#include "cwCommon.h" #include "cwLog.h" #include "cwCommonImpl.h" #include "cwTest.h" #include "cwMem.h" #include "cwObject.h" #include "cwFileSys.h" #include "cwFile.h" #include "cwTime.h" #include "cwVectOps.h" #include "cwMtx.h" #include "cwTime.h" #include "cwMidiDecls.h" #include "cwDspTypes.h" #include "cwFlowDecl.h" #include "cwFlow.h" #include "cwFlowTypes.h" #include "cwFlowCross.h" #include "cwIo.h" #include "cwIoFlow.h" namespace cw { namespace io_flow { // An audio_dev_t record exists for each possible input or output device. typedef struct audio_dev_str { unsigned ioDevIdx; // device index in the io:: API unsigned ioDevId; // device id in the io:: API flow::abuf_t abuf; // src/dst buffer for incoming/outgoing (record/play) samples used by flow proc 'audio_in' and 'audio_out'. } audio_dev_t; typedef struct audio_group_str { double srate; unsigned dspFrameCnt; unsigned ioGroupIdx; audio_dev_t* iDeviceA; unsigned iDeviceN; audio_dev_t* oDeviceA; unsigned oDeviceN; } audio_group_t; typedef struct io_flow_str { io::handle_t ioH; // flow::external_device_t* deviceA; // Array of generic device descriptions used by the ioFlow controller unsigned deviceN; // (This array must exist for the life of ioFlow controller) audio_group_t* audioGroupA; // Array of real time audio device control records. unsigned audioGroupN; // flow_cross::handle_t crossFlowH; // } io_flow_t; io_flow_t* _handleToPtr( handle_t h ) { return handleToPtr(h); } rc_t _destroy( io_flow_t* p ) { flow_cross::destroy( p->crossFlowH ); mem::release(p->deviceA); p->deviceN = 0; for(unsigned gi=0; giaudioGroupN; ++gi) { audio_group_t* ag = p->audioGroupA + gi; for(unsigned di=0; diiDeviceN; ++di) mem::release( ag->iDeviceA[di].abuf.buf ); for(unsigned di=0; dioDeviceN; ++di) mem::release( ag->oDeviceA[di].abuf.buf ); mem::release( ag->iDeviceA); mem::release( ag->oDeviceA); } mem::release(p->audioGroupA); mem::release(p); return kOkRC; } unsigned _calc_device_count(io_flow_t* p) { unsigned devN = 0; devN += socketCount(p->ioH); devN += serialDeviceCount(p->ioH); unsigned midiDevN = midiDeviceCount(p->ioH); for(unsigned i=0; iioH,i,true) + midiDevicePortCount(p->ioH,i,false); for(unsigned i=0; iaudioGroupN; ++i) devN += p->audioGroupA[i].iDeviceN + p->audioGroupA[i].oDeviceN; return devN; } void _setup_audio_device( io_flow_t* p,audio_dev_t* dev, unsigned inOrOutFl, unsigned ioDevIdx, unsigned dspFrameCnt ) { dev->ioDevIdx = ioDevIdx; dev->ioDevId = audioDeviceUserId( p->ioH, ioDevIdx ); dev->abuf.srate = audioDeviceSampleRate( p->ioH, ioDevIdx ); dev->abuf.chN = audioDeviceChannelCount( p->ioH, ioDevIdx, inOrOutFl ); dev->abuf.frameN = dspFrameCnt; dev->abuf.buf = mem::allocZ< flow::sample_t >( dev->abuf.chN * dev->abuf.frameN ); //printf("%i %s\n", dev->abuf.chN, audioDeviceLabel( p->ioH, ioDevIdx ) ); } void _setup_audio_groups( io_flow_t* p ) { p->audioGroupN = audioGroupCount( p->ioH ); p->audioGroupA = mem::allocZ( p->audioGroupN ); for(unsigned gi=0; giioH); ++gi) { audio_group_t* ag = p->audioGroupA + gi; ag->srate = audioGroupSampleRate( p->ioH, gi ); ag->dspFrameCnt = audioGroupDspFrameCount( p->ioH, gi ); ag->ioGroupIdx = gi; ag->iDeviceN = audioGroupDeviceCount( p->ioH, gi, io::kInFl ); ag->iDeviceA = mem::allocZ< audio_dev_t >( ag->iDeviceN ); for(unsigned gdi=0; gdiiDeviceN; ++gdi) _setup_audio_device( p, ag->iDeviceA + gdi, io::kInFl, audioGroupDeviceIndex( p->ioH, gi, io::kInFl, gdi), ag->dspFrameCnt ); ag->oDeviceN = audioGroupDeviceCount( p->ioH, gi, io::kOutFl ); ag->oDeviceA = mem::allocZ< audio_dev_t >( ag->oDeviceN ); for(unsigned gdi=0; gdioDeviceN; ++gdi) _setup_audio_device( p, ag->oDeviceA + gdi, io::kOutFl, audioGroupDeviceIndex( p->ioH, gi, io::kOutFl, gdi), ag->dspFrameCnt ); } } rc_t _send_midi_triple( flow::external_device_t* dev, uint8_t ch, uint8_t status, uint8_t d0, uint8_t d1 ) { return midiDeviceSend(((io_flow_t*)dev->reserved)->ioH, dev->ioDevIdx, dev->ioPortIdx, status |= ch, d0, d1); } void _setup_device_cfg( io_flow_t* p, flow::external_device_t* d, const char* devLabel, unsigned ioDevIdx, unsigned typeId, unsigned flags, const char* midiPortLabel=nullptr, unsigned midiPortIdx=kInvalidIdx ) { d->reserved = p; d->devLabel = devLabel; d->portLabel = midiPortLabel; d->typeId = typeId; d->flags = flags; d->ioDevIdx = ioDevIdx; d->ioPortIdx = midiPortIdx; } void _setup_midi_device_cfg( io_flow_t* p, flow::external_device_t* d, const char* devLabel, unsigned ioDevIdx, unsigned flags, unsigned ioMidiPortIdx ) { const char* midiPortLabel = io::midiDevicePortName(p->ioH,ioDevIdx, flags & flow::kInFl ? true : false,ioMidiPortIdx); _setup_device_cfg( p, d, devLabel, ioDevIdx, flow::kMidiDevTypeId, flags, midiPortLabel, ioMidiPortIdx ); d->u.m.maxMsgCnt = io::midiDeviceMaxBufferMsgCount(p->ioH); d->u.m.sendTripleFunc = _send_midi_triple; } void _setup_audio_device_cfg( io_flow_t* p, flow::external_device_t* d, audio_group_t* ag, audio_dev_t* ad, unsigned flags ) { _setup_device_cfg( p, d, io::audioDeviceLabel(p->ioH,ad->ioDevIdx), ad->ioDevIdx, flow::kAudioDevTypeId, flags ); // Each audio device is given a flow::abuf to hold incoming or outgoing audio. // This buffer also allows the 'audio_in' and 'audio_out' flow procs to configure themselves. d->u.a.abuf = &ad->abuf; } void _setup_generic_device_array( io_flow_t* p ) { unsigned i = 0; // allocate the generic device control records p->deviceN = _calc_device_count(p); p->deviceA = mem::allocZ( p->deviceN ); // get serial devices for(unsigned di=0; ideviceN && diioH); ++di,++i) _setup_device_cfg( p, p->deviceA + i, io::serialDeviceLabel(p->ioH,di), di, flow::kSerialDevTypeId, flow::kInFl | flow::kOutFl ); // get sockets for(unsigned di=0; ideviceN && diioH); ++di,++i) _setup_device_cfg( p, p->deviceA + i, io::socketLabel(p->ioH,di), di, flow::kSocketDevTypeId, flow::kInFl | flow::kOutFl ); // get midi devices for(unsigned di=0; ideviceN && diioH); ++di) { // input port setup for(unsigned pi=0; piioH,di,true); ++pi,++i) _setup_midi_device_cfg( p, p->deviceA + i, io::midiDeviceName(p->ioH,di), di, flow::kInFl, pi); // output port setup for(unsigned pi=0; piioH,di,false); ++pi,++i) _setup_midi_device_cfg( p, p->deviceA + i, io::midiDeviceName(p->ioH,di), di, flow::kOutFl, pi); } // get the audio devices for(unsigned gi=0; giaudioGroupN; ++gi) { audio_group_t* ag = p->audioGroupA + gi; for(unsigned di=0; ideviceN && diiDeviceN; ++di,++i) _setup_audio_device_cfg( p, p->deviceA + i, ag, ag->iDeviceA + di, flow::kInFl ); for(unsigned di=0; ideviceN && dioDeviceN; ++di,++i) _setup_audio_device_cfg( p, p->deviceA + i, ag, ag->oDeviceA + di, flow::kOutFl ); } assert( i == p->deviceN ); } rc_t _device_index_to_abuf( io_flow_t* p, unsigned ioGroupIdx, unsigned ioDevIdx, unsigned inOrOutFl, flow::abuf_t*& abuf_ref ) { rc_t rc = kOkRC; for(unsigned gi=0; giaudioGroupN; ++gi) if( p->audioGroupA[gi].ioGroupIdx == ioGroupIdx ) { audio_dev_t* adA = inOrOutFl == flow::kInFl ? p->audioGroupA[gi].iDeviceA : p->audioGroupA[gi].oDeviceA; unsigned adN = inOrOutFl == flow::kInFl ? p->audioGroupA[gi].iDeviceN : p->audioGroupA[gi].oDeviceN; for(unsigned di=0; dibuf + (i*dst_abuf->frameN); memcpy(dst,src,dst_abuf->frameN*sizeof(flow::sample_t)); } } void _zero_output_buffer( flow::abuf_t* dst_abuf ) { memset(dst_abuf->buf,0, dst_abuf->chN*dst_abuf->frameN*sizeof(flow::sample_t)); } void _fill_output_buffer( const flow::abuf_t* src_abuf, flow::sample_t** bufChArray, unsigned bufChArrayN ) { for(unsigned i=0; ichN; ++i) { const flow::sample_t* src = src_abuf->buf + (i*src_abuf->frameN); flow::sample_t* dst = bufChArray[i]; memcpy(dst,src,src_abuf->frameN*sizeof(flow::sample_t)); } } rc_t _audio_callback( io_flow_t* p, io::audio_msg_t& m ) { rc_t rc = kOkRC; flow::abuf_t* abuf = nullptr; // Get an array of incoming MIDI events which have occurred since the last call to 'io::midiDeviceBuffer()' unsigned midiBufMsgCnt = 0; const midi::ch_msg_t* midiBuf = midiDeviceBuffer(p->ioH,midiBufMsgCnt); // Give each MIDI input device a pointer to the incoming MIDI msgs for(unsigned i=0; ideviceN; ++i) if( p->deviceA[i].typeId == flow::kMidiDevTypeId && cwIsFlag(p->deviceA[i].flags,flow::kInFl) ) { p->deviceA[i].u.m.msgArray = midiBuf; p->deviceA[i].u.m.msgCnt = midiBufMsgCnt; } // if there is incoming (recorded) audio if( m.iBufChCnt > 0 ) { unsigned chIdx = 0; // for each input device in this group for(io::audio_group_dev_t* agd = m.iDevL; agd!=nullptr; agd=agd->link) { // get the abuf associated with each device in this group if((rc = _device_index_to_abuf( p, m.groupIndex, agd->devIdx, flow::kInFl, abuf )) != kOkRC ) goto errLabel; // fill the input audio buf from the the external audio device _fill_input_buffer( m.iBufArray + chIdx, agd->chCnt, abuf ); chIdx += agd->chCnt; } } // if there are empty output (playback) buffers if( m.oBufChCnt > 0 ) { // for each output device in this group for(io::audio_group_dev_t* agd=m.oDevL; agd!=nullptr; agd=agd->link) { // get the output audio buf associated with this external audio device if((rc = _device_index_to_abuf( p, m.groupIndex, agd->devIdx, flow::kOutFl, abuf )) != kOkRC ) goto errLabel; // zerot the output buffer _zero_output_buffer( abuf ); } } // update the flow network - this will generate audio into the output audio buffers flow_cross::exec_cycle(p->crossFlowH); // if there are empty output (playback) buffers if( m.oBufChCnt > 0 ) { unsigned chIdx = 0; // for each output device in this group for(io::audio_group_dev_t* agd=m.oDevL; agd!=nullptr; agd=agd->link) { // get the output audio buf associated with this external audio device if((rc = _device_index_to_abuf( p, m.groupIndex, agd->devIdx, flow::kOutFl, abuf )) != kOkRC ) goto errLabel; // copy the samples from the flow 'audio_out' buffers to the outgoing buffer passed from the device driver _fill_output_buffer( abuf, m.oBufArray + chIdx, agd->chCnt ); chIdx += agd->chCnt; } } errLabel: // Drop the MIDI messages that were processed on this call. midiDeviceClearBuffer(p->ioH,midiBufMsgCnt); return rc; } } } cw::rc_t cw::io_flow::create( handle_t& hRef, io::handle_t ioH, double srate, unsigned crossFadeCnt, const object_t& flow_class_dict, const object_t& network_cfg ) { rc_t rc; if((rc = destroy(hRef)) != kOkRC ) return rc; io_flow_t* p = mem::allocZ(); p->ioH = ioH; // allocate p->audioGroupA[] and create the audio input/output buffers associated with each audio device _setup_audio_groups(p); // setup the control record for each external device known to the IO interface _setup_generic_device_array(p); // create the flow object if((rc = flow_cross::create( p->crossFlowH, flow_class_dict, network_cfg, srate, crossFadeCnt, p->deviceA, p->deviceN )) != kOkRC ) { cwLogError(rc,"The 'flow' object create failed."); goto errLabel; } //flow_cross::print(p->crossFlowH); hRef.set(p); errLabel: if( rc != kOkRC ) { rc = cwLogError(rc,"io_flow create failed."); _destroy(p); } return rc; } cw::rc_t cw::io_flow::destroy( handle_t& hRef ) { rc_t rc = kOkRC;; if( !hRef.isValid() ) return rc; io_flow_t* p = _handleToPtr(hRef); if((rc = _destroy(p)) != kOkRC ) return rc; hRef.clear(); return rc; } unsigned cw::io_flow::preset_cfg_flags( handle_t h ) { io_flow_t* p = _handleToPtr(h); return preset_cfg_flags(p->crossFlowH); } cw::rc_t cw::io_flow::exec( handle_t h, const io::msg_t& msg ) { rc_t rc = kOkRC; io_flow_t* p = _handleToPtr(h); switch( msg.tid ) { case io::kAudioTId: if( msg.u.audio != nullptr ) _audio_callback(p,*msg.u.audio); break; default: rc = kOkRC; } return rc; } cw::rc_t cw::io_flow::apply_preset( handle_t h, unsigned crossFadeMs, const char* presetLabel ) { rc_t rc; if((rc = apply_preset( h, flow_cross::kNextDestId, presetLabel )) == kOkRC ) rc = begin_cross_fade( h, crossFadeMs ); return rc; } cw::rc_t cw::io_flow::apply_preset( handle_t h, flow_cross::destId_t destId, const char* presetLabel ) { return apply_preset( _handleToPtr(h)->crossFlowH, destId, presetLabel ); } cw::rc_t cw::io_flow::apply_preset( handle_t h, flow_cross::destId_t destId, const flow::multi_preset_selector_t& multi_preset_sel ) { return apply_preset( _handleToPtr(h)->crossFlowH, destId, multi_preset_sel ); } cw::rc_t cw::io_flow::set_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, bool value ) { return flow_cross::set_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, value ); } cw::rc_t cw::io_flow::set_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, int value ) { return flow_cross::set_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, value ); } cw::rc_t cw::io_flow::set_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, unsigned value ) { return flow_cross::set_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, value ); } cw::rc_t cw::io_flow::set_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, float value ) { return flow_cross::set_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, value ); } cw::rc_t cw::io_flow::set_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, double value ) { return flow_cross::set_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, value ); } cw::rc_t cw::io_flow::begin_cross_fade( handle_t h, unsigned crossFadeMs ) { return flow_cross::begin_cross_fade( _handleToPtr(h)->crossFlowH, crossFadeMs ); } cw::rc_t cw::io_flow::get_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, bool& valueRef ) { return flow_cross::get_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, valueRef ); } cw::rc_t cw::io_flow::get_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, int& valueRef ) { return flow_cross::get_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, valueRef ); } cw::rc_t cw::io_flow::get_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, unsigned& valueRef ) { return flow_cross::get_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, valueRef ); } cw::rc_t cw::io_flow::get_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, float& valueRef ) { return flow_cross::get_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, valueRef ); } cw::rc_t cw::io_flow::get_variable_value( handle_t h, flow_cross::destId_t destId, const char* inst_label, const char* var_label, unsigned chIdx, double& valueRef ) { return flow_cross::get_variable_value( _handleToPtr(h)->crossFlowH, destId, inst_label, var_label, chIdx, valueRef ); } void cw::io_flow::print( handle_t h ) { return flow_cross::print( _handleToPtr(h)->crossFlowH ); } void cw::io_flow::print_network( handle_t h, flow_cross::destId_t destId ) { return flow_cross::print_network( _handleToPtr(h)->crossFlowH, destId ); } void cw::io_flow::report( handle_t h ) { flow_cross::report( _handleToPtr(h)->crossFlowH ); }