/** @param file */
 public void export(File file) {
   LOG.debug("Writing index file for directory...");
   ObjectOutputStream out = null;
   try {
     out = new ObjectOutputStream(new BufferedOutputStream(new FileOutputStream(file)));
     out.writeObject(qtree);
     out.writeObject(createEnvelope(envelope));
     out.writeObject(rasterDataInfo);
     out.writeObject(rasterGeoReference.getOriginLocation());
     out.writeDouble(rasterGeoReference.getResolutionX());
     out.writeDouble(rasterGeoReference.getResolutionY());
     out.writeDouble(rasterGeoReference.getRotationX());
     out.writeDouble(rasterGeoReference.getRotationY());
     out.writeDouble(rasterGeoReference.getOriginEasting());
     out.writeDouble(rasterGeoReference.getOriginNorthing());
     out.writeObject(rasterGeoReference.getCrs());
     out.writeObject(resolutionInfo);
     out.writeObject(options);
     LOG.debug("Done.");
   } catch (IOException e) {
     LOG.debug(
         "Raster pyramid file '{}' could not be written: '{}'.", file, e.getLocalizedMessage());
     LOG.trace("Stack trace:", e);
   } finally {
     if (out != null) {
       try {
         out.close();
       } catch (IOException e) {
         LOG.debug(
             "Raster pyramid file '{}' could not be closed: '{}'.", file, e.getLocalizedMessage());
         LOG.trace("Stack trace:", e);
       }
     }
   }
 }
Example #2
0
 /**
  * Creates a new empty SimpleRaster with same DataType and InterleaveType. Size is determined by
  * the given envelope.
  *
  * @param rEnv The raster envelope of the new SimpleRaster.
  * @param env The boundary of the new SimpleRaster.
  * @return A new empty SimpleRaster.
  */
 public SimpleRaster createCompatibleSimpleRaster(RasterGeoReference rEnv, Envelope env) {
   int[] size = rEnv.getSize(env);
   RasterRect rasterRect = new RasterRect(0, 0, size[0], size[1]);
   RasterData data = this.getRasterData();
   BandType[] bands = data.getDataInfo().bandInfo;
   RasterData newRaster = data.createCompatibleWritableRasterData(rasterRect, bands);
   return new SimpleRaster(newRaster, env, rEnv, metadata);
 }
Example #3
0
  private WarpPolynomial createWarp(
      int dstWidth,
      int dstHeight,
      ICRS srcCRS,
      RasterGeoReference srcREnv,
      RasterGeoReference dstREnv)
      throws TransformationException {
    int k = 0;
    // create/calculate reference points
    float dx = (dstWidth - 1) / (float) (refPointsGridSize - 1);
    float dy = (dstHeight - 1) / (float) (refPointsGridSize - 1);
    float[] srcCoords = new float[refPointsGridSize * refPointsGridSize * 2];
    float[] dstCoords = new float[refPointsGridSize * refPointsGridSize * 2];
    List<Point3d> points = new ArrayList<Point3d>(refPointsGridSize * refPointsGridSize);
    for (int j = 0; j < refPointsGridSize; j++) {
      for (int i = 0; i < refPointsGridSize; i++) {
        dstCoords[k] = i * dx;
        dstCoords[k + 1] = j * dy;
        double[] dstWCoords =
            dstREnv.getWorldCoordinate((int) dstCoords[k], (int) dstCoords[k + 1]);
        points.add(new Point3d(dstWCoords[0], dstWCoords[1], Double.NaN));
        k += 2;
      }
    }
    List<Point3d> resultList = transformDstToSrc(srcCRS, points);

    k = 0;
    for (Point3d point : resultList) {
      double[] srcRCoords = srcREnv.getRasterCoordinateUnrounded(point.x, point.y);
      srcCoords[k] = (float) srcRCoords[0];
      srcCoords[k + 1] = (float) srcRCoords[1];
      k += 2;
    }

    // create a best fit polynomial for out grid
    WarpPolynomial warp =
        WarpPolynomial.createWarp(
            srcCoords, 0, dstCoords, 0, srcCoords.length, 1f, 1f, 1f, 1f, polynomialOrder);
    return warp;
  }
Example #4
0
  /**
   * Creates a transformed raster from a given source raster.
   *
   * <p>This method transforms the requested envelope and returns a new raster with the requested
   * size. The source raster can be larger than the requested envelope (like a large tiled raster),
   * or smaller (the source raster nodata value will be used outside the source raster).
   *
   * <p>If the dstEnvelope does not contain a CRS or the CRS is the same as the {@link
   * AbstractRaster#getCoordinateSystem()} only interpolation will be applied. If the requested size
   * is the same as the number of rows/columns of the source raster, only the subset of the given
   * raster will be returned, without interpolation being applied.
   *
   * @param sourceRaster the source raster
   * @param dstEnvelope the requested envelope (already in the target crs)
   * @param dstWidth the requested raster size
   * @param dstHeight the requested raster size
   * @param interpolationType the type of the interpolation
   * @return the transformed raster
   * @throws TransformationException
   */
  public AbstractRaster transform(
      AbstractRaster sourceRaster,
      Envelope dstEnvelope,
      int dstWidth,
      int dstHeight,
      InterpolationType interpolationType)
      throws TransformationException {

    synchronized (sourceRaster) {
      ICRS srcCRS = sourceRaster.getCoordinateSystem();

      // get the (transformed) subraster which intersects with the given envelope.
      AbstractRaster source = getSubRaster(srcCRS, sourceRaster, dstEnvelope);
      if (source.getColumns() == dstHeight && source.getRows() == dstWidth) {
        // no need to interpolate.
        return source;
      }
      SimpleRaster simpleSourceRaster = source.getAsSimpleRaster();
      RasterData srcData = simpleSourceRaster.getReadOnlyRasterData();
      RasterGeoReference srcREnv = simpleSourceRaster.getRasterReference();

      if (backgroundValue != null) {
        srcData.setNoDataValue(backgroundValue);
      }

      // interpolation is needed.
      Interpolation interpolation =
          InterpolationFactory.getInterpolation(interpolationType, srcData);

      RasterRect rr = new RasterRect(0, 0, dstWidth, dstHeight);
      RasterData dstData = srcData.createCompatibleWritableRasterData(rr, null);
      RasterGeoReference dstREnv =
          RasterGeoReference.create(
              sourceRaster.getRasterReference().getOriginLocation(),
              dstEnvelope,
              dstWidth,
              dstHeight);

      // use warp to calculate the correct sample positions in the source raster.
      // the warp is a cubic polynomial function created of 100 points in the dstEnvelope. This
      // function will map
      // points from the source crs to the target crs very accurate.
      WarpPolynomial warp = createWarp(dstWidth, dstHeight, srcCRS, srcREnv, dstREnv);
      warpTransform(warp, interpolation, dstData);

      return new SimpleRaster(dstData, dstEnvelope, dstREnv, null);
    }
  }
  /** @param file */
  public DiskBasedTileContainer(File file) {
    ObjectInputStream in = null;
    LOG.debug("Reading index file for directory...");
    try {
      in = new ObjectInputStream(new BufferedInputStream(new FileInputStream(file)));
      qtree = (QTree<File>) in.readObject();
      envelope = createEnvelope((float[]) in.readObject(), null);
      rasterDataInfo = (RasterDataInfo) in.readObject();

      rasterGeoReference =
          new RasterGeoReference(
              (OriginLocation) in.readObject(),
              in.readDouble(),
              in.readDouble(),
              in.readDouble(),
              in.readDouble(),
              in.readDouble(),
              in.readDouble(),
              (CRS) in.readObject());

      envelope.setCoordinateSystem(rasterGeoReference.getCrs());
      resolutionInfo = (ResolutionInfo) in.readObject();
      options = (RasterIOOptions) in.readObject();
      initialized = true;
      LOG.debug("Done.");
    } catch (FileNotFoundException e) {
      LOG.debug("Raster pyramid file '{}' could not be found.", file);
      LOG.trace("Stack trace:", e);
    } catch (IOException e) {
      LOG.debug("Raster pyramid file '{}' could not be read: '{}'", file, e.getLocalizedMessage());
      LOG.trace("Stack trace:", e);
    } catch (ClassNotFoundException e) {
      LOG.debug("Raster pyramid file '{}' was in the wrong format.", file);
      LOG.trace("Stack trace:", e);
    } finally {
      if (in != null) {
        try {
          in.close();
        } catch (IOException e) {
          LOG.debug(
              "Raster pyramid file '{}' could not be closed: '{}'.", file, e.getLocalizedMessage());
          LOG.trace("Stack trace:", e);
        }
      }
    }
  }
Example #6
0
  /**
   * Merge two Raster references. Returns a new RasterReference where the upper-left corner is set
   * to the values of the smallest upper and smallest left ordinate. The resolution is set to the
   * minimum value (i.e. the highest resolution [unit/pixel]). Some assumptions are made (not
   * checked):
   *
   * <ul>
   *   <li>The pixel location (center/outer) of the origin are equal, if not, the location of the
   *       first reference will be used (translated origin of second)
   *   <li>Crs is identical
   *   <li>rotation around axis are equal
   * </ul>
   *
   * @param geoRef1
   * @param geoRef2
   * @return new RasterReference
   */
  public static RasterGeoReference merger(RasterGeoReference geoRef1, RasterGeoReference geoRef2) {

    if (geoRef1 == null) {
      return geoRef2;
    }
    if (geoRef2 == null) {
      return geoRef1;
    }
    RasterGeoReference geoRef2Copy = geoRef2;
    if (geoRef1.location != geoRef2.location) {
      double[] orig = geoRef2.getOrigin(geoRef1.location);
      geoRef2Copy =
          new RasterGeoReference(
              geoRef1.location,
              geoRef2.getResolutionX(),
              geoRef2.getResolutionY(),
              geoRef2.getRotationX(),
              geoRef2.getRotationY(),
              orig[0],
              orig[1],
              geoRef2.crs);
    }
    double[] origin1 = geoRef1.getOrigin();
    double[] origin2 = geoRef2Copy.getOrigin();

    double res1x = geoRef1.getResolutionX();
    double res1y = geoRef1.getResolutionY();

    double res2x = geoRef2Copy.getResolutionX();
    double res2y = geoRef2Copy.getResolutionY();

    double nResx = (res1x < 0) ? max(res1x, res2x) : min(res1x, res2x);
    double nResy = (res1y < 0) ? max(res1y, res2y) : min(res1y, res2y);

    double nOrigx = (res1x < 0) ? max(origin1[0], origin2[0]) : min(origin1[0], origin2[0]);
    double nOrigy = (res1y < 0) ? max(origin1[1], origin2[1]) : min(origin1[1], origin2[1]);

    return new RasterGeoReference(
        geoRef1.location,
        nResx,
        nResy,
        geoRef1.getRotationX(),
        geoRef1.getRotationY(),
        nOrigx,
        nOrigy,
        geoRef1.crs);
  }