356 lines
11 KiB
C++
356 lines
11 KiB
C++
//------------------------------------------------------------------------------
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// File: RefClock.cpp
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//
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// Desc: DirectShow base classes - implements the IReferenceClock interface.
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//
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// Copyright (c) 1992-2001 Microsoft Corporation. All rights reserved.
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//------------------------------------------------------------------------------
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#include <streams.h>
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#include <limits.h>
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//@@BEGIN_MSINTERNAL
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#ifdef DXMPERF
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#include "dxmperf.h"
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#endif // DXMPERF
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//@@END_MSINTERNAL
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// 'this' used in constructor list
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#pragma warning(disable:4355)
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STDMETHODIMP CBaseReferenceClock::NonDelegatingQueryInterface(
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REFIID riid,
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void ** ppv)
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{
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HRESULT hr;
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if (riid == IID_IReferenceClock)
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{
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hr = GetInterface((IReferenceClock *) this, ppv);
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}
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else
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{
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hr = CUnknown::NonDelegatingQueryInterface(riid, ppv);
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}
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return hr;
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}
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CBaseReferenceClock::~CBaseReferenceClock()
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{
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//@@BEGIN_MSINTERNAL
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#ifdef DXMPERF
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PERFLOG_DTOR( L"CBaseReferenceClock", (IReferenceClock *) this );
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#endif // DXMPERF
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//@@END_MSINTERNAL
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if (m_TimerResolution) timeEndPeriod(m_TimerResolution);
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m_pSchedule->DumpLinkedList();
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if (m_hThread)
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{
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m_bAbort = TRUE;
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TriggerThread();
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WaitForSingleObject( m_hThread, INFINITE );
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EXECUTE_ASSERT( CloseHandle(m_hThread) );
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m_hThread = 0;
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EXECUTE_ASSERT( CloseHandle(m_pSchedule->GetEvent()) );
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delete m_pSchedule;
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}
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}
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// A derived class may supply a hThreadEvent if it has its own thread that will take care
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// of calling the schedulers Advise method. (Refere to CBaseReferenceClock::AdviseThread()
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// to see what such a thread has to do.)
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CBaseReferenceClock::CBaseReferenceClock( TCHAR *pName, LPUNKNOWN pUnk, HRESULT *phr, CAMSchedule * pShed )
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: CUnknown( pName, pUnk )
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, m_rtLastGotTime(0)
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, m_TimerResolution(0)
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, m_bAbort( FALSE )
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, m_pSchedule( pShed ? pShed : new CAMSchedule(CreateEvent(NULL, FALSE, FALSE, NULL)) )
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, m_hThread(0)
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{
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//@@BEGIN_MSINTERNAL
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#ifdef DXMPERF
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PERFLOG_CTOR( pName ? pName : L"CBaseReferenceClock", (IReferenceClock *) this );
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#endif // DXMPERF
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//@@END_MSINTERNAL
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ASSERT(m_pSchedule);
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if (!m_pSchedule)
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{
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*phr = E_OUTOFMEMORY;
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}
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else
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{
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// Set up the highest resolution timer we can manage
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TIMECAPS tc;
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m_TimerResolution = (TIMERR_NOERROR == timeGetDevCaps(&tc, sizeof(tc)))
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? tc.wPeriodMin
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: 1;
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timeBeginPeriod(m_TimerResolution);
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/* Initialise our system times - the derived clock should set the right values */
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m_dwPrevSystemTime = timeGetTime();
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m_rtPrivateTime = (UNITS / MILLISECONDS) * m_dwPrevSystemTime;
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#ifdef PERF
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m_idGetSystemTime = MSR_REGISTER(TEXT("CBaseReferenceClock::GetTime"));
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#endif
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if ( !pShed )
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{
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DWORD ThreadID;
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m_hThread = ::CreateThread(NULL, // Security attributes
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(DWORD) 0, // Initial stack size
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AdviseThreadFunction, // Thread start address
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(LPVOID) this, // Thread parameter
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(DWORD) 0, // Creation flags
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&ThreadID); // Thread identifier
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if (m_hThread)
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{
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SetThreadPriority( m_hThread, THREAD_PRIORITY_TIME_CRITICAL );
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}
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else
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{
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*phr = E_FAIL;
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EXECUTE_ASSERT( CloseHandle(m_pSchedule->GetEvent()) );
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delete m_pSchedule;
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}
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}
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}
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}
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STDMETHODIMP CBaseReferenceClock::GetTime(REFERENCE_TIME *pTime)
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{
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HRESULT hr;
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if (pTime)
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{
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REFERENCE_TIME rtNow;
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Lock();
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rtNow = GetPrivateTime();
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if (rtNow > m_rtLastGotTime)
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{
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m_rtLastGotTime = rtNow;
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hr = S_OK;
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}
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else
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{
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hr = S_FALSE;
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}
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*pTime = m_rtLastGotTime;
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Unlock();
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MSR_INTEGER(m_idGetSystemTime, LONG((*pTime) / (UNITS/MILLISECONDS)) );
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//@@BEGIN_MSINTERNAL
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#ifdef DXMPERF
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PERFLOG_GETTIME( (IReferenceClock *) this, *pTime );
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#endif // DXMPERF
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//@@END_MSINTERNAL
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}
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else hr = E_POINTER;
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return hr;
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}
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/* Ask for an async notification that a time has elapsed */
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STDMETHODIMP CBaseReferenceClock::AdviseTime(
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REFERENCE_TIME baseTime, // base reference time
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REFERENCE_TIME streamTime, // stream offset time
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HEVENT hEvent, // advise via this event
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DWORD_PTR *pdwAdviseCookie) // where your cookie goes
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{
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CheckPointer(pdwAdviseCookie, E_POINTER);
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*pdwAdviseCookie = 0;
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// Check that the event is not already set
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ASSERT(WAIT_TIMEOUT == WaitForSingleObject(HANDLE(hEvent),0));
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HRESULT hr;
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const REFERENCE_TIME lRefTime = baseTime + streamTime;
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if ( lRefTime <= 0 || lRefTime == MAX_TIME )
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{
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hr = E_INVALIDARG;
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}
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else
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{
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*pdwAdviseCookie = m_pSchedule->AddAdvisePacket( lRefTime, 0, HANDLE(hEvent), FALSE );
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hr = *pdwAdviseCookie ? NOERROR : E_OUTOFMEMORY;
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}
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return hr;
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}
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/* Ask for an asynchronous periodic notification that a time has elapsed */
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STDMETHODIMP CBaseReferenceClock::AdvisePeriodic(
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REFERENCE_TIME StartTime, // starting at this time
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REFERENCE_TIME PeriodTime, // time between notifications
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HSEMAPHORE hSemaphore, // advise via a semaphore
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DWORD_PTR *pdwAdviseCookie) // where your cookie goes
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{
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CheckPointer(pdwAdviseCookie, E_POINTER);
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*pdwAdviseCookie = 0;
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HRESULT hr;
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if (StartTime > 0 && PeriodTime > 0 && StartTime != MAX_TIME )
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{
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*pdwAdviseCookie = m_pSchedule->AddAdvisePacket( StartTime, PeriodTime, HANDLE(hSemaphore), TRUE );
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hr = *pdwAdviseCookie ? NOERROR : E_OUTOFMEMORY;
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}
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else hr = E_INVALIDARG;
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return hr;
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}
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STDMETHODIMP CBaseReferenceClock::Unadvise(DWORD_PTR dwAdviseCookie)
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{
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return m_pSchedule->Unadvise(dwAdviseCookie);
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}
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REFERENCE_TIME CBaseReferenceClock::GetPrivateTime()
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{
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CAutoLock cObjectLock(this);
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/* If the clock has wrapped then the current time will be less than
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* the last time we were notified so add on the extra milliseconds
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*
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* The time period is long enough so that the likelihood of
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* successive calls spanning the clock cycle is not considered.
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*/
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DWORD dwTime = timeGetTime();
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{
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m_rtPrivateTime += Int32x32To64(UNITS / MILLISECONDS, (DWORD)(dwTime - m_dwPrevSystemTime));
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m_dwPrevSystemTime = dwTime;
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}
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return m_rtPrivateTime;
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}
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/* Adjust the current time by the input value. This allows an
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external time source to work out some of the latency of the clock
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system and adjust the "current" time accordingly. The intent is
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that the time returned to the user is synchronised to a clock
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source and allows drift to be catered for.
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For example: if the clock source detects a drift it can pass a delta
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to the current time rather than having to set an explicit time.
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*/
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STDMETHODIMP CBaseReferenceClock::SetTimeDelta(const REFERENCE_TIME & TimeDelta)
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{
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#ifdef DEBUG
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// Just break if passed an improper time delta value
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LONGLONG llDelta = TimeDelta > 0 ? TimeDelta : -TimeDelta;
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if (llDelta > UNITS * 1000) {
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DbgLog((LOG_TRACE, 0, TEXT("Bad Time Delta")));
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//DebugBreak();
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}
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// We're going to calculate a "severity" for the time change. Max -1
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// min 8. We'll then use this as the debug logging level for a
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// debug log message.
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const LONG usDelta = LONG(TimeDelta/10); // Delta in micro-secs
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DWORD delta = abs(usDelta); // varying delta
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// Severity == 8 - ceil(log<base 8>(abs( micro-secs delta)))
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int Severity = 8;
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while ( delta > 0 )
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{
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delta >>= 3; // div 8
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Severity--;
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}
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// Sev == 0 => > 2 second delta!
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DbgLog((LOG_TIMING, Severity < 0 ? 0 : Severity,
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TEXT("Sev %2i: CSystemClock::SetTimeDelta(%8ld us) %lu -> %lu ms."),
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Severity, usDelta, DWORD(ConvertToMilliseconds(m_rtPrivateTime)),
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DWORD(ConvertToMilliseconds(TimeDelta+m_rtPrivateTime)) ));
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// Don't want the DbgBreak to fire when running stress on debug-builds.
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#ifdef BREAK_ON_SEVERE_TIME_DELTA
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if (Severity < 0)
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DbgBreakPoint(TEXT("SetTimeDelta > 16 seconds!"),
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TEXT(__FILE__),__LINE__);
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#endif
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#endif
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CAutoLock cObjectLock(this);
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m_rtPrivateTime += TimeDelta;
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// If time goes forwards, and we have advises, then we need to
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// trigger the thread so that it can re-evaluate its wait time.
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// Since we don't want the cost of the thread switches if the change
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// is really small, only do it if clock goes forward by more than
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// 0.5 millisecond. If the time goes backwards, the thread will
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// wake up "early" (relativly speaking) and will re-evaluate at
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// that time.
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if ( TimeDelta > 5000 && m_pSchedule->GetAdviseCount() > 0 ) TriggerThread();
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return NOERROR;
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}
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// Thread stuff
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DWORD __stdcall CBaseReferenceClock::AdviseThreadFunction(LPVOID p)
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{
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return DWORD(reinterpret_cast<CBaseReferenceClock*>(p)->AdviseThread());
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}
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HRESULT CBaseReferenceClock::AdviseThread()
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{
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DWORD dwWait = INFINITE;
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// The first thing we do is wait until something interesting happens
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// (meaning a first advise or shutdown). This prevents us calling
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// GetPrivateTime immediately which is goodness as that is a virtual
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// routine and the derived class may not yet be constructed. (This
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// thread is created in the base class constructor.)
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while ( !m_bAbort )
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{
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// Wait for an interesting event to happen
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DbgLog((LOG_TIMING, 3, TEXT("CBaseRefClock::AdviseThread() Delay: %lu ms"), dwWait ));
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WaitForSingleObject(m_pSchedule->GetEvent(), dwWait);
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if (m_bAbort) break;
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// There are several reasons why we need to work from the internal
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// time, mainly to do with what happens when time goes backwards.
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// Mainly, it stop us looping madly if an event is just about to
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// expire when the clock goes backward (i.e. GetTime stop for a
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// while).
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const REFERENCE_TIME rtNow = GetPrivateTime();
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DbgLog((LOG_TIMING, 3,
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TEXT("CBaseRefClock::AdviseThread() Woke at = %lu ms"),
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ConvertToMilliseconds(rtNow) ));
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// We must add in a millisecond, since this is the resolution of our
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// WaitForSingleObject timer. Failure to do so will cause us to loop
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// franticly for (approx) 1 a millisecond.
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m_rtNextAdvise = m_pSchedule->Advise( 10000 + rtNow );
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LONGLONG llWait = m_rtNextAdvise - rtNow;
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ASSERT( llWait > 0 );
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llWait = ConvertToMilliseconds(llWait);
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// DON'T replace this with a max!! (The type's of these things is VERY important)
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dwWait = (llWait > REFERENCE_TIME(UINT_MAX)) ? UINT_MAX : DWORD(llWait);
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};
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return NOERROR;
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}
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