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duplex.cpp
167 lines (137 loc) · 4.8 KB
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duplex.cpp
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/******************************************/
/*
duplex.cpp
by Gary P. Scavone, 2006-2019.
This program opens a duplex stream and passes
input directly through to the output.
*/
/******************************************/
#include "RtAudio.h"
#include <iostream>
#include <cstdlib>
#include <cstring>
/*
typedef int8_t MY_TYPE;
#define FORMAT RTAUDIO_SINT8
*/
typedef int16_t MY_TYPE;
#define FORMAT RTAUDIO_SINT16
/*
typedef S24 MY_TYPE;
#define FORMAT RTAUDIO_SINT24
typedef int32_t MY_TYPE;
#define FORMAT RTAUDIO_SINT32
typedef float MY_TYPE;
#define FORMAT RTAUDIO_FLOAT32
typedef double MY_TYPE;
#define FORMAT RTAUDIO_FLOAT64
*/
void usage( void ) {
// Error function in case of incorrect command-line
// argument specifications
std::cout << "\nuseage: duplex N fs <iDevice> <oDevice> <iChannelOffset> <oChannelOffset>\n";
std::cout << " where N = number of channels,\n";
std::cout << " fs = the sample rate,\n";
std::cout << " iDevice = optional input device index to use (default = 0),\n";
std::cout << " oDevice = optional output device index to use (default = 0),\n";
std::cout << " iChannelOffset = an optional input channel offset (default = 0),\n";
std::cout << " and oChannelOffset = optional output channel offset (default = 0).\n\n";
exit( 0 );
}
unsigned int getDeviceIndex( std::vector<std::string> deviceNames, bool isInput = false )
{
unsigned int i;
std::string keyHit;
std::cout << '\n';
for ( i=0; i<deviceNames.size(); i++ )
std::cout << " Device #" << i << ": " << deviceNames[i] << '\n';
do {
if ( isInput )
std::cout << "\nChoose an input device #: ";
else
std::cout << "\nChoose an output device #: ";
std::cin >> i;
} while ( i >= deviceNames.size() );
std::getline( std::cin, keyHit ); // used to clear out stdin
return i;
}
double streamTimePrintIncrement = 1.0; // seconds
double streamTimePrintTime = 1.0; // seconds
int inout( void *outputBuffer, void *inputBuffer, unsigned int /*nBufferFrames*/,
double streamTime, RtAudioStreamStatus status, void *data )
{
// Since the number of input and output channels is equal, we can do
// a simple buffer copy operation here.
if ( status ) std::cout << "Stream over/underflow detected." << std::endl;
if ( streamTime >= streamTimePrintTime ) {
std::cout << "streamTime = " << streamTime << std::endl;
streamTimePrintTime += streamTimePrintIncrement;
}
unsigned int *bytes = (unsigned int *) data;
memcpy( outputBuffer, inputBuffer, *bytes );
return 0;
}
int main( int argc, char *argv[] )
{
unsigned int channels, fs, bufferBytes, oDevice = 0, iDevice = 0, iOffset = 0, oOffset = 0;
// Minimal command-line checking
if (argc < 3 || argc > 7 ) usage();
RtAudio adac;
std::vector<unsigned int> deviceIds = adac.getDeviceIds();
if ( deviceIds.size() < 1 ) {
std::cout << "\nNo audio devices found!\n";
exit( 1 );
}
channels = (unsigned int) atoi(argv[1]);
fs = (unsigned int) atoi(argv[2]);
if ( argc > 3 )
iDevice = (unsigned int) atoi(argv[3]);
if ( argc > 4 )
oDevice = (unsigned int) atoi(argv[4]);
if ( argc > 5 )
iOffset = (unsigned int) atoi(argv[5]);
if ( argc > 6 )
oOffset = (unsigned int) atoi(argv[6]);
// Let RtAudio print messages to stderr.
adac.showWarnings( true );
// Set the same number of channels for both input and output.
unsigned int bufferFrames = 512;
RtAudio::StreamParameters iParams, oParams;
iParams.nChannels = channels;
iParams.firstChannel = iOffset;
oParams.nChannels = channels;
oParams.firstChannel = oOffset;
if ( iDevice == 0 )
iParams.deviceId = adac.getDefaultInputDevice();
else {
if ( iDevice >= deviceIds.size() )
iDevice = getDeviceIndex( adac.getDeviceNames(), true );
iParams.deviceId = deviceIds[iDevice];
}
if ( oDevice == 0 )
oParams.deviceId = adac.getDefaultOutputDevice();
else {
if ( oDevice >= deviceIds.size() )
oDevice = getDeviceIndex( adac.getDeviceNames() );
oParams.deviceId = deviceIds[oDevice];
}
RtAudio::StreamOptions options;
//options.flags |= RTAUDIO_NONINTERLEAVED;
bufferBytes = bufferFrames * channels * sizeof( MY_TYPE );
if ( adac.openStream( &oParams, &iParams, FORMAT, fs, &bufferFrames, &inout, (void *)&bufferBytes, &options ) ) {
goto cleanup;
}
if ( adac.isStreamOpen() == false ) goto cleanup;
// Test RtAudio functionality for reporting latency.
std::cout << "\nStream latency = " << adac.getStreamLatency() << " frames" << std::endl;
if ( adac.startStream() ) goto cleanup;
char input;
std::cout << "\nRunning ... press <enter> to quit (buffer frames = " << bufferFrames << ").\n";
std::cin.get(input);
// Stop the stream.
if ( adac.isStreamRunning() )
adac.stopStream();
cleanup:
if ( adac.isStreamOpen() ) adac.closeStream();
return 0;
}