If a dead device comes back, put it into the right slot.

[nageru] / audio_mixer.h

#ifndef _AUDIO_MIXER_H
#define _AUDIO_MIXER_H 1

// The audio mixer, dealing with extracting the right signals from
// each capture card, resampling signals so that they are in sync,
// processing them with effects (if desired), and then mixing them
// all together into one final audio signal.
//
// All operations on AudioMixer (except destruction) are thread-safe.

#include <math.h>
#include <stdint.h>
#include <atomic>
#include <map>
#include <memory>
#include <mutex>
#include <set>
#include <vector>
#include <zita-resampler/resampler.h>

#include "alsa_input.h"
#include "bmusb/bmusb.h"
#include "correlation_measurer.h"
#include "db.h"
#include "defs.h"
#include "ebu_r128_proc.h"
#include "filter.h"
#include "resampling_queue.h"
#include "stereocompressor.h"

namespace bmusb {
struct AudioFormat;
}  // namespace bmusb

enum class InputSourceType { SILENCE, CAPTURE_CARD, ALSA_INPUT };
struct DeviceSpec {
        InputSourceType type;
        unsigned index;

        bool operator== (const DeviceSpec &other) const {
                return type == other.type && index == other.index;
        }

        bool operator< (const DeviceSpec &other) const {
                if (type != other.type)
                        return type < other.type;
                return index < other.index;
        }
};
struct DeviceInfo {
        std::string name;
        unsigned num_channels;
};

enum EQBand {
        EQ_BAND_BASS = 0,
        EQ_BAND_MID,
        EQ_BAND_TREBLE,
        NUM_EQ_BANDS
};

static inline uint64_t DeviceSpec_to_key(const DeviceSpec &device_spec)
{
        return (uint64_t(device_spec.type) << 32) | device_spec.index;
}

static inline DeviceSpec key_to_DeviceSpec(uint64_t key)
{
        return DeviceSpec{ InputSourceType(key >> 32), unsigned(key & 0xffffffff) };
}

struct InputMapping {
        struct Bus {
                std::string name;
                DeviceSpec device;
                int source_channel[2] { -1, -1 };  // Left and right. -1 = none.
        };

        std::vector<Bus> buses;
};

class AudioMixer {
public:
        AudioMixer(unsigned num_cards);
        void reset_resampler(DeviceSpec device_spec);
        void reset_meters();

        // Add audio (or silence) to the given device's queue. Can return false if
        // the lock wasn't successfully taken; if so, you should simply try again.
        // (This is to avoid a deadlock where a card hangs on the mutex in add_audio()
        // while we are trying to shut it down from another thread that also holds
        // the mutex.) frame_length is in TIMEBASE units.
        bool add_audio(DeviceSpec device_spec, const uint8_t *data, unsigned num_samples, bmusb::AudioFormat audio_format, int64_t frame_length);
        bool add_silence(DeviceSpec device_spec, unsigned samples_per_frame, unsigned num_frames, int64_t frame_length);

        // If a given device is offline for whatever reason and cannot deliver audio
        // (by means of add_audio() or add_silence()), you can call put it in silence mode,
        // where it will be taken to only output silence. Note that when taking it _out_
        // of silence mode, the resampler will be reset, so that old audio will not
        // affect it. Same true/false behavior as add_audio().
        bool silence_card(DeviceSpec device_spec, bool silence);

        std::vector<float> get_output(double pts, unsigned num_samples, ResamplingQueue::RateAdjustmentPolicy rate_adjustment_policy);

        void set_fader_volume(unsigned bus_index, float level_db) { fader_volume_db[bus_index] = level_db; }

        // Note: This operation holds all ALSA devices (see ALSAPool::get_devices()).
        // You will need to call set_input_mapping() to get the hold state correctly,
        // or every card will be held forever.
        std::map<DeviceSpec, DeviceInfo> get_devices();

        // See comments on ALSAPool::get_card_state().
        ALSAPool::Device::State get_alsa_card_state(unsigned index)
        {
                return alsa_pool.get_card_state(index);
        }

        void set_name(DeviceSpec device_spec, const std::string &name);

        void set_input_mapping(const InputMapping &input_mapping);
        InputMapping get_input_mapping() const;

        void set_locut_cutoff(float cutoff_hz)
        {
                locut_cutoff_hz = cutoff_hz;
        }

        float get_locut_cutoff() const
        {
                return locut_cutoff_hz;
        }

        void set_locut_enabled(unsigned bus, bool enabled)
        {
                locut_enabled[bus] = enabled;
        }

        bool get_locut_enabled(unsigned bus)
        {
                return locut_enabled[bus];
        }

        void set_eq(unsigned bus_index, EQBand band, float db_gain)
        {
                assert(band >= 0 && band < NUM_EQ_BANDS);
                eq_level_db[bus_index][band] = db_gain;
        }

        float get_eq(unsigned bus_index, EQBand band) const
        {
                assert(band >= 0 && band < NUM_EQ_BANDS);
                return eq_level_db[bus_index][band];
        }

        float get_limiter_threshold_dbfs() const
        {
                return limiter_threshold_dbfs;
        }

        float get_compressor_threshold_dbfs(unsigned bus_index) const
        {
                return compressor_threshold_dbfs[bus_index];
        }

        void set_limiter_threshold_dbfs(float threshold_dbfs)
        {
                limiter_threshold_dbfs = threshold_dbfs;
        }

        void set_compressor_threshold_dbfs(unsigned bus_index, float threshold_dbfs)
        {
                compressor_threshold_dbfs[bus_index] = threshold_dbfs;
        }

        void set_limiter_enabled(bool enabled)
        {
                limiter_enabled = enabled;
        }

        bool get_limiter_enabled() const
        {
                return limiter_enabled;
        }

        void set_compressor_enabled(unsigned bus_index, bool enabled)
        {
                compressor_enabled[bus_index] = enabled;
        }

        bool get_compressor_enabled(unsigned bus_index) const
        {
                return compressor_enabled[bus_index];
        }

        void set_gain_staging_db(unsigned bus_index, float gain_db)
        {
                std::unique_lock<std::mutex> lock(compressor_mutex);
                level_compressor_enabled[bus_index] = false;
                gain_staging_db[bus_index] = gain_db;
        }

        float get_gain_staging_db(unsigned bus_index) const
        {
                std::unique_lock<std::mutex> lock(compressor_mutex);
                return gain_staging_db[bus_index];
        }

        void set_gain_staging_auto(unsigned bus_index, bool enabled)
        {
                std::unique_lock<std::mutex> lock(compressor_mutex);
                level_compressor_enabled[bus_index] = enabled;
        }

        bool get_gain_staging_auto(unsigned bus_index) const
        {
                std::unique_lock<std::mutex> lock(compressor_mutex);
                return level_compressor_enabled[bus_index];
        }

        void set_final_makeup_gain_db(float gain_db)
        {
                std::unique_lock<std::mutex> lock(compressor_mutex);
                final_makeup_gain_auto = false;
                final_makeup_gain = from_db(gain_db);
        }

        float get_final_makeup_gain_db()
        {
                std::unique_lock<std::mutex> lock(compressor_mutex);
                return to_db(final_makeup_gain);
        }

        void set_final_makeup_gain_auto(bool enabled)
        {
                std::unique_lock<std::mutex> lock(compressor_mutex);
                final_makeup_gain_auto = enabled;
        }

        bool get_final_makeup_gain_auto() const
        {
                std::unique_lock<std::mutex> lock(compressor_mutex);
                return final_makeup_gain_auto;
        }

        void reset_peak(unsigned bus_index);

        struct BusLevel {
                float current_level_dbfs[2];  // Digital peak of last frame, left and right.
                float peak_level_dbfs[2];  // Digital peak with hold, left and right.
                float historic_peak_dbfs;
                float gain_staging_db;
                float compressor_attenuation_db;  // A positive number; 0.0 for no attenuation.
        };

        typedef std::function<void(float level_lufs, float peak_db,
                                   std::vector<BusLevel> bus_levels,
                                   float global_level_lufs, float range_low_lufs, float range_high_lufs,
                                   float final_makeup_gain_db,
                                   float correlation)> audio_level_callback_t;
        void set_audio_level_callback(audio_level_callback_t callback)
        {
                audio_level_callback = callback;
        }

private:
        struct AudioDevice {
                std::unique_ptr<ResamplingQueue> resampling_queue;
                int64_t next_local_pts = 0;
                std::string name;
                unsigned capture_frequency = OUTPUT_FREQUENCY;
                // Which channels we consider interesting (ie., are part of some input_mapping).
                std::set<unsigned> interesting_channels;
                bool silenced = false;
        };

        const AudioDevice *find_audio_device(DeviceSpec device_spec) const
        {
                return const_cast<AudioMixer *>(this)->find_audio_device(device_spec);
        }

        AudioDevice *find_audio_device(DeviceSpec device_spec);

        void find_sample_src_from_device(const std::map<DeviceSpec, std::vector<float>> &samples_card, DeviceSpec device_spec, int source_channel, const float **srcptr, unsigned *stride);
        void fill_audio_bus(const std::map<DeviceSpec, std::vector<float>> &samples_card, const InputMapping::Bus &bus, unsigned num_samples, float *output);
        void reset_resampler_mutex_held(DeviceSpec device_spec);
        void apply_eq(unsigned bus_index, std::vector<float> *samples_bus);
        void update_meters(const std::vector<float> &samples);
        void add_bus_to_master(unsigned bus_index, const std::vector<float> &samples_bus, std::vector<float> *samples_out);
        void measure_bus_levels(unsigned bus_index, const std::vector<float> &left, const std::vector<float> &right);
        void send_audio_level_callback();
        std::vector<DeviceSpec> get_active_devices() const;

        unsigned num_cards;

        mutable std::timed_mutex audio_mutex;

        ALSAPool alsa_pool;
        AudioDevice video_cards[MAX_VIDEO_CARDS];  // Under audio_mutex.
        AudioDevice alsa_inputs[MAX_ALSA_CARDS];  // Under audio_mutex.

        std::atomic<float> locut_cutoff_hz{120};
        StereoFilter locut[MAX_BUSES];  // Default cutoff 120 Hz, 24 dB/oct.
        std::atomic<bool> locut_enabled[MAX_BUSES];
        StereoFilter eq[MAX_BUSES][NUM_EQ_BANDS];  // The one for EQBand::MID isn't actually used (see comments in apply_eq()).

        // First compressor; takes us up to about -12 dBFS.
        mutable std::mutex compressor_mutex;
        std::unique_ptr<StereoCompressor> level_compressor[MAX_BUSES];  // Under compressor_mutex. Used to set/override gain_staging_db if <level_compressor_enabled>.
        float gain_staging_db[MAX_BUSES];  // Under compressor_mutex.
        bool level_compressor_enabled[MAX_BUSES];  // Under compressor_mutex.

        static constexpr float ref_level_dbfs = -14.0f;  // Chosen so that we end up around 0 LU in practice.
        static constexpr float ref_level_lufs = -23.0f;  // 0 LU, more or less by definition.

        StereoCompressor limiter;
        std::atomic<float> limiter_threshold_dbfs{ref_level_dbfs + 4.0f};   // 4 dB.
        std::atomic<bool> limiter_enabled{true};
        std::unique_ptr<StereoCompressor> compressor[MAX_BUSES];
        std::atomic<float> compressor_threshold_dbfs[MAX_BUSES];
        std::atomic<bool> compressor_enabled[MAX_BUSES];

        // Note: The values here are not in dB.
        struct PeakHistory {
                float current_level = 0.0f;  // Peak of the last frame.
                float historic_peak = 0.0f;  // Highest peak since last reset; no falloff.
                float current_peak = 0.0f;  // Current peak of the peak meter.
                float last_peak = 0.0f;
                float age_seconds = 0.0f;   // Time since "last_peak" was set.
        };
        PeakHistory peak_history[MAX_BUSES][2];  // Separate for each channel. Under audio_mutex.

        double final_makeup_gain = 1.0;  // Under compressor_mutex. Read/write by the user. Note: Not in dB, we want the numeric precision so that we can change it slowly.
        bool final_makeup_gain_auto = true;  // Under compressor_mutex.

        InputMapping input_mapping;  // Under audio_mutex.
        std::atomic<float> fader_volume_db[MAX_BUSES] {{ 0.0f }};
        float last_fader_volume_db[MAX_BUSES] { 0.0f };  // Under audio_mutex.
        std::atomic<float> eq_level_db[MAX_BUSES][NUM_EQ_BANDS] {{{ 0.0f }}};

        audio_level_callback_t audio_level_callback = nullptr;
        mutable std::mutex audio_measure_mutex;
        Ebu_r128_proc r128;  // Under audio_measure_mutex.
        CorrelationMeasurer correlation;  // Under audio_measure_mutex.
        Resampler peak_resampler;  // Under audio_measure_mutex.
        std::atomic<float> peak{0.0f};
};

extern AudioMixer *global_audio_mixer;

#endif  // !defined(_AUDIO_MIXER_H)