File: spat.cpp1

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//----------------------------------------------------------
// author: "Grame"
// copyright: "(c)GRAME 2006"
// license: "BSD"
// name: "spat"
// version: "1.0"
//
// Code generated with Faust 2.77.2 (https://faust.grame.fr)
//----------------------------------------------------------

/* link with  */
#include <math.h>
#ifndef FAUSTFLOAT
#define FAUSTFLOAT float
#endif 


#ifndef FAUSTCLASS 
#define FAUSTCLASS mydsp
#endif

class mydsp : public dsp {
  private:
	FAUSTFLOAT 	fslider0;
	FAUSTFLOAT 	fslider1;
	// Recursion delay fVeeec0 is of type kMonoDelay
	// While its definition is of type kZeroDelay
	float 	fVeeec0State; // Mono Delay
	// Recursion delay fVeeec2 is of type kMonoDelay
	// While its definition is of type kZeroDelay
	float 	fVeeec2State; // Mono Delay
	// Recursion delay fVeeec4 is of type kMonoDelay
	// While its definition is of type kZeroDelay
	float 	fVeeec4State; // Mono Delay
	// Recursion delay fVeeec6 is of type kMonoDelay
	// While its definition is of type kZeroDelay
	float 	fVeeec6State; // Mono Delay
	// Recursion delay fVeeec8 is of type kMonoDelay
	// While its definition is of type kZeroDelay
	float 	fVeeec8State; // Mono Delay
	// Recursion delay fVeeec10 is of type kMonoDelay
	// While its definition is of type kZeroDelay
	float 	fVeeec10State; // Mono Delay
	// Recursion delay fVeeec12 is of type kMonoDelay
	// While its definition is of type kZeroDelay
	float 	fVeeec12State; // Mono Delay
	// Recursion delay fVeeec14 is of type kMonoDelay
	// While its definition is of type kZeroDelay
	float 	fVeeec14State; // Mono Delay
	int fSampleRate;

  public:
	virtual void metadata(Meta* m) { 
		m->declare("author", "Grame");
		m->declare("copyright", "(c)GRAME 2006");
		m->declare("filename", "spat.dsp");
		m->declare("license", "BSD");
		m->declare("name", "spat");
		m->declare("version", "1.0");
	}

	virtual int getNumInputs() { return 1; }
	virtual int getNumOutputs() { return 8; }
	static void classInit(int sample_rate) {
	}
	virtual void instanceConstants(int sample_rate) {
		fSampleRate = sample_rate;
	}
	virtual void instanceResetUserInterface() {
		fslider0 = 0.5f;
		fslider1 = 0.0f;
	}
	virtual void instanceClear() {
		fVeeec0State = 0;
		fVeeec2State = 0;
		fVeeec4State = 0;
		fVeeec6State = 0;
		fVeeec8State = 0;
		fVeeec10State = 0;
		fVeeec12State = 0;
		fVeeec14State = 0;
	}
	virtual void init(int sample_rate) {
		classInit(sample_rate);
		instanceInit(sample_rate);
	}
	virtual void instanceInit(int sample_rate) {
		instanceConstants(sample_rate);
		instanceResetUserInterface();
		instanceClear();
	}
	virtual mydsp* clone() {
		return new mydsp();
	}
	virtual int getSampleRate() {
		return fSampleRate;
	}
	virtual void buildUserInterface(UI* ui_interface) {
		ui_interface->openVerticalBox("Spatializer 1x8");
		ui_interface->addHorizontalSlider("angle", &fslider1, 0.0f, 0.0f, 1.0f, 0.01f);
		ui_interface->addHorizontalSlider("distance", &fslider0, 0.5f, 0.0f, 1.0f, 0.01f);
		ui_interface->closeBox();
	}
	virtual void compute (int count, FAUSTFLOAT** input, FAUSTFLOAT** output) {
		float 	fSlow0 = float(fslider0); // step: 10
		float 	fSlow1 = float(fslider1); // step: 12
		float 	fSlow2 = (fSlow0 + 1.0f); // step: 23
		float 	fSlow3 = (5e-05f * (sqrtf(max(0.0f, (1.0f - (8.0f * (fSlow0 * fabsf((fmodf((fSlow1 + 1.5f),1.0f) + -0.5f))))))) * fSlow2)); // step: 26
		float 	fVeeec0;
		float 	fSlow4 = (5e-05f * (fSlow2 * sqrtf(max(0.0f, (1.0f - (8.0f * (fSlow0 * fabsf((fmodf((fSlow1 + 1.375f),1.0f) + -0.5f))))))))); // step: 44
		float 	fVeeec2;
		float 	fSlow5 = (5e-05f * (fSlow2 * sqrtf(max(0.0f, (1.0f - (8.0f * (fSlow0 * fabsf((fmodf((fSlow1 + 1.25f),1.0f) + -0.5f))))))))); // step: 62
		float 	fVeeec4;
		float 	fSlow6 = (5e-05f * (fSlow2 * sqrtf(max(0.0f, (1.0f - (8.0f * (fSlow0 * fabsf((fmodf((fSlow1 + 1.125f),1.0f) + -0.5f))))))))); // step: 80
		float 	fVeeec6;
		float 	fSlow7 = (5e-05f * (fSlow2 * sqrtf(max(0.0f, (1.0f - (8.0f * (fSlow0 * fabsf((fmodf((fSlow1 + 1.0f),1.0f) + -0.5f))))))))); // step: 97
		float 	fVeeec8;
		float 	fSlow8 = (5e-05f * (fSlow2 * sqrtf(max(0.0f, (1.0f - (8.0f * (fSlow0 * fabsf((fmodf((fSlow1 + 0.875f),1.0f) + -0.5f))))))))); // step: 115
		float 	fVeeec10;
		float 	fSlow9 = (5e-05f * (fSlow2 * sqrtf(max(0.0f, (1.0f - (8.0f * (fSlow0 * fabsf((fmodf((fSlow1 + 0.75f),1.0f) + -0.5f))))))))); // step: 133
		float 	fVeeec12;
		float 	fSlow10 = (5e-05f * (fSlow2 * sqrtf(max(0.0f, (1.0f - (8.0f * (fSlow0 * fabsf((fmodf((fSlow1 + 0.625f),1.0f) + -0.5f))))))))); // step: 151
		float 	fVeeec14;
		int fullcount = count;
		for (int index = 0; index < fullcount; index += 32) {
			int count = min(32, fullcount-index);
			FAUSTFLOAT* input0 = &input[0][index]; // Zone 3
			FAUSTFLOAT* output0 = &output[0][index]; // Zone 3
			FAUSTFLOAT* output1 = &output[1][index]; // Zone 3
			FAUSTFLOAT* output2 = &output[2][index]; // Zone 3
			FAUSTFLOAT* output3 = &output[3][index]; // Zone 3
			FAUSTFLOAT* output4 = &output[4][index]; // Zone 3
			FAUSTFLOAT* output5 = &output[5][index]; // Zone 3
			FAUSTFLOAT* output6 = &output[6][index]; // Zone 3
			FAUSTFLOAT* output7 = &output[7][index]; // Zone 3
			fVeeec0 = fVeeec0State;
			fVeeec2 = fVeeec2State;
			fVeeec4 = fVeeec4State;
			fVeeec6 = fVeeec6State;
			fVeeec8 = fVeeec8State;
			fVeeec10 = fVeeec10State;
			fVeeec12 = fVeeec12State;
			fVeeec14 = fVeeec14State;
			for (int i=0; i<count; i++) {
				float 	fTemp0 = (float)input0[i]; // step: 1
				fVeeec0 = (fSlow3 + (0.9999f * fVeeec0));
				fVeeec2 = (fSlow4 + (0.9999f * fVeeec2));
				fVeeec4 = (fSlow5 + (0.9999f * fVeeec4));
				fVeeec6 = (fSlow6 + (0.9999f * fVeeec6));
				fVeeec8 = (fSlow7 + (0.9999f * fVeeec8));
				fVeeec10 = (fSlow8 + (0.9999f * fVeeec10));
				fVeeec12 = (fSlow9 + (0.9999f * fVeeec12));
				fVeeec14 = (fSlow10 + (0.9999f * fVeeec14));
				output0[i] = (FAUSTFLOAT)((fTemp0 * fVeeec0));  // Zone Exec Code
				output1[i] = (FAUSTFLOAT)((fTemp0 * fVeeec2));  // Zone Exec Code
				output2[i] = (FAUSTFLOAT)((fTemp0 * fVeeec4));  // Zone Exec Code
				output3[i] = (FAUSTFLOAT)((fTemp0 * fVeeec6));  // Zone Exec Code
				output4[i] = (FAUSTFLOAT)((fTemp0 * fVeeec8));  // Zone Exec Code
				output5[i] = (FAUSTFLOAT)((fTemp0 * fVeeec10));  // Zone Exec Code
				output6[i] = (FAUSTFLOAT)((fTemp0 * fVeeec12));  // Zone Exec Code
				output7[i] = (FAUSTFLOAT)((fTemp0 * fVeeec14));  // Zone Exec Code
			}
			fVeeec0State = fVeeec0;
			fVeeec2State = fVeeec2;
			fVeeec4State = fVeeec4;
			fVeeec6State = fVeeec6;
			fVeeec8State = fVeeec8;
			fVeeec10State = fVeeec10;
			fVeeec12State = fVeeec12;
			fVeeec14State = fVeeec14;
		}
	}
};