libcm/cmAudioAggDev.c

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2012-10-30 03:52:39 +00:00
#include "cmGlobal.h"
#include "cmRpt.h"
#include "cmErr.h"
#include "cmCtx.h"
#include "cmMem.h"
#include "cmMallocDebug.h"
#include "cmTime.h"
2012-10-30 03:52:39 +00:00
#include "cmAudioPort.h"
#include "cmAudioAggDev.h"
#include "cmThread.h" // cmThUIntIncr()
#include "cmApBuf.h" // only needed for cmApBufTest().
enum
{
kBufArrayCnt = 2
};
struct cmApAgg_str;
typedef struct
{
unsigned physDevIdx;
struct cmApAgg_str* ap;
unsigned iChIdx;
unsigned iChCnt;
unsigned oChIdx;
unsigned oChCnt;
} cmApAggDev_t;
typedef struct cmApAgg_str
{
cmChar_t* label; // agg. device label
unsigned aggDevIdx; // agg. device index
unsigned sysDevIdx; // system device index
unsigned devCnt; // count of phys devices
cmApAggDev_t* devArray; // devArray[ devCnt ] - physical device array
unsigned iChCnt; // sum of phys device input channels
unsigned oChCnt; // sum of phys device output channels
double srate; // agg. dev sample rate
unsigned framesPerCycle; // agg. dev frames per cycle
unsigned flags; // kAgInFl | kAgOutFl
cmApCallbackPtr_t cbFunc; // client supplied callback func
void* cbArg; // client supplied callback func arg.
bool startedFl; // true if the agg. device is started
struct cmApAgg_str* link; // _cmAg.list link
} cmApAgg_t;
typedef struct
{
cmErr_t err;
cmApAgg_t* list;
} cmApAggMain_t;
cmApAggMain_t _cmAg;
void _cmApAggCb( cmApAudioPacket_t* inPktArray, unsigned inPktCnt, cmApAudioPacket_t* outPktArray, unsigned outPktCnt )
{
unsigned i;
cmApAudioPacket_t pkt;
for(i=0; i<inPktCnt; ++i)
{
cmApAggDev_t* dp = (cmApAggDev_t*)inPktArray[i].userCbPtr;
pkt = inPktArray[i];
pkt.devIdx = dp->ap->sysDevIdx;
pkt.begChIdx = dp->iChIdx;
pkt.userCbPtr = dp->ap->cbArg;
dp->ap->cbFunc( &pkt, 1, NULL, 0 );
}
for(i=0; i<outPktCnt; ++i)
{
cmApAggDev_t* dp = (cmApAggDev_t*)outPktArray[i].userCbPtr;
pkt = outPktArray[i];
pkt.devIdx = dp->ap->sysDevIdx;
pkt.begChIdx = dp->oChIdx;
pkt.userCbPtr = dp->ap->cbArg;
dp->ap->cbFunc( NULL, 0, &pkt, 1 );
}
}
void _cmApAgDeleteAggDev( cmApAgg_t* ap )
{
cmApAgg_t* cp = _cmAg.list;
cmApAgg_t* pp = NULL;
while( cp != NULL )
{
if( cp == ap )
{
if( pp == NULL )
_cmAg.list = cp->link;
else
pp->link = cp->link;
cmMemFree(ap->label);
cmMemFree(ap->devArray);
cmMemFree(ap);
return;
}
pp = cp;
cp = cp->link;
}
}
cmAgRC_t cmApAggAllocate( cmRpt_t* rpt )
{
cmAgRC_t rc = kOkAgRC;
cmErrSetup(&_cmAg.err,rpt,"cmAudioAggDev");
_cmAg.list = NULL;
return rc;
}
cmAgRC_t cmApAggFree()
{
cmAgRC_t rc = kOkAgRC;
while( _cmAg.list != NULL )
_cmApAgDeleteAggDev(_cmAg.list );
return rc;
}
cmAgRC_t cmApAggInitialize( cmRpt_t* rpt, unsigned baseApDevIdx )
{
cmApAgg_t* ap = _cmAg.list;
unsigned i;
assert( baseApDevIdx == cmApDeviceCount() );
for(i=0; ap!=NULL; ap=ap->link,++i)
{
ap->sysDevIdx = cmApDeviceCount() + i;
ap->iChCnt = 0;
ap->oChCnt = 0;
unsigned i;
for(i=0; i<ap->devCnt; ++i)
{
ap->devArray[i].iChIdx = ap->iChCnt;
ap->devArray[i].oChIdx = ap->oChCnt;
ap->devArray[i].iChCnt = cmApDeviceChannelCount(ap->devArray[i].physDevIdx,true);
ap->devArray[i].oChCnt = cmApDeviceChannelCount(ap->devArray[i].physDevIdx,false);
ap->iChCnt += ap->devArray[i].iChCnt;
ap->oChCnt += ap->devArray[i].oChCnt;
}
}
return kOkAgRC;
}
cmAgRC_t cmApAggFinalize()
{ return kOkAgRC; }
cmAgRC_t cmApAggCreateDevice(
const cmChar_t* label,
unsigned devCnt,
const unsigned physDevIdxArray[],
unsigned flags )
{
cmAgRC_t rc = kOkAgRC;
unsigned i;
if( devCnt < 2 )
return cmErrMsg(&_cmAg.err,kMustAggTwoAgRC,"Cannot aggregate less than two devices.");
/*
for(i=0; i<devCnt; ++i)
{
unsigned physDevIdx = physDevIdxArray[i];
if( cmApAggIsDeviceAggregated(physDevIdx) )
return cmErrMsg(&_cmAg.err,kDevAlreadyAggAgRC,"The physical device associated with index '%i' ('%s') has already been assigned to another aggregated device.",physDevIdx,cmStringNullGuard(cmApDeviceLabel(physDevIdx)));
if( cmApDeviceIsStarted(physDevIdx) )
return cmErrMsg(&_cmAg.err,kCantUseStartedDevAgRC,"The physical device associated with index '%i' ('%s') cannot be aggregated while it is running.",physDevIdx,cmStringNullGuard(cmApDeviceLabel(physDevIdx)));
}
*/
cmApAgg_t* ap = cmMemAllocZ(cmApAgg_t,1);
ap->label = cmMemAllocStr(label==NULL?"Aggregated Device":label);
ap->devArray = cmMemAllocZ(cmApAggDev_t,devCnt);
ap->aggDevIdx = cmApAggDeviceCount();
ap->sysDevIdx = cmInvalidIdx;
ap->devCnt = devCnt;
ap->iChCnt = 0;
ap->oChCnt = 0;
for(i=0; i<devCnt; ++i)
{
ap->devArray[i].ap = ap;
ap->devArray[i].physDevIdx = physDevIdxArray[i];
}
ap->link = _cmAg.list;
_cmAg.list = ap;
return rc;
}
cmApAgg_t* _cmApAggDevIdxToPtr( unsigned aggDevIdx )
{
cmApAgg_t* ap = _cmAg.list;
unsigned i = 0;
for(; ap!=NULL; ap=ap->link,++i)
if( ap->aggDevIdx == aggDevIdx )
return ap;
return NULL;
}
cmAgRC_t _cmApAggGetAgg( unsigned aggDevIdx, cmApAgg_t** retPtrPtr )
{
if((*retPtrPtr = _cmApAggDevIdxToPtr(aggDevIdx)) == NULL )
return cmErrMsg(&_cmAg.err,kInvalidDevIdxAgRC,"The aggregate system device index '%i' is invalid.");
return kOkAgRC;
}
bool cmApAggIsDeviceAggregated( unsigned physDevIdx )
{
cmApAgg_t* ap = _cmAg.list;
for(; ap!=NULL; ap=ap->link)
{
unsigned i;
for(i=0; i<ap->devCnt; ++i)
if( ap->devArray[i].physDevIdx == physDevIdx )
return true;
}
return false;
}
cmAgRC_t cmApAggDeviceCount()
{
unsigned devCnt=0;
cmApAgg_t* ap = _cmAg.list;
for(; ap!=NULL; ap=ap->link)
++devCnt;
return devCnt;
}
const char* cmApAggDeviceLabel( unsigned aggDevIdx )
{
cmApAgg_t* ap;
cmAgRC_t rc;
if((rc = _cmApAggGetAgg(aggDevIdx, &ap )) == kOkAgRC )
return ap->label;
return NULL;
}
unsigned cmApAggDeviceChannelCount( unsigned aggDevIdx, bool inputFl )
{
cmApAgg_t* ap;
cmAgRC_t rc;
if((rc = _cmApAggGetAgg(aggDevIdx, &ap )) == kOkAgRC )
return inputFl ? ap->iChCnt : ap->oChCnt;
return 0;
}
double cmApAggDeviceSampleRate( unsigned aggDevIdx )
{
cmApAgg_t* ap;
cmAgRC_t rc;
if((rc = _cmApAggGetAgg(aggDevIdx, &ap )) == kOkAgRC )
return ap->srate;
return 0;
}
unsigned cmApAggDeviceFramesPerCycle( unsigned aggDevIdx, bool inputFl )
{
cmApAgg_t* ap;
cmAgRC_t rc;
if((rc = _cmApAggGetAgg(aggDevIdx, &ap )) == kOkAgRC )
return ap->framesPerCycle;
return 0;
}
cmAgRC_t cmApAggDeviceSetup(
unsigned aggDevIdx,
double srate,
unsigned framesPerCycle,
cmApCallbackPtr_t callbackPtr,
void* userCbPtr )
{
cmApAgg_t* ap;
cmAgRC_t rc;
unsigned i;
if((rc = _cmApAggGetAgg(aggDevIdx, &ap )) != kOkAgRC )
return rc;
if((rc = cmApAggDeviceStop(aggDevIdx)) != kOkAgRC )
return rc;
for(i=0; i<ap->devCnt; ++i)
{
unsigned physDevIdx = ap->devArray[i].physDevIdx;
cmApAggDev_t* devPtr = ap->devArray + i;
if( cmApDeviceSetup( physDevIdx, srate, framesPerCycle, _cmApAggCb, devPtr ) != kOkApRC )
rc = cmErrMsg(&_cmAg.err,kPhysDevSetupFailAgRC,"The physical device (index:%i '%s') setup failed for sample rate:%f frames-per-cycle:%i.",physDevIdx,cmStringNullGuard(cmApDeviceLabel(physDevIdx)),srate,framesPerCycle);
}
if( rc == kOkAgRC )
{
ap->cbFunc = callbackPtr;
ap->cbArg = userCbPtr;
}
return rc;
}
cmAgRC_t cmApAggDeviceStart( unsigned aggDevIdx )
{
cmAgRC_t rc = kOkAgRC;
cmApAgg_t* ap;
unsigned i;
if((rc = _cmApAggGetAgg(aggDevIdx, &ap )) != kOkAgRC )
return rc;
for(i=0; i<ap->devCnt; ++i)
{
unsigned physDevIdx = ap->devArray[i].physDevIdx;
if( cmApDeviceStart( physDevIdx ) != kOkApRC )
return cmErrMsg(&_cmAg.err,kPhysDevStartFailAgRC,"The physical device (index:%i '%s') start failed.",physDevIdx,cmStringNullGuard(cmApDeviceLabel(physDevIdx)));
}
ap->startedFl = true;
return rc;
}
cmAgRC_t cmApAggDeviceStop( unsigned aggDevIdx )
{
cmAgRC_t rc = kOkAgRC;
cmApAgg_t* ap;
unsigned i;
if((rc = _cmApAggGetAgg(aggDevIdx, &ap )) != kOkAgRC )
return rc;
for(i=0; i<ap->devCnt; ++i)
{
unsigned physDevIdx = ap->devArray[i].physDevIdx;
if( cmApDeviceStop( physDevIdx ) != kOkApRC )
return cmErrMsg(&_cmAg.err,kPhysDevStartFailAgRC,"The physical device (index:%i '%s') start failed.",physDevIdx,cmStringNullGuard(cmApDeviceLabel(physDevIdx)));
}
ap->startedFl = false;
return rc;
}
bool cmApAggDeviceIsStarted( unsigned aggDevIdx )
{
cmApAgg_t* ap;
if(_cmApAggGetAgg(aggDevIdx, &ap ) != kOkAgRC )
return false;
return ap->startedFl;
}
typedef struct
{
unsigned bufCnt; // 2=double buffering 3=triple buffering
unsigned chIdx; // first test channel
unsigned chCnt; // count of channels to test
unsigned framesPerCycle; // DSP frames per cycle
unsigned bufFrmCnt; // count of DSP frames used by the audio buffer (bufCnt * framesPerCycle)
unsigned bufSmpCnt; // count of samples used by the audio buffer (chCnt * bufFrmCnt)
unsigned inDevIdx; // input device index
unsigned outDevIdx; // output device index
double srate; // audio sample rate
unsigned meterMs; // audio meter buffer length
// param's and state for cmApSynthSine()
bool synthFl;
unsigned phase; // sine synth phase
double frqHz; // sine synth frequency in Hz
// buffer and state for cmApCopyIn/Out()
cmApSample_t* buf; // buf[bufSmpCnt] - circular interleaved audio buffer
unsigned bufInIdx; // next input buffer index
unsigned bufOutIdx; // next output buffer index
unsigned bufFullCnt; // count of full samples
unsigned cbCnt; // count the callback
unsigned underunCnt; //
unsigned overunCnt;
double* iMeter; // iMeter[ chCnt ]
FILE* ifp;
FILE* ofp;
} cmApAggPortTestRecd;
// The application can request any block of channels from the device. The packets are provided with the starting
// device channel and channel count. This function converts device channels and channel counts to buffer
// channel indexes and counts.
//
// Example:
// input output
// i,n i n
// App: 0,4 0 1 2 3 -> 2 2
// Pkt 2,8 2 3 4 5 6 7 8 -> 0 2
//
// The return value is the count of application requested channels located in this packet.
//
// input: *appChIdxPtr and appChCnt describe a block of device channels requested by the application.
// *pktChIdxPtr and pktChCnt describe a block of device channels provided to the application
//
// output:*appChIdxPtr and <return value> describe a block of app buffer channels which will send/recv samples.
// *pktChIdxPtr and <return value> describe a block of pkt buffer channels which will send/recv samples
//
unsigned _cmApAggDeviceToBuffer( unsigned* appChIdxPtr, unsigned appChCnt, unsigned* pktChIdxPtr, unsigned pktChCnt )
{
unsigned abi = *appChIdxPtr;
unsigned aei = abi+appChCnt-1;
unsigned pbi = *pktChIdxPtr;
unsigned pei = pbi+pktChCnt-1;
// if the ch's rqstd by the app do not overlap with this packet - return false.
if( aei < pbi || abi > pei )
return 0;
// if the ch's rqstd by the app overlap with the beginning of the pkt channel block
if( abi < pbi )
{
appChCnt -= pbi - abi;
*appChIdxPtr = pbi - abi;
*pktChIdxPtr = 0;
}
else
{
// the rqstd ch's begin inside the pkt channel block
pktChCnt -= abi - pbi;
*pktChIdxPtr = abi - pbi;
*appChIdxPtr = 0;
}
// if the pkt channels extend beyond the rqstd ch block
if( aei < pei )
pktChCnt -= pei - aei;
else
appChCnt -= aei - pei; // the rqstd ch's extend beyond or coincide with the pkt block
// the returned channel count must always be the same for both the rqstd and pkt
return cmMin(appChCnt,pktChCnt);
}
// synthesize a sine signal into an interleaved audio buffer
unsigned _cmApAggSynthSine( cmApAggPortTestRecd* r, float* p, unsigned chIdx, unsigned chCnt, unsigned frmCnt, unsigned phs, double hz )
{
long ph = 0;
unsigned i;
unsigned bufIdx = r->chIdx;
unsigned bufChCnt;
if( (bufChCnt = _cmApAggDeviceToBuffer( &bufIdx, r->chCnt, &chIdx, chCnt )) == 0)
return phs;
//if( r->cbCnt < 50 )
// printf("ch:%i cnt:%i ch:%i cnt:%i bi:%i bcn:%i\n",r->chIdx,r->chCnt,chIdx,chCnt,bufIdx,bufChCnt);
for(i=bufIdx; i<bufIdx+bufChCnt; ++i)
{
unsigned j;
float* op = p + i;
ph = phs;
for(j=0; j<frmCnt; j++, op+=chCnt, ph++)
{
*op = (float)(0.9 * sin( 2.0 * M_PI * hz * ph / r->srate ));
}
}
return ph;
}
// Copy the audio samples in the interleaved audio buffer sp[srcChCnt*srcFrameCnt]
// to the internal record buffer.
void _cmApAggCopyIn( cmApAggPortTestRecd* r, const cmApSample_t* sp, unsigned srcChIdx, unsigned srcChCnt, unsigned srcFrameCnt )
{
unsigned i,j;
unsigned chCnt = cmMin(r->chCnt,srcChCnt);
// write the incoming sample to an output file for debugging
if( r->ifp != NULL )
if( fwrite(sp,sizeof(cmApSample_t),srcChCnt*srcFrameCnt,r->ifp) != srcChCnt*srcFrameCnt )
printf("file write fail.\n");
// zero the input meter array
for(i=0; i<r->chCnt; ++i)
r->iMeter[i] = 0;
for(i=0; i<srcFrameCnt; ++i)
{
// copy samples from the src to the buffer - both src and buffer are interleaved
for(j=0; j<chCnt; ++j)
{
r->buf[ r->bufInIdx + j ] = sp[ (i*srcChCnt) + srcChIdx + j ];
// record the max value in the input meter array
if( r->buf[ r->bufInIdx + j ] > r->iMeter[j] )
r->iMeter[j] = r->buf[ r->bufInIdx + j ];
}
// zero channels that are not used in the buffer
for(; j<r->chCnt; ++j)
r->buf[ r->bufInIdx + j ] = 0;
// advance to the next frame
r->bufInIdx = (r->bufInIdx+r->chCnt) % r->bufFrmCnt;
}
//r->bufFullCnt = (r->bufFullCnt + srcFrameCnt) % r->bufFrmCnt;
cmThUIntIncr(&r->bufFullCnt,srcFrameCnt);
if( r->bufFullCnt > r->bufFrmCnt )
{
//printf("Input buffer overrun.\n");
++r->overunCnt;
r->bufFullCnt = 0;
}
}
// Copy audio samples out of the internal record buffer into dp[dstChCnt*dstFrameCnt].
void _cmApAggCopyOut( cmApAggPortTestRecd* r, cmApSample_t* dp, unsigned dstChIdx, unsigned dstChCnt, unsigned dstFrameCnt )
{
// if there are not enough samples available to fill the destination
// buffer then zero the dst buf.
if( r->bufFullCnt < dstFrameCnt )
{
//printf("Empty Output Buffer %i < %i\n",r->bufFullCnt,dstFrameCnt);
memset( dp, 0, dstFrameCnt*dstChCnt*sizeof(cmApSample_t) );
++r->underunCnt;
}
else
{
unsigned i,j;
unsigned chCnt = cmMin(dstChCnt,r->chCnt);
for(i=0; i<dstFrameCnt; ++i)
{
// copy the stored buffer samples to the dst buffer
for(j=0; j<chCnt; ++j)
dp[ (i*dstChCnt) + dstChIdx + j ] = r->buf[ r->bufOutIdx + j ];
// zero unset channels in the dst buffer
for(; j<dstChCnt; ++j)
dp[ (i*dstChCnt) + dstChIdx + j ] = 0;
r->bufOutIdx = (r->bufOutIdx + r->chCnt) % r->bufFrmCnt;
}
cmThUIntDecr(&r->bufFullCnt,dstFrameCnt);
}
if( r->ofp != NULL )
fwrite(dp,sizeof(cmApSample_t),dstChCnt*dstFrameCnt,r->ofp);
}
// Audio port callback function called from the audio device thread.
void _cmApAggPortCb( cmApAudioPacket_t* inPktArray, unsigned inPktCnt, cmApAudioPacket_t* outPktArray, unsigned outPktCnt )
{
unsigned i;
// for each incoming audio packet
for(i=0; i<inPktCnt; ++i)
{
cmApAggPortTestRecd* r = (cmApAggPortTestRecd*)inPktArray[i].userCbPtr;
if( r->synthFl==false && inPktArray[i].devIdx == r->inDevIdx )
{
// copy the incoming audio into an internal buffer where it can be picked up by _cpApCopyOut().
_cmApAggCopyIn( r, (cmApSample_t*)inPktArray[i].audioBytesPtr, inPktArray[i].begChIdx, inPktArray[i].chCnt, inPktArray[i].audioFramesCnt );
}
++r->cbCnt;
//printf("i %4i in:%4i out:%4i\n",r->bufFullCnt,r->bufInIdx,r->bufOutIdx);
}
unsigned hold_phase = 0;
// for each outgoing audio packet
for(i=0; i<outPktCnt; ++i)
{
cmApAggPortTestRecd* r = (cmApAggPortTestRecd*)outPktArray[i].userCbPtr;
if( outPktArray[i].devIdx == r->outDevIdx )
{
// zero the output buffer
memset(outPktArray[i].audioBytesPtr,0,outPktArray[i].chCnt * outPktArray[i].audioFramesCnt * sizeof(cmApSample_t) );
// if the synth is enabled
if( r->synthFl )
{
unsigned tmp_phase = _cmApAggSynthSine( r, outPktArray[i].audioBytesPtr, outPktArray[i].begChIdx, outPktArray[i].chCnt, outPktArray[i].audioFramesCnt, r->phase, r->frqHz );
// the phase will only change on packets that are actually used
if( tmp_phase != r->phase )
hold_phase = tmp_phase;
}
else
{
// copy the any audio in the internal record buffer to the playback device
_cmApAggCopyOut( r, (cmApSample_t*)outPktArray[i].audioBytesPtr, outPktArray[i].begChIdx, outPktArray[i].chCnt, outPktArray[i].audioFramesCnt );
}
}
r->phase = hold_phase;
//printf("o %4i in:%4i out:%4i\n",r->bufFullCnt,r->bufInIdx,r->bufOutIdx);
// count callbacks
++r->cbCnt;
}
}
// print the usage message for cmAudioPortTest.c
void _cmApAggPrintUsage( cmRpt_t* rpt )
{
char msg[] =
"cmApAggPortTest() command switches\n"
"-r <srate> -c <chcnt> -b <bufcnt> -f <frmcnt> -i <idevidx> -o <odevidx> -t -p -h \n"
"\n"
"-r <srate> = sample rate\n"
"-a <chidx> = first channel\n"
"-c <chcnt> = audio channels\n"
"-b <bufcnt> = count of buffers\n"
"-f <frmcnt> = count of samples per buffer\n"
"-i <idevidx> = input device index\n"
"-o <odevidx> = output device index\n"
"-p = print report but do not start audio devices\n"
"-h = print this usage message\n";
cmRptPrintf(rpt,msg);
}
// Get a command line option.
int _cmApAggGetOpt( int argc, const char* argv[], const char* label, int defaultVal, bool boolFl )
{
int i = 0;
for(; i<argc; ++i)
if( strcmp(label,argv[i]) == 0 )
{
if(boolFl)
return 1;
if( i == (argc-1) )
return defaultVal;
return atoi(argv[i+1]);
}
return defaultVal;
}
void _cmApBufShowMeter( cmRpt_t* rpt, unsigned devIdx )
{
unsigned faultCnt = 0;
unsigned meterCnt = cmApBufChannelCount(devIdx,kInApFl);
double meterArray[ meterCnt ];
unsigned n = cmApBufGetStatus(devIdx, kInApFl, meterArray, meterCnt, &faultCnt );
unsigned i;
cmRptPrintf(rpt,"In: actual:%i fault: %i : ",n,faultCnt);
for(i=0; i<meterCnt; ++i)
cmRptPrintf(rpt,"%i:%f ",i,meterArray[i]);
cmRptPrintf(rpt,"\n");
}
unsigned _cmAggGlobalInDevIdx = 0;
unsigned _cmAggGlobalOutDevIdx = 0;
void _cmApAggPortCb2( cmApAudioPacket_t* inPktArray, unsigned inPktCnt, cmApAudioPacket_t* outPktArray, unsigned outPktCnt )
{
cmApBufInputToOutput( _cmAggGlobalInDevIdx, _cmAggGlobalOutDevIdx );
cmApBufUpdate( inPktArray, inPktCnt, outPktArray, outPktCnt );
}
void recdPrint();
// Audio Port testing function
int cmApAggTest( bool runFl, cmCtx_t* ctx, int argc, const char* argv[] )
{
cmApAggPortTestRecd r;
unsigned i;
cmRpt_t* rpt = &ctx->rpt;
if( _cmApAggGetOpt(argc,argv,"-h",0,true) )
_cmApAggPrintUsage(rpt);
runFl = _cmApAggGetOpt(argc,argv,"-p",!runFl,true)?false:true;
r.chIdx = _cmApAggGetOpt(argc,argv,"-a",0,false);
r.chCnt = _cmApAggGetOpt(argc,argv,"-c",2,false);
r.bufCnt = _cmApAggGetOpt(argc,argv,"-b",3,false);
r.framesPerCycle = _cmApAggGetOpt(argc,argv,"-f",512,false);
r.bufFrmCnt = (r.bufCnt*r.framesPerCycle);
r.bufSmpCnt = (r.chCnt * r.bufFrmCnt);
r.synthFl = false;
r.meterMs = 50;
cmApSample_t buf[r.bufSmpCnt];
double imeter[r.chCnt];
r.iMeter = imeter;
r.inDevIdx = _cmAggGlobalInDevIdx = _cmApAggGetOpt(argc,argv,"-i",0,false);
r.outDevIdx = _cmAggGlobalOutDevIdx = _cmApAggGetOpt(argc,argv,"-o",2,false);
r.phase = 0;
r.frqHz = 2000;
r.srate = 44100;
r.bufInIdx = 0;
r.bufOutIdx = 0;
r.bufFullCnt = 0;
r.buf = buf;
r.cbCnt = 0;
r.underunCnt = 0;
r.overunCnt = 0;
r.ifp = NULL;
r.ofp = NULL;
if(0)
{
if((r.ifp = fopen("/home/kevin/temp/itemp0.bin","wb")) == NULL )
cmRptPrintf(rpt,"File open failed.\n");
if((r.ofp = fopen("/home/kevin/temp/otemp0.bin","wb")) == NULL )
cmRptPrintf(rpt,"File open failed.\n");
}
cmRptPrintf(rpt,"%s in:%i out:%i chidx:%i chs:%i bufs=%i frm=%i rate=%f\n",runFl?"exec":"rpt",r.inDevIdx,r.outDevIdx,r.chIdx,r.chCnt,r.bufCnt,r.framesPerCycle,r.srate);
// allocate the aggregate device system
if( cmApAggAllocate(rpt) != kOkAgRC )
{
cmRptPrintf(rpt,"The aggregate device system allocation failed.\n");
return 1;
}
unsigned physDevIdxArray[] = { 0, 1 };
unsigned physDevCnt = sizeof(physDevIdxArray)/sizeof(physDevIdxArray[0]);
if( cmApAggCreateDevice("aggdev",physDevCnt,physDevIdxArray,kInAggFl | kOutAggFl) != kOkAgRC )
{
cmRptPrintf(rpt,"The aggregate device creation failed.n");
goto doneLabel;
}
// initialize the audio device interface
if( cmApInitialize(rpt) != kOkApRC )
{
cmRptPrintf(rpt,"Initialize failed.\n");
goto doneLabel;
}
// report the current audio device configuration
for(i=0; i<cmApDeviceCount(); ++i)
{
cmRptPrintf(rpt,"%i [in: chs=%i frames=%i] [out: chs=%i frames=%i] srate:%f %s\n",i,cmApDeviceChannelCount(i,true),cmApDeviceFramesPerCycle(i,true),cmApDeviceChannelCount(i,false),cmApDeviceFramesPerCycle(i,false),cmApDeviceSampleRate(i),cmApDeviceLabel(i));
}
// report the current audio devices using the audio port interface function
cmApReport(rpt);
if( runFl )
{
// initialize the audio bufer
cmApBufInitialize( cmApDeviceCount(), r.meterMs );
// setup the buffer for the output device
cmApBufSetup( r.outDevIdx, r.srate, r.framesPerCycle, r.bufCnt, cmApDeviceChannelCount(r.outDevIdx,true), r.framesPerCycle, cmApDeviceChannelCount(r.outDevIdx,false), r.framesPerCycle );
// setup the buffer for the input device
if( r.inDevIdx != r.outDevIdx )
cmApBufSetup( r.inDevIdx, r.srate, r.framesPerCycle, r.bufCnt, cmApDeviceChannelCount(r.inDevIdx,true), r.framesPerCycle, cmApDeviceChannelCount(r.inDevIdx,false), r.framesPerCycle );
// setup an input device
if( cmApDeviceSetup(r.inDevIdx,r.srate,r.framesPerCycle,_cmApAggPortCb2,&r) != kOkApRC )
{
cmRptPrintf(rpt,"In device setup failed.\n");
goto errLabel;
}
// setup an output device
if( r.inDevIdx != r.outDevIdx )
{
if(cmApDeviceSetup(r.outDevIdx,r.srate,r.framesPerCycle,_cmApAggPortCb2,&r) != kOkApRC )
{
cmRptPrintf(rpt,"Out device setup failed.\n");
goto errLabel;
}
}
// start the input device
if( cmApDeviceStart(r.inDevIdx) != kOkApRC )
{
cmRptPrintf(rpt,"In device start failed.\n");
goto errLabel;
}
if( r.inDevIdx != r.outDevIdx )
{
// start the output device
if( cmApDeviceStart(r.outDevIdx) != kOkApRC )
{
cmRptPrintf(rpt,"Out Device start failed.\n");
goto errLabel;
}
}
cmApBufEnableChannel(r.inDevIdx, -1, kInApFl | kEnableApFl );
cmApBufEnableChannel(r.outDevIdx, -1, kOutApFl | kEnableApFl );
cmApBufEnableMeter(r.inDevIdx, -1, kInApFl | kEnableApFl );
cmRptPrintf(rpt,"q=quit O/o output tone, I/i input tone P/p pass\n");
char c;
while((c=getchar()) != 'q')
{
//cmApDeviceRtReport(rpt,r.outDevIdx);
switch(c)
{
case 'i':
case 'I':
cmApBufEnableTone(r.inDevIdx,-1,kInApFl | (c=='I'?kEnableApFl:0));
break;
case 'o':
case 'O':
cmApBufEnableTone(r.outDevIdx,-1,kOutApFl | (c=='O'?kEnableApFl:0));
break;
case 'p':
case 'P':
cmApBufEnablePass(r.outDevIdx,-1,kOutApFl | (c=='P'?kEnableApFl:0));
break;
case 's':
cmApBufReport(rpt);
break;
case 'm':
_cmApBufShowMeter(rpt,_cmAggGlobalInDevIdx);
/*
cmRptPrintf(rpt,"iMeter: ");
for(i=0; i<r.chCnt; ++i)
cmRptPrintf(rpt,"%f ",r.iMeter[i]);
cmRptPrintf(rpt,"\n");
*/
break;
case 'r':
recdPrint();
break;
default:
cmRptPrintf(rpt,"cb:%i\n",r.cbCnt);
}
}
errLabel:
// stop the input device
if( cmApDeviceIsStarted(r.inDevIdx) )
if( cmApDeviceStop(r.inDevIdx) != kOkApRC )
cmRptPrintf(rpt,"In device stop failed.\n");
// stop the output device
if( cmApDeviceIsStarted(r.outDevIdx) )
if( cmApDeviceStop(r.outDevIdx) != kOkApRC )
cmRptPrintf(rpt,"Out device stop failed.\n");
}
doneLabel:
// report the count of audio buffer callbacks
cmRptPrintf(rpt,"cb:%i under:%i over:%i\n", r.cbCnt, r.underunCnt, r.overunCnt );
// release any resources held by the audio port interface
if( cmApFinalize() != kOkApRC )
cmRptPrintf(rpt,"Finalize failed.\n");
if( cmApAggFree() != kOkAgRC )
cmRptPrintf(rpt,"Agg device system free failed.");
if(r.ifp != NULL)
fclose(r.ifp);
if(r.ofp != NULL)
fclose(r.ofp);
cmApBufFinalize();
return 0;
}