| blob | e5632f674bc8b7e11612fa2e45009065b662d572 |
1 /*
2 *
3 * Copyright (c) 1993 Ning and David Mosberger.
5 This is based on code originally written by Bas Laarhoven (bas@vimec.nl)
6 and David L. Brown, Jr., and incorporates improvements suggested by
7 Kai Harrekilde-Petersen.
9 This program is free software; you can redistribute it and/or
10 modify it under the terms of the GNU General Public License as
11 published by the Free Software Foundation; either version 2, or (at
12 your option) any later version.
14 This program is distributed in the hope that it will be useful, but
15 WITHOUT ANY WARRANTY; without even the implied warranty of
16 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
17 General Public License for more details.
19 You should have received a copy of the GNU General Public License
20 along with this program; see the file COPYING. If not, write to
21 the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139,
22 USA.
24 *
25 * $Source: /homes/cvs/ftape-stacked/ftape/lowlevel/ftape-ecc.c,v $
26 * $Revision: 1.3 $
27 * $Date: 1997/10/05 19:18:10 $
28 *
29 * This file contains the Reed-Solomon error correction code
30 * for the QIC-40/80 floppy-tape driver for Linux.
31 */
33 #include <linux/ftape.h>
38 /* Machines that are big-endian should define macro BIG_ENDIAN.
39 * Unfortunately, there doesn't appear to be a standard include file
40 * that works for all OSs.
41 */
43 #if defined(__sparc__) || defined(__hppa)
44 #define BIG_ENDIAN
47 #if defined(__mips__)
48 #error Find a smart way to determine the Endianness of the MIPS CPU
49 #endif
51 /* Notice: to minimize the potential for confusion, we use r to
52 * denote the independent variable of the polynomials in the
53 * Galois Field GF(2^8). We reserve x for polynomials that
54 * that have coefficients in GF(2^8).
55 *
56 * The Galois Field in which coefficient arithmetic is performed are
57 * the polynomials over Z_2 (i.e., 0 and 1) modulo the irreducible
58 * polynomial f(r), where f(r)=r^8 + r^7 + r^2 + r + 1. A polynomial
59 * is represented as a byte with the MSB as the coefficient of r^7 and
60 * the LSB as the coefficient of r^0. For example, the binary
61 * representation of f(x) is 0x187 (of course, this doesn't fit into 8
62 * bits). In this field, the polynomial r is a primitive element.
63 * That is, r^i with i in 0,...,255 enumerates all elements in the
64 * field.
65 *
66 * The generator polynomial for the QIC-80 ECC is
67 *
68 * g(x) = x^3 + r^105*x^2 + r^105*x + 1
69 *
70 * which can be factored into:
71 *
72 * g(x) = (x-r^-1)(x-r^0)(x-r^1)
73 *
74 * the byte representation of the coefficients are:
75 *
76 * r^105 = 0xc0
77 * r^-1 = 0xc3
78 * r^0 = 0x01
79 * r^1 = 0x02
80 *
81 * Notice that r^-1 = r^254 as exponent arithmetic is performed
82 * modulo 2^8-1 = 255.
83 *
84 * For more information on Galois Fields and Reed-Solomon codes, refer
85 * to any good book. I found _An Introduction to Error Correcting
86 * Codes with Applications_ by S. A. Vanstone and P. C. van Oorschot
87 * to be a good introduction into the former. _CODING THEORY: The
88 * Essentials_ I found very useful for its concise description of
89 * Reed-Solomon encoding/decoding.
90 *
91 */
95 /*
96 * gfpow[] is defined such that gfpow[i] returns r^i if
97 * i is in the range [0..255].
98 */
100 {
133 };
135 /*
136 * This is a log table. That is, gflog[r^i] returns i (modulo f(r)).
137 * gflog[0] is undefined and the first element is therefore not valid.
138 */
140 {
173 };
175 /* This is a multiplication table for the factor 0xc0 (i.e., r^105 (mod f(r)).
176 * gfmul_c0[f] returns r^105 * f(r) (modulo f(r)).
177 */
179 {
212 };
215 /* Returns V modulo 255 provided V is in the range -255,-254,...,509.
216 */
218 {
224 }
227 }
228 }
231 /* Add two numbers in the field. Addition in this field is equivalent
232 * to a bit-wise exclusive OR operation---subtraction is therefore
233 * identical to addition.
234 */
236 {
238 }
241 /* Add two vectors of numbers in the field. Each byte in A and B gets
242 * added individually.
243 */
245 {
247 }
250 /* Multiply two numbers in the field:
251 */
253 {
258 }
259 }
262 /* Just like gfmul, except we have already looked up the log of the
263 * second number.
264 */
266 {
271 }
272 }
275 /* Just like gfmul_exp, except that A is a vector of numbers. That
276 * is, each byte in A gets multiplied by gfpow[mod255(B)].
277 */
279 {
280 __u8 t;
314 }
315 }
318 /* Divide two numbers in the field. Returns a/b (modulo f(x)).
319 */
321 {
329 }
330 }
333 /* The following functions return the inverse of the matrix of the
334 * linear system that needs to be solved to determine the error
335 * magnitudes. The first deals with matrices of rank 3, while the
336 * second deals with matrices of rank 2. The error indices are passed
337 * in arguments L0,..,L2 (0=first sector, 31=last sector). The error
338 * indices must be sorted in ascending order, i.e., L0<L1<L2.
339 *
340 * The linear system that needs to be solved for the error magnitudes
341 * is A * b = s, where s is the known vector of syndromes, b is the
342 * vector of error magnitudes and A in the ORDER=3 case:
343 *
344 * A_3 = {{1/r^L[0], 1/r^L[1], 1/r^L[2]},
345 * { 1, 1, 1},
346 * { r^L[0], r^L[1], r^L[2]}}
347 */
349 __u8 l1,
350 __u8 l2,
351 Matrix Ainv)
352 {
353 __u8 det;
357 /* compute some intermediate results: */
364 /* Calculate the determinant of matrix A_3^-1 (sometimes
365 * called the Vandermonde determinant):
366 */
372 }
375 /* Now, calculate all of the coefficients:
376 */
390 }
394 {
395 __u8 det;
406 }
409 /* Now, calculate all of the coefficients:
410 */
417 }
420 /* Multiply matrix A by vector S and return result in vector B. M is
421 * assumed to be of order NxN, S and B of order Nx1.
422 */
425 {
427 __u8 dot_prod;
433 }
435 }
436 }
437 \f
440 /* The Reed Solomon ECC codes are computed over the N-th byte of each
441 * block, where N=SECTOR_SIZE. There are up to 29 blocks of data, and
442 * 3 blocks of ECC. The blocks are stored contiguously in memory. A
443 * segment, consequently, is assumed to have at least 4 blocks: one or
444 * more data blocks plus three ECC blocks.
445 *
446 * Notice: In QIC-80 speak, a CRC error is a sector with an incorrect
447 * CRC. A CRC failure is a sector with incorrect data, but
448 * a valid CRC. In the error control literature, the former
449 * is usually called "erasure", the latter "error."
450 */
451 /* Compute the parity bytes for C columns of data, where C is the
452 * number of bytes that fit into a long integer. We use a linear
453 * feed-back register to do this. The parity bytes P[0], P[STRIDE],
454 * P[2*STRIDE] are computed such that:
455 *
456 * x^k * p(x) + m(x) = 0 (modulo g(x))
457 *
458 * where k = NBLOCKS,
459 * p(x) = P[0] + P[STRIDE]*x + P[2*STRIDE]*x^2, and
460 * m(x) = sum_{i=0}^k m_i*x^i.
461 * m_i = DATA[i*SECTOR_SIZE]
462 */
467 {
473 /* The new parity bytes p0_i, p1_i, p2_i are computed
474 * from the old values p0_{i-1}, p1_{i-1}, p2_{i-1}
475 * recursively as:
476 *
477 * p0_i = p1_{i-1} + r^105 * (m_{i-1} - p0_{i-1})
478 * p1_i = p2_{i-1} + r^105 * (m_{i-1} - p0_{i-1})
479 * p2_i = (m_{i-1} - p0_{i-1})
480 *
481 * With the initial condition: p0_0 = p1_0 = p2_0 = 0.
482 */
484 /*
485 * Multiply each byte in t1 by 0xc0:
486 */
505 TRACE_EXIT;
506 }
511 }
518 }
521 /* Compute the 3 syndrome values. DATA should point to the first byte
522 * of the column for which the syndromes are desired. The syndromes
523 * are computed over the first NBLOCKS of rows. The three bytes will
524 * be placed in S[0], S[1], and S[2].
525 *
526 * S[i] is the value of the "message" polynomial m(x) evaluated at the
527 * i-th root of the generator polynomial g(x).
528 *
529 * As g(x)=(x-r^-1)(x-1)(x-r^1) we evaluate the message polynomial at
530 * x=r^-1 to get S[0], at x=r^0=1 to get S[1], and at x=r to get S[2].
531 * This could be done directly and efficiently via the Horner scheme.
532 * However, it would require multiplication tables for the factors
533 * r^-1 (0xc3) and r (0x02). The following scheme does not require
534 * any multiplication tables beyond what's needed for set_parity()
535 * anyway and is slightly faster if there are no errors and slightly
536 * slower if there are errors. The latter is hopefully the infrequent
537 * case.
538 *
539 * To understand the alternative algorithm, notice that set_parity(m,
540 * k, p) computes parity bytes such that:
541 *
542 * x^k * p(x) = m(x) (modulo g(x)).
543 *
544 * That is, to evaluate m(r^m), where r^m is a root of g(x), we can
545 * simply evaluate (r^m)^k*p(r^m). Also, notice that p is 0 if and
546 * only if s is zero. That is, if all parity bytes are 0, we know
547 * there is no error in the data and consequently there is no need to
548 * compute s(x) at all! In all other cases, we compute s(x) from p(x)
549 * by evaluating (r^m)^k*p(r^m) for m=-1, m=0, and m=1. The p(x)
550 * polynomial is evaluated via the Horner scheme.
551 */
553 {
558 /* Some of the checked columns do not have a zero
559 * syndrome. For simplicity, we compute the syndromes
560 * for all columns that we have computed the
561 * remainders for.
562 */
577 nblocks);
581 }
582 }
585 /* Correct the block in the column pointed to by DATA. There are NBAD
586 * CRC errors and their indices are in BAD_LOC[0], up to
587 * BAD_LOC[NBAD-1]. If NBAD>1, Ainv holds the inverse of the matrix
588 * of the linear system that needs to be solved to determine the error
589 * magnitudes. S[0], S[1], and S[2] are the syndrome values. If row
590 * j gets corrected, then bit j will be set in CORRECTION_MAP.
591 */
596 {
607 /* might have a CRC failure: */
609 /* more than one error */
612 }
619 }
626 /* one erasure, no error: */
629 /* one erasure and more than one error: */
633 /* one erasure, one error: */
641 }
643 /* inversion failed---must have more
644 * than one error
645 */
647 }
648 }
649 /* FALL THROUGH TO ERROR MAGNITUDE COMPUTATION:
650 */
653 /* compute error magnitudes: */
660 }
662 /* Perform correction by adding ERROR_MAG[i] to the byte at
663 * offset BAD_LOC[i]. Also add the value of the computed
664 * error polynomial to the syndrome values. If the correction
665 * was successful, the resulting check bytes should be zero
666 * (i.e., the corrected data is a valid code word).
667 */
674 /* correct the byte at offset L by magnitude E: */
685 }
686 }
690 }
691 TRACE_EXIT ncorrected;
692 }
695 #if defined(ECC_SANITY_CHECK) || defined(ECC_PARANOID)
697 /* Perform a sanity check on the computed parity bytes:
698 */
700 {
707 }
709 }
713 /* Compute the parity for an entire segment of data.
714 */
716 {
725 #ifdef ECC_PARANOID
729 }
731 }
733 }
736 /* Checks and corrects (if possible) the segment MSEG. Returns one of
737 * ECC_OK, ECC_CORRECTED, and ECC_FAILED.
738 */
740 {
747 Matrix Ainv;
752 /* find first column that has non-zero syndromes: */
756 /* something is wrong---have to fix things */
758 }
759 }
761 /* all syndromes are ok, therefore nothing to correct */
762 TRACE_EXIT ECC_OK;
763 }
764 /* count the number of CRC errors if there were any: */
769 /* this is too much for ECC */
774 }
775 }
776 }
777 /*
778 * If there are at least 2 CRC errors, determine inverse of matrix
779 * of linear system to be solved:
780 */
784 TRACE_EXIT ECC_FAILED;
785 }
790 TRACE_EXIT ECC_FAILED;
791 }
794 /* this is not an error condition... */
796 }
804 #ifdef BIG_ENDIAN
808 nerasures,
809 erasure_loc,
810 Ainv,
811 s,
813 #else
816 nerasures,
817 erasure_loc,
818 Ainv,
819 s,
821 #endif
823 TRACE_EXIT ECC_FAILED;
824 }
826 }
830 }
832 #ifdef ECC_SANITY_CHECK
835 TRACE_EXIT ECC_FAILED;
836 }
839 /* find next column with non-zero syndromes: */
843 /* something is wrong---have to fix things */
845 }
846 }
850 }
853 }