secret key (but this manual solution has many limitations). Here also, it is up to the developer to define which solution to use, taking into account the target use-case features.
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Let us now consider attacks against the FEC parameters (or FEC OTI). The FEC OTI can either be sent in-band (i.e., in an EXT_FTI or in an FDT Instance containing FEC OTI for the object) or 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 B parameter will lead to a different block partitioning at a receiver thereby compromising decoding; or setting the m parameter to 16 instead of 8 with FEC Encoding ID 2 will increase the processing load while compromising decoding.
It is therefore RECOMMENDED that security measures be taken to guarantee the FEC OTI integrity. To that purpose, the packets carrying the FEC parameters sent in-band (i.e., in an EXT_FTI header extension or in an FDT Instance) may be protected by one of the per-packet techniques described above: TESLA, digital signature, or a group MAC. Alternatively, when FEC OTI is contained in an FDT Instance, this object may be digitally signed. Finally, when FEC OTI is sent out-of-band for instance in a session description, this latter may be protected by a digital signature.
The same considerations concerning the key management aspects apply here also.
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Values of FEC Encoding IDs and FEC Instance IDs are subject to IANA registration. For general guidelines on IANA considerations as they apply to this document, see [2] (Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” August 2007.).
This document assigns the Fully-Specified FEC Encoding ID 2 under the "ietf:rmt:fec:encoding" name-space to "Reed-Solomon Codes over GF(2^^m)".
This document assigns the Fully-Specified FEC Encoding ID 5 under the "ietf:rmt:fec:encoding" name-space to "Reed-Solomon Codes over GF(2^^8)".
This document assigns the FEC Instance ID 0 scoped by the Under-Specified FEC Encoding ID 129 to "Reed-Solomon Codes over GF(2^^8)". More specifically, under the "ietf:rmt:fec:encoding:instance" sub-name-space that is scoped by the "ietf:rmt:fec:encoding" called "Small Block Systematic FEC Codes", this document assigns FEC Instance ID 0 to "Reed-Solomon Codes over GF(2^^8)".
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The authors want to thank Brian Adamson, Igor Slepchin, Stephen Kent, and Francis Dupont for their valuable comments. The authors also want to thank Luigi Rizzo for his comments and for the design of the reference Reed-Solomon codec.
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[1] | Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” RFC 2119. |
[2] | Watson, M., Luby, M., and L. Vicisano, “Forward Error Correction (FEC) Building Block,” RFC 5052, August 2007. |
[3] | Watson, M., “Basic Forward Error Correction (FEC) Schemes,” draft-ietf-rmt-bb-fec-basic-schemes-revised-03.txt (work in progress), February 2007. |
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[4] | 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. |
[5] | 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. |
[6] | Mac Williams, F. and N. Sloane, “The Theory of Error Correcting Codes,” North Holland, 1977. |
[7] | Gohberg, I. and V. Olshevsky, “Fast algorithms with preprocessing for matrix-vector multiplication problems,” Journal of Complexity, pp. 411-427, vol. 10, 1994. |
[8] | Roca, V., Neumann, C., and D. Furodet, “Low Density Parity Check (LDPC) Forward Error Correction,” draft-ietf-rmt-bb-fec-ldpc-06.txt (work in progress), May 2007. |
[9] | Luby, M., Shokrollahi, A., Watson, M., and T. Stockhammer, “Raptor Forward Error Correction Scheme,” draft-ietf-rmt-bb-fec-raptor-object-09 (work in progress), June 2007. |
[10] | Luby, M., Watson, M., and L. Vicisano, “Asynchronous Layered Coding (ALC) Protocol Instantiation,” draft-ietf-rmt-pi-alc-revised-04.txt (work in progress), February 2007. |
[11] | Adamson, B., Bormann, C., Handley, M., and J. Macker, “Negative-acknowledgment (NACK)-Oriented Reliable Multicast (NORM) Protocol,” draft-ietf-rmt-pi-norm-revised-05.txt (work in progress), March 2007. |
[12] | Paila, T., Walsh, R., Luby, M., Lehtonen, R., and V. Roca, “FLUTE - File Delivery over Unidirectional Transport,” draft-ietf-rmt-flute-revised-04.txt (work in progress), October 2007. |
[13] | Jonsson, J. and B. Kaliski, “Public-Key Cryptography Standards (PKCS) #1: RSA Cryptography Specifications Version 2.1,” RFC 3447, February 2003 (TXT). |
[14] | Kent, S., “IP Encapsulating Security Payload (ESP),” RFC 4303, December 2005 (TXT). |
[15] | “HMAC: Keyed-Hashing for Message Authentication,” RFC 2104, February 1997. |
[16] | “Timed Efficient Stream Loss-Tolerant Authentication (TESLA): Multicast Source Authentication Transform Introduction,” RFC 4082, June 2005. |
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Jerome Lacan | |
ISAE | |
1, place Emile Blouin | |
Toulouse 31056 | |
France | |
Email: | jerome.lacan@isae.fr |
URI: | http://dmi.ensica.fr/auteur.php3?id_auteur=5 |
Vincent Roca | |
INRIA | |
655, av. de l'Europe | |
Inovallee; Montbonnot | |
ST ISMIER cedex 38334 | |
France | |
Email: | vincent.roca@inrialpes.fr |
URI: | http://planete.inrialpes.fr/~roca/ |
Jani Peltotalo | |
Tampere University of Technology | |
P.O. Box 553 (Korkeakoulunkatu 1) | |
Tampere FIN-33101 | |
Finland | |
Email: | jani.peltotalo@tut.fi |
URI: | http://atm.tut.fi/mad |
Sami Peltotalo | |
Tampere University of Technology | |
P.O. Box 553 (Korkeakoulunkatu 1) | |
Tampere FIN-33101 | |
Finland | |
Email: | sami.peltotalo@tut.fi |
URI: | http://atm.tut.fi/mad |
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