Write code (C or Java) to simulate the following CPU scheduling algorithms, assuming a single CPU.
1. Round Robin
Add the processes to a regular First-In-First-Out (FIFO) queue in the order they arrive. If multiple processes arrive at the same time, add them to the queue in the order they appear in the input file. When the time quantum expires, the process that has the CPU is placed at the end of the queue if it has not terminated yet. If a new process arrives and a time quantum expires at the same time, insert the new arrival at the end of the queue before inserting the process whose time quantum expired. After Time 0, scheduling decisions are made when either the process that has the CPU terminates or the time quantum expires. In either case, the scheduler gives the CPU to the first process in the queue. The value of the time quantum is a parameter that is specified in the input file next to the algorithm's name as shown in Example 1 below.
2. Shortest Job First (SJF)
Assume no-preemption but take arrival times into account. To do that, you have to simulate the time (by simply defining an integer variable that keeps track of the time). At any given point in time, your scheduler considers only the processes that have arrived. Whenever a new process arrives, add it to a priority queue in which the key is the CPU burst length. After Time 0, scheduling decisions are made only when the process that currently has the CPU terminates. The scheduler will then give the CPU to the process with the shortest CPU burst. Ties must be broken based on arrival times, that is, if the ready queue has two or more processes with the same CPU burst, these processes get the CPU in the order they have arrived (FCFS). If multiple processes have the same CPU burst and the same arrival time, ties are broken arbitrarily.
3. Priority Scheduling without Preemption (PR_noPREMP)
Take arrival times into account. Whenever a new process arrives, add it to a priority queue, in which the key is the priority value read from the input file. After Time 0, scheduling decisions are made only when the process that currently has the CPU terminates (no preemption). The scheduler will then give the CPU to the process with the highest priority (smallest priority number). Ties are broken arbitrarily.
4. Priority Scheduling with Preemption (PR_withPREMP)
Take arrival times into account, and implement preemption. Whenever a new process arrives, add it to a priority queue, in which the key is the priority number read from the input file. After Time 0, scheduling decisions are made when the process that currently has the CPU terminates or when a higher priority process arrives. The schedule will then give the CPU to the process with the highest priority (smallest priority number). Ties are broken arbitrarily. If the process with the highest priority is the new process that has just arrived, the process that has the CPU must get preempted and added to the priority queue (unless it has just terminated at that point).
Your program should read an input file named "input.txt" and write the results into an output file named "output.txt". The formats of these files are as follows:
Input File
The first line has the name of the scheduling algorithm to run (one of the four names given above).
The second line has a single integer representing the number of processes in the file.
In the rest of the file, there is one line per process with the following information:
Process number Arrival Time CPU burst time Priority
If multiple processes have the same arrival time, your scheduling algorithm should assume that the processes have arrived in the order they appear in the file (there are negligibly small differences in arrival times). For priority scheduling, assume that smaller numbers indicate higher priorities. Non-priority algorithms should simply ignore the priority field.
Output File
Your output file will show the scheduling results for each of the algorithms listed in the input file. The first line in the output file has the name of the scheduling algorithm. The file then shows the schedule using a simple text format in which there is one line for each CPU assignment (each line corresponds to a vertical line in the Gantt chart). Each line has two numbers: one indicating the time point and one indicating the process number that got the CPU at that point. The last line in the output file shows the average waiting time.
Examples
As shown in the example below, when the algorithm is RR, there should be an integer parameter next to the algorithm's name specifying the length of the time quantum:
Input 1 (from the book)
RR 4
3
1 0 24 1
2 0 3 1
3 0 3 1
Output 1
RR 4
0 1
4 2
7 3
10 1
14 1
18 1
22 1
26 1
AVG Waiting Time: 5.67