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|
/**
* Copyright (C) 2013 MongoDB Inc.
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License, version 3,
* as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Affero General Public License for more details.
*
* You should have received a copy of the GNU Affero General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*
* As a special exception, the copyright holders give permission to link the
* code of portions of this program with the OpenSSL library under certain
* conditions as described in each individual source file and distribute
* linked combinations including the program with the OpenSSL library. You
* must comply with the GNU Affero General Public License in all respects for
* all of the code used other than as permitted herein. If you modify file(s)
* with this exception, you may extend this exception to your version of the
* file(s), but you are not obligated to do so. If you do not wish to do so,
* delete this exception statement from your version. If you delete this
* exception statement from all source files in the program, then also delete
* it in the license file.
*/
#include "mongo/db/geo/geoquery.h"
#include "mongo/db/geo/geoconstants.h"
#include "mongo/db/geo/s2common.h"
namespace mongo {
using mongoutils::str::equals;
bool NearQuery::parseLegacyQuery(const BSONObj &obj) {
bool hasGeometry = false;
// First, try legacy near, e.g.:
// t.find({ loc : { $nearSphere: [0,0], $minDistance: 1, $maxDistance: 3 }})
// t.find({ loc : { $nearSphere: [0,0] }})
// t.find({ loc : { $near : [0, 0, 1] } });
// t.find({ loc : { $near: { someGeoJSONPoint}})
// t.find({ loc : { $geoNear: { someGeoJSONPoint}})
BSONObjIterator it(obj);
while (it.more()) {
BSONElement e = it.next();
if (equals(e.fieldName(), "$near") || equals(e.fieldName(), "$geoNear")
|| equals(e.fieldName(), "$nearSphere")) {
if (!e.isABSONObj()) { return false; }
BSONObj embeddedObj = e.embeddedObject();
if ((GeoParser::isPoint(embeddedObj) && GeoParser::parsePoint(embeddedObj, ¢roid))
|| GeoParser::parsePointWithMaxDistance(embeddedObj, ¢roid, &maxDistance)) {
uassert(18522, "max distance must be non-negative", maxDistance >= 0.0);
hasGeometry = true;
isNearSphere = equals(e.fieldName(), "$nearSphere");
}
} else if (equals(e.fieldName(), "$minDistance")) {
uassert(16893, "$minDistance must be a number", e.isNumber());
minDistance = e.Number();
uassert(16894, "$minDistance must be non-negative", minDistance >= 0.0);
} else if (equals(e.fieldName(), "$maxDistance")) {
uassert(16895, "$maxDistance must be a number", e.isNumber());
maxDistance = e.Number();
uassert(16896, "$maxDistance must be non-negative", maxDistance >= 0.0);
} else if (equals(e.fieldName(), "$uniqueDocs")) {
warning() << "ignoring deprecated option $uniqueDocs";
}
}
// The user-provided point can be flat. We need to make sure that it's in bounds.
if (isNearSphere) {
uassert(17444,
"Legacy point is out of bounds for spherical query",
centroid.flatUpgradedToSphere || (SPHERE == centroid.crs));
}
return hasGeometry;
}
Status NearQuery::parseNewQuery(const BSONObj &obj) {
bool hasGeometry = false;
BSONObjIterator objIt(obj);
if (!objIt.more()) {
return Status(ErrorCodes::BadValue, "empty geo near query object");
}
BSONElement e = objIt.next();
// Just one arg. to $geoNear.
if (objIt.more()) {
return Status(ErrorCodes::BadValue, mongoutils::str::stream() <<
"geo near accepts just one argument when querying for a GeoJSON " <<
"point. Extra field found: " << objIt.next());
}
// Parse "new" near:
// t.find({"geo" : {"$near" : {"$geometry": pointA, $minDistance: 1, $maxDistance: 3}}})
// t.find({"geo" : {"$geoNear" : {"$geometry": pointA, $minDistance: 1, $maxDistance: 3}}})
if (!e.isABSONObj()) {
return Status(ErrorCodes::BadValue, "geo near query argument is not an object");
}
BSONObj::MatchType matchType = static_cast<BSONObj::MatchType>(e.getGtLtOp());
if (BSONObj::opNEAR != matchType) {
return Status(ErrorCodes::BadValue, mongoutils::str::stream() <<
"invalid geo near query operator: " << e.fieldName());
}
// Iterate over the argument.
BSONObjIterator it(e.embeddedObject());
while (it.more()) {
BSONElement e = it.next();
if (equals(e.fieldName(), "$geometry")) {
if (e.isABSONObj()) {
BSONObj embeddedObj = e.embeddedObject();
uassert(16885, "$near requires a point, given " + embeddedObj.toString(),
GeoParser::isPoint(embeddedObj));
if (!GeoParser::parsePoint(embeddedObj, ¢roid)) {
return Status(ErrorCodes::BadValue, mongoutils::str::stream() <<
"invalid point in geo near query $geometry argument: " <<
embeddedObj);
}
uassert(16681, "$near requires geojson point, given " + embeddedObj.toString(),
(SPHERE == centroid.crs));
hasGeometry = true;
}
} else if (equals(e.fieldName(), "$minDistance")) {
uassert(16897, "$minDistance must be a number", e.isNumber());
minDistance = e.Number();
uassert(16898, "$minDistance must be non-negative", minDistance >= 0.0);
} else if (equals(e.fieldName(), "$maxDistance")) {
uassert(16899, "$maxDistance must be a number", e.isNumber());
maxDistance = e.Number();
uassert(16900, "$maxDistance must be non-negative", maxDistance >= 0.0);
}
}
if (!hasGeometry) {
return Status(ErrorCodes::BadValue, "$geometry is required for geo near query");
}
return Status::OK();
}
Status NearQuery::parseFrom(const BSONObj &obj) {
if (parseLegacyQuery(obj)) {
return Status::OK();
}
// Clear out any half-baked data.
minDistance = 0;
isNearSphere = false;
maxDistance = std::numeric_limits<double>::max();
centroid = PointWithCRS();
// And try parsing new format.
return parseNewQuery(obj);
}
bool GeoQuery::parseLegacyQuery(const BSONObj &obj) {
// The only legacy syntax is {$within: {.....}}
BSONObjIterator outerIt(obj);
if (!outerIt.more()) { return false; }
BSONElement withinElt = outerIt.next();
if (outerIt.more()) { return false; }
if (!withinElt.isABSONObj()) { return false; }
if (!equals(withinElt.fieldName(), "$within") && !equals(withinElt.fieldName(), "$geoWithin")) {
return false;
}
BSONObj withinObj = withinElt.embeddedObject();
bool hasGeometry = false;
BSONObjIterator withinIt(withinObj);
while (withinIt.more()) {
BSONElement elt = withinIt.next();
if (equals(elt.fieldName(), "$uniqueDocs")) {
warning() << "deprecated $uniqueDocs option: " << obj.toString() << endl;
// return false;
}
else if (elt.isABSONObj()) {
hasGeometry = geoContainer.parseFrom(elt.wrap());
}
else {
warning() << "bad geo query: " << obj.toString() << endl;
return false;
}
}
predicate = GeoQuery::WITHIN;
return hasGeometry;
}
bool GeoQuery::parseNewQuery(const BSONObj &obj) {
// pointA = { "type" : "Point", "coordinates": [ 40, 5 ] }
// t.find({ "geo" : { "$intersect" : { "$geometry" : pointA} } })
// t.find({ "geo" : { "$within" : { "$geometry" : polygon } } })
// where field.name is "geo"
BSONElement e = obj.firstElement();
if (!e.isABSONObj()) { return false; }
BSONObj::MatchType matchType = static_cast<BSONObj::MatchType>(e.getGtLtOp());
if (BSONObj::opGEO_INTERSECTS == matchType) {
predicate = GeoQuery::INTERSECT;
} else if (BSONObj::opWITHIN == matchType) {
predicate = GeoQuery::WITHIN;
} else {
return false;
}
bool hasGeometry = false;
BSONObjIterator argIt(e.embeddedObject());
while (argIt.more()) {
BSONElement e = argIt.next();
if (mongoutils::str::equals(e.fieldName(), "$geometry")) {
if (e.isABSONObj()) {
BSONObj embeddedObj = e.embeddedObject();
if (geoContainer.parseFrom(embeddedObj)) {
hasGeometry = true;
}
}
}
}
// Don't want to give the error below if we could not pull any geometry out.
if (!hasGeometry) { return false; }
if (GeoQuery::WITHIN == predicate) {
// Why do we only deal with $within {polygon}?
// 1. Finding things within a point is silly and only valid
// for points and degenerate lines/polys.
//
// 2. Finding points within a line is easy but that's called intersect.
// Finding lines within a line is kind of tricky given what S2 gives us.
// Doing line-within-line is a valid yet unsupported feature,
// though I wonder if we want to preserve orientation for lines or
// allow (a,b),(c,d) to be within (c,d),(a,b). Anyway, punt on
// this for now.
uassert(16672, "$within not supported with provided geometry: " + obj.toString(),
geoContainer.supportsContains());
}
return hasGeometry;
}
bool GeoQuery::parseFrom(const BSONObj &obj) {
return parseLegacyQuery(obj) || parseNewQuery(obj);
}
GeometryContainer::GeometryContainer() {
}
bool GeometryContainer::isSimpleContainer() const {
return NULL != _point || NULL != _line || NULL != _polygon;
}
bool GeometryContainer::supportsContains() const {
return NULL != _polygon
|| NULL != _cap
|| NULL != _multiPolygon
|| (NULL != _geometryCollection
&& (_geometryCollection->polygons.vector().size() > 0
|| _geometryCollection->multiPolygons.vector().size() > 0));
}
bool GeometryContainer::hasS2Region() const {
return (NULL != _point && (_point->crs == SPHERE || _point->flatUpgradedToSphere))
|| NULL != _line
|| (NULL != _polygon && _polygon->crs == SPHERE)
|| (NULL != _cap && _cap->crs == SPHERE)
|| NULL != _multiPoint
|| NULL != _multiLine
|| NULL != _multiPolygon
|| NULL != _geometryCollection;
}
const S2Region& GeometryContainer::getS2Region() const {
if (NULL != _point) {
// _point->crs might be FLAT but we "upgrade" it for free if it was in bounds.
if (FLAT == _point->crs) {
verify(_point->flatUpgradedToSphere);
}
return _point->cell;
} else if (NULL != _line) {
return _line->line;
} else if (NULL != _cap && SPHERE == _cap->crs) {
return _cap->cap;
} else if (NULL != _multiPoint) {
return *_s2Region;
} else if (NULL != _multiLine) {
return *_s2Region;
} else if (NULL != _multiPolygon) {
return *_s2Region;
} else if (NULL != _geometryCollection) {
return *_s2Region;
} else {
verify(NULL != _polygon);
verify(SPHERE == _polygon->crs);
return _polygon->polygon;
}
}
bool GeometryContainer::hasR2Region() const {
return _cap || _box || _point || (_polygon && _polygon->crs == FLAT)
|| (_multiPoint && FLAT == _multiPoint->crs);
}
class GeometryContainer::R2BoxRegion : public R2Region {
public:
R2BoxRegion(const GeometryContainer* geometry);
virtual ~R2BoxRegion();
Box getR2Bounds() const;
bool fastContains(const Box& other) const;
bool fastDisjoint(const Box& other) const;
private:
static Box buildBounds(const GeometryContainer& geometry);
// Not owned here
const GeometryContainer* _geometry;
// TODO: For big complex shapes, may be better to use actual shape from above
const Box _bounds;
};
GeometryContainer::R2BoxRegion::R2BoxRegion(const GeometryContainer* geometry) :
_geometry(geometry), _bounds(buildBounds(*geometry)) {
}
GeometryContainer::R2BoxRegion::~R2BoxRegion() {
}
Box GeometryContainer::R2BoxRegion::getR2Bounds() const {
return _bounds;
}
bool GeometryContainer::R2BoxRegion::fastContains(const Box& other) const {
// TODO: Add more cases here to make coverings better
if (_geometry->_box && FLAT == _geometry->_box->crs) {
const Box& box = _geometry->_box->box;
if (box.contains(other))
return true;
} else if (_geometry->_cap && FLAT == _geometry->_cap->crs) {
const Circle& circle = _geometry->_cap->circle;
// Exact test
return circleContainsBox(circle, other);
}
if (_geometry->_polygon && FLAT == _geometry->_polygon->crs) {
const Polygon& polygon = _geometry->_polygon->oldPolygon;
// Exact test
return polygonContainsBox(polygon, other);
}
// Not sure
return false;
}
bool GeometryContainer::R2BoxRegion::fastDisjoint(const Box& other) const {
if (!_bounds.intersects(other))
return true;
// Not sure
return false;
}
static Point toLngLatPoint(const S2Point& s2Point) {
Point point;
S2LatLng latLng(s2Point);
point.x = latLng.lng().degrees();
point.y = latLng.lat().degrees();
return point;
}
static void lineR2Bounds(const S2Polyline& flatLine, Box* flatBounds) {
int numVertices = flatLine.num_vertices();
verify(flatLine.num_vertices() > 0);
flatBounds->init(toLngLatPoint(flatLine.vertex(0)), toLngLatPoint(flatLine.vertex(0)));
for (int i = 1; i < numVertices; ++i) {
flatBounds->expandToInclude(toLngLatPoint(flatLine.vertex(i)));
}
}
static void circleR2Bounds(const Circle& circle, Box* flatBounds) {
flatBounds->init(Point(circle.center.x - circle.radius, circle.center.y - circle.radius),
Point(circle.center.x + circle.radius, circle.center.y + circle.radius));
}
static void multiPointR2Bounds(const vector<S2Point>& points, Box* flatBounds) {
verify(!points.empty());
flatBounds->init(toLngLatPoint(points.front()), toLngLatPoint(points.front()));
vector<S2Point>::const_iterator it = points.begin();
for (++it; it != points.end(); ++it) {
const S2Point& s2Point = *it;
flatBounds->expandToInclude(toLngLatPoint(s2Point));
}
}
static void polygonR2Bounds(const Polygon& polygon, Box* flatBounds) {
*flatBounds = polygon.bounds();
}
static void s2RegionR2Bounds(const S2Region& region, Box* flatBounds) {
S2LatLngRect s2Bounds = region.GetRectBound();
flatBounds->init(Point(s2Bounds.lng_lo().degrees(), s2Bounds.lat_lo().degrees()),
Point(s2Bounds.lng_hi().degrees(), s2Bounds.lat_hi().degrees()));
}
Box GeometryContainer::R2BoxRegion::buildBounds(const GeometryContainer& geometry) {
Box bounds;
if (geometry._point && FLAT == geometry._point->crs) {
bounds.init(geometry._point->oldPoint, geometry._point->oldPoint);
}
else if (geometry._line && FLAT == geometry._line->crs) {
lineR2Bounds(geometry._line->line, &bounds);
}
else if (geometry._cap && FLAT == geometry._cap->crs) {
circleR2Bounds(geometry._cap->circle, &bounds);
}
else if (geometry._box && FLAT == geometry._box->crs) {
bounds = geometry._box->box;
}
else if (geometry._polygon && FLAT == geometry._polygon->crs) {
polygonR2Bounds(geometry._polygon->oldPolygon, &bounds);
}
else if (geometry._multiPoint && FLAT == geometry._multiPoint->crs) {
multiPointR2Bounds(geometry._multiPoint->points, &bounds);
}
else if (geometry._multiLine && FLAT == geometry._multiLine->crs) {
verify(false);
}
else if (geometry._multiPolygon && FLAT == geometry._multiPolygon->crs) {
verify(false);
}
else if (geometry._geometryCollection) {
verify(false);
}
else if (geometry.hasS2Region()) {
// For now, just support spherical cap for $centerSphere and GeoJSON points
verify((geometry._cap && FLAT != geometry._cap->crs) ||
(geometry._point && FLAT != geometry._point->crs));
s2RegionR2Bounds(geometry.getS2Region(), &bounds);
}
return bounds;
}
const R2Region& GeometryContainer::getR2Region() const {
return *_r2Region;
}
bool GeometryContainer::contains(const GeometryContainer& otherContainer) const {
// First let's deal with the case where we are FLAT.
if (NULL != _polygon && (FLAT == _polygon->crs)) {
if (NULL == otherContainer._point) { return false; }
return _polygon->oldPolygon.contains(otherContainer._point->oldPoint);
}
if (NULL != _box) {
verify(FLAT == _box->crs);
if (NULL == otherContainer._point) { return false; }
return _box->box.inside(otherContainer._point->oldPoint);
}
if (NULL != _cap && (FLAT == _cap->crs)) {
if (NULL == otherContainer._point) { return false; }
// Let's be as consistent epsilon-wise as we can with the '2d' indextype.
return distanceWithin(_cap->circle.center, otherContainer._point->oldPoint,
_cap->circle.radius);
}
// Now we deal with all the SPHERE stuff.
// Iterate over the other thing and see if we contain it all.
if (NULL != otherContainer._point) {
// The point must be valid lng, lat if it was old-style.
if (FLAT == otherContainer._point->crs
&& !otherContainer._point->flatUpgradedToSphere) {
return false;
}
return contains(otherContainer._point->cell, otherContainer._point->point);
}
if (NULL != otherContainer._line) {
return contains(otherContainer._line->line);
}
if (NULL != otherContainer._polygon) {
return contains(otherContainer._polygon->polygon);
}
if (NULL != otherContainer._multiPoint) {
for (size_t i = 0; i < otherContainer._multiPoint->points.size(); ++i) {
if (!contains(otherContainer._multiPoint->cells[i],
otherContainer._multiPoint->points[i])) {
return false;
}
}
return true;
}
if (NULL != otherContainer._multiLine) {
const vector<S2Polyline*>& lines = otherContainer._multiLine->lines.vector();
for (size_t i = 0; i < lines.size(); ++i) {
if (!contains(*lines[i])) { return false; }
}
return true;
}
if (NULL != otherContainer._multiPolygon) {
const vector<S2Polygon*>& polys = otherContainer._multiPolygon->polygons.vector();
for (size_t i = 0; i < polys.size(); ++i) {
if (!contains(*polys[i])) { return false; }
}
return true;
}
if (NULL != otherContainer._geometryCollection) {
GeometryCollection& c = *otherContainer._geometryCollection;
for (size_t i = 0; i < c.points.size(); ++i) {
if (!contains(c.points[i].cell, c.points[i].point)) {
return false;
}
}
const vector<LineWithCRS*>& lines = c.lines.vector();
for (size_t i = 0; i < lines.size(); ++i) {
if (!contains(lines[i]->line)) { return false; }
}
const vector<PolygonWithCRS*>& polys = c.polygons.vector();
for (size_t i = 0; i < polys.size(); ++i) {
if (!contains(polys[i]->polygon)) { return false; }
}
const vector<MultiPointWithCRS*>& multipoints = c.multiPoints.vector();
for (size_t i = 0; i < multipoints.size(); ++i) {
MultiPointWithCRS* mp = multipoints[i];
for (size_t j = 0; j < mp->points.size(); ++j) {
if (!contains(mp->cells[j], mp->points[j])) { return false; }
}
}
const vector<MultiLineWithCRS*>& multilines = c.multiLines.vector();
for (size_t i = 0; i < multilines.size(); ++i) {
const vector<S2Polyline*>& lines = multilines[i]->lines.vector();
for (size_t j = 0; j < lines.size(); ++j) {
if (!contains(*lines[j])) { return false; }
}
}
const vector<MultiPolygonWithCRS*>& multipolys = c.multiPolygons.vector();
for (size_t i = 0; i < multipolys.size(); ++i) {
const vector<S2Polygon*>& polys = multipolys[i]->polygons.vector();
for (size_t j = 0; j < polys.size(); ++j) {
if (!contains(*polys[j])) { return false; }
}
}
return true;
}
return false;
}
bool containsPoint(const S2Polygon& poly, const S2Cell& otherCell, const S2Point& otherPoint) {
// This is much faster for actual containment checking.
if (poly.Contains(otherPoint)) { return true; }
// This is slower but contains edges/vertices.
return poly.MayIntersect(otherCell);
}
bool GeometryContainer::contains(const S2Cell& otherCell, const S2Point& otherPoint) const {
if (NULL != _polygon && (_polygon->crs == SPHERE)) {
return containsPoint(_polygon->polygon, otherCell, otherPoint);
}
if (NULL != _cap && (_cap->crs == SPHERE)) {
return _cap->cap.MayIntersect(otherCell);
}
if (NULL != _multiPolygon) {
const vector<S2Polygon*>& polys = _multiPolygon->polygons.vector();
for (size_t i = 0; i < polys.size(); ++i) {
if (containsPoint(*polys[i], otherCell, otherPoint)) { return true; }
}
}
if (NULL != _geometryCollection) {
const vector<PolygonWithCRS*>& polys = _geometryCollection->polygons.vector();
for (size_t i = 0; i < polys.size(); ++i) {
if (containsPoint(polys[i]->polygon, otherCell, otherPoint)) { return true; }
}
const vector<MultiPolygonWithCRS*>& multipolys =_geometryCollection->multiPolygons.vector();
for (size_t i = 0; i < multipolys.size(); ++i) {
const vector<S2Polygon*>& innerpolys = multipolys[i]->polygons.vector();
for (size_t j = 0; j < innerpolys.size(); ++j) {
if (containsPoint(*innerpolys[j], otherCell, otherPoint)) { return true; }
}
}
}
return false;
}
bool containsLine(const S2Polygon& poly, const S2Polyline& otherLine) {
// Kind of a mess. We get a function for clipping the line to the
// polygon. We do this and make sure the line is the same as the
// line we're clipping against.
OwnedPointerVector<S2Polyline> clippedOwned;
vector<S2Polyline*>& clipped = clippedOwned.mutableVector();
poly.IntersectWithPolyline(&otherLine, &clipped);
if (1 != clipped.size()) { return false; }
// If the line is entirely contained within the polygon, we should be
// getting it back verbatim, so really there should be no error.
bool ret = clipped[0]->NearlyCoversPolyline(otherLine,
S1Angle::Degrees(1e-10));
return ret;
}
bool GeometryContainer::contains(const S2Polyline& otherLine) const {
if (NULL != _polygon && (_polygon->crs == SPHERE)) {
return containsLine(_polygon->polygon, otherLine);
}
if (NULL != _multiPolygon) {
const vector<S2Polygon*>& polys = _multiPolygon->polygons.vector();
for (size_t i = 0; i < polys.size(); ++i) {
if (containsLine(*polys[i], otherLine)) { return true; }
}
}
if (NULL != _geometryCollection) {
const vector<PolygonWithCRS*>& polys = _geometryCollection->polygons.vector();
for (size_t i = 0; i < polys.size(); ++i) {
if (containsLine(polys[i]->polygon, otherLine)) { return true; }
}
const vector<MultiPolygonWithCRS*>& multipolys =_geometryCollection->multiPolygons.vector();
for (size_t i = 0; i < multipolys.size(); ++i) {
const vector<S2Polygon*>& innerpolys = multipolys[i]->polygons.vector();
for (size_t j = 0; j < innerpolys.size(); ++j) {
if (containsLine(*innerpolys[j], otherLine)) { return true; }
}
}
}
return false;
}
bool containsPolygon(const S2Polygon& poly, const S2Polygon& otherPoly) {
return poly.Contains(&otherPoly);
}
bool GeometryContainer::contains(const S2Polygon& otherPolygon) const {
if (NULL != _polygon && (_polygon->crs == SPHERE)) {
return containsPolygon(_polygon->polygon, otherPolygon);
}
if (NULL != _multiPolygon) {
const vector<S2Polygon*>& polys = _multiPolygon->polygons.vector();
for (size_t i = 0; i < polys.size(); ++i) {
if (containsPolygon(*polys[i], otherPolygon)) { return true; }
}
}
if (NULL != _geometryCollection) {
const vector<PolygonWithCRS*>& polys = _geometryCollection->polygons.vector();
for (size_t i = 0; i < polys.size(); ++i) {
if (containsPolygon(polys[i]->polygon, otherPolygon)) { return true; }
}
const vector<MultiPolygonWithCRS*>& multipolys =_geometryCollection->multiPolygons.vector();
for (size_t i = 0; i < multipolys.size(); ++i) {
const vector<S2Polygon*>& innerpolys = multipolys[i]->polygons.vector();
for (size_t j = 0; j < innerpolys.size(); ++j) {
if (containsPolygon(*innerpolys[j], otherPolygon)) { return true; }
}
}
}
return false;
}
bool GeometryContainer::intersects(const GeometryContainer& otherContainer) const {
if (NULL != otherContainer._point) {
// The point must be valid lng, lat if it was old-style.
if (FLAT == otherContainer._point->crs
&& !otherContainer._point->flatUpgradedToSphere) {
return false;
}
return intersects(otherContainer._point->cell);
} else if (NULL != otherContainer._line) {
return intersects(otherContainer._line->line);
} else if (NULL != otherContainer._polygon) {
if (SPHERE != otherContainer._polygon->crs) { return false; }
return intersects(otherContainer._polygon->polygon);
} else if (NULL != otherContainer._multiPoint) {
return intersects(*otherContainer._multiPoint);
} else if (NULL != otherContainer._multiLine) {
return intersects(*otherContainer._multiLine);
} else if (NULL != otherContainer._multiPolygon) {
return intersects(*otherContainer._multiPolygon);
} else if (NULL != otherContainer._geometryCollection) {
const GeometryCollection& c = *otherContainer._geometryCollection;
for (size_t i = 0; i < c.points.size(); ++i) {
if (intersects(c.points[i].cell)) { return true; }
}
for (size_t i = 0; i < c.polygons.vector().size(); ++i) {
if (intersects(c.polygons.vector()[i]->polygon)) { return true; }
}
for (size_t i = 0; i < c.lines.vector().size(); ++i) {
if (intersects(c.lines.vector()[i]->line)) { return true; }
}
for (size_t i = 0; i < c.multiPolygons.vector().size(); ++i) {
if (intersects(*c.multiPolygons.vector()[i])) { return true; }
}
for (size_t i = 0; i < c.multiLines.vector().size(); ++i) {
if (intersects(*c.multiLines.vector()[i])) { return true; }
}
for (size_t i = 0; i < c.multiPoints.vector().size(); ++i) {
if (intersects(*c.multiPoints.vector()[i])) { return true; }
}
}
return false;
}
bool GeometryContainer::intersects(const MultiPointWithCRS& otherMultiPoint) const {
for (size_t i = 0; i < otherMultiPoint.cells.size(); ++i) {
if (intersects(otherMultiPoint.cells[i])) { return true; }
}
return false;
}
bool GeometryContainer::intersects(const MultiLineWithCRS& otherMultiLine) const {
for (size_t i = 0; i < otherMultiLine.lines.vector().size(); ++i) {
if (intersects(*otherMultiLine.lines.vector()[i])) { return true; }
}
return false;
}
bool GeometryContainer::intersects(const MultiPolygonWithCRS& otherMultiPolygon) const {
for (size_t i = 0; i < otherMultiPolygon.polygons.vector().size(); ++i) {
if (intersects(*otherMultiPolygon.polygons.vector()[i])) { return true; }
}
return false;
}
// Does this (GeometryContainer) intersect the provided data?
bool GeometryContainer::intersects(const S2Cell &otherPoint) const {
if (NULL != _point) {
// The point must be valid lng, lat if it was old-style.
if (FLAT == _point->crs && !_point->flatUpgradedToSphere) {
return false;
}
return _point->cell.MayIntersect(otherPoint);
} else if (NULL != _line) {
return _line->line.MayIntersect(otherPoint);
} else if (NULL != _polygon) {
return _polygon->polygon.MayIntersect(otherPoint);
} else if (NULL != _multiPoint) {
const vector<S2Cell>& cells = _multiPoint->cells;
for (size_t i = 0; i < cells.size(); ++i) {
if (cells[i].MayIntersect(otherPoint)) { return true; }
}
} else if (NULL != _multiLine) {
const vector<S2Polyline*>& lines = _multiLine->lines.vector();
for (size_t i = 0; i < lines.size(); ++i) {
if (lines[i]->MayIntersect(otherPoint)) { return true; }
}
} else if (NULL != _multiPolygon) {
const vector<S2Polygon*>& polys = _multiPolygon->polygons.vector();
for (size_t i = 0; i < polys.size(); ++i) {
if (polys[i]->MayIntersect(otherPoint)) { return true; }
}
} else if (NULL != _geometryCollection) {
const GeometryCollection& c = *_geometryCollection;
for (size_t i = 0; i < c.points.size(); ++i) {
if (c.points[i].cell.MayIntersect(otherPoint)) { return true; }
}
for (size_t i = 0; i < c.polygons.vector().size(); ++i) {
if (c.polygons.vector()[i]->polygon.MayIntersect(otherPoint)) { return true; }
}
for (size_t i = 0; i < c.lines.vector().size(); ++i) {
if (c.lines.vector()[i]->line.MayIntersect(otherPoint)) { return true; }
}
for (size_t i = 0; i < c.multiPolygons.vector().size(); ++i) {
const vector<S2Polygon*>& innerPolys =
c.multiPolygons.vector()[i]->polygons.vector();
for (size_t j = 0; j < innerPolys.size(); ++j) {
if (innerPolys[j]->MayIntersect(otherPoint)) { return true; }
}
}
for (size_t i = 0; i < c.multiLines.vector().size(); ++i) {
const vector<S2Polyline*>& innerLines =
c.multiLines.vector()[i]->lines.vector();
for (size_t j = 0; j < innerLines.size(); ++j) {
if (innerLines[j]->MayIntersect(otherPoint)) { return true; }
}
}
for (size_t i = 0; i < c.multiPoints.vector().size(); ++i) {
const vector<S2Cell>& innerCells = c.multiPoints.vector()[i]->cells;
for (size_t j = 0; j < innerCells.size(); ++j) {
if (innerCells[j].MayIntersect(otherPoint)) { return true; }
}
}
}
return false;
}
bool polygonLineIntersection(const S2Polyline& line, const S2Polygon& poly) {
// TODO(hk): modify s2 library to just let us know if it intersected
// rather than returning all this.
vector<S2Polyline*> clipped;
poly.IntersectWithPolyline(&line, &clipped);
bool ret = clipped.size() > 0;
for (size_t i = 0; i < clipped.size(); ++i) delete clipped[i];
return ret;
}
bool GeometryContainer::intersects(const S2Polyline& otherLine) const {
if (NULL != _point) {
// The point must be valid lng, lat if it was old-style.
if (FLAT == _point->crs && !_point->flatUpgradedToSphere) {
return false;
}
return otherLine.MayIntersect(_point->cell);
} else if (NULL != _line) {
return otherLine.Intersects(&_line->line);
} else if (NULL != _polygon && (_polygon->crs == SPHERE)) {
return polygonLineIntersection(otherLine, _polygon->polygon);
} else if (NULL != _multiPoint) {
for (size_t i = 0; i < _multiPoint->cells.size(); ++i) {
if (otherLine.MayIntersect(_multiPoint->cells[i])) { return true; }
}
} else if (NULL != _multiLine) {
for (size_t i = 0; i < _multiLine->lines.vector().size(); ++i) {
if (otherLine.Intersects(_multiLine->lines.vector()[i])) {
return true;
}
}
} else if (NULL != _multiPolygon) {
for (size_t i = 0; i < _multiPolygon->polygons.vector().size(); ++i) {
if (polygonLineIntersection(otherLine, *_multiPolygon->polygons.vector()[i])) {
return true;
}
}
} else if (NULL != _geometryCollection) {
const GeometryCollection& c = *_geometryCollection;
for (size_t i = 0; i < c.points.size(); ++i) {
if (otherLine.MayIntersect(c.points[i].cell)) { return true; }
}
for (size_t i = 0; i < c.polygons.vector().size(); ++i) {
if (polygonLineIntersection(otherLine, c.polygons.vector()[i]->polygon)) {
return true;
}
}
for (size_t i = 0; i < c.lines.vector().size(); ++i) {
if (c.lines.vector()[i]->line.Intersects(&otherLine)) { return true; }
}
for (size_t i = 0; i < c.multiPolygons.vector().size(); ++i) {
const vector<S2Polygon*>& innerPolys =
c.multiPolygons.vector()[i]->polygons.vector();
for (size_t j = 0; j < innerPolys.size(); ++j) {
if (polygonLineIntersection(otherLine, *innerPolys[j])) {
return true;
}
}
}
for (size_t i = 0; i < c.multiLines.vector().size(); ++i) {
const vector<S2Polyline*>& innerLines =
c.multiLines.vector()[i]->lines.vector();
for (size_t j = 0; j < innerLines.size(); ++j) {
if (innerLines[j]->Intersects(&otherLine)) { return true; }
}
}
for (size_t i = 0; i < c.multiPoints.vector().size(); ++i) {
const vector<S2Cell>& innerCells = c.multiPoints.vector()[i]->cells;
for (size_t j = 0; j < innerCells.size(); ++j) {
if (otherLine.MayIntersect(innerCells[j])) { return true; }
}
}
}
return false;
}
// Does 'this' intersect with the provided polygon?
bool GeometryContainer::intersects(const S2Polygon& otherPolygon) const {
if (NULL != _point) {
// The point must be valid lng, lat if it was old-style.
if (FLAT == _point->crs && !_point->flatUpgradedToSphere) {
return false;
}
return otherPolygon.MayIntersect(_point->cell);
} else if (NULL != _line) {
return polygonLineIntersection(_line->line, otherPolygon);
} else if (NULL != _polygon) {
return otherPolygon.Intersects(&_polygon->polygon);
} else if (NULL != _multiPoint) {
for (size_t i = 0; i < _multiPoint->cells.size(); ++i) {
if (otherPolygon.MayIntersect(_multiPoint->cells[i])) { return true; }
}
} else if (NULL != _multiLine) {
for (size_t i = 0; i < _multiLine->lines.vector().size(); ++i) {
if (polygonLineIntersection(*_multiLine->lines.vector()[i], otherPolygon)) {
return true;
}
}
} else if (NULL != _multiPolygon) {
for (size_t i = 0; i < _multiPolygon->polygons.vector().size(); ++i) {
if (otherPolygon.Intersects(_multiPolygon->polygons.vector()[i])) {
return true;
}
}
} else if (NULL != _geometryCollection) {
const GeometryCollection& c = *_geometryCollection;
for (size_t i = 0; i < c.points.size(); ++i) {
if (otherPolygon.MayIntersect(c.points[i].cell)) { return true; }
}
for (size_t i = 0; i < c.polygons.vector().size(); ++i) {
if (otherPolygon.Intersects(&c.polygons.vector()[i]->polygon)) {
return true;
}
}
for (size_t i = 0; i < c.lines.vector().size(); ++i) {
if (polygonLineIntersection(c.lines.vector()[i]->line, otherPolygon)) {
return true;
}
}
for (size_t i = 0; i < c.multiPolygons.vector().size(); ++i) {
const vector<S2Polygon*>& innerPolys =
c.multiPolygons.vector()[i]->polygons.vector();
for (size_t j = 0; j < innerPolys.size(); ++j) {
if (otherPolygon.Intersects(innerPolys[j])) {
return true;
}
}
}
for (size_t i = 0; i < c.multiLines.vector().size(); ++i) {
const vector<S2Polyline*>& innerLines =
c.multiLines.vector()[i]->lines.vector();
for (size_t j = 0; j < innerLines.size(); ++j) {
if (polygonLineIntersection(*innerLines[j], otherPolygon)) {
return true;
}
}
}
for (size_t i = 0; i < c.multiPoints.vector().size(); ++i) {
const vector<S2Cell>& innerCells = c.multiPoints.vector()[i]->cells;
for (size_t j = 0; j < innerCells.size(); ++j) {
if (otherPolygon.MayIntersect(innerCells[j])) {
return true;
}
}
}
}
return false;
}
bool GeometryContainer::parseFrom(const BSONObj& obj) {
if (GeoParser::isPolygon(obj)) {
// We can't really pass these things around willy-nilly except by ptr.
_polygon.reset(new PolygonWithCRS());
if (!GeoParser::parsePolygon(obj, _polygon.get())) { return false; }
} else if (GeoParser::isIndexablePoint(obj)) {
_point.reset(new PointWithCRS());
if (!GeoParser::parsePoint(obj, _point.get())) { return false; }
} else if (GeoParser::isLine(obj)) {
_line.reset(new LineWithCRS());
if (!GeoParser::parseLine(obj, _line.get())) { return false; }
} else if (GeoParser::isBox(obj)) {
_box.reset(new BoxWithCRS());
if (!GeoParser::parseBox(obj, _box.get())) { return false; }
} else if (GeoParser::isCap(obj)) {
_cap.reset(new CapWithCRS());
if (!GeoParser::parseCap(obj, _cap.get())) { return false; }
} else if (GeoParser::isMultiPoint(obj)) {
_multiPoint.reset(new MultiPointWithCRS());
if (!GeoParser::parseMultiPoint(obj, _multiPoint.get())) { return false; }
_s2Region.reset(new S2RegionUnion());
for (size_t i = 0; i < _multiPoint->cells.size(); ++i) {
_s2Region->Add(&_multiPoint->cells[i]);
}
} else if (GeoParser::isMultiLine(obj)) {
_multiLine.reset(new MultiLineWithCRS());
if (!GeoParser::parseMultiLine(obj, _multiLine.get())) { return false; }
_s2Region.reset(new S2RegionUnion());
for (size_t i = 0; i < _multiLine->lines.vector().size(); ++i) {
_s2Region->Add(_multiLine->lines.vector()[i]);
}
} else if (GeoParser::isMultiPolygon(obj)) {
_multiPolygon.reset(new MultiPolygonWithCRS());
if (!GeoParser::parseMultiPolygon(obj, _multiPolygon.get())) { return false; }
_s2Region.reset(new S2RegionUnion());
for (size_t i = 0; i < _multiPolygon->polygons.vector().size(); ++i) {
_s2Region->Add(_multiPolygon->polygons.vector()[i]);
}
} else if (GeoParser::isGeometryCollection(obj)) {
_geometryCollection.reset(new GeometryCollection());
if (!GeoParser::parseGeometryCollection(obj, _geometryCollection.get())) {
return false;
}
_s2Region.reset(new S2RegionUnion());
for (size_t i = 0; i < _geometryCollection->points.size(); ++i) {
_s2Region->Add(&_geometryCollection->points[i].cell);
}
for (size_t i = 0; i < _geometryCollection->lines.vector().size(); ++i) {
_s2Region->Add(&_geometryCollection->lines.vector()[i]->line);
}
for (size_t i = 0; i < _geometryCollection->polygons.vector().size(); ++i) {
_s2Region->Add(&_geometryCollection->polygons.vector()[i]->polygon);
}
for (size_t i = 0; i < _geometryCollection->multiPoints.vector().size(); ++i) {
MultiPointWithCRS* multiPoint = _geometryCollection->multiPoints.vector()[i];
for (size_t j = 0; j < multiPoint->cells.size(); ++j) {
_s2Region->Add(&multiPoint->cells[j]);
}
}
for (size_t i = 0; i < _geometryCollection->multiLines.vector().size(); ++i) {
const MultiLineWithCRS* multiLine = _geometryCollection->multiLines.vector()[i];
for (size_t j = 0; j < multiLine->lines.vector().size(); ++j) {
_s2Region->Add(multiLine->lines.vector()[j]);
}
}
for (size_t i = 0; i < _geometryCollection->multiPolygons.vector().size(); ++i) {
const MultiPolygonWithCRS* multiPolygon =
_geometryCollection->multiPolygons.vector()[i];
for (size_t j = 0; j < multiPolygon->polygons.vector().size(); ++j) {
_s2Region->Add(multiPolygon->polygons.vector()[j]);
}
}
} else {
return false;
}
// If we support R2 regions, build the region immediately
if (hasR2Region())
_r2Region.reset(new R2BoxRegion(this));
return true;
}
string GeometryContainer::getDebugType() const {
if (NULL != _point) { return "pt"; }
else if (NULL != _line) { return "ln"; }
else if (NULL != _box) { return "bx"; }
else if (NULL != _polygon) { return "pl"; }
else if (NULL != _cap ) { return "cc"; }
else if (NULL != _multiPoint) { return "mp"; }
else if (NULL != _multiLine) { return "ml"; }
else if (NULL != _multiPolygon) { return "my"; }
else if (NULL != _geometryCollection) { return "gc"; }
else {
invariant(false);
return "";
}
}
CRS GeometryContainer::getNativeCRS() const {
// TODO: Fix geometry collection reporting when/if we support multiple CRSes
if (NULL != _point) { return _point->crs; }
else if (NULL != _line) { return _line->crs; }
else if (NULL != _box) { return _box->crs; }
else if (NULL != _polygon) { return _polygon->crs; }
else if (NULL != _cap ) { return _cap->crs; }
else if (NULL != _multiPoint) { return _multiPoint->crs; }
else if (NULL != _multiLine) { return _multiLine->crs; }
else if (NULL != _multiPolygon) { return _multiPolygon->crs; }
else if (NULL != _geometryCollection) { return SPHERE; }
else {
invariant(false);
return FLAT;
}
}
bool GeometryContainer::supportsProject(CRS otherCRS) const {
// TODO: Fix geometry collection reporting when/if we support more CRSes
if (NULL != _point) {
if (_point->crs == otherCRS) return true;
// SPHERE can always go FLAT, but FLAT may not always go back to SPHERE
return _point->crs == SPHERE || _point->flatUpgradedToSphere;
}
else if (NULL != _line) { return _line->crs == otherCRS; }
else if (NULL != _box) { return _box->crs == otherCRS; }
else if (NULL != _polygon) { return _polygon->crs == otherCRS; }
else if (NULL != _cap ) { return _cap->crs == otherCRS; }
else if (NULL != _multiPoint) { return _multiPoint->crs == otherCRS; }
else if (NULL != _multiLine) { return _multiLine->crs == otherCRS; }
else if (NULL != _multiPolygon) { return _multiPolygon->crs == otherCRS; }
else if (NULL != _geometryCollection) { return SPHERE == otherCRS; }
else {
invariant(false);
return false;
}
}
void GeometryContainer::projectInto(CRS otherCRS) {
if (otherCRS == getNativeCRS())
return;
invariant(NULL != _point);
if (FLAT == _point->crs) {
invariant(_point->flatUpgradedToSphere);
_point->crs = SPHERE;
}
else {
invariant(FLAT == otherCRS);
S2LatLng latLng(_point->point);
_point->oldPoint = Point(latLng.lng().degrees(), latLng.lat().degrees());
_point->flatUpgradedToSphere = true;
_point->crs = FLAT;
}
}
static double s2MinDistanceRad(const S2Point& s2Point, const MultiPointWithCRS& s2MultiPoint) {
double minDistance = -1;
for (vector<S2Point>::const_iterator it = s2MultiPoint.points.begin();
it != s2MultiPoint.points.end(); ++it) {
double nextDistance = S2Distance::distanceRad(s2Point, *it);
if (minDistance < 0 || nextDistance < minDistance) {
minDistance = nextDistance;
}
}
return minDistance;
}
static double s2MinDistanceRad(const S2Point& s2Point, const MultiLineWithCRS& s2MultiLine) {
double minDistance = -1;
for (vector<S2Polyline*>::const_iterator it = s2MultiLine.lines.vector().begin();
it != s2MultiLine.lines.vector().end(); ++it) {
double nextDistance = S2Distance::minDistanceRad(s2Point, **it);
if (minDistance < 0 || nextDistance < minDistance) {
minDistance = nextDistance;
}
}
return minDistance;
}
static double s2MinDistanceRad(const S2Point& s2Point, const MultiPolygonWithCRS& s2MultiPolygon) {
double minDistance = -1;
for (vector<S2Polygon*>::const_iterator it = s2MultiPolygon.polygons.vector().begin();
it != s2MultiPolygon.polygons.vector().end(); ++it) {
double nextDistance = S2Distance::minDistanceRad(s2Point, **it);
if (minDistance < 0 || nextDistance < minDistance) {
minDistance = nextDistance;
}
}
return minDistance;
}
static double s2MinDistanceRad(const S2Point& s2Point,
const GeometryCollection& geometryCollection) {
double minDistance = -1;
for (vector<PointWithCRS>::const_iterator it = geometryCollection.points.begin();
it != geometryCollection.points.end(); ++it) {
invariant(SPHERE == it->crs);
double nextDistance = S2Distance::distanceRad(s2Point, it->point);
if (minDistance < 0 || nextDistance < minDistance) {
minDistance = nextDistance;
}
}
for (vector<LineWithCRS*>::const_iterator it = geometryCollection.lines.vector().begin();
it != geometryCollection.lines.vector().end(); ++it) {
invariant(SPHERE == (*it)->crs);
double nextDistance = S2Distance::minDistanceRad(s2Point, (*it)->line);
if (minDistance < 0 || nextDistance < minDistance) {
minDistance = nextDistance;
}
}
for (vector<PolygonWithCRS*>::const_iterator it = geometryCollection.polygons.vector().begin();
it != geometryCollection.polygons.vector().end(); ++it) {
invariant(SPHERE == (*it)->crs);
double nextDistance = S2Distance::minDistanceRad(s2Point, (*it)->polygon);
if (minDistance < 0 || nextDistance < minDistance) {
minDistance = nextDistance;
}
}
for (vector<MultiPointWithCRS*>::const_iterator it = geometryCollection.multiPoints.vector()
.begin(); it != geometryCollection.multiPoints.vector().end(); ++it) {
double nextDistance = s2MinDistanceRad(s2Point, **it);
if (minDistance < 0 || nextDistance < minDistance) {
minDistance = nextDistance;
}
}
for (vector<MultiLineWithCRS*>::const_iterator it = geometryCollection.multiLines.vector()
.begin(); it != geometryCollection.multiLines.vector().end(); ++it) {
double nextDistance = s2MinDistanceRad(s2Point, **it);
if (minDistance < 0 || nextDistance < minDistance) {
minDistance = nextDistance;
}
}
for (vector<MultiPolygonWithCRS*>::const_iterator it = geometryCollection.multiPolygons
.vector().begin(); it != geometryCollection.multiPolygons.vector().end(); ++it) {
double nextDistance = s2MinDistanceRad(s2Point, **it);
if (minDistance < 0 || nextDistance < minDistance) {
minDistance = nextDistance;
}
}
return minDistance;
}
double GeometryContainer::minDistance(const PointWithCRS& otherPoint) const {
const CRS crs = getNativeCRS();
if (FLAT == crs) {
invariant(NULL != _point);
if (FLAT == otherPoint.crs) {
return distance(_point->oldPoint, otherPoint.oldPoint);
}
else {
S2LatLng latLng(otherPoint.point);
return distance(_point->oldPoint,
Point(latLng.lng().degrees(), latLng.lat().degrees()));
}
}
else {
invariant(SPHERE == crs);
invariant(FLAT != otherPoint.crs || otherPoint.flatUpgradedToSphere);
double minDistance = -1;
if (NULL != _point) {
minDistance = S2Distance::distanceRad(otherPoint.point, _point->point);
}
else if (NULL != _line) {
minDistance = S2Distance::minDistanceRad(otherPoint.point, _line->line);
}
else if (NULL != _polygon) {
minDistance = S2Distance::minDistanceRad(otherPoint.point, _polygon->polygon);
}
else if (NULL != _cap) {
minDistance = S2Distance::minDistanceRad(otherPoint.point, _cap->cap);
}
else if (NULL != _multiPoint) {
minDistance = s2MinDistanceRad(otherPoint.point, *_multiPoint);
}
else if (NULL != _multiLine) {
minDistance = s2MinDistanceRad(otherPoint.point, *_multiLine);
}
else if (NULL != _multiPolygon) {
minDistance = s2MinDistanceRad(otherPoint.point, *_multiPolygon);
}
else if (NULL != _geometryCollection) {
minDistance = s2MinDistanceRad(otherPoint.point, *_geometryCollection);
}
invariant(minDistance != -1);
return minDistance * kRadiusOfEarthInMeters;
}
}
const CapWithCRS* GeometryContainer::getCapGeometryHack() const {
return _cap.get();
}
} // namespace mongo
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