/* * Copyright (C) 2014-2018 Paul Davis * Copyright (C) 2014-2018 Robin Gareus * * 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. */ #ifndef __libbackend_dummy_audiobackend_h__ #define __libbackend_dummy_audiobackend_h__ #include #include #include #include #include #include #include #include #include "pbd/natsort.h" #include "pbd/ringbuffer.h" #include "ardour/types.h" #include "ardour/audio_backend.h" #include "ardour/dsp_load_calculator.h" #include "ardour/port_engine_shared.h" namespace ARDOUR { class DummyAudioBackend; namespace DummyMidiData { typedef struct _MIDISequence { float beat_time; uint8_t size; uint8_t event[3]; } MIDISequence; }; class DummyMidiEvent { public: DummyMidiEvent (const pframes_t timestamp, const uint8_t* data, size_t size); DummyMidiEvent (const DummyMidiEvent& other); ~DummyMidiEvent (); size_t size () const { return _size; }; pframes_t timestamp () const { return _timestamp; }; const unsigned char* const_data () const { return _data; }; unsigned char* data () { return _data; }; bool operator< (const DummyMidiEvent &other) const { return timestamp () < other.timestamp (); }; private: size_t _size; pframes_t _timestamp; uint8_t *_data; }; typedef std::vector > DummyMidiBuffer; class DummyPort : public BackendPort { protected: DummyPort (DummyAudioBackend &b, const std::string&, PortFlags); public: virtual ~DummyPort (); void next_period () { _gen_cycle = false; } protected: /* random number generator */ void setup_random_number_generator (); inline float randf (); inline uint32_t randi (); uint32_t _rseed; /* engine time */ pframes_t pulse_position () const; // signal generator volatile bool _gen_cycle; Glib::Threads::Mutex generator_lock; private: AudioBackend& _engine; }; // class DummyPort class DummyAudioPort : public DummyPort { public: DummyAudioPort (DummyAudioBackend &b, const std::string&, PortFlags); ~DummyAudioPort (); DataType type () const { return DataType::AUDIO; }; Sample* buffer () { return _buffer; } const Sample* const_buffer () const { return _buffer; } void* get_buffer (pframes_t nframes); enum GeneratorType { Silence, DC05, Demolition, UniformWhiteNoise, GaussianWhiteNoise, PinkNoise, PonyNoise, SineWave, SineWaveOctaves, SquareWave, KronekerDelta, SineSweep, SineSweepSwell, SquareSweep, SquareSweepSwell, OneHz, LTC, Loopback, }; std::string setup_generator (GeneratorType const, float const, int, int); void fill_wavetable (const float* d, size_t n_samples) { assert(_wavetable != 0); memcpy(_wavetable, d, n_samples * sizeof(float)); } void midi_to_wavetable (DummyMidiBuffer const * const src, size_t n_samples); private: Sample _buffer[8192]; // signal generator ('fake' physical inputs) void generate (const pframes_t n_samples); GeneratorType _gen_type; // generator buffers // pink-noise filters float _b0, _b1, _b2, _b3, _b4, _b5, _b6; // generated sinf() samples Sample * _wavetable; uint32_t _gen_period; uint32_t _gen_offset; uint32_t _gen_perio2; uint32_t _gen_count2; // gaussian noise generator float grandf (); bool _pass; float _rn1; // LTC generator LTCEncoder* _ltc; PBD::RingBuffer* _ltcbuf; float _ltc_spd; float _ltc_rand; }; // class DummyAudioPort class DummyMidiPort : public DummyPort { public: DummyMidiPort (DummyAudioBackend &b, const std::string&, PortFlags); ~DummyMidiPort (); DataType type () const { return DataType::MIDI; }; void* get_buffer (pframes_t nframes); const DummyMidiBuffer * const_buffer () const { return &_buffer; } std::string setup_generator (int, float const); void set_loopback (DummyMidiBuffer const * const src); private: DummyMidiBuffer _buffer; DummyMidiBuffer _loopback; // midi event generator ('fake' physical inputs) void midi_generate (const pframes_t n_samples); float _midi_seq_spb; // samples per beat int64_t _midi_seq_time; uint32_t _midi_seq_pos; DummyMidiData::MIDISequence const * _midi_seq_dat; }; // class DummyMidiPort class DummyAudioBackend : public AudioBackend, public PortEngineSharedImpl { friend class DummyPort; public: DummyAudioBackend (AudioEngine& e, AudioBackendInfo& info); ~DummyAudioBackend (); bool is_running () const { return _running; } /* AUDIOBACKEND API */ std::string name () const; bool is_realtime () const; bool requires_driver_selection() const { return true; } std::string driver_name () const; std::vector enumerate_drivers () const; int set_driver (const std::string&); std::vector enumerate_devices () const; std::vector available_sample_rates (const std::string& device) const; std::vector available_buffer_sizes (const std::string& device) const; uint32_t available_input_channel_count (const std::string& device) const; uint32_t available_output_channel_count (const std::string& device) const; bool can_change_sample_rate_when_running () const; bool can_change_buffer_size_when_running () const; bool can_measure_systemic_latency () const { return true; } int set_device_name (const std::string&); int set_sample_rate (float); int set_buffer_size (uint32_t); int set_interleaved (bool yn); int set_input_channels (uint32_t); int set_output_channels (uint32_t); int set_systemic_input_latency (uint32_t); int set_systemic_output_latency (uint32_t); int set_systemic_midi_input_latency (std::string const, uint32_t) { return 0; } int set_systemic_midi_output_latency (std::string const, uint32_t) { return 0; } int reset_device () { return 0; }; /* Retrieving parameters */ std::string device_name () const; float sample_rate () const; uint32_t buffer_size () const; bool interleaved () const; uint32_t input_channels () const; uint32_t output_channels () const; uint32_t systemic_input_latency () const; uint32_t systemic_output_latency () const; uint32_t systemic_midi_input_latency (std::string const) const { return 0; } uint32_t systemic_midi_output_latency (std::string const) const { return 0; } /* External control app */ std::string control_app_name () const { return std::string (); } void launch_control_app () {} /* MIDI */ std::vector enumerate_midi_options () const; int set_midi_option (const std::string&); std::string midi_option () const; std::vector enumerate_midi_devices () const { return std::vector (); } int set_midi_device_enabled (std::string const, bool) { return 0; } bool midi_device_enabled (std::string const) const { return true; } bool can_set_systemic_midi_latencies () const { return false; } /* State Control */ protected: int _start (bool for_latency_measurement); public: int stop (); int freewheel (bool); float dsp_load () const; size_t raw_buffer_size (DataType t); /* Process time */ samplepos_t sample_time (); samplepos_t sample_time_at_cycle_start (); pframes_t samples_since_cycle_start (); int create_process_thread (boost::function func); int join_process_threads (); bool in_process_thread (); uint32_t process_thread_count (); void update_latencies (); /* PORTENGINE API */ void* private_handle () const; const std::string& my_name () const; /* PortEngine API - forwarded to PortEngineSharedImpl */ bool port_is_physical (PortEngine::PortHandle ph) const { return PortEngineSharedImpl::port_is_physical (ph); } void get_physical_outputs (DataType type, std::vector& results) { PortEngineSharedImpl::get_physical_outputs (type, results); } void get_physical_inputs (DataType type, std::vector& results) { PortEngineSharedImpl::get_physical_inputs (type, results); } ChanCount n_physical_outputs () const { return PortEngineSharedImpl::n_physical_outputs (); } ChanCount n_physical_inputs () const { return PortEngineSharedImpl::n_physical_inputs (); } uint32_t port_name_size () const { return PortEngineSharedImpl::port_name_size(); } int set_port_name (PortEngine::PortHandle ph, const std::string& name) { return PortEngineSharedImpl::set_port_name (ph, name); } std::string get_port_name (PortEngine::PortHandle ph) const { return PortEngineSharedImpl::get_port_name (ph); } PortFlags get_port_flags (PortEngine::PortHandle ph) const { return PortEngineSharedImpl::get_port_flags (ph); } PortEngine::PortPtr get_port_by_name (std::string const & name) const { return PortEngineSharedImpl::get_port_by_name (name); } int get_port_property (PortEngine::PortHandle ph, const std::string& key, std::string& value, std::string& type) const { return PortEngineSharedImpl::get_port_property (ph, key, value, type); } int set_port_property (PortEngine::PortHandle ph, const std::string& key, const std::string& value, const std::string& type) { return PortEngineSharedImpl::set_port_property (ph, key, value, type); } int get_ports (const std::string& port_name_pattern, DataType type, PortFlags flags, std::vector& results) const { return PortEngineSharedImpl::get_ports (port_name_pattern, type, flags, results); } DataType port_data_type (PortEngine::PortHandle ph) const { return PortEngineSharedImpl::port_data_type (ph); } PortEngine::PortPtr register_port (const std::string& shortname, ARDOUR::DataType type, ARDOUR::PortFlags flags) { return PortEngineSharedImpl::register_port (shortname, type, flags); } void unregister_port (PortHandle ph) { if (!_running) return; PortEngineSharedImpl::unregister_port (ph); } int connect (const std::string& src, const std::string& dst) { return PortEngineSharedImpl::connect (src, dst); } int disconnect (const std::string& src, const std::string& dst) { return PortEngineSharedImpl::disconnect (src, dst); } int connect (PortEngine::PortHandle ph, const std::string& other) { return PortEngineSharedImpl::connect (ph, other); } int disconnect (PortEngine::PortHandle ph, const std::string& other) { return PortEngineSharedImpl::disconnect (ph, other); } int disconnect_all (PortEngine::PortHandle ph) { return PortEngineSharedImpl::disconnect_all (ph); } bool connected (PortEngine::PortHandle ph, bool process_callback_safe) { return PortEngineSharedImpl::connected (ph, process_callback_safe); } bool connected_to (PortEngine::PortHandle ph, const std::string& other, bool process_callback_safe) { return PortEngineSharedImpl::connected_to (ph, other, process_callback_safe); } bool physically_connected (PortEngine::PortHandle ph, bool process_callback_safe) { return PortEngineSharedImpl::physically_connected (ph, process_callback_safe); } int get_connections (PortEngine::PortHandle ph, std::vector& results, bool process_callback_safe) { return PortEngineSharedImpl::get_connections (ph, results, process_callback_safe); } /* MIDI */ int midi_event_get (pframes_t& timestamp, size_t& size, uint8_t const** buf, void* port_buffer, uint32_t event_index); int midi_event_put (void* port_buffer, pframes_t timestamp, const uint8_t* buffer, size_t size); uint32_t get_midi_event_count (void* port_buffer); void midi_clear (void* port_buffer); /* Monitoring */ bool can_monitor_input () const; int request_input_monitoring (PortHandle, bool); int ensure_input_monitoring (PortHandle, bool); bool monitoring_input (PortHandle); /* Latency management */ void set_latency_range (PortHandle, bool for_playback, LatencyRange); LatencyRange get_latency_range (PortHandle, bool for_playback); /* Getting access to the data buffer for a port */ void* get_buffer (PortHandle, pframes_t); void* main_process_thread (); static size_t max_buffer_size() {return _max_buffer_size;} private: enum MidiPortMode { MidiNoEvents, MidiGenerator, MidiOneHz, MidiLoopback, MidiToAudio, }; struct DriverSpeed { std::string name; float speedup; DriverSpeed (const std::string& n, float s) : name (n), speedup (s) {} }; std::string _instance_name; static std::vector _midi_options; static std::vector _device_status; static std::vector _driver_speed; bool _running; bool _freewheel; bool _freewheeling; float _speedup; std::string _device; float _samplerate; size_t _samples_per_period; float _dsp_load; DSPLoadCalculator _dsp_load_calc; static size_t _max_buffer_size; uint32_t _n_inputs; uint32_t _n_outputs; uint32_t _n_midi_inputs; uint32_t _n_midi_outputs; MidiPortMode _midi_mode; uint32_t _systemic_input_latency; uint32_t _systemic_output_latency; samplecnt_t _processed_samples; pthread_t _main_thread; /* process threads */ static void* dummy_process_thread (void *); std::vector _threads; struct ThreadData { DummyAudioBackend* engine; boost::function f; size_t stacksize; ThreadData (DummyAudioBackend* e, boost::function fp, size_t stacksz) : engine (e) , f (fp) , stacksize (stacksz) {} }; /* port engine */ int register_system_ports (); struct PortConnectData { std::string a; std::string b; bool c; PortConnectData (const std::string& a, const std::string& b, bool c) : a (a) , b (b) , c (c) {} }; std::vector _port_connection_queue; pthread_mutex_t _port_callback_mutex; bool _port_change_flag; void port_connect_callback (const std::string& a, const std::string& b, bool conn) { pthread_mutex_lock (&_port_callback_mutex); _port_connection_queue.push_back(new PortConnectData(a, b, conn)); pthread_mutex_unlock (&_port_callback_mutex); } void port_connect_add_remove_callback () { pthread_mutex_lock (&_port_callback_mutex); _port_change_flag = true; pthread_mutex_unlock (&_port_callback_mutex); } BackendPort* port_factory (std::string const & name, ARDOUR::DataType type, ARDOUR::PortFlags); }; // class DummyAudioBackend } // namespace #endif /* __libbackend_dummy_audiobackend_h__ */