291 lines
6.4 KiB
C
291 lines
6.4 KiB
C
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// A Somewhat Useful Sample Real Time Client.
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// Author: Joseph Ballantyne
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// Date: 3/12/99
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// This is the first real time client that actually does something
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// useful. This is a midi MPU401 sequencer. It is simple, but it
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// works and uses less CPU than our current 98 and NT WDM sequencer.
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// Of course since this is a sample and I am not in the business of
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// writing MIDI sequencers, it has some limitations.
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// The data to be sequenced is passed in in one big block.
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// It is passed in already formatted and timestamped appropriately.
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// This code simply processes the buffer it was passed, and when
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// it has sequenced everything that was passed in, it returns -
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// which kills the real time thread.
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#include "common.h"
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#include "rt.h"
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#include "sequence.h"
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// This code only supports the MPU401 at a fixed IO location of 0x330.
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// MPU401 defines
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#define MPU401BASEADDRESS 0x330
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#define MPU401_REG_DATA 0x00 // Data in/out register offset from base address
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#define MPU401_REG_COMMAND 0x01 // Command register offset from base address
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#define MPU401_REG_STATUS 0x01 // Status register offset from base addess
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#define MPU401_DRR 0x40 // Output ready (for command or data)
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#define MPU401_DSR 0x80 // Input ready (for data)
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#define MPU401_CMD_RESET 0xFF // Reset command
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#define MPU401_CMD_UART 0x3F // Switch to UART mod
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#define MPU401_ACK 0xFE // Ack from MPU401 after successful command.
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#define MidiWriteOK(status) ((status & MPU401_DRR) == 0)
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#define MidiReadOK(status) ((status & MPU401_DSR) == 0)
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// Here is the format of the data we process.
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#pragma pack(push,1)
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typedef struct MidiChunk{
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struct MidiChunk *next;
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struct MidiChunk *previous;
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ULONGLONG timestamp;
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ULONG numbytes;
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UCHAR data[3];
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} MidiMessage, *PMidiMessage;
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#pragma pack(pop)
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// Remember, everything we touch HAS to be locked down.
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#pragma LOCKED_CODE
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#pragma LOCKED_DATA
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MidiMessage testmidi[2]={
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{&testmidi[1],&testmidi[1],0,3,0x99,0x25,0x7f},
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{&testmidi[0],&testmidi[0],240,3,0x99,0x25,0}
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};
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#pragma warning ( disable : 4035 )
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#define rdtsc __asm _emit 0x0f __asm _emit 0x31
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LONGLONG __inline ReadCycleCounter(VOID)
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{
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__asm {
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rdtsc
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}
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}
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#pragma warning ( default : 4035 )
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VOID OutB(ULONG address, ULONG data)
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{
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__asm {
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mov edx,address
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mov eax,data
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out dx,al
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}
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}
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#pragma warning( disable : 4035 )
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ULONG InB(ULONG address)
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{
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__asm {
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mov edx,address
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xor eax,eax
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in al,dx
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}
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}
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#pragma warning( default : 4035 )
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// This routine sends a command to the MPU401 and waits for an acknowledge from
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// the MPU that the command succeeded. If no ack is recieved in 200ms then
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// it returns FALSE, otherwise it returns TRUE.
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BOOL SendMpuCommand(ULONG MidiBaseAddress, UCHAR command)
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{
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LONG count=0;
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// Wait until OK to write a command.
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while (!MidiWriteOK(InB(MidiBaseAddress+MPU401_REG_STATUS))) {
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RtYield(0, 0);
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}
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// Send command to the MPU401.
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OutB(MidiBaseAddress+MPU401_REG_COMMAND, command);
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// Wait for the MPU acknowlege. If we don't get the correct response
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// in 200ms or less, then punt.
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while (!MidiReadOK(InB(MidiBaseAddress+MPU401_REG_STATUS))) {
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count++;
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if (count<=200) {
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RtYield(0, 0);
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}
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else {
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// We did not get any response, perhaps we were in UART mode.
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#if 0
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return FALSE;
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#else
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break;
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#endif
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}
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}
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// At this point we received something from the MPU, check if it is an ack.
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if (InB(MidiBaseAddress+MPU401_REG_DATA)!=0xfe) {
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// Not a command acknowledge.
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Trap();
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return FALSE;
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}
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return TRUE;
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}
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VOID PlayMidi(PVOID Context, ThreadStats *Statistics)
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{
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PMidiMessage RealTimeMidiData;
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ULONG MidiBaseAddress;
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ULONG MidiStatus;
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ULONG count;
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LONGLONG starttime;
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//Trap();
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RealTimeMidiData=(PMidiMessage)Context;
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MidiBaseAddress=MPU401BASEADDRESS;
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count=0;
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// First wait until the MPU401 comes on line. We need to do this because
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// many MPU401s are plug and play devices and do not appear until
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// the hardware is setup. Note that on most machines, when there is
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// no device on the bus at the I/O port address, InB will return
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// 0xff.
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while (InB(MidiBaseAddress+MPU401_REG_STATUS)==0xff) {
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RtYield(0, 0);
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}
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//Trap();
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// At this point, there is detected hardware at 331.
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// Now wait an extra 10 seconds.
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starttime=Statistics->ThisPeriodStartTime;
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while((Statistics->ThisPeriodStartTime-starttime)/SEC<10) {
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RtYield(0, 0);
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}
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//Trap();
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// Now read the MPU401 data register until it is empty.
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while (MidiReadOK(InB(MidiBaseAddress+MPU401_REG_STATUS))) {
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InB(MidiBaseAddress+MPU401_REG_DATA);
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RtYield(0, 0);
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}
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//Trap();
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// Now reset the MPU401. If this succeeds, we know we have a real
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// MPU at our base address. Note that the MPU may be in UART
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// mode. If so, then we will NOT get an acknowlege back when we reset it.
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// To handle this case, if there is no acknowlege on the first
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// reset, we will retry once and see if we get the acknowlege the second
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// time. If not, then we punt.
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if (!SendMpuCommand(MidiBaseAddress, MPU401_CMD_RESET)) {
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if (!SendMpuCommand(MidiBaseAddress, MPU401_CMD_RESET)) {
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Trap();
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return;
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}
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}
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// Now put the MPU into UART mode.
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if (!SendMpuCommand(MidiBaseAddress, MPU401_CMD_UART)) {
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// For now we disable the trap and the thread exit.
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// We do this because if we run this code on current WDM driven devices,
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// the acknowlege code will be handled by the read interrupt service
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// routine of the driver and so we will not see it.
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Trap();
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return;
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}
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// Now reset the starttime.
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starttime=ReadCycleCounter();
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// Run until we are out of data to send.
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while (RealTimeMidiData!=NULL) {
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// Wait until we need to send the next chunk of data.
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// if (Statistics->totalperiods*MSEC<RealTimeMidiData->timestamp) {
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if ((ULONGLONG)(ReadCycleCounter()-starttime)/200000<RealTimeMidiData->timestamp) {
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RtYield(0, 0);
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continue;
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}
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// Read the status of the device.
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MidiStatus=InB(MidiBaseAddress+MPU401_REG_STATUS);
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// Make sure its OK to write to the device. We should ALWAYS
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// be able to, since we syncronize with the hardware. If not,
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// then update the syncronization, and slip to our next time slice.
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if (!MidiWriteOK(MidiStatus)) {
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RtYield(0, 0);
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continue;
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}
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// Now write the next byte out to the MPU.
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OutB(MidiBaseAddress+MPU401_REG_DATA, RealTimeMidiData->data[count]);
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// Update our state.
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count++;
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if (count>=RealTimeMidiData->numbytes) {
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RealTimeMidiData->timestamp+=250;
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RealTimeMidiData=RealTimeMidiData->next;
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count=0;
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}
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// And yeild - we are done until its time for the next byte.
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RtYield(0, 0);
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}
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}
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