Leaked source code of windows server 2003
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//+-------------------------------------------------------------------------
//
// Microsoft Windows
//
// Copyright (c) 1999-1999 Microsoft Corporation
//
// File: mgentrk.cpp
//
//--------------------------------------------------------------------------
// READ THIS!!!!!!!!!!!!!!!!!!!!!!!!!!!
//
// 4530: C++ exception handler used, but unwind semantics are not enabled. Specify -GX
//
// We disable this because we use exceptions and do *not* specify -GX (USE_NATIVE_EH in
// sources).
//
// The one place we use exceptions is around construction of objects that call
// InitializeCriticalSection. We guarantee that it is safe to use in this case with
// the restriction given by not using -GX (automatic objects in the call chain between
// throw and handler are not destructed). Turning on -GX buys us nothing but +10% to code
// size because of the unwind code.
//
// Any other use of exceptions must follow these restrictions or -GX must be turned on.
//
// READ THIS!!!!!!!!!!!!!!!!!!!!!!!!!!!
//
#pragma warning(disable:4530)
// MGenTrk.cpp : Implementation of CMelodyFormulationTrack
#include "MGenTrk.h"
#include "dmstyle.h"
#include "debug.h"
#include "..\shared\Validate.h"
DirectMusicTimeSig CompositionFragment::m_staticTimeSig(4, 4, 4);
const BYTE g_bDefaultPlaymode = DMUS_PLAYMODE_ALWAYSPLAY;
// Since one of these is typedef'd to the other, we only need a single
// implementation that does a structure-wide copy (but keep the other 3 implementations
// around, in case we separate the types out later)
HRESULT CopyMelodyFragment(DMUS_MELODY_FRAGMENT& rTo, const DMUS_MELODY_FRAGMENT& rFrom)
{
rTo = rFrom;
rTo.dwPlayModeFlags = DMUS_PLAYMODE_NONE; // only flag supported for dx8
return S_OK;
}
BOOL Less(DMUS_IO_SEQ_ITEM& SeqItem1, DMUS_IO_SEQ_ITEM& SeqItem2)
{ return SeqItem1.mtTime + SeqItem1.nOffset < SeqItem2.mtTime + SeqItem2.nOffset; }
BOOL Greater(DMUS_IO_SEQ_ITEM& SeqItem1, DMUS_IO_SEQ_ITEM& SeqItem2)
{ return SeqItem1.mtTime + SeqItem1.nOffset > SeqItem2.mtTime + SeqItem2.nOffset; }
BOOL Less(EventWrapper& SeqItem1, EventWrapper& SeqItem2)
{
MUSIC_TIME mtOffset1 = SeqItem1.m_pEvent ? SeqItem1.m_pEvent->m_nTimeOffset : 0;
MUSIC_TIME mtOffset2 = SeqItem2.m_pEvent ? SeqItem2.m_pEvent->m_nTimeOffset : 0;
return SeqItem1.m_mtTime + mtOffset1 < SeqItem2.m_mtTime + mtOffset2;
}
BOOL Greater(EventWrapper& SeqItem1, EventWrapper& SeqItem2)
{
MUSIC_TIME mtOffset1 = SeqItem1.m_pEvent ? SeqItem1.m_pEvent->m_nTimeOffset : 0;
MUSIC_TIME mtOffset2 = SeqItem2.m_pEvent ? SeqItem2.m_pEvent->m_nTimeOffset : 0;
return SeqItem1.m_mtTime + mtOffset1 > SeqItem2.m_mtTime + mtOffset2;
}
/*
HRESULT CopyMelodyFragment(DMUS_MELODY_FRAGMENT& rTo, const DMUS_IO_MELODY_FRAGMENT& rFrom)
{
rTo = rFrom;
return S_OK;
}
HRESULT CopyMelodyFragment(DMUS_IO_MELODY_FRAGMENT& rTo, const DMUS_MELODY_FRAGMENT& rFrom)
{
rTo = rFrom;
return S_OK;
}
HRESULT CopyMelodyFragment(DMUS_IO_MELODY_FRAGMENT& rTo, const DMUS_IO_MELODY_FRAGMENT& rFrom)
{
rTo = rFrom;
return S_OK;
}
*/
/////////////////////////////////////////////////////////////////////////////
// CMelodyFormulationTrack
CMelodyFormulationTrack::CMelodyFormulationTrack() :
m_bRequiresSave(0), m_dwLastId(0), m_bPlaymode(g_bDefaultPlaymode),
m_cRef(1), m_fNotifyRecompose(FALSE)
{
// Do this first since it might throw an exception
//
::InitializeCriticalSection( &m_CriticalSection );
InterlockedIncrement(&g_cComponent);
}
CMelodyFormulationTrack::CMelodyFormulationTrack(const CMelodyFormulationTrack& rTrack, MUSIC_TIME mtStart, MUSIC_TIME mtEnd) :
m_bRequiresSave(0), m_dwLastId(rTrack.m_dwLastId), m_bPlaymode(rTrack.m_bPlaymode),
m_cRef(1), m_fNotifyRecompose(FALSE)
{
// Do this first since it might throw an exception
//
::InitializeCriticalSection( &m_CriticalSection );
InterlockedIncrement(&g_cComponent);
m_bPlaymode = rTrack.m_bPlaymode;
BOOL fStarted = FALSE;
TListItem<DMUS_MELODY_FRAGMENT>* pScan = rTrack.m_FragmentList.GetHead();
TListItem<DMUS_MELODY_FRAGMENT>* pPrevious = NULL;
for(; pScan; pScan = pScan->GetNext())
{
DMUS_MELODY_FRAGMENT& rScan = pScan->GetItemValue();
if (rScan.mtTime < mtStart)
{
pPrevious = pScan;
}
else if (rScan.mtTime < mtEnd)
{
if (rScan.mtTime == mtStart)
{
pPrevious = NULL;
}
if (!fStarted)
{
fStarted = TRUE;
}
TListItem<DMUS_MELODY_FRAGMENT>* pNew = new TListItem<DMUS_MELODY_FRAGMENT>;
if (pNew)
{
DMUS_MELODY_FRAGMENT& rNew = pNew->GetItemValue();
CopyMelodyFragment(rNew, rScan);
rNew.mtTime = rScan.mtTime - mtStart;
m_FragmentList.AddTail(pNew);
}
}
else break;
}
if (pPrevious)
{
DMUS_MELODY_FRAGMENT& rPrevious = pPrevious->GetItemValue();
TListItem<DMUS_MELODY_FRAGMENT>* pNew = new TListItem<DMUS_MELODY_FRAGMENT>;
if (pNew)
{
DMUS_MELODY_FRAGMENT& rNew = pNew->GetItemValue();
CopyMelodyFragment(rNew, rPrevious);
rNew.mtTime = 0;
m_FragmentList.AddHead(pNew);
}
}
}
CMelodyFormulationTrack::~CMelodyFormulationTrack()
{
::DeleteCriticalSection( &m_CriticalSection );
InterlockedDecrement(&g_cComponent);
}
void CMelodyFormulationTrack::Clear()
{
m_FragmentList.CleanUp();
m_dwLastId = 0;
}
HRESULT CMelodyFormulationTrack::SetID(DWORD& rdwID)
{
m_dwLastId++;
rdwID = m_dwLastId;
return S_OK;
}
HRESULT CMelodyFormulationTrack::GetID(DWORD& rdwID)
{
rdwID = m_dwLastId;
return S_OK;
}
STDMETHODIMP CMelodyFormulationTrack::QueryInterface(
const IID &iid,
void **ppv)
{
V_INAME(CMelodyFormulationTrack::QueryInterface);
V_PTRPTR_WRITE(ppv);
V_REFGUID(iid);
if (iid == IID_IUnknown || iid == IID_IDirectMusicTrack || iid == IID_IDirectMusicTrack8)
{
*ppv = static_cast<IDirectMusicTrack*>(this);
}
else if (iid == IID_IPersistStream)
{
*ppv = static_cast<IPersistStream*>(this);
}
else
{
*ppv = NULL;
return E_NOINTERFACE;
}
reinterpret_cast<IUnknown*>(this)->AddRef();
return S_OK;
}
STDMETHODIMP_(ULONG) CMelodyFormulationTrack::AddRef()
{
return InterlockedIncrement(&m_cRef);
}
STDMETHODIMP_(ULONG) CMelodyFormulationTrack::Release()
{
if (!InterlockedDecrement(&m_cRef))
{
delete this;
return 0;
}
return m_cRef;
}
HRESULT CMelodyFormulationTrack::Init(
/*[in]*/ IDirectMusicSegment* pSegment
)
{
return S_OK; // if I return an error, dmime gives me an assertion failure
}
HRESULT CMelodyFormulationTrack::InitPlay(
/*[in]*/ IDirectMusicSegmentState* pSegmentState,
/*[in]*/ IDirectMusicPerformance* pPerformance,
/*[out]*/ void** ppStateData,
/*[in]*/ DWORD dwTrackID,
/*[in]*/ DWORD dwFlags
)
{
return S_OK;
}
HRESULT CMelodyFormulationTrack::EndPlay(
/*[in]*/ void* pStateData
)
{
return S_OK;
}
HRESULT CMelodyFormulationTrack::Play(
/*[in]*/ void* pStateData,
/*[in]*/ MUSIC_TIME mtStart,
/*[in]*/ MUSIC_TIME mtEnd,
/*[in]*/ MUSIC_TIME mtOffset,
DWORD dwFlags,
IDirectMusicPerformance* pPerf,
IDirectMusicSegmentState* pSegState,
DWORD dwVirtualID
)
{
bool fStart = (dwFlags & DMUS_TRACKF_START) ? true : false;
bool fLoop = (dwFlags & DMUS_TRACKF_LOOP) ? true : false;
bool fCompose = (dwFlags & DMUS_TRACKF_RECOMPOSE) ? true : false;
bool fPlayOff = (dwFlags & DMUS_TRACKF_PLAY_OFF) ? true : false;
HRESULT hr = S_OK;
EnterCriticalSection(&m_CriticalSection);
DWORD dwTrackGroup = 1;
if ( fStart || fLoop )
{
if ( fCompose && !fPlayOff )
{
IDirectMusicSegment* pSegment = NULL;
if (SUCCEEDED(hr = pSegState->GetSegment(&pSegment)))
{
IDirectMusicTrack* pTrack = NULL;
if (SUCCEEDED(hr = QueryInterface(IID_IDirectMusicTrack, (void**)&pTrack)))
{
pSegment->GetTrackGroup(pTrack, &dwTrackGroup);
pTrack->Release();
// call Track::Compose on this track
if (SUCCEEDED(hr = Compose(pSegment, dwTrackGroup, &pTrack)))
{
if (SUCCEEDED(AddToSegment(pSegment, pTrack, dwTrackGroup)))
{
// if we recomposed, send a recompose notification
SendNotification(mtStart + mtOffset, pPerf, pSegment, pSegState, dwFlags);
}
pTrack->Release();
}
}
}
pSegment->Release();
}
}
LeaveCriticalSection(&m_CriticalSection);
return hr;
}
// This will modify an existing segment by adding *only* a pattern track to it.
// Any existing pattern tracks with conflicting group bits will be modifed.
HRESULT CMelodyFormulationTrack::AddToSegment(IDirectMusicSegment* pTempSeg,
IDirectMusicTrack* pNewPatternTrack,
DWORD dwGroupBits)
{
HRESULT hr = S_OK;
IDirectMusicTrack* pCurrentPatternTrack = NULL;
IStream* pNewPatternStream = NULL;
IPersistStream* pNewPatternTrackStream = NULL;
IPersistStream* pCurrentPatternTrackStream = NULL;
// if there exists a pattern track with these group bits, reload this pattern into that
// track (use the first track that's found). Otherwise, insert this track into the segment.
hr = pTempSeg->GetTrack(CLSID_DirectMusicPatternTrack, dwGroupBits, 0, &pCurrentPatternTrack);
if (S_OK != hr)
{
// insert the passed-in track
hr = pTempSeg->InsertTrack(pNewPatternTrack, dwGroupBits);
}
else
{
// load the new track into the one that already exists
hr = CreateStreamOnHGlobal(NULL, TRUE, &pNewPatternStream);
if (S_OK != hr) goto ON_END;
hr = pNewPatternTrack->QueryInterface( IID_IPersistStream, (void**)&pNewPatternTrackStream);
if (S_OK != hr) goto ON_END;
pNewPatternTrackStream->Save(pNewPatternStream, FALSE);
hr = pCurrentPatternTrack->QueryInterface(IID_IPersistStream, (void**)&pCurrentPatternTrackStream);
if (!SUCCEEDED(hr)) goto ON_END;
StreamSeek(pNewPatternStream, 0, STREAM_SEEK_SET);
hr = pCurrentPatternTrackStream->Load(pNewPatternStream);
if (!SUCCEEDED(hr)) goto ON_END;
}
ON_END:
if (pCurrentPatternTrack) pCurrentPatternTrack->Release();
if (pCurrentPatternTrackStream) pCurrentPatternTrackStream->Release();
if (pNewPatternStream) pNewPatternStream->Release();
if (pNewPatternTrackStream) pNewPatternTrackStream->Release();
return hr;
}
HRESULT CMelodyFormulationTrack::SendNotification(MUSIC_TIME mtTime,
IDirectMusicPerformance* pPerf,
IDirectMusicSegment* pSegment,
IDirectMusicSegmentState* pSegState,
DWORD dwFlags)
{
if (!m_fNotifyRecompose || (dwFlags & DMUS_TRACKF_NOTIFY_OFF))
{
return S_OK;
}
DMUS_NOTIFICATION_PMSG* pEvent = NULL;
HRESULT hr = pPerf->AllocPMsg( sizeof(DMUS_NOTIFICATION_PMSG), (DMUS_PMSG**)&pEvent );
if( SUCCEEDED( hr ))
{
pEvent->dwField1 = 0;
pEvent->dwField2 = 0;
pEvent->dwType = DMUS_PMSGT_NOTIFICATION;
pEvent->mtTime = mtTime;
pEvent->dwFlags = DMUS_PMSGF_MUSICTIME | DMUS_PMSGF_TOOL_ATTIME;
pSegState->QueryInterface(IID_IUnknown, (void**)&pEvent->punkUser);
pEvent->dwNotificationOption = DMUS_NOTIFICATION_RECOMPOSE;
pEvent->guidNotificationType = GUID_NOTIFICATION_RECOMPOSE;
if (FAILED(pSegment->GetTrackGroup(this, &pEvent->dwGroupID)))
{
pEvent->dwGroupID = 0xffffffff;
}
IDirectMusicGraph* pGraph;
hr = pSegState->QueryInterface( IID_IDirectMusicGraph, (void**)&pGraph );
if( SUCCEEDED( hr ))
{
pGraph->StampPMsg((DMUS_PMSG*) pEvent );
pGraph->Release();
}
hr = pPerf->SendPMsg((DMUS_PMSG*) pEvent );
if( FAILED(hr) )
{
pPerf->FreePMsg((DMUS_PMSG*) pEvent );
}
}
return hr;
}
HRESULT CMelodyFormulationTrack::GetParam(
REFGUID rParamGuid,
MUSIC_TIME mtTime,
MUSIC_TIME* pmtNext,
void* pData
)
{
V_INAME(CMelodyFormulationTrack::GetParam);
V_PTR_WRITE_OPT(pmtNext,MUSIC_TIME);
V_PTR_WRITE(pData, 1);
V_REFGUID(rParamGuid);
HRESULT hr = S_OK;
EnterCriticalSection(&m_CriticalSection);
if (rParamGuid == GUID_MelodyFragment)
{
TListItem<DMUS_MELODY_FRAGMENT>* pMelGen = m_FragmentList.GetHead();
if (pMelGen)
{
TListItem<DMUS_MELODY_FRAGMENT>* pNext = pMelGen->GetNext();
for(; pNext; pNext = pNext->GetNext())
{
if (pNext->GetItemValue().mtTime <= mtTime) // may be it, but we need a next time
{
pMelGen = pNext;
}
else // passed it
{
break;
}
}
*(DMUS_MELODY_FRAGMENT*)pData = pMelGen->GetItemValue();
if (pmtNext)
{
if (pNext)
{
*pmtNext = pNext->GetItemValue().mtTime - mtTime;
}
else
{
*pmtNext = 0;
}
}
hr = S_OK;
}
else hr = DMUS_E_NOT_FOUND;
}
else if (rParamGuid == GUID_MelodyFragmentRepeat)
{
// replace the passed-in fragment with the one its repeat field refers to
DMUS_MELODY_FRAGMENT* pFragment = (DMUS_MELODY_FRAGMENT*)pData;
if (!(pFragment->dwFragmentFlags & DMUS_FRAGMENTF_USE_REPEAT))
{
hr = DMUS_E_NOT_FOUND;
}
else
{
TListItem<DMUS_MELODY_FRAGMENT>* pMelGen = m_FragmentList.GetHead();
for(; pMelGen; pMelGen = pMelGen->GetNext())
{
if (pMelGen->GetItemValue().dwID == pFragment->dwRepeatFragmentID)
{
break;
}
}
if (pMelGen)
{
*(DMUS_MELODY_FRAGMENT*)pData = pMelGen->GetItemValue();
if (pmtNext)
{
TListItem<DMUS_MELODY_FRAGMENT>* pNext = pMelGen->GetNext();
if (pNext)
{
*pmtNext = pNext->GetItemValue().mtTime - mtTime;
}
else
{
*pmtNext = 0;
}
}
hr = S_OK;
}
else hr = DMUS_E_NOT_FOUND;
}
}
else if (rParamGuid == GUID_MelodyPlaymode)
{
*(BYTE*)pData = m_bPlaymode;
if (pmtNext)
{
*pmtNext = 0;
}
}
else
{
hr = DMUS_E_GET_UNSUPPORTED;
}
LeaveCriticalSection(&m_CriticalSection);
return hr;
}
HRESULT CMelodyFormulationTrack::SetParam(
REFGUID rParamGuid,
MUSIC_TIME mtTime,
void __RPC_FAR *pData)
{
V_INAME(CMelodyFormulationTrack::SetParam);
V_PTR_WRITE(pData, 1);
V_REFGUID(rParamGuid);
HRESULT hr;
EnterCriticalSection( &m_CriticalSection );
if (rParamGuid == GUID_Clear_All_MelodyFragments)
{
Clear();
hr = S_OK;
}
else if (rParamGuid == GUID_MelodyFragment)
{
DMUS_MELODY_FRAGMENT* pFragment = (DMUS_MELODY_FRAGMENT*)pData;
TListItem<DMUS_MELODY_FRAGMENT>* pFragmentItem = m_FragmentList.GetHead();
TListItem<DMUS_MELODY_FRAGMENT>* pPrevious = NULL;
TListItem<DMUS_MELODY_FRAGMENT>* pNew = new TListItem<DMUS_MELODY_FRAGMENT>;
if (!pNew)
{
hr = E_OUTOFMEMORY;
}
else
{
pNew->GetItemValue() = *pFragment;
// overide time in struct with time passed in
pNew->GetItemValue().mtTime = mtTime;
for(; pFragmentItem != NULL; pFragmentItem = pFragmentItem->GetNext())
{
if (pFragmentItem->GetItemValue().mtTime >= mtTime) break;
pPrevious = pFragmentItem;
}
if (pPrevious)
{
pPrevious->SetNext(pNew);
pNew->SetNext(pFragmentItem);
}
else // pFragmentItem is current head of list
{
m_FragmentList.AddHead(pNew);
}
if (pFragmentItem && pFragmentItem->GetItemValue().mtTime == mtTime)
{
// remove it
pNew->GetItemValue().dwID = pFragmentItem->GetItemValue().dwID;
pNew->SetNext(pFragmentItem->GetNext());
pFragmentItem->SetNext(NULL);
delete pFragmentItem;
}
else
{
// give the struct a brand new ID
SetID(pNew->GetItemValue().dwID);
}
hr = S_OK;
}
}
else
{
hr = DMUS_E_SET_UNSUPPORTED;
}
LeaveCriticalSection( &m_CriticalSection );
return hr;
}
// IPersist methods
HRESULT CMelodyFormulationTrack::GetClassID( LPCLSID pClassID )
{
V_INAME(CMelodyFormulationTrack::GetClassID);
V_PTR_WRITE(pClassID, CLSID);
*pClassID = CLSID_DirectMusicMelodyFormulationTrack;
return S_OK;
}
HRESULT CMelodyFormulationTrack::IsParamSupported(
/*[in]*/ REFGUID rGuid
)
{
V_INAME(CMelodyFormulationTrack::IsParamSupported);
V_REFGUID(rGuid);
if (rGuid == GUID_MelodyFragment ||
rGuid == GUID_MelodyPlaymode ||
rGuid == GUID_Clear_All_MelodyFragments)
return S_OK;
else
return DMUS_E_TYPE_UNSUPPORTED;
}
// IPersistStream methods
HRESULT CMelodyFormulationTrack::IsDirty()
{
return m_bRequiresSave ? S_OK : S_FALSE;
}
HRESULT CMelodyFormulationTrack::Save( LPSTREAM pStream, BOOL fClearDirty )
{
V_INAME(CMelodyFormulationTrack::Save);
V_INTERFACE(pStream);
HRESULT hr = S_OK;
IAARIFFStream* pRIFF = NULL;
MMCKINFO ckMain, ckHeader, ckBody;
DWORD cb;
DWORD dwSize;
DMUS_IO_MELODY_FRAGMENT oMelGen;
TListItem<DMUS_MELODY_FRAGMENT>* pMelGen;
EnterCriticalSection( &m_CriticalSection );
hr = AllocRIFFStream( pStream, &pRIFF );
if ( FAILED( hr ) )
{
goto ON_END;
}
// Create a chunk to store the MelGen data
ckMain.fccType = DMUS_FOURCC_MELODYFORM_TRACK_LIST;
if( pRIFF->CreateChunk( &ckMain, MMIO_CREATELIST ) != 0 )
{
hr = E_FAIL;
goto ON_END;
}
// Write MelForm chunk header
ckHeader.ckid = DMUS_FOURCC_MELODYFORM_HEADER_CHUNK;
if( pRIFF->CreateChunk( &ckHeader, 0 ) != 0 )
{
hr = E_FAIL;
goto ON_END;
}
// Prepare DMUS_IO_MELFORM
DMUS_IO_MELFORM oMelForm;
memset( &oMelForm, 0, sizeof(DMUS_IO_MELFORM) );
oMelForm.dwPlaymode = m_bPlaymode;
// Write MelForm chunk data
hr = pStream->Write( &oMelForm, sizeof(DMUS_IO_MELFORM), &cb);
if( FAILED( hr ) || cb != sizeof(DMUS_IO_MELFORM) )
{
hr = E_FAIL;
goto ON_END;
}
if( pRIFF->Ascend( &ckHeader, 0 ) != 0 )
{
hr = E_FAIL;
goto ON_END;
}
// Write MelForm chunk body
ckBody.ckid = DMUS_FOURCC_MELODYFORM_BODY_CHUNK;
if( pRIFF->CreateChunk( &ckBody, 0 ) == 0 )
{
dwSize = sizeof( oMelGen );
hr = pStream->Write( &dwSize, sizeof( dwSize ), &cb );
if( FAILED( hr ) || cb != sizeof( dwSize ) )
{
if (SUCCEEDED(hr)) hr = E_FAIL;
goto ON_END;
}
for( pMelGen = m_FragmentList.GetHead(); pMelGen != NULL ; pMelGen = pMelGen->GetNext() )
{
DMUS_MELODY_FRAGMENT& rMelGen = pMelGen->GetItemValue();
memset( &oMelGen, 0, sizeof( oMelGen ) );
CopyMelodyFragment(oMelGen, rMelGen);
if( FAILED( pStream->Write( &oMelGen, sizeof( oMelGen ), &cb ) ) ||
cb != sizeof( oMelGen ) )
{
break;
}
}
if( pMelGen == NULL )
{
hr = S_OK;
}
// Ascend out of the MelForm Body chunk
if( pRIFF->Ascend( &ckBody, 0 ) != 0 )
{
hr = E_FAIL;
goto ON_END;
}
}
// Ascend out of the MelGen chunk.
pRIFF->Ascend( &ckMain, 0 );
ON_END:
if (pRIFF) pRIFF->Release();
LeaveCriticalSection( &m_CriticalSection );
return hr;
}
HRESULT CMelodyFormulationTrack::GetSizeMax( ULARGE_INTEGER* /*pcbSize*/ )
{
return E_NOTIMPL;
}
BOOL Less(DMUS_MELODY_FRAGMENT& MF1, DMUS_MELODY_FRAGMENT& MF2)
{ return MF1.mtTime < MF2.mtTime; }
HRESULT CMelodyFormulationTrack::Load(LPSTREAM pStream )
{
V_INAME(CMelodyFormulationTrack::Load);
V_INTERFACE(pStream);
// Melody formulation temporarily turned off for DX8.
return E_NOTIMPL;
/*
HRESULT hr = DMUS_E_CHUNKNOTFOUND;
DWORD dwPos;
IAARIFFStream* pRIFF;
EnterCriticalSection( &m_CriticalSection );
Clear();
m_dwLastId = 0;
dwPos = StreamTell( pStream );
StreamSeek( pStream, dwPos, STREAM_SEEK_SET );
MMCKINFO ck;
MMCKINFO ckMain;
MMCKINFO ckHeader;
bool fFoundTrack = false;
if( SUCCEEDED( AllocRIFFStream( pStream, &pRIFF ) ) )
{
ckMain.fccType = DMUS_FOURCC_MELODYFORM_TRACK_LIST;
if( pRIFF->Descend( &ckMain, NULL, MMIO_FINDLIST ) == 0)
{
// New melform track
long lFileSize = ckMain.cksize - 4; // subtract off the list type
DMUS_IO_MELFORM iMelform;
DWORD cb;
if (pRIFF->Descend(&ckHeader, &ckMain, 0) == 0)
{
if (ckHeader.ckid == DMUS_FOURCC_MELODYFORM_HEADER_CHUNK )
{
lFileSize -= 8; // chunk id + chunk size: double words
lFileSize -= ckHeader.cksize;
hr = pStream->Read( &iMelform, sizeof( iMelform ), &cb );
if (FAILED(hr) || cb != sizeof( iMelform ) )
{
if (SUCCEEDED(hr)) hr = DMUS_E_CHUNKNOTFOUND;
}
else
{
//m_bPlaymode = (BYTE) iMelform.dwPlaymode;
m_bPlaymode = DMUS_PLAYMODE_NONE; // only flag supported for dx8
}
}
pRIFF->Ascend( &ckHeader, 0 );
}
if (SUCCEEDED(hr))
{
hr = DMUS_E_CHUNKNOTFOUND;
if (pRIFF->Descend(&ck, &ckMain, 0) == 0)
{
if (ck.ckid == DMUS_FOURCC_MELODYFORM_BODY_CHUNK )
{
if( SUCCEEDED(LoadFragments(pStream, (long) ck.cksize)) )
{
hr = S_OK;
m_FragmentList.MergeSort(Less);
}
}
pRIFF->Ascend( &ck, 0 );
}
}
fFoundTrack = true;
}
pRIFF->Release();
pRIFF = NULL;
}
if (!fFoundTrack)
{
StreamSeek( pStream, dwPos, STREAM_SEEK_SET );
// old (obsolete) melform track
if( SUCCEEDED( AllocRIFFStream( pStream, &pRIFF ) ) )
{
ck.ckid = DMUS_FOURCC_MELODYGEN_TRACK_CHUNK;
if ( pRIFF->Descend( &ck, NULL, MMIO_FINDCHUNK ) == 0 )
{
if( SUCCEEDED(LoadFragments(pStream, (long) ck.cksize)) &&
pRIFF->Ascend( &ck, 0 ) == 0 )
{
hr = S_OK;
m_FragmentList.MergeSort(Less);
}
}
pRIFF->Release();
}
}
LeaveCriticalSection( &m_CriticalSection );
return hr;*/
}
HRESULT CMelodyFormulationTrack::LoadFragments(LPSTREAM pStream, long lFileSize )
{
DWORD dwNodeSize;
DWORD cb;
HRESULT hr = pStream->Read( &dwNodeSize, sizeof( dwNodeSize ), &cb );
DMUS_IO_MELODY_FRAGMENT iMelGen;
if( SUCCEEDED( hr ) && cb == sizeof( dwNodeSize ) )
{
lFileSize -= 4; // for the size dword
TListItem<DMUS_MELODY_FRAGMENT>* pMelGen;
if (lFileSize % dwNodeSize)
{
hr = E_FAIL;
}
else
{
while( lFileSize > 0 )
{
pMelGen = new TListItem<DMUS_MELODY_FRAGMENT>;
if( pMelGen )
{
DMUS_MELODY_FRAGMENT& rMelGen = pMelGen->GetItemValue();
if( dwNodeSize <= sizeof( iMelGen ) )
{
pStream->Read( &iMelGen, dwNodeSize, NULL );
}
else
{
pStream->Read( &iMelGen, sizeof( iMelGen ), NULL );
DWORD dw = (lFileSize >= sizeof( iMelGen ) ) ? lFileSize - sizeof( iMelGen ) : 0;
StreamSeek( pStream, dw, STREAM_SEEK_CUR );
}
memset( &rMelGen, 0, sizeof( rMelGen ) );
CopyMelodyFragment(rMelGen, iMelGen);
m_FragmentList.AddHead(pMelGen);
lFileSize -= dwNodeSize;
}
else break;
}
}
}
if (SUCCEEDED(hr))
{
if (lFileSize != 0)
{
hr = E_FAIL;
}
}
return hr;
}
HRESULT STDMETHODCALLTYPE CMelodyFormulationTrack::AddNotificationType(
/* [in] */ REFGUID rGuidNotify)
{
V_INAME(CPersonalityTrack::AddNotificationType);
V_REFGUID(rGuidNotify);
if( rGuidNotify == GUID_NOTIFICATION_RECOMPOSE )
{
m_fNotifyRecompose = TRUE;
return S_OK;
}
else
{
return S_FALSE;
}
}
HRESULT STDMETHODCALLTYPE CMelodyFormulationTrack::RemoveNotificationType(
/* [in] */ REFGUID rGuidNotify)
{
V_INAME(CPersonalityTrack::RemoveNotificationType);
V_REFGUID(rGuidNotify);
if( rGuidNotify == GUID_NOTIFICATION_RECOMPOSE )
{
m_fNotifyRecompose = FALSE;
return S_OK;
}
else
{
return S_FALSE;
}
}
HRESULT STDMETHODCALLTYPE CMelodyFormulationTrack::Clone(
MUSIC_TIME mtStart,
MUSIC_TIME mtEnd,
IDirectMusicTrack** ppTrack)
{
V_INAME(CSPstTrk::Clone);
V_PTRPTR_WRITE(ppTrack);
HRESULT hr = S_OK;
if(mtStart < 0 )
{
return E_INVALIDARG;
}
if(mtStart > mtEnd)
{
return E_INVALIDARG;
}
EnterCriticalSection( &m_CriticalSection );
CMelodyFormulationTrack *pDM;
try
{
pDM = new CMelodyFormulationTrack(*this, mtStart, mtEnd);
}
catch( ... )
{
pDM = NULL;
}
if (pDM == NULL) {
LeaveCriticalSection( &m_CriticalSection );
return E_OUTOFMEMORY;
}
hr = pDM->QueryInterface(IID_IDirectMusicTrack, (void**)ppTrack);
pDM->Release();
LeaveCriticalSection( &m_CriticalSection );
return hr;
}
HRESULT MelodyFragment::GetChord(IDirectMusicSegment* pTempSeg,
IDirectMusicSong* pSong,
DWORD dwTrackGroup,
MUSIC_TIME& rmtNext,
DMUS_CHORD_PARAM& rCurrentChord,
MUSIC_TIME& rmtCurrent,
DMUS_CHORD_PARAM& rRealCurrentChord)
{
HRESULT hr = S_OK;
hr = GetChord(m_mtTime, pTempSeg, pSong, dwTrackGroup, rmtNext, rRealCurrentChord);
if ( SUCCEEDED(hr) )
{
rmtCurrent = rmtNext;
if (m_dwFragmentFlags & DMUS_FRAGMENTF_ANTICIPATE)
{
hr = GetChord(rmtCurrent, pTempSeg, pSong, dwTrackGroup, rmtNext, rCurrentChord);
}
else
{
rCurrentChord = rRealCurrentChord;
}
}
return hr;
}
HRESULT MelodyFragment::GetChord(MUSIC_TIME mtTime,
IDirectMusicSegment* pTempSeg,
IDirectMusicSong* pSong,
DWORD dwTrackGroup,
MUSIC_TIME& rmtNext,
DMUS_CHORD_PARAM& rCurrentChord)
{
HRESULT hr = E_FAIL;
DMUS_CHORD_PARAM DefaultChord;
wcscpy(DefaultChord.wszName, L"M7");
DefaultChord.wMeasure = 0;
DefaultChord.bBeat = 0;
DefaultChord.bSubChordCount = 1;
DefaultChord.dwScale = 0xab5ab5; // default: major scale
DefaultChord.bKey = 12; // default: C2
DefaultChord.SubChordList[0].dwChordPattern = 0x91; // default: major chord
DefaultChord.SubChordList[0].dwScalePattern = 0xab5ab5; // default: major scale
DefaultChord.SubChordList[0].dwInversionPoints = 0xffffff; // default: inversions everywhere
DefaultChord.SubChordList[0].dwLevels = 0xffffff; // let this work with anything...
DefaultChord.SubChordList[0].bChordRoot = 12; // default: C2
DefaultChord.SubChordList[0].bScaleRoot = 0;
if (pTempSeg)
{
hr = pTempSeg->GetParam(GUID_ChordParam, dwTrackGroup, 0, mtTime, &rmtNext, (void*)&rCurrentChord);
}
else if (pSong)
{
hr = pSong->GetParam(GUID_ChordParam, dwTrackGroup, 0, mtTime, &rmtNext, (void*)&rCurrentChord);
}
if (SUCCEEDED(hr))
{
rmtNext += mtTime;
hr = S_OK;
}
else
{
rCurrentChord = DefaultChord;
rmtNext = 0;
hr = S_FALSE;
}
return hr;
}
HRESULT MelodyFragment::GetPattern(DMStyleStruct* pStyleStruct,
CDirectMusicPattern*& rpPattern,
TListItem<CompositionFragment>* pLastFragment)
{
HRESULT hr = S_OK;
DMUS_COMMAND_PARAM_2 Command[1];
Command[0].mtTime = 0;
if (m_Command.bGrooveLevel == 0 && pLastFragment)
{
m_Command = pLastFragment->GetItemValue().GetCommand();
}
Command[0].bCommand = m_Command.bCommand;
Command[0].bGrooveLevel = m_Command.bGrooveLevel;
Command[0].bGrooveRange = m_Command.bGrooveRange;
TListItem<CDirectMusicPattern*>* pPatItem = pStyleStruct->m_PatternList.GetHead();
if (pPatItem)
{
// choose the first matching pattern
for ( ; pPatItem; pPatItem = pPatItem->GetNext())
{
CDirectMusicPattern* pPattern = pPatItem->GetItemValue();
if (pPattern && pPattern->MatchCommand(Command, 1) )
{
rpPattern = pPattern;
hr = S_OK;
break;
}
}
if (!pPatItem) // problem; fallback to first pattern
{
pPatItem = pStyleStruct->m_PatternList.GetHead();
rpPattern = pPatItem->GetItemValue();
hr = S_OK;
}
}
else
{
hr = DMUS_E_NOT_FOUND;
}
return hr;
}
// GetTransitionNotes: given the time of a note, and a fragment, return the appropriate
// transition note tuple (last and overlap; ghost tested separately)
HRESULT GetTransitionNotes(MUSIC_TIME mtTime,
DWORD dwPart,
TListItem<CompositionFragment>* pCompFragment,
TransitionConstraint& rTransition)
{
rTransition.dwFlags &= ~DMUS_TRANSITIONF_OVERLAP_FOUND;
rTransition.dwFlags &= ~DMUS_TRANSITIONF_LAST_FOUND;
// Check pCompFragment overlaps for the last note to start before mtTime,
// and the first note to start on or after mtTime.
if (pCompFragment)
{
CompositionFragment& rFragment = pCompFragment->GetItemValue();
TListItem<EventOverlap>* pOverlap = rFragment.GetOverlapHead();
MUSIC_TIME nMinOverlap = 0;
MUSIC_TIME nMaxPlayed = 0;
for (; pOverlap; pOverlap = pOverlap->GetNext() )
{
EventOverlap& rOverlap = pOverlap->GetItemValue();
if ( rOverlap.m_PartRef.m_dwLogicalPartID == dwPart &&
(rOverlap.m_pEvent->m_dwEventTag & DMUS_EVENT_NOTE) )
{
if (rOverlap.m_mtTime >= mtTime) // this note overlaps
{
if ( !(rTransition.dwFlags & DMUS_TRANSITIONF_OVERLAP_FOUND) ||
rOverlap.m_mtTime < nMinOverlap )
{
HRESULT hr = rFragment.GetNote(rOverlap.m_pEvent, rOverlap.m_Chord, rOverlap.m_PartRef, rTransition.bOverlap);
if (SUCCEEDED(hr))
{
nMinOverlap = rOverlap.m_mtTime;
rTransition.dwFlags |= DMUS_TRANSITIONF_OVERLAP_FOUND;
}
}
}
if (rOverlap.m_mtTime < mtTime) // this note will be played
{
if ( !(rTransition.dwFlags & DMUS_TRANSITIONF_LAST_FOUND) ||
rOverlap.m_mtTime >= nMaxPlayed )
{
HRESULT hr = rFragment.GetNote(rOverlap.m_pEvent, rOverlap.m_Chord, rOverlap.m_PartRef, rTransition.bLastPlayed);
if (SUCCEEDED(hr))
{
nMaxPlayed = rOverlap.m_mtTime;
rTransition.dwFlags |= DMUS_TRANSITIONF_LAST_FOUND;
}
}
}
}
}
// If we couldn't find a last note, use the last note in the event list of pCompFragment
TListItem<CompositionFragment>* pfragmentScan = pCompFragment;
while (pfragmentScan && !(rTransition.dwFlags & DMUS_TRANSITIONF_LAST_FOUND))
{
CompositionFragment& rfragmentScan = pfragmentScan->GetItemValue();
TListItem<DirectMusicPartRef>* pPartRef = rfragmentScan.m_pPattern->m_PartRefList.GetHead();
int nParts = rfragmentScan.m_pPattern->m_PartRefList.GetCount();
for (int i = 0; pPartRef != NULL; pPartRef = pPartRef->GetNext(), i++)
{
if (pPartRef->GetItemValue().m_dwLogicalPartID == dwPart) break;
}
if (i < nParts)
{
TListItem<EventWrapper>* pEventItem = rfragmentScan.GetEventHead(i);
if (pEventItem)
{
// The list is sorted in reverse order, so the head is the last element
rTransition.bLastPlayed = pEventItem->GetItemValue().m_bMIDI;
rTransition.dwFlags |= DMUS_TRANSITIONF_LAST_FOUND;
}
}
pfragmentScan = pfragmentScan->GetNext(); // goes backwards to first fragment
}
}
return S_OK;
}
HRESULT MelodyFragment::TestTransition(BYTE bMIDI,
MUSIC_TIME mtNote,
DMUS_CHORD_PARAM& rCurrentChord,
int nPartIndex,
DirectMusicPartRef& rPartRef,
TListItem<CompositionFragment>* pLastFragment)
{
bool fGhost = false;
bool fOverlap = false;
bool fGoodInterval = false;
if (pLastFragment)
{
// if this variation doesn't meet the constraints, return S_FALSE; otherwise return S_OK
DMUS_CONNECTION_RULE Connection = pLastFragment->GetItemValue().GetConnectionArc();
DWORD dwPart = rPartRef.m_dwLogicalPartID;
TransitionConstraint Transition;
ZeroMemory(&Transition , sizeof(Transition));
GetTransitionNotes(mtNote, dwPart, pLastFragment, Transition);
// Test ghost notes
if ( (Connection.dwFlags & DMUS_CONNECTIONF_GHOST) )
{
BYTE bGhost = 0;
CDMStyleNote* pNoteEvent = new CDMStyleNote;
if (pNoteEvent)
{
pNoteEvent->m_bDurRange = 0;
pNoteEvent->m_bFlags = 0;
pNoteEvent->m_bTimeRange = 0;
pNoteEvent->m_bVelocity = 0;
pNoteEvent->m_dwFragmentID = 0;
pNoteEvent->m_mtDuration = 0;
pNoteEvent->m_nGridStart = 0;
pNoteEvent->m_nTimeOffset = 0;
TListItem<DMUS_IO_STYLERESOLUTION>* pScan = rPartRef.m_pDMPart->m_ResolutionList.GetHead();
for(; pScan; pScan = pScan->GetNext() )
{
DMUS_IO_STYLERESOLUTION& rResolution = pScan->GetItemValue();
pNoteEvent->m_bInversionId = rResolution.bInversionID;
pNoteEvent->m_bPlayModeFlags = rResolution.bPlayModeFlags;
pNoteEvent->m_dwVariation = rResolution.dwVariation;
pNoteEvent->m_wMusicValue = rResolution.wMusicValue;
if ((1 << pLastFragment->GetItemValue().m_abVariations[nPartIndex]) & pNoteEvent->m_dwVariation &&
SUCCEEDED(GetNote(pNoteEvent, rCurrentChord, rPartRef, bGhost)))
{
if (bGhost == bMIDI)
{
fGhost = true;
break;
}
}
}
delete pNoteEvent;
}
}
// Test overlap notes
if ( (Connection.dwFlags & DMUS_CONNECTIONF_OVERLAP) &&
(Transition.dwFlags & DMUS_TRANSITIONF_OVERLAP_FOUND) )
{
if (Transition.bOverlap == bMIDI) fOverlap = true;
}
// Test last played notes
// Assumptions:
// 1. intervals go in either direction (up or down)
// 2. intervals are in absolute semitones.
if ( (Connection.dwFlags & DMUS_CONNECTIONF_INTERVALS) &&
(Transition.dwFlags & DMUS_TRANSITIONF_LAST_FOUND) )
{
DWORD dwIntervals = Connection.dwIntervals;
for (int nTranspose = 0; nTranspose <= 12; nTranspose++)
{
if ( dwIntervals & (1 << nTranspose) )
{
if (Transition.bLastPlayed + nTranspose == bMIDI ||
Transition.bLastPlayed - nTranspose == bMIDI)
{
fGoodInterval = true;
}
}
}
}
}
return (fGhost || fOverlap || fGoodInterval) ? S_OK : S_FALSE;
}
// Currently assuming diatonic intervals spanning an octave
#define MAX_INTERVAL 8
// Currently only transposes up...
BYTE TransposeNote(BYTE bMIDI, int nInterval, DMUS_CHORD_PARAM& rChord)
{
if (!bMIDI) return bMIDI;
nInterval++; // To correspond to scale intervals
for (int nSemitone = 0; nSemitone < 24; nSemitone++)
{
if (rChord.dwScale & (1 << nSemitone))
{
nInterval--;
if (!nInterval) break;
}
}
if (nSemitone < 24)
{
bMIDI = (BYTE) (bMIDI + nSemitone);
}
return bMIDI;
}
DWORD ShiftScale(DWORD dwScale, char chRoot)
{
while (chRoot < 0) chRoot += 12;
while (chRoot > 11) chRoot -= 12;
dwScale &= 0xfff;
dwScale <<= chRoot;
dwScale |= (dwScale >> 12);
return dwScale & 0xfff;
}
void ScaleMisses(BYTE bTone, DWORD dwScale, BYTE& rFlats, BYTE& rSharps)
{
// make sure the flats don't underflow the scale
bool fUnderflow = true;
for (int i = 0; i <= bTone; i++)
{
if (dwScale & (1 << i))
{
fUnderflow = false;
break;
}
}
if (fUnderflow)
{
bTone += 12;
}
// make sure the sharps don't overflow the scale
bool fOverflow = true;
for (i = bTone; i < 24; i++)
{
if (dwScale & (1 << i))
{
fOverflow = false;
break;
}
}
if (fOverflow)
{
dwScale |= ((dwScale << 12) & 0xfff000);
}
rFlats = rSharps = 0;
// If this note is in the scale, no need to do any other processing
if ( !(dwScale & (1 << bTone)) )
{
for (i = 0; i <= bTone; i++)
{
if (dwScale & (1 << i))
{
rFlats = 0;
}
else
{
rFlats++;
}
}
for (i = bTone; i < 24; i++)
{
if (dwScale & (1 << i))
{
return;
}
else
{
rSharps++;
}
}
}
}
// Transpose all events in the repeat fragment diatonically, according to the underlying scale given
// in the chord, adjusting all times relative to the the current fragment.
// Return the time of the first note in the transposed fragment.
HRESULT MelodyFragment::TransposeEventList(int nInterval,
CompositionFragment& rfragmentRepeat,
DMUS_CHORD_PARAM& rCurrentChord,
DMUS_CHORD_PARAM& rRealCurrentChord,
BYTE bPlaymode,
DirectMusicPartRef& rPartRef,
TListItem<EventWrapper>*& rpOldEventHead,
TList<EventWrapper>& rNewEventList,
BYTE& rbFirstMIDI,
MUSIC_TIME& rmtFirstTime)
{
DWORD dwScale = ShiftScale(rCurrentChord.dwScale, rCurrentChord.bKey);
DWORD dwChord = ShiftScale(rCurrentChord.SubChordList[0].dwChordPattern, rCurrentChord.SubChordList[0].bChordRoot);
rbFirstMIDI = 0;
rmtFirstTime = 0;
bool fFirstEvent = true;
HRESULT hr = S_OK;
MUSIC_TIME mtElapsed = m_mtTime - rfragmentRepeat.GetTime();
//if (!mtElapsed) mtElapsed = 0; // clamp mtElapsed to non-negative (??)
if (m_dwTransposeIntervals & (1 << nInterval))
{
rNewEventList.CleanUp();
// Find the corresponding part in the repeat fragment
TListItem<DirectMusicPartRef>* pPartRef = rfragmentRepeat.m_pPattern->m_PartRefList.GetHead();
int nParts = rfragmentRepeat.m_pPattern->m_PartRefList.GetCount();
for (int i = 0; pPartRef != NULL; pPartRef = pPartRef->GetNext(), i++)
{
if (pPartRef->GetItemValue().m_dwLogicalPartID == rPartRef.m_dwLogicalPartID) break;
}
if (i < nParts)
{
TListItem<EventWrapper>* pScan = rfragmentRepeat.GetEventHead(i);
rpOldEventHead = pScan;
for (; pScan && SUCCEEDED(hr); pScan = pScan->GetNext())
{
EventWrapper ScanEvent = pScan->GetItemValue();
TListItem<EventWrapper>* pEventItem = new TListItem<EventWrapper>;
if (!pEventItem) hr = E_OUTOFMEMORY;
else
{
EventWrapper& rEvent = pEventItem->GetItemValue();
rEvent.m_mtTime = ScanEvent.m_mtTime + mtElapsed;
rEvent.m_bMIDI = TransposeNote(ScanEvent.m_bMIDI, nInterval, rCurrentChord);
BYTE bTone = (BYTE) (rEvent.m_bMIDI % 12);
ScaleMisses(bTone, dwScale, rEvent.m_bScaleFlat, rEvent.m_bScaleSharp);
ScaleMisses(bTone, dwChord, rEvent.m_bChordFlat, rEvent.m_bChordSharp);
hr = rPartRef.ConvertMIDIValue(rEvent.m_bMIDI,
rRealCurrentChord,
bPlaymode,
NULL,
rEvent.m_wMusic);
if (FAILED(rEvent.m_wMusic))
{
rEvent.m_wMusic = 0;
}
rEvent.m_bPlaymode = bPlaymode;
rEvent.m_pEvent = ScanEvent.m_pEvent;
rEvent.m_dwPChannel = ScanEvent.m_dwPChannel;
rNewEventList.AddHead(pEventItem);
if (fFirstEvent || rEvent.m_mtTime < rmtFirstTime)
{
rmtFirstTime = rEvent.m_mtTime;
rbFirstMIDI = rEvent.m_bMIDI;
fFirstEvent = false;
}
}
}
if (SUCCEEDED(hr))
{
rNewEventList.MergeSort(Greater);
}
}
else hr = E_FAIL;
}
else hr = E_FAIL;
return hr;
}
HRESULT MelodyFragment::TestHarmonicConstraints(TListItem<EventWrapper>* pOldEventHead,
TList<EventWrapper>& rNewEventList)
{
HRESULT hr = S_OK;
TListItem<EventWrapper>* pOldScan = pOldEventHead;
TListItem<EventWrapper>* pNewScan = rNewEventList.GetHead();
for (; pOldScan && pNewScan && SUCCEEDED(hr); pOldScan = pOldScan->GetNext(), pNewScan = pNewScan->GetNext())
{
EventWrapper& rOldEvent = pOldScan->GetItemValue();
EventWrapper& rNewEvent = pNewScan->GetItemValue();
BYTE bOldFlats, bOldSharps, bNewFlats, bNewSharps;
if (m_dwFragmentFlags & DMUS_FRAGMENTF_CHORD)
{
bOldFlats = rOldEvent.m_bChordFlat;
bOldSharps = rOldEvent.m_bChordSharp;
bNewFlats = rNewEvent.m_bChordFlat;
bNewSharps = rNewEvent.m_bChordSharp;
}
else if (m_dwFragmentFlags & DMUS_FRAGMENTF_SCALE)
{
bOldFlats = rOldEvent.m_bScaleFlat;
bOldSharps = rOldEvent.m_bScaleSharp;
bNewFlats = rNewEvent.m_bScaleFlat;
bNewSharps = rNewEvent.m_bScaleSharp;
}
else // something's wrong
{
hr = E_FAIL;
break;
}
if (bOldFlats != bNewFlats && bOldSharps != bNewSharps)
{
hr = E_FAIL;
break;
}
}
return hr;
}
HRESULT MelodyFragment::GetRepeatedEvents(CompositionFragment& rfragmentRepeat,
DMUS_CHORD_PARAM& rCurrentChord,
DMUS_CHORD_PARAM& rRealCurrentChord,
BYTE bPlaymode,
int nPartIndex,
DirectMusicPartRef& rPartRef,
TListItem<CompositionFragment>* pLastFragment,
MUSIC_TIME& rmtFirstNote,
TList<EventWrapper>& rEventList)
{
HRESULT hr = E_FAIL;
BYTE bMIDI = 0;
TListItem<EventWrapper>* pOldEventHead;
// For each transposition interval (unison is always the first interval tested):
for (int i = 0; i < MAX_INTERVAL; i++)
{
if (SUCCEEDED(TransposeEventList(i, rfragmentRepeat, rCurrentChord, rRealCurrentChord, bPlaymode, rPartRef, pOldEventHead, rEventList, bMIDI, rmtFirstNote)))
{
// Test transposed notes against harmonic constraints
if (SUCCEEDED(TestHarmonicConstraints(pOldEventHead, rEventList)))
{
// Test transposed notes against transition constraints (assuming there are any)
// (note: eventually this test may be allowed to add transition notes as appropriate)
// If there are no transition constraints, don't bother to test them.
if (!pLastFragment ||
!pLastFragment->GetItemValue().UsesTransitionRules())
{
hr = S_OK;
break;
}
if (S_OK == TestTransition(bMIDI, rmtFirstNote, rCurrentChord, nPartIndex, rPartRef, pLastFragment))
{
hr = S_OK;
break;
}
}
}
}
// If no interval satisfies both constraints, fail.
if (FAILED(hr)) rEventList.CleanUp();
return hr;
}
// this should ensure, if possible, that the selected variations
// work for all chords from the current one to mtNext
HRESULT MelodyFragment::GetVariations(CompositionFragment& rCompFragment,
CompositionFragment& rfragmentRepeat,
CompositionFragment& rfragmentLast,
DMUS_CHORD_PARAM& rCurrentChord,
DMUS_CHORD_PARAM& rNextChord,
MUSIC_TIME mtNextChord,
TListItem<CompositionFragment>* pLastFragment)
{
DWORD* adwVariationMask = NULL;
DWORD* adwRemoveVariations = NULL;
static BYTE abVariationGroups[MAX_VARIATION_LOCKS];
DWORD dwVariationFlags = 0;
CDirectMusicPattern* pPattern = NULL;
if (m_dwFragmentFlags & DMUS_FRAGMENTF_USE_REPEAT)
{
dwVariationFlags = rfragmentRepeat.GetVariationFlags();
pPattern = rfragmentRepeat.m_pPattern;
int nParts = rfragmentRepeat.m_pPattern->m_PartRefList.GetCount();
adwVariationMask = new DWORD[nParts];
adwRemoveVariations = new DWORD[nParts];
if (!adwVariationMask || !adwRemoveVariations)
{
return E_OUTOFMEMORY;
}
for (int i = 0; i < nParts; i++)
{
adwRemoveVariations[i] = 0;
}
if (m_dwFragmentFlags & DMUS_FRAGMENTF_REJECT_REPEAT)
{
// any variation but the one previously selected (for all parts)
for (int i = 0; i < nParts; i++)
{
adwVariationMask[i] = dwVariationFlags ^ (1 << rfragmentLast.m_abVariations[i]);
}
}
else
{
// only the variation previously selected (for all parts)
for (int i = 0; i < nParts; i++)
{
adwVariationMask[i] = dwVariationFlags & (1 << rfragmentLast.m_abVariations[i]);
}
}
}
else
{
pPattern = rCompFragment.m_pPattern;
int nParts = rCompFragment.m_pPattern->m_PartRefList.GetCount();
adwVariationMask = new DWORD[nParts];
if (!adwVariationMask)
{
return E_OUTOFMEMORY;
}
adwRemoveVariations = new DWORD[nParts];
if (!adwRemoveVariations)
{
delete [] adwVariationMask;
return E_OUTOFMEMORY;
}
for (int i = 0; i < nParts; i++)
{
adwRemoveVariations[i] = 0;
}
if (m_dwFragmentFlags & DMUS_FRAGMENTF_USE_LABEL)
{
delete [] adwVariationMask;
delete [] adwRemoveVariations;
return E_NOTIMPL;
}
else
{
for (int i = 0; i < nParts; i++)
{
adwVariationMask[i] = rCompFragment.GetVariationFlags();
}
}
}
// filter variations according to transition constraints
if (pLastFragment && pLastFragment->GetItemValue().UsesTransitionRules())
{
TListItem<DirectMusicPartRef>* pPartRef = rCompFragment.m_pPattern->m_PartRefList.GetHead();
for (int i = 0; pPartRef != NULL; pPartRef = pPartRef->GetNext(), i++)
{
DWORD dwOriginalMask = adwVariationMask[i];
//int nPart = pPartRef->GetItemValue().m_wLogicalPartID;
for (int nVar = 0; nVar < 32; nVar++)
{
if ( adwVariationMask[i] & (1 << nVar) )
{
// get the first note of the variation
BYTE bMIDI = 0;
MUSIC_TIME mtNote = 0;
HRESULT hrFirst = GetFirstNote(nVar, rCurrentChord, rCompFragment, pPartRef->GetItemValue(), bMIDI, mtNote);
// if this variation doesn't meet the constraints, remove it from the mask
if ( SUCCEEDED(hrFirst) &&
S_OK != TestTransition(bMIDI, mtNote, rCurrentChord, i, pPartRef->GetItemValue(), pLastFragment) )
{
adwVariationMask[i] &= ~(1 << nVar);
}
}
}
// If none of the variations meet all the constraints, fall back to the original mask
if (!adwVariationMask[i]) adwVariationMask[i] = dwOriginalMask;
}
}
DWORD dwFlags = (COMPUTE_VARIATIONSF_USE_MASK | COMPUTE_VARIATIONSF_NEW_PATTERN | COMPUTE_VARIATIONSF_DX8);
HRESULT hr = pPattern->ComputeVariations(dwFlags,
rCurrentChord,
rNextChord,
abVariationGroups,
adwVariationMask,
adwRemoveVariations,
rCompFragment.m_abVariations,
m_mtTime,
mtNextChord);
if (adwVariationMask) delete [] adwVariationMask;
if (adwRemoveVariations) delete [] adwRemoveVariations;
return hr;
}
HRESULT MelodyFragment::GetFirstNote(int nVariation,
DMUS_CHORD_PARAM& rCurrentChord,
CompositionFragment& rCompFragment,
DirectMusicPartRef& rPartRef,
BYTE& rbMidi,
MUSIC_TIME& rmtNote)
{
HRESULT hr = S_OK;
DirectMusicPart* pPart = rPartRef.m_pDMPart;
DirectMusicTimeSig& TimeSig = rCompFragment.GetTimeSig(pPart);
CDirectMusicEventItem* pEvent = pPart->EventList.GetHead();
bool fFoundNote = false;
for (; pEvent; pEvent = pEvent->GetNext())
{
if ( pEvent->m_dwVariation & (1 << nVariation) )
{
if (pEvent->m_dwEventTag == DMUS_EVENT_NOTE)
{
MUSIC_TIME mtNow = GetTime() +
TimeSig.GridToClocks(pEvent->m_nGridStart) + pEvent->m_nTimeOffset;
if (!fFoundNote || mtNow < rmtNote)
{
hr = GetNote(pEvent, rCurrentChord, rPartRef, rbMidi);
if (SUCCEEDED(hr))
{
fFoundNote = true;
rmtNote = mtNow;
}
}
}
}
}
if (!fFoundNote) hr = S_FALSE;
return hr;
}
HRESULT MelodyFragment::GetNote(CDirectMusicEventItem* pEvent,
DMUS_CHORD_PARAM& rCurrentChord,
DirectMusicPartRef& rPartRef,
BYTE& rbMidi)
{
HRESULT hr = S_OK;
// only process note events
CDMStyleNote* pNoteEvent = NULL;
if (pEvent->m_dwEventTag == DMUS_EVENT_NOTE) // we have a note event
{
pNoteEvent = (CDMStyleNote*)pEvent;
// get a playmode (either from the note or from the melody fragment)
BYTE bPlaymode = (BYTE) m_dwPlayModeFlags;
short nMidiOffset = 0;
if (bPlaymode == DMUS_PLAYMODE_NONE)
{
bPlaymode =
(pNoteEvent->m_bPlayModeFlags & DMUS_PLAYMODE_NONE) ?
rPartRef.m_pDMPart->m_bPlayModeFlags :
pNoteEvent->m_bPlayModeFlags;
}
// generate a MIDI value from the melody note, fragment, chord, and playmode
HRESULT hrTest = rPartRef.ConvertMusicValue(pNoteEvent,
rCurrentChord,
bPlaymode,
FALSE,
m_aInversionGroups,
NULL,
rbMidi,
nMidiOffset);
}
else
{
hr = S_FALSE;
}
return hr;
}
HRESULT MelodyFragment::GetEvent(CDirectMusicEventItem* pEvent,
DMUS_CHORD_PARAM& rCurrentChord,
DMUS_CHORD_PARAM& rRealCurrentChord,
MUSIC_TIME mtNow,
DirectMusicPartRef& rPartRef,
TListItem<EventWrapper>*& rpEventItem)
{
DWORD dwScale = ShiftScale(rCurrentChord.dwScale, rCurrentChord.bKey);
DWORD dwChord = ShiftScale(rCurrentChord.SubChordList[0].dwChordPattern, rCurrentChord.SubChordList[0].bChordRoot);
HRESULT hr = S_OK;
// only process note events
CDMStyleNote* pNoteEvent = NULL;
if (pEvent->m_dwEventTag == DMUS_EVENT_NOTE) // we have a note event
{
pNoteEvent = (CDMStyleNote*)pEvent;
// get a playmode (either from the note or from the melody fragment)
BYTE bPlaymode = (BYTE) m_dwPlayModeFlags;
BYTE bMIDI = 0;
WORD wMusic = 0;
short nMidiOffset = 0;
if (bPlaymode == DMUS_PLAYMODE_NONE)
{
bPlaymode =
(pNoteEvent->m_bPlayModeFlags & DMUS_PLAYMODE_NONE) ?
rPartRef.m_pDMPart->m_bPlayModeFlags :
pNoteEvent->m_bPlayModeFlags;
}
// generate a MIDI value from the melody note, fragment, chord, and playmode
HRESULT hrTest = rPartRef.ConvertMusicValue(pNoteEvent,
rCurrentChord,
bPlaymode,
FALSE,
m_aInversionGroups,
NULL,
bMIDI,
nMidiOffset);
if (SUCCEEDED(hrTest))
{
hrTest = rPartRef.ConvertMIDIValue(bMIDI,
rRealCurrentChord,
bPlaymode,
NULL,
wMusic);
}
if (FAILED(hrTest)) hr = hrTest;
else
{
rpEventItem = new TListItem<EventWrapper>;
if (!rpEventItem) hr = E_OUTOFMEMORY;
else
{
EventWrapper& rEvent = rpEventItem->GetItemValue();
rEvent.m_mtTime = mtNow - pNoteEvent->m_nTimeOffset; // remove the offset (it's in m_nTimeOffset)
rEvent.m_bMIDI = bMIDI;
BYTE bTone = (BYTE) (bMIDI % 12);
ScaleMisses(bTone, dwScale, rEvent.m_bScaleFlat, rEvent.m_bScaleSharp);
ScaleMisses(bTone, dwChord, rEvent.m_bChordFlat, rEvent.m_bChordSharp);
rEvent.m_wMusic = wMusic;
rEvent.m_pEvent = pNoteEvent;
rEvent.m_dwPChannel = rPartRef.m_dwLogicalPartID;
rEvent.m_bPlaymode = bPlaymode;
}
}
}
else
{
hr = S_FALSE;
}
return hr;
}
// IDirectMusicTrack8 Methods
// For consistency with other track types
STDMETHODIMP CMelodyFormulationTrack::GetParamEx(REFGUID rguidType,REFERENCE_TIME rtTime,
REFERENCE_TIME* prtNext,void* pParam,void * pStateData, DWORD dwFlags)
{
HRESULT hr;
MUSIC_TIME mtNext;
hr = GetParam(rguidType,(MUSIC_TIME) rtTime, &mtNext, pParam);
if (prtNext)
{
*prtNext = mtNext;
}
return hr;
}
// For consistency with other track types
STDMETHODIMP CMelodyFormulationTrack::SetParamEx(REFGUID rguidType,REFERENCE_TIME rtTime,
void* pParam, void * pStateData, DWORD dwFlags)
{
return SetParam(rguidType, (MUSIC_TIME) rtTime , pParam);
}
// For consistency with other track types
STDMETHODIMP CMelodyFormulationTrack::PlayEx(void* pStateData,REFERENCE_TIME rtStart,
REFERENCE_TIME rtEnd,REFERENCE_TIME rtOffset,
DWORD dwFlags,IDirectMusicPerformance* pPerf,
IDirectMusicSegmentState* pSegSt,DWORD dwVirtualID)
{
V_INAME(IDirectMusicTrack::PlayEx);
V_INTERFACE(pPerf);
V_INTERFACE(pSegSt);
HRESULT hr;
EnterCriticalSection(&m_CriticalSection);
hr = Play(pStateData, (MUSIC_TIME)rtStart, (MUSIC_TIME)rtEnd,
(MUSIC_TIME)rtOffset, dwFlags, pPerf, pSegSt, dwVirtualID);
LeaveCriticalSection(&m_CriticalSection);
return hr;
}
STDMETHODIMP CMelodyFormulationTrack::Compose(
IUnknown* pContext,
DWORD dwTrackGroup,
IDirectMusicTrack** ppResultTrack)
{
V_INAME(Compose)
V_INTERFACE(pContext);
V_PTRPTR_WRITE(ppResultTrack);
EnterCriticalSection(&m_CriticalSection);
HRESULT hr = S_OK;
IDirectMusicTrack* pPatternTrack = NULL;
IDirectMusicStyle* pStyle = NULL;
IDMStyle* pDMStyle = NULL;
MUSIC_TIME mtLength = 0;
IDirectMusicSegment* pTempSeg = NULL;
IDirectMusicSong* pSong = NULL;
if (FAILED(pContext->QueryInterface(IID_IDirectMusicSegment, (void**)&pTempSeg)))
{
if (FAILED(pContext->QueryInterface(IID_IDirectMusicSong, (void**)&pSong)))
{
hr = E_INVALIDARG;
goto ON_END;
}
}
if (pTempSeg)
{
if (FAILED(hr = pTempSeg->GetParam(GUID_IDirectMusicStyle, dwTrackGroup, 0, 0, NULL, (void*)&pStyle))) goto ON_END;
if (FAILED(hr = pTempSeg->GetLength(&mtLength))) goto ON_END;
}
else if (pSong)
{
MUSIC_TIME mtNow = 0;
MUSIC_TIME mtNext = 0;
while (FAILED(hr = pSong->GetParam(GUID_IDirectMusicStyle, dwTrackGroup, 0, mtNow, &mtNext, (void*)&pStyle)))
{
if (mtNext <= 0) goto ON_END;
mtNow = mtNext;
}
//if (FAILED(hr = pSong->GetParam(GUID_IDirectMusicStyle, dwTrackGroup, 0, 0, NULL, (void*)&pStyle))) goto ON_END;
IDirectMusicSegment* pSeg = NULL;
DWORD dwSeg = 0;
while (S_OK == hr)
{
if (FAILED(hr = pSong->EnumSegment(dwSeg, &pSeg))) goto ON_END;
if (hr == S_OK)
{
MUSIC_TIME mt = 0;
hr = pSeg->GetLength(&mt);
if (FAILED(hr)) goto ON_END;
mtLength += mt;
pSeg->Release();
pSeg = NULL;
dwSeg++;
}
}
}
// Using chord track, style, and melgen track, create a pattern track
hr = pStyle->QueryInterface(IID_IDMStyle, (void**)&pDMStyle);
if (SUCCEEDED(hr))
{
hr = pDMStyle->GenerateTrack(pTempSeg, pSong, dwTrackGroup, pStyle, this, mtLength, pPatternTrack);
if (SUCCEEDED(hr))
{
*ppResultTrack = pPatternTrack;
}
pDMStyle->Release();
}
ON_END:
// Release from Addref in GetStyle
if (pStyle) pStyle->Release();
if (pSong) pSong->Release();
if (pTempSeg) pTempSeg->Release();
LeaveCriticalSection(&m_CriticalSection);
return hr;
}
// if ppResultTrack is NULL, add pNewTrack to the end of the current track;
// otherwise, create a copy of the current track and add pNewTrack to the end of the copy.
// The new track starts at mtJoin, so get rid of everything before that in the current
// track (or its clone). If cloning, simply clone to mtJoin.
STDMETHODIMP CMelodyFormulationTrack::Join(
IDirectMusicTrack* pNewTrack,
MUSIC_TIME mtJoin,
IUnknown* pContext,
DWORD dwTrackGroup,
IDirectMusicTrack** ppResultTrack)
{
V_INAME(IDirectMusicTrack::Join);
V_INTERFACE(pNewTrack);
V_PTRPTR_WRITE_OPT(ppResultTrack);
HRESULT hr = S_OK;
EnterCriticalSection(&m_CriticalSection);
TList<DMUS_MELODY_FRAGMENT> ResultList;
CMelodyFormulationTrack* pResultTrack = NULL;
DWORD dwMaxID = 0;
if (ppResultTrack)
{
hr = Clone(0, mtJoin, ppResultTrack);
pResultTrack = (CMelodyFormulationTrack*)*ppResultTrack;
while(!pResultTrack->m_FragmentList.IsEmpty())
{
ResultList.AddHead(pResultTrack->m_FragmentList.RemoveHead());
DWORD dwThis = ResultList.GetHead()->GetItemValue().dwID;
if (dwThis > dwMaxID) dwMaxID = dwThis;
}
}
else
{
pResultTrack = this;
while(!m_FragmentList.IsEmpty() &&
m_FragmentList.GetHead()->GetItemValue().mtTime < mtJoin)
{
ResultList.AddHead(m_FragmentList.RemoveHead());
DWORD dwThis = ResultList.GetHead()->GetItemValue().dwID;
if (dwThis > dwMaxID) dwMaxID = dwThis;
}
m_FragmentList.CleanUp();
}
CMelodyFormulationTrack* pOtherTrack = (CMelodyFormulationTrack*)pNewTrack;
TListItem<DMUS_MELODY_FRAGMENT>* pScan = pOtherTrack->m_FragmentList.GetHead();
for (; pScan; pScan = pScan->GetNext())
{
TListItem<DMUS_MELODY_FRAGMENT>* pNew = new TListItem<DMUS_MELODY_FRAGMENT>(pScan->GetItemValue());
if (pNew)
{
DMUS_MELODY_FRAGMENT& rNew = pNew->GetItemValue();
rNew.mtTime += mtJoin;
rNew.dwID += dwMaxID;
if (rNew.dwRepeatFragmentID &&
(rNew.dwFragmentFlags & (DMUS_FRAGMENTF_USE_REPEAT | DMUS_FRAGMENTF_REJECT_REPEAT)) )
{
rNew.dwRepeatFragmentID += dwMaxID;
}
ResultList.AddHead(pNew);
}
else
{
ResultList.CleanUp();
hr = E_OUTOFMEMORY;
break;
}
}
if (SUCCEEDED(hr))
{
pResultTrack->m_FragmentList.CleanUp();
while(!ResultList.IsEmpty() )
{
pResultTrack->m_FragmentList.AddHead(ResultList.RemoveHead());
}
}
LeaveCriticalSection(&m_CriticalSection);
return hr;
}