mirror of https://github.com/AxioDL/metaforce.git
438 lines
14 KiB
C++
438 lines
14 KiB
C++
#include "MeshOptimizer.hpp"
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#include <numeric>
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#include <cmath>
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namespace hecl::blender {
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logvisor::Module Log("MeshOptimizer");
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template <typename T>
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static void insert_unique_attr(std::unordered_map<T, uint32_t>& set, const T& attr) {
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if (set.find(attr) == set.cend()) {
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size_t sz = set.size();
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set.insert(std::make_pair(attr, sz));
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}
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}
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template <typename T>
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static std::vector<T> sort_unordered_map(const std::unordered_map<T, uint32_t>& map) {
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struct SortableIterator {
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typename std::unordered_map<T, uint32_t>::const_iterator it;
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bool operator<(const SortableIterator& other) const { return it->second < other.it->second; }
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explicit SortableIterator(typename std::unordered_map<T, uint32_t>::const_iterator i) : it(i) {}
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};
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std::vector<SortableIterator> to_sort;
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to_sort.reserve(map.size());
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for (auto I = map.cbegin(), E = map.cend(); I != E; ++I)
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to_sort.emplace_back(I);
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std::sort(to_sort.begin(), to_sort.end());
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std::vector<T> ret;
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ret.reserve(to_sort.size());
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for (const auto& sit : to_sort)
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ret.push_back(sit.it->first);
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return ret;
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}
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static bool material_is_lightmapped(const Material& mat) {
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auto search = mat.iprops.find("retro_lightmapped");
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if (search != mat.iprops.cend())
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return search->second;
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return false;
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}
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MeshOptimizer::Vertex::Vertex(Connection& conn) {
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co.read(conn);
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Index skin_count(conn);
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if (skin_count.val > MaxSkinEntries)
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Log.report(logvisor::Fatal, "Skin entry overflow %u/%u", skin_count.val, MaxSkinEntries);
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for (uint32_t i = 0; i < skin_count.val; ++i)
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skin_ents[i] = Mesh::SkinBind(conn);
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}
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MeshOptimizer::Loop::Loop(Connection& conn, uint32_t color_count, uint32_t uv_count) {
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normal.read(conn);
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for (uint32_t i = 0; i < color_count; ++i)
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colors[i].read(conn);
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for (uint32_t i = 0; i < uv_count; ++i)
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uvs[i].read(conn);
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vert = Index(conn).val;
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edge = Index(conn).val;
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face = Index(conn).val;
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link_loop_next = Index(conn).val;
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link_loop_prev = Index(conn).val;
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link_loop_radial_next = Index(conn).val;
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link_loop_radial_prev = Index(conn).val;
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}
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MeshOptimizer::Edge::Edge(Connection& conn) {
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for (uint32_t i = 0; i < 2; ++i)
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verts[i] = Index(conn).val;
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Index face_count(conn);
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if (face_count > MaxLinkFaces)
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Log.report(logvisor::Fatal, "Face overflow %u/%u", face_count.val, MaxLinkFaces);
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for (uint32_t i = 0; i < face_count.val; ++i)
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link_faces[i] = Index(conn).val;
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is_contiguous = Boolean(conn).val;
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}
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MeshOptimizer::Face::Face(Connection& conn) {
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normal.read(conn);
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centroid.read(conn);
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material_index = Index(conn).val;
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for (uint32_t i = 0; i < 3; ++i)
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loops[i] = Index(conn).val;
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}
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uint32_t MeshOptimizer::get_pos_idx(const Vertex& v) const {
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auto search = b_pos.find(v.co);
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if (search != b_pos.cend())
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return search->second;
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return UINT32_MAX;
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}
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uint32_t MeshOptimizer::get_norm_idx(const Loop& l) const {
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auto search = b_norm.find(l.normal);
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if (search != b_norm.cend())
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return search->second;
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return UINT32_MAX;
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}
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uint32_t MeshOptimizer::get_skin_idx(const Vertex& v) const {
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auto search = b_skin.find(v.skin_ents);
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if (search != b_skin.cend())
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return search->second;
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return UINT32_MAX;
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}
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uint32_t MeshOptimizer::get_color_idx(const Loop& l, uint32_t cidx) const {
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auto search = b_color.find(l.colors[cidx]);
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if (search != b_color.cend())
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return search->second;
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return UINT32_MAX;
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}
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uint32_t MeshOptimizer::get_uv_idx(const Loop& l, uint32_t uidx) const {
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if (use_luvs && uidx == 0 && material_is_lightmapped(materials[faces[l.face].material_index])) {
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auto search = b_luv.find(l.uvs[0]);
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if (search != b_luv.cend())
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return search->second;
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return UINT32_MAX;
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}
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auto search = b_uv.find(l.uvs[uidx]);
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if (search != b_uv.cend())
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return search->second;
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return UINT32_MAX;
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}
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bool MeshOptimizer::loops_contiguous(const Loop& la, const Loop& lb) const {
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if (la.vert != lb.vert)
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return false;
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if (get_norm_idx(la) != get_norm_idx(lb))
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return false;
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for (uint32_t i = 0; i < color_count; ++i)
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if (get_color_idx(la, i) != get_color_idx(lb, i))
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return false;
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for (uint32_t i = 0; i < uv_count; ++i)
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if (get_uv_idx(la, i) != get_uv_idx(lb, i))
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return false;
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return true;
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}
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bool MeshOptimizer::splitable_edge(const Edge& e) const {
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if (!e.is_contiguous)
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return false;
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for (uint32_t vidx : e.verts) {
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const Loop* found = nullptr;
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for (uint32_t fidx : e.link_faces) {
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for (uint32_t lidx : faces[fidx].loops) {
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if (loops[lidx].vert == vidx) {
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if (!found) {
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found = &loops[lidx];
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break;
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} else {
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if (!loops_contiguous(*found, loops[lidx]))
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return true;
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break;
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}
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}
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}
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}
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}
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return false;
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}
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void MeshOptimizer::sort_faces_by_skin_group(std::vector<uint32_t>& sfaces) const {
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std::vector<uint32_t> faces_out;
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faces_out.reserve(sfaces.size());
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std::unordered_set<uint32_t> done_sg;
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uint32_t ref_sg = UINT32_MAX;
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while (faces_out.size() < sfaces.size()) {
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for (uint32_t f : sfaces) {
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bool found = false;
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for (uint32_t l : faces[f].loops) {
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uint32_t skin_idx = get_skin_idx(verts[loops[l].vert]);
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if (done_sg.find(skin_idx) == done_sg.end()) {
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ref_sg = skin_idx;
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done_sg.insert(skin_idx);
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found = true;
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break;
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}
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}
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if (found)
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break;
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}
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for (uint32_t f : sfaces) {
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if (std::find(faces_out.begin(), faces_out.end(), f) != faces_out.end())
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continue;
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for (uint32_t l : faces[f].loops) {
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uint32_t skin_idx = get_skin_idx(verts[loops[l].vert]);
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if (skin_idx == ref_sg) {
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faces_out.push_back(f);
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break;
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}
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}
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}
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}
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sfaces = std::move(faces_out);
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}
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std::pair<uint32_t, uint32_t> MeshOptimizer::strip_next_loop(uint32_t prev_loop, uint32_t out_count) const {
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if (out_count & 0x1) {
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uint32_t radial_loop = loops[prev_loop].link_loop_radial_next;
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uint32_t loop = loops[radial_loop].link_loop_prev;
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return {loop, loop};
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} else {
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uint32_t radial_loop = loops[prev_loop].link_loop_radial_prev;
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uint32_t loop = loops[radial_loop].link_loop_next;
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return {loops[loop].link_loop_next, loop};
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}
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}
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static float Magnitude(const Vector3f& v) { return std::sqrt(v.val.simd.dot3(v.val.simd)); }
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static void Normalize(Vector3f& v) {
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float mag = 1.f / Magnitude(v);
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v.val.simd *= athena::simd<float>(mag);
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}
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Mesh::Surface MeshOptimizer::generate_surface(std::vector<uint32_t>& island_faces, uint32_t mat_idx) const {
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Mesh::Surface ret = {};
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ret.materialIdx = mat_idx;
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/* Centroid of surface */
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for (const auto& f : island_faces)
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ret.centroid.val.simd += faces[f].centroid.val.simd;
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ret.centroid.val.simd /= athena::simd<float>(island_faces.size());
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/* AABB of surface */
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ret.aabbMin.val.simd = athena::simd<float>(FLT_MAX);
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ret.aabbMax.val.simd = athena::simd<float>(-FLT_MAX);
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for (const auto& f : island_faces) {
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for (const auto& l : faces[f].loops) {
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const Vertex& v = verts[loops[l].vert];
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for (int c = 0; c < 3; ++c) {
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if (v.co.val.simd[c] < ret.aabbMin.val.simd[c])
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ret.aabbMin.val.simd[c] = v.co.val.simd[c];
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if (v.co.val.simd[c] > ret.aabbMax.val.simd[c])
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ret.aabbMax.val.simd[c] = v.co.val.simd[c];
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}
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}
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}
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/* Average normal of surface */
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for (const auto& f : island_faces)
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ret.reflectionNormal.val.simd += faces[f].normal.val.simd;
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Normalize(ret.reflectionNormal);
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/* Verts themselves */
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uint32_t prev_loop_emit = UINT32_MAX;
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std::vector<std::pair<std::vector<uint32_t>, std::vector<uint32_t>>> sel_lists_local;
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sel_lists_local.reserve(loops.size());
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while (island_faces.size()) {
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sel_lists_local.clear();
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for (uint32_t start_face : island_faces) {
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for (uint32_t l : faces[start_face].loops) {
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std::vector<uint32_t> island_local(island_faces);
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uint32_t prev_loop = loops[l].link_loop_next;
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uint32_t loop = loops[prev_loop].link_loop_next;
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std::vector<uint32_t> sel_list;
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sel_list.reserve(64);
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sel_list.push_back(l);
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sel_list.push_back(prev_loop);
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sel_list.push_back(loop);
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island_local.erase(std::find(island_local.begin(), island_local.end(), start_face));
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while (true) {
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const Edge& prev_edge = edges[loops[prev_loop].edge];
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if (!prev_edge.is_contiguous || prev_edge.tag)
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break;
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std::tie(loop, prev_loop) = strip_next_loop(prev_loop, sel_list.size());
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uint32_t face = loops[loop].face;
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auto search = std::find(island_local.begin(), island_local.end(), face);
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if (search == island_local.end())
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break;
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sel_list.push_back(loop);
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island_local.erase(search);
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}
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sel_lists_local.emplace_back(std::move(sel_list), std::move(island_local));
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}
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}
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uint32_t max_count = 0;
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const std::vector<uint32_t>* max_sl = nullptr;
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const std::vector<uint32_t>* max_island_faces = nullptr;
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for (const auto& sl : sel_lists_local) {
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if (sl.first.size() > max_count) {
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max_count = sl.first.size();
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max_sl = &sl.first;
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max_island_faces = &sl.second;
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}
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}
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assert(max_island_faces && "Should not be null");
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assert(max_island_faces->size() < island_faces.size() && "Infinite loop condition");
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island_faces = std::move(*max_island_faces);
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if (prev_loop_emit != UINT32_MAX)
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ret.verts.emplace_back();
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for (uint32_t loop : *max_sl) {
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ret.verts.emplace_back();
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const auto& l = loops[loop];
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auto& vert = ret.verts.back();
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vert.iPos = get_pos_idx(verts[l.vert]);
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vert.iNorm = get_norm_idx(l);
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for (uint32_t i = 0; i < color_count; ++i)
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vert.iColor[i] = get_color_idx(l, i);
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for (uint32_t i = 0; i < uv_count; ++i)
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vert.iUv[i] = get_uv_idx(l, i);
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vert.iSkin = get_skin_idx(verts[l.vert]);
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prev_loop_emit = loop;
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}
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}
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return ret;
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}
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void MeshOptimizer::optimize(Mesh& mesh, int max_skin_banks) const {
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mesh.topology = HMDLTopology::TriStrips;
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mesh.pos = sort_unordered_map(b_pos);
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mesh.norm = sort_unordered_map(b_norm);
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mesh.colorLayerCount = color_count;
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mesh.color = sort_unordered_map(b_color);
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mesh.uvLayerCount = uv_count;
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mesh.uv = sort_unordered_map(b_uv);
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mesh.luv = sort_unordered_map(b_luv);
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mesh.skins = sort_unordered_map(b_skin);
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/* Sort materials by pass index */
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std::vector<uint32_t> sorted_material_idxs(materials.size());
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std::iota(sorted_material_idxs.begin(), sorted_material_idxs.end(), 0);
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std::sort(sorted_material_idxs.begin(), sorted_material_idxs.end(),
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[this](uint32_t a, uint32_t b) { return materials[a].passIndex < materials[b].passIndex; });
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/* Generate island surfaces */
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std::vector<uint32_t> mat_faces_rem, the_list;
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mat_faces_rem.reserve(faces.size());
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the_list.reserve(faces.size());
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std::unordered_set<uint32_t> skin_slot_set;
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skin_slot_set.reserve(b_skin.size());
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for (uint32_t mat_idx : sorted_material_idxs) {
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const auto& mat = materials[mat_idx];
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mat_faces_rem.clear();
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for (auto B = faces.begin(), I = B, E = faces.end(); I != E; ++I) {
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if (I->material_index == mat_idx)
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mat_faces_rem.push_back(I - B);
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}
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if (b_skin.size())
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sort_faces_by_skin_group(mat_faces_rem);
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size_t rem_count = mat_faces_rem.size();
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while (rem_count) {
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the_list.clear();
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skin_slot_set.clear();
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for (uint32_t& f : mat_faces_rem) {
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if (f == UINT32_MAX)
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continue;
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if (b_skin.size()) {
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bool brk = false;
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for (const auto& l : faces[f].loops) {
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const Vertex& v = verts[loops[l].vert];
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uint32_t skin_idx = get_skin_idx(v);
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if (skin_slot_set.find(skin_idx) == skin_slot_set.end()) {
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if (max_skin_banks > 0 && skin_slot_set.size() == max_skin_banks) {
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brk = true;
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break;
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}
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skin_slot_set.insert(skin_idx);
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}
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}
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if (brk)
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break;
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}
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the_list.push_back(f);
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f = UINT32_MAX;
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--rem_count;
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}
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mesh.surfaces.push_back(generate_surface(the_list, mat_idx));
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}
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}
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}
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MeshOptimizer::MeshOptimizer(Connection& conn, const std::vector<Material>& materials, bool use_luvs)
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: materials(materials), use_luvs(use_luvs) {
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color_count = Index(conn).val;
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if (color_count > MaxColorLayers)
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Log.report(logvisor::Fatal, "Color layer overflow %u/%u", color_count, MaxColorLayers);
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uv_count = Index(conn).val;
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if (uv_count > MaxUVLayers)
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Log.report(logvisor::Fatal, "UV layer overflow %u/%u", uv_count, MaxUVLayers);
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/* Simultaneously load topology objects and build unique mapping indices */
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Index vert_count(conn);
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verts.reserve(vert_count.val);
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b_pos.reserve(vert_count.val);
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b_skin.reserve(vert_count.val * 4);
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for (uint32_t i = 0; i < vert_count.val; ++i) {
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verts.emplace_back(conn);
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insert_unique_attr(b_pos, verts.back().co);
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if (verts.back().skin_ents[0].valid())
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insert_unique_attr(b_skin, verts.back().skin_ents);
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}
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Index loop_count(conn);
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loops.reserve(loop_count.val);
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b_norm.reserve(loop_count.val);
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if (use_luvs) {
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b_uv.reserve(std::max(int(loop_count.val) - 1, 0) * uv_count);
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b_luv.reserve(loop_count.val);
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} else {
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b_uv.reserve(loop_count.val * uv_count);
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}
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for (uint32_t i = 0; i < loop_count.val; ++i) {
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loops.emplace_back(conn, color_count, uv_count);
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insert_unique_attr(b_norm, loops.back().normal);
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for (const auto& c : loops.back().colors)
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insert_unique_attr(b_color, c);
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if (use_luvs && material_is_lightmapped(materials[faces[loops.back().face].material_index])) {
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insert_unique_attr(b_luv, loops.back().uvs[0]);
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for (auto I = std::begin(loops.back().uvs) + 1, E = std::end(loops.back().uvs); I != E; ++I)
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insert_unique_attr(b_uv, *I);
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} else {
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for (const auto& c : loops.back().uvs)
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insert_unique_attr(b_uv, c);
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}
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}
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Index edge_count(conn);
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edges.reserve(edge_count.val);
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for (uint32_t i = 0; i < edge_count.val; ++i)
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edges.emplace_back(conn);
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Index face_count(conn);
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faces.reserve(face_count.val);
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for (uint32_t i = 0; i < face_count.val; ++i)
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faces.emplace_back(conn);
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/* Cache edges that should block tristrip traversal */
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for (auto& e : edges)
|
|
e.tag = splitable_edge(e);
|
|
}
|
|
|
|
}
|