RWTH-BuS-2026/bs-01-scheduling
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f0tt3r 2026-05-22 12:56:03 +02:00
parent 16a9b047ae
commit f896ac89e1
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128
doubly_linked_list.c Normal file
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#include <stdbool.h>
#include "scheduler.h"
#include "doubly_linked_list.h"
/**
* \brief Checks whether a run_queue is empty
*
* \param rq Pointer to the run_queue
*
* \returns `true` iff the run_queue is empty
*/
bool stud_rq_empty(struct run_queue const *rq) {
return false;
}
/**
* \brief Creates a task
*
* \param pid The pid of the new task
* \param state Default state of the task
*
* \return A pointer to the new task, `NULL` if failed
*/
struct task *stud_task_create(int pid, enum states state) {
return NULL;
}
/**
* \brief Frees/destroys a task This function assumes the task has already been
* removed from any run queue. It does not handle linked list operations
* or modifications to the run queue.
*
* \param task Pointer to the task to-be-destroyed
*/
void stud_task_free(struct task *task) {
return;
}
/**
* \brief Frees all the elements of the `run_queue` and empties it.
* `rq` itself should NOT be freed. After calling this function,
* `rq` must simply be an empty `run_queue`.
*
* \param rq Pointer to the run_queue to-be-destroyed
*/
void stud_rq_destroy(struct run_queue *rq) {
return;
}
/**
* \brief Tries to find a task in a run_queue by its PID
*
* \param rq Pointer to the run_queue
* \param pid PID of the wanted task
*
* \returns Pointer to the task, `NULL` if failed
*/
struct task *stud_rq_find(struct run_queue *rq, int pid) {
return NULL;
}
/**
* \brief Returns the head of the `run_queue`.
*
* \param rq Pointer to the run_queue
*/
struct task *stud_rq_head(struct run_queue *rq) {
return NULL;
}
/**
* \brief Returns the tail of the `run_queue`.
*
* \param rq Pointer to the run_queue
*/
struct task *stud_rq_tail(struct run_queue *rq) {
return NULL;
}
/**
* \brief Enqueues a task on the given run_queue. The head stays where it is
* and the new task is put at the END of the list.
*
* \param rq Pointer to the run_queue
* \param task The task to-be-enqueued
*
* \returns `true` iff successful
*/
bool stud_rq_enqueue(struct run_queue *rq, struct task *task) {
return false;
}
/**
* \brief Enqueues a task into the run_queue sorted by ascending runtime.
*
* \param rq Pointer to the run_queue
* \param task The task to be inserted
*
* \returns `true` if successful
*/
bool stud_rq_enqueue_sorted(struct run_queue* rq, struct task* task){
return false;
}
/**
* \brief Prepends a task on the given run_queue. The head of the list MUST be
* moved to the new task!
*
* \param rq Pointer the run_queue
* \param task The task to-be-prepended
*
* \returns `true` iff successful
*/
bool stud_rq_prepend(struct run_queue *rq, struct task *task) {
return false;
}
/**
* \brief Computes the length of a `run_queue`
*
* \param rq The run_queue
*
* \return The length of `rq`
*/
size_t stud_rq_length(struct run_queue *rq) {
return false;
}

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fcfs.c Normal file
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#include "fcfs.h"
void sched_fcfs(struct proc *list, int *schedule) {
return;
}

40
scheduler.h Normal file
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#ifndef SCHEDULER_H__
#define SCHEDULER_H__
#include <stddef.h>
#include <stdio.h>
#include <stdlib.h>
#include <stdbool.h>
#define QUANTUM 10
enum states {
BLOCKED = 0,
RUNNING,
READY,
TERMINATED,
};
enum events {
start = 0,
wait,
wake_up,
terminate,
clock_tick,
};
struct task {
int pid;
enum states state;
struct task* prev;
struct task* next;
int runtime;
};
struct run_queue {
struct task* head;
size_t n_tasks;
int time_counter;
};
#endif // SCHEDULER_H__

101
scheduler_round_robin.c Normal file
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#include "scheduler.h"
#include "scheduler_round_robin.h"
#include "doubly_linked_list.h"
/**
* \brief Enqueues a process in READY state
*
* \param rq The scheduler's run queue
* \param pid The process to be enqueued
*/
void stud_RR_start(struct run_queue* rq, int pid) {
return;
}
/**
* \brief Elects and starts a process from the run queue. The running process MUST be placed
* at the head of `rq` if it is not already there.
*
* \param rq The scheduler's run queue
*/
void stud_RR_elect(struct run_queue* rq) {
return;
}
/**
* \brief Terminates the current running process (i.e. rq->head) and places it at the BACK
* of the run_queue.
*
* \param rq The scheduler's run queue
*/
void stud_RR_terminate(struct run_queue* rq) {
return;
}
/**
* \brief Performs a clock tick as specified by RR.
*
* \param rq The scheduler's run queue
*/
void stud_RR_clock_tick(struct run_queue* rq) {
return;
}
/**
* \brief Sets the state of the running process to BLOCKED, moves it to the BACK of the
* run_queue, and elects and runs a new process.
*
* \param rq The scheduler's run queue
*/
void stud_RR_wait(struct run_queue* rq) {
return;
}
/**
* \brief Sets the state of `pid` to READY, if it exists, and moves it to the BACK
* of the run_queue
*
* \param rq The scheduler's run queue
* \param pid The process to be woken up
*/
void stud_RR_wake_up(struct run_queue* rq, int pid) {
return;
}
/**
* \brief Event handler for RR
*
* \param rq The scheduler's run queue
* \param event The event to be handled
* \param pid Depending on `event`, the `pid` of the target process.
* If the `event` doesn't need this, it is ignored.
*/
void stud_RR(struct run_queue* rq, enum events event, int pid) {
switch(event) {
case start: {
stud_RR_start(rq, pid);
break;
}
case terminate: {
stud_RR_terminate(rq);
break;
}
case clock_tick: {
stud_RR_clock_tick(rq);
break;
}
case wait: {
stud_RR_wait(rq);
break;
}
case wake_up: {
stud_RR_wake_up(rq, pid);
break;
}
}
}

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sjf.c Normal file
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#include "sjf.h"
void sched_sjf(struct proc *list, int *schedule) {
return;
}