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//----------------------------------------------------------
// name: "priority"
// version: "2.44.4"
//
// 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:
class SIG0 {
private:
int fSampleRate;
int iVec3State; // Single Delay
// Recursion delay iVeeec14 is of type kMonoDelay
// While its definition is of type kZeroDelay
int iVeeec14State; // Mono Delay
public:
int getNumInputs() { return 0; }
int getNumOutputs() { return 1; }
void init(int sample_rate) {
fSampleRate = sample_rate;
iVec3State = 0;
iVeeec14State = 0;
}
void fill(int count, float output[]) {
int iVec3[2];
int iVeeec14;
int fullcount = count;
for (int index = 0; index < fullcount; index += 32) {
int count = min(32, fullcount-index);
iVec3[1] = iVec3State;
iVeeec14 = iVeeec14State;
for (int i=0; i<count; i++) {
iVec3[0] = 1;
iVeeec14 = ((iVec3[1] + iVeeec14) % 65536);
output[i] = sinf((9.58738e-05f * float(iVeeec14)));
// post processing
iVec3[1] = iVec3[0];
}
iVec3State = iVec3[1];
iVeeec14State = iVeeec14;
output += 32;
}
}
};
int iVec0State; // Single Delay
float fConst0; // step: 17
int iConst1; // step: 19
// Recursion delay iVeeec3 is of type kSingleDelay
// While its definition is of type kZeroDelay
int iVeeec3State; // Single Delay
int iVec1State; // Single Delay
// Recursion delay iVeeec1 is of type kMonoDelay
// While its definition is of type kZeroDelay
int iVeeec1State; // Mono Delay
int iConst2; // step: 33
// Recursion delay iVeeec8 is of type kSingleDelay
// While its definition is of type kZeroDelay
int iVeeec8State; // Single Delay
int iVec2State; // Single Delay
// Recursion delay iVeeec7 is of type kMonoDelay
// While its definition is of type kZeroDelay
int iVeeec7State; // Mono Delay
float fConst3; // step: 49
// Recursion delay fVeeec0 is of type kMonoDelay
// While its definition is of type kZeroDelay
float fVeeec0State; // Mono Delay
static float ftbl0[65536];
int fSampleRate;
public:
virtual void metadata(Meta* m) {
m->declare("basics_lib_counter_author", "Stephane Letz");
m->declare("basics_lib_name", "Faust Basic Element Library");
m->declare("basics_lib_version", "0.8");
m->declare("compile_options", "-single -scal -e dsp/priority.dsp -o priority_exp.dsp");
m->declare("filename", "priority.dsp");
m->declare("library_path0", "/usr/local/share/faust/stdfaust.lib");
m->declare("library_path1", "/usr/local/share/faust/basics.lib");
m->declare("library_path2", "/usr/local/share/faust/maths.lib");
m->declare("library_path3", "/usr/local/share/faust/platform.lib");
m->declare("library_path4", "/usr/local/share/faust/oscillators.lib");
m->declare("maths_lib_author", "GRAME");
m->declare("maths_lib_copyright", "GRAME");
m->declare("maths_lib_license", "LGPL with exception");
m->declare("maths_lib_name", "Faust Math Library");
m->declare("maths_lib_version", "2.5");
m->declare("name", "priority");
m->declare("oscillators_lib_name", "Faust Oscillator Library");
m->declare("oscillators_lib_version", "0.3");
m->declare("platform_lib_name", "Generic Platform Library");
m->declare("platform_lib_version", "0.2");
m->declare("version", "2.44.4");
}
virtual int getNumInputs() { return 0; }
virtual int getNumOutputs() { return 1; }
static void classInit(int sample_rate) {
SIG0 sig0;
sig0.init(sample_rate);
sig0.fill(65536,ftbl0);
}
virtual void instanceConstants(int sample_rate) {
fSampleRate = sample_rate;
fConst0 = min(1.92e+05f, max(1.0f, float(fSampleRate))); // step: 17
iConst1 = int((0.5f * fConst0)); // step: 19
iConst2 = int(fConst0); // step: 33
fConst3 = (1.0f / fConst0); // step: 49
}
virtual void instanceResetUserInterface() {
}
virtual void instanceClear() {
iVec0State = 0;
iVeeec3State = 0;
iVec1State = 0;
iVeeec1State = 0;
iVeeec8State = 0;
iVec2State = 0;
iVeeec7State = 0;
fVeeec0State = 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("priority");
ui_interface->closeBox();
}
virtual void compute (int count, FAUSTFLOAT** input, FAUSTFLOAT** output) {
int iVec0[2];
int iVeeec3[2];
int iVec1[2];
int iVeeec1;
int iVeeec8[2];
int iVec2[2];
int iVeeec7;
float fVeeec0;
int fullcount = count;
for (int index = 0; index < fullcount; index += 32) {
int count = min(32, fullcount-index);
FAUSTFLOAT* output0 = &output[0][index]; // Zone 3
iVec0[1] = iVec0State;
iVeeec3[1] = iVeeec3State;
iVec1[1] = iVec1State;
iVeeec1 = iVeeec1State;
iVeeec8[1] = iVeeec8State;
iVec2[1] = iVec2State;
iVeeec7 = iVeeec7State;
fVeeec0 = fVeeec0State;
for (int i=0; i<count; i++) {
iVec0[0] = 1;
int iTemp0 = iVec0[1]; // step: 8
int iTemp1 = iVeeec3[1]; // step: 9
iVeeec3[0] = ((iTemp0 + iTemp1) % iConst1);
int iTemp2 = (iVeeec3[0] <= iTemp1); // step: 23
iVec1[0] = iTemp2;
iVeeec1 = (iVeeec1 + (iVec1[0] > iVec1[1]));
int iTemp3 = iVeeec8[1]; // step: 31
iVeeec8[0] = ((iTemp0 + iTemp3) % iConst2);
int iTemp4 = (iVeeec8[0] <= iTemp3); // step: 37
iVec2[0] = iTemp4;
iVeeec7 = (iVeeec7 + (iVec2[0] > iVec2[1]));
float fTemp5 = (fVeeec0 + (fConst3 * float((200 * (((iVeeec1 % 2) + (2 * (iVeeec7 % 2))) + 1))))); // step: 51
fVeeec0 = (fTemp5 - floorf(fTemp5));
output0[i] = (FAUSTFLOAT)(ftbl0[max(0, int(min(int(int((65536.0f * fVeeec0))), 65535)))]); // Zone Exec Code
// post processing
iVec2[1] = iVec2[0];
iVeeec8[1] = iVeeec8[0];
iVec1[1] = iVec1[0];
iVeeec3[1] = iVeeec3[0];
iVec0[1] = iVec0[0];
}
iVec0State = iVec0[1];
iVeeec3State = iVeeec3[1];
iVec1State = iVec1[1];
iVeeec1State = iVeeec1;
iVeeec8State = iVeeec8[1];
iVec2State = iVec2[1];
iVeeec7State = iVeeec7;
fVeeec0State = fVeeec0;
}
}
};
float mydsp::ftbl0[65536];
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