""" ____ _ ____ _ ____ _ ____ _ / ___| / \ | _ \ / \ / ___| ___ _ __ __| | | _ \ __ _| |_ __ _ \___ \ / _ \ | |_) | / _ \ \___ \ / _ \ '_ \ / _` | | | | |/ _` | __/ _` | ___) / ___ \| _ < / ___ \ ___) | __/ | | | (_| | | |_| | (_| | || (_| | |____/_/ \_\_| \_\/_/ \_\ |____/ \___|_| |_|\__,_| |____/ \__,_|\__\__,_| Main loop to gather data from sensor inside SQLite database: * NPM * Envea * I2C BME280 * Noise sensor and send it to AirCarto servers via SARA R4 HTTP post requests also send the timestamp (already stored inside the DB) ! /usr/bin/python3 /var/www/moduleair_pro_4g/loop/SARA_send_data_v2.py ATTENTION: # This script is triggered every minutes by /var/www/moduleair_pro_4g/master.py (as a service) CSV PAYLOAD (AirCarto Servers) Endpoint: data.moduleair.fr /pro_4G/data.php?sensor_id={device_id}×tamp={rtc_module_time} ATTENTION : do not change order ! CSV size: 18 {PM1},{PM25},{PM10},{temp},{hum},{press},{avg_noise},{max_noise},{min_noise},{envea_no2},{envea_h2s},{envea_o3},{4g_signal_quality} 0 -> PM1 (μg/m3) 1 -> PM25 (μg/m3) 2 -> PM10 (μg/m3) 3 -> temp 4 -> hum 5 -> press 6 -> avg_noise 7 -> max_noise 8 -> min_noise 9 -> envea_no2 10 -> envea_h2s 11 -> envea_nh3 12 -> 4G signal quality, 13 -> PM 0.2μm to 0.5μm quantity (Nb/L) 14 -> PM 0.5μm to 1.0μm quantity (Nb/L) 15 -> PM 1.0μm to 2.5μm quantity (Nb/L) 16 -> PM 2.5μm to 5.0μm quantity (Nb/L) 17 -> PM 5.0μm to 10μm quantity (Nb/L) 18 -> NPM temp inside 19 -> NPM hum inside 20 -> CO2 JSON PAYLOAD (Micro-Spot Servers) Same as moduleair wifi Endpoint: api-prod.uspot.probesys.net moduleair?token=2AFF6dQk68daFZ port 443 {"moduleairid": "82D25549434", "software_version": "ModuleAirV2-V1-042022", "sensordatavalues": [ {"value_type":"NPM_P0","value":"1.54"}, {"value_type":"NPM_P1","value":"1.54"}, {"value_type":"NPM_P2","value":"1.54"}, {"value_type":"NPM_N1","value":"0.02"}, {"value_type":"NPM_N10","value":"0.02"}, {"value_type":"NPM_N25","value":"0.02"}, {"value_type":"MHZ16_CO2","value":"793.00"}, {"value_type":"SGP40_VOC","value":"29915.00"}, {"value_type":"samples","value":"134400"}, {"value_type":"min_micro","value":"137"}, {"value_type":"max_micro","value":"155030"}, {"value_type":"interval","value":"145000"}, {"value_type":"signal","value":"-80"}, {"value_type":"latitude","value":"43.2964"}, {"value_type":"longitude","value":"5.36978"}, {"value_type":"state_npm","value":"State: 00000000"}, {"value_type":"BME280_temperature","value":"28.47"}, {"value_type":"BME280_humidity","value":"28.47"}, {"value_type":"BME280_pressure","value":"28.47"}, {"value_type":"CAIRSENS_NO2","value":"54"}, {"value_type":"CAIRSENS_H2S","value":"54"}, {"value_type":"CAIRSENS_O3","value":"54"} ] } """ #import board import json import serial import time import busio import requests import re import os import traceback import sys import sqlite3 import RPi.GPIO as GPIO from threading import Thread from datetime import datetime # Record the start time of the script start_time_script = time.time() #Payload CSV to be sent to data.moduleair.fr payload_csv = [None] * 25 #Payload JSON to be sent to uSpot payload_json = { "moduleairid": "XXX", "software_version": "ModuleAirV2-V1-042022", "sensordatavalues": [] # Empty list to start with } # SARA R4 UHTTPC profile IDs aircarto_profile_id = 0 uSpot_profile_id = 1 # database connection conn = sqlite3.connect("/var/www/moduleair_pro_4g/sqlite/sensors.db") cursor = conn.cursor() def update_config_sqlite(key, value, value_type=None, max_retries=4, retry_delay=1.0): """ Update or insert a configuration value in SQLite config table with retry logic Args: key (str): Configuration key value: Configuration value (any type) value_type (str, optional): Force specific type ('str', 'int', 'float', 'bool') If None, auto-detect from value type max_retries (int): Maximum number of retry attempts (default: 4) retry_delay (float): Delay between retries in seconds (default: 1.0) Returns: bool: True if successful, False otherwise """ # Auto-detect type if not specified if value_type is None: if isinstance(value, bool): value_type = 'bool' elif isinstance(value, int): value_type = 'int' elif isinstance(value, float): value_type = 'float' else: value_type = 'str' # Convert value to string for storage if value_type == 'bool': str_value = '1' if value else '0' else: str_value = str(value) # Retry logic for attempt in range(max_retries): try: # Use WAL mode and immediate transaction for better concurrency conn.execute("PRAGMA journal_mode=WAL") conn.execute("PRAGMA busy_timeout=30000") # Wait up to 30 seconds for lock # Begin immediate transaction to acquire lock quickly conn.execute("BEGIN IMMEDIATE") # Use INSERT OR REPLACE to update existing or create new cursor.execute(""" INSERT OR REPLACE INTO config_table (key, value, type) VALUES (?, ?, ?) """, (key, str_value, value_type)) conn.commit() print(f"✓ Config updated: {key} = {value} ({value_type}) [attempt {attempt + 1}]") return True except sqlite3.OperationalError as e: if "database is locked" in str(e).lower() or "locked" in str(e).lower(): print(f"⚠ Database locked on attempt {attempt + 1}/{max_retries} for key '{key}': {e}") # Rollback any pending transaction try: conn.rollback() except: pass # If not the last attempt, wait and retry if attempt < max_retries - 1: print(f"⏳ Retrying in {retry_delay} seconds...") time.sleep(retry_delay) # Increase delay slightly for each retry (exponential backoff) retry_delay *= 1.2 else: print(f"✗ Failed to update config {key} after {max_retries} attempts: database remains locked") return False else: # Non-lock related operational error print(f"✗ Operational error updating config {key}: {e}") try: conn.rollback() except: pass return False except Exception as e: # Other unexpected errors print(f"✗ Unexpected error updating config {key} on attempt {attempt + 1}: {e}") try: conn.rollback() except: pass # For unexpected errors, don't retry unless it's clearly a temporary issue if "busy" in str(e).lower() or "locked" in str(e).lower(): if attempt < max_retries - 1: print(f"⏳ Retrying in {retry_delay} seconds...") time.sleep(retry_delay) retry_delay *= 1.2 continue return False # If we get here, all retries failed print(f"✗ Failed to update config {key} after {max_retries} attempts") return False #get config data from SQLite table def load_config_sqlite(): """ Load configuration data from SQLite config table Returns: dict: Configuration data with proper type conversion """ try: # Query the config table cursor.execute("SELECT key, value, type FROM config_table") rows = cursor.fetchall() # Create config dictionary config_data = {} for key, value, type_name in rows: # Convert value based on its type if type_name == 'bool': config_data[key] = value == '1' or value == 'true' elif type_name == 'int': config_data[key] = int(value) elif type_name == 'float': config_data[key] = float(value) else: config_data[key] = value return config_data except Exception as e: print(f"Error loading config from SQLite: {e}") return {} #Load config config = load_config_sqlite() #config device_id = config.get('deviceID', 'unknown') device_id = device_id.upper() modem_config_mode = config.get('modem_config_mode', False) device_latitude_raw = config.get('latitude_raw', 0) device_longitude_raw = config.get('longitude_raw', 0) modem_version=config.get('modem_version', "") Sara_baudrate = config.get('SaraR4_baudrate', 115200) npm_5channel = config.get('npm_5channel', False) #5 canaux du NPM selected_networkID = int(config.get('SARA_R4_neworkID', 0)) send_uSpot = config.get('send_uSpot', False) #envoi sur MicroSpot () bme_280_config = config.get('BME280', False) co2_mhz19= config.get('MHZ19', False) sensirion_sfa30= config.get('SFA30', False) reset_uSpot_url = False #update device id in the payload json payload_json["moduleairid"] = device_id # Skip execution if modem_config_mode is true if modem_config_mode: print("Modem 4G (SARA R4) is in config mode -> EXIT") sys.exit() ser_sara = serial.Serial( port='/dev/ttyAMA2', baudrate=Sara_baudrate, #115200 ou 9600 parity=serial.PARITY_NONE, #PARITY_NONE, PARITY_EVEN or PARITY_ODD stopbits=serial.STOPBITS_ONE, bytesize=serial.EIGHTBITS, timeout = 2 ) def read_complete_response(serial_connection, timeout=2, end_of_response_timeout=2, wait_for_lines=None, debug=True): ''' Fonction très importante !!! Reads the complete response from a serial connection and waits for specific lines. timeout -> temps d'attente de la réponse de la première ligne (assez rapide car le SARA répond direct avec la commande recue) end_of_response_timeout -> le temps d'inactivité entre deux lignes imprimées (plus long dans certain cas: le SARA mouline avant de finir vraiment) wait_for_lines -> si on rencontre la string la fonction s'arrete ''' if wait_for_lines is None: wait_for_lines = [] # Default to an empty list if not provided response = bytearray() serial_connection.timeout = timeout end_time = time.time() + end_of_response_timeout start_time = time.time() while True: elapsed_time = time.time() - start_time # Time since function start if serial_connection.in_waiting > 0: data = serial_connection.read(serial_connection.in_waiting) response.extend(data) end_time = time.time() + end_of_response_timeout # Reset timeout on new data # Decode and check for any target line decoded_response = response.decode('utf-8', errors='replace') for target_line in wait_for_lines: if target_line in decoded_response: if debug: print(f"[DEBUG] 🔎 Found target line: {target_line} (in {elapsed_time:.2f}s)") return decoded_response # Return response immediately if a target line is found elif time.time() > end_time: if debug: print(f"[DEBUG] Timeout reached. No more data received.") break time.sleep(0.1) # Short sleep to prevent busy waiting # Final response and debug output total_elapsed_time = time.time() - start_time if debug: print(f"[DEBUG] ⏱️ elapsed time: {total_elapsed_time:.2f}s. ⏱️") # Check if the elapsed time exceeded 10 seconds if total_elapsed_time > 10 and debug: print(f"[ALERT] 🚨 The operation took too long 🚨") print(f'[ALERT] ⚠️{total_elapsed_time:.2f}s⚠️') return response.decode('utf-8', errors='replace') # Return the full response if no target line is found def extract_error_code(response): """ Extract just the error code from AT+UHTTPER response """ for line in response.split('\n'): if '+UHTTPER' in line: try: # Split the line and get the third value (error code) parts = line.split(':')[1].strip().split(',') if len(parts) >= 3: error_code = int(parts[2]) return error_code except: pass # Return None if we couldn't find the error code return None def send_error_notification(device_id, error_type, additional_info=None): """ Send an error notification to the server when issues with the SARA module occur. Will silently fail if there's no internet connection. Parameters: ----------- device_id : str The unique identifier of the device error_type : str Type of error encountered (e.g., 'serial_error', 'cme_error', 'http_error', 'timeout') additional_info : str, optional Any additional information about the error for logging purposes Returns: -------- bool True if notification was sent successfully, False otherwise """ # Create the alert URL with all relevant parameters base_url = 'http://data.nebuleair.fr/pro_4G/alert.php' alert_url = f'{base_url}?capteur_id={device_id}&error_type={error_type}' # Add additional info if provided if additional_info: # Make sure to URL encode the additional info from urllib.parse import quote alert_url += f'&details={quote(str(additional_info))}' # Try to send the notification, catch ALL exceptions try: response = requests.post(alert_url, timeout=3) if response.status_code == 200: print(f"✅ Alert notification sent successfully") return True else: print(f"⚠️ Alert notification failed: Status code {response.status_code}") except Exception as e: print(f"⚠️ Alert notification couldn't be sent: {e}") return False def modem_hardware_reboot(): """ Performs a hardware reboot using transistors connected to pin 16 and 20: pin 16 set to SARA GND pin 20 set to SARA ON (not used) LOW -> cut the current HIGH -> current flow """ print('🔄 Hardware SARA reboot 🔄') SARA_power_GPIO = 16 SARA_ON_GPIO = 20 GPIO.setmode(GPIO.BCM) # Use BCM numbering GPIO.setup(SARA_power_GPIO, GPIO.OUT) # Set GPIO17 as an output GPIO.output(SARA_power_GPIO, GPIO.LOW) time.sleep(2) GPIO.output(SARA_power_GPIO, GPIO.HIGH) time.sleep(2) print("Checking if modem is responsive...") for attempt in range(5): ser_sara.write(b'AT\r') response_check = read_complete_response(ser_sara, wait_for_lines=["OK"], debug=True) if response_check and "OK" in response_check: print("✅ Modem is responsive after reboot.") return True print(f"⏳ Waiting for modem... attempt {attempt + 1}") time.sleep(2) else: print("❌ Modem not responding after reboot.") return False def reset_PSD_CSD_connection(): """ Function that reset the PSD CSD connection for the SARA R5 returns true or false """ print("⚠️Reseting PDP connection ") pdp_reset_success = True # Activate PDP context 1 print('➡️ Activate PDP context 1') command = f'AT+CGACT=1,1\r' ser_sara.write(command.encode('utf-8')) response_pdp1 = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_pdp1, end="") pdp_reset_success = pdp_reset_success and (response_pdp1 is not None and "OK" in response_pdp1) time.sleep(1) # Set the PDP type print('➡️ Set the PDP type to IPv4 referring to the output of the +CGDCONT read command') command = f'AT+UPSD=0,0,0\r' ser_sara.write(command.encode('utf-8')) response_pdp2 = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_pdp2, end="") pdp_reset_success = pdp_reset_success and (response_pdp2 is not None and "OK" in response_pdp2) time.sleep(1) # Profile #0 is mapped on CID=1 print('➡️ Profile #0 is mapped on CID=1.') command = f'AT+UPSD=0,100,1\r' ser_sara.write(command.encode('utf-8')) response_pdp3 = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_pdp3, end="") pdp_reset_success = pdp_reset_success and (response_pdp3 is not None and "OK" in response_pdp3) time.sleep(1) # Activate the PSD profile print('➡️ Activate the PSD profile #0: the IPv4 address is already assigned by the network.') command = f'AT+UPSDA=0,3\r' ser_sara.write(command.encode('utf-8')) response_pdp4 = read_complete_response(ser_sara, wait_for_lines=["OK", "+UUPSDA"]) print(response_pdp4, end="") pdp_reset_success = pdp_reset_success and (response_pdp4 is not None and ("OK" in response_pdp4 or "+UUPSDA" in response_pdp4)) time.sleep(1) if not pdp_reset_success: print("⚠️ PDP connection reset had some issues") return pdp_reset_success def reset_server_hostname(profile_id): """ Function that reset server hostname (URL) connection for the SARA R5 returns true or false """ print("⚠️Reseting Server Hostname connection ") http_reset_success = False # Default fallback if profile_id == 0: print('🔧 Resetting AirCarto HTTP Profile') command = f'AT+UHTTP={profile_id},1,"data.moduleair.fr"\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_5 = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_5) time.sleep(1) http_reset_success = response_SARA_5 is not None and "OK" in response_SARA_5 if not http_reset_success: print("⚠️ AirCarto HTTP profile reset failed") elif profile_id ==1: pass # on utilise la fonction reset_server_hostname_https pour uSpot else: print(f"❌ Unsupported profile ID: {profile_id}") http_reset_success = False return http_reset_success def reset_server_hostname_https(profile_id): """ Function that reset server hostname (URL) connection for the SARA R5 returns true or false """ print("⚠️Reseting Server Hostname HTTS secure connection ") http_reset_success = False # Default fallback #Pour uSpot if profile_id == 1: print('🔧 Resetting uSpot HTTPs Profile') uSpot_url="api-prod.uspot.probesys.net" security_profile_id = 1 #step 1: import the certificate print("➡️ import certificate") certificate_name = "e6" with open("/var/www/moduleair_pro_4g/SARA/SSL/certificate/e6.pem", "rb") as cert_file: certificate = cert_file.read() size_of_string = len(certificate) # AT+USECMNG=0,,, # type-> 0 -> trusted root CA command = f'AT+USECMNG=0,0,"{certificate_name}",{size_of_string}\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_1 = read_complete_response(ser_sara, wait_for_lines=[">"]) print(response_SARA_1) time.sleep(0.5) print("➡️ add certificate") ser_sara.write(certificate) response_SARA_2 = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_2) time.sleep(0.5) # op_code: 0 -> certificate validation level # param_val : 0 -> Level 0 No validation; 1-> Level 1 Root certificate validation print("➡️Set the security profile (params)") certification_level=0 command = f'AT+USECPRF={security_profile_id},0,{certification_level}\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_5b = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_5b) time.sleep(0.5) # op_code: 1 -> minimum SSL/TLS version # param_val : 0 -> any; server can use any version for the connection; 1-> LSv1.0; 2->TLSv1.1; 3->TLSv1.2; print("➡️Set the security profile (params)") minimum_SSL_version = 0 command = f'AT+USECPRF={security_profile_id},1,{minimum_SSL_version}\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_5bb = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_5bb) time.sleep(0.5) #op_code: 2 -> legacy cipher suite selection # 0 (factory-programmed value): a list of default cipher suites is proposed at the beginning of handshake process, and a cipher suite will be negotiated among the cipher suites proposed in the list. print("➡️Set cipher") cipher_suite = 0 command = f'AT+USECPRF={security_profile_id},2,{cipher_suite}\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_5cc = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_5cc) time.sleep(0.5) # op_code: 3 -> trusted root certificate internal name print("➡️Set the security profile (choose cert)") command = f'AT+USECPRF={security_profile_id},3,"{certificate_name}"\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_5c = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_5c) time.sleep(0.5) # op_code: 10 -> SNI (server name indication) print("➡️Set the SNI") command = f'AT+USECPRF={security_profile_id},10,"{uSpot_url}"\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_5cf = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_5cf) time.sleep(0.5) #step 4: set url (op_code = 1) print("➡️SET URL") command = f'AT+UHTTP={profile_id},1,"{uSpot_url}"\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_5 = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_5) time.sleep(1) #step 4: set PORT (op_code = 5) print("➡️SET PORT") port = 443 command = f'AT+UHTTP={profile_id},5,{port}\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_55 = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_55) time.sleep(1) #step 4: set url to SSL (op_code = 6) (http_secure = 1 for HTTPS)(USECMNG_PROFILE = 2) print("➡️SET SSL") http_secure = 1 command = f'AT+UHTTP={profile_id},6,{http_secure},{security_profile_id}\r' ser_sara.write(command.encode('utf-8')) response_SARA_5fg = read_complete_response(ser_sara, wait_for_lines=["OK"]) print(response_SARA_5fg) time.sleep(1) http_reset_success = response_SARA_5 is not None and "OK" in response_SARA_5 if not http_reset_success: print("⚠️ AirCarto HTTP profile reset failed") #Pour uSpot elif profile_id ==1: pass #on utilise la fonction reset_server_hostname_https pour uSpot else: print(f"❌ Unsupported profile ID: {profile_id}") http_reset_success = False return http_reset_success try: ''' _ ___ ___ ____ | | / _ \ / _ \| _ \ | | | | | | | | | |_) | | |__| |_| | |_| | __/ |_____\___/ \___/|_| ''' print('

START LOOP

', end="") # Check system uptime with open('/proc/uptime', 'r') as f: uptime_seconds = float(f.readline().split()[0]) # Skip execution if uptime is less than 2 minutes (120 seconds) if uptime_seconds < 120: print(f"System just booted ({uptime_seconds:.2f} seconds uptime), skipping execution.") update_config_sqlite('SARA_network_status', 'booting') sys.exit() #Local timestamp cursor.execute("SELECT * FROM timestamp_table LIMIT 1") row = cursor.fetchone() # Get the first (and only) row rtc_time_str = row[1] # '2025-02-07 12:30:45' print(f"➡️Getting local timestamp: {rtc_time_str}") if rtc_time_str == 'not connected': print("⛔ Atttention RTC module not connected⛔") rtc_status = "disconnected" influx_timestamp="rtc_disconnected" else : # Convert to a datetime object dt_object = datetime.strptime(rtc_time_str, '%Y-%m-%d %H:%M:%S') # Check if timestamp is reset (year 2000) if dt_object.year == 2000: print("⛔ Attention: RTC has been reset to default date ⛔") rtc_status = "reset" else: print("✅ RTC timestamp is valid") rtc_status = "valid" # Always convert to InfluxDB format # Convert to InfluxDB RFC3339 format with UTC 'Z' suffix influx_timestamp = dt_object.strftime('%Y-%m-%dT%H:%M:%SZ') rtc_status = "valid" #print(influx_timestamp) #NEXTPM print("➡️Getting NPM values (last 6 measures)") #cursor.execute("SELECT * FROM data_NPM ORDER BY timestamp DESC LIMIT 1") #cursor.execute("SELECT * FROM data_NPM ORDER BY timestamp DESC LIMIT 6") cursor.execute("SELECT rowid, * FROM data_NPM ORDER BY rowid DESC LIMIT 6") rows = cursor.fetchall() # Exclude the timestamp column (assuming first column is timestamp) data_values = [row[2:] for row in rows] # Exclude timestamp # Compute column-wise average num_columns = len(data_values[0]) averages = [round(sum(col) / len(col),1) for col in zip(*data_values)] PM1 = averages[0] PM25 = averages[1] PM10 = averages[2] npm_temp = averages[3] npm_hum = averages[4] #Add data to payload CSV payload_csv[0] = PM1 payload_csv[1] = PM25 payload_csv[2] = PM10 payload_csv[18] = npm_temp payload_csv[19] = npm_hum #Add data to payload JSON payload_json["sensordatavalues"].append({"value_type": "NPM_P0", "value": str(PM1)}) payload_json["sensordatavalues"].append({"value_type": "NPM_P1", "value": str(PM10)}) payload_json["sensordatavalues"].append({"value_type": "NPM_P2", "value": str(PM25)}) #NextPM 5 channels if npm_5channel: print("➡️Getting NextPM 5 channels values (last 6 measures)") cursor.execute("SELECT * FROM data_NPM_5channels ORDER BY timestamp DESC LIMIT 6") rows = cursor.fetchall() # Exclude the timestamp column (assuming first column is timestamp) data_values = [row[1:] for row in rows] # Exclude timestamp # Compute column-wise average num_columns = len(data_values[0]) averages = [round(sum(col) / len(col)) for col in zip(*data_values)] # Store averages in specific indices payload_csv[13] = averages[0] # Channel 1 payload_csv[14] = averages[1] # Channel 2 payload_csv[15] = averages[2] # Channel 3 payload_csv[16] = averages[3] # Channel 4 payload_csv[17] = averages[4] # Channel 5 #BME280 if bme_280_config: print("➡️Getting BME280 values") cursor.execute("SELECT * FROM data_BME280 ORDER BY timestamp DESC LIMIT 1") last_row = cursor.fetchone() if last_row: print("SQLite DB last available row:", last_row) BME280_temperature = last_row[1] BME280_humidity = last_row[2] BME280_pressure = last_row[3] #Add data to payload CSV payload_csv[3] = BME280_temperature payload_csv[4] = BME280_humidity payload_csv[5] = BME280_pressure #Add data to payload JSON payload_json["sensordatavalues"].append({"value_type": "BME280_temperature", "value": str(BME280_temperature)}) payload_json["sensordatavalues"].append({"value_type": "BME280_humidity", "value": str(BME280_humidity)}) payload_json["sensordatavalues"].append({"value_type": "BME280_pressure", "value": str(BME280_pressure)}) else: print("No data available in the database.") #HM-Z19 if co2_mhz19: # CO2 sensor - average of last 6 measures print("➡️Getting CO2 values (last 6 measures)") cursor.execute("SELECT rowid, * FROM data_CO2 ORDER BY rowid DESC LIMIT 6") rows = cursor.fetchall() if rows: # Extract just the CO2 values (assuming CO2 is in column 2 after rowid and timestamp) co2_values = [row[2] for row in rows] # Adjust index based on your table structure # Calculate average co2_average = round(sum(co2_values) / len(co2_values), 1) # Add data to payload CSV payload_csv[20] = co2_average # Choose appropriate index # Add data to payload JSON payload_json["sensordatavalues"].append({"value_type": "MHZ16_CO2", "value": str(co2_average)}) print(f"CO2 average from {len(co2_values)} measurements: {co2_average}") else: print("No CO2 data available in the database.") #print("Verify SARA R4 connection") # Getting the LTE Signal print("➡️Getting LTE signal") ser_sara.write(b'AT+CSQ\r') response2 = read_complete_response(ser_sara, wait_for_lines=["OK", "ERROR", "+CME ERROR"]) print('

') print(response2) print("

", end="") #Here it's possible that the SARA do not repond at all or send a error message #-> TO DO : harware reboot #-> send notification #-> end loop, no need to continue #1. No answer at all form SARA if response2 is None or response2 == "": print("⚠️ATTENTION: No answer from SARA module") print('🛑STOP LOOP🛑') print("
") #Send notification (WIFI) send_error_notification(device_id, "SERIAL ISSUE ->no answer from sara") #Hardware Reboot hardware_reboot_success = modem_hardware_reboot() if hardware_reboot_success: print("✅Modem successfully rebooted and reinitialized") else: print("⛔There were issues with the modem reboot/reinitialize process") #end loop sys.exit() #2. si on a une reponse du SARA mais c'est une erreur elif "+CME ERROR" in response2: print(f"SARA module returned error: {response2}") print("The CSQ command is not supported by this module or in its current state") print("⚠️ATTENTION: SARA is connected over serial but CSQ command not supported") print('🛑STOP LOOP🛑') print("
") #end loop sys.exit() #3. On peut avoir une erreur de type "Socket:bind: Treck error 222 : Invalid argument" elif "Socket:bind: Treck error" in response2: print(f"SARA module returned error: {response2}") print("⚠️ATTENTION: low-level error from the Treck TCP/IP stack") print('🛑STOP LOOP🛑') print("
") #Send notification (WIFI) send_error_notification(device_id, "SERIAL ISSUE -> Treck TCP/IP stack error") #hardware reboot hardware_reboot_success = modem_hardware_reboot() if hardware_reboot_success: print("✅Modem successfully rebooted and reinitialized") else: print("⛔There were issues with the modem reboot/reinitialize process") #end loop sys.exit() else : print("✅SARA is connected over serial") match = re.search(r'\+CSQ:\s*(\d+),', response2) if match: signal_quality = int(match.group(1)) payload_csv[12]=signal_quality time.sleep(0.1) # On vérifie si le signal n'est pas à 99 pour déconnexion if signal_quality == 99: update_config_sqlite('SARA_network_status', 'disconnected') update_config_sqlite('SARA_signal_quality', '99') print('⚠️ATTENTION: Signal Quality indicates no signal (99)⚠️') #print("TRY TO RECONNECT:") #command = f'AT+COPS=1,2,"{selected_networkID}"\r' #ser_sara.write(command.encode('utf-8')) #responseReconnect = read_complete_response(ser_sara, timeout=20, end_of_response_timeout=20, wait_for_lines=["OK", "+CME ERROR", "ERROR"], debug=True) #print('

') #print(responseReconnect) #print("

", end="") print('🛑STOP LOOP🛑') print("
") #on arrete le script pas besoin de continuer sys.exit() else: print("Signal Quality:", signal_quality) update_config_sqlite('SARA_signal_quality', signal_quality) ''' ____ _____ _ _ ____ _ ___ ____ ____ _ ____ _____ ___ / ___|| ____| \ | | _ \ / \ |_ _| _ \ / ___| / \ | _ \_ _/ _ \ \___ \| _| | \| | | | | / _ \ | || |_) | | / _ \ | |_) || || | | | ___) | |___| |\ | |_| | / ___ \ | || _ <| |___ / ___ \| _ < | || |_| | |____/|_____|_| \_|____/ /_/ \_\___|_| \_\\____/_/ \_\_| \_\|_| \___/ ''' print('

➡️SEND TO AIRCARTO SERVERS

', end="") # Write Data to saraR4 # 1. Open sensordata_csv.json (with correct data size) csv_string = ','.join(str(value) if value is not None else '' for value in payload_csv) size_of_string = len(csv_string) print("Open JSON:") command = f'AT+UDWNFILE="sensordata_csv.json",{size_of_string}\r' ser_sara.write(command.encode('utf-8')) response_SARA_1 = read_complete_response(ser_sara, wait_for_lines=[">"], debug=False) print(response_SARA_1) time.sleep(1) #2. Write to shell print("Write data to memory:") ser_sara.write(csv_string.encode()) response_SARA_2 = read_complete_response(ser_sara, wait_for_lines=["OK"], debug=False) print(response_SARA_2) #3. Send to endpoint (with device ID) print("Send data (POST REQUEST):") command= f'AT+UHTTPC={aircarto_profile_id},4,"/pro_4G/data.php?sensor_id={device_id}&datetime={influx_timestamp}","server_response.txt","sensordata_csv.json",4\r' ser_sara.write(command.encode('utf-8')) response_SARA_3 = read_complete_response(ser_sara, timeout=5, end_of_response_timeout=120, wait_for_lines=["+UUHTTPCR", "+CME ERROR", "ERROR"], debug=True) print('

') print(response_SARA_3) print("

", end="") # si on recoit la réponse UHTTPCR if "+UUHTTPCR" in response_SARA_3: print("✅ Received +UUHTTPCR response.") # Les types de réponse # 1.La commande n'a pas fonctionné # +CME ERROR: No connection to phone # +CME ERROR: Operation not allowed # 2.La commande fonctionne: elle renvoie un code # +UUHTTPCR: ,, # : 1 pour sucess et 0 pour fail # +UUHTTPCR: 0,4,1 -> OK # +UUHTTPCR: 0,4,0 -> error # Split response into lines lines = response_SARA_3.strip().splitlines() # 1.Vérifier si la réponse contient un message d'erreur CME if "+CME ERROR" in lines[-1]: print("*****") print('⛔ATTENTION: CME ERROR') print("error:", lines[-1]) print("*****") # Gestion de l'erreur spécifique if "No connection to phone" in lines[-1]: print("No connection to the phone. Retrying or reset may be required.") # Actions spécifiques pour ce type d'erreur (par exemple, réinitialiser ou tenter de reconnecter) # need to reconnect to network # and reset HTTP profile (AT+UHTTP=0) -> ne fonctionne pas.. # tester un reset avec CFUN 15 # 1.Reconnexion au réseau (AT+COPS) command = f'AT+COPS=1,2,"{selected_networkID}"\r' ser_sara.write(command.encode('utf-8')) responseReconnect = read_complete_response(ser_sara) print("Response reconnect:") print(responseReconnect) print("End response reconnect") elif "Operation not allowed" in lines[-1]: print("Operation not allowed. This may require a different configuration.") # Actions spécifiques pour ce type d'erreur else: # 2.Si la réponse contient une réponse HTTP valide # Extract HTTP response code from the last line # ATTENTION: lines[-1] renvoie l'avant dernière ligne et il peut y avoir un soucis avec le OK # rechercher plutot http_response = lines[-1] # "+UUHTTPCR: 0,4,0" parts = http_response.split(',') # 2.1 code 0 (HTTP failed) ⛔⛔⛔ if len(parts) == 3 and parts[-1] == '0': # The third value indicates success print("*****") print('⛔ATTENTION: HTTP operation failed') print("*****") update_config_sqlite('SARA_network_status', 'error') # Get error code print("Getting error code", end="") command = f'AT+UHTTPER={aircarto_profile_id}\r' ser_sara.write(command.encode('utf-8')) response_SARA_9 = read_complete_response(ser_sara, wait_for_lines=["OK","ERROR"], debug=False) print('

') print(response_SARA_9) print("

", end="") # Extract just the error code error_code = extract_error_code(response_SARA_9) if error_code is not None: # Display interpretation based on error code if error_code == 0: print('

No error detected

', end="") # N°4 INVALID SERVER HOSTNAME elif error_code == 4: print('

Error 4: Invalid server Hostname

', end="") send_error_notification(device_id, "UHTTPER (error n°4) -> Invalid Server Hostname") server_hostname_resets = reset_server_hostname(aircarto_profile_id) if server_hostname_resets: print("✅server hostname reset successfully", end="") else: print("⛔There were issues with the modem server hostname reinitialize process") # N°11 SERVER CONNECTION ERROR elif error_code == 11: print('

Error 11: AirCarto - Server connection error

', end="") hardware_reboot_success = modem_hardware_reboot() if hardware_reboot_success: print("✅Modem successfully rebooted and reinitialized") else: print("⛔There were issues with the modem reboot/reinitialize process") # N°22 PSD CSD CONNECTION NOT ESTABLISHED elif error_code == 22: print('

⚠️Error 22: PSD or CSD connection not established (SARA-R5 need to reset PDP conection)⚠️

', end="") send_error_notification(device_id, "UHTTPER (error n°22) -> PSD or CSD connection not established") psd_csd_resets = reset_PSD_CSD_connection() if psd_csd_resets: print("✅PSD CSD connection reset successfully", end="") else: print("⛔There were issues with the modem CSD PSD reinitialize process", end="") # N°26 CONNECTION TIMED OUT elif error_code == 26: print('

Error 26: Connection timed out

', end="") send_error_notification(device_id, "UHTTPER (error n°26) -> Connection timed out") # N°26 CONNECTION LOST elif error_code == 44: print('

Error 44: Connection lost

') send_error_notification(device_id, "UHTTPER (error n°44) -> Connection lost") elif error_code == 73: print('

Error 73: Secure socket connect error

', end="") else: print(f'

Unknown error code: {error_code}

', end="") else: print('

Could not extract error code from response

',end="") if "ERROR" in response_SARA_9: print('

⚠️Sara Module returned an error

',end="") print('

⚠️set up hardware reboot here???

',end="") # 2.2 code 1 (✅✅HHTP / UUHTTPCR succeded✅✅) else: # Si la commande HTTP a réussi print('✅✅HTTP operation successful.',end="") #update SARA_network_status update_config_sqlite('SARA_network_status', 'connected') #4. Read reply from server print("Reply from server:") ser_sara.write(b'AT+URDFILE="server_response.txt"\r') response_SARA_4 = read_complete_response(ser_sara, wait_for_lines=["OK"], debug=False) print('

') print(response_SARA_4) print("

", end="") #Parse the server datetime # Extract just the date from the response date_string = None date_start = response_SARA_4.find("Date: ") if date_start != -1: date_end = response_SARA_4.find("\n", date_start) date_string = response_SARA_4[date_start + 6:date_end].strip() print(f'
Server date: {date_string}
', end="") # Optionally convert to datetime object try: from datetime import datetime server_datetime = datetime.strptime( date_string, "%a, %d %b %Y %H:%M:%S %Z" ) #print(f'

Parsed datetime: {server_datetime}

') except Exception as e: print(f'

Error parsing date: {e}

') # Get RTC time from SQLite cursor.execute("SELECT * FROM timestamp_table LIMIT 1") row = cursor.fetchone() rtc_time_str = row[1] # '2025-02-07 12:30:45' or '2000-01-01 00:55:21' or 'not connected' print(f'
RTC time: {rtc_time_str}
', end="") # Compare times if both are available if server_datetime and rtc_time_str != 'not connected': try: # Convert RTC time string to datetime rtc_datetime = datetime.strptime(rtc_time_str, '%Y-%m-%d %H:%M:%S') # Calculate time difference in seconds time_diff = abs((server_datetime - rtc_datetime).total_seconds()) print(f'
Time difference: {time_diff:.2f} seconds
', end="") # Check if difference is more than 60 seconds # and update the RTC clock if time_diff > 60: print(f'
⚠️ RTC time differs from server time by {time_diff:.2f} seconds!
', end="") # Format server time for RTC update server_time_formatted = server_datetime.strftime('%Y-%m-%d %H:%M:%S') #update RTC module do not wait for answer, non blocking #/usr/bin/python3 /var/www/moduleair_pro_4g/RTC/set_with_browserTime.py '2024-01-30 12:48:39' # Launch RTC update script as non-blocking subprocess import subprocess update_command = [ "/usr/bin/python3", "/var/www/moduleair_pro_4g/RTC/set_with_browserTime.py", server_time_formatted ] # Execute the command without waiting for result subprocess.Popen(update_command, stdout=subprocess.DEVNULL, stderr=subprocess.DEVNULL) print(f'
➡️ Updating RTC with server time: {server_time_formatted}
', end="") else: print(f'
✅ RTC time is synchronized with server time (within 60 seconds)
') except Exception as e: print(f'

Error comparing times: {e}

') #Si non ne recoit pas de réponse UHTTPCR #on a peut etre une ERROR de type "+CME ERROR: No connection to phone" else: print('No UUHTTPCR response') #Vérification de l'erreur print("Getting type of error") # Split the response into lines and search for "+CME ERROR:" lines2 = response_SARA_3.strip().splitlines() for line in lines2: if "+CME ERROR" in line: error_message = line.split("+CME ERROR:")[1].strip() print("*****") print('⚠️ATTENTION: CME ERROR⚠️') print(f"Error type: {error_message}") print("*****") # Handle "No connection to phone" error if error_message == "No connection to phone": print('📞Try reconnect to network📞') #IMPORTANT! # Reconnexion au réseau (AT+COPS) #command = f'AT+COPS=1,2,{selected_networkID}\r' command = f'AT+COPS=0\r' ser_sara.write(command.encode('utf-8')) responseReconnect = read_complete_response(ser_sara, timeout=5, end_of_response_timeout=120, wait_for_lines=["OK", "+CME ERROR"], debug=True) print('

') print(responseReconnect) print("

", end="") # Handle "Operation not allowed" error if error_message == "Operation not allowed": print('❓Try Resetting the HTTP Profile❓') command = f'AT+UHTTP={aircarto_profile_id},1,"data.moduleair.fr"\r' ser_sara.write(command.encode('utf-8')) responseResetHTTP_profile = read_complete_response(ser_sara, timeout=5, end_of_response_timeout=5, wait_for_lines=["OK", "+CME ERROR"], debug=True) print('

') print(responseResetHTTP_profile) print("

", end="") if "ERROR" in line: print("⛔Attention ERROR!⛔") #Send notification (WIFI) send_error_notification(device_id, "sara_error") #Software Reboot #software_reboot_success = modem_complete_reboot_and_reinitialize(modem_version, aircarto_profile_id) #if software_reboot_success: # print("Modem successfully rebooted and reinitialized") #else: # print("There were issues with the modem reboot/reinitialize process") #Hardware Reboot hardware_reboot_success = modem_hardware_reboot() if hardware_reboot_success: print("✅Modem successfully rebooted and reinitialized") else: print("⛔There were issues with the modem reboot/reinitialize process") #5. empty json print("Empty SARA memory:", end="") ser_sara.write(b'AT+UDELFILE="sensordata_csv.json"\r') response_SARA_5 = read_complete_response(ser_sara, wait_for_lines=["OK"], debug=False) print('

') print(response_SARA_5) print("

", end="") if "+CME ERROR" in response_SARA_5: print("⛔ Attention CME ERROR ⛔") ''' _ ____ _ ___ ___ _ __ __| | _ _/ ___| _ __ ___ | |_ / __|/ _ \ '_ \ / _` | | | | \___ \| '_ \ / _ \| __| \__ \ __/ | | | (_| | | |_| |___) | |_) | (_) | |_ |___/\___|_| |_|\__,_| \__,_|____/| .__/ \___/ \__| |_| ''' if send_uSpot: print('

➡️SEND TO uSPOT SERVERS

', end="") # 1. Open sensordata_json.json (with correct data size) print("Open JSON:") payload_string = json.dumps(payload_json) # Convert dict to JSON string size_of_string = len(payload_string) command = f'AT+UDWNFILE="sensordata_json.json",{size_of_string}\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_6 = read_complete_response(ser_sara, wait_for_lines=[">"], debug=False) print(response_SARA_6) time.sleep(1) #2. Write to shell print("Write to memory:") ser_sara.write(payload_string.encode()) response_SARA_7 = read_complete_response(ser_sara, wait_for_lines=["OK"], debug=False) print(response_SARA_7) #step 4: trigger the request (http_command=1 for GET and http_command=1 for POST) print("****") print("Trigger POST REQUEST") command = f'AT+UHTTPC={uSpot_profile_id},4,"/moduleair?token=2AFF6dQk68daFZ","uSpot_server_response.txt","sensordata_json.json",4\r' ser_sara.write(command.encode('utf-8')) response_SARA_8 = read_complete_response(ser_sara, timeout=5, end_of_response_timeout=120, wait_for_lines=["+UUHTTPCR", "+CME ERROR"], debug=True) print('

') print(response_SARA_8) print("

", end="") # si on recoit la réponse UHTTPCR if "+UUHTTPCR" in response_SARA_8: print("✅ Received +UUHTTPCR response.") lines = response_SARA_8.strip().splitlines() # 1.Vérifier si la réponse contient un message d'erreur CME if "+CME ERROR" in lines[-1]: print("*****") print('⛔ATTENTION: CME ERROR') print("error:", lines[-1]) print("*****") #update status # Gestion de l'erreur spécifique if "No connection to phone" in lines[-1]: print("No connection to the phone.") elif "Operation not allowed" in lines[-1]: print("Operation not allowed. This may require a different configuration.") # Actions spécifiques pour ce type d'erreur else: # 2.Si la réponse contient une réponse HTTP valide # Extract HTTP response code from the last line # ATTENTION: lines[-1] renvoie l'avant dernière ligne et il peut y avoir un soucis avec le OK # rechercher plutot http_response = lines[-1] # "+UUHTTPCR: 0,4,0" parts = http_response.split(',') # 2.1 code 0 (HTTP failed) if len(parts) == 3 and parts[-1] == '0': # The third value indicates success print("*****") print('⛔ATTENTION: HTTP operation failed') print("*****") # Get error code print("Getting error code", end="") command = f'AT+UHTTPER={uSpot_profile_id}\r' ser_sara.write(command.encode('utf-8')) response_SARA_9b = read_complete_response(ser_sara, wait_for_lines=["OK"], debug=False) print('

') print(response_SARA_9b) print("

", end="") # Extract just the error code error_code = extract_error_code(response_SARA_9b) if error_code is not None: # Display interpretation based on error code if error_code == 0: print('

No error detected

') # INVALID SERVER HOSTNAME elif error_code == 4: print('

Error 4: Invalid server Hostname

', end="") send_error_notification(device_id, "UHTTPER (4) uSpot Invalid server Hostname") server_hostname_resets = reset_server_hostname_https(uSpot_profile_id) if server_hostname_resets: print("✅server hostname reset successfully") else: print("⛔There were issues with the modem server hostname reinitialize process") # SERVER CONNECTION ERROR elif error_code == 11: print('

Error 11: uSpot - Server connection error

', end="") elif error_code == 22: print('

Error 22: PSD or CSD connection not established

', end="") elif error_code == 26: print('

Error 26: Connection timed out

') elif error_code == 44: print('

Error 44: Connection lost

') elif error_code == 73: print('

Error 73: Secure socket connect error

', end="") send_error_notification(device_id, "uSpot - Secure socket connect error") #Software Reboot ?? else: print(f'

Unknown error code: {error_code}

',end="") else: print('

Could not extract error code from response

', end="") #Pas forcément un moyen de résoudre le soucis # 2.2 code 1 (✅✅HHTP / UUHTTPCR succeded✅✅) else: # Si la commande HTTP a réussi print('✅✅HTTP operation successful.') #4. Read reply from server print("Reply from server:") command = f'AT+URDFILE="uSpot_server_response.txt"\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_4b = read_complete_response(ser_sara, wait_for_lines=["OK"], debug=False) print('

') print(response_SARA_4b) print("

", end="") # Initialize http_response_code to 0 as a default value http_response_code = 0 # Safely extract HTTP code try: http_prefix = "HTTP/" # response_SARA_4b is a string, not a function - use .find() method http_pos = response_SARA_4b.find(http_prefix) if http_pos != -1: # Find the space after the HTTP version space_pos = response_SARA_4b.find(" ", http_pos) if space_pos != -1: # Extract the code after the space code_start = space_pos + 1 code_end = response_SARA_4b.find(" ", code_start) if code_end != -1: # Extract and convert to integer http_code_str = response_SARA_4b[code_start:code_end] http_response_code = int(http_code_str) print(f"HTTP response code: {http_response_code}") if http_response_code == 201: print('✅✅HTTP 201 ressource created.') elif http_response_code == 308: print(' ⚠️⚠️HTTP 308 Redirect, need to set up HTTPS.') server_hostname_resets = reset_server_hostname_https(uSpot_profile_id) if server_hostname_resets: print("✅server hostname reset successfully") else: print("⛔There were issues with the modem server hostname reinitialize process") except Exception as e: # If any error occurs during parsing, keep the default value print(f"Error parsing HTTP code: {e}") #5. empty json print("Empty SARA memory:", end="") command = f'AT+UDELFILE="sensordata_json.json"\r' ser_sara.write((command + '\r').encode('utf-8')) response_SARA_9t = read_complete_response(ser_sara, wait_for_lines=["OK"], debug=False) print(response_SARA_9t) # Calculate and print the elapsed time elapsed_time = time.time() - start_time_script print(f"Elapsed time: {elapsed_time:.2f} seconds") print("
", end="") print("
", end="") except Exception as e: print("An error occurred:", e) traceback.print_exc() # This prints the full traceback