// Velocity.cpp : Implementation of CVelocityTool // // Copyright (C) 2000 Microsoft Corporation. All Rights Reserved // #include "dmusicc.h" #include "dmusici.h" #include "debug.h" #include "velocity.h" #include "toolhelp.h" CVelocityTool::CVelocityTool() { ParamInfo Params[DMUS_VELOCITY_PARAMCOUNT] = { { DMUS_VELOCITY_STRENGTH, MPT_INT,MP_CAPS_ALL,0,100,100, L"Percent",L"Strength",NULL }, // Strength - 100% by default { DMUS_VELOCITY_LOWLIMIT, MPT_INT,MP_CAPS_ALL,1,127,1, L"Velocity",L"Lower Limit",NULL }, // Lower limit - 1 by default { DMUS_VELOCITY_HIGHLIMIT, MPT_INT,MP_CAPS_ALL,1,127,127, L"Velocity",L"Upper Limit",NULL }, // Upper limit - 127 by default { DMUS_VELOCITY_CURVESTART, MPT_INT,MP_CAPS_ALL,1,127,1, L"Velocity",L"Curve Start",NULL }, // Curve start - 1 by default { DMUS_VELOCITY_CURVEEND, MPT_INT,MP_CAPS_ALL,1,127,127, L"Velocity",L"Curve End",NULL }, // Curve End - 127 by default }; InitParams(DMUS_VELOCITY_PARAMCOUNT,Params); m_fMusicTime = TRUE; // override default setting. } STDMETHODIMP_(ULONG) CVelocityTool::AddRef() { return InterlockedIncrement(&m_cRef); } STDMETHODIMP_(ULONG) CVelocityTool::Release() { if( 0 == InterlockedDecrement(&m_cRef) ) { delete this; return 0; } return m_cRef; } STDMETHODIMP CVelocityTool::QueryInterface(const IID &iid, void **ppv) { if (iid == IID_IUnknown || iid == IID_IDirectMusicTool || iid == IID_IDirectMusicTool8) { *ppv = static_cast(this); } else if(iid == IID_IPersistStream) { *ppv = static_cast(this); } else if(iid == IID_IDirectMusicVelocityTool) { *ppv = static_cast(this); } else if(iid == IID_IMediaParams) { *ppv = static_cast(this); } else if(iid == IID_IMediaParamInfo) { *ppv = static_cast(this); } else if(iid == IID_ISpecifyPropertyPages) { *ppv = static_cast(this); } else { *ppv = NULL; return E_NOINTERFACE; } AddRef(); return S_OK; } ////////////////////////////////////////////////////////////////////// // IPersistStream STDMETHODIMP CVelocityTool::GetClassID(CLSID* pClassID) { if (pClassID) { *pClassID = CLSID_DirectMusicVelocityTool; return S_OK; } return E_POINTER; } ////////////////////////////////////////////////////////////////////// // IPersistStream Methods: STDMETHODIMP CVelocityTool::IsDirty() { if (m_fDirty) return S_OK; else return S_FALSE; } STDMETHODIMP CVelocityTool::Load(IStream* pStream) { EnterCriticalSection(&m_CrSec); DWORD dwChunkID; DWORD dwSize; HRESULT hr = pStream->Read(&dwChunkID, sizeof(dwChunkID), NULL); hr = pStream->Read(&dwSize, sizeof(dwSize), NULL); if(SUCCEEDED(hr) && (dwChunkID == FOURCC_VELOCITY_CHUNK)) { DMUS_IO_VELOCITY_HEADER Header; memset(&Header,0,sizeof(Header)); hr = pStream->Read(&Header, min(sizeof(Header),dwSize), NULL); if (SUCCEEDED(hr)) { SetParam(DMUS_VELOCITY_STRENGTH,(float) Header.lStrength); SetParam(DMUS_VELOCITY_LOWLIMIT,(float) Header.lLowLimit); SetParam(DMUS_VELOCITY_HIGHLIMIT,(float) Header.lHighLimit); SetParam(DMUS_VELOCITY_CURVESTART,(float) Header.lCurveStart); SetParam(DMUS_VELOCITY_CURVEEND,(float) Header.lCurveEnd); } } m_fDirty = FALSE; LeaveCriticalSection(&m_CrSec); return hr; } STDMETHODIMP CVelocityTool::Save(IStream* pStream, BOOL fClearDirty) { EnterCriticalSection(&m_CrSec); DWORD dwChunkID = FOURCC_VELOCITY_CHUNK; DWORD dwSize = sizeof(DMUS_IO_VELOCITY_HEADER); HRESULT hr = pStream->Write(&dwChunkID, sizeof(dwChunkID), NULL); if (SUCCEEDED(hr)) { hr = pStream->Write(&dwSize, sizeof(dwSize), NULL); } if (SUCCEEDED(hr)) { DMUS_IO_VELOCITY_HEADER Header; GetParamInt(DMUS_VELOCITY_STRENGTH,MAX_REF_TIME,&Header.lStrength); GetParamInt(DMUS_VELOCITY_LOWLIMIT,MAX_REF_TIME,&Header.lLowLimit); GetParamInt(DMUS_VELOCITY_HIGHLIMIT,MAX_REF_TIME,&Header.lHighLimit); GetParamInt(DMUS_VELOCITY_CURVESTART,MAX_REF_TIME,&Header.lCurveStart); GetParamInt(DMUS_VELOCITY_CURVEEND,MAX_REF_TIME,&Header.lCurveEnd); hr = pStream->Write(&Header, sizeof(Header),NULL); } if (fClearDirty) m_fDirty = FALSE; LeaveCriticalSection(&m_CrSec); return hr; } STDMETHODIMP CVelocityTool::GetSizeMax(ULARGE_INTEGER* pcbSize) { if (pcbSize == NULL) { return E_POINTER; } pcbSize->QuadPart = sizeof(DMUS_IO_VELOCITY_HEADER) + 8; // Data plus RIFF header. return S_OK; } STDMETHODIMP CVelocityTool::GetPages(CAUUID * pPages) { pPages->cElems = 1; pPages->pElems = (GUID *) CoTaskMemAlloc(sizeof(GUID)); if (pPages->pElems == NULL) return E_OUTOFMEMORY; *(pPages->pElems) = CLSID_VelocityPage; return NOERROR; } ///////////////////////////////////////////////////////////////// // IDirectMusicTool STDMETHODIMP CVelocityTool::ProcessPMsg( IDirectMusicPerformance* pPerf, DMUS_PMSG* pPMsg ) { // returning S_FREE frees the message. If StampPMsg() // fails, there is no destination for this message so // free it. if(NULL == pPMsg->pGraph ) { return DMUS_S_FREE; } if (FAILED(pPMsg->pGraph->StampPMsg(pPMsg))) { return DMUS_S_FREE; } // We need to know the time format so we can call GetParamInt() to read control parameters. REFERENCE_TIME rtTime; if (m_fMusicTime) rtTime = pPMsg->mtTime; else rtTime = pPMsg->rtTime; if( pPMsg->dwType == DMUS_PMSGT_NOTE ) { DMUS_NOTE_PMSG *pNote = (DMUS_NOTE_PMSG *) pPMsg; long lStrength; long lLowLimit, lHighLimit, lCurveStart, lCurveEnd; GetParamInt(DMUS_VELOCITY_STRENGTH,rtTime,&lStrength); GetParamInt(DMUS_VELOCITY_LOWLIMIT,rtTime,&lLowLimit); GetParamInt(DMUS_VELOCITY_HIGHLIMIT,rtTime,&lHighLimit); GetParamInt(DMUS_VELOCITY_CURVESTART,rtTime,&lCurveStart); GetParamInt(DMUS_VELOCITY_CURVEEND,rtTime,&lCurveEnd); if (lCurveStart <= lCurveEnd) { long lNewVelocity; if (pNote->bVelocity <= lCurveStart) { lNewVelocity = lLowLimit; } else if (pNote->bVelocity >= lCurveEnd) { lNewVelocity = lHighLimit; } else { // For this case, compute the point on the line between (lCurveStart, lLowLimit) and (lCurveEnd, lHighLimit) lNewVelocity = lLowLimit + ((lHighLimit - lLowLimit) * (pNote->bVelocity - lCurveStart)) / (lCurveEnd - lCurveStart); } // Now, calculate the change we want to apply. lNewVelocity -= pNote->bVelocity; // Scale it to the amount we'll actually do. lNewVelocity = (lNewVelocity * lStrength) / 100; lNewVelocity += pNote->bVelocity; if (lNewVelocity < 1) lNewVelocity = 1; if (lNewVelocity > 127) lNewVelocity = 127; pNote->bVelocity = (BYTE) lNewVelocity; } } return DMUS_S_REQUEUE; } STDMETHODIMP CVelocityTool::Clone( IDirectMusicTool ** ppTool) { CVelocityTool *pNew = new CVelocityTool; if (pNew) { HRESULT hr = pNew->CopyParamsFromSource(this); if (SUCCEEDED(hr)) { *ppTool = (IDirectMusicTool *) pNew; } else { delete pNew; } return hr; } else { return E_OUTOFMEMORY; } } STDMETHODIMP CVelocityTool::SetStrength(long lStrength) { return SetParam(DMUS_VELOCITY_STRENGTH,(float) lStrength); } STDMETHODIMP CVelocityTool::SetLowLimit(long lVelocityOut) { return SetParam(DMUS_VELOCITY_LOWLIMIT,(float) lVelocityOut); } STDMETHODIMP CVelocityTool::SetHighLimit(long lVelocityOut) { return SetParam(DMUS_VELOCITY_HIGHLIMIT,(float) lVelocityOut); } STDMETHODIMP CVelocityTool::SetCurveStart(long lVelocityIn) { return SetParam(DMUS_VELOCITY_CURVESTART,(float) lVelocityIn); } STDMETHODIMP CVelocityTool::SetCurveEnd(long lVelocityIn) { return SetParam(DMUS_VELOCITY_CURVEEND,(float) lVelocityIn); } STDMETHODIMP CVelocityTool::GetStrength(long * plStrength) { return GetParamInt(DMUS_VELOCITY_STRENGTH,MAX_REF_TIME,plStrength); } STDMETHODIMP CVelocityTool::GetLowLimit(long * plVelocityOut) { return GetParamInt(DMUS_VELOCITY_LOWLIMIT,MAX_REF_TIME,plVelocityOut); } STDMETHODIMP CVelocityTool::GetHighLimit(long * plVelocityOut) { return GetParamInt(DMUS_VELOCITY_HIGHLIMIT,MAX_REF_TIME,plVelocityOut); } STDMETHODIMP CVelocityTool::GetCurveStart(long * plVelocityIn) { return GetParamInt(DMUS_VELOCITY_CURVESTART,MAX_REF_TIME,plVelocityIn); } STDMETHODIMP CVelocityTool::GetCurveEnd(long * plVelocityIn) { return GetParamInt(DMUS_VELOCITY_CURVEEND,MAX_REF_TIME,plVelocityIn); }