/* SPDX-FileCopyrightText: 2011-2022 Blender Foundation * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include "blender/attribute_convert.h" #include "blender/session.h" #include "blender/sync.h" #include "blender/util.h" #include "scene/camera.h" #include "scene/mesh.h" #include "scene/object.h" #include "scene/scene.h" #include "subd/split.h" #include "util/algorithm.h" #include "util/disjoint_set.h" #include "util/hash.h" #include "util/log.h" #include "util/math.h" #include "BKE_anonymous_attribute_id.hh" #include "BKE_attribute.hh" #include "BKE_attribute_math.hh" #include "BKE_customdata.hh" #include "BKE_mesh.hh" CCL_NAMESPACE_BEGIN static void attr_create_motion_from_velocity(Mesh *mesh, const blender::Span b_attr, const float motion_scale) { const int numverts = mesh->get_verts().size(); /* Override motion steps to fixed number. */ mesh->set_motion_steps(3); AttributeSet &attributes = mesh->get_subdivision_type() == Mesh::SUBDIVISION_NONE ? mesh->attributes : mesh->subd_attributes; /* Find or add attribute */ float3 *P = mesh->get_verts().data(); Attribute *attr_mP = attributes.find(ATTR_STD_MOTION_VERTEX_POSITION); if (!attr_mP) { attr_mP = attributes.add(ATTR_STD_MOTION_VERTEX_POSITION); } /* Only export previous and next frame, we don't have any in between data. */ const float motion_times[2] = {-1.0f, 1.0f}; for (int step = 0; step < 2; step++) { const float relative_time = motion_times[step] * 0.5f * motion_scale; float3 *mP = attr_mP->data_float3() + step * numverts; for (int i = 0; i < numverts; i++) { mP[i] = P[i] + make_float3(b_attr[i][0], b_attr[i][1], b_attr[i][2]) * relative_time; } } } static void attr_create_generic(Scene *scene, Mesh *mesh, const ::Mesh &b_mesh, const bool subdivision, const bool need_motion, const float motion_scale) { blender::Span corner_tris; blender::Span tri_faces; if (!subdivision) { corner_tris = b_mesh.corner_tris(); tri_faces = b_mesh.corner_tri_faces(); } const blender::bke::AttributeAccessor b_attributes = b_mesh.attributes(); AttributeSet &attributes = (subdivision) ? mesh->subd_attributes : mesh->attributes; static const ustring u_velocity("velocity"); const ustring default_color_name{ std::string_view(BKE_id_attributes_default_color_name(&b_mesh.id).value_or(""))}; b_attributes.foreach_attribute([&](const blender::bke::AttributeIter &iter) { const ustring name{std::string_view(iter.name)}; const bool is_render_color = name == default_color_name; if (need_motion && name == u_velocity) { const blender::VArraySpan b_attribute = *iter.get( blender::bke::AttrDomain::Point); attr_create_motion_from_velocity(mesh, b_attribute, motion_scale); } if (!(mesh->need_attribute(scene, name) || (is_render_color && mesh->need_attribute(scene, ATTR_STD_VERTEX_COLOR)))) { return; } if (attributes.find(name)) { return; } blender::bke::AttrDomain b_domain = iter.domain; if (b_domain == blender::bke::AttrDomain::Edge) { /* Blender's attribute API handles edge to vertex attribute domain interpolation. */ b_domain = blender::bke::AttrDomain::Point; } const blender::bke::GAttributeReader b_attr = iter.get(b_domain); if (b_attr.varray.is_empty()) { return; } if (b_attr.domain == blender::bke::AttrDomain::Corner && iter.data_type == CD_PROP_BYTE_COLOR) { Attribute *attr = attributes.add(name, TypeRGBA, ATTR_ELEMENT_CORNER_BYTE); if (is_render_color) { attr->std = ATTR_STD_VERTEX_COLOR; } uchar4 *data = attr->data_uchar4(); const blender::VArraySpan src = b_attr.varray.typed(); if (subdivision) { for (const int i : src.index_range()) { data[i] = make_uchar4(src[i][0], src[i][1], src[i][2], src[i][3]); } } else { for (const int i : corner_tris.index_range()) { const blender::int3 &tri = corner_tris[i]; data[i * 3 + 0] = make_uchar4( src[tri[0]][0], src[tri[0]][1], src[tri[0]][2], src[tri[0]][3]); data[i * 3 + 1] = make_uchar4( src[tri[1]][0], src[tri[1]][1], src[tri[1]][2], src[tri[1]][3]); data[i * 3 + 2] = make_uchar4( src[tri[2]][0], src[tri[2]][1], src[tri[2]][2], src[tri[2]][3]); } } return; } AttributeElement element = ATTR_ELEMENT_NONE; switch (b_domain) { case blender::bke::AttrDomain::Corner: element = ATTR_ELEMENT_CORNER; break; case blender::bke::AttrDomain::Point: element = ATTR_ELEMENT_VERTEX; break; case blender::bke::AttrDomain::Face: element = ATTR_ELEMENT_FACE; break; default: assert(false); return; } blender::bke::attribute_math::convert_to_static_type(b_attr.varray.type(), [&](auto dummy) { using BlenderT = decltype(dummy); using Converter = typename ccl::AttributeConverter; using CyclesT = typename Converter::CyclesT; if constexpr (!std::is_void_v) { Attribute *attr = attributes.add(name, Converter::type_desc, element); if (is_render_color) { attr->std = ATTR_STD_VERTEX_COLOR; } CyclesT *data = reinterpret_cast(attr->data()); const blender::VArraySpan src = b_attr.varray.typed(); switch (b_attr.domain) { case blender::bke::AttrDomain::Corner: { if (subdivision) { for (const int i : src.index_range()) { data[i] = Converter::convert(src[i]); } } else { for (const int i : corner_tris.index_range()) { const blender::int3 &tri = corner_tris[i]; data[i * 3 + 0] = Converter::convert(src[tri[0]]); data[i * 3 + 1] = Converter::convert(src[tri[1]]); data[i * 3 + 2] = Converter::convert(src[tri[2]]); } } break; } case blender::bke::AttrDomain::Point: { for (const int i : src.index_range()) { data[i] = Converter::convert(src[i]); } break; } case blender::bke::AttrDomain::Face: { if (subdivision) { for (const int i : src.index_range()) { data[i] = Converter::convert(src[i]); } } else { for (const int i : corner_tris.index_range()) { data[i] = Converter::convert(src[tri_faces[i]]); } } break; } default: { assert(false); break; } } } }); }); } static set get_blender_uv_names(const ::Mesh &b_mesh) { set uv_names; b_mesh.attributes().foreach_attribute([&](const blender::bke::AttributeIter &iter) { if (iter.domain == blender::bke::AttrDomain::Corner && iter.data_type == CD_PROP_FLOAT2) { if (!blender::bke::attribute_name_is_anonymous(iter.name)) { uv_names.emplace(std::string_view(iter.name)); } } }); return uv_names; } /* Create uv map attributes. */ static void attr_create_uv_map(Scene *scene, Mesh *mesh, const ::Mesh &b_mesh, const set &blender_uv_names) { const blender::Span corner_tris = b_mesh.corner_tris(); const blender::bke::AttributeAccessor b_attributes = b_mesh.attributes(); const ustring render_name(CustomData_get_render_layer_name(&b_mesh.corner_data, CD_PROP_FLOAT2)); if (blender_uv_names.empty()) { return; } for (const ustring &uv_name : blender_uv_names) { const bool active_render = uv_name == render_name; const AttributeStandard uv_std = (active_render) ? ATTR_STD_UV : ATTR_STD_NONE; const AttributeStandard tangent_std = (active_render) ? ATTR_STD_UV_TANGENT : ATTR_STD_NONE; const ustring tangent_name = ustring((string(uv_name) + ".tangent").c_str()); /* Denotes whether UV map was requested directly. */ const bool need_uv = mesh->need_attribute(scene, uv_name) || mesh->need_attribute(scene, uv_std); /* Denotes whether tangent was requested directly. */ const bool need_tangent = mesh->need_attribute(scene, tangent_name) || (active_render && mesh->need_attribute(scene, tangent_std)); /* UV map */ Attribute *uv_attr = nullptr; if (need_uv || need_tangent) { if (active_render) { uv_attr = mesh->attributes.add(uv_std, uv_name); } else { uv_attr = mesh->attributes.add(uv_name, TypeFloat2, ATTR_ELEMENT_CORNER); } const blender::VArraySpan b_uv_map = *b_attributes.lookup( uv_name.c_str(), blender::bke::AttrDomain::Corner); float2 *fdata = uv_attr->data_float2(); for (const int i : corner_tris.index_range()) { const blender::int3 &tri = corner_tris[i]; fdata[i * 3 + 0] = make_float2(b_uv_map[tri[0]][0], b_uv_map[tri[0]][1]); fdata[i * 3 + 1] = make_float2(b_uv_map[tri[1]][0], b_uv_map[tri[1]][1]); fdata[i * 3 + 2] = make_float2(b_uv_map[tri[2]][0], b_uv_map[tri[2]][1]); } } } } static void attr_create_subd_uv_map(Scene *scene, Mesh *mesh, const ::Mesh &b_mesh, const set &blender_uv_names) { const blender::OffsetIndices faces = b_mesh.faces(); if (faces.is_empty()) { return; } if (blender_uv_names.empty()) { return; } const blender::bke::AttributeAccessor b_attributes = b_mesh.attributes(); const ustring render_name(CustomData_get_render_layer_name(&b_mesh.corner_data, CD_PROP_FLOAT2)); for (const ustring &uv_name : blender_uv_names) { const bool active_render = uv_name == render_name; const AttributeStandard uv_std = (active_render) ? ATTR_STD_UV : ATTR_STD_NONE; const AttributeStandard tangent_std = (active_render) ? ATTR_STD_UV_TANGENT : ATTR_STD_NONE; const ustring tangent_name = ustring((string(uv_name) + ".tangent").c_str()); /* Denotes whether UV map was requested directly. */ const bool need_uv = mesh->need_attribute(scene, uv_name) || mesh->need_attribute(scene, uv_std); /* Denotes whether tangent was requested directly. */ const bool need_tangent = mesh->need_attribute(scene, tangent_name) || (active_render && mesh->need_attribute(scene, tangent_std)); Attribute *uv_attr = nullptr; /* UV map */ if (need_uv || need_tangent) { if (active_render) { uv_attr = mesh->subd_attributes.add(uv_std, uv_name); } else { uv_attr = mesh->subd_attributes.add(uv_name, TypeFloat2, ATTR_ELEMENT_CORNER); } uv_attr->flags |= ATTR_SUBDIVIDE_SMOOTH_FVAR; const blender::VArraySpan b_uv_map = *b_attributes.lookup( uv_name.c_str(), blender::bke::AttrDomain::Corner); float2 *fdata = uv_attr->data_float2(); for (const int i : faces.index_range()) { const blender::IndexRange face = faces[i]; for (const int corner : face) { *(fdata++) = make_float2(b_uv_map[corner][0], b_uv_map[corner][1]); } } } } } /* Create vertex pointiness attributes. */ /* Compare vertices by sum of their coordinates. */ class VertexAverageComparator { public: VertexAverageComparator(const array &verts) : verts_(verts) {} bool operator()(const int &vert_idx_a, const int &vert_idx_b) { const float3 &vert_a = verts_[vert_idx_a]; const float3 &vert_b = verts_[vert_idx_b]; if (vert_a == vert_b) { /* Special case for doubles, so we ensure ordering. */ return vert_idx_a > vert_idx_b; } const float x1 = vert_a.x + vert_a.y + vert_a.z; const float x2 = vert_b.x + vert_b.y + vert_b.z; return x1 < x2; } protected: const array &verts_; }; static void attr_create_pointiness(Mesh *mesh, const blender::Span positions, const blender::Span b_vert_normals, const blender::Span edges, bool subdivision) { const int num_verts = positions.size(); if (positions.is_empty()) { return; } /* STEP 1: Find out duplicated vertices and point duplicates to a single * original vertex. */ vector sorted_vert_indeices(num_verts); for (int vert_index = 0; vert_index < num_verts; ++vert_index) { sorted_vert_indeices[vert_index] = vert_index; } const VertexAverageComparator compare(mesh->get_verts()); sort(sorted_vert_indeices.begin(), sorted_vert_indeices.end(), compare); /* This array stores index of the original vertex for the given vertex * index. */ vector vert_orig_index(num_verts); for (int sorted_vert_index = 0; sorted_vert_index < num_verts; ++sorted_vert_index) { const int vert_index = sorted_vert_indeices[sorted_vert_index]; const float3 &vert_co = mesh->get_verts()[vert_index]; bool found = false; for (int other_sorted_vert_index = sorted_vert_index + 1; other_sorted_vert_index < num_verts; ++other_sorted_vert_index) { const int other_vert_index = sorted_vert_indeices[other_sorted_vert_index]; const float3 &other_vert_co = mesh->get_verts()[other_vert_index]; /* We are too far away now, we wouldn't have duplicate. */ if ((other_vert_co.x + other_vert_co.y + other_vert_co.z) - (vert_co.x + vert_co.y + vert_co.z) > 3 * FLT_EPSILON) { break; } /* Found duplicate. */ if (len_squared(other_vert_co - vert_co) < FLT_EPSILON) { found = true; vert_orig_index[vert_index] = other_vert_index; break; } } if (!found) { vert_orig_index[vert_index] = vert_index; } } /* Make sure we always points to the very first orig vertex. */ for (int vert_index = 0; vert_index < num_verts; ++vert_index) { int orig_index = vert_orig_index[vert_index]; while (orig_index != vert_orig_index[orig_index]) { orig_index = vert_orig_index[orig_index]; } vert_orig_index[vert_index] = orig_index; } sorted_vert_indeices.free_memory(); /* STEP 2: Calculate vertex normals taking into account their possible * duplicates which gets "welded" together. */ vector vert_normal(num_verts, zero_float3()); /* First we accumulate all vertex normals in the original index. */ for (int vert_index = 0; vert_index < num_verts; ++vert_index) { const float *b_vert_normal = b_vert_normals[vert_index]; const int orig_index = vert_orig_index[vert_index]; vert_normal[orig_index] += make_float3(b_vert_normal[0], b_vert_normal[1], b_vert_normal[2]); } /* Then we normalize the accumulated result and flush it to all duplicates * as well. */ for (int vert_index = 0; vert_index < num_verts; ++vert_index) { const int orig_index = vert_orig_index[vert_index]; vert_normal[vert_index] = normalize(vert_normal[orig_index]); } /* STEP 3: Calculate pointiness using single ring neighborhood. */ vector counter(num_verts, 0); vector raw_data(num_verts, 0.0f); vector edge_accum(num_verts, zero_float3()); EdgeMap visited_edges; memset(counter.data(), 0, sizeof(int) * counter.size()); for (const int i : edges.index_range()) { const blender::int2 b_edge = edges[i]; const int v0 = vert_orig_index[b_edge[0]]; const int v1 = vert_orig_index[b_edge[1]]; if (visited_edges.exists(v0, v1)) { continue; } visited_edges.insert(v0, v1); const float3 co0 = make_float3(positions[v0][0], positions[v0][1], positions[v0][2]); const float3 co1 = make_float3(positions[v1][0], positions[v1][1], positions[v1][2]); const float3 edge = normalize(co1 - co0); edge_accum[v0] += edge; edge_accum[v1] += -edge; ++counter[v0]; ++counter[v1]; } for (int vert_index = 0; vert_index < num_verts; ++vert_index) { const int orig_index = vert_orig_index[vert_index]; if (orig_index != vert_index) { /* Skip duplicates, they'll be overwritten later on. */ continue; } if (counter[vert_index] > 0) { const float3 normal = vert_normal[vert_index]; const float angle = safe_acosf(dot(normal, edge_accum[vert_index] / counter[vert_index])); raw_data[vert_index] = angle * M_1_PI_F; } else { raw_data[vert_index] = 0.0f; } } /* STEP 3: Blur vertices to approximate 2 ring neighborhood. */ AttributeSet &attributes = (subdivision) ? mesh->subd_attributes : mesh->attributes; Attribute *attr = attributes.add(ATTR_STD_POINTINESS); float *data = attr->data_float(); memcpy(data, raw_data.data(), sizeof(float) * raw_data.size()); memset(counter.data(), 0, sizeof(int) * counter.size()); visited_edges.clear(); for (const int i : edges.index_range()) { const blender::int2 b_edge = edges[i]; const int v0 = vert_orig_index[b_edge[0]]; const int v1 = vert_orig_index[b_edge[1]]; if (visited_edges.exists(v0, v1)) { continue; } visited_edges.insert(v0, v1); data[v0] += raw_data[v1]; data[v1] += raw_data[v0]; ++counter[v0]; ++counter[v1]; } for (int vert_index = 0; vert_index < num_verts; ++vert_index) { data[vert_index] /= counter[vert_index] + 1; } /* STEP 4: Copy attribute to the duplicated vertices. */ for (int vert_index = 0; vert_index < num_verts; ++vert_index) { const int orig_index = vert_orig_index[vert_index]; data[vert_index] = data[orig_index]; } } /* The Random Per Island attribute is a random float associated with each * connected component (island) of the mesh. The attribute is computed by * first classifying the vertices into different sets using a Disjoint Set * data structure. Then the index of the root of each vertex (Which is the * representative of the set the vertex belongs to) is hashed and stored. * * We are using a face attribute to avoid interpolation during rendering, * allowing the user to safely hash the output further. Had we used vertex * attribute, the interpolation will introduce very slight variations, * making the output unsafe to hash. */ static void attr_create_random_per_island(Scene *scene, Mesh *mesh, const ::Mesh &b_mesh, bool subdivision) { if (!mesh->need_attribute(scene, ATTR_STD_RANDOM_PER_ISLAND)) { return; } if (b_mesh.verts_num == 0) { return; } DisjointSet vertices_sets(b_mesh.verts_num); const blender::Span edges = b_mesh.edges(); const blender::Span corner_verts = b_mesh.corner_verts(); for (const int i : edges.index_range()) { vertices_sets.join(edges[i][0], edges[i][1]); } AttributeSet &attributes = (subdivision) ? mesh->subd_attributes : mesh->attributes; Attribute *attribute = attributes.add(ATTR_STD_RANDOM_PER_ISLAND); float *data = attribute->data_float(); if (!subdivision) { const blender::Span corner_tris = b_mesh.corner_tris(); if (!corner_tris.is_empty()) { for (const int i : corner_tris.index_range()) { const int vert = corner_verts[corner_tris[i][0]]; data[i] = hash_uint_to_float(vertices_sets.find(vert)); } } } else { const blender::OffsetIndices faces = b_mesh.faces(); if (!faces.is_empty()) { for (const int i : faces.index_range()) { const int vert = corner_verts[faces[i].start()]; data[i] = hash_uint_to_float(vertices_sets.find(vert)); } } } } /* Create Mesh */ static void create_mesh(Scene *scene, Mesh *mesh, const ::Mesh &b_mesh, const array &used_shaders, const bool need_motion, const float motion_scale, const bool subdivision = false) { const blender::Span positions = b_mesh.vert_positions(); const blender::OffsetIndices faces = b_mesh.faces(); const blender::Span corner_verts = b_mesh.corner_verts(); const blender::bke::AttributeAccessor b_attributes = b_mesh.attributes(); const blender::bke::MeshNormalDomain normals_domain = b_mesh.normals_domain(true); const int numfaces = (!subdivision) ? b_mesh.corner_tris().size() : faces.size(); const bool use_corner_normals = normals_domain == blender::bke::MeshNormalDomain::Corner && (mesh->get_subdivision_type() != Mesh::SUBDIVISION_CATMULL_CLARK); /* If no faces, create empty mesh. */ if (faces.is_empty()) { return; } const blender::VArraySpan material_indices = *b_attributes.lookup( "material_index", blender::bke::AttrDomain::Face); const blender::VArraySpan sharp_faces = *b_attributes.lookup( "sharp_face", blender::bke::AttrDomain::Face); blender::Span corner_normals; if (use_corner_normals) { corner_normals = b_mesh.corner_normals(); } int numtris = 0; if (!subdivision) { numtris = numfaces; } /* allocate memory */ if (subdivision) { mesh->resize_subd_faces(numfaces, corner_verts.size()); } mesh->resize_mesh(positions.size(), numtris); float3 *verts = mesh->get_verts().data(); for (const int i : positions.index_range()) { verts[i] = make_float3(positions[i][0], positions[i][1], positions[i][2]); } AttributeSet &attributes = (subdivision) ? mesh->subd_attributes : mesh->attributes; Attribute *attr_N = attributes.add(ATTR_STD_VERTEX_NORMAL); float3 *N = attr_N->data_float3(); if (subdivision || !(use_corner_normals && !corner_normals.is_empty())) { const blender::Span vert_normals = b_mesh.vert_normals(); for (const int i : vert_normals.index_range()) { N[i] = make_float3(vert_normals[i][0], vert_normals[i][1], vert_normals[i][2]); } } const set blender_uv_names = get_blender_uv_names(b_mesh); /* create generated coordinates from undeformed coordinates */ const bool need_default_tangent = (subdivision == false) && (blender_uv_names.empty()) && (mesh->need_attribute(scene, ATTR_STD_UV_TANGENT)); if (mesh->need_attribute(scene, ATTR_STD_GENERATED) || need_default_tangent) { const float(*orco)[3] = static_cast( CustomData_get_layer(&b_mesh.vert_data, CD_ORCO)); Attribute *attr = attributes.add(ATTR_STD_GENERATED); float3 loc; float3 size; mesh_texture_space(b_mesh, loc, size); float texspace_location[3]; float texspace_size[3]; BKE_mesh_texspace_get(const_cast<::Mesh *>(b_mesh.texcomesh ? b_mesh.texcomesh : &b_mesh), texspace_location, texspace_size); float3 *generated = attr->data_float3(); for (const int i : positions.index_range()) { blender::float3 value; if (orco) { madd_v3_v3v3v3(value, texspace_location, orco[i], texspace_size); } else { value = positions[i]; } generated[i] = make_float3(value[0], value[1], value[2]) * size - loc; } } auto clamp_material_index = [&](const int material_index) -> int { return clamp(material_index, 0, used_shaders.size() - 1); }; /* create faces */ if (!subdivision) { int *triangles = mesh->get_triangles().data(); bool *smooth = mesh->get_smooth().data(); int *shader = mesh->get_shader().data(); const blender::Span corner_tris = b_mesh.corner_tris(); for (const int i : corner_tris.index_range()) { const blender::int3 &tri = corner_tris[i]; triangles[i * 3 + 0] = corner_verts[tri[0]]; triangles[i * 3 + 1] = corner_verts[tri[1]]; triangles[i * 3 + 2] = corner_verts[tri[2]]; } if (!material_indices.is_empty()) { const blender::Span tri_faces = b_mesh.corner_tri_faces(); for (const int i : corner_tris.index_range()) { shader[i] = clamp_material_index(material_indices[tri_faces[i]]); } } else { std::fill(shader, shader + numtris, 0); } if (!sharp_faces.is_empty() && !(use_corner_normals && !corner_normals.is_empty())) { const blender::Span tri_faces = b_mesh.corner_tri_faces(); for (const int i : corner_tris.index_range()) { smooth[i] = !sharp_faces[tri_faces[i]]; } } else { /* If only face normals are needed, all faces are sharp. */ std::fill(smooth, smooth + numtris, normals_domain != blender::bke::MeshNormalDomain::Face); } if (use_corner_normals && !corner_normals.is_empty()) { for (const int i : corner_tris.index_range()) { const blender::int3 &tri = corner_tris[i]; for (int i = 0; i < 3; i++) { const int corner = tri[i]; const int vert = corner_verts[corner]; const float *normal = corner_normals[corner]; N[vert] = make_float3(normal[0], normal[1], normal[2]); } } } mesh->tag_triangles_modified(); mesh->tag_shader_modified(); mesh->tag_smooth_modified(); } else { int *subd_start_corner = mesh->get_subd_start_corner().data(); int *subd_num_corners = mesh->get_subd_num_corners().data(); int *subd_shader = mesh->get_subd_shader().data(); bool *subd_smooth = mesh->get_subd_smooth().data(); int *subd_ptex_offset = mesh->get_subd_ptex_offset().data(); int *subd_face_corners = mesh->get_subd_face_corners().data(); if (!sharp_faces.is_empty() && !use_corner_normals) { for (int i = 0; i < numfaces; i++) { subd_smooth[i] = !sharp_faces[i]; } } else { std::fill(subd_smooth, subd_smooth + numfaces, true); } if (!material_indices.is_empty()) { for (int i = 0; i < numfaces; i++) { subd_shader[i] = clamp_material_index(material_indices[i]); } } else { std::fill(subd_shader, subd_shader + numfaces, 0); } std::copy(corner_verts.data(), corner_verts.data() + corner_verts.size(), subd_face_corners); const blender::OffsetIndices faces = b_mesh.faces(); int ptex_offset = 0; for (const int i : faces.index_range()) { const blender::IndexRange face = faces[i]; subd_start_corner[i] = face.start(); subd_num_corners[i] = face.size(); subd_ptex_offset[i] = ptex_offset; const int num_ptex = (face.size() == 4) ? 1 : face.size(); ptex_offset += num_ptex; } mesh->tag_subd_face_corners_modified(); mesh->tag_subd_start_corner_modified(); mesh->tag_subd_num_corners_modified(); mesh->tag_subd_shader_modified(); mesh->tag_subd_smooth_modified(); mesh->tag_subd_ptex_offset_modified(); } /* Create all needed attributes. * The calculate functions will check whether they're needed or not. */ if (mesh->need_attribute(scene, ATTR_STD_POINTINESS)) { attr_create_pointiness(mesh, positions, b_mesh.vert_normals(), b_mesh.edges(), subdivision); } attr_create_random_per_island(scene, mesh, b_mesh, subdivision); attr_create_generic(scene, mesh, b_mesh, subdivision, need_motion, motion_scale); if (subdivision) { attr_create_subd_uv_map(scene, mesh, b_mesh, blender_uv_names); } else { attr_create_uv_map(scene, mesh, b_mesh, blender_uv_names); } /* For volume objects, create a matrix to transform from object space to * mesh texture space. this does not work with deformations but that can * probably only be done well with a volume grid mapping of coordinates. */ if (mesh->need_attribute(scene, ATTR_STD_GENERATED_TRANSFORM)) { Attribute *attr = mesh->attributes.add(ATTR_STD_GENERATED_TRANSFORM); Transform *tfm = attr->data_transform(); float3 loc; float3 size; mesh_texture_space(b_mesh, loc, size); *tfm = transform_translate(-loc) * transform_scale(size); } } static void create_subd_mesh(Scene *scene, Mesh *mesh, BObjectInfo &b_ob_info, const ::Mesh &b_mesh, const array &used_shaders, const bool need_motion, const float motion_scale, const float dicing_rate, const int max_subdivisions) { BL::Object b_ob = b_ob_info.real_object; BL::SubsurfModifier subsurf_mod(b_ob.modifiers[b_ob.modifiers.length() - 1]); const bool use_creases = subsurf_mod.use_creases(); create_mesh(scene, mesh, b_mesh, used_shaders, need_motion, motion_scale, true); if (use_creases) { const blender::VArraySpan creases = *b_mesh.attributes().lookup( "crease_edge", blender::bke::AttrDomain::Edge); if (!creases.is_empty()) { size_t num_creases = 0; for (const int i : creases.index_range()) { if (creases[i] != 0.0f) { num_creases++; } } mesh->reserve_subd_creases(num_creases); const blender::Span edges = b_mesh.edges(); for (const int i : edges.index_range()) { const float crease = creases[i]; if (crease != 0.0f) { const blender::int2 &b_edge = edges[i]; mesh->add_edge_crease(b_edge[0], b_edge[1], crease); } } } const blender::VArraySpan vert_creases = *b_mesh.attributes().lookup( "crease_vert", blender::bke::AttrDomain::Point); if (!vert_creases.is_empty()) { for (const int i : vert_creases.index_range()) { if (vert_creases[i] != 0.0f) { mesh->add_vertex_crease(i, vert_creases[i]); } } } } /* Set subd parameters. */ PointerRNA cobj = RNA_pointer_get(&b_ob.ptr, "cycles"); const float subd_dicing_rate = max(0.1f, RNA_float_get(&cobj, "dicing_rate") * dicing_rate); mesh->set_subd_dicing_rate(subd_dicing_rate); mesh->set_subd_max_level(max_subdivisions); mesh->set_subd_objecttoworld(get_transform(b_ob.matrix_world())); } /* Sync */ void BlenderSync::sync_mesh(BObjectInfo &b_ob_info, Mesh *mesh) { /* make a copy of the shaders as the caller in the main thread still need them for syncing the * attributes */ array used_shaders = mesh->get_used_shaders(); Mesh new_mesh; new_mesh.set_used_shaders(used_shaders); if (view_layer.use_surfaces) { object_subdivision_to_mesh(b_ob_info.real_object, new_mesh, preview, use_adaptive_subdivision); BL::Mesh b_mesh = object_to_mesh(b_ob_info); if (b_mesh) { /* Motion blur attribute is relative to seconds, we need it relative to frames. */ const bool need_motion = object_need_motion_attribute(b_ob_info, scene); const float motion_scale = (need_motion) ? scene->motion_shutter_time() / (b_scene.render().fps() / b_scene.render().fps_base()) : 0.0f; /* Sync mesh itself. */ if (new_mesh.get_subdivision_type() != Mesh::SUBDIVISION_NONE) { create_subd_mesh(scene, &new_mesh, b_ob_info, *static_cast(b_mesh.ptr.data), new_mesh.get_used_shaders(), need_motion, motion_scale, dicing_rate, max_subdivisions); } else { create_mesh(scene, &new_mesh, *static_cast(b_mesh.ptr.data), new_mesh.get_used_shaders(), need_motion, motion_scale, false); } free_object_to_mesh(b_ob_info, b_mesh); } } /* update original sockets */ mesh->clear_non_sockets(); for (const SocketType &socket : new_mesh.type->inputs) { /* Those sockets are updated in sync_object, so do not modify them. */ if (socket.name == "use_motion_blur" || socket.name == "used_shaders") { continue; } mesh->set_value(socket, new_mesh, socket); } mesh->attributes.update(std::move(new_mesh.attributes)); mesh->subd_attributes.update(std::move(new_mesh.subd_attributes)); mesh->set_num_subd_faces(new_mesh.get_num_subd_faces()); /* tag update */ const bool rebuild = (mesh->triangles_is_modified()) || (mesh->subd_num_corners_is_modified()) || (mesh->subd_shader_is_modified()) || (mesh->subd_smooth_is_modified()) || (mesh->subd_ptex_offset_is_modified()) || (mesh->subd_start_corner_is_modified()) || (mesh->subd_face_corners_is_modified()); mesh->tag_update(scene, rebuild); } void BlenderSync::sync_mesh_motion(BObjectInfo &b_ob_info, Mesh *mesh, const int motion_step) { /* Skip if no vertices were exported. */ const size_t numverts = mesh->get_verts().size(); if (numverts == 0) { return; } /* Skip objects without deforming modifiers. this is not totally reliable, * would need a more extensive check to see which objects are animated. */ BL::Mesh b_mesh_rna(PointerRNA_NULL); if (ccl::BKE_object_is_deform_modified(b_ob_info, b_scene, preview)) { /* get derived mesh */ b_mesh_rna = object_to_mesh(b_ob_info); } const std::string ob_name = b_ob_info.real_object.name(); /* TODO(sergey): Perform preliminary check for number of vertices. */ if (b_mesh_rna) { const ::Mesh &b_mesh = *static_cast(b_mesh_rna.ptr.data); const int b_verts_num = b_mesh.verts_num; const blender::Span positions = b_mesh.vert_positions(); if (positions.is_empty()) { free_object_to_mesh(b_ob_info, b_mesh_rna); return; } AttributeSet &attributes = mesh->get_subdivision_type() == Mesh::SUBDIVISION_NONE ? mesh->attributes : mesh->subd_attributes; /* Export deformed coordinates. */ /* Find attributes. */ Attribute *attr_mP = attributes.find(ATTR_STD_MOTION_VERTEX_POSITION); Attribute *attr_mN = attributes.find(ATTR_STD_MOTION_VERTEX_NORMAL); Attribute *attr_N = attributes.find(ATTR_STD_VERTEX_NORMAL); bool new_attribute = false; /* Add new attributes if they don't exist already. */ if (!attr_mP) { attr_mP = attributes.add(ATTR_STD_MOTION_VERTEX_POSITION); if (attr_N) { attr_mN = attributes.add(ATTR_STD_MOTION_VERTEX_NORMAL); } new_attribute = true; } /* Load vertex data from mesh. */ float3 *mP = attr_mP->data_float3() + motion_step * numverts; float3 *mN = (attr_mN) ? attr_mN->data_float3() + motion_step * numverts : nullptr; /* NOTE: We don't copy more that existing amount of vertices to prevent * possible memory corruption. */ for (int i = 0; i < std::min(b_verts_num, numverts); i++) { mP[i] = make_float3(positions[i][0], positions[i][1], positions[i][2]); } if (mN) { const blender::Span b_vert_normals = b_mesh.vert_normals(); for (int i = 0; i < std::min(b_verts_num, numverts); i++) { mN[i] = make_float3(b_vert_normals[i][0], b_vert_normals[i][1], b_vert_normals[i][2]); } } if (new_attribute) { /* In case of new attribute, we verify if there really was any motion. */ if (b_verts_num != numverts || memcmp(mP, mesh->get_verts().data(), sizeof(float3) * numverts) == 0) { /* no motion, remove attributes again */ if (b_verts_num != numverts) { VLOG_WARNING << "Topology differs, disabling motion blur for object " << ob_name; } else { VLOG_DEBUG << "No actual deformation motion for object " << ob_name; } attributes.remove(ATTR_STD_MOTION_VERTEX_POSITION); if (attr_mN) { attributes.remove(ATTR_STD_MOTION_VERTEX_NORMAL); } } else if (motion_step > 0) { VLOG_DEBUG << "Filling deformation motion for object " << ob_name; /* motion, fill up previous steps that we might have skipped because * they had no motion, but we need them anyway now */ const float3 *P = mesh->get_verts().data(); const float3 *N = (attr_N) ? attr_N->data_float3() : nullptr; for (int step = 0; step < motion_step; step++) { std::copy_n(P, numverts, attr_mP->data_float3() + step * numverts); if (attr_mN) { std::copy_n(N, numverts, attr_mN->data_float3() + step * numverts); } } } } else { if (b_verts_num != numverts) { VLOG_WARNING << "Topology differs, discarding motion blur for object " << ob_name << " at time " << motion_step; const float3 *P = mesh->get_verts().data(); const float3 *N = (attr_N) ? attr_N->data_float3() : nullptr; std::copy_n(P, numverts, mP); if (mN != nullptr) { std::copy_n(N, numverts, mN); } } } free_object_to_mesh(b_ob_info, b_mesh_rna); return; } /* No deformation on this frame, copy coordinates if other frames did have it. */ mesh->copy_center_to_motion_step(motion_step); } CCL_NAMESPACE_END