Files
vtt_work/nucleares_monitor/control_board_monitor.py
T
2025-10-21 12:28:39 +02:00

3508 lines
166 KiB
Python
Raw Blame History

This file contains ambiguous Unicode characters
This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.
#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
Control Board Monitor — v1.8
Whats new:
- POSTs are now **exactly** like the sample app:
POST http://<host>:<port>/?variable=<NAME>&value=<ARG> (method=POST, no body)
(All previous POST modes removed.)
- Select Variables dialog: typing in the filter **does not clear** previously ticked checkboxes.
- Mouse wheel scrolling enabled (selector canvas, main variables tree, actions tree).
"""
import json
import math
import queue
import re
import threading
from collections import deque
import time
import urllib.parse
import urllib.request
from dataclasses import dataclass, field
from datetime import datetime
from typing import Dict, List, Optional, Tuple, Deque
import math # NOWE: do decymacji i obliczeń
import traceback
import signal
import sys
# --- Qt log & DPI: uspokojenie Qt na multi-monitor (opcjonalne, ale pomaga) ---
import os
os.environ.setdefault("QT_LOGGING_RULES", "qt.core.qobject.connect=false")
os.environ.setdefault("QT_ENABLE_HIGHDPI_SCALING", "0")
os.environ.setdefault("QT_AUTO_SCREEN_SCALE_FACTOR", "0")
try:
import faulthandler as _fh
except Exception:
_fh = None # brak modułu lub inny problem pomijamy
def _fh_install_signal_dump(sig_name: str):
"""Próbuje włączyć dump stacka pod danym sygnałem.
1) preferuj _fh.register jeśli dostępny,
2) w przeciwnym razie zwykły signal.signal z fallbackiem na dump_traceback.
"""
if _fh is None:
return
sig = getattr(signal, sig_name, None)
if sig is None:
return
# Najpierw spróbuj natywnego rejestru faulthandlera (jeśli istnieje w tej wersji Pythona)
if hasattr(_fh, "register"):
try:
_fh.register(sig, file=sys.stderr, all_threads=True)
return
except Exception:
# Brak wsparcia / błąd rejestracji spróbuj fallbacku
pass
# Fallback: zwykły handler sygnału, który zrzuci stack wszystkich wątków
def _dump(_signo, _frame):
try:
_fh.dump_traceback(file=sys.stderr, all_threads=True)
except Exception:
raise RuntimeError("Faulthandler dump_traceback failed")
try:
signal.signal(sig, _dump)
except Exception:
# Nie udało się trudno, po prostu odpuszczamy ten sygnał
raise RuntimeError(f"Faulthandler signal registration failed for {sig_name}")
# Włącz faulthandler globalnie (o ile jest)
if _fh is not None:
try:
_fh.enable(all_threads=True)
except Exception:
# Nie blokuj uruchomienia aplikacji to tylko narzędzie diagnostyczne
pass
# Spróbuj podczepić kilka sensownych sygnałów; ignoruj, jeśli ich nie ma na danej platformie
for _sig_name in ("SIGBREAK", "SIGTERM", "SIGINT"):
_fh_install_signal_dump(_sig_name)
# --- koniec bezpiecznej inicjalizacji faulthandlera ---
DEBUG_LOG = True # możesz wyłączyć na False gdy już będzie stabilnie
def DBGL(msg: str):
if not DEBUG_LOG:
return
try:
from datetime import datetime
with open("cbm_debug.log", "a", encoding="utf-8") as f:
f.write(f"{datetime.now().strftime('%H:%M:%S.%f')} {msg}\n")
except Exception:
DBGEX("DBGL")
def DBGEX(where: str):
DBGL(f"[EXC] {where}\n{traceback.format_exc()}")
# 3) global excepthook (main thread)
def _global_excepthook(exctype, value, tb):
DBGL("[GLOBAL EXC] " + "".join(traceback.format_exception(exctype, value, tb)))
sys.__excepthook__(exctype, value, tb)
sys.excepthook = _global_excepthook
# 4) thread excepthook (Python 3.8+)
def _thread_excepthook(args):
DBGL("[THREAD EXC] " + "".join(traceback.format_exception(args.exc_type, args.exc_value, args.exc_traceback)))
threading.excepthook = _thread_excepthook
# 5) Qt message handler (jeśli PySide6 / pyqtgraph dostępne)
try:
from PySide6 import QtCore
def _qt_msg_handler(mode, ctx, message):
DBGL(f"[QT] {message}")
QtCore.qInstallMessageHandler(_qt_msg_handler)
except Exception:
DBGEX("Qt qInstallMessageHandler")
SAFE_GLOBALS = {
"__builtins__": {},
"abs": abs, "min": min, "max": max, "round": round,
"int": int, "float": float, "pow": pow, "math": math,
}
def safe_eval(expr: str, symbols: dict):
"""Bardzo ograniczony eval tylko dopuszczone funkcje i przekazane symbole."""
clean = {k: v for k, v in (symbols or {}).items() if v is not None}
return eval(expr, SAFE_GLOBALS, clean)
def eval_user_expression(expr: str, x, y, z) -> float:
"""Eval wyrażenia użytkownika (np. w schedulerze) na (x,y,z)."""
val = safe_eval(expr, {"x": x, "y": y, "z": z})
return float(val)
# Spójna warstwa Qt z pyqtgraph (nie mieszamy bezpośrednio PyQt5/PySide6)
_pyqtgraph_available = False
_pyqtgraph_unavailable_reason = ""
try:
import pyqtgraph as pg
from pyqtgraph.Qt import QtCore, QtWidgets
_pyqtgraph_available = True
except Exception as e:
DBGEX(f"pyqtgraph import {e}")
_pyqtgraph_unavailable_reason = str(e)
try:
import tkinter as tk
from tkinter import ttk, messagebox
except Exception:
raise SystemExit("Tkinter is required to run this app.")
# Optional plotting support
try:
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
from matplotlib.figure import Figure
HAS_MPL = True
import matplotlib as mpl
mpl.rcParams["path.simplify"] = True
mpl.rcParams["agg.path.chunksize"] = 10000
PLOT_SCALE = -200
except Exception:
DBGEX("matplotlib import")
HAS_MPL = False
# --- Daemon thread spawner ----------------------------------------------------
def spawn_daemon(name: str, target, *args, **kwargs):
"""
Start background thread as daemon=True. Returns the Thread object.
"""
t = threading.Thread(target=target, args=args, kwargs=kwargs, daemon=True, name=name)
t.start()
return t
# =====================
# Global configuration
# =====================
AVERAGE_WINDOW_N: int = 60 # default for moving average window (cycles)
SERVER_HOST: str = "localhost"
SERVER_PORT: int = 8785
REFRESH_INTERVAL_S: int = 1
REQUEST_TIMEOUT_S: float = 5.0
USER_AGENT: str = "ControlBoardMonitor/1.16 (+tkinter)"
# Fallback defaults (extracted from your HTML)
DEFAULT_VARS: List[str] = ['ALARMS_ACTIVE', 'AMBIENT_TEMPERATURE', 'CHEM_BORON_DOSAGE_ACTUAL', 'CHEM_BORON_DOSAGE_ORDERED', 'CHEM_BORON_FILTER_ACTUAL', 'CHEM_BORON_FILTER_ORDERED', 'CHEM_BORON_PPM', 'CHEM_TRUCK_CONNECTED', 'CHEM_TRUCK_IN_ZONE', 'CHEMICAL_CLEANING_PUMP_DRY_STATUS', 'CHEMICAL_CLEANING_PUMP_OVERLOAD_STATUS', 'CHEMICAL_CLEANING_PUMP_STATUS', 'CHEMICAL_DOSING_PUMP_DRY_STATUS', 'CHEMICAL_DOSING_PUMP_OVERLOAD_STATUS', 'CHEMICAL_DOSING_PUMP_STATUS', 'CHEMICAL_FILTER_PUMP_DRY_STATUS', 'CHEMICAL_FILTER_PUMP_OVERLOAD_STATUS', 'CHEMICAL_FILTER_PUMP_STATUS', 'CONDENSER_CIRCULATION_PUMP_ACTIVE', 'CONDENSER_CIRCULATION_PUMP_ORDERED_SPEED', 'CONDENSER_CIRCULATION_PUMP_OVERLOAD_STATUS', 'CONDENSER_CIRCULATION_PUMP_SPEED', 'CONDENSER_CIRCULATION_PUMP_SWITCH', 'CONDENSER_CONDENSATE_FLOW_RATE', 'CONDENSER_COOLANT_EVAPORATED', 'CONDENSER_EXTRACTION_FLOW_RATE', 'CONDENSER_PRESSURE', 'CONDENSER_TEMPERATURE', 'CONDENSER_VACUUM', 'CONDENSER_VACUUM_PUMP_ACTIVE', 'CONDENSER_VACUUM_PUMP_MODE', 'CONDENSER_VACUUM_PUMP_POWER', 'CONDENSER_VACUUM_RELIEF_VALVE_OPENING', 'CONDENSER_VAPOR_VOLUME', 'CONDENSER_VOLUME', 'COOLANT_CORE_CIRCULATION_PUMP_0_CAPACITY', 'COOLANT_CORE_CIRCULATION_PUMP_0_DRY_STATUS', 'COOLANT_CORE_CIRCULATION_PUMP_0_ORDERED_SPEED', 'COOLANT_CORE_CIRCULATION_PUMP_0_OVERLOAD_STATUS', 'COOLANT_CORE_CIRCULATION_PUMP_0_SPEED', 'COOLANT_CORE_CIRCULATION_PUMP_0_STATUS', 'COOLANT_CORE_CIRCULATION_PUMP_1_CAPACITY', 'COOLANT_CORE_CIRCULATION_PUMP_1_DRY_STATUS', 'COOLANT_CORE_CIRCULATION_PUMP_1_ORDERED_SPEED', 'COOLANT_CORE_CIRCULATION_PUMP_1_OVERLOAD_STATUS', 'COOLANT_CORE_CIRCULATION_PUMP_1_SPEED', 'COOLANT_CORE_CIRCULATION_PUMP_1_STATUS', 'COOLANT_CORE_CIRCULATION_PUMP_2_CAPACITY', 'COOLANT_CORE_CIRCULATION_PUMP_2_DRY_STATUS', 'COOLANT_CORE_CIRCULATION_PUMP_2_ORDERED_SPEED', 'COOLANT_CORE_CIRCULATION_PUMP_2_OVERLOAD_STATUS', 'COOLANT_CORE_CIRCULATION_PUMP_2_SPEED', 'COOLANT_CORE_CIRCULATION_PUMP_2_STATUS', 'COOLANT_CORE_FLOW_IN', 'COOLANT_CORE_FLOW_ORDERED_SPEED', 'COOLANT_CORE_FLOW_OUT', 'COOLANT_CORE_FLOW_REACHED_SPEED', 'COOLANT_CORE_FLOW_SPEED', 'COOLANT_CORE_MAX_PRESSURE', 'COOLANT_CORE_PRESSURE', 'COOLANT_CORE_PRIMARY_LOOP_LEVEL', 'COOLANT_CORE_QUANTITY_CIRCULATION_PUMPS_PRESENT', 'COOLANT_CORE_QUANTITY_FREIGHT_PUMPS_PRESENT', 'COOLANT_CORE_QUANTITY_IN_VESSEL', 'COOLANT_CORE_STATE', 'COOLANT_CORE_VESSEL_TEMPERATURE', 'COOLANT_SEC_0_LIQUID_VOLUME', 'COOLANT_SEC_0_PRESSURE', 'COOLANT_SEC_0_TEMPERATURE', 'COOLANT_SEC_0_VOLUME', 'COOLANT_SEC_1_LIQUID_VOLUME', 'COOLANT_SEC_1_PRESSURE', 'COOLANT_SEC_1_TEMPERATURE', 'COOLANT_SEC_1_VOLUME', 'COOLANT_SEC_2_LIQUID_VOLUME', 'COOLANT_SEC_2_PRESSURE', 'COOLANT_SEC_2_TEMPERATURE', 'COOLANT_SEC_2_VOLUME', 'COOLANT_SEC_CIRCULATION_PUMP_0_CAPACITY', 'COOLANT_SEC_CIRCULATION_PUMP_0_DRY_STATUS', 'COOLANT_SEC_CIRCULATION_PUMP_0_ORDERED_SPEED', 'COOLANT_SEC_CIRCULATION_PUMP_0_OVERLOAD_STATUS', 'COOLANT_SEC_CIRCULATION_PUMP_0_SPEED', 'COOLANT_SEC_CIRCULATION_PUMP_0_STATUS', 'COOLANT_SEC_CIRCULATION_PUMP_1_CAPACITY', 'COOLANT_SEC_CIRCULATION_PUMP_1_DRY_STATUS', 'COOLANT_SEC_CIRCULATION_PUMP_1_ORDERED_SPEED', 'COOLANT_SEC_CIRCULATION_PUMP_1_OVERLOAD_STATUS', 'COOLANT_SEC_CIRCULATION_PUMP_1_SPEED', 'COOLANT_SEC_CIRCULATION_PUMP_1_STATUS', 'COOLANT_SEC_CIRCULATION_PUMP_2_CAPACITY', 'COOLANT_SEC_CIRCULATION_PUMP_2_DRY_STATUS', 'COOLANT_SEC_CIRCULATION_PUMP_2_ORDERED_SPEED', 'COOLANT_SEC_CIRCULATION_PUMP_2_OVERLOAD_STATUS', 'COOLANT_SEC_CIRCULATION_PUMP_2_SPEED', 'COOLANT_SEC_CIRCULATION_PUMP_2_STATUS', 'CORE_BAY_1_HATCH_OPEN', 'CORE_BAY_1_STATE', 'CORE_BAY_2_HATCH_OPEN', 'CORE_BAY_2_STATE', 'CORE_BAY_3_HATCH_OPEN', 'CORE_BAY_3_STATE', 'CORE_BAY_4_HATCH_OPEN', 'CORE_BAY_4_STATE', 'CORE_BAY_5_HATCH_OPEN', 'CORE_BAY_5_STATE', 'CORE_BAY_6_HATCH_OPEN', 'CORE_BAY_6_STATE', 'CORE_BAY_7_HATCH_OPEN', 'CORE_BAY_7_STATE', 'CORE_BAY_8_HATCH_OPEN', 'CORE_BAY_8_STATE', 'CORE_BAY_9_HATCH_OPEN', 'CORE_BAY_9_STATE', 'CORE_CRITICAL_MASS_REACHED', 'CORE_CRITICAL_MASS_REACHED_COUNTER', 'CORE_EXTERNAL_COOLANT_RESERVOIR_VOLUME', 'CORE_FACTOR', 'CORE_FACTOR_CHANGE', 'CORE_FUEL_1_FISSIONABLE', 'CORE_FUEL_1_POWER_FACTOR', 'CORE_FUEL_1_TEMPERATURE', 'CORE_FUEL_2_FISSIONABLE', 'CORE_FUEL_2_POWER_FACTOR', 'CORE_FUEL_2_TEMPERATURE', 'CORE_FUEL_3_FISSIONABLE', 'CORE_FUEL_3_POWER_FACTOR', 'CORE_FUEL_3_TEMPERATURE', 'CORE_FUEL_4_FISSIONABLE', 'CORE_FUEL_4_POWER_FACTOR', 'CORE_FUEL_4_TEMPERATURE', 'CORE_FUEL_5_FISSIONABLE', 'CORE_FUEL_5_POWER_FACTOR', 'CORE_FUEL_5_TEMPERATURE', 'CORE_FUEL_6_FISSIONABLE', 'CORE_FUEL_6_POWER_FACTOR', 'CORE_FUEL_6_TEMPERATURE', 'CORE_FUEL_7_FISSIONABLE', 'CORE_FUEL_7_POWER_FACTOR', 'CORE_FUEL_7_TEMPERATURE', 'CORE_FUEL_8_FISSIONABLE', 'CORE_FUEL_8_POWER_FACTOR', 'CORE_FUEL_8_TEMPERATURE', 'CORE_FUEL_9_FISSIONABLE', 'CORE_FUEL_9_POWER_FACTOR', 'CORE_FUEL_9_TEMPERATURE', 'CORE_FUEL_AVG_FISSIONABLE', 'CORE_FUEL_AVG_POWER_FACTOR', 'CORE_FUEL_AVG_TEMPERATURE', 'CORE_HIGH_STEAM_PRESENT', 'CORE_IMMINENT_FUSION', 'CORE_INTEGRITY', 'CORE_IODINE_CUMULATIVE', 'CORE_IODINE_GENERATION', 'CORE_OPERATION_MODE', 'CORE_POOL_COOLANT_TANK_VOLUME', 'CORE_POOL_PUMP', 'CORE_PRESSURE', 'CORE_PRESSURE_MAX', 'CORE_PRESSURE_OPERATIVE', 'CORE_PRIMARY_CIRCUIT_COOLING_TANK_VOLUME', 'CORE_READY_FOR_START', 'CORE_STATE', 'CORE_STATE_CRITICALITY', 'CORE_STEAM_PRESENT', 'CORE_TEMP', 'CORE_TEMP_MAX', 'CORE_TEMP_MIN', 'CORE_TEMP_OPERATIVE', 'CORE_TEMP_RESIDUAL', 'CORE_WEAR', 'CORE_XENON_CUMULATIVE', 'CORE_XENON_GENERATION', 'EMERGENCY_BATTERIES_MODE', 'EMERGENCY_BATTERIES_POWER_OUTPUT_KW', 'EMERGENCY_GENERATOR_1_FUEL', 'EMERGENCY_GENERATOR_1_MAINTENANCE_NEEDED', 'EMERGENCY_GENERATOR_1_MODE', 'EMERGENCY_GENERATOR_1_PRESSURIZER', 'EMERGENCY_GENERATOR_1_STATUS', 'EMERGENCY_GENERATOR_2_FUEL', 'EMERGENCY_GENERATOR_2_MAINTENANCE_NEEDED', 'EMERGENCY_GENERATOR_2_MODE', 'EMERGENCY_GENERATOR_2_PRESSURIZER', 'EMERGENCY_GENERATOR_2_STATUS', 'EMERGENCY_GENERATOR_POWER_OUTPUT_KW', 'FREIGHT_PUMP_CONDENSER_ACTIVE', 'FREIGHT_PUMP_CONDENSER_SWITCH', 'FREIGHT_PUMP_EXTERNAL_ACTIVE', 'FREIGHT_PUMP_EXTERNAL_SWITCH', 'FREIGHT_PUMP_FEEDWATER_ACTIVE', 'FREIGHT_PUMP_FEEDWATER_SWITCH', 'FREIGHT_PUMP_INTERNAL_ACTIVE', 'FREIGHT_PUMP_INTERNAL_SWITCH', 'FUN_IS_ENABLED', 'GAME_DIFFICULTY', 'GAME_SIM_SPEED', 'GAME_VERSION', 'GENERATOR_0_A', 'GENERATOR_0_BREAKER', 'GENERATOR_0_HERTZ', 'GENERATOR_0_KW', 'GENERATOR_0_V', 'GENERATOR_1_A', 'GENERATOR_1_BREAKER', 'GENERATOR_1_HERTZ', 'GENERATOR_1_KW', 'GENERATOR_1_V', 'GENERATOR_2_A', 'GENERATOR_2_BREAKER', 'GENERATOR_2_HERTZ', 'GENERATOR_2_KW', 'GENERATOR_2_V', 'INSTALLED_LOOPS_JSON', 'INVENTORY_HTML', 'MAINTENANCE_REPORT_HTML', 'MSCV_0_OPENING_ACTUAL', 'MSCV_1_OPENING_ACTUAL', 'MSCV_2_OPENING_ACTUAL', 'POWER_DEMAND_MW', 'POWER_FROM_EXTERNAL_KW', 'POWER_FROM_TURBINE_KW', 'POWER_MAX_THEORETICAL_FINAL_PLANT_OUTPUT_MW', 'POWER_MAX_THEORETICAL_PLANT_OUTPUT_MW', 'RES_ABSORPTION_CAPACITY_MW', 'RES_DIVERT_SURPLUS_FROM_MW', 'RES_EFFECTIVELY_DERIVED_ENERGY_MW', 'RESISTOR_BANK_01_SWITCH', 'RESISTOR_BANK_02_SWITCH', 'RESISTOR_BANK_03_SWITCH', 'RESISTOR_BANK_04_SWITCH', 'RESISTOR_BANKS_JSON', 'RESISTOR_BANKS_MAIN_SWITCH', 'ROD_BANK_POS_0_ACTUAL', 'ROD_BANK_POS_0_ORDERED', 'ROD_BANK_POS_1_ACTUAL', 'ROD_BANK_POS_1_ORDERED', 'ROD_BANK_POS_2_ACTUAL', 'ROD_BANK_POS_2_ORDERED', 'ROD_BANK_POS_3_ACTUAL', 'ROD_BANK_POS_3_ORDERED', 'ROD_BANK_POS_4_ACTUAL', 'ROD_BANK_POS_4_ORDERED', 'ROD_BANK_POS_5_ACTUAL', 'ROD_BANK_POS_5_ORDERED', 'ROD_BANK_POS_6_ACTUAL', 'ROD_BANK_POS_6_ORDERED', 'ROD_BANK_POS_7_ACTUAL', 'ROD_BANK_POS_7_ORDERED', 'ROD_BANK_POS_8_ACTUAL', 'ROD_BANK_POS_8_ORDERED', 'RODS_ALIGNED', 'RODS_DEFORMED', 'RODS_MAX_TEMPERATURE', 'RODS_MOVEMENT_SPEED', 'RODS_MOVEMENT_SPEED_DECREASED_HIGH_TEMPERATURE', 'RODS_POS_ACTUAL', 'RODS_POS_ORDERED', 'RODS_POS_REACHED', 'RODS_QUANTITY', 'RODS_STATUS', 'RODS_TEMPERATURE', 'STEAM_EJECTOR_CONDENSER_RETURN_VALVE_ACTUAL', 'STEAM_EJECTOR_CONDENSER_RETURN_VALVE_ORDERED', 'STEAM_EJECTOR_MOTIVE', 'STEAM_EJECTOR_OPERATIONAL_MOTIVE_VALVE_ACTUAL', 'STEAM_EJECTOR_OPERATIONAL_MOTIVE_VALVE_ORDERED', 'STEAM_EJECTOR_STARTUP_MOTIVE_VALVE_ACTUAL', 'STEAM_EJECTOR_STARTUP_MOTIVE_VALVE_ORDERED', 'STEAM_GEN_0_BOILING_POINT', 'STEAM_GEN_0_EVAPORATED', 'STEAM_GEN_0_INLET', 'STEAM_GEN_0_OUTLET', 'STEAM_GEN_0_RETURN_FLOW_PLUS_CONDENSED', 'STEAM_GEN_0_STATUS', 'STEAM_GEN_0_VENT_SWITCH', 'STEAM_GEN_1_BOILING_POINT', 'STEAM_GEN_1_EVAPORATED', 'STEAM_GEN_1_INLET', 'STEAM_GEN_1_OUTLET', 'STEAM_GEN_1_RETURN_FLOW_PLUS_CONDENSED', 'STEAM_GEN_1_STATUS', 'STEAM_GEN_1_VENT_SWITCH', 'STEAM_GEN_2_BOILING_POINT', 'STEAM_GEN_2_EVAPORATED', 'STEAM_GEN_2_INLET', 'STEAM_GEN_2_OUTLET', 'STEAM_GEN_2_RETURN_FLOW_PLUS_CONDENSED', 'STEAM_GEN_2_STATUS', 'STEAM_GEN_2_VENT_SWITCH', 'STEAM_TURBINE_0_BYPASS_ACTUAL', 'STEAM_TURBINE_0_INSTALLED', 'STEAM_TURBINE_0_PRESSURE', 'STEAM_TURBINE_0_RPM', 'STEAM_TURBINE_0_TEMPERATURE', 'STEAM_TURBINE_0_TORQUE', 'STEAM_TURBINE_1_BYPASS_ACTUAL', 'STEAM_TURBINE_1_INSTALLED', 'STEAM_TURBINE_1_PRESSURE', 'STEAM_TURBINE_1_RPM', 'STEAM_TURBINE_1_TEMPERATURE', 'STEAM_TURBINE_1_TORQUE', 'STEAM_TURBINE_2_BYPASS_ACTUAL', 'STEAM_TURBINE_2_INSTALLED', 'STEAM_TURBINE_2_PRESSURE', 'STEAM_TURBINE_2_RPM', 'STEAM_TURBINE_2_TEMPERATURE', 'STEAM_TURBINE_2_TORQUE', 'TIME', 'TIME_DAY', 'TIME_STAMP', 'VACUUM_RETENTION_TANK_PRESSURE', 'VACUUM_RETENTION_TANK_VOLUME', 'VALVE_M01_OPEN', 'VALVE_M02_OPEN', 'VALVE_M03_OPEN', 'VALVE_PANEL_JSON', 'WEATHER_FORECAST_JSON', 'WEBSERVER_BATCH_GET', 'WEBSERVER_LIST_VARIABLES', 'WEBSERVER_LIST_VARIABLES_JSON', 'WEBSERVER_VIEW_VARIABLES']
DEFAULT_FUNCTIONS: List[str] = ['CHEM_BORON_DOSAGE_ORDERED_RATE', 'CHEM_BORON_FILTER_ORDERED_SPEED', 'CONDENSER_CIRCULATION_PUMP_ORDERED_SPEED', 'CONDENSER_CIRCULATION_PUMP_SWITCH', 'CONDENSER_VACUUM_PUMP_MODE', 'CONDENSER_VACUUM_PUMP_START_STOP', 'COOLANT_CORE_CIRCULATION_PUMP_0_ORDERED_SPEED', 'COOLANT_CORE_CIRCULATION_PUMP_1_ORDERED_SPEED', 'COOLANT_CORE_CIRCULATION_PUMP_2_ORDERED_SPEED', 'COOLANT_SEC_CIRCULATION_PUMP_0_ORDERED_SPEED', 'COOLANT_SEC_CIRCULATION_PUMP_1_ORDERED_SPEED', 'COOLANT_SEC_CIRCULATION_PUMP_2_ORDERED_SPEED', 'CORE_BAY_1_FUEL_LOADING', 'CORE_BAY_1_HATCH', 'CORE_BAY_2_FUEL_LOADING', 'CORE_BAY_2_HATCH', 'CORE_BAY_3_FUEL_LOADING', 'CORE_BAY_3_HATCH', 'CORE_BAY_4_FUEL_LOADING', 'CORE_BAY_4_HATCH', 'CORE_BAY_5_FUEL_LOADING', 'CORE_BAY_5_HATCH', 'CORE_BAY_6_FUEL_LOADING', 'CORE_BAY_6_HATCH', 'CORE_BAY_7_FUEL_LOADING', 'CORE_BAY_7_HATCH', 'CORE_BAY_8_FUEL_LOADING', 'CORE_BAY_8_HATCH', 'CORE_BAY_9_FUEL_LOADING', 'CORE_BAY_9_HATCH', 'CORE_EMERGENCY_STOP', 'CORE_END_EMERGENCY_STOP', 'CORE_OPERATION_MODE', 'CORE_POOL_PUMP', 'CORE_SCRAM_BUTTON', 'EMERGENCY_BATTERIES_MODE', 'EMERGENCY_GENERATOR_1_MODE', 'EMERGENCY_GENERATOR_1_START_STOP', 'EMERGENCY_GENERATOR_2_MODE', 'EMERGENCY_GENERATOR_2_START_STOP', 'FREIGHT_PUMP_CONDENSER_SWITCH', 'FREIGHT_PUMP_EXTERNAL_SWITCH', 'FREIGHT_PUMP_FEEDWATER_SWITCH', 'FREIGHT_PUMP_INTERNAL_SWITCH', 'FUN_AO_SABOTAGE_ONCE', 'FUN_AO_SABOTAGE_TIME', 'FUN_BANK_ROBBERY', 'FUN_BREAKER_TRIP', 'FUN_DECREASE_INTEGRITY', 'FUN_FIRE_DRILL', 'FUN_IODINE_SPILL', 'FUN_OIL_SPILL', 'FUN_PUMP_JAM', 'FUN_REQUEST_ENABLE', 'FUN_SHOW_MESSAGE', 'FUN_TOGGLE_RANDOM_SWITCH', 'FUN_TRIGGER_AUDIT', 'FUN_WEATHER_CONTROL', 'FUN_XENON_SPILL', 'MSCV_0_OPENING_ORDERED', 'MSCV_1_OPENING_ORDERED', 'MSCV_2_OPENING_ORDERED', 'RESET_AO', 'RESISTOR_BANK_01_SWITCH', 'RESISTOR_BANK_02_SWITCH', 'RESISTOR_BANK_03_SWITCH', 'RESISTOR_BANK_04_SWITCH', 'RESISTOR_BANKS_MAIN_SWITCH', 'ROD_BANK_POS_0_ORDERED', 'ROD_BANK_POS_1_ORDERED', 'ROD_BANK_POS_2_ORDERED', 'ROD_BANK_POS_3_ORDERED', 'ROD_BANK_POS_4_ORDERED', 'ROD_BANK_POS_5_ORDERED', 'ROD_BANK_POS_6_ORDERED', 'ROD_BANK_POS_7_ORDERED', 'ROD_BANK_POS_8_ORDERED', 'RODS_ALL_POS_ORDERED', 'STEAM_EJECTOR_CONDENSER_RETURN_VALVE', 'STEAM_EJECTOR_OPERATIONAL_MOTIVE_VALVE', 'STEAM_EJECTOR_STARTUP_MOTIVE_VALVE', 'STEAM_GEN_0_VENT_SWITCH', 'STEAM_GEN_1_VENT_SWITCH', 'STEAM_GEN_2_VENT_SWITCH', 'STEAM_TURBINE_0_BYPASS_ORDERED', 'STEAM_TURBINE_1_BYPASS_ORDERED', 'STEAM_TURBINE_2_BYPASS_ORDERED', 'STEAM_TURBINE_TRIP', 'VALVE_CLOSE', 'VALVE_OFF', 'VALVE_OPEN']
# One global lock to serialize every HTTP call
_HTTP_LOCK = threading.Lock()
# =====================
# Helpers
# =====================
def build_base_url(host: str, port: int) -> str:
return f"http://{host}:{port}/"
def _request(req: urllib.request.Request) -> Tuple[int, str, Dict[str, str]]:
DBGL(f"[HTTP] {req}")
with _HTTP_LOCK:
try:
with urllib.request.urlopen(req, timeout=REQUEST_TIMEOUT_S) as resp:
status = resp.getcode()
body_bytes = resp.read()
try:
body = body_bytes.decode("utf-8", errors="replace")
except Exception:
DBGEX("_request decode utf-8")
body = body_bytes.decode("latin-1", errors="replace")
headers = {k.lower(): v for k, v in resp.getheaders()}
return status, body, headers
except urllib.error.HTTPError as e:
try:
body = e.read().decode("utf-8", errors="replace")
except Exception:
DBGEX("_request HTTPError decode utf-8")
body = str(e)
return e.code, body, dict(e.headers or {})
except Exception as e:
DBGEX("_request")
return 0, str(e), {}
def http_get(base_url: str, params: Dict[str, str]) -> Tuple[int, str, Dict[str, str]]:
url = base_url + "?" + urllib.parse.urlencode(params)
req = urllib.request.Request(url, headers={"User-Agent": USER_AGENT, "Connection": "close"})
DBGL(f"[HTTP] GET {url}")
return _request(req)
def http_post_query(base_url: str, params: Dict[str, str]) -> Tuple[int, str, Dict[str, str]]:
# EXACT behavior requested: POST with query string, no body.
url = base_url + "?" + urllib.parse.urlencode(params)
req = urllib.request.Request(url, headers={"User-Agent": USER_AGENT, "Connection": "close"}, method="POST")
DBGL(f"[HTTP] POST {url}")
return _request(req)
def http_get_root(base_url: str) -> Tuple[int, str, Dict[str, str]]:
req = urllib.request.Request(base_url, headers={"User-Agent": USER_AGENT, "Connection": "close"})
DBGL(f"[HTTP] GET ROOT {base_url}")
return _request(req)
def coerce_preview(value: str, maxlen: int = 80) -> str:
v = value.strip().replace("\r", " ").replace("\n", " ")
return v if len(v) <= maxlen else (v[:maxlen - 1] + "…")
def parse_function_names_from_html_index(html_text: str) -> List[str]:
start = html_text.find("==== POST ====")
if start == -1:
return []
post_html = html_text[start:]
names = re.findall(r"<b>([A-Z0-9_]+)</b>", post_html)
seen = set(); uniq: List[str] = []
for n in names:
if n not in seen:
seen.add(n); uniq.append(n)
return uniq
def parse_variable_names_from_html_index(html_text: str) -> List[str]:
tokens: List[str] = []
for m in re.finditer(r'href\s*=\s*["\']([^"\']+)["\']', html_text, flags=re.I):
href = m.group(1)
parsed = urllib.parse.urlparse(href)
qs = urllib.parse.parse_qs(parsed.query)
for v in qs.get("variable", []) + qs.get("Variable", []):
tokens.append(v)
for m in re.finditer(r'(?:Variable|variable)\s*=\s*["\']?([A-Za-z0-9_.:-]+)', html_text, flags=re.I):
tokens.append(m.group(1))
seen = set(); uniq: List[str] = []
for v in tokens:
if v and v.upper() not in {"VARNAME", "VARIABLE", "NAME"} and v not in seen:
seen.add(v); uniq.append(v)
return uniq
# ---- Parse WEBSERVER_LIST_VARIABLES_JSON ----
def parse_weblist_names(body: str) -> Tuple[List[str], List[str]]:
"""Return (get_list, post_list). Keep discovered case for function names."""
try:
data = json.loads(body)
except Exception:
DBGEX("parse_weblist_names json.loads")
return [], []
get_names: List[str] = []
post_names: List[str] = []
if isinstance(data, dict):
for k, v in data.items():
key = str(k).strip().rstrip(":").upper()
if key in ("GET", "POST"):
names = extract_names_preserve_case(v)
if key == "GET":
get_names.extend(names)
else:
post_names.extend(names)
elif isinstance(data, list):
get_names.extend(extract_names_preserve_case(data))
def dedup(seq):
seen=set(); out=[]
for s in seq:
if s not in seen:
seen.add(s); out.append(s)
return out
return dedup(get_names), dedup(post_names)
def extract_names_preserve_case(value_obj) -> List[str]:
out: List[str] = []
def add(n):
if isinstance(n, str) and n and n not in out:
out.append(n)
if isinstance(value_obj, list):
for it in value_obj:
if isinstance(it, str):
add(it)
elif isinstance(it, dict):
for k in ("name","variable","var","id","func","function"):
if k in it and isinstance(it[k], str):
add(it[k])
for k in list(it.keys()):
if isinstance(k, str) and k.upper() == k:
add(k)
elif isinstance(value_obj, dict):
for k in value_obj.keys():
if isinstance(k, str):
add(k)
elif isinstance(value_obj, str):
for m in re.findall(r"[A-Za-z0-9_]+", value_obj):
add(m)
return out
# ---- Parse WEBSERVER_BATCH_GET ----
def parse_batch_values(body: str) -> Dict[str, str]:
try:
data = json.loads(body)
except Exception:
DBGEX("parse_batch_values json.loads")
return {}
# Jeśli serwer owinął odpowiedź w {"values": {...}}, wyciągamy środek:
if isinstance(data, dict) and isinstance(data.get("values"), dict):
data = data["values"]
values: Dict[str, str] = {}
if isinstance(data, dict):
for k, v in data.items():
if not isinstance(k, str):
k = str(k)
try:
values[k] = v if isinstance(v, str) else json.dumps(v)
except Exception:
DBGEX("parse_batch_values json.dumps")
values[k] = str(v)
return values
def detect_batch_payload_type(body: str) -> str:
try:
data = json.loads(body)
if isinstance(data, dict) and isinstance(data.get("values"), dict):
return "enveloped(values+errors)"
if isinstance(data, dict):
return "flat"
except Exception:
DBGEX("detect_batch_payload_type json.loads")
pass
return "unknown"
def eval_threshold_expr(expr: str,
stats_x: Optional[dict],
stats_y: Optional[dict],
stats_z: Optional[dict]) -> Optional[float]:
"""
Eval progu z dostępem do: x, x_avg, dx, dx_avg, y, y_avg, dy, dy_avg, z, z_avg, dz, dz_avg.
Zwraca float albo None przy błędzie.
"""
if not expr:
return None
env: dict = {}
def push(prefix: str, d: Optional[dict]):
if not d:
return
env[prefix] = d.get("x")
env[f"{prefix}_avg"] = d.get("x_avg")
env[f"d{prefix}"] = d.get("dx")
env[f"d{prefix}_avg"] = d.get("dx_avg")
push("x", stats_x)
push("y", stats_y)
push("z", stats_z)
try:
# jeżeli masz już safe_eval w kodzie użyj go; inaczej zwykły eval bez builtins
val = safe_eval(expr, env) if 'safe_eval' in globals() else eval(expr, {"__builtins__": {}}, env)
return float(val)
except Exception:
DBGEX("eval_threshold_expr")
return None
# =====================
# Data model
# =====================
@dataclass
class Thresholds:
dead_low: Optional[float] = None
low: Optional[float] = None
high: Optional[float] = None
extreme_high: Optional[float] = None
# alarms (defaults: on for dead_low & extreme_high as requested)
alarm_dead_low: bool = True
alarm_low: bool = False
alarm_high: bool = False
alarm_extreme_high: bool = True
# function actions
action_dead_low: Optional[str] = None
value_dead_low: str = "1"
action_low: Optional[str] = None
value_low: str = "1"
action_high: Optional[str] = None
value_high: str = "1"
action_extreme_high: Optional[str] = None
value_extreme_high: str = "1"
# interval while-in-state (0 = once on enter)
action_dead_low_interval: float = 1.0
action_low_interval: float = 1.0
action_high_interval: float = 1.0
action_extreme_high_interval: float = 1.0
action_operating: Optional[str] = None
value_operating: str = "1"
action_operating_interval: float = 1.0
# expression actions
expr_dead_low: Optional[str] = None
expr_low: Optional[str] = None
expr_high: Optional[str] = None
expr_extreme_high: Optional[str] = None
# expression target function (per state)
expr_target_dead_low: Optional[str] = None
expr_target_low: Optional[str] = None
expr_target_high: Optional[str] = None
expr_target_extreme_high: Optional[str] = None
expr_operating: Optional[str] = None
expr_target_operating: Optional[str] = None
expr_operating_interval: float = 1.0
# sources for y and z
y_source: Optional[str] = None
z_source: Optional[str] = None
expr_x_source_dead_low: str = "raw" # "raw" | "x_avg" | "dx" | "dx_avg"
expr_x_source_low: str = "raw"
expr_x_source_operating: str = "raw"
expr_x_source_high: str = "raw"
expr_x_source_extreme_high: str = "raw"
# Optional expressions for dynamic thresholds (override numeric constants if provided)
expr_thr_dead_low: Optional[str] = None
expr_thr_low: Optional[str] = None
expr_thr_high: Optional[str] = None
expr_thr_extreme_high: Optional[str] = None
@dataclass
class VarInfo:
key: str # canonical lower-case key
display_name: str # original case as chosen
last_value: str = ""
last_updated: float = 0.0
last_status: int = 0
error: Optional[str] = None
thresholds: Thresholds = field(default_factory=Thresholds)
last_state: str = "UNKNOWN"
# analytics
delta_last: Optional[float] = None
history: Deque[float] = field(default_factory=lambda: deque(maxlen=3600))
history_delta: Deque[float] = field(default_factory=lambda: deque(maxlen=3600))
hist_ver: int = 0 # rośnie przy każdym append do history (optymalizacja pod ploty)
@dataclass
class ActionTask:
name: str
value: str
interval_s: float
# dataclass ActionTask (dodaj pole)
tag: Optional[str] = None
enabled: bool = True
last_run: float = 0.0
next_run: float = 0.0
task_id: int = 0
expr: Optional[str] = None
x_src: Optional[str] = None
y_src: Optional[str] = None
z_src: Optional[str] = None
x_mode: str = "raw" # "raw" | "x_avg" | "dx" | "dx_avg"
# =====================
# Scheduler thread
# =====================
class ActionScheduler(threading.Thread):
def __init__(self, get_base_url_cb, get_value_cb):
super().__init__(daemon=True)
self.get_base_url_cb = get_base_url_cb
self.get_value_cb = get_value_cb
self.tasks: Dict[int, ActionTask] = {}
self._lock = threading.Lock()
self._stop = threading.Event()
self._counter = 1
def add_task(self, task: ActionTask) -> int:
with self._lock:
tid = self._counter
self._counter += 1
task.task_id = tid
now = time.time()
task.next_run = now if task.interval_s == 0 else now + task.interval_s
self.tasks[tid] = task
return tid
def remove_task(self, task_id: int) -> None:
with self._lock:
self.tasks.pop(task_id, None)
def remove_tasks_by_tag(self, tag: str) -> None:
with self._lock:
to_del = [tid for tid, t in self.tasks.items() if getattr(t, "tag", None) == tag]
for tid in to_del:
self.tasks.pop(tid, None)
def list_tasks(self) -> List[ActionTask]:
with self._lock:
return list(self.tasks.values())
def set_enabled(self, task_id: int, enabled: bool) -> None:
with self._lock:
t = self.tasks.get(task_id)
if t:
t.enabled = enabled
if enabled and t.interval_s > 0:
t.next_run = time.time() + t.interval_s
def run_task_once(self, task: "ActionTask") -> Tuple[int, str, Dict[str, str]]:
# Compute value if expression is provided
value_to_send = task.value
if getattr(task, "expr", None):
# fetch x/y/z using callback; None -> 0.0 for x
def gv(n):
try:
return self.get_value_cb(n) if n else None
except Exception:
DBGEX("Scheduler.run_task_once->get_value_cb")
return None
# stara wersja:
# x = gv(task.x_src); y = gv(task.y_src); z = gv(task.z_src)
def pick(stats: Optional[dict], mode: str) -> Optional[float]:
if not stats:
return None
if mode == "x_avg":
return stats.get("x_avg")
if mode == "dx":
return stats.get("dx")
if mode == "dx_avg":
return stats.get("dx_avg")
return stats.get("x")
xs = self.get_value_cb(task.x_src)
ys = self.get_value_cb(task.y_src)
zs = self.get_value_cb(task.z_src)
x = pick(xs, getattr(task, "x_mode", "raw"))
y = pick(ys, getattr(task, "y_mode", "raw"))
z = pick(zs, getattr(task, "z_mode", "raw"))
if x is None:
x = 0.0
try:
computed = eval_user_expression(task.expr, x, y, z)
value_to_send = str(computed)
except Exception as e:
DBGEX(f"Scheduler.run_task_once->eval_user_expression: {e}")
# Return synthetic error without posting
return 0, f"Expression error: {e}", {}
base = self.get_base_url_cb()
params = {"variable": task.name, "value": value_to_send}
return http_post_query(base, params)
def run_once(self, name: str, value: str) -> Tuple[int, str, Dict[str, str]]:
base = self.get_base_url_cb()
params = {"variable": name, "value": value}
return http_post_query(base, params)
def stop(self) -> None:
self._stop.set()
def run(self) -> None:
# Pętla bez time.sleep; tylko _stop.wait(...)
while not self._stop.is_set():
now = time.time()
to_run: List[ActionTask] = []
with self._lock:
# wybierz zadania do uruchomienia
for t in list(self.tasks.values()):
if not t.enabled:
continue
if t.interval_s == 0:
# jednorazowe uruchom dokładnie raz (gdy nie było jeszcze run)
if t.last_run <= 0:
to_run.append(t)
else:
if now >= t.next_run:
to_run.append(t)
# wykonaj poza lockiem
for t in to_run:
try:
code, msg, _hdrs = self.run_task_once(t)
t.last_run = time.time()
if t.interval_s == 0:
# jednorazowe wyłącz po wykonaniu
t.enabled = False
else:
t.next_run = t.last_run + max(0.0, float(t.interval_s))
except Exception:
# nie blokujemy pętli schedulera na wyjątkach z pojedynczego taska
DBGEX("Scheduler.run->run_task_once")
# krótka, przerywalna drzemka
# (nie używamy time.sleep; dzięki temu zamknięcie jest natychmiastowe)
self._stop.wait(0.01)
# =====================
# Poller thread (uses BATCH_GET)
# =====================
class Poller(threading.Thread):
def __init__(
self,
host: str,
port: int,
variables_keys: List[str], # canonical lower-case keys
ui_queue: queue.Queue,
refresh_interval: float,
stop_event: threading.Event,
paused_event: threading.Event,
) -> None:
super().__init__(daemon=True)
self.host = host
self.port = port
self.variables_keys = variables_keys
self.ui_queue = ui_queue
self.refresh_interval = float(max(0.1, refresh_interval))
self.stop_event = stop_event
self.paused_event = paused_event
def run(self) -> None:
base_url = build_base_url(self.host, self.port)
DBGL("[Poller] start")
while not self.stop_event.is_set():
cycle_start = time.time()
try:
try:
self.ui_queue.put(("cycle_start", datetime.now().strftime("%H:%M:%S")))
# główny odczyt (BATCH lub fallback na pojedyncze)
status, body, _ = http_get(base_url, {"variable": "WEBSERVER_BATCH_GET"})
except Exception:
DBGEX("Poller.run->http_get(BATCH_GET)")
status, body, _ = None, None, None
if status == 200:
try:
values_map = parse_batch_values(body)
except Exception:
DBGEX("Poller.run->parse_batch_values")
values_map = None
if values_map:
lower_map = {k.lower(): v for k, v in values_map.items()}
self.ui_queue.put(("batch", lower_map))
for key in list(self.variables_keys):
if key in lower_map:
self.ui_queue.put(("update", key, str(lower_map[key]), 200))
else:
self.ui_queue.put(("error", key, 206, "Not in BATCH_GET payload"))
else:
for key in list(self.variables_keys):
try:
st, b, _h = http_get(base_url, {"variable": key})
if st == 200:
self.ui_queue.put(("update", key, b, st))
else:
self.ui_queue.put(("error", key, st, coerce_preview(b, 200)))
except Exception:
DBGEX(f"Poller.run->http_get({key})")
else:
for key in list(self.variables_keys):
st, b, _h = http_get(base_url, {"variable": key})
if st == 200:
self.ui_queue.put(("update", key, b, st))
else:
self.ui_queue.put(("error", key, st, coerce_preview(b, 200)))
except Exception:
# nigdy nie wywalamy wątku na zewnątrz
DBGEX("Poller.run(main loop)")
# OBSŁUGA PAUZY aktywnie czekamy, ale przerywalnie
while self.paused_event.is_set() and not self.stop_event.is_set():
# czekaj 50ms lub do przerwania
self.stop_event.wait(0.05)
# Odmierz pozostały czas do końca interwału też przerywalnie
cycle_dt = time.time() - cycle_start
remaining = float(self.refresh_interval) - cycle_dt
if remaining > 0:
waited = 0.0
# czekamy w małych porcjach, by reagować na pause/stop
while waited < remaining and not self.stop_event.is_set():
if self.paused_event.is_set():
break
chunk = min(0.1, remaining - waited)
self.stop_event.wait(chunk)
waited += chunk
DBGL("[Poller] stop")
# sygnalizacja zakończenia
try:
self.ui_queue.put(("stopped", ""))
except Exception:
DBGEX("Poller.run(stop)")
# =====================
# GUI
# =====================
class App(tk.Tk):
def __init__(self) -> None:
super().__init__()
self.title("Control Board Monitor — v1.16")
self.geometry("1280x860")
# Canonical registry: lower-case key -> VarInfo
self.vars: Dict[str, VarInfo] = {}
self.stop_event = threading.Event()
self.paused_event = threading.Event()
self.ui_queue: queue.Queue = queue.Queue()
self.poller: Optional[Poller] = None
self.variables_keys: List[str] = [] # list of lower-case keys in selection order
self.functions_list: List[str] = [] # preserve original casing
self._closing = False
self._stop_event = threading.Event()
self.scheduler = ActionScheduler(
lambda: build_base_url(self.host_var.get().strip(), int(self.port_var.get())),
self.get_stats_for
)
self.scheduler.start()
controls = ttk.Frame(self, padding=10)
controls.pack(side=tk.TOP, fill=tk.X)
self.host_var = tk.StringVar(value=SERVER_HOST)
self.port_var = tk.IntVar(value=SERVER_PORT)
self.refresh_var = tk.DoubleVar(value=REFRESH_INTERVAL_S)
self.avg_window_var = tk.IntVar(value=AVERAGE_WINDOW_N)
ttk.Label(controls, text="Host:").grid(row=0, column=0, sticky="w")
ttk.Entry(controls, textvariable=self.host_var, width=16).grid(row=0, column=1, padx=(0, 10))
ttk.Label(controls, text="Port:").grid(row=0, column=2, sticky="w")
ttk.Entry(controls, textvariable=self.port_var, width=8).grid(row=0, column=3, padx=(0, 10))
ttk.Label(controls, text="Refresh (s):").grid(row=0, column=4, sticky="w")
ttk.Entry(controls, textvariable=self.refresh_var, width=8).grid(row=0, column=5, padx=(0, 10))
ttk.Label(controls, text="Avg N:").grid(row=0, column=6, sticky="w")
ttk.Entry(controls, textvariable=self.avg_window_var, width=6).grid(row=0, column=7, padx=(0, 10))
self.status_lbl = ttk.Label(controls, text="Idle", foreground="#666")
self.status_lbl.grid(row=0, column=8, padx=(10, 0))
btns = ttk.Frame(controls)
btns.grid(row=0, column=9, padx=10, sticky="e")
ttk.Button(btns, text="Select Vars…", command=self.open_selector).grid(row=0, column=0, padx=4)
ttk.Button(btns, text="Reload (disc.)", command=self.reload_discovery).grid(row=0, column=1, padx=4)
self.start_btn = ttk.Button(btns, text="Start", command=self.start_polling)
self.start_btn.grid(row=0, column=2, padx=4)
self.pause_btn = ttk.Button(btns, text="Pause", command=self.toggle_pause, state="disabled")
self.pause_btn.grid(row=0, column=3, padx=4)
main = ttk.Panedwindow(self, orient=tk.VERTICAL)
main.pack(side=tk.TOP, fill=tk.BOTH, expand=True, padx=10, pady=(0,10))
search_frame = ttk.Frame(self, padding=(0, 6, 0, 6))
ttk.Label(search_frame, text="Filter:").pack(side=tk.LEFT)
self.filter_var = tk.StringVar(value="")
self.filter_var.trace_add("write", lambda *_: self.refresh_tree())
ttk.Entry(search_frame, textvariable=self.filter_var, width=50).pack(side=tk.LEFT, padx=8)
self.display_show_thresholds_var = tk.BooleanVar(value=True)
top_frame = ttk.Frame(main)
search_frame.pack(in_=top_frame, side=tk.TOP, fill=tk.X)
columns = ("value", "delta", "davg", "avg", "updated", "status")
self.tree = ttk.Treeview(top_frame, columns=columns, show="tree headings", height=20, selectmode="browse")
self.tree.pack(side=tk.LEFT, fill=tk.BOTH, expand=True)
vsb = ttk.Scrollbar(top_frame, orient="vertical", command=self.tree.yview)
vsb.pack(side=tk.RIGHT, fill=tk.Y)
self.tree.configure(yscrollcommand=vsb.set)
self._bind_mousewheel(self.tree)
self.avg_window_var.trace_add("write", lambda *_: (self.tree.heading("avg", text=f"Avg ({self.avg_window_var.get()})"), self.tree.heading("davg", text=f"Δ avg ({self.avg_window_var.get()})")))
self.tree.heading("#0", text="Variable")
self.tree.heading("value", text="Value")
self.tree.heading("delta", text="Δ last")
self.tree.heading("davg", text=f"Δ avg ({self.avg_window_var.get()})")
self.tree.heading("avg", text=f"Avg ({self.avg_window_var.get()})")
self.tree.heading("updated", text="Updated")
self.tree.heading("status", text="HTTP")
self.tree.column("#0", width=500, anchor="w")
self.tree.column("value", width=340, anchor="w")
self.tree.column("delta", width=110, anchor="e")
self.tree.column("davg", width=120, anchor="e")
self.tree.column("avg", width=120, anchor="e")
self.tree.column("updated", width=110, anchor="center")
self.tree.column("status", width=60, anchor="center")
style = ttk.Style(self)
try: style.theme_use("clam")
except Exception: DBGEX("App.__init__ theme_use clam")
# Context menu
self.tree_menu = tk.Menu(self, tearoff=False)
self.tree_menu.add_command(label="Set thresholds, actions & alarms…", command=self.open_thresholds_dialog)
self.tree_menu.add_command(label="Open plot window…", command=self.open_plot_window)
self.tree.bind("<Button-3>", self.on_tree_right_click)
self.tree.bind("<Double-1>", lambda _e: self.open_plot_window())
bottom = ttk.Frame(main)
act_controls = ttk.Frame(bottom, padding=(0,6,0,6))
ttk.Label(act_controls, text="Function:").pack(side=tk.LEFT)
self.func_name_var = tk.StringVar(value="")
self.func_combo = ttk.Combobox(act_controls, textvariable=self.func_name_var, width=44)
self.func_combo.pack(side=tk.LEFT, padx=6)
self._attach_search_filter_to_combobox(self.func_combo, self.functions_list)
ttk.Label(act_controls, text="Value:").pack(side=tk.LEFT)
self.func_value_var = tk.StringVar(value="1")
ttk.Entry(act_controls, textvariable=self.func_value_var, width=10).pack(side=tk.LEFT, padx=6)
ttk.Button(act_controls, text="Run Once", command=self.run_func_once).pack(side=tk.LEFT, padx=4)
ttk.Button(act_controls, text="Schedule…", command=self.add_schedule_dialog).pack(side=tk.LEFT, padx=4)
columns2 = ("func", "value", "mode", "interval", "next", "enabled")
self.actions_tree = ttk.Treeview(bottom, columns=columns2, show="headings", height=10, selectmode="browse")
for col, hdr, w in zip(columns2, ["Function", "Value", "Mode", "Interval(s)", "Next Run", "Enabled"], [280, 160, 100, 100, 180, 80]):
self.actions_tree.heading(col, text=hdr)
self.actions_tree.column(col, width=w, anchor="center")
self.actions_tree.pack(side=tk.LEFT, fill=tk.BOTH, expand=True)
vsb2 = ttk.Scrollbar(bottom, orient="vertical", command=self.actions_tree.yview)
vsb2.pack(side=tk.RIGHT, fill=tk.Y)
self.actions_tree.configure(yscrollcommand=vsb2.set)
self._bind_mousewheel(self.actions_tree)
main.add(top_frame, weight=3)
main.add(bottom, weight=2)
footer = ttk.Frame(self, padding=10)
footer.pack(side=tk.BOTTOM, fill=tk.X)
self.cycle_lbl = ttk.Label(footer, text="Last cycle: —")
self.cycle_lbl.pack(side=tk.LEFT)
self.protocol("WM_DELETE_WINDOW", self.on_close)
# DOMYŚLNE USTAWIENIA WYŚWIETLANIA (trzymane w tk.Variable, będą też zapisane w konfigu)
self.display_backend_var = tk.StringVar(value="matplotlib") # "matplotlib" | "canvas" | "pyqtgraph"
self.default_samples_var = tk.IntVar(value=200) # domyślna liczba próbek na wykres
self.default_maxpts_var = tk.IntVar(value=400) # ile maks. punktów realnie rysować
# Menu „Opcje” -> „Display”
menubar = tk.Menu(self) # <-- najpierw twórz menubar
opmenu = tk.Menu(menubar, tearoff=0)
display_menu = tk.Menu(opmenu, tearoff=0)
display_menu.add_radiobutton(label="Backend: Matplotlib",
variable=self.display_backend_var, value="matplotlib")
display_menu.add_radiobutton(label="Backend: Canvas (lite)",
variable=self.display_backend_var, value="canvas")
display_menu.add_radiobutton(label="Backend: PyQtGraph",
variable=self.display_backend_var, value="pyqtgraph",
state=("normal" if _pyqtgraph_available else "disabled"))
display_menu.add_separator()
display_menu.add_command(label="Display Defaults…",
command=self.open_display_defaults_dialog)
# Sklej podmenu Display pod „Opcje”
opmenu.add_cascade(label="Display", menu=display_menu)
opmenu.add_separator()
opmenu.add_command(label="Arrange plot windows", command=self.arrange_plot_windows)
opmenu.add_command(label="Count plot windows", command=lambda: tk.messagebox.showinfo("Plots", f"Open plots: {self.count_plot_windows()}"))
# Reszta menubar
filemenu = tk.Menu(menubar, tearoff=False)
filemenu.add_command(label="Save Configuration...", command=self.save_config)
filemenu.add_command(label="Load Configuration...", command=self.load_config)
filemenu.add_separator()
filemenu.add_command(label="Exit", command=self.on_close)
menubar.add_cascade(label="File", menu=filemenu)
funmenu = tk.Menu(menubar, tearoff=False)
funmenu.add_command(label="Run Function Once...", command=self.menu_run_once_dialog)
funmenu.add_command(label="Add Scheduled Function...", command=self.menu_schedule_dialog)
funmenu.add_separator()
funmenu.add_command(label="Open Plot for Selected…", command=self.open_plot_window)
funmenu.add_separator()
funmenu.add_command(label="Reload Discovery", command=self.reload_discovery)
funmenu.add_command(label="Select Variables…", command=self.open_selector)
menubar.add_cascade(label="Function", menu=funmenu)
# Dodaj „Opcje” do menubar na końcu
menubar.add_cascade(label="Opcje", menu=opmenu)
# Podłącz menubar do okna
self.config(menu=menubar)
self.functions_list = list(DEFAULT_FUNCTIONS)
self.func_combo["values"] = self.functions_list
if self.functions_list and not self.func_name_var.get():
self.func_name_var.set(self.functions_list[0])
# Stable IDs
self._group_ids: Dict[str, str] = {}
self._var_ids: Dict[str, str] = {}
# Color tag cache: color_hex -> tag_name
self._color_tags: Dict[str, str] = {}
# Track repeating actions per (var_key,state)
self.state_tasks: Dict[tuple, int] = {}
self.expr_state_tasks: Dict[tuple, int] = {}
# Latest values from batch (lowercased keys)
self.latest_values: Dict[str, str] = {}
self.known_variables: List[str] = []
# Trigger discovery shortly after startup so function list populates
self.after(200, self.reload_discovery)
# Live watch for refresh interval changes
self._last_refresh_val = float(self.refresh_var.get())
self.after(2000, self._watch_refresh_interval)
# Actions context menu
self.actions_menu = tk.Menu(self, tearoff=False)
self.actions_menu.add_command(label="Toggle Enable/Disable", command=self.toggle_selected_task)
self.actions_menu.add_command(label="Run Now", command=self.run_selected_task_now)
self.actions_menu.add_command(label="Remove", command=self.remove_selected_task)
self.actions_tree.bind("<Button-3>", self.on_actions_right_click)
if _pyqtgraph_available:
self._qt_ensure_app()
def _qt_ensure_app(self):
"""Utwórz (raz) QApplication wspólną dla wszystkich okien Qt."""
try:
from pyqtgraph.Qt import QtWidgets
except Exception:
DBGEX("Qt import in _qt_ensure_app")
self._qt_app = None
return
if getattr(self, "_qt_app", None) is None:
self._qt_app = QtWidgets.QApplication.instance() or QtWidgets.QApplication([])
def _ensure_qt_pump(self):
if getattr(self, "_qt_pump_on", False):
return
self._qt_pump_on = True
self.after(16, self._pump_qt_events)
def _maybe_stop_qt_pump(self):
"""Wyłącz pompowanie zdarzeń Qt jeśli żadne okno Qt nie jest już widoczne."""
try:
has_visible_qt = False
for w in getattr(self, "_plot_windows", {}).values():
if getattr(w, "_backend", "") == "pyqtgraph":
qtwin = getattr(w, "_qt_win", None) or getattr(w, "_qt_widget", None)
# Najprostsze i najpewniejsze: sprawdzamy widoczność/istnienie
if qtwin is not None and hasattr(qtwin, "isVisible") and qtwin.isVisible():
has_visible_qt = True
break
if not has_visible_qt:
self._qt_pump_on = False
except Exception as e:
DBGEX(f"[qt] stop-pump check error: {e!r}")
# Na wszelki wypadek nie wyłączaj pompy na błędzie
def _pump_qt_events(self):
"""Pompowanie zdarzeń Qt z pętli Tk bez blokowania i bez reentrancji."""
try:
# Jeśli nie ma okien QT nie pompuj
if not getattr(self, "_plot_windows", None):
return
if not any(getattr(w, "_backend", "") == "pyqtgraph" for w in self._plot_windows.values()):
return
from pyqtgraph.Qt import QtWidgets, QtCore
app = getattr(self, "_qt_app", None) or QtWidgets.QApplication.instance()
if app is None:
return
# Reentrancy guard jeśli jesteśmy już w środku, odpuść
if getattr(self, "_qt_pumping", False):
return
self._qt_pumping = True
try:
# Nie blokuj; przetwórz tylko to, co już jest w kolejce
app.sendPostedEvents()
app.processEvents(QtCore.QEventLoop.AllEvents | QtCore.QEventLoop.DontWait)
finally:
self._qt_pumping = False
except Exception:
DBGEX("_pump_qt_events")
finally:
# Pętla cykliczna ale tylko jeśli aplikacja nie zamyka się i wciąż mamy okna QT
if not getattr(self, "_closing", False) and any(
getattr(w, "_backend", "") == "pyqtgraph" for w in getattr(self, "_plot_windows", {}).values()
):
# ~60 FPS max
self.after(16, self._pump_qt_events)
def _safe_bool(self, tkvar, default=False):
try:
return bool(tkvar.get())
except Exception:
DBGEX("get_safe_bool")
return default
def get_stats_for(self, name: Optional[str]) -> Optional[dict]:
if not name:
return None
key = str(name).lower()
vi = self.vars.get(key)
def _avg(dq, n):
if not dq or n <= 0 or len(dq) < n:
return None
lst = list(dq)[-n:]
try:
return sum(lst) / float(n)
except Exception:
DBGEX("get_stats_for avg")
return None
try:
n = max(1, int(self.avg_window_var.get()))
except Exception:
DBGEX("get_stats_for avg_window_var")
n = 60
if vi:
return {
"x": parse_first_float(vi.last_value),
"x_avg": _avg(vi.history, n),
"dx": vi.delta_last,
"dx_avg": _avg(vi.history_delta, n),
}
# fallback dla zmiennych nie-monitorowanych
val = self.get_current_value(name)
return {"x": val, "x_avg": None, "dx": None, "dx_avg": None}
# --- Discovery ---
def reload_discovery(self) -> None:
host = self.host_var.get().strip()
port = int(self.port_var.get())
base = build_base_url(host, port)
discovered_vars: List[str] = []
discovered_funcs: List[str] = []
msgs = []
# 1) Functions via WEBSERVER_LIST_VARIABLES_JSON (POST list)
s1, b1, _1 = http_get(base, {"variable": "WEBSERVER_LIST_VARIABLES_JSON"})
if s1 == 200 and b1:
_get_list, post_list = parse_weblist_names(b1)
if post_list:
discovered_funcs.extend(post_list)
else:
msgs.append(f"LIST_VARIABLES_JSON HTTP {s1}: {coerce_preview(b1,120)}")
# 2) Variables via WEBSERVER_BATCH_GET keys
s2, b2, _2 = http_get(base, {"variable": "WEBSERVER_BATCH_GET"})
if s2 == 200 and b2:
values_map = parse_batch_values(b2)
if values_map:
seen=set()
for k in values_map.keys():
kl = k.lower()
if kl not in seen:
seen.add(kl); discovered_vars.append(k)
else:
msgs.append(f"BATCH_GET HTTP {s2}: {coerce_preview(b2,120)}")
# 3) Fallbacks
if not discovered_vars or not discovered_funcs:
s3, b3, _3 = http_get_root(base)
if s3 == 200 and b3:
if not discovered_vars:
discovered_vars = parse_variable_names_from_html_index(b3) or discovered_vars
if not discovered_funcs:
discovered_funcs = parse_function_names_from_html_index(b3) or discovered_funcs
else:
msgs.append(f"Main page HTTP {s3}: {coerce_preview(b3,120)}")
# 4) embedded defaults
used_defaults = False
if not discovered_vars:
discovered_vars = list(DEFAULT_VARS); used_defaults = True
if not discovered_funcs:
discovered_funcs = list(DEFAULT_FUNCTIONS)
# Apply
self.functions_list = discovered_funcs
self.func_combo["values"] = self.functions_list
if self.functions_list and not self.func_name_var.get():
self.func_name_var.set(self.functions_list[0])
# Remember known variables for y/z source selectors
self.known_variables = list(discovered_vars)
self.show_selector_dialog(discovered_vars)
# Status
if used_defaults:
messagebox.showwarning(
"Discovery fallback",
"Could not fully discover via LIST_VARIABLES_JSON / BATCH_GET.\n"
"Loaded embedded defaults so you can proceed.\n\n" + ("\n".join(msgs[:6]) if msgs else ""))
self.status_lbl.configure(text=f"Loaded defaults ({len(discovered_vars)} vars, {len(discovered_funcs)} funcs)")
else:
self.status_lbl.configure(text=f"Discovered: vars {len(discovered_vars)} | funcs {len(discovered_funcs)}")
# --- Select Vars dialog ---
def open_selector(self) -> None:
union = set([vi.display_name for vi in self.vars.values()]) or set(DEFAULT_VARS)
self.show_selector_dialog(sorted(union))
def _reschedule_state_tasks_for(self, vi: VarInfo) -> None:
"""
Usuwa wszystkie 'while-in-state' taski dla tej zmiennej i tworzy na nowo
tylko te, które powinny działać w bieżącym stanie według aktualnych progów.
Interwał 0 => run once; >0 => cykliczne.
"""
if not hasattr(self, "scheduler") or self.scheduler is None:
return
t = vi.thresholds
# 1) Usuń istniejące zadania powiązane z tą zmienną (po tagu):
for state in ("DEAD_LOW", "LOW", "OPERATING", "HIGH", "EXTREME_HIGH"):
tag = f"state::{vi.key}::{state}"
self.scheduler.remove_tasks_by_tag(tag)
# 2) Zmapuj ustawienia dla stanów:
mapping = {
"DEAD_LOW": (
t.action_dead_low, t.value_dead_low, t.action_dead_low_interval,
getattr(t, "expr_dead_low", None), getattr(t, "expr_target_dead_low", None)
),
"LOW": (
t.action_low, t.value_low, t.action_low_interval,
getattr(t, "expr_low", None), getattr(t, "expr_target_low", None)
),
"OPERATING": (
getattr(t, "action_operating", None), getattr(t, "value_operating", "1"),
getattr(t, "action_operating_interval", 1.0),
getattr(t, "expr_operating", None), getattr(t, "expr_target_operating", None)
),
"HIGH": (
t.action_high, t.value_high, t.action_high_interval,
getattr(t, "expr_high", None), getattr(t, "expr_target_high", None)
),
"EXTREME_HIGH": (
t.action_extreme_high, t.value_extreme_high, t.action_extreme_high_interval,
getattr(t, "expr_extreme_high", None), getattr(t, "expr_target_extreme_high", None)
),
}
curr_state = vi.last_state # aktualny stan (ustawiany w evaluate_thresholds / on_state_change) :contentReference[oaicite:4]{index=4}
if curr_state not in mapping:
self.refresh_actions_tree()
return
name, value, interval_s, expr, expr_target = mapping[curr_state]
# Jeśli użytkownik ustawił 0 => 'run once' przy wejściu w stan:
# Samo przełączenie na 0 ma natychmiast skasować ew. cykliczne zadania zrobiliśmy to wyżej.
# Nie dodajemy nowego zadania, jeśli nie ma co wykonywać.
if not any([name, expr, expr_target]):
self.refresh_actions_tree()
return
tag = f"state::{vi.key}::{curr_state}"
if expr or expr_target:
# zadanie 'obliczeniowe' liczymy x/y/z (x=monitorowana)
task = ActionTask(
name=(name or expr_target or ""), # nazwa do tabeli/POST (gdy expr_target)
value=(value if name else "0"), # value nie jest używane gdy expr_target
interval_s=float(interval_s),
expr=expr,
x_src=vi.display_name,
y_src=getattr(t, "y_source", None),
z_src=getattr(t, "z_source", None),
tag=tag,
)
else:
# zwykły POST do 'name' z 'value'
task = ActionTask(
name=name or "",
value=str(value),
interval_s=float(interval_s),
tag=tag,
)
self.scheduler.add_task(task)
self.refresh_actions_tree()
def show_selector_dialog(self, discovered: List[str]) -> None:
seen=set(); disp=[]
for n in discovered:
kl = n.lower()
if kl not in seen:
seen.add(kl); disp.append(n)
dlg = tk.Toplevel(self)
dlg.title("Select Variables to Monitor")
dlg.geometry("600x540")
dlg.transient(self)
dlg.grab_set()
temp_selected = {k: True for k in self.variables_keys}
top = ttk.Frame(dlg, padding=8)
top.pack(side=tk.TOP, fill=tk.X)
ttk.Label(top, text="Filter:").pack(side=tk.LEFT)
filt_var = tk.StringVar(value="")
ttk.Entry(top, textvariable=filt_var, width=40).pack(side=tk.LEFT, padx=6)
sel_all = ttk.Button(top, text="Select All")
sel_none = ttk.Button(top, text="Clear")
sel_all.pack(side=tk.LEFT, padx=4); sel_none.pack(side=tk.LEFT, padx=4)
frame = ttk.Frame(dlg)
frame.pack(side=tk.TOP, fill=tk.BOTH, expand=True, padx=8, pady=8)
canvas = tk.Canvas(frame, borderwidth=0)
vsb = ttk.Scrollbar(frame, orient="vertical", command=canvas.yview)
inner = ttk.Frame(canvas)
inner.bind("<Configure>", lambda e: canvas.configure(scrollregion=canvas.bbox("all")))
canvas.create_window((0,0), window=inner, anchor="nw")
canvas.configure(yscrollcommand=vsb.set)
canvas.pack(side="left", fill="both", expand=True); vsb.pack(side="right", fill="y")
def _mw(event):
if event.delta:
canvas.yview_scroll(int(-1*(event.delta/120)), "units")
return "break"
def _mw_up(_e):
canvas.yview_scroll(-1, "units"); return "break"
def _mw_down(_e):
canvas.yview_scroll(1, "units"); return "break"
canvas.bind("<MouseWheel>", _mw)
inner.bind("<MouseWheel>", _mw)
canvas.bind("<Button-4>", _mw_up)
canvas.bind("<Button-5>", _mw_down)
inner.bind("<Button-4>", _mw_up)
inner.bind("<Button-5>", _mw_down)
rows: List[Tuple[str, str, tk.BooleanVar]] = []
def rebuild():
for child in inner.winfo_children():
child.destroy()
rows.clear()
f = filt_var.get().strip().lower()
for name in disp:
if f and f not in name.lower():
continue
key = name.lower()
var = tk.BooleanVar(value=temp_selected.get(key, False))
def bind_trace(k=key, v=var):
def _(*_a):
temp_selected[k] = v.get()
v.trace_add("write", _)
bind_trace()
cb = ttk.Checkbutton(inner, text=name, variable=var)
cb.pack(anchor="w", pady=2, padx=4)
rows.append((name, key, var))
rebuild()
filt_var.trace_add("write", lambda *_: rebuild())
def select_all():
for _, key, var in rows:
var.set(True); temp_selected[key] = True
def clear_all():
for _, key, var in rows:
var.set(False); temp_selected[key] = False
sel_all.configure(command=select_all)
sel_none.configure(command=clear_all)
bot = ttk.Frame(dlg, padding=8)
bot.pack(side=tk.BOTTOM, fill=tk.X)
def apply_and_close():
selected_keys = [k for k, sel in temp_selected.items() if sel]
new_order = [k for k in self.variables_keys if k in selected_keys]
for name in disp:
key = name.lower()
if temp_selected.get(key, False) and key not in new_order:
new_order.append(key)
self.variables_keys = new_order
new_vars: Dict[str, VarInfo] = {}
for key in self.variables_keys:
if key in self.vars:
vi = self.vars[key]
else:
disp_name = next((n for n, k, _ in rows if k == key), key)
vi = VarInfo(key=key, display_name=disp_name)
new_vars[key] = vi
self.vars = new_vars
# If poller is running, update its live list
if self.poller and self.poller.is_alive():
self.poller.variables_keys = self.variables_keys[:]
self.refresh_tree()
dlg.destroy()
ttk.Button(bot, text="Apply", command=apply_and_close).pack(side=tk.RIGHT, padx=4)
ttk.Button(bot, text="Cancel", command=dlg.destroy).pack(side=tk.RIGHT, padx=4)
# --- Actions UI ---
def on_actions_right_click(self, event):
try:
iid = self.actions_tree.identify_row(event.y)
if iid:
self.actions_tree.selection_set(iid)
finally:
self.actions_menu.tk_popup(event.x_root, event.y_root)
def run_func_once(self):
fname = self.func_name_var.get().strip()
if not fname:
messagebox.showinfo("No function", "Choose a function first.")
return
val = self.func_value_var.get()
status, body, _ = self.scheduler.run_once(fname, val)
messagebox.showinfo("Run Once", f"POST ?variable={fname}&value={val}\nHTTP {status}\n{coerce_preview(body, 300)}")
def add_schedule_dialog(self):
fname = self.func_name_var.get().strip()
if not fname:
messagebox.showinfo("No function", "Choose a function first.")
return
top = tk.Toplevel(self); top.title("Schedule Function"); top.geometry("360x170"); top.transient(self); top.grab_set()
ttk.Label(top, text=f"Function: {fname}").pack(pady=(10,4))
val_var = tk.StringVar(value=self.func_value_var.get())
ttk.Label(top, text="Value:").pack()
ttk.Entry(top, textvariable=val_var, width=16).pack()
int_var = tk.DoubleVar(value=1.0)
ttk.Label(top, text="Interval (seconds):").pack(pady=(6,0))
ttk.Entry(top, textvariable=int_var, width=10).pack()
def add_it():
interval = float(int_var.get())
task = ActionTask(name=fname, value=val_var.get(), interval_s=max(0.0, interval))
tid = self.scheduler.add_task(task)
self.refresh_actions_tree()
top.destroy()
ttk.Button(top, text="Add", command=add_it).pack(pady=10)
def toggle_selected_task(self):
sel = self.actions_tree.selection()
if not sel: return
tid = int(sel[0])
tasks = {t.task_id: t for t in self.scheduler.list_tasks()}
t = tasks.get(tid);
if not t: return
self.scheduler.set_enabled(tid, not t.enabled)
self.refresh_actions_tree()
def run_selected_task_now(self):
sel = self.actions_tree.selection()
if not sel: return
tid = int(sel[0])
tasks = {t.task_id: t for t in self.scheduler.list_tasks()}
t = tasks.get(tid)
if not t: return
status, body, _ = self.scheduler.run_task_once(t)
messagebox.showinfo("Run Now", f"POST ?variable={t.name}&value={t.value}\nHTTP {status}\n{coerce_preview(body, 300)}")
def remove_selected_task(self):
sel = self.actions_tree.selection()
if not sel: return
tid = int(sel[0])
self.scheduler.remove_task(tid)
self.refresh_actions_tree()
def get_current_value(self, name: Optional[str]) -> Optional[float]:
if not name:
return None
key = str(name).lower()
if hasattr(self, "latest_values") and key in self.latest_values:
return parse_first_float(self.latest_values.get(key))
base = build_base_url(self.host_var.get().strip(), int(self.port_var.get()))
st, bd, _h = http_get(base, {"variable": key})
if st == 200:
return parse_first_float(bd)
return None
def refresh_actions_tree(self):
# zapamiętaj zaznaczenie/fokus
sel_before = self.actions_tree.selection()
focus_before = self.actions_tree.focus()
# przebuduj
self.actions_tree.delete(*self.actions_tree.get_children())
for t in self.scheduler.list_tasks():
mode = ("Interval" if t.interval_s > 0 else "Once") + (" + Expr" if getattr(t, 'expr', None) else "")
next_s = ("—" if t.interval_s == 0 else datetime.fromtimestamp(t.next_run).strftime("%H:%M:%S"))
self.actions_tree.insert(
"", "end", iid=str(t.task_id),
values=(t.name, t.value, mode, t.interval_s, next_s, "Yes" if t.enabled else "No")
)
# odtwórz zaznaczenie/fokus (o ile elementy wciąż istnieją)
if sel_before:
kept = [iid for iid in sel_before if self.actions_tree.exists(iid)]
if kept:
self.actions_tree.selection_set(kept)
if focus_before and self.actions_tree.exists(focus_before):
self.actions_tree.focus(focus_before)
# --- [DROP-IN] jeden zegar do wszystkich backendów ---------------------------
def _ensure_plot_timer(self):
"""Gwarantuje, że działa pojedynczy timer do odświeżania wszystkich wykresów."""
if getattr(self, "_plot_timer", None) is None and not getattr(self, "_closing", False):
try:
ms = int(max(100, float(self.refresh_var.get()) * 1000)) # ~10 FPS max (wg refresh)
except Exception:
DBGEX("_ensure_plot_timer refresh_var")
ms = 200
self._plot_timer = self.after(ms, self._plot_tick)
def _decimate(self, seq, max_pts: int):
"""Prosta decymacja do maks. liczby punktów: zwraca (xs, ys)."""
if not seq:
return [], []
if len(seq) <= max_pts:
return list(range(len(seq))), list(seq)
step = max(1, int(math.ceil(len(seq) / float(max_pts))))
ys = seq[::step]
xs = list(range(0, len(seq), step))[:len(ys)]
return xs, ys
def _plot_tick(self):
"""
Jeden tick: iteruje po wszystkich oknach w self._plot_windows
i wywołuje odpowiednie aktualizacje dla backendu okna.
"""
wins = list(getattr(self, "_plot_windows", {}).items()) if hasattr(self, "_plot_windows") else []
if not wins:
self._plot_timer = None
return
# Zbierz żywe okna per backend
alive = []
for key, win in wins:
backend = getattr(win, "_backend", "")
try:
if backend in ("matplotlib", "canvas"):
# Tk toplevel sprawdź, czy okno istnieje
if hasattr(win, "winfo_exists") and win.winfo_exists():
alive.append((key, win))
elif backend == "pyqtgraph":
# Qt sprawdź, czy widget widoczny
qt = getattr(win, "_qt_widget", None)
if qt is not None:
try:
vis = bool(qt.isVisible())
except Exception:
DBGEX("pyqtgraph isVisible")
vis = True
if vis:
alive.append((key, win))
else:
# nieznane (pomijamy)
pass
except Exception:
DBGEX("_plot_tick(check window alive)")
# okno padło usuwamy z rejestru
try:
self._plot_windows.pop(key, None)
except Exception:
DBGEX("_plot_tick(remove dead window)")
pass
if not alive:
self._plot_timer = None
return
for key, win in alive:
try:
vi = self.vars.get(key)
if not vi:
continue
# Aktualizacja tytułu (nazwa + ostatnia wartość) bez nadmiernego spamowania
val_num = parse_first_float(vi.last_value)
new_title = f"{vi.display_name}{val_num:.6g}" if val_num is not None else f"{vi.display_name}"
if getattr(win, "_last_title", None) != new_title:
try:
# Tk
if hasattr(win, "title"):
win.title(new_title)
except Exception:
DBGEX("_plot_tick(update title Tk)")
pass
try:
# Qt
if getattr(win, "_backend", "") == "pyqtgraph":
qtw = getattr(win, "_qt_widget", None)
if qtw is not None and hasattr(qtw, "setWindowTitle"):
qtw.setWindowTitle(new_title)
except Exception:
DBGEX("_plot_tick(update title Qt)")
pass
win._last_title = new_title
# Pomiń rysowanie, gdy brak nowych danych
last_ver = getattr(win, "_last_seen_ver", -1)
if getattr(vi, "hist_ver", 0) == last_ver:
continue
# Pobranie danych (per-okno liczba próbek i max rys. punktów)
try:
n = int(getattr(win, "_sample_len_var", self.default_samples_var).get())
except Exception:
DBGEX("_plot_tick(get sample length)")
n = int(self.default_samples_var.get())
try:
max_pts = int(getattr(win, "_max_draw_var", self.default_maxpts_var).get())
except Exception:
DBGEX("_plot_tick(get max points)")
max_pts = int(self.default_maxpts_var.get())
vals = list(vi.history)[-n:] if hasattr(vi, "history") else []
dels = list(vi.history_delta)[-n:] if hasattr(vi, "history_delta") else []
xs_v, vals_draw = self._decimate(vals, max_pts)
xs_b, dels_draw = self._decimate(dels, max_pts)
# Progi efektywne (odporne na None)
thr = self._effective_thresholds(vi) if hasattr(self, "_effective_thresholds") else {}
# backend-specyficzny update
b = getattr(win, "_backend", "")
if b == "matplotlib":
self._plot_update_matplotlib(win, xs_v, vals_draw, xs_b, dels_draw, thr)
elif b == "canvas":
self._plot_update_canvas(win, xs_v, vals_draw, xs_b, dels_draw, thr)
elif b == "pyqtgraph":
self._plot_update_pyqtgraph(win, xs_v, vals_draw, xs_b, dels_draw, thr)
win._last_seen_ver = getattr(vi, "hist_ver", win._last_seen_ver)
except Exception:
DBGEX("_plot_tick(one window)")
continue
# kolejny tick
try:
ms = int(max(100, float(self.refresh_var.get()) * 1000))
except Exception:
DBGEX("_plot_tick(refresh_var)")
ms = 200
if not getattr(self, "_closing", False):
self._plot_timer = self.after(ms, self._plot_tick)
# --- Poller control / rendering ---
def start_polling(self) -> None:
if hasattr(self, "poller") and self.poller and self.poller.is_alive():
messagebox.showinfo("Already running", "Polling is already active.")
return
if not self.variables_keys:
messagebox.showwarning("No variables", "Variable list is empty. Use Select Vars… first.")
return
self.stop_event.clear()
self.paused_event.clear()
self.poller = Poller(
host=self.host_var.get().strip(),
port=int(self.port_var.get()),
variables_keys=self.variables_keys,
ui_queue=self.ui_queue,
refresh_interval=float(self.refresh_var.get()),
stop_event=self.stop_event,
paused_event=self.paused_event,
)
self.poller.start()
self.start_btn.configure(state="disabled")
self.pause_btn.configure(state="normal", text="Pause")
self.status_lbl.configure(text="Running…")
self.after(100, self.drain_queue)
def toggle_pause(self) -> None:
if not (self.poller and self.poller.is_alive()):
return
if self.paused_event.is_set():
self.paused_event.clear()
self.pause_btn.configure(text="Pause")
self.status_lbl.configure(text="Running…")
else:
self.paused_event.set()
self.pause_btn.configure(text="Resume")
self.status_lbl.configure(text="Paused")
def _bind_mousewheel(self, widget):
# Windows / macOS
def _mw(event):
if event.delta:
widget.yview_scroll(int(-1 * (event.delta / 120)), "units")
return "break"
# Linux (X11)
def _mw_up(_e):
widget.yview_scroll(-1, "units")
return "break"
def _mw_down(_e):
widget.yview_scroll(1, "units")
return "break"
widget.bind("<MouseWheel>", _mw)
widget.bind("<Button-4>", _mw_up)
widget.bind("<Button-5>", _mw_down)
def drain_queue(self) -> None:
try:
while True:
item = self.ui_queue.get_nowait()
kind = item[0]
if kind == "update":
_, key, value, status = item
vi = self.vars.get(key)
if not vi:
vi = VarInfo(key=key, display_name=key)
prev_num = parse_first_float(vi.last_value)
curr_num = parse_first_float(value)
vi.last_value = value
vi.last_updated = time.time()
vi.last_status = status
vi.error = None
# analytics update
if prev_num is not None and curr_num is not None:
vi.delta_last = curr_num - prev_num
try:
vi.history_delta.append(vi.delta_last)
except Exception:
DBGEX("Scheduler.run_task_once->get_value_cb")
pass
else:
vi.delta_last = None
if curr_num is not None:
try:
vi.history.append(curr_num)
vi.hist_ver += 1 # NOWE: sygnał dla wykresów, że są nowe dane
except Exception:
DBGEX("Scheduler.run_task_once->get_value_cb")
pass
self.vars[key] = vi
self.evaluate_thresholds(vi, value)
elif kind == "error":
_, key, status, msg = item
vi = self.vars.get(key) or VarInfo(key=key, display_name=key)
vi.last_status = status
vi.error = msg
vi.last_updated = time.time()
self.vars[key] = vi
elif kind == "cycle_start":
_, hhmmss = item
self.cycle_lbl.configure(text=f"Last cycle start: {hhmmss}")
elif kind == "batch":
_, mapping = item
if isinstance(mapping, dict):
self.latest_values.update(mapping)
# refresh known_variables list from batch keys (preserve case with existing where possible)
keys = list(mapping.keys())
# prefer existing display names from self.vars, else use given keys
disp = [self.vars.get(k.lower()).display_name if self.vars.get(k.lower()) else k for k in keys]
self.known_variables = sorted(set(list(self.known_variables) + disp), key=str.lower)
elif kind == "stopped":
self.status_lbl.configure(text="Stopped")
elif kind == "batch_fmt":
_, fmt = item
# nie nadpisuj info o błędach/paused tylko dołóż sufiks
cur = self.status_lbl.cget("text") or ""
base = cur.split(" | ")[0] # zachowaj, co było przedtem
self.status_lbl.configure(text=f"{base} | batch: {fmt}")
self.ui_queue.task_done()
except queue.Empty:
pass
self.refresh_tree()
self.refresh_actions_tree()
if self.poller and self.poller.is_alive():
self.after(250, self.drain_queue)
# --- Threshold logic & rendering ---
def on_tree_right_click(self, event):
try:
iid = self.tree.identify_row(event.y)
if iid:
self.tree.selection_set(iid)
finally:
self.tree_menu.tk_popup(event.x_root, event.y_root)
def open_plot_window(self, var_key: str | None = None):
if var_key is None:
sel = self.tree.selection()
if not sel:
tk.messagebox.showwarning("Plot", "Najpierw zaznacz zmienną w tabeli.")
return
iid = sel[0]
if not iid.startswith("var:"):
tk.messagebox.showwarning("Plot", "Wybierz wiersz ze zmienną (nie grupę).")
return
key = iid.split("var:", 1)[1]
else:
key = str(var_key).lower()
if key not in self.vars:
for k, vi in self.vars.items():
if vi.display_name.lower() == str(var_key).lower():
key = k
break
if key not in self.vars:
tk.messagebox.showwarning("Plot", f"Zmienna '{var_key or key}' nie jest monitorowana.")
return
backend = self.display_backend_var.get().lower()
if backend == "canvas":
self._open_canvas_window(key); return
if backend == "pyqtgraph":
if _pyqtgraph_available:
self._open_pyqtgraph_window(key); return
tk.messagebox.showwarning("PyQtGraph", "PyQtGraph nie jest dostępny użyj Matplotlib lub Canvas.")
return
# domyślnie matplotlib
self._open_matplotlib_window(key)
def open_display_defaults_dialog(self):
dlg = tk.Toplevel(self)
dlg.title("Display defaults")
dlg.geometry("360x220")
dlg.transient(self)
dlg.grab_set()
# Backend
ttk.Label(dlg, text="Default backend:").pack(anchor="w", padx=10, pady=(10,2))
back = tk.StringVar(value=self.display_backend_var.get())
frm = ttk.Frame(dlg); frm.pack(anchor="w", padx=10)
ttk.Radiobutton(frm, text="Matplotlib", variable=back, value="matplotlib").pack(side=tk.LEFT, padx=(0,10))
ttk.Radiobutton(frm, text="Canvas (lite)", variable=back, value="canvas").pack(side=tk.LEFT, padx=(0,10))
state = "normal" if _pyqtgraph_available else "disabled"
ttk.Radiobutton(frm, text="PyQtGraph", variable=back, value="pyqtgraph", state=state).pack(side=tk.LEFT)
# Samples / max points
box = ttk.Frame(dlg); box.pack(fill=tk.X, padx=10, pady=(12,2))
ttk.Label(box, text="Default samples:").grid(row=0, column=0, sticky="w")
ds = tk.IntVar(value=int(self.default_samples_var.get()))
ttk.Spinbox(box, from_=20, to=5000, increment=10, textvariable=ds, width=6).grid(row=0, column=1, padx=6)
ttk.Label(box, text="Default max draw pts:").grid(row=1, column=0, sticky="w", pady=(6,0))
md = tk.IntVar(value=int(self.default_maxpts_var.get()))
ttk.Spinbox(box, from_=100, to=5000, increment=50, textvariable=md, width=6).grid(row=1, column=1, padx=6, pady=(6,0))
# Show thresholds on plots
chk_box = ttk.Frame(dlg); chk_box.pack(fill=tk.X, padx=10, pady=(10,0))
show_thr_local = tk.BooleanVar(value=bool(self.display_show_thresholds_var.get()))
ttk.Checkbutton(chk_box, text="Show thresholds (plots)", variable=show_thr_local).pack(anchor="w")
# Buttons
bar = ttk.Frame(dlg); bar.pack(fill=tk.X, pady=12, padx=10)
def apply():
self.display_backend_var.set(back.get())
self.default_samples_var.set(int(ds.get()))
self.default_maxpts_var.set(int(md.get()))
self.display_show_thresholds_var.set(bool(show_thr_local.get()))
dlg.destroy()
tk.messagebox.showinfo("Display defaults",
"Zapisz te ustawienia na stałe przez File → Save Configuration.\n"
"Nowe wykresy będą używać tych domyślnych wartości.")
ttk.Button(bar, text="OK", command=apply).pack(side=tk.RIGHT, padx=6)
ttk.Button(bar, text="Cancel", command=dlg.destroy).pack(side=tk.RIGHT)
def open_thresholds_dialog(self):
sel = self.tree.selection()
expr_xsrc_vars = {}
if not sel:
messagebox.showinfo("No selection", "Select a variable first.")
return
iid = sel[0]
if not iid.startswith("var:"):
messagebox.showinfo("Select variable", "Select a specific variable row (not a group).")
return
key = iid.split("var:",1)[1]
vi = self.vars.get(key)
if not vi:
messagebox.showinfo("Missing", "Selected variable is not available.")
return
dlg = tk.Toplevel(self)
dlg.title(f"Thresholds, actions & alarms — {vi.display_name}")
dlg.geometry("980x700")
dlg.transient(self); dlg.grab_set()
t = vi.thresholds
cur = parse_first_float(vi.last_value)
auto_defaults = {}
if cur is not None:
auto_defaults = {"dead_low": round(cur*0.8, 6), "low": round(cur*0.9, 6), "high": round(cur*1.1, 6), "extreme_high": round(cur*1.2, 6)}
# Scrollable body
outer = ttk.Frame(dlg); outer.pack(fill=tk.BOTH, expand=True)
canvas = tk.Canvas(outer, highlightthickness=0)
vsb = ttk.Scrollbar(outer, orient="vertical", command=canvas.yview)
canvas.configure(yscrollcommand=vsb.set)
vsb.pack(side=tk.RIGHT, fill=tk.Y)
canvas.pack(side=tk.LEFT, fill=tk.BOTH, expand=True)
grid = ttk.Frame(canvas)
win = canvas.create_window((0,0), window=grid, anchor="nw")
def _on_cfg(event=None):
canvas.configure(scrollregion=canvas.bbox("all"))
canvas.itemconfigure(win, width=canvas.winfo_width())
grid.bind("<Configure>", _on_cfg)
canvas.bind("<Configure>", _on_cfg)
# thresholds
ttk.Label(grid, text="DEAD LOW").grid(row=0, column=0, sticky="w", pady=2)
ttk.Label(grid, text="LOW").grid(row=1, column=0, sticky="w", pady=2)
ttk.Label(grid, text="HIGH").grid(row=2, column=0, sticky="w", pady=2)
ttk.Label(grid, text="EXTREME HIGH").grid(row=3, column=0, sticky="w", pady=2)
def mk_val(default, keyname, row):
dv = auto_defaults.get(keyname) if default is None else default
sv = tk.StringVar(value="" if dv is None else str(dv))
ttk.Entry(grid, textvariable=sv, width=12).grid(row=row, column=1, sticky="w", padx=6)
return sv
dead_low_var = mk_val(t.dead_low, "dead_low", 0)
low_var = mk_val(t.low, "low", 1)
high_var = mk_val(t.high, "high", 2)
extreme_high_var = mk_val(t.extreme_high, "extreme_high", 3)
ttk.Label(grid, text="Alarm on enter:").grid(row=0, column=3, sticky="w")
alarm_dead_low = tk.BooleanVar(value=t.alarm_dead_low)
alarm_low = tk.BooleanVar(value=t.alarm_low)
alarm_high = tk.BooleanVar(value=t.alarm_high)
alarm_ext = tk.BooleanVar(value=t.alarm_extreme_high)
ttk.Checkbutton(grid, text="Dead Low", variable=alarm_dead_low).grid(row=1, column=3, sticky="w")
ttk.Checkbutton(grid, text="Low", variable=alarm_low).grid(row=2, column=3, sticky="w")
ttk.Checkbutton(grid, text="High", variable=alarm_high).grid(row=3, column=3, sticky="w")
ttk.Checkbutton(grid, text="Extreme High", variable=alarm_ext).grid(row=4, column=3, sticky="w")
# actions
ttk.Label(grid, text="On enter: call function (optional)").grid(row=6, column=0, sticky="w", pady=(12,4))
ttk.Label(grid, text="Interval(s) while in state (0 = once)").grid(row=6, column=3, sticky="w")
rows = [("Dead Low", "action_dead_low", "value_dead_low", "action_dead_low_interval"),
("Low", "action_low", "value_low", "action_low_interval"),
("Operating", "action_operating", "value_operating", "action_operating_interval"),
("High", "action_high", "value_high", "action_high_interval"),
("Extreme High", "action_extreme_high", "value_extreme_high", "action_extreme_high_interval")]
action_vars = {}; value_vars = {}; interval_vars = {}
for i, (label, action_key, value_key, interval_key) in enumerate(rows):
r = 7+i
ttk.Label(grid, text=label).grid(row=r, column=0, sticky="w", pady=2)
s = ttk.Combobox(grid, values=self.functions_list or DEFAULT_FUNCTIONS, width=44)
s.set(getattr(t, action_key) or "")
s.grid(row=r, column=1, sticky="w", padx=6)
self._attach_search_filter_to_combobox(s, self.functions_list)
action_vars[action_key] = s
sv = tk.StringVar(value=getattr(t, value_key))
ttk.Entry(grid, textvariable=sv, width=12).grid(row=r, column=2, sticky="w", padx=6)
value_vars[value_key] = sv
iv = tk.DoubleVar(value=getattr(t, interval_key) if getattr(t, interval_key) is not None else 1.0)
ttk.Entry(grid, textvariable=iv, width=10).grid(row=r, column=3, sticky="w", padx=6)
interval_vars[interval_key] = iv
# y/z sources
ttk.Label(grid, text="y source (optional)").grid(row=13, column=0, sticky="w", pady=(14,4))
y_source_var = tk.StringVar(value=t.y_source or "")
y_combo = ttk.Combobox(grid, values=(self.known_variables or [vi.display_name]), textvariable=y_source_var, width=44)
y_combo.grid(row=13, column=1, sticky="w", padx=6)
self._attach_search_filter_to_combobox(y_combo, self.known_variables)
ttk.Label(grid, text="z source (optional)").grid(row=13, column=2, sticky="e")
z_source_var = tk.StringVar(value=t.z_source or "")
z_combo = ttk.Combobox(grid, values=(self.known_variables or [vi.display_name]), textvariable=z_source_var, width=32)
z_combo.grid(row=13, column=3, sticky="w", padx=6)
self._attach_search_filter_to_combobox(z_combo, self.known_variables)
# expressions
ttk.Label(grid, text="On enter: evaluate expression/snippet (x, y, z available) and optionally POST to a function").grid(row=15, column=0, sticky="w", pady=(14,4), columnspan=3)
expr_rows = [("Dead Low expr", "expr_dead_low", "expr_target_dead_low"),
("Low expr", "expr_low", "expr_target_low"),
("Operating expr", "expr_operating", "expr_target_operating"),
("High expr", "expr_high", "expr_target_high"),
("Extreme High expr", "expr_extreme_high", "expr_target_extreme_high")]
expr_vars = {}; expr_target_vars = {}
for i, (label, keyname, tkey) in enumerate(expr_rows):
r = 16+i
ttk.Label(grid, text=label).grid(row=r, column=0, sticky="w", pady=2)
expr_vars[keyname] = tk.StringVar(value=getattr(t, keyname) or "")
ttk.Entry(grid, textvariable=expr_vars[keyname], width=64).grid(row=r, column=1, sticky="w", padx=6)
ttk.Label(grid, text="→ POST to function").grid(row=r, column=2, sticky="e")
s = ttk.Combobox(grid, values=self.functions_list or DEFAULT_FUNCTIONS, width=32)
s.set(getattr(t, tkey) or "")
s.grid(row=r, column=3, sticky="w", padx=6)
self._attach_search_filter_to_combobox(s, self.functions_list)
expr_target_vars[tkey] = s
ttk.Label(grid, text="x from").grid(row=r, column=4, sticky="e")
src_combo = ttk.Combobox(grid, values=["raw", "x_avg", "dx", "dx_avg"], width=8)
# mapowanie nazwy wiersza na pole w Thresholds:
statekey = {
"Dead Low expr": "dead_low",
"Low expr": "low",
"Operating expr": "operating",
"High expr": "high",
"Extreme High expr": "extreme_high",
}[label]
field_name = f"expr_x_source_{statekey}"
src_combo.set(getattr(t, field_name, "raw"))
src_combo.grid(row=r, column=5, sticky="w")
expr_xsrc_vars[field_name] = src_combo
# Bottom bar
btns = ttk.Frame(dlg); btns.pack(fill=tk.X, padx=10, pady=10)
def do_save():
def _parse_threshold_field(var_or_entry) -> tuple[Optional[float], Optional[str]]:
# Przyjmujemy tk.StringVar / tk.Entry / str
if hasattr(var_or_entry, "get"):
s = var_or_entry.get().strip()
else:
s = str(var_or_entry).strip()
if s == "":
return None, None
try:
return float(s), None
except Exception:
DBGEX("App.__init__ theme_use clam")
# potraktuj jako wyrażenie (np. "x_avg - 5")
return None, s
# UŻYJ POPRAWNYCH ZMIENNYCH:
dead_val, dead_expr = _parse_threshold_field(dead_low_var)
low_val, low_expr = _parse_threshold_field(low_var)
high_val, high_expr = _parse_threshold_field(high_var)
ext_val, ext_expr = _parse_threshold_field(extreme_high_var)
nt = Thresholds(
dead_low=dead_val, low=low_val, high=high_val, extreme_high=ext_val,
expr_thr_dead_low=dead_expr, expr_thr_low=low_expr,
expr_thr_high=high_expr, expr_thr_extreme_high=ext_expr,
alarm_dead_low=bool(alarm_dead_low.get()),
alarm_low=bool(alarm_low.get()),
alarm_high=bool(alarm_high.get()),
alarm_extreme_high=bool(alarm_ext.get()),
action_dead_low=action_vars["action_dead_low"].get() or None,
value_dead_low=value_vars["value_dead_low"].get(),
action_dead_low_interval=float(interval_vars["action_dead_low_interval"].get() or 1.0),
action_low=action_vars["action_low"].get() or None,
value_low=value_vars["value_low"].get(),
action_low_interval=float(interval_vars["action_low_interval"].get() or 1.0),
action_operating=action_vars["action_operating"].get() or None,
value_operating=value_vars["value_operating"].get(),
action_operating_interval=float(interval_vars["action_operating_interval"].get() or 1.0),
action_high=action_vars["action_high"].get() or None,
value_high=value_vars["value_high"].get(),
action_high_interval=float(interval_vars["action_high_interval"].get() or 1.0),
action_extreme_high=action_vars["action_extreme_high"].get() or None,
value_extreme_high=value_vars["value_extreme_high"].get(),
action_extreme_high_interval=float(interval_vars["action_extreme_high_interval"].get() or 1.0),
expr_dead_low=(expr_vars["expr_dead_low"].get().strip() or None),
expr_low=(expr_vars["expr_low"].get().strip() or None),
expr_operating=(expr_vars["expr_operating"].get().strip() or None),
expr_high=(expr_vars["expr_high"].get().strip() or None),
expr_extreme_high=(expr_vars["expr_extreme_high"].get().strip() or None),
expr_target_dead_low=(expr_target_vars["expr_target_dead_low"].get().strip() or None),
expr_target_low=(expr_target_vars["expr_target_low"].get().strip() or None),
expr_target_operating=(expr_target_vars["expr_target_operating"].get().strip() or None),
expr_target_high=(expr_target_vars["expr_target_high"].get().strip() or None),
expr_target_extreme_high=(expr_target_vars["expr_target_extreme_high"].get().strip() or None),
y_source=(y_source_var.get().strip() or None),
z_source=(z_source_var.get().strip() or None),
expr_x_source_dead_low = expr_xsrc_vars["expr_x_source_dead_low"].get(),
expr_x_source_low = expr_xsrc_vars["expr_x_source_low"].get(),
expr_x_source_operating = expr_xsrc_vars["expr_x_source_operating"].get(),
expr_x_source_high = expr_xsrc_vars["expr_x_source_high"].get(),
expr_x_source_extreme_high = expr_xsrc_vars["expr_x_source_extreme_high"].get(),
)
vi.thresholds = nt
# Re-enter current state to refresh scheduled actions/intervals
try:
cur_x = parse_first_float(vi.last_value)
self.on_state_change(vi, vi.last_state, vi.last_state, cur_x)
except Exception:
DBGEX("App.open_thresholds_dialog->do_save on_state_change")
pass
dlg.destroy()
self._reschedule_state_tasks_for(vi)
ttk.Button(btns, text="Save", command=do_save).pack(side=tk.RIGHT, padx=6)
ttk.Button(btns, text="Cancel", command=dlg.destroy).pack(side=tk.RIGHT)
def evaluate_thresholds(self, vi: VarInfo, value: str) -> None:
x = parse_first_float(value)
t = vi.thresholds
# Dynamic thresholds
stats_x = self.get_stats_for(vi.key)
stats_y = self.get_stats_for(getattr(t, "y_source", None))
stats_z = self.get_stats_for(getattr(t, "z_source", None))
thr_dead = t.dead_low
thr_low = t.low
thr_high = t.high
thr_ext = t.extreme_high
if t.expr_thr_dead_low:
v = eval_threshold_expr(t.expr_thr_dead_low, stats_x, stats_y, stats_z)
if v is not None: thr_dead = v
if t.expr_thr_low:
v = eval_threshold_expr(t.expr_thr_low, stats_x, stats_y, stats_z)
if v is not None: thr_low = v
if t.expr_thr_high:
v = eval_threshold_expr(t.expr_thr_high, stats_x, stats_y, stats_z)
if v is not None: thr_high = v
if t.expr_thr_extreme_high:
v = eval_threshold_expr(t.expr_thr_extreme_high, stats_x, stats_y, stats_z)
if v is not None: thr_ext = v
# Auto-defaults based on current value if thresholds are empty
cur = parse_first_float(vi.last_value)
auto_defaults = {}
if cur is not None:
auto_defaults = {
"dead_low": round(cur * 0.8, 6),
"low": round(cur * 0.9, 6),
"high": round(cur * 1.1, 6),
"extreme_high": round(cur * 1.2, 6),
}
prev = vi.last_state
state = "UNKNOWN"
no_thr = all(v is None for v in (thr_dead, thr_low, thr_high, thr_ext))
if x is None or no_thr:
state = "OPERATING"
else:
dl = thr_dead if thr_dead is not None else -float("inf")
lo = thr_low if thr_low is not None else -float("inf")
hi = thr_high if thr_high is not None else float("inf")
ex = thr_ext if thr_ext is not None else float("inf")
if x < dl:
state = "DEAD_LOW"
elif x < lo:
state = "LOW"
elif x < hi:
state = "OPERATING"
elif x < ex:
state = "HIGH"
else:
state = "EXTREME_HIGH"
if state != prev:
self.on_state_change(vi, prev, state, x)
vi.last_state = state
def on_state_change(self, vi: VarInfo, prev_state: str, new_state: str, x: Optional[float]) -> None:
# stop any repeating task associated with previous state
tid = self.state_tasks.pop((vi.key, prev_state), None)
if tid is not None:
try:
self.scheduler.remove_task(tid)
except Exception:
DBGEX("App.on_state_change remove_task")
pass
# stop any repeating expr task for previous state
etid = self.expr_state_tasks.pop((vi.key, prev_state), None)
if etid is not None:
try:
self.scheduler.remove_task(etid)
except Exception:
DBGEX("App.on_state_change remove_task expr")
pass
# then handle enter actions for new_state
self.on_enter_state(vi, new_state, x)
def on_enter_state(self, vi: VarInfo, state: str, x: Optional[float]) -> None:
t = vi.thresholds
# Auto-defaults based on current value if thresholds are empty
cur = parse_first_float(vi.last_value)
auto_defaults = {}
if cur is not None:
auto_defaults = {
"dead_low": round(cur * 0.8, 6),
"low": round(cur * 0.9, 6),
"high": round(cur * 1.1, 6),
"extreme_high": round(cur * 1.2, 6),
}
alarm_map = {
"DEAD_LOW": t.alarm_dead_low,
"LOW": t.alarm_low,
"OPERATING": False,
"HIGH": t.alarm_high,
"EXTREME_HIGH": t.alarm_extreme_high,
}
if alarm_map.get(state):
try:
import winsound
freq = {"DEAD_LOW": 350, "LOW": 550, "HIGH": 800, "EXTREME_HIGH": 1000}.get(state, 600)
dur = 400 if state in ("DEAD_LOW", "EXTREME_HIGH") else 300
winsound.Beep(freq, dur)
except Exception:
DBGEX("App.on_enter_state winsound.Beep")
try: self.bell()
except Exception: DBGEX("App.on_enter_state bell")
expr_key = {
"DEAD_LOW": "expr_dead_low", "LOW": "expr_low",
"HIGH": "expr_high", "EXTREME_HIGH": "expr_extreme_high"
}.get(state)
target_key = {
"DEAD_LOW": "expr_target_dead_low", "LOW": "expr_target_low",
"HIGH": "expr_target_high", "EXTREME_HIGH": "expr_target_extreme_high"
}.get(state)
expr = getattr(t, expr_key) if expr_key else None
target_func = getattr(t, target_key) if target_key else None
# Determine y/z current values (prefer explicit sources)
y_val = None; z_val = None
y_source = (t.y_source or '').strip() or None
z_source = (t.z_source or '').strip() or None
if not y_source:
if target_func:
y_source = target_func
else:
action_map = {"DEAD_LOW": t.action_dead_low, "LOW": t.action_low, "HIGH": t.action_high, "EXTREME_HIGH": t.action_extreme_high}
y_source = action_map.get(state)
for label, src_name in (('y', y_source), ('z', z_source)):
if not src_name: continue
key = src_name.lower()
val = None
if hasattr(self, 'latest_values') and key in self.latest_values:
val = parse_first_float(self.latest_values.get(key))
else:
base = build_base_url(self.host_var.get().strip(), int(self.port_var.get()))
st, bd, _h = http_get(base, {"variable": key})
if st == 200:
val = parse_first_float(bd)
if label == 'y': y_val = val
else: z_val = val
x_variants = self.get_stats_for(vi.key) or {}
mode_map = {
"DEAD_LOW": t.expr_x_source_dead_low,
"LOW": t.expr_x_source_low,
"OPERATING": t.expr_x_source_operating,
"HIGH": t.expr_x_source_high,
"EXTREME_HIGH": t.expr_x_source_extreme_high,
}
x_for_expr = {
"raw": x_variants.get("x"),
"x_avg": x_variants.get("x_avg"),
"dx": x_variants.get("dx"),
"dx_avg": x_variants.get("dx_avg"),
}.get(mode_map.get(state, "raw"), x_variants.get("x"))
if expr and x_for_expr is not None:
try:
computed = eval_user_expression(expr, x_for_expr, y_val, z_val)
if target_func:
base = build_base_url(self.host_var.get().strip(), int(self.port_var.get()))
params = {"variable": target_func, "value": str(computed)}
http_post_query(base, params)
else:
self.status_lbl.configure(text=f"Expr computed for {vi.display_name} [{state}], no target function set")
except Exception as e:
messagebox.showwarning("Expression error", f"{vi.display_name}: expression failed on enter {state}: {e}")
act_map = {
"DEAD_LOW": (t.action_dead_low, t.value_dead_low),
"LOW": (t.action_low, t.value_low),
"OPERATING": (t.action_operating, t.value_operating),
"HIGH": (t.action_high, t.value_high),
"EXTREME_HIGH": (t.action_extreme_high, t.value_extreme_high),
}
act, val = act_map.get(state, (None, "1"))
if act:
# Once on enter if interval == 0
interval_map = {
"DEAD_LOW": t.action_dead_low_interval,
"LOW": t.action_low_interval,
"OPERATING": t.action_operating_interval,
"HIGH": t.action_high_interval,
"EXTREME_HIGH": t.action_extreme_high_interval,
}
interval = float(interval_map.get(state, 0) or 0.0)
if interval <= 0.0:
self.scheduler.add_task(ActionTask(name=act, value=val, interval_s=0.0))
else:
tid = self.scheduler.add_task(ActionTask(name=act, value=val, interval_s=max(0.0, interval)))
self.state_tasks[(vi.key, state)] = tid
# Expression scheduling while in state
expr_key_map = {
"DEAD_LOW": ("expr_dead_low", "expr_target_dead_low"),
"LOW": ("expr_low", "expr_target_low"),
"OPERATING": ("expr_operating", "expr_target_operating"),
"HIGH": ("expr_high", "expr_target_high"),
"EXTREME_HIGH": ("expr_extreme_high", "expr_target_extreme_high"),
}
ekey, tkey = expr_key_map.get(state, (None, None))
expr_str = getattr(t, ekey) if ekey else None
expr_target = getattr(t, tkey) if tkey else None
if expr_str and expr_target:
# Use action intervals as default pacing for expressions
expr_interval = {
"DEAD_LOW": t.action_dead_low_interval,
"LOW": t.action_low_interval,
"OPERATING": t.action_operating_interval,
"HIGH": t.action_high_interval,
"EXTREME_HIGH": t.action_extreme_high_interval,
}.get(state, 1.0) or 1.0
if expr_interval <= 0.0:
# compute once on enter (already computed above in expressions block),
# but ensure it posts now via scheduler so behavior is consistent
task = ActionTask(name=expr_target, value="", interval_s=0.0, expr=expr_str,
x_src=vi.key, y_src=t.y_source, z_src=t.z_source)
self.scheduler.add_task(task)
else:
# schedule repeating expression task
task = ActionTask(
name=expr_target, value="", interval_s=max(0.0, float(expr_interval)),
expr=expr_str, x_src=vi.key, y_src=t.y_source, z_src=t.z_source,
x_mode=mode_map.get(state, "raw")
)
tid = self.scheduler.add_task(task)
self.expr_state_tasks[(vi.key, state)] = tid
# --- Tree helpers & rendering ---
def _ensure_group(self, group: str) -> str:
iid = self._group_ids.get(group)
if iid and self.tree.exists(iid):
return iid
iid = f"grp:{group}"
self._group_ids[group] = iid
if not self.tree.exists(iid):
self.tree.insert("", "end", iid=iid, text=group, values=("", "", ""), open=True)
return iid
def _ensure_var(self, group_iid: str, key: str, display_name: str) -> str:
iid = self._var_ids.get(key)
if iid and self.tree.exists(iid):
return iid
iid = f"var:{key}"
self._var_ids[key] = iid
if not self.tree.exists(iid):
self.tree.insert(group_iid, "end", iid=iid, text=display_name, values=("", "", ""))
return iid
def _get_color_tag(self, hex_color: str) -> str:
tag = self._color_tags.get(hex_color)
if tag:
return tag
tag = f"col_{hex_color[1:]}"
self._color_tags[hex_color] = tag
try:
self.tree.tag_configure(tag, background=hex_color)
except Exception:
DBGEX("App._get_color_tag")
pass
return tag
def _effective_thresholds(self, vi:"VarInfo") -> dict:
return self._compute_effective_thresholds(vi)
def _compute_effective_thresholds(self, vi: "VarInfo") -> dict[str, float | None]:
"""
Liczy progi efektywne: bierzemy liczby z konfiguracji + nadpisujemy je, jeśli
zdefiniowano formuły expr_thr_*. Zwracamy też 'mid'=(low+high)/2 jeżeli możliwe.
"""
DBGL(f"[_thr] key={vi.key} start")
t = vi.thresholds
stats_x = self.get_stats_for(vi.key)
stats_y = self.get_stats_for(getattr(t, "y_source", None))
stats_z = self.get_stats_for(getattr(t, "z_source", None))
def eff(num, expr):
if expr:
try:
DBGL(f"[_thr] expr {expr} for {vi.key} -> try")
v = eval_threshold_expr(expr, stats_x, stats_y, stats_z)
DBGL(f"[_thr] expr {expr} for {vi.key} -> {v}")
if v is not None:
return float(v)
except Exception:
DBGEX("eval_threshold_expr")
return float(num) if num is not None else None
dead = eff(getattr(t, "dead_low", None), getattr(t, "expr_thr_dead_low", None))
low = eff(getattr(t, "low", None), getattr(t, "expr_thr_low", None))
high = eff(getattr(t, "high", None), getattr(t, "expr_thr_high", None))
ext = eff(getattr(t, "extreme_high", None), getattr(t, "expr_thr_extreme_high", None))
mid = (low + high) / 2.0 if (low is not None and high is not None) else None
DBGL(f"[_thr] key={vi.key} done -> dead={dead} low={low} high={high} ext={ext} mid={mid}")
return {"dead_low": dead, "low": low, "high": high, "extreme": ext, "mid": mid}
def evaluate_thresholds(self, vi: VarInfo, value: str) -> None:
try:
x = parse_first_float(value)
thr = self._compute_effective_thresholds(vi)
dead, low, high, ext = thr["dead_low"], thr["low"], thr["high"], thr["extreme"]
prev = vi.last_state
state = "OPERATING"
if x is None:
state = "OPERATING"
else:
dl = dead if dead is not None else -float("inf")
lo = low if low is not None else -float("inf")
hi = high if high is not None else float("inf")
ex = ext if ext is not None else float("inf")
if x < dl:
state = "DEAD_LOW"
elif x < lo:
state = "LOW"
elif x < hi:
state = "OPERATING"
elif x < ex:
state = "HIGH"
else:
state = "EXTREME_HIGH"
if state != prev:
self.on_state_change(vi, prev, state, x)
vi.last_state = state
except Exception:
DBGEX("evaluate_thresholds")
def _state_color(self, vi, x_value=None) -> str:
"""Kolor tła w hex na bazie progów efektywnych; odporne na None."""
try:
thr = self._compute_effective_thresholds(vi)
thr_dead = thr["dead_low"]
thr_low = thr["low"]
thr_high = thr["high"]
thr_ext = thr["extreme"]
try:
x = float(x_value) if x_value is not None else parse_first_float(vi.last_value)
except Exception:
DBGEX("_state_color parse_first_float")
x = None
if x is None:
return "#E9ECEF" # brak danych
if thr_dead is None:
thr_dead = -float("inf")
if thr_low is None and thr_high is None:
thr_low, thr_high = x - 1e-6, x + 1e-6
if thr_low is None:
thr_low = thr_dead if thr_dead != -float("inf") else (x - 1e-6)
if thr_high is None:
thr_high = max(thr_low, x + 1e-6)
if thr_ext is None:
thr_ext = float("inf")
def _hex(c): return "#{:02X}{:02X}{:02X}".format(*c)
def _lerp(c1, c2, t):
t = 0.0 if t < 0 else 1.0 if t > 1 else t
return (
int(c1[0] + (c2[0]-c1[0])*t),
int(c1[1] + (c2[1]-c1[1])*t),
int(c1[2] + (c2[2]-c1[2])*t),
)
Y_LO, Y_HI = (255, 244, 178), (255, 149, 0)
G_OK = (46, 204, 113)
R_LO, R_HI = (255, 138, 128), (213, 0, 0)
if x <= thr_low:
denom = (thr_low - thr_dead) if (thr_low > thr_dead) else 1.0
t = (thr_low - x) / max(denom, 1e-9)
return _hex(_lerp(Y_LO, Y_HI, t))
if x <= thr_high:
return _hex(G_OK)
denom = (thr_ext - thr_high) if (thr_ext > thr_high) else 1.0
t = (x - thr_high) / max(denom, 1e-9)
return _hex(_lerp(R_LO, R_HI, t))
except Exception:
DBGEX("_state_color")
return "#E9ECEF"
def refresh_tree(self) -> None:
filt = self.filter_var.get().strip().lower()
groups: Dict[str, List[VarInfo]] = {}
for key, vi in self.vars.items():
text = vi.display_name
if filt and filt not in text.lower() and (not vi.last_value or filt not in vi.last_value.lower()):
continue
prefix = text.split("_", 1)[0] if "_" in text else "MISC"
groups.setdefault(prefix, []).append(vi)
sel = self.tree.selection()
sel_iid = sel[0] if sel else None
valid_var_iids = set()
valid_group_iids = set()
for g in sorted(groups.keys(), key=lambda s: s.lower()):
gid = self._ensure_group(g)
valid_group_iids.add(gid)
for vi in sorted(groups[g], key=lambda x: x.display_name.lower()):
vid = self._ensure_var(gid, vi.key, vi.display_name)
valid_var_iids.add(vid)
updated_str = "—"
if vi.last_updated:
updated_str = datetime.fromtimestamp(vi.last_updated).strftime("%H:%M:%S")
if vi.error:
value_preview = f"[ERR] {vi.error}"
else:
value_preview = coerce_preview(vi.last_value, 120)
# Δ last
delta_str = "N/A"
if vi.delta_last is not None:
try:
delta_str = f"{vi.delta_last:+.6g}"
except Exception:
DBGEX("_state_color delta_last")
delta_str = str(vi.delta_last)
# Δ avg(N)
davg_str = "N/A"
try:
n = max(1, int(self.avg_window_var.get()))
except Exception:
n = AVERAGE_WINDOW_N
if hasattr(vi, "history_delta") and vi.history_delta:
dvals = list(vi.history_delta)[-n:]
if len(dvals) >= n:
try:
davg_val = sum(dvals) / float(n)
davg_str = f"{davg_val:.6g}"
except Exception:
DBGEX("_state_color davg_last")
davg_str = "N/A"
# value avg(N)
avg_str = "N/A"
if hasattr(vi, "history") and vi.history:
vals = list(vi.history)[-n:]
if len(vals) >= n:
try:
avg_val = sum(vals) / float(n)
avg_str = f"{avg_val:.6g}"
except Exception:
DBGEX("_state_color avg_last")
avg_str = "N/A"
x = parse_first_float(vi.last_value)
color = self._state_color(vi, x)
tag = self._get_color_tag(color)
self.tree.item(vid, text=vi.display_name, values=(value_preview, delta_str, davg_str, avg_str, updated_str, vi.last_status or "—"), tags=(tag,))
for key, vid in list(self._var_ids.items()):
if vid not in valid_var_iids and self.tree.exists(vid):
self.tree.delete(vid); self._var_ids.pop(key, None)
for g, gid in list(self._group_ids.items()):
if gid not in valid_group_iids and self.tree.exists(gid):
self.tree.delete(gid); self._group_ids.pop(g, None)
if sel_iid and self.tree.exists(sel_iid):
self.tree.selection_set(sel_iid)
def _attach_search_filter_to_combobox(self, combo: ttk.Combobox, source: List[str] | None):
if source is None:
source = []
original = list(source)
combo.configure(state="normal") # allow typing to filter
def on_key(_event=None):
text = combo.get()
vals = [v for v in original if text.lower() in v.lower()]
combo["values"] = vals if vals else original
combo.bind("<KeyRelease>", on_key)
def _watch_refresh_interval(self):
try:
val = float(self.refresh_var.get())
except Exception:
DBGEX("_watch_refresh_interval parse float")
val = self._last_refresh_val
if val != self._last_refresh_val:
self._last_refresh_val = val
if self.poller and self.poller.is_alive():
try:
self.poller.refresh_interval = max(0.1, val)
self.status_lbl.configure(text=f"Running… (refresh {self.poller.refresh_interval}s)")
except Exception:
DBGEX("_watch_refresh_interval set refresh_interval")
pass
self.after(2000, self._watch_refresh_interval)
def menu_run_once_dialog(self):
top = tk.Toplevel(self); top.title("Run Function Once"); top.geometry("420x180"); top.transient(self); top.grab_set()
ttk.Label(top, text="Function:").pack(pady=(10,2))
name = tk.StringVar(value=(self.functions_list[0] if self.functions_list else ""))
cmb = ttk.Combobox(top, values=self.functions_list, textvariable=name, width=44)
self._attach_search_filter_to_combobox(cmb, self.functions_list)
cmb.pack()
ttk.Label(top, text="Value:").pack(pady=(6,2))
val = tk.StringVar(value="1")
ttk.Entry(top, textvariable=val, width=16).pack()
def go():
fname = name.get().strip()
if not fname: return
status, body, _ = self.scheduler.run_once(fname, val.get())
messagebox.showinfo("Run Once", f"POST ?variable={fname}&value={val.get()}\nHTTP {status}\n{coerce_preview(body, 300)}")
top.destroy()
ttk.Button(top, text="Run", command=go).pack(pady=10)
def menu_schedule_dialog(self):
top = tk.Toplevel(self); top.title("Add Scheduled Function"); top.geometry("520x360"); top.transient(self); top.grab_set()
ttk.Label(top, text="Function:").pack(pady=(10,2))
name = tk.StringVar(value=(self.functions_list[0] if self.functions_list else ""))
cmb = ttk.Combobox(top, values=self.functions_list, textvariable=name, width=44)
self._attach_search_filter_to_combobox(cmb, self.functions_list)
cmb.pack()
# Mode: Fixed vs Expression
mode = tk.StringVar(value="expr")
frm = ttk.Frame(top); frm.pack(pady=(8,2))
ttk.Radiobutton(frm, text="Fixed value", variable=mode, value="fixed").pack(side=tk.LEFT, padx=6)
ttk.Radiobutton(frm, text="Expression", variable=mode, value="expr").pack(side=tk.LEFT, padx=6)
# Fixed value input
val = tk.StringVar(value="1")
fixed_row = ttk.Frame(top); fixed_row.pack(fill=tk.X, padx=10, pady=(4,2))
ttk.Label(fixed_row, text="Value:").pack(side=tk.LEFT)
val_entry = ttk.Entry(fixed_row, textvariable=val, width=16)
val_entry.pack(side=tk.LEFT, padx=6)
# Expression + sources
expr = tk.StringVar(value="x")
expr_row = ttk.Frame(top); expr_row.pack(fill=tk.X, padx=10, pady=(4,2))
ttk.Label(expr_row, text="Expression (x,y,z):").pack(side=tk.LEFT)
expr_entry = ttk.Entry(expr_row, textvariable=expr, width=46)
expr_entry.pack(side=tk.LEFT, padx=6)
# Sources row
src_row = ttk.Frame(top); src_row.pack(fill=tk.X, padx=10, pady=(4,2))
ttk.Label(src_row, text="x:").pack(side=tk.LEFT)
x_src = tk.StringVar(value="")
x_combo = ttk.Combobox(src_row, values=self.known_variables, textvariable=x_src, width=18)
self._attach_search_filter_to_combobox(x_combo, self.known_variables)
x_combo.pack(side=tk.LEFT, padx=4)
ttk.Label(src_row, text="y:").pack(side=tk.LEFT)
y_src = tk.StringVar(value="")
y_combo = ttk.Combobox(src_row, values=self.known_variables, textvariable=y_src, width=18)
self._attach_search_filter_to_combobox(y_combo, self.known_variables)
y_combo.pack(side=tk.LEFT, padx=4)
ttk.Label(src_row, text="z:").pack(side=tk.LEFT)
z_src = tk.StringVar(value="")
z_combo = ttk.Combobox(src_row, values=self.known_variables, textvariable=z_src, width=18)
self._attach_search_filter_to_combobox(z_combo, self.known_variables)
z_combo.pack(side=tk.LEFT, padx=4)
xmode_row = ttk.Frame(top); xmode_row.pack(fill=tk.X, padx=10, pady=(4,2))
ttk.Label(xmode_row, text="x from:").pack(side=tk.LEFT)
x_mode = tk.StringVar(value="raw")
xmode_combo = ttk.Combobox(xmode_row, values=["raw", "x_avg", "dx", "dx_avg"], textvariable=x_mode, width=10)
xmode_combo.pack(side=tk.LEFT, padx=6)
# Interval input
ttk.Label(top, text="Interval (seconds, can be < 1.0):").pack(pady=(6,2))
interval = tk.DoubleVar(value=1.0)
ttk.Entry(top, textvariable=interval, width=12).pack()
def update_mode(*_):
if mode.get() == "fixed":
val_entry.configure(state="normal")
expr_entry.configure(state="disabled")
x_combo.configure(state="disabled"); y_combo.configure(state="disabled"); z_combo.configure(state="disabled")
else:
val_entry.configure(state="disabled")
expr_entry.configure(state="normal")
x_combo.configure(state="normal"); y_combo.configure(state="normal"); z_combo.configure(state="normal")
mode.trace_add("write", update_mode); update_mode()
def go():
fname = name.get().strip()
if not fname: return
if mode.get() == "fixed":
task = ActionTask(name=fname, value=val.get(), interval_s=max(0.0, float(interval.get())))
else:
task = ActionTask(
name=fname, value="", interval_s=max(0.0, float(interval.get())),
expr=expr.get().strip() or "x",
x_src=(x_src.get().strip() or None), y_src=(y_src.get().strip() or None), z_src=(z_src.get().strip() or None),
x_mode=x_mode.get()
)
tid = self.scheduler.add_task(task)
self.refresh_actions_tree()
top.destroy()
ttk.Button(top, text="Add", command=go).pack(pady=10)
def save_config(self):
try:
from tkinter import filedialog
cfg = {
"host": self.host_var.get(),
"port": int(self.port_var.get()),
"refresh_interval": float(self.refresh_var.get()),
"variables_keys": self.variables_keys,
"vars": {k: self._serialize_varinfo(v) for k,v in self.vars.items() if k in self.variables_keys},
"scheduled_tasks": [self._serialize_task(t) for t in self.scheduler.list_tasks()],
}
cfg["display_defaults"] = {
"backend": self.display_backend_var.get(),
"samples": int(self.default_samples_var.get()),
"max_draw_pts": int(self.default_maxpts_var.get()),
"show_thresholds": bool(self.display_show_thresholds_var.get()),
}
path = filedialog.asksaveasfilename(defaultextension=".json", filetypes=[("JSON","*.json")], title="Save Configuration")
if not path: return
import json
with open(path, "w", encoding="utf-8") as f:
json.dump(cfg, f, indent=2)
messagebox.showinfo("Saved", f"Configuration saved to:\n{path}")
except Exception as e:
messagebox.showerror("Save failed", str(e))
def load_config(self):
try:
from tkinter import filedialog
path = filedialog.askopenfilename(filetypes=[("JSON","*.json")], title="Load Configuration")
if not path: return
import json
with open(path, "r", encoding="utf-8") as f:
cfg = json.load(f)
self.host_var.set(cfg.get("host", self.host_var.get()))
self.port_var.set(cfg.get("port", self.port_var.get()))
self.refresh_var.set(cfg.get("refresh_interval", self.refresh_var.get()))
keys = cfg.get("variables_keys", [])
self.variables_keys = [k.lower() for k in keys]
new_vars = {}
for k, data in (cfg.get("vars") or {}).items():
vi = self._deserialize_varinfo(k, data)
new_vars[k.lower()] = vi
self.vars = new_vars
dd = cfg.get("display_defaults", {})
try:
self.display_backend_var.set(dd.get("backend", "matplotlib"))
except Exception:
DBGEX("load_config display_backend_var")
pass
try:
self.default_samples_var.set(int(dd.get("samples", 200)))
except Exception:
DBGEX("load_config default_samples_var")
pass
try:
self.default_maxpts_var.set(int(dd.get("max_draw_pts", 400)))
except Exception:
DBGEX("load_config default_maxpts_var")
pass
try:
self.display_show_thresholds_var.set(bool(dd.get("show_thresholds", True)))
except Exception:
DBGEX("load_config display_show_thresholds_var")
pass
# replace scheduled tasks
for t in [t.task_id for t in self.scheduler.list_tasks()]:
self.scheduler.remove_task(t)
for td in cfg.get("scheduled_tasks", []):
self.scheduler.add_task(self._deserialize_task(td))
if self.poller and self.poller.is_alive():
self.poller.variables_keys = self.variables_keys[:]
self.refresh_tree()
self.refresh_actions_tree()
messagebox.showinfo("Loaded", f"Configuration loaded from:\n{path}")
except Exception as e:
messagebox.showerror("Load failed", str(e))
def _serialize_varinfo(self, vi: VarInfo):
t = vi.thresholds
return {
"display_name": vi.display_name,
"thresholds": {
"dead_low": t.dead_low, "low": t.low, "high": t.high, "extreme_high": t.extreme_high,
"alarm_dead_low": t.alarm_dead_low, "alarm_low": t.alarm_low, "alarm_high": t.alarm_high, "alarm_extreme_high": t.alarm_extreme_high,
"action_dead_low": t.action_dead_low, "value_dead_low": t.value_dead_low, "action_dead_low_interval": t.action_dead_low_interval,
"action_low": t.action_low, "value_low": t.value_low, "action_low_interval": t.action_low_interval,
"action_high": t.action_high, "value_high": t.value_high, "action_high_interval": t.action_high_interval,
"action_extreme_high": t.action_extreme_high, "value_extreme_high": t.value_extreme_high, "action_extreme_high_interval": t.action_extreme_high_interval,
"action_operating": t.action_operating, "value_operating": t.value_operating, "action_operating_interval": t.action_operating_interval,
"expr_dead_low": t.expr_dead_low, "expr_low": t.expr_low, "expr_operating": t.expr_operating, "expr_high": t.expr_high, "expr_extreme_high": t.expr_extreme_high,
"expr_target_dead_low": t.expr_target_dead_low, "expr_target_low": t.expr_target_low, "expr_target_operating": t.expr_target_operating, "expr_target_high": t.expr_target_high, "expr_target_extreme_high": t.expr_target_extreme_high,
# nowości:
"expr_operating_interval": getattr(t, "expr_operating_interval", 1.0),
"y_source": getattr(t, "y_source", None),
"z_source": getattr(t, "z_source", None),
"expr_x_source_dead_low": t.expr_x_source_dead_low,
"expr_x_source_low": t.expr_x_source_low,
"expr_x_source_operating": t.expr_x_source_operating,
"expr_x_source_high": t.expr_x_source_high,
"expr_x_source_extreme_high": t.expr_x_source_extreme_high,
"expr_thr_dead_low": t.expr_thr_dead_low,
"expr_thr_low": t.expr_thr_low,
"expr_thr_high": t.expr_thr_high,
"expr_thr_extreme_high": t.expr_thr_extreme_high,
},
}
def _deserialize_varinfo(self, key: str, data: dict) -> VarInfo:
name = data.get("display_name", key)
td = (data or {}).get("thresholds", {}) or {}
t = Thresholds(
dead_low=td.get("dead_low"), low=td.get("low"), high=td.get("high"), extreme_high=td.get("extreme_high"),
alarm_dead_low=bool(td.get("alarm_dead_low", True)), alarm_low=bool(td.get("alarm_low", False)),
alarm_high=bool(td.get("alarm_high", False)), alarm_extreme_high=bool(td.get("alarm_extreme_high", True)),
action_dead_low=td.get("action_dead_low"), value_dead_low=str(td.get("value_dead_low", "1")), action_dead_low_interval=float(td.get("action_dead_low_interval", 1.0)),
action_low=td.get("action_low"), value_low=str(td.get("value_low", "1")), action_low_interval=float(td.get("action_low_interval", 1.0)),
action_high=td.get("action_high"), value_high=str(td.get("value_high", "1")), action_high_interval=float(td.get("action_high_interval", 1.0)),
action_extreme_high=td.get("action_extreme_high"), value_extreme_high=str(td.get("value_extreme_high", "1")), action_extreme_high_interval=float(td.get("action_extreme_high_interval", 1.0)),
action_operating=td.get("action_operating"), value_operating=str(td.get("value_operating", "1")), action_operating_interval=float(td.get("action_operating_interval", 1.0)),
expr_dead_low=td.get("expr_dead_low"), expr_low=td.get("expr_low"), expr_operating=td.get("expr_operating"),
expr_high=td.get("expr_high"), expr_extreme_high=td.get("expr_extreme_high"),
expr_target_dead_low=td.get("expr_target_dead_low"), expr_target_low=td.get("expr_target_low"),
expr_target_operating=td.get("expr_target_operating"), expr_target_high=td.get("expr_target_high"), expr_target_extreme_high=td.get("expr_target_extreme_high"),
# nowości (wstecznie opcjonalne):
expr_operating_interval=float(td.get("expr_operating_interval", 1.0)),
y_source=td.get("y_source"), z_source=td.get("z_source"),
expr_x_source_dead_low=td.get("expr_x_source_dead_low","raw"),
expr_x_source_low=td.get("expr_x_source_low","raw"),
expr_x_source_operating=td.get("expr_x_source_operating","raw"),
expr_x_source_high=td.get("expr_x_source_high","raw"),
expr_x_source_extreme_high=td.get("expr_x_source_extreme_high","raw"),
expr_thr_dead_low=td.get("expr_thr_dead_low"),
expr_thr_low=td.get("expr_thr_low"),
expr_thr_high=td.get("expr_thr_high"),
expr_thr_extreme_high=td.get("expr_thr_extreme_high"),
)
return VarInfo(key=key.lower(), display_name=name, thresholds=t)
def _serialize_task(self, t: ActionTask):
return {"name": t.name, "value": t.value, "interval_s": t.interval_s, "enabled": t.enabled,
"expr": t.expr, "x_src": t.x_src, "y_src": t.y_src, "z_src": t.z_src, "x_mode": getattr(t, "x_mode", "raw")}
def _deserialize_task(self, d: dict) -> ActionTask:
return ActionTask(name=d.get("name",""), value=d.get("value","1"),
interval_s=float(d.get("interval_s", 1.0)), enabled=d.get("enabled", True),
expr=d.get("expr"), x_src=d.get("x_src"), y_src=d.get("y_src"), z_src=d.get("z_src"),
x_mode=d.get("x_mode","raw"))
def on_close(self) -> None:
# zatrzymaj Pollera
self._closing = True
# zatrzymaj okna/timery Qt (jeśli są)
try:
for _k, tup in list(getattr(self, "_qt_windows", {}).items()):
try:
win, timer = tup
except Exception:
DBGEX("on_close get timer")
continue
try:
timer.stop(); timer.deleteLater()
except Exception:
DBGEX("on_close stop timer")
pass
try:
win.close()
except Exception:
DBGEX("on_close close win")
pass
self._qt_windows.clear()
except Exception:
DBGEX("on_close clear windows")
pass
try:
if getattr(self, "poller", None) and self.poller.is_alive():
self.stop_event.set() # natychmiast przerwie wait() w pętli
self.paused_event.clear()
self.poller.join(timeout=1.5)
except Exception:
DBGEX("on_close poller")
pass
# zatrzymaj scheduler
try:
if getattr(self, "scheduler", None) and self.scheduler.is_alive():
self.scheduler.stop() # ustawia wewnętrzny _stop Event
self.scheduler.join(timeout=1.5)
except Exception:
DBGEX("on_close scheduler")
pass
# zatrzymaj timer do plotów, jeśli działa
try:
if getattr(self, "_plot_timer", None):
self.after_cancel(self._plot_timer)
except Exception:
DBGEX("on_close plot_timer")
pass
# zamknij okna wykresów
try:
for win in list(self._plot_windows.values()):
try:
win.destroy()
except Exception:
DBGEX("on_close destroy plot win")
pass
except Exception:
DBGEX("on_close plot_windows")
pass
self.destroy()
# --- [DROP-IN] otwieranie okna Canvas (lite) --------------------------------
def _open_canvas_window(self, key: str):
vi = self.vars[key]
win = tk.Toplevel(self)
win.title(f"{vi.display_name} — plot")
win.geometry("740x360")
win._key = key
win._backend = "canvas"
tools = ttk.Frame(win); tools.pack(side=tk.TOP, fill=tk.X)
win._show_thr_var = tk.BooleanVar(value=bool(self.display_show_thresholds_var.get()))
ttk.Checkbutton(tools, text="Show thresholds", variable=win._show_thr_var).pack(side=tk.LEFT, padx=(8,6))
ttk.Label(tools, text="Samples:").pack(side=tk.LEFT, padx=(8,2))
win._sample_len_var = tk.IntVar(value=int(self.default_samples_var.get()))
ttk.Spinbox(tools, from_=20, to=5000, increment=10,
textvariable=win._sample_len_var, width=6).pack(side=tk.LEFT)
ttk.Label(tools, text="Max draw pts:").pack(side=tk.LEFT, padx=(10,2))
win._max_draw_var = tk.IntVar(value=int(self.default_maxpts_var.get()))
ttk.Spinbox(tools, from_=100, to=5000, increment=50,
textvariable=win._max_draw_var, width=6).pack(side=tk.LEFT)
cv = tk.Canvas(win, background="white", highlightthickness=0)
cv.pack(fill=tk.BOTH, expand=True)
win._tk_canvas = cv
# id narysowanych elementów (żeby kasować przy nast. klatce)
win._cv_ids = []
win._last_seen_ver = -1
if not hasattr(self, "_plot_windows"):
self._plot_windows = {}
self._plot_windows[key] = win
self._ensure_plot_timer()
# --- [DROP-IN] aktualizacja Canvas (lite) -----------------------------------
def _plot_update_canvas(self, win, xs_v, vals_draw, xs_b, dels_draw, thr: dict):
try:
cv = win._tk_canvas
for iid in getattr(win, "_cv_ids", []):
try: cv.delete(iid)
except Exception: DBGEX("_plot_update_canvas delete iid")
win._cv_ids = []
W = max(10, cv.winfo_width())
H = max(10, cv.winfo_height())
H1 = int(H*0.6)
H2 = H - H1
# mapowanie Y (górny wykres)
if vals_draw:
vmin, vmax = min(vals_draw), max(vals_draw)
if vmax == vmin:
vmax = vmin + 1.0
def y1(v): return int((1.0 - (v - vmin)/(vmax - vmin)) * (H1-20)) + 10
def x(i): return int((i / max(1, len(vals_draw)-1)) * (W-20)) + 10
# polyline
pts = []
for i, v in enumerate(vals_draw):
pts.append(x(i)); pts.append(y1(v))
if len(pts) >= 4:
win._cv_ids.append(cv.create_line(*pts, width=2))
# progi
if bool(getattr(win, "_show_thr_var", self.display_show_thresholds_var).get()):
def within(y): return y is not None and (vmin <= y <= vmax)
colors = {
"dead_low": "#FBC02D", "low": "#FFF59D", "mid": "#2ECC71",
"high": "#FF8A80", "extreme": "#D50000",
}
for name in ("dead_low","low","mid","high","extreme"):
y = thr.get(name)
if within(y):
Y = y1(y)
win._cv_ids.append(cv.create_line(10, Y, W-10, Y, dash=(4,3), fill=colors[name]))
# wskaźnik najbliższego progu
cur = vals_draw[-1]
cands = [(k, thr.get(k)) for k in ("dead_low","low","mid","high","extreme") if thr.get(k) is not None]
if cands:
k_best, y_best = min(cands, key=lambda kv: abs(kv[1]-cur))
up = (y_best > cur)
char = "▲" if up else "▼"
col = {"dead_low": "#FBC02D","low": "#FFF59D","mid": "#2ECC71","high":"#FF8A80","extreme":"#D50000"}[k_best]
win._cv_ids.append(cv.create_text(18, 8, text=char, fill=col, anchor="nw"))
# dolny wykres (Δ) jako słupki
if dels_draw:
dmin, dmax = min(dels_draw), max(dels_draw)
if dmax == dmin:
dmax = dmin + 1.0
def y2(v): return H1 + 10 + int((1.0 - (v - dmin)/(dmax - dmin)) * (H2-20))
def x2(i): return int((i / max(1, len(dels_draw)-1)) * (W-20)) + 10
bw = max(1, int((W-20) / max(1, len(dels_draw))))
for i, v in enumerate(dels_draw):
X = x2(i)
Y = y2(v)
win._cv_ids.append(cv.create_rectangle(X, Y, X+bw, H-10, width=0))
# wskaźnik tylko strzałka (kolor jak wyżej), rysowana nad osią
# (prosto: nie liczymy „najbliższego” drugi raz to kosmetyka)
except Exception:
DBGEX("_plot_update_canvas")
# --- [DROP-IN] otwieranie okna PyQtGraph (bez QTimer) -----------------------
def _open_pyqtgraph_window(self, key: str):
if not _pyqtgraph_available:
tk.messagebox.showwarning("PyQtGraph", "PyQtGraph nie jest dostępny.")
return
vi = self.vars[key]
if not vi:
tk.messagebox.showerror("Plot", f'Zmienna "{key}" nie jest monitorowana')
return
self._qt_ensure_app()
app = getattr(self, "_qt_app", None) or QtWidgets.QApplication.instance()
if app is None:
tk.messagebox.showerror("PyQtGraph", "Brak QApplication pyqtgraph nie może wystartować.")
return
# Qt window
glw = pg.GraphicsLayoutWidget(show=True, title=f"{vi.display_name} — plot")
glw.resize(780, 480)
glw.setWindowTitle(f"{vi.display_name} — plot")
p1 = glw.addPlot(row=0, col=0)
p2 = glw.addPlot(row=1, col=0)
p2.setXLink(p1)
p1.showGrid(x=True, y=True, alpha=0.2)
p2.showGrid(x=True, y=True, alpha=0.2)
curve = p1.plot([], [], pen=None) # ustawimy pen później przez setData
# BarGraphItem dla delt
bars = None
bars_x = []
bars_w = 1.0
# Linie progów (InfiniteLine)
thr_lines = {
"dead_low": pg.InfiniteLine(angle=0, pen=pg.mkPen("#FBC02D", width=2, style=QtCore.Qt.DashLine)),
"low": pg.InfiniteLine(angle=0, pen=pg.mkPen("#FFF59D", width=2, style=QtCore.Qt.DashLine)),
"mid": pg.InfiniteLine(angle=0, pen=pg.mkPen("#2ECC71", width=1, style=QtCore.Qt.DotLine)),
"high": pg.InfiniteLine(angle=0, pen=pg.mkPen("#FF8A80", width=2, style=QtCore.Qt.DashLine)),
"extreme": pg.InfiniteLine(angle=0, pen=pg.mkPen("#D50000", width=2, style=QtCore.Qt.DashLine)),
}
for ln in thr_lines.values():
ln.setVisible(False); p1.addItem(ln)
# Wskaźnik najbliższego progu: TextItem po lewej
tri_val = pg.TextItem("", anchor=(0,0))
tri_delta = pg.TextItem("", anchor=(0,1))
tri_val.setColor("#2ECC71"); tri_delta.setColor("#2ECC71")
tri_val.setVisible(False); tri_delta.setVisible(False)
p1.addItem(tri_val); p2.addItem(tri_delta)
# wrapper (bez Tk toplevel tylko referencje i ustawienia)
class _QtHandle:
pass
win = _QtHandle()
win._backend = "pyqtgraph"
win._key = key
win._qt_widget = glw
win._p1 = p1; win._p2 = p2
win._curve = curve
win._bars = bars
win._bars_x = bars_x
win._bars_w = bars_w
win._thr_lines = thr_lines
win._tri_val = tri_val
win._tri_delta = tri_delta
win._sample_len_var = tk.IntVar(value=int(self.default_samples_var.get()))
win._max_draw_var = tk.IntVar(value=int(self.default_maxpts_var.get()))
win._show_thr_var = tk.BooleanVar(value=bool(self.display_show_thresholds_var.get()))
win._last_seen_ver = -1
win._last_title = None
if not hasattr(self, "_plot_windows"):
self._plot_windows = {}
self._plot_windows[key] = win
self._ensure_qt_pump() # włącz pompowanie zdarzeń Qt w pętli Tk
self._ensure_plot_timer()
# --- [DROP-IN] aktualizacja PyQtGraph ---------------------------------------
def _plot_update_pyqtgraph(self, win, xs_v, vals_draw, xs_b, dels_draw, thr: dict):
try:
w = getattr(win, "_qt_widget", None)
if w is None or not hasattr(w, "isVisible") or not w.isVisible():
return
p1 = win._p1; p2 = win._p2
# krzywa wartości
if vals_draw:
if win._curve.opts["pen"] is None:
win._curve.setPen(pg.mkPen(width=2))
win._curve.setData(xs_v, vals_draw)
p1.setXRange(0, max(1, (xs_v[-1] if xs_v else 1)), padding=0.02)
vmin, vmax = min(vals_draw), max(vals_draw)
vmin, vmax = min(vals_draw), max(vals_draw)
span = (vmax - vmin) or 1.0
p1.setYRange(vmin - 0.03*span, vmax + 0.03*span, padding=0.1)
# --- delty (słupki) ---
if dels_draw:
dmin, dmax = min(dels_draw), max(dels_draw)
dspan = (dmax - dmin) or 1.0
p2.setYRange(dmin - 0.03*dspan, dmax + 0.03*dspan, padding=0.0)
# len(dels_draw) == len(xs_b)
if win._bars is None:
# pierwszy raz twórz BarGraphItem
# (barWidth będzie aktualizowany przy zmianie rozdzielczości)
win._bars = pg.BarGraphItem(x=xs_b, height=dels_draw, width=1.0)
p2.addItem(win._bars)
else:
win._bars.setOpts(x=xs_b, height=dels_draw)
# aktualizuj szerokość słupków
n = max(1, len(xs_b))
win._bars_w = max(1.0, float(len(xs_b)) / n) # symboliczne pyqtgraph skaluje z X
try:
win._bars.setOpts(width=1.0) # stała, bo mamy indeksy jako X
except Exception:
DBGEX("_plot_update_pyqtgraph set bar width")
# --- progi + wskaźnik ---
for ln in win._thr_lines.values():
ln.setVisible(False)
win._tri_val.setVisible(False); win._tri_delta.setVisible(False)
if bool(getattr(win, "_show_thr_var", self.display_show_thresholds_var).get()) and vals_draw:
# linie pokaż tylko, jeśli są w zakresie Y aktualnego widoku
vmin, vmax = p1.viewRange()[1]
def within(y): return (y is not None) and (vmin <= y <= vmax)
for name in ("dead_low","low","mid","high","extreme"):
y = thr.get(name)
if within(y):
ln = win._thr_lines[name]
ln.setValue(float(y))
ln.setVisible(True)
# wskaźnik najbliższego progu
cur = vals_draw[-1]
cands = [(k, thr.get(k)) for k in ("dead_low","low","mid","high","extreme") if thr.get(k) is not None]
if cands:
k_best, y_best = min(cands, key=lambda kv: abs(kv[1]-cur))
up = (y_best > cur)
char = "▲" if up else "▼"
col = {"dead_low":"#FBC02D","low":"#FFF59D","mid":"#2ECC71","high":"#FF8A80","extreme":"#D50000"}[k_best]
win._tri_val.setText(char); win._tri_val.setColor(col); win._tri_val.setVisible(True)
win._tri_delta.setText(char); win._tri_delta.setColor(col); win._tri_delta.setVisible(True)
try:
x0 = p1.viewRange()[0][0]
y0 = p1.viewRange()[1][0]
y1 = p2.viewRange()[1][1]
win._tri_val.setPos(x0, y0)
win._tri_delta.setPos(x0, y1)
except Exception:
DBGEX("_plot_update_pyqtgraph set tri pos")
except Exception:
DBGEX("_plot_update_pyqtgraph")
# --- [DROP-IN] otwieranie okna Matplotlib -----------------------------------
def _open_matplotlib_window(self, key: str):
import matplotlib
matplotlib.use("Agg")
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
from matplotlib.figure import Figure
vi = self.vars[key]
win = tk.Toplevel(self)
win.title(f"{vi.display_name} — plot")
win.geometry("760x420")
win._key = key
win._backend = "matplotlib"
tools = ttk.Frame(win); tools.pack(side=tk.TOP, fill=tk.X)
win._show_thr_var = tk.BooleanVar(value=bool(self.display_show_thresholds_var.get()))
ttk.Checkbutton(tools, text="Show thresholds", variable=win._show_thr_var).pack(side=tk.LEFT, padx=(8,6))
ttk.Label(tools, text="Samples:").pack(side=tk.LEFT, padx=(8,2))
win._sample_len_var = tk.IntVar(value=int(self.default_samples_var.get()))
ttk.Spinbox(tools, from_=20, to=5000, increment=10,
textvariable=win._sample_len_var, width=6).pack(side=tk.LEFT)
ttk.Label(tools, text="Max draw pts:").pack(side=tk.LEFT, padx=(10,2))
win._max_draw_var = tk.IntVar(value=int(self.default_maxpts_var.get()))
sp = ttk.Spinbox(tools, from_=100, to=5000, increment=50,
textvariable=win._max_draw_var, width=6)
sp.pack(side=tk.LEFT)
win._max_draw_pts = int(win._max_draw_var.get())
sp.configure(command=lambda w=win: setattr(w, "_max_draw_pts", int(w._max_draw_var.get())))
fig = Figure(figsize=(8,4), dpi=100)
ax_val = fig.add_subplot(2,1,1)
ax_delta = fig.add_subplot(2,1,2, sharex=ax_val)
ax_val.set_ylabel("value"); ax_delta.set_ylabel("Δ"); ax_delta.set_xlabel("samples")
# linie progów
win._thr_lines = {
"dead_low": ax_val.axhline(0, color="#FBC02D", linewidth=1.2, linestyle="--", visible=False),
"low": ax_val.axhline(0, color="#FFF59D", linewidth=1.2, linestyle="--", visible=False),
"mid": ax_val.axhline(0, color="#2ECC71", linewidth=1.0, linestyle=":", visible=False),
"high": ax_val.axhline(0, color="#FF8A80", linewidth=1.2, linestyle="--", visible=False),
"extreme": ax_val.axhline(0, color="#D50000", linewidth=1.2, linestyle="--", visible=False),
}
canvas = FigureCanvasTkAgg(fig, master=win)
canvas.draw(); canvas.get_tk_widget().pack(fill=tk.BOTH, expand=True)
# wskaźniki (trójkąty)
win._tri_val = ax_val.text(-0.03, -0.10, "▲", transform=ax_val.transAxes,
ha="left", va="top", color="#2ECC71", fontsize=12,
clip_on=False, visible=False)
win._tri_delta = ax_delta.text(-0.03, 1.10, "▲", transform=ax_delta.transAxes,
ha="left", va="bottom", color="#2ECC71", fontsize=12,
clip_on=False, visible=False)
(line,) = ax_val.plot([], [], linewidth=1.2, antialiased=False)
bars = ax_delta.bar([], [], linewidth=0, antialiased=False)
win._fig = fig; win._ax_val = ax_val; win._ax_delta = ax_delta
win._canvas = canvas; win._line = line; win._bars = bars; win._bars_len = 0
win._last_seen_ver = -1
win._layout_dirty = True
canvas.mpl_connect("resize_event", lambda _evt=None: setattr(win, "_layout_dirty", True))
if not hasattr(self, "_plot_windows"):
self._plot_windows = {}
self._plot_windows[key] = win
self._ensure_plot_timer()
# --- [DROP-IN] aktualizacja Matplotlib --------------------------------------
def _plot_update_matplotlib(self, win, xs_v, vals_draw, xs_b, dels_draw, thr: dict):
try:
# wartości
win._line.set_data(xs_v, vals_draw)
if vals_draw:
vmin, vmax = min(vals_draw), max(vals_draw)
span = (vmax - vmin) or 1.0
m = 0.08 * span
win._ax_val.set_xlim(0, max(1, len(xs_v) - 1))
win._ax_val.set_ylim(vmin - m, vmax + m)
# delty (słupki)
if len(dels_draw) != getattr(win, "_bars_len", 0):
for b in getattr(win, "_bars", []):
try: b.remove()
except Exception: DBGEX("_plot_update_matplotlib remove bar")
win._bars = win._ax_delta.bar(xs_b, dels_draw)
win._bars_len = len(dels_draw)
else:
for b, h in zip(win._bars, dels_draw):
b.set_height(h)
if dels_draw:
dmin, dmax = min(dels_draw), max(dels_draw)
span = (dmax - dmin) or 1.0
m = 0.08 * span
win._ax_delta.set_xlim(0, max(1, len(dels_draw) - 1))
win._ax_delta.set_ylim(dmin - m, dmax + m)
win._ax_delta.set_xlabel(f"last {len(vals_draw)} samples")
# progi + wskaźnik
for ln in win._thr_lines.values():
ln.set_visible(False)
win._tri_val.set_visible(False); win._tri_delta.set_visible(False)
if bool(getattr(win, "_show_thr_var", self.display_show_thresholds_var).get()) and vals_draw:
vmin, vmax = win._ax_val.get_ylim()
def within(y): return (y is not None) and (vmin <= y <= vmax)
for name in ("dead_low","low","mid","high","extreme"):
y = thr.get(name)
if within(y):
win._thr_lines[name].set_ydata([y, y])
win._thr_lines[name].set_visible(True)
cur = vals_draw[-1] if vals_draw else None
cands = [(k, thr.get(k)) for k in ("dead_low","low","mid","high","extreme") if thr.get(k) is not None]
if (cur is not None) and cands:
k_best, y_best = min(cands, key=lambda kv: abs(kv[1]-cur))
color_map = {
"dead_low": "#FBC02D", "low": "#FFF59D", "mid": "#2ECC71",
"high": "#FF8A80", "extreme": "#D50000",
}
col = color_map.get(k_best, "#2ECC71")
up = (y_best > cur)
char = "▲" if up else "▼"
win._tri_val.set_text(char); win._tri_val.set_color(col); win._tri_val.set_visible(True)
win._tri_delta.set_text(char); win._tri_delta.set_color(col); win._tri_delta.set_visible(True)
if getattr(win, "_layout_dirty", False):
try: win._fig.tight_layout()
except Exception: DBGEX("_plot_update_matplotlib tight_layout")
win._layout_dirty = False
win._canvas.draw_idle()
except Exception:
DBGEX("_plot_update_matplotlib")
def count_plot_windows(self) -> int:
n_tk = len([w for w in getattr(self, "_plot_windows", {}).values() if getattr(w, "winfo_exists", lambda: False)()])
n_qt = len([w for w in getattr(self, "_plot_windows_qt", []) if getattr(w, "isVisible", lambda: False)()])
return n_tk + n_qt
# --- helpers: monitory (Windows) + fallback ---
def _enum_monitors(self):
monitors = []
try:
import ctypes
from ctypes import wintypes
class RECT(ctypes.Structure):
_fields_ = [("left", ctypes.c_long), ("top", ctypes.c_long),
("right", ctypes.c_long), ("bottom", ctypes.c_long)]
MONITORENUMPROC = ctypes.WINFUNCTYPE(ctypes.c_int, ctypes.c_ulong, ctypes.c_ulong, ctypes.POINTER(RECT), ctypes.c_double)
user32 = ctypes.windll.user32
def _cb(hMon, hDC, lprc, dwData):
r = lprc.contents
monitors.append((int(r.left), int(r.top), int(r.right), int(r.bottom)))
return 1
user32.EnumDisplayMonitors(0, 0, MONITORENUMPROC(_cb), 0)
if not monitors:
raise RuntimeError("No monitors from EnumDisplayMonitors")
except Exception:
# Fallback: pojedynczy ekran wg Tk
DBGEX("_enum_monitors")
w = self.winfo_screenwidth()
h = self.winfo_screenheight()
monitors = [(0, 0, w, h)]
return monitors
def _win_center(self, x, y, w, h):
return (x + w // 2, y + h // 2)
def _which_monitor(self, monitors, x, y, w, h):
cx, cy = self._win_center(x, y, w, h)
best = 0; best_d = float("inf")
for i, (L, T, R, B) in enumerate(monitors):
if L <= cx <= R and T <= cy <= B:
return i
# odległość do środka monitora
mcx, mcy = (L + R) // 2, (T + B) // 2
d = (mcx - cx) ** 2 + (mcy - cy) ** 2
if d < best_d:
best, best_d = i, d
return best
def _best_grid(self, n):
if n <= 0:
return (1, 1)
c = int(math.ceil(math.sqrt(n)))
r = int(math.ceil(n / c))
return (r, c)
def arrange_plot_windows(self):
"""
Układa wszystkie otwarte okna wykresów (Tk-Matplotlib, Tk-Canvas, Qt-PyQtGraph)
w siatki na poszczególnych monitorach.
Zasady:
- grupujemy okna wg monitora, NA KTÓRYM AKTUALNIE SĄ otwarte,
- w każdej grupie sortujemy alfabetycznie wg nazwy zmiennej (display_name),
- wypełniamy siatkę od lewej do prawej, potem kolejny wiersz,
- jeśli n>=9 na danym monitorze → siatka pełnoekranowa,
jeśli n<9 → okna max ~połowa domyślnego rozmiaru (dodatkowo skalujemy w dół, gdy trzeba),
- zostawiamy marginesy na krawędziach (TOP_MARGIN, SIDE/BOTTOM), żeby tytuły nie „wychodziły” poza ekran.
"""
monitors = self._enum_monitors()
# Zbierz okna (Tk MPL)
tk_wins = []
for w in list(getattr(self, "_plot_windows", {}).values()):
if getattr(w, "winfo_exists", lambda: False)():
try:
x = w.winfo_rootx(); y = w.winfo_rooty()
ww = w.winfo_width(); hh = w.winfo_height()
if ww <= 1 or hh <= 1:
geo = w.geometry() # "WxH+X+Y"
parts = geo.replace("x", "+").split("+")
ww = int(parts[0]); hh = int(parts[1]); x = int(parts[2]); y = int(parts[3])
key = getattr(w, "_key", None)
name = None
if key and key in self.vars:
name = self.vars[key].display_name
if not name:
# fallback: tytuł okna
name = str(w.title() or "")
tk_wins.append(("tk", w, x, y, ww, hh, name))
except Exception:
DBGEX("arrange_plot_windows Tk MPL")
# Zbierz okna (Tk Canvas)
for w in list(getattr(self, "_plot_windows_canvas", [])):
if getattr(w, "winfo_exists", lambda: False)():
try:
x = w.winfo_rootx(); y = w.winfo_rooty()
ww = w.winfo_width(); hh = w.winfo_height()
if ww <= 1 or hh <= 1:
geo = w.geometry()
parts = geo.replace("x", "+").split("+")
ww = int(parts[0]); hh = int(parts[1]); x = int(parts[2]); y = int(parts[3])
key = getattr(w, "_key", None)
name = None
if key and key in self.vars:
name = self.vars[key].display_name
if not name:
name = str(w.title() or "")
tk_wins.append(("tk", w, x, y, ww, hh, name))
except Exception:
DBGEX("arrange_plot_windows Tk Canvas")
# Zbierz okna (Qt pyqtgraph)
qt_wins = []
for qw in list(getattr(self, "_plot_windows_qt", [])):
if getattr(qw, "isVisible", lambda: False)():
try:
fg = qw.frameGeometry()
x = fg.x(); y = fg.y(); ww = fg.width(); hh = fg.height()
key = getattr(qw, "_key", None)
name = getattr(qw, "_display_name", None)
if not name and key and key in self.vars:
name = self.vars[key].display_name
if not name:
name = str(qw.windowTitle() or "")
qt_wins.append(("qt", qw, x, y, ww, hh, name))
except Exception:
DBGEX("arrange_plot_windows Qt pyqtgraph")
all_wins = tk_wins + qt_wins
if not all_wins:
tk.messagebox.showinfo("Arrange", "Brak otwartych okien wykresów.")
return
# Grupowanie po monitorach (wg aktualnej pozycji)
groups = {i: [] for i in range(len(monitors))}
for kind, win, x, y, ww, hh, name in all_wins:
mid = self._which_monitor(monitors, x, y, ww, hh)
groups[mid].append((kind, win, name))
# USTAWIENIA rozmiaru/marginesów
DEF_W, DEF_H = 760, 420
MAX_W, MAX_H = DEF_W // 2, DEF_H // 2
SIDE_MARGIN = 12
TOP_MARGIN = 40 # większy top, żeby tytuły Qt nie wychodziły
BOTTOM_MARGIN = 12
CELL_PAD = 10 # odstęp między kratkami
# Helper: najlepsza siatka (r,c)
def best_grid(n):
if n <= 0: return (1, 1)
c = int(math.ceil(math.sqrt(n)))
r = int(math.ceil(n / c))
return (r, c)
for midx, items in groups.items():
if not items:
continue
# Sortowanie alfabetycznie wg nazwy zmiennej (display_name)
items.sort(key=lambda it: (str(it[2]).lower(), str(it[2])))
L, T, R, B = monitors[midx]
mon_w = R - L
mon_h = B - T
n = len(items)
rows, cols = best_grid(n)
full = (n >= 9)
# wstępny wymiar kratki
if full:
cell_w = max(1, (mon_w - (cols + 1) * CELL_PAD - 2 * SIDE_MARGIN) // cols)
cell_h = max(1, (mon_h - (rows + 1) * CELL_PAD - TOP_MARGIN - BOTTOM_MARGIN) // rows)
else:
cell_w = min(MAX_W, max(1, (mon_w - (cols + 1) * CELL_PAD - 2 * SIDE_MARGIN) // cols))
cell_h = min(MAX_H, max(1, (mon_h - (rows + 1) * CELL_PAD - TOP_MARGIN - BOTTOM_MARGIN) // rows))
# dopasowanie, jeśli dalej nie mieści
while (cell_w * cols + (cols + 1) * CELL_PAD + 2 * SIDE_MARGIN) > mon_w or \
(cell_h * rows + (rows + 1) * CELL_PAD + TOP_MARGIN + BOTTOM_MARGIN) > mon_h:
cell_w = max(120, int(cell_w * 0.9))
cell_h = max(100, int(cell_h * 0.9))
if cell_w <= 120 and cell_h <= 100:
break
# rozmiar całej siatki + pozycja startowa (centrowanie)
grid_w = cell_w * cols + (cols + 1) * CELL_PAD
grid_h = cell_h * rows + (rows + 1) * CELL_PAD
origin_x = L + SIDE_MARGIN + max(0, (mon_w - grid_w - 2 * SIDE_MARGIN) // 2)
origin_y = T + TOP_MARGIN + max(0, (mon_h - grid_h - TOP_MARGIN - BOTTOM_MARGIN) // 2)
# „bezpieczny” rozmiar (obcięty o mały bufor, różne dekoracje)
cell_w_adj = max(50, cell_w - 8)
cell_h_adj = max(50, cell_h - 12)
# Rozmieszczaj od lewej do prawej, potem kolejny wiersz
i = 0
for c in range(cols):
for r in range(rows):
if i >= n:
break
kind, win, _nm = items[i]
x = origin_x + CELL_PAD + c * (cell_w + CELL_PAD)
y = origin_y + CELL_PAD + r * (cell_h + CELL_PAD)
# „clamp” do granic ekranu (z marginesami)
x = max(L + SIDE_MARGIN, min(x, R - SIDE_MARGIN - cell_w_adj))
y = max(T + TOP_MARGIN, min(y, B - BOTTOM_MARGIN - cell_h_adj))
try:
if kind == "tk":
win.geometry(f"{cell_w_adj}x{cell_h_adj}+{x}+{y}")
else:
win.setGeometry(x, y, cell_w_adj, cell_h_adj)
except Exception:
DBGEX("arrange_plot_windows set geometry")
i += 1
# --- Utils ---
def parse_first_float(value: str) -> Optional[float]:
if value is None:
return None
m = re.search(r"[-+]?\d+(?:\.\d+)?", str(value).replace(",", "."))
if m:
try:
return float(m.group(0))
except Exception:
DBGEX("parse_first_float")
return None
return None
def safe_eval(expression: str, env: dict):
"""
Bezpieczna ewaluacja krótkich wyrażeń progowych.
Dostępne: math, min, max, abs, round, int, float.
Zmiennych szukamy w `env` (np. x, x_avg, dx, dx_avg, y, y_avg, ...).
"""
allowed_globals = {
"__builtins__": {},
"math": math, "min": min, "max": max,
"abs": abs, "round": round, "int": int, "float": float,
}
# tylko 'eval' bez snippetów wieloliniowych:
code = compile(expression, "<thr>", "eval")
return eval(code, allowed_globals, env)
def eval_user_expression(expr: str, x: float, y: float | None = None, z: float | None = None):
"""Evaluate user expression/snippet with x available.
Allowed: math.*, min, max, abs, round, int, float, clamp (custom).
Returns the computed result.
"""
def clamp(v, lo, hi):
return max(lo, min(hi, v))
safe_globals = {"__builtins__": {}, "math": math, "min": min, "max": max, "abs": abs, "round": round, "int": int, "float": float, "clamp": clamp}
safe_locals = {"x": x, "y": y, "z": z}
if "\n" in expr or ";" in expr:
code = compile(expr, "<expr>", "exec")
exec(code, safe_globals, safe_locals)
if "result" not in safe_locals:
raise ValueError("Snippet must assign to 'result', e.g., result = x * 1.1")
return safe_locals["result"]
else:
code = compile(expr, "<expr>", "eval")
return eval(code, safe_globals, safe_locals)
def main() -> None:
app = App()
import atexit
def _graceful_shutdown():
try:
# jeżeli App jeszcze żyje wywołaj on_close
# (dopasuj, jeśli trzymasz referencję gdzie indziej)
app.on_close()
except Exception:
DBGEX("graceful_shutdown")
atexit.register(_graceful_shutdown)
app.mainloop()
if __name__ == "__main__":
main()