2014-09-15 14:33:30 +00:00
# ifdef RTAUDIO_ENABLED
/************************************************************************/
/*! \class RtAudio
\ brief Realtime audio i / o C + + classes .
RtAudio provides a common API ( Application Programming Interface )
for realtime audio input / output across Linux ( native ALSA , Jack ,
and OSS ) , Macintosh OS X ( CoreAudio and Jack ) , and Windows
( DirectSound , ASIO and WASAPI ) operating systems .
RtAudio WWW site : http : //www.music.mcgill.ca/~gary/rtaudio/
RtAudio : realtime audio i / o C + + classes
Copyright ( c ) 2001 - 2014 Gary P . Scavone
Permission is hereby granted , free of charge , to any person
obtaining a copy of this software and associated documentation files
( the " Software " ) , to deal in the Software without restriction ,
including without limitation the rights to use , copy , modify , merge ,
publish , distribute , sublicense , and / or sell copies of the Software ,
and to permit persons to whom the Software is furnished to do so ,
subject to the following conditions :
The above copyright notice and this permission notice shall be
included in all copies or substantial portions of the Software .
Any person wishing to distribute modifications to the Software is
asked to send the modifications to the original developer so that
they can be incorporated into the canonical version . This is ,
however , not a binding provision of this license .
THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND ,
EXPRESS OR IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
MERCHANTABILITY , FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT .
IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR
ANY CLAIM , DAMAGES OR OTHER LIABILITY , WHETHER IN AN ACTION OF
CONTRACT , TORT OR OTHERWISE , ARISING FROM , OUT OF OR IN CONNECTION
WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE .
*/
/************************************************************************/
// RtAudio: Version 4.1.1
# include "RtAudio.h"
# include <iostream>
# include <cstdlib>
# include <cstring>
# include <climits>
// Static variable definitions.
const unsigned int RtApi : : MAX_SAMPLE_RATES = 14 ;
const unsigned int RtApi : : SAMPLE_RATES [ ] = {
4000 , 5512 , 8000 , 9600 , 11025 , 16000 , 22050 ,
32000 , 44100 , 48000 , 88200 , 96000 , 176400 , 192000
} ;
# if defined(__WINDOWS_DS__) || defined(__WINDOWS_ASIO__) || defined(__WINDOWS_WASAPI__)
# ifdef WINRT_ENABLED
# define MUTEX_INITIALIZE(A) InitializeCriticalSectionEx(A, 0, 0)
# else
# define MUTEX_INITIALIZE(A) InitializeCriticalSection(A)
# endif
# define MUTEX_DESTROY(A) DeleteCriticalSection(A)
# define MUTEX_LOCK(A) EnterCriticalSection(A)
# define MUTEX_UNLOCK(A) LeaveCriticalSection(A)
# elif defined(__LINUX_ALSA__) || defined(__LINUX_PULSE__) || defined(__UNIX_JACK__) || defined(__LINUX_OSS__) || defined(__MACOSX_CORE__)
// pthread API
# define MUTEX_INITIALIZE(A) pthread_mutex_init(A, NULL)
# define MUTEX_DESTROY(A) pthread_mutex_destroy(A)
# define MUTEX_LOCK(A) pthread_mutex_lock(A)
# define MUTEX_UNLOCK(A) pthread_mutex_unlock(A)
# else
# define MUTEX_INITIALIZE(A) abs(*A) // dummy definitions
# define MUTEX_DESTROY(A) abs(*A) // dummy definitions
# endif
// *************************************************** //
//
// RtAudio definitions.
//
// *************************************************** //
std : : string RtAudio : : getVersion ( void ) throw ( )
{
return RTAUDIO_VERSION ;
}
void RtAudio : : getCompiledApi ( std : : vector < RtAudio : : Api > & apis ) throw ( )
{
apis . clear ( ) ;
// The order here will control the order of RtAudio's API search in
// the constructor.
# if defined(__UNIX_JACK__)
apis . push_back ( UNIX_JACK ) ;
# endif
# if defined(__LINUX_ALSA__)
apis . push_back ( LINUX_ALSA ) ;
# endif
# if defined(__LINUX_PULSE__)
apis . push_back ( LINUX_PULSE ) ;
# endif
# if defined(__LINUX_OSS__)
apis . push_back ( LINUX_OSS ) ;
# endif
# if defined(__WINDOWS_ASIO__)
apis . push_back ( WINDOWS_ASIO ) ;
# endif
# if defined(__WINDOWS_WASAPI__)
apis . push_back ( WINDOWS_WASAPI ) ;
# endif
# if defined(__WINDOWS_DS__)
apis . push_back ( WINDOWS_DS ) ;
# endif
# if defined(__MACOSX_CORE__)
apis . push_back ( MACOSX_CORE ) ;
# endif
# if defined(__RTAUDIO_DUMMY__)
apis . push_back ( RTAUDIO_DUMMY ) ;
# endif
}
void RtAudio : : openRtApi ( RtAudio : : Api api )
{
if ( rtapi_ )
delete rtapi_ ;
rtapi_ = 0 ;
# if defined(__UNIX_JACK__)
if ( api = = UNIX_JACK )
rtapi_ = new RtApiJack ( ) ;
# endif
# if defined(__LINUX_ALSA__)
if ( api = = LINUX_ALSA )
rtapi_ = new RtApiAlsa ( ) ;
# endif
# if defined(__LINUX_PULSE__)
if ( api = = LINUX_PULSE )
rtapi_ = new RtApiPulse ( ) ;
# endif
# if defined(__LINUX_OSS__)
if ( api = = LINUX_OSS )
rtapi_ = new RtApiOss ( ) ;
# endif
# if defined(__WINDOWS_ASIO__)
if ( api = = WINDOWS_ASIO )
rtapi_ = new RtApiAsio ( ) ;
# endif
# if defined(__WINDOWS_WASAPI__)
if ( api = = WINDOWS_WASAPI )
rtapi_ = new RtApiWasapi ( ) ;
# endif
# if defined(__WINDOWS_DS__)
if ( api = = WINDOWS_DS )
rtapi_ = new RtApiDs ( ) ;
# endif
# if defined(__MACOSX_CORE__)
if ( api = = MACOSX_CORE )
rtapi_ = new RtApiCore ( ) ;
# endif
# if defined(__RTAUDIO_DUMMY__)
if ( api = = RTAUDIO_DUMMY )
rtapi_ = new RtApiDummy ( ) ;
# endif
}
RtAudio : : RtAudio ( RtAudio : : Api api )
{
rtapi_ = 0 ;
if ( api ! = UNSPECIFIED ) {
// Attempt to open the specified API.
openRtApi ( api ) ;
if ( rtapi_ ) return ;
// No compiled support for specified API value. Issue a debug
// warning and continue as if no API was specified.
std : : cerr < < " \n RtAudio: no compiled support for specified API argument! \n " < < std : : endl ;
}
// Iterate through the compiled APIs and return as soon as we find
// one with at least one device or we reach the end of the list.
std : : vector < RtAudio : : Api > apis ;
getCompiledApi ( apis ) ;
for ( unsigned int i = 0 ; i < apis . size ( ) ; i + + ) {
openRtApi ( apis [ i ] ) ;
if ( rtapi_ - > getDeviceCount ( ) ) break ;
}
if ( rtapi_ ) return ;
// It should not be possible to get here because the preprocessor
// definition __RTAUDIO_DUMMY__ is automatically defined if no
// API-specific definitions are passed to the compiler. But just in
// case something weird happens, we'll thow an error.
std : : string errorText = " \n RtAudio: no compiled API support found ... critical error!! \n \n " ;
throw ( RtAudioError ( errorText , RtAudioError : : UNSPECIFIED ) ) ;
}
RtAudio : : ~ RtAudio ( ) throw ( )
{
if ( rtapi_ )
delete rtapi_ ;
}
void RtAudio : : openStream ( RtAudio : : StreamParameters * outputParameters ,
RtAudio : : StreamParameters * inputParameters ,
RtAudioFormat format , unsigned int sampleRate ,
unsigned int * bufferFrames ,
RtAudioCallback callback , void * userData ,
RtAudio : : StreamOptions * options ,
RtAudioErrorCallback errorCallback )
{
return rtapi_ - > openStream ( outputParameters , inputParameters , format ,
sampleRate , bufferFrames , callback ,
userData , options , errorCallback ) ;
}
// *************************************************** //
//
// Public RtApi definitions (see end of file for
// private or protected utility functions).
//
// *************************************************** //
RtApi : : RtApi ( )
{
stream_ . state = STREAM_CLOSED ;
stream_ . mode = UNINITIALIZED ;
stream_ . apiHandle = 0 ;
stream_ . userBuffer [ 0 ] = 0 ;
stream_ . userBuffer [ 1 ] = 0 ;
MUTEX_INITIALIZE ( & stream_ . mutex ) ;
showWarnings_ = true ;
firstErrorOccurred_ = false ;
}
RtApi : : ~ RtApi ( )
{
MUTEX_DESTROY ( & stream_ . mutex ) ;
}
void RtApi : : openStream ( RtAudio : : StreamParameters * oParams ,
RtAudio : : StreamParameters * iParams ,
RtAudioFormat format , unsigned int sampleRate ,
unsigned int * bufferFrames ,
RtAudioCallback callback , void * userData ,
RtAudio : : StreamOptions * options ,
RtAudioErrorCallback errorCallback )
{
if ( stream_ . state ! = STREAM_CLOSED ) {
errorText_ = " RtApi::openStream: a stream is already open! " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
// Clear stream information potentially left from a previously open stream.
clearStreamInfo ( ) ;
if ( oParams & & oParams - > nChannels < 1 ) {
errorText_ = " RtApi::openStream: a non-NULL output StreamParameters structure cannot have an nChannels value less than one. " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
if ( iParams & & iParams - > nChannels < 1 ) {
errorText_ = " RtApi::openStream: a non-NULL input StreamParameters structure cannot have an nChannels value less than one. " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
if ( oParams = = NULL & & iParams = = NULL ) {
errorText_ = " RtApi::openStream: input and output StreamParameters structures are both NULL! " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
if ( formatBytes ( format ) = = 0 ) {
errorText_ = " RtApi::openStream: 'format' parameter value is undefined. " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
unsigned int nDevices = getDeviceCount ( ) ;
unsigned int oChannels = 0 ;
if ( oParams ) {
oChannels = oParams - > nChannels ;
if ( oParams - > deviceId > = nDevices ) {
errorText_ = " RtApi::openStream: output device parameter value is invalid. " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
}
unsigned int iChannels = 0 ;
if ( iParams ) {
iChannels = iParams - > nChannels ;
if ( iParams - > deviceId > = nDevices ) {
errorText_ = " RtApi::openStream: input device parameter value is invalid. " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
}
bool result ;
if ( oChannels > 0 ) {
result = probeDeviceOpen ( oParams - > deviceId , OUTPUT , oChannels , oParams - > firstChannel ,
sampleRate , format , bufferFrames , options ) ;
if ( result = = false ) {
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
}
if ( iChannels > 0 ) {
result = probeDeviceOpen ( iParams - > deviceId , INPUT , iChannels , iParams - > firstChannel ,
sampleRate , format , bufferFrames , options ) ;
if ( result = = false ) {
if ( oChannels > 0 ) closeStream ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
}
stream_ . callbackInfo . callback = ( void * ) callback ;
stream_ . callbackInfo . userData = userData ;
stream_ . callbackInfo . errorCallback = ( void * ) errorCallback ;
if ( options ) options - > numberOfBuffers = stream_ . nBuffers ;
stream_ . state = STREAM_STOPPED ;
}
unsigned int RtApi : : getDefaultInputDevice ( void )
{
// Should be implemented in subclasses if possible.
return 0 ;
}
unsigned int RtApi : : getDefaultOutputDevice ( void )
{
// Should be implemented in subclasses if possible.
return 0 ;
}
void RtApi : : closeStream ( void )
{
// MUST be implemented in subclasses!
return ;
}
bool RtApi : : probeDeviceOpen ( unsigned int /*device*/ , StreamMode /*mode*/ , unsigned int /*channels*/ ,
unsigned int /*firstChannel*/ , unsigned int /*sampleRate*/ ,
RtAudioFormat /*format*/ , unsigned int * /*bufferSize*/ ,
RtAudio : : StreamOptions * /*options*/ )
{
// MUST be implemented in subclasses!
return FAILURE ;
}
void RtApi : : tickStreamTime ( void )
{
// Subclasses that do not provide their own implementation of
// getStreamTime should call this function once per buffer I/O to
// provide basic stream time support.
stream_ . streamTime + = ( stream_ . bufferSize * 1.0 / stream_ . sampleRate ) ;
# if defined( HAVE_GETTIMEOFDAY )
gettimeofday ( & stream_ . lastTickTimestamp , NULL ) ;
# endif
}
long RtApi : : getStreamLatency ( void )
{
verifyStream ( ) ;
long totalLatency = 0 ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX )
totalLatency = stream_ . latency [ 0 ] ;
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX )
totalLatency + = stream_ . latency [ 1 ] ;
return totalLatency ;
}
double RtApi : : getStreamTime ( void )
{
verifyStream ( ) ;
# if defined( HAVE_GETTIMEOFDAY )
// Return a very accurate estimate of the stream time by
// adding in the elapsed time since the last tick.
struct timeval then ;
struct timeval now ;
if ( stream_ . state ! = STREAM_RUNNING | | stream_ . streamTime = = 0.0 )
return stream_ . streamTime ;
gettimeofday ( & now , NULL ) ;
then = stream_ . lastTickTimestamp ;
return stream_ . streamTime +
( ( now . tv_sec + 0.000001 * now . tv_usec ) -
( then . tv_sec + 0.000001 * then . tv_usec ) ) ;
# else
return stream_ . streamTime ;
# endif
}
void RtApi : : setStreamTime ( double time )
{
verifyStream ( ) ;
if ( time > = 0.0 )
stream_ . streamTime = time ;
}
unsigned int RtApi : : getStreamSampleRate ( void )
{
verifyStream ( ) ;
return stream_ . sampleRate ;
}
// *************************************************** //
//
// OS/API-specific methods.
//
// *************************************************** //
# if defined(__MACOSX_CORE__)
// The OS X CoreAudio API is designed to use a separate callback
// procedure for each of its audio devices. A single RtAudio duplex
// stream using two different devices is supported here, though it
// cannot be guaranteed to always behave correctly because we cannot
// synchronize these two callbacks.
//
// A property listener is installed for over/underrun information.
// However, no functionality is currently provided to allow property
// listeners to trigger user handlers because it is unclear what could
// be done if a critical stream parameter (buffer size, sample rate,
// device disconnect) notification arrived. The listeners entail
// quite a bit of extra code and most likely, a user program wouldn't
// be prepared for the result anyway. However, we do provide a flag
// to the client callback function to inform of an over/underrun.
// A structure to hold various information related to the CoreAudio API
// implementation.
struct CoreHandle {
AudioDeviceID id [ 2 ] ; // device ids
# if defined( MAC_OS_X_VERSION_10_5 ) && ( MAC_OS_X_VERSION_MIN_REQUIRED >= MAC_OS_X_VERSION_10_5 )
AudioDeviceIOProcID procId [ 2 ] ;
# endif
UInt32 iStream [ 2 ] ; // device stream index (or first if using multiple)
UInt32 nStreams [ 2 ] ; // number of streams to use
bool xrun [ 2 ] ;
char * deviceBuffer ;
pthread_cond_t condition ;
int drainCounter ; // Tracks callback counts when draining
bool internalDrain ; // Indicates if stop is initiated from callback or not.
CoreHandle ( )
: deviceBuffer ( 0 ) , drainCounter ( 0 ) , internalDrain ( false ) { nStreams [ 0 ] = 1 ; nStreams [ 1 ] = 1 ; id [ 0 ] = 0 ; id [ 1 ] = 0 ; xrun [ 0 ] = false ; xrun [ 1 ] = false ; }
} ;
RtApiCore : : RtApiCore ( )
{
# if defined( AVAILABLE_MAC_OS_X_VERSION_10_6_AND_LATER )
// This is a largely undocumented but absolutely necessary
// requirement starting with OS-X 10.6. If not called, queries and
// updates to various audio device properties are not handled
// correctly.
CFRunLoopRef theRunLoop = NULL ;
AudioObjectPropertyAddress property = { kAudioHardwarePropertyRunLoop ,
kAudioObjectPropertyScopeGlobal ,
kAudioObjectPropertyElementMaster } ;
OSStatus result = AudioObjectSetPropertyData ( kAudioObjectSystemObject , & property , 0 , NULL , sizeof ( CFRunLoopRef ) , & theRunLoop ) ;
if ( result ! = noErr ) {
errorText_ = " RtApiCore::RtApiCore: error setting run loop property! " ;
error ( RtAudioError : : WARNING ) ;
}
# endif
}
RtApiCore : : ~ RtApiCore ( )
{
// The subclass destructor gets called before the base class
// destructor, so close an existing stream before deallocating
// apiDeviceId memory.
if ( stream_ . state ! = STREAM_CLOSED ) closeStream ( ) ;
}
unsigned int RtApiCore : : getDeviceCount ( void )
{
// Find out how many audio devices there are, if any.
UInt32 dataSize ;
AudioObjectPropertyAddress propertyAddress = { kAudioHardwarePropertyDevices , kAudioObjectPropertyScopeGlobal , kAudioObjectPropertyElementMaster } ;
OSStatus result = AudioObjectGetPropertyDataSize ( kAudioObjectSystemObject , & propertyAddress , 0 , NULL , & dataSize ) ;
if ( result ! = noErr ) {
errorText_ = " RtApiCore::getDeviceCount: OS-X error getting device info! " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
return dataSize / sizeof ( AudioDeviceID ) ;
}
unsigned int RtApiCore : : getDefaultInputDevice ( void )
{
unsigned int nDevices = getDeviceCount ( ) ;
if ( nDevices < = 1 ) return 0 ;
AudioDeviceID id ;
UInt32 dataSize = sizeof ( AudioDeviceID ) ;
AudioObjectPropertyAddress property = { kAudioHardwarePropertyDefaultInputDevice , kAudioObjectPropertyScopeGlobal , kAudioObjectPropertyElementMaster } ;
OSStatus result = AudioObjectGetPropertyData ( kAudioObjectSystemObject , & property , 0 , NULL , & dataSize , & id ) ;
if ( result ! = noErr ) {
errorText_ = " RtApiCore::getDefaultInputDevice: OS-X system error getting device. " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
dataSize * = nDevices ;
AudioDeviceID deviceList [ nDevices ] ;
property . mSelector = kAudioHardwarePropertyDevices ;
result = AudioObjectGetPropertyData ( kAudioObjectSystemObject , & property , 0 , NULL , & dataSize , ( void * ) & deviceList ) ;
if ( result ! = noErr ) {
errorText_ = " RtApiCore::getDefaultInputDevice: OS-X system error getting device IDs. " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
for ( unsigned int i = 0 ; i < nDevices ; i + + )
if ( id = = deviceList [ i ] ) return i ;
errorText_ = " RtApiCore::getDefaultInputDevice: No default device found! " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
unsigned int RtApiCore : : getDefaultOutputDevice ( void )
{
unsigned int nDevices = getDeviceCount ( ) ;
if ( nDevices < = 1 ) return 0 ;
AudioDeviceID id ;
UInt32 dataSize = sizeof ( AudioDeviceID ) ;
AudioObjectPropertyAddress property = { kAudioHardwarePropertyDefaultOutputDevice , kAudioObjectPropertyScopeGlobal , kAudioObjectPropertyElementMaster } ;
OSStatus result = AudioObjectGetPropertyData ( kAudioObjectSystemObject , & property , 0 , NULL , & dataSize , & id ) ;
if ( result ! = noErr ) {
errorText_ = " RtApiCore::getDefaultOutputDevice: OS-X system error getting device. " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
dataSize = sizeof ( AudioDeviceID ) * nDevices ;
AudioDeviceID deviceList [ nDevices ] ;
property . mSelector = kAudioHardwarePropertyDevices ;
result = AudioObjectGetPropertyData ( kAudioObjectSystemObject , & property , 0 , NULL , & dataSize , ( void * ) & deviceList ) ;
if ( result ! = noErr ) {
errorText_ = " RtApiCore::getDefaultOutputDevice: OS-X system error getting device IDs. " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
for ( unsigned int i = 0 ; i < nDevices ; i + + )
if ( id = = deviceList [ i ] ) return i ;
errorText_ = " RtApiCore::getDefaultOutputDevice: No default device found! " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
RtAudio : : DeviceInfo RtApiCore : : getDeviceInfo ( unsigned int device )
{
RtAudio : : DeviceInfo info ;
info . probed = false ;
// Get device ID
unsigned int nDevices = getDeviceCount ( ) ;
if ( nDevices = = 0 ) {
errorText_ = " RtApiCore::getDeviceInfo: no devices found! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
if ( device > = nDevices ) {
errorText_ = " RtApiCore::getDeviceInfo: device ID is invalid! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
AudioDeviceID deviceList [ nDevices ] ;
UInt32 dataSize = sizeof ( AudioDeviceID ) * nDevices ;
AudioObjectPropertyAddress property = { kAudioHardwarePropertyDevices ,
kAudioObjectPropertyScopeGlobal ,
kAudioObjectPropertyElementMaster } ;
OSStatus result = AudioObjectGetPropertyData ( kAudioObjectSystemObject , & property ,
0 , NULL , & dataSize , ( void * ) & deviceList ) ;
if ( result ! = noErr ) {
errorText_ = " RtApiCore::getDeviceInfo: OS-X system error getting device IDs. " ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
AudioDeviceID id = deviceList [ device ] ;
// Get the device name.
info . name . erase ( ) ;
CFStringRef cfname ;
dataSize = sizeof ( CFStringRef ) ;
property . mSelector = kAudioObjectPropertyManufacturer ;
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , & cfname ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceInfo: system error ( " < < getErrorCode ( result ) < < " ) getting device manufacturer. " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
//const char *mname = CFStringGetCStringPtr( cfname, CFStringGetSystemEncoding() );
int length = CFStringGetLength ( cfname ) ;
char * mname = ( char * ) malloc ( length * 3 + 1 ) ;
# if defined( UNICODE ) || defined( _UNICODE )
CFStringGetCString ( cfname , mname , length * 3 + 1 , kCFStringEncodingUTF8 ) ;
# else
CFStringGetCString ( cfname , mname , length * 3 + 1 , CFStringGetSystemEncoding ( ) ) ;
# endif
info . name . append ( ( const char * ) mname , strlen ( mname ) ) ;
info . name . append ( " : " ) ;
CFRelease ( cfname ) ;
free ( mname ) ;
property . mSelector = kAudioObjectPropertyName ;
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , & cfname ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceInfo: system error ( " < < getErrorCode ( result ) < < " ) getting device name. " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
//const char *name = CFStringGetCStringPtr( cfname, CFStringGetSystemEncoding() );
length = CFStringGetLength ( cfname ) ;
char * name = ( char * ) malloc ( length * 3 + 1 ) ;
# if defined( UNICODE ) || defined( _UNICODE )
CFStringGetCString ( cfname , name , length * 3 + 1 , kCFStringEncodingUTF8 ) ;
# else
CFStringGetCString ( cfname , name , length * 3 + 1 , CFStringGetSystemEncoding ( ) ) ;
# endif
info . name . append ( ( const char * ) name , strlen ( name ) ) ;
CFRelease ( cfname ) ;
free ( name ) ;
// Get the output stream "configuration".
AudioBufferList * bufferList = nil ;
property . mSelector = kAudioDevicePropertyStreamConfiguration ;
property . mScope = kAudioDevicePropertyScopeOutput ;
// property.mElement = kAudioObjectPropertyElementWildcard;
dataSize = 0 ;
result = AudioObjectGetPropertyDataSize ( id , & property , 0 , NULL , & dataSize ) ;
if ( result ! = noErr | | dataSize = = 0 ) {
errorStream_ < < " RtApiCore::getDeviceInfo: system error ( " < < getErrorCode ( result ) < < " ) getting output stream configuration info for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Allocate the AudioBufferList.
bufferList = ( AudioBufferList * ) malloc ( dataSize ) ;
if ( bufferList = = NULL ) {
errorText_ = " RtApiCore::getDeviceInfo: memory error allocating output AudioBufferList. " ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , bufferList ) ;
if ( result ! = noErr | | dataSize = = 0 ) {
free ( bufferList ) ;
errorStream_ < < " RtApiCore::getDeviceInfo: system error ( " < < getErrorCode ( result ) < < " ) getting output stream configuration for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Get output channel information.
unsigned int i , nStreams = bufferList - > mNumberBuffers ;
for ( i = 0 ; i < nStreams ; i + + )
info . outputChannels + = bufferList - > mBuffers [ i ] . mNumberChannels ;
free ( bufferList ) ;
// Get the input stream "configuration".
property . mScope = kAudioDevicePropertyScopeInput ;
result = AudioObjectGetPropertyDataSize ( id , & property , 0 , NULL , & dataSize ) ;
if ( result ! = noErr | | dataSize = = 0 ) {
errorStream_ < < " RtApiCore::getDeviceInfo: system error ( " < < getErrorCode ( result ) < < " ) getting input stream configuration info for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Allocate the AudioBufferList.
bufferList = ( AudioBufferList * ) malloc ( dataSize ) ;
if ( bufferList = = NULL ) {
errorText_ = " RtApiCore::getDeviceInfo: memory error allocating input AudioBufferList. " ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , bufferList ) ;
if ( result ! = noErr | | dataSize = = 0 ) {
free ( bufferList ) ;
errorStream_ < < " RtApiCore::getDeviceInfo: system error ( " < < getErrorCode ( result ) < < " ) getting input stream configuration for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Get input channel information.
nStreams = bufferList - > mNumberBuffers ;
for ( i = 0 ; i < nStreams ; i + + )
info . inputChannels + = bufferList - > mBuffers [ i ] . mNumberChannels ;
free ( bufferList ) ;
// If device opens for both playback and capture, we determine the channels.
if ( info . outputChannels > 0 & & info . inputChannels > 0 )
info . duplexChannels = ( info . outputChannels > info . inputChannels ) ? info . inputChannels : info . outputChannels ;
// Probe the device sample rates.
bool isInput = false ;
if ( info . outputChannels = = 0 ) isInput = true ;
// Determine the supported sample rates.
property . mSelector = kAudioDevicePropertyAvailableNominalSampleRates ;
if ( isInput = = false ) property . mScope = kAudioDevicePropertyScopeOutput ;
result = AudioObjectGetPropertyDataSize ( id , & property , 0 , NULL , & dataSize ) ;
if ( result ! = kAudioHardwareNoError | | dataSize = = 0 ) {
errorStream_ < < " RtApiCore::getDeviceInfo: system error ( " < < getErrorCode ( result ) < < " ) getting sample rate info. " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
UInt32 nRanges = dataSize / sizeof ( AudioValueRange ) ;
AudioValueRange rangeList [ nRanges ] ;
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , & rangeList ) ;
if ( result ! = kAudioHardwareNoError ) {
errorStream_ < < " RtApiCore::getDeviceInfo: system error ( " < < getErrorCode ( result ) < < " ) getting sample rates. " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// The sample rate reporting mechanism is a bit of a mystery. It
// seems that it can either return individual rates or a range of
// rates. I assume that if the min / max range values are the same,
// then that represents a single supported rate and if the min / max
// range values are different, the device supports an arbitrary
// range of values (though there might be multiple ranges, so we'll
// use the most conservative range).
Float64 minimumRate = 1.0 , maximumRate = 10000000000.0 ;
bool haveValueRange = false ;
info . sampleRates . clear ( ) ;
for ( UInt32 i = 0 ; i < nRanges ; i + + ) {
if ( rangeList [ i ] . mMinimum = = rangeList [ i ] . mMaximum )
info . sampleRates . push_back ( ( unsigned int ) rangeList [ i ] . mMinimum ) ;
else {
haveValueRange = true ;
if ( rangeList [ i ] . mMinimum > minimumRate ) minimumRate = rangeList [ i ] . mMinimum ;
if ( rangeList [ i ] . mMaximum < maximumRate ) maximumRate = rangeList [ i ] . mMaximum ;
}
}
if ( haveValueRange ) {
for ( unsigned int k = 0 ; k < MAX_SAMPLE_RATES ; k + + ) {
if ( SAMPLE_RATES [ k ] > = ( unsigned int ) minimumRate & & SAMPLE_RATES [ k ] < = ( unsigned int ) maximumRate )
info . sampleRates . push_back ( SAMPLE_RATES [ k ] ) ;
}
}
// Sort and remove any redundant values
std : : sort ( info . sampleRates . begin ( ) , info . sampleRates . end ( ) ) ;
info . sampleRates . erase ( unique ( info . sampleRates . begin ( ) , info . sampleRates . end ( ) ) , info . sampleRates . end ( ) ) ;
if ( info . sampleRates . size ( ) = = 0 ) {
errorStream_ < < " RtApiCore::probeDeviceInfo: No supported sample rates found for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// CoreAudio always uses 32-bit floating point data for PCM streams.
// Thus, any other "physical" formats supported by the device are of
// no interest to the client.
info . nativeFormats = RTAUDIO_FLOAT32 ;
if ( info . outputChannels > 0 )
if ( getDefaultOutputDevice ( ) = = device ) info . isDefaultOutput = true ;
if ( info . inputChannels > 0 )
if ( getDefaultInputDevice ( ) = = device ) info . isDefaultInput = true ;
info . probed = true ;
return info ;
}
static OSStatus callbackHandler ( AudioDeviceID inDevice ,
const AudioTimeStamp * /*inNow*/ ,
const AudioBufferList * inInputData ,
const AudioTimeStamp * /*inInputTime*/ ,
AudioBufferList * outOutputData ,
const AudioTimeStamp * /*inOutputTime*/ ,
void * infoPointer )
{
CallbackInfo * info = ( CallbackInfo * ) infoPointer ;
RtApiCore * object = ( RtApiCore * ) info - > object ;
if ( object - > callbackEvent ( inDevice , inInputData , outOutputData ) = = false )
return kAudioHardwareUnspecifiedError ;
else
return kAudioHardwareNoError ;
}
static OSStatus xrunListener ( AudioObjectID /*inDevice*/ ,
UInt32 nAddresses ,
const AudioObjectPropertyAddress properties [ ] ,
void * handlePointer )
{
CoreHandle * handle = ( CoreHandle * ) handlePointer ;
for ( UInt32 i = 0 ; i < nAddresses ; i + + ) {
if ( properties [ i ] . mSelector = = kAudioDeviceProcessorOverload ) {
if ( properties [ i ] . mScope = = kAudioDevicePropertyScopeInput )
handle - > xrun [ 1 ] = true ;
else
handle - > xrun [ 0 ] = true ;
}
}
return kAudioHardwareNoError ;
}
static OSStatus rateListener ( AudioObjectID inDevice ,
UInt32 /*nAddresses*/ ,
const AudioObjectPropertyAddress /*properties*/ [ ] ,
void * ratePointer )
{
Float64 * rate = ( Float64 * ) ratePointer ;
UInt32 dataSize = sizeof ( Float64 ) ;
AudioObjectPropertyAddress property = { kAudioDevicePropertyNominalSampleRate ,
kAudioObjectPropertyScopeGlobal ,
kAudioObjectPropertyElementMaster } ;
AudioObjectGetPropertyData ( inDevice , & property , 0 , NULL , & dataSize , rate ) ;
return kAudioHardwareNoError ;
}
bool RtApiCore : : probeDeviceOpen ( unsigned int device , StreamMode mode , unsigned int channels ,
unsigned int firstChannel , unsigned int sampleRate ,
RtAudioFormat format , unsigned int * bufferSize ,
RtAudio : : StreamOptions * options )
{
// Get device ID
unsigned int nDevices = getDeviceCount ( ) ;
if ( nDevices = = 0 ) {
// This should not happen because a check is made before this function is called.
errorText_ = " RtApiCore::probeDeviceOpen: no devices found! " ;
return FAILURE ;
}
if ( device > = nDevices ) {
// This should not happen because a check is made before this function is called.
errorText_ = " RtApiCore::probeDeviceOpen: device ID is invalid! " ;
return FAILURE ;
}
AudioDeviceID deviceList [ nDevices ] ;
UInt32 dataSize = sizeof ( AudioDeviceID ) * nDevices ;
AudioObjectPropertyAddress property = { kAudioHardwarePropertyDevices ,
kAudioObjectPropertyScopeGlobal ,
kAudioObjectPropertyElementMaster } ;
OSStatus result = AudioObjectGetPropertyData ( kAudioObjectSystemObject , & property ,
0 , NULL , & dataSize , ( void * ) & deviceList ) ;
if ( result ! = noErr ) {
errorText_ = " RtApiCore::probeDeviceOpen: OS-X system error getting device IDs. " ;
return FAILURE ;
}
AudioDeviceID id = deviceList [ device ] ;
// Setup for stream mode.
bool isInput = false ;
if ( mode = = INPUT ) {
isInput = true ;
property . mScope = kAudioDevicePropertyScopeInput ;
}
else
property . mScope = kAudioDevicePropertyScopeOutput ;
// Get the stream "configuration".
AudioBufferList * bufferList = nil ;
dataSize = 0 ;
property . mSelector = kAudioDevicePropertyStreamConfiguration ;
result = AudioObjectGetPropertyDataSize ( id , & property , 0 , NULL , & dataSize ) ;
if ( result ! = noErr | | dataSize = = 0 ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) getting stream configuration info for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Allocate the AudioBufferList.
bufferList = ( AudioBufferList * ) malloc ( dataSize ) ;
if ( bufferList = = NULL ) {
errorText_ = " RtApiCore::probeDeviceOpen: memory error allocating AudioBufferList. " ;
return FAILURE ;
}
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , bufferList ) ;
if ( result ! = noErr | | dataSize = = 0 ) {
free ( bufferList ) ;
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) getting stream configuration for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Search for one or more streams that contain the desired number of
// channels. CoreAudio devices can have an arbitrary number of
// streams and each stream can have an arbitrary number of channels.
// For each stream, a single buffer of interleaved samples is
// provided. RtAudio prefers the use of one stream of interleaved
// data or multiple consecutive single-channel streams. However, we
// now support multiple consecutive multi-channel streams of
// interleaved data as well.
UInt32 iStream , offsetCounter = firstChannel ;
UInt32 nStreams = bufferList - > mNumberBuffers ;
bool monoMode = false ;
bool foundStream = false ;
// First check that the device supports the requested number of
// channels.
UInt32 deviceChannels = 0 ;
for ( iStream = 0 ; iStream < nStreams ; iStream + + )
deviceChannels + = bufferList - > mBuffers [ iStream ] . mNumberChannels ;
if ( deviceChannels < ( channels + firstChannel ) ) {
free ( bufferList ) ;
errorStream_ < < " RtApiCore::probeDeviceOpen: the device ( " < < device < < " ) does not support the requested channel count. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Look for a single stream meeting our needs.
UInt32 firstStream , streamCount = 1 , streamChannels = 0 , channelOffset = 0 ;
for ( iStream = 0 ; iStream < nStreams ; iStream + + ) {
streamChannels = bufferList - > mBuffers [ iStream ] . mNumberChannels ;
if ( streamChannels > = channels + offsetCounter ) {
firstStream = iStream ;
channelOffset = offsetCounter ;
foundStream = true ;
break ;
}
if ( streamChannels > offsetCounter ) break ;
offsetCounter - = streamChannels ;
}
// If we didn't find a single stream above, then we should be able
// to meet the channel specification with multiple streams.
if ( foundStream = = false ) {
monoMode = true ;
offsetCounter = firstChannel ;
for ( iStream = 0 ; iStream < nStreams ; iStream + + ) {
streamChannels = bufferList - > mBuffers [ iStream ] . mNumberChannels ;
if ( streamChannels > offsetCounter ) break ;
offsetCounter - = streamChannels ;
}
firstStream = iStream ;
channelOffset = offsetCounter ;
Int32 channelCounter = channels + offsetCounter - streamChannels ;
if ( streamChannels > 1 ) monoMode = false ;
while ( channelCounter > 0 ) {
streamChannels = bufferList - > mBuffers [ + + iStream ] . mNumberChannels ;
if ( streamChannels > 1 ) monoMode = false ;
channelCounter - = streamChannels ;
streamCount + + ;
}
}
free ( bufferList ) ;
// Determine the buffer size.
AudioValueRange bufferRange ;
dataSize = sizeof ( AudioValueRange ) ;
property . mSelector = kAudioDevicePropertyBufferFrameSizeRange ;
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , & bufferRange ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) getting buffer size range for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
if ( bufferRange . mMinimum > * bufferSize ) * bufferSize = ( unsigned long ) bufferRange . mMinimum ;
else if ( bufferRange . mMaximum < * bufferSize ) * bufferSize = ( unsigned long ) bufferRange . mMaximum ;
if ( options & & options - > flags & RTAUDIO_MINIMIZE_LATENCY ) * bufferSize = ( unsigned long ) bufferRange . mMinimum ;
// Set the buffer size. For multiple streams, I'm assuming we only
// need to make this setting for the master channel.
UInt32 theSize = ( UInt32 ) * bufferSize ;
dataSize = sizeof ( UInt32 ) ;
property . mSelector = kAudioDevicePropertyBufferFrameSize ;
result = AudioObjectSetPropertyData ( id , & property , 0 , NULL , dataSize , & theSize ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) setting the buffer size for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// If attempting to setup a duplex stream, the bufferSize parameter
// MUST be the same in both directions!
* bufferSize = theSize ;
if ( stream_ . mode = = OUTPUT & & mode = = INPUT & & * bufferSize ! = stream_ . bufferSize ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error setting buffer size for duplex stream on device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
stream_ . bufferSize = * bufferSize ;
stream_ . nBuffers = 1 ;
// Try to set "hog" mode ... it's not clear to me this is working.
if ( options & & options - > flags & RTAUDIO_HOG_DEVICE ) {
pid_t hog_pid ;
dataSize = sizeof ( hog_pid ) ;
property . mSelector = kAudioDevicePropertyHogMode ;
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , & hog_pid ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) getting 'hog' state! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
if ( hog_pid ! = getpid ( ) ) {
hog_pid = getpid ( ) ;
result = AudioObjectSetPropertyData ( id , & property , 0 , NULL , dataSize , & hog_pid ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) setting 'hog' state! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
}
// Check and if necessary, change the sample rate for the device.
Float64 nominalRate ;
dataSize = sizeof ( Float64 ) ;
property . mSelector = kAudioDevicePropertyNominalSampleRate ;
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , & nominalRate ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) getting current sample rate. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Only change the sample rate if off by more than 1 Hz.
if ( fabs ( nominalRate - ( double ) sampleRate ) > 1.0 ) {
// Set a property listener for the sample rate change
Float64 reportedRate = 0.0 ;
AudioObjectPropertyAddress tmp = { kAudioDevicePropertyNominalSampleRate , kAudioObjectPropertyScopeGlobal , kAudioObjectPropertyElementMaster } ;
result = AudioObjectAddPropertyListener ( id , & tmp , rateListener , ( void * ) & reportedRate ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) setting sample rate property listener for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
nominalRate = ( Float64 ) sampleRate ;
result = AudioObjectSetPropertyData ( id , & property , 0 , NULL , dataSize , & nominalRate ) ;
if ( result ! = noErr ) {
AudioObjectRemovePropertyListener ( id , & tmp , rateListener , ( void * ) & reportedRate ) ;
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) setting sample rate for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Now wait until the reported nominal rate is what we just set.
UInt32 microCounter = 0 ;
while ( reportedRate ! = nominalRate ) {
microCounter + = 5000 ;
if ( microCounter > 5000000 ) break ;
usleep ( 5000 ) ;
}
// Remove the property listener.
AudioObjectRemovePropertyListener ( id , & tmp , rateListener , ( void * ) & reportedRate ) ;
if ( microCounter > 5000000 ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: timeout waiting for sample rate update for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
// Now set the stream format for all streams. Also, check the
// physical format of the device and change that if necessary.
AudioStreamBasicDescription description ;
dataSize = sizeof ( AudioStreamBasicDescription ) ;
property . mSelector = kAudioStreamPropertyVirtualFormat ;
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , & description ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) getting stream format for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Set the sample rate and data format id. However, only make the
// change if the sample rate is not within 1.0 of the desired
// rate and the format is not linear pcm.
bool updateFormat = false ;
if ( fabs ( description . mSampleRate - ( Float64 ) sampleRate ) > 1.0 ) {
description . mSampleRate = ( Float64 ) sampleRate ;
updateFormat = true ;
}
if ( description . mFormatID ! = kAudioFormatLinearPCM ) {
description . mFormatID = kAudioFormatLinearPCM ;
updateFormat = true ;
}
if ( updateFormat ) {
result = AudioObjectSetPropertyData ( id , & property , 0 , NULL , dataSize , & description ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) setting sample rate or data format for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
// Now check the physical format.
property . mSelector = kAudioStreamPropertyPhysicalFormat ;
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , & description ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) getting stream physical format for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
//std::cout << "Current physical stream format:" << std::endl;
//std::cout << " mBitsPerChan = " << description.mBitsPerChannel << std::endl;
//std::cout << " aligned high = " << (description.mFormatFlags & kAudioFormatFlagIsAlignedHigh) << ", isPacked = " << (description.mFormatFlags & kAudioFormatFlagIsPacked) << std::endl;
//std::cout << " bytesPerFrame = " << description.mBytesPerFrame << std::endl;
//std::cout << " sample rate = " << description.mSampleRate << std::endl;
if ( description . mFormatID ! = kAudioFormatLinearPCM | | description . mBitsPerChannel < 16 ) {
description . mFormatID = kAudioFormatLinearPCM ;
//description.mSampleRate = (Float64) sampleRate;
AudioStreamBasicDescription testDescription = description ;
UInt32 formatFlags ;
// We'll try higher bit rates first and then work our way down.
std : : vector < std : : pair < UInt32 , UInt32 > > physicalFormats ;
formatFlags = ( description . mFormatFlags | kLinearPCMFormatFlagIsFloat ) & ~ kLinearPCMFormatFlagIsSignedInteger ;
physicalFormats . push_back ( std : : pair < Float32 , UInt32 > ( 32 , formatFlags ) ) ;
formatFlags = ( description . mFormatFlags | kLinearPCMFormatFlagIsSignedInteger | kAudioFormatFlagIsPacked ) & ~ kLinearPCMFormatFlagIsFloat ;
physicalFormats . push_back ( std : : pair < Float32 , UInt32 > ( 32 , formatFlags ) ) ;
physicalFormats . push_back ( std : : pair < Float32 , UInt32 > ( 24 , formatFlags ) ) ; // 24-bit packed
formatFlags & = ~ ( kAudioFormatFlagIsPacked | kAudioFormatFlagIsAlignedHigh ) ;
physicalFormats . push_back ( std : : pair < Float32 , UInt32 > ( 24.2 , formatFlags ) ) ; // 24-bit in 4 bytes, aligned low
formatFlags | = kAudioFormatFlagIsAlignedHigh ;
physicalFormats . push_back ( std : : pair < Float32 , UInt32 > ( 24.4 , formatFlags ) ) ; // 24-bit in 4 bytes, aligned high
formatFlags = ( description . mFormatFlags | kLinearPCMFormatFlagIsSignedInteger | kAudioFormatFlagIsPacked ) & ~ kLinearPCMFormatFlagIsFloat ;
physicalFormats . push_back ( std : : pair < Float32 , UInt32 > ( 16 , formatFlags ) ) ;
physicalFormats . push_back ( std : : pair < Float32 , UInt32 > ( 8 , formatFlags ) ) ;
bool setPhysicalFormat = false ;
for ( unsigned int i = 0 ; i < physicalFormats . size ( ) ; i + + ) {
testDescription = description ;
testDescription . mBitsPerChannel = ( UInt32 ) physicalFormats [ i ] . first ;
testDescription . mFormatFlags = physicalFormats [ i ] . second ;
if ( ( 24 = = ( UInt32 ) physicalFormats [ i ] . first ) & & ~ ( physicalFormats [ i ] . second & kAudioFormatFlagIsPacked ) )
testDescription . mBytesPerFrame = 4 * testDescription . mChannelsPerFrame ;
else
testDescription . mBytesPerFrame = testDescription . mBitsPerChannel / 8 * testDescription . mChannelsPerFrame ;
testDescription . mBytesPerPacket = testDescription . mBytesPerFrame * testDescription . mFramesPerPacket ;
result = AudioObjectSetPropertyData ( id , & property , 0 , NULL , dataSize , & testDescription ) ;
if ( result = = noErr ) {
setPhysicalFormat = true ;
//std::cout << "Updated physical stream format:" << std::endl;
//std::cout << " mBitsPerChan = " << testDescription.mBitsPerChannel << std::endl;
//std::cout << " aligned high = " << (testDescription.mFormatFlags & kAudioFormatFlagIsAlignedHigh) << ", isPacked = " << (testDescription.mFormatFlags & kAudioFormatFlagIsPacked) << std::endl;
//std::cout << " bytesPerFrame = " << testDescription.mBytesPerFrame << std::endl;
//std::cout << " sample rate = " << testDescription.mSampleRate << std::endl;
break ;
}
}
if ( ! setPhysicalFormat ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) setting physical data format for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
} // done setting virtual/physical formats.
// Get the stream / device latency.
UInt32 latency ;
dataSize = sizeof ( UInt32 ) ;
property . mSelector = kAudioDevicePropertyLatency ;
if ( AudioObjectHasProperty ( id , & property ) = = true ) {
result = AudioObjectGetPropertyData ( id , & property , 0 , NULL , & dataSize , & latency ) ;
if ( result = = kAudioHardwareNoError ) stream_ . latency [ mode ] = latency ;
else {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error ( " < < getErrorCode ( result ) < < " ) getting device latency for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
}
}
// Byte-swapping: According to AudioHardware.h, the stream data will
// always be presented in native-endian format, so we should never
// need to byte swap.
stream_ . doByteSwap [ mode ] = false ;
// From the CoreAudio documentation, PCM data must be supplied as
// 32-bit floats.
stream_ . userFormat = format ;
stream_ . deviceFormat [ mode ] = RTAUDIO_FLOAT32 ;
if ( streamCount = = 1 )
stream_ . nDeviceChannels [ mode ] = description . mChannelsPerFrame ;
else // multiple streams
stream_ . nDeviceChannels [ mode ] = channels ;
stream_ . nUserChannels [ mode ] = channels ;
stream_ . channelOffset [ mode ] = channelOffset ; // offset within a CoreAudio stream
if ( options & & options - > flags & RTAUDIO_NONINTERLEAVED ) stream_ . userInterleaved = false ;
else stream_ . userInterleaved = true ;
stream_ . deviceInterleaved [ mode ] = true ;
if ( monoMode = = true ) stream_ . deviceInterleaved [ mode ] = false ;
// Set flags for buffer conversion.
stream_ . doConvertBuffer [ mode ] = false ;
if ( stream_ . userFormat ! = stream_ . deviceFormat [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . nUserChannels [ mode ] < stream_ . nDeviceChannels [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( streamCount = = 1 ) {
if ( stream_ . nUserChannels [ mode ] > 1 & &
stream_ . userInterleaved ! = stream_ . deviceInterleaved [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
}
else if ( monoMode & & stream_ . userInterleaved )
stream_ . doConvertBuffer [ mode ] = true ;
// Allocate our CoreHandle structure for the stream.
CoreHandle * handle = 0 ;
if ( stream_ . apiHandle = = 0 ) {
try {
handle = new CoreHandle ;
}
catch ( std : : bad_alloc & ) {
errorText_ = " RtApiCore::probeDeviceOpen: error allocating CoreHandle memory. " ;
goto error ;
}
if ( pthread_cond_init ( & handle - > condition , NULL ) ) {
errorText_ = " RtApiCore::probeDeviceOpen: error initializing pthread condition variable. " ;
goto error ;
}
stream_ . apiHandle = ( void * ) handle ;
}
else
handle = ( CoreHandle * ) stream_ . apiHandle ;
handle - > iStream [ mode ] = firstStream ;
handle - > nStreams [ mode ] = streamCount ;
handle - > id [ mode ] = id ;
// Allocate necessary internal buffers.
unsigned long bufferBytes ;
bufferBytes = stream_ . nUserChannels [ mode ] * * bufferSize * formatBytes ( stream_ . userFormat ) ;
// stream_.userBuffer[mode] = (char *) calloc( bufferBytes, 1 );
stream_ . userBuffer [ mode ] = ( char * ) malloc ( bufferBytes * sizeof ( char ) ) ;
memset ( stream_ . userBuffer [ mode ] , 0 , bufferBytes * sizeof ( char ) ) ;
if ( stream_ . userBuffer [ mode ] = = NULL ) {
errorText_ = " RtApiCore::probeDeviceOpen: error allocating user buffer memory. " ;
goto error ;
}
// If possible, we will make use of the CoreAudio stream buffers as
// "device buffers". However, we can't do this if using multiple
// streams.
if ( stream_ . doConvertBuffer [ mode ] & & handle - > nStreams [ mode ] > 1 ) {
bool makeBuffer = true ;
bufferBytes = stream_ . nDeviceChannels [ mode ] * formatBytes ( stream_ . deviceFormat [ mode ] ) ;
if ( mode = = INPUT ) {
if ( stream_ . mode = = OUTPUT & & stream_ . deviceBuffer ) {
unsigned long bytesOut = stream_ . nDeviceChannels [ 0 ] * formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
if ( bufferBytes < = bytesOut ) makeBuffer = false ;
}
}
if ( makeBuffer ) {
bufferBytes * = * bufferSize ;
if ( stream_ . deviceBuffer ) free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . deviceBuffer = = NULL ) {
errorText_ = " RtApiCore::probeDeviceOpen: error allocating device buffer memory. " ;
goto error ;
}
}
}
stream_ . sampleRate = sampleRate ;
stream_ . device [ mode ] = device ;
stream_ . state = STREAM_STOPPED ;
stream_ . callbackInfo . object = ( void * ) this ;
// Setup the buffer conversion information structure.
if ( stream_ . doConvertBuffer [ mode ] ) {
if ( streamCount > 1 ) setConvertInfo ( mode , 0 ) ;
else setConvertInfo ( mode , channelOffset ) ;
}
if ( mode = = INPUT & & stream_ . mode = = OUTPUT & & stream_ . device [ 0 ] = = device )
// Only one callback procedure per device.
stream_ . mode = DUPLEX ;
else {
# if defined( MAC_OS_X_VERSION_10_5 ) && ( MAC_OS_X_VERSION_MIN_REQUIRED >= MAC_OS_X_VERSION_10_5 )
result = AudioDeviceCreateIOProcID ( id , callbackHandler , ( void * ) & stream_ . callbackInfo , & handle - > procId [ mode ] ) ;
# else
// deprecated in favor of AudioDeviceCreateIOProcID()
result = AudioDeviceAddIOProc ( id , callbackHandler , ( void * ) & stream_ . callbackInfo ) ;
# endif
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::probeDeviceOpen: system error setting callback for device ( " < < device < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto error ;
}
if ( stream_ . mode = = OUTPUT & & mode = = INPUT )
stream_ . mode = DUPLEX ;
else
stream_ . mode = mode ;
}
// Setup the device property listener for over/underload.
property . mSelector = kAudioDeviceProcessorOverload ;
property . mScope = kAudioObjectPropertyScopeGlobal ;
result = AudioObjectAddPropertyListener ( id , & property , xrunListener , ( void * ) handle ) ;
return SUCCESS ;
error :
if ( handle ) {
pthread_cond_destroy ( & handle - > condition ) ;
delete handle ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
stream_ . state = STREAM_CLOSED ;
return FAILURE ;
}
void RtApiCore : : closeStream ( void )
{
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiCore::closeStream(): no open stream to close! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
CoreHandle * handle = ( CoreHandle * ) stream_ . apiHandle ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
if ( stream_ . state = = STREAM_RUNNING )
AudioDeviceStop ( handle - > id [ 0 ] , callbackHandler ) ;
# if defined( MAC_OS_X_VERSION_10_5 ) && ( MAC_OS_X_VERSION_MIN_REQUIRED >= MAC_OS_X_VERSION_10_5 )
AudioDeviceDestroyIOProcID ( handle - > id [ 0 ] , handle - > procId [ 0 ] ) ;
# else
// deprecated in favor of AudioDeviceDestroyIOProcID()
AudioDeviceRemoveIOProc ( handle - > id [ 0 ] , callbackHandler ) ;
# endif
}
if ( stream_ . mode = = INPUT | | ( stream_ . mode = = DUPLEX & & stream_ . device [ 0 ] ! = stream_ . device [ 1 ] ) ) {
if ( stream_ . state = = STREAM_RUNNING )
AudioDeviceStop ( handle - > id [ 1 ] , callbackHandler ) ;
# if defined( MAC_OS_X_VERSION_10_5 ) && ( MAC_OS_X_VERSION_MIN_REQUIRED >= MAC_OS_X_VERSION_10_5 )
AudioDeviceDestroyIOProcID ( handle - > id [ 1 ] , handle - > procId [ 1 ] ) ;
# else
// deprecated in favor of AudioDeviceDestroyIOProcID()
AudioDeviceRemoveIOProc ( handle - > id [ 1 ] , callbackHandler ) ;
# endif
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
// Destroy pthread condition variable.
pthread_cond_destroy ( & handle - > condition ) ;
delete handle ;
stream_ . apiHandle = 0 ;
stream_ . mode = UNINITIALIZED ;
stream_ . state = STREAM_CLOSED ;
}
void RtApiCore : : startStream ( void )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_RUNNING ) {
errorText_ = " RtApiCore::startStream(): the stream is already running! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
OSStatus result = noErr ;
CoreHandle * handle = ( CoreHandle * ) stream_ . apiHandle ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
result = AudioDeviceStart ( handle - > id [ 0 ] , callbackHandler ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::startStream: system error ( " < < getErrorCode ( result ) < < " ) starting callback procedure on device ( " < < stream_ . device [ 0 ] < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
if ( stream_ . mode = = INPUT | |
( stream_ . mode = = DUPLEX & & stream_ . device [ 0 ] ! = stream_ . device [ 1 ] ) ) {
result = AudioDeviceStart ( handle - > id [ 1 ] , callbackHandler ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::startStream: system error starting input callback procedure on device ( " < < stream_ . device [ 1 ] < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
handle - > drainCounter = 0 ;
handle - > internalDrain = false ;
stream_ . state = STREAM_RUNNING ;
unlock :
if ( result = = noErr ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiCore : : stopStream ( void )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiCore::stopStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
OSStatus result = noErr ;
CoreHandle * handle = ( CoreHandle * ) stream_ . apiHandle ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
if ( handle - > drainCounter = = 0 ) {
handle - > drainCounter = 2 ;
pthread_cond_wait ( & handle - > condition , & stream_ . mutex ) ; // block until signaled
}
result = AudioDeviceStop ( handle - > id [ 0 ] , callbackHandler ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::stopStream: system error ( " < < getErrorCode ( result ) < < " ) stopping callback procedure on device ( " < < stream_ . device [ 0 ] < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
if ( stream_ . mode = = INPUT | | ( stream_ . mode = = DUPLEX & & stream_ . device [ 0 ] ! = stream_ . device [ 1 ] ) ) {
result = AudioDeviceStop ( handle - > id [ 1 ] , callbackHandler ) ;
if ( result ! = noErr ) {
errorStream_ < < " RtApiCore::stopStream: system error ( " < < getErrorCode ( result ) < < " ) stopping input callback procedure on device ( " < < stream_ . device [ 1 ] < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
stream_ . state = STREAM_STOPPED ;
unlock :
if ( result = = noErr ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiCore : : abortStream ( void )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiCore::abortStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
CoreHandle * handle = ( CoreHandle * ) stream_ . apiHandle ;
handle - > drainCounter = 2 ;
stopStream ( ) ;
}
// This function will be called by a spawned thread when the user
// callback function signals that the stream should be stopped or
// aborted. It is better to handle it this way because the
// callbackEvent() function probably should return before the AudioDeviceStop()
// function is called.
static void * coreStopStream ( void * ptr )
{
CallbackInfo * info = ( CallbackInfo * ) ptr ;
RtApiCore * object = ( RtApiCore * ) info - > object ;
object - > stopStream ( ) ;
pthread_exit ( NULL ) ;
}
bool RtApiCore : : callbackEvent ( AudioDeviceID deviceId ,
const AudioBufferList * inBufferList ,
const AudioBufferList * outBufferList )
{
if ( stream_ . state = = STREAM_STOPPED | | stream_ . state = = STREAM_STOPPING ) return SUCCESS ;
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiCore::callbackEvent(): the stream is closed ... this shouldn't happen! " ;
error ( RtAudioError : : WARNING ) ;
return FAILURE ;
}
CallbackInfo * info = ( CallbackInfo * ) & stream_ . callbackInfo ;
CoreHandle * handle = ( CoreHandle * ) stream_ . apiHandle ;
// Check if we were draining the stream and signal is finished.
if ( handle - > drainCounter > 3 ) {
ThreadHandle threadId ;
stream_ . state = STREAM_STOPPING ;
if ( handle - > internalDrain = = true )
pthread_create ( & threadId , NULL , coreStopStream , info ) ;
else // external call to stopStream()
pthread_cond_signal ( & handle - > condition ) ;
return SUCCESS ;
}
AudioDeviceID outputDevice = handle - > id [ 0 ] ;
// Invoke user callback to get fresh output data UNLESS we are
// draining stream or duplex mode AND the input/output devices are
// different AND this function is called for the input device.
if ( handle - > drainCounter = = 0 & & ( stream_ . mode ! = DUPLEX | | deviceId = = outputDevice ) ) {
RtAudioCallback callback = ( RtAudioCallback ) info - > callback ;
double streamTime = getStreamTime ( ) ;
RtAudioStreamStatus status = 0 ;
if ( stream_ . mode ! = INPUT & & handle - > xrun [ 0 ] = = true ) {
status | = RTAUDIO_OUTPUT_UNDERFLOW ;
handle - > xrun [ 0 ] = false ;
}
if ( stream_ . mode ! = OUTPUT & & handle - > xrun [ 1 ] = = true ) {
status | = RTAUDIO_INPUT_OVERFLOW ;
handle - > xrun [ 1 ] = false ;
}
int cbReturnValue = callback ( stream_ . userBuffer [ 0 ] , stream_ . userBuffer [ 1 ] ,
stream_ . bufferSize , streamTime , status , info - > userData ) ;
if ( cbReturnValue = = 2 ) {
stream_ . state = STREAM_STOPPING ;
handle - > drainCounter = 2 ;
abortStream ( ) ;
return SUCCESS ;
}
else if ( cbReturnValue = = 1 ) {
handle - > drainCounter = 1 ;
handle - > internalDrain = true ;
}
}
if ( stream_ . mode = = OUTPUT | | ( stream_ . mode = = DUPLEX & & deviceId = = outputDevice ) ) {
if ( handle - > drainCounter > 1 ) { // write zeros to the output stream
if ( handle - > nStreams [ 0 ] = = 1 ) {
memset ( outBufferList - > mBuffers [ handle - > iStream [ 0 ] ] . mData ,
0 ,
outBufferList - > mBuffers [ handle - > iStream [ 0 ] ] . mDataByteSize ) ;
}
else { // fill multiple streams with zeros
for ( unsigned int i = 0 ; i < handle - > nStreams [ 0 ] ; i + + ) {
memset ( outBufferList - > mBuffers [ handle - > iStream [ 0 ] + i ] . mData ,
0 ,
outBufferList - > mBuffers [ handle - > iStream [ 0 ] + i ] . mDataByteSize ) ;
}
}
}
else if ( handle - > nStreams [ 0 ] = = 1 ) {
if ( stream_ . doConvertBuffer [ 0 ] ) { // convert directly to CoreAudio stream buffer
convertBuffer ( ( char * ) outBufferList - > mBuffers [ handle - > iStream [ 0 ] ] . mData ,
stream_ . userBuffer [ 0 ] , stream_ . convertInfo [ 0 ] ) ;
}
else { // copy from user buffer
memcpy ( outBufferList - > mBuffers [ handle - > iStream [ 0 ] ] . mData ,
stream_ . userBuffer [ 0 ] ,
outBufferList - > mBuffers [ handle - > iStream [ 0 ] ] . mDataByteSize ) ;
}
}
else { // fill multiple streams
Float32 * inBuffer = ( Float32 * ) stream_ . userBuffer [ 0 ] ;
if ( stream_ . doConvertBuffer [ 0 ] ) {
convertBuffer ( stream_ . deviceBuffer , stream_ . userBuffer [ 0 ] , stream_ . convertInfo [ 0 ] ) ;
inBuffer = ( Float32 * ) stream_ . deviceBuffer ;
}
if ( stream_ . deviceInterleaved [ 0 ] = = false ) { // mono mode
UInt32 bufferBytes = outBufferList - > mBuffers [ handle - > iStream [ 0 ] ] . mDataByteSize ;
for ( unsigned int i = 0 ; i < stream_ . nUserChannels [ 0 ] ; i + + ) {
memcpy ( outBufferList - > mBuffers [ handle - > iStream [ 0 ] + i ] . mData ,
( void * ) & inBuffer [ i * stream_ . bufferSize ] , bufferBytes ) ;
}
}
else { // fill multiple multi-channel streams with interleaved data
UInt32 streamChannels , channelsLeft , inJump , outJump , inOffset ;
Float32 * out , * in ;
bool inInterleaved = ( stream_ . userInterleaved ) ? true : false ;
UInt32 inChannels = stream_ . nUserChannels [ 0 ] ;
if ( stream_ . doConvertBuffer [ 0 ] ) {
inInterleaved = true ; // device buffer will always be interleaved for nStreams > 1 and not mono mode
inChannels = stream_ . nDeviceChannels [ 0 ] ;
}
if ( inInterleaved ) inOffset = 1 ;
else inOffset = stream_ . bufferSize ;
channelsLeft = inChannels ;
for ( unsigned int i = 0 ; i < handle - > nStreams [ 0 ] ; i + + ) {
in = inBuffer ;
out = ( Float32 * ) outBufferList - > mBuffers [ handle - > iStream [ 0 ] + i ] . mData ;
streamChannels = outBufferList - > mBuffers [ handle - > iStream [ 0 ] + i ] . mNumberChannels ;
outJump = 0 ;
// Account for possible channel offset in first stream
if ( i = = 0 & & stream_ . channelOffset [ 0 ] > 0 ) {
streamChannels - = stream_ . channelOffset [ 0 ] ;
outJump = stream_ . channelOffset [ 0 ] ;
out + = outJump ;
}
// Account for possible unfilled channels at end of the last stream
if ( streamChannels > channelsLeft ) {
outJump = streamChannels - channelsLeft ;
streamChannels = channelsLeft ;
}
// Determine input buffer offsets and skips
if ( inInterleaved ) {
inJump = inChannels ;
in + = inChannels - channelsLeft ;
}
else {
inJump = 1 ;
in + = ( inChannels - channelsLeft ) * inOffset ;
}
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( unsigned int j = 0 ; j < streamChannels ; j + + ) {
* out + + = in [ j * inOffset ] ;
}
out + = outJump ;
in + = inJump ;
}
channelsLeft - = streamChannels ;
}
}
}
}
// Don't bother draining input
if ( handle - > drainCounter ) {
handle - > drainCounter + + ;
goto unlock ;
}
AudioDeviceID inputDevice ;
inputDevice = handle - > id [ 1 ] ;
if ( stream_ . mode = = INPUT | | ( stream_ . mode = = DUPLEX & & deviceId = = inputDevice ) ) {
if ( handle - > nStreams [ 1 ] = = 1 ) {
if ( stream_ . doConvertBuffer [ 1 ] ) { // convert directly from CoreAudio stream buffer
convertBuffer ( stream_ . userBuffer [ 1 ] ,
( char * ) inBufferList - > mBuffers [ handle - > iStream [ 1 ] ] . mData ,
stream_ . convertInfo [ 1 ] ) ;
}
else { // copy to user buffer
memcpy ( stream_ . userBuffer [ 1 ] ,
inBufferList - > mBuffers [ handle - > iStream [ 1 ] ] . mData ,
inBufferList - > mBuffers [ handle - > iStream [ 1 ] ] . mDataByteSize ) ;
}
}
else { // read from multiple streams
Float32 * outBuffer = ( Float32 * ) stream_ . userBuffer [ 1 ] ;
if ( stream_ . doConvertBuffer [ 1 ] ) outBuffer = ( Float32 * ) stream_ . deviceBuffer ;
if ( stream_ . deviceInterleaved [ 1 ] = = false ) { // mono mode
UInt32 bufferBytes = inBufferList - > mBuffers [ handle - > iStream [ 1 ] ] . mDataByteSize ;
for ( unsigned int i = 0 ; i < stream_ . nUserChannels [ 1 ] ; i + + ) {
memcpy ( ( void * ) & outBuffer [ i * stream_ . bufferSize ] ,
inBufferList - > mBuffers [ handle - > iStream [ 1 ] + i ] . mData , bufferBytes ) ;
}
}
else { // read from multiple multi-channel streams
UInt32 streamChannels , channelsLeft , inJump , outJump , outOffset ;
Float32 * out , * in ;
bool outInterleaved = ( stream_ . userInterleaved ) ? true : false ;
UInt32 outChannels = stream_ . nUserChannels [ 1 ] ;
if ( stream_ . doConvertBuffer [ 1 ] ) {
outInterleaved = true ; // device buffer will always be interleaved for nStreams > 1 and not mono mode
outChannels = stream_ . nDeviceChannels [ 1 ] ;
}
if ( outInterleaved ) outOffset = 1 ;
else outOffset = stream_ . bufferSize ;
channelsLeft = outChannels ;
for ( unsigned int i = 0 ; i < handle - > nStreams [ 1 ] ; i + + ) {
out = outBuffer ;
in = ( Float32 * ) inBufferList - > mBuffers [ handle - > iStream [ 1 ] + i ] . mData ;
streamChannels = inBufferList - > mBuffers [ handle - > iStream [ 1 ] + i ] . mNumberChannels ;
inJump = 0 ;
// Account for possible channel offset in first stream
if ( i = = 0 & & stream_ . channelOffset [ 1 ] > 0 ) {
streamChannels - = stream_ . channelOffset [ 1 ] ;
inJump = stream_ . channelOffset [ 1 ] ;
in + = inJump ;
}
// Account for possible unread channels at end of the last stream
if ( streamChannels > channelsLeft ) {
inJump = streamChannels - channelsLeft ;
streamChannels = channelsLeft ;
}
// Determine output buffer offsets and skips
if ( outInterleaved ) {
outJump = outChannels ;
out + = outChannels - channelsLeft ;
}
else {
outJump = 1 ;
out + = ( outChannels - channelsLeft ) * outOffset ;
}
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( unsigned int j = 0 ; j < streamChannels ; j + + ) {
out [ j * outOffset ] = * in + + ;
}
out + = outJump ;
in + = inJump ;
}
channelsLeft - = streamChannels ;
}
}
if ( stream_ . doConvertBuffer [ 1 ] ) { // convert from our internal "device" buffer
convertBuffer ( stream_ . userBuffer [ 1 ] ,
stream_ . deviceBuffer ,
stream_ . convertInfo [ 1 ] ) ;
}
}
}
unlock :
//MUTEX_UNLOCK( &stream_.mutex );
RtApi : : tickStreamTime ( ) ;
return SUCCESS ;
}
const char * RtApiCore : : getErrorCode ( OSStatus code )
{
switch ( code ) {
case kAudioHardwareNotRunningError :
return " kAudioHardwareNotRunningError " ;
case kAudioHardwareUnspecifiedError :
return " kAudioHardwareUnspecifiedError " ;
case kAudioHardwareUnknownPropertyError :
return " kAudioHardwareUnknownPropertyError " ;
case kAudioHardwareBadPropertySizeError :
return " kAudioHardwareBadPropertySizeError " ;
case kAudioHardwareIllegalOperationError :
return " kAudioHardwareIllegalOperationError " ;
case kAudioHardwareBadObjectError :
return " kAudioHardwareBadObjectError " ;
case kAudioHardwareBadDeviceError :
return " kAudioHardwareBadDeviceError " ;
case kAudioHardwareBadStreamError :
return " kAudioHardwareBadStreamError " ;
case kAudioHardwareUnsupportedOperationError :
return " kAudioHardwareUnsupportedOperationError " ;
case kAudioDeviceUnsupportedFormatError :
return " kAudioDeviceUnsupportedFormatError " ;
case kAudioDevicePermissionsError :
return " kAudioDevicePermissionsError " ;
default :
return " CoreAudio unknown error " ;
}
}
//******************** End of __MACOSX_CORE__ *********************//
# endif
# if defined(__UNIX_JACK__)
// JACK is a low-latency audio server, originally written for the
// GNU/Linux operating system and now also ported to OS-X. It can
// connect a number of different applications to an audio device, as
// well as allowing them to share audio between themselves.
//
// When using JACK with RtAudio, "devices" refer to JACK clients that
// have ports connected to the server. The JACK server is typically
// started in a terminal as follows:
//
// .jackd -d alsa -d hw:0
//
// or through an interface program such as qjackctl. Many of the
// parameters normally set for a stream are fixed by the JACK server
// and can be specified when the JACK server is started. In
// particular,
//
// .jackd -d alsa -d hw:0 -r 44100 -p 512 -n 4
//
// specifies a sample rate of 44100 Hz, a buffer size of 512 sample
// frames, and number of buffers = 4. Once the server is running, it
// is not possible to override these values. If the values are not
// specified in the command-line, the JACK server uses default values.
//
// The JACK server does not have to be running when an instance of
// RtApiJack is created, though the function getDeviceCount() will
// report 0 devices found until JACK has been started. When no
// devices are available (i.e., the JACK server is not running), a
// stream cannot be opened.
# include <jack/jack.h>
# include <unistd.h>
# include <cstdio>
// A structure to hold various information related to the Jack API
// implementation.
struct JackHandle {
jack_client_t * client ;
jack_port_t * * ports [ 2 ] ;
std : : string deviceName [ 2 ] ;
bool xrun [ 2 ] ;
pthread_cond_t condition ;
int drainCounter ; // Tracks callback counts when draining
bool internalDrain ; // Indicates if stop is initiated from callback or not.
JackHandle ( )
: client ( 0 ) , drainCounter ( 0 ) , internalDrain ( false ) { ports [ 0 ] = 0 ; ports [ 1 ] = 0 ; xrun [ 0 ] = false ; xrun [ 1 ] = false ; }
} ;
static void jackSilentError ( const char * ) { } ;
RtApiJack : : RtApiJack ( )
{
// Nothing to do here.
# if !defined(__RTAUDIO_DEBUG__)
// Turn off Jack's internal error reporting.
jack_set_error_function ( & jackSilentError ) ;
# endif
}
RtApiJack : : ~ RtApiJack ( )
{
if ( stream_ . state ! = STREAM_CLOSED ) closeStream ( ) ;
}
unsigned int RtApiJack : : getDeviceCount ( void )
{
// See if we can become a jack client.
jack_options_t options = ( jack_options_t ) ( JackNoStartServer ) ; //JackNullOption;
jack_status_t * status = NULL ;
jack_client_t * client = jack_client_open ( " RtApiJackCount " , options , status ) ;
if ( client = = 0 ) return 0 ;
const char * * ports ;
std : : string port , previousPort ;
unsigned int nChannels = 0 , nDevices = 0 ;
ports = jack_get_ports ( client , NULL , NULL , 0 ) ;
if ( ports ) {
// Parse the port names up to the first colon (:).
size_t iColon = 0 ;
do {
port = ( char * ) ports [ nChannels ] ;
iColon = port . find ( " : " ) ;
if ( iColon ! = std : : string : : npos ) {
port = port . substr ( 0 , iColon + 1 ) ;
if ( port ! = previousPort ) {
nDevices + + ;
previousPort = port ;
}
}
} while ( ports [ + + nChannels ] ) ;
free ( ports ) ;
}
jack_client_close ( client ) ;
return nDevices ;
}
RtAudio : : DeviceInfo RtApiJack : : getDeviceInfo ( unsigned int device )
{
RtAudio : : DeviceInfo info ;
info . probed = false ;
jack_options_t options = ( jack_options_t ) ( JackNoStartServer ) ; //JackNullOption
jack_status_t * status = NULL ;
jack_client_t * client = jack_client_open ( " RtApiJackInfo " , options , status ) ;
if ( client = = 0 ) {
errorText_ = " RtApiJack::getDeviceInfo: Jack server not found or connection error! " ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
const char * * ports ;
std : : string port , previousPort ;
unsigned int nPorts = 0 , nDevices = 0 ;
ports = jack_get_ports ( client , NULL , NULL , 0 ) ;
if ( ports ) {
// Parse the port names up to the first colon (:).
size_t iColon = 0 ;
do {
port = ( char * ) ports [ nPorts ] ;
iColon = port . find ( " : " ) ;
if ( iColon ! = std : : string : : npos ) {
port = port . substr ( 0 , iColon ) ;
if ( port ! = previousPort ) {
if ( nDevices = = device ) info . name = port ;
nDevices + + ;
previousPort = port ;
}
}
} while ( ports [ + + nPorts ] ) ;
free ( ports ) ;
}
if ( device > = nDevices ) {
jack_client_close ( client ) ;
errorText_ = " RtApiJack::getDeviceInfo: device ID is invalid! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
// Get the current jack server sample rate.
info . sampleRates . clear ( ) ;
info . sampleRates . push_back ( jack_get_sample_rate ( client ) ) ;
// Count the available ports containing the client name as device
// channels. Jack "input ports" equal RtAudio output channels.
unsigned int nChannels = 0 ;
ports = jack_get_ports ( client , info . name . c_str ( ) , NULL , JackPortIsInput ) ;
if ( ports ) {
while ( ports [ nChannels ] ) nChannels + + ;
free ( ports ) ;
info . outputChannels = nChannels ;
}
// Jack "output ports" equal RtAudio input channels.
nChannels = 0 ;
ports = jack_get_ports ( client , info . name . c_str ( ) , NULL , JackPortIsOutput ) ;
if ( ports ) {
while ( ports [ nChannels ] ) nChannels + + ;
free ( ports ) ;
info . inputChannels = nChannels ;
}
if ( info . outputChannels = = 0 & & info . inputChannels = = 0 ) {
jack_client_close ( client ) ;
errorText_ = " RtApiJack::getDeviceInfo: error determining Jack input/output channels! " ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// If device opens for both playback and capture, we determine the channels.
if ( info . outputChannels > 0 & & info . inputChannels > 0 )
info . duplexChannels = ( info . outputChannels > info . inputChannels ) ? info . inputChannels : info . outputChannels ;
// Jack always uses 32-bit floats.
info . nativeFormats = RTAUDIO_FLOAT32 ;
// Jack doesn't provide default devices so we'll use the first available one.
if ( device = = 0 & & info . outputChannels > 0 )
info . isDefaultOutput = true ;
if ( device = = 0 & & info . inputChannels > 0 )
info . isDefaultInput = true ;
jack_client_close ( client ) ;
info . probed = true ;
return info ;
}
static int jackCallbackHandler ( jack_nframes_t nframes , void * infoPointer )
{
CallbackInfo * info = ( CallbackInfo * ) infoPointer ;
RtApiJack * object = ( RtApiJack * ) info - > object ;
if ( object - > callbackEvent ( ( unsigned long ) nframes ) = = false ) return 1 ;
return 0 ;
}
// This function will be called by a spawned thread when the Jack
// server signals that it is shutting down. It is necessary to handle
// it this way because the jackShutdown() function must return before
// the jack_deactivate() function (in closeStream()) will return.
static void * jackCloseStream ( void * ptr )
{
CallbackInfo * info = ( CallbackInfo * ) ptr ;
RtApiJack * object = ( RtApiJack * ) info - > object ;
object - > closeStream ( ) ;
pthread_exit ( NULL ) ;
}
static void jackShutdown ( void * infoPointer )
{
CallbackInfo * info = ( CallbackInfo * ) infoPointer ;
RtApiJack * object = ( RtApiJack * ) info - > object ;
// Check current stream state. If stopped, then we'll assume this
// was called as a result of a call to RtApiJack::stopStream (the
// deactivation of a client handle causes this function to be called).
// If not, we'll assume the Jack server is shutting down or some
// other problem occurred and we should close the stream.
if ( object - > isStreamRunning ( ) = = false ) return ;
ThreadHandle threadId ;
pthread_create ( & threadId , NULL , jackCloseStream , info ) ;
std : : cerr < < " \n RtApiJack: the Jack server is shutting down this client ... stream stopped and closed!! \n " < < std : : endl ;
}
static int jackXrun ( void * infoPointer )
{
JackHandle * handle = ( JackHandle * ) infoPointer ;
if ( handle - > ports [ 0 ] ) handle - > xrun [ 0 ] = true ;
if ( handle - > ports [ 1 ] ) handle - > xrun [ 1 ] = true ;
return 0 ;
}
bool RtApiJack : : probeDeviceOpen ( unsigned int device , StreamMode mode , unsigned int channels ,
unsigned int firstChannel , unsigned int sampleRate ,
RtAudioFormat format , unsigned int * bufferSize ,
RtAudio : : StreamOptions * options )
{
JackHandle * handle = ( JackHandle * ) stream_ . apiHandle ;
// Look for jack server and try to become a client (only do once per stream).
jack_client_t * client = 0 ;
if ( mode = = OUTPUT | | ( mode = = INPUT & & stream_ . mode ! = OUTPUT ) ) {
jack_options_t jackoptions = ( jack_options_t ) ( JackNoStartServer ) ; //JackNullOption;
jack_status_t * status = NULL ;
if ( options & & ! options - > streamName . empty ( ) )
client = jack_client_open ( options - > streamName . c_str ( ) , jackoptions , status ) ;
else
client = jack_client_open ( " RtApiJack " , jackoptions , status ) ;
if ( client = = 0 ) {
errorText_ = " RtApiJack::probeDeviceOpen: Jack server not found or connection error! " ;
error ( RtAudioError : : WARNING ) ;
return FAILURE ;
}
}
else {
// The handle must have been created on an earlier pass.
client = handle - > client ;
}
const char * * ports ;
std : : string port , previousPort , deviceName ;
unsigned int nPorts = 0 , nDevices = 0 ;
ports = jack_get_ports ( client , NULL , NULL , 0 ) ;
if ( ports ) {
// Parse the port names up to the first colon (:).
size_t iColon = 0 ;
do {
port = ( char * ) ports [ nPorts ] ;
iColon = port . find ( " : " ) ;
if ( iColon ! = std : : string : : npos ) {
port = port . substr ( 0 , iColon ) ;
if ( port ! = previousPort ) {
if ( nDevices = = device ) deviceName = port ;
nDevices + + ;
previousPort = port ;
}
}
} while ( ports [ + + nPorts ] ) ;
free ( ports ) ;
}
if ( device > = nDevices ) {
errorText_ = " RtApiJack::probeDeviceOpen: device ID is invalid! " ;
return FAILURE ;
}
// Count the available ports containing the client name as device
// channels. Jack "input ports" equal RtAudio output channels.
unsigned int nChannels = 0 ;
unsigned long flag = JackPortIsInput ;
if ( mode = = INPUT ) flag = JackPortIsOutput ;
ports = jack_get_ports ( client , deviceName . c_str ( ) , NULL , flag ) ;
if ( ports ) {
while ( ports [ nChannels ] ) nChannels + + ;
free ( ports ) ;
}
// Compare the jack ports for specified client to the requested number of channels.
if ( nChannels < ( channels + firstChannel ) ) {
errorStream_ < < " RtApiJack::probeDeviceOpen: requested number of channels ( " < < channels < < " ) + offset ( " < < firstChannel < < " ) not found for specified device ( " < < device < < " : " < < deviceName < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Check the jack server sample rate.
unsigned int jackRate = jack_get_sample_rate ( client ) ;
if ( sampleRate ! = jackRate ) {
jack_client_close ( client ) ;
errorStream_ < < " RtApiJack::probeDeviceOpen: the requested sample rate ( " < < sampleRate < < " ) is different than the JACK server rate ( " < < jackRate < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
stream_ . sampleRate = jackRate ;
// Get the latency of the JACK port.
ports = jack_get_ports ( client , deviceName . c_str ( ) , NULL , flag ) ;
if ( ports [ firstChannel ] ) {
// Added by Ge Wang
jack_latency_callback_mode_t cbmode = ( mode = = INPUT ? JackCaptureLatency : JackPlaybackLatency ) ;
// the range (usually the min and max are equal)
jack_latency_range_t latrange ; latrange . min = latrange . max = 0 ;
// get the latency range
jack_port_get_latency_range ( jack_port_by_name ( client , ports [ firstChannel ] ) , cbmode , & latrange ) ;
// be optimistic, use the min!
stream_ . latency [ mode ] = latrange . min ;
//stream_.latency[mode] = jack_port_get_latency( jack_port_by_name( client, ports[ firstChannel ] ) );
}
free ( ports ) ;
// The jack server always uses 32-bit floating-point data.
stream_ . deviceFormat [ mode ] = RTAUDIO_FLOAT32 ;
stream_ . userFormat = format ;
if ( options & & options - > flags & RTAUDIO_NONINTERLEAVED ) stream_ . userInterleaved = false ;
else stream_ . userInterleaved = true ;
// Jack always uses non-interleaved buffers.
stream_ . deviceInterleaved [ mode ] = false ;
// Jack always provides host byte-ordered data.
stream_ . doByteSwap [ mode ] = false ;
// Get the buffer size. The buffer size and number of buffers
// (periods) is set when the jack server is started.
stream_ . bufferSize = ( int ) jack_get_buffer_size ( client ) ;
* bufferSize = stream_ . bufferSize ;
stream_ . nDeviceChannels [ mode ] = channels ;
stream_ . nUserChannels [ mode ] = channels ;
// Set flags for buffer conversion.
stream_ . doConvertBuffer [ mode ] = false ;
if ( stream_ . userFormat ! = stream_ . deviceFormat [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . userInterleaved ! = stream_ . deviceInterleaved [ mode ] & &
stream_ . nUserChannels [ mode ] > 1 )
stream_ . doConvertBuffer [ mode ] = true ;
// Allocate our JackHandle structure for the stream.
if ( handle = = 0 ) {
try {
handle = new JackHandle ;
}
catch ( std : : bad_alloc & ) {
errorText_ = " RtApiJack::probeDeviceOpen: error allocating JackHandle memory. " ;
goto error ;
}
if ( pthread_cond_init ( & handle - > condition , NULL ) ) {
errorText_ = " RtApiJack::probeDeviceOpen: error initializing pthread condition variable. " ;
goto error ;
}
stream_ . apiHandle = ( void * ) handle ;
handle - > client = client ;
}
handle - > deviceName [ mode ] = deviceName ;
// Allocate necessary internal buffers.
unsigned long bufferBytes ;
bufferBytes = stream_ . nUserChannels [ mode ] * * bufferSize * formatBytes ( stream_ . userFormat ) ;
stream_ . userBuffer [ mode ] = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . userBuffer [ mode ] = = NULL ) {
errorText_ = " RtApiJack::probeDeviceOpen: error allocating user buffer memory. " ;
goto error ;
}
if ( stream_ . doConvertBuffer [ mode ] ) {
bool makeBuffer = true ;
if ( mode = = OUTPUT )
bufferBytes = stream_ . nDeviceChannels [ 0 ] * formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
else { // mode == INPUT
bufferBytes = stream_ . nDeviceChannels [ 1 ] * formatBytes ( stream_ . deviceFormat [ 1 ] ) ;
if ( stream_ . mode = = OUTPUT & & stream_ . deviceBuffer ) {
unsigned long bytesOut = stream_ . nDeviceChannels [ 0 ] * formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
if ( bufferBytes < bytesOut ) makeBuffer = false ;
}
}
if ( makeBuffer ) {
bufferBytes * = * bufferSize ;
if ( stream_ . deviceBuffer ) free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . deviceBuffer = = NULL ) {
errorText_ = " RtApiJack::probeDeviceOpen: error allocating device buffer memory. " ;
goto error ;
}
}
}
// Allocate memory for the Jack ports (channels) identifiers.
handle - > ports [ mode ] = ( jack_port_t * * ) malloc ( sizeof ( jack_port_t * ) * channels ) ;
if ( handle - > ports [ mode ] = = NULL ) {
errorText_ = " RtApiJack::probeDeviceOpen: error allocating port memory. " ;
goto error ;
}
stream_ . device [ mode ] = device ;
stream_ . channelOffset [ mode ] = firstChannel ;
stream_ . state = STREAM_STOPPED ;
stream_ . callbackInfo . object = ( void * ) this ;
if ( stream_ . mode = = OUTPUT & & mode = = INPUT )
// We had already set up the stream for output.
stream_ . mode = DUPLEX ;
else {
stream_ . mode = mode ;
jack_set_process_callback ( handle - > client , jackCallbackHandler , ( void * ) & stream_ . callbackInfo ) ;
jack_set_xrun_callback ( handle - > client , jackXrun , ( void * ) & handle ) ;
jack_on_shutdown ( handle - > client , jackShutdown , ( void * ) & stream_ . callbackInfo ) ;
}
// Register our ports.
char label [ 64 ] ;
if ( mode = = OUTPUT ) {
for ( unsigned int i = 0 ; i < stream_ . nUserChannels [ 0 ] ; i + + ) {
snprintf ( label , 64 , " outport %d " , i ) ;
handle - > ports [ 0 ] [ i ] = jack_port_register ( handle - > client , ( const char * ) label ,
JACK_DEFAULT_AUDIO_TYPE , JackPortIsOutput , 0 ) ;
}
}
else {
for ( unsigned int i = 0 ; i < stream_ . nUserChannels [ 1 ] ; i + + ) {
snprintf ( label , 64 , " inport %d " , i ) ;
handle - > ports [ 1 ] [ i ] = jack_port_register ( handle - > client , ( const char * ) label ,
JACK_DEFAULT_AUDIO_TYPE , JackPortIsInput , 0 ) ;
}
}
// Setup the buffer conversion information structure. We don't use
// buffers to do channel offsets, so we override that parameter
// here.
if ( stream_ . doConvertBuffer [ mode ] ) setConvertInfo ( mode , 0 ) ;
return SUCCESS ;
error :
if ( handle ) {
pthread_cond_destroy ( & handle - > condition ) ;
jack_client_close ( handle - > client ) ;
if ( handle - > ports [ 0 ] ) free ( handle - > ports [ 0 ] ) ;
if ( handle - > ports [ 1 ] ) free ( handle - > ports [ 1 ] ) ;
delete handle ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
return FAILURE ;
}
void RtApiJack : : closeStream ( void )
{
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiJack::closeStream(): no open stream to close! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
JackHandle * handle = ( JackHandle * ) stream_ . apiHandle ;
if ( handle ) {
if ( stream_ . state = = STREAM_RUNNING )
jack_deactivate ( handle - > client ) ;
jack_client_close ( handle - > client ) ;
}
if ( handle ) {
if ( handle - > ports [ 0 ] ) free ( handle - > ports [ 0 ] ) ;
if ( handle - > ports [ 1 ] ) free ( handle - > ports [ 1 ] ) ;
pthread_cond_destroy ( & handle - > condition ) ;
delete handle ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
stream_ . mode = UNINITIALIZED ;
stream_ . state = STREAM_CLOSED ;
}
void RtApiJack : : startStream ( void )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_RUNNING ) {
errorText_ = " RtApiJack::startStream(): the stream is already running! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
JackHandle * handle = ( JackHandle * ) stream_ . apiHandle ;
int result = jack_activate ( handle - > client ) ;
if ( result ) {
errorText_ = " RtApiJack::startStream(): unable to activate JACK client! " ;
goto unlock ;
}
const char * * ports ;
// Get the list of available ports.
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
result = 1 ;
ports = jack_get_ports ( handle - > client , handle - > deviceName [ 0 ] . c_str ( ) , NULL , JackPortIsInput ) ;
if ( ports = = NULL ) {
errorText_ = " RtApiJack::startStream(): error determining available JACK input ports! " ;
goto unlock ;
}
// Now make the port connections. Since RtAudio wasn't designed to
// allow the user to select particular channels of a device, we'll
// just open the first "nChannels" ports with offset.
for ( unsigned int i = 0 ; i < stream_ . nUserChannels [ 0 ] ; i + + ) {
result = 1 ;
if ( ports [ stream_ . channelOffset [ 0 ] + i ] )
result = jack_connect ( handle - > client , jack_port_name ( handle - > ports [ 0 ] [ i ] ) , ports [ stream_ . channelOffset [ 0 ] + i ] ) ;
if ( result ) {
free ( ports ) ;
errorText_ = " RtApiJack::startStream(): error connecting output ports! " ;
goto unlock ;
}
}
free ( ports ) ;
}
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) {
result = 1 ;
ports = jack_get_ports ( handle - > client , handle - > deviceName [ 1 ] . c_str ( ) , NULL , JackPortIsOutput ) ;
if ( ports = = NULL ) {
errorText_ = " RtApiJack::startStream(): error determining available JACK output ports! " ;
goto unlock ;
}
// Now make the port connections. See note above.
for ( unsigned int i = 0 ; i < stream_ . nUserChannels [ 1 ] ; i + + ) {
result = 1 ;
if ( ports [ stream_ . channelOffset [ 1 ] + i ] )
result = jack_connect ( handle - > client , ports [ stream_ . channelOffset [ 1 ] + i ] , jack_port_name ( handle - > ports [ 1 ] [ i ] ) ) ;
if ( result ) {
free ( ports ) ;
errorText_ = " RtApiJack::startStream(): error connecting input ports! " ;
goto unlock ;
}
}
free ( ports ) ;
}
handle - > drainCounter = 0 ;
handle - > internalDrain = false ;
stream_ . state = STREAM_RUNNING ;
unlock :
if ( result = = 0 ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiJack : : stopStream ( void )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiJack::stopStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
JackHandle * handle = ( JackHandle * ) stream_ . apiHandle ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
if ( handle - > drainCounter = = 0 ) {
handle - > drainCounter = 2 ;
pthread_cond_wait ( & handle - > condition , & stream_ . mutex ) ; // block until signaled
}
}
jack_deactivate ( handle - > client ) ;
stream_ . state = STREAM_STOPPED ;
}
void RtApiJack : : abortStream ( void )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiJack::abortStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
JackHandle * handle = ( JackHandle * ) stream_ . apiHandle ;
handle - > drainCounter = 2 ;
stopStream ( ) ;
}
// This function will be called by a spawned thread when the user
// callback function signals that the stream should be stopped or
// aborted. It is necessary to handle it this way because the
// callbackEvent() function must return before the jack_deactivate()
// function will return.
static void * jackStopStream ( void * ptr )
{
CallbackInfo * info = ( CallbackInfo * ) ptr ;
RtApiJack * object = ( RtApiJack * ) info - > object ;
object - > stopStream ( ) ;
pthread_exit ( NULL ) ;
}
bool RtApiJack : : callbackEvent ( unsigned long nframes )
{
if ( stream_ . state = = STREAM_STOPPED | | stream_ . state = = STREAM_STOPPING ) return SUCCESS ;
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiCore::callbackEvent(): the stream is closed ... this shouldn't happen! " ;
error ( RtAudioError : : WARNING ) ;
return FAILURE ;
}
if ( stream_ . bufferSize ! = nframes ) {
errorText_ = " RtApiCore::callbackEvent(): the JACK buffer size has changed ... cannot process! " ;
error ( RtAudioError : : WARNING ) ;
return FAILURE ;
}
CallbackInfo * info = ( CallbackInfo * ) & stream_ . callbackInfo ;
JackHandle * handle = ( JackHandle * ) stream_ . apiHandle ;
// Check if we were draining the stream and signal is finished.
if ( handle - > drainCounter > 3 ) {
ThreadHandle threadId ;
stream_ . state = STREAM_STOPPING ;
if ( handle - > internalDrain = = true )
pthread_create ( & threadId , NULL , jackStopStream , info ) ;
else
pthread_cond_signal ( & handle - > condition ) ;
return SUCCESS ;
}
// Invoke user callback first, to get fresh output data.
if ( handle - > drainCounter = = 0 ) {
RtAudioCallback callback = ( RtAudioCallback ) info - > callback ;
double streamTime = getStreamTime ( ) ;
RtAudioStreamStatus status = 0 ;
if ( stream_ . mode ! = INPUT & & handle - > xrun [ 0 ] = = true ) {
status | = RTAUDIO_OUTPUT_UNDERFLOW ;
handle - > xrun [ 0 ] = false ;
}
if ( stream_ . mode ! = OUTPUT & & handle - > xrun [ 1 ] = = true ) {
status | = RTAUDIO_INPUT_OVERFLOW ;
handle - > xrun [ 1 ] = false ;
}
int cbReturnValue = callback ( stream_ . userBuffer [ 0 ] , stream_ . userBuffer [ 1 ] ,
stream_ . bufferSize , streamTime , status , info - > userData ) ;
if ( cbReturnValue = = 2 ) {
stream_ . state = STREAM_STOPPING ;
handle - > drainCounter = 2 ;
ThreadHandle id ;
pthread_create ( & id , NULL , jackStopStream , info ) ;
return SUCCESS ;
}
else if ( cbReturnValue = = 1 ) {
handle - > drainCounter = 1 ;
handle - > internalDrain = true ;
}
}
jack_default_audio_sample_t * jackbuffer ;
unsigned long bufferBytes = nframes * sizeof ( jack_default_audio_sample_t ) ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
if ( handle - > drainCounter > 1 ) { // write zeros to the output stream
for ( unsigned int i = 0 ; i < stream_ . nDeviceChannels [ 0 ] ; i + + ) {
jackbuffer = ( jack_default_audio_sample_t * ) jack_port_get_buffer ( handle - > ports [ 0 ] [ i ] , ( jack_nframes_t ) nframes ) ;
memset ( jackbuffer , 0 , bufferBytes ) ;
}
}
else if ( stream_ . doConvertBuffer [ 0 ] ) {
convertBuffer ( stream_ . deviceBuffer , stream_ . userBuffer [ 0 ] , stream_ . convertInfo [ 0 ] ) ;
for ( unsigned int i = 0 ; i < stream_ . nDeviceChannels [ 0 ] ; i + + ) {
jackbuffer = ( jack_default_audio_sample_t * ) jack_port_get_buffer ( handle - > ports [ 0 ] [ i ] , ( jack_nframes_t ) nframes ) ;
memcpy ( jackbuffer , & stream_ . deviceBuffer [ i * bufferBytes ] , bufferBytes ) ;
}
}
else { // no buffer conversion
for ( unsigned int i = 0 ; i < stream_ . nUserChannels [ 0 ] ; i + + ) {
jackbuffer = ( jack_default_audio_sample_t * ) jack_port_get_buffer ( handle - > ports [ 0 ] [ i ] , ( jack_nframes_t ) nframes ) ;
memcpy ( jackbuffer , & stream_ . userBuffer [ 0 ] [ i * bufferBytes ] , bufferBytes ) ;
}
}
}
// Don't bother draining input
if ( handle - > drainCounter ) {
handle - > drainCounter + + ;
goto unlock ;
}
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) {
if ( stream_ . doConvertBuffer [ 1 ] ) {
for ( unsigned int i = 0 ; i < stream_ . nDeviceChannels [ 1 ] ; i + + ) {
jackbuffer = ( jack_default_audio_sample_t * ) jack_port_get_buffer ( handle - > ports [ 1 ] [ i ] , ( jack_nframes_t ) nframes ) ;
memcpy ( & stream_ . deviceBuffer [ i * bufferBytes ] , jackbuffer , bufferBytes ) ;
}
convertBuffer ( stream_ . userBuffer [ 1 ] , stream_ . deviceBuffer , stream_ . convertInfo [ 1 ] ) ;
}
else { // no buffer conversion
for ( unsigned int i = 0 ; i < stream_ . nUserChannels [ 1 ] ; i + + ) {
jackbuffer = ( jack_default_audio_sample_t * ) jack_port_get_buffer ( handle - > ports [ 1 ] [ i ] , ( jack_nframes_t ) nframes ) ;
memcpy ( & stream_ . userBuffer [ 1 ] [ i * bufferBytes ] , jackbuffer , bufferBytes ) ;
}
}
}
unlock :
RtApi : : tickStreamTime ( ) ;
return SUCCESS ;
}
//******************** End of __UNIX_JACK__ *********************//
# endif
# if defined(__WINDOWS_ASIO__) // ASIO API on Windows
// The ASIO API is designed around a callback scheme, so this
// implementation is similar to that used for OS-X CoreAudio and Linux
// Jack. The primary constraint with ASIO is that it only allows
// access to a single driver at a time. Thus, it is not possible to
// have more than one simultaneous RtAudio stream.
//
// This implementation also requires a number of external ASIO files
// and a few global variables. The ASIO callback scheme does not
// allow for the passing of user data, so we must create a global
// pointer to our callbackInfo structure.
//
// On unix systems, we make use of a pthread condition variable.
// Since there is no equivalent in Windows, I hacked something based
// on information found in
// http://www.cs.wustl.edu/~schmidt/win32-cv-1.html.
# include "asiosys.h"
# include "asio.h"
# include "iasiothiscallresolver.h"
# include "asiodrivers.h"
# include <cmath>
static AsioDrivers drivers ;
static ASIOCallbacks asioCallbacks ;
static ASIODriverInfo driverInfo ;
static CallbackInfo * asioCallbackInfo ;
static bool asioXRun ;
struct AsioHandle {
int drainCounter ; // Tracks callback counts when draining
bool internalDrain ; // Indicates if stop is initiated from callback or not.
ASIOBufferInfo * bufferInfos ;
HANDLE condition ;
AsioHandle ( )
: drainCounter ( 0 ) , internalDrain ( false ) , bufferInfos ( 0 ) { }
} ;
// Function declarations (definitions at end of section)
static const char * getAsioErrorString ( ASIOError result ) ;
static void sampleRateChanged ( ASIOSampleRate sRate ) ;
static long asioMessages ( long selector , long value , void * message , double * opt ) ;
RtApiAsio : : RtApiAsio ( )
{
// ASIO cannot run on a multi-threaded appartment. You can call
// CoInitialize beforehand, but it must be for appartment threading
// (in which case, CoInitilialize will return S_FALSE here).
coInitialized_ = false ;
HRESULT hr = CoInitialize ( NULL ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiAsio::ASIO requires a single-threaded appartment. Call CoInitializeEx(0,COINIT_APARTMENTTHREADED) " ;
error ( RtAudioError : : WARNING ) ;
}
coInitialized_ = true ;
drivers . removeCurrentDriver ( ) ;
driverInfo . asioVersion = 2 ;
// See note in DirectSound implementation about GetDesktopWindow().
driverInfo . sysRef = GetForegroundWindow ( ) ;
}
RtApiAsio : : ~ RtApiAsio ( )
{
if ( stream_ . state ! = STREAM_CLOSED ) closeStream ( ) ;
if ( coInitialized_ ) CoUninitialize ( ) ;
}
unsigned int RtApiAsio : : getDeviceCount ( void )
{
return ( unsigned int ) drivers . asioGetNumDev ( ) ;
}
RtAudio : : DeviceInfo RtApiAsio : : getDeviceInfo ( unsigned int device )
{
RtAudio : : DeviceInfo info ;
info . probed = false ;
// Get device ID
unsigned int nDevices = getDeviceCount ( ) ;
if ( nDevices = = 0 ) {
errorText_ = " RtApiAsio::getDeviceInfo: no devices found! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
if ( device > = nDevices ) {
errorText_ = " RtApiAsio::getDeviceInfo: device ID is invalid! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
// If a stream is already open, we cannot probe other devices. Thus, use the saved results.
if ( stream_ . state ! = STREAM_CLOSED ) {
if ( device > = devices_ . size ( ) ) {
errorText_ = " RtApiAsio::getDeviceInfo: device ID was not present before stream was opened. " ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
return devices_ [ device ] ;
}
char driverName [ 32 ] ;
ASIOError result = drivers . asioGetDriverName ( ( int ) device , driverName , 32 ) ;
if ( result ! = ASE_OK ) {
errorStream_ < < " RtApiAsio::getDeviceInfo: unable to get driver name ( " < < getAsioErrorString ( result ) < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
info . name = driverName ;
if ( ! drivers . loadDriver ( driverName ) ) {
errorStream_ < < " RtApiAsio::getDeviceInfo: unable to load driver ( " < < driverName < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
result = ASIOInit ( & driverInfo ) ;
if ( result ! = ASE_OK ) {
errorStream_ < < " RtApiAsio::getDeviceInfo: error ( " < < getAsioErrorString ( result ) < < " ) initializing driver ( " < < driverName < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Determine the device channel information.
long inputChannels , outputChannels ;
result = ASIOGetChannels ( & inputChannels , & outputChannels ) ;
if ( result ! = ASE_OK ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::getDeviceInfo: error ( " < < getAsioErrorString ( result ) < < " ) getting channel count ( " < < driverName < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
info . outputChannels = outputChannels ;
info . inputChannels = inputChannels ;
if ( info . outputChannels > 0 & & info . inputChannels > 0 )
info . duplexChannels = ( info . outputChannels > info . inputChannels ) ? info . inputChannels : info . outputChannels ;
// Determine the supported sample rates.
info . sampleRates . clear ( ) ;
for ( unsigned int i = 0 ; i < MAX_SAMPLE_RATES ; i + + ) {
result = ASIOCanSampleRate ( ( ASIOSampleRate ) SAMPLE_RATES [ i ] ) ;
if ( result = = ASE_OK )
info . sampleRates . push_back ( SAMPLE_RATES [ i ] ) ;
}
// Determine supported data types ... just check first channel and assume rest are the same.
ASIOChannelInfo channelInfo ;
channelInfo . channel = 0 ;
channelInfo . isInput = true ;
if ( info . inputChannels < = 0 ) channelInfo . isInput = false ;
result = ASIOGetChannelInfo ( & channelInfo ) ;
if ( result ! = ASE_OK ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::getDeviceInfo: error ( " < < getAsioErrorString ( result ) < < " ) getting driver channel info ( " < < driverName < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
info . nativeFormats = 0 ;
if ( channelInfo . type = = ASIOSTInt16MSB | | channelInfo . type = = ASIOSTInt16LSB )
info . nativeFormats | = RTAUDIO_SINT16 ;
else if ( channelInfo . type = = ASIOSTInt32MSB | | channelInfo . type = = ASIOSTInt32LSB )
info . nativeFormats | = RTAUDIO_SINT32 ;
else if ( channelInfo . type = = ASIOSTFloat32MSB | | channelInfo . type = = ASIOSTFloat32LSB )
info . nativeFormats | = RTAUDIO_FLOAT32 ;
else if ( channelInfo . type = = ASIOSTFloat64MSB | | channelInfo . type = = ASIOSTFloat64LSB )
info . nativeFormats | = RTAUDIO_FLOAT64 ;
else if ( channelInfo . type = = ASIOSTInt24MSB | | channelInfo . type = = ASIOSTInt24LSB )
info . nativeFormats | = RTAUDIO_SINT24 ;
if ( info . outputChannels > 0 )
if ( getDefaultOutputDevice ( ) = = device ) info . isDefaultOutput = true ;
if ( info . inputChannels > 0 )
if ( getDefaultInputDevice ( ) = = device ) info . isDefaultInput = true ;
info . probed = true ;
drivers . removeCurrentDriver ( ) ;
return info ;
}
static void bufferSwitch ( long index , ASIOBool /*processNow*/ )
{
RtApiAsio * object = ( RtApiAsio * ) asioCallbackInfo - > object ;
object - > callbackEvent ( index ) ;
}
void RtApiAsio : : saveDeviceInfo ( void )
{
devices_ . clear ( ) ;
unsigned int nDevices = getDeviceCount ( ) ;
devices_ . resize ( nDevices ) ;
for ( unsigned int i = 0 ; i < nDevices ; i + + )
devices_ [ i ] = getDeviceInfo ( i ) ;
}
bool RtApiAsio : : probeDeviceOpen ( unsigned int device , StreamMode mode , unsigned int channels ,
unsigned int firstChannel , unsigned int sampleRate ,
RtAudioFormat format , unsigned int * bufferSize ,
RtAudio : : StreamOptions * options )
{
// For ASIO, a duplex stream MUST use the same driver.
if ( mode = = INPUT & & stream_ . mode = = OUTPUT & & stream_ . device [ 0 ] ! = device ) {
errorText_ = " RtApiAsio::probeDeviceOpen: an ASIO duplex stream must use the same device for input and output! " ;
return FAILURE ;
}
char driverName [ 32 ] ;
ASIOError result = drivers . asioGetDriverName ( ( int ) device , driverName , 32 ) ;
if ( result ! = ASE_OK ) {
errorStream_ < < " RtApiAsio::probeDeviceOpen: unable to get driver name ( " < < getAsioErrorString ( result ) < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Only load the driver once for duplex stream.
if ( mode ! = INPUT | | stream_ . mode ! = OUTPUT ) {
// The getDeviceInfo() function will not work when a stream is open
// because ASIO does not allow multiple devices to run at the same
// time. Thus, we'll probe the system before opening a stream and
// save the results for use by getDeviceInfo().
this - > saveDeviceInfo ( ) ;
if ( ! drivers . loadDriver ( driverName ) ) {
errorStream_ < < " RtApiAsio::probeDeviceOpen: unable to load driver ( " < < driverName < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
result = ASIOInit ( & driverInfo ) ;
if ( result ! = ASE_OK ) {
errorStream_ < < " RtApiAsio::probeDeviceOpen: error ( " < < getAsioErrorString ( result ) < < " ) initializing driver ( " < < driverName < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
// Check the device channel count.
long inputChannels , outputChannels ;
result = ASIOGetChannels ( & inputChannels , & outputChannels ) ;
if ( result ! = ASE_OK ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::probeDeviceOpen: error ( " < < getAsioErrorString ( result ) < < " ) getting channel count ( " < < driverName < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
if ( ( mode = = OUTPUT & & ( channels + firstChannel ) > ( unsigned int ) outputChannels ) | |
( mode = = INPUT & & ( channels + firstChannel ) > ( unsigned int ) inputChannels ) ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::probeDeviceOpen: driver ( " < < driverName < < " ) does not support requested channel count ( " < < channels < < " ) + offset ( " < < firstChannel < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
stream_ . nDeviceChannels [ mode ] = channels ;
stream_ . nUserChannels [ mode ] = channels ;
stream_ . channelOffset [ mode ] = firstChannel ;
// Verify the sample rate is supported.
result = ASIOCanSampleRate ( ( ASIOSampleRate ) sampleRate ) ;
if ( result ! = ASE_OK ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::probeDeviceOpen: driver ( " < < driverName < < " ) does not support requested sample rate ( " < < sampleRate < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Get the current sample rate
ASIOSampleRate currentRate ;
result = ASIOGetSampleRate ( & currentRate ) ;
if ( result ! = ASE_OK ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::probeDeviceOpen: driver ( " < < driverName < < " ) error getting sample rate. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Set the sample rate only if necessary
if ( currentRate ! = sampleRate ) {
result = ASIOSetSampleRate ( ( ASIOSampleRate ) sampleRate ) ;
if ( result ! = ASE_OK ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::probeDeviceOpen: driver ( " < < driverName < < " ) error setting sample rate ( " < < sampleRate < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
// Determine the driver data type.
ASIOChannelInfo channelInfo ;
channelInfo . channel = 0 ;
if ( mode = = OUTPUT ) channelInfo . isInput = false ;
else channelInfo . isInput = true ;
result = ASIOGetChannelInfo ( & channelInfo ) ;
if ( result ! = ASE_OK ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::probeDeviceOpen: driver ( " < < driverName < < " ) error ( " < < getAsioErrorString ( result ) < < " ) getting data format. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Assuming WINDOWS host is always little-endian.
stream_ . doByteSwap [ mode ] = false ;
stream_ . userFormat = format ;
stream_ . deviceFormat [ mode ] = 0 ;
if ( channelInfo . type = = ASIOSTInt16MSB | | channelInfo . type = = ASIOSTInt16LSB ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT16 ;
if ( channelInfo . type = = ASIOSTInt16MSB ) stream_ . doByteSwap [ mode ] = true ;
}
else if ( channelInfo . type = = ASIOSTInt32MSB | | channelInfo . type = = ASIOSTInt32LSB ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT32 ;
if ( channelInfo . type = = ASIOSTInt32MSB ) stream_ . doByteSwap [ mode ] = true ;
}
else if ( channelInfo . type = = ASIOSTFloat32MSB | | channelInfo . type = = ASIOSTFloat32LSB ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_FLOAT32 ;
if ( channelInfo . type = = ASIOSTFloat32MSB ) stream_ . doByteSwap [ mode ] = true ;
}
else if ( channelInfo . type = = ASIOSTFloat64MSB | | channelInfo . type = = ASIOSTFloat64LSB ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_FLOAT64 ;
if ( channelInfo . type = = ASIOSTFloat64MSB ) stream_ . doByteSwap [ mode ] = true ;
}
else if ( channelInfo . type = = ASIOSTInt24MSB | | channelInfo . type = = ASIOSTInt24LSB ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT24 ;
if ( channelInfo . type = = ASIOSTInt24MSB ) stream_ . doByteSwap [ mode ] = true ;
}
if ( stream_ . deviceFormat [ mode ] = = 0 ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::probeDeviceOpen: driver ( " < < driverName < < " ) data format not supported by RtAudio. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Set the buffer size. For a duplex stream, this will end up
// setting the buffer size based on the input constraints, which
// should be ok.
long minSize , maxSize , preferSize , granularity ;
result = ASIOGetBufferSize ( & minSize , & maxSize , & preferSize , & granularity ) ;
if ( result ! = ASE_OK ) {
drivers . removeCurrentDriver ( ) ;
errorStream_ < < " RtApiAsio::probeDeviceOpen: driver ( " < < driverName < < " ) error ( " < < getAsioErrorString ( result ) < < " ) getting buffer size. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
if ( * bufferSize < ( unsigned int ) minSize ) * bufferSize = ( unsigned int ) minSize ;
else if ( * bufferSize > ( unsigned int ) maxSize ) * bufferSize = ( unsigned int ) maxSize ;
else if ( granularity = = - 1 ) {
// Make sure bufferSize is a power of two.
int log2_of_min_size = 0 ;
int log2_of_max_size = 0 ;
for ( unsigned int i = 0 ; i < sizeof ( long ) * 8 ; i + + ) {
if ( minSize & ( ( long ) 1 < < i ) ) log2_of_min_size = i ;
if ( maxSize & ( ( long ) 1 < < i ) ) log2_of_max_size = i ;
}
long min_delta = std : : abs ( ( long ) * bufferSize - ( ( long ) 1 < < log2_of_min_size ) ) ;
int min_delta_num = log2_of_min_size ;
for ( int i = log2_of_min_size + 1 ; i < = log2_of_max_size ; i + + ) {
long current_delta = std : : abs ( ( long ) * bufferSize - ( ( long ) 1 < < i ) ) ;
if ( current_delta < min_delta ) {
min_delta = current_delta ;
min_delta_num = i ;
}
}
* bufferSize = ( ( unsigned int ) 1 < < min_delta_num ) ;
if ( * bufferSize < ( unsigned int ) minSize ) * bufferSize = ( unsigned int ) minSize ;
else if ( * bufferSize > ( unsigned int ) maxSize ) * bufferSize = ( unsigned int ) maxSize ;
}
else if ( granularity ! = 0 ) {
// Set to an even multiple of granularity, rounding up.
* bufferSize = ( * bufferSize + granularity - 1 ) / granularity * granularity ;
}
if ( mode = = INPUT & & stream_ . mode = = OUTPUT & & stream_ . bufferSize ! = * bufferSize ) {
drivers . removeCurrentDriver ( ) ;
errorText_ = " RtApiAsio::probeDeviceOpen: input/output buffersize discrepancy! " ;
return FAILURE ;
}
stream_ . bufferSize = * bufferSize ;
stream_ . nBuffers = 2 ;
if ( options & & options - > flags & RTAUDIO_NONINTERLEAVED ) stream_ . userInterleaved = false ;
else stream_ . userInterleaved = true ;
// ASIO always uses non-interleaved buffers.
stream_ . deviceInterleaved [ mode ] = false ;
// Allocate, if necessary, our AsioHandle structure for the stream.
AsioHandle * handle = ( AsioHandle * ) stream_ . apiHandle ;
if ( handle = = 0 ) {
try {
handle = new AsioHandle ;
}
catch ( std : : bad_alloc & ) {
//if ( handle == NULL ) {
drivers . removeCurrentDriver ( ) ;
errorText_ = " RtApiAsio::probeDeviceOpen: error allocating AsioHandle memory. " ;
return FAILURE ;
}
handle - > bufferInfos = 0 ;
// Create a manual-reset event.
handle - > condition = CreateEvent ( NULL , // no security
TRUE , // manual-reset
FALSE , // non-signaled initially
NULL ) ; // unnamed
stream_ . apiHandle = ( void * ) handle ;
}
// Create the ASIO internal buffers. Since RtAudio sets up input
// and output separately, we'll have to dispose of previously
// created output buffers for a duplex stream.
long inputLatency , outputLatency ;
if ( mode = = INPUT & & stream_ . mode = = OUTPUT ) {
ASIODisposeBuffers ( ) ;
if ( handle - > bufferInfos ) free ( handle - > bufferInfos ) ;
}
// Allocate, initialize, and save the bufferInfos in our stream callbackInfo structure.
bool buffersAllocated = false ;
unsigned int i , nChannels = stream_ . nDeviceChannels [ 0 ] + stream_ . nDeviceChannels [ 1 ] ;
handle - > bufferInfos = ( ASIOBufferInfo * ) malloc ( nChannels * sizeof ( ASIOBufferInfo ) ) ;
if ( handle - > bufferInfos = = NULL ) {
errorStream_ < < " RtApiAsio::probeDeviceOpen: error allocating bufferInfo memory for driver ( " < < driverName < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto error ;
}
ASIOBufferInfo * infos ;
infos = handle - > bufferInfos ;
for ( i = 0 ; i < stream_ . nDeviceChannels [ 0 ] ; i + + , infos + + ) {
infos - > isInput = ASIOFalse ;
infos - > channelNum = i + stream_ . channelOffset [ 0 ] ;
infos - > buffers [ 0 ] = infos - > buffers [ 1 ] = 0 ;
}
for ( i = 0 ; i < stream_ . nDeviceChannels [ 1 ] ; i + + , infos + + ) {
infos - > isInput = ASIOTrue ;
infos - > channelNum = i + stream_ . channelOffset [ 1 ] ;
infos - > buffers [ 0 ] = infos - > buffers [ 1 ] = 0 ;
}
// Set up the ASIO callback structure and create the ASIO data buffers.
asioCallbacks . bufferSwitch = & bufferSwitch ;
asioCallbacks . sampleRateDidChange = & sampleRateChanged ;
asioCallbacks . asioMessage = & asioMessages ;
asioCallbacks . bufferSwitchTimeInfo = NULL ;
result = ASIOCreateBuffers ( handle - > bufferInfos , nChannels , stream_ . bufferSize , & asioCallbacks ) ;
if ( result ! = ASE_OK ) {
errorStream_ < < " RtApiAsio::probeDeviceOpen: driver ( " < < driverName < < " ) error ( " < < getAsioErrorString ( result ) < < " ) creating buffers. " ;
errorText_ = errorStream_ . str ( ) ;
goto error ;
}
buffersAllocated = true ;
// Set flags for buffer conversion.
stream_ . doConvertBuffer [ mode ] = false ;
if ( stream_ . userFormat ! = stream_ . deviceFormat [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . userInterleaved ! = stream_ . deviceInterleaved [ mode ] & &
stream_ . nUserChannels [ mode ] > 1 )
stream_ . doConvertBuffer [ mode ] = true ;
// Allocate necessary internal buffers
unsigned long bufferBytes ;
bufferBytes = stream_ . nUserChannels [ mode ] * * bufferSize * formatBytes ( stream_ . userFormat ) ;
stream_ . userBuffer [ mode ] = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . userBuffer [ mode ] = = NULL ) {
errorText_ = " RtApiAsio::probeDeviceOpen: error allocating user buffer memory. " ;
goto error ;
}
if ( stream_ . doConvertBuffer [ mode ] ) {
bool makeBuffer = true ;
bufferBytes = stream_ . nDeviceChannels [ mode ] * formatBytes ( stream_ . deviceFormat [ mode ] ) ;
if ( mode = = INPUT ) {
if ( stream_ . mode = = OUTPUT & & stream_ . deviceBuffer ) {
unsigned long bytesOut = stream_ . nDeviceChannels [ 0 ] * formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
if ( bufferBytes < = bytesOut ) makeBuffer = false ;
}
}
if ( makeBuffer ) {
bufferBytes * = * bufferSize ;
if ( stream_ . deviceBuffer ) free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . deviceBuffer = = NULL ) {
errorText_ = " RtApiAsio::probeDeviceOpen: error allocating device buffer memory. " ;
goto error ;
}
}
}
stream_ . sampleRate = sampleRate ;
stream_ . device [ mode ] = device ;
stream_ . state = STREAM_STOPPED ;
asioCallbackInfo = & stream_ . callbackInfo ;
stream_ . callbackInfo . object = ( void * ) this ;
if ( stream_ . mode = = OUTPUT & & mode = = INPUT )
// We had already set up an output stream.
stream_ . mode = DUPLEX ;
else
stream_ . mode = mode ;
// Determine device latencies
result = ASIOGetLatencies ( & inputLatency , & outputLatency ) ;
if ( result ! = ASE_OK ) {
errorStream_ < < " RtApiAsio::probeDeviceOpen: driver ( " < < driverName < < " ) error ( " < < getAsioErrorString ( result ) < < " ) getting latency. " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ; // warn but don't fail
}
else {
stream_ . latency [ 0 ] = outputLatency ;
stream_ . latency [ 1 ] = inputLatency ;
}
// Setup the buffer conversion information structure. We don't use
// buffers to do channel offsets, so we override that parameter
// here.
if ( stream_ . doConvertBuffer [ mode ] ) setConvertInfo ( mode , 0 ) ;
return SUCCESS ;
error :
if ( buffersAllocated )
ASIODisposeBuffers ( ) ;
drivers . removeCurrentDriver ( ) ;
if ( handle ) {
CloseHandle ( handle - > condition ) ;
if ( handle - > bufferInfos )
free ( handle - > bufferInfos ) ;
delete handle ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
return FAILURE ;
}
void RtApiAsio : : closeStream ( )
{
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiAsio::closeStream(): no open stream to close! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
if ( stream_ . state = = STREAM_RUNNING ) {
stream_ . state = STREAM_STOPPED ;
ASIOStop ( ) ;
}
ASIODisposeBuffers ( ) ;
drivers . removeCurrentDriver ( ) ;
AsioHandle * handle = ( AsioHandle * ) stream_ . apiHandle ;
if ( handle ) {
CloseHandle ( handle - > condition ) ;
if ( handle - > bufferInfos )
free ( handle - > bufferInfos ) ;
delete handle ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
stream_ . mode = UNINITIALIZED ;
stream_ . state = STREAM_CLOSED ;
}
bool stopThreadCalled = false ;
void RtApiAsio : : startStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_RUNNING ) {
errorText_ = " RtApiAsio::startStream(): the stream is already running! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
AsioHandle * handle = ( AsioHandle * ) stream_ . apiHandle ;
ASIOError result = ASIOStart ( ) ;
if ( result ! = ASE_OK ) {
errorStream_ < < " RtApiAsio::startStream: error ( " < < getAsioErrorString ( result ) < < " ) starting device. " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
handle - > drainCounter = 0 ;
handle - > internalDrain = false ;
ResetEvent ( handle - > condition ) ;
stream_ . state = STREAM_RUNNING ;
asioXRun = false ;
unlock :
stopThreadCalled = false ;
if ( result = = ASE_OK ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiAsio : : stopStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiAsio::stopStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
AsioHandle * handle = ( AsioHandle * ) stream_ . apiHandle ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
if ( handle - > drainCounter = = 0 ) {
handle - > drainCounter = 2 ;
WaitForSingleObject ( handle - > condition , INFINITE ) ; // block until signaled
}
}
stream_ . state = STREAM_STOPPED ;
ASIOError result = ASIOStop ( ) ;
if ( result ! = ASE_OK ) {
errorStream_ < < " RtApiAsio::stopStream: error ( " < < getAsioErrorString ( result ) < < " ) stopping device. " ;
errorText_ = errorStream_ . str ( ) ;
}
if ( result = = ASE_OK ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiAsio : : abortStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiAsio::abortStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
// The following lines were commented-out because some behavior was
// noted where the device buffers need to be zeroed to avoid
// continuing sound, even when the device buffers are completely
// disposed. So now, calling abort is the same as calling stop.
// AsioHandle *handle = (AsioHandle *) stream_.apiHandle;
// handle->drainCounter = 2;
stopStream ( ) ;
}
// This function will be called by a spawned thread when the user
// callback function signals that the stream should be stopped or
// aborted. It is necessary to handle it this way because the
// callbackEvent() function must return before the ASIOStop()
// function will return.
static unsigned __stdcall asioStopStream ( void * ptr )
{
CallbackInfo * info = ( CallbackInfo * ) ptr ;
RtApiAsio * object = ( RtApiAsio * ) info - > object ;
object - > stopStream ( ) ;
_endthreadex ( 0 ) ;
return 0 ;
}
bool RtApiAsio : : callbackEvent ( long bufferIndex )
{
if ( stream_ . state = = STREAM_STOPPED | | stream_ . state = = STREAM_STOPPING ) return SUCCESS ;
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiAsio::callbackEvent(): the stream is closed ... this shouldn't happen! " ;
error ( RtAudioError : : WARNING ) ;
return FAILURE ;
}
CallbackInfo * info = ( CallbackInfo * ) & stream_ . callbackInfo ;
AsioHandle * handle = ( AsioHandle * ) stream_ . apiHandle ;
// Check if we were draining the stream and signal if finished.
if ( handle - > drainCounter > 3 ) {
stream_ . state = STREAM_STOPPING ;
if ( handle - > internalDrain = = false )
SetEvent ( handle - > condition ) ;
else { // spawn a thread to stop the stream
unsigned threadId ;
stream_ . callbackInfo . thread = _beginthreadex ( NULL , 0 , & asioStopStream ,
& stream_ . callbackInfo , 0 , & threadId ) ;
}
return SUCCESS ;
}
// Invoke user callback to get fresh output data UNLESS we are
// draining stream.
if ( handle - > drainCounter = = 0 ) {
RtAudioCallback callback = ( RtAudioCallback ) info - > callback ;
double streamTime = getStreamTime ( ) ;
RtAudioStreamStatus status = 0 ;
if ( stream_ . mode ! = INPUT & & asioXRun = = true ) {
status | = RTAUDIO_OUTPUT_UNDERFLOW ;
asioXRun = false ;
}
if ( stream_ . mode ! = OUTPUT & & asioXRun = = true ) {
status | = RTAUDIO_INPUT_OVERFLOW ;
asioXRun = false ;
}
int cbReturnValue = callback ( stream_ . userBuffer [ 0 ] , stream_ . userBuffer [ 1 ] ,
stream_ . bufferSize , streamTime , status , info - > userData ) ;
if ( cbReturnValue = = 2 ) {
stream_ . state = STREAM_STOPPING ;
handle - > drainCounter = 2 ;
unsigned threadId ;
stream_ . callbackInfo . thread = _beginthreadex ( NULL , 0 , & asioStopStream ,
& stream_ . callbackInfo , 0 , & threadId ) ;
return SUCCESS ;
}
else if ( cbReturnValue = = 1 ) {
handle - > drainCounter = 1 ;
handle - > internalDrain = true ;
}
}
unsigned int nChannels , bufferBytes , i , j ;
nChannels = stream_ . nDeviceChannels [ 0 ] + stream_ . nDeviceChannels [ 1 ] ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
bufferBytes = stream_ . bufferSize * formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
if ( handle - > drainCounter > 1 ) { // write zeros to the output stream
for ( i = 0 , j = 0 ; i < nChannels ; i + + ) {
if ( handle - > bufferInfos [ i ] . isInput ! = ASIOTrue )
memset ( handle - > bufferInfos [ i ] . buffers [ bufferIndex ] , 0 , bufferBytes ) ;
}
}
else if ( stream_ . doConvertBuffer [ 0 ] ) {
convertBuffer ( stream_ . deviceBuffer , stream_ . userBuffer [ 0 ] , stream_ . convertInfo [ 0 ] ) ;
if ( stream_ . doByteSwap [ 0 ] )
byteSwapBuffer ( stream_ . deviceBuffer ,
stream_ . bufferSize * stream_ . nDeviceChannels [ 0 ] ,
stream_ . deviceFormat [ 0 ] ) ;
for ( i = 0 , j = 0 ; i < nChannels ; i + + ) {
if ( handle - > bufferInfos [ i ] . isInput ! = ASIOTrue )
memcpy ( handle - > bufferInfos [ i ] . buffers [ bufferIndex ] ,
& stream_ . deviceBuffer [ j + + * bufferBytes ] , bufferBytes ) ;
}
}
else {
if ( stream_ . doByteSwap [ 0 ] )
byteSwapBuffer ( stream_ . userBuffer [ 0 ] ,
stream_ . bufferSize * stream_ . nUserChannels [ 0 ] ,
stream_ . userFormat ) ;
for ( i = 0 , j = 0 ; i < nChannels ; i + + ) {
if ( handle - > bufferInfos [ i ] . isInput ! = ASIOTrue )
memcpy ( handle - > bufferInfos [ i ] . buffers [ bufferIndex ] ,
& stream_ . userBuffer [ 0 ] [ bufferBytes * j + + ] , bufferBytes ) ;
}
}
}
// Don't bother draining input
if ( handle - > drainCounter ) {
handle - > drainCounter + + ;
goto unlock ;
}
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) {
bufferBytes = stream_ . bufferSize * formatBytes ( stream_ . deviceFormat [ 1 ] ) ;
if ( stream_ . doConvertBuffer [ 1 ] ) {
// Always interleave ASIO input data.
for ( i = 0 , j = 0 ; i < nChannels ; i + + ) {
if ( handle - > bufferInfos [ i ] . isInput = = ASIOTrue )
memcpy ( & stream_ . deviceBuffer [ j + + * bufferBytes ] ,
handle - > bufferInfos [ i ] . buffers [ bufferIndex ] ,
bufferBytes ) ;
}
if ( stream_ . doByteSwap [ 1 ] )
byteSwapBuffer ( stream_ . deviceBuffer ,
stream_ . bufferSize * stream_ . nDeviceChannels [ 1 ] ,
stream_ . deviceFormat [ 1 ] ) ;
convertBuffer ( stream_ . userBuffer [ 1 ] , stream_ . deviceBuffer , stream_ . convertInfo [ 1 ] ) ;
}
else {
for ( i = 0 , j = 0 ; i < nChannels ; i + + ) {
if ( handle - > bufferInfos [ i ] . isInput = = ASIOTrue ) {
memcpy ( & stream_ . userBuffer [ 1 ] [ bufferBytes * j + + ] ,
handle - > bufferInfos [ i ] . buffers [ bufferIndex ] ,
bufferBytes ) ;
}
}
if ( stream_ . doByteSwap [ 1 ] )
byteSwapBuffer ( stream_ . userBuffer [ 1 ] ,
stream_ . bufferSize * stream_ . nUserChannels [ 1 ] ,
stream_ . userFormat ) ;
}
}
unlock :
// The following call was suggested by Malte Clasen. While the API
// documentation indicates it should not be required, some device
// drivers apparently do not function correctly without it.
ASIOOutputReady ( ) ;
RtApi : : tickStreamTime ( ) ;
return SUCCESS ;
}
static void sampleRateChanged ( ASIOSampleRate sRate )
{
// The ASIO documentation says that this usually only happens during
// external sync. Audio processing is not stopped by the driver,
// actual sample rate might not have even changed, maybe only the
// sample rate status of an AES/EBU or S/PDIF digital input at the
// audio device.
RtApi * object = ( RtApi * ) asioCallbackInfo - > object ;
try {
object - > stopStream ( ) ;
}
catch ( RtAudioError & exception ) {
std : : cerr < < " \n RtApiAsio: sampleRateChanged() error ( " < < exception . getMessage ( ) < < " )! \n " < < std : : endl ;
return ;
}
std : : cerr < < " \n RtApiAsio: driver reports sample rate changed to " < < sRate < < " ... stream stopped!!! \n " < < std : : endl ;
}
static long asioMessages ( long selector , long value , void * /*message*/ , double * /*opt*/ )
{
long ret = 0 ;
switch ( selector ) {
case kAsioSelectorSupported :
if ( value = = kAsioResetRequest
| | value = = kAsioEngineVersion
| | value = = kAsioResyncRequest
| | value = = kAsioLatenciesChanged
// The following three were added for ASIO 2.0, you don't
// necessarily have to support them.
| | value = = kAsioSupportsTimeInfo
| | value = = kAsioSupportsTimeCode
| | value = = kAsioSupportsInputMonitor )
ret = 1L ;
break ;
case kAsioResetRequest :
// Defer the task and perform the reset of the driver during the
// next "safe" situation. You cannot reset the driver right now,
// as this code is called from the driver. Reset the driver is
// done by completely destruct is. I.e. ASIOStop(),
// ASIODisposeBuffers(), Destruction Afterwards you initialize the
// driver again.
std : : cerr < < " \n RtApiAsio: driver reset requested!!! " < < std : : endl ;
ret = 1L ;
break ;
case kAsioResyncRequest :
// This informs the application that the driver encountered some
// non-fatal data loss. It is used for synchronization purposes
// of different media. Added mainly to work around the Win16Mutex
// problems in Windows 95/98 with the Windows Multimedia system,
// which could lose data because the Mutex was held too long by
// another thread. However a driver can issue it in other
// situations, too.
// std::cerr << "\nRtApiAsio: driver resync requested!!!" << std::endl;
asioXRun = true ;
ret = 1L ;
break ;
case kAsioLatenciesChanged :
// This will inform the host application that the drivers were
// latencies changed. Beware, it this does not mean that the
// buffer sizes have changed! You might need to update internal
// delay data.
std : : cerr < < " \n RtApiAsio: driver latency may have changed!!! " < < std : : endl ;
ret = 1L ;
break ;
case kAsioEngineVersion :
// Return the supported ASIO version of the host application. If
// a host application does not implement this selector, ASIO 1.0
// is assumed by the driver.
ret = 2L ;
break ;
case kAsioSupportsTimeInfo :
// Informs the driver whether the
// asioCallbacks.bufferSwitchTimeInfo() callback is supported.
// For compatibility with ASIO 1.0 drivers the host application
// should always support the "old" bufferSwitch method, too.
ret = 0 ;
break ;
case kAsioSupportsTimeCode :
// Informs the driver whether application is interested in time
// code info. If an application does not need to know about time
// code, the driver has less work to do.
ret = 0 ;
break ;
}
return ret ;
}
static const char * getAsioErrorString ( ASIOError result )
{
struct Messages
{
ASIOError value ;
const char * message ;
} ;
static const Messages m [ ] =
{
{ ASE_NotPresent , " Hardware input or output is not present or available. " } ,
{ ASE_HWMalfunction , " Hardware is malfunctioning. " } ,
{ ASE_InvalidParameter , " Invalid input parameter. " } ,
{ ASE_InvalidMode , " Invalid mode. " } ,
{ ASE_SPNotAdvancing , " Sample position not advancing. " } ,
{ ASE_NoClock , " Sample clock or rate cannot be determined or is not present. " } ,
{ ASE_NoMemory , " Not enough memory to complete the request. " }
} ;
for ( unsigned int i = 0 ; i < sizeof ( m ) / sizeof ( m [ 0 ] ) ; + + i )
if ( m [ i ] . value = = result ) return m [ i ] . message ;
return " Unknown error. " ;
}
//******************** End of __WINDOWS_ASIO__ *********************//
# endif
# if defined(__WINDOWS_WASAPI__) // Windows WASAPI API
// Authored by Marcus Tomlinson <themarcustomlinson@gmail.com>, April 2014
// - Introduces support for the Windows WASAPI API
// - Aims to deliver bit streams to and from hardware at the lowest possible latency, via the absolute minimum buffer sizes required
// - Provides flexible stream configuration to an otherwise strict and inflexible WASAPI interface
// - Includes automatic internal conversion of sample rate and buffer size between hardware and the user
# ifndef INITGUID
# define INITGUID
# endif
# include <audioclient.h>
# include <avrt.h>
# include <mmdeviceapi.h>
# include <functiondiscoverykeys_devpkey.h>
//=============================================================================
# define SAFE_RELEASE( objectPtr )\
if ( objectPtr ) \
{ \
objectPtr - > Release ( ) ; \
objectPtr = NULL ; \
}
typedef HANDLE ( __stdcall * TAvSetMmThreadCharacteristicsPtr ) ( LPCWSTR TaskName , LPDWORD TaskIndex ) ;
//-----------------------------------------------------------------------------
// WASAPI dictates stream sample rate, format, channel count, and in some cases, buffer size.
// Therefore we must perform all necessary conversions to user buffers in order to satisfy these
// requirements. WasapiBuffer ring buffers are used between HwIn->UserIn and UserOut->HwOut to
// provide intermediate storage for read / write synchronization.
class WasapiBuffer
{
public :
WasapiBuffer ( )
: buffer_ ( NULL ) ,
bufferSize_ ( 0 ) ,
inIndex_ ( 0 ) ,
outIndex_ ( 0 ) { }
~ WasapiBuffer ( ) {
delete buffer_ ;
}
// sets the length of the internal ring buffer
void setBufferSize ( unsigned int bufferSize , unsigned int formatBytes ) {
delete buffer_ ;
buffer_ = ( char * ) calloc ( bufferSize , formatBytes ) ;
bufferSize_ = bufferSize ;
inIndex_ = 0 ;
outIndex_ = 0 ;
}
// attempt to push a buffer into the ring buffer at the current "in" index
bool pushBuffer ( char * buffer , unsigned int bufferSize , RtAudioFormat format )
{
if ( ! buffer | | // incoming buffer is NULL
bufferSize = = 0 | | // incoming buffer has no data
bufferSize > bufferSize_ ) // incoming buffer too large
{
return false ;
}
unsigned int relOutIndex = outIndex_ ;
unsigned int inIndexEnd = inIndex_ + bufferSize ;
if ( relOutIndex < inIndex_ & & inIndexEnd > = bufferSize_ ) {
relOutIndex + = bufferSize_ ;
}
// "in" index can end on the "out" index but cannot begin at it
if ( inIndex_ < = relOutIndex & & inIndexEnd > relOutIndex ) {
return false ; // not enough space between "in" index and "out" index
}
// copy buffer from external to internal
int fromZeroSize = inIndex_ + bufferSize - bufferSize_ ;
fromZeroSize = fromZeroSize < 0 ? 0 : fromZeroSize ;
int fromInSize = bufferSize - fromZeroSize ;
switch ( format )
{
case RTAUDIO_SINT8 :
memcpy ( & ( ( char * ) buffer_ ) [ inIndex_ ] , buffer , fromInSize * sizeof ( char ) ) ;
memcpy ( buffer_ , & ( ( char * ) buffer ) [ fromInSize ] , fromZeroSize * sizeof ( char ) ) ;
break ;
case RTAUDIO_SINT16 :
memcpy ( & ( ( short * ) buffer_ ) [ inIndex_ ] , buffer , fromInSize * sizeof ( short ) ) ;
memcpy ( buffer_ , & ( ( short * ) buffer ) [ fromInSize ] , fromZeroSize * sizeof ( short ) ) ;
break ;
case RTAUDIO_SINT24 :
memcpy ( & ( ( S24 * ) buffer_ ) [ inIndex_ ] , buffer , fromInSize * sizeof ( S24 ) ) ;
memcpy ( buffer_ , & ( ( S24 * ) buffer ) [ fromInSize ] , fromZeroSize * sizeof ( S24 ) ) ;
break ;
case RTAUDIO_SINT32 :
memcpy ( & ( ( int * ) buffer_ ) [ inIndex_ ] , buffer , fromInSize * sizeof ( int ) ) ;
memcpy ( buffer_ , & ( ( int * ) buffer ) [ fromInSize ] , fromZeroSize * sizeof ( int ) ) ;
break ;
case RTAUDIO_FLOAT32 :
memcpy ( & ( ( float * ) buffer_ ) [ inIndex_ ] , buffer , fromInSize * sizeof ( float ) ) ;
memcpy ( buffer_ , & ( ( float * ) buffer ) [ fromInSize ] , fromZeroSize * sizeof ( float ) ) ;
break ;
case RTAUDIO_FLOAT64 :
memcpy ( & ( ( double * ) buffer_ ) [ inIndex_ ] , buffer , fromInSize * sizeof ( double ) ) ;
memcpy ( buffer_ , & ( ( double * ) buffer ) [ fromInSize ] , fromZeroSize * sizeof ( double ) ) ;
break ;
}
// update "in" index
inIndex_ + = bufferSize ;
inIndex_ % = bufferSize_ ;
return true ;
}
// attempt to pull a buffer from the ring buffer from the current "out" index
bool pullBuffer ( char * buffer , unsigned int bufferSize , RtAudioFormat format )
{
if ( ! buffer | | // incoming buffer is NULL
bufferSize = = 0 | | // incoming buffer has no data
bufferSize > bufferSize_ ) // incoming buffer too large
{
return false ;
}
unsigned int relInIndex = inIndex_ ;
unsigned int outIndexEnd = outIndex_ + bufferSize ;
if ( relInIndex < outIndex_ & & outIndexEnd > = bufferSize_ ) {
relInIndex + = bufferSize_ ;
}
// "out" index can begin at and end on the "in" index
if ( outIndex_ < relInIndex & & outIndexEnd > relInIndex ) {
return false ; // not enough space between "out" index and "in" index
}
// copy buffer from internal to external
int fromZeroSize = outIndex_ + bufferSize - bufferSize_ ;
fromZeroSize = fromZeroSize < 0 ? 0 : fromZeroSize ;
int fromOutSize = bufferSize - fromZeroSize ;
switch ( format )
{
case RTAUDIO_SINT8 :
memcpy ( buffer , & ( ( char * ) buffer_ ) [ outIndex_ ] , fromOutSize * sizeof ( char ) ) ;
memcpy ( & ( ( char * ) buffer ) [ fromOutSize ] , buffer_ , fromZeroSize * sizeof ( char ) ) ;
break ;
case RTAUDIO_SINT16 :
memcpy ( buffer , & ( ( short * ) buffer_ ) [ outIndex_ ] , fromOutSize * sizeof ( short ) ) ;
memcpy ( & ( ( short * ) buffer ) [ fromOutSize ] , buffer_ , fromZeroSize * sizeof ( short ) ) ;
break ;
case RTAUDIO_SINT24 :
memcpy ( buffer , & ( ( S24 * ) buffer_ ) [ outIndex_ ] , fromOutSize * sizeof ( S24 ) ) ;
memcpy ( & ( ( S24 * ) buffer ) [ fromOutSize ] , buffer_ , fromZeroSize * sizeof ( S24 ) ) ;
break ;
case RTAUDIO_SINT32 :
memcpy ( buffer , & ( ( int * ) buffer_ ) [ outIndex_ ] , fromOutSize * sizeof ( int ) ) ;
memcpy ( & ( ( int * ) buffer ) [ fromOutSize ] , buffer_ , fromZeroSize * sizeof ( int ) ) ;
break ;
case RTAUDIO_FLOAT32 :
memcpy ( buffer , & ( ( float * ) buffer_ ) [ outIndex_ ] , fromOutSize * sizeof ( float ) ) ;
memcpy ( & ( ( float * ) buffer ) [ fromOutSize ] , buffer_ , fromZeroSize * sizeof ( float ) ) ;
break ;
case RTAUDIO_FLOAT64 :
memcpy ( buffer , & ( ( double * ) buffer_ ) [ outIndex_ ] , fromOutSize * sizeof ( double ) ) ;
memcpy ( & ( ( double * ) buffer ) [ fromOutSize ] , buffer_ , fromZeroSize * sizeof ( double ) ) ;
break ;
}
// update "out" index
outIndex_ + = bufferSize ;
outIndex_ % = bufferSize_ ;
return true ;
}
private :
char * buffer_ ;
unsigned int bufferSize_ ;
unsigned int inIndex_ ;
unsigned int outIndex_ ;
} ;
//-----------------------------------------------------------------------------
// In order to satisfy WASAPI's buffer requirements, we need a means of converting sample rate
// between HW and the user. The convertBufferWasapi function is used to perform this conversion
// between HwIn->UserIn and UserOut->HwOut during the stream callback loop.
// This sample rate converter favors speed over quality, and works best with conversions between
// one rate and its multiple.
void convertBufferWasapi ( char * outBuffer ,
const char * inBuffer ,
const unsigned int & channelCount ,
const unsigned int & inSampleRate ,
const unsigned int & outSampleRate ,
const unsigned int & inSampleCount ,
unsigned int & outSampleCount ,
const RtAudioFormat & format )
{
// calculate the new outSampleCount and relative sampleStep
float sampleRatio = ( float ) outSampleRate / inSampleRate ;
float sampleStep = 1.0f / sampleRatio ;
float inSampleFraction = 0.0f ;
outSampleCount = ( unsigned int ) ( inSampleCount * sampleRatio ) ;
// frame-by-frame, copy each relative input sample into it's corresponding output sample
for ( unsigned int outSample = 0 ; outSample < outSampleCount ; outSample + + )
{
unsigned int inSample = ( unsigned int ) inSampleFraction ;
switch ( format )
{
case RTAUDIO_SINT8 :
memcpy ( & ( ( char * ) outBuffer ) [ outSample * channelCount ] , & ( ( char * ) inBuffer ) [ inSample * channelCount ] , channelCount * sizeof ( char ) ) ;
break ;
case RTAUDIO_SINT16 :
memcpy ( & ( ( short * ) outBuffer ) [ outSample * channelCount ] , & ( ( short * ) inBuffer ) [ inSample * channelCount ] , channelCount * sizeof ( short ) ) ;
break ;
case RTAUDIO_SINT24 :
memcpy ( & ( ( S24 * ) outBuffer ) [ outSample * channelCount ] , & ( ( S24 * ) inBuffer ) [ inSample * channelCount ] , channelCount * sizeof ( S24 ) ) ;
break ;
case RTAUDIO_SINT32 :
memcpy ( & ( ( int * ) outBuffer ) [ outSample * channelCount ] , & ( ( int * ) inBuffer ) [ inSample * channelCount ] , channelCount * sizeof ( int ) ) ;
break ;
case RTAUDIO_FLOAT32 :
memcpy ( & ( ( float * ) outBuffer ) [ outSample * channelCount ] , & ( ( float * ) inBuffer ) [ inSample * channelCount ] , channelCount * sizeof ( float ) ) ;
break ;
case RTAUDIO_FLOAT64 :
memcpy ( & ( ( double * ) outBuffer ) [ outSample * channelCount ] , & ( ( double * ) inBuffer ) [ inSample * channelCount ] , channelCount * sizeof ( double ) ) ;
break ;
}
// jump to next in sample
inSampleFraction + = sampleStep ;
}
}
//-----------------------------------------------------------------------------
// A structure to hold various information related to the WASAPI implementation.
struct WasapiHandle
{
IAudioClient * captureAudioClient ;
IAudioClient * renderAudioClient ;
IAudioCaptureClient * captureClient ;
IAudioRenderClient * renderClient ;
HANDLE captureEvent ;
HANDLE renderEvent ;
WasapiHandle ( )
: captureAudioClient ( NULL ) ,
renderAudioClient ( NULL ) ,
captureClient ( NULL ) ,
renderClient ( NULL ) ,
captureEvent ( NULL ) ,
renderEvent ( NULL ) { }
} ;
//=============================================================================
RtApiWasapi : : RtApiWasapi ( )
: coInitialized_ ( false ) , deviceEnumerator_ ( NULL )
{
// WASAPI can run either apartment or multi-threaded
HRESULT hr = CoInitialize ( NULL ) ;
if ( ! FAILED ( hr ) )
coInitialized_ = true ;
// Instantiate device enumerator
hr = CoCreateInstance ( __uuidof ( MMDeviceEnumerator ) , NULL ,
CLSCTX_ALL , __uuidof ( IMMDeviceEnumerator ) ,
( void * * ) & deviceEnumerator_ ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::RtApiWasapi: Unable to instantiate device enumerator " ;
error ( RtAudioError : : DRIVER_ERROR ) ;
}
}
//-----------------------------------------------------------------------------
RtApiWasapi : : ~ RtApiWasapi ( )
{
if ( stream_ . state ! = STREAM_CLOSED )
closeStream ( ) ;
SAFE_RELEASE ( deviceEnumerator_ ) ;
// If this object previously called CoInitialize()
if ( coInitialized_ )
CoUninitialize ( ) ;
}
//=============================================================================
unsigned int RtApiWasapi : : getDeviceCount ( void )
{
unsigned int captureDeviceCount = 0 ;
unsigned int renderDeviceCount = 0 ;
IMMDeviceCollection * captureDevices = NULL ;
IMMDeviceCollection * renderDevices = NULL ;
// Count capture devices
errorText_ . clear ( ) ;
HRESULT hr = deviceEnumerator_ - > EnumAudioEndpoints ( eCapture , DEVICE_STATE_ACTIVE , & captureDevices ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceCount: Unable to retrieve capture device collection. " ;
goto Exit ;
}
hr = captureDevices - > GetCount ( & captureDeviceCount ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceCount: Unable to retrieve capture device count. " ;
goto Exit ;
}
// Count render devices
hr = deviceEnumerator_ - > EnumAudioEndpoints ( eRender , DEVICE_STATE_ACTIVE , & renderDevices ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceCount: Unable to retrieve render device collection. " ;
goto Exit ;
}
hr = renderDevices - > GetCount ( & renderDeviceCount ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceCount: Unable to retrieve render device count. " ;
goto Exit ;
}
Exit :
// release all references
SAFE_RELEASE ( captureDevices ) ;
SAFE_RELEASE ( renderDevices ) ;
if ( errorText_ . empty ( ) )
return captureDeviceCount + renderDeviceCount ;
error ( RtAudioError : : DRIVER_ERROR ) ;
return 0 ;
}
//-----------------------------------------------------------------------------
RtAudio : : DeviceInfo RtApiWasapi : : getDeviceInfo ( unsigned int device )
{
RtAudio : : DeviceInfo info ;
unsigned int captureDeviceCount = 0 ;
unsigned int renderDeviceCount = 0 ;
std : : wstring deviceName ;
std : : string defaultDeviceName ;
bool isCaptureDevice = false ;
PROPVARIANT deviceNameProp ;
PROPVARIANT defaultDeviceNameProp ;
IMMDeviceCollection * captureDevices = NULL ;
IMMDeviceCollection * renderDevices = NULL ;
IMMDevice * devicePtr = NULL ;
IMMDevice * defaultDevicePtr = NULL ;
IAudioClient * audioClient = NULL ;
IPropertyStore * devicePropStore = NULL ;
IPropertyStore * defaultDevicePropStore = NULL ;
WAVEFORMATEX * deviceFormat = NULL ;
WAVEFORMATEX * closestMatchFormat = NULL ;
// probed
info . probed = false ;
// Count capture devices
errorText_ . clear ( ) ;
RtAudioError : : Type errorType = RtAudioError : : DRIVER_ERROR ;
HRESULT hr = deviceEnumerator_ - > EnumAudioEndpoints ( eCapture , DEVICE_STATE_ACTIVE , & captureDevices ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve capture device collection. " ;
goto Exit ;
}
hr = captureDevices - > GetCount ( & captureDeviceCount ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve capture device count. " ;
goto Exit ;
}
// Count render devices
hr = deviceEnumerator_ - > EnumAudioEndpoints ( eRender , DEVICE_STATE_ACTIVE , & renderDevices ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve render device collection. " ;
goto Exit ;
}
hr = renderDevices - > GetCount ( & renderDeviceCount ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve render device count. " ;
goto Exit ;
}
// validate device index
if ( device > = captureDeviceCount + renderDeviceCount ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Invalid device index. " ;
errorType = RtAudioError : : INVALID_USE ;
goto Exit ;
}
// determine whether index falls within capture or render devices
if ( device > = renderDeviceCount ) {
hr = captureDevices - > Item ( device - renderDeviceCount , & devicePtr ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve capture device handle. " ;
goto Exit ;
}
isCaptureDevice = true ;
}
else {
hr = renderDevices - > Item ( device , & devicePtr ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve render device handle. " ;
goto Exit ;
}
isCaptureDevice = false ;
}
// get default device name
if ( isCaptureDevice ) {
hr = deviceEnumerator_ - > GetDefaultAudioEndpoint ( eCapture , eConsole , & defaultDevicePtr ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve default capture device handle. " ;
goto Exit ;
}
}
else {
hr = deviceEnumerator_ - > GetDefaultAudioEndpoint ( eRender , eConsole , & defaultDevicePtr ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve default render device handle. " ;
goto Exit ;
}
}
hr = defaultDevicePtr - > OpenPropertyStore ( STGM_READ , & defaultDevicePropStore ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to open default device property store. " ;
goto Exit ;
}
PropVariantInit ( & defaultDeviceNameProp ) ;
hr = defaultDevicePropStore - > GetValue ( PKEY_Device_FriendlyName , & defaultDeviceNameProp ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve default device property: PKEY_Device_FriendlyName. " ;
goto Exit ;
}
deviceName = defaultDeviceNameProp . pwszVal ;
defaultDeviceName = std : : string ( deviceName . begin ( ) , deviceName . end ( ) ) ;
// name
hr = devicePtr - > OpenPropertyStore ( STGM_READ , & devicePropStore ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to open device property store. " ;
goto Exit ;
}
PropVariantInit ( & deviceNameProp ) ;
hr = devicePropStore - > GetValue ( PKEY_Device_FriendlyName , & deviceNameProp ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve device property: PKEY_Device_FriendlyName. " ;
goto Exit ;
}
deviceName = deviceNameProp . pwszVal ;
info . name = std : : string ( deviceName . begin ( ) , deviceName . end ( ) ) ;
// is default
if ( isCaptureDevice ) {
info . isDefaultInput = info . name = = defaultDeviceName ;
info . isDefaultOutput = false ;
}
else {
info . isDefaultInput = false ;
info . isDefaultOutput = info . name = = defaultDeviceName ;
}
// channel count
hr = devicePtr - > Activate ( __uuidof ( IAudioClient ) , CLSCTX_ALL , NULL , ( void * * ) & audioClient ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve device audio client. " ;
goto Exit ;
}
hr = audioClient - > GetMixFormat ( & deviceFormat ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::getDeviceInfo: Unable to retrieve device mix format. " ;
goto Exit ;
}
if ( isCaptureDevice ) {
info . inputChannels = deviceFormat - > nChannels ;
info . outputChannels = 0 ;
info . duplexChannels = 0 ;
}
else {
info . inputChannels = 0 ;
info . outputChannels = deviceFormat - > nChannels ;
info . duplexChannels = 0 ;
}
// sample rates
info . sampleRates . clear ( ) ;
// allow support for all sample rates as we have a built-in sample rate converter
for ( unsigned int i = 0 ; i < MAX_SAMPLE_RATES ; i + + ) {
info . sampleRates . push_back ( SAMPLE_RATES [ i ] ) ;
}
// native format
info . nativeFormats = 0 ;
if ( deviceFormat - > wFormatTag = = WAVE_FORMAT_IEEE_FLOAT | |
( deviceFormat - > wFormatTag = = WAVE_FORMAT_EXTENSIBLE & &
( ( WAVEFORMATEXTENSIBLE * ) deviceFormat ) - > SubFormat = = KSDATAFORMAT_SUBTYPE_IEEE_FLOAT ) )
{
if ( deviceFormat - > wBitsPerSample = = 32 ) {
info . nativeFormats | = RTAUDIO_FLOAT32 ;
}
else if ( deviceFormat - > wBitsPerSample = = 64 ) {
info . nativeFormats | = RTAUDIO_FLOAT64 ;
}
}
else if ( deviceFormat - > wFormatTag = = WAVE_FORMAT_PCM | |
( deviceFormat - > wFormatTag = = WAVE_FORMAT_EXTENSIBLE & &
( ( WAVEFORMATEXTENSIBLE * ) deviceFormat ) - > SubFormat = = KSDATAFORMAT_SUBTYPE_PCM ) )
{
if ( deviceFormat - > wBitsPerSample = = 8 ) {
info . nativeFormats | = RTAUDIO_SINT8 ;
}
else if ( deviceFormat - > wBitsPerSample = = 16 ) {
info . nativeFormats | = RTAUDIO_SINT16 ;
}
else if ( deviceFormat - > wBitsPerSample = = 24 ) {
info . nativeFormats | = RTAUDIO_SINT24 ;
}
else if ( deviceFormat - > wBitsPerSample = = 32 ) {
info . nativeFormats | = RTAUDIO_SINT32 ;
}
}
// probed
info . probed = true ;
Exit :
// release all references
PropVariantClear ( & deviceNameProp ) ;
PropVariantClear ( & defaultDeviceNameProp ) ;
SAFE_RELEASE ( captureDevices ) ;
SAFE_RELEASE ( renderDevices ) ;
SAFE_RELEASE ( devicePtr ) ;
SAFE_RELEASE ( defaultDevicePtr ) ;
SAFE_RELEASE ( audioClient ) ;
SAFE_RELEASE ( devicePropStore ) ;
SAFE_RELEASE ( defaultDevicePropStore ) ;
CoTaskMemFree ( deviceFormat ) ;
CoTaskMemFree ( closestMatchFormat ) ;
if ( ! errorText_ . empty ( ) )
error ( errorType ) ;
return info ;
}
//-----------------------------------------------------------------------------
unsigned int RtApiWasapi : : getDefaultOutputDevice ( void )
{
for ( unsigned int i = 0 ; i < getDeviceCount ( ) ; i + + ) {
if ( getDeviceInfo ( i ) . isDefaultOutput ) {
return i ;
}
}
return 0 ;
}
//-----------------------------------------------------------------------------
unsigned int RtApiWasapi : : getDefaultInputDevice ( void )
{
for ( unsigned int i = 0 ; i < getDeviceCount ( ) ; i + + ) {
if ( getDeviceInfo ( i ) . isDefaultInput ) {
return i ;
}
}
return 0 ;
}
//-----------------------------------------------------------------------------
void RtApiWasapi : : closeStream ( void )
{
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiWasapi::closeStream: No open stream to close. " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
if ( stream_ . state ! = STREAM_STOPPED )
stopStream ( ) ;
// clean up stream memory
SAFE_RELEASE ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureAudioClient )
SAFE_RELEASE ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderAudioClient )
SAFE_RELEASE ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureClient )
SAFE_RELEASE ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderClient )
if ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureEvent )
CloseHandle ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureEvent ) ;
if ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderEvent )
CloseHandle ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderEvent ) ;
delete ( WasapiHandle * ) stream_ . apiHandle ;
stream_ . apiHandle = NULL ;
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
// update stream state
stream_ . state = STREAM_CLOSED ;
}
//-----------------------------------------------------------------------------
void RtApiWasapi : : startStream ( void )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_RUNNING ) {
errorText_ = " RtApiWasapi::startStream: The stream is already running. " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
// update stream state
stream_ . state = STREAM_RUNNING ;
// create WASAPI stream thread
stream_ . callbackInfo . thread = ( ThreadHandle ) CreateThread ( NULL , 0 , runWasapiThread , this , CREATE_SUSPENDED , NULL ) ;
if ( ! stream_ . callbackInfo . thread ) {
errorText_ = " RtApiWasapi::startStream: Unable to instantiate callback thread. " ;
error ( RtAudioError : : THREAD_ERROR ) ;
}
else {
SetThreadPriority ( ( void * ) stream_ . callbackInfo . thread , stream_ . callbackInfo . priority ) ;
ResumeThread ( ( void * ) stream_ . callbackInfo . thread ) ;
}
}
//-----------------------------------------------------------------------------
void RtApiWasapi : : stopStream ( void )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiWasapi::stopStream: The stream is already stopped. " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
// inform stream thread by setting stream state to STREAM_STOPPING
stream_ . state = STREAM_STOPPING ;
// wait until stream thread is stopped
while ( stream_ . state ! = STREAM_STOPPED ) {
Sleep ( 1 ) ;
}
// Wait for the last buffer to play before stopping.
Sleep ( 1000 * stream_ . bufferSize / stream_ . sampleRate ) ;
// stop capture client if applicable
if ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureAudioClient ) {
HRESULT hr = ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureAudioClient - > Stop ( ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::stopStream: Unable to stop capture stream. " ;
error ( RtAudioError : : DRIVER_ERROR ) ;
return ;
}
}
// stop render client if applicable
if ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderAudioClient ) {
HRESULT hr = ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderAudioClient - > Stop ( ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::stopStream: Unable to stop render stream. " ;
error ( RtAudioError : : DRIVER_ERROR ) ;
return ;
}
}
// close thread handle
if ( stream_ . callbackInfo . thread & & ! CloseHandle ( ( void * ) stream_ . callbackInfo . thread ) ) {
errorText_ = " RtApiWasapi::stopStream: Unable to close callback thread. " ;
error ( RtAudioError : : THREAD_ERROR ) ;
return ;
}
stream_ . callbackInfo . thread = ( ThreadHandle ) NULL ;
}
//-----------------------------------------------------------------------------
void RtApiWasapi : : abortStream ( void )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiWasapi::abortStream: The stream is already stopped. " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
// inform stream thread by setting stream state to STREAM_STOPPING
stream_ . state = STREAM_STOPPING ;
// wait until stream thread is stopped
while ( stream_ . state ! = STREAM_STOPPED ) {
Sleep ( 1 ) ;
}
// stop capture client if applicable
if ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureAudioClient ) {
HRESULT hr = ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureAudioClient - > Stop ( ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::abortStream: Unable to stop capture stream. " ;
error ( RtAudioError : : DRIVER_ERROR ) ;
return ;
}
}
// stop render client if applicable
if ( ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderAudioClient ) {
HRESULT hr = ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderAudioClient - > Stop ( ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::abortStream: Unable to stop render stream. " ;
error ( RtAudioError : : DRIVER_ERROR ) ;
return ;
}
}
// close thread handle
if ( stream_ . callbackInfo . thread & & ! CloseHandle ( ( void * ) stream_ . callbackInfo . thread ) ) {
errorText_ = " RtApiWasapi::abortStream: Unable to close callback thread. " ;
error ( RtAudioError : : THREAD_ERROR ) ;
return ;
}
stream_ . callbackInfo . thread = ( ThreadHandle ) NULL ;
}
//-----------------------------------------------------------------------------
bool RtApiWasapi : : probeDeviceOpen ( unsigned int device , StreamMode mode , unsigned int channels ,
unsigned int firstChannel , unsigned int sampleRate ,
RtAudioFormat format , unsigned int * bufferSize ,
RtAudio : : StreamOptions * options )
{
bool methodResult = FAILURE ;
unsigned int captureDeviceCount = 0 ;
unsigned int renderDeviceCount = 0 ;
IMMDeviceCollection * captureDevices = NULL ;
IMMDeviceCollection * renderDevices = NULL ;
IMMDevice * devicePtr = NULL ;
WAVEFORMATEX * deviceFormat = NULL ;
unsigned int bufferBytes ;
stream_ . state = STREAM_STOPPED ;
// create API Handle if not already created
if ( ! stream_ . apiHandle )
stream_ . apiHandle = ( void * ) new WasapiHandle ( ) ;
// Count capture devices
errorText_ . clear ( ) ;
RtAudioError : : Type errorType = RtAudioError : : DRIVER_ERROR ;
HRESULT hr = deviceEnumerator_ - > EnumAudioEndpoints ( eCapture , DEVICE_STATE_ACTIVE , & captureDevices ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve capture device collection. " ;
goto Exit ;
}
hr = captureDevices - > GetCount ( & captureDeviceCount ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve capture device count. " ;
goto Exit ;
}
// Count render devices
hr = deviceEnumerator_ - > EnumAudioEndpoints ( eRender , DEVICE_STATE_ACTIVE , & renderDevices ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve render device collection. " ;
goto Exit ;
}
hr = renderDevices - > GetCount ( & renderDeviceCount ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve render device count. " ;
goto Exit ;
}
// validate device index
if ( device > = captureDeviceCount + renderDeviceCount ) {
errorType = RtAudioError : : INVALID_USE ;
errorText_ = " RtApiWasapi::probeDeviceOpen: Invalid device index. " ;
goto Exit ;
}
// determine whether index falls within capture or render devices
if ( device > = renderDeviceCount ) {
if ( mode ! = INPUT ) {
errorType = RtAudioError : : INVALID_USE ;
errorText_ = " RtApiWasapi::probeDeviceOpen: Capture device selected as output device. " ;
goto Exit ;
}
// retrieve captureAudioClient from devicePtr
IAudioClient * & captureAudioClient = ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureAudioClient ;
hr = captureDevices - > Item ( device - renderDeviceCount , & devicePtr ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve capture device handle. " ;
goto Exit ;
}
hr = devicePtr - > Activate ( __uuidof ( IAudioClient ) , CLSCTX_ALL ,
NULL , ( void * * ) & captureAudioClient ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve device audio client. " ;
goto Exit ;
}
hr = captureAudioClient - > GetMixFormat ( & deviceFormat ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve device mix format. " ;
goto Exit ;
}
stream_ . nDeviceChannels [ mode ] = deviceFormat - > nChannels ;
captureAudioClient - > GetStreamLatency ( ( long long * ) & stream_ . latency [ mode ] ) ;
}
else {
if ( mode ! = OUTPUT ) {
errorType = RtAudioError : : INVALID_USE ;
errorText_ = " RtApiWasapi::probeDeviceOpen: Render device selected as input device. " ;
goto Exit ;
}
// retrieve renderAudioClient from devicePtr
IAudioClient * & renderAudioClient = ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderAudioClient ;
hr = renderDevices - > Item ( device , & devicePtr ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve render device handle. " ;
goto Exit ;
}
hr = devicePtr - > Activate ( __uuidof ( IAudioClient ) , CLSCTX_ALL ,
NULL , ( void * * ) & renderAudioClient ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve device audio client. " ;
goto Exit ;
}
hr = renderAudioClient - > GetMixFormat ( & deviceFormat ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::probeDeviceOpen: Unable to retrieve device mix format. " ;
goto Exit ;
}
stream_ . nDeviceChannels [ mode ] = deviceFormat - > nChannels ;
renderAudioClient - > GetStreamLatency ( ( long long * ) & stream_ . latency [ mode ] ) ;
}
// fill stream data
if ( ( stream_ . mode = = OUTPUT & & mode = = INPUT ) | |
( stream_ . mode = = INPUT & & mode = = OUTPUT ) ) {
stream_ . mode = DUPLEX ;
}
else {
stream_ . mode = mode ;
}
stream_ . device [ mode ] = device ;
stream_ . doByteSwap [ mode ] = false ;
stream_ . sampleRate = sampleRate ;
stream_ . bufferSize = * bufferSize ;
stream_ . nBuffers = 1 ;
stream_ . nUserChannels [ mode ] = channels ;
stream_ . channelOffset [ mode ] = firstChannel ;
stream_ . userFormat = format ;
stream_ . deviceFormat [ mode ] = getDeviceInfo ( device ) . nativeFormats ;
if ( options & & options - > flags & RTAUDIO_NONINTERLEAVED )
stream_ . userInterleaved = false ;
else
stream_ . userInterleaved = true ;
stream_ . deviceInterleaved [ mode ] = true ;
// Set flags for buffer conversion.
stream_ . doConvertBuffer [ mode ] = false ;
if ( stream_ . userFormat ! = stream_ . deviceFormat [ mode ] | |
stream_ . nUserChannels ! = stream_ . nDeviceChannels )
stream_ . doConvertBuffer [ mode ] = true ;
else if ( stream_ . userInterleaved ! = stream_ . deviceInterleaved [ mode ] & &
stream_ . nUserChannels [ mode ] > 1 )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . doConvertBuffer [ mode ] )
setConvertInfo ( mode , 0 ) ;
// Allocate necessary internal buffers
bufferBytes = stream_ . nUserChannels [ mode ] * stream_ . bufferSize * formatBytes ( stream_ . userFormat ) ;
stream_ . userBuffer [ mode ] = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( ! stream_ . userBuffer [ mode ] ) {
errorType = RtAudioError : : MEMORY_ERROR ;
errorText_ = " RtApiWasapi::probeDeviceOpen: Error allocating user buffer memory. " ;
goto Exit ;
}
if ( options & & options - > flags & RTAUDIO_SCHEDULE_REALTIME )
stream_ . callbackInfo . priority = 15 ;
else
stream_ . callbackInfo . priority = 0 ;
///! TODO: RTAUDIO_MINIMIZE_LATENCY // Provide stream buffers directly to callback
///! TODO: RTAUDIO_HOG_DEVICE // Exclusive mode
methodResult = SUCCESS ;
Exit :
//clean up
SAFE_RELEASE ( captureDevices ) ;
SAFE_RELEASE ( renderDevices ) ;
SAFE_RELEASE ( devicePtr ) ;
CoTaskMemFree ( deviceFormat ) ;
// if method failed, close the stream
if ( methodResult = = FAILURE )
closeStream ( ) ;
if ( ! errorText_ . empty ( ) )
error ( errorType ) ;
return methodResult ;
}
//=============================================================================
DWORD WINAPI RtApiWasapi : : runWasapiThread ( void * wasapiPtr )
{
if ( wasapiPtr )
( ( RtApiWasapi * ) wasapiPtr ) - > wasapiThread ( ) ;
return 0 ;
}
DWORD WINAPI RtApiWasapi : : stopWasapiThread ( void * wasapiPtr )
{
if ( wasapiPtr )
( ( RtApiWasapi * ) wasapiPtr ) - > stopStream ( ) ;
return 0 ;
}
DWORD WINAPI RtApiWasapi : : abortWasapiThread ( void * wasapiPtr )
{
if ( wasapiPtr )
( ( RtApiWasapi * ) wasapiPtr ) - > abortStream ( ) ;
return 0 ;
}
//-----------------------------------------------------------------------------
void RtApiWasapi : : wasapiThread ( )
{
// as this is a new thread, we must CoInitialize it
CoInitialize ( NULL ) ;
HRESULT hr ;
IAudioClient * captureAudioClient = ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureAudioClient ;
IAudioClient * renderAudioClient = ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderAudioClient ;
IAudioCaptureClient * captureClient = ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureClient ;
IAudioRenderClient * renderClient = ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderClient ;
HANDLE captureEvent = ( ( WasapiHandle * ) stream_ . apiHandle ) - > captureEvent ;
HANDLE renderEvent = ( ( WasapiHandle * ) stream_ . apiHandle ) - > renderEvent ;
WAVEFORMATEX * captureFormat = NULL ;
WAVEFORMATEX * renderFormat = NULL ;
float captureSrRatio = 0.0f ;
float renderSrRatio = 0.0f ;
WasapiBuffer captureBuffer ;
WasapiBuffer renderBuffer ;
// declare local stream variables
RtAudioCallback callback = ( RtAudioCallback ) stream_ . callbackInfo . callback ;
BYTE * streamBuffer = NULL ;
unsigned long captureFlags = 0 ;
unsigned int bufferFrameCount = 0 ;
unsigned int numFramesPadding = 0 ;
unsigned int convBufferSize = 0 ;
bool callbackPushed = false ;
bool callbackPulled = false ;
bool callbackStopped = false ;
int callbackResult = 0 ;
// convBuffer is used to store converted buffers between WASAPI and the user
char * convBuffer = NULL ;
unsigned int convBuffSize = 0 ;
unsigned int deviceBuffSize = 0 ;
errorText_ . clear ( ) ;
RtAudioError : : Type errorType = RtAudioError : : DRIVER_ERROR ;
// Attempt to assign "Pro Audio" characteristic to thread
HMODULE AvrtDll = LoadLibrary ( ( LPCTSTR ) " AVRT.dll " ) ;
if ( AvrtDll ) {
DWORD taskIndex = 0 ;
TAvSetMmThreadCharacteristicsPtr AvSetMmThreadCharacteristicsPtr = ( TAvSetMmThreadCharacteristicsPtr ) GetProcAddress ( AvrtDll , " AvSetMmThreadCharacteristicsW " ) ;
AvSetMmThreadCharacteristicsPtr ( L " Pro Audio " , & taskIndex ) ;
FreeLibrary ( AvrtDll ) ;
}
// start capture stream if applicable
if ( captureAudioClient ) {
hr = captureAudioClient - > GetMixFormat ( & captureFormat ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to retrieve device mix format. " ;
goto Exit ;
}
captureSrRatio = ( ( float ) captureFormat - > nSamplesPerSec / stream_ . sampleRate ) ;
// initialize capture stream according to desire buffer size
float desiredBufferSize = stream_ . bufferSize * captureSrRatio ;
REFERENCE_TIME desiredBufferPeriod = ( REFERENCE_TIME ) ( ( float ) desiredBufferSize * 10000000 / captureFormat - > nSamplesPerSec ) ;
if ( ! captureClient ) {
hr = captureAudioClient - > Initialize ( AUDCLNT_SHAREMODE_SHARED ,
AUDCLNT_STREAMFLAGS_EVENTCALLBACK ,
desiredBufferPeriod ,
desiredBufferPeriod ,
captureFormat ,
NULL ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to initialize capture audio client. " ;
goto Exit ;
}
hr = captureAudioClient - > GetService ( __uuidof ( IAudioCaptureClient ) ,
( void * * ) & captureClient ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to retrieve capture client handle. " ;
goto Exit ;
}
// configure captureEvent to trigger on every available capture buffer
captureEvent = CreateEvent ( NULL , FALSE , FALSE , NULL ) ;
if ( ! captureEvent ) {
errorType = RtAudioError : : SYSTEM_ERROR ;
errorText_ = " RtApiWasapi::wasapiThread: Unable to create capture event. " ;
goto Exit ;
}
hr = captureAudioClient - > SetEventHandle ( captureEvent ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to set capture event handle. " ;
goto Exit ;
}
( ( WasapiHandle * ) stream_ . apiHandle ) - > captureClient = captureClient ;
( ( WasapiHandle * ) stream_ . apiHandle ) - > captureEvent = captureEvent ;
}
unsigned int inBufferSize = 0 ;
hr = captureAudioClient - > GetBufferSize ( & inBufferSize ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to get capture buffer size. " ;
goto Exit ;
}
// scale outBufferSize according to stream->user sample rate ratio
unsigned int outBufferSize = ( unsigned int ) ( stream_ . bufferSize * captureSrRatio ) * stream_ . nDeviceChannels [ INPUT ] ;
inBufferSize * = stream_ . nDeviceChannels [ INPUT ] ;
// set captureBuffer size
captureBuffer . setBufferSize ( inBufferSize + outBufferSize , formatBytes ( stream_ . deviceFormat [ INPUT ] ) ) ;
// reset the capture stream
hr = captureAudioClient - > Reset ( ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to reset capture stream. " ;
goto Exit ;
}
// start the capture stream
hr = captureAudioClient - > Start ( ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to start capture stream. " ;
goto Exit ;
}
}
// start render stream if applicable
if ( renderAudioClient ) {
hr = renderAudioClient - > GetMixFormat ( & renderFormat ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to retrieve device mix format. " ;
goto Exit ;
}
renderSrRatio = ( ( float ) renderFormat - > nSamplesPerSec / stream_ . sampleRate ) ;
// initialize render stream according to desire buffer size
float desiredBufferSize = stream_ . bufferSize * renderSrRatio ;
REFERENCE_TIME desiredBufferPeriod = ( REFERENCE_TIME ) ( ( float ) desiredBufferSize * 10000000 / renderFormat - > nSamplesPerSec ) ;
if ( ! renderClient ) {
hr = renderAudioClient - > Initialize ( AUDCLNT_SHAREMODE_SHARED ,
AUDCLNT_STREAMFLAGS_EVENTCALLBACK ,
desiredBufferPeriod ,
desiredBufferPeriod ,
renderFormat ,
NULL ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to initialize render audio client. " ;
goto Exit ;
}
hr = renderAudioClient - > GetService ( __uuidof ( IAudioRenderClient ) ,
( void * * ) & renderClient ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to retrieve render client handle. " ;
goto Exit ;
}
// configure renderEvent to trigger on every available render buffer
renderEvent = CreateEvent ( NULL , FALSE , FALSE , NULL ) ;
if ( ! renderEvent ) {
errorType = RtAudioError : : SYSTEM_ERROR ;
errorText_ = " RtApiWasapi::wasapiThread: Unable to create render event. " ;
goto Exit ;
}
hr = renderAudioClient - > SetEventHandle ( renderEvent ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to set render event handle. " ;
goto Exit ;
}
( ( WasapiHandle * ) stream_ . apiHandle ) - > renderClient = renderClient ;
( ( WasapiHandle * ) stream_ . apiHandle ) - > renderEvent = renderEvent ;
}
unsigned int outBufferSize = 0 ;
hr = renderAudioClient - > GetBufferSize ( & outBufferSize ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to get render buffer size. " ;
goto Exit ;
}
// scale inBufferSize according to user->stream sample rate ratio
unsigned int inBufferSize = ( unsigned int ) ( stream_ . bufferSize * renderSrRatio ) * stream_ . nDeviceChannels [ OUTPUT ] ;
outBufferSize * = stream_ . nDeviceChannels [ OUTPUT ] ;
// set renderBuffer size
renderBuffer . setBufferSize ( inBufferSize + outBufferSize , formatBytes ( stream_ . deviceFormat [ OUTPUT ] ) ) ;
// reset the render stream
hr = renderAudioClient - > Reset ( ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to reset render stream. " ;
goto Exit ;
}
// start the render stream
hr = renderAudioClient - > Start ( ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to start render stream. " ;
goto Exit ;
}
}
if ( stream_ . mode = = INPUT ) {
convBuffSize = ( size_t ) ( stream_ . bufferSize * captureSrRatio ) * stream_ . nDeviceChannels [ INPUT ] * formatBytes ( stream_ . deviceFormat [ INPUT ] ) ;
deviceBuffSize = stream_ . bufferSize * stream_ . nDeviceChannels [ INPUT ] * formatBytes ( stream_ . deviceFormat [ INPUT ] ) ;
}
else if ( stream_ . mode = = OUTPUT ) {
convBuffSize = ( size_t ) ( stream_ . bufferSize * renderSrRatio ) * stream_ . nDeviceChannels [ OUTPUT ] * formatBytes ( stream_ . deviceFormat [ OUTPUT ] ) ;
deviceBuffSize = stream_ . bufferSize * stream_ . nDeviceChannels [ OUTPUT ] * formatBytes ( stream_ . deviceFormat [ OUTPUT ] ) ;
}
else if ( stream_ . mode = = DUPLEX ) {
convBuffSize = std : : max ( ( size_t ) ( stream_ . bufferSize * captureSrRatio ) * stream_ . nDeviceChannels [ INPUT ] * formatBytes ( stream_ . deviceFormat [ INPUT ] ) ,
( size_t ) ( stream_ . bufferSize * renderSrRatio ) * stream_ . nDeviceChannels [ OUTPUT ] * formatBytes ( stream_ . deviceFormat [ OUTPUT ] ) ) ;
deviceBuffSize = std : : max ( stream_ . bufferSize * stream_ . nDeviceChannels [ INPUT ] * formatBytes ( stream_ . deviceFormat [ INPUT ] ) ,
stream_ . bufferSize * stream_ . nDeviceChannels [ OUTPUT ] * formatBytes ( stream_ . deviceFormat [ OUTPUT ] ) ) ;
}
convBuffer = ( char * ) malloc ( convBuffSize ) ;
stream_ . deviceBuffer = ( char * ) malloc ( deviceBuffSize ) ;
if ( ! convBuffer | | ! stream_ . deviceBuffer ) {
errorType = RtAudioError : : MEMORY_ERROR ;
errorText_ = " RtApiWasapi::wasapiThread: Error allocating device buffer memory. " ;
goto Exit ;
}
// stream process loop
while ( stream_ . state ! = STREAM_STOPPING ) {
if ( ! callbackPulled ) {
// Callback Input
// ==============
// 1. Pull callback buffer from inputBuffer
// 2. If 1. was successful: Convert callback buffer to user sample rate and channel count
// Convert callback buffer to user format
if ( captureAudioClient ) {
// Pull callback buffer from inputBuffer
callbackPulled = captureBuffer . pullBuffer ( convBuffer ,
( unsigned int ) ( stream_ . bufferSize * captureSrRatio ) * stream_ . nDeviceChannels [ INPUT ] ,
stream_ . deviceFormat [ INPUT ] ) ;
if ( callbackPulled ) {
// Convert callback buffer to user sample rate
convertBufferWasapi ( stream_ . deviceBuffer ,
convBuffer ,
stream_ . nDeviceChannels [ INPUT ] ,
captureFormat - > nSamplesPerSec ,
stream_ . sampleRate ,
( unsigned int ) ( stream_ . bufferSize * captureSrRatio ) ,
convBufferSize ,
stream_ . deviceFormat [ INPUT ] ) ;
if ( stream_ . doConvertBuffer [ INPUT ] ) {
// Convert callback buffer to user format
convertBuffer ( stream_ . userBuffer [ INPUT ] ,
stream_ . deviceBuffer ,
stream_ . convertInfo [ INPUT ] ) ;
}
else {
// no further conversion, simple copy deviceBuffer to userBuffer
memcpy ( stream_ . userBuffer [ INPUT ] ,
stream_ . deviceBuffer ,
stream_ . bufferSize * stream_ . nUserChannels [ INPUT ] * formatBytes ( stream_ . userFormat ) ) ;
}
}
}
else {
// if there is no capture stream, set callbackPulled flag
callbackPulled = true ;
}
// Execute Callback
// ================
// 1. Execute user callback method
// 2. Handle return value from callback
// if callback has not requested the stream to stop
if ( callbackPulled & & ! callbackStopped ) {
// Execute user callback method
callbackResult = callback ( stream_ . userBuffer [ OUTPUT ] ,
stream_ . userBuffer [ INPUT ] ,
stream_ . bufferSize ,
getStreamTime ( ) ,
captureFlags & AUDCLNT_BUFFERFLAGS_DATA_DISCONTINUITY ? RTAUDIO_INPUT_OVERFLOW : 0 ,
stream_ . callbackInfo . userData ) ;
// Handle return value from callback
if ( callbackResult = = 1 ) {
// instantiate a thread to stop this thread
HANDLE threadHandle = CreateThread ( NULL , 0 , stopWasapiThread , this , 0 , NULL ) ;
if ( ! threadHandle ) {
errorType = RtAudioError : : THREAD_ERROR ;
errorText_ = " RtApiWasapi::wasapiThread: Unable to instantiate stream stop thread. " ;
goto Exit ;
}
else if ( ! CloseHandle ( threadHandle ) ) {
errorType = RtAudioError : : THREAD_ERROR ;
errorText_ = " RtApiWasapi::wasapiThread: Unable to close stream stop thread handle. " ;
goto Exit ;
}
callbackStopped = true ;
}
else if ( callbackResult = = 2 ) {
// instantiate a thread to stop this thread
HANDLE threadHandle = CreateThread ( NULL , 0 , abortWasapiThread , this , 0 , NULL ) ;
if ( ! threadHandle ) {
errorType = RtAudioError : : THREAD_ERROR ;
errorText_ = " RtApiWasapi::wasapiThread: Unable to instantiate stream abort thread. " ;
goto Exit ;
}
else if ( ! CloseHandle ( threadHandle ) ) {
errorType = RtAudioError : : THREAD_ERROR ;
errorText_ = " RtApiWasapi::wasapiThread: Unable to close stream abort thread handle. " ;
goto Exit ;
}
callbackStopped = true ;
}
}
}
// Callback Output
// ===============
// 1. Convert callback buffer to stream format
// 2. Convert callback buffer to stream sample rate and channel count
// 3. Push callback buffer into outputBuffer
if ( renderAudioClient & & callbackPulled ) {
if ( stream_ . doConvertBuffer [ OUTPUT ] ) {
// Convert callback buffer to stream format
convertBuffer ( stream_ . deviceBuffer ,
stream_ . userBuffer [ OUTPUT ] ,
stream_ . convertInfo [ OUTPUT ] ) ;
}
// Convert callback buffer to stream sample rate
convertBufferWasapi ( convBuffer ,
stream_ . deviceBuffer ,
stream_ . nDeviceChannels [ OUTPUT ] ,
stream_ . sampleRate ,
renderFormat - > nSamplesPerSec ,
stream_ . bufferSize ,
convBufferSize ,
stream_ . deviceFormat [ OUTPUT ] ) ;
// Push callback buffer into outputBuffer
callbackPushed = renderBuffer . pushBuffer ( convBuffer ,
convBufferSize * stream_ . nDeviceChannels [ OUTPUT ] ,
stream_ . deviceFormat [ OUTPUT ] ) ;
}
else {
// if there is no render stream, set callbackPushed flag
callbackPushed = true ;
}
// Stream Capture
// ==============
// 1. Get capture buffer from stream
// 2. Push capture buffer into inputBuffer
// 3. If 2. was successful: Release capture buffer
if ( captureAudioClient ) {
// if the callback input buffer was not pulled from captureBuffer, wait for next capture event
if ( ! callbackPulled ) {
WaitForSingleObject ( captureEvent , INFINITE ) ;
}
// Get capture buffer from stream
hr = captureClient - > GetBuffer ( & streamBuffer ,
& bufferFrameCount ,
& captureFlags , NULL , NULL ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to retrieve capture buffer. " ;
goto Exit ;
}
if ( bufferFrameCount ! = 0 ) {
// Push capture buffer into inputBuffer
if ( captureBuffer . pushBuffer ( ( char * ) streamBuffer ,
bufferFrameCount * stream_ . nDeviceChannels [ INPUT ] ,
stream_ . deviceFormat [ INPUT ] ) )
{
// Release capture buffer
hr = captureClient - > ReleaseBuffer ( bufferFrameCount ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to release capture buffer. " ;
goto Exit ;
}
}
else
{
// Inform WASAPI that capture was unsuccessful
hr = captureClient - > ReleaseBuffer ( 0 ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to release capture buffer. " ;
goto Exit ;
}
}
}
else
{
// Inform WASAPI that capture was unsuccessful
hr = captureClient - > ReleaseBuffer ( 0 ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to release capture buffer. " ;
goto Exit ;
}
}
}
// Stream Render
// =============
// 1. Get render buffer from stream
// 2. Pull next buffer from outputBuffer
// 3. If 2. was successful: Fill render buffer with next buffer
// Release render buffer
if ( renderAudioClient ) {
// if the callback output buffer was not pushed to renderBuffer, wait for next render event
if ( callbackPulled & & ! callbackPushed ) {
WaitForSingleObject ( renderEvent , INFINITE ) ;
}
// Get render buffer from stream
hr = renderAudioClient - > GetBufferSize ( & bufferFrameCount ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to retrieve render buffer size. " ;
goto Exit ;
}
hr = renderAudioClient - > GetCurrentPadding ( & numFramesPadding ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to retrieve render buffer padding. " ;
goto Exit ;
}
bufferFrameCount - = numFramesPadding ;
if ( bufferFrameCount ! = 0 ) {
hr = renderClient - > GetBuffer ( bufferFrameCount , & streamBuffer ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to retrieve render buffer. " ;
goto Exit ;
}
// Pull next buffer from outputBuffer
// Fill render buffer with next buffer
if ( renderBuffer . pullBuffer ( ( char * ) streamBuffer ,
bufferFrameCount * stream_ . nDeviceChannels [ OUTPUT ] ,
stream_ . deviceFormat [ OUTPUT ] ) )
{
// Release render buffer
hr = renderClient - > ReleaseBuffer ( bufferFrameCount , 0 ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to release render buffer. " ;
goto Exit ;
}
}
else
{
// Inform WASAPI that render was unsuccessful
hr = renderClient - > ReleaseBuffer ( 0 , 0 ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to release render buffer. " ;
goto Exit ;
}
}
}
else
{
// Inform WASAPI that render was unsuccessful
hr = renderClient - > ReleaseBuffer ( 0 , 0 ) ;
if ( FAILED ( hr ) ) {
errorText_ = " RtApiWasapi::wasapiThread: Unable to release render buffer. " ;
goto Exit ;
}
}
}
// if the callback buffer was pushed renderBuffer reset callbackPulled flag
if ( callbackPushed ) {
callbackPulled = false ;
}
// tick stream time
RtApi : : tickStreamTime ( ) ;
}
Exit :
// clean up
CoTaskMemFree ( captureFormat ) ;
CoTaskMemFree ( renderFormat ) ;
free ( convBuffer ) ;
CoUninitialize ( ) ;
// update stream state
stream_ . state = STREAM_STOPPED ;
if ( errorText_ . empty ( ) )
return ;
else
error ( errorType ) ;
}
//******************** End of __WINDOWS_WASAPI__ *********************//
# endif
# if defined(__WINDOWS_DS__) // Windows DirectSound API
// Modified by Robin Davies, October 2005
// - Improvements to DirectX pointer chasing.
// - Bug fix for non-power-of-two Asio granularity used by Edirol PCR-A30.
// - Auto-call CoInitialize for DSOUND and ASIO platforms.
// Various revisions for RtAudio 4.0 by Gary Scavone, April 2007
// Changed device query structure for RtAudio 4.0.7, January 2010
# include <dsound.h>
# include <assert.h>
# include <algorithm>
# if defined(__MINGW32__)
// missing from latest mingw winapi
# define WAVE_FORMAT_96M08 0x00010000 /* 96 kHz, Mono, 8-bit */
# define WAVE_FORMAT_96S08 0x00020000 /* 96 kHz, Stereo, 8-bit */
# define WAVE_FORMAT_96M16 0x00040000 /* 96 kHz, Mono, 16-bit */
# define WAVE_FORMAT_96S16 0x00080000 /* 96 kHz, Stereo, 16-bit */
# endif
# define MINIMUM_DEVICE_BUFFER_SIZE 32768
# ifdef _MSC_VER // if Microsoft Visual C++
# pragma comment( lib, "winmm.lib" ) // then, auto-link winmm.lib. Otherwise, it has to be added manually.
# endif
static inline DWORD dsPointerBetween ( DWORD pointer , DWORD laterPointer , DWORD earlierPointer , DWORD bufferSize )
{
if ( pointer > bufferSize ) pointer - = bufferSize ;
if ( laterPointer < earlierPointer ) laterPointer + = bufferSize ;
if ( pointer < earlierPointer ) pointer + = bufferSize ;
return pointer > = earlierPointer & & pointer < laterPointer ;
}
// A structure to hold various information related to the DirectSound
// API implementation.
struct DsHandle {
unsigned int drainCounter ; // Tracks callback counts when draining
bool internalDrain ; // Indicates if stop is initiated from callback or not.
void * id [ 2 ] ;
void * buffer [ 2 ] ;
bool xrun [ 2 ] ;
UINT bufferPointer [ 2 ] ;
DWORD dsBufferSize [ 2 ] ;
DWORD dsPointerLeadTime [ 2 ] ; // the number of bytes ahead of the safe pointer to lead by.
HANDLE condition ;
DsHandle ( )
: drainCounter ( 0 ) , internalDrain ( false ) { id [ 0 ] = 0 ; id [ 1 ] = 0 ; buffer [ 0 ] = 0 ; buffer [ 1 ] = 0 ; xrun [ 0 ] = false ; xrun [ 1 ] = false ; bufferPointer [ 0 ] = 0 ; bufferPointer [ 1 ] = 0 ; }
} ;
// Declarations for utility functions, callbacks, and structures
// specific to the DirectSound implementation.
static BOOL CALLBACK deviceQueryCallback ( LPGUID lpguid ,
LPCTSTR description ,
LPCTSTR module ,
LPVOID lpContext ) ;
static const char * getErrorString ( int code ) ;
static unsigned __stdcall callbackHandler ( void * ptr ) ;
struct DsDevice {
LPGUID id [ 2 ] ;
bool validId [ 2 ] ;
bool found ;
std : : string name ;
DsDevice ( )
: found ( false ) { validId [ 0 ] = false ; validId [ 1 ] = false ; }
} ;
struct DsProbeData {
bool isInput ;
std : : vector < struct DsDevice > * dsDevices ;
} ;
RtApiDs : : RtApiDs ( )
{
// Dsound will run both-threaded. If CoInitialize fails, then just
// accept whatever the mainline chose for a threading model.
coInitialized_ = false ;
HRESULT hr = CoInitialize ( NULL ) ;
if ( ! FAILED ( hr ) ) coInitialized_ = true ;
}
RtApiDs : : ~ RtApiDs ( )
{
if ( coInitialized_ ) CoUninitialize ( ) ; // balanced call.
if ( stream_ . state ! = STREAM_CLOSED ) closeStream ( ) ;
}
// The DirectSound default output is always the first device.
unsigned int RtApiDs : : getDefaultOutputDevice ( void )
{
return 0 ;
}
// The DirectSound default input is always the first input device,
// which is the first capture device enumerated.
unsigned int RtApiDs : : getDefaultInputDevice ( void )
{
return 0 ;
}
unsigned int RtApiDs : : getDeviceCount ( void )
{
// Set query flag for previously found devices to false, so that we
// can check for any devices that have disappeared.
for ( unsigned int i = 0 ; i < dsDevices . size ( ) ; i + + )
dsDevices [ i ] . found = false ;
// Query DirectSound devices.
struct DsProbeData probeInfo ;
probeInfo . isInput = false ;
probeInfo . dsDevices = & dsDevices ;
HRESULT result = DirectSoundEnumerate ( ( LPDSENUMCALLBACK ) deviceQueryCallback , & probeInfo ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::getDeviceCount: error ( " < < getErrorString ( result ) < < " ) enumerating output devices! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
}
// Query DirectSoundCapture devices.
probeInfo . isInput = true ;
result = DirectSoundCaptureEnumerate ( ( LPDSENUMCALLBACK ) deviceQueryCallback , & probeInfo ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::getDeviceCount: error ( " < < getErrorString ( result ) < < " ) enumerating input devices! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
}
// Clean out any devices that may have disappeared.
std : : vector < int > indices ;
for ( unsigned int i = 0 ; i < dsDevices . size ( ) ; i + + )
if ( dsDevices [ i ] . found = = false ) indices . push_back ( i ) ;
//unsigned int nErased = 0;
for ( unsigned int i = 0 ; i < indices . size ( ) ; i + + )
dsDevices . erase ( dsDevices . begin ( ) + indices [ i ] ) ;
//dsDevices.erase( dsDevices.begin()-nErased++ );
return static_cast < unsigned int > ( dsDevices . size ( ) ) ;
}
RtAudio : : DeviceInfo RtApiDs : : getDeviceInfo ( unsigned int device )
{
RtAudio : : DeviceInfo info ;
info . probed = false ;
if ( dsDevices . size ( ) = = 0 ) {
// Force a query of all devices
getDeviceCount ( ) ;
if ( dsDevices . size ( ) = = 0 ) {
errorText_ = " RtApiDs::getDeviceInfo: no devices found! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
}
if ( device > = dsDevices . size ( ) ) {
errorText_ = " RtApiDs::getDeviceInfo: device ID is invalid! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
HRESULT result ;
if ( dsDevices [ device ] . validId [ 0 ] = = false ) goto probeInput ;
LPDIRECTSOUND output ;
DSCAPS outCaps ;
result = DirectSoundCreate ( dsDevices [ device ] . id [ 0 ] , & output , NULL ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::getDeviceInfo: error ( " < < getErrorString ( result ) < < " ) opening output device ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
goto probeInput ;
}
outCaps . dwSize = sizeof ( outCaps ) ;
result = output - > GetCaps ( & outCaps ) ;
if ( FAILED ( result ) ) {
output - > Release ( ) ;
errorStream_ < < " RtApiDs::getDeviceInfo: error ( " < < getErrorString ( result ) < < " ) getting capabilities! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
goto probeInput ;
}
// Get output channel information.
info . outputChannels = ( outCaps . dwFlags & DSCAPS_PRIMARYSTEREO ) ? 2 : 1 ;
// Get sample rate information.
info . sampleRates . clear ( ) ;
for ( unsigned int k = 0 ; k < MAX_SAMPLE_RATES ; k + + ) {
if ( SAMPLE_RATES [ k ] > = ( unsigned int ) outCaps . dwMinSecondarySampleRate & &
SAMPLE_RATES [ k ] < = ( unsigned int ) outCaps . dwMaxSecondarySampleRate )
info . sampleRates . push_back ( SAMPLE_RATES [ k ] ) ;
}
// Get format information.
if ( outCaps . dwFlags & DSCAPS_PRIMARY16BIT ) info . nativeFormats | = RTAUDIO_SINT16 ;
if ( outCaps . dwFlags & DSCAPS_PRIMARY8BIT ) info . nativeFormats | = RTAUDIO_SINT8 ;
output - > Release ( ) ;
if ( getDefaultOutputDevice ( ) = = device )
info . isDefaultOutput = true ;
if ( dsDevices [ device ] . validId [ 1 ] = = false ) {
info . name = dsDevices [ device ] . name ;
info . probed = true ;
return info ;
}
probeInput :
LPDIRECTSOUNDCAPTURE input ;
result = DirectSoundCaptureCreate ( dsDevices [ device ] . id [ 1 ] , & input , NULL ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::getDeviceInfo: error ( " < < getErrorString ( result ) < < " ) opening input device ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
DSCCAPS inCaps ;
inCaps . dwSize = sizeof ( inCaps ) ;
result = input - > GetCaps ( & inCaps ) ;
if ( FAILED ( result ) ) {
input - > Release ( ) ;
errorStream_ < < " RtApiDs::getDeviceInfo: error ( " < < getErrorString ( result ) < < " ) getting object capabilities ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Get input channel information.
info . inputChannels = inCaps . dwChannels ;
// Get sample rate and format information.
std : : vector < unsigned int > rates ;
if ( inCaps . dwChannels > = 2 ) {
if ( inCaps . dwFormats & WAVE_FORMAT_1S16 ) info . nativeFormats | = RTAUDIO_SINT16 ;
if ( inCaps . dwFormats & WAVE_FORMAT_2S16 ) info . nativeFormats | = RTAUDIO_SINT16 ;
if ( inCaps . dwFormats & WAVE_FORMAT_4S16 ) info . nativeFormats | = RTAUDIO_SINT16 ;
if ( inCaps . dwFormats & WAVE_FORMAT_96S16 ) info . nativeFormats | = RTAUDIO_SINT16 ;
if ( inCaps . dwFormats & WAVE_FORMAT_1S08 ) info . nativeFormats | = RTAUDIO_SINT8 ;
if ( inCaps . dwFormats & WAVE_FORMAT_2S08 ) info . nativeFormats | = RTAUDIO_SINT8 ;
if ( inCaps . dwFormats & WAVE_FORMAT_4S08 ) info . nativeFormats | = RTAUDIO_SINT8 ;
if ( inCaps . dwFormats & WAVE_FORMAT_96S08 ) info . nativeFormats | = RTAUDIO_SINT8 ;
if ( info . nativeFormats & RTAUDIO_SINT16 ) {
if ( inCaps . dwFormats & WAVE_FORMAT_1S16 ) rates . push_back ( 11025 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_2S16 ) rates . push_back ( 22050 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_4S16 ) rates . push_back ( 44100 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_96S16 ) rates . push_back ( 96000 ) ;
}
else if ( info . nativeFormats & RTAUDIO_SINT8 ) {
if ( inCaps . dwFormats & WAVE_FORMAT_1S08 ) rates . push_back ( 11025 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_2S08 ) rates . push_back ( 22050 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_4S08 ) rates . push_back ( 44100 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_96S08 ) rates . push_back ( 96000 ) ;
}
}
else if ( inCaps . dwChannels = = 1 ) {
if ( inCaps . dwFormats & WAVE_FORMAT_1M16 ) info . nativeFormats | = RTAUDIO_SINT16 ;
if ( inCaps . dwFormats & WAVE_FORMAT_2M16 ) info . nativeFormats | = RTAUDIO_SINT16 ;
if ( inCaps . dwFormats & WAVE_FORMAT_4M16 ) info . nativeFormats | = RTAUDIO_SINT16 ;
if ( inCaps . dwFormats & WAVE_FORMAT_96M16 ) info . nativeFormats | = RTAUDIO_SINT16 ;
if ( inCaps . dwFormats & WAVE_FORMAT_1M08 ) info . nativeFormats | = RTAUDIO_SINT8 ;
if ( inCaps . dwFormats & WAVE_FORMAT_2M08 ) info . nativeFormats | = RTAUDIO_SINT8 ;
if ( inCaps . dwFormats & WAVE_FORMAT_4M08 ) info . nativeFormats | = RTAUDIO_SINT8 ;
if ( inCaps . dwFormats & WAVE_FORMAT_96M08 ) info . nativeFormats | = RTAUDIO_SINT8 ;
if ( info . nativeFormats & RTAUDIO_SINT16 ) {
if ( inCaps . dwFormats & WAVE_FORMAT_1M16 ) rates . push_back ( 11025 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_2M16 ) rates . push_back ( 22050 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_4M16 ) rates . push_back ( 44100 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_96M16 ) rates . push_back ( 96000 ) ;
}
else if ( info . nativeFormats & RTAUDIO_SINT8 ) {
if ( inCaps . dwFormats & WAVE_FORMAT_1M08 ) rates . push_back ( 11025 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_2M08 ) rates . push_back ( 22050 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_4M08 ) rates . push_back ( 44100 ) ;
if ( inCaps . dwFormats & WAVE_FORMAT_96M08 ) rates . push_back ( 96000 ) ;
}
}
else info . inputChannels = 0 ; // technically, this would be an error
input - > Release ( ) ;
if ( info . inputChannels = = 0 ) return info ;
// Copy the supported rates to the info structure but avoid duplication.
bool found ;
for ( unsigned int i = 0 ; i < rates . size ( ) ; i + + ) {
found = false ;
for ( unsigned int j = 0 ; j < info . sampleRates . size ( ) ; j + + ) {
if ( rates [ i ] = = info . sampleRates [ j ] ) {
found = true ;
break ;
}
}
if ( found = = false ) info . sampleRates . push_back ( rates [ i ] ) ;
}
std : : sort ( info . sampleRates . begin ( ) , info . sampleRates . end ( ) ) ;
// If device opens for both playback and capture, we determine the channels.
if ( info . outputChannels > 0 & & info . inputChannels > 0 )
info . duplexChannels = ( info . outputChannels > info . inputChannels ) ? info . inputChannels : info . outputChannels ;
if ( device = = 0 ) info . isDefaultInput = true ;
// Copy name and return.
info . name = dsDevices [ device ] . name ;
info . probed = true ;
return info ;
}
bool RtApiDs : : probeDeviceOpen ( unsigned int device , StreamMode mode , unsigned int channels ,
unsigned int firstChannel , unsigned int sampleRate ,
RtAudioFormat format , unsigned int * bufferSize ,
RtAudio : : StreamOptions * options )
{
if ( channels + firstChannel > 2 ) {
errorText_ = " RtApiDs::probeDeviceOpen: DirectSound does not support more than 2 channels per device. " ;
return FAILURE ;
}
size_t nDevices = dsDevices . size ( ) ;
if ( nDevices = = 0 ) {
// This should not happen because a check is made before this function is called.
errorText_ = " RtApiDs::probeDeviceOpen: no devices found! " ;
return FAILURE ;
}
if ( device > = nDevices ) {
// This should not happen because a check is made before this function is called.
errorText_ = " RtApiDs::probeDeviceOpen: device ID is invalid! " ;
return FAILURE ;
}
if ( mode = = OUTPUT ) {
if ( dsDevices [ device ] . validId [ 0 ] = = false ) {
errorStream_ < < " RtApiDs::probeDeviceOpen: device ( " < < device < < " ) does not support output! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
else { // mode == INPUT
if ( dsDevices [ device ] . validId [ 1 ] = = false ) {
errorStream_ < < " RtApiDs::probeDeviceOpen: device ( " < < device < < " ) does not support input! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
// According to a note in PortAudio, using GetDesktopWindow()
// instead of GetForegroundWindow() is supposed to avoid problems
// that occur when the application's window is not the foreground
// window. Also, if the application window closes before the
// DirectSound buffer, DirectSound can crash. In the past, I had
// problems when using GetDesktopWindow() but it seems fine now
// (January 2010). I'll leave it commented here.
// HWND hWnd = GetForegroundWindow();
HWND hWnd = GetDesktopWindow ( ) ;
// Check the numberOfBuffers parameter and limit the lowest value to
// two. This is a judgement call and a value of two is probably too
// low for capture, but it should work for playback.
int nBuffers = 0 ;
if ( options ) nBuffers = options - > numberOfBuffers ;
if ( options & & options - > flags & RTAUDIO_MINIMIZE_LATENCY ) nBuffers = 2 ;
if ( nBuffers < 2 ) nBuffers = 3 ;
// Check the lower range of the user-specified buffer size and set
// (arbitrarily) to a lower bound of 32.
if ( * bufferSize < 32 ) * bufferSize = 32 ;
// Create the wave format structure. The data format setting will
// be determined later.
WAVEFORMATEX waveFormat ;
ZeroMemory ( & waveFormat , sizeof ( WAVEFORMATEX ) ) ;
waveFormat . wFormatTag = WAVE_FORMAT_PCM ;
waveFormat . nChannels = channels + firstChannel ;
waveFormat . nSamplesPerSec = ( unsigned long ) sampleRate ;
// Determine the device buffer size. By default, we'll use the value
// defined above (32K), but we will grow it to make allowances for
// very large software buffer sizes.
DWORD dsBufferSize = MINIMUM_DEVICE_BUFFER_SIZE ;
DWORD dsPointerLeadTime = 0 ;
void * ohandle = 0 , * bhandle = 0 ;
HRESULT result ;
if ( mode = = OUTPUT ) {
LPDIRECTSOUND output ;
result = DirectSoundCreate ( dsDevices [ device ] . id [ 0 ] , & output , NULL ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) opening output device ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
DSCAPS outCaps ;
outCaps . dwSize = sizeof ( outCaps ) ;
result = output - > GetCaps ( & outCaps ) ;
if ( FAILED ( result ) ) {
output - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) getting capabilities ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Check channel information.
if ( channels + firstChannel = = 2 & & ! ( outCaps . dwFlags & DSCAPS_PRIMARYSTEREO ) ) {
errorStream_ < < " RtApiDs::getDeviceInfo: the output device ( " < < dsDevices [ device ] . name < < " ) does not support stereo playback. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Check format information. Use 16-bit format unless not
// supported or user requests 8-bit.
if ( outCaps . dwFlags & DSCAPS_PRIMARY16BIT & &
! ( format = = RTAUDIO_SINT8 & & outCaps . dwFlags & DSCAPS_PRIMARY8BIT ) ) {
waveFormat . wBitsPerSample = 16 ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT16 ;
}
else {
waveFormat . wBitsPerSample = 8 ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT8 ;
}
stream_ . userFormat = format ;
// Update wave format structure and buffer information.
waveFormat . nBlockAlign = waveFormat . nChannels * waveFormat . wBitsPerSample / 8 ;
waveFormat . nAvgBytesPerSec = waveFormat . nSamplesPerSec * waveFormat . nBlockAlign ;
dsPointerLeadTime = nBuffers * ( * bufferSize ) * ( waveFormat . wBitsPerSample / 8 ) * channels ;
// If the user wants an even bigger buffer, increase the device buffer size accordingly.
while ( dsPointerLeadTime * 2U > dsBufferSize )
dsBufferSize * = 2 ;
// Set cooperative level to DSSCL_EXCLUSIVE ... sound stops when window focus changes.
// result = output->SetCooperativeLevel( hWnd, DSSCL_EXCLUSIVE );
// Set cooperative level to DSSCL_PRIORITY ... sound remains when window focus changes.
result = output - > SetCooperativeLevel ( hWnd , DSSCL_PRIORITY ) ;
if ( FAILED ( result ) ) {
output - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) setting cooperative level ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Even though we will write to the secondary buffer, we need to
// access the primary buffer to set the correct output format
// (since the default is 8-bit, 22 kHz!). Setup the DS primary
// buffer description.
DSBUFFERDESC bufferDescription ;
ZeroMemory ( & bufferDescription , sizeof ( DSBUFFERDESC ) ) ;
bufferDescription . dwSize = sizeof ( DSBUFFERDESC ) ;
bufferDescription . dwFlags = DSBCAPS_PRIMARYBUFFER ;
// Obtain the primary buffer
LPDIRECTSOUNDBUFFER buffer ;
result = output - > CreateSoundBuffer ( & bufferDescription , & buffer , NULL ) ;
if ( FAILED ( result ) ) {
output - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) accessing primary buffer ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Set the primary DS buffer sound format.
result = buffer - > SetFormat ( & waveFormat ) ;
if ( FAILED ( result ) ) {
output - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) setting primary buffer format ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Setup the secondary DS buffer description.
ZeroMemory ( & bufferDescription , sizeof ( DSBUFFERDESC ) ) ;
bufferDescription . dwSize = sizeof ( DSBUFFERDESC ) ;
bufferDescription . dwFlags = ( DSBCAPS_STICKYFOCUS |
DSBCAPS_GLOBALFOCUS |
DSBCAPS_GETCURRENTPOSITION2 |
DSBCAPS_LOCHARDWARE ) ; // Force hardware mixing
bufferDescription . dwBufferBytes = dsBufferSize ;
bufferDescription . lpwfxFormat = & waveFormat ;
// Try to create the secondary DS buffer. If that doesn't work,
// try to use software mixing. Otherwise, there's a problem.
result = output - > CreateSoundBuffer ( & bufferDescription , & buffer , NULL ) ;
if ( FAILED ( result ) ) {
bufferDescription . dwFlags = ( DSBCAPS_STICKYFOCUS |
DSBCAPS_GLOBALFOCUS |
DSBCAPS_GETCURRENTPOSITION2 |
DSBCAPS_LOCSOFTWARE ) ; // Force software mixing
result = output - > CreateSoundBuffer ( & bufferDescription , & buffer , NULL ) ;
if ( FAILED ( result ) ) {
output - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) creating secondary buffer ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
// Get the buffer size ... might be different from what we specified.
DSBCAPS dsbcaps ;
dsbcaps . dwSize = sizeof ( DSBCAPS ) ;
result = buffer - > GetCaps ( & dsbcaps ) ;
if ( FAILED ( result ) ) {
output - > Release ( ) ;
buffer - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) getting buffer settings ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
dsBufferSize = dsbcaps . dwBufferBytes ;
// Lock the DS buffer
LPVOID audioPtr ;
DWORD dataLen ;
result = buffer - > Lock ( 0 , dsBufferSize , & audioPtr , & dataLen , NULL , NULL , 0 ) ;
if ( FAILED ( result ) ) {
output - > Release ( ) ;
buffer - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) locking buffer ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Zero the DS buffer
ZeroMemory ( audioPtr , dataLen ) ;
// Unlock the DS buffer
result = buffer - > Unlock ( audioPtr , dataLen , NULL , 0 ) ;
if ( FAILED ( result ) ) {
output - > Release ( ) ;
buffer - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) unlocking buffer ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
ohandle = ( void * ) output ;
bhandle = ( void * ) buffer ;
}
if ( mode = = INPUT ) {
LPDIRECTSOUNDCAPTURE input ;
result = DirectSoundCaptureCreate ( dsDevices [ device ] . id [ 1 ] , & input , NULL ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) opening input device ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
DSCCAPS inCaps ;
inCaps . dwSize = sizeof ( inCaps ) ;
result = input - > GetCaps ( & inCaps ) ;
if ( FAILED ( result ) ) {
input - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) getting input capabilities ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Check channel information.
if ( inCaps . dwChannels < channels + firstChannel ) {
errorText_ = " RtApiDs::getDeviceInfo: the input device does not support requested input channels. " ;
return FAILURE ;
}
// Check format information. Use 16-bit format unless user
// requests 8-bit.
DWORD deviceFormats ;
if ( channels + firstChannel = = 2 ) {
deviceFormats = WAVE_FORMAT_1S08 | WAVE_FORMAT_2S08 | WAVE_FORMAT_4S08 | WAVE_FORMAT_96S08 ;
if ( format = = RTAUDIO_SINT8 & & inCaps . dwFormats & deviceFormats ) {
waveFormat . wBitsPerSample = 8 ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT8 ;
}
else { // assume 16-bit is supported
waveFormat . wBitsPerSample = 16 ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT16 ;
}
}
else { // channel == 1
deviceFormats = WAVE_FORMAT_1M08 | WAVE_FORMAT_2M08 | WAVE_FORMAT_4M08 | WAVE_FORMAT_96M08 ;
if ( format = = RTAUDIO_SINT8 & & inCaps . dwFormats & deviceFormats ) {
waveFormat . wBitsPerSample = 8 ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT8 ;
}
else { // assume 16-bit is supported
waveFormat . wBitsPerSample = 16 ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT16 ;
}
}
stream_ . userFormat = format ;
// Update wave format structure and buffer information.
waveFormat . nBlockAlign = waveFormat . nChannels * waveFormat . wBitsPerSample / 8 ;
waveFormat . nAvgBytesPerSec = waveFormat . nSamplesPerSec * waveFormat . nBlockAlign ;
dsPointerLeadTime = nBuffers * ( * bufferSize ) * ( waveFormat . wBitsPerSample / 8 ) * channels ;
// If the user wants an even bigger buffer, increase the device buffer size accordingly.
while ( dsPointerLeadTime * 2U > dsBufferSize )
dsBufferSize * = 2 ;
// Setup the secondary DS buffer description.
DSCBUFFERDESC bufferDescription ;
ZeroMemory ( & bufferDescription , sizeof ( DSCBUFFERDESC ) ) ;
bufferDescription . dwSize = sizeof ( DSCBUFFERDESC ) ;
bufferDescription . dwFlags = 0 ;
bufferDescription . dwReserved = 0 ;
bufferDescription . dwBufferBytes = dsBufferSize ;
bufferDescription . lpwfxFormat = & waveFormat ;
// Create the capture buffer.
LPDIRECTSOUNDCAPTUREBUFFER buffer ;
result = input - > CreateCaptureBuffer ( & bufferDescription , & buffer , NULL ) ;
if ( FAILED ( result ) ) {
input - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) creating input buffer ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Get the buffer size ... might be different from what we specified.
DSCBCAPS dscbcaps ;
dscbcaps . dwSize = sizeof ( DSCBCAPS ) ;
result = buffer - > GetCaps ( & dscbcaps ) ;
if ( FAILED ( result ) ) {
input - > Release ( ) ;
buffer - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) getting buffer settings ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
dsBufferSize = dscbcaps . dwBufferBytes ;
// NOTE: We could have a problem here if this is a duplex stream
// and the play and capture hardware buffer sizes are different
// (I'm actually not sure if that is a problem or not).
// Currently, we are not verifying that.
// Lock the capture buffer
LPVOID audioPtr ;
DWORD dataLen ;
result = buffer - > Lock ( 0 , dsBufferSize , & audioPtr , & dataLen , NULL , NULL , 0 ) ;
if ( FAILED ( result ) ) {
input - > Release ( ) ;
buffer - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) locking input buffer ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Zero the buffer
ZeroMemory ( audioPtr , dataLen ) ;
// Unlock the buffer
result = buffer - > Unlock ( audioPtr , dataLen , NULL , 0 ) ;
if ( FAILED ( result ) ) {
input - > Release ( ) ;
buffer - > Release ( ) ;
errorStream_ < < " RtApiDs::probeDeviceOpen: error ( " < < getErrorString ( result ) < < " ) unlocking input buffer ( " < < dsDevices [ device ] . name < < " )! " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
ohandle = ( void * ) input ;
bhandle = ( void * ) buffer ;
}
// Set various stream parameters
DsHandle * handle = 0 ;
stream_ . nDeviceChannels [ mode ] = channels + firstChannel ;
stream_ . nUserChannels [ mode ] = channels ;
stream_ . bufferSize = * bufferSize ;
stream_ . channelOffset [ mode ] = firstChannel ;
stream_ . deviceInterleaved [ mode ] = true ;
if ( options & & options - > flags & RTAUDIO_NONINTERLEAVED ) stream_ . userInterleaved = false ;
else stream_ . userInterleaved = true ;
// Set flag for buffer conversion
stream_ . doConvertBuffer [ mode ] = false ;
if ( stream_ . nUserChannels [ mode ] ! = stream_ . nDeviceChannels [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . userFormat ! = stream_ . deviceFormat [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . userInterleaved ! = stream_ . deviceInterleaved [ mode ] & &
stream_ . nUserChannels [ mode ] > 1 )
stream_ . doConvertBuffer [ mode ] = true ;
// Allocate necessary internal buffers
long bufferBytes = stream_ . nUserChannels [ mode ] * * bufferSize * formatBytes ( stream_ . userFormat ) ;
stream_ . userBuffer [ mode ] = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . userBuffer [ mode ] = = NULL ) {
errorText_ = " RtApiDs::probeDeviceOpen: error allocating user buffer memory. " ;
goto error ;
}
if ( stream_ . doConvertBuffer [ mode ] ) {
bool makeBuffer = true ;
bufferBytes = stream_ . nDeviceChannels [ mode ] * formatBytes ( stream_ . deviceFormat [ mode ] ) ;
if ( mode = = INPUT ) {
if ( stream_ . mode = = OUTPUT & & stream_ . deviceBuffer ) {
unsigned long bytesOut = stream_ . nDeviceChannels [ 0 ] * formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
if ( bufferBytes < = ( long ) bytesOut ) makeBuffer = false ;
}
}
if ( makeBuffer ) {
bufferBytes * = * bufferSize ;
if ( stream_ . deviceBuffer ) free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . deviceBuffer = = NULL ) {
errorText_ = " RtApiDs::probeDeviceOpen: error allocating device buffer memory. " ;
goto error ;
}
}
}
// Allocate our DsHandle structures for the stream.
if ( stream_ . apiHandle = = 0 ) {
try {
handle = new DsHandle ;
}
catch ( std : : bad_alloc & ) {
errorText_ = " RtApiDs::probeDeviceOpen: error allocating AsioHandle memory. " ;
goto error ;
}
// Create a manual-reset event.
handle - > condition = CreateEvent ( NULL , // no security
TRUE , // manual-reset
FALSE , // non-signaled initially
NULL ) ; // unnamed
stream_ . apiHandle = ( void * ) handle ;
}
else
handle = ( DsHandle * ) stream_ . apiHandle ;
handle - > id [ mode ] = ohandle ;
handle - > buffer [ mode ] = bhandle ;
handle - > dsBufferSize [ mode ] = dsBufferSize ;
handle - > dsPointerLeadTime [ mode ] = dsPointerLeadTime ;
stream_ . device [ mode ] = device ;
stream_ . state = STREAM_STOPPED ;
if ( stream_ . mode = = OUTPUT & & mode = = INPUT )
// We had already set up an output stream.
stream_ . mode = DUPLEX ;
else
stream_ . mode = mode ;
stream_ . nBuffers = nBuffers ;
stream_ . sampleRate = sampleRate ;
// Setup the buffer conversion information structure.
if ( stream_ . doConvertBuffer [ mode ] ) setConvertInfo ( mode , firstChannel ) ;
// Setup the callback thread.
if ( stream_ . callbackInfo . isRunning = = false ) {
unsigned threadId ;
stream_ . callbackInfo . isRunning = true ;
stream_ . callbackInfo . object = ( void * ) this ;
stream_ . callbackInfo . thread = _beginthreadex ( NULL , 0 , & callbackHandler ,
& stream_ . callbackInfo , 0 , & threadId ) ;
if ( stream_ . callbackInfo . thread = = 0 ) {
errorText_ = " RtApiDs::probeDeviceOpen: error creating callback thread! " ;
goto error ;
}
// Boost DS thread priority
SetThreadPriority ( ( HANDLE ) stream_ . callbackInfo . thread , THREAD_PRIORITY_HIGHEST ) ;
}
return SUCCESS ;
error :
if ( handle ) {
if ( handle - > buffer [ 0 ] ) { // the object pointer can be NULL and valid
LPDIRECTSOUND object = ( LPDIRECTSOUND ) handle - > id [ 0 ] ;
LPDIRECTSOUNDBUFFER buffer = ( LPDIRECTSOUNDBUFFER ) handle - > buffer [ 0 ] ;
if ( buffer ) buffer - > Release ( ) ;
object - > Release ( ) ;
}
if ( handle - > buffer [ 1 ] ) {
LPDIRECTSOUNDCAPTURE object = ( LPDIRECTSOUNDCAPTURE ) handle - > id [ 1 ] ;
LPDIRECTSOUNDCAPTUREBUFFER buffer = ( LPDIRECTSOUNDCAPTUREBUFFER ) handle - > buffer [ 1 ] ;
if ( buffer ) buffer - > Release ( ) ;
object - > Release ( ) ;
}
CloseHandle ( handle - > condition ) ;
delete handle ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
stream_ . state = STREAM_CLOSED ;
return FAILURE ;
}
void RtApiDs : : closeStream ( )
{
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiDs::closeStream(): no open stream to close! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
// Stop the callback thread.
stream_ . callbackInfo . isRunning = false ;
WaitForSingleObject ( ( HANDLE ) stream_ . callbackInfo . thread , INFINITE ) ;
CloseHandle ( ( HANDLE ) stream_ . callbackInfo . thread ) ;
DsHandle * handle = ( DsHandle * ) stream_ . apiHandle ;
if ( handle ) {
if ( handle - > buffer [ 0 ] ) { // the object pointer can be NULL and valid
LPDIRECTSOUND object = ( LPDIRECTSOUND ) handle - > id [ 0 ] ;
LPDIRECTSOUNDBUFFER buffer = ( LPDIRECTSOUNDBUFFER ) handle - > buffer [ 0 ] ;
if ( buffer ) {
buffer - > Stop ( ) ;
buffer - > Release ( ) ;
}
object - > Release ( ) ;
}
if ( handle - > buffer [ 1 ] ) {
LPDIRECTSOUNDCAPTURE object = ( LPDIRECTSOUNDCAPTURE ) handle - > id [ 1 ] ;
LPDIRECTSOUNDCAPTUREBUFFER buffer = ( LPDIRECTSOUNDCAPTUREBUFFER ) handle - > buffer [ 1 ] ;
if ( buffer ) {
buffer - > Stop ( ) ;
buffer - > Release ( ) ;
}
object - > Release ( ) ;
}
CloseHandle ( handle - > condition ) ;
delete handle ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
stream_ . mode = UNINITIALIZED ;
stream_ . state = STREAM_CLOSED ;
}
void RtApiDs : : startStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_RUNNING ) {
errorText_ = " RtApiDs::startStream(): the stream is already running! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
DsHandle * handle = ( DsHandle * ) stream_ . apiHandle ;
// Increase scheduler frequency on lesser windows (a side-effect of
// increasing timer accuracy). On greater windows (Win2K or later),
// this is already in effect.
timeBeginPeriod ( 1 ) ;
buffersRolling = false ;
duplexPrerollBytes = 0 ;
if ( stream_ . mode = = DUPLEX ) {
// 0.5 seconds of silence in DUPLEX mode while the devices spin up and synchronize.
duplexPrerollBytes = ( int ) ( 0.5 * stream_ . sampleRate * formatBytes ( stream_ . deviceFormat [ 1 ] ) * stream_ . nDeviceChannels [ 1 ] ) ;
}
HRESULT result = 0 ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
LPDIRECTSOUNDBUFFER buffer = ( LPDIRECTSOUNDBUFFER ) handle - > buffer [ 0 ] ;
result = buffer - > Play ( 0 , 0 , DSBPLAY_LOOPING ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::startStream: error ( " < < getErrorString ( result ) < < " ) starting output buffer! " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) {
LPDIRECTSOUNDCAPTUREBUFFER buffer = ( LPDIRECTSOUNDCAPTUREBUFFER ) handle - > buffer [ 1 ] ;
result = buffer - > Start ( DSCBSTART_LOOPING ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::startStream: error ( " < < getErrorString ( result ) < < " ) starting input buffer! " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
handle - > drainCounter = 0 ;
handle - > internalDrain = false ;
ResetEvent ( handle - > condition ) ;
stream_ . state = STREAM_RUNNING ;
unlock :
if ( FAILED ( result ) ) error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiDs : : stopStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiDs::stopStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
HRESULT result = 0 ;
LPVOID audioPtr ;
DWORD dataLen ;
DsHandle * handle = ( DsHandle * ) stream_ . apiHandle ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
if ( handle - > drainCounter = = 0 ) {
handle - > drainCounter = 2 ;
WaitForSingleObject ( handle - > condition , INFINITE ) ; // block until signaled
}
stream_ . state = STREAM_STOPPED ;
MUTEX_LOCK ( & stream_ . mutex ) ;
// Stop the buffer and clear memory
LPDIRECTSOUNDBUFFER buffer = ( LPDIRECTSOUNDBUFFER ) handle - > buffer [ 0 ] ;
result = buffer - > Stop ( ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::stopStream: error ( " < < getErrorString ( result ) < < " ) stopping output buffer! " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
// Lock the buffer and clear it so that if we start to play again,
// we won't have old data playing.
result = buffer - > Lock ( 0 , handle - > dsBufferSize [ 0 ] , & audioPtr , & dataLen , NULL , NULL , 0 ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::stopStream: error ( " < < getErrorString ( result ) < < " ) locking output buffer! " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
// Zero the DS buffer
ZeroMemory ( audioPtr , dataLen ) ;
// Unlock the DS buffer
result = buffer - > Unlock ( audioPtr , dataLen , NULL , 0 ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::stopStream: error ( " < < getErrorString ( result ) < < " ) unlocking output buffer! " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
// If we start playing again, we must begin at beginning of buffer.
handle - > bufferPointer [ 0 ] = 0 ;
}
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) {
LPDIRECTSOUNDCAPTUREBUFFER buffer = ( LPDIRECTSOUNDCAPTUREBUFFER ) handle - > buffer [ 1 ] ;
audioPtr = NULL ;
dataLen = 0 ;
stream_ . state = STREAM_STOPPED ;
if ( stream_ . mode ! = DUPLEX )
MUTEX_LOCK ( & stream_ . mutex ) ;
result = buffer - > Stop ( ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::stopStream: error ( " < < getErrorString ( result ) < < " ) stopping input buffer! " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
// Lock the buffer and clear it so that if we start to play again,
// we won't have old data playing.
result = buffer - > Lock ( 0 , handle - > dsBufferSize [ 1 ] , & audioPtr , & dataLen , NULL , NULL , 0 ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::stopStream: error ( " < < getErrorString ( result ) < < " ) locking input buffer! " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
// Zero the DS buffer
ZeroMemory ( audioPtr , dataLen ) ;
// Unlock the DS buffer
result = buffer - > Unlock ( audioPtr , dataLen , NULL , 0 ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::stopStream: error ( " < < getErrorString ( result ) < < " ) unlocking input buffer! " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
// If we start recording again, we must begin at beginning of buffer.
handle - > bufferPointer [ 1 ] = 0 ;
}
unlock :
timeEndPeriod ( 1 ) ; // revert to normal scheduler frequency on lesser windows.
MUTEX_UNLOCK ( & stream_ . mutex ) ;
if ( FAILED ( result ) ) error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiDs : : abortStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiDs::abortStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
DsHandle * handle = ( DsHandle * ) stream_ . apiHandle ;
handle - > drainCounter = 2 ;
stopStream ( ) ;
}
void RtApiDs : : callbackEvent ( )
{
if ( stream_ . state = = STREAM_STOPPED | | stream_ . state = = STREAM_STOPPING ) {
Sleep ( 50 ) ; // sleep 50 milliseconds
return ;
}
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiDs::callbackEvent(): the stream is closed ... this shouldn't happen! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
CallbackInfo * info = ( CallbackInfo * ) & stream_ . callbackInfo ;
DsHandle * handle = ( DsHandle * ) stream_ . apiHandle ;
// Check if we were draining the stream and signal is finished.
if ( handle - > drainCounter > stream_ . nBuffers + 2 ) {
stream_ . state = STREAM_STOPPING ;
if ( handle - > internalDrain = = false )
SetEvent ( handle - > condition ) ;
else
stopStream ( ) ;
return ;
}
// Invoke user callback to get fresh output data UNLESS we are
// draining stream.
if ( handle - > drainCounter = = 0 ) {
RtAudioCallback callback = ( RtAudioCallback ) info - > callback ;
double streamTime = getStreamTime ( ) ;
RtAudioStreamStatus status = 0 ;
if ( stream_ . mode ! = INPUT & & handle - > xrun [ 0 ] = = true ) {
status | = RTAUDIO_OUTPUT_UNDERFLOW ;
handle - > xrun [ 0 ] = false ;
}
if ( stream_ . mode ! = OUTPUT & & handle - > xrun [ 1 ] = = true ) {
status | = RTAUDIO_INPUT_OVERFLOW ;
handle - > xrun [ 1 ] = false ;
}
int cbReturnValue = callback ( stream_ . userBuffer [ 0 ] , stream_ . userBuffer [ 1 ] ,
stream_ . bufferSize , streamTime , status , info - > userData ) ;
if ( cbReturnValue = = 2 ) {
stream_ . state = STREAM_STOPPING ;
handle - > drainCounter = 2 ;
abortStream ( ) ;
return ;
}
else if ( cbReturnValue = = 1 ) {
handle - > drainCounter = 1 ;
handle - > internalDrain = true ;
}
}
HRESULT result ;
DWORD currentWritePointer , safeWritePointer ;
DWORD currentReadPointer , safeReadPointer ;
UINT nextWritePointer ;
LPVOID buffer1 = NULL ;
LPVOID buffer2 = NULL ;
DWORD bufferSize1 = 0 ;
DWORD bufferSize2 = 0 ;
char * buffer ;
long bufferBytes ;
MUTEX_LOCK ( & stream_ . mutex ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
MUTEX_UNLOCK ( & stream_ . mutex ) ;
return ;
}
if ( buffersRolling = = false ) {
if ( stream_ . mode = = DUPLEX ) {
//assert( handle->dsBufferSize[0] == handle->dsBufferSize[1] );
// It takes a while for the devices to get rolling. As a result,
// there's no guarantee that the capture and write device pointers
// will move in lockstep. Wait here for both devices to start
// rolling, and then set our buffer pointers accordingly.
// e.g. Crystal Drivers: the capture buffer starts up 5700 to 9600
// bytes later than the write buffer.
// Stub: a serious risk of having a pre-emptive scheduling round
// take place between the two GetCurrentPosition calls... but I'm
// really not sure how to solve the problem. Temporarily boost to
// Realtime priority, maybe; but I'm not sure what priority the
// DirectSound service threads run at. We *should* be roughly
// within a ms or so of correct.
LPDIRECTSOUNDBUFFER dsWriteBuffer = ( LPDIRECTSOUNDBUFFER ) handle - > buffer [ 0 ] ;
LPDIRECTSOUNDCAPTUREBUFFER dsCaptureBuffer = ( LPDIRECTSOUNDCAPTUREBUFFER ) handle - > buffer [ 1 ] ;
DWORD startSafeWritePointer , startSafeReadPointer ;
result = dsWriteBuffer - > GetCurrentPosition ( NULL , & startSafeWritePointer ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) getting current write position! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
result = dsCaptureBuffer - > GetCurrentPosition ( NULL , & startSafeReadPointer ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) getting current read position! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
while ( true ) {
result = dsWriteBuffer - > GetCurrentPosition ( NULL , & safeWritePointer ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) getting current write position! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
result = dsCaptureBuffer - > GetCurrentPosition ( NULL , & safeReadPointer ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) getting current read position! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
if ( safeWritePointer ! = startSafeWritePointer & & safeReadPointer ! = startSafeReadPointer ) break ;
Sleep ( 1 ) ;
}
//assert( handle->dsBufferSize[0] == handle->dsBufferSize[1] );
handle - > bufferPointer [ 0 ] = safeWritePointer + handle - > dsPointerLeadTime [ 0 ] ;
if ( handle - > bufferPointer [ 0 ] > = handle - > dsBufferSize [ 0 ] ) handle - > bufferPointer [ 0 ] - = handle - > dsBufferSize [ 0 ] ;
handle - > bufferPointer [ 1 ] = safeReadPointer ;
}
else if ( stream_ . mode = = OUTPUT ) {
// Set the proper nextWritePosition after initial startup.
LPDIRECTSOUNDBUFFER dsWriteBuffer = ( LPDIRECTSOUNDBUFFER ) handle - > buffer [ 0 ] ;
result = dsWriteBuffer - > GetCurrentPosition ( & currentWritePointer , & safeWritePointer ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) getting current write position! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
handle - > bufferPointer [ 0 ] = safeWritePointer + handle - > dsPointerLeadTime [ 0 ] ;
if ( handle - > bufferPointer [ 0 ] > = handle - > dsBufferSize [ 0 ] ) handle - > bufferPointer [ 0 ] - = handle - > dsBufferSize [ 0 ] ;
}
buffersRolling = true ;
}
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
LPDIRECTSOUNDBUFFER dsBuffer = ( LPDIRECTSOUNDBUFFER ) handle - > buffer [ 0 ] ;
if ( handle - > drainCounter > 1 ) { // write zeros to the output stream
bufferBytes = stream_ . bufferSize * stream_ . nUserChannels [ 0 ] ;
bufferBytes * = formatBytes ( stream_ . userFormat ) ;
memset ( stream_ . userBuffer [ 0 ] , 0 , bufferBytes ) ;
}
// Setup parameters and do buffer conversion if necessary.
if ( stream_ . doConvertBuffer [ 0 ] ) {
buffer = stream_ . deviceBuffer ;
convertBuffer ( buffer , stream_ . userBuffer [ 0 ] , stream_ . convertInfo [ 0 ] ) ;
bufferBytes = stream_ . bufferSize * stream_ . nDeviceChannels [ 0 ] ;
bufferBytes * = formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
}
else {
buffer = stream_ . userBuffer [ 0 ] ;
bufferBytes = stream_ . bufferSize * stream_ . nUserChannels [ 0 ] ;
bufferBytes * = formatBytes ( stream_ . userFormat ) ;
}
// No byte swapping necessary in DirectSound implementation.
// Ahhh ... windoze. 16-bit data is signed but 8-bit data is
// unsigned. So, we need to convert our signed 8-bit data here to
// unsigned.
if ( stream_ . deviceFormat [ 0 ] = = RTAUDIO_SINT8 )
for ( int i = 0 ; i < bufferBytes ; i + + ) buffer [ i ] = ( unsigned char ) ( buffer [ i ] + 128 ) ;
DWORD dsBufferSize = handle - > dsBufferSize [ 0 ] ;
nextWritePointer = handle - > bufferPointer [ 0 ] ;
DWORD endWrite , leadPointer ;
while ( true ) {
// Find out where the read and "safe write" pointers are.
result = dsBuffer - > GetCurrentPosition ( & currentWritePointer , & safeWritePointer ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) getting current write position! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
// We will copy our output buffer into the region between
// safeWritePointer and leadPointer. If leadPointer is not
// beyond the next endWrite position, wait until it is.
leadPointer = safeWritePointer + handle - > dsPointerLeadTime [ 0 ] ;
//std::cout << "safeWritePointer = " << safeWritePointer << ", leadPointer = " << leadPointer << ", nextWritePointer = " << nextWritePointer << std::endl;
if ( leadPointer > dsBufferSize ) leadPointer - = dsBufferSize ;
if ( leadPointer < nextWritePointer ) leadPointer + = dsBufferSize ; // unwrap offset
endWrite = nextWritePointer + bufferBytes ;
// Check whether the entire write region is behind the play pointer.
if ( leadPointer > = endWrite ) break ;
// If we are here, then we must wait until the leadPointer advances
// beyond the end of our next write region. We use the
// Sleep() function to suspend operation until that happens.
double millis = ( endWrite - leadPointer ) * 1000.0 ;
millis / = ( formatBytes ( stream_ . deviceFormat [ 0 ] ) * stream_ . nDeviceChannels [ 0 ] * stream_ . sampleRate ) ;
if ( millis < 1.0 ) millis = 1.0 ;
Sleep ( ( DWORD ) millis ) ;
}
if ( dsPointerBetween ( nextWritePointer , safeWritePointer , currentWritePointer , dsBufferSize )
| | dsPointerBetween ( endWrite , safeWritePointer , currentWritePointer , dsBufferSize ) ) {
// We've strayed into the forbidden zone ... resync the read pointer.
handle - > xrun [ 0 ] = true ;
nextWritePointer = safeWritePointer + handle - > dsPointerLeadTime [ 0 ] - bufferBytes ;
if ( nextWritePointer > = dsBufferSize ) nextWritePointer - = dsBufferSize ;
handle - > bufferPointer [ 0 ] = nextWritePointer ;
endWrite = nextWritePointer + bufferBytes ;
}
// Lock free space in the buffer
result = dsBuffer - > Lock ( nextWritePointer , bufferBytes , & buffer1 ,
& bufferSize1 , & buffer2 , & bufferSize2 , 0 ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) locking buffer during playback! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
// Copy our buffer into the DS buffer
CopyMemory ( buffer1 , buffer , bufferSize1 ) ;
if ( buffer2 ! = NULL ) CopyMemory ( buffer2 , buffer + bufferSize1 , bufferSize2 ) ;
// Update our buffer offset and unlock sound buffer
dsBuffer - > Unlock ( buffer1 , bufferSize1 , buffer2 , bufferSize2 ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) unlocking buffer during playback! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
nextWritePointer = ( nextWritePointer + bufferSize1 + bufferSize2 ) % dsBufferSize ;
handle - > bufferPointer [ 0 ] = nextWritePointer ;
}
// Don't bother draining input
if ( handle - > drainCounter ) {
handle - > drainCounter + + ;
goto unlock ;
}
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) {
// Setup parameters.
if ( stream_ . doConvertBuffer [ 1 ] ) {
buffer = stream_ . deviceBuffer ;
bufferBytes = stream_ . bufferSize * stream_ . nDeviceChannels [ 1 ] ;
bufferBytes * = formatBytes ( stream_ . deviceFormat [ 1 ] ) ;
}
else {
buffer = stream_ . userBuffer [ 1 ] ;
bufferBytes = stream_ . bufferSize * stream_ . nUserChannels [ 1 ] ;
bufferBytes * = formatBytes ( stream_ . userFormat ) ;
}
LPDIRECTSOUNDCAPTUREBUFFER dsBuffer = ( LPDIRECTSOUNDCAPTUREBUFFER ) handle - > buffer [ 1 ] ;
long nextReadPointer = handle - > bufferPointer [ 1 ] ;
DWORD dsBufferSize = handle - > dsBufferSize [ 1 ] ;
// Find out where the write and "safe read" pointers are.
result = dsBuffer - > GetCurrentPosition ( & currentReadPointer , & safeReadPointer ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) getting current read position! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
if ( safeReadPointer < ( DWORD ) nextReadPointer ) safeReadPointer + = dsBufferSize ; // unwrap offset
DWORD endRead = nextReadPointer + bufferBytes ;
// Handling depends on whether we are INPUT or DUPLEX.
// If we're in INPUT mode then waiting is a good thing. If we're in DUPLEX mode,
// then a wait here will drag the write pointers into the forbidden zone.
//
// In DUPLEX mode, rather than wait, we will back off the read pointer until
// it's in a safe position. This causes dropouts, but it seems to be the only
// practical way to sync up the read and write pointers reliably, given the
// the very complex relationship between phase and increment of the read and write
// pointers.
//
// In order to minimize audible dropouts in DUPLEX mode, we will
// provide a pre-roll period of 0.5 seconds in which we return
// zeros from the read buffer while the pointers sync up.
if ( stream_ . mode = = DUPLEX ) {
if ( safeReadPointer < endRead ) {
if ( duplexPrerollBytes < = 0 ) {
// Pre-roll time over. Be more agressive.
int adjustment = endRead - safeReadPointer ;
handle - > xrun [ 1 ] = true ;
// Two cases:
// - large adjustments: we've probably run out of CPU cycles, so just resync exactly,
// and perform fine adjustments later.
// - small adjustments: back off by twice as much.
if ( adjustment > = 2 * bufferBytes )
nextReadPointer = safeReadPointer - 2 * bufferBytes ;
else
nextReadPointer = safeReadPointer - bufferBytes - adjustment ;
if ( nextReadPointer < 0 ) nextReadPointer + = dsBufferSize ;
}
else {
// In pre=roll time. Just do it.
nextReadPointer = safeReadPointer - bufferBytes ;
while ( nextReadPointer < 0 ) nextReadPointer + = dsBufferSize ;
}
endRead = nextReadPointer + bufferBytes ;
}
}
else { // mode == INPUT
while ( safeReadPointer < endRead & & stream_ . callbackInfo . isRunning ) {
// See comments for playback.
double millis = ( endRead - safeReadPointer ) * 1000.0 ;
millis / = ( formatBytes ( stream_ . deviceFormat [ 1 ] ) * stream_ . nDeviceChannels [ 1 ] * stream_ . sampleRate ) ;
if ( millis < 1.0 ) millis = 1.0 ;
Sleep ( ( DWORD ) millis ) ;
// Wake up and find out where we are now.
result = dsBuffer - > GetCurrentPosition ( & currentReadPointer , & safeReadPointer ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) getting current read position! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
if ( safeReadPointer < ( DWORD ) nextReadPointer ) safeReadPointer + = dsBufferSize ; // unwrap offset
}
}
// Lock free space in the buffer
result = dsBuffer - > Lock ( nextReadPointer , bufferBytes , & buffer1 ,
& bufferSize1 , & buffer2 , & bufferSize2 , 0 ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) locking capture buffer! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
if ( duplexPrerollBytes < = 0 ) {
// Copy our buffer into the DS buffer
CopyMemory ( buffer , buffer1 , bufferSize1 ) ;
if ( buffer2 ! = NULL ) CopyMemory ( buffer + bufferSize1 , buffer2 , bufferSize2 ) ;
}
else {
memset ( buffer , 0 , bufferSize1 ) ;
if ( buffer2 ! = NULL ) memset ( buffer + bufferSize1 , 0 , bufferSize2 ) ;
duplexPrerollBytes - = bufferSize1 + bufferSize2 ;
}
// Update our buffer offset and unlock sound buffer
nextReadPointer = ( nextReadPointer + bufferSize1 + bufferSize2 ) % dsBufferSize ;
dsBuffer - > Unlock ( buffer1 , bufferSize1 , buffer2 , bufferSize2 ) ;
if ( FAILED ( result ) ) {
errorStream_ < < " RtApiDs::callbackEvent: error ( " < < getErrorString ( result ) < < " ) unlocking capture buffer! " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
handle - > bufferPointer [ 1 ] = nextReadPointer ;
// No byte swapping necessary in DirectSound implementation.
// If necessary, convert 8-bit data from unsigned to signed.
if ( stream_ . deviceFormat [ 1 ] = = RTAUDIO_SINT8 )
for ( int j = 0 ; j < bufferBytes ; j + + ) buffer [ j ] = ( signed char ) ( buffer [ j ] - 128 ) ;
// Do buffer conversion if necessary.
if ( stream_ . doConvertBuffer [ 1 ] )
convertBuffer ( stream_ . userBuffer [ 1 ] , stream_ . deviceBuffer , stream_ . convertInfo [ 1 ] ) ;
}
unlock :
MUTEX_UNLOCK ( & stream_ . mutex ) ;
RtApi : : tickStreamTime ( ) ;
}
// Definitions for utility functions and callbacks
// specific to the DirectSound implementation.
static unsigned __stdcall callbackHandler ( void * ptr )
{
CallbackInfo * info = ( CallbackInfo * ) ptr ;
RtApiDs * object = ( RtApiDs * ) info - > object ;
bool * isRunning = & info - > isRunning ;
while ( * isRunning = = true ) {
object - > callbackEvent ( ) ;
}
_endthreadex ( 0 ) ;
return 0 ;
}
# include "tchar.h"
static std : : string convertTChar ( LPCTSTR name )
{
# if defined( UNICODE ) || defined( _UNICODE )
int length = WideCharToMultiByte ( CP_UTF8 , 0 , name , - 1 , NULL , 0 , NULL , NULL ) ;
std : : string s ( length - 1 , ' \0 ' ) ;
WideCharToMultiByte ( CP_UTF8 , 0 , name , - 1 , & s [ 0 ] , length , NULL , NULL ) ;
# else
std : : string s ( name ) ;
# endif
return s ;
}
static BOOL CALLBACK deviceQueryCallback ( LPGUID lpguid ,
LPCTSTR description ,
LPCTSTR /*module*/ ,
LPVOID lpContext )
{
struct DsProbeData & probeInfo = * ( struct DsProbeData * ) lpContext ;
std : : vector < struct DsDevice > & dsDevices = * probeInfo . dsDevices ;
HRESULT hr ;
bool validDevice = false ;
if ( probeInfo . isInput = = true ) {
DSCCAPS caps ;
LPDIRECTSOUNDCAPTURE object ;
hr = DirectSoundCaptureCreate ( lpguid , & object , NULL ) ;
if ( hr ! = DS_OK ) return TRUE ;
caps . dwSize = sizeof ( caps ) ;
hr = object - > GetCaps ( & caps ) ;
if ( hr = = DS_OK ) {
if ( caps . dwChannels > 0 & & caps . dwFormats > 0 )
validDevice = true ;
}
object - > Release ( ) ;
}
else {
DSCAPS caps ;
LPDIRECTSOUND object ;
hr = DirectSoundCreate ( lpguid , & object , NULL ) ;
if ( hr ! = DS_OK ) return TRUE ;
caps . dwSize = sizeof ( caps ) ;
hr = object - > GetCaps ( & caps ) ;
if ( hr = = DS_OK ) {
if ( caps . dwFlags & DSCAPS_PRIMARYMONO | | caps . dwFlags & DSCAPS_PRIMARYSTEREO )
validDevice = true ;
}
object - > Release ( ) ;
}
// If good device, then save its name and guid.
std : : string name = convertTChar ( description ) ;
//if ( name == "Primary Sound Driver" || name == "Primary Sound Capture Driver" )
if ( lpguid = = NULL )
name = " Default Device " ;
if ( validDevice ) {
for ( unsigned int i = 0 ; i < dsDevices . size ( ) ; i + + ) {
if ( dsDevices [ i ] . name = = name ) {
dsDevices [ i ] . found = true ;
if ( probeInfo . isInput ) {
dsDevices [ i ] . id [ 1 ] = lpguid ;
dsDevices [ i ] . validId [ 1 ] = true ;
}
else {
dsDevices [ i ] . id [ 0 ] = lpguid ;
dsDevices [ i ] . validId [ 0 ] = true ;
}
return TRUE ;
}
}
DsDevice device ;
device . name = name ;
device . found = true ;
if ( probeInfo . isInput ) {
device . id [ 1 ] = lpguid ;
device . validId [ 1 ] = true ;
}
else {
device . id [ 0 ] = lpguid ;
device . validId [ 0 ] = true ;
}
dsDevices . push_back ( device ) ;
}
return TRUE ;
}
static const char * getErrorString ( int code )
{
switch ( code ) {
case DSERR_ALLOCATED :
return " Already allocated " ;
case DSERR_CONTROLUNAVAIL :
return " Control unavailable " ;
case DSERR_INVALIDPARAM :
return " Invalid parameter " ;
case DSERR_INVALIDCALL :
return " Invalid call " ;
case DSERR_GENERIC :
return " Generic error " ;
case DSERR_PRIOLEVELNEEDED :
return " Priority level needed " ;
case DSERR_OUTOFMEMORY :
return " Out of memory " ;
case DSERR_BADFORMAT :
return " The sample rate or the channel format is not supported " ;
case DSERR_UNSUPPORTED :
return " Not supported " ;
case DSERR_NODRIVER :
return " No driver " ;
case DSERR_ALREADYINITIALIZED :
return " Already initialized " ;
case DSERR_NOAGGREGATION :
return " No aggregation " ;
case DSERR_BUFFERLOST :
return " Buffer lost " ;
case DSERR_OTHERAPPHASPRIO :
return " Another application already has priority " ;
case DSERR_UNINITIALIZED :
return " Uninitialized " ;
default :
return " DirectSound unknown error " ;
}
}
//******************** End of __WINDOWS_DS__ *********************//
# endif
# if defined(__LINUX_ALSA__)
# include <alsa/asoundlib.h>
# include <unistd.h>
// A structure to hold various information related to the ALSA API
// implementation.
struct AlsaHandle {
snd_pcm_t * handles [ 2 ] ;
bool synchronized ;
bool xrun [ 2 ] ;
pthread_cond_t runnable_cv ;
bool runnable ;
AlsaHandle ( )
: synchronized ( false ) , runnable ( false ) { xrun [ 0 ] = false ; xrun [ 1 ] = false ; }
} ;
static void * alsaCallbackHandler ( void * ptr ) ;
RtApiAlsa : : RtApiAlsa ( )
{
// Nothing to do here.
}
RtApiAlsa : : ~ RtApiAlsa ( )
{
if ( stream_ . state ! = STREAM_CLOSED ) closeStream ( ) ;
}
unsigned int RtApiAlsa : : getDeviceCount ( void )
{
unsigned nDevices = 0 ;
int result , subdevice , card ;
char name [ 64 ] ;
snd_ctl_t * handle ;
// Count cards and devices
card = - 1 ;
snd_card_next ( & card ) ;
while ( card > = 0 ) {
sprintf ( name , " hw:%d " , card ) ;
result = snd_ctl_open ( & handle , name , 0 ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::getDeviceCount: control open, card = " < < card < < " , " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
goto nextcard ;
}
subdevice = - 1 ;
while ( 1 ) {
result = snd_ctl_pcm_next_device ( handle , & subdevice ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::getDeviceCount: control next device, card = " < < card < < " , " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
break ;
}
if ( subdevice < 0 )
break ;
nDevices + + ;
}
nextcard :
snd_ctl_close ( handle ) ;
snd_card_next ( & card ) ;
}
result = snd_ctl_open ( & handle , " default " , 0 ) ;
if ( result = = 0 ) {
nDevices + + ;
snd_ctl_close ( handle ) ;
}
return nDevices ;
}
RtAudio : : DeviceInfo RtApiAlsa : : getDeviceInfo ( unsigned int device )
{
RtAudio : : DeviceInfo info ;
info . probed = false ;
unsigned nDevices = 0 ;
int result , subdevice , card ;
char name [ 64 ] ;
snd_ctl_t * chandle ;
// Count cards and devices
card = - 1 ;
snd_card_next ( & card ) ;
while ( card > = 0 ) {
sprintf ( name , " hw:%d " , card ) ;
result = snd_ctl_open ( & chandle , name , SND_CTL_NONBLOCK ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::getDeviceInfo: control open, card = " < < card < < " , " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
goto nextcard ;
}
subdevice = - 1 ;
while ( 1 ) {
result = snd_ctl_pcm_next_device ( chandle , & subdevice ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::getDeviceInfo: control next device, card = " < < card < < " , " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
break ;
}
if ( subdevice < 0 ) break ;
if ( nDevices = = device ) {
sprintf ( name , " hw:%d,%d " , card , subdevice ) ;
goto foundDevice ;
}
nDevices + + ;
}
nextcard :
snd_ctl_close ( chandle ) ;
snd_card_next ( & card ) ;
}
result = snd_ctl_open ( & chandle , " default " , SND_CTL_NONBLOCK ) ;
if ( result = = 0 ) {
if ( nDevices = = device ) {
strcpy ( name , " default " ) ;
goto foundDevice ;
}
nDevices + + ;
}
if ( nDevices = = 0 ) {
errorText_ = " RtApiAlsa::getDeviceInfo: no devices found! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
if ( device > = nDevices ) {
errorText_ = " RtApiAlsa::getDeviceInfo: device ID is invalid! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
foundDevice :
// If a stream is already open, we cannot probe the stream devices.
// Thus, use the saved results.
if ( stream_ . state ! = STREAM_CLOSED & &
( stream_ . device [ 0 ] = = device | | stream_ . device [ 1 ] = = device ) ) {
snd_ctl_close ( chandle ) ;
if ( device > = devices_ . size ( ) ) {
errorText_ = " RtApiAlsa::getDeviceInfo: device ID was not present before stream was opened. " ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
return devices_ [ device ] ;
}
int openMode = SND_PCM_ASYNC ;
snd_pcm_stream_t stream ;
snd_pcm_info_t * pcminfo ;
snd_pcm_info_alloca ( & pcminfo ) ;
snd_pcm_t * phandle ;
snd_pcm_hw_params_t * params ;
snd_pcm_hw_params_alloca ( & params ) ;
// First try for playback unless default device (which has subdev -1)
stream = SND_PCM_STREAM_PLAYBACK ;
snd_pcm_info_set_stream ( pcminfo , stream ) ;
if ( subdevice ! = - 1 ) {
snd_pcm_info_set_device ( pcminfo , subdevice ) ;
snd_pcm_info_set_subdevice ( pcminfo , 0 ) ;
result = snd_ctl_pcm_info ( chandle , pcminfo ) ;
if ( result < 0 ) {
// Device probably doesn't support playback.
goto captureProbe ;
}
}
result = snd_pcm_open ( & phandle , name , stream , openMode | SND_PCM_NONBLOCK ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::getDeviceInfo: snd_pcm_open error for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
goto captureProbe ;
}
// The device is open ... fill the parameter structure.
result = snd_pcm_hw_params_any ( phandle , params ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::getDeviceInfo: snd_pcm_hw_params error for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
goto captureProbe ;
}
// Get output channel information.
unsigned int value ;
result = snd_pcm_hw_params_get_channels_max ( params , & value ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::getDeviceInfo: error getting device ( " < < name < < " ) output channels, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
goto captureProbe ;
}
info . outputChannels = value ;
snd_pcm_close ( phandle ) ;
captureProbe :
stream = SND_PCM_STREAM_CAPTURE ;
snd_pcm_info_set_stream ( pcminfo , stream ) ;
// Now try for capture unless default device (with subdev = -1)
if ( subdevice ! = - 1 ) {
result = snd_ctl_pcm_info ( chandle , pcminfo ) ;
snd_ctl_close ( chandle ) ;
if ( result < 0 ) {
// Device probably doesn't support capture.
if ( info . outputChannels = = 0 ) return info ;
goto probeParameters ;
}
}
else
snd_ctl_close ( chandle ) ;
result = snd_pcm_open ( & phandle , name , stream , openMode | SND_PCM_NONBLOCK ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::getDeviceInfo: snd_pcm_open error for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
if ( info . outputChannels = = 0 ) return info ;
goto probeParameters ;
}
// The device is open ... fill the parameter structure.
result = snd_pcm_hw_params_any ( phandle , params ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::getDeviceInfo: snd_pcm_hw_params error for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
if ( info . outputChannels = = 0 ) return info ;
goto probeParameters ;
}
result = snd_pcm_hw_params_get_channels_max ( params , & value ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::getDeviceInfo: error getting device ( " < < name < < " ) input channels, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
if ( info . outputChannels = = 0 ) return info ;
goto probeParameters ;
}
info . inputChannels = value ;
snd_pcm_close ( phandle ) ;
// If device opens for both playback and capture, we determine the channels.
if ( info . outputChannels > 0 & & info . inputChannels > 0 )
info . duplexChannels = ( info . outputChannels > info . inputChannels ) ? info . inputChannels : info . outputChannels ;
// ALSA doesn't provide default devices so we'll use the first available one.
if ( device = = 0 & & info . outputChannels > 0 )
info . isDefaultOutput = true ;
if ( device = = 0 & & info . inputChannels > 0 )
info . isDefaultInput = true ;
probeParameters :
// At this point, we just need to figure out the supported data
// formats and sample rates. We'll proceed by opening the device in
// the direction with the maximum number of channels, or playback if
// they are equal. This might limit our sample rate options, but so
// be it.
if ( info . outputChannels > = info . inputChannels )
stream = SND_PCM_STREAM_PLAYBACK ;
else
stream = SND_PCM_STREAM_CAPTURE ;
snd_pcm_info_set_stream ( pcminfo , stream ) ;
result = snd_pcm_open ( & phandle , name , stream , openMode | SND_PCM_NONBLOCK ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::getDeviceInfo: snd_pcm_open error for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// The device is open ... fill the parameter structure.
result = snd_pcm_hw_params_any ( phandle , params ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::getDeviceInfo: snd_pcm_hw_params error for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Test our discrete set of sample rate values.
info . sampleRates . clear ( ) ;
for ( unsigned int i = 0 ; i < MAX_SAMPLE_RATES ; i + + ) {
if ( snd_pcm_hw_params_test_rate ( phandle , params , SAMPLE_RATES [ i ] , 0 ) = = 0 )
info . sampleRates . push_back ( SAMPLE_RATES [ i ] ) ;
}
if ( info . sampleRates . size ( ) = = 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::getDeviceInfo: no supported sample rates found for device ( " < < name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Probe the supported data formats ... we don't care about endian-ness just yet
snd_pcm_format_t format ;
info . nativeFormats = 0 ;
format = SND_PCM_FORMAT_S8 ;
if ( snd_pcm_hw_params_test_format ( phandle , params , format ) = = 0 )
info . nativeFormats | = RTAUDIO_SINT8 ;
format = SND_PCM_FORMAT_S16 ;
if ( snd_pcm_hw_params_test_format ( phandle , params , format ) = = 0 )
info . nativeFormats | = RTAUDIO_SINT16 ;
format = SND_PCM_FORMAT_S24 ;
if ( snd_pcm_hw_params_test_format ( phandle , params , format ) = = 0 )
info . nativeFormats | = RTAUDIO_SINT24 ;
format = SND_PCM_FORMAT_S32 ;
if ( snd_pcm_hw_params_test_format ( phandle , params , format ) = = 0 )
info . nativeFormats | = RTAUDIO_SINT32 ;
format = SND_PCM_FORMAT_FLOAT ;
if ( snd_pcm_hw_params_test_format ( phandle , params , format ) = = 0 )
info . nativeFormats | = RTAUDIO_FLOAT32 ;
format = SND_PCM_FORMAT_FLOAT64 ;
if ( snd_pcm_hw_params_test_format ( phandle , params , format ) = = 0 )
info . nativeFormats | = RTAUDIO_FLOAT64 ;
// Check that we have at least one supported format
if ( info . nativeFormats = = 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::getDeviceInfo: pcm device ( " < < name < < " ) data format not supported by RtAudio. " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Get the device name
char * cardname ;
result = snd_card_get_name ( card , & cardname ) ;
if ( result > = 0 ) {
sprintf ( name , " hw:%s,%d " , cardname , subdevice ) ;
free ( cardname ) ;
}
info . name = name ;
// That's all ... close the device and return
snd_pcm_close ( phandle ) ;
info . probed = true ;
return info ;
}
void RtApiAlsa : : saveDeviceInfo ( void )
{
devices_ . clear ( ) ;
unsigned int nDevices = getDeviceCount ( ) ;
devices_ . resize ( nDevices ) ;
for ( unsigned int i = 0 ; i < nDevices ; i + + )
devices_ [ i ] = getDeviceInfo ( i ) ;
}
bool RtApiAlsa : : probeDeviceOpen ( unsigned int device , StreamMode mode , unsigned int channels ,
unsigned int firstChannel , unsigned int sampleRate ,
RtAudioFormat format , unsigned int * bufferSize ,
RtAudio : : StreamOptions * options )
{
# if defined(__RTAUDIO_DEBUG__)
snd_output_t * out ;
snd_output_stdio_attach ( & out , stderr , 0 ) ;
# endif
// I'm not using the "plug" interface ... too much inconsistent behavior.
unsigned nDevices = 0 ;
int result , subdevice , card ;
char name [ 64 ] ;
snd_ctl_t * chandle ;
if ( options & & options - > flags & RTAUDIO_ALSA_USE_DEFAULT )
snprintf ( name , sizeof ( name ) , " %s " , " default " ) ;
else {
// Count cards and devices
card = - 1 ;
snd_card_next ( & card ) ;
while ( card > = 0 ) {
sprintf ( name , " hw:%d " , card ) ;
result = snd_ctl_open ( & chandle , name , SND_CTL_NONBLOCK ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::probeDeviceOpen: control open, card = " < < card < < " , " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
subdevice = - 1 ;
while ( 1 ) {
result = snd_ctl_pcm_next_device ( chandle , & subdevice ) ;
if ( result < 0 ) break ;
if ( subdevice < 0 ) break ;
if ( nDevices = = device ) {
sprintf ( name , " hw:%d,%d " , card , subdevice ) ;
snd_ctl_close ( chandle ) ;
goto foundDevice ;
}
nDevices + + ;
}
snd_ctl_close ( chandle ) ;
snd_card_next ( & card ) ;
}
result = snd_ctl_open ( & chandle , " default " , SND_CTL_NONBLOCK ) ;
if ( result = = 0 ) {
if ( nDevices = = device ) {
strcpy ( name , " default " ) ;
goto foundDevice ;
}
nDevices + + ;
}
if ( nDevices = = 0 ) {
// This should not happen because a check is made before this function is called.
errorText_ = " RtApiAlsa::probeDeviceOpen: no devices found! " ;
return FAILURE ;
}
if ( device > = nDevices ) {
// This should not happen because a check is made before this function is called.
errorText_ = " RtApiAlsa::probeDeviceOpen: device ID is invalid! " ;
return FAILURE ;
}
}
foundDevice :
// The getDeviceInfo() function will not work for a device that is
// already open. Thus, we'll probe the system before opening a
// stream and save the results for use by getDeviceInfo().
if ( mode = = OUTPUT | | ( mode = = INPUT & & stream_ . mode ! = OUTPUT ) ) // only do once
this - > saveDeviceInfo ( ) ;
snd_pcm_stream_t stream ;
if ( mode = = OUTPUT )
stream = SND_PCM_STREAM_PLAYBACK ;
else
stream = SND_PCM_STREAM_CAPTURE ;
snd_pcm_t * phandle ;
int openMode = SND_PCM_ASYNC ;
result = snd_pcm_open ( & phandle , name , stream , openMode ) ;
if ( result < 0 ) {
if ( mode = = OUTPUT )
errorStream_ < < " RtApiAlsa::probeDeviceOpen: pcm device ( " < < name < < " ) won't open for output. " ;
else
errorStream_ < < " RtApiAlsa::probeDeviceOpen: pcm device ( " < < name < < " ) won't open for input. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Fill the parameter structure.
snd_pcm_hw_params_t * hw_params ;
snd_pcm_hw_params_alloca ( & hw_params ) ;
result = snd_pcm_hw_params_any ( phandle , hw_params ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error getting pcm device ( " < < name < < " ) parameters, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
# if defined(__RTAUDIO_DEBUG__)
fprintf ( stderr , " \n RtApiAlsa: dump hardware params just after device open: \n \n " ) ;
snd_pcm_hw_params_dump ( hw_params , out ) ;
# endif
// Set access ... check user preference.
if ( options & & options - > flags & RTAUDIO_NONINTERLEAVED ) {
stream_ . userInterleaved = false ;
result = snd_pcm_hw_params_set_access ( phandle , hw_params , SND_PCM_ACCESS_RW_NONINTERLEAVED ) ;
if ( result < 0 ) {
result = snd_pcm_hw_params_set_access ( phandle , hw_params , SND_PCM_ACCESS_RW_INTERLEAVED ) ;
stream_ . deviceInterleaved [ mode ] = true ;
}
else
stream_ . deviceInterleaved [ mode ] = false ;
}
else {
stream_ . userInterleaved = true ;
result = snd_pcm_hw_params_set_access ( phandle , hw_params , SND_PCM_ACCESS_RW_INTERLEAVED ) ;
if ( result < 0 ) {
result = snd_pcm_hw_params_set_access ( phandle , hw_params , SND_PCM_ACCESS_RW_NONINTERLEAVED ) ;
stream_ . deviceInterleaved [ mode ] = false ;
}
else
stream_ . deviceInterleaved [ mode ] = true ;
}
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error setting pcm device ( " < < name < < " ) access, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Determine how to set the device format.
stream_ . userFormat = format ;
snd_pcm_format_t deviceFormat = SND_PCM_FORMAT_UNKNOWN ;
if ( format = = RTAUDIO_SINT8 )
deviceFormat = SND_PCM_FORMAT_S8 ;
else if ( format = = RTAUDIO_SINT16 )
deviceFormat = SND_PCM_FORMAT_S16 ;
else if ( format = = RTAUDIO_SINT24 )
deviceFormat = SND_PCM_FORMAT_S24 ;
else if ( format = = RTAUDIO_SINT32 )
deviceFormat = SND_PCM_FORMAT_S32 ;
else if ( format = = RTAUDIO_FLOAT32 )
deviceFormat = SND_PCM_FORMAT_FLOAT ;
else if ( format = = RTAUDIO_FLOAT64 )
deviceFormat = SND_PCM_FORMAT_FLOAT64 ;
if ( snd_pcm_hw_params_test_format ( phandle , hw_params , deviceFormat ) = = 0 ) {
stream_ . deviceFormat [ mode ] = format ;
goto setFormat ;
}
// The user requested format is not natively supported by the device.
deviceFormat = SND_PCM_FORMAT_FLOAT64 ;
if ( snd_pcm_hw_params_test_format ( phandle , hw_params , deviceFormat ) = = 0 ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_FLOAT64 ;
goto setFormat ;
}
deviceFormat = SND_PCM_FORMAT_FLOAT ;
if ( snd_pcm_hw_params_test_format ( phandle , hw_params , deviceFormat ) = = 0 ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_FLOAT32 ;
goto setFormat ;
}
deviceFormat = SND_PCM_FORMAT_S32 ;
if ( snd_pcm_hw_params_test_format ( phandle , hw_params , deviceFormat ) = = 0 ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT32 ;
goto setFormat ;
}
deviceFormat = SND_PCM_FORMAT_S24 ;
if ( snd_pcm_hw_params_test_format ( phandle , hw_params , deviceFormat ) = = 0 ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT24 ;
goto setFormat ;
}
deviceFormat = SND_PCM_FORMAT_S16 ;
if ( snd_pcm_hw_params_test_format ( phandle , hw_params , deviceFormat ) = = 0 ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT16 ;
goto setFormat ;
}
deviceFormat = SND_PCM_FORMAT_S8 ;
if ( snd_pcm_hw_params_test_format ( phandle , hw_params , deviceFormat ) = = 0 ) {
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT8 ;
goto setFormat ;
}
// If we get here, no supported format was found.
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: pcm device " < < device < < " data format not supported by RtAudio. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
setFormat :
result = snd_pcm_hw_params_set_format ( phandle , hw_params , deviceFormat ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error setting pcm device ( " < < name < < " ) data format, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Determine whether byte-swaping is necessary.
stream_ . doByteSwap [ mode ] = false ;
if ( deviceFormat ! = SND_PCM_FORMAT_S8 ) {
result = snd_pcm_format_cpu_endian ( deviceFormat ) ;
if ( result = = 0 )
stream_ . doByteSwap [ mode ] = true ;
else if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error getting pcm device ( " < < name < < " ) endian-ness, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
// Set the sample rate.
result = snd_pcm_hw_params_set_rate_near ( phandle , hw_params , ( unsigned int * ) & sampleRate , 0 ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error setting sample rate on device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Determine the number of channels for this device. We support a possible
// minimum device channel number > than the value requested by the user.
stream_ . nUserChannels [ mode ] = channels ;
unsigned int value ;
result = snd_pcm_hw_params_get_channels_max ( hw_params , & value ) ;
unsigned int deviceChannels = value ;
if ( result < 0 | | deviceChannels < channels + firstChannel ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: requested channel parameters not supported by device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
result = snd_pcm_hw_params_get_channels_min ( hw_params , & value ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error getting minimum channels for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
deviceChannels = value ;
if ( deviceChannels < channels + firstChannel ) deviceChannels = channels + firstChannel ;
stream_ . nDeviceChannels [ mode ] = deviceChannels ;
// Set the device channels.
result = snd_pcm_hw_params_set_channels ( phandle , hw_params , deviceChannels ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error setting channels for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Set the buffer (or period) size.
int dir = 0 ;
snd_pcm_uframes_t periodSize = * bufferSize ;
result = snd_pcm_hw_params_set_period_size_near ( phandle , hw_params , & periodSize , & dir ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error setting period size for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
* bufferSize = periodSize ;
// Set the buffer number, which in ALSA is referred to as the "period".
unsigned int periods = 0 ;
if ( options & & options - > flags & RTAUDIO_MINIMIZE_LATENCY ) periods = 2 ;
if ( options & & options - > numberOfBuffers > 0 ) periods = options - > numberOfBuffers ;
if ( periods < 2 ) periods = 4 ; // a fairly safe default value
result = snd_pcm_hw_params_set_periods_near ( phandle , hw_params , & periods , & dir ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error setting periods for device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// If attempting to setup a duplex stream, the bufferSize parameter
// MUST be the same in both directions!
if ( stream_ . mode = = OUTPUT & & mode = = INPUT & & * bufferSize ! = stream_ . bufferSize ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: system error setting buffer size for duplex stream on device ( " < < name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
stream_ . bufferSize = * bufferSize ;
// Install the hardware configuration
result = snd_pcm_hw_params ( phandle , hw_params ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error installing hardware configuration on device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
# if defined(__RTAUDIO_DEBUG__)
fprintf ( stderr , " \n RtApiAlsa: dump hardware params after installation: \n \n " ) ;
snd_pcm_hw_params_dump ( hw_params , out ) ;
# endif
// Set the software configuration to fill buffers with zeros and prevent device stopping on xruns.
snd_pcm_sw_params_t * sw_params = NULL ;
snd_pcm_sw_params_alloca ( & sw_params ) ;
snd_pcm_sw_params_current ( phandle , sw_params ) ;
snd_pcm_sw_params_set_start_threshold ( phandle , sw_params , * bufferSize ) ;
snd_pcm_sw_params_set_stop_threshold ( phandle , sw_params , ULONG_MAX ) ;
snd_pcm_sw_params_set_silence_threshold ( phandle , sw_params , 0 ) ;
// The following two settings were suggested by Theo Veenker
//snd_pcm_sw_params_set_avail_min( phandle, sw_params, *bufferSize );
//snd_pcm_sw_params_set_xfer_align( phandle, sw_params, 1 );
// here are two options for a fix
//snd_pcm_sw_params_set_silence_size( phandle, sw_params, ULONG_MAX );
snd_pcm_uframes_t val ;
snd_pcm_sw_params_get_boundary ( sw_params , & val ) ;
snd_pcm_sw_params_set_silence_size ( phandle , sw_params , val ) ;
result = snd_pcm_sw_params ( phandle , sw_params ) ;
if ( result < 0 ) {
snd_pcm_close ( phandle ) ;
errorStream_ < < " RtApiAlsa::probeDeviceOpen: error installing software configuration on device ( " < < name < < " ), " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
# if defined(__RTAUDIO_DEBUG__)
fprintf ( stderr , " \n RtApiAlsa: dump software params after installation: \n \n " ) ;
snd_pcm_sw_params_dump ( sw_params , out ) ;
# endif
// Set flags for buffer conversion
stream_ . doConvertBuffer [ mode ] = false ;
if ( stream_ . userFormat ! = stream_ . deviceFormat [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . nUserChannels [ mode ] < stream_ . nDeviceChannels [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . userInterleaved ! = stream_ . deviceInterleaved [ mode ] & &
stream_ . nUserChannels [ mode ] > 1 )
stream_ . doConvertBuffer [ mode ] = true ;
// Allocate the ApiHandle if necessary and then save.
AlsaHandle * apiInfo = 0 ;
if ( stream_ . apiHandle = = 0 ) {
try {
apiInfo = ( AlsaHandle * ) new AlsaHandle ;
}
catch ( std : : bad_alloc & ) {
errorText_ = " RtApiAlsa::probeDeviceOpen: error allocating AlsaHandle memory. " ;
goto error ;
}
if ( pthread_cond_init ( & apiInfo - > runnable_cv , NULL ) ) {
errorText_ = " RtApiAlsa::probeDeviceOpen: error initializing pthread condition variable. " ;
goto error ;
}
stream_ . apiHandle = ( void * ) apiInfo ;
apiInfo - > handles [ 0 ] = 0 ;
apiInfo - > handles [ 1 ] = 0 ;
}
else {
apiInfo = ( AlsaHandle * ) stream_ . apiHandle ;
}
apiInfo - > handles [ mode ] = phandle ;
phandle = 0 ;
// Allocate necessary internal buffers.
unsigned long bufferBytes ;
bufferBytes = stream_ . nUserChannels [ mode ] * * bufferSize * formatBytes ( stream_ . userFormat ) ;
stream_ . userBuffer [ mode ] = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . userBuffer [ mode ] = = NULL ) {
errorText_ = " RtApiAlsa::probeDeviceOpen: error allocating user buffer memory. " ;
goto error ;
}
if ( stream_ . doConvertBuffer [ mode ] ) {
bool makeBuffer = true ;
bufferBytes = stream_ . nDeviceChannels [ mode ] * formatBytes ( stream_ . deviceFormat [ mode ] ) ;
if ( mode = = INPUT ) {
if ( stream_ . mode = = OUTPUT & & stream_ . deviceBuffer ) {
unsigned long bytesOut = stream_ . nDeviceChannels [ 0 ] * formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
if ( bufferBytes < = bytesOut ) makeBuffer = false ;
}
}
if ( makeBuffer ) {
bufferBytes * = * bufferSize ;
if ( stream_ . deviceBuffer ) free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . deviceBuffer = = NULL ) {
errorText_ = " RtApiAlsa::probeDeviceOpen: error allocating device buffer memory. " ;
goto error ;
}
}
}
stream_ . sampleRate = sampleRate ;
stream_ . nBuffers = periods ;
stream_ . device [ mode ] = device ;
stream_ . state = STREAM_STOPPED ;
// Setup the buffer conversion information structure.
if ( stream_ . doConvertBuffer [ mode ] ) setConvertInfo ( mode , firstChannel ) ;
// Setup thread if necessary.
if ( stream_ . mode = = OUTPUT & & mode = = INPUT ) {
// We had already set up an output stream.
stream_ . mode = DUPLEX ;
// Link the streams if possible.
apiInfo - > synchronized = false ;
if ( snd_pcm_link ( apiInfo - > handles [ 0 ] , apiInfo - > handles [ 1 ] ) = = 0 )
apiInfo - > synchronized = true ;
else {
errorText_ = " RtApiAlsa::probeDeviceOpen: unable to synchronize input and output devices. " ;
error ( RtAudioError : : WARNING ) ;
}
}
else {
stream_ . mode = mode ;
// Setup callback thread.
stream_ . callbackInfo . object = ( void * ) this ;
// Set the thread attributes for joinable and realtime scheduling
// priority (optional). The higher priority will only take affect
// if the program is run as root or suid. Note, under Linux
// processes with CAP_SYS_NICE privilege, a user can change
// scheduling policy and priority (thus need not be root). See
// POSIX "capabilities".
pthread_attr_t attr ;
pthread_attr_init ( & attr ) ;
pthread_attr_setdetachstate ( & attr , PTHREAD_CREATE_JOINABLE ) ;
# ifdef SCHED_RR // Undefined with some OSes (eg: NetBSD 1.6.x with GNU Pthread)
if ( options & & options - > flags & RTAUDIO_SCHEDULE_REALTIME ) {
// We previously attempted to increase the audio callback priority
// to SCHED_RR here via the attributes. However, while no errors
// were reported in doing so, it did not work. So, now this is
// done in the alsaCallbackHandler function.
stream_ . callbackInfo . doRealtime = true ;
int priority = options - > priority ;
int min = sched_get_priority_min ( SCHED_RR ) ;
int max = sched_get_priority_max ( SCHED_RR ) ;
if ( priority < min ) priority = min ;
else if ( priority > max ) priority = max ;
stream_ . callbackInfo . priority = priority ;
}
# endif
stream_ . callbackInfo . isRunning = true ;
result = pthread_create ( & stream_ . callbackInfo . thread , & attr , alsaCallbackHandler , & stream_ . callbackInfo ) ;
pthread_attr_destroy ( & attr ) ;
if ( result ) {
stream_ . callbackInfo . isRunning = false ;
errorText_ = " RtApiAlsa::error creating callback thread! " ;
goto error ;
}
}
return SUCCESS ;
error :
if ( apiInfo ) {
pthread_cond_destroy ( & apiInfo - > runnable_cv ) ;
if ( apiInfo - > handles [ 0 ] ) snd_pcm_close ( apiInfo - > handles [ 0 ] ) ;
if ( apiInfo - > handles [ 1 ] ) snd_pcm_close ( apiInfo - > handles [ 1 ] ) ;
delete apiInfo ;
stream_ . apiHandle = 0 ;
}
if ( phandle ) snd_pcm_close ( phandle ) ;
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
stream_ . state = STREAM_CLOSED ;
return FAILURE ;
}
void RtApiAlsa : : closeStream ( )
{
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiAlsa::closeStream(): no open stream to close! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
AlsaHandle * apiInfo = ( AlsaHandle * ) stream_ . apiHandle ;
stream_ . callbackInfo . isRunning = false ;
MUTEX_LOCK ( & stream_ . mutex ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
apiInfo - > runnable = true ;
pthread_cond_signal ( & apiInfo - > runnable_cv ) ;
}
MUTEX_UNLOCK ( & stream_ . mutex ) ;
pthread_join ( stream_ . callbackInfo . thread , NULL ) ;
if ( stream_ . state = = STREAM_RUNNING ) {
stream_ . state = STREAM_STOPPED ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX )
snd_pcm_drop ( apiInfo - > handles [ 0 ] ) ;
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX )
snd_pcm_drop ( apiInfo - > handles [ 1 ] ) ;
}
if ( apiInfo ) {
pthread_cond_destroy ( & apiInfo - > runnable_cv ) ;
if ( apiInfo - > handles [ 0 ] ) snd_pcm_close ( apiInfo - > handles [ 0 ] ) ;
if ( apiInfo - > handles [ 1 ] ) snd_pcm_close ( apiInfo - > handles [ 1 ] ) ;
delete apiInfo ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
stream_ . mode = UNINITIALIZED ;
stream_ . state = STREAM_CLOSED ;
}
void RtApiAlsa : : startStream ( )
{
// This method calls snd_pcm_prepare if the device isn't already in that state.
verifyStream ( ) ;
if ( stream_ . state = = STREAM_RUNNING ) {
errorText_ = " RtApiAlsa::startStream(): the stream is already running! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
MUTEX_LOCK ( & stream_ . mutex ) ;
int result = 0 ;
snd_pcm_state_t state ;
AlsaHandle * apiInfo = ( AlsaHandle * ) stream_ . apiHandle ;
snd_pcm_t * * handle = ( snd_pcm_t * * ) apiInfo - > handles ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
state = snd_pcm_state ( handle [ 0 ] ) ;
if ( state ! = SND_PCM_STATE_PREPARED ) {
result = snd_pcm_prepare ( handle [ 0 ] ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::startStream: error preparing output pcm device, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
}
if ( ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) & & ! apiInfo - > synchronized ) {
result = snd_pcm_drop ( handle [ 1 ] ) ; // fix to remove stale data received since device has been open
state = snd_pcm_state ( handle [ 1 ] ) ;
if ( state ! = SND_PCM_STATE_PREPARED ) {
result = snd_pcm_prepare ( handle [ 1 ] ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::startStream: error preparing input pcm device, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
}
stream_ . state = STREAM_RUNNING ;
unlock :
apiInfo - > runnable = true ;
pthread_cond_signal ( & apiInfo - > runnable_cv ) ;
MUTEX_UNLOCK ( & stream_ . mutex ) ;
if ( result > = 0 ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiAlsa : : stopStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiAlsa::stopStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
stream_ . state = STREAM_STOPPED ;
MUTEX_LOCK ( & stream_ . mutex ) ;
int result = 0 ;
AlsaHandle * apiInfo = ( AlsaHandle * ) stream_ . apiHandle ;
snd_pcm_t * * handle = ( snd_pcm_t * * ) apiInfo - > handles ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
if ( apiInfo - > synchronized )
result = snd_pcm_drop ( handle [ 0 ] ) ;
else
result = snd_pcm_drain ( handle [ 0 ] ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::stopStream: error draining output pcm device, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
if ( ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) & & ! apiInfo - > synchronized ) {
result = snd_pcm_drop ( handle [ 1 ] ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::stopStream: error stopping input pcm device, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
unlock :
apiInfo - > runnable = false ; // fixes high CPU usage when stopped
MUTEX_UNLOCK ( & stream_ . mutex ) ;
if ( result > = 0 ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiAlsa : : abortStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiAlsa::abortStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
stream_ . state = STREAM_STOPPED ;
MUTEX_LOCK ( & stream_ . mutex ) ;
int result = 0 ;
AlsaHandle * apiInfo = ( AlsaHandle * ) stream_ . apiHandle ;
snd_pcm_t * * handle = ( snd_pcm_t * * ) apiInfo - > handles ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
result = snd_pcm_drop ( handle [ 0 ] ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::abortStream: error aborting output pcm device, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
if ( ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) & & ! apiInfo - > synchronized ) {
result = snd_pcm_drop ( handle [ 1 ] ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::abortStream: error aborting input pcm device, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
unlock :
apiInfo - > runnable = false ; // fixes high CPU usage when stopped
MUTEX_UNLOCK ( & stream_ . mutex ) ;
if ( result > = 0 ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiAlsa : : callbackEvent ( )
{
AlsaHandle * apiInfo = ( AlsaHandle * ) stream_ . apiHandle ;
if ( stream_ . state = = STREAM_STOPPED ) {
MUTEX_LOCK ( & stream_ . mutex ) ;
while ( ! apiInfo - > runnable )
pthread_cond_wait ( & apiInfo - > runnable_cv , & stream_ . mutex ) ;
if ( stream_ . state ! = STREAM_RUNNING ) {
MUTEX_UNLOCK ( & stream_ . mutex ) ;
return ;
}
MUTEX_UNLOCK ( & stream_ . mutex ) ;
}
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiAlsa::callbackEvent(): the stream is closed ... this shouldn't happen! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
int doStopStream = 0 ;
RtAudioCallback callback = ( RtAudioCallback ) stream_ . callbackInfo . callback ;
double streamTime = getStreamTime ( ) ;
RtAudioStreamStatus status = 0 ;
if ( stream_ . mode ! = INPUT & & apiInfo - > xrun [ 0 ] = = true ) {
status | = RTAUDIO_OUTPUT_UNDERFLOW ;
apiInfo - > xrun [ 0 ] = false ;
}
if ( stream_ . mode ! = OUTPUT & & apiInfo - > xrun [ 1 ] = = true ) {
status | = RTAUDIO_INPUT_OVERFLOW ;
apiInfo - > xrun [ 1 ] = false ;
}
doStopStream = callback ( stream_ . userBuffer [ 0 ] , stream_ . userBuffer [ 1 ] ,
stream_ . bufferSize , streamTime , status , stream_ . callbackInfo . userData ) ;
if ( doStopStream = = 2 ) {
abortStream ( ) ;
return ;
}
MUTEX_LOCK ( & stream_ . mutex ) ;
// The state might change while waiting on a mutex.
if ( stream_ . state = = STREAM_STOPPED ) goto unlock ;
int result ;
char * buffer ;
int channels ;
snd_pcm_t * * handle ;
snd_pcm_sframes_t frames ;
RtAudioFormat format ;
handle = ( snd_pcm_t * * ) apiInfo - > handles ;
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) {
// Setup parameters.
if ( stream_ . doConvertBuffer [ 1 ] ) {
buffer = stream_ . deviceBuffer ;
channels = stream_ . nDeviceChannels [ 1 ] ;
format = stream_ . deviceFormat [ 1 ] ;
}
else {
buffer = stream_ . userBuffer [ 1 ] ;
channels = stream_ . nUserChannels [ 1 ] ;
format = stream_ . userFormat ;
}
// Read samples from device in interleaved/non-interleaved format.
if ( stream_ . deviceInterleaved [ 1 ] )
result = snd_pcm_readi ( handle [ 1 ] , buffer , stream_ . bufferSize ) ;
else {
void * bufs [ channels ] ;
size_t offset = stream_ . bufferSize * formatBytes ( format ) ;
for ( int i = 0 ; i < channels ; i + + )
bufs [ i ] = ( void * ) ( buffer + ( i * offset ) ) ;
result = snd_pcm_readn ( handle [ 1 ] , bufs , stream_ . bufferSize ) ;
}
if ( result < ( int ) stream_ . bufferSize ) {
// Either an error or overrun occured.
if ( result = = - EPIPE ) {
snd_pcm_state_t state = snd_pcm_state ( handle [ 1 ] ) ;
if ( state = = SND_PCM_STATE_XRUN ) {
apiInfo - > xrun [ 1 ] = true ;
result = snd_pcm_prepare ( handle [ 1 ] ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::callbackEvent: error preparing device after overrun, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
}
}
else {
errorStream_ < < " RtApiAlsa::callbackEvent: error, current state is " < < snd_pcm_state_name ( state ) < < " , " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
}
}
else {
errorStream_ < < " RtApiAlsa::callbackEvent: audio read error, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
}
error ( RtAudioError : : WARNING ) ;
goto tryOutput ;
}
// Do byte swapping if necessary.
if ( stream_ . doByteSwap [ 1 ] )
byteSwapBuffer ( buffer , stream_ . bufferSize * channels , format ) ;
// Do buffer conversion if necessary.
if ( stream_ . doConvertBuffer [ 1 ] )
convertBuffer ( stream_ . userBuffer [ 1 ] , stream_ . deviceBuffer , stream_ . convertInfo [ 1 ] ) ;
// Check stream latency
result = snd_pcm_delay ( handle [ 1 ] , & frames ) ;
if ( result = = 0 & & frames > 0 ) stream_ . latency [ 1 ] = frames ;
}
tryOutput :
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
// Setup parameters and do buffer conversion if necessary.
if ( stream_ . doConvertBuffer [ 0 ] ) {
buffer = stream_ . deviceBuffer ;
convertBuffer ( buffer , stream_ . userBuffer [ 0 ] , stream_ . convertInfo [ 0 ] ) ;
channels = stream_ . nDeviceChannels [ 0 ] ;
format = stream_ . deviceFormat [ 0 ] ;
}
else {
buffer = stream_ . userBuffer [ 0 ] ;
channels = stream_ . nUserChannels [ 0 ] ;
format = stream_ . userFormat ;
}
// Do byte swapping if necessary.
if ( stream_ . doByteSwap [ 0 ] )
byteSwapBuffer ( buffer , stream_ . bufferSize * channels , format ) ;
// Write samples to device in interleaved/non-interleaved format.
if ( stream_ . deviceInterleaved [ 0 ] )
result = snd_pcm_writei ( handle [ 0 ] , buffer , stream_ . bufferSize ) ;
else {
void * bufs [ channels ] ;
size_t offset = stream_ . bufferSize * formatBytes ( format ) ;
for ( int i = 0 ; i < channels ; i + + )
bufs [ i ] = ( void * ) ( buffer + ( i * offset ) ) ;
result = snd_pcm_writen ( handle [ 0 ] , bufs , stream_ . bufferSize ) ;
}
if ( result < ( int ) stream_ . bufferSize ) {
// Either an error or underrun occured.
if ( result = = - EPIPE ) {
snd_pcm_state_t state = snd_pcm_state ( handle [ 0 ] ) ;
if ( state = = SND_PCM_STATE_XRUN ) {
apiInfo - > xrun [ 0 ] = true ;
result = snd_pcm_prepare ( handle [ 0 ] ) ;
if ( result < 0 ) {
errorStream_ < < " RtApiAlsa::callbackEvent: error preparing device after underrun, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
}
}
else {
errorStream_ < < " RtApiAlsa::callbackEvent: error, current state is " < < snd_pcm_state_name ( state ) < < " , " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
}
}
else {
errorStream_ < < " RtApiAlsa::callbackEvent: audio write error, " < < snd_strerror ( result ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
}
error ( RtAudioError : : WARNING ) ;
goto unlock ;
}
// Check stream latency
result = snd_pcm_delay ( handle [ 0 ] , & frames ) ;
if ( result = = 0 & & frames > 0 ) stream_ . latency [ 0 ] = frames ;
}
unlock :
MUTEX_UNLOCK ( & stream_ . mutex ) ;
RtApi : : tickStreamTime ( ) ;
if ( doStopStream = = 1 ) this - > stopStream ( ) ;
}
static void * alsaCallbackHandler ( void * ptr )
{
CallbackInfo * info = ( CallbackInfo * ) ptr ;
RtApiAlsa * object = ( RtApiAlsa * ) info - > object ;
bool * isRunning = & info - > isRunning ;
# ifdef SCHED_RR // Undefined with some OSes (eg: NetBSD 1.6.x with GNU Pthread)
if ( & info - > doRealtime ) {
pthread_t tID = pthread_self ( ) ; // ID of this thread
sched_param prio = { info - > priority } ; // scheduling priority of thread
pthread_setschedparam ( tID , SCHED_RR , & prio ) ;
}
# endif
while ( * isRunning = = true ) {
pthread_testcancel ( ) ;
object - > callbackEvent ( ) ;
}
pthread_exit ( NULL ) ;
}
//******************** End of __LINUX_ALSA__ *********************//
# endif
# if defined(__LINUX_PULSE__)
// Code written by Peter Meerwald, pmeerw@pmeerw.net
// and Tristan Matthews.
# include <pulse/error.h>
# include <pulse/simple.h>
# include <cstdio>
static const unsigned int SUPPORTED_SAMPLERATES [ ] = { 8000 , 16000 , 22050 , 32000 ,
44100 , 48000 , 96000 , 0 } ;
struct rtaudio_pa_format_mapping_t {
RtAudioFormat rtaudio_format ;
pa_sample_format_t pa_format ;
} ;
static const rtaudio_pa_format_mapping_t supported_sampleformats [ ] = {
{ RTAUDIO_SINT16 , PA_SAMPLE_S16LE } ,
{ RTAUDIO_SINT32 , PA_SAMPLE_S32LE } ,
{ RTAUDIO_FLOAT32 , PA_SAMPLE_FLOAT32LE } ,
{ 0 , PA_SAMPLE_INVALID } } ;
struct PulseAudioHandle {
pa_simple * s_play ;
pa_simple * s_rec ;
pthread_t thread ;
pthread_cond_t runnable_cv ;
bool runnable ;
PulseAudioHandle ( ) : s_play ( 0 ) , s_rec ( 0 ) , runnable ( false ) { }
} ;
RtApiPulse : : ~ RtApiPulse ( )
{
if ( stream_ . state ! = STREAM_CLOSED )
closeStream ( ) ;
}
unsigned int RtApiPulse : : getDeviceCount ( void )
{
return 1 ;
}
RtAudio : : DeviceInfo RtApiPulse : : getDeviceInfo ( unsigned int /*device*/ )
{
RtAudio : : DeviceInfo info ;
info . probed = true ;
info . name = " PulseAudio " ;
info . outputChannels = 2 ;
info . inputChannels = 2 ;
info . duplexChannels = 2 ;
info . isDefaultOutput = true ;
info . isDefaultInput = true ;
for ( const unsigned int * sr = SUPPORTED_SAMPLERATES ; * sr ; + + sr )
info . sampleRates . push_back ( * sr ) ;
info . nativeFormats = RTAUDIO_SINT16 | RTAUDIO_SINT32 | RTAUDIO_FLOAT32 ;
return info ;
}
static void * pulseaudio_callback ( void * user )
{
CallbackInfo * cbi = static_cast < CallbackInfo * > ( user ) ;
RtApiPulse * context = static_cast < RtApiPulse * > ( cbi - > object ) ;
volatile bool * isRunning = & cbi - > isRunning ;
while ( * isRunning ) {
pthread_testcancel ( ) ;
context - > callbackEvent ( ) ;
}
pthread_exit ( NULL ) ;
}
void RtApiPulse : : closeStream ( void )
{
PulseAudioHandle * pah = static_cast < PulseAudioHandle * > ( stream_ . apiHandle ) ;
stream_ . callbackInfo . isRunning = false ;
if ( pah ) {
MUTEX_LOCK ( & stream_ . mutex ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
pah - > runnable = true ;
pthread_cond_signal ( & pah - > runnable_cv ) ;
}
MUTEX_UNLOCK ( & stream_ . mutex ) ;
pthread_join ( pah - > thread , 0 ) ;
if ( pah - > s_play ) {
pa_simple_flush ( pah - > s_play , NULL ) ;
pa_simple_free ( pah - > s_play ) ;
}
if ( pah - > s_rec )
pa_simple_free ( pah - > s_rec ) ;
pthread_cond_destroy ( & pah - > runnable_cv ) ;
delete pah ;
stream_ . apiHandle = 0 ;
}
if ( stream_ . userBuffer [ 0 ] ) {
free ( stream_ . userBuffer [ 0 ] ) ;
stream_ . userBuffer [ 0 ] = 0 ;
}
if ( stream_ . userBuffer [ 1 ] ) {
free ( stream_ . userBuffer [ 1 ] ) ;
stream_ . userBuffer [ 1 ] = 0 ;
}
stream_ . state = STREAM_CLOSED ;
stream_ . mode = UNINITIALIZED ;
}
void RtApiPulse : : callbackEvent ( void )
{
PulseAudioHandle * pah = static_cast < PulseAudioHandle * > ( stream_ . apiHandle ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
MUTEX_LOCK ( & stream_ . mutex ) ;
while ( ! pah - > runnable )
pthread_cond_wait ( & pah - > runnable_cv , & stream_ . mutex ) ;
if ( stream_ . state ! = STREAM_RUNNING ) {
MUTEX_UNLOCK ( & stream_ . mutex ) ;
return ;
}
MUTEX_UNLOCK ( & stream_ . mutex ) ;
}
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiPulse::callbackEvent(): the stream is closed ... "
" this shouldn't happen! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
RtAudioCallback callback = ( RtAudioCallback ) stream_ . callbackInfo . callback ;
double streamTime = getStreamTime ( ) ;
RtAudioStreamStatus status = 0 ;
int doStopStream = callback ( stream_ . userBuffer [ OUTPUT ] , stream_ . userBuffer [ INPUT ] ,
stream_ . bufferSize , streamTime , status ,
stream_ . callbackInfo . userData ) ;
if ( doStopStream = = 2 ) {
abortStream ( ) ;
return ;
}
MUTEX_LOCK ( & stream_ . mutex ) ;
void * pulse_in = stream_ . doConvertBuffer [ INPUT ] ? stream_ . deviceBuffer : stream_ . userBuffer [ INPUT ] ;
void * pulse_out = stream_ . doConvertBuffer [ OUTPUT ] ? stream_ . deviceBuffer : stream_ . userBuffer [ OUTPUT ] ;
if ( stream_ . state ! = STREAM_RUNNING )
goto unlock ;
int pa_error ;
size_t bytes ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
if ( stream_ . doConvertBuffer [ OUTPUT ] ) {
convertBuffer ( stream_ . deviceBuffer ,
stream_ . userBuffer [ OUTPUT ] ,
stream_ . convertInfo [ OUTPUT ] ) ;
bytes = stream_ . nDeviceChannels [ OUTPUT ] * stream_ . bufferSize *
formatBytes ( stream_ . deviceFormat [ OUTPUT ] ) ;
} else
bytes = stream_ . nUserChannels [ OUTPUT ] * stream_ . bufferSize *
formatBytes ( stream_ . userFormat ) ;
if ( pa_simple_write ( pah - > s_play , pulse_out , bytes , & pa_error ) < 0 ) {
errorStream_ < < " RtApiPulse::callbackEvent: audio write error, " < <
pa_strerror ( pa_error ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
}
}
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) {
if ( stream_ . doConvertBuffer [ INPUT ] )
bytes = stream_ . nDeviceChannels [ INPUT ] * stream_ . bufferSize *
formatBytes ( stream_ . deviceFormat [ INPUT ] ) ;
else
bytes = stream_ . nUserChannels [ INPUT ] * stream_ . bufferSize *
formatBytes ( stream_ . userFormat ) ;
if ( pa_simple_read ( pah - > s_rec , pulse_in , bytes , & pa_error ) < 0 ) {
errorStream_ < < " RtApiPulse::callbackEvent: audio read error, " < <
pa_strerror ( pa_error ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
}
if ( stream_ . doConvertBuffer [ INPUT ] ) {
convertBuffer ( stream_ . userBuffer [ INPUT ] ,
stream_ . deviceBuffer ,
stream_ . convertInfo [ INPUT ] ) ;
}
}
unlock :
MUTEX_UNLOCK ( & stream_ . mutex ) ;
RtApi : : tickStreamTime ( ) ;
if ( doStopStream = = 1 )
stopStream ( ) ;
}
void RtApiPulse : : startStream ( void )
{
PulseAudioHandle * pah = static_cast < PulseAudioHandle * > ( stream_ . apiHandle ) ;
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiPulse::startStream(): the stream is not open! " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
if ( stream_ . state = = STREAM_RUNNING ) {
errorText_ = " RtApiPulse::startStream(): the stream is already running! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
MUTEX_LOCK ( & stream_ . mutex ) ;
stream_ . state = STREAM_RUNNING ;
pah - > runnable = true ;
pthread_cond_signal ( & pah - > runnable_cv ) ;
MUTEX_UNLOCK ( & stream_ . mutex ) ;
}
void RtApiPulse : : stopStream ( void )
{
PulseAudioHandle * pah = static_cast < PulseAudioHandle * > ( stream_ . apiHandle ) ;
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiPulse::stopStream(): the stream is not open! " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiPulse::stopStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
stream_ . state = STREAM_STOPPED ;
MUTEX_LOCK ( & stream_ . mutex ) ;
if ( pah & & pah - > s_play ) {
int pa_error ;
if ( pa_simple_drain ( pah - > s_play , & pa_error ) < 0 ) {
errorStream_ < < " RtApiPulse::stopStream: error draining output device, " < <
pa_strerror ( pa_error ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
MUTEX_UNLOCK ( & stream_ . mutex ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
}
stream_ . state = STREAM_STOPPED ;
MUTEX_UNLOCK ( & stream_ . mutex ) ;
}
void RtApiPulse : : abortStream ( void )
{
PulseAudioHandle * pah = static_cast < PulseAudioHandle * > ( stream_ . apiHandle ) ;
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiPulse::abortStream(): the stream is not open! " ;
error ( RtAudioError : : INVALID_USE ) ;
return ;
}
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiPulse::abortStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
stream_ . state = STREAM_STOPPED ;
MUTEX_LOCK ( & stream_ . mutex ) ;
if ( pah & & pah - > s_play ) {
int pa_error ;
if ( pa_simple_flush ( pah - > s_play , & pa_error ) < 0 ) {
errorStream_ < < " RtApiPulse::abortStream: error flushing output device, " < <
pa_strerror ( pa_error ) < < " . " ;
errorText_ = errorStream_ . str ( ) ;
MUTEX_UNLOCK ( & stream_ . mutex ) ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
return ;
}
}
stream_ . state = STREAM_STOPPED ;
MUTEX_UNLOCK ( & stream_ . mutex ) ;
}
bool RtApiPulse : : probeDeviceOpen ( unsigned int device , StreamMode mode ,
unsigned int channels , unsigned int firstChannel ,
unsigned int sampleRate , RtAudioFormat format ,
unsigned int * bufferSize , RtAudio : : StreamOptions * options )
{
PulseAudioHandle * pah = 0 ;
unsigned long bufferBytes = 0 ;
pa_sample_spec ss ;
if ( device ! = 0 ) return false ;
if ( mode ! = INPUT & & mode ! = OUTPUT ) return false ;
if ( channels ! = 1 & & channels ! = 2 ) {
errorText_ = " RtApiPulse::probeDeviceOpen: unsupported number of channels. " ;
return false ;
}
ss . channels = channels ;
if ( firstChannel ! = 0 ) return false ;
bool sr_found = false ;
for ( const unsigned int * sr = SUPPORTED_SAMPLERATES ; * sr ; + + sr ) {
if ( sampleRate = = * sr ) {
sr_found = true ;
stream_ . sampleRate = sampleRate ;
ss . rate = sampleRate ;
break ;
}
}
if ( ! sr_found ) {
errorText_ = " RtApiPulse::probeDeviceOpen: unsupported sample rate. " ;
return false ;
}
bool sf_found = 0 ;
for ( const rtaudio_pa_format_mapping_t * sf = supported_sampleformats ;
sf - > rtaudio_format & & sf - > pa_format ! = PA_SAMPLE_INVALID ; + + sf ) {
if ( format = = sf - > rtaudio_format ) {
sf_found = true ;
stream_ . userFormat = sf - > rtaudio_format ;
stream_ . deviceFormat [ mode ] = stream_ . userFormat ;
ss . format = sf - > pa_format ;
break ;
}
}
if ( ! sf_found ) { // Use internal data format conversion.
stream_ . userFormat = format ;
stream_ . deviceFormat [ mode ] = RTAUDIO_FLOAT32 ;
ss . format = PA_SAMPLE_FLOAT32LE ;
}
// Set other stream parameters.
if ( options & & options - > flags & RTAUDIO_NONINTERLEAVED ) stream_ . userInterleaved = false ;
else stream_ . userInterleaved = true ;
stream_ . deviceInterleaved [ mode ] = true ;
stream_ . nBuffers = 1 ;
stream_ . doByteSwap [ mode ] = false ;
stream_ . nUserChannels [ mode ] = channels ;
stream_ . nDeviceChannels [ mode ] = channels + firstChannel ;
stream_ . channelOffset [ mode ] = 0 ;
std : : string streamName = " RtAudio " ;
// Set flags for buffer conversion.
stream_ . doConvertBuffer [ mode ] = false ;
if ( stream_ . userFormat ! = stream_ . deviceFormat [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . nUserChannels [ mode ] < stream_ . nDeviceChannels [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
// Allocate necessary internal buffers.
bufferBytes = stream_ . nUserChannels [ mode ] * * bufferSize * formatBytes ( stream_ . userFormat ) ;
stream_ . userBuffer [ mode ] = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . userBuffer [ mode ] = = NULL ) {
errorText_ = " RtApiPulse::probeDeviceOpen: error allocating user buffer memory. " ;
goto error ;
}
stream_ . bufferSize = * bufferSize ;
if ( stream_ . doConvertBuffer [ mode ] ) {
bool makeBuffer = true ;
bufferBytes = stream_ . nDeviceChannels [ mode ] * formatBytes ( stream_ . deviceFormat [ mode ] ) ;
if ( mode = = INPUT ) {
if ( stream_ . mode = = OUTPUT & & stream_ . deviceBuffer ) {
unsigned long bytesOut = stream_ . nDeviceChannels [ 0 ] * formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
if ( bufferBytes < = bytesOut ) makeBuffer = false ;
}
}
if ( makeBuffer ) {
bufferBytes * = * bufferSize ;
if ( stream_ . deviceBuffer ) free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . deviceBuffer = = NULL ) {
errorText_ = " RtApiPulse::probeDeviceOpen: error allocating device buffer memory. " ;
goto error ;
}
}
}
stream_ . device [ mode ] = device ;
// Setup the buffer conversion information structure.
if ( stream_ . doConvertBuffer [ mode ] ) setConvertInfo ( mode , firstChannel ) ;
if ( ! stream_ . apiHandle ) {
PulseAudioHandle * pah = new PulseAudioHandle ;
if ( ! pah ) {
errorText_ = " RtApiPulse::probeDeviceOpen: error allocating memory for handle. " ;
goto error ;
}
stream_ . apiHandle = pah ;
if ( pthread_cond_init ( & pah - > runnable_cv , NULL ) ! = 0 ) {
errorText_ = " RtApiPulse::probeDeviceOpen: error creating condition variable. " ;
goto error ;
}
}
pah = static_cast < PulseAudioHandle * > ( stream_ . apiHandle ) ;
int error ;
if ( ! options - > streamName . empty ( ) ) streamName = options - > streamName ;
switch ( mode ) {
case INPUT :
pa_buffer_attr buffer_attr ;
buffer_attr . fragsize = bufferBytes ;
buffer_attr . maxlength = - 1 ;
pah - > s_rec = pa_simple_new ( NULL , streamName . c_str ( ) , PA_STREAM_RECORD , NULL , " Record " , & ss , NULL , & buffer_attr , & error ) ;
if ( ! pah - > s_rec ) {
errorText_ = " RtApiPulse::probeDeviceOpen: error connecting input to PulseAudio server. " ;
goto error ;
}
break ;
case OUTPUT :
pah - > s_play = pa_simple_new ( NULL , " RtAudio " , PA_STREAM_PLAYBACK , NULL , " Playback " , & ss , NULL , NULL , & error ) ;
if ( ! pah - > s_play ) {
errorText_ = " RtApiPulse::probeDeviceOpen: error connecting output to PulseAudio server. " ;
goto error ;
}
break ;
default :
goto error ;
}
if ( stream_ . mode = = UNINITIALIZED )
stream_ . mode = mode ;
else if ( stream_ . mode = = mode )
goto error ;
else
stream_ . mode = DUPLEX ;
if ( ! stream_ . callbackInfo . isRunning ) {
stream_ . callbackInfo . object = this ;
stream_ . callbackInfo . isRunning = true ;
if ( pthread_create ( & pah - > thread , NULL , pulseaudio_callback , ( void * ) & stream_ . callbackInfo ) ! = 0 ) {
errorText_ = " RtApiPulse::probeDeviceOpen: error creating thread. " ;
goto error ;
}
}
stream_ . state = STREAM_STOPPED ;
return true ;
error :
if ( pah & & stream_ . callbackInfo . isRunning ) {
pthread_cond_destroy ( & pah - > runnable_cv ) ;
delete pah ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
return FAILURE ;
}
//******************** End of __LINUX_PULSE__ *********************//
# endif
# if defined(__LINUX_OSS__)
# include <unistd.h>
# include <sys/ioctl.h>
# include <unistd.h>
# include <fcntl.h>
# include <sys/soundcard.h>
# include <errno.h>
# include <math.h>
static void * ossCallbackHandler ( void * ptr ) ;
// A structure to hold various information related to the OSS API
// implementation.
struct OssHandle {
int id [ 2 ] ; // device ids
bool xrun [ 2 ] ;
bool triggered ;
pthread_cond_t runnable ;
OssHandle ( )
: triggered ( false ) { id [ 0 ] = 0 ; id [ 1 ] = 0 ; xrun [ 0 ] = false ; xrun [ 1 ] = false ; }
} ;
RtApiOss : : RtApiOss ( )
{
// Nothing to do here.
}
RtApiOss : : ~ RtApiOss ( )
{
if ( stream_ . state ! = STREAM_CLOSED ) closeStream ( ) ;
}
unsigned int RtApiOss : : getDeviceCount ( void )
{
int mixerfd = open ( " /dev/mixer " , O_RDWR , 0 ) ;
if ( mixerfd = = - 1 ) {
errorText_ = " RtApiOss::getDeviceCount: error opening '/dev/mixer'. " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
oss_sysinfo sysinfo ;
if ( ioctl ( mixerfd , SNDCTL_SYSINFO , & sysinfo ) = = - 1 ) {
close ( mixerfd ) ;
errorText_ = " RtApiOss::getDeviceCount: error getting sysinfo, OSS version >= 4.0 is required. " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
close ( mixerfd ) ;
return sysinfo . numaudios ;
}
RtAudio : : DeviceInfo RtApiOss : : getDeviceInfo ( unsigned int device )
{
RtAudio : : DeviceInfo info ;
info . probed = false ;
int mixerfd = open ( " /dev/mixer " , O_RDWR , 0 ) ;
if ( mixerfd = = - 1 ) {
errorText_ = " RtApiOss::getDeviceInfo: error opening '/dev/mixer'. " ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
oss_sysinfo sysinfo ;
int result = ioctl ( mixerfd , SNDCTL_SYSINFO , & sysinfo ) ;
if ( result = = - 1 ) {
close ( mixerfd ) ;
errorText_ = " RtApiOss::getDeviceInfo: error getting sysinfo, OSS version >= 4.0 is required. " ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
unsigned nDevices = sysinfo . numaudios ;
if ( nDevices = = 0 ) {
close ( mixerfd ) ;
errorText_ = " RtApiOss::getDeviceInfo: no devices found! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
if ( device > = nDevices ) {
close ( mixerfd ) ;
errorText_ = " RtApiOss::getDeviceInfo: device ID is invalid! " ;
error ( RtAudioError : : INVALID_USE ) ;
return info ;
}
oss_audioinfo ainfo ;
ainfo . dev = device ;
result = ioctl ( mixerfd , SNDCTL_AUDIOINFO , & ainfo ) ;
close ( mixerfd ) ;
if ( result = = - 1 ) {
errorStream_ < < " RtApiOss::getDeviceInfo: error getting device ( " < < ainfo . name < < " ) info. " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Probe channels
if ( ainfo . caps & PCM_CAP_OUTPUT ) info . outputChannels = ainfo . max_channels ;
if ( ainfo . caps & PCM_CAP_INPUT ) info . inputChannels = ainfo . max_channels ;
if ( ainfo . caps & PCM_CAP_DUPLEX ) {
if ( info . outputChannels > 0 & & info . inputChannels > 0 & & ainfo . caps & PCM_CAP_DUPLEX )
info . duplexChannels = ( info . outputChannels > info . inputChannels ) ? info . inputChannels : info . outputChannels ;
}
// Probe data formats ... do for input
unsigned long mask = ainfo . iformats ;
if ( mask & AFMT_S16_LE | | mask & AFMT_S16_BE )
info . nativeFormats | = RTAUDIO_SINT16 ;
if ( mask & AFMT_S8 )
info . nativeFormats | = RTAUDIO_SINT8 ;
if ( mask & AFMT_S32_LE | | mask & AFMT_S32_BE )
info . nativeFormats | = RTAUDIO_SINT32 ;
if ( mask & AFMT_FLOAT )
info . nativeFormats | = RTAUDIO_FLOAT32 ;
if ( mask & AFMT_S24_LE | | mask & AFMT_S24_BE )
info . nativeFormats | = RTAUDIO_SINT24 ;
// Check that we have at least one supported format
if ( info . nativeFormats = = 0 ) {
errorStream_ < < " RtApiOss::getDeviceInfo: device ( " < < ainfo . name < < " ) data format not supported by RtAudio. " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
return info ;
}
// Probe the supported sample rates.
info . sampleRates . clear ( ) ;
if ( ainfo . nrates ) {
for ( unsigned int i = 0 ; i < ainfo . nrates ; i + + ) {
for ( unsigned int k = 0 ; k < MAX_SAMPLE_RATES ; k + + ) {
if ( ainfo . rates [ i ] = = SAMPLE_RATES [ k ] ) {
info . sampleRates . push_back ( SAMPLE_RATES [ k ] ) ;
break ;
}
}
}
}
else {
// Check min and max rate values;
for ( unsigned int k = 0 ; k < MAX_SAMPLE_RATES ; k + + ) {
if ( ainfo . min_rate < = ( int ) SAMPLE_RATES [ k ] & & ainfo . max_rate > = ( int ) SAMPLE_RATES [ k ] )
info . sampleRates . push_back ( SAMPLE_RATES [ k ] ) ;
}
}
if ( info . sampleRates . size ( ) = = 0 ) {
errorStream_ < < " RtApiOss::getDeviceInfo: no supported sample rates found for device ( " < < ainfo . name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
error ( RtAudioError : : WARNING ) ;
}
else {
info . probed = true ;
info . name = ainfo . name ;
}
return info ;
}
bool RtApiOss : : probeDeviceOpen ( unsigned int device , StreamMode mode , unsigned int channels ,
unsigned int firstChannel , unsigned int sampleRate ,
RtAudioFormat format , unsigned int * bufferSize ,
RtAudio : : StreamOptions * options )
{
int mixerfd = open ( " /dev/mixer " , O_RDWR , 0 ) ;
if ( mixerfd = = - 1 ) {
errorText_ = " RtApiOss::probeDeviceOpen: error opening '/dev/mixer'. " ;
return FAILURE ;
}
oss_sysinfo sysinfo ;
int result = ioctl ( mixerfd , SNDCTL_SYSINFO , & sysinfo ) ;
if ( result = = - 1 ) {
close ( mixerfd ) ;
errorText_ = " RtApiOss::probeDeviceOpen: error getting sysinfo, OSS version >= 4.0 is required. " ;
return FAILURE ;
}
unsigned nDevices = sysinfo . numaudios ;
if ( nDevices = = 0 ) {
// This should not happen because a check is made before this function is called.
close ( mixerfd ) ;
errorText_ = " RtApiOss::probeDeviceOpen: no devices found! " ;
return FAILURE ;
}
if ( device > = nDevices ) {
// This should not happen because a check is made before this function is called.
close ( mixerfd ) ;
errorText_ = " RtApiOss::probeDeviceOpen: device ID is invalid! " ;
return FAILURE ;
}
oss_audioinfo ainfo ;
ainfo . dev = device ;
result = ioctl ( mixerfd , SNDCTL_AUDIOINFO , & ainfo ) ;
close ( mixerfd ) ;
if ( result = = - 1 ) {
errorStream_ < < " RtApiOss::getDeviceInfo: error getting device ( " < < ainfo . name < < " ) info. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Check if device supports input or output
if ( ( mode = = OUTPUT & & ! ( ainfo . caps & PCM_CAP_OUTPUT ) ) | |
( mode = = INPUT & & ! ( ainfo . caps & PCM_CAP_INPUT ) ) ) {
if ( mode = = OUTPUT )
errorStream_ < < " RtApiOss::probeDeviceOpen: device ( " < < ainfo . name < < " ) does not support output. " ;
else
errorStream_ < < " RtApiOss::probeDeviceOpen: device ( " < < ainfo . name < < " ) does not support input. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
int flags = 0 ;
OssHandle * handle = ( OssHandle * ) stream_ . apiHandle ;
if ( mode = = OUTPUT )
flags | = O_WRONLY ;
else { // mode == INPUT
if ( stream_ . mode = = OUTPUT & & stream_ . device [ 0 ] = = device ) {
// We just set the same device for playback ... close and reopen for duplex (OSS only).
close ( handle - > id [ 0 ] ) ;
handle - > id [ 0 ] = 0 ;
if ( ! ( ainfo . caps & PCM_CAP_DUPLEX ) ) {
errorStream_ < < " RtApiOss::probeDeviceOpen: device ( " < < ainfo . name < < " ) does not support duplex mode. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Check that the number previously set channels is the same.
if ( stream_ . nUserChannels [ 0 ] ! = channels ) {
errorStream_ < < " RtApiOss::probeDeviceOpen: input/output channels must be equal for OSS duplex device ( " < < ainfo . name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
flags | = O_RDWR ;
}
else
flags | = O_RDONLY ;
}
// Set exclusive access if specified.
if ( options & & options - > flags & RTAUDIO_HOG_DEVICE ) flags | = O_EXCL ;
// Try to open the device.
int fd ;
fd = open ( ainfo . devnode , flags , 0 ) ;
if ( fd = = - 1 ) {
if ( errno = = EBUSY )
errorStream_ < < " RtApiOss::probeDeviceOpen: device ( " < < ainfo . name < < " ) is busy. " ;
else
errorStream_ < < " RtApiOss::probeDeviceOpen: error opening device ( " < < ainfo . name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// For duplex operation, specifically set this mode (this doesn't seem to work).
/*
if ( flags | O_RDWR ) {
result = ioctl ( fd , SNDCTL_DSP_SETDUPLEX , NULL ) ;
if ( result = = - 1 ) {
errorStream_ < < " RtApiOss::probeDeviceOpen: error setting duplex mode for device ( " < < ainfo . name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
}
*/
// Check the device channel support.
stream_ . nUserChannels [ mode ] = channels ;
if ( ainfo . max_channels < ( int ) ( channels + firstChannel ) ) {
close ( fd ) ;
errorStream_ < < " RtApiOss::probeDeviceOpen: the device ( " < < ainfo . name < < " ) does not support requested channel parameters. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Set the number of channels.
int deviceChannels = channels + firstChannel ;
result = ioctl ( fd , SNDCTL_DSP_CHANNELS , & deviceChannels ) ;
if ( result = = - 1 | | deviceChannels < ( int ) ( channels + firstChannel ) ) {
close ( fd ) ;
errorStream_ < < " RtApiOss::probeDeviceOpen: error setting channel parameters on device ( " < < ainfo . name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
stream_ . nDeviceChannels [ mode ] = deviceChannels ;
// Get the data format mask
int mask ;
result = ioctl ( fd , SNDCTL_DSP_GETFMTS , & mask ) ;
if ( result = = - 1 ) {
close ( fd ) ;
errorStream_ < < " RtApiOss::probeDeviceOpen: error getting device ( " < < ainfo . name < < " ) data formats. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Determine how to set the device format.
stream_ . userFormat = format ;
int deviceFormat = - 1 ;
stream_ . doByteSwap [ mode ] = false ;
if ( format = = RTAUDIO_SINT8 ) {
if ( mask & AFMT_S8 ) {
deviceFormat = AFMT_S8 ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT8 ;
}
}
else if ( format = = RTAUDIO_SINT16 ) {
if ( mask & AFMT_S16_NE ) {
deviceFormat = AFMT_S16_NE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT16 ;
}
else if ( mask & AFMT_S16_OE ) {
deviceFormat = AFMT_S16_OE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT16 ;
stream_ . doByteSwap [ mode ] = true ;
}
}
else if ( format = = RTAUDIO_SINT24 ) {
if ( mask & AFMT_S24_NE ) {
deviceFormat = AFMT_S24_NE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT24 ;
}
else if ( mask & AFMT_S24_OE ) {
deviceFormat = AFMT_S24_OE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT24 ;
stream_ . doByteSwap [ mode ] = true ;
}
}
else if ( format = = RTAUDIO_SINT32 ) {
if ( mask & AFMT_S32_NE ) {
deviceFormat = AFMT_S32_NE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT32 ;
}
else if ( mask & AFMT_S32_OE ) {
deviceFormat = AFMT_S32_OE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT32 ;
stream_ . doByteSwap [ mode ] = true ;
}
}
if ( deviceFormat = = - 1 ) {
// The user requested format is not natively supported by the device.
if ( mask & AFMT_S16_NE ) {
deviceFormat = AFMT_S16_NE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT16 ;
}
else if ( mask & AFMT_S32_NE ) {
deviceFormat = AFMT_S32_NE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT32 ;
}
else if ( mask & AFMT_S24_NE ) {
deviceFormat = AFMT_S24_NE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT24 ;
}
else if ( mask & AFMT_S16_OE ) {
deviceFormat = AFMT_S16_OE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT16 ;
stream_ . doByteSwap [ mode ] = true ;
}
else if ( mask & AFMT_S32_OE ) {
deviceFormat = AFMT_S32_OE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT32 ;
stream_ . doByteSwap [ mode ] = true ;
}
else if ( mask & AFMT_S24_OE ) {
deviceFormat = AFMT_S24_OE ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT24 ;
stream_ . doByteSwap [ mode ] = true ;
}
else if ( mask & AFMT_S8 ) {
deviceFormat = AFMT_S8 ;
stream_ . deviceFormat [ mode ] = RTAUDIO_SINT8 ;
}
}
if ( stream_ . deviceFormat [ mode ] = = 0 ) {
// This really shouldn't happen ...
close ( fd ) ;
errorStream_ < < " RtApiOss::probeDeviceOpen: device ( " < < ainfo . name < < " ) data format not supported by RtAudio. " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Set the data format.
int temp = deviceFormat ;
result = ioctl ( fd , SNDCTL_DSP_SETFMT , & deviceFormat ) ;
if ( result = = - 1 | | deviceFormat ! = temp ) {
close ( fd ) ;
errorStream_ < < " RtApiOss::probeDeviceOpen: error setting data format on device ( " < < ainfo . name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Attempt to set the buffer size. According to OSS, the minimum
// number of buffers is two. The supposed minimum buffer size is 16
// bytes, so that will be our lower bound. The argument to this
// call is in the form 0xMMMMSSSS (hex), where the buffer size (in
// bytes) is given as 2^SSSS and the number of buffers as 2^MMMM.
// We'll check the actual value used near the end of the setup
// procedure.
int ossBufferBytes = * bufferSize * formatBytes ( stream_ . deviceFormat [ mode ] ) * deviceChannels ;
if ( ossBufferBytes < 16 ) ossBufferBytes = 16 ;
int buffers = 0 ;
if ( options ) buffers = options - > numberOfBuffers ;
if ( options & & options - > flags & RTAUDIO_MINIMIZE_LATENCY ) buffers = 2 ;
if ( buffers < 2 ) buffers = 3 ;
temp = ( ( int ) buffers < < 16 ) + ( int ) ( log10 ( ( double ) ossBufferBytes ) / log10 ( 2.0 ) ) ;
result = ioctl ( fd , SNDCTL_DSP_SETFRAGMENT , & temp ) ;
if ( result = = - 1 ) {
close ( fd ) ;
errorStream_ < < " RtApiOss::probeDeviceOpen: error setting buffer size on device ( " < < ainfo . name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
stream_ . nBuffers = buffers ;
// Save buffer size (in sample frames).
* bufferSize = ossBufferBytes / ( formatBytes ( stream_ . deviceFormat [ mode ] ) * deviceChannels ) ;
stream_ . bufferSize = * bufferSize ;
// Set the sample rate.
int srate = sampleRate ;
result = ioctl ( fd , SNDCTL_DSP_SPEED , & srate ) ;
if ( result = = - 1 ) {
close ( fd ) ;
errorStream_ < < " RtApiOss::probeDeviceOpen: error setting sample rate ( " < < sampleRate < < " ) on device ( " < < ainfo . name < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
// Verify the sample rate setup worked.
if ( abs ( srate - sampleRate ) > 100 ) {
close ( fd ) ;
errorStream_ < < " RtApiOss::probeDeviceOpen: device ( " < < ainfo . name < < " ) does not support sample rate ( " < < sampleRate < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
return FAILURE ;
}
stream_ . sampleRate = sampleRate ;
if ( mode = = INPUT & & stream_ . mode = = OUTPUT & & stream_ . device [ 0 ] = = device ) {
// We're doing duplex setup here.
stream_ . deviceFormat [ 0 ] = stream_ . deviceFormat [ 1 ] ;
stream_ . nDeviceChannels [ 0 ] = deviceChannels ;
}
// Set interleaving parameters.
stream_ . userInterleaved = true ;
stream_ . deviceInterleaved [ mode ] = true ;
if ( options & & options - > flags & RTAUDIO_NONINTERLEAVED )
stream_ . userInterleaved = false ;
// Set flags for buffer conversion
stream_ . doConvertBuffer [ mode ] = false ;
if ( stream_ . userFormat ! = stream_ . deviceFormat [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . nUserChannels [ mode ] < stream_ . nDeviceChannels [ mode ] )
stream_ . doConvertBuffer [ mode ] = true ;
if ( stream_ . userInterleaved ! = stream_ . deviceInterleaved [ mode ] & &
stream_ . nUserChannels [ mode ] > 1 )
stream_ . doConvertBuffer [ mode ] = true ;
// Allocate the stream handles if necessary and then save.
if ( stream_ . apiHandle = = 0 ) {
try {
handle = new OssHandle ;
}
catch ( std : : bad_alloc & ) {
errorText_ = " RtApiOss::probeDeviceOpen: error allocating OssHandle memory. " ;
goto error ;
}
if ( pthread_cond_init ( & handle - > runnable , NULL ) ) {
errorText_ = " RtApiOss::probeDeviceOpen: error initializing pthread condition variable. " ;
goto error ;
}
stream_ . apiHandle = ( void * ) handle ;
}
else {
handle = ( OssHandle * ) stream_ . apiHandle ;
}
handle - > id [ mode ] = fd ;
// Allocate necessary internal buffers.
unsigned long bufferBytes ;
bufferBytes = stream_ . nUserChannels [ mode ] * * bufferSize * formatBytes ( stream_ . userFormat ) ;
stream_ . userBuffer [ mode ] = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . userBuffer [ mode ] = = NULL ) {
errorText_ = " RtApiOss::probeDeviceOpen: error allocating user buffer memory. " ;
goto error ;
}
if ( stream_ . doConvertBuffer [ mode ] ) {
bool makeBuffer = true ;
bufferBytes = stream_ . nDeviceChannels [ mode ] * formatBytes ( stream_ . deviceFormat [ mode ] ) ;
if ( mode = = INPUT ) {
if ( stream_ . mode = = OUTPUT & & stream_ . deviceBuffer ) {
unsigned long bytesOut = stream_ . nDeviceChannels [ 0 ] * formatBytes ( stream_ . deviceFormat [ 0 ] ) ;
if ( bufferBytes < = bytesOut ) makeBuffer = false ;
}
}
if ( makeBuffer ) {
bufferBytes * = * bufferSize ;
if ( stream_ . deviceBuffer ) free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = ( char * ) calloc ( bufferBytes , 1 ) ;
if ( stream_ . deviceBuffer = = NULL ) {
errorText_ = " RtApiOss::probeDeviceOpen: error allocating device buffer memory. " ;
goto error ;
}
}
}
stream_ . device [ mode ] = device ;
stream_ . state = STREAM_STOPPED ;
// Setup the buffer conversion information structure.
if ( stream_ . doConvertBuffer [ mode ] ) setConvertInfo ( mode , firstChannel ) ;
// Setup thread if necessary.
if ( stream_ . mode = = OUTPUT & & mode = = INPUT ) {
// We had already set up an output stream.
stream_ . mode = DUPLEX ;
if ( stream_ . device [ 0 ] = = device ) handle - > id [ 0 ] = fd ;
}
else {
stream_ . mode = mode ;
// Setup callback thread.
stream_ . callbackInfo . object = ( void * ) this ;
// Set the thread attributes for joinable and realtime scheduling
// priority. The higher priority will only take affect if the
// program is run as root or suid.
pthread_attr_t attr ;
pthread_attr_init ( & attr ) ;
pthread_attr_setdetachstate ( & attr , PTHREAD_CREATE_JOINABLE ) ;
# ifdef SCHED_RR // Undefined with some OSes (eg: NetBSD 1.6.x with GNU Pthread)
if ( options & & options - > flags & RTAUDIO_SCHEDULE_REALTIME ) {
struct sched_param param ;
int priority = options - > priority ;
int min = sched_get_priority_min ( SCHED_RR ) ;
int max = sched_get_priority_max ( SCHED_RR ) ;
if ( priority < min ) priority = min ;
else if ( priority > max ) priority = max ;
param . sched_priority = priority ;
pthread_attr_setschedparam ( & attr , & param ) ;
pthread_attr_setschedpolicy ( & attr , SCHED_RR ) ;
}
else
pthread_attr_setschedpolicy ( & attr , SCHED_OTHER ) ;
# else
pthread_attr_setschedpolicy ( & attr , SCHED_OTHER ) ;
# endif
stream_ . callbackInfo . isRunning = true ;
result = pthread_create ( & stream_ . callbackInfo . thread , & attr , ossCallbackHandler , & stream_ . callbackInfo ) ;
pthread_attr_destroy ( & attr ) ;
if ( result ) {
stream_ . callbackInfo . isRunning = false ;
errorText_ = " RtApiOss::error creating callback thread! " ;
goto error ;
}
}
return SUCCESS ;
error :
if ( handle ) {
pthread_cond_destroy ( & handle - > runnable ) ;
if ( handle - > id [ 0 ] ) close ( handle - > id [ 0 ] ) ;
if ( handle - > id [ 1 ] ) close ( handle - > id [ 1 ] ) ;
delete handle ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
return FAILURE ;
}
void RtApiOss : : closeStream ( )
{
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiOss::closeStream(): no open stream to close! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
OssHandle * handle = ( OssHandle * ) stream_ . apiHandle ;
stream_ . callbackInfo . isRunning = false ;
MUTEX_LOCK ( & stream_ . mutex ) ;
if ( stream_ . state = = STREAM_STOPPED )
pthread_cond_signal ( & handle - > runnable ) ;
MUTEX_UNLOCK ( & stream_ . mutex ) ;
pthread_join ( stream_ . callbackInfo . thread , NULL ) ;
if ( stream_ . state = = STREAM_RUNNING ) {
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX )
ioctl ( handle - > id [ 0 ] , SNDCTL_DSP_HALT , 0 ) ;
else
ioctl ( handle - > id [ 1 ] , SNDCTL_DSP_HALT , 0 ) ;
stream_ . state = STREAM_STOPPED ;
}
if ( handle ) {
pthread_cond_destroy ( & handle - > runnable ) ;
if ( handle - > id [ 0 ] ) close ( handle - > id [ 0 ] ) ;
if ( handle - > id [ 1 ] ) close ( handle - > id [ 1 ] ) ;
delete handle ;
stream_ . apiHandle = 0 ;
}
for ( int i = 0 ; i < 2 ; i + + ) {
if ( stream_ . userBuffer [ i ] ) {
free ( stream_ . userBuffer [ i ] ) ;
stream_ . userBuffer [ i ] = 0 ;
}
}
if ( stream_ . deviceBuffer ) {
free ( stream_ . deviceBuffer ) ;
stream_ . deviceBuffer = 0 ;
}
stream_ . mode = UNINITIALIZED ;
stream_ . state = STREAM_CLOSED ;
}
void RtApiOss : : startStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_RUNNING ) {
errorText_ = " RtApiOss::startStream(): the stream is already running! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
MUTEX_LOCK ( & stream_ . mutex ) ;
stream_ . state = STREAM_RUNNING ;
// No need to do anything else here ... OSS automatically starts
// when fed samples.
MUTEX_UNLOCK ( & stream_ . mutex ) ;
OssHandle * handle = ( OssHandle * ) stream_ . apiHandle ;
pthread_cond_signal ( & handle - > runnable ) ;
}
void RtApiOss : : stopStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiOss::stopStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
MUTEX_LOCK ( & stream_ . mutex ) ;
// The state might change while waiting on a mutex.
if ( stream_ . state = = STREAM_STOPPED ) {
MUTEX_UNLOCK ( & stream_ . mutex ) ;
return ;
}
int result = 0 ;
OssHandle * handle = ( OssHandle * ) stream_ . apiHandle ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
// Flush the output with zeros a few times.
char * buffer ;
int samples ;
RtAudioFormat format ;
if ( stream_ . doConvertBuffer [ 0 ] ) {
buffer = stream_ . deviceBuffer ;
samples = stream_ . bufferSize * stream_ . nDeviceChannels [ 0 ] ;
format = stream_ . deviceFormat [ 0 ] ;
}
else {
buffer = stream_ . userBuffer [ 0 ] ;
samples = stream_ . bufferSize * stream_ . nUserChannels [ 0 ] ;
format = stream_ . userFormat ;
}
memset ( buffer , 0 , samples * formatBytes ( format ) ) ;
for ( unsigned int i = 0 ; i < stream_ . nBuffers + 1 ; i + + ) {
result = write ( handle - > id [ 0 ] , buffer , samples * formatBytes ( format ) ) ;
if ( result = = - 1 ) {
errorText_ = " RtApiOss::stopStream: audio write error. " ;
error ( RtAudioError : : WARNING ) ;
}
}
result = ioctl ( handle - > id [ 0 ] , SNDCTL_DSP_HALT , 0 ) ;
if ( result = = - 1 ) {
errorStream_ < < " RtApiOss::stopStream: system error stopping callback procedure on device ( " < < stream_ . device [ 0 ] < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
handle - > triggered = false ;
}
if ( stream_ . mode = = INPUT | | ( stream_ . mode = = DUPLEX & & handle - > id [ 0 ] ! = handle - > id [ 1 ] ) ) {
result = ioctl ( handle - > id [ 1 ] , SNDCTL_DSP_HALT , 0 ) ;
if ( result = = - 1 ) {
errorStream_ < < " RtApiOss::stopStream: system error stopping input callback procedure on device ( " < < stream_ . device [ 0 ] < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
unlock :
stream_ . state = STREAM_STOPPED ;
MUTEX_UNLOCK ( & stream_ . mutex ) ;
if ( result ! = - 1 ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiOss : : abortStream ( )
{
verifyStream ( ) ;
if ( stream_ . state = = STREAM_STOPPED ) {
errorText_ = " RtApiOss::abortStream(): the stream is already stopped! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
MUTEX_LOCK ( & stream_ . mutex ) ;
// The state might change while waiting on a mutex.
if ( stream_ . state = = STREAM_STOPPED ) {
MUTEX_UNLOCK ( & stream_ . mutex ) ;
return ;
}
int result = 0 ;
OssHandle * handle = ( OssHandle * ) stream_ . apiHandle ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
result = ioctl ( handle - > id [ 0 ] , SNDCTL_DSP_HALT , 0 ) ;
if ( result = = - 1 ) {
errorStream_ < < " RtApiOss::abortStream: system error stopping callback procedure on device ( " < < stream_ . device [ 0 ] < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
handle - > triggered = false ;
}
if ( stream_ . mode = = INPUT | | ( stream_ . mode = = DUPLEX & & handle - > id [ 0 ] ! = handle - > id [ 1 ] ) ) {
result = ioctl ( handle - > id [ 1 ] , SNDCTL_DSP_HALT , 0 ) ;
if ( result = = - 1 ) {
errorStream_ < < " RtApiOss::abortStream: system error stopping input callback procedure on device ( " < < stream_ . device [ 0 ] < < " ). " ;
errorText_ = errorStream_ . str ( ) ;
goto unlock ;
}
}
unlock :
stream_ . state = STREAM_STOPPED ;
MUTEX_UNLOCK ( & stream_ . mutex ) ;
if ( result ! = - 1 ) return ;
error ( RtAudioError : : SYSTEM_ERROR ) ;
}
void RtApiOss : : callbackEvent ( )
{
OssHandle * handle = ( OssHandle * ) stream_ . apiHandle ;
if ( stream_ . state = = STREAM_STOPPED ) {
MUTEX_LOCK ( & stream_ . mutex ) ;
pthread_cond_wait ( & handle - > runnable , & stream_ . mutex ) ;
if ( stream_ . state ! = STREAM_RUNNING ) {
MUTEX_UNLOCK ( & stream_ . mutex ) ;
return ;
}
MUTEX_UNLOCK ( & stream_ . mutex ) ;
}
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApiOss::callbackEvent(): the stream is closed ... this shouldn't happen! " ;
error ( RtAudioError : : WARNING ) ;
return ;
}
// Invoke user callback to get fresh output data.
int doStopStream = 0 ;
RtAudioCallback callback = ( RtAudioCallback ) stream_ . callbackInfo . callback ;
double streamTime = getStreamTime ( ) ;
RtAudioStreamStatus status = 0 ;
if ( stream_ . mode ! = INPUT & & handle - > xrun [ 0 ] = = true ) {
status | = RTAUDIO_OUTPUT_UNDERFLOW ;
handle - > xrun [ 0 ] = false ;
}
if ( stream_ . mode ! = OUTPUT & & handle - > xrun [ 1 ] = = true ) {
status | = RTAUDIO_INPUT_OVERFLOW ;
handle - > xrun [ 1 ] = false ;
}
doStopStream = callback ( stream_ . userBuffer [ 0 ] , stream_ . userBuffer [ 1 ] ,
stream_ . bufferSize , streamTime , status , stream_ . callbackInfo . userData ) ;
if ( doStopStream = = 2 ) {
this - > abortStream ( ) ;
return ;
}
MUTEX_LOCK ( & stream_ . mutex ) ;
// The state might change while waiting on a mutex.
if ( stream_ . state = = STREAM_STOPPED ) goto unlock ;
int result ;
char * buffer ;
int samples ;
RtAudioFormat format ;
if ( stream_ . mode = = OUTPUT | | stream_ . mode = = DUPLEX ) {
// Setup parameters and do buffer conversion if necessary.
if ( stream_ . doConvertBuffer [ 0 ] ) {
buffer = stream_ . deviceBuffer ;
convertBuffer ( buffer , stream_ . userBuffer [ 0 ] , stream_ . convertInfo [ 0 ] ) ;
samples = stream_ . bufferSize * stream_ . nDeviceChannels [ 0 ] ;
format = stream_ . deviceFormat [ 0 ] ;
}
else {
buffer = stream_ . userBuffer [ 0 ] ;
samples = stream_ . bufferSize * stream_ . nUserChannels [ 0 ] ;
format = stream_ . userFormat ;
}
// Do byte swapping if necessary.
if ( stream_ . doByteSwap [ 0 ] )
byteSwapBuffer ( buffer , samples , format ) ;
if ( stream_ . mode = = DUPLEX & & handle - > triggered = = false ) {
int trig = 0 ;
ioctl ( handle - > id [ 0 ] , SNDCTL_DSP_SETTRIGGER , & trig ) ;
result = write ( handle - > id [ 0 ] , buffer , samples * formatBytes ( format ) ) ;
trig = PCM_ENABLE_INPUT | PCM_ENABLE_OUTPUT ;
ioctl ( handle - > id [ 0 ] , SNDCTL_DSP_SETTRIGGER , & trig ) ;
handle - > triggered = true ;
}
else
// Write samples to device.
result = write ( handle - > id [ 0 ] , buffer , samples * formatBytes ( format ) ) ;
if ( result = = - 1 ) {
// We'll assume this is an underrun, though there isn't a
// specific means for determining that.
handle - > xrun [ 0 ] = true ;
errorText_ = " RtApiOss::callbackEvent: audio write error. " ;
error ( RtAudioError : : WARNING ) ;
// Continue on to input section.
}
}
if ( stream_ . mode = = INPUT | | stream_ . mode = = DUPLEX ) {
// Setup parameters.
if ( stream_ . doConvertBuffer [ 1 ] ) {
buffer = stream_ . deviceBuffer ;
samples = stream_ . bufferSize * stream_ . nDeviceChannels [ 1 ] ;
format = stream_ . deviceFormat [ 1 ] ;
}
else {
buffer = stream_ . userBuffer [ 1 ] ;
samples = stream_ . bufferSize * stream_ . nUserChannels [ 1 ] ;
format = stream_ . userFormat ;
}
// Read samples from device.
result = read ( handle - > id [ 1 ] , buffer , samples * formatBytes ( format ) ) ;
if ( result = = - 1 ) {
// We'll assume this is an overrun, though there isn't a
// specific means for determining that.
handle - > xrun [ 1 ] = true ;
errorText_ = " RtApiOss::callbackEvent: audio read error. " ;
error ( RtAudioError : : WARNING ) ;
goto unlock ;
}
// Do byte swapping if necessary.
if ( stream_ . doByteSwap [ 1 ] )
byteSwapBuffer ( buffer , samples , format ) ;
// Do buffer conversion if necessary.
if ( stream_ . doConvertBuffer [ 1 ] )
convertBuffer ( stream_ . userBuffer [ 1 ] , stream_ . deviceBuffer , stream_ . convertInfo [ 1 ] ) ;
}
unlock :
MUTEX_UNLOCK ( & stream_ . mutex ) ;
RtApi : : tickStreamTime ( ) ;
if ( doStopStream = = 1 ) this - > stopStream ( ) ;
}
static void * ossCallbackHandler ( void * ptr )
{
CallbackInfo * info = ( CallbackInfo * ) ptr ;
RtApiOss * object = ( RtApiOss * ) info - > object ;
bool * isRunning = & info - > isRunning ;
while ( * isRunning = = true ) {
pthread_testcancel ( ) ;
object - > callbackEvent ( ) ;
}
pthread_exit ( NULL ) ;
}
//******************** End of __LINUX_OSS__ *********************//
# endif
// *************************************************** //
//
// Protected common (OS-independent) RtAudio methods.
//
// *************************************************** //
// This method can be modified to control the behavior of error
// message printing.
void RtApi : : error ( RtAudioError : : Type type )
{
errorStream_ . str ( " " ) ; // clear the ostringstream
RtAudioErrorCallback errorCallback = ( RtAudioErrorCallback ) stream_ . callbackInfo . errorCallback ;
if ( errorCallback ) {
// abortStream() can generate new error messages. Ignore them. Just keep original one.
if ( firstErrorOccurred_ )
return ;
firstErrorOccurred_ = true ;
const std : : string errorMessage = errorText_ ;
if ( type ! = RtAudioError : : WARNING & & stream_ . state ! = STREAM_STOPPED ) {
stream_ . callbackInfo . isRunning = false ; // exit from the thread
abortStream ( ) ;
}
errorCallback ( type , errorMessage ) ;
firstErrorOccurred_ = false ;
return ;
}
if ( type = = RtAudioError : : WARNING & & showWarnings_ = = true )
std : : cerr < < ' \n ' < < errorText_ < < " \n \n " ;
else if ( type ! = RtAudioError : : WARNING )
throw ( RtAudioError ( errorText_ , type ) ) ;
}
void RtApi : : verifyStream ( )
{
if ( stream_ . state = = STREAM_CLOSED ) {
errorText_ = " RtApi:: a stream is not open! " ;
error ( RtAudioError : : INVALID_USE ) ;
}
}
void RtApi : : clearStreamInfo ( )
{
stream_ . mode = UNINITIALIZED ;
stream_ . state = STREAM_CLOSED ;
stream_ . sampleRate = 0 ;
stream_ . bufferSize = 0 ;
stream_ . nBuffers = 0 ;
stream_ . userFormat = 0 ;
stream_ . userInterleaved = true ;
stream_ . streamTime = 0.0 ;
stream_ . apiHandle = 0 ;
stream_ . deviceBuffer = 0 ;
stream_ . callbackInfo . callback = 0 ;
stream_ . callbackInfo . userData = 0 ;
stream_ . callbackInfo . isRunning = false ;
stream_ . callbackInfo . errorCallback = 0 ;
for ( int i = 0 ; i < 2 ; i + + ) {
stream_ . device [ i ] = 11111 ;
stream_ . doConvertBuffer [ i ] = false ;
stream_ . deviceInterleaved [ i ] = true ;
stream_ . doByteSwap [ i ] = false ;
stream_ . nUserChannels [ i ] = 0 ;
stream_ . nDeviceChannels [ i ] = 0 ;
stream_ . channelOffset [ i ] = 0 ;
stream_ . deviceFormat [ i ] = 0 ;
stream_ . latency [ i ] = 0 ;
stream_ . userBuffer [ i ] = 0 ;
stream_ . convertInfo [ i ] . channels = 0 ;
stream_ . convertInfo [ i ] . inJump = 0 ;
stream_ . convertInfo [ i ] . outJump = 0 ;
stream_ . convertInfo [ i ] . inFormat = 0 ;
stream_ . convertInfo [ i ] . outFormat = 0 ;
stream_ . convertInfo [ i ] . inOffset . clear ( ) ;
stream_ . convertInfo [ i ] . outOffset . clear ( ) ;
}
}
unsigned int RtApi : : formatBytes ( RtAudioFormat format )
{
if ( format = = RTAUDIO_SINT16 )
return 2 ;
else if ( format = = RTAUDIO_SINT32 | | format = = RTAUDIO_FLOAT32 )
return 4 ;
else if ( format = = RTAUDIO_FLOAT64 )
return 8 ;
else if ( format = = RTAUDIO_SINT24 )
return 3 ;
else if ( format = = RTAUDIO_SINT8 )
return 1 ;
errorText_ = " RtApi::formatBytes: undefined format. " ;
error ( RtAudioError : : WARNING ) ;
return 0 ;
}
void RtApi : : setConvertInfo ( StreamMode mode , unsigned int firstChannel )
{
if ( mode = = INPUT ) { // convert device to user buffer
stream_ . convertInfo [ mode ] . inJump = stream_ . nDeviceChannels [ 1 ] ;
stream_ . convertInfo [ mode ] . outJump = stream_ . nUserChannels [ 1 ] ;
stream_ . convertInfo [ mode ] . inFormat = stream_ . deviceFormat [ 1 ] ;
stream_ . convertInfo [ mode ] . outFormat = stream_ . userFormat ;
}
else { // convert user to device buffer
stream_ . convertInfo [ mode ] . inJump = stream_ . nUserChannels [ 0 ] ;
stream_ . convertInfo [ mode ] . outJump = stream_ . nDeviceChannels [ 0 ] ;
stream_ . convertInfo [ mode ] . inFormat = stream_ . userFormat ;
stream_ . convertInfo [ mode ] . outFormat = stream_ . deviceFormat [ 0 ] ;
}
if ( stream_ . convertInfo [ mode ] . inJump < stream_ . convertInfo [ mode ] . outJump )
stream_ . convertInfo [ mode ] . channels = stream_ . convertInfo [ mode ] . inJump ;
else
stream_ . convertInfo [ mode ] . channels = stream_ . convertInfo [ mode ] . outJump ;
// Set up the interleave/deinterleave offsets.
if ( stream_ . deviceInterleaved [ mode ] ! = stream_ . userInterleaved ) {
if ( ( mode = = OUTPUT & & stream_ . deviceInterleaved [ mode ] ) | |
( mode = = INPUT & & stream_ . userInterleaved ) ) {
for ( int k = 0 ; k < stream_ . convertInfo [ mode ] . channels ; k + + ) {
stream_ . convertInfo [ mode ] . inOffset . push_back ( k * stream_ . bufferSize ) ;
stream_ . convertInfo [ mode ] . outOffset . push_back ( k ) ;
stream_ . convertInfo [ mode ] . inJump = 1 ;
}
}
else {
for ( int k = 0 ; k < stream_ . convertInfo [ mode ] . channels ; k + + ) {
stream_ . convertInfo [ mode ] . inOffset . push_back ( k ) ;
stream_ . convertInfo [ mode ] . outOffset . push_back ( k * stream_ . bufferSize ) ;
stream_ . convertInfo [ mode ] . outJump = 1 ;
}
}
}
else { // no (de)interleaving
if ( stream_ . userInterleaved ) {
for ( int k = 0 ; k < stream_ . convertInfo [ mode ] . channels ; k + + ) {
stream_ . convertInfo [ mode ] . inOffset . push_back ( k ) ;
stream_ . convertInfo [ mode ] . outOffset . push_back ( k ) ;
}
}
else {
for ( int k = 0 ; k < stream_ . convertInfo [ mode ] . channels ; k + + ) {
stream_ . convertInfo [ mode ] . inOffset . push_back ( k * stream_ . bufferSize ) ;
stream_ . convertInfo [ mode ] . outOffset . push_back ( k * stream_ . bufferSize ) ;
stream_ . convertInfo [ mode ] . inJump = 1 ;
stream_ . convertInfo [ mode ] . outJump = 1 ;
}
}
}
// Add channel offset.
if ( firstChannel > 0 ) {
if ( stream_ . deviceInterleaved [ mode ] ) {
if ( mode = = OUTPUT ) {
for ( int k = 0 ; k < stream_ . convertInfo [ mode ] . channels ; k + + )
stream_ . convertInfo [ mode ] . outOffset [ k ] + = firstChannel ;
}
else {
for ( int k = 0 ; k < stream_ . convertInfo [ mode ] . channels ; k + + )
stream_ . convertInfo [ mode ] . inOffset [ k ] + = firstChannel ;
}
}
else {
if ( mode = = OUTPUT ) {
for ( int k = 0 ; k < stream_ . convertInfo [ mode ] . channels ; k + + )
stream_ . convertInfo [ mode ] . outOffset [ k ] + = ( firstChannel * stream_ . bufferSize ) ;
}
else {
for ( int k = 0 ; k < stream_ . convertInfo [ mode ] . channels ; k + + )
stream_ . convertInfo [ mode ] . inOffset [ k ] + = ( firstChannel * stream_ . bufferSize ) ;
}
}
}
}
void RtApi : : convertBuffer ( char * outBuffer , char * inBuffer , ConvertInfo & info )
{
// This function does format conversion, input/output channel compensation, and
// data interleaving/deinterleaving. 24-bit integers are assumed to occupy
// the lower three bytes of a 32-bit integer.
// Clear our device buffer when in/out duplex device channels are different
if ( outBuffer = = stream_ . deviceBuffer & & stream_ . mode = = DUPLEX & &
( stream_ . nDeviceChannels [ 0 ] < stream_ . nDeviceChannels [ 1 ] ) )
memset ( outBuffer , 0 , stream_ . bufferSize * info . outJump * formatBytes ( info . outFormat ) ) ;
int j ;
if ( info . outFormat = = RTAUDIO_FLOAT64 ) {
Float64 scale ;
Float64 * out = ( Float64 * ) outBuffer ;
if ( info . inFormat = = RTAUDIO_SINT8 ) {
signed char * in = ( signed char * ) inBuffer ;
scale = 1.0 / 127.5 ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float64 ) in [ info . inOffset [ j ] ] ;
out [ info . outOffset [ j ] ] + = 0.5 ;
out [ info . outOffset [ j ] ] * = scale ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT16 ) {
Int16 * in = ( Int16 * ) inBuffer ;
scale = 1.0 / 32767.5 ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float64 ) in [ info . inOffset [ j ] ] ;
out [ info . outOffset [ j ] ] + = 0.5 ;
out [ info . outOffset [ j ] ] * = scale ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT24 ) {
Int24 * in = ( Int24 * ) inBuffer ;
scale = 1.0 / 8388607.5 ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float64 ) ( in [ info . inOffset [ j ] ] . asInt ( ) ) ;
out [ info . outOffset [ j ] ] + = 0.5 ;
out [ info . outOffset [ j ] ] * = scale ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT32 ) {
Int32 * in = ( Int32 * ) inBuffer ;
scale = 1.0 / 2147483647.5 ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float64 ) in [ info . inOffset [ j ] ] ;
out [ info . outOffset [ j ] ] + = 0.5 ;
out [ info . outOffset [ j ] ] * = scale ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT32 ) {
Float32 * in = ( Float32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float64 ) in [ info . inOffset [ j ] ] ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT64 ) {
// Channel compensation and/or (de)interleaving only.
Float64 * in = ( Float64 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = in [ info . inOffset [ j ] ] ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
}
else if ( info . outFormat = = RTAUDIO_FLOAT32 ) {
Float32 scale ;
Float32 * out = ( Float32 * ) outBuffer ;
if ( info . inFormat = = RTAUDIO_SINT8 ) {
signed char * in = ( signed char * ) inBuffer ;
scale = ( Float32 ) ( 1.0 / 127.5 ) ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float32 ) in [ info . inOffset [ j ] ] ;
out [ info . outOffset [ j ] ] + = 0.5 ;
out [ info . outOffset [ j ] ] * = scale ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT16 ) {
Int16 * in = ( Int16 * ) inBuffer ;
scale = ( Float32 ) ( 1.0 / 32767.5 ) ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float32 ) in [ info . inOffset [ j ] ] ;
out [ info . outOffset [ j ] ] + = 0.5 ;
out [ info . outOffset [ j ] ] * = scale ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT24 ) {
Int24 * in = ( Int24 * ) inBuffer ;
scale = ( Float32 ) ( 1.0 / 8388607.5 ) ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float32 ) ( in [ info . inOffset [ j ] ] . asInt ( ) ) ;
out [ info . outOffset [ j ] ] + = 0.5 ;
out [ info . outOffset [ j ] ] * = scale ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT32 ) {
Int32 * in = ( Int32 * ) inBuffer ;
scale = ( Float32 ) ( 1.0 / 2147483647.5 ) ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float32 ) in [ info . inOffset [ j ] ] ;
out [ info . outOffset [ j ] ] + = 0.5 ;
out [ info . outOffset [ j ] ] * = scale ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT32 ) {
// Channel compensation and/or (de)interleaving only.
Float32 * in = ( Float32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = in [ info . inOffset [ j ] ] ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT64 ) {
Float64 * in = ( Float64 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Float32 ) in [ info . inOffset [ j ] ] ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
}
else if ( info . outFormat = = RTAUDIO_SINT32 ) {
Int32 * out = ( Int32 * ) outBuffer ;
if ( info . inFormat = = RTAUDIO_SINT8 ) {
signed char * in = ( signed char * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) in [ info . inOffset [ j ] ] ;
out [ info . outOffset [ j ] ] < < = 24 ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT16 ) {
Int16 * in = ( Int16 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) in [ info . inOffset [ j ] ] ;
out [ info . outOffset [ j ] ] < < = 16 ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT24 ) {
Int24 * in = ( Int24 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) in [ info . inOffset [ j ] ] . asInt ( ) ;
out [ info . outOffset [ j ] ] < < = 8 ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT32 ) {
// Channel compensation and/or (de)interleaving only.
Int32 * in = ( Int32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = in [ info . inOffset [ j ] ] ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT32 ) {
Float32 * in = ( Float32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) ( in [ info . inOffset [ j ] ] * 2147483647.5 - 0.5 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT64 ) {
Float64 * in = ( Float64 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) ( in [ info . inOffset [ j ] ] * 2147483647.5 - 0.5 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
}
else if ( info . outFormat = = RTAUDIO_SINT24 ) {
Int24 * out = ( Int24 * ) outBuffer ;
if ( info . inFormat = = RTAUDIO_SINT8 ) {
signed char * in = ( signed char * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) ( in [ info . inOffset [ j ] ] < < 16 ) ;
//out[info.outOffset[j]] <<= 16;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT16 ) {
Int16 * in = ( Int16 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) ( in [ info . inOffset [ j ] ] < < 8 ) ;
//out[info.outOffset[j]] <<= 8;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT24 ) {
// Channel compensation and/or (de)interleaving only.
Int24 * in = ( Int24 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = in [ info . inOffset [ j ] ] ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT32 ) {
Int32 * in = ( Int32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) ( in [ info . inOffset [ j ] ] > > 8 ) ;
//out[info.outOffset[j]] >>= 8;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT32 ) {
Float32 * in = ( Float32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) ( in [ info . inOffset [ j ] ] * 8388607.5 - 0.5 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT64 ) {
Float64 * in = ( Float64 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int32 ) ( in [ info . inOffset [ j ] ] * 8388607.5 - 0.5 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
}
else if ( info . outFormat = = RTAUDIO_SINT16 ) {
Int16 * out = ( Int16 * ) outBuffer ;
if ( info . inFormat = = RTAUDIO_SINT8 ) {
signed char * in = ( signed char * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int16 ) in [ info . inOffset [ j ] ] ;
out [ info . outOffset [ j ] ] < < = 8 ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT16 ) {
// Channel compensation and/or (de)interleaving only.
Int16 * in = ( Int16 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = in [ info . inOffset [ j ] ] ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT24 ) {
Int24 * in = ( Int24 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int16 ) ( in [ info . inOffset [ j ] ] . asInt ( ) > > 8 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT32 ) {
Int32 * in = ( Int32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int16 ) ( ( in [ info . inOffset [ j ] ] > > 16 ) & 0x0000ffff ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT32 ) {
Float32 * in = ( Float32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int16 ) ( in [ info . inOffset [ j ] ] * 32767.5 - 0.5 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT64 ) {
Float64 * in = ( Float64 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( Int16 ) ( in [ info . inOffset [ j ] ] * 32767.5 - 0.5 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
}
else if ( info . outFormat = = RTAUDIO_SINT8 ) {
signed char * out = ( signed char * ) outBuffer ;
if ( info . inFormat = = RTAUDIO_SINT8 ) {
// Channel compensation and/or (de)interleaving only.
signed char * in = ( signed char * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = in [ info . inOffset [ j ] ] ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
if ( info . inFormat = = RTAUDIO_SINT16 ) {
Int16 * in = ( Int16 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( signed char ) ( ( in [ info . inOffset [ j ] ] > > 8 ) & 0x00ff ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT24 ) {
Int24 * in = ( Int24 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( signed char ) ( in [ info . inOffset [ j ] ] . asInt ( ) > > 16 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_SINT32 ) {
Int32 * in = ( Int32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( signed char ) ( ( in [ info . inOffset [ j ] ] > > 24 ) & 0x000000ff ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT32 ) {
Float32 * in = ( Float32 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( signed char ) ( in [ info . inOffset [ j ] ] * 127.5 - 0.5 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
else if ( info . inFormat = = RTAUDIO_FLOAT64 ) {
Float64 * in = ( Float64 * ) inBuffer ;
for ( unsigned int i = 0 ; i < stream_ . bufferSize ; i + + ) {
for ( j = 0 ; j < info . channels ; j + + ) {
out [ info . outOffset [ j ] ] = ( signed char ) ( in [ info . inOffset [ j ] ] * 127.5 - 0.5 ) ;
}
in + = info . inJump ;
out + = info . outJump ;
}
}
}
}
//static inline uint16_t bswap_16(uint16_t x) { return (x>>8) | (x<<8); }
//static inline uint32_t bswap_32(uint32_t x) { return (bswap_16(x&0xffff)<<16) | (bswap_16(x>>16)); }
//static inline uint64_t bswap_64(uint64_t x) { return (((unsigned long long)bswap_32(x&0xffffffffull))<<32) | (bswap_32(x>>32)); }
void RtApi : : byteSwapBuffer ( char * buffer , unsigned int samples , RtAudioFormat format )
{
register char val ;
register char * ptr ;
ptr = buffer ;
if ( format = = RTAUDIO_SINT16 ) {
for ( unsigned int i = 0 ; i < samples ; i + + ) {
// Swap 1st and 2nd bytes.
val = * ( ptr ) ;
* ( ptr ) = * ( ptr + 1 ) ;
* ( ptr + 1 ) = val ;
// Increment 2 bytes.
ptr + = 2 ;
}
}
else if ( format = = RTAUDIO_SINT32 | |
format = = RTAUDIO_FLOAT32 ) {
for ( unsigned int i = 0 ; i < samples ; i + + ) {
// Swap 1st and 4th bytes.
val = * ( ptr ) ;
* ( ptr ) = * ( ptr + 3 ) ;
* ( ptr + 3 ) = val ;
// Swap 2nd and 3rd bytes.
ptr + = 1 ;
val = * ( ptr ) ;
* ( ptr ) = * ( ptr + 1 ) ;
* ( ptr + 1 ) = val ;
// Increment 3 more bytes.
ptr + = 3 ;
}
}
else if ( format = = RTAUDIO_SINT24 ) {
for ( unsigned int i = 0 ; i < samples ; i + + ) {
// Swap 1st and 3rd bytes.
val = * ( ptr ) ;
* ( ptr ) = * ( ptr + 2 ) ;
* ( ptr + 2 ) = val ;
// Increment 2 more bytes.
ptr + = 2 ;
}
}
else if ( format = = RTAUDIO_FLOAT64 ) {
for ( unsigned int i = 0 ; i < samples ; i + + ) {
// Swap 1st and 8th bytes
val = * ( ptr ) ;
* ( ptr ) = * ( ptr + 7 ) ;
* ( ptr + 7 ) = val ;
// Swap 2nd and 7th bytes
ptr + = 1 ;
val = * ( ptr ) ;
* ( ptr ) = * ( ptr + 5 ) ;
* ( ptr + 5 ) = val ;
// Swap 3rd and 6th bytes
ptr + = 1 ;
val = * ( ptr ) ;
* ( ptr ) = * ( ptr + 3 ) ;
* ( ptr + 3 ) = val ;
// Swap 4th and 5th bytes
ptr + = 1 ;
val = * ( ptr ) ;
* ( ptr ) = * ( ptr + 1 ) ;
* ( ptr + 1 ) = val ;
// Increment 5 more bytes.
ptr + = 5 ;
}
}
}
// Indentation settings for Vim and Emacs
//
// Local Variables:
// c-basic-offset: 2
// indent-tabs-mode: nil
// End:
//
// vim: et sts=2 sw=2
# endif