charger-display/charger-display.py

#!/usr/bin/env python3

import math
import os
import struct
import time
import random
import serial
import sys

import numpy as np

from PyQt5.QtCore import Qt, QTimer, QThread, QObject, pyqtSignal
from PyQt5.QtWidgets import (
    QApplication,
    QWidget,
    QPushButton,
    QVBoxLayout,
    QHBoxLayout,
    QGridLayout,
    QLabel,
    QGroupBox,
    QFrame,
    QSizePolicy,
)


BITRATE = 115200  # baud/s
TIMEOUT = 1  # seconds
N_SLAVES = 9
LOG_FRAME_LENGTH = 8  # bytes

PARALLEL_CELLS = 9
CELLS_PER_SLAVE = 10
TEMP_SENSORS_PER_SLAVE = 32
VOLTAGE_CONV = 5.0 / 0xFFFF  # volts/quantum
TEMP_CONV = 0.0625  # °C/quantum

ERRORCODE_TIMEOUT_SLAVE = 1
ERRORCODE_SLAVE_PANIC = 2
ERRORCODE_TIMEOUT_SLAVE_FRAMES = 3
ERRORCODE_TOO_FEW_TEMPS = 4
ERRORCODE_TIMEOUT_SHUNT = 6
ERRORCODE_MASTER_THRESH = 7
SLAVE_ERROR_UV = 0
SLAVE_ERROR_OV = 1
SLAVE_ERROR_UT = 2
SLAVE_ERROR_OT = 3
SLAVE_ERROR_BQ = 4
SLAVE_ERROR_TMP144 = 5
MASTER_THRESH_UT = 0
MASTER_THRESH_OT = 1
MASTER_THRESH_UV = 2
MASTER_THRESH_OV = 3

TS_ERROR = 4


class SlaveData:
    cell_voltages: list[float]
    cell_temps: list[float]

    def __init__(self) -> None:
        self.cell_voltages = [-1] * CELLS_PER_SLAVE
        self.cell_temps = ([-1] * (TEMP_SENSORS_PER_SLAVE // 2)) + (
            [0] * (TEMP_SENSORS_PER_SLAVE // 2)
        )


class AccumulatorData:
    slaves: list[SlaveData]
    min_voltage: float
    max_voltage: float
    min_soc: float
    max_soc: float
    min_temp: float
    max_temp: float
    last_frame: float
    time_since_last_frame: float
    current: float
    panic: bool
    panic_errorcode: int
    panic_errorarg: int

    def __init__(self) -> None:
        self.slaves = [SlaveData() for _ in range(N_SLAVES)]
        self.min_voltage = (
            self.max_voltage
        ) = (
            self.min_soc
        ) = (
            self.max_soc
        ) = self.min_temp = self.max_temp = self.last_frame = self.current = 0
        self.panic = False
        self.panic_errorcode = self.panic_errorarg = 0
        self.time_since_last_frame = 0

    def fill_dummy_data(self):
        self.min_voltage = random.uniform(1, 3)
        self.max_voltage = random.uniform(3, 5)
        self.min_temp = random.uniform(0, 25)
        self.max_temp = random.uniform(25, 60)
        self.current = random.uniform(25, 60)
        self.last_frame = time.time() - random.random()
        self.panic = random.choice([True, False])
        if self.panic:
            self.panic_errorcode = random.randint(1, 10000)
            self.panic_errorarg = "ABCDERFG"
        else:
            self.panic_errorcode = 0
            self.panic_errorarg = ""
        data.time_since_last_frame = random.uniform(1, 60)

        for i in range(N_SLAVES):
            self.slaves[i].cell_voltages = [
                random.uniform(1, 5) for i in range(CELLS_PER_SLAVE)
            ]
            self.slaves[i].cell_temps = [
                random.uniform(25, 60) for i in range(TEMP_SENSORS_PER_SLAVE)
            ]


class StackGuiElement:
    title: str
    stack_id: int
    min_voltage_label: QLabel
    max_voltage_label: QLabel
    min_temp_label: QLabel
    max_temp_label: QLabel
    groupBox: QGroupBox
    detail_popup: QWidget

    def __init__(self, title: str, stack_id: int):
        self.title = title
        self.stack_id = stack_id
        self.min_voltage_label = QLabel()
        self.max_voltage_label = QLabel()
        self.min_temp_label = QLabel()
        self.max_temp_label = QLabel()
        self.groupBox = QGroupBox()
        self.detail_popup = None
        self.__post__init__()

    def __post__init__(self):
        l1 = QLabel("Min Voltage [V]")
        l2 = QLabel("Max Voltage [V]")
        l3 = QLabel("Min Temperature [°C]")
        l4 = QLabel("Max Temperature [°C]")
        popup_btn = QPushButton("Details")
        popup_btn.clicked.connect(self.show_popup)

        l1.setAlignment(Qt.AlignLeft)
        l2.setAlignment(Qt.AlignLeft)
        l3.setAlignment(Qt.AlignLeft)
        l4.setAlignment(Qt.AlignLeft)

        self.min_voltage_label.setAlignment(Qt.AlignLeft)
        self.max_voltage_label.setAlignment(Qt.AlignLeft)
        self.min_temp_label.setAlignment(Qt.AlignLeft)
        self.max_temp_label.setAlignment(Qt.AlignLeft)

        grid = QGridLayout()
        grid.addWidget(l1, 0, 0)
        grid.addWidget(l2, 1, 0)
        grid.addWidget(l3, 2, 0)
        grid.addWidget(l4, 3, 0)

        grid.addWidget(self.min_voltage_label, 0, 1)
        grid.addWidget(self.max_voltage_label, 1, 1)
        grid.addWidget(self.min_temp_label, 2, 1)
        grid.addWidget(self.max_temp_label, 3, 1)

        grid.addWidget(popup_btn, 0, 2)

        self.groupBox.setTitle(self.title)
        self.groupBox.setLayout(grid)

    def update_data_from_slave(self, slave: SlaveData):
        self.min_voltage_label.setText(f"{min(slave.cell_voltages):.02f}")
        self.max_voltage_label.setText(f"{max(slave.cell_voltages):.02f}")
        self.min_temp_label.setText(f"{min(slave.cell_temps):.02f}")
        self.max_temp_label.setText(f"{max(slave.cell_temps):.02f}")

    def show_popup(self):
        if self.detail_popup is None:
            self.detail_popup = StackPopup(self.stack_id)
        self.detail_popup.show()


class QVSeperationLine(QFrame):
    """
    a vertical seperation line
    """

    def __init__(self):
        super().__init__()
        self.setFixedWidth(20)
        self.setMinimumHeight(1)
        self.setFrameShape(QFrame.VLine)
        self.setFrameShadow(QFrame.Sunken)
        self.setSizePolicy(QSizePolicy.Minimum, QSizePolicy.Preferred)
        return


class StackPopup(QWidget):
    stack_id: int
    voltage_labels: list[QLabel]
    temp_labels: list[QLabel]

    def __init__(self, stack_id: int):
        super().__init__()
        self.stack_id = stack_id
        self.voltage_labels = []
        self.temp_labels = []
        layout = QVBoxLayout()
        groupbox = QGroupBox()

        grid = QGridLayout()

        for i in range(len(data.slaves[stack_id].cell_voltages)):
            l1 = QLabel(f"Voltage Cell {i}")
            l1.setAlignment(Qt.AlignLeft)

            l_v = QLabel()
            l_v.setNum(data.slaves[stack_id].cell_voltages[i])
            l_v.setAlignment(Qt.AlignLeft)
            self.voltage_labels.append(l_v)

            grid.addWidget(l1, i, 0)
            grid.addWidget(l_v, i, 1)

        # vertical separators between rows in popup
        separator_vertical = QVSeperationLine()
        grid.addWidget(separator_vertical, 0, 2, CELLS_PER_SLAVE, 1)
        num_temp_cols = len(data.slaves[stack_id].cell_temps) // CELLS_PER_SLAVE
        for i in range(num_temp_cols):
            separator_vertical = QVSeperationLine()
            grid.addWidget(separator_vertical, 0, 5 + i * 3, CELLS_PER_SLAVE, 1)

        for i in range(len(data.slaves[stack_id].cell_temps)):
            l2 = QLabel(f"Temp. Sensor {i}")
            l2.setAlignment(Qt.AlignLeft)

            l_t = QLabel()
            l_t.setNum(data.slaves[stack_id].cell_temps[i])
            l_t.setAlignment(Qt.AlignLeft)
            self.temp_labels.append(l_t)

            grid.addWidget(l2, i % CELLS_PER_SLAVE, 3 + (i // CELLS_PER_SLAVE) * 3)
            grid.addWidget(l_t, i % CELLS_PER_SLAVE, 4 + (i // CELLS_PER_SLAVE) * 3)

        groupbox.setTitle(f"Stack {stack_id}")
        groupbox.setLayout(grid)
        layout.addWidget(groupbox)
        self.setLayout(layout)
        self.update_data()
        timer.timeout.connect(self.update_data)

    def update_data(self):
        for i in range(len(data.slaves[self.stack_id].cell_voltages)):
            self.voltage_labels[i].setNum(data.slaves[self.stack_id].cell_voltages[i])
        for i in range(len(data.slaves[self.stack_id].cell_temps)):
            self.temp_labels[i].setNum(data.slaves[self.stack_id].cell_temps[i])


class Window(QWidget):

    stop_signal = (
        pyqtSignal()
    )  # make a stop signal to communicate with the worker in another thread

    def __init__(self, parent=None):
        super(Window, self).__init__(parent)

        win = QVBoxLayout()

        ### ACCUMULATOR GENERAL ###
        self.l1 = QLabel("Min Voltage [V]")
        self.l1.setAlignment(Qt.AlignLeft)
        self.l_min_voltage = QLabel()
        self.l_min_voltage.setNum(data.min_voltage)
        self.l_min_voltage.setAlignment(Qt.AlignLeft)

        self.l2 = QLabel("Max Voltage [V]")
        self.l2.setAlignment(Qt.AlignLeft)
        self.l_max_voltage = QLabel()
        self.l_max_voltage.setNum(data.max_voltage)
        self.l_max_voltage.setAlignment(Qt.AlignLeft)

        self.l3 = QLabel("Min SoC [%]")
        self.l3.setAlignment(Qt.AlignLeft)
        self.l_min_soc = QLabel()
        self.l_min_soc.setNum(data.min_soc)
        self.l_min_soc.setAlignment(Qt.AlignLeft)

        self.l4 = QLabel("Max SoC [%]")
        self.l4.setAlignment(Qt.AlignLeft)
        self.l_max_soc = QLabel()
        self.l_max_soc.setNum(data.max_soc)
        self.l_max_soc.setAlignment(Qt.AlignLeft)

        self.l5 = QLabel("Min Temperature [°C]")
        self.l5.setAlignment(Qt.AlignLeft)
        self.l_min_temp = QLabel()
        self.l_min_temp.setNum(data.min_temp)
        self.l_min_temp.setAlignment(Qt.AlignLeft)

        self.l6 = QLabel("Max Temperature [°C]")
        self.l6.setAlignment(Qt.AlignLeft)
        self.l_max_temp = QLabel()
        self.l_max_temp.setNum(data.max_temp)
        self.l_max_temp.setAlignment(Qt.AlignLeft)

        self.l7 = QLabel("Current [A]")
        self.l7.setAlignment(Qt.AlignLeft)
        self.l_current = QLabel()
        self.l_current.setNum(data.current)
        self.l_current.setAlignment(Qt.AlignLeft)

        self.l8 = QLabel("Error")
        self.l_error = QLabel()
        self.l_error.setText(str(data.panic))
        self.l_error.setAlignment(Qt.AlignLeft)
        self.l_errorcode = QLabel()
        self.l_errorcode.setText(str(data.panic_errorcode))
        self.l_errorcode.setAlignment(Qt.AlignLeft)
        self.l_errorarg = QLabel()
        self.l_errorarg.setText(str(data.panic_errorarg))
        self.l_errorcode.setAlignment(Qt.AlignLeft)

        self.l9 = QLabel("Time Since Last Dataframe")
        self.l_time_since_last_frame = QLabel()
        self.l_time_since_last_frame.setText(str(data.time_since_last_frame))
        self.l_time_since_last_frame.setAlignment(Qt.AlignLeft)

        ### LAYOUT ACCUMULATOR GENERAL ###
        grid_accumulator = QGridLayout()
        grid_accumulator.addWidget(self.l1, 0, 0)
        grid_accumulator.addWidget(self.l2, 1, 0)
        grid_accumulator.addWidget(self.l3, 2, 0)
        grid_accumulator.addWidget(self.l4, 3, 0)
        grid_accumulator.addWidget(self.l5, 0, 2)
        grid_accumulator.addWidget(self.l6, 1, 2)
        grid_accumulator.addWidget(self.l7, 2, 2)
        grid_accumulator.addWidget(self.l8, 5, 0)
        grid_accumulator.addWidget(self.l9, 3, 2)

        grid_accumulator.addWidget(self.l_min_voltage, 0, 1)
        grid_accumulator.addWidget(self.l_max_voltage, 1, 1)
        grid_accumulator.addWidget(self.l_min_soc, 2, 1)
        grid_accumulator.addWidget(self.l_max_soc, 3, 1)
        grid_accumulator.addWidget(self.l_min_temp, 0, 3)
        grid_accumulator.addWidget(self.l_max_temp, 1, 3)
        grid_accumulator.addWidget(self.l_current, 2, 3)
        grid_accumulator.addWidget(self.l_error, 5, 1)
        grid_accumulator.addWidget(self.l_errorcode, 5, 2)
        grid_accumulator.addWidget(self.l_errorarg, 5, 3)
        grid_accumulator.addWidget(self.l_time_since_last_frame, 3, 3)

        groupBox_accumulator = QGroupBox("Accumulator General")
        groupBox_accumulator.setLayout(grid_accumulator)

        win.addWidget(groupBox_accumulator)

        ### STACKS ###
        self.stack_gui_elements = []
        for i in range(N_SLAVES):
            sge = StackGuiElement(f"Stack {i}", i)
            sge.update_data_from_slave(data.slaves[i])
            self.stack_gui_elements.append(sge)

        ### LAYOUT STACKS ###
        n_slaves_half = math.ceil(N_SLAVES / 2)
        grid_stacks = QGridLayout()
        for i, sge in enumerate(self.stack_gui_elements):
            grid_stacks.addWidget(
                sge.groupBox, 0 if i < n_slaves_half else 1, i % n_slaves_half
            )

        groupBox_stacks = QGroupBox("Individual Stacks")
        groupBox_stacks.setLayout(grid_stacks)

        win.addWidget(groupBox_stacks)

        ### BUTTONS ###
        self.btn_start = QPushButton("Start Serial")
        self.btn_start.resize(self.btn_start.sizeHint())
        self.btn_start.move(50, 50)
        self.btn_stop = QPushButton("Stop Serial")
        self.btn_stop.resize(self.btn_stop.sizeHint())
        self.btn_stop.move(150, 50)
        self.btn_charge = QPushButton("Start Charging")
        self.btn_charge.resize(self.btn_charge.sizeHint())
        self.btn_charge.move(250, 50)
        self.btn_balance = QPushButton("Start Balancing")
        self.btn_balance.resize(self.btn_balance.sizeHint())
        self.btn_balance.move(350, 50)

        ### LAYOUT BUTTONS ###
        vbox_controls = QVBoxLayout()
        vbox_controls.addWidget(self.btn_start)
        vbox_controls.addWidget(self.btn_stop)
        vbox_controls.addWidget(self.btn_charge)
        vbox_controls.addWidget(self.btn_balance)
        groupBox_controls = QGroupBox("Controls")
        groupBox_controls.setLayout(vbox_controls)
        win.addWidget(groupBox_controls)

        # Start Button action
        self.btn_start.clicked.connect(self.start_thread)

        # Stop Button action
        self.btn_stop.clicked.connect(self.stop_thread)

        # Charge Button action
        self.btn_charge.clicked.connect(self.start_charge)

        # Balance Button action
        self.btn_balance.clicked.connect(self.start_balance)

        self.setLayout(win)
        self.setWindowTitle("FT22 Charger Display")

    # When start_btn is clicked this runs. Creates the worker and the thread.
    def start_thread(self):
        self.thread = QThread()
        self.worker = Worker()
        self.stop_signal.connect(
            self.worker.stop
        )  # connect stop signal to worker stop method
        self.worker.moveToThread(self.thread)

        self.worker.finished.connect(
            self.thread.quit
        )  # connect the workers finished signal to stop thread
        self.worker.finished.connect(
            self.worker.deleteLater
        )  # connect the workers finished signal to clean up worker
        self.thread.finished.connect(
            self.thread.deleteLater
        )  # connect threads finished signal to clean up thread

        self.thread.started.connect(self.worker.do_work)
        self.thread.finished.connect(self.worker.stop)
        self.thread.start()

    # When stop_btn is clicked this runs. Terminates the worker and the thread.
    def stop_thread(self):
        self.stop_signal.emit()  # emit the finished signal on stop

    def start_charge(self):
        ser.write(b"C")

    def start_balance(self):
        ser.write(b"B")

    def update(self):
        # Accumulator
        self.l_min_voltage.setText(f"{data.min_voltage:.02f}")
        self.l_max_voltage.setText(f"{data.max_voltage:.02f}")
        self.l_min_soc.setText(f"{data.min_soc:.01f}")
        self.l_max_soc.setText(f"{data.max_soc:.01f}")
        self.l_min_temp.setText(f"{data.min_temp:.02f}")
        self.l_max_temp.setText(f"{data.max_temp:.02f}")
        self.l_current.setText(f"{data.current:.02f}")
        self.l_error.setText(str(data.panic))
        self.l_errorcode.setText(str(data.panic_errorcode))
        self.l_errorarg.setText(str(data.panic_errorarg))
        last_time = time.time() - data.last_frame
        self.l_time_since_last_frame.setText(f"{last_time:.03f}")

        # Stacks
        for i, sge in enumerate(self.stack_gui_elements):
            sge.update_data_from_slave(data.slaves[i])


class Worker(QObject):

    finished = pyqtSignal()  # give worker class a finished signal

    def __init__(self, parent=None):
        QObject.__init__(self, parent=parent)
        self.continue_run = True  # provide a bool run condition for the class

    def do_work(self):
        i = 1
        while self.continue_run:  # give the loop a stoppable condition
            # data.fill_dummy_data()
            self.charger_communication()
            # QThread.msleep(1)

        self.finished.emit()  # emit the finished signal when the loop is done

    def charger_communication(self):
        rx_data = ser.read(256)
        # print(len(rx_data), rx_data)
        while len(rx_data) > 0:
            if (frame_start := self.check_log_start(rx_data)) != -1:
                self.decode_log_frame(rx_data[frame_start + 3 : frame_start + 11])
                rx_data = rx_data[frame_start + 11 :]
                continue
            elif (frame_start := self.check_current_start(rx_data)) != -1:
                self.decode_current_frame(rx_data[frame_start + 3 : frame_start + 11])
                rx_data = rx_data[frame_start + 11 :]
                continue
            elif (frame_start := self.check_panic_start(rx_data)) != -1:
                self.decode_panic_frame(rx_data[frame_start + 3 : frame_start + 11])
                rx_data = rx_data[frame_start + 11 :]
                continue
            elif (frame_start := self.check_status_start(rx_data)) != -1:
                self.decode_status_frame(rx_data[frame_start + 3 : frame_start + 11])
                rx_data = rx_data[frame_start + 11 :]
                continue
            break

    def check_log_start(self, buf: bytes):
        return buf[:-12].find(b"LOG")

    def check_current_start(self, buf: bytes):
        return buf[:-12].find(b"CUR")

    def check_panic_start(self, buf: bytes):
        return buf[:-12].find(b"PAN")

    def check_status_start(self, buf: bytes):
        return buf[:-12].find(b"STA")

    def decode_log_frame(self, buf: bytes):
        msg_id = buf[0]
        slave = msg_id >> 4
        frame_id = msg_id & 0x0F
        if slave >= N_SLAVES:
            print(f"Unknown slave: {slave}", file=sys.stderr)
            return

        if frame_id == 0:
            for i in range(3):
                raw = (buf[i * 2 + 1] << 8) | buf[i * 2 + 2]
                data.slaves[slave].cell_voltages[i] = raw * VOLTAGE_CONV
        elif frame_id == 1:
            for i in range(3):
                raw = (buf[i * 2 + 1] << 8) | buf[i * 2 + 2]
                data.slaves[slave].cell_voltages[i + 3] = raw * VOLTAGE_CONV
        elif frame_id == 2:
            for i in range(3):
                raw = (buf[i * 2 + 1] << 8) | buf[i * 2 + 2]
                data.slaves[slave].cell_voltages[i + 6] = raw * VOLTAGE_CONV
        elif frame_id == 3:
            for i in range(1):
                raw = (buf[i * 2 + 1] << 8) | buf[i * 2 + 2]
                data.slaves[slave].cell_voltages[i + 9] = raw * VOLTAGE_CONV
            for i in range(2):
                raw = (buf[i * 2 + 3] << 8) | buf[i * 2 + 4]
                data.slaves[slave].cell_temps[i] = raw * TEMP_CONV
        elif frame_id == 4:
            for i in range(3):
                raw = (buf[i * 2 + 1] << 8) | buf[i * 2 + 2]
                data.slaves[slave].cell_temps[i + 2] = raw * TEMP_CONV
        elif frame_id == 5:
            for i in range(3):
                raw = (buf[i * 2 + 1] << 8) | buf[i * 2 + 2]
                data.slaves[slave].cell_temps[i + 5] = raw * TEMP_CONV
        elif frame_id == 6:
            for i in range(3):
                raw = (buf[i * 2 + 1] << 8) | buf[i * 2 + 2]
                data.slaves[slave].cell_temps[i + 8] = raw * TEMP_CONV
        elif frame_id == 7:
            for i in range(3):
                raw = (buf[i * 2 + 1] << 8) | buf[i * 2 + 2]
                data.slaves[slave].cell_temps[i + 11] = raw * TEMP_CONV
        elif frame_id == 8:
            for i in range(3):
                raw = (buf[i * 2 + 1] << 8) | buf[i * 2 + 2]
                data.slaves[slave].cell_temps[i + 14] = raw * TEMP_CONV
        else:
            print(f"Unknown frame ID: {frame_id} (buf: {repr(buf)})", file=sys.stderr)
            # time.sleep(1)
            return
        voltages = [
            slave.cell_voltages[i]
            for i in range(CELLS_PER_SLAVE)
            for slave in data.slaves
        ]
        self.parse_cell_temps(slave)
        temps = [
            slave.cell_temps[i]
            for i in range(TEMP_SENSORS_PER_SLAVE)
            for slave in data.slaves
        ]
        data.min_voltage = min(voltages)
        data.max_voltage = max(voltages)
        data.min_soc = self.calculate_soc(data.min_voltage)
        data.max_soc = self.calculate_soc(data.max_voltage)
        data.min_temp = min(temps)
        data.max_temp = max(temps)
        data.time_since_last_frame = time.time() - data.last_frame

        data.last_frame = time.time()

    def decode_current_frame(self, buf: bytes):
        # current = (buf[2] << 24) | (buf[3] << 16) | (buf[4] << 8) | (buf[5])
        current = struct.unpack(">i", buf[2:6])[0]
        data.current = current / 1000.0

    def decode_panic_frame(self, buf: bytes):
        data.panic = True
        errorcode = int(buf[0])
        errorargs = [int(buf[1]), int(buf[2])]
        if errorcode == ERRORCODE_TIMEOUT_SLAVE:
            data.panic_errorcode = "Slave timeout"
            data.panic_errorarg = f"Slave ID {errorargs[0]}"
        elif errorcode == ERRORCODE_SLAVE_PANIC:
            data.panic_errorcode = "Slave panic"
            if errorargs[1] == SLAVE_ERROR_UV:
                slave_error = "Undervoltage"
            elif errorargs[1] == SLAVE_ERROR_OV:
                slave_error = "Overvoltage"
            elif errorargs[1] == SLAVE_ERROR_UT:
                slave_error = "Undertemperature"
            elif errorargs[1] == SLAVE_ERROR_OT:
                slave_error = "Overtemperature"
            elif errorargs[1] == SLAVE_ERROR_BQ:
                slave_error = "BQ Communication error"
            elif errorargs[1] == SLAVE_ERROR_TMP144:
                slave_error = "TMP144 communication error"
            else:
                slave_error = f"Unknown error ({errorargs[1]})"
            data.panic_errorarg = f"Slave ID {errorargs[0]}: {slave_error}"
        elif errorcode == ERRORCODE_TIMEOUT_SLAVE_FRAMES:
            data.panic_errorcode = "Slave frame timeout"
            data.panic_errorarg = f"Slave ID {errorargs[0]}, frame {errorargs[1]}"
        elif errorcode == ERRORCODE_TOO_FEW_TEMPS:
            data.panic_errorcode = "Too few temperature sensors"
            data.panic_errorarg = f"Slave ID {errorargs[0]}"
        elif errorcode == ERRORCODE_TIMEOUT_SHUNT:
            data.panic_errorcode = "Shunt timeout"
        elif errorcode == ERRORCODE_MASTER_THRESH:
            data.panic_errorcode = "Master detected threshold"
            if errorargs[0] == MASTER_THRESH_UT:
                data.panic_errorarg = "Undertemperature"
            elif errorargs[0] == MASTER_THRESH_OT:
                data.panic_errorarg = "Overtemperature"
            elif errorargs[0] == MASTER_THRESH_UV:
                data.panic_errorarg = "Undervoltage"
            elif errorargs[0] == MASTER_THRESH_OV:
                data.panic_errorarg = "Overvoltage"
            else:
                data.panic_errorarg = f"Unknown threshold ({errorargs[0]})"
        else:
            data.panic_errorcode = buf[0]
            data.panic_errorarg = buf[1]

    def decode_status_frame(self, buf: bytes):
        ts_state = buf[1] & 0x7F
        data.panic = ts_state == TS_ERROR

    INTERNAL_RESISTANCE_CURVE_X = [2.0, 4.12]
    INTERNAL_RESISTANCE_CURVE_Y = [0.0528, 0.0294]
    SOC_OCV_X = [2.1, 2.9, 3.2, 3.3, 3.4, 3.5, 3.68, 4.0, 4.15, 4.2]
    SOC_OCV_Y = [0, 0.023, 0.06, 0.08, 0.119, 0.227, 0.541, 0.856, 0.985, 1.0]

    def calculate_soc(self, voltage: float):
        r_i = np.interp(
            [voltage],
            self.INTERNAL_RESISTANCE_CURVE_X,
            self.INTERNAL_RESISTANCE_CURVE_Y,
        )[0]
        # i = data.current / PARALLEL_CELLS
        i = 3 / PARALLEL_CELLS
        ocv = voltage - i * r_i
        return np.interp([ocv], self.SOC_OCV_X, self.SOC_OCV_Y)[0] * 100

    def parse_cell_temps(self, slave: int):
        temps = list(
            filter(lambda t: t > 0 and t < 60, data.slaves[slave].cell_temps[:16])
        )
        if len(temps) == 0:
            temps = [-1]
        min_t = min(temps)
        max_t = max(temps)
        # for i in range(16, 32):
        #     data.slaves[slave].cell_temps[i] = random.randint(min_t, max_t)

    def stop(self):
        self.continue_run = False  # set the run condition to false on stop


if __name__ == "__main__":
    data = AccumulatorData()
    rx_buf = bytes()

    if len(sys.argv) != 2:
        print(f"Usage: {sys.argv[0]} SERIAL-PORT", file=sys.stderr)
        sys.exit(os.EX_USAGE)

    SERIAL_PORT = sys.argv[1]
    print(SERIAL_PORT)
    ser = serial.Serial(SERIAL_PORT, BITRATE, timeout=TIMEOUT)

    app = QApplication(sys.argv)
    gui = Window()
    gui.show()

    timer = QTimer()
    # timer.timeout.connect(data.fill_dummy_data)
    timer.timeout.connect(gui.update)
    timer.start(1000)  # every 1,000 milliseconds

    sys.exit(app.exec_())