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Add libnest tests for various basic object functions

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This commit is contained in:
tamasmeszaros 2020-03-27 09:20:06 +01:00
parent 8c04536514
commit 69c02a407b
4 changed files with 133 additions and 32 deletions
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136
tests/libnest2d/libnest2d_tests_main.cpp
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@ -472,32 +472,30 @@ TEST_CASE("ArrangeRectanglesLoose", "[Nesting]")
namespace {
using namespace libnest2d;
template<long long SCALE = 1, class Bin>
void exportSVG(std::vector<std::reference_wrapper<Item>>& result, const Bin& bin, int idx = 0) {
std::string loc = "out";
template<long long SCALE = 1, class It>
void exportSVG(const char *loc, It from, It to) {
static std::string svg_header =
R"raw(<?xml version="1.0" encoding="UTF-8" standalone="yes"?>
static const char* svg_header =
R"raw(<?xml version="1.0" encoding="UTF-8" standalone="yes"?>
<!DOCTYPE svg PUBLIC "-//W3C//DTD SVG 1.0//EN" "http://www.w3.org/TR/2001/REC-SVG-20010904/DTD/svg10.dtd">
<svg height="500" width="500" xmlns="http://www.w3.org/2000/svg" xmlns:svg="http://www.w3.org/2000/svg" xmlns:xlink="http://www.w3.org/1999/xlink">
)raw";
int i = idx;
auto r = result;
// for(auto r : result) {
std::fstream out(loc + std::to_string(i) + ".svg", std::fstream::out);
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<Formats::SVG>(rbin.rawShape()) << std::endl;
for(Item& sh : r) {
Item tsh(sh.transformedShape());
// 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<Formats::SVG>(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);
@ -509,10 +507,16 @@ void exportSVG(std::vector<std::reference_wrapper<Item>>& result, const Bin& bin
out << "\n</svg>" << std::endl;
}
out.close();
// i++;
// }
}
template<long long SCALE = 1>
void exportSVG(std::vector<std::reference_wrapper<Item>>& result, int idx = 0) {
exportSVG((std::string("out") + std::to_string(idx) + ".svg").c_str(),
result.begin(), result.end());
}
}
TEST_CASE("BottomLeftStressTest", "[Geometry]") {
@ -541,7 +545,7 @@ TEST_CASE("BottomLeftStressTest", "[Geometry]") {
valid = (valid && !r1.isInside(r2) && !r2.isInside(r1));
if(!valid) {
std::cout << "error index: " << i << std::endl;
exportSVG(result, bin, i);
exportSVG<SCALE>(result, i);
}
REQUIRE(valid);
} else {
@ -894,7 +898,7 @@ void testNfp(const std::vector<ItemPair>& testdata) {
int TEST_CASEcase = 0;
auto& exportfun = exportSVG<SCALE, Box>;
auto& exportfun = exportSVG<SCALE>;
auto onetest = [&](Item& orbiter, Item& stationary, unsigned /*testidx*/){
TEST_CASEcase++;
@ -941,7 +945,7 @@ void testNfp(const std::vector<ItemPair>& testdata) {
std::ref(stationary), std::ref(tmp), std::ref(infp)
};
exportfun(inp, bin, TEST_CASEcase*i++);
exportfun(inp, TEST_CASEcase*i++);
}
REQUIRE(touching);
@ -1096,3 +1100,91 @@ TEST_CASE("MinAreaBBWithRotatingCalipers", "[Geometry]") {
REQUIRE(succ);
}
}
template<class It> 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<RectangleItem> input(9, {W, W});
auto bin = Box::infinite();
NfpPlacer::Config pconfig;
pconfig.object_function = [](const Item &item) -> double {
return pl::magnsq<PointImpl, double>(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<RectangleItem> 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<PolygonImpl> &/*packed_items*/,
const _ItemGroup<PolygonImpl> &/*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<double>() / (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);
}