-------- Erasure codes based on Vandermonde matrices --------- -------- (C) 1996-1998 Luigi Rizzo (luigi@iet.unipi.it) --------- See fec.c for other contributors. fec.c contains an implementation of an encoder/decoder for an erasure code based on Vandermonde matrices computed over GF(2^m), m=2..16 PRINCIPLE OF OPERATION The encoded data is computer as y = E x where x is a k-vector with source data, y is an n-vector with the redundant info, and E is an n*k matrix derived from a Vandermonde matrix. The code is systematic. At the receiver, any subset y' of k elements from y allows the reconstruction of the whole x by solving the system y' = E' x where E' is made of rows from E corresponding to the received elements. The complexity of matrix inversion is O(k*l^2) where l is the number of elements not in x available at the receiver. This might seem large, but data elements are in fact be packets of large size, so the inversion cost can be amortized over the size of the packet. For practical applications (k and l as large as 30, packet sizes of 1KB) the cost can be neglected. In addition, each of the l lost data packets has a reconstruction cost O(k), (obviously) similar to the cost of the encoding phase. Being the code systematic, you can express encoding and decoding costs roughly as Encoding speed: (c_e/l) MB/s Decoding speed: (c_d/l) MB/s PERFORMANCE The values of c_d and c_e (similar) are very sensitive to issues such as cache hit rate, memory speed, field size (8 or 16 bits), etc. Also some machines are better than others in working with bytes or 16-bit words. With the June'98 implementation I have measured the following values for c_e and c_d (8-bit version; 16-bit version has a penalty between 3 and 4). Hardware C version Optimized version(*) PentiumII 266 62 33 PentiumPRO 200 56 30 Pentium133 14.5 18 486dx2/66 4.05 4.55 (*) The 'optimized' version has some manual optimizations of the assembly code generated by the compiler. It is generally faster for machines with a single instruction pipeline, and generally slower for machines with multiple pipelines. See the manpage for detailed usage information.