/* Copyright (C) 2006-2011 Nasca Octavian Paul Author: Nasca Octavian Paul Copyright (C) 2017 Xenakios This program is free software; you can redistribute it and/or modify it under the terms of version 2 of the GNU General Public License as published by the Free Software Foundation. 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 (version 2) for more details. You should have received a copy of the GNU General Public License (version 2) along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "PluginProcessor.h" #include "PluginEditor.h" #include #ifdef WIN32 #undef min #undef max #endif String g_plugintitle{ "PaulXStretch 1.0.0 preview 5" }; std::set g_activeprocessors; struct PresetEntry { PresetEntry(String name, String data) : m_name(name), m_data(data) {} String m_name; String m_data; }; const int g_num_presets = 4; static const PresetEntry g_presets[g_num_presets] = { {"Factory 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}; int get_optimized_updown(int n, bool up) { int orig_n = n; while (true) { n = orig_n; while (!(n % 11)) n /= 11; while (!(n % 7)) n /= 7; while (!(n % 5)) n /= 5; while (!(n % 3)) n /= 3; while (!(n % 2)) n /= 2; if (n<2) break; if (up) orig_n++; else orig_n--; if (orig_n<4) return 4; }; return orig_n; }; int optimizebufsize(int n) { int n1 = get_optimized_updown(n, false); int n2 = get_optimized_updown(n, true); if ((n - n1)<(n2 - n)) return n1; else return n2; }; //============================================================================== PaulstretchpluginAudioProcessor::PaulstretchpluginAudioProcessor() : m_bufferingthread("pspluginprebufferthread") #ifndef JucePlugin_PreferredChannelConfigurations : AudioProcessor (BusesProperties() #if ! JucePlugin_IsMidiEffect #if ! JucePlugin_IsSynth .withInput ("Input", AudioChannelSet::stereo(), true) #endif .withOutput ("Output", AudioChannelSet::stereo(), true) #endif ) #endif { g_activeprocessors.insert(this); m_recbuffer.setSize(2, 44100); m_recbuffer.clear(); if (m_afm->getNumKnownFormats()==0) m_afm->registerBasicFormats(); m_thumb = std::make_unique(512, *m_afm, *m_thumbcache); // The default priority of 2 is a bit too low in some cases, it seems... m_thumbcache->getTimeSliceThread().setPriority(3); m_stretch_source = std::make_unique(2, m_afm); m_ppar.pitch_shift.enabled = true; m_ppar.freq_shift.enabled = true; m_ppar.filter.enabled = true; m_ppar.compressor.enabled = true; m_stretch_source->setOnsetDetection(0.0); m_stretch_source->setLoopingEnabled(true); m_stretch_source->setFFTWindowingType(1); addParameter(new AudioParameterFloat("mainvolume0", "Main volume", -24.0f, 12.0f, -3.0f)); // 0 addParameter(new AudioParameterFloat("stretchamount0", "Stretch amount", NormalisableRange(0.1f, 1024.0f, 0.01f, 0.25),1.0f)); // 1 addParameter(new AudioParameterFloat("fftsize0", "FFT size", 0.0f, 1.0f, 0.7f)); // 2 addParameter(new AudioParameterFloat("pitchshift0", "Pitch shift", -24.0f, 24.0f, 0.0f)); // 3 addParameter(new AudioParameterFloat("freqshift0", "Frequency shift", -1000.0f, 1000.0f, 0.0f)); // 4 addParameter(new AudioParameterFloat("playrange_start0", "Sound start", 0.0f, 1.0f, 0.0f)); // 5 addParameter(new AudioParameterFloat("playrange_end0", "Sound end", 0.0f, 1.0f, 1.0f)); // 6 addParameter(new AudioParameterBool("freeze0", "Freeze", false)); // 7 addParameter(new AudioParameterFloat("spread0", "Frequency spread", 0.0f, 1.0f, 0.0f)); // 8 addParameter(new AudioParameterFloat("compress0", "Compress", 0.0f, 1.0f, 0.0f)); // 9 addParameter(new AudioParameterFloat("loopxfadelen0", "Loop xfade length", 0.0f, 1.0f, 0.01f)); // 10 auto numhar_convertFrom0To1Func = [](float rangemin, float rangemax, float value) { return jmap(value, 0.0f, 1.0f, 101.0f, 1.0f); }; auto numhar_convertTo0To1Func = [](float rangemin, float rangemax, float value) { return jmap(value, 101.0f, 1.0f, 0.0f, 1.0f); }; addParameter(new AudioParameterFloat("numharmonics0", "Num harmonics", NormalisableRange(1.0f, 101.0f, numhar_convertFrom0To1Func, numhar_convertTo0To1Func), 101.0f)); // 11 addParameter(new AudioParameterFloat("harmonicsfreq0", "Harmonics base freq", NormalisableRange(1.0f, 5000.0f, 1.00f, 0.5), 128.0f)); // 12 addParameter(new AudioParameterFloat("harmonicsbw0", "Harmonics bandwidth", 0.1f, 200.0f, 25.0f)); // 13 addParameter(new AudioParameterBool("harmonicsgauss0", "Gaussian harmonics", false)); // 14 addParameter(new AudioParameterFloat("octavemixm2_0", "2 octaves down level", 0.0f, 1.0f, 0.0f)); // 15 addParameter(new AudioParameterFloat("octavemixm1_0", "Octave down level", 0.0f, 1.0f, 0.0f)); // 16 addParameter(new AudioParameterFloat("octavemix0_0", "Normal pitch level", 0.0f, 1.0f, 1.0f)); // 17 addParameter(new AudioParameterFloat("octavemix1_0", "1 octave up level", 0.0f, 1.0f, 0.0f)); // 18 addParameter(new AudioParameterFloat("octavemix15_0", "1 octave and fifth up level", 0.0f, 1.0f, 0.0f)); // 19 addParameter(new AudioParameterFloat("octavemix2_0", "2 octaves up level", 0.0f, 1.0f, 0.0f)); // 20 addParameter(new AudioParameterFloat("tonalvsnoisebw_0", "Tonal vs Noise BW", 0.74f, 1.0f, 0.74f)); // 21 addParameter(new AudioParameterFloat("tonalvsnoisepreserve_0", "Tonal vs Noise preserve", -1.0f, 1.0f, 0.5f)); // 22 auto filt_convertFrom0To1Func = [](float rangemin, float rangemax, float value) { if (value < 0.5f) return jmap(value, 0.0f, 0.5f, 20.0f, 1000.0f); return jmap(value, 0.5f, 1.0f, 1000.0f, 20000.0f); }; auto filt_convertTo0To1Func = [](float rangemin, float rangemax, float value) { if (value < 1000.0f) return jmap(value, 20.0f, 1000.0f, 0.0f, 0.5f); return jmap(value, 1000.0f, 20000.0f, 0.5f, 1.0f); }; addParameter(new AudioParameterFloat("filter_low_0", "Filter low", NormalisableRange(20.0f, 20000.0f, filt_convertFrom0To1Func, filt_convertTo0To1Func), 20.0f)); // 23 addParameter(new AudioParameterFloat("filter_high_0", "Filter high", NormalisableRange(20.0f, 20000.0f, filt_convertFrom0To1Func,filt_convertTo0To1Func), 20000.0f));; // 24 addParameter(new AudioParameterFloat("onsetdetect_0", "Onset detection", 0.0f, 1.0f, 0.0f)); // 25 addParameter(new AudioParameterBool("capture_enabled0", "Capture", false)); // 26 m_outchansparam = new AudioParameterInt("numoutchans0", "Num output channels", 2, 8, 2); // 27 addParameter(m_outchansparam); // 27 addParameter(new AudioParameterBool("pause_enabled0", "Pause", false)); // 28 addParameter(new AudioParameterFloat("maxcapturelen_0", "Max capture length", 1.0f, 120.0f, 10.0f)); // 29 addParameter(new AudioParameterBool("passthrough0", "Pass input through", false)); // 30 auto& pars = getParameters(); for (const auto& p : pars) m_reset_pars.push_back(p->getValue()); setPreBufferAmount(2); startTimer(1, 50); } PaulstretchpluginAudioProcessor::~PaulstretchpluginAudioProcessor() { g_activeprocessors.erase(this); m_thumb->removeAllChangeListeners(); m_thumb = nullptr; m_bufferingthread.stopThread(1000); } void PaulstretchpluginAudioProcessor::resetParameters() { ScopedLock locker(m_cs); for (int i = 0; i < m_reset_pars.size(); ++i) { if (i!=cpi_main_volume && i!=cpi_passthrough) setParameter(i, m_reset_pars[i]); } } void PaulstretchpluginAudioProcessor::setPreBufferAmount(int x) { int temp = jlimit(0, 5, x); if (temp != m_prebuffer_amount || m_use_backgroundbuffering == false) { m_use_backgroundbuffering = true; m_prebuffer_amount = temp; m_recreate_buffering_source = true; ScopedLock locker(m_cs); m_prebuffering_inited = false; m_cur_num_out_chans = *m_outchansparam; //Logger::writeToLog("Switching to use " + String(m_cur_num_out_chans) + " out channels"); String err; startplay({ *getFloatParameter(cpi_soundstart),*getFloatParameter(cpi_soundend) }, m_cur_num_out_chans, m_curmaxblocksize, err); m_prebuffering_inited = true; } } int PaulstretchpluginAudioProcessor::getPreBufferAmount() { if (m_use_backgroundbuffering == false) return -1; return m_prebuffer_amount; } ValueTree PaulstretchpluginAudioProcessor::getStateTree(bool ignoreoptions, bool ignorefile) { ValueTree paramtree("paulstretch3pluginstate"); for (int i = 0; iparamID, (double)*par, nullptr); } } paramtree.setProperty(m_outchansparam->paramID, (int)*m_outchansparam, nullptr); if (m_current_file != File() && ignorefile == false) { paramtree.setProperty("importedfile", m_current_file.getFullPathName(), nullptr); } auto specorder = m_stretch_source->getSpectrumProcessOrder(); paramtree.setProperty("numspectralstages", (int)specorder.size(), nullptr); for (int i = 0; i < specorder.size(); ++i) { paramtree.setProperty("specorder" + String(i), specorder[i], nullptr); } if (ignoreoptions == false) { if (m_use_backgroundbuffering) paramtree.setProperty("prebufamount", m_prebuffer_amount, nullptr); else paramtree.setProperty("prebufamount", -1, nullptr); paramtree.setProperty("loadfilewithstate", m_load_file_with_state, nullptr); } return paramtree; } void PaulstretchpluginAudioProcessor::setStateFromTree(ValueTree tree) { if (tree.isValid()) { { ScopedLock locker(m_cs); m_load_file_with_state = tree.getProperty("loadfilewithstate", true); if (tree.hasProperty("numspectralstages")) { std::vector order; int ordersize = tree.getProperty("numspectralstages"); for (int i = 0; i < ordersize; ++i) { order.push_back((int)tree.getProperty("specorder" + String(i))); } m_stretch_source->setSpectrumProcessOrder(order); } for (int i = 0; i < getNumParameters(); ++i) { auto par = getFloatParameter(i); if (par != nullptr) { double parval = tree.getProperty(par->paramID, (double)*par); *par = parval; } } if (tree.hasProperty(m_outchansparam->paramID)) *m_outchansparam = tree.getProperty(m_outchansparam->paramID, 2); } int prebufamt = tree.getProperty("prebufamount", 2); if (prebufamt == -1) m_use_backgroundbuffering = false; else setPreBufferAmount(prebufamt); if (m_load_file_with_state == true) { String fn = tree.getProperty("importedfile"); if (fn.isEmpty() == false) { File f(fn); setAudioFile(f); } } m_state_dirty = true; } } //============================================================================== const String PaulstretchpluginAudioProcessor::getName() const { return JucePlugin_Name; } bool PaulstretchpluginAudioProcessor::acceptsMidi() const { #if JucePlugin_WantsMidiInput return true; #else return false; #endif } bool PaulstretchpluginAudioProcessor::producesMidi() const { #if JucePlugin_ProducesMidiOutput return true; #else return false; #endif } bool PaulstretchpluginAudioProcessor::isMidiEffect() const { #if JucePlugin_IsMidiEffect return true; #else return false; #endif } double PaulstretchpluginAudioProcessor::getTailLengthSeconds() const { return 0.0; //return (double)m_bufamounts[m_prebuffer_amount]/getSampleRate(); } int PaulstretchpluginAudioProcessor::getNumPrograms() { return g_num_presets; } int PaulstretchpluginAudioProcessor::getCurrentProgram() { return m_cur_program; } void PaulstretchpluginAudioProcessor::setCurrentProgram (int index) { index = jlimit(0, g_num_presets-1, index); m_cur_program = index; bool temp = m_load_file_with_state; m_load_file_with_state = false; MemoryBlock mb; MemoryOutputStream stream(mb, true); if (Base64::convertFromBase64(stream, g_presets[index].m_data)==true) { ValueTree tree = ValueTree::readFromData(mb.getData(), mb.getSize()); tree.setProperty("loadfilewithstate", false, nullptr); setStateFromTree(tree); } m_load_file_with_state = temp; } const String PaulstretchpluginAudioProcessor::getProgramName (int index) { index = jlimit(0, g_num_presets-1, index); return g_presets[index].m_name; } void PaulstretchpluginAudioProcessor::changeProgramName (int index, const String& newName) { } void PaulstretchpluginAudioProcessor::setFFTSize(double size) { if (m_prebuffer_amount == 5) m_fft_size_to_use = pow(2, 7.0 + size * 14.5); else m_fft_size_to_use = pow(2, 7.0 + size * 10.0); // chicken out from allowing huge FFT sizes if not enough prebuffering int optim = optimizebufsize(m_fft_size_to_use); m_fft_size_to_use = optim; m_stretch_source->setFFTSize(optim); //Logger::writeToLog(String(m_fft_size_to_use)); } void PaulstretchpluginAudioProcessor::startplay(Range playrange, int numoutchans, int maxBlockSize, String& err) { m_stretch_source->setPlayRange(playrange, true); int bufamt = m_bufamounts[m_prebuffer_amount]; if (m_buffering_source != nullptr && numoutchans != m_buffering_source->getNumberOfChannels()) m_recreate_buffering_source = true; if (m_recreate_buffering_source == true) { m_buffering_source = std::make_unique(m_stretch_source.get(), m_bufferingthread, false, bufamt, numoutchans, false); m_recreate_buffering_source = false; } if (m_bufferingthread.isThreadRunning() == false) m_bufferingthread.startThread(); m_stretch_source->setNumOutChannels(numoutchans); m_stretch_source->setFFTSize(m_fft_size_to_use); m_stretch_source->setProcessParameters(&m_ppar); m_last_outpos_pos = 0.0; m_last_in_pos = playrange.getStart()*m_stretch_source->getInfileLengthSeconds(); m_buffering_source->prepareToPlay(maxBlockSize, getSampleRateChecked()); } void PaulstretchpluginAudioProcessor::setParameters(const std::vector& pars) { ScopedLock locker(m_cs); for (int i = 0; i < getNumParameters(); ++i) { if (isetAudioBufferAsInputSource(&m_recbuffer, getSampleRateChecked(), len); m_thumb->reset(m_recbuffer.getNumChannels(), sampleRate, len); } if (m_prebuffering_inited == false) { setFFTSize(*getFloatParameter(cpi_fftsize)); m_stretch_source->setProcessParameters(&m_ppar); m_stretch_source->setFFTWindowingType(1); String err; startplay({ *getFloatParameter(cpi_soundstart),*getFloatParameter(cpi_soundend) }, numoutchans, samplesPerBlock, err); m_cur_num_out_chans = numoutchans; m_prebuffering_inited = true; } else { m_buffering_source->prepareToPlay(samplesPerBlock, getSampleRateChecked()); } } void PaulstretchpluginAudioProcessor::releaseResources() { //m_control->stopplay(); //m_ready_to_play = false; } #ifndef JucePlugin_PreferredChannelConfigurations bool PaulstretchpluginAudioProcessor::isBusesLayoutSupported (const BusesLayout& layouts) const { #if JucePlugin_IsMidiEffect ignoreUnused (layouts); return true; #else // This is the place where you check if the layout is supported. // In this template code we only support mono or stereo. if (layouts.getMainOutputChannelSet() != AudioChannelSet::mono() && layouts.getMainOutputChannelSet() != AudioChannelSet::stereo()) return false; // This checks if the input layout matches the output layout #if ! JucePlugin_IsSynth if (layouts.getMainOutputChannelSet() != layouts.getMainInputChannelSet()) return false; #endif return true; #endif } #endif void copyAudioBufferWrappingPosition(const AudioBuffer& src, AudioBuffer& dest, int destbufpos, int maxdestpos) { for (int i = 0; i < dest.getNumChannels(); ++i) { int channel_to_copy = i % src.getNumChannels(); if (destbufpos + src.getNumSamples() > maxdestpos) { int wrappos = (destbufpos + src.getNumSamples()) % maxdestpos; int partial_len = src.getNumSamples() - wrappos; dest.copyFrom(channel_to_copy, destbufpos, src, channel_to_copy, 0, partial_len); dest.copyFrom(channel_to_copy, partial_len, src, channel_to_copy, 0, wrappos); } else { dest.copyFrom(channel_to_copy, destbufpos, src, channel_to_copy, 0, src.getNumSamples()); } } } void PaulstretchpluginAudioProcessor::processBlock (AudioSampleBuffer& buffer, MidiBuffer& midiMessages) { ScopedLock locker(m_cs); AudioPlayHead* phead = getPlayHead(); if (phead != nullptr) { phead->getCurrentPosition(m_playposinfo); } ScopedNoDenormals noDenormals; double srtemp = getSampleRate(); if (srtemp != m_cur_sr) m_cur_sr = srtemp; const int totalNumInputChannels = getTotalNumInputChannels(); const int totalNumOutputChannels = getTotalNumOutputChannels(); for (int i = 0; i < totalNumInputChannels; ++i) m_input_buffer.copyFrom(i, 0, buffer, i, 0, buffer.getNumSamples()); for (int i = totalNumInputChannels; i < totalNumOutputChannels; ++i) buffer.clear (i, 0, buffer.getNumSamples()); if (m_prebuffering_inited == false) return; if (m_is_recording == true) { if (m_playposinfo.isPlaying == false && m_capture_when_host_plays == true) return; int recbuflenframes = m_max_reclen * getSampleRate(); copyAudioBufferWrappingPosition(buffer, m_recbuffer, m_rec_pos, recbuflenframes); m_thumb->addBlock(m_rec_pos, buffer, 0, buffer.getNumSamples()); m_rec_pos = (m_rec_pos + buffer.getNumSamples()) % recbuflenframes; return; } jassert(m_buffering_source != nullptr); jassert(m_bufferingthread.isThreadRunning()); if (m_last_host_playing == false && m_playposinfo.isPlaying) { m_stretch_source->seekPercent(*getFloatParameter(cpi_soundstart)); m_last_host_playing = true; } else if (m_last_host_playing == true && m_playposinfo.isPlaying == false) { m_last_host_playing = false; } if (m_play_when_host_plays == true && m_playposinfo.isPlaying == false) return; m_stretch_source->setMainVolume(*getFloatParameter(cpi_main_volume)); m_stretch_source->setRate(*getFloatParameter(cpi_stretchamount)); setFFTSize(*getFloatParameter(cpi_fftsize)); m_ppar.pitch_shift.cents = *getFloatParameter(cpi_pitchshift) * 100.0; m_ppar.freq_shift.Hz = *getFloatParameter(cpi_frequencyshift); m_ppar.spread.enabled = *getFloatParameter(cpi_spreadamount) > 0.0f; m_ppar.spread.bandwidth = *getFloatParameter(cpi_spreadamount); m_ppar.compressor.enabled = *getFloatParameter(cpi_compress)>0.0f; m_ppar.compressor.power = *getFloatParameter(cpi_compress); m_ppar.harmonics.enabled = *getFloatParameter(cpi_numharmonics)<101.0; m_ppar.harmonics.nharmonics = *getFloatParameter(cpi_numharmonics); m_ppar.harmonics.freq = *getFloatParameter(cpi_harmonicsfreq); m_ppar.harmonics.bandwidth = *getFloatParameter(cpi_harmonicsbw); m_ppar.harmonics.gauss = getParameter(cpi_harmonicsgauss); m_ppar.octave.om2 = *getFloatParameter(cpi_octavesm2); m_ppar.octave.om1 = *getFloatParameter(cpi_octavesm1); m_ppar.octave.o0 = *getFloatParameter(cpi_octaves0); m_ppar.octave.o1 = *getFloatParameter(cpi_octaves1); m_ppar.octave.o15 = *getFloatParameter(cpi_octaves15); m_ppar.octave.o2 = *getFloatParameter(cpi_octaves2); m_ppar.octave.enabled = true; m_ppar.filter.low = *getFloatParameter(cpi_filter_low); m_ppar.filter.high = *getFloatParameter(cpi_filter_high); m_ppar.tonal_vs_noise.enabled = (*getFloatParameter(cpi_tonalvsnoisebw)) > 0.75; m_ppar.tonal_vs_noise.bandwidth = *getFloatParameter(cpi_tonalvsnoisebw); m_ppar.tonal_vs_noise.preserve = *getFloatParameter(cpi_tonalvsnoisepreserve); m_stretch_source->setOnsetDetection(*getFloatParameter(cpi_onsetdetection)); m_stretch_source->setLoopXFadeLength(*getFloatParameter(cpi_loopxfadelen)); double t0 = *getFloatParameter(cpi_soundstart); double t1 = *getFloatParameter(cpi_soundend); if (t0 > t1) std::swap(t0, t1); if (t1 - t0 < 0.001) t1 = t0 + 0.001; m_stretch_source->setPlayRange({ t0,t1 }, true); m_stretch_source->setFreezing(getParameter(cpi_freeze)); m_stretch_source->setPaused(getParameter(cpi_pause_enabled)); m_stretch_source->setProcessParameters(&m_ppar); AudioSourceChannelInfo aif(buffer); if (isNonRealtime() || m_use_backgroundbuffering == false) { m_stretch_source->getNextAudioBlock(aif); } else { m_buffering_source->getNextAudioBlock(aif); } if (getParameter(cpi_passthrough) > 0.5f) { for (int i = 0; i < totalNumInputChannels; ++i) { buffer.addFrom(i, 0, m_input_buffer, i, 0, buffer.getNumSamples()); } } for (int i = 0; i < buffer.getNumChannels(); ++i) { for (int j = 0; j < buffer.getNumSamples(); ++j) { float sample = buffer.getSample(i,j); if (std::isnan(sample) || std::isinf(sample)) ++m_abnormal_output_samples; } } } //============================================================================== bool PaulstretchpluginAudioProcessor::hasEditor() const { return true; // (change this to false if you choose to not supply an editor) } AudioProcessorEditor* PaulstretchpluginAudioProcessor::createEditor() { return new PaulstretchpluginAudioProcessorEditor (*this); } //============================================================================== void PaulstretchpluginAudioProcessor::getStateInformation (MemoryBlock& destData) { ValueTree paramtree = getStateTree(false,false); MemoryOutputStream stream(destData,true); paramtree.writeToStream(stream); } void PaulstretchpluginAudioProcessor::setStateInformation (const void* data, int sizeInBytes) { ValueTree tree = ValueTree::readFromData(data, sizeInBytes); setStateFromTree(tree); } void PaulstretchpluginAudioProcessor::setRecordingEnabled(bool b) { ScopedLock locker(m_cs); int lenbufframes = getSampleRateChecked()*m_max_reclen; if (b == true) { m_using_memory_buffer = true; m_current_file = File(); m_recbuffer.setSize(2, m_max_reclen*getSampleRateChecked()+4096,false,false,true); m_recbuffer.clear(); m_rec_pos = 0; m_thumb->reset(m_recbuffer.getNumChannels(), getSampleRateChecked(), lenbufframes); m_is_recording = true; } else { if (m_is_recording == true) { finishRecording(lenbufframes); } } } double PaulstretchpluginAudioProcessor::getRecordingPositionPercent() { if (m_is_recording==false) return 0.0; return 1.0 / m_recbuffer.getNumSamples()*m_rec_pos; } String PaulstretchpluginAudioProcessor::setAudioFile(File f) { //if (f==File()) // return String(); //if (f==m_current_file && f.getLastModificationTime()==m_current_file_date) // return String(); auto ai = unique_from_raw(m_afm->createReaderFor(f)); if (ai != nullptr) { if (ai->numChannels > 32) { //MessageManager::callAsync([cb, file]() { cb("Too many channels in file " + file.getFullPathName()); }); return "Too many channels in file "+f.getFullPathName(); } if (ai->bitsPerSample>32) { //MessageManager::callAsync([cb, file]() { cb("Too high bit depth in file " + file.getFullPathName()); }); return "Too high bit depth in file " + f.getFullPathName(); } m_thumb->setSource(new FileInputSource(f)); ScopedLock locker(m_cs); m_stretch_source->setAudioFile(f); m_stretch_source->seekPercent(*getFloatParameter(cpi_soundstart)); m_current_file = f; m_current_file_date = m_current_file.getLastModificationTime(); m_using_memory_buffer = false; return String(); //MessageManager::callAsync([cb, file]() { cb(String()); }); } return "Could not open file " + f.getFullPathName(); } Range PaulstretchpluginAudioProcessor::getTimeSelection() { return { *getFloatParameter(cpi_soundstart),*getFloatParameter(cpi_soundend) }; } double PaulstretchpluginAudioProcessor::getPreBufferingPercent() { if (m_buffering_source==nullptr) return 0.0; return m_buffering_source->getPercentReady(); } void PaulstretchpluginAudioProcessor::timerCallback(int id) { if (id == 1) { bool capture = getParameter(cpi_capture_enabled); if (capture == false && m_max_reclen != *getFloatParameter(cpi_max_capture_len)) { m_max_reclen = *getFloatParameter(cpi_max_capture_len); //Logger::writeToLog("Changing max capture len to " + String(m_max_reclen)); } if (capture == true && m_is_recording == false) { setRecordingEnabled(true); return; } if (capture == false && m_is_recording == true) { setRecordingEnabled(false); return; } if (m_cur_num_out_chans != *m_outchansparam) { jassert(m_curmaxblocksize > 0); ScopedLock locker(m_cs); m_prebuffering_inited = false; m_cur_num_out_chans = *m_outchansparam; //Logger::writeToLog("Switching to use " + String(m_cur_num_out_chans) + " out channels"); String err; startplay({ *getFloatParameter(cpi_soundstart),*getFloatParameter(cpi_soundend) }, m_cur_num_out_chans, m_curmaxblocksize, err); m_prebuffering_inited = true; } } } void PaulstretchpluginAudioProcessor::finishRecording(int lenrecording) { m_is_recording = false; m_stretch_source->setAudioBufferAsInputSource(&m_recbuffer, getSampleRateChecked(), lenrecording); m_stretch_source->setPlayRange({ *getFloatParameter(cpi_soundstart),*getFloatParameter(cpi_soundend) }, true); auto ed = dynamic_cast(getActiveEditor()); if (ed) { //ed->setAudioBuffer(&m_recbuffer, getSampleRate(), lenrecording); } } //============================================================================== // This creates new instances of the plugin.. AudioProcessor* JUCE_CALLTYPE createPluginFilter() { return new PaulstretchpluginAudioProcessor(); }