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Diffstat (limited to 'include/mapbox/cheap_ruler.hpp')
| -rw-r--r-- | include/mapbox/cheap_ruler.hpp | 358 |
1 files changed, 0 insertions, 358 deletions
diff --git a/include/mapbox/cheap_ruler.hpp b/include/mapbox/cheap_ruler.hpp deleted file mode 100644 index ae82706..0000000 --- a/include/mapbox/cheap_ruler.hpp +++ /dev/null @@ -1,358 +0,0 @@ -#pragma once - -#include <mapbox/geometry.hpp> - -#include <cmath> -#include <cstdint> -#include <limits> -#include <tuple> -#include <utility> - -namespace mapbox { -namespace cheap_ruler { - -using box = geometry::box<double>; -using line_string = geometry::line_string<double>; -using linear_ring = geometry::linear_ring<double>; -using multi_line_string = geometry::multi_line_string<double>; -using point = geometry::point<double>; -using polygon = geometry::polygon<double>; - -class CheapRuler { -public: - enum Unit { - Kilometers, - Miles, - NauticalMiles, - Meters, - Metres = Meters, - Yards, - Feet, - Inches - }; - - // - // A collection of very fast approximations to common geodesic measurements. Useful - // for performance-sensitive code that measures things on a city scale. Point coordinates - // are in the [x = longitude, y = latitude] form. - // - explicit CheapRuler(double latitude, Unit unit = Kilometers) { - double m = 0.; - - switch (unit) { - case Kilometers: - m = 1.; - break; - case Miles: - m = 1000. / 1609.344; - break; - case NauticalMiles: - m = 1000. / 1852.; - break; - case Meters: - m = 1000.; - break; - case Yards: - m = 1000. / 0.9144; - break; - case Feet: - m = 1000. / 0.3048; - break; - case Inches: - m = 1000. / 0.0254; - break; - } - - auto cos = std::cos(latitude * M_PI / 180.); - auto cos2 = 2. * cos * cos - 1.; - auto cos3 = 2. * cos * cos2 - cos; - auto cos4 = 2. * cos * cos3 - cos2; - auto cos5 = 2. * cos * cos4 - cos3; - - // multipliers for converting longitude and latitude - // degrees into distance (http://1.usa.gov/1Wb1bv7) - kx = m * (111.41513 * cos - 0.09455 * cos3 + 0.00012 * cos5); - ky = m * (111.13209 - 0.56605 * cos2 + 0.0012 * cos4); - } - - static CheapRuler fromTile(uint32_t y, uint32_t z) { - double n = M_PI * (1. - 2. * (y + 0.5) / std::pow(2., z)); - double latitude = std::atan(0.5 * (std::exp(n) - std::exp(-n))) * 180. / M_PI; - - return CheapRuler(latitude); - } - - // - // Given two points of the form [x = longitude, y = latitude], returns the distance. - // - double distance(point a, point b) { - auto dx = (a.x - b.x) * kx; - auto dy = (a.y - b.y) * ky; - - return std::sqrt(dx * dx + dy * dy); - } - - // - // Returns the bearing between two points in angles. - // - double bearing(point a, point b) { - auto dx = (b.x - a.x) * kx; - auto dy = (b.y - a.y) * ky; - - if (!dx && !dy) { - return 0.; - } - - auto bearing = std::atan2(-dy, dx) * 180. / M_PI + 90.; - - if (bearing > 180.) { - bearing -= 360.; - } - - return bearing; - } - - // - // Returns a new point given distance and bearing from the starting point. - // - point destination(point origin, double dist, double bearing) { - auto a = (90. - bearing) * M_PI / 180.; - - return offset(origin, std::cos(a) * dist, std::sin(a) * dist); - } - - // - // Returns a new point given easting and northing offsets from the starting point. - // - point offset(point origin, double dx, double dy) { - return point(origin.x + dx / kx, origin.y + dy / ky); - } - - // - // Given a line (an array of points), returns the total line distance. - // - double lineDistance(const line_string& points) { - double total = 0.; - - for (unsigned i = 0; i < points.size() - 1; ++i) { - total += distance(points[i], points[i + 1]); - } - - return total; - } - - // - // Given a polygon (an array of rings, where each ring is an array of points), - // returns the area. - // - double area(polygon poly) { - double sum = 0.; - - for (unsigned i = 0; i < poly.size(); ++i) { - auto& ring = poly[i]; - - for (unsigned j = 0, len = ring.size(), k = len - 1; j < len; k = j++) { - sum += (ring[j].x - ring[k].x) * (ring[j].y + ring[k].y) * (i ? -1. : 1.); - } - } - - return (std::abs(sum) / 2.) * kx * ky; - } - - // - // Returns the point at a specified distance along the line. - // - point along(const line_string& line, double dist) { - double sum = 0.; - - if (dist <= 0.) { - return line[0]; - } - - for (unsigned i = 0; i < line.size() - 1; ++i) { - auto p0 = line[i]; - auto p1 = line[i + 1]; - auto d = distance(p0, p1); - - sum += d; - - if (sum > dist) { - return interpolate(p0, p1, (dist - (sum - d)) / d); - } - } - - return line[line.size() - 1]; - } - - // - // Returns a pair of the form <point, index> where point is closest point on the line from - // the given point and index is the start index of the segment with the closest point. - // - std::pair<point, unsigned> pointOnLine(const line_string& line, point p) { - auto result = _pointOnLine(line, p); - - return std::make_pair(std::get<0>(result), std::get<1>(result)); - } - - // - // Returns a part of the given line between the start and the stop points (or their closest - // points on the line). - // - line_string lineSlice(point start, point stop, const line_string& line) { - constexpr auto getPoint = [](auto tuple) { return std::get<0>(tuple); }; - constexpr auto getIndex = [](auto tuple) { return std::get<1>(tuple); }; - constexpr auto getT = [](auto tuple) { return std::get<2>(tuple); }; - - auto p1 = _pointOnLine(line, start); - auto p2 = _pointOnLine(line, stop); - - if (getIndex(p1) > getIndex(p2) || (getIndex(p1) == getIndex(p2) && getT(p1) > getT(p2))) { - auto tmp = p1; - p1 = p2; - p2 = tmp; - } - - line_string slice = { getPoint(p1) }; - - auto l = getIndex(p1) + 1; - auto r = getIndex(p2); - - if (line[l] != slice[0] && l <= r) { - slice.push_back(line[l]); - } - - for (unsigned i = l + 1; i <= r; ++i) { - slice.push_back(line[i]); - } - - if (line[r] != getPoint(p2)) { - slice.push_back(getPoint(p2)); - } - - return slice; - }; - - // - // Returns a part of the given line between the start and the stop points - // indicated by distance along the line. - // - line_string lineSliceAlong(double start, double stop, const line_string& line) { - double sum = 0.; - line_string slice; - - for (unsigned i = 0; i < line.size() - 1; ++i) { - auto p0 = line[i]; - auto p1 = line[i + 1]; - auto d = distance(p0, p1); - - sum += d; - - if (sum > start && slice.size() == 0) { - slice.push_back(interpolate(p0, p1, (start - (sum - d)) / d)); - } - - if (sum >= stop) { - slice.push_back(interpolate(p0, p1, (stop - (sum - d)) / d)); - return slice; - } - - if (sum > start) { - slice.push_back(p1); - } - } - - return slice; - }; - - // - // Given a point, returns a bounding box object ([w, s, e, n]) - // created from the given point buffered by a given distance. - // - box bufferPoint(point p, double buffer) { - auto v = buffer / ky; - auto h = buffer / kx; - - return box( - point(p.x - h, p.y - v), - point(p.x + h, p.y + v) - ); - } - - // - // Given a bounding box, returns the box buffered by a given distance. - // - box bufferBBox(box bbox, double buffer) { - auto v = buffer / ky; - auto h = buffer / kx; - - return box( - point(bbox.min.x - h, bbox.min.y - v), - point(bbox.max.x + h, bbox.max.y + v) - ); - } - - // - // Returns true if the given point is inside in the given bounding box, otherwise false. - // - bool insideBBox(point p, box bbox) { - return p.x >= bbox.min.x && - p.x <= bbox.max.x && - p.y >= bbox.min.y && - p.y <= bbox.max.y; - } - - static point interpolate(point a, point b, double t) { - double dx = b.x - a.x; - double dy = b.y - a.y; - - return point(a.x + dx * t, a.y + dy * t); - } - -private: - std::tuple<point, unsigned, double> _pointOnLine(const line_string& line, point p) { - double minDist = std::numeric_limits<double>::infinity(); - double minX = 0., minY = 0., minI = 0., minT = 0.; - - for (unsigned i = 0; i < line.size() - 1; ++i) { - auto t = 0.; - auto x = line[i].x; - auto y = line[i].y; - auto dx = (line[i + 1].x - x) * kx; - auto dy = (line[i + 1].y - y) * ky; - - if (dx != 0. || dy != 0.) { - t = ((p.x - x) * kx * dx + (p.y - y) * ky * dy) / (dx * dx + dy * dy); - - if (t > 1) { - x = line[i + 1].x; - y = line[i + 1].y; - - } else if (t > 0) { - x += (dx / kx) * t; - y += (dy / ky) * t; - } - } - - dx = (p.x - x) * kx; - dy = (p.y - y) * ky; - - auto sqDist = dx * dx + dy * dy; - - if (sqDist < minDist) { - minDist = sqDist; - minX = x; - minY = y; - minI = i; - minT = t; - } - } - - return std::make_tuple(point(minX, minY), minI, minT); - } - - double ky; - double kx; -}; - -} // namespace cheap_ruler -} // namespace mapbox |