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io.h

/*
    Copyright (C) 2000 Paul Davis 

    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., 675 Mass Ave, Cambridge, MA 02139, USA.

*/

#ifndef __ardour_io_h__
#define __ardour_io_h__

#include <string>
#include <vector>
#include <cmath>
#include <sigc++/signal.h>
#include <jack/jack.h>

#include <glibmm/thread.h>

#include <pbd/fastlog.h>
#include <pbd/undo.h>
#include <pbd/statefuldestructible.h> 
#include <pbd/controllable.h>

#include <ardour/ardour.h>
#include <ardour/utils.h>
#include <ardour/curve.h>
#include <ardour/types.h>
#include <ardour/data_type.h>

using std::string;
using std::vector;

class XMLNode;

namespace ARDOUR {

class Session;
class AudioEngine;
class Port;
class Connection;
class Panner;

/** A collection of input and output ports with connections.
 *
 * An IO can contain ports of varying types, making routes/inserts/etc with
 * varied combinations of types (eg MIDI and audio) possible.
 */
00060 class IO : public PBD::StatefulDestructible
{

  public:
      static const string state_node_name;

      IO (Session&, string name, 
          int input_min = -1, int input_max = -1, 
          int output_min = -1, int output_max = -1,
          DataType default_type = DataType::AUDIO);

      IO (Session&, const XMLNode&, DataType default_type = DataType::AUDIO);

      virtual ~IO();

      bool active() const { return _active; }
      void set_active (bool yn);

      int input_minimum() const { return _input_minimum; }
      int input_maximum() const { return _input_maximum; }
      int output_minimum() const { return _output_minimum; }
      int output_maximum() const { return _output_maximum; }

      void set_input_minimum (int n);
      void set_input_maximum (int n);
      void set_output_minimum (int n);
      void set_output_maximum (int n);

      DataType default_type() const { return _default_type; }

      const string& name() const { return _name; }
      virtual int set_name (string str, void *src);
      
      virtual void silence  (nframes_t, nframes_t offset);

      // These should be moved in to a separate object that manipulates an IO
      
      void pan (vector<Sample*>& bufs, uint32_t nbufs, nframes_t nframes, nframes_t offset, gain_t gain_coeff);
      void pan_automated (vector<Sample*>& bufs, uint32_t nbufs, nframes_t start_frame, nframes_t end_frame, 
                      nframes_t nframes, nframes_t offset);
      void collect_input  (vector<Sample*>&, uint32_t nbufs, nframes_t nframes, nframes_t offset);
      void deliver_output (vector<Sample*>&, uint32_t nbufs, nframes_t nframes, nframes_t offset);
      void deliver_output_no_pan (vector<Sample*>&, uint32_t nbufs, nframes_t nframes, nframes_t offset);
      void just_meter_input (nframes_t start_frame, nframes_t end_frame, 
                         nframes_t nframes, nframes_t offset);

      virtual uint32_t n_process_buffers () { return 0; }

      virtual void   set_gain (gain_t g, void *src);
      void           inc_gain (gain_t delta, void *src);
      gain_t         gain () const { return _desired_gain; }
      virtual gain_t effective_gain () const;

      Panner& panner() { return *_panner; }
      const Panner& panner() const { return *_panner; }
      
      int ensure_io (uint32_t, uint32_t, bool clear, void *src);

      int use_input_connection (Connection&, void *src);
      int use_output_connection (Connection&, void *src);

      Connection *input_connection() const { return _input_connection; }
      Connection *output_connection() const { return _output_connection; }

      int add_input_port (string source, void *src, DataType type = DataType::NIL);
      int add_output_port (string destination, void *src, DataType type = DataType::NIL);

      int remove_input_port (Port *, void *src);
      int remove_output_port (Port *, void *src);

      int set_input (Port *, void *src);

      int connect_input (Port *our_port, string other_port, void *src);
      int connect_output (Port *our_port, string other_port, void *src);

      int disconnect_input (Port *our_port, string other_port, void *src);
      int disconnect_output (Port *our_port, string other_port, void *src);

      int disconnect_inputs (void *src);
      int disconnect_outputs (void *src);

      nframes_t output_latency() const;
      nframes_t input_latency() const;
      void           set_port_latency (nframes_t);

      Port *output (uint32_t n) const {
            if (n < _noutputs) {
                  return _outputs[n];
            } else {
                  return 0;
            }
      }

      Port *input (uint32_t n) const {
            if (n < _ninputs) {
                  return _inputs[n];
            } else {
                  return 0;
            }
      }

      uint32_t n_inputs () const { return _ninputs; }
      uint32_t n_outputs () const { return _noutputs; }

      sigc::signal<void>                active_changed;

      sigc::signal<void,IOChange,void*> input_changed;
      sigc::signal<void,IOChange,void*> output_changed;

      sigc::signal<void,void*> gain_changed;
      sigc::signal<void,void*> name_changed;

      virtual XMLNode& state (bool full);
      XMLNode& get_state (void);
      int set_state (const XMLNode&);

      static int  disable_connecting (void);
      static int  enable_connecting (void);
      static int  disable_ports (void);
      static int  enable_ports (void);
      static int  disable_panners (void);
      static int  reset_panners (void);
      
      static sigc::signal<int> PortsLegal;
      static sigc::signal<int> PannersLegal;
      static sigc::signal<int> ConnectingLegal;
      static sigc::signal<void,uint32_t> MoreOutputs;
      static sigc::signal<int> PortsCreated;

      PBD::Controllable& gain_control() {
            return _gain_control;
      }

      const PBD::Controllable& gain_control() const {
            return _gain_control;
      }
      
      /* Peak metering */

      float peak_input_power (uint32_t n) { 
            if (n < std::max (_ninputs, _noutputs)) {
                  return _visible_peak_power[n];
            } else {
                  return minus_infinity();
            }
      }

      float max_peak_power (uint32_t n) {
            if (n < std::max (_ninputs, _noutputs)) {
                  return _max_peak_power[n];
            } else {
                  return minus_infinity();
            }
      }

      void reset_max_peak_meters ();

      
      static void update_meters();

  private: 

      static sigc::signal<void>   Meter;
      static Glib::StaticMutex    m_meter_signal_lock;
      sigc::connection            m_meter_connection;

  public:

         bool                     _active;

       /* automation */
       
       static void set_automation_interval (jack_nframes_t frames) {
             _automation_interval = frames;
       }
       
       static jack_nframes_t automation_interval() { 
             return _automation_interval;
       }
       
       void clear_automation ();
       
       bool gain_automation_recording() const { 
             return (_gain_automation_curve.automation_state() & (Write|Touch));
       }
       
       bool gain_automation_playback() const {
             return (_gain_automation_curve.automation_state() & Play) ||
                   ((_gain_automation_curve.automation_state() & Touch) && 
                    !_gain_automation_curve.touching());
       }

       virtual void set_gain_automation_state (AutoState);
      AutoState gain_automation_state() const { return _gain_automation_curve.automation_state(); }
      sigc::signal<void> gain_automation_state_changed;

      virtual void set_gain_automation_style (AutoStyle);
      AutoStyle gain_automation_style () const { return _gain_automation_curve.automation_style(); }
      sigc::signal<void> gain_automation_style_changed;

      virtual void transport_stopped (nframes_t now);
      void automation_snapshot (nframes_t now);

      ARDOUR::Curve& gain_automation_curve () { return _gain_automation_curve; }

      void start_gain_touch ();
      void end_gain_touch ();

      void start_pan_touch (uint32_t which);
      void end_pan_touch (uint32_t which);

      void defer_pan_reset ();
      void allow_pan_reset ();

      /* the session calls this for master outs before
         anyone else. controls outs too, at some point.
      */

      XMLNode *pending_state_node;
      int ports_became_legal ();

  private:
      mutable Glib::Mutex io_lock;

  protected:
      Session&            _session;
      Panner*             _panner;
      gain_t              _gain;
      gain_t              _effective_gain;
      gain_t              _desired_gain;
      Glib::Mutex         declick_lock;
      vector<Port*>       _outputs;
      vector<Port*>       _inputs;
      vector<float>       _peak_power;
      vector<float>       _visible_peak_power;
      vector<float>       _max_peak_power;
      string              _name;
      Connection*         _input_connection;
      Connection*         _output_connection;
      bool                 no_panner_reset;
      XMLNode*             deferred_state;
      DataType            _default_type;
      bool                _ignore_gain_on_deliver;
      

      virtual void set_deferred_state() {}

      void reset_peak_meters();
      void reset_panner ();

      virtual uint32_t pans_required() const { return _ninputs; }

      static void apply_declick (vector<Sample*>&, uint32_t nbufs, nframes_t nframes, 
                           gain_t initial, gain_t target, bool invert_polarity);

      struct GainControllable : public PBD::Controllable {
          GainControllable (std::string name, IO& i) : Controllable (name), io (i) {}
       
          void set_value (float val);
          float get_value (void) const;
   
          IO& io;
      };

      GainControllable _gain_control;

      nframes_t last_automation_snapshot;
      static nframes_t _automation_interval;

      AutoState      _gain_automation_state;
      AutoStyle      _gain_automation_style;

      bool     apply_gain_automation;
      Curve    _gain_automation_curve;
      
      Glib::Mutex automation_lock;

      virtual int set_automation_state (const XMLNode&);
      virtual XMLNode& get_automation_state ();
      virtual int load_automation (std::string path);

      /* AudioTrack::deprecated_use_diskstream_connections() needs these */

      int set_inputs (const string& str);
      int set_outputs (const string& str);

      static bool connecting_legal;
      static bool ports_legal;

  private:

      uint32_t _ninputs;
      uint32_t _noutputs;

      /* are these the best variable names ever, or what? */

      sigc::connection input_connection_configuration_connection;
      sigc::connection output_connection_configuration_connection;
      sigc::connection input_connection_connection_connection;
      sigc::connection output_connection_connection_connection;

      static bool panners_legal;
      
      int connecting_became_legal ();
      int panners_became_legal ();
      sigc::connection connection_legal_c;
      sigc::connection port_legal_c;
      sigc::connection panner_legal_c;

      int _input_minimum;
      int _input_maximum;
      int _output_minimum;
      int _output_maximum;


      static int parse_io_string (const string&, vector<string>& chns);

      static int parse_gain_string (const string&, vector<string>& chns);
      
      int set_sources (vector<string>&, void *src, bool add);
      int set_destinations (vector<string>&, void *src, bool add);

      int ensure_inputs (uint32_t, bool clear, bool lockit, void *src);
      int ensure_outputs (uint32_t, bool clear, bool lockit, void *src);

      void drop_input_connection ();
      void drop_output_connection ();

      void input_connection_configuration_changed ();
      void input_connection_connection_changed (int);
      void output_connection_configuration_changed ();
      void output_connection_connection_changed (int);

      int create_ports (const XMLNode&);
      int make_connections (const XMLNode&);

      void setup_peak_meters ();
      void meter ();

      bool ensure_inputs_locked (uint32_t, bool clear, void *src);
      bool ensure_outputs_locked (uint32_t, bool clear, void *src);

      std::string build_legal_port_name (bool for_input);
      int32_t find_input_port_hole (const char* base);
      int32_t find_output_port_hole (const char* base);
};

} // namespace ARDOUR

#endif /*__ardour_io_h__ */

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