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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 "SubmeshParameters_0p1.h" #include #include using namespace NvParameterized; namespace nvidia { namespace parameterized { using namespace SubmeshParameters_0p1NS; const char* const SubmeshParameters_0p1Factory::vptr = NvParameterized::getVptr(); const uint32_t NumParamDefs = 10; static NvParameterized::DefinitionImpl* ParamDefTable; // now allocated in buildTree [NumParamDefs]; static const size_t ParamLookupChildrenTable[] = { 1, 2, 4, 6, 8, 3, 5, 7, 9, }; #define TENUM(type) nvidia::##type #define CHILDREN(index) &ParamLookupChildrenTable[index] static const NvParameterized::ParamLookupNode ParamLookupTable[NumParamDefs] = { { TYPE_STRUCT, false, 0, CHILDREN(0), 5 }, { TYPE_REF, false, (size_t)(&((ParametersStruct*)0)->vertexBuffer), NULL, 0 }, // vertexBuffer { TYPE_ARRAY, true, (size_t)(&((ParametersStruct*)0)->indexBuffer), CHILDREN(5), 1 }, // indexBuffer { TYPE_U32, false, 1 * sizeof(uint32_t), NULL, 0 }, // indexBuffer[] { TYPE_ARRAY, true, (size_t)(&((ParametersStruct*)0)->vertexPartition), CHILDREN(6), 1 }, // vertexPartition { TYPE_U32, false, 1 * sizeof(uint32_t), NULL, 0 }, // vertexPartition[] { TYPE_ARRAY, true, (size_t)(&((ParametersStruct*)0)->indexPartition), CHILDREN(7), 1 }, // indexPartition { TYPE_U32, false, 1 * sizeof(uint32_t), NULL, 0 }, // indexPartition[] { TYPE_ARRAY, true, (size_t)(&((ParametersStruct*)0)->smoothingGroups), CHILDREN(8), 1 }, // smoothingGroups { TYPE_U32, false, 1 * sizeof(uint32_t), NULL, 0 }, // smoothingGroups[] }; bool SubmeshParameters_0p1::mBuiltFlag = false; NvParameterized::MutexType SubmeshParameters_0p1::mBuiltFlagMutex; SubmeshParameters_0p1::SubmeshParameters_0p1(NvParameterized::Traits* traits, void* buf, int32_t* refCount) : NvParameters(traits, buf, refCount) { //mParameterizedTraits->registerFactory(className(), &SubmeshParameters_0p1FactoryInst); if (!buf) //Do not init data if it is inplace-deserialized { initDynamicArrays(); initStrings(); initReferences(); initDefaults(); } } SubmeshParameters_0p1::~SubmeshParameters_0p1() { freeStrings(); freeReferences(); freeDynamicArrays(); } void SubmeshParameters_0p1::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->~SubmeshParameters_0p1(); NvParameters::destroy(this, traits, doDeallocateSelf, refCount, buf); } const NvParameterized::DefinitionImpl* SubmeshParameters_0p1::getParameterDefinitionTree(void) { if (!mBuiltFlag) // Double-checked lock { NvParameterized::MutexType::ScopedLock lock(mBuiltFlagMutex); if (!mBuiltFlag) { buildTree(); } } return(&ParamDefTable[0]); } const NvParameterized::DefinitionImpl* SubmeshParameters_0p1::getParameterDefinitionTree(void) const { SubmeshParameters_0p1* tmpParam = const_cast(this); if (!mBuiltFlag) // Double-checked lock { NvParameterized::MutexType::ScopedLock lock(mBuiltFlagMutex); if (!mBuiltFlag) { tmpParam->buildTree(); } } return(&ParamDefTable[0]); } NvParameterized::ErrorType SubmeshParameters_0p1::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 SubmeshParameters_0p1::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 SubmeshParameters_0p1::getVarPtr(const Handle& handle, void*& ptr, size_t& offset) const { ptr = getVarPtrHelper(&ParamLookupTable[0], const_cast(¶meters()), handle, offset); } /* Dynamic Handle Indices */ void SubmeshParameters_0p1::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 SubmeshParameters_0p1::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); } // Initialize DefinitionImpl node: nodeIndex=1, longName="vertexBuffer" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[1]; ParamDef->init("vertexBuffer", 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[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("INCLUDED", uint64_t(1), true); HintTable[1].init("longDescription", "This is the vertex buffer included with this submesh. The submesh is defined\nby a vertex buffer and an index buffer (see indexBuffer). The vertices for\ndifferent mesh parts are stored in contiguous subsets of the whole vertex buffer.\nThe vertexPartition array holds the offsets into the vertexBuffer for each part.\n", true); HintTable[2].init("shortDescription", "The vertex buffer for this submesh", true); ParamDefTable[1].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ static const char* const RefVariantVals[] = { "VertexBufferParameters" }; ParamDefTable[1].setRefVariantVals((const char**)RefVariantVals, 1); } // Initialize DefinitionImpl node: nodeIndex=2, longName="indexBuffer" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[2]; ParamDef->init("indexBuffer", TYPE_ARRAY, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("NOPVD", uint64_t(1), true); ParamDefTable[2].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("NOPVD", uint64_t(1), true); HintTable[1].init("longDescription", "This is the vertex buffer included with this submesh. The submesh is defined\nby a index buffer and an vertex buffer (see vertexBuffer). The indices for\ndifferent mesh parts are stored in contiguous subsets of the whole index buffer.\nThe indexPartition array holds the offsets into the indexBuffer for each part.\n", true); HintTable[2].init("shortDescription", "The index buffer for this submesh", true); ParamDefTable[2].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ ParamDef->setArraySize(-1); } // Initialize DefinitionImpl node: nodeIndex=3, longName="indexBuffer[]" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[3]; ParamDef->init("indexBuffer", TYPE_U32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS static HintImpl HintTable[1]; static Hint* HintPtrTable[1] = { &HintTable[0], }; HintTable[0].init("NOPVD", uint64_t(1), true); ParamDefTable[3].setHints((const NvParameterized::Hint**)HintPtrTable, 1); #else static HintImpl HintTable[3]; static Hint* HintPtrTable[3] = { &HintTable[0], &HintTable[1], &HintTable[2], }; HintTable[0].init("NOPVD", uint64_t(1), true); HintTable[1].init("longDescription", "This is the vertex buffer included with this submesh. The submesh is defined\nby a index buffer and an vertex buffer (see vertexBuffer). The indices for\ndifferent mesh parts are stored in contiguous subsets of the whole index buffer.\nThe indexPartition array holds the offsets into the indexBuffer for each part.\n", true); HintTable[2].init("shortDescription", "The index buffer for this submesh", true); ParamDefTable[3].setHints((const NvParameterized::Hint**)HintPtrTable, 3); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=4, longName="vertexPartition" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[4]; ParamDef->init("vertexPartition", TYPE_ARRAY, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("longDescription", "Index offset into vertexBuffer for each part. The first vertex index for part\ni is vertexPartition[i]. The vertexPartition array size is N+1, where N = the\nnumber of mesh parts, and vertexPartition[N] = vertexBuffer.vertexCount (the\nsize of the vertex buffer). This way, the number of vertices for part i can be\nalways be obtained with vertexPartition[i+1]-vertexPartition[i].\n", true); HintTable[1].init("shortDescription", "Part lookup into vertexBuffer", true); ParamDefTable[4].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ ParamDef->setArraySize(-1); } // Initialize DefinitionImpl node: nodeIndex=5, longName="vertexPartition[]" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[5]; ParamDef->init("vertexPartition", TYPE_U32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("longDescription", "Index offset into vertexBuffer for each part. The first vertex index for part\ni is vertexPartition[i]. The vertexPartition array size is N+1, where N = the\nnumber of mesh parts, and vertexPartition[N] = vertexBuffer.vertexCount (the\nsize of the vertex buffer). This way, the number of vertices for part i can be\nalways be obtained with vertexPartition[i+1]-vertexPartition[i].\n", true); HintTable[1].init("shortDescription", "Part lookup into vertexBuffer", true); ParamDefTable[5].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=6, longName="indexPartition" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[6]; ParamDef->init("indexPartition", TYPE_ARRAY, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("longDescription", "Index offset into indexBuffer for each part. The first index location in\nindexPartition for part i is indexPartition[i]. The indexPartition array\nsize is N+1, where N = the number of mesh parts, and indexPartition[N] =\nthe size of the indexBuffer. This way, the number of indices for part i\ncan be always be obtained with indexPartition[i+1]-indexPartition[i].\n", true); HintTable[1].init("shortDescription", "Part lookup into indexBuffer", true); ParamDefTable[6].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ ParamDef->setArraySize(-1); } // Initialize DefinitionImpl node: nodeIndex=7, longName="indexPartition[]" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[7]; ParamDef->init("indexPartition", TYPE_U32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("longDescription", "Index offset into indexBuffer for each part. The first index location in\nindexPartition for part i is indexPartition[i]. The indexPartition array\nsize is N+1, where N = the number of mesh parts, and indexPartition[N] =\nthe size of the indexBuffer. This way, the number of indices for part i\ncan be always be obtained with indexPartition[i+1]-indexPartition[i].\n", true); HintTable[1].init("shortDescription", "Part lookup into indexBuffer", true); ParamDefTable[7].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // Initialize DefinitionImpl node: nodeIndex=8, longName="smoothingGroups" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[8]; ParamDef->init("smoothingGroups", TYPE_ARRAY, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("longDescription", "Per-triangle smoothing group masks", true); HintTable[1].init("shortDescription", "Per-triangle smoothing group masks", true); ParamDefTable[8].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ ParamDef->setArraySize(-1); } // Initialize DefinitionImpl node: nodeIndex=9, longName="smoothingGroups[]" { NvParameterized::DefinitionImpl* ParamDef = &ParamDefTable[9]; ParamDef->init("smoothingGroups", TYPE_U32, NULL, true); #ifdef NV_PARAMETERIZED_HIDE_DESCRIPTIONS #else static HintImpl HintTable[2]; static Hint* HintPtrTable[2] = { &HintTable[0], &HintTable[1], }; HintTable[0].init("longDescription", "Per-triangle smoothing group masks", true); HintTable[1].init("shortDescription", "Per-triangle smoothing group masks", true); ParamDefTable[9].setHints((const NvParameterized::Hint**)HintPtrTable, 2); #endif /* NV_PARAMETERIZED_HIDE_DESCRIPTIONS */ } // SetChildren for: nodeIndex=0, longName="" { static Definition* Children[5]; Children[0] = PDEF_PTR(1); Children[1] = PDEF_PTR(2); Children[2] = PDEF_PTR(4); Children[3] = PDEF_PTR(6); Children[4] = PDEF_PTR(8); ParamDefTable[0].setChildren(Children, 5); } // SetChildren for: nodeIndex=2, longName="indexBuffer" { static Definition* Children[1]; Children[0] = PDEF_PTR(3); ParamDefTable[2].setChildren(Children, 1); } // SetChildren for: nodeIndex=4, longName="vertexPartition" { static Definition* Children[1]; Children[0] = PDEF_PTR(5); ParamDefTable[4].setChildren(Children, 1); } // SetChildren for: nodeIndex=6, longName="indexPartition" { static Definition* Children[1]; Children[0] = PDEF_PTR(7); ParamDefTable[6].setChildren(Children, 1); } // SetChildren for: nodeIndex=8, longName="smoothingGroups" { static Definition* Children[1]; Children[0] = PDEF_PTR(9); ParamDefTable[8].setChildren(Children, 1); } mBuiltFlag = true; } void SubmeshParameters_0p1::initStrings(void) { } void SubmeshParameters_0p1::initDynamicArrays(void) { indexBuffer.buf = NULL; indexBuffer.isAllocated = true; indexBuffer.elementSize = sizeof(uint32_t); indexBuffer.arraySizes[0] = 0; vertexPartition.buf = NULL; vertexPartition.isAllocated = true; vertexPartition.elementSize = sizeof(uint32_t); vertexPartition.arraySizes[0] = 0; indexPartition.buf = NULL; indexPartition.isAllocated = true; indexPartition.elementSize = sizeof(uint32_t); indexPartition.arraySizes[0] = 0; smoothingGroups.buf = NULL; smoothingGroups.isAllocated = true; smoothingGroups.elementSize = sizeof(uint32_t); smoothingGroups.arraySizes[0] = 0; } void SubmeshParameters_0p1::initDefaults(void) { freeStrings(); freeReferences(); freeDynamicArrays(); initDynamicArrays(); initStrings(); initReferences(); } void SubmeshParameters_0p1::initReferences(void) { vertexBuffer = NULL; } void SubmeshParameters_0p1::freeDynamicArrays(void) { if (indexBuffer.isAllocated && indexBuffer.buf) { mParameterizedTraits->free(indexBuffer.buf); } if (vertexPartition.isAllocated && vertexPartition.buf) { mParameterizedTraits->free(vertexPartition.buf); } if (indexPartition.isAllocated && indexPartition.buf) { mParameterizedTraits->free(indexPartition.buf); } if (smoothingGroups.isAllocated && smoothingGroups.buf) { mParameterizedTraits->free(smoothingGroups.buf); } } void SubmeshParameters_0p1::freeStrings(void) { } void SubmeshParameters_0p1::freeReferences(void) { if (vertexBuffer) { vertexBuffer->destroy(); } } } // namespace parameterized } // namespace nvidia