// // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions // are met: // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in the // documentation and/or other materials provided with the distribution. // * Neither the name of NVIDIA CORPORATION nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ``AS IS'' AND ANY // EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR // PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR // CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, // PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR // PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY // OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // // Copyright (c) 2018 NVIDIA Corporation. All rights reserved. // This file was generated by NvParameterized/scripts/GenParameterized.pl #include "ApexEmitterAssetParameters_0p2.h" #include #include using namespace NvParameterized; namespace nvidia { namespace parameterized { using namespace ApexEmitterAssetParameters_0p2NS; const char* const ApexEmitterAssetParameters_0p2Factory::vptr = NvParameterized::getVptr(); const uint32_t NumParamDefs = 26; static NvParameterized::DefinitionImpl* ParamDefTable; // now allocated in buildTree [NumParamDefs]; static const size_t ParamLookupChildrenTable[] = { 1, 4, 7, 10, 13, 14, 22, 23, 24, 25, 2, 3, 5, 6, 8, 9, 11, 12, 15, 16, 17, 18, 19, 20, 21, }; #define TENUM(type) nvidia::##type #define CHILDREN(index) &ParamLookupChildrenTable[index] static const NvParameterized::ParamLookupNode ParamLookupTable[NumParamDefs] = { { TYPE_STRUCT, false, 0, CHILDREN(0), 10 }, { TYPE_STRUCT, false, (size_t)(&((ParametersStruct*)0)->densityRange), CHILDREN(10), 2 }, // densityRange { TYPE_F32, false, (size_t)(&((rangeStructF32_Type*)0)->min), NULL, 0 }, // densityRange.min { TYPE_F32, false, (size_t)(&((rangeStructF32_Type*)0)->max), NULL, 0 }, // densityRange.max { TYPE_STRUCT, false, (size_t)(&((ParametersStruct*)0)->rateRange), CHILDREN(12), 2 }, // rateRange { TYPE_F32, false, (size_t)(&((rangeStructF32_Type*)0)->min), NULL, 0 }, // rateRange.min { TYPE_F32, false, (size_t)(&((rangeStructF32_Type*)0)->max), NULL, 0 }, // rateRange.max { TYPE_STRUCT, false, (size_t)(&((ParametersStruct*)0)->lifetimeRange), CHILDREN(14), 2 }, // lifetimeRange { TYPE_F32, false, (size_t)(&((rangeStructF32_Type*)0)->min), NULL, 0 }, // lifetimeRange.min { TYPE_F32, false, (size_t)(&((rangeStructF32_Type*)0)->max), NULL, 0 }, // lifetimeRange.max { TYPE_STRUCT, false, (size_t)(&((ParametersStruct*)0)->velocityRange), CHILDREN(16), 2 }, // velocityRange { TYPE_VEC3, false, (size_t)(&((rangeStructVec3_Type*)0)->min), NULL, 0 }, // velocityRange.min { TYPE_VEC3, false, (size_t)(&((rangeStructVec3_Type*)0)->max), NULL, 0 }, // velocityRange.max { TYPE_U32, false, (size_t)(&((ParametersStruct*)0)->maxSamples), NULL, 0 }, // maxSamples { TYPE_STRUCT, false, (size_t)(&((ParametersStruct*)0)->lodParamDesc), CHILDREN(18), 7 }, // lodParamDesc { TYPE_U32, false, (size_t)(&((emitterLodParamDesc_Type*)0)->version), NULL, 0 }, // lodParamDesc.version { TYPE_F32, false, (size_t)(&((emitterLodParamDesc_Type*)0)->maxDistance), NULL, 0 }, // lodParamDesc.maxDistance { TYPE_F32, false, (size_t)(&((emitterLodParamDesc_Type*)0)->distanceWeight), NULL, 0 }, // lodParamDesc.distanceWeight { TYPE_F32, false, (size_t)(&((emitterLodParamDesc_Type*)0)->speedWeight), NULL, 0 }, // lodParamDesc.speedWeight { TYPE_F32, false, (size_t)(&((emitterLodParamDesc_Type*)0)->lifeWeight), NULL, 0 }, // lodParamDesc.lifeWeight { TYPE_F32, false, (size_t)(&((emitterLodParamDesc_Type*)0)->separationWeight), NULL, 0 }, // lodParamDesc.separationWeight { TYPE_F32, false, (size_t)(&((emitterLodParamDesc_Type*)0)->bias), NULL, 0 }, // lodParamDesc.bias { TYPE_REF, false, (size_t)(&((ParametersStruct*)0)->iofxAssetName), NULL, 0 }, // iofxAssetName { TYPE_REF, false, (size_t)(&((ParametersStruct*)0)->iosAssetName), NULL, 0 }, // iosAssetName { TYPE_REF, false, (size_t)(&((ParametersStruct*)0)->geometryType), NULL, 0 }, // geometryType { TYPE_F32, false, (size_t)(&((ParametersStruct*)0)->emitterDuration), NULL, 0 }, // emitterDuration }; bool ApexEmitterAssetParameters_0p2::mBuiltFlag = false; NvParameterized::MutexType ApexEmitterAssetParameters_0p2::mBuiltFlagMutex; ApexEmitterAssetParameters_0p2::ApexEmitterAssetParameters_0p2(NvParameterized::Traits* traits, void* buf, int32_t* refCount) : NvParameters(traits, buf, refCount) { //mParameterizedTraits->registerFactory(className(), &ApexEmitterAssetParameters_0p2FactoryInst); if (!buf) //Do not init data if it is inplace-deserialized { initDynamicArrays(); initStrings(); initReferences(); initDefaults(); } } ApexEmitterAssetParameters_0p2::~ApexEmitterAssetParameters_0p2() { freeStrings(); freeReferences(); freeDynamicArrays(); } void ApexEmitterAssetParameters_0p2::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->~ApexEmitterAssetParameters_0p2(); NvParameters::destroy(this, traits, doDeallocateSelf, refCount, buf); } const NvParameterized::DefinitionImpl* ApexEmitterAssetParameters_0p2::getParameterDefinitionTree(void) { if (!mBuiltFlag) // Double-checked lock { NvParameterized::MutexType::ScopedLock lock(mBuiltFlagMutex); if (!mBuiltFlag) { buildTree(); } } return(&ParamDefTable[0]); } const NvParameterized::DefinitionImpl* ApexEmitterAssetParameters_0p2::getParameterDefinitionTree(void) const { ApexEmitterAssetParameters_0p2* tmpParam = const_cast(this); if (!mBuiltFlag) // Double-checked lock { NvParameterized::MutexType::ScopedLock lock(mBuiltFlagMutex); if (!mBuiltFlag) { tmpParam->buildTree(); } } return(&ParamDefTable[0]); } NvParameterized::ErrorType ApexEmitterAssetParameters_0p2::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 ApexEmitterAssetParameters_0p2::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 ApexEmitterAssetParameters_0p2::getVarPtr(const Handle& handle, void*& ptr, size_t& offset) const { ptr = getVarPtrHelper(&ParamLookupTable[0], const_cast(¶meters()), handle, offset); } /* Dynamic Handle Indices */ void ApexEmitterAssetParameters_0p2::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 ApexEmitterAssetParameters_0p2::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[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("longDescription", "This class contains the parameters for the APEX Emitter asset. The APEX Emitter is sometimes described\nas a shaped APEX Emitter because it contains the box, sphere, and sphere shell shapes. It also\nincludes an explicit shape that allows for preauthored particles positions and velocities and runtime\nparticle injections.\n", true); HintTable[1].init("shortDescription", "APEX Emitter Asset Parameters", true); ParamDefTable[0].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=1, longName="densityRange" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[1]; ParamDef->init("densityRange", TYPE_STRUCT, "rangeStructF32", true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("tweakable", "true", 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("longDescription", "For an explicit emitter, the density is actually a spawn probability. For the shaped emitters, it represents the density of the particles per unit volume.\n", true); HintTable[1].init("shortDescription", "Desired density of spawned particles per unit of volume.", true); HintTable[2].init("tweakable", "true", true); ParamDefTable[1].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=2, longName="densityRange.min" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[2]; ParamDef->init("min", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Minimum (scalar value)", true); ParamDefTable[2].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=3, longName="densityRange.max" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[3]; ParamDef->init("max", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Maximum (scalar value)", true); ParamDefTable[3].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=4, longName="rateRange" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[4]; ParamDef->init("rateRange", TYPE_STRUCT, "rangeStructF32", true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("tweakable", "true", true); ParamDefTable[4].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("longDescription", "The emitter actor will use the maximum rate in the range if it is a rate-based shape, but it will back off to the minimum density if the actor is LOD resource limited.\n", true); HintTable[1].init("shortDescription", "min if LOD limited / max if rate-based shape", true); HintTable[2].init("tweakable", "true", true); ParamDefTable[4].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=5, longName="rateRange.min" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[5]; ParamDef->init("min", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Minimum (scalar value)", true); ParamDefTable[5].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=6, longName="rateRange.max" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[6]; ParamDef->init("max", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Maximum (scalar value)", true); ParamDefTable[6].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=7, longName="lifetimeRange" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[7]; ParamDef->init("lifetimeRange", TYPE_STRUCT, "rangeStructF32", true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("tweakable", "true", true); ParamDefTable[7].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("longDescription", "The emitter actor will create particles with a random lifetime (in seconds) within the lifetime range.\n", true); HintTable[1].init("shortDescription", "Range (in sec) of particle lifetime", true); HintTable[2].init("tweakable", "true", true); ParamDefTable[7].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=8, longName="lifetimeRange.min" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[8]; ParamDef->init("min", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Minimum (scalar value)", true); ParamDefTable[8].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=9, longName="lifetimeRange.max" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[9]; ParamDef->init("max", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Maximum (scalar value)", true); ParamDefTable[9].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=10, longName="velocityRange" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[10]; ParamDef->init("velocityRange", TYPE_STRUCT, "rangeStructVec3", true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("gameScale", "true", true); HintTable[1].init("tweakable", "true", true); ParamDefTable[10].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #else static HintImpl HintTable[4]; static Hint* HintPtrTable[4] = { &HintTable[0], &HintTable[1], &HintTable[2], &HintTable[3], }; HintTable[0].init("gameScale", "true", true); HintTable[1].init("longDescription", "The emitter actor will create particles with a random velocity within the velocity range.\n", true); HintTable[2].init("shortDescription", "Random velocity given within range", true); HintTable[3].init("tweakable", "true", true); ParamDefTable[10].setHints((const NvParameterized::Hint**)HintPtrTable, 4); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=11, longName="velocityRange.min" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[11]; ParamDef->init("min", TYPE_VEC3, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Minimum (vector value)", true); ParamDefTable[11].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=12, longName="velocityRange.max" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[12]; ParamDef->init("max", TYPE_VEC3, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "Maximum (vector value)", true); ParamDefTable[12].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=13, longName="maxSamples" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[13]; ParamDef->init("maxSamples", TYPE_U32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("min", uint64_t(0), true); ParamDefTable[13].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #else static HintImpl HintTable[4]; static Hint* HintPtrTable[4] = { &HintTable[0], &HintTable[1], &HintTable[2], &HintTable[3], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("longDescription", "For an explicit emitter, Max Samples is ignored. For shaped emitters, it is the maximum number of particles spawned in a step.\n", true); HintTable[2].init("min", uint64_t(0), true); HintTable[3].init("shortDescription", "Shaped emitter only. Max particles spawned each step.", true); ParamDefTable[13].setHints((const NvParameterized::Hint**)HintPtrTable, 4); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=14, longName="lodParamDesc" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[14]; ParamDef->init("lodParamDesc", TYPE_STRUCT, "emitterLodParamDesc", true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("tweakable", "true", true); ParamDefTable[14].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("shortDescription", "Bias given to this emitter when sharing IOS with another emitter", true); HintTable[1].init("tweakable", "true", true); ParamDefTable[14].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=15, longName="lodParamDesc.version" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[15]; ParamDef->init("version", TYPE_U32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("defaultValue", uint64_t(0), true); ParamDefTable[15].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("shortDescription", "Version", true); ParamDefTable[15].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=16, longName="lodParamDesc.maxDistance" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[16]; ParamDef->init("maxDistance", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("min", uint64_t(0), true); ParamDefTable[16].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("min", uint64_t(0), true); HintTable[2].init("shortDescription", "Objects greater than this distance from the player will be culled more aggressively", true); ParamDefTable[16].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=17, longName="lodParamDesc.distanceWeight" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[17]; ParamDef->init("distanceWeight", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("defaultValue", uint64_t(1), true); HintTable[1].init("max", uint64_t(1), true); HintTable[2].init("min", uint64_t(0), true); ParamDefTable[17].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #else static HintImpl HintTable[4]; static Hint* HintPtrTable[4] = { &HintTable[0], &HintTable[1], &HintTable[2], &HintTable[3], }; HintTable[0].init("defaultValue", uint64_t(1), true); HintTable[1].init("max", uint64_t(1), true); HintTable[2].init("min", uint64_t(0), true); HintTable[3].init("shortDescription", "Weight given to distance parameter in LOD function", true); ParamDefTable[17].setHints((const NvParameterized::Hint**)HintPtrTable, 4); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=18, longName="lodParamDesc.speedWeight" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[18]; ParamDef->init("speedWeight", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("max", uint64_t(1), true); HintTable[2].init("min", uint64_t(0), true); ParamDefTable[18].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #else static HintImpl HintTable[4]; static Hint* HintPtrTable[4] = { &HintTable[0], &HintTable[1], &HintTable[2], &HintTable[3], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("max", uint64_t(1), true); HintTable[2].init("min", uint64_t(0), true); HintTable[3].init("shortDescription", "Weight given to velocity parameter in LOD function", true); ParamDefTable[18].setHints((const NvParameterized::Hint**)HintPtrTable, 4); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=19, longName="lodParamDesc.lifeWeight" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[19]; ParamDef->init("lifeWeight", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("max", uint64_t(1), true); HintTable[2].init("min", uint64_t(0), true); ParamDefTable[19].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #else static HintImpl HintTable[4]; static Hint* HintPtrTable[4] = { &HintTable[0], &HintTable[1], &HintTable[2], &HintTable[3], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("max", uint64_t(1), true); HintTable[2].init("min", uint64_t(0), true); HintTable[3].init("shortDescription", "Weight given to life remain parameter in LOD function", true); ParamDefTable[19].setHints((const NvParameterized::Hint**)HintPtrTable, 4); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=20, longName="lodParamDesc.separationWeight" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[20]; ParamDef->init("separationWeight", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("max", uint64_t(1), true); HintTable[2].init("min", uint64_t(0), true); ParamDefTable[20].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #else static HintImpl HintTable[4]; static Hint* HintPtrTable[4] = { &HintTable[0], &HintTable[1], &HintTable[2], &HintTable[3], }; HintTable[0].init("defaultValue", uint64_t(0), true); HintTable[1].init("max", uint64_t(1), true); HintTable[2].init("min", uint64_t(0), true); HintTable[3].init("shortDescription", "Weight given to separation parameter in LOD function", true); ParamDefTable[20].setHints((const NvParameterized::Hint**)HintPtrTable, 4); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=21, longName="lodParamDesc.bias" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[21]; ParamDef->init("bias", TYPE_F32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("defaultValue", uint64_t(1), true); HintTable[1].init("min", uint64_t(0), true); ParamDefTable[21].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("defaultValue", uint64_t(1), true); HintTable[1].init("min", uint64_t(0), true); HintTable[2].init("shortDescription", "Bias given to objects spawned by this emitter, relative to other emitters in the same IOS", true); ParamDefTable[21].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=22, longName="iofxAssetName" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[22]; ParamDef->init("iofxAssetName", TYPE_REF, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "The name of the instanced object effects asset that will render particles", true); ParamDefTable[22].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ static const char* const RefVariantVals[] = { "IOFX" }; ParamDefTable[22].setRefVariantVals((const char**)RefVariantVals, 1); } // Initialize DefinitionImpl node: nodeIndex=23, longName="iosAssetName" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[23]; ParamDef->init("iosAssetName", TYPE_REF, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("shortDescription", "The asset name of the IOS and the type of IOS that will simulate particles", true); ParamDefTable[23].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ static const char* const RefVariantVals[] = { "NxFluidIosAsset", "NxBasicIosAsset", "ParticleIosAsset" }; ParamDefTable[23].setRefVariantVals((const char**)RefVariantVals, 3); } // Initialize DefinitionImpl node: nodeIndex=24, longName="geometryType" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[24]; ParamDef->init("geometryType", TYPE_REF, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("INCLUDED", uint64_t(1), true); ParamDefTable[24].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("INCLUDED", uint64_t(1), true); HintTable[1].init("longDescription", "Specifies the geometry type of the emitter", true); HintTable[2].init("shortDescription", "Geometry Type", true); ParamDefTable[24].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ static const char* const RefVariantVals[] = { "EmitterGeomBoxParams", "EmitterGeomSphereParams", "EmitterGeomSphereShellParams", "EmitterGeomCylinderParams", "EmitterGeomExplicitParams" }; ParamDefTable[24].setRefVariantVals((const char**)RefVariantVals, 5); } // Initialize DefinitionImpl node: nodeIndex=25, longName="emitterDuration" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[25]; ParamDef->init("emitterDuration", 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[25].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("longDescription", "Specifies a duration (in seconds) that the emitter will emit for after being enabled.\nAfter the specified duration, the emitter will turn off, unless it has already been explicitly turned off via an API call.\nThe special value 0.0f means there is no duration, and the emitter will remain on until explicitly turned off.", true); HintTable[1].init("min", uint64_t(0), true); HintTable[2].init("shortDescription", "Emitter duration time (in seconds)", true); ParamDefTable[25].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // SetChildren for: nodeIndex=0, longName="" { static Definition* Children[10]; Children[0] = PDEF_PTR(1); Children[1] = PDEF_PTR(4); Children[2] = PDEF_PTR(7); Children[3] = PDEF_PTR(10); Children[4] = PDEF_PTR(13); Children[5] = PDEF_PTR(14); Children[6] = PDEF_PTR(22); Children[7] = PDEF_PTR(23); Children[8] = PDEF_PTR(24); Children[9] = PDEF_PTR(25); ParamDefTable[0].setChildren(Children, 10); } // SetChildren for: nodeIndex=1, longName="densityRange" { static Definition* Children[2]; Children[0] = PDEF_PTR(2); Children[1] = PDEF_PTR(3); ParamDefTable[1].setChildren(Children, 2); } // SetChildren for: nodeIndex=4, longName="rateRange" { static Definition* Children[2]; Children[0] = PDEF_PTR(5); Children[1] = PDEF_PTR(6); ParamDefTable[4].setChildren(Children, 2); } // SetChildren for: nodeIndex=7, longName="lifetimeRange" { static Definition* Children[2]; Children[0] = PDEF_PTR(8); Children[1] = PDEF_PTR(9); ParamDefTable[7].setChildren(Children, 2); } // SetChildren for: nodeIndex=10, longName="velocityRange" { static Definition* Children[2]; Children[0] = PDEF_PTR(11); Children[1] = PDEF_PTR(12); ParamDefTable[10].setChildren(Children, 2); } // SetChildren for: nodeIndex=14, longName="lodParamDesc" { static Definition* Children[7]; Children[0] = PDEF_PTR(15); Children[1] = PDEF_PTR(16); Children[2] = PDEF_PTR(17); Children[3] = PDEF_PTR(18); Children[4] = PDEF_PTR(19); Children[5] = PDEF_PTR(20); Children[6] = PDEF_PTR(21); ParamDefTable[14].setChildren(Children, 7); } mBuiltFlag = true; } void ApexEmitterAssetParameters_0p2::initStrings(void) { } void ApexEmitterAssetParameters_0p2::initDynamicArrays(void) { } void ApexEmitterAssetParameters_0p2::initDefaults(void) { freeStrings(); freeReferences(); freeDynamicArrays(); densityRange.min = 1.0f; densityRange.max = 1.0f; rateRange.min = 1.0f; rateRange.max = 1.0f; lifetimeRange.min = 1.0f; lifetimeRange.max = 1.0f; velocityRange.min.x = 0.0f; velocityRange.max.y = 0.0f; velocityRange.min.y = 0.0f; velocityRange.max.z = 0.0f; velocityRange.min.z = 0.0f; velocityRange.max.x = 0.0f; maxSamples = uint32_t(0); lodParamDesc.version = uint32_t(0); lodParamDesc.maxDistance = float(0); lodParamDesc.distanceWeight = float(1); lodParamDesc.speedWeight = float(0); lodParamDesc.lifeWeight = float(0); lodParamDesc.separationWeight = float(0); lodParamDesc.bias = float(1); emitterDuration = float(PX_MAX_F32); initDynamicArrays(); initStrings(); initReferences(); } void ApexEmitterAssetParameters_0p2::initReferences(void) { iofxAssetName = NULL; iosAssetName = NULL; geometryType = NULL; } void ApexEmitterAssetParameters_0p2::freeDynamicArrays(void) { } void ApexEmitterAssetParameters_0p2::freeStrings(void) { } void ApexEmitterAssetParameters_0p2::freeReferences(void) { if (iofxAssetName) { iofxAssetName->destroy(); } if (iosAssetName) { iosAssetName->destroy(); } if (geometryType) { geometryType->destroy(); } } } // namespace parameterized } // namespace nvidia