#!/usr/bin/env python3 # -*- coding: utf-8 -*- """ Created on Sun Dec 27 20:43:40 2020 @author: DJ2LS """ import sys import logging, structlog, log_handler import threading import time from random import randrange import asyncio import zlib import ujson as json import static import modem import helpers import codec2 import queue import sock import uuid import base64 TESTMODE = False DATA_QUEUE_TRANSMIT = queue.Queue() DATA_QUEUE_RECEIVED = queue.Queue() class DATA(): def __init__(self): self.data_queue_transmit = DATA_QUEUE_TRANSMIT self.data_queue_received = DATA_QUEUE_RECEIVED self.data_channel_last_received = 0.0 # time of last "live sign" of a frame self.burst_ack_snr = 0 # SNR from received ack frames self.burst_ack = False # if we received an acknowledge frame for a burst self.data_frame_ack_received = False # if we received an acknowledge frame for a data frame self.rpt_request_received = False # if we received an request for repeater frames self.rpt_request_buffer = [] # requested frames, saved in a list self.rx_start_of_transmission = 0 # time of transmission start self.data_frame_bof = b'BOF' # 2 bytes for the BOF End of File indicator in a data frame self.data_frame_eof = b'EOF' # 2 bytes for the EOF End of File indicator in a data frame self.rx_n_max_retries_per_burst = 10 self.n_retries_per_burst = 0 self.received_low_bandwith_mode = False # indicator if we recevied a low bandwith mode channel ope ner self.data_channel_max_retries = 3 self.mode_list_low_bw = [14,12] self.time_list_low_bw = [3,6] self.mode_list_high_bw = [14,12,10] # mode list of available modes, each mode will be used 2times per speed level self.time_list_high_bw = [3, 6, 7] # list for time to wait for correspinding mode in seconds # mode list for selecting between low bandwith ( 500Hz ) and normal modes with higher bandwith if static.LOW_BANDWITH_MODE: self.mode_list = self.mode_list_low_bw # mode list of available modes, each mode will be used 2times per speed level self.time_list = self.time_list_low_bw # list for time to wait for correspinding mode in seconds else: self.mode_list = self.mode_list_high_bw # mode list of available modes, each mode will be used 2times per speed level self.time_list = self.time_list_high_bw # list for time to wait for correspinding mode in seconds self.speed_level = len(self.mode_list) - 1 # speed level for selecting mode self.is_IRS = False self.burst_nack = False self.burst_nack_counter = 0 self.frame_received_counter = 0 self.rx_frame_bof_received = False self.rx_frame_eof_received = False self.transmission_timeout = 30 # transmission timeout in seconds worker_thread_transmit = threading.Thread(target=self.worker_transmit, name="worker thread transmit",daemon=True) worker_thread_transmit.start() worker_thread_receive = threading.Thread(target=self.worker_receive, name="worker thread receive",daemon=True) worker_thread_receive.start() # START THE THREAD FOR THE TIMEOUT WATCHDOG watchdog_thread = threading.Thread(target=self.watchdog, name="watchdog",daemon=True) watchdog_thread.start() def worker_transmit(self): while True: data = self.data_queue_transmit.get() # [0] Command if data[0] == 'CQ': # [0] CQ self.transmit_cq() elif data[0] == 'STOP': # [0] STOP self.stop_transmission() elif data[0] == 'PING': # [0] PING # [1] dxcallsign self.transmit_ping(data[1]) elif data[0] == 'BEACON': # [0] BEACON # [1] INTERVAL int # [2] STATE bool self.run_beacon(data[1]) elif data[0] == 'ARQ_FILE': # [0] ARQ_FILE # [1] DATA_OUT bytes # [2] MODE int # [3] N_FRAMES_PER_BURST int self.open_dc_and_transmit(data[1], data[2], data[3]) elif data[0] == 'ARQ_RAW': # [0] ARQ_RAW # [1] DATA_OUT bytes # [2] MODE int # [3] N_FRAMES_PER_BURST int self.open_dc_and_transmit(data[1], data[2], data[3]) elif data[0] == 'ARQ_MESSAGE': # [0] ARQ_FILE # [1] DATA_OUT bytes # [2] MODE int # [3] N_FRAMES_PER_BURST int self.open_dc_and_transmit(data[1], data[2], data[3]) else: # wrong command print(f"wrong command {data}") pass def worker_receive(self): while True: data = self.data_queue_received.get() # [0] bytes # [1] freedv instance # [2] bytes_per_frame self.process_data(bytes_out=data[0],freedv=data[1],bytes_per_frame=data[2]) def process_data(self, bytes_out, freedv, bytes_per_frame): # forward data only if broadcast or we are the receiver # bytes_out[1:3] == callsign check for signalling frames, # bytes_out[2:4] == transmission # we could also create an own function, which returns True. frametype = int.from_bytes(bytes(bytes_out[:1]), "big") if bytes(bytes_out[1:3]) == static.MYCALLSIGN_CRC or bytes(bytes_out[2:4]) == static.MYCALLSIGN_CRC or frametype == 200 or frametype == 250: # CHECK IF FRAMETYPE IS BETWEEN 10 and 50 ------------------------ frame = frametype - 10 n_frames_per_burst = int.from_bytes(bytes(bytes_out[1:2]), "big") #frequency_offset = self.get_frequency_offset(freedv) #print("Freq-Offset: " + str(frequency_offset)) if 50 >= frametype >= 10: # get snr of received data #snr = self.calculate_snr(freedv) # we need to find a wy fixing this because of mooving to class system this isn't working anymore snr = static.SNR structlog.get_logger("structlog").debug("[TNC] RX SNR", snr=snr) # send payload data to arq checker without CRC16 self.arq_data_received(bytes(bytes_out[:-2]), bytes_per_frame, snr, freedv) # if we received the last frame of a burst or the last remaining rpt frame, do a modem unsync #if static.RX_BURST_BUFFER.count(None) <= 1 or (frame+1) == n_frames_per_burst: # structlog.get_logger("structlog").debug(f"LAST FRAME OF BURST --> UNSYNC {frame+1}/{n_frames_per_burst}") # self.c_lib.freedv_set_sync(freedv, 0) # BURST ACK elif frametype == 60: structlog.get_logger("structlog").debug("ACK RECEIVED....") self.burst_ack_received(bytes_out[:-2]) # FRAME ACK elif frametype == 61: structlog.get_logger("structlog").debug("FRAME ACK RECEIVED....") self.frame_ack_received() # FRAME RPT elif frametype == 62: structlog.get_logger("structlog").debug("REPEAT REQUEST RECEIVED....") self.burst_rpt_received(bytes_out[:-2]) # FRAME NACK elif frametype == 63: structlog.get_logger("structlog").debug("FRAME NACK RECEIVED....") self.frame_nack_received(bytes_out[:-2]) # BURST NACK elif frametype == 64: structlog.get_logger("structlog").debug("BURST NACK RECEIVED....") self.burst_nack_received(bytes_out[:-2]) # CQ FRAME elif frametype == 200: structlog.get_logger("structlog").debug("CQ RECEIVED....") self.received_cq(bytes_out[:-2]) # PING FRAME elif frametype == 210: structlog.get_logger("structlog").debug("PING RECEIVED....") # = self.get_frequency_offset(freedv) # we need to fix this later frequency_offset = 0 #print("Freq-Offset: " + str(frequency_offset)) self.received_ping(bytes_out[:-2], frequency_offset) # PING ACK elif frametype == 211: structlog.get_logger("structlog").debug("PING ACK RECEIVED....") # early detection of frequency offset #frequency_offset = int.from_bytes(bytes(bytes_out[9:11]), "big", signed=True) #print("Freq-Offset: " + str(frequency_offset)) #current_frequency = self.my_rig.get_freq() #corrected_frequency = current_frequency + frequency_offset # temporarely disabled this feature, beacuse it may cause some confusion. # we also have problems if we are operating at band bordes like 7.000Mhz # If we get a corrected frequency less 7.000 Mhz, Ham Radio devices will not transmit... #self.my_rig.set_vfo(Hamlib.RIG_VFO_A) #self.my_rig.set_freq(Hamlib.RIG_VFO_A, corrected_frequency) self.received_ping_ack(bytes_out[:-2]) # ARQ FILE TRANSFER RECEIVED! elif frametype == 225 or frametype == 227: structlog.get_logger("structlog").debug("ARQ arq_received_data_channel_opener") self.arq_received_data_channel_opener(bytes_out[:-2]) # ARQ CHANNEL IS OPENED elif frametype == 226 or frametype == 228: structlog.get_logger("structlog").debug("ARQ arq_received_channel_is_open") self.arq_received_channel_is_open(bytes_out[:-2]) # ARQ MANUAL MODE TRANSMISSION elif 230 <= frametype <= 240 : structlog.get_logger("structlog").debug("ARQ manual mode ") self.arq_received_data_channel_opener(bytes_out[:-2]) # ARQ STOP TRANSMISSION elif frametype == 249: structlog.get_logger("structlog").debug("ARQ received stop transmission") self.received_stop_transmission() # this is outdated and we may remove it elif frametype == 250: structlog.get_logger("structlog").debug("BEACON RECEIVED") self.received_beacon(bytes_out[:-2]) # TESTFRAMES elif frametype == 255: structlog.get_logger("structlog").debug("TESTFRAME RECEIVED", frame=bytes_out[:]) else: structlog.get_logger("structlog").warning("[TNC] ARQ - other frame type", frametype=frametype) else: # for debugging purposes to receive all data structlog.get_logger("structlog").debug("[TNC] Unknown frame received", frame=bytes_out[:-2]) def arq_data_received(self, data_in:bytes, bytes_per_frame:int, snr:int, freedv): data_in = bytes(data_in) global TESTMODE # only process data if we are in ARQ and BUSY state else return to quit if not static.ARQ_STATE and static.TNC_STATE != 'BUSY': return RX_PAYLOAD_PER_MODEM_FRAME = bytes_per_frame - 2 # payload per moden frame static.TNC_STATE = 'BUSY' static.ARQ_STATE = True static.INFO.append("ARQ;RECEIVING") self.data_channel_last_received = int(time.time()) # get some important data from the frame RX_N_FRAME_OF_BURST = int.from_bytes(bytes(data_in[:1]), "big") - 10 # get number of burst frame RX_N_FRAMES_PER_BURST = int.from_bytes(bytes(data_in[1:2]), "big") # get number of bursts from received frame ''' The RX burst buffer needs to have a fixed length filled with "None". We need this later for counting the "Nones" check if burst buffer has expected length else create it ''' if len(static.RX_BURST_BUFFER) != RX_N_FRAMES_PER_BURST: static.RX_BURST_BUFFER = [None] * RX_N_FRAMES_PER_BURST # append data to rx burst buffer static.RX_BURST_BUFFER[RX_N_FRAME_OF_BURST] = data_in[6:] # [frame_type][n_frames_per_burst][CRC16][CRC16] structlog.get_logger("structlog").debug("[TNC] static.RX_BURST_BUFFER", buffer=static.RX_BURST_BUFFER) ''' check if we received all frames per burst by checking if burst buffer has no more "Nones" this is the ideal case because we received all data ''' if not None in static.RX_BURST_BUFFER: # then iterate through burst buffer and stick the burst together # the temp burst buffer is needed for checking, if we already recevied data temp_burst_buffer = b'' for i in range(0,len(static.RX_BURST_BUFFER)): #static.RX_FRAME_BUFFER += static.RX_BURST_BUFFER[i] temp_burst_buffer += static.RX_BURST_BUFFER[i] # if frame buffer ends not with the current frame, we are going to append new data # if data already exists, we received the frame correctly, but the ACK frame didnt receive its destination (ISS) if not static.RX_FRAME_BUFFER.endswith(temp_burst_buffer): static.RX_FRAME_BUFFER += temp_burst_buffer static.RX_BURST_BUFFER = [] else: structlog.get_logger("structlog").info("[TNC] ARQ | RX | Frame already received - sending ACK again") static.RX_BURST_BUFFER = [] # lets check if we didnt receive a BOF and EOF yet to avoid sending ack frames if we already received all data if not self.rx_frame_bof_received and not self.rx_frame_eof_received and data_in.find(self.data_frame_eof) < 0: self.frame_received_counter += 1 if self.frame_received_counter >= 2: self.frame_received_counter = 0 self.speed_level += 1 if self.speed_level >= len(self.mode_list): self.speed_level = len(self.mode_list) - 1 # updated modes we are listening to self.set_listening_modes(self.mode_list[self.speed_level]) # create an ack frame ack_frame = bytearray(14) ack_frame[:1] = bytes([60]) ack_frame[1:3] = static.DXCALLSIGN_CRC ack_frame[3:5] = static.MYCALLSIGN_CRC ack_frame[5:6] = bytes([int(snr)]) ack_frame[6:7] = bytes([int(self.speed_level)]) # and transmit it txbuffer = [ack_frame] structlog.get_logger("structlog").info("[TNC] ARQ | RX | SENDING ACK") static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) self.calculate_transfer_rate_rx(self.rx_start_of_transmission, len(static.RX_FRAME_BUFFER)) # check if we received last frame of burst and we have "Nones" in our rx buffer # this is an indicator for missed frames. # with this way of doing this, we always MUST receive the last frame of a burst otherwise the entire # burst is lost elif RX_N_FRAME_OF_BURST == RX_N_FRAMES_PER_BURST -1: # check where a None is in our burst buffer and do frame+1, beacuse lists start at 0 missing_frames = [(frame+1) for frame, element in enumerate(static.RX_BURST_BUFFER) if element == None] structlog.get_logger("structlog").debug("all frames per burst received", frame=RX_N_FRAME_OF_BURST, frames=RX_N_FRAMES_PER_BURST) # set n frames per burst to modem # this is an idea so its not getting lost.... # we need to work on this codec2.api.freedv_set_frames_per_burst(freedv,len(missing_frames)) # then create a repeat frame rpt_frame = bytearray(14) rpt_frame[:1] = bytes([62]) rpt_frame[1:3] = static.DXCALLSIGN_CRC rpt_frame[3:5] = static.MYCALLSIGN_CRC rpt_frame[5:11] = missing_frames # and transmit it txbuffer = [rpt_frame] structlog.get_logger("structlog").info("[TNC] ARQ | RX | Requesting", frames=missing_frames) static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) self.calculate_transfer_rate_rx(self.rx_start_of_transmission, len(static.RX_FRAME_BUFFER)) # we should never reach this point else: structlog.get_logger("structlog").error("we shouldnt reach this point...", frame=RX_N_FRAME_OF_BURST, frames=RX_N_FRAMES_PER_BURST) # We have a BOF and EOF flag in our data. If we received both we received our frame. # In case of loosing data but we received already a BOF and EOF we need to make sure, we # received the complete last burst by checking it for Nones bof_position = static.RX_FRAME_BUFFER.find(self.data_frame_bof) eof_position = static.RX_FRAME_BUFFER.find(self.data_frame_eof) # get total bytes per transmission information as soon we recevied a frame with a BOF if bof_position >=0: payload = static.RX_FRAME_BUFFER[bof_position+len(self.data_frame_bof):eof_position] frame_length = int.from_bytes(payload[4:8], "big") #4:8 4bytes static.TOTAL_BYTES = frame_length compression_factor = int.from_bytes(payload[8:9], "big") #4:8 4bytes static.ARQ_COMPRESSION_FACTOR = compression_factor / 10 self.calculate_transfer_rate_rx(self.rx_start_of_transmission, len(static.RX_FRAME_BUFFER)) if bof_position >= 0 and eof_position > 0 and not None in static.RX_BURST_BUFFER: print(f"bof_position {bof_position} / eof_position {eof_position}") self.rx_frame_bof_received = True self.rx_frame_eof_received = True #now extract raw data from buffer payload = static.RX_FRAME_BUFFER[bof_position+len(self.data_frame_bof):eof_position] # get the data frame crc data_frame_crc = payload[:4] #0:4 4bytes frame_length = int.from_bytes(payload[4:8], "big") #4:8 4bytes static.TOTAL_BYTES = frame_length # 8:9 = compression factor data_frame = payload[9:] data_frame_crc_received = helpers.get_crc_32(data_frame) # check if data_frame_crc is equal with received crc if data_frame_crc == data_frame_crc_received: structlog.get_logger("structlog").info("[TNC] ARQ | RX | DATA FRAME SUCESSFULLY RECEIVED") # decompression data_frame_decompressed = zlib.decompress(data_frame) static.ARQ_COMPRESSION_FACTOR = len(data_frame_decompressed) / len(data_frame) data_frame = data_frame_decompressed # decode to utf-8 string #data_frame = data_frame.decode("utf-8") # decode json objects from data frame to inspect if we received a file or message #rawdata = json.loads(data_frame) ''' if datatype is a file, we append to RX_BUFFER, which contains files only dt = datatype --> f = file --> m = message fn = filename ft = filetype d = data crc = checksum ''' #if rawdata["dt"] == "f" or rawdata["dt"] == "m": # datatype = rawdata["dt"] #else: # datatype = "raw" uniqueid = str(uuid.uuid4()) base64_data = base64.b64encode(data_frame) base64_data = base64_data.decode("utf-8") static.RX_BUFFER.append([uniqueid, int(time.time()), static.DXCALLSIGN,static.DXGRID, base64_data]) jsondata = {"arq":"received", "uuid" : static.RX_BUFFER[i][0], "timestamp": static.RX_BUFFER[i][1], "dxcallsign": str(static.RX_BUFFER[i][2], 'utf-8'), "dxgrid": str(static.RX_BUFFER[i][3], 'utf-8'), "data": base64_data} data_out = json.dumps(jsondata) sock.SOCKET_QUEUE.put(data_out) static.INFO.append("ARQ;RECEIVING;SUCCESS") # BUILDING ACK FRAME FOR DATA FRAME ack_frame = bytearray(14) ack_frame[:1] = bytes([61]) ack_frame[1:3] = static.DXCALLSIGN_CRC ack_frame[3:5] = static.MYCALLSIGN_CRC ack_frame[5:6] = bytes([int(snr)]) ack_frame[6:7] = bytes([int(self.speed_level)]) # TRANSMIT ACK FRAME FOR BURST structlog.get_logger("structlog").info("[TNC] ARQ | RX | SENDING DATA FRAME ACK", snr=static.SNR, crc=data_frame_crc.hex()) txbuffer = [ack_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) # update our statistics AFTER the frame ACK self.calculate_transfer_rate_rx(self.rx_start_of_transmission, len(static.RX_FRAME_BUFFER)) structlog.get_logger("structlog").info("[TNC] | RX | DATACHANNEL [" + str(static.MYCALLSIGN, 'utf-8') + "]<< >>[" + str(static.DXCALLSIGN, 'utf-8') + "]", snr=static.SNR) else: static.INFO.append("ARQ;RECEIVING;FAILED") structlog.get_logger("structlog").warning("[TNC] ARQ | RX | DATA FRAME NOT SUCESSFULLY RECEIVED!", e="wrong crc", expected=data_frame_crc, received=data_frame_crc_received, overflows=static.BUFFER_OVERFLOW_COUNTER) # BUILDING NACK FRAME FOR DATA FRAME nack_frame = bytearray(14) nack_frame[:1] = bytes([63]) nack_frame[1:3] = static.DXCALLSIGN_CRC nack_frame[3:5] = static.MYCALLSIGN_CRC nack_frame[5:6] = bytes([int(snr)]) nack_frame[6:7] = bytes([int(self.speed_level)]) # TRANSMIT NACK FRAME FOR BURST txbuffer = [nack_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) # And finally we do a cleanup of our buffers and states # do cleanup only when not in testmode if not TESTMODE: self.arq_cleanup() def arq_transmit(self, data_out:bytes, mode:int, n_frames_per_burst:int): global TESTMODE self.speed_level = len(self.mode_list) - 1 # speed level for selecting mode TX_N_SENT_BYTES = 0 # already sent bytes per data frame self.tx_n_retry_of_burst = 0 # retries we already sent data TX_N_MAX_RETRIES_PER_BURST = 50 # max amount of retries we sent before frame is lost TX_N_FRAMES_PER_BURST = n_frames_per_burst # amount of n frames per burst TX_BUFFER = [] # our buffer for appending new data # TIMEOUTS BURST_ACK_TIMEOUT_SECONDS = 3.0 # timeout for burst acknowledges DATA_FRAME_ACK_TIMEOUT_SECONDS = 3.0 # timeout for data frame acknowledges RPT_ACK_TIMEOUT_SECONDS = 3.0 # timeout for rpt frame acknowledges # save len of data_out to TOTAL_BYTES for our statistics --> kBytes #static.TOTAL_BYTES = round(len(data_out) / 1024, 2) static.TOTAL_BYTES = len(data_out) frame_total_size = len(data_out).to_bytes(4, byteorder='big') static.INFO.append("ARQ;TRANSMITTING") structlog.get_logger("structlog").info("[TNC] | TX | DATACHANNEL", mode=mode, Bytes=static.TOTAL_BYTES) # compression data_frame_compressed = zlib.compress(data_out) compression_factor = len(data_out) / len(data_frame_compressed) static.ARQ_COMPRESSION_FACTOR = compression_factor compression_factor = bytes([int(static.ARQ_COMPRESSION_FACTOR * 10)]) data_out = data_frame_compressed # reset statistics tx_start_of_transmission = time.time() self.calculate_transfer_rate_tx(tx_start_of_transmission, 0, len(data_out)) # append a crc and beginn and end of file indicators frame_payload_crc = helpers.get_crc_32(data_out) # data_out = self.data_frame_bof + frame_payload_crc + data_out + self.data_frame_eof data_out = self.data_frame_bof + frame_payload_crc + frame_total_size + compression_factor + data_out + self.data_frame_eof #initial bufferposition is 0 bufferposition = 0 # iterate through data out buffer while bufferposition < len(data_out) and not self.data_frame_ack_received and static.ARQ_STATE: # we have TX_N_MAX_RETRIES_PER_BURST attempts for sending a burst for self.tx_n_retry_of_burst in range(0,TX_N_MAX_RETRIES_PER_BURST): # AUTO MODE SELECTION # mode 255 == AUTO MODE # force usage of selected mode if mode != 255: data_mode = mode structlog.get_logger("structlog").debug("FIXED MODE", mode=data_mode) else: # we are doing a modulo check of transmission retries of the actual burst # every 2nd retry which failes, decreases speedlevel by 1. # as soon as we received an ACK for the current burst, speed_level will increase # by 1. # the can be optimised by checking the optimal speed level for the current conditions ''' if not self.tx_n_retry_of_burst % 2 and self.tx_n_retry_of_burst > 0: self.speed_level -= 1 if self.speed_level < 0: self.speed_level = 0 ''' #if self.tx_n_retry_of_burst <= 1: # self.speed_level += 1 # if self.speed_level >= len(self.mode_list)-1: # self.speed_level = len(self.mode_list)-1 # if speed level is greater than our available modes, set speed level to maximum = lenght of mode list -1 print(self.mode_list) if self.speed_level >= len(self.mode_list): self.speed_level = len(self.mode_list) - 1 data_mode = self.mode_list[self.speed_level] structlog.get_logger("structlog").debug("Speed-level", level=self.speed_level, retry=self.tx_n_retry_of_burst) # payload information payload_per_frame = modem.get_bytes_per_frame(data_mode) -2 # tempbuffer list for storing our data frames tempbuffer = [] # append data frames with TX_N_FRAMES_PER_BURST to tempbuffer # this part ineeds to a completly rewrite! # TX_NF_RAMES_PER_BURST = 1 is working arqheader = bytearray() arqheader[:1] = bytes([10]) #bytes([10 + i]) arqheader[1:2] = bytes([TX_N_FRAMES_PER_BURST]) arqheader[2:4] = static.DXCALLSIGN_CRC arqheader[4:6] = static.MYCALLSIGN_CRC bufferposition_end = (bufferposition + payload_per_frame - len(arqheader)) # normal behavior if bufferposition_end <= len(data_out): frame = data_out[bufferposition:bufferposition_end] frame = arqheader + frame # this point shouldnt reached that often elif bufferposition > len(data_out): break # the last bytes of a frame else: extended_data_out = data_out[bufferposition:] extended_data_out += bytes([0]) * (payload_per_frame-len(extended_data_out)-len(arqheader)) frame = arqheader + extended_data_out # append frame to tempbuffer for transmission tempbuffer.append(frame) structlog.get_logger("structlog").debug("[TNC] tempbuffer", tempbuffer=tempbuffer) structlog.get_logger("structlog").info("[TNC] ARQ | TX | FRAMES", mode=data_mode, fpb=TX_N_FRAMES_PER_BURST, retry=self.tx_n_retry_of_burst) # we need to set our TRANSMITTING flag before we are adding an object the transmit queue # this is not that nice, we could improve this somehow static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([data_mode,1,0,tempbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) # after transmission finished wait for an ACK or RPT frame ''' burstacktimeout = time.time() + BURST_ACK_TIMEOUT_SECONDS + 100 while not self.burst_ack and not self.burst_nack and not self.rpt_request_received and not self.data_frame_ack_received and time.time() < burstacktimeout and static.ARQ_STATE: time.sleep(0.01) ''' #burstacktimeout = time.time() + BURST_ACK_TIMEOUT_SECONDS + 100 while not self.burst_ack and not self.burst_nack and not self.rpt_request_received and not self.data_frame_ack_received and static.ARQ_STATE: time.sleep(0.01) # once we received a burst ack, reset its state and break the RETRIES loop if self.burst_ack: self.burst_ack = False # reset ack state self.tx_n_retry_of_burst = 0 # reset retries break #break retry loop if self.burst_nack: self.burst_nack = False #reset nack state # not yet implemented if self.rpt_request_received: pass if self.data_frame_ack_received: break #break retry loop # we need this part for leaving the repeat loop # static.ARQ_STATE == 'DATA' --> when stopping transmission manually if not static.ARQ_STATE: #print("not ready for data...leaving loop....") break self.calculate_transfer_rate_tx(tx_start_of_transmission, bufferposition_end, len(data_out)) # NEXT ATTEMPT structlog.get_logger("structlog").debug("ATTEMPT", retry=self.tx_n_retry_of_burst, maxretries=TX_N_MAX_RETRIES_PER_BURST,overflows=static.BUFFER_OVERFLOW_COUNTER) # update buffer position bufferposition = bufferposition_end # # update stats self.calculate_transfer_rate_tx(tx_start_of_transmission, bufferposition_end, len(data_out)) #GOING TO NEXT ITERATION if self.data_frame_ack_received: static.INFO.append("ARQ;TRANSMITTING;SUCCESS") structlog.get_logger("structlog").info("ARQ | TX | DATA TRANSMITTED!", BytesPerMinute=static.ARQ_BYTES_PER_MINUTE, BitsPerSecond=static.ARQ_BITS_PER_SECOND, overflows=static.BUFFER_OVERFLOW_COUNTER) else: static.INFO.append("ARQ;TRANSMITTING;FAILED") structlog.get_logger("structlog").info("ARQ | TX | TRANSMISSION FAILED OR TIME OUT!", overflows=static.BUFFER_OVERFLOW_COUNTER) # and last but not least doing a state cleanup # do cleanup only when not in testmode if not TESTMODE: self.arq_cleanup() # quit after transmission if TESTMODE: import os os._exit(0) # signalling frames received def burst_ack_received(self, data_in:bytes): # increase speed level if we received a burst ack #self.speed_level += 1 #if self.speed_level >= len(self.mode_list)-1: # self.speed_level = len(self.mode_list)-1 # only process data if we are in ARQ and BUSY state if static.ARQ_STATE: self.burst_ack = True # Force data loops of TNC to stop and continue with next frame self.data_channel_last_received = int(time.time()) # we need to update our timeout timestamp self.burst_ack_snr= int.from_bytes(bytes(data_in[5:6]), "big") self.speed_level= int.from_bytes(bytes(data_in[6:7]), "big") print(self.speed_level) self.burst_nack_counter = 0 # signalling frames received def burst_nack_received(self, data_in:bytes): # increase speed level if we received a burst ack #self.speed_level += 1 #if self.speed_level >= len(self.mode_list)-1: # self.speed_level = len(self.mode_list)-1 # only process data if we are in ARQ and BUSY state if static.ARQ_STATE: self.burst_nack = True # Force data loops of TNC to stop and continue with next frame self.data_channel_last_received = int(time.time()) # we need to update our timeout timestamp self.burst_ack_snr= int.from_bytes(bytes(data_in[5:6]), "big") self.speed_level= int.from_bytes(bytes(data_in[6:7]), "big") self.burst_nack_counter += 1 print(self.speed_level) def frame_ack_received(self): # only process data if we are in ARQ and BUSY state if static.ARQ_STATE: self.data_frame_ack_received = True # Force data loops of TNC to stop and continue with next frame self.data_channel_last_received = int(time.time()) # we need to update our timeout timestamp def frame_nack_received(self, data_in:bytes): static.INFO.append("ARQ;TRANSMITTING;FAILED") if not TESTMODE: self.arq_cleanup() def burst_rpt_received(self, data_in:bytes): # only process data if we are in ARQ and BUSY state if static.ARQ_STATE and static.TNC_STATE == 'BUSY': self.rpt_request_received = True self.data_channel_last_received = int(time.time()) # we need to update our timeout timestamp self.rpt_request_buffer = [] missing_area = bytes(data_in[3:12]) # 1:9 for i in range(0, 6, 2): if not missing_area[i:i + 2].endswith(b'\x00\x00'): missing = missing_area[i:i + 2] self.rpt_request_buffer.insert(0, missing) # ############################################################################################################ # ARQ DATA CHANNEL HANDLER # ############################################################################################################ def open_dc_and_transmit(self, data_out:bytes, mode:int, n_frames_per_burst:int): static.TNC_STATE = 'BUSY' self.datachannel_timeout = False # we need to compress data for gettin a compression factor. # so we are compressing twice. This is not that nice and maybe theres another way # for calculating transmission statistics static.ARQ_COMPRESSION_FACTOR = len(data_out) / len(zlib.compress(data_out)) self.arq_open_data_channel(mode, n_frames_per_burst) # wait until data channel is open while not static.ARQ_STATE and not self.datachannel_timeout: time.sleep(0.01) if static.ARQ_STATE: self.arq_transmit(data_out, mode, n_frames_per_burst) else: return False def arq_open_data_channel(self, mode:int, n_frames_per_burst:int): self.is_IRS = False self.data_channel_last_received = int(time.time()) if static.LOW_BANDWITH_MODE and mode == 255: frametype = bytes([227]) structlog.get_logger("structlog").debug("requesting low bandwith mode") else: frametype = bytes([225]) structlog.get_logger("structlog").debug("requesting high bandwith mode") if 230 <= mode <= 240: structlog.get_logger("structlog").debug("requesting manual mode --> not yet implemented ") frametype = bytes([mode]) connection_frame = bytearray(14) connection_frame[:1] = frametype connection_frame[1:3] = static.DXCALLSIGN_CRC connection_frame[3:5] = static.MYCALLSIGN_CRC connection_frame[5:11] = static.MYCALLSIGN connection_frame[13:14] = bytes([n_frames_per_burst]) while not static.ARQ_STATE: time.sleep(0.01) for attempt in range(1,self.data_channel_max_retries+1): static.INFO.append("DATACHANNEL;OPENING") structlog.get_logger("structlog").info("[TNC] ARQ | DATA | TX | [" + str(static.MYCALLSIGN, 'utf-8') + "]>> <<[" + str(static.DXCALLSIGN, 'utf-8') + "]", attempt=str(attempt) + "/" + str(self.data_channel_max_retries)) txbuffer = [connection_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) timeout = time.time() + 3 while time.time() < timeout: time.sleep(0.01) # break if data channel is openend if static.ARQ_STATE: break if static.ARQ_STATE: break if not static.ARQ_STATE and attempt == self.data_channel_max_retries: static.INFO.append("DATACHANNEL;FAILED") structlog.get_logger("structlog").warning("[TNC] ARQ | TX | DATA [" + str(static.MYCALLSIGN, 'utf-8') + "]>>X<<[" + str(static.DXCALLSIGN, 'utf-8') + "]") self.datachannel_timeout = True if not TESTMODE: self.arq_cleanup() return False #sys.exit() # close thread and so connection attempts def arq_received_data_channel_opener(self, data_in:bytes): self.is_IRS = True static.INFO.append("DATACHANNEL;RECEIVEDOPENER") static.DXCALLSIGN_CRC = bytes(data_in[3:5]) static.DXCALLSIGN = bytes(data_in[5:11]).rstrip(b'\x00') n_frames_per_burst = int.from_bytes(bytes(data_in[13:14]), "big") frametype = int.from_bytes(bytes(data_in[:1]), "big") #check if we received low bandwith mode if frametype == 225: self.received_low_bandwith_mode = False self.mode_list = self.mode_list_high_bw self.time_list = self.time_list_high_bw self.speed_level = len(self.mode_list) - 1 else: self.received_low_bandwith_mode = True self.mode_list = self.mode_list_low_bw self.time_list = self.time_list_low_bw self.speed_level = len(self.mode_list) - 1 if 230 <= frametype <= 240: print("manual mode request") # updated modes we are listening to self.set_listening_modes(self.mode_list[self.speed_level]) helpers.add_to_heard_stations(static.DXCALLSIGN,static.DXGRID, 'DATA-CHANNEL', static.SNR, static.FREQ_OFFSET, static.HAMLIB_FREQUENCY) structlog.get_logger("structlog").info("[TNC] ARQ | DATA | RX | [" + str(static.MYCALLSIGN, 'utf-8') + "]>> <<[" + str(static.DXCALLSIGN, 'utf-8') + "]", bandwith="wide") static.ARQ_STATE = True static.TNC_STATE = 'BUSY' self.reset_statistics() self.data_channel_last_received = int(time.time()) # check if we are in low bandwith mode if static.LOW_BANDWITH_MODE or self.received_low_bandwith_mode: frametype = bytes([228]) structlog.get_logger("structlog").debug("responding with low bandwith mode") else: frametype = bytes([226]) structlog.get_logger("structlog").debug("responding with high bandwith mode") connection_frame = bytearray(14) connection_frame[:1] = frametype connection_frame[1:3] = static.DXCALLSIGN_CRC connection_frame[3:5] = static.MYCALLSIGN_CRC connection_frame[13:14] = bytes([static.ARQ_PROTOCOL_VERSION]) #crc8 of version for checking protocol version txbuffer = [connection_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) structlog.get_logger("structlog").info("[TNC] ARQ | DATA | RX | [" + str(static.MYCALLSIGN, 'utf-8') + "]>>|<<[" + str(static.DXCALLSIGN, 'utf-8') + "]", bandwith="wide", snr=static.SNR) # set start of transmission for our statistics self.rx_start_of_transmission = time.time() def arq_received_channel_is_open(self, data_in:bytes): protocol_version = int.from_bytes(bytes(data_in[13:14]), "big") if protocol_version == static.ARQ_PROTOCOL_VERSION: static.INFO.append("DATACHANNEL;OPEN") static.DXCALLSIGN_CRC = bytes(data_in[3:5]) frametype = int.from_bytes(bytes(data_in[:1]), "big") if frametype == 228: self.received_low_bandwith_mode = True self.mode_list = self.mode_list_low_bw self.time_list = self.time_list_low_bw self.speed_level = len(self.mode_list) - 1 structlog.get_logger("structlog").debug("low bandwith mode", modes=self.mode_list) else: self.received_low_bandwith_mode = False self.mode_list = self.mode_list_high_bw self.time_list = self.time_list_high_bw self.speed_level = len(self.mode_list) - 1 structlog.get_logger("structlog").debug("high bandwith mode", modes=self.mode_list) helpers.add_to_heard_stations(static.DXCALLSIGN,static.DXGRID, 'DATA-CHANNEL', static.SNR, static.FREQ_OFFSET, static.HAMLIB_FREQUENCY) structlog.get_logger("structlog").info("[TNC] ARQ | DATA | TX | [" + str(static.MYCALLSIGN, 'utf-8') + "]>>|<<[" + str(static.DXCALLSIGN, 'utf-8') + "]", snr=static.SNR) # as soon as we set ARQ_STATE to DATA, transmission starts static.ARQ_STATE = True self.data_channel_last_received = int(time.time()) else: static.TNC_STATE = 'IDLE' static.ARQ_STATE = False static.INFO.append("PROTOCOL;VERSION_MISSMATCH") structlog.get_logger("structlog").warning("protocol version missmatch", received=protocol_version, own=static.ARQ_PROTOCOL_VERSION) self.arq_cleanup() # ---------- PING def transmit_ping(self, callsign:str): static.DXCALLSIGN = bytes(callsign, 'utf-8').rstrip(b'\x00') static.DXCALLSIGN_CRC = helpers.get_crc_16(static.DXCALLSIGN) static.INFO.append("PING;SENDING") structlog.get_logger("structlog").info("[TNC] PING REQ [" + str(static.MYCALLSIGN, 'utf-8') + "] >>> [" + str(static.DXCALLSIGN, 'utf-8') + "]" ) ping_frame = bytearray(14) ping_frame[:1] = bytes([210]) ping_frame[1:3] = static.DXCALLSIGN_CRC ping_frame[3:5] = static.MYCALLSIGN_CRC ping_frame[5:11] = static.MYCALLSIGN txbuffer = [ping_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) def received_ping(self, data_in:bytes, frequency_offset:str): static.DXCALLSIGN_CRC = bytes(data_in[3:5]) static.DXCALLSIGN = bytes(data_in[5:11]).rstrip(b'\x00') helpers.add_to_heard_stations(static.DXCALLSIGN,static.DXGRID, 'PING', static.SNR, static.FREQ_OFFSET, static.HAMLIB_FREQUENCY) static.INFO.append("PING;RECEIVING") structlog.get_logger("structlog").info("[TNC] PING REQ [" + str(static.MYCALLSIGN, 'utf-8') + "] <<< [" + str(static.DXCALLSIGN, 'utf-8') + "]", snr=static.SNR ) ping_frame = bytearray(14) ping_frame[:1] = bytes([211]) ping_frame[1:3] = static.DXCALLSIGN_CRC ping_frame[3:5] = static.MYCALLSIGN_CRC ping_frame[5:11] = static.MYGRID ping_frame[11:13] = frequency_offset.to_bytes(2, byteorder='big', signed=True) txbuffer = [ping_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) def received_ping_ack(self, data_in:bytes): static.DXCALLSIGN_CRC = bytes(data_in[3:5]) static.DXGRID = bytes(data_in[5:11]).rstrip(b'\x00') helpers.add_to_heard_stations(static.DXCALLSIGN,static.DXGRID, 'PING-ACK', static.SNR, static.FREQ_OFFSET, static.HAMLIB_FREQUENCY) static.INFO.append("PING;RECEIVEDACK") structlog.get_logger("structlog").info("[TNC] PING ACK [" + str(static.MYCALLSIGN, 'utf-8') + "] >|< [" + str(static.DXCALLSIGN, 'utf-8') + "]", snr=static.SNR ) static.TNC_STATE = 'IDLE' def stop_transmission(self): structlog.get_logger("structlog").warning("[TNC] Stopping transmission!") stop_frame = bytearray(14) stop_frame[:1] = bytes([249]) stop_frame[1:3] = static.DXCALLSIGN_CRC stop_frame[3:5] = static.MYCALLSIGN_CRC txbuffer = [stop_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,2,250,txbuffer]) while static.TRANSMITTING: time.sleep(0.01) static.TNC_STATE = 'IDLE' static.ARQ_STATE = False static.INFO.append("TRANSMISSION;STOPPED") self.arq_cleanup() def received_stop_transmission(self): structlog.get_logger("structlog").warning("[TNC] Stopping transmission!") static.TNC_STATE = 'IDLE' static.ARQ_STATE = False static.INFO.append("TRANSMISSION;STOPPED") self.arq_cleanup() # ----------- BROADCASTS def run_beacon(self, interval:int): try: structlog.get_logger("structlog").warning("[TNC] Starting beacon!", interval=interval) while static.BEACON_STATE and not static.ARQ_STATE: beacon_frame = bytearray(14) beacon_frame[:1] = bytes([250]) beacon_frame[1:7] = static.MYCALLSIGN beacon_frame[7:13] = static.MYGRID static.INFO.append("BEACON;SENDING") structlog.get_logger("structlog").info("[TNC] Sending beacon!", interval=interval) txbuffer = [beacon_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) time.sleep(interval) #threading.Event().wait(interval) except Exception as e: print(e) def received_beacon(self, data_in:bytes): # here we add the received station to the heard stations buffer dxcallsign = bytes(data_in[2:8]).rstrip(b'\x00') dxgrid = bytes(data_in[8:14]).rstrip(b'\x00') static.INFO.append("BEACON;RECEIVING") structlog.get_logger("structlog").info("[TNC] BEACON RCVD [" + str(dxcallsign, 'utf-8') + "]["+ str(dxgrid, 'utf-8') +"] ", snr=static.SNR) helpers.add_to_heard_stations(dxcallsign,dxgrid, 'BEACON', static.SNR, static.FREQ_OFFSET, static.HAMLIB_FREQUENCY) def transmit_cq(self): logging.info("CQ CQ CQ") static.INFO.append("CQ;SENDING") cq_frame = bytearray(14) cq_frame[:1] = bytes([200]) cq_frame[1:7] = static.MYCALLSIGN cq_frame[7:13] = static.MYGRID txbuffer = [cq_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,2,500,txbuffer]) # wait while transmitting while static.TRANSMITTING: time.sleep(0.01) return def received_cq(self, data_in:bytes): # here we add the received station to the heard stations buffer dxcallsign = bytes(data_in[1:7]).rstrip(b'\x00') dxgrid = bytes(data_in[7:13]).rstrip(b'\x00') static.INFO.append("CQ;RECEIVING") structlog.get_logger("structlog").info("[TNC] CQ RCVD [" + str(dxcallsign, 'utf-8') + "]["+ str(dxgrid, 'utf-8') +"] ", snr=static.SNR) helpers.add_to_heard_stations(dxcallsign,dxgrid, 'CQ CQ CQ', static.SNR, static.FREQ_OFFSET, static.HAMLIB_FREQUENCY) # ------------ CALUCLATE TRANSFER RATES def calculate_transfer_rate_rx(self, rx_start_of_transmission:float, receivedbytes:int) -> list: try: static.ARQ_TRANSMISSION_PERCENT = int((receivedbytes*static.ARQ_COMPRESSION_FACTOR / (static.TOTAL_BYTES)) * 100) transmissiontime = time.time() - self.rx_start_of_transmission if receivedbytes > 0: static.ARQ_BITS_PER_SECOND = int((receivedbytes*8) / transmissiontime) static.ARQ_BYTES_PER_MINUTE = int((receivedbytes) / (transmissiontime/60)) else: static.ARQ_BITS_PER_SECOND = 0 static.ARQ_BYTES_PER_MINUTE = 0 except: static.ARQ_TRANSMISSION_PERCENT = 0.0 static.ARQ_BITS_PER_SECOND = 0 static.ARQ_BYTES_PER_MINUTE = 0 return [static.ARQ_BITS_PER_SECOND, \ static.ARQ_BYTES_PER_MINUTE, \ static.ARQ_TRANSMISSION_PERCENT] def reset_statistics(self): # reset ARQ statistics static.ARQ_BYTES_PER_MINUTE_BURST = 0 static.ARQ_BYTES_PER_MINUTE = 0 static.ARQ_BITS_PER_SECOND_BURST = 0 static.ARQ_BITS_PER_SECOND = 0 static.ARQ_TRANSMISSION_PERCENT = 0 static.TOTAL_BYTES = 0 def calculate_transfer_rate_tx(self, tx_start_of_transmission:float, sentbytes:int, tx_buffer_length:int) -> list: try: static.ARQ_TRANSMISSION_PERCENT = int((sentbytes / tx_buffer_length) * 100) transmissiontime = time.time() - tx_start_of_transmission if sentbytes > 0: static.ARQ_BITS_PER_SECOND = int((sentbytes*8) / transmissiontime) # Bits per Second static.ARQ_BYTES_PER_MINUTE = int((sentbytes) / (transmissiontime/60)) #Bytes per Minute else: static.ARQ_BITS_PER_SECOND = 0 static.ARQ_BYTES_PER_MINUTE = 0 except: static.ARQ_TRANSMISSION_PERCENT = 0.0 static.ARQ_BITS_PER_SECOND = 0 static.ARQ_BYTES_PER_MINUTE = 0 return [static.ARQ_BITS_PER_SECOND, \ static.ARQ_BYTES_PER_MINUTE, \ static.ARQ_TRANSMISSION_PERCENT] # ----------------------CLEANUP AND RESET FUNCTIONS def arq_cleanup(self): structlog.get_logger("structlog").debug("cleanup") self.rx_frame_bof_received = False self.rx_frame_eof_received = False static.TNC_STATE = 'IDLE' static.ARQ_STATE = False self.burst_ack = False self.rpt_request_received = False self.data_frame_ack_received = False static.RX_BURST_BUFFER = [] static.RX_FRAME_BUFFER = b'' self.burst_ack_snr= 255 # reset modem receiving state to reduce cpu load modem.RECEIVE_DATAC1 = False modem.RECEIVE_DATAC3 = False # reset buffer overflow counter static.BUFFER_OVERFLOW_COUNTER = [0,0,0] self.is_IRS = False self.burst_nack = False self.burst_nack_counter = 0 self.frame_received_counter = 0 self.speed_level = len(self.mode_list) - 1 # low bandwith mode indicator self.received_low_bandwith_mode = False # reset retry counter for rx channel / burst self.n_retries_per_burst = 0 def arq_reset_ack(self,state:bool): self.burst_ack = state self.rpt_request_received = state self.data_frame_ack_received = state def set_listening_modes(self, mode): # set modes we want listening to mode_name = codec2.freedv_get_mode_name_by_value(mode) if mode_name == 'datac1': modem.RECEIVE_DATAC1 = True structlog.get_logger("structlog").debug("changing listening data mode", mode="datac1") elif mode_name == 'datac3': modem.RECEIVE_DATAC3 = True structlog.get_logger("structlog").debug("changing listening data mode", mode="datac3") elif mode_name == 'allmodes': modem.RECEIVE_DATAC1 = True modem.RECEIVE_DATAC3 = True structlog.get_logger("structlog").debug("changing listening data mode", mode="datac1/datac3") # ------------------------- WATCHDOG FUNCTIONS FOR TIMER def watchdog(self): """ Author: DJ2LS watchdog master function. Frome here we call the watchdogs """ while True: time.sleep(0.1) self.data_channel_keep_alive_watchdog() self.burst_watchdog() def burst_watchdog(self): # IRS SIDE if static.ARQ_STATE and static.TNC_STATE == 'BUSY' and self.is_IRS: if self.data_channel_last_received + self.time_list[self.speed_level] > time.time(): #print((self.data_channel_last_received + self.time_list[self.speed_level])-time.time()) pass else: print("TIMEOUT") self.frame_received_counter = 0 self.speed_level -= 1 if self.speed_level <= 0: self.speed_level = 0 # updated modes we are listening to self.set_listening_modes(self.mode_list[self.speed_level]) # BUILDING NACK FRAME FOR DATA FRAME burst_nack_frame = bytearray(14) burst_nack_frame[:1] = bytes([64]) burst_nack_frame[1:3] = static.DXCALLSIGN_CRC burst_nack_frame[3:5] = static.MYCALLSIGN_CRC burst_nack_frame[5:6] = bytes([0]) burst_nack_frame[6:7] = bytes([int(self.speed_level)]) # TRANSMIT NACK FRAME FOR BURST txbuffer = [burst_nack_frame] static.TRANSMITTING = True modem.MODEM_TRANSMIT_QUEUE.put([14,1,0,txbuffer]) # wait while transmitting #while static.TRANSMITTING: # #time.sleep(0.01) # self.data_channel_last_received = time.time() self.data_channel_last_received = time.time() self.n_retries_per_burst += 1 if self.n_retries_per_burst >= self.rx_n_max_retries_per_burst: self.arq_cleanup() print("RX TIMEOUT!!!!") #print(self.n_retries_per_burst) def data_channel_keep_alive_watchdog(self): """ Author: DJ2LS """ # and not static.ARQ_SEND_KEEP_ALIVE: if static.ARQ_STATE and static.TNC_STATE == 'BUSY': time.sleep(0.01) if self.data_channel_last_received + self.transmission_timeout > time.time(): time.sleep(0.01) #print(self.data_channel_last_received + self.transmission_timeout - time.time()) #pass else: self.data_channel_last_received = 0 logging.info("DATA [" + str(static.MYCALLSIGN, 'utf-8') + "]<>[" + str(static.DXCALLSIGN, 'utf-8') + "]") static.INFO.append("ARQ;RECEIVING;FAILED") if not TESTMODE: self.arq_cleanup()