# -*- coding: utf-8 -*- """ *************************************************************************** flightlinesToCHM.py --------------------- Date : May 2014 Copyright : (C) 2014 by Martin Isenburg Email : martin near rapidlasso point com *************************************************************************** * * * This program is free software; you can redistribute it and/or modify * * it under the terms of the GNU General Public License as published by * * the Free Software Foundation; either version 2 of the License, or * * (at your option) any later version. * * * *************************************************************************** """ __author__ = 'Martin Isenburg' __date__ = 'May 2014' __copyright__ = '(C) 2014, Martin Isenburg' # This will get replaced with a git SHA1 when you do a git archive __revision__ = '$Format:%H$' import os from .LAStoolsUtils import LAStoolsUtils from .LAStoolsAlgorithm import LAStoolsAlgorithm from processing.core.parameters import ParameterSelection from processing.core.parameters import ParameterNumber from processing.core.parameters import ParameterString class flightlinesToCHM(LAStoolsAlgorithm): TILE_SIZE = "TILE_SIZE" BUFFER = "BUFFER" TERRAIN = "TERRAIN" TERRAINS = ["wilderness", "nature", "town", "city", "metro"] BEAM_WIDTH = "BEAM_WIDTH" BASE_NAME = "BASE_NAME" def defineCharacteristics(self): self.name, self.i18n_name = self.trAlgorithm('flightlinesToCHM') self.group, self.i18n_group = self.trAlgorithm('LAStools Pipelines') self.addParametersPointInputFolderGUI() self.addParameter(ParameterNumber(flightlinesToCHM.TILE_SIZE, self.tr("tile size (side length of square tile)"), 0, None, 1000.0)) self.addParameter(ParameterNumber(flightlinesToCHM.BUFFER, self.tr("buffer around each tile (avoids edge artifacts)"), 0, None, 25.0)) self.addParameter(ParameterSelection(flightlinesToCHM.TERRAIN, self.tr("terrain type"), flightlinesToCHM.TERRAINS, 1)) self.addParameter(ParameterNumber(flightlinesToCHM.BEAM_WIDTH, self.tr("laser beam width (diameter of laser footprint)"), 0, None, 0.2)) self.addParametersStepGUI() self.addParametersTemporaryDirectoryGUI() self.addParametersOutputDirectoryGUI() self.addParameter(ParameterString(flightlinesToCHM.BASE_NAME, self.tr("tile base name (using 'sydney' creates sydney_274000_4714000...)"), "tile")) self.addParametersRasterOutputFormatGUI() self.addParametersCoresGUI() self.addParametersVerboseGUI() def processAlgorithm(self, progress): # first we tile the data commands = [os.path.join(LAStoolsUtils.LAStoolsPath(), "bin", "lastile")] self.addParametersVerboseCommands(commands) self.addParametersPointInputFolderCommands(commands) commands.append("-files_are_flightlines") tile_size = self.getParameterValue(flightlinesToCHM.TILE_SIZE) commands.append("-tile_size") commands.append(unicode(tile_size)) buffer = self.getParameterValue(flightlinesToCHM.BUFFER) if buffer != 0.0: commands.append("-buffer") commands.append(unicode(buffer)) self.addParametersTemporaryDirectoryAsOutputDirectoryCommands(commands) base_name = self.getParameterValue(flightlinesToCHM.BASE_NAME) if base_name == "": base_name = "tile" commands.append("-o") commands.append(base_name) commands.append("-olaz") LAStoolsUtils.runLAStools(commands, progress) # then we ground classify the tiles commands = [os.path.join(LAStoolsUtils.LAStoolsPath(), "bin", "lasground")] self.addParametersVerboseCommands(commands) self.addParametersTemporaryDirectoryAsInputFilesCommands(commands, base_name + "*.laz") method = self.getParameterValue(flightlinesToCHM.TERRAIN) if method != 1: commands.append("-" + flightlinesToCHM.TERRAINS[method]) if method > 2: commands.append("-ultra_fine") elif method > 1: commands.append("-extra_fine") elif method > 0: commands.append("-fine") self.addParametersTemporaryDirectoryAsOutputDirectoryCommands(commands) commands.append("-odix") commands.append("_g") commands.append("-olaz") self.addParametersCoresCommands(commands) LAStoolsUtils.runLAStools(commands, progress) # then we height-normalize the tiles commands = [os.path.join(LAStoolsUtils.LAStoolsPath(), "bin", "lasheight")] self.addParametersVerboseCommands(commands) self.addParametersTemporaryDirectoryAsInputFilesCommands(commands, base_name + "*_g.laz") commands.append("-replace_z") self.addParametersTemporaryDirectoryAsOutputDirectoryCommands(commands) commands.append("-odix") commands.append("h") commands.append("-olaz") self.addParametersCoresCommands(commands) LAStoolsUtils.runLAStools(commands, progress) # then we thin and splat the tiles commands = [os.path.join(LAStoolsUtils.LAStoolsPath(), "bin", "lasthin")] self.addParametersVerboseCommands(commands) self.addParametersTemporaryDirectoryAsInputFilesCommands(commands, base_name + "*_gh.laz") beam_width = self.getParameterValue(flightlinesToCHM.BEAM_WIDTH) if beam_width != 0.0: commands.append("-subcircle") commands.append(unicode(beam_width / 2)) step = self.getParametersStepValue() commands.append("-step") commands.append(unicode(step / 4)) commands.append("-highest") self.addParametersTemporaryDirectoryAsOutputDirectoryCommands(commands) commands.append("-odix") commands.append("t") commands.append("-olaz") self.addParametersCoresCommands(commands) LAStoolsUtils.runLAStools(commands, progress) # then we rasterize the classified tiles into CHMs commands = [os.path.join(LAStoolsUtils.LAStoolsPath(), "bin", "las2dem")] self.addParametersVerboseCommands(commands) self.addParametersTemporaryDirectoryAsInputFilesCommands(commands, base_name + "*_ght.laz") self.addParametersStepCommands(commands) commands.append("-use_tile_bb") self.addParametersOutputDirectoryCommands(commands) commands.append("-ocut") commands.append("4") commands.append("-odix") commands.append("_chm") self.addParametersRasterOutputFormatCommands(commands) self.addParametersCoresCommands(commands) LAStoolsUtils.runLAStools(commands, progress)