Python/scheduling/multi_level_feedback_queue.py

from collections import deque


class Process:
    def __init__(self, process_name: str, arrival_time: int, burst_time: int) -> None:
        self.process_name = process_name  # process name
        self.arrival_time = arrival_time  # arrival time of the process
        # completion time of finished process or last interrupted time
        self.stop_time = arrival_time
        self.burst_time = burst_time  # remaining burst time
        self.waiting_time = 0  # total time of the process wait in ready queue
        self.turnaround_time = 0  # time from arrival time to completion time


class MLFQ:
    """
    MLFQ(Multi Level Feedback Queue)
    https://en.wikipedia.org/wiki/Multilevel_feedback_queue
    MLFQ has a lot of queues that have different priority
    In this MLFQ,
    The first Queue(0) to last second Queue(N-2) of MLFQ have Round Robin Algorithm
    The last Queue(N-1) has First Come, First Served Algorithm
    """

    def __init__(
        self,
        number_of_queues: int,
        time_slices: list[int],
        queue: deque[Process],
        current_time: int,
    ) -> None:
        # total number of mlfq's queues
        self.number_of_queues = number_of_queues
        # time slice of queues that round robin algorithm applied
        self.time_slices = time_slices
        # unfinished process is in this ready_queue
        self.ready_queue = queue
        # current time
        self.current_time = current_time
        # finished process is in this sequence queue
        self.finish_queue: deque[Process] = deque()

    def calculate_sequence_of_finish_queue(self) -> list[str]:
        """
        This method returns the sequence of finished processes
        >>> P1 = Process("P1", 0, 53)
        >>> P2 = Process("P2", 0, 17)
        >>> P3 = Process("P3", 0, 68)
        >>> P4 = Process("P4", 0, 24)
        >>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)
        >>> _ = mlfq.multi_level_feedback_queue()
        >>> mlfq.calculate_sequence_of_finish_queue()
        ['P2', 'P4', 'P1', 'P3']
        """
        sequence = []
        for i in range(len(self.finish_queue)):
            sequence.append(self.finish_queue[i].process_name)
        return sequence

    def calculate_waiting_time(self, queue: list[Process]) -> list[int]:
        """
        This method calculates waiting time of processes
        >>> P1 = Process("P1", 0, 53)
        >>> P2 = Process("P2", 0, 17)
        >>> P3 = Process("P3", 0, 68)
        >>> P4 = Process("P4", 0, 24)
        >>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)
        >>> _ = mlfq.multi_level_feedback_queue()
        >>> mlfq.calculate_waiting_time([P1, P2, P3, P4])
        [83, 17, 94, 101]
        """
        waiting_times = []
        for i in range(len(queue)):
            waiting_times.append(queue[i].waiting_time)
        return waiting_times

    def calculate_turnaround_time(self, queue: list[Process]) -> list[int]:
        """
        This method calculates turnaround time of processes
        >>> P1 = Process("P1", 0, 53)
        >>> P2 = Process("P2", 0, 17)
        >>> P3 = Process("P3", 0, 68)
        >>> P4 = Process("P4", 0, 24)
        >>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)
        >>> _ = mlfq.multi_level_feedback_queue()
        >>> mlfq.calculate_turnaround_time([P1, P2, P3, P4])
        [136, 34, 162, 125]
        """
        turnaround_times = []
        for i in range(len(queue)):
            turnaround_times.append(queue[i].turnaround_time)
        return turnaround_times

    def calculate_completion_time(self, queue: list[Process]) -> list[int]:
        """
        This method calculates completion time of processes
        >>> P1 = Process("P1", 0, 53)
        >>> P2 = Process("P2", 0, 17)
        >>> P3 = Process("P3", 0, 68)
        >>> P4 = Process("P4", 0, 24)
        >>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)
        >>> _ = mlfq.multi_level_feedback_queue()
        >>> mlfq.calculate_turnaround_time([P1, P2, P3, P4])
        [136, 34, 162, 125]
        """
        completion_times = []
        for i in range(len(queue)):
            completion_times.append(queue[i].stop_time)
        return completion_times

    def calculate_remaining_burst_time_of_processes(
        self, queue: deque[Process]
    ) -> list[int]:
        """
        This method calculate remaining burst time of processes
        >>> P1 = Process("P1", 0, 53)
        >>> P2 = Process("P2", 0, 17)
        >>> P3 = Process("P3", 0, 68)
        >>> P4 = Process("P4", 0, 24)
        >>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)
        >>> finish_queue, ready_queue = mlfq.round_robin(deque([P1, P2, P3, P4]), 17)
        >>> mlfq.calculate_remaining_burst_time_of_processes(mlfq.finish_queue)
        [0]
        >>> mlfq.calculate_remaining_burst_time_of_processes(ready_queue)
        [36, 51, 7]
        >>> finish_queue, ready_queue = mlfq.round_robin(ready_queue, 25)
        >>> mlfq.calculate_remaining_burst_time_of_processes(mlfq.finish_queue)
        [0, 0]
        >>> mlfq.calculate_remaining_burst_time_of_processes(ready_queue)
        [11, 26]
        """
        return [q.burst_time for q in queue]

    def update_waiting_time(self, process: Process) -> int:
        """
        This method updates waiting times of unfinished processes
        >>> P1 = Process("P1", 0, 53)
        >>> P2 = Process("P2", 0, 17)
        >>> P3 = Process("P3", 0, 68)
        >>> P4 = Process("P4", 0, 24)
        >>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)
        >>> mlfq.current_time = 10
        >>> P1.stop_time = 5
        >>> mlfq.update_waiting_time(P1)
        5
        """
        process.waiting_time += self.current_time - process.stop_time
        return process.waiting_time

    def first_come_first_served(self, ready_queue: deque[Process]) -> deque[Process]:
        """
        FCFS(First Come, First Served)
        FCFS will be applied to MLFQ's last queue
        A first came process will be finished at first
        >>> P1 = Process("P1", 0, 53)
        >>> P2 = Process("P2", 0, 17)
        >>> P3 = Process("P3", 0, 68)
        >>> P4 = Process("P4", 0, 24)
        >>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)
        >>> _ = mlfq.first_come_first_served(mlfq.ready_queue)
        >>> mlfq.calculate_sequence_of_finish_queue()
        ['P1', 'P2', 'P3', 'P4']
        """
        finished: deque[Process] = deque()  # sequence deque of finished process
        while len(ready_queue) != 0:
            cp = ready_queue.popleft()  # current process

            # if process's arrival time is later than current time, update current time
            if self.current_time < cp.arrival_time:
                self.current_time += cp.arrival_time

            # update waiting time of current process
            self.update_waiting_time(cp)
            # update current time
            self.current_time += cp.burst_time
            # finish the process and set the process's burst-time 0
            cp.burst_time = 0
            # set the process's turnaround time because it is finished
            cp.turnaround_time = self.current_time - cp.arrival_time
            # set the completion time
            cp.stop_time = self.current_time
            # add the process to queue that has finished queue
            finished.append(cp)

        self.finish_queue.extend(finished)  # add finished process to finish queue
        # FCFS will finish all remaining processes
        return finished

    def round_robin(
        self, ready_queue: deque[Process], time_slice: int
    ) -> tuple[deque[Process], deque[Process]]:
        """
        RR(Round Robin)
        RR will be applied to MLFQ's all queues except last queue
        All processes can't use CPU for time more than time_slice
        If the process consume CPU up to time_slice, it will go back to ready queue
        >>> P1 = Process("P1", 0, 53)
        >>> P2 = Process("P2", 0, 17)
        >>> P3 = Process("P3", 0, 68)
        >>> P4 = Process("P4", 0, 24)
        >>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)
        >>> finish_queue, ready_queue = mlfq.round_robin(mlfq.ready_queue, 17)
        >>> mlfq.calculate_sequence_of_finish_queue()
        ['P2']
        """
        finished: deque[Process] = deque()  # sequence deque of terminated process
        # just for 1 cycle and unfinished processes will go back to queue
        for _ in range(len(ready_queue)):
            cp = ready_queue.popleft()  # current process

            # if process's arrival time is later than current time, update current time
            if self.current_time < cp.arrival_time:
                self.current_time += cp.arrival_time

            # update waiting time of unfinished processes
            self.update_waiting_time(cp)
            # if the burst time of process is bigger than time-slice
            if cp.burst_time > time_slice:
                # use CPU for only time-slice
                self.current_time += time_slice
                # update remaining burst time
                cp.burst_time -= time_slice
                # update end point time
                cp.stop_time = self.current_time
                # locate the process behind the queue because it is not finished
                ready_queue.append(cp)
            else:
                # use CPU for remaining burst time
                self.current_time += cp.burst_time
                # set burst time 0 because the process is finished
                cp.burst_time = 0
                # set the finish time
                cp.stop_time = self.current_time
                # update the process' turnaround time because it is finished
                cp.turnaround_time = self.current_time - cp.arrival_time
                # add the process to queue that has finished queue
                finished.append(cp)

        self.finish_queue.extend(finished)  # add finished process to finish queue
        # return finished processes queue and remaining processes queue
        return finished, ready_queue

    def multi_level_feedback_queue(self) -> deque[Process]:
        """
        MLFQ(Multi Level Feedback Queue)
        >>> P1 = Process("P1", 0, 53)
        >>> P2 = Process("P2", 0, 17)
        >>> P3 = Process("P3", 0, 68)
        >>> P4 = Process("P4", 0, 24)
        >>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)
        >>> finish_queue = mlfq.multi_level_feedback_queue()
        >>> mlfq.calculate_sequence_of_finish_queue()
        ['P2', 'P4', 'P1', 'P3']
        """

        #  all queues except last one have round_robin algorithm
        for i in range(self.number_of_queues - 1):
            finished, self.ready_queue = self.round_robin(
                self.ready_queue, self.time_slices[i]
            )
        #  the last queue has first_come_first_served algorithm
        self.first_come_first_served(self.ready_queue)

        return self.finish_queue


if __name__ == "__main__":
    import doctest

    P1 = Process("P1", 0, 53)
    P2 = Process("P2", 0, 17)
    P3 = Process("P3", 0, 68)
    P4 = Process("P4", 0, 24)
    number_of_queues = 3
    time_slices = [17, 25]
    queue = deque([P1, P2, P3, P4])

    if len(time_slices) != number_of_queues - 1:
        raise SystemExit(0)

    doctest.testmod(extraglobs={"queue": deque([P1, P2, P3, P4])})

    P1 = Process("P1", 0, 53)
    P2 = Process("P2", 0, 17)
    P3 = Process("P3", 0, 68)
    P4 = Process("P4", 0, 24)
    number_of_queues = 3
    time_slices = [17, 25]
    queue = deque([P1, P2, P3, P4])
    mlfq = MLFQ(number_of_queues, time_slices, queue, 0)
    finish_queue = mlfq.multi_level_feedback_queue()

    # print total waiting times of processes(P1, P2, P3, P4)
    print(
        f"waiting time:\
        \t\t\t{MLFQ.calculate_waiting_time(mlfq, [P1, P2, P3, P4])}"
    )
    # print completion times of processes(P1, P2, P3, P4)
    print(
        f"completion time:\
        \t\t{MLFQ.calculate_completion_time(mlfq, [P1, P2, P3, P4])}"
    )
    # print total turnaround times of processes(P1, P2, P3, P4)
    print(
        f"turnaround time:\
        \t\t{MLFQ.calculate_turnaround_time(mlfq, [P1, P2, P3, P4])}"
    )
    # print sequence of finished processes
    print(
        f"sequence of finished processes:\
        {mlfq.calculate_sequence_of_finish_queue()}"
    )
Add Multi-Level-Feedback-Queue scheduling algorithm (#6165) * Add Multi-Level-Feedback-Queue scheduling algorithm * fix type hint annotation for pre-commit * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> Co-authored-by: John Law <johnlaw.po@gmail.com> 2022-06-04 16:41:52 +00:00			`from collections import deque`


			`class Process:`
			`def __init__(self, process_name: str, arrival_time: int, burst_time: int) -> None:`
			`self.process_name = process_name # process name`
			`self.arrival_time = arrival_time # arrival time of the process`
			`# completion time of finished process or last interrupted time`
			`self.stop_time = arrival_time`
			`self.burst_time = burst_time # remaining burst time`
			`self.waiting_time = 0 # total time of the process wait in ready queue`
			`self.turnaround_time = 0 # time from arrival time to completion time`


			`class MLFQ:`
			`"""`
			`MLFQ(Multi Level Feedback Queue)`
			`https://en.wikipedia.org/wiki/Multilevel_feedback_queue`
			`MLFQ has a lot of queues that have different priority`
			`In this MLFQ,`
			`The first Queue(0) to last second Queue(N-2) of MLFQ have Round Robin Algorithm`
			`The last Queue(N-1) has First Come, First Served Algorithm`
			`"""`

			`def __init__(`
			`self,`
			`number_of_queues: int,`
			`time_slices: list[int],`
			`queue: deque[Process],`
			`current_time: int,`
			`) -> None:`
			`# total number of mlfq's queues`
			`self.number_of_queues = number_of_queues`
			`# time slice of queues that round robin algorithm applied`
			`self.time_slices = time_slices`
			`# unfinished process is in this ready_queue`
			`self.ready_queue = queue`
			`# current time`
			`self.current_time = current_time`
			`# finished process is in this sequence queue`
			`self.finish_queue: deque[Process] = deque()`

			`def calculate_sequence_of_finish_queue(self) -> list[str]:`
			`"""`
			`This method returns the sequence of finished processes`
			`>>> P1 = Process("P1", 0, 53)`
			`>>> P2 = Process("P2", 0, 17)`
			`>>> P3 = Process("P3", 0, 68)`
			`>>> P4 = Process("P4", 0, 24)`
			`>>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)`
			`>>> _ = mlfq.multi_level_feedback_queue()`
			`>>> mlfq.calculate_sequence_of_finish_queue()`
			`['P2', 'P4', 'P1', 'P3']`
			`"""`
			`sequence = []`
			`for i in range(len(self.finish_queue)):`
			`sequence.append(self.finish_queue[i].process_name)`
			`return sequence`

			`def calculate_waiting_time(self, queue: list[Process]) -> list[int]:`
			`"""`
			`This method calculates waiting time of processes`
			`>>> P1 = Process("P1", 0, 53)`
			`>>> P2 = Process("P2", 0, 17)`
			`>>> P3 = Process("P3", 0, 68)`
			`>>> P4 = Process("P4", 0, 24)`
			`>>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)`
			`>>> _ = mlfq.multi_level_feedback_queue()`
			`>>> mlfq.calculate_waiting_time([P1, P2, P3, P4])`
			`[83, 17, 94, 101]`
			`"""`
			`waiting_times = []`
			`for i in range(len(queue)):`
			`waiting_times.append(queue[i].waiting_time)`
			`return waiting_times`

			`def calculate_turnaround_time(self, queue: list[Process]) -> list[int]:`
			`"""`
			`This method calculates turnaround time of processes`
			`>>> P1 = Process("P1", 0, 53)`
			`>>> P2 = Process("P2", 0, 17)`
			`>>> P3 = Process("P3", 0, 68)`
			`>>> P4 = Process("P4", 0, 24)`
			`>>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)`
			`>>> _ = mlfq.multi_level_feedback_queue()`
			`>>> mlfq.calculate_turnaround_time([P1, P2, P3, P4])`
			`[136, 34, 162, 125]`
			`"""`
			`turnaround_times = []`
			`for i in range(len(queue)):`
			`turnaround_times.append(queue[i].turnaround_time)`
			`return turnaround_times`

			`def calculate_completion_time(self, queue: list[Process]) -> list[int]:`
			`"""`
			`This method calculates completion time of processes`
			`>>> P1 = Process("P1", 0, 53)`
			`>>> P2 = Process("P2", 0, 17)`
			`>>> P3 = Process("P3", 0, 68)`
			`>>> P4 = Process("P4", 0, 24)`
			`>>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)`
			`>>> _ = mlfq.multi_level_feedback_queue()`
			`>>> mlfq.calculate_turnaround_time([P1, P2, P3, P4])`
			`[136, 34, 162, 125]`
			`"""`
			`completion_times = []`
			`for i in range(len(queue)):`
			`completion_times.append(queue[i].stop_time)`
			`return completion_times`

			`def calculate_remaining_burst_time_of_processes(`
			`self, queue: deque[Process]`
			`) -> list[int]:`
			`"""`
			`This method calculate remaining burst time of processes`
			`>>> P1 = Process("P1", 0, 53)`
			`>>> P2 = Process("P2", 0, 17)`
			`>>> P3 = Process("P3", 0, 68)`
			`>>> P4 = Process("P4", 0, 24)`
			`>>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)`
			`>>> finish_queue, ready_queue = mlfq.round_robin(deque([P1, P2, P3, P4]), 17)`
			`>>> mlfq.calculate_remaining_burst_time_of_processes(mlfq.finish_queue)`
			`[0]`
			`>>> mlfq.calculate_remaining_burst_time_of_processes(ready_queue)`
			`[36, 51, 7]`
			`>>> finish_queue, ready_queue = mlfq.round_robin(ready_queue, 25)`
			`>>> mlfq.calculate_remaining_burst_time_of_processes(mlfq.finish_queue)`
			`[0, 0]`
			`>>> mlfq.calculate_remaining_burst_time_of_processes(ready_queue)`
			`[11, 26]`
			`"""`
			`return [q.burst_time for q in queue]`

			`def update_waiting_time(self, process: Process) -> int:`
			`"""`
			`This method updates waiting times of unfinished processes`
			`>>> P1 = Process("P1", 0, 53)`
			`>>> P2 = Process("P2", 0, 17)`
			`>>> P3 = Process("P3", 0, 68)`
			`>>> P4 = Process("P4", 0, 24)`
			`>>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)`
			`>>> mlfq.current_time = 10`
			`>>> P1.stop_time = 5`
			`>>> mlfq.update_waiting_time(P1)`
			`5`
			`"""`
			`process.waiting_time += self.current_time - process.stop_time`
			`return process.waiting_time`

			`def first_come_first_served(self, ready_queue: deque[Process]) -> deque[Process]:`
			`"""`
			`FCFS(First Come, First Served)`
			`FCFS will be applied to MLFQ's last queue`
			`A first came process will be finished at first`
			`>>> P1 = Process("P1", 0, 53)`
			`>>> P2 = Process("P2", 0, 17)`
			`>>> P3 = Process("P3", 0, 68)`
			`>>> P4 = Process("P4", 0, 24)`
			`>>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)`
			`>>> _ = mlfq.first_come_first_served(mlfq.ready_queue)`
			`>>> mlfq.calculate_sequence_of_finish_queue()`
			`['P1', 'P2', 'P3', 'P4']`
			`"""`
			`finished: deque[Process] = deque() # sequence deque of finished process`
			`while len(ready_queue) != 0:`
			`cp = ready_queue.popleft() # current process`

			`# if process's arrival time is later than current time, update current time`
			`if self.current_time < cp.arrival_time:`
			`self.current_time += cp.arrival_time`

			`# update waiting time of current process`
			`self.update_waiting_time(cp)`
			`# update current time`
			`self.current_time += cp.burst_time`
			`# finish the process and set the process's burst-time 0`
			`cp.burst_time = 0`
			`# set the process's turnaround time because it is finished`
			`cp.turnaround_time = self.current_time - cp.arrival_time`
			`# set the completion time`
			`cp.stop_time = self.current_time`
			`# add the process to queue that has finished queue`
			`finished.append(cp)`

			`self.finish_queue.extend(finished) # add finished process to finish queue`
			`# FCFS will finish all remaining processes`
			`return finished`

			`def round_robin(`
			`self, ready_queue: deque[Process], time_slice: int`
			`) -> tuple[deque[Process], deque[Process]]:`
			`"""`
			`RR(Round Robin)`
			`RR will be applied to MLFQ's all queues except last queue`
			`All processes can't use CPU for time more than time_slice`
			`If the process consume CPU up to time_slice, it will go back to ready queue`
			`>>> P1 = Process("P1", 0, 53)`
			`>>> P2 = Process("P2", 0, 17)`
			`>>> P3 = Process("P3", 0, 68)`
			`>>> P4 = Process("P4", 0, 24)`
			`>>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)`
			`>>> finish_queue, ready_queue = mlfq.round_robin(mlfq.ready_queue, 17)`
			`>>> mlfq.calculate_sequence_of_finish_queue()`
			`['P2']`
			`"""`
			`finished: deque[Process] = deque() # sequence deque of terminated process`
			`# just for 1 cycle and unfinished processes will go back to queue`
Add flake8 pluin flake8 bugbear to pre-commit (#7132) * ci(pre-commit): Add ``flake8-builtins`` additional dependency to ``pre-commit`` (#7104) * refactor: Fix ``flake8-builtins`` (#7104) * fix(lru_cache): Fix naming conventions in docstrings (#7104) * ci(pre-commit): Order additional dependencies alphabetically (#7104) * fix(lfu_cache): Correct function name in docstring (#7104) * Update strings/snake_case_to_camel_pascal_case.py Co-authored-by: Christian Clauss <cclauss@me.com> * Update data_structures/stacks/next_greater_element.py Co-authored-by: Christian Clauss <cclauss@me.com> * Update digital_image_processing/index_calculation.py Co-authored-by: Christian Clauss <cclauss@me.com> * Update graphs/prim.py Co-authored-by: Christian Clauss <cclauss@me.com> * Update hashes/djb2.py Co-authored-by: Christian Clauss <cclauss@me.com> * refactor: Rename `_builtin` to `builtin_` ( #7104) * fix: Rename all instances (#7104) * refactor: Update variable names (#7104) * [pre-commit.ci] auto fixes from pre-commit.com hooks for more information, see https://pre-commit.ci * ci: Create ``tox.ini`` and ignore ``A003`` (#7123) * revert: Remove function name changes (#7104) * [pre-commit.ci] auto fixes from pre-commit.com hooks for more information, see https://pre-commit.ci * Rename tox.ini to .flake8 * Update data_structures/heap/heap.py Co-authored-by: Dhruv Manilawala <dhruvmanila@gmail.com> * refactor: Rename `next_` to `next_item` (#7104) * ci(pre-commit): Add `flake8` plugin `flake8-bugbear` (#7127) * refactor: Follow `flake8-bugbear` plugin (#7127) * fix: Correct `knapsack` code (#7127) * [pre-commit.ci] auto fixes from pre-commit.com hooks for more information, see https://pre-commit.ci Co-authored-by: Christian Clauss <cclauss@me.com> Co-authored-by: pre-commit-ci[bot] <66853113+pre-commit-ci[bot]@users.noreply.github.com> Co-authored-by: Dhruv Manilawala <dhruvmanila@gmail.com> 2022-10-13 16:03:06 +00:00			`for _ in range(len(ready_queue)):`
Add Multi-Level-Feedback-Queue scheduling algorithm (#6165) * Add Multi-Level-Feedback-Queue scheduling algorithm * fix type hint annotation for pre-commit * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> Co-authored-by: John Law <johnlaw.po@gmail.com> 2022-06-04 16:41:52 +00:00			`cp = ready_queue.popleft() # current process`

			`# if process's arrival time is later than current time, update current time`
			`if self.current_time < cp.arrival_time:`
			`self.current_time += cp.arrival_time`

			`# update waiting time of unfinished processes`
			`self.update_waiting_time(cp)`
			`# if the burst time of process is bigger than time-slice`
			`if cp.burst_time > time_slice:`
			`# use CPU for only time-slice`
			`self.current_time += time_slice`
			`# update remaining burst time`
			`cp.burst_time -= time_slice`
			`# update end point time`
			`cp.stop_time = self.current_time`
			`# locate the process behind the queue because it is not finished`
			`ready_queue.append(cp)`
			`else:`
			`# use CPU for remaining burst time`
			`self.current_time += cp.burst_time`
			`# set burst time 0 because the process is finished`
			`cp.burst_time = 0`
			`# set the finish time`
			`cp.stop_time = self.current_time`
			`# update the process' turnaround time because it is finished`
			`cp.turnaround_time = self.current_time - cp.arrival_time`
			`# add the process to queue that has finished queue`
			`finished.append(cp)`

			`self.finish_queue.extend(finished) # add finished process to finish queue`
			`# return finished processes queue and remaining processes queue`
			`return finished, ready_queue`

			`def multi_level_feedback_queue(self) -> deque[Process]:`
			`"""`
			`MLFQ(Multi Level Feedback Queue)`
			`>>> P1 = Process("P1", 0, 53)`
			`>>> P2 = Process("P2", 0, 17)`
			`>>> P3 = Process("P3", 0, 68)`
			`>>> P4 = Process("P4", 0, 24)`
			`>>> mlfq = MLFQ(3, [17, 25], deque([P1, P2, P3, P4]), 0)`
			`>>> finish_queue = mlfq.multi_level_feedback_queue()`
			`>>> mlfq.calculate_sequence_of_finish_queue()`
			`['P2', 'P4', 'P1', 'P3']`
			`"""`

			`# all queues except last one have round_robin algorithm`
			`for i in range(self.number_of_queues - 1):`
			`finished, self.ready_queue = self.round_robin(`
			`self.ready_queue, self.time_slices[i]`
			`)`
			`# the last queue has first_come_first_served algorithm`
			`self.first_come_first_served(self.ready_queue)`

			`return self.finish_queue`


			`if __name__ == "__main__":`
			`import doctest`

			`P1 = Process("P1", 0, 53)`
			`P2 = Process("P2", 0, 17)`
			`P3 = Process("P3", 0, 68)`
			`P4 = Process("P4", 0, 24)`
			`number_of_queues = 3`
			`time_slices = [17, 25]`
			`queue = deque([P1, P2, P3, P4])`

			`if len(time_slices) != number_of_queues - 1:`
Misc fixes across multiple algorithms (#6912) Source: Snyk code quality Add scikit-fuzzy to requirements Co-authored-by: pre-commit-ci[bot] <66853113+pre-commit-ci[bot]@users.noreply.github.com> Co-authored-by: Dhruv Manilawala <dhruvmanila@gmail.com> 2022-10-16 05:25:38 +00:00			`raise SystemExit(0)`
Add Multi-Level-Feedback-Queue scheduling algorithm (#6165) * Add Multi-Level-Feedback-Queue scheduling algorithm * fix type hint annotation for pre-commit * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> Co-authored-by: John Law <johnlaw.po@gmail.com> 2022-06-04 16:41:52 +00:00
			`doctest.testmod(extraglobs={"queue": deque([P1, P2, P3, P4])})`

			`P1 = Process("P1", 0, 53)`
			`P2 = Process("P2", 0, 17)`
			`P3 = Process("P3", 0, 68)`
			`P4 = Process("P4", 0, 24)`
			`number_of_queues = 3`
			`time_slices = [17, 25]`
			`queue = deque([P1, P2, P3, P4])`
			`mlfq = MLFQ(number_of_queues, time_slices, queue, 0)`
			`finish_queue = mlfq.multi_level_feedback_queue()`

			`# print total waiting times of processes(P1, P2, P3, P4)`
			`print(`
			`f"waiting time:\`
			`\t\t\t{MLFQ.calculate_waiting_time(mlfq, [P1, P2, P3, P4])}"`
			`)`
			`# print completion times of processes(P1, P2, P3, P4)`
			`print(`
			`f"completion time:\`
			`\t\t{MLFQ.calculate_completion_time(mlfq, [P1, P2, P3, P4])}"`
			`)`
			`# print total turnaround times of processes(P1, P2, P3, P4)`
			`print(`
			`f"turnaround time:\`
			`\t\t{MLFQ.calculate_turnaround_time(mlfq, [P1, P2, P3, P4])}"`
			`)`
			`# print sequence of finished processes`
			`print(`
[pre-commit.ci] pre-commit autoupdate (#6629) * [pre-commit.ci] pre-commit autoupdate updates: - [github.com/psf/black: 22.6.0 → 22.8.0](https://github.com/psf/black/compare/22.6.0...22.8.0) - [github.com/asottile/pyupgrade: v2.37.0 → v2.38.2](https://github.com/asottile/pyupgrade/compare/v2.37.0...v2.38.2) - https://gitlab.com/pycqa/flake8 → https://github.com/PyCQA/flake8 - [github.com/PyCQA/flake8: 3.9.2 → 5.0.4](https://github.com/PyCQA/flake8/compare/3.9.2...5.0.4) - [github.com/pre-commit/mirrors-mypy: v0.961 → v0.981](https://github.com/pre-commit/mirrors-mypy/compare/v0.961...v0.981) - [github.com/codespell-project/codespell: v2.1.0 → v2.2.1](https://github.com/codespell-project/codespell/compare/v2.1.0...v2.2.1) * Fix a long line * Update sol1.py * Update sol1.py * lambda_ * Update multi_level_feedback_queue.py * Update double_ended_queue.py * Update sequential_minimum_optimization.py * Update .pre-commit-config.yaml Co-authored-by: pre-commit-ci[bot] <66853113+pre-commit-ci[bot]@users.noreply.github.com> Co-authored-by: Christian Clauss <cclauss@me.com> 2022-10-03 20:00:45 +00:00			`f"sequence of finished processes:\`
Add Multi-Level-Feedback-Queue scheduling algorithm (#6165) * Add Multi-Level-Feedback-Queue scheduling algorithm * fix type hint annotation for pre-commit * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> * Update scheduling/multi_level_feedback_queue.py * Update scheduling/multi_level_feedback_queue.py Co-authored-by: John Law <johnlaw.po@gmail.com> Co-authored-by: John Law <johnlaw.po@gmail.com> 2022-06-04 16:41:52 +00:00			`{mlfq.calculate_sequence_of_finish_queue()}"`
			`)`