diff options
| author | Miller Puckette <millerpuckette@users.sourceforge.net> | 2006-09-11 20:34:38 +0000 |
|---|---|---|
| committer | Miller Puckette <millerpuckette@users.sourceforge.net> | 2006-09-11 20:34:38 +0000 |
| commit | 408ecb8a54e30651faedb32ab11dbd57d4a57c0e (patch) | |
| tree | d389b1340ba8ee3b29aa533e135921a948f08ba0 /pd | |
| parent | 026589c77ea733ae92c38b78fbd633bfbd0b8e94 (diff) | |
add sigmund~
svn path=/trunk/; revision=5917
Diffstat (limited to 'pd')
| -rw-r--r-- | pd/extra/sigmund~/makefile | 4 | ||||
| -rw-r--r-- | pd/extra/sigmund~/sigmund~-help.pd | 172 | ||||
| -rw-r--r-- | pd/extra/sigmund~/sigmund~.c | 1333 |
3 files changed, 1509 insertions, 0 deletions
diff --git a/pd/extra/sigmund~/makefile b/pd/extra/sigmund~/makefile new file mode 100644 index 00000000..3dc176b3 --- /dev/null +++ b/pd/extra/sigmund~/makefile @@ -0,0 +1,4 @@ +NAME=sigmund~ +CSYM=sigmund_tilde + +include ../makefile diff --git a/pd/extra/sigmund~/sigmund~-help.pd b/pd/extra/sigmund~/sigmund~-help.pd new file mode 100644 index 00000000..f3556c9c --- /dev/null +++ b/pd/extra/sigmund~/sigmund~-help.pd @@ -0,0 +1,172 @@ +#N canvas 209 199 580 617 12; +#X text 42 4 sigmund~ - sinusoidal analysis and pitch tracking; +#N canvas 432 117 573 597 using-with-tables 0; +#X obj 29 368 print peak; +#N canvas 0 0 450 300 (subpatch) 0; +#X array insignal 1024 float 2; +#X coords 0 1 1023 -1 200 140 1; +#X restore 83 426 graph; +#X obj 314 513 phasor~; +#X obj 294 429 loadbang; +#X obj 314 461 440; +#X floatatom 313 488 5 0 0 0 - - -; +#X obj 305 544 tabwrite~ insignal; +#X obj 290 516 bng 15 250 50 0 empty empty empty 17 7 0 10 -262144 +-1 -1; +#X text 114 11 Using sigmund~ on arrays; +#X text 42 33 If invoked with the "-t" flag (as a creation argument) +\, sigmund~ analyzes waveforms stored in arrays. Instead of an incoming +signal \, feed it "list" messages with the following arguments:; +#X text 37 118 table name (a symbol); +#X text 38 137 number of points; +#X obj 29 342 sigmund~ -t -npeak 10 -maxfreq 5000 peaks; +#X msg 29 316 list insignal 1024 0 44100 0; +#X text 37 158 index of first point; +#X text 39 179 sample rate; +#X text 38 200 debug flag (print debugging info if nonzero); +#X text 23 232 In this mode \, only the "env" \, "pitch" \, and "peaks" +outputs are meaningful.; +#X text 31 294 click here to test:; +#X connect 2 0 6 0; +#X connect 3 0 4 0; +#X connect 4 0 5 0; +#X connect 5 0 2 0; +#X connect 5 0 7 0; +#X connect 7 0 6 0; +#X connect 12 0 0 0; +#X connect 13 0 12 0; +#X restore 330 553 pd using-with-tables; +#X obj 40 512 phasor~; +#X obj 40 425 loadbang; +#X floatatom 40 471 5 0 120 0 - - -; +#X floatatom 39 561 5 0 0 0 - - -; +#X floatatom 245 563 5 0 0 0 - - -; +#X obj 40 490 mtof; +#X obj 40 448 69; +#X text 38 579 pitch; +#X text 222 582 envelope; +#X text 13 28 Sigmund~ analyzes an incoming sound into sinusoidal components +\, which may be reported individually or combined to form a pitch estimate. +Possible outputs are specified as creation arguments:; +#X text 55 129 env - output pitches at the beginning of notes; +#X text 56 95 pitch - output pitch continuously; +#N canvas 518 74 588 728 setting-parameters 0; +#X msg 182 66 print; +#X floatatom 192 92 5 0 0 0 - - -; +#X msg 192 113 minpower \$1; +#X obj 182 139 sigmund~ -minpower 40; +#X text 39 14 You can set parameters either by creation arguments \, +or else using messages. The "print" message gives you the current values +of all the parameters:; +#X text 28 169 npts: number of points used in an analysis. Must be +a power of two \, at least 128 The minimum frequency that can be tracked +is about 2(sample_rate)/npts.; +#X text 26 219 hop: number of points between analyses. Must be a power +of two \, at least the DSP vector size (usually 64). This regulates +the number of analyses done per unit of time.; +#X text 28 271 npeak: maximum number of sinusoidal peaks to look for. +The computation time is quadratic in the number of peaks actually found +(this number only sets an upper limit). Use it to balance CPU time +with quality of results.; +#X text 30 336 maxfreq: maximum frequency of sinusoidal peaks to look +for. This can be useful in situations where background noise creates +high-frequency \, spurious peaks..; +#X text 37 388 vibrato: maximum deviation from "pitch" to accept as +normal vibrato (affects "notes" output only). If the value is too small. +vibratos will appear as trills. If too large \, very small melodic +intervals may not be reported as new notes.; +#X text 33 457 stabletime: time period to wait before reporting a note +(affects "notes" output only). The "pitch" must be present and must +not vary more than "vibrato" for this entire period to report a note. +If too large \, the "notes" will be unnecessarily delayed. If too small +\, spurious notes get output.; +#X text 31 551 minpower: minimum measured RMS level to report a pitch +(affects "pitch" and "notes" output only). Signals quieter than this +will be assumed to be crosstalk and ignored.; +#X text 32 602 growth: minimum measured RMS growth to report a new +note (affects "notes" output only). The RMS level must rise by this +many dB (within a time period given by "stabletime") to report a repetition +of a note at or near the previously output pitch.; +#X connect 0 0 3 0; +#X connect 1 0 2 0; +#X connect 2 0 3 0; +#X restore 330 531 pd setting-parameters; +#N canvas 190 230 640 535 sinusoid-tracking 0; +#X obj 124 267 sigmund~ -npeak 10 peaks; +#X obj 124 214 phasor~; +#X obj 124 144 loadbang; +#X floatatom 124 190 5 0 120 0 - - -; +#X obj 124 295 route 0 1 2 3 4 5 6 7 8 9; +#X obj 82 339 unpack 0 0 0 0; +#X floatatom 82 461 5 0 0 0 - - -; +#X floatatom 122 431 5 0 0 0 - - -; +#X floatatom 162 406 5 0 0 0 - - -; +#X obj 124 167 440; +#X floatatom 203 380 5 0 0 0 - - -; +#X obj 322 349 unpack 0 0 0 0; +#X floatatom 322 471 5 0 0 0 - - -; +#X floatatom 362 441 5 0 0 0 - - -; +#X floatatom 402 416 5 0 0 0 - - -; +#X floatatom 443 390 5 0 0 0 - - -; +#X text 385 475 frequency (Hz.); +#X text 419 442 peak amplitude (linear); +#X text 464 416 cosine component; +#X text 499 390 sine component; +#X text 42 26 You can ask for sinusoidal peaks in decreasing order +of amplitude or arranged into maximally continuous tracks for resynthesis. +(Or you can ask for both.) In any case \, out come lists of five numbers +\, one for each sinusoid at each analysis period. The first is the +number of the sinusoid (so you can use "route" to claw them apart). +The other four are as shown:; +#X text 79 505 loudest partial; +#X text 332 508 quietest partial; +#X connect 0 0 4 0; +#X connect 1 0 0 0; +#X connect 2 0 9 0; +#X connect 3 0 1 0; +#X connect 4 0 5 0; +#X connect 4 9 11 0; +#X connect 5 0 6 0; +#X connect 5 1 7 0; +#X connect 5 2 8 0; +#X connect 5 3 10 0; +#X connect 9 0 3 0; +#X connect 11 0 12 0; +#X connect 11 1 13 0; +#X connect 11 2 14 0; +#X connect 11 3 15 0; +#X restore 330 508 pd sinusoid-tracking; +#X text 52 165 tracks - output sinusoidal peaks organized into tracks +; +#X text 56 111 notes - output pitch at the beginning of notes; +#X text 339 485 more details:; +#X text 10 184 Parameters you may set (in creation arguments or messages): +; +#X text 60 207 npts - number of points in each analysis window (1024) +; +#X text 60 225 hop - number of points between each analysis (512); +#X text 60 242 npeak - number of sinusoidal peaks (20); +#X text 61 279 vibrato - depth of vibrato to expect in 1/2-tones (1) +; +#X text 60 298 stabletime - time (msec) to wait to report notes (50) +; +#X obj 39 535 sigmund~ -hop 4096 pitch env; +#X text 62 316 minpower - minimum power (dB) to report a pitch (50) +; +#X text 62 335 growth - growth (dB) to report a new note (7); +#X text 54 147 peaks - output all sinusoidal peaks in order of amplitude +; +#X text 380 596 updated for Pd v0.40; +#X text 11 356 The npts and hop parameters are in samples \, and are +powers of two. The example below specifies a huge hop of 4096 (to slow +the output down) and to output "pitch" and "env". (Those are the default +outputs.); +#X text 61 260 maxfreq - maximum sinusoid frequency in Hz. (1000000) +; +#X connect 2 0 25 0; +#X connect 3 0 8 0; +#X connect 4 0 7 0; +#X connect 7 0 2 0; +#X connect 8 0 4 0; +#X connect 25 0 5 0; +#X connect 25 1 6 0; diff --git a/pd/extra/sigmund~/sigmund~.c b/pd/extra/sigmund~/sigmund~.c new file mode 100644 index 00000000..96d15a2c --- /dev/null +++ b/pd/extra/sigmund~/sigmund~.c @@ -0,0 +1,1333 @@ +/* Copyright (c) 2005 Miller Puckette. BSD licensed. No warranties. */ + +/* + fix parameter settings + not to report pitch if evidence too scanty? + note-on detection triggered by falling envelope (a posteriori) + reentrancy bug setting loud flag (other parameters too?) + tweaked freqs still not stable enough + implement block ("-b") mode +*/ + +#include "m_pd.h" +#include <math.h> +#include <stdio.h> +#include <string.h> +#ifdef MSW +#include <malloc.h> +#else +#include <alloca.h> +#endif +#include <stdlib.h> +#ifdef NT +#pragma warning( disable : 4244 ) +#pragma warning( disable : 4305 ) +#endif + +typedef struct peak +{ + float p_freq; + float p_amp; + float p_ampreal; + float p_ampimag; + float p_pit; + float p_db; + float p_salience; + float p_tmp; +} t_peak; + +/********************** service routines **************************/ + +static int sigmund_ilog2(int n) +{ + int ret = -1; + while (n) + { + n >>= 1; + ret++; + } + return (ret); +} + +/* parameters for von Hann window (change these to get Hamming if desired) */ +#define W_ALPHA 0.5 +#define W_BETA 0.5 +#define NEGBINS 4 /* number of bins of negative frequency we'll need */ + +#define PI 3.14159265 +#define LOG2 0.69314718 +#define LOG10 2.30258509 + +static float sinx(float theta, float sintheta) +{ + if (theta > -0.003 && theta < 0.003) + return (1); + else return (sintheta/theta); +} + +static float window_hann_mag(float pidetune, float sinpidetune) +{ + return (W_ALPHA * sinx(pidetune, sinpidetune) + - 0.5 * W_BETA * + (sinx(pidetune+PI, sinpidetune) + sinx(pidetune-PI, sinpidetune))); +} + +static float window_mag(float pidetune, float cospidetune) +{ + return (sinx(pidetune + (PI/2), cospidetune) + + sinx(pidetune - (PI/2), -cospidetune)); +} + +/*********** Routines to analyze a window into sinusoidal peaks *************/ + +static int sigmund_cmp_freq(const void *p1, const void *p2) +{ + if ((*(t_peak **)p1)->p_freq > (*(t_peak **)p2)->p_freq) + return (1); + else if ((*(t_peak **)p1)->p_freq < (*(t_peak **)p2)->p_freq) + return (-1); + else return (0); +} + +static void sigmund_tweak(int npts, float *ftreal, float *ftimag, + int npeak, t_peak *peaks, float fperbin, int loud) +{ + t_peak **peakptrs = (t_peak **)alloca(sizeof (*peakptrs) * (npeak+1)); + t_peak negpeak; + int peaki, j, k; + float ampreal[3], ampimag[3]; + float binperf = 1./fperbin; + float phaseperbin = (npts-0.5)/npts, oneovern = 1./npts; + if (npeak < 1) + return; + for (peaki = 0; peaki < npeak; peaki++) + peakptrs[peaki+1] = &peaks[peaki]; + qsort(peakptrs+1, npeak, sizeof (*peakptrs), sigmund_cmp_freq); + peakptrs[0] = &negpeak; + negpeak.p_ampreal = peakptrs[1]->p_ampreal; + negpeak.p_ampimag = -peakptrs[1]->p_ampimag; + negpeak.p_freq = -peakptrs[1]->p_freq; + for (peaki = 1; peaki <= npeak; peaki++) + { + int cbin = peakptrs[peaki]->p_freq*binperf + 0.5; + int nsub = (peaki == npeak ? 1:2); + float windreal, windimag, windpower, detune, pidetune, sinpidetune, + cospidetune, ampcorrect, ampout, ampoutreal, ampoutimag, freqout; + /* post("3 nsub %d amp %f freq %f", nsub, + peakptrs[peaki]->p_amp, peakptrs[peaki]->p_freq); */ + if (cbin < 0 || cbin > 2*npts - 3) + continue; + for (j = 0; j < 3; j++) + ampreal[j] = ftreal[cbin+2*j-2], ampimag[j] = ftimag[cbin+2*j-2]; + /* post("a %f %f", ampreal[1], ampimag[1]); */ + for (j = 0; j < nsub; j++) + { + t_peak *neighbor = peakptrs[(peaki-1) + 2*j]; + float neighborreal = npts * neighbor->p_ampreal; + float neighborimag = npts * neighbor->p_ampimag; + for (k = 0; k < 3; k++) + { + float freqdiff = (0.5*PI) * ((cbin + 2*k-2) + -binperf * neighbor->p_freq); + float sx = sinx(freqdiff, sin(freqdiff)); + float phasere = cos(freqdiff * phaseperbin); + float phaseim = sin(freqdiff * phaseperbin); + ampreal[k] -= + sx * (phasere * neighborreal - phaseim * neighborimag); + ampimag[k] -= + sx * (phaseim * neighborreal + phasere * neighborimag); + } + /* post("b %f %f", ampreal[1], ampimag[1]); */ + } + + windreal = W_ALPHA * ampreal[1] - + (0.5 * W_BETA) * (ampreal[0] + ampreal[2]); + windimag = W_ALPHA * ampimag[1] - + (0.5 * W_BETA) * (ampimag[0] + ampimag[2]); + windpower = windreal * windreal + windimag * windimag; + detune = ( + W_BETA*(ampreal[0] - ampreal[2]) * + (2.0*W_ALPHA * ampreal[1] - W_BETA * (ampreal[0] + ampreal[2])) + + + W_BETA*(ampimag[0] - ampimag[2]) * + (2.0*W_ALPHA * ampimag[1] - W_BETA * (ampimag[0] + ampimag[2])) + ) / (4.0 * windpower); + if (detune > 0.5) + detune = 0.5; + else if (detune < -0.5) + detune = -0.5; + /* if (loud > 0) + post("tweak: windpower %f, bin %d, detune %f", + windpower, cbin, detune); */ + pidetune = PI * detune; + sinpidetune = sin(pidetune); + cospidetune = cos(pidetune); + + ampcorrect = 1.0 / window_hann_mag(pidetune, sinpidetune); + + ampout = oneovern * ampcorrect *sqrt(windpower); + ampoutreal = oneovern * ampcorrect * + (windreal * cospidetune - windimag * sinpidetune); + ampoutimag = oneovern * ampcorrect * + (windreal * sinpidetune + windimag * cospidetune); + freqout = (cbin + 2*detune) * fperbin; + if (loud > 1) + post("amp %f, freq %f", ampout, freqout); + + peakptrs[peaki]->p_freq = freqout; + peakptrs[peaki]->p_amp = ampout; + peakptrs[peaki]->p_ampreal = ampoutreal; + peakptrs[peaki]->p_ampimag = ampoutimag; + } +} + + +static void sigmund_getrawpeaks(int npts, float *insamps, + int npeak, t_peak *peakv, int *nfound, float *power, float srate, int loud, + float param1, float param2, float param3, float hifreq) +{ + float oneovern = 1.0/ (float)npts; + float fperbin = 0.5 * srate * oneovern; + int npts2 = 2*npts, i, bin; + int count, peakcount = 0; + float *fp1, *fp2; + float *rawpow, *rawreal, *rawimag, *maskbuf; + float *bigbuf = alloca(sizeof (float ) * (2*NEGBINS + 5*npts)); + int maxbin = hifreq/fperbin; + int altwind = (param3 == 1); + int tweak = (param3 == 0); + if (maxbin > npts - NEGBINS) + maxbin = npts - NEGBINS; + if (loud) post("tweak %d", tweak); + maskbuf = bigbuf + npts2; + rawreal = maskbuf + npts+NEGBINS; + rawimag = rawreal+npts+NEGBINS; + for (i = 0; i < npts; i++) + maskbuf[i] = 0; + + for (i = 0; i < npts; i++) + bigbuf[i] = insamps[i]; + for (i = npts; i < 2*npts; i++) + bigbuf[i] = 0; + mayer_realfft(npts2, bigbuf); + for (i = 0; i < npts; i++) + rawreal[i] = bigbuf[i]; + for (i = 1; i < npts-1; i++) + rawimag[i] = bigbuf[npts2-i]; + if (loud && npts == 1024) + { + float bigbuf2[2048]; + for (i = 0; i < 1024; i++) + bigbuf2[i] = insamps[i]; + for (i = 1024; i < 2048; i++) + bigbuf2[i] = 0; + mayer_realfft(2048, bigbuf2); + for (i = 1; i < 10; i++) + post("(%10.2f, %10.2f) -> (%10.2f, %10.2f)", + bigbuf2[i], bigbuf2[2048-i], rawreal[i], rawimag[i]); + } + + rawreal[-1] = rawreal[1]; + rawreal[-2] = rawreal[2]; + rawreal[-3] = rawreal[3]; + rawreal[-4] = rawreal[4]; + rawimag[0] = rawimag[npts-1] = 0; + rawimag[-1] = -rawimag[1]; + rawimag[-2] = -rawimag[2]; + rawimag[-3] = -rawimag[3]; + rawimag[-4] = -rawimag[4]; + + for (peakcount = 0; peakcount < npeak; peakcount++) + { + float pow1, maxpower = 0, totalpower = 0, windreal, windimag, windpower, + detune, pidetune, sinpidetune, cospidetune, ampcorrect, ampout, + ampoutreal, ampoutimag, freqout, freqcount1, freqcount2, powmask; + int bestindex = -1; + for (bin = 2, fp1 = rawreal+2, fp2 = rawimag+2; + bin < maxbin; bin++, fp1++, fp2++) + { + float x1, x2, a1, a2, b1, b2, thresh; + if (altwind) + { + x1 = fp1[0] - 0.5*(fp1[-2] +fp1[2]); + x2 = fp2[0] - 0.5*(fp2[-2] +fp2[2]); + a1 = fp1[4] - 0.5*(fp1[2] +fp1[6]); + a2 = fp2[2] - 0.5*(fp2[2] +fp2[6]); + b1 = fp1[-4] - 0.5*(fp1[-2] +fp1[-6]); + b2 = fp2[-4] - 0.5*(fp2[-2] +fp2[-6]); + thresh = param2 * (a1*a1+a2*a2+b1*b1+b2*b2); + } + else + { + x1 = fp1[1] - fp1[-1]; + x2 = fp2[1] - fp2[-1]; + a1 = fp1[3] - fp1[1]; + a2 = fp2[3] - fp2[1]; + b1 = fp1[-1] - fp1[-3]; + b2 = fp2[-1] - fp2[-3]; + thresh = param2 * (a1*a1+a2*a2+b1*b1+b2*b2); + } + pow1 = x1*x1+x2*x2; + if (pow1 > maxpower && pow1 > maskbuf[bin]) + { + if (pow1 > thresh) + maxpower = pow1, bestindex = bin; + } + totalpower += pow1; + } + if (totalpower <= 0 || maxpower < 1e-10*totalpower || bestindex < 0) + break; + fp1 = rawreal+bestindex; + fp2 = rawimag+bestindex; + *power = 0.5 * totalpower *oneovern * oneovern; + powmask = maxpower * exp(-param1 * log(10.) / 10.); + if (loud > 2) + post("maxpower %f, powmask %f, param1 %f", + maxpower, powmask, param1); + for (bin = 2; bin < maxbin; bin++) + { + float bindiff = bin - bestindex; + float mymask = + powmask/ (1. + bindiff * bindiff * bindiff * bindiff); + if (bindiff < 2 && bindiff > -2) + mymask = 2*maxpower; + if (mymask > maskbuf[bin]) + maskbuf[bin] = mymask; + } + + if (loud > 1) + post("best index %d, total power %f", bestindex, totalpower); + if (altwind) + { + windreal = W_ALPHA * fp1[0] - (0.5 * W_BETA) * (fp1[2] + fp1[-2]); + windimag = W_ALPHA * fp2[0] - (0.5 * W_BETA) * (fp2[2] + fp2[-2]); + windpower = windreal * windreal + windimag * windimag; + detune = ( + (W_BETA*(rawreal[bestindex-2] - rawreal[bestindex+2])) * + (2.0 * W_ALPHA * rawreal[bestindex] - + W_BETA * (rawreal[bestindex-2] + rawreal[bestindex+2])) + + + (W_BETA*(rawimag[bestindex-2] - rawimag[bestindex+2])) * + (2.0 * W_ALPHA * rawimag[bestindex] - + W_BETA * (rawimag[bestindex-2] + rawimag[bestindex+2])) + ) / (4.0 * windpower); + } + else + { + windreal = fp1[1] - fp1[-1]; + windimag = fp2[1] - fp2[-1]; + windpower = windreal * windreal + windimag * windimag; + detune = ((fp1[1] * fp1[1] - fp1[-1]*fp1[-1]) + + (fp2[1] * fp2[1] - fp2[-1]*fp2[-1])) / (2 * windpower); + if (loud > 2) post("(-1) %f %f; (1) %f %f", + fp1[-1], fp2[-1], fp1[1], fp2[1]); + if (loud > 2) post("peak %f %f", + fp1[0], fp2[0]); + } + if (detune > 0.5) + detune = 0.5; + else if (detune < -0.5) + detune = -0.5; + if (loud > 1) + post("windpower %f, index %d, detune %f", + windpower, bestindex, detune); + pidetune = PI * detune; + sinpidetune = sin(pidetune); + cospidetune = cos(pidetune); + if (altwind) + ampcorrect = 1.0 / window_hann_mag(pidetune, sinpidetune); + else ampcorrect = 1.0 / window_mag(pidetune, cospidetune); + + ampout = ampcorrect *sqrt(windpower); + ampoutreal = ampcorrect * + (windreal * cospidetune - windimag * sinpidetune); + ampoutimag = ampcorrect * + (windreal * sinpidetune + windimag * cospidetune); + + /* the frequency is the sum of the bin frequency and detuning */ + + peakv[peakcount].p_freq = (freqout = (bestindex + 2*detune)) * fperbin; + peakv[peakcount].p_amp = oneovern * ampout; + peakv[peakcount].p_ampreal = oneovern * ampoutreal; + peakv[peakcount].p_ampimag = oneovern * ampoutimag; + } + if (tweak) + { + sigmund_tweak(npts, rawreal, rawimag, peakcount, peakv, fperbin, loud); + sigmund_tweak(npts, rawreal, rawimag, peakcount, peakv, fperbin, loud); + } + for (i = 0; i < peakcount; i++) + { + peakv[i].p_pit = ftom(peakv[i].p_freq); + peakv[i].p_db = powtodb(peakv[i].p_amp); + } + *nfound = peakcount; +} + +/*************** Routines for finding fundamental pitch *************/ + +#define PITCHNPEAK 12 +#define PITCHUNCERTAINTY 0.3 +#define HALFTONEINC 0.059 +#define SUBHARMONICS 16 +#define DBPERHALFTONE 0.5 + +static void sigmund_getpitch(int npeak, t_peak *peakv, float *freqp, + float npts, float srate, int loud) +{ + float fperbin = 0.5 * srate / npts; + int npit = 48 * sigmund_ilog2(npts), i, j, k, nsalient; + float bestbin, bestweight, sumamp, sumweight, sumfreq, sumallamp, + freq; + float *weights = (float *)alloca(sizeof(float) * npit); + t_peak *bigpeaks[PITCHNPEAK]; + int nbigpeaks; + if (npeak < 1) + { + freq = 0; + goto done; + } + for (i = 0; i < npit; i++) + weights[i] = 0; + for (i = 0; i < npeak; i++) + { + peakv[i].p_tmp = 0; + peakv[i].p_salience = peakv[i].p_db - DBPERHALFTONE * peakv[i].p_pit; + } + for (nsalient = 0; nsalient < PITCHNPEAK; nsalient++) + { + t_peak *bestpeak = 0; + float bestsalience = -1e20; + for (j = 0; j < npeak; j++) + if (peakv[j].p_tmp == 0 && peakv[j].p_salience > bestsalience) + { + bestsalience = peakv[j].p_salience; + bestpeak = &peakv[j]; + } + if (!bestpeak) + break; + bigpeaks[nsalient] = bestpeak; + bestpeak->p_tmp = 1; + /* post("peak f=%f a=%f", bestpeak->p_freq, bestpeak->p_amp); */ + } + sumweight = 0; + for (i = 0; i < nsalient; i++) + { + t_peak *thispeak = bigpeaks[i]; + float pitchuncertainty = + 4 * PITCHUNCERTAINTY * fperbin / (HALFTONEINC * thispeak->p_freq); + float weightindex = (48./LOG2) * + log(thispeak->p_freq/(2.*fperbin)); + float loudness = sqrt(thispeak->p_amp); + /* post("index %f, uncertainty %f", weightindex, pitchuncertainty); */ + for (j = 0; j < SUBHARMONICS; j++) + { + float subindex = weightindex - + (48./LOG2) * log(j + 1.); + int loindex = subindex - pitchuncertainty; + int hiindex = subindex + pitchuncertainty + 1; + if (hiindex < 0) + break; + if (hiindex >= npit) + continue; + if (loindex < 0) + loindex = 0; + for (k = loindex; k <= hiindex; k++) + weights[k] += loudness * 4. / (4. + j); + } + sumweight += loudness; + } +#if 0 + for (i = 0; i < npit; i++) + { + postfloat(weights[i]); + if (!((i+1)%12)) post(""); + } +#endif + bestbin = -1; + bestweight = -1e20; + for (i = 0; i < npit; i++) + if (weights[i] > bestweight) + bestweight = weights[i], bestbin = i; + if (bestweight < sumweight * 0.4) + bestbin = -1; + + if (bestbin < 0) + { + freq = 0; + goto done; + } + for (i = bestbin+1; i < npit; i++) + { + if (weights[i] < bestweight) + break; + bestbin += 0.5; + } + freq = 2*fperbin * exp((LOG2/48.)*bestbin); + + for (sumamp = sumweight = sumfreq = 0, i = 0; i < nsalient; i++) + { + t_peak *thispeak = bigpeaks[i]; + float thisloudness = sqrt(thispeak->p_amp); + float thisfreq = thispeak->p_freq; + float harmonic = thisfreq/freq; + float intpart = (int)(0.5 + harmonic); + float inharm = freq * (harmonic - intpart); + if (harmonic < 1) + continue; + if (inharm < 0.25*fperbin && inharm > -0.25*fperbin) + { + float weight = thisloudness * intpart; + sumweight += weight; + sumfreq += weight*thisfreq/intpart; + } + } + if (sumweight > 0) + freq = sumfreq / sumweight; +done: + if (!(freq >= 0 || freq <= 0)) + { + post("freq nan cancelled"); + freq = 0; + } + *freqp = freq; +} + +/*************** gather peak lists into sinusoidal tracks *************/ + +static void sigmund_peaktrack(int ninpeak, t_peak *inpeakv, + int noutpeak, t_peak *outpeakv, int loud) +{ + int incnt, outcnt; + for (outcnt = 0; outcnt < noutpeak; outcnt++) + outpeakv[outcnt].p_tmp = -1; + + /* first pass. Match each "in" peak with the closest previous + "out" peak, but no two to the same one. */ + for (incnt = 0; incnt < ninpeak; incnt++) + { + float besterror = 1e20; + int bestcnt = -1; + inpeakv[incnt].p_tmp = -1; + for (outcnt = 0; outcnt < noutpeak; outcnt++) + { + float thiserror = + inpeakv[incnt].p_freq - outpeakv[outcnt].p_freq; + if (thiserror < 0) + thiserror = -thiserror; + if (thiserror < besterror) + { + besterror = thiserror; + bestcnt = outcnt; + } + } + if (outpeakv[bestcnt].p_tmp < 0) + { + outpeakv[bestcnt] = inpeakv[incnt]; + inpeakv[incnt].p_tmp = 0; + outpeakv[bestcnt].p_tmp = 0; + } + } + /* second pass. Unmatched "in" peaks assigned to free "out" + peaks */ + for (incnt = 0; incnt < ninpeak; incnt++) + if (inpeakv[incnt].p_tmp < 0) + { + for (outcnt = 0; outcnt < noutpeak; outcnt++) + if (outpeakv[outcnt].p_tmp < 0) + { + outpeakv[outcnt] = inpeakv[incnt]; + inpeakv[incnt].p_tmp = 0; + outpeakv[outcnt].p_tmp = 1; + break; + } + } + for (outcnt = 0; outcnt < noutpeak; outcnt++) + if (outpeakv[outcnt].p_tmp == -1) + outpeakv[outcnt].p_amp = 0; +} + +/**************** parse continuous pitch into note starts ***************/ + +#define NHISTPOINT 100 + +typedef struct _histpoint +{ + float h_freq; + float h_power; +} t_histpoint; + +typedef struct _notefinder +{ + float n_age; + float n_hifreq; + float n_lofreq; + int n_peaked; + t_histpoint n_hist[NHISTPOINT]; + int n_histphase; +} t_notefinder; + + +static void notefinder_init(t_notefinder *x) +{ + int i; + x->n_peaked = x->n_age = 0; + x->n_hifreq = x->n_lofreq = 0; + x->n_histphase = 0; + for (i = 0; i < NHISTPOINT; i++) + x->n_hist[i].h_freq =x->n_hist[i].h_power = 0; +} + +static void notefinder_doit(t_notefinder *x, float freq, float power, + float *note, float vibrato, int stableperiod, float powerthresh, + float growththresh, int loud) +{ + /* calculate frequency ratio between allowable vibrato extremes + (equal to twice the vibrato deviation from center) */ + float vibmultiple = exp((2*LOG2/12) * vibrato); + int oldhistphase, i, k; + if (stableperiod > NHISTPOINT - 1) + stableperiod = NHISTPOINT - 1; + if (++x->n_histphase == NHISTPOINT) + x->n_histphase = 0; + x->n_hist[x->n_histphase].h_freq = freq; + x->n_hist[x->n_histphase].h_power = power; + x->n_age++; + *note = 0; + if (loud) + { + post("stable %d, age %d, vibmultiple %f, powerthresh %f, hifreq %f", + stableperiod, (int)x->n_age ,vibmultiple, powerthresh, x->n_hifreq); + post("histfreq %f %f %f %f", + x->n_hist[x->n_histphase].h_freq, + x->n_hist[(x->n_histphase+NHISTPOINT-1)%NHISTPOINT].h_freq, + x->n_hist[(x->n_histphase+NHISTPOINT-2)%NHISTPOINT].h_freq, + x->n_hist[(x->n_histphase+NHISTPOINT-3)%NHISTPOINT].h_freq); + post("power %f %f %f %f", + x->n_hist[x->n_histphase].h_power, + x->n_hist[(x->n_histphase+NHISTPOINT-1)%NHISTPOINT].h_power, + x->n_hist[(x->n_histphase+NHISTPOINT-2)%NHISTPOINT].h_power, + x->n_hist[(x->n_histphase+NHISTPOINT-3)%NHISTPOINT].h_power); + for (i = 0, k = x->n_histphase; i < stableperiod; i++) + { + post("pit %5.1f pow %f", ftom(x->n_hist[k].h_freq), + x->n_hist[k].h_power); + if (--k < 0) + k = NHISTPOINT - 1; + } + } + /* look for shorter notes than "stableperiod" in length. + The amplitude must rise and then fall while the pitch holds + steady. */ + if (x->n_hifreq <= 0 && x->n_age > stableperiod) + { + float maxpow = 0, freqatmaxpow = 0, + localhifreq = -1e20, locallofreq = 1e20; + int startphase = x->n_histphase - stableperiod + 1; + if (startphase < 0) + startphase += NHISTPOINT; + for (i = 0, k = startphase; i < stableperiod; i++) + { + if (x->n_hist[k].h_freq <= 0) + break; + if (x->n_hist[k].h_power > maxpow) + maxpow = x->n_hist[k].h_power, + freqatmaxpow = x->n_hist[k].h_freq; + if (x->n_hist[k].h_freq > localhifreq) + localhifreq = x->n_hist[k].h_freq; + if (x->n_hist[k].h_freq < locallofreq) + locallofreq = x->n_hist[k].h_freq; + if (localhifreq > locallofreq * vibmultiple) + break; + if (maxpow > power * growththresh && + maxpow > x->n_hist[startphase].h_power * growththresh && + localhifreq < vibmultiple * locallofreq + && freqatmaxpow > 0 && maxpow > powerthresh) + { + x->n_hifreq = x->n_lofreq = *note = freqatmaxpow; + x->n_age = 0; + x->n_peaked = 0; + /* post("got short note"); */ + return; + } + if (++k >= NHISTPOINT) + k = 0; + } + + } + if (x->n_hifreq > 0) + { + /* test if we're within "vibrato" range, and if so update range */ + if (freq * vibmultiple >= x->n_hifreq && + x->n_lofreq * vibmultiple >= freq) + { + if (freq > x->n_hifreq) + x->n_hifreq = freq; + if (freq < x->n_lofreq) + x->n_lofreq = freq; + } + else if (x->n_hifreq > 0 && x->n_age > stableperiod) + { + /* if we've been out of range at least 1/2 the + last "stableperiod" analyses, clear the note */ + int nbad = 0; + for (i = 0, k = x->n_histphase; i < stableperiod - 1; i++) + { + if (--k < 0) + k = NHISTPOINT - 1; + if (x->n_hist[k].h_freq * vibmultiple <= x->n_hifreq || + x->n_lofreq * vibmultiple <= x->n_hist[k].h_freq) + nbad++; + } + if (2 * nbad >= stableperiod) + { + x->n_hifreq = x->n_lofreq = 0; + x->n_age = 0; + } + } + } + + oldhistphase = x->n_histphase - stableperiod; + if (oldhistphase < 0) + oldhistphase += NHISTPOINT; + + /* look for envelope attacks */ + + if (x->n_hifreq > 0 && x->n_peaked) + { + if (freq > 0 && power > powerthresh && + power > x->n_hist[oldhistphase].h_power * + exp((LOG10*0.1)*growththresh)) + { + /* clear it and fall through for new stable-note test */ + x->n_peaked = 0; + x->n_hifreq = x->n_lofreq = 0; + x->n_age = 0; + } + } + else if (!x->n_peaked) + { + if (x->n_hist[oldhistphase].h_power > powerthresh && + x->n_hist[oldhistphase].h_power > power) + x->n_peaked = 1; + } + + /* test for a new note using a stability criterion. */ + + if (freq >= 0 && + (x->n_hifreq <= 0 || freq > x->n_hifreq || freq < x->n_lofreq)) + { + float testfhi, testflo, maxpow = 0; + for (i = 0, k = x->n_histphase, testfhi = testflo = freq; + i < stableperiod-1; i++) + { + if (--k < 0) + k = NHISTPOINT - 1; + if (x->n_hist[k].h_freq > testfhi) + testfhi = x->n_hist[k].h_freq; + if (x->n_hist[k].h_freq < testflo) + testflo = x->n_hist[k].h_freq; + if (x->n_hist[k].h_power > maxpow) + maxpow = x->n_hist[k].h_power; + } + if (testflo > 0 && testfhi <= vibmultiple * testflo + && maxpow > powerthresh) + { + /* report new note */ + float sumf = 0, sumw = 0, thisf, thisw; + for (i = 0, k = x->n_histphase; i < stableperiod; i++) + { + thisw = x->n_hist[k].h_power; + sumw += thisw; + sumf += thisw*x->n_hist[k].h_freq; + if (--k < 0) + k = NHISTPOINT - 1; + } + x->n_hifreq = x->n_lofreq = *note = (sumw > 0 ? sumf/sumw : 0); +#if 0 + /* debugging printout */ + for (i = 0; i < stableperiod; i++) + { + int k3 = x->n_histphase - i; + if (k3 < 0) + k3 += NHISTPOINT; + startpost("%5.1f ", ftom(x->n_hist[k3].h_freq)); + } + post(""); +#endif + x->n_age = 0; + x->n_peaked = 0; + return; + } + } + *note = 0; + return; +} + +/*************************** Glue for Pd ************************/ + +static t_class *sigmund_class; +#define NHIST 100 + +#define MODE_STREAM 1 +#define MODE_BLOCK 2 /* uninplemented */ +#define MODE_TABLE 3 + +#define NPOINTS_DEF 1024 +#define NPOINTS_MIN 128 + +#define HOP_DEF 512 +#define NPEAK_DEF 20 + +#define VIBRATO_DEF 1 +#define STABLETIME_DEF 50 +#define MINPOWER_DEF 50 +#define GROWTH_DEF 7 + +#define OUT_PITCH 0 +#define OUT_ENV 1 +#define OUT_NOTE 2 +#define OUT_PEAKS 3 +#define OUT_TRACKS 4 +#define OUT_SMSPITCH 5 +#define OUT_SMSNONPITCH 6 + +typedef struct _varout +{ + t_outlet *v_outlet; + int v_what; +} t_varout; + +typedef struct _sigmund +{ + t_object x_obj; + t_varout *x_varoutv; + int x_nvarout; + t_clock *x_clock; + float x_f; /* for main signal inlet */ + float x_sr; /* sample rate */ + int x_mode; /* MODE_STREAM, etc. */ + int x_npts; /* number of points in analysis window */ + int x_npeak; /* number of peaks to find */ + int x_loud; /* debug level */ + t_sample *x_inbuf; /* input buffer */ + int x_infill; /* number of points filled */ + int x_countdown; /* countdown to start filling buffer */ + int x_hop; /* samples between analyses */ + float x_maxfreq; /* highest-frequency peak to report */ + float x_vibrato; /* vibrato depth in half tones */ + float x_stabletime; /* period of stability needed for note */ + float x_growth; /* growth to set off a new note */ + float x_minpower; /* minimum power, in DB, for a note */ + float x_param1; + float x_param2; + float x_param3; + t_notefinder x_notefinder; + t_peak *x_trackv; + int x_ntrack; + unsigned int x_dopitch:1; + unsigned int x_donote:1; + unsigned int x_dotracks:1; +} t_sigmund; + +static void sigmund_clock(t_sigmund *x); +static void sigmund_clear(t_sigmund *x); +static void sigmund_npts(t_sigmund *x, t_floatarg f); +static void sigmund_hop(t_sigmund *x, t_floatarg f); +static void sigmund_npeak(t_sigmund *x, t_floatarg f); +static void sigmund_maxfreq(t_sigmund *x, t_floatarg f); +static void sigmund_vibrato(t_sigmund *x, t_floatarg f); +static void sigmund_stabletime(t_sigmund *x, t_floatarg f); +static void sigmund_growth(t_sigmund *x, t_floatarg f); +static void sigmund_minpower(t_sigmund *x, t_floatarg f); + +static void *sigmund_new(t_symbol *s, int argc, t_atom *argv) +{ + t_sigmund *x = (t_sigmund *)pd_new(sigmund_class); + x->x_param1 = 0; + x->x_param2 = 0.6; + x->x_param3 = 0; + x->x_npts = NPOINTS_DEF; + x->x_hop = HOP_DEF; + x->x_mode = MODE_STREAM; + x->x_npeak = NPEAK_DEF; + x->x_vibrato = VIBRATO_DEF; + x->x_stabletime = STABLETIME_DEF; + x->x_growth = GROWTH_DEF; + x->x_minpower = MINPOWER_DEF; + x->x_maxfreq = 1000000; + x->x_loud = 0; + x->x_sr = 1; + x->x_nvarout = 0; + x->x_varoutv = (t_varout *)getbytes(0); + x->x_trackv = 0; + x->x_ntrack = 0; + x->x_dopitch = x->x_donote = x->x_dotracks = 0; + + while (argc > 0) + { + t_symbol *firstarg = atom_getsymbolarg(0, argc, argv); + if (!strcmp(firstarg->s_name, "-t")) + { + x->x_mode = MODE_TABLE; + argc--, argv++; + } + else if (!strcmp(firstarg->s_name, "-s")) + { + x->x_mode = MODE_STREAM; + argc--, argv++; + } +#if 0 + else if (!strcmp(firstarg->s_name, "-b")) + { + x->x_mode = MODE_BLOCK; + argc--, argv++; + } +#endif + else if (!strcmp(firstarg->s_name, "-npts") && argc > 1) + { + sigmund_npts(x, atom_getfloatarg(1, argc, argv)); + argc -= 2; argv += 2; + } + else if (!strcmp(firstarg->s_name, "-hop") && argc > 1) + { + sigmund_hop(x, atom_getfloatarg(1, argc, argv)); + argc -= 2; argv += 2; + } + else if (!strcmp(firstarg->s_name, "-npeak") && argc > 1) + { + sigmund_npeak(x, atom_getfloatarg(1, argc, argv)); + argc -= 2; argv += 2; + } + else if (!strcmp(firstarg->s_name, "-maxfreq") && argc > 1) + { + sigmund_maxfreq(x, atom_getfloatarg(1, argc, argv)); + argc -= 2; argv += 2; + } + else if (!strcmp(firstarg->s_name, "-vibrato") && argc > 1) + { + sigmund_vibrato(x, atom_getfloatarg(1, argc, argv)); + argc -= 2; argv += 2; + } + else if (!strcmp(firstarg->s_name, "-stabletime") && argc > 1) + { + sigmund_stabletime(x, atom_getfloatarg(1, argc, argv)); + argc -= 2; argv += 2; + } + else if (!strcmp(firstarg->s_name, "-growth") && argc > 1) + { + sigmund_growth(x, atom_getfloatarg(1, argc, argv)); + argc -= 2; argv += 2; + } + else if (!strcmp(firstarg->s_name, "-minpower") && argc > 1) + { + sigmund_minpower(x, atom_getfloatarg(1, argc, argv)); + argc -= 2; argv += 2; + } + else if (!strcmp(firstarg->s_name, "pitch")) + { + int n2 = x->x_nvarout+1; + x->x_varoutv = (t_varout *)t_resizebytes(x->x_varoutv, + x->x_nvarout*sizeof(t_varout), n2*sizeof(t_varout)); + x->x_varoutv[x->x_nvarout].v_outlet = + outlet_new(&x->x_obj, &s_float); + x->x_varoutv[x->x_nvarout].v_what = OUT_PITCH; + x->x_nvarout = n2; + x->x_dopitch = 1; + argc--, argv++; + } + else if (!strcmp(firstarg->s_name, "env")) + { + int n2 = x->x_nvarout+1; + x->x_varoutv = (t_varout *)t_resizebytes(x->x_varoutv, + x->x_nvarout*sizeof(t_varout), n2*sizeof(t_varout)); + x->x_varoutv[x->x_nvarout].v_outlet = + outlet_new(&x->x_obj, &s_float); + x->x_varoutv[x->x_nvarout].v_what = OUT_ENV; + x->x_nvarout = n2; + argc--, argv++; + } + else if (!strcmp(firstarg->s_name, "note") + || !strcmp(firstarg->s_name, "notes")) + { + int n2 = x->x_nvarout+1; + x->x_varoutv = (t_varout *)t_resizebytes(x->x_varoutv, + x->x_nvarout*sizeof(t_varout), n2*sizeof(t_varout)); + x->x_varoutv[x->x_nvarout].v_outlet = + outlet_new(&x->x_obj, &s_float); + x->x_varoutv[x->x_nvarout].v_what = OUT_NOTE; + x->x_nvarout = n2; + x->x_dopitch = x->x_donote = 1; + argc--, argv++; + } + else if (!strcmp(firstarg->s_name, "peaks")) + { + int n2 = x->x_nvarout+1; + x->x_varoutv = (t_varout *)t_resizebytes(x->x_varoutv, + x->x_nvarout*sizeof(t_varout), n2*sizeof(t_varout)); + x->x_varoutv[x->x_nvarout].v_outlet = + outlet_new(&x->x_obj, &s_list); + x->x_varoutv[x->x_nvarout].v_what = OUT_PEAKS; + x->x_nvarout = n2; + argc--, argv++; + } + else if (!strcmp(firstarg->s_name, "tracks")) + { + int n2 = x->x_nvarout+1; + x->x_varoutv = (t_varout *)t_resizebytes(x->x_varoutv, + x->x_nvarout*sizeof(t_varout), n2*sizeof(t_varout)); + x->x_varoutv[x->x_nvarout].v_outlet = + outlet_new(&x->x_obj, &s_list); + x->x_varoutv[x->x_nvarout].v_what = OUT_TRACKS; + x->x_nvarout = n2; + x->x_dotracks = 1; + argc--, argv++; + } + else + { + pd_error(x, "sigmund: %s: unknown flag or argument missing", + firstarg->s_name); + argc--, argv++; + } + } + if (!x->x_nvarout) + { + x->x_varoutv = (t_varout *)t_resizebytes(x->x_varoutv, + 0, 2*sizeof(t_varout)); + x->x_varoutv[0].v_outlet = outlet_new(&x->x_obj, &s_float); + x->x_varoutv[0].v_what = OUT_PITCH; + x->x_varoutv[1].v_outlet = outlet_new(&x->x_obj, &s_float); + x->x_varoutv[1].v_what = OUT_ENV; + x->x_nvarout = 2; + x->x_dopitch = 1; + } + if (x->x_dotracks) + { + x->x_ntrack = x->x_npeak; + x->x_trackv = (t_peak *)getbytes(x->x_ntrack * sizeof(*x->x_trackv)); + } + x->x_clock = clock_new(&x->x_obj.ob_pd, (t_method)sigmund_clock); + + /* check parameter ranges */ + if (x->x_npts < NPOINTS_MIN) + post("sigmund~: minimum points %d", NPOINTS_MIN), + x->x_npts = NPOINTS_MIN; + if (x->x_npts != (1 << sigmund_ilog2(x->x_npts))) + post("sigmund~: adjusting analysis size to %d points", + (x->x_npts = (1 << sigmund_ilog2(x->x_npts)))); + if (x->x_hop != (1 << sigmund_ilog2(x->x_hop))) + post("sigmund~: adjusting hop size to %d points", + (x->x_hop = (1 << sigmund_ilog2(x->x_hop)))); + if (x->x_mode == MODE_STREAM) + x->x_inbuf = getbytes(sizeof(*x->x_inbuf) * x->x_npts); + else x->x_inbuf = 0; + x->x_infill = 0; + x->x_countdown = 0; + notefinder_init(&x->x_notefinder); + sigmund_clear(x); + return (x); +} + +static void sigmund_doit(t_sigmund *x, int npts, float *arraypoints, + int loud, float srate) +{ + t_peak *peakv = (t_peak *)alloca(sizeof(t_peak) * x->x_npeak); + int nfound, i, cnt; + float freq = 0, power, note = 0; + sigmund_getrawpeaks(npts, arraypoints, x->x_npeak, peakv, + &nfound, &power, srate, loud, x->x_param1, x->x_param2, x->x_param3, + x->x_maxfreq); + if (x->x_dopitch) + sigmund_getpitch(nfound, peakv, &freq, npts, srate, loud); + if (x->x_donote) + notefinder_doit(&x->x_notefinder, freq, power, ¬e, x->x_vibrato, + x->x_stabletime * 0.001f * x->x_sr / (float)x->x_hop, + exp(LOG10*0.1*(x->x_minpower - 100)), x->x_growth, loud); + if (x->x_dotracks) + sigmund_peaktrack(nfound, peakv, x->x_ntrack, x->x_trackv, loud); + + for (cnt = x->x_nvarout; cnt--;) + { + t_varout *v = &x->x_varoutv[cnt]; + switch (v->v_what) + { + case OUT_PITCH: + outlet_float(v->v_outlet, ftom(freq)); + break; + case OUT_ENV: + outlet_float(v->v_outlet, powtodb(power)); + break; + case OUT_NOTE: + if (note > 0) + outlet_float(v->v_outlet, ftom(note)); + break; + case OUT_PEAKS: + for (i = 0; i < nfound; i++) + { + t_atom at[5]; + SETFLOAT(at, (float)i); + SETFLOAT(at+1, peakv[i].p_freq); + SETFLOAT(at+2, 2*peakv[i].p_amp); + SETFLOAT(at+3, 2*peakv[i].p_ampreal); + SETFLOAT(at+4, 2*peakv[i].p_ampimag); + outlet_list(v->v_outlet, &s_list, 5, at); + } + break; + case OUT_TRACKS: + for (i = 0; i < x->x_ntrack; i++) + { + t_atom at[4]; + SETFLOAT(at, (float)i); + SETFLOAT(at+1, x->x_trackv[i].p_freq); + SETFLOAT(at+2, 2*x->x_trackv[i].p_amp); + SETFLOAT(at+3, x->x_trackv[i].p_tmp); + outlet_list(v->v_outlet, &s_list, 4, at); + } + break; + } + } +} + +static void sigmund_list(t_sigmund *x, t_symbol *s, int argc, t_atom *argv) +{ + t_symbol *syminput = atom_getsymbolarg(0, argc, argv); + int npts = atom_getintarg(1, argc, argv); + int onset = atom_getintarg(2, argc, argv); + float srate = atom_getfloatarg(3, argc, argv); + int loud = atom_getfloatarg(4, argc, argv); + int arraysize, totstorage, nfound, i; + t_garray *a; + float *arraypoints, pit; + + if (argc < 5) + { + post( + "sigmund: array-name, npts, array-onset, samplerate, loud"); + return; + } + if (npts < 64 || npts != (1 << ilog2(npts))) + { + error("sigmund: bad npoints"); + return; + } + if (onset < 0) + { + error("sigmund: negative onset"); + return; + } + + if (!(a = (t_garray *)pd_findbyclass(syminput, garray_class)) || + !garray_getfloatarray(a, &arraysize, &arraypoints) || + arraysize < onset + npts) + { + error("%s: array missing or too small", syminput->s_name); + return; + } + if (arraysize < npts) + { + error("sigmund~: too few points in array"); + return; + } + sigmund_doit(x, npts, arraypoints+onset, loud, srate); +} + +static void sigmund_clear(t_sigmund *x) +{ + if (x->x_trackv) + memset(x->x_trackv, 0, x->x_ntrack * sizeof(*x->x_trackv)); + x->x_infill = x->x_countdown = 0; +} + + /* these are for testing; their meanings vary... */ +static void sigmund_param1(t_sigmund *x, t_floatarg f) +{ + x->x_param1 = f; +} + +static void sigmund_param2(t_sigmund *x, t_floatarg f) +{ + x->x_param2 = f; +} + +static void sigmund_param3(t_sigmund *x, t_floatarg f) +{ + x->x_param3 = f; +} + +static void sigmund_npts(t_sigmund *x, t_floatarg f) +{ + x->x_npts = f; + /* check parameter ranges */ + if (x->x_npts < NPOINTS_MIN) + post("sigmund~: minimum points %d", NPOINTS_MIN), + x->x_npts = NPOINTS_MIN; + if (x->x_npts != (1 << sigmund_ilog2(x->x_npts))) + post("sigmund~: adjusting analysis size to %d points", + (x->x_npts = (1 << sigmund_ilog2(x->x_npts)))); +} + +static void sigmund_hop(t_sigmund *x, t_floatarg f) +{ + x->x_hop = f; + /* check parameter ranges */ + if (x->x_hop != (1 << sigmund_ilog2(x->x_hop))) + post("sigmund~: adjusting analysis size to %d points", + (x->x_hop = (1 << sigmund_ilog2(x->x_hop)))); +} + +static void sigmund_npeak(t_sigmund *x, t_floatarg f) +{ + if (f < 1) + f = 1; + x->x_npeak = f; +} + +static void sigmund_maxfreq(t_sigmund *x, t_floatarg f) +{ + x->x_maxfreq = f; +} + +static void sigmund_vibrato(t_sigmund *x, t_floatarg f) +{ + if (f < 0) + f = 0; + x->x_vibrato = f; +} + +static void sigmund_stabletime(t_sigmund *x, t_floatarg f) +{ + if (f < 0) + f = 0; + x->x_stabletime = f; +} + +static void sigmund_growth(t_sigmund *x, t_floatarg f) +{ + if (f < 0) + f = 0; + x->x_growth = f; +} + +static void sigmund_minpower(t_sigmund *x, t_floatarg f) +{ + if (f < 0) + f = 0; + x->x_minpower = f; +} + +static void sigmund_print(t_sigmund *x) +{ + post("sigmund~ settings:"); + post("npts %d", (int)x->x_npts); + post("hop %d", (int)x->x_hop); + post("npeak %d", (int)x->x_npeak); + post("maxfreq %g", x->x_maxfreq); + post("vibrato %g", x->x_vibrato); + post("stabletime %g", x->x_stabletime); + post("growth %g", x->x_growth); + post("minpower %g", x->x_minpower); +} + +static void sigmund_printnext(t_sigmund *x, t_float f) +{ + x->x_loud = f; +} + +static void sigmund_clock(t_sigmund *x) +{ + if (x->x_infill == x->x_npts) + { + sigmund_doit(x, x->x_npts, x->x_inbuf, x->x_loud, x->x_sr); + if (x->x_hop >= x->x_npts) + { + x->x_infill = 0; + x->x_countdown = x->x_hop - x->x_npts; + } + else + { + memmove(x->x_inbuf, x->x_inbuf + x->x_hop, + (x->x_infill = x->x_npts - x->x_hop) * sizeof(*x->x_inbuf)); + x->x_countdown = 0; + } + x->x_loud = 0; + } +} + +static t_int *sigmund_perform(t_int *w) +{ + t_sigmund *x = (t_sigmund *)(w[1]); + float *in = (float *)(w[2]); + int n = (int)(w[3]); + + if (x->x_countdown > 0) + x->x_countdown -= n; + else if (x->x_infill != x->x_npts) + { + int i, j; + float *fp = x->x_inbuf + x->x_infill; + for (j = 0; j < n; j++) + *fp++ = *in++; + x->x_infill += n; + if (x->x_infill == x->x_npts) + clock_delay(x->x_clock, 0); + } + return (w+4); +} + +static void sigmund_dsp(t_sigmund *x, t_signal **sp) +{ + if (x->x_mode == MODE_STREAM) + { + if (x->x_hop % sp[0]->s_n) + post("sigmund: adjusting hop size to %d", + (x->x_hop = sp[0]->s_n * (x->x_hop / sp[0]->s_n))); + x->x_sr = sp[0]->s_sr; + dsp_add(sigmund_perform, 3, x, sp[0]->s_vec, sp[0]->s_n); + } +} + +static void sigmund_free(t_sigmund *x) +{ + if (x->x_inbuf) + freebytes(x->x_inbuf, x->x_npts * sizeof(*x->x_inbuf)); + if (x->x_trackv) + freebytes(x->x_trackv, x->x_ntrack * sizeof(*x->x_trackv)); + clock_free(x->x_clock); +} + +void sigmund_tilde_setup(void) +{ + sigmund_class = class_new(gensym("sigmund~"), (t_newmethod)sigmund_new, + (t_method)sigmund_free, sizeof(t_sigmund), 0, A_GIMME, 0); + class_addlist(sigmund_class, sigmund_list); + class_addmethod(sigmund_class, (t_method)sigmund_dsp, gensym("dsp"), 0); + CLASS_MAINSIGNALIN(sigmund_class, t_sigmund, x_f); + class_addmethod(sigmund_class, (t_method)sigmund_param1, + gensym("param1"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_param2, + gensym("param2"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_param3, + gensym("param3"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_npts, + gensym("npts"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_hop, + gensym("hop"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_maxfreq, + gensym("maxfreq"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_npeak, + gensym("npeak"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_vibrato, + gensym("vibrato"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_stabletime, + gensym("stabletime"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_growth, + gensym("growth"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_minpower, + gensym("minpower"), A_FLOAT, 0); + class_addmethod(sigmund_class, (t_method)sigmund_print, + gensym("print"), 0); + class_addmethod(sigmund_class, (t_method)sigmund_printnext, + gensym("printnext"), A_FLOAT, 0); + post("sigmund version 0.02"); +} + |