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import logging
import time
from .types import *
from threading import Thread
from typing import Callable, Optional
from .inverter_wrapper import wrapper_instance as inverter
from inverterd import InverterError
from ..util import Stopwatch, StopwatchError
from ..config import config
logger = logging.getLogger(__name__)
def _pd_from_string(pd: str) -> BatteryPowerDirection:
if pd == 'Discharge':
return BatteryPowerDirection.DISCHARGING
elif pd == 'Charge':
return BatteryPowerDirection.CHARGING
elif pd == 'Do nothing':
return BatteryPowerDirection.DO_NOTHING
else:
raise ValueError(f'invalid power direction: {pd}')
class MonitorConfig:
def __getattr__(self, item):
return config.app_config['monitor'][item]
cfg = MonitorConfig()
"""
TODO:
- поддержать возможность ручного (через бота) переключения тока заряда вверх и вниз
- поддержать возможность бесшовного перезапуска бота, когда монитор понимает, что зарядка уже идет, и он
не запускает программу с начала, а продолжает с уже существующей позиции. Уведомления при этом можно не
присылать совсем, либо прислать какое-то одно приложение, в духе "программа была перезапущена"
"""
class InverterMonitor(Thread):
charging_event_handler: Optional[Callable]
battery_event_handler: Optional[Callable]
util_event_handler: Optional[Callable]
error_handler: Optional[Callable]
osp_change_cb: Optional[Callable]
osp: Optional[OutputSourcePriority]
def __init__(self):
super().__init__()
self.setName('InverterMonitor')
self.interrupted = False
self.min_allowed_current = 0
self.ac_mode = None
self.osp = None
# Event handlers for the bot.
self.charging_event_handler = None
self.battery_event_handler = None
self.util_event_handler = None
self.error_handler = None
self.osp_change_cb = None
# Currents list, defined in the bot config.
self.currents = cfg.gen_currents
self.currents.sort()
# We start charging at lowest possible current, then increase it once per minute (or so) to the maximum level.
# This is done so that the load on the generator increases smoothly, not abruptly. Generator will thank us.
self.current_change_direction = CurrentChangeDirection.UP
self.next_current_enter_time = 0
self.active_current_idx = -1
self.battery_state = BatteryState.NORMAL
self.charging_state = ChargingState.NOT_CHARGING
# 'Mostly-charged' means that we've already lowered the charging current to the level
# at which batteries are charging pretty slow. So instead of burning gasoline and shaking the air,
# we can just turn the generator off at this point.
self.mostly_charged = False
# The stopwatch is used to measure how long does the battery voltage exceeds the float voltage level.
# We don't want to damage our batteries, right?
self.floating_stopwatch = Stopwatch()
# State variables for utilities charging program
self.util_ac_present = None
self.util_pd = None
self.util_solar = None
@property
def active_current(self) -> Optional[int]:
try:
if self.active_current_idx < 0:
return None
return self.currents[self.active_current_idx]
except IndexError:
return None
def run(self):
# Check allowed currents and validate the config.
allowed_currents = list(inverter.exec('get-allowed-ac-charge-currents')['data'])
allowed_currents.sort()
for a in self.currents:
if a not in allowed_currents:
raise ValueError(f'invalid value {a} in gen_currents list')
self.min_allowed_current = min(allowed_currents)
# Reading rated configuration
rated = inverter.exec('get-rated')['data']
self.osp = OutputSourcePriority.from_text(rated['output_source_priority'])
# Read data and run implemented programs every 2 seconds.
while not self.interrupted:
try:
response = inverter.exec('get-status')
if response['result'] != 'ok':
logger.error('get-status failed:', response)
else:
gs = response['data']
ac = gs['grid_voltage']['value'] > 0 or gs['grid_freq']['value'] > 0
solar = gs['pv1_input_voltage']['value'] > 0 or gs['pv2_input_voltage']['value'] > 0
solar_input = gs['pv1_input_power']['value']
v = float(gs['battery_voltage']['value'])
load_watts = int(gs['ac_output_active_power']['value'])
pd = _pd_from_string(gs['battery_power_direction'])
logger.debug(f'got status: ac={ac}, solar={solar}, v={v}, pd={pd}')
if self.ac_mode == ACMode.GENERATOR:
self.gen_charging_program(ac, solar, v, pd)
elif self.ac_mode == ACMode.UTILITIES:
self.utilities_monitoring_program(ac, solar, v, load_watts, solar_input, pd)
if not ac or pd != BatteryPowerDirection.CHARGING:
# if AC is disconnected or not charging, run the low voltage checking program
self.low_voltage_program(v, load_watts)
elif self.battery_state != BatteryState.NORMAL:
# AC is connected and the battery is charging, assume battery level is normal
self.battery_state = BatteryState.NORMAL
except InverterError as e:
logger.exception(e)
time.sleep(2)
def utilities_monitoring_program(self,
ac: bool, # whether AC is connected
solar: bool, # whether MPPT is active
v: float, # battery voltage
load_watts: int, # load, wh
solar_input: int, # input from solar panels, wh
pd: BatteryPowerDirection # current power direction
):
pd_event_send = False
if self.util_solar is None or solar != self.util_solar:
self.util_solar = solar
if solar and self.util_ac_present and self.util_pd == BatteryPowerDirection.CHARGING:
self.charging_event_handler(ChargingEvent.UTIL_CHARGING_STOPPED_SOLAR)
pd_event_send = True
if solar:
if v <= 48 and self.osp == OutputSourcePriority.SolarBatteryUtility:
self.osp_change_cb(OutputSourcePriority.SolarUtilityBattery, solar_input=solar_input, v=v)
self.osp = OutputSourcePriority.SolarUtilityBattery
if self.osp == OutputSourcePriority.SolarUtilityBattery and solar_input >= 900:
self.osp_change_cb(OutputSourcePriority.SolarBatteryUtility, solar_input=solar_input, v=v)
self.osp = OutputSourcePriority.SolarBatteryUtility
if self.util_ac_present is None or ac != self.util_ac_present:
self.util_event_handler(ACPresentEvent.CONNECTED if ac else ACPresentEvent.DISCONNECTED)
self.util_ac_present = ac
if self.util_pd is None or self.util_pd != pd:
self.util_pd = pd
if not pd_event_send and not solar:
if pd == BatteryPowerDirection.CHARGING:
self.charging_event_handler(ChargingEvent.UTIL_CHARGING_STARTED)
elif pd == BatteryPowerDirection.DISCHARGING:
self.charging_event_handler(ChargingEvent.UTIL_CHARGING_STOPPED)
def gen_charging_program(self,
ac: bool, # whether AC is connected
solar: bool, # whether MPPT is active
v: float, # current battery voltage
pd: BatteryPowerDirection # current power direction
):
if self.charging_state == ChargingState.NOT_CHARGING:
if ac and solar:
# Not charging because MPPT is active (solar line is connected).
# Notify users about it and change the current state.
self.charging_state = ChargingState.AC_BUT_SOLAR
self.charging_event_handler(ChargingEvent.AC_CHARGING_UNAVAILABLE_BECAUSE_SOLAR)
logger.info('entering AC_BUT_SOLAR state')
elif ac:
# Not charging, but AC is connected and ready to use.
# Start the charging program.
self.gen_start(pd)
elif self.charging_state == ChargingState.AC_BUT_SOLAR:
if not ac:
# AC charger has been disconnected. Since the state is AC_BUT_SOLAR,
# charging probably never even started. Stop the charging program.
self.gen_stop(ChargingState.NOT_CHARGING)
elif not solar:
# MPPT has been disconnected, and, since AC is still connected, we can
# try to start the charging program.
self.gen_start(pd)
elif self.charging_state in (ChargingState.AC_OK, ChargingState.AC_WAITING):
if not ac:
# Charging was in progress, but AC has been suddenly disconnected.
# Sad, but what can we do? Stop the charging program and return.
self.gen_stop(ChargingState.NOT_CHARGING)
return
if solar:
# Charging was in progress, but MPPT has been detected. Inverter doesn't charge
# batteries from AC when MPPT is active, so we have to pause our program.
self.charging_state = ChargingState.AC_BUT_SOLAR
self.charging_event_handler(ChargingEvent.AC_CHARGING_UNAVAILABLE_BECAUSE_SOLAR)
try:
self.floating_stopwatch.pause()
except StopwatchError:
msg = 'gen_charging_program: floating_stopwatch.pause() failed at (1)'
logger.warning(msg)
# self.error_handler(msg)
logger.info('solar power connected during charging, entering AC_BUT_SOLAR state')
return
# No surprises at this point, just check the values and make decisions based on them.
# - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
# We've reached the 'mostly-charged' point, the voltage level is not float,
# but inverter decided to stop charging (or somebody used a kettle, lol).
# Anyway, assume that charging is complete, stop the program, notify users and return.
if self.mostly_charged and v > (cfg.gen_floating_v - 1) and pd != BatteryPowerDirection.CHARGING:
self.gen_stop(ChargingState.AC_DONE)
return
# Monitor inverter power direction and notify users when it changes.
state = ChargingState.AC_OK if pd == BatteryPowerDirection.CHARGING else ChargingState.AC_WAITING
if state != self.charging_state:
self.charging_state = state
evt = ChargingEvent.AC_CHARGING_STARTED if state == ChargingState.AC_OK else ChargingEvent.AC_NOT_CHARGING
self.charging_event_handler(evt)
if self.floating_stopwatch.get_elapsed_time() >= cfg.gen_floating_time_max:
# We've been at a bulk voltage level too long, so we have to stop charging.
# Set the minimum current possible.
if self.current_change_direction == CurrentChangeDirection.UP:
# This shouldn't happen, obviously an error.
msg = 'gen_charging_program:'
msg += ' been at bulk voltage level too long, but current change direction is still \'up\'!'
msg += ' This is obviously an error, please fix it'
logger.warning(msg)
self.error_handler(msg)
self.gen_next_current(current=self.min_allowed_current)
elif self.active_current is not None:
# If voltage is greater than float voltage, keep the stopwatch ticking
if v > cfg.gen_floating_v and self.floating_stopwatch.is_paused():
try:
self.floating_stopwatch.go()
except StopwatchError:
msg = 'gen_charging_program: floating_stopwatch.go() failed at (2)'
logger.warning(msg)
self.error_handler(msg)
# Otherwise, pause it
elif v <= cfg.gen_floating_v and not self.floating_stopwatch.is_paused():
try:
self.floating_stopwatch.pause()
except StopwatchError:
msg = 'gen_charging_program: floating_stopwatch.pause() failed at (3)'
logger.warning(msg)
self.error_handler(msg)
# Charging current monitoring
if self.current_change_direction == CurrentChangeDirection.UP:
# Generator is warming up in this code path
if self.next_current_enter_time != 0 and pd != BatteryPowerDirection.CHARGING:
# Generator was warming up and charging, but stopped (pd has changed).
# Resetting to the minimum possible current
logger.info(f'gen_charging_program (warming path): was charging but power direction suddeny changed. resetting to minimum current')
self.next_current_enter_time = 0
self.gen_next_current(current=self.min_allowed_current)
elif self.next_current_enter_time == 0 and pd == BatteryPowerDirection.CHARGING:
self.next_current_enter_time = time.time() + cfg.gen_raise_intervals[self.active_current_idx]
logger.info(f'gen_charging_program (warming path): set next_current_enter_time to {self.next_current_enter_time}')
elif self.next_current_enter_time != 0 and time.time() >= self.next_current_enter_time:
logger.info('gen_charging_program (warming path): hit next_current_enter_time, calling gen_next_current()')
self.gen_next_current()
else:
# Gradually lower the current level, based on how close
# battery voltage has come to the bulk level.
if self.active_current >= 30:
upper_bound = cfg.gen_cur30_v_limit
elif self.active_current == 20:
upper_bound = cfg.gen_cur20_v_limit
else:
upper_bound = cfg.gen_cur10_v_limit
# Voltage is high enough already and it's close to bulk level; we hit the upper bound,
# so let's lower the current
if v >= upper_bound:
self.gen_next_current()
elif self.charging_state == ChargingState.AC_DONE:
# We've already finished charging, but AC was connected. Not that it's disconnected,
# set the appropriate state and notify users.
if not ac:
self.gen_stop(ChargingState.NOT_CHARGING)
def gen_start(self, pd: BatteryPowerDirection):
if pd == BatteryPowerDirection.CHARGING:
self.charging_state = ChargingState.AC_OK
self.charging_event_handler(ChargingEvent.AC_CHARGING_STARTED)
logger.info('AC line connected and charging, entering AC_OK state')
# Continue the stopwatch, if needed
try:
self.floating_stopwatch.go()
except StopwatchError:
msg = 'floating_stopwatch.go() failed at ac_charging_start(), AC_OK path'
logger.warning(msg)
self.error_handler(msg)
else:
self.charging_state = ChargingState.AC_WAITING
self.charging_event_handler(ChargingEvent.AC_NOT_CHARGING)
logger.info('AC line connected but not charging yet, entering AC_WAITING state')
# Pause the stopwatch, if needed
try:
if not self.floating_stopwatch.is_paused():
self.floating_stopwatch.pause()
except StopwatchError:
msg = 'floating_stopwatch.pause() failed at ac_charging_start(), AC_WAITING path'
logger.warning(msg)
self.error_handler(msg)
# idx == -1 means haven't started our program yet.
if self.active_current_idx == -1:
self.gen_next_current()
# self.set_hw_charging_current(self.min_allowed_current)
def gen_stop(self, reason: ChargingState):
self.charging_state = reason
if reason == ChargingState.AC_DONE:
event = ChargingEvent.AC_CHARGING_FINISHED
elif reason == ChargingState.NOT_CHARGING:
event = ChargingEvent.AC_DISCONNECTED
else:
raise ValueError(f'ac_charging_stop: unexpected reason {reason}')
logger.info(f'charging is finished, entering {reason} state')
self.charging_event_handler(event)
self.next_current_enter_time = 0
self.mostly_charged = False
self.active_current_idx = -1
self.floating_stopwatch.reset()
self.current_change_direction = CurrentChangeDirection.UP
self.set_hw_charging_current(self.min_allowed_current)
def gen_next_current(self, current=None):
if current is None:
try:
current = self._next_current()
logger.debug(f'gen_next_current: ready to change charging current to {current} A')
except IndexError:
logger.debug('gen_next_current: was going to change charging current, but no currents left; finishing charging program')
self.gen_stop(ChargingState.AC_DONE)
return
else:
try:
idx = self.currents.index(current)
except ValueError:
msg = f'gen_next_current: got current={current} but it\'s not in the currents list'
logger.error(msg)
self.error_handler(msg)
return
self.active_current_idx = idx
if self.current_change_direction == CurrentChangeDirection.DOWN:
if current == self.currents[0]:
self.mostly_charged = True
self.gen_stop(ChargingState.AC_DONE)
elif current == self.currents[1] and not self.mostly_charged:
self.mostly_charged = True
self.charging_event_handler(ChargingEvent.AC_MOSTLY_CHARGED)
self.set_hw_charging_current(current)
def set_hw_charging_current(self, current: int):
try:
response = inverter.exec('set-max-ac-charge-current', (0, current))
if response['result'] != 'ok':
logger.error(f'failed to change AC charging current to {current} A')
raise InverterError('set-max-ac-charge-current: inverterd reported error')
else:
self.charging_event_handler(ChargingEvent.AC_CURRENT_CHANGED, current=current)
logger.info(f'changed AC charging current to {current} A')
except InverterError as e:
self.error_handler(f'failed to set charging current to {current} A (caught InverterError)')
logger.exception(e)
def _next_current(self):
if self.current_change_direction == CurrentChangeDirection.UP:
self.active_current_idx += 1
if self.active_current_idx == len(self.currents)-1:
logger.info('_next_current: charging current power direction to DOWN')
self.current_change_direction = CurrentChangeDirection.DOWN
self.next_current_enter_time = 0
else:
if self.active_current_idx == 0:
raise IndexError('can\'t go lower')
self.active_current_idx -= 1
logger.info(f'_next_current: active_current_idx set to {self.active_current_idx}, returning current of {self.currents[self.active_current_idx]} A')
return self.currents[self.active_current_idx]
def low_voltage_program(self, v: float, load_watts: int):
crit_level = cfg.vcrit
low_level = cfg.vlow
if v <= crit_level:
state = BatteryState.CRITICAL
elif v <= low_level:
state = BatteryState.LOW
else:
state = BatteryState.NORMAL
if state != self.battery_state:
self.battery_state = state
self.battery_event_handler(state, v, load_watts)
def set_charging_event_handler(self, handler: Callable):
self.charging_event_handler = handler
def set_battery_event_handler(self, handler: Callable):
self.battery_event_handler = handler
def set_util_event_handler(self, handler: Callable):
self.util_event_handler = handler
def set_error_handler(self, handler: Callable):
self.error_handler = handler
def set_osp_need_change_callback(self, cb: Callable):
self.osp_change_cb = cb
def set_ac_mode(self, mode: ACMode):
self.ac_mode = mode
def notify_osp(self, osp: OutputSourcePriority):
self.osp = osp
def stop(self):
self.interrupted = True
def dump_status(self) -> dict:
return {
'interrupted': self.interrupted,
'currents': self.currents,
'active_current': self.active_current,
'current_change_direction': self.current_change_direction.name,
'battery_state': self.battery_state.name,
'charging_state': self.charging_state.name,
'mostly_charged': self.mostly_charged,
'floating_stopwatch_paused': self.floating_stopwatch.is_paused(),
'floating_stopwatch_elapsed': self.floating_stopwatch.get_elapsed_time(),
'time_now': time.time(),
'next_current_enter_time': self.next_current_enter_time,
'ac_mode': self.ac_mode,
'osp': self.osp,
'util_ac_present': self.util_ac_present,
'util_pd': self.util_pd.name,
'util_solar': self.util_solar
}
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