173 lines
4.5 KiB
C
173 lines
4.5 KiB
C
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#include "kiss_fftr.h"
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#include "_kiss_fft_guts.h"
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#include <sys/times.h>
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#include <time.h>
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#include <unistd.h>
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static double cputime(void)
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{
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struct tms t;
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times(&t);
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return (double)(t.tms_utime + t.tms_stime)/ sysconf(_SC_CLK_TCK) ;
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}
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static
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kiss_fft_scalar rand_scalar(void)
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{
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#ifdef USE_SIMD
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return _mm_set1_ps(rand()-RAND_MAX/2);
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#else
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kiss_fft_scalar s = (kiss_fft_scalar)(rand() -RAND_MAX/2);
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return s/2;
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#endif
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}
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static
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double snr_compare( kiss_fft_cpx * vec1,kiss_fft_cpx * vec2, int n)
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{
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int k;
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double sigpow=1e-10,noisepow=1e-10,err,snr,scale=0;
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#ifdef USE_SIMD
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float *fv1 = (float*)vec1;
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float *fv2 = (float*)vec2;
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for (k=0;k<8*n;++k) {
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sigpow += *fv1 * *fv1;
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err = *fv1 - *fv2;
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noisepow += err*err;
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++fv1;
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++fv2;
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}
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#else
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for (k=0;k<n;++k) {
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sigpow += (double)vec1[k].r * (double)vec1[k].r +
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(double)vec1[k].i * (double)vec1[k].i;
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err = (double)vec1[k].r - (double)vec2[k].r;
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noisepow += err * err;
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err = (double)vec1[k].i - (double)vec2[k].i;
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noisepow += err * err;
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if (vec1[k].r)
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scale +=(double) vec2[k].r / (double)vec1[k].r;
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}
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#endif
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snr = 10*log10( sigpow / noisepow );
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scale /= n;
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if (snr<10) {
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printf( "\npoor snr, try a scaling factor %f\n" , scale );
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exit(1);
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}
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return snr;
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}
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#ifndef NUMFFTS
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#define NUMFFTS 10000
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#endif
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int main(int argc,char ** argv)
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{
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int nfft = 8*3*5;
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double ts,tfft,trfft;
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int i;
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if (argc>1)
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nfft = atoi(argv[1]);
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kiss_fft_cpx cin[nfft];
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kiss_fft_cpx cout[nfft];
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kiss_fft_cpx sout[nfft];
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kiss_fft_cfg kiss_fft_state;
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kiss_fftr_cfg kiss_fftr_state;
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kiss_fft_scalar rin[nfft+2];
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kiss_fft_scalar rout[nfft+2];
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kiss_fft_scalar zero;
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memset(&zero,0,sizeof(zero) ); // ugly way of setting short,int,float,double, or __m128 to zero
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srand(time(0));
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for (i=0;i<nfft;++i) {
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rin[i] = rand_scalar();
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cin[i].r = rin[i];
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cin[i].i = zero;
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}
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kiss_fft_state = kiss_fft_alloc(nfft,0,0,0);
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kiss_fftr_state = kiss_fftr_alloc(nfft,0,0,0);
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kiss_fft(kiss_fft_state,cin,cout);
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kiss_fftr(kiss_fftr_state,rin,sout);
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/*
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printf(" results from kiss_fft : (%f,%f), (%f,%f), (%f,%f) ...\n "
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, (float)cout[0].r , (float)cout[0].i
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, (float)cout[1].r , (float)cout[1].i
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, (float)cout[2].r , (float)cout[2].i);
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printf(" results from kiss_fftr: (%f,%f), (%f,%f), (%f,%f) ...\n "
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, (float)sout[0].r , (float)sout[0].i
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, (float)sout[1].r , (float)sout[1].i
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, (float)sout[2].r , (float)sout[2].i);
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*/
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printf( "nfft=%d, inverse=%d, snr=%g\n",
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nfft,0, snr_compare(cout,sout,(nfft/2)+1) );
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ts = cputime();
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for (i=0;i<NUMFFTS;++i) {
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kiss_fft(kiss_fft_state,cin,cout);
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}
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tfft = cputime() - ts;
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ts = cputime();
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for (i=0;i<NUMFFTS;++i) {
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kiss_fftr( kiss_fftr_state, rin, cout );
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/* kiss_fftri(kiss_fftr_state,cout,rin); */
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}
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trfft = cputime() - ts;
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printf("%d complex ffts took %gs, real took %gs\n",NUMFFTS,tfft,trfft);
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free(kiss_fft_state);
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free(kiss_fftr_state);
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kiss_fft_state = kiss_fft_alloc(nfft,1,0,0);
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kiss_fftr_state = kiss_fftr_alloc(nfft,1,0,0);
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memset(cin,0,sizeof(cin));
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#if 1
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for (i=1;i< nfft/2;++i) {
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//cin[i].r = (kiss_fft_scalar)(rand()-RAND_MAX/2);
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cin[i].r = rand_scalar();
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cin[i].i = rand_scalar();
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}
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#else
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cin[0].r = 12000;
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cin[3].r = 12000;
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cin[nfft/2].r = 12000;
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#endif
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// conjugate symmetry of real signal
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for (i=1;i< nfft/2;++i) {
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cin[nfft-i].r = cin[i].r;
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cin[nfft-i].i = - cin[i].i;
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}
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kiss_fft(kiss_fft_state,cin,cout);
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kiss_fftri(kiss_fftr_state,cin,rout);
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/*
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printf(" results from inverse kiss_fft : (%f,%f), (%f,%f), (%f,%f), (%f,%f), (%f,%f) ...\n "
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, (float)cout[0].r , (float)cout[0].i , (float)cout[1].r , (float)cout[1].i , (float)cout[2].r , (float)cout[2].i , (float)cout[3].r , (float)cout[3].i , (float)cout[4].r , (float)cout[4].i
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);
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printf(" results from inverse kiss_fftr: %f,%f,%f,%f,%f ... \n"
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,(float)rout[0] ,(float)rout[1] ,(float)rout[2] ,(float)rout[3] ,(float)rout[4]);
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*/
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for (i=0;i<nfft;++i) {
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sout[i].r = rout[i];
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sout[i].i = zero;
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}
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printf( "nfft=%d, inverse=%d, snr=%g\n",
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nfft,1, snr_compare(cout,sout,nfft/2) );
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free(kiss_fft_state);
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free(kiss_fftr_state);
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return 0;
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}
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