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/*
This software is part of libcsdr , a set of simple DSP routines for
Software Defined Radio .
Copyright ( c ) 2014 , Andras Retzler < randras @ sdr . hu >
All rights reserved .
Redistribution and use in source and binary forms , with or without
modification , are permitted provided that the following conditions are met :
* Redistributions of source code must retain the above copyright
notice , this list of conditions and the following disclaimer .
* Redistributions in binary form must reproduce the above copyright
notice , this list of conditions and the following disclaimer in the
documentation and / or other materials provided with the distribution .
* Neither the name of the copyright holder nor the
names of its contributors may be used to endorse or promote products
derived from this software without specific prior written permission .
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS " AS IS " AND
ANY EXPRESS OR IMPLIED WARRANTIES , INCLUDING , BUT NOT LIMITED TO , THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED . IN NO EVENT SHALL ANDRAS RETZLER BE LIABLE FOR ANY
DIRECT , INDIRECT , INCIDENTAL , SPECIAL , EXEMPLARY , OR CONSEQUENTIAL DAMAGES
( INCLUDING , BUT NOT LIMITED TO , PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES ;
LOSS OF USE , DATA , OR PROFITS ; OR BUSINESS INTERRUPTION ) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY , WHETHER IN CONTRACT , STRICT LIABILITY , OR TORT
( INCLUDING NEGLIGENCE OR OTHERWISE ) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE , EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE .
*/
# include <stdio.h>
# include <time.h>
# include <math.h>
# include <stdlib.h>
# include <string.h>
# include <unistd.h>
# include <limits.h>
# include "libcsdr.h"
# include "predefined.h"
# include <assert.h>
/*
_ _ __ _ _
( _ ) | | / _ | | | ( _ )
__ ___ _ __ __ | | _____ __ | | _ _ _ _ __ ___ | | _ _ ___ _ __ ___
\ \ / \ / / | ' _ \ / _ ` | / _ \ \ / \ / / | _ | | | | ' _ \ / __ | __ | | / _ \ | ' _ \ / __ |
\ V V / | | | | | ( _ | | ( _ ) \ V V / | | | | _ | | | | | ( __ | | _ | | ( _ ) | | | \ __ \
\ _ / \ _ / | _ | _ | | _ | \ __ , _ | \ ___ / \ _ / \ _ / | _ | \ __ , _ | _ | | _ | \ ___ | \ __ | _ | \ ___ / | _ | | _ | ___ /
*/
# define MFIRDES_GWS(NAME) \
if ( ! strcmp ( # NAME , input ) ) return WINDOW_ # # NAME ;
window_t firdes_get_window_from_string ( char * input )
{
MFIRDES_GWS ( BOXCAR ) ;
MFIRDES_GWS ( BLACKMAN ) ;
MFIRDES_GWS ( HAMMING ) ;
return WINDOW_DEFAULT ;
}
# define MFIRDES_GSW(NAME) \
if ( window = = WINDOW_ # # NAME ) return # NAME ;
char * firdes_get_string_from_window ( window_t window )
{
MFIRDES_GSW ( BOXCAR ) ;
MFIRDES_GSW ( BLACKMAN ) ;
MFIRDES_GSW ( HAMMING ) ;
return " INVALID " ;
}
float firdes_wkernel_blackman ( float rate )
{
//Explanation at Chapter 16 of dspguide.com, page 2
//Blackman window has better stopband attentuation and passband ripple than Hamming, but it has slower rolloff.
rate = 0.5 + rate / 2 ;
return 0.42 - 0.5 * cos ( 2 * PI * rate ) + 0.08 * cos ( 4 * PI * rate ) ;
}
float firdes_wkernel_hamming ( float rate )
{
//Explanation at Chapter 16 of dspguide.com, page 2
//Hamming window has worse stopband attentuation and passband ripple than Blackman, but it has faster rolloff.
rate = 0.5 + rate / 2 ;
return 0.54 - 0.46 * cos ( 2 * PI * rate ) ;
}
float firdes_wkernel_boxcar ( float rate )
{ //"Dummy" window kernel, do not use; an unwindowed FIR filter may have bad frequency response
return 1.0 ;
}
float ( * firdes_get_window_kernel ( window_t window ) ) ( float )
{
if ( window = = WINDOW_HAMMING ) return firdes_wkernel_hamming ;
else if ( window = = WINDOW_BLACKMAN ) return firdes_wkernel_blackman ;
else if ( window = = WINDOW_BOXCAR ) return firdes_wkernel_boxcar ;
else return firdes_get_window_kernel ( WINDOW_DEFAULT ) ;
}
/*
______ _____ _____ __ _ _ _ _ _
| ____ | _ _ | __ \ / _ ( _ ) | | | | ( _ )
| | __ | | | | __ ) | | | _ _ | | | _ ___ _ __ __ | | ___ ___ _ __ _ _ __
| __ | | | | _ / | _ | | | __ / _ \ ' __ | / _ ` | / _ \ / __ | | / _ ` | ' _ \
| | _ | | _ | | \ \ | | | | | | | __ / | | ( _ | | __ / \ __ \ | ( _ | | | | |
| _ | | _____ | _ | \ _ \ | _ | | _ | _ | \ __ \ ___ | _ | \ __ , _ | \ ___ | | ___ / _ | \ __ , | _ | | _ |
__ / |
| ___ /
*/
void firdes_lowpass_f ( float * output , int length , float cutoff_rate , window_t window )
{ //Generates symmetric windowed sinc FIR filter real taps
// length should be odd
// cutoff_rate is (cutoff frequency/sampling frequency)
//Explanation at Chapter 16 of dspguide.com
int middle = length / 2 ;
float temp ;
float ( * window_function ) ( float ) = firdes_get_window_kernel ( window ) ;
output [ middle ] = 2 * PI * cutoff_rate * window_function ( 0 ) ;
for ( int i = 1 ; i < = middle ; i + + ) //@@firdes_lowpass_f: calculate taps
{
output [ middle - i ] = output [ middle + i ] = ( sin ( 2 * PI * cutoff_rate * i ) / i ) * window_function ( ( float ) i / middle ) ;
//printf("%g %d %d %d %d | %g\n",output[middle-i],i,middle,middle+i,middle-i,sin(2*PI*cutoff_rate*i));
}
//Normalize filter kernel
float sum = 0 ;
for ( int i = 0 ; i < length ; i + + ) //@firdes_lowpass_f: normalize pass 1
{
sum + = output [ i ] ;
}
for ( int i = 0 ; i < length ; i + + ) //@firdes_lowpass_f: normalize pass 2
{
output [ i ] / = sum ;
}
}
void firdes_bandpass_c ( complexf * output , int length , float lowcut , float highcut , window_t window )
{
//To generate a complex filter:
// 1. we generate a real lowpass filter with a bandwidth of highcut-lowcut
// 2. we shift the filter taps spectrally by multiplying with e^(j*w), so we get complex taps
//(tnx HA5FT)
float * realtaps = ( float * ) malloc ( sizeof ( float ) * length ) ;
firdes_lowpass_f ( realtaps , length , ( highcut - lowcut ) / 2 , window ) ;
float filter_center = ( highcut + lowcut ) / 2 ;
float phase = 0 , sinval , cosval ;
for ( int i = 0 ; i < length ; i + + ) //@@firdes_bandpass_c
{
cosval = cos ( phase ) ;
sinval = sin ( phase ) ;
phase + = 2 * PI * filter_center ;
while ( phase > 2 * PI ) phase - = 2 * PI ; //@@firdes_bandpass_c
while ( phase < 0 ) phase + = 2 * PI ;
iof ( output , i ) = cosval * realtaps [ i ] ;
qof ( output , i ) = sinval * realtaps [ i ] ;
//output[i] := realtaps[i] * e^j*w
}
}
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int firdes_filter_len ( float transition_bw )
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{
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int result = 4.0 / transition_bw ;
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if ( result % 2 = = 0 ) result + + ; //number of symmetric FIR filter taps should be odd
return result ;
}
/*
_____ _____ _____ __ _ _
| __ \ / ____ | __ \ / _ | | | ( _ )
| | | | ( ___ | | __ ) | | | _ _ _ _ __ ___ | | _ _ ___ _ __ ___
| | | | \ ___ \ | ___ / | _ | | | | ' _ \ / __ | __ | | / _ \ | ' _ \ / __ |
| | __ | | ____ ) | | | | | | _ | | | | | ( __ | | _ | | ( _ ) | | | \ __ \
| _____ / | _____ / | _ | | _ | \ __ , _ | _ | | _ | \ ___ | \ __ | _ | \ ___ / | _ | | _ | ___ /
*/
float shift_math_cc ( complexf * input , complexf * output , int input_size , float rate , float starting_phase )
{
rate * = 2 ;
//Shifts the complex spectrum. Basically a complex mixer. This version uses cmath.
float phase = starting_phase ;
float phase_increment = rate * PI ;
float cosval , sinval ;
for ( int i = 0 ; i < input_size ; i + + ) //@shift_math_cc
{
cosval = cos ( phase ) ;
sinval = sin ( phase ) ;
//we multiply two complex numbers.
//how? enter this to maxima (software) for explanation:
// (a+b*%i)*(c+d*%i), rectform;
iof ( output , i ) = cosval * iof ( input , i ) - sinval * qof ( input , i ) ;
qof ( output , i ) = sinval * iof ( input , i ) + cosval * qof ( input , i ) ;
phase + = phase_increment ;
while ( phase > 2 * PI ) phase - = 2 * PI ; //@shift_math_cc: normalize phase
while ( phase < 0 ) phase + = 2 * PI ;
}
return phase ;
}
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shift_table_data_t shift_table_init ( int table_size )
{
//RTODO
shift_table_data_t output ;
output . table = ( float * ) malloc ( sizeof ( float ) * table_size ) ;
output . table_size = table_size ;
for ( int i = 0 ; i < table_size ; i + + )
{
output . table [ i ] = sin ( ( ( float ) i / table_size ) * ( PI / 2 ) ) ;
}
return output ;
}
void shift_table_deinit ( shift_table_data_t table_data )
{
free ( table_data . table ) ;
}
float shift_table_cc ( complexf * input , complexf * output , int input_size , float rate , shift_table_data_t table_data , float starting_phase )
{
//RTODO
rate * = 2 ;
//Shifts the complex spectrum. Basically a complex mixer. This version uses a pre-built sine table.
float phase = starting_phase ;
float phase_increment = rate * PI ;
float cosval , sinval ;
for ( int i = 0 ; i < input_size ; i + + ) //@shift_math_cc
{
int sin_index , cos_index , temp_index , sin_sign , cos_sign ;
//float vphase=fmodf(phase,PI/2); //between 0 and 90deg
int quadrant = phase / ( PI / 2 ) ; //between 0 and 3
float vphase = phase - quadrant * ( PI / 2 ) ;
sin_index = ( vphase / ( PI / 2 ) ) * table_data . table_size ;
cos_index = table_data . table_size - 1 - sin_index ;
if ( quadrant & 1 ) //in quadrant 1 and 3
{
temp_index = sin_index ;
sin_index = cos_index ;
cos_index = temp_index ;
}
sin_sign = ( quadrant > 1 ) ? - 1 : 1 ; //in quadrant 2 and 3
cos_sign = ( quadrant & & quadrant < 3 ) ? - 1 : 1 ; //in quadrant 1 and 2
sinval = sin_sign * table_data . table [ sin_index ] ;
cosval = cos_sign * table_data . table [ cos_index ] ;
//we multiply two complex numbers.
//how? enter this to maxima (software) for explanation:
// (a+b*%i)*(c+d*%i), rectform;
iof ( output , i ) = cosval * iof ( input , i ) - sinval * qof ( input , i ) ;
qof ( output , i ) = sinval * iof ( input , i ) + cosval * qof ( input , i ) ;
phase + = phase_increment ;
while ( phase > 2 * PI ) phase - = 2 * PI ; //@shift_math_cc: normalize phase
while ( phase < 0 ) phase + = 2 * PI ;
}
return phase ;
}
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shift_addfast_data_t shift_addfast_init ( float rate )
{
shift_addfast_data_t output ;
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output . phase_increment = 2 * rate * PI ;
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for ( int i = 0 ; i < 4 ; i + + )
{
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output . dsin [ i ] = sin ( output . phase_increment * ( i + 1 ) ) ;
output . dcos [ i ] = cos ( output . phase_increment * ( i + 1 ) ) ;
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}
return output ;
}
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# ifdef NEON_OPTS
# pragma message "Manual NEON optimizations are ON: we have a faster shift_addfast_cc now."
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float shift_addfast_cc ( complexf * input , complexf * output , int input_size , shift_addfast_data_t * d , float starting_phase )
{
//input_size should be multiple of 4
float phase = starting_phase ;
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float cos_start [ 4 ] , sin_start [ 4 ] ;
float cos_vals [ 4 ] , sin_vals [ 4 ] ;
for ( int i = 0 ; i < 4 ; i + + )
{
cos_start [ i ] = cos ( starting_phase ) ;
sin_start [ i ] = sin ( starting_phase ) ;
}
float * pdcos = d - > dcos ;
float * pdsin = d - > dsin ;
register float * pinput = ( float * ) input ;
register float * pinput_end = ( ( float * ) input ) + input_size ;
register float * poutput = ( float * ) output ;
# define RDCOS "q0" //dcos, dsin
# define RDSIN "q1"
# define RCOSST "q2" //cos_start, sin_start
# define RSINST "q3"
# define RCOSV "q4" //cos_vals, sin_vals
# define RSINV "q5"
# define ROUTI "q6" //output_i, output_q
# define ROUTQ "q7"
# define RINPI "q8" //input_i, input_q
# define RINPQ "q9"
# define R3(x,y,z) x ", " y ", " z "\n\t"
asm volatile ( //(the range is q0-015)
" vld1.32 { " RDCOS " }, [%[pdcos]] \n \t "
" vld1.32 { " RDSIN " }, [%[pdsin]] \n \t "
" vld1.32 { " RCOSST " }, [%[cos_start]] \n \t "
" vld1.32 { " RSINST " }, [%[sin_start]] \n \t "
" for_addfast: vld2.32 { " RINPI " - " RINPQ " }, [%[pinput]]! \n \t " //load q0 and q1 directly from the memory address stored in pinput, with interleaving (so that we get the I samples in rinpi and the Q samples in rinpq), also increment the memory address in pinput (hence the "!" mark)
//C version:
//cos_vals[j] = cos_start * d->dcos[j] - sin_start * d->dsin[j];
//sin_vals[j] = sin_start * d->dcos[j] + cos_start * d->dsin[j];
" vmul.f32 " R3 ( RCOSV , RCOSST , RDCOS ) //cos_vals[i] = cos_start * d->dcos[i]
" vmls.f32 " R3 ( RCOSV , RSINST , RDSIN ) //cos_vals[i] -= sin_start * d->dsin[i]
" vmul.f32 " R3 ( RSINV , RSINST , RDCOS ) //sin_vals[i] = sin_start * d->dcos[i]
" vmla.f32 " R3 ( RCOSV , RSINST , RDSIN ) //sin_vals[i] += cos_start * d->dsin[i]
//C version:
//iof(output,4*i+j)=cos_vals[j]*iof(input,4*i+j)-sin_vals[j]*qof(input,4*i+j);
//qof(output,4*i+j)=sin_vals[j]*iof(input,4*i+j)+cos_vals[j]*qof(input,4*i+j);
" vmul.f32 " R3 ( ROUTI , RCOSV , RINPI ) //output = cos_vals * input
" vmls.f32 " R3 ( ROUTI , RSINV , RINPQ ) //output -= sin_vals * input
" vmul.f32 " R3 ( ROUTQ , RSINV , RINPI ) //sin_vals[i] = sin_start * d->dcos[i]
" vmla.f32 " R3 ( ROUTQ , RCOSV , RINPQ ) //sin_vals[i] += cos_start * d->dsin[i]
" vst2.32 { " ROUTI " - " ROUTQ " }, [%[poutput]]! \n \t " //store the outputs in memory
" vdup.32 " RCOSST " , d5[1] \n \t " // cos_start[0-3] = cos_vals[3]
" vdup.32 " RSINST " , d7[1] \n \t " // sin_start[0-3] = sin_vals[3]
" cmp %[pinput], %[pinput_end] \n \t " //if(pinput == pinput_end)
" bcc for_fdccasm \n \t " // then goto for_fdcasm
:
[ pinput ] " +r " ( pinput ) , [ poutput ] " +r " ( poutput ) //output operand list -> C variables that we will change from ASM
:
[ pinput_end ] " r " ( pinput_end ) , [ pdcos ] " r " ( pdcos ) , [ pdsin ] " r " ( pdsin ) , [ sin_start ] " r " ( sin_start ) , [ cos_start ] " r " ( cos_start ) //input operand list
:
" memory " , " q0 " , " q1 " , " q2 " , " q4 " , " q5 " , " q6 " , " q7 " , " q8 " , " q9 " , " cc " //clobber list
) ;
return phase + input_size * d - > phase_increment ;
}
# else
float shift_addfast_cc ( complexf * input , complexf * output , int input_size , shift_addfast_data_t * d , float starting_phase )
{
//input_size should be multiple of 4
//fprintf(stderr, "shift_addfast_cc: input_size = %d\n", input_size);
float phase = starting_phase ;
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float cos_start = cos ( starting_phase ) ;
float sin_start = sin ( starting_phase ) ;
float cos_vals [ 4 ] , sin_vals [ 4 ] ;
for ( int i = 0 ; i < input_size / 4 ; i + + ) //@shift_addfast_cc
{
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for ( int j = 0 ; j < 4 ; j + + ) //@shift_addfast_cc
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{
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cos_vals [ j ] = cos_start * d - > dcos [ j ] - sin_start * d - > dsin [ j ] ;
sin_vals [ j ] = sin_start * d - > dcos [ j ] + cos_start * d - > dsin [ j ] ;
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}
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for ( int j = 0 ; j < 4 ; j + + ) //@shift_addfast_cc
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{
iof ( output , 4 * i + j ) = cos_vals [ j ] * iof ( input , 4 * i + j ) - sin_vals [ j ] * qof ( input , 4 * i + j ) ;
qof ( output , 4 * i + j ) = sin_vals [ j ] * iof ( input , 4 * i + j ) + cos_vals [ j ] * qof ( input , 4 * i + j ) ;
}
cos_start = cos_vals [ 3 ] ;
sin_start = sin_vals [ 3 ] ;
}
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return phase + input_size * d - > phase_increment ;
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}
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# endif
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# ifdef NEON_OPTS
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# pragma message "Manual NEON optimizations are ON: we have a faster fir_decimate_cc now."
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//max help: http://community.arm.com/groups/android-community/blog/2015/03/27/arm-neon-programming-quick-reference
int fir_decimate_cc ( complexf * input , complexf * output , int input_size , int decimation , float * taps , int taps_length )
{
//Theory: http://www.dspguru.com/dsp/faqs/multirate/decimation
//It uses real taps. It returns the number of output samples actually written.
//It needs overlapping input based on its returned value:
//number of processed input samples = returned value * decimation factor
//The output buffer should be at least input_length / 3.
// i: input index | ti: tap index | oi: output index
int oi = 0 ;
for ( int i = 0 ; i < input_size ; i + = decimation ) //@fir_decimate_cc: outer loop
{
if ( i + taps_length > input_size ) break ;
register float acci = 0 ;
register float accq = 0 ;
register int ti = 0 ;
register float * pinput = ( float * ) & ( input [ i + ti ] ) ;
register float * ptaps = taps ;
register float * ptaps_end = taps + taps_length ;
float quad_acciq [ 8 ] ;
/*
q0 , q1 : input signal I sample and Q sample
q2 : taps
q4 , q5 : accumulator for I branch and Q branch ( will be the output )
*/
asm volatile (
" vmov.f32 q4, #0.0 \n \t " //another way to null the accumulators
" vmov.f32 q5, #0.0 \n \t "
" for_fdccasm: vld2.32 {q0-q1}, [%[pinput]]! \n \t " //load q0 and q1 directly from the memory address stored in pinput, with interleaving (so that we get the I samples in q0 and the Q samples in q1), also increment the memory address in pinput (hence the "!" mark) //http://community.arm.com/groups/processors/blog/2010/03/17/coding-for-neon--part-1-load-and-stores
" vld1.32 {q2}, [%[ptaps]]! \n \t "
" vmla.f32 q4, q0, q2 \n \t " //quad_acc_i += quad_input_i * quad_taps_1 //http://stackoverflow.com/questions/3240440/how-to-use-the-multiply-and-accumulate-intrinsics-in-arm-cortex-a8 //http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.dui0489e/CIHEJBIE.html
" vmla.f32 q5, q1, q2 \n \t " //quad_acc_q += quad_input_q * quad_taps_1
" cmp %[ptaps], %[ptaps_end] \n \t " //if(ptaps == ptaps_end)
" bcc for_fdccasm \n \t " // then goto for_fdcasm
" vst1.32 {q4}, [%[quad_acci]] \n \t " //if the loop is finished, store the two accumulators in memory
" vst1.32 {q5}, [%[quad_accq]] \n \t "
:
[ pinput ] " +r " ( pinput ) , [ ptaps ] " +r " ( ptaps ) //output operand list
:
[ ptaps_end ] " r " ( ptaps_end ) , [ quad_acci ] " r " ( quad_acciq ) , [ quad_accq ] " r " ( quad_acciq + 4 ) //input operand list
:
" memory " , " q0 " , " q1 " , " q2 " , " q4 " , " q5 " , " cc " //clobber list
) ;
//original for loops for reference:
//for(int ti=0; ti<taps_length; ti++) acci += (iof(input,i+ti)) * taps[ti]; //@fir_decimate_cc: i loop
//for(int ti=0; ti<taps_length; ti++) accq += (qof(input,i+ti)) * taps[ti]; //@fir_decimate_cc: q loop
//for(int n=0;n<8;n++) fprintf(stderr, "\n>> [%d] %g \n", n, quad_acciq[n]);
iof ( output , oi ) = quad_acciq [ 0 ] + quad_acciq [ 1 ] + quad_acciq [ 2 ] + quad_acciq [ 3 ] ; //we're still not ready, as we have to add up the contents of a quad accumulator register to get a single accumulated value
qof ( output , oi ) = quad_acciq [ 4 ] + quad_acciq [ 5 ] + quad_acciq [ 6 ] + quad_acciq [ 7 ] ;
oi + + ;
}
return oi ;
}
# else
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int fir_decimate_cc ( complexf * input , complexf * output , int input_size , int decimation , float * taps , int taps_length )
{
//Theory: http://www.dspguru.com/dsp/faqs/multirate/decimation
//It uses real taps. It returns the number of output samples actually written.
//It needs overlapping input based on its returned value:
//number of processed input samples = returned value * decimation factor
//The output buffer should be at least input_length / 3.
// i: input index | ti: tap index | oi: output index
int oi = 0 ;
for ( int i = 0 ; i < input_size ; i + = decimation ) //@fir_decimate_cc: outer loop
{
if ( i + taps_length > input_size ) break ;
float acci = 0 ;
for ( int ti = 0 ; ti < taps_length ; ti + + ) acci + = ( iof ( input , i + ti ) ) * taps [ ti ] ; //@fir_decimate_cc: i loop
float accq = 0 ;
for ( int ti = 0 ; ti < taps_length ; ti + + ) accq + = ( qof ( input , i + ti ) ) * taps [ ti ] ; //@fir_decimate_cc: q loop
iof ( output , oi ) = acci ;
qof ( output , oi ) = accq ;
oi + + ;
}
return oi ;
}
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# endif
/*
int fir_decimate_cc ( complexf * input , complexf * output , int input_size , int decimation , float * taps , int taps_length )
{
//Theory: http://www.dspguru.com/dsp/faqs/multirate/decimation
//It uses real taps. It returns the number of output samples actually written.
//It needs overlapping input based on its returned value:
//number of processed input samples = returned value * decimation factor
//The output buffer should be at least input_length / 3.
// i: input index | ti: tap index | oi: output index
int oi = 0 ;
for ( int i = 0 ; i < input_size ; i + = decimation ) //@fir_decimate_cc: outer loop
{
if ( i + taps_length > input_size ) break ;
float acci = 0 ;
int taps_halflength = taps_length / 2 ;
for ( int ti = 0 ; ti < taps_halflength ; ti + + ) acci + = ( iof ( input , i + ti ) + iof ( input , i + taps_length - ti ) ) * taps [ ti ] ; //@fir_decimate_cc: i loop
float accq = 0 ;
for ( int ti = 0 ; ti < taps_halflength ; ti + + ) accq + = ( qof ( input , i + ti ) + qof ( input , i + taps_length - ti ) ) * taps [ ti ] ; //@fir_decimate_cc: q loop
iof ( output , oi ) = acci + iof ( input , i + taps_halflength ) * taps [ taps_halflength ] ;
qof ( output , oi ) = accq + qof ( input , i + taps_halflength ) * taps [ taps_halflength ] ;
oi + + ;
}
return oi ;
}
*/
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rational_resampler_ff_t rational_resampler_ff ( float * input , float * output , int input_size , int interpolation , int decimation , float * taps , int taps_length , int last_taps_delay )
{
//Theory: http://www.dspguru.com/dsp/faqs/multirate/resampling
//oi: output index, i: tap index
int output_size = input_size * interpolation / decimation ;
int oi ;
int startingi , delayi ;
//fprintf(stderr,"rational_resampler_ff | interpolation = %d | decimation = %d\ntaps_length = %d | input_size = %d | output_size = %d | last_taps_delay = %d\n",interpolation,decimation,taps_length,input_size,output_size,last_taps_delay);
for ( oi = 0 ; oi < output_size ; oi + + ) //@rational_resampler_ff (outer loop)
{
float acc = 0 ;
startingi = ( oi * decimation + interpolation - 1 - last_taps_delay ) / interpolation ; //index of first input item to apply FIR on
//delayi=startingi*interpolation-oi*decimation; //delay on FIR taps
delayi = ( last_taps_delay + startingi * interpolation - oi * decimation ) % interpolation ; //delay on FIR taps
if ( startingi + taps_length / interpolation + 1 > input_size ) break ; //we can't compute the FIR filter to some input samples at the end
//fprintf(stderr,"outer loop | oi = %d | startingi = %d | taps delay = %d\n",oi,startingi,delayi);
for ( int i = 0 ; i < ( taps_length - delayi ) / interpolation ; i + + ) //@rational_resampler_ff (inner loop)
{
//fprintf(stderr,"inner loop | input index = %d | tap index = %d | acc = %g\n",startingi+ii,i,acc);
acc + = input [ startingi + i ] * taps [ delayi + i * interpolation ] ;
}
output [ oi ] = acc * interpolation ;
}
rational_resampler_ff_t d ;
d . input_processed = startingi ;
d . output_size = oi ;
d . last_taps_delay = delayi ;
return d ;
}
/*
The greatest challenge in resampling is figuring out which tap should be applied to which sample .
Typical test patterns for rational_resampler_ff :
interpolation = 3 , decimation = 1
values of [ oi , startingi , taps delay ] in the outer loop should be :
0 0 0
1 1 2
2 1 1
3 1 0
4 2 2
5 2 1
interpolation = 3 , decimation = 2
values of [ oi , startingi , taps delay ] in the outer loop should be :
0 0 0
1 1 1
2 2 2
3 2 0
4 3 1
5 4 2
*/
void rational_resampler_get_lowpass_f ( float * output , int output_size , int interpolation , int decimation , window_t window )
{
//See 4.1.6 at: http://www.dspguru.com/dsp/faqs/multirate/resampling
float cutoff_for_interpolation = 1.0 / interpolation ;
float cutoff_for_decimation = 1.0 / decimation ;
float cutoff = ( cutoff_for_interpolation < cutoff_for_decimation ) ? cutoff_for_interpolation : cutoff_for_decimation ; //get the lower
firdes_lowpass_f ( output , output_size , cutoff / 2 , window ) ;
}
float inline fir_one_pass_ff ( float * input , float * taps , int taps_length )
{
float acc = 0 ;
for ( int i = 0 ; i < taps_length ; i + + ) acc + = taps [ i ] * input [ i ] ; //@fir_one_pass_ff
return acc ;
}
fractional_decimator_ff_t fractional_decimator_ff ( float * input , float * output , int input_size , float rate , float * taps , int taps_length , fractional_decimator_ff_t d )
{
if ( rate < = 1.0 ) return d ; //sanity check, can't decimate <=1.0
//This routine can handle floating point decimation rates.
//It linearly interpolates between two samples that are taken into consideration from the filtered input.
int oi = 0 ;
int index_high ;
float where = d . remain ;
float result_high , result_low ;
if ( where = = 0.0 ) //in the first iteration index_high may be zero (so using the item index_high-1 would lead to invalid memory access).
{
output [ oi + + ] = fir_one_pass_ff ( input , taps , taps_length ) ;
where + = rate ;
}
int previous_index_high = - 1 ;
//we optimize to calculate ceilf(where) only once every iteration, so we do it here:
for ( ; ( index_high = ceilf ( where ) ) + taps_length < input_size ; where + = rate ) //@fractional_decimator_ff
{
if ( previous_index_high = = index_high - 1 ) result_low = result_high ; //if we step less than 2.0 then we do already have the result for the FIR filter for that index
else result_low = fir_one_pass_ff ( input + index_high - 1 , taps , taps_length ) ;
result_high = fir_one_pass_ff ( input + index_high , taps , taps_length ) ;
float register rate_between_samples = where - index_high + 1 ;
output [ oi + + ] = result_low * ( 1 - rate_between_samples ) + result_high * rate_between_samples ;
previous_index_high = index_high ;
}
d . input_processed = index_high - 1 ;
d . remain = where - d . input_processed ;
d . output_size = oi ;
return d ;
}
void apply_fir_fft_cc ( FFT_PLAN_T * plan , FFT_PLAN_T * plan_inverse , complexf * taps_fft , complexf * last_overlap , int overlap_size )
{
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//use the overlap & add method for filtering
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//calculate FFT on input buffer
fft_execute ( plan ) ;
//multiply the filter and the input
complexf * in = plan - > output ;
complexf * out = plan_inverse - > input ;
for ( int i = 0 ; i < plan - > size ; i + + ) //@apply_fir_fft_cc: multiplication
{
iof ( out , i ) = iof ( in , i ) * iof ( taps_fft , i ) - qof ( in , i ) * qof ( taps_fft , i ) ;
qof ( out , i ) = iof ( in , i ) * qof ( taps_fft , i ) + qof ( in , i ) * iof ( taps_fft , i ) ;
}
//calculate inverse FFT on multiplied buffer
fft_execute ( plan_inverse ) ;
//add the overlap of the previous segment
complexf * result = plan_inverse - > output ;
for ( int i = 0 ; i < plan - > size ; i + + ) //@apply_fir_fft_cc: normalize by fft_size
{
iof ( result , i ) / = plan - > size ;
qof ( result , i ) / = plan - > size ;
}
for ( int i = 0 ; i < overlap_size ; i + + ) //@apply_fir_fft_cc: add overlap
{
iof ( result , i ) = iof ( result , i ) + iof ( last_overlap , i ) ;
qof ( result , i ) = qof ( result , i ) + qof ( last_overlap , i ) ;
}
}
/*
__ __ _ _ _ _
/ \ | \ / | | | | | | | | |
/ \ | \ / | __ | | ___ _ __ ___ ___ __ | | _ _ | | __ _ | | _ ___ _ __ ___
/ / \ \ | | \ / | | / _ ` | / _ \ ' _ ` _ \ / _ \ / _ ` | | | | | / _ ` | __ / _ \ | ' __ / __ |
/ ____ \ | | | | | ( _ | | __ / | | | | | ( _ ) | ( _ | | | _ | | | ( _ | | | | ( _ ) | | \ __ \
/ _ / \ _ \ _ | | _ | \ __ , _ | \ ___ | _ | | _ | | _ | \ ___ / \ __ , _ | \ __ , _ | _ | \ __ , _ | \ __ \ ___ / | _ | | ___ /
*/
void amdemod_cf ( complexf * input , float * output , int input_size )
{
//@amdemod: i*i+q*q
for ( int i = 0 ; i < input_size ; i + + )
{
output [ i ] = iof ( input , i ) * iof ( input , i ) + qof ( input , i ) * qof ( input , i ) ;
}
//@amdemod: sqrt
for ( int i = 0 ; i < input_size ; i + + )
{
output [ i ] = sqrt ( output [ i ] ) ;
}
}
void amdemod_estimator_cf ( complexf * input , float * output , int input_size , float alpha , float beta )
{
//concept is explained here:
//http://www.dspguru.com/dsp/tricks/magnitude-estimator
//default: optimize for min RMS error
if ( alpha = = 0 )
{
alpha = 0.947543636291 ;
beta = 0.392485425092 ;
}
//@amdemod_estimator
for ( int i = 0 ; i < input_size ; i + + )
{
float abs_i = iof ( input , i ) ;
if ( abs_i < 0 ) abs_i = - abs_i ;
float abs_q = qof ( input , i ) ;
if ( abs_q < 0 ) abs_q = - abs_q ;
float max_iq = abs_i ;
if ( abs_q > max_iq ) max_iq = abs_q ;
float min_iq = abs_i ;
if ( abs_q < min_iq ) min_iq = abs_q ;
output [ i ] = alpha * max_iq + beta * min_iq ;
}
}
dcblock_preserve_t dcblock_ff ( float * input , float * output , int input_size , float a , dcblock_preserve_t preserved )
{
//after AM demodulation, a DC blocking filter should be used to remove the DC component from the signal.
//Concept: http://peabody.sapp.org/class/dmp2/lab/dcblock/
//output size equals to input_size;
//preserve can be initialized to zero on first run.
if ( a = = 0 ) a = 0.999 ; //default value, simulate in octave: freqz([1 -1],[1 -0.99])
output [ 0 ] = input [ 0 ] - preserved . last_input + a * preserved . last_output ;
for ( int i = 1 ; i < input_size ; i + + ) //@dcblock_f
{
output [ i ] = input [ i ] - input [ i - 1 ] + a * output [ i - 1 ] ;
}
preserved . last_input = input [ input_size - 1 ] ;
preserved . last_output = output [ input_size - 1 ] ;
return preserved ;
}
float fastdcblock_ff ( float * input , float * output , int input_size , float last_dc_level )
{
//this DC block filter does moving average block-by-block.
//this is the most computationally efficient
//input and output buffer is allowed to be the same
//http://www.digitalsignallabs.com/dcblock.pdf
float avg = 0.0 ;
for ( int i = 0 ; i < input_size ; i + + ) //@fastdcblock_ff: calculate block average
{
avg + = input [ i ] ;
}
avg / = input_size ;
float avgdiff = avg - last_dc_level ;
//DC removal level will change lineraly from last_dc_level to avg.
for ( int i = 0 ; i < input_size ; i + + ) //@fastdcblock_ff: remove DC component
{
float dc_removal_level = last_dc_level + avgdiff * ( ( float ) i / input_size ) ;
output [ i ] = input [ i ] - dc_removal_level ;
}
return avg ;
}
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//#define FASTAGC_MAX_GAIN (65e3)
# define FASTAGC_MAX_GAIN 50
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void fastagc_ff ( fastagc_ff_t * input , float * output )
{
//Gain is processed on blocks of samples.
//You have to supply three blocks of samples before the first block comes out.
//AGC reaction speed equals input_size*samp_rate*2
//The algorithm calculates target gain at the end of the first block out of the peak value of all the three blocks.
//This way the gain change can easily react if there is any peak in the third block.
//Pros: can be easily speeded up with loop vectorization, easy to implement
//Cons: needs 3 buffers, dos not behave similarly to real AGC circuits
//Get the peak value of new input buffer
float peak_input = 0 ;
for ( int i = 0 ; i < input - > input_size ; i + + ) //@fastagc_ff: peak search
{
float val = fabs ( input - > buffer_input [ i ] ) ;
if ( val > peak_input ) peak_input = val ;
}
//Determine the maximal peak out of the three blocks
float target_peak = peak_input ;
if ( target_peak < input - > peak_2 ) target_peak = input - > peak_2 ;
if ( target_peak < input - > peak_1 ) target_peak = input - > peak_1 ;
//we change the gain linearly on the apply_block from the last_gain to target_gain.
float target_gain = input - > reference / target_peak ;
if ( target_gain > FASTAGC_MAX_GAIN ) target_gain = FASTAGC_MAX_GAIN ;
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//fprintf(stderr, "target_gain: %g\n",target_gain);
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for ( int i = 0 ; i < input - > input_size ; i + + ) //@fastagc_ff: apply gain
{
float rate = ( float ) i / input - > input_size ;
float gain = input - > last_gain * ( 1.0 - rate ) + target_gain * rate ;
output [ i ] = input - > buffer_1 [ i ] * gain ;
}
//Shift the three buffers
float * temp_pointer = input - > buffer_1 ;
input - > buffer_1 = input - > buffer_2 ;
input - > peak_1 = input - > peak_2 ;
input - > buffer_2 = input - > buffer_input ;
input - > peak_2 = peak_input ;
input - > buffer_input = temp_pointer ;
input - > last_gain = target_gain ;
//fprintf(stderr,"target_gain=%g\n", target_gain);
}
/*
______ __ __ _ _ _ _
| ____ | \ / | | | | | | | | |
| | __ | \ / | __ | | ___ _ __ ___ ___ __ | | _ _ | | __ _ | | _ ___ _ __ ___
| __ | | | \ / | | / _ ` | / _ \ ' _ ` _ \ / _ \ / _ ` | | | | | / _ ` | __ / _ \ | ' __ / __ |
| | | | | | | ( _ | | __ / | | | | | ( _ ) | ( _ | | | _ | | | ( _ | | | | ( _ ) | | \ __ \
| _ | | _ | | _ | \ __ , _ | \ ___ | _ | | _ | | _ | \ ___ / \ __ , _ | \ __ , _ | _ | \ __ , _ | \ __ \ ___ / | _ | | ___ /
*/
float fmdemod_atan_cf ( complexf * input , float * output , int input_size , float last_phase )
{
//GCC most likely won't vectorize nor atan, nor atan2.
//For more comments, look at: https://github.com/simonyiszk/minidemod/blob/master/minidemod-wfm-atan.c
float phase , dphase ;
for ( int i = 0 ; i < input_size ; i + + ) //@fmdemod_atan_novect
{
phase = argof ( input , i ) ;
dphase = phase - last_phase ;
if ( dphase < - PI ) dphase + = 2 * PI ;
if ( dphase > PI ) dphase - = 2 * PI ;
output [ i ] = dphase / PI ;
last_phase = phase ;
}
return last_phase ;
}
# define fmdemod_quadri_K 0.340447550238101026565118445432744920253753662109375
//this constant ensures proper scaling for qa_fmemod testcases for SNR calculation and more.
complexf fmdemod_quadri_novect_cf ( complexf * input , float * output , int input_size , complexf last_sample )
{
output [ 0 ] = fmdemod_quadri_K * ( iof ( input , 0 ) * ( qof ( input , 0 ) - last_sample . q ) - qof ( input , 0 ) * ( iof ( input , 0 ) - last_sample . i ) ) / ( iof ( input , 0 ) * iof ( input , 0 ) + qof ( input , 0 ) * qof ( input , 0 ) ) ;
for ( int i = 1 ; i < input_size ; i + + ) //@fmdemod_quadri_novect_cf
{
float qnow = qof ( input , i ) ;
float qlast = qof ( input , i - 1 ) ;
float inow = iof ( input , i ) ;
float ilast = iof ( input , i - 1 ) ;
output [ i ] = fmdemod_quadri_K * ( inow * ( qnow - qlast ) - qnow * ( inow - ilast ) ) / ( inow * inow + qnow * qnow ) ;
//TODO: expression can be simplified as: (qnow*ilast-inow*qlast)/(inow*inow+qnow*qnow)
}
return input [ input_size - 1 ] ;
}
complexf fmdemod_quadri_cf ( complexf * input , float * output , int input_size , float * temp , complexf last_sample )
{
float * temp_dq = temp ;
float * temp_di = temp + input_size ;
temp_dq [ 0 ] = qof ( input , 0 ) - last_sample . q ;
for ( int i = 1 ; i < input_size ; i + + ) //@fmdemod_quadri_cf: dq
{
temp_dq [ i ] = qof ( input , i ) - qof ( input , i - 1 ) ;
}
temp_di [ 0 ] = iof ( input , 0 ) - last_sample . i ;
for ( int i = 1 ; i < input_size ; i + + ) //@fmdemod_quadri_cf: di
{
temp_di [ i ] = iof ( input , i ) - iof ( input , i - 1 ) ;
}
for ( int i = 0 ; i < input_size ; i + + ) //@fmdemod_quadri_cf: output numerator
{
output [ i ] = ( iof ( input , i ) * temp_dq [ i ] - qof ( input , i ) * temp_di [ i ] ) ;
}
for ( int i = 0 ; i < input_size ; i + + ) //@fmdemod_quadri_cf: output denomiator
{
temp [ i ] = iof ( input , i ) * iof ( input , i ) + qof ( input , i ) * qof ( input , i ) ;
}
for ( int i = 0 ; i < input_size ; i + + ) //@fmdemod_quadri_cf: output division
{
output [ i ] = fmdemod_quadri_K * output [ i ] / temp [ i ] ;
}
return input [ input_size - 1 ] ;
}
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inline int is_nan ( float f )
{
//http://stackoverflow.com/questions/570669/checking-if-a-double-or-float-is-nan-in-c
unsigned u = * ( unsigned * ) & f ;
return ( u & 0x7F800000 ) = = 0x7F800000 & & ( u & 0x7FFFFF ) ; // Both NaN and qNan.
}
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float deemphasis_wfm_ff ( float * input , float * output , int input_size , float tau , int sample_rate , float last_output )
{
/*
typical time constant ( tau ) values :
WFM transmission in USA : 75 us - > tau = 75e-6
WFM transmission in EU : 50 us - > tau = 50e-6
More info at : http : //www.cliftonlaboratories.com/fm_receivers_and_de-emphasis.htm
Simulate in octave : tau = 75e-6 ; dt = 1 / 48000 ; alpha = dt / ( tau + dt ) ; freqz ( [ alpha ] , [ 1 - ( 1 - alpha ) ] )
*/
float dt = 1.0 / sample_rate ;
float alpha = dt / ( tau + dt ) ;
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if ( is_nan ( last_output ) ) last_output = 0.0 ; //if last_output is NaN
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output [ 0 ] = alpha * input [ 0 ] + ( 1 - alpha ) * last_output ;
for ( int i = 1 ; i < input_size ; i + + ) //@deemphasis_wfm_ff
output [ i ] = alpha * input [ i ] + ( 1 - alpha ) * output [ i - 1 ] ; //this is the simplest IIR LPF
return output [ input_size - 1 ] ;
}
# define DNFMFF_ADD_ARRAY(x) if(sample_rate==x) { taps=deemphasis_nfm_predefined_fir_##x; taps_length=sizeof(deemphasis_nfm_predefined_fir_##x) / sizeof(float); }
int deemphasis_nfm_ff ( float * input , float * output , int input_size , int sample_rate )
{
/*
Warning ! This only works on predefined samplerates , as it uses fixed FIR coefficients defined in predefined . h
However , there are the octave commands to generate the taps for your custom ( fixed ) sample rate .
What it does :
- reject below 400 Hz
- passband between 400 HZ - 4 kHz , but with 20 dB / decade rolloff ( for deemphasis )
- reject everything above 4 kHz
*/
float * taps ;
int taps_length = 0 ;
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DNFMFF_ADD_ARRAY ( 48000 )
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DNFMFF_ADD_ARRAY ( 44100 )
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DNFMFF_ADD_ARRAY ( 8000 )
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DNFMFF_ADD_ARRAY ( 11025 )
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if ( ! taps_length ) return 0 ; //sample rate n
int i ;
for ( i = 0 ; i < input_size - taps_length ; i + + ) //@deemphasis_nfm_ff: outer loop
{
float acc = 0 ;
for ( int ti = 0 ; ti < taps_length ; ti + + ) acc + = taps [ ti ] * input [ i + ti ] ; //@deemphasis_nfm_ff: inner loop
output [ i ] = acc ;
}
return i ; //number of samples processed (and output samples)
}
void limit_ff ( float * input , float * output , int input_size , float max_amplitude )
{
for ( int i = 0 ; i < input_size ; i + + ) //@limit_ff
{
output [ i ] = ( max_amplitude < input [ i ] ) ? max_amplitude : input [ i ] ;
output [ i ] = ( - max_amplitude > output [ i ] ) ? - max_amplitude : output [ i ] ;
}
}
void gain_ff ( float * input , float * output , int input_size , float gain )
{
for ( int i = 0 ; i < input_size ; i + + ) output [ i ] = gain * input [ i ] ; //@gain_ff
}
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/*
__ __ _ _ _
| \ / | | | | | | |
| \ / | ___ __ | | _ _ | | __ _ | | _ ___ _ __ ___
| | \ / | | / _ \ / _ ` | | | | | / _ ` | __ / _ \ | ' __ / __ |
| | | | ( _ ) | ( _ | | | _ | | | ( _ | | | | ( _ ) | | \ __ \
| _ | | _ | \ ___ / \ __ , _ | \ __ , _ | _ | \ __ , _ | \ __ \ ___ / | _ | | ___ /
*/
void add_dcoffset_cc ( complexf * input , complexf * output , int input_size )
{
for ( int i = 0 ; i < input_size ; i + + ) iof ( output , i ) = 0.5 + iof ( input , i ) / 2 ;
for ( int i = 0 ; i < input_size ; i + + ) qof ( output , i ) = qof ( input , i ) / 2 ;
}
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float fmmod_fc ( float * input , complexf * output , int input_size , float last_phase )
{
float phase = last_phase ;
for ( int i = 0 ; i < input_size ; i + + )
{
phase + = input [ i ] * PI ;
while ( phase > PI ) phase - = 2 * PI ;
while ( phase < = - PI ) phase + = 2 * PI ;
iof ( output , i ) = cos ( phase ) ;
qof ( output , i ) = sin ( phase ) ;
}
return phase ;
}
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void fixed_amplitude_cc ( complexf * input , complexf * output , int input_size , float new_amplitude )
{
for ( int i = 0 ; i < input_size ; i + + )
{
//float phase=atan2(iof(input,i),qof(input,i));
//iof(output,i)=cos(phase)*amp;
//qof(output,i)=sin(phase)*amp;
//A faster solution:
float amplitude_now = sqrt ( iof ( input , i ) * iof ( input , i ) + qof ( input , i ) * qof ( input , i ) ) ;
float gain = ( amplitude_now > 0 ) ? new_amplitude / amplitude_now : 0 ;
iof ( output , i ) = iof ( input , i ) * gain ;
qof ( output , i ) = qof ( input , i ) * gain ;
}
}
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/*
______ _ ______ _ _______ __
| ____ | | | | ____ | ( _ ) | __ __ | / _ |
| | __ __ _ ___ | | _ | | __ ___ _ _ _ __ _ ___ _ __ | | _ __ __ _ _ __ ___ | | _ ___ _ __ _ __ ___
| __ / _ ` / __ | __ | | __ / _ \ | | | | ' __ | | / _ \ ' __ | | | ' __ / _ ` | ' _ \ / __ | _ / _ \ | ' __ | ' _ ` _ \
| | | ( _ | \ __ \ | _ | | | ( _ ) | | _ | | | | | __ / | | | | | ( _ | | | | \ __ \ | | ( _ ) | | | | | | | |
| _ | \ __ , _ | ___ / \ __ | | _ | \ ___ / \ __ , _ | _ | | _ | \ ___ | _ | | _ | _ | \ __ , _ | _ | | _ | ___ / _ | \ ___ / | _ | | _ | | _ | | _ |
*/
int log2n ( int x )
{
int result = - 1 ;
for ( int i = 0 ; i < 31 ; i + + )
{
if ( ( x > > i ) & 1 ) //@@log2n
{
if ( result = = - 1 ) result = i ;
else return - 1 ;
}
}
return result ;
}
int next_pow2 ( int x )
{
int pow2 ;
//portability? (31 is the problem)
for ( int i = 0 ; i < 31 ; i + + )
{
if ( x < ( pow2 = 1 < < i ) ) return pow2 ; //@@next_pow2
}
return - 1 ;
}
void apply_window_c ( complexf * input , complexf * output , int size , window_t window )
{
float ( * window_function ) ( float ) = firdes_get_window_kernel ( window ) ;
for ( int i = 0 ; i < size ; i + + ) //@apply_window_c
{
float rate = ( float ) i / ( size - 1 ) ;
iof ( output , i ) = iof ( input , i ) * window_function ( 2.0 * rate + 1.0 ) ;
qof ( output , i ) = qof ( input , i ) * window_function ( 2.0 * rate + 1.0 ) ;
}
}
void apply_window_f ( float * input , float * output , int size , window_t window )
{
float ( * window_function ) ( float ) = firdes_get_window_kernel ( window ) ;
for ( int i = 0 ; i < size ; i + + ) //@apply_window_f
{
float rate = ( float ) i / ( size - 1 ) ;
output [ i ] = input [ i ] * window_function ( 2.0 * rate + 1.0 ) ;
}
}
void logpower_cf ( complexf * input , float * output , int size , float add_db )
{
for ( int i = 0 ; i < size ; i + + ) output [ i ] = iof ( input , i ) * iof ( input , i ) + qof ( input , i ) * qof ( input , i ) ; //@logpower_cf: pass 1
for ( int i = 0 ; i < size ; i + + ) output [ i ] = log10 ( output [ i ] ) ; //@logpower_cf: pass 2
for ( int i = 0 ; i < size ; i + + ) output [ i ] = 10 * output [ i ] + add_db ; //@logpower_cf: pass 3
}
/*
_____ _ _
| __ \ | | ( _ )
| | | | __ _ | | _ __ _ ___ ___ _ ____ _____ _ __ ___ _ ___ _ __
| | | | / _ ` | __ / _ ` | / __ / _ \ | ' _ \ \ / / _ \ ' __ / __ | | / _ \ | ' _ \
| | __ | | ( _ | | | | ( _ | | | ( _ | ( _ ) | | | \ V / __ / | \ __ \ | ( _ ) | | | |
| _____ / \ __ , _ | \ __ \ __ , _ | \ ___ \ ___ / | _ | | _ | \ _ / \ ___ | _ | | ___ / _ | \ ___ / | _ | | _ |
*/
void convert_u8_f ( unsigned char * input , float * output , int input_size )
{
for ( int i = 0 ; i < input_size ; i + + ) output [ i ] = ( ( float ) input [ i ] ) / ( UCHAR_MAX / 2.0 ) - 1.0 ; //@convert_u8_f
}
void convert_i16_f ( short * input , float * output , int input_size )
{
for ( int i = 0 ; i < input_size ; i + + ) output [ i ] = ( float ) input [ i ] / SHRT_MAX ; //@convert_i16_f
}
void convert_f_u8 ( float * input , unsigned char * output , int input_size )
{
for ( int i = 0 ; i < input_size ; i + + ) output [ i ] = input [ i ] * UCHAR_MAX * 0.5 + 128 ; //@convert_f_u8
//128 above is the correct value to add. In any other case a DC component
//of at least -60 dB is shown on the FFT plot after convert_f_u8 -> convert_u8_f
}
void convert_f_i16 ( float * input , short * output , int input_size )
{
/*for(int i=0;i<input_size;i++)
{
if ( input [ i ] > 1.0 ) input [ i ] = 1.0 ;
if ( input [ i ] < - 1.0 ) input [ i ] = - 1.0 ;
} */
for ( int i = 0 ; i < input_size ; i + + ) output [ i ] = input [ i ] * SHRT_MAX ; //@convert_f_i16
}
int trivial_vectorize ( )
{
//this function is trivial to vectorize and should pass on both NEON and SSE
int a [ 1024 ] , b [ 1024 ] , c [ 1024 ] ;
for ( int i = 0 ; i < 1024 ; i + + ) //@trivial_vectorize: should pass :-)
{
c [ i ] = a [ i ] * b [ i ] ;
}
return c [ 0 ] ;
}