Fix path sorting

This commit is contained in:
Pavel Mikus 2023-04-25 18:30:52 +02:00 committed by Pavel Mikuš
parent ebbbb1505c
commit aa85d050fe
3 changed files with 118 additions and 142 deletions

View File

@ -2,12 +2,15 @@
#define SRC_LIBSLIC3R_PATH_SORTING_HPP_
#include "AABBTreeLines.hpp"
#include "BoundingBox.hpp"
#include "Line.hpp"
#include "ankerl/unordered_dense.h"
#include <algorithm>
#include <iterator>
#include <libslic3r/Point.hpp>
#include <libslic3r/Polygon.hpp>
#include <libslic3r/ExPolygon.hpp>
#include <limits>
#include <type_traits>
#include <unordered_set>
@ -21,154 +24,122 @@ namespace Algorithm {
// to the second, then they touch.
// convert_to_lines is a lambda that should accept the path as argument and return it as Lines vector, in correct order.
template<typename RandomAccessIterator, typename ToLines>
void sort_paths(RandomAccessIterator begin, RandomAccessIterator end, RandomAccessIterator last_seed, double touch_limit_distance, ToLines convert_to_lines)
void sort_paths(RandomAccessIterator begin, RandomAccessIterator end, Point start, double touch_limit_distance, ToLines convert_to_lines)
{
size_t paths_count = std::distance(begin, end);
if (paths_count <= 1)
return;
auto paths_min_distance = [](const AABBTreeLines::LinesDistancer<Line> &left, const AABBTreeLines::LinesDistancer<Line> &right) {
double min_distance = std::numeric_limits<double>::max();
for (const Line &l : left.get_lines()) {
if (double dist = right.distance_from_lines<false>(l.a); dist < min_distance) {
min_distance = dist;
}
}
if (double dist = right.distance_from_lines<false>(left.get_lines().back().b); dist < min_distance) {
min_distance = dist;
}
for (const Line &l : right.get_lines()) {
if (double dist = left.distance_from_lines<false>(l.a); dist < min_distance) {
min_distance = dist;
}
}
if (double dist = left.distance_from_lines<false>(right.get_lines().back().b); dist < min_distance) {
min_distance = dist;
}
return min_distance;
};
std::vector<AABBTreeLines::LinesDistancer<Line>> distancers(paths_count);
for (size_t path_idx = 0; path_idx < paths_count; path_idx++) {
distancers[path_idx] = AABBTreeLines::LinesDistancer<Line>{convert_to_lines(*std::next(begin, path_idx))};
}
auto paths_touch = [touch_limit_distance](const AABBTreeLines::LinesDistancer<Line> &left,
const AABBTreeLines::LinesDistancer<Line> &right) {
for (const Line &l : left.get_lines()) {
if (right.distance_from_lines<false>(l.a) < touch_limit_distance) {
return true;
}
}
if (right.distance_from_lines<false>(left.get_lines().back().b) < touch_limit_distance) {
return true;
}
for (const Line &l : right.get_lines()) {
if (left.distance_from_lines<false>(l.a) < touch_limit_distance) {
return true;
}
}
if (left.distance_from_lines<false>(right.get_lines().back().b) < touch_limit_distance) {
return true;
}
return false;
};
std::vector<std::unordered_set<size_t>> dependencies(paths_count);
for (size_t path_idx = 0; path_idx < paths_count; path_idx++) {
for (size_t prev_path_idx = 0; prev_path_idx < path_idx; prev_path_idx++) {
if (paths_touch(distancers[path_idx], distancers[prev_path_idx])) {
dependencies[path_idx].insert(prev_path_idx);
dependencies[prev_path_idx].insert(path_idx);
for (size_t next_path_idx = path_idx + 1; next_path_idx < paths_count; next_path_idx++) {
double dist = paths_min_distance(distancers[path_idx], distancers[next_path_idx]);
if (dist < touch_limit_distance) {
dependencies[next_path_idx].insert(path_idx);
}
}
}
size_t index_of_last_fixed = std::distance(begin, last_seed);
std::vector<bool> processed(paths_count, false);
for (size_t path_idx = 0; path_idx <= index_of_last_fixed; path_idx++) {
processed[path_idx] = true;
for (size_t path_idx = 0; path_idx < paths_count; path_idx++) {
std::cout << "Dependencies of " << path_idx << " are ";
for (size_t dep : dependencies[path_idx])
std::cout << dep << ", ";
std::cout << std::endl;
}
for (size_t i = index_of_last_fixed + 1; i < paths_count; i++) {
bool change = false;
for (size_t path_idx = index_of_last_fixed + 1; path_idx < paths_count; path_idx++) {
if (processed[path_idx])
continue;
auto processed_dep = std::find_if(dependencies[path_idx].begin(), dependencies[path_idx].end(),
[&](size_t dep) { return processed[dep]; });
if (processed_dep != dependencies[path_idx].end()) {
for (auto it = dependencies[path_idx].begin(); it != dependencies[path_idx].end();) {
if (!processed[*it]) {
dependencies[*it].insert(path_idx);
dependencies[path_idx].erase(it++);
} else {
++it;
}
}
processed[path_idx] = true;
change = true;
}
}
if (!change) {
break;
}
}
Point current_point = start;
Point current_point = distancers.begin()->get_lines().begin()->a;
size_t null_idx = size_t(-1);
std::vector<std::pair<size_t, bool>> correct_order_and_direction(paths_count);
size_t unsorted_idx = 0;
size_t null_idx = size_t(-1);
size_t next_idx = null_idx;
bool reverse = false;
while (true) {
if (next_idx == null_idx) { // find next pidx to print
double dist = std::numeric_limits<double>::max();
while (unsorted_idx < paths_count) {
next_idx = null_idx;
double lines_dist = std::numeric_limits<double>::max();
for (size_t path_idx = 0; path_idx < paths_count; path_idx++) {
if (!dependencies[path_idx].empty())
continue;
const auto& lines = distancers[path_idx].get_lines();
double dist_a = (lines.front().a - current_point).cast<double>().squaredNorm();
if (dist_a < dist) {
dist = dist_a;
next_idx = path_idx;
reverse = false;
}
double dist_b = (lines.back().b - current_point).cast<double>().squaredNorm();
if (dist_b < dist) {
dist = dist_b;
next_idx = path_idx;
reverse = true;
}
}
if (next_idx == null_idx) {
break;
}
} else {
// we have valid next_idx, sort it, update dependencies, update current point and potentialy set new next_idx
std::iter_swap(std::next(begin, unsorted_idx), std::next(begin, next_idx)); // next_path is now at sorted spot
if (reverse) {
std::next(begin, unsorted_idx)->reverse();
}
unsorted_idx++;
assert(dependencies[next_idx].empty());
dependencies[next_idx].insert(null_idx);
double ldist = distancers[path_idx].distance_from_lines<false>(current_point);
if (ldist < lines_dist) {
const auto &lines = distancers[path_idx].get_lines();
double dist_a = line_alg::distance_to(lines.front(), current_point);
double dist_b = line_alg::distance_to(lines.back(), current_point);
if (std::abs(dist_a - dist_b) < touch_limit_distance) {
dist_a = (lines.front().a - current_point).squaredNorm();
dist_b = (lines.back().b - current_point).squaredNorm();
}
next_idx = path_idx;
reverse = dist_b < dist_a;
}
}
// we have valid next_idx, sort it, update dependencies, update current point
correct_order_and_direction[next_idx] = {unsorted_idx, reverse};
unsorted_idx++;
current_point = reverse ? distancers[next_idx].get_lines().front().a : distancers[next_idx].get_lines().back().b;
dependencies[next_idx].insert(null_idx); // prevent it from being selected again
for (size_t path_idx = 0; path_idx < paths_count; path_idx++) {
dependencies[path_idx].erase(next_idx);
}
double dist = std::numeric_limits<double>::max();
next_idx = null_idx;
}
for (size_t path_idx = next_idx + 1; path_idx < paths_count; path_idx++) {
if (!dependencies[path_idx].empty()) {
continue;
std::cout << "Final order is ";
for (size_t path_idx = 0; path_idx < paths_count; path_idx++) {
std::cout << correct_order_and_direction[path_idx].first << ", ";
}
const auto &lines = distancers[path_idx].get_lines();
double dist_a = (lines.front().a - current_point).cast<double>().squaredNorm();
if (dist_a < dist) {
dist = dist_a;
next_idx = path_idx;
reverse = false;
}
double dist_b = (lines.back().b - current_point).cast<double>().squaredNorm();
if (dist_b < dist) {
dist = dist_b;
next_idx = path_idx;
reverse = true;
std::cout << std::endl;
for (size_t path_idx = 0; path_idx < paths_count; path_idx++) {
if (correct_order_and_direction[path_idx].second) {
std::next(begin, path_idx)->reverse();
}
}
if (dist > scaled(5.0)) {
next_idx = null_idx;
for (size_t i = 0; i < correct_order_and_direction.size() - 1; i++) {
bool swapped = false;
for (size_t j = 0; j < correct_order_and_direction.size() - i - 1; j++) {
if (correct_order_and_direction[j].first > correct_order_and_direction[j + 1].first) {
std::swap(correct_order_and_direction[j], correct_order_and_direction[j + 1]);
std::iter_swap(std::next(begin, j), std::next(begin, j + 1));
swapped = true;
}
}
if (swapped == false) {
break;
}
}
}
}
}
}} // namespace Slic3r::Algorithm
#endif /*SRC_LIBSLIC3R_PATH_SORTING_HPP_*/

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@ -4,6 +4,7 @@
#include "AABBTreeLines.hpp"
#include "Algorithm/PathSorting.hpp"
#include "BoundingBox.hpp"
#include "ExPolygon.hpp"
#include "FillEnsuring.hpp"
#include "KDTreeIndirect.hpp"
@ -322,14 +323,14 @@ ThickPolylines FillEnsuring::fill_surface_arachne(const Surface *surface, const
}
// gaps_for_additional_filling = opening_ex(gaps_for_additional_filling, 0.3 * scaled_spacing);
// BoundingBox bbox = get_extents(filled_area);
// bbox.offset(scale_(1.));
// ::Slic3r::SVG svg(debug_out_path(("surface" + std::to_string(surface->area())).c_str()).c_str(), bbox);
// svg.draw(to_lines(filled_area), "red", scale_(0.4));
// svg.draw(to_lines(reconstructed_area), "blue", scale_(0.3));
// svg.draw(to_lines(gaps_for_additional_filling), "green", scale_(0.2));
// svg.draw(vertical_lines, "black", scale_(0.1));
// svg.Close();
BoundingBox bbox = get_extents(filled_area);
bbox.offset(scale_(1.));
::Slic3r::SVG svg(debug_out_path(("surface" + std::to_string(surface->area())).c_str()).c_str(), bbox);
svg.draw(to_lines(filled_area), "red", scale_(0.4));
svg.draw(to_lines(reconstructed_area), "blue", scale_(0.3));
svg.draw(to_lines(gaps_for_additional_filling), "green", scale_(0.2));
svg.draw(vertical_lines, "black", scale_(0.1));
svg.Close();
for (ExPolygon &ex_poly : gaps_for_additional_filling) {
Point bbox_size = ex_poly.contour.bounding_box().size();
@ -447,8 +448,6 @@ ThickPolylines FillEnsuring::fill_surface_arachne(const Surface *surface, const
}
}
rotate_thick_polylines(thick_polylines_out, cos(-aligning_angle), sin(-aligning_angle));
thick_polylines_out.erase(std::remove_if(thick_polylines_out.begin(), thick_polylines_out.end(),
[scaled_spacing](const ThickPolyline &tp) {
return tp.length() < scaled_spacing &&
@ -457,8 +456,12 @@ ThickPolylines FillEnsuring::fill_surface_arachne(const Surface *surface, const
}),
thick_polylines_out.end());
Algorithm::sort_paths(thick_polylines_out.begin(), thick_polylines_out.end(), thick_polylines_out.begin(), scaled_spacing * 2,
[](const ThickPolyline &tp) {
std::sort(thick_polylines_out.begin(), thick_polylines_out.end(), [](const ThickPolyline &left, const ThickPolyline &right) {
return BoundingBox(left.points).min.x() < BoundingBox(right.points).min.x();
});
Algorithm::sort_paths(thick_polylines_out.begin(), thick_polylines_out.end(), bb.min, scaled_spacing * 1.2, [](const ThickPolyline
&tp) {
Lines ls;
Point prev = tp.first_point();
for (size_t i = 1; i < tp.points.size(); i++) {
@ -468,6 +471,7 @@ ThickPolylines FillEnsuring::fill_surface_arachne(const Surface *surface, const
return ls;
});
rotate_thick_polylines(thick_polylines_out, cos(-aligning_angle), sin(-aligning_angle));
return thick_polylines_out;
}

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@ -40,6 +40,7 @@
#include <stack>
#include <string>
#include <unordered_map>
#include <unordered_set>
#include <utility>
#include <vector>