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<objdefs>
<obj.normal id="moog_vcf" uuid="9329f089dced01ba64f7e22ac77fd78fbec47db9" sha="6b8d84e43d5934e94f32e1d50318f8feede69769">
<sDescription>Moog VCF (from Faust)</sDescription>
<author>Ricardo Wurmus</author>
<license>GPL</license>
<helpPatch>filter.axh</helpPatch>
<includes>
<include>math.h</include>
</includes>
<inlets>
<frac32buffer name="in" description="filter input"/>
</inlets>
<outlets>
<frac32buffer name="out" description="filter output"/>
</outlets>
<displays/>
<attribs/>
<code.declaration><![CDATA[
// convert float to fixed point notation
// * take absolute value
// * multiply with constant to keep precision;
// to get a fixed point at x:y we multiply by 2^y,
// e.g. for 24:8 (24 significant bits before decimal point)
// we multiply f by 2^8 (1<<8).
// * truncate and cast to int32_t
// * invert bits if negative
int32_t floatToFrac32(float f) {
// was 1 000 000 000 and then >> 2
// now is 2^27 = 134 217 728
// 2^32 = 4 294 967 296
// 2^29 = 536 870 912 (3:29)
int32_t preout = int32_t(((f < 0) ? (-f) : f) * (1<<29));
return ((f < 0) ? ~preout : preout);
}
// convert fixed point to float
// * invert bits if sign bit is set (0x08000000, or (1<<27))
// * cast int to float
// * divide by constant to shift decimal point
// * multiply by -1 if sign bit was set
float frac32ToFloat(int32_t frac) {
bool neg = (((1<<27) & frac) != 0);
float res = (float)(neg ? frac : ~frac);
res = res / (float(1<<29));
return (neg ? (-1 * res) : res);
}
float fslider0;
float fslider1;
float fslider2;
float fcheckbox0;
float fcheckbox1;
float fcheckbox2;
float fRec0[2];
float fRec1[2];
float fRec2[2];
float fRec3[2];
float fRec4[2];
float fRec5[2];
float fRec6[3];
float fRec7[3];
float fRec8[2];
float fRec10[2];
float fRec11[2];
float fRec13[2];
float fRec14[2];
float fConst1;
float fConst2;
float fSqrtTwo;
inline float faustpower2(float x) {
return powf(x,2);
}
inline float faustpower4(float x) {
return powf(x,4);
}
// template <int N> inline float faustpower(float x) { return powf(x,N); }
// template <int N> inline double faustpower(double x) { return pow(x,N); }
// template <int N> inline int faustpower(int x) { return faustpower<N/2>(x) * faustpower<N-N/2>(x); }
// template <> inline int faustpower<0>(int x) { return 1; }
// template <> inline int faustpower<1>(int x) { return x; }
]]></code.declaration>
<code.init><![CDATA[
fConst1 = ((2 * PI_F) / float(SAMPLERATE));
fConst2 = (PI_F / float(SAMPLERATE));
fSqrtTwo = 1.4142135623730951f;
fcheckbox0 = 0.0;
fcheckbox1 = 0.0;
fcheckbox2 = 0.0;
fslider0 = 25.0f;
fslider1 = 0.9f;
fslider2 = 5.0f;
for (int i=0; i<2; i++) fRec0[i] = 0;
for (int i=0; i<2; i++) fRec1[i] = 0;
for (int i=0; i<2; i++) fRec2[i] = 0;
for (int i=0; i<2; i++) fRec3[i] = 0;
for (int i=0; i<2; i++) fRec4[i] = 0;
for (int i=0; i<2; i++) fRec5[i] = 0;
for (int i=0; i<3; i++) fRec6[i] = 0;
for (int i=0; i<3; i++) fRec7[i] = 0;
for (int i=0; i<2; i++) fRec8[i] = 0;
for (int i=0; i<2; i++) fRec10[i] = 0;
for (int i=0; i<2; i++) fRec11[i] = 0;
for (int i=0; i<2; i++) fRec13[i] = 0;
for (int i=0; i<2; i++) fRec14[i] = 0;
]]></code.init>
<code.krate><![CDATA[
float fSlow0 = (0.4400000000000004f * powf(2.0f,(0.08333333333333333f * (float(fslider0) - 49.0f))));
int iSlow1 = int(float(fcheckbox0));
float fSlow2 = float(fslider1);
float fSlow3 = (0 - (4.0f * fmaxf((float)0, fminf(faustpower4(fSlow2), 0.999999f))));
float fSlow4 = fminf(1.412799348810722f, (fSqrtTwo * fSlow2));
float fSlow5 = (fSqrtTwo * fSlow4);
float fSlow6 = 2 - fSlow5;
float fSlow7 = 1 + (fSlow4 * (fSlow4 - fSqrtTwo));
float fSlow8 = 2 + fSlow5;
float fSlow9 = 1 + (fSlow4 * (fSqrtTwo + fSlow4));
float fSlow10 = 2 * fSlow2;
float fSlow11 = 2 - fSlow10;
float fSlow12 = faustpower2((1.412799348810722f * fSlow2));
float fSlow13 = ((1 + fSlow12) - fSlow10);
float fSlow14 = (2 + fSlow10);
float fSlow15 = (1 + (fSlow10 + fSlow12));
int iSlow16 = int(float(fcheckbox1));
int iSlow17 = int(float(fcheckbox2));
float fSlow18 = (0.001f * powf(10,(0.05f * float(fslider2))));
//const int32_t* input0 = inlet_in;
int32_t* output0 = outlet_out;
for (int i=0; i<BUFSIZE; i++) {
fRec1[0] = (fSlow0 + (0.999f * fRec1[1]));
float fTemp0 = (fConst1 * fRec1[0]);
float fTemp1 = (1.0f - fTemp0);
float fTemp2 = frac32ToFloat(inlet_in[i]);
float fTemp3 = ((iSlow1)?0:fTemp2);
fRec5[0] = ((fSlow3 * fRec0[1]) + (fTemp3 + (fTemp1 * fRec5[1])));
fRec4[0] = (fRec5[0] + (fTemp1 * fRec4[1]));
fRec3[0] = (fRec4[0] + (fTemp1 * fRec3[1]));
fRec2[0] = (fRec3[0] + (fRec2[1] * fTemp1));
fRec0[0] = (fRec2[0] * powf(fTemp0,4.0f));
float fTemp4 = tanf((fConst2 * fmaxf((float)20, fminf((float)10000, fRec1[0]))));
float fTemp5 = (1.0f / fTemp4);
float fTemp6 = (fSlow7 + ((fSlow6 + fTemp5) / fTemp4));
float fTemp7 = (1.0f / faustpower2(fTemp4));
float fTemp8 = (fSlow9 + ((fSlow8 + fTemp5) / fTemp4));
fRec7[0] = (fTemp3 - (((fRec7[2] * (fSlow9 + ((fTemp5 - fSlow8) / fTemp4))) + (2 * (fRec7[1] * (fSlow9 - fTemp7)))) / fTemp8));
fRec6[0] = (((fRec7[2] + (fRec7[0] + (2.0f * fRec7[1]))) / fTemp8) - (((fRec6[2] * (fSlow7 + ((fTemp5 - fSlow6) / fTemp4))) + (2 * (fRec6[1] * (fSlow7 - fTemp7)))) / fTemp6));
float fTemp9 = tanf((fConst2 * fmaxf(fRec1[0], (float)20)));
float fTemp10 = (1.0f / fTemp9);
float fTemp11 = (fSlow13 + ((fSlow11 + fTemp10) / fTemp9));
float fTemp12 = ((fSlow13 + ((fTemp10 - fSlow11) / fTemp9)) / fTemp11);
float fTemp13 = (1.0f / faustpower2(fTemp9));
float fTemp14 = (fSlow13 - fTemp13);
float fTemp15 = fmaxf(-0.9999f, fminf(0.9999f, (2 * (fTemp14 / (fTemp11 * (1 + fTemp12))))));
float fTemp16 = (1 - faustpower2(fTemp15));
float fTemp17 = fmaxf(-0.9999f, fminf(0.9999f, fTemp12));
float fTemp18 = (1 - faustpower2(fTemp17));
float fTemp19 = sqrtf(fTemp18);
float fTemp20 = (2.0f - (2.0f * (fTemp14 / fTemp11)));
float fTemp21 = sqrtf(fmaxf((float)0, fTemp16));
float fTemp22 = (fSlow15 + ((fSlow14 + fTemp10) / fTemp9));
float fTemp23 = sqrtf(fmaxf((float)0, fTemp18));
float fTemp24 = ((fSlow15 + ((fTemp10 - fSlow14) / fTemp9)) / fTemp22);
float fTemp25 = (fSlow15 - fTemp13);
float fTemp26 = fmaxf(-0.9999f, fminf(0.9999f, (2 * (fTemp25 / (fTemp22 * (1 + fTemp24))))));
float fTemp27 = (1 - faustpower2(fTemp26));
float fTemp28 = fmaxf(-0.9999f, fminf(0.9999f, fTemp24));
float fTemp29 = (1 - faustpower2(fTemp28));
float fTemp30 = sqrtf(fTemp29);
float fTemp31 = (2.0f - (2.0f * (fTemp25 / fTemp22)));
float fTemp32 = sqrtf(fmaxf((float)0, fTemp27));
float fTemp33 = sqrtf(fmaxf((float)0, fTemp29));
float fTemp34 = ((fRec11[1] * (0 - fTemp28)) + (fTemp3 * fTemp33));
fRec13[0] = ((fRec13[1] * (0 - fTemp26)) + (fTemp34 * fTemp32));
fRec11[0] = ((fTemp34 * fTemp26) + (fRec13[1] * fTemp32));
float fRec12 = fRec13[0];
float fTemp35 = ((((fTemp3 * fTemp28) + (fRec11[1] * fTemp33)) + ((fRec11[0] * fTemp31) / fTemp30)) + ((fRec12 * ((1.0f - fTemp24) - (fTemp26 * fTemp31))) / (fTemp30 * sqrtf(fTemp27))));
float fTemp36 = ((fRec8[1] * (0 - fTemp17)) + ((fTemp35 * fTemp23) / fTemp22));
fRec10[0] = ((fRec10[1] * (0 - fTemp15)) + (fTemp36 * fTemp21));
fRec8[0] = ((fTemp36 * fTemp15) + (fRec10[1] * fTemp21));
float fRec9 = fRec10[0];
fRec14[0] = ((0.999f * fRec14[1]) + fSlow18);
float fTemp37 = ((iSlow1)?fTemp2:(fRec14[0] * ((iSlow17)?((iSlow16)?((((((fTemp35 * fTemp17) / fTemp22) + (fRec8[1] * fTemp23)) + ((fRec8[0] * fTemp20) / fTemp19)) + ((fRec9 * ((1.0f - fTemp12) - (fTemp15 * fTemp20))) / (fTemp19 * sqrtf(fTemp16)))) / fTemp11):((fRec6[2] + (fRec6[0] + (2.0f * fRec6[1]))) / fTemp6)):fRec0[0])));
output0[i] = floatToFrac32(fTemp37);
// post processing
fRec14[1] = fRec14[0];
fRec8[1] = fRec8[0];
fRec10[1] = fRec10[0];
fRec11[1] = fRec11[0];
fRec13[1] = fRec13[0];
fRec6[2] = fRec6[1]; fRec6[1] = fRec6[0];
fRec7[2] = fRec7[1]; fRec7[1] = fRec7[0];
fRec0[1] = fRec0[0];
fRec2[1] = fRec2[0];
fRec3[1] = fRec3[0];
fRec4[1] = fRec4[0];
fRec5[1] = fRec5[0];
fRec1[1] = fRec1[0];
}
]]></code.krate>
</obj.normal>
</objdefs>
|
