oops, missing
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#include "thekla_atlas.h"
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#include <cfloat>
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#include "nvmesh/halfedge/Edge.h"
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#include "nvmesh/halfedge/Mesh.h"
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#include "nvmesh/halfedge/Face.h"
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#include "nvmesh/halfedge/Vertex.h"
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#include "nvmesh/param/Atlas.h"
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#include "nvmath/Vector.inl"
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#include "nvmath/ftoi.h"
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#include "nvcore/Array.inl"
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using namespace Thekla;
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using namespace nv;
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inline Atlas_Output_Mesh * set_error(Atlas_Error * error, Atlas_Error code) {
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if (error) *error = code;
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return NULL;
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}
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static void input_to_mesh(const Atlas_Input_Mesh * input, HalfEdge::Mesh * mesh, Atlas_Error * error) {
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Array<uint> canonicalMap;
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canonicalMap.reserve(input->vertex_count);
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for (int i = 0; i < input->vertex_count; i++) {
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const Atlas_Input_Vertex & input_vertex = input->vertex_array[i];
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const float * pos = input_vertex.position;
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const float * nor = input_vertex.normal;
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const float * tex = input_vertex.uv;
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HalfEdge::Vertex * vertex = mesh->addVertex(Vector3(pos[0], pos[1], pos[2]));
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vertex->nor.set(nor[0], nor[1], nor[2]);
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vertex->tex.set(tex[0], tex[1]);
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canonicalMap.append(input_vertex.first_colocal);
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}
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mesh->linkColocalsWithCanonicalMap(canonicalMap);
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const int face_count = input->face_count;
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int non_manifold_faces = 0;
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for (int i = 0; i < face_count; i++) {
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const Atlas_Input_Face & input_face = input->face_array[i];
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int v0 = input_face.vertex_index[0];
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int v1 = input_face.vertex_index[1];
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int v2 = input_face.vertex_index[2];
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HalfEdge::Face * face = mesh->addFace(v0, v1, v2);
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if (face != NULL) {
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face->material = input_face.material_index;
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}
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else {
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non_manifold_faces++;
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}
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}
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mesh->linkBoundary();
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if (non_manifold_faces != 0 && error != NULL) {
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*error = Atlas_Error_Invalid_Mesh_Non_Manifold;
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}
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}
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static Atlas_Output_Mesh * mesh_atlas_to_output(const HalfEdge::Mesh * mesh, const Atlas & atlas, Atlas_Error * error) {
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Atlas_Output_Mesh * output = new Atlas_Output_Mesh;
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const MeshCharts * charts = atlas.meshAt(0);
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// Allocate vertices.
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const int vertex_count = charts->vertexCount();
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output->vertex_count = vertex_count;
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output->vertex_array = new Atlas_Output_Vertex[vertex_count];
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int w = 0;
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int h = 0;
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// Output vertices.
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const int chart_count = charts->chartCount();
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for (int i = 0; i < chart_count; i++) {
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const Chart * chart = charts->chartAt(i);
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uint vertexOffset = charts->vertexCountBeforeChartAt(i);
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const uint chart_vertex_count = chart->vertexCount();
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for (uint v = 0; v < chart_vertex_count; v++) {
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Atlas_Output_Vertex & output_vertex = output->vertex_array[vertexOffset + v];
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uint original_vertex = chart->mapChartVertexToOriginalVertex(v);
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output_vertex.xref = original_vertex;
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Vector2 uv = chart->chartMesh()->vertexAt(v)->tex;
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output_vertex.uv[0] = uv.x;
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output_vertex.uv[1] = uv.y;
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w = max(w, ftoi_ceil(uv.x));
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h = max(h, ftoi_ceil(uv.y));
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}
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}
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const int face_count = mesh->faceCount();
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output->index_count = face_count * 3;
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output->index_array = new int[face_count * 3];
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// Set face indices.
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for (int f = 0; f < face_count; f++) {
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uint c = charts->faceChartAt(f);
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uint i = charts->faceIndexWithinChartAt(f);
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uint vertexOffset = charts->vertexCountBeforeChartAt(c);
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const Chart * chart = charts->chartAt(c);
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nvDebugCheck(chart->faceAt(i) == f);
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const HalfEdge::Face * face = chart->chartMesh()->faceAt(i);
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const HalfEdge::Edge * edge = face->edge;
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output->index_array[3*f+0] = vertexOffset + edge->vertex->id;
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output->index_array[3*f+1] = vertexOffset + edge->next->vertex->id;
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output->index_array[3*f+2] = vertexOffset + edge->next->next->vertex->id;
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}
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*error = Atlas_Error_Success;
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output->atlas_width = w;
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output->atlas_height = h;
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return output;
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}
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void Thekla::atlas_set_default_options(Atlas_Options * options) {
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if (options != NULL) {
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// These are the default values we use on The Witness.
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options->charter = Atlas_Charter_Default;
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options->charter_options.witness.proxy_fit_metric_weight = 2.0f;
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options->charter_options.witness.roundness_metric_weight = 0.01f;
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options->charter_options.witness.straightness_metric_weight = 6.0f;
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options->charter_options.witness.normal_seam_metric_weight = 4.0f;
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options->charter_options.witness.texture_seam_metric_weight = 0.5f;
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options->charter_options.witness.max_chart_area = FLT_MAX;
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options->charter_options.witness.max_boundary_length = FLT_MAX;
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options->mapper = Atlas_Mapper_Default;
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options->packer = Atlas_Packer_Default;
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options->packer_options.witness.packing_quality = 0;
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options->packer_options.witness.texel_area = 8;
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options->packer_options.witness.block_align = true;
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options->packer_options.witness.conservative = false;
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}
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}
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Atlas_Output_Mesh * Thekla::atlas_generate(const Atlas_Input_Mesh * input, const Atlas_Options * options, Atlas_Error * error) {
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// Validate args.
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if (input == NULL || options == NULL || error == NULL) return set_error(error, Atlas_Error_Invalid_Args);
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// Validate options.
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if (options->charter != Atlas_Charter_Witness) {
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return set_error(error, Atlas_Error_Invalid_Options);
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}
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if (options->charter == Atlas_Charter_Witness) {
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// @@ Validate input options!
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}
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if (options->mapper != Atlas_Mapper_LSCM) {
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return set_error(error, Atlas_Error_Invalid_Options);
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}
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if (options->mapper == Atlas_Mapper_LSCM) {
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// No options.
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}
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if (options->packer != Atlas_Packer_Witness) {
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return set_error(error, Atlas_Error_Invalid_Options);
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}
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if (options->packer == Atlas_Packer_Witness) {
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// @@ Validate input options!
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}
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// Validate input mesh.
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for (int i = 0; i < input->face_count; i++) {
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int v0 = input->face_array[i].vertex_index[0];
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int v1 = input->face_array[i].vertex_index[1];
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int v2 = input->face_array[i].vertex_index[2];
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if (v0 < 0 || v0 >= input->vertex_count ||
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v1 < 0 || v1 >= input->vertex_count ||
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v2 < 0 || v2 >= input->vertex_count)
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{
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return set_error(error, Atlas_Error_Invalid_Mesh);
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}
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}
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// Build half edge mesh.
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AutoPtr<HalfEdge::Mesh> mesh(new HalfEdge::Mesh);
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input_to_mesh(input, mesh.ptr(), error);
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if (*error == Atlas_Error_Invalid_Mesh) {
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return NULL;
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}
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Atlas atlas;
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// Charter.
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if (options->charter == Atlas_Charter_Extract) {
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return set_error(error, Atlas_Error_Not_Implemented);
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}
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else if (options->charter == Atlas_Charter_Witness) {
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SegmentationSettings segmentation_settings;
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segmentation_settings.proxyFitMetricWeight = options->charter_options.witness.proxy_fit_metric_weight;
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segmentation_settings.roundnessMetricWeight = options->charter_options.witness.roundness_metric_weight;
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segmentation_settings.straightnessMetricWeight = options->charter_options.witness.straightness_metric_weight;
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segmentation_settings.normalSeamMetricWeight = options->charter_options.witness.normal_seam_metric_weight;
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segmentation_settings.textureSeamMetricWeight = options->charter_options.witness.texture_seam_metric_weight;
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segmentation_settings.maxChartArea = options->charter_options.witness.max_chart_area;
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segmentation_settings.maxBoundaryLength = options->charter_options.witness.max_boundary_length;
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Array<uint> uncharted_materials;
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atlas.computeCharts(mesh.ptr(), segmentation_settings, uncharted_materials);
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}
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if (atlas.hasFailed())
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return NULL;
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// Mapper.
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if (options->mapper == Atlas_Mapper_LSCM) {
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atlas.parameterizeCharts();
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}
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if (atlas.hasFailed())
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return NULL;
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// Packer.
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if (options->packer == Atlas_Packer_Witness) {
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int packing_quality = options->packer_options.witness.packing_quality;
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float texel_area = options->packer_options.witness.texel_area;
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int block_align = options->packer_options.witness.block_align;
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int conservative = options->packer_options.witness.conservative;
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/*float utilization =*/ atlas.packCharts(packing_quality, texel_area, block_align, conservative);
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}
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if (atlas.hasFailed())
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return NULL;
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// Build output mesh.
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return mesh_atlas_to_output(mesh.ptr(), atlas, error);
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}
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void Thekla::atlas_free(Atlas_Output_Mesh * output) {
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if (output != NULL) {
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delete [] output->vertex_array;
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delete [] output->index_array;
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delete output;
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}
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}
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@ -0,0 +1,116 @@
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// Thekla Atlas Generator
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namespace Thekla {
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enum Atlas_Charter {
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Atlas_Charter_Witness, // Options: threshold
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Atlas_Charter_Extract, // Options: ---
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Atlas_Charter_Default = Atlas_Charter_Witness
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};
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enum Atlas_Mapper {
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Atlas_Mapper_LSCM, // Options: ---
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Atlas_Mapper_Default = Atlas_Mapper_LSCM
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};
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enum Atlas_Packer {
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Atlas_Packer_Witness, // Options: texel_area
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Atlas_Packer_Default = Atlas_Packer_Witness
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};
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struct Atlas_Options {
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Atlas_Charter charter;
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union {
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struct {
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float proxy_fit_metric_weight;
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float roundness_metric_weight;
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float straightness_metric_weight;
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float normal_seam_metric_weight;
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float texture_seam_metric_weight;
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float max_chart_area;
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float max_boundary_length;
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} witness;
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struct {
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} extract;
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} charter_options;
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Atlas_Mapper mapper;
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union {
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} mapper_options;
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Atlas_Packer packer;
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union {
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struct {
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int packing_quality;
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float texel_area; // This is not really texel area, but 1 / texel width?
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bool block_align; // Align charts to 4x4 blocks.
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bool conservative; // Pack charts with extra padding.
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} witness;
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} packer_options;
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};
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struct Atlas_Input_Vertex {
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float position[3];
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float normal[3];
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float uv[2];
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int first_colocal;
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};
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struct Atlas_Input_Face {
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int vertex_index[3];
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int material_index;
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};
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struct Atlas_Input_Mesh {
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int vertex_count;
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int face_count;
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Atlas_Input_Vertex * vertex_array;
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Atlas_Input_Face * face_array;
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};
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struct Atlas_Output_Vertex {
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float uv[2];
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int xref; // Index of input vertex from which this output vertex originated.
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};
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struct Atlas_Output_Mesh {
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int atlas_width;
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int atlas_height;
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int vertex_count;
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int index_count;
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Atlas_Output_Vertex * vertex_array;
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int * index_array;
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};
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enum Atlas_Error {
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Atlas_Error_Success,
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Atlas_Error_Invalid_Args,
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Atlas_Error_Invalid_Options,
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Atlas_Error_Invalid_Mesh,
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Atlas_Error_Invalid_Mesh_Non_Manifold,
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Atlas_Error_Not_Implemented,
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};
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void atlas_set_default_options(Atlas_Options * options);
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Atlas_Output_Mesh * atlas_generate(const Atlas_Input_Mesh * input, const Atlas_Options * options, Atlas_Error * error);
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void atlas_free(Atlas_Output_Mesh * output);
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/*
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Should we represent the input mesh with an opaque structure that simply holds pointers to the user data? That would allow us to avoid having to copy attributes to an intermediate representation.
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struct Atlas_Input_Mesh;
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void mesh_set_vertex_position(Atlas_Input_Mesh * mesh, float * ptr, int stride);
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void mesh_set_vertex_normal(Atlas_Input_Mesh * mesh, float * ptr, int stride);
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void mesh_set_vertex_uv(Mesh * mesh, float * ptr, int stride);
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void mesh_set_index(Mesh * mesh, int * ptr);
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*/
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} // Thekla namespace
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