# ##########################################################
# FlatCAM: 2D Post-processing for Manufacturing #
# File Author: Marius Adrian Stanciu (c) #
# Date: 3/10/2019 #
# MIT Licence #
# ##########################################################
from PyQt5 import QtWidgets, QtCore, QtGui
from appTool import AppTool
from appGUI.GUIElements import FCDoubleSpinner, EvalEntry, FCCheckBox, OptionalInputSection, FCEntry
from appGUI.GUIElements import FCTable, FCComboBox, RadioSet
from appEditors.AppTextEditor import AppTextEditor
from shapely.geometry import Point
from shapely.geometry.base import *
from shapely.affinity import scale, skew
import math
from datetime import datetime
import logging
from copy import deepcopy
import gettext
import appTranslation as fcTranslate
import builtins
fcTranslate.apply_language('strings')
if '_' not in builtins.__dict__:
_ = gettext.gettext
log = logging.getLogger('base')
class ToolCalibration(AppTool):
def __init__(self, app):
AppTool.__init__(self, app)
self.app = app
self.canvas = self.app.plotcanvas
self.decimals = self.app.decimals
# #############################################################################
# ######################### Tool GUI ##########################################
# #############################################################################
self.ui = CalibUI(layout=self.layout, app=self.app)
self.toolName = self.ui.toolName
self.mr = None
self.units = ''
# here store 4 points to be used for calibration
self.click_points = [[], [], [], []]
# store the status of the grid
self.grid_status_memory = None
self.target_obj = None
# if the mouse events are connected to a local method set this True
self.local_connected = False
# reference for the tab where to open and view the verification GCode
self.gcode_editor_tab = None
# calibrated object
self.cal_object = None
# ## Signals
self.ui.cal_source_radio.activated_custom.connect(self.on_cal_source_radio)
self.ui.obj_type_combo.currentIndexChanged.connect(self.on_obj_type_combo)
self.ui.adj_object_type_combo.currentIndexChanged.connect(self.on_adj_obj_type_combo)
self.ui.start_button.clicked.connect(self.on_start_collect_points)
self.ui.gcode_button.clicked.connect(self.generate_verification_gcode)
self.ui.adj_gcode_button.clicked.connect(self.generate_verification_gcode)
self.ui.generate_factors_button.clicked.connect(self.calculate_factors)
self.ui.scale_button.clicked.connect(self.on_scale_button)
self.ui.skew_button.clicked.connect(self.on_skew_button)
self.ui.cal_button.clicked.connect(self.on_cal_button_click)
self.ui.reset_button.clicked.connect(self.set_tool_ui)
def run(self, toggle=True):
self.app.defaults.report_usage("ToolCalibration()")
if toggle:
# if the splitter is hidden, display it, else hide it but only if the current widget is the same
if self.app.ui.splitter.sizes()[0] == 0:
self.app.ui.splitter.setSizes([1, 1])
else:
try:
if self.app.ui.tool_scroll_area.widget().objectName() == self.toolName:
# if tab is populated with the tool but it does not have the focus, focus on it
if not self.app.ui.notebook.currentWidget() is self.app.ui.tool_tab:
# focus on Tool Tab
self.app.ui.notebook.setCurrentWidget(self.app.ui.tool_tab)
else:
self.app.ui.splitter.setSizes([0, 1])
except AttributeError:
pass
else:
if self.app.ui.splitter.sizes()[0] == 0:
self.app.ui.splitter.setSizes([1, 1])
AppTool.run(self)
self.set_tool_ui()
self.app.ui.notebook.setTabText(2, _("Calibration Tool"))
def install(self, icon=None, separator=None, **kwargs):
AppTool.install(self, icon, separator, shortcut='Alt+E', **kwargs)
def set_tool_ui(self):
self.units = self.app.defaults['units'].upper()
if self.local_connected is True:
self.disconnect_cal_events()
self.ui.bottom_left_coordx_found.set_value(_("Origin"))
self.ui.bottom_left_coordy_found.set_value(_("Origin"))
self.reset_calibration_points()
self.ui.cal_source_radio.set_value(self.app.defaults['tools_cal_calsource'])
self.ui.travelz_entry.set_value(self.app.defaults['tools_cal_travelz'])
self.ui.verz_entry.set_value(self.app.defaults['tools_cal_verz'])
self.ui.zeroz_cb.set_value(self.app.defaults['tools_cal_zeroz'])
self.ui.toolchangez_entry.set_value(self.app.defaults['tools_cal_toolchangez'])
self.ui.toolchange_xy_entry.set_value(self.app.defaults['tools_cal_toolchange_xy'])
self.ui.second_point_radio.set_value(self.app.defaults['tools_cal_sec_point'])
self.ui.scalex_entry.set_value(1.0)
self.ui.scaley_entry.set_value(1.0)
self.ui.skewx_entry.set_value(0.0)
self.ui.skewy_entry.set_value(0.0)
# default object selection is Excellon = index_1
self.ui.obj_type_combo.setCurrentIndex(1)
self.on_obj_type_combo()
self.ui.adj_object_type_combo.setCurrentIndex(0)
self.on_adj_obj_type_combo()
# self.adj_object_combo.setCurrentIndex(0)
# calibrated object
self.cal_object = None
self.app.inform.emit('%s...' % _("Tool initialized"))
def on_obj_type_combo(self):
obj_type = self.ui.obj_type_combo.currentIndex()
self.ui.object_combo.setRootModelIndex(self.app.collection.index(obj_type, 0, QtCore.QModelIndex()))
# self.object_combo.setCurrentIndex(0)
self.ui.object_combo.obj_type = {
_("Gerber"): "Gerber", _("Excellon"): "Excellon"
}[self.ui.obj_type_combo.get_value()]
def on_adj_obj_type_combo(self):
obj_type = self.ui.adj_object_type_combo.currentIndex()
self.ui.adj_object_combo.setRootModelIndex(self.app.collection.index(obj_type, 0, QtCore.QModelIndex()))
# self.adj_object_combo.setCurrentIndex(0)
self.ui.adj_object_combo.obj_type = {
_("Gerber"): "Gerber", _("Excellon"): "Excellon", _("Geometry"): "Geometry"
}[self.ui.adj_object_type_combo.get_value()]
def on_cal_source_radio(self, val):
if val == 'object':
self.ui.obj_type_label.setDisabled(False)
self.ui.obj_type_combo.setDisabled(False)
self.ui.object_label.setDisabled(False)
self.ui.object_combo.setDisabled(False)
else:
self.ui.obj_type_label.setDisabled(True)
self.ui.obj_type_combo.setDisabled(True)
self.ui.object_label.setDisabled(True)
self.ui.object_combo.setDisabled(True)
def on_start_collect_points(self):
if self.ui.cal_source_radio.get_value() == 'object':
selection_index = self.ui.object_combo.currentIndex()
model_index = self.app.collection.index(selection_index, 0, self.ui.object_combo.rootModelIndex())
try:
self.target_obj = model_index.internalPointer().obj
except AttributeError:
self.app.inform.emit('[WARNING_NOTCL] %s' % _("There is no source FlatCAM object selected..."))
return
# disengage the grid snapping since it will be hard to find the drills on grid
if self.app.ui.grid_snap_btn.isChecked():
self.grid_status_memory = True
self.app.ui.grid_snap_btn.trigger()
else:
self.grid_status_memory = False
self.mr = self.canvas.graph_event_connect('mouse_release', self.on_mouse_click_release)
if self.app.is_legacy is False:
self.canvas.graph_event_disconnect('mouse_release', self.app.on_mouse_click_release_over_plot)
else:
self.canvas.graph_event_disconnect(self.app.mr)
self.local_connected = True
self.reset_calibration_points()
self.app.inform.emit(_("Get First calibration point. Bottom Left..."))
def on_mouse_click_release(self, event):
if self.app.is_legacy is False:
event_pos = event.pos
right_button = 2
self.app.event_is_dragging = self.app.event_is_dragging
else:
event_pos = (event.xdata, event.ydata)
right_button = 3
self.app.event_is_dragging = self.app.ui.popMenu.mouse_is_panning
pos_canvas = self.canvas.translate_coords(event_pos)
if event.button == 1:
click_pt = Point([pos_canvas[0], pos_canvas[1]])
if self.app.selection_type is not None:
# delete previous selection shape
self.app.delete_selection_shape()
self.app.selection_type = None
else:
if self.ui.cal_source_radio.get_value() == 'object':
if self.target_obj.kind.lower() == 'excellon':
for tool, tool_dict in self.target_obj.tools.items():
for geo in tool_dict['solid_geometry']:
if click_pt.within(geo):
center_pt = geo.centroid
self.click_points.append(
[
float('%.*f' % (self.decimals, center_pt.x)),
float('%.*f' % (self.decimals, center_pt.y))
]
)
self.check_points()
else:
for apid, apid_val in self.target_obj.apertures.items():
for geo_el in apid_val['geometry']:
if 'solid' in geo_el:
if click_pt.within(geo_el['solid']):
if isinstance(geo_el['follow'], Point):
center_pt = geo_el['solid'].centroid
self.click_points.append(
[
float('%.*f' % (self.decimals, center_pt.x)),
float('%.*f' % (self.decimals, center_pt.y))
]
)
self.check_points()
else:
self.click_points.append(
[
float('%.*f' % (self.decimals, click_pt.x)),
float('%.*f' % (self.decimals, click_pt.y))
]
)
self.check_points()
elif event.button == right_button and self.app.event_is_dragging is False:
if len(self.click_points) != 4:
self.reset_calibration_points()
self.disconnect_cal_events()
self.app.inform.emit('[WARNING_NOTCL] %s' % _("Cancelled by user request."))
def check_points(self):
if len(self.click_points) == 1:
self.ui.bottom_left_coordx_tgt.set_value(self.click_points[0][0])
self.ui.bottom_left_coordy_tgt.set_value(self.click_points[0][1])
self.app.inform.emit(_("Get Second calibration point. Bottom Right (Top Left)..."))
elif len(self.click_points) == 2:
self.ui.bottom_right_coordx_tgt.set_value(self.click_points[1][0])
self.ui.bottom_right_coordy_tgt.set_value(self.click_points[1][1])
self.app.inform.emit(_("Get Third calibration point. Top Left (Bottom Right)..."))
elif len(self.click_points) == 3:
self.ui.top_left_coordx_tgt.set_value(self.click_points[2][0])
self.ui.top_left_coordy_tgt.set_value(self.click_points[2][1])
self.app.inform.emit(_("Get Forth calibration point. Top Right..."))
elif len(self.click_points) == 4:
self.ui.top_right_coordx_tgt.set_value(self.click_points[3][0])
self.ui.top_right_coordy_tgt.set_value(self.click_points[3][1])
self.app.inform.emit('[success] %s' % _("Done."))
self.disconnect_cal_events()
def reset_calibration_points(self):
self.click_points = []
self.ui.bottom_left_coordx_tgt.set_value('')
self.ui.bottom_left_coordy_tgt.set_value('')
self.ui.bottom_right_coordx_tgt.set_value('')
self.ui.bottom_right_coordy_tgt.set_value('')
self.ui.top_left_coordx_tgt.set_value('')
self.ui.top_left_coordy_tgt.set_value('')
self.ui.top_right_coordx_tgt.set_value('')
self.ui.top_right_coordy_tgt.set_value('')
self.ui.bottom_right_coordx_found.set_value('')
self.ui.bottom_right_coordy_found.set_value('')
self.ui.top_left_coordx_found.set_value('')
self.ui.top_left_coordy_found.set_value('')
def gcode_header(self):
log.debug("ToolCalibration.gcode_header()")
time_str = "{:%A, %d %B %Y at %H:%M}".format(datetime.now())
gcode = '(G-CODE GENERATED BY FLATCAM v%s - www.flatcam.org - Version Date: %s)\n' % \
(str(self.app.version), str(self.app.version_date)) + '\n'
gcode += '(Name: ' + _('Verification GCode for FlatCAM Calibration Tool') + ')\n'
gcode += '(Units: ' + self.units.upper() + ')\n\n'
gcode += '(Created on ' + time_str + ')\n\n'
gcode += 'G20\n' if self.units.upper() == 'IN' else 'G21\n'
gcode += 'G90\n'
gcode += 'G17\n'
gcode += 'G94\n\n'
return gcode
def close_tab(self):
for idx in range(self.app.ui.plot_tab_area.count()):
if self.app.ui.plot_tab_area.tabText(idx) == _("Gcode Viewer"):
wdg = self.app.ui.plot_tab_area.widget(idx)
wdg.deleteLater()
self.app.ui.plot_tab_area.removeTab(idx)
def generate_verification_gcode(self):
sec_point = self.ui.second_point_radio.get_value()
travel_z = '%.*f' % (self.decimals, self.ui.travelz_entry.get_value())
toolchange_z = '%.*f' % (self.decimals, self.ui.toolchangez_entry.get_value())
toolchange_xy_temp = self.ui.toolchange_xy_entry.get_value().split(",")
toolchange_xy = [float(eval(a)) for a in toolchange_xy_temp if a != '']
verification_z = '%.*f' % (self.decimals, self.ui.verz_entry.get_value())
if len(self.click_points) != 4:
self.app.inform.emit('[WARNING_NOTCL] %s' % _("Cancelled. Four points are needed for GCode generation."))
return 'fail'
gcode = self.gcode_header()
if self.ui.zeroz_cb.get_value():
gcode += 'M5\n'
gcode += 'G00 Z%s\n' % toolchange_z
if toolchange_xy:
gcode += 'G00 X%s Y%s\n' % (toolchange_xy[0], toolchange_xy[1])
gcode += 'M0\n'
gcode += 'G01 Z0\n'
gcode += 'M0\n'
gcode += 'G00 Z%s\n' % toolchange_z
gcode += 'M0\n'
# first point: bottom - left -> ORIGIN set
gcode += 'G00 Z%s\n' % travel_z
gcode += 'G00 X%s Y%s\n' % (self.click_points[0][0], self.click_points[0][1])
gcode += 'G01 Z%s\n' % verification_z
gcode += 'M0\n'
if sec_point == 'tl':
# second point: top - left -> align the PCB to this point
gcode += 'G00 Z%s\n' % travel_z
gcode += 'G00 X%s Y%s\n' % (self.click_points[2][0], self.click_points[2][1])
gcode += 'G01 Z%s\n' % verification_z
gcode += 'M0\n'
# third point: bottom - right -> check for scale on X axis or for skew on Y axis
gcode += 'G00 Z%s\n' % travel_z
gcode += 'G00 X%s Y%s\n' % (self.click_points[1][0], self.click_points[1][1])
gcode += 'G01 Z%s\n' % verification_z
gcode += 'M0\n'
# forth point: top - right -> verification point
gcode += 'G00 Z%s\n' % travel_z
gcode += 'G00 X%s Y%s\n' % (self.click_points[3][0], self.click_points[3][1])
gcode += 'G01 Z%s\n' % verification_z
gcode += 'M0\n'
else:
# second point: bottom - right -> align the PCB to this point
gcode += 'G00 Z%s\n' % travel_z
gcode += 'G00 X%s Y%s\n' % (self.click_points[1][0], self.click_points[1][1])
gcode += 'G01 Z%s\n' % verification_z
gcode += 'M0\n'
# third point: top - left -> check for scale on Y axis or for skew on X axis
gcode += 'G00 Z%s\n' % travel_z
gcode += 'G00 X%s Y%s\n' % (self.click_points[2][0], self.click_points[2][1])
gcode += 'G01 Z%s\n' % verification_z
gcode += 'M0\n'
# forth point: top - right -> verification point
gcode += 'G00 Z%s\n' % travel_z
gcode += 'G00 X%s Y%s\n' % (self.click_points[3][0], self.click_points[3][1])
gcode += 'G01 Z%s\n' % verification_z
gcode += 'M0\n'
# return to (toolchange_xy[0], toolchange_xy[1], toolchange_z) point for toolchange event
gcode += 'G00 Z%s\n' % travel_z
gcode += 'G00 X0 Y0\n'
gcode += 'G00 Z%s\n' % toolchange_z
if toolchange_xy:
gcode += 'G00 X%s Y%s\n' % (toolchange_xy[0], toolchange_xy[1])
gcode += 'M2'
self.gcode_editor_tab = AppTextEditor(app=self.app, plain_text=True)
# add the tab if it was closed
self.app.ui.plot_tab_area.addTab(self.gcode_editor_tab, '%s' % _("Gcode Viewer"))
self.gcode_editor_tab.setObjectName('gcode_viewer_tab')
# delete the absolute and relative position and messages in the infobar
self.app.ui.position_label.setText("")
self.app.ui.rel_position_label.setText("")
self.gcode_editor_tab.code_editor.completer_enable = False
self.gcode_editor_tab.buttonRun.hide()
# Switch plot_area to CNCJob tab
self.app.ui.plot_tab_area.setCurrentWidget(self.gcode_editor_tab)
self.gcode_editor_tab.t_frame.hide()
# then append the text from GCode to the text editor
try:
self.gcode_editor_tab.load_text(gcode, move_to_start=True, clear_text=True)
except Exception as e:
self.app.inform.emit('[ERROR] %s %s' % ('ERROR -->', str(e)))
return
self.gcode_editor_tab.t_frame.show()
self.app.proc_container.view.set_idle()
self.app.inform.emit('[success] %s...' % _('Loaded Machine Code into Code Editor'))
_filter_ = "G-Code Files (*.nc);;All Files (*.*)"
self.gcode_editor_tab.buttonSave.clicked.disconnect()
self.gcode_editor_tab.buttonSave.clicked.connect(
lambda: self.gcode_editor_tab.handleSaveGCode(name='fc_ver_gcode', filt=_filter_, callback=self.close_tab))
def calculate_factors(self):
origin_x = self.click_points[0][0]
origin_y = self.click_points[0][1]
top_left_x = self.click_points[2][0]
top_left_y = self.click_points[2][1]
bot_right_x = self.click_points[1][0]
bot_right_y = self.click_points[1][1]
try:
top_left_dx = float(self.ui.top_left_coordx_found.get_value())
except TypeError:
top_left_dx = top_left_x
try:
top_left_dy = float(self.ui.top_left_coordy_found.get_value())
except TypeError:
top_left_dy = top_left_y
try:
bot_right_dx = float(self.ui.bottom_right_coordx_found.get_value())
except TypeError:
bot_right_dx = bot_right_x
try:
bot_right_dy = float(self.ui.bottom_right_coordy_found.get_value())
except TypeError:
bot_right_dy = bot_right_y
# ------------------------------------------------------------------------------- #
# --------------------------- FACTORS CALCULUS ---------------------------------- #
# ------------------------------------------------------------------------------- #
if bot_right_dx != float('%.*f' % (self.decimals, bot_right_x)):
# we have scale on X
scale_x = (bot_right_dx / (bot_right_x - origin_x)) + 1
self.ui.scalex_entry.set_value(scale_x)
if top_left_dy != float('%.*f' % (self.decimals, top_left_y)):
# we have scale on Y
scale_y = (top_left_dy / (top_left_y - origin_y)) + 1
self.ui.scaley_entry.set_value(scale_y)
if top_left_dx != float('%.*f' % (self.decimals, top_left_x)):
# we have skew on X
dx = top_left_dx
dy = top_left_y - origin_y
skew_angle_x = math.degrees(math.atan(dx / dy))
self.ui.skewx_entry.set_value(skew_angle_x)
if bot_right_dy != float('%.*f' % (self.decimals, bot_right_y)):
# we have skew on Y
dx = bot_right_x - origin_x
dy = bot_right_dy + origin_y
skew_angle_y = math.degrees(math.atan(dy / dx))
self.ui.skewy_entry.set_value(skew_angle_y)
@property
def target_values_in_table(self):
self.click_points[0][0] = self.ui.bottom_left_coordx_tgt.get_value()
self.click_points[0][1] = self.ui.bottom_left_coordy_tgt.get_value()
self.click_points[1][0] = self.ui.bottom_right_coordx_tgt.get_value()
self.click_points[1][1] = self.ui.bottom_right_coordy_tgt.get_value()
self.click_points[2][0] = self.ui.top_left_coordx_tgt.get_value()
self.click_points[2][1] = self.ui.top_left_coordy_tgt.get_value()
self.click_points[3][0] = self.ui.top_right_coordx_tgt.get_value()
self.click_points[3][1] = self.ui.top_right_coordy_tgt.get_value()
return self.click_points
@target_values_in_table.setter
def target_values_in_table(self, param):
bl_pt, br_pt, tl_pt, tr_pt = param
self.click_points[0] = [bl_pt[0], bl_pt[1]]
self.click_points[1] = [br_pt[0], br_pt[1]]
self.click_points[2] = [tl_pt[0], tl_pt[1]]
self.click_points[3] = [tr_pt[0], tr_pt[1]]
self.ui.bottom_left_coordx_tgt.set_value(float('%.*f' % (self.decimals, bl_pt[0])))
self.ui.bottom_left_coordy_tgt.set_value(float('%.*f' % (self.decimals, bl_pt[1])))
self.ui.bottom_right_coordx_tgt.set_value(float('%.*f' % (self.decimals, br_pt[0])))
self.ui.bottom_right_coordy_tgt.set_value(float('%.*f' % (self.decimals, br_pt[1])))
self.ui.top_left_coordx_tgt.set_value(float('%.*f' % (self.decimals, tl_pt[0])))
self.ui.top_left_coordy_tgt.set_value(float('%.*f' % (self.decimals, tl_pt[1])))
self.ui.top_right_coordx_tgt.set_value(float('%.*f' % (self.decimals, tr_pt[0])))
self.ui.top_right_coordy_tgt.set_value(float('%.*f' % (self.decimals, tr_pt[1])))
def on_scale_button(self):
scalex_fact = self.ui.scalex_entry.get_value()
scaley_fact = self.ui.scaley_entry.get_value()
bl, br, tl, tr = self.target_values_in_table
bl_geo = Point(bl[0], bl[1])
br_geo = Point(br[0], br[1])
tl_geo = Point(tl[0], tl[1])
tr_geo = Point(tr[0], tr[1])
bl_scaled = scale(bl_geo, xfact=scalex_fact, yfact=scaley_fact, origin=(bl[0], bl[1]))
br_scaled = scale(br_geo, xfact=scalex_fact, yfact=scaley_fact, origin=(bl[0], bl[1]))
tl_scaled = scale(tl_geo, xfact=scalex_fact, yfact=scaley_fact, origin=(bl[0], bl[1]))
tr_scaled = scale(tr_geo, xfact=scalex_fact, yfact=scaley_fact, origin=(bl[0], bl[1]))
scaled_values = [
[bl_scaled.x, bl_scaled.y],
[br_scaled.x, br_scaled.y],
[tl_scaled.x, tl_scaled.y],
[tr_scaled.x, tr_scaled.y]
]
self.target_values_in_table = scaled_values
def on_skew_button(self):
skewx_angle = self.ui.skewx_entry.get_value()
skewy_angle = self.ui.skewy_entry.get_value()
bl, br, tl, tr = self.target_values_in_table
bl_geo = Point(bl[0], bl[1])
br_geo = Point(br[0], br[1])
tl_geo = Point(tl[0], tl[1])
tr_geo = Point(tr[0], tr[1])
bl_skewed = skew(bl_geo, xs=skewx_angle, ys=skewy_angle, origin=(bl[0], bl[1]))
br_skewed = skew(br_geo, xs=skewx_angle, ys=skewy_angle, origin=(bl[0], bl[1]))
tl_skewed = skew(tl_geo, xs=skewx_angle, ys=skewy_angle, origin=(bl[0], bl[1]))
tr_skewed = skew(tr_geo, xs=skewx_angle, ys=skewy_angle, origin=(bl[0], bl[1]))
skewed_values = [
[bl_skewed.x, bl_skewed.y],
[br_skewed.x, br_skewed.y],
[tl_skewed.x, tl_skewed.y],
[tr_skewed.x, tr_skewed.y]
]
self.target_values_in_table = skewed_values
def on_cal_button_click(self):
# get the FlatCAM object to calibrate
selection_index = self.ui.adj_object_combo.currentIndex()
model_index = self.app.collection.index(selection_index, 0, self.ui.adj_object_combo.rootModelIndex())
try:
self.cal_object = model_index.internalPointer().obj
except Exception as e:
log.debug("ToolCalibration.on_cal_button_click() --> %s" % str(e))
self.app.inform.emit('[WARNING_NOTCL] %s' % _("There is no FlatCAM object selected..."))
return 'fail'
obj_name = self.cal_object.options["name"] + "_calibrated"
self.app.worker_task.emit({'fcn': self.new_calibrated_object, 'params': [obj_name]})
def new_calibrated_object(self, obj_name):
try:
origin_x = self.click_points[0][0]
origin_y = self.click_points[0][1]
except IndexError as e:
log.debug("ToolCalibration.new_calibrated_object() --> %s" % str(e))
return 'fail'
scalex = self.ui.scalex_entry.get_value()
scaley = self.ui.scaley_entry.get_value()
skewx = self.ui.skewx_entry.get_value()
skewy = self.ui.skewy_entry.get_value()
# create a new object adjusted (calibrated)
def initialize_geometry(obj_init, app):
obj_init.solid_geometry = deepcopy(obj.solid_geometry)
try:
obj_init.follow_geometry = deepcopy(obj.follow_geometry)
except AttributeError:
pass
try:
obj_init.apertures = deepcopy(obj.apertures)
except AttributeError:
pass
try:
if obj.tools:
obj_init.tools = deepcopy(obj.tools)
except Exception as ee:
app.log.debug("ToolCalibration.new_calibrated_object.initialize_geometry() --> %s" % str(ee))
obj_init.scale(xfactor=scalex, yfactor=scaley, point=(origin_x, origin_y))
obj_init.skew(angle_x=skewx, angle_y=skewy, point=(origin_x, origin_y))
try:
obj_init.source_file = deepcopy(obj.source_file)
except (AttributeError, TypeError):
pass
def initialize_gerber(obj_init, app_obj):
obj_init.solid_geometry = deepcopy(obj.solid_geometry)
try:
obj_init.follow_geometry = deepcopy(obj.follow_geometry)
except AttributeError:
pass
try:
obj_init.apertures = deepcopy(obj.apertures)
except AttributeError:
pass
try:
if obj.tools:
obj_init.tools = deepcopy(obj.tools)
except Exception as err:
log.debug("ToolCalibration.new_calibrated_object.initialize_gerber() --> %s" % str(err))
obj_init.scale(xfactor=scalex, yfactor=scaley, point=(origin_x, origin_y))
obj_init.skew(angle_x=skewx, angle_y=skewy, point=(origin_x, origin_y))
try:
obj_init.source_file = app_obj.f_handlers.export_gerber(obj_name=obj_name, filename=None,
local_use=obj_init, use_thread=False)
except (AttributeError, TypeError):
pass
def initialize_excellon(obj_init, app_obj):
obj_init.tools = deepcopy(obj.tools)
# drills are offset, so they need to be deep copied
obj_init.drills = deepcopy(obj.drills)
# slots are offset, so they need to be deep copied
obj_init.slots = deepcopy(obj.slots)
obj_init.scale(xfactor=scalex, yfactor=scaley, point=(origin_x, origin_y))
obj_init.skew(angle_x=skewx, angle_y=skewy, point=(origin_x, origin_y))
obj_init.create_geometry()
obj_init.source_file = app_obj.f_handlers.export_excellon(obj_name=obj_name, local_use=obj, filename=None,
use_thread=False)
obj = self.cal_object
obj_name = obj_name
if obj is None:
self.app.inform.emit('[WARNING_NOTCL] %s' % _("There is no FlatCAM object selected..."))
log.debug("ToolCalibration.new_calibrated_object() --> No object to calibrate")
return 'fail'
try:
if obj.kind.lower() == 'excellon':
self.app.app_obj.new_object("excellon", str(obj_name), initialize_excellon)
elif obj.kind.lower() == 'gerber':
self.app.app_obj.new_object("gerber", str(obj_name), initialize_gerber)
elif obj.kind.lower() == 'geometry':
self.app.app_obj.new_object("geometry", str(obj_name), initialize_geometry)
except Exception as e:
log.debug("ToolCalibration.new_calibrated_object() --> %s" % str(e))
return "Operation failed: %s" % str(e)
def disconnect_cal_events(self):
# restore the Grid snapping if it was active before
if self.grid_status_memory is True:
self.app.ui.grid_snap_btn.trigger()
self.app.mr = self.canvas.graph_event_connect('mouse_release', self.app.on_mouse_click_release_over_plot)
if self.app.is_legacy is False:
self.canvas.graph_event_disconnect('mouse_release', self.on_mouse_click_release)
else:
self.canvas.graph_event_disconnect(self.mr)
self.local_connected = False
def reset_fields(self):
self.ui.object_combo.setRootModelIndex(self.app.collection.index(0, 0, QtCore.QModelIndex()))
self.ui.adj_object_combo.setRootModelIndex(self.app.collection.index(0, 0, QtCore.QModelIndex()))
class CalibUI:
toolName = _("Calibration Tool")
def __init__(self, layout, app):
self.app = app
self.decimals = self.app.decimals
self.layout = layout
# ## Title
title_label = QtWidgets.QLabel("%s" % self.toolName)
title_label.setStyleSheet("""
QLabel
{
font-size: 16px;
font-weight: bold;
}
""")
self.layout.addWidget(title_label)
self.layout.addWidget(QtWidgets.QLabel(""))
# ## Grid Layout
grid_lay = QtWidgets.QGridLayout()
self.layout.addLayout(grid_lay)
grid_lay.setColumnStretch(0, 0)
grid_lay.setColumnStretch(1, 1)
grid_lay.setColumnStretch(2, 0)
self.gcode_title_label = QtWidgets.QLabel('%s:' % _('Parameters'))
self.gcode_title_label.setToolTip(
_("Parameters used when creating the GCode in this tool.")
)
grid_lay.addWidget(self.gcode_title_label, 0, 0, 1, 3)
# Travel Z entry
travelz_lbl = QtWidgets.QLabel('%s:' % _("Travel Z"))
travelz_lbl.setToolTip(
_("Height (Z) for travelling between the points.")
)
self.travelz_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.travelz_entry.set_range(-10000.0000, 10000.0000)
self.travelz_entry.set_precision(self.decimals)
self.travelz_entry.setSingleStep(0.1)
grid_lay.addWidget(travelz_lbl, 1, 0)
grid_lay.addWidget(self.travelz_entry, 1, 1, 1, 2)
# Verification Z entry
verz_lbl = QtWidgets.QLabel('%s:' % _("Verification Z"))
verz_lbl.setToolTip(
_("Height (Z) for checking the point.")
)
self.verz_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.verz_entry.set_range(-10000.0000, 10000.0000)
self.verz_entry.set_precision(self.decimals)
self.verz_entry.setSingleStep(0.1)
grid_lay.addWidget(verz_lbl, 2, 0)
grid_lay.addWidget(self.verz_entry, 2, 1, 1, 2)
# Zero the Z of the verification tool
self.zeroz_cb = FCCheckBox('%s' % _("Zero Z tool"))
self.zeroz_cb.setToolTip(
_("Include a sequence to zero the height (Z)\n"
"of the verification tool.")
)
grid_lay.addWidget(self.zeroz_cb, 3, 0, 1, 3)
# Toolchange Z entry
toolchangez_lbl = QtWidgets.QLabel('%s:' % _("Toolchange Z"))
toolchangez_lbl.setToolTip(
_("Height (Z) for mounting the verification probe.")
)
self.toolchangez_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.toolchangez_entry.set_range(0.0000, 10000.0000)
self.toolchangez_entry.set_precision(self.decimals)
self.toolchangez_entry.setSingleStep(0.1)
grid_lay.addWidget(toolchangez_lbl, 4, 0)
grid_lay.addWidget(self.toolchangez_entry, 4, 1, 1, 2)
# Toolchange X-Y entry
toolchangexy_lbl = QtWidgets.QLabel('%s:' % _('Toolchange X-Y'))
toolchangexy_lbl.setToolTip(
_("Toolchange X,Y position.\n"
"If no value is entered then the current\n"
"(x, y) point will be used,")
)
self.toolchange_xy_entry = FCEntry()
grid_lay.addWidget(toolchangexy_lbl, 5, 0)
grid_lay.addWidget(self.toolchange_xy_entry, 5, 1, 1, 2)
self.z_ois = OptionalInputSection(
self.zeroz_cb,
[
toolchangez_lbl,
self.toolchangez_entry,
toolchangexy_lbl,
self.toolchange_xy_entry
]
)
separator_line1 = QtWidgets.QFrame()
separator_line1.setFrameShape(QtWidgets.QFrame.HLine)
separator_line1.setFrameShadow(QtWidgets.QFrame.Sunken)
grid_lay.addWidget(separator_line1, 6, 0, 1, 3)
# Second point choice
second_point_lbl = QtWidgets.QLabel('%s:' % _("Second point"))
second_point_lbl.setToolTip(
_("Second point in the Gcode verification can be:\n"
"- top-left -> the user will align the PCB vertically\n"
"- bottom-right -> the user will align the PCB horizontally")
)
self.second_point_radio = RadioSet([{'label': _('Top Left'), 'value': 'tl'},
{'label': _('Bottom Right'), 'value': 'br'}],
orientation='vertical')
grid_lay.addWidget(second_point_lbl, 7, 0)
grid_lay.addWidget(self.second_point_radio, 7, 1, 1, 2)
separator_line1 = QtWidgets.QFrame()
separator_line1.setFrameShape(QtWidgets.QFrame.HLine)
separator_line1.setFrameShadow(QtWidgets.QFrame.Sunken)
grid_lay.addWidget(separator_line1, 8, 0, 1, 3)
grid_lay.addWidget(QtWidgets.QLabel(''), 9, 0, 1, 3)
step_1 = QtWidgets.QLabel('%s' % _("STEP 1: Acquire Calibration Points"))
step_1.setToolTip(
_("Pick four points by clicking on canvas.\n"
"Those four points should be in the four\n"
"(as much as possible) corners of the object.")
)
grid_lay.addWidget(step_1, 10, 0, 1, 3)
self.cal_source_lbl = QtWidgets.QLabel("%s:" % _("Source Type"))
self.cal_source_lbl.setToolTip(_("The source of calibration points.\n"
"It can be:\n"
"- Object -> click a hole geo for Excellon or a pad for Gerber\n"
"- Free -> click freely on canvas to acquire the calibration points"))
self.cal_source_radio = RadioSet([{'label': _('Object'), 'value': 'object'},
{'label': _('Free'), 'value': 'free'}],
stretch=False)
grid_lay.addWidget(self.cal_source_lbl, 11, 0)
grid_lay.addWidget(self.cal_source_radio, 11, 1, 1, 2)
self.obj_type_label = QtWidgets.QLabel("%s:" % _("Object Type"))
self.obj_type_combo = FCComboBox()
self.obj_type_combo.addItem(_("Gerber"))
self.obj_type_combo.addItem(_("Excellon"))
self.obj_type_combo.setItemIcon(0, QtGui.QIcon(self.app.resource_location + "/flatcam_icon16.png"))
self.obj_type_combo.setItemIcon(1, QtGui.QIcon(self.app.resource_location + "/drill16.png"))
grid_lay.addWidget(self.obj_type_label, 12, 0)
grid_lay.addWidget(self.obj_type_combo, 12, 1, 1, 2)
self.object_combo = FCComboBox()
self.object_combo.setModel(self.app.collection)
self.object_combo.setRootModelIndex(self.app.collection.index(1, 0, QtCore.QModelIndex()))
self.object_combo.is_last = True
self.object_label = QtWidgets.QLabel("%s:" % _("Source object selection"))
self.object_label.setToolTip(
_("FlatCAM Object to be used as a source for reference points.")
)
grid_lay.addWidget(self.object_label, 13, 0, 1, 3)
grid_lay.addWidget(self.object_combo, 14, 0, 1, 3)
self.points_table_label = QtWidgets.QLabel('%s' % _('Calibration Points'))
self.points_table_label.setToolTip(
_("Contain the expected calibration points and the\n"
"ones measured.")
)
grid_lay.addWidget(self.points_table_label, 15, 0, 1, 3)
self.points_table = FCTable()
self.points_table.setSelectionBehavior(QtWidgets.QAbstractItemView.SelectRows)
# self.points_table.setSizeAdjustPolicy(QtWidgets.QAbstractScrollArea.AdjustToContents)
grid_lay.addWidget(self.points_table, 16, 0, 1, 3)
self.points_table.setColumnCount(4)
self.points_table.setHorizontalHeaderLabels(
[
'#',
_("Name"),
_("Target"),
_("Found Delta")
]
)
self.points_table.setRowCount(8)
row = 0
# BOTTOM LEFT
id_item_1 = QtWidgets.QTableWidgetItem('%d' % 1)
flags = QtCore.Qt.ItemIsEnabled
id_item_1.setFlags(flags)
self.points_table.setItem(row, 0, id_item_1) # Tool name/id
self.bottom_left_coordx_lbl = QtWidgets.QLabel('%s' % _('Bot Left X'))
self.points_table.setCellWidget(row, 1, self.bottom_left_coordx_lbl)
self.bottom_left_coordx_tgt = EvalEntry()
self.points_table.setCellWidget(row, 2, self.bottom_left_coordx_tgt)
self.bottom_left_coordx_tgt.setReadOnly(True)
self.bottom_left_coordx_found = EvalEntry()
self.points_table.setCellWidget(row, 3, self.bottom_left_coordx_found)
row += 1
self.bottom_left_coordy_lbl = QtWidgets.QLabel('%s' % _('Bot Left Y'))
self.points_table.setCellWidget(row, 1, self.bottom_left_coordy_lbl)
self.bottom_left_coordy_tgt = EvalEntry()
self.points_table.setCellWidget(row, 2, self.bottom_left_coordy_tgt)
self.bottom_left_coordy_tgt.setReadOnly(True)
self.bottom_left_coordy_found = EvalEntry()
self.points_table.setCellWidget(row, 3, self.bottom_left_coordy_found)
self.bottom_left_coordx_found.setDisabled(True)
self.bottom_left_coordy_found.setDisabled(True)
row += 1
# BOTTOM RIGHT
id_item_2 = QtWidgets.QTableWidgetItem('%d' % 2)
flags = QtCore.Qt.ItemIsEnabled
id_item_2.setFlags(flags)
self.points_table.setItem(row, 0, id_item_2) # Tool name/id
self.bottom_right_coordx_lbl = QtWidgets.QLabel('%s' % _('Bot Right X'))
self.points_table.setCellWidget(row, 1, self.bottom_right_coordx_lbl)
self.bottom_right_coordx_tgt = EvalEntry()
self.points_table.setCellWidget(row, 2, self.bottom_right_coordx_tgt)
self.bottom_right_coordx_tgt.setReadOnly(True)
self.bottom_right_coordx_found = EvalEntry()
self.points_table.setCellWidget(row, 3, self.bottom_right_coordx_found)
row += 1
self.bottom_right_coordy_lbl = QtWidgets.QLabel('%s' % _('Bot Right Y'))
self.points_table.setCellWidget(row, 1, self.bottom_right_coordy_lbl)
self.bottom_right_coordy_tgt = EvalEntry()
self.points_table.setCellWidget(row, 2, self.bottom_right_coordy_tgt)
self.bottom_right_coordy_tgt.setReadOnly(True)
self.bottom_right_coordy_found = EvalEntry()
self.points_table.setCellWidget(row, 3, self.bottom_right_coordy_found)
row += 1
# TOP LEFT
id_item_3 = QtWidgets.QTableWidgetItem('%d' % 3)
flags = QtCore.Qt.ItemIsEnabled
id_item_3.setFlags(flags)
self.points_table.setItem(row, 0, id_item_3) # Tool name/id
self.top_left_coordx_lbl = QtWidgets.QLabel('%s' % _('Top Left X'))
self.points_table.setCellWidget(row, 1, self.top_left_coordx_lbl)
self.top_left_coordx_tgt = EvalEntry()
self.points_table.setCellWidget(row, 2, self.top_left_coordx_tgt)
self.top_left_coordx_tgt.setReadOnly(True)
self.top_left_coordx_found = EvalEntry()
self.points_table.setCellWidget(row, 3, self.top_left_coordx_found)
row += 1
self.top_left_coordy_lbl = QtWidgets.QLabel('%s' % _('Top Left Y'))
self.points_table.setCellWidget(row, 1, self.top_left_coordy_lbl)
self.top_left_coordy_tgt = EvalEntry()
self.points_table.setCellWidget(row, 2, self.top_left_coordy_tgt)
self.top_left_coordy_tgt.setReadOnly(True)
self.top_left_coordy_found = EvalEntry()
self.points_table.setCellWidget(row, 3, self.top_left_coordy_found)
row += 1
# TOP RIGHT
id_item_4 = QtWidgets.QTableWidgetItem('%d' % 4)
flags = QtCore.Qt.ItemIsEnabled
id_item_4.setFlags(flags)
self.points_table.setItem(row, 0, id_item_4) # Tool name/id
self.top_right_coordx_lbl = QtWidgets.QLabel('%s' % _('Top Right X'))
self.points_table.setCellWidget(row, 1, self.top_right_coordx_lbl)
self.top_right_coordx_tgt = EvalEntry()
self.points_table.setCellWidget(row, 2, self.top_right_coordx_tgt)
self.top_right_coordx_tgt.setReadOnly(True)
self.top_right_coordx_found = EvalEntry()
self.top_right_coordx_found.setDisabled(True)
self.points_table.setCellWidget(row, 3, self.top_right_coordx_found)
row += 1
self.top_right_coordy_lbl = QtWidgets.QLabel('%s' % _('Top Right Y'))
self.points_table.setCellWidget(row, 1, self.top_right_coordy_lbl)
self.top_right_coordy_tgt = EvalEntry()
self.points_table.setCellWidget(row, 2, self.top_right_coordy_tgt)
self.top_right_coordy_tgt.setReadOnly(True)
self.top_right_coordy_found = EvalEntry()
self.top_right_coordy_found.setDisabled(True)
self.points_table.setCellWidget(row, 3, self.top_right_coordy_found)
vertical_header = self.points_table.verticalHeader()
vertical_header.hide()
self.points_table.setVerticalScrollBarPolicy(QtCore.Qt.ScrollBarAlwaysOff)
horizontal_header = self.points_table.horizontalHeader()
horizontal_header.setMinimumSectionSize(10)
horizontal_header.setDefaultSectionSize(70)
self.points_table.setSizeAdjustPolicy(QtWidgets.QAbstractScrollArea.AdjustToContents)
# for x in range(4):
# self.points_table.resizeColumnToContents(x)
self.points_table.resizeColumnsToContents()
self.points_table.resizeRowsToContents()
horizontal_header.setSectionResizeMode(0, QtWidgets.QHeaderView.Fixed)
horizontal_header.resizeSection(0, 20)
horizontal_header.setSectionResizeMode(1, QtWidgets.QHeaderView.Fixed)
horizontal_header.setSectionResizeMode(2, QtWidgets.QHeaderView.Stretch)
horizontal_header.setSectionResizeMode(3, QtWidgets.QHeaderView.Stretch)
self.points_table.setMinimumHeight(self.points_table.getHeight() + 2)
self.points_table.setMaximumHeight(self.points_table.getHeight() + 3)
# ## Get Points Button
self.start_button = QtWidgets.QPushButton(_("Get Points"))
self.start_button.setToolTip(
_("Pick four points by clicking on canvas if the source choice\n"
"is 'free' or inside the object geometry if the source is 'object'.\n"
"Those four points should be in the four squares of\n"
"the object.")
)
self.start_button.setStyleSheet("""
QPushButton
{
font-weight: bold;
}
""")
grid_lay.addWidget(self.start_button, 17, 0, 1, 3)
separator_line = QtWidgets.QFrame()
separator_line.setFrameShape(QtWidgets.QFrame.HLine)
separator_line.setFrameShadow(QtWidgets.QFrame.Sunken)
grid_lay.addWidget(separator_line, 18, 0, 1, 3)
grid_lay.addWidget(QtWidgets.QLabel(''), 19, 0)
# STEP 2 #
step_2 = QtWidgets.QLabel('%s' % _("STEP 2: Verification GCode"))
step_2.setToolTip(
_("Generate GCode file to locate and align the PCB by using\n"
"the four points acquired above.\n"
"The points sequence is:\n"
"- first point -> set the origin\n"
"- second point -> alignment point. Can be: top-left or bottom-right.\n"
"- third point -> check point. Can be: top-left or bottom-right.\n"
"- forth point -> final verification point. Just for evaluation.")
)
grid_lay.addWidget(step_2, 20, 0, 1, 3)
# ## GCode Button
self.gcode_button = QtWidgets.QPushButton(_("Generate GCode"))
self.gcode_button.setToolTip(
_("Generate GCode file to locate and align the PCB by using\n"
"the four points acquired above.\n"
"The points sequence is:\n"
"- first point -> set the origin\n"
"- second point -> alignment point. Can be: top-left or bottom-right.\n"
"- third point -> check point. Can be: top-left or bottom-right.\n"
"- forth point -> final verification point. Just for evaluation.")
)
self.gcode_button.setStyleSheet("""
QPushButton
{
font-weight: bold;
}
""")
grid_lay.addWidget(self.gcode_button, 21, 0, 1, 3)
separator_line1 = QtWidgets.QFrame()
separator_line1.setFrameShape(QtWidgets.QFrame.HLine)
separator_line1.setFrameShadow(QtWidgets.QFrame.Sunken)
grid_lay.addWidget(separator_line1, 22, 0, 1, 3)
grid_lay.addWidget(QtWidgets.QLabel(''), 23, 0, 1, 3)
# STEP 3 #
step_3 = QtWidgets.QLabel('%s' % _("STEP 3: Adjustments"))
step_3.setToolTip(
_("Calculate Scale and Skew factors based on the differences (delta)\n"
"found when checking the PCB pattern. The differences must be filled\n"
"in the fields Found (Delta).")
)
grid_lay.addWidget(step_3, 24, 0, 1, 3)
# ## Factors Button
self.generate_factors_button = QtWidgets.QPushButton(_("Calculate Factors"))
self.generate_factors_button.setToolTip(
_("Calculate Scale and Skew factors based on the differences (delta)\n"
"found when checking the PCB pattern. The differences must be filled\n"
"in the fields Found (Delta).")
)
self.generate_factors_button.setStyleSheet("""
QPushButton
{
font-weight: bold;
}
""")
grid_lay.addWidget(self.generate_factors_button, 25, 0, 1, 3)
separator_line1 = QtWidgets.QFrame()
separator_line1.setFrameShape(QtWidgets.QFrame.HLine)
separator_line1.setFrameShadow(QtWidgets.QFrame.Sunken)
grid_lay.addWidget(separator_line1, 26, 0, 1, 3)
grid_lay.addWidget(QtWidgets.QLabel(''), 27, 0, 1, 3)
# STEP 4 #
step_4 = QtWidgets.QLabel('%s' % _("STEP 4: Adjusted GCode"))
step_4.setToolTip(
_("Generate verification GCode file adjusted with\n"
"the factors above.")
)
grid_lay.addWidget(step_4, 28, 0, 1, 3)
self.scalex_label = QtWidgets.QLabel(_("Scale Factor X:"))
self.scalex_label.setToolTip(
_("Factor for Scale action over X axis.")
)
self.scalex_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.scalex_entry.set_range(0, 10000.0000)
self.scalex_entry.set_precision(self.decimals)
self.scalex_entry.setSingleStep(0.1)
grid_lay.addWidget(self.scalex_label, 29, 0)
grid_lay.addWidget(self.scalex_entry, 29, 1, 1, 2)
self.scaley_label = QtWidgets.QLabel(_("Scale Factor Y:"))
self.scaley_label.setToolTip(
_("Factor for Scale action over Y axis.")
)
self.scaley_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.scaley_entry.set_range(0, 10000.0000)
self.scaley_entry.set_precision(self.decimals)
self.scaley_entry.setSingleStep(0.1)
grid_lay.addWidget(self.scaley_label, 30, 0)
grid_lay.addWidget(self.scaley_entry, 30, 1, 1, 2)
self.scale_button = QtWidgets.QPushButton(_("Apply Scale Factors"))
self.scale_button.setToolTip(
_("Apply Scale factors on the calibration points.")
)
self.scale_button.setStyleSheet("""
QPushButton
{
font-weight: bold;
}
""")
grid_lay.addWidget(self.scale_button, 31, 0, 1, 3)
self.skewx_label = QtWidgets.QLabel(_("Skew Angle X:"))
self.skewx_label.setToolTip(
_("Angle, in degrees.\n"
"Float number between -360 and 359.")
)
self.skewx_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.skewx_entry.set_range(-360, 360)
self.skewx_entry.set_precision(self.decimals)
self.skewx_entry.setSingleStep(0.1)
grid_lay.addWidget(self.skewx_label, 32, 0)
grid_lay.addWidget(self.skewx_entry, 32, 1, 1, 2)
self.skewy_label = QtWidgets.QLabel(_("Skew Angle Y:"))
self.skewy_label.setToolTip(
_("Angle, in degrees.\n"
"Float number between -360 and 359.")
)
self.skewy_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.skewy_entry.set_range(-360, 360)
self.skewy_entry.set_precision(self.decimals)
self.skewy_entry.setSingleStep(0.1)
grid_lay.addWidget(self.skewy_label, 33, 0)
grid_lay.addWidget(self.skewy_entry, 33, 1, 1, 2)
self.skew_button = QtWidgets.QPushButton(_("Apply Skew Factors"))
self.skew_button.setToolTip(
_("Apply Skew factors on the calibration points.")
)
self.skew_button.setStyleSheet("""
QPushButton
{
font-weight: bold;
}
""")
grid_lay.addWidget(self.skew_button, 34, 0, 1, 3)
# final_factors_lbl = QtWidgets.QLabel('%s' % _("Final Factors"))
# final_factors_lbl.setToolTip(
# _("Generate verification GCode file adjusted with\n"
# "the factors above.")
# )
# grid_lay.addWidget(final_factors_lbl, 27, 0, 1, 3)
#
# self.fin_scalex_label = QtWidgets.QLabel(_("Scale Factor X:"))
# self.fin_scalex_label.setToolTip(
# _("Final factor for Scale action over X axis.")
# )
# self.fin_scalex_entry = FCDoubleSpinner(callback=self.confirmation_message)
# self.fin_scalex_entry.set_range(0, 10000.0000)
# self.fin_scalex_entry.set_precision(self.decimals)
# self.fin_scalex_entry.setSingleStep(0.1)
#
# grid_lay.addWidget(self.fin_scalex_label, 28, 0)
# grid_lay.addWidget(self.fin_scalex_entry, 28, 1, 1, 2)
#
# self.fin_scaley_label = QtWidgets.QLabel(_("Scale Factor Y:"))
# self.fin_scaley_label.setToolTip(
# _("Final factor for Scale action over Y axis.")
# )
# self.fin_scaley_entry = FCDoubleSpinner(callback=self.confirmation_message)
# self.fin_scaley_entry.set_range(0, 10000.0000)
# self.fin_scaley_entry.set_precision(self.decimals)
# self.fin_scaley_entry.setSingleStep(0.1)
#
# grid_lay.addWidget(self.fin_scaley_label, 29, 0)
# grid_lay.addWidget(self.fin_scaley_entry, 29, 1, 1, 2)
#
# self.fin_skewx_label = QtWidgets.QLabel(_("Skew Angle X:"))
# self.fin_skewx_label.setToolTip(
# _("Final value for angle for Skew action, in degrees.\n"
# "Float number between -360 and 359.")
# )
# self.fin_skewx_entry = FCDoubleSpinner(callback=self.confirmation_message)
# self.fin_skewx_entry.set_range(-360, 360)
# self.fin_skewx_entry.set_precision(self.decimals)
# self.fin_skewx_entry.setSingleStep(0.1)
#
# grid_lay.addWidget(self.fin_skewx_label, 30, 0)
# grid_lay.addWidget(self.fin_skewx_entry, 30, 1, 1, 2)
#
# self.fin_skewy_label = QtWidgets.QLabel(_("Skew Angle Y:"))
# self.fin_skewy_label.setToolTip(
# _("Final value for angle for Skew action, in degrees.\n"
# "Float number between -360 and 359.")
# )
# self.fin_skewy_entry = FCDoubleSpinner(callback=self.confirmation_message)
# self.fin_skewy_entry.set_range(-360, 360)
# self.fin_skewy_entry.set_precision(self.decimals)
# self.fin_skewy_entry.setSingleStep(0.1)
#
# grid_lay.addWidget(self.fin_skewy_label, 31, 0)
# grid_lay.addWidget(self.fin_skewy_entry, 31, 1, 1, 2)
# ## Adjusted GCode Button
self.adj_gcode_button = QtWidgets.QPushButton(_("Generate Adjusted GCode"))
self.adj_gcode_button.setToolTip(
_("Generate verification GCode file adjusted with\n"
"the factors set above.\n"
"The GCode parameters can be readjusted\n"
"before clicking this button.")
)
self.adj_gcode_button.setStyleSheet("""
QPushButton
{
font-weight: bold;
}
""")
grid_lay.addWidget(self.adj_gcode_button, 42, 0, 1, 3)
separator_line1 = QtWidgets.QFrame()
separator_line1.setFrameShape(QtWidgets.QFrame.HLine)
separator_line1.setFrameShadow(QtWidgets.QFrame.Sunken)
grid_lay.addWidget(separator_line1, 43, 0, 1, 3)
grid_lay.addWidget(QtWidgets.QLabel(''), 44, 0, 1, 3)
# STEP 5 #
step_5 = QtWidgets.QLabel('%s' % _("STEP 5: Calibrate FlatCAM Objects"))
step_5.setToolTip(
_("Adjust the FlatCAM objects\n"
"with the factors determined and verified above.")
)
grid_lay.addWidget(step_5, 45, 0, 1, 3)
self.adj_object_type_combo = FCComboBox()
self.adj_object_type_combo.addItems([_("Gerber"), _("Excellon"), _("Geometry")])
self.adj_object_type_combo.setItemIcon(0, QtGui.QIcon(self.app.resource_location + "/flatcam_icon16.png"))
self.adj_object_type_combo.setItemIcon(1, QtGui.QIcon(self.app.resource_location + "/drill16.png"))
self.adj_object_type_combo.setItemIcon(2, QtGui.QIcon(self.app.resource_location + "/geometry16.png"))
self.adj_object_type_label = QtWidgets.QLabel("%s:" % _("Adjusted object type"))
self.adj_object_type_label.setToolTip(_("Type of the FlatCAM Object to be adjusted."))
grid_lay.addWidget(self.adj_object_type_label, 46, 0, 1, 3)
grid_lay.addWidget(self.adj_object_type_combo, 47, 0, 1, 3)
self.adj_object_combo = FCComboBox()
self.adj_object_combo.setModel(self.app.collection)
self.adj_object_combo.setRootModelIndex(self.app.collection.index(0, 0, QtCore.QModelIndex()))
self.adj_object_combo.is_last = True
self.adj_object_combo.obj_type = {
_("Gerber"): "Gerber", _("Excellon"): "Excellon", _("Geometry"): "Geometry"
}[self.adj_object_type_combo.get_value()]
self.adj_object_label = QtWidgets.QLabel("%s:" % _("Adjusted object selection"))
self.adj_object_label.setToolTip(
_("The FlatCAM Object to be adjusted.")
)
grid_lay.addWidget(self.adj_object_label, 48, 0, 1, 3)
grid_lay.addWidget(self.adj_object_combo, 49, 0, 1, 3)
# ## Adjust Objects Button
self.cal_button = QtWidgets.QPushButton(_("Calibrate"))
self.cal_button.setToolTip(
_("Adjust (scale and/or skew) the objects\n"
"with the factors determined above.")
)
self.cal_button.setStyleSheet("""
QPushButton
{
font-weight: bold;
}
""")
grid_lay.addWidget(self.cal_button, 50, 0, 1, 3)
separator_line2 = QtWidgets.QFrame()
separator_line2.setFrameShape(QtWidgets.QFrame.HLine)
separator_line2.setFrameShadow(QtWidgets.QFrame.Sunken)
grid_lay.addWidget(separator_line2, 51, 0, 1, 3)
grid_lay.addWidget(QtWidgets.QLabel(''), 52, 0, 1, 3)
self.layout.addStretch()
# ## Reset Tool
self.reset_button = QtWidgets.QPushButton(_("Reset Tool"))
self.reset_button.setIcon(QtGui.QIcon(self.app.resource_location + '/reset32.png'))
self.reset_button.setToolTip(
_("Will reset the tool parameters.")
)
self.reset_button.setStyleSheet("""
QPushButton
{
font-weight: bold;
}
""")
self.layout.addWidget(self.reset_button)
# #################################### FINSIHED GUI ###########################
# #############################################################################
def confirmation_message(self, accepted, minval, maxval):
if accepted is False:
self.app.inform[str, bool].emit('[WARNING_NOTCL] %s: [%.*f, %.*f]' % (_("Edited value is out of range"),
self.decimals,
minval,
self.decimals,
maxval), False)
else:
self.app.inform[str, bool].emit('[success] %s' % _("Edited value is within limits."), False)
def confirmation_message_int(self, accepted, minval, maxval):
if accepted is False:
self.app.inform[str, bool].emit('[WARNING_NOTCL] %s: [%d, %d]' %
(_("Edited value is out of range"), minval, maxval), False)
else:
self.app.inform[str, bool].emit('[success] %s' % _("Edited value is within limits."), False)