729 lines
20 KiB
C
729 lines
20 KiB
C
// Author: Claudio Maggioni
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// Author: Tommaso Rodolfo Masera
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#include "threads/thread.h"
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#include <debug.h>
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#include <stddef.h>
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#include <random.h>
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#include <stdio.h>
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#include <string.h>
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#include "threads/flags.h"
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#include "threads/interrupt.h"
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#include "threads/intr-stubs.h"
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#include "threads/palloc.h"
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#include "threads/switch.h"
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#include "threads/synch.h"
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#include "threads/vaddr.h"
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#include "devices/timer.h"
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#ifdef USERPROG
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#include "userprog/process.h"
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#endif
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/* Random value for struct thread's `magic' member.
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Used to detect stack overflow. See the big comment at the top
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of thread.h for details. */
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#define THREAD_MAGIC 0xcd6abf4b
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/* List of processes in THREAD_READY state, that is, processes
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that are ready to run but not actually running. */
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static struct list ready_list;
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/* List of all processes. Processes are added to this list
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when they are first scheduled and removed when they exit. */
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static struct list all_list;
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/* Idle thread. */
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static struct thread *idle_thread;
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/* Initial thread, the thread running init.c:main(). */
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static struct thread *initial_thread;
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/* Lock used by allocate_tid(). */
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static struct lock tid_lock;
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static struct list sleeping;
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static FPReal load_avg;
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/* Stack frame for kernel_thread(). */
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struct kernel_thread_frame
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{
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void *eip; /* Return address. */
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thread_func *function; /* Function to call. */
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void *aux; /* Auxiliary data for function. */
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};
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/* Statistics. */
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static long long idle_ticks; /* # of timer ticks spent idle. */
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static long long kernel_ticks; /* # of timer ticks in kernel threads. */
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static long long user_ticks; /* # of timer ticks in user programs. */
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/* Scheduling. */
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#define TIME_SLICE 4 /* # of timer ticks to give each thread. */
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static unsigned thread_ticks; /* # of timer ticks since last yield. */
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/* If false (default), use round-robin scheduler.
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If true, use multi-level feedback queue scheduler.
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Controlled by kernel command-line option "-o mlfqs". */
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bool thread_mlfqs;
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static void kernel_thread (thread_func *, void *aux);
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static void idle (void *aux UNUSED);
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static struct thread *running_thread (void);
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static struct thread *next_thread_to_run (void);
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static void init_thread (struct thread *, const char *name, int priority);
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static bool is_thread (struct thread *) UNUSED;
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static void *alloc_frame (struct thread *, size_t size);
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static void schedule (void);
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void thread_schedule_tail (struct thread *prev);
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static tid_t allocate_tid (void);
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void thread_yield_for_higher_priority(void);
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static void compute_mlfqs_priority(struct thread* t);
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bool comp_priority(struct list_elem *, struct list_elem *, void *);
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/* Initializes the threading system by transforming the code
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that's currently running into a thread. This can't work in
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general and it is possible in this case only because loader.S
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was careful to put the bottom of the stack at a page boundary.
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Also initializes the run queue and the tid lock.
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After calling this function, be sure to initialize the page
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allocator before trying to create any threads with
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thread_create().
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It is not safe to call thread_current() until this function
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finishes. */
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void
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thread_init (void)
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{
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ASSERT (intr_get_level () == INTR_OFF);
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lock_init (&tid_lock);
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list_init (&ready_list);
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list_init (&all_list);
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/* Set up a thread structure for the running thread. */
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initial_thread = running_thread ();
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init_thread (initial_thread, "main", PRI_DEFAULT);
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initial_thread->status = THREAD_RUNNING;
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initial_thread->tid = allocate_tid ();
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list_init(&sleeping);
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load_avg = INT_TO_FPR(0);
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}
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static bool
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earlier_wakeup(const struct list_elem* a, const struct list_elem* b, void* aux UNUSED) {
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return list_entry(a, struct thread, elem)->wakeup <
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list_entry(b, struct thread, elem)->wakeup;
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}
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void
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thread_sleep(uint64_t ticks) {
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enum intr_level old_level = intr_disable();
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struct thread* cur = thread_current();
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cur->wakeup = timer_ticks() + ticks;
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// printf("sleeping insert %X\n", cur);
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list_insert_ordered(&sleeping, &(cur->elem), earlier_wakeup, NULL);
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thread_block();
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intr_set_level(old_level);
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}
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static struct thread* thr(struct list_elem* l) {
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return list_entry(l, struct thread, elem);
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}
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void
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thread_unsleep() {
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const uint64_t ticks = timer_ticks();
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enum intr_level old_level = intr_disable();
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if (!list_empty(&sleeping)) {
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struct list_elem* t = list_begin(&sleeping);
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while (thr(t)->wakeup <= ticks) {
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// printf("sleeping remove %X\n", thr(t));
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struct thread* s = thr(t);
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t = list_remove(t);
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thread_unblock(s);
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}
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}
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intr_set_level(old_level);
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}
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/* Starts preemptive thread scheduling by enabling interrupts.
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Also creates the idle thread. */
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void
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thread_start (void)
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{
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/* Create the idle thread. */
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struct semaphore idle_started;
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sema_init (&idle_started, 0);
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thread_create ("idle", PRI_MIN, idle, &idle_started);
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/* Start preemptive thread scheduling. */
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intr_enable ();
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/* Wait for the idle thread to initialize idle_thread. */
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sema_down (&idle_started);
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}
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/* Called by the timer interrupt handler at each timer tick.
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Thus, this function runs in an external interrupt context. */
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void
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thread_tick (void)
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{
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struct thread *t = thread_current ();
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/* Update statistics. */
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if (t == idle_thread)
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idle_ticks++;
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#ifdef USERPROG
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else if (t->pagedir != NULL)
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user_ticks++;
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#endif
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else
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kernel_ticks++;
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++thread_ticks;
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if (thread_mlfqs) {
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if (timer_ticks() % 4 == 0) {
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compute_mlfqs_priority(t);
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}
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if (thread_current() != idle_thread) {
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t->recent_cpu = FPR_ADD_INT(t->recent_cpu, 1);
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}
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if (timer_ticks() % TIMER_FREQ == 0) { // this is true every second
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int a = t != idle_thread && (t->status == THREAD_RUNNING || t->status == THREAD_READY) ? 1 : 0;
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int thr_running = list_size(&ready_list) + a;
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load_avg = FPR_ADD_FPR(
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FPR_MUL_FPR(INT_DIV_INT(59, 60), load_avg),
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FPR_MUL_INT(INT_DIV_INT(1, 60), thr_running));
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FPReal dag = FPR_MUL_INT(load_avg, 2);
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struct list_elem* e;
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for (e = list_begin(&all_list); e != list_end(&all_list);) {
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struct thread* i = list_entry(e, struct thread, allelem);
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i->recent_cpu = FPR_MUL_FPR(i->recent_cpu,
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FPR_DIV_FPR(dag, FPR_ADD_INT(dag, 1))) + INT_TO_FPR(i->nice);
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//printf("\nmalusa recent_cpu: %d, running: %d b %d\n", FPR_TO_INT(t->recent_cpu), thr_running, a);
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e = list_next(e);
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}
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}
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}
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/* Enforce preemption. */
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if (thread_ticks >= TIME_SLICE)
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intr_yield_on_return ();
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}
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int
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thread_get_nice (void)
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{
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enum intr_level old_level = intr_disable();
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int r = thread_current()->nice;
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intr_set_level(old_level);
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return r;
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}
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void
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thread_set_nice (int nice)
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{
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struct thread* t = thread_current();
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enum intr_level old_level = intr_disable();
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t->nice = nice > 20 || nice < -20 ? 0 : nice;
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compute_mlfqs_priority(t);
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intr_set_level(old_level);
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thread_yield_for_higher_priority();
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}
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int
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thread_get_recent_cpu (void)
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{
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enum intr_level old_level = intr_disable();
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int r = FPR_TO_INT(FPR_MUL_INT(thread_current()->recent_cpu, 100));
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intr_set_level(old_level);
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return r;
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}
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int
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thread_get_load_avg (void)
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{
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enum intr_level old_level = intr_disable();
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int r = FPR_TO_INT(FPR_MUL_INT(load_avg, 100));
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intr_set_level(old_level);
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return r;
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}
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/* Prints thread statistics. */
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void
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thread_print_stats (void)
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{
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printf ("Thread: %lld idle ticks, %lld kernel ticks, %lld user ticks\n",
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idle_ticks, kernel_ticks, user_ticks);
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}
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/* Creates a new kernel thread named NAME with the given initial
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PRIORITY, which executes FUNCTION passing AUX as the argument,
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and adds it to the ready queue. Returns the thread identifier
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for the new thread, or TID_ERROR if creation fails.
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If thread_start() has been called, then the new thread may be
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scheduled before thread_create() returns. It could even exit
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before thread_create() returns. Contrariwise, the original
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thread may run for any amount of time before the new thread is
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scheduled. Use a semaphore or some other form of
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synchronization if you need to ensure ordering.
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The code provided sets the new thread's `priority' member to
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PRIORITY, but no actual priority scheduling is implemented.
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Priority scheduling is the goal of Problem 1-3. */
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tid_t
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thread_create (const char *name, int priority,
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thread_func *function, void *aux)
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{
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struct thread *t;
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struct kernel_thread_frame *kf;
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struct switch_entry_frame *ef;
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struct switch_threads_frame *sf;
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tid_t tid;
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enum intr_level old_level;
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ASSERT (function != NULL);
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/* Allocate thread. */
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t = palloc_get_page (PAL_ZERO);
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if (t == NULL)
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return TID_ERROR;
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/* Initialize thread. */
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init_thread (t, name, priority);
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tid = t->tid = allocate_tid ();
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/* Prepare thread for first run by initializing its stack.
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Do this atomically so intermediate values for the 'stack'
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member cannot be observed. */
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old_level = intr_disable ();
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/* Stack frame for kernel_thread(). */
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kf = alloc_frame (t, sizeof *kf);
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kf->eip = NULL;
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kf->function = function;
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kf->aux = aux;
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/* Stack frame for switch_entry(). */
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ef = alloc_frame (t, sizeof *ef);
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ef->eip = (void (*) (void)) kernel_thread;
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/* Stack frame for switch_threads(). */
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sf = alloc_frame (t, sizeof *sf);
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sf->eip = switch_entry;
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sf->ebp = 0;
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intr_set_level (old_level);
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/* Add to run queue. */
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thread_unblock (t);
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thread_yield_for_higher_priority();
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return tid;
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}
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/* Puts the current thread to sleep. It will not be scheduled
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again until awoken by thread_unblock().
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This function must be called with interrupts turned off. It
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is usually a better idea to use one of the synchronization
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primitives in synch.h. */
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void
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thread_block (void)
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{
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ASSERT (!intr_context ());
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ASSERT (intr_get_level () == INTR_OFF);
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thread_current ()->status = THREAD_BLOCKED;
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schedule ();
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}
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/* Transitions a blocked thread T to the ready-to-run state.
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This is an error if T is not blocked. (Use thread_yield() to
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make the running thread ready.)
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This function does not preempt the running thread. This can
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be important: if the caller had disabled interrupts itself,
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it may expect that it can atomically unblock a thread and
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update other data. */
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void
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thread_unblock (struct thread *t)
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{
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enum intr_level old_level;
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ASSERT (is_thread (t));
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old_level = intr_disable ();
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ASSERT (t->status == THREAD_BLOCKED);
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list_push_back (&ready_list, &t->elem);
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t->status = THREAD_READY;
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intr_set_level (old_level);
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}
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/* Returns the name of the running thread. */
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const char *
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thread_name (void)
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{
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return thread_current ()->name;
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}
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/* Returns the running thread.
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This is running_thread() plus a couple of sanity checks.
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See the big comment at the top of thread.h for details. */
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struct thread *
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thread_current (void)
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{
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struct thread *t = running_thread ();
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/* Make sure T is really a thread.
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If either of these assertions fire, then your thread may
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have overflowed its stack. Each thread has less than 4 kB
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of stack, so a few big automatic arrays or moderate
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recursion can cause stack overflow. */
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ASSERT (is_thread (t));
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ASSERT (t->status == THREAD_RUNNING);
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return t;
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}
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/* Returns the running thread's tid. */
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tid_t
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thread_tid (void)
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{
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return thread_current ()->tid;
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}
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/* Deschedules the current thread and destroys it. Never
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returns to the caller. */
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void
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thread_exit (void)
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{
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ASSERT (!intr_context ());
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#ifdef USERPROG
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process_exit ();
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#endif
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/* Remove thread from all threads list, set our status to dying,
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and schedule another process. That process will destroy us
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when it calls thread_schedule_tail(). */
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intr_disable ();
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list_remove (&thread_current()->allelem);
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thread_current ()->status = THREAD_DYING;
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schedule ();
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NOT_REACHED ();
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}
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/* Yields the CPU. The current thread is not put to sleep and
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may be scheduled again immediately at the scheduler's whim. */
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void
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thread_yield (void)
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{
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struct thread *cur = thread_current ();
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enum intr_level old_level;
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ASSERT (!intr_context ());
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old_level = intr_disable ();
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if (cur != idle_thread)
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list_push_back (&ready_list, &cur->elem);
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cur->status = THREAD_READY;
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schedule ();
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intr_set_level (old_level);
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}
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/* Invoke function 'func' on all threads, passing along 'aux'.
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This function must be called with interrupts off. */
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void
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thread_foreach (thread_action_func *func, void *aux)
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{
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struct list_elem *e;
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ASSERT (intr_get_level () == INTR_OFF);
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for (e = list_begin (&all_list); e != list_end (&all_list);
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e = list_next (e))
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{
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struct thread *t = list_entry (e, struct thread, allelem);
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func (t, aux);
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}
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}
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int
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thread_get_priority (void) {
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return thread_current()->priority;
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}
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/* Sets the current thread's priority to NEW_PRIORITY. */
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void
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thread_set_priority (int new_priority)
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{
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thread_current ()->priority = new_priority;
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thread_yield_for_higher_priority();
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}
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/* Idle thread. Executes when no other thread is ready to run.
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The idle thread is initially put on the ready list by
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thread_start(). It will be scheduled once initially, at which
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point it initializes idle_thread, "up"s the semaphore passed
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to it to enable thread_start() to continue, and immediately
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blocks. After that, the idle thread never appears in the
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ready list. It is returned by next_thread_to_run() as a
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special case when the ready list is empty. */
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static void
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idle (void *idle_started_ UNUSED)
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{
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struct semaphore *idle_started = idle_started_;
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idle_thread = thread_current ();
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sema_up (idle_started);
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for (;;)
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{
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/* Let someone else run. */
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intr_disable ();
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thread_block ();
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/* Re-enable interrupts and wait for the next one.
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The `sti' instruction disables interrupts until the
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completion of the next instruction, so these two
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instructions are executed atomically. This atomicity is
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important; otherwise, an interrupt could be handled
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between re-enabling interrupts and waiting for the next
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one to occur, wasting as much as one clock tick worth of
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time.
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See [IA32-v2a] "HLT", [IA32-v2b] "STI", and [IA32-v3a]
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7.11.1 "HLT Instruction". */
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asm volatile ("sti; hlt" : : : "memory");
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}
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}
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/* Function used as the basis for a kernel thread. */
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static void
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kernel_thread (thread_func *function, void *aux)
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{
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ASSERT (function != NULL);
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intr_enable (); /* The scheduler runs with interrupts off. */
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function (aux); /* Execute the thread function. */
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thread_exit (); /* If function() returns, kill the thread. */
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}
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/* Returns the running thread. */
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struct thread *
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running_thread (void)
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{
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uint32_t *esp;
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/* Copy the CPU's stack pointer into `esp', and then round that
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down to the start of a page. Because `struct thread' is
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always at the beginning of a page and the stack pointer is
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somewhere in the middle, this locates the curent thread. */
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asm ("mov %%esp, %0" : "=g" (esp));
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||
return pg_round_down (esp);
|
||
}
|
||
|
||
/* Returns true if T appears to point to a valid thread. */
|
||
static bool
|
||
is_thread (struct thread *t)
|
||
{
|
||
return t != NULL && t->magic == THREAD_MAGIC;
|
||
}
|
||
|
||
static void
|
||
compute_mlfqs_priority(struct thread* t) {
|
||
t->priority = PRI_MAX - FPR_TO_INT(FPR_DIV_INT(t->recent_cpu, 4))
|
||
- (t->nice * 2);
|
||
|
||
if (t->priority < PRI_MIN) t->priority = PRI_MIN;
|
||
else if (t->priority > PRI_MAX) t->priority = PRI_MAX;
|
||
}
|
||
|
||
/* Does basic initialization of T as a blocked thread named
|
||
NAME. */
|
||
static void
|
||
init_thread (struct thread *t, const char *name, int priority)
|
||
{
|
||
ASSERT (t != NULL);
|
||
ASSERT (PRI_MIN <= priority && priority <= PRI_MAX);
|
||
ASSERT (name != NULL);
|
||
|
||
memset (t, 0, sizeof *t);
|
||
t->status = THREAD_BLOCKED;
|
||
strlcpy (t->name, name, sizeof t->name);
|
||
t->stack = (uint8_t *) t + PGSIZE;
|
||
|
||
if (thread_mlfqs) {
|
||
t->nice_init = priority > 20 || priority < 20 ? 0 : priority;
|
||
t->nice = t->nice_init;
|
||
t->recent_cpu = 0;
|
||
compute_mlfqs_priority(t);
|
||
} else {
|
||
t->priority = priority;
|
||
}
|
||
|
||
t->magic = THREAD_MAGIC;
|
||
list_push_back (&all_list, &t->allelem);
|
||
}
|
||
|
||
/* Allocates a SIZE-byte frame at the top of thread T's stack and
|
||
returns a pointer to the frame's base. */
|
||
static void *
|
||
alloc_frame (struct thread *t, size_t size)
|
||
{
|
||
/* Stack data is always allocated in word-size units. */
|
||
ASSERT (is_thread (t));
|
||
ASSERT (size % sizeof (uint32_t) == 0);
|
||
|
||
t->stack -= size;
|
||
return t->stack;
|
||
}
|
||
|
||
/* Chooses and returns the next thread to be scheduled. Should
|
||
return a thread from the run queue, unless the run queue is
|
||
empty. (If the running thread can continue running, then it
|
||
will be in the run queue.) If the run queue is empty, return
|
||
idle_thread. */
|
||
static struct thread *
|
||
next_thread_to_run (void)
|
||
{
|
||
if (list_empty (&ready_list))
|
||
return idle_thread;
|
||
else {
|
||
// return list_entry (list_pop_front (&ready_list), struct thread, elem);
|
||
|
||
struct list_elem * th_max_elem = list_max(&ready_list, comp_priority, NULL);
|
||
struct thread * th_max = list_entry(th_max_elem, struct thread, elem);
|
||
list_remove(th_max_elem);
|
||
return th_max;
|
||
}
|
||
}
|
||
|
||
bool comp_priority(struct list_elem * a, struct list_elem * b, void *aux) {
|
||
struct thread * at = list_entry(a, struct thread, elem);
|
||
struct thread * bt = list_entry(b, struct thread, elem);
|
||
|
||
return at -> priority < bt -> priority;
|
||
}
|
||
|
||
void thread_yield_for_higher_priority(void) {
|
||
enum intr_level old_level = intr_disable();
|
||
|
||
if (!list_empty(&ready_list)) {
|
||
struct list_elem * th_max_elem = list_max(&ready_list, comp_priority, NULL);
|
||
struct thread * th_max = list_entry(th_max_elem, struct thread, elem);
|
||
|
||
struct thread * th_cur = thread_current();
|
||
if (th_cur -> priority < th_max -> priority)
|
||
thread_yield();
|
||
}
|
||
|
||
intr_set_level(old_level);
|
||
}
|
||
|
||
/* Completes a thread switch by activating the new thread's page
|
||
tables, and, if the previous thread is dying, destroying it.
|
||
|
||
At this function's invocation, we just switched from thread
|
||
PREV, the new thread is already running, and interrupts are
|
||
still disabled. This function is normally invoked by
|
||
thread_schedule() as its final action before returning, but
|
||
the first time a thread is scheduled it is called by
|
||
switch_entry() (see switch.S).
|
||
|
||
It's not safe to call printf() until the thread switch is
|
||
complete. In practice that means that printf()s should be
|
||
added at the end of the function.
|
||
|
||
After this function and its caller returns, the thread switch
|
||
is complete. */
|
||
void
|
||
thread_schedule_tail (struct thread *prev)
|
||
{
|
||
struct thread *cur = running_thread ();
|
||
|
||
ASSERT (intr_get_level () == INTR_OFF);
|
||
|
||
/* Mark us as running. */
|
||
cur->status = THREAD_RUNNING;
|
||
|
||
/* Start new time slice. */
|
||
thread_ticks = 0;
|
||
|
||
#ifdef USERPROG
|
||
/* Activate the new address space. */
|
||
process_activate ();
|
||
#endif
|
||
|
||
/* If the thread we switched from is dying, destroy its struct
|
||
thread. This must happen late so that thread_exit() doesn't
|
||
pull out the rug under itself. (We don't free
|
||
initial_thread because its memory was not obtained via
|
||
palloc().) */
|
||
if (prev != NULL && prev->status == THREAD_DYING && prev != initial_thread)
|
||
{
|
||
ASSERT (prev != cur);
|
||
palloc_free_page (prev);
|
||
}
|
||
}
|
||
|
||
/* Schedules a new process. At entry, interrupts must be off and
|
||
the running process's state must have been changed from
|
||
running to some other state. This function finds another
|
||
thread to run and switches to it.
|
||
|
||
It's not safe to call printf() until thread_schedule_tail()
|
||
has completed. */
|
||
static void
|
||
schedule (void)
|
||
{
|
||
struct thread *cur = running_thread ();
|
||
struct thread *next = next_thread_to_run ();
|
||
struct thread *prev = NULL;
|
||
|
||
ASSERT (intr_get_level () == INTR_OFF);
|
||
ASSERT (cur->status != THREAD_RUNNING);
|
||
ASSERT (is_thread (next));
|
||
|
||
if (cur != next)
|
||
prev = switch_threads (cur, next);
|
||
thread_schedule_tail (prev);
|
||
}
|
||
|
||
/* Returns a tid to use for a new thread. */
|
||
static tid_t
|
||
allocate_tid (void)
|
||
{
|
||
static tid_t next_tid = 1;
|
||
tid_t tid;
|
||
|
||
lock_acquire (&tid_lock);
|
||
tid = next_tid++;
|
||
lock_release (&tid_lock);
|
||
|
||
return tid;
|
||
}
|
||
|
||
/* Offset of `stack' member within `struct thread'.
|
||
Used by switch.S, which can't figure it out on its own. */
|
||
uint32_t thread_stack_ofs = offsetof (struct thread, stack);
|