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sdrangel/plugins/channelrx/demoddatv/ldpctool/flooding_decoder.h

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2021-03-02 00:02:38 -05:00
/*
LDPC SISO flooding decoder
Copyright 2018 Ahmet Inan <xdsopl@gmail.com>
*/
#ifndef FLOODING_DECODER_HH
#define FLOODING_DECODER_HH
#include <stdlib.h>
#include "exclusive_reduce.h"
#include "ldpc.h"
namespace ldpctool {
template <typename TYPE, typename ALG>
class LDPCDecoder
{
void *aligned_buffer;
TYPE *bnl, *bnv, *cnl, *cnv;
uint8_t *cnc;
LDPCInterface *ldpc;
ALG alg;
int N, K, R, CNL, LT;
bool initialized;
void bit_node_init(TYPE *data, TYPE *parity)
{
TYPE *bl = bnl;
for (int i = 0; i < R-1; ++i) {
bnv[i] = parity[i];
*bl++ = parity[i];
*bl++ = parity[i];
}
bnv[R-1] = parity[R-1];
*bl++ = parity[R-1];
ldpc->first_bit();
for (int j = 0; j < K; ++j) {
bnv[j+R] = data[j];
int bit_deg = ldpc->bit_deg();
for (int n = 0; n < bit_deg; ++n)
*bl++ = data[j];
ldpc->next_bit();
}
}
void check_node_update()
{
TYPE *bl = bnl;
cnv[0] = alg.sign(alg.one(), bnv[0]);
cnl[0] = *bl++;
cnc[0] = 1;
for (int i = 1; i < R; ++i) {
cnv[i] = alg.sign(alg.sign(alg.one(), bnv[i-1]), bnv[i]);
cnl[CNL*i] = *bl++;
cnl[CNL*i+1] = *bl++;
cnc[i] = 2;
}
ldpc->first_bit();
for (int j = 0; j < K; ++j) {
int *acc_pos = ldpc->acc_pos();
int bit_deg = ldpc->bit_deg();
for (int n = 0; n < bit_deg; ++n) {
int i = acc_pos[n];
cnv[i] = alg.sign(cnv[i], bnv[j+R]);
cnl[CNL*i+cnc[i]++] = *bl++;
}
ldpc->next_bit();
}
for (int i = 0; i < R; ++i)
alg.finalp(cnl+CNL*i, cnc[i]);
}
void bit_node_update(TYPE *data, TYPE *parity)
{
TYPE *bl = bnl;
bnv[0] = alg.add(parity[0], alg.add(cnl[0], cnl[CNL]));
alg.update(bl++, alg.add(parity[0], cnl[CNL]));
alg.update(bl++, alg.add(parity[0], cnl[0]));
cnc[0] = 1;
for (int i = 1; i < R-1; ++i) {
bnv[i] = alg.add(parity[i], alg.add(cnl[CNL*i+1], cnl[CNL*(i+1)]));
alg.update(bl++, alg.add(parity[i], cnl[CNL*(i+1)]));
alg.update(bl++, alg.add(parity[i], cnl[CNL*i+1]));
cnc[i] = 2;
}
bnv[R-1] = alg.add(parity[R-1], cnl[CNL*(R-1)+1]);
alg.update(bl++, parity[R-1]);
cnc[R-1] = 2;
ldpc->first_bit();
for (int j = 0; j < K; ++j) {
int *acc_pos = ldpc->acc_pos();
int bit_deg = ldpc->bit_deg();
TYPE inp[bit_deg];
for (int n = 0; n < bit_deg; ++n) {
int i = acc_pos[n];
inp[n] = cnl[CNL*i+cnc[i]++];
}
TYPE out[bit_deg];
CODE::exclusive_reduce(inp, out, bit_deg, alg.add);
bnv[j+R] = alg.add(data[j], alg.add(out[0], inp[0]));
for (int n = 0; n < bit_deg; ++n)
alg.update(bl++, alg.add(data[j], out[n]));
ldpc->next_bit();
}
}
bool hard_decision(int blocks)
{
for (int i = 0; i < R; ++i)
if (alg.bad(cnv[i], blocks))
return true;
return false;
}
void update_user(TYPE *data, TYPE *parity)
{
for (int i = 0; i < R; ++i)
parity[i] = bnv[i];
for (int i = 0; i < K; ++i)
data[i] = bnv[i+R];
}
public:
LDPCDecoder() : initialized(false)
{
}
void init(LDPCInterface *it)
{
if (initialized) {
free(aligned_buffer);
delete[] cnc;
delete ldpc;
}
initialized = true;
ldpc = it->clone();
N = ldpc->code_len();
K = ldpc->data_len();
R = N - K;
CNL = ldpc->links_max_cn();
LT = ldpc->links_total();
int num = LT + N + R * CNL + R;
aligned_buffer = aligned_alloc(sizeof(TYPE), sizeof(TYPE) * num);
TYPE *ptr = reinterpret_cast<TYPE *>(aligned_buffer);
bnl = ptr; ptr += LT;
bnv = ptr; ptr += N;
cnl = ptr; ptr += R * CNL;
cnv = ptr; ptr += R;
cnc = new uint8_t[R];
}
int operator()(TYPE *data, TYPE *parity, int trials = 50, int blocks = 1)
{
bit_node_init(data, parity);
check_node_update();
if (!hard_decision(blocks))
return trials;
--trials;
bit_node_update(data, parity);
check_node_update();
while (hard_decision(blocks) && --trials >= 0) {
bit_node_update(data, parity);
check_node_update();
}
update_user(data, parity);
return trials;
}
~LDPCDecoder()
{
if (initialized) {
free(aligned_buffer);
delete[] cnc;
delete ldpc;
}
}
};
} // namespace ldpctool
#endif