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552 lines
14 KiB
552 lines
14 KiB
/* HOOK. Fixed comments; otherwise impossible to compile */
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/*
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* $Log: V:/Flite/archives/TrueFFS5/Src/REEDSOL.C_V $
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*
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* Rev 1.3 Jul 13 2001 01:10:00 oris
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* Moved saved syndrome array definition (used by d2tst).
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*
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* Rev 1.2 Apr 09 2001 15:10:20 oris
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* End with an empty line.
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*
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* Rev 1.1 Apr 01 2001 08:00:14 oris
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* copywrite notice.
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*
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* Rev 1.0 Feb 04 2001 12:37:38 oris
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* Initial revision.
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*
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*/
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/************************************************************************/
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/* */
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/* FAT-FTL Lite Software Development Kit */
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/* Copyright (C) M-Systems Ltd. 1995-2001 */
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/* */
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/************************************************************************/
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#include "reedsol.h"
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#define T 2 /* Number of recoverable errors */
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#define SYND_LEN (T*2) /* length of syndrom vector */
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#define K512 (((512+1)*8+6)/10) /* number of inf symbols for record
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of 512 bytes (K512=411) */
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#define N512 (K512 + SYND_LEN) /* code word length for record of 512 bytes */
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#define INIT_DEG 510
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#define MOD 1023
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#define BLOCK_SIZE 512
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#ifdef D2TST
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byte saveSyndromForDumping[SYNDROM_BYTES];
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#endif /* D2TST */
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static short gfi(short val);
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static short gfmul( short f, short s );
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static short gfdiv( short f, short s );
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static short flog(short val);
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static short alog(short val);
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/*------------------------------------------------------------------------------*/
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/* Function Name: RTLeightToTen */
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/* Purpose......: convert an array of five 8-bit values into an array of */
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/* four 10-bit values, from right to left. */
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/* Returns......: Nothing */
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/*------------------------------------------------------------------------------*/
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static void RTLeightToTen(char *reg8, unsigned short reg10[])
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{
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reg10[0] = (reg8[0] & 0xFF) | ((reg8[1] & 0x03) << 8);
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reg10[1] = ((reg8[1] & 0xFC) >> 2) | ((reg8[2] & 0x0F) << 6);
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reg10[2] = ((reg8[2] & 0xF0) >> 4) | ((reg8[3] & 0x3F) << 4);
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reg10[3] = ((reg8[3] & 0xC0) >> 6) | ((reg8[4] & 0xFF) << 2);
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}
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/*----------------------------------------------------------------------------*/
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static void unpack( short word, short length, short vector[] )
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/* */
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/* Function unpacks word into vector */
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/* */
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/* Parameters: */
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/* word - word to be unpacked */
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/* vector - array to be filled */
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/* length - number of bits in word */
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{
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short i, *ptr;
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ptr = vector + length - 1;
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for( i = 0; i < length; i++ )
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{
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*ptr-- = word & 1;
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word >>= 1;
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}
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}
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/*----------------------------------------------------------------------------*/
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static short pack( short *vector, short length )
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/* */
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/* Function packs vector into word */
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/* */
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/* Parameters: */
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/* vector - array to be packed */
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/* length - number of bits in word */
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{
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short tmp, i;
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vector += length - 1;
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tmp = 0;
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i = 1;
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while( length-- > 0 )
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{
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if( *vector-- )
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tmp |= i;
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i <<= 1;
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}
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return( tmp );
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}
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/*----------------------------------------------------------------------------*/
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static short gfi( short val) /* GF inverse */
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{
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return alog((short)(MOD-flog(val)));
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}
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/*----------------------------------------------------------------------------*/
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static short gfmul( short f, short s ) /* GF multiplication */
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{
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short i;
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if( f==0 || s==0 )
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return 0;
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else
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{
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i = flog(f) + flog(s);
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if( i > MOD ) i -= MOD;
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return( alog(i) );
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}
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}
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/*----------------------------------------------------------------------------*/
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static short gfdiv( short f, short s ) /* GF division */
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{
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return gfmul(f,gfi(s));
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}
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/*----------------------------------------------------------------------------*/
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static void residue_to_syndrom( short reg[], short realsynd[] )
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{
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short i,l,alpha,x,s,x4;
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short deg,deg4;
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for(i=0,deg=INIT_DEG;i<SYND_LEN;i++,deg++)
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{
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s = reg[0];
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alpha = x = alog(deg);
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deg4 = deg+deg;
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if( deg4 >= MOD ) deg4 -= MOD;
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deg4 += deg4;
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if( deg4 >= MOD ) deg4 -= MOD;
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x4 = alog(deg4);
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for(l=1;l<SYND_LEN;l++)
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{
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s ^= gfmul( reg[l], x );
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x = gfmul( alpha, x );
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}
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realsynd[i] = gfdiv( s, x4 );
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}
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}
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/*----------------------------------------------------------------------------*/
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static short alog(short i)
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{
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short j=0, val=1;
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for( ; j < i ; j++ )
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{
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val <<= 1 ;
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if ( val > 0x3FF )
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{
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if ( val & 8 ) val -= (0x400+7);
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else val -= (0x400-9);
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}
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}
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return val ;
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}
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static short flog(short val)
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{
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short j, val1;
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if (val == 0)
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return (short)0xFFFF;
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j=0;
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val1=1;
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for( ; j <= MOD ; j++ )
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{
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if (val1 == val)
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return j;
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val1 <<= 1 ;
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if ( val1 > 0x3FF )
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{
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if ( val1 & 8 ) val1 -= (0x400+7);
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else val1 -= (0x400-9);
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}
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}
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return 0;
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}
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/*----------------------------------------------------------------------------*/
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static short convert_to_byte_patterns( short *locators, short *values,
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short noferr, short *blocs, short *bvals )
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{
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static short mask[] = { 0x0, 0x1, 0x3, 0x7, 0xf, 0x1f, 0x3f, 0x7f, 0xff };
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short i,j,n, n0, n1, tmp;
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short n_bit, n_byte, k_bit, nb;
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for( i = 0, nb = 0; i< noferr; i++)
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{
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n = locators[i];
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tmp = values[i];
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n_bit = n *10 - 6 ;
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n_byte = n_bit >> 3;
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k_bit = n_bit - (n_byte<<3);
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n_byte++;
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if( k_bit == 7 )
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{
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/* 3 corrupted bytes */
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blocs[nb] = n_byte+1;
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bvals[nb++] = tmp & 1 ? 0x80 : 0;
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tmp >>= 1;
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blocs[nb] = n_byte;
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bvals[nb++] = tmp & 0xff;
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tmp >>= 8;
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bvals[nb++] = tmp & 0xff;
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}
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else
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{
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n0 = 8 - k_bit;
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n1 = 10 - n0;
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blocs[nb] = n_byte;
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bvals[nb++] = (tmp & mask[n1]) << (8 - n1);
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tmp >>= n1;
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blocs[nb] = n_byte - 1;
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bvals[nb++] = (tmp & mask[n0]);
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}
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}
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for( i = 0, j = -1; i < nb; i++ )
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{
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if( bvals[i] == 0 ) continue;
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if( (blocs[i] == blocs[j]) && ( j>= 0 ) )
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{
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bvals[j] |= bvals[i];
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}
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else
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{
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j++;
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blocs[j] = blocs[i];
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bvals[j] = bvals[i];
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}
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}
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return j+1;
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}
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/*----------------------------------------------------------------------------*/
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static short deg512( short x )
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{
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short i;
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short l,m;
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l = flog(x);
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for( i=0;i<9;i++)
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{
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m = 0;
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if( (l & 0x200) )
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m = 1;
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l = ( ( l << 1 ) & 0x3FF ) | m;
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}
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return alog(l);
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}
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/*----------------------------------------------------------------------------*/
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static short decoder_for_2_errors( short s[], short lerr[], short verr[] )
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{
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/* decoder for correcting up to 2 errors */
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short i,j,k,temp,delta;
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short ind, x1, x2;
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short r1, r2, r3, j1, j2;
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short sigma1, sigma2;
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short xu[10], ku[10];
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short yd, yn;
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ind = 0;
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for(i=0;i<SYND_LEN;i++)
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if( s[i] != 0 )
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ind++; /* ind = number of nonzero syndrom symbols */
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if( ind == 0 ) return 0; /* no errors */
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if( ind < 4 )
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goto two_or_more_errors;
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/* checking s1/s0 = s2/s1 = s3/s2 = alpha**j for some j */
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r1 = gfdiv( s[1], s[0] );
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r2 = gfdiv( s[2], s[1] );
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r3 = gfdiv( s[3], s[2] );
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if( r1 != r2 || r2 != r3)
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goto two_or_more_errors;
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j = flog(r1);
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if( j > 414 )
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goto two_or_more_errors;
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lerr[0] = j;
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/* pattern = (s0/s1)**(510+1) * s1
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or
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pattern = (s0/s1)**(512 - 1 ) * s1 */
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temp = gfi( r1 );
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#ifndef NT5PORT
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{
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int i;
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for (i = 0; i < 9; i++)
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temp = gfmul( temp, temp ); /* deg = 512 */
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}
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#else /*NT5PORT*/
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for (i = 0; i < 9; i++)
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{
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temp = gfmul( temp, temp ); /* deg = 512 */
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}
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#endif /*NT5PORT*/
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verr[0] = gfmul( gfmul(temp, r1), s[1] );
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return 1; /* 1 error */
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two_or_more_errors:
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delta = gfmul( s[0], s[2] ) ^ gfmul( s[1], s[1] );
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if( delta == 0 )
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return -1; /* uncorrectable error */
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temp = gfmul( s[1], s[3] ) ^ gfmul( s[2], s[2] );
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if( temp == 0 )
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return -1; /* uncorrectable error */
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sigma2 = gfdiv( temp, delta );
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temp = gfmul( s[1], s[2] ) ^ gfmul( s[0], s[3] );
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if( temp == 0 )
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return -1; /* uncorrectable error */
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sigma1 = gfdiv( temp, delta );
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k = gfdiv( sigma2, gfmul( sigma1, sigma1 ) );
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unpack( k, 10, ku );
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if( ku[2] != 0 )
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return -1;
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xu[4] = ku[9];
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xu[5] = ku[0] ^ ku[1];
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xu[6] = ku[6] ^ ku[9];
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xu[3] = ku[4] ^ ku[9];
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xu[1] = ku[3] ^ ku[4] ^ ku[6];
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xu[0] = ku[0] ^ xu[1];
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xu[8] = ku[8] ^ xu[0];
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xu[7] = ku[7] ^ xu[3] ^ xu[8];
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xu[2] = ku[5] ^ xu[7] ^ xu[5] ^ xu[0];
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xu[9] = 0;
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x1 = pack( xu, 10 );
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x2 = x1 | 1;
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x1 = gfmul( sigma1, x1 );
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x2 = gfmul( sigma1, x2 );
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j1 = flog(x1);
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j2 = flog(x2);
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if( (j1 > 414) || (j2 > 414) )
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return -1;
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r1 = x1 ^ x2;
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r2 = deg512( x1 );
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temp = gfmul( x1, x1 );
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r2 = gfdiv( r2, temp );
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yd = gfmul( r2, r1 );
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if( yd == 0 )
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return -1;
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yn = gfmul( s[0], x2 ) ^ s[1];
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if( yn == 0 )
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return -1;
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verr[0] = gfdiv( yn, yd );
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r2 = deg512( x2 );
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temp = gfmul( x2, x2 );
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r2 = gfdiv( r2, temp );
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yd = gfmul( r2, r1 );
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if( yd == 0 )
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return -1;
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yn = gfmul( s[0], x1 ) ^ s[1];
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if( yn == 0 )
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return -1;
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verr[1] = gfdiv( yn, yd );
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if( j1 > j2 ) {
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lerr[0] = j2;
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lerr[1] = j1;
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temp = verr[0];
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verr[0] = verr[1];
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verr[1] = temp;
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}
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else
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{
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lerr[0] = j1;
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lerr[1] = j2;
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}
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return 2;
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}
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/*------------------------------------------------------------------------------*/
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/* Function Name: flDecodeEDC */
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/* Purpose......: Trys to correct errors. */
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/* errorSyndrom[] should contain the syndrom as 5 bytes and one */
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/* parity byte. (identical to the output of calcEDCSyndrom()). */
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/* Upon returning, errorNum will contain the number of errors, */
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/* errorLocs[] will contain error locations, and */
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/* errorVals[] will contain error values (to be XORed with the */
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/* data). */
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/* Parity error is relevant only if there are other errors, and */
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/* the EDC code fails parity check. */
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/* NOTE! Only the first errorNum indexes of the above two arrays */
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/* are relevant. The others contain garbage. */
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/* Returns......: The error status. */
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/* NOTE! If the error status is NO_EDC_ERROR upon return, ignore */
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/* the value of the arguments. */
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/*------------------------------------------------------------------------------*/
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EDCstatus flDecodeEDC(char *errorSyndrom, char *errorsNum,
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short errorLocs[3*T], short errorVals[3*T])
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{
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short noferr; /* number of errors */
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short dec_parity; /* parity byte of decoded word */
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short rec_parity; /* parity byte of received word */
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short realsynd[SYND_LEN]; /* real syndrom calculated from residue */
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short locators[T], /* error locators */
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values[T]; /* error values */
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short reg[SYND_LEN]; /* register for main division procedure */
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int i;
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RTLeightToTen(errorSyndrom, (unsigned short *)reg);
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rec_parity = errorSyndrom[5] & 0xFF; /* The parity byte */
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residue_to_syndrom(reg, realsynd);
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noferr = decoder_for_2_errors(realsynd, locators, values);
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if(noferr == 0)
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return NO_EDC_ERROR; /* No error found */
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if(noferr < 0) /* If an uncorrectable error was found */
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return UNCORRECTABLE_ERROR;
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for (i=0;i<noferr;i++)
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locators[i] = N512 - 1 - locators[i];
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*errorsNum = (char)convert_to_byte_patterns(locators, values, noferr, errorLocs, errorVals);
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for(dec_parity=i=0; i < *errorsNum; i++)/* Calculate the parity for all the */
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{ /* errors found: */
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if(errorLocs[i] <= 512)
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dec_parity ^= errorVals[i];
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}
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if(dec_parity != rec_parity)
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return UNCORRECTABLE_ERROR; /* Parity error */
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else
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return CORRECTABLE_ERROR;
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}
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/*------------------------------------------------------------------------------*/
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/* Function Name: flCheckAndFixEDC */
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/* Purpose......: Decodes the EDC syndrom and fixs the errors if possible. */
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/* block[] should contain 512 bytes of data. */
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/* NOTE! Call this function only if errors where detected by */
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/* syndCalc or by the ASIC module. */
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/* Returns......: The error status. */
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/*------------------------------------------------------------------------------*/
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EDCstatus flCheckAndFixEDC(char FAR1 *block, char *syndrom, FLBoolean byteSwap)
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{
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char errorsNum;
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short errorLocs[3*T];
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short errorVals[3*T];
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EDCstatus status;
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status = flDecodeEDC(syndrom, &errorsNum, errorLocs, errorVals);
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if(status == CORRECTABLE_ERROR) /* Fix the errors if possible */
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{
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int i;
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for (i=0; i < errorsNum; i++)
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if( (errorLocs[i] ^ byteSwap) < BLOCK_SIZE ) /* Fix only in Data Area */
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block[errorLocs[i] ^ byteSwap] ^= errorVals[i];
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return NO_EDC_ERROR; /* All errors are fixed */
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}
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else
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return status; /* Uncorrectable error */
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}
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