Source code for pyleecan.Classes.CondType21

# -*- coding: utf-8 -*-
# File generated according to Generator/ClassesRef/Machine/CondType21.csv
# WARNING! All changes made in this file will be lost!
"""Method code available at

from os import linesep
from sys import getsizeof
from logging import getLogger
from ._check import check_var, raise_
from ..Functions.get_logger import get_logger
from import save
from ..Functions.load import load_init_dict
from ..Functions.Load.import_class import import_class
from copy import deepcopy
from .Conductor import Conductor

# Import all class method
# Try/catch to remove unnecessary dependencies in unused method
    from ..Methods.Machine.CondType21.comp_surface_active import comp_surface_active
except ImportError as error:
    comp_surface_active = error

    from ..Methods.Machine.CondType21.comp_height import comp_height
except ImportError as error:
    comp_height = error

    from ..Methods.Machine.CondType21.comp_surface import comp_surface
except ImportError as error:
    comp_surface = error

    from ..Methods.Machine.CondType21.comp_width import comp_width
except ImportError as error:
    comp_width = error

    from ..Methods.Machine.CondType21.plot import plot
except ImportError as error:
    plot = error

    from ..Methods.Machine.CondType21.comp_width_wire import comp_width_wire
except ImportError as error:
    comp_width_wire = error

    from ..Methods.Machine.CondType21.comp_height_wire import comp_height_wire
except ImportError as error:
    comp_height_wire = error

    from ..Methods.Machine.CondType21.comp_nb_circumferential_wire import (
except ImportError as error:
    comp_nb_circumferential_wire = error

    from ..Methods.Machine.CondType21.comp_nb_radial_wire import comp_nb_radial_wire
except ImportError as error:
    comp_nb_radial_wire = error

    from ..Methods.Machine.CondType21.is_round_wire import is_round_wire
except ImportError as error:
    is_round_wire = error

from numpy import isnan
from ._check import InitUnKnowClassError

[docs]class CondType21(Conductor): """single rectangular conductor \nhas to be used for LamSquirrelCages's conductor""" VERSION = 1 # Check ImportError to remove unnecessary dependencies in unused method # cf Methods.Machine.CondType21.comp_surface_active if isinstance(comp_surface_active, ImportError): comp_surface_active = property( fget=lambda x: raise_( ImportError( "Can't use CondType21 method comp_surface_active: " + str(comp_surface_active) ) ) ) else: comp_surface_active = comp_surface_active # cf Methods.Machine.CondType21.comp_height if isinstance(comp_height, ImportError): comp_height = property( fget=lambda x: raise_( ImportError( "Can't use CondType21 method comp_height: " + str(comp_height) ) ) ) else: comp_height = comp_height # cf Methods.Machine.CondType21.comp_surface if isinstance(comp_surface, ImportError): comp_surface = property( fget=lambda x: raise_( ImportError( "Can't use CondType21 method comp_surface: " + str(comp_surface) ) ) ) else: comp_surface = comp_surface # cf Methods.Machine.CondType21.comp_width if isinstance(comp_width, ImportError): comp_width = property( fget=lambda x: raise_( ImportError( "Can't use CondType21 method comp_width: " + str(comp_width) ) ) ) else: comp_width = comp_width # cf Methods.Machine.CondType21.plot if isinstance(plot, ImportError): plot = property( fget=lambda x: raise_( ImportError("Can't use CondType21 method plot: " + str(plot)) ) ) else: plot = plot # cf Methods.Machine.CondType21.comp_width_wire if isinstance(comp_width_wire, ImportError): comp_width_wire = property( fget=lambda x: raise_( ImportError( "Can't use CondType21 method comp_width_wire: " + str(comp_width_wire) ) ) ) else: comp_width_wire = comp_width_wire # cf Methods.Machine.CondType21.comp_height_wire if isinstance(comp_height_wire, ImportError): comp_height_wire = property( fget=lambda x: raise_( ImportError( "Can't use CondType21 method comp_height_wire: " + str(comp_height_wire) ) ) ) else: comp_height_wire = comp_height_wire # cf Methods.Machine.CondType21.comp_nb_circumferential_wire if isinstance(comp_nb_circumferential_wire, ImportError): comp_nb_circumferential_wire = property( fget=lambda x: raise_( ImportError( "Can't use CondType21 method comp_nb_circumferential_wire: " + str(comp_nb_circumferential_wire) ) ) ) else: comp_nb_circumferential_wire = comp_nb_circumferential_wire # cf Methods.Machine.CondType21.comp_nb_radial_wire if isinstance(comp_nb_radial_wire, ImportError): comp_nb_radial_wire = property( fget=lambda x: raise_( ImportError( "Can't use CondType21 method comp_nb_radial_wire: " + str(comp_nb_radial_wire) ) ) ) else: comp_nb_radial_wire = comp_nb_radial_wire # cf Methods.Machine.CondType21.is_round_wire if isinstance(is_round_wire, ImportError): is_round_wire = property( fget=lambda x: raise_( ImportError( "Can't use CondType21 method is_round_wire: " + str(is_round_wire) ) ) ) else: is_round_wire = is_round_wire # generic save method is available in all object save = save # get_logger method is available in all object get_logger = get_logger def __init__( self, Hbar=0.01, Wbar=0.01, Wins=0, cond_mat=-1, ins_mat=-1, init_dict=None, init_str=None, ): """Constructor of the class. Can be use in three ways : - __init__ (arg1 = 1, arg3 = 5) every parameters have name and default values for pyleecan type, -1 will call the default constructor - __init__ (init_dict = d) d must be a dictionary with property names as keys - __init__ (init_str = s) s must be a string s is the file path to load ndarray or list can be given for Vector and Matrix object or dict can be given for pyleecan Object""" if init_str is not None: # Load from a file init_dict = load_init_dict(init_str)[1] if init_dict is not None: # Initialisation by dict assert type(init_dict) is dict # Overwrite default value with init_dict content if "Hbar" in list(init_dict.keys()): Hbar = init_dict["Hbar"] if "Wbar" in list(init_dict.keys()): Wbar = init_dict["Wbar"] if "Wins" in list(init_dict.keys()): Wins = init_dict["Wins"] if "cond_mat" in list(init_dict.keys()): cond_mat = init_dict["cond_mat"] if "ins_mat" in list(init_dict.keys()): ins_mat = init_dict["ins_mat"] # Set the properties (value check and convertion are done in setter) self.Hbar = Hbar self.Wbar = Wbar self.Wins = Wins # Call Conductor init super(CondType21, self).__init__(cond_mat=cond_mat, ins_mat=ins_mat) # The class is frozen (in Conductor init), for now it's impossible to # add new properties def __str__(self): """Convert this object in a readeable string (for print)""" CondType21_str = "" # Get the properties inherited from Conductor CondType21_str += super(CondType21, self).__str__() CondType21_str += "Hbar = " + str(self.Hbar) + linesep CondType21_str += "Wbar = " + str(self.Wbar) + linesep CondType21_str += "Wins = " + str(self.Wins) + linesep return CondType21_str def __eq__(self, other): """Compare two objects (skip parent)""" if type(other) != type(self): return False # Check the properties inherited from Conductor if not super(CondType21, self).__eq__(other): return False if other.Hbar != self.Hbar: return False if other.Wbar != self.Wbar: return False if other.Wins != self.Wins: return False return True
[docs] def compare(self, other, name="self", ignore_list=None, is_add_value=False): """Compare two objects and return list of differences""" if ignore_list is None: ignore_list = list() if type(other) != type(self): return ["type(" + name + ")"] diff_list = list() # Check the properties inherited from Conductor diff_list.extend( super(CondType21, self).compare( other, name=name, ignore_list=ignore_list, is_add_value=is_add_value ) ) if ( other._Hbar is not None and self._Hbar is not None and isnan(other._Hbar) and isnan(self._Hbar) ): pass elif other._Hbar != self._Hbar: if is_add_value: val_str = ( " (self=" + str(self._Hbar) + ", other=" + str(other._Hbar) + ")" ) diff_list.append(name + ".Hbar" + val_str) else: diff_list.append(name + ".Hbar") if ( other._Wbar is not None and self._Wbar is not None and isnan(other._Wbar) and isnan(self._Wbar) ): pass elif other._Wbar != self._Wbar: if is_add_value: val_str = ( " (self=" + str(self._Wbar) + ", other=" + str(other._Wbar) + ")" ) diff_list.append(name + ".Wbar" + val_str) else: diff_list.append(name + ".Wbar") if ( other._Wins is not None and self._Wins is not None and isnan(other._Wins) and isnan(self._Wins) ): pass elif other._Wins != self._Wins: if is_add_value: val_str = ( " (self=" + str(self._Wins) + ", other=" + str(other._Wins) + ")" ) diff_list.append(name + ".Wins" + val_str) else: diff_list.append(name + ".Wins") # Filter ignore differences diff_list = list(filter(lambda x: x not in ignore_list, diff_list)) return diff_list
def __sizeof__(self): """Return the size in memory of the object (including all subobject)""" S = 0 # Full size of the object # Get size of the properties inherited from Conductor S += super(CondType21, self).__sizeof__() S += getsizeof(self.Hbar) S += getsizeof(self.Wbar) S += getsizeof(self.Wins) return S
[docs] def as_dict(self, type_handle_ndarray=0, keep_function=False, **kwargs): """ Convert this object in a json serializable dict (can be use in __init__). type_handle_ndarray: int How to handle ndarray (0: tolist, 1: copy, 2: nothing) keep_function : bool True to keep the function object, else return str Optional keyword input parameter is for internal use only and may prevent json serializability. """ # Get the properties inherited from Conductor CondType21_dict = super(CondType21, self).as_dict( type_handle_ndarray=type_handle_ndarray, keep_function=keep_function, **kwargs ) CondType21_dict["Hbar"] = self.Hbar CondType21_dict["Wbar"] = self.Wbar CondType21_dict["Wins"] = self.Wins # The class name is added to the dict for deserialisation purpose # Overwrite the mother class name CondType21_dict["__class__"] = "CondType21" return CondType21_dict
[docs] def copy(self): """Creates a deepcopy of the object""" # Handle deepcopy of all the properties Hbar_val = self.Hbar Wbar_val = self.Wbar Wins_val = self.Wins if self.cond_mat is None: cond_mat_val = None else: cond_mat_val = self.cond_mat.copy() if self.ins_mat is None: ins_mat_val = None else: ins_mat_val = self.ins_mat.copy() # Creates new object of the same type with the copied properties obj_copy = type(self)( Hbar=Hbar_val, Wbar=Wbar_val, Wins=Wins_val, cond_mat=cond_mat_val, ins_mat=ins_mat_val, ) return obj_copy
def _set_None(self): """Set all the properties to None (except pyleecan object)""" self.Hbar = None self.Wbar = None self.Wins = None # Set to None the properties inherited from Conductor super(CondType21, self)._set_None() def _get_Hbar(self): """getter of Hbar""" return self._Hbar def _set_Hbar(self, value): """setter of Hbar""" check_var("Hbar", value, "float", Vmin=0) self._Hbar = value Hbar = property( fget=_get_Hbar, fset=_set_Hbar, doc=u"""Bar height :Type: float :min: 0 """, ) def _get_Wbar(self): """getter of Wbar""" return self._Wbar def _set_Wbar(self, value): """setter of Wbar""" check_var("Wbar", value, "float", Vmin=0) self._Wbar = value Wbar = property( fget=_get_Wbar, fset=_set_Wbar, doc=u"""Bar width :Type: float :min: 0 """, ) def _get_Wins(self): """getter of Wins""" return self._Wins def _set_Wins(self, value): """setter of Wins""" check_var("Wins", value, "float", Vmin=0) self._Wins = value Wins = property( fget=_get_Wins, fset=_set_Wins, doc=u"""Width of insulation :Type: float :min: 0 """, )