ba-thesis/sw/utility/simulation.py

"""This file contains utility functions relating to tests and simulations of the decoders."""
import time

import numpy as np
import typing
from tqdm import tqdm
from timeit import default_timer
import signal
from dataclasses import dataclass
import pickle
import os.path
from pathlib import Path
import spdlog as spd

from utility import noise


def count_bit_errors(d: np.array, d_hat: np.array) -> int:
    """Count the number of wrong bits in a decoded codeword.

    :param d: Originally sent data
    :param d_hat: Received data
    :return: Number of bit errors
    """
    return np.sum(d != d_hat)


# TODO: Write unit tests
class Simulator:
    """Class allowing for saving of simulations state.

    Given a list of decoders, this class allows for simulating the Bit-Error-Rates of each decoder for various SNRs.

    The functionality implemented by this class could be achieved by a bunch of loops and a function.
    However, storing the state of the simulation as member variables allows for pausing and resuming the simulation
    at a later state.
    """
    def __init__(self, n: int, k: int,
                 decoders: typing.Sequence[typing.Any],
                 SNRs: typing.Sequence[float],
                 target_frame_errors: int):
        """Construct and object of type simulator.

        :param n: Number of bits in a codeword
        :param k: Number of bits in a dataword
        :param decoders: Sequence of decoders to test
        :param SNRs: Sequence of SNRs for which the BERs should be calculated
        :param target_frame_errors: Number of frame errors after which to stop the simulation
        """
        # Simulation parameters

        self._n = n
        self._k = k
        self._decoders = decoders
        self._SNRs = SNRs
        self._target_frame_errors = target_frame_errors

        self._x = np.zeros(self._n)
        self._x_bpsk = 1 - 2 * self._x  # Map x from [0, 1]^n to [-1, 1]^n

        # Simulation state

        self._current_decoder_index = 0
        self._current_SNRs_index = 0

        self._curr_num_frame_errors = 0
        self._curr_num_bit_errors = 0
        self._curr_num_iterations = 0

        # Results & Miscellaneous

        self._sim_running = False
        self._sim_done = False
        self._BERs = [[]]

    def _simulate_transmission(self) -> int:
        """Simulate the transmission of a single codeword.

        :return: Number of bit errors that occurred
        """
        SNR = self._SNRs[self._current_SNRs_index]
        decoder = self._decoders[self._current_decoder_index]

        y = noise.add_awgn(self._x_bpsk, SNR, self._n, self._k)
        x_hat = decoder.decode(y)

        return count_bit_errors(self._x, x_hat)

    def _update_statistics(self, bit_errors: int) -> None:
        """Update the statistics of the simulator.

        :param bit_errors: Number of bit errors that occurred during the last transmission
        """
        self._curr_num_iterations += 1

        if bit_errors > 0:
            self._curr_num_frame_errors += 1
            self._curr_num_bit_errors += bit_errors

    def _advance_state(self) -> None:
        """Advance the state of the simulator.

        This function also appends a new BER value to the self._BERs array
        if the number of target frame errors has been reached
        """
        if self._curr_num_frame_errors >= self._target_frame_errors:
            # TODO: Properly handle the multiple decoders
            self._BERs[self._current_decoder_index]\
                .append(self._curr_num_bit_errors / (self._curr_num_iterations * self._n))

            self._curr_num_frame_errors = 0
            self._curr_num_bit_errors = 0
            self._curr_num_iterations = 0

            if self._current_SNRs_index < len(self._SNRs)-1:
                self._current_SNRs_index += 1
            else:
                if self._current_decoder_index < len(self._decoders)-1:
                    self._current_decoder_index += 1
                    self._current_SNRs_index = 0
                    self._BERs.append([])
                else:
                    self._sim_running = False
                    self._sim_done = True

    def start(self) -> None:
        """Start the simulation.

        This is a blocking call. A call to the stop() function
        from another thread will stop this function.
        """
        if not self._sim_done:
            self._sim_running = True

            while self._sim_running:
                bit_errors = self._simulate_transmission()
                self._update_statistics(bit_errors)
                self._advance_state()

    def stop(self) -> None:
        """Stop the simulation."""
        self._sim_running = False

    @property
    def simulation_done(self) -> bool:
        """Check whether the simulation is still ongoing or completed.

        :return: True if the simulation is completed
        """
        return self._sim_done

    # TODO: Make sure the length of each BER_array is the same as the number of SNRs
    @property
    def SNRs_and_BERs(self) -> typing.Tuple[np.array, np.array]:
        """Get the current results.

        If the simulation has not yet completed, the BERs which have not yet been calculated are set to 0.

        :return: Tuple of numpy arrays of the form (SNRs, BERs), where BERs is a list of the form
            [BER_decoder_1, BER_decoder_2, ...]
        """
        SNRs = np.array(self._SNRs)
        BERs = [np.array(BER_array) for BER_array in self._BERs]

        return SNRs, BERs


# TODO: Remove save data after successful execution
# TODO: Write currently calculated BERs to file when simulation is stopped
class SimulationManager:
    """This class only contains functions relating to stopping and restarting of simulations
    (and storing of the simulation state in a file, to be resumed at a later date).

    All actual work is outsourced to a provided simulator class.
    """
    def __init__(self, save_dir: str, results_dir: str):
        """Construct a SimulationManager object.

        :param save_dir: Directory in which the simulation state of a paused simulation should be stored
        :param results_dir: Directory in which the results of the simulation should be stored
        """
        self._save_dir = save_dir
        self._sim_state_filepath = f"{self._save_dir}/sim_state.pickle"
        self._logs_filepath = f"{self._save_dir}/logs.txt"
        self._results_dir = results_dir

        self._simulator = None

        Path(self._save_dir).mkdir(parents=True, exist_ok=True)

        self._logger = spd.FileLogger("SimulationManager", self._logs_filepath)
        self._logger.set_level(spd.LogLevel.DEBUG)

        signal.signal(signal.SIGINT, self._exit_gracefully)
        signal.signal(signal.SIGTERM, self._exit_gracefully)

    #
    # Functions relating to the pausing and restarting of simulations
    #

    def unfinished_simulation_present(self) -> bool:
        """Check whether the savefile of a previously unfinished simulation is present."""
        return os.path.isfile(self._sim_state_filepath)

    def load_unfinished(self):
        """Load the state of an unfinished simulation its savefile."""
        assert self.unfinished_simulation_present()

        self._logger.info("Loading saved simulation state")

        with open(self._sim_state_filepath, "rb") as file:
            self._simulator = pickle.load(file)

    # TODO: Make sure old state is overwritten
    def _save_state(self) -> None:
        """Write the state of the currently configured simulation to a savefile."""
        if self._simulator is not None:
            with open(self._sim_state_filepath, "wb") as file:
                pickle.dump(self._simulator, file)

            self._logger.info("Saved simulation state")
        else:
            self._logger.info("No simulation state to save: simulator object is 'None'")

    def _exit_gracefully(self, *args) -> None:
        """Handler called when the program is interrupted.

        Pauses and saves the currently running simulation
        """
        self._logger.debug("Intercepted signal SIGINT/SIGTERM")

        if self._simulator is not None:
            self._simulator.stop()
            self._save_state()

    #
    # Functions responsible for the actual simulation
    #

    def set_simulator(self, simulator: typing.Any) -> None:
        """Select a simulator to do the actual work."""
        self._simulator = simulator

    def start(self):
        """Start the simulation.

        This is a blocking call. A call to the stop() function
        from another thread will stop this function.
        """
        assert self._simulator is not None

        self._logger.info("Starting simulation")
        self._simulator.start()

    @property
    def simulation_done(self):
        """Check whether the configured simulation has been completed."""
        return self._simulator.simulation_done

    def get_current_results(self) -> typing.Any:
        """Get the current results of the configured simulation."""
        return self._simulator.SNRs_and_BERs