mirror of
git://projects.qi-hardware.com/nanomap.git
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290 lines
7.9 KiB
C
290 lines
7.9 KiB
C
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/*
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Copyright 2010 Christian Vetter veaac.fdirct@gmail.com
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This file is part of MoNav.
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MoNav is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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MoNav is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with MoNav. If not, see <http://www.gnu.org/licenses/>.
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*/
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#ifndef COORDINATES_H_INCLUDED
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#define COORDINATES_H_INCLUDED
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#include <limits>
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#include <cmath>
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#include <cassert>
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#ifndef M_PI
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#define M_PI 3.14159265358979323846
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#endif
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class GPSCoordinate {
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public:
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GPSCoordinate()
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{
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latitude = longitude = std::numeric_limits< double >::max();
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}
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GPSCoordinate( double lat, double lon )
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{
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latitude = lat;
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longitude = lon;
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}
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double Distance( const GPSCoordinate &right ) const
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{
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assert( fabs( latitude ) < 90 && fabs( right.latitude ) < 90 );
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//assert ( nicht antipodal, nicht an den Polen )
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// convert inputs in degrees to radians:
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static const double DEG_TO_RAD = 0.017453292519943295769236907684886;
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double lat1 = latitude * DEG_TO_RAD;
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double lon1 = longitude * DEG_TO_RAD;
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double lat2 = right.latitude * DEG_TO_RAD;
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double lon2 = right.longitude * DEG_TO_RAD;
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static const double a = 6378137;
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static const double b = 6356752.31424518;
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static const double f = ( a - b ) / a;
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const double U1 = atan(( 1 - f ) * tan( lat1 ) );
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const double U2 = atan(( 1 - f ) * tan( lat2 ) );
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const double cosU1 = cos( U1 );
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const double cosU2 = cos( U2 );
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const double sinU1 = sin( U1 );
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const double sinU2 = sin( U2 );
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const double L = fabs( lon2 - lon1 );
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double lambda = L;
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double lambdaOld;
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unsigned iterLimit = 50;
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while ( true ) {
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const double cosLambda = cos( lambda );
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const double sinLambda = sin( lambda );
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const double leftSinSigma = cosU2 * sinLambda;
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const double rightSinSigma = cosU1 * sinU2 - sinU1 * cosU2 * cosLambda;
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const double sinSigma = sqrt( leftSinSigma * leftSinSigma + rightSinSigma * rightSinSigma );
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if ( sinSigma == 0 ) // Fast identisch
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return 0;
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const double cosSigma = sinU1 * sinU2 + cosU1 * cosU2 * cosLambda;
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const double sigma = atan2( sinSigma, cosSigma );
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const double sinAlpha = cosU1 * cosU2 * sinLambda / sinSigma;
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const double cosSquareAlpha = 1 - sinAlpha * sinAlpha;
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double cos2sigmam = cosSigma - 2 * sinU1 * sinU2 / cosSquareAlpha;
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if ( cos2sigmam != cos2sigmam ) // NAN: Parellel zum Äquator
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cos2sigmam = 0;
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const double C = f / 16 * cosSquareAlpha * ( 4 + f * ( 4 - 3 * cosSquareAlpha ) );
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lambdaOld = lambda;
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lambda = L + ( 1 - C ) * f * sinAlpha * ( sigma + C * sinSigma * ( cos2sigmam + C * cosSigma * ( -1 + 2 * cos2sigmam * cos2sigmam ) ) );
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if ( fabs( lambda - lambdaOld ) < 1e-12 || --iterLimit == 0 ) {
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const double u2 = cosSquareAlpha * ( a * a - b * b ) / ( b * b );
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const double A = 1 + u2 / 16384 * ( 4096 + u2 * ( -768 + u2 * ( 320 - 175 * u2 ) ) );
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const double B = u2 / 1024 * ( 256 + u2 * ( -128 + u2 * ( 74 - 47 * u2 ) ) );
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const double deltasigma = B * sinSigma * ( cos2sigmam + B / 4 * ( cosSigma * ( -1 + 2 * cos2sigmam * cos2sigmam ) - B / 6 * cos2sigmam * ( -3 + 4 * sinSigma * sinSigma ) * ( -3 + 4 * cos2sigmam * cos2sigmam ) ) );
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return b * A * ( sigma - deltasigma );
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}
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}
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//should never be reached
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return 0;
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}
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double ApproximateDistance( const GPSCoordinate &right ) const
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{
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static const double DEG_TO_RAD = 0.017453292519943295769236907684886;
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///Earth's quatratic mean radius for WGS-84
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static const double EARTH_RADIUS_IN_METERS = 6372797.560856;
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double latitudeArc = ( latitude - right.latitude ) * DEG_TO_RAD;
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double longitudeArc = ( longitude - right.longitude ) * DEG_TO_RAD;
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double latitudeH = sin( latitudeArc * 0.5 );
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latitudeH *= latitudeH;
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double lontitudeH = sin( longitudeArc * 0.5 );
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lontitudeH *= lontitudeH;
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double tmp = cos( latitude * DEG_TO_RAD ) * cos( right.latitude * DEG_TO_RAD );
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double distanceArc = 2.0 * asin( sqrt( latitudeH + tmp * lontitudeH ) );
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return EARTH_RADIUS_IN_METERS * distanceArc;
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}
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bool operator==( const GPSCoordinate& right ) const
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{
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return latitude == right.latitude && longitude == right.longitude;
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}
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bool operator!=( const GPSCoordinate& right ) const
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{
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return !( *this == right );
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}
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bool operator<( const GPSCoordinate& right ) const
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{
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if ( latitude != right.latitude )
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return latitude < right.latitude;
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return longitude < right.longitude;
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}
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bool IsValid() const
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{
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return latitude != std::numeric_limits< double >::max() && longitude != std::numeric_limits< double >::max();
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}
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double latitude, longitude;
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};
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class ProjectedCoordinate {
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public:
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ProjectedCoordinate()
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{
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x = y = std::numeric_limits< double >::max();
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}
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ProjectedCoordinate( double xVal, double yVal )
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{
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x = xVal;
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y = yVal;
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}
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ProjectedCoordinate( double xVal, double yVal, int zoom ) {
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x = xVal / ( 1u << zoom );
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y = yVal / ( 1u << zoom );
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}
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explicit ProjectedCoordinate( const GPSCoordinate& gps )
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{
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x = ( gps.longitude + 180.0 ) / 360.0;
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y = ( 1.0 - log( tan( gps.latitude * M_PI / 180.0 ) + 1.0 / cos( gps.latitude * M_PI / 180.0 ) ) / M_PI ) / 2.0;
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}
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GPSCoordinate ToGPSCoordinate() const
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{
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GPSCoordinate gps;
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gps.longitude = x * 360.0 - 180;
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const double n = M_PI - 2.0 * M_PI * y;
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gps.latitude = 180.0 / M_PI * atan( 0.5 * ( exp( n ) - exp( -n ) ) );
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return gps;
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}
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bool operator==( const ProjectedCoordinate& right ) const
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{
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return x == right.x && y == right.y;
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}
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bool operator!=( const ProjectedCoordinate& right ) const
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{
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return !( *this == right );
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}
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bool operator<( const ProjectedCoordinate& right ) const
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{
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if ( x != right.x )
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return x < right.x;
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return y < right.y;
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}
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bool IsValid() const
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{
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return x != std::numeric_limits< double >::max() && y != std::numeric_limits< double >::max();
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}
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double x, y;
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};
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class UnsignedCoordinate {
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public:
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UnsignedCoordinate()
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{
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x = y = std::numeric_limits< unsigned >::max();
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}
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UnsignedCoordinate( unsigned xVal, unsigned yVal )
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{
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x = xVal;
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y = yVal;
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}
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explicit UnsignedCoordinate( ProjectedCoordinate tile )
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{
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x = floor( tile.x * ( 1u << 30 ) );
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y = floor( tile.y * ( 1u << 30 ) );
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}
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explicit UnsignedCoordinate( GPSCoordinate gps )
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{
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*this = UnsignedCoordinate( ProjectedCoordinate( gps ) );
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}
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GPSCoordinate ToGPSCoordinate() const
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{
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return ToProjectedCoordinate().ToGPSCoordinate();
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}
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ProjectedCoordinate ToProjectedCoordinate() const
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{
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ProjectedCoordinate tile;
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tile.x = x;
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tile.y = y;
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tile.x /= ( 1u << 30 );
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tile.y /= ( 1u << 30 );
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return tile;
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}
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unsigned GetTileX( int zoom ) const {
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if ( zoom == 0 )
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return 0;
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return x >> ( 30 - zoom );
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}
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unsigned GetTileY( int zoom ) const {
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if ( zoom == 0 )
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return 0;
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return y >> ( 30 - zoom );
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}
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unsigned GetTileSubX( int zoom, int precision ) const {
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assert( zoom + precision < 31 );
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assert( zoom + precision > 0 );
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const unsigned subX = ( x << zoom ) >> zoom;
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return subX >> ( 30 - precision - zoom );
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}
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unsigned GetTileSubY( int zoom, int precision ) const {
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assert( zoom + precision < 31 );
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assert( zoom + precision > 0 );
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const unsigned subY = ( y << zoom ) >> zoom;
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return subY >> ( 30 - precision - zoom );
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}
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bool operator==( const UnsignedCoordinate& right ) const
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{
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return x == right.x && y == right.y;
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}
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bool operator!=( const UnsignedCoordinate& right ) const
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{
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return !( *this == right );
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}
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bool operator<( const UnsignedCoordinate& right ) const
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{
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if ( x != right.x )
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return x < right.x;
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return y < right.y;
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}
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bool IsValid() const
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{
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return x != std::numeric_limits< unsigned >::max() && y != std::numeric_limits< unsigned >::max();
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}
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unsigned x, y;
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};
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#endif // COORDINATES_H_INCLUDED
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