#include #include #include #include "printer_parts.hpp" //#include #include "../tools/svgtools.hpp" #include #if defined(_MSC_VER) && defined(__clang__) #define BOOST_NO_CXX17_HDR_STRING_VIEW #endif #include "boost/multiprecision/integer.hpp" #include "boost/rational.hpp" //#include "../tools/libnfpglue.hpp" //#include "../tools/nfp_svgnest_glue.hpp" namespace libnest2d { #if !defined(_MSC_VER) && defined(__SIZEOF_INT128__) && !defined(__APPLE__) using LargeInt = __int128; #else using LargeInt = boost::multiprecision::int128_t; template<> struct _NumTag { using Type = ScalarTag; }; #endif template struct _NumTag> { using Type = RationalTag; }; using RectangleItem = libnest2d::Rectangle; namespace nfp { template struct NfpImpl { NfpResult operator()(const S &sh, const S &other) { return nfpConvexOnly>(sh, other); } }; } } static std::vector& prusaParts() { static std::vector ret; if(ret.empty()) { ret.reserve(PRINTER_PART_POLYGONS.size()); for(auto& inp : PRINTER_PART_POLYGONS) ret.emplace_back(inp); } return ret; } TEST_CASE("Angles", "[Geometry]") { using namespace libnest2d; Degrees deg(180); Radians rad(deg); Degrees deg2(rad); REQUIRE(Approx(rad) == Pi); REQUIRE(Approx(deg) == 180); REQUIRE(Approx(deg2) == 180); REQUIRE(Approx(rad) == Radians(deg)); REQUIRE(Approx(Degrees(rad)) == deg); REQUIRE(rad == deg); Segment seg = {{0, 0}, {12, -10}}; REQUIRE(Degrees(seg.angleToXaxis()) > 270); REQUIRE(Degrees(seg.angleToXaxis()) < 360); seg = {{0, 0}, {12, 10}}; REQUIRE(Degrees(seg.angleToXaxis()) > 0); REQUIRE(Degrees(seg.angleToXaxis()) < 90); seg = {{0, 0}, {-12, 10}}; REQUIRE(Degrees(seg.angleToXaxis()) > 90); REQUIRE(Degrees(seg.angleToXaxis()) < 180); seg = {{0, 0}, {-12, -10}}; REQUIRE(Degrees(seg.angleToXaxis()) > 180); REQUIRE(Degrees(seg.angleToXaxis()) < 270); seg = {{0, 0}, {1, 0}}; REQUIRE(Degrees(seg.angleToXaxis()) == Approx(0.)); seg = {{0, 0}, {0, 1}}; REQUIRE(Degrees(seg.angleToXaxis()) == Approx(90.)); seg = {{0, 0}, {-1, 0}}; REQUIRE(Degrees(seg.angleToXaxis()) == Approx(180.)); seg = {{0, 0}, {0, -1}}; REQUIRE(Degrees(seg.angleToXaxis()) == Approx(270.)); } // Simple TEST_CASE, does not use gmock TEST_CASE("ItemCreationAndDestruction", "[Nesting]") { using namespace libnest2d; Item sh = { {0, 0}, {1, 0}, {1, 1}, {0, 1} }; REQUIRE(sh.vertexCount() == 4u); Item sh2 ({ {0, 0}, {1, 0}, {1, 1}, {0, 1} }); REQUIRE(sh2.vertexCount() == 4u); // copy Item sh3 = sh2; REQUIRE(sh3.vertexCount() == 4u); sh2 = {}; REQUIRE(sh2.vertexCount() == 0u); REQUIRE(sh3.vertexCount() == 4u); } TEST_CASE("boundingCircle", "[Geometry]") { using namespace libnest2d; using placers::boundingCircle; PolygonImpl p = {{{0, 10}, {10, 0}, {0, -10}, {0, 10}}, {}}; Circle c = boundingCircle(p); REQUIRE(c.center().X == 0); REQUIRE(c.center().Y == 0); REQUIRE(c.radius() == Approx(10)); shapelike::translate(p, PointImpl{10, 10}); c = boundingCircle(p); REQUIRE(c.center().X == 10); REQUIRE(c.center().Y == 10); REQUIRE(c.radius() == Approx(10)); auto parts = prusaParts(); int i = 0; for(auto& part : parts) { c = boundingCircle(part.transformedShape()); if(std::isnan(c.radius())) std::cout << "fail: radius is nan" << std::endl; else for(auto v : shapelike::contour(part.transformedShape()) ) { auto d = pointlike::distance(v, c.center()); if(d > c.radius() ) { auto e = std::abs( 1.0 - d/c.radius()); REQUIRE(e <= 1e-3); } } i++; } } TEST_CASE("Distance", "[Geometry]") { using namespace libnest2d; Point p1 = {0, 0}; Point p2 = {10, 0}; Point p3 = {10, 10}; REQUIRE(pointlike::distance(p1, p2) == Approx(10)); REQUIRE(pointlike::distance(p1, p3) == Approx(sqrt(200))); Segment seg(p1, p3); // REQUIRE(pointlike::distance(p2, seg) == Approx(7.0710678118654755)); auto result = pointlike::horizontalDistance(p2, seg); auto check = [](TCompute val, TCompute expected) { if(std::is_floating_point>::value) REQUIRE(static_cast(val) == Approx(static_cast(expected))); else REQUIRE(val == expected); }; REQUIRE(result.second); check(result.first, 10); result = pointlike::verticalDistance(p2, seg); REQUIRE(result.second); check(result.first, -10); result = pointlike::verticalDistance(Point{10, 20}, seg); REQUIRE(result.second); check(result.first, 10); Point p4 = {80, 0}; Segment seg2 = { {0, 0}, {0, 40} }; result = pointlike::horizontalDistance(p4, seg2); REQUIRE(result.second); check(result.first, 80); result = pointlike::verticalDistance(p4, seg2); // Point should not be related to the segment REQUIRE_FALSE(result.second); } TEST_CASE("Area", "[Geometry]") { using namespace libnest2d; RectangleItem rect(10, 10); REQUIRE(rect.area() == Approx(100)); RectangleItem rect2 = {100, 100}; REQUIRE(rect2.area() == Approx(10000)); Item item = { {61, 97}, {70, 151}, {176, 151}, {189, 138}, {189, 59}, {70, 59}, {61, 77}, {61, 97} }; REQUIRE(shapelike::area(item.transformedShape()) > 0 ); } TEST_CASE("IsPointInsidePolygon", "[Geometry]") { using namespace libnest2d; RectangleItem rect(10, 10); Point p = {1, 1}; REQUIRE(rect.isInside(p)); p = {11, 11}; REQUIRE_FALSE(rect.isInside(p)); p = {11, 12}; REQUIRE_FALSE(rect.isInside(p)); p = {3, 3}; REQUIRE(rect.isInside(p)); } //TEST_CASE(GeometryAlgorithms, Intersections) { // using namespace binpack2d; // RectangleItem rect(70, 30); // rect.translate({80, 60}); // RectangleItem rect2(80, 60); // rect2.translate({80, 0}); //// REQUIRE_FALSE(Item::intersects(rect, rect2)); // Segment s1({0, 0}, {10, 10}); // Segment s2({1, 1}, {11, 11}); // REQUIRE_FALSE(ShapeLike::intersects(s1, s1)); // REQUIRE_FALSE(ShapeLike::intersects(s1, s2)); //} TEST_CASE("LeftAndDownPolygon", "[Geometry]") { using namespace libnest2d; Box bin(100, 100); BottomLeftPlacer placer(bin); Item item = {{70, 75}, {88, 60}, {65, 50}, {60, 30}, {80, 20}, {42, 20}, {35, 35}, {35, 55}, {40, 75}, {70, 75}}; Item leftControl = { {40, 75}, {35, 55}, {35, 35}, {42, 20}, {0, 20}, {0, 75}, {40, 75}}; Item downControl = {{88, 60}, {88, 0}, {35, 0}, {35, 35}, {42, 20}, {80, 20}, {60, 30}, {65, 50}, {88, 60}}; Item leftp(placer.leftPoly(item)); REQUIRE(shapelike::isValid(leftp.rawShape()).first); REQUIRE(leftp.vertexCount() == leftControl.vertexCount()); for(unsigned long i = 0; i < leftControl.vertexCount(); i++) { REQUIRE(getX(leftp.vertex(i)) == getX(leftControl.vertex(i))); REQUIRE(getY(leftp.vertex(i)) == getY(leftControl.vertex(i))); } Item downp(placer.downPoly(item)); REQUIRE(shapelike::isValid(downp.rawShape()).first); REQUIRE(downp.vertexCount() == downControl.vertexCount()); for(unsigned long i = 0; i < downControl.vertexCount(); i++) { REQUIRE(getX(downp.vertex(i)) == getX(downControl.vertex(i))); REQUIRE(getY(downp.vertex(i)) == getY(downControl.vertex(i))); } } TEST_CASE("ArrangeRectanglesTight", "[Nesting]") { using namespace libnest2d; std::vector rects = { {80, 80}, {60, 90}, {70, 30}, {80, 60}, {60, 60}, {60, 40}, {40, 40}, {10, 10}, {10, 10}, {10, 10}, {10, 10}, {10, 10}, {5, 5}, {5, 5}, {5, 5}, {5, 5}, {5, 5}, {5, 5}, {5, 5}, {20, 20} }; Box bin(210, 250, {105, 125}); REQUIRE(bin.width() == 210); REQUIRE(bin.height() == 250); REQUIRE(getX(bin.center()) == 105); REQUIRE(getY(bin.center()) == 125); _Nester arrange(bin); arrange.execute(rects.begin(), rects.end()); auto max_group = std::max_element(rects.begin(), rects.end(), [](const Item &i1, const Item &i2) { return i1.binId() < i2.binId(); }); int groups = max_group == rects.end() ? 0 : max_group->binId() + 1; REQUIRE(groups == 1u); REQUIRE( std::all_of(rects.begin(), rects.end(), [](const RectangleItem &itm) { return itm.binId() != BIN_ID_UNSET; })); // check for no intersections, no containment: bool valid = true; for(Item& r1 : rects) { for(Item& r2 : rects) { if(&r1 != &r2 ) { valid = !Item::intersects(r1, r2) || Item::touches(r1, r2); REQUIRE(valid); valid = (valid && !r1.isInside(r2) && !r2.isInside(r1)); REQUIRE(valid); } } } } TEST_CASE("ArrangeRectanglesLoose", "[Nesting]") { using namespace libnest2d; // std::vector rects = { {40, 40}, {10, 10}, {20, 20} }; std::vector rects = { {80, 80}, {60, 90}, {70, 30}, {80, 60}, {60, 60}, {60, 40}, {40, 40}, {10, 10}, {10, 10}, {10, 10}, {10, 10}, {10, 10}, {5, 5}, {5, 5}, {5, 5}, {5, 5}, {5, 5}, {5, 5}, {5, 5}, {20, 20} }; Box bin(210, 250, {105, 125}); REQUIRE(bin.width() == 210); REQUIRE(bin.height() == 250); REQUIRE(getX(bin.center()) == 105); REQUIRE(getY(bin.center()) == 125); Coord min_obj_distance = 5; _Nester arrange(bin, min_obj_distance); arrange.execute(rects.begin(), rects.end()); auto max_group = std::max_element(rects.begin(), rects.end(), [](const Item &i1, const Item &i2) { return i1.binId() < i2.binId(); }); auto groups = size_t(max_group == rects.end() ? 0 : max_group->binId() + 1); REQUIRE(groups == 1u); REQUIRE( std::all_of(rects.begin(), rects.end(), [](const RectangleItem &itm) { return itm.binId() != BIN_ID_UNSET; })); // check for no intersections, no containment: bool valid = true; for(Item& r1 : rects) { for(Item& r2 : rects) { if(&r1 != &r2 ) { valid = !Item::intersects(r1, r2); valid = (valid && !r1.isInside(r2) && !r2.isInside(r1)); REQUIRE(valid); } } } } namespace { using namespace libnest2d; template void exportSVG(const char *loc, It from, It to) { static const char* svg_header = R"raw( )raw"; // for(auto r : result) { std::fstream out(loc, std::fstream::out); if(out.is_open()) { out << svg_header; // Item rbin( RectangleItem(bin.width(), bin.height()) ); // for(unsigned j = 0; j < rbin.vertexCount(); j++) { // auto v = rbin.vertex(j); // setY(v, -getY(v)/SCALE + 500 ); // setX(v, getX(v)/SCALE); // rbin.setVertex(j, v); // } // out << shapelike::serialize(rbin.rawShape()) << std::endl; for(auto it = from; it != to; ++it) { const Item &itm = *it; Item tsh(itm.transformedShape()); for(unsigned j = 0; j < tsh.vertexCount(); j++) { auto v = tsh.vertex(j); setY(v, -getY(v)/SCALE + 500); setX(v, getX(v)/SCALE); tsh.setVertex(j, v); } out << shapelike::serialize(tsh.rawShape()) << std::endl; } out << "\n" << std::endl; } out.close(); // i++; // } } template void exportSVG(std::vector>& result, int idx = 0) { exportSVG((std::string("out") + std::to_string(idx) + ".svg").c_str(), result.begin(), result.end()); } } TEST_CASE("BottomLeftStressTest", "[Geometry]") { using namespace libnest2d; const Coord SCALE = 1000000; auto& input = prusaParts(); Box bin(210*SCALE, 250*SCALE); BottomLeftPlacer placer(bin); auto it = input.begin(); auto next = it; int i = 0; while(it != input.end() && ++next != input.end()) { placer.pack(*it); placer.pack(*next); auto result = placer.getItems(); bool valid = true; if(result.size() == 2) { Item& r1 = result[0]; Item& r2 = result[1]; valid = !Item::intersects(r1, r2) || Item::touches(r1, r2); valid = (valid && !r1.isInside(r2) && !r2.isInside(r1)); if(!valid) { std::cout << "error index: " << i << std::endl; exportSVG(result, i); } REQUIRE(valid); } else { std::cout << "something went terribly wrong!" << std::endl; FAIL(); } placer.clearItems(); it++; i++; } } TEST_CASE("convexHull", "[Geometry]") { using namespace libnest2d; ClipperLib::Path poly = PRINTER_PART_POLYGONS[0]; auto chull = sl::convexHull(poly); REQUIRE(chull.size() == poly.size()); } TEST_CASE("PrusaPartsShouldFitIntoTwoBins", "[Nesting]") { // Get the input items and define the bin. std::vector input = prusaParts(); auto bin = Box(250000000, 210000000); // Do the nesting. Check in each step if the remaining items are less than // in the previous step. (Some algorithms can place more items in one step) size_t pcount = input.size(); size_t bins = libnest2d::nest(input, bin, 0, {}, ProgressFunction{[&pcount](unsigned cnt) { REQUIRE(cnt < pcount); pcount = cnt; }}); // For prusa parts, 2 bins should be enough... REQUIRE(bins > 0u); REQUIRE(bins <= 2u); // All parts should be processed by the algorithm REQUIRE( std::all_of(input.begin(), input.end(), [](const Item &itm) { return itm.binId() != BIN_ID_UNSET; })); // Gather the items into piles of arranged polygons... using Pile = TMultiShape; std::vector piles(bins); for (auto &itm : input) piles[size_t(itm.binId())].emplace_back(itm.transformedShape()); // Now check all the piles, the bounding box of each pile should be inside // the defined bin. for (auto &pile : piles) { auto bb = sl::boundingBox(pile); REQUIRE(sl::isInside(bb, bin)); } } TEST_CASE("EmptyItemShouldBeUntouched", "[Nesting]") { auto bin = Box(250000000, 210000000); // dummy bin std::vector items; items.emplace_back(Item{}); // Emplace empty item items.emplace_back(Item{0, 200, 0}); // Emplace zero area item size_t bins = libnest2d::nest(items, bin); REQUIRE(bins == 0u); for (auto &itm : items) REQUIRE(itm.binId() == BIN_ID_UNSET); } TEST_CASE("LargeItemShouldBeUntouched", "[Nesting]") { auto bin = Box(250000000, 210000000); // dummy bin std::vector items; items.emplace_back(RectangleItem{250000001, 210000001}); // Emplace large item size_t bins = libnest2d::nest(items, bin); REQUIRE(bins == 0u); REQUIRE(items.front().binId() == BIN_ID_UNSET); } TEST_CASE("Items can be preloaded", "[Nesting]") { auto bin = Box({0, 0}, {250000000, 210000000}); // dummy bin std::vector items; items.reserve(2); NestConfig<> cfg; cfg.placer_config.alignment = NestConfig<>::Placement::Alignment::DONT_ALIGN; items.emplace_back(RectangleItem{10000000, 10000000}); Item &fixed_rect = items.back(); fixed_rect.translate(bin.center()); items.emplace_back(RectangleItem{20000000, 20000000}); Item &movable_rect = items.back(); movable_rect.translate(bin.center()); SECTION("Preloaded Item should be untouched") { fixed_rect.markAsFixedInBin(0); size_t bins = libnest2d::nest(items, bin, 0, cfg); REQUIRE(bins == 1); REQUIRE(fixed_rect.binId() == 0); REQUIRE(fixed_rect.translation().X == bin.center().X); REQUIRE(fixed_rect.translation().Y == bin.center().Y); REQUIRE(movable_rect.binId() == 0); REQUIRE(movable_rect.translation().X != bin.center().X); REQUIRE(movable_rect.translation().Y != bin.center().Y); } SECTION("Preloaded Item should not affect free bins") { fixed_rect.markAsFixedInBin(1); size_t bins = libnest2d::nest(items, bin, 0, cfg); REQUIRE(bins == 2); REQUIRE(fixed_rect.binId() == 1); REQUIRE(fixed_rect.translation().X == bin.center().X); REQUIRE(fixed_rect.translation().Y == bin.center().Y); REQUIRE(movable_rect.binId() == 0); auto bb = movable_rect.boundingBox(); REQUIRE(bb.center().X == bin.center().X); REQUIRE(bb.center().Y == bin.center().Y); } } namespace { struct ItemPair { Item orbiter; Item stationary; }; std::vector nfp_testdata = { { { {80, 50}, {100, 70}, {120, 50}, {80, 50} }, { {10, 10}, {10, 40}, {40, 40}, {40, 10}, {10, 10} } }, { { {80, 50}, {60, 70}, {80, 90}, {120, 90}, {140, 70}, {120, 50}, {80, 50} }, { {10, 10}, {10, 40}, {40, 40}, {40, 10}, {10, 10} } }, { { {40, 10}, {30, 10}, {20, 20}, {20, 30}, {30, 40}, {40, 40}, {50, 30}, {50, 20}, {40, 10} }, { {80, 0}, {80, 30}, {110, 30}, {110, 0}, {80, 0} } }, { { {117, 107}, {118, 109}, {120, 112}, {122, 113}, {128, 113}, {130, 112}, {132, 109}, {133, 107}, {133, 103}, {132, 101}, {130, 98}, {128, 97}, {122, 97}, {120, 98}, {118, 101}, {117, 103}, {117, 107} }, { {102, 116}, {111, 126}, {114, 126}, {144, 106}, {148, 100}, {148, 85}, {147, 84}, {102, 84}, {102, 116}, } }, { { {99, 122}, {108, 140}, {110, 142}, {139, 142}, {151, 122}, {151, 102}, {142, 70}, {139, 68}, {111, 68}, {108, 70}, {99, 102}, {99, 122}, }, { {107, 124}, {128, 125}, {133, 125}, {136, 124}, {140, 121}, {142, 119}, {143, 116}, {143, 109}, {141, 93}, {139, 89}, {136, 86}, {134, 85}, {108, 85}, {107, 86}, {107, 124}, } }, { { {91, 100}, {94, 144}, {117, 153}, {118, 153}, {159, 112}, {159, 110}, {156, 66}, {133, 57}, {132, 57}, {91, 98}, {91, 100}, }, { {101, 90}, {103, 98}, {107, 113}, {114, 125}, {115, 126}, {135, 126}, {136, 125}, {144, 114}, {149, 90}, {149, 89}, {148, 87}, {145, 84}, {105, 84}, {102, 87}, {101, 89}, {101, 90}, } } }; std::vector nfp_concave_testdata = { { // ItemPair { { {533726, 142141}, {532359, 143386}, {530141, 142155}, {528649, 160091}, {533659, 157607}, {538669, 160091}, {537178, 142155}, {534959, 143386}, {533726, 142141}, } }, { { {118305, 11603}, {118311, 26616}, {113311, 26611}, {109311, 29604}, {109300, 44608}, {109311, 49631}, {113300, 52636}, {118311, 52636}, {118308, 103636}, {223830, 103636}, {236845, 90642}, {236832, 11630}, {232825, 11616}, {210149, 11616}, {211308, 13625}, {209315, 17080}, {205326, 17080}, {203334, 13629}, {204493, 11616}, {118305, 11603}, } }, } }; template void testNfp(const std::vector& testdata) { using namespace libnest2d; Box bin(210*SCALE, 250*SCALE); int TEST_CASEcase = 0; auto& exportfun = exportSVG; auto onetest = [&](Item& orbiter, Item& stationary, unsigned /*testidx*/){ TEST_CASEcase++; orbiter.translate({210*SCALE, 0}); auto&& nfp = nfp::noFitPolygon(stationary.rawShape(), orbiter.transformedShape()); placers::correctNfpPosition(nfp, stationary, orbiter); auto valid = shapelike::isValid(nfp.first); /*Item infp(nfp.first); if(!valid.first) { std::cout << "TEST_CASE instance: " << TEST_CASEidx << " " << valid.second << std::endl; std::vector> inp = {std::ref(infp)}; exportfun(inp, bin, TEST_CASEidx); }*/ REQUIRE(valid.first); Item infp(nfp.first); int i = 0; auto rorbiter = orbiter.transformedShape(); auto vo = nfp::referenceVertex(rorbiter); REQUIRE(stationary.isInside(infp)); for(auto v : infp) { auto dx = getX(v) - getX(vo); auto dy = getY(v) - getY(vo); Item tmp = orbiter; tmp.translate({dx, dy}); bool touching = Item::touches(tmp, stationary); if(!touching || !valid.first) { std::vector> inp = { std::ref(stationary), std::ref(tmp), std::ref(infp) }; exportfun(inp, TEST_CASEcase*i++); } REQUIRE(touching); } }; unsigned tidx = 0; for(auto& td : testdata) { auto orbiter = td.orbiter; auto stationary = td.stationary; onetest(orbiter, stationary, tidx++); } tidx = 0; for(auto& td : testdata) { auto orbiter = td.stationary; auto stationary = td.orbiter; onetest(orbiter, stationary, tidx++); } } } TEST_CASE("nfpConvexConvex", "[Geometry]") { testNfp(nfp_testdata); } //TEST_CASE(GeometryAlgorithms, nfpConcaveConcave) { // TEST_CASENfp(nfp_concave_TEST_CASEdata); //} TEST_CASE("pointOnPolygonContour", "[Geometry]") { using namespace libnest2d; RectangleItem input(10, 10); placers::EdgeCache ecache(input); auto first = *input.begin(); REQUIRE(getX(first) == getX(ecache.coords(0))); REQUIRE(getY(first) == getY(ecache.coords(0))); auto last = *std::prev(input.end()); REQUIRE(getX(last) == getX(ecache.coords(1.0))); REQUIRE(getY(last) == getY(ecache.coords(1.0))); for(int i = 0; i <= 100; i++) { auto v = ecache.coords(i*(0.01)); REQUIRE(shapelike::touches(v, input.transformedShape())); } } TEST_CASE("mergePileWithPolygon", "[Geometry]") { using namespace libnest2d; RectangleItem rect1(10, 15); RectangleItem rect2(15, 15); RectangleItem rect3(20, 15); rect2.translate({10, 0}); rect3.translate({25, 0}); TMultiShape pile; pile.push_back(rect1.transformedShape()); pile.push_back(rect2.transformedShape()); auto result = nfp::merge(pile, rect3.transformedShape()); REQUIRE(result.size() == 1); RectangleItem ref(45, 15); REQUIRE(shapelike::area(result.front()) == Approx(ref.area())); } namespace { long double refMinAreaBox(const PolygonImpl& p) { auto it = sl::cbegin(p), itx = std::next(it); long double min_area = std::numeric_limits::max(); auto update_min = [&min_area, &it, &itx, &p]() { Segment s(*it, *itx); PolygonImpl rotated = p; sl::rotate(rotated, -s.angleToXaxis()); auto bb = sl::boundingBox(rotated); auto area = cast(sl::area(bb)); if(min_area > area) min_area = area; }; while(itx != sl::cend(p)) { update_min(); ++it; ++itx; } it = std::prev(sl::cend(p)); itx = sl::cbegin(p); update_min(); return min_area; } template struct BoostGCD { T operator()(const T &a, const T &b) { return boost::gcd(a, b); } }; using Unit = int64_t; using Ratio = boost::rational; } //TEST_CASE(GeometryAlgorithms, MinAreaBBCClk) { // auto u = [](ClipperLib::cInt n) { return n*1000000; }; // PolygonImpl poly({ {u(0), u(0)}, {u(4), u(1)}, {u(2), u(4)}}); // long double arearef = refMinAreaBox(poly); // long double area = minAreaBoundingBox(poly).area(); // REQUIRE(std::abs(area - arearef) <= 500e6 ); //} TEST_CASE("MinAreaBBWithRotatingCalipers", "[Geometry]") { long double err_epsilon = 500e6l; for(ClipperLib::Path rinput : PRINTER_PART_POLYGONS) { PolygonImpl poly(rinput); long double arearef = refMinAreaBox(poly); auto bb = minAreaBoundingBox(rinput); long double area = cast(bb.area()); bool succ = std::abs(arearef - area) < err_epsilon; REQUIRE(succ); } for(ClipperLib::Path rinput : STEGOSAUR_POLYGONS) { rinput.pop_back(); std::reverse(rinput.begin(), rinput.end()); PolygonImpl poly(removeCollinearPoints(rinput, 1000000)); long double arearef = refMinAreaBox(poly); auto bb = minAreaBoundingBox(poly); long double area = cast(bb.area()); bool succ = std::abs(arearef - area) < err_epsilon; REQUIRE(succ); } } template MultiPolygon merged_pile(It from, It to, int bin_id) { MultiPolygon pile; pile.reserve(size_t(to - from)); for (auto it = from; it != to; ++it) { if (it->binId() == bin_id) pile.emplace_back(it->transformedShape()); } return nfp::merge(pile); } TEST_CASE("Test for bed center distance optimization", "[Nesting], [NestKernels]") { static const constexpr ClipperLib::cInt W = 10000000; // Get the input items and define the bin. std::vector input(9, {W, W}); auto bin = Box::infinite(); NfpPlacer::Config pconfig; pconfig.object_function = [](const Item &item) -> double { return pl::magnsq(item.boundingBox().center()); }; size_t bins = nest(input, bin, 0, NestConfig{pconfig}); REQUIRE(bins == 1); // Gather the items into piles of arranged polygons... MultiPolygon pile; pile.reserve(input.size()); for (auto &itm : input) { REQUIRE(itm.binId() == 0); pile.emplace_back(itm.transformedShape()); } MultiPolygon m = merged_pile(input.begin(), input.end(), 0); REQUIRE(m.size() == 1); REQUIRE(sl::area(m) == Approx(9. * W * W)); } TEST_CASE("Test for biggest bounding box area", "[Nesting], [NestKernels]") { static const constexpr ClipperLib::cInt W = 10000000; static const constexpr size_t N = 100; // Get the input items and define the bin. std::vector input(N, {W, W}); auto bin = Box::infinite(); NfpPlacer::Config pconfig; pconfig.rotations = {0.}; Box pile_box; pconfig.before_packing = [&pile_box](const MultiPolygon &pile, const _ItemGroup &/*packed_items*/, const _ItemGroup &/*remaining_items*/) { pile_box = sl::boundingBox(pile); }; pconfig.object_function = [&pile_box](const Item &item) -> double { Box b = sl::boundingBox(item.boundingBox(), pile_box); double area = b.area() / (W * W); return -area; }; size_t bins = nest(input, bin, 0, NestConfig{pconfig}); // To debug: exportSVG<1000000>("out", input.begin(), input.end()); REQUIRE(bins == 1); MultiPolygon pile = merged_pile(input.begin(), input.end(), 0); Box bb = sl::boundingBox(pile); // Here the result shall be a stairway of boxes REQUIRE(pile.size() == N); REQUIRE(bb.area() == N * N * W * W); }