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Sebastian Kujas
2025-03-27 17:14:14 +01:00
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carvera_edge_cut.py Normal file
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# ##########################################################
# FlatCAM: 2D Post-processing for Manufacturing #
# http://flatcam.org #
# File Author: Matthieu Berthomé #
# Date: 5/26/2017 #
# MIT Licence #
# ##########################################################
from appPreProcessor import *
class carvera_EDGE(PreProc):
include_header = True
coordinate_format = "%.*f"
feedrate_format = '%.*f'
def start_code(self, p):
units = ' ' + str(p['units']).lower()
coords_xy = p['xy_toolchange']
end_coords_xy = p['xy_end']
gcode = '(This preprocessor is a test for the Carvera from Makera.)\n'
gcode += '(It is made to work with the Carvera)\n\n'
xmin = '%.*f' % (p.coords_decimals, p['options']['xmin'])
xmax = '%.*f' % (p.coords_decimals, p['options']['xmax'])
ymin = '%.*f' % (p.coords_decimals, p['options']['ymin'])
ymax = '%.*f' % (p.coords_decimals, p['options']['ymax'])
if str(p['options']['type']) == 'Geometry':
gcode += '(TOOL DIAMETER: ' + str(p['options']['tool_dia']) + units + ')\n'
gcode += '(Feedrate_XY: ' + str(p['feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate_Z: ' + str(p['z_feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate rapids ' + str(p['feedrate_rapid']) + units + '/min' + ')\n' + '\n'
gcode += '(Z_Cut: ' + str(p['z_cut']) + units + ')\n'
if p['multidepth'] is True:
gcode += '(DepthPerCut: ' + str(p['z_depthpercut']) + units + ' <=>' + \
str(math.ceil(abs(p['z_cut']) / p['z_depthpercut'])) + ' passes' + ')\n'
gcode += '(Z_Move: ' + str(p['z_move']) + units + ')\n'
elif str(p['options']['type']) == 'Excellon' and p['use_ui'] is True:
gcode += '\n(TOOLS DIAMETER: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Dia: %s' % str(val["tooldia"]) + ')\n'
gcode += '\n(FEEDRATE Z: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate: %s' % \
str(val['data']["tools_drill_feedrate_z"]) + ')\n'
gcode += '\n(FEEDRATE RAPIDS: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate Rapids: %s' % \
str(val['data']["tools_drill_feedrate_rapid"]) + ')\n'
gcode += '\n(Z_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Cut: %s' % str(val['data']["tools_drill_cutz"]) + ')\n'
gcode += '\n(Tools Offset: )\n'
for tool, val in p['exc_cnc_tools'].items():
gcode += '(Tool: %s -> ' % str(val['tool']) + 'Offset Z: %s' % \
str(val['data']["tools_drill_offset"]) + ')\n'
if p['multidepth'] is True:
gcode += '\n(DEPTH_PER_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'DeptPerCut: %s' % \
str(val['data']["tools_drill_depthperpass"]) + ')\n'
gcode += '\n(Z_MOVE: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Move: %s' % str(val['data']["tools_drill_travelz"]) + ')\n'
gcode += '\n'
if p['toolchange'] is True:
gcode += '(Z Toolchange: ' + str(p['z_toolchange']) + units + ')\n'
if coords_xy is not None:
gcode += '(X,Y Toolchange: ' + "%.*f, %.*f" % (p.decimals, coords_xy[0],
p.decimals, coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y Toolchange: ' + "None" + units + ')\n'
gcode += '(Z Start: ' + str(p['startz']) + units + ')\n'
gcode += '(Z End: ' + str(p['z_end']) + units + ')\n'
if end_coords_xy is not None:
gcode += '(X,Y End: ' + "%.*f, %.*f" % (p.decimals, end_coords_xy[0],
p.decimals, end_coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y End: ' + "None" + units + ')\n'
gcode += '(Steps per circle: ' + str(p['steps_per_circle']) + ')\n'
if str(p['options']['type']) == 'Excellon' or str(p['options']['type']) == 'Excellon Geometry':
gcode += '(Preprocessor Excellon: ' + str(p['pp_excellon_name']) + ')\n' + '\n'
else:
gcode += '(Preprocessor Geometry: ' + str(p['pp_geometry_name']) + ')\n' + '\n'
gcode += '(X range: ' + '{: >9s}'.format(xmin) + ' ... ' + '{: >9s}'.format(xmax) + ' ' + units + ')\n'
gcode += '(Y range: ' + '{: >9s}'.format(ymin) + ' ... ' + '{: >9s}'.format(ymax) + ' ' + units + ')\n\n'
gcode += '(Spindle Speed: %s RPM)\n' % str(p['spindlespeed'])
gcode += ('G20 ' if p.units.upper() == 'IN' else 'G21 ')
gcode += 'G40 '
gcode += 'G54\n'
gcode += 'G80 '
gcode += 'G90 '
gcode += 'G94\n'
return gcode
def startz_code(self, p):
if p.startz is not None:
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.startz)
else:
return ''
def lift_code(self, p):
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.z_move)
def down_code(self, p):
return 'G01 Z' + self.coordinate_format % (p.coords_decimals, p.z_cut)
def toolchange_code(self, p):
return "T4 M06"
def up_to_zero_code(self, p):
return 'G01 Z0'
def position_code(self, p):
return ('X' + self.coordinate_format + ' Y' + self.coordinate_format) % \
(p.coords_decimals, p.x, p.coords_decimals, p.y)
def rapid_code(self, p):
return ('G00 ' + self.position_code(p)).format(**p)
def linear_code(self, p):
return ('G01 ' + self.position_code(p)).format(**p)
def end_code(self, p):
end_coords_xy = p['xy_end']
gcode = ('G00 Z' + self.feedrate_format % (p.fr_decimals, p.z_end) + "\n")
if end_coords_xy and end_coords_xy != '':
gcode += 'G00 X{x} Y{y}'.format(x=end_coords_xy[0], y=end_coords_xy[1]) + "\n"
return gcode
def feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.feedrate))
def z_feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.z_feedrate))
def spindle_code(self, p):
sdir = {'CW': 'M03', 'CCW': 'M04'}[p.spindledir]
if p.spindlespeed:
return '%s S%s' % (sdir, str(p.spindlespeed))
else:
return sdir
def dwell_code(self, p):
if p.dwelltime:
return 'G4 P' + str(p.dwelltime)
def spindle_stop_code(self, p):
return 'M05'
def test_function(self, p):
return '(HALLO)'

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carvera_edge_cut_0.8mm.py Normal file
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# ##########################################################
# FlatCAM: 2D Post-processing for Manufacturing #
# http://flatcam.org #
# File Author: Matthieu Berthomé #
# Date: 5/26/2017 #
# MIT Licence #
# ##########################################################
from appPreProcessor import *
class carvera_EDGE(PreProc):
include_header = True
coordinate_format = "%.*f"
feedrate_format = '%.*f'
def start_code(self, p):
units = ' ' + str(p['units']).lower()
coords_xy = p['xy_toolchange']
end_coords_xy = p['xy_end']
gcode = '(This preprocessor is a test for the Carvera from Makera.)\n'
gcode += '(It is made to work with the Carvera)\n\n'
xmin = '%.*f' % (p.coords_decimals, p['options']['xmin'])
xmax = '%.*f' % (p.coords_decimals, p['options']['xmax'])
ymin = '%.*f' % (p.coords_decimals, p['options']['ymin'])
ymax = '%.*f' % (p.coords_decimals, p['options']['ymax'])
if str(p['options']['type']) == 'Geometry':
gcode += '(TOOL DIAMETER: ' + str(p['options']['tool_dia']) + units + ')\n'
gcode += '(Feedrate_XY: ' + str(p['feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate_Z: ' + str(p['z_feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate rapids ' + str(p['feedrate_rapid']) + units + '/min' + ')\n' + '\n'
gcode += '(Z_Cut: ' + str(p['z_cut']) + units + ')\n'
if p['multidepth'] is True:
gcode += '(DepthPerCut: ' + str(p['z_depthpercut']) + units + ' <=>' + \
str(math.ceil(abs(p['z_cut']) / p['z_depthpercut'])) + ' passes' + ')\n'
gcode += '(Z_Move: ' + str(p['z_move']) + units + ')\n'
elif str(p['options']['type']) == 'Excellon' and p['use_ui'] is True:
gcode += '\n(TOOLS DIAMETER: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Dia: %s' % str(val["tooldia"]) + ')\n'
gcode += '\n(FEEDRATE Z: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate: %s' % \
str(val['data']["tools_drill_feedrate_z"]) + ')\n'
gcode += '\n(FEEDRATE RAPIDS: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate Rapids: %s' % \
str(val['data']["tools_drill_feedrate_rapid"]) + ')\n'
gcode += '\n(Z_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Cut: %s' % str(val['data']["tools_drill_cutz"]) + ')\n'
gcode += '\n(Tools Offset: )\n'
for tool, val in p['exc_cnc_tools'].items():
gcode += '(Tool: %s -> ' % str(val['tool']) + 'Offset Z: %s' % \
str(val['data']["tools_drill_offset"]) + ')\n'
if p['multidepth'] is True:
gcode += '\n(DEPTH_PER_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'DeptPerCut: %s' % \
str(val['data']["tools_drill_depthperpass"]) + ')\n'
gcode += '\n(Z_MOVE: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Move: %s' % str(val['data']["tools_drill_travelz"]) + ')\n'
gcode += '\n'
if p['toolchange'] is True:
gcode += '(Z Toolchange: ' + str(p['z_toolchange']) + units + ')\n'
if coords_xy is not None:
gcode += '(X,Y Toolchange: ' + "%.*f, %.*f" % (p.decimals, coords_xy[0],
p.decimals, coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y Toolchange: ' + "None" + units + ')\n'
gcode += '(Z Start: ' + str(p['startz']) + units + ')\n'
gcode += '(Z End: ' + str(p['z_end']) + units + ')\n'
if end_coords_xy is not None:
gcode += '(X,Y End: ' + "%.*f, %.*f" % (p.decimals, end_coords_xy[0],
p.decimals, end_coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y End: ' + "None" + units + ')\n'
gcode += '(Steps per circle: ' + str(p['steps_per_circle']) + ')\n'
if str(p['options']['type']) == 'Excellon' or str(p['options']['type']) == 'Excellon Geometry':
gcode += '(Preprocessor Excellon: ' + str(p['pp_excellon_name']) + ')\n' + '\n'
else:
gcode += '(Preprocessor Geometry: ' + str(p['pp_geometry_name']) + ')\n' + '\n'
gcode += '(X range: ' + '{: >9s}'.format(xmin) + ' ... ' + '{: >9s}'.format(xmax) + ' ' + units + ')\n'
gcode += '(Y range: ' + '{: >9s}'.format(ymin) + ' ... ' + '{: >9s}'.format(ymax) + ' ' + units + ')\n\n'
gcode += '(Spindle Speed: %s RPM)\n' % str(p['spindlespeed'])
gcode += ('G20 ' if p.units.upper() == 'IN' else 'G21 ')
gcode += 'G40 '
gcode += 'G54\n'
gcode += 'G80 '
gcode += 'G90 '
gcode += 'G94\n'
return gcode
def startz_code(self, p):
if p.startz is not None:
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.startz)
else:
return ''
def lift_code(self, p):
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.z_move)
def down_code(self, p):
return 'G01 Z' + self.coordinate_format % (p.coords_decimals, p.z_cut)
def toolchange_code(self, p):
return "T3 M06"
def up_to_zero_code(self, p):
return 'G01 Z0'
def position_code(self, p):
return ('X' + self.coordinate_format + ' Y' + self.coordinate_format) % \
(p.coords_decimals, p.x, p.coords_decimals, p.y)
def rapid_code(self, p):
return ('G00 ' + self.position_code(p)).format(**p)
def linear_code(self, p):
return ('G01 ' + self.position_code(p)).format(**p)
def end_code(self, p):
end_coords_xy = p['xy_end']
gcode = ('G00 Z' + self.feedrate_format % (p.fr_decimals, p.z_end) + "\n")
if end_coords_xy and end_coords_xy != '':
gcode += 'G00 X{x} Y{y}'.format(x=end_coords_xy[0], y=end_coords_xy[1]) + "\n"
return gcode
def feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.feedrate))
def z_feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.z_feedrate))
def spindle_code(self, p):
sdir = {'CW': 'M03', 'CCW': 'M04'}[p.spindledir]
if p.spindlespeed:
return '%s S%s' % (sdir, str(p.spindlespeed))
else:
return sdir
def dwell_code(self, p):
if p.dwelltime:
return 'G4 P' + str(p.dwelltime)
def spindle_stop_code(self, p):
return 'M05'
def test_function(self, p):
return '(HALLO)'

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carvera_free_pads.py Normal file
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# ##########################################################
# FlatCAM: 2D Post-processing for Manufacturing #
# http://flatcam.org #
# File Author: Matthieu Berthomé #
# Date: 5/26/2017 #
# MIT Licence #
# ##########################################################
from appPreProcessor import *
class carvera_PADS(PreProc):
include_header = True
coordinate_format = "%.*f"
feedrate_format = '%.*f'
def start_code(self, p):
units = ' ' + str(p['units']).lower()
coords_xy = p['xy_toolchange']
end_coords_xy = p['xy_end']
gcode = '(This preprocessor is a test for the Carvera from Makera.)\n'
gcode += '(It is made to work with the Carvera)\n\n'
xmin = '%.*f' % (p.coords_decimals, p['options']['xmin'])
xmax = '%.*f' % (p.coords_decimals, p['options']['xmax'])
ymin = '%.*f' % (p.coords_decimals, p['options']['ymin'])
ymax = '%.*f' % (p.coords_decimals, p['options']['ymax'])
if str(p['options']['type']) == 'Geometry':
gcode += '(TOOL DIAMETER: ' + str(p['options']['tool_dia']) + units + ')\n'
gcode += '(Feedrate_XY: ' + str(p['feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate_Z: ' + str(p['z_feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate rapids ' + str(p['feedrate_rapid']) + units + '/min' + ')\n' + '\n'
gcode += '(Z_Cut: ' + str(p['z_cut']) + units + ')\n'
if p['multidepth'] is True:
gcode += '(DepthPerCut: ' + str(p['z_depthpercut']) + units + ' <=>' + \
str(math.ceil(abs(p['z_cut']) / p['z_depthpercut'])) + ' passes' + ')\n'
gcode += '(Z_Move: ' + str(p['z_move']) + units + ')\n'
elif str(p['options']['type']) == 'Excellon' and p['use_ui'] is True:
gcode += '\n(TOOLS DIAMETER: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Dia: %s' % str(val["tooldia"]) + ')\n'
gcode += '\n(FEEDRATE Z: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate: %s' % \
str(val['data']["tools_drill_feedrate_z"]) + ')\n'
gcode += '\n(FEEDRATE RAPIDS: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate Rapids: %s' % \
str(val['data']["tools_drill_feedrate_rapid"]) + ')\n'
gcode += '\n(Z_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Cut: %s' % str(val['data']["tools_drill_cutz"]) + ')\n'
gcode += '\n(Tools Offset: )\n'
for tool, val in p['exc_cnc_tools'].items():
gcode += '(Tool: %s -> ' % str(val['tool']) + 'Offset Z: %s' % \
str(val['data']["tools_drill_offset"]) + ')\n'
if p['multidepth'] is True:
gcode += '\n(DEPTH_PER_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'DeptPerCut: %s' % \
str(val['data']["tools_drill_depthperpass"]) + ')\n'
gcode += '\n(Z_MOVE: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Move: %s' % str(val['data']["tools_drill_travelz"]) + ')\n'
gcode += '\n'
if p['toolchange'] is True:
gcode += '(Z Toolchange: ' + str(p['z_toolchange']) + units + ')\n'
if coords_xy is not None:
gcode += '(X,Y Toolchange: ' + "%.*f, %.*f" % (p.decimals, coords_xy[0],
p.decimals, coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y Toolchange: ' + "None" + units + ')\n'
gcode += '(Z Start: ' + str(p['startz']) + units + ')\n'
gcode += '(Z End: ' + str(p['z_end']) + units + ')\n'
if end_coords_xy is not None:
gcode += '(X,Y End: ' + "%.*f, %.*f" % (p.decimals, end_coords_xy[0],
p.decimals, end_coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y End: ' + "None" + units + ')\n'
gcode += '(Steps per circle: ' + str(p['steps_per_circle']) + ')\n'
if str(p['options']['type']) == 'Excellon' or str(p['options']['type']) == 'Excellon Geometry':
gcode += '(Preprocessor Excellon: ' + str(p['pp_excellon_name']) + ')\n' + '\n'
else:
gcode += '(Preprocessor Geometry: ' + str(p['pp_geometry_name']) + ')\n' + '\n'
gcode += '(X range: ' + '{: >9s}'.format(xmin) + ' ... ' + '{: >9s}'.format(xmax) + ' ' + units + ')\n'
gcode += '(Y range: ' + '{: >9s}'.format(ymin) + ' ... ' + '{: >9s}'.format(ymax) + ' ' + units + ')\n\n'
gcode += '(Spindle Speed: %s RPM)\n' % str(p['spindlespeed'])
gcode += ('G20 ' if p.units.upper() == 'IN' else 'G21 ')
gcode += 'G40 '
gcode += 'G54\n'
gcode += 'G80 '
gcode += 'G90 '
gcode += 'G94\n'
return gcode
def startz_code(self, p):
if p.startz is not None:
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.startz)
else:
return ''
def lift_code(self, p):
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.z_move)
def down_code(self, p):
return 'G01 Z' + self.coordinate_format % (p.coords_decimals, p.z_cut)
def toolchange_code(self, p):
return "T5 M06"
def up_to_zero_code(self, p):
return 'G01 Z0'
def position_code(self, p):
return ('X' + self.coordinate_format + ' Y' + self.coordinate_format) % \
(p.coords_decimals, p.x, p.coords_decimals, p.y)
def rapid_code(self, p):
return ('G00 ' + self.position_code(p)).format(**p)
def linear_code(self, p):
return ('G01 ' + self.position_code(p)).format(**p)
def end_code(self, p):
end_coords_xy = p['xy_end']
gcode = ('G00 Z' + self.feedrate_format % (p.fr_decimals, p.z_end) + "\n")
if end_coords_xy and end_coords_xy != '':
gcode += 'G00 X{x} Y{y}'.format(x=end_coords_xy[0], y=end_coords_xy[1]) + "\n"
return gcode
def feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.feedrate))
def z_feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.z_feedrate))
def spindle_code(self, p):
sdir = {'CW': 'M03', 'CCW': 'M04'}[p.spindledir]
if p.spindlespeed:
return '%s S%s' % (sdir, str(p.spindlespeed))
else:
return sdir
def dwell_code(self, p):
if p.dwelltime:
return 'G4 P' + str(p.dwelltime)
def spindle_stop_code(self, p):
return 'M05'
def test_function(self, p):
return '(HALLO)'

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carvera_hole_mill.py Normal file
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# ##########################################################
# FlatCAM: 2D Post-processing for Manufacturing #
# http://flatcam.org #
# File Author: Matthieu Berthomé #
# Date: 5/26/2017 #
# MIT Licence #
# ##########################################################
from appPreProcessor import *
class carvera_HOLE(PreProc):
include_header = True
coordinate_format = "%.*f"
feedrate_format = '%.*f'
def start_code(self, p):
units = ' ' + str(p['units']).lower()
coords_xy = p['xy_toolchange']
end_coords_xy = p['xy_end']
gcode = '(This preprocessor is a test for the Carvera from Makera.)\n'
gcode += '(It is made to work with the Carvera)\n\n'
xmin = '%.*f' % (p.coords_decimals, p['options']['xmin'])
xmax = '%.*f' % (p.coords_decimals, p['options']['xmax'])
ymin = '%.*f' % (p.coords_decimals, p['options']['ymin'])
ymax = '%.*f' % (p.coords_decimals, p['options']['ymax'])
if str(p['options']['type']) == 'Geometry':
gcode += '(TOOL DIAMETER: ' + str(p['options']['tool_dia']) + units + ')\n'
gcode += '(Feedrate_XY: ' + str(p['feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate_Z: ' + str(p['z_feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate rapids ' + str(p['feedrate_rapid']) + units + '/min' + ')\n' + '\n'
gcode += '(Z_Cut: ' + str(p['z_cut']) + units + ')\n'
if p['multidepth'] is True:
gcode += '(DepthPerCut: ' + str(p['z_depthpercut']) + units + ' <=>' + \
str(math.ceil(abs(p['z_cut']) / p['z_depthpercut'])) + ' passes' + ')\n'
gcode += '(Z_Move: ' + str(p['z_move']) + units + ')\n'
elif str(p['options']['type']) == 'Excellon' and p['use_ui'] is True:
gcode += '\n(TOOLS DIAMETER: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Dia: %s' % str(val["tooldia"]) + ')\n'
gcode += '\n(FEEDRATE Z: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate: %s' % \
str(val['data']["tools_drill_feedrate_z"]) + ')\n'
gcode += '\n(FEEDRATE RAPIDS: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate Rapids: %s' % \
str(val['data']["tools_drill_feedrate_rapid"]) + ')\n'
gcode += '\n(Z_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Cut: %s' % str(val['data']["tools_drill_cutz"]) + ')\n'
gcode += '\n(Tools Offset: )\n'
for tool, val in p['exc_cnc_tools'].items():
gcode += '(Tool: %s -> ' % str(val['tool']) + 'Offset Z: %s' % \
str(val['data']["tools_drill_offset"]) + ')\n'
if p['multidepth'] is True:
gcode += '\n(DEPTH_PER_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'DeptPerCut: %s' % \
str(val['data']["tools_drill_depthperpass"]) + ')\n'
gcode += '\n(Z_MOVE: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Move: %s' % str(val['data']["tools_drill_travelz"]) + ')\n'
gcode += '\n'
if p['toolchange'] is True:
gcode += '(Z Toolchange: ' + str(p['z_toolchange']) + units + ')\n'
if coords_xy is not None:
gcode += '(X,Y Toolchange: ' + "%.*f, %.*f" % (p.decimals, coords_xy[0],
p.decimals, coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y Toolchange: ' + "None" + units + ')\n'
gcode += '(Z Start: ' + str(p['startz']) + units + ')\n'
gcode += '(Z End: ' + str(p['z_end']) + units + ')\n'
if end_coords_xy is not None:
gcode += '(X,Y End: ' + "%.*f, %.*f" % (p.decimals, end_coords_xy[0],
p.decimals, end_coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y End: ' + "None" + units + ')\n'
gcode += '(Steps per circle: ' + str(p['steps_per_circle']) + ')\n'
if str(p['options']['type']) == 'Excellon' or str(p['options']['type']) == 'Excellon Geometry':
gcode += '(Preprocessor Excellon: ' + str(p['pp_excellon_name']) + ')\n' + '\n'
else:
gcode += '(Preprocessor Geometry: ' + str(p['pp_geometry_name']) + ')\n' + '\n'
gcode += '(X range: ' + '{: >9s}'.format(xmin) + ' ... ' + '{: >9s}'.format(xmax) + ' ' + units + ')\n'
gcode += '(Y range: ' + '{: >9s}'.format(ymin) + ' ... ' + '{: >9s}'.format(ymax) + ' ' + units + ')\n\n'
gcode += '(Spindle Speed: %s RPM)\n' % str(p['spindlespeed'])
gcode += ('G20 ' if p.units.upper() == 'IN' else 'G21 ')
gcode += 'G40 '
gcode += 'G54\n'
gcode += 'G80 '
gcode += 'G90 '
gcode += 'G94\n'
return gcode
def startz_code(self, p):
if p.startz is not None:
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.startz)
else:
return ''
def lift_code(self, p):
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.z_move)
def down_code(self, p):
return 'G01 Z' + self.coordinate_format % (p.coords_decimals, p.z_cut)
def toolchange_code(self, p):
return "T3 M06"
def up_to_zero_code(self, p):
return 'G01 Z0'
def position_code(self, p):
return ('X' + self.coordinate_format + ' Y' + self.coordinate_format) % \
(p.coords_decimals, p.x, p.coords_decimals, p.y)
def rapid_code(self, p):
return ('G00 ' + self.position_code(p)).format(**p)
def linear_code(self, p):
return ('G01 ' + self.position_code(p)).format(**p)
def end_code(self, p):
end_coords_xy = p['xy_end']
gcode = ('G00 Z' + self.feedrate_format % (p.fr_decimals, p.z_end) + "\n")
if end_coords_xy and end_coords_xy != '':
gcode += 'G00 X{x} Y{y}'.format(x=end_coords_xy[0], y=end_coords_xy[1]) + "\n"
return gcode
def feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.feedrate))
def z_feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.z_feedrate))
def spindle_code(self, p):
sdir = {'CW': 'M03', 'CCW': 'M04'}[p.spindledir]
if p.spindlespeed:
return '%s S%s' % (sdir, str(p.spindlespeed))
else:
return sdir
def dwell_code(self, p):
if p.dwelltime:
return 'G4 P' + str(p.dwelltime)
def spindle_stop_code(self, p):
return 'M05'
def test_function(self, p):
return '(HALLO)'

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# ##########################################################
# FlatCAM: 2D Post-processing for Manufacturing #
# http://flatcam.org #
# File Author: Matthieu Berthomé #
# Date: 5/26/2017 #
# MIT Licence #
# ##########################################################
from appPreProcessor import *
class carvera_ISO(PreProc):
include_header = True
coordinate_format = "%.*f"
feedrate_format = '%.*f'
def start_code(self, p):
units = ' ' + str(p['units']).lower()
coords_xy = p['xy_toolchange']
end_coords_xy = p['xy_end']
gcode = '(This preprocessor is a test for the Carvera from Makera.)\n'
gcode += '(It is made to work with the Carvera)\n\n'
xmin = '%.*f' % (p.coords_decimals, p['options']['xmin'])
xmax = '%.*f' % (p.coords_decimals, p['options']['xmax'])
ymin = '%.*f' % (p.coords_decimals, p['options']['ymin'])
ymax = '%.*f' % (p.coords_decimals, p['options']['ymax'])
if str(p['options']['type']) == 'Geometry':
gcode += '(TOOL DIAMETER: ' + str(p['options']['tool_dia']) + units + ')\n'
gcode += '(Feedrate_XY: ' + str(p['feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate_Z: ' + str(p['z_feedrate']) + units + '/min' + ')\n'
gcode += '(Feedrate rapids ' + str(p['feedrate_rapid']) + units + '/min' + ')\n' + '\n'
gcode += '(Z_Cut: ' + str(p['z_cut']) + units + ')\n'
if p['multidepth'] is True:
gcode += '(DepthPerCut: ' + str(p['z_depthpercut']) + units + ' <=>' + \
str(math.ceil(abs(p['z_cut']) / p['z_depthpercut'])) + ' passes' + ')\n'
gcode += '(Z_Move: ' + str(p['z_move']) + units + ')\n'
elif str(p['options']['type']) == 'Excellon' and p['use_ui'] is True:
gcode += '\n(TOOLS DIAMETER: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Dia: %s' % str(val["tooldia"]) + ')\n'
gcode += '\n(FEEDRATE Z: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate: %s' % \
str(val['data']["tools_drill_feedrate_z"]) + ')\n'
gcode += '\n(FEEDRATE RAPIDS: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Feedrate Rapids: %s' % \
str(val['data']["tools_drill_feedrate_rapid"]) + ')\n'
gcode += '\n(Z_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Cut: %s' % str(val['data']["tools_drill_cutz"]) + ')\n'
gcode += '\n(Tools Offset: )\n'
for tool, val in p['exc_cnc_tools'].items():
gcode += '(Tool: %s -> ' % str(val['tool']) + 'Offset Z: %s' % \
str(val['data']["tools_drill_offset"]) + ')\n'
if p['multidepth'] is True:
gcode += '\n(DEPTH_PER_CUT: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'DeptPerCut: %s' % \
str(val['data']["tools_drill_depthperpass"]) + ')\n'
gcode += '\n(Z_MOVE: )\n'
for tool, val in p['exc_tools'].items():
gcode += '(Tool: %s -> ' % str(tool) + 'Z_Move: %s' % str(val['data']["tools_drill_travelz"]) + ')\n'
gcode += '\n'
if p['toolchange'] is True:
gcode += '(Z Toolchange: ' + str(p['z_toolchange']) + units + ')\n'
if coords_xy is not None:
gcode += '(X,Y Toolchange: ' + "%.*f, %.*f" % (p.decimals, coords_xy[0],
p.decimals, coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y Toolchange: ' + "None" + units + ')\n'
gcode += '(Z Start: ' + str(p['startz']) + units + ')\n'
gcode += '(Z End: ' + str(p['z_end']) + units + ')\n'
if end_coords_xy is not None:
gcode += '(X,Y End: ' + "%.*f, %.*f" % (p.decimals, end_coords_xy[0],
p.decimals, end_coords_xy[1]) + units + ')\n'
else:
gcode += '(X,Y End: ' + "None" + units + ')\n'
gcode += '(Steps per circle: ' + str(p['steps_per_circle']) + ')\n'
if str(p['options']['type']) == 'Excellon' or str(p['options']['type']) == 'Excellon Geometry':
gcode += '(Preprocessor Excellon: ' + str(p['pp_excellon_name']) + ')\n' + '\n'
else:
gcode += '(Preprocessor Geometry: ' + str(p['pp_geometry_name']) + ')\n' + '\n'
gcode += '(X range: ' + '{: >9s}'.format(xmin) + ' ... ' + '{: >9s}'.format(xmax) + ' ' + units + ')\n'
gcode += '(Y range: ' + '{: >9s}'.format(ymin) + ' ... ' + '{: >9s}'.format(ymax) + ' ' + units + ')\n\n'
gcode += '(Spindle Speed: %s RPM)\n' % str(p['spindlespeed'])
gcode += ('G20 ' if p.units.upper() == 'IN' else 'G21 ')
gcode += 'G40 '
gcode += 'G54\n'
gcode += 'G80 '
gcode += 'G90 '
gcode += 'G94\n'
return gcode
def startz_code(self, p):
if p.startz is not None:
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.startz)
else:
return ''
def lift_code(self, p):
return 'G00 Z' + self.coordinate_format % (p.coords_decimals, p.z_move)
def down_code(self, p):
return 'G01 Z' + self.coordinate_format % (p.coords_decimals, p.z_cut)
def toolchange_code(self, p):
return "T2 M06"
def up_to_zero_code(self, p):
return 'G01 Z0'
def position_code(self, p):
return ('X' + self.coordinate_format + ' Y' + self.coordinate_format) % \
(p.coords_decimals, p.x, p.coords_decimals, p.y)
def rapid_code(self, p):
return ('G00 ' + self.position_code(p)).format(**p)
def linear_code(self, p):
return ('G01 ' + self.position_code(p)).format(**p)
def end_code(self, p):
end_coords_xy = p['xy_end']
gcode = ('G00 Z' + self.feedrate_format % (p.fr_decimals, p.z_end) + "\n")
if end_coords_xy and end_coords_xy != '':
gcode += 'G00 X{x} Y{y}'.format(x=end_coords_xy[0], y=end_coords_xy[1]) + "\n"
return gcode
def feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.feedrate))
def z_feedrate_code(self, p):
return 'G01 F' + str(self.feedrate_format % (p.fr_decimals, p.z_feedrate))
def spindle_code(self, p):
sdir = {'CW': 'M03', 'CCW': 'M04'}[p.spindledir]
if p.spindlespeed:
return '%s S%s' % (sdir, str(p.spindlespeed))
else:
return sdir
def dwell_code(self, p):
if p.dwelltime:
return 'G4 P' + str(p.dwelltime)
def spindle_stop_code(self, p):
return 'M05'
def test_function(self, p):
return '(HALLO)'