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All rights reserved. // This file was generated by NvParameterized/scripts/GenParameterized.pl #include "NoiseFSAssetParams.h" #include #include using namespace NvParameterized; namespace nvidia { namespace basicfs { using namespace NoiseFSAssetParamsNS; const char* const NoiseFSAssetParamsFactory::vptr = NvParameterized::getVptr(); const uint32_t NumParamDefs = 19; static NvParameterized::DefinitionImpl* ParamDefTable; // now allocated in buildTree [NumParamDefs]; static const size_t ParamLookupChildrenTable[] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, }; #define TENUM(type) nvidia::##type #define CHILDREN(index) &ParamLookupChildrenTable[index] static const NvParameterized::ParamLookupNode ParamLookupTable[NumParamDefs] = { { TYPE_STRUCT, false, 0, CHILDREN(0), 18 }, { TYPE_F32, false, (size_t)(&((ParametersStruct*)0)->defaultScale), NULL, 0 }, // defaultScale { TYPE_VEC3, false, (size_t)(&((ParametersStruct*)0)->boundarySize), NULL, 0 }, // boundarySize { TYPE_F32, false, (size_t)(&((ParametersStruct*)0)->boundaryFadePercentage), NULL, 0 }, // boundaryFadePercentage { TYPE_ENUM, false, (size_t)(&((ParametersStruct*)0)->fieldType), NULL, 0 }, // fieldType { TYPE_F32, false, (size_t)(&((ParametersStruct*)0)->fieldDragCoeff), NULL, 0 }, // fieldDragCoeff { TYPE_F32, false, (size_t)(&((ParametersStruct*)0)->fieldWeight), NULL, 0 }, // fieldWeight { TYPE_ENUM, false, (size_t)(&((ParametersStruct*)0)->noiseType), NULL, 0 }, // noiseType { TYPE_U32, false, (size_t)(&((ParametersStruct*)0)->noiseSeed), NULL, 0 }, // noiseSeed { TYPE_F32, false, (size_t)(&((ParametersStruct*)0)->noiseStrength), NULL, 0 }, // noiseStrength { TYPE_VEC3, false, (size_t)(&((ParametersStruct*)0)->noiseSpacePeriod), NULL, 0 }, // noiseSpacePeriod { TYPE_F32, false, (size_t)(&((ParametersStruct*)0)->noiseTimePeriod), NULL, 0 }, // noiseTimePeriod { TYPE_U32, false, (size_t)(&((ParametersStruct*)0)->noiseOctaves), NULL, 0 }, // noiseOctaves { TYPE_F32, false, (size_t)(&((ParametersStruct*)0)->noiseStrengthOctaveMultiplier), NULL, 0 }, // noiseStrengthOctaveMultiplier { TYPE_VEC3, false, (size_t)(&((ParametersStruct*)0)->noiseSpacePeriodOctaveMultiplier), NULL, 0 }, // noiseSpacePeriodOctaveMultiplier { TYPE_F32, false, (size_t)(&((ParametersStruct*)0)->noiseTimePeriodOctaveMultiplier), NULL, 0 }, // noiseTimePeriodOctaveMultiplier { TYPE_STRING, false, (size_t)(&((ParametersStruct*)0)->fieldBoundaryFilterDataName), NULL, 0 }, // fieldBoundaryFilterDataName { TYPE_STRING, false, (size_t)(&((ParametersStruct*)0)->fieldSamplerFilterDataName), NULL, 0 }, // fieldSamplerFilterDataName { TYPE_BOOL, false, (size_t)(&((ParametersStruct*)0)->useLocalSpace), NULL, 0 }, // useLocalSpace }; bool NoiseFSAssetParams::mBuiltFlag = false; NvParameterized::MutexType NoiseFSAssetParams::mBuiltFlagMutex; NoiseFSAssetParams::NoiseFSAssetParams(NvParameterized::Traits* traits, void* buf, int32_t* refCount) : NvParameters(traits, buf, refCount) { //mParameterizedTraits->registerFactory(className(), &NoiseFSAssetParamsFactoryInst); if (!buf) //Do not init data if it is inplace-deserialized { initDynamicArrays(); initStrings(); initReferences(); initDefaults(); } } NoiseFSAssetParams::~NoiseFSAssetParams() { freeStrings(); freeReferences(); freeDynamicArrays(); } void NoiseFSAssetParams::destroy() { // We cache these fields here to avoid overwrite in destructor bool doDeallocateSelf = mDoDeallocateSelf; NvParameterized::Traits* traits = mParameterizedTraits; int32_t* refCount = mRefCount; void* buf = mBuffer; this->~NoiseFSAssetParams(); NvParameters::destroy(this, traits, doDeallocateSelf, refCount, buf); } const NvParameterized::DefinitionImpl* NoiseFSAssetParams::getParameterDefinitionTree(void) { if (!mBuiltFlag) // Double-checked lock { NvParameterized::MutexType::ScopedLock lock(mBuiltFlagMutex); if (!mBuiltFlag) { buildTree(); } } return(&ParamDefTable[0]); } const NvParameterized::DefinitionImpl* NoiseFSAssetParams::getParameterDefinitionTree(void) const { NoiseFSAssetParams* tmpParam = const_cast(this); if (!mBuiltFlag) // Double-checked lock { NvParameterized::MutexType::ScopedLock lock(mBuiltFlagMutex); if (!mBuiltFlag) { tmpParam->buildTree(); } } return(&ParamDefTable[0]); } NvParameterized::ErrorType NoiseFSAssetParams::getParameterHandle(const char* long_name, Handle& handle) const { ErrorType Ret = NvParameters::getParameterHandle(long_name, handle); if (Ret != ERROR_NONE) { return(Ret); } size_t offset; void* ptr; getVarPtr(handle, ptr, offset); if (ptr == NULL) { return(ERROR_INDEX_OUT_OF_RANGE); } return(ERROR_NONE); } NvParameterized::ErrorType NoiseFSAssetParams::getParameterHandle(const char* long_name, Handle& handle) { ErrorType Ret = NvParameters::getParameterHandle(long_name, handle); if (Ret != ERROR_NONE) { return(Ret); } size_t offset; void* ptr; getVarPtr(handle, ptr, offset); if (ptr == NULL) { return(ERROR_INDEX_OUT_OF_RANGE); } return(ERROR_NONE); } void NoiseFSAssetParams::getVarPtr(const Handle& handle, void*& ptr, size_t& offset) const { ptr = getVarPtrHelper(&ParamLookupTable[0], const_cast(¶meters()), handle, offset); } /* Dynamic Handle Indices */ void NoiseFSAssetParams::freeParameterDefinitionTable(NvParameterized::Traits* traits) { if (!traits) { return; } if (!mBuiltFlag) // Double-checked lock { return; } NvParameterized::MutexType::ScopedLock lock(mBuiltFlagMutex); if (!mBuiltFlag) { return; } for (uint32_t i = 0; i < NumParamDefs; ++i) { ParamDefTable[i].~DefinitionImpl(); } traits->free(ParamDefTable); mBuiltFlag = false; } #define PDEF_PTR(index) (&ParamDefTable[index]) void NoiseFSAssetParams::buildTree(void) { uint32_t allocSize = sizeof(NvParameterized::DefinitionImpl) * NumParamDefs; ParamDefTable = (NvParameterized::DefinitionImpl*)(mParameterizedTraits->alloc(allocSize)); memset(ParamDefTable, 0, allocSize); for (uint32_t i = 0; i < NumParamDefs; ++i) { NV_PARAM_PLACEMENT_NEW(ParamDefTable + i, NvParameterized::DefinitionImpl)(*mParameterizedTraits); } // Initialize DefinitionImpl node: nodeIndex=0, longName="" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[0]; ParamDef->init("", TYPE_STRUCT, "STRUCT", true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Contains the asset properties for this Noise Field Sampler.", true); ParamDefTable[0].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=1, longName="defaultScale" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[1]; ParamDef->init("defaultScale", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("HIDDEN", uint64_t(1), true); ParamDefTable[1].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("HIDDEN", uint64_t(1), true); HintTable[1].init("longDescription", "The default scale factor of the boundary shape. The default value is 1.0.", true); HintTable[2].init("shortDescription", "The default scale factor of the boundary shape.", true); ParamDefTable[1].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=2, longName="boundarySize" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[2]; ParamDef->init("boundarySize", TYPE_VEC3, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Size of the boundary box.", true); ParamDefTable[2].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=3, longName="boundaryFadePercentage" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[3]; ParamDef->init("boundaryFadePercentage", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("max", uint64_t(1), true); HintTable[1].init("min", uint64_t(0), true); ParamDefTable[3].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("max", uint64_t(1), true); HintTable[1].init("min", uint64_t(0), true); HintTable[2].init("shortDescription", "Percentage of distance from boundary to center where fade out starts.", true); ParamDefTable[3].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=4, longName="fieldType" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[4]; ParamDef->init("fieldType", TYPE_ENUM, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Type of field.", true); ParamDefTable[4].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ static const char* const EnumVals[] = { "FORCE", "VELOCITY_DRAG", "VELOCITY_DIRECT" }; ParamDefTable[4].setEnumVals((const char**)EnumVals, 3); } // Initialize DefinitionImpl node: nodeIndex=5, longName="fieldDragCoeff" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[5]; ParamDef->init("fieldDragCoeff", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("min", uint64_t(0), true); ParamDefTable[5].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("min", uint64_t(0), true); HintTable[1].init("shortDescription", "Field drag coefficient (only for VELOCITY_DRAG field type).", true); ParamDefTable[5].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=6, longName="fieldWeight" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[6]; ParamDef->init("fieldWeight", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("max", uint64_t(1), true); HintTable[1].init("min", uint64_t(0), true); ParamDefTable[6].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("max", uint64_t(1), true); HintTable[1].init("min", uint64_t(0), true); HintTable[2].init("shortDescription", "A weight for the field, it controls how strongly the field affects particles", true); ParamDefTable[6].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=7, longName="noiseType" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[7]; ParamDef->init("noiseType", TYPE_ENUM, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Type of noise (simplex, curl and etc.).", true); ParamDefTable[7].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ static const char* const EnumVals[] = { "SIMPLEX", "CURL" }; ParamDefTable[7].setEnumVals((const char**)EnumVals, 2); } // Initialize DefinitionImpl node: nodeIndex=8, longName="noiseSeed" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[8]; ParamDef->init("noiseSeed", TYPE_U32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Seed for the noise random generator.", true); ParamDefTable[8].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=9, longName="noiseStrength" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[9]; ParamDef->init("noiseStrength", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Noise strength.", true); ParamDefTable[9].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=10, longName="noiseSpacePeriod" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[10]; ParamDef->init("noiseSpacePeriod", TYPE_VEC3, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Noise period in space.", true); ParamDefTable[10].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=11, longName="noiseTimePeriod" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[11]; ParamDef->init("noiseTimePeriod", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Noise period in time.", true); ParamDefTable[11].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=12, longName="noiseOctaves" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[12]; ParamDef->init("noiseOctaves", TYPE_U32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Number of the noise octaves (more octaves give more turbulent noise, but increase computational time).", true); ParamDefTable[12].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=13, longName="noiseStrengthOctaveMultiplier" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[13]; ParamDef->init("noiseStrengthOctaveMultiplier", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Noise strength multiplier from one octave to the next.", true); ParamDefTable[13].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=14, longName="noiseSpacePeriodOctaveMultiplier" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[14]; ParamDef->init("noiseSpacePeriodOctaveMultiplier", TYPE_VEC3, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Noise period in space multiplier from one octave to the next.", true); ParamDefTable[14].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=15, longName="noiseTimePeriodOctaveMultiplier" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[15]; ParamDef->init("noiseTimePeriodOctaveMultiplier", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Noise period in time multiplier from one octave to the next.", true); ParamDefTable[15].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=16, longName="fieldBoundaryFilterDataName" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[16]; ParamDef->init("fieldBoundaryFilterDataName", TYPE_STRING, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("HIDDEN", uint64_t(1), true); ParamDefTable[16].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("HIDDEN", uint64_t(1), true); HintTable[1].init("shortDescription", "The filter data name for NoiseFS vs Field Boundaries interaction.", true); ParamDefTable[16].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=17, longName="fieldSamplerFilterDataName" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[17]; ParamDef->init("fieldSamplerFilterDataName", TYPE_STRING, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "The filter data name for NoiseFS vs other Field Samplers interaction.", true); ParamDefTable[17].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=18, longName="useLocalSpace" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[18]; ParamDef->init("useLocalSpace", TYPE_BOOL, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "when enabled, noise calculation is done in the local space.", true); ParamDefTable[18].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // SetChildren for: nodeIndex=0, longName="" { static Definition* Children[18]; Children[0] = PDEF_PTR(1); Children[1] = PDEF_PTR(2); Children[2] = PDEF_PTR(3); Children[3] = PDEF_PTR(4); Children[4] = PDEF_PTR(5); Children[5] = PDEF_PTR(6); Children[6] = PDEF_PTR(7); Children[7] = PDEF_PTR(8); Children[8] = PDEF_PTR(9); Children[9] = PDEF_PTR(10); Children[10] = PDEF_PTR(11); Children[11] = PDEF_PTR(12); Children[12] = PDEF_PTR(13); Children[13] = PDEF_PTR(14); Children[14] = PDEF_PTR(15); Children[15] = PDEF_PTR(16); Children[16] = PDEF_PTR(17); Children[17] = PDEF_PTR(18); ParamDefTable[0].setChildren(Children, 18); } mBuiltFlag = true; } void NoiseFSAssetParams::initStrings(void) { fieldBoundaryFilterDataName.isAllocated = true; fieldBoundaryFilterDataName.buf = NULL; fieldSamplerFilterDataName.isAllocated = true; fieldSamplerFilterDataName.buf = NULL; } void NoiseFSAssetParams::initDynamicArrays(void) { } void NoiseFSAssetParams::initDefaults(void) { freeStrings(); freeReferences(); freeDynamicArrays(); defaultScale = float(1); boundarySize = physx::PxVec3(init(10, 10, 10)); boundaryFadePercentage = float(0.1); fieldType = (const char*)"VELOCITY_DIRECT"; fieldDragCoeff = float(1); fieldWeight = float(1); noiseType = (const char*)"CURL"; noiseSeed = uint32_t(0); noiseStrength = float(1); noiseSpacePeriod = physx::PxVec3(init(1.0, 1.0, 1.0)); noiseTimePeriod = float(1); noiseOctaves = uint32_t(1); noiseStrengthOctaveMultiplier = float(0.5); noiseSpacePeriodOctaveMultiplier = physx::PxVec3(init(0.5, 0.5, 0.5)); noiseTimePeriodOctaveMultiplier = float(0.5); useLocalSpace = bool(false); initDynamicArrays(); initStrings(); initReferences(); } void NoiseFSAssetParams::initReferences(void) { } void NoiseFSAssetParams::freeDynamicArrays(void) { } void NoiseFSAssetParams::freeStrings(void) { if (fieldBoundaryFilterDataName.isAllocated && fieldBoundaryFilterDataName.buf) { mParameterizedTraits->strfree((char*)fieldBoundaryFilterDataName.buf); } if (fieldSamplerFilterDataName.isAllocated && fieldSamplerFilterDataName.buf) { mParameterizedTraits->strfree((char*)fieldSamplerFilterDataName.buf); } } void NoiseFSAssetParams::freeReferences(void) { } } // namespace basicfs } // namespace nvidia