def __init__(self, config, bedmesh):
self.printer = config.get_printer()
self.name = config.get_name()
self.bedmesh = bedmesh
self.probed_z_table = None
self.build_map = False
self.probe_params = collections.OrderedDict()
points = self._generate_points(config)
self._init_probe_params(config, points)
self.probe_helper = probe.ProbePointsHelper(config,
self.probe_finalize,
points)
# setup persistent storage
self.profiles = {}
self._load_storage(config)
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('BED_MESH_CALIBRATE',
self.cmd_BED_MESH_CALIBRATE,
desc=self.cmd_BED_MESH_CALIBRATE_help)
self.gcode.register_command('BED_MESH_MAP',
self.cmd_BED_MESH_MAP,
desc=self.cmd_BED_MESH_MAP_help)
self.gcode.register_command('BED_MESH_PROFILE',
self.cmd_BED_MESH_PROFILE,
desc=self.cmd_BED_MESH_PROFILE_help)
def __init__(self, config):
self.printer = config.get_printer()
self.probe_helper = probe.ProbePointsHelper(config, self)
probe_location = config.get('probe_location').split(',')
gantry_corners = config.get('gantry_corners').split('\n')
try:
gantry_corners = [
line.split(',', 1) for line in gantry_corners if line.strip()
]
self.gantry_corners = [(float(zp[0].strip()), float(zp[1].strip()))
for zp in gantry_corners]
except:
raise config.error("Unable to parse gantry_corners in %s" %
(config.get_name()))
if len(gantry_corners) < 2:
raise config.error(
"ganry_level requires at least two gantry_corners")
self.probe_location = [
float(probe_location[0].strip()),
float(probe_location[1].strip())
]
self.z_steppers = []
# Register GANTRY_LEVEL command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('GANTRY_LEVEL',
self.cmd_GANTRY_LEVEL,
desc=self.cmd_GANTRY_LEVEL_help)
def __init__(self, config):
self.printer = config.get_printer()
self.retry_helper = z_tilt.RetryHelper(
config, "Possibly Z motor numbering is wrong")
self.max_adjust = config.getfloat("max_adjust", 4, above=0)
self.horizontal_move_z = config.getfloat("horizontal_move_z", 5.0)
self.probe_helper = probe.ProbePointsHelper(config,
self.probe_finalize)
if len(self.probe_helper.probe_points) != 4:
raise config.error(
"Need exactly 4 probe points for quad_gantry_level")
self.z_helper = z_tilt.ZAdjustHelper(config, 4)
gantry_corners = config.get('gantry_corners').split('\n')
try:
gantry_corners = [
line.split(',', 1) for line in gantry_corners if line.strip()
]
self.gantry_corners = [(float(zp[0].strip()), float(zp[1].strip()))
for zp in gantry_corners]
except:
raise config.error("Unable to parse gantry_corners in %s" %
(config.get_name()))
if len(self.gantry_corners) < 2:
raise config.error(
"quad_gantry_level requires at least two gantry_corners")
# Register QUAD_GANTRY_LEVEL command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('QUAD_GANTRY_LEVEL',
self.cmd_QUAD_GANTRY_LEVEL,
desc=self.cmd_QUAD_GANTRY_LEVEL_help)
def __init__(self, config, bedmesh):
self.printer = config.get_printer()
self.name = config.get_name()
self.radius = self.origin = None
self.relative_reference_index = config.getint(
'relative_reference_index', None)
self.bedmesh = bedmesh
self.probed_matrix = None
self.mesh_params = collections.OrderedDict()
self.points = self._generate_points(config)
self._init_mesh_params(config, self.points)
self.probe_helper = probe.ProbePointsHelper(config,
self.probe_finalize,
self.points)
self.probe_helper.minimum_points(3)
self.probe_helper.use_xy_offsets(True)
# setup persistent storage
self.profiles = {}
self.incompatible_profiles = []
self._load_storage(config)
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('BED_MESH_CALIBRATE',
self.cmd_BED_MESH_CALIBRATE,
desc=self.cmd_BED_MESH_CALIBRATE_help)
self.gcode.register_command('BED_MESH_PROFILE',
self.cmd_BED_MESH_PROFILE,
desc=self.cmd_BED_MESH_PROFILE_help)
def __init__(self, config):
self.printer = config.get_printer()
self.printer.register_event_handler("klippy:connect",
self.handle_connect)
self.probe_helper = probe.ProbePointsHelper(config,
self.probe_finalize)
gantry_corners = config.get('gantry_corners').split('\n')
try:
gantry_corners = [
line.split(',', 1) for line in gantry_corners if line.strip()
]
self.gantry_corners = [(float(zp[0].strip()), float(zp[1].strip()))
for zp in gantry_corners]
except:
raise config.error("Unable to parse gantry_corners in %s" %
(config.get_name()))
if len(self.gantry_corners) < 2:
raise config.error(
"quad_gantry_level requires at least two gantry_corners")
self.z_steppers = []
# Register QUAD_GANTRY_LEVEL command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('QUAD_GANTRY_LEVEL',
self.cmd_QUAD_GANTRY_LEVEL,
desc=self.cmd_QUAD_GANTRY_LEVEL_help)
def __init__(self, config):
self.config = config
self.printer = config.get_printer()
self.screws = []
# Read config
for i in range(99):
prefix = "screw%d" % (i + 1,)
if config.get(prefix, None) is None:
break
screw_coord = parse_coord(config, prefix)
screw_name = "screw at %.3f,%.3f" % screw_coord
screw_name = config.get(prefix + "_name", screw_name)
self.screws.append((screw_coord, screw_name))
if len(self.screws) < 3:
raise config.error("screws_tilt_adjust: Must have "
"at least three screws")
self.threads = {'CW-M3': 0, 'CCW-M3': 1, 'CW-M4': 2, 'CCW-M4': 3,
'CW-M5': 4, 'CCW-M5': 5}
self.thread = config.getchoice('screw_thread', self.threads,
default='CW-M3')
# Initialize ProbePointsHelper
points = [coord for coord, name in self.screws]
self.probe_helper = probe.ProbePointsHelper(self.config,
self.probe_finalize,
default_points=points)
self.probe_helper.minimum_points(3)
# Register command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command("SCREWS_TILT_CALCULATE",
self.cmd_SCREWS_TILT_CALCULATE,
desc=self.cmd_SCREWS_TILT_CALCULATE_help)
def __init__(self, config, bedtilt):
self.printer = config.get_printer()
self.bedtilt = bedtilt
self.probe_helper = probe.ProbePointsHelper(config,
self.probe_finalize)
# Register BED_TILT_CALIBRATE command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('BED_TILT_CALIBRATE',
self.cmd_BED_TILT_CALIBRATE,
desc=self.cmd_BED_TILT_CALIBRATE_help)
def cmd_DELTA_CALIBRATE(self, params):
# Setup probe points
points = [(0., 0.)]
scatter = [.95, .90, .85, .70, .75, .80]
for i in range(6):
r = math.radians(90. + 60. * i)
dist = self.radius * scatter[i]
points.append((math.cos(r) * dist, math.sin(r) * dist))
# Probe them
self.gcode.run_script("G28")
probe.ProbePointsHelper(self.printer, points, self.horizontal_move_z,
self.speed, self.manual_probe, self)
def __init__(self, config):
self.printer = config.get_printer()
self.printer.register_event_handler("klippy:connect",
self.handle_connect)
# Calculate default probing points
radius = config.getfloat('radius', above=0.)
points = [(0., 0.)]
scatter = [.95, .90, .85, .70, .75, .80]
for i in range(6):
r = math.radians(90. + 60. * i)
dist = radius * scatter[i]
points.append((math.cos(r) * dist, math.sin(r) * dist))
self.probe_helper = probe.ProbePointsHelper(config,
self.probe_finalize,
default_points=points)
self.probe_helper.minimum_points(3)
# Restore probe stable positions
self.last_probe_positions = []
for i in range(999):
height = config.getfloat("height%d" % (i, ), None)
if height is None:
break
height_pos = load_config_stable(config, "height%d_pos" % (i, ))
self.last_probe_positions.append((height, height_pos))
# Restore manually entered heights
self.manual_heights = []
for i in range(999):
height = config.getfloat("manual_height%d" % (i, ), None)
if height is None:
break
height_pos = load_config_stable(config,
"manual_height%d_pos" % (i, ))
self.manual_heights.append((height, height_pos))
# Restore distance measurements
self.delta_analyze_entry = {'SCALE': (1., )}
self.last_distances = []
for i in range(999):
dist = config.getfloat("distance%d" % (i, ), None)
if dist is None:
break
distance_pos1 = load_config_stable(config,
"distance%d_pos1" % (i, ))
distance_pos2 = load_config_stable(config,
"distance%d_pos2" % (i, ))
self.last_distances.append((dist, distance_pos1, distance_pos2))
# Register gcode commands
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('DELTA_CALIBRATE',
self.cmd_DELTA_CALIBRATE,
desc=self.cmd_DELTA_CALIBRATE_help)
self.gcode.register_command('DELTA_ANALYZE',
self.cmd_DELTA_ANALYZE,
desc=self.cmd_DELTA_ANALYZE_help)
def __init__(self, config, bedtilt):
self.printer = config.get_printer()
self.bedtilt = bedtilt
self.probe_helper = probe.ProbePointsHelper(config, self)
# Automatic probe:z_virtual_endstop XY detection
self.z_position_endstop = None
if config.has_section('stepper_z'):
zconfig = config.getsection('stepper_z')
self.z_position_endstop = zconfig.getfloat('position_endstop', None)
# Register BED_TILT_CALIBRATE command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command(
'BED_TILT_CALIBRATE', self.cmd_BED_TILT_CALIBRATE,
desc=self.cmd_BED_TILT_CALIBRATE_help)
def __init__(self, config):
self.printer = config.get_printer()
if config.getsection('printer').get('kinematics') != 'delta':
raise config.error("Delta calibrate is only for delta printers")
# Calculate default probing points
radius = config.getfloat('radius', above=0.)
points = [(0., 0.)]
scatter = [.95, .90, .85, .70, .75, .80]
for i in range(6):
r = math.radians(90. + 60. * i)
dist = radius * scatter[i]
points.append((math.cos(r) * dist, math.sin(r) * dist))
self.probe_helper = probe.ProbePointsHelper(
config, self, default_points=points)
# Register DELTA_CALIBRATE command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command(
'DELTA_CALIBRATE', self.cmd_DELTA_CALIBRATE,
desc=self.cmd_DELTA_CALIBRATE_help)
def __init__(self, config):
self.printer = config.get_printer()
z_positions = config.get('z_positions').split('\n')
try:
z_positions = [line.split(',', 1)
for line in z_positions if line.strip()]
self.z_positions = [(float(zp[0].strip()), float(zp[1].strip()))
for zp in z_positions]
except:
raise config.error("Unable to parse z_positions in %s" % (
config.get_name()))
self.retry_helper = RetryHelper(config)
self.probe_helper = probe.ProbePointsHelper(config, self.probe_finalize)
self.probe_helper.minimum_points(2)
self.z_helper = ZAdjustHelper(config, len(self.z_positions))
# Register Z_TILT_ADJUST command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('Z_TILT_ADJUST', self.cmd_Z_TILT_ADJUST,
desc=self.cmd_Z_TILT_ADJUST_help)
def __init__(self, config):
self.printer = config.get_printer()
if config.getsection('printer').get('kinematics') != 'delta':
raise config.error("Delta calibrate is only for delta printers")
# Calculate default probing points
radius = config.getfloat('radius', above=0.)
points = [(0., 0.)]
scatter = [.95, .90, .85, .70, .75, .80]
for i in range(6):
r = math.radians(90. + 60. * i)
dist = radius * scatter[i]
points.append((math.cos(r) * dist, math.sin(r) * dist))
self.probe_helper = probe.ProbePointsHelper(config,
self,
default_points=points)
# Restore probe stable positions
self.last_probe_positions = []
for i in range(999):
height = config.getfloat("height%d" % (i, ), None)
if height is None:
break
height_pos = load_config_stable(config, "height%d_pos" % (i, ))
self.last_probe_positions.append((height, height_pos))
# Restore distance measurements
self.delta_analyze_entry = {'SCALE': (1., )}
self.last_distances = []
for i in range(999):
dist = config.getfloat("distance%d" % (i, ), None)
if dist is None:
break
distance_pos1 = load_config_stable(config,
"distance%d_pos1" % (i, ))
distance_pos2 = load_config_stable(config,
"distance%d_pos2" % (i, ))
self.last_distances.append((dist, distance_pos1, distance_pos2))
# Register gcode commands
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('DELTA_CALIBRATE',
self.cmd_DELTA_CALIBRATE,
desc=self.cmd_DELTA_CALIBRATE_help)
self.gcode.register_command('DELTA_ANALYZE',
self.cmd_DELTA_ANALYZE,
desc=self.cmd_DELTA_ANALYZE_help)
def __init__(self, config):
self.printer = config.get_printer()
z_positions = config.get('z_positions').split('\n')
try:
z_positions = [line.split(',', 1)
for line in z_positions if line.strip()]
self.z_positions = [(float(zp[0].strip()), float(zp[1].strip()))
for zp in z_positions]
except:
raise config.error("Unable to parse z_positions in %s" % (
config.get_name()))
if len(z_positions) < 2:
raise config.error("z_tilt requires at least two z_positions")
self.probe_helper = probe.ProbePointsHelper(config, self.probe_finalize)
self.z_steppers = []
# Register Z_TILT_ADJUST command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command(
'Z_TILT_ADJUST', self.cmd_Z_TILT_ADJUST,
desc=self.cmd_Z_TILT_ADJUST_help)
def __init__(self, config, bedmesh):
self.printer = config.get_printer()
self.bedmesh = bedmesh
self.probed_z_table = None
self.build_map = False
self.probe_params = {}
points = self._generate_points(config)
self._init_probe_params(config, points)
self.probe_helper = probe.ProbePointsHelper(config, self, points)
self.z_endstop_pos = None
if config.has_section('stepper_z'):
zconfig = config.getsection('stepper_z')
self.z_endstop_pos = zconfig.getfloat('position_endstop', None)
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('BED_MESH_CALIBRATE',
self.cmd_BED_MESH_CALIBRATE,
desc=self.cmd_BED_MESH_CALIBRATE_help)
self.gcode.register_command('BED_MESH_MAP',
self.cmd_BED_MESH_MAP,
desc=self.cmd_BED_MESH_MAP_help)
def __init__(self, config, bedmesh):
self.printer = config.get_printer()
self.bedmesh = bedmesh
#TODO: Instead of calculating probe points, add them to config
self.probe_helper = probe.ProbePointsHelper(
config, self, self.calculate_probe_points())
# Automatic probe:z_virtual_endstop XY detection
self.z_position_endstop = None
if config.has_section('stepper_z'):
zconfig = config.getsection('stepper_z')
self.z_position_endstop = zconfig.getfloat('position_endstop',
None)
# Register MESH_BED_LEVING command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('BED_MESH_CALIBRATE',
self.cmd_BED_MESH_CALIBRATE,
desc=self.cmd_BED_MESH_CALIBRATE_help)
# Register G80 as alias
self.gcode.register_command('G80',
self.cmd_BED_MESH_CALIBRATE,
desc=self.cmd_BED_MESH_CALIBRATE_help)
def cmd_BED_TILT_CALIBRATE(self, params):
self.gcode.run_script("G28")
probe.ProbePointsHelper(
self.printer, self.points, self.horizontal_move_z,
self.speed, self.manual_probe, self)
def __init__(self, config):
self.printer = config.get_printer()
self.printer.register_event_handler("klippy:ready", self.handle_ready)
self.retry_helper = z_tilt.RetryHelper(
config, "Possibly Z motor numbering is wrong")
self.max_adjust = config.getfloat("max_adjust", 4, above=0)
self.horizontal_move_z = config.getfloat("horizontal_move_z", 5.0)
self.probe_helper = probe.ProbePointsHelper(config,
self.probe_finalize)
if len(self.probe_helper.probe_points) != 4:
raise config.error(
"Need exactly 4 probe points for quad_gantry_level")
self.default_adjust = [Decimal(0), Decimal(0), Decimal(0), Decimal(0)]
self.z_mesh_matrix = None
self.last_position = [0., 0., 0., 0.]
self.load_custom_data()
gantry_corners = config.get('gantry_corners').split('\n')
try:
gantry_corners = [
line.split(',', 1) for line in gantry_corners if line.strip()
]
self.gantry_corners = [(Decimal(zp[0].strip()),
Decimal(zp[1].strip()))
for zp in gantry_corners]
except:
raise config.error("Unable to parse gantry_corners in %s" %
(config.get_name()))
if len(self.gantry_corners) < 2:
raise config.error(
"quad_gantry_level requires at least two gantry_corners")
# Register QUAD_GANTRY_LEVEL command
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command('QUAD_GANTRY_LEVEL',
self.cmd_QUAD_GANTRY_LEVEL,
desc=self.cmd_QUAD_GANTRY_LEVEL_help)
self.gcode.register_command('QUAD_GANTRY_MANUAL',
self.cmd_QUAD_GANTRY_MANUAL,
desc=self.cmd_QUAD_GANTRY_MANUAL_help)
self.gcode.register_command('QUAD_GANTRY_ADJUST',
self.cmd_QUAD_GANTRY_ADJUST,
desc=self.cmd_QUAD_GANTRY_ADJUST_help)
self.tool_head = None
self.z_mesh = None
self.use_additional_z_mesh = config.getboolean("use_additional_z_mesh",
False)
if self.use_additional_z_mesh:
self.gcode.register_command(
'QUAD_BED_MESH_ADJUST',
self.cmd_QUAD_BED_MESH_ADJUST,
desc=self.cmd_cmd_QUAD_BED_MESH_ADJUST_help)
self.gcode.register_command('QUAD_BED_MESH_CLEAR',
self.cmd_QUAD_BED_MESH_CLEAR,
desc=self.cmd_QUAD_BED_MESH_CLEAR_help)
self.gcode.register_command('QUAD_PRINT_BED_MESH',
self.cmd_QUAD_PRINT_BED_MESH,
desc=self.cmd_QUAD_PRINT_BED_MESH_help)
self.mesh_params = collections.OrderedDict()
self.mesh_params['algo'] = 'direct'
size = bed_mesh.parse_pair(config, ('probe_count', '3'),
check=False,
cast=int,
minval=3)
# rectangular
min = bed_mesh.parse_pair(config, ('mesh_min', ))
max = bed_mesh.parse_pair(config, ('mesh_max', ))
# pps = bed_mesh.parse_pair(config, ('mesh_pps', '2'), check=False, cast=int, minval=0)
x_cnt, y_cnt = size
min_x, min_y = min
max_x, max_y = max
pps = [0, 0]
if self.z_mesh_matrix is not None:
row_count = len(self.z_mesh_matrix)
column_count = len(self.z_mesh_matrix[0])
if row_count * column_count != x_cnt * y_cnt:
self.z_mesh_matrix = None
if max_x <= min_x or max_y <= min_y:
raise config.error('bed_mesh: invalid min/max points')
self.mesh_params['x_count'] = x_cnt
self.mesh_params['y_count'] = y_cnt
self.mesh_params['min_x'] = min_x
self.mesh_params['max_x'] = max_x
self.mesh_params['min_y'] = min_y
self.mesh_params['max_y'] = max_y
self.mesh_params['mesh_x_pps'] = pps[0]
self.mesh_params['mesh_y_pps'] = pps[1]
try:
self.points = self._generate_points(size, min, max)
except Exception as e:
raise config.error(str(e))
self.fade_start = config.getfloat('fade_start', 1.)
self.fade_end = config.getfloat('fade_end', 0.)
self.fade_dist = self.fade_end - self.fade_start
if self.fade_dist <= 0.:
self.fade_start = self.fade_end = self.FADE_DISABLE
self.log_fade_complete = False
self.base_fade_target = config.getfloat('fade_target', None)
self.fade_target = 0.
self.splitter = bed_mesh.MoveSplitter(config, self.gcode)
self.gcode.set_move_transform(self)
