libcm/cmAudioPort.h

154 rader
6.2 KiB
C

//( { file_desc: "Cross platform audio device interface." kw:[audio rt] }
//
// This interface provides data declarations for platform dependent
// audio I/O functions. The implementation for the functions are
// in platform specific modules. See cmAudioPortOsx.c and cmAudioPortAlsa.c.
//
// ALSA Notes:
// Assign capture device to line or mic input:
// amixer -c 0 cset iface=MIXER,name='Input Source',index=0 Mic
// amixer -c 0 cset iface=MIXER,name='Input Source',index=0 Line
//
// -c 0 select the first card
// -iface=MIXER the cset is targetting the MIXER component
// -name='Input Source',index=0 the control to set is the first 'Input Source'
// Note that the 'Capture' control sets the input gain.
//
// See alsamixer for a GUI to accomplish the same thing.
//
//
//)
#ifndef cmAudioPort_h
#define cmAudioPort_h
#ifdef __cplusplus
extern "C" {
#endif
//(
typedef unsigned cmApRC_t; // Audio port interface result code.
typedef float cmApSample_t; // Audio sample type.
enum
{
kOkApRC =0,
kSysErrApRC,
kInvalidDevIdApRC,
kAudioPortFileFailApRC,
kParamRangeErrorApRC,
kThreadFailApRC
};
// cmApAudioPacket_t flags
enum
{
kInterleavedApFl = 0x01, // The audio samples are interleaved.
kFloatApFl = 0x02 // The audio samples are single precision floating point values.
};
// Audio packet record used by the cmApAudioPacket_t callback.
// Audio ports send and receive audio using this data structure.
typedef struct
{
unsigned devIdx; // device associated with packet
unsigned begChIdx; // first device channel
unsigned chCnt; // count of channels
unsigned audioFramesCnt; // samples per channel (see note below)
unsigned bitsPerSample; // bits per sample word
unsigned flags; // kInterleavedApFl | kFloatApFl
void* audioBytesPtr; // pointer to sample data
void* userCbPtr; // user defined value passed in cmApDeviceSetup()
cmTimeSpec_t timeStamp; // Packet time stamp.
} cmApAudioPacket_t;
// Audio port callback signature.
// inPktArray[inPktCnt] are full packets of audio coming from the ADC to the application.
// outPktArray[outPktCnt] are empty packets of audio which will be filled by the application
// and then sent to the DAC.
//
// The value of audioFrameCnt gives the number of samples per channel which are available
// in the packet data buffer 'audioBytesPtr'. The callback function may decrease this number in
// output packets if the number of samples available is less than the size of the buffer.
// It is the responsibility of the calling audio port to notice this change and pass the new,
// decreased number of samples to the hardware.
//
// In general it should be assmed that this call is made from a system thread which is not
// the same as the application thread.
// The usual thread safety precautions should therefore be taken if this function implementation
// interacts with data structures also handled by the application. The audio buffer class (\see cmApBuf.h)
// is designed to provide a safe and efficient way to communicate between
// the audio thread and the application.
typedef void (*cmApCallbackPtr_t)( cmApAudioPacket_t* inPktArray, unsigned inPktCnt, cmApAudioPacket_t* outPktArray, unsigned outPktCnt );
// Setup the audio port management object for this machine.
cmApRC_t cmApInitialize( cmRpt_t* rpt );
// Stop all audio devices and release any resources held
// by the audio port management object.
cmApRC_t cmApFinalize();
// Return the count of audio devices attached to this machine.
unsigned cmApDeviceCount();
// Get a textual description of the device at index 'devIdx'.
const char* cmApDeviceLabel( unsigned devIdx );
// Given an audio device label return the associated device index.
unsigned cmApDeviceLabelToIndex( const cmChar_t* label );
// Get the count of audio input or output channesl on device at index 'devIdx'.
unsigned cmApDeviceChannelCount( unsigned devIdx, bool inputFl );
// Get the current sample rate of a device. Note that if the device has both
// input and output capability then the sample rate is the same for both.
double cmApDeviceSampleRate( unsigned devIdx );
// Get the count of samples per callback for the input or output for this device.
unsigned cmApDeviceFramesPerCycle( unsigned devIdx, bool inputFl );
// Configure a device.
// All devices must be setup before they are started.
// framesPerCycle is the requested number of samples per audio callback. The
// actual number of samples made from a callback may be smaller. See the note
// regarding this in cmApAudioPacket_t.
// If the device cannot support the requested configuration then the function
// will return an error code.
// If the device is started when this function is called then it will be
// automatically stopped and then restarted following the reconfiguration.
// If the reconfiguration fails then the device may not be restared.
cmApRC_t cmApDeviceSetup(
unsigned devIdx,
double srate,
unsigned framesPerCycle,
cmApCallbackPtr_t callbackPtr,
void* userCbPtr );
// Start a device. Note that the callback may be made prior to this function returning.
cmApRC_t cmApDeviceStart( unsigned devIdx );
// Stop a device.
cmApRC_t cmApDeviceStop( unsigned devIdx );
// Return true if the device is currently started.
bool cmApDeviceIsStarted( unsigned devIdx );
// Print a report of all the current audio device configurations.
void cmApReport( cmRpt_t* rpt );
// Test the audio port by synthesizing a sine signal or passing audio through
// from the input to the output. This is also a good example of how to
// use all of the functions in the interface.
// Set runFl to false to print a report without starting any audio devices.
// See cmAudiotPortTest.c for usage example for this function.
int cmApPortTest(bool runFl, cmRpt_t* rpt, int argc, const char* argv[] );
//)
#ifdef __cplusplus
}
#endif
#endif