def __init__(self, settings, platform_info=None):
# Fulfill singleton factory.
TerkinDatalogger.__instance__ = self
# Obtain configuration settings.
self.settings = TerkinConfiguration()
self.settings.add(settings)
self.settings.add_user_file()
self.application_info = ApplicationInfo(name=self.name,
version=self.version,
settings=self.settings,
application=self,
platform_info=platform_info)
# Configure logging.
logging_enabled = self.settings.get('main.logging.enabled', False)
if not logging_enabled:
log.info('Disabling logging to save bytes')
logging.disable_logging()
# Initialize transient storage.
self.storage = TransientStorage()
# Initialize device.
self.device = TerkinDevice(self.application_info)
# Button manager instance (optional).
self.button_manager = None
# Initialize sensor domain.
self.sensor_manager = SensorManager()
self.duty_chrono = GenericChronometer()
def __init__(self, settings, platform_info: PlatformInfo = None):
# Reference to the chronometer used for general timekeeping.
self.duty_chrono = bootloader.duty_chrono
# Signal startup with first available timestamp.
log.info('Starting Terkin datalogger')
# Obtain configuration settings.
self.settings = TerkinConfiguration()
self.settings.add(settings)
self.settings.add_user_file()
# Configure logging.
logging_enabled = self.settings.get('main.logging.enabled', False)
if not logging_enabled:
log.info('Disabling logging to save bytes')
logging.disable_logging()
# Initialize ApplicationInfo object.
self.application_info = ApplicationInfo(
name=self.name, version=self.version, settings=self.settings,
application=self, platform_info=platform_info)
# Initialize transient storage.
self.storage = TransientStorage()
# Initialize device.
self.device = TerkinDevice(self.application_info)
# Button manager instance (optional).
self.button_manager = None
# Initialize sensor domain.
self.sensor_manager = SensorManager(self.settings)
def __init__(self, settings):
# Obtain configuration settings.
self.settings = TerkinConfiguration()
self.settings.add(settings)
# Configure logging.
logging_enabled = self.settings.get('main.logging.enabled', False)
if not logging_enabled:
logging.disable_logging()
# Initialize device.
self.device = TerkinDevice(name=self.name, version=self.version, settings=self.settings)
# Button manager instance (optional).
self.button_manager = None
# Initialize sensor domain.
self.sensor_manager = SensorManager()
def includeme(sensor_manager: SensorManager, sensor_info):
"""
Create DS18x20 sensor object.
:param sensor_manager:
:param sensor_info:
:return: sensor_object
"""
sensor_object = DS18x20Sensor(settings=sensor_info)
sensor_bus = sensor_manager.get_bus_by_name(sensor_info.get('bus'))
sensor_object.acquire_bus(sensor_bus)
return sensor_object
class TerkinDatalogger:
# Application metadata.
name = 'Terkin MicroPython Datalogger'
version = __version__
def __init__(self, settings):
# Obtain configuration settings.
self.settings = TerkinConfiguration()
self.settings.add(settings)
# Configure logging.
logging_enabled = self.settings.get('main.logging.enabled', False)
if not logging_enabled:
logging.disable_logging()
# Initialize device.
self.device = TerkinDevice(name=self.name, version=self.version, settings=self.settings)
# Button manager instance (optional).
self.button_manager = None
# Initialize sensor domain.
self.sensor_manager = SensorManager()
@property
def appname(self):
return '{} {}'.format(self.name, self.version)
def start(self):
# Report about wakeup reason and run wakeup tasks.
self.device.resume()
# Turn off LTE modem and Bluetooth as we don't use them yet.
# Todo: Revisit where this should actually go.
self.device.power_off_lte_modem()
self.device.power_off_bluetooth()
log.info('Starting %s', self.appname)
# Start the watchdog for sanity.
self.device.start_watchdog()
# Configure RGB-LED according to settings.
self.device.configure_rgb_led()
# Dump configuration settings.
log_configuration = self.settings.get('main.logging.configuration', False)
if log_configuration:
self.settings.dump()
# Initialize buttons / touch pads.
buttons_enabled = self.settings.get('sensors.system.buttons.enabled', False)
if buttons_enabled:
self.button_manager = ButtonManager()
self.start_buttons()
# Disable this if you don't want serial access.
#self.device.enable_serial()
# Hello world.
self.device.print_bootscreen()
# Bootstrap infrastructure.
self.device.start_networking()
# Conditionally start telemetry if networking is available.
if self.device.status.networking:
self.device.start_telemetry()
# Todo: Signal readyness by publishing information about the device (Microhomie).
# e.g. ``self.device.publish_properties()``
# Setup sensors.
self.device.feed_watchdog()
bus_settings = self.settings.get('sensors.busses')
self.sensor_manager.register_busses(bus_settings)
self.register_sensors()
# Power up sensor peripherals.
self.sensor_manager.power_on()
# Ready.
self.start_mainloop()
def start_mainloop(self):
# Todo: Refactor by using timers.
# Enter the main loop.
while True:
# Feed the watchdog timer to keep the system alive.
self.device.feed_watchdog()
# Indicate activity.
# Todo: Optionally disable this output.
log.info('--- loop ---')
# Run downstream mainloop handlers.
self.loop()
# Yup.
machine.idle()
def loop(self):
"""
Main duty cycle loop.
"""
#log.info('Terkin loop')
# Read sensors.
readings = self.read_sensors()
# Transmit data.
self.transmit_readings(readings)
# Run the garbage collector.
self.device.run_gc()
# Sleep how ever.
self.sleep()
def sleep(self):
"""
Sleep until the next measurement cycle.
"""
interval = self.settings.get('main.interval')
#print(dir(machine))
# Use deep sleep if requested.
try:
deep = self.settings.get('main.deepsleep', False)
if deep:
# Shut down sensor peripherals.
self.sensor_manager.power_off()
# Shut down device peripherals.
self.device.power_off()
# Send device to deep sleep.
self.device.hibernate(interval, deep=deep)
# When hibernation fails, fall back to regular "time.sleep".
except:
log.exception('Failed to hibernate, falling back to regular sleep')
# Todo: Emit error message here.
log.info('Sleeping for {} seconds'.format(interval))
time.sleep(interval)
def register_sensors(self):
"""
Add system sensors.
"""
log.info('Registering Terkin sensors')
system_sensors = [
SystemMemoryFree,
SystemTemperature,
SystemBatteryLevel,
SystemUptime,
]
# Create environmental sensor adapters.
for sensor_factory in system_sensors:
sensor = sensor_factory()
if hasattr(sensor, 'setup') and callable(sensor.setup):
sensor.setup(self.settings)
self.sensor_manager.register_sensor(sensor)
# Add WiFi metrics.
try:
self.sensor_manager.register_sensor(SystemWiFiMetrics(self.device.networking.wifi_manager.station))
except:
log.exception('Enabling SystemWiFiMetrics sensor failed')
def read_sensors(self):
"""Read sensors"""
data = {}
sensors = self.sensor_manager.sensors
log.info('Reading %s sensor ports', len(sensors))
for sensor in sensors:
sensorname = sensor.__class__.__name__
log.info('Reading sensor port "%s"', sensorname)
try:
reading = sensor.read()
if reading is None or reading is AbstractSensor.SENSOR_NOT_INITIALIZED:
continue
data.update(reading)
except:
log.exception('Reading sensor "%s" failed', sensorname)
self.device.feed_watchdog()
# Debugging: Print sensor data before running telemetry.
log.info('Sensor data: %s', data)
return data
def transmit_readings(self, data):
"""Transmit data"""
# TODO: Optionally disable telemetry.
if self.device.telemetry is None:
log.warning('Telemetry disabled')
return False
telemetry_status = self.device.telemetry.transmit(data)
count_total = len(telemetry_status)
success = all(telemetry_status.values())
# Evaluate telemetry status outcome.
if success:
log.info('Telemetry status: SUCCESS ({}/{})'.format(count_total, count_total))
else:
count_failed = len([item for item in telemetry_status.values() if item is not True])
log.warning('Telemetry status: FAILURE. {} out of {} targets failed. '
'Status: {}'.format(count_failed, count_total, telemetry_status))
return success
def start_buttons(self):
# RGB-LED: 2
# POWER-ENABLE: 3
# SD-Card: 4, 8
# LTE 19, 20
# Misc: 13, 14, 9, 23
# Physical location when looking at the board with the RGB-LED oriented to the top.
# Location: Left side, 6th pin from top.
self.button_manager.setup_touchpad('P4', name='Touch3', location='Module-Left-Top-6th')
# Location: Left side, 5th pin from bottom.
self.button_manager.setup_touchpad('P8', name='Touch2', location='Module-Left-Bottom-5th')
# Location: Right side.
self.button_manager.setup_touchpad('P23', name='Touch6', location='Module-Right-Top-4th')
class TerkinDatalogger:
# Application metadata.
name = 'Terkin MicroPython Datalogger'
version = __version__
# For the singleton factory.
__instance__ = None
def __init__(self, settings, platform_info=None):
# Fulfill singleton factory.
TerkinDatalogger.__instance__ = self
# Obtain configuration settings.
self.settings = TerkinConfiguration()
self.settings.add(settings)
self.settings.add_user_file()
self.application_info = ApplicationInfo(name=self.name,
version=self.version,
settings=self.settings,
application=self,
platform_info=platform_info)
# Configure logging.
logging_enabled = self.settings.get('main.logging.enabled', False)
if not logging_enabled:
log.info('Disabling logging to save bytes')
logging.disable_logging()
# Initialize transient storage.
self.storage = TransientStorage()
# Initialize device.
self.device = TerkinDevice(self.application_info)
# Button manager instance (optional).
self.button_manager = None
# Initialize sensor domain.
self.sensor_manager = SensorManager()
self.duty_chrono = GenericChronometer()
@staticmethod
def getInstance(settings=None):
"""
Singleton factory.
"""
if TerkinDatalogger.__instance__ is None:
if settings is None:
raise Exception(
"Settings are None but instance wasn't created before.")
else:
TerkinDatalogger(settings)
return TerkinDatalogger.__instance__
def setup(self):
pass
def start(self):
self.duty_chrono.reset()
# Report about wakeup reason and run wakeup tasks.
self.device.resume()
# Start the watchdog for sanity.
self.device.watchdog.start()
# Configure RGB-LED according to settings.
self.device.configure_rgb_led()
# Alternative startup signalling: 2 x green.
self.device.blink_led(0x000b00, count=2)
self.device.run_gc()
# Turn off LTE modem and Bluetooth as we don't use them yet.
# Todo: Revisit where this should actually go.
# The modem driver takes about six seconds to initialize, so adjust the watchdog accordingly.
self.device.watchdog.reconfigure_minimum_timeout(15000)
if not self.settings.get('main.fastboot', False):
self.device.power_off_lte_modem()
self.device.power_off_bluetooth()
self.device.watchdog.resume()
log.info('Starting %s', self.application_info.fullname)
# Dump configuration settings.
log_configuration = self.settings.get('main.logging.configuration',
False)
if log_configuration:
self.settings.dump()
# Initialize buttons / touch pads.
buttons_enabled = self.settings.get('sensors.system.buttons.enabled',
False)
if buttons_enabled:
from terkin.sensor.button import ButtonManager
self.button_manager = ButtonManager()
self.start_buttons()
# Disable this if you don't want serial access.
#self.device.enable_serial()
# Hello world.
self.device.print_bootscreen()
# Start networking and telemetry subsystems.
# Conditionally start network services and telemetry if networking is available.
try:
self.device.start_networking()
except Exception as ex:
log.exc(ex, 'Networking subsystem failed')
self.device.status.networking = False
self.device.start_telemetry()
# Todo: Signal readyness by publishing information about the device (Microhomie).
# e.g. ``self.device.publish_properties()``
# Setup sensors.
self.device.watchdog.feed()
bus_settings = self.settings.get('sensors.busses', [])
self.sensor_manager.setup_busses(bus_settings)
self.register_sensors()
# Power up sensor peripherals.
self.sensor_manager.power_on()
# Ready.
self.start_mainloop()
def start_mainloop(self):
# Todo: Refactor by using timers.
# Enter the main loop.
while True:
# Feed the watchdog timer to keep the system alive.
self.device.watchdog.feed()
# Indicate activity.
# Todo: Optionally disable this output.
log.info('--- loop ---')
# Run downstream mainloop handlers.
self.loop()
# Give the system some breath.
machine.idle()
def loop(self):
"""
Main duty cycle loop.
"""
if not self.settings.get('main.deepsleep', False):
self.duty_chrono.reset()
#log.info('Terkin loop')
# Alternative loop signalling: 1 x blue.
# https://forum.pycom.io/topic/2067/brightness-of-on-board-led/7
self.device.blink_led(0x00000b, count=2)
# Read sensors.
readings = self.read_sensors()
# Remember current reading
self.storage.last_reading = readings
# Run the garbage collector.
self.device.run_gc()
# Transmit data.
transmission_success = self.transmit_readings(readings)
# Signal transmission outcome.
if transmission_success:
self.device.blink_led(0x00000b)
else:
self.device.blink_led(0x0b0000)
# Run the garbage collector.
self.device.run_gc()
# Sleep how ever.
self.sleep()
def sleep(self):
"""
Sleep until the next measurement cycle.
"""
lightsleep = self.settings.get('main.lightsleep', False)
deepsleep = self.settings.get('main.deepsleep', False)
interval = self.get_sleep_time()
# Amend deep sleep intent when masked through maintenance mode.
if self.device.status.maintenance is True:
lightsleep = False
deepsleep = False
log.info('Device is in maintenance mode. Skipping deep sleep and '
'adjusting interval to {} seconds'.format(interval))
# Use deep sleep if requested.
try:
if deepsleep:
# Shut down sensor peripherals.
self.sensor_manager.power_off()
# Shut down device peripherals.
self.device.power_off()
# Send device to deep sleep.
self.device.hibernate(interval,
lightsleep=lightsleep,
deepsleep=deepsleep)
# When hibernation fails, fall back to regular "time.sleep".
except Exception as ex:
log.exc(ex, 'Failed to hibernate, falling back to regular sleep')
# Todo: Emit error message here.
log.info('Sleeping for {} seconds'.format(interval))
time.sleep(interval)
def get_sleep_time(self):
interval = self.settings.get('main.interval', 60.0)
# Configuration switchover backward compatibility / defaults.
if isinstance(interval, (float, int)):
self.settings.set('main.interval', {})
self.settings.setdefault('main.interval.field', interval)
self.settings.setdefault('main.interval.maintenance', 5.0)
# Compute interval.
interval = self.settings.get('main.interval.field')
# Amend deep sleep intent when masked through maintenance mode.
if self.device.status.maintenance is True:
interval = self.settings.get('main.interval.maintenance')
# Compute sleeping duration from measurement interval and elapsed time.
elapsed = self.duty_chrono.read()
sleep_time = interval - elapsed
if sleep_time <= 0:
sleep_time = interval
return sleep_time
def register_sensors(self):
"""
Add system sensors.
"""
log.info('Registering system sensors')
system_sensors = [
SystemMemoryFree,
SystemTemperature,
SystemBatteryLevel,
SystemUptime,
]
for sensor_factory in system_sensors:
sensor_name = sensor_factory.__name__
try:
sensor = sensor_factory()
if not sensor.enabled():
log.info('Sensor %s not enabled, skipping', sensor_name)
continue
if hasattr(sensor, 'setup') and callable(sensor.setup):
sensor.setup(self.settings)
self.sensor_manager.register_sensor(sensor)
except Exception as ex:
log.exc(ex, 'Registering system sensor "%s" failed',
sensor_name)
# Add WiFi metrics.
try:
self.sensor_manager.register_sensor(
SystemWiFiMetrics(self.device.networking.wifi_manager.station))
except Exception as ex:
log.exc(ex, 'Enabling SystemWiFiMetrics sensor failed')
def read_sensors(self):
"""
Read sensors
"""
# Collect observations.
data = {}
richdata = {}
# Iterate all registered sensors.
sensors = self.sensor_manager.sensors
log.info('Reading %s sensor ports', len(sensors))
for sensor in sensors:
# Signal sensor reading to user.
sensorname = sensor.__class__.__name__
log.info('Reading sensor port "%s"', sensorname)
# Read sensor port.
try:
# Disable garbage collector to guarantee reasonable
# realtime behavior before invoking sensor reading.
with gc_disabled():
reading = sensor.read()
# Evaluate sensor outcome.
if reading is None or reading is AbstractSensor.SENSOR_NOT_INITIALIZED:
continue
# Add sensor reading to observations.
data.update(reading)
# Record reading for prettified output.
self.record_reading(sensor, reading, richdata)
except Exception as ex:
# Because of the ``gc_disabled`` context manager used above,
# the propagation of exceptions has to be tweaked like that.
log.exc(ex, 'Reading sensor "%s" failed', sensorname)
# Feed the watchdog.
self.device.watchdog.feed()
self.device.run_gc()
# Debugging: Print sensor data before running telemetry.
prettify_log = self.settings.get('sensors.prettify_log', False)
if prettify_log:
log.info('Sensor data:\n\n%s', ddformat(richdata, indent=11))
else:
log.info('Sensor data: %s', data)
return data
def record_reading(self, sensor, reading, richdata):
for key, value in reading.items():
richdata[key] = {'value': value}
if hasattr(sensor,
'settings') and 'description' in sensor.settings:
richdata[key]['description'] = sensor.settings.get(
'description')
# Hack to propagate the correct detail-description to prettified output.
# TODO: Attach settings directly to its reading, while actually reading it.
if 'devices' in sensor.settings:
for device_settings in sensor.settings['devices']:
device_address = device_settings['address'].lower()
if device_address in key:
if hasattr(sensor, 'get_device_description'):
device_description = sensor.get_device_description(
device_address)
if device_description:
richdata[key][
'description'] = device_description
def transmit_readings(self, data):
"""Transmit data"""
# TODO: Optionally disable telemetry.
if self.device.telemetry is None:
log.warning('Telemetry disabled')
return False
telemetry_status = self.device.telemetry.transmit(data)
count_total = len(telemetry_status)
success = all(telemetry_status.values())
# Evaluate telemetry status outcome.
if success:
log.info('Telemetry status: SUCCESS ({}/{})'.format(
count_total, count_total))
else:
count_failed = len([
item for item in telemetry_status.values() if item is not True
])
log.warning(
'Telemetry status: FAILURE. {} out of {} targets failed. '
'Status: {}'.format(count_failed, count_total,
telemetry_status))
return success
def start_buttons(self):
# RGB-LED: 2
# POWER-ENABLE: 3
# SD-Card: 4, 8
# LTE 19, 20
# Misc: 13, 14, 9, 23
# Physical location when looking at the board with the RGB-LED oriented to the top.
# Location: Left side, 6th pin from top.
self.button_manager.setup_touchpad('P4',
name='Touch3',
location='Module-Left-Top-6th')
# Location: Left side, 5th pin from bottom.
self.button_manager.setup_touchpad('P8',
name='Touch2',
location='Module-Left-Bottom-5th')
# Location: Right side.
self.button_manager.setup_touchpad('P23',
name='Touch6',
location='Module-Right-Top-4th')
# Location: Right side.
# ValueError: invalid pin for touchpad
"""
class TerkinDatalogger:
"""
Main class of project.
Handles loop & sleep, registers sensors, reads their data and stores them.
Shows up as 'datalogger' in the rest of the program.
"""
# Application metadata.
name = 'Terkin Datalogger'
version = __version__
# For the singleton factory.
__instance__ = None
def __init__(self, settings, platform_info: PlatformInfo = None):
# Reference to the chronometer used for general timekeeping.
self.duty_chrono = bootloader.duty_chrono
# Signal startup with first available timestamp.
log.info('Starting Terkin datalogger')
# Obtain configuration settings.
self.settings = TerkinConfiguration()
self.settings.add(settings)
self.settings.add_user_file()
# Configure logging.
logging_enabled = self.settings.get('main.logging.enabled', False)
if not logging_enabled:
log.info('Disabling logging to save bytes')
logging.disable_logging()
# Initialize ApplicationInfo object.
self.application_info = ApplicationInfo(name=self.name,
version=self.version,
settings=self.settings,
application=self,
platform_info=platform_info)
# Initialize transient storage.
self.storage = TransientStorage()
# Initialize device.
self.device = TerkinDevice(self.application_info)
# Button manager instance (optional).
self.button_manager = None
# Initialize sensor domain.
self.sensor_manager = SensorManager(self.settings)
def setup(self):
# Report about wakeup reason and run wakeup tasks.
self.device.resume()
# Start the watchdog for sanity.
self.device.watchdog.start()
# Configure RGB-LED according to settings.
self.device.configure_rgb_led()
# Alternative startup signalling: 2 x green.
self.device.blink_led(0x000b00, count=2)
# Free up some memory.
self.device.run_gc()
# Turn off LTE modem and Bluetooth as we don't use them yet.
# TODO: Make this configurable.
has_lte_modem = self.application_info.platform_info.device_name in [
'GPy', 'FiPy'
]
lte_enabled = self.settings.get('networking.lte.enabled')
if has_lte_modem and not lte_enabled:
self.device.power_off_lte_modem()
self.device.power_off_bluetooth()
log.info('Starting %s', self.application_info.fullname)
# Dump configuration settings.
log_configuration = self.settings.get('main.logging.configuration',
False)
if log_configuration:
self.settings.dump()
# Disable this if you don't want serial access.
#self.device.enable_serial()
# Hello world.
self.device.print_bootscreen()
# Start networking and telemetry subsystems.
# Conditionally start network services and telemetry if networking is available.
try:
self.device.start_networking()
except Exception as ex:
log.exc(ex, 'Networking subsystem failed')
self.device.status.networking = False
self.device.start_telemetry()
# Todo: Signal readyness by publishing information about the device (Microhomie).
# e.g. ``self.device.publish_properties()``
self.setup_sensors()
def setup_sensors(self):
# Setup sensors.
log.info('Setting up sensors')
self.device.watchdog.feed()
bus_settings = self.settings.get(
'sensors.buses', self.settings.get('sensors.busses', []))
self.sensor_manager.setup_buses(bus_settings)
self.register_sensors()
self.sensor_manager.start_sensors()
log.info('Setup finished')
def start(self):
self.start_mainloop()
def start_mainloop(self):
""" """
# Todo: Refactor by using timers.
# Enter the main loop.
while True:
self.duty_task()
def duty_task(self):
"""Main duty cycle task."""
# Feed the watchdog timer to keep the system alive.
self.device.watchdog.feed()
# Indicate activity.
# Todo: Optionally disable this output.
log.info('--- cycle ---')
# Run downstream mainloop handlers.
self.duty_cycle()
# Sleep how configured
self.sleep()
def duty_cycle(self):
"""Main duty cycle"""
if not self.settings.get('main.deepsleep', False):
self.duty_chrono.reset()
#log.info('Terkin loop')
# Alternative loop signalling: 1 x blue.
# https://forum.pycom.io/topic/2067/brightness-of-on-board-led/7
self.device.blink_led(0x00000b, count=2)
# Read sensors.
readings = self.read_sensors()
# Remember current reading
self.storage.last_reading = readings.data_in
# Run the garbage collector.
self.device.run_gc()
# Transmit data.
transmission_success = self.transmit_readings(readings)
# Signal transmission outcome.
if transmission_success:
self.device.blink_led(0x00000b)
else:
self.device.blink_led(0x0b0000)
# Run the garbage collector.
self.device.run_gc()
# Give the system some breath.
machine.idle()
def sleep(self):
"""Sleep or shutoff until the next measurement cycle."""
lightsleep = self.settings.get('main.lightsleep', False)
deepsleep = self.settings.get('main.deepsleep', False)
shutoff = self.settings.get('main.shutoff', False)
interval = self.get_sleep_time()
# Amend deep sleep intent when masked through maintenance mode.
if self.device.status.maintenance is True:
lightsleep = False
deepsleep = False
shutoff = False
log.info('Device is in maintenance mode. Skipping deep sleep and '
'adjusting sleep time to {} seconds.'.format(interval))
# Prepare device shutdown.
try:
# Shut down sensor peripherals.
self.sensor_manager.power_off()
# Shut down networking.
if deepsleep or shutoff:
self.device.networking.stop()
except Exception as ex:
log.exc(ex, 'Power off failed')
if shutoff:
# shut off the MCU via DS3231
self.shutoff()
else:
# Activate device sleep mode.
try:
self.device.hibernate(interval,
lightsleep=lightsleep,
deepsleep=deepsleep)
# When hibernation fails, fall back to regular "time.sleep".
except Exception as ex:
log.exc(ex,
'Failed to hibernate, falling back to regular sleep')
# Todo: Emit error message here.
log.info('Sleeping for {} seconds'.format(interval))
time.sleep(interval)
def get_sleep_time(self):
"""
Calculate the next sleep intervall.
"""
interval = self.settings.get('main.interval', 60.0)
# Configuration switchover backward compatibility / defaults.
if isinstance(interval, (float, int)):
self.settings.set('main.interval', {})
self.settings.setdefault('main.interval.field', interval)
self.settings.setdefault('main.interval.maintenance', 5.0)
interval = self.settings.get('main.interval.field')
# First, try to acquire deep sleep interval from NVRAM.
# This gets used when set from a LoRaWAN downlink message.
# pycom.nvs_get should return "None" in case of unset key. Instead it throws an error
try:
import pycom
interval_minutes = pycom.nvs_get('deepsleep')
if isinstance(interval_minutes, int):
log.info(
'Deep sleep interval set to %s minute(s) by LoRaWAN downlink message',
interval_minutes)
interval = interval_minutes * 60
# Otherwise, use original configuration setting.
except Exception as ex:
pass
# Amend deep sleep intent when masked through maintenance mode.
if self.device.status.maintenance is True:
interval = self.settings.get('main.interval.maintenance')
# Compute sleeping duration from measurement interval and elapsed time.
elapsed = self.duty_chrono.read()
sleep_time = interval - elapsed
if sleep_time <= 0:
sleep_time = interval
return sleep_time
def register_sensors(self):
"""
Configure and register sensor objects.
There are three types of sensors: system, environment & buses.
The sensors are registered by calling their respective classes
from terkin/driver.
Definitions are in 'settings.py'.
"""
# Add sensors.
log.info('Registering sensors')
sensor_infos = []
# Get list of system sensors from configuration settings.
sensor_infos += self.settings.get('sensors.system', [])
# Get list of environmental sensors from configuration settings.
sensor_infos += self.settings.get('sensors.environment', [])
# Backward compatibility for environmental sensors.
if sensor_infos is None:
sensor_infos += self.settings.get('sensors.registry',
{}).values() or []
# Scan sensor definitions, create and register sensor objects.
for sensor_info in sensor_infos:
sensor_type = sensor_info.get('type', 'unknown').lower()
sensor_id = sensor_info.get('id',
sensor_info.get('key', sensor_type))
# Skip sensor if disabled in configuration.
if not sensor_info.get('enabled', False):
log.debug(
'Sensor with id={} and type={} is disabled, skipping registration'
.format(sensor_id, sensor_type))
continue
# Skip WiFi sensor registration when WiFi is disabled.
if sensor_type == 'system.wifi':
if not self.settings.get('networking.wifi.enabled'):
log.info('WiFi is disabled, skipping sensor registration')
continue
self.register_sensor(sensor_info)
# Clean up memory after creating each sensor object.
#self.device.run_gc()
def register_sensor(self, sensor_info):
"""
Register one sensor.
"""
sensor_type = sensor_info.get('type', 'unknown').lower()
sensor_id = sensor_info.get('id', sensor_info.get('key', sensor_type))
description = sensor_info.get('description')
# Resolve associated bus object.
sensor_bus = None
sensor_bus_name = None
if 'bus' in sensor_info:
sensor_info_bus = sensor_info['bus']
sensor_bus = self.sensor_manager.get_bus_by_name(sensor_info_bus)
# Skip sensor if associated bus is disabled in configuration.
if sensor_bus is None:
log.info(
'Bus {} for sensor with id={} and type={} is disabled, '
'skipping registration'.format(sensor_info_bus, sensor_id,
sensor_type))
return
sensor_bus_name = sensor_bus.name
# Human readable sensor address.
if 'address' in sensor_info:
sensor_address = hex(sensor_info.get('address'))
else:
sensor_address = None
# Report sensor registration to user.
message = 'Setting up sensor with id={} and type={} on bus={} with address={}'.format(
sensor_id, sensor_type, sensor_bus_name, sensor_address)
if description:
message += ' described as "{}"'.format(description)
log.info(message)
# Backward compat.
if sensor_type == 'ds18b20':
sensor_type = 'ds18x20'
# Registration NG
# Run self-registration procedure by invoking
# the "includeme()" function on each sensor module.
try:
# Load sensor module.
import terkin.driver
modulename = '{}_sensor'.format(sensor_type)
fullname = 'terkin.driver.{}'.format(modulename)
log.info('Importing module "{}"'.format(fullname))
__import__(fullname)
module = getattr(terkin.driver, modulename)
# Acquire sensor object.
includeme = getattr(module, 'includeme')
sensor_object = includeme(self.sensor_manager, sensor_info)
# Register sensor with sensor manager.
self.sensor_manager.register_sensor(sensor_object)
return
except ImportError as ex:
if not fullname.startswith('terkin.driver.system'):
log.error('Driver module "{}" not found'.format(fullname))
except AttributeError as ex:
if "has no attribute 'includeme'" in str(ex):
log.warning(
'Driver module "{}" is deprecated, "includeme" is missing'.
format(fullname))
else:
log.exc(ex, 'Driver module "{}" failed'.format(fullname))
except Exception as ex:
log.exc(ex,
'Registering driver module "{}" failed'.format(fullname))
# Legacy registration
try:
self.register_sensor_legacy(sensor_info, sensor_bus)
except Exception as ex:
log.exc(
ex, 'Setting up sensor with id={} and type={} failed'.format(
sensor_id, sensor_type))
def register_sensor_legacy(self, sensor_info, sensor_bus):
sensor_type = sensor_info.get('type', 'unknown').lower()
# Sensor reporting about free system memory.
if sensor_type == 'system.memfree':
sensor_object = SystemMemoryFree(sensor_info)
# Sensor which reports system temperature.
elif sensor_type == 'system.temperature':
sensor_object = SystemTemperature(sensor_info)
# Sensor which reports battery voltage.
elif sensor_type in [
'system.voltage.battery', 'system.battery-voltage'
]:
sensor_object = SystemVoltage(sensor_info)
# Sensor which reports solar panel voltage.
elif sensor_type == 'system.voltage.solar':
sensor_object = SystemVoltage(sensor_info)
# Sensor which reports system uptime metrics.
elif sensor_type == 'system.uptime':
sensor_object = SystemUptime(sensor_info)
# Sensor which reports WiFi metrics.
elif sensor_type == 'system.wifi':
try:
sensor_object = SystemWiFiMetrics(
sensor_info, self.device.networking.wifi_manager.station)
except Exception as ex:
log.exc(ex, 'Enabling SystemWiFiMetrics sensor failed')
return
# Initialize buttons / touch pads.
elif sensor_type == 'system.touch-buttons':
from terkin.sensor.button import ButtonManager
self.button_manager = ButtonManager()
self.start_buttons()
return
else:
raise SensorUnknownError(
'Unknown sensor type "{}"'.format(sensor_type))
# Register sensor object with sensor manager.
self.sensor_manager.register_sensor(sensor_object)
def read_sensors(self) -> DataFrame:
"""
Read measurements from all sensor objects that have been registered in the sensor_manager.
Reading is done with the read() function of each respective sensor object.
"""
# Power up sensor peripherals.
self.sensor_manager.power_on()
# Collect observations.
data = {}
richdata = {}
readings = []
# Iterate all registered sensors.
sensors = self.sensor_manager.sensors
log.info('Reading %s sensor ports', len(sensors))
for sensor in sensors:
# Signal sensor reading to user.
sensorname = sensor.__class__.__name__
log.info('Reading sensor port "%s"', sensorname)
# Read sensor port.
try:
# Disable garbage collector to guarantee reasonable
# realtime behavior before invoking sensor reading.
with gc_disabled():
sensor_outcome = sensor.read()
# Power off HX711 after reading
if "HX711Sensor" in sensorname:
sensor.power_off()
# Backward compat.
if isinstance(sensor_outcome, SensorReading):
sensor_reading = sensor_outcome
else:
sensor_reading = SensorReading()
sensor_reading.sensor = sensor
sensor_reading.data = sensor_outcome
sensor_data = sensor_reading.data
# Evaluate sensor outcome.
if sensor_data is None or sensor_data is AbstractSensor.SENSOR_NOT_INITIALIZED:
continue
# Round values according to sensor settings.
if sensor.settings.get('decimals') is not None:
for key, value in sensor_data.items():
sensor_data[key] = round(
sensor_data[key], sensor.settings.get('decimals'))
# Add sensor reading to observations.
data.update(sensor_data)
# Record reading for prettified output.
self.record_reading(sensor, sensor_data, richdata)
readings.append(sensor_reading)
except Exception as ex:
# Because of the ``gc_disabled`` context manager used above,
# the propagation of exceptions has to be tweaked like that.
log.exc(ex, 'Reading sensor "%s" failed', sensorname)
# Feed the watchdog.
self.device.watchdog.feed()
# Clean up memory after reading each sensor object.
#self.device.run_gc()
# Debugging: Print sensor data before running telemetry.
prettify_log = self.settings.get('sensors.prettify_log', False)
if prettify_log:
from terkin.util import ddformat
log.info('Sensor data:\n\n%s', ddformat(richdata, indent=11))
else:
log.info('Sensor data: %s', data)
# Capture all sensor readings.
result = DataFrame()
result.readings = readings
result.data_in = data
return result
def record_reading(self, sensor, reading, richdata):
"""
:param sensor:
:param reading:
:param richdata:
"""
for key, value in reading.items():
richdata[key] = {'value': value}
if hasattr(sensor,
'settings') and 'description' in sensor.settings:
richdata[key]['description'] = sensor.settings.get(
'description')
# Hack to propagate the correct detail-description to prettified output.
# TODO: Attach settings directly to its reading, while actually reading it.
if 'devices' in sensor.settings:
for device_settings in sensor.settings['devices']:
device_address = device_settings['address'].lower()
if device_address in key:
if hasattr(sensor, 'get_device_description'):
device_description = sensor.get_device_description(
device_address)
if device_description:
richdata[key][
'description'] = device_description
def transmit_readings(self, dataframe: DataFrame):
"""
Transmit data
:param dataframe:
"""
# TODO: Optionally disable telemetry.
if self.device.telemetry is None:
log.warning('Telemetry disabled')
return False
telemetry_status = self.device.telemetry.transmit(dataframe)
count_total = len(telemetry_status)
success = all(telemetry_status.values())
# Evaluate telemetry status outcome.
if success:
log.info('Telemetry status: SUCCESS ({}/{})'.format(
count_total, count_total))
else:
count_failed = len([
item for item in telemetry_status.values() if item is not True
])
log.warning(
'Telemetry status: FAILURE. {} out of {} targets failed. '
'Status: {}'.format(count_failed, count_total,
telemetry_status))
return success
def start_buttons(self):
"""
Configure ESP32 touchpads.
"""
# RGB-LED: 2
# POWER-ENABLE: 3
# SD-Card: 4, 8
# LTE 19, 20
# Misc: 13, 14, 9, 23
# Physical location when looking at the board with the RGB-LED oriented to the top.
# Location: Left side, 6th pin from top.
self.button_manager.setup_touchpad('P4',
name='Touch3',
location='Module-Left-Top-6th')
# Location: Left side, 5th pin from bottom.
self.button_manager.setup_touchpad('P8',
name='Touch2',
location='Module-Left-Bottom-5th')
# Location: Right side.
self.button_manager.setup_touchpad('P23',
name='Touch6',
location='Module-Right-Top-4th')
# Location: Right side.
# ValueError: invalid pin for touchpad
"""
P18 and P17 are able to wake up on rising and falling edge. These two pins have internal
pull-ups configurable by software (Pull-downs if needed must be added externally)
-- https://docs.pycom.io/gitbook/assets/deepsleep-pinout.pdf
ext0 External Wake-up Source
RTC controller contains logic to trigger wake-up when one particular pin is set to
a predefined logic level. That pin can be one of RTC GPIOs 0,2,4,12-15,25-27,32-39.
-- https://lastminuteengineers.com/esp32-deep-sleep-wakeup-sources/#ext0-external-wakeup-source
"""
#self.button_manager.setup_touchpad('P17', name='TouchX', location='Module-Right-Bottom-5th')
#self.button_manager.setup_touchpad('P18', name='TouchY', location='Module-Right-Bottom-6th')
# Will yield ``ValueError: Touch pad error``.
#self.button_manager.setup_touchpad('P20', name='Touch8', location='Module-Right-Top-7th')
#self.button_manager.setup_touchpad('P19', name='Touch9', location='Module-Right-Top-8th')
def shutoff(self):
""" shut off the MCU """
import DS3231tokei
import utime
from machine import Pin, RTC
bus = self.sensor_manager.get_bus_by_sensortype('DS3231')
ds = DS3231tokei.DS3231(bus.adapter)
interval = self.settings.get(
'main.interval.shutoff',
10) * 60 # convert from minutes to seconds
(year, month, day, dotw, hour, minute,
second) = ds.getDateTime() # get the current time
rtc = RTC() # create RTC
if year < 2001:
year = 2001 # sanity check, as of mpy 1.12 year must be >= 2001
rtc.init((year, month, day, dotw, hour, minute, second, 0)) # set time
# check if its night or winter and adjust interval
night_start = self.settings.get('main.interval.night_start', 0)
night_end = self.settings.get('main.interval.night_end', 0)
winter_start = self.settings.get('main.interval.winter_start', 0)
winter_end = self.settings.get('main.interval.winter_end', 0)
if night_start > 0 and (hour >= night_start or hour <= night_end
): # double interval for the night
interval *= 2
if winter_start > 0 and (month >= winter_start or month <= winter_end
): # double interval for winter
interval *= 2
# Compute sleeping duration from measurement interval and elapsed time.
elapsed = int(self.duty_chrono.read())
now_secs = utime.mktime(utime.localtime())
wake_at = now_secs - elapsed + interval
if (wake_at - now_secs) < 180: # don't shutoff for less than 3 minutes
wake_at += interval
(year, month, day, hour, minute, second, dotw,
doty) = utime.localtime(wake_at) # convert the wake up time
# set alarm
ds.setAlarm2(day, hour, minute, DS3231tokei.A2_ON_HOUR_MINUTE)
# turn off MCU via MOSFET
utime.sleep(1)
ds.enableAlarm2()
ds.resetAlarm2()
# The End
def scale_wizard(self):
"""
Invoke scale adjustment wizard.
Synopsis:
- Invoke Terkin datalogger.
- Interrupt by pressing CTRL+C.
- Type ``datalogger.scale_wizard()``.
"""
# Setup sensors.
self.setup_sensors()
# Invoke scale adjustment routine.
from terkin.sensor.scale import ScaleAdjustment
adj = ScaleAdjustment(sensor_manager=self.sensor_manager)
adj.start_wizard()
class TerkinDatalogger:
"""
Main class of project.
Handles loop & sleep, registers sensors, reads their data and stores them.
Shows up as 'datalogger' in the rest of the program.
"""
# Application metadata.
name = 'Terkin MicroPython Datalogger'
version = __version__
# For the singleton factory.
__instance__ = None
def __init__(self, settings, platform_info: PlatformInfo = None):
# Reference to the chronometer used for general timekeeping.
self.duty_chrono = bootloader.duty_chrono
# Fulfill singleton factory.
TerkinDatalogger.__instance__ = self
# Signal startup with first available timestamp.
log.info('Starting Terkin datalogger')
# Obtain configuration settings.
self.settings = TerkinConfiguration()
self.settings.add(settings)
self.settings.add_user_file()
# Configure logging.
logging_enabled = self.settings.get('main.logging.enabled', False)
if not logging_enabled:
log.info('Disabling logging to save bytes')
logging.disable_logging()
# Initialize ApplicationInfo object.
self.application_info = ApplicationInfo(name=self.name,
version=self.version,
settings=self.settings,
application=self,
platform_info=platform_info)
# Initialize transient storage.
self.storage = TransientStorage()
# Initialize device.
self.device = TerkinDevice(self.application_info)
# Button manager instance (optional).
self.button_manager = None
# Initialize sensor domain.
self.sensor_manager = SensorManager()
@staticmethod
def getInstance(settings=None):
"""Singleton factory.
:param settings: (Default value = None)
"""
if TerkinDatalogger.__instance__ is None:
if settings is None:
raise Exception(
"Settings are None but instance wasn't created before.")
else:
TerkinDatalogger(settings)
return TerkinDatalogger.__instance__
def setup(self):
""" """
pass
def start(self):
""" """
# Report about wakeup reason and run wakeup tasks.
self.device.resume()
# Start the watchdog for sanity.
self.device.watchdog.start()
# Configure RGB-LED according to settings.
self.device.configure_rgb_led()
# Alternative startup signalling: 2 x green.
self.device.blink_led(0x000b00, count=2)
# Free up some memory.
self.device.run_gc()
# Turn off LTE modem and Bluetooth as we don't use them yet.
# TODO: Make this configurable.
if self.application_info.platform_info.device_name in ['GPy', 'FiPy']:
self.device.power_off_lte_modem()
self.device.power_off_bluetooth()
log.info('Starting %s', self.application_info.fullname)
# Dump configuration settings.
log_configuration = self.settings.get('main.logging.configuration',
False)
if log_configuration:
self.settings.dump()
# Disable this if you don't want serial access.
#self.device.enable_serial()
# Hello world.
self.device.print_bootscreen()
# Start networking and telemetry subsystems.
# Conditionally start network services and telemetry if networking is available.
try:
self.device.start_networking()
except Exception as ex:
log.exc(ex, 'Networking subsystem failed')
self.device.status.networking = False
self.device.start_telemetry()
# Todo: Signal readyness by publishing information about the device (Microhomie).
# e.g. ``self.device.publish_properties()``
# Setup sensors.
self.device.watchdog.feed()
bus_settings = self.settings.get('sensors.busses', [])
self.sensor_manager.setup_busses(bus_settings)
self.register_sensors()
# Ready.
self.start_mainloop()
def start_mainloop(self):
""" """
# Todo: Refactor by using timers.
# Enter the main loop.
while True:
# Feed the watchdog timer to keep the system alive.
self.device.watchdog.feed()
# Indicate activity.
# Todo: Optionally disable this output.
log.info('--- loop ---')
# Run downstream mainloop handlers.
self.loop()
# Give the system some breath.
machine.idle()
def loop(self):
"""Main duty cycle loop."""
if not self.settings.get('main.deepsleep', False):
self.duty_chrono.reset()
#log.info('Terkin loop')
# Alternative loop signalling: 1 x blue.
# https://forum.pycom.io/topic/2067/brightness-of-on-board-led/7
self.device.blink_led(0x00000b, count=2)
# Read sensors.
readings = self.read_sensors()
# Remember current reading
self.storage.last_reading = readings.data_in
# Run the garbage collector.
self.device.run_gc()
# Transmit data.
transmission_success = self.transmit_readings(readings)
# Signal transmission outcome.
if transmission_success:
self.device.blink_led(0x00000b)
else:
self.device.blink_led(0x0b0000)
# Run the garbage collector.
self.device.run_gc()
# Sleep how ever.
self.sleep()
def sleep(self):
"""Sleep until the next measurement cycle."""
lightsleep = self.settings.get('main.lightsleep', False)
deepsleep = self.settings.get('main.deepsleep', False)
interval = self.get_sleep_time()
# Amend deep sleep intent when masked through maintenance mode.
if self.device.status.maintenance is True:
lightsleep = False
deepsleep = False
log.info('Device is in maintenance mode. Skipping deep sleep and '
'adjusting interval to {} seconds'.format(interval))
# Prepare device shutdown.
try:
# Shut down sensor peripherals.
self.sensor_manager.power_off()
# Shut down networking.
if deepsleep:
self.device.networking.stop()
except Exception as ex:
log.exc(ex, 'Power off failed')
# Activate device sleep mode.
try:
self.device.hibernate(interval,
lightsleep=lightsleep,
deepsleep=deepsleep)
# When hibernation fails, fall back to regular "time.sleep".
except Exception as ex:
log.exc(ex, 'Failed to hibernate, falling back to regular sleep')
# Todo: Emit error message here.
log.info('Sleeping for {} seconds'.format(interval))
time.sleep(interval)
def get_sleep_time(self):
""" """
import pycom
interval = self.settings.get('main.interval', 60.0)
# Configuration switchover backward compatibility / defaults.
if isinstance(interval, (float, int)):
self.settings.set('main.interval', {})
self.settings.setdefault('main.interval.field', interval)
self.settings.setdefault('main.interval.maintenance', 5.0)
# First, try to acquire deep sleep interval from NVRAM.
# This gets used when set from a LoRaWAN downlink message.
# pycom.nvs_get should return "None" in case of unset key. Instead it throws an error
try:
interval_minutes = pycom.nvs_get('deepsleep')
log.info(
'Deep sleep interval set to %s minute(s) by LoRaWAN downlink message',
interval_minutes)
interval = interval_minutes * 60
# Otherwise, fall back to original configuration setting.
except Exception as ex:
interval = self.settings.get('main.interval.field')
# Amend deep sleep intent when masked through maintenance mode.
if self.device.status.maintenance is True:
interval = self.settings.get('main.interval.maintenance')
# Compute sleeping duration from measurement interval and elapsed time.
elapsed = self.duty_chrono.read()
sleep_time = interval - elapsed
if sleep_time <= 0:
sleep_time = interval
return sleep_time
def register_sensors(self):
"""
Configure and register sensor objects.
There are three types of sensors: system, environment & busses. Only the former two are assigned to the latter (if applicable).
Definitions are in 'settings.py'.
The sensor are registered by calling their respective classes from terkin/drivers/
"""
# Add sensors.
log.info('Registering sensors')
sensor_infos = []
# Get list of system sensors from configuration settings.
sensor_infos += self.settings.get('sensors.system', [])
# Get list of environmental sensors from configuration settings.
sensor_infos += self.settings.get('sensors.environment', [])
# Backward compatibility for environmental sensors.
if sensor_infos is None:
sensor_infos += self.settings.get('sensors.registry',
{}).values() or []
# Scan sensor definitions, create and register sensor objects.
for sensor_info in sensor_infos:
sensor_type = sensor_info.get('type', 'unknown').lower()
sensor_id = sensor_info.get('id',
sensor_info.get('key', sensor_type))
description = sensor_info.get('description')
# Skip sensor if disabled in configuration.
if sensor_info.get('enabled') is False:
log.info(
'Sensor with id={} and type={} is disabled, skipping registration'
.format(sensor_id, sensor_type))
continue
# skip WiFi sensor registration when WiFi is disabled
if sensor_type == 'system.wifi':
if not self.settings.get('networking.wifi.enabled'):
log.info('WiFi is disabled, skipping sensor registration')
continue
# Resolve associated bus object.
sensor_bus = None
sensor_bus_name = None
if 'bus' in sensor_info:
sensor_info_bus = sensor_info['bus']
sensor_bus = self.sensor_manager.get_bus_by_name(
sensor_info_bus)
# Skip sensor if associated bus is disabled in configuration.
if sensor_bus is None:
log.info(
'Bus {} for sensor with id={} and type={} is disabled, '
'skipping registration'.format(sensor_info_bus,
sensor_id, sensor_type))
continue
sensor_bus_name = sensor_bus.name
# Human readable sensor address.
if 'address' in sensor_info:
sensor_address = hex(sensor_info.get('address'))
else:
sensor_address = None
# Report sensor registration to user.
message = 'Setting up sensor with with id={} and type={} on bus={} with address={} ' \
'described as "{}"'.format(sensor_id, sensor_type, sensor_bus_name, sensor_address, description)
log.info(message)
try:
# Sensor reporting about free system memory.
if sensor_type == 'system.memfree':
sensor_object = SystemMemoryFree(sensor_info)
# Sensor which reports system temperature.
elif sensor_type == 'system.temperature':
sensor_object = SystemTemperature(sensor_info)
# Sensor which reports battery voltage.
elif sensor_type in [
'system.voltage.battery', 'system.battery-voltage'
]:
sensor_object = SystemVoltage(sensor_info)
# Sensor which reports solar panel voltage.
elif sensor_type == 'system.voltage.solar':
sensor_object = SystemVoltage(sensor_info)
# Sensor which reports system uptime metrics.
elif sensor_type == 'system.uptime':
sensor_object = SystemUptime(sensor_info)
# Sensor which reports WiFi metrics.
elif sensor_type == 'system.wifi':
try:
sensor_object = SystemWiFiMetrics(
sensor_info,
self.device.networking.wifi_manager.station)
except Exception as ex:
log.exc(ex, 'Enabling SystemWiFiMetrics sensor failed')
continue
# Initialize buttons / touch pads.
elif sensor_type == 'system.touch-buttons':
from terkin.sensor.button import ButtonManager
self.button_manager = ButtonManager()
self.start_buttons()
# Setup and register HX711 sensors.
elif sensor_type == 'hx711':
sensor_object = HX711Sensor(settings=sensor_info)
sensor_object.set_address(
sensor_info.get('number',
sensor_info.get('address', 0)))
sensor_object.register_pin('dout', sensor_info['pin_dout'])
sensor_object.register_pin('pdsck',
sensor_info['pin_pdsck'])
sensor_object.register_parameter('scale',
sensor_info['scale'])
sensor_object.register_parameter('offset',
sensor_info['offset'])
sensor_object.register_parameter(
'gain', sensor_info.get('gain', 128))
# Select driver module. Use "gerber" (vanilla) or "heisenberg" (extended).
# hx711_sensor.select_driver('gerber')
sensor_object.select_driver('heisenberg')
# Start sensor.
sensor_object.start()
# Setup and register DS18X20 sensors.
elif sensor_type == 'ds18b20':
sensor_object = DS18X20Sensor(settings=sensor_info)
sensor_object.acquire_bus(sensor_bus)
# Start sensor.
sensor_object.start()
# Setup and register BME280 sensors.
elif sensor_type == 'bme280':
sensor_object = BME280Sensor(settings=sensor_info)
if 'address' in sensor_info:
sensor_object.set_address(sensor_info['address'])
sensor_object.acquire_bus(sensor_bus)
# Start sensor.
sensor_object.start()
elif sensor_type == 'max17043':
sensor_object = MAX17043Sensor(settings=sensor_info)
if 'address' in sensor_info:
sensor_object.set_address(sensor_info['address'])
sensor_object.acquire_bus(sensor_bus)
# Start sensor.
sensor_object.start()
else:
log.warning(
'Sensor with id={} has unknown type, skipping registration. '
'Sensor settings:\n{}'.format(sensor_id, sensor_info))
continue
# Register sensor object with sensor manager.
self.sensor_manager.register_sensor(sensor_object)
except Exception as ex:
log.exc(
ex,
'Setting up sensor with id={} and type={} failed'.format(
sensor_id, sensor_type))
# Clean up memory after creating each sensor object.
#self.device.run_gc()
def read_sensors(self) -> DataFrame:
"""
Read measurements from all sensor objects that have been registered in the sensor_manager.
Reading is done with the read() function of each respective sensor object.
"""
# Power up sensor peripherals.
self.sensor_manager.power_on()
# Collect observations.
data = {}
richdata = {}
readings = []
# Iterate all registered sensors.
sensors = self.sensor_manager.sensors
log.info('Reading %s sensor ports', len(sensors))
for sensor in sensors:
# Signal sensor reading to user.
sensorname = sensor.__class__.__name__
log.info('Reading sensor port "%s"', sensorname)
# Read sensor port.
try:
# Disable garbage collector to guarantee reasonable
# realtime behavior before invoking sensor reading.
with gc_disabled():
sensor_data = sensor.read()
# Evaluate sensor outcome.
if sensor_data is None or sensor_data is AbstractSensor.SENSOR_NOT_INITIALIZED:
continue
# Add sensor reading to observations.
data.update(sensor_data)
# Record reading for prettified output.
self.record_reading(sensor, sensor_data, richdata)
# Capture single sensor reading.
item = SensorReading()
item.sensor = sensor
item.data = sensor_data
readings.append(item)
except Exception as ex:
# Because of the ``gc_disabled`` context manager used above,
# the propagation of exceptions has to be tweaked like that.
log.exc(ex, 'Reading sensor "%s" failed', sensorname)
# Feed the watchdog.
self.device.watchdog.feed()
# Clean up memory after reading each sensor object.
#self.device.run_gc()
# Debugging: Print sensor data before running telemetry.
prettify_log = self.settings.get('sensors.prettify_log', False)
if prettify_log:
log.info('Sensor data:\n\n%s', ddformat(richdata, indent=11))
else:
log.info('Sensor data: %s', data)
# Capture all sensor readings.
result = DataFrame()
result.readings = readings
result.data_in = data
return result
def record_reading(self, sensor, reading, richdata):
"""
:param sensor:
:param reading:
:param richdata:
"""
for key, value in reading.items():
richdata[key] = {'value': value}
if hasattr(sensor,
'settings') and 'description' in sensor.settings:
richdata[key]['description'] = sensor.settings.get(
'description')
# Hack to propagate the correct detail-description to prettified output.
# TODO: Attach settings directly to its reading, while actually reading it.
if 'devices' in sensor.settings:
for device_settings in sensor.settings['devices']:
device_address = device_settings['address'].lower()
if device_address in key:
if hasattr(sensor, 'get_device_description'):
device_description = sensor.get_device_description(
device_address)
if device_description:
richdata[key][
'description'] = device_description
def transmit_readings(self, dataframe: DataFrame):
"""
Transmit data
:param dataframe:
"""
# TODO: Optionally disable telemetry.
if self.device.telemetry is None:
log.warning('Telemetry disabled')
return False
telemetry_status = self.device.telemetry.transmit(dataframe)
count_total = len(telemetry_status)
success = all(telemetry_status.values())
# Evaluate telemetry status outcome.
if success:
log.info('Telemetry status: SUCCESS ({}/{})'.format(
count_total, count_total))
else:
count_failed = len([
item for item in telemetry_status.values() if item is not True
])
log.warning(
'Telemetry status: FAILURE. {} out of {} targets failed. '
'Status: {}'.format(count_failed, count_total,
telemetry_status))
return success
def start_buttons(self):
"""
Configure ESP32 touchpads.
"""
# RGB-LED: 2
# POWER-ENABLE: 3
# SD-Card: 4, 8
# LTE 19, 20
# Misc: 13, 14, 9, 23
# Physical location when looking at the board with the RGB-LED oriented to the top.
# Location: Left side, 6th pin from top.
self.button_manager.setup_touchpad('P4',
name='Touch3',
location='Module-Left-Top-6th')
# Location: Left side, 5th pin from bottom.
self.button_manager.setup_touchpad('P8',
name='Touch2',
location='Module-Left-Bottom-5th')
# Location: Right side.
self.button_manager.setup_touchpad('P23',
name='Touch6',
location='Module-Right-Top-4th')
# Location: Right side.
# ValueError: invalid pin for touchpad
"""