Exemple #1
0
void NetworkTCPSource::myProcess( realvec& in, realvec& out )
{

  mrs_natural inSamples = getctrl("mrs_natural/inSamples")->to<mrs_natural>();
  mrs_natural inObservations = getctrl("mrs_natural/inObservations")->to<mrs_natural>();

  //checkFlow(in,out);

  if (!valid( s_sock)) {
    refresh();
  }

  int status = NetworkSocket::recvTCP( out );

  if ( status < 0 ) {
    throw SocketException ( "Cannot read from socket." );
  } else if ( status == 0 ) {
    throw SocketException ( "Client closed connection." );
  }

  if ( byteSwap ) {
    int i = 0;
    mrs_real* data = out.getData();

    for ( i = 0; i < (inObservations * inSamples); i++ ) {
      mrs_real tmp = swap( data[i] );
      data[i] = tmp;
    }
  }
}
Exemple #2
0
/**
 * Function: sendTCP
 * Description: Sends a vector to a TCP socket connection.  In this function,
 * 				we can send the controls as a seperate packet because with
 * 				TCP we know the next packet will be a vector.
 */
bool NetworkSocket::sendTCP ( realvec& in, mrs_natural inSamples,
                              mrs_natural inObservations, mrs_real israte )  {

  // for TCP we can send the controls seperately
  mrs_real ctrl_send[4];
  ctrl_send[0] = 1.0; // for endien check
  ctrl_send[1] = (mrs_real) inSamples;
  ctrl_send[2] = (mrs_real) inObservations;
  ctrl_send[3] = israte;


  if ( ::send(c_sock, ctrl_send, sizeof( mrs_real )*4, 0 ) <= 0 ) {
    MRSERR("sendTCP: Could not send TCP control data.");
    return false;
  }

  // vector data...
  if ( ::send ( s_sock, in.getData(), sizeof(mrs_real) *
                (inSamples*inObservations), 0 ) <= 0 ) {
    MRSERR("sendTCP: Could not send TCP vector data.");
    return false;
  }

  return true;
}
Exemple #3
0
/**
 * Function: sendUDP
 * Description: Sends a vector to a UDP socket connection. In this function,
 * 				the controls are included in the realvec as the first three
 * 				elements.
 */
bool
NetworkSocket::sendUDP(realvec& in, mrs_natural inSamples,
                       mrs_natural inObservations, mrs_real israte )
{

  // create buffer of proper size to include control data...
  mrs_real* buffer = new mrs_real[inSamples + 3];

  buffer[0] = ( mrs_real ) inSamples;
  buffer[1] = ( mrs_real ) inObservations;
  buffer[2] = israte;

  // now fill the buffer with samples...
  mrs_real* data = in.getData();
  int i;

  for ( i = 3; i < inSamples + 3; i++ ) {
    buffer[i] = *(data + i - 3);
  }

  if ( ::sendto ( s_sock, buffer, sizeof(mrs_real) *
                  (inSamples+3), 0, (struct sockaddr*)&m_addr, sizeof(m_addr) ) <= 0) {
    MRSERR("Could not send vector over UDP socket.");
    delete buffer;
    return false;
  }

  delete buffer;
  return true;
}
Exemple #4
0
void
MATLABengine::putVariable(realvec value, mrs_string MATLABname)
{
  //----------------------------------
  // send a realvec to a MATLAB matrix
  //----------------------------------
  mwSize dims[2]; //realvec is 2D
  dims[0] = value.getRows();
  dims[1] = value.getCols();

  //realvec are by default double precision matrices => mxDOUBLE_CLASS
  mxArray *mxMatrix = mxCreateNumericArray(2, dims, mxDOUBLE_CLASS, mxREAL);
  mrs_real *data = value.getData();
  memcpy((void *)mxGetPr(mxMatrix), (void *)(data), dims[0]*dims[1]*mxGetElementSize(mxMatrix));
  engPutVariable(engine_, MATLABname.c_str(), mxMatrix);

  mxDestroyArray(mxMatrix);
}
Exemple #5
0
/**
 * Function: recvUDP
 * Description: Receive a vector from a peer on a UDP socket connection.
 */
int NetworkSocket::recvUDP ( realvec& out )  {

  int status = 0;

  // assume a size 512 vector
  mrs_natural inSamples = getctrl("mrs_natural/inSamples")->to<mrs_natural>();
  mrs_natural inObservations = getctrl("mrs_natural/inObservations")->to<mrs_natural>();


  mrs_real* buffer = new mrs_real[(inSamples*inObservations)+3];
  int cliLen = sizeof(cliAddr);
#ifndef MARSYAS_CYGWIN
  status = ::recvfrom(s_sock, buffer, sizeof(mrs_real) *
                      ((inSamples*inObservations)+3), MSG_WAITALL,
                      (struct sockaddr *) &cliAddr, (socklen_t *)&cliLen);
#else
  status = ::recvfrom(s_sock, buffer, sizeof(mrs_real) *
                      ((inSamples*inObservations)+3), MSG_NOSIGNAL,
                      (struct sockaddr *) &cliAddr, (socklen_t *)&cliLen);

#endif

  if ( status <= 0 ) {
    MRSERR("Could not receive UDP data...");
    return 0;
  } else {
    updctrl("mrs_natural/inSamples", (mrs_natural) buffer[0]);
    updctrl("mrs_natural/inObservations",(mrs_natural) buffer[1]);
    updctrl("mrs_real/israte", buffer[2]);
  }

  // process the data to an output vector...
  out.create( inObservations, inSamples );
  mrs_real* data = out.getData();

  int i;
  for ( i = 0; i < 512; i++ ) {
    // *( data + i ) = buffer[i+3];
  }

  // delete [] buffer;
  return status;
}
Exemple #6
0
/**
 * Function: recvTCP
 * Description: Receive a vector from a peer on a TCP socket connection.
 */
int NetworkSocket::recvTCP ( realvec& out )
{

  // create our slice with updated controls
  mrs_natural inSamples = getctrl("mrs_natural/inSamples")->to<mrs_natural>();
  mrs_natural inObservations = getctrl("mrs_natural/inObservations")->to<mrs_natural>();

  out.create(inObservations, inSamples);
  mrs_real* data = out.getData();


#ifndef MARSYAS_CYGWIN
  return ::recv ( client_d, data, sizeof(mrs_real)*(inObservations*inSamples),
                  MSG_WAITALL );
#else
  return ::recv ( client_d, data, sizeof(mrs_real)*(inObservations*inSamples),
                  MSG_NOSIGNAL);
#endif

}
void
Yin::myProcess(realvec& in, realvec& out)
{

  // The tolerance for the yin algorithm
  const mrs_real tol = ctrl_tolerance_->to<mrs_real>();

  // get pointers to avoid excessive (long,long) lookups
  mrs_real *yin_buffer = yin_buffer_realvec_.getData();
  const mrs_natural yin_buffer_size = yin_buffer_realvec_.getSize();
  // ASSUME: only one channel
  mrs_real *input = in.getData();


  mrs_real pitch = -1.0;

//   cout << "yin.getSize()=" << yin.getSize() << endl;
//   cout << "tol=" << tol << endl;

  const mrs_real freq_max = ctrl_frequency_max_->to<mrs_real>();
  const mrs_real freq_min = ctrl_frequency_min_->to<mrs_real>();

  // yes, low_sample comes from the highest pitch
  mrs_natural low_sample = 4;
  if (freq_max > 0) {
    low_sample = israte_ / freq_max;
  }
  mrs_natural high_sample = yin_buffer_size;
  if (freq_min > 0) {
    high_sample = israte_ / freq_min;
  }

  // Calculate the pitch with the Yin method
  //mrs_natural c=0;
  mrs_real cmndf = 0.; // cumulative mean normalized difference function


  std::fill(yin_buffer, yin_buffer + yin_buffer_size, 0.0);
  yin_buffer[0] = 1.;

  //for (mrs_natural tau=1; tau < yin_size_; tau++)
  for (mrs_natural tau=1; tau < high_sample; tau++)
	{
      // d_t( tau )
	  for (mrs_natural j=0; j < yin_buffer_size;j++)
		{
		  const mrs_real delta = input[j] - input[j+tau];
		  yin_buffer[tau] += delta * delta;
		}
	  cmndf += yin_buffer[tau];
	  yin_buffer[tau] *= tau / cmndf;
      if (tau > low_sample) {
	    const mrs_natural period = tau-3;
	    //if(tau > 4 && (yin_buffer_(c,period) < tol) && 
	    // (yin_buffer_(c,period) < yin_buffer_(c,period+1)))
	    if((yin_buffer[period] < tol) && 
		   (yin_buffer[period] < yin_buffer[period+1])) {
		    pitch = vec_quadint_min(&yin_buffer_realvec_,period,1);
		    break;
          }
	    }
        }
  if (pitch < 0) {
	  pitch = vec_quadint_min(&yin_buffer_realvec_,
        vec_min_elem(&yin_buffer_realvec_),1);
  }
  
  if (pitch !=0)
	  out(0,0) = ctrl_osrate_/pitch; 
  else 
	  out(0,0) = 0.0;

}