#include "cwCommon.h" #include "cwLog.h" #include "cwCommonImpl.h" #include "cwMem.h" #include "cwFile.h" #include "cwText.h" #include "cwObject.h" #include "cwAudioFile.h" #include "cwUtility.h" #include "cwFileSys.h" #include "cwAudioFileOps.h" #include "cwMath.h" #include "cwVectOps.h" #include "cwDsp.h" #include "cwAudioTransforms.h" #include "cwAudioFileProc.h" namespace cw { namespace afop { //------------------------------------------------------------------------------------------------ // Template Process // namespace process { typedef struct process_str { int foo; double blah; } process_t; rc_t open( proc_ctx_t* ctx ) { rc_t rc = kOkRC; process_t* p = mem::allocZ(); ctx->userPtr = p; if((rc = ctx->args->getv( "foo", p->foo, "blah", p->blah)) != kOkRC ) { rc = cwLogError(rc,"Parsing of 'template' args. failed."); } return rc; } rc_t close( proc_ctx_t* ctx ) { rc_t rc = kOkRC; process_t* p = (process_t*)ctx->userPtr; mem::release(p); return rc; } rc_t process( proc_ctx_t* ctx ) { rc_t rc = kOkRC; return rc; } rc_t main( proc_ctx_t* ctx ) { rc_t rc = kOkRC; switch( ctx->procId ) { case kOpenProcId: rc = open(ctx); break; case kCloseProcId: rc = close(ctx); break; case kProcProcId: rc = process(ctx); break; } return rc; } } //------------------------------------------------------------------------------------------------ // Phase Vocoder Process // namespace pvoc { typedef struct process_str { dsp::pv_anl::fobj_t** anlA; // anlA[chCnt] dsp::pv_syn::fobj_t** synA; // synA[chCnt] unsigned chCnt; // unsigned procSmpN; // unsigned wndSmpN; // unsigned hopSmpN; // double inGain; // double outGain; // } process_t; rc_t open( proc_ctx_t* ctx ) { rc_t rc = kOkRC; process_t* p = mem::allocZ(); ctx->userPtr = p; if((rc = ctx->args->getv( "procSmpN", p->procSmpN, "hopSmpN", p->hopSmpN, "wndSmpN", p->wndSmpN)) != kOkRC ) { rc = cwLogError(rc,"Parsing of 'pvoc' required arguments failed."); } p->chCnt = std::min( ctx->srcChN, ctx->dstChN ); p->anlA = mem::allocZ< dsp::pv_anl::fobj_t* >( p->chCnt ); p->synA = mem::allocZ< dsp::pv_syn::fobj_t* >( p->chCnt ); for(unsigned i=0; ichCnt; ++i) { if((rc = dsp::pv_anl::create( p->anlA[i], p->procSmpN, ctx->srcSrate, p->wndSmpN, p->wndSmpN, p->hopSmpN, dsp::pv_anl::kNoCalcHzPvaFl )) != kOkRC ) { rc = cwLogError(rc,"PVOC analysis component create failed."); goto errLabel; } if((rc = dsp::pv_syn::create( p->synA[i], p->procSmpN, ctx->dstSrate, p->wndSmpN, p->hopSmpN )) != kOkRC ) { rc = cwLogError(rc,"PVOC synthesis component create failed."); goto errLabel; } } errLabel: return rc; } rc_t close( proc_ctx_t* ctx ) { rc_t rc = kOkRC; process_t* p = (process_t*)ctx->userPtr; for(unsigned i=0; ichCnt; ++i) { if( p->anlA ) dsp::pv_anl::destroy(p->anlA[i]); if( p->synA ) dsp::pv_syn::destroy(p->synA[i]); } mem::release(p); return rc; } rc_t process( proc_ctx_t* ctx ) { rc_t rc = kOkRC; process_t* p = (process_t*)ctx->userPtr; for(unsigned i=0; ichCnt; ++i) { if( dsp::pv_anl::exec( p->anlA[i], ctx->srcChV[i], p->hopSmpN) ) { float buf[ p->anlA[i]->binCnt ]; vop::mul( buf, p->anlA[i]->magV, p->anlA[i]->binCnt/2, p->anlA[i]->binCnt ); if((rc = dsp::pv_syn::exec( p->synA[i], buf, p->anlA[i]->phsV )) != kOkRC ) { rc = cwLogError(rc,"Pvoc synthesis failed."); goto errLabel; } vop::copy( ctx->dstChV[i], p->synA[i]->ola->outV, p->hopSmpN ); } } errLabel: return rc; } rc_t main( proc_ctx_t* ctx ) { rc_t rc = kOkRC; switch( ctx->procId ) { case kOpenProcId: rc = open(ctx); break; case kCloseProcId: rc = close(ctx); break; case kProcProcId: rc = process(ctx); break; } return rc; } } //------------------------------------------------------------------------------------------------ // Tremelo Process // namespace tremelo { typedef struct tremelo_str { double hz; double depth; double phase; } tremelo_t; rc_t open( proc_ctx_t* ctx ) { rc_t rc; tremelo_t* p = mem::allocZ(); ctx->userPtr = p; if((rc = ctx->args->getv( "hz", p->hz, "depth", p->depth)) != kOkRC ) { rc = cwLogError(rc,"Parsing of 'tremelo' ctx. failed."); } return rc; } rc_t close( proc_ctx_t* ctx ) { tremelo_t* p = (tremelo_t*)ctx->userPtr; mem::release(p); return kOkRC; } rc_t process( proc_ctx_t* ctx ) { tremelo_t* p = (tremelo_t*)ctx->userPtr; unsigned chCnt = std::min( ctx->srcChN, ctx->dstChN ); unsigned hopSmpN = std::min( ctx->srcHopSmpN, ctx->dstHopSmpN ); for(unsigned i=0; idepth * std::sin( p->phase ); for(unsigned j=0; jdstChV[j][i] = gain * ctx->srcChV[j][i]; p->phase += 2*M_PI*p->hz / ctx->srcSrate; } return kOkRC; } rc_t main( proc_ctx_t* ctx ) { rc_t rc = kOkRC; switch( ctx->procId ) { case kOpenProcId: rc = open(ctx); break; case kCloseProcId: rc = close(ctx); break; case kProcProcId: rc = process(ctx); break; } return rc; } } } } //------------------------------------------------------------------------------------------------ // Audio File Processor // cw::rc_t cw::afop::file_processor( const char* srcFn, const char* dstFn, proc_func_t func, unsigned wndSmpN, unsigned hopSmpN, void* userPtr, const object_t* args, const object_t* recorder_cfg, unsigned recordChN ) { rc_t rc = kOkRC; typedef float sample_t; audiofile::handle_t srcAfH; audiofile::handle_t dstAfH; audiofile::info_t info; proc_ctx_t proc_ctx = {}; if( hopSmpN > wndSmpN ) return cwLogError(kInvalidArgRC,"The hop sample count (%i) cannot exceed the window sample count (%i).", hopSmpN, wndSmpN ); proc_ctx.userPtr = userPtr; proc_ctx.args = args; // By default wndSmpN and hopSmpN set both the src and dst wndSmpN and hopSmpN parameters proc_ctx.srcWndSmpN = wndSmpN; proc_ctx.srcHopSmpN = hopSmpN; proc_ctx.dstWndSmpN = wndSmpN; proc_ctx.dstHopSmpN = hopSmpN; // if a source audio file was given if( srcFn != nullptr ) { // open the source audio file if((rc = audiofile::open(srcAfH,srcFn,&info)) != kOkRC ) { rc = cwLogError(rc,"Unable to open the source file:%s", cwStringNullGuard(srcFn) ); goto errLabel; } // Configure the input signal proc_ctx.srcFn = mem::duplStr(srcFn); proc_ctx.srcSrate = info.srate; proc_ctx.srcChN = info.chCnt; proc_ctx.srcBits = info.bits; // By default the output signal has the same configuration as the input file proc_ctx.dstSrate = info.srate; proc_ctx.dstChN = info.chCnt; proc_ctx.dstBits = info.bits; // TODO: allow setting output file bits as optional parameter (0=float) // Be sure if settting bits from input file with floating point sample format // that this case is correctly handled here. } // During the 'open' call the user defined function (UDF) can override the destination file configuration proc_ctx.procId = kOpenProcId; if((rc = func( &proc_ctx )) != kOkRC ) { rc = cwLogError(rc,"Open processes failed."); goto errLabel; } // Create the output file if( dstFn != nullptr ) { if((rc = audiofile::create(dstAfH,dstFn, proc_ctx.dstSrate, proc_ctx.dstBits, proc_ctx.dstChN )) != kOkRC ) { rc = cwLogError(rc,"Unable to create the destination file:%s", cwStringNullGuard(dstFn) ); goto errLabel; } proc_ctx.dstFn = mem::duplStr(dstFn); } if( rc == kOkRC ) { sample_t* srcChFileBuf[ proc_ctx.srcChN ]; // srcChFileBuf[ srcChN ][ srcHopSmpCnt ] - src file ch buffer sample_t* dstChFileBuf[ proc_ctx.dstChN ]; // dstChFileBuf[ dstChN ][ dstHopSmpCnt ] - dst file ch buffer const sample_t* iChBuf[ proc_ctx.srcChN ]; // iChBuf[ srcChN ][ srcWndSmpCnt ] - src processing buffer sample_t* oChBuf[ proc_ctx.dstChN ]; // oChBuf[ dstChN ][ dstWndSmpCnt ] - dst processing buffer struct dsp::shift_buf::obj_str* srcShiftBufA[ proc_ctx.srcChN ]; // src shift buffer struct dsp::shift_buf::obj_str* dstShiftBufA[ proc_ctx.dstChN ]; // dst shift buffer // Allocate memory for the source/dest file buffer sample_t* srcFileBuf = mem::allocZ( proc_ctx.srcChN * proc_ctx.srcHopSmpN ); sample_t* dstFileBuf = mem::allocZ( proc_ctx.dstChN * proc_ctx.dstHopSmpN ); sample_t* procFileBuf = mem::allocZ( proc_ctx.dstChN * proc_ctx.dstHopSmpN ); // Setup the input and output processing buffer proc_ctx.srcChV = iChBuf; proc_ctx.dstChV = oChBuf; // For each source channel - setup the source file buffer and create the src shift buffer for(unsigned i = 0; i( recordChN ); for(unsigned i = 0; ioutV; } if(!rd_fl) break; // src shift-buf iterations are done } // Call the processing function proc_ctx.procId = kProcProcId; if((rc = func( &proc_ctx )) != kOkRC ) { // kEof isn't an error if( rc == kEofRC ) rc = kOkRC; else rc = cwLogError(rc,"Audio file process reported an error."); goto doneLabel; } // if output samples exist - shift the new samples into the output shift buffer if( proc_ctx.dstChN ) { do // destination shif-buffer iteration processing loop { bool wr_fl = false; // Update the dst shift buffers // Note that the shift buffer has to be called until it returns false therefore // we must iterate over the file writing process writing hopSmpN frames on each call. for(unsigned j=0; joutV; } } // if no true's were returned by the shift-buffer (Note that all channels must return the same // value because they are all configured the same way.) if( !wr_fl ) break; // If a destination file was specified if( dstFn != nullptr ) { if((rc = audiofile::writeFloat( dstAfH, proc_ctx.dstHopSmpN, proc_ctx.dstChN, dstChFileBuf )) != kOkRC ) { rc = cwLogError(rc,"Audio process source file '%s' read failed.", srcFn ); goto doneLabel; } } }while(1); // desination shift-buffer interation processing loop } }while(1); // source shift-buffer iteration processing loop proc_ctx.cycleIndex += 1; } // end while doneLabel: for(unsigned i=0; igetv("srcFn", srcFn, "dstFn", dstFn, "cfg", cfgLabel)) != kOkRC ) { rc = cwLogError(kSyntaxErrorRC,"Error parsing the main audio file proc configuration record."); goto errLabel; } // locate the cfg for the specific process function to run if((rc = cfg->getv(cfgLabel, pgm)) != kOkRC ) { rc = cwLogError(kSyntaxErrorRC,"The audio file proc. configuration '%s' was not found.",cwStringNullGuard(cfgLabel)); goto errLabel; } // parse the specific process function configuration record if((rc = pgm->getv("wndSmpN", wndSmpN, "hopSmpN", hopSmpN, "program", program, "args", args)) != kOkRC ) { rc = cwLogError(kSyntaxErrorRC,"The audio file proc. configuration '%s' parse failed.",cwStringNullGuard(cfgLabel)); goto errLabel; } // parse the recorder spec if((rc = cfg->getv_opt("recordChN", recordChN, "recorder", recorder)) != kOkRC ) { rc = cwLogError(kSyntaxErrorRC,"Error parsing the main audio file proc optional configuration fields."); goto errLabel; } // TODO: add optional args: inGain,outGain,dstBits // locate the executable function associated with the specified process function for(unsigned i=0; true; ++i) { // if the function was not found if( labelFuncA[i].func == nullptr ) { rc = cwLogError(kInvalidArgRC,"The audio processing program '%s' could not be found.", cwStringNullGuard(program)); goto errLabel; } // if this is the specified function if( textCompare(labelFuncA[i].label,program ) == 0 ) { procFunc = labelFuncA[i].func; break; } } // run the processr if((rc = file_processor( srcFn, dstFn, procFunc, wndSmpN, hopSmpN, nullptr, args, recorder, recordChN)) != kOkRC ) { rc = cwLogError(rc,"The audio file proc. failed."); goto errLabel; } errLabel: return rc; }