diff options
author | Jamie Bullock <postlude@users.sourceforge.net> | 2006-05-30 13:42:23 +0000 |
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committer | Jamie Bullock <postlude@users.sourceforge.net> | 2006-05-30 13:42:23 +0000 |
commit | 4de225a88232e3dafdc8d907b58bc5d06cdb7c38 (patch) | |
tree | 0e039e1b847b52a08c6fa48e6d977bf4e321225f | |
parent | c56a043c7b42ee7dec7b54790eb16057f97959b2 (diff) |
New checkin after sf upgrade
svn path=/trunk/externals/postlude/; revision=5152
-rw-r--r-- | flib/src/cc~.c | 199 | ||||
-rw-r--r-- | flib/src/flib.h | 2 | ||||
-rw-r--r-- | flib/src/irreg~.c | 2 | ||||
-rw-r--r-- | flib/src/sfm~.c | 2 | ||||
-rw-r--r-- | flib/src/ss~.c | 6 |
5 files changed, 147 insertions, 64 deletions
diff --git a/flib/src/cc~.c b/flib/src/cc~.c index 2d06d9b..da2d50b 100644 --- a/flib/src/cc~.c +++ b/flib/src/cc~.c @@ -17,29 +17,36 @@ */ -/*Calculate the cross correlation of two signal vectors*/ +/*Calculate the cc correlation of two signal vectors*/ /*The time domain implementation is based on code by Phil Bourke * the frequency domain version is based on code by Charles Henry * - * Specify a time delay as an argument for the time domain implemenation, for example an argument of 32 will give the correlation coefficients for delays from -32 to 32 samples between the two input vectors + * Specify a time delay as an argument for the time domain implemenation, for example an argument of 32 will give the + * correlation coefficients for delays from -32 to 32 samples between the two input vectors * - * Specify an argument of 'f' for the frequency domain implementation*/ + * Specify an argument of 'f' for the frequency domain implementation, + * or 'r' for the running cross covariance (not normalized) instead of the numerical delay argument + * these two methods both have got positive delays on 0,N/2-1 and the negative delays (-N/2, -1) are indexed on N/2,N-1 */ #include "flib.h" #define SQ(a) (a * a) -static t_class *cross_class; +static t_class *cc_class; -typedef struct _cross { +typedef struct _cc { t_object x_obj; t_float f; t_int delay; t_int is_freq_domain; -} t_cross; + t_float *buffer2Nsig1, *buffer2Nsig2; + t_float *output_prev_block; + t_int is_new; + t_int n; +} t_cc; -static t_int *cross_perform_time_domain(t_int *w) +static t_int *cc_perform_time_domain(t_int *w) { t_sample *x = (t_sample *)(w[1]); t_sample *y = (t_sample *)(w[2]); @@ -51,7 +58,7 @@ static t_int *cross_perform_time_domain(t_int *w) if(maxdelay > N * .5){ maxdelay = N * .5; - post("cross~: invalid maxdelay, must be <= blocksize/2"); + post("cc~: invalid maxdelay, must be <= blocksize/2"); } /* Calculate the mean of the two series x[], y[] */ @@ -97,103 +104,179 @@ static t_int *cross_perform_time_domain(t_int *w) } -t_int *cross_perform_freq_domain(t_int *w) +static t_int *cc_perform_freq_domain(t_int *w) { - t_cross *x = (t_cross *)(w[1]); + t_cc *x = (t_cc *)(w[1]); t_sample *sig1 = (t_sample *)(w[2]); t_sample *sig2 = (t_sample *)(w[3]); t_sample *out = (t_sample *)(w[4]); - long int size = (long int) w[5]; - long int k = size/2; - float *expsig1 = NULL; - float *revsig2 = NULL; - float temp, temp2; - long int i=0; - int well_defined=1; - int qtr, thrqtr; - -// The two signals are created, nonzero on 0 to N/4 and 3N/4 to N -// This will be revised - - expsig1=(float *) alloca(size*sizeof(float)); - revsig2=(float *) alloca(size*sizeof(float)); - qtr = size/4; - thrqtr = 3*size/4; - for (i=0; i < qtr ; i++) + t_int size = (int) w[5]; + x->n = size; + t_int size2 = size*2; + t_int half = size/2; + t_float *expsig1 = NULL; + t_float *revsig2 = NULL; + t_float temp, temp2; + t_int i=0; + t_int thrhalf; + +// This stuff here sets up two buffers to hold the previous N samples +// To get the usual overlapping block (2) design on each input + + if (x->is_new) { - expsig1[i]=sig1[i]; + x->buffer2Nsig1=getbytes(size*sizeof(t_float)); + x->buffer2Nsig2=getbytes(size*sizeof(t_float)); + x->output_prev_block=getbytes(size*sizeof(t_float)); + x->is_new=0; + } +// Here we set the buffers for the next round + for(i=half; i < size; i++) + { + x->buffer2Nsig1[i]=sig1[i]; + x->buffer2Nsig2[i]=sig2[i]; + } +// The two signals are created, nonzero on 0 to 1/4 and 3/4 to 1 +// Using a block size of 2N, --size2 + + expsig1=(float *) getbytes(size2*sizeof(float)); + revsig2=(float *) getbytes(size2*sizeof(float)); + +// Loops for assignment of old values in buffer + new block + thrhalf = 3*half; + for (i=0; i < half ; i++) + { + expsig1[i]=x->buffer2Nsig1[i]; revsig2[i]=0; } - for (i=qtr; i < thrqtr ; i++) + for (i=half; i < size ; i++) + { + expsig1[i]=x->buffer2Nsig1[i]; + revsig2[i]=sig2[size-i]; /// Needs revision here, not too clear + } + expsig1[size]=sig1[0]; + revsig2[size]=sig2[0]; + for (i=size+1; i < thrhalf ; i++) { - expsig1[i]=sig1[i]; - revsig2[i]=sig2[size-i]; + expsig1[i]=sig1[i-size]; + revsig2[i]=x->buffer2Nsig2[size2-i]; } - for (i=thrqtr; i < size ; i++) + for (i=thrhalf; i < size2 ; i++) { - expsig1[i]=sig1[i]; + expsig1[i]=sig1[i-size]; revsig2[i]=0; } - mayer_realfft(size, expsig1); - mayer_realfft(size, revsig2); +// fft the two blocks and multiply them + mayer_realfft(size2, expsig1); + mayer_realfft(size2, revsig2); + expsig1[0]*=revsig2[0]; - expsig1[k]*=revsig2[k]; - for(i=1; i < k; i++) + expsig1[size]*=revsig2[size]; + for(i=1; i < size2; i++) { temp=expsig1[i]; - temp2=expsig1[size-i]; - expsig1[i]=temp*revsig2[i]-temp2*revsig2[size-i]; - expsig1[size-i]=temp*revsig2[size-i]+temp2*revsig2[i]; + temp2=expsig1[size2-i]; + expsig1[i]=temp*revsig2[i]-temp2*revsig2[size2-i]; + expsig1[size2-i]=temp*revsig2[size2-i]+temp2*revsig2[i]; } - mayer_realifft(size, expsig1); - for(i=0; i < size; i++) +// ifft + mayer_realifft(size2, expsig1); + +// format the output: this section formats the ouptut either as +// a simple cc or as a running cc +if (x->is_freq_domain == 1) +{ + for(i=0; i < half; i++) + { + out[i]=expsig1[i]/size2; + out[half + i]=expsig1[half + i]/size2; + } +} else { + for(i=0; i < half; i++) { - out[i]=expsig1[i]; + out[i]=x->output_prev_block[i] + expsig1[i]/size2; + out[half + i]=x->output_prev_block[half + i] + expsig1[half + i]/size2; + x->output_prev_block[i] = out[i]; + x->output_prev_block[half + i] = out[half + i]; } +} +freebytes(expsig1, size2*sizeof(float)); +freebytes(revsig2, size2*sizeof(float)); return(w+6); } -static void cross_dsp(t_cross *x, t_signal **sp) +static void cc_dsp(t_cc *x, t_signal **sp) { if(!x->is_freq_domain) - dsp_add(cross_perform_time_domain, 5, + dsp_add(cc_perform_time_domain, 5, sp[0]->s_vec, sp[1]->s_vec, sp[2]->s_vec, sp[0]->s_n, x->delay); else - dsp_add(cross_perform_freq_domain, 5, x, + dsp_add(cc_perform_freq_domain, 5, x, sp[0]->s_vec, sp[1]->s_vec, sp[2]->s_vec, sp[0]->s_n); } -static void *cross_new(t_symbol *s, t_int argc, t_atom *argv) + +// For using with running calculation, send a bang to clear the buffer +// and start over with calculations + +static void cc_bang(t_cc *x) { - t_cross *x = (t_cross *)pd_new(cross_class); + int i; + for(i=0;i<x->n;i++) + x->output_prev_block[i]=0; +} + +static void *cc_new(t_symbol *s, t_int argc, t_atom *argv) +{ + t_cc *x = (t_cc *)pd_new(cc_class); if(atom_getsymbol(argv) == gensym("f")){ x->is_freq_domain = 1; - post("flib: cross: Frequency domain selected"); + post("flib: cc: Frequency domain selected"); + } + else if(atom_getsymbol(argv) == gensym("r")){ + x->is_freq_domain = 2; + post("flib: cc: Running frequency domain selected"); } else { x->delay = atom_getfloat(argv); - post("flib: cross: Time domain selected"); + post("flib: cc: Time domain selected"); } inlet_new(&x->x_obj, &x->x_obj.ob_pd, &s_signal, &s_signal); outlet_new(&x->x_obj, &s_signal); + x->is_new=1; + x->buffer2Nsig1=NULL; + x->buffer2Nsig2=NULL; + x->output_prev_block=NULL; return (void *)x; } +static void cc_free(t_cc *x) +{ + if (x->buffer2Nsig1 != NULL) + freebytes(x->buffer2Nsig1, x->n*sizeof(float)); + if (x->buffer2Nsig2 != NULL) + freebytes(x->buffer2Nsig2, x->n*sizeof(float)); + if (x->output_prev_block != NULL) + freebytes(x->output_prev_block, x->n*sizeof(float)); +} -void cross_tilde_setup(void) { - cross_class = class_new(gensym("cross~"), - (t_newmethod)cross_new, - 0, sizeof(t_cross), + +void cc_tilde_setup(void) { + cc_class = class_new(gensym("cc~"), + (t_newmethod)cc_new, + (t_method)cc_free, sizeof(t_cc), CLASS_DEFAULT, A_GIMME, 0); - class_addmethod(cross_class, - (t_method)cross_dsp, gensym("dsp"), 0); - CLASS_MAINSIGNALIN(cross_class, t_cross,f); - class_sethelpsymbol(cross_class, gensym("help-flib")); + class_addbang(cc_class, (t_method)cc_bang); + class_addmethod(cc_class, + (t_method)cc_dsp, gensym("dsp"), 0); + CLASS_MAINSIGNALIN(cc_class, t_cc,f); + class_sethelpsymbol(cc_class, gensym("help-flib")); } + diff --git a/flib/src/flib.h b/flib/src/flib.h index c43f63b..4e93d2e 100644 --- a/flib/src/flib.h +++ b/flib/src/flib.h @@ -21,7 +21,7 @@ Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. #include <stdlib.h> #include <string.h> -#define VERSION "0.82" +#define VERSION "0.83" void sc_tilde_setup(void); void ss_tilde_setup(void); diff --git a/flib/src/irreg~.c b/flib/src/irreg~.c index 7616c63..2b17828 100644 --- a/flib/src/irreg~.c +++ b/flib/src/irreg~.c @@ -18,7 +18,7 @@ Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. -/* calculates the spectral irreg of one frame according to Jensen et al 1999*/ +/* calculates the spectral irreg of one frame according to Jensen 1999. Original formula by Krimphoff et al 1994*/ #include "flib.h" static t_class *irreg_class; diff --git a/flib/src/sfm~.c b/flib/src/sfm~.c index ee745c2..f2fbfdd 100644 --- a/flib/src/sfm~.c +++ b/flib/src/sfm~.c @@ -18,7 +18,7 @@ Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. -/* calculates spectral flatness measure as described by Tae Hong Park*/ +/* calculates spectral flatness measure: Geometric Mean/ Arithemtic Mean (In this case converted to a DB scale */ #include "m_pd.h" #include <math.h> diff --git a/flib/src/ss~.c b/flib/src/ss~.c index 8ad1caa..83baf82 100644 --- a/flib/src/ss~.c +++ b/flib/src/ss~.c @@ -18,7 +18,7 @@ Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. -/* calculates the spectral smoothness of one frame according to Krimphoff et al. 1994*/ +/* calculates the spectral smoothness of one frame according to McAdams 1999. Takes magnitude spectrum as input*/ #include "flib.h" static t_class *ss_class; @@ -35,9 +35,9 @@ static t_int *ss_perform(t_int *w) t_int N = (t_int)(w[3]),M = N >> 1,n; t_float I = 0, buf[M]; for(n = 0; n < M; buf[n++] = *in++); - for(n = 2; n < M - 1; n++){ + for(n = 2; n < M - 1; n++){ if(buf[n] != 0 && buf[n-1] != 0 && buf[n+1] != 0) - I += (buf[n] - (buf[n-1] + buf[n] + buf[n+1]) / 3); + I += (20 * log10(buf[n]) - (20 * log10(buf[n-1]) + 20 * log10(buf[n]) + 20 * log10(buf[n+1])) / 3); } outlet_float(x->x_obj.ob_outlet, I); |