// 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.
+// All operations on AudioMixer, except destruction and set_delay_analyzer(),
+// are thread-safe.
#include <assert.h>
#include <stdint.h>
#include "alsa_pool.h"
#include "correlation_measurer.h"
-#include "db.h"
+#include "decibel.h"
#include "defs.h"
#include "ebu_r128_proc.h"
#include "filter.h"
#include "resampling_queue.h"
#include "stereocompressor.h"
+class DelayAnalyzerInterface;
class DeviceSpecProto;
namespace bmusb {
struct AudioFormat;
} // namespace bmusb
+// Convert the given audio from {16,24,32}-bit M-channel to 32-bit N-channel PCM.
+// Assumes little-endian and chunky, signed PCM throughout.
+std::vector<int32_t> convert_audio_to_fixed32(const uint8_t *data, unsigned num_samples, bmusb::AudioFormat audio_format, unsigned num_destination_channels);
+
+// Similar, except converts to floating-point instead, and converts only one channel.
+void convert_audio_to_fp32(float *dst, size_t out_channel, size_t out_num_channels,
+ const uint8_t *src, size_t in_channel, bmusb::AudioFormat in_audio_format,
+ size_t num_samples);
+
enum EQBand {
EQ_BAND_BASS = 0,
EQ_BAND_MID,
// 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, std::chrono::steady_clock::time_point frame_time);
- bool add_silence(DeviceSpec device_spec, unsigned samples_per_frame, unsigned num_frames, int64_t frame_length);
+ // the mutex.)
+ bool add_audio(DeviceSpec device_spec, const uint8_t *data, unsigned num_samples, bmusb::AudioFormat audio_format, std::chrono::steady_clock::time_point frame_time);
+ bool add_silence(DeviceSpec device_spec, unsigned samples_per_frame, unsigned num_frames);
// 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,
bool get_mute(unsigned bus_index) const { return mute[bus_index]; }
void set_mute(unsigned bus_index, bool muted) { mute[bus_index] = muted; }
- // 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();
+ enum HoldDevices {
+ HOLD_NO_DEVICES,
+
+ // Note: 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.
+ HOLD_ALSA_DEVICES
+ };
+ std::map<DeviceSpec, DeviceInfo> get_devices(HoldDevices hold_devices);
// See comments on ALSAPool::get_card_state().
ALSAPool::Device::State get_alsa_card_state(unsigned index)
MappingMode get_mapping_mode() const;
InputMapping get_input_mapping() const;
+ // See extra_devices.
+ void set_extra_devices(const std::set<DeviceSpec> &devices);
+
unsigned num_buses() const;
void set_locut_cutoff(float cutoff_hz)
void set_gain_staging_db(unsigned bus_index, float gain_db)
{
- std::unique_lock<std::mutex> lock(compressor_mutex);
+ std::lock_guard<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);
+ std::lock_guard<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);
+ std::lock_guard<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);
+ std::lock_guard<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);
+ std::lock_guard<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);
+ std::lock_guard<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);
+ std::lock_guard<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);
+ std::lock_guard<std::mutex> lock(compressor_mutex);
return final_makeup_gain_auto;
}
BusSettings get_bus_settings(unsigned bus_index) const;
void set_bus_settings(unsigned bus_index, const BusSettings &settings);
+ // Does not take ownership. Not thread-safe (so only call when the mixer is being created).
+ void set_delay_analyzer(DelayAnalyzerInterface *delay_analyzer)
+ {
+ this->delay_analyzer = delay_analyzer;
+ }
+
private:
struct AudioDevice {
std::unique_ptr<ResamplingQueue> resampling_queue;
// Which channels we consider interesting (ie., are part of some input_mapping).
std::set<unsigned> interesting_channels;
bool silenced = false;
+
+ // Positive means the audio is delayed, negative means we try to have it earlier
+ // (although we can't time-travel!). Stored together with the input mapping.
+ double extra_delay_ms = 0.0;
};
const AudioDevice *find_audio_device(DeviceSpec device_spec) const
void send_audio_level_callback();
std::vector<DeviceSpec> get_active_devices() const;
void set_input_mapping_lock_held(const InputMapping &input_mapping);
+ void start_or_stop_alsa_capture(DeviceSpec device_spec);
unsigned num_capture_cards, num_ffmpeg_inputs;
std::atomic<double> compressor_attenuation_db{0.0/0.0};
};
std::unique_ptr<BusMetrics[]> bus_metrics; // One for each bus in <input_mapping>.
+
+ DelayAnalyzerInterface *delay_analyzer = nullptr;
+
+ // A set of devices (potentially empty) that should be kept open even
+ // if they're not used in any bus. This allows the delay analyzer to
+ // make sure a given ALSA device is opened to tap into its data, even if
+ // there is no bus using it. (Non-ALSA devices are allowed to be here,
+ // but won't do anything.)
+ std::set<DeviceSpec> extra_devices;
};
extern AudioMixer *global_audio_mixer;