playseq.c
33.3 KB
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/*
* NINTENDO64 SAMPLE PROGRAM
*
* FILE : playseq.c (for 64DD)
*
* Copyright (C) 1998, NINTENDO Co,Ltd.
*/
#include <ultra64.h>
#include <assert.h>
#include <PR/os.h>
#include <PR/ramrom.h>
#include <PR/gu.h>
#include <PR/leo.h>
#include "dd_audio.h"
#include "playseq.h"
/*
* Threads
*/
u64 bootStack[STACKSIZE/8];
static void mainproc(u8 *);
static OSThread mainThread;
static u64 mainThreadStack[STACKSIZE/8];
static void gameproc(u8 *);
static OSThread gameThread;
static u64 gameThreadStack[STACKSIZE/8];
/*
* For PI manager
*/
static OSMesgQueue PiMessageQ;
static OSMesg PiMessages[DMA_QUEUE_SIZE];
/*
* For 64DD
*/
static OSMesgQueue diskQ;
static OSMesg diskQBuf;
static OSMesg LeoMessages[NUM_LEO_MESGS];
static LEODiskID diskID;
static LEOCmd cmdBlock;
void DiskInitialize(void);
void CheckDiskInsert(void);
s32 CheckDiskEject(void);
void DiskRead(u32, void *, u32);
/*
* For synchronization
*/
static OSMesgQueue retraceMessageQ;
static OSMesg retraceMessageBuf;
static OSMesgQueue taskMessageQ;
static OSMesg taskMessageBuf;
static OSMesgQueue dmaMessageQ;
static OSMesg dmaMessageBuf[DMA_QUEUE_SIZE];
static OSMesgQueue resetMessageQ;
static OSMesg resetMessageBuf;
/*
* For audio
*/
static ALGlobals g;
static u8 audioHeap[AUDIO_HEAP_SIZE];
static ALHeap hp;
static ALSynConfig c;
static ALSeqpConfig seqc;
static s32 curBuf = 0;
static s32 curAudioBuf = 1;
/*
* Double-buffer
*/
static OSTask *tlist[2];
static Acmd *cmdList[2];
/*
* Triple-buffer
*/
static s16 audioSamples[3] = {0, 0, 0};
static s16 *audioBuffer[3];
/*
* For vibrato and tremelo
*/
static ALMicroTime initOsc(void **oscState, f32 *initVal, u8 oscType,
u8 oscRate, u8 oscDepth, u8 oscDelay);
static ALMicroTime updateOsc(void *oscState, f32 *updateVal);
static void stopOsc(void *oscState);
/*
* For dma callback routine
*/
#define NBUFFERS 64
typedef struct
{
ALLink node;
int startAddr;
u32 lastFrame;
char *ptr;
} DMABuffer;
typedef struct
{
u8 initialized;
DMABuffer *firstUsed;
DMABuffer *firstFree;
} DMAState;
static OSPiHandle *cartromHandle;
static OSPiHandle *driveromHandle;
static OSIoMesg dmaIOMesgBuf[DMA_QUEUE_SIZE];
static s32 nextDMA = 0;
DMAState dmaState;
DMABuffer dmaBuffs[NBUFFERS];
u32 gFrameCt;
s32 dmaCallBack(s32 addr, s32 len, void *state)
{
s32
delta,
addrEnd,
buffEnd;
u32
tmp;
DMABuffer
*dmaPtr,
*lastDmaPtr;
void
*freeBuffer;
OSPiHandle
*piHandle;
OSIoMesg
*ioMesg;
/* check address (device flag) */
tmp = addr & DDROM_FLAG;
/* When in DDROM */
if(tmp == DDROM_FLAG) {
piHandle = driveromHandle;
addr &= 0x0fffffff;
}
/* When in other media */
else {
/* When in RAM */
if(tmp)
return (osVirtualToPhysical((void *)addr));
/* When in CARTRIDGE ROM */
#ifdef FINAL
piHandle = cartromHandle;
#else
osSyncPrintf("Error : Data in CARTRIDGE ROM\n");
#endif
}
lastDmaPtr = 0;
dmaPtr = dmaState.firstUsed;
addrEnd = addr+len;
while(dmaPtr) /* see if buffer is already set up */
{
buffEnd = dmaPtr->startAddr + MAX_BUFFER_LENGTH;
if(dmaPtr->startAddr > addr) /* since buffers are ordered */
break; /* abort if past possible */
else if(addrEnd <= buffEnd) /* yes, found one */
{
dmaPtr->lastFrame = gFrameCt; /* mark it used */
freeBuffer = dmaPtr->ptr + addr - dmaPtr->startAddr;
return (int) osVirtualToPhysical(freeBuffer);
}
lastDmaPtr = dmaPtr;
dmaPtr = (DMABuffer*)dmaPtr->node.next;
}
/* get here, and you didn't find a buffer, so dma a new one */
/* get a buffer from the free list */
dmaPtr = dmaState.firstFree;
assert(dmaPtr); /* be sure you have a buffer */
dmaState.firstFree = (DMABuffer*)dmaPtr->node.next;
alUnlink((ALLink*)dmaPtr);
/* add it to the used list */
if(lastDmaPtr) /* normal procedure */
{
alLink((ALLink*)dmaPtr,(ALLink*)lastDmaPtr);
}
else if(dmaState.firstUsed) /* jam at begining of list */
{
lastDmaPtr = dmaState.firstUsed;
dmaState.firstUsed = dmaPtr;
dmaPtr->node.next = (ALLink*)lastDmaPtr;
dmaPtr->node.prev = 0;
lastDmaPtr->node.prev = (ALLink*)dmaPtr;
}
else /* no buffers in list, this is the first one */
{
dmaState.firstUsed = dmaPtr;
dmaPtr->node.next = 0;
dmaPtr->node.prev = 0;
}
freeBuffer = dmaPtr->ptr;
delta = addr & 0x1;
addr -= delta;
dmaPtr->startAddr = addr;
dmaPtr->lastFrame = gFrameCt; /* mark it */
ioMesg = &dmaIOMesgBuf[nextDMA ++];
ioMesg->hdr.pri = OS_MESG_PRI_NORMAL;
ioMesg->hdr.retQueue = &dmaMessageQ;
ioMesg->dramAddr = freeBuffer;
ioMesg->devAddr = addr;
ioMesg->size = MAX_BUFFER_LENGTH;
if(tmp)
piHandle->transferInfo.cmdType = OS_OTHERS;
osEPiStartDma(piHandle, ioMesg, OS_READ);
return (int) osVirtualToPhysical(freeBuffer) + delta;
}
ALDMAproc dmaNew(DMAState **state)
{
int i;
if(!dmaState.initialized) /* only do this once */
{
dmaState.firstFree = &dmaBuffs[0];
for (i=0; i<NBUFFERS-1; i++)
{
alLink((ALLink*)&dmaBuffs[i+1],(ALLink*)&dmaBuffs[i]);
dmaBuffs[i].ptr = alHeapAlloc(&hp, 1, MAX_BUFFER_LENGTH);
}
dmaState.initialized = 1;
}
*state = &dmaState; /* state is never used in this case */
/* Initialize device handle */
cartromHandle = osCartRomInit();
driveromHandle = osDriveRomInit();
return dmaCallBack;
}
void CleanDMABuffs(void)
{
DMABuffer
*dmaPtr,
*nextPtr;
dmaPtr = dmaState.firstUsed;
while(dmaPtr)
{
nextPtr = (DMABuffer*)dmaPtr->node.next;
/* Can change this value. Should be at least one. */
/* Larger values mean more buffers needed, but fewer DMA's */
if(dmaPtr->lastFrame + 2 < gFrameCt) /* remove from used list */
{
if(dmaState.firstUsed == dmaPtr)
dmaState.firstUsed = (DMABuffer*)dmaPtr->node.next;
alUnlink((ALLink*)dmaPtr);
if(dmaState.firstFree)
alLink((ALLink*)dmaPtr,(ALLink*)dmaState.firstFree);
else
{
dmaState.firstFree = dmaPtr;
dmaPtr->node.next = 0;
dmaPtr->node.prev = 0;
}
}
dmaPtr = nextPtr;
}
}
/***********************************************************************
* initOsc, updateOsc and stopOsc are callbacks used to implement
* LFO's for vibrato and tremelo. Type values are set in the bank.inst
* file, and should always be different between vibrato and tremelo.
* Your initOsc routine should then be able to distinguish based on this
* value whether the LFO is for tremelo or vibrato. The audio library
* does not use the type value to know, but uses a different method, so
* applications are free to use any values 1-255 for types. (A type of
* zero means no vibrato or no tremelo.) In the initOsc routine, the
* application initializes the oscillator, allocates memory for the
* oscState and stores a pointer to that memory in the oscState handle.
* This pointer will be handed back to the application at each updateOsc
* call. The initVal is a pointer to either a u8, when the osc is a tremelo
* oscillator, or a f32 when the oscillator is a vibrato oscillator.
* This value should always be set. In the case of tremelo oscillators,
* the u8 should be a volume value from 0-127. In the case of the vibrato
* oscillator, the f32 is a ratio that the original pitch of the note should
* be multiplied by. A ratio of 1.0 will produce unity pitch, while a value
* of 0.5 will produce one octave lower, and 2.0 will produce one octave higher.
* initOsc returns a deltaTime in microseconds until the first call to
* updateOsc. If a deltaTime of zero is returned the initVal will be used
* but no further calls to the oscillator will be made. When an updateOsc
* call occurs the application should do any necessary calculations to update
* the oscillator, set the value pointed to by updateVal, and return the
* time, in microseconds, until the next updateOsc call. When a stopOsc
* call occurs, the application should do any necessary cleaning up, and
* freeing of memory. Given below are several examples of how to implement
* an LFO to control tremelo and vibrato.
*****************************************************************************/
/**********************************************************************
* OscType may be assigned in any way suited to the application. In
* this example, oscType's are assigned as follows:
* oscType = 1 A tremelo that uses a sin function
* oscType = 2 A tremelo that uses a square wave
* oscType = 3 A tremelo that uses a descending sawtooth
* oscType = 4 A tremelo that uses an ascending sawtooth
* oscType = 128 A vibrato that uses a sin function
* oscType = 129 A vibrato that uses a square wave
* oscType = 130 A vibrato that uses a descending sawtooth
* oscType = 131 A vibrato that uses an ascending sawtooth
**********************************************************************/
#define TREMELO_SIN 1
#define TREMELO_SQR 2
#define TREMELO_DSC_SAW 3
#define TREMELO_ASC_SAW 4
#define VIBRATO_SIN 128
#define VIBRATO_SQR 129
#define VIBRATO_DSC_SAW 130
#define VIBRATO_ASC_SAW 131
#define OSC_HIGH 0
#define OSC_LOW 1
#define TWO_PI 6.2831853
/*****************************************************************************
* oscDepth, oscRate and oscDelay may be used in anyway deemed appropriate
* by the programmer. These values are not used by the sequence player, but
* merely passed to the init routine. In this example, oscDelay is converted
* to microseconds by multiplying by 0x4000. But many other methods could have
* been chosen. In the vibrato examples, oscDepth is converted by the routine
* _depth2Cents. Cents can then easily be converted to ratio. For the tremelo
* examples, oscDepth is the max depth on the volume scale of 0-127. Sin
* oscillators are implemented using the sinf() library call.
*****************************************************************************/
typedef struct {
u8 rate;
u8 depth;
u8 oscCount;
} defData;
typedef struct {
u8 halfdepth;
u8 baseVol;
} tremSinData;
typedef struct {
u8 curVal;
u8 hiVal;
u8 loVal;
} tremSqrData;
typedef struct {
u8 baseVol;
u8 depth;
} tremSawData;
typedef struct {
f32 depthcents;
} vibSinData;
typedef struct {
f32 loRatio;
f32 hiRatio;
} vibSqrData;
typedef struct {
s32 hicents;
s32 centsrange;
} vibDSawData;
typedef struct {
s32 locents;
s32 centsrange;
} vibASawData;
typedef struct oscData_s {
struct oscData_s *next;
u8 type;
u8 stateFlags;
u16 maxCount;
u16 curCount;
union {
defData def;
tremSinData tsin;
tremSqrData tsqr;
tremSawData tsaw;
vibSinData vsin;
vibSqrData vsqr;
vibDSawData vdsaw;
vibASawData vasaw;
} data;
} oscData;
/*
* Number of osc states needed. In worst case will need two for each
* voice. But if tremelo and vibrato not used on all instruments will
* need less.
*/
#define OSC_STATE_COUNT 2*MAX_VOICES
oscData *freeOscStateList;
oscData oscStates[OSC_STATE_COUNT];
/************************************************************************
* _depth2Cents() convert a u8 (0-255) to a cents value. Convert using
* 1.03099303^(depth). This gives an exponential range of values from
* 1 to 2400. (2400 cents is 2 octaves). Lots of small values for
* good control of depth in musical applications, and a couple of
* really broad ranges for special effects.
************************************************************************/
f32 _depth2Cents(u8 depth)
{
f32 x = 1.03099303;
f32 cents = 1.0;
while(depth)
{
if(depth & 1)
cents *= x;
x *= x;
depth >>= 1;
}
return(cents);
}
ALMicroTime initOsc(void **oscState, f32 *initVal,u8 oscType,
u8 oscRate,u8 oscDepth,u8 oscDelay)
{
oscData *statePtr;
ALMicroTime deltaTime = 0;
if(freeOscStateList) /* yes there are oscStates available */
{
statePtr = freeOscStateList;
freeOscStateList = freeOscStateList->next;
statePtr->type = oscType;
*oscState = statePtr;
/*
* Convert delay into usec's, In this example, multiply by
* 0x4000, but could easily use another conversion method.
*/
deltaTime = oscDelay * 0x4000;
switch(oscType) /* set the initVal */
{
case TREMELO_SIN:
statePtr->curCount = 0;
statePtr->maxCount = 259-oscRate; /* gives values 4-259 */
statePtr->data.tsin.halfdepth = oscDepth >> 1;
statePtr->data.tsin.baseVol = AL_VOL_FULL - statePtr->data.tsin.halfdepth;
*initVal = (f32)statePtr->data.tsin.baseVol;
break;
case TREMELO_SQR:
statePtr->maxCount = 256-oscRate; /* values from 1-256 */
statePtr->curCount = statePtr->maxCount;
statePtr->stateFlags = OSC_HIGH;
statePtr->data.tsqr.loVal = AL_VOL_FULL-oscDepth;
statePtr->data.tsqr.hiVal = AL_VOL_FULL;
statePtr->data.tsqr.curVal = AL_VOL_FULL;
*initVal = (f32)AL_VOL_FULL;
break;
case TREMELO_DSC_SAW:
statePtr->maxCount = 256-oscRate;
statePtr->curCount = 0;
statePtr->data.tsaw.depth = oscDepth;
statePtr->data.tsaw.baseVol = AL_VOL_FULL;
*initVal = (f32)statePtr->data.tsaw.baseVol;
break;
case TREMELO_ASC_SAW:
statePtr->maxCount = 256-oscRate;
statePtr->curCount = 0;
statePtr->data.tsaw.depth = oscDepth;
statePtr->data.tsaw.baseVol = AL_VOL_FULL - oscDepth;
*initVal = (f32)statePtr->data.tsaw.baseVol;
break;
case VIBRATO_SIN:
statePtr->data.vsin.depthcents = _depth2Cents(oscDepth);
statePtr->curCount = 0;
statePtr->maxCount = 259-oscRate; /* gives values 4-259 */
*initVal = 1.0f; /* start at unity pitch */
break;
case VIBRATO_SQR:
{
s32 cents;
statePtr->maxCount = 256-oscRate; /* values from 1-256 */
statePtr->curCount = statePtr->maxCount;
statePtr->stateFlags = OSC_HIGH;
cents = _depth2Cents(oscDepth);
statePtr->data.vsqr.loRatio = alCents2Ratio(-cents);
statePtr->data.vsqr.hiRatio = alCents2Ratio(cents);
*initVal = statePtr->data.vsqr.hiRatio;
}
break;
case VIBRATO_DSC_SAW:
{
s32 cents;
statePtr->maxCount = 256-oscRate; /* values from 1-256 */
statePtr->curCount = statePtr->maxCount;
cents = _depth2Cents(oscDepth);
statePtr->data.vdsaw.hicents = cents;
statePtr->data.vdsaw.centsrange = 2 * cents;
*initVal = alCents2Ratio(statePtr->data.vdsaw.hicents);
}
break;
case VIBRATO_ASC_SAW:
{
s32 cents;
statePtr->maxCount = 256-oscRate; /* values from 1-256 */
statePtr->curCount = statePtr->maxCount;
cents = _depth2Cents(oscDepth);
statePtr->data.vasaw.locents = -cents;
statePtr->data.vasaw.centsrange = 2 * cents;
*initVal = alCents2Ratio(statePtr->data.vasaw.locents);
}
break;
}
}
return(deltaTime); /* if there are no oscStates, return zero, but if
oscState was available, return delay in usecs */
}
ALMicroTime updateOsc(void *oscState, f32 *updateVal)
{
f32 tmpFlt;
oscData *statePtr = (oscData*)oscState;
ALMicroTime deltaTime = AL_USEC_PER_FRAME; /* in this example callback every */
/* frame, but could be at any interval */
switch(statePtr->type) /* perform update calculations */
{
case TREMELO_SIN:
statePtr->curCount++;
if(statePtr->curCount >= statePtr->maxCount)
statePtr->curCount = 0;
tmpFlt = (f32)statePtr->curCount / (f32)statePtr->maxCount;
tmpFlt = sinf(tmpFlt*TWO_PI);
tmpFlt = tmpFlt * (f32)statePtr->data.tsin.halfdepth;
*updateVal = (f32)statePtr->data.tsin.baseVol + tmpFlt;
break;
case TREMELO_SQR:
if(statePtr->stateFlags == OSC_HIGH)
{
*updateVal = (f32)statePtr->data.tsqr.loVal;
statePtr->stateFlags = OSC_LOW;
}
else
{
*updateVal = (f32)statePtr->data.tsqr.hiVal;
statePtr->stateFlags = OSC_HIGH;
}
deltaTime *= statePtr->maxCount;
break;
case TREMELO_DSC_SAW:
statePtr->curCount++;
if(statePtr->curCount > statePtr->maxCount)
statePtr->curCount = 0;
tmpFlt = (f32)statePtr->curCount / (f32)statePtr->maxCount;
tmpFlt *= (f32)statePtr->data.tsaw.depth;
*updateVal = (f32)statePtr->data.tsaw.baseVol - tmpFlt;
break;
case TREMELO_ASC_SAW:
statePtr->curCount++;
if(statePtr->curCount > statePtr->maxCount)
statePtr->curCount = 0;
tmpFlt = (f32)statePtr->curCount / (f32)statePtr->maxCount;
tmpFlt *= (f32)statePtr->data.tsaw.depth;
*updateVal = (f32)statePtr->data.tsaw.baseVol + tmpFlt;
break;
case VIBRATO_SIN:
/* calculate a sin value (from -1 to 1) and multiply it by depthcents.
Then convert cents to ratio. */
statePtr->curCount++;
if(statePtr->curCount >= statePtr->maxCount)
statePtr->curCount = 0;
tmpFlt = (f32)statePtr->curCount / (f32)statePtr->maxCount;
tmpFlt = sinf(tmpFlt*TWO_PI) * statePtr->data.vsin.depthcents;
*updateVal = alCents2Ratio((s32)tmpFlt);
break;
case VIBRATO_SQR:
if(statePtr->stateFlags == OSC_HIGH)
{
statePtr->stateFlags = OSC_LOW;
*updateVal = statePtr->data.vsqr.loRatio;
}
else
{
statePtr->stateFlags = OSC_HIGH;
*updateVal = statePtr->data.vsqr.hiRatio;
}
deltaTime *= statePtr->maxCount;
break;
case VIBRATO_DSC_SAW:
statePtr->curCount++;
if(statePtr->curCount > statePtr->maxCount)
statePtr->curCount = 0;
tmpFlt = (f32)statePtr->curCount / (f32)statePtr->maxCount;
tmpFlt *= (f32)statePtr->data.vdsaw.centsrange;
tmpFlt = (f32)statePtr->data.vdsaw.hicents - tmpFlt;
*updateVal = alCents2Ratio((s32)tmpFlt);
break;
case VIBRATO_ASC_SAW:
statePtr->curCount++;
if(statePtr->curCount > statePtr->maxCount)
statePtr->curCount = 0;
tmpFlt = (f32)statePtr->curCount / (f32)statePtr->maxCount;
tmpFlt *= (f32)statePtr->data.vasaw.centsrange;
tmpFlt += (f32)statePtr->data.vasaw.locents;
*updateVal = alCents2Ratio((s32)tmpFlt);
break;
}
return(deltaTime);
}
void stopOsc(void *oscState)
{
((oscData*)oscState)->next = freeOscStateList;
freeOscStateList = (oscData*)oscState;
}
/*
* BOOT
*/
boot(void *arg)
{
osInitialize();
osCreateThread(&mainThread, 1, (void(*)(void *))mainproc, arg,
((u8 *) mainThreadStack) + STACKSIZE, 10);
osStartThread(&mainThread);
}
/*
* Idle thread
*/
static void mainproc(u8 *argv)
{
/*
* Initialize video
*/
osCreateViManager(OS_PRIORITY_VIMGR);
osViSetMode(&osViModeTable[OS_VI_NTSC_LAN1]);
/*
* Start PI Manager
*/
osCreatePiManager((OSPri) 150, &PiMessageQ, PiMessages, DMA_QUEUE_SIZE);
/*
* Create and start game(main) thread
*/
osCreateThread(&gameThread, 3, (void(*)(void *))gameproc, argv,
((u8 *) gameThreadStack) + STACKSIZE, 10);
osStartThread(&gameThread);
/*
* Become the idle thread
*/
osSetIntMask( OS_IM_ALL );
osSetThreadPri( 0, 0 );
for (;;);
}
/*
* Main(game) thread
*/
static void gameproc(u8 *argv)
{
ALCSPlayer
sequencePlayer,
*seqp = &sequencePlayer;
ALCSeq
sequence,
*seq = &sequence;
ALBank
*waveBank;
Acmd
*cmdlp;
OSTask
*tlistp;
s16
*audioOp;
s32
frameSize,
minFrameSize,
buf,
clcount,
samplesLeft = 0;
u32
i,
tmp_u32;
f32
fsize;
oscData
*oscStatePtr;
/*
* Message queue for PI manager return messages
*/
osCreateMesgQueue(&dmaMessageQ, dmaMessageBuf, DMA_QUEUE_SIZE);
/*
* Set up message queue for TASK interrupts
*/
osCreateMesgQueue(&taskMessageQ, &taskMessageBuf, 1);
osSetEventMesg(OS_EVENT_SP, &taskMessageQ, NULL);
osSendMesg(&taskMessageQ, NULL, OS_MESG_BLOCK);
/*
* Set up message queue for video interrupts
*/
osCreateMesgQueue(&retraceMessageQ, &retraceMessageBuf, 1);
osViSetEvent(&retraceMessageQ, NULL, NUM_FIELDS);
/*
* Set up message queue for preNMI interrupts
*/
osCreateMesgQueue(&resetMessageQ, &resetMessageBuf, 1);
osSetEventMesg(OS_EVENT_PRENMI, &resetMessageQ, NULL);
/*
* Audio heap
*/
alHeapInit(&hp, (u8 *) audioHeap, AUDIO_HEAP_SIZE);
/*
* Allocate storage for command list and task headers
*/
cmdList[0] = alHeapAlloc(&hp, 1, MAX_CLIST_SIZE*sizeof(Acmd));
cmdList[1] = alHeapAlloc(&hp, 1, MAX_CLIST_SIZE*sizeof(Acmd));
tlist[0] = alHeapAlloc(&hp, 1, sizeof(OSTask));
tlist[1] = alHeapAlloc(&hp, 1, sizeof(OSTask));
audioBuffer[0] = alHeapAlloc(&hp, 1, sizeof(s32)*MAX_AUDIO_LENGTH);
audioBuffer[1] = alHeapAlloc(&hp, 1, sizeof(s32)*MAX_AUDIO_LENGTH);
audioBuffer[2] = alHeapAlloc(&hp, 1, sizeof(s32)*MAX_AUDIO_LENGTH);
/*
* Initialize 64DD
*/
DiskInitialize();
/*
* Read .ctl file
*/
tmp_u32 = (u32)_wavebankSegmentDiskEnd - (u32)_wavebankSegmentDiskStart;
DiskRead((u32)_wavebankSegmentDiskStart, waveBankFile, tmp_u32);
/*
* Read .tbl file
*/
tmp_u32 = (u32)_wavetableSegmentDiskEnd - (u32)_wavetableSegmentDiskStart;
DiskRead((u32)_wavetableSegmentDiskStart, waveTableFile, tmp_u32);
dd_alBnkfNew((ALBankFile *)waveBankFile, (u8 *)waveTableFile);
waveBank = ((ALBankFile *)waveBankFile)->bankArray[0];
/*
* Read sequence data
*/
tmp_u32 = (u32)_seqSegmentDiskEnd - (u32)_seqSegmentDiskStart;
DiskRead((u32)_seqSegmentDiskStart, seqData, tmp_u32);
/*
* Initialize DAC output rate
*/
c.outputRate = osAiSetFrequency(OUTPUT_RATE);
fsize = (f32) NUM_FIELDS * c.outputRate / (f32) 60;
frameSize = (s32) fsize;
if (frameSize < fsize)
frameSize++;
if (frameSize & 0xf)
frameSize = (frameSize & ~0xf) + 0x10;
minFrameSize = frameSize - 16;
/*
* Audio synthesizer initialization
*/
c.maxVVoices = MAX_VOICES;
c.maxPVoices = MAX_VOICES;
c.maxUpdates = MAX_UPDATES;
c.dmaproc = &dmaNew;
c.heap = &hp;
c.fxType = AL_FX_SMALLROOM;
alInit(&g, &c);
/*
* For vibrato and tremelo
*/
freeOscStateList = &oscStates[0];
oscStatePtr = &oscStates[0];
for(i=0;i<(OSC_STATE_COUNT-1);i++)
{
oscStatePtr->next = &oscStates[i+1];
oscStatePtr = oscStatePtr->next;
}
oscStatePtr->next = 0; /* set last pointer to zero */
/*
* Sequence player initialization
*/
seqc.maxVoices = MAX_VOICES;
seqc.maxEvents = EVT_COUNT;
seqc.maxChannels = 16;
seqc.heap = &hp;
seqc.initOsc = &initOsc;
seqc.updateOsc = &updateOsc;
seqc.stopOsc = &stopOsc;
#ifdef _DEBUG
seqc.debugFlags = NO_VOICE_ERR_MASK |NOTE_OFF_ERR_MASK | NO_SOUND_ERR_MASK;
#endif
alCSPNew(seqp, &seqc);
/*
* Allocate wavebank and sequence data
*/
alCSPSetBank(seqp, waveBank);
alCSeqNew(seq, seqData);
alCSPSetSeq(seqp, seq);
/*
* Main loop
*/
while (1){
alCSPPlay(seqp);
/*
* Sync up on vertical retrace - read more than 1 to be sure!
*/
(void)osRecvMesg(&retraceMessageQ, NULL, OS_MESG_BLOCK);
(void)osRecvMesg(&retraceMessageQ, NULL, OS_MESG_BLOCK);
/*
* Note that this must be a do-while in order for seqp's state to
* get updated during the alAudioFrame processing.
*/
do {
/*
* Where the task list goes in DRAM
*/
tlistp = tlist[curBuf];
cmdlp = cmdList[curBuf];
/*
* Where the audio goes in DRAM
*/
buf = curAudioBuf % 3;
audioOp = (s16 *) osVirtualToPhysical(audioBuffer[buf]);
audioSamples[buf] = 16 + (frameSize - samplesLeft + EXTRA_SAMPLES) & ~0xf;
if (audioSamples[buf] < minFrameSize)
audioSamples[buf] = minFrameSize;
/*
* Call the frame handler
*/
cmdlp = alAudioFrame(cmdlp, &clcount, audioOp, audioSamples[buf]);
/*
* Build the audio task
*/
tlistp->t.type = M_AUDTASK;
tlistp->t.flags = 0x0;
tlistp->t.ucode_boot = (u64 *)rspbootTextStart;
tlistp->t.ucode_boot_size = ((s32)rspbootTextEnd -
(s32)rspbootTextStart);
tlistp->t.ucode = (u64 *) aspMainTextStart;
tlistp->t.ucode_size = SP_UCODE_SIZE;
tlistp->t.ucode_data = (u64 *) aspMainDataStart;
tlistp->t.ucode_data_size = SP_UCODE_DATA_SIZE;
tlistp->t.data_ptr = (u64 *) cmdList[curBuf];
tlistp->t.data_size = (cmdlp - cmdList[curBuf]) * sizeof(Acmd);
/*
* Video does nothing - just syncs up on the frame boundary.
*/
(void)osRecvMesg(&retraceMessageQ, NULL, OS_MESG_BLOCK);
/*
* Find out how many samples left in the currently running
* audio buffer
*/
samplesLeft = IO_READ(AI_LEN_REG)>>2;
/*
* The last task should have finished before the frame message
* so this just clears the message queue
*/
(void)osRecvMesg(&taskMessageQ, NULL, OS_MESG_BLOCK);
/*
* Point the DAC at the next buffer
*/
buf = (curAudioBuf-1) % 3;
osAiSetNextBuffer(audioBuffer[buf], audioSamples[buf]<<2);
/*
* Empty the dma queue to make sure all DMAs have completed.
* If the app blocks here it is a bug since resources must
* be managed so that all DMAs complete.
*/
for (i=0; i<nextDMA; i++)
if (osRecvMesg(&dmaMessageQ, NULL, OS_MESG_NOBLOCK) == -1)
osSyncPrintf("Dma not done\n");
/*
* Flush the cache and start task on RSP
*/
osWritebackDCacheAll();
osSpTaskStart(tlistp);
CleanDMABuffs();
/*
* Check preNMI
*/
if(!osRecvMesg(&resetMessageQ, NULL, OS_MESG_NOBLOCK))
LeoReset();
/*
* Swap buffers for wavetable storage and output
*/
gFrameCt++;
curBuf ^= 1;
curAudioBuf++;
nextDMA = 0;
} while (seqp->state != AL_STOPPED);
alCSeqNew(seq, seqData);
}
alCSPStop(seqp);
alClose(&g);
}
/*
* Initialize 64DD
*/
void DiskInitialize(void)
{
s32
error;
osCreateMesgQueue(&diskQ, &diskQBuf, 1);
error = LeoCreateLeoManager((OSPri)OS_PRIORITY_LEOMGR - 1,
(OSPri)OS_PRIORITY_LEOMGR,
LeoMessages, NUM_LEO_MESGS);
if(error == LEO_ERROR_DEVICE_COMMUNICATION_FAILURE){
osSyncPrintf("Error %d\n", error);
osSyncPrintf("Please read 64DD manual.\n");
for(;;);
}
CheckDiskInsert();
if(bcmp((void *)&leoBootID, (void *)&diskID, sizeof(LEODiskID))){
osSyncPrintf("You insert a bad disk. Please reboot 64DD.\n");
for(;;);
}
}
/*
* Disk insert check
*/
void CheckDiskInsert(void)
{
s32
loop_flag = 1,
error,
old_error = -100;
do {
LeoReadDiskID(&cmdBlock, &diskID, &diskQ);
osRecvMesg(&diskQ, (OSMesg *)&error, OS_MESG_BLOCK);
switch(error) {
case LEO_ERROR_GOOD:
loop_flag = 0;
break;
case LEO_ERROR_QUEUE_FULL:
break;
case LEO_ERROR_EJECTED_ILLEGALLY_RESUME:
if(error != old_error){
osSyncPrintf("Error %d\n", error);
osSyncPrintf("Please don't eject the disk when the accsess-lamp is blinking.\n");
}
break;
case LEO_ERROR_MEDIUM_NOT_PRESENT:
if(error != old_error){
osSyncPrintf("Error %d\n", error);
osSyncPrintf("Please insert a disk.\n");
}
break;
case LEO_ERROR_INCOMPATIBLE_MEDIUM_INSTALLED:
osSyncPrintf("Error %d\n", error);
osSyncPrintf("Please read 64DD manual.\n");
while(!CheckDiskEject());
break;
case LEO_ERROR_DIAGNOSTIC_FAILURE:
osSyncPrintf("Error %d\n", error);
osSyncPrintf("Please eject the disk and then insert it again.\n");
while(!CheckDiskEject());
break;
case LEO_ERROR_COMMAND_TERMINATED:
default:
osSyncPrintf("Error %d\n", error);
osSyncPrintf("Please read 64DD manual.\n");
for(;;);
}
old_error = error;
} while(loop_flag);
}
/*
* Disk eject check
*/
s32 CheckDiskEject(void)
{
s32
loop_flag = 1,
error;
do {
LeoSpdlMotor(&cmdBlock, LEO_MOTOR_SLEEP, &diskQ);
osRecvMesg(&diskQ, (OSMesg *)&error, OS_MESG_BLOCK);
switch(error){
case LEO_ERROR_GOOD:
case LEO_ERROR_DIAGNOSTIC_FAILURE:
error = 0;
case LEO_ERROR_MEDIUM_NOT_PRESENT:
case LEO_ERROR_MEDIUM_MAY_HAVE_CHANGED:
case LEO_ERROR_EJECTED_ILLEGALLY_RESUME:
loop_flag = 0;
break;
case LEO_ERROR_QUEUE_FULL:
break;
case LEO_ERROR_COMMAND_TERMINATED:
default:
osSyncPrintf("Error %d\n", error);
osSyncPrintf("Please read 64DD manual.\n");
for(;;);
}
} while(loop_flag);
return error;
}
/*
* Read disk (only)
*/
void DiskRead(u32 srcLBA, void *destDRAM, u32 nLBAs)
{
s32
loop_flag = 1,
error;
do {
osWritebackDCacheAll();
LeoReadWrite(&cmdBlock,
OS_READ,
srcLBA,
destDRAM,
nLBAs,
&diskQ);
osRecvMesg(&diskQ, (OSMesg *)&error, OS_MESG_BLOCK);
switch(error){
case LEO_ERROR_GOOD:
loop_flag = 0;
break;
case LEO_ERROR_QUEUE_FULL:
break;
case LEO_ERROR_DIAGNOSTIC_FAILURE:
osSyncPrintf("Error %d\n", error);
osSyncPrintf("Please eject the disk and then insert it again.\n");
do {
while(!CheckDiskEject());
CheckDiskInsert();
if(bcmp((void *)&leoBootID, (void *)&diskID, sizeof(LEODiskID)))
osSyncPrintf("You insert a bad disk. Please check the disk.\n");
else
break;
} while(1);
break;
case LEO_ERROR_EJECTED_ILLEGALLY_RESUME:
case LEO_ERROR_MEDIUM_NOT_PRESENT:
osSyncPrintf("Error %d\n", error);
if(error == LEO_ERROR_EJECTED_ILLEGALLY_RESUME)
osSyncPrintf("Please don't eject the disk when the accsess-lamp is blinking.\n");
else
osSyncPrintf("Please insert a disk.\n");
case LEO_ERROR_MEDIUM_MAY_HAVE_CHANGED:
do {
CheckDiskInsert();
if(!bcmp((void *)&leoBootID, (void *)&diskID, sizeof(LEODiskID)))
break;
osSyncPrintf("You insert a bad disk. Please check the disk.\n");
while(!CheckDiskEject());
} while(1);
break;
case LEO_ERROR_COMMAND_TERMINATED:
default:
osSyncPrintf("Error %d\n", error);
osSyncPrintf("Please read 64DD manual.\n");
for(;;);
}
} while(loop_flag);
}