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// SPDX-License-Identifier: GPL-2.0
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/*
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* Generic Reed Solomon encoder / decoder library
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*
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* Copyright 2002 , Phil Karn , KA9Q
* May be used under the terms of the GNU General Public License ( GPL )
*
* Adaption to the kernel by Thomas Gleixner ( tglx @ linutronix . de )
*
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* Generic data width independent code which is included by the wrappers .
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*/
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{
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struct rs_codec * rs = rsc - > codec ;
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int deg_lambda , el , deg_omega ;
int i , j , r , k , pad ;
int nn = rs - > nn ;
int nroots = rs - > nroots ;
int fcr = rs - > fcr ;
int prim = rs - > prim ;
int iprim = rs - > iprim ;
uint16_t * alpha_to = rs - > alpha_to ;
uint16_t * index_of = rs - > index_of ;
uint16_t u , q , tmp , num1 , num2 , den , discr_r , syn_error ;
int count = 0 ;
uint16_t msk = ( uint16_t ) rs - > nn ;
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/*
* The decoder buffers are in the rs control struct . They are
* arrays sized [ nroots + 1 ]
*/
uint16_t * lambda = rsc - > buffers + RS_DECODE_LAMBDA * ( nroots + 1 ) ;
uint16_t * syn = rsc - > buffers + RS_DECODE_SYN * ( nroots + 1 ) ;
uint16_t * b = rsc - > buffers + RS_DECODE_B * ( nroots + 1 ) ;
uint16_t * t = rsc - > buffers + RS_DECODE_T * ( nroots + 1 ) ;
uint16_t * omega = rsc - > buffers + RS_DECODE_OMEGA * ( nroots + 1 ) ;
uint16_t * root = rsc - > buffers + RS_DECODE_ROOT * ( nroots + 1 ) ;
uint16_t * reg = rsc - > buffers + RS_DECODE_REG * ( nroots + 1 ) ;
uint16_t * loc = rsc - > buffers + RS_DECODE_LOC * ( nroots + 1 ) ;
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/* Check length parameter for validity */
pad = nn - nroots - len ;
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BUG_ON ( pad < 0 | | pad > = nn ) ;
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/* Does the caller provide the syndrome ? */
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if ( s ! = NULL )
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goto decode ;
/* form the syndromes; i.e., evaluate data(x) at roots of
* g ( x ) */
for ( i = 0 ; i < nroots ; i + + )
syn [ i ] = ( ( ( uint16_t ) data [ 0 ] ) ^ invmsk ) & msk ;
for ( j = 1 ; j < len ; j + + ) {
for ( i = 0 ; i < nroots ; i + + ) {
if ( syn [ i ] = = 0 ) {
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syn [ i ] = ( ( ( uint16_t ) data [ j ] ) ^
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invmsk ) & msk ;
} else {
syn [ i ] = ( ( ( ( uint16_t ) data [ j ] ) ^
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invmsk ) & msk ) ^
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alpha_to [ rs_modnn ( rs , index_of [ syn [ i ] ] +
( fcr + i ) * prim ) ] ;
}
}
}
for ( j = 0 ; j < nroots ; j + + ) {
for ( i = 0 ; i < nroots ; i + + ) {
if ( syn [ i ] = = 0 ) {
syn [ i ] = ( ( uint16_t ) par [ j ] ) & msk ;
} else {
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syn [ i ] = ( ( ( uint16_t ) par [ j ] ) & msk ) ^
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alpha_to [ rs_modnn ( rs , index_of [ syn [ i ] ] +
( fcr + i ) * prim ) ] ;
}
}
}
s = syn ;
/* Convert syndromes to index form, checking for nonzero condition */
syn_error = 0 ;
for ( i = 0 ; i < nroots ; i + + ) {
syn_error | = s [ i ] ;
s [ i ] = index_of [ s [ i ] ] ;
}
if ( ! syn_error ) {
/* if syndrome is zero, data[] is a codeword and there are no
* errors to correct . So return data [ ] unmodified
*/
count = 0 ;
goto finish ;
}
decode :
memset ( & lambda [ 1 ] , 0 , nroots * sizeof ( lambda [ 0 ] ) ) ;
lambda [ 0 ] = 1 ;
if ( no_eras > 0 ) {
/* Init lambda to be the erasure locator polynomial */
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lambda [ 1 ] = alpha_to [ rs_modnn ( rs ,
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prim * ( nn - 1 - eras_pos [ 0 ] ) ) ] ;
for ( i = 1 ; i < no_eras ; i + + ) {
u = rs_modnn ( rs , prim * ( nn - 1 - eras_pos [ i ] ) ) ;
for ( j = i + 1 ; j > 0 ; j - - ) {
tmp = index_of [ lambda [ j - 1 ] ] ;
if ( tmp ! = nn ) {
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lambda [ j ] ^ =
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alpha_to [ rs_modnn ( rs , u + tmp ) ] ;
}
}
}
}
for ( i = 0 ; i < nroots + 1 ; i + + )
b [ i ] = index_of [ lambda [ i ] ] ;
/*
* Begin Berlekamp - Massey algorithm to determine error + erasure
* locator polynomial
*/
r = no_eras ;
el = no_eras ;
while ( + + r < = nroots ) { /* r is the step number */
/* Compute discrepancy at the r-th step in poly-form */
discr_r = 0 ;
for ( i = 0 ; i < r ; i + + ) {
if ( ( lambda [ i ] ! = 0 ) & & ( s [ r - i - 1 ] ! = nn ) ) {
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discr_r ^ =
alpha_to [ rs_modnn ( rs ,
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index_of [ lambda [ i ] ] +
s [ r - i - 1 ] ) ] ;
}
}
discr_r = index_of [ discr_r ] ; /* Index form */
if ( discr_r = = nn ) {
/* 2 lines below: B(x) <-- x*B(x) */
memmove ( & b [ 1 ] , b , nroots * sizeof ( b [ 0 ] ) ) ;
b [ 0 ] = nn ;
} else {
/* 7 lines below: T(x) <-- lambda(x)-discr_r*x*b(x) */
t [ 0 ] = lambda [ 0 ] ;
for ( i = 0 ; i < nroots ; i + + ) {
if ( b [ i ] ! = nn ) {
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t [ i + 1 ] = lambda [ i + 1 ] ^
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alpha_to [ rs_modnn ( rs , discr_r +
b [ i ] ) ] ;
} else
t [ i + 1 ] = lambda [ i + 1 ] ;
}
if ( 2 * el < = r + no_eras - 1 ) {
el = r + no_eras - el ;
/*
* 2 lines below : B ( x ) < - - inv ( discr_r ) *
* lambda ( x )
*/
for ( i = 0 ; i < = nroots ; i + + ) {
b [ i ] = ( lambda [ i ] = = 0 ) ? nn :
rs_modnn ( rs , index_of [ lambda [ i ] ]
- discr_r + nn ) ;
}
} else {
/* 2 lines below: B(x) <-- x*B(x) */
memmove ( & b [ 1 ] , b , nroots * sizeof ( b [ 0 ] ) ) ;
b [ 0 ] = nn ;
}
memcpy ( lambda , t , ( nroots + 1 ) * sizeof ( t [ 0 ] ) ) ;
}
}
/* Convert lambda to index form and compute deg(lambda(x)) */
deg_lambda = 0 ;
for ( i = 0 ; i < nroots + 1 ; i + + ) {
lambda [ i ] = index_of [ lambda [ i ] ] ;
if ( lambda [ i ] ! = nn )
deg_lambda = i ;
}
/* Find roots of error+erasure locator polynomial by Chien search */
memcpy ( & reg [ 1 ] , & lambda [ 1 ] , nroots * sizeof ( reg [ 0 ] ) ) ;
count = 0 ; /* Number of roots of lambda(x) */
for ( i = 1 , k = iprim - 1 ; i < = nn ; i + + , k = rs_modnn ( rs , k + iprim ) ) {
q = 1 ; /* lambda[0] is always 0 */
for ( j = deg_lambda ; j > 0 ; j - - ) {
if ( reg [ j ] ! = nn ) {
reg [ j ] = rs_modnn ( rs , reg [ j ] + j ) ;
q ^ = alpha_to [ reg [ j ] ] ;
}
}
if ( q ! = 0 )
continue ; /* Not a root */
/* store root (index-form) and error location number */
root [ count ] = i ;
loc [ count ] = k ;
/* If we've already found max possible roots,
* abort the search to save time
*/
if ( + + count = = deg_lambda )
break ;
}
if ( deg_lambda ! = count ) {
/*
* deg ( lambda ) unequal to number of roots = > uncorrectable
* error detected
*/
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count = - EBADMSG ;
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goto finish ;
}
/*
* Compute err + eras evaluator poly omega ( x ) = s ( x ) * lambda ( x ) ( modulo
* x * * nroots ) . in index form . Also find deg ( omega ) .
*/
deg_omega = deg_lambda - 1 ;
for ( i = 0 ; i < = deg_omega ; i + + ) {
tmp = 0 ;
for ( j = i ; j > = 0 ; j - - ) {
if ( ( s [ i - j ] ! = nn ) & & ( lambda [ j ] ! = nn ) )
tmp ^ =
alpha_to [ rs_modnn ( rs , s [ i - j ] + lambda [ j ] ) ] ;
}
omega [ i ] = index_of [ tmp ] ;
}
/*
* Compute error values in poly - form . num1 = omega ( inv ( X ( l ) ) ) , num2 =
* inv ( X ( l ) ) * * ( fcr - 1 ) and den = lambda_pr ( inv ( X ( l ) ) ) all in poly - form
*/
for ( j = count - 1 ; j > = 0 ; j - - ) {
num1 = 0 ;
for ( i = deg_omega ; i > = 0 ; i - - ) {
if ( omega [ i ] ! = nn )
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num1 ^ = alpha_to [ rs_modnn ( rs , omega [ i ] +
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i * root [ j ] ) ] ;
}
num2 = alpha_to [ rs_modnn ( rs , root [ j ] * ( fcr - 1 ) + nn ) ] ;
den = 0 ;
/* lambda[i+1] for i even is the formal derivative
* lambda_pr of lambda [ i ] */
for ( i = min ( deg_lambda , nroots - 1 ) & ~ 1 ; i > = 0 ; i - = 2 ) {
if ( lambda [ i + 1 ] ! = nn ) {
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den ^ = alpha_to [ rs_modnn ( rs , lambda [ i + 1 ] +
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i * root [ j ] ) ] ;
}
}
/* Apply error to data */
if ( num1 ! = 0 & & loc [ j ] > = pad ) {
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uint16_t cor = alpha_to [ rs_modnn ( rs , index_of [ num1 ] +
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index_of [ num2 ] +
nn - index_of [ den ] ) ] ;
/* Store the error correction pattern, if a
* correction buffer is available */
if ( corr ) {
corr [ j ] = cor ;
} else {
/* If a data buffer is given and the
* error is inside the message ,
* correct it */
if ( data & & ( loc [ j ] < ( nn - nroots ) ) )
data [ loc [ j ] - pad ] ^ = cor ;
}
}
}
finish :
if ( eras_pos ! = NULL ) {
for ( i = 0 ; i < count ; i + + )
eras_pos [ i ] = loc [ i ] - pad ;
}
return count ;
}