Datasets:

dhuck
/

faust_code

Modalities:

Text

Formats:

Size:

Libraries:

Dataset card Viewer Files Files and versions Community

Dataset Viewer

Auto-converted to Parquet

Full Screen Viewer

Full Screen

Split (1)

train · 4.22k rows

_id stringlengths 64 64	repository stringlengths 7 61	name stringlengths 5 45	content stringlengths 0 943k	download_url stringlengths 94 213	language stringclasses 1 value	comments stringlengths 0 20.9k	code stringlengths 0 943k
3828b2cddb5f7c7092cbd4eb9e7181024d1ac83176899f5754613c2e203197db	knisterpapier/esp32a1s-audio-concept	coresignal.dsp	//import("stdfaust.lib"); //process = dm.zita_rev_fdn_demo; //other reverb algorythm import("stdfaust.lib"); //process = dm.fdnrev0_demo(4,3,1); process = dm.stereo_reverb_tester; // own delay //import("stdfaust.lib"); //own_delay = hslider("own_delay",15000,2000,20000,500); //dry_wet = hslider("dry_wet",0.5,0,1,0.1); //process = + <: +~@(own_delay)0.5(dry_wet),(1-dry_wet):> +; //simple pipeline //import ("stdfaust.lib"); //process = +; // own reverbarator // A = hslider("label",0.5,0.1,0.9,0.05); // B = hslider("delay",15000,2000,20000,500); // process = + : (+<:@(B),(A))~*(A) : +;	https://raw.githubusercontent.com/knisterpapier/esp32a1s-audio-concept/b7024f01bd90801e0ca86dc694f26af186c1aed3/src/coresignal.dsp	faust	import("stdfaust.lib"); process = dm.zita_rev_fdn_demo; other reverb algorythm process = dm.fdnrev0_demo(4,3,1); own delay import("stdfaust.lib"); own_delay = hslider("own_delay",15000,2000,20000,500); dry_wet = hslider("dry_wet",0.5,0,1,0.1); process = + <: +~@(own_delay)0.5(dry_wet),(1-dry_wet):> +; simple pipeline import ("stdfaust.lib"); process = +; own reverbarator A = hslider("label",0.5,0.1,0.9,0.05); B = hslider("delay",15000,2000,20000,500); process = + : (+<:@(B),(A))~*(A) : +;	import("stdfaust.lib"); process = dm.stereo_reverb_tester;
b5fce45e29dd683e058a2531a6019252e1008f1c3913fb2e4c39098381d6b9bb	rasmusnuko/FaustCode	onePoll_letrec.dsp	import("stdfaust.lib"); onePoll(a1, x) = y letrec{ 'y = x + y*a1; }; process = onePoll(0.999);import("stdfaust.lib");	https://raw.githubusercontent.com/rasmusnuko/FaustCode/f58d7a5d35d28a644e73903ab530fcdce314dfd6/onePoll_letrec.dsp	faust		import("stdfaust.lib"); onePoll(a1, x) = y letrec{ 'y = x + y*a1; }; process = onePoll(0.999);import("stdfaust.lib");
c0aec1f6705c5c96bca7ee5230c0518aa6fc097e95c6fa9850cf410ba8c5d562	tomara-x/magi	2022-09-02.dsp	//trans rights /* import("stdfaust.lib"); freq0 = os.osc(880)880; freq2 = 440; gain0 = 0.1; gain2 = 0.1; process = os.osc(freq0)gain0, os.osc(freq2)gain2 :> _ // merging signals here <: dm.zita_light; // and then splitting them for stereo in / /* import("stdfaust.lib"); carrierFreq = 400; modulatorFreq = 110; index = 0.1; process = os.osc(carrierFreq+os.osc(modulatorFreq)index) <: dm.zita_light; / /* import("stdfaust.lib"); random = +(12345) ~ (1103515245); process = random : aa.clip(-1,1)0.1; / / import("stdfaust.lib"); process = dm.cubicnl_demo : // distortion dm.wah4_demo <: // wah pedal dm.phaser2_demo : // stereo phaser dm.compressor_demo : // stereo compressor dm.zita_light; // stereo reverb / / import("stdfaust.lib"); freq = hslider("[2]frq", 440, 20, 4408, 1); res = hslider("[3]res", 0, -1, 1, 0.01); gate = button("[1]gate"); string(frequency,resonance,trigger) = trigger : ba.impulsify : fi.fb_fcomb(1024,del,1,resonance) with { del = ma.SR/frequency; }; process = string(freq,res,gate) <: _,_; / //study import("stdfaust.lib"); freqMod = hslider("h:Modulator/Frequency", 777, 20, 15000, 1) : si.smoo; modIndex = hslider("h:Modulator/Modulation Index", 1000, 0, 10000, 1) : si.smoo; freq = hslider("h:General Parameters/freq", 440, 20, 8000, 1) : si.smoo; gain = hslider("gain", 1, 0, 1, 0.01) : si.smoo; gate = button("gate") : si.smoo; process = vgroup("FMsynth [style:keyboard]",os.osc(freqMod)modIndex + freq : os.oscgate*gain <: _,_);	https://raw.githubusercontent.com/tomara-x/magi/bcf22a4ef23899cd8ce3bf5e08e374994907f81a/practice/2022-09-02.dsp	faust	trans rights import("stdfaust.lib"); freq0 = os.osc(880)880; freq2 = 440; gain0 = 0.1; gain2 = 0.1; process = os.osc(freq0)gain0, os.osc(freq2)gain2 :> _ // merging signals here <: dm.zita_light; // and then splitting them for stereo in import("stdfaust.lib"); carrierFreq = 400; modulatorFreq = 110; index = 0.1; process = os.osc(carrierFreq+os.osc(modulatorFreq)index) <: dm.zita_light; import("stdfaust.lib"); random = +(12345) ~ (1103515245); process = random : aa.clip(-1,1)0.1; import("stdfaust.lib"); process = dm.cubicnl_demo : // distortion dm.wah4_demo <: // wah pedal dm.phaser2_demo : // stereo phaser dm.compressor_demo : // stereo compressor dm.zita_light; // stereo reverb import("stdfaust.lib"); freq = hslider("[2]frq", 440, 20, 440*8, 1); res = hslider("[3]res", 0, -1, 1, 0.01); gate = button("[1]gate"); string(frequency,resonance,trigger) = trigger : ba.impulsify : fi.fb_fcomb(1024,del,1,resonance) with { del = ma.SR/frequency; }; process = string(freq,res,gate) <: _,_; study	import("stdfaust.lib"); freqMod = hslider("h:Modulator/Frequency", 777, 20, 15000, 1) : si.smoo; modIndex = hslider("h:Modulator/Modulation Index", 1000, 0, 10000, 1) : si.smoo; freq = hslider("h:General Parameters/freq", 440, 20, 8000, 1) : si.smoo; gain = hslider("gain", 1, 0, 1, 0.01) : si.smoo; gate = button("gate") : si.smoo; process = vgroup("FMsynth [style:keyboard]",os.osc(freqMod)modIndex + freq : os.oscgate*gain <: _,_);
86de6b37f2a183c2137e72944fdb4d8f7c02384da52873e36e6968c3cea68875	FarayMecatronico/devin	IPlugFaustDSP.dsp	// declare options "[midi:on][nvoices:12]"; // declare name "IPlugFaustDSP (polydsp synth example)"; // import("stdfaust.lib"); // freq = hslider("freq ",200,50,1000,0.01); // gain = hslider("gain",0.5,0,1,0.01); // master = hslider("master [midi: ctrl 7]",0.5,0,1,0.01); // gate = button("gate"); // envelope = en.adsr(0.01,0.01,0.8,0.1,gate)gain; // process = os.sawtooth(freq)envelopemaster <: (_,_); declare name "IPlugFaustDSP (mono example)"; import("stdfaust.lib"); g = vslider("[1]Gain", 0, 0., 1, 0.1); f1 = vslider("[2]Freq1", 440, 100., 1000, 0.1); f2 = vslider("[3]Freq2", 441, 100., 1000, 0.1); process = os.osc(f1) g, os.osc(f2) * g;	https://raw.githubusercontent.com/FarayMecatronico/devin/89a233f26291e059f2fcb505e8f1a87329ef5579/Examples/IPlugFaustDSP/IPlugFaustDSP.dsp	faust	declare options "[midi:on][nvoices:12]"; declare name "IPlugFaustDSP (polydsp synth example)"; import("stdfaust.lib"); freq = hslider("freq ",200,50,1000,0.01); gain = hslider("gain",0.5,0,1,0.01); master = hslider("master [midi: ctrl 7]",0.5,0,1,0.01); gate = button("gate"); envelope = en.adsr(0.01,0.01,0.8,0.1,gate)gain; process = os.sawtooth(freq)envelope*master <: (_,_);	declare name "IPlugFaustDSP (mono example)"; import("stdfaust.lib"); g = vslider("[1]Gain", 0, 0., 1, 0.1); f1 = vslider("[2]Freq1", 440, 100., 1000, 0.1); f2 = vslider("[3]Freq2", 441, 100., 1000, 0.1); process = os.osc(f1) * g, os.osc(f2) * g;
86af9c3d1c3ba23ad7746c1eb7f8082cbb7492ba54b551764e592d8d92b34d02	JaoRamos/Faust	clase4.dsp	/* import("stdfaust.lib"); parteDecimal(x) = x - int(x); fase(f) = f/ma.SR : (+ : parteDecimal) ~ _; senialCuadrada(f) = fase(f) > 0.9125; ondaCuadrada(f) = ((senialCuadrada(f)) * 2) - 1; process = ondaCuadrada(220) * 0.2; / / import("stdfaust.lib"); parteDecimal(x) = x - int(x); fase = numeroSuma : (+ : parteDecimal) ~ _; frecuencia = hslider("frec", 220, 60, 880, 0.01); numeroSuma = frecuencia / ma.SR; process = ((fase2)-1) 0.2; / / import("stdfaust.lib"); parteDecimal(x) = x - int(x); rampa = 0.005 : + ~ _; // A ~ A fase = parteDecimal(rampa)(ma.PI0.7); process = sin(fase)0.5; /	https://raw.githubusercontent.com/JaoRamos/Faust/60093b31029fa157f16055590ff188f6b19aeb89/unq/Clase_4/clase4.dsp	faust	import("stdfaust.lib"); parteDecimal(x) = x - int(x); fase(f) = f/ma.SR : (+ : parteDecimal) ~ _; senialCuadrada(f) = fase(f) > 0.9125; ondaCuadrada(f) = ((senialCuadrada(f)) * 2) - 1; process = ondaCuadrada(220) * 0.2; import("stdfaust.lib"); parteDecimal(x) = x - int(x); fase = numeroSuma : (+ : parteDecimal) ~ _; frecuencia = hslider("frec", 220, 60, 880, 0.01); numeroSuma = frecuencia / ma.SR; process = ((fase2)-1) 0.2; import("stdfaust.lib"); parteDecimal(x) = x - int(x); rampa = 0.005 : + ~ _; // A ~ A fase = parteDecimal(rampa)(ma.PI0.7); process = sin(fase)*0.5;
2c75f6838f24863b1838c1357a7b8277270f762694256c2375a036745a13b9db	JaoRamos/Faust	Clase_5.dsp	/* import("stdfaust.lib"); // les damos otro nombre para que sean mas faciles de leer sampleRate = ma.SR; pi = ma.PI; // el generador de fase de siempre partedecimal(x) = x - int(x); fase(frec) = frec/sampleRate : (+ : partedecimal) ~ _; // onda senoidal a partir de funcion seno senoidal(frecuencia) = sin(fase(frecuencia) * 2 * pi); frec = 500; sierra = (senoidal(1 * frec)1) + (senoidal(2 frec)/2.0) + (senoidal(3 * frec)/3.0) + (senoidal(4 * frec)/4.0) + (senoidal(5 * frec)/5.0); process = sierra * 0.3; / / import("stdfaust.lib"); volumen = hslider("-volumen-", 0.05, 0, 1, 0.01); fundamental = hslider("-frecuencia-", 80, 20, 2000, 10); // oscilador de cada parcial, será duplicado por sum() parcial(indiceParcial, frecFundamental) = os.osc(frecFundamental * indiceParcial) * hslider("%indiceParcial Parcial", 1 / indiceParcial, 0, 1, 0.01); // duplicamos el oscilador 10 veces para tener 10 parciales, probar que pasa con mas! generador = sum(numParcial, 30, parcial(numParcial + 1, fundamental) ) * volumen; process = generador, generador; / / import("stdfaust.lib"); volumen = hslider("-volumen-", 0.05, 0, 1, 0.01); fundamental = hslider("-frecuencia-", 80, 20, 2000, 10); // oscilador de cada parcial, será duplicado por sum() parcial(indiceParcial, frecFundamental) = os.osc(frecFundamental * indiceParcial) * hslider("%indiceParcial Parcial", 1 / indiceParcial, 0, 1, 0.01); // duplicamos el oscilador 10 veces para tener 10 parciales, probar que pasa con mas! cuadrada = sum(numParcial, 10, parcial((numParcial2) + 1, fundamental) ) volumen; process = cuadrada, cuadrada; / // UNA - "La" voz import("stdfaust.lib"); // faust reconoce estos labels // los mapea desde el controlador externo // "gate" si hay una nota encendida o no // "freq" me dice la frecuencia de la nota recibida // "gain" velocity midi (0-1) sonar = button("gate"); frecuencia = nentry("freq", 200, 50, 2000, 0.001); velocity = nentry("gain", 0, 0, 1, 0.001); volumen = hslider("-volumen-", 0.5, 0, 1, 0.01); // tiempos en segundos // adsr(at,dt,sl,rt, gate) // t t n t envolvente = en.adsr(0.02, 0.01, 0.5, 0.5, sonar); parcial(indiceParcial, frecFundamental) = os.osc(frecFundamental indiceParcial) * hslider("%indiceParcial Parcial", 1 / indiceParcial, 0, 1, 0.01); // duplicamos el oscilador 10 veces para tener 10 parciales, probar que pasa con mas! //mod = os.osc(10) * hslider("modulacion", 0, 0, 1, 0.01) + 1; cuadrada = sum(numParcial, 40, parcial((numParcial2) + 1, frecuencia) ) volumen * velocity;// * mod; process = cuadradaenvolvente0.5, cuadradaenvolvente0.5;	https://raw.githubusercontent.com/JaoRamos/Faust/60093b31029fa157f16055590ff188f6b19aeb89/unq/Clase_5/Clase_5.dsp	faust	import("stdfaust.lib"); // les damos otro nombre para que sean mas faciles de leer sampleRate = ma.SR; pi = ma.PI; // el generador de fase de siempre partedecimal(x) = x - int(x); fase(frec) = frec/sampleRate : (+ : partedecimal) ~ _; // onda senoidal a partir de funcion seno senoidal(frecuencia) = sin(fase(frecuencia) * 2 * pi); frec = 500; sierra = (senoidal(1 * frec)1) + (senoidal(2 frec)/2.0) + (senoidal(3 * frec)/3.0) + (senoidal(4 * frec)/4.0) + (senoidal(5 * frec)/5.0); process = sierra * 0.3; import("stdfaust.lib"); volumen = hslider("-volumen-", 0.05, 0, 1, 0.01); fundamental = hslider("-frecuencia-", 80, 20, 2000, 10); // oscilador de cada parcial, será duplicado por sum() parcial(indiceParcial, frecFundamental) = os.osc(frecFundamental * indiceParcial) * hslider("%indiceParcial Parcial", 1 / indiceParcial, 0, 1, 0.01); // duplicamos el oscilador 10 veces para tener 10 parciales, probar que pasa con mas! generador = sum(numParcial, 30, parcial(numParcial + 1, fundamental) ) * volumen; process = generador, generador; import("stdfaust.lib"); volumen = hslider("-volumen-", 0.05, 0, 1, 0.01); fundamental = hslider("-frecuencia-", 80, 20, 2000, 10); // oscilador de cada parcial, será duplicado por sum() parcial(indiceParcial, frecFundamental) = os.osc(frecFundamental * indiceParcial) * hslider("%indiceParcial Parcial", 1 / indiceParcial, 0, 1, 0.01); // duplicamos el oscilador 10 veces para tener 10 parciales, probar que pasa con mas! cuadrada = sum(numParcial, 10, parcial((numParcial2) + 1, fundamental) ) volumen; process = cuadrada, cuadrada; UNA - "La" voz faust reconoce estos labels los mapea desde el controlador externo "gate" si hay una nota encendida o no "freq" me dice la frecuencia de la nota recibida "gain" velocity midi (0-1) tiempos en segundos adsr(at,dt,sl,rt, gate) t t n t duplicamos el oscilador 10 veces para tener 10 parciales, probar que pasa con mas! mod = os.osc(10) * hslider("modulacion", 0, 0, 1, 0.01) + 1; * mod;	import("stdfaust.lib"); sonar = button("gate"); frecuencia = nentry("freq", 200, 50, 2000, 0.001); velocity = nentry("gain", 0, 0, 1, 0.001); volumen = hslider("-volumen-", 0.5, 0, 1, 0.01); envolvente = en.adsr(0.02, 0.01, 0.5, 0.5, sonar); parcial(indiceParcial, frecFundamental) = os.osc(frecFundamental * indiceParcial) * hslider("%indiceParcial Parcial", 1 / indiceParcial, 0, 1, 0.01); process = cuadradaenvolvente0.5, cuadradaenvolvente0.5;
e719291c66d809adcaefa409d8bf1f84564f8e13c9e4cb5dee2bb71bd0bea24e	tomara-x/magi	days2-5.dsp	//doodles and examples from the manual //for sentimental reasons //delay 2 seconds //process = no.noise0.1 : @(ma.SR2); //process = +(1,3); //prefex //process = 1,3 : +; //core //process = 1+3; //infix //foreign constant (fvariable, ffunction) //sr = fconstant(int fSamplingFreq, <math.h>); //can those be returned by functions? //struct = environment { // m = -1; // n = 1; //}; //can be inlined //environment{m = -1; n = 1;}.m; // -1 //N = 10; //process = route(N,N,par(i,N,(i+1,N-i))); //process = 1,1 : + : _,1 : +; //process = +(1,(+(1,1))); //import("stdfaust.lib"); //add1 = +(1); //add2 = +(2); //add3 = +(3); //mute = (0); //process = add2~add1 : mute; // any diff between those? //process = add1~_ : out; //process = _~add1 : out; //import("stdfaust.lib"); //filter = +~(0.9); //process = no.no.noise0.01 : filter; //process = 135 : ba.beat; //clock //process = 60 : ba.beat; //eq import("stdfaust.lib"); nBands = 8; filterBank(N) = hgroup("Filter Bank",seq(i,N,oneBand(i))) with { oneBand(j) = vgroup("[%j]Band %a",fi.peak_eq(l,f,b)) with { a = j+1; // just so that band numbers don't start at 0 l = vslider("[2]Level[unit:db]",0,-70,12,0.01) : si.smoo; f = nentry("[1]Freq",(80+(10008/N(j+1)-80)),20,20000,0.01) : si.smoo; b = f/hslider("[0]Q[style:knob]",1,1,50,0.01) : si.smoo; }; }; process = no.noise0.01 : filterBank(nBands) <: _,_; //additive synth with par iteration import("stdfaust.lib"); freq = hslider("freq",440,50,3000,0.01); gain = hslider("gain",1,0,1,0.01); gate = button("gate"); envelope = gaingate : si.smoo; nHarmonics = 4; process = par(i,nHarmonics,os.osc(freq(i+1))) :> /(nHarmonics)envelope; //mute = (0); //process = par(j,4,par(i,2,i:mute)); //am with prod iteration import("stdfaust.lib"); freq = hslider("[0]freq",440,50,3000,0.01); gain = hslider("[1]gain",1,0,1,0.01); shift = hslider("[2]shift",0,0,1,0.01); gate = button("[3]gate"); envelope = gaingate : si.smoo; nOscs = 16; process = prod(i,nOscs,os.osc(freq(i+1+shift)))*envelope;	https://raw.githubusercontent.com/tomara-x/magi/bcf22a4ef23899cd8ce3bf5e08e374994907f81a/practice/days2-5.dsp	faust	doodles and examples from the manual for sentimental reasons delay 2 seconds process = no.noise0.1 : @(ma.SR2); process = +(1,3); //prefex process = 1,3 : +; //core process = 1+3; //infix foreign constant (fvariable, ffunction) sr = fconstant(int fSamplingFreq, <math.h>); can those be returned by functions? struct = environment { m = -1; n = 1; }; can be inlined environment{m = -1; n = 1;}.m; // -1 N = 10; process = route(N,N,par(i,N,(i+1,N-i))); process = 1,1 : + : _,1 : +; process = +(1,(+(1,1))); import("stdfaust.lib"); add1 = +(1); add2 = +(2); add3 = +(3); mute = (0); process = add2~add1 : mute; any diff between those? process = add1~_ : out; process = _~add1 : out; import("stdfaust.lib"); filter = +~(0.9); process = no.no.noise0.01 : filter; process = 135 : ba.beat; clock process = 60 : ba.beat; eq just so that band numbers don't start at 0 additive synth with par iteration mute = (0); process = par(j,4,par(i,2,i:mute)); am with prod iteration	import("stdfaust.lib"); nBands = 8; filterBank(N) = hgroup("Filter Bank",seq(i,N,oneBand(i))) with { oneBand(j) = vgroup("[%j]Band %a",fi.peak_eq(l,f,b)) with { l = vslider("[2]Level[unit:db]",0,-70,12,0.01) : si.smoo; f = nentry("[1]Freq",(80+(10008/N(j+1)-80)),20,20000,0.01) : si.smoo; b = f/hslider("[0]Q[style:knob]",1,1,50,0.01) : si.smoo; }; }; process = no.noise0.01 : filterBank(nBands) <: _,_; import("stdfaust.lib"); freq = hslider("freq",440,50,3000,0.01); gain = hslider("gain",1,0,1,0.01); gate = button("gate"); envelope = gaingate : si.smoo; nHarmonics = 4; process = par(i,nHarmonics,os.osc(freq(i+1))) :> /(nHarmonics)envelope; import("stdfaust.lib"); freq = hslider("[0]freq",440,50,3000,0.01); gain = hslider("[1]gain",1,0,1,0.01); shift = hslider("[2]shift",0,0,1,0.01); gate = button("[3]gate"); envelope = gaingate : si.smoo; nOscs = 16; process = prod(i,nOscs,os.osc(freq(i+1+shift)))*envelope;
932cc1ce36498fe441272dbf47e9a51d661b679fa8c54b5d664a7e589a12dfd5	arthtyagi/faustfun	reverb1.dsp	import("stdfaust.lib"); process = ba.pulsen(1, 10000) : pm.djembe(60, 0.3, 0.4, 1) <: dm.freeverb_demo;	https://raw.githubusercontent.com/arthtyagi/faustfun/8092e270861907df91f1c4d4a3c31f2cca0b4d16/reverb1.dsp	faust		import("stdfaust.lib"); process = ba.pulsen(1, 10000) : pm.djembe(60, 0.3, 0.4, 1) <: dm.freeverb_demo;
99d30cb378be3fe911a5730bafdda8ceabf7639a336cfce36556c578075d3ca9	jpcima/jest	new_faust.dsp	import("stdfaust.lib"); process = _;	https://raw.githubusercontent.com/jpcima/jest/f16cde58edb9470b2422b522a24d1f6916c5cae1/resources/templates/new_faust.dsp	faust		import("stdfaust.lib"); process = _;
0b65ae533862571a41a7f51f5b9cea0df5ec0b88d03610c1f344c9756d427d86	clearly-broken-software/Uprising	lpFilter.dsp	import("stdfaust.lib"); lpFilter= fi.resonlp(lpfCuttoff,lpfQ,lpfGain); lpfCuttoff = hslider("lpfCuttoff",20000,0,20000,0.1); lpfQ = hslider("lpQ",1,0,20,0.1); lpfGain = hslider("filterGain",1,0,1,0.01); process = lpFilter;import("stdfaust.lib");	https://raw.githubusercontent.com/clearly-broken-software/Uprising/89f5b49d90cd47611da7e7dc2009061768716b4c/plugins/uprising/dsp/faust/lpFilter.dsp	faust		import("stdfaust.lib"); lpFilter= fi.resonlp(lpfCuttoff,lpfQ,lpfGain); lpfCuttoff = hslider("lpfCuttoff",20000,0,20000,0.1); lpfQ = hslider("lpQ",1,0,20,0.1); lpfGain = hslider("filterGain",1,0,1,0.01); process = lpFilter;import("stdfaust.lib");
38ce472a13a559fc627a8ea800288e5491705b34a076085d4f55d4f751913c21	publicsamples/Scriptnode-Tests	granular.dsp	// Faust Source File: granular // Created with HISE on 2023-03-04 import("stdfaust.lib"); process = _, _;	https://raw.githubusercontent.com/publicsamples/Scriptnode-Tests/a4ffde4a88cdc9001cb1b206287c59d0bb546d0b/DspNetworks/CodeLibrary/faust/granular.dsp	faust	Faust Source File: granular Created with HISE on 2023-03-04	import("stdfaust.lib"); process = _, _;
9d6afe513195574e6779566e4497abda85d9ca81eb65c7c43d0cd14067f96d19	potatosalad775/flutter_faust_example	main.dsp	import("stdfaust.lib"); gate = button("gate") : si.smoo; gain = hslider("gain", 1, 0, 1, 0.01); process = os.sawtooth(440) * gate * gain <: _,_;	https://raw.githubusercontent.com/potatosalad775/flutter_faust_example/3093f1cc34eb729f8df65f50ccfb3d32902c7c8d/DSP/main.dsp	faust		import("stdfaust.lib"); gate = button("gate") : si.smoo; gain = hslider("gain", 1, 0, 1, 0.01); process = os.sawtooth(440) * gate * gain <: _,_;
549ade4a228993d15e6057d7bf95972fa79c14f1e34233a1fcf2d7d759f3fb0d	oshibka404/faust_flutter	main.dsp	import("stdfaust.lib"); gate = button("gate") : si.smoo; process = os.sawtooth(440) * gate <: _,_;	https://raw.githubusercontent.com/oshibka404/faust_flutter/30b674011ed6092a199bf7f548d647505631ee65/DSP/main.dsp	faust		import("stdfaust.lib"); gate = button("gate") : si.smoo; process = os.sawtooth(440) * gate <: _,_;
b4efed7539d8809385e021a81e70ec5776e2105ac8ad7111e564bf6a2a43039f	clearly-broken-software/Uprising	scratchpad.dsp	import("stdfaust.lib"); gate = abs(button("gate")-1); ramp(timeInSeconds,start,end,rgate) = up with{ rs1 = timeInSeconds * ma.SR; up = ba.countup(rs1,rgate) : ba.bpf.start(0,start) : ba.bpf.end(rs1,end); }; myFilter = fi.resonbp(fc,q,gain) with{ fc = ramp(5,20,2000,gate); q = hslider("q",20,1,20,0.01); gain = hslider("gain",0.5,0,1,0.01); }; process = no.noise:myFilter; import("stdfaust.lib"); gate = 1-button("gate"); startFreq = 880; endFreq = 220; length = ma.SR * 4; counter = ba.countup(length,gate): ba.bpf.start(0,startFreq) : ba.bpf.end(length,endFreq); index = 1; dataPoints = (0,100,100,100); process = os.osc(counter); up = ba.countup(rs1,rgate) : ba.bpf.start(0,start) : ba.bpf.end(rs1,end); ////////////// import("stdfaust.lib"); gate = 1-button("gate"); // general purpose ramp env(sFreq,eFreq,len) = urRamp with { urRamp = ba.countup(len,gate): ba.bpf.start(0,sFreq): ba.bpf.end(len,eFreq); }; sineStartFreq = hslider("sineStartFreq", 100, 20, 20000,0.01); sineEndFreq = hslider("sineEndFreq", 100, 20, 20000, 0.01); bufferSize = hslider("bufferSize", 512, 1, 2 * 44100,1); pitchRamp = env(sineStartFreq,sineEndFreq,bufferSize); // lfo lfoStartFreq = hslider("lfoStartFreq", 6, 0.001, 15, 0.001); lfoEndFreq = hslider("lfoEndFreq", 6, 0.001, 15, 0.001); lfoStartDepth = hslider("lfoStartDepth", 1, 0,1, 0.001); lfoEndDepth = hslider("lfoEndDepth", 1, 0,1, 0.001); lfoPitchRamp = env(lfoStartFreq,lfoEndFreq,bufferSize); lfoDepthRamp = env(lfoStartDepth,lfoEndDepth,bufferSize); LFO = os.lf_triangle(lfoPitchRamp)lfoDepthRamp20; allFreq = pitchRamp + LFO; oscAmp = hslider("oscAmp", 0.5, 0, 1, 0.001):si.smoo; sineOsc = os.osc(allFreq)oscAmp; process = sineOsc; /// import("stdfaust.lib"); gate = 1-button("gate"); // general purpose ramp env(start,end,len) = urRamp with { urRamp = ba.countup(len,gate): ba.bpf.start(0,start): ba.bpf.end(len,end);//:si.smoo; }; // sine oscilator sineStartFreq = hslider("sineStartFreq", 440, 20, 20000,0.01); sineEndFreq = hslider("sineEndFreq", 440, 20, 20000, 0.01); bufferSize = hslider("bufferSize", 1024, 1, 2 44100,1); sineStartGain = hslider("sineStartGain", 1, 0, 1, 0.001); sineEndGain = hslider("sineEndGain",1,0,1,0.001); sineAmp = env(sineStartGain,sineEndGain,bufferSize); sinePitchRamp = env(sineStartFreq,sineEndFreq,bufferSize); sineFreq = sinePitchRamp + LFO; sineOsc = os.osc(sineFreq)sineAmp; // lfo lfoStartFreq = hslider("lfoStartFreq", 6, 0.001, 15, 0.001); lfoEndFreq = hslider("lfoEndFreq", 6, 0.001, 15, 0.001); lfoStartDepth = hslider("lfoStartDepth", 0, 0,1, 0.001); lfoEndDepth = hslider("lfoEndDepth", 0, 0,1, 0.001); lfoPitchRamp = env(lfoStartFreq,lfoEndFreq,bufferSize); lfoDepthRamp = env(lfoStartDepth,lfoEndDepth,bufferSize); LFO = os.lf_triangle(lfoPitchRamp)lfoDepthRamp20; process = sineOsc; /////////////////////////////////////// import("stdfaust.lib"); // constant power panning ; reference The Audio Programming Book p.236 piOver2 = ma.PI/2; root2over2 = (2 : sqrt) 0.5; angle = pan * piOver2 * 0.5; posLeft = root2over2 * (cos(angle) - sin(angle)); posRight = root2over2 * (cos(angle) + sin(angle)); panStartPos = hslider("panStartPosition",0,-1,1,0.001); panEndPos = hslider("panEndPosition", 0,-1,1,0.001); pan = env(panStartPos,panEndPos,bufferSize); gate = 1-button("gate"); // starts the ramp envelope // general purpose ramp envelope env(start,end,len) = urRamp with { urRamp = ba.countup(len,gate): ba.bpf.start(0,start): ba.bpf.end(len,end);//:si.smoo; }; // sine oscilator sineStartFreq = hslider("sineStartFreq", 440, 20, 20000,0.01); sineEndFreq = hslider("sineEndFreq", 440, 20, 20000, 0.01); bufferSize = hslider("bufferSize", 1024, 1, 2 * 44100,1); sineStartGain = hslider("sineStartGain", 1, 0, 1, 0.001); sineEndGain = hslider("sineEndGain",1,0,1,0.001); sineAmp = env(sineStartGain,sineEndGain,bufferSize); sinePitchRamp = env(sineStartFreq,sineEndFreq,bufferSize); sineFreq = sinePitchRamp + LFO; sineOsc = os.osc(sineFreq)sineAmp; // lfo lfoStartFreq = hslider("lfoStartFreq", 6, 0.001, 15, 0.001); lfoEndFreq = hslider("lfoEndFreq", 6, 0.001, 15, 0.001); lfoStartDepth = hslider("lfoStartDepth", 0, 0,1, 0.001); lfoEndDepth = hslider("lfoEndDepth", 0, 0,1, 0.001); lfoPitchRamp = env(lfoStartFreq,lfoEndFreq,bufferSize); lfoDepthRamp = env(lfoStartDepth,lfoEndDepth,bufferSize); LFO = os.lf_triangle(lfoPitchRamp)lfoDepthRamp20; process = sineOsc<:_posLeft,_posRight; // import("stdfaust.lib"); // constant power panning ; reference The Audio Programming Book p.236 piOver2 = ma.PI/2; root2over2 = (2 : sqrt) 0.5; angle = pan * piOver2 * 0.5; posLeft = root2over2 * (cos(angle) - sin(angle)); posRight = root2over2 * (cos(angle) + sin(angle)); panStartPos = hslider("panStartPosition",0,-1,1,0.001); panEndPos = hslider("panEndPosition", 0,-1,1,0.001); pan = env(panStartPos,panEndPos,bufferSize); gate = 1-button("gate"); // starts the ramp envelope // general purpose ramp envelope env(start,end,len) = urRamp with { urRamp = ba.countup(len,gate): ba.bpf.start(0,start): ba.bpf.end(len,end);//:si.smoo; }; // sine oscilator sineStartFreq = hslider("sineStartFreq", 440, 20, 20000,0.01); sineEndFreq = hslider("sineEndFreq", 440, 20, 20000, 0.01); bufferSize = hslider("bufferSize", 1024, 1, 2 * 44100,1); sineStartGain = hslider("sineStartGain", 1, 0, 1, 0.001); sineEndGain = hslider("sineEndGain",1,0,1,0.001); sineAmp = env(sineStartGain,sineEndGain,bufferSize); sinePitchRamp = env(sineStartFreq,sineEndFreq,bufferSize); sineFreq = sinePitchRamp + LFO; sineOsc = os.osc(sineFreq)sineAmp; // lfo lfoStartFreq = hslider("lfoStartFreq", 6, 0, 15, 0.001); lfoEndFreq = hslider("lfoEndFreq", 6, 0.001, 15, 0.001); lfoStartDepth = hslider("lfoStartDepth", 0, 0,1, 0.001); lfoEndDepth = hslider("lfoEndDepth", 0, 0,1, 0.001); lfoPitchRamp = env(lfoStartFreq,lfoEndFreq,bufferSize); lfoDepthRamp = env(lfoStartDepth,lfoEndDepth,bufferSize); LFO = os.lf_triangle(lfoPitchRamp)lfoDepthRamp20; process = sineOsc<:_posLeft,_*posRight;	https://raw.githubusercontent.com/clearly-broken-software/Uprising/89f5b49d90cd47611da7e7dc2009061768716b4c/plugins/uprising/dsp/faust/scratchpad.dsp	faust	//////////// general purpose ramp lfo / general purpose ramp :si.smoo; sine oscilator lfo ///////////////////////////////////// constant power panning ; reference The Audio Programming Book p.236 starts the ramp envelope general purpose ramp envelope :si.smoo; sine oscilator lfo constant power panning ; reference The Audio Programming Book p.236 starts the ramp envelope general purpose ramp envelope :si.smoo; sine oscilator lfo	import("stdfaust.lib"); gate = abs(button("gate")-1); ramp(timeInSeconds,start,end,rgate) = up with{ rs1 = timeInSeconds * ma.SR; up = ba.countup(rs1,rgate) : ba.bpf.start(0,start) : ba.bpf.end(rs1,end); }; myFilter = fi.resonbp(fc,q,gain) with{ fc = ramp(5,20,2000,gate); q = hslider("q",20,1,20,0.01); gain = hslider("gain",0.5,0,1,0.01); }; process = no.noise:myFilter; import("stdfaust.lib"); gate = 1-button("gate"); startFreq = 880; endFreq = 220; length = ma.SR * 4; counter = ba.countup(length,gate): ba.bpf.start(0,startFreq) : ba.bpf.end(length,endFreq); index = 1; dataPoints = (0,100,100,100); process = os.osc(counter); up = ba.countup(rs1,rgate) : ba.bpf.start(0,start) : ba.bpf.end(rs1,end); import("stdfaust.lib"); gate = 1-button("gate"); env(sFreq,eFreq,len) = urRamp with { urRamp = ba.countup(len,gate): ba.bpf.start(0,sFreq): ba.bpf.end(len,eFreq); }; sineStartFreq = hslider("sineStartFreq", 100, 20, 20000,0.01); sineEndFreq = hslider("sineEndFreq", 100, 20, 20000, 0.01); bufferSize = hslider("bufferSize", 512, 1, 2 * 44100,1); pitchRamp = env(sineStartFreq,sineEndFreq,bufferSize); lfoStartFreq = hslider("lfoStartFreq", 6, 0.001, 15, 0.001); lfoEndFreq = hslider("lfoEndFreq", 6, 0.001, 15, 0.001); lfoStartDepth = hslider("lfoStartDepth", 1, 0,1, 0.001); lfoEndDepth = hslider("lfoEndDepth", 1, 0,1, 0.001); lfoPitchRamp = env(lfoStartFreq,lfoEndFreq,bufferSize); lfoDepthRamp = env(lfoStartDepth,lfoEndDepth,bufferSize); LFO = os.lf_triangle(lfoPitchRamp)lfoDepthRamp20; allFreq = pitchRamp + LFO; oscAmp = hslider("oscAmp", 0.5, 0, 1, 0.001):si.smoo; sineOsc = os.osc(allFreq)oscAmp; process = sineOsc; import("stdfaust.lib"); gate = 1-button("gate"); env(start,end,len) = urRamp with { }; sineStartFreq = hslider("sineStartFreq", 440, 20, 20000,0.01); sineEndFreq = hslider("sineEndFreq", 440, 20, 20000, 0.01); bufferSize = hslider("bufferSize", 1024, 1, 2 44100,1); sineStartGain = hslider("sineStartGain", 1, 0, 1, 0.001); sineEndGain = hslider("sineEndGain",1,0,1,0.001); sineAmp = env(sineStartGain,sineEndGain,bufferSize); sinePitchRamp = env(sineStartFreq,sineEndFreq,bufferSize); sineFreq = sinePitchRamp + LFO; sineOsc = os.osc(sineFreq)sineAmp; lfoStartFreq = hslider("lfoStartFreq", 6, 0.001, 15, 0.001); lfoEndFreq = hslider("lfoEndFreq", 6, 0.001, 15, 0.001); lfoStartDepth = hslider("lfoStartDepth", 0, 0,1, 0.001); lfoEndDepth = hslider("lfoEndDepth", 0, 0,1, 0.001); lfoPitchRamp = env(lfoStartFreq,lfoEndFreq,bufferSize); lfoDepthRamp = env(lfoStartDepth,lfoEndDepth,bufferSize); LFO = os.lf_triangle(lfoPitchRamp)lfoDepthRamp20; process = sineOsc; import("stdfaust.lib"); piOver2 = ma.PI/2; root2over2 = (2 : sqrt) 0.5; angle = pan * piOver2 * 0.5; posLeft = root2over2 * (cos(angle) - sin(angle)); posRight = root2over2 * (cos(angle) + sin(angle)); panStartPos = hslider("panStartPosition",0,-1,1,0.001); panEndPos = hslider("panEndPosition", 0,-1,1,0.001); pan = env(panStartPos,panEndPos,bufferSize); env(start,end,len) = urRamp with { }; sineStartFreq = hslider("sineStartFreq", 440, 20, 20000,0.01); sineEndFreq = hslider("sineEndFreq", 440, 20, 20000, 0.01); bufferSize = hslider("bufferSize", 1024, 1, 2 * 44100,1); sineStartGain = hslider("sineStartGain", 1, 0, 1, 0.001); sineEndGain = hslider("sineEndGain",1,0,1,0.001); sineAmp = env(sineStartGain,sineEndGain,bufferSize); sinePitchRamp = env(sineStartFreq,sineEndFreq,bufferSize); sineFreq = sinePitchRamp + LFO; sineOsc = os.osc(sineFreq)sineAmp; lfoStartFreq = hslider("lfoStartFreq", 6, 0.001, 15, 0.001); lfoEndFreq = hslider("lfoEndFreq", 6, 0.001, 15, 0.001); lfoStartDepth = hslider("lfoStartDepth", 0, 0,1, 0.001); lfoEndDepth = hslider("lfoEndDepth", 0, 0,1, 0.001); lfoPitchRamp = env(lfoStartFreq,lfoEndFreq,bufferSize); lfoDepthRamp = env(lfoStartDepth,lfoEndDepth,bufferSize); LFO = os.lf_triangle(lfoPitchRamp)lfoDepthRamp20; process = sineOsc<:_posLeft,_posRight; import("stdfaust.lib"); piOver2 = ma.PI/2; root2over2 = (2 : sqrt) 0.5; angle = pan * piOver2 * 0.5; posLeft = root2over2 * (cos(angle) - sin(angle)); posRight = root2over2 * (cos(angle) + sin(angle)); panStartPos = hslider("panStartPosition",0,-1,1,0.001); panEndPos = hslider("panEndPosition", 0,-1,1,0.001); pan = env(panStartPos,panEndPos,bufferSize); env(start,end,len) = urRamp with { }; sineStartFreq = hslider("sineStartFreq", 440, 20, 20000,0.01); sineEndFreq = hslider("sineEndFreq", 440, 20, 20000, 0.01); bufferSize = hslider("bufferSize", 1024, 1, 2 * 44100,1); sineStartGain = hslider("sineStartGain", 1, 0, 1, 0.001); sineEndGain = hslider("sineEndGain",1,0,1,0.001); sineAmp = env(sineStartGain,sineEndGain,bufferSize); sinePitchRamp = env(sineStartFreq,sineEndFreq,bufferSize); sineFreq = sinePitchRamp + LFO; sineOsc = os.osc(sineFreq)sineAmp; lfoStartFreq = hslider("lfoStartFreq", 6, 0, 15, 0.001); lfoEndFreq = hslider("lfoEndFreq", 6, 0.001, 15, 0.001); lfoStartDepth = hslider("lfoStartDepth", 0, 0,1, 0.001); lfoEndDepth = hslider("lfoEndDepth", 0, 0,1, 0.001); lfoPitchRamp = env(lfoStartFreq,lfoEndFreq,bufferSize); lfoDepthRamp = env(lfoStartDepth,lfoEndDepth,bufferSize); LFO = os.lf_triangle(lfoPitchRamp)lfoDepthRamp20; process = sineOsc<:_posLeft,_*posRight;
1404c78ffd6f41c143c423cc67a07eb7cbe578a00c6545977e94c5bd41e46cc2	LSSN/2020-01-23-dsp-3a-giusnare	GiuseppeFerraro.dsp	//GS - il file di faust deve avere estensione .dsp //Spiega cos'è la sintesi sottrattiva. Per processo di sintesi si intende un processo con cui si produce qualcosa per sintesi sottrattiva si intende analizzare il suono attraverso degli strumenti, lo spettogramma- sonogramma- forma d'onda //GS - non hai spiegato cos'è la sintesi sottrattiva, a cosa servogno quegli strumenti di analisi //GS - il codice non gira per i seguenti motivi: //GS - mancano i caratteri che identificano la riga di commento -> // <- QUESTI! //GS - hai inserito due import identici, non si può fare //GS - hai inserito due righe di process, non si può fare //GS - hai dichiarato variabili fcut e order due volte, non si può fare import("stdfaust.lib"); fcut = vslider("cut-off [style:knob] [scale:exp]", 1000,20,20000,1); order= 8; process= no.noise : fi.lowpass (order,fcut) : fi.highpass (order,fcut); import("stdfaust.lib"); fcut=vslider("cut-off [style:knob] [scale:exp]", 1000,20,20000,1); order = 128; // init min max step gain = vslider("gain", -20, -96, 0, 0.1) : ba.db2linear : si.smoo; process= fi.lowpass(order,fcut) : fi.highpass(order,fcut) : *(gain);	https://raw.githubusercontent.com/LSSN/2020-01-23-dsp-3a-giusnare/ed1278f796ea25368a848541e82a6282f7ff7de1/GiuseppeFerraro.dsp	faust	GS - il file di faust deve avere estensione .dsp Spiega cos'è la sintesi sottrattiva. GS - non hai spiegato cos'è la sintesi sottrattiva, a cosa servogno quegli strumenti di analisi GS - il codice non gira per i seguenti motivi: GS - mancano i caratteri che identificano la riga di commento -> // <- QUESTI! GS - hai inserito due import identici, non si può fare GS - hai inserito due righe di process, non si può fare GS - hai dichiarato variabili fcut e order due volte, non si può fare init min max step	Per processo di sintesi si intende un processo con cui si produce qualcosa per sintesi sottrattiva si intende analizzare il suono attraverso degli strumenti, lo spettogramma- sonogramma- forma d'onda import("stdfaust.lib"); fcut = vslider("cut-off [style:knob] [scale:exp]", 1000,20,20000,1); order= 8; process= no.noise : fi.lowpass (order,fcut) : fi.highpass (order,fcut); import("stdfaust.lib"); fcut=vslider("cut-off [style:knob] [scale:exp]", 1000,20,20000,1); order = 128; gain = vslider("gain", -20, -96, 0, 0.1) : ba.db2linear : si.smoo; process= fi.lowpass(order,fcut) : fi.highpass(order,fcut) : *(gain);
9ed1d862455b5e0cd0a1b8bb525449d7c52ad9d5eb2f32fd8f5eb2e3a5957ae0	TheArpeggiator/juce-keyboard	FaustReverb.dsp	import("stdfaust.lib"); process = _ <: dm.zita_rev1;	https://raw.githubusercontent.com/TheArpeggiator/juce-keyboard/6323b1d484c8f35e3bffbe8b989dbbfc76a0f54d/Source/FaustReverb.dsp	faust		import("stdfaust.lib"); process = _ <: dm.zita_rev1;
23f408e16f526fcde4160f5a00c0863b69ab6e5f9cb775767c2d6cc1aa03b12a	theyoogle/FaustAudioKitExample	MyOsc.dsp	import("stdfaust.lib"); freq = nentry("freq", 440, 20,20000, 0.01) : si.smoo; gain = nentry("gain", 1, 0,1, 0.01) : si.smoo; gate = nentry("gate", 1, 0,1, 1) : si.smoo; process = os.sawtooth(freq) * gain * gate <: _,_;	https://raw.githubusercontent.com/theyoogle/FaustAudioKitExample/af2c8021874bf9f9ec272802168574e7b07f0620/FaustAKit/MyOsc.dsp	faust		import("stdfaust.lib"); freq = nentry("freq", 440, 20,20000, 0.01) : si.smoo; gain = nentry("gain", 1, 0,1, 0.01) : si.smoo; gate = nentry("gate", 1, 0,1, 1) : si.smoo; process = os.sawtooth(freq) * gain * gate <: _,_;
8d89fc4f82f782cd49bc1e8c491ecb37c38480befbd870008a8226724644c219	cantina-lib/cantina_plugin	test.dsp	import("stdfaust.lib"); rx = library("lib/routing_ext.lib"); // MUST BE A POWER OF TWO!! N = 8;//nentry("N", 4, 4, 4, 4); k = 2; // process = an.rtorv(N) : rvwcf(N, k); process = rx.argMax(N); //process = swap(N, 4,8);	https://raw.githubusercontent.com/cantina-lib/cantina_plugin/e709738540688c7b7411d4afcb087470e8c0ef3f/bindings/faust/source/test.dsp	faust	MUST BE A POWER OF TWO!! nentry("N", 4, 4, 4, 4); process = an.rtorv(N) : rvwcf(N, k); process = swap(N, 4,8);	import("stdfaust.lib"); rx = library("lib/routing_ext.lib"); k = 2; process = rx.argMax(N);
68e9e0974512ef770f9b39d16ee0d65f48794055a6be3ed87e8a715ddff0574e	tomara-x/magi	day6.dsp	//i shan't perish like a human //that lydian is just a list of ratios (2^0/12,...) import("stdfaust.lib"); step = ba.counter(ba.beat(135))%7; ratio = qu.lydian : ba.selectn(7,step); process = 440*ratio : os.osc; //noooooo! //import("stdfaust.lib"); //struct = environment{x=1;y=3;}; //structs = par(i,4,struct); //process = ba.take(1,structs).x; //import("stdfaust.lib"); // list = ((0,13),(3,4)); // 3 items // list = (0,13,(3,4)); // 4 items // list = ((0,13,3,4)); // 4 items // list = (0,(13,3),4); // 3 items //process = ba.count(list); //cute af! duplicate(1,x) = x; duplicate(n,x) = x,duplicate(n-1,x); count((x,rest)) = 1+count(rest); count(x) = 1;	https://raw.githubusercontent.com/tomara-x/magi/bcf22a4ef23899cd8ce3bf5e08e374994907f81a/practice/day6.dsp	faust	i shan't perish like a human that lydian is just a list of ratios (2^0/12,...) noooooo! import("stdfaust.lib"); struct = environment{x=1;y=3;}; structs = par(i,4,struct); process = ba.take(1,structs).x; import("stdfaust.lib"); list = ((0,13),(3,4)); // 3 items list = (0,13,(3,4)); // 4 items list = ((0,13,3,4)); // 4 items list = (0,(13,3),4); // 3 items process = ba.count(list); cute af!	import("stdfaust.lib"); step = ba.counter(ba.beat(135))%7; ratio = qu.lydian : ba.selectn(7,step); process = 440*ratio : os.osc; duplicate(1,x) = x; duplicate(n,x) = x,duplicate(n-1,x); count((x,rest)) = 1+count(rest); count(x) = 1;
044450e444bfaa6155b5359b492ceff30942b490b2c768379dc4b2cb54f31678	inokawa/faust-sandbox	hello.dsp	import("stdfaust.lib"); ctFreq = hslider("[0]cutoffFrequency",500,50,10000,0.01) : si.smoo; q = hslider("[1]q",5,1,30,0.1) : si.smoo; gain = hslider("[2]gain",1,0,1,0.01) : si.smoo; t = button("[3]gate") : si.smoo; process = no.noise : fi.resonlp(ctFreq,q,gain)*t <: dm.zita_light;	https://raw.githubusercontent.com/inokawa/faust-sandbox/e2c6c3687a53fa51136764cd3b9130152544b2ba/hello.dsp	faust		import("stdfaust.lib"); ctFreq = hslider("[0]cutoffFrequency",500,50,10000,0.01) : si.smoo; q = hslider("[1]q",5,1,30,0.1) : si.smoo; gain = hslider("[2]gain",1,0,1,0.01) : si.smoo; t = button("[3]gate") : si.smoo; process = no.noise : fi.resonlp(ctFreq,q,gain)*t <: dm.zita_light;
1cf41eda253c23e3c3c3c9b3b9bf62e2d1773504907392f2d2ae97e85fae7cb2	itsnestee/Verber	JpRevTest.dsp	import("stdfaust.lib"); process = dm.zita_rev1;	https://raw.githubusercontent.com/itsnestee/Verber/f02c5c6e3b9fd45354259d6ec22c1f7c4b6f1029/DspNetworks/CodeLibrary/faust/JpRevTest.dsp	faust		import("stdfaust.lib"); process = dm.zita_rev1;
1e112fc139a623113b62162659d6c2a0a0ffd58ef96c19ea303d2626f8558590	SpotlightKid/dfzitarev1	dfzitarev1.dsp	declare name "DFZitaRev1"; declare description "A feedback-delay-network reverb"; declare author "Julius O. Smith III, Christopher Arndt"; declare copyright "Copyright (C) 2003-2019 by Julius O. Smith III <[email protected]>"; declare license "STK-4.3 license"; declare version "0.1.0"; import("stdfaust.lib"); process = _,_ : dm.zita_rev1 : _,_;	https://raw.githubusercontent.com/SpotlightKid/dfzitarev1/8508c4bd9e2dd4f280e302a7884a28d1428db096/faust/dfzitarev1.dsp	faust		declare name "DFZitaRev1"; declare description "A feedback-delay-network reverb"; declare author "Julius O. Smith III, Christopher Arndt"; declare copyright "Copyright (C) 2003-2019 by Julius O. Smith III <[email protected]>"; declare license "STK-4.3 license"; declare version "0.1.0"; import("stdfaust.lib"); process = _,_ : dm.zita_rev1 : _,_;
22dae3c57918347444a8d7eee224e2dadbd65ef3d1f7c55c8e38bd091950ae63	LucaSpanedda/Analisi_Effetto_Larsen	LAR_Peakholder.dsp	// FAUST standard library import("stdfaust.lib"); // Peakholder IIR - Loop Stage Peakholder = _ : abs <: loop ~_ with{ loop = ((_,_) : max); }; // Counterbalancing LARPeakholder = _ <: *(1-Peakholder); process = LARPeakholder;	https://raw.githubusercontent.com/LucaSpanedda/Analisi_Effetto_Larsen/af64a95fbc4dc2de7d69ffa86d1ae7ba22dd0827/LAR_Peakholder.dsp	faust	FAUST standard library Peakholder IIR - Loop Stage Counterbalancing	import("stdfaust.lib"); Peakholder = _ : abs <: loop ~_ with{ loop = ((_,_) : max); }; LARPeakholder = _ <: *(1-Peakholder); process = LARPeakholder;
095de15337b8bdd0345cd661191e16aa24ea6ac39a7aa6131ad7f9c9961cb754	Barabas5532/TubeScreamer	tubescreamer.dsp	import("stdfaust.lib"); gain = hslider("gain", 0.5, 0, 1, 0.01) : si.smoo; tone = hslider("tone", 0.5, 0, 1, 0.01) : si.smoo; volume = hslider("volume", 0.5, 0, 1, 0.01) : si.smoo; input_filter = fi.highpass(1, 720); clipping = ef.cubicnl(gain, 0); post_filter = fi.lowpass(1, 350 + (tone * (4500 - 350))); volume_control = ba.db2linear((volume - 1) * 40); process = _,_ :> input_filter : clipping : post_filter * volume_control <: _,_;	https://raw.githubusercontent.com/Barabas5532/TubeScreamer/519334dcbe3b4afc1f937889383ddc8a884e12d2/tubescreamer.dsp	faust		import("stdfaust.lib"); gain = hslider("gain", 0.5, 0, 1, 0.01) : si.smoo; tone = hslider("tone", 0.5, 0, 1, 0.01) : si.smoo; volume = hslider("volume", 0.5, 0, 1, 0.01) : si.smoo; input_filter = fi.highpass(1, 720); clipping = ef.cubicnl(gain, 0); post_filter = fi.lowpass(1, 350 + (tone * (4500 - 350))); volume_control = ba.db2linear((volume - 1) * 40); process = _,_ :> input_filter : clipping : post_filter * volume_control <: _,_;
3fe0b9accaa36cff86bca03da0d8c2c852e80a872ec105c6df977faf89c261da	2020V3DisHenricHJonathanKEget/FaustDelayPlugin	faust_delay_exjobb.dsp	import("stdfaust.lib"); MAX_DELAY_TIME = 2000; SAMPLE_RATE = ma.SR; Xdelay = _ <: (1-DryWet), (+~(de.fdelay(SAMPLE_RATE2, Time)Feedback) : (DryWet)) :> _ with { DryWet = hslider("Dry/Wet", 0, 0, 1, 0.01) : si.smooth(0.999); Feedback = hslider("Feedback", 0, 0, 1, 0.001) : si.smooth(0.999); Time = hslider("Time (ms)", 250, 0, MAX_DELAY_TIME, 0.1) * 0.001 * SAMPLE_RATE : si.smooth(0.999); }; process = Xdelay;	https://raw.githubusercontent.com/2020V3DisHenricHJonathanKEget/FaustDelayPlugin/4ec1ae6ccd3b9c1a68ad6e5cdbcc0d0ec94870d4/faust_delay_exjobb.dsp	faust		import("stdfaust.lib"); MAX_DELAY_TIME = 2000; SAMPLE_RATE = ma.SR; Xdelay = _ <: (1-DryWet), (+~(de.fdelay(SAMPLE_RATE2, Time)Feedback) : (DryWet)) :> _ with { DryWet = hslider("Dry/Wet", 0, 0, 1, 0.01) : si.smooth(0.999); Feedback = hslider("Feedback", 0, 0, 1, 0.001) : si.smooth(0.999); Time = hslider("Time (ms)", 250, 0, MAX_DELAY_TIME, 0.1) * 0.001 * SAMPLE_RATE : si.smooth(0.999); }; process = Xdelay;
2bd405bdc2f0a2b40bece63c2ffe2cebd89c78d9d2d17de27d25a2997d2bb054	mathiasbredholt/BredholtPlugins	MonoPhaser.dsp	import("stdfaust.lib"); depth = hslider("depth", 0.5, 0, 3, 0.01); fb = hslider("fb", 0, 0, 1, 0.01); rate = hslider("rate", 1, 0.001, 20, 0.01); phase = hslider("phase", 0, 0, 1, 0.01); notchWidth = hslider("width", 10e3, 20, 20e3, 0.01); fMin = hslider("fMin", 20, 20, 20e3, 0.01); fMax = hslider("fMax", 20e3, 20, 20e3, 0.01); process = _ : pf.phaser2_mono(8, phase, notchWidth, fMin, 1, fMax, rate, depth, fb, 0);	https://raw.githubusercontent.com/mathiasbredholt/BredholtPlugins/7a212ea48dfdf3aa2847f7a7d7f48dfa9783ed4e/Plugins/MonoPhaser/MonoPhaser.dsp	faust		import("stdfaust.lib"); depth = hslider("depth", 0.5, 0, 3, 0.01); fb = hslider("fb", 0, 0, 1, 0.01); rate = hslider("rate", 1, 0.001, 20, 0.01); phase = hslider("phase", 0, 0, 1, 0.01); notchWidth = hslider("width", 10e3, 20, 20e3, 0.01); fMin = hslider("fMin", 20, 20, 20e3, 0.01); fMax = hslider("fMax", 20e3, 20, 20e3, 0.01); process = _ : pf.phaser2_mono(8, phase, notchWidth, fMin, 1, fMax, rate, depth, fb, 0);
fe08eb393bb18a8b7f35e3b2367209177cc3e681ee41dc114ccd78002778158a	Martinacontu/programmazione	sotrattiva.dsp	import("stdfaust.lib"); process= no.noise : fi.lowpass(2,6000) : fi.highpass(2,6000);	https://raw.githubusercontent.com/Martinacontu/programmazione/f0881603fdec0ad0bc624e148530d54818919510/sotrattiva.dsp	faust		import("stdfaust.lib"); process= no.noise : fi.lowpass(2,6000) : fi.highpass(2,6000);
c933067162566cb1c19eeafd9810823fcd0df96e5762ccef6af132b8053496ce	JuanSaudio/AudioDevKitDemo	SquareWave.dsp	import("stdfaust.lib"); nOsc = 10; // number of oscillators fc = 100; // base frequency process = par(i, nOsc, os.osc(fc * (i + 1)) / (i + 1)) :> _ * 0.00001;	https://raw.githubusercontent.com/JuanSaudio/AudioDevKitDemo/6a87465f58b48442c47d535188cdb82a7f9eb98e/SquareWave/SquareWave.dsp	faust	number of oscillators base frequency	import("stdfaust.lib"); process = par(i, nOsc, os.osc(fc * (i + 1)) / (i + 1)) :> _ * 0.00001;
fa3f400a2b884715ffc56f8d5b966abf43b58846299a1057f1791706f9a96f9c	moldeo/moldeojs	wind.dsp	//----------------------`wind`-------------------------- // A very simple wind simulator, based on a filtered white noise // // #### Usage // // ``` // wind(f) : _ // ``` // // Where: // // * `f`: is the force of the wind: between 0 and 1 // //---------------------------------------------------------- import("stdfaust.lib"); wind(force) = no.multinoise(2) : par(i, 2, ve.moog_vcf_2bn(force,freq)) : par(i, 2, (force)) with { freq = (force87)+1 : ba.pianokey2hz; }; process = wind ( hslider("v:wind/force",0.66,0,1,0.01) : si.smooth (0.997) );	https://raw.githubusercontent.com/moldeo/moldeojs/68a309d9df674d613dadbbc0417730cd87e991a3/src/assets/data/effects/faust/wind.dsp	faust	----------------------`wind`-------------------------- A very simple wind simulator, based on a filtered white noise #### Usage ``` wind(f) : _ ``` Where: * `f`: is the force of the wind: between 0 and 1 ----------------------------------------------------------	import("stdfaust.lib"); wind(force) = no.multinoise(2) : par(i, 2, ve.moog_vcf_2bn(force,freq)) : par(i, 2, (force)) with { freq = (force87)+1 : ba.pianokey2hz; }; process = wind ( hslider("v:wind/force",0.66,0,1,0.01) : si.smooth (0.997) );
5ff66fd7c8c1c3a83674bfbf15a612773188b67c846568328f59ad7dfbd909fb	tomara-x/magi	cbat.dsp	import("stdfaust.lib"); bpm = 81; res = 4; trig = ba.beat(bpmres); beat = ba.cycle(16, trig) : _,!,_,_,!,!,_,!,_,_,_,!,_,!,!,! :> _; sig = sy.hat(3170,18000,0.0005,0,beat); process = sig <: _,_; / import("stdfaust.lib"); trig2gate(t,time) = t : ba.peakholder(ba.sec2samp(time)); bpm = 96; // htrig = ba.beat(bpm3); // f(x) = ba.resetCtr(12,x,htrig); // hbeat = 1,5,9,10,11 : par(i,5,f) :> _; hat = sy.hat(3100,18e3,0.0005,0,hbeat); htrig = ba.beat(bpm6); f(x) = ba.resetCtr(24,x,htrig); hbeat = 1,10,18,20,21,22 : par(i,6,f) :> _; ktrig = ba.beat(bpm4); g(x) = ba.resetCtr(16,x,ktrig); kbeat = 1,5,9,13 : par(i,4,g) :> _; kick = sy.kick(44, 0.01, 0.001, .6, 1, trig2gate(kbeat,0.1)); process = kick+hat <: _,_; //1,3,4,7,9,10,11,13 //amen! // process = +(ba.beat(30)) ~ _ : -(1) : %(16); // process = +(gate(30,0.5)) ~ _ : /(ma.SR); / /* import("stdfaust.lib"); trig2gate(t,time) = t : ba.peakholder(ba.sec2samp(time)); bpm = 96; htrig = ba.beat(bpm3); hbeat = ba.cycle(12, htrig) : _,!,!,_,!,!,_,!,!,_,!,_ :> _; hat = sy.hat(3100,18e3,0.0005,0,hbeat); ktrig = ba.beat(bpm4); kbeat = ba.cycle(16, ktrig) : _,!,!,!,_,!,!,!,_,!,!,!,_,!,_,! :> _; kick = sy.kick(44, 0.01, 0.001, .6, 1, trig2gate(kbeat,0.05)); process = kick+hat <: dm.freeverb_demo; */	https://raw.githubusercontent.com/tomara-x/magi/d9ad895a70b6e27cc683f1342d406e87ea979220/practice/cbat.dsp	faust	import("stdfaust.lib"); trig2gate(t,time) = t : ba.peakholder(ba.sec2samp(time)); bpm = 96; // htrig = ba.beat(bpm3); // f(x) = ba.resetCtr(12,x,htrig); // hbeat = 1,5,9,10,11 : par(i,5,f) :> _; hat = sy.hat(3100,18e3,0.0005,0,hbeat); htrig = ba.beat(bpm6); f(x) = ba.resetCtr(24,x,htrig); hbeat = 1,10,18,20,21,22 : par(i,6,f) :> _; ktrig = ba.beat(bpm4); g(x) = ba.resetCtr(16,x,ktrig); kbeat = 1,5,9,13 : par(i,4,g) :> _; kick = sy.kick(44, 0.01, 0.001, .6, 1, trig2gate(kbeat,0.1)); process = kick+hat <: _,_; //1,3,4,7,9,10,11,13 //amen! // process = +(ba.beat(30)) ~ _ : -(1) : %(16); // process = +(gate(30,0.5)) ~ _ : /(ma.SR); import("stdfaust.lib"); trig2gate(t,time) = t : ba.peakholder(ba.sec2samp(time)); bpm = 96; htrig = ba.beat(bpm3); hbeat = ba.cycle(12, htrig) : _,!,!,_,!,!,_,!,!,_,!,_ :> _; hat = sy.hat(3100,18e3,0.0005,0,hbeat); ktrig = ba.beat(bpm*4); kbeat = ba.cycle(16, ktrig) : _,!,!,!,_,!,!,!,_,!,!,!,_,!,_,! :> _; kick = sy.kick(44, 0.01, 0.001, .6, 1, trig2gate(kbeat,0.05)); process = kick+hat <: dm.freeverb_demo;	import("stdfaust.lib"); bpm = 81; res = 4; trig = ba.beat(bpm*res); beat = ba.cycle(16, trig) : _,!,_,_,!,!,_,!,_,_,_,!,_,!,!,! :> _; sig = sy.hat(3170,18000,0.0005,0,beat); process = sig <: _,_;
a25192edc514db5395e036e85c23f07545bd0bae2ebf107a68b003cc5db7ab0a	tomara-x/magi	jam10.dsp	/* import("stdfaust.lib"); list = par(i,16, par(j,8, (j+(j+1)i)%16)); t = ba.beat(128); c = ba.counter(t); step = list : ba.selectn(816,c); midc = 261.626; frq = midcba.semi2ratio(step) : qu.quantize(midc,qu.dorian); process = frq : os.osc0.1 <: _,_; //different import("stdfaust.lib"); scaleRep(rats,octs) = par(i,octs,rats) : par(i,octs,par(j,c,_(i+1))) with { c = outputs(rats); }; list = par(i,16, par(j,8, ((j+1)+(j+1)i)%14)); t = ba.beat(1284); c = ba.counter(t)%outputs(list); step = list : ba.selectn(outputs(list),c); midc = 261.626; scale = scaleRep(qu.eolian, 2); frq = midcba.selectn(outputs(scale),step,scale)/2; process = frq : os.osc0.1 <: _,_; / // a bit better import("stdfaust.lib"); scaleRep(scal,octs) = par(i,octs,par(j,outputs(scal),ba.take(j+1,scal)(i+1))); scale = scaleRep(qu.eolian, 2); list = par(i,14,par(j,8, ((j+1)+(j+1)i)%14)); t = ba.beat(1284); c = ba.counter(t)%outputs(list); //this is horrble! they're not vars! do you see it now? step = list : ba.selectn(outputs(list),c); rat = scale : ba.selectn(outputs(scale),step); midc = 261.626; frq = midcrat/2; process = frq : os.osc*0.1 <: _,_;	https://raw.githubusercontent.com/tomara-x/magi/bcf22a4ef23899cd8ce3bf5e08e374994907f81a/practice/jam10.dsp	faust	import("stdfaust.lib"); list = par(i,16, par(j,8, (j+(j+1)i)%16)); t = ba.beat(128); c = ba.counter(t); step = list : ba.selectn(816,c); midc = 261.626; frq = midcba.semi2ratio(step) : qu.quantize(midc,qu.dorian); process = frq : os.osc0.1 <: _,_; //different import("stdfaust.lib"); scaleRep(rats,octs) = par(i,octs,rats) : par(i,octs,par(j,c,_(i+1))) with { c = outputs(rats); }; list = par(i,16, par(j,8, ((j+1)+(j+1)i)%14)); t = ba.beat(1284); c = ba.counter(t)%outputs(list); step = list : ba.selectn(outputs(list),c); midc = 261.626; scale = scaleRep(qu.eolian, 2); frq = midcba.selectn(outputs(scale),step,scale)/2; process = frq : os.osc*0.1 <: _,_; a bit better this is horrble! they're not vars! do you see it now?	import("stdfaust.lib"); scaleRep(scal,octs) = par(i,octs,par(j,outputs(scal),ba.take(j+1,scal)(i+1))); scale = scaleRep(qu.eolian, 2); list = par(i,14,par(j,8, ((j+1)+(j+1)i)%14)); t = ba.beat(1284); c = ba.counter(t)%outputs(list); step = list : ba.selectn(outputs(list),c); rat = scale : ba.selectn(outputs(scale),step); midc = 261.626; frq = midcrat/2; process = frq : os.osc*0.1 <: _,_;
f232aae3279986da527b2d1e2667c6bc6ea81535da60845b996729b41065d045	miselaytes-anton/faust-echo	FaustEcho.dsp	import("stdfaust.lib"); lp = fi.lowpass(1, 1000); process = + : lp:lp:lp: _* 0.6 : ef.echo(2,1,0.5):re.satrev;	https://raw.githubusercontent.com/miselaytes-anton/faust-echo/13282816ff8a97e1f1e683f80974dc131f6d23f1/FaustEcho.dsp	faust		import("stdfaust.lib"); lp = fi.lowpass(1, 1000); process = + : lp:lp:lp: _* 0.6 : ef.echo(2,1,0.5):re.satrev;
8fe70c87d0d4498d3c73bce45c3ffa13310a648379e934e0534ba0cd64e187a2	Lcchy/orac-modules	moogf.dsp	import("stdfaust.lib"); v = 2 * ma.PI * hslider("freq", 100, 20, 5000, 1) / ma.SR; F1 = * (v / (1+v)) : + ~ * (1 / (1+v)); stage = (_ <: F1, ^(3)), _ : (_ <: _, (^(3) : *(-1))), + : _, (+ :_: F1); full = stage : stage : stage : stage; process = full;	https://raw.githubusercontent.com/Lcchy/orac-modules/eb9de9db65b9403404717186ca1f214d9219e64a/fates_usermodules/fx/aapart/moogf/moogf.dsp	faust		import("stdfaust.lib"); v = 2 * ma.PI * hslider("freq", 100, 20, 5000, 1) / ma.SR; F1 = * (v / (1+v)) : + ~ * (1 / (1+v)); stage = (_ <: F1, ^(3)), _ : (_ <: _, (^(3) : *(-1))), + : _, (+ :_: F1); full = stage : stage : stage : stage; process = full;
9c52391f7096ce39c01742d30c52fa4d46a1ce385e3c9903c26d5611e109ebb3	NickSeagull/soup_machine	noise.dsp	declare options "[osc:on]"; import("stdfaust.lib"); process = g * a * os.oscrs(f*b) <: _,_; a = hslider("gain",1,0,1,0.001); f = hslider("freq",392.0,200.0,2000.0,0.01); b = ba.semi2ratio(hslider("bend",0,-2,2,0.001)); g = button("gate");	https://raw.githubusercontent.com/NickSeagull/soup_machine/8e864b1f13c61540850470750c5e197dfdfe6087/faust/noise.dsp	faust		declare options "[osc:on]"; import("stdfaust.lib"); process = g * a * os.oscrs(f*b) <: _,_; a = hslider("gain",1,0,1,0.001); f = hslider("freq",392.0,200.0,2000.0,0.01); b = ba.semi2ratio(hslider("bend",0,-2,2,0.001)); g = button("gate");
a8056e1381b11a93acbd5673f1a22ea8d55088d4a6bc162da6557ae7edf5e120	lwakefield/tesla-tree	poly.dsp	declare options "[midi:on][nvoices:12]"; import("stdfaust.lib"); freq = hslider("freq",200,50,1000,0.01); gain = hslider("gain",0.1,0,1,0.01); gate = button("gate"); envelope = en.adsr(0.01,0.01,0.8,0.1,gate)gain; process = os.sawtooth(freq)envelope <: _,_ : dm.zita_rev1;	https://raw.githubusercontent.com/lwakefield/tesla-tree/070d740ab0c4bc326a9df2a699d383326763df6f/poly.dsp	faust		declare options "[midi:on][nvoices:12]"; import("stdfaust.lib"); freq = hslider("freq",200,50,1000,0.01); gain = hslider("gain",0.1,0,1,0.01); gate = button("gate"); envelope = en.adsr(0.01,0.01,0.8,0.1,gate)gain; process = os.sawtooth(freq)envelope <: _,_ : dm.zita_rev1;
4597d4fe8070f343f135f51041cb34093bf1bf01fe7fac27166ea2629419d181	dynamicspeaker/esp32	fluteMIDI.dsp	declare name "FluteMIDI"; declare description "Simple MIDI-controllable flute physical model with physical parameters."; declare license "MIT"; declare copyright "(c)Romain Michon, CCRMA (Stanford University), GRAME"; import("stdfaust.lib"); process = pm.flute_ui_MIDI <: _,_;	https://raw.githubusercontent.com/dynamicspeaker/esp32/e10c3af4b3b47193dbb9e8975038992541591e8c/lib/arduino-audio-tools-main/examples/examples-faust/streams-faust_flute-i2s/fluteMIDI.dsp	faust		declare name "FluteMIDI"; declare description "Simple MIDI-controllable flute physical model with physical parameters."; declare license "MIT"; declare copyright "(c)Romain Michon, CCRMA (Stanford University), GRAME"; import("stdfaust.lib"); process = pm.flute_ui_MIDI <: _,_;
92351a7b0af974f22317cb396a29442eb3572296a919c0f030af574dc71c007a	misterinterrupt/Faust2AudioKitExample	MyOsc.dsp	import("stdfaust.lib"); freq = nentry("freq",440,20,20000,0.01) : si.smoo; gain = nentry("gain",1,0,1,0.01) : si.smoo; process = os.sawtooth(freq)*gain <: _,_;	https://raw.githubusercontent.com/misterinterrupt/Faust2AudioKitExample/0e16ac1ff62460c04cf88be85d177f1455dcef30/Faust2AudioKitExample/MyOsc.dsp	faust		import("stdfaust.lib"); freq = nentry("freq",440,20,20000,0.01) : si.smoo; gain = nentry("gain",1,0,1,0.01) : si.smoo; process = os.sawtooth(freq)*gain <: _,_;
5610ecf3a3c7fc454aded91e7a1cc4112aabccbcce98fa7debf5bea4cbdf68f7	aike/audiolang	sine.dsp	import("stdfaust.lib"); freq = 440; gain = 0.5; process = os.osc(freq) * gain <: _,_;	https://raw.githubusercontent.com/aike/audiolang/1a211888945eed4257d6078eff83af32068a550a/faust/sine.dsp	faust		import("stdfaust.lib"); freq = 440; gain = 0.5; process = os.osc(freq) * gain <: _,_;
d4ecfcb0f099a7ba682beda3121261264deaca529d8dd6d646ecdfb7d72540ad	rd--/hsc3	zitaRev.dsp	declare name "zitaRev"; declare version "0.0"; declare author "JOS, Revised by RM"; declare description "Example GUI for `zita_rev1_stereo` (mostly following the Linux `zita-rev1` GUI)."; import("stdfaust.lib"); process = dm.zita_rev1;	https://raw.githubusercontent.com/rd--/hsc3/dea91cd9401ce4532706909d62ef3f19d007c759/ext/faust/zitaRev.dsp	faust		declare name "zitaRev"; declare version "0.0"; declare author "JOS, Revised by RM"; declare description "Example GUI for `zita_rev1_stereo` (mostly following the Linux `zita-rev1` GUI)."; import("stdfaust.lib"); process = dm.zita_rev1;
d1c94096d7c72ad0108e56a92cff7b91c2ff71a721203789d90d3ddeaac417a1	SpotlightKid/cookiecutter-dpf-faust	{{ cookiecutter.plugin_name\|lower }}.dsp	declare name "{{ cookiecutter.plugin_name }}"; declare description "{{ cookiecutter.plugin_description }}"; declare author "{{ cookiecutter.author_name }}"; declare license "{{ cookiecutter.project_license }} license"; import("stdfaust.lib"); gain = hslider("[0]Gain [symbol: gain][abbrev: gain][unit: dB]", -6.0, -90.0, 30.0, 0.1):si.smoo; process = _ * ba.db2linear(gain);	https://raw.githubusercontent.com/SpotlightKid/cookiecutter-dpf-faust/a8b6541953fdcb68fa45e017cd355657a42d295e/%7B%7B%20cookiecutter.repo_name%20%7D%7D/faust/%7B%7B%20cookiecutter.plugin_name%7Clower%20%7D%7D.dsp	faust		declare name "{{ cookiecutter.plugin_name }}"; declare description "{{ cookiecutter.plugin_description }}"; declare author "{{ cookiecutter.author_name }}"; declare license "{{ cookiecutter.project_license }} license"; import("stdfaust.lib"); gain = hslider("[0]Gain [symbol: gain][abbrev: gain][unit: dB]", -6.0, -90.0, 30.0, 0.1):si.smoo; process = _ * ba.db2linear(gain);
54b7a150976b7e9fa0ed346b2469f449cc3fed5bc78393053b73df4cb9153e26	slemouton/mantra2021	mantra.dsp	declare name "Mantra v.0 Ring Modulation"; /* ======== DESCRIPTION ========== - Ring modulation consists in modulating a sound by multiplying it with a sine wave - Head = no modulation - Downward = modulation, varying the modulating frequency / import("stdfaust.lib"); process = ringmod; ringmod = _<:_,(os.oscs(freq)):drywet with { freq = hslider ( "[1]Modulation Frequency[style:knob][acc:1 0 -10 0 10][scale:log]", 220,5,1000,0.001):si.smooth(0.999); drywet(x,y) = (1-c)x + cy; c = hslider("[2]Modulation intensity[style:knob][unit:%][acc:1 0 -10 0 10]", 90,0,100,0.01)*(0.01):si.smooth(0.999); };	https://raw.githubusercontent.com/slemouton/mantra2021/37659371a34d790bc670fdc0247f1d5c85387965/mantra-faust/mantra.dsp	faust	======== DESCRIPTION ========== - Ring modulation consists in modulating a sound by multiplying it with a sine wave - Head = no modulation - Downward = modulation, varying the modulating frequency	declare name "Mantra v.0 Ring Modulation"; import("stdfaust.lib"); process = ringmod; ringmod = _<:_,(os.oscs(freq)):drywet with { freq = hslider ( "[1]Modulation Frequency[style:knob][acc:1 0 -10 0 10][scale:log]", 220,5,1000,0.001):si.smooth(0.999); drywet(x,y) = (1-c)x + cy; c = hslider("[2]Modulation intensity[style:knob][unit:%][acc:1 0 -10 0 10]", 90,0,100,0.01)(0.01):si.smooth(0.999); };
9a4d172182401078223dd03da18031cd571055f5182ec8af81155bf09a852db2	Stinos98/Faustcode-	lezione1.dsp	//commento: il : fa una connessione seriale //connessioone parallela è " , " connessione seria //tutti i segni algebrici (+,-,:,*) sono operatori matematici import("stdfaust.lib"); //libreria standard di faust process = _ +_ , _ +_; //ogni riga si chiude con un ;	https://raw.githubusercontent.com/Stinos98/Faustcode-/19afcd0898f91339ff0dcc92f4a1886cddff5a89/lezione1.dsp	faust	commento: il : fa una connessione seriale connessioone parallela è " , " tutti i segni algebrici (+,-,:,*) sono operatori matematici libreria standard di faust ogni riga si chiude con un ;	connessione seria
3a585341b70b4686820b5bc2591038acef0a9611bdd79e0606ed169ebbaba125	Smona/faust-loader	TestSynth.dsp	declare name "TestSynth"; declare version "1.0"; declare author "Smona"; declare license "BSD"; import("stdfaust.lib"); // TODO: test all input & output types process = no.noise * 0.1;	https://raw.githubusercontent.com/Smona/faust-loader/9fd67bb88f7183b660a95599673a0b7eb7c1b015/test/TestSynth.dsp	faust	TODO: test all input & output types	declare name "TestSynth"; declare version "1.0"; declare author "Smona"; declare license "BSD"; import("stdfaust.lib"); process = no.noise * 0.1;
577e696e43dae5273b324c792d7a9517d6f1475abe7861968c6f1d0fe399092c	LucaSpanedda/Analisi_Effetto_Larsen	LAR_RMS.dsp	// FAUST standard library import("stdfaust.lib"); // RMS with indipendent attack and release time RMS(att,rel,x) = loop ~ _ : sqrt with { loop(y) = (1.0 - coeff) * x * x + coeff * y with { attCoeff = exp(-2.0 * ma.PI * ma.T / att); relCoeff = exp(-2.0 * ma.PI * ma.T / rel); coeff = ba.if(abs(x) > y, attCoeff, relCoeff); }; }; // Counterbalancing LARRMS(att,rel,z) = z*(1-(z:RMS(att,rel))); process = LARRMS(0.01,0.01) <: _,_;	https://raw.githubusercontent.com/LucaSpanedda/Analisi_Effetto_Larsen/7f0e59fb8f75f7855e8c5e92befe08328fdcb1ec/LAR_RMS.dsp	faust	FAUST standard library RMS with indipendent attack and release time Counterbalancing	import("stdfaust.lib"); RMS(att,rel,x) = loop ~ _ : sqrt with { loop(y) = (1.0 - coeff) * x * x + coeff * y with { attCoeff = exp(-2.0 * ma.PI * ma.T / att); relCoeff = exp(-2.0 * ma.PI * ma.T / rel); coeff = ba.if(abs(x) > y, attCoeff, relCoeff); }; }; LARRMS(att,rel,z) = z*(1-(z:RMS(att,rel))); process = LARRMS(0.01,0.01) <: _,_;
0bd6a8f3e5ed616149c7c77fb5c84cae5567a19359185958750f3066d5f52ae1	CICM/pd-faustgen	gain.dsp	import("stdfaust.lib"); process = _ * (gain) with { gain = vslider("gain [unit:linear]", 0,0,1,0.001); };	https://raw.githubusercontent.com/CICM/pd-faustgen/9e2aaeabe94a7fab6928711050535ac12a1a591a/external/examples/gain.dsp	faust		import("stdfaust.lib"); process = _ * (gain) with { gain = vslider("gain [unit:linear]", 0,0,1,0.001); };
22856573419b1dc628e1c00f062d3d365dabe83f01fcc2a943e1f7dee11beea9	brummer10/slowmo.lv2	Gain.dsp	declare id "gain"; declare name "Gain"; declare category "Tone Control"; import("stdfaust.lib"); gain = vslider("Volume[name:Volume][tooltip:gain (dB)]", 0, -20, 20, 0.1) : ba.db2linear : si.smooth(0.999); process = *(gain);	https://raw.githubusercontent.com/brummer10/slowmo.lv2/1a32ab4e5b3740dab64e6f9dcce54baa9162a7bd/slowmo/Faust/Gain.dsp	faust		declare id "gain"; declare name "Gain"; declare category "Tone Control"; import("stdfaust.lib"); gain = vslider("Volume[name:Volume][tooltip:gain (dB)]", 0, -20, 20, 0.1) : ba.db2linear : si.smooth(0.999); process = *(gain);
fddfbf4a504fec3621cd4cd12f3af023baf5cc5eb0016bbfd50eb1d4bb2f64ed	plule/faust-egui	instrument.dsp	declare name "NylonGuitarMidi"; declare description "Simple acoustic guitar model with nylon strings."; declare license "MIT"; declare copyright "(c)Romain Michon, CCRMA (Stanford University), GRAME"; import("stdfaust.lib"); process = pm.nylonGuitar_ui_MIDI <: _,_;	https://raw.githubusercontent.com/plule/faust-egui/a1d84b9a08e6fdb02480338dc705802cd0aa3560/dsp/instrument.dsp	faust		declare name "NylonGuitarMidi"; declare description "Simple acoustic guitar model with nylon strings."; declare license "MIT"; declare copyright "(c)Romain Michon, CCRMA (Stanford University), GRAME"; import("stdfaust.lib"); process = pm.nylonGuitar_ui_MIDI <: _,_;
7e2ac802651e021be061c19998f6e7dc35c68988c308769b821f7b54744a799a	quidmonkey/autopanner	autopanner.dsp	declare name "autopanner"; declare version "1.0"; declare author "Abraham Walters"; declare license "BSD"; declare copyright "(c)quid 2021"; import("filter.lib"); import("music.lib"); import("stdfaust.lib"); depth = hslider("depth", 1, 0, 15, 0.01) : smooth(0.999); enabled = checkbox("enabled"); gain = hslider("gain", 0.1, 0, 1, 0.01) : smooth(0.999); rate = hslider("rate", 0.5, 0, 10, 0.01) : smooth(0.999); tremolo = hgroup("tremolo", osc(depth) * enabled); volume = gain * (1 + tremolo); left = 1 + osc(rate); right = 1 - osc(rate); autopanner = _ <: (left volume), (right volume); process = no.noise : autopanner;	https://raw.githubusercontent.com/quidmonkey/autopanner/5114cdc1068763f6ed8974211d46ee23e7ce4510/autopanner.dsp	faust		declare name "autopanner"; declare version "1.0"; declare author "Abraham Walters"; declare license "BSD"; declare copyright "(c)quid 2021"; import("filter.lib"); import("music.lib"); import("stdfaust.lib"); depth = hslider("depth", 1, 0, 15, 0.01) : smooth(0.999); enabled = checkbox("enabled"); gain = hslider("gain", 0.1, 0, 1, 0.01) : smooth(0.999); rate = hslider("rate", 0.5, 0, 10, 0.01) : smooth(0.999); tremolo = hgroup("tremolo", osc(depth) * enabled); volume = gain * (1 + tremolo); left = 1 + osc(rate); right = 1 - osc(rate); autopanner = _ <: (left volume), (right volume); process = no.noise : autopanner;
34c010c1c430b9fc8b67cf745bf504a6ffcc3bb4e6e8d9c38ba4d13ce2c3b47b	ThiloSch/Faust_Kick_Synthesizer	Live_patch.dsp	import("stdfaust.lib"); import("stdfaust.lib"); import("physmodels.lib"); // Trigger and global Gain trigger = button("gate"); // Amplitude Envelope attack = hslider("A",0.05,0.01,0.11,0.001); decay = 1; sustain = 0; release = hslider("/h:[1]envelope/Release",1, 0.1, 3, 0.001); // Filter control f_frequency = hslider("Cut Off", 900, 50, 4000, 1); qfactor = hslider("Q", 1,0.1,20,0.1); // Additional Controls physmix = hslider("mix",-1,-1,1,0.1); // Classic/Physical Mix sigType = hslider("Shape", 0, 0, 1.5, 0.01); // Signal Type frequency = hslider("/h:[0]Pitch/frequency", 50, 40, 100, 0.1); // Endfrequency p_release = 0.1; punch = hslider("Punch",0.5,0.001,1,0.001); //OSCILLATOR SECTION// //-----------------// oscillator_sin(sig) = signal with{ swing = pitcher(40+punch400, frequency, 0.04-punch0.030, p_release, trigger); coef = 1; signal = os.osc(swing) * coef ; // signal = 0; }; oscillator_tri(sig) = signal with{ swing = pitcher(40+punch400, frequency, 0.04-punch0.030, p_release, trigger); coef = select2(sig<2,0,select2(sig<1,2-sig,sig)); signal = os.triangle(swing)* coef ; }; oscillator_sqa(sig) = signal with{ swing = pitcher(40+punch400, frequency, 0.04-punch0.030, p_release, trigger); coef = select2(sig>1,0,select2(sig<2,3-sig,-1+sig)); signal = os.square(swing) * coef ; }; // Classic Approach with Pitch Envelope pitcher(start, end, sus, rel, trig) = freq with { //time raises/resets indefinitely when the trigger is pressed time = (raisereset + upfront) ~ _ with { upfront = trig > trig'; reset = trig <= trig'; raise(x) = (x + (x > 0)); }; // time = select2() susSamps = int(sus 44100); target = select2( susSamps>time, end, start); relPhase = susSamps < time; pole = ba.tau2pole(rel/6.91); freq = target : select2(relPhase, start, si.smooth(pole)); }; //-----------------// //PHYSICAL MODELLING SECTION// //-----------------// character = hslider("Character",0.5,0.001,1,0.001); physfreq = frequency; striker = pm.impulseExcitation(trigger) : chain; meshed = striker : drumModel(frequency,0,1,1,2000character) : (en.ar(attack,10,trigger)); // composite = 8meshed; // Extracted Modes drumModel(freq ,exPos,t60,t60DecayRatio,t60DecaySlope) = _ <: par(i,nModes,modeFilter(modesFreqs(i),modesT60s(i),modesGains(int(exPos),i))) :> /(nModes) with{ nModes = 40; nExPos = 5; modesFreqRatios(n) = ba.take(n+1,(0.496487 ,0.498829 ,0.510539 ,1.000000 ,1.402810 ,1.407494 ,1.510539 ,1.512881 ,1.562061 ,1.805621 ,1.807963 ,1.814988 ,2.032787 ,2.072600 ,2.081967 ,2.086651 ,2.100703 ,2.271663 ,2.278689 ,2.510539 ,2.576112 ,2.580796 ,2.608899 ,2.648712 ,2.660422 ,2.702576 ,2.711944 ,2.714286 ,2.777518 ,2.789227 ,2.868852 ,2.873536 ,3.133489 ,3.222482 ,3.224824 ,3.302108 ,3.318501 ,3.416862 ,3.444965 ,3.449649)); modesFreqs(i) = freq/(2-character1.5)modesFreqRatios(i); modesGains(p,n) = waveform{0.002800 ,0.002910 ,0.002828 ,1.000000 ,0.000329 ,0.261250 ,0.000724 ,0.004314 ,0.002937 ,0.009676 ,0.002475 ,0.003697 ,1.504010 ,0.030839 ,0.086771 ,0.000730 ,0.010672 ,0.000401 ,0.036587 ,0.002806 ,0.024838 ,0.000031 ,0.001831 ,0.000088 ,0.033158 ,0.004144 ,0.004803 ,0.002403 ,0.063744 ,0.000837 ,0.009838 ,0.001281 ,1.908791 ,0.005826 ,0.016356 ,0.000032 ,0.142409 ,0.004683 ,0.033018 ,0.001156},int(pnModes+n) : rdtable : select2(modesFreqs(n)<(ma.SR/2-1),0); modesT60s(i) = t60pow(1-(modesFreqRatios(i)/3000)t60DecayRatio,t60DecaySlope); }; //-----------------// process = ((oscillator_sin(sigType), oscillator_sqa(sigType), oscillator_tri(sigType)) :> _ * en.adsre(attack, decay, sustain, release, trigger))* (0.5(1-physmix) : sqrt) , composite(0.5*(1+physmix) : sqrt):> fi.resonlp(f_frequency,qfactor,1) <:_,_;	https://raw.githubusercontent.com/ThiloSch/Faust_Kick_Synthesizer/2a4136c85bbd10e2e68f928ebfae5d0a88c594c5/Live_patch.dsp	faust	Trigger and global Gain Amplitude Envelope Filter control Additional Controls Classic/Physical Mix Signal Type Endfrequency OSCILLATOR SECTION// -----------------// signal = 0; Classic Approach with Pitch Envelope time raises/resets indefinitely when the trigger is pressed time = select2() -----------------// PHYSICAL MODELLING SECTION// -----------------// Extracted Modes -----------------//	import("stdfaust.lib"); import("stdfaust.lib"); import("physmodels.lib"); trigger = button("gate"); attack = hslider("A",0.05,0.01,0.11,0.001); decay = 1; sustain = 0; release = hslider("/h:[1]envelope/Release",1, 0.1, 3, 0.001); f_frequency = hslider("Cut Off", 900, 50, 4000, 1); qfactor = hslider("Q", 1,0.1,20,0.1); p_release = 0.1; punch = hslider("Punch",0.5,0.001,1,0.001); oscillator_sin(sig) = signal with{ swing = pitcher(40+punch400, frequency, 0.04-punch0.030, p_release, trigger); coef = 1; signal = os.osc(swing) * coef ; }; oscillator_tri(sig) = signal with{ swing = pitcher(40+punch400, frequency, 0.04-punch0.030, p_release, trigger); coef = select2(sig<2,0,select2(sig<1,2-sig,sig)); signal = os.triangle(swing)* coef ; }; oscillator_sqa(sig) = signal with{ swing = pitcher(40+punch400, frequency, 0.04-punch0.030, p_release, trigger); coef = select2(sig>1,0,select2(sig<2,3-sig,-1+sig)); signal = os.square(swing) * coef ; }; pitcher(start, end, sus, rel, trig) = freq with { time = (raisereset + upfront) ~ _ with { upfront = trig > trig'; reset = trig <= trig'; raise(x) = (x + (x > 0)); }; susSamps = int(sus 44100); target = select2( susSamps>time, end, start); relPhase = susSamps < time; pole = ba.tau2pole(rel/6.91); freq = target : select2(relPhase, start, si.smooth(pole)); }; character = hslider("Character",0.5,0.001,1,0.001); physfreq = frequency; striker = pm.impulseExcitation(trigger) : chain; composite = 8meshed; drumModel(freq ,exPos,t60,t60DecayRatio,t60DecaySlope) = _ <: par(i,nModes,modeFilter(modesFreqs(i),modesT60s(i),modesGains(int(exPos),i))) :> /(nModes) with{ nModes = 40; nExPos = 5; modesFreqRatios(n) = ba.take(n+1,(0.496487 ,0.498829 ,0.510539 ,1.000000 ,1.402810 ,1.407494 ,1.510539 ,1.512881 ,1.562061 ,1.805621 ,1.807963 ,1.814988 ,2.032787 ,2.072600 ,2.081967 ,2.086651 ,2.100703 ,2.271663 ,2.278689 ,2.510539 ,2.576112 ,2.580796 ,2.608899 ,2.648712 ,2.660422 ,2.702576 ,2.711944 ,2.714286 ,2.777518 ,2.789227 ,2.868852 ,2.873536 ,3.133489 ,3.222482 ,3.224824 ,3.302108 ,3.318501 ,3.416862 ,3.444965 ,3.449649)); modesFreqs(i) = freq/(2-character1.5)modesFreqRatios(i); modesGains(p,n) = waveform{0.002800 ,0.002910 ,0.002828 ,1.000000 ,0.000329 ,0.261250 ,0.000724 ,0.004314 ,0.002937 ,0.009676 ,0.002475 ,0.003697 ,1.504010 ,0.030839 ,0.086771 ,0.000730 ,0.010672 ,0.000401 ,0.036587 ,0.002806 ,0.024838 ,0.000031 ,0.001831 ,0.000088 ,0.033158 ,0.004144 ,0.004803 ,0.002403 ,0.063744 ,0.000837 ,0.009838 ,0.001281 ,1.908791 ,0.005826 ,0.016356 ,0.000032 ,0.142409 ,0.004683 ,0.033018 ,0.001156},int(pnModes+n) : rdtable : select2(modesFreqs(n)<(ma.SR/2-1),0); modesT60s(i) = t60pow(1-(modesFreqRatios(i)/3000)t60DecayRatio,t60DecaySlope); }; process = ((oscillator_sin(sigType), oscillator_sqa(sigType), oscillator_tri(sigType)) :> _ * en.adsre(attack, decay, sustain, release, trigger))* (0.5(1-physmix) : sqrt) , composite(0.5*(1+physmix) : sqrt):> fi.resonlp(f_frequency,qfactor,1) <:_,_;
506ddf880a82c3d831c9cd6efbe6dc96907d2de292b8ae79d89f4121382a6acd	ArcAudio/FaustWebAudioInput	audioinput.dsp	import("stdfaust.lib"); vol = hslider("volume [unit:dB]", 0, -96, 0, 0.1) : ba.db2linear : si.smoo; freq = hslider("freq [unit:Hz]", 1000, 20, 24000, 1) : si.smoo; flanger(p,wet,depth) = _ <: de.delay(256,d)wet,_ :> /(2) with{ d = (os.osc(p) + 1)127depth; }; tremolo(fr,dep) = _(1-(os.osc(fr)0.5 + 0.5)dep); f = hslider("ffreq [unit:Hz]",10,0.1,100,0.01); w = hslider("fwet",0.5,0,1,0.01); d = hslider("fdepth",0.5,0,1,0.01); tf = hslider("tfreq [unit:Hz]",10,0.1,100,0.01); td = hslider("tdepth",0.5,0,1,0.01); gain = hslider("gain [knob:2] [midi:ctrl 7]", 0.5, 0, 1, 0.01); gate = button("gate [switch:1]"); process = + : flanger(f,w,d) : tremolo(tf,td) <: _,_;	https://raw.githubusercontent.com/ArcAudio/FaustWebAudioInput/f80bd1948e90725b1dcb1cf2945637d6c82fd651/audioinput.dsp	faust		import("stdfaust.lib"); vol = hslider("volume [unit:dB]", 0, -96, 0, 0.1) : ba.db2linear : si.smoo; freq = hslider("freq [unit:Hz]", 1000, 20, 24000, 1) : si.smoo; flanger(p,wet,depth) = _ <: de.delay(256,d)wet,_ :> /(2) with{ d = (os.osc(p) + 1)127depth; }; tremolo(fr,dep) = _(1-(os.osc(fr)0.5 + 0.5)dep); f = hslider("ffreq [unit:Hz]",10,0.1,100,0.01); w = hslider("fwet",0.5,0,1,0.01); d = hslider("fdepth",0.5,0,1,0.01); tf = hslider("tfreq [unit:Hz]",10,0.1,100,0.01); td = hslider("tdepth",0.5,0,1,0.01); gain = hslider("gain [knob:2] [midi:ctrl 7]", 0.5, 0, 1, 0.01); gate = button("gate [switch:1]"); process = + : flanger(f,w,d) : tremolo(tf,td) <: _,_;
ee640da4f890d724e1753b1694a3f46efa4f3e8d905f36ed26bcf511d7bc89ea	brummer10/slowmo.lv2	bandsplit.dsp	declare id "bandsplit"; declare name "Bandsplit"; declare category "Filter"; import("stdfaust.lib"); geq = fi.filterbank(3, (51.0, 160.0, 284.5, 427.0, 590.5, 778.0, 992.5, 1238.0, 1519.0, 1841.0, 2210.0, 2632.0, 3115.0, 3668.5, 4302.5, 5028.5, 5859.5)); process = geq;	https://raw.githubusercontent.com/brummer10/slowmo.lv2/1a32ab4e5b3740dab64e6f9dcce54baa9162a7bd/slowmo/Faust/bandsplit.dsp	faust		declare id "bandsplit"; declare name "Bandsplit"; declare category "Filter"; import("stdfaust.lib"); geq = fi.filterbank(3, (51.0, 160.0, 284.5, 427.0, 590.5, 778.0, 992.5, 1238.0, 1519.0, 1841.0, 2210.0, 2632.0, 3115.0, 3668.5, 4302.5, 5028.5, 5859.5)); process = geq;
4f5d0d3fc3477ff12609496794af7579a222542e74409778d9948326c1c0ed90	mathiasbredholt/MapLooper-faust	Faust.dsp	import("stdfaust.lib"); ctFreq = hslider("cutoffFrequency",500,50,3000,0.01); res = hslider("res",0.5,0,1,0.1); gain = hslider("gain",1,0,1,0.01); process = no.pink_noise : ve.moog_vcf(res,ctFreq) * gain;	https://raw.githubusercontent.com/mathiasbredholt/MapLooper-faust/6123f2489c356446b267f346cb2e07a80f21067c/main/Faust.dsp	faust		import("stdfaust.lib"); ctFreq = hslider("cutoffFrequency",500,50,3000,0.01); res = hslider("res",0.5,0,1,0.1); gain = hslider("gain",1,0,1,0.01); process = no.pink_noise : ve.moog_vcf(res,ctFreq) * gain;
44d70ea1458b988232de0ac8980ab3eea2726d283abdd87dc41557837e671bbc	Rhoumi/Comparator	phasor.dsp	import("stdfaust.lib"); phasor_imp(freq, reset, phase) = (select2(reset, +(freq/ma.SR), phase) : ma.decimal) ~ _; // Version to be used with tables phasor_table(tablesize, freq, reset, phase) = phasor_imp(freq, reset, phase) : *(float(tablesize)); phasor(tablesize, freq) = phasor_table(tablesize, freq, 0, 0); process = phasor(hslider("table",0.5,0.1,1,0.1),hslider("freq",440,20,3000,1));	https://raw.githubusercontent.com/Rhoumi/Comparator/3b3608310834a5c0d07eeb252bc31b4e70a2f711/phasor.dsp	faust	Version to be used with tables	import("stdfaust.lib"); phasor_imp(freq, reset, phase) = (select2(reset, +(freq/ma.SR), phase) : ma.decimal) ~ _; phasor_table(tablesize, freq, reset, phase) = phasor_imp(freq, reset, phase) : *(float(tablesize)); phasor(tablesize, freq) = phasor_table(tablesize, freq, 0, 0); process = phasor(hslider("table",0.5,0.1,1,0.1),hslider("freq",440,20,3000,1));
84f5a937a9ece238c2e57ee25f6a11e3c55a024a8b411f1a1ff9ecd861d240d8	abmwine/FreeBSD-ports	example.dsp	// from https://faustdoc.grame.fr/tutorials/basic-osc/ import("stdfaust.lib"); f = hslider("freq",440,50,2000,0.01); g = hslider("gain",1,0,1,0.01); t = si.smoo(button("gate")); phasor(freq) = (+(freq/ma.SR) ~ ma.frac); osc(freq) = sin(phasor(freq)2ma.PI); organ(freq) = (osc(freq) + osc(freq2) + osc(freq3))/3; process = organ(f)gt;	https://raw.githubusercontent.com/abmwine/FreeBSD-ports/af67f424b69f6f2ebc90c65fdaedb96140421201/audio/faust/files/example.dsp	faust	from https://faustdoc.grame.fr/tutorials/basic-osc/	import("stdfaust.lib"); f = hslider("freq",440,50,2000,0.01); g = hslider("gain",1,0,1,0.01); t = si.smoo(button("gate")); phasor(freq) = (+(freq/ma.SR) ~ ma.frac); osc(freq) = sin(phasor(freq)2ma.PI); organ(freq) = (osc(freq) + osc(freq2) + osc(freq3))/3; process = organ(f)gt;
4dd3dabe43e111eb899e3f61c0465374611e30392d0c38c9259c6db915ae5d48	neidhub/smallest-synth	faustSynth.dsp	import("stdfaust.lib"); freq = nentry("freq", 400, 0, 20000, 0.1); //gain = nentry("gain", 0.5, 0, 1, 0.01); gate = button("gate") : si.smoo; // Teensy Oscillator // lowering the resolution of the sine oscillators' lookup table // in order to make computation easier on the Teensy MCU and memory // from https://github.com/makingsoundmachines/Faust-on-Teensy/blob/main/AdditiveSynth_Faust/faustAdditive.dsp oscTeensy(f) = rdtable(tablesize, os.sinwaveform(tablesize), int(os.phasor(tablesize,f))) with{ tablesize = 1 << 13; // instead of 1 << 16 }; process = oscTeensy(freq)*gate;	https://raw.githubusercontent.com/neidhub/smallest-synth/9c31dbfcea644038ea8a5565306b38d41f3536a0/generic/faustSynth.dsp	faust	gain = nentry("gain", 0.5, 0, 1, 0.01); Teensy Oscillator lowering the resolution of the sine oscillators' lookup table in order to make computation easier on the Teensy MCU and memory from https://github.com/makingsoundmachines/Faust-on-Teensy/blob/main/AdditiveSynth_Faust/faustAdditive.dsp instead of 1 << 16	import("stdfaust.lib"); freq = nentry("freq", 400, 0, 20000, 0.1); gate = button("gate") : si.smoo; oscTeensy(f) = rdtable(tablesize, os.sinwaveform(tablesize), int(os.phasor(tablesize,f))) with{ }; process = oscTeensy(freq)*gate;
8f24909e57aaff7e79b8bf1f4d14ff475eded4f35ec9cce20b3ec8453ea3617b	aike/audiolang	delay.dsp	// compile: faust2sndfile delay.dsp // run: ./delay ../voice.wav voice_with_fx.wav import("stdfaust.lib"); maxDelayTime = 1.0; delayTime = 0.4; feedback = 0.5; process = ef.echo(maxDelayTime, delayTime, feedback) <: _,_;	https://raw.githubusercontent.com/aike/audiolang/1a211888945eed4257d6078eff83af32068a550a/faust/delay.dsp	faust	compile: faust2sndfile delay.dsp run: ./delay ../voice.wav voice_with_fx.wav	import("stdfaust.lib"); maxDelayTime = 1.0; delayTime = 0.4; feedback = 0.5; process = ef.echo(maxDelayTime, delayTime, feedback) <: _,_;
e8a9365c095da5f82638980f62ed432f8336f008429f9fe8360f469416b1ed41	cengizozel/SynthesizerWithFaust	ESQ.dsp	import("stdfaust.lib"); gain = hslider("v:Synth/v:[1]Edit/[0]Volume", 0.2, 0, 1, 0.01); freq = hslider("v:Synth/v:[1]Edit/[1]Frequency", 262, 50, 1000, 0.1); pw = hslider("v:Synth/v:[1]Edit/[2]PW", 0.5, 0, 1, 0.001); cutoff = hslider("v:Synth/v:[1]Edit/[3]Cutoff",10000,50,10000,0.01); Q = hslider("v:Synth/v:[1]Edit/[4]Q",1,1,30,0.1); saw = os.lf_saw(freq); square = os.pulsetrain(freq, pw); sawCB = checkbox("v:Synth/h:[0]Waveform/[0]Saw")saw; squareCB = checkbox("v:Synth/h:[0]Waveform/[1]Square")square; cutoffEffect = fi.resonlp(cutoff,Q,gain); process = sawCB, squareCB :> _,gain : * <: attach(_,abs : ba.linear2db : hbargraph("v:Synth/v:[1]Edit/[5]Level",-60,0)) : cutoffEffect <: _,_;	https://raw.githubusercontent.com/cengizozel/SynthesizerWithFaust/33078869473f410970a17f743ecfbe77456efd5f/ESQ.dsp	faust		import("stdfaust.lib"); gain = hslider("v:Synth/v:[1]Edit/[0]Volume", 0.2, 0, 1, 0.01); freq = hslider("v:Synth/v:[1]Edit/[1]Frequency", 262, 50, 1000, 0.1); pw = hslider("v:Synth/v:[1]Edit/[2]PW", 0.5, 0, 1, 0.001); cutoff = hslider("v:Synth/v:[1]Edit/[3]Cutoff",10000,50,10000,0.01); Q = hslider("v:Synth/v:[1]Edit/[4]Q",1,1,30,0.1); saw = os.lf_saw(freq); square = os.pulsetrain(freq, pw); sawCB = checkbox("v:Synth/h:[0]Waveform/[0]Saw")saw; squareCB = checkbox("v:Synth/h:[0]Waveform/[1]Square")square; cutoffEffect = fi.resonlp(cutoff,Q,gain); process = sawCB, squareCB :> _,gain : * <: attach(_,abs : ba.linear2db : hbargraph("v:Synth/v:[1]Edit/[5]Level",-60,0)) : cutoffEffect <: _,_;
248bc47cae723eb89593c70f897b4bf14739802a08602d6f053bc17345e9a9f2	bkfox/foxlive	echo.dsp	import("stdfaust.lib"); maxDuration = nentry("max duration", 10, 0, 20, 0.1); duration = nentry("duration", 5, 0, 10, 0.1); feedback = nentry("feedback", 0.5, 0, 1, 0.01); process = ef.echo(maxDuration,duration,feedback);	https://raw.githubusercontent.com/bkfox/foxlive/690ec8e74a387e8ca1ef0fd0b37d95fcf98e146f/libfoxlive/src/dsp/plugins/echo.dsp	faust		import("stdfaust.lib"); maxDuration = nentry("max duration", 10, 0, 20, 0.1); duration = nentry("duration", 5, 0, 10, 0.1); feedback = nentry("feedback", 0.5, 0, 1, 0.01); process = ef.echo(maxDuration,duration,feedback);
72c3d9a4ceff4ab1a8a4a307d884c52c3921648db8be28bd45bdedc7068c2db9	schollz/norns-ugens	FaustZitaRevLight.dsp	declare name "FaustZitaVerbLight"; import("stdfaust.lib"); process = re.zita_rev1_stereo(pre_del, lf_x, hf_damp, low_rt60, mid_rt60, fsmax) with{ fsmax = 48000.0; pre_del = vslider("[1] pre_del [unit:ms] [tooltip: reverb pre-delay ]", 20, 0, 200, 1); lf_x = vslider("[2] lf_x [unit:Hz] [scale:log] [tooltip: low band cutoff frequency ] ", 200, 30, 1200, 1); low_rt60 = vslider("[3] low_rt60 [unit:s] [tooltip: -60db decay time for low band ]", 1, 0.1, 3, 0.1); mid_rt60 = vslider("[4] mid_rt60 [unit:s] [tooltip: -60db decay time for middle band ]", 1, 0.1, 3, 0.1); hf_damp = vslider("[5] hf_damp [unit:Hz] [tooltip: damping frequency (decay time is 1/2 mid) ] [scale:log]", 6000, 1200, 0.49*fsmax, 1); };	https://raw.githubusercontent.com/schollz/norns-ugens/f9ad0805afb898f68c4fb8031c7eb1062fb2d078/FaustZitaRevLight/FaustZitaRevLight.dsp	faust		declare name "FaustZitaVerbLight"; import("stdfaust.lib"); process = re.zita_rev1_stereo(pre_del, lf_x, hf_damp, low_rt60, mid_rt60, fsmax) with{ fsmax = 48000.0; pre_del = vslider("[1] pre_del [unit:ms] [tooltip: reverb pre-delay ]", 20, 0, 200, 1); lf_x = vslider("[2] lf_x [unit:Hz] [scale:log] [tooltip: low band cutoff frequency ] ", 200, 30, 1200, 1); low_rt60 = vslider("[3] low_rt60 [unit:s] [tooltip: -60db decay time for low band ]", 1, 0.1, 3, 0.1); mid_rt60 = vslider("[4] mid_rt60 [unit:s] [tooltip: -60db decay time for middle band ]", 1, 0.1, 3, 0.1); hf_damp = vslider("[5] hf_damp [unit:Hz] [tooltip: damping frequency (decay time is 1/2 mid) ] [scale:log]", 6000, 1200, 0.49*fsmax, 1); };
4847df7344f24a2b99e137823128b639c9cb3e7d29374be7807a7388c4e5adae	REIS0/AkoFlanger	akoflanger.dsp	declare filename "akoflanger.dsp"; declare name "AkoFlanger"; declare author "REIS0"; declare license "GNU GPLv3"; declare version "0.1"; import("stdfaust.lib"); max_delay = ma.SR * 0.005; min_delay = ma.SR * 0.002; freq = hslider("[0]Frequency", 1, 0.1, 2, 0.01) : si.smooth(0.999); lfo = ((os.osc(freq) * 0.85) * 0.5) + 0.5; ldelay = min_delay + (lfo * (max_delay - min_delay)); flanger(depth, regen) = (+ <: de.fdelay(max_delay, ldelay) * depth, _) ~ (regen) : + : (0.5); akoflanger = _ <: flanger(depth, regen), _ : (dry_wet), (1-dry_wet) : + : fi.lowpass(1, 22000) with{ depth = hslider("[1]Depth", 0.5, 0.1, 0.9, 0.01) : si.smooth(0.999); regen = hslider("[2]Regen", 0.25, 0.0, 0.5, 0.01); dry_wet = hslider("[3]Dry/Wet", 0.5, 0, 1, 0.01) : si.smooth(0.999); }; process = akoflanger, akoflanger;	https://raw.githubusercontent.com/REIS0/AkoFlanger/e2d477f2845ce77790908f380da182ea4ed60c17/plugins/AkoFlanger/faust/akoflanger.dsp	faust		declare filename "akoflanger.dsp"; declare name "AkoFlanger"; declare author "REIS0"; declare license "GNU GPLv3"; declare version "0.1"; import("stdfaust.lib"); max_delay = ma.SR * 0.005; min_delay = ma.SR * 0.002; freq = hslider("[0]Frequency", 1, 0.1, 2, 0.01) : si.smooth(0.999); lfo = ((os.osc(freq) * 0.85) * 0.5) + 0.5; ldelay = min_delay + (lfo * (max_delay - min_delay)); flanger(depth, regen) = (+ <: de.fdelay(max_delay, ldelay) * depth, _) ~ (regen) : + : (0.5); akoflanger = _ <: flanger(depth, regen), _ : (dry_wet), (1-dry_wet) : + : fi.lowpass(1, 22000) with{ depth = hslider("[1]Depth", 0.5, 0.1, 0.9, 0.01) : si.smooth(0.999); regen = hslider("[2]Regen", 0.25, 0.0, 0.5, 0.01); dry_wet = hslider("[3]Dry/Wet", 0.5, 0, 1, 0.01) : si.smooth(0.999); }; process = akoflanger, akoflanger;
1a5d5d5bab55b4d4bcebd98bfbc13a29b4b13b813b501e8960f569f00c695f4f	mariaelenafenu8/faustcode	lezione0.dsp	// questo è un commento // un commento è una riga di codice ignorata dal compilatore // il testo che segue è un programma di faust // faust è un linguaggio di progammazione funzionale // crea applicazioni per il trattamento digitale del segnale // dsp = digital signal processing import("stdfaust.lib"); // importare la libreria standard di faust process = +; // in ogni rpogramma c'è un solo process = qualcosa ; //faust segue il contenuto di process // ogni riga deve finire con un * ; * // gli operatori matematici sono * + - * / *	https://raw.githubusercontent.com/mariaelenafenu8/faustcode/1985eaed9fcb9bdd9c45efcebd58606d4b767307/lezione0.dsp	faust	questo è un commento un commento è una riga di codice ignorata dal compilatore il testo che segue è un programma di faust faust è un linguaggio di progammazione funzionale crea applicazioni per il trattamento digitale del segnale dsp = digital signal processing importare la libreria standard di faust in ogni rpogramma c'è un solo process = qualcosa ; faust segue il contenuto di process ogni riga deve finire con un * ; * gli operatori matematici sono * + - * / *
8ab59d3b81b4d42ae40c8f47057108973fff1e646a40ce01075a94308382dd82	JuanSaudio/AudioDevKitDemo	FaustDistortion.dsp	// Faust Example of simple distortion import("stdfaust.lib"); // Define Sliders bias = hslider("Bias",0,0,1,0.001); drive = hslider("Drive",0,-20,20,0.1) : ba.db2linear; outGain = hslider("Level",0,-20,20,0.1) : ba.db2linear; // Define Non Linearity nonLinearity = atan((drive * _ + bias) * ma.PI / 2.0) * 2.0 / ma.PI * outGain; // Process removing DC process = _ : nonLinearity : fi.dcblocker; // faust FaustDistortion.dsp -o Source/FaustDistortion.h -cn Distortion -ns faust	https://raw.githubusercontent.com/JuanSaudio/AudioDevKitDemo/fb644c3b528de6d7be5c8ed2e7b30f9414660bae/Distortion/FaustDistortion.dsp	faust	Faust Example of simple distortion Define Sliders Define Non Linearity Process removing DC faust FaustDistortion.dsp -o Source/FaustDistortion.h -cn Distortion -ns faust	import("stdfaust.lib"); bias = hslider("Bias",0,0,1,0.001); drive = hslider("Drive",0,-20,20,0.1) : ba.db2linear; outGain = hslider("Level",0,-20,20,0.1) : ba.db2linear; nonLinearity = atan((drive * _ + bias) * ma.PI / 2.0) * 2.0 / ma.PI * outGain; process = _ : nonLinearity : fi.dcblocker;
849fba124fa1e0ef261eefaf62fa21fb3a8be78dbf2b17b887139a3ee854960c	ThiloSch/Faust_Kick_Synthesizer	Sampling_patch.dsp	import("stdfaust.lib"); import("stdfaust.lib"); import("physmodels.lib"); // Trigger and global Gain trigger = button("gate"); // Amplitude Envelope attack = 0.03; decay = 1; sustain = 0; release = hslider("/h:[1]envelope/Release",1, 0.05, 3, 0.001); // Filter control f_frequency = hslider("Cut Off", 900, 50, 4000, 1); qfactor = hslider("Q", 1,0.1,20,0.1); // Additional Controls physmix = hslider("mix",-1,-1,1,0.01); // Classic/Physical Mix sigType = hslider("Shape", 0, 0, 1.5, 0.01); // Signal Type // Pitch Controls p_note = hslider("/h:[0]Pitch/Pitch Note",250,40, 1000, 0.1); // Starting Pitch frequency = hslider("/h:[0]Pitch/frequency", 50, 40, 100, 0.1); // Endfrequency p_sustain = hslider("/h:[0]Pitch/Pitch Sustain", 0.02, 0.001, 0.05, 0.001); // Pitch Sustain p_release = hslider("/h:[0]Pitch/Pitch Release",0.1, 0.001, 3, 0.001); // Pitch release //OSCILLATOR SECTION// //-----------------// oscillator_sin(sig) = signal with{ swing = pitcher(p_note, frequency, p_sustain, p_release, trigger); coef = 1; signal = os.osc(swing) * coef ; }; oscillator_tri(sig) = signal with{ swing = pitcher(p_note, frequency, p_sustain, p_release, trigger); coef = select2(sig<2,0,select2(sig<1,2-sig,sig)); signal = os.triangle(swing)* coef ; }; oscillator_sqa(sig) = signal with{ swing = pitcher(p_note, frequency, p_sustain, p_release, trigger); coef = select2(sig>1,0,select2(sig<2,3-sig,-1+sig)); signal = os.square(swing) * coef ; }; // Classic Approach with Pitch Envelope pitcher(start, end, sus, rel, trig) = freq with { //time raises/resets indefinitely when the trigger is pressed time = (raisereset + upfront) ~ _ with { upfront = trig > trig'; reset = trig <= trig'; raise(x) = (x + (x > 0)); }; susSamps = int(sus 44100); target = select2( susSamps>time, end, start); relPhase = susSamps < time; pole = ba.tau2pole(rel/6.91); freq = target : select2(relPhase, start, si.smooth(pole)); }; //-----------------// //PHYSICAL MODELLING SECTION// //-----------------// meshdecay = hslider("/h:[3]Physical Modelling/Damping",25,1,2000,0.01); phystune = hslider("/h:[3]Physical Modelling/Pitch",1,0,1,0.01); physfreq = frequency; striker = pm.impulseExcitation(trigger) : chain; meshed = striker : drumModel(frequency,0,1,1,meshdecay) : (en.ar(0.03,10,trigger)); // composite = 8meshed; // Extracted Modes drumModel(freq ,exPos,t60,t60DecayRatio,t60DecaySlope) = _ <: par(i,nModes,modeFilter(modesFreqs(i),modesT60s(i),modesGains(int(exPos),i))) :> /(nModes) with{ nModes = 40; nExPos = 5; modesFreqRatios(n) = ba.take(n+1,(0.496487 ,0.498829 ,0.510539 ,1.000000 ,1.402810 ,1.407494 ,1.510539 ,1.512881 ,1.562061 ,1.805621 ,1.807963 ,1.814988 ,2.032787 ,2.072600 ,2.081967 ,2.086651 ,2.100703 ,2.271663 ,2.278689 ,2.510539 ,2.576112 ,2.580796 ,2.608899 ,2.648712 ,2.660422 ,2.702576 ,2.711944 ,2.714286 ,2.777518 ,2.789227 ,2.868852 ,2.873536 ,3.133489 ,3.222482 ,3.224824 ,3.302108 ,3.318501 ,3.416862 ,3.444965 ,3.449649)); modesFreqs(i) = freq/(2-phystune1.5)modesFreqRatios(i); modesGains(p,n) = waveform{0.002800 ,0.002910 ,0.002828 ,1.000000 ,0.000329 ,0.261250 ,0.000724 ,0.004314 ,0.002937 ,0.009676 ,0.002475 ,0.003697 ,1.504010 ,0.030839 ,0.086771 ,0.000730 ,0.010672 ,0.000401 ,0.036587 ,0.002806 ,0.024838 ,0.000031 ,0.001831 ,0.000088 ,0.033158 ,0.004144 ,0.004803 ,0.002403 ,0.063744 ,0.000837 ,0.009838 ,0.001281 ,1.908791 ,0.005826 ,0.016356 ,0.000032 ,0.142409 ,0.004683 ,0.033018 ,0.001156},int(pnModes+n) : rdtable : select2(modesFreqs(n)<(ma.SR/2-1),0); modesT60s(i) = t60pow(1-(modesFreqRatios(i)/3000)t60DecayRatio,t60DecaySlope); }; //-----------------// process = ((oscillator_sin(sigType), oscillator_sqa(sigType), oscillator_tri(sigType)) :> _ en.adsre(attack, decay, sustain, release, trigger))* (0.5(1-physmix) : sqrt) , composite(0.5*(1+physmix) : sqrt):> fi.resonlp(f_frequency,qfactor,1) <:_,_;	https://raw.githubusercontent.com/ThiloSch/Faust_Kick_Synthesizer/2a4136c85bbd10e2e68f928ebfae5d0a88c594c5/Sampling_patch.dsp	faust	Trigger and global Gain Amplitude Envelope Filter control Additional Controls Classic/Physical Mix Signal Type Pitch Controls Starting Pitch Endfrequency Pitch Sustain Pitch release OSCILLATOR SECTION// -----------------// Classic Approach with Pitch Envelope time raises/resets indefinitely when the trigger is pressed -----------------// PHYSICAL MODELLING SECTION// -----------------// Extracted Modes -----------------//	import("stdfaust.lib"); import("stdfaust.lib"); import("physmodels.lib"); trigger = button("gate"); attack = 0.03; decay = 1; sustain = 0; release = hslider("/h:[1]envelope/Release",1, 0.05, 3, 0.001); f_frequency = hslider("Cut Off", 900, 50, 4000, 1); qfactor = hslider("Q", 1,0.1,20,0.1); oscillator_sin(sig) = signal with{ swing = pitcher(p_note, frequency, p_sustain, p_release, trigger); coef = 1; signal = os.osc(swing) * coef ; }; oscillator_tri(sig) = signal with{ swing = pitcher(p_note, frequency, p_sustain, p_release, trigger); coef = select2(sig<2,0,select2(sig<1,2-sig,sig)); signal = os.triangle(swing)* coef ; }; oscillator_sqa(sig) = signal with{ swing = pitcher(p_note, frequency, p_sustain, p_release, trigger); coef = select2(sig>1,0,select2(sig<2,3-sig,-1+sig)); signal = os.square(swing) * coef ; }; pitcher(start, end, sus, rel, trig) = freq with { time = (raisereset + upfront) ~ _ with { upfront = trig > trig'; reset = trig <= trig'; raise(x) = (x + (x > 0)); }; susSamps = int(sus 44100); target = select2( susSamps>time, end, start); relPhase = susSamps < time; pole = ba.tau2pole(rel/6.91); freq = target : select2(relPhase, start, si.smooth(pole)); }; meshdecay = hslider("/h:[3]Physical Modelling/Damping",25,1,2000,0.01); phystune = hslider("/h:[3]Physical Modelling/Pitch",1,0,1,0.01); physfreq = frequency; striker = pm.impulseExcitation(trigger) : chain; composite = 8meshed; drumModel(freq ,exPos,t60,t60DecayRatio,t60DecaySlope) = _ <: par(i,nModes,modeFilter(modesFreqs(i),modesT60s(i),modesGains(int(exPos),i))) :> /(nModes) with{ nModes = 40; nExPos = 5; modesFreqRatios(n) = ba.take(n+1,(0.496487 ,0.498829 ,0.510539 ,1.000000 ,1.402810 ,1.407494 ,1.510539 ,1.512881 ,1.562061 ,1.805621 ,1.807963 ,1.814988 ,2.032787 ,2.072600 ,2.081967 ,2.086651 ,2.100703 ,2.271663 ,2.278689 ,2.510539 ,2.576112 ,2.580796 ,2.608899 ,2.648712 ,2.660422 ,2.702576 ,2.711944 ,2.714286 ,2.777518 ,2.789227 ,2.868852 ,2.873536 ,3.133489 ,3.222482 ,3.224824 ,3.302108 ,3.318501 ,3.416862 ,3.444965 ,3.449649)); modesFreqs(i) = freq/(2-phystune1.5)modesFreqRatios(i); modesGains(p,n) = waveform{0.002800 ,0.002910 ,0.002828 ,1.000000 ,0.000329 ,0.261250 ,0.000724 ,0.004314 ,0.002937 ,0.009676 ,0.002475 ,0.003697 ,1.504010 ,0.030839 ,0.086771 ,0.000730 ,0.010672 ,0.000401 ,0.036587 ,0.002806 ,0.024838 ,0.000031 ,0.001831 ,0.000088 ,0.033158 ,0.004144 ,0.004803 ,0.002403 ,0.063744 ,0.000837 ,0.009838 ,0.001281 ,1.908791 ,0.005826 ,0.016356 ,0.000032 ,0.142409 ,0.004683 ,0.033018 ,0.001156},int(pnModes+n) : rdtable : select2(modesFreqs(n)<(ma.SR/2-1),0); modesT60s(i) = t60pow(1-(modesFreqRatios(i)/3000)t60DecayRatio,t60DecaySlope); }; process = ((oscillator_sin(sigType), oscillator_sqa(sigType), oscillator_tri(sigType)) :> _ * en.adsre(attack, decay, sustain, release, trigger))* (0.5(1-physmix) : sqrt) , composite(0.5*(1+physmix) : sqrt):> fi.resonlp(f_frequency,qfactor,1) <:_,_;
156273a6647e84fdc8dcd4efd143946e9f0b254c1f441358759227262837d275	oshibka404/sound_design	osc1.dsp	import("stdfaust.lib"); cc = library("midi_cc.dsp"); process = os.sawtooth(cc.freq);	https://raw.githubusercontent.com/oshibka404/sound_design/8d0505f4f6e76db08f52061b2b5f9a76079147b9/DSP/oscillators/osc1.dsp	faust		import("stdfaust.lib"); cc = library("midi_cc.dsp"); process = os.sawtooth(cc.freq);
627dd245221ca502c4d6273f15528518799f4f57b3d748c0f123a08d6250e137	oshibka404/sound_design	osc2.dsp	import("stdfaust.lib"); cc = library("midi_cc.dsp"); process = os.triangle(cc.freq);	https://raw.githubusercontent.com/oshibka404/sound_design/8d0505f4f6e76db08f52061b2b5f9a76079147b9/DSP/oscillators/osc2.dsp	faust		import("stdfaust.lib"); cc = library("midi_cc.dsp"); process = os.triangle(cc.freq);
ce1fa1b7bce3000faf0827ec82c665bf92274147cc30fc876707f4a1ff8a61ad	LSSN/2020-01-23-2a-dsp-giulialorenzonii	verifica sottrattiva.dsp	import("stdfaust.lib"); process= fi.highpass(4,1000) : fi.lowpass(4,1000); //il filtro passa basso è un programma che opera su un segnale infiltraggio delle altefrequenze a partire da 1000 Hz. //il punto di taglio espresso in hertz indica il punto in cui l'ampiezza del segnale d'entrata viene attenuata a 3 dB. //fi.highpass ha un'entrata mentre fi.lowpass non ce l'ha, ma ha un'uscita.	https://raw.githubusercontent.com/LSSN/2020-01-23-2a-dsp-giulialorenzonii/06cf2c220e88e8facf662f4f968a7d934bed4bda/verifica%20sottrattiva.dsp	faust	il filtro passa basso è un programma che opera su un segnale infiltraggio delle altefrequenze a partire da 1000 Hz. il punto di taglio espresso in hertz indica il punto in cui l'ampiezza del segnale d'entrata viene attenuata a 3 dB. fi.highpass ha un'entrata mentre fi.lowpass non ce l'ha, ma ha un'uscita.	import("stdfaust.lib"); process= fi.highpass(4,1000) : fi.lowpass(4,1000);
8f6839631f1d9b1e0f098c226657b77253ec946224b54fbf32e8c92e07bbf746	consba/Segnale-Bilanciato	balanced.dsp	import("stdfaust.lib"); sorgente = os.osc(1000); // os. puntatore lib oscillatori bilanciatore = _ <: _, 0-_; // A <: B "divide" : replica il segnale A in nA volte in B ricevitore = _+(0-_) : /(2); //rumore = _ + no.noise, _ + no.noise; rumore = par(i, 2, _ + no.noise); //par fa n volte la funzione in parallelo process = sorgente : bilanciatore : rumore : ricevitore; //process = no.noise;	https://raw.githubusercontent.com/consba/Segnale-Bilanciato/c07dc4a7701afecbd4c29855a17d164b547931c1/balanced.dsp	faust	os. puntatore lib oscillatori A <: B "divide" : replica il segnale A in nA volte in B rumore = _ + no.noise, _ + no.noise; par fa n volte la funzione in parallelo process = no.noise;	import("stdfaust.lib"); ricevitore = _+(0-_) : /(2); process = sorgente : bilanciatore : rumore : ricevitore;
96fe9dffb4ef52036938ee508ba8d12476524855504238dee0d2c0f8f4814076	Sinuslabs/Reach	Flanger.dsp	declare name "flanger"; declare version "0.0"; declare author "JOS, revised by RM"; declare description "Flanger effect application."; import("stdfaust.lib"); process = dm.flanger_demo;	https://raw.githubusercontent.com/Sinuslabs/Reach/1e716dfc0640d73b9385970049c1dc6a6498ece5/DspNetworks/CodeLibrary/faust/Flanger.dsp	faust		declare name "flanger"; declare version "0.0"; declare author "JOS, revised by RM"; declare description "Flanger effect application."; import("stdfaust.lib"); process = dm.flanger_demo;
14584a98b37f45c3910de02940306d8c1525e7643a625963c4c5b1d81d5ee77a	consba/Segnale-Bilanciato	saw.dsp	import("stdfaust.lib"); saw(N,f) = par(i, N, os.osc(f(i+1))/(i+1)) :> _ /(2); filtro(N,f) = seq(i,N,eavg(acor(f))); eavg(a) = (a) : +~(1-a); acor(fc) = cos(omega(fc))-1+sqrt(cosq(omega(fc))-4cos(omega(fc))+3); omega(fc) = fctwopi/ma.SR; twopi = 2ma.PI; cosq(x) = cos(x)cos(x); process = par(i, 6, saw(100,(220+(i(sqrt(2)))))) :> _ : /(6) : filtro(10,2000);	https://raw.githubusercontent.com/consba/Segnale-Bilanciato/c07dc4a7701afecbd4c29855a17d164b547931c1/saw.dsp	faust		import("stdfaust.lib"); saw(N,f) = par(i, N, os.osc(f(i+1))/(i+1)) :> _ /(2); filtro(N,f) = seq(i,N,eavg(acor(f))); eavg(a) = (a) : +~(1-a); acor(fc) = cos(omega(fc))-1+sqrt(cosq(omega(fc))-4cos(omega(fc))+3); omega(fc) = fctwopi/ma.SR; twopi = 2ma.PI; cosq(x) = cos(x)cos(x); process = par(i, 6, saw(100,(220+(i(sqrt(2)))))) :> _ : /(6) : filtro(10,2000);
804a7da45c93e7ff113841c84012122e84eef24e3617f7421825fe01d19d4639	geofholbrook/sequence-collab	dumbMarimba.dsp	import("stdfaust.lib"); freq = nentry("freq", 100, 10, 10000, 1); gain = nentry("gain", 1, 0, 1, .01); process = pm.marimba(freq / 2, 1, 7000, 0.25, gain, button("gate"));	https://raw.githubusercontent.com/geofholbrook/sequence-collab/779c0d085f67dec2f6842b130b8474c7ed367163/src/sound-generation/faust/dsp-files/dumbMarimba.dsp	faust		import("stdfaust.lib"); freq = nentry("freq", 100, 10, 10000, 1); gain = nentry("gain", 1, 0, 1, .01); process = pm.marimba(freq / 2, 1, 7000, 0.25, gain, button("gate"));
8b13630e4a626dec067b6072228bcc1074d8927ee945388759ca3c3eca5f258b	CICM/pd-faustgen	resonator.dsp	import("stdfaust.lib"); // Example programmed by Christophe Lebreton - GRAME f(i) = hslider("freq%3i", 160.,-0.,20000.,0.001); r(i) = hslider("decay%3i", 0.,0.,1.,0.001):((pow(4.78)6)+0.0001):ba.tau2pole; g(i) = hslider("gain%3i", 0.,0.,1.,0.0001); resonator(n) = _<:par(i,n,(g(i)):fi.nlf2(f(i),r(i)):_,!:(ba.db2linear((100(log(1/r(i))))))):>*(0.003162); process = resonator(20) ;	https://raw.githubusercontent.com/CICM/pd-faustgen/9e2aaeabe94a7fab6928711050535ac12a1a591a/external/examples/resonator.dsp	faust	Example programmed by Christophe Lebreton - GRAME	import("stdfaust.lib"); f(i) = hslider("freq%3i", 160.,-0.,20000.,0.001); r(i) = hslider("decay%3i", 0.,0.,1.,0.001):((pow(4.78)6)+0.0001):ba.tau2pole; g(i) = hslider("gain%3i", 0.,0.,1.,0.0001); resonator(n) = _<:par(i,n,(g(i)):fi.nlf2(f(i),r(i)):_,!:(ba.db2linear((100(log(1/r(i))))))):>*(0.003162); process = resonator(20) ;
35729d22c18393772b45664dfed53998a21c25e9c51815b4f79b29768006b2d1	LSSN/Panner	Pan.dsp	declare name "Pan"; import("stdfaust.lib"); // panning di ampiezza pan = vslider("pan [style:knob]", 0.5,0,1,0.01); process = _<: // separatore _ * (1-pan), // left _ * (pan); // right	https://raw.githubusercontent.com/LSSN/Panner/9868ac3a446d63c8f1fbd2c68588d5f8080b9c57/Pan.dsp	faust	panning di ampiezza separatore left right	declare name "Pan"; import("stdfaust.lib"); pan = vslider("pan [style:knob]", 0.5,0,1,0.01);
a0166bfae987924cd77f8561e6954f65b38f5e2266bc01d9201e1c1819356774	LSSN/Panner	pan1.dsp	import("stdfaust.lib"); // panning con 2 attenuatori di livello indipendenti process = _<: // separatore hgroup("pan", vslider("left", 0,0,1,0.01)_, // attenuatore sinistro vslider("right", 0,0,1,0.01)_); // attenuatore destro	https://raw.githubusercontent.com/LSSN/Panner/9868ac3a446d63c8f1fbd2c68588d5f8080b9c57/pan1.dsp	faust	panning con 2 attenuatori di livello indipendenti separatore attenuatore sinistro attenuatore destro	import("stdfaust.lib"); hgroup("pan",
8d81e7ed8c3d8e55f5d89cd9191877e9e04d9f3ff8ee9d6ed5a7bc881c4f5517	troopersinger/audio	IPlugFaustDSP.dsp	declare name "FaustExample"; import("stdfaust.lib"); g = vslider("Gain", 1, 0., 1, 0.1); process = os.osc(200), os.osc(1000) * g;	https://raw.githubusercontent.com/troopersinger/audio/1b4a376f9afb0590ac62685e741ba7902dfaa4c5/Examples/IPlugFaustDSP/IPlugFaustDSP.dsp	faust		declare name "FaustExample"; import("stdfaust.lib"); g = vslider("Gain", 1, 0., 1, 0.1); process = os.osc(200), os.osc(1000) * g;
38317dd3ff0e894ef4f4b97d2ec2ebc17fcbcac093387b9963c932d966109657	Jacajack/stm32-faust-synth	noise.dsp	import("stdfaust.lib"); process = no.noise;	https://raw.githubusercontent.com/Jacajack/stm32-faust-synth/5987bc2508e94318affbbccaaeaea0fd7f7ad694/faust/noise.dsp	faust		import("stdfaust.lib"); process = no.noise;
8121593a2c0b7ca383be0d34b9f2827174f33f65171b5c36dd127eab32f454da	LSSN/Panner	Pansqrt.dsp	declare name "Pansqrt"; import("stdfaust.lib"); // panning di ampiezza quadratico pan = vslider("pan [style:knob]", 0.5,0,1,0.01); process = _<: // separatore _ * ((1-pan) : sqrt), // left _ * ((pan) : sqrt); // right	https://raw.githubusercontent.com/LSSN/Panner/9868ac3a446d63c8f1fbd2c68588d5f8080b9c57/Pansqrt.dsp	faust	panning di ampiezza quadratico separatore left right	declare name "Pansqrt"; import("stdfaust.lib"); pan = vslider("pan [style:knob]", 0.5,0,1,0.01);
f734742b1561209369946f748a5bf31af17723bd5f9949dfb8469f18a192c996	diegomonteagudo/TC-SON	testSynth.dsp	import("stdfaust.lib"); res = 2; frequence = hslider("frequence",262,20,10000,0.1); gate = button("gate"); gain = hslider("gain",1,0,1,0.1); process = gain*sy.combString(frequence,res,gate);	https://raw.githubusercontent.com/diegomonteagudo/TC-SON/4a68a72ba9e03edc952e0c38a5a5d37b0570a26d/testSynth.dsp	faust		import("stdfaust.lib"); res = 2; frequence = hslider("frequence",262,20,10000,0.1); gate = button("gate"); gain = hslider("gain",1,0,1,0.1); process = gain*sy.combString(frequence,res,gate);
f78fb6cd9ab8797b2a483da653a487bac1d87c9947f8a53c9cb36a3dce227258	anwaldt/seamless	FoaReverb.dsp	import("stdfaust.lib"); // `rgxyz` = relative gain of lanes 1,4,2 to lane 0 in output (e.g., -9 to 9) rgxyz = nentry("rgxyz",1,-9,9,0.01) ; // `rdel` = delay (in ms) before reverberation begins (e.g., 0 to ~100 ms) rdel= nentry("rdel",2,0,100,0.01) ; // * `f1`: crossover frequency (Hz) separating dc and midrange frequencies f1 = nentry("f1",300,10,10000,0.1) ; // * `f2`: frequency (Hz) above f1 where T60 = t60m/2 (see below) f2 = nentry("f2",1000,10,10000,0.1) ; // * `t60dc`: desired decay time (t60) at frequency 0 (sec) t60dc=nentry("t60dc",3,0.01,7,0.01) ; // * `t60m`: desired decay time (t60) at midrange frequencies (sec) t60m=nentry("t60m",4,0.01,7,0.01) ; // * `fsmax`: maximum sampling rate to be used (Hz) fsmax=48000; process = _<: _,_ : re.zita_rev1_ambi(rgxyz,rdel,f1,f2,t60dc,t60m,fsmax) : _,_,_,_;	https://raw.githubusercontent.com/anwaldt/seamless/78ddf8b4b7108fd5120ce77041716e21a2f36f1f/Faust/reverb/FoaReverb.dsp	faust	`rgxyz` = relative gain of lanes 1,4,2 to lane 0 in output (e.g., -9 to 9) `rdel` = delay (in ms) before reverberation begins (e.g., 0 to ~100 ms) * `f1`: crossover frequency (Hz) separating dc and midrange frequencies * `f2`: frequency (Hz) above f1 where T60 = t60m/2 (see below) * `t60dc`: desired decay time (t60) at frequency 0 (sec) * `t60m`: desired decay time (t60) at midrange frequencies (sec) * `fsmax`: maximum sampling rate to be used (Hz)	import("stdfaust.lib"); rgxyz = nentry("rgxyz",1,-9,9,0.01) ; rdel= nentry("rdel",2,0,100,0.01) ; f1 = nentry("f1",300,10,10000,0.1) ; f2 = nentry("f2",1000,10,10000,0.1) ; t60dc=nentry("t60dc",3,0.01,7,0.01) ; t60m=nentry("t60m",4,0.01,7,0.01) ; fsmax=48000; process = _<: _,_ : re.zita_rev1_ambi(rgxyz,rdel,f1,f2,t60dc,t60m,fsmax) : _,_,_,_;
8eeb2a1e421f33705454bf71f0c8b1f6c5a82593d5e6c7bbd60f053d675a37fd	LSSN/Panner	esercizio01.dsp	import("stdfaust.lib"); frq = vslider("frequency [style:knob]", 440,100,20000,1); pan = vslider("pan [style:knob]", 0.5,0,1,0.01); process = os.oscsin(frq) <: _ * (sqrt(1-pan)), _ * (sqrt(pan));	https://raw.githubusercontent.com/LSSN/Panner/9868ac3a446d63c8f1fbd2c68588d5f8080b9c57/esercizio01.dsp	faust		import("stdfaust.lib"); frq = vslider("frequency [style:knob]", 440,100,20000,1); pan = vslider("pan [style:knob]", 0.5,0,1,0.01); process = os.oscsin(frq) <: _ * (sqrt(1-pan)), _ * (sqrt(pan));
8125ae0f565ef0e8ce652d6c175bacf2373fc086fd95226779afe8328755f59b	rochelletham/clarinetPlugin	clarinetMIDI.dsp	declare name "ClarinetMIDI"; declare description "Simple MIDI-controllable clarinet physical model with physical parameters."; declare license "MIT"; declare copyright "(c)Romain Michon, CCRMA (Stanford University), GRAME"; import("stdfaust.lib"); process = pm.clarinet_ui_MIDI <: _,_;	https://raw.githubusercontent.com/rochelletham/clarinetPlugin/e17616e0690ed05ca8c6c75e59b120eff786758f/capstone_v2/ClarinetModel/Source/clarinetMIDI.dsp	faust		declare name "ClarinetMIDI"; declare description "Simple MIDI-controllable clarinet physical model with physical parameters."; declare license "MIT"; declare copyright "(c)Romain Michon, CCRMA (Stanford University), GRAME"; import("stdfaust.lib"); process = pm.clarinet_ui_MIDI <: _,_;
ba064733dc5e08d9b65ee52987ab878d533f90ad7eb4ee01ea8fcdcbc281174d	brummer10/slowmo.lv2	delay.dsp	declare id "delay"; declare name "Delay"; declare category "Echo / Delay"; import("stdfaust.lib"); msec = ma.SR/1000.0; interp = 100msec; N = int( 2^19); gain = vslider("gain[name:Gain]", 0, -20, 20, 0.1) : ba.db2linear : si.smooth(0.999); d = ba.tempo(hslider("bpm[name:BPM][tooltip:Delay in Beats per Minute]",120,24,360,1)); feedback = vslider("feedback[name:feedback]", 0.5, 0, 1, 0.01) : si.smooth(0.999); process = _ <: _ + gain (+:de.sdelay(N, interp,d))~(de.sdelay(N, interp,d)*(feedback)) :> _;	https://raw.githubusercontent.com/brummer10/slowmo.lv2/1a32ab4e5b3740dab64e6f9dcce54baa9162a7bd/slowmo/Faust/delay.dsp	faust		declare id "delay"; declare name "Delay"; declare category "Echo / Delay"; import("stdfaust.lib"); msec = ma.SR/1000.0; interp = 100msec; N = int( 2^19); gain = vslider("gain[name:Gain]", 0, -20, 20, 0.1) : ba.db2linear : si.smooth(0.999); d = ba.tempo(hslider("bpm[name:BPM][tooltip:Delay in Beats per Minute]",120,24,360,1)); feedback = vslider("feedback[name:feedback]", 0.5, 0, 1, 0.01) : si.smooth(0.999); process = _ <: _ + gain (+:de.sdelay(N, interp,d))~(de.sdelay(N, interp,d)*(feedback)) :> _;
bc416489e76ea6aa3829f6ec79f8486364526922d2c0e3b59077cb7edcd84e68	ElMagicarp/SON	code_faust.dsp	import("stdfaust.lib"); equalizer = fi.high_shelf(midLevel,200):fi.low_shelf(lowLevel,200):fi.high_shelf(highLevel-midLevel,8000) with{ equalizer(x) = hgroup("Equalizer",x); lowLevel = equalizer(hslider("low",0,-40,40,0.1)); highLevel = equalizer(hslider("high",0,-40,40,.1)); midLevel = equalizer(hslider("mid",0,-40,40,.1)); }; transp(w, x, s, sig) = de.delay(maxDelay,d,sig)ma.fmin(d/x,1) + de.delay(maxDelay,d+w,sig)(1-ma.fmin(d/x,1)) with { maxDelay = 3001; i = 1 - pow(2, s/12); d = i : (+ : +(w) : fmod(_,w)) ~ _; }; pitchShift = transp(1000,100,hslider("shift", 0, -50, +50, 1)); delay = hslider("echoDelay", 0, 0, 1000, 10); feedback = hslider("echoFeedback", 0.5, 0, 1, 0.1); myEcho = vgroup("echo", +~(de.delay(2000, int(delayba.millisec)-1) feedback)); gain = hslider("volume",0.5,0,1,.1); main = equalizer:myEcho:pitchShift: *(gain); process = par(i,2,main);	https://raw.githubusercontent.com/ElMagicarp/SON/892a95590c1e0a9f394728d0bd8b85d4efac64a6/code/code_faust.dsp	faust		import("stdfaust.lib"); equalizer = fi.high_shelf(midLevel,200):fi.low_shelf(lowLevel,200):fi.high_shelf(highLevel-midLevel,8000) with{ equalizer(x) = hgroup("Equalizer",x); lowLevel = equalizer(hslider("low",0,-40,40,0.1)); highLevel = equalizer(hslider("high",0,-40,40,.1)); midLevel = equalizer(hslider("mid",0,-40,40,.1)); }; transp(w, x, s, sig) = de.delay(maxDelay,d,sig)ma.fmin(d/x,1) + de.delay(maxDelay,d+w,sig)(1-ma.fmin(d/x,1)) with { maxDelay = 3001; i = 1 - pow(2, s/12); d = i : (+ : +(w) : fmod(_,w)) ~ _; }; pitchShift = transp(1000,100,hslider("shift", 0, -50, +50, 1)); delay = hslider("echoDelay", 0, 0, 1000, 10); feedback = hslider("echoFeedback", 0.5, 0, 1, 0.1); myEcho = vgroup("echo", +~(de.delay(2000, int(delayba.millisec)-1) feedback)); gain = hslider("volume",0.5,0,1,.1); main = equalizer:myEcho:pitchShift: *(gain); process = par(i,2,main);
03b83607291e1105061dc0fc9b413796df5d39e9577eb0b87f41ac86c138b6c6	ArcAudio/FaustTest	osc.dsp	import("stdfaust.lib"); vol = hslider("volume [unit:dB]", 0, -96, 0, 0.1) : ba.db2linear : si.smoo; freq = hslider("freq [unit:Hz]", 1000, 20, 24000, 1) : si.smoo; flanger(p,wet,depth) = _ <: de.delay(256,d)wet,_ :> /(2) with{ d = (os.osc(p) + 1)127depth; }; tremolo(fr,dep) = _(1-(os.osc(fr)0.5 + 0.5)dep); f = hslider("tfreq [unit:Hz]",10,0.1,100,0.01); w = hslider("twet",0.5,0,1,0.01); d = hslider("tdepth",0.5,0,1,0.01); gain = hslider("gain [knob:2] [midi:ctrl 7]", 0.5, 0, 1, 0.01); gate = button("gate [switch:1]"); process = os.osc(freq)*vol : flanger(f,w,d) : tremolo(5,1) <: _,_;	https://raw.githubusercontent.com/ArcAudio/FaustTest/bdf9f50cf8a651a7e54fa95db093d2a669187b68/osc.dsp	faust		import("stdfaust.lib"); vol = hslider("volume [unit:dB]", 0, -96, 0, 0.1) : ba.db2linear : si.smoo; freq = hslider("freq [unit:Hz]", 1000, 20, 24000, 1) : si.smoo; flanger(p,wet,depth) = _ <: de.delay(256,d)wet,_ :> /(2) with{ d = (os.osc(p) + 1)127depth; }; tremolo(fr,dep) = _(1-(os.osc(fr)0.5 + 0.5)dep); f = hslider("tfreq [unit:Hz]",10,0.1,100,0.01); w = hslider("twet",0.5,0,1,0.01); d = hslider("tdepth",0.5,0,1,0.01); gain = hslider("gain [knob:2] [midi:ctrl 7]", 0.5, 0, 1, 0.01); gate = button("gate [switch:1]"); process = os.osc(freq)*vol : flanger(f,w,d) : tremolo(5,1) <: _,_;
1eab40540e90d8715f1067627858a5162ec7db66619059df0ba8248767bff994	nyanpasu64-backup/snes-echo	lagrange-delay-fir.dsp	declare name "lagrange delay"; declare version "0."; declare author "nyanpasu64"; declare license "bsd"; declare copyright "nyanpasu64"; import("math.lib"); import("stdfaust.lib"); import("delays.lib"); snes2sr = _ * SR / 32000.0; DELAY = 32; ORDER = DELAY; FIR_NDELAY = 1; delayt = vslider("Delay samples", 0.5, 0, 1, 0.01) + DELAY; fir_delay(i, signal) = fdelaylti(ORDER, 2DELAY, DELAY + snes2sr(i), signal); process(l, r) = ( fdelaylti(ORDER, 2DELAY, delayt, l) , /fdelay(2DELAY, delayt, r)/ // 8 FIR taps, with delays from 0..7. // coeff x is multiplied with delay 7-x. sum( i, FIR_NDELAY, 1/8 fir_delay(FIR_NDELAY-1 - i, r) ) );	https://raw.githubusercontent.com/nyanpasu64-backup/snes-echo/8378166012807e96eca69cb2bc3ee9cf5537a69f/snes-echo/test/lagrange-delay-fir.dsp	faust	fdelay(2*DELAY, delayt, r) 8 FIR taps, with delays from 0..7. coeff x is multiplied with delay 7-x.	declare name "lagrange delay"; declare version "0."; declare author "nyanpasu64"; declare license "bsd"; declare copyright "nyanpasu64"; import("math.lib"); import("stdfaust.lib"); import("delays.lib"); snes2sr = _ * SR / 32000.0; DELAY = 32; ORDER = DELAY; FIR_NDELAY = 1; delayt = vslider("Delay samples", 0.5, 0, 1, 0.01) + DELAY; fir_delay(i, signal) = fdelaylti(ORDER, 2DELAY, DELAY + snes2sr(i), signal); process(l, r) = ( fdelaylti(ORDER, 2DELAY, delayt, l) , sum( i, FIR_NDELAY, 1/8 * fir_delay(FIR_NDELAY-1 - i, r) ) );
a715059dab4b14e0e2b77e360c8f495b17c94285b46e313766f4c5475b419a97	geofholbrook/sequence-collab	monoDjembe.dsp	import("stdfaust.lib"); freq = nentry("freq", 100, 10, 10000, 1); gain = nentry("gain", 1, 0, 1, .01); // process = os.triangle(freq) * 0.1 * gain * (button("gate") : (en.ar(0.01, 2) ^ 10)); process = button("gate") : pm.djembe(freq, .25, .25, gain);	https://raw.githubusercontent.com/geofholbrook/sequence-collab/779c0d085f67dec2f6842b130b8474c7ed367163/src/sound-generation/faust/dsp-files/monoDjembe.dsp	faust	process = os.triangle(freq) * 0.1 * gain * (button("gate") : (en.ar(0.01, 2) ^ 10));	import("stdfaust.lib"); freq = nentry("freq", 100, 10, 10000, 1); gain = nentry("gain", 1, 0, 1, .01); process = button("gate") : pm.djembe(freq, .25, .25, gain);
04eda93f95e4a8d26c8b1a810740a8a4703a0885aea7617760b5b9e525b18e87	michal-cab/faust-snippets	sah.dsp	import("stdfaust.lib"); import("basics.lib"); process = harmOsc :>_; harmOsc = par(i,10,os.osc(isah100)); sah = no.lfnoise0(500) : sAndH(trig); trig = button("hold");	https://raw.githubusercontent.com/michal-cab/faust-snippets/6c77964d29e7640409905a51ec61ce62e052d7cb/sah.dsp	faust		import("stdfaust.lib"); import("basics.lib"); process = harmOsc :>_; harmOsc = par(i,10,os.osc(isah100)); sah = no.lfnoise0(500) : sAndH(trig); trig = button("hold");
fad195550fafe6c6c0142d679f6296a6379b577704aa91690f246b5fde59c2ff	michal-cab/faust-snippets	ar.dsp	import("stdfaust.lib"); process = pattern1,pattern2 :>_; pattern1 = en.ar(0.01,0.1,gate) * no.noise * 0.1; pattern2 = en.ar(0.01,0.05,gate1) * no.pink_noise; gate = no.lfnoise0(5); gate1 = no.lfnoise0(7);	https://raw.githubusercontent.com/michal-cab/faust-snippets/6c77964d29e7640409905a51ec61ce62e052d7cb/ar.dsp	faust		import("stdfaust.lib"); process = pattern1,pattern2 :>_; pattern1 = en.ar(0.01,0.1,gate) * no.noise * 0.1; pattern2 = en.ar(0.01,0.05,gate1) * no.pink_noise; gate = no.lfnoise0(5); gate1 = no.lfnoise0(7);
061692d152526eacf8a875acd4d9e9423ff288b415d804cb5303766c44437fbb	Tonton-Blax/supasynth	main.dsp	import("stdfaust.lib"); import("socisse.dsp"); import("feumeu.dsp"); import("osync.dsp"); import("moogish.dsp"); process = feumeu, oscsaw, osync :> _ : moogvcf <: _,_;	https://raw.githubusercontent.com/Tonton-Blax/supasynth/ec39566ad52e2417154301ee86f5bf94b650a3e8/faust/main.dsp	faust		import("stdfaust.lib"); import("socisse.dsp"); import("feumeu.dsp"); import("osync.dsp"); import("moogish.dsp"); process = feumeu, oscsaw, osync :> _ : moogvcf <: _,_;
44d3416a7a902ccd24f372b0a7052d194f933f73a0e576681959cdbe5b300f30	geofholbrook/sequence-collab	faustTriangle.dsp	import("stdfaust.lib"); freq = nentry("freq", 100, 10, 10000, 1); gain = nentry("gain", 1, 0, 1, .01); // process = os.triangle(freq) * 0.1 * gain * (button("gate") : (en.ar(0.01, 2) ^ 10)); process = (button("gate") : en.arfe(0.001, 0.5, 0)) * os.triangle(freq) : fi.lowpass(2, 2500) * gain;	https://raw.githubusercontent.com/geofholbrook/sequence-collab/779c0d085f67dec2f6842b130b8474c7ed367163/src/sound-generation/faust/dsp-files/faustTriangle.dsp	faust	process = os.triangle(freq) * 0.1 * gain * (button("gate") : (en.ar(0.01, 2) ^ 10));	import("stdfaust.lib"); freq = nentry("freq", 100, 10, 10000, 1); gain = nentry("gain", 1, 0, 1, .01); process = (button("gate") : en.arfe(0.001, 0.5, 0)) * os.triangle(freq) : fi.lowpass(2, 2500) * gain;
6a631c44a4e4454f6d0d52473630b1b067c7a1371f3b29bee7a3befe7aedea3b	Jacajack/stm32-faust-synth	square.dsp	import("stdfaust.lib"); //process = os.square( hslider("note_freq", 0, 1, 50, 1e-3 ) ) * en.adsr( 1e-3, 0.2, 0.7, 0.5, button( "gate" ) ); process = (os.square( 220 ) + os.square( 110.5 ))/2;	https://raw.githubusercontent.com/Jacajack/stm32-faust-synth/5987bc2508e94318affbbccaaeaea0fd7f7ad694/faust/square.dsp	faust	process = os.square( hslider("note_freq", 0, 1, 50, 1e-3 ) ) * en.adsr( 1e-3, 0.2, 0.7, 0.5, button( "gate" ) );	import("stdfaust.lib"); process = (os.square( 220 ) + os.square( 110.5 ))/2;
30a663f1d803785fb039bcaab26a6e3385e6105f039143e4004be342ac4cb05c	rhinocerose/eurorack-modularev	FAUST.dsp	// // FAUST .dsp file for the programmable Eurorack DSP Module NEMESIS by Arev Imer // // src/FAUST.dsp // // Copyright © 2021 Arev Imer if not mentioned elsewise // released under GNU GPL v3 // import("stdfaust.lib"); param_1 = hslider("POT X",0.5,0,1,0.001) : si.smoo; param_2 = hslider("POT Y",0.5,0,1,0.001) : si.smoo; param_3 = hslider("POT Z",0.5,0,1,0.001) : si.smoo; param_4 = hslider("POT A",0.5,0,1,0.001) : si.smoo; param_5 = hslider("POT B",0.5,0,1,0.001) : si.smoo; param_6 = hslider("POT C",0.5,0,1,0.001) : si.smoo; param_7 = hslider("POT D",0.5,0,1,0.001) : si.smoo; param_8 = hslider("POT E",0.5,0,1,0.001) : si.smoo; param_9 = hslider("POT F",0.5,0,1,0.001) : si.smoo; process = _,_,_,_,_,_,_,_;	https://raw.githubusercontent.com/rhinocerose/eurorack-modularev/0da6b85bbd3564c98ff45eb650747f4e9a911c48/Nemesis-hw-rev-2/software/template/src/FAUST.dsp	faust	FAUST .dsp file for the programmable Eurorack DSP Module NEMESIS by Arev Imer src/FAUST.dsp Copyright © 2021 Arev Imer if not mentioned elsewise released under GNU GPL v3	import("stdfaust.lib"); param_1 = hslider("POT X",0.5,0,1,0.001) : si.smoo; param_2 = hslider("POT Y",0.5,0,1,0.001) : si.smoo; param_3 = hslider("POT Z",0.5,0,1,0.001) : si.smoo; param_4 = hslider("POT A",0.5,0,1,0.001) : si.smoo; param_5 = hslider("POT B",0.5,0,1,0.001) : si.smoo; param_6 = hslider("POT C",0.5,0,1,0.001) : si.smoo; param_7 = hslider("POT D",0.5,0,1,0.001) : si.smoo; param_8 = hslider("POT E",0.5,0,1,0.001) : si.smoo; param_9 = hslider("POT F",0.5,0,1,0.001) : si.smoo; process = _,_,_,_,_,_,_,_;
1334653e2432ce245c7ac47eb8c3117287626b52a6cc9ba2f392128284ddb2d6	glocq/jacob_collier_polyrhythm	jc.dsp	import("stdfaust.lib"); s2 = gain2 * os.lf_saw(f0); s3 = gain3 * os.lf_saw(f03/2); s4 = gain4 os.lf_saw(f02); s5 = gain5 os.lf_saw(f05/2); s6 = gain6 os.lf_saw(f0*3); f0 = ba.midikey2hz(nentry("MIDI pitch", -45, -50, 100, 1)); gain2 = hslider("Gain 2", 1, 0, 1, 0.01); gain3 = hslider("Gain 3", 1, 0, 1, 0.01); gain4 = hslider("Gain 4", 1, 0, 1, 0.01); gain5 = hslider("Gain 5", 1, 0, 1, 0.01); gain6 = hslider("Gain 6", 1, 0, 1, 0.01); process = (s2+s3+s4+s5+s6)/5 : fi.bandpass(1, 50, 2000) <: (_,_);	https://raw.githubusercontent.com/glocq/jacob_collier_polyrhythm/daf78e52da6ef5cda7c21c604af43ad1399259c4/jc.dsp	faust		import("stdfaust.lib"); s2 = gain2 * os.lf_saw(f0); s3 = gain3 * os.lf_saw(f03/2); s4 = gain4 os.lf_saw(f02); s5 = gain5 os.lf_saw(f05/2); s6 = gain6 os.lf_saw(f0*3); f0 = ba.midikey2hz(nentry("MIDI pitch", -45, -50, 100, 1)); gain2 = hslider("Gain 2", 1, 0, 1, 0.01); gain3 = hslider("Gain 3", 1, 0, 1, 0.01); gain4 = hslider("Gain 4", 1, 0, 1, 0.01); gain5 = hslider("Gain 5", 1, 0, 1, 0.01); gain6 = hslider("Gain 6", 1, 0, 1, 0.01); process = (s2+s3+s4+s5+s6)/5 : fi.bandpass(1, 50, 2000) <: (_,_);
0f088451052f27833944a4ca1c2e4cd8f14d92b714aaeef7cb61b394f7a9ff6b	lupu2022/phy2raw	sawtooth.dsp	import("stdfaust.lib"); freq = nentry("h:Basic_Parameters/freq [1][unit:Hz] [tooltip:Tone frequency]",440,20,20000,1); gain = nentry("h:Basic_Parameters/gain [1][tooltip:Gain (value between 0 and 1)]",1,0,1,0.01); process = os.sawtooth(freq) * gain;	https://raw.githubusercontent.com/lupu2022/phy2raw/7f01bf933e2ddc04fc331f55ada81e8033d5c211/phy/sawtooth.dsp	faust		import("stdfaust.lib"); freq = nentry("h:Basic_Parameters/freq [1][unit:Hz] [tooltip:Tone frequency]",440,20,20000,1); gain = nentry("h:Basic_Parameters/gain [1][tooltip:Gain (value between 0 and 1)]",1,0,1,0.01); process = os.sawtooth(freq) * gain;
08f49b7e3892c9891bb3b15f8cc18943764f5b4f1aca5ba7658bc529de7f4226	alainbonardi/enecho	zeroCross.dsp	//--------------------------------------------------------------------------------------// //----------------------------------------enecho----------------------------------------// // //-----------------------FAUST CODE FOR THE PRESERVATION OF EN ECHO---------------------// //-----------------FOR SOPRANO AND LIVE ELECTRONICS BY PHILIPPE MANOOURY----------------// // //----------------------------------BY ALAIN BONARDI - 2022-----------------------------// //---------------------CICM - MUSIDANSE LABORATORY - PARIS 8 UNIVERSITY-----------------// //--------------------------------------------------------------------------------------// // declare author "Alain Bonardi"; declare licence "GPL-2.0"; declare name "zeroCross"; // import("stdfaust.lib"); clear = nentry("clear", 1, 0, 1, 1); process=((_, ma.zc) : +) ~ (*(1-clear));	https://raw.githubusercontent.com/alainbonardi/enecho/afc94af2c59d25e42b32d003236fc3af4e65d5d0/faustCodes/zeroCross.dsp	faust	--------------------------------------------------------------------------------------// ----------------------------------------enecho----------------------------------------// -----------------------FAUST CODE FOR THE PRESERVATION OF EN ECHO---------------------// -----------------FOR SOPRANO AND LIVE ELECTRONICS BY PHILIPPE MANOOURY----------------// ----------------------------------BY ALAIN BONARDI - 2022-----------------------------// ---------------------CICM - MUSIDANSE LABORATORY - PARIS 8 UNIVERSITY-----------------// --------------------------------------------------------------------------------------//	declare author "Alain Bonardi"; declare licence "GPL-2.0"; declare name "zeroCross"; import("stdfaust.lib"); clear = nentry("clear", 1, 0, 1, 1); process=((_, ma.zc) : +) ~ (*(1-clear));
477cf06cbad546ef92fc12352e8f3bc17b5e6d5574dd66672398309a4963d765	jkbd/scannervibrato	scannervibrato.dsp	// --Faust-- declare name "scannervibrato"; declare author "Jakob Dübel"; declare copyright "(c) 2018 Jakob Dübel"; declare version "1.0.0"; declare license "MIT"; import("stdfaust.lib"); fx = library("effect.lib"); process = fx.scannervibrato;	https://raw.githubusercontent.com/jkbd/scannervibrato/5f70bb63344e404c337b88eee057962c7cca1a72/scannervibrato.dsp	faust	--Faust--	declare name "scannervibrato"; declare author "Jakob Dübel"; declare copyright "(c) 2018 Jakob Dübel"; declare version "1.0.0"; declare license "MIT"; import("stdfaust.lib"); fx = library("effect.lib"); process = fx.scannervibrato;
7e5a79d4affb9853dd3f5d5bb0951adea9b86afbbd5fe2ac3e662791dbf38744	digosuoza/linguist	FFT.dsp	// Radix 2 FFT, decimation in time, real and imag parts interleaved declare name "FFT"; // Faust Fourier Transform :-) declare author "JOS"; declare license "STK-4.3"; import("stdfaust.lib"); N=32; // FFT size (power of 2) // Number of frequency bins (including dc and SR/2) is N/2+1 No2 = N>>1; signal = amp * cosine with { cosine = select2(k==0, select2(k==No2, 2.0os.oscrc(f(k)), // 2x since negative-frequencies not displayed 1-1':+~(-1) // Alternating sequence: 1, -1, 1, -1 ), 1.0); // make sure phase is zero (freq jumps around) f(k) = float(k) * ma.SR / float(N); // only test FFT bin frequencies k = hslider("[2] FFT Bin Number",N/4,0,No2,0.001) : int <: _,dpy : attach; dpy = hbargraph("[3] Measured FFT Bin Number",0,No2); amp = hslider("[4] Amplitude",0.1,0,1,0.001); }; process = signal : dm.fft_spectral_level_demo(N) <: _,_;	https://raw.githubusercontent.com/digosuoza/linguist/f3d507f68af37296463c0dc261ca21ecbb338bb6/samples/Faust/FFT.dsp	faust	Radix 2 FFT, decimation in time, real and imag parts interleaved Faust Fourier Transform :-) FFT size (power of 2) Number of frequency bins (including dc and SR/2) is N/2+1 2x since negative-frequencies not displayed Alternating sequence: 1, -1, 1, -1 make sure phase is zero (freq jumps around) only test FFT bin frequencies	declare author "JOS"; declare license "STK-4.3"; import("stdfaust.lib"); No2 = N>>1; signal = amp * cosine with { cosine = select2(k==0, select2(k==No2, ), k = hslider("[2] FFT Bin Number",N/4,0,No2,0.001) : int <: _,dpy : attach; dpy = hbargraph("[3] Measured FFT Bin Number",0,No2); amp = hslider("[4] Amplitude",0.1,0,1,0.001); }; process = signal : dm.fft_spectral_level_demo(N) <: _,_;
566818d33ca24b5113a205960475e6cea4c8a3b861d345f237e80b556381639a	michelemanca18/esercizi	lezione2.dsp	// questo è un commento // la riga di commento è ignorata dal compilatore // il compilatore è un software che legge // il nostro codice seguendo le istruzioni // import("stdfaust.lib"); // _ canale audio // + - * /operatori matematici // _ : _ due punti identifica un flusso seriale // _ , _ virgola flusso parallelo // ogni riga finisce con ; punto e virgola process = _ + _ , _ + _ , _ , _ ;	https://raw.githubusercontent.com/michelemanca18/esercizi/7720d7779912358c9a67233e8f2a93cf679c79c8/faust/lezione2.dsp	faust	questo è un commento la riga di commento è ignorata dal compilatore il compilatore è un software che legge il nostro codice seguendo le istruzioni _ canale audio + - * /operatori matematici _ : _ due punti identifica un flusso seriale _ , _ virgola flusso parallelo ogni riga finisce con ; punto e virgola	import("stdfaust.lib"); process = _ + _ , _ + _ , _ , _ ;
691e364578b784075de147ebb20de9156ce3de666f80471d1abd8c81b18ce6d6	michelemanca18/esercizi	lezione03.dsp	// questo è un commento // la riga di commento è ignorata dal compilatore // il compilatore è un software che legge // il nostro codice seguendo le istruzioni // import("stdfaust.lib"); // _ canale audio // + - * /operatori matematici // _ : _ due punti identifica un flusso seriale // _ , _ virgola flusso parallelo // ogni riga finisce con ; punto e virgola process = _ * 0.5;	https://raw.githubusercontent.com/michelemanca18/esercizi/7720d7779912358c9a67233e8f2a93cf679c79c8/faust/lezione03.dsp	faust	questo è un commento la riga di commento è ignorata dal compilatore il compilatore è un software che legge il nostro codice seguendo le istruzioni _ canale audio + - * /operatori matematici _ : _ due punti identifica un flusso seriale _ , _ virgola flusso parallelo ogni riga finisce con ; punto e virgola	import("stdfaust.lib"); process = _ * 0.5;
04c9b91f0de388d6b4a71fb40edab8b572c11e6e4c93bdcfdb812841f1243690	JoaoSvidzinski/HermesV2	compressor.dsp	declare name "compressor"; declare version "0.0"; declare author "JOS, revised by RM"; declare description "Compressor demo application"; import("stdfaust.lib"); process = dm.compressor_demo;	https://raw.githubusercontent.com/JoaoSvidzinski/HermesV2/a96f9cd288d5cb68be2f5bb5788d5869008d8cef/faust/compressor.dsp	faust		declare name "compressor"; declare version "0.0"; declare author "JOS, revised by RM"; declare description "Compressor demo application"; import("stdfaust.lib"); process = dm.compressor_demo;
1ab0440766b1b82fda0b04783bd58222f9a7576d1b12812bc9e20b54b188845c	opampband/distortion	distortion.dsp	import("stdfaust.lib"); // Simulates soft clipping from tube amp softClip = _ <: /(_, sqrt(1 + ^(_, 2))); hardClip(ceiling) = min(hi) : max(lo) with { hi = ceiling; lo = (-1) * ceiling; }; // gain before hard clipping stage fuzzGain = hslider("[0]fuzz gain", 1, 1, 10, 0.01) * 10 - 9 : ba.db2linear; // gain before soft clipping stage tubeGain = hslider("[1]tube gain", 1, 1, 10, 0.01) * 10 - 9 : ba.db2linear; // gain after distortion vol = hslider("[2]post-distortion gain (dB)", -10, -30, 0, 0.01) : ba.db2linear; // The entire guitar amp // (distortion + speaker) amp = // LPF before hard clipping makes it less harsh fi.resonlp(3000, 1, 1) : (fuzzGain) : hardClip(1) : (tubeGain) : softClip : (vol) : fi.dcblocker : ef.speakerbp(100, 5000); feedback = hslider("[3]feedback (dB)", -50, -50, 0, 1) : ba.db2linear; delay = hslider("[4]delay (ms)", 0, 0, 100, 0.1) : /(1000) : ba.sec2samp; process = amp(+(_)) ~ (@(delay) : (feedback)); //process = amp(os.osc(440));	https://raw.githubusercontent.com/opampband/distortion/bfa26c446aab63a5d2eeb3157350bc341b68acd0/distortion.dsp	faust	Simulates soft clipping from tube amp gain before hard clipping stage gain before soft clipping stage gain after distortion The entire guitar amp (distortion + speaker) LPF before hard clipping makes it less harsh process = amp(os.osc(440));	import("stdfaust.lib"); softClip = _ <: /(_, sqrt(1 + ^(_, 2))); hardClip(ceiling) = min(hi) : max(lo) with { hi = ceiling; lo = (-1) * ceiling; }; fuzzGain = hslider("[0]fuzz gain", 1, 1, 10, 0.01) * 10 - 9 : ba.db2linear; tubeGain = hslider("[1]tube gain", 1, 1, 10, 0.01) * 10 - 9 : ba.db2linear; vol = hslider("[2]post-distortion gain (dB)", -10, -30, 0, 0.01) : ba.db2linear; amp = fi.resonlp(3000, 1, 1) : (fuzzGain) : hardClip(1) : (tubeGain) : softClip : (vol) : fi.dcblocker : ef.speakerbp(100, 5000); feedback = hslider("[3]feedback (dB)", -50, -50, 0, 1) : ba.db2linear; delay = hslider("[4]delay (ms)", 0, 0, 100, 0.1) : /(1000) : ba.sec2samp; process = amp(+(_)) ~ (@(delay) : (feedback));

End of preview. Expand in Dataset Viewer.

Dataset Card for "faust_code"

More Information needed

Downloads last month: 240

Edit dataset card

Size of downloaded dataset files:

737 MB

Size of the auto-converted Parquet files:

737 MB

Number of rows:

157,157