@ -31,20 +31,490 @@
# include <math.h>
# include <complex.h>
# include <stdint.h>
# include <string.h>
# include "soft_algs.h"
# include "liblte/phy/utils/vector.h"
# define LLR_APPROX_USE_VOLK
# define QAM16_THRESHOLD 2 / sqrt(10)
# define QAM64_THRESHOLD_1 2 / sqrt(42)
# define QAM64_THRESHOLD_2 4 / sqrt(42)
# define QAM64_THRESHOLD_3 6 / sqrt(42)
# ifdef LLR_APPROX_USE_VOLK
typedef _Complex float cf_t ;
// There are 3 implemenations: 1 - based on zones; 2 - using volk, 3 - straightforward C
# define LLR_APPROX_IMPLEMENTATION 1
# if LLR_APPROX_IMPLEMENTATION == 1
float dd [ 10000 ] [ 7 ] ; // 7 distances that are needed to compute LLR approx for 64QAM
uint32_t zone [ 10000 ] ; // Zone of received symbol with respect to grid of QAM constellation diagram
/**
* @ ingroup Received modulation symbol zone
* Determine location of received modulation symbol
*
* \ param in input symbol ( _Complex float )
* \ param z associated zone in constellation diagram ( int )
* \ param N number of symbols
*/
static void zone_QPSK ( const cf_t * in , uint32_t * z , int N )
{
int s ;
float re , im ;
for ( s = 0 ; s < N ; s + + ) {
re = __real__ in [ s ] ;
im = __imag__ in [ s ] ;
if ( re > 0 ) {
if ( im > 0 ) { /* 1st Quadrand (upper-right) */
z [ s ] = 0 ;
} else { /* 4th Quadrand (lower-right) */
z [ s ] = 1 ;
}
} else {
if ( im > 0 ) { /* 2nd Quadrand (upper-left) */
z [ s ] = 2 ;
} else { /* 3rd Quadrand (lower-left) */
z [ s ] = 3 ;
}
}
}
}
/**
* @ ingroup Received modulation symbol zone
* Determine location of received modulation symbol
*
* \ param in input symbol ( _Complex float )
* \ param z associated zone in constellation diagram ( int )
* \ param N number of symbols
*/
static void zone_QAM16 ( const cf_t * in , uint32_t * z , int N )
{
int s ;
float re , im ;
for ( s = 0 ; s < N ; s + + ) {
re = __real__ in [ s ] ;
im = __imag__ in [ s ] ;
if ( re > 0 ) {
if ( im > 0 ) { /* 1st Quadrand (upper-right) */
if ( re > QAM16_THRESHOLD ) {
if ( im > QAM16_THRESHOLD ) {
z [ s ] = 3 ;
} else {
z [ s ] = 2 ;
}
} else {
if ( im > QAM16_THRESHOLD ) {
z [ s ] = 1 ;
} else {
z [ s ] = 0 ;
}
}
} else { /* 4th Quadrand (lower-right) */
if ( re > QAM16_THRESHOLD ) {
if ( im < - QAM16_THRESHOLD ) {
z [ s ] = 7 ;
} else {
z [ s ] = 6 ;
}
} else {
if ( im < - QAM16_THRESHOLD ) {
z [ s ] = 5 ;
} else {
z [ s ] = 4 ;
}
}
}
} else {
if ( im > 0 ) { /* 2nd Quadrand (upper-left) */
if ( re < - QAM16_THRESHOLD ) {
if ( im > QAM16_THRESHOLD ) {
z [ s ] = 11 ;
} else {
z [ s ] = 10 ;
}
} else {
if ( im > QAM16_THRESHOLD ) {
z [ s ] = 9 ;
} else {
z [ s ] = 8 ;
}
}
} else { /* 3rd Quadrand (lower-left) */
if ( re < - QAM16_THRESHOLD ) {
if ( im < - QAM16_THRESHOLD ) {
z [ s ] = 15 ;
} else {
z [ s ] = 14 ;
}
} else {
if ( im < - QAM16_THRESHOLD ) {
z [ s ] = 13 ;
} else {
z [ s ] = 12 ;
}
}
}
}
}
}
/**
* @ ingroup Received modulation symbol zone
* Determine location of received modulation symbol
*
* \ param in input symbol ( _Complex float )
* \ param z associated zone in constellation diagram ( int )
* \ param N number of symbols
*/
static void zone_QAM64 ( const cf_t * in , uint32_t * z , int N )
{
int s ;
float re , im ;
for ( s = 0 ; s < N ; s + + ) {
re = __real__ in [ s ] ;
im = __imag__ in [ s ] ;
if ( re > 0 ) {
if ( im > 0 ) {
if ( re > QAM64_THRESHOLD_2 ) {
if ( re > QAM64_THRESHOLD_3 ) {
if ( im > QAM64_THRESHOLD_2 ) {
if ( im > QAM64_THRESHOLD_3 ) {
z [ s ] = 15 ;
} else {
z [ s ] = 14 ;
}
} else if ( im > QAM64_THRESHOLD_1 ) {
z [ s ] = 10 ;
} else {
z [ s ] = 11 ;
}
} else {
if ( im > QAM64_THRESHOLD_2 ) {
if ( im > QAM64_THRESHOLD_3 ) {
z [ s ] = 13 ;
} else {
z [ s ] = 12 ;
}
} else if ( im > QAM64_THRESHOLD_1 ) {
z [ s ] = 8 ;
} else {
z [ s ] = 9 ;
}
}
} else if ( re > QAM64_THRESHOLD_1 ) {
if ( im > QAM64_THRESHOLD_2 ) {
if ( im > QAM64_THRESHOLD_3 ) {
z [ s ] = 5 ;
} else {
z [ s ] = 4 ;
}
} else if ( im > QAM64_THRESHOLD_1 ) {
z [ s ] = 0 ;
} else {
z [ s ] = 1 ;
}
} else {
if ( im > QAM64_THRESHOLD_2 ) {
if ( im > QAM64_THRESHOLD_3 ) {
z [ s ] = 7 ;
} else {
z [ s ] = 6 ;
}
} else if ( im > QAM64_THRESHOLD_1 ) {
z [ s ] = 2 ;
} else {
z [ s ] = 3 ;
}
}
} else { /* forth quadrant (lower-right) */
if ( re > QAM64_THRESHOLD_2 ) {
if ( re > QAM64_THRESHOLD_3 ) {
if ( im < - QAM64_THRESHOLD_2 ) {
if ( im < - QAM64_THRESHOLD_3 ) {
z [ s ] = 31 ;
} else {
z [ s ] = 30 ;
}
} else if ( im < - QAM64_THRESHOLD_1 ) {
z [ s ] = 26 ;
} else {
z [ s ] = 27 ;
}
} else {
if ( im < - QAM64_THRESHOLD_2 ) {
if ( im < - QAM64_THRESHOLD_3 ) {
z [ s ] = 29 ;
} else {
z [ s ] = 28 ;
}
} else if ( im < - QAM64_THRESHOLD_1 ) {
z [ s ] = 24 ;
} else {
z [ s ] = 25 ;
}
}
} else if ( re > QAM64_THRESHOLD_1 ) {
if ( im < - QAM64_THRESHOLD_2 ) {
if ( im < - QAM64_THRESHOLD_3 ) {
z [ s ] = 21 ;
} else {
z [ s ] = 20 ;
}
} else if ( im < - QAM64_THRESHOLD_1 ) {
z [ s ] = 16 ;
} else {
z [ s ] = 17 ;
}
} else {
if ( im < - QAM64_THRESHOLD_2 ) {
if ( im < - QAM64_THRESHOLD_3 ) {
z [ s ] = 23 ;
} else {
z [ s ] = 22 ;
}
} else if ( im < - QAM64_THRESHOLD_1 ) {
z [ s ] = 18 ;
} else {
z [ s ] = 19 ;
}
}
}
} else { /* re < 0 */
if ( im > 0 ) { /* second quadrant (upper-left) */
if ( re < - QAM64_THRESHOLD_2 ) {
if ( re < - QAM64_THRESHOLD_3 ) {
if ( im > QAM64_THRESHOLD_2 ) {
if ( im > QAM64_THRESHOLD_3 ) {
z [ s ] = 47 ;
} else {
z [ s ] = 46 ;
}
} else if ( im > QAM64_THRESHOLD_1 ) {
z [ s ] = 42 ;
} else {
z [ s ] = 43 ;
}
} else {
if ( im > QAM64_THRESHOLD_2 ) {
if ( im > QAM64_THRESHOLD_3 ) {
z [ s ] = 45 ;
} else {
z [ s ] = 44 ;
}
} else if ( im > QAM64_THRESHOLD_1 ) {
z [ s ] = 40 ;
} else {
z [ s ] = 41 ;
}
}
} else if ( re < - QAM64_THRESHOLD_1 ) {
if ( im > QAM64_THRESHOLD_2 ) {
if ( im > QAM64_THRESHOLD_3 ) {
z [ s ] = 37 ;
} else {
z [ s ] = 36 ;
}
} else if ( im > QAM64_THRESHOLD_1 ) {
z [ s ] = 32 ;
} else {
z [ s ] = 33 ;
}
} else {
if ( im > QAM64_THRESHOLD_2 ) {
if ( im > QAM64_THRESHOLD_3 ) {
z [ s ] = 39 ;
} else {
z [ s ] = 38 ;
}
} else if ( im > QAM64_THRESHOLD_1 ) {
z [ s ] = 34 ;
} else {
z [ s ] = 35 ;
}
}
} else { /* third quadrant (lower-left) */
if ( re < - QAM64_THRESHOLD_2 ) {
if ( re < - QAM64_THRESHOLD_3 ) {
if ( im < - QAM64_THRESHOLD_2 ) {
if ( im < - QAM64_THRESHOLD_3 ) {
z [ s ] = 63 ;
} else {
z [ s ] = 62 ;
}
} else if ( im < - QAM64_THRESHOLD_1 ) {
z [ s ] = 58 ;
} else {
z [ s ] = 59 ;
}
} else {
if ( im < - QAM64_THRESHOLD_2 ) {
if ( im < - QAM64_THRESHOLD_3 ) {
z [ s ] = 61 ;
} else {
z [ s ] = 60 ;
}
} else if ( im < - QAM64_THRESHOLD_1 ) {
z [ s ] = 56 ;
} else {
z [ s ] = 57 ;
}
}
} else if ( re < - QAM64_THRESHOLD_1 ) {
if ( im < - QAM64_THRESHOLD_2 ) {
if ( im < - QAM64_THRESHOLD_3 ) {
z [ s ] = 53 ;
} else {
z [ s ] = 52 ;
}
} else if ( im < - QAM64_THRESHOLD_1 ) {
z [ s ] = 48 ;
} else {
z [ s ] = 49 ;
}
} else {
if ( im < - QAM64_THRESHOLD_2 ) {
if ( im < - QAM64_THRESHOLD_3 ) {
z [ s ] = 55 ;
} else {
z [ s ] = 54 ;
}
} else if ( im < - QAM64_THRESHOLD_1 ) {
z [ s ] = 50 ;
} else {
z [ s ] = 51 ;
}
}
}
}
}
}
static void compute_zone ( const cf_t * in , uint32_t * z , int N , int B )
{
switch ( B ) {
case 1 : {
memset ( zone , 0 , N * sizeof ( int ) ) ;
break ;
} /* BPSK */
case 2 : {
zone_QPSK ( in , z , N ) ;
break ;
} /* QPSK */
case 4 : {
zone_QAM16 ( in , z , N ) ;
break ;
} /* 16QAM */
case 6 : {
zone_QAM64 ( in , z , N ) ;
break ;
} /* 64QAM */
}
}
static void compute_square_dist ( const cf_t * in , cf_t * symbols ,
uint32_t ( * idx ) [ 7 ] , int N , int B )
{
int s , b ;
float * d_ptr ;
cf_t symbols_extract [ 7 ] ;
for ( s = 0 ; s < N ; s + + ) { /* N: number of received symbols */
d_ptr = dd [ s ] ;
for ( b = 0 ; b < B + 1 ; b + + ) {
symbols_extract [ b ] = symbols [ idx [ zone [ s ] ] [ b ] ] ; /* only subset of distances to constellation points needed for LLR approx */
//x = __real__ in[s] - __real__ symbols[idx[zone[s]][b]];
//y = __imag__ in[s] - __imag__ symbols[idx[zone[s]][b]];
//dd[s][b] = x*x + y*y;
//printf("\n%f + j %f", __real__ symbols_extract[b], __imag__ symbols_extract[b]);
}
vec_square_dist ( in [ s ] , symbols_extract , d_ptr , B + 1 ) ; /* B+1 distances to be computed */
}
}
static void compute_llr ( int N , int B , uint32_t ( * min ) [ 64 ] [ 6 ] , float sigma2 ,
float * out )
{
int s , b ;
for ( s = 0 ; s < N ; s + + ) {
for ( b = 0 ; b < B ; b + + ) { /* bits per symbol */
out [ s * B + b ] =
( dd [ s ] [ min [ 0 ] [ zone [ s ] ] [ b ] ] - dd [ s ] [ min [ 1 ] [ zone [ s ] ] [ b ] ] ) / sigma2 ;
}
}
}
void llr_approx ( const _Complex float * in , float * out , int N , int M , int B ,
_Complex float * symbols , uint32_t ( * S ) [ 6 ] [ 32 ] , uint32_t ( * idx ) [ 7 ] ,
uint32_t ( * min ) [ 64 ] [ 6 ] , float sigma2 )
{
if ( ( M = = 2 ) | | ( M = = 4 ) | | ( M = = 16 ) | | ( M = = 64 ) ) {
compute_zone ( in , zone , N , B ) ;
compute_square_dist ( in , symbols , idx , N , B ) ;
compute_llr ( N , B , min , sigma2 , out ) ;
}
}
# elif LLR_APPROX_IMPLEMENTATION == 2
float d [ 10000 ] [ 64 ] ;
float num [ 10000 ] , den [ 10000 ] ;
static void compute_square_dist ( const cf_t * in , cf_t * symbols , int N , int M ) {
static void compute_square_dist ( const cf_t * in , cf_t * symbols , int N , int M )
{
int s ;
float * d_ptr ;
for ( s = 0 ; s < N ; s + + ) {
@ -53,7 +523,8 @@ static void compute_square_dist(const cf_t *in, cf_t *symbols, int N, int M) {
}
}
static void compute_min_dist ( uint32_t ( * S ) [ 6 ] [ 32 ] , int N , int B , int M ) {
static void compute_min_dist ( uint32_t ( * S ) [ 6 ] [ 32 ] , int N , int B , int M )
{
int s , b , i ;
for ( s = 0 ; s < N ; s + + ) {
for ( b = 0 ; b < B ; b + + ) { /* bits per symbol */
@ -73,11 +544,12 @@ static void compute_min_dist(uint32_t (*S)[6][32], int N, int B, int M) {
}
}
static void compute_llr ( int N , int B , float sigma2 , float * out ) {
static void compute_llr ( int N , int B , float sigma2 , float * out )
{
int s , b ;
for ( s = 0 ; s < N ; s + + ) {
for ( b = 0 ; b < B ; b + + ) { /* bits per symbol */
out [ s * B + b ] = ( num [ s * B + b ] - den [ s * B + b ] ) / sigma2 ;
out [ s * B + b ] = ( num [ s * B + b ] - den [ s * B + b ] ) / sigma2 ;
}
}
}
@ -86,6 +558,23 @@ void llr_approx(const _Complex float *in, float *out, int N, int M, int B,
_Complex float * symbols , uint32_t ( * S ) [ 6 ] [ 32 ] , float sigma2 )
{
if ( M < = 64 ) {
compute_square_dist ( in , symbols , N , M ) ;
compute_min_dist ( S , N , B , M ) ;
compute_llr ( N , B , sigma2 , out ) ;
}
for ( b = 0 ; b < B ; b + + ) { /* bits per symbol */
out [ s * B + b ] = ( num [ s * B + b ] - den [ s * B + b ] ) / sigma2 ;
}
}
void llr_approx ( const _Complex float * in , float * out , int N , int M , int B ,
_Complex float * symbols , uint32_t ( * S ) [ 6 ] [ 32 ] , uint32_t ( * idx ) [ 7 ] ,
uint32_t ( * min ) [ 64 ] [ 6 ] , float sigma2 )
{
if ( M < = 64 ) {
compute_square_dist ( in , symbols , N , M ) ;
@ -113,9 +602,9 @@ void llr_approx(const _Complex float *in, float *out, int N, int M, int B,
* \ param S Soft demapping auxiliary matrix
* \ param sigma2 Noise vatiance
*/
void
llr_approx ( const _Complex float * in , float * out , int N , int M , int B ,
_Complex float * symbols , uint32_t ( * S ) [ 6 ] [ 32 ] , float sigma2 )
void llr_approx ( const _Complex float * in , float * out , int N , int M , int B ,
_Complex float * symbols , uint32_t ( * S ) [ 6 ] [ 32 ] , uint32_t ( * idx ) [ 7 ] ,
uint32_t ( * min ) [ 64 ] [ 6 ] , float sigma2 )
{
int i , s , b ;
float num , den ;
@ -150,10 +639,12 @@ llr_approx(const _Complex float *in, float *out, int N, int M, int B,
* with ' 1 ' are closer .
* Change sign if mapping negative to ' 0 ' and positive to ' 1 ' */
out [ s * B + b ] = change_sign * ( den - num ) / sigma2 ;
if ( s < 10 )
printf ( " out[%d]=%f=%f/%f \n " , s * B + b , out [ s * B + b ] , num , den ) ;
}
if ( s < 10 )
printf ( " out[%d]=%f=%f/%f \n " , s * B + b , out [ s * B + b ] , num , den ) ;
}
/* if (s<10)
printf ( " out[%d]=%f=%f/%f \n " , s * B + b , out [ s * B + b ] , num , den ) ;
*/ }
}