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|
/*
* Mach Operating System
* Copyright (c) 1993-1988 Carnegie Mellon University
* All Rights Reserved.
*
* Permission to use, copy, modify and distribute this software and its
* documentation is hereby granted, provided that both the copyright
* notice and this permission notice appear in all copies of the
* software, derivative works or modified versions, and any portions
* thereof, and that both notices appear in supporting documentation.
*
* CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
* CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR
* ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
*
* Carnegie Mellon requests users of this software to return to
*
* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
* School of Computer Science
* Carnegie Mellon University
* Pittsburgh PA 15213-3890
*
* any improvements or extensions that they make and grant Carnegie Mellon
* the rights to redistribute these changes.
*/
/*
* File: kern/task.c
* Author: Avadis Tevanian, Jr., Michael Wayne Young, David Golub,
* David Black
*
* Task management primitives implementation.
*/
#include <string.h>
#include <mach/machine/vm_types.h>
#include <mach/vm_param.h>
#include <mach/task_info.h>
#include <mach/task_special_ports.h>
#include <ipc/ipc_space.h>
#include <ipc/ipc_types.h>
#include <kern/debug.h>
#include <kern/mach_param.h>
#include <kern/task.h>
#include <kern/thread.h>
#include <kern/zalloc.h>
#include <kern/kalloc.h>
#include <kern/processor.h>
#include <kern/sched_prim.h> /* for thread_wakeup */
#include <kern/ipc_tt.h>
#include <vm/vm_kern.h> /* for kernel_map, ipc_kernel_map */
#include <machine/machspl.h> /* for splsched */
task_t kernel_task = TASK_NULL;
zone_t task_zone;
extern void eml_init(void);
extern void eml_task_reference(task_t, task_t);
extern void eml_task_deallocate(task_t);
void task_init(void)
{
task_zone = zinit(
sizeof(struct task), 0,
TASK_MAX * sizeof(struct task),
TASK_CHUNK * sizeof(struct task),
0, "tasks");
eml_init();
machine_task_module_init ();
/*
* Create the kernel task as the first task.
* Task_create must assign to kernel_task as a side effect,
* for other initialization. (:-()
*/
(void) task_create(TASK_NULL, FALSE, &kernel_task);
}
/*
* Create a task running in the kernel address space. It may
* have its own map of size mem_size (if 0, it uses the kernel map),
* and may have ipc privileges.
*/
task_t kernel_task_create(
task_t parent_task,
vm_size_t map_size)
{
task_t new_task;
vm_offset_t min, max;
/*
* Create the task.
*/
(void) task_create(parent_task, FALSE, &new_task);
/*
* Task_create creates the task with a user-space map.
* Remove the map and replace it with the kernel map
* or a submap of the kernel map.
*/
vm_map_deallocate(new_task->map);
if (map_size == 0)
new_task->map = kernel_map;
else
new_task->map = kmem_suballoc(kernel_map, &min, &max,
map_size, FALSE);
return new_task;
}
kern_return_t task_create(
task_t parent_task,
boolean_t inherit_memory,
task_t *child_task) /* OUT */
{
register task_t new_task;
register processor_set_t pset;
int i;
new_task = (task_t) zalloc(task_zone);
if (new_task == TASK_NULL) {
panic("task_create: no memory for task structure");
}
/* one ref for just being alive; one for our caller */
new_task->ref_count = 2;
if (child_task == &kernel_task) {
new_task->map = kernel_map;
} else if (inherit_memory) {
new_task->map = vm_map_fork(parent_task->map);
} else {
new_task->map = vm_map_create(pmap_create(0),
round_page(VM_MIN_ADDRESS),
trunc_page(VM_MAX_ADDRESS), TRUE);
}
simple_lock_init(&new_task->lock);
queue_init(&new_task->thread_list);
new_task->suspend_count = 0;
new_task->active = TRUE;
new_task->user_stop_count = 0;
new_task->thread_count = 0;
eml_task_reference(new_task, parent_task);
ipc_task_init(new_task, parent_task);
machine_task_init (new_task);
new_task->total_user_time.seconds = 0;
new_task->total_user_time.microseconds = 0;
new_task->total_system_time.seconds = 0;
new_task->total_system_time.microseconds = 0;
record_time_stamp (&new_task->creation_time);
if (parent_task != TASK_NULL) {
task_lock(parent_task);
pset = parent_task->processor_set;
if (!pset->active)
pset = &default_pset;
pset_reference(pset);
new_task->priority = parent_task->priority;
task_unlock(parent_task);
}
else {
pset = &default_pset;
pset_reference(pset);
new_task->priority = BASEPRI_USER;
}
pset_lock(pset);
pset_add_task(pset, new_task);
pset_unlock(pset);
new_task->may_assign = TRUE;
new_task->assign_active = FALSE;
#if MACH_PCSAMPLE
new_task->pc_sample.buffer = 0;
new_task->pc_sample.seqno = 0;
new_task->pc_sample.sampletypes = 0;
#endif /* MACH_PCSAMPLE */
#if FAST_TAS
for (i = 0; i < TASK_FAST_TAS_NRAS; i++) {
if (inherit_memory) {
new_task->fast_tas_base[i] = parent_task->fast_tas_base[i];
new_task->fast_tas_end[i] = parent_task->fast_tas_end[i];
} else {
new_task->fast_tas_base[i] = (vm_offset_t)0;
new_task->fast_tas_end[i] = (vm_offset_t)0;
}
}
#endif /* FAST_TAS */
ipc_task_enable(new_task);
*child_task = new_task;
return KERN_SUCCESS;
}
/*
* task_deallocate:
*
* Give up a reference to the specified task and destroy it if there
* are no other references left. It is assumed that the current thread
* is never in this task.
*/
void task_deallocate(
register task_t task)
{
register int c;
register processor_set_t pset;
if (task == TASK_NULL)
return;
task_lock(task);
c = --(task->ref_count);
task_unlock(task);
if (c != 0)
return;
machine_task_terminate (task);
eml_task_deallocate(task);
pset = task->processor_set;
pset_lock(pset);
pset_remove_task(pset,task);
pset_unlock(pset);
pset_deallocate(pset);
vm_map_deallocate(task->map);
is_release(task->itk_space);
zfree(task_zone, (vm_offset_t) task);
}
void task_reference(
register task_t task)
{
if (task == TASK_NULL)
return;
task_lock(task);
task->ref_count++;
task_unlock(task);
}
/*
* task_terminate:
*
* Terminate the specified task. See comments on thread_terminate
* (kern/thread.c) about problems with terminating the "current task."
*/
kern_return_t task_terminate(
register task_t task)
{
register thread_t thread, cur_thread;
register queue_head_t *list;
register task_t cur_task;
spl_t s;
if (task == TASK_NULL)
return KERN_INVALID_ARGUMENT;
list = &task->thread_list;
cur_task = current_task();
cur_thread = current_thread();
/*
* Deactivate task so that it can't be terminated again,
* and so lengthy operations in progress will abort.
*
* If the current thread is in this task, remove it from
* the task's thread list to keep the thread-termination
* loop simple.
*/
if (task == cur_task) {
task_lock(task);
if (!task->active) {
/*
* Task is already being terminated.
*/
task_unlock(task);
return KERN_FAILURE;
}
/*
* Make sure current thread is not being terminated.
*/
s = splsched();
thread_lock(cur_thread);
if (!cur_thread->active) {
thread_unlock(cur_thread);
(void) splx(s);
task_unlock(task);
thread_terminate(cur_thread);
return KERN_FAILURE;
}
task->active = FALSE;
queue_remove(list, cur_thread, thread_t, thread_list);
thread_unlock(cur_thread);
(void) splx(s);
task_unlock(task);
/*
* Shut down this thread's ipc now because it must
* be left alone to terminate the task.
*/
ipc_thread_disable(cur_thread);
ipc_thread_terminate(cur_thread);
}
else {
/*
* Lock both current and victim task to check for
* potential deadlock.
*/
if ((vm_offset_t)task < (vm_offset_t)cur_task) {
task_lock(task);
task_lock(cur_task);
}
else {
task_lock(cur_task);
task_lock(task);
}
/*
* Check if current thread or task is being terminated.
*/
s = splsched();
thread_lock(cur_thread);
if ((!cur_task->active) ||(!cur_thread->active)) {
/*
* Current task or thread is being terminated.
*/
thread_unlock(cur_thread);
(void) splx(s);
task_unlock(task);
task_unlock(cur_task);
thread_terminate(cur_thread);
return KERN_FAILURE;
}
thread_unlock(cur_thread);
(void) splx(s);
task_unlock(cur_task);
if (!task->active) {
/*
* Task is already being terminated.
*/
task_unlock(task);
return KERN_FAILURE;
}
task->active = FALSE;
task_unlock(task);
}
/*
* Prevent further execution of the task. ipc_task_disable
* prevents further task operations via the task port.
* If this is the current task, the current thread will
* be left running.
*/
ipc_task_disable(task);
(void) task_hold(task);
(void) task_dowait(task,TRUE); /* may block */
/*
* Terminate each thread in the task.
*
* The task_port is closed down, so no more thread_create
* operations can be done. Thread_force_terminate closes the
* thread port for each thread; when that is done, the
* thread will eventually disappear. Thus the loop will
* terminate. Call thread_force_terminate instead of
* thread_terminate to avoid deadlock checks. Need
* to call thread_block() inside loop because some other
* thread (e.g., the reaper) may have to run to get rid
* of all references to the thread; it won't vanish from
* the task's thread list until the last one is gone.
*/
task_lock(task);
while (!queue_empty(list)) {
thread = (thread_t) queue_first(list);
thread_reference(thread);
task_unlock(task);
thread_force_terminate(thread);
thread_deallocate(thread);
thread_block((void (*)()) 0);
task_lock(task);
}
task_unlock(task);
/*
* Shut down IPC.
*/
ipc_task_terminate(task);
/*
* Deallocate the task's reference to itself.
*/
task_deallocate(task);
/*
* If the current thread is in this task, it has not yet
* been terminated (since it was removed from the task's
* thread-list). Put it back in the thread list (for
* completeness), and terminate it. Since it holds the
* last reference to the task, terminating it will deallocate
* the task.
*/
if (cur_thread->task == task) {
task_lock(task);
s = splsched();
queue_enter(list, cur_thread, thread_t, thread_list);
(void) splx(s);
task_unlock(task);
(void) thread_terminate(cur_thread);
}
return KERN_SUCCESS;
}
/*
* task_hold:
*
* Suspend execution of the specified task.
* This is a recursive-style suspension of the task, a count of
* suspends is maintained.
*/
kern_return_t task_hold(
register task_t task)
{
register queue_head_t *list;
register thread_t thread, cur_thread;
cur_thread = current_thread();
task_lock(task);
if (!task->active) {
task_unlock(task);
return KERN_FAILURE;
}
task->suspend_count++;
/*
* Iterate through all the threads and hold them.
* Do not hold the current thread if it is within the
* task.
*/
list = &task->thread_list;
queue_iterate(list, thread, thread_t, thread_list) {
if (thread != cur_thread)
thread_hold(thread);
}
task_unlock(task);
return KERN_SUCCESS;
}
/*
* task_dowait:
*
* Wait until the task has really been suspended (all of the threads
* are stopped). Skip the current thread if it is within the task.
*
* If task is deactivated while waiting, return a failure code unless
* must_wait is true.
*/
kern_return_t task_dowait(
register task_t task,
boolean_t must_wait)
{
register queue_head_t *list;
register thread_t thread, cur_thread, prev_thread;
register kern_return_t ret = KERN_SUCCESS;
/*
* Iterate through all the threads.
* While waiting for each thread, we gain a reference to it
* to prevent it from going away on us. This guarantees
* that the "next" thread in the list will be a valid thread.
*
* We depend on the fact that if threads are created while
* we are looping through the threads, they will be held
* automatically. We don't care about threads that get
* deallocated along the way (the reference prevents it
* from happening to the thread we are working with).
*
* If the current thread is in the affected task, it is skipped.
*
* If the task is deactivated before we're done, and we don't
* have to wait for it (must_wait is FALSE), just bail out.
*/
cur_thread = current_thread();
list = &task->thread_list;
prev_thread = THREAD_NULL;
task_lock(task);
queue_iterate(list, thread, thread_t, thread_list) {
if (!(task->active) && !(must_wait)) {
ret = KERN_FAILURE;
break;
}
if (thread != cur_thread) {
thread_reference(thread);
task_unlock(task);
if (prev_thread != THREAD_NULL)
thread_deallocate(prev_thread);
/* may block */
(void) thread_dowait(thread, TRUE); /* may block */
prev_thread = thread;
task_lock(task);
}
}
task_unlock(task);
if (prev_thread != THREAD_NULL)
thread_deallocate(prev_thread); /* may block */
return ret;
}
kern_return_t task_release(
register task_t task)
{
register queue_head_t *list;
register thread_t thread, next;
task_lock(task);
if (!task->active) {
task_unlock(task);
return KERN_FAILURE;
}
task->suspend_count--;
/*
* Iterate through all the threads and release them
*/
list = &task->thread_list;
thread = (thread_t) queue_first(list);
while (!queue_end(list, (queue_entry_t) thread)) {
next = (thread_t) queue_next(&thread->thread_list);
thread_release(thread);
thread = next;
}
task_unlock(task);
return KERN_SUCCESS;
}
kern_return_t task_threads(
task_t task,
thread_array_t *thread_list,
natural_t *count)
{
unsigned int actual; /* this many threads */
thread_t thread;
thread_t *threads;
int i;
vm_size_t size, size_needed;
vm_offset_t addr;
if (task == TASK_NULL)
return KERN_INVALID_ARGUMENT;
size = 0; addr = 0;
for (;;) {
task_lock(task);
if (!task->active) {
task_unlock(task);
return KERN_FAILURE;
}
actual = task->thread_count;
/* do we have the memory we need? */
size_needed = actual * sizeof(mach_port_t);
if (size_needed <= size)
break;
/* unlock the task and allocate more memory */
task_unlock(task);
if (size != 0)
kfree(addr, size);
assert(size_needed > 0);
size = size_needed;
addr = kalloc(size);
if (addr == 0)
return KERN_RESOURCE_SHORTAGE;
}
/* OK, have memory and the task is locked & active */
threads = (thread_t *) addr;
for (i = 0, thread = (thread_t) queue_first(&task->thread_list);
i < actual;
i++, thread = (thread_t) queue_next(&thread->thread_list)) {
/* take ref for convert_thread_to_port */
thread_reference(thread);
threads[i] = thread;
}
assert(queue_end(&task->thread_list, (queue_entry_t) thread));
/* can unlock task now that we've got the thread refs */
task_unlock(task);
if (actual == 0) {
/* no threads, so return null pointer and deallocate memory */
*thread_list = 0;
*count = 0;
if (size != 0)
kfree(addr, size);
} else {
/* if we allocated too much, must copy */
if (size_needed < size) {
vm_offset_t newaddr;
newaddr = kalloc(size_needed);
if (newaddr == 0) {
for (i = 0; i < actual; i++)
thread_deallocate(threads[i]);
kfree(addr, size);
return KERN_RESOURCE_SHORTAGE;
}
memcpy((void *) newaddr, (void *) addr, size_needed);
kfree(addr, size);
threads = (thread_t *) newaddr;
}
*thread_list = (mach_port_t *) threads;
*count = actual;
/* do the conversion that Mig should handle */
for (i = 0; i < actual; i++)
((ipc_port_t *) threads)[i] =
convert_thread_to_port(threads[i]);
}
return KERN_SUCCESS;
}
kern_return_t task_suspend(
register task_t task)
{
register boolean_t hold;
if (task == TASK_NULL)
return KERN_INVALID_ARGUMENT;
hold = FALSE;
task_lock(task);
if ((task->user_stop_count)++ == 0)
hold = TRUE;
task_unlock(task);
/*
* If the stop count was positive, the task is
* already stopped and we can exit.
*/
if (!hold) {
return KERN_SUCCESS;
}
/*
* Hold all of the threads in the task, and wait for
* them to stop. If the current thread is within
* this task, hold it separately so that all of the
* other threads can stop first.
*/
if (task_hold(task) != KERN_SUCCESS)
return KERN_FAILURE;
if (task_dowait(task, FALSE) != KERN_SUCCESS)
return KERN_FAILURE;
if (current_task() == task) {
spl_t s;
thread_hold(current_thread());
/*
* We want to call thread_block on our way out,
* to stop running.
*/
s = splsched();
ast_on(cpu_number(), AST_BLOCK);
(void) splx(s);
}
return KERN_SUCCESS;
}
kern_return_t task_resume(
register task_t task)
{
register boolean_t release;
if (task == TASK_NULL)
return KERN_INVALID_ARGUMENT;
release = FALSE;
task_lock(task);
if (task->user_stop_count > 0) {
if (--(task->user_stop_count) == 0)
release = TRUE;
}
else {
task_unlock(task);
return KERN_FAILURE;
}
task_unlock(task);
/*
* Release the task if necessary.
*/
if (release)
return task_release(task);
return KERN_SUCCESS;
}
kern_return_t task_info(
task_t task,
int flavor,
task_info_t task_info_out, /* pointer to OUT array */
natural_t *task_info_count) /* IN/OUT */
{
vm_map_t map;
if (task == TASK_NULL)
return KERN_INVALID_ARGUMENT;
switch (flavor) {
case TASK_BASIC_INFO:
{
register task_basic_info_t basic_info;
/* Allow *task_info_count to be two words smaller than
the usual amount, because creation_time is a new member
that some callers might not know about. */
if (*task_info_count < TASK_BASIC_INFO_COUNT - 2) {
return KERN_INVALID_ARGUMENT;
}
basic_info = (task_basic_info_t) task_info_out;
map = (task == kernel_task) ? kernel_map : task->map;
basic_info->virtual_size = map->size;
basic_info->resident_size = pmap_resident_count(map->pmap)
* PAGE_SIZE;
task_lock(task);
basic_info->base_priority = task->priority;
basic_info->suspend_count = task->user_stop_count;
basic_info->user_time.seconds
= task->total_user_time.seconds;
basic_info->user_time.microseconds
= task->total_user_time.microseconds;
basic_info->system_time.seconds
= task->total_system_time.seconds;
basic_info->system_time.microseconds
= task->total_system_time.microseconds;
basic_info->creation_time = task->creation_time;
task_unlock(task);
if (*task_info_count > TASK_BASIC_INFO_COUNT)
*task_info_count = TASK_BASIC_INFO_COUNT;
break;
}
case TASK_THREAD_TIMES_INFO:
{
register task_thread_times_info_t times_info;
register thread_t thread;
if (*task_info_count < TASK_THREAD_TIMES_INFO_COUNT) {
return KERN_INVALID_ARGUMENT;
}
times_info = (task_thread_times_info_t) task_info_out;
times_info->user_time.seconds = 0;
times_info->user_time.microseconds = 0;
times_info->system_time.seconds = 0;
times_info->system_time.microseconds = 0;
task_lock(task);
queue_iterate(&task->thread_list, thread,
thread_t, thread_list)
{
time_value_t user_time, system_time;
spl_t s;
s = splsched();
thread_lock(thread);
thread_read_times(thread, &user_time, &system_time);
thread_unlock(thread);
splx(s);
time_value_add(×_info->user_time, &user_time);
time_value_add(×_info->system_time, &system_time);
}
task_unlock(task);
*task_info_count = TASK_THREAD_TIMES_INFO_COUNT;
break;
}
default:
return KERN_INVALID_ARGUMENT;
}
return KERN_SUCCESS;
}
#if MACH_HOST
/*
* task_assign:
*
* Change the assigned processor set for the task
*/
kern_return_t
task_assign(
task_t task,
processor_set_t new_pset,
boolean_t assign_threads)
{
kern_return_t ret = KERN_SUCCESS;
register thread_t thread, prev_thread;
register queue_head_t *list;
register processor_set_t pset;
if (task == TASK_NULL || new_pset == PROCESSOR_SET_NULL) {
return KERN_INVALID_ARGUMENT;
}
/*
* Freeze task`s assignment. Prelude to assigning
* task. Only one freeze may be held per task.
*/
task_lock(task);
while (task->may_assign == FALSE) {
task->assign_active = TRUE;
assert_wait((event_t)&task->assign_active, TRUE);
task_unlock(task);
thread_block((void (*)()) 0);
task_lock(task);
}
/*
* Avoid work if task already in this processor set.
*/
if (task->processor_set == new_pset) {
/*
* No need for task->assign_active wakeup:
* task->may_assign is still TRUE.
*/
task_unlock(task);
return KERN_SUCCESS;
}
task->may_assign = FALSE;
task_unlock(task);
/*
* Safe to get the task`s pset: it cannot change while
* task is frozen.
*/
pset = task->processor_set;
/*
* Lock both psets now. Use ordering to avoid deadlock.
*/
Restart:
if ((vm_offset_t) pset < (vm_offset_t) new_pset) {
pset_lock(pset);
pset_lock(new_pset);
}
else {
pset_lock(new_pset);
pset_lock(pset);
}
/*
* Check if new_pset is ok to assign to. If not,
* reassign to default_pset.
*/
if (!new_pset->active) {
pset_unlock(pset);
pset_unlock(new_pset);
new_pset = &default_pset;
goto Restart;
}
pset_reference(new_pset);
/*
* Now grab the task lock and move the task.
*/
task_lock(task);
pset_remove_task(pset, task);
pset_add_task(new_pset, task);
pset_unlock(pset);
pset_unlock(new_pset);
if (assign_threads == FALSE) {
/*
* We leave existing threads at their
* old assignments. Unfreeze task`s
* assignment.
*/
task->may_assign = TRUE;
if (task->assign_active) {
task->assign_active = FALSE;
thread_wakeup((event_t) &task->assign_active);
}
task_unlock(task);
pset_deallocate(pset);
return KERN_SUCCESS;
}
/*
* If current thread is in task, freeze its assignment.
*/
if (current_thread()->task == task) {
task_unlock(task);
thread_freeze(current_thread());
task_lock(task);
}
/*
* Iterate down the thread list reassigning all the threads.
* New threads pick up task's new processor set automatically.
* Do current thread last because new pset may be empty.
*/
list = &task->thread_list;
prev_thread = THREAD_NULL;
queue_iterate(list, thread, thread_t, thread_list) {
if (!(task->active)) {
ret = KERN_FAILURE;
break;
}
if (thread != current_thread()) {
thread_reference(thread);
task_unlock(task);
if (prev_thread != THREAD_NULL)
thread_deallocate(prev_thread); /* may block */
thread_assign(thread,new_pset); /* may block */
prev_thread = thread;
task_lock(task);
}
}
/*
* Done, wakeup anyone waiting for us.
*/
task->may_assign = TRUE;
if (task->assign_active) {
task->assign_active = FALSE;
thread_wakeup((event_t)&task->assign_active);
}
task_unlock(task);
if (prev_thread != THREAD_NULL)
thread_deallocate(prev_thread); /* may block */
/*
* Finish assignment of current thread.
*/
if (current_thread()->task == task)
thread_doassign(current_thread(), new_pset, TRUE);
pset_deallocate(pset);
return ret;
}
#else /* MACH_HOST */
/*
* task_assign:
*
* Change the assigned processor set for the task
*/
kern_return_t
task_assign(
task_t task,
processor_set_t new_pset,
boolean_t assign_threads)
{
return KERN_FAILURE;
}
#endif /* MACH_HOST */
/*
* task_assign_default:
*
* Version of task_assign to assign to default processor set.
*/
kern_return_t
task_assign_default(
task_t task,
boolean_t assign_threads)
{
return task_assign(task, &default_pset, assign_threads);
}
/*
* task_get_assignment
*
* Return name of processor set that task is assigned to.
*/
kern_return_t task_get_assignment(
task_t task,
processor_set_t *pset)
{
if (!task->active)
return KERN_FAILURE;
*pset = task->processor_set;
pset_reference(*pset);
return KERN_SUCCESS;
}
/*
* task_priority
*
* Set priority of task; used only for newly created threads.
* Optionally change priorities of threads.
*/
kern_return_t
task_priority(
task_t task,
int priority,
boolean_t change_threads)
{
kern_return_t ret = KERN_SUCCESS;
if (task == TASK_NULL || invalid_pri(priority))
return KERN_INVALID_ARGUMENT;
task_lock(task);
task->priority = priority;
if (change_threads) {
register thread_t thread;
register queue_head_t *list;
list = &task->thread_list;
queue_iterate(list, thread, thread_t, thread_list) {
if (thread_priority(thread, priority, FALSE)
!= KERN_SUCCESS)
ret = KERN_FAILURE;
}
}
task_unlock(task);
return ret;
}
/*
* task_collect_scan:
*
* Attempt to free resources owned by tasks.
*/
void task_collect_scan(void)
{
register task_t task, prev_task;
processor_set_t pset, prev_pset;
prev_task = TASK_NULL;
prev_pset = PROCESSOR_SET_NULL;
simple_lock(&all_psets_lock);
queue_iterate(&all_psets, pset, processor_set_t, all_psets) {
pset_lock(pset);
queue_iterate(&pset->tasks, task, task_t, pset_tasks) {
task_reference(task);
pset_reference(pset);
pset_unlock(pset);
simple_unlock(&all_psets_lock);
machine_task_collect (task);
pmap_collect(task->map->pmap);
if (prev_task != TASK_NULL)
task_deallocate(prev_task);
prev_task = task;
if (prev_pset != PROCESSOR_SET_NULL)
pset_deallocate(prev_pset);
prev_pset = pset;
simple_lock(&all_psets_lock);
pset_lock(pset);
}
pset_unlock(pset);
}
simple_unlock(&all_psets_lock);
if (prev_task != TASK_NULL)
task_deallocate(prev_task);
if (prev_pset != PROCESSOR_SET_NULL)
pset_deallocate(prev_pset);
}
boolean_t task_collect_allowed = TRUE;
unsigned task_collect_last_tick = 0;
unsigned task_collect_max_rate = 0; /* in ticks */
/*
* consider_task_collect:
*
* Called by the pageout daemon when the system needs more free pages.
*/
void consider_task_collect(void)
{
/*
* By default, don't attempt task collection more frequently
* than once a second.
*/
if (task_collect_max_rate == 0)
task_collect_max_rate = hz;
if (task_collect_allowed &&
(sched_tick > (task_collect_last_tick + task_collect_max_rate))) {
task_collect_last_tick = sched_tick;
task_collect_scan();
}
}
kern_return_t
task_ras_control(
task_t task,
vm_offset_t pc,
vm_offset_t endpc,
int flavor)
{
kern_return_t ret = KERN_FAILURE;
#if FAST_TAS
int i;
ret = KERN_SUCCESS;
task_lock(task);
switch (flavor) {
case TASK_RAS_CONTROL_PURGE_ALL: /* remove all RAS */
for (i = 0; i < TASK_FAST_TAS_NRAS; i++) {
task->fast_tas_base[i] = task->fast_tas_end[i] = 0;
}
break;
case TASK_RAS_CONTROL_PURGE_ONE: /* remove this RAS, collapse remaining */
for (i = 0; i < TASK_FAST_TAS_NRAS; i++) {
if ( (task->fast_tas_base[i] == pc)
&& (task->fast_tas_end[i] == endpc)) {
while (i < TASK_FAST_TAS_NRAS-1) {
task->fast_tas_base[i] = task->fast_tas_base[i+1];
task->fast_tas_end[i] = task->fast_tas_end[i+1];
i++;
}
task->fast_tas_base[TASK_FAST_TAS_NRAS-1] = 0;
task->fast_tas_end[TASK_FAST_TAS_NRAS-1] = 0;
break;
}
}
if (i == TASK_FAST_TAS_NRAS) {
ret = KERN_INVALID_ADDRESS;
}
break;
case TASK_RAS_CONTROL_PURGE_ALL_AND_INSTALL_ONE:
/* remove all RAS an install this RAS */
for (i = 0; i < TASK_FAST_TAS_NRAS; i++) {
task->fast_tas_base[i] = task->fast_tas_end[i] = 0;
}
/* FALL THROUGH */
case TASK_RAS_CONTROL_INSTALL_ONE: /* install this RAS */
for (i = 0; i < TASK_FAST_TAS_NRAS; i++) {
if ( (task->fast_tas_base[i] == pc)
&& (task->fast_tas_end[i] == endpc)) {
/* already installed */
break;
}
if ((task->fast_tas_base[i] == 0) && (task->fast_tas_end[i] == 0)){
task->fast_tas_base[i] = pc;
task->fast_tas_end[i] = endpc;
break;
}
}
if (i == TASK_FAST_TAS_NRAS) {
ret = KERN_RESOURCE_SHORTAGE;
}
break;
default: ret = KERN_INVALID_VALUE;
break;
}
task_unlock(task);
#endif
return ret;
}
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