1 /* -----------------------------------------------------------------------------
3 * (c) The GHC Team 2001-2005
5 * The task manager subsystem. Tasks execute STG code, with this
6 * module providing the API which the Scheduler uses to control their
7 * creation and destruction.
9 * -------------------------------------------------------------------------*/
13 #include "OSThreads.h"
15 #include "Capability.h"
27 // Task lists and global counters.
28 // Locks required: sched_mutex.
29 Task *all_tasks = NULL;
30 static Task *task_free_list = NULL; // singly-linked
32 static nat tasksRunning;
33 static nat workerCount;
35 /* -----------------------------------------------------------------------------
36 * Remembering the current thread's Task
37 * -------------------------------------------------------------------------- */
39 // A thread-local-storage key that we can use to get access to the
40 // current thread's Task structure.
41 #if defined(THREADED_RTS)
42 ThreadLocalKey currentTaskKey;
47 /* -----------------------------------------------------------------------------
48 * Rest of the Task API
49 * -------------------------------------------------------------------------- */
52 initTaskManager (void)
54 static int initialized = 0;
61 #if defined(THREADED_RTS)
62 newThreadLocalKey(¤tTaskKey);
69 stopTaskManager (void)
73 debugTrace(DEBUG_sched,
74 "stopping task manager, %d tasks still running",
77 ACQUIRE_LOCK(&sched_mutex);
78 for (task = task_free_list; task != NULL; task = task->next) {
79 #if defined(THREADED_RTS)
80 closeCondition(&task->cond);
81 closeMutex(&task->lock);
84 RELEASE_LOCK(&sched_mutex);
89 freeTaskManager (void)
93 debugTrace(DEBUG_sched, "freeing task manager");
95 ACQUIRE_LOCK(&sched_mutex);
96 for (task = task_free_list; task != NULL; task = next) {
100 task_free_list = NULL;
101 RELEASE_LOCK(&sched_mutex);
108 #if defined(THREADED_RTS)
109 Ticks currentElapsedTime, currentUserTime;
113 task = stgMallocBytes(sizeof(Task), "newTask");
116 task->stopped = rtsFalse;
117 task->suspended_tso = NULL;
119 task->stat = NoStatus;
122 #if defined(THREADED_RTS)
123 initCondition(&task->cond);
124 initMutex(&task->lock);
125 task->wakeup = rtsFalse;
128 #if defined(THREADED_RTS)
129 currentUserTime = getThreadCPUTime();
130 currentElapsedTime = getProcessElapsedTime();
135 task->muttimestart = currentUserTime;
136 task->elapsedtimestart = currentElapsedTime;
141 task->return_link = NULL;
143 task->all_link = all_tasks;
157 ASSERT_LOCK_HELD(&sched_mutex);
158 if (task_free_list == NULL) {
161 task = task_free_list;
162 task_free_list = task->next;
165 task->stopped = rtsFalse;
167 #if defined(THREADED_RTS)
168 task->id = osThreadId();
170 ASSERT(task->cap == NULL);
176 debugTrace(DEBUG_sched, "new task (taskCount: %d)", taskCount);
181 boundTaskExiting (Task *task)
183 task->stopped = rtsTrue;
186 #if defined(THREADED_RTS)
187 ASSERT(osThreadId() == task->id);
189 ASSERT(myTask() == task);
190 setMyTask(task->prev_stack);
194 // sadly, we need a lock around the free task list. Todo: eliminate.
195 ACQUIRE_LOCK(&sched_mutex);
196 task->next = task_free_list;
197 task_free_list = task;
198 RELEASE_LOCK(&sched_mutex);
200 debugTrace(DEBUG_sched, "task exiting");
204 #define TASK_ID(t) (t)->id
206 #define TASK_ID(t) (t)
210 discardTask (Task *task)
212 ASSERT_LOCK_HELD(&sched_mutex);
213 if (!task->stopped) {
214 debugTrace(DEBUG_sched, "discarding task %ld", (long)TASK_ID(task));
217 task->stopped = rtsTrue;
219 task->next = task_free_list;
220 task_free_list = task;
225 taskTimeStamp (Task *task USED_IF_THREADS)
227 #if defined(THREADED_RTS)
228 Ticks currentElapsedTime, currentUserTime, elapsedGCTime;
230 currentUserTime = getThreadCPUTime();
231 currentElapsedTime = getProcessElapsedTime();
233 // XXX this is wrong; we want elapsed GC time since the
235 elapsedGCTime = stat_getElapsedGCTime();
238 currentUserTime - task->muttimestart - task->gc_time;
240 currentElapsedTime - task->elapsedtimestart - elapsedGCTime;
242 if (task->mut_time < 0) { task->mut_time = 0; }
243 if (task->mut_etime < 0) { task->mut_etime = 0; }
248 workerTaskStop (Task *task)
250 #if defined(THREADED_RTS)
253 ASSERT(task->id == id);
254 ASSERT(myTask() == task);
258 task->stopped = rtsTrue;
263 resetTaskManagerAfterFork (void)
269 #if defined(THREADED_RTS)
272 startWorkerTask (Capability *cap,
273 void OSThreadProcAttr (*taskStart)(Task *task))
281 // A worker always gets a fresh Task structure.
286 // The lock here is to synchronise with taskStart(), to make sure
287 // that we have finished setting up the Task structure before the
288 // worker thread reads it.
289 ACQUIRE_LOCK(&task->lock);
293 // Give the capability directly to the worker; we can't let anyone
294 // else get in, because the new worker Task has nowhere to go to
295 // sleep so that it could be woken up again.
296 ASSERT_LOCK_HELD(&cap->lock);
297 cap->running_task = task;
299 r = createOSThread(&tid, (OSThreadProc *)taskStart, task);
301 sysErrorBelch("failed to create OS thread");
302 stg_exit(EXIT_FAILURE);
305 debugTrace(DEBUG_sched, "new worker task (taskCount: %d)", taskCount);
309 // ok, finished with the Task struct.
310 RELEASE_LOCK(&task->lock);
313 #endif /* THREADED_RTS */
317 static void *taskId(Task *task)
320 return (void *)task->id;
326 void printAllTasks(void);
332 for (task = all_tasks; task != NULL; task = task->all_link) {
333 debugBelch("task %p is %s, ", taskId(task), task->stopped ? "stopped" : "alive");
334 if (!task->stopped) {
336 debugBelch("on capability %d, ", task->cap->no);
339 debugBelch("bound to thread %lu", (unsigned long)task->tso->id);
341 debugBelch("worker");