// Copyright 2009-2020 Intel Corporation // SPDX-License-Identifier: Apache-2.0 #pragma once #include "catmullclark_ring.h" #include "bezier_curve.h" namespace embree { template class __aligned(64) CatmullClarkPatchT { public: typedef CatmullClark1RingT CatmullClark1Ring; typedef typename CatmullClark1Ring::Type Type; array_t,4> ring; public: __forceinline CatmullClarkPatchT () {} __forceinline CatmullClarkPatchT (const HalfEdge* first_half_edge, const char* vertices, size_t stride) { init(first_half_edge,vertices,stride); } __forceinline CatmullClarkPatchT (const HalfEdge* first_half_edge, const BufferView& vertices) { init(first_half_edge,vertices.getPtr(),vertices.getStride()); } __forceinline void init (const HalfEdge* first_half_edge, const char* vertices, size_t stride) { for (unsigned i=0; i<4; i++) ring[i].init(first_half_edge+i,vertices,stride); assert(verify()); } __forceinline size_t bytes() const { return ring[0].bytes()+ring[1].bytes()+ring[2].bytes()+ring[3].bytes(); } __forceinline void serialize(void* ptr, size_t& ofs) const { for (size_t i=0; i<4; i++) ring[i].serialize((char*)ptr,ofs); } __forceinline void deserialize(void* ptr) { size_t ofs = 0; for (size_t i=0; i<4; i++) ring[i].deserialize((char*)ptr,ofs); } __forceinline BBox3fa bounds() const { BBox3fa bounds (ring[0].bounds()); for (size_t i=1; i<4; i++) bounds.extend(ring[i].bounds()); return bounds; } __forceinline Type type() const { const int ty0 = ring[0].type() ^ CatmullClark1Ring::TYPE_CREASES; const int ty1 = ring[1].type() ^ CatmullClark1Ring::TYPE_CREASES; const int ty2 = ring[2].type() ^ CatmullClark1Ring::TYPE_CREASES; const int ty3 = ring[3].type() ^ CatmullClark1Ring::TYPE_CREASES; return (Type) ((ty0 & ty1 & ty2 & ty3) ^ CatmullClark1Ring::TYPE_CREASES); } __forceinline bool isFinalResolution(float res) const { return ring[0].isFinalResolution(res) && ring[1].isFinalResolution(res) && ring[2].isFinalResolution(res) && ring[3].isFinalResolution(res); } static __forceinline void init_regular(const CatmullClark1RingT& p0, const CatmullClark1RingT& p1, CatmullClark1RingT& dest0, CatmullClark1RingT& dest1) { assert(p1.face_valence > 2); dest1.vertex_level = dest0.vertex_level = p0.edge_level; dest1.face_valence = dest0.face_valence = 4; dest1.edge_valence = dest0.edge_valence = 8; dest1.border_index = dest0.border_index = -1; dest1.vtx = dest0.vtx = (Vertex_t)p0.ring[0]; dest1.vertex_crease_weight = dest0.vertex_crease_weight = 0.0f; dest1.ring[2] = dest0.ring[0] = (Vertex_t)p0.ring[1]; dest1.ring[1] = dest0.ring[7] = (Vertex_t)p1.ring[0]; dest1.ring[0] = dest0.ring[6] = (Vertex_t)p1.vtx; dest1.ring[7] = dest0.ring[5] = (Vertex_t)p1.ring[4]; dest1.ring[6] = dest0.ring[4] = (Vertex_t)p0.ring[p0.edge_valence-1]; dest1.ring[5] = dest0.ring[3] = (Vertex_t)p0.ring[p0.edge_valence-2]; dest1.ring[4] = dest0.ring[2] = (Vertex_t)p0.vtx; dest1.ring[3] = dest0.ring[1] = (Vertex_t)p0.ring[2]; dest1.crease_weight[1] = dest0.crease_weight[0] = 0.0f; dest1.crease_weight[0] = dest0.crease_weight[3] = p1.crease_weight[1]; dest1.crease_weight[3] = dest0.crease_weight[2] = 0.0f; dest1.crease_weight[2] = dest0.crease_weight[1] = p0.crease_weight[0]; if (p0.eval_unique_identifier <= p1.eval_unique_identifier) { dest0.eval_start_index = 3; dest1.eval_start_index = 0; dest0.eval_unique_identifier = p0.eval_unique_identifier; dest1.eval_unique_identifier = p0.eval_unique_identifier; } else { dest0.eval_start_index = 1; dest1.eval_start_index = 2; dest0.eval_unique_identifier = p1.eval_unique_identifier; dest1.eval_unique_identifier = p1.eval_unique_identifier; } } static __forceinline void init_border(const CatmullClark1RingT &p0, const CatmullClark1RingT &p1, CatmullClark1RingT &dest0, CatmullClark1RingT &dest1) { dest1.vertex_level = dest0.vertex_level = p0.edge_level; dest1.face_valence = dest0.face_valence = 3; dest1.edge_valence = dest0.edge_valence = 6; dest0.border_index = 2; dest1.border_index = 4; dest1.vtx = dest0.vtx = (Vertex_t)p0.ring[0]; dest1.vertex_crease_weight = dest0.vertex_crease_weight = 0.0f; dest1.ring[2] = dest0.ring[0] = (Vertex_t)p0.ring[1]; dest1.ring[1] = dest0.ring[5] = (Vertex_t)p1.ring[0]; dest1.ring[0] = dest0.ring[4] = (Vertex_t)p1.vtx; dest1.ring[5] = dest0.ring[3] = (Vertex_t)p0.ring[p0.border_index+1]; // dummy dest1.ring[4] = dest0.ring[2] = (Vertex_t)p0.vtx; dest1.ring[3] = dest0.ring[1] = (Vertex_t)p0.ring[2]; dest1.crease_weight[1] = dest0.crease_weight[0] = 0.0f; dest1.crease_weight[0] = dest0.crease_weight[2] = p1.crease_weight[1]; dest1.crease_weight[2] = dest0.crease_weight[1] = p0.crease_weight[0]; if (p0.eval_unique_identifier <= p1.eval_unique_identifier) { dest0.eval_start_index = 1; dest1.eval_start_index = 2; dest0.eval_unique_identifier = p0.eval_unique_identifier; dest1.eval_unique_identifier = p0.eval_unique_identifier; } else { dest0.eval_start_index = 2; dest1.eval_start_index = 0; dest0.eval_unique_identifier = p1.eval_unique_identifier; dest1.eval_unique_identifier = p1.eval_unique_identifier; } } static __forceinline void init_regular(const Vertex_t ¢er, const Vertex_t center_ring[8], const unsigned int offset, CatmullClark1RingT &dest) { dest.vertex_level = 0.0f; dest.face_valence = 4; dest.edge_valence = 8; dest.border_index = -1; dest.vtx = (Vertex_t)center; dest.vertex_crease_weight = 0.0f; for (size_t i=0; i<8; i++) dest.ring[i] = (Vertex_t)center_ring[(offset+i)%8]; for (size_t i=0; i<4; i++) dest.crease_weight[i] = 0.0f; dest.eval_start_index = (8-offset)>>1; if (dest.eval_start_index >= dest.face_valence) dest.eval_start_index -= dest.face_valence; assert( dest.eval_start_index < dest.face_valence ); dest.eval_unique_identifier = 0; } __noinline void subdivide(array_t& patch) const { ring[0].subdivide(patch[0].ring[0]); ring[1].subdivide(patch[1].ring[1]); ring[2].subdivide(patch[2].ring[2]); ring[3].subdivide(patch[3].ring[3]); patch[0].ring[0].edge_level = 0.5f*ring[0].edge_level; patch[0].ring[1].edge_level = 0.25f*(ring[1].edge_level+ring[3].edge_level); patch[0].ring[2].edge_level = 0.25f*(ring[0].edge_level+ring[2].edge_level); patch[0].ring[3].edge_level = 0.5f*ring[3].edge_level; patch[1].ring[0].edge_level = 0.5f*ring[0].edge_level; patch[1].ring[1].edge_level = 0.5f*ring[1].edge_level; patch[1].ring[2].edge_level = 0.25f*(ring[0].edge_level+ring[2].edge_level); patch[1].ring[3].edge_level = 0.25f*(ring[1].edge_level+ring[3].edge_level); patch[2].ring[0].edge_level = 0.25f*(ring[0].edge_level+ring[2].edge_level); patch[2].ring[1].edge_level = 0.5f*ring[1].edge_level; patch[2].ring[2].edge_level = 0.5f*ring[2].edge_level; patch[2].ring[3].edge_level = 0.25f*(ring[1].edge_level+ring[3].edge_level); patch[3].ring[0].edge_level = 0.25f*(ring[0].edge_level+ring[2].edge_level); patch[3].ring[1].edge_level = 0.25f*(ring[1].edge_level+ring[3].edge_level); patch[3].ring[2].edge_level = 0.5f*ring[2].edge_level; patch[3].ring[3].edge_level = 0.5f*ring[3].edge_level; const bool regular0 = ring[0].has_last_face() && ring[1].face_valence > 2; if (likely(regular0)) init_regular(patch[0].ring[0],patch[1].ring[1],patch[0].ring[1],patch[1].ring[0]); else init_border(patch[0].ring[0],patch[1].ring[1],patch[0].ring[1],patch[1].ring[0]); const bool regular1 = ring[1].has_last_face() && ring[2].face_valence > 2; if (likely(regular1)) init_regular(patch[1].ring[1],patch[2].ring[2],patch[1].ring[2],patch[2].ring[1]); else init_border(patch[1].ring[1],patch[2].ring[2],patch[1].ring[2],patch[2].ring[1]); const bool regular2 = ring[2].has_last_face() && ring[3].face_valence > 2; if (likely(regular2)) init_regular(patch[2].ring[2],patch[3].ring[3],patch[2].ring[3],patch[3].ring[2]); else init_border(patch[2].ring[2],patch[3].ring[3],patch[2].ring[3],patch[3].ring[2]); const bool regular3 = ring[3].has_last_face() && ring[0].face_valence > 2; if (likely(regular3)) init_regular(patch[3].ring[3],patch[0].ring[0],patch[3].ring[0],patch[0].ring[3]); else init_border(patch[3].ring[3],patch[0].ring[0],patch[3].ring[0],patch[0].ring[3]); Vertex_t center = (ring[0].vtx + ring[1].vtx + ring[2].vtx + ring[3].vtx) * 0.25f; Vertex_t center_ring[8]; center_ring[0] = (Vertex_t)patch[3].ring[3].ring[0]; center_ring[7] = (Vertex_t)patch[3].ring[3].vtx; center_ring[6] = (Vertex_t)patch[2].ring[2].ring[0]; center_ring[5] = (Vertex_t)patch[2].ring[2].vtx; center_ring[4] = (Vertex_t)patch[1].ring[1].ring[0]; center_ring[3] = (Vertex_t)patch[1].ring[1].vtx; center_ring[2] = (Vertex_t)patch[0].ring[0].ring[0]; center_ring[1] = (Vertex_t)patch[0].ring[0].vtx; init_regular(center,center_ring,0,patch[0].ring[2]); init_regular(center,center_ring,2,patch[1].ring[3]); init_regular(center,center_ring,4,patch[2].ring[0]); init_regular(center,center_ring,6,patch[3].ring[1]); assert(patch[0].verify()); assert(patch[1].verify()); assert(patch[2].verify()); assert(patch[3].verify()); } bool verify() const { return ring[0].hasValidPositions() && ring[1].hasValidPositions() && ring[2].hasValidPositions() && ring[3].hasValidPositions(); } __forceinline void init( FinalQuad& quad ) const { quad.vtx[0] = (Vertex_t)ring[0].vtx; quad.vtx[1] = (Vertex_t)ring[1].vtx; quad.vtx[2] = (Vertex_t)ring[2].vtx; quad.vtx[3] = (Vertex_t)ring[3].vtx; }; friend __forceinline embree_ostream operator<<(embree_ostream o, const CatmullClarkPatchT &p) { o << "CatmullClarkPatch { " << embree_endl; for (size_t i=0; i<4; i++) o << "ring" << i << ": " << p.ring[i] << embree_endl; o << "}" << embree_endl; return o; } }; typedef CatmullClarkPatchT CatmullClarkPatch3fa; template class __aligned(64) GeneralCatmullClarkPatchT { public: typedef CatmullClarkPatchT CatmullClarkPatch; typedef CatmullClark1RingT CatmullClark1Ring; typedef BezierCurveT BezierCurve; static const unsigned SIZE = MAX_PATCH_VALENCE; DynamicStackArray,8,SIZE> ring; unsigned N; __forceinline GeneralCatmullClarkPatchT () : N(0) {} GeneralCatmullClarkPatchT (const HalfEdge* h, const char* vertices, size_t stride) { init(h,vertices,stride); } __forceinline GeneralCatmullClarkPatchT (const HalfEdge* first_half_edge, const BufferView& vertices) { init(first_half_edge,vertices.getPtr(),vertices.getStride()); } __forceinline void init (const HalfEdge* h, const char* vertices, size_t stride) { unsigned int i = 0; const HalfEdge* edge = h; do { ring[i].init(edge,vertices,stride); edge = edge->next(); i++; } while ((edge != h) && (i < SIZE)); N = i; } __forceinline unsigned size() const { return N; } __forceinline bool isQuadPatch() const { return (N == 4) && ring[0].only_quads && ring[1].only_quads && ring[2].only_quads && ring[3].only_quads; } static __forceinline void init_regular(const CatmullClark1RingT& p0, const CatmullClark1RingT& p1, CatmullClark1RingT& dest0, CatmullClark1RingT& dest1) { assert(p1.face_valence > 2); dest1.vertex_level = dest0.vertex_level = p0.edge_level; dest1.face_valence = dest0.face_valence = 4; dest1.edge_valence = dest0.edge_valence = 8; dest1.border_index = dest0.border_index = -1; dest1.vtx = dest0.vtx = (Vertex_t)p0.ring[0]; dest1.vertex_crease_weight = dest0.vertex_crease_weight = 0.0f; dest1.ring[2] = dest0.ring[0] = (Vertex_t)p0.ring[1]; dest1.ring[1] = dest0.ring[7] = (Vertex_t)p1.ring[0]; dest1.ring[0] = dest0.ring[6] = (Vertex_t)p1.vtx; dest1.ring[7] = dest0.ring[5] = (Vertex_t)p1.ring[4]; dest1.ring[6] = dest0.ring[4] = (Vertex_t)p0.ring[p0.edge_valence-1]; dest1.ring[5] = dest0.ring[3] = (Vertex_t)p0.ring[p0.edge_valence-2]; dest1.ring[4] = dest0.ring[2] = (Vertex_t)p0.vtx; dest1.ring[3] = dest0.ring[1] = (Vertex_t)p0.ring[2]; dest1.crease_weight[1] = dest0.crease_weight[0] = 0.0f; dest1.crease_weight[0] = dest0.crease_weight[3] = p1.crease_weight[1]; dest1.crease_weight[3] = dest0.crease_weight[2] = 0.0f; dest1.crease_weight[2] = dest0.crease_weight[1] = p0.crease_weight[0]; if (p0.eval_unique_identifier <= p1.eval_unique_identifier) { dest0.eval_start_index = 3; dest1.eval_start_index = 0; dest0.eval_unique_identifier = p0.eval_unique_identifier; dest1.eval_unique_identifier = p0.eval_unique_identifier; } else { dest0.eval_start_index = 1; dest1.eval_start_index = 2; dest0.eval_unique_identifier = p1.eval_unique_identifier; dest1.eval_unique_identifier = p1.eval_unique_identifier; } } static __forceinline void init_border(const CatmullClark1RingT &p0, const CatmullClark1RingT &p1, CatmullClark1RingT &dest0, CatmullClark1RingT &dest1) { dest1.vertex_level = dest0.vertex_level = p0.edge_level; dest1.face_valence = dest0.face_valence = 3; dest1.edge_valence = dest0.edge_valence = 6; dest0.border_index = 2; dest1.border_index = 4; dest1.vtx = dest0.vtx = (Vertex_t)p0.ring[0]; dest1.vertex_crease_weight = dest0.vertex_crease_weight = 0.0f; dest1.ring[2] = dest0.ring[0] = (Vertex_t)p0.ring[1]; dest1.ring[1] = dest0.ring[5] = (Vertex_t)p1.ring[0]; dest1.ring[0] = dest0.ring[4] = (Vertex_t)p1.vtx; dest1.ring[5] = dest0.ring[3] = (Vertex_t)p0.ring[p0.border_index+1]; // dummy dest1.ring[4] = dest0.ring[2] = (Vertex_t)p0.vtx; dest1.ring[3] = dest0.ring[1] = (Vertex_t)p0.ring[2]; dest1.crease_weight[1] = dest0.crease_weight[0] = 0.0f; dest1.crease_weight[0] = dest0.crease_weight[2] = p1.crease_weight[1]; dest1.crease_weight[2] = dest0.crease_weight[1] = p0.crease_weight[0]; if (p0.eval_unique_identifier <= p1.eval_unique_identifier) { dest0.eval_start_index = 1; dest1.eval_start_index = 2; dest0.eval_unique_identifier = p0.eval_unique_identifier; dest1.eval_unique_identifier = p0.eval_unique_identifier; } else { dest0.eval_start_index = 2; dest1.eval_start_index = 0; dest0.eval_unique_identifier = p1.eval_unique_identifier; dest1.eval_unique_identifier = p1.eval_unique_identifier; } } static __forceinline void init_regular(const Vertex_t ¢er, const array_t& center_ring, const float vertex_level, const unsigned int N, const unsigned int offset, CatmullClark1RingT &dest) { assert(N<(MAX_RING_FACE_VALENCE)); assert(2*N<(MAX_RING_EDGE_VALENCE)); dest.vertex_level = vertex_level; dest.face_valence = N; dest.edge_valence = 2*N; dest.border_index = -1; dest.vtx = (Vertex_t)center; dest.vertex_crease_weight = 0.0f; for (unsigned i=0; i<2*N; i++) { dest.ring[i] = (Vertex_t)center_ring[(2*N+offset+i-1)%(2*N)]; assert(isvalid(dest.ring[i])); } for (unsigned i=0; i>1; if (dest.eval_start_index >= dest.face_valence) dest.eval_start_index -= dest.face_valence; assert( dest.eval_start_index < dest.face_valence ); dest.eval_unique_identifier = 0; } __noinline void subdivide(array_t& patch, unsigned& N_o) const { N_o = N; assert( N ); for (unsigned i=0; i center_ring; float center_vertex_level = 2.0f; // guarantees that irregular vertices get always isolated also for non-quads for (unsigned i=0; i 2; if (likely(regular)) init_regular(patch[i].ring[0],patch[ip1].ring[0],patch[i].ring[1],patch[ip1].ring[3]); else init_border (patch[i].ring[0],patch[ip1].ring[0],patch[i].ring[1],patch[ip1].ring[3]); assert( patch[i].ring[1].hasValidPositions() ); assert( patch[ip1].ring[3].hasValidPositions() ); float level = 0.25f*(ring[im1].edge_level+ring[ip1].edge_level); patch[i].ring[1].edge_level = patch[ip1].ring[2].edge_level = level; center_vertex_level = max(center_vertex_level,level); center += ring[i].vtx; center_ring[2*i+0] = (Vertex_t)patch[i].ring[0].vtx; center_ring[2*i+1] = (Vertex_t)patch[i].ring[0].ring[0]; } center /= float(N); for (unsigned int i=0; i& patches) { CatmullClark1Ring patches1ring1 = patches[1].ring[1]; patches[1].ring[1] = patches[1].ring[0]; // FIXME: optimize these assignments patches[1].ring[0] = patches[1].ring[3]; patches[1].ring[3] = patches[1].ring[2]; patches[1].ring[2] = patches1ring1; CatmullClark1Ring patches2ring2 = patches[2].ring[2]; patches[2].ring[2] = patches[2].ring[0]; patches[2].ring[0] = patches2ring2; CatmullClark1Ring patches2ring3 = patches[2].ring[3]; patches[2].ring[3] = patches[2].ring[1]; patches[2].ring[1] = patches2ring3; CatmullClark1Ring patches3ring3 = patches[3].ring[3]; patches[3].ring[3] = patches[3].ring[0]; patches[3].ring[0] = patches[3].ring[1]; patches[3].ring[1] = patches[3].ring[2]; patches[3].ring[2] = patches3ring3; } __forceinline void getLimitBorder(BezierCurve curves[GeneralCatmullClarkPatchT::SIZE]) const { Vertex P0 = ring[0].getLimitVertex(); for (unsigned i=0; i GeneralCatmullClarkPatch3fa; }