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/* ========================================
* NonlinearSpace - NonlinearSpace.h
* Copyright (c) 2016 airwindows, All rights reserved
* ======================================== */
#ifndef __NonlinearSpace_H
#include "NonlinearSpace.h"
#endif
AudioEffect* createEffectInstance(audioMasterCallback audioMaster) {return new NonlinearSpace(audioMaster);}
NonlinearSpace::NonlinearSpace(audioMasterCallback audioMaster) :
AudioEffectX(audioMaster, kNumPrograms, kNumParameters)
{
A = 0.3; //this is the sample rate so it will become a 'popup' with fixed values
B = 0.5;
C = 0.5;
D = 0.5;
E = 0.5; //this is nonlin, so it produces -1 to 1: 0.5 will become 0
F = 1.0;
int count;
for(count = 0; count < 2347; count++) {dMid[count] = 0.0;}
for(count = 0; count < 1333; count++) {dSide[count] = 0.0;}
for(count = 0; count < 5923; count++) {dLeft[count] = 0.0;}
for(count = 0; count < 5925; count++) {dRight[count] = 0.0;}
for(count = 0; count < 7574; count++) {dpreR[count] = 0.0;}
for(count = 0; count < 7574; count++) {dpreL[count] = 0.0;}
for(count = 0; count < 7574; count++) {dA[count] = 0.0;}
for(count = 0; count < 7308; count++) {dB[count] = 0.0;}
for(count = 0; count < 7178; count++) {dC[count] = 0.0;}
for(count = 0; count < 6908; count++) {dD[count] = 0.0;}
for(count = 0; count < 6780; count++) {dE[count] = 0.0;}
for(count = 0; count < 6522; count++) {dF[count] = 0.0;}
for(count = 0; count < 5982; count++) {dG[count] = 0.0;}
for(count = 0; count < 5564; count++) {dH[count] = 0.0;}
for(count = 0; count < 5298; count++) {dI[count] = 0.0;}
for(count = 0; count < 4904; count++) {dJ[count] = 0.0;}
for(count = 0; count < 4760; count++) {dK[count] = 0.0;}
for(count = 0; count < 4490; count++) {dL[count] = 0.0;}
for(count = 0; count < 4392; count++) {dM[count] = 0.0;}
for(count = 0; count < 4230; count++) {dN[count] = 0.0;}
for(count = 0; count < 4154; count++) {dO[count] = 0.0;}
for(count = 0; count < 3990; count++) {dP[count] = 0.0;}
for(count = 0; count < 3660; count++) {dQ[count] = 0.0;}
for(count = 0; count < 3408; count++) {dR[count] = 0.0;}
for(count = 0; count < 3252; count++) {dS[count] = 0.0;}
for(count = 0; count < 3000; count++) {dT[count] = 0.0;}
for(count = 0; count < 2918; count++) {dU[count] = 0.0;}
for(count = 0; count < 2750; count++) {dV[count] = 0.0;}
for(count = 0; count < 2504; count++) {dW[count] = 0.0;}
for(count = 0; count < 2424; count++) {dX[count] = 0.0;}
for(count = 0; count < 2147; count++) {dY[count] = 0.0;}
for(count = 0; count < 2089; count++) {dZ[count] = 0.0;}
oneMid = 1; delayMid = 2346; maxdelayMid = 2346;
oneSide = 1; delaySide = 1332; maxdelaySide = 1332;
oneLeft = 1; delayLeft = 5922; maxdelayLeft = 5922;
oneRight = 1; delayRight = 5924; maxdelayRight = 5924;
onepre = 1; delaypre = 7573; maxdelaypre = 7573;
oneA = 1; twoA = 2; treA = 3; delayA = 7573; maxdelayA = 7573;
oneB = 1; twoB = 2; treB = 3; delayB = 7307; maxdelayB = 7307;
oneC = 1; twoC = 2; treC = 3; delayC = 7177; maxdelayC = 7177;
oneD = 1; twoD = 2; treD = 3; delayD = 6907; maxdelayD = 6907;
oneE = 1; twoE = 2; treE = 3; delayE = 6779; maxdelayE = 6779;
oneF = 1; twoF = 2; treF = 3; delayF = 6521; maxdelayF = 6521;
oneG = 1; twoG = 2; treG = 3; delayG = 5981; maxdelayG = 5981;
oneH = 1; twoH = 2; treH = 3; delayH = 5563; maxdelayH = 5563;
oneI = 1; twoI = 2; treI = 3; delayI = 5297; maxdelayI = 5297;
oneJ = 1; twoJ = 2; treJ = 3; delayJ = 4903; maxdelayJ = 4903;
oneK = 1; twoK = 2; treK = 3; delayK = 4759; maxdelayK = 4759;
oneL = 1; twoL = 2; treL = 3; delayL = 4489; maxdelayL = 4489;
oneM = 1; twoM = 2; treM = 3; delayM = 4391; maxdelayM = 4391;
oneN = 1; twoN = 2; treN = 3; delayN = 4229; maxdelayN = 4229;
oneO = 1; twoO = 2; treO = 3; delayO = 4153; maxdelayO = 4153;
oneP = 1; twoP = 2; treP = 3; delayP = 3989; maxdelayP = 3989;
oneQ = 1; twoQ = 2; treQ = 3; delayQ = 3659; maxdelayQ = 3659;
oneR = 1; twoR = 2; treR = 3; delayR = 3407; maxdelayR = 3407;
oneS = 1; twoS = 2; treS = 3; delayS = 3251; maxdelayS = 3251;
oneT = 1; twoT = 2; treT = 3; delayT = 2999; maxdelayT = 2999;
oneU = 1; twoU = 2; treU = 3; delayU = 2917; maxdelayU = 2917;
oneV = 1; twoV = 2; treV = 3; delayV = 2749; maxdelayV = 2749;
oneW = 1; twoW = 2; treW = 3; delayW = 2503; maxdelayW = 2503;
oneX = 1; twoX = 2; treX = 3; delayX = 2423; maxdelayX = 2423;
oneY = 1; twoY = 2; treY = 3; delayY = 2146; maxdelayY = 2146;
oneZ = 1; twoZ = 2; treZ = 3; delayZ = 2088; maxdelayZ = 2088;
avgInputL = 0.0;
avgInputR = 0.0;
avgOutputL = 0.0;
avgOutputR = 0.0;
avg2InputL = 0.0;
avg2InputR = 0.0;
avg2OutputL = 0.0;
avg2OutputR = 0.0;
a2vgInputL = 0.0;
a2vgInputR = 0.0;
a2vgOutputL = 0.0;
a2vgOutputR = 0.0;
a2vg2InputL = 0.0;
a2vg2InputR = 0.0;
a2vg2OutputL = 0.0;
a2vg2OutputR = 0.0;
lowpassSampleAA = 0.0;
lowpassSampleAB = 0.0;
lowpassSampleBA = 0.0;
lowpassSampleBB = 0.0;
lowpassSampleCA = 0.0;
lowpassSampleCB = 0.0;
lowpassSampleDA = 0.0;
lowpassSampleDB = 0.0;
lowpassSampleE = 0.0;
lowpassSampleF = 0.0;
lowpassSampleG = 0.0;
rowpassSampleAA = 0.0;
rowpassSampleAB = 0.0;
rowpassSampleBA = 0.0;
rowpassSampleBB = 0.0;
rowpassSampleCA = 0.0;
rowpassSampleCB = 0.0;
rowpassSampleDA = 0.0;
rowpassSampleDB = 0.0;
rowpassSampleE = 0.0;
rowpassSampleF = 0.0;
rowpassSampleG = 0.0;
interpolA = 0.0;
interpolB = 0.0;
interpolC = 0.0;
interpolD = 0.0;
interpolE = 0.0;
interpolF = 0.0;
interpolG = 0.0;
interpolH = 0.0;
interpolI = 0.0;
interpolJ = 0.0;
interpolK = 0.0;
interpolL = 0.0;
interpolM = 0.0;
interpolN = 0.0;
interpolO = 0.0;
interpolP = 0.0;
interpolQ = 0.0;
interpolR = 0.0;
interpolS = 0.0;
interpolT = 0.0;
interpolU = 0.0;
interpolV = 0.0;
interpolW = 0.0;
interpolX = 0.0;
interpolY = 0.0;
interpolZ = 0.0;
pitchshiftA = 1.0 / maxdelayA;
pitchshiftB = 1.0 / maxdelayB;
pitchshiftC = 1.0 / maxdelayC;
pitchshiftD = 1.0 / maxdelayD;
pitchshiftE = 1.0 / maxdelayE;
pitchshiftF = 1.0 / maxdelayF;
pitchshiftG = 1.0 / maxdelayG;
pitchshiftH = 1.0 / maxdelayH;
pitchshiftI = 1.0 / maxdelayI;
pitchshiftJ = 1.0 / maxdelayJ;
pitchshiftK = 1.0 / maxdelayK;
pitchshiftL = 1.0 / maxdelayL;
pitchshiftM = 1.0 / maxdelayM;
pitchshiftN = 1.0 / maxdelayN;
pitchshiftO = 1.0 / maxdelayO;
pitchshiftP = 1.0 / maxdelayP;
pitchshiftQ = 1.0 / maxdelayQ;
pitchshiftR = 1.0 / maxdelayR;
pitchshiftS = 1.0 / maxdelayS;
pitchshiftT = 1.0 / maxdelayT;
pitchshiftU = 1.0 / maxdelayU;
pitchshiftV = 1.0 / maxdelayV;
pitchshiftW = 1.0 / maxdelayW;
pitchshiftX = 1.0 / maxdelayX;
pitchshiftY = 1.0 / maxdelayY;
pitchshiftZ = 1.0 / maxdelayZ;
nonlin = 0.0;
verboutL = 0.0;
verboutR = 0.0;
iirCCSampleL = 0.0;
iirCCSampleR = 0.0;
iirSampleL = 0.0;
iirSampleR = 0.0;
savedRoomsize = -1.0; //force update to begin
countdown = -1;
flip = true;
fpNShapeL = 0.0;
fpNShapeR = 0.0;
//this is reset: values being initialized only once. Startup values, whatever they are.
_canDo.insert("plugAsChannelInsert"); // plug-in can be used as a channel insert effect.
_canDo.insert("plugAsSend"); // plug-in can be used as a send effect.
_canDo.insert("x2in2out");
setNumInputs(kNumInputs);
setNumOutputs(kNumOutputs);
setUniqueID(kUniqueId);
canProcessReplacing(); // supports output replacing
canDoubleReplacing(); // supports double precision processing
programsAreChunks(true);
vst_strncpy (_programName, "Default", kVstMaxProgNameLen); // default program name
}
NonlinearSpace::~NonlinearSpace() {}
VstInt32 NonlinearSpace::getVendorVersion () {return 1000;}
void NonlinearSpace::setProgramName(char *name) {vst_strncpy (_programName, name, kVstMaxProgNameLen);}
void NonlinearSpace::getProgramName(char *name) {vst_strncpy (name, _programName, kVstMaxProgNameLen);}
//airwindows likes to ignore this stuff. Make your own programs, and make a different plugin rather than
//trying to do versioning and preventing people from using older versions. Maybe they like the old one!
static float pinParameter(float data)
{
if (data < 0.0f) return 0.0f;
if (data > 1.0f) return 1.0f;
return data;
}
VstInt32 NonlinearSpace::getChunk (void** data, bool isPreset)
{
float *chunkData = (float *)calloc(kNumParameters, sizeof(float));
chunkData[0] = A;
chunkData[1] = B;
chunkData[2] = C;
chunkData[3] = D;
chunkData[4] = E;
chunkData[5] = F;
/* Note: The way this is set up, it will break if you manage to save settings on an Intel
machine and load them on a PPC Mac. However, it's fine if you stick to the machine you
started with. */
*data = chunkData;
return kNumParameters * sizeof(float);
}
VstInt32 NonlinearSpace::setChunk (void* data, VstInt32 byteSize, bool isPreset)
{
float *chunkData = (float *)data;
A = pinParameter(chunkData[0]);
B = pinParameter(chunkData[1]);
C = pinParameter(chunkData[2]);
D = pinParameter(chunkData[3]);
E = pinParameter(chunkData[4]);
F = pinParameter(chunkData[5]);
/* We're ignoring byteSize as we found it to be a filthy liar */
/* calculate any other fields you need here - you could copy in
code from setParameter() here. */
return 0;
}
void NonlinearSpace::setParameter(VstInt32 index, float value) {
switch (index) {
case kParamA: A = value; break;
case kParamB: B = value; break;
case kParamC: C = value; break;
case kParamD: D = value; break;
case kParamE: E = value; break;
case kParamF: F = value; break;
default: throw; // unknown parameter, shouldn't happen!
}
}
float NonlinearSpace::getParameter(VstInt32 index) {
switch (index) {
case kParamA: return A; break;
case kParamB: return B; break;
case kParamC: return C; break;
case kParamD: return D; break;
case kParamE: return E; break;
case kParamF: return F; break;
default: break; // unknown parameter, shouldn't happen!
} return 0.0; //we only need to update the relevant name, this is simple to manage
}
void NonlinearSpace::getParameterName(VstInt32 index, char *text) {
switch (index) {
case kParamA: vst_strncpy (text, "SmpRate", kVstMaxParamStrLen); break;
case kParamB: vst_strncpy (text, "Livenes", kVstMaxParamStrLen); break;
case kParamC: vst_strncpy (text, "Treble", kVstMaxParamStrLen); break;
case kParamD: vst_strncpy (text, "Bass", kVstMaxParamStrLen); break;
case kParamE: vst_strncpy (text, "Nonlin", kVstMaxParamStrLen); break;
case kParamF: vst_strncpy (text, "Dry/Wet", kVstMaxParamStrLen); break;
default: break; // unknown parameter, shouldn't happen!
} //this is our labels for displaying in the VST host
}
void NonlinearSpace::getParameterDisplay(VstInt32 index, char *text) {
switch (index) {
case kParamA: switch((VstInt32)( A * 6.999 )) //0 to almost edge of # of params
{ case 0: vst_strncpy (text, "16K", kVstMaxParamStrLen); break;
case 1: vst_strncpy (text, "32K", kVstMaxParamStrLen); break;
case 2: vst_strncpy (text, "44.1K", kVstMaxParamStrLen); break;
case 3: vst_strncpy (text, "48K", kVstMaxParamStrLen); break;
case 4: vst_strncpy (text, "64K", kVstMaxParamStrLen); break;
case 5: vst_strncpy (text, "88.2K", kVstMaxParamStrLen); break;
case 6: vst_strncpy (text, "96K", kVstMaxParamStrLen); break;
default: break; // unknown parameter, shouldn't happen!
} break; //E as example 'popup' parameter with four values */
case kParamB: float2string (B, text, kVstMaxParamStrLen); break;
case kParamC: float2string (C, text, kVstMaxParamStrLen); break;
case kParamD: float2string (D, text, kVstMaxParamStrLen); break;
case kParamE: float2string ((E*2.0)-1.0, text, kVstMaxParamStrLen); break;
case kParamF: float2string (F, text, kVstMaxParamStrLen); break;
default: break; // unknown parameter, shouldn't happen!
} //this displays the values and handles 'popups' where it's discrete choices
}
void NonlinearSpace::getParameterLabel(VstInt32 index, char *text) {
switch (index) {
case kParamA: vst_strncpy (text, "", kVstMaxParamStrLen); break;
case kParamB: vst_strncpy (text, "", kVstMaxParamStrLen); break;
case kParamC: vst_strncpy (text, "", kVstMaxParamStrLen); break;
case kParamD: vst_strncpy (text, "", kVstMaxParamStrLen); break;
case kParamE: vst_strncpy (text, "", kVstMaxParamStrLen); break;
case kParamF: vst_strncpy (text, "", kVstMaxParamStrLen); break;
default: break; // unknown parameter, shouldn't happen!
}
}
VstInt32 NonlinearSpace::canDo(char *text)
{ return (_canDo.find(text) == _canDo.end()) ? -1: 1; } // 1 = yes, -1 = no, 0 = don't know
bool NonlinearSpace::getEffectName(char* name) {
vst_strncpy(name, "NonlinearSpace", kVstMaxProductStrLen); return true;
}
VstPlugCategory NonlinearSpace::getPlugCategory() {return kPlugCategEffect;}
bool NonlinearSpace::getProductString(char* text) {
vst_strncpy (text, "airwindows NonlinearSpace", kVstMaxProductStrLen); return true;
}
bool NonlinearSpace::getVendorString(char* text) {
vst_strncpy (text, "airwindows", kVstMaxVendorStrLen); return true;
}
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