226 lines
5.4 KiB
Plaintext
226 lines
5.4 KiB
Plaintext
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#include <iostream>
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#include <fstream>
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#include <cstring>
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#include <unistd.h>
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#include <chrono>
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#include <sstream>
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#include <string>
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#include <bits/stdc++.h>
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using namespace std;
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struct process_detail {
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//cpu_burst_times[0] is arrival time
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int pid;
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vector<int> burst_times;
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int in_cpu;
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int ptr;
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};
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struct clock{
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int push_signal; //boolean
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int timer;
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};
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//// operator overloading
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//struct CompareHeight {
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// bool operator()(struct process_detail p1, struct process_detail p2)
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// {
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// // return "true" if "p1" is ordered
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// // before "p2", for example:
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// return p1.height < p2.height;
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// }
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//};
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vector<struct process_detail> processes;
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vector<struct process_detail> ready_queue;
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queue<struct process_detail*> ready_queue_fifo;
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vector<struct process_detail*> waiting;
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struct process_detail* CPU = NULL;
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void fifo() {
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//clock initialized to 0
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struct clock time;
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memset(&time, 0, sizeof(struct clock));
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int process_count = processes.size();
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//ready queue initialized as process 1 will arrive at time 0
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ready_queue_fifo.push(&processes[0]);
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processes[0].ptr++;
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int brk = 0;
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while(true){
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for(int i = 0; i < process_count; ++i) {
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if(processes[i].burst_times[processes[i].ptr] == -1) {
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brk = 1;
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}
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else brk = 0;
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}
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if(brk) break;
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//managing arrival times
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for(int i = 1; i < process_count; ++i) {
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//if process not in cpu
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if(processes[i].in_cpu != 1) {
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if(time.timer == processes[i].burst_times[0]) {
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ready_queue_fifo.push(&processes[i]);
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processes[i].ptr++;
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}
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}
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}
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//THE FIFO RULE
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if(CPU == NULL) {
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CPU = ready_queue_fifo.front();
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CPU->in_cpu = 1;
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ready_queue_fifo.pop();
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}
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else {
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//check cpu_burst complete
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for(int i = 0; i < process_count; ++i) {
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if(processes[i].in_cpu == 1) {
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if(time.push_signal + CPU->burst_times[processes[i].ptr] == time.timer){
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waiting.push_back(CPU); // process added to waiting queue
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CPU->in_cpu = 0;
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CPU = ready_queue_fifo.front(); // process added to CPU
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CPU->in_cpu = 1;
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ready_queue_fifo.pop();
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time.push_signal = time.push_signal + CPU->burst_times[processes[i].ptr] ;
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}
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}
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}
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// removing form waiting list
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for(int j = 0; j < waiting.size(); ++j) {
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if(waiting[j] != NULL) {
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if(waiting[j]->burst_times[waiting[j]->ptr] == 0) {
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ready_queue_fifo.push(waiting[j]);
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waiting[j]->ptr++;
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waiting[j] = NULL;
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}
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else waiting[j]->burst_times[waiting[j]->ptr]--; // reducing the io burst till it reaches 0
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}
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}
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}
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time.timer++;
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}
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cout << "fifo" << endl;
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return;
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}
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int main(int argc, char **argv) {
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if(argc != 3)
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{
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cout <<"usage: ./scheduler.out <path-to-workload-file> <scheduler_algorithm>\nprovided arguments:\n";
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for(int i = 0; i < argc; i++)
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cout << argv[i] << "\n";
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return -1;
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}
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char *file_to_search_in = argv[1];
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char *scheduler_algorithm = argv[2];
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ifstream file(file_to_search_in, ios::binary);
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string buffer;
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int pid = 0;
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while(getline(file, buffer)) {
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if(buffer[0] == '<'){
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continue;
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}
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istringstream iss(buffer);
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string word;
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struct process_detail pd;
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memset(&pd,0,sizeof(struct process_detail));
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pd.pid = pid++;
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pd.ptr = 0;
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while(iss>>word){
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// if(i == 0){
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// pd.cpu_burst_times.push_back(stoi(word));
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// }
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// else if(i % 2 == 0){
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// pd.io_burst_times.push_back(stoi(word));
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// }
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// else if(i % 2 == 1){
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// }
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pd.burst_times.push_back(stoi(word));
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// i++;
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// cout << stoi(word) << endl;
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}
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processes.push_back(pd);
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}
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map<string, int> temp;
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temp["fifo"] = 1;
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string temp1 = scheduler_algorithm;
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switch(temp[temp1]){
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case 1:
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fifo();
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break;
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default:
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cout << "enter fifo" << endl;
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}
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cout << processes[0].in_cpu << endl;
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cout << processes[0].ptr << endl;
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cout << processes[1].in_cpu << endl;
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cout << processes[1].ptr << endl;
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return 0;
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}
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I am writing the above code to as an answer for the following question:
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Process Scheduling
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Laboratory 3
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Duration: 3 weeks
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This assignment will help us learn different process scheduling algorithms and their relative pros
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and cons.
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To do this task, you will need to develop a simulator of a scheduler in C / C++. The simulator
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must take in the following command line arguments: <scheduling-algorithm>
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<path-to-workload-description-file>. The simulator must produce as output the following metrics:
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Makespan, Completion Time (average and maximum), and Waiting Time (average and
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maximum), Run Time of your simulator (not counting I/O). Also, report the schedule itself
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(choose a nice format which will also help you debug).
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For all the studies, we will use the workload description files given here. Each row in the file
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refers to one process. The row format is as follows:
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<process-arrival-time> <cpu-burst-1-duration> <io-burst-1-duration> <cpu-burst-2-duration>
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<io-burst-2-duration> … -1
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For example:
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0 100 2 200 3 25 -1 indicates arrival time = 0; CPU burst 1 duration = 100; I/O burst 1 duration =
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2; CPU burst 2 duration = 200; I/O burst 2 duration = 3; CPU burst 3 duration = 25; end of
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process.
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Assume that every line ends with -1. A process may have any number of CPU / I/O burst
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cycles terminated with a -1. There will be any number of processes, terminated by an end of file.
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The arrival times are in nondecreasing order.
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Part I
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Implement the following algorithms:
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A. First In First Out
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Also here is the input file:
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<html>
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<body>
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<pre>
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0 100 2 -1
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2 80 2 -1
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</pre></body></html>
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Help me write the appropriate code
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