Source code of Windows XP (NT5)
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/*****************************************************************************
midiemu.c
MIDI support -- routines for stream emulation
Copyright (c) 1990-1999 Microsoft Corporation
*****************************************************************************/
#define INCL_WINMM
#include "winmmi.h"
#include "muldiv32.h"
#define NUM_NOTES (128)
#define NUM_CHANNELS (16)
#define MEMU_CB_NOTEON (NUM_CHANNELS*NUM_NOTES/2) // 16 chan * 128 notes (4 bits/note)
#define MAX_NOTES_ON (0xF)
#define TIMER_OFF (0)
PMIDIEMU gpEmuList = NULL;
UINT guMIDIInTimer = 0;
UINT guMIDITimerID = TIMER_OFF;
BOOL gfMinPeriod = FALSE;
UINT guMIDIPeriodMin;
STATIC HMIDI FAR PASCAL mseIDtoHMidi(
PMIDIEMU pme,
DWORD dwStreamID);
MMRESULT FAR PASCAL mseOpen(
PDWORD_PTR lpdwUser,
LPMIDIOPENDESC lpmod,
DWORD fdwOpen);
MMRESULT FAR PASCAL mseClose(
PMIDIEMU pme);
MMRESULT FAR PASCAL mseProperty(
PMIDIEMU pme,
LPBYTE lpbProp,
DWORD fdwProp);
MMRESULT FAR PASCAL mseGetPosition(
PMIDIEMU pme,
LPMMTIME lpmmt);
MMRESULT FAR PASCAL mseGetVolume(
PMIDIEMU pme,
LPDWORD lpdwVolume);
MMRESULT FAR PASCAL mseSetVolume(
PMIDIEMU pme,
DWORD dwVolume);
MMRESULT FAR PASCAL mseOutStop(
PMIDIEMU pme);
MMRESULT FAR PASCAL mseOutReset(
PMIDIEMU pme);
MMRESULT FAR PASCAL mseOutPause(
PMIDIEMU pme);
MMRESULT FAR PASCAL mseOutRestart(
PMIDIEMU pme,
DWORD msTime,
DWORD tkTime);
MMRESULT FAR PASCAL mseOutCachePatches(
PMIDIEMU pme,
UINT uBank,
LPWORD pwpa,
UINT fuCache);
MMRESULT FAR PASCAL mseOutCacheDrumPatches(
PMIDIEMU pme,
UINT uPatch,
LPWORD pwkya,
UINT fuCache);
DWORD FAR PASCAL mseOutBroadcast(
PMIDIEMU pme,
UINT msg,
DWORD_PTR dwParam1,
DWORD_PTR dwParam2);
DWORD FAR PASCAL mseTimebase(
PCLOCK pclock);
#ifndef WIN32
#pragma alloc_text(FIXMIDI, mseIDtoHMidi)
#pragma alloc_text(FIXMIDI, mseMessage)
#pragma alloc_text(FIXMIDI, mseOutReset)
#pragma alloc_text(FIXMIDI, midiOutScheduleNextEvent)
#pragma alloc_text(FIXMIDI, midiOutPlayNextPolyEvent)
#pragma alloc_text(FIXMIDI, midiOutDequeueAndCallback)
#pragma alloc_text(FIXMIDI, midiOutTimerTick)
#pragma alloc_text(FIXMIDI, midiOutCallback)
#pragma alloc_text(FIXMIDI, midiOutSetClockRate)
#pragma alloc_text(INIT,midiEmulatorInit)
#pragma alloc_text(FIXMIDI, mseTimebase)
#endif
/****************************************************************************/
/****************************************************************************/
INLINE LONG PDEVLOCK(PMIDIEMU pdev)
{
LONG lTemp;
lTemp = InterlockedIncrement(&(pdev->lLockCount));
EnterCriticalSection(&(pdev->CritSec));
return lTemp;
}
INLINE LONG PDEVUNLOCK(PMIDIEMU pdev)
{
LONG lTemp;
lTemp = InterlockedDecrement(&(pdev->lLockCount));
LeaveCriticalSection(&(pdev->CritSec));
return lTemp;
}
/****************************************************************************/
/****************************************************************************/
DWORD FAR PASCAL mseMessage(
UINT msg,
DWORD_PTR dwUser,
DWORD_PTR dwParam1,
DWORD_PTR dwParam2)
{
MMRESULT mmr = MMSYSERR_NOERROR;
PMIDIEMU pme = (PMIDIEMU)dwUser;
switch(msg)
{
case MODM_OPEN:
mmr = mseOpen((PDWORD_PTR)dwUser, (LPMIDIOPENDESC)dwParam1, (DWORD)dwParam2);
break;
case MODM_CLOSE:
mmr = mseClose(pme);
break;
case MODM_GETVOLUME:
mmr = mseGetVolume(pme, (LPDWORD)dwParam1);
break;
case MODM_SETVOLUME:
mmr = mseSetVolume(pme, (DWORD)dwParam1);
break;
case MODM_PREPARE:
case MODM_UNPREPARE:
mmr = MMSYSERR_NOTSUPPORTED;
break;
case MODM_DATA:
//#pragma FIXMSG("How to route async short messages to other stream-ids?")
if (!(dwParam1 & 0x80))
mmr = MIDIERR_BADOPENMODE;
else
mmr = midiOutShortMsg((HMIDIOUT)pme->rIds[0].hMidi, (DWORD)dwParam1);
break;
case MODM_RESET:
mmr = mseOutReset(pme);
break;
case MODM_STOP:
mmr = mseOutStop(pme);
break;
case MODM_CACHEPATCHES:
mmr = mseOutCachePatches(pme, HIWORD(dwParam2), (LPWORD)dwParam1, LOWORD(dwParam2));
break;
case MODM_CACHEDRUMPATCHES:
mmr = mseOutCacheDrumPatches(pme, HIWORD(dwParam2), (LPWORD)dwParam1, LOWORD(dwParam2));
break;
case MODM_PAUSE:
mmr = mseOutPause(pme);
break;
case MODM_RESTART:
mmr = mseOutRestart(pme, (DWORD)dwParam1, (DWORD)dwParam2);
break;
case MODM_STRMDATA:
mmr = mseOutSend(pme, (LPMIDIHDR)dwParam1, (UINT)dwParam2);
break;
case MODM_PROPERTIES:
mmr = mseProperty(pme, (LPBYTE)dwParam1, (DWORD)dwParam2);
break;
case MODM_GETPOS:
mmr = mseGetPosition(pme, (LPMMTIME)dwParam1);
break;
default:
if ((msg < DRVM_IOCTL) ||
(msg >= DRVM_IOCTL_LAST) && (msg < DRVM_MAPPER))
{
dprintf1(("Unknown message [%04X] in MIDI emulator", (WORD)msg));
mmr = MMSYSERR_NOTSUPPORTED;
}
else
mmr = mseOutBroadcast(pme, msg, dwParam1, dwParam2);
}
return mmr;
}
MMRESULT FAR PASCAL mseOpen(
PDWORD_PTR lpdwUser,
LPMIDIOPENDESC lpmod,
DWORD fdwOpen)
{
MMRESULT mmrc = MMSYSERR_NOERROR;
DWORD cbHandle;
PMIDIEMU pme = NULL;
UINT idx;
mmrc = MMSYSERR_NOMEM;
cbHandle = sizeof(MIDIEMU) + lpmod->cIds * ELESIZE(MIDIEMU, rIds[0]);
if (cbHandle >= 65536L)
{
dprintf1(("mSEO: cbHandle >= 64K!"));
goto mseOpen_Cleanup;
}
if (NULL == (pme = (PMIDIEMU)winmmAlloc(cbHandle)))
{
dprintf1(("mSEO: !winmmAlloc(cbHandle)"));
goto mseOpen_Cleanup;
}
if (NULL == (pme->rbNoteOn = winmmAlloc(MEMU_CB_NOTEON)))
{
dprintf1(("mSEO: !GlobalAlloc(MEMU_CB_NOTEON"));
goto mseOpen_Cleanup;
}
pme->fdwDev |= MDV_F_LOCKED;
pme->hStream = (HMIDISTRM)lpmod->hMidi;
pme->dwTimeDiv = DEFAULT_TIMEDIV;
pme->dwTempo = DEFAULT_TEMPO;
pme->dwCallback = lpmod->dwCallback;
pme->dwFlags = fdwOpen;
pme->dwInstance = lpmod->dwInstance;
pme->dwPolyMsgState = PM_STATE_PAUSED;
pme->chMidi = (UINT)lpmod->cIds;
pme->dwSavedState = PM_STATE_STOPPED;
pme->tkPlayed = 0;
pme->lLockCount = -1;
pme->dwSignature = MSE_SIGNATURE;
for (idx = 0; idx < pme->chMidi; idx++)
{
pme->rIds[idx].dwStreamID = lpmod->rgIds[idx].dwStreamID;
mmrc = midiOutOpen((LPHMIDIOUT)&pme->rIds[idx].hMidi,
lpmod->rgIds[idx].uDeviceID,
(DWORD_PTR)midiOutCallback,
0L,
CALLBACK_FUNCTION);
if (MMSYSERR_NOERROR != mmrc)
goto mseOpen_Cleanup;
}
if (!mmInitializeCriticalSection(&pme->CritSec)) {
mmrc = MMSYSERR_NOMEM;
goto mseOpen_Cleanup;
}
clockInit(&pme->clock, 0, 0, mseTimebase);
dprintf2(("midiOutOpen: midiOutSetClockRate()"));
midiOutSetClockRate(pme, 0);
mseOpen_Cleanup:
if (MMSYSERR_NOERROR != mmrc)
{
if (pme)
{
if (pme->rbNoteOn)
{
winmmFree(pme->rbNoteOn);
}
DeleteCriticalSection(&pme->CritSec);
pme->dwSignature = 0L;
for (idx = 0; idx < pme->chMidi; idx++)
if (NULL != pme->rIds[idx].hMidi)
midiOutClose((HMIDIOUT)pme->rIds[idx].hMidi);
winmmFree(pme);
}
}
else
{
pme->pNext = gpEmuList;
gpEmuList = pme;
*lpdwUser = (DWORD_PTR)pme;
}
return mmrc;
}
MMRESULT FAR PASCAL mseClose(
PMIDIEMU pme)
{
UINT idx;
MMRESULT mmrc;
PMIDIEMU pmePrev;
PMIDIEMU pmeCurr;
#ifdef DEBUG
{
dprintf2(("cEvents %lu", pme->cEvents));
for (idx = 0; idx < MEM_MAX_LATENESS; idx++)
dprintf2(("%5u: %u", idx, pme->auLateness[idx]));
}
#endif
if ((PM_STATE_STOPPED != pme->dwPolyMsgState &&
PM_STATE_PAUSED != pme->dwPolyMsgState &&
PM_STATE_EMPTY != pme->dwPolyMsgState))
{
dprintf1(("mseClose: Started playing again since close query!!!"));
mseOutStop(pme);
}
midiOutAllNotesOff(pme);
for (idx = 0; idx < pme->chMidi; idx++)
{
mmrc = midiOutClose((HMIDIOUT)pme->rIds[idx].hMidi);
if (MMSYSERR_NOERROR != mmrc)
{
dprintf1(( "mseClose: HMIDI %04X returned %u for close", pme->rIds[idx].hMidi, mmrc));
}
}
winmmFree(pme->rbNoteOn);
pmePrev = NULL;
pmeCurr = gpEmuList;
while (pmeCurr)
{
if (pmeCurr == pme)
break;
pmePrev = pmeCurr;
pmeCurr = pmeCurr->pNext;
}
if (pmeCurr)
{
if (pmePrev)
pmePrev->pNext = pmeCurr->pNext;
else
gpEmuList = pmeCurr->pNext;
}
//
// Make sure that we don't have the critical section before
// we try to delete it. Otherwise we will leak critical section
// handles in the kernel.
//
while ( pme->lLockCount >= 0 )
{
PDEVUNLOCK( pme );
}
DeleteCriticalSection(&pme->CritSec);
pme->dwSignature = 0L;
winmmFree(pme);
return MMSYSERR_NOERROR;
}
STATIC HMIDI FAR PASCAL mseIDtoHMidi(
PMIDIEMU pme,
DWORD dwStreamID)
{
UINT idx;
PMIDIEMUSID pmesi;
for (idx = 0, pmesi = pme->rIds; idx < pme->chMidi; idx++, pmesi++)
if (pmesi->dwStreamID == dwStreamID)
return pmesi->hMidi;
return NULL;
}
MMRESULT FAR PASCAL mseProperty(
PMIDIEMU pme,
LPBYTE lppropdata,
DWORD fdwProp)
{
PMIDISTRM pms;
pms = (PMIDISTRM)(pme->hStream);
if ((!(fdwProp&MIDIPROP_SET)) && (!(fdwProp&MIDIPROP_GET)))
return MMSYSERR_INVALPARAM;
V_RPOINTER(lppropdata, sizeof(DWORD), MMSYSERR_INVALPARAM);
if (fdwProp & MIDIPROP_SET)
{
V_RPOINTER(lppropdata, (UINT)(*(LPDWORD)(lppropdata)), MMSYSERR_INVALPARAM);
}
else
{
V_WPOINTER(lppropdata, (UINT)(*(LPDWORD)(lppropdata)), MMSYSERR_INVALPARAM);
}
switch(fdwProp & MIDIPROP_PROPVAL)
{
case MIDIPROP_TIMEDIV:
if (((LPMIDIPROPTIMEDIV)lppropdata)->cbStruct < sizeof(MIDIPROPTIMEDIV))
return MMSYSERR_INVALPARAM;
if (fdwProp & MIDIPROP_GET)
{
((LPMIDIPROPTIMEDIV)lppropdata)->dwTimeDiv = pme->dwTimeDiv;
return MMSYSERR_NOERROR;
}
if (PM_STATE_STOPPED != pme->dwPolyMsgState &&
PM_STATE_PAUSED != pme->dwPolyMsgState)
return MMSYSERR_INVALPARAM;
pme->dwTimeDiv = ((LPMIDIPROPTIMEDIV)lppropdata)->dwTimeDiv;
dprintf1(( "dwTimeDiv %08lX", pme->dwTimeDiv));
midiOutSetClockRate(pme, 0);
return MMSYSERR_NOERROR;
case MIDIPROP_TEMPO:
if (((LPMIDIPROPTEMPO)lppropdata)->cbStruct < sizeof(MIDIPROPTEMPO))
return MMSYSERR_INVALPARAM;
if (fdwProp & MIDIPROP_GET)
{
((LPMIDIPROPTEMPO)lppropdata)->dwTempo = pme->dwTempo;
return MMSYSERR_NOERROR;
}
pme->dwTempo = ((LPMIDIPROPTEMPO)lppropdata)->dwTempo;
midiOutSetClockRate(pme, pme->tkPlayed);
return MMSYSERR_NOERROR;
default:
return MMSYSERR_INVALPARAM;
}
}
MMRESULT FAR PASCAL mseGetPosition(
PMIDIEMU pme,
LPMMTIME pmmt)
{
DWORD tkTime;
DWORD dw10Min;
DWORD dw10MinCycle;
DWORD dw1Min;
DWORD dwDropMe;
//
// Figure out position in stream based on emulation.
//
//
// Validate wType parameter and change it if needed.
//
if (pmmt->wType != TIME_TICKS && pmmt->wType != TIME_MS)
{
if (pme->dwTimeDiv & IS_SMPTE)
{
if (pmmt->wType != TIME_SMPTE)
{
pmmt->wType = TIME_MS;
}
}
else
{
if (pmmt->wType != TIME_MIDI)
{
pmmt->wType = TIME_MS;
}
}
}
switch(pmmt->wType)
{
case TIME_TICKS:
//
// We interpret samples to be straight MIDI ticks.
//
tkTime = (DWORD)clockTime(&pme->clock);
pmmt->u.ticks = (((TICKS)tkTime) < 0) ? 0 : tkTime;
break;
case TIME_MIDI:
//
// Song position pointer is number of 1/16th notes we've
// played which we can get from number of ticks played and
// number of 1/4 notes per tick.
//
tkTime = (DWORD)clockTime(&pme->clock);
if (((TICKS)tkTime) < 0)
tkTime = 0;
pmmt->u.midi.songptrpos =
muldiv32(
tkTime,
4,
TICKS_PER_QN(pme->dwTimeDiv));
break;
case TIME_SMPTE:
tkTime = (DWORD)clockTime(&pme->clock);
if (((TICKS)tkTime) < 0)
tkTime = 0;
pmmt->u.smpte.fps = (BYTE)(-SMPTE_FORMAT(pme->dwTimeDiv));
//
// If this has managed to get set to something bizarre, just
// do normal 30 nondrop.
//
if ((pmmt->u.smpte.fps != SMPTE_24) &&
(pmmt->u.smpte.fps != SMPTE_25) &&
(pmmt->u.smpte.fps != SMPTE_30DROP) &&
(pmmt->u.smpte.fps != SMPTE_30))
{
pmmt->u.smpte.fps = SMPTE_30;
}
switch(pmmt->u.smpte.fps)
{
case SMPTE_24:
pmmt->u.smpte.frame = (BYTE)(tkTime%24);
tkTime /= 24;
break;
case SMPTE_25:
pmmt->u.smpte.frame = (BYTE)(tkTime%25);
tkTime /= 25;
break;
case SMPTE_30DROP:
//
// Calculate drop-frame stuff.
//
// We add 2 frames per 1-minute interval except
// on every 10th minute.
//
dw10Min = tkTime/S30D_FRAMES_PER_10MIN;
dw10MinCycle = tkTime%S30D_FRAMES_PER_10MIN;
dw1Min = (dw10MinCycle < 2
? 0 :
(dw10MinCycle-2)/S30D_FRAMES_PER_MIN);
dwDropMe = 18*dw10Min + 2*dw1Min;
tkTime += dwDropMe;
//
// !!! Falling through to 30-nondrop case !!!
//
case SMPTE_30:
pmmt->u.smpte.frame = (BYTE)(tkTime%30);
tkTime /= 30;
break;
}
pmmt->u.smpte.sec = (BYTE)(tkTime%60);
tkTime /= 60;
pmmt->u.smpte.min = (BYTE)(tkTime%60);
tkTime /= 60;
pmmt->u.smpte.hour = (BYTE)(tkTime);
break;
case TIME_MS:
//
// Use msTotal + ms since time parms last updated; this
// takes starvation/paused time into account.
//
pmmt->u.ms =
clockMsTime(&pme->clock);
break;
default:
dprintf1(( "midiOutGetPosition: unexpected wType!!!"));
return MMSYSERR_INVALPARAM;
}
return MMSYSERR_NOERROR;
}
MMRESULT FAR PASCAL mseGetVolume(
PMIDIEMU pme,
LPDWORD lpdwVolume)
{
MMRESULT mmr = MMSYSERR_NOTSUPPORTED;
UINT idx;
// Walk the device list underneath us until someone knows the volume
//
for (idx = 0; idx < pme->chMidi; ++idx)
if (MMSYSERR_NOERROR ==
(midiOutGetVolume((HMIDIOUT)pme->rIds[idx].hMidi, lpdwVolume)))
{
mmr = MMSYSERR_NOERROR;
break;
}
return mmr;
}
MMRESULT FAR PASCAL mseSetVolume(
PMIDIEMU pme,
DWORD dwVolume)
{
MMRESULT mmr = MMSYSERR_NOERROR;
MMRESULT mmr2;
UINT idx;
// Try to set everyone's volume
//
for (idx = 0; idx < pme->chMidi; ++idx)
if (MMSYSERR_NOERROR !=
(mmr2 = midiOutSetVolume((HMIDIOUT)pme->rIds[idx].hMidi, dwVolume)))
mmr = mmr2;
return mmr;
}
MMRESULT FAR PASCAL mseOutReset(
PMIDIEMU pme)
{
LPMIDIHDR lpmh;
LPMIDIHDR lpmhWork;
UINT idx;
MSG msg;
// If we have anything posted to mmtask to be cleaned up, process
// it first
//
while (pme->cPostedBuffers)
{
Sleep(0);
}
//
// If we're running the timer, interrupt and force a reschedule
// of all remaining channels.
//
if (guMIDITimerID != TIMER_OFF)
{
dprintf2(( "mOR: About to take %u", guMIDITimerID));
if (MMSYSERR_NOERROR != timeKillEvent(guMIDITimerID))
{
dprintf1(( "timeKillEvent() failed in midiOutPolyMsg"));
}
else
{
guMIDITimerID = TIMER_OFF;
}
midiOutTimerTick(
guMIDITimerID, // ID of our timer
0, // wMsg is unused
timeGetTime(), // dwUser unused
0L, // dw1 unused
0L); // dw2 unused
dprintf2(( "mOR: mOTT"));
if (gfMinPeriod)
{
gfMinPeriod = FALSE;
timeEndPeriod(guMIDIPeriodMin);
}
}
//
// Kill anything queued for midiOutPolyMsg. This will ensure that
// sending will stop after the current buffer.
//
PDEVLOCK( pme );
lpmh = pme->lpmhFront;
pme->lpmhFront = NULL;
pme->lpmhRear = NULL;
pme->dwPolyMsgState = PM_STATE_EMPTY;
while (lpmh)
{
lpmh->dwFlags &= ~MHDR_INQUEUE;
lpmh->dwFlags |= MHDR_DONE;
lpmhWork = lpmh->lpNext;
dprintf2(( "mOR: Next buffer to nuke %08lx", lpmhWork));
midiOutNukePMBuffer(pme, lpmh);
lpmh = lpmhWork;
}
//
// Check to see if our pme structure is still valid. Someone
// might have called midiStreamClose in their callback and we
// don't want to touch it after it's closed and freed. This
// is what the MidiPlyr sample application does.
//
try
{
if (MSE_SIGNATURE != pme->dwSignature) // must have been freed
return MMSYSERR_NOERROR;
PDEVUNLOCK( pme ); // keep it in try for extra protection
}
except(EXCEPTION_EXECUTE_HANDLER)
{
return MMSYSERR_NOERROR;
}
//
// We've just reset the stream; restart the tick clock at 0 and invalidate
// the time division to force the time stuff to be reset when the next
// polymsg comes in.
//
dprintf2(( "midiOutReset: clockInit()/ midiOutSetClockRate()"));
clockInit(&pme->clock, 0, 0, mseTimebase);
midiOutSetClockRate(pme, 0);
pme->tkPlayed = 0;
// Have a reset party on all the drivers under us
//
for (idx = 0; idx < pme->chMidi; idx++)
midiOutReset((HMIDIOUT)pme->rIds[idx].hMidi);
pme->dwPolyMsgState = PM_STATE_PAUSED;
return MMSYSERR_NOERROR;
}
MMRESULT FAR PASCAL mseOutStop(
PMIDIEMU pme)
{
LPMIDIHDR lpmh;
LPMIDIHDR lpmhWork;
MSG msg;
BOOL fSetEvent = FALSE;
// If we have anything posted to mmtask to be cleaned up, process
// it first
//
while (pme->cPostedBuffers)
{
Sleep(0);
}
//
// If we're running the timer, interrupt and force a reschedule
// of all remaining channels.
//
if (guMIDITimerID != TIMER_OFF)
{
dprintf2(( "mOS: About to take %u", guMIDITimerID));
if (MMSYSERR_NOERROR != timeKillEvent(guMIDITimerID))
{
dprintf1(( "timeKillEvent() failed in midiOutPolyMsg"));
}
else
{
guMIDITimerID = TIMER_OFF;
}
dprintf2(( "mOS: take -- About to mOTT"));
midiOutTimerTick(
guMIDITimerID, // ID of our timer
0, // wMsg is unused
timeGetTime(), // dwUser unused
0L, // dw1 unused
0L); // dw2 unused
dprintf2(( "mOS: mOTT"));
if (gfMinPeriod)
{
gfMinPeriod = FALSE;
timeEndPeriod(guMIDIPeriodMin);
}
}
//
// Kill anything queued for midiOutPolyMsg. This will ensure that
// sending will stop after the current buffer.
//
PDEVLOCK( pme );
lpmh = pme->lpmhFront;
pme->lpmhFront = NULL;
pme->lpmhRear = NULL;
pme->dwPolyMsgState = PM_STATE_EMPTY;
while (lpmh)
{
lpmh->dwFlags &= ~MHDR_INQUEUE;
lpmh->dwFlags |= MHDR_DONE;
lpmhWork = lpmh->lpNext;
dprintf2(( "mOS: Next buffer to nuke %08lx", lpmhWork));
midiOutNukePMBuffer(pme, lpmh);
lpmh = lpmhWork;
}
//
// Check to see if our pme structure is still valid. Someone
// might have called midiStreamClose in their callback and we
// don't want to touch it after it's closed and freed. This
// is what the MidiPlyr sample application does.
//
try
{
if (MSE_SIGNATURE != pme->dwSignature) // must have been freed
return MMSYSERR_NOERROR;
PDEVUNLOCK( pme ); // keep it in try for extra protection
}
except(EXCEPTION_EXECUTE_HANDLER)
{
return MMSYSERR_NOERROR;
}
//
// We've just reset the stream; restart the tick clock at 0 and invalidate
// the time division to force the time stuff to be reset when the next
// polymsg comes in.
//
dprintf2(( "midiOutStop: clockInit()/ midiOutSetClockRate()"));
clockInit(&pme->clock, 0, 0, mseTimebase);
midiOutSetClockRate(pme, 0);
pme->tkPlayed = 0;
//
// In case someone queues up headers during the stop
// operation we want to make sure that all they have to
// do is restart the stream to get started again.
//
mseOutPause(pme);
//midiOutAllNotesOff(pme);
//pme->dwPolyMsgState = PM_STATE_STOPPED;
return MMSYSERR_NOERROR;
}
MMRESULT FAR PASCAL mseOutPause(
PMIDIEMU pme)
{
//
// Emulating on this handle - do the pause ourselves.
//
if (pme->dwPolyMsgState == PM_STATE_PAUSED)
return MMSYSERR_NOERROR;
pme->dwSavedState = pme->dwPolyMsgState;
pme->dwPolyMsgState = PM_STATE_PAUSED;
clockPause(&pme->clock, CLK_TK_NOW);
midiOutAllNotesOff(pme);
return MMSYSERR_NOERROR;
}
MMRESULT FAR PASCAL mseOutRestart(
PMIDIEMU pme,
DWORD msTime,
DWORD tkTime)
{
//
// Emulating on this handle - do the pause ourselves.
//
if (pme->dwPolyMsgState != PM_STATE_PAUSED)
return MMSYSERR_NOERROR;
pme->dwPolyMsgState = pme->dwSavedState;
clockRestart(&pme->clock, tkTime, msTime);
dprintf2(( "restart: state->%lu", pme->dwPolyMsgState));
midiOutTimerTick(
guMIDITimerID, // ID of our timer
0, // wMsg is unused
timeGetTime(),
0L, // dw1 unused
0L); // dw2 unused
return MMSYSERR_NOERROR;
}
/*****************************************************************************
* @doc INTERNAL MIDI
*
* @api void | midiEmulatorInit | This function is called at init time to
* allow MMSYSTEM to initialize anything it needs to for the polymsg
* emulators. Right now, all we do is find the minimum period of the
* timeGetTime clock.
*
* @rdesc Currently always returns MMSYSERR_NOERROR.
****************************************************************************/
#ifdef DEBUG
STATIC SZCODE aszInit[] = "midiEmulatorInit: Using clock res of %lums.";
#endif
void NEAR PASCAL midiEmulatorInit
(
void
)
{
TIMECAPS tc;
if (MMSYSERR_NOERROR != timeGetDevCaps(&tc, sizeof(tc)))
{
dprintf1(( "*** MMSYSTEM IS HORKED ***"));
dprintf1(( "*** timeGetDevCaps failed in midiEmulatorInit ***"));
return;
}
//
// Select the larger of the period we would like to have or
// the minimum period the timer supports.
//
guMIDIPeriodMin = max(MIN_PERIOD, tc.wPeriodMin);
// guMIDIPeriodMin = MIN_PERIOD;
#ifdef DEBUG
dprintf2(( aszInit, (DWORD)guMIDIPeriodMin));
#endif
}
/*****************************************************************************
* @doc EXTERNAL MIDI M4
*
* @api UINT | mseOutSend | Plays or queues a buffer of
* MIDI data to a MIDI output device.
*
* @parm PMIDIEMU | pme | Specifies the stream instance the data should
* go to.
*
* @parm LPMIDIHDR | lpMidiOutHdr | Specifies a far pointer to a <t MIDIHDR>
* structure that identifies the MIDI data buffer.
*
* @parm UINT | cbMidiHdr | Specifies the size of the <t MIDIHDR> structure.
*
* @rdesc The return value is zero if the function is successful. Otherwise,
* it returns an error number. Possible error values include the following:
*
* @flag MMSYSERR_INVALHANDLE | The specified device handle is invalid.
* @flag MMSYSERR_INVALPARAM | The value of <p lpMidiOutHdr> is invalid.
* @flag MIDIERR_UNPREPARED | The output buffer header <p lpMidiOutHdr> has
* not been prepared.
* @flag MIDIERR_STILLPLAYING | <p lpMidiOutHdr> is still playing or
* queued from a previous call to <f midiOutPolyMsg>.
*
* @comm The polymessage buffer contains one or more MIDI messages. Entries in the
* buffer can be of the following three types:
*
* @flag Short Message | Is two DWORDs. One contains time data, the other
* contains message content. Time information is the time to wait between the
* previous event and the event being described. Time units are based on the
* time-division header in the MIDI file.
*
* Message content for short messages occupy the 24 least-significant bits of
* the DWORD; the high-order byte contains a zero.
*
* @flag System Message | Is a multiple of two DWORDs. The first DWORD contains
* time information that specifies the amount of time to wait between the
* previous event and the event being described. Time units are based on the
* time-division header in the MIDI file.
*
* The second DWORD contains the length of the system-message data (SysEx) in
* the 24 least-significant bits of the DWORD; the high-order bit contains
* a one.
*
* Remaining DWORDs in the system message contain SysEx data.
*
* @flag End-of-Buffer | Is two DWORDs, each with the value -1. This entry
* indicates the end of data in the poly-message buffer. This message is not passed
* to MIDI devices.
*
* @comm This function cannot be called at interrupt time.
*
* @xref <f midiOutLongMsg> <f midiOutPrepareHeader>
****************************************************************************/
#define ERROR_EXIT(x) \
{ \
uRet = (x); \
goto CLEANUP; \
}
#define SKIP_BYTES(x,s) \
{ \
if (dwLength < (x)) \
{ \
dprintf1(( "!midiOutPolyMsg: ran off end of polymsg buffer in parse!\r\n%ls\r\nOffset %lu", (LPSTR)(s), (DWORD)(((LPBYTE)lpdwBuffer) - lpMidiHdr->lpData))); \
uRet = MMSYSERR_INVALPARAM; \
goto CLEANUP; \
} \
((LPBYTE)lpdwBuffer) += (x); \
dwLength -= (x); \
}
MMRESULT FAR PASCAL mseOutSend(
PMIDIEMU pme,
LPMIDIHDR lpMidiHdr,
UINT cbMidiHdr)
{
UINT uRet = MMSYSERR_NOERROR;
UINT idx;
LPDWORD lpdwBuffer;
DWORD dwLength;
LPMIDIHDR lpmhWork;
LPMIDIHDREXT lpExt;
BOOL fQueueWasEmpty;
BYTE bEvent;
DWORD dwParm;
DWORD dwStreamID;
HMIDIOUT hmo;
DWORD_PTR dwBase;
UINT cNewHeaders;
dprintf2(( "mseOutSend pme %04X lpmh %08lX", (UINT_PTR)pme, (DWORD_PTR)lpMidiHdr));
dwBase = lpMidiHdr->reserved;
if ((lpExt = winmmAlloc(sizeof(MIDIHDREXT))) == NULL)
{
dprintf1(( "midiOutPolyMsg: No room for shadow"));
ERROR_EXIT(MMSYSERR_NOMEM);
}
//
// This needs to be done ASAP in case we error out.
//
lpMidiHdr->reserved = (DWORD_PTR)(lpExt);
lpMidiHdr->dwReserved[MH_BUFIDX] = 0;
lpExt->nHeaders = 0;
lpExt->lpmidihdr = (LPMIDIHDR)(lpExt+1);
//
// Parse the poly msg buffer and see if there are any long msgs.
// If there are, allocate MIDIHDR's for them on the end of the
// main MIDIHDR extension and fill them in and prepare them.
//
lpdwBuffer = (LPDWORD)lpMidiHdr->lpData;
dwLength = lpMidiHdr->dwBytesRecorded;
while (dwLength)
{
//
// Skip over the delta time stamp
//
SKIP_BYTES(sizeof(DWORD), "d-time");
dwStreamID = *lpdwBuffer;
SKIP_BYTES(sizeof(DWORD), "stream-id");
//
// Extract the event type and parameter and skip the event DWORD
//
bEvent = MEVT_EVENTTYPE(*lpdwBuffer) & (BYTE)~(MEVT_F_CALLBACK >> 24);
dwParm = MEVT_EVENTPARM(*lpdwBuffer);
SKIP_BYTES(sizeof(DWORD), "event");
if (bEvent == MEVT_LONGMSG)
{
LPMIDIHDREXT lpExtRealloc;
if (dwParm > dwLength)
{
dprintf1(( "parse: I don't like stuff that sucks!"));
ERROR_EXIT(MMSYSERR_INVALPARAM);
}
cNewHeaders = 1;
if (dwStreamID == (DWORD)-1L)
cNewHeaders = pme->chMidi;
lpExt->nHeaders += cNewHeaders;
if ((lpExtRealloc = (LPMIDIHDREXT)HeapReAlloc(hHeap,
HEAP_ZERO_MEMORY, lpExt,
sizeof(MIDIHDREXT)+sizeof(MIDIHDR)*lpExt->nHeaders))
== NULL)
{
lpExt->nHeaders -= cNewHeaders;
ERROR_EXIT(MMSYSERR_NOMEM);
}
lpExt = lpExtRealloc;
lpMidiHdr->reserved = (DWORD_PTR)(lpExt);
lpmhWork = ((LPMIDIHDR)(lpExt+1)) + lpExt->nHeaders - cNewHeaders;
while (cNewHeaders--)
{
lpmhWork->lpData = (LPSTR)lpdwBuffer;
lpmhWork->dwBufferLength = dwParm;
lpmhWork->dwBytesRecorded = 0;
lpmhWork->dwUser = 0;
lpmhWork->dwFlags =
(lpMidiHdr->dwFlags & MHDR_MAPPED) | MHDR_SHADOWHDR;
if (dwStreamID == (DWORD)-1L)
lpmhWork->dwReserved[MH_STREAM] = cNewHeaders;
else
lpmhWork->dwReserved[MH_STREAM] = dwStreamID;
lpmhWork->dwReserved[MH_STRMPME] = (DWORD_PTR)pme;
++lpmhWork;
}
dwParm = (dwParm+3)&~3;
SKIP_BYTES(dwParm, "longmsg parm");
}
else
{
//
// Skip any additional paramters for other length-class messages
//
if (bEvent & (MEVT_F_LONG >> 24))
{
dwParm = (dwParm+3)&~3;
// dprintf1(( "Length [%lu] rounded [%lu]", dwParm, (dwParm+3)&~3));
SKIP_BYTES(dwParm, "generic long event data");
}
}
}
// Now prepare any headers we allocated
//
lpmhWork = (LPMIDIHDR)(lpExt+1);
for (idx = 0; idx < lpExt->nHeaders; idx++, lpmhWork++)
{
hmo = (HMIDIOUT)mseIDtoHMidi(pme, (DWORD)lpmhWork->dwReserved[MH_STREAM]);
if (NULL != hmo)
{
if ((uRet = midiOutPrepareHeader(hmo,
lpmhWork,
sizeof(MIDIHDR))) != MMSYSERR_NOERROR)
{
dprintf1(( "parse: pre-prepare of embedded long msg failed! (%lu)", (DWORD)uRet));
ERROR_EXIT(uRet);
}
}
}
//
// Reset lpExt->lpmidihdr to the next header to play
//
lpExt->lpmidihdr = (LPMIDIHDR)(lpExt+1);
//
// Prepare to update handle information to contain this header
//
PDEVLOCK( pme );
//
// Shove the block in the queue, noting if it was empty
//
fQueueWasEmpty = FALSE;
if (pme->lpmhRear == NULL)
{
fQueueWasEmpty = TRUE;
pme->lpmhRear = pme->lpmhFront = lpMidiHdr;
}
else
{
pme->lpmhRear->lpNext = lpMidiHdr;
pme->lpmhRear = lpMidiHdr;
}
lpMidiHdr->lpNext = NULL;
lpMidiHdr->dwFlags |= MHDR_INQUEUE;
PDEVUNLOCK( pme );
if (pme->dwPolyMsgState == PM_STATE_PAUSED)
{
if (fQueueWasEmpty)
pme->dwSavedState = PM_STATE_READY;
}
else
{
if (fQueueWasEmpty)
{
// We want to schedule this now. If the there's no timer
// or we can kill the current one, send. If we can't kill the
// pending timer, it's in the process of being scheduled anyway
//
if (guMIDITimerID == TIMER_OFF ||
MMSYSERR_NOERROR == timeKillEvent(guMIDITimerID))
{
guMIDITimerID = TIMER_OFF;
pme->dwPolyMsgState = PM_STATE_READY;
dprintf2(( "mseSend take -- about to mot"));
midiOutTimerTick(
guMIDITimerID, // ID of our timer
0, // wMsg is unused
timeGetTime(), // dwUser unused
0L, // dw1 unused
0L); // dw2 unused
dprintf2(( "mseSend mot"));
}
}
}
CLEANUP:
if (uRet != MMSYSERR_NOERROR)
{
if (lpExt != NULL)
{
lpMidiHdr = (LPMIDIHDR)(lpExt+1);
while (lpExt->nHeaders--)
{
hmo = (HMIDIOUT)mseIDtoHMidi(pme, (DWORD)lpMidiHdr->dwReserved[MH_STREAM]);
#ifdef DEBUG
if (NULL == hmo)
dprintf1(( "stream-id disappeared during cleanup!!!"));
#endif
midiOutUnprepareHeader(hmo, lpMidiHdr++, sizeof(MIDIHDR));
}
winmmFree(lpExt);
}
}
return uRet;
} /* midiOutPolyMsg() */
/** void FAR PASCAL midiOutSetClockRate(PMIDIEMU pme, TICKS tkWhen)
*
* DESCRIPTION:
*
* This function is called whenever the clock rate for the stream
* needs to be changed.
*
* ARGUMENTS:
* (PMIDIEMU pme, TICKS tkWhen)
*
* pme indicates the handle to change the clock rate of.
*
* tkWhen is the absolute tick time at which the time change occurs.
*
** jfg */
void FAR PASCAL midiOutSetClockRate(
PMIDIEMU pme,
TICKS tkWhen)
{
DWORD dwNum;
DWORD dwDenom;
if (pme->dwTimeDiv&IS_SMPTE)
{
switch(-SMPTE_FORMAT(pme->dwTimeDiv))
{
case SMPTE_24:
dwNum = 24L;
dwDenom = 1L;
break;
case SMPTE_25:
dwNum = 25L;
dwDenom = 1L;
break;
case SMPTE_30DROP:
case SMPTE_30:
//
// Actual frame rate for 30 fps (color television) is
// 29.97 fps.
//
dwNum = 2997L;
dwDenom = 100L;
break;
default:
dprintf1(( "Invalid SMPTE frames/sec in midiOutSetClockRate! (using 30)"));
dwNum = 2997L;
dwDenom = 100L;
break;
}
dwNum *= (DWORD)TICKS_PER_FRAME(pme->dwTimeDiv);
dwDenom *= 1000L;
}
else
{
dwNum = 1000L * TICKS_PER_QN(pme->dwTimeDiv);
dwDenom = pme->dwTempo;
}
clockSetRate(&pme->clock, tkWhen, dwNum, dwDenom);
}
/** BOOL NEAR PASCAL midiOutScheduleNextEvent(PMIDIEMU pme)
*
* DESCRIPTION:
*
* Determine when (in ticks defined for this device) the next event
* is due.
*
* ARGUMENTS:
* (PMIDIEMU pme)
*
* RETURN (BOOL):
*
* TRUE if there was an event in this buffer to schedule.
*
* NOTES:
*
* Just calculate how many ticks till next event and store in the
* device struct.
*
* This function does NOT schedule across buffers; caller must
* link to next buffer if needed.
*
** jfg */
BOOL NEAR PASCAL midiOutScheduleNextEvent(
PMIDIEMU pme)
{
LPMIDIHDR lpmhdr;
LPBYTE lpb;
DWORD tkDelta;
if ((lpmhdr = pme->lpmhFront) == NULL ||
lpmhdr->dwReserved[MH_BUFIDX] == lpmhdr->dwBytesRecorded)
{
pme->dwPolyMsgState = PM_STATE_EMPTY;
return FALSE;
}
lpb = (LPBYTE)lpmhdr->lpData;
tkDelta = *(LPDWORD)(lpb+lpmhdr->dwReserved[MH_BUFIDX]);
pme->tkNextEventDue = pme->tkPlayed + tkDelta;
pme->dwPolyMsgState = PM_STATE_READY;
return TRUE;
} /* ScheduleNextEvent() */
/** void NEAR PASCAL midiOutPlayNextPolyEvent(PMIDIEMU pme)
*
* DESCRIPTION:
*
* Play the next event if there is one. Current buffer must
* be pointing at an event (*NOT* end-of-buffer).
*
* - Plays all events which are due
*
* - Schedules next event
*
* ARGUMENTS:
* (PMIDIEMU pme)
*
* NOTES:
*
* First, play the event. If it's a short msg, just do it.
* If it's a SysEx, pull the appropriate (already prepared)
* header from the extension block and send it. Mark the state
* of the device as blocked so nothing else will be played
* until the SysEx is done.
*
* Update dwReserved[MH_BUFIDX] to point at the next event.
*
* Determine the next event and schedule it, crossing to the
* next buffer if needed. If the next event is already due
* (i.e. had a delta-time of zero), stick around and send that,
* too.
*
*
*
** jfg */
void NEAR PASCAL midiOutPlayNextPolyEvent(
PMIDIEMU pme
#ifdef DEBUG
,DWORD dwStartTime
#endif
)
{
LPBYTE lpb;
LPMIDIHDR lpmhdr;
DWORD dwMsg;
LPMIDIHDREXT lpExt;
MMRESULT mmrError;
DWORD tkDelta;
BYTE bEvent;
DWORD dwOffset;
DWORD dwStreamID;
HMIDIOUT hmo;
UINT cToSend;
#if 0
if (NULL != pme->lpmhFront)
{
lpb = (LPBYTE)(pme->lpmhFront->lpData);
_asm
{
mov ax, word ptr lpb
mov dx, word ptr lpb+2
int 3
}
}
#endif
while (pme->dwPolyMsgState == PM_STATE_READY)
{
for(;;)
{
lpmhdr = pme->lpmhFront;
if (!lpmhdr)
return;
// Make sure next buffer contains valid data and skip if it
// doesn't
//
if (midiOutScheduleNextEvent(pme))
break;
// That buffer is done or empty
//
midiOutDequeueAndCallback(pme);
}
lpb = lpmhdr->lpData;
tkDelta = *(LPDWORD)(lpb+lpmhdr->dwReserved[MH_BUFIDX]);
// dprintf2(( "dwReserved[MH_BUFIDX] %lu tkDelta %lu", lpmhdr->dwReserved[0], tkDelta));
pme->tkNextEventDue = pme->tkPlayed + tkDelta;
if (pme->tkNextEventDue > pme->tkTime)
{
return;
}
//
// There is an event pending and it's due; send it and update pointers
//
dwOffset = (DWORD)lpmhdr->dwReserved[MH_BUFIDX];
pme->tkPlayed += tkDelta;
// Skip tkDelta and stream-id
//
lpmhdr->dwReserved[MH_BUFIDX] += sizeof(DWORD);
dwStreamID = *(LPDWORD)(lpb+lpmhdr->dwReserved[MH_BUFIDX]);
lpmhdr->dwReserved[MH_BUFIDX] += sizeof(DWORD);
// Will be NULL if dwStreamID == -1 (all IDs)
//
hmo = (HMIDIOUT)mseIDtoHMidi(pme, dwStreamID);
//
// Extract event type and parms and update past event
//
dwMsg = *(LPDWORD)(lpb+lpmhdr->dwReserved[MH_BUFIDX]);
bEvent = MEVT_EVENTTYPE(dwMsg);
dwMsg = MEVT_EVENTPARM(dwMsg);
lpmhdr->dwReserved[MH_BUFIDX] += sizeof(DWORD);
if (hmo && (bEvent & (MEVT_F_CALLBACK >> 24)))
{
lpmhdr->dwOffset = dwOffset;
DriverCallback(
pme->dwCallback,
HIWORD(pme->dwFlags),
(HDRVR)pme->hStream,
MM_MOM_POSITIONCB,
pme->dwInstance,
(DWORD_PTR)lpmhdr,
0L);
}
bEvent &= ~(MEVT_F_CALLBACK >> 24);
switch(bEvent)
{
case MEVT_SHORTMSG:
{
BYTE bEventType;
BYTE bNote;
BYTE bVelocity;
LPBYTE pbEntry = pme->rbNoteOn;
if (NULL == hmo)
{
dprintf1(( "Event skipped - not ours"));
break;
}
//
// If we're sending a note on or note off, track note-on
// count.
//
bEventType = (BYTE)(dwMsg&0xFF);
if (!(bEventType & 0x80))
{
bEventType = pme->bRunningStatus;
bNote = (BYTE)(dwMsg&0xFF);
bVelocity = (BYTE)((dwMsg >> 8)&0xFF);
// ALWAYS expand running status - individual dev's can't
// track running status of entire stream.
//
dwMsg = (dwMsg << 8) | (DWORD)(bEventType);
}
else
{
pme->bRunningStatus = bEventType;
bNote = (BYTE)((dwMsg >> 8)&0xFF);
bVelocity = (BYTE)((dwMsg >> 16)&0xFF);
}
if ((bEventType&0xF0) == MIDI_NOTEON ||
(bEventType&0xF0) == MIDI_NOTEOFF)
{
BYTE bChannel = (bEventType & 0x0F);
UINT cbOffset = (bChannel * NUM_NOTES + bNote) / 2;
//
// Note-on with a velocity of 0 == note off
//
if ((bEventType&0xF0) == MIDI_NOTEOFF || bVelocity == 0)
{
if (bNote&0x01) // odd
{
if ((*(pbEntry + cbOffset)&0xF0) != 0)
*(pbEntry + cbOffset) -= 0x10;
}
else //even
{
if ((*(pbEntry + cbOffset)&0xF) != 0)
*(pbEntry + cbOffset) -= 0x01;
}
}
else
{
if (bNote&0x01) // odd
{
if ((*(pbEntry + cbOffset)&0xF0) != 0xF0)
*(pbEntry + cbOffset) += 0x10;
}
else //even
{
if ((*(pbEntry + cbOffset)&0xF) != 0xF)
*(pbEntry + cbOffset) += 0x01;
}
}
}
mmrError = midiOutShortMsg(hmo, dwMsg);
if (MMSYSERR_NOERROR != mmrError)
{
dprintf(("Short msg returned %08lX!!!", (DWORD)mmrError));
}
}
break;
case MEVT_TEMPO:
pme->dwTempo = dwMsg;
dprintf1(( "dwTempo %lu", pme->dwTempo));
midiOutSetClockRate((PMIDIEMU)pme, pme->tkPlayed);
break;
case MEVT_LONGMSG:
//
// Advance lpmhdr past the message; the header is already
// prepared with the proper address and length, so we set
// the polymsg header so that it points at the next message
// when this long msg completes.
//
// Keep low 24 bits of dwMsg (SysEx length, byte aligned),
// round to next DWORD (buffer must be padded to match this),
// and skip past dwMsg and the SysEx buffer.
//
dwMsg = (dwMsg+3)&~3;
lpmhdr->dwReserved[MH_BUFIDX] += dwMsg;
cToSend = 1;
if (dwStreamID == (DWORD)-1L)
cToSend = pme->chMidi;
lpExt = (LPMIDIHDREXT)lpmhdr->reserved;
pme->cSentLongMsgs = 0;
pme->dwPolyMsgState = PM_STATE_BLOCKED;
pme->fdwDev |= MDV_F_SENDING;
while (cToSend--)
{
lpmhdr = lpExt->lpmidihdr;
++lpExt->lpmidihdr;
hmo = (HMIDIOUT)mseIDtoHMidi(pme,
(DWORD)lpmhdr->dwReserved[MH_STREAM]);
if (hmo)
mmrError = midiOutLongMsg(hmo, lpmhdr, sizeof(MIDIHDR));
else
dprintf1(( "mseIDtoHMidi() failed and returned a NULL" ));
if ((hmo) && (MMSYSERR_NOERROR == mmrError))
++pme->cSentLongMsgs;
else
dprintf1(( "MODM_LONGDATA returned %u in emulator!",
(UINT)mmrError));
}
if (0 == pme->cSentLongMsgs)
pme->dwPolyMsgState = PM_STATE_READY;
pme->fdwDev &= ~MDV_F_SENDING;
break;
default:
//
// If we didn't understand a length-class message, skip it.
//
if (bEvent&(MEVT_F_LONG >> 24))
{
dwMsg = (dwMsg+3)&~3;
lpmhdr->dwReserved[MH_BUFIDX] += dwMsg;
}
break;
}
//
// Find the next schedulable polyMsg
//
while (!midiOutScheduleNextEvent(pme))
{
midiOutDequeueAndCallback(pme);
if (pme->lpmhFront == NULL)
break;
}
}
}
/** void NEAR PASCAL midiOutDequeueAndCallback(PMIDIEMU pme)
*
* DESCRIPTION:
*
* The current polymsg buffer has finished. Pull it off the queue
* and do a callback.
*
* ARGUMENTS:
* (PMIDIEMU pme)
*
* NOTES:
*
** jfg */
void NEAR PASCAL midiOutDequeueAndCallback(
PMIDIEMU pme)
{
LPMIDIHDR lpmidihdr;
BOOL fPosted;
dprintf2(( "DQ"));
//
// A polymsg buffer has finished. Pull it off the queue and
// call back the app.
//
if ((lpmidihdr = pme->lpmhFront) == NULL)
return;
if ((pme->lpmhFront = lpmidihdr->lpNext) == NULL)
{
dprintf2(( "DQ/CB -- last buffer"));
pme->lpmhRear = NULL;
}
//
// Can't be at interrupt callback time to unprepare possible
// embedded long messages in this thing. The notify window's
// wndproc will call midiOutNukePMBuffer to clean up.
//
dprintf2(( "!DQ/CB %08lX", (DWORD_PTR)lpmidihdr));
++pme->cPostedBuffers;
fPosted = PostMessage(
hwndNotify,
MM_POLYMSGBUFRDONE,
(WPARAM)pme,
(DWORD_PTR)lpmidihdr);
WinAssert(fPosted);
if (!fPosted)
{
GetLastError();
--pme->cPostedBuffers;
}
}
void FAR PASCAL midiOutNukePMBuffer(
PMIDIEMU pme,
LPMIDIHDR lpmh)
{
LPMIDIHDREXT lpExt;
LPMIDIHDR lpmhWork;
MMRESULT mmrc;
HMIDIOUT hmo;
dprintf2(( "Nuke %08lX", (DWORD_PTR)lpmh));
//
// Unprepare internal stuff and do user callback
//
lpExt = (LPMIDIHDREXT)(lpmh->reserved);
lpmhWork = (LPMIDIHDR)(lpExt+1);
while (lpExt->nHeaders--)
{
if ((lpmhWork->dwFlags&MHDR_PREPARED) &&
(!(lpmhWork->dwFlags&MHDR_INQUEUE)))
{
hmo = (HMIDIOUT)mseIDtoHMidi(pme, (DWORD)lpmhWork->dwReserved[MH_STREAM]);
mmrc = midiOutUnprepareHeader(hmo, lpmhWork, sizeof(*lpmhWork));
#ifdef DEBUG
if (MMSYSERR_NOERROR != mmrc)
{
dprintf1(( "midiOutNukePMBuffer: Could not unprepare! (%lu)", (DWORD)mmrc));
}
#endif
}
else
{
dprintf1(( "midiOutNukePMBuffer: Emulation header flags bogus!!!"));
}
lpmhWork++;
}
winmmFree(lpExt);
lpmh->reserved = 0L;
lpmh->dwFlags &= ~MHDR_INQUEUE;
lpmh->dwFlags |= MHDR_DONE;
// dprintf2(( "Nuke: callback"));
DriverCallback(
pme->dwCallback,
HIWORD(pme->dwFlags),
(HDRVR)pme->hStream,
MM_MOM_DONE,
pme->dwInstance,
(DWORD_PTR)lpmh,
0L);
}
/*****************************************************************************
*
* @doc INTERNAL MIDI
*
* @api void | midiOutTimerTick |
* This function handles the timing of polymsg out buffers. One timer instance
* is shared by all polymsg out streams. When <f midiOutPolyMsg> is called
* and the timer is not running, or <f midiOutTimerTick> finished processing,
* the timer is set to go off based on the time until the event with the
* shortest time remaining of all events. All timers are one-shot timers.
*
* @parm UINT | uTimerID |
* The timer ID of the timer that fired.
*
* @parm UINT | wMsg |
* Unused.
*
* @parm DWORD | dwUser |
* User instance data for the timer callback (unused).
*
* @parm DWORD | dwParam1 |
* Unused.
*
* @parm DWORD | dwParam2 |
* Unused.
*
* @comm Determine elapsed microseconds using <f timeGetTime>.
*
* Traverse the list of output handles. Update the tick clock for each handle. If there are
* events to do on that handle, start them.
*
* Determine the next event due on any stream. Start another one-shot timer
* to call <f midiOutTimerTick> when this interval has expired.
*
*****************************************************************************/
STATIC UINT uTimesIn = 0;
void CALLBACK midiOutTimerTick(
UINT uTimerID,
UINT wMsg,
DWORD_PTR dwUser,
DWORD_PTR dw1,
DWORD_PTR dw2)
{
PMIDIEMU pme;
DWORD msNextEventMin = (DWORD)-1L;
DWORD msNextEvent;
UINT uDelay;
#ifdef DEBUG
DWORD dwNow = timeGetTime();
#endif
if (guMIDIInTimer)
{
dprintf2(( "midiOutTimerTick() re-entered (%u)", guMIDIInTimer));
return;
}
guMIDIInTimer++;
#ifdef DEBUG
{
DWORD dwDelta = dwNow - (DWORD)dwUser;
if (dwDelta > 1)
dprintf2(( "Timer event delivered %lu ms late", dwDelta));
}
#endif
for (pme = gpEmuList; pme; pme = pme->pNext)
{
pme->tkTime = clockTime(&pme->clock);
//
// Play all events on this pdev that are due
//
if (pme->dwPolyMsgState == PM_STATE_READY)
{
//
// Lock starts at -1. When incrementing the lock
// if we are the only one with the lock the count
// will be 0, otherwise it will be some non-zero
// value determined by InterlockedIncrement.
//
if (PDEVLOCK( pme ) == 0)
midiOutPlayNextPolyEvent(pme
#ifdef DEBUG
,dwNow
#endif
);
PDEVUNLOCK( pme );
}
//
// If there's still data to play on this stream, figure out when
// it'll be due so we can schedule the next nearest event.
//
if (pme->dwPolyMsgState != PM_STATE_EMPTY)
{
// dprintf1(( "tkNextEventDue %lu pdev->tkTime %lu", pme->tkNextEventDue, pme->tkTime));
if (pme->tkNextEventDue <= pme->tkTime)
{
//
// This can happen if we send a long embedded SysEx and the
// next event is scheduled a short time away (comes due before
// SysEx finishes). In this case, we want the timer to fire
// again ASAP.
//
msNextEvent = 0;
}
else
{
msNextEvent =
clockOffsetTo(&pme->clock, pme->tkNextEventDue);
}
if (msNextEvent < msNextEventMin)
{
msNextEventMin = msNextEvent;
}
}
else
{
dprintf1(( "dwPolyMsgState == PM_STATE_EMPTY"));
}
}
if (0 == msNextEventMin)
{
dprintf1(( "midiEmu: Next event due now!!!"));
}
--guMIDIInTimer;
//
// Schedule the next event. In no case schedule an event less than
// guMIDIPeriodMin away (no point in coming back w/ no time elapsed).
//
if (msNextEventMin != (DWORD)-1L)
{
uDelay = max(guMIDIPeriodMin, (UINT)msNextEventMin);
// dprintf1(("PM Resched %u ms (ID=%u)", uDelay, guMIDITimerID));
if (!gfMinPeriod)
{
timeBeginPeriod(guMIDIPeriodMin);
gfMinPeriod = TRUE;
}
#ifdef DEBUG
guMIDITimerID = timeSetEvent(uDelay, guMIDIPeriodMin, midiOutTimerTick, timeGetTime()+uDelay, TIME_ONESHOT | TIME_KILL_SYNCHRONOUS);
#else
guMIDITimerID = timeSetEvent(uDelay, guMIDIPeriodMin, midiOutTimerTick, uDelay, TIME_ONESHOT | TIME_KILL_SYNCHRONOUS);
#endif
dprintf2(( "mOTT tse(%u) = %u", guMIDIPeriodMin, guMIDITimerID));
if (guMIDITimerID == TIMER_OFF)
dprintf1(( "timeSetEvent(%u) failed in midiOutTimerTick!!!", uDelay));
}
else
{
dprintf1(( "Stop in the name of all that which does not suck!"));
guMIDITimerID = TIMER_OFF;
if (gfMinPeriod)
{
dprintf1(( "timeEndPeriod"));
gfMinPeriod = FALSE;
timeEndPeriod(guMIDIPeriodMin);
}
}
#ifdef DEBUG
{
DWORD dwDelta = timeGetTime() - dwNow;
if (dwDelta > 1)
dprintf2(( "Spent %lu ms in midiOutTimerTick", dwDelta));
}
#endif
} /* TimerTick() */
/*****************************************************************************
*
* @doc INTERNAL MIDI
*
* @api void | midiOutCallback |
* This function is called by the midi output driver whenever an event
* completes. It filters long message completions when we are emulating
* polymsg out.
*
* @parm HMIDIOUT | hMidiOut |
* Handle of the device which completed something.
*
* @parm UINT | wMsg |
* Specifies the event which completed.
*
* @parm DWORD | dwInstance |
* User instance data for the callback.
*
* @parm DWORD | dwParam1 |
* Message specific parameter.
*
* @parm DWORD | dwParam2 |
* Message specific parameter.
*
* @comm
*
* If this is a completion for a long message buffer on a stream we are
* emulating polymsg out for, mark the stream as ready to play.
*
*****************************************************************************/
void CALLBACK midiOutCallback(
HMIDIOUT hMidiOut,
WORD wMsg,
DWORD_PTR dwInstance,
DWORD_PTR dwParam1,
DWORD_PTR dwParam2)
{
PMIDIEMU pme;
LPMIDIHDR lpmh;
if (MM_MOM_DONE != wMsg)
return;
lpmh = (LPMIDIHDR)dwParam1;
pme = (PMIDIEMU)lpmh->dwReserved[MH_STRMPME];
#ifdef DEBUG
if (lpmh->dwFlags & MHDR_ISSTRM)
dprintf1(( "Uh-oh, got stream header back from 3.1 driver???"));
#endif
if (MM_MOM_DONE == wMsg)
{
if (0 == --pme->cSentLongMsgs &&
!(pme->fdwDev & MDV_F_SENDING))
pme->dwPolyMsgState = PM_STATE_READY;
}
}
/*****************************************************************************
* @doc INTERNAL MIDI
*
* @api void | midiOutAllNotesOff | This function turns off all notes
* by using the map kept in polymsg emulation. It only works if we're
* opened with MIDI_IO_COOKED and are emulating on that device.
*
* @parm PMIDIEMU | pme | The device to turn off notes on.
*
* @xref midiOutPause midiOutStop
****************************************************************************/
void NEAR PASCAL midiOutAllNotesOff(
PMIDIEMU pme)
{
UINT uChannel;
UINT uNote;
BYTE bCount;
DWORD dwMsg;
UINT idx;
LPBYTE pbEntry = pme->rbNoteOn;
for (uChannel=0; uChannel < NUM_CHANNELS; uChannel++)
{
// Turn off any sustained notes so the note off won't be ignored
//
dwMsg = ((DWORD)MIDI_CONTROLCHANGE) |
((DWORD)uChannel)|
(((DWORD)MIDI_SUSTAIN)<<8);
for (idx = 0; idx < pme->chMidi; idx++)
midiOutShortMsg((HMIDIOUT)pme->rIds[idx].hMidi, dwMsg);
for (uNote=0; uNote < NUM_NOTES; uNote++)
{
if (uNote&0x01) // odd
{
bCount = (*(pbEntry + (uChannel * NUM_NOTES + uNote)/2) & 0xF0)>>4;
}
else // even
{
bCount = *(pbEntry + (uChannel * NUM_NOTES + uNote)/2) & 0xF;
}
if (bCount != 0)
{
//
// Message is Note off on this channel and note
// with a turn off velocity of 127
//
dwMsg =
((DWORD)MIDI_NOTEOFF)|
((DWORD)uChannel)|
((DWORD)(uNote<<8))|
0x007F0000L;
dprintf1(( "mOANO: dwMsg %08lX count %u", dwMsg, (UINT)bCount));
while (bCount--)
{
for (idx = 0; idx < pme->chMidi; idx++)
midiOutShortMsg((HMIDIOUT)pme->rIds[idx].hMidi, dwMsg);
}
}
}
}
}
MMRESULT FAR PASCAL mseOutCachePatches(
PMIDIEMU pme,
UINT uBank,
LPWORD pwpa,
UINT fuCache)
{
UINT cmesi;
PMIDIEMUSID pmesi;
MMRESULT mmrc;
MMRESULT mmrc2;
cmesi = pme->chMidi;
pmesi = pme->rIds;
mmrc2 = MMSYSERR_NOERROR;
while (cmesi--)
{
mmrc = midiOutCachePatches((HMIDIOUT)pmesi->hMidi, uBank, pwpa, fuCache);
if (MMSYSERR_NOERROR != mmrc && MMSYSERR_NOTSUPPORTED != mmrc)
mmrc2 = mmrc;
}
return mmrc2;
}
MMRESULT FAR PASCAL mseOutCacheDrumPatches(
PMIDIEMU pme,
UINT uPatch,
LPWORD pwkya,
UINT fuCache)
{
UINT cmesi;
PMIDIEMUSID pmesi;
MMRESULT mmrc;
MMRESULT mmrc2;
cmesi = pme->chMidi;
pmesi = pme->rIds;
mmrc2 = MMSYSERR_NOERROR;
while (cmesi--)
{
mmrc = midiOutCacheDrumPatches((HMIDIOUT)pmesi->hMidi, uPatch, pwkya, fuCache);
if (MMSYSERR_NOERROR != mmrc && MMSYSERR_NOTSUPPORTED != mmrc)
mmrc2 = mmrc;
}
return mmrc2;
}
DWORD FAR PASCAL mseOutBroadcast(
PMIDIEMU pme,
UINT msg,
DWORD_PTR dwParam1,
DWORD_PTR dwParam2)
{
UINT idx;
DWORD dwRet;
DWORD dwRetImmed;
dwRet = 0;
for (idx = 0; idx < pme->chMidi; idx++)
{
dwRetImmed = midiOutMessage((HMIDIOUT)pme->rIds[idx].hMidi, msg, dwParam1, dwParam2);
if (dwRetImmed)
dwRet = dwRetImmed;
}
return dwRet;
}
DWORD FAR PASCAL mseTimebase(
PCLOCK pclock)
{
return timeGetTime();
}