void Compute(const cNineFractals &fractals, const sFractalIn &in, sFractalOut *out) { fractalFormulaFcn fractalFormulaFunction; // repeat, move and rotate CVector3 pointTransformed = (in.point - in.common.fractalPosition).mod(in.common.repeat); pointTransformed = in.common.mRotFractalRotation.RotateVector(pointTransformed); CVector4 z = CVector4(pointTransformed, 0.0); double colorMin = 1000.0; if (in.forcedFormulaIndex >= 0) { z.w = fractals.GetInitialWAxis(in.forcedFormulaIndex); } else { z.w = fractals.GetInitialWAxis(0); } double r = z.Length(); double initR = r; double initialWAxisColor = z.w; double orbitTrapTotal = 0.0; out->orbitTrapR = 0.0; enumFractalFormula formula = fractal::none; out->maxiter = true; int fractalIndex = 0; if (in.forcedFormulaIndex >= 0) fractalIndex = in.forcedFormulaIndex; const sFractal *defaultFractal = fractals.GetFractal(fractalIndex); sExtendedAux extendedAux; extendedAux.c = z; extendedAux.const_c = z; extendedAux.old_z = CVector4(0.0, 0.0, 0.0, 0.0); extendedAux.sum_z = CVector4(0.0, 0.0, 0.0, 0.0); extendedAux.pos_neg = 1.0; extendedAux.cw = 0; extendedAux.r = r; extendedAux.DE = 1.0; extendedAux.pseudoKleinianDE = 1.0; extendedAux.actualScale = fractals.GetFractal(fractalIndex)->mandelbox.scale; extendedAux.actualScaleA = 0.0; extendedAux.color = 1.0; extendedAux.colorHybrid = 0.0; extendedAux.temp100 = 100.0; extendedAux.addDist = 0.0; // main iteration loop int i; int sequence = 0; CVector4 lastGoodZ; CVector4 lastZ; CVector4 lastLastZ; // main iteration loop for (i = 0; i < in.maxN; i++) { lastGoodZ = lastZ; lastLastZ = lastZ; ; lastZ = z; // hybrid fractal sequence if (in.forcedFormulaIndex >= 0) { sequence = in.forcedFormulaIndex; } else { sequence = fractals.GetSequence(i); } // foldings if (in.common.foldings.boxEnable) { BoxFolding(z, &in.common.foldings, extendedAux); r = z.Length(); } if (in.common.foldings.sphericalEnable) { extendedAux.r = r; SphericalFolding(z, &in.common.foldings, extendedAux); r = z.Length(); } const sFractal *fractal = fractals.GetFractal(sequence); formula = fractal->formula; // temporary vector for weight function CVector4 tempZ = z; extendedAux.r = r; extendedAux.i = i; fractalFormulaFunction = fractals.GetFractalFormulaFunction(sequence); if (!fractals.IsHybrid() || fractals.GetWeight(sequence) > 0.0) { // -------------- call for fractal formulas by function pointers --------------- if (fractalFormulaFunction) { fractalFormulaFunction(z, fractal, extendedAux); } else { double high = fractals.GetBailout(sequence) * 10.0; z = CVector4(high, high, high, high); out->distance = 10.0; out->iters = 1; out->z = z.GetXYZ(); return; } // ----------------------------------------------------------------------------- } // addition of constant if (fractals.IsAddCConstant(sequence)) { switch (formula) { case aboxMod1: case amazingSurf: // case amazingSurfMod1: { if (fractals.IsJuliaEnabled(sequence)) { CVector3 juliaC = fractals.GetJuliaConstant(sequence) * fractals.GetConstantMultiplier(sequence); z += CVector4(juliaC.y, juliaC.x, juliaC.z, 0.0); } else { z += CVector4(extendedAux.const_c.y, extendedAux.const_c.x, extendedAux.const_c.z, 0.0) * fractals.GetConstantMultiplier(sequence); } break; } default: { if (fractals.IsJuliaEnabled(sequence)) { z += CVector4( fractals.GetJuliaConstant(sequence) * fractals.GetConstantMultiplier(sequence), 0.0); } else { z += extendedAux.const_c * fractals.GetConstantMultiplier(sequence); } break; } } } if (fractals.IsHybrid()) { z = SmoothCVector(tempZ, z, fractals.GetWeight(sequence)); } // r calculation // r = sqrt(z.x * z.x + z.y * z.y + z.z * z.z + w * w); switch (fractal->formula) { case scatorPower2: // add v2.15 case scatorPower2Real: // add v2.15 case scatorPower2Imaginary: // corrected v2.14 case testingLog: { CVector4 z2 = z * z; r = sqrt(z2.x + z2.y + z2.z + (z2.y * z2.z) / z2.x); // initial condition is normal r, becomes aux.r // r = sqrt(z2.x - z2.y - z2.z + (z2.y * z2.z) / (z2.x)); break; } // scator magnitudes // magnitude in imaginary scator algebra // case pseudoKleinian: // case pseudoKleinianMod1: // case pseudoKleinianMod2: case pseudoKleinianStdDE: { r = sqrt(z.x * z.x + z.y * z.y); break; } default: { r = z.Length(); // r = sqrt(z.x * z.x + z.y * z.y + z.z * z.z); break; } } if (z.IsNotANumber()) { z = lastZ; r = z.Length(); out->maxiter = true; break; } // escape conditions if (fractals.IsCheckForBailout(sequence)) { if (Mode == calcModeNormal || Mode == calcModeDeltaDE1) { if (r > fractals.GetBailout(sequence)) { out->maxiter = false; break; } if (fractals.UseAdditionalBailoutCond(sequence)) { out->maxiter = false; // maxiter flag has to be always disabled for pseudo klienian if ((z - lastZ).Length() / r < 0.1 / fractals.GetBailout(sequence)) { break; } if ((z - lastLastZ).Length() / r < 0.1 / fractals.GetBailout(sequence)) { break; } } } else if (Mode == calcModeDeltaDE2) { if (i == in.maxN) break; } else if (Mode == calcModeColouring) { CVector4 colorZ = z; if (!in.material->fractalColoring.color4dEnabledFalse) colorZ.w = 0.0; double len = 0.0; switch (in.material->fractalColoring.coloringAlgorithm) { case fractalColoring_Standard: { len = colorZ.Length(); break; } case fractalColoring_ZDotPoint: { len = fabs(colorZ.Dot(CVector4(pointTransformed, initialWAxisColor))); break; } case fractalColoring_Sphere: { len = fabs((colorZ - CVector4(pointTransformed, initialWAxisColor)).Length() - in.material->fractalColoring.sphereRadius); break; } case fractalColoring_Cross: { len = dMin(fabs(colorZ.x), fabs(colorZ.y), fabs(colorZ.z)); if (in.material->fractalColoring.color4dEnabledFalse) len = min(len, fabs(colorZ.w)); break; } case fractalColoring_Line: { len = fabs(colorZ.Dot(in.material->fractalColoring.lineDirection)); break; } case fractalColoring_None: { len = r; break; } } if (!in.material->fractalColoring.colorPreV215False) { // V2.15 code if (fractal->formula != mandelbox) { if (len < colorMin) colorMin = len; if (r > fractals.GetBailout(sequence) || (z - lastZ).Length() / r < 1e-15) break; } else // for Mandelbox. Note in Normal Mode (abox_color) colorMin = 0, else has a value { if (in.material->fractalColoring.coloringAlgorithm == fractalColoring_Standard) { if (r > 1e15 || (z - lastZ).Length() / r < 1e-15) break; } else { if (len < colorMin) colorMin = len; if (r > fractals.GetBailout(sequence) || (z - lastZ).Length() / r < 1e-15) break; } } } else // pre-v2.15 mode { if (fractal->formula != mandelbox || in.material->fractalColoring.coloringAlgorithm != fractalColoring_Standard) { if (len < colorMin) colorMin = len; if (r > 1e15 || (z - lastZ).Length() / r < 1e-15) break; // old, is updated v2.15 } else // for mandbox and fractalColoring_Standard { if (r > 1e15 || (z - lastZ).Length() / r < 1e-15) break; } } } else if (Mode == calcModeOrbitTrap) { CVector4 delta = z - CVector4(in.common.fakeLightsOrbitTrap, 0.0); double distance = delta.Length(); if (i >= in.common.fakeLightsMinIter && i <= in.common.fakeLightsMaxIter) orbitTrapTotal += (1.0 / (distance * distance)); if (distance > fractals.GetBailout(sequence)) { out->orbitTrapR = orbitTrapTotal; break; } } else if (Mode == calcModeCubeOrbitTrap) { if (i >= in.material->textureFractalizeStartIteration) { double size = in.material->textureFractalizeCubeSize; CVector3 zz = z.GetXYZ() - pointTransformed; if (zz.x > -size && zz.x < size && zz.y > -size && zz.y < size && zz.z > -size && zz.z < size) { out->colorIndex = (fabs(z.x - size) + fabs(z.y - size) + fabs(z.z - size)) * 100.0; out->iters = i + 1; out->z = z.GetXYZ(); return; } } if (r > in.material->textureFractalizeCubeSize * 100.0) { out->colorIndex = 0.0; out->iters = i + 1; out->z = z.GetXYZ() / z.Length(); return; } } } if (z.IsNotANumber()) // detection of dead computation { z = lastGoodZ; break; } } // final calculations if (Mode == calcModeNormal) // analytic { if (extendedAux.DE > 0.0) { if (fractals.IsHybrid()) { if (fractals.GetDEFunctionType(0) == fractal::linearDEFunction) { out->distance = (r - in.common.linearDEOffset) / extendedAux.DE; } else if (fractals.GetDEFunctionType(0) == fractal::logarithmicDEFunction) { out->distance = 0.5 * r * log(r) / extendedAux.DE; } else if (fractals.GetDEFunctionType(0) == fractal::pseudoKleinianDEFunction) { double rxy = sqrt(z.x * z.x + z.y * z.y); out->distance = max(rxy - extendedAux.pseudoKleinianDE, fabs(rxy * z.z) / r) / extendedAux.DE; } else if (fractals.GetDEFunctionType(0) == fractal::josKleinianDEFunction) { if (fractals.GetFractal(0)->transformCommon.spheresEnabled) z.y = min(z.y, fractals.GetFractal(0)->transformCommon.foldingValue - z.y); out->distance = min(z.y, fractals.GetFractal(0)->analyticDE.tweak005) / max(extendedAux.DE, fractals.GetFractal(0)->analyticDE.offset1); } /*else if (fractals.GetDEFunctionType(0) == fractal:: testingDEFunction) { double logDE = ((0.5 * r * log(r)) - in.common.linearDEOffset) / extendedAux.DE; double linDE = (r - in.common.linearDEOffset) / extendedAux.DE; out->distance = linDE + (logDE - linDE) * extendedAux.temp100; // (logDE, linDE, extendedAux.temp100 / 100)); // temp use of auxtemp100. }*/ } else { switch (fractals.GetDEAnalyticFunction(sequence)) { case analyticFunctionLogarithmic: { out->distance = 0.5 * r * log(r) / extendedAux.DE; break; } case analyticFunctionLinear: { out->distance = r / extendedAux.DE; break; } case analyticFunctionIFS: { out->distance = (r - 2.0) / extendedAux.DE; break; } case analyticFunctionPseudoKleinian: { double rxy = sqrt(z.x * z.x + z.y * z.y); out->distance = max(rxy - extendedAux.pseudoKleinianDE, fabs(rxy * z.z) / r) / extendedAux.DE; break; } case analyticFunctionJosKleinian: { if (fractals.GetFractal(sequence)->transformCommon.spheresEnabled) z.y = min(z.y, fractals.GetFractal(sequence)->transformCommon.foldingValue - z.y); out->distance = min(z.y, fractals.GetFractal(sequence)->analyticDE.tweak005) / max(extendedAux.DE, fractals.GetFractal(sequence)->analyticDE.offset1); break; } case analyticFunctionNone: out->distance = -1.0; break; case analyticFunctionUndefined: out->distance = r; break; } } // TEMPORARY CODE. To be removed afer testing if (fractals.GetFractal(sequence)->transformCommon.functionEnabledTempFalse) { out->distance = out->distance * initR * initR / (fractals.GetFractal(sequence)->transformCommon.maxR2d1 + initR * out->distance); } } else out->distance = r; } // color calculation else if (Mode == calcModeColouring) { enumColoringFunction coloringFunction = fractals.GetColoringFunction(sequence); out->colorIndex = CalculateColorIndex(fractals.IsHybrid(), r, z, colorMin, extendedAux, in.material->fractalColoring, coloringFunction, defaultFractal); } else { out->distance = 0.0; // needed for JosKleinian fractal to calculate spheres in deltaDE mode if (fractals.GetDEFunctionType(0) == fractal::josKleinianDEFunction) { if (fractals.GetFractal(sequence)->transformCommon.spheresEnabled) z.y = min(z.y, fractals.GetFractal(sequence)->transformCommon.foldingValue - z.y); } } out->iters = i + 1; out->z = z.GetXYZ(); }
void Compute(const cNineFractals &fractals, const sFractalIn &in, sFractalOut *out) { //QTextStream outStream(stdout); //clock_t tim; //tim = rdtsc(); //repeat, move and rotate CVector3 point2 = in.point.mod(in.common.repeat) - in.common.fractalPosition; point2 = in.common.mRotFractalRotation.RotateVector(point2); CVector3 z = point2; double r = z.Length(); CVector3 c = z; double minimumR = 100.0; double w = 0.0; double orbitTrapTotal = 0.0; enumFractalFormula formula = fractal::none; out->maxiter = true; int fractalIndex = 0; if (in.forcedFormulaIndex >= 0) fractalIndex = in.forcedFormulaIndex; const cFractal *defaultFractal = fractals.GetFractal(fractalIndex); sExtendedAux extendedAux[NUMBER_OF_FRACTALS]; int maxFractal = (in.forcedFormulaIndex >= 0) ? in.forcedFormulaIndex : fractals.GetMaxFractalIndex(); int minFractal = (in.forcedFormulaIndex >= 0) ? in.forcedFormulaIndex : 0; for (int i = minFractal; i <= maxFractal; i++) { extendedAux[i].r_dz = 1.0; extendedAux[i].r = r; extendedAux[i].color = 1.0; extendedAux[i].actualScale = fractals.GetFractal(i)->mandelbox.scale; extendedAux[i].DE = 1.0; extendedAux[i].c = c; extendedAux[i].cw = 0; extendedAux[i].newR = 1e+20; extendedAux[i].axisBias = 1e+20; extendedAux[i].orbitTraps = 1e+20; extendedAux[i].transformSampling = 1e+20; } //main iteration loop int i; int sequence = 0; int lastSequnce = 0; for (i = 0; i < in.maxN; i++) { //hybrid fractal sequence if (in.forcedFormulaIndex >= 0) { sequence = in.forcedFormulaIndex; } else { sequence = fractals.GetSequence(i); } //for optimized DE calculation if(fractals.UseOptimizedDE()) { extendedAux[sequence] = extendedAux[lastSequnce]; lastSequnce = sequence; } //foldings if (in.common.foldings.boxEnable) { BoxFolding(z, &in.common.foldings, extendedAux[sequence]); r = z.Length(); } if (in.common.foldings.sphericalEnable) { extendedAux[sequence].r = r; SphericalFolding(z, &in.common.foldings, extendedAux[sequence]); r = z.Length(); } const cFractal *fractal = fractals.GetFractal(sequence); formula = fractal->formula; //temporary vector for weight function CVector3 tempZ = z; extendedAux[sequence].r = r; if (!fractals.IsHybrid() || fractals.GetWeight(sequence) > 0.0) { //calls for fractal formulas switch (formula) { case mandelbulb: { MandelbulbIteration(z, fractal, extendedAux[sequence]); break; } case mandelbulb2: { Mandelbulb2Iteration(z, extendedAux[sequence]); break; } case mandelbulb3: { Mandelbulb3Iteration(z, extendedAux[sequence]); break; } case mandelbulb4: { Mandelbulb4Iteration(z, fractal, extendedAux[sequence]); break; } case fast_mandelbulb_power2: { MandelbulbPower2Iteration(z, extendedAux[sequence]); break; } case xenodreambuie: { XenodreambuieIteration(z, fractal, extendedAux[sequence]); break; } case mandelbox: { MandelboxIteration(z, fractal, extendedAux[sequence]); break; } case smoothMandelbox: { SmoothMandelboxIteration(z, fractal, extendedAux[sequence]); break; } case boxFoldBulbPow2: { BoxFoldBulbPow2Iteration(z, fractal); break; } case menger_sponge: { MengerSpongeIteration(z, extendedAux[sequence]); break; } case kaleidoscopicIFS: { KaleidoscopicIFSIteration(z, fractal, extendedAux[sequence]); break; } case aexion: { AexionIteration(z, w, i, fractal, extendedAux[sequence]); break; } case hypercomplex: { HypercomplexIteration(z, w, extendedAux[sequence]); break; } case quaternion: { QuaternionIteration(z, w, extendedAux[sequence]); break; } case benesi: { BenesiIteration(z, c, extendedAux[sequence]); break; } case bristorbrot: { BristorbrotIteration(z, extendedAux[sequence]); break; } case ides: { IdesIteration(z, fractal); break; } case ides2: { Ides2Iteration(z, fractal); break; } case buffalo: { BuffaloIteration(z, fractal, extendedAux[sequence]); break; } case quickdudley: { QuickDudleyIteration(z); break; } case quickDudleyMod: { QuickDudleyModIteration(z, fractal); break; } case lkmitch: { LkmitchIteration(z); break; } case makin3d2: { Makin3D2Iteration(z); break; } case msltoeDonut: { MsltoeDonutIteration(z, fractal, extendedAux[sequence]); break; } case msltoesym2Mod: { MsltoeSym2ModIteration(z, c, fractal, extendedAux[sequence]); break; } case msltoesym3Mod: { MsltoeSym3ModIteration(z, c, i, fractal, extendedAux[sequence]); break; } case msltoesym3Mod2: { MsltoeSym3Mod2Iteration(z, c, fractal, extendedAux[sequence]); break; } case msltoesym3Mod3: { MsltoeSym3Mod3Iteration(z, c, i, fractal, extendedAux[sequence]); break; } case msltoesym4Mod: { MsltoeSym4ModIteration(z, c, fractal, extendedAux[sequence]); break; } case generalizedFoldBox: { GeneralizedFoldBoxIteration(z, fractal, extendedAux[sequence]); break; } case mandelbulb5: { Mandelbulb5Iteration(z, c, minimumR, i, fractal, extendedAux[sequence]); break; } case mandelbox103: { Mandelbox103Iteration(z, c, minimumR, i, fractal, extendedAux[sequence]); break; } case quaternion104: { CVector4 z4D(z, w); Quaternion104Iteration(z4D, CVector4(c, 0.0), i, fractal, extendedAux[sequence]); z = z4D.GetXYZ(); w = z4D.w; break; } case mengerSponge105: { MengerSponge105Iteration(z, c, minimumR, i, fractal, extendedAux[sequence]); break; } case mandelbulb6Beta: { Mandelbulb6BetaIteration(z, c, minimumR, i, fractal, extendedAux[sequence]); break; } case benesiTransforms: { BenesiTransformsIteration(z, c, minimumR, i, fractal, extendedAux[sequence]); break; } case aboxMod1: { AboxMod1Iteration(z, fractal, extendedAux[sequence]); break; } case aboxMod2: { AboxMod2Iteration(z, fractal, extendedAux[sequence]); break; } case aboxModKali: { AboxModKaliIteration(z, fractal, extendedAux[sequence]); break; } case aboxVSIcen1: { AboxVSIcen1Iteration(z, c, fractal, extendedAux[sequence]); break; } case aexionOctopusMod: { AexionOctopusModIteration(z, c, fractal); break; } case amazingSurf: { AmazingSurfIteration(z, fractal, extendedAux[sequence]); break; } case amazingSurfMod1: { AmazingSurfMod1Iteration(z, fractal, extendedAux[sequence]); break; } case benesiPineTree: { BenesiPineTreeIteration(z, c, fractal, extendedAux[sequence]); break; } case benesiT1PineTree: { BenesiT1PineTreeIteration(z, c, i, fractal, extendedAux[sequence]); break; } case eiffieMsltoe: { EiffieMsltoeIteration(z, c, fractal, extendedAux[sequence]); break; } case foldBoxMod1: { FoldBoxMod1Iteration(z, i, fractal, extendedAux[sequence]); break; } case iqBulb: { IQbulbIteration(z, fractal, extendedAux[sequence]); break; } case kalisets1: { Kalisets1Iteration(z, c, fractal, extendedAux[sequence]); break; } case mandelbulbMulti: { MandelbulbMultiIteration(z, fractal, extendedAux[sequence]); break; } case mandelbulbVaryPowerV1: { MandelbulbVaryPowerV1Iteration(z, i, fractal, extendedAux[sequence]); break; } case mengerMod1: { MengerMod1Iteration(z, i, fractal, extendedAux[sequence]); break; } case riemannSphereMsltoe: { RiemannSphereMsltoeIteration(z, fractal); break; } case riemannSphereMsltoeV1: { RiemannSphereMsltoeV1Iteration(z, fractal); break; } case quaternion3D: { Quaternion3DIteration(z, fractal, extendedAux[sequence]); break; } //transforms ------------------------------------------------------------------------------------------ case transfAdditionConstant: { TransformAdditionConstantIteration(z, fractal); break; } case transfAdditionConstantVaryV1: { TransformAdditionConstantVaryV1Iteration(z, i, fractal); break; } case transfAddCpixel: { TransformAddCpixelIteration(z, c, fractal); break; } case transfAddCpixelAxisSwap: { TransformAddCpixelAxisSwapIteration(z, c, fractal); break; } case transfAddCpixelCxCyAxisSwap: { TransformAddCpixelCxCyAxisSwapIteration(z, c, fractal); break; } case transfAddCpixelPosNeg: { TransformAddCpixelPosNegIteration(z, c, fractal); break; } case transfAddCpixelVaryV1: { TransformAddCpixelVaryV1Iteration(z, c, i, fractal); break; } case transfBenesiT1: { TransformBenesiT1Iteration(z, fractal, extendedAux[sequence]); break; } case transfBenesiT1Mod: { TransformBenesiT1ModIteration(z, fractal, extendedAux[sequence]); break; } case transfBenesiT2: { TransformBenesiT2Iteration(z, fractal, extendedAux[sequence]); break; } case transfBenesiT3: { TransformBenesiT3Iteration(z, fractal); break; } case transfBenesiT4: { TransformBenesiT4Iteration(z, fractal); break; } case transfBenesiT5b: { TransformBenesiT5bIteration(z, fractal); break; } case transfBenesiMagForward: { TransformBenesiMagForwardIteration(z); break; } case transfBenesiMagBackward: { TransformBenesiMagBackwardIteration(z); break; } case transfBenesiCubeSphere: { TransformBenesiCubeSphereIteration(z); break; } case transfBenesiSphereCube: { TransformBenesiSphereCubeIteration(z); break; } case transfBoxFold: { TransformBoxFoldIteration(z, fractal, extendedAux[sequence]); break; } case transfBoxFoldXYZ: { TransformBoxFoldXYZIteration(z, fractal, extendedAux[sequence]); break; } case transfBoxOffset: { TransformBoxOffsetIteration(z, fractal, extendedAux[sequence]); break; } case transfFabsAddConstant: { TransformFabsAddConstantIteration(z, fractal); break; } case transfFabsAddConstantV2: { TransformFabsAddConstantV2Iteration(z, fractal); break; } case transfFabsAddMulti: { TransformFabsAddMultiIteration(z, fractal); break; } case transfIterationWeight: { TransformIterationWeightIteration(z, i, fractal); break; } case transfLinCombineCxyz: { TransformLinCombineCxyz(c, fractal); break; } case transfMultipleAngle: { TransformMultipleAngle(z, fractal, extendedAux[sequence]); break; } case transfNegFabsAddConstant: { TransformNegFabsAddConstantIteration(z, fractal); break; } case transfRotation: { TransformRotationIteration(z, fractal); break; } case transfRotationVaryV1: { TransformRotationVaryV1Iteration(z, i, fractal); break; } case transfScale: { TransformScaleIteration(z, fractal, extendedAux[sequence]); break; } case transfScaleVaryV1: { TransformScaleVaryV1Iteration(z, i, fractal, extendedAux[sequence]); break; } case transfScale3D: { TransformScale3DIteration(z, fractal, extendedAux[sequence]); break; } case platonicSolid: { TransformPlatonicSolidIteration(z, fractal); break; } case transfRPower: { TransformPowerR(z, fractal, extendedAux[sequence]); break; } case transfSphereInvC: { TransformSphereInvCIteration(z, c, fractal); break; } case transfSphericalOffset: { TransformSphericalOffsetIteration(z, fractal, extendedAux[sequence]); break; } case transfSphericalFold: { TransformSphericalFoldIteration(z, fractal, extendedAux[sequence]); break; } case transfSphericalPwrFold: { TransformSphericalPwrFoldIteration(z, fractal, extendedAux[sequence]); break; } case transfZvectorAxisSwap: { TransformZvectorAxisSwapIteration(z, fractal ); break; } // 4D --------------------------------------------------------------------------- case quaternion4D: { CVector4 z4D(z, w); Quaternion4DIteration(z4D, i, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case mandelboxVaryScale4D: { CVector4 z4D(z, w); MandelboxVaryScale4DIteration(z4D, i, fractal, extendedAux[sequence]); z = z4D.GetXYZ(); w = z4D.w; break; } case transfAdditionConstant4D: { CVector4 z4D(z, w); TransformAdditionConstant4DIteration(z4D, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case transfBoxFold4D: { CVector4 z4D(z, w); TransformBoxFold4DIteration(z4D, fractal, extendedAux[sequence]); z = z4D.GetXYZ(); w = z4D.w; break; } case transfFabsAddConstant4D: { CVector4 z4D(z, w); TransformFabsAddConstant4DIteration(z4D, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case transfFabsAddConstantV24D: { CVector4 z4D(z, w); TransformFabsAddConstantV24DIteration(z4D, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case transfIterationWeight4D: { CVector4 z4D(z, w); TransformIterationWeight4DIteration(z4D, i, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case transfScale4D: { CVector4 z4D(z, w); TransformScale4DIteration(z4D, fractal, extendedAux[sequence]); z = z4D.GetXYZ(); w = z4D.w; break; } case transfSphericalFold4D: { CVector4 z4D(z, w); TransformSphericalFold4DIteration(z4D, fractal, extendedAux[sequence]); z = z4D.GetXYZ(); w = z4D.w; break; } default: z = CVector3(0.0, 0.0, 0.0); break; } } //addition of constant if (fractals.IsAddCConstant(sequence)) { switch (formula) { case aboxMod1: case amazingSurf: //case amazingSurfMod1: { if (fractals.IsJuliaEnabled(sequence)) { CVector3 juliaC = fractals.GetJuliaConstant(sequence) * fractals.GetConstantMultiplier(sequence); z += CVector3(juliaC.y, juliaC.x, juliaC.z); } else { z += CVector3(c.y, c.x, c.z) * fractals.GetConstantMultiplier(sequence); } break; } default: { if (fractals.IsJuliaEnabled(sequence)) { z += fractals.GetJuliaConstant(sequence) * fractals.GetConstantMultiplier(sequence); } else { z += c * fractals.GetConstantMultiplier(sequence); } break; } } } if (fractals.IsHybrid()) { z = SmoothCVector(tempZ, z, fractals.GetWeight(sequence)); } //r calculation r = sqrt(z.x * z.x + z.y * z.y + z.z * z.z + w * w); //escape conditions if (fractals.IsCheckForBailout(sequence)) { if (Mode == calcModeNormal) { if (r > fractals.GetBailout(sequence)) { out->maxiter = false; break; } } else if (Mode == calcModeDeltaDE1) { if (r > fractals.GetBailout(sequence)) { out->maxiter = false; break; } } else if (Mode == calcModeDeltaDE2) { if (i == in.maxN) break; } else if (Mode == calcModeColouring) { double len = 0.0; switch (in.common.fractalColoringAlgorithm) { case fractalColoringStandard: { len = r; break; } case fractalColoringZDotPoint: { len = fabs(z.Dot(in.point)); break; } case fractalColoringSphere: { len = fabs((z - in.point).Length() - in.common.fractalColoringSphereRadius); break; } case fractalColoringCross: { len = dMin(fabs(z.x), fabs(z.y), fabs(z.z)); break; } case fractalColoringLine: { len = fabs(z.Dot(in.common.fractalColoringLineDirection)); break; } } if (fractal->formula != mandelbox || in.common.fractalColoringAlgorithm != fractalColoringStandard) { if (len < minimumR) minimumR = len; } if (r > 1e15) break; } else if (Mode == calcModeOrbitTrap) { CVector3 delta = z - in.common.fakeLightsOrbitTrap; double distance = delta.Length(); if (i >= in.common.fakeLightsMinIter && i <= in.common.fakeLightsMaxIter) orbitTrapTotal += (1.0f / (distance * distance)); if (distance > 1000) { out->orbitTrapR = orbitTrapTotal; break; } } } } //final calculations if (Mode == calcModeNormal) { if (fractals.IsHybrid()) { if(extendedAux[sequence].r_dz > 0) { if (fractals.GetDEFunctionType(0) == fractal::linearDEFunction) { out->distance = r / fabs(extendedAux[sequence].DE); } else if (fractals.GetDEFunctionType(0) == fractal::logarithmicDEFunction) { out->distance = 0.5 * r * log(r) / extendedAux[sequence].r_dz; } } else { out->distance = r; } } else { switch (formula) { case benesi: case benesiPineTree: case benesiT1PineTree: case bristorbrot: case buffalo: case eiffieMsltoe: case fast_mandelbulb_power2: case hypercomplex: case iqBulb: case mandelbulb: case mandelbulb2: case mandelbulb3: case mandelbulb4: case mandelbulb5: case mandelbulb6Beta: case mandelbulbMulti: case mandelbulbVaryPowerV1: case msltoesym2Mod: case msltoesym3Mod: case msltoesym3Mod2: case msltoesym3Mod3: case msltoesym4Mod: case quaternion: case quaternion3D: case xenodreambuie: { if(extendedAux[sequence].r_dz > 0) out->distance = 0.5 * r * log(r) / extendedAux[sequence].r_dz; else out->distance = r; break; } case mandelbox: case smoothMandelbox: case mandelboxVaryScale4D: case generalizedFoldBox: case mandelbox103: case mengerSponge105: case foldBoxMod1: case aboxModKali: case mengerMod1: case aboxMod1: case aboxMod2: case amazingSurf: case amazingSurfMod1: case kalisets1: case aboxVSIcen1: { if(extendedAux[sequence].r_dz > 0) out->distance = r / fabs(extendedAux[sequence].DE); else out->distance = r; break; } case kaleidoscopicIFS: case menger_sponge: { if(extendedAux[sequence].r_dz > 0) out->distance = (r - 2.0) / (extendedAux[sequence].DE); else out->distance = r; break; } default: out->distance = -1.0; break; } } } //color calculation else if (Mode == calcModeColouring) { if (fractals.IsHybrid()) { if (minimumR > 100) minimumR = 100; double mboxColor = 0.0; double mboxDE = 1.0; for (int h = minFractal; h <= maxFractal; h++) { mboxColor += extendedAux[h].color; mboxDE *= extendedAux[h].DE; //mboxDE *= mandelboxAux[h].mboxDE + extendedAux[h].color; } double r2 = r / fabs(mboxDE); if (r2 > 20) r2 = 20; if (mboxColor > 1000) mboxColor = 1000; out->colorIndex = minimumR * 1000.0 + mboxColor * 100 + r2 * 5000.0; } else { switch (formula) { case mandelbox: case smoothMandelbox: case mandelboxVaryScale4D: case generalizedFoldBox: case foldBoxMod1: out->colorIndex = extendedAux[fractalIndex].color * 100.0 + r * defaultFractal->mandelbox.color.factorR + ((in.common.fractalColoringAlgorithm != fractalColoringStandard) ? minimumR * 1000.0 : 0.0); break; case mandelbulb5: case mandelbox103: case mandelbulb6Beta: case benesiTransforms: case mengerSponge105: out->colorIndex = extendedAux[fractalIndex].newR + ((in.common.fractalColoringAlgorithm != fractalColoringStandard) ? minimumR * 1000.0 : 0.0); break; case mengerMod1: case aboxModKali: case aboxMod1: case menger_sponge: case kaleidoscopicIFS: out->colorIndex = minimumR * 1000.0; break; case amazingSurf: case amazingSurfMod1: out->colorIndex = minimumR * 200.0; break; case msltoeDonut: out->colorIndex = extendedAux[fractalIndex].color * 2000.0 / i; break; default: out->colorIndex = minimumR * 5000.0; break; } } } else { out->distance = 0.0; } out->iters = i + 1; out->z = z; // CVector3( z.x, z.y, w); //tim = rdtsc() - tim; perf+= tim; perfCount++; outStream << (double)perf/perfCount - 560.0 << endl; //------------- 3249 ns for all calculation ---------------- }
double CalculateDistanceSimple(const sParamRender ¶ms, const cNineFractals &fractals, const sDistanceIn &in, sDistanceOut *out, int forcedFormulaIndex) { double distance = 0; const int N = (in.normalCalculationMode && params.common.iterThreshMode) ? params.N * 5 : params.N; sFractalIn fractIn( in.point, params.minN, N, params.common, forcedFormulaIndex, in.normalCalculationMode); sFractalOut fractOut; fractOut.colorIndex = 0; if (fractals.GetDEType(forcedFormulaIndex) == fractal::analyticDEType) { Compute<fractal::calcModeNormal>(fractals, fractIn, &fractOut); distance = fractOut.distance; // qDebug() << "computed distance" << distance; out->maxiter = fractOut.maxiter; out->iters = fractOut.iters; out->colorIndex = fractOut.colorIndex; out->totalIters += fractOut.iters; // don't use maxiter when limits are disabled and iterThresh mode is not used if (!params.limitsEnabled) { if (!params.common.iterThreshMode) out->maxiter = false; } else { // never use maxiter if normal vectors are calculated if (in.normalCalculationMode) out->maxiter = false; } if (out->maxiter) distance = 0.0; if (fractOut.iters < params.minN && distance < in.detailSize) distance = in.detailSize; if (params.interiorMode && !in.normalCalculationMode) { if (distance < 0.5 * in.detailSize || fractOut.maxiter) { distance = in.detailSize; out->maxiter = false; } } else if (params.interiorMode && in.normalCalculationMode) { if (distance < 0.9 * in.detailSize) { distance = in.detailSize - distance; out->maxiter = false; } } if (params.common.iterThreshMode && !in.normalCalculationMode && !fractOut.maxiter) { if (distance < in.detailSize) { distance = in.detailSize * 1.01; } } } else { const double deltaDE = 1e-10; Compute<fractal::calcModeDeltaDE1>(fractals, fractIn, &fractOut); const double r = fractOut.z.Length(); out->maxiter = fractOut.maxiter; bool maxiter = fractOut.maxiter; out->iters = fractOut.iters; out->colorIndex = fractOut.colorIndex; out->totalIters += fractOut.iters; // don't use maxiter when limits are disabled and iterThresh mode is not used if (!params.limitsEnabled) { if (!params.common.iterThreshMode) maxiter = false; } else { // never use maxiter if normal vectors are calculated if (in.normalCalculationMode) maxiter = false; } fractIn.maxN = fractOut.iters; // for other directions must be the same number of iterations fractIn.point = in.point + CVector3(deltaDE, 0.0, 0.0); Compute<fractal::calcModeDeltaDE1>(fractals, fractIn, &fractOut); double r2 = fractOut.z.Length(); const double dr1 = fabs(r2 - r) / deltaDE; out->totalIters += fractOut.iters; fractIn.point = in.point + CVector3(0.0, deltaDE, 0.0); Compute<fractal::calcModeDeltaDE1>(fractals, fractIn, &fractOut); r2 = fractOut.z.Length(); const double dr2 = fabs(r2 - r) / deltaDE; out->totalIters += fractOut.iters; fractIn.point = in.point + CVector3(0.0, 0.0, deltaDE); Compute<fractal::calcModeDeltaDE1>(fractals, fractIn, &fractOut); r2 = fractOut.z.Length(); const double dr3 = fabs(r2 - r) / deltaDE; out->totalIters += fractOut.iters; const double dr = sqrt(dr1 * dr1 + dr2 * dr2 + dr3 * dr3); if (dr > 0) { // DE functions for deltaDE if (fractals.GetDEFunctionType(forcedFormulaIndex) == fractal::linearDEFunction) distance = 0.5 * r / dr; else if (fractals.GetDEFunctionType(forcedFormulaIndex) == fractal::logarithmicDEFunction) distance = 0.5 * r * log(r) / dr; else if (fractals.GetDEFunctionType(forcedFormulaIndex) == fractal::pseudoKleinianDEFunction) { const CVector3 z = fractOut.z; const double rxy = sqrt(z.x * z.x + z.y * z.y); distance = max(rxy - 0.92784, fabs(rxy * z.z) / r) / (dr); } else if (fractals.GetDEFunctionType(forcedFormulaIndex) == fractal::josKleinianDEFunction) { const CVector3 z = fractOut.z; const double rxy = sqrt(z.x * z.x + z.z * z.z); distance = (fabs(rxy * z.y) / r) / (dr); maxiter = false; } } else { distance = r; } // if (distance < 1e-20) distance = 1e-20; if (maxiter) { distance = 0; } if (fractOut.iters < params.minN && distance < in.detailSize) distance = in.detailSize; if (params.interiorMode && !in.normalCalculationMode) { if (distance < 0.5 * in.detailSize || maxiter) { distance = in.detailSize; out->maxiter = false; } } else if (params.interiorMode && in.normalCalculationMode) { if (distance < 0.9 * in.detailSize) { distance = in.detailSize - distance; out->maxiter = false; } } if (params.common.iterThreshMode && !in.normalCalculationMode && !maxiter) { if (distance < in.detailSize) { distance = in.detailSize * 1.01; } } } return distance; }
void Compute(const cNineFractals &fractals, const sFractalIn &in, sFractalOut *out) { // QTextStream outStream(stdout); // clock_t tim; // tim = rdtsc(); // repeat, move and rotate CVector3 point2 = in.point.mod(in.common.repeat) - in.common.fractalPosition; point2 = in.common.mRotFractalRotation.RotateVector(point2); CVector3 z = point2; double r = z.Length(); CVector3 c = z; double minimumR = 100.0; double w = 0.0; double orbitTrapTotal = 0.0; enumFractalFormula formula = fractal::none; out->maxiter = true; int fractalIndex = 0; if (in.forcedFormulaIndex >= 0) fractalIndex = in.forcedFormulaIndex; const cFractal *defaultFractal = fractals.GetFractal(fractalIndex); sExtendedAux extendedAux; extendedAux.r_dz = 1.0; extendedAux.r = r; extendedAux.color = 1.0; extendedAux.actualScale = fractals.GetFractal(fractalIndex)->mandelbox.scale; extendedAux.DE = 1.0; extendedAux.c = c; extendedAux.cw = 0; extendedAux.foldFactor = 0.0; extendedAux.minRFactor = 0.0; extendedAux.scaleFactor = 0.0; // extendedAux.newR = 1e+20; // extendedAux.axisBias = 1e+20; // extendedAux.orbitTraps = 1e+20; // extendedAux.transformSampling = 1e+20; // main iteration loop int i; int sequence = 0; CVector3 lastGoodZ; CVector3 lastZ; for (i = 0; i < in.maxN; i++) { lastGoodZ = lastZ; lastZ = z; // hybrid fractal sequence if (in.forcedFormulaIndex >= 0) { sequence = in.forcedFormulaIndex; } else { sequence = fractals.GetSequence(i); } // foldings if (in.common.foldings.boxEnable) { BoxFolding(z, &in.common.foldings, extendedAux); r = z.Length(); } if (in.common.foldings.sphericalEnable) { extendedAux.r = r; SphericalFolding(z, &in.common.foldings, extendedAux); r = z.Length(); } const cFractal *fractal = fractals.GetFractal(sequence); formula = fractal->formula; // temporary vector for weight function CVector3 tempZ = z; extendedAux.r = r; if (!fractals.IsHybrid() || fractals.GetWeight(sequence) > 0.0) { // calls for fractal formulas switch (formula) { case mandelbulb: { MandelbulbIteration(z, fractal, extendedAux); break; } case mandelbulb2: { Mandelbulb2Iteration(z, extendedAux); break; } case mandelbulb3: { Mandelbulb3Iteration(z, extendedAux); break; } case mandelbulb4: { Mandelbulb4Iteration(z, fractal, extendedAux); break; } case fast_mandelbulb_power2: { MandelbulbPower2Iteration(z, extendedAux); break; } case xenodreambuie: { XenodreambuieIteration(z, fractal, extendedAux); break; } case mandelbox: { MandelboxIteration(z, fractal, extendedAux); break; } case smoothMandelbox: { SmoothMandelboxIteration(z, fractal, extendedAux); break; } case boxFoldBulbPow2: { BoxFoldBulbPow2Iteration(z, fractal); break; } case menger_sponge: { MengerSpongeIteration(z, extendedAux); break; } case kaleidoscopicIFS: { KaleidoscopicIFSIteration(z, fractal, extendedAux); break; } case aexion: { AexionIteration(z, w, i, fractal, extendedAux); break; } case hypercomplex: { HypercomplexIteration(z, w, extendedAux); break; } case quaternion: { QuaternionIteration(z, w, extendedAux); break; } case benesi: { BenesiIteration(z, c, extendedAux); break; } case bristorbrot: { BristorbrotIteration(z, extendedAux); break; } case ides: { IdesIteration(z, fractal); break; } case ides2: { Ides2Iteration(z, fractal); break; } case buffalo: { BuffaloIteration(z, fractal, extendedAux); break; } case quickdudley: { QuickDudleyIteration(z); break; } case quickDudleyMod: { QuickDudleyModIteration(z, fractal); break; } case lkmitch: { LkmitchIteration(z); break; } case makin3d2: { Makin3D2Iteration(z); break; } case msltoeDonut: { MsltoeDonutIteration(z, fractal, extendedAux); break; } case msltoesym2Mod: { MsltoeSym2ModIteration(z, c, fractal, extendedAux); break; } case msltoesym3Mod: { MsltoeSym3ModIteration(z, c, i, fractal, extendedAux); break; } case msltoesym3Mod2: { MsltoeSym3Mod2Iteration(z, c, fractal, extendedAux); break; } case msltoesym3Mod3: { MsltoeSym3Mod3Iteration(z, c, i, fractal, extendedAux); break; } case msltoesym4Mod: { MsltoeSym4ModIteration(z, c, fractal, extendedAux); break; } case msltoeToroidal: { MsltoeToroidalIteration(z, fractal, extendedAux); break; } case msltoeToroidalMulti: { MsltoeToroidalMultiIteration(z, fractal, extendedAux); break; } case generalizedFoldBox: { GeneralizedFoldBoxIteration(z, fractal, extendedAux); break; } case aboxMod1: { AboxMod1Iteration(z, fractal, extendedAux); break; } case aboxMod2: { AboxMod2Iteration(z, fractal, extendedAux); break; } case aboxModKali: { AboxModKaliIteration(z, fractal, extendedAux); break; } case aboxModKaliEiffie: { AboxModKaliEiffieIteration(z, c, i, fractal, extendedAux); break; } case aboxVSIcen1: { AboxVSIcen1Iteration(z, c, fractal, extendedAux); break; } case aexionOctopusMod: { AexionOctopusModIteration(z, c, fractal); break; } case amazingSurf: { AmazingSurfIteration(z, fractal, extendedAux); break; } case amazingSurfMod1: { AmazingSurfMod1Iteration(z, fractal, extendedAux); break; } case amazingSurfMulti: { AmazingSurfMultiIteration(z, i, fractal, extendedAux); break; } case benesiPineTree: { BenesiPineTreeIteration(z, c, fractal, extendedAux); break; } case benesiT1PineTree: { BenesiT1PineTreeIteration(z, c, i, fractal, extendedAux); break; } case benesiMagTransforms: { BenesiMagTransformsIteration(z, c, i, fractal, extendedAux); break; } case collatz: { CollatzIteration(z, extendedAux); break; } case collatzMod: { CollatzModIteration(z, c, fractal, extendedAux); break; } case eiffieMsltoe: { EiffieMsltoeIteration(z, c, fractal, extendedAux); break; } case foldBoxMod1: { FoldBoxMod1Iteration(z, i, fractal, extendedAux); break; } case iqBulb: { IQbulbIteration(z, fractal, extendedAux); break; } case kalisets1: { Kalisets1Iteration(z, c, fractal, extendedAux); break; } case mandelboxMenger: { MandelboxMengerIteration(z, c, i, fractal, extendedAux); break; } case mandelbulbBermarte: { MandelbulbBermarteIteration(z, fractal, extendedAux); break; } case mandelbulbKali: { MandelbulbKaliIteration(z, fractal, extendedAux); break; } case mandelbulbKaliMulti: { MandelbulbKaliMultiIteration(z, c, fractal, extendedAux); break; } case mandelbulbMulti: { MandelbulbMultiIteration(z, c, fractal, extendedAux); break; } case mandelbulbVaryPowerV1: { MandelbulbVaryPowerV1Iteration(z, i, fractal, extendedAux); break; } case mengerMod1: { MengerMod1Iteration(z, i, fractal, extendedAux); break; } case mengerMiddleMod: { MengerMiddleModIteration(z, c, i, fractal, extendedAux); break; } case mengerPrismShape: { MengerPrismShapeIteration(z, i, fractal, extendedAux); break; } case mengerPwr2Poly: { MengerPwr2PolyIteration(z, c, i, fractal, extendedAux); break; } case riemannSphereMsltoe: { RiemannSphereMsltoeIteration(z, fractal); break; } case riemannSphereMsltoeV1: { RiemannSphereMsltoeV1Iteration(z, fractal); break; } case riemannBulbMsltoeMod2: { RiemannBulbMsltoeMod2Iteration(z, fractal); break; } case quaternion3D: { Quaternion3DIteration(z, fractal, extendedAux); break; } case fastImagscaPower2: { FastImagscaPower2Iteration(z); break; } case crossMenger: { CrossMengerIteration(z, c, i, fractal, extendedAux); break; } // transforms // ------------------------------------------------------------------------------------------ case transfAdditionConstant: { TransformAdditionConstantIteration(z, fractal); break; } case transfAdditionConstantVaryV1: { TransformAdditionConstantVaryV1Iteration(z, i, fractal); break; } case transfAddCpixel: { TransformAddCpixelIteration(z, c, fractal); break; } case transfAddCpixelAxisSwap: { TransformAddCpixelAxisSwapIteration(z, c, fractal); break; } case transfAddCpixelCxCyAxisSwap: { TransformAddCpixelCxCyAxisSwapIteration(z, c, fractal); break; } case transfAddCpixelPosNeg: { TransformAddCpixelPosNegIteration(z, c, fractal); break; } case transfAddCpixelVaryV1: { TransformAddCpixelVaryV1Iteration(z, c, i, fractal); break; } case transfBenesiT1: { TransformBenesiT1Iteration(z, fractal, extendedAux); break; } case transfBenesiT1Mod: { TransformBenesiT1ModIteration(z, fractal, extendedAux); break; } case transfBenesiT2: { TransformBenesiT2Iteration(z, fractal, extendedAux); break; } case transfBenesiT3: { TransformBenesiT3Iteration(z, fractal); break; } case transfBenesiT4: { TransformBenesiT4Iteration(z, fractal); break; } case transfBenesiT5b: { TransformBenesiT5bIteration(z, fractal); break; } case transfBenesiMagForward: { TransformBenesiMagForwardIteration(z); break; } case transfBenesiMagBackward: { TransformBenesiMagBackwardIteration(z); break; } case transfBenesiCubeSphere: { TransformBenesiCubeSphereIteration(z); break; } case transfBenesiSphereCube: { TransformBenesiSphereCubeIteration(z); break; } case transfBoxFold: { TransformBoxFoldIteration(z, fractal, extendedAux); break; } case transfBoxFoldXYZ: { TransformBoxFoldXYZIteration(z, fractal, extendedAux); break; } case transfBoxOffset: { TransformBoxOffsetIteration(z, fractal, extendedAux); break; } case transfFabsAddConstant: { TransformFabsAddConstantIteration(z, fractal); break; } case transfFabsAddConstantV2: { TransformFabsAddConstantV2Iteration(z, fractal); break; } case transfFabsAddMulti: { TransformFabsAddMultiIteration(z, fractal); break; } case transfFoldingTetra3D: { TransformFoldingTetra3DIteration(z, fractal); break; } case transfIterationWeight: { TransformIterationWeightIteration(z, i, fractal); break; } case transfInvCylindrical: { TransformInvCylindricalIteration(z, fractal, extendedAux); break; } case transfLinCombineCxyz: { TransformLinCombineCxyz(c, fractal); break; } case transfMultipleAngle: { TransformMultipleAngle(z, fractal, extendedAux); break; } case transfNegFabsAddConstant: { TransformNegFabsAddConstantIteration(z, fractal); break; } case transfPwr2Polynomial: { TransformPwr2PolynomialIteration(z, fractal, extendedAux); break; } case transfRotation: { TransformRotationIteration(z, fractal); break; } case transfRotationVaryV1: { TransformRotationVaryV1Iteration(z, i, fractal); break; } case transfRpow3: { TransformRpow3Iteration(z, fractal, extendedAux); break; } case transfScale: { TransformScaleIteration(z, fractal, extendedAux); break; } case transfScaleVaryV1: { TransformScaleVaryV1Iteration(z, i, fractal, extendedAux); break; } case transfScale3D: { TransformScale3DIteration(z, fractal, extendedAux); break; } case platonicSolid: { TransformPlatonicSolidIteration(z, fractal); break; } case transfRPower: { TransformPowerR(z, fractal, extendedAux); break; } case transfSphereInvC: { TransformSphereInvCIteration(z, c, fractal); break; } case transfSphereInv: { TransformSphereInvIteration(z, fractal, extendedAux); break; } case transfSphericalOffset: { TransformSphericalOffsetIteration(z, fractal, extendedAux); break; } case transfSphericalFold: { TransformSphericalFoldIteration(z, fractal, extendedAux); break; } case transfSphericalFoldAbox: { TransformSphericalFoldAboxIteration(z, fractal, extendedAux); break; } case transfSphericalFoldVaryV1: { TransformSphericalFoldVaryV1Iteration(z, i, fractal, extendedAux); break; } case transfSphericalPwrFold: { TransformSphericalPwrFoldIteration(z, fractal, extendedAux); break; } case transfSurfFoldMulti: { TransformSurfFoldMultiIteration(z, fractal, extendedAux); break; } case transfZvectorAxisSwap: { TransformZvectorAxisSwapIteration(z, fractal); break; } case transfRotationFoldingPlane: { TransformRotationFoldingPlane(z, fractal, extendedAux); break; } case transfQuaternionFold: { TransformQuaternionFoldIteration(z, c, fractal, extendedAux); break; } case transfMengerFold: { TransformMengerFoldIteration(z, fractal, extendedAux); break; } // 4D --------------------------------------------------------------------------- case quaternion4D: { CVector4 z4D(z, w); Quaternion4DIteration(z4D, i, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case mandelboxVaryScale4D: { CVector4 z4D(z, w); MandelboxVaryScale4DIteration(z4D, i, fractal, extendedAux); z = z4D.GetXYZ(); w = z4D.w; break; } case transfAdditionConstant4D: { CVector4 z4D(z, w); TransformAdditionConstant4DIteration(z4D, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case transfBoxFold4D: { CVector4 z4D(z, w); TransformBoxFold4DIteration(z4D, fractal, extendedAux); z = z4D.GetXYZ(); w = z4D.w; break; } case transfFabsAddConstant4D: { CVector4 z4D(z, w); TransformFabsAddConstant4DIteration(z4D, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case transfFabsAddConstantV24D: { CVector4 z4D(z, w); TransformFabsAddConstantV24DIteration(z4D, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case transfIterationWeight4D: { CVector4 z4D(z, w); TransformIterationWeight4DIteration(z4D, i, fractal); z = z4D.GetXYZ(); w = z4D.w; break; } case transfScale4D: { CVector4 z4D(z, w); TransformScale4DIteration(z4D, fractal, extendedAux); z = z4D.GetXYZ(); w = z4D.w; break; } case transfSphericalFold4D: { CVector4 z4D(z, w); TransformSphericalFold4DIteration(z4D, fractal, extendedAux); z = z4D.GetXYZ(); w = z4D.w; break; } default: double high = fractals.GetBailout(sequence) * 10.0; z = CVector3(high, high, high); break; } } // addition of constant if (fractals.IsAddCConstant(sequence)) { switch (formula) { case aboxMod1: case amazingSurf: // case amazingSurfMod1: { if (fractals.IsJuliaEnabled(sequence)) { CVector3 juliaC = fractals.GetJuliaConstant(sequence) * fractals.GetConstantMultiplier(sequence); z += CVector3(juliaC.y, juliaC.x, juliaC.z); } else { z += CVector3(c.y, c.x, c.z) * fractals.GetConstantMultiplier(sequence); } break; } default: { if (fractals.IsJuliaEnabled(sequence)) { z += fractals.GetJuliaConstant(sequence) * fractals.GetConstantMultiplier(sequence); } else { z += c * fractals.GetConstantMultiplier(sequence); } break; } } } if (fractals.IsHybrid()) { z = SmoothCVector(tempZ, z, fractals.GetWeight(sequence)); } // r calculation // r = sqrt(z.x * z.x + z.y * z.y + z.z * z.z + w * w); switch (fractal->formula) { case fastImagscaPower2: { CVector3 z2 = z * z; r = sqrt(z2.x + z2.y + z2.z) + (z2.y * z2.z) / (z2.x); break; } // scator magnitudes // magnitude in imaginary scator algebra default: { r = sqrt(z.x * z.x + z.y * z.y + z.z * z.z + w * w); break; } } if (z.IsNotANumber()) { z = lastZ; r = z.Length(); w = 0.0; out->maxiter = true; break; } // escape conditions if (fractals.IsCheckForBailout(sequence)) { if (Mode == calcModeNormal) { if (r > fractals.GetBailout(sequence)) { out->maxiter = false; break; } } else if (Mode == calcModeDeltaDE1) { if (r > fractals.GetBailout(sequence)) { out->maxiter = false; break; } } else if (Mode == calcModeDeltaDE2) { if (i == in.maxN) break; } else if (Mode == calcModeColouring) { double len = 0.0; switch (in.fractalColoring.coloringAlgorithm) { case sFractalColoring::fractalColoringStandard: { len = r; break; } case sFractalColoring::fractalColoringZDotPoint: { len = fabs(z.Dot(in.point)); break; } case sFractalColoring::fractalColoringSphere: { len = fabs((z - in.point).Length() - in.fractalColoring.sphereRadius); break; } case sFractalColoring::fractalColoringCross: { len = dMin(fabs(z.x), fabs(z.y), fabs(z.z)); break; } case sFractalColoring::fractalColoringLine: { len = fabs(z.Dot(in.fractalColoring.lineDirection)); break; } case sFractalColoring::fractalColoringNone: { len = r; break; } } if (fractal->formula != mandelbox || in.fractalColoring.coloringAlgorithm != sFractalColoring::fractalColoringStandard) { if (len < minimumR) minimumR = len; } if (r > 1e15) break; } else if (Mode == calcModeOrbitTrap) { CVector3 delta = z - in.common.fakeLightsOrbitTrap; double distance = delta.Length(); if (i >= in.common.fakeLightsMinIter && i <= in.common.fakeLightsMaxIter) orbitTrapTotal += (1.0f / (distance * distance)); if (distance > 1000) { out->orbitTrapR = orbitTrapTotal; break; } } } if (z.IsNotANumber()) // detection of dead computation { // if(Mode != calcModeColouring) // qWarning() << "Dead computation\n" // << "iteration: " << i << "Formula:" << formula << "Sequence:" << sequence // << "\nPoint:" << in.point.Debug() // << "\nLast good z:" << lastGoodZ.Debug() // << "\nPrevious z:" << lastZ.Debug(); z = lastGoodZ; break; } } // final calculations if (Mode == calcModeNormal) { if (fractals.IsHybrid()) { if (extendedAux.r_dz > 0) { if (fractals.GetDEFunctionType(0) == fractal::linearDEFunction) { out->distance = r / fabs(extendedAux.DE); } else if (fractals.GetDEFunctionType(0) == fractal::logarithmicDEFunction) { out->distance = 0.5 * r * log(r) / extendedAux.r_dz; } } else { out->distance = r; } } else { switch (formula) { case benesi: case benesiPineTree: case benesiT1PineTree: case bristorbrot: case buffalo: case eiffieMsltoe: case fast_mandelbulb_power2: case hypercomplex: case iqBulb: case mandelbulb: case mandelbulb2: case mandelbulb3: case mandelbulb4: case mandelbulbBermarte: case mandelbulbKali: case mandelbulbKaliMulti: case mandelbulbMulti: case mandelbulbVaryPowerV1: case msltoesym2Mod: case msltoesym3Mod: case msltoesym3Mod2: case msltoesym3Mod3: case msltoesym4Mod: case msltoeToroidal: // TODO fix?? case msltoeToroidalMulti: // TODO fix?? case quaternion: case transfQuaternionFold: // hmmm, this issue again case quaternion3D: case xenodreambuie: { if (extendedAux.r_dz > 0) out->distance = 0.5 * r * log(r) / extendedAux.r_dz; else out->distance = r; break; } case mandelbox: case mandelboxMenger: case smoothMandelbox: case mandelboxVaryScale4D: case generalizedFoldBox: case foldBoxMod1: case aboxModKali: case aboxModKaliEiffie: case aboxMod1: case aboxMod2: case amazingSurf: case amazingSurfMod1: case amazingSurfMulti: case kalisets1: case aboxVSIcen1: { if (extendedAux.DE > 0) out->distance = r / fabs(extendedAux.DE); else out->distance = r; break; } case kaleidoscopicIFS: case menger_sponge: case crossMenger: case mengerPrismShape: case collatz: case collatzMod: case mengerMod1: case mengerMiddleMod: case transfMengerFold: // hmmm, this issue again case mengerPwr2Poly: { if (extendedAux.DE > 0) out->distance = (r - 2.0) / (extendedAux.DE); else out->distance = r; break; } default: out->distance = -1.0; break; } } } // color calculation else if (Mode == calcModeColouring) { double mboxDE = 1.0; mboxDE = extendedAux.DE; double r2 = r / fabs(mboxDE); if (r2 > 20) r2 = 20; if (fractals.IsHybrid()) { if (minimumR > 100) minimumR = 100; double mboxColor = 0.0; mboxColor = extendedAux.color; if (mboxColor > 1000) mboxColor = 1000; out->colorIndex = minimumR * 1000.0 + mboxColor * 100 + r2 * 5000.0; /*out->colorIndex = extendedAux.color * 100.0 * extendedAux.foldFactor // folds part + r * defaultFractal->mandelbox.color.factorR / 1e13 // abs z part + 1.0 * r2 * 5000.0 // for backwards compatability + extendedAux.scaleFactor * r * i / 1e15 // scale part conditional on i & r + ((in.fractalColoring.coloringAlgorithm != sFractalColoring::fractalColoringStandard) ? minimumR * extendedAux.minRFactor * 1000.0 : 0.0);*/ } else { switch (formula) { case mandelbox: case smoothMandelbox: case mandelboxVaryScale4D: case generalizedFoldBox: case amazingSurfMod1: case foldBoxMod1: out->colorIndex = extendedAux.color * 100.0 // folds part + r * defaultFractal->mandelbox.color.factorR / 1e13 // abs z part + ((in.fractalColoring.coloringAlgorithm != sFractalColoring::fractalColoringStandard) ? minimumR * 1000.0 : 0.0); break; case mengerMod1: case aboxModKali: case aboxMod1: case menger_sponge: case collatz: case collatzMod: case kaleidoscopicIFS: case mengerPwr2Poly: case mengerMiddleMod: out->colorIndex = minimumR * 1000.0; break; case amazingSurf: out->colorIndex = minimumR * 200.0; break; case amazingSurfMulti: case mandelboxMenger: // case amazingSurfMod1: out->colorIndex = extendedAux.color * 100.0 * extendedAux.foldFactor // folds part + r * defaultFractal->mandelbox.color.factorR / 1e13 // abs z part + extendedAux.scaleFactor * r2 * 5000.0 // for backwards compatability //+ extendedAux.scaleFactor * r * i / 1e15 // scale part conditional on i & r + ((in.fractalColoring.coloringAlgorithm != sFractalColoring::fractalColoringStandard) ? minimumR * extendedAux.minRFactor * 1000.0 : 0.0); break; case msltoeDonut: out->colorIndex = extendedAux.color * 2000.0 / i; break; default: out->colorIndex = minimumR * 5000.0; break; } } } else { out->distance = 0.0; } out->iters = i + 1; out->z = z; // CVector3( z.x, z.y, w); // tim = rdtsc() - tim; perf+= tim; perfCount++; outStream << (double)perf/perfCount - 560.0 << // endl; //------------- 3249 ns for all calculation ---------------- }