/************************************************************************************
Filename : OVR_ThreadsWinAPI.cpp
Platform : WinAPI
Content : Windows specific thread-related (safe) functionality
Created : September 19, 2012
Notes :
Copyright : Copyright 2014 Oculus VR, Inc. All Rights reserved.
Licensed under the Oculus VR Rift SDK License Version 3.1 (the "License");
you may not use the Oculus VR Rift SDK except in compliance with the License,
which is provided at the time of installation or download, or which
otherwise accompanies this software in either electronic or hard copy form.
You may obtain a copy of the License at
http://www.oculusvr.com/licenses/LICENSE-3.1
Unless required by applicable law or agreed to in writing, the Oculus VR SDK
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
************************************************************************************/
#include "OVR_Threads.h"
#include "OVR_Hash.h"
#include "OVR_Log.h"
#ifdef OVR_ENABLE_THREADS
// For _beginthreadex / _endtheadex
#include <process.h>
namespace OVR {
//-----------------------------------------------------------------------------------
// *** Internal Mutex implementation class
class MutexImpl : public NewOverrideBase
{
// System mutex or semaphore
HANDLE hMutexOrSemaphore;
bool Recursive;
volatile unsigned LockCount;
friend class WaitConditionImpl;
public:
// Constructor/destructor
MutexImpl(bool recursive = 1);
~MutexImpl();
// Locking functions
void DoLock();
bool TryLock();
void Unlock(Mutex* pmutex);
// Returns 1 if the mutes is currently locked
bool IsLockedByAnotherThread(Mutex* pmutex);
};
// *** Constructor/destructor
MutexImpl::MutexImpl(bool recursive)
{
Recursive = recursive;
LockCount = 0;
hMutexOrSemaphore = Recursive ? CreateMutex(NULL, 0, NULL) : CreateSemaphore(NULL, 1, 1, NULL);
}
MutexImpl::~MutexImpl()
{
CloseHandle(hMutexOrSemaphore);
}
// Lock and try lock
void MutexImpl::DoLock()
{
if (::WaitForSingleObject(hMutexOrSemaphore, INFINITE) != WAIT_OBJECT_0)
return;
LockCount++;
}
bool MutexImpl::TryLock()
{
DWORD ret;
if ((ret=::WaitForSingleObject(hMutexOrSemaphore, 0)) != WAIT_OBJECT_0)
return 0;
LockCount++;
return 1;
}
void MutexImpl::Unlock(Mutex* pmutex)
{
OVR_UNUSED(pmutex);
unsigned lockCount;
LockCount--;
lockCount = LockCount;
// Release mutex
if ((Recursive ? ReleaseMutex(hMutexOrSemaphore) :
ReleaseSemaphore(hMutexOrSemaphore, 1, NULL)) != 0)
{
// This used to call Wait handlers if lockCount == 0.
}
}
bool MutexImpl::IsLockedByAnotherThread(Mutex* pmutex)
{
// There could be multiple interpretations of IsLocked with respect to current thread
if (LockCount == 0)
return 0;
if (!TryLock())
return 1;
Unlock(pmutex);
return 0;
}
/*
bool MutexImpl::IsSignaled() const
{
// An mutex is signaled if it is not locked ANYWHERE
// Note that this is different from IsLockedByAnotherThread function,
// that takes current thread into account
return LockCount == 0;
}
*/
// *** Actual Mutex class implementation
Mutex::Mutex(bool recursive)
{
pImpl = new MutexImpl(recursive);
}
Mutex::~Mutex()
{
delete pImpl;
}
// Lock and try lock
void Mutex::DoLock()
{
pImpl->DoLock();
}
bool Mutex::TryLock()
{
return pImpl->TryLock();
}
void Mutex::Unlock()
{
pImpl->Unlock(this);
}
bool Mutex::IsLockedByAnotherThread()
{
return pImpl->IsLockedByAnotherThread(this);
}
//-----------------------------------------------------------------------------------
// ***** Event
bool Event::Wait(unsigned delay)
{
Mutex::Locker lock(&StateMutex);
// Do the correct amount of waiting
if (delay == OVR_WAIT_INFINITE)
{
while(!State)
StateWaitCondition.Wait(&StateMutex);
}
else if (delay)
{
if (!State)
StateWaitCondition.Wait(&StateMutex, delay);
}
bool state = State;
// Take care of temporary 'pulsing' of a state
if (Temporary)
{
Temporary = false;
State = false;
}
return state;
}
void Event::updateState(bool newState, bool newTemp, bool mustNotify)
{
Mutex::Locker lock(&StateMutex);
State = newState;
Temporary = newTemp;
if (mustNotify)
StateWaitCondition.NotifyAll();
}
//-----------------------------------------------------------------------------------
// ***** Win32 Wait Condition Implementation
// Internal implementation class
class WaitConditionImpl : public NewOverrideBase
{
// Event pool entries for extra events
struct EventPoolEntry : public NewOverrideBase
{
HANDLE hEvent;
EventPoolEntry *pNext;
EventPoolEntry *pPrev;
};
Lock WaitQueueLoc;
// Stores free events that can be used later
EventPoolEntry * pFreeEventList;
// A queue of waiting objects to be signaled
EventPoolEntry* pQueueHead;
EventPoolEntry* pQueueTail;
// Allocation functions for free events
EventPoolEntry* GetNewEvent();
void ReleaseEvent(EventPoolEntry* pevent);
// Queue operations
void QueuePush(EventPoolEntry* pentry);
EventPoolEntry* QueuePop();
void QueueFindAndRemove(EventPoolEntry* pentry);
public:
// Constructor/destructor
WaitConditionImpl();
~WaitConditionImpl();
// Release mutex and wait for condition. The mutex is re-acqured after the wait.
bool Wait(Mutex *pmutex, unsigned delay = OVR_WAIT_INFINITE);
// Notify a condition, releasing at one object waiting
void Notify();
// Notify a condition, releasing all objects waiting
void NotifyAll();
};
WaitConditionImpl::WaitConditionImpl()
{
pFreeEventList = 0;
pQueueHead =
pQueueTail = 0;
}
WaitConditionImpl::~WaitConditionImpl()
{
// Free all the resources
EventPoolEntry* p = pFreeEventList;
EventPoolEntry* pentry;
while(p)
{
// Move to next
pentry = p;
p = p->pNext;
// Delete old
::CloseHandle(pentry->hEvent);
delete pentry;
}
// Shouldn't we also consider the queue?
// To be safe
pFreeEventList = 0;
pQueueHead =
pQueueTail = 0;
}
// Allocation functions for free events
WaitConditionImpl::EventPoolEntry* WaitConditionImpl::GetNewEvent()
{
EventPoolEntry* pentry;
// If there are any free nodes, use them
if (pFreeEventList)
{
pentry = pFreeEventList;
pFreeEventList = pFreeEventList->pNext;
}
else
{
// Allocate a new node
pentry = new EventPoolEntry;
pentry->pNext = 0;
pentry->pPrev = 0;
// Non-signaled manual event
pentry->hEvent = ::CreateEvent(NULL, TRUE, 0, NULL);
}
return pentry;
}
void WaitConditionImpl::ReleaseEvent(EventPoolEntry* pevent)
{
// Mark event as non-signaled
::ResetEvent(pevent->hEvent);
// And add it to free pool
pevent->pNext = pFreeEventList;
pevent->pPrev = 0;
pFreeEventList = pevent;
}
// Queue operations
void WaitConditionImpl::QueuePush(EventPoolEntry* pentry)
{
// Items already exist? Just add to tail
if (pQueueTail)
{
pentry->pPrev = pQueueTail;
pQueueTail->pNext = pentry;
pentry->pNext = 0;
pQueueTail = pentry;
}
else
{
// No items in queue
pentry->pNext =
pentry->pPrev = 0;
pQueueHead =
pQueueTail = pentry;
}
}
WaitConditionImpl::EventPoolEntry* WaitConditionImpl::QueuePop()
{
EventPoolEntry* pentry = pQueueHead;
// No items, null pointer
if (pentry)
{
// More items after this one? just grab the first item
if (pQueueHead->pNext)
{
pQueueHead = pentry->pNext;
pQueueHead->pPrev = 0;
}
else
{
// Last item left
pQueueTail =
pQueueHead = 0;
}
}
return pentry;
}
void WaitConditionImpl::QueueFindAndRemove(EventPoolEntry* pentry)
{
// Do an exhaustive search looking for an entry
EventPoolEntry* p = pQueueHead;
while(p)
{
// Entry found? Remove.
if (p == pentry)
{
// Remove the node form the list
// Prev link
if (pentry->pPrev)
pentry->pPrev->pNext = pentry->pNext;
else
pQueueHead = pentry->pNext;
// Next link
if (pentry->pNext)
pentry->pNext->pPrev = pentry->pPrev;
else
pQueueTail = pentry->pPrev;
// Done
return;
}
// Move to next item
p = p->pNext;
}
}
bool WaitConditionImpl::Wait(Mutex *pmutex, unsigned delay)
{
bool result = 0;
unsigned i;
unsigned lockCount = pmutex->pImpl->LockCount;
EventPoolEntry* pentry;
// Mutex must have been locked
if (lockCount == 0)
return 0;
// Add an object to the wait queue
WaitQueueLoc.DoLock();
QueuePush(pentry = GetNewEvent());
WaitQueueLoc.Unlock();
// Finally, release a mutex or semaphore
if (pmutex->pImpl->Recursive)
{
// Release the recursive mutex N times
pmutex->pImpl->LockCount = 0;
for(i=0; i<lockCount; i++)
::ReleaseMutex(pmutex->pImpl->hMutexOrSemaphore);
}
else
{
pmutex->pImpl->LockCount = 0;
::ReleaseSemaphore(pmutex->pImpl->hMutexOrSemaphore, 1, NULL);
}
// Note that there is a gap here between mutex.Unlock() and Wait(). However,
// if notify() comes in at this point in the other thread it will set our
// corresponding event so wait will just fall through, as expected.
// Block and wait on the event
DWORD waitResult = ::WaitForSingleObject(pentry->hEvent,
(delay == OVR_WAIT_INFINITE) ? INFINITE : delay);
/*
repeat_wait:
DWORD waitResult =
::MsgWaitForMultipleObjects(1, &pentry->hEvent, FALSE,
(delay == OVR_WAIT_INFINITE) ? INFINITE : delay,
QS_ALLINPUT);
*/
WaitQueueLoc.DoLock();
switch(waitResult)
{
case WAIT_ABANDONED:
case WAIT_OBJECT_0:
result = 1;
// Wait was successful, therefore the event entry should already be removed
// So just add entry back to a free list
ReleaseEvent(pentry);
break;
/*
case WAIT_OBJECT_0 + 1:
// Messages in WINDOWS queue
{
MSG msg;
PeekMessage(&msg, NULL, 0U, 0U, PM_NOREMOVE);
WaitQueueLoc.Unlock();
goto repeat_wait;
}
break; */
default:
// Timeout, our entry should still be in a queue
QueueFindAndRemove(pentry);
ReleaseEvent(pentry);
}
WaitQueueLoc.Unlock();
// Re-aquire the mutex
for(i=0; i<lockCount; i++)
pmutex->DoLock();
// Return the result
return result;
}
// Notify a condition, releasing the least object in a queue
void WaitConditionImpl::Notify()
{
Lock::Locker lock(&WaitQueueLoc);
// Pop last entry & signal it
EventPoolEntry* pentry = QueuePop();
if (pentry)
::SetEvent(pentry->hEvent);
}
// Notify a condition, releasing all objects waiting
void WaitConditionImpl::NotifyAll()
{
Lock::Locker lock(&WaitQueueLoc);
// Pop and signal all events
// NOTE : There is no need to release the events, it's the waiters job to do so
EventPoolEntry* pentry = QueuePop();
while (pentry)
{
::SetEvent(pentry->hEvent);
pentry = QueuePop();
}
}
// *** Actual implementation of WaitCondition
WaitCondition::WaitCondition()
{
pImpl = new WaitConditionImpl;
}
WaitCondition::~WaitCondition()
{
delete pImpl;
}
// Wait without a mutex
bool WaitCondition::Wait(Mutex *pmutex, unsigned delay)
{
return pImpl->Wait(pmutex, delay);
}
// Notification
void WaitCondition::Notify()
{
pImpl->Notify();
}
void WaitCondition::NotifyAll()
{
pImpl->NotifyAll();
}
//-----------------------------------------------------------------------------------
// ***** Thread Class
// Per-thread variable
// MA: Don't use TLS for now - portability issues with DLLs, etc.
/*
#if !defined(OVR_CC_MSVC) || (OVR_CC_MSVC < 1300)
__declspec(thread) Thread* pCurrentThread = 0;
#else
#pragma data_seg(".tls$")
__declspec(thread) Thread* pCurrentThread = 0;
#pragma data_seg(".rwdata")
#endif
*/
// *** Thread constructors.
Thread::Thread(UPInt stackSize, int processor)
{
CreateParams params;
params.stackSize = stackSize;
params.processor = processor;
Init(params);
}
Thread::Thread(Thread::ThreadFn threadFunction, void* userHandle, UPInt stackSize,
int processor, Thread::ThreadState initialState)
{
CreateParams params(threadFunction, userHandle, stackSize, processor, initialState);
Init(params);
}
Thread::Thread(const CreateParams& params)
{
Init(params);
}
void Thread::Init(const CreateParams& params)
{
// Clear the variables
ThreadFlags = 0;
ThreadHandle = 0;
IdValue = 0;
ExitCode = 0;
SuspendCount = 0;
StackSize = params.stackSize;
Processor = params.processor;
Priority = params.priority;
// Clear Function pointers
ThreadFunction = params.threadFunction;
UserHandle = params.userHandle;
if (params.initialState != NotRunning)
Start(params.initialState);
}
Thread::~Thread()
{
// Thread should not running while object is being destroyed,
// this would indicate ref-counting issue.
//OVR_ASSERT(IsRunning() == 0);
// Clean up thread.
CleanupSystemThread();
ThreadHandle = 0;
}
// *** Overridable User functions.
// Default Run implementation
int Thread::Run()
{
// Call pointer to function, if available.
return (ThreadFunction) ? ThreadFunction(this, UserHandle) : 0;
}
void Thread::OnExit()
{
}
// Finishes the thread and releases internal reference to it.
void Thread::FinishAndRelease()
{
// Note: thread must be US.
ThreadFlags &= (UInt32)~(OVR_THREAD_STARTED);
ThreadFlags |= OVR_THREAD_FINISHED;
// Release our reference; this is equivalent to 'delete this'
// from the point of view of our thread.
Release();
}
// *** ThreadList - used to tack all created threads
class ThreadList : public NewOverrideBase
{
//------------------------------------------------------------------------
struct ThreadHashOp
{
UPInt operator()(const Thread* ptr)
{
return (((UPInt)ptr) >> 6) ^ (UPInt)ptr;
}
};
HashSet<Thread*, ThreadHashOp> ThreadSet;
Mutex ThreadMutex;
WaitCondition ThreadsEmpty;
// Track the root thread that created us.
ThreadId RootThreadId;
static ThreadList* volatile pRunningThreads;
void addThread(Thread *pthread)
{
Mutex::Locker lock(&ThreadMutex);
ThreadSet.Add(pthread);
}
void removeThread(Thread *pthread)
{
Mutex::Locker lock(&ThreadMutex);
ThreadSet.Remove(pthread);
if (ThreadSet.GetSize() == 0)
ThreadsEmpty.Notify();
}
void finishAllThreads()
{
// Only original root thread can call this.
OVR_ASSERT(GetCurrentThreadId() == RootThreadId);
Mutex::Locker lock(&ThreadMutex);
while (ThreadSet.GetSize() != 0)
ThreadsEmpty.Wait(&ThreadMutex);
}
public:
ThreadList()
{
RootThreadId = GetCurrentThreadId();
}
~ThreadList() { }
static void AddRunningThread(Thread *pthread)
{
// Non-atomic creation ok since only the root thread
if (!pRunningThreads)
{
pRunningThreads = new ThreadList;
OVR_ASSERT(pRunningThreads);
}
pRunningThreads->addThread(pthread);
}
// NOTE: 'pthread' might be a dead pointer when this is
// called so it should not be accessed; it is only used
// for removal.
static void RemoveRunningThread(Thread *pthread)
{
OVR_ASSERT(pRunningThreads);
pRunningThreads->removeThread(pthread);
}
static void FinishAllThreads()
{
// This is ok because only root thread can wait for other thread finish.
if (pRunningThreads)
{
pRunningThreads->finishAllThreads();
delete pRunningThreads;
pRunningThreads = 0;
}
}
};
// By default, we have no thread list.
ThreadList* volatile ThreadList::pRunningThreads = 0;
// FinishAllThreads - exposed publicly in Thread.
void Thread::FinishAllThreads()
{
ThreadList::FinishAllThreads();
}
// *** Run override
int Thread::PRun()
{
// Suspend us on start, if requested
if (ThreadFlags & OVR_THREAD_START_SUSPENDED)
{
Suspend();
ThreadFlags &= (UInt32)~OVR_THREAD_START_SUSPENDED;
}
// Call the virtual run function
ExitCode = Run();
return ExitCode;
}
/* MA: Don't use TLS for now.
// Static function to return a pointer to the current thread
void Thread::InitCurrentThread(Thread *pthread)
{
pCurrentThread = pthread;
}
// Static function to return a pointer to the current thread
Thread* Thread::GetThread()
{
return pCurrentThread;
}
*/
// *** User overridables
bool Thread::GetExitFlag() const
{
return (ThreadFlags & OVR_THREAD_EXIT) != 0;
}
void Thread::SetExitFlag(bool exitFlag)
{
// The below is atomic since ThreadFlags is AtomicInt.
if (exitFlag)
ThreadFlags |= OVR_THREAD_EXIT;
else
ThreadFlags &= (UInt32) ~OVR_THREAD_EXIT;
}
// Determines whether the thread was running and is now finished
bool Thread::IsFinished() const
{
return (ThreadFlags & OVR_THREAD_FINISHED) != 0;
}
// Determines whether the thread is suspended
bool Thread::IsSuspended() const
{
return SuspendCount > 0;
}
// Returns current thread state
Thread::ThreadState Thread::GetThreadState() const
{
if (IsSuspended())
return Suspended;
if (ThreadFlags & OVR_THREAD_STARTED)
return Running;
return NotRunning;
}
// ***** Thread management
/* static */
int Thread::GetOSPriority(ThreadPriority p)
{
switch(p)
{
case Thread::CriticalPriority: return THREAD_PRIORITY_TIME_CRITICAL;
case Thread::HighestPriority: return THREAD_PRIORITY_HIGHEST;
case Thread::AboveNormalPriority: return THREAD_PRIORITY_ABOVE_NORMAL;
case Thread::NormalPriority: return THREAD_PRIORITY_NORMAL;
case Thread::BelowNormalPriority: return THREAD_PRIORITY_BELOW_NORMAL;
case Thread::LowestPriority: return THREAD_PRIORITY_LOWEST;
case Thread::IdlePriority: return THREAD_PRIORITY_IDLE;
}
return THREAD_PRIORITY_NORMAL;
}
// The actual first function called on thread start
unsigned WINAPI Thread_Win32StartFn(void * phandle)
{
Thread * pthread = (Thread*)phandle;
if (pthread->Processor != -1)
{
DWORD_PTR ret = SetThreadAffinityMask(GetCurrentThread(), (DWORD)pthread->Processor);
if (ret == 0)
OVR_DEBUG_LOG(("Could not set hardware processor for the thread"));
}
BOOL ret = ::SetThreadPriority(GetCurrentThread(), Thread::GetOSPriority(pthread->Priority));
if (ret == 0)
OVR_DEBUG_LOG(("Could not set thread priority"));
OVR_UNUSED(ret);
// Ensure that ThreadId is assigned once thread is running, in case
// beginthread hasn't filled it in yet.
pthread->IdValue = (ThreadId)::GetCurrentThreadId();
DWORD result = pthread->PRun();
// Signal the thread as done and release it atomically.
pthread->FinishAndRelease();
// At this point Thread object might be dead; however we can still pass
// it to RemoveRunningThread since it is only used as a key there.
ThreadList::RemoveRunningThread(pthread);
return (unsigned) result;
}
bool Thread::Start(ThreadState initialState)
{
if (initialState == NotRunning)
return 0;
if (GetThreadState() != NotRunning)
{
OVR_DEBUG_LOG(("Thread::Start failed - thread %p already running", this));
return 0;
}
// Free old thread handle before creating the new one
CleanupSystemThread();
// AddRef to us until the thread is finished.
AddRef();
ThreadList::AddRunningThread(this);
ExitCode = 0;
SuspendCount = 0;
ThreadFlags = (initialState == Running) ? 0 : OVR_THREAD_START_SUSPENDED;
ThreadHandle = (HANDLE) _beginthreadex(0, (unsigned)StackSize,
Thread_Win32StartFn, this, 0, (unsigned*)&IdValue);
// Failed? Fail the function
if (ThreadHandle == 0)
{
ThreadFlags = 0;
Release();
ThreadList::RemoveRunningThread(this);
return 0;
}
return 1;
}
// Suspend the thread until resumed
bool Thread::Suspend()
{
// Can't suspend a thread that wasn't started
if (!(ThreadFlags & OVR_THREAD_STARTED))
return 0;
if (::SuspendThread(ThreadHandle) != 0xFFFFFFFF)
{
SuspendCount++;
return 1;
}
return 0;
}
// Resumes currently suspended thread
bool Thread::Resume()
{
// Can't suspend a thread that wasn't started
if (!(ThreadFlags & OVR_THREAD_STARTED))
return 0;
// Decrement count, and resume thread if it is 0
SInt32 oldCount = SuspendCount.ExchangeAdd_Acquire(-1);
if (oldCount >= 1)
{
if (oldCount == 1)
{
if (::ResumeThread(ThreadHandle) != 0xFFFFFFFF)
return 1;
}
else
{
return 1;
}
}
return 0;
}
// Quits with an exit code
void Thread::Exit(int exitCode)
{
// Can only exist the current thread.
// MA: Don't use TLS for now.
//if (GetThread() != this)
// return;
// Call the virtual OnExit function.
OnExit();
// Signal this thread object as done and release it's references.
FinishAndRelease();
ThreadList::RemoveRunningThread(this);
// Call the exit function.
_endthreadex((unsigned)exitCode);
}
void Thread::CleanupSystemThread()
{
if (ThreadHandle != 0)
{
::CloseHandle(ThreadHandle);
ThreadHandle = 0;
}
}
// *** Sleep functions
// static
bool Thread::Sleep(unsigned secs)
{
::Sleep(secs*1000);
return 1;
}
// static
bool Thread::MSleep(unsigned msecs)
{
::Sleep(msecs);
return 1;
}
void Thread::SetThreadName( const char* name )
{
#if !defined(OVR_BUILD_SHIPPING) || defined(OVR_BUILD_PROFILING)
// Looks ugly, but it is the recommended way to name a thread.
typedef struct tagTHREADNAME_INFO {
DWORD dwType; // Must be 0x1000
LPCSTR szName; // Pointer to name (in user address space)
DWORD dwThreadID; // Thread ID (-1 for caller thread)
DWORD dwFlags; // Reserved for future use; must be zero
} THREADNAME_INFO;
THREADNAME_INFO info;
info.dwType = 0x1000;
info.szName = name;
info.dwThreadID = reinterpret_cast<DWORD>(GetThreadId());
info.dwFlags = 0;
__try
{
#ifdef _WIN64
RaiseException( 0x406D1388, 0, sizeof(info)/sizeof(DWORD), (const ULONG_PTR *)&info );
#else
RaiseException( 0x406D1388, 0, sizeof(info)/sizeof(DWORD), (DWORD *)&info );
#endif
}
__except( GetExceptionCode()==0x406D1388 ? EXCEPTION_CONTINUE_EXECUTION : EXCEPTION_EXECUTE_HANDLER )
{
}
#endif // OVR_BUILD_SHIPPING
}
// static
int Thread::GetCPUCount()
{
SYSTEM_INFO sysInfo;
GetSystemInfo(&sysInfo);
return (int) sysInfo.dwNumberOfProcessors;
}
// Returns the unique Id of a thread it is called on, intended for
// comparison purposes.
ThreadId GetCurrentThreadId()
{
return (ThreadId)::GetCurrentThreadId();
}
} // OVR
#endif