#include "cwCommon.h" #include "cwLog.h" #include "cwCommonImpl.h" #include "cwMem.h" #include "cwTime.h" #include "cwMidi.h" #include "cwTextBuf.h" #include "cwMidiPort.h" //=================================================================================================== // // namespace cw { namespace midi { namespace parser { enum { kBufByteCnt = 1024, kExpectStatusStId=0, // 0 kExpectDataStId, // 1 kExpectStatusOrDataStId, // 2 kExpectEOXStId // 3 }; typedef struct cmMpParserCb_str { cbFunc_t cbFunc; void* cbDataPtr; struct cmMpParserCb_str* linkPtr; } cbRecd_t; typedef struct parser_str { cbRecd_t* cbChain; packet_t pkt; unsigned state; // parser state id unsigned errCnt; // accumlated error count uint8_t status; // running status uint8_t data0; // data byte 0 unsigned dataCnt; // data byte cnt for current status unsigned dataIdx; // index (0 or 1) of next data byte uint8_t* buf; // output buffer unsigned bufByteCnt; // output buffer byte cnt unsigned bufIdx; // next output buffer index unsigned msgCnt; // count of channel messages in the buffer } parser_t; parser_t* _handleToPtr( handle_t h ) { return handleToPtr(h); } void _cmMpParserCb( parser_t* p, packet_t* pkt, unsigned pktCnt ) { cbRecd_t* c = p->cbChain; for(; c!=NULL; c=c->linkPtr) { pkt->cbDataPtr = c->cbDataPtr; c->cbFunc( pkt, pktCnt ); } } void _cmMpTransmitChMsgs( parser_t* p ) { if( p->msgCnt > 0 ) { p->pkt.msgArray = (msg_t*)p->buf; p->pkt.msgCnt = p->msgCnt; p->pkt.sysExMsg = NULL; //p->cbFunc( &p->pkt, 1 ); _cmMpParserCb(p,&p->pkt,1); p->bufIdx = 0; p->msgCnt = 0; } } void _cmMpTransmitSysEx( parser_t* p ) { p->pkt.msgArray = NULL; p->pkt.sysExMsg = p->buf; p->pkt.msgCnt = p->bufIdx; //p->cbFunc( &p->pkt, 1 ); _cmMpParserCb(p,&p->pkt,1); p->bufIdx = 0; } void _cmMpParserStoreChMsg( parser_t* p, const time::spec_t* timeStamp, uint8_t d ) { // if there is not enough room left in the buffer then transmit // the current messages if( p->bufByteCnt - p->bufIdx < sizeof(msg_t) ) _cmMpTransmitChMsgs(p); assert( p->bufByteCnt - p->bufIdx >= sizeof(msg_t) ); // get a pointer to the next msg in the buffer msg_t* msgPtr = (msg_t*)(p->buf + p->bufIdx); // fill the buffer msg msgPtr->timeStamp = *timeStamp; msgPtr->status = p->status; switch( p->dataCnt ) { case 0: break; case 1: msgPtr->d0 = d; msgPtr->d1 = 0; break; case 2: msgPtr->d0 = p->data0; msgPtr->d1 = d; break; default: assert(0); } // update the msg count and next buffer ++p->msgCnt; p->bufIdx += sizeof(msg_t); } void _report( parser_t* p ) { cwLogInfo("state:%i st:0x%x d0:%i dcnt:%i didx:%i buf[%i]->%i msg:%i err:%i\n",p->state,p->status,p->data0,p->dataCnt,p->dataIdx,p->bufByteCnt,p->bufIdx,p->msgCnt,p->errCnt); } void _destroy( parser_t* p ) { mem::release(p->buf); cbRecd_t* c = p->cbChain; while(c != NULL) { cbRecd_t* nc = c->linkPtr; mem::release(c); c = nc; } mem::release(p); } } // parser } // midi } // cw cw::rc_t cw::midi::parser::create( handle_t& hRef, unsigned devIdx, unsigned portIdx, cbFunc_t cbFunc, void* cbDataPtr, unsigned bufByteCnt ) { rc_t rc = kOkRC; parser_t* p = mem::allocZ( 1 ); p->pkt.devIdx = devIdx; p->pkt.portIdx = portIdx; //p->cbChain = cmMemAllocZ( cbRecd_t, 1 ); //p->cbChain->cbFunc = cbFunc; //p->cbChain->cbDataPtr = cbDataPtr; //p->cbChain->linkPtr = NULL; p->cbChain = NULL; p->buf = mem::allocZ( bufByteCnt ); p->bufByteCnt = bufByteCnt; p->bufIdx = 0; p->msgCnt = 0; p->state = kExpectStatusStId; p->dataIdx = kInvalidIdx; p->dataCnt = kInvalidCnt; p->status = kInvalidStatusMdId; hRef.set(p); if( cbFunc != NULL ) rc = installCallback(hRef, cbFunc, cbDataPtr ); if( rc != kOkRC ) { _destroy(p); hRef.clear(); } return rc; } cw::rc_t cw::midi::parser::destroy( handle_t& hRef ) { rc_t rc = kOkRC; if( !hRef.isValid() ) return rc; parser_t* p = _handleToPtr(hRef); _destroy(p); hRef.clear(); return rc; } unsigned cw::midi::parser::errorCount( handle_t h ) { parser_t* p = _handleToPtr(h); if( p == NULL ) return 0; return p->errCnt; } void cw::midi::parser::parseMidiData( handle_t h, const time::spec_t* timeStamp, const uint8_t* iBuf, unsigned iByteCnt ) { parser_t* p = _handleToPtr(h); if( p == NULL ) return; const uint8_t* ip = iBuf; const uint8_t* ep = iBuf + iByteCnt; for(; ip < ep; ++ip ) { // if this byte is a status byte if( isStatus(*ip) ) { if( p->state != kExpectStatusStId && p->state != kExpectStatusOrDataStId ) ++p->errCnt; p->status = *ip; p->dataCnt = statusToByteCount(*ip); switch( p->status ) { case kSysExMdId: // if this is the start of a sys-ex msg ... // ... clear the buffer to prepare from sys-ex data _cmMpTransmitChMsgs(p); p->state = kExpectEOXStId; p->dataCnt = kInvalidCnt; p->dataIdx = kInvalidIdx; p->buf[ p->bufIdx++ ] = kSysExMdId; break; case kSysComEoxMdId: // if this is the end of a sys-ex msg assert( p->bufIdx < p->bufByteCnt ); p->buf[p->bufIdx++] = *ip; _cmMpTransmitSysEx(p); p->state = kExpectStatusStId; break; default: // ... otherwise it is a 1,2, or 3 byte msg status if( p->dataCnt > 0 ) { p->state = kExpectDataStId; p->dataIdx = 0; } else { // this is a status only msg - store it _cmMpParserStoreChMsg(p,timeStamp,*ip); p->state = kExpectStatusStId; p->dataIdx = kInvalidIdx; p->dataCnt = kInvalidCnt; } } continue; } // at this point the current byte (*ip) is a data byte switch(p->state) { case kExpectStatusOrDataStId: assert( p->dataIdx == 0 ); case kExpectDataStId: switch( p->dataIdx ) { case 0: // expecting data byte 0 ... switch( p->dataCnt ) { case 1: // ... of a 1 byte msg - the msg is complete _cmMpParserStoreChMsg(p,timeStamp,*ip); p->state = kExpectStatusOrDataStId; break; case 2: // ... of a 2 byte msg - prepare to recv the second data byte p->state = kExpectDataStId; p->dataIdx = 1; p->data0 = *ip; break; default: assert(0); } break; case 1: // expecting data byte 1 of a two byte msg assert( p->dataCnt == 2 ); assert( p->state == kExpectDataStId ); _cmMpParserStoreChMsg(p,timeStamp,*ip); p->state = kExpectStatusOrDataStId; p->dataIdx = 0; break; default: assert(0); } break; case kExpectEOXStId: assert( p->bufIdx < p->bufByteCnt ); p->buf[p->bufIdx++] = *ip; // if the buffer is full - then transmit it if( p->bufIdx == p->bufByteCnt ) _cmMpTransmitSysEx(p); break; } } // ip loop _cmMpTransmitChMsgs(p); } cw::rc_t cw::midi::parser::midiTriple( handle_t h, const time::spec_t* timeStamp, uint8_t status, uint8_t d0, uint8_t d1 ) { rc_t rc = kOkRC; parser_t* p = _handleToPtr(h); uint8_t mb = 0xff; // a midi triple may never have a status of 0xff if( d0 == 0xff ) p->dataCnt = 0; else if( d1 == 0xff ) p->dataCnt = 1; else p->dataCnt = 2; p->status = status; switch( p->dataCnt ) { case 0: mb = status; break; case 1: mb = d0; break; case 2: p->data0 = d0; mb = d1; break; default: rc = cwLogError(kInvalidArgRC,"An invalid MIDI status byte (0x%x) was encountered by the MIDI data parser."); goto errLabel; break; } if( mb != 0xff ) _cmMpParserStoreChMsg(p,timeStamp,mb); p->dataCnt = kInvalidCnt; errLabel: return rc; } cw::rc_t cw::midi::parser::transmit( handle_t h ) { parser_t* p = _handleToPtr(h); _cmMpTransmitChMsgs(p); return kOkRC; } cw::rc_t cw::midi::parser::installCallback( handle_t h, cbFunc_t cbFunc, void* cbDataPtr ) { parser_t* p = _handleToPtr(h); cbRecd_t* newCbPtr = mem::allocZ( 1 ); cbRecd_t* c = p->cbChain; newCbPtr->cbFunc = cbFunc; newCbPtr->cbDataPtr = cbDataPtr; newCbPtr->linkPtr = NULL; if( p->cbChain == NULL ) p->cbChain = newCbPtr; else { while( c->linkPtr != NULL ) c = c->linkPtr; c->linkPtr = newCbPtr; } return kOkRC; } cw::rc_t cw::midi::parser::removeCallback( handle_t h, cbFunc_t cbFunc, void* cbDataPtr ) { parser_t* p = _handleToPtr(h); cbRecd_t* c1 = p->cbChain; // target link cbRecd_t* c0 = NULL; // link pointing to target // search for the cbFunc to remove for(; c1!=NULL; c1=c1->linkPtr) { if( c1->cbFunc == cbFunc && c1->cbDataPtr == cbDataPtr) break; c0 = c1; } // if the cbFunc was not found if( c1 == NULL ) return cwLogError(kInvalidArgRC,"Unable to locate the callback function %p for removal.",cbFunc); // the cbFunc to remove was found // if it was the first cb in the chain if( c0 == NULL ) p->cbChain = c1->linkPtr; else c0->linkPtr = c1->linkPtr; mem::release(c1); return kOkRC; } bool cw::midi::parser::hasCallback( handle_t h, cbFunc_t cbFunc, void* cbArg ) { parser_t* p = _handleToPtr(h); cbRecd_t* c = p->cbChain; // target link // search for the cbFunc to remove for(; c!=NULL; c=c->linkPtr) if( c->cbFunc == cbFunc && c->cbDataPtr == cbArg ) return true; return false; } //==================================================================================================== // // unsigned cw::midi::device::nameToIndex(handle_t h, const char* deviceName) { assert(deviceName!=NULL); unsigned i; unsigned n = count(h); for(i=0; imsgCnt; ++j) if( p->msgArray != NULL ) printf("%ld %ld 0x%x %i %i\n", p->msgArray[j].timeStamp.tv_sec, p->msgArray[j].timeStamp.tv_nsec, p->msgArray[j].status,p->msgArray[j].d0, p->msgArray[j].d1); else printf("0x%x ",p->sysExMsg[j]); } } } // device } // midi } // cw cw::rc_t cw::midi::device::test() { rc_t rc = kOkRC; char ch; unsigned parserBufByteCnt = 1024; textBuf::handle_t tbH; handle_t h; // initialie the MIDI system if((rc = create(h,testCallback,NULL,parserBufByteCnt,"app")) != kOkRC ) return rc; // create a text buffer to hold the MIDI system report text if((rc = textBuf::create(tbH)) != kOkRC ) goto errLabel; // generate and print the MIDI system report report(h,tbH); cwLogInfo("%s",textBuf::text(tbH)); cwLogInfo("any key to send note-on (=quit)\n"); while((ch = getchar()) != 'q') { send(h,2,0,0x90,60,60); } errLabel: textBuf::destroy(tbH); destroy(h); return rc; }