TEST(TileCover, DISABLED_FuzzPoly) {
    while(1)
    {
        std::srand (time(NULL));
        std::size_t len = std::rand() % 10000 + 3;
        Polygon<double> polygon;

        std::size_t num_rings = 1;
        num_rings += std::rand() % 5;
        while (num_rings > 0) {
            LinearRing<double> ring;
            for (std::size_t i = 0; i < len; ++i) {
                double x = std::rand() % 180;
                double y = std::rand() % 90;

                ring.push_back({x,y});
            }
            polygon.emplace_back(ring);
            --num_rings;
        }
        
        std::clog << ".";
        util::TileCover tc(polygon, 5);
        while(tc.next()) {
        };
    }
}
Exemplo n.º 2
0
static Feature::geometry_type convertGeometry(const GeometryTileFeature& geometryTileFeature, const CanonicalTileID& tileID) {
    const double size = util::EXTENT * std::pow(2, tileID.z);
    const double x0 = util::EXTENT * tileID.x;
    const double y0 = util::EXTENT * tileID.y;

    auto tileCoordinatesToLatLng = [&] (const Point<int16_t>& p) {
        double y2 = 180 - (p.y + y0) * 360 / size;
        return Point<double>(
            (p.x + x0) * 360 / size - 180,
            360.0 / M_PI * std::atan(std::exp(y2 * M_PI / 180)) - 90.0
        );
    };

    GeometryCollection geometries = geometryTileFeature.getGeometries();

    switch (geometryTileFeature.getType()) {
        case FeatureType::Unknown: {
            assert(false);
            return Point<double>(NAN, NAN);
        }

        case FeatureType::Point: {
            MultiPoint<double> multiPoint;
            for (const auto& p : geometries.at(0)) {
                multiPoint.push_back(tileCoordinatesToLatLng(p));
            }
            if (multiPoint.size() == 1) {
                return multiPoint[0];
            } else {
                return multiPoint;
            }
        }

        case FeatureType::LineString: {
            MultiLineString<double> multiLineString;
            for (const auto& g : geometries) {
                LineString<double> lineString;
                for (const auto& p : g) {
                    lineString.push_back(tileCoordinatesToLatLng(p));
                }
                multiLineString.push_back(std::move(lineString));
            }
            if (multiLineString.size() == 1) {
                return multiLineString[0];
            } else {
                return multiLineString;
            }
        }

        case FeatureType::Polygon: {
            MultiPolygon<double> multiPolygon;
            for (const auto& pg : classifyRings(geometries)) {
                Polygon<double> polygon;
                for (const auto& r : pg) {
                    LinearRing<double> linearRing;
                    for (const auto& p : r) {
                        linearRing.push_back(tileCoordinatesToLatLng(p));
                    }
                    polygon.push_back(std::move(linearRing));
                }
                multiPolygon.push_back(std::move(polygon));
            }
            if (multiPolygon.size() == 1) {
                return multiPolygon[0];
            } else {
                return multiPolygon;
            }
        }
    }

    // Unreachable, but placate GCC.
    return Point<double>();
}