Carla/source/native-plugins/audio-file.cpp

/*
 * Carla Native Plugins
 * Copyright (C) 2013-2022 Filipe Coelho <falktx@falktx.com>
 *
 * 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 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.
 *
 * For a full copy of the GNU General Public License see the doc/GPL.txt file.
 */

#include "CarlaNativePrograms.hpp"
#include "CarlaString.hpp"

#include "audio-base.hpp"

static const char* const audiofilesWildcard =
#ifdef HAVE_SNDFILE
    "*.aif;*.aifc;*.aiff;*.au;*.bwf;*.flac;*.htk;*.iff;*.mat4;*.mat5;*.oga;*.ogg;"
    "*.paf;*.pvf;*.pvf5;*.sd2;*.sf;*.snd;*.svx;*.vcc;*.w64;*.wav;*.xi;"
#endif
#ifdef HAVE_FFMPEG
    "*.3g2;*.3gp;*.aac;*.ac3;*.amr;*.ape;*.mp2;*.mp3;*.mpc;*.wma;"
# ifndef HAVE_SNDFILE
    "*.flac;*.oga;*.ogg;*.w64;*.wav;"
# endif
#else
    "*.mp3;"
#endif
;

// -----------------------------------------------------------------------

class AudioFilePlugin : public NativePluginWithMidiPrograms<FileAudio>
{
public:
#ifndef __MOD_DEVICES__
    typedef enum _PendingInlineDisplay
# ifdef CARLA_PROPER_CPP11_SUPPORT
    : uint8_t
# endif
    {
        InlineDisplayNotPending,
        InlineDisplayNeedRequest,
        InlineDisplayRequesting
    } PendingInlineDisplay;
#endif

    enum Parameters {
        kParameterLooping,
        kParameterHostSync,
        kParameterVolume,
        kParameterEnabled,
        kParameterInfoChannels,
        kParameterInfoBitRate,
        kParameterInfoBitDepth,
        kParameterInfoSampleRate,
        kParameterInfoLength,
        kParameterInfoPosition,
        kParameterInfoPoolFill,
        kParameterCount
    };

    AudioFilePlugin(const NativeHostDescriptor* const host)
        : NativePluginWithMidiPrograms<FileAudio>(host, fPrograms, 2),
          fLoopMode(true),
#ifdef __MOD_DEVICES__
          fHostSync(false),
#else
          fHostSync(true),
#endif
          fEnabled(true),
          fDoProcess(false),
          fWasPlayingBefore(false),
          fNeedsFileRead(false),
          fEntireFileLoaded(false),
          fMaxFrame(0),
          fInternalTransportFrame(0),
          fLastPosition(0.0f),
          fLastPoolFill(0.0f),
          fVolume(1.0f),
          fPool(),
          fReader(),
          fFilename(),
          fPrograms(hostGetFilePath("audio"), audiofilesWildcard),
          fPreviewData()
#ifndef __MOD_DEVICES__
        , fInlineDisplay()
#endif
    {
    }

    ~AudioFilePlugin() override
    {
        fReader.destroy();
        fPool.destroy();
    }

protected:
    // -------------------------------------------------------------------
    // Plugin parameter calls

    uint32_t getParameterCount() const override
    {
        return kParameterCount;
    }

    const NativeParameter* getParameterInfo(const uint32_t index) const override
    {
        static NativeParameter param;

        param.scalePointCount  = 0;
        param.scalePoints      = nullptr;
        param.unit             = nullptr;
        param.ranges.step      = 1.0f;
        param.ranges.stepSmall = 1.0f;
        param.ranges.stepLarge = 1.0f;
        param.designation      = NATIVE_PARAMETER_DESIGNATION_NONE;

        switch (index)
        {
        case kParameterLooping:
            param.name  = "Loop Mode";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_BOOLEAN);
            param.ranges.def = 1.0f;
            param.ranges.min = 0.0f;
            param.ranges.max = 1.0f;
            break;
        case kParameterHostSync:
            param.name  = "Host Sync";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_BOOLEAN);
#ifdef __MOD_DEVICES__
            param.ranges.def = 0.0f;
#else
            param.ranges.def = 1.0f;
#endif
            param.ranges.min = 0.0f;
            param.ranges.max = 1.0f;
            break;
        case kParameterVolume:
            param.name  = "Volume";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED);
            param.ranges.def = 100.0f;
            param.ranges.min = 0.0f;
            param.ranges.max = 127.0f;
            param.ranges.stepSmall = 0.5f;
            param.ranges.stepLarge = 10.0f;
            param.unit = "%";
            break;
        case kParameterEnabled:
            param.name  = "Enabled";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_BOOLEAN|
                                                            NATIVE_PARAMETER_USES_DESIGNATION);
            param.ranges.def = 1.0f;
            param.ranges.min = 0.0f;
            param.ranges.max = 1.0f;
            param.designation = NATIVE_PARAMETER_DESIGNATION_ENABLED;
            break;
        case kParameterInfoChannels:
            param.name  = "Num Channels";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_INTEGER|
                                                            NATIVE_PARAMETER_IS_OUTPUT);
            param.ranges.def = 0.0f;
            param.ranges.min = 0.0f;
            param.ranges.max = 2.0f;
            break;
        case kParameterInfoBitRate:
            param.name  = "Bit Rate";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_INTEGER|
                                                            NATIVE_PARAMETER_IS_OUTPUT);
            param.ranges.def = 0.0f;
            param.ranges.min = -1.0f;
            param.ranges.max = 384000.0f * 64.0f * 2.0f;
            break;
        case kParameterInfoBitDepth:
            param.name  = "Bit Depth";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_INTEGER|
                                                            NATIVE_PARAMETER_IS_OUTPUT);
            param.ranges.def = 0.0f;
            param.ranges.min = 0.0f;
            param.ranges.max = 64.0f;
            break;
        case kParameterInfoSampleRate:
            param.name  = "Sample Rate";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_INTEGER|
                                                            NATIVE_PARAMETER_IS_OUTPUT);
            param.ranges.def = 0.0f;
            param.ranges.min = 0.0f;
            param.ranges.max = 384000.0f;
            break;
        case kParameterInfoLength:
            param.name  = "Length";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_OUTPUT);
            param.ranges.def = 0.0f;
            param.ranges.min = 0.0f;
            param.ranges.max = (float)INT64_MAX;
            param.unit = "s";
            break;
        case kParameterInfoPosition:
            param.name  = "Position";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_OUTPUT);
            param.ranges.def = 0.0f;
            param.ranges.min = 0.0f;
            param.ranges.max = 100.0f;
            param.unit = "%";
            break;
        case kParameterInfoPoolFill:
            param.name  = "Pool Fill";
            param.hints = static_cast<NativeParameterHints>(NATIVE_PARAMETER_IS_AUTOMATABLE|
                                                            NATIVE_PARAMETER_IS_ENABLED|
                                                            NATIVE_PARAMETER_IS_OUTPUT);
            param.ranges.def = 0.0f;
            param.ranges.min = 0.0f;
            param.ranges.max = 100.0f;
            param.unit = "%";
            break;
        default:
            return nullptr;
        }

        return &param;
    }

    float getParameterValue(const uint32_t index) const override
    {
        switch (index)
        {
        case kParameterLooping:
            return fLoopMode ? 1.0f : 0.0f;
        case kParameterHostSync:
            return fHostSync ? 1.0f : 0.0f;
        case kParameterEnabled:
            return fEnabled ? 1.0f : 0.0f;
        case kParameterVolume:
            return fVolume * 100.0f;
        case kParameterInfoPosition:
            return fLastPosition;
        case kParameterInfoPoolFill:
            return fLastPoolFill;
        case kParameterInfoBitRate:
            return static_cast<float>(fReader.getCurrentBitRate());
        }

        const ADInfo nfo = fReader.getFileInfo();

        switch (index)
        {
        case kParameterInfoChannels:
            return static_cast<float>(nfo.channels);
        case kParameterInfoBitDepth:
            return static_cast<float>(nfo.bit_depth);
        case kParameterInfoSampleRate:
            return static_cast<float>(nfo.sample_rate);
        case kParameterInfoLength:
            return static_cast<float>(nfo.length)/1000.0f;
        default:
            return 0.0f;
        }
    }

    // -------------------------------------------------------------------
    // Plugin state calls

    void setParameterValue(const uint32_t index, const float value) override
    {
        if (index == kParameterVolume)
        {
            fVolume = value / 100.0f;
            return;
        }

        const bool b = (value > 0.5f);

        switch (index)
        {
        case kParameterLooping:
            if (fLoopMode != b)
            {
                fLoopMode = b;
                fReader.setLoopingMode(b);
            }
            break;
        case kParameterHostSync:
            if (fHostSync != b)
            {
                fInternalTransportFrame = 0;
                fHostSync = b;
            }
            break;
        case kParameterEnabled:
            if (fEnabled != b)
            {
                fInternalTransportFrame = 0;
                fEnabled = b;
            }
            break;
        default:
            break;
        }
    }

    void setCustomData(const char* const key, const char* const value) override
    {
        if (std::strcmp(key, "file") != 0)
            return;

        invalidateNextFilename();
        loadFilename(value);
    }

    // -------------------------------------------------------------------
    // Plugin process calls

    void process2(const float* const*, float** const outBuffer, const uint32_t frames,
                  const NativeMidiEvent*, uint32_t) override
    {
        float* const out1 = outBuffer[0];
        float* const out2 = outBuffer[1];

        const water::GenericScopedLock<water::SpinLock> gsl(fPool.mutex);

        if (! fDoProcess)
        {
            // carla_stderr("P: no process");
            carla_zeroFloats(out1, frames);
            carla_zeroFloats(out2, frames);
            fLastPosition = 0.0f;
            return;
        }

        const bool loopMode = fLoopMode;
        const float volume = fVolume;
        bool needsIdleRequest = false;
        bool playing;
        uint64_t frame;

        if (fHostSync)
        {
            const NativeTimeInfo* const timePos = getTimeInfo();
            playing = fEnabled && timePos->playing;
            frame = timePos->frame;
        }
        else
        {
            playing = fEnabled;
            frame = fInternalTransportFrame;

            if (playing)
                fInternalTransportFrame += frames;
        }

        // not playing
        if (! playing)
        {
            // carla_stderr("P: not playing");
            if (frame == 0 && fWasPlayingBefore)
                fReader.setNeedsRead(frame);

            carla_zeroFloats(out1, frames);
            carla_zeroFloats(out2, frames);
            fWasPlayingBefore = false;
            return;
        }
        else
        {
            fWasPlayingBefore = true;
        }

        // out of reach
        if ((frame < fPool.startFrame || frame >= fMaxFrame) && !loopMode)
        {
            if (frame < fPool.startFrame)
            {
                needsIdleRequest = true;
                fNeedsFileRead = true;
                fReader.setNeedsRead(frame);
            }

            carla_zeroFloats(out1, frames);
            carla_zeroFloats(out2, frames);

#ifndef __MOD_DEVICES__
            if (fInlineDisplay.writtenValues < 32)
            {
                fInlineDisplay.lastValuesL[fInlineDisplay.writtenValues] = 0.0f;
                fInlineDisplay.lastValuesR[fInlineDisplay.writtenValues] = 0.0f;
                ++fInlineDisplay.writtenValues;
            }
            if (fInlineDisplay.pending == InlineDisplayNotPending)
            {
                needsIdleRequest = true;
                fInlineDisplay.pending = InlineDisplayNeedRequest;
            }
#endif

            if (needsIdleRequest)
                hostRequestIdle();

            if (frame == 0)
                fLastPosition = 0.0f;
            else if (frame >= fMaxFrame)
                fLastPosition = 100.0f;
            else
                fLastPosition = static_cast<float>(frame) / static_cast<float>(fMaxFrame) * 100.0f;
            return;
        }

        if (fEntireFileLoaded)
        {
            // NOTE: frame is always < fMaxFrame (or looping)
            uint32_t targetStartFrame = static_cast<uint32_t>(loopMode ? frame % fMaxFrame : frame);

            for (uint32_t framesDone=0, framesToDo=frames, remainingFrames; framesDone < frames;)
            {
                if (targetStartFrame + framesToDo <= fMaxFrame)
                {
                    // everything fits together
                    carla_copyFloats(out1+framesDone, fPool.buffer[0]+targetStartFrame, framesToDo);
                    carla_copyFloats(out2+framesDone, fPool.buffer[1]+targetStartFrame, framesToDo);
                    break;
                }

                remainingFrames = std::min(fMaxFrame - targetStartFrame, framesToDo);
                carla_copyFloats(out1+framesDone, fPool.buffer[0]+targetStartFrame, remainingFrames);
                carla_copyFloats(out2+framesDone, fPool.buffer[1]+targetStartFrame, remainingFrames);
                framesDone += remainingFrames;
                framesToDo -= remainingFrames;

                if (! loopMode)
                {
                    // not looping, stop here
                    if (framesToDo != 0)
                    {
                        carla_zeroFloats(out1+framesDone, framesToDo);
                        carla_zeroFloats(out2+framesDone, framesToDo);
                    }
                    break;
                }

                // reset for next loop
                targetStartFrame = 0;
            }

            fLastPosition = static_cast<float>(targetStartFrame) / static_cast<float>(fMaxFrame) * 100.0f;
        }
        else
        {
            const bool offline = isOffline();

            if (! fReader.tryPutData(fPool, out1, out2, frame, frames, loopMode, offline, needsIdleRequest))
            {
                carla_zeroFloats(out1, frames);
                carla_zeroFloats(out2, frames);
            }

            if (needsIdleRequest)
            {
                fNeedsFileRead = true;

                if (isOffline())
                {
                    needsIdleRequest = false;
                    fReader.readPoll();

                    if (! fReader.tryPutData(fPool, out1, out2, frame, frames, loopMode, offline, needsIdleRequest))
                    {
                        carla_zeroFloats(out1, frames);
                        carla_zeroFloats(out2, frames);
                    }

                    if (needsIdleRequest)
                        fNeedsFileRead = true;
                }
            }

            const uint32_t modframe = static_cast<uint32_t>(frame % fMaxFrame);
            fLastPosition = static_cast<float>(modframe) / static_cast<float>(fMaxFrame) * 100.0f;

            if (modframe > fPool.startFrame)
                fLastPoolFill = static_cast<float>(modframe - fPool.startFrame) / static_cast<float>(fPool.numFrames) * 100.0f;
            else
                fLastPoolFill = 100.0f;
        }

        if (carla_isNotZero(volume-1.0f))
        {
            carla_multiply(out1, volume, frames);
            carla_multiply(out2, volume, frames);
        }

#ifndef __MOD_DEVICES__
        if (fInlineDisplay.writtenValues < 32)
        {
            fInlineDisplay.lastValuesL[fInlineDisplay.writtenValues] = carla_findMaxNormalizedFloat(out1, frames);
            fInlineDisplay.lastValuesR[fInlineDisplay.writtenValues] = carla_findMaxNormalizedFloat(out2, frames);
            ++fInlineDisplay.writtenValues;
        }
        if (fInlineDisplay.pending == InlineDisplayNotPending)
        {
            needsIdleRequest = true;
            fInlineDisplay.pending = InlineDisplayNeedRequest;
        }
#endif

        if (needsIdleRequest)
            hostRequestIdle();
    }

    // -------------------------------------------------------------------
    // Plugin UI calls

    void uiShow(const bool show) override
    {
        if (! show)
            return;

        if (const char* const filename = uiOpenFile(false, "Open Audio File", ""))
            uiCustomDataChanged("file", filename);

        uiClosed();
    }

    // -------------------------------------------------------------------
    // Plugin state calls

    void setStateFromFile(const char* const filename) override
    {
        loadFilename(filename);
    }

    // -------------------------------------------------------------------
    // Plugin dispatcher calls

    void idle() override
    {
        NativePluginWithMidiPrograms<FileAudio>::idle();

        if (fNeedsFileRead)
        {
            fReader.readPoll();
            fNeedsFileRead = false;
        }

#ifndef __MOD_DEVICES__
        if (fInlineDisplay.pending == InlineDisplayNeedRequest)
        {
            fInlineDisplay.pending = InlineDisplayRequesting;
            hostQueueDrawInlineDisplay();
        }
#endif
    }

#ifndef __MOD_DEVICES__
    const NativeInlineDisplayImageSurface* renderInlineDisplay(const uint32_t rwidth, const uint32_t height) override
    {
        CARLA_SAFE_ASSERT_RETURN(height > 4, nullptr);

        const uint32_t width = rwidth == height ? height * 4 : rwidth;

        /* NOTE the code is this function is not optimized, still learning my way through pixels...
         */
        const size_t stride = width * 4;
        const size_t dataSize = stride * height;
        const uint pxToMove = fDoProcess ? fInlineDisplay.writtenValues : 0;

        uchar* data = fInlineDisplay.data;

        if (fInlineDisplay.dataSize != dataSize || data == nullptr)
        {
            delete[] data;
            data = new uchar[dataSize];
            std::memset(data, 0, dataSize);
            fInlineDisplay.data = data;
            fInlineDisplay.dataSize = dataSize;
        }
        else if (pxToMove != 0)
        {
            // shift all previous values to the left
            for (uint w=0; w < width - pxToMove; ++w)
                for (uint h=0; h < height; ++h)
                    std::memmove(&data[h * stride + w * 4], &data[h * stride + (w+pxToMove) * 4], 4);
        }

        fInlineDisplay.width  = static_cast<int>(width);
        fInlineDisplay.height = static_cast<int>(height);
        fInlineDisplay.stride = static_cast<int>(stride);

        if (pxToMove != 0)
        {
            const uint h2 = height / 2;

            // clear current line
            for (uint w=width-pxToMove; w < width; ++w)
                for (uint h=0; h < height; ++h)
                    memset(&data[h * stride + w * 4], 0, 4);

            // draw upper/left
            for (uint i=0; i < pxToMove && i < 32; ++i)
            {
                const float valueL = fInlineDisplay.lastValuesL[i];
                const float valueR = fInlineDisplay.lastValuesR[i];

                const uint h2L = static_cast<uint>(valueL * (float)h2);
                const uint h2R = static_cast<uint>(valueR * (float)h2);
                const uint w   = width - pxToMove + i;

                for (uint h=0; h < h2L; ++h)
                {
                    // -30dB
                    //if (valueL < 0.032f)
                    //    continue;

                    data[(h2 - h) * stride + w * 4 + 3] = 160;

                    // -12dB
                    if (valueL < 0.25f)
                    {
                        data[(h2 - h) * stride + w * 4 + 1] = 255;
                    }
                    // -3dB
                    else if (valueL < 0.70f)
                    {
                        data[(h2 - h) * stride + w * 4 + 2] = 255;
                        data[(h2 - h) * stride + w * 4 + 1] = 255;
                    }
                    else
                    {
                        data[(h2 - h) * stride + w * 4 + 2] = 255;
                    }
                }

                for (uint h=0; h < h2R; ++h)
                {
                    // -30dB
                    //if (valueR < 0.032f)
                    //    continue;

                    data[(h2 + h) * stride + w * 4 + 3] = 160;

                    // -12dB
                    if (valueR < 0.25f)
                    {
                        data[(h2 + h) * stride + w * 4 + 1] = 255;
                    }
                    // -3dB
                    else if (valueR < 0.70f)
                    {
                        data[(h2 + h) * stride + w * 4 + 2] = 255;
                        data[(h2 + h) * stride + w * 4 + 1] = 255;
                    }
                    else
                    {
                        data[(h2 + h) * stride + w * 4 + 2] = 255;
                    }
                }
            }
        }

        fInlineDisplay.writtenValues = 0;
        fInlineDisplay.pending = InlineDisplayNotPending;
        return (NativeInlineDisplayImageSurface*)(NativeInlineDisplayImageSurfaceCompat*)&fInlineDisplay;
    }
#endif

    void sampleRateChanged(double) override
    {
        if (char* const filename = fFilename.releaseBufferPointer())
        {
            loadFilename(filename);
            std::free(filename);
        }
    }

    // -------------------------------------------------------------------

private:
    bool fLoopMode;
    bool fHostSync;
    bool fEnabled;
    bool fDoProcess;
    bool fWasPlayingBefore;
    volatile bool fNeedsFileRead;

    bool fEntireFileLoaded;
    uint32_t fMaxFrame;
    uint32_t fInternalTransportFrame;
    float fLastPosition;
    float fLastPoolFill;
    float fVolume;

    AudioFilePool   fPool;
    AudioFileReader fReader;
    CarlaString     fFilename;

    NativeMidiPrograms fPrograms;
    float fPreviewData[108];

#ifndef __MOD_DEVICES__
    struct InlineDisplay : NativeInlineDisplayImageSurfaceCompat {
        float lastValuesL[32];
        float lastValuesR[32];
        volatile PendingInlineDisplay pending;
        volatile uint8_t writtenValues;

        InlineDisplay()
            : NativeInlineDisplayImageSurfaceCompat(),
# ifdef CARLA_PROPER_CPP11_SUPPORT
              lastValuesL{0.0f},
              lastValuesR{0.0f},
# endif
              pending(InlineDisplayNotPending),
              writtenValues(0)
        {
# ifndef CARLA_PROPER_CPP11_SUPPORT
            carla_zeroFloats(lastValuesL, 32);
            carla_zeroFloats(lastValuesR, 32);
# endif
        }

        ~InlineDisplay()
        {
            if (data != nullptr)
            {
                delete[] data;
                data = nullptr;
            }
        }

        CARLA_DECLARE_NON_COPY_STRUCT(InlineDisplay)
        CARLA_PREVENT_HEAP_ALLOCATION
    } fInlineDisplay;
#endif

    void loadFilename(const char* const filename)
    {
        CARLA_ASSERT(filename != nullptr);
        carla_debug("AudioFilePlugin::loadFilename(\"%s\")", filename);

        fDoProcess = false;
        fLastPoolFill = 0.0f;
        fInternalTransportFrame = 0;
        fPool.destroy();
        fReader.destroy();
        fFilename.clear();

        if (filename == nullptr || *filename == '\0')
        {
            fMaxFrame = 0;
            return;
        }

        const uint32_t previewDataSize = sizeof(fPreviewData)/sizeof(float);

        if (fReader.loadFilename(filename, static_cast<uint32_t>(getSampleRate()), previewDataSize, fPreviewData))
        {
            fEntireFileLoaded = fReader.isEntireFileLoaded();
            fMaxFrame = fReader.getMaxFrame();

            if (fEntireFileLoaded)
            {
                fReader.putAndSwapAllData(fPool);
                fLastPoolFill = 100.0f;
            }
            else
            {
                fReader.createSwapablePool(fPool);
                fReader.readPoll();
            }

            fDoProcess = true;
            fFilename = filename;
            hostSendPreviewBufferData('f', previewDataSize, fPreviewData);
        }
        else
        {
            fEntireFileLoaded = false;
            fMaxFrame = 0;
        }
    }

    PluginClassEND(AudioFilePlugin)
    CARLA_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR(AudioFilePlugin)
};

// -----------------------------------------------------------------------

static const NativePluginDescriptor audiofileDesc = {
    /* category  */ NATIVE_PLUGIN_CATEGORY_UTILITY,
    /* hints     */ static_cast<NativePluginHints>(NATIVE_PLUGIN_IS_RTSAFE
                                                  |NATIVE_PLUGIN_HAS_UI
#ifndef __MOD_DEVICES__
                                                  |NATIVE_PLUGIN_HAS_INLINE_DISPLAY
#endif
                                                  |NATIVE_PLUGIN_REQUESTS_IDLE
                                                  |NATIVE_PLUGIN_NEEDS_UI_OPEN_SAVE
                                                  |NATIVE_PLUGIN_USES_TIME),
    /* supports  */ NATIVE_PLUGIN_SUPPORTS_NOTHING,
    /* audioIns  */ 0,
    /* audioOuts */ 2,
    /* midiIns   */ 0,
    /* midiOuts  */ 0,
    /* paramIns  */ 1,
    /* paramOuts */ 0,
    /* name      */ "Audio File",
    /* label     */ "audiofile",
    /* maker     */ "falkTX",
    /* copyright */ "GNU GPL v2+",
    PluginDescriptorFILL(AudioFilePlugin)
};

// -----------------------------------------------------------------------

CARLA_API_EXPORT
void carla_register_native_plugin_audiofile();

CARLA_API_EXPORT
void carla_register_native_plugin_audiofile()
{
    carla_register_native_plugin(&audiofileDesc);
}

// -----------------------------------------------------------------------