WSJT-X/lib/wsprd/jelinek.c
Steven Franke 8ed8b9eb13 Remove redundant comparison.
git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5724 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-07-27 00:46:32 +00:00

164 lines
5.9 KiB
C

/*
Soft-decision stack-based sequential decoder for K=32 r=1/2
convolutional code. This code implements the "stack-bucket" algorithm
described in:
"Fast Sequential Decoding Algorithm Using a Stack", F. Jelinek
The ENCODE macro from Phil Karn's (KA9Q) Fano decoder is used.
Written by Steve Franke, K9AN for WSJT-X (July 2015)
*/
#include "jelinek.h"
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <string.h> /* memset */
#include "fano.h"
/* WSPR uses the Layland-Lushbaugh code
* Nonsystematic, non-quick look-in, dmin=?, dfree=?
*/
#define POLY1 0xf2d05351
#define POLY2 0xe4613c47
//Decoder - returns 0 on success, -1 on timeout
int jelinek(
unsigned int *metric, /* Final path metric (returned value) */
unsigned int *cycles, /* Cycle count (returned value) */
unsigned char *data, /* Decoded output data */
unsigned char *symbols, /* Raw deinterleaved input symbols */
unsigned int nbits, /* Number of output bits */
unsigned int stacksize,
struct snode *stack,
int mettab[2][256], /* Metric table, [sent sym][rx symbol] */
unsigned int maxcycles)/* Decoding timeout in cycles per bit */
{
// Compute branch metrics for each symbol pair
// The sequential decoding algorithm only uses the metrics, not the
// symbol values.
unsigned int i;
long int metrics[81][4];
for(i=0; i<nbits; i++){
metrics[i][0] = mettab[0][symbols[0]] + mettab[0][symbols[1]];
metrics[i][1] = mettab[0][symbols[0]] + mettab[1][symbols[1]];
metrics[i][2] = mettab[1][symbols[0]] + mettab[0][symbols[1]];
metrics[i][3] = mettab[1][symbols[0]] + mettab[1][symbols[1]];
symbols += 2;
}
// zero the stack
memset(stack,0,stacksize*sizeof(struct snode));
// initialize the loop variables
unsigned int lsym, ntail=31;
uint64_t encstate=0;
unsigned int nbuckets=1000;
unsigned int low_bucket=nbuckets-1; //will be set on first run-through
unsigned int high_bucket=0;
unsigned int *buckets, bucket;
buckets=malloc(nbuckets*sizeof(unsigned int));
memset(buckets,0,nbuckets*sizeof(unsigned int));
unsigned int ptr=1;
unsigned int stackptr=1; //pointer values of 0 are reserved (they mean that a bucket is empty)
unsigned int depth=0, nbits_minus_ntail=nbits-ntail;
unsigned int stacksize_minus_1=stacksize-1;
long int totmet0, totmet1, gamma=0;
unsigned int ncycles=maxcycles*nbits;
/********************* Start the stack decoder *****************/
for (i=1; i <= ncycles; i++) {
#ifdef DEBUG
printf("***stackptr=%ld, depth=%d, gamma=%d, encstate=%lx, bucket %d, low_bucket %d, high_bucket %d\n",
stackptr, depth, gamma, encstate, bucket, low_bucket, high_bucket);
#endif
// no need to store more than 7 bytes (56 bits) for encoder state because
// only 50 bits are not 0's.
if( depth < 56 ) {
encstate=encstate<<1;
ENCODE(lsym,encstate); // get channel symbols associated with the 0 branch
} else {
ENCODE(lsym,encstate<<(depth-55));
}
// lsym are the 0-branch channel symbols and 3^lsym are the 1-branch
// channel symbols (due to a special property of our generator polynomials)
totmet0 = gamma+metrics[depth][lsym]; // total metric for 0-branch daughter node
totmet1 = gamma+metrics[depth][3^lsym]; // total metric for 1-branch daughter node
depth++; //the depth of the daughter nodes
bucket=(totmet0>>5)+200; //fast, but not particularly safe - totmet can be negative
if( bucket > high_bucket ) high_bucket=bucket;
if( bucket < low_bucket ) low_bucket=bucket;
// place the 0 node on the stack, overwriting the parent (current) node
stack[ptr].encstate=encstate;
stack[ptr].gamma=totmet0;
stack[ptr].depth=depth;
stack[ptr].jpointer=buckets[bucket];
buckets[bucket]=ptr;
// if in the tail, only need to evaluate the "0" branch.
// Otherwise, enter this "if" and place the 1 node on the stack,
if( depth <= nbits_minus_ntail ) {
if( stackptr < stacksize_minus_1 ) {
stackptr++;
ptr=stackptr;
} else { // stack full
while( buckets[low_bucket] == 0 ) { //write latest to where the top of the lowest bucket points
low_bucket++;
}
ptr=buckets[low_bucket];
buckets[low_bucket]=stack[ptr].jpointer; //make bucket point to next older entry
}
bucket=(totmet1>>5)+200; //this may not be safe on all compilers
if( bucket > high_bucket ) high_bucket=bucket;
if( bucket < low_bucket ) low_bucket=bucket;
stack[ptr].encstate=encstate+1;
stack[ptr].gamma=totmet1;
stack[ptr].depth=depth;
stack[ptr].jpointer=buckets[bucket];
buckets[bucket]=ptr;
}
// pick off the latest entry from the high bucket
while( buckets[high_bucket] == 0 ) {
high_bucket--;
}
ptr=buckets[high_bucket];
buckets[high_bucket]=stack[ptr].jpointer;
depth=stack[ptr].depth;
gamma=stack[ptr].gamma;
encstate=stack[ptr].encstate;
// we are done if the top entry on the stack is at depth nbits
if (depth == nbits) {
break;
}
}
*cycles = i+1;
*metric = gamma; /* Return final path metric */
// printf("cycles %d stackptr=%d, depth=%d, gamma=%d, encstate=%lx\n",
// *cycles, stackptr, depth, *metric, encstate);
for (i=0; i<7; i++) {
data[i]=(encstate>>(48-i*8))&(0x00000000000000ff);
}
for (i=7; i<11; i++) {
data[i]=0;
}
if(*cycles/nbits >= maxcycles) //timed out
{
return -1;
}
return 0; //success
}