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|
/*
* litmus/sched_cedf.c
*
* Implementation of the C-EDF scheduling algorithm.
*
* This implementation is based on G-EDF:
* - CPUs are clustered around L2 or L3 caches.
* - Clusters topology is automatically detected (this is arch dependent
* and is working only on x86 at the moment --- and only with modern
* cpus that exports cpuid4 information)
* - The plugins _does not_ attempt to put tasks in the right cluster i.e.
* the programmer needs to be aware of the topology to place tasks
* in the desired cluster
* - default clustering is around L2 cache (cache index = 2)
* supported clusters are: L1 (private cache: pedf), L2, L3
*
* For details on functions, take a look at sched_gsn_edf.c
*
* This version uses the simple approach and serializes all scheduling
* decisions by the use of a queue lock. This is probably not the
* best way to do it, but it should suffice for now.
*/
#include <linux/spinlock.h>
#include <linux/percpu.h>
#include <linux/sched.h>
#include <litmus/litmus.h>
#include <litmus/jobs.h>
#include <litmus/sched_plugin.h>
#include <litmus/edf_common.h>
#include <litmus/sched_trace.h>
#include <litmus/bheap.h>
#include <linux/module.h>
/* forward declaration... a funny thing with C ;) */
struct clusterdomain;
/* cpu_entry_t - maintain the linked and scheduled state
*
* A cpu also contains a pointer to the cedf_domain_t cluster
* that owns it (struct clusterdomain*)
*/
typedef struct {
int cpu;
struct clusterdomain* cluster; /* owning cluster */
struct task_struct* linked; /* only RT tasks */
struct task_struct* scheduled; /* only RT tasks */
atomic_t will_schedule; /* prevent unneeded IPIs */
struct bheap_node* hn;
} cpu_entry_t;
/* one cpu_entry_t per CPU */
DEFINE_PER_CPU(cpu_entry_t, cedf_cpu_entries);
#define set_will_schedule() \
(atomic_set(&__get_cpu_var(cedf_cpu_entries).will_schedule, 1))
#define clear_will_schedule() \
(atomic_set(&__get_cpu_var(cedf_cpu_entries).will_schedule, 0))
#define test_will_schedule(cpu) \
(atomic_read(&per_cpu(cedf_cpu_entries, cpu).will_schedule))
/*
* In C-EDF there is a cedf domain _per_ cluster
* The number of clusters is dynamically determined accordingly to the
* total cpu number and the cluster size
*/
typedef struct clusterdomain {
/* rt_domain for this cluster */
rt_domain_t domain;
/* cpus in this cluster */
cpu_entry_t* *cpus;
/* map of this cluster cpus */
cpumask_var_t cpu_map;
/* the cpus queue themselves according to priority in here */
struct bheap_node *heap_node;
struct bheap cpu_heap;
/* lock for this cluster */
#define lock domain.ready_lock
} cedf_domain_t;
/* a cedf_domain per cluster; allocation is done at init/activation time */
cedf_domain_t *cedf;
#define remote_cluster(cpu) ((cedf_domain_t *) per_cpu(cedf_cpu_entries, cpu).cluster)
#define task_cpu_cluster(task) remote_cluster(get_partition(task))
/* Uncomment WANT_ALL_SCHED_EVENTS if you want to see all scheduling
* decisions in the TRACE() log; uncomment VERBOSE_INIT for verbose
* information during the initialization of the plugin (e.g., topology)
#define WANT_ALL_SCHED_EVENTS
*/
#define VERBOSE_INIT
static int cpu_lower_prio(struct bheap_node *_a, struct bheap_node *_b)
{
cpu_entry_t *a, *b;
a = _a->value;
b = _b->value;
/* Note that a and b are inverted: we want the lowest-priority CPU at
* the top of the heap.
*/
return edf_higher_prio(b->linked, a->linked);
}
/* update_cpu_position - Move the cpu entry to the correct place to maintain
* order in the cpu queue. Caller must hold cedf lock.
*/
static void update_cpu_position(cpu_entry_t *entry)
{
cedf_domain_t *cluster = entry->cluster;
if (likely(bheap_node_in_heap(entry->hn)))
bheap_delete(cpu_lower_prio,
&cluster->cpu_heap,
entry->hn);
bheap_insert(cpu_lower_prio, &cluster->cpu_heap, entry->hn);
}
/* caller must hold cedf lock */
static cpu_entry_t* lowest_prio_cpu(cedf_domain_t *cluster)
{
struct bheap_node* hn;
hn = bheap_peek(cpu_lower_prio, &cluster->cpu_heap);
return hn->value;
}
/* link_task_to_cpu - Update the link of a CPU.
* Handles the case where the to-be-linked task is already
* scheduled on a different CPU.
*/
static noinline void link_task_to_cpu(struct task_struct* linked,
cpu_entry_t *entry)
{
cpu_entry_t *sched;
struct task_struct* tmp;
int on_cpu;
BUG_ON(linked && !is_realtime(linked));
/* Currently linked task is set to be unlinked. */
if (entry->linked) {
entry->linked->rt_param.linked_on = NO_CPU;
}
/* Link new task to CPU. */
if (linked) {
set_rt_flags(linked, RT_F_RUNNING);
/* handle task is already scheduled somewhere! */
on_cpu = linked->rt_param.scheduled_on;
if (on_cpu != NO_CPU) {
sched = &per_cpu(cedf_cpu_entries, on_cpu);
/* this should only happen if not linked already */
BUG_ON(sched->linked == linked);
/* If we are already scheduled on the CPU to which we
* wanted to link, we don't need to do the swap --
* we just link ourselves to the CPU and depend on
* the caller to get things right.
*/
if (entry != sched) {
TRACE_TASK(linked,
"already scheduled on %d, updating link.\n",
sched->cpu);
tmp = sched->linked;
linked->rt_param.linked_on = sched->cpu;
sched->linked = linked;
update_cpu_position(sched);
linked = tmp;
}
}
if (linked) /* might be NULL due to swap */
linked->rt_param.linked_on = entry->cpu;
}
entry->linked = linked;
#ifdef WANT_ALL_SCHED_EVENTS
if (linked)
TRACE_TASK(linked, "linked to %d.\n", entry->cpu);
else
TRACE("NULL linked to %d.\n", entry->cpu);
#endif
update_cpu_position(entry);
}
/* unlink - Make sure a task is not linked any longer to an entry
* where it was linked before. Must hold cedf_lock.
*/
static noinline void unlink(struct task_struct* t)
{
cpu_entry_t *entry;
if (unlikely(!t)) {
TRACE_BUG_ON(!t);
return;
}
if (t->rt_param.linked_on != NO_CPU) {
/* unlink */
entry = &per_cpu(cedf_cpu_entries, t->rt_param.linked_on);
t->rt_param.linked_on = NO_CPU;
link_task_to_cpu(NULL, entry);
} else if (is_queued(t)) {
/* This is an interesting situation: t is scheduled,
* but was just recently unlinked. It cannot be
* linked anywhere else (because then it would have
* been relinked to this CPU), thus it must be in some
* queue. We must remove it from the list in this
* case.
*
* in C-EDF case is should be somewhere in the queue for
* its domain, therefore and we can get the domain using
* task_cpu_cluster
*/
remove(&(task_cpu_cluster(t))->domain, t);
}
}
/* preempt - force a CPU to reschedule
*/
static void preempt(cpu_entry_t *entry)
{
preempt_if_preemptable(entry->scheduled, entry->cpu);
}
/* requeue - Put an unlinked task into gsn-edf domain.
* Caller must hold cedf_lock.
*/
static noinline void requeue(struct task_struct* task)
{
cedf_domain_t *cluster = task_cpu_cluster(task);
BUG_ON(!task);
/* sanity check before insertion */
BUG_ON(is_queued(task));
if (is_released(task, litmus_clock()))
__add_ready(&cluster->domain, task);
else {
/* it has got to wait */
add_release(&cluster->domain, task);
}
}
/* check for any necessary preemptions */
static void check_for_preemptions(cedf_domain_t *cluster)
{
struct task_struct *task;
cpu_entry_t* last;
for(last = lowest_prio_cpu(cluster);
edf_preemption_needed(&cluster->domain, last->linked);
last = lowest_prio_cpu(cluster)) {
/* preemption necessary */
task = __take_ready(&cluster->domain);
TRACE("check_for_preemptions: attempting to link task %d to %d\n",
task->pid, last->cpu);
if (last->linked)
requeue(last->linked);
link_task_to_cpu(task, last);
preempt(last);
}
}
/* cedf_job_arrival: task is either resumed or released */
static noinline void cedf_job_arrival(struct task_struct* task)
{
cedf_domain_t *cluster = task_cpu_cluster(task);
BUG_ON(!task);
requeue(task);
check_for_preemptions(cluster);
}
static void cedf_release_jobs(rt_domain_t* rt, struct bheap* tasks)
{
cedf_domain_t* cluster = container_of(rt, cedf_domain_t, domain);
unsigned long flags;
spin_lock_irqsave(&cluster->lock, flags);
__merge_ready(&cluster->domain, tasks);
check_for_preemptions(cluster);
spin_unlock_irqrestore(&cluster->lock, flags);
}
/* caller holds cedf_lock */
static noinline void job_completion(struct task_struct *t, int forced)
{
BUG_ON(!t);
sched_trace_task_completion(t, forced);
TRACE_TASK(t, "job_completion().\n");
/* set flags */
set_rt_flags(t, RT_F_SLEEP);
/* prepare for next period */
prepare_for_next_period(t);
if (is_released(t, litmus_clock()))
sched_trace_task_release(t);
/* unlink */
unlink(t);
/* requeue
* But don't requeue a blocking task. */
if (is_running(t))
cedf_job_arrival(t);
}
/* cedf_tick - this function is called for every local timer
* interrupt.
*
* checks whether the current task has expired and checks
* whether we need to preempt it if it has not expired
*/
static void cedf_tick(struct task_struct* t)
{
if (is_realtime(t) && budget_exhausted(t)) {
if (!is_np(t)) {
/* np tasks will be preempted when they become
* preemptable again
*/
set_tsk_need_resched(t);
set_will_schedule();
TRACE("cedf_scheduler_tick: "
"%d is preemptable "
" => FORCE_RESCHED\n", t->pid);
} else if (is_user_np(t)) {
TRACE("cedf_scheduler_tick: "
"%d is non-preemptable, "
"preemption delayed.\n", t->pid);
request_exit_np(t);
}
}
}
/* Getting schedule() right is a bit tricky. schedule() may not make any
* assumptions on the state of the current task since it may be called for a
* number of reasons. The reasons include a scheduler_tick() determined that it
* was necessary, because sys_exit_np() was called, because some Linux
* subsystem determined so, or even (in the worst case) because there is a bug
* hidden somewhere. Thus, we must take extreme care to determine what the
* current state is.
*
* The CPU could currently be scheduling a task (or not), be linked (or not).
*
* The following assertions for the scheduled task could hold:
*
* - !is_running(scheduled) // the job blocks
* - scheduled->timeslice == 0 // the job completed (forcefully)
* - get_rt_flag() == RT_F_SLEEP // the job completed (by syscall)
* - linked != scheduled // we need to reschedule (for any reason)
* - is_np(scheduled) // rescheduling must be delayed,
* sys_exit_np must be requested
*
* Any of these can occur together.
*/
static struct task_struct* cedf_schedule(struct task_struct * prev)
{
cpu_entry_t* entry = &__get_cpu_var(cedf_cpu_entries);
cedf_domain_t *cluster = entry->cluster;
int out_of_time, sleep, preempt, np, exists, blocks;
struct task_struct* next = NULL;
spin_lock(&cluster->lock);
clear_will_schedule();
/* sanity checking */
BUG_ON(entry->scheduled && entry->scheduled != prev);
BUG_ON(entry->scheduled && !is_realtime(prev));
BUG_ON(is_realtime(prev) && !entry->scheduled);
/* (0) Determine state */
exists = entry->scheduled != NULL;
blocks = exists && !is_running(entry->scheduled);
out_of_time = exists && budget_exhausted(entry->scheduled);
np = exists && is_np(entry->scheduled);
sleep = exists && get_rt_flags(entry->scheduled) == RT_F_SLEEP;
preempt = entry->scheduled != entry->linked;
#ifdef WANT_ALL_SCHED_EVENTS
TRACE_TASK(prev, "invoked cedf_schedule.\n");
#endif
if (exists)
TRACE_TASK(prev,
"blocks:%d out_of_time:%d np:%d sleep:%d preempt:%d "
"state:%d sig:%d\n",
blocks, out_of_time, np, sleep, preempt,
prev->state, signal_pending(prev));
if (entry->linked && preempt)
TRACE_TASK(prev, "will be preempted by %s/%d\n",
entry->linked->comm, entry->linked->pid);
/* If a task blocks we have no choice but to reschedule.
*/
if (blocks)
unlink(entry->scheduled);
/* Request a sys_exit_np() call if we would like to preempt but cannot.
* We need to make sure to update the link structure anyway in case
* that we are still linked. Multiple calls to request_exit_np() don't
* hurt.
*/
if (np && (out_of_time || preempt || sleep)) {
unlink(entry->scheduled);
request_exit_np(entry->scheduled);
}
/* Any task that is preemptable and either exhausts its execution
* budget or wants to sleep completes. We may have to reschedule after
* this. Don't do a job completion if we block (can't have timers running
* for blocked jobs). Preemption go first for the same reason.
*/
if (!np && (out_of_time || sleep) && !blocks && !preempt)
job_completion(entry->scheduled, !sleep);
/* Link pending task if we became unlinked.
*/
if (!entry->linked)
link_task_to_cpu(__take_ready(&cluster->domain), entry);
/* The final scheduling decision. Do we need to switch for some reason?
* If linked is different from scheduled, then select linked as next.
*/
if ((!np || blocks) &&
entry->linked != entry->scheduled) {
/* Schedule a linked job? */
if (entry->linked) {
entry->linked->rt_param.scheduled_on = entry->cpu;
next = entry->linked;
}
if (entry->scheduled) {
/* not gonna be scheduled soon */
entry->scheduled->rt_param.scheduled_on = NO_CPU;
TRACE_TASK(entry->scheduled, "scheduled_on = NO_CPU\n");
}
} else
/* Only override Linux scheduler if we have a real-time task
* scheduled that needs to continue.
*/
if (exists)
next = prev;
spin_unlock(&cluster->lock);
#ifdef WANT_ALL_SCHED_EVENTS
TRACE("cedf_lock released, next=0x%p\n", next);
if (next)
TRACE_TASK(next, "scheduled at %llu\n", litmus_clock());
else if (exists && !next)
TRACE("becomes idle at %llu.\n", litmus_clock());
#endif
return next;
}
/* _finish_switch - we just finished the switch away from prev
*/
static void cedf_finish_switch(struct task_struct *prev)
{
cpu_entry_t* entry = &__get_cpu_var(cedf_cpu_entries);
entry->scheduled = is_realtime(current) ? current : NULL;
#ifdef WANT_ALL_SCHED_EVENTS
TRACE_TASK(prev, "switched away from\n");
#endif
}
/* Prepare a task for running in RT mode
*/
static void cedf_task_new(struct task_struct * t, int on_rq, int running)
{
unsigned long flags;
cpu_entry_t* entry;
cedf_domain_t* cluster;
TRACE("gsn edf: task new %d\n", t->pid);
/* the cluster doesn't change even if t is running */
cluster = task_cpu_cluster(t);
spin_lock_irqsave(&cluster->domain.ready_lock, flags);
/* setup job params */
release_at(t, litmus_clock());
if (running) {
entry = &per_cpu(cedf_cpu_entries, task_cpu(t));
BUG_ON(entry->scheduled);
entry->scheduled = t;
tsk_rt(t)->scheduled_on = task_cpu(t);
} else {
t->rt_param.scheduled_on = NO_CPU;
}
t->rt_param.linked_on = NO_CPU;
cedf_job_arrival(t);
spin_unlock_irqrestore(&(cluster->domain.ready_lock), flags);
}
static void cedf_task_wake_up(struct task_struct *task)
{
unsigned long flags;
lt_t now;
cedf_domain_t *cluster;
TRACE_TASK(task, "wake_up at %llu\n", litmus_clock());
cluster = task_cpu_cluster(task);
spin_lock_irqsave(&cluster->lock, flags);
/* We need to take suspensions because of semaphores into
* account! If a job resumes after being suspended due to acquiring
* a semaphore, it should never be treated as a new job release.
*/
if (get_rt_flags(task) == RT_F_EXIT_SEM) {
set_rt_flags(task, RT_F_RUNNING);
} else {
now = litmus_clock();
if (is_tardy(task, now)) {
/* new sporadic release */
release_at(task, now);
sched_trace_task_release(task);
}
else {
if (task->rt.time_slice) {
/* came back in time before deadline
*/
set_rt_flags(task, RT_F_RUNNING);
}
}
}
cedf_job_arrival(task);
spin_unlock_irqrestore(&cluster->lock, flags);
}
static void cedf_task_block(struct task_struct *t)
{
unsigned long flags;
cedf_domain_t *cluster;
TRACE_TASK(t, "block at %llu\n", litmus_clock());
cluster = task_cpu_cluster(t);
/* unlink if necessary */
spin_lock_irqsave(&cluster->lock, flags);
unlink(t);
spin_unlock_irqrestore(&cluster->lock, flags);
BUG_ON(!is_realtime(t));
}
static void cedf_task_exit(struct task_struct * t)
{
unsigned long flags;
cedf_domain_t *cluster = task_cpu_cluster(t);
/* unlink if necessary */
spin_lock_irqsave(&cluster->lock, flags);
unlink(t);
if (tsk_rt(t)->scheduled_on != NO_CPU) {
cluster->cpus[tsk_rt(t)->scheduled_on]->scheduled = NULL;
tsk_rt(t)->scheduled_on = NO_CPU;
}
spin_unlock_irqrestore(&cluster->lock, flags);
BUG_ON(!is_realtime(t));
TRACE_TASK(t, "RIP\n");
}
static long cedf_admit_task(struct task_struct* tsk)
{
return task_cpu(tsk) == tsk->rt_param.task_params.cpu ? 0 : -EINVAL;
}
/* total number of cluster */
static int num_clusters;
/* we do not support cluster of different sizes */
static unsigned int cluster_size;
#ifdef VERBOSE_INIT
static void print_cluster_topology(cpumask_var_t mask, int cpu)
{
int chk;
char buf[255];
chk = cpulist_scnprintf(buf, 254, mask);
buf[chk] = '\0';
printk(KERN_INFO "CPU = %d, shared cpu(s) = %s\n", cpu, buf);
}
#endif
static int clusters_allocated = 0;
static void cleanup_cedf(void)
{
int i;
if (clusters_allocated) {
for (i = 0; i < num_clusters; i++) {
kfree(cedf[i].cpus);
kfree(cedf[i].heap_node);
free_cpumask_var(cedf[i].cpu_map);
}
kfree(cedf);
}
}
static long cedf_activate_plugin(void)
{
int i, j, cpu, ccpu, cpu_count;
cpu_entry_t *entry;
cpumask_var_t mask;
int chk = 0;
/* de-allocate old clusters, if any */
cleanup_cedf();
printk(KERN_INFO "C-EDF: Activate Plugin, cache index = %d\n",
cluster_cache_index);
/* need to get cluster_size first */
if(!zalloc_cpumask_var(&mask, GFP_ATOMIC))
return -ENOMEM;
chk = get_shared_cpu_map(mask, 0, cluster_cache_index);
if (chk) {
/* if chk != 0 then it is the max allowed index */
printk(KERN_INFO "C-EDF: Cannot support cache index = %d\n",
cluster_cache_index);
printk(KERN_INFO "C-EDF: Using cache index = %d\n",
chk);
cluster_cache_index = chk;
}
cluster_size = cpumask_weight(mask);
if ((num_online_cpus() % cluster_size) != 0) {
/* this can't be right, some cpus are left out */
printk(KERN_ERR "C-EDF: Trying to group %d cpus in %d!\n",
num_online_cpus(), cluster_size);
return -1;
}
num_clusters = num_online_cpus() / cluster_size;
printk(KERN_INFO "C-EDF: %d cluster(s) of size = %d\n",
num_clusters, cluster_size);
/* initialize clusters */
cedf = kmalloc(num_clusters * sizeof(cedf_domain_t), GFP_ATOMIC);
for (i = 0; i < num_clusters; i++) {
cedf[i].cpus = kmalloc(cluster_size * sizeof(cpu_entry_t),
GFP_ATOMIC);
cedf[i].heap_node = kmalloc(
cluster_size * sizeof(struct bheap_node),
GFP_ATOMIC);
bheap_init(&(cedf[i].cpu_heap));
edf_domain_init(&(cedf[i].domain), NULL, cedf_release_jobs);
if(!zalloc_cpumask_var(&cedf[i].cpu_map, GFP_ATOMIC))
return -ENOMEM;
}
/* cycle through cluster and add cpus to them */
for (i = 0; i < num_clusters; i++) {
for_each_online_cpu(cpu) {
/* check if the cpu is already in a cluster */
for (j = 0; j < num_clusters; j++)
if (cpumask_test_cpu(cpu, cedf[j].cpu_map))
break;
/* if it is in a cluster go to next cpu */
if (cpumask_test_cpu(cpu, cedf[j].cpu_map))
continue;
/* this cpu isn't in any cluster */
/* get the shared cpus */
get_shared_cpu_map(mask, cpu, cluster_cache_index);
cpumask_copy(cedf[i].cpu_map, mask);
#ifdef VERBOSE_INIT
print_cluster_topology(mask, cpu);
#endif
/* add cpus to current cluster and init cpu_entry_t */
cpu_count = 0;
for_each_cpu(ccpu, cedf[i].cpu_map) {
entry = &per_cpu(cedf_cpu_entries, ccpu);
cedf[i].cpus[cpu_count] = entry;
atomic_set(&entry->will_schedule, 0);
entry->cpu = ccpu;
entry->cluster = &cedf[i];
entry->hn = &(cedf[i].heap_node[cpu_count]);
bheap_node_init(&entry->hn, entry);
cpu_count++;
entry->linked = NULL;
entry->scheduled = NULL;
update_cpu_position(entry);
}
/* done with this cluster */
break;
}
}
free_cpumask_var(mask);
clusters_allocated = 1;
return 0;
}
/* Plugin object */
static struct sched_plugin cedf_plugin __cacheline_aligned_in_smp = {
.plugin_name = "C-EDF",
.finish_switch = cedf_finish_switch,
.tick = cedf_tick,
.task_new = cedf_task_new,
.complete_job = complete_job,
.task_exit = cedf_task_exit,
.schedule = cedf_schedule,
.task_wake_up = cedf_task_wake_up,
.task_block = cedf_task_block,
.admit_task = cedf_admit_task,
.activate_plugin = cedf_activate_plugin,
};
static int __init init_cedf(void)
{
return register_sched_plugin(&cedf_plugin);
}
static void clean_cedf(void)
{
cleanup_cedf();
}
module_init(init_cedf);
module_exit(clean_cedf);
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