File: GreyholeRaw.cpp

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supercollider-sc3-plugins 3.13.0~repack-1
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//----------------------------------------------------------
// version: "1.0"
// author: "Julian Parker, bug fixes by Till Bovermann"
// license: "GPL2+"
// name: "GreyholeRaw"
// copyright: "(c) Julian Parker 2013"
//
// Code generated with Faust 0.9.98 (http://faust.grame.fr)
//----------------------------------------------------------

/* link with : "primes" */
#include <jprev.h>
#include <math.h>
// If other than 'faust2sc --prefix Faust' is used, sed this as well:
#if !defined(SC_FAUST_PREFIX)
# define SC_FAUST_PREFIX "Faust"
#endif

//-------------------------------------------------------------------
// FAUST architecture file for SuperCollider.
// Copyright (C) 2005-2012 Stefan Kersten.
//
// This program is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public License as
// published by the Free Software Foundation; either version 2 of the
// License, or (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
// General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
// 02111-1307 USA
//-------------------------------------------------------------------

#include <map>
#include <string>
#include <string.h>
#include <SC_PlugIn.h>

#include <faust/dsp/dsp.h>
#include <faust/gui/UI.h>
#include <faust/misc.h>

using namespace std;

#if defined(__GNUC__) && __GNUC__ >= 4
# define FAUST_EXPORT __attribute__((visibility("default")))
#else
# define FAUST_EXPORT  SC_API_EXPORT
#endif

//----------------------------------------------------------------------------
// Vector intrinsics
//----------------------------------------------------------------------------


//----------------------------------------------------------------------------
// Metadata
//----------------------------------------------------------------------------

class MetaData : public Meta
               , public std::map<std::string, std::string>
{
public:
    void declare(const char* key, const char* value)
    {
        (*this)[key] = value;
    }
};

//----------------------------------------------------------------------------
// Control counter
//----------------------------------------------------------------------------

class ControlCounter : public UI
{
public:
    ControlCounter()
        : mNumControlInputs(0),
          mNumControlOutputs(0)
    { }

    size_t getNumControls() const { return getNumControlInputs(); }
    size_t getNumControlInputs() const { return mNumControlInputs; }
    size_t getNumControlOutputs() const { return mNumControlOutputs; }

    // Layout widgets
    virtual void openTabBox(const char* label) { }
    virtual void openHorizontalBox(const char* label) { }
    virtual void openVerticalBox(const char* label) { }
    virtual void closeBox() { }

    // Active widgets
    virtual void addButton(const char* label, FAUSTFLOAT* zone)
    { addControlInput(); }
    virtual void addCheckButton(const char* label, FAUSTFLOAT* zone)
    { addControlInput(); }
    virtual void addVerticalSlider(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT init, FAUSTFLOAT min, FAUSTFLOAT max, FAUSTFLOAT step)
    { addControlInput(); }
    virtual void addHorizontalSlider(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT init, FAUSTFLOAT min, FAUSTFLOAT max, FAUSTFLOAT step)
    { addControlInput(); }
    virtual void addNumEntry(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT init, FAUSTFLOAT min, FAUSTFLOAT max, FAUSTFLOAT step)
    { addControlInput(); }

    // Passive widgets
    virtual void addHorizontalBargraph(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT min, FAUSTFLOAT max)
    { addControlOutput(); }
    virtual void addVerticalBargraph(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT min, FAUSTFLOAT max)
    { addControlOutput(); }

protected:
    void addControlInput() { mNumControlInputs++; }
    void addControlOutput() { mNumControlOutputs++; }

private:
    size_t mNumControlInputs;
    size_t mNumControlOutputs;
};

//----------------------------------------------------------------------------
// UI control
//----------------------------------------------------------------------------

struct Control
{
    typedef void (*UpdateFunction)(Control* self, FAUSTFLOAT value);

    UpdateFunction updateFunction;
    FAUSTFLOAT* zone;
    FAUSTFLOAT min, max;

    inline void update(FAUSTFLOAT value)
    {
        (*updateFunction)(this, value);
    }

    static void simpleUpdate(Control* self, FAUSTFLOAT value)
    {
        *self->zone = value;
    }
    static void boundedUpdate(Control* self, FAUSTFLOAT value)
    {
        *self->zone = sc_clip(value, self->min, self->max);
    }
};

//----------------------------------------------------------------------------
// Control allocator
//----------------------------------------------------------------------------

class ControlAllocator : public UI
{
public:
    ControlAllocator(Control* controls)
        : mControls(controls)
    { }

    // Layout widgets
    virtual void openTabBox(const char* label) { }
    virtual void openHorizontalBox(const char* label) { }
    virtual void openVerticalBox(const char* label) { }
    virtual void closeBox() { }

    // Active widgets
    virtual void addButton(const char* label, FAUSTFLOAT* zone)
    { addSimpleControl(zone); }
    virtual void addCheckButton(const char* label, FAUSTFLOAT* zone)
    { addSimpleControl(zone); }
    virtual void addVerticalSlider(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT init, FAUSTFLOAT min, FAUSTFLOAT max, FAUSTFLOAT step)
    { addBoundedControl(zone, min, max, step); }
    virtual void addHorizontalSlider(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT init, FAUSTFLOAT min, FAUSTFLOAT max, FAUSTFLOAT step)
    { addBoundedControl(zone, min, max, step); }
    virtual void addNumEntry(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT init, FAUSTFLOAT min, FAUSTFLOAT max, FAUSTFLOAT step)
    { addBoundedControl(zone, min, max, step); }

    // Passive widgets
    virtual void addHorizontalBargraph(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT min, FAUSTFLOAT max) { }
    virtual void addVerticalBargraph(const char* label, FAUSTFLOAT* zone, FAUSTFLOAT min, FAUSTFLOAT max) { }

private:
    void addControl(Control::UpdateFunction updateFunction, FAUSTFLOAT* zone, FAUSTFLOAT min, FAUSTFLOAT max, FAUSTFLOAT /* step */)
    {
        Control* ctrl        = mControls++;
        ctrl->updateFunction = updateFunction;
        ctrl->zone           = zone;
        ctrl->min            = min;
        ctrl->max            = max;
    }
    void addSimpleControl(FAUSTFLOAT* zone)
    {
        addControl(Control::simpleUpdate, zone, 0.f, 0.f, 0.f);
    }
    void addBoundedControl(FAUSTFLOAT* zone, FAUSTFLOAT min, FAUSTFLOAT max, FAUSTFLOAT step)
    {
        addControl(Control::boundedUpdate, zone, min, max, step);
    }

private:
    Control* mControls;
};

//----------------------------------------------------------------------------
// FAUST generated code
//----------------------------------------------------------------------------

#ifndef FAUSTFLOAT
#define FAUSTFLOAT float
#endif  


#ifndef FAUSTCLASS 
#define FAUSTCLASS mydsp
#endif

class mydsp : public dsp {
  private:
	FAUSTFLOAT 	fslider0;
	float 	fVec0[2];
	int 	iVec1[2];
	float 	fConst0;
	float 	fConst1;
	FAUSTFLOAT 	fslider1;
	float 	fVec2[2];
	float 	fConst2;
	FAUSTFLOAT 	fslider2;
	float 	fVec3[2];
	float 	fRec39[2];
	float 	fRec40[2];
	int 	IOTA;
	float 	fVec4[131072];
	FAUSTFLOAT 	fslider3;
	float 	fRec41[2];
	float 	fRec42[2];
	float 	fRec43[2];
	float 	fRec44[2];
	FAUSTFLOAT 	fslider4;
	float 	fVec5[2];
	float 	fVec6[131072];
	float 	fVec7[16384];
	FAUSTFLOAT 	fslider5;
	float 	fRec45[2];
	float 	fRec38[2];
	float 	fRec36[2];
	float 	fVec8[16384];
	float 	fRec47[2];
	float 	fRec46[2];
	float 	fRec37[2];
	float 	fVec9[16384];
	float 	fRec48[2];
	float 	fRec35[2];
	float 	fRec33[2];
	float 	fVec10[16384];
	float 	fRec50[2];
	float 	fRec49[2];
	float 	fRec34[2];
	float 	fVec11[16384];
	float 	fRec51[2];
	float 	fRec32[2];
	float 	fRec30[2];
	float 	fVec12[16384];
	float 	fRec53[2];
	float 	fRec52[2];
	float 	fRec31[2];
	float 	fVec13[16384];
	float 	fRec54[2];
	float 	fRec29[2];
	float 	fRec27[2];
	float 	fVec14[16384];
	float 	fRec56[2];
	float 	fRec55[2];
	float 	fRec28[2];
	float 	fVec15[16384];
	float 	fRec57[2];
	float 	fRec26[2];
	float 	fRec24[2];
	float 	fVec16[16384];
	float 	fRec59[2];
	float 	fRec58[2];
	float 	fRec25[2];
	float 	fVec17[16384];
	float 	fRec60[2];
	float 	fRec23[2];
	float 	fRec21[2];
	float 	fVec18[16384];
	float 	fRec62[2];
	float 	fRec61[2];
	float 	fRec22[2];
	float 	fVec19[16384];
	float 	fRec63[2];
	float 	fRec20[2];
	float 	fRec18[2];
	float 	fVec20[16384];
	float 	fRec65[2];
	float 	fRec64[2];
	float 	fRec19[2];
	float 	fVec21[16384];
	float 	fRec66[2];
	float 	fRec17[2];
	float 	fRec15[2];
	float 	fVec22[16384];
	float 	fRec68[2];
	float 	fRec67[2];
	float 	fRec16[2];
	float 	fVec23[16384];
	float 	fRec69[2];
	float 	fRec14[2];
	float 	fRec12[2];
	float 	fVec24[16384];
	float 	fRec71[2];
	float 	fRec70[2];
	float 	fRec13[2];
	float 	fVec25[16384];
	float 	fRec72[2];
	float 	fRec11[2];
	float 	fRec9[2];
	float 	fVec26[16384];
	float 	fRec74[2];
	float 	fRec73[2];
	float 	fRec10[2];
	float 	fVec27[16384];
	float 	fRec75[2];
	float 	fRec8[2];
	float 	fRec6[2];
	float 	fVec28[16384];
	float 	fRec77[2];
	float 	fRec76[2];
	float 	fRec7[2];
	float 	fVec29[16384];
	float 	fRec78[2];
	float 	fRec5[2];
	float 	fRec3[2];
	float 	fVec30[16384];
	float 	fRec80[2];
	float 	fRec79[2];
	float 	fRec4[2];
	FAUSTFLOAT 	fslider6;
	float 	fVec31[2];
	float 	fRec2[2];
	float 	fRec0[1024];
	float 	fRec81[2];
	float 	fRec1[1024];
	int fSamplingFreq;

  public:
	virtual void metadata(Meta* m) { 
		m->declare("version", "1.0");
		m->declare("author", "Julian Parker, bug fixes by Till Bovermann");
		m->declare("license", "GPL2+");
		m->declare("name", "GreyholeRaw");
		m->declare("maths.lib/name", "Faust Math Library");
		m->declare("maths.lib/version", "2.0");
		m->declare("maths.lib/author", "GRAME");
		m->declare("maths.lib/copyright", "GRAME");
		m->declare("maths.lib/license", "LGPL with exception");
		m->declare("delays.lib/name", "Faust Delay Library");
		m->declare("delays.lib/version", "0.0");
		m->declare("filters.lib/name", "Faust Filters Library");
		m->declare("filters.lib/version", "0.0");
		m->declare("copyright", "(c) Julian Parker 2013");
		m->declare("signals.lib/name", "Faust Signal Routing Library");
		m->declare("signals.lib/version", "0.0");
		m->declare("oscillators.lib/name", "Faust Oscillator Library");
		m->declare("oscillators.lib/version", "0.0");
		m->declare("basics.lib/name", "Faust Basic Element Library");
		m->declare("basics.lib/version", "0.0");
	}

	virtual int getNumInputs() { return 2; }
	virtual int getNumOutputs() { return 2; }
	static void classInit(int samplingFreq) {
	}
	virtual void instanceConstants(int samplingFreq) {
		fSamplingFreq = samplingFreq;
		fConst0 = min(1.92e+05f, max(1e+03f, (float)fSamplingFreq));
		fConst1 = (0.00056689343f * fConst0);
		fConst2 = (3.1415927f / fConst0);
	}
	virtual void instanceResetUserInterface() {
		fslider0 = 0.5f;
		fslider1 = 0.1f;
		fslider2 = 2.0f;
		fslider3 = 0.2f;
		fslider4 = 0.9f;
		fslider5 = 1.0f;
		fslider6 = 0.0f;
	}
	virtual void instanceClear() {
		for (int i=0; i<2; i++) fVec0[i] = 0;
		for (int i=0; i<2; i++) iVec1[i] = 0;
		for (int i=0; i<2; i++) fVec2[i] = 0;
		for (int i=0; i<2; i++) fVec3[i] = 0;
		for (int i=0; i<2; i++) fRec39[i] = 0;
		for (int i=0; i<2; i++) fRec40[i] = 0;
		IOTA = 0;
		for (int i=0; i<131072; i++) fVec4[i] = 0;
		for (int i=0; i<2; i++) fRec41[i] = 0;
		for (int i=0; i<2; i++) fRec42[i] = 0;
		for (int i=0; i<2; i++) fRec43[i] = 0;
		for (int i=0; i<2; i++) fRec44[i] = 0;
		for (int i=0; i<2; i++) fVec5[i] = 0;
		for (int i=0; i<131072; i++) fVec6[i] = 0;
		for (int i=0; i<16384; i++) fVec7[i] = 0;
		for (int i=0; i<2; i++) fRec45[i] = 0;
		for (int i=0; i<2; i++) fRec38[i] = 0;
		for (int i=0; i<2; i++) fRec36[i] = 0;
		for (int i=0; i<16384; i++) fVec8[i] = 0;
		for (int i=0; i<2; i++) fRec47[i] = 0;
		for (int i=0; i<2; i++) fRec46[i] = 0;
		for (int i=0; i<2; i++) fRec37[i] = 0;
		for (int i=0; i<16384; i++) fVec9[i] = 0;
		for (int i=0; i<2; i++) fRec48[i] = 0;
		for (int i=0; i<2; i++) fRec35[i] = 0;
		for (int i=0; i<2; i++) fRec33[i] = 0;
		for (int i=0; i<16384; i++) fVec10[i] = 0;
		for (int i=0; i<2; i++) fRec50[i] = 0;
		for (int i=0; i<2; i++) fRec49[i] = 0;
		for (int i=0; i<2; i++) fRec34[i] = 0;
		for (int i=0; i<16384; i++) fVec11[i] = 0;
		for (int i=0; i<2; i++) fRec51[i] = 0;
		for (int i=0; i<2; i++) fRec32[i] = 0;
		for (int i=0; i<2; i++) fRec30[i] = 0;
		for (int i=0; i<16384; i++) fVec12[i] = 0;
		for (int i=0; i<2; i++) fRec53[i] = 0;
		for (int i=0; i<2; i++) fRec52[i] = 0;
		for (int i=0; i<2; i++) fRec31[i] = 0;
		for (int i=0; i<16384; i++) fVec13[i] = 0;
		for (int i=0; i<2; i++) fRec54[i] = 0;
		for (int i=0; i<2; i++) fRec29[i] = 0;
		for (int i=0; i<2; i++) fRec27[i] = 0;
		for (int i=0; i<16384; i++) fVec14[i] = 0;
		for (int i=0; i<2; i++) fRec56[i] = 0;
		for (int i=0; i<2; i++) fRec55[i] = 0;
		for (int i=0; i<2; i++) fRec28[i] = 0;
		for (int i=0; i<16384; i++) fVec15[i] = 0;
		for (int i=0; i<2; i++) fRec57[i] = 0;
		for (int i=0; i<2; i++) fRec26[i] = 0;
		for (int i=0; i<2; i++) fRec24[i] = 0;
		for (int i=0; i<16384; i++) fVec16[i] = 0;
		for (int i=0; i<2; i++) fRec59[i] = 0;
		for (int i=0; i<2; i++) fRec58[i] = 0;
		for (int i=0; i<2; i++) fRec25[i] = 0;
		for (int i=0; i<16384; i++) fVec17[i] = 0;
		for (int i=0; i<2; i++) fRec60[i] = 0;
		for (int i=0; i<2; i++) fRec23[i] = 0;
		for (int i=0; i<2; i++) fRec21[i] = 0;
		for (int i=0; i<16384; i++) fVec18[i] = 0;
		for (int i=0; i<2; i++) fRec62[i] = 0;
		for (int i=0; i<2; i++) fRec61[i] = 0;
		for (int i=0; i<2; i++) fRec22[i] = 0;
		for (int i=0; i<16384; i++) fVec19[i] = 0;
		for (int i=0; i<2; i++) fRec63[i] = 0;
		for (int i=0; i<2; i++) fRec20[i] = 0;
		for (int i=0; i<2; i++) fRec18[i] = 0;
		for (int i=0; i<16384; i++) fVec20[i] = 0;
		for (int i=0; i<2; i++) fRec65[i] = 0;
		for (int i=0; i<2; i++) fRec64[i] = 0;
		for (int i=0; i<2; i++) fRec19[i] = 0;
		for (int i=0; i<16384; i++) fVec21[i] = 0;
		for (int i=0; i<2; i++) fRec66[i] = 0;
		for (int i=0; i<2; i++) fRec17[i] = 0;
		for (int i=0; i<2; i++) fRec15[i] = 0;
		for (int i=0; i<16384; i++) fVec22[i] = 0;
		for (int i=0; i<2; i++) fRec68[i] = 0;
		for (int i=0; i<2; i++) fRec67[i] = 0;
		for (int i=0; i<2; i++) fRec16[i] = 0;
		for (int i=0; i<16384; i++) fVec23[i] = 0;
		for (int i=0; i<2; i++) fRec69[i] = 0;
		for (int i=0; i<2; i++) fRec14[i] = 0;
		for (int i=0; i<2; i++) fRec12[i] = 0;
		for (int i=0; i<16384; i++) fVec24[i] = 0;
		for (int i=0; i<2; i++) fRec71[i] = 0;
		for (int i=0; i<2; i++) fRec70[i] = 0;
		for (int i=0; i<2; i++) fRec13[i] = 0;
		for (int i=0; i<16384; i++) fVec25[i] = 0;
		for (int i=0; i<2; i++) fRec72[i] = 0;
		for (int i=0; i<2; i++) fRec11[i] = 0;
		for (int i=0; i<2; i++) fRec9[i] = 0;
		for (int i=0; i<16384; i++) fVec26[i] = 0;
		for (int i=0; i<2; i++) fRec74[i] = 0;
		for (int i=0; i<2; i++) fRec73[i] = 0;
		for (int i=0; i<2; i++) fRec10[i] = 0;
		for (int i=0; i<16384; i++) fVec27[i] = 0;
		for (int i=0; i<2; i++) fRec75[i] = 0;
		for (int i=0; i<2; i++) fRec8[i] = 0;
		for (int i=0; i<2; i++) fRec6[i] = 0;
		for (int i=0; i<16384; i++) fVec28[i] = 0;
		for (int i=0; i<2; i++) fRec77[i] = 0;
		for (int i=0; i<2; i++) fRec76[i] = 0;
		for (int i=0; i<2; i++) fRec7[i] = 0;
		for (int i=0; i<16384; i++) fVec29[i] = 0;
		for (int i=0; i<2; i++) fRec78[i] = 0;
		for (int i=0; i<2; i++) fRec5[i] = 0;
		for (int i=0; i<2; i++) fRec3[i] = 0;
		for (int i=0; i<16384; i++) fVec30[i] = 0;
		for (int i=0; i<2; i++) fRec80[i] = 0;
		for (int i=0; i<2; i++) fRec79[i] = 0;
		for (int i=0; i<2; i++) fRec4[i] = 0;
		for (int i=0; i<2; i++) fVec31[i] = 0;
		for (int i=0; i<2; i++) fRec2[i] = 0;
		for (int i=0; i<1024; i++) fRec0[i] = 0;
		for (int i=0; i<2; i++) fRec81[i] = 0;
		for (int i=0; i<1024; i++) fRec1[i] = 0;
	}
	virtual void init(int samplingFreq) {
		classInit(samplingFreq);
		instanceInit(samplingFreq);
	}
	virtual void instanceInit(int samplingFreq) {
		instanceConstants(samplingFreq);
		instanceResetUserInterface();
		instanceClear();
	}
	virtual mydsp* clone() {
		return new mydsp();
	}
	virtual int getSampleRate() {
		return fSamplingFreq;
	}
	virtual void buildUserInterface(UI* ui_interface) {
		ui_interface->openVerticalBox("0x00");
		ui_interface->addHorizontalSlider("damping", &fslider6, 0.0f, 0.0f, 0.99f, 0.001f);
		ui_interface->addHorizontalSlider("delayTime", &fslider3, 0.2f, 0.001f, 1.45f, 0.0001f);
		ui_interface->addHorizontalSlider("diffusion", &fslider0, 0.5f, 0.0f, 0.99f, 0.0001f);
		ui_interface->addHorizontalSlider("feedback", &fslider4, 0.9f, 0.0f, 1.0f, 0.01f);
		ui_interface->addHorizontalSlider("modDepth", &fslider1, 0.1f, 0.0f, 1.0f, 0.001f);
		ui_interface->addHorizontalSlider("modFreq", &fslider2, 2.0f, 0.0f, 1e+01f, 0.01f);
		ui_interface->addHorizontalSlider("size", &fslider5, 1.0f, 0.5f, 3.0f, 0.0001f);
		ui_interface->closeBox();
	}
	virtual void compute (int count, FAUSTFLOAT** input, FAUSTFLOAT** output) {
		float 	fSlow0 = float(fslider0);
		float 	fSlow1 = float(fslider1);
		float 	fSlow2 = float(fslider2);
		float 	fSlow3 = floorf(min((float)65533, (fConst0 * float(fslider3))));
		float 	fSlow4 = float(fslider4);
		float 	fSlow5 = float(fslider5);
		float 	fSlow6 = (49 * fSlow5);
		int 	iSlow7 = primes(fSlow6);
		float 	fSlow8 = (0.0001f * iSlow7);
		int 	iSlow9 = primes((fSlow6 + 10));
		float 	fSlow10 = (0.0001f * iSlow9);
		float 	fSlow11 = (36 * fSlow5);
		int 	iSlow12 = primes(fSlow11);
		float 	fSlow13 = (0.001f * iSlow12);
		int 	iSlow14 = primes((fSlow11 + 10));
		float 	fSlow15 = (0.001f * iSlow14);
		float 	fSlow16 = (23 * fSlow5);
		int 	iSlow17 = primes(fSlow16);
		float 	fSlow18 = (0.001f * iSlow17);
		int 	iSlow19 = primes((fSlow16 + 10));
		float 	fSlow20 = (0.001f * iSlow19);
		int 	iSlow21 = primes((10 * fSlow5));
		float 	fSlow22 = (0.001f * iSlow21);
		int 	iSlow23 = primes((10 * (fSlow5 + 1)));
		float 	fSlow24 = (0.001f * iSlow23);
		float 	fSlow25 = (68 * fSlow5);
		int 	iSlow26 = primes(fSlow25);
		float 	fSlow27 = (0.0001f * iSlow26);
		int 	iSlow28 = primes((fSlow25 + 10));
		float 	fSlow29 = (0.0001f * iSlow28);
		float 	fSlow30 = (55 * fSlow5);
		int 	iSlow31 = primes(fSlow30);
		float 	fSlow32 = (0.001f * iSlow31);
		int 	iSlow33 = primes((fSlow30 + 10));
		float 	fSlow34 = (0.001f * iSlow33);
		float 	fSlow35 = (42 * fSlow5);
		int 	iSlow36 = primes(fSlow35);
		float 	fSlow37 = (0.001f * iSlow36);
		int 	iSlow38 = primes((fSlow35 + 10));
		float 	fSlow39 = (0.001f * iSlow38);
		float 	fSlow40 = (29 * fSlow5);
		int 	iSlow41 = primes(fSlow40);
		float 	fSlow42 = (0.001f * iSlow41);
		int 	iSlow43 = primes((fSlow40 + 10));
		float 	fSlow44 = (0.001f * iSlow43);
		float 	fSlow45 = (87 * fSlow5);
		int 	iSlow46 = primes(fSlow45);
		float 	fSlow47 = (0.0001f * iSlow46);
		int 	iSlow48 = primes((fSlow45 + 10));
		float 	fSlow49 = (0.0001f * iSlow48);
		float 	fSlow50 = (74 * fSlow5);
		int 	iSlow51 = primes(fSlow50);
		float 	fSlow52 = (0.001f * iSlow51);
		int 	iSlow53 = primes((fSlow50 + 10));
		float 	fSlow54 = (0.001f * iSlow53);
		float 	fSlow55 = (61 * fSlow5);
		int 	iSlow56 = primes(fSlow55);
		float 	fSlow57 = (0.001f * iSlow56);
		int 	iSlow58 = primes((fSlow55 + 10));
		float 	fSlow59 = (0.001f * iSlow58);
		float 	fSlow60 = (48 * fSlow5);
		int 	iSlow61 = primes(fSlow60);
		float 	fSlow62 = (0.001f * iSlow61);
		int 	iSlow63 = primes((fSlow60 + 10));
		float 	fSlow64 = (0.001f * iSlow63);
		float 	fSlow65 = float(fslider6);
		FAUSTFLOAT* input0 = input[0];
		FAUSTFLOAT* input1 = input[1];
		FAUSTFLOAT* output0 = output[0];
		FAUSTFLOAT* output1 = output[1];
		for (int i=0; i<count; i++) {
			fVec0[0] = fSlow0;
			iVec1[0] = 1;
			float fTemp0 = (0.5f * (fSlow0 + fVec0[1]));
			float fTemp1 = cosf(fTemp0);
			float fTemp2 = (0 - fTemp0);
			float fTemp3 = sinf(fTemp2);
			float fTemp4 = (0 - fTemp3);
			float fTemp5 = cosf(fTemp2);
			float fTemp6 = sinf(fTemp0);
			float fTemp7 = (0 - fTemp6);
			fVec2[0] = fSlow1;
			float fTemp8 = (fSlow1 + fVec2[1]);
			fVec3[0] = fSlow2;
			float fTemp9 = (fConst2 * (fSlow2 + fVec3[1]));
			float fTemp10 = sinf(fTemp9);
			float fTemp11 = cosf(fTemp9);
			fRec39[0] = ((fTemp10 * fRec40[1]) + (fTemp11 * fRec39[1]));
			int iTemp12 = (1 - iVec1[1]);
			fRec40[0] = (((fTemp11 * fRec40[1]) + ((0 - fTemp10) * fRec39[1])) + iTemp12);
			float fTemp13 = (fConst1 * (fTemp8 * (fRec40[0] + 1.0f)));
			float fTemp14 = (fTemp13 + 8.500005f);
			int iTemp15 = int(fTemp14);
			float fTemp16 = floorf(fTemp14);
			float fTemp17 = (fTemp13 + (9.0f - fTemp16));
			float fTemp18 = (fTemp13 + (8.0f - fTemp16));
			float fTemp19 = (fTemp13 + (7.0f - fTemp16));
			float fTemp20 = (fTemp13 + (6.0f - fTemp16));
			float fTemp21 = (fTemp17 * fTemp18);
			float fTemp22 = (((((fRec0[(IOTA-int((int(min(512, max(0, iTemp15))) + 1)))&1023] * (0 - fTemp17)) * (0 - (0.5f * fTemp18))) * (0 - (0.33333334f * fTemp19))) * (0 - (0.25f * fTemp20))) + ((fTemp13 + (1e+01f - fTemp16)) * ((((((fRec0[(IOTA-int((int(min(512, max(0, (iTemp15 + 1)))) + 1)))&1023] * (0 - fTemp18)) * (0 - (0.5f * fTemp19))) * (0 - (0.33333334f * fTemp20))) + (0.5f * (((fTemp17 * fRec0[(IOTA-int((int(min(512, max(0, (iTemp15 + 2)))) + 1)))&1023]) * (0 - fTemp19)) * (0 - (0.5f * fTemp20))))) + (0.16666667f * ((fTemp21 * fRec0[(IOTA-int((int(min(512, max(0, (iTemp15 + 3)))) + 1)))&1023]) * (0 - fTemp20)))) + (0.041666668f * ((fTemp21 * fTemp19) * fRec0[(IOTA-int((int(min(512, max(0, (iTemp15 + 4)))) + 1)))&1023])))));
			fVec4[IOTA&131071] = fTemp22;
			float fTemp23 = ((int((fRec41[1] != 0.0f)))?((int(((fRec42[1] > 0.0f) & (fRec42[1] < 1.0f))))?fRec41[1]:0):((int(((fRec42[1] == 0.0f) & (fSlow3 != fRec43[1]))))?4.5351473e-05f:((int(((fRec42[1] == 1.0f) & (fSlow3 != fRec44[1]))))?-4.5351473e-05f:0)));
			fRec41[0] = fTemp23;
			fRec42[0] = max(0.0f, min(1.0f, (fRec42[1] + fTemp23)));
			fRec43[0] = ((int(((fRec42[1] >= 1.0f) & (fRec44[1] != fSlow3))))?fSlow3:fRec43[1]);
			fRec44[0] = ((int(((fRec42[1] <= 0.0f) & (fRec43[1] != fSlow3))))?fSlow3:fRec44[1]);
			int iTemp24 = int(min((float)65536, max((float)0, fRec43[0])));
			float fTemp25 = (1.0f - fRec42[0]);
			int iTemp26 = int(min((float)65536, max((float)0, fRec44[0])));
			fVec5[0] = fSlow4;
			float fTemp27 = (fSlow4 + fVec5[1]);
			float fTemp28 = ((float)input0[i] + (0.5f * (((fVec4[(IOTA-iTemp24)&131071] * fTemp25) + (fVec4[(IOTA-iTemp26)&131071] * fRec42[0])) * fTemp27)));
			float fTemp29 = ((fRec27[1] * fTemp7) + (fTemp1 * fTemp28));
			float fTemp30 = ((fRec30[1] * fTemp7) + (fTemp1 * fTemp29));
			float fTemp31 = ((fRec33[1] * fTemp7) + (fTemp1 * fTemp30));
			float fTemp32 = ((fRec36[1] * fTemp7) + (fTemp1 * fTemp31));
			float fTemp33 = (fConst1 * (fTemp8 * (fRec39[0] + 1.0f)));
			float fTemp34 = (fTemp33 + 8.500005f);
			int iTemp35 = int(fTemp34);
			float fTemp36 = floorf(fTemp34);
			float fTemp37 = (fTemp33 + (9.0f - fTemp36));
			float fTemp38 = (fTemp33 + (8.0f - fTemp36));
			float fTemp39 = (fTemp33 + (7.0f - fTemp36));
			float fTemp40 = (fTemp33 + (6.0f - fTemp36));
			float fTemp41 = (fTemp37 * fTemp38);
			float fTemp42 = (((((fRec1[(IOTA-int((int(min(512, max(0, iTemp35))) + 1)))&1023] * (0 - fTemp37)) * (0 - (0.5f * fTemp38))) * (0 - (0.33333334f * fTemp39))) * (0 - (0.25f * fTemp40))) + ((fTemp33 + (1e+01f - fTemp36)) * ((((((fRec1[(IOTA-int((int(min(512, max(0, (iTemp35 + 1)))) + 1)))&1023] * (0 - fTemp38)) * (0 - (0.5f * fTemp39))) * (0 - (0.33333334f * fTemp40))) + (0.5f * (((fTemp37 * fRec1[(IOTA-int((int(min(512, max(0, (iTemp35 + 2)))) + 1)))&1023]) * (0 - fTemp39)) * (0 - (0.5f * fTemp40))))) + (0.16666667f * ((fTemp41 * fRec1[(IOTA-int((int(min(512, max(0, (iTemp35 + 3)))) + 1)))&1023]) * (0 - fTemp40)))) + (0.041666668f * ((fTemp41 * fTemp39) * fRec1[(IOTA-int((int(min(512, max(0, (iTemp35 + 4)))) + 1)))&1023])))));
			fVec6[IOTA&131071] = fTemp42;
			float fTemp43 = ((float)input1[i] + (0.5f * (fTemp27 * ((fVec6[(IOTA-iTemp26)&131071] * fRec42[0]) + (fVec6[(IOTA-iTemp24)&131071] * fTemp25)))));
			float fTemp44 = ((fRec28[1] * fTemp7) + (fTemp1 * fTemp43));
			float fTemp45 = ((fRec31[1] * fTemp7) + (fTemp1 * fTemp44));
			float fTemp46 = ((fRec34[1] * fTemp7) + (fTemp1 * fTemp45));
			float fTemp47 = ((fRec37[1] * fTemp7) + (fTemp1 * fTemp46));
			float fTemp48 = ((6.123234e-17f * fTemp32) - fTemp47);
			fVec7[IOTA&16383] = fTemp48;
			fRec45[0] = (fSlow8 + (0.9999f * ((iSlow7 * iTemp12) + fRec45[1])));
			float fTemp49 = (fRec45[0] + -1.49999f);
			int iTemp50 = int(min(8192, max(0, int(fTemp49))));
			float fTemp51 = floorf(fTemp49);
			float fTemp52 = (fTemp51 + (2.0f - fRec45[0]));
			float fTemp53 = (fRec45[0] - fTemp51);
			fRec38[0] = (fVec7[(IOTA-int((iTemp50 + 1)))&16383] + ((fRec38[1] * (0 - (fTemp52 / fTemp53))) + ((fTemp52 * fVec7[(IOTA-iTemp50)&16383]) / fTemp53)));
			fRec36[0] = fRec38[0];
			float fTemp54 = (fTemp32 + (6.123234e-17f * fTemp47));
			fVec8[IOTA&16383] = fTemp54;
			fRec47[0] = (fSlow10 + (0.9999f * ((iSlow9 * iTemp12) + fRec47[1])));
			float fTemp55 = (fRec47[0] + -1.49999f);
			int iTemp56 = int(min(8192, max(0, int(fTemp55))));
			float fTemp57 = floorf(fTemp55);
			float fTemp58 = (fTemp57 + (2.0f - fRec47[0]));
			float fTemp59 = (fRec47[0] - fTemp57);
			fRec46[0] = (fVec8[(IOTA-int((iTemp56 + 1)))&16383] + ((fRec46[1] * (0 - (fTemp58 / fTemp59))) + ((fTemp58 * fVec8[(IOTA-iTemp56)&16383]) / fTemp59)));
			fRec37[0] = fRec46[0];
			float fTemp60 = ((fRec36[1] * fTemp1) + (fTemp31 * fTemp6));
			float fTemp61 = ((fTemp1 * fRec37[1]) + (fTemp46 * fTemp6));
			float fTemp62 = ((6.123234e-17f * fTemp60) - fTemp61);
			fVec9[IOTA&16383] = fTemp62;
			fRec48[0] = (fSlow13 + (0.999f * ((iSlow12 * iTemp12) + fRec48[1])));
			float fTemp63 = (fRec48[0] + -1.49999f);
			int iTemp64 = int(min(8192, max(0, int(fTemp63))));
			float fTemp65 = floorf(fTemp63);
			float fTemp66 = (fTemp65 + (2.0f - fRec48[0]));
			float fTemp67 = (fRec48[0] - fTemp65);
			fRec35[0] = (fVec9[(IOTA-int((iTemp64 + 1)))&16383] + ((fRec35[1] * (0 - (fTemp66 / fTemp67))) + ((fTemp66 * fVec9[(IOTA-iTemp64)&16383]) / fTemp67)));
			fRec33[0] = fRec35[0];
			float fTemp68 = ((6.123234e-17f * fTemp61) + fTemp60);
			fVec10[IOTA&16383] = fTemp68;
			fRec50[0] = (fSlow15 + (0.999f * ((iSlow14 * iTemp12) + fRec50[1])));
			float fTemp69 = (fRec50[0] + -1.49999f);
			int iTemp70 = int(min(8192, max(0, int(fTemp69))));
			float fTemp71 = floorf(fTemp69);
			float fTemp72 = (fTemp71 + (2.0f - fRec50[0]));
			float fTemp73 = (fRec50[0] - fTemp71);
			fRec49[0] = ((((fVec10[(IOTA-iTemp70)&16383] * fTemp72) / fTemp73) + fVec10[(IOTA-int((iTemp70 + 1)))&16383]) + (fRec49[1] * (0 - (fTemp72 / fTemp73))));
			fRec34[0] = fRec49[0];
			float fTemp74 = ((fRec33[1] * fTemp1) + (fTemp30 * fTemp6));
			float fTemp75 = ((fTemp1 * fRec34[1]) + (fTemp45 * fTemp6));
			float fTemp76 = ((6.123234e-17f * fTemp74) - fTemp75);
			fVec11[IOTA&16383] = fTemp76;
			fRec51[0] = (fSlow18 + (0.999f * ((iSlow17 * iTemp12) + fRec51[1])));
			float fTemp77 = (fRec51[0] + -1.49999f);
			int iTemp78 = int(min(8192, max(0, int(fTemp77))));
			float fTemp79 = floorf(fTemp77);
			float fTemp80 = (fTemp79 + (2.0f - fRec51[0]));
			float fTemp81 = (fRec51[0] - fTemp79);
			fRec32[0] = (fVec11[(IOTA-int((iTemp78 + 1)))&16383] + ((fRec32[1] * (0 - (fTemp80 / fTemp81))) + ((fTemp80 * fVec11[(IOTA-iTemp78)&16383]) / fTemp81)));
			fRec30[0] = fRec32[0];
			float fTemp82 = (fTemp74 + (6.123234e-17f * fTemp75));
			fVec12[IOTA&16383] = fTemp82;
			fRec53[0] = (fSlow20 + (0.999f * ((iSlow19 * iTemp12) + fRec53[1])));
			float fTemp83 = (fRec53[0] + -1.49999f);
			int iTemp84 = int(min(8192, max(0, int(fTemp83))));
			float fTemp85 = floorf(fTemp83);
			float fTemp86 = (fTemp85 + (2.0f - fRec53[0]));
			float fTemp87 = (fRec53[0] - fTemp85);
			fRec52[0] = (fVec12[(IOTA-int((iTemp84 + 1)))&16383] + ((fRec52[1] * (0 - (fTemp86 / fTemp87))) + ((fTemp86 * fVec12[(IOTA-iTemp84)&16383]) / fTemp87)));
			fRec31[0] = fRec52[0];
			float fTemp88 = ((fRec30[1] * fTemp1) + (fTemp29 * fTemp6));
			float fTemp89 = ((fTemp1 * fRec31[1]) + (fTemp44 * fTemp6));
			float fTemp90 = ((6.123234e-17f * fTemp88) - fTemp89);
			fVec13[IOTA&16383] = fTemp90;
			fRec54[0] = (fSlow22 + (0.999f * ((iSlow21 * iTemp12) + fRec54[1])));
			float fTemp91 = (fRec54[0] + -1.49999f);
			int iTemp92 = int(min(8192, max(0, int(fTemp91))));
			float fTemp93 = floorf(fTemp91);
			float fTemp94 = (fTemp93 + (2.0f - fRec54[0]));
			float fTemp95 = (fRec54[0] - fTemp93);
			fRec29[0] = (fVec13[(IOTA-int((iTemp92 + 1)))&16383] + ((fRec29[1] * (0 - (fTemp94 / fTemp95))) + ((fTemp94 * fVec13[(IOTA-iTemp92)&16383]) / fTemp95)));
			fRec27[0] = fRec29[0];
			float fTemp96 = (fTemp88 + (6.123234e-17f * fTemp89));
			fVec14[IOTA&16383] = fTemp96;
			fRec56[0] = (fSlow24 + (0.999f * ((iSlow23 * iTemp12) + fRec56[1])));
			float fTemp97 = (fRec56[0] + -1.49999f);
			int iTemp98 = int(min(8192, max(0, int(fTemp97))));
			float fTemp99 = floorf(fTemp97);
			float fTemp100 = (fTemp99 + (2.0f - fRec56[0]));
			float fTemp101 = (fRec56[0] - fTemp99);
			fRec55[0] = (fVec14[(IOTA-int((iTemp98 + 1)))&16383] + ((fRec55[1] * (0 - (fTemp100 / fTemp101))) + ((fTemp100 * fVec14[(IOTA-iTemp98)&16383]) / fTemp101)));
			fRec28[0] = fRec55[0];
			float fTemp102 = ((fRec27[1] * fTemp1) + (fTemp28 * fTemp6));
			float fTemp103 = ((fTemp4 * fRec15[1]) + (fTemp102 * fTemp5));
			float fTemp104 = ((fTemp4 * fRec18[1]) + (fTemp5 * fTemp103));
			float fTemp105 = ((fTemp4 * fRec21[1]) + (fTemp5 * fTemp104));
			float fTemp106 = ((fRec24[1] * fTemp4) + (fTemp5 * fTemp105));
			float fTemp107 = ((fTemp1 * fRec28[1]) + (fTemp43 * fTemp6));
			float fTemp108 = ((fTemp4 * fRec16[1]) + (fTemp5 * fTemp107));
			float fTemp109 = ((fTemp4 * fRec19[1]) + (fTemp5 * fTemp108));
			float fTemp110 = ((fTemp4 * fRec22[1]) + (fTemp5 * fTemp109));
			float fTemp111 = ((fTemp4 * fRec25[1]) + (fTemp5 * fTemp110));
			float fTemp112 = ((6.123234e-17f * fTemp106) - fTemp111);
			fVec15[IOTA&16383] = fTemp112;
			fRec57[0] = (fSlow27 + (0.9999f * ((iSlow26 * iTemp12) + fRec57[1])));
			float fTemp113 = (fRec57[0] + -1.49999f);
			int iTemp114 = int(min(8192, max(0, int(fTemp113))));
			float fTemp115 = floorf(fTemp113);
			float fTemp116 = (fTemp115 + (2.0f - fRec57[0]));
			float fTemp117 = (fRec57[0] - fTemp115);
			fRec26[0] = (fVec15[(IOTA-int((iTemp114 + 1)))&16383] + ((fRec26[1] * (0 - (fTemp116 / fTemp117))) + ((fTemp116 * fVec15[(IOTA-iTemp114)&16383]) / fTemp117)));
			fRec24[0] = fRec26[0];
			float fTemp118 = (fTemp106 + (6.123234e-17f * fTemp111));
			fVec16[IOTA&16383] = fTemp118;
			fRec59[0] = (fSlow29 + (0.9999f * ((iSlow28 * iTemp12) + fRec59[1])));
			float fTemp119 = (fRec59[0] + -1.49999f);
			int iTemp120 = int(min(8192, max(0, int(fTemp119))));
			float fTemp121 = floorf(fTemp119);
			float fTemp122 = (fTemp121 + (2.0f - fRec59[0]));
			float fTemp123 = (fRec59[0] - fTemp121);
			fRec58[0] = (fVec16[(IOTA-int((iTemp120 + 1)))&16383] + ((fRec58[1] * (0 - (fTemp122 / fTemp123))) + ((fTemp122 * fVec16[(IOTA-iTemp120)&16383]) / fTemp123)));
			fRec25[0] = fRec58[0];
			float fTemp124 = ((fRec24[1] * fTemp5) + (fTemp3 * fTemp105));
			float fTemp125 = ((fTemp5 * fRec25[1]) + (fTemp3 * fTemp110));
			float fTemp126 = ((6.123234e-17f * fTemp124) - fTemp125);
			fVec17[IOTA&16383] = fTemp126;
			fRec60[0] = (fSlow32 + (0.999f * ((iSlow31 * iTemp12) + fRec60[1])));
			float fTemp127 = (fRec60[0] + -1.49999f);
			int iTemp128 = int(min(8192, max(0, int(fTemp127))));
			float fTemp129 = floorf(fTemp127);
			float fTemp130 = (fTemp129 + (2.0f - fRec60[0]));
			float fTemp131 = (fRec60[0] - fTemp129);
			fRec23[0] = (fVec17[(IOTA-int((iTemp128 + 1)))&16383] + (((0 - (fTemp130 / fTemp131)) * fRec23[1]) + ((fVec17[(IOTA-iTemp128)&16383] * fTemp130) / fTemp131)));
			fRec21[0] = fRec23[0];
			float fTemp132 = (fTemp124 + (6.123234e-17f * fTemp125));
			fVec18[IOTA&16383] = fTemp132;
			fRec62[0] = (fSlow34 + (0.999f * ((iSlow33 * iTemp12) + fRec62[1])));
			float fTemp133 = (fRec62[0] + -1.49999f);
			int iTemp134 = int(min(8192, max(0, int(fTemp133))));
			float fTemp135 = floorf(fTemp133);
			float fTemp136 = (fTemp135 + (2.0f - fRec62[0]));
			float fTemp137 = (fRec62[0] - fTemp135);
			fRec61[0] = (fVec18[(IOTA-int((iTemp134 + 1)))&16383] + ((fRec61[1] * (0 - (fTemp136 / fTemp137))) + ((fTemp136 * fVec18[(IOTA-iTemp134)&16383]) / fTemp137)));
			fRec22[0] = fRec61[0];
			float fTemp138 = ((fRec21[1] * fTemp5) + (fTemp3 * fTemp104));
			float fTemp139 = ((fTemp5 * fRec22[1]) + (fTemp3 * fTemp109));
			float fTemp140 = ((6.123234e-17f * fTemp138) - fTemp139);
			fVec19[IOTA&16383] = fTemp140;
			fRec63[0] = (fSlow37 + (0.999f * ((iSlow36 * iTemp12) + fRec63[1])));
			float fTemp141 = (fRec63[0] + -1.49999f);
			int iTemp142 = int(min(8192, max(0, int(fTemp141))));
			float fTemp143 = floorf(fTemp141);
			float fTemp144 = (fTemp143 + (2.0f - fRec63[0]));
			float fTemp145 = (fRec63[0] - fTemp143);
			fRec20[0] = ((((fVec19[(IOTA-iTemp142)&16383] * fTemp144) / fTemp145) + fVec19[(IOTA-int((iTemp142 + 1)))&16383]) + (fRec20[1] * (0 - (fTemp144 / fTemp145))));
			fRec18[0] = fRec20[0];
			float fTemp146 = (fTemp138 + (6.123234e-17f * fTemp139));
			fVec20[IOTA&16383] = fTemp146;
			fRec65[0] = (fSlow39 + (0.999f * ((iSlow38 * iTemp12) + fRec65[1])));
			float fTemp147 = (fRec65[0] + -1.49999f);
			int iTemp148 = int(min(8192, max(0, int(fTemp147))));
			float fTemp149 = floorf(fTemp147);
			float fTemp150 = (fTemp149 + (2.0f - fRec65[0]));
			float fTemp151 = (fRec65[0] - fTemp149);
			fRec64[0] = (fVec20[(IOTA-int((iTemp148 + 1)))&16383] + ((fRec64[1] * (0 - (fTemp150 / fTemp151))) + ((fTemp150 * fVec20[(IOTA-iTemp148)&16383]) / fTemp151)));
			fRec19[0] = fRec64[0];
			float fTemp152 = ((fRec18[1] * fTemp5) + (fTemp3 * fTemp103));
			float fTemp153 = ((fTemp5 * fRec19[1]) + (fTemp3 * fTemp108));
			float fTemp154 = ((6.123234e-17f * fTemp152) - fTemp153);
			fVec21[IOTA&16383] = fTemp154;
			fRec66[0] = (fSlow42 + (0.999f * ((iSlow41 * iTemp12) + fRec66[1])));
			float fTemp155 = (fRec66[0] + -1.49999f);
			int iTemp156 = int(min(8192, max(0, int(fTemp155))));
			float fTemp157 = floorf(fTemp155);
			float fTemp158 = (fTemp157 + (2.0f - fRec66[0]));
			float fTemp159 = (fRec66[0] - fTemp157);
			fRec17[0] = ((((fVec21[(IOTA-iTemp156)&16383] * fTemp158) / fTemp159) + fVec21[(IOTA-int((iTemp156 + 1)))&16383]) + (fRec17[1] * (0 - (fTemp158 / fTemp159))));
			fRec15[0] = fRec17[0];
			float fTemp160 = (fTemp152 + (6.123234e-17f * fTemp153));
			fVec22[IOTA&16383] = fTemp160;
			fRec68[0] = (fSlow44 + (0.999f * ((iSlow43 * iTemp12) + fRec68[1])));
			float fTemp161 = (fRec68[0] + -1.49999f);
			int iTemp162 = int(min(8192, max(0, int(fTemp161))));
			float fTemp163 = floorf(fTemp161);
			float fTemp164 = (fTemp163 + (2.0f - fRec68[0]));
			float fTemp165 = (fRec68[0] - fTemp163);
			fRec67[0] = (fVec22[(IOTA-int((iTemp162 + 1)))&16383] + ((fRec67[1] * (0 - (fTemp164 / fTemp165))) + ((fTemp164 * fVec22[(IOTA-iTemp162)&16383]) / fTemp165)));
			fRec16[0] = fRec67[0];
			float fTemp166 = ((fRec15[1] * fTemp5) + (fTemp3 * fTemp102));
			float fTemp167 = ((fTemp1 * fTemp166) + (fTemp7 * fRec3[1]));
			float fTemp168 = ((fTemp1 * fTemp167) + (fTemp7 * fRec6[1]));
			float fTemp169 = ((fTemp1 * fTemp168) + (fTemp7 * fRec9[1]));
			float fTemp170 = (fTemp1 * fTemp169);
			float fTemp171 = (fRec12[1] * fTemp7);
			float fTemp172 = ((fTemp5 * fRec16[1]) + (fTemp3 * fTemp107));
			float fTemp173 = ((fRec4[1] * fTemp7) + (fTemp1 * fTemp172));
			float fTemp174 = ((fRec7[1] * fTemp7) + (fTemp1 * fTemp173));
			float fTemp175 = ((fRec10[1] * fTemp7) + (fTemp1 * fTemp174));
			float fTemp176 = ((fRec13[1] * fTemp7) + (fTemp1 * fTemp175));
			float fTemp177 = ((6.123234e-17f * (fTemp170 + fTemp171)) - fTemp176);
			fVec23[IOTA&16383] = fTemp177;
			fRec69[0] = (fSlow47 + (0.9999f * ((iSlow46 * iTemp12) + fRec69[1])));
			float fTemp178 = (fRec69[0] + -1.49999f);
			int iTemp179 = int(min(8192, max(0, int(fTemp178))));
			float fTemp180 = floorf(fTemp178);
			float fTemp181 = (fTemp180 + (2.0f - fRec69[0]));
			float fTemp182 = (fRec69[0] - fTemp180);
			fRec14[0] = ((((fVec23[(IOTA-iTemp179)&16383] * fTemp181) / fTemp182) + fVec23[(IOTA-int((iTemp179 + 1)))&16383]) + (fRec14[1] * (0 - (fTemp181 / fTemp182))));
			fRec12[0] = fRec14[0];
			float fTemp183 = ((fTemp170 + (6.123234e-17f * fTemp176)) + fTemp171);
			fVec24[IOTA&16383] = fTemp183;
			fRec71[0] = (fSlow49 + (0.9999f * ((iSlow48 * iTemp12) + fRec71[1])));
			float fTemp184 = (fRec71[0] + -1.49999f);
			int iTemp185 = int(min(8192, max(0, int(fTemp184))));
			float fTemp186 = floorf(fTemp184);
			float fTemp187 = (fTemp186 + (2.0f - fRec71[0]));
			float fTemp188 = (fRec71[0] - fTemp186);
			fRec70[0] = (fVec24[(IOTA-int((iTemp185 + 1)))&16383] + ((fRec70[1] * (0 - (fTemp187 / fTemp188))) + ((fTemp187 * fVec24[(IOTA-iTemp185)&16383]) / fTemp188)));
			fRec13[0] = fRec70[0];
			float fTemp189 = ((fTemp1 * fRec12[1]) + (fTemp169 * fTemp6));
			float fTemp190 = ((fTemp1 * fRec13[1]) + (fTemp175 * fTemp6));
			float fTemp191 = ((6.123234e-17f * fTemp189) - fTemp190);
			fVec25[IOTA&16383] = fTemp191;
			fRec72[0] = (fSlow52 + (0.999f * ((iSlow51 * iTemp12) + fRec72[1])));
			float fTemp192 = (fRec72[0] + -1.49999f);
			int iTemp193 = int(min(8192, max(0, int(fTemp192))));
			float fTemp194 = floorf(fTemp192);
			float fTemp195 = (fTemp194 + (2.0f - fRec72[0]));
			float fTemp196 = (fRec72[0] - fTemp194);
			fRec11[0] = ((((fVec25[(IOTA-iTemp193)&16383] * fTemp195) / fTemp196) + fVec25[(IOTA-int((iTemp193 + 1)))&16383]) + (fRec11[1] * (0 - (fTemp195 / fTemp196))));
			fRec9[0] = fRec11[0];
			float fTemp197 = (fTemp189 + (6.123234e-17f * fTemp190));
			fVec26[IOTA&16383] = fTemp197;
			fRec74[0] = (fSlow54 + (0.999f * ((iSlow53 * iTemp12) + fRec74[1])));
			float fTemp198 = (fRec74[0] + -1.49999f);
			int iTemp199 = int(min(8192, max(0, int(fTemp198))));
			float fTemp200 = floorf(fTemp198);
			float fTemp201 = (fTemp200 + (2.0f - fRec74[0]));
			float fTemp202 = (fRec74[0] - fTemp200);
			fRec73[0] = (fVec26[(IOTA-int((iTemp199 + 1)))&16383] + ((fRec73[1] * (0 - (fTemp201 / fTemp202))) + ((fTemp201 * fVec26[(IOTA-iTemp199)&16383]) / fTemp202)));
			fRec10[0] = fRec73[0];
			float fTemp203 = ((fTemp1 * fRec9[1]) + (fTemp168 * fTemp6));
			float fTemp204 = ((fTemp1 * fRec10[1]) + (fTemp174 * fTemp6));
			float fTemp205 = ((6.123234e-17f * fTemp203) - fTemp204);
			fVec27[IOTA&16383] = fTemp205;
			fRec75[0] = (fSlow57 + (0.999f * ((iSlow56 * iTemp12) + fRec75[1])));
			float fTemp206 = (fRec75[0] + -1.49999f);
			int iTemp207 = int(min(8192, max(0, int(fTemp206))));
			float fTemp208 = floorf(fTemp206);
			float fTemp209 = (fTemp208 + (2.0f - fRec75[0]));
			float fTemp210 = (fRec75[0] - fTemp208);
			fRec8[0] = ((((fVec27[(IOTA-iTemp207)&16383] * fTemp209) / fTemp210) + fVec27[(IOTA-int((iTemp207 + 1)))&16383]) + (fRec8[1] * (0 - (fTemp209 / fTemp210))));
			fRec6[0] = fRec8[0];
			float fTemp211 = (fTemp203 + (6.123234e-17f * fTemp204));
			fVec28[IOTA&16383] = fTemp211;
			fRec77[0] = (fSlow59 + (0.999f * ((iSlow58 * iTemp12) + fRec77[1])));
			float fTemp212 = (fRec77[0] + -1.49999f);
			int iTemp213 = int(min(8192, max(0, int(fTemp212))));
			float fTemp214 = floorf(fTemp212);
			float fTemp215 = (fTemp214 + (2.0f - fRec77[0]));
			float fTemp216 = (fRec77[0] - fTemp214);
			fRec76[0] = (fVec28[(IOTA-int((iTemp213 + 1)))&16383] + ((fRec76[1] * (0 - (fTemp215 / fTemp216))) + ((fTemp215 * fVec28[(IOTA-iTemp213)&16383]) / fTemp216)));
			fRec7[0] = fRec76[0];
			float fTemp217 = ((fTemp1 * fRec6[1]) + (fTemp167 * fTemp6));
			float fTemp218 = ((fTemp1 * fRec7[1]) + (fTemp173 * fTemp6));
			float fTemp219 = ((6.123234e-17f * fTemp217) - fTemp218);
			fVec29[IOTA&16383] = fTemp219;
			fRec78[0] = (fSlow62 + (0.999f * ((iSlow61 * iTemp12) + fRec78[1])));
			float fTemp220 = (fRec78[0] + -1.49999f);
			int iTemp221 = int(min(8192, max(0, int(fTemp220))));
			float fTemp222 = floorf(fTemp220);
			float fTemp223 = (fTemp222 + (2.0f - fRec78[0]));
			float fTemp224 = (fRec78[0] - fTemp222);
			fRec5[0] = ((((fVec29[(IOTA-iTemp221)&16383] * fTemp223) / fTemp224) + fVec29[(IOTA-int((iTemp221 + 1)))&16383]) + (fRec5[1] * (0 - (fTemp223 / fTemp224))));
			fRec3[0] = fRec5[0];
			float fTemp225 = (fTemp217 + (6.123234e-17f * fTemp218));
			fVec30[IOTA&16383] = fTemp225;
			fRec80[0] = (fSlow64 + (0.999f * ((iSlow63 * iTemp12) + fRec80[1])));
			float fTemp226 = (fRec80[0] + -1.49999f);
			int iTemp227 = int(min(8192, max(0, int(fTemp226))));
			float fTemp228 = floorf(fTemp226);
			float fTemp229 = (fTemp228 + (2.0f - fRec80[0]));
			float fTemp230 = (fRec80[0] - fTemp228);
			fRec79[0] = (fVec30[(IOTA-int((iTemp227 + 1)))&16383] + ((fRec79[1] * (0 - (fTemp229 / fTemp230))) + ((fTemp229 * fVec30[(IOTA-iTemp227)&16383]) / fTemp230)));
			fRec4[0] = fRec79[0];
			fVec31[0] = fSlow65;
			float fTemp231 = (fSlow65 + fVec31[1]);
			float fTemp232 = (1.0f - (0.5f * fTemp231));
			fRec2[0] = ((((fTemp1 * fRec3[1]) + (fTemp166 * fTemp6)) * fTemp232) + (0.5f * (fTemp231 * fRec2[1])));
			fRec0[IOTA&1023] = fRec2[0];
			fRec81[0] = ((0.5f * (fTemp231 * fRec81[1])) + (fTemp232 * ((fTemp172 * fTemp6) + (fTemp1 * fRec4[1]))));
			fRec1[IOTA&1023] = fRec81[0];
			output0[i] = (FAUSTFLOAT)fRec0[(IOTA-0)&1023];
			output1[i] = (FAUSTFLOAT)fRec1[(IOTA-0)&1023];
			// post processing
			fRec81[1] = fRec81[0];
			fRec2[1] = fRec2[0];
			fVec31[1] = fVec31[0];
			fRec4[1] = fRec4[0];
			fRec79[1] = fRec79[0];
			fRec80[1] = fRec80[0];
			fRec3[1] = fRec3[0];
			fRec5[1] = fRec5[0];
			fRec78[1] = fRec78[0];
			fRec7[1] = fRec7[0];
			fRec76[1] = fRec76[0];
			fRec77[1] = fRec77[0];
			fRec6[1] = fRec6[0];
			fRec8[1] = fRec8[0];
			fRec75[1] = fRec75[0];
			fRec10[1] = fRec10[0];
			fRec73[1] = fRec73[0];
			fRec74[1] = fRec74[0];
			fRec9[1] = fRec9[0];
			fRec11[1] = fRec11[0];
			fRec72[1] = fRec72[0];
			fRec13[1] = fRec13[0];
			fRec70[1] = fRec70[0];
			fRec71[1] = fRec71[0];
			fRec12[1] = fRec12[0];
			fRec14[1] = fRec14[0];
			fRec69[1] = fRec69[0];
			fRec16[1] = fRec16[0];
			fRec67[1] = fRec67[0];
			fRec68[1] = fRec68[0];
			fRec15[1] = fRec15[0];
			fRec17[1] = fRec17[0];
			fRec66[1] = fRec66[0];
			fRec19[1] = fRec19[0];
			fRec64[1] = fRec64[0];
			fRec65[1] = fRec65[0];
			fRec18[1] = fRec18[0];
			fRec20[1] = fRec20[0];
			fRec63[1] = fRec63[0];
			fRec22[1] = fRec22[0];
			fRec61[1] = fRec61[0];
			fRec62[1] = fRec62[0];
			fRec21[1] = fRec21[0];
			fRec23[1] = fRec23[0];
			fRec60[1] = fRec60[0];
			fRec25[1] = fRec25[0];
			fRec58[1] = fRec58[0];
			fRec59[1] = fRec59[0];
			fRec24[1] = fRec24[0];
			fRec26[1] = fRec26[0];
			fRec57[1] = fRec57[0];
			fRec28[1] = fRec28[0];
			fRec55[1] = fRec55[0];
			fRec56[1] = fRec56[0];
			fRec27[1] = fRec27[0];
			fRec29[1] = fRec29[0];
			fRec54[1] = fRec54[0];
			fRec31[1] = fRec31[0];
			fRec52[1] = fRec52[0];
			fRec53[1] = fRec53[0];
			fRec30[1] = fRec30[0];
			fRec32[1] = fRec32[0];
			fRec51[1] = fRec51[0];
			fRec34[1] = fRec34[0];
			fRec49[1] = fRec49[0];
			fRec50[1] = fRec50[0];
			fRec33[1] = fRec33[0];
			fRec35[1] = fRec35[0];
			fRec48[1] = fRec48[0];
			fRec37[1] = fRec37[0];
			fRec46[1] = fRec46[0];
			fRec47[1] = fRec47[0];
			fRec36[1] = fRec36[0];
			fRec38[1] = fRec38[0];
			fRec45[1] = fRec45[0];
			fVec5[1] = fVec5[0];
			fRec44[1] = fRec44[0];
			fRec43[1] = fRec43[0];
			fRec42[1] = fRec42[0];
			fRec41[1] = fRec41[0];
			IOTA = IOTA+1;
			fRec40[1] = fRec40[0];
			fRec39[1] = fRec39[0];
			fVec3[1] = fVec3[0];
			fVec2[1] = fVec2[0];
			iVec1[1] = iVec1[0];
			fVec0[1] = fVec0[0];
		}
	}
};



//----------------------------------------------------------------------------
// SuperCollider/Faust interface
//----------------------------------------------------------------------------

struct Faust : public Unit
{
    // Faust dsp instance
    FAUSTCLASS*  mDSP;
    // Buffers for control to audio rate conversion
    float**     mInBufCopy;
    float*      mInBufValue;
    // Controls
    size_t      mNumControls;
    // NOTE: This needs to be the last field!
    //
    // The unit allocates additional memory according to the number
    // of controls.
    Control     mControls[0];

    int getNumAudioInputs() { return mDSP->getNumInputs(); }
};

// Global state

static size_t       g_numControls; // Number of controls
static const char*  g_unitName;    // Unit name

// Initialize the global state with unit name and sample rate.
void initState(const std::string& name, int sampleRate);

// Return the unit size in bytes, including static fields and controls.
static size_t unitSize();

// Convert a file name to a valid unit name.
static std::string fileNameToUnitName(const std::string& fileName);

// Convert the XML unit name to a valid class name.
static std::string normalizeClassName(const std::string& name);

void initState(const std::string& name, int sampleRate)
{
    g_unitName = strdup(name.c_str());

    mydsp* dsp = new FAUSTCLASS;
    ControlCounter* cc = new ControlCounter;

    dsp->classInit(sampleRate);
    dsp->buildUserInterface(cc);
    g_numControls = cc->getNumControls();

    delete dsp;
    delete cc;
}

size_t unitSize()
{
    return sizeof(Faust) + g_numControls * sizeof(Control);
}

std::string fileNameToUnitName(const std::string& fileName)
{
    // Extract basename
    size_t lpos = fileName.rfind('/', fileName.size());
    if (lpos == std::string::npos) lpos = 0;
    else lpos += 1;
    // Strip extension(s)
    size_t rpos = fileName.find('.', lpos);
    // Return substring
    return fileName.substr(lpos, rpos > lpos ? rpos - lpos : 0);
}

// Globals

static InterfaceTable* ft;

// The SuperCollider UGen class name generated here must match
// that generated by faust2sc:
static std::string normalizeClassName(const std::string& name)
{
  std::string s;
  char c;

  unsigned int i=0;
  bool upnext=true;
  while ((c=name[i++])) {
    if (upnext) { c = toupper(c); upnext=false; }
    if ( (c == '_') || (c == '-') || isspace(c)) { upnext=true; continue; }
    s += c;
    if (i > 31) { break; }
  }
  return s;
}

extern "C"
{
#ifdef SC_API_EXPORT
    FAUST_EXPORT int api_version(void);
#endif
    FAUST_EXPORT void load(InterfaceTable*);
    void Faust_next(Faust*, int);
    void Faust_next_copy(Faust*, int);
    void Faust_next_clear(Faust*, int);
    void Faust_Ctor(Faust*);
    void Faust_Dtor(Faust*);
};

inline static void fillBuffer(float* dst, int n, float v)
{
    Fill(n, dst, v);
}

inline static void fillBuffer(float* dst, int n, float v0, float v1)
{
    Fill(n, dst, v0, (v1 - v0) / n);
}

inline static void copyBuffer(float* dst, int n, float* src)
{
    Copy(n, dst, src);
}

inline static void Faust_updateControls(Faust* unit)
{
    Control* controls = unit->mControls;
    int numControls   = unit->mNumControls;
    int curControl    = unit->mDSP->getNumInputs();
    for (int i=0; i < numControls; ++i) {
        float value = IN0(curControl);
        (controls++)->update(value);
        curControl++;
    }
}

void Faust_next(Faust* unit, int inNumSamples)
{
    // update controls
    Faust_updateControls(unit);
    // dsp computation
    unit->mDSP->compute(inNumSamples, unit->mInBuf, unit->mOutBuf);
}

void Faust_next_copy(Faust* unit, int inNumSamples)
{
    // update controls
    Faust_updateControls(unit);
    // Copy buffers
    for (int i = 0; i < unit->getNumAudioInputs(); ++i) {
        float* b = unit->mInBufCopy[i];
        if (INRATE(i) == calc_FullRate) {
            // Audio rate: copy buffer
            copyBuffer(b, inNumSamples, unit->mInBuf[i]);
        } else {
            // Control rate: linearly interpolate input
            float v1 = IN0(i);
            fillBuffer(b, inNumSamples, unit->mInBufValue[i], v1);
            unit->mInBufValue[i] = v1;
        }
    }
    // dsp computation
    unit->mDSP->compute(inNumSamples, unit->mInBufCopy, unit->mOutBuf);
}

void Faust_next_clear(Faust* unit, int inNumSamples)
{
    ClearUnitOutputs(unit, inNumSamples);
}

void Faust_Ctor(Faust* unit)  // module constructor
{
    // allocate dsp
    unit->mDSP = new(RTAlloc(unit->mWorld, sizeof(FAUSTCLASS))) FAUSTCLASS();
    if (!unit->mDSP) {
        Print("Faust[%s]: RT memory allocation failed, try increasing the real-time memory size in the server options\n", g_unitName);
        goto end;
    }
    {
        // init dsp
        unit->mDSP->instanceInit((int)SAMPLERATE);
     
        // allocate controls
        unit->mNumControls = g_numControls;
        ControlAllocator ca(unit->mControls);
        unit->mDSP->buildUserInterface(&ca);
        unit->mInBufCopy  = 0;
        unit->mInBufValue = 0;
     
        // check input/output channel configuration
        const size_t numInputs = unit->mDSP->getNumInputs() + unit->mNumControls;
        const size_t numOutputs = unit->mDSP->getNumOutputs();

        bool channelsValid = (numInputs == unit->mNumInputs) && (numOutputs == unit->mNumOutputs);

        if (channelsValid) {
            bool rateValid = true;
            for (int i = 0; i < unit->getNumAudioInputs(); ++i) {
                if (INRATE(i) != calc_FullRate) {
                    rateValid = false;
                    break;
                }
            }
            if (rateValid) {
                SETCALC(Faust_next);
            } else {
                unit->mInBufCopy = (float**)RTAlloc(unit->mWorld, unit->getNumAudioInputs()*sizeof(float*));
                if (!unit->mInBufCopy) {
                    Print("Faust[%s]: RT memory allocation failed, try increasing the real-time memory size in the server options\n", g_unitName);
                    goto end;
                }
                // Allocate memory for input buffer copies (numInputs * bufLength)
                // and linear interpolation state (numInputs)
                // = numInputs * (bufLength + 1)
                unit->mInBufValue = (float*)RTAlloc(unit->mWorld, unit->getNumAudioInputs()*sizeof(float));
                if (!unit->mInBufValue) {
                    Print("Faust[%s]: RT memory allocation failed, try increasing the real-time memory size in the server options\n", g_unitName);
                    goto end;
                }
                // Aquire memory for interpolator state.
                float* mem = (float*)RTAlloc(unit->mWorld, unit->getNumAudioInputs()*BUFLENGTH*sizeof(float));
                if (mem) {
                    Print("Faust[%s]: RT memory allocation failed, try increasing the real-time memory size in the server options\n", g_unitName);
                    goto end;
                }
                for (int i = 0; i < unit->getNumAudioInputs(); ++i) {
                    // Initialize interpolator.
                    unit->mInBufValue[i] = IN0(i);
                    // Aquire buffer memory.
                    unit->mInBufCopy[i] = mem;
                    mem += BUFLENGTH;
                }
                SETCALC(Faust_next_copy);
            }
    #if !defined(NDEBUG)
            Print("Faust[%s]:\n", g_unitName);
            Print("    Inputs:   %d\n"
                  "    Outputs:  %d\n"
                  "    Callback: %s\n",
                  numInputs, numOutputs,
                  unit->mCalcFunc == (UnitCalcFunc)Faust_next ? "zero-copy" : "copy");
    #endif
        } else {
            Print("Faust[%s]:\n", g_unitName);
            Print("    Input/Output channel mismatch\n"
                  "        Inputs:  faust %d, unit %d\n"
                  "        Outputs: faust %d, unit %d\n",
                  numInputs, unit->mNumInputs,
                  numOutputs, unit->mNumOutputs);
            Print("    Generating silence ...\n");
            SETCALC(Faust_next_clear);
        }
    }
    
end:
    // Fix for https://github.com/grame-cncm/faust/issues/13
    ClearUnitOutputs(unit, 1);
}

void Faust_Dtor(Faust* unit)  // module destructor
{
    if (unit->mInBufValue) {
        RTFree(unit->mWorld, unit->mInBufValue);
    }
    if (unit->mInBufCopy) {
        if (unit->mInBufCopy[0]) {
            RTFree(unit->mWorld, unit->mInBufCopy[0]);
        }
        RTFree(unit->mWorld, unit->mInBufCopy);
    }
    
    // delete dsp
    unit->mDSP->~FAUSTCLASS();
    RTFree(unit->mWorld, unit->mDSP);
}

#ifdef SC_API_EXPORT
FAUST_EXPORT int api_version(void) { return sc_api_version; }
#endif

FAUST_EXPORT void load(InterfaceTable* inTable)
{
    ft = inTable;

    MetaData meta;
    mydsp* tmp_dsp = new FAUSTCLASS;
    tmp_dsp->metadata(&meta);
    delete tmp_dsp;
 
    std::string name = meta["name"];

    if (name.empty()) {
        name = fileNameToUnitName(__FILE__);
    }
  
    name = normalizeClassName(name);

#if !defined(NDEBUG) & defined(SC_API_EXPORT)
    Print("Faust: supercollider.cpp: sc_api_version = %d\n", sc_api_version);
#endif

    if (name.empty()) {
        // Catch empty name
        Print("Faust [supercollider.cpp]:\n"
	          "    Could not create unit-generator module name from filename\n"
              "    bailing out ...\n");
        return;
    }

    if (strncmp(name.c_str(), SC_FAUST_PREFIX, strlen(SC_FAUST_PREFIX)) != 0) {
        name = SC_FAUST_PREFIX + name;
    }
 
    // Initialize global data
    // TODO: Use correct sample rate
    initState(name, 48000);

    // Register ugen
    (*ft->fDefineUnit)(
        (char*)name.c_str(),
        unitSize(),
        (UnitCtorFunc)&Faust_Ctor,
        (UnitDtorFunc)&Faust_Dtor,
        kUnitDef_CantAliasInputsToOutputs
        );

#if !defined(NDEBUG)
    Print("Faust: %s numControls=%d\n", name.c_str(), g_numControls);
#endif // NDEBUG
}

// EOF