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// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#include "vm/thread_interrupter.h"
#include "vm/flags.h"
#include "vm/lockers.h"
#include "vm/os.h"
#include "vm/simulator.h"
namespace dart {
// Notes:
//
// The ThreadInterrupter interrupts all threads actively running isolates once
// per interrupt period (default is 1 millisecond). While the thread is
// interrupted, the thread's interrupt callback is invoked. Callbacks cannot
// rely on being executed on the interrupted thread.
//
// There are two mechanisms used to interrupt a thread. The first, used on OSs
// with pthreads (Android, Linux, and Mac), is thread specific signal delivery.
// The second, used on Windows, is explicit suspend and resume thread system
// calls. Signal delivery forbids taking locks and allocating memory (which
// takes a lock). Explicit suspend and resume means that the interrupt callback
// will not be executing on the interrupted thread, making it meaningless to
// access TLS from within the thread interrupt callback. Combining these
// limitations, thread interrupt callbacks are forbidden from:
//
// * Accessing TLS.
// * Allocating memory.
// * Taking a lock.
//
// The ThreadInterrupter has a single monitor (monitor_). This monitor is used
// to synchronize startup, shutdown, and waking up from a deep sleep.
//
// A thread can only register and unregister itself. Each thread has a heap
// allocated ThreadState. A thread's ThreadState is lazily allocated the first
// time the thread is registered. A pointer to a thread's ThreadState is stored
// in the list of threads registered to receive interrupts (threads_) and in
// thread local storage. When a thread's ThreadState is being modified, the
// thread local storage pointer is temporarily set to NULL while the
// modification is occurring. After the ThreadState has been updated, the
// thread local storage pointer is set again. This has an important side
// effect: if the thread is interrupted by a signal handler during a ThreadState
// update the signal handler will immediately return.
DEFINE_FLAG(bool, trace_thread_interrupter, false,
"Trace thread interrupter");
bool ThreadInterrupter::initialized_ = false;
bool ThreadInterrupter::shutdown_ = false;
bool ThreadInterrupter::thread_running_ = false;
ThreadJoinId ThreadInterrupter::interrupter_thread_id_ =
OSThread::kInvalidThreadJoinId;
Monitor* ThreadInterrupter::monitor_ = NULL;
intptr_t ThreadInterrupter::interrupt_period_ = 1000;
intptr_t ThreadInterrupter::current_wait_time_ = Monitor::kNoTimeout;
void ThreadInterrupter::InitOnce() {
ASSERT(!initialized_);
monitor_ = new Monitor();
ASSERT(monitor_ != NULL);
initialized_ = true;
}
void ThreadInterrupter::Startup() {
ASSERT(initialized_);
if (FLAG_trace_thread_interrupter) {
OS::Print("ThreadInterrupter starting up.\n");
}
ASSERT(interrupter_thread_id_ == OSThread::kInvalidThreadJoinId);
{
MonitorLocker startup_ml(monitor_);
OSThread::Start(ThreadMain, 0);
while (!thread_running_) {
startup_ml.Wait();
}
}
ASSERT(interrupter_thread_id_ != OSThread::kInvalidThreadJoinId);
if (FLAG_trace_thread_interrupter) {
OS::Print("ThreadInterrupter running.\n");
}
}
void ThreadInterrupter::Shutdown() {
{
MonitorLocker shutdown_ml(monitor_);
if (shutdown_) {
// Already shutdown.
return;
}
shutdown_ = true;
// Notify.
monitor_->Notify();
ASSERT(initialized_);
if (FLAG_trace_thread_interrupter) {
OS::Print("ThreadInterrupter shutting down.\n");
}
}
// Join the thread.
ASSERT(interrupter_thread_id_ != OSThread::kInvalidThreadJoinId);
OSThread::Join(interrupter_thread_id_);
interrupter_thread_id_ = OSThread::kInvalidThreadJoinId;
if (FLAG_trace_thread_interrupter) {
OS::Print("ThreadInterrupter shut down.\n");
}
}
// Delay between interrupts.
void ThreadInterrupter::SetInterruptPeriod(intptr_t period) {
if (shutdown_) {
return;
}
ASSERT(initialized_);
ASSERT(period > 0);
interrupt_period_ = period;
}
void ThreadInterrupter::WakeUp() {
ASSERT(initialized_);
{
MonitorLocker ml(monitor_);
if (!InDeepSleep()) {
// No need to notify, regularly waking up.
return;
}
// Notify the interrupter to wake it from its deep sleep.
ml.Notify();
}
}
void ThreadInterruptNoOp(const InterruptedThreadState& state, void* data) {
// NoOp.
}
class ThreadInterrupterVisitIsolates : public IsolateVisitor {
public:
ThreadInterrupterVisitIsolates() {
profiled_thread_count_ = 0;
}
void VisitIsolate(Isolate* isolate) {
ASSERT(isolate != NULL);
profiled_thread_count_ += isolate->ProfileInterrupt();
}
intptr_t profiled_thread_count() const {
return profiled_thread_count_;
}
void set_profiled_thread_count(intptr_t profiled_thread_count) {
profiled_thread_count_ = profiled_thread_count;
}
private:
intptr_t profiled_thread_count_;
};
void ThreadInterrupter::ThreadMain(uword parameters) {
ASSERT(initialized_);
InstallSignalHandler();
if (FLAG_trace_thread_interrupter) {
OS::Print("ThreadInterrupter thread running.\n");
}
{
// Signal to main thread we are ready.
MonitorLocker startup_ml(monitor_);
interrupter_thread_id_ = OSThread::GetCurrentThreadJoinId();
thread_running_ = true;
startup_ml.Notify();
}
{
ThreadInterrupterVisitIsolates visitor;
current_wait_time_ = interrupt_period_;
MonitorLocker wait_ml(monitor_);
while (!shutdown_) {
intptr_t r = wait_ml.WaitMicros(current_wait_time_);
if ((r == Monitor::kNotified) && shutdown_) {
break;
}
if ((r == Monitor::kNotified) && InDeepSleep()) {
// Woken up from deep sleep.
ASSERT(visitor.profiled_thread_count() == 0);
// Return to regular interrupts.
current_wait_time_ = interrupt_period_;
}
// Reset count before visiting isolates.
visitor.set_profiled_thread_count(0);
Isolate::VisitIsolates(&visitor);
if (visitor.profiled_thread_count() == 0) {
// No isolates were profiled. In order to reduce unnecessary CPU
// load, we will wait until we are notified before attempting to
// interrupt again.
current_wait_time_ = Monitor::kNoTimeout;
continue;
}
ASSERT(current_wait_time_ != Monitor::kNoTimeout);
}
}
RemoveSignalHandler();
if (FLAG_trace_thread_interrupter) {
OS::Print("ThreadInterrupter thread exiting.\n");
}
{
// Signal to main thread we are exiting.
MonitorLocker shutdown_ml(monitor_);
thread_running_ = false;
shutdown_ml.Notify();
}
}
} // namespace dart