FreeDATA/tests/test_p2p_connection.py
2024-03-19 13:01:25 +01:00

190 lines
7.3 KiB
Python

import sys
import time
sys.path.append('modem')
import unittest
import unittest.mock
from config import CONFIG
import helpers
import queue
import threading
import base64
from command_p2p_connection import P2PConnectionCommand
from state_manager import StateManager
from frame_dispatcher import DISPATCHER
import random
import structlog
import numpy as np
from event_manager import EventManager
from state_manager import StateManager
from data_frame_factory import DataFrameFactory
import codec2
import p2p_connection
from socket_interface_commands import SocketCommandHandler
class TestModem:
def __init__(self, event_q, state_q):
self.data_queue_received = queue.Queue()
self.demodulator = unittest.mock.Mock()
self.event_manager = EventManager([event_q])
self.logger = structlog.get_logger('Modem')
self.states = StateManager(state_q)
def getFrameTransmissionTime(self, mode):
samples = 0
c2instance = codec2.open_instance(mode.value)
samples += codec2.api.freedv_get_n_tx_preamble_modem_samples(c2instance)
samples += codec2.api.freedv_get_n_tx_modem_samples(c2instance)
samples += codec2.api.freedv_get_n_tx_postamble_modem_samples(c2instance)
time = samples / 8000
return time
def transmit(self, mode, repeats: int, repeat_delay: int, frames: bytearray) -> bool:
# Simulate transmission time
tx_time = self.getFrameTransmissionTime(mode) + 0.1 # PTT
self.logger.info(f"TX {tx_time} seconds...")
threading.Event().wait(tx_time)
transmission = {
'mode': mode,
'bytes': frames,
}
self.data_queue_received.put(transmission)
class TestP2PConnectionSession(unittest.TestCase):
@classmethod
def setUpClass(cls):
config_manager = CONFIG('modem/config.ini.example')
cls.config = config_manager.read()
cls.logger = structlog.get_logger("TESTS")
cls.frame_factory = DataFrameFactory(cls.config)
# ISS
cls.iss_config_manager = config_manager
cls.iss_state_manager = StateManager(queue.Queue())
cls.iss_event_manager = EventManager([queue.Queue()])
cls.iss_event_queue = queue.Queue()
cls.iss_state_queue = queue.Queue()
cls.iss_p2p_data_queue = queue.Queue()
cls.iss_modem = TestModem(cls.iss_event_queue, cls.iss_state_queue)
cls.iss_frame_dispatcher = DISPATCHER(cls.config,
cls.iss_event_manager,
cls.iss_state_manager,
cls.iss_modem)
#cls.iss_socket_interface_handler = SocketInterfaceHandler(cls.iss_modem, cls.iss_config_manager, cls.iss_state_manager, cls.iss_event_manager)
#cls.iss_socket_command_handler = CommandSocket(TestSocket(), '127.0.0.1', 51234)
# IRS
cls.irs_state_manager = StateManager(queue.Queue())
cls.irs_event_manager = EventManager([queue.Queue()])
cls.irs_event_queue = queue.Queue()
cls.irs_state_queue = queue.Queue()
cls.irs_p2p_data_queue = queue.Queue()
cls.irs_modem = TestModem(cls.irs_event_queue, cls.irs_state_queue)
cls.irs_frame_dispatcher = DISPATCHER(cls.config,
cls.irs_event_manager,
cls.irs_state_manager,
cls.irs_modem)
# Frame loss probability in %
cls.loss_probability = 30
cls.channels_running = True
def channelWorker(self, modem_transmit_queue: queue.Queue, frame_dispatcher: DISPATCHER):
while self.channels_running:
# Transfer data between both parties
try:
transmission = modem_transmit_queue.get(timeout=1)
if random.randint(0, 100) < self.loss_probability:
self.logger.info(f"[{threading.current_thread().name}] Frame lost...")
continue
frame_bytes = transmission['bytes']
frame_dispatcher.new_process_data(frame_bytes, None, len(frame_bytes), 0, 0)
except queue.Empty:
continue
self.logger.info(f"[{threading.current_thread().name}] Channel closed.")
def waitForSession(self, q, outbound=False):
key = 'arq-transfer-outbound' if outbound else 'arq-transfer-inbound'
while True and self.channels_running:
ev = q.get()
if key in ev and ('success' in ev[key] or 'ABORTED' in ev[key]):
self.logger.info(f"[{threading.current_thread().name}] {key} session ended.")
break
def establishChannels(self):
self.channels_running = True
self.iss_to_irs_channel = threading.Thread(target=self.channelWorker,
args=[self.iss_modem.data_queue_received,
self.irs_frame_dispatcher],
name="ISS to IRS channel")
self.iss_to_irs_channel.start()
self.irs_to_iss_channel = threading.Thread(target=self.channelWorker,
args=[self.irs_modem.data_queue_received,
self.iss_frame_dispatcher],
name="IRS to ISS channel")
self.irs_to_iss_channel.start()
def waitAndCloseChannels(self):
self.waitForSession(self.iss_event_queue, True)
self.channels_running = False
self.waitForSession(self.irs_event_queue, False)
self.channels_running = False
def generate_random_string(self, min_length, max_length):
import string
length = random.randint(min_length, max_length)
return ''.join(random.choices(string.ascii_letters, k=length))#
def testARQSessionSmallPayload(self):
# set Packet Error Rate (PER) / frame loss probability
self.loss_probability = 0
self.establishChannels()
handler = SocketCommandHandler(TestSocket(self), self.iss_modem, self.iss_config_manager, self.iss_state_manager, self.iss_event_manager)
handler.handle_connect(["AA1AAA-1", "BB2BBB-2"])
self.connected_event = threading.Event()
self.connected_event.wait()
for session_id in self.iss_state_manager.p2p_connection_sessions:
session = self.iss_state_manager.get_p2p_connection_session(session_id)
# Generate and add 5 random entries to the queue
for _ in range(5):
random_entry = self.generate_random_string(2, 11)
session.p2p_data_tx_queue.put(random_entry)
self.waitAndCloseChannels()
class TestSocket:
def __init__(self, test_class):
self.sent_data = [] # To capture data sent through this socket
self.test_class = test_class
def sendall(self, data):
print(f"Mock sendall called with data: {data}")
self.sent_data.append(data)
self.event_handler(data)
def event_handler(self, data):
if b'CONNECTED AA1AAA-1 BB2BBB-2 0\r\n' in self.sent_data:
self.test_class.connected_event.set()
if __name__ == '__main__':
unittest.main()