Python/scheduling/non_preemptive_shortest_job_first.py

"""
Non-preemptive Shortest Job First
Shortest execution time process is chosen for the next execution.
https://www.guru99.com/shortest-job-first-sjf-scheduling.html
https://en.wikipedia.org/wiki/Shortest_job_next
"""


from __future__ import annotations

from statistics import mean


def calculate_waitingtime(
    arrival_time: list[int], burst_time: list[int], no_of_processes: int
) -> list[int]:
    """
    Calculate the waiting time of each processes

    Return: The waiting time for each process.
    >>> calculate_waitingtime([0,1,2], [10, 5, 8], 3)
    [0, 9, 13]
    >>> calculate_waitingtime([1,2,2,4], [4, 6, 3, 1], 4)
    [0, 7, 4, 1]
    >>> calculate_waitingtime([0,0,0], [12, 2, 10],3)
    [12, 0, 2]
    """

    waiting_time = [0] * no_of_processes
    remaining_time = [0] * no_of_processes

    # Initialize remaining_time to waiting_time.

    for i in range(no_of_processes):
        remaining_time[i] = burst_time[i]
    ready_process: list[int] = []

    completed = 0
    total_time = 0

    # When processes are not completed,
    # A process whose arrival time has passed \
    # and has remaining execution time is put into the ready_process.
    # The shortest process in the ready_process, target_process is executed.

    while completed != no_of_processes:
        ready_process = []
        target_process = -1

        for i in range(no_of_processes):
            if (arrival_time[i] <= total_time) and (remaining_time[i] > 0):
                ready_process.append(i)

        if len(ready_process) > 0:
            target_process = ready_process[0]
            for i in ready_process:
                if remaining_time[i] < remaining_time[target_process]:
                    target_process = i
            total_time += burst_time[target_process]
            completed += 1
            remaining_time[target_process] = 0
            waiting_time[target_process] = (
                total_time - arrival_time[target_process] - burst_time[target_process]
            )
        else:
            total_time += 1

    return waiting_time


def calculate_turnaroundtime(
    burst_time: list[int], no_of_processes: int, waiting_time: list[int]
) -> list[int]:
    """
    Calculate the turnaround time of each process.

    Return: The turnaround time for each process.
    >>> calculate_turnaroundtime([0,1,2], 3, [0, 10, 15])
    [0, 11, 17]
    >>> calculate_turnaroundtime([1,2,2,4], 4, [1, 8, 5, 4])
    [2, 10, 7, 8]
    >>> calculate_turnaroundtime([0,0,0], 3, [12, 0, 2])
    [12, 0, 2]
    """

    turn_around_time = [0] * no_of_processes
    for i in range(no_of_processes):
        turn_around_time[i] = burst_time[i] + waiting_time[i]
    return turn_around_time


if __name__ == "__main__":
    print("[TEST CASE 01]")

    no_of_processes = 4
    burst_time = [2, 5, 3, 7]
    arrival_time = [0, 0, 0, 0]
    waiting_time = calculate_waitingtime(arrival_time, burst_time, no_of_processes)
    turn_around_time = calculate_turnaroundtime(
        burst_time, no_of_processes, waiting_time
    )

    # Printing the Result
    print("PID\tBurst Time\tArrival Time\tWaiting Time\tTurnaround Time")
    for i, process_ID in enumerate(list(range(1, 5))):
        print(
            f"{process_ID}\t{burst_time[i]}\t\t\t{arrival_time[i]}\t\t\t\t"
            f"{waiting_time[i]}\t\t\t\t{turn_around_time[i]}"
        )
    print(f"\nAverage waiting time = {mean(waiting_time):.5f}")
    print(f"Average turnaround time = {mean(turn_around_time):.5f}")
Create non_preemptive_shortest_job_first.py (#6169) * Create non_preemptive_shortest_job_first.py * 파일 위치 변경 * Delete non_preemptive_shortest_job_first.py * delete Korean comments * change comments, & to and, type annotation * type annotation * delete unnecessary comment 2022-06-06 16:44:49 +00:00			`"""`
			`Non-preemptive Shortest Job First`
			`Shortest execution time process is chosen for the next execution.`
			`https://www.guru99.com/shortest-job-first-sjf-scheduling.html`
			`https://en.wikipedia.org/wiki/Shortest_job_next`
			`"""`


			`from __future__ import annotations`

			`from statistics import mean`


			`def calculate_waitingtime(`
			`arrival_time: list[int], burst_time: list[int], no_of_processes: int`
			`) -> list[int]:`
			`"""`
			`Calculate the waiting time of each processes`

			`Return: The waiting time for each process.`
			`>>> calculate_waitingtime([0,1,2], [10, 5, 8], 3)`
			`[0, 9, 13]`
			`>>> calculate_waitingtime([1,2,2,4], [4, 6, 3, 1], 4)`
			`[0, 7, 4, 1]`
			`>>> calculate_waitingtime([0,0,0], [12, 2, 10],3)`
			`[12, 0, 2]`
			`"""`

			`waiting_time = [0] * no_of_processes`
			`remaining_time = [0] * no_of_processes`

			`# Initialize remaining_time to waiting_time.`

			`for i in range(no_of_processes):`
			`remaining_time[i] = burst_time[i]`
			`ready_process: list[int] = []`

			`completed = 0`
			`total_time = 0`

			`# When processes are not completed,`
			`# A process whose arrival time has passed \`
			`# and has remaining execution time is put into the ready_process.`
			`# The shortest process in the ready_process, target_process is executed.`

			`while completed != no_of_processes:`
			`ready_process = []`
			`target_process = -1`

			`for i in range(no_of_processes):`
			`if (arrival_time[i] <= total_time) and (remaining_time[i] > 0):`
			`ready_process.append(i)`

			`if len(ready_process) > 0:`
			`target_process = ready_process[0]`
			`for i in ready_process:`
			`if remaining_time[i] < remaining_time[target_process]:`
			`target_process = i`
			`total_time += burst_time[target_process]`
			`completed += 1`
			`remaining_time[target_process] = 0`
			`waiting_time[target_process] = (`
			`total_time - arrival_time[target_process] - burst_time[target_process]`
			`)`
			`else:`
			`total_time += 1`

			`return waiting_time`


			`def calculate_turnaroundtime(`
			`burst_time: list[int], no_of_processes: int, waiting_time: list[int]`
			`) -> list[int]:`
			`"""`
			`Calculate the turnaround time of each process.`

			`Return: The turnaround time for each process.`
			`>>> calculate_turnaroundtime([0,1,2], 3, [0, 10, 15])`
			`[0, 11, 17]`
			`>>> calculate_turnaroundtime([1,2,2,4], 4, [1, 8, 5, 4])`
			`[2, 10, 7, 8]`
			`>>> calculate_turnaroundtime([0,0,0], 3, [12, 0, 2])`
			`[12, 0, 2]`
			`"""`

			`turn_around_time = [0] * no_of_processes`
			`for i in range(no_of_processes):`
			`turn_around_time[i] = burst_time[i] + waiting_time[i]`
			`return turn_around_time`


			`if __name__ == "__main__":`
			`print("[TEST CASE 01]")`

			`no_of_processes = 4`
			`burst_time = [2, 5, 3, 7]`
			`arrival_time = [0, 0, 0, 0]`
			`waiting_time = calculate_waitingtime(arrival_time, burst_time, no_of_processes)`
			`turn_around_time = calculate_turnaroundtime(`
			`burst_time, no_of_processes, waiting_time`
			`)`

			`# Printing the Result`
			`print("PID\tBurst Time\tArrival Time\tWaiting Time\tTurnaround Time")`
			`for i, process_ID in enumerate(list(range(1, 5))):`
			`print(`
			`f"{process_ID}\t{burst_time[i]}\t\t\t{arrival_time[i]}\t\t\t\t"`
			`f"{waiting_time[i]}\t\t\t\t{turn_around_time[i]}"`
			`)`
			`print(f"\nAverage waiting time = {mean(waiting_time):.5f}")`
			`print(f"Average turnaround time = {mean(turn_around_time):.5f}")`