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/*
*
* This file is part of QMapControl,
* an open-source cross-platform map widget
*
* Copyright (C) 2007 - 2008 Kai Winter
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* 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 Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with QMapControl. If not, see <http://www.gnu.org/licenses/>.
*
* Contact e-mail: kaiwinter@gmx.de
* Program URL : http://qmapcontrol.sourceforge.net/
*
*/
#include "googlesatmapadapter.h"
#include <math.h>
namespace qmapcontrol
{
GoogleSatMapAdapter::GoogleSatMapAdapter()
: TileMapAdapter("kh.google.com", "/kh?n=404&v=8&t=trtqtt", 256, 0, 19)
{
// name = "googlesat";
numberOfTiles = pow(2, current_zoom+0.0);
coord_per_x_tile = 360. / numberOfTiles;
coord_per_y_tile = 180. / numberOfTiles;
}
GoogleSatMapAdapter::~GoogleSatMapAdapter()
{
}
QString GoogleSatMapAdapter::getHost() const
{
int random = qrand() % 4;
return QString("kh%1.google.com").arg(random);
}
QPoint GoogleSatMapAdapter::coordinateToDisplay(const QPointF& coordinate) const
{
//double x = ((coordinate.x()+180)*(tilesize*numberOfTiles/360));
//double y = (((coordinate.y()*-1)+90)*(tilesize*numberOfTiles/180));
qreal x = (coordinate.x()+180.) * (numberOfTiles*mytilesize)/360.; // coord to pixel!
//double y = -1*(coordinate.y()-90) * (numberOfTiles*tilesize)/180.; // coord to pixel!
qreal y = (getMercatorYCoord(coordinate.y())-M_PI) * -1 * (numberOfTiles*mytilesize)/(2*M_PI); // coord to pixel!
return QPoint(int(x), int(y));
}
QPointF GoogleSatMapAdapter::displayToCoordinate(const QPoint& point) const
{
//double lon = ((point.x()/tilesize*numberOfTiles)*360)-180;
//double lat = (((point.y()/tilesize*numberOfTiles)*180)-90)*-1;
qreal lon = (point.x()*(360./(numberOfTiles*mytilesize)))-180.;
//double lat = -(point.y()*(180./(numberOfTiles*tilesize)))+90;
//qreal lat = getMercatorLatitude(point.y()*-1*(2*M_PI/(numberOfTiles*tilesize)) + M_PI);
qreal lat = lat *180./M_PI;
return QPointF(lon, lat);
}
qreal GoogleSatMapAdapter::getMercatorLatitude(qreal YCoord) const
{
//http://welcome.warnercnr.colostate.edu/class_info/nr502/lg4/projection_mathematics/converting.html
if (YCoord > M_PI) return 9999.;
if (YCoord < -M_PI) return -9999.;
qreal t = atan(exp(YCoord));
qreal res = (2.*(t))-(M_PI/2.);
return res;
}
qreal GoogleSatMapAdapter::getMercatorYCoord(qreal lati) const
{
qreal lat = lati;
// conversion degre=>radians
qreal phi = M_PI * lat / 180;
qreal res;
//double temp = Math.Tan(Math.PI / 4 - phi / 2);
//res = Math.Log(temp);
res = 0.5 * log((1 + sin(phi)) / (1 - sin(phi)));
return res;
}
void GoogleSatMapAdapter::zoom_in()
{
current_zoom+=1;
numberOfTiles = pow(2, current_zoom+0.0);
coord_per_x_tile = 360. / numberOfTiles;
coord_per_y_tile = 180. / numberOfTiles;
}
void GoogleSatMapAdapter::zoom_out()
{
current_zoom-=1;
numberOfTiles = pow(2, current_zoom+0.0);
coord_per_x_tile = 360. / numberOfTiles;
coord_per_y_tile = 180. / numberOfTiles;
}
bool GoogleSatMapAdapter::isValid(int x, int y, int z) const
{
if ((x>=0 && x < numberOfTiles) && (y>=0 && y < numberOfTiles) && z>=0)
{
return true;
}
return false;
}
QString GoogleSatMapAdapter::query(int i, int j, int z) const
{
return getQ(-180+i*coord_per_x_tile,
90-(j+1)*coord_per_y_tile, z);
}
QString GoogleSatMapAdapter::getQ(qreal longitude, qreal latitude, int zoom) const
{
qreal xmin=-180;
qreal xmax=180;
qreal ymin=-90;
qreal ymax=90;
qreal xmoy=0;
qreal ymoy=0;
QString location="t";
//Google uses a latitude divided by 2;
qreal halflat = latitude;
for (int i = 0; i < zoom; i++)
{
xmoy = (xmax + xmin) / 2;
ymoy = (ymax + ymin) / 2;
if (halflat >= ymoy) //upper part (q or r)
{
ymin = ymoy;
if (longitude < xmoy)
{ /*q*/
location+= "q";
xmax = xmoy;
}
else
{/*r*/
location+= "r";
xmin = xmoy;
}
}
else //lower part (t or s)
{
ymax = ymoy;
if (longitude < xmoy)
{ /*t*/
location+= "t";
xmax = xmoy;
}
else
{/*s*/
location+= "s";
xmin = xmoy;
}
}
}
return QString("/kh?n=404&v=24&t=%1").arg(location);
}
}