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288 lines
10 KiB
C
288 lines
10 KiB
C
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/**
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This is a simple Reed-Solomon encoder
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(C) Cliff Hones 2004
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Redistribution and use in source and binary forms, with or without
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modification, are permitted provided that the following conditions
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are met:
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1. Redistributions of source code must retain the above copyright
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notice, this list of conditions and the following disclaimer.
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2. Redistributions in binary form must reproduce the above copyright
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notice, this list of conditions and the following disclaimer in the
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documentation and/or other materials provided with the distribution.
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3. Neither the name of the project nor the names of its contributors
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may be used to endorse or promote products derived from this software
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without specific prior written permission.
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THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
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ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE
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FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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SUCH DAMAGE.
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*/
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/* vim: set ts=4 sw=4 et : */
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// It is not written with high efficiency in mind, so is probably
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// not suitable for real-time encoding. The aim was to keep it
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// simple, general and clear.
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//
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// <Some notes on the theory and implementation need to be added here>
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// Usage:
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// First call rs_init_gf(&rs, prime_poly) to set up the Galois Field parameters.
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// Then call rs_init_code(&rs, nsym, index) to set the encoding size
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// Then call rs_encode(&rs, datalen, data, out) to encode the data.
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//
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// These can be called repeatedly as required - but note that
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// rs_init_code must be called following any rs_init_gf call.
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//
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// If the parameters are fixed, some of the statics below can be
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// replaced with constants in the obvious way, and additionally
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// malloc/free can be avoided by using static arrays of a suitable
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// size.
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// Note: use of statics has been done for (up to) 8-bit tables.
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#ifdef _MSC_VER
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#include <malloc.h>
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#endif
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#include "common.h"
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#include "reedsol.h"
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#include "reedsol_logs.h"
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// rs_init_gf(&rs, prime_poly) initialises the parameters for the Galois Field.
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// The symbol size is determined from the highest bit set in poly
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// This implementation will support sizes up to 8 bits (see rs_uint_init_gf()
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// for sizes > 8 bits and <= 30 bits) - bit sizes of 8 or 4 are typical
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//
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// The poly is the bit pattern representing the GF characteristic
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// polynomial. e.g. for ECC200 (8-bit symbols) the polynomial is
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// a**8 + a**5 + a**3 + a**2 + 1, which translates to 0x12d.
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INTERNAL void rs_init_gf(rs_t *rs, const unsigned int prime_poly) {
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struct item {
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const unsigned char *logt;
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const unsigned char *alog;
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};
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/* To add a new prime poly of degree <= 8 add its details to this table and to the table in `test_generate()`
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* in "backend/tests/test_reedsol.c" and regenerate the log tables by running "./test_reedsol -f generate -g".
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* Paste the result in "reedsol_logs.h" */
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static const struct item data[] = {
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{ logt_0x13, alog_0x13 }, /* 0 000- */
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{ logt_0x25, alog_0x25 }, /* 0 001- */
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{ logt_0x43, alog_0x43 }, /* 0 010- */
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{ NULL, NULL },
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{ logt_0x89, alog_0x89 }, /* 0 100- */
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{ NULL, NULL },
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{ NULL, NULL },
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{ NULL, NULL },
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{ logt_0x11d, alog_0x11d }, /* 1 000- */
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{ logt_0x12d, alog_0x12d }, /* 1 001- */
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{ NULL, NULL },
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{ logt_0x163, alog_0x163 }, /* 1 011- */
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};
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/* Using bits 9-6 as hash to save a few cycles */
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/* Alter this hash or just iterate if new prime poly added that doesn't fit */
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unsigned int hash = prime_poly >> 5;
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rs->logt = data[hash].logt;
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rs->alog = data[hash].alog;
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}
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// rs_init_code(&rs, nsym, index) initialises the Reed-Solomon encoder
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// nsym is the number of symbols to be generated (to be appended
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// to the input data). index is usually 1 - it is the index of
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// the constant in the first term (i) of the RS generator polynomial:
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// (x + 2**i)*(x + 2**(i+1))*... [nsym terms]
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// For ECC200, index is 1.
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INTERNAL void rs_init_code(rs_t *rs, const int nsym, int index) {
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int i, k;
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const unsigned char *logt = rs->logt;
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const unsigned char *alog = rs->alog;
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unsigned char *rspoly = rs->rspoly;
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rs->nsym = nsym;
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rspoly[0] = 1;
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for (i = 1; i <= nsym; i++) {
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rspoly[i] = 1;
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for (k = i - 1; k > 0; k--) {
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if (rspoly[k])
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rspoly[k] = alog[logt[rspoly[k]] + index]; /* Multiply coeff by 2**index */
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rspoly[k] ^= rspoly[k - 1]; /* Add coeff of x**(k-1) * x */
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}
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rspoly[0] = alog[logt[rspoly[0]] + index]; /* 2**(i + (i+1) + ... + index) */
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index++;
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}
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}
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/* rs_encode(&rs, datalen, data, res) generates nsym Reed-Solomon codes (nsym as given in rs_init_code())
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* and places them in reverse order in res */
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INTERNAL void rs_encode(const rs_t *rs, const int datalen, const unsigned char *data, unsigned char *res) {
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int i, k;
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const unsigned char *logt = rs->logt;
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const unsigned char *alog = rs->alog;
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const unsigned char *rspoly = rs->rspoly;
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const int nsym = rs->nsym;
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memset(res, 0, nsym);
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for (i = 0; i < datalen; i++) {
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unsigned int m = res[nsym - 1] ^ data[i];
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if (m) {
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unsigned int log_m = logt[m];
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for (k = nsym - 1; k > 0; k--) {
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if (rspoly[k])
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res[k] = (unsigned char) (res[k - 1] ^ alog[log_m + logt[rspoly[k]]]);
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else
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res[k] = res[k - 1];
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}
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res[0] = alog[log_m + logt[rspoly[0]]]; /* rspoly[0] can't be zero */
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} else {
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memmove(res + 1, res, nsym - 1);
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res[0] = 0;
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}
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}
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}
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/* The same as above but for unsigned int data and result - Aztec code compatible */
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INTERNAL void rs_encode_uint(const rs_t *rs, const int datalen, const unsigned int *data, unsigned int *res) {
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int i, k;
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const unsigned char *logt = rs->logt;
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const unsigned char *alog = rs->alog;
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const unsigned char *rspoly = rs->rspoly;
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const int nsym = rs->nsym;
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memset(res, 0, sizeof(unsigned int) * nsym);
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for (i = 0; i < datalen; i++) {
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unsigned int m = res[nsym - 1] ^ data[i];
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if (m) {
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unsigned int log_m = logt[m];
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for (k = nsym - 1; k > 0; k--) {
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if (rspoly[k])
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res[k] = res[k - 1] ^ alog[log_m + logt[rspoly[k]]];
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else
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res[k] = res[k - 1];
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}
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res[0] = alog[log_m + logt[rspoly[0]]];
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} else {
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memmove(res + 1, res, sizeof(unsigned int) * (nsym - 1));
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res[0] = 0;
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}
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}
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}
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/* Versions of the above for bitlengths > 8 and <= 30 and unsigned int data and results - Aztec code compatible */
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// Usage:
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// First call rs_uint_init_gf(&rs_uint, prime_poly, logmod) to set up the Galois Field parameters.
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// Then call rs_uint_init_code(&rs_uint, nsym, index) to set the encoding size
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// Then call rs_uint_encode(&rs_uint, datalen, data, out) to encode the data.
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// Then call rs_uint_free(&rs_uint) to free the log tables.
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/* `logmod` (field characteristic) will be 2**bitlength - 1, eg 1023 for bitlength 10, 4095 for bitlength 12 */
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INTERNAL int rs_uint_init_gf(rs_uint_t *rs_uint, const unsigned int prime_poly, const int logmod) {
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int b, p, v;
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unsigned int *logt, *alog;
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b = logmod + 1;
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rs_uint->logt = NULL;
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rs_uint->alog = NULL;
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if (!(logt = (unsigned int *) calloc(b, sizeof(unsigned int)))) {
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return 0;
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}
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if (!(alog = (unsigned int *) calloc(b * 2, sizeof(unsigned int)))) {
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free(logt);
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return 0;
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}
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// Calculate the log/alog tables
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for (p = 1, v = 0; v < logmod; v++) {
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alog[v] = p;
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alog[logmod + v] = p; /* Double up, avoids mod */
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logt[p] = v;
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p <<= 1;
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if (p & b) /* If overflow */
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p ^= prime_poly; /* Subtract prime poly */
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}
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rs_uint->logt = logt;
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rs_uint->alog = alog;
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return 1;
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}
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INTERNAL void rs_uint_init_code(rs_uint_t *rs_uint, const int nsym, int index) {
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int i, k;
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const unsigned int *logt = rs_uint->logt;
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const unsigned int *alog = rs_uint->alog;
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unsigned short *rspoly = rs_uint->rspoly;
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if (logt == NULL || alog == NULL) {
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return;
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}
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rs_uint->nsym = nsym;
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rspoly[0] = 1;
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for (i = 1; i <= nsym; i++) {
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rspoly[i] = 1;
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for (k = i - 1; k > 0; k--) {
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if (rspoly[k])
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rspoly[k] = alog[(logt[rspoly[k]] + index)];
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rspoly[k] ^= rspoly[k - 1];
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}
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rspoly[0] = alog[(logt[rspoly[0]] + index)];
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index++;
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}
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}
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INTERNAL void rs_uint_encode(const rs_uint_t *rs_uint, const int datalen, const unsigned int *data,
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unsigned int *res) {
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int i, k;
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const unsigned int *logt = rs_uint->logt;
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const unsigned int *alog = rs_uint->alog;
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const unsigned short *rspoly = rs_uint->rspoly;
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const int nsym = rs_uint->nsym;
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memset(res, 0, sizeof(unsigned int) * nsym);
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if (logt == NULL || alog == NULL) {
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return;
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}
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for (i = 0; i < datalen; i++) {
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unsigned int m = res[nsym - 1] ^ data[i];
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if (m) {
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unsigned int log_m = logt[m];
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for (k = nsym - 1; k > 0; k--) {
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if (rspoly[k])
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res[k] = res[k - 1] ^ alog[log_m + logt[rspoly[k]]];
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else
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res[k] = res[k - 1];
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}
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res[0] = alog[log_m + logt[rspoly[0]]];
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} else {
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memmove(res + 1, res, sizeof(unsigned int) * (nsym - 1));
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res[0] = 0;
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}
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}
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}
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INTERNAL void rs_uint_free(rs_uint_t *rs_uint) {
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if (rs_uint->logt) {
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free(rs_uint->logt);
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rs_uint->logt = NULL;
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}
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if (rs_uint->alog) {
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free(rs_uint->alog);
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rs_uint->alog = NULL;
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}
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}
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