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Rack/plugins/community/repos/Autodafe/dep/stk/projects/examples/controlbee.cpp

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  1. // controlbee.cpp STK tutorial program

  2. 

  3. #include "BeeThree.h"

  4. #include "RtAudio.h"

  5. #include "Messager.h"

  6. #include "SKINImsg.h"

  7. #include <math.h>

  8. #include <algorithm>

  9. using std::min;

  10. 

  11. using namespace stk;

  12. 

  13. void usage(void) {

  14.   // Error function in case of incorrect command-line

  15.   // argument specifications.

  16.   std::cout << "\nuseage: controlbee file\n";

  17.   std::cout << "    where file = a SKINI scorefile.\n\n";

  18.   exit(0);

  19. }

  20. 

  21. // The TickData structure holds all the class instances and data that

  22. // are shared by the various processing functions.

  23. struct TickData {

  24.   Instrmnt *instrument;

  25.   Messager messager;

  26.   Skini::Message message;

  27.   int counter;

  28.   bool haveMessage;

  29.   bool done;

  30. 

  31.   // Default constructor.

  32.   TickData()

  33.     : instrument(0), counter(0), haveMessage(false), done( false ) {}

  34. };

  35. 

  36. #define DELTA_CONTROL_TICKS 64 // default sample frames between control input checks

  37. 

  38. // The processMessage() function encapsulates the handling of control

  39. // messages.  It can be easily relocated within a program structure

  40. // depending on the desired scheduling scheme.

  41. void processMessage( TickData* data )

  42. {

  43.   register StkFloat value1 = data->message.floatValues[0];

  44.   register StkFloat value2 = data->message.floatValues[1];

  45. 

  46.   switch( data->message.type ) {

  47. 

  48.   case __SK_Exit_:

  49.     data->done = true;

  50.     return;

  51. 

  52.   case __SK_NoteOn_:

  53.     if ( value2 == 0.0 ) // velocity is zero ... really a NoteOff

  54.       data->instrument->noteOff( 0.5 );

  55.     else { // a NoteOn

  56.       StkFloat frequency = 220.0 * pow( 2.0, (value1 - 57.0) / 12.0 ); 

  57.       data->instrument->noteOn( frequency, value2 * ONE_OVER_128 );

  58.     }

  59.     break;

  60. 

  61.   case __SK_NoteOff_:

  62.     data->instrument->noteOff( value2 * ONE_OVER_128 );

  63.     break;

  64. 

  65.   case __SK_ControlChange_:

  66.     data->instrument->controlChange( (int) value1, value2 );

  67.     break;

  68. 

  69.   case __SK_AfterTouch_:

  70.     data->instrument->controlChange( 128, value1 );

  71. 

  72.   } // end of switch

  73. 

  74.   data->haveMessage = false;

  75.   return;

  76. }

  77. 

  78. // This tick() function handles sample computation and scheduling of

  79. // control updates.  It will be called automatically when the system

  80. // needs a new buffer of audio samples.

  81. int tick( void *outputBuffer, void *inputBuffer, unsigned int nBufferFrames,

  82.          double streamTime, RtAudioStreamStatus status, void *dataPointer )

  83. {

  84.   TickData *data = (TickData *) dataPointer;

  85.   register StkFloat *samples = (StkFloat *) outputBuffer;

  86.   int counter, nTicks = (int) nBufferFrames;

  87. 

  88.   while ( nTicks > 0 && !data->done ) {

  89. 

  90.     if ( !data->haveMessage ) {

  91.       data->messager.popMessage( data->message );

  92.       if ( data->message.type > 0 ) {

  93.         data->counter = (long) (data->message.time * Stk::sampleRate());

  94.         data->haveMessage = true;

  95.       }

  96.       else

  97.         data->counter = DELTA_CONTROL_TICKS;

  98.     }

  99. 

  100.     counter = min( nTicks, data->counter );

  101.     data->counter -= counter;

  102. 

  103.     for ( int i=0; i<counter; i++ ) {

  104.       *samples++ = data->instrument->tick();

  105.       nTicks--;

  106.     }

  107.     if ( nTicks == 0 ) break;

  108. 

  109.     // Process control messages.

  110.     if ( data->haveMessage ) processMessage( data );

  111.   }

  112. 

  113.   return 0;

  114. }

  115. 

  116. int main( int argc, char *argv[] )

  117. {

  118.   if ( argc != 2 ) usage();

  119. 

  120.   // Set the global sample rate and rawwave path before creating class instances.

  121.   Stk::setSampleRate( 44100.0 );

  122.   Stk::setRawwavePath( "../../rawwaves/" );

  123. 

  124.   TickData data;

  125.   RtAudio dac;

  126. 

  127.   // Figure out how many bytes in an StkFloat and setup the RtAudio stream.

  128.   RtAudio::StreamParameters parameters;

  129.   parameters.deviceId = dac.getDefaultOutputDevice();

  130.   parameters.nChannels = 1;

  131.   RtAudioFormat format = ( sizeof(StkFloat) == 8 ) ? RTAUDIO_FLOAT64 : RTAUDIO_FLOAT32;

  132.   unsigned int bufferFrames = RT_BUFFER_SIZE;

  133.   try {

  134.     dac.openStream( &parameters, NULL, format, (unsigned int)Stk::sampleRate(), &bufferFrames, &tick, (void *)&data );

  135.   }

  136.   catch ( RtAudioError &error ) {

  137.     error.printMessage();

  138.     goto cleanup;

  139.   }

  140. 

  141.   try {

  142.     // Define and load the BeeThree instrument

  143.     data.instrument = new BeeThree();

  144.   }

  145.   catch ( StkError & ) {

  146.     goto cleanup;

  147.   }

  148. 

  149.   if ( data.messager.setScoreFile( argv[1] ) == false )

  150.     goto cleanup;

  151. 

  152.   try {

  153.     dac.startStream();

  154.   }

  155.   catch ( RtAudioError &error ) {

  156.     error.printMessage();

  157.     goto cleanup;

  158.   }

  159. 

  160.   // Block waiting until callback signals done.

  161.   while ( !data.done )

  162.     Stk::sleep( 100 );

  163.   

  164.   // Shut down the output stream.

  165.   try {

  166.     dac.closeStream();

  167.   }

  168.   catch ( RtAudioError &error ) {

  169.     error.printMessage();

  170.   }

  171. 

  172.  cleanup:

  173.   delete data.instrument;

  174. 

  175.   return 0;

  176. }