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All rights reserved. #ifndef NVBLASTAUTHORINGFRACTURETOOL_H #define NVBLASTAUTHORINGFRACTURETOOL_H #include "NvBlastExtAuthoringTypes.h" namespace Nv { namespace Blast { class SpatialAccelerator; class Triangulator; class Mesh; class CutoutSet; /* Chunk data, chunk with chunkId == 0 is always source mesh. */ struct ChunkInfo { enum ChunkFlags { NO_FLAGS = 0, APPROXIMATE_BONDING = 1 // Created by island splitting or chunk merge, etc. and should check for inexact bonds }; Mesh* meshData; int32_t parent; int32_t chunkId; uint32_t flags; bool isLeaf; bool isChanged; }; /** Abstract base class for user-defined random value generator. */ class RandomGeneratorBase { public: // Generates uniformly distributed value in [0, 1] range. virtual float getRandomValue() = 0; // Seeds random value generator virtual void seed(int32_t seed) = 0; virtual ~RandomGeneratorBase(){}; }; /* Noise fracturing configuration for chunks's faces */ struct NoiseConfiguration { /** Noisy slicing configutaion: Amplitude of cutting surface noise. If it is 0 - noise is disabled. */ float amplitude = 0.f; /** Frequencey of cutting surface noise. */ float frequency = 1.f; /** Octave number in slicing surface noise. */ uint32_t octaveNumber = 1; /** Sampling interval for surface grid. */ NvcVec3 samplingInterval = { 1, 1, 1 }; }; /* Slicing fracturing configuration */ struct SlicingConfiguration { /** Number of slices in each direction */ int32_t x_slices = 1, y_slices = 1, z_slices = 1; /** Offset variation, value in [0, 1] */ float offset_variations = 0.f; /** Angle variation, value in [0, 1] */ float angle_variations = 0.f; /* Noise parameters for faces between sliced chunks */ NoiseConfiguration noise; }; /** Cutout fracturing configuration */ struct CutoutConfiguration { /** Set of grouped convex loop patterns for cutout in normal direction. Not required for PLANE_ONLY mode */ CutoutSet* cutoutSet = nullptr; /** Transform for initial pattern position and orientation. By default 2d pattern lies in XY plane (Y is up) the center of pattern is (0, 0) */ NvcTransform transform = {{0, 0, 0, 1}, {0, 0, 0}}; /** Scale for pattern. Unscaled pattern has size (1, 1). For negative scale pattern will be placed at the center of chunk and scaled with max distance between points of its AABB */ NvcVec2 scale = { -1, -1 }; /** Conic aperture in degree, for cylindric cutout set it to 0. */ float aperture = 0.f; /** If relative transform is set - position will be displacement vector from chunk's center. Otherwise from global origin. */ bool isRelativeTransform = true; /** Add generatad faces to the same smoothing group as original face without noise */ bool useSmoothing = false; /** Noise parameters for cutout surface, see NoiseConfiguration. */ NoiseConfiguration noise; }; /** Class for voronoi sites generation inside supplied mesh. */ class VoronoiSitesGenerator { public: virtual ~VoronoiSitesGenerator() {} /** Release VoronoiSitesGenerator memory */ virtual void release() = 0; /** Set base fracture mesh */ virtual void setBaseMesh(const Mesh* mesh) = 0; /** Access to generated voronoi sites. \param[out] Pointer to generated voronoi sites \return Count of generated voronoi sites. */ virtual uint32_t getVoronoiSites(const NvcVec3*& sites) = 0; /** Add site in particular point \param[in] site Site coordinates */ virtual void addSite(const NvcVec3& site) = 0; /** Uniformly generate sites inside the mesh \param[in] numberOfSites Number of generated sites */ virtual void uniformlyGenerateSitesInMesh(uint32_t numberOfSites) = 0; /** Generate sites in clustered fashion \param[in] numberOfClusters Number of generated clusters \param[in] sitesPerCluster Number of sites in each cluster \param[in] clusterRadius Voronoi cells cluster radius */ virtual void clusteredSitesGeneration(uint32_t numberOfClusters, uint32_t sitesPerCluster, float clusterRadius) = 0; /** Radial pattern of sites generation \param[in] center Center of generated pattern \param[in] normal Normal to plane in which sites are generated \param[in] radius Pattern radius \param[in] angularSteps Number of angular steps \param[in] radialSteps Number of radial steps \param[in] angleOffset Angle offset at each radial step \param[in] variability Randomness of sites distribution */ virtual void radialPattern(const NvcVec3& center, const NvcVec3& normal, float radius, int32_t angularSteps, int32_t radialSteps, float angleOffset = 0.0f, float variability = 0.0f) = 0; /** Generate sites inside sphere \param[in] count Count of generated sites \param[in] radius Radius of sphere \param[in] center Center of sphere */ virtual void generateInSphere(const uint32_t count, const float radius, const NvcVec3& center) = 0; /** Set stencil mesh. With stencil mesh sites are generated only inside both of fracture and stencil meshes. \param[in] stencil Stencil mesh. */ virtual void setStencil(const Mesh* stencil) = 0; /** Removes stencil mesh */ virtual void clearStencil() = 0; /** Deletes sites inside supplied sphere \param[in] radius Radius of sphere \param[in] center Center of sphere \param[in] eraserProbability Probability of removing some particular site */ virtual void deleteInSphere(const float radius, const NvcVec3& center, const float eraserProbability = 1) = 0; }; /** FractureTool class provides methods to fracture provided mesh and generate Blast asset data */ class FractureTool { public: virtual ~FractureTool() {} /** Release FractureTool memory */ virtual void release() = 0; /** Reset FractureTool state. */ virtual void reset() = 0; /** Set input mesh which will be fractured, FractureTool will be reseted. */ virtual void setSourceMesh(const Mesh* mesh) = 0; /** Set chunk mesh, parentId should be valid, return id of new chunk. */ virtual int32_t setChunkMesh(const Mesh* mesh, int32_t parentId) = 0; /** Set the material id to use for new interior faces. Defaults to kMaterialInteriorId */ virtual void setInteriorMaterialId(int32_t materialId) = 0; /** Gets the material id to use for new interior faces */ virtual int32_t getInteriorMaterialId() const = 0; /** Replaces an material id on faces with a new one */ virtual void replaceMaterialId(int32_t oldMaterialId, int32_t newMaterialId) = 0; /** Get chunk mesh in polygonal representation. User's code should release it after usage. */ virtual Mesh* createChunkMesh(int32_t chunkId) = 0; /** Input mesh is scaled and transformed internally to fit unit cube centered in origin. Method provides offset vector and scale parameter; */ virtual void getTransformation(NvcVec3& offset, float& scale) = 0; /** Fractures specified chunk with voronoi method. \param[in] chunkId Chunk to fracture \param[in] cellPoints Array of voronoi sites \param[in] replaceChunk if 'true', newly generated chunks will replace source chunk, if 'false', newly generated chunks will be at next depth level, source chunk will be parent for them. Case replaceChunk == true && chunkId == 0 considered as wrong input parameters \return If 0, fracturing is successful. */ virtual int32_t voronoiFracturing(uint32_t chunkId, uint32_t cellCount, const NvcVec3* cellPoints, bool replaceChunk) = 0; /** Fractures specified chunk with voronoi method. Cells can be scaled along x,y,z axes. \param[in] chunkId Chunk to fracture \param[in] cellPoints Array of voronoi sites \param[in] cellPoints Array of voronoi sites \param[in] scale Voronoi cells scaling factor \param[in] rotation Voronoi cells rotation. Has no effect without cells scale factor \param[in] replaceChunk if 'true', newly generated chunks will replace source chunk, if 'false', newly generated chunks will be at next depth level, source chunk will be parent for them. Case replaceChunk == true && chunkId == 0 considered as wrong input parameters \return If 0, fracturing is successful. */ virtual int32_t voronoiFracturing(uint32_t chunkId, uint32_t cellCount, const NvcVec3* cellPoints, const NvcVec3& scale, const NvcQuat& rotation, bool replaceChunk) = 0; /** Fractures specified chunk with slicing method. \param[in] chunkId Chunk to fracture \param[in] conf Slicing parameters, see SlicingConfiguration. \param[in] replaceChunk if 'true', newly generated chunks will replace source chunk, if 'false', newly generated chunks will be at next depth level, source chunk will be parent for them. Case replaceChunk == true && chunkId == 0 considered as wrong input parameters \param[in] rnd User supplied random number generator \return If 0, fracturing is successful. */ virtual int32_t slicing(uint32_t chunkId, const SlicingConfiguration& conf, bool replaceChunk, RandomGeneratorBase* rnd) = 0; /** Cut chunk with plane. \param[in] chunkId Chunk to fracture \param[in] normal Plane normal \param[in] position Point on plane \param[in] noise Noise configuration for plane-chunk intersection, see NoiseConfiguration. \param[in] replaceChunk if 'true', newly generated chunks will replace source chunk, if 'false', newly generated chunks will be at next depth level, source chunk will be parent for them. Case replaceChunk == true && chunkId == 0 considered as wrong input parameters \param[in] rnd User supplied random number generator \return If 0, fracturing is successful. */ virtual int32_t cut(uint32_t chunkId, const NvcVec3& normal, const NvcVec3& position, const NoiseConfiguration& noise, bool replaceChunk, RandomGeneratorBase* rnd) = 0; /** Cutout fracture for specified chunk. \param[in] chunkId Chunk to fracture \param[in] conf Cutout parameters, see CutoutConfiguration. \param[in] replaceChunk if 'true', newly generated chunks will replace source chunk, if 'false', newly generated chunks will be at next depth level, source chunk will be parent for them. Case replaceChunk == true && chunkId == 0 considered as wrong input parameters \param[in] rnd User supplied random number generator \return If 0, fracturing is successful. */ virtual int32_t cutout(uint32_t chunkId, CutoutConfiguration conf, bool replaceChunk, RandomGeneratorBase* rnd) = 0; /** Creates resulting fractured mesh geometry from intermediate format */ virtual void finalizeFracturing() = 0; /** Returns overall number of chunks in fracture. */ virtual uint32_t getChunkCount() const = 0; /** Get chunk information */ virtual const ChunkInfo& getChunkInfo(int32_t chunkIndex) = 0; /** Get percentage of mesh overlap. percentage computed as volume(intersection(meshA , meshB)) / volume (meshA) \param[in] meshA Mesh A \param[in] meshB Mesh B \return mesh overlap percentage */ virtual float getMeshOverlap(const Mesh& meshA, const Mesh& meshB) = 0; /** Get chunk base mesh \param[in] chunkIndex Chunk index \param[out] output Array of triangles to be filled \return number of triangles in base mesh */ virtual uint32_t getBaseMesh(int32_t chunkIndex, Triangle*& output) = 0; /** Update chunk base mesh \note Doesn't allocates output array, Triangle* output should be preallocated by user \param[in] chunkIndex Chunk index \param[out] output Array of triangles to be filled \return number of triangles in base mesh */ virtual uint32_t updateBaseMesh(int32_t chunkIndex, Triangle* output) = 0; /** Return index of chunk with specified chunkId \param[in] chunkId Chunk ID \return Chunk index in internal buffer, if not exist -1 is returned. */ virtual int32_t getChunkIndex(int32_t chunkId) = 0; /** Return id of chunk with specified index. \param[in] chunkIndex Chunk index \return Chunk id or -1 if there is no such chunk. */ virtual int32_t getChunkId(int32_t chunkIndex) = 0; /** Return depth level of the given chunk \param[in] chunkId Chunk ID \return Chunk depth or -1 if there is no such chunk. */ virtual int32_t getChunkDepth(int32_t chunkId) = 0; /** Return array of chunks IDs with given depth. \param[in] depth Chunk depth \param[out] Pointer to array of chunk IDs \return Number of chunks in array */ virtual uint32_t getChunksIdAtDepth(uint32_t depth, int32_t*& chunkIds) = 0; /** Get result geometry without noise as vertex and index buffers, where index buffers contain series of triplets which represent triangles. \param[out] vertexBuffer Array of vertices to be filled \param[out] indexBuffer Array of indices to be filled \param[out] indexBufferOffsets Array of offsets in indexBuffer for each base mesh. Contains getChunkCount() + 1 elements. Last one is indexBuffer size \return Number of vertices in vertexBuffer */ virtual uint32_t getBufferedBaseMeshes(Vertex*& vertexBuffer, uint32_t*& indexBuffer, uint32_t*& indexBufferOffsets) = 0; /** Set automatic islands removing. May cause instabilities. \param[in] isRemoveIslands Flag whether remove or not islands. */ virtual void setRemoveIslands(bool isRemoveIslands) = 0; /** Try find islands and remove them on some specifical chunk. If chunk has childs, island removing can lead to wrong results! Apply it before further chunk splitting. \param[in] chunkId Chunk ID which should be checked for islands \return Number of found islands is returned */ virtual int32_t islandDetectionAndRemoving(int32_t chunkId, bool createAtNewDepth = false) = 0; /** Check if input mesh contains open edges. Open edges can lead to wrong fracturing results. \return true if mesh contains open edges */ virtual bool isMeshContainOpenEdges(const Mesh* input) = 0; /** Delete all children for specified chunk (also recursively delete chidren of children). \param[in] chunkId Chunk ID which children should be deleted \param[in] deleteRoot (optional) If true, deletes the given chunk too \return true if one or more chunks were removed */ virtual bool deleteChunkSubhierarchy(int32_t chunkId, bool deleteRoot = false) = 0; /** Optimize chunk hierarhy for better runtime performance. It tries to unite chunks to groups of some size in order to transform flat hierarchy (all chunks are children of single root) to tree like hieracrhy with limited number of children for each chunk. \param[in] threshold If number of children of some chunk less then maxAtLevel then it would be considered as already optimized and skipped. \param[in] targetClusterSize Target number of children for processed chunks. \param[in] chunksToMerge Which chunks are merge candidate. If NULL, all chunks will be a merge candidate. \param[in] mergeChunkCount size of chunksToMerge array, if chunksToMerge != NULL. \param[in] adjChunks Optional index pairs to describe chunk adjacency. May be NULL. \param[in] adjChunksSize If 'adjChunks' is not NULL, the number of index pairs in the adjChunks array. \param[in] removeOriginalChunks If true, original chunks that are merged are removed. */ virtual void uniteChunks(uint32_t threshold, uint32_t targetClusterSize, const uint32_t* chunksToMerge, uint32_t mergeChunkCount, const NvcVec2i* adjChunks, uint32_t adjChunksSize, bool removeOriginalChunks = false) = 0; /** Set the APPROXIMATE_BONDING flag in the chunk's ChunkInfo \param[in] chunkIndex chunk index - use getChunkIndex(ID) \param[in] useApproximateBonding value of flag to set \return true if the chunk ID is found, false otherwise */ virtual bool setApproximateBonding(uint32_t chunkIndex, bool useApproximateBonding) = 0; /** Rescale interior uv coordinates of given chunk to fit square of given size. \param[in] side Size of square side \param[in] chunkId Chunk ID for which UVs should be scaled. */ virtual void fitUvToRect(float side, uint32_t chunkId) = 0; /** Rescale interior uv coordinates of all existing chunks to fit square of given size, relative sizes will be preserved. \param[in] side Size of square side */ virtual void fitAllUvToRect(float side) = 0; }; } // namespace Blast } // namespace Nv #endif // ifndef NVBLASTAUTHORINGFRACTURETOOL_H