/** * Furnace Tracker - multi-system chiptune tracker * Copyright (C) 2021-2023 tildearrow and contributors * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #define _USE_MATH_DEFINES #include "gui.h" #include "../ta-log.h" #include "imgui.h" #include "imgui_internal.h" #include "misc/cpp/imgui_stdlib.h" #define FURNACE_FFT_SIZE 4096 #define FURNACE_FFT_RATE 80.0 #define FURNACE_FFT_CUTOFF 0.1 const char* chanOscRefs[]={ "None (0%)", "None (50%)", "None (100%)", "Frequency", "Volume", "Channel", "Brightness", "Note Trigger" }; const char* autoColsTypes[]={ "Off", "Mode 1", "Mode 2", "Mode 3" }; float FurnaceGUI::computeGradPos(int type, int chan) { switch (type) { case GUI_OSCREF_NONE: return 0.0f; break; case GUI_OSCREF_CENTER: return 0.5f; break; case GUI_OSCREF_MAX: return 1.0f; break; case GUI_OSCREF_FREQUENCY: return chanOscPitch[chan]; break; case GUI_OSCREF_VOLUME: return chanOscVol[chan]; break; case GUI_OSCREF_CHANNEL: return (float)chan/(float)(e->getTotalChannelCount()-1); break; case GUI_OSCREF_BRIGHT: return chanOscBright[chan]; break; case GUI_OSCREF_NOTE_TRIGGER: return keyHit1[chan]; break; } return 0.0f; } void FurnaceGUI::calcChanOsc() { std::vector oscBufs; std::vector oscFFTs; std::vector oscChans; int chans=e->getTotalChannelCount(); for (int i=0; igetOscBuffer(i); while (buf==NULL) { if (--tryAgain<0) break; buf=e->getOscBuffer(tryAgain); } if (buf!=NULL && e->curSubSong->chanShow[i]) { // 30ms should be enough int displaySize=(float)(buf->rate)*0.03f; if (e->isRunning()) { float minLevel=1.0f; float maxLevel=-1.0f; unsigned short needlePos=buf->needle; needlePos-=displaySize; for (unsigned short i=0; i<512; i++) { float y=(float)buf->data[(unsigned short)(needlePos+(i*displaySize/512))]/32768.0f; if (minLevel>y) minLevel=y; if (maxLevel1.0f) estimate=1.0f; chanOscVol[i]=MAX(chanOscVol[i]*0.87f,estimate); } } else { chanOscVol[i]=MAX(chanOscVol[i]*0.87f,0.0f); } if (chanOscVol[i]<0.00001f) chanOscVol[i]=0.0f; } } void FurnaceGUI::drawChanOsc() { if (nextWindow==GUI_WINDOW_CHAN_OSC) { chanOscOpen=true; ImGui::SetNextWindowFocus(); nextWindow=GUI_WINDOW_NOTHING; } if (!chanOscOpen) return; ImGui::SetNextWindowSizeConstraints(ImVec2(64.0f*dpiScale,32.0f*dpiScale),ImVec2(canvasW,canvasH)); if (ImGui::Begin("Oscilloscope (per-channel)",&chanOscOpen,globalWinFlags)) { bool centerSettingReset=false; ImDrawList* dl=ImGui::GetWindowDrawList(); if (chanOscOptions) { if (ImGui::BeginTable("ChanOscSettings",2)) { ImGui::TableNextRow(); ImGui::TableNextColumn(); ImGui::AlignTextToFramePadding(); ImGui::Text("Columns"); ImGui::SameLine(); ImGui::SetNextItemWidth(ImGui::GetContentRegionAvail().x); if (ImGui::InputInt("##COSColumns",&chanOscCols,1,1)) { if (chanOscCols<1) chanOscCols=1; if (chanOscCols>64) chanOscCols=64; } ImGui::TableNextColumn(); ImGui::Text("Size (ms)"); ImGui::SameLine(); ImGui::SetNextItemWidth(ImGui::GetContentRegionAvail().x); if (ImGui::InputFloat("##COSWinSize",&chanOscWindowSize,1.0f,1.0f)) { if (chanOscWindowSize<1.0f) chanOscWindowSize=1.0f; if (chanOscWindowSize>50.0f) chanOscWindowSize=50.0f; } ImGui::TableNextRow(); ImGui::TableNextColumn(); ImGui::AlignTextToFramePadding(); ImGui::Text("Automatic columns"); ImGui::SameLine(); ImGui::SetNextItemWidth(ImGui::GetContentRegionAvail().x); const char* previewColType=autoColsTypes[chanOscAutoColsType&3]; if (ImGui::BeginCombo("##AutoCols",previewColType)) { for (int j=0; j<4; j++) { const bool isSelected=(chanOscAutoColsType==j); if (ImGui::Selectable(autoColsTypes[j],isSelected)) chanOscAutoColsType=j; if (isSelected) ImGui::SetItemDefaultFocus(); } ImGui::EndCombo(); } ImGui::TableNextColumn(); if (ImGui::Checkbox("Center waveform",&chanOscWaveCorr)) { centerSettingReset=true; } ImGui::EndTable(); } ImGui::AlignTextToFramePadding(); ImGui::Text("Amplitude"); ImGui::SameLine(); ImGui::SetNextItemWidth(ImGui::GetContentRegionAvail().x); if (CWSliderFloat("##COSAmp",&chanOscAmplify,0.0f,2.0f)) { if (chanOscAmplify<0.0f) chanOscAmplify=0.0f; if (chanOscAmplify>2.0f) chanOscAmplify=2.0f; } ImGui::Checkbox("Gradient",&chanOscUseGrad); if (chanOscUseGrad) { if (chanOscGradTex==NULL) { chanOscGradTex=rend->createTexture(true,chanOscGrad.width,chanOscGrad.height); if (chanOscGradTex==NULL) { logE("error while creating gradient texture!"); } else { updateChanOscGradTex=true; } } if (ImGui::BeginTable("ChanOscGradSet",2)) { ImGui::TableSetupColumn("c0",ImGuiTableColumnFlags_WidthFixed); ImGui::TableSetupColumn("c1",ImGuiTableColumnFlags_WidthStretch); ImGui::TableNextRow(); ImGui::TableNextColumn(); if (chanOscGradTex!=NULL) { if (updateChanOscGradTex) { chanOscGrad.render(); if (rend->updateTexture(chanOscGradTex,chanOscGrad.grad.get(),chanOscGrad.width*4)) { updateChanOscGradTex=false; } else { logE("error while updating gradient texture!"); } } ImVec2 gradLeft=ImGui::GetCursorPos(); ImVec2 gradSize=ImVec2(400.0f*dpiScale,400.0f*dpiScale); ImGui::Image(rend->getTextureID(chanOscGradTex),gradSize); ImVec2 gradLeftAbs=ImGui::GetItemRectMin(); if (ImGui::IsItemClicked(ImGuiMouseButton_Right)) { if (chanOscGrad.points.size()<32) { chanOscGrad.points.push_back(Gradient2DPoint( (ImGui::GetMousePos().x-gradLeftAbs.x)/gradSize.x, (ImGui::GetMousePos().y-gradLeftAbs.y)/gradSize.y )); updateChanOscGradTex=true; } } ImVec2 oldCurPos=ImGui::GetCursorPos(); int index=0; int removePoint=-1; for (Gradient2DPoint& i: chanOscGrad.points) { ImGui::PushID(index+16); ImGui::SetCursorPos(ImVec2(gradLeft.x+i.x*gradSize.x-8.0*dpiScale,gradLeft.y+i.y*gradSize.y-8.0*dpiScale)); if (ImGui::InvisibleButton("gradPoint",ImVec2(16.0*dpiScale,16.0*dpiScale))) { if (!i.grab) { ImGui::OpenPopup("gradPointSettings"); } } if (ImGui::IsItemHovered() || ImGui::IsItemActive()) { ImGui::SetTooltip("(%.1f, %.1f)",i.x*100.0f,(1.0f-i.y)*100.0f); } if (ImGui::IsItemClicked(ImGuiMouseButton_Middle)) { removePoint=index; } if (ImGui::IsItemActive()) { float mX=(ImGui::GetMousePos().x-gradLeftAbs.x)/gradSize.x; float mY=(ImGui::GetMousePos().y-gradLeftAbs.y)/gradSize.y; if (i.grab || (fabs(i.x-mX)>0.015 || fabs(i.y-mY)>0.015)) { i.x=mX; i.y=mY; i.grab=true; if (i.x<0) i.x=0; if (i.x>1) i.x=1; if (i.y<0) i.y=0; if (i.y>1) i.y=1; updateChanOscGradTex=true; } } else { i.grab=false; i.prevX=i.x; i.prevY=i.y; } if (ImGui::BeginPopup("gradPointSettings",ImGuiWindowFlags_NoTitleBar|ImGuiWindowFlags_NoMove|ImGuiWindowFlags_AlwaysAutoResize)) { if (ImGui::ColorPicker4("Color",(float*)&i.color)) { updateChanOscGradTex=true; } ImGui::AlignTextToFramePadding(); ImGui::Text("Distance"); ImGui::SameLine(); float pDist=i.distance*100.0f; if (ImGui::SliderFloat("##PDistance",&pDist,0.0f,150.0f,"%.1f%%")) { i.distance=pDist/100.0f; updateChanOscGradTex=true; } ImGui::AlignTextToFramePadding(); ImGui::Text("Spread"); ImGui::SameLine(); float pSpread=i.spread*100.0f; if (ImGui::SliderFloat("##PSpread",&pSpread,0.0f,150.0f,"%.1f%%")) { i.spread=pSpread/100.0f; updateChanOscGradTex=true; } pushDestColor(); if (ImGui::Button("Remove")) { removePoint=index; ImGui::CloseCurrentPopup(); } popDestColor(); ImGui::EndPopup(); } dl->AddCircle(ImVec2(gradLeftAbs.x+i.x*gradSize.x,gradLeftAbs.y+i.y*gradSize.y),8.0*dpiScale,ImGui::ColorConvertFloat4ToU32(ImVec4(0.5,0.5,0.5,1.0)),6,2.0f*dpiScale); dl->AddCircle(ImVec2(gradLeftAbs.x+i.x*gradSize.x,gradLeftAbs.y+i.y*gradSize.y),5.0*dpiScale,ImGui::ColorConvertFloat4ToU32(ImVec4(0.1,0.1,0.1,1.0)),6,2.0f*dpiScale); ImGui::PopID(); index++; } ImGui::SetCursorPos(oldCurPos); if (removePoint>=0) { chanOscGrad.points.erase(chanOscGrad.points.begin()+removePoint); updateChanOscGradTex=true; } } ImGui::TableNextColumn(); if (ImGui::ColorEdit4("Background",(float*)&chanOscGrad.bgColor)) { updateChanOscGradTex=true; } ImGui::Combo("X Axis##AxisX",&chanOscColorX,chanOscRefs,GUI_OSCREF_MAX); ImGui::Combo("Y Axis##AxisY",&chanOscColorY,chanOscRefs,GUI_OSCREF_MAX); ImGui::EndTable(); } } else { ImGui::SetNextItemWidth(400.0f*dpiScale); ImGui::ColorPicker4("Color",(float*)&chanOscColor); } ImGui::AlignTextToFramePadding(); ImGui::Text("Text format:"); ImGui::SameLine(); ImGui::InputText("##TextFormat",&chanOscTextFormat); if (ImGui::IsItemHovered()) { if (ImGui::BeginTooltip()) { ImGui::TextUnformatted( "format guide:\n" "- %c: channel name\n" "- %C: channel short name\n" "- %d: channel number (starting from 0)\n" "- %D: channel number (starting from 1)\n" "- %n: channel note\n" "- %i: instrument name\n" "- %I: instrument number (decimal)\n" "- %x: instrument number (hex)\n" "- %s: chip name\n" "- %p: chip part number\n" "- %S: chip ID\n" "- %v: volume (decimal)\n" "- %V: volume (percentage)\n" "- %b: volume (hex)\n" "- %%: percent sign" ); ImGui::EndTooltip(); } } ImGui::ColorEdit4("Text color",(float*)&chanOscTextColor); if (ImGui::Button("OK")) { chanOscOptions=false; } } else { ImGui::PushStyleVar(ImGuiStyleVar_CellPadding,ImVec2(0.0f,0.0f)); float availY=ImGui::GetContentRegionAvail().y; if (ImGui::BeginTable("ChanOsc",chanOscCols,ImGuiTableFlags_Borders)) { std::vector oscBufs; std::vector oscFFTs; std::vector oscChans; int chans=e->getTotalChannelCount(); ImGuiWindow* window=ImGui::GetCurrentWindow(); ImGuiStyle& style=ImGui::GetStyle(); ImVec2 waveform[1024]; // check work thread if (chanOscWorkPool==NULL) { logV("creating chan osc work pool"); chanOscWorkPool=new DivWorkPool(settings.chanOscThreads); } // fill buffers for (int i=0; igetOscBuffer(i); if (buf!=NULL && e->curSubSong->chanShow[i]) { oscBufs.push_back(buf); oscFFTs.push_back(&chanOscChan[i]); oscChans.push_back(i); } } // process for (size_t i=0; irelatedBuf=oscBufs[i]; fft_->relatedCh=oscChans[i]; if (fft_->relatedBuf!=NULL) { // prepare if (centerSettingReset) { fft_->relatedBuf->readNeedle=fft_->relatedBuf->needle; } // check FFT status existence if (!fft_->ready) { logD("creating FFT plan for channel %d",fft_->relatedCh); fft_->inBuf=(double*)fftw_malloc(FURNACE_FFT_SIZE*sizeof(double)); fft_->outBuf=(fftw_complex*)fftw_malloc(FURNACE_FFT_SIZE*sizeof(fftw_complex)); fft_->corrBuf=(double*)fftw_malloc(FURNACE_FFT_SIZE*sizeof(double)); fft_->plan=fftw_plan_dft_r2c_1d(FURNACE_FFT_SIZE,fft_->inBuf,fft_->outBuf,FFTW_ESTIMATE); fft_->planI=fftw_plan_dft_c2r_1d(FURNACE_FFT_SIZE,fft_->outBuf,fft_->corrBuf,FFTW_ESTIMATE); if (fft_->plan==NULL) { logE("failed to create plan!"); } else if (fft_->planI==NULL) { logE("failed to create inverse plan!"); } else if (fft_->inBuf==NULL || fft_->outBuf==NULL || fft_->corrBuf==NULL) { logE("failed to create FFT buffers"); } else { fft_->ready=true; } } if (fft_->ready && e->isRunning()) { chanOscWorkPool->push([this](void* fft_v) { ChanOscStatus* fft=(ChanOscStatus*)fft_v; DivDispatchOscBuffer* buf=fft->relatedBuf; int ch=fft->relatedCh; // the STRATEGY // 1. FFT of windowed signal // 2. inverse FFT of auto-correlation // 3. find size of one period // 4. DFT of the fundamental of ONE PERIOD // 5. now we can get phase information // // I have a feeling this could be simplified to two FFTs or even one... // if you know how, please tell me // initialization double phase=0.0; int displaySize=(float)(buf->rate)*(chanOscWindowSize/1000.0f); fft->loudEnough=false; fft->needle=buf->needle; // first FFT for (int j=0; jinBuf[j]=(double)buf->data[(unsigned short)(fft->needle-displaySize*2+((j*displaySize*2)/(FURNACE_FFT_SIZE)))]/32768.0; if (fft->inBuf[j]>0.001 || fft->inBuf[j]<-0.001) fft->loudEnough=true; fft->inBuf[j]*=0.55-0.45*cos(M_PI*(double)j/(double)(FURNACE_FFT_SIZE>>1)); } // only proceed if not quiet if (fft->loudEnough) { fftw_execute(fft->plan); // auto-correlation and second FFT for (int j=0; joutBuf[j][0]/=FURNACE_FFT_SIZE; fft->outBuf[j][1]/=FURNACE_FFT_SIZE; fft->outBuf[j][0]=fft->outBuf[j][0]*fft->outBuf[j][0]+fft->outBuf[j][1]*fft->outBuf[j][1]; fft->outBuf[j][1]=0; } fft->outBuf[0][0]=0; fft->outBuf[0][1]=0; fft->outBuf[1][0]=0; fft->outBuf[1][1]=0; fftw_execute(fft->planI); // window for (int j=0; j<(FURNACE_FFT_SIZE>>1); j++) { fft->corrBuf[j]*=1.0-((double)j/(double)(FURNACE_FFT_SIZE<<1)); } // find size of period double waveLenCandL=DBL_MAX; double waveLenCandH=DBL_MIN; fft->waveLen=FURNACE_FFT_SIZE-1; fft->waveLenBottom=0; fft->waveLenTop=0; // find lowest point for (int j=(FURNACE_FFT_SIZE>>2); j>2; j--) { if (fft->corrBuf[j]corrBuf[j]; fft->waveLenBottom=j; } } // find highest point for (int j=(FURNACE_FFT_SIZE>>1)-1; j>fft->waveLenBottom; j--) { if (fft->corrBuf[j]>waveLenCandH) { waveLenCandH=fft->corrBuf[j]; fft->waveLen=j; } } fft->waveLenTop=fft->waveLen; // did we find the period size? if (fft->waveLen<(FURNACE_FFT_SIZE-32)) { // we got pitch chanOscPitch[ch]=pow(1.0-(fft->waveLen/(double)(FURNACE_FFT_SIZE>>1)),4.0); fft->waveLen*=(double)displaySize*2.0/(double)FURNACE_FFT_SIZE; // DFT of one period (x_1) double dft[2]; dft[0]=0.0; dft[1]=0.0; for (int j=fft->needle-1-(displaySize>>1)-(int)fft->waveLen, k=0; kwaveLen; j++, k++) { double one=((double)buf->data[j&0xffff]/32768.0); double two=(double)k*(-2.0*M_PI)/fft->waveLen; dft[0]+=one*cos(two); dft[1]+=one*sin(two); } // calculate and lock into phase phase=(0.5+(atan2(dft[1],dft[0])/(2.0*M_PI))); if (chanOscWaveCorr) { fft->needle-=phase*fft->waveLen; } } } fft->needle-=displaySize; },fft_); } } } chanOscWorkPool->wait(); // 0: none // 1: sqrt(chans) // 2: sqrt(chans+1) // 3: sqrt(chans)+1 switch (chanOscAutoColsType) { case 1: chanOscCols=sqrt(oscChans.size()); break; case 2: chanOscCols=sqrt(oscChans.size()+1); break; case 3: chanOscCols=sqrt(oscChans.size())+1; break; } if (chanOscCols<1) chanOscCols=1; if (chanOscCols>64) chanOscCols=64; int rows=(oscBufs.size()+(chanOscCols-1))/chanOscCols; // render for (size_t i=0; iDC.CursorPos; ImVec2 maxArea=ImVec2( minArea.x+size.x, minArea.y+size.y ); ImRect rect=ImRect(minArea,maxArea); ImRect inRect=rect; inRect.Min.x+=dpiScale; inRect.Min.y+=2.0*dpiScale; inRect.Max.x-=dpiScale; inRect.Max.y-=2.0*dpiScale; int precision=inRect.Max.x-inRect.Min.x; if (precision<1) precision=1; if (precision>1024) precision=1024; ImGui::ItemSize(size,style.FramePadding.y); if (ImGui::ItemAdd(rect,ImGui::GetID("chOscDisplay"))) { if (!e->isRunning()) { for (unsigned short j=0; jrate)*(chanOscWindowSize/1000.0f); float minLevel=1.0f; float maxLevel=-1.0f; float dcOff=0.0f; if (debugFFT) { // FFT debug code! double maxavg=0.0; for (unsigned short j=0; j<(FURNACE_FFT_SIZE>>1); j++) { if (fabs(fft->corrBuf[j]>maxavg)) { maxavg=fabs(fft->corrBuf[j]); } } if (maxavg>0.0000001) maxavg=0.5/maxavg; for (unsigned short j=0; j=precision/2) { y=fft->inBuf[((j-(precision/2))*FURNACE_FFT_SIZE*2)/(precision)]; } else { y=fft->corrBuf[(j*FURNACE_FFT_SIZE)/precision]*maxavg; } waveform[j]=ImLerp(inRect.Min,inRect.Max,ImVec2(x,0.5f-y)); } if (fft->loudEnough) { String cPhase=fmt::sprintf("\n%.1f (b: %d t: %d)",fft->waveLen,fft->waveLenBottom,fft->waveLenTop); dl->AddText(inRect.Min,0xffffffff,cPhase.c_str()); dl->AddLine( ImLerp(inRect.Min,inRect.Max,ImVec2((double)fft->waveLenBottom/(double)FURNACE_FFT_SIZE,0.0)), ImLerp(inRect.Min,inRect.Max,ImVec2((double)fft->waveLenBottom/(double)FURNACE_FFT_SIZE,1.0)), 0xffffff00 ); dl->AddLine( ImLerp(inRect.Min,inRect.Max,ImVec2((double)fft->waveLenTop/(double)FURNACE_FFT_SIZE,0.0)), ImLerp(inRect.Min,inRect.Max,ImVec2((double)fft->waveLenTop/(double)FURNACE_FFT_SIZE,1.0)), 0xff00ff00 ); } else { if (debugFFT) { dl->AddText(inRect.Min,0xffffffff,"\nquiet"); } } } else { for (unsigned short j=0; jdata[(unsigned short)(fft->needle+(j*displaySize/precision))]/32768.0f; if (minLevel>y) minLevel=y; if (maxLeveldata[(unsigned short)(fft->needle+(j*displaySize/precision))]/32768.0f; y-=dcOff; if (y<-0.5f) y=-0.5f; if (y>0.5f) y=0.5f; y*=chanOscAmplify; waveform[j]=ImLerp(inRect.Min,inRect.Max,ImVec2(x,0.5f-y)); } } } ImU32 color=ImGui::GetColorU32(chanOscColor); if (chanOscUseGrad) { float xVal=computeGradPos(chanOscColorX,ch); float yVal=computeGradPos(chanOscColorY,ch); xVal=CLAMP(xVal,0.0f,1.0f); yVal=CLAMP(yVal,0.0f,1.0f); color=chanOscGrad.get(xVal,1.0f-yVal); } ImGui::PushClipRect(inRect.Min,inRect.Max,false); ImDrawListFlags prevFlags=dl->Flags; //if (!settings.oscAntiAlias) { dl->Flags&=~(ImDrawListFlags_AntiAliasedLines|ImDrawListFlags_AntiAliasedLinesUseTex); //} dl->AddPolyline(waveform,precision,color,ImDrawFlags_None,dpiScale); dl->Flags=prevFlags; if (!chanOscTextFormat.empty()) { String text; bool inFormat=false; for (char j: chanOscTextFormat) { if (inFormat) { switch (j) { case 'c': text+=e->getChannelName(ch); break; case 'C': text+=e->getChannelShortName(ch); break; case 'd': text+=fmt::sprintf("%d",ch); break; case 'D': text+=fmt::sprintf("%d",ch+1); break; case 'i': { DivChannelState* chanState=e->getChanState(ch); if (chanState==NULL) break; DivInstrument* ins=e->getIns(chanState->lastIns); text+=ins->name; break; } case 'I': { DivChannelState* chanState=e->getChanState(ch); if (chanState==NULL) break; text+=fmt::sprintf("%d",chanState->lastIns); break; } case 'x': { DivChannelState* chanState=e->getChanState(ch); if (chanState==NULL) break; if (chanState->lastIns<0) { text+="??"; } else { text+=fmt::sprintf("%.2X",chanState->lastIns); } break; } case 's': { text+=e->getSystemName(e->sysOfChan[ch]); break; } case 'p': { text+=FurnaceGUI::getSystemPartNumber(e->sysOfChan[ch],e->song.systemFlags[e->dispatchOfChan[ch]]); break; } case 'S': { text+=fmt::sprintf("%d",e->dispatchOfChan[ch]); break; } case 'v': { DivChannelState* chanState=e->getChanState(ch); if (chanState==NULL) break; text+=fmt::sprintf("%d",chanState->volume>>8); break; } case 'V': { DivChannelState* chanState=e->getChanState(ch); if (chanState==NULL) break; int volMax=chanState->volMax>>8; if (volMax<1) volMax=1; text+=fmt::sprintf("%d%%",(chanState->volume>>8)/volMax); break; } case 'b': { DivChannelState* chanState=e->getChanState(ch); if (chanState==NULL) break; text+=fmt::sprintf("%.2X",chanState->volume>>8); break; } case 'n': { DivChannelState* chanState=e->getChanState(ch); if (chanState==NULL || !(chanState->keyOn)) break; short tempNote=chanState->note; //all of this conversion is necessary because notes 100-102 are special chars short noteMod=tempNote%12+12; //also note 0 is a BUG, hence +12 on the note and -1 on the octave short oct=tempNote/12-1; text+=fmt::sprintf("%s",noteName(noteMod,oct)); break; } case '%': text+='%'; break; default: text+='%'; text+=j; break; } inFormat=false; } else { if (j=='%') { inFormat=true; } else { text+=j; } } } dl->AddText(ImLerp(inRect.Min,inRect.Max,ImVec2(0.0f,0.0f)),ImGui::GetColorU32(chanOscTextColor),text.c_str()); } ImGui::PopClipRect(); } } } ImGui::EndTable(); if (ImGui::IsItemClicked(ImGuiMouseButton_Right)) { chanOscOptions=!chanOscOptions; } } ImGui::PopStyleVar(); } } if (ImGui::IsWindowFocused(ImGuiFocusedFlags_ChildWindows)) curWindow=GUI_WINDOW_CHAN_OSC; ImGui::End(); }