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/* -----------------------------------------------------------------------------
*
* (c) The GHC Team 2001-2005
*
* The task manager subsystem. Tasks execute STG code, with this
* module providing the API which the Scheduler uses to control their
* creation and destruction.
*
* -------------------------------------------------------------------------*/
#include "PosixSource.h"
#include "Rts.h"
#include "RtsUtils.h"
#include "Task.h"
#include "Capability.h"
#include "Stats.h"
#include "Schedule.h"
#include "Hash.h"
#include "Trace.h"
#if HAVE_SIGNAL_H
#include <signal.h>
#endif
// Task lists and global counters.
// Locks required: all_tasks_mutex.
Task *all_tasks = NULL;
nat taskCount; // current number of bound tasks + total number of worker tasks.
nat workerCount;
nat currentWorkerCount;
nat peakWorkerCount;
static int tasksInitialized = 0;
static void freeTask (Task *task);
static Task * allocTask (void);
static Task * newTask (rtsBool);
#if defined(THREADED_RTS)
Mutex all_tasks_mutex;
#endif
/* -----------------------------------------------------------------------------
* Remembering the current thread's Task
* -------------------------------------------------------------------------- */
// A thread-local-storage key that we can use to get access to the
// current thread's Task structure.
#if defined(THREADED_RTS)
# if defined(MYTASK_USE_TLV)
__thread Task *my_task;
# else
ThreadLocalKey currentTaskKey;
# endif
#else
Task *my_task;
#endif
/* -----------------------------------------------------------------------------
* Rest of the Task API
* -------------------------------------------------------------------------- */
void
initTaskManager (void)
{
if (!tasksInitialized) {
taskCount = 0;
workerCount = 0;
currentWorkerCount = 0;
peakWorkerCount = 0;
tasksInitialized = 1;
#if defined(THREADED_RTS)
#if !defined(MYTASK_USE_TLV)
newThreadLocalKey(¤tTaskKey);
#endif
initMutex(&all_tasks_mutex);
#endif
}
}
nat
freeTaskManager (void)
{
Task *task, *next;
nat tasksRunning = 0;
ACQUIRE_LOCK(&all_tasks_mutex);
for (task = all_tasks; task != NULL; task = next) {
next = task->all_next;
if (task->stopped) {
freeTask(task);
} else {
tasksRunning++;
}
}
debugTrace(DEBUG_sched, "freeing task manager, %d tasks still running",
tasksRunning);
all_tasks = NULL;
RELEASE_LOCK(&all_tasks_mutex);
#if defined(THREADED_RTS)
closeMutex(&all_tasks_mutex);
#if !defined(MYTASK_USE_TLV)
freeThreadLocalKey(¤tTaskKey);
#endif
#endif
tasksInitialized = 0;
return tasksRunning;
}
static Task *
allocTask (void)
{
Task *task;
task = myTask();
if (task != NULL) {
return task;
} else {
task = newTask(rtsFalse);
#if defined(THREADED_RTS)
task->id = osThreadId();
#endif
setMyTask(task);
return task;
}
}
void freeMyTask (void)
{
Task *task;
task = myTask();
if (task == NULL) return;
if (!task->stopped) {
errorBelch(
"freeMyTask() called, but the Task is not stopped; ignoring");
return;
}
if (task->worker) {
errorBelch("freeMyTask() called on a worker; ignoring");
return;
}
ACQUIRE_LOCK(&all_tasks_mutex);
if (task->all_prev) {
task->all_prev->all_next = task->all_next;
} else {
all_tasks = task->all_next;
}
if (task->all_next) {
task->all_next->all_prev = task->all_prev;
}
taskCount--;
RELEASE_LOCK(&all_tasks_mutex);
freeTask(task);
setMyTask(NULL);
}
static void
freeTask (Task *task)
{
InCall *incall, *next;
// We only free resources if the Task is not in use. A
// Task may still be in use if we have a Haskell thread in
// a foreign call while we are attempting to shut down the
// RTS (see conc059).
#if defined(THREADED_RTS)
closeCondition(&task->cond);
closeMutex(&task->lock);
#endif
for (incall = task->incall; incall != NULL; incall = next) {
next = incall->prev_stack;
stgFree(incall);
}
for (incall = task->spare_incalls; incall != NULL; incall = next) {
next = incall->next;
stgFree(incall);
}
stgFree(task);
}
static Task*
newTask (rtsBool worker)
{
Task *task;
#define ROUND_TO_CACHE_LINE(x) ((((x)+63) / 64) * 64)
task = stgMallocBytes(ROUND_TO_CACHE_LINE(sizeof(Task)), "newTask");
task->cap = NULL;
task->worker = worker;
task->stopped = rtsFalse;
task->running_finalizers = rtsFalse;
task->n_spare_incalls = 0;
task->spare_incalls = NULL;
task->incall = NULL;
task->preferred_capability = -1;
#if defined(THREADED_RTS)
initCondition(&task->cond);
initMutex(&task->lock);
task->wakeup = rtsFalse;
#endif
task->next = NULL;
ACQUIRE_LOCK(&all_tasks_mutex);
task->all_prev = NULL;
task->all_next = all_tasks;
if (all_tasks != NULL) {
all_tasks->all_prev = task;
}
all_tasks = task;
taskCount++;
if (worker) {
workerCount++;
currentWorkerCount++;
if (currentWorkerCount > peakWorkerCount) {
peakWorkerCount = currentWorkerCount;
}
}
RELEASE_LOCK(&all_tasks_mutex);
return task;
}
// avoid the spare_incalls list growing unboundedly
#define MAX_SPARE_INCALLS 8
static void
newInCall (Task *task)
{
InCall *incall;
if (task->spare_incalls != NULL) {
incall = task->spare_incalls;
task->spare_incalls = incall->next;
task->n_spare_incalls--;
} else {
incall = stgMallocBytes((sizeof(InCall)), "newInCall");
}
incall->tso = NULL;
incall->task = task;
incall->suspended_tso = NULL;
incall->suspended_cap = NULL;
incall->rstat = NoStatus;
incall->ret = NULL;
incall->next = NULL;
incall->prev = NULL;
incall->prev_stack = task->incall;
task->incall = incall;
}
static void
endInCall (Task *task)
{
InCall *incall;
incall = task->incall;
incall->tso = NULL;
task->incall = task->incall->prev_stack;
if (task->n_spare_incalls >= MAX_SPARE_INCALLS) {
stgFree(incall);
} else {
incall->next = task->spare_incalls;
task->spare_incalls = incall;
task->n_spare_incalls++;
}
}
Task *
newBoundTask (void)
{
Task *task;
if (!tasksInitialized) {
errorBelch("newBoundTask: RTS is not initialised; call hs_init() first");
stg_exit(EXIT_FAILURE);
}
task = allocTask();
task->stopped = rtsFalse;
newInCall(task);
debugTrace(DEBUG_sched, "new task (taskCount: %d)", taskCount);
return task;
}
void
boundTaskExiting (Task *task)
{
#if defined(THREADED_RTS)
ASSERT(osThreadId() == task->id);
#endif
ASSERT(myTask() == task);
endInCall(task);
// Set task->stopped, but only if this is the last call (#4850).
// Remember that we might have a worker Task that makes a foreign
// call and then a callback, so it can transform into a bound
// Task for the duration of the callback.
if (task->incall == NULL) {
task->stopped = rtsTrue;
}
debugTrace(DEBUG_sched, "task exiting");
}
#ifdef THREADED_RTS
#define TASK_ID(t) (t)->id
#else
#define TASK_ID(t) (t)
#endif
void
discardTasksExcept (Task *keep)
{
Task *task, *next;
// Wipe the task list, except the current Task.
ACQUIRE_LOCK(&all_tasks_mutex);
for (task = all_tasks; task != NULL; task=next) {
next = task->all_next;
if (task != keep) {
debugTrace(DEBUG_sched, "discarding task %" FMT_SizeT "", (size_t)TASK_ID(task));
#if defined(THREADED_RTS)
// It is possible that some of these tasks are currently blocked
// (in the parent process) either on their condition variable
// `cond` or on their mutex `lock`. If they are we may deadlock
// when `freeTask` attempts to call `closeCondition` or
// `closeMutex` (the behaviour of these functions is documented to
// be undefined in the case that there are threads blocked on
// them). To avoid this, we re-initialize both the condition
// variable and the mutex before calling `freeTask` (we do
// precisely the same for all global locks in `forkProcess`).
initCondition(&task->cond);
initMutex(&task->lock);
#endif
// Note that we do not traceTaskDelete here because
// we are not really deleting a task.
// The OS threads for all these tasks do not exist in
// this process (since we're currently
// in the child of a forkProcess).
freeTask(task);
}
}
all_tasks = keep;
keep->all_next = NULL;
keep->all_prev = NULL;
RELEASE_LOCK(&all_tasks_mutex);
}
#if defined(THREADED_RTS)
void
workerTaskStop (Task *task)
{
DEBUG_ONLY( OSThreadId id );
DEBUG_ONLY( id = osThreadId() );
ASSERT(task->id == id);
ASSERT(myTask() == task);
ACQUIRE_LOCK(&all_tasks_mutex);
if (task->all_prev) {
task->all_prev->all_next = task->all_next;
} else {
all_tasks = task->all_next;
}
if (task->all_next) {
task->all_next->all_prev = task->all_prev;
}
currentWorkerCount--;
RELEASE_LOCK(&all_tasks_mutex);
traceTaskDelete(task);
freeTask(task);
}
#endif
#if defined(THREADED_RTS)
static void OSThreadProcAttr
workerStart(Task *task)
{
Capability *cap;
// See startWorkerTask().
ACQUIRE_LOCK(&task->lock);
cap = task->cap;
RELEASE_LOCK(&task->lock);
if (RtsFlags.ParFlags.setAffinity) {
setThreadAffinity(cap->no, n_capabilities);
}
// set the thread-local pointer to the Task:
setMyTask(task);
newInCall(task);
// Everything set up; emit the event before the worker starts working.
traceTaskCreate(task, cap);
scheduleWorker(cap,task);
}
void
startWorkerTask (Capability *cap)
{
int r;
OSThreadId tid;
Task *task;
// A worker always gets a fresh Task structure.
task = newTask(rtsTrue);
// The lock here is to synchronise with taskStart(), to make sure
// that we have finished setting up the Task structure before the
// worker thread reads it.
ACQUIRE_LOCK(&task->lock);
// We don't emit a task creation event here, but in workerStart,
// where the kernel thread id is known.
task->cap = cap;
// Give the capability directly to the worker; we can't let anyone
// else get in, because the new worker Task has nowhere to go to
// sleep so that it could be woken up again.
ASSERT_LOCK_HELD(&cap->lock);
cap->running_task = task;
r = createOSThread(&tid, "ghc_worker", (OSThreadProc*)workerStart, task);
if (r != 0) {
sysErrorBelch("failed to create OS thread");
stg_exit(EXIT_FAILURE);
}
debugTrace(DEBUG_sched, "new worker task (taskCount: %d)", taskCount);
task->id = tid;
// ok, finished with the Task struct.
RELEASE_LOCK(&task->lock);
}
void
interruptWorkerTask (Task *task)
{
ASSERT(osThreadId() != task->id); // seppuku not allowed
ASSERT(task->incall->suspended_tso); // use this only for FFI calls
interruptOSThread(task->id);
debugTrace(DEBUG_sched, "interrupted worker task %#" FMT_HexWord64,
serialisableTaskId(task));
}
#endif /* THREADED_RTS */
void
setInCallCapability (int preferred_capability)
{
Task *task = allocTask();
task->preferred_capability = preferred_capability;
}
#ifdef DEBUG
void printAllTasks(void);
void
printAllTasks(void)
{
Task *task;
for (task = all_tasks; task != NULL; task = task->all_next) {
debugBelch("task %#" FMT_HexWord64 " is %s, ", serialisableTaskId(task),
task->stopped ? "stopped" : "alive");
if (!task->stopped) {
if (task->cap) {
debugBelch("on capability %d, ", task->cap->no);
}
if (task->incall->tso) {
debugBelch("bound to thread %lu",
(unsigned long)task->incall->tso->id);
} else {
debugBelch("worker");
}
}
debugBelch("\n");
}
}
#endif
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