klipper-dgus/klippy/mcu.py

817 lines
37 KiB
Python

# Interface to Klipper micro-controller code
#
# Copyright (C) 2016-2020 Kevin O'Connor <kevin@koconnor.net>
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import sys, os, zlib, logging, math
import serialhdl, pins, chelper, clocksync
class error(Exception):
pass
class MCU_endstop:
RETRY_QUERY = 1.000
def __init__(self, mcu, pin_params):
self._mcu = mcu
self._steppers = []
self._pin = pin_params['pin']
self._pullup = pin_params['pullup']
self._invert = pin_params['invert']
self._reactor = mcu.get_printer().get_reactor()
self._oid = self._home_cmd = self._requery_cmd = self._query_cmd = None
self._mcu.register_config_callback(self._build_config)
self._min_query_time = self._last_sent_time = 0.
self._next_query_print_time = self._end_home_time = 0.
self._trigger_completion = self._home_completion = None
def get_mcu(self):
return self._mcu
def add_stepper(self, stepper):
if stepper.get_mcu() is not self._mcu:
raise pins.error("Endstop and stepper must be on the same mcu")
if stepper in self._steppers:
return
self._steppers.append(stepper)
def get_steppers(self):
return list(self._steppers)
def _build_config(self):
self._oid = self._mcu.create_oid()
self._mcu.add_config_cmd(
"config_endstop oid=%d pin=%s pull_up=%d stepper_count=%d" % (
self._oid, self._pin, self._pullup, len(self._steppers)))
self._mcu.add_config_cmd(
"endstop_home oid=%d clock=0 sample_ticks=0 sample_count=0"
" rest_ticks=0 pin_value=0" % (self._oid,), on_restart=True)
for i, s in enumerate(self._steppers):
self._mcu.add_config_cmd(
"endstop_set_stepper oid=%d pos=%d stepper_oid=%d" % (
self._oid, i, s.get_oid()), is_init=True)
cmd_queue = self._mcu.alloc_command_queue()
self._home_cmd = self._mcu.lookup_command(
"endstop_home oid=%c clock=%u sample_ticks=%u sample_count=%c"
" rest_ticks=%u pin_value=%c", cq=cmd_queue)
self._requery_cmd = self._mcu.lookup_command(
"endstop_query_state oid=%c", cq=cmd_queue)
self._query_cmd = self._mcu.lookup_query_command(
"endstop_query_state oid=%c",
"endstop_state oid=%c homing=%c pin_value=%c", oid=self._oid,
cq=cmd_queue)
def home_start(self, print_time, sample_time, sample_count, rest_time,
triggered=True):
clock = self._mcu.print_time_to_clock(print_time)
rest_ticks = self._mcu.print_time_to_clock(print_time+rest_time) - clock
self._next_query_print_time = print_time + self.RETRY_QUERY
self._min_query_time = self._reactor.monotonic()
self._last_sent_time = 0.
self._home_end_time = self._reactor.NEVER
self._trigger_completion = self._reactor.completion()
self._mcu.register_response(self._handle_endstop_state,
"endstop_state", self._oid)
self._home_cmd.send(
[self._oid, clock, self._mcu.seconds_to_clock(sample_time),
sample_count, rest_ticks, triggered ^ self._invert],
reqclock=clock)
self._home_completion = self._reactor.register_callback(
self._home_retry)
return self._trigger_completion
def _handle_endstop_state(self, params):
logging.debug("endstop_state %s", params)
if params['#sent_time'] >= self._min_query_time:
if params['homing']:
self._last_sent_time = params['#sent_time']
else:
self._min_query_time = self._reactor.NEVER
self._reactor.async_complete(self._trigger_completion, True)
def _home_retry(self, eventtime):
if self._mcu.is_fileoutput():
return True
while 1:
did_trigger = self._trigger_completion.wait(eventtime + 0.100)
if did_trigger is not None:
# Homing completed successfully
return True
# Check for timeout
last = self._mcu.estimated_print_time(self._last_sent_time)
if last > self._home_end_time or self._mcu.is_shutdown():
return False
# Check for resend
eventtime = self._reactor.monotonic()
est_print_time = self._mcu.estimated_print_time(eventtime)
if est_print_time >= self._next_query_print_time:
self._next_query_print_time = est_print_time + self.RETRY_QUERY
self._requery_cmd.send([self._oid])
def home_wait(self, home_end_time):
self._home_end_time = home_end_time
did_trigger = self._home_completion.wait()
self._mcu.register_response(None, "endstop_state", self._oid)
self._home_cmd.send([self._oid, 0, 0, 0, 0, 0])
for s in self._steppers:
s.note_homing_end(did_trigger=did_trigger)
if not self._trigger_completion.test():
self._trigger_completion.complete(False)
return did_trigger
def query_endstop(self, print_time):
clock = self._mcu.print_time_to_clock(print_time)
if self._mcu.is_fileoutput():
return 0
params = self._query_cmd.send([self._oid], minclock=clock)
return params['pin_value'] ^ self._invert
class MCU_digital_out:
def __init__(self, mcu, pin_params):
self._mcu = mcu
self._oid = None
self._mcu.register_config_callback(self._build_config)
self._pin = pin_params['pin']
self._invert = pin_params['invert']
self._start_value = self._shutdown_value = self._invert
self._is_static = False
self._max_duration = 2.
self._last_clock = 0
self._set_cmd = None
def get_mcu(self):
return self._mcu
def setup_max_duration(self, max_duration):
self._max_duration = max_duration
def setup_start_value(self, start_value, shutdown_value, is_static=False):
if is_static and start_value != shutdown_value:
raise pins.error("Static pin can not have shutdown value")
self._start_value = (not not start_value) ^ self._invert
self._shutdown_value = (not not shutdown_value) ^ self._invert
self._is_static = is_static
def _build_config(self):
if self._is_static:
self._mcu.add_config_cmd("set_digital_out pin=%s value=%d"
% (self._pin, self._start_value))
return
self._oid = self._mcu.create_oid()
self._mcu.add_config_cmd(
"config_digital_out oid=%d pin=%s value=%d default_value=%d"
" max_duration=%d" % (
self._oid, self._pin, self._start_value, self._shutdown_value,
self._mcu.seconds_to_clock(self._max_duration)))
self._mcu.add_config_cmd("update_digital_out oid=%d value=%d"
% (self._oid, self._start_value),
on_restart=True)
cmd_queue = self._mcu.alloc_command_queue()
self._set_cmd = self._mcu.lookup_command(
"schedule_digital_out oid=%c clock=%u value=%c", cq=cmd_queue)
def set_digital(self, print_time, value):
clock = self._mcu.print_time_to_clock(print_time)
self._set_cmd.send([self._oid, clock, (not not value) ^ self._invert],
minclock=self._last_clock, reqclock=clock)
self._last_clock = clock
def set_pwm(self, print_time, value, cycle_time=None):
self.set_digital(print_time, value >= 0.5)
class MCU_pwm:
def __init__(self, mcu, pin_params):
self._mcu = mcu
self._hardware_pwm = False
self._cycle_time = 0.100
self._max_duration = 2.
self._oid = None
self._mcu.register_config_callback(self._build_config)
self._pin = pin_params['pin']
self._invert = pin_params['invert']
self._start_value = self._shutdown_value = float(self._invert)
self._is_static = False
self._last_clock = 0
self._pwm_max = 0.
self._set_cmd = None
def get_mcu(self):
return self._mcu
def setup_max_duration(self, max_duration):
self._max_duration = max_duration
def setup_cycle_time(self, cycle_time, hardware_pwm=False):
self._cycle_time = cycle_time
self._hardware_pwm = hardware_pwm
def setup_start_value(self, start_value, shutdown_value, is_static=False):
if is_static and start_value != shutdown_value:
raise pins.error("Static pin can not have shutdown value")
if self._invert:
start_value = 1. - start_value
shutdown_value = 1. - shutdown_value
self._start_value = max(0., min(1., start_value))
self._shutdown_value = max(0., min(1., shutdown_value))
self._is_static = is_static
def _build_config(self):
cmd_queue = self._mcu.alloc_command_queue()
cycle_ticks = self._mcu.seconds_to_clock(self._cycle_time)
if self._hardware_pwm:
self._pwm_max = self._mcu.get_constant_float("PWM_MAX")
if self._is_static:
self._mcu.add_config_cmd(
"set_pwm_out pin=%s cycle_ticks=%d value=%d"
% (self._pin, cycle_ticks,
self._start_value * self._pwm_max))
return
self._oid = self._mcu.create_oid()
self._mcu.add_config_cmd(
"config_pwm_out oid=%d pin=%s cycle_ticks=%d value=%d"
" default_value=%d max_duration=%d"
% (self._oid, self._pin, cycle_ticks,
self._start_value * self._pwm_max,
self._shutdown_value * self._pwm_max,
self._mcu.seconds_to_clock(self._max_duration)))
curtime = self._mcu.get_printer().get_reactor().monotonic()
printtime = self._mcu.estimated_print_time(curtime)
self._last_clock = self._mcu.print_time_to_clock(printtime + 0.100)
svalue = int(self._start_value * self._pwm_max + 0.5)
self._mcu.add_config_cmd("schedule_pwm_out oid=%d clock=%d value=%d"
% (self._oid, self._last_clock, svalue),
on_restart=True)
self._set_cmd = self._mcu.lookup_command(
"schedule_pwm_out oid=%c clock=%u value=%hu", cq=cmd_queue)
return
# Software PWM
if self._shutdown_value not in [0., 1.]:
raise pins.error("shutdown value must be 0.0 or 1.0 on soft pwm")
self._pwm_max = float(cycle_ticks)
if self._is_static:
self._mcu.add_config_cmd("set_digital_out pin=%s value=%d"
% (self._pin, self._start_value >= 0.5))
return
self._oid = self._mcu.create_oid()
self._mcu.add_config_cmd(
"config_soft_pwm_out oid=%d pin=%s value=%d"
" default_value=%d max_duration=%d"
% (self._oid, self._pin, self._start_value >= 1.0,
self._shutdown_value >= 0.5,
self._mcu.seconds_to_clock(self._max_duration)))
curtime = self._mcu.get_printer().get_reactor().monotonic()
printtime = self._mcu.estimated_print_time(curtime)
self._last_clock = self._mcu.print_time_to_clock(printtime + 0.100)
svalue = int(self._start_value * self._pwm_max + 0.5)
self._mcu.add_config_cmd(
"schedule_soft_pwm_out oid=%d clock=%d on_ticks=%d off_ticks=%d"
% (self._oid, self._last_clock, svalue, cycle_ticks - svalue),
is_init=True)
self._set_cmd = self._mcu.lookup_command(
"schedule_soft_pwm_out oid=%c clock=%u on_ticks=%u off_ticks=%u",
cq=cmd_queue)
def set_pwm(self, print_time, value, cycle_time=None):
clock = self._mcu.print_time_to_clock(print_time)
minclock = self._last_clock
self._last_clock = clock
if self._invert:
value = 1. - value
if self._hardware_pwm:
v = int(max(0., min(1., value)) * self._pwm_max + 0.5)
self._set_cmd.send([self._oid, clock, v],
minclock=minclock, reqclock=clock)
return
# Soft pwm update
if cycle_time is None:
cycle_time = self._cycle_time
cycle_ticks = self._mcu.seconds_to_clock(cycle_time)
on_ticks = int(max(0., min(1., value)) * float(cycle_ticks) + 0.5)
self._set_cmd.send([self._oid, clock, on_ticks, cycle_ticks - on_ticks],
minclock=minclock, reqclock=clock)
class MCU_adc:
def __init__(self, mcu, pin_params):
self._mcu = mcu
self._pin = pin_params['pin']
self._min_sample = self._max_sample = 0.
self._sample_time = self._report_time = 0.
self._sample_count = self._range_check_count = 0
self._report_clock = 0
self._last_state = (0., 0.)
self._oid = self._callback = None
self._mcu.register_config_callback(self._build_config)
self._inv_max_adc = 0.
def get_mcu(self):
return self._mcu
def setup_minmax(self, sample_time, sample_count,
minval=0., maxval=1., range_check_count=0):
self._sample_time = sample_time
self._sample_count = sample_count
self._min_sample = minval
self._max_sample = maxval
self._range_check_count = range_check_count
def setup_adc_callback(self, report_time, callback):
self._report_time = report_time
self._callback = callback
def get_last_value(self):
return self._last_state
def _build_config(self):
if not self._sample_count:
return
self._oid = self._mcu.create_oid()
self._mcu.add_config_cmd("config_analog_in oid=%d pin=%s" % (
self._oid, self._pin))
clock = self._mcu.get_query_slot(self._oid)
sample_ticks = self._mcu.seconds_to_clock(self._sample_time)
mcu_adc_max = self._mcu.get_constant_float("ADC_MAX")
max_adc = self._sample_count * mcu_adc_max
self._inv_max_adc = 1.0 / max_adc
self._report_clock = self._mcu.seconds_to_clock(self._report_time)
min_sample = max(0, min(0xffff, int(self._min_sample * max_adc)))
max_sample = max(0, min(0xffff, int(
math.ceil(self._max_sample * max_adc))))
self._mcu.add_config_cmd(
"query_analog_in oid=%d clock=%d sample_ticks=%d sample_count=%d"
" rest_ticks=%d min_value=%d max_value=%d range_check_count=%d" % (
self._oid, clock, sample_ticks, self._sample_count,
self._report_clock, min_sample, max_sample,
self._range_check_count), is_init=True)
self._mcu.register_response(self._handle_analog_in_state,
"analog_in_state", self._oid)
def _handle_analog_in_state(self, params):
last_value = params['value'] * self._inv_max_adc
next_clock = self._mcu.clock32_to_clock64(params['next_clock'])
last_read_clock = next_clock - self._report_clock
last_read_time = self._mcu.clock_to_print_time(last_read_clock)
self._last_state = (last_value, last_read_time)
if self._callback is not None:
self._callback(last_read_time, last_value)
# Class to retry sending of a query command until a given response is received
class RetryAsyncCommand:
TIMEOUT_TIME = 5.0
RETRY_TIME = 0.500
def __init__(self, serial, name, oid=None):
self.serial = serial
self.name = name
self.oid = oid
self.reactor = serial.get_reactor()
self.completion = self.reactor.completion()
self.min_query_time = self.reactor.monotonic()
self.serial.register_response(self.handle_callback, name, oid)
def handle_callback(self, params):
if params['#sent_time'] >= self.min_query_time:
self.min_query_time = self.reactor.NEVER
self.reactor.async_complete(self.completion, params)
def get_response(self, cmd, cmd_queue, minclock=0):
self.serial.raw_send_wait_ack(cmd, minclock, minclock, cmd_queue)
first_query_time = query_time = self.reactor.monotonic()
while 1:
params = self.completion.wait(query_time + self.RETRY_TIME)
if params is not None:
self.serial.register_response(None, self.name, self.oid)
return params
query_time = self.reactor.monotonic()
if query_time > first_query_time + self.TIMEOUT_TIME:
self.serial.register_response(None, self.name, self.oid)
raise error("Timeout on wait for '%s' response" % (self.name,))
self.serial.raw_send(cmd, minclock, minclock, cmd_queue)
# Wrapper around query commands
class CommandQueryWrapper:
def __init__(self, serial, msgformat, respformat, oid=None,
cmd_queue=None, is_async=False):
self._serial = serial
self._cmd = serial.get_msgparser().lookup_command(msgformat)
serial.get_msgparser().lookup_command(respformat)
self._response = respformat.split()[0]
self._oid = oid
self._xmit_helper = serialhdl.SerialRetryCommand
if is_async:
self._xmit_helper = RetryAsyncCommand
if cmd_queue is None:
cmd_queue = serial.get_default_command_queue()
self._cmd_queue = cmd_queue
def send(self, data=(), minclock=0):
cmd = self._cmd.encode(data)
xh = self._xmit_helper(self._serial, self._response, self._oid)
try:
return xh.get_response(cmd, self._cmd_queue, minclock=minclock)
except serialhdl.error as e:
raise error(str(e))
# Wrapper around command sending
class CommandWrapper:
def __init__(self, serial, msgformat, cmd_queue=None):
self._serial = serial
self._cmd = serial.get_msgparser().lookup_command(msgformat)
if cmd_queue is None:
cmd_queue = serial.get_default_command_queue()
self._cmd_queue = cmd_queue
def send(self, data=(), minclock=0, reqclock=0):
cmd = self._cmd.encode(data)
self._serial.raw_send(cmd, minclock, reqclock, self._cmd_queue)
class MCU:
error = error
def __init__(self, config, clocksync):
self._printer = config.get_printer()
self._clocksync = clocksync
self._reactor = self._printer.get_reactor()
self._name = config.get_name()
if self._name.startswith('mcu '):
self._name = self._name[4:]
self._printer.register_event_handler("klippy:connect", self._connect)
self._printer.register_event_handler("klippy:mcu_identify",
self._mcu_identify)
self._printer.register_event_handler("klippy:shutdown", self._shutdown)
self._printer.register_event_handler("klippy:disconnect",
self._disconnect)
# Serial port
self._serialport = config.get('serial', '/dev/ttyS0')
serial_rts = True
if config.get('restart_method', None) == "cheetah":
# Special case: Cheetah boards require RTS to be deasserted, else
# a reset will trigger the built-in bootloader.
serial_rts = False
baud = 0
if not (self._serialport.startswith("/dev/rpmsg_")
or self._serialport.startswith("/tmp/klipper_host_")):
baud = config.getint('baud', 250000, minval=2400)
self._serial = serialhdl.SerialReader(
self._reactor, self._serialport, baud, serial_rts)
# Restarts
self._restart_method = 'command'
if baud:
rmethods = {m: m for m in [None, 'arduino', 'cheetah', 'command',
'rpi_usb']}
self._restart_method = config.getchoice(
'restart_method', rmethods, None)
self._reset_cmd = self._config_reset_cmd = None
self._emergency_stop_cmd = None
self._is_shutdown = self._is_timeout = False
self._shutdown_msg = ""
# Config building
self._printer.lookup_object('pins').register_chip(self._name, self)
self._oid_count = 0
self._config_callbacks = []
self._config_cmds = []
self._restart_cmds = []
self._init_cmds = []
self._pin_map = config.get('pin_map', None)
self._mcu_freq = 0.
# Move command queuing
ffi_main, self._ffi_lib = chelper.get_ffi()
self._max_stepper_error = config.getfloat('max_stepper_error', 0.000025,
minval=0.)
self._stepqueues = []
self._steppersync = None
# Stats
self._stats_sumsq_base = 0.
self._mcu_tick_avg = 0.
self._mcu_tick_stddev = 0.
self._mcu_tick_awake = 0.
# Serial callbacks
def _handle_mcu_stats(self, params):
count = params['count']
tick_sum = params['sum']
c = 1.0 / (count * self._mcu_freq)
self._mcu_tick_avg = tick_sum * c
tick_sumsq = params['sumsq'] * self._stats_sumsq_base
diff = count*tick_sumsq - tick_sum**2
self._mcu_tick_stddev = c * math.sqrt(max(0., diff))
self._mcu_tick_awake = tick_sum / self._mcu_freq
def _handle_shutdown(self, params):
if self._is_shutdown:
return
self._is_shutdown = True
self._shutdown_msg = msg = params['static_string_id']
logging.info("MCU '%s' %s: %s\n%s\n%s", self._name, params['#name'],
self._shutdown_msg, self._clocksync.dump_debug(),
self._serial.dump_debug())
prefix = "MCU '%s' shutdown: " % (self._name,)
if params['#name'] == 'is_shutdown':
prefix = "Previous MCU '%s' shutdown: " % (self._name,)
self._printer.invoke_async_shutdown(prefix + msg + error_help(msg))
def _handle_starting(self, params):
if not self._is_shutdown:
self._printer.invoke_async_shutdown("MCU '%s' spontaneous restart"
% (self._name,))
# Connection phase
def _check_restart(self, reason):
start_reason = self._printer.get_start_args().get("start_reason")
if start_reason == 'firmware_restart':
return
logging.info("Attempting automated MCU '%s' restart: %s",
self._name, reason)
self._printer.request_exit('firmware_restart')
self._reactor.pause(self._reactor.monotonic() + 2.000)
raise error("Attempt MCU '%s' restart failed" % (self._name,))
def _connect_file(self, pace=False):
# In a debugging mode. Open debug output file and read data dictionary
start_args = self._printer.get_start_args()
if self._name == 'mcu':
out_fname = start_args.get('debugoutput')
dict_fname = start_args.get('dictionary')
else:
out_fname = start_args.get('debugoutput') + "-" + self._name
dict_fname = start_args.get('dictionary_' + self._name)
outfile = open(out_fname, 'wb')
dfile = open(dict_fname, 'rb')
dict_data = dfile.read()
dfile.close()
self._serial.connect_file(outfile, dict_data)
self._clocksync.connect_file(self._serial, pace)
# Handle pacing
if not pace:
def dummy_estimated_print_time(eventtime):
return 0.
self.estimated_print_time = dummy_estimated_print_time
def _send_config(self, prev_crc):
# Build config commands
for cb in self._config_callbacks:
cb()
self._config_cmds.insert(0, "allocate_oids count=%d"
% (self._oid_count,))
# Resolve pin names
mcu_type = self._serial.get_msgparser().get_constant('MCU')
ppins = self._printer.lookup_object('pins')
pin_resolver = ppins.get_pin_resolver(self._name)
if self._pin_map is not None:
pin_resolver.add_pin_mapping(mcu_type, self._pin_map)
for cmdlist in (self._config_cmds, self._restart_cmds, self._init_cmds):
for i, cmd in enumerate(cmdlist):
cmdlist[i] = pin_resolver.update_command(cmd)
# Calculate config CRC
config_crc = zlib.crc32('\n'.join(self._config_cmds)) & 0xffffffff
self.add_config_cmd("finalize_config crc=%d" % (config_crc,))
if prev_crc is not None and config_crc != prev_crc:
self._check_restart("CRC mismatch")
raise error("MCU '%s' CRC does not match config" % (self._name,))
# Transmit config messages (if needed)
self.register_response(self._handle_starting, 'starting')
if prev_crc is None:
logging.info("Sending MCU '%s' printer configuration...",
self._name)
for c in self._config_cmds:
self._serial.send(c)
else:
for c in self._restart_cmds:
self._serial.send(c)
# Transmit init messages
for c in self._init_cmds:
self._serial.send(c)
def _send_get_config(self):
get_config_cmd = self.lookup_query_command(
"get_config",
"config is_config=%c crc=%u move_count=%hu is_shutdown=%c")
if self.is_fileoutput():
return { 'is_config': 0, 'move_count': 500, 'crc': 0 }
config_params = get_config_cmd.send()
if self._is_shutdown:
raise error("MCU '%s' error during config: %s" % (
self._name, self._shutdown_msg))
if config_params['is_shutdown']:
raise error("Can not update MCU '%s' config as it is shutdown" % (
self._name,))
return config_params
def _log_info(self):
msgparser = self._serial.get_msgparser()
log_info = [
"Loaded MCU '%s' %d commands (%s / %s)" % (
self._name, len(msgparser.messages_by_id),
msgparser.version, msgparser.build_versions),
"MCU '%s' config: %s" % (self._name, " ".join(
["%s=%s" % (k, v) for k, v in self.get_constants().items()]))]
return "\n".join(log_info)
def _connect(self):
config_params = self._send_get_config()
if not config_params['is_config']:
if self._restart_method == 'rpi_usb':
# Only configure mcu after usb power reset
self._check_restart("full reset before config")
# Not configured - send config and issue get_config again
self._send_config(None)
config_params = self._send_get_config()
if not config_params['is_config'] and not self.is_fileoutput():
raise error("Unable to configure MCU '%s'" % (self._name,))
else:
start_reason = self._printer.get_start_args().get("start_reason")
if start_reason == 'firmware_restart':
raise error("Failed automated reset of MCU '%s'"
% (self._name,))
# Already configured - send init commands
self._send_config(config_params['crc'])
# Setup steppersync with the move_count returned by get_config
move_count = config_params['move_count']
ffi_main, ffi_lib = chelper.get_ffi()
self._steppersync = ffi_main.gc(
ffi_lib.steppersync_alloc(self._serial.serialqueue,
self._stepqueues, len(self._stepqueues),
move_count),
ffi_lib.steppersync_free)
ffi_lib.steppersync_set_time(self._steppersync, 0., self._mcu_freq)
# Log config information
move_msg = "Configured MCU '%s' (%d moves)" % (self._name, move_count)
logging.info(move_msg)
log_info = self._log_info() + "\n" + move_msg
self._printer.set_rollover_info(self._name, log_info, log=False)
def _mcu_identify(self):
if self.is_fileoutput():
self._connect_file()
else:
if (self._restart_method == 'rpi_usb'
and not os.path.exists(self._serialport)):
# Try toggling usb power
self._check_restart("enable power")
try:
self._serial.connect()
self._clocksync.connect(self._serial)
except serialhdl.error as e:
raise error(str(e))
logging.info(self._log_info())
ppins = self._printer.lookup_object('pins')
pin_resolver = ppins.get_pin_resolver(self._name)
for cname, value in self.get_constants().items():
if cname.startswith("RESERVE_PINS_"):
for pin in value.split(','):
pin_resolver.reserve_pin(pin, cname[13:])
self._mcu_freq = self.get_constant_float('CLOCK_FREQ')
self._stats_sumsq_base = self.get_constant_float('STATS_SUMSQ_BASE')
self._emergency_stop_cmd = self.lookup_command("emergency_stop")
self._reset_cmd = self.try_lookup_command("reset")
self._config_reset_cmd = self.try_lookup_command("config_reset")
ext_only = self._reset_cmd is None and self._config_reset_cmd is None
mbaud = self._serial.get_msgparser().get_constant('SERIAL_BAUD', None)
if self._restart_method is None and mbaud is None and not ext_only:
self._restart_method = 'command'
self.register_response(self._handle_shutdown, 'shutdown')
self.register_response(self._handle_shutdown, 'is_shutdown')
self.register_response(self._handle_mcu_stats, 'stats')
# Config creation helpers
def setup_pin(self, pin_type, pin_params):
pcs = {'endstop': MCU_endstop,
'digital_out': MCU_digital_out, 'pwm': MCU_pwm, 'adc': MCU_adc}
if pin_type not in pcs:
raise pins.error("pin type %s not supported on mcu" % (pin_type,))
return pcs[pin_type](self, pin_params)
def create_oid(self):
self._oid_count += 1
return self._oid_count - 1
def register_config_callback(self, cb):
self._config_callbacks.append(cb)
def add_config_cmd(self, cmd, is_init=False, on_restart=False):
if is_init:
self._init_cmds.append(cmd)
elif on_restart:
self._restart_cmds.append(cmd)
else:
self._config_cmds.append(cmd)
def get_query_slot(self, oid):
slot = self.seconds_to_clock(oid * .01)
t = int(self.estimated_print_time(self._reactor.monotonic()) + 1.5)
return self.print_time_to_clock(t) + slot
def register_stepqueue(self, stepqueue):
self._stepqueues.append(stepqueue)
def seconds_to_clock(self, time):
return int(time * self._mcu_freq)
def get_max_stepper_error(self):
return self._max_stepper_error
# Wrapper functions
def get_printer(self):
return self._printer
def get_name(self):
return self._name
def register_response(self, cb, msg, oid=None):
self._serial.register_response(cb, msg, oid)
def alloc_command_queue(self):
return self._serial.alloc_command_queue()
def lookup_command(self, msgformat, cq=None):
return CommandWrapper(self._serial, msgformat, cq)
def lookup_query_command(self, msgformat, respformat, oid=None,
cq=None, is_async=False):
return CommandQueryWrapper(self._serial, msgformat, respformat, oid,
cq, is_async)
def try_lookup_command(self, msgformat):
try:
return self.lookup_command(msgformat)
except self._serial.get_msgparser().error as e:
return None
def lookup_command_id(self, msgformat):
return self._serial.get_msgparser().lookup_command(msgformat).msgid
def get_enumerations(self):
return self._serial.get_msgparser().get_enumerations()
def get_constants(self):
return self._serial.get_msgparser().get_constants()
def get_constant_float(self, name):
return self._serial.get_msgparser().get_constant_float(name)
def print_time_to_clock(self, print_time):
return self._clocksync.print_time_to_clock(print_time)
def clock_to_print_time(self, clock):
return self._clocksync.clock_to_print_time(clock)
def estimated_print_time(self, eventtime):
return self._clocksync.estimated_print_time(eventtime)
def clock32_to_clock64(self, clock32):
return self._clocksync.clock32_to_clock64(clock32)
# Restarts
def _disconnect(self):
self._serial.disconnect()
self._steppersync = None
def _shutdown(self, force=False):
if (self._emergency_stop_cmd is None
or (self._is_shutdown and not force)):
return
self._emergency_stop_cmd.send()
def _restart_arduino(self):
logging.info("Attempting MCU '%s' reset", self._name)
self._disconnect()
serialhdl.arduino_reset(self._serialport, self._reactor)
def _restart_cheetah(self):
logging.info("Attempting MCU '%s' Cheetah-style reset", self._name)
self._disconnect()
serialhdl.cheetah_reset(self._serialport, self._reactor)
def _restart_via_command(self):
if ((self._reset_cmd is None and self._config_reset_cmd is None)
or not self._clocksync.is_active()):
logging.info("Unable to issue reset command on MCU '%s'",
self._name)
return
if self._reset_cmd is None:
# Attempt reset via config_reset command
logging.info("Attempting MCU '%s' config_reset command", self._name)
self._is_shutdown = True
self._shutdown(force=True)
self._reactor.pause(self._reactor.monotonic() + 0.015)
self._config_reset_cmd.send()
else:
# Attempt reset via reset command
logging.info("Attempting MCU '%s' reset command", self._name)
self._reset_cmd.send()
self._reactor.pause(self._reactor.monotonic() + 0.015)
self._disconnect()
def _restart_rpi_usb(self):
logging.info("Attempting MCU '%s' reset via rpi usb power", self._name)
self._disconnect()
chelper.run_hub_ctrl(0)
self._reactor.pause(self._reactor.monotonic() + 2.)
chelper.run_hub_ctrl(1)
def microcontroller_restart(self):
if self._restart_method == 'rpi_usb':
self._restart_rpi_usb()
elif self._restart_method == 'command':
self._restart_via_command()
elif self._restart_method == 'cheetah':
self._restart_cheetah()
else:
self._restart_arduino()
# Misc external commands
def is_fileoutput(self):
return self._printer.get_start_args().get('debugoutput') is not None
def is_shutdown(self):
return self._is_shutdown
def flush_moves(self, print_time):
if self._steppersync is None:
return
clock = self.print_time_to_clock(print_time)
if clock < 0:
return
ret = self._ffi_lib.steppersync_flush(self._steppersync, clock)
if ret:
raise error("Internal error in MCU '%s' stepcompress"
% (self._name,))
def check_active(self, print_time, eventtime):
if self._steppersync is None:
return
offset, freq = self._clocksync.calibrate_clock(print_time, eventtime)
self._ffi_lib.steppersync_set_time(self._steppersync, offset, freq)
if (self._clocksync.is_active() or self.is_fileoutput()
or self._is_timeout):
return
self._is_timeout = True
logging.info("Timeout with MCU '%s' (eventtime=%f)",
self._name, eventtime)
self._printer.invoke_shutdown("Lost communication with MCU '%s'" % (
self._name,))
def stats(self, eventtime):
msg = "%s: mcu_awake=%.03f mcu_task_avg=%.06f mcu_task_stddev=%.06f" % (
self._name, self._mcu_tick_awake, self._mcu_tick_avg,
self._mcu_tick_stddev)
return False, ' '.join([msg, self._serial.stats(eventtime),
self._clocksync.stats(eventtime)])
Common_MCU_errors = {
("Timer too close", "No next step", "Missed scheduling of next "): """
This is generally indicative of an intermittent
communication failure between micro-controller and host.""",
("ADC out of range",): """
This generally occurs when a heater temperature exceeds
its configured min_temp or max_temp.""",
("Rescheduled timer in the past", "Stepper too far in past"): """
This generally occurs when the micro-controller has been
requested to step at a rate higher than it is capable of
obtaining.""",
("Command request",): """
This generally occurs in response to an M112 G-Code command
or in response to an internal error in the host software.""",
}
def error_help(msg):
for prefixes, help_msg in Common_MCU_errors.items():
for prefix in prefixes:
if msg.startswith(prefix):
return help_msg
return ""
def add_printer_objects(config):
printer = config.get_printer()
reactor = printer.get_reactor()
mainsync = clocksync.ClockSync(reactor)
printer.add_object('mcu', MCU(config.getsection('mcu'), mainsync))
for s in config.get_prefix_sections('mcu '):
printer.add_object(s.section, MCU(
s, clocksync.SecondarySync(reactor, mainsync)))
def get_printer_mcu(printer, name):
if name == 'mcu':
return printer.lookup_object(name)
return printer.lookup_object('mcu ' + name)