Python remove_file Beispiele

Beispiel #1

def build_pixel_points(etrf_array,
                       etrf_geo,
                       cal_dict,
                       shapefile_flag=False,
                       pixels_ws=None,
                       mc_iter=None):
    """Build new suggested hot/cold pixels

    Parameters
    ----------
    etrf_array :
        The ETrF array (assuming non-ag pixels were masked).
    cal_dict : dict
        Calibration parameters.
    shapefile_flag : bool
        If True, save calibration points to shapefile (the default is False)
    pixels_ws : str

    Returns
    -------

    """
    logging.info('Building new hot/cold calibration points')

    # Suggested pixel points
    cold_pixel_path = os.path.join(pixels_ws, 'cold.shp')
    hot_pixel_path = os.path.join(pixels_ws, 'hot.shp')
    if shapefile_flag:
        dripy.remove_file(cold_pixel_path)
        dripy.remove_file(hot_pixel_path)

    # #  Limit etrf raster to just correct NDVI ranges?
    # apply_ndvi_mask = True
    # if apply_ndvi_mask:
    #     etrf_cold_array = np.copy(etrf_array)
    #     etrf_hot_array = np.copy(etrf_array)
    #     etrf_cold_array[ndvi_array < 0.4] = np.nan
    #     etrf_hot_array[ndvi_array > 0.4] = np.nan

    # Select target pixel
    cold_x, cold_y = get_target_point_in_array(etrf_array, etrf_geo,
                                               cal_dict['tgt_c_kc'])
    hot_x, hot_y = get_target_point_in_array(etrf_array, etrf_geo,
                                             cal_dict['tgt_h_kc'])

    # Save pixels
    if shapefile_flag and cold_x and cold_y:
        drigo.save_point_to_shapefile(cold_pixel_path, cold_x, cold_y)
    if shapefile_flag and hot_x and hot_y:
        drigo.save_point_to_shapefile(hot_pixel_path, hot_x, hot_y)

    # Eventually don't save a shapefile and just return the coordinates
    return (cold_x, cold_y), (hot_x, hot_y)

Beispiel #2

Datei: landsat_prep_scene_func.py Projekt: getawork/pymetric

        def metric_weather_func(output_raster, input_ws, input_re,
                                prev_dt, next_dt,
                                resample_method=gdal.GRA_NearestNeighbour,
                                rounding_flag=False):
            """Interpolate/project/clip METRIC hourly rasters"""
            logging.debug('    Output: {}'.format(output_raster))
            if os.path.isfile(output_raster):
                if overwrite_flag:
                    logging.debug('    Overwriting output')
                    dripy.remove_file(output_raster)
                else:
                    logging.debug('    Skipping, file already exists ' +
                                  'and overwrite is False')
                    return False
            prev_ws = os.path.join(input_ws, str(prev_dt.year))
            next_ws = os.path.join(input_ws, str(next_dt.year))

            # Technically previous and next could come from different days
            # or even years, although this won't happen in the U.S.
            try:
                prev_path = [
                    os.path.join(prev_ws, input_name)
                    for input_name in os.listdir(prev_ws)
                    for input_match in [input_re.match(input_name)]
                    if (input_match and
                        (prev_dt.strftime('%Y%m%d') ==
                         input_match.group('YYYYMMDD')))][0]
                logging.debug('    Input prev: {}'.format(prev_path))
            except IndexError:
                logging.error('  No previous hourly file')
                logging.error('    {}'.format(prev_dt))
                return False
            try:
                next_path = [
                    os.path.join(next_ws, input_name)
                    for input_name in os.listdir(next_ws)
                    for input_match in [input_re.match(input_name)]
                    if (input_match and
                        (next_dt.strftime('%Y%m%d') ==
                         input_match.group('YYYYMMDD')))][0]
                logging.debug('    Input next: {}'.format(next_path))
            except IndexError:
                logging.error('  No next hourly file')
                logging.error('    {}'.format(next_dt))
                return False

            # Band numbers are 1's based
            prev_band = int(prev_dt.strftime('%H')) + 1
            next_band = int(next_dt.strftime('%H')) + 1
            logging.debug('    Input prev band: {}'.format(prev_band))
            logging.debug('    Input next band: {}'.format(next_band))

            # Read arrays
            prev_array = drigo.raster_to_array(
                prev_path, band=prev_band, mask_extent=common_gcs_extent,
                return_nodata=False)
            next_array = drigo.raster_to_array(
                next_path, band=next_band, mask_extent=common_gcs_extent,
                return_nodata=False)
            if not np.any(prev_array) or not np.any(next_array):
                logging.warning('\nWARNING: Input NLDAS array is all nodata\n')
                return None

            output_array = hourly_interpolate_func(
                prev_array, next_array,
                prev_dt, next_dt, image.acq_datetime)
            output_array = drigo.project_array(
                output_array, resample_method,
                input_osr, input_cs, common_gcs_extent,
                common_osr, env.cellsize, common_extent, output_nodata=None)

            # Apply common area mask
            output_array[~common_array] = np.nan

            # Reduce the file size by rounding to the nearest n digits
            if rounding_flag:
                output_array = np.around(output_array, rounding_digits)
            # Force output to 32-bit float
            drigo.array_to_raster(
                output_array.astype(np.float32), output_raster,
                output_geo=common_geo, output_proj=common_proj,
                stats_flag=stats_flag)
            del output_array
            return True

Beispiel #3

Datei: landsat_prep_scene_func.py Projekt: getawork/pymetric

def main(image_ws, ini_path, bs=2048, stats_flag=False, overwrite_flag=False):
    """Prep a Landsat scene for METRIC

    Parameters
    ----------
    image_ws : str
        Landsat scene folder that will be prepped.
    ini_path : str
        File path of the input parameters file.
    bs : int, optional
        Processing block size (the default is 2048).
    stats_flag : bool, optional
        If True, compute raster statistics (the default is True).
    overwrite_flag : bool, optional
        If True, overwrite existing files (the default is False).

    Returns
    -------
    True is successful

    """

    # Open config file
    config = dripy.open_ini(ini_path)

    # Get input parameters
    logging.debug('  Reading Input File')
    calc_refl_toa_flag = dripy.read_param(
        'calc_refl_toa_flag', True, config, 'INPUTS')
    calc_refl_toa_qa_flag = dripy.read_param(
        'calc_refl_toa_qa_flag', True, config, 'INPUTS')
    # calc_refl_sur_ledaps_flag = dripy.read_param(
    #     'calc_refl_sur_ledaps_flag', False, config, 'INPUTS')
    # calc_refl_sur_qa_flag = dripy.read_param(
    #     'calc_refl_sur_qa_flag', False, config, 'INPUTS')
    calc_ts_bt_flag = dripy.read_param(
        'calc_ts_bt_flag', True, config, 'INPUTS')

    # Use QA band to set common area
    # Fmask cloud, shadow, & snow pixels will be removed from common area
    calc_fmask_common_flag = dripy.read_param(
        'calc_fmask_common_flag', True, config, 'INPUTS')
    fmask_smooth_flag = dripy.read_param(
        'fmask_smooth_flag', False, config, 'INPUTS')
    fmask_buffer_flag = dripy.read_param(
        'fmask_buffer_flag', False, config, 'INPUTS')
    fmask_erode_flag = dripy.read_param(
        'fmask_erode_flag', False, config, 'INPUTS')
    if fmask_smooth_flag:
        fmask_smooth_cells = int(dripy.read_param(
            'fmask_smooth_cells', 1, config, 'INPUTS'))
        if fmask_smooth_cells == 0 and fmask_smooth_flag:
            fmask_smooth_flag = False
    if fmask_erode_flag:
        fmask_erode_cells = int(dripy.read_param(
            'fmask_erode_cells', 1, config, 'INPUTS'))
        if fmask_erode_cells == 0 and fmask_erode_flag:
            fmask_erode_flag = False
    if fmask_buffer_flag:
        fmask_buffer_cells = int(dripy.read_param(
            'fmask_buffer_cells', 1, config, 'INPUTS'))
        if fmask_buffer_cells == 0 and fmask_buffer_flag:
            fmask_buffer_flag = False

    # Remove edge (fringe) cells
    edge_smooth_flag = dripy.read_param(
        'edge_smooth_flag', True, config, 'INPUTS')

    # Include hand made cloud masks
    cloud_mask_flag = dripy.read_param(
        'cloud_mask_flag', False, config, 'INPUTS')
    cloud_mask_ws = ""
    if cloud_mask_flag:
        cloud_mask_ws = config.get('INPUTS', 'cloud_mask_ws')

    # Extract separate Fmask rasters
    calc_fmask_flag = dripy.read_param(
        'calc_fmask_flag', True, config, 'INPUTS')
    calc_fmask_cloud_flag = dripy.read_param(
        'calc_fmask_cloud_flag', True, config, 'INPUTS')
    calc_fmask_snow_flag = dripy.read_param(
        'calc_fmask_snow_flag', True, config, 'INPUTS')
    calc_fmask_water_flag = dripy.read_param(
        'calc_fmask_water_flag', True, config, 'INPUTS')

    # Keep Landsat DN, LEDAPS, and Fmask rasters
    keep_dn_flag = dripy.read_param(
        'keep_dn_flag', True, config, 'INPUTS')
    # keep_sr_flag = dripy.read_param(
    #     'keep_sr_flag', True, config, 'INPUTS')

    # For this to work I would need to pass in the metric input file
    # calc_elev_flag = dripy.read_param(
    #     'calc_elev_flag', False, config, 'INPUTS')
    # calc_landuse_flag = dripy.read_param(
    #     'calc_landuse_flag', False, config, 'INPUTS')

    # calc_acca_cloud_flag = dripy.read_param(
    #     'calc_acca_cloud_flag', True, config, 'INPUTS')
    # calc_acca_snow_flag = dripy.read_param(
    #     'calc_acca_snow_flag', True, config, 'INPUTS')
    # calc_ledaps_dem_land_flag = dripy.read_param(
    #     'calc_ledaps_dem_land_flag', False, config, 'INPUTS')
    # calc_ledaps_veg_flag = dripy.read_param(
    #     'calc_ledaps_veg_flag', False, config, 'INPUTS')
    # calc_ledaps_snow_flag = dripy.read_param(
    #     'calc_ledaps_snow_flag', False, config, 'INPUTS')
    # calc_ledaps_land_flag = dripy.read_param(
    #     'calc_ledaps_land_flag', False, config, 'INPUTS')
    # calc_ledaps_cloud_flag = dripy.read_param(
    #     'calc_ledaps_cloud_flag', False, config, 'INPUTS')

    # Interpolate/clip/project hourly rasters for each Landsat scene
    # calc_metric_flag = dripy.read_param(
    #     'calc_metric_flag', False, config, 'INPUTS')
    calc_metric_ea_flag = dripy.read_param(
        'calc_metric_ea_flag', False, config, 'INPUTS')
    calc_metric_wind_flag = dripy.read_param(
        'calc_metric_wind_flag', False, config, 'INPUTS')
    calc_metric_etr_flag = dripy.read_param(
        'calc_metric_etr_flag', False, config, 'INPUTS')
    calc_metric_tair_flag = dripy.read_param(
        'calc_metric_tair_flag', False, config, 'INPUTS')

    # Interpolate/clip/project AWC and daily ETr/PPT rasters
    # to compute SWB Ke for each Landsat scene
    calc_swb_ke_flag = dripy.read_param(
        'calc_swb_ke_flag', False, config, 'INPUTS')
    if cloud_mask_flag:
        spinup_days = dripy.read_param(
            'swb_spinup_days', 30, config, 'INPUTS')
        min_spinup_days = dripy.read_param(
            'swb_min_spinup_days', 5, config, 'INPUTS')

    # Round ea raster to N digits to save space
    rounding_digits = dripy.read_param(
        'rounding_digits', 3, config, 'INPUTS')

    env = drigo.env
    image = et_image.Image(image_ws, env)
    np.seterr(invalid='ignore', divide='ignore')
    gdal.UseExceptions()

    # Input file paths
    dn_image_dict = et_common.landsat_band_image_dict(
        image.orig_data_ws, image.image_name_re)

    # # Open METRIC config file
    # if config_file:
    #    logging.info(
    #        log_f.format('METRIC INI File:', os.path.basename(config_file)))
    #    config = configparser.ConfigParser()
    #    try:
    #        config.read(config_file)
    #    except:
    #        logging.error('\nERROR: Config file could not be read, ' +
    #                      'is not an input file, or does not exist\n' +
    #                      'ERROR: config_file = {}\n').format(config_file)
    #        sys.exit()
    #    #  Overwrite
    #    overwrite_flag = dripy.read_param('overwrite_flag', True, config)
    #
    #    #  Elevation and landuse parameters/flags from METRIC input file
    #    calc_elev_flag = dripy.read_param('save_dem_raster_flag', True, config)
    #    calc_landuse_flag = dripy.read_param(
    #        'save_landuse_raster_flag', True, config)
    #    if calc_elev_flag:
    #        elev_pr_path = config.get('INPUTS','dem_raster')
    #    if calc_landuse_flag:
    #        landuse_pr_path = config.get('INPUTS', 'landuse_raster')
    # else:
    #    overwrite_flag = False
    #    calc_elev_flag = False
    #    calc_landuse_flag = False
    #
    # Elev raster must exist
    # if calc_elev_flag and not os.path.isfile(elev_pr_path):
    #    logging.error('\nERROR: Elevation raster {} does not exist\n'.format(
    #        elev_pr_path))
    #    return False
    # Landuse raster must exist
    # if calc_landuse_flag and not os.path.isfile(landuse_pr_path):
    #    logging.error('\nERROR: Landuse raster {} does not exist\n'.format(
    #        landuse_pr_path))
    #    return False

    # Removing ancillary files before checking for inputs
    if os.path.isdir(os.path.join(image.orig_data_ws, 'gap_mask')):
        shutil.rmtree(os.path.join(image.orig_data_ws, 'gap_mask'))
    for item in os.listdir(image.orig_data_ws):
        if (image.type == 'Landsat7' and
            (item.endswith('_B8.TIF') or
             item.endswith('_B6_VCID_2.TIF'))):
            os.remove(os.path.join(image.orig_data_ws, item))
        elif (image.type == 'Landsat8' and
              (item.endswith('_B1.TIF') or
               item.endswith('_B8.TIF') or
               item.endswith('_B9.TIF') or
               item.endswith('_B11.TIF'))):
            os.remove(os.path.join(image.orig_data_ws, item))
        elif (item.endswith('_VER.jpg') or
              item.endswith('_VER.txt') or
              item.endswith('_GCP.txt') or
              item == 'README.GTF'):
            os.remove(os.path.join(image.orig_data_ws, item))

    # Check correction level (image must be L1T to process)
    if image.correction != 'L1TP':
        logging.debug('  Image is not L1TP corrected, skipping')
        return False
        # calc_fmask_common_flag = False
        # calc_refl_toa_flag = False
        # calc_ts_bt_flag = False
        # calc_metric_ea_flag = False
        # calc_metric_wind_flag = False
        # calc_metric_etr_flag = False
        # overwrite_flag = False

    # QA band must exist
    if calc_fmask_common_flag and image.qa_band not in dn_image_dict.keys():
        logging.warning(
             '\nQA band does not exist but calc_fmask_common_flag=True'
             '\n  Setting calc_fmask_common_flag=False\n  {}'.format(
                 image.qa_band))
        calc_fmask_common_flag = False
    if cloud_mask_flag and not os.path.isdir(cloud_mask_ws):
        logging.warning(
             '\ncloud_mask_ws is not a directory but cloud_mask_flag=True.'
             '\n  Setting cloud_mask_flag=False\n   {}'.format(cloud_mask_ws))
        cloud_mask_flag = False

    # Check for Landsat TOA images
    if (calc_refl_toa_flag and
        (set(list(image.band_toa_dict.keys()) +
                 [image.thermal_band, image.qa_band]) !=
            set(dn_image_dict.keys()))):
        logging.warning(
            '\nMissing Landsat images but calc_refl_toa_flag=True'
            '\n  Setting calc_refl_toa_flag=False')
        calc_refl_toa_flag = False

    # Check for Landsat brightness temperature image
    if calc_ts_bt_flag and image.thermal_band not in dn_image_dict.keys():
        logging.warning(
            '\nThermal band image does not exist but calc_ts_bt_flag=True'
            '\n  Setting calc_ts_bt_flag=False')
        calc_ts_bt_flag = False
        # DEADBEEF - Should the function return False if Ts doesn't exist?
        # return False

    # Check for METRIC hourly/daily input folders
    if calc_metric_ea_flag:
        metric_ea_input_ws = config.get('INPUTS', 'metric_ea_input_folder')
        if not os.path.isdir(metric_ea_input_ws):
            logging.warning(
                 '\nHourly Ea folder does not exist but calc_metric_ea_flag=True'
                 '\n  Setting calc_metric_ea_flag=False\n  {}'.format(
                     metric_ea_input_ws))
            calc_metric_ea_flag = False
    if calc_metric_wind_flag:
        metric_wind_input_ws = config.get('INPUTS', 'metric_wind_input_folder')
        if not os.path.isdir(metric_wind_input_ws):
            logging.warning(
                 '\nHourly wind folder does not exist but calc_metric_wind_flag=True'
                 '\n  Setting calc_metric_wind_flag=False\n  {}'.format(
                     metric_wind_input_ws))
            calc_metric_wind_flag = False
    if calc_metric_etr_flag:
        metric_etr_input_ws = config.get('INPUTS', 'metric_etr_input_folder')
        if not os.path.isdir(metric_etr_input_ws):
            logging.warning(
                 '\nHourly ETr folder does not exist but calc_metric_etr_flag=True'
                 '\n  Setting calc_metric_etr_flag=False\n  {}'.format(
                     metric_etr_input_ws))
            calc_metric_etr_flag = False
    if calc_metric_tair_flag:
        metric_tair_input_ws = config.get('INPUTS', 'metric_tair_input_folder')
        if not os.path.isdir(metric_tair_input_ws):
            logging.warning(
                 '\nHourly Tair folder does not exist but calc_metric_tair_flag=True'
                 '\n  Setting calc_metric_tair_flag=False\n  {}'.format(
                     metric_tair_input_ws))
            calc_metric_tair_flag = False
    if (calc_metric_ea_flag or calc_metric_wind_flag or
            calc_metric_etr_flag or calc_metric_tair_flag):
        metric_hourly_re = re.compile(config.get('INPUTS', 'metric_hourly_re'))
        metric_daily_re = re.compile(config.get('INPUTS', 'metric_daily_re'))

    if calc_swb_ke_flag:
        awc_input_path = config.get('INPUTS', 'awc_input_path')
        etr_input_ws = config.get('INPUTS', 'etr_input_folder')
        ppt_input_ws = config.get('INPUTS', 'ppt_input_folder')
        etr_input_re = re.compile(config.get('INPUTS', 'etr_input_re'))
        ppt_input_re = re.compile(config.get('INPUTS', 'ppt_input_re'))
        if not os.path.isfile(awc_input_path):
            logging.warning(
                 '\nAWC raster does not exist but calc_swb_ke_flag=True'
                 '\n  Setting calc_swb_ke_flag=False\n  {}'.format(
                     awc_input_path))
            calc_swb_ke_flag = False
        if not os.path.isdir(etr_input_ws):
            logging.warning(
                 '\nDaily ETr folder does not exist but calc_swb_ke_flag=True'
                 '\n  Setting calc_swb_ke_flag=False\n  {}'.format(
                     etr_input_ws))
            calc_swb_ke_flag = False
        if not os.path.isdir(ppt_input_ws):
            logging.warning(
                 '\nDaily PPT folder does not exist but calc_swb_ke_flag=True'
                 '\n  Setting calc_swb_ke_flag=False\n  {}'.format(
                     ppt_input_ws))
            calc_swb_ke_flag = False

    # Build folders for support rasters
    if ((calc_fmask_common_flag or calc_refl_toa_flag or
         # calc_refl_sur_ledaps_flag or
         calc_ts_bt_flag or
         calc_metric_ea_flag or calc_metric_wind_flag or
         calc_metric_etr_flag or calc_metric_tair_flag or
         calc_swb_ke_flag) and
        not os.path.isdir(image.support_ws)):
        os.makedirs(image.support_ws)
    if calc_refl_toa_flag and not os.path.isdir(image.refl_toa_ws):
        os.makedirs(image.refl_toa_ws)
    # if calc_refl_sur_ledaps_flag and not os.path.isdir(image.refl_sur_ws):
    #     os.makedirs(image.refl_sur_ws)

    # DEADBEEF - This is being further down just for the Fmask images
    # # Apply overwrite flag
    # if overwrite_flag:
    #     overwrite_list = [
    #         image.fmask_cloud_raster, image.fmask_snow_raster,
    #         image.fmask_water_raster
    #         # image.elev_raster, image.landuse_raster
    #         # image.common_area_raster
    #     ]
    #     for overwrite_path in overwrite_list:
    #         try:
    #             dripy.remove_file(image.fmask_cloud_raster)
    #         except:
    #             pass

    # Use QA band to build common area rasters
    logging.info('\nCommon Area Raster')
    qa_ds = gdal.Open(dn_image_dict[image.qa_band], 0)
    common_geo = drigo.raster_ds_geo(qa_ds)
    common_extent = drigo.raster_ds_extent(qa_ds)
    common_proj = drigo.raster_ds_proj(qa_ds)
    common_osr = drigo.raster_ds_osr(qa_ds)
    # Initialize common_area as all non-fill QA values
    qa_array = drigo.raster_ds_to_array(qa_ds, return_nodata=False)
    common_array = qa_array != 1
    common_rows, common_cols = common_array.shape
    del qa_ds

    # Erode and dilate to remove fringe on edge
    # Default is to not smooth, but user can force smoothing
    # This needs to be applied before Fmask
    if edge_smooth_flag and image.prefix in ['LT05', 'LE07']:
        struct = ndimage.generate_binary_structure(2, 2).astype(np.uint8)
        if image.prefix == 'LT05':
            cells = 8
        elif image.prefix == 'LE07':
            cells = 2
        else:
            cells = 0
        common_array = ndimage.binary_dilation(
            ndimage.binary_erosion(common_array, struct, cells),
            struct, cells)

    # Try applying user defined cloud masks to common_area
    cloud_mask_path = os.path.join(
        cloud_mask_ws, image.folder_id + '_mask.shp')
    if cloud_mask_flag and os.path.isfile(cloud_mask_path):
        logging.info('  Applying cloud mask shapefile')
        feature_path = os.path.join(
            cloud_mask_ws, (image.folder_id + '_mask.shp'))
        logging.info('    {}'.format(feature_path))
        cloud_mask_memory_ds = drigo.polygon_to_raster_ds(
            feature_path, nodata_value=0, burn_value=1,
            output_osr=common_osr, output_cs=30,
            output_extent=common_extent)
        cloud_array = drigo.raster_ds_to_array(
            cloud_mask_memory_ds, return_nodata=False)
        # DEADBEEF - If user sets a cloud mask,
        #   it is probably better than Fmask
        # Eventually change "if" calc_fmask_common_flag: to "elif"
        common_array[cloud_array == 1] = 0
        del cloud_mask_memory_ds, cloud_array

    # Remove Fmask cloud, shadow, and snow pixels from common_area
    if calc_fmask_common_flag:
        logging.info('  Applying Fmask to common area')
        fmask_array = et_numpy.bqa_fmask_func(qa_array)
        fmask_mask = (fmask_array >= 2) & (fmask_array <= 4)

        if fmask_smooth_flag:
            logging.debug(
                '  Smoothing (dilate/erode/erode/dilate) Fmask clouds, shadows,'
                ' and snow pixels by {} cells'.format(fmask_smooth_cells))
            # ArcGIS smoothing procedure
            fmask_mask = ndimage.binary_dilation(
                fmask_mask, iterations=fmask_smooth_cells,
                structure=ndimage.generate_binary_structure(2, 2))
            fmask_mask = ndimage.binary_erosion(
                fmask_mask, iterations=fmask_smooth_cells,
                structure=ndimage.generate_binary_structure(2, 2))
            fmask_mask = ndimage.binary_erosion(
                fmask_mask, iterations=fmask_smooth_cells,
                structure=ndimage.generate_binary_structure(2, 2))
            fmask_mask = ndimage.binary_dilation(
                fmask_mask, iterations=fmask_smooth_cells,
                structure=ndimage.generate_binary_structure(2, 2))

        if fmask_erode_flag:
            logging.debug(
                '  Eroding Fmask clouds, shadows, and snow pixels by '
                '{} cells'.format(fmask_erode_cells))
            fmask_mask = ndimage.binary_erosion(
                fmask_mask, iterations=fmask_erode_cells,
                structure=ndimage.generate_binary_structure(2, 2))

        if fmask_buffer_flag:
            logging.debug(
                '  Dilating (buffering) Fmask clouds, shadows, and snow pixels '
                'by {} cells'.format(fmask_buffer_cells))
            fmask_mask = ndimage.binary_dilation(
                fmask_mask, iterations=fmask_buffer_cells,
                structure=ndimage.generate_binary_structure(2, 2))

        # Reset common_array for buffered cells
        common_array[fmask_mask] = 0

        del fmask_array, fmask_mask

    # Check that there are some cloud free pixels
    if not np.any(common_array):
        logging.error(
            '  ERROR: There are no cloud/snow free pixels, returning False')
        return False

    # Always overwrite common area raster
    # if not os.path.isfile(image.common_area_raster):
    drigo.array_to_raster(
        common_array, image.common_area_raster,
        output_geo=common_geo, output_proj=common_proj,
        stats_flag=stats_flag)

    # Print common geo/extent
    logging.debug('  Common geo:      {}'.format(common_geo))
    logging.debug('  Common extent:   {}'.format(common_extent))

    # Extract Fmask components as separate rasters
    if (calc_fmask_flag or calc_fmask_cloud_flag or calc_fmask_snow_flag or
            calc_fmask_water_flag):
        logging.info('\nFmask')
        fmask_array = et_numpy.bqa_fmask_func(qa_array)

        # Remove existing Fmask rasters
        if (calc_fmask_flag and overwrite_flag and
                os.path.isfile(image.fmask_output_raster)):
            logging.debug('  Overwriting: {}'.format(
                image.fmask_output_raster))
            dripy.remove_file(image.fmask_output_raster)
        if (calc_fmask_cloud_flag and overwrite_flag and
                os.path.isfile(image.fmask_cloud_raster)):
            logging.debug('  Overwriting: {}'.format(
                image.fmask_cloud_raster))
            dripy.remove_file(image.fmask_cloud_raster)
        if (calc_fmask_snow_flag and overwrite_flag and
                os.path.isfile(image.fmask_snow_raster)):
            logging.debug('  Overwriting: {}'.format(
                image.fmask_snow_raster))
            dripy.remove_file(image.fmask_snow_raster)
        if (calc_fmask_water_flag and overwrite_flag and
                os.path.isfile(image.fmask_water_raster)):
            logging.debug('  Overwriting: {}'.format(
                image.fmask_water_raster))
            dripy.remove_file(image.fmask_water_raster)

        # Save Fmask data as separate rasters
        if (calc_fmask_flag and not os.path.isfile(image.fmask_output_raster)):
            logging.debug('  Saving Fmask raster')
            drigo.array_to_raster(
                fmask_array.astype(np.uint8), image.fmask_output_raster,
                output_geo=common_geo, output_proj=common_proj,
                mask_array=None, output_nodata=255, stats_flag=stats_flag)
        if (calc_fmask_cloud_flag and
                not os.path.isfile(image.fmask_cloud_raster)):
            logging.debug('  Saving Fmask cloud raster')
            fmask_cloud_array = (fmask_array == 2) | (fmask_array == 4)
            drigo.array_to_raster(
                fmask_cloud_array.astype(np.uint8), image.fmask_cloud_raster,
                output_geo=common_geo, output_proj=common_proj,
                mask_array=None, output_nodata=255, stats_flag=stats_flag)
            del fmask_cloud_array
        if (calc_fmask_snow_flag and
                not os.path.isfile(image.fmask_snow_raster)):
            logging.debug('  Saving Fmask snow raster')
            fmask_snow_array = (fmask_array == 3)
            drigo.array_to_raster(
                fmask_snow_array.astype(np.uint8), image.fmask_snow_raster,
                output_geo=common_geo, output_proj=common_proj,
                mask_array=None, output_nodata=255, stats_flag=stats_flag)
            del fmask_snow_array
        if (calc_fmask_water_flag and
                not os.path.isfile(image.fmask_water_raster)):
            logging.debug('  Saving Fmask water raster')
            fmask_water_array = (fmask_array == 1)
            drigo.array_to_raster(
                fmask_water_array.astype(np.uint8), image.fmask_water_raster,
                output_geo=common_geo, output_proj=common_proj,
                mask_array=None, output_nodata=255, stats_flag=stats_flag)
            del fmask_water_array
        del fmask_array

    # # Calculate elevation
    # if calc_elev_flag and not os.path.isfile(elev_path):
    #     logging.info('Elevation')
    #     elev_array, elev_nodata = drigo.raster_to_array(
    #         elev_pr_path, 1, common_extent)
    #     drigo.array_to_raster(
    #         elev_array, elev_raster,
    #         output_geo=common_geo, output_proj=env.snap_proj,
    #         mask_array=common_array, stats_flag=stats_flag)
    #     del elev_array, elev_nodata, elev_path
    #
    # # Calculate landuse
    # if calc_landuse_flag and not os.path.isfile(landuse_raster):
    #     logging.info('Landuse')
    #     landuse_array, landuse_nodata = drigo.raster_to_array(
    #         landuse_pr_path, 1, common_extent)
    #     drigo.array_to_raster(
    #         landuse_array, landuse_raster,
    #         output_geo=common_geo, output_proj=env.snap_proj,
    #         mask_array=common_array, stats_flag=stats_flag)
    #     del landuse_array, landuse_nodata, landuse_raster

    # Calculate toa reflectance
    # f32_gtype, f32_nodata = numpy_to_gdal_type(np.float32)
    if calc_refl_toa_flag:
        logging.info('Top-of-Atmosphere Reflectance')
        if os.path.isfile(image.refl_toa_raster) and overwrite_flag:
            logging.debug('  Overwriting: {}'.format(
                image.refl_toa_raster))
            dripy.remove_file(image.refl_toa_raster)
        if not os.path.isfile(image.refl_toa_raster):
            # First build empty composite raster
            drigo.build_empty_raster(
                image.refl_toa_raster, image.band_toa_cnt, np.float32, None,
                env.snap_proj, env.cellsize, common_extent)
            # cos_theta_solar_flt = et_common.cos_theta_solar_func(
            #    image.sun_elevation)

            # Process by block
            logging.info('Processing by block')
            logging.debug('  Mask  cols/rows: {}/{}'.format(
                common_cols, common_rows))
            for b_i, b_j in drigo.block_gen(common_rows, common_cols, bs):
                logging.debug('  Block  y: {:5d}  x: {:5d}'.format(b_i, b_j))
                block_data_mask = drigo.array_to_block(
                    common_array, b_i, b_j, bs).astype(np.bool)
                block_rows, block_cols = block_data_mask.shape
                block_geo = drigo.array_offset_geo(common_geo, b_j, b_i)
                block_extent = drigo.geo_extent(
                    block_geo, block_rows, block_cols)
                logging.debug('    Block rows: {}  cols: {}'.format(
                    block_rows, block_cols))
                logging.debug('    Block extent: {}'.format(block_extent))
                logging.debug('    Block geo: {}'.format(block_geo))

                # Process each TOA band
                # for band, band_i in sorted(image.band_toa_dict.items()):
                for band, dn_image in sorted(dn_image_dict.items()):
                    if band not in image.band_toa_dict.keys():
                        continue
                    # thermal_band_flag = (band == image.thermal_band)
                    # Set 0 as nodata value
                    drigo.raster_path_set_nodata(dn_image, 0)
                    # Calculate TOA reflectance
                    dn_array, dn_nodata = drigo.raster_to_array(
                        dn_image, 1, block_extent)
                    dn_array = dn_array.astype(np.float64)
                    # dn_array = dn_array.astype(np.float32)
                    dn_array[dn_array == 0] = np.nan
                    #
                    if image.type in ['Landsat4', 'Landsat5', 'Landsat7']:
                        refl_toa_array = et_numpy.l457_refl_toa_band_func(
                            dn_array, image.cos_theta_solar,
                            image.dr, image.esun_dict[band],
                            image.lmin_dict[band], image.lmax_dict[band],
                            image.qcalmin_dict[band], image.qcalmax_dict[band])
                    elif image.type in ['Landsat8']:
                        refl_toa_array = et_numpy.l8_refl_toa_band_func(
                            dn_array, image.cos_theta_solar,
                            image.refl_mult_dict[band],
                            image.refl_add_dict[band])
                    # if (image.type in ['Landsat4', 'Landsat5', 'Landsat7'] and
                    #     not thermal_band_flag):
                    #     refl_toa_array = et_numpy.l457_refl_toa_band_func(
                    #         dn_array, image.cos_theta_solar,
                    #         image.dr, image.esun_dict[band],
                    #         image.lmin_dict[band], image.lmax_dict[band],
                    #         image.qcalmin_dict[band],
                    #         image.qcalmax_dict[band])
                    #         # image.rad_mult_dict[band],
                    #         # image.rad_add_dict[band])
                    # elif (image.type in ['Landsat8'] and
                    #       not thermal_band_flag):
                    #     refl_toa_array = et_numpy.l8_refl_toa_band_func(
                    #         dn_array, image.cos_theta_solar,
                    #         image.refl_mult_dict[band],
                    #         image.refl_add_dict[band])
                    # elif (image.type in ['Landsat4', 'Landsat5', 'Landsat7'] and
                    #       thermal_band_flag):
                    #     refl_toa_array = et_numpy.l457_ts_bt_band_func(
                    #         dn_array,
                    #         image.lmin_dict[band], image.lmax_dict[band],
                    #         image.qcalmin_dict[band],
                    #         image.qcalmax_dict[band],
                    #         # image.rad_mult_dict[band],
                    #         # image.rad_add_dict[band],
                    #         image.k1_dict[band], image.k2_dict[band])
                    # elif (image.type in ['Landsat8'] and
                    #       thermal_band_flag):
                    #     refl_toa_array = et_numpy.l8_ts_bt_band_func(
                    #         dn_array,
                    #         image.rad_mult_dict[band],
                    #         image.rad_add_dict[band],
                    #         image.k1_dict[band], image.k2_dict[band])

                    # refl_toa_array = et_numpy.refl_toa_band_func(
                    #     dn_array, cos_theta_solar_flt,
                    #     image.dr, image.esun_dict[band],
                    #     image.lmin_dict[band], image.lmax_dict[band],
                    #     image.qcalmin_dict[band], image.qcalmax_dict[band],
                    #     thermal_band_flag)
                    drigo.block_to_raster(
                        refl_toa_array.astype(np.float32),
                        image.refl_toa_raster,
                        b_i, b_j, band=image.band_toa_dict[band])
                    # drigo.array_to_comp_raster(
                    #    refl_toa_array.astype(np.float32),
                    #    image.refl_toa_raster,
                    #    image.band_toa_dict[band], common_array)
                    del refl_toa_array, dn_array
            if stats_flag:
                drigo.raster_statistics(image.refl_toa_raster)

        # # Process each TOA band
        # # for band, band_i in sorted(image.band_toa_dict.items()):
        # for band, dn_image in sorted(dn_image_dict.items()):
        #     thermal_band_flag = (band == image.thermal_band)
        #     #  Set 0 as nodata value
        #     drigo.raster_path_set_nodata(dn_image, 0)
        #     #  Calculate TOA reflectance
        #     dn_array, dn_nodata = drigo.raster_to_array(
        #         dn_image, 1, common_extent)
        #     dn_array = dn_array.astype(np.float64)
        #     # dn_array = dn_array.astype(np.float32)
        #     dn_array[dn_array == 0] = np.nan
        #     #
        #     if (image.type in ['Landsat4', 'Landsat5', 'Landsat7'] and
        #         not thermal_band_flag):
        #         refl_toa_array = et_numpy.l457_refl_toa_band_func(
        #             dn_array, image.cos_theta_solar,
        #             image.dr, image.esun_dict[band],
        #             image.lmin_dict[band], image.lmax_dict[band],
        #             image.qcalmin_dict[band], image.qcalmax_dict[band])
        #             # image.rad_mult_dict[band], image.rad_add_dict[band])
        #     elif (image.type in ['Landsat4', 'Landsat5', 'Landsat7'] and
        #           thermal_band_flag):
        #         refl_toa_array = et_numpy.l457_ts_bt_band_func(
        #             dn_array, image.lmin_dict[band], image.lmax_dict[band],
        #             image.qcalmin_dict[band], image.qcalmax_dict[band],
        #             # image.rad_mult_dict[band], image.rad_add_dict[band],
        #             image.k1_dict[band], image.k2_dict[band])
        #     elif (image.type in ['Landsat8'] and
        #           not thermal_band_flag):
        #         refl_toa_array = et_numpy.l8_refl_toa_band_func(
        #             dn_array, image.cos_theta_solar,
        #             image.refl_mult_dict[band], image.refl_add_dict[band])
        #     elif (image.type in ['Landsat8'] and
        #           thermal_band_flag):
        #         refl_toa_array = et_numpy.l8_ts_bt_band_func(
        #             dn_array,
        #             image.rad_mult_dict[band], image.rad_add_dict[band],
        #             image.k1_dict[band], image.k2_dict[band])
        #     # refl_toa_array = et_numpy.refl_toa_band_func(
        #     #     dn_array, cos_theta_solar_flt,
        #     #     image.dr, image.esun_dict[band],
        #     #     image.lmin_dict[band], image.lmax_dict[band],
        #     #     image.qcalmin_dict[band], image.qcalmax_dict[band],
        #     #     thermal_band_flag)
        #     drigo.array_to_comp_raster(
        #         refl_toa_array.astype(np.float32), image.refl_toa_raster,
        #         image.band_toa_dict[band], common_array)
        #     del refl_toa_array, dn_array


    # Calculate brightness temperature
    if calc_ts_bt_flag:
        logging.info('Brightness Temperature')
        if os.path.isfile(image.ts_bt_raster) and overwrite_flag:
            logging.debug('  Overwriting: {}'.format(image.ts_bt_raster))
            dripy.remove_file(image.ts_bt_raster)
        if not os.path.isfile(image.ts_bt_raster):
            band = image.thermal_band
            thermal_dn_path = dn_image_dict[band]
            drigo.raster_path_set_nodata(thermal_dn_path, 0)
            thermal_dn_array, thermal_dn_nodata = drigo.raster_to_array(
                thermal_dn_path, 1, common_extent, return_nodata=True)
            thermal_dn_mask = thermal_dn_array != thermal_dn_nodata
            if image.type in ['Landsat4', 'Landsat5', 'Landsat7']:
                ts_bt_array = et_numpy.l457_ts_bt_band_func(
                    thermal_dn_array,
                    image.lmin_dict[band], image.lmax_dict[band],
                    image.qcalmin_dict[band], image.qcalmax_dict[band],
                    # image.rad_mult_dict[band], image.rad_add_dict[band],
                    image.k1_dict[band], image.k2_dict[band])
            elif image.type in ['Landsat8']:
                ts_bt_array = et_numpy.l8_ts_bt_band_func(
                    thermal_dn_array,
                    image.rad_mult_dict[band], image.rad_add_dict[band],
                    image.k1_dict[band], image.k2_dict[band])
            # thermal_rad_array = et_numpy.refl_toa_band_func(
            #     thermal_dn_array, image.cos_theta_solar,
            #     image.dr, image.esun_dict[band],
            #     image.lmin_dict[band], image.lmax_dict[band],
            #     image.qcalmin_dict[band], image.qcalmax_dict[band],
            #     thermal_band_flag=True)
            # ts_bt_array = et_numpy.ts_bt_func(
            #     thermal_rad_array, image.k1_dict[image.thermal_band],
            #     image.k2_dict[image.thermal_band])
            ts_bt_array[~thermal_dn_mask] = np.nan
            drigo.array_to_raster(
                ts_bt_array, image.ts_bt_raster,
                output_geo=common_geo, output_proj=env.snap_proj,
                # mask_array=common_array,
                stats_flag=stats_flag)
            # del thermal_dn_array, thermal_rad_array
            del thermal_dn_path, thermal_dn_array, ts_bt_array


    # Interpolate/project/clip METRIC hourly/daily rasters
    if (calc_metric_ea_flag or
            calc_metric_wind_flag or
            calc_metric_etr_flag):
        logging.info('METRIC hourly/daily rasters')

        # Get bracketing hours from image acquisition time
        image_prev_dt = image.acq_datetime.replace(
            minute=0, second=0, microsecond=0)
        image_next_dt = image_prev_dt + timedelta(seconds=3600)

        # Get NLDAS properties from one of the images
        input_ws = os.path.join(
            metric_etr_input_ws, str(image_prev_dt.year))
        try:
            input_path = [
                os.path.join(input_ws, file_name)
                for file_name in os.listdir(input_ws)
                for match in [metric_hourly_re.match(file_name)]
                if (match and
                    (image_prev_dt.strftime('%Y%m%d') ==
                     match.group('YYYYMMDD')))][0]
        except IndexError:
            logging.error('  No hourly file for {}'.format(
                image_prev_dt.strftime('%Y-%m-%d %H00')))
            return False
        try:
            input_ds = gdal.Open(input_path)
            input_osr = drigo.raster_ds_osr(input_ds)
            # input_proj = drigo.osr_proj(input_osr)
            input_extent = drigo.raster_ds_extent(input_ds)
            input_cs = drigo.raster_ds_cellsize(input_ds, x_only=True)
            # input_geo = input_extent.geo(input_cs)
            input_x, input_y = input_extent.origin()
            input_ds = None
        except:
            logging.error('  Could not get default input image properties')
            logging.error('    {}'.format(input_path))
            return False

        # Project Landsat scene extent to NLDAS GCS
        common_gcs_osr = common_osr.CloneGeogCS()
        common_gcs_extent = drigo.project_extent(
            common_extent, common_osr, common_gcs_osr,
            cellsize=env.cellsize)
        common_gcs_extent.buffer_extent(0.1)
        common_gcs_extent.adjust_to_snap(
            'EXPAND', input_x, input_y, input_cs)
        # common_gcs_geo = common_gcs_extent.geo(input_cs)

        def metric_weather_func(output_raster, input_ws, input_re,
                                prev_dt, next_dt,
                                resample_method=gdal.GRA_NearestNeighbour,
                                rounding_flag=False):
            """Interpolate/project/clip METRIC hourly rasters"""
            logging.debug('    Output: {}'.format(output_raster))
            if os.path.isfile(output_raster):
                if overwrite_flag:
                    logging.debug('    Overwriting output')
                    dripy.remove_file(output_raster)
                else:
                    logging.debug('    Skipping, file already exists ' +
                                  'and overwrite is False')
                    return False
            prev_ws = os.path.join(input_ws, str(prev_dt.year))
            next_ws = os.path.join(input_ws, str(next_dt.year))

            # Technically previous and next could come from different days
            # or even years, although this won't happen in the U.S.
            try:
                prev_path = [
                    os.path.join(prev_ws, input_name)
                    for input_name in os.listdir(prev_ws)
                    for input_match in [input_re.match(input_name)]
                    if (input_match and
                        (prev_dt.strftime('%Y%m%d') ==
                         input_match.group('YYYYMMDD')))][0]
                logging.debug('    Input prev: {}'.format(prev_path))
            except IndexError:
                logging.error('  No previous hourly file')
                logging.error('    {}'.format(prev_dt))
                return False
            try:
                next_path = [
                    os.path.join(next_ws, input_name)
                    for input_name in os.listdir(next_ws)
                    for input_match in [input_re.match(input_name)]
                    if (input_match and
                        (next_dt.strftime('%Y%m%d') ==
                         input_match.group('YYYYMMDD')))][0]
                logging.debug('    Input next: {}'.format(next_path))
            except IndexError:
                logging.error('  No next hourly file')
                logging.error('    {}'.format(next_dt))
                return False

            # Band numbers are 1's based
            prev_band = int(prev_dt.strftime('%H')) + 1
            next_band = int(next_dt.strftime('%H')) + 1
            logging.debug('    Input prev band: {}'.format(prev_band))
            logging.debug('    Input next band: {}'.format(next_band))

            # Read arrays
            prev_array = drigo.raster_to_array(
                prev_path, band=prev_band, mask_extent=common_gcs_extent,
                return_nodata=False)
            next_array = drigo.raster_to_array(
                next_path, band=next_band, mask_extent=common_gcs_extent,
                return_nodata=False)
            if not np.any(prev_array) or not np.any(next_array):
                logging.warning('\nWARNING: Input NLDAS array is all nodata\n')
                return None

            output_array = hourly_interpolate_func(
                prev_array, next_array,
                prev_dt, next_dt, image.acq_datetime)
            output_array = drigo.project_array(
                output_array, resample_method,
                input_osr, input_cs, common_gcs_extent,
                common_osr, env.cellsize, common_extent, output_nodata=None)

            # Apply common area mask
            output_array[~common_array] = np.nan

            # Reduce the file size by rounding to the nearest n digits
            if rounding_flag:
                output_array = np.around(output_array, rounding_digits)
            # Force output to 32-bit float
            drigo.array_to_raster(
                output_array.astype(np.float32), output_raster,
                output_geo=common_geo, output_proj=common_proj,
                stats_flag=stats_flag)
            del output_array
            return True

        # Ea - Project to Landsat scene after clipping
        if calc_metric_ea_flag:
            logging.info('  Hourly vapor pressure (Ea)')
            metric_weather_func(
                image.metric_ea_raster, metric_ea_input_ws,
                metric_hourly_re, image_prev_dt, image_next_dt,
                gdal.GRA_Bilinear, rounding_flag=True)

        # Wind - Project to Landsat scene after clipping
        if calc_metric_wind_flag:
            logging.info('  Hourly windspeed')
            metric_weather_func(
                image.metric_wind_raster, metric_wind_input_ws,
                metric_hourly_re, image_prev_dt, image_next_dt,
                gdal.GRA_NearestNeighbour, rounding_flag=False)

        # ETr - Project to Landsat scene after clipping
        if calc_metric_etr_flag:
            logging.info('  Hourly reference ET (ETr)')
            metric_weather_func(
                image.metric_etr_raster, metric_etr_input_ws,
                metric_hourly_re, image_prev_dt, image_next_dt,
                gdal.GRA_NearestNeighbour, rounding_flag=False)

        # ETr 24hr - Project to Landsat scene after clipping
        if calc_metric_etr_flag:
            logging.info('  Daily reference ET (ETr)')
            logging.debug('    Output: {}'.format(
                image.metric_etr_24hr_raster))
            if (os.path.isfile(image.metric_etr_24hr_raster) and
                    overwrite_flag):
                logging.debug('    Overwriting output')
                os.remove(image.metric_etr_24hr_raster)
            if not os.path.isfile(image.metric_etr_24hr_raster):
                etr_prev_ws = os.path.join(
                    metric_etr_input_ws, str(image_prev_dt.year))
                try:
                    input_path = [
                        os.path.join(etr_prev_ws, file_name)
                        for file_name in os.listdir(etr_prev_ws)
                        for match in [metric_daily_re.match(file_name)]
                        if (match and
                            (image_prev_dt.strftime('%Y%m%d') ==
                             match.group('YYYYMMDD')))][0]
                    logging.debug('    Input: {}'.format(input_path))
                except IndexError:
                    logging.error('  No daily file for {}'.format(
                        image_prev_dt.strftime('%Y-%m-%d')))
                    return False
                output_array = drigo.raster_to_array(
                    input_path, mask_extent=common_gcs_extent,
                    return_nodata=False)
                output_array = drigo.project_array(
                    output_array, gdal.GRA_NearestNeighbour,
                    input_osr, input_cs, common_gcs_extent,
                    common_osr, env.cellsize, common_extent,
                    output_nodata=None)
                # Apply common area mask
                output_array[~common_array] = np.nan
                # Reduce the file size by rounding to the nearest n digits
                # output_array = np.around(output_array, rounding_digits)
                drigo.array_to_raster(
                    output_array, image.metric_etr_24hr_raster,
                    output_geo=common_geo, output_proj=common_proj,
                    stats_flag=stats_flag)
                del output_array
                del input_path

        # Tair - Project to Landsat scene after clipping
        if calc_metric_tair_flag:
            logging.info('  Hourly air temperature (Tair)')
            metric_weather_func(
                image.metric_tair_raster, metric_tair_input_ws,
                metric_hourly_re, image_prev_dt, image_next_dt,
                gdal.GRA_NearestNeighbour, rounding_flag=False)

        # Cleanup
        del image_prev_dt, image_next_dt

    # Soil Water Balance
    if calc_swb_ke_flag:
        logging.info('Daily soil water balance')

        # Check if output file already exists
        logging.debug('  Ke:  {}'.format(image.ke_raster))
        if os.path.isfile(image.ke_raster):
            if overwrite_flag:
                logging.debug('    Overwriting output')
                dripy.remove_file(image.ke_raster)
            else:
                logging.debug('    Skipping, file already '
                              'exists and overwrite is False')
                return False
        ke_array = et_common.raster_swb_func(
            image.acq_datetime, common_osr, env.cellsize, common_extent,
            awc_input_path, etr_input_ws, etr_input_re,
            ppt_input_ws, ppt_input_re,
            spinup_days=spinup_days, min_spinup_days=min_spinup_days)
        # Apply common area mask
        ke_array[~common_array] = np.nan
        # Reduce the file size by rounding to the nearest 2 digits
        np.around(ke_array, 2, out=ke_array)

        # Force output to 32-bit float
        drigo.array_to_raster(
            ke_array.astype(np.float32), image.ke_raster,
            output_geo=common_geo, output_proj=common_proj,
            stats_flag=stats_flag)

    # Remove Landsat TOA rasters
    if not keep_dn_flag:
        for landsat_item in dripy.build_file_list(
                image.orig_data_ws, image.image_name_re):
            os.remove(os.path.join(image.orig_data_ws, landsat_item))
    return True

Beispiel #4

Datei: pixel_rating_func.py Projekt: shepherdmeng/pyMETRIC

def pixel_rating(image_ws, ini_path, stats_flag=False, overwrite_flag=None):
    """Calculate pixel rating

    Args:
        image_ws (str): Image folder path
        ini_path (str): Pixel regions config file path
        stats_flag (bool): if True, compute raster statistics
        ovewrite_flag (bool): if True, overwrite existing files

    Returns:
        None
    """
    logging.info('Generating suggested hot/cold pixel regions')
    log_fmt = '  {:<18s} {}'

    env = gdc.env
    image = et_image.Image(image_ws, env)
    np.seterr(invalid='ignore')

    # # Check  that image_ws is valid
    # image_re = re.compile(
    #     '^(LT04|LT05|LE07|LC08)_(\d{3})(\d{3})_(\d{4})(\d{2})(\d{2})')
    # if not os.path.isdir(image_ws) or not image_re.match(scene_id):
    #     logging.error('\nERROR: Image folder is invalid or does not exist\n')
    #     return False

    # Folder Paths
    region_ws = os.path.join(image_ws, 'PIXEL_REGIONS')

    # Open config file
    config = open_ini(ini_path)

    # Get input parameters
    logging.debug('  Reading Input File')
    # Arrays are processed by block
    bs = read_param('block_size', 1024, config)
    logging.info('  {:<18s} {}'.format('Block Size:', bs))

    # Raster pyramids/statistics
    pyramids_flag = read_param('pyramids_flag', False, config)
    if pyramids_flag:
        gdal.SetConfigOption('HFA_USE_RRD', 'YES')
    if stats_flag is None:
        stats_flag = read_param('statistics_flag', False, config)

    # Overwrite
    if overwrite_flag is None:
        overwrite_flag = read_param('overwrite_flag', True, config)

    # Check that common_area raster exists
    if not os.path.isfile(image.common_area_raster):
        logging.error(
            '\nERROR: A common area raster was not found.' +
            '\nERROR: Please rerun prep tool to build these files.\n' +
            '    {}\n'.format(image.common_area_raster))
        sys.exit()

    # Use common_area to set mask parameters
    common_ds = gdal.Open(image.common_area_raster)
    # env.mask_proj = raster_ds_proj(common_ds)
    env.mask_geo = gdc.raster_ds_geo(common_ds)
    env.mask_rows, env.mask_cols = gdc.raster_ds_shape(common_ds)
    env.mask_extent = gdc.geo_extent(env.mask_geo, env.mask_rows,
                                     env.mask_cols)
    env.mask_array = gdc.raster_ds_to_array(common_ds)[0]
    env.mask_path = image.common_area_raster
    env.snap_osr = gdc.raster_path_osr(image.common_area_raster)
    env.snap_proj = env.snap_osr.ExportToWkt()
    env.cellsize = gdc.raster_path_cellsize(image.common_area_raster)[0]
    common_ds = None
    logging.debug('  {:<18s} {}'.format('Mask Extent:', env.mask_extent))

    # Read Pixel Regions config file
    # Currently there is no code to support applying an NLCD mask
    apply_nlcd_mask = False
    # apply_nlcd_mask = read_param('apply_nlcd_mask', False, config)
    apply_cdl_ag_mask = read_param('apply_cdl_ag_mask', False, config)
    apply_field_mask = read_param('apply_field_mask', False, config)
    apply_ndwi_mask = read_param('apply_ndwi_mask', True, config)
    apply_ndvi_mask = read_param('apply_ndvi_mask', True, config)
    # Currently the code to apply a study area mask is commented out
    # apply_study_area_mask = read_param(
    #     'apply_study_area_mask', False, config)

    albedo_rating_flag = read_param('albedo_rating_flag', True, config)
    nlcd_rating_flag = read_param('nlcd_rating_flag', True, config)
    ndvi_rating_flag = read_param('ndvi_rating_flag', True, config)
    ts_rating_flag = read_param('ts_rating_flag', True, config)
    ke_rating_flag = read_param('ke_rating_flag', False, config)

    # if apply_study_area_mask:
    #     study_area_path = config.get('INPUTS', 'study_area_path')
    if apply_nlcd_mask or nlcd_rating_flag:
        nlcd_raster = config.get('INPUTS', 'landuse_raster')
    if apply_cdl_ag_mask:
        cdl_ag_raster = config.get('INPUTS', 'cdl_ag_raster')
        cdl_buffer_cells = read_param('cdl_buffer_cells', 0, config)
        cdl_ag_eroded_name = read_param('cdl_ag_eroded_name',
                                        'cdl_ag_eroded_{}.img', config)
    if apply_field_mask:
        field_raster = config.get('INPUTS', 'fields_raster')

    cold_rating_pct = read_param('cold_percentile', 99, config)
    hot_rating_pct = read_param('hot_percentile', 99, config)
    # min_cold_rating_score = read_param('min_cold_rating_score', 0.3, config)
    # min_hot_rating_score = read_param('min_hot_rating_score', 0.3, config)

    ts_bin_count = int(read_param('ts_bin_count', 10, config))
    if 100 % ts_bin_count != 0:
        logging.warning(
            'WARNING: ts_bins_count of {} is not a divisor ' +
            'of 100. Using default ts_bins_count = 4'.format(ts_bin_count))
        ts_bin_count = 10
    bin_size = 1. / (ts_bin_count - 1)
    hot_rating_values = np.arange(0., 1. + bin_size, step=bin_size)
    cold_rating_values = hot_rating_values[::-1]

    # Input raster paths
    r_fmt = '.img'
    if 'Landsat' in image.type:
        albedo_raster = image.albedo_sur_raster
        ndvi_raster = image.ndvi_toa_raster
        ndwi_raster = image.ndwi_toa_raster
        ts_raster = image.ts_raster
        ke_raster = image.ke_raster

    # Check config file input paths
    # if apply_study_area_mask and not os.path.isfile(study_area_path):
    #     logging.error(
    #         ('\nERROR: The study area shapefile {} does ' +
    #             'not exist\n').format(study_area_path))
    #     sys.exit()
    if ((apply_nlcd_mask or nlcd_rating_flag)
            and not os.path.isfile(nlcd_raster)):
        logging.error(('\nERROR: The NLCD raster {} does ' +
                       'not exist\n').format(nlcd_raster))
        sys.exit()
    if apply_cdl_ag_mask and not os.path.isfile(cdl_ag_raster):
        logging.error(('\nERROR: The CDL Ag raster {} does ' +
                       'not exist\n').format(cdl_ag_raster))
        sys.exit()
    if apply_field_mask and not os.path.isfile(field_raster):
        logging.error(('\nERROR: The field raster {} does ' +
                       'not exist\n').format(field_raster))
        sys.exit()
    if (not (isinstance(cold_rating_pct,
                        (int, float)) and (0 <= cold_rating_pct <= 100))):
        logging.error(
            '\nERROR: cold_percentile must be a value between 0 and 100\n')
        sys.exit()
    if (not (isinstance(hot_rating_pct,
                        (int, float)) and (0 <= hot_rating_pct <= 100))):
        logging.error(
            '\nERROR: hot_percentile must be a value between 0 and 100\n')
        sys.exit()

    # Set raster names
    raster_dict = dict()

    # Output Rasters
    raster_dict['region_mask'] = os.path.join(region_ws, 'region_mask' + r_fmt)
    raster_dict['cold_rating'] = os.path.join(region_ws,
                                              'cold_pixel_rating' + r_fmt)
    raster_dict['hot_rating'] = os.path.join(region_ws,
                                             'hot_pixel_rating' + r_fmt)
    raster_dict['cold_sugg'] = os.path.join(region_ws,
                                            'cold_pixel_suggestion' + r_fmt)
    raster_dict['hot_sugg'] = os.path.join(region_ws,
                                           'hot_pixel_suggestion' + r_fmt)

    # Read pixel region raster flags
    save_dict = dict()
    save_dict['region_mask'] = read_param('save_region_mask_flag', False,
                                          config)
    save_dict['cold_rating'] = read_param('save_rating_rasters_flag', False,
                                          config)
    save_dict['hot_rating'] = read_param('save_rating_rasters_flag', False,
                                         config)
    save_dict['cold_sugg'] = read_param('save_suggestion_rasters_flag', True,
                                        config)
    save_dict['hot_sugg'] = read_param('save_suggestion_rasters_flag', True,
                                       config)

    # Output folder
    if not os.path.isdir(region_ws):
        os.mkdir(region_ws)

    # Remove existing files if necessary
    region_ws_file_list = [
        os.path.join(region_ws, item) for item in os.listdir(region_ws)
    ]
    if overwrite_flag and region_ws_file_list:
        for raster_path in raster_dict.values():
            if raster_path in region_ws_file_list:
                remove_file(raster_path)

    # Check scene specific input paths
    if apply_ndwi_mask and not os.path.isfile(ndwi_raster):
        logging.error(
            'ERROR: NDWI raster does not exist\n {}'.format(ndwi_raster))
        sys.exit()
    elif apply_ndvi_mask and not os.path.isfile(ndvi_raster):
        logging.error(
            'ERROR: NDVI raster does not exist\n {}'.format(ndvi_raster))
        sys.exit()
    elif ke_rating_flag and not os.path.isfile(ke_raster):
        logging.error(
            ('ERROR: The Ke raster does not exist\n {}').format(ke_raster))
        sys.exit()

    # Remove existing and build new empty rasters if necessary
    # If processing by block, rating rasters must be built
    logging.debug('\nBuilding empty rasters')
    for name, save_flag in sorted(save_dict.items()):
        if save_flag and 'rating' in name:
            gdc.build_empty_raster(raster_dict[name], 1, np.float32)
        elif save_flag:
            gdc.build_empty_raster(raster_dict[name],
                                   1,
                                   np.uint8,
                                   output_nodata=0)

    if apply_cdl_ag_mask:
        logging.info('Building CDL ag mask')
        cdl_array = gdc.raster_to_array(cdl_ag_raster,
                                        mask_extent=env.mask_extent,
                                        return_nodata=False)
        if cdl_buffer_cells > 0:
            logging.info('  Eroding CDL by {} cells'.format(cdl_buffer_cells))
            structure_array = np.ones((cdl_buffer_cells, cdl_buffer_cells),
                                      dtype=np.int)
            # Deadbeef - This could blow up in memory on bigger rasters
            cdl_array = ndimage.binary_erosion(
                cdl_array, structure_array).astype(structure_array.dtype)
        cdl_ag_eroded_raster = os.path.join(
            image.support_ws, cdl_ag_eroded_name.format(cdl_buffer_cells))
        gdc.array_to_raster(cdl_array,
                            cdl_ag_eroded_raster,
                            output_geo=env.mask_geo,
                            output_proj=env.snap_proj,
                            mask_array=env.mask_array,
                            output_nodata=0,
                            stats_flag=False)
        cdl_array = None
        del cdl_array

    # Build region mask
    logging.debug('Building region mask')
    region_mask = np.copy(env.mask_array).astype(np.bool)
    if apply_field_mask:
        field_mask, field_nodata = gdc.raster_to_array(
            field_raster, mask_extent=env.mask_extent, return_nodata=True)
        region_mask &= field_mask != field_nodata
        del field_mask, field_nodata
    if apply_ndwi_mask:
        ndwi_array = gdc.raster_to_array(ndwi_raster,
                                         1,
                                         mask_extent=env.mask_extent,
                                         return_nodata=False)
        region_mask &= ndwi_array > 0.0
        del ndwi_array
    if apply_ndvi_mask:
        ndvi_array = gdc.raster_to_array(ndvi_raster,
                                         1,
                                         mask_extent=env.mask_extent,
                                         return_nodata=False)
        region_mask &= ndvi_array > 0.12
        del ndvi_array
    if apply_cdl_ag_mask:
        cdl_array, cdl_nodata = gdc.raster_to_array(
            cdl_ag_eroded_raster,
            mask_extent=env.mask_extent,
            return_nodata=True)
        region_mask &= cdl_array != cdl_nodata
        del cdl_array, cdl_nodata
    if save_dict['region_mask']:
        gdc.array_to_raster(region_mask,
                            raster_dict['region_mask'],
                            stats_flag=False)

    # Initialize rating arrays
    # This needs to be done before the ts_rating if block
    cold_rating_array = np.ones(env.mask_array.shape, dtype=np.float32)
    hot_rating_array = np.ones(env.mask_array.shape, dtype=np.float32)
    cold_rating_array[~region_mask] = np.nan
    hot_rating_array[~region_mask] = np.nan

    # Temperature pixel rating - grab the max and min value for the entire
    #  Ts image in a memory safe way by using gdal_common blocks
    # The following is a percentile based approach
    if ts_rating_flag:
        logging.debug('Computing Ts percentile rating')
        ts_array = gdc.raster_to_array(ts_raster,
                                       mask_extent=env.mask_extent,
                                       return_nodata=False)
        ts_array[~region_mask] = np.nan

        percentiles = range(0, (100 + ts_bin_count), int(100 / ts_bin_count))
        ts_score_value = 1. / (ts_bin_count - 1)
        hot_rating_values = np.arange(0, (1. + ts_score_value),
                                      step=ts_score_value)[:ts_bin_count]
        cold_rating_values = hot_rating_values[::-1]
        ts_percentile_array = stats.scoreatpercentile(
            ts_array[np.isfinite(ts_array)], percentiles)

        for bins_i in range(len(ts_percentile_array))[:-1]:
            bool_array = ((ts_array > ts_percentile_array[bins_i]) &
                          (ts_array <= ts_percentile_array[bins_i + 1]))
            cold_rating_array[bool_array] = cold_rating_values[bins_i]
            hot_rating_array[bool_array] = hot_rating_values[bins_i]
        # gdc.array_to_raster(cold_rating_array, raster_dict['cold_rating'])
        # gdc.array_to_raster(hot_rating_array, raster_dict['hot_rating'])

        # Cleanup
        del ts_array, ts_percentile_array
        del cold_rating_values, hot_rating_values
        del ts_score_value, percentiles

    # Process by block
    logging.info('\nProcessing by block')
    logging.debug('  Mask  cols/rows: {}/{}'.format(env.mask_cols,
                                                    env.mask_rows))
    for b_i, b_j in gdc.block_gen(env.mask_rows, env.mask_cols, bs):
        logging.debug('  Block  y: {:5d}  x: {:5d}'.format(b_i, b_j))
        block_data_mask = gdc.array_to_block(env.mask_array, b_i, b_j,
                                             bs).astype(np.bool)
        # block_nodata_mask = ~block_data_mask
        block_rows, block_cols = block_data_mask.shape
        block_geo = gdc.array_offset_geo(env.mask_geo, b_j, b_i)
        block_extent = gdc.geo_extent(block_geo, block_rows, block_cols)
        logging.debug('    Block rows: {}  cols: {}'.format(
            block_rows, block_cols))
        # logging.debug('    Block extent: {}'.format(block_extent))
        # logging.debug('    Block geo: {}'.format(block_geo))

        # Don't skip empty blocks since block rating needs to be written
        #  back to the array at the end of the block loop
        block_region_mask = gdc.array_to_block(region_mask, b_i, b_j, bs)
        if not np.any(block_region_mask):
            logging.debug('    Empty block')
            block_empty_flag = True
        else:
            block_empty_flag = False

        # New style continuous pixel weighting
        cold_rating_block = gdc.array_to_block(cold_rating_array, b_i, b_j, bs)
        hot_rating_block = gdc.array_to_block(hot_rating_array, b_i, b_j, bs)

        # Rating arrays already have region_mask set
        # cold_rating_block = np.ones(block_region_mask.shape, dtype=np.float32)
        # hot_rating_block = np.ones(block_region_mask.shape, dtype=np.float32)
        # cold_rating_block[~block_region_mask] = np.nan
        # hot_rating_block[~block_region_mask] = np.nan
        # del block_region_mask

        if ndvi_rating_flag and not block_empty_flag:
            # NDVI based rating
            ndvi_array = gdc.raster_to_array(ndvi_raster,
                                             1,
                                             mask_extent=block_extent,
                                             return_nodata=False)
            # Don't let NDVI be negative
            ndvi_array.clip(0., 0.833, out=ndvi_array)
            # ndvi_array.clip(0.001, 0.833, out=ndvi_array)
            cold_rating_block *= ndvi_array
            cold_rating_block *= 1.20
            ndvi_mask = (ndvi_array > 0)
            # DEADBEEF - Can this calculation be masked to only NDVI > 0?
            ndvi_mask = ndvi_array > 0
            hot_rating_block[ndvi_mask] *= stats.norm.pdf(
                np.log(ndvi_array[ndvi_mask]), math.log(0.15), 0.5)
            hot_rating_block[ndvi_mask] *= 1.25
            del ndvi_mask
            # hot_rating_block *= stats.norm.pdf(
            #     np.log(ndvi_array), math.log(0.15), 0.5)
            # hot_rating_block *= 1.25
            # cold_rating_block.clip(0., 1., out=cold_rating_block)
            # hot_rating_block.clip(0., 1., out=hot_rating_block)
            del ndvi_array

        if albedo_rating_flag and not block_empty_flag:
            # Albdo based rating
            albedo_array = gdc.raster_to_array(albedo_raster,
                                               1,
                                               mask_extent=block_extent,
                                               return_nodata=False)
            albedo_cold_pdf = stats.norm.pdf(albedo_array, 0.21, 0.03)
            albedo_hot_pdf = stats.norm.pdf(albedo_array, 0.21, 0.06)
            del albedo_array
            cold_rating_block *= albedo_cold_pdf
            cold_rating_block *= 0.07
            hot_rating_block *= albedo_hot_pdf
            hot_rating_block *= 0.15
            # cold_rating_block.clip(0., 1., out=cold_rating_block)
            # hot_rating_block.clip(0., 1., out=hot_rating_block)
            del albedo_cold_pdf, albedo_hot_pdf

        if nlcd_rating_flag and not block_empty_flag:
            # NLCD based weighting, this could be CDL instead?
            nlcd_array = nlcd_rating(
                gdc.raster_to_array(nlcd_raster,
                                    1,
                                    mask_extent=block_extent,
                                    return_nodata=False))
            cold_rating_block *= nlcd_array
            hot_rating_block *= nlcd_array
            del nlcd_array

        if ke_rating_flag and not block_empty_flag:
            # SWB Ke based rating
            ke_array = gdc.raster_to_array(ke_raster,
                                           1,
                                           mask_extent=block_extent,
                                           return_nodata=False)
            # Don't let NDVI be negative
            ke_array.clip(0., 1., out=ke_array)
            # Assumption, lower Ke is better for selecting the hot pixel
            # As the power (2) decreases and approaches 1,
            #   the relationship gets more linear
            # cold_rating_block *= (1 - ke_array ** 2)
            # hot_rating_block *= (1 - ke_array ** 1.5)
            # Linear inverse
            # cold_rating_block *= (1. - ke_array)
            hot_rating_block *= (1. - ke_array)
            # cold_rating_block.clip(0., 1., out=cold_rating_block)
            # hot_rating_block.clip(0., 1., out=hot_rating_block)
            del ke_array

        # Clearness
        # clearness = 1.0
        # cold_rating *= clearness
        # hot_rating *= clearness

        # Reset nan values
        # cold_rating_block[~region_mask] = np.nan
        # hot_rating_block[~region_mask] = np.nan

        # Save rating values
        cold_rating_array = gdc.block_to_array(cold_rating_block,
                                               cold_rating_array, b_i, b_j, bs)
        hot_rating_array = gdc.block_to_array(hot_rating_block,
                                              hot_rating_array, b_i, b_j, bs)

        # Save rating rasters
        if save_dict['cold_rating']:
            gdc.block_to_raster(cold_rating_block, raster_dict['cold_rating'],
                                b_i, b_j, bs)
        if save_dict['hot_rating']:
            gdc.block_to_raster(hot_rating_block, raster_dict['hot_rating'],
                                b_i, b_j, bs)
        # Save rating values
        cold_rating_array = gdc.block_to_array(cold_rating_block,
                                               cold_rating_array, b_i, b_j, bs)
        hot_rating_array = gdc.block_to_array(hot_rating_block,
                                              hot_rating_array, b_i, b_j, bs)

        del cold_rating_block, hot_rating_block

    # Select pixels above target percentile
    # Only build suggestion arrays if saving
    logging.debug('Building suggested pixel rasters')
    if save_dict['cold_sugg']:
        cold_rating_score = float(
            stats.scoreatpercentile(
                cold_rating_array[np.isfinite(cold_rating_array)],
                cold_rating_pct))
        # cold_rating_array, cold_rating_nodata = gdc.raster_to_array(
        #     raster_dict['cold_rating'], 1, mask_extent=env.mask_extent)
        # if cold_rating_score < float(min_cold_rating_score):
        #     logging.error(('ERROR: The cold_rating_score ({}) is less ' +
        #                    'than the min_cold_rating_score ({})').format(
        #                     cold_rating_score, min_cold_rating_score))
        #     sys.exit()
        cold_sugg_mask = cold_rating_array >= cold_rating_score
        gdc.array_to_raster(cold_sugg_mask,
                            raster_dict['cold_sugg'],
                            stats_flag=stats_flag)
        logging.debug('  Cold Percentile: {}'.format(cold_rating_pct))
        logging.debug('  Cold Score:  {:.6f}'.format(cold_rating_score))
        logging.debug('  Cold Pixels: {}'.format(np.sum(cold_sugg_mask)))
        del cold_sugg_mask, cold_rating_array
    if save_dict['hot_sugg']:
        hot_rating_score = float(
            stats.scoreatpercentile(
                hot_rating_array[np.isfinite(hot_rating_array)],
                hot_rating_pct))
        # hot_rating_array, hot_rating_nodata = gdc.raster_to_array(
        #     raster_dict['hot_rating'], 1, mask_extent=env.mask_extent)
        # if hot_rating_score < float(min_hot_rating_score):
        #     logging.error(('ERROR: The hot_rating_array ({}) is less ' +
        #                    'than the min_hot_rating_score ({})').format(
        #                     hot_rating_array, min_hot_rating_score))
        #     sys.exit()
        hot_sugg_mask = hot_rating_array >= hot_rating_score
        gdc.array_to_raster(hot_sugg_mask,
                            raster_dict['hot_sugg'],
                            stats_flag=stats_flag)
        logging.debug('  Hot Percentile: {}'.format(hot_rating_pct))
        logging.debug('  Hot Score:  {:.6f}'.format(hot_rating_score))
        logging.debug('  Hot Pixels: {}'.format(np.sum(hot_sugg_mask)))
        del hot_sugg_mask, hot_rating_array

    # Raster Statistics
    if stats_flag:
        logging.info('Calculating Statistics')
        for name, save_flag in save_dict.items():
            if save_flag:
                gdc.raster_statistics(raster_dict[name])
    # Raster Pyramids
    if pyramids_flag:
        logging.info('Building Pyramids')
        for name, save_flag in save_dict.items():
            if save_flag:
                gdc.raster_pyramids(raster_dict[name])

Beispiel #5

def pixel_points(image_ws,
                 groupsize=1,
                 blocksize=2048,
                 mc_iter=None,
                 shapefile_flag=False,
                 multipoint_flag=False,
                 pixel_point_iters=0,
                 overwrite_flag=None):
    """Place hot/cold pixels within .\PIXEL_REGIONS\pixel_suggestion.shp

    Parameters
    ----------
    image_ws : str
        Image folder path.
    groupsize : int, optional
        Script will try to place calibration point randomly into a
        labeled group of clustered values with at least n pixels.
        -1 = In the largest group
         0 = Anywhere in the image (not currently implemented)
         1 >= In any group with a pixel count greater or equal to n
    blocksize : int, optional
        Processing block size (the default is 2048).
    shapefile_flag : bool, optional
        If True, save calibration points to shapefile (the default is False).
    multipoing_flag : bool, optional
        If True, save calibration points to multipoint shapefile
        (the default is False).
    pixel_point_iters : int, optional
        Number of iterations (the default is 0).
    ovewrite_flag : bool, optional
        If True, overwrite existing files (the default is None).

    Returns
    -------
    tuple of cold coordinates, tuple of hot coordinates

    """
    logging.info('Placing hot/cold pixels in suggested regions')

    env = drigo.env
    image = et_image.Image(image_ws, env)
    np.seterr(invalid='ignore')
    common_ds = drigo.raster_path_ds(image.common_area_raster, read_only=True)
    env.snap_proj = drigo.raster_ds_proj(common_ds)
    common_ds = None

    # Open config file
    # config = dripy.open_ini(ini_path)

    # Get input parameters
    # logging.debug('  Reading Input File')
    pixels_folder = 'PIXELS'
    if mc_iter:
        cold_pixel_name = 'cold_{:02d}'.format(int(mc_iter))
        hot_pixel_name = 'hot_{:02d}'.format(int(mc_iter))
    else:
        cold_pixel_name = 'cold'
        hot_pixel_name = 'hot'
    hot_cold_pixels_name = 'hot_cold'
    r_fmt = '.img'
    s_fmt = '.shp'
    # json_format = '.geojson'

    # pixels_folder = dripy.read_param(pixels_folder, 'PIXELS', config)
    # cold_pixel_name = dripy.read_param(cold_pixel_name, 'cold', config)
    # hot_pixel_name = dripy.read_param(hot_pixel_name, 'hot', config)

    # Create Pixels Folder and Scratch Folder
    pixels_ws = os.path.join(image_ws, pixels_folder)
    region_ws = os.path.join(image_ws, 'PIXEL_REGIONS')
    if not os.path.isdir(pixels_ws):
        os.mkdir(pixels_ws)

    # Generate pixels shapefiles if they don't exist
    cold_pixel_path = os.path.join(pixels_ws, cold_pixel_name + s_fmt)
    hot_pixel_path = os.path.join(pixels_ws, hot_pixel_name + s_fmt)
    hot_cold_pixel_path = os.path.join(pixels_ws, hot_cold_pixels_name + s_fmt)
    if shapefile_flag and overwrite_flag:
        dripy.remove_file(cold_pixel_path)
        dripy.remove_file(hot_pixel_path)
        # dripy.remove_file(hot_cold_pixel_path)

    # Place points in the suggested pixel location raster
    cold_region_raster = os.path.join(region_ws,
                                      'cold_pixel_suggestion' + r_fmt)
    hot_region_raster = os.path.join(region_ws, 'hot_pixel_suggestion' + r_fmt)
    if not os.path.isfile(cold_region_raster):
        logging.error('\nERROR: The cold pixel suggestion raster {} does '
                      'not exist\n'.format(
                          os.path.basename(cold_region_raster)))
        sys.exit()
    if not os.path.isfile(hot_region_raster):
        logging.error('\nERROR: The hot pixel suggestion raster {} does '
                      'not exist\n'.format(
                          os.path.basename(hot_region_raster)))
        sys.exit()

    # Check placement_mode value
    # Make sure it is between -1 and max pixelcount?

    # Pixel placement mode
    logging.info('Calibration point placement method:')
    if type(groupsize) is not int:
        logging.error('\nGroupsize must be an integer\n')
        sys.exit()
    elif groupsize <= -1:
        logging.info('  Randomly within largest suggested region polygon')
    elif groupsize == 0:
        logging.info('  Randomly anywhere in the image')
        sys.exit()
    elif groupsize >= 1:
        logging.info('  Randomly within suggested region polygons with '
                     'more than {} pixels'.format(groupsize))

    # Select random pixel
    cold_x, cold_y = get_random_point_in_raster(cold_region_raster, groupsize,
                                                blocksize)
    hot_x, hot_y = get_random_point_in_raster(hot_region_raster, groupsize,
                                              blocksize)

    # Save pixels
    if shapefile_flag and cold_x and cold_y:
        drigo.save_point_to_shapefile(cold_pixel_path, cold_x, cold_y,
                                      env.snap_proj)
    if shapefile_flag and hot_x and hot_y:
        drigo.save_point_to_shapefile(hot_pixel_path, hot_x, hot_y,
                                      env.snap_proj)
    if multipoint_flag and cold_x and cold_y:
        drigo.multipoint_shapefile(hot_cold_pixel_path,
                                   cold_x,
                                   cold_y,
                                   'COLD_{:02d}_{:02d}'.format(
                                       int(mc_iter), int(pixel_point_iters)),
                                   id_=mc_iter,
                                   input_proj=env.snap_proj)
    if multipoint_flag and hot_x and hot_y:
        drigo.multipoint_shapefile(hot_cold_pixel_path,
                                   hot_x,
                                   hot_y,
                                   'HOT_{:02d}_{:02d}'.format(
                                       int(mc_iter), int(pixel_point_iters)),
                                   id_=mc_iter,
                                   input_proj=env.snap_proj)

    # Eventually don't save a shapefile and just return the coordinates
    return (cold_x, cold_y), (hot_x, hot_y)