klipper/klippy/gcode.py

444 lines
18 KiB
Python

# Parse gcode commands
#
# Copyright (C) 2016 Kevin O'Connor <kevin@koconnor.net>
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import os, re, logging, collections
import homing
# Parse out incoming GCode and find and translate head movements
class GCodeParser:
RETRY_TIME = 0.100
def __init__(self, printer, fd, is_fileinput=False):
self.printer = printer
self.fd = fd
self.is_fileinput = is_fileinput
# Input handling
self.reactor = printer.reactor
self.is_processing_data = False
self.fd_handle = None
if not is_fileinput:
self.fd_handle = self.reactor.register_fd(self.fd, self.process_data)
self.input_commands = [""]
self.bytes_read = 0
self.input_log = collections.deque([], 50)
# Command handling
self.gcode_handlers = self.build_handlers(False)
self.is_printer_ready = False
self.need_ack = False
self.toolhead = self.heater_nozzle = self.heater_bed = self.fan = None
self.speed = 25.0
self.absolutecoord = self.absoluteextrude = True
self.base_position = [0.0, 0.0, 0.0, 0.0]
self.last_position = [0.0, 0.0, 0.0, 0.0]
self.homing_add = [0.0, 0.0, 0.0, 0.0]
self.axis2pos = {'X': 0, 'Y': 1, 'Z': 2, 'E': 3}
def build_handlers(self, is_ready):
handlers = self.all_handlers
if not is_ready:
handlers = [h for h in handlers
if getattr(self, 'cmd_'+h+'_when_not_ready', False)]
gcode_handlers = dict((h, getattr(self, 'cmd_'+h)) for h in handlers)
for h, f in gcode_handlers.items():
aliases = getattr(self, 'cmd_'+h+'_aliases', [])
gcode_handlers.update(dict([(a, f) for a in aliases]))
return gcode_handlers
def stats(self, eventtime):
return "gcodein=%d" % (self.bytes_read,)
def set_printer_ready(self, is_ready):
if self.is_printer_ready == is_ready:
return
self.is_printer_ready = is_ready
self.gcode_handlers = self.build_handlers(is_ready)
if not is_ready:
# Printer is shutdown (could be running in a background thread)
return
# Lookup printer components
self.toolhead = self.printer.objects.get('toolhead')
self.heater_nozzle = None
extruder = self.printer.objects.get('extruder')
if extruder:
self.heater_nozzle = extruder.heater
self.heater_bed = self.printer.objects.get('heater_bed')
self.fan = self.printer.objects.get('fan')
if self.is_fileinput and self.fd_handle is None:
self.fd_handle = self.reactor.register_fd(self.fd, self.process_data)
def motor_heater_off(self):
if self.toolhead is None:
return
self.toolhead.motor_off()
print_time = self.toolhead.get_last_move_time()
if self.heater_nozzle is not None:
self.heater_nozzle.set_temp(print_time, 0.)
if self.heater_bed is not None:
self.heater_bed.set_temp(print_time, 0.)
if self.fan is not None:
self.fan.set_speed(print_time, 0.)
def dump_debug(self):
logging.info("Dumping gcode input %d blocks" % (
len(self.input_log),))
for eventtime, data in self.input_log:
logging.info("Read %f: %s" % (eventtime, repr(data)))
# Parse input into commands
args_r = re.compile('([a-zA-Z_]+|[a-zA-Z*])')
def process_commands(self, eventtime):
while len(self.input_commands) > 1:
line = self.input_commands.pop(0)
# Ignore comments and leading/trailing spaces
line = origline = line.strip()
cpos = line.find(';')
if cpos >= 0:
line = line[:cpos]
# Break command into parts
parts = self.args_r.split(line)[1:]
params = dict((parts[i].upper(), parts[i+1].strip())
for i in range(0, len(parts), 2))
params['#original'] = origline
if parts and parts[0].upper() == 'N':
# Skip line number at start of command
del parts[:2]
if not parts:
self.cmd_default(params)
continue
params['#command'] = cmd = parts[0].upper() + parts[1].strip()
# Invoke handler for command
self.need_ack = True
handler = self.gcode_handlers.get(cmd, self.cmd_default)
try:
handler(params)
except error, e:
self.respond_error(str(e))
except:
logging.exception("Exception in command handler")
self.toolhead.force_shutdown()
self.respond_error('Internal error on command:"%s"' % (cmd,))
if self.is_fileinput:
self.printer.request_exit('exit_eof')
break
self.ack()
def process_data(self, eventtime):
data = os.read(self.fd, 4096)
self.input_log.append((eventtime, data))
self.bytes_read += len(data)
lines = data.split('\n')
lines[0] = self.input_commands.pop() + lines[0]
self.input_commands.extend(lines)
if self.is_processing_data:
if len(lines) <= 1:
return
if not self.is_fileinput and lines[0].strip().upper() == 'M112':
self.cmd_M112({})
self.reactor.unregister_fd(self.fd_handle)
self.fd_handle = None
return
self.is_processing_data = True
self.process_commands(eventtime)
self.is_processing_data = False
if self.fd_handle is None:
self.fd_handle = self.reactor.register_fd(self.fd, self.process_data)
if not data and self.is_fileinput:
self.motor_heater_off()
self.printer.request_exit('exit_eof')
# Response handling
def ack(self, msg=None):
if not self.need_ack or self.is_fileinput:
return
if msg:
os.write(self.fd, "ok %s\n" % (msg,))
else:
os.write(self.fd, "ok\n")
self.need_ack = False
def respond(self, msg):
logging.debug(msg)
if self.is_fileinput:
return
os.write(self.fd, msg+"\n")
def respond_info(self, msg):
lines = [l.strip() for l in msg.strip().split('\n')]
self.respond("// " + "\n// ".join(lines))
def respond_error(self, msg):
lines = msg.strip().split('\n')
if len(lines) > 1:
self.respond_info("\n".join(lines[:-1]))
self.respond('!! %s' % (lines[-1].strip(),))
# Parameter parsing helpers
def get_int(self, name, params, default=None):
if name in params:
try:
return int(params[name])
except ValueError:
raise error("Error on '%s': unable to parse %s" % (
params['#original'], params[name]))
if default is not None:
return default
raise error("Error on '%s': missing %s" % (params['#original'], name))
def get_float(self, name, params, default=None):
if name in params:
try:
return float(params[name])
except ValueError:
raise error("Error on '%s': unable to parse %s" % (
params['#original'], params[name]))
if default is not None:
return default
raise error("Error on '%s': missing %s" % (params['#original'], name))
# Temperature wrappers
def get_temp(self):
if not self.is_printer_ready:
return "T:0"
# T:XXX /YYY B:XXX /YYY
out = []
if self.heater_nozzle:
cur, target = self.heater_nozzle.get_temp()
out.append("T:%.1f /%.1f" % (cur, target))
if self.heater_bed:
cur, target = self.heater_bed.get_temp()
out.append("B:%.1f /%.1f" % (cur, target))
return " ".join(out)
def bg_temp(self, heater):
if self.is_fileinput:
return
eventtime = self.reactor.monotonic()
while self.is_printer_ready and heater.check_busy(eventtime):
print_time = self.toolhead.get_last_move_time()
self.respond(self.get_temp())
eventtime = self.reactor.pause(eventtime + 1.)
def set_temp(self, heater, params, wait=False):
temp = self.get_float('S', params, 0.)
if heater is None:
if temp > 0.:
self.respond_error("Heater not configured")
return
print_time = self.toolhead.get_last_move_time()
try:
heater.set_temp(print_time, temp)
except heater.error, e:
self.respond_error(str(e))
return
if wait:
self.bg_temp(heater)
def set_fan_speed(self, speed):
if self.fan is None:
if speed:
self.respond_info("Fan not configured")
return
print_time = self.toolhead.get_last_move_time()
self.fan.set_speed(print_time, speed)
# Individual command handlers
def cmd_default(self, params):
if not self.is_printer_ready:
self.respond_error(self.printer.get_state_message())
return
cmd = params.get('#command')
if not cmd:
logging.debug(params['#original'])
return
self.respond('echo:Unknown command:"%s"' % (cmd,))
all_handlers = [
'G1', 'G4', 'G20', 'G28', 'G90', 'G91', 'G92',
'M82', 'M83', 'M18', 'M105', 'M104', 'M109', 'M112', 'M114', 'M115',
'M140', 'M190', 'M106', 'M107', 'M206', 'M400',
'IGNORE', 'QUERY_ENDSTOPS', 'PID_TUNE', 'RESTART', 'FIRMWARE_RESTART',
'STATUS', 'HELP']
cmd_G1_aliases = ['G0']
def cmd_G1(self, params):
# Move
try:
for a, p in self.axis2pos.items():
if a in params:
v = float(params[a])
if (not self.absolutecoord
or (p>2 and not self.absoluteextrude)):
# value relative to position of last move
self.last_position[p] += v
else:
# value relative to base coordinate position
self.last_position[p] = v + self.base_position[p]
if 'F' in params:
speed = float(params['F']) / 60.
if speed <= 0.:
raise ValueError()
self.speed = speed
except ValueError, e:
self.last_position = self.toolhead.get_position()
raise error("Unable to parse move '%s'" % (params['#original'],))
try:
self.toolhead.move(self.last_position, self.speed)
except homing.EndstopError, e:
self.respond_error(str(e))
self.last_position = self.toolhead.get_position()
def cmd_G4(self, params):
# Dwell
if 'S' in params:
delay = self.get_float('S', params)
else:
delay = self.get_float('P', params, 0.) / 1000.
self.toolhead.dwell(delay)
def cmd_G20(self, params):
# Set units to inches
self.respond_error('Machine does not support G20 (inches) command')
def cmd_G28(self, params):
# Move to origin
axes = []
for axis in 'XYZ':
if axis in params:
axes.append(self.axis2pos[axis])
if not axes:
axes = [0, 1, 2]
homing_state = homing.Homing(self.toolhead, axes)
if self.is_fileinput:
homing_state.set_no_verify_retract()
try:
self.toolhead.home(homing_state)
except homing.EndstopError, e:
self.toolhead.motor_off()
self.respond_error(str(e))
return
newpos = self.toolhead.get_position()
for axis in homing_state.get_axes():
self.last_position[axis] = newpos[axis]
self.base_position[axis] = -self.homing_add[axis]
def cmd_G90(self, params):
# Use absolute coordinates
self.absolutecoord = True
def cmd_G91(self, params):
# Use relative coordinates
self.absolutecoord = False
def cmd_G92(self, params):
# Set position
offsets = { p: self.get_float(a, params)
for a, p in self.axis2pos.items() if a in params }
for p, offset in offsets.items():
self.base_position[p] = self.last_position[p] - offset
if not offsets:
self.base_position = list(self.last_position)
def cmd_M82(self, params):
# Use absolute distances for extrusion
self.absoluteextrude = True
def cmd_M83(self, params):
# Use relative distances for extrusion
self.absoluteextrude = False
cmd_M18_aliases = ["M84"]
def cmd_M18(self, params):
# Turn off motors
self.toolhead.motor_off()
cmd_M105_when_not_ready = True
def cmd_M105(self, params):
# Get Extruder Temperature
self.ack(self.get_temp())
def cmd_M104(self, params):
# Set Extruder Temperature
self.set_temp(self.heater_nozzle, params)
def cmd_M109(self, params):
# Set Extruder Temperature and Wait
self.set_temp(self.heater_nozzle, params, wait=True)
def cmd_M112(self, params):
# Emergency Stop
self.toolhead.force_shutdown()
cmd_M114_when_not_ready = True
def cmd_M114(self, params):
# Get Current Position
if self.toolhead is None:
self.cmd_default(params)
return
kinpos = self.toolhead.get_position()
self.respond("X:%.3f Y:%.3f Z:%.3f E:%.3f Count X:%.3f Y:%.3f Z:%.3f" % (
self.last_position[0], self.last_position[1],
self.last_position[2], self.last_position[3],
kinpos[0], kinpos[1], kinpos[2]))
cmd_M115_when_not_ready = True
def cmd_M115(self, params):
# Get Firmware Version and Capabilities
kw = {"FIRMWARE_NAME": "Klipper"
, "FIRMWARE_VERSION": self.printer.software_version}
self.ack(" ".join(["%s:%s" % (k, v) for k, v in kw.items()]))
def cmd_M140(self, params):
# Set Bed Temperature
self.set_temp(self.heater_bed, params)
def cmd_M190(self, params):
# Set Bed Temperature and Wait
self.set_temp(self.heater_bed, params, wait=True)
def cmd_M106(self, params):
# Set fan speed
self.set_fan_speed(self.get_float('S', params, 255.) / 255.)
def cmd_M107(self, params):
# Turn fan off
self.set_fan_speed(0.)
def cmd_M206(self, params):
# Set home offset
offsets = { p: self.get_float(a, params)
for a, p in self.axis2pos.items() if a in params }
for p, offset in offsets.items():
self.base_position[p] += self.homing_add[p] - offset
self.homing_add[p] = offset
def cmd_M400(self, params):
# Wait for current moves to finish
self.toolhead.wait_moves()
cmd_IGNORE_when_not_ready = True
cmd_IGNORE_aliases = ["G21", "M110", "M21"]
def cmd_IGNORE(self, params):
# Commands that are just silently accepted
pass
cmd_QUERY_ENDSTOPS_help = "Report on the status of each endstop"
cmd_QUERY_ENDSTOPS_aliases = ["M119"]
def cmd_QUERY_ENDSTOPS(self, params):
# Get Endstop Status
if self.is_fileinput:
return
try:
res = self.toolhead.query_endstops()
except self.printer.mcu.error, e:
self.respond_error(str(e))
return
self.respond(" ".join(["%s:%s" % (name, ["open", "TRIGGERED"][not not t])
for name, t in res]))
cmd_PID_TUNE_help = "Run PID Tuning"
cmd_PID_TUNE_aliases = ["M303"]
def cmd_PID_TUNE(self, params):
# Run PID tuning
heater = self.get_int('E', params, 0)
heater = {0: self.heater_nozzle, -1: self.heater_bed}[heater]
if heater is None:
self.respond_error("Heater not configured")
temp = self.get_float('S', params)
heater.start_auto_tune(temp)
self.bg_temp(heater)
def prep_restart(self):
if self.is_printer_ready:
self.respond_info("Preparing to restart...")
self.motor_heater_off()
self.toolhead.dwell(0.500)
self.toolhead.wait_moves()
cmd_RESTART_when_not_ready = True
cmd_RESTART_help = "Reload config file and restart host software"
def cmd_RESTART(self, params):
self.prep_restart()
self.printer.request_exit('restart')
cmd_FIRMWARE_RESTART_when_not_ready = True
cmd_FIRMWARE_RESTART_help = "Restart firmware, host, and reload config"
def cmd_FIRMWARE_RESTART(self, params):
self.prep_restart()
self.printer.request_exit('firmware_restart')
cmd_STATUS_when_not_ready = True
cmd_STATUS_help = "Report the printer status"
def cmd_STATUS(self, params):
msg = self.printer.get_state_message()
if self.is_printer_ready:
self.respond_info(msg)
else:
self.respond_error(msg)
cmd_HELP_when_not_ready = True
def cmd_HELP(self, params):
cmdhelp = []
if not self.is_printer_ready:
cmdhelp.append("Printer is not ready - not all commands available.")
cmdhelp.append("Available extended commands:")
for cmd in sorted(self.gcode_handlers):
desc = getattr(self, 'cmd_'+cmd+'_help', None)
if desc is not None:
cmdhelp.append("%-10s: %s" % (cmd, desc))
self.respond_info("\n".join(cmdhelp))
class error(Exception):
pass