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/******************************************/
/*
twostreams.cpp
by Gary P. Scavone, 2001
Test executable using two streams with
callbacks.
*/
/******************************************/
#include "RtAudio.h"
#include <iostream.h>
/*
typedef signed long MY_TYPE;
#define FORMAT RtAudio::RTAUDIO_SINT24
#define SCALE 2147483647.0
typedef char MY_TYPE;
#define FORMAT RtAudio::RTAUDIO_SINT8
#define SCALE 127.0
typedef signed short MY_TYPE;
#define FORMAT RtAudio::RTAUDIO_SINT16
#define SCALE 32767.0
typedef signed long MY_TYPE;
#define FORMAT RtAudio::RTAUDIO_SINT32
#define SCALE 2147483647.0
typedef float MY_TYPE;
#define FORMAT RtAudio::RTAUDIO_FLOAT32
#define SCALE 1.0
*/
typedef double MY_TYPE;
#define FORMAT RtAudio::RTAUDIO_FLOAT64
#define SCALE 1.0
void usage(void) {
/* Error function in case of incorrect command-line
argument specifications
*/
cout << "\nuseage: call_twostreams N fs <device>\n";
cout << " where N = number of channels,\n";
cout << " fs = the sample rate,\n";
cout << " and device = the device to use (default = 0).\n\n";
exit(0);
}
int chans;
int in(char *buffer, int buffer_size, void *data)
{
extern int chans;
MY_TYPE *my_buffer = (MY_TYPE *) buffer;
MY_TYPE *my_data = (MY_TYPE *) data;
long buffer_bytes = buffer_size * chans * sizeof(MY_TYPE);
memcpy(my_data, my_buffer, buffer_bytes);
return 0;
}
int out(char *buffer, int buffer_size, void *data)
{
extern int chans;
MY_TYPE *my_buffer = (MY_TYPE *) buffer;
MY_TYPE *my_data = (MY_TYPE *) data;
long buffer_bytes = buffer_size * chans * sizeof(MY_TYPE);
memcpy(my_buffer, my_data, buffer_bytes);
return 0;
}
int main(int argc, char *argv[])
{
int buffer_size, stream1 = 0, stream2 = 0, fs, device = 0;
MY_TYPE *data = 0;
RtAudio *audio;
char input;
// minimal command-line checking
if (argc != 3 && argc != 4 ) usage();
chans = (int) atoi(argv[1]);
fs = (int) atoi(argv[2]);
if ( argc == 4 )
device = (int) atoi(argv[3]);
// Open the realtime output device
buffer_size = 512;
try {
audio = new RtAudio();
}
catch (RtError &) {
exit(EXIT_FAILURE);
}
try {
stream1 = audio->openStream(0, 0, device, chans,
FORMAT, fs, &buffer_size, 8);
stream2 = audio->openStream(device, chans, 0, 0,
FORMAT, fs, &buffer_size, 8);
}
catch (RtError &) {
goto cleanup;
}
data = (MY_TYPE *) calloc(chans*buffer_size, sizeof(MY_TYPE));
try {
audio->setStreamCallback(stream1, &in, (void *)data);
audio->setStreamCallback(stream2, &out, (void *)data);
audio->startStream(stream1);
audio->startStream(stream2);
}
catch (RtError &) {
goto cleanup;
}
cout << "\nRunning two streams (quasi-duplex) ... press <enter> to quit.\n";
cin.get(input);
cout << "\nStopping both streams.\n";
try {
audio->stopStream(stream1);
audio->stopStream(stream2);
}
catch (RtError &) {
goto cleanup;
}
cout << "\nPress <enter> to restart streams:\n";
cin.get(input);
try {
audio->startStream(stream1);
audio->startStream(stream2);
}
catch (RtError &) {
goto cleanup;
}
cout << "\nRunning two streams (quasi-duplex) ... press <enter> to quit.\n";
cin.get(input);
try {
audio->stopStream(stream1);
audio->stopStream(stream2);
}
catch (RtError &) {
}
cleanup:
audio->closeStream(stream1);
audio->closeStream(stream2);
delete audio;
if (data) free(data);
return 0;
}
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