int main(int argc, char** argv)
{
osg::ArgumentParser arguments(&argc,argv);
osgViewer::Viewer viewer(arguments);
// Start by creating the map:
MapOptions mapOptions;
mapOptions.cachePolicy() = CachePolicy::NO_CACHE;
Map* map = new Map( mapOptions );
// Create out image layer with a custom tile source.
ImageLayerOptions options( "custom" );
CustomTileSource* tileSource = new CustomTileSource();
tileSource->open();
map->addImageLayer( new ImageLayer(options, tileSource) );
// That's it, the map is ready; now create a MapNode to render the Map:
MapNode* mapNode = new MapNode( map );
viewer.setSceneData( mapNode );
viewer.setCameraManipulator( new EarthManipulator() );
// add some stock OSG handlers:
viewer.addEventHandler(new osgViewer::StatsHandler());
viewer.addEventHandler(new osgViewer::WindowSizeHandler());
viewer.addEventHandler(new osgGA::StateSetManipulator(viewer.getCamera()->getOrCreateStateSet()));
return viewer.run();
}
virtual ReadResult readNode(const std::string& fileName, const osgDB::Options* options) const
{
std::string ext = osgDB::getFileExtension( fileName );
if ( !acceptsExtension( ext ) )
return ReadResult::FILE_NOT_HANDLED;
// See if the filename starts with server: and strip it off. This will trick OSG into
// passing in the filename to our plugin instead of using the CURL plugin if the filename
// contains a URL. So, if you want to read a URL, you can use the following format
// osgDB::readNodeFile("server:http://myserver/myearth.earth"). This should only be
// necessary for the first level as the other files will have a tilekey prepended to them.
if ((fileName.length() > 7) && (fileName.substr(0, 7) == "server:"))
return readNode(fileName.substr(7), options);
if ( fileName == "__globe.earth" )
{
return ReadResult( new MapNode() );
}
else if ( fileName == "__cube.earth" )
{
MapOptions options;
options.coordSysType() = MapOptions::CSTYPE_GEOCENTRIC_CUBE;
return ReadResult( new MapNode( new Map(options) ) );
}
else
{
std::string fullFileName = fileName;
if ( !osgDB::containsServerAddress( fileName ) )
{
fullFileName = osgDB::findDataFile( fileName, options );
if (fullFileName.empty()) return ReadResult::FILE_NOT_FOUND;
}
osgEarth::ReadResult r = URI(fullFileName).readString( options );
if ( r.failed() )
return ReadResult::ERROR_IN_READING_FILE;
// Since we're now passing off control to the stream, we have to pass along the
// reference URI as well..
osg::ref_ptr<osgDB::Options> myOptions = Registry::instance()->cloneOrCreateOptions(options);
URIContext( fullFileName ).apply( myOptions.get() );
std::stringstream in( r.getString() );
return readNode( in, myOptions.get() );
}
}
/**
* Makes a simple projected MapNode that contains a basemap of the world
*/
MapNode* makeMiniMapNode( ) {
MapOptions mapOpt;
mapOpt.coordSysType() = MapOptions::CSTYPE_PROJECTED;
mapOpt.profile() = ProfileOptions("plate-carre");
Map* map = new Map( mapOpt );
GDALOptions basemapOpt;
basemapOpt.url() = "../data/world.tif";
map->addImageLayer( new ImageLayer( ImageLayerOptions("basemap", basemapOpt) ) );
// That's it, the map is ready; now create a MapNode to render the Map:
MapNodeOptions mapNodeOptions;
mapNodeOptions.enableLighting() = false;
return new MapNode( map, mapNodeOptions );
}
Map::Impl::Impl(RendererFrontend& frontend_,
MapObserver& observer_,
std::shared_ptr<FileSource> fileSource_,
const MapOptions& mapOptions)
: observer(observer_),
rendererFrontend(frontend_),
transform(observer, mapOptions.constrainMode(), mapOptions.viewportMode()),
mode(mapOptions.mapMode()),
pixelRatio(mapOptions.pixelRatio()),
crossSourceCollisions(mapOptions.crossSourceCollisions()),
fileSource(std::move(fileSource_)),
style(std::make_unique<style::Style>(*fileSource, pixelRatio)),
annotationManager(*style) {
transform.setNorthOrientation(mapOptions.northOrientation());
style->impl->setObserver(this);
rendererFrontend.setObserver(*this);
transform.resize(mapOptions.size());
}
void
SimpleOceanNode::rebuild()
{
this->removeChildren( 0, this->getNumChildren() );
osg::ref_ptr<MapNode> mapNode;
if (_parentMapNode.lock(mapNode))
{
const MapOptions& parentMapOptions = mapNode->getMap()->getMapOptions();
const MapNodeOptions& parentMapNodeOptions = mapNode->getMapNodeOptions();
// set up the map to "match" the parent map:
MapOptions mo;
mo.coordSysType() = parentMapOptions.coordSysType();
mo.profile() = mapNode->getMap()->getProfile()->toProfileOptions();
// new data model for the ocean:
Map* oceanMap = new Map( mo );
// ditto with the map node options:
MapNodeOptions mno;
if ( mno.enableLighting().isSet() )
mno.enableLighting() = *mno.enableLighting();
RexTerrainEngineOptions terrainoptions;
terrainoptions.enableBlending() = true; // gotsta blend with the main node
terrainoptions.color() = baseColor().get();
terrainoptions.tileSize() = 5;
mno.setTerrainOptions( terrainoptions );
// make the ocean's map node:
MapNode* oceanMapNode = new MapNode( oceanMap, mno );
// set up the shaders.
osg::StateSet* ss = this->getOrCreateStateSet();
// if the caller requested a mask layer, install that now.
if ( maskLayer().isSet() )
{
if ( !maskLayer()->maxLevel().isSet() )
{
// set the max subdivision level if it's not already specified in the
// mask layer options:
maskLayer()->maxLevel() = maxLOD().get();
}
// make sure the mask is shared (so we can access it from our shader)
// and invisible (so we can't see it)
maskLayer()->shared() = true;
maskLayer()->visible() = false;
ImageLayer* layer = new ImageLayer("ocean-mask", maskLayer().get());
oceanMap->addLayer( layer );
ss->setDefine("OE_SIMPLE_OCEAN_USE_MASK");
OE_INFO << LC << "Using mask layer \"" << layer->getName() << "\"\n";
}
// otherwise, install a "proxy layer" that will use the elevation data in the map
// to determine where the ocean is. This approach is limited in that it cannot
// detect the difference between ocean and inland areas that are below sea level.
else
{
// install an "elevation proxy" layer that reads elevation tiles from the
// parent map and turns them into encoded images for our shader to use.
ImageLayerOptions epo( "ocean-proxy" );
epo.cachePolicy() = CachePolicy::NO_CACHE;
epo.shared() = true;
epo.visible() = false;
epo.shareTexUniformName() = "oe_ocean_proxyTex";
epo.shareTexMatUniformName() = "oe_ocean_proxyMat";
oceanMap->addLayer( new ElevationProxyImageLayer(mapNode->getMap(), epo) );
OE_INFO << LC << "Using elevation proxy layer\n";
}
this->addChild( oceanMapNode );
// install the shaders on the ocean map node.
VirtualProgram* vp = VirtualProgram::getOrCreate( ss );
vp->setName( "osgEarth SimpleOcean" );
Shaders shaders;
shaders.loadAll(vp, 0L);
// set up the options uniforms.
_seaLevel = new osg::Uniform(osg::Uniform::FLOAT, "ocean_seaLevel");
ss->addUniform( _seaLevel.get() );
_lowFeather = new osg::Uniform(osg::Uniform::FLOAT, "ocean_lowFeather");
ss->addUniform( _lowFeather.get() );
_highFeather = new osg::Uniform(osg::Uniform::FLOAT, "ocean_highFeather");
ss->addUniform( _highFeather.get() );
_baseColor = new osg::Uniform(osg::Uniform::FLOAT_VEC4, "ocean_baseColor");
ss->addUniform( _baseColor.get() );
_maxRange = new osg::Uniform(osg::Uniform::FLOAT, "ocean_max_range");
ss->addUniform( _maxRange.get() );
_fadeRange = new osg::Uniform(osg::Uniform::FLOAT, "ocean_fade_range");
ss->addUniform( _fadeRange.get() );
_alphaUniform = new osg::Uniform(osg::Uniform::FLOAT, "oe_ocean_alpha");
ss->addUniform( _alphaUniform.get() );
// disable depth writes.
ss->setAttributeAndModes( new osg::Depth(osg::Depth::LEQUAL, 0.0, 1.0, false) );
// load up a surface texture
osg::ref_ptr<osg::Image> surfaceImage;
if ( textureURI().isSet() )
{
surfaceImage = textureURI()->getImage();
}
//if ( !surfaceImage.valid() )
//{
// surfaceImage = createSurfaceImage();
//}
if ( surfaceImage.valid() )
{
osg::Texture2D* tex = new osg::Texture2D( surfaceImage.get() );
tex->setFilter( osg::Texture::MIN_FILTER, osg::Texture::LINEAR_MIPMAP_LINEAR );
tex->setFilter( osg::Texture::MAG_FILTER, osg::Texture::LINEAR );
tex->setWrap ( osg::Texture::WRAP_S, osg::Texture::REPEAT );
tex->setWrap ( osg::Texture::WRAP_T, osg::Texture::REPEAT );
ss->setTextureAttributeAndModes( 5, tex, 1 );
ss->getOrCreateUniform( "ocean_surface_tex", osg::Uniform::SAMPLER_2D )->set( 5 );
ss->setDefine("OE_SIMPLE_OCEAN_USE_TEXTURE");
OE_INFO << LC << "Using a surface texture (" << surfaceImage->getFileName() << ")\n";
}
// remove backface culling so we can see underwater
// (use OVERRIDE since the terrain engine sets back face culling.)
ss->setAttributeAndModes(
new osg::CullFace(),
osg::StateAttribute::OFF | osg::StateAttribute::OVERRIDE );
// Material.
osg::Material* m = new osgEarth::MaterialGL3();
m->setAmbient(m->FRONT_AND_BACK, osg::Vec4(.5,.5,.5,1));
m->setDiffuse(m->FRONT_AND_BACK, osg::Vec4(1,1,1,1));
m->setSpecular(m->FRONT_AND_BACK, osg::Vec4(0.2,0.2,0.2,1));
m->setEmission(m->FRONT_AND_BACK, osg::Vec4(0,0,0,1));
m->setShininess(m->FRONT_AND_BACK, 40.0);
ss->setAttributeAndModes(m, osg::StateAttribute::ON | osg::StateAttribute::OVERRIDE );
// force apply options:
applyOptions();
}
}
void
OceanSurfaceContainer::rebuild()
{
this->removeChildren( 0, this->getNumChildren() );
if ( _parentMapNode.valid() )
{
const MapOptions& parentMapOptions = _parentMapNode->getMap()->getMapOptions();
const MapNodeOptions& parentMapNodeOptions = _parentMapNode->getMapNodeOptions();
// set up the map to "match" the parent map:
MapOptions mo;
mo.coordSysType() = parentMapOptions.coordSysType();
mo.profile() = _parentMapNode->getMap()->getProfile()->toProfileOptions();
// new data model for the ocean:
Map* oceanMap = new Map( mo );
// ditto with the map node options:
MapNodeOptions mno;
if ( mno.enableLighting().isSet() )
mno.enableLighting() = *mno.enableLighting();
QuadTreeTerrainEngineOptions to;
to.heightFieldSkirtRatio() = 0.0; // don't want to see skirts
to.clusterCulling() = false; // want to see underwater
to.enableBlending() = true; // gotsta blend with the main node
mno.setTerrainOptions( to );
// make the ocean's map node:
MapNode* oceanMapNode = new MapNode( oceanMap, mno );
// install a custom compositor. Must do this before adding any image layers.
oceanMapNode->setCompositorTechnique( new OceanCompositor() );
// install an "elevation proxy" layer that reads elevation tiles from the
// parent map and turns them into encoded images for our shader to use.
ImageLayerOptions epo( "ocean-proxy" );
epo.cachePolicy() = CachePolicy::NO_CACHE;
epo.maxLevel() = *_options.maxLOD();
oceanMap->addImageLayer( new ElevationProxyImageLayer(_parentMapNode->getMap(), epo) );
this->addChild( oceanMapNode );
// set up the options uniforms.
osg::StateSet* ss = this->getOrCreateStateSet();
_seaLevel = new osg::Uniform(osg::Uniform::FLOAT, "ocean_seaLevel");
ss->addUniform( _seaLevel.get() );
_lowFeather = new osg::Uniform(osg::Uniform::FLOAT, "ocean_lowFeather");
ss->addUniform( _lowFeather.get() );
_highFeather = new osg::Uniform(osg::Uniform::FLOAT, "ocean_highFeather");
ss->addUniform( _highFeather.get() );
_baseColor = new osg::Uniform(osg::Uniform::FLOAT_VEC4, "ocean_baseColor");
ss->addUniform( _baseColor.get() );
// trick to prevent z-fighting..
ss->setAttributeAndModes( new osg::Depth(osg::Depth::LEQUAL, 0.0, 1.0, false) );
ss->setRenderBinDetails( 15, "RenderBin" );
// load up a surface texture
ss->getOrCreateUniform( "ocean_has_tex1", osg::Uniform::BOOL )->set( false );
if ( _options.textureURI().isSet() )
{
//TODO: enable cache support here:
osg::Image* image = _options.textureURI()->getImage();
if ( image )
{
osg::Texture2D* tex = new osg::Texture2D( image );
tex->setFilter( osg::Texture::MIN_FILTER, osg::Texture::LINEAR_MIPMAP_LINEAR );
tex->setFilter( osg::Texture::MAG_FILTER, osg::Texture::LINEAR );
tex->setWrap ( osg::Texture::WRAP_S, osg::Texture::REPEAT );
tex->setWrap ( osg::Texture::WRAP_T, osg::Texture::REPEAT );
ss->setTextureAttributeAndModes( 1, tex, 1 );
ss->getOrCreateUniform( "ocean_tex1", osg::Uniform::SAMPLER_2D )->set( 1 );
ss->getOrCreateUniform( "ocean_has_tex1", osg::Uniform::BOOL )->set( true );
}
}
// remove backface culling so we can see underwater
// (use OVERRIDE since the terrain engine sets back face culling.)
ss->setAttributeAndModes( new osg::CullFace(), osg::StateAttribute::OFF | osg::StateAttribute::OVERRIDE );
apply( _options );
}
}
void GlobePlugin::setupMap()
{
QSettings settings;
QString cacheDirectory = settings.value( "cache/directory", QgsApplication::qgisSettingsDirPath() + "cache" ).toString();
TMSCacheOptions cacheOptions;
cacheOptions.setPath( cacheDirectory.toStdString() );
MapOptions mapOptions;
mapOptions.cache() = cacheOptions;
osgEarth::Map *map = new osgEarth::Map( mapOptions );
//Default image layer
GDALOptions driverOptions;
driverOptions.url() = QDir::cleanPath( QgsApplication::pkgDataPath() + "/globe/world.tif" ).toStdString();
ImageLayerOptions layerOptions( "world", driverOptions );
layerOptions.cacheEnabled() = false;
map->addImageLayer( new osgEarth::ImageLayer( layerOptions ) );
MapNodeOptions nodeOptions;
//nodeOptions.proxySettings() =
//nodeOptions.enableLighting() = false;
//LoadingPolicy loadingPolicy( LoadingPolicy::MODE_SEQUENTIAL );
TerrainOptions terrainOptions;
//terrainOptions.loadingPolicy() = loadingPolicy;
terrainOptions.compositingTechnique() = TerrainOptions::COMPOSITING_MULTITEXTURE_FFP;
nodeOptions.setTerrainOptions( terrainOptions );
// The MapNode will render the Map object in the scene graph.
mMapNode = new osgEarth::MapNode( map, nodeOptions );
//prefill cache
if ( !QFile::exists( cacheDirectory + "/worldwind_srtm" ) )
{
copyFolder( QgsApplication::pkgDataPath() + "/globe/data/worldwind_srtm", cacheDirectory + "/globe/worldwind_srtm" );
}
mRootNode = new osg::Group();
mRootNode->addChild( mMapNode );
// Add layers to the map
layersChanged();
// model placement utils
mElevationManager = new osgEarth::Util::ElevationManager( mMapNode->getMap() );
mElevationManager->setTechnique( osgEarth::Util::ElevationManager::TECHNIQUE_GEOMETRIC );
mElevationManager->setMaxTilesToCache( 50 );
mObjectPlacer = new osgEarth::Util::ObjectPlacer( mMapNode );
// place 3D model on point layer
if ( mSettingsDialog.modelLayer() && !mSettingsDialog.modelPath().isEmpty() )
{
osg::Node* model = osgDB::readNodeFile( mSettingsDialog.modelPath().toStdString() );
if ( model )
{
QgsVectorLayer* layer = mSettingsDialog.modelLayer();
QgsAttributeList fetchAttributes;
layer->select( fetchAttributes ); //TODO: select only visible features
QgsFeature feature;
while ( layer->nextFeature( feature ) )
{
QgsPoint point = feature.geometry()->asPoint();
placeNode( model, point.y(), point.x() );
}
}
}
}
void
SimpleOceanNode::rebuild()
{
this->removeChildren( 0, this->getNumChildren() );
if ( _parentMapNode.valid() )
{
const MapOptions& parentMapOptions = _parentMapNode->getMap()->getMapOptions();
const MapNodeOptions& parentMapNodeOptions = _parentMapNode->getMapNodeOptions();
// set up the map to "match" the parent map:
MapOptions mo;
mo.coordSysType() = parentMapOptions.coordSysType();
mo.profile() = _parentMapNode->getMap()->getProfile()->toProfileOptions();
// new data model for the ocean:
Map* oceanMap = new Map( mo );
// ditto with the map node options:
MapNodeOptions mno;
if ( mno.enableLighting().isSet() )
mno.enableLighting() = *mno.enableLighting();
MPTerrainEngineOptions mpoptions;
mpoptions.heightFieldSkirtRatio() = 0.0; // don't want to see skirts
mpoptions.minLOD() = _options.maxLOD().get(); // weird, I know
// so we can the surface from underwater:
mpoptions.clusterCulling() = false; // want to see underwater
mpoptions.enableBlending() = true; // gotsta blend with the main node
mpoptions.color() = _options.baseColor().get();
mno.setTerrainOptions( mpoptions );
// make the ocean's map node:
MapNode* oceanMapNode = new MapNode( oceanMap, mno );
// if the caller requested a mask layer, install that now.
if ( _options.maskLayer().isSet() )
{
if ( !_options.maskLayer()->maxLevel().isSet() )
{
// set the max subdivision level if it's not already specified in the
// mask layer options:
_options.maskLayer()->maxLevel() = *_options.maxLOD();
}
// make sure the mask is shared (so we can access it from our shader)
// and invisible (so we can't see it)
_options.maskLayer()->shared() = true;
_options.maskLayer()->visible() = false;
ImageLayer* maskLayer = new ImageLayer( "ocean-mask", *_options.maskLayer() );
oceanMap->addImageLayer( maskLayer );
}
// otherwise, install a "proxy layer" that will use the elevation data in the map
// to determine where the ocean is. This approach is limited in that it cannot
// detect the difference between ocean and inland areas that are below sea level.
else
{
// install an "elevation proxy" layer that reads elevation tiles from the
// parent map and turns them into encoded images for our shader to use.
ImageLayerOptions epo( "ocean-proxy" );
epo.cachePolicy() = CachePolicy::NO_CACHE;
//epo.maxLevel() = *_options.maxLOD();
oceanMap->addImageLayer( new ElevationProxyImageLayer(_parentMapNode->getMap(), epo) );
}
this->addChild( oceanMapNode );
// set up the shaders.
osg::StateSet* ss = this->getOrCreateStateSet();
// install the shaders on the ocean map node.
VirtualProgram* vp = VirtualProgram::getOrCreate( ss );
vp->setName( "osgEarth SimpleOcean" );
// use the appropriate shader for the active technique:
std::string vertSource = _options.maskLayer().isSet() ? source_vertMask : source_vertProxy;
std::string fragSource = _options.maskLayer().isSet() ? source_fragMask : source_fragProxy;
vp->setFunction( "oe_ocean_vertex", vertSource, ShaderComp::LOCATION_VERTEX_VIEW );
vp->setFunction( "oe_ocean_fragment", fragSource, ShaderComp::LOCATION_FRAGMENT_COLORING, 0.6f );
// install the slot attribute(s)
ss->getOrCreateUniform( "ocean_data", osg::Uniform::SAMPLER_2D )->set( 0 );
// set up the options uniforms.
_seaLevel = new osg::Uniform(osg::Uniform::FLOAT, "ocean_seaLevel");
ss->addUniform( _seaLevel.get() );
_lowFeather = new osg::Uniform(osg::Uniform::FLOAT, "ocean_lowFeather");
ss->addUniform( _lowFeather.get() );
_highFeather = new osg::Uniform(osg::Uniform::FLOAT, "ocean_highFeather");
ss->addUniform( _highFeather.get() );
_baseColor = new osg::Uniform(osg::Uniform::FLOAT_VEC4, "ocean_baseColor");
ss->addUniform( _baseColor.get() );
_maxRange = new osg::Uniform(osg::Uniform::FLOAT, "ocean_max_range");
ss->addUniform( _maxRange.get() );
_fadeRange = new osg::Uniform(osg::Uniform::FLOAT, "ocean_fade_range");
ss->addUniform( _fadeRange.get() );
// trick to mitigate z-fighting..
ss->setAttributeAndModes( new osg::Depth(osg::Depth::LEQUAL, 0.0, 1.0, false) );
ss->setRenderingHint( osg::StateSet::TRANSPARENT_BIN );
// load up a surface texture
osg::ref_ptr<osg::Image> surfaceImage;
ss->getOrCreateUniform( "ocean_has_surface_tex", osg::Uniform::BOOL )->set( false );
if ( _options.textureURI().isSet() )
{
//TODO: enable cache support here?
surfaceImage = _options.textureURI()->getImage();
}
if ( !surfaceImage.valid() )
{
surfaceImage = createSurfaceImage();
}
if ( surfaceImage.valid() )
{
osg::Texture2D* tex = new osg::Texture2D( surfaceImage.get() );
tex->setFilter( osg::Texture::MIN_FILTER, osg::Texture::LINEAR_MIPMAP_LINEAR );
tex->setFilter( osg::Texture::MAG_FILTER, osg::Texture::LINEAR );
tex->setWrap ( osg::Texture::WRAP_S, osg::Texture::REPEAT );
tex->setWrap ( osg::Texture::WRAP_T, osg::Texture::REPEAT );
ss->setTextureAttributeAndModes( 2, tex, 1 );
ss->getOrCreateUniform( "ocean_surface_tex", osg::Uniform::SAMPLER_2D )->set( 2 );
ss->getOrCreateUniform( "ocean_has_surface_tex", osg::Uniform::BOOL )->set( true );
}
// remove backface culling so we can see underwater
// (use OVERRIDE since the terrain engine sets back face culling.)
ss->setAttributeAndModes(
new osg::CullFace(),
osg::StateAttribute::OFF | osg::StateAttribute::OVERRIDE );
// Material.
osg::Material* m = new osg::Material();
m->setAmbient(m->FRONT_AND_BACK, osg::Vec4(0,0,0,1));
m->setDiffuse(m->FRONT_AND_BACK, osg::Vec4(1,1,1,1));
m->setSpecular(m->FRONT_AND_BACK, osg::Vec4(0.1,0.1,0.1,1));
m->setEmission(m->FRONT_AND_BACK, osg::Vec4(0,0,0,1));
m->setShininess(m->FRONT_AND_BACK, 32.0);
ss->setAttributeAndModes(m, osg::StateAttribute::ON | osg::StateAttribute::OVERRIDE );
// force apply options:
applyOptions();
}
}
void GlobePlugin::setupMap()
{
QSettings settings;
QString cacheDirectory = settings.value( "cache/directory", QgsApplication::qgisSettingsDirPath() + "cache" ).toString();
#if OSGEARTH_VERSION_GREATER_OR_EQUAL( 2, 2, 0 )
FileSystemCacheOptions cacheOptions;
cacheOptions.rootPath() = cacheDirectory.toStdString();
#else
TMSCacheOptions cacheOptions;
cacheOptions.setPath( cacheDirectory.toStdString() );
#endif
MapOptions mapOptions;
mapOptions.cache() = cacheOptions;
osgEarth::Map *map = new osgEarth::Map( mapOptions );
//Default image layer
/*
GDALOptions driverOptions;
driverOptions.url() = QDir::cleanPath( QgsApplication::pkgDataPath() + "/globe/world.tif" ).toStdString();
ImageLayerOptions layerOptions( "world", driverOptions );
map->addImageLayer( new osgEarth::ImageLayer( layerOptions ) );
*/
MapNodeOptions nodeOptions;
//nodeOptions.proxySettings() =
//nodeOptions.enableLighting() = false;
//LoadingPolicy loadingPolicy( LoadingPolicy::MODE_SEQUENTIAL );
TerrainOptions terrainOptions;
//terrainOptions.loadingPolicy() = loadingPolicy;
terrainOptions.compositingTechnique() = TerrainOptions::COMPOSITING_MULTITEXTURE_FFP;
//terrainOptions.lodFallOff() = 6.0;
nodeOptions.setTerrainOptions( terrainOptions );
// The MapNode will render the Map object in the scene graph.
mMapNode = new osgEarth::MapNode( map, nodeOptions );
if ( settings.value( "/Plugin-Globe/baseLayerEnabled", true ).toBool() )
{
setBaseMap( settings.value( "/Plugin-Globe/baseLayerURL", "http://readymap.org/readymap/tiles/1.0.0/7/" ).toString() );
}
mRootNode = new osg::Group();
mRootNode->addChild( mMapNode );
// Add layers to the map
imageLayersChanged();
elevationLayersChanged();
// model placement utils
#ifdef HAVE_OSGEARTH_ELEVATION_QUERY
#else
mElevationManager = new osgEarth::Util::ElevationManager( mMapNode->getMap() );
mElevationManager->setTechnique( osgEarth::Util::ElevationManager::TECHNIQUE_GEOMETRIC );
mElevationManager->setMaxTilesToCache( 50 );
mObjectPlacer = new osgEarth::Util::ObjectPlacer( mMapNode );
// place 3D model on point layer
if ( mSettingsDialog->modelLayer() && !mSettingsDialog->modelPath().isEmpty() )
{
osg::Node* model = osgDB::readNodeFile( mSettingsDialog->modelPath().toStdString() );
if ( model )
{
QgsVectorLayer* layer = mSettingsDialog->modelLayer();
QgsFeatureIterator fit = layer->getFeatures( QgsFeatureRequest().setSubsetOfAttributes( QgsAttributeList() ) ); //TODO: select only visible features
QgsFeature feature;
while ( fit.nextFeature( feature ) )
{
QgsPoint point = feature.geometry()->asPoint();
placeNode( model, point.y(), point.x() );
}
}
}
#endif
}
