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#include <stack>
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#include <queue>
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#include <post_topo.hpp>
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std::vector<dynamic_bitset<>> propagate_subface_labels(size_t subface_count,
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const std::vector<polygon_face_t>& faces,
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const std::vector<std::vector<uint32_t>>& patches,
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const std::vector<std::vector<uint32_t>>& arrangement_cells,
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const std::vector<uint32_t>& shell_of_half_patch,
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const std::vector<std::vector<uint32_t>>& shells,
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const std::vector<uint32_t>& shell_to_cell)
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{
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// in turn: [subface_index][cell_index] = sign
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std::vector<dynamic_bitset<>> cell_subface_signs(subface_count, dynamic_bitset<>(arrangement_cells.size()));
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std::vector<bool> visited_cells(arrangement_cells.size(), false);
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std::vector<bool> visited_subfaces(subface_count, false);
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std::vector<std::vector<uint32_t>> cell_indices_of_inactive_subfaces(subface_count);
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std::queue<uint32_t> Q{};
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dynamic_bitset<> opposed_cells(arrangement_cells.size());
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std::vector<uint32_t> unique_opposed_cells{};
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Q.emplace(0);
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while (!Q.empty()) {
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const auto cell_index = Q.front();
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const auto cell = arrangement_cells[cell_index];
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Q.pop();
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if (!visited_cells[cell_index]) {
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visited_cells[cell_index] = true;
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opposed_cells.reset();
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unique_opposed_cells.clear();
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for (auto shell : cell) {
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for (auto half_patch : shells[shell]) {
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auto subface_label = faces[patches[half_patch / 2][0]].subface_index;
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// CAUTION: we assume that the sign is 1 when the surface is inside the sdf before
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// but in blobtree we assume that the sign is 0 when the surface is inside the sdf
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// so we need to flip the sign here
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// EDIT: to keep sign operation nice and easy, we'll just keep the sign being 1 when the surface is inside
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// the sdf
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bool sign = (half_patch % 2 == 0) ? 1 : 0;
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auto oppose_cell = shell_to_cell[shell_of_half_patch[sign ? (half_patch + 1) : (half_patch - 1)]];
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// bool sign = (half_patch % 2 == 0) ? 0 : 1;
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// auto oppose_cell = shell_to_cell[shell_of_half_patch[!sign ? (half_patch + 1) : (half_patch - 1)]];
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// sign broadcast
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if (oppose_cell != cell_index) {
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if (!opposed_cells[oppose_cell]) {
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for (uint32_t si = 0; si < subface_count; ++si)
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cell_subface_signs[si][oppose_cell] = cell_subface_signs[si][cell_index];
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opposed_cells[oppose_cell] = true;
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unique_opposed_cells.emplace_back(oppose_cell);
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if (!visited_cells[oppose_cell]) Q.emplace(oppose_cell);
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}
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cell_subface_signs[subface_label][oppose_cell] = !sign;
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}
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#ifndef RELEASE_BRANCH
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if (visited_subfaces[subface_label] != false && cell_subface_signs[subface_label][cell_index] != sign) {
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throw std::runtime_error("ERROR: Inconsistent Cell Function Labels.");
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}
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#endif
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cell_subface_signs[subface_label][cell_index] = sign;
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visited_subfaces[subface_label] = true;
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// propagate the function signs to all previously inactive cells
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if (cell_indices_of_inactive_subfaces[subface_label].size() > 0) {
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for (const auto cell_index : cell_indices_of_inactive_subfaces[subface_label]) {
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cell_subface_signs[subface_label][cell_index] = sign;
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}
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cell_indices_of_inactive_subfaces[subface_label].clear();
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}
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}
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}
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// fetch inactive subface index
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for (uint32_t subface_index = 0; subface_index < subface_count; subface_index++) {
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if (visited_subfaces[subface_index] == false) {
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cell_indices_of_inactive_subfaces[subface_index].emplace_back(cell_index);
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for (const auto& other_cell_index : unique_opposed_cells) {
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cell_indices_of_inactive_subfaces[subface_index].emplace_back(other_cell_index);
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}
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}
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}
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}
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}
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#ifndef RELEASE_BRANCH
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for (size_t i = 0; i < subface_count; ++i) {
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if (visited_subfaces[i] == false) { throw std::logic_error("ERROR: Still have sign-unknown subfaces."); }
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}
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#endif
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return cell_subface_signs;
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}
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dynamic_bitset<> filter_cells_by_boolean(const baked_blobtree_t& tree, std::vector<dynamic_bitset<>>& cell_primitive_signs)
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{
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struct compact_node_info {
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dynamic_bitset<> cell_signs{};
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uint32_t parent_index{};
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};
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std::stack<compact_node_info> stacked_nodes{};
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auto iter = tree.nodes.begin();
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stacked_nodes.emplace(compact_node_info{std::move(cell_primitive_signs[iter->primitive_index]), iter->parent_index});
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iter++;
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while (iter != tree.nodes.end()) {
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// each out iteration must start with leaf node, only 1 leaf node is absorbed in one iteration
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assert(iter->is_primitive_node());
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compact_node_info temp_info{std::move(cell_primitive_signs[iter->primitive_index]), iter->parent_index};
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iter++; // to parent or neighboring node
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while (!stacked_nodes.empty() && temp_info.parent_index == stacked_nodes.top().parent_index) {
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// do bool operation, util meet next primitive node.
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assert(iter->is_operation_node());
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// HINT: other_cell_signs here should always be left nodes
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const auto& other_cell_sign = stacked_nodes.top().cell_signs;
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switch (iter->get_operation()) {
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case internal::eNodeOperation::unionOp: temp_info.cell_signs |= other_cell_sign; break;
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case internal::eNodeOperation::intersectionOp: temp_info.cell_signs &= other_cell_sign; break;
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case internal::eNodeOperation::differenceOp:
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// stacked nodes are always left childs
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temp_info.cell_signs = other_cell_sign & ~temp_info.cell_signs;
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break;
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default: throw std::runtime_error("ERROR: baked blobtree with unknown type operation node"); break;
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}
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temp_info.parent_index = iter->parent_index;
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stacked_nodes.pop();
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iter++; // to parent or neighboring node
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}
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stacked_nodes.emplace(std::move(temp_info));
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}
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assert(stacked_nodes.size() == 1);
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assert(stacked_nodes.top().parent_index == 0xFFFFFFFF);
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// sign 0 in blobtree means inside, so we need to flip the sign
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// EDIT: no need to flip signs here
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return stacked_nodes.top().cell_signs;
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}
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