PrusaSlicer-NonPlainar/src/libslic3r/Arrange.cpp

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#include "Arrange.hpp"
#include "Geometry.hpp"
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#include "SVG.hpp"
#include "MTUtils.hpp"
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#include <libnest2d/backends/clipper/geometries.hpp>
#include <libnest2d/optimizers/nlopt/subplex.hpp>
#include <libnest2d/placers/nfpplacer.hpp>
#include <libnest2d/selections/firstfit.hpp>
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#include <numeric>
#include <ClipperUtils.hpp>
#include <boost/geometry/index/rtree.hpp>
#if defined(_MSC_VER) && defined(__clang__)
#define BOOST_NO_CXX17_HDR_STRING_VIEW
#endif
#include <boost/multiprecision/integer.hpp>
#include <boost/rational.hpp>
namespace libnest2d {
#if !defined(_MSC_VER) && defined(__SIZEOF_INT128__) && !defined(__APPLE__)
using LargeInt = __int128;
#else
using LargeInt = boost::multiprecision::int128_t;
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template<> struct _NumTag<LargeInt>
{
using Type = ScalarTag;
};
#endif
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template<class T> struct _NumTag<boost::rational<T>>
{
using Type = RationalTag;
};
namespace nfp {
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template<class S> struct NfpImpl<S, NfpLevel::CONVEX_ONLY>
{
NfpResult<S> operator()(const S &sh, const S &other)
{
return nfpConvexOnly<S, boost::rational<LargeInt>>(sh, other);
}
};
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} // namespace nfp
} // namespace libnest2d
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namespace Slic3r {
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template<class Tout = double, class = FloatingOnly<Tout>, int...EigenArgs>
inline SLIC3R_CONSTEXPR Eigen::Matrix<Tout, 2, EigenArgs...> unscaled(
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const ClipperLib::IntPoint &v) SLIC3R_NOEXCEPT
{
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return Eigen::Matrix<Tout, 2, EigenArgs...>{unscaled<Tout>(v.X),
unscaled<Tout>(v.Y)};
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}
namespace arrangement {
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using namespace libnest2d;
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namespace clppr = ClipperLib;
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// Get the libnest2d types for clipper backend
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using Item = _Item<clppr::Polygon>;
using Box = _Box<clppr::IntPoint>;
using Circle = _Circle<clppr::IntPoint>;
using Segment = _Segment<clppr::IntPoint>;
using MultiPolygon = TMultiShape<clppr::Polygon>;
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// Summon the spatial indexing facilities from boost
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namespace bgi = boost::geometry::index;
using SpatElement = std::pair<Box, unsigned>;
using SpatIndex = bgi::rtree< SpatElement, bgi::rstar<16, 4> >;
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using ItemGroup = std::vector<std::reference_wrapper<Item>>;
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// A coefficient used in separating bigger items and smaller items.
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const double BIG_ITEM_TRESHOLD = 0.02;
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// Fill in the placer algorithm configuration with values carefully chosen for
// Slic3r.
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template<class PConf>
void fillConfig(PConf& pcfg) {
// Align the arranged pile into the center of the bin
pcfg.alignment = PConf::Alignment::CENTER;
// Start placing the items from the center of the print bed
pcfg.starting_point = PConf::Alignment::CENTER;
// TODO cannot use rotations until multiple objects of same geometry can
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// handle different rotations.
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pcfg.rotations = { 0.0 };
// The accuracy of optimization.
// Goes from 0.0 to 1.0 and scales performance as well
pcfg.accuracy = 0.65f;
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// Allow parallel execution.
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pcfg.parallel = true;
}
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// Apply penalty to object function result. This is used only when alignment
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// after arrange is explicitly disabled (PConfig::Alignment::DONT_ALIGN)
double fixed_overfit(const std::tuple<double, Box>& result, const Box &binbb)
{
double score = std::get<0>(result);
Box pilebb = std::get<1>(result);
Box fullbb = sl::boundingBox(pilebb, binbb);
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auto diff = double(fullbb.area()) - binbb.area();
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if(diff > 0) score += diff;
return score;
}
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// A class encapsulating the libnest2d Nester class and extending it with other
// management and spatial index structures for acceleration.
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template<class TBin>
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class AutoArranger {
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public:
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// Useful type shortcuts...
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using Placer = typename placers::_NofitPolyPlacer<clppr::Polygon, TBin>;
using Selector = selections::_FirstFitSelection<clppr::Polygon>;
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using Packer = _Nester<Placer, Selector>;
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using PConfig = typename Packer::PlacementConfig;
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using Distance = TCoord<PointImpl>;
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protected:
Packer m_pck;
PConfig m_pconf; // Placement configuration
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TBin m_bin;
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double m_bin_area;
#ifdef _MSC_VER
#pragma warning(push)
#pragma warning(disable: 4244)
#pragma warning(disable: 4267)
#endif
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SpatIndex m_rtree; // spatial index for the normal (bigger) objects
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SpatIndex m_smallsrtree; // spatial index for only the smaller items
#ifdef _MSC_VER
#pragma warning(pop)
#endif
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double m_norm; // A coefficient to scale distances
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MultiPolygon m_merged_pile; // The already merged pile (vector of items)
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Box m_pilebb; // The bounding box of the merged pile.
ItemGroup m_remaining; // Remaining items
ItemGroup m_items; // allready packed items
size_t m_item_count = 0; // Number of all items to be packed
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template<class T> ArithmeticOnly<T, double> norm(T val)
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{
return double(val) / m_norm;
}
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// This is "the" object function which is evaluated many times for each
// vertex (decimated with the accuracy parameter) of each object.
// Therefore it is upmost crucial for this function to be as efficient
// as it possibly can be but at the same time, it has to provide
// reasonable results.
std::tuple<double /*score*/, Box /*farthest point from bin center*/>
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objfunc(const Item &item, const clppr::IntPoint &bincenter)
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{
const double bin_area = m_bin_area;
const SpatIndex& spatindex = m_rtree;
const SpatIndex& smalls_spatindex = m_smallsrtree;
// We will treat big items (compared to the print bed) differently
auto isBig = [bin_area](double a) {
return a/bin_area > BIG_ITEM_TRESHOLD ;
};
// Candidate item bounding box
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auto ibb = item.boundingBox();
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// Calculate the full bounding box of the pile with the candidate item
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auto fullbb = sl::boundingBox(m_pilebb, ibb);
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// The bounding box of the big items (they will accumulate in the center
// of the pile
Box bigbb;
if(spatindex.empty()) bigbb = fullbb;
else {
auto boostbb = spatindex.bounds();
boost::geometry::convert(boostbb, bigbb);
}
// Will hold the resulting score
double score = 0;
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// Density is the pack density: how big is the arranged pile
double density = 0;
// Distinction of cases for the arrangement scene
enum e_cases {
// This branch is for big items in a mixed (big and small) scene
// OR for all items in a small-only scene.
BIG_ITEM,
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// This branch is for the last big item in a mixed scene
LAST_BIG_ITEM,
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// For small items in a mixed scene.
SMALL_ITEM
} compute_case;
bool bigitems = isBig(item.area()) || spatindex.empty();
if(bigitems && !m_remaining.empty()) compute_case = BIG_ITEM;
else if (bigitems && m_remaining.empty()) compute_case = LAST_BIG_ITEM;
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else compute_case = SMALL_ITEM;
switch (compute_case) {
case BIG_ITEM: {
const clppr::IntPoint& minc = ibb.minCorner(); // bottom left corner
const clppr::IntPoint& maxc = ibb.maxCorner(); // top right corner
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// top left and bottom right corners
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clppr::IntPoint top_left{getX(minc), getY(maxc)};
clppr::IntPoint bottom_right{getX(maxc), getY(minc)};
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// Now the distance of the gravity center will be calculated to the
// five anchor points and the smallest will be chosen.
std::array<double, 5> dists;
auto cc = fullbb.center(); // The gravity center
dists[0] = pl::distance(minc, cc);
dists[1] = pl::distance(maxc, cc);
dists[2] = pl::distance(ibb.center(), cc);
dists[3] = pl::distance(top_left, cc);
dists[4] = pl::distance(bottom_right, cc);
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// The smalles distance from the arranged pile center:
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double dist = norm(*(std::min_element(dists.begin(), dists.end())));
double bindist = norm(pl::distance(ibb.center(), bincenter));
dist = 0.8 * dist + 0.2 * bindist;
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// Prepare a variable for the alignment score.
// This will indicate: how well is the candidate item
// aligned with its neighbors. We will check the alignment
// with all neighbors and return the score for the best
// alignment. So it is enough for the candidate to be
// aligned with only one item.
auto alignment_score = 1.0;
auto query = bgi::intersects(ibb);
auto& index = isBig(item.area()) ? spatindex : smalls_spatindex;
// Query the spatial index for the neighbors
std::vector<SpatElement> result;
result.reserve(index.size());
index.query(query, std::back_inserter(result));
// now get the score for the best alignment
for(auto& e : result) {
auto idx = e.second;
Item& p = m_items[idx];
auto parea = p.area();
if(std::abs(1.0 - parea/item.area()) < 1e-6) {
auto bb = sl::boundingBox(p.boundingBox(), ibb);
auto bbarea = bb.area();
auto ascore = 1.0 - (item.area() + parea)/bbarea;
if(ascore < alignment_score) alignment_score = ascore;
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}
}
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density = std::sqrt(norm(fullbb.width()) * norm(fullbb.height()));
double R = double(m_remaining.size()) / m_item_count;
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// The final mix of the score is the balance between the
// distance from the full pile center, the pack density and
// the alignment with the neighbors
if (result.empty())
score = 0.50 * dist + 0.50 * density;
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else
score = R * 0.60 * dist +
(1.0 - R) * 0.20 * density +
0.20 * alignment_score;
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break;
}
case LAST_BIG_ITEM: {
score = norm(pl::distance(ibb.center(), m_pilebb.center()));
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break;
}
case SMALL_ITEM: {
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// Here there are the small items that should be placed around the
// already processed bigger items.
// No need to play around with the anchor points, the center will be
// just fine for small items
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score = norm(pl::distance(ibb.center(), bigbb.center()));
break;
}
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}
return std::make_tuple(score, fullbb);
}
std::function<double(const Item&)> get_objfn();
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public:
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AutoArranger(const TBin & bin,
Distance dist,
std::function<void(unsigned)> progressind,
std::function<bool(void)> stopcond)
: m_pck(bin, dist)
, m_bin(bin)
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, m_bin_area(sl::area(bin))
, m_norm(std::sqrt(m_bin_area))
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{
fillConfig(m_pconf);
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// Set up a callback that is called just before arranging starts
// This functionality is provided by the Nester class (m_pack).
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m_pconf.before_packing =
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[this](const MultiPolygon& merged_pile, // merged pile
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const ItemGroup& items, // packed items
const ItemGroup& remaining) // future items to be packed
{
m_items = items;
m_merged_pile = merged_pile;
m_remaining = remaining;
m_pilebb = sl::boundingBox(merged_pile);
m_rtree.clear();
m_smallsrtree.clear();
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// We will treat big items (compared to the print bed) differently
auto isBig = [this](double a) {
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return a / m_bin_area > BIG_ITEM_TRESHOLD ;
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};
for(unsigned idx = 0; idx < items.size(); ++idx) {
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Item& itm = items[idx];
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if(isBig(itm.area())) m_rtree.insert({itm.boundingBox(), idx});
m_smallsrtree.insert({itm.boundingBox(), idx});
}
};
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m_pconf.object_function = get_objfn();
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if (progressind) m_pck.progressIndicator(progressind);
if (stopcond) m_pck.stopCondition(stopcond);
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m_pck.configure(m_pconf);
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}
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AutoArranger(const TBin & bin,
std::function<void(unsigned)> progressind,
std::function<bool(void)> stopcond)
: AutoArranger{bin, 0 /* no min distance */, progressind, stopcond}
{}
template<class It> inline void operator()(It from, It to) {
m_rtree.clear();
m_item_count += size_t(to - from);
m_pck.execute(from, to);
m_item_count = 0;
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}
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inline void preload(std::vector<Item>& fixeditems) {
m_pconf.alignment = PConfig::Alignment::DONT_ALIGN;
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auto bb = sl::boundingBox(m_bin);
auto bbcenter = bb.center();
m_pconf.object_function = [this, bb, bbcenter](const Item &item) {
return fixed_overfit(objfunc(item, bbcenter), bb);
};
// Build the rtree for queries to work
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for(unsigned idx = 0; idx < fixeditems.size(); ++idx) {
Item& itm = fixeditems[idx];
itm.markAsFixed();
}
m_pck.configure(m_pconf);
m_item_count += fixeditems.size();
}
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};
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template<> std::function<double(const Item&)> AutoArranger<Box>::get_objfn()
{
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auto bincenter = m_bin.center();
return [this, bincenter](const Item &itm) {
auto result = objfunc(itm, bincenter);
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double score = std::get<0>(result);
auto& fullbb = std::get<1>(result);
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double miss = Placer::overfit(fullbb, m_bin);
miss = miss > 0? miss : 0;
score += miss*miss;
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return score;
};
}
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template<> std::function<double(const Item&)> AutoArranger<Circle>::get_objfn()
{
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auto bincenter = m_bin.center();
return [this, bincenter](const Item &item) {
auto result = objfunc(item, bincenter);
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double score = std::get<0>(result);
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auto isBig = [this](const Item& itm) {
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return itm.area() / m_bin_area > BIG_ITEM_TRESHOLD ;
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};
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if(isBig(item)) {
auto mp = m_merged_pile;
mp.push_back(item.transformedShape());
auto chull = sl::convexHull(mp);
double miss = Placer::overfit(chull, m_bin);
if(miss < 0) miss = 0;
score += miss*miss;
}
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return score;
};
}
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// Specialization for a generalized polygon.
// Warning: this is unfinished business. It may or may not work.
template<>
std::function<double(const Item &)> AutoArranger<clppr::Polygon>::get_objfn()
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{
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auto bincenter = sl::boundingBox(m_bin).center();
return [this, bincenter](const Item &item) {
return std::get<0>(objfunc(item, bincenter));
};
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}
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inline Circle to_lnCircle(const CircleBed& circ) {
return Circle({circ.center()(0), circ.center()(1)}, circ.radius());
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}
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// Get the type of bed geometry from a simple vector of points.
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void BedShapeHint::reset(BedShapes type)
{
if (m_type != type) {
if (m_type == bsIrregular)
m_bed.polygon.Slic3r::Polyline::~Polyline();
else if (type == bsIrregular)
::new (&m_bed.polygon) Polyline();
}
m_type = type;
}
BedShapeHint::BedShapeHint(const Polyline &bed) {
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auto x = [](const Point& p) { return p(X); };
auto y = [](const Point& p) { return p(Y); };
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auto width = [x](const BoundingBox& box) {
return x(box.max) - x(box.min);
};
auto height = [y](const BoundingBox& box) {
return y(box.max) - y(box.min);
};
auto area = [&width, &height](const BoundingBox& box) {
double w = width(box);
double h = height(box);
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return w * h;
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};
auto poly_area = [](Polyline p) {
Polygon pp; pp.points.reserve(p.points.size() + 1);
pp.points = std::move(p.points);
pp.points.emplace_back(pp.points.front());
return std::abs(pp.area());
};
auto distance_to = [x, y](const Point& p1, const Point& p2) {
double dx = x(p2) - x(p1);
double dy = y(p2) - y(p1);
return std::sqrt(dx*dx + dy*dy);
};
auto bb = bed.bounding_box();
auto isCircle = [bb, distance_to](const Polyline& polygon) {
auto center = bb.center();
std::vector<double> vertex_distances;
double avg_dist = 0;
for (auto pt: polygon.points)
{
double distance = distance_to(center, pt);
vertex_distances.push_back(distance);
avg_dist += distance;
}
avg_dist /= vertex_distances.size();
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CircleBed ret(center, avg_dist);
for(auto el : vertex_distances)
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{
if (std::abs(el - avg_dist) > 10 * SCALED_EPSILON) {
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ret = CircleBed();
break;
}
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}
return ret;
};
auto parea = poly_area(bed);
if( (1.0 - parea/area(bb)) < 1e-3 ) {
m_type = BedShapes::bsBox;
m_bed.box = bb;
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}
else if(auto c = isCircle(bed)) {
m_type = BedShapes::bsCircle;
m_bed.circ = c;
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} else {
assert(m_type != BedShapes::bsIrregular);
m_type = BedShapes::bsIrregular;
::new (&m_bed.polygon) Polyline(bed);
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}
}
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BedShapeHint &BedShapeHint::operator=(BedShapeHint &&cpy)
{
reset(cpy.m_type);
switch(m_type) {
case bsBox: m_bed.box = std::move(cpy.m_bed.box); break;
case bsCircle: m_bed.circ = std::move(cpy.m_bed.circ); break;
case bsIrregular: m_bed.polygon = std::move(cpy.m_bed.polygon); break;
case bsInfinite: m_bed.infbed = std::move(cpy.m_bed.infbed); break;
case bsUnknown: break;
}
return *this;
}
BedShapeHint &BedShapeHint::operator=(const BedShapeHint &cpy)
{
reset(cpy.m_type);
switch(m_type) {
case bsBox: m_bed.box = cpy.m_bed.box; break;
case bsCircle: m_bed.circ = cpy.m_bed.circ; break;
case bsIrregular: m_bed.polygon = cpy.m_bed.polygon; break;
case bsInfinite: m_bed.infbed = cpy.m_bed.infbed; break;
case bsUnknown: break;
}
return *this;
}
template<class Bin> void remove_large_items(std::vector<Item> &items, Bin &&bin)
{
auto it = items.begin();
while (it != items.end())
sl::isInside(it->transformedShape(), bin) ?
++it : it = items.erase(it);
}
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template<class BinT> // Arrange for arbitrary bin type
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void _arrange(
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std::vector<Item> & shapes,
std::vector<Item> & excludes,
const BinT & bin,
coord_t minobjd,
std::function<void(unsigned)> progressfn,
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std::function<bool()> stopfn)
{
// Integer ceiling the min distance from the bed perimeters
coord_t md = minobjd - 2 * scaled(0.1 + EPSILON);
md = (md % 2) ? md / 2 + 1 : md / 2;
auto corrected_bin = bin;
sl::offset(corrected_bin, md);
AutoArranger<BinT> arranger{corrected_bin, progressfn, stopfn};
auto infl = coord_t(std::ceil(minobjd / 2.0));
for (Item& itm : shapes) itm.inflate(infl);
for (Item& itm : excludes) itm.inflate(infl);
remove_large_items(excludes, corrected_bin);
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// If there is something on the plate
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if (!excludes.empty()) arranger.preload(excludes);
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std::vector<std::reference_wrapper<Item>> inp;
inp.reserve(shapes.size() + excludes.size());
for (auto &itm : shapes ) inp.emplace_back(itm);
for (auto &itm : excludes) inp.emplace_back(itm);
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arranger(inp.begin(), inp.end());
for (Item &itm : inp) itm.inflate(-infl);
}
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// The final client function for arrangement. A progress indicator and
// a stop predicate can be also be passed to control the process.
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void arrange(ArrangePolygons & arrangables,
const ArrangePolygons & excludes,
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coord_t min_obj_dist,
const BedShapeHint & bedhint,
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std::function<void(unsigned)> progressind,
std::function<bool()> stopcondition)
{
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namespace clppr = ClipperLib;
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std::vector<Item> items, fixeditems;
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items.reserve(arrangables.size());
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// Create Item from Arrangeable
auto process_arrangeable = [](const ArrangePolygon &arrpoly,
std::vector<Item> & outp)
{
Polygon p = arrpoly.poly.contour;
const Vec2crd &offs = arrpoly.translation;
double rotation = arrpoly.rotation;
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if (p.is_counter_clockwise()) p.reverse();
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clppr::Polygon clpath(Slic3rMultiPoint_to_ClipperPath(p));
if (!clpath.Contour.empty()) {
auto firstp = clpath.Contour.front();
clpath.Contour.emplace_back(firstp);
}
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outp.emplace_back(std::move(clpath));
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outp.back().rotation(rotation);
outp.back().translation({offs.x(), offs.y()});
outp.back().binId(arrpoly.bed_idx);
outp.back().priority(arrpoly.priority);
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};
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for (ArrangePolygon &arrangeable : arrangables)
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process_arrangeable(arrangeable, items);
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for (const ArrangePolygon &fixed: excludes)
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process_arrangeable(fixed, fixeditems);
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for (Item &itm : fixeditems) itm.inflate(scaled(-2. * EPSILON));
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auto &cfn = stopcondition;
auto &pri = progressind;
switch (bedhint.get_type()) {
case bsBox: {
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// Create the arranger for the box shaped bed
BoundingBox bbb = bedhint.get_box();
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Box binbb{{bbb.min(X), bbb.min(Y)}, {bbb.max(X), bbb.max(Y)}};
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_arrange(items, fixeditems, binbb, min_obj_dist, pri, cfn);
break;
}
case bsCircle: {
auto cc = to_lnCircle(bedhint.get_circle());
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_arrange(items, fixeditems, cc, min_obj_dist, pri, cfn);
break;
}
case bsIrregular: {
auto ctour = Slic3rMultiPoint_to_ClipperPath(bedhint.get_irregular());
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auto irrbed = sl::create<clppr::Polygon>(std::move(ctour));
BoundingBox polybb(bedhint.get_irregular());
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_arrange(items, fixeditems, irrbed, min_obj_dist, pri, cfn);
break;
}
case bsInfinite: {
const InfiniteBed& nobin = bedhint.get_infinite();
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auto infbb = Box::infinite({nobin.center.x(), nobin.center.y()});
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_arrange(items, fixeditems, infbb, min_obj_dist, pri, cfn);
break;
}
case bsUnknown: {
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// We know nothing about the bed, let it be infinite and zero centered
_arrange(items, fixeditems, Box::infinite(), min_obj_dist, pri, cfn);
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break;
}
}
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for(size_t i = 0; i < items.size(); ++i) {
clppr::IntPoint tr = items[i].translation();
arrangables[i].translation = {coord_t(tr.X), coord_t(tr.Y)};
arrangables[i].rotation = items[i].rotation();
arrangables[i].bed_idx = items[i].binId();
}
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}
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// Arrange, without the fixed items (excludes)
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void arrange(ArrangePolygons & inp,
coord_t min_d,
const BedShapeHint & bedhint,
std::function<void(unsigned)> prfn,
std::function<bool()> stopfn)
{
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arrange(inp, {}, min_d, bedhint, prfn, stopfn);
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}
} // namespace arr
} // namespace Slic3r