int
purge( osg::ArgumentParser& args )
{
    osg::ref_ptr<osg::Node> node = osgDB::readNodeFiles( args );
    if ( !node.valid() )
        return usage( "Failed to read .earth file." );

    MapNode* mapNode = MapNode::findMapNode( node.get() );
    if ( !mapNode )
        return usage( "Input file was not a .earth file" );

    Map* map = mapNode->getMap();

    if ( !map->getCache() )
        return message( "Earth file does not contain a cache." );

    std::vector<Entry> entries;


    ImageLayerVector imageLayers;
    map->getLayers( imageLayers );
    for( ImageLayerVector::const_iterator i = imageLayers.begin(); i != imageLayers.end(); ++i )
    {
        ImageLayer* layer = i->get();

        bool useMFP =
            layer->getProfile() &&
            layer->getProfile()->getSRS()->isSphericalMercator() &&
            mapNode->getMapNodeOptions().getTerrainOptions().enableMercatorFastPath() == true;

        const Profile* cacheProfile = useMFP ? layer->getProfile() : map->getProfile();

        CacheSettings* cacheSettings = layer->getCacheSettings();
        if (cacheSettings)
        {
            CacheBin* bin = cacheSettings->getCacheBin();
            if ( bin )
            {
                entries.push_back(Entry());
                entries.back()._isImage = true;
                entries.back()._name = i->get()->getName();
                entries.back()._bin = bin;
            }
        }
    }

    ElevationLayerVector elevationLayers;
    map->getLayers( elevationLayers );
    for( ElevationLayerVector::const_iterator i = elevationLayers.begin(); i != elevationLayers.end(); ++i )
    {
        ElevationLayer* layer = i->get();

        bool useMFP =
            layer->getProfile() &&
            layer->getProfile()->getSRS()->isSphericalMercator() &&
            mapNode->getMapNodeOptions().getTerrainOptions().enableMercatorFastPath() == true;

        const Profile* cacheProfile = useMFP ? layer->getProfile() : map->getProfile();
        
        CacheSettings* cacheSettings = layer->getCacheSettings();
        if (cacheSettings)
        {
            CacheBin* bin = cacheSettings->getCacheBin();
            if (bin)
            {
                entries.push_back(Entry());
                entries.back()._isImage = false;
                entries.back()._name = i->get()->getName();
                entries.back()._bin = bin;
            }
        }
    }

    if ( entries.size() > 0 )
    {
        std::cout << std::endl;

        for( unsigned i=0; i<entries.size(); ++i )
        {
            std::cout << (i+1) << ") " << entries[i]._name << " (" << (entries[i]._isImage? "image" : "elevation" ) << ")" << std::endl;
        }

        std::cout 
            << std::endl
            << "Enter number of cache to purge, or <enter> to quit: "
            << std::flush;

        std::string input;
        std::getline( std::cin, input );

        if ( !input.empty() )
        {
            unsigned k = as<unsigned>(input, 0L);
            if ( k > 0 && k <= entries.size() )
            {
                Config meta = entries[k-1]._bin->readMetadata();
                if ( !meta.empty() )
                {
                    std::cout
                        << std::endl
                        << "Cache METADATA:" << std::endl
                        << meta.toJSON() 
                        << std::endl << std::endl;
                }

                std::cout
                    << "Are you sure (y/N)? "
                    << std::flush;

                std::getline( std::cin, input );
                if ( input == "y" || input == "Y" )
                {
                    std::cout << "Purging.." << std::flush;
                    entries[k-1]._bin->clear();
                }
                else
                {
                    std::cout << "No action taken." << std::endl;
                }
            }
            else
            {
                std::cout << "Invalid choice." << std::endl;
            }
        }
        else
        {
            std::cout << "No action taken." << std::endl;
        }
    }

    return 0;
}
示例#2
0
/**
 * Command-line tool that copies the contents of one TileSource
 * to another. All arguments are Config name/value pairs, so you need
 * to look in the header file for each driver's Options structure for
 * options :)
 *
 * Example: copy a GDAL file to an MBTiles repo:
 *
 *   osgearth_conv
 *      --in driver gdal
 *      --in url world.tif
 *      --out driver mbtiles
 *      --out filename world.db
 *
 * The "in" properties come from the GDALOptions getConfig method. The
 * "out" properties come from the MBTilesOptions getConfig method.
 *
 * Other arguments:
 *
 *      --elevation           : convert as elevation data (instead of image data)
 *      --profile [profile]   : reproject to the target profile, e.g. "wgs84"
 *      --min-level [int]     : min level of detail to copy
 *      --max-level [int]     : max level of detail to copy
 *      --threads [n]         : threads to use (may crash. Careful.)
 *
 *      --extents [minLat] [minLong] [maxLat] [maxLong] : Lat/Long extends to copy (*)
 *
 * Of course, the output driver must support writing (by implementing
 * the ReadWriteTileSource interface).
 */
int
main(int argc, char** argv)
{
    osg::ArgumentParser args(&argc,argv);

    if ( argc == 1 )
        return usage(argv);

    typedef std::map<std::string,std::string> KeyValue;
    std::string key, value;

    // collect input configuration:
    Config inConf;
    while( args.read("--in", key, value) )
        inConf.set(key, value);

    TileSourceOptions inOptions(inConf);
    osg::ref_ptr<TileSource> input = TileSourceFactory::create(inOptions);
    if ( !input.valid() )
    {
        OE_WARN << LC << "Failed to open input" << std::endl;
        return -1;
    }

    TileSource::Status inputStatus = input->open();
    if ( inputStatus.isError() )
    {
        OE_WARN << LC << "Error initializing input" << std::endl;
        return -1;
    }

    // collect output configuration:
    Config outConf;
    while( args.read("--out", key, value) )
        outConf.set(key, value);

    // heightfields?
    bool heightFields = args.read("--heightfield") || args.read("--hf") || args.read("--elevation");
    if ( heightFields )
        OE_INFO << LC << "Converting heightfield tiles" << std::endl;
    else
        OE_INFO << LC << "Converting image tiles" << std::endl;

    // are we changing profiles?
    osg::ref_ptr<const Profile> outputProfile = input->getProfile();
    std::string profileString;
    bool isSameProfile = true;

    if ( args.read("--profile", profileString) )
    {
        outputProfile = Profile::create(profileString);
        if ( !outputProfile.valid() || !outputProfile->isOK() )
        {
            OE_WARN << LC << "Output profile is not recognized" << std::endl;
            return -1;
        }
        isSameProfile = outputProfile->isHorizEquivalentTo(input->getProfile());
    }

    // set the output profile.
    ProfileOptions profileOptions = outputProfile->toProfileOptions();
    outConf.add("profile", profileOptions.getConfig());

    // open the output tile source:
    TileSourceOptions outOptions(outConf);
    osg::ref_ptr<TileSource> output = TileSourceFactory::create(outOptions);
    if ( !output.valid() )
    {
        OE_WARN << LC << "Failed to open output" << std::endl;
        return -1;
    }

    TileSource::Status outputStatus = output->open(TileSource::MODE_WRITE | TileSource::MODE_CREATE);
    if ( outputStatus.isError() )
    {
        OE_WARN << LC << "Error initializing output" << std::endl;
        return -1;
    }

    // Dump out some stuff...
    OE_NOTICE << LC << "FROM:\n"
        << inConf.toJSON(true)
        << std::endl;

    OE_NOTICE << LC << "TO:\n"
        << outConf.toJSON(true)
        << std::endl;

    // create the visitor.
    osg::ref_ptr<TileVisitor> visitor;

    unsigned numThreads = 1;
    if (args.read("--threads", numThreads))
    {
        MultithreadedTileVisitor* mtv = new MultithreadedTileVisitor();
        mtv->setNumThreads( numThreads < 1 ? 1 : numThreads );
        visitor = mtv;
    }
    else
    {
        visitor = new TileVisitor();
    }

    // If the profiles are identical, just use a tile copier.
    if ( isSameProfile )
    {
        OE_NOTICE << LC << "Profiles match - initiating simple tile copy" << std::endl;
        visitor->setTileHandler( new TileSourceToTileSource(input.get(), output.get(), heightFields) );
    }
    else
    {
        OE_NOTICE << LC << "Profiles differ - initiating tile transformation" << std::endl;

        if (heightFields)
        {
            ElevationLayer* layer = new ElevationLayer(ElevationLayerOptions(), input.get());
            if ( !layer->getProfile() || !layer->getProfile()->isOK() )
            {
                OE_WARN << LC << "Input profile is not valid" << std::endl;
                return -1;
            }
            visitor->setTileHandler( new ElevationLayerToTileSource(layer, output.get()) );
        }
        else
        {
            ImageLayer* layer = new ImageLayer(ImageLayerOptions(), input.get());
            if ( !layer->getProfile() || !layer->getProfile()->isOK() )
            {
                OE_WARN << LC << "Input profile is not valid" << std::endl;
                return -1;
            }
            visitor->setTileHandler( new ImageLayerToTileSource(layer, output.get()) );
        }
    }
    
    // Set the level limits:
    unsigned minLevel = ~0;
    bool minLevelSet = args.read("--min-level", minLevel);

    unsigned maxLevel = 0;
    bool maxLevelSet = args.read("--max-level", maxLevel);

    // figure out the max source level:
    if ( !minLevelSet || !maxLevelSet )
    {
        for(DataExtentList::const_iterator i = input->getDataExtents().begin();
            i != input->getDataExtents().end();
            ++i)
        {
            if ( !maxLevelSet && i->maxLevel().isSet() && i->maxLevel().value() > maxLevel )
                maxLevel = i->maxLevel().value();
            if ( !minLevelSet && i->minLevel().isSet() && i->minLevel().value() < minLevel )
                minLevel = i->minLevel().value();
        }
    }
       
    if ( minLevel < ~0 )
    {
        visitor->setMinLevel( minLevel );
    }

    if ( maxLevel > 0 )
    {
        maxLevel = outputProfile->getEquivalentLOD( input->getProfile(), maxLevel );
        visitor->setMaxLevel( maxLevel );
        OE_NOTICE << LC << "Calculated max level = " << maxLevel << std::endl;
    }

    // set the extents:
    double minlat, minlon, maxlat, maxlon;
    while( args.read("--extents", minlat, minlon, maxlat, maxlon) )
    {
        GeoExtent extent(SpatialReference::get("wgs84"), minlon, minlat, maxlon, maxlat);
        visitor->addExtent( extent );
    }

    // Ready!!!
    std::cout << "Working..." << std::endl;

    visitor->setProgressCallback( new ProgressReporter() );

    osg::Timer_t t0 = osg::Timer::instance()->tick();

    visitor->run( outputProfile.get() );

    osg::Timer_t t1 = osg::Timer::instance()->tick();

    std::cout
        << "Time = " 
        << std::fixed
        << std::setprecision(1)
        << osg::Timer::instance()->delta_s(t0, t1)
        << " seconds." << std::endl;

    return 0;
}
示例#3
0
文件: Map.cpp 项目: korash/osgearth
bool
MapFrame::isCached( const osgEarth::TileKey& key ) const
{
    const Profile* mapProfile = getProfile();

    //Check the imagery layers
    for( ImageLayerVector::const_iterator i = imageLayers().begin(); i != imageLayers().end(); i++ )
    {
        ImageLayer* layer = i->get();
        osg::ref_ptr< Cache > cache = layer->getCache();

        if ( !cache.valid() || !layer->getProfile() ) 
            return false;

        std::vector< TileKey > keys;

        if ( mapProfile->isEquivalentTo( layer->getProfile() ) )
        {
            keys.push_back( key );
        }
        else
        {
            layer->getProfile()->getIntersectingTiles( key, keys );
        }

        for (unsigned int j = 0; j < keys.size(); ++j)
        {
            if ( layer->isKeyValid( keys[j] ) )
            {
                if ( !cache->isCached( keys[j], layer->getCacheSpec() ) )
                {
                    return false;
                }
            }
        }
    }

    for( ElevationLayerVector::const_iterator i = elevationLayers().begin(); i != elevationLayers().end(); ++i )
    {
        ElevationLayer* layer = i->get();
        osg::ref_ptr< Cache > cache = layer->getCache();

        if ( !cache.valid() || !layer->getProfile() )
            return false;

        std::vector<TileKey> keys;

        if ( mapProfile->isEquivalentTo( layer->getProfile() ) )
        {
            keys.push_back( key );
        }
        else
        {
            layer->getProfile()->getIntersectingTiles( key, keys );
        }

        for (unsigned int j = 0; j < keys.size(); ++j)
        {
            if ( layer->isKeyValid( keys[j] ) )
            {
                if ( !cache->isCached( keys[j], layer->getCacheSpec() ) )
                {
                    return false;
                }
            }
        }
    }
    return true;
}