FlatCAM/tclCommands/TclCommandDrillcncjob.py

from tclCommands.TclCommand import TclCommandSignaled
from FlatCAMObj import FlatCAMExcellon

import collections
import math


class TclCommandDrillcncjob(TclCommandSignaled):
    """
    Tcl shell command to Generates a Drill CNC Job from a Excellon Object.
    """

    # array of all command aliases, to be able use  old names for backward compatibility (add_poly, add_polygon)
    aliases = ['drillcncjob']

    # dictionary of types from Tcl command, needs to be ordered
    arg_names = collections.OrderedDict([
        ('name', str)
    ])

    # dictionary of types from Tcl command, needs to be ordered , this  is  for options  like -optionname value
    option_types = collections.OrderedDict([
        ('drilled_dias', str),
        ('drillz', float),
        ('travelz', float),
        ('feedrate', float),
        ('feedrate_rapid', float),
        ('spindlespeed', int),
        ('toolchange', bool),
        ('toolchangez', float),
        ('toolchangexy', tuple),
        ('endz', float),
        ('pp', str),
        ('outname', str),
        ('opt_type', str),
        ('diatol', float),
        ('muted', int)
    ])

    # array of mandatory options for current Tcl command: required = {'name','outname'}
    required = ['name']

    # structured help for current command, args needs to be ordered
    help = {
        'main': "Generates a Drill CNC Job from a Excellon Object.",
        'args': collections.OrderedDict([
            ('name', 'Name of the source object.'),
            ('drilled_dias',
             'Comma separated tool diameters of the drills to be drilled (example: 0.6, 1.0 or 3.125).'),
            ('drillz', 'Drill depth into material (example: -2.0).'),
            ('travelz', 'Travel distance above material (example: 2.0).'),
            ('feedrate', 'Drilling feed rate.'),
            ('feedrate_rapid', 'Rapid drilling feed rate.'),
            ('spindlespeed', 'Speed of the spindle in rpm (example: 4000).'),
            ('toolchange', 'Enable tool changes (example: True).'),
            ('toolchangez', 'Z distance for toolchange (example: 30.0).'),
            ('toolchangexy', 'X, Y coordonates for toolchange in format (x, y) (example: (2.0, 3.1) ).'),
            ('endz', 'Z distance at job end (example: 30.0).'),
            ('pp', 'This is the Excellon postprocessor name: case_sensitive, no_quotes'),
            ('outname', 'Name of the resulting Geometry object.'),
            ('opt_type', 'Name of move optimization type. B by default for Basic OR-Tools, M for Metaheuristic OR-Tools'
                         'T from Travelling Salesman Algorithm. B and M works only for 64bit version of FlatCAM and '
                         'T works only for 32bit version of FlatCAM'),
            ('diatol', 'Tolerance. Percentange (0.0 ... 100.0) within which dias in drilled_dias will be judged to be '
                       'the same as the ones in the tools from the Excellon object. E.g: if in drill_dias we have a '
                       'diameter with value 1.0, in the Excellon we have a tool with dia = 1.05 and we set a tolerance '
                       'diatol = 5.0 then the drills with the dia = (0.95 ... 1.05) '
                       'in Excellon will be processed. Float number.'),
            ('muted', 'It will not put errors in the Shell or status bar.')
        ]),
        'examples': ['drillcncjob test.TXT -drillz -1.5 -travelz 14 -feedrate 222 -feedrate_rapid 456 -spindlespeed 777'
                     ' -toolchange True -toolchangez 33 -endz 22 -pp default\n'
                     'Usage of -feedrate_rapid matter only when the posptocessor is using it, like -marlin-.']
    }

    def execute(self, args, unnamed_args):
        """
        execute current TCL shell command

        :param args: array of known named arguments and options
        :param unnamed_args: array of other values which were passed into command
            without -somename and  we do not have them in known arg_names
        :return: None or exception
        """

        name = args['name']

        if 'outname' not in args:
            args['outname'] = name + "_cnc"

        if 'muted' in args:
            muted = args['muted']
        else:
            muted = 0

        obj = self.app.collection.get_by_name(name)
        if obj is None:
            if muted == 0:
                self.raise_tcl_error("Object not found: %s" % name)
            else:
                return "fail"

        if not isinstance(obj, FlatCAMExcellon):
            if muted == 0:
                self.raise_tcl_error('Expected FlatCAMExcellon, got %s %s.' % (name, type(obj)))
            else:
                return "fail"

        xmin = obj.options['xmin']
        ymin = obj.options['ymin']
        xmax = obj.options['xmax']
        ymax = obj.options['ymax']

        def job_init(job_obj, app_obj):
            # tools = args["tools"] if "tools" in args else 'all'
            units = self.app.ui.general_defaults_form.general_app_group.units_radio.get_value().upper()

            try:
                if 'drilled_dias' in args and args['drilled_dias'] != 'all':
                    diameters = [x.strip() for x in args['drilled_dias'].split(",") if x != '']
                    nr_diameters = len(diameters)

                    req_tools = set()
                    for tool in obj.tools:
                        for req_dia in diameters:
                            obj_dia_form = float('%.2f' % float(obj.tools[tool]["C"])) if units == 'MM' else \
                                float('%.4f' % float(obj.tools[tool]["C"]))
                            req_dia_form = float('%.2f' % float(req_dia)) if units == 'MM' else \
                                float('%.4f' % float(req_dia))

                            if 'diatol' in args:
                                tolerance = args['diatol'] / 100

                                tolerance = 0.0 if tolerance < 0.0 else tolerance
                                tolerance = 1.0 if tolerance > 1.0 else tolerance
                                if math.isclose(obj_dia_form, req_dia_form, rel_tol=tolerance):
                                    req_tools.add(tool)
                                    nr_diameters -= 1
                            else:
                                if obj_dia_form == req_dia_form:
                                    req_tools.add(tool)
                                    nr_diameters -= 1

                    if nr_diameters > 0:
                        if muted == 0:
                            self.raise_tcl_error("One or more tool diameters of the drills to be drilled passed to the "
                                                 "TclCommand are not actual tool diameters in the Excellon object.")
                        else:
                            return "fail"

                    # make a string of diameters separated by comma; this is what generate_from_excellon_by_tool() is
                    # expecting as tools parameter
                    tools = ','.join(req_tools)

                    # no longer needed
                    del args['drilled_dias']
                    del args['diatol']

                    # Split and put back. We are passing the whole dictionary later.
                    # args['milled_dias'] = [x.strip() for x in args['tools'].split(",")]
                else:
                    tools = 'all'
            except Exception as e:
                tools = 'all'

                if muted == 0:
                    self.raise_tcl_error("Bad tools: %s" % str(e))
                else:
                    return "fail"

            drillz = args["drillz"] if "drillz" in args and args["drillz"] else obj.options["drillz"]
            toolchangez = args["toolchangez"] if "toolchangez" in args and args["toolchangez"] else \
                obj.options["toolchangez"]
            endz = args["endz"] if "endz" in args and args["endz"] else obj.options["endz"]
            toolchange = True if "toolchange" in args and args["toolchange"] == 1 else False
            opt_type = args["opt_type"] if "opt_type" in args and args["opt_type"] else 'B'

            job_obj.z_move = args["travelz"] if "travelz" in args and args["travelz"] else obj.options["travelz"]
            job_obj.feedrate = args["feedrate"] if "feedrate" in args and args["feedrate"] else obj.options["feedrate"]
            job_obj.feedrate_rapid = args["feedrate_rapid"] \
                if "feedrate_rapid" in args and args["feedrate_rapid"] else obj.options["feedrate_rapid"]

            job_obj.spindlespeed = args["spindlespeed"] if "spindlespeed" in args else None
            job_obj.pp_excellon_name = args["pp"] if "pp" in args and args["pp"] \
                else obj.options["ppname_e"]

            job_obj.coords_decimals = int(self.app.defaults["cncjob_coords_decimals"])
            job_obj.fr_decimals = int(self.app.defaults["cncjob_fr_decimals"])

            job_obj.options['type'] = 'Excellon'

            job_obj.toolchangexy = args["toolchangexy"] if "toolchangexy" in args and args["toolchangexy"] else \
                obj.options["toolchangexy"]

            job_obj.toolchange_xy_type = "excellon"

            job_obj.options['xmin'] = xmin
            job_obj.options['ymin'] = ymin
            job_obj.options['xmax'] = xmax
            job_obj.options['ymax'] = ymax

            job_obj.generate_from_excellon_by_tool(obj, tools, drillz=drillz, toolchangez=toolchangez,
                                                   endz=endz,
                                                   toolchange=toolchange, excellon_optimization_type=opt_type)
            job_obj.gcode_parse()
            job_obj.create_geometry()

        self.app.new_object("cncjob", args['outname'], job_init, plot=False)