static int lua_alDistanceModel(lua_State* lua_state)
{
ALenum enum_parameter;
enum_parameter = lua_tointeger(lua_state, 1);
alDistanceModel(enum_parameter);
return 0;
}
bool ALSound::Create()
{
CleanUp();
if (m_enabled)
return true;
GetLogger()->Info("Opening audio device...\n");
m_device = alcOpenDevice(nullptr);
if (!m_device)
{
GetLogger()->Error("Could not open audio device!\n");
return false;
}
m_context = alcCreateContext(m_device, nullptr);
if (!m_context)
{
GetLogger()->Error("Could not create audio context!\n");
return false;
}
alcMakeContextCurrent(m_context);
alListenerf(AL_GAIN, m_audioVolume);
alDistanceModel(AL_LINEAR_DISTANCE_CLAMPED);
GetLogger()->Info("Done.\n");
m_enabled = true;
return true;
}
COpenALSound::COpenALSound()
{
maxSounds = configHandler.GetInt("MaxSounds",16);
noSound = false;
cur = 0;
if (!noSound) {
ALCdevice *device = alcOpenDevice(NULL);
if (device != NULL) {
ALCcontext *context = alcCreateContext(device, NULL);
if (context != NULL)
alcMakeContextCurrent(context);
else {
handleerror(0, "Could not create audio context","OpenAL error",MBF_OK);
noSound = true;
alcCloseDevice(device);
return;
}
} else {
handleerror(0,"Could not create audio device","OpenAL error",MBF_OK);
noSound = true;
return;
}
}
// Generate sound sources
Sources = new ALuint[maxSounds];
for (int a=0;a<maxSounds;a++) Sources[a]=0;
// Set distance model (sound attenuation)
alDistanceModel (AL_INVERSE_DISTANCE);
posScale.x = 0.02f;
posScale.y = 0.02f;
posScale.z = 0.0005f;
}
void
sound_init ()
{
if (have_al)
return;
if ((dev = alcOpenDevice (NULL)) == NULL)
return;
if ((context_id = alcCreateContext (dev, NULL)) == NULL)
{
alcCloseDevice (dev);
have_al = 0;
return;
}
alcMakeContextCurrent (context_id);
alGenSources (1, &source);
alGenBuffers (2, wave);
sound_load (wave[SOUND_BOINK], "/boink.wav");
sound_load (wave[SOUND_NNGNGNG], "/lose.wav");
alDistanceModel (AL_DISTANCE_MODEL);
alSourcef (source, AL_REFERENCE_DISTANCE, 22.0);
have_al = 1;
return;
}
GAudio::GAudio() : mDevice(NULL), mContext(NULL), mChannels(NULL)
{
// open the device
mDevice = alcOpenDevice(NULL);
if(mDevice==NULL) GAssert("GAudio: could not open the al device!.");
// create a context
ALCint caps[] =
{
ALC_FREQUENCY, 44100,
ALC_STEREO_SOURCES, 4,
0, 0
};
mContext = alcCreateContext(mDevice, caps);
if(mContext==NULL) GAssert("GAudio: could not create a al context.");
CHECK(alcMakeContextCurrent(mContext));
// initialize channels.
mChannels = GNEW(GAudioSource[MAX_AUDIO_CHANNELS]);
CHECK(mChannels);
for(U32 i = 0; i < MAX_AUDIO_CHANNELS; i++)
{
mFrees.push_back(&mChannels[i]);
}
// use our own distance model.
alDistanceModel(AL_NONE);
}
void cOAL_Device::SetDistanceModel(eOAL_DistanceModel aModel)
{
DEF_FUNC_NAME("OAL_SetDistanceModel");
FUNC_USES_AL;
ALenum distModel;
switch(aModel)
{
case eOAL_DistanceModel_Inverse:
distModel = AL_INVERSE_DISTANCE;
break;
case eOAL_DistanceModel_Inverse_Clamped:
distModel = AL_INVERSE_DISTANCE_CLAMPED;
break;
case eOAL_DistanceModel_Linear:
distModel = AL_LINEAR_DISTANCE;
break;
case eOAL_DistanceModel_Linear_Clamped:
distModel = AL_LINEAR_DISTANCE_CLAMPED;
break;
case eOAL_DistanceModel_Exponent:
distModel = AL_EXPONENT_DISTANCE;
break;
case eOAL_DistanceModel_Exponent_Clamped:
distModel = AL_EXPONENT_DISTANCE_CLAMPED;
break;
case eOAL_DistanceModel_None:
distModel = AL_NONE;
default:
break;
}
RUN_AL_FUNC(alDistanceModel(distModel));
}
// Thread: Any. Must be locked: AudioMutex.
bool CreatePlaybackDevice() {
if (AudioDevice) return true;
AudioDevice = alcOpenDevice(nullptr);
if (!AudioDevice) {
LOG(("Audio Error: Could not create default playback device, enumerating.."));
EnumeratePlaybackDevices();
return false;
}
ALCint attributes[] = {
ALC_STEREO_SOURCES, 128,
ALC_FREQUENCY, Media::Player::kDefaultFrequency,
0
};
AudioContext = alcCreateContext(AudioDevice, attributes);
alcMakeContextCurrent(AudioContext);
if (ContextErrorHappened()) {
DestroyPlaybackDevice();
return false;
}
ALfloat v[] = { 0.f, 0.f, -1.f, 0.f, 1.f, 0.f };
alListener3f(AL_POSITION, 0.f, 0.f, 0.f);
alListener3f(AL_VELOCITY, 0.f, 0.f, 0.f);
alListenerfv(AL_ORIENTATION, v);
alDistanceModel(AL_NONE);
return true;
}
int DS_Init(void)
{
// Already initialized?
if(initOk) return true;
// Open the default playback device.
device = alcOpenDevice(NULL);
if(!device)
{
Con_Message("OpenAL init failed (default playback device).");
return false;
}
// Create and make current a new context.
alcMakeContextCurrent(context = alcCreateContext(device, NULL));
DSOPENAL_ERRCHECK(alGetError());
// Attempt to load and configure the EAX extensions.
loadExtensions();
// Configure the listener and global OpenAL properties/state.
alListenerf(AL_GAIN, 1);
alDistanceModel(AL_INVERSE_DISTANCE_CLAMPED);
headYaw = headPitch = 0;
unitsPerMeter = 36;
// Everything is OK.
DSOPENAL_TRACE("DS_Init: OpenAL initialized%s." << (hasEAX? " (EAX 2.0 available)" : ""));
initOk = true;
return true;
}
AudioWorld::AudioWorld(Engine::BaseEngine& engine, AudioEngine& audio_engine, const VDFS::FileIndex& vdfidx)
: m_Engine(engine)
, m_VDFSIndex(vdfidx)
, m_exiting(false)
{
#ifdef RE_USE_SOUND
if (!audio_engine.getDevice())
return;
m_Context = alcCreateContext(audio_engine.getDevice(), nullptr);
if (!m_Context)
{
LogWarn() << "Could not create OpenAL context: "
<< AudioEngine::getErrorString(alcGetError(audio_engine.getDevice()));
return;
}
alcMakeContextCurrent(m_Context);
alListener3f(AL_POSITION, 0, 0, 0.0f);
// check for errors
alListener3f(AL_VELOCITY, 0, 0, 0);
// check for errors
ALfloat listenerOri[] = {0.0f, 0.0f, 1.0f, 0.0f, 1.0f, 0.0f};
alListenerfv(AL_ORIENTATION, listenerOri);
// Need this for AL_MAX_DISTANCE to work
alDistanceModel(AL_LINEAR_DISTANCE_CLAMPED);
createSounds();
initializeMusic();
#endif
}
OpenALSoundManager(OnDemandSoundFetcher *fetcher):
m_fetcher(fetcher),
m_device(NULL),
m_context(NULL),
m_can_vorbis(false),
m_next_id(1),
m_is_initialized(false)
{
ALCenum error = ALC_NO_ERROR;
infostream<<"Audio: Initializing..."<<std::endl;
m_device = alcOpenDevice(NULL);
if(!m_device){
infostream<<"Audio: No audio device available, audio system "
<<"not initialized"<<std::endl;
return;
}
if(alcIsExtensionPresent(m_device, "EXT_vorbis")){
infostream<<"Audio: Vorbis extension present"<<std::endl;
m_can_vorbis = true;
} else{
infostream<<"Audio: Vorbis extension NOT present"<<std::endl;
m_can_vorbis = false;
}
m_context = alcCreateContext(m_device, NULL);
if(!m_context){
error = alcGetError(m_device);
infostream<<"Audio: Unable to initialize audio context, "
<<"aborting audio initialization ("<<alcErrorString(error)
<<")"<<std::endl;
alcCloseDevice(m_device);
m_device = NULL;
return;
}
if(!alcMakeContextCurrent(m_context) ||
(error = alcGetError(m_device) != ALC_NO_ERROR))
{
infostream<<"Audio: Error setting audio context, aborting audio "
<<"initialization ("<<alcErrorString(error)<<")"<<std::endl;
alcDestroyContext(m_context);
m_context = NULL;
alcCloseDevice(m_device);
m_device = NULL;
return;
}
alDistanceModel(AL_EXPONENT_DISTANCE);
infostream<<"Audio: Initialized: OpenAL "<<alGetString(AL_VERSION)
<<", using "<<alcGetString(m_device, ALC_DEVICE_SPECIFIER)
<<std::endl;
m_is_initialized = true;
}
void OpenALDevice::setDistanceModel(DistanceModel model)
{
std::lock_guard<std::recursive_mutex> lock(m_mutex);
switch(model)
{
case DISTANCE_MODEL_INVERSE:
alDistanceModel(AL_INVERSE_DISTANCE);
break;
case DISTANCE_MODEL_INVERSE_CLAMPED:
alDistanceModel(AL_INVERSE_DISTANCE_CLAMPED);
break;
case DISTANCE_MODEL_LINEAR:
alDistanceModel(AL_LINEAR_DISTANCE);
break;
case DISTANCE_MODEL_LINEAR_CLAMPED:
alDistanceModel(AL_LINEAR_DISTANCE_CLAMPED);
break;
case DISTANCE_MODEL_EXPONENT:
alDistanceModel(AL_EXPONENT_DISTANCE);
break;
case DISTANCE_MODEL_EXPONENT_CLAMPED:
alDistanceModel(AL_EXPONENT_DISTANCE_CLAMPED);
break;
default:
alDistanceModel(AL_NONE);
}
}
void AUD_OpenALDevice::setDistanceModel(AUD_DistanceModel model)
{
switch(model)
{
case AUD_DISTANCE_MODEL_INVERSE:
alDistanceModel(AL_INVERSE_DISTANCE);
break;
case AUD_DISTANCE_MODEL_INVERSE_CLAMPED:
alDistanceModel(AL_INVERSE_DISTANCE_CLAMPED);
break;
case AUD_DISTANCE_MODEL_LINEAR:
alDistanceModel(AL_LINEAR_DISTANCE);
break;
case AUD_DISTANCE_MODEL_LINEAR_CLAMPED:
alDistanceModel(AL_LINEAR_DISTANCE_CLAMPED);
break;
case AUD_DISTANCE_MODEL_EXPONENT:
alDistanceModel(AL_EXPONENT_DISTANCE);
break;
case AUD_DISTANCE_MODEL_EXPONENT_CLAMPED:
alDistanceModel(AL_EXPONENT_DISTANCE_CLAMPED);
break;
default:
alDistanceModel(AL_NONE);
}
}
Audio::Audio(){
dev = alcOpenDevice(NULL);
ctx = alcCreateContext(dev, NULL);
alcMakeContextCurrent(ctx);
// alDistanceModel(AL_INVERSE_DISTANCE);
alDistanceModel(AL_INVERSE_DISTANCE_CLAMPED);
//alListenerf(AL_GAIN, 0.0f);
}
optional<string> AudioDevice::initialize() {
if ((device = alcOpenDevice(nullptr))) {
if ((context = alcCreateContext((ALCdevice*)device, nullptr))) {
alcMakeContextCurrent((ALCcontext*)context);
alDistanceModel(AL_NONE);
initialized = true;
return none;
}
}
return "Error code: " + toString(alGetError());
}
void CSoundManager::InitListener()
{
ALfloat listenerPos[] = {0.0, 0.0, 0.0};
ALfloat listenerVel[] = {0.0, 0.0, 0.0};
ALfloat listenerOri[] = {0.0, 0.0, -1.0, 0.0, 1.0, 0.0};
alListenerfv(AL_POSITION, listenerPos);
alListenerfv(AL_VELOCITY, listenerVel);
alListenerfv(AL_ORIENTATION, listenerOri);
alDistanceModel(AL_LINEAR_DISTANCE);
}
void CSound::StartThread(int maxSounds)
{
#if BOOST_VERSION >= 103500
try
{
#endif
{
boost::mutex::scoped_lock lck(soundMutex);
// Generate sound sources
for (int i = 0; i < maxSounds; i++)
{
SoundSource* thenewone = new SoundSource();
if (thenewone->IsValid())
{
sources.push_back(thenewone);
}
else
{
maxSounds = std::max(i-1,0);
LogObject(LOG_SOUND) << "Your hardware/driver can not handle more than " << maxSounds << " soundsources";
delete thenewone;
break;
}
}
// Set distance model (sound attenuation)
alDistanceModel(AL_INVERSE_DISTANCE_CLAMPED);
//alDopplerFactor(1.0);
alListenerf(AL_GAIN, masterVolume);
}
configHandler->Set("MaxSounds", maxSounds);
soundThreadRunning = true;
while (soundThreadRunning) {
#if BOOST_VERSION >= 103500
boost::this_thread::sleep(boost::posix_time::millisec(50)); // sleep
#else
SDL_Delay(50);
#endif
boost::mutex::scoped_lock lck(soundMutex); // lock
Update(); // call update
}
#if BOOST_VERSION >= 103500
}
catch(boost::thread_interrupted const&)
{
// do cleanup here
}
#endif
}
Handle<Value> ALDistanceModelCallback(const Arguments& args) {
//if less that nbr of formal parameters then do nothing
if (args.Length() < 1)
return v8::Undefined();
//get arguments
int arg0 = args[0]->IntegerValue();
//make call
alDistanceModel((ALenum)arg0);
return v8::Undefined();
}
// Thread: Any. Must be locked: AudioMutex.
bool CreatePlaybackDevice() {
if (AudioDevice) return true;
AudioDevice = alcOpenDevice(nullptr);
if (!AudioDevice) {
LOG(("Audio Error: Could not create default playback device, enumerating.."));
EnumeratePlaybackDevices();
return false;
}
ALCint attributes[] = {
ALC_STEREO_SOURCES, 128,
ALC_FREQUENCY, Media::Player::kDefaultFrequency,
0
};
AudioContext = alcCreateContext(AudioDevice, attributes);
alcMakeContextCurrent(AudioContext);
if (ContextErrorHappened()) {
DestroyPlaybackDevice();
return false;
}
ALfloat v[] = { 0.f, 0.f, -1.f, 0.f, 1.f, 0.f };
alListener3f(AL_POSITION, 0.f, 0.f, 0.f);
alListener3f(AL_VELOCITY, 0.f, 0.f, 0.f);
alListenerfv(AL_ORIENTATION, v);
#ifndef TDESKTOP_DISABLE_OPENAL_EFFECTS
// playback speed related init
// generate an effect slot and an effect
alGenAuxiliaryEffectSlots(1, &_playbackSpeedData.uiEffectSlot);
alGenEffects(1, &_playbackSpeedData.uiEffect);
// initialize the pitch shifter effect
alEffecti(_playbackSpeedData.uiEffect, AL_EFFECT_TYPE, AL_EFFECT_PITCH_SHIFTER);
// 12 semitones = 1 octave
alEffecti(_playbackSpeedData.uiEffect, AL_PITCH_SHIFTER_COARSE_TUNE, kPlaybackSpeedTune);
// connect the effect with the effect slot
alAuxiliaryEffectSloti(_playbackSpeedData.uiEffectSlot, AL_EFFECTSLOT_EFFECT, _playbackSpeedData.uiEffect);
// initialize a filter to disable the direct (dry) path
alGenFilters(1, &_playbackSpeedData.uiFilter);
alFilteri(_playbackSpeedData.uiFilter, AL_FILTER_TYPE, AL_FILTER_LOWPASS);
// disable all frequencies
alFilterf(_playbackSpeedData.uiFilter, AL_LOWPASS_GAIN, 0.f);
// to use the modified playback speed:
// connect both the effect slot and filter with the stream source and set AL_PITCH
#endif // TDESKTOP_DISABLE_OPENAL_EFFECTS
alDistanceModel(AL_NONE);
return true;
}
/* The open method starts up the driver and should lock the device, using the
previously set paramters, or defaults. It shouldn't need to start sending
audio data to the device yet, however. */
static int _openal_open(void)
{
ALenum openal_err;
ALCenum alc_err;
ALLEGRO_INFO("Starting OpenAL\n");
/* clear the error state */
openal_err = alGetError();
/* pick default device. always a good choice */
openal_dev = alcOpenDevice(NULL);
alc_err = ALC_NO_ERROR;
if (!openal_dev || (alc_err = alcGetError(openal_dev)) != ALC_NO_ERROR) {
ALLEGRO_ERROR("Could not open audio device: %s\n",
alc_get_err_str(alc_err));
return 1;
}
openal_context = alcCreateContext(openal_dev, NULL);
alc_err = ALC_NO_ERROR;
if (!openal_context || (alc_err = alcGetError(openal_dev)) != ALC_NO_ERROR) {
ALLEGRO_ERROR("Could not create current device context: %s\n",
alc_get_err_str(alc_err));
return 1;
}
alcMakeContextCurrent(openal_context);
#if !defined ALLEGRO_IPHONE
if ((alc_err = alcGetError(openal_dev)) != ALC_NO_ERROR) {
ALLEGRO_ERROR("Could not make context current: %s\n",
alc_get_err_str(alc_err));
return 1;
}
alDistanceModel(AL_NONE);
if ((openal_err = alGetError()) != AL_NO_ERROR) {
ALLEGRO_ERROR("Could not set distance model: %s\n",
openal_get_err_str(openal_err));
return 1;
}
#endif
ALLEGRO_DEBUG("Vendor: %s\n", alGetString(AL_VENDOR));
ALLEGRO_DEBUG("Version: %s\n", alGetString(AL_VERSION));
ALLEGRO_DEBUG("Renderer: %s\n", alGetString(AL_RENDERER));
ALLEGRO_DEBUG("Extensions: %s\n", alGetString(AL_EXTENSIONS));
return 0;
}
void ConfigurarEntorno ( ALsizei identificador, ALenum modelo,
ALfloat doppler_factor, ALfloat doppler_vel,
ALint room, ALint room_high_frequency,
ALfloat rolloff_factor, ALfloat decay_time,
ALfloat decay_high_frequency_ratio, ALint reflections,
ALfloat reflections_delay, ALint reverb,
ALfloat reverb_delay, ALfloat diffusion,
ALfloat density, ALfloat high_frequency_reference ){
/* Configuramos la atenuacion y el efecto doppler */
alEnable ( AL_DISTANCE_MODEL );
alDistanceModel ( modelo );
alDopplerFactor ( doppler_factor );
alDopplerVelocity ( doppler_vel ); /* Recordad que en metros la velocidad del sonido es 343 */
#ifdef _LINUX
/* Generamos el entorno y comprobamos errores */
alGenEnvironmentIASIG ( identificador, &entornos[identificador] );
if ( !alIsEnvironmentIASIG ( entornos[identificador] )){
fprintf ( logs, "No se puede configurar parte del entorno\n");
}
/* Configuramos las propiedades del entorno */
alEnvironmentiIASIG ( entornos[identificador], AL_ENV_ROOM_IASIG, room );
alEnvironmentiIASIG ( entornos[identificador], AL_ENV_ROOM_HIGH_FREQUENCY_IASIG,
room_high_frequency);
alEnvironmentfIASIG ( entornos[identificador], AL_ENV_ROOM_ROLLOFF_FACTOR_IASIG, rolloff_factor );
alEnvironmentfIASIG ( entornos[identificador], AL_ENV_DECAY_TIME_IASIG, decay_time );
alEnvironmentfIASIG ( entornos[identificador], AL_ENV_DECAY_HIGH_FREQUENCY_RATIO_IASIG,
decay_high_frequency_ratio );
alEnvironmentiIASIG ( entornos[identificador], AL_ENV_REFLECTIONS_IASIG, reflections );
alEnvironmentfIASIG ( entornos[identificador], AL_ENV_REFLECTIONS_DELAY_IASIG, reflections_delay );
alEnvironmentiIASIG ( entornos[identificador], AL_ENV_REVERB_IASIG, reverb );
alEnvironmentfIASIG ( entornos[identificador], AL_ENV_REVERB_DELAY_IASIG, reverb_delay );
alEnvironmentfIASIG ( entornos[identificador], AL_ENV_DIFFUSION_IASIG, diffusion );
alEnvironmentfIASIG ( entornos[identificador], AL_ENV_DENSITY_IASIG, density );
alEnvironmentfIASIG ( entornos[identificador], AL_ENV_HIGH_FREQUENCY_REFERENCE_IASIG,
high_frequency_reference );
#endif
#ifdef _WIN32
/* Para windows se pueden crear y configurar entornos utilizando las extensiones EAX
que admiten algunas tarjetas Soundblaster. Pero como no sé si es gratuito la utilizacion
de dichas extensiones, de momento para windows no se generaran entornos
*/
#endif
}
void Contexte::setDistanceModel(ALenum modele)
{
alGetError();
alDistanceModel(modele);
ALenum error = alCheckError();
if (error == AL_INVALID_VALUE)
{
std::cerr << "The specified distance model is not valid." << std::endl;
} else if (error == AL_INVALID_OPERATION) {
std::cerr << "There is no current context." << std::endl;
}
}
static int
_context_setdistancemodel (PyObject* self, PyObject *value, void *closure)
{
int model;
ASSERT_CONTEXT_IS_CURRENT (self, -1);
if (!IntFromObj (value, &model))
return -1;
CLEAR_ALERROR_STATE ();
alDistanceModel ((ALenum)model);
if (SetALErrorException (alGetError (), 0))
return -1;
return 0;
}
OALAudioEngine::OALAudioEngine()
{
ALCdevice* device = alcOpenDevice(nullptr);
ALCcontext* context = alcCreateContext(device, 0);
alcMakeContextCurrent(context);
this->SetListenerPos(float3(0, 0, 0));
this->SetListenerVel(float3(0, 0, 0));
this->SetListenerOri(float3(0, 0, 1), float3(0, 1, 0));
alDistanceModel(AL_INVERSE_DISTANCE);
alDopplerFactor(1);
alDopplerVelocity(343); // m/s
}
Engine::Audio::AudioRenderer::AudioRenderer(void)
{
_device = alcOpenDevice(NULL);
if (!_device)
{
throw std::exception("Error init OpenAL device");
}
_context = alcCreateContext(_device, NULL);
if (!alcMakeContextCurrent(_context))
{
throw std::exception("Error init OpenAL context");
}
alDistanceModel(AL_LINEAR_DISTANCE_CLAMPED);
}
void init()
{
s_al_device = alcOpenDevice(NULL);
CE_ASSERT(s_al_device, "Cannot open OpenAL audio device");
s_al_context = alcCreateContext(s_al_device, NULL);
CE_ASSERT(s_al_context, "Cannot create OpenAL context");
AL_CHECK(alcMakeContextCurrent(s_al_context));
CE_LOGD("OpenAL Vendor : %s", alGetString(AL_VENDOR));
CE_LOGD("OpenAL Version : %s", alGetString(AL_VERSION));
CE_LOGD("OpenAL Renderer : %s", alGetString(AL_RENDERER));
AL_CHECK(alDistanceModel(AL_INVERSE_DISTANCE_CLAMPED));
AL_CHECK(alDopplerFactor(1.0f));
AL_CHECK(alDopplerVelocity(343.0f));
}
static int Initialize(void *hnd)
{
ALCdevice *dev;
ALCcontext *ctxt;
ALCint attrs[3];
// TODO: Check for failures (generally, not just in this file).
dev = alcOpenDevice(NULL);
attrs[0] = ALC_FREQUENCY;
attrs[1] = RLX.Audio.SR_to_Khz[RLX.Audio.SamplingRate];
attrs[2] = 0;
ctxt = alcCreateContext(dev, (ALCint *)&attrs);
alcMakeContextCurrent(ctxt);
alDistanceModel(AL_INVERSE_DISTANCE);
alDopplerFactor(0.f); // No doppler
alDopplerVelocity(0.f); // No velocity
RLX.Audio.Config|=RLXAUDIO_Use3D;
return 0;
}
COpenALSound::COpenALSound()
{
Sources = NULL;
maxSounds = configHandler.GetInt("MaxSounds", 16);
if (maxSounds <= 0) {
throw content_error("Internal error, (maxSounds <= 0) in COpenALSound");
}
globalVolume = 1.0f;
cur = 0;
ALCdevice *device = alcOpenDevice(NULL);
if (device == NULL) {
throw content_error("Could not create OpenAL audio device");
} else {
ALCcontext *context = alcCreateContext(device, NULL);
if (context != NULL) {
alcMakeContextCurrent(context);
} else {
alcCloseDevice(device);
throw content_error("Could not create OpenAL audio context");
}
}
logOutput.Print("OpenAL: %s\n", (const char*)alGetString(AL_VERSION));
logOutput.Print("OpenAL: %s", (const char*)alGetString(AL_EXTENSIONS));
// Generate sound sources
Sources = SAFE_NEW ALuint[maxSounds];
for (int a=0;a<maxSounds;a++) {
Sources[a]=0;
}
// Set distance model (sound attenuation)
alDistanceModel (AL_INVERSE_DISTANCE);
posScale.x = 0.02f;
posScale.y = 0.0005f;
posScale.z = 0.02f;
}
void SetupAndPlayAudio() {
g_MyState.source_pos[0] = 1.0f;
g_MyState.source_pos[1] = 1.0f;
g_MyState.source_pos[2] = 1.0f;
g_MyState.source_vel[0] = 0.0f;
g_MyState.source_vel[1] = 0.0f;
g_MyState.source_vel[2] = 0.0f;
g_MyState.listener_pos[0] = 0.0f;
g_MyState.listener_pos[1] = 0.0f;
g_MyState.listener_pos[2] = 0.0f;
g_MyState.listener_vel[0] = 0.0f;
g_MyState.listener_vel[1] = 0.0f;
g_MyState.listener_vel[2] = 0.0f;
g_MyState.pitch = 1.0f;
g_MyState.gain = 1.0f;
alDistanceModel(AL_LINEAR_DISTANCE_CLAMPED);
assert(alGetError() == AL_NO_ERROR);
alSourcei(g_MyState.source, AL_LOOPING, AL_TRUE);
assert(alGetError() == AL_NO_ERROR);
alSourcefv(g_MyState.source, AL_POSITION, g_MyState.source_pos);
assert(alGetError() == AL_NO_ERROR);
alSourcef(g_MyState.source, AL_REFERENCE_DISTANCE, 1.0f);
assert(alGetError() == AL_NO_ERROR);
alSourcef(g_MyState.source, AL_MAX_DISTANCE, 70.0f);
assert(alGetError() == AL_NO_ERROR);
alSourcef(g_MyState.source, AL_GAIN, 1.0f);
assert(alGetError() == AL_NO_ERROR);
alSourcei(g_MyState.source, AL_BUFFER, g_MyState.buffer);
assert(alGetError() == AL_NO_ERROR);
alSourcef(g_MyState.source, AL_PITCH, g_MyState.pitch);
assert(alGetError() == AL_NO_ERROR);
alSourcef(g_MyState.source, AL_GAIN, g_MyState.gain);
assert(alGetError() == AL_NO_ERROR);
alSourcePlay(g_MyState.source);
assert(alGetError() == AL_NO_ERROR);
}
void sound_init() {
ALCdevice* pDevice;
ALCcontext* pContext;
// Get handle to device.
pDevice = alcOpenDevice(NULL);
// Create audio context.
pContext = alcCreateContext(pDevice, NULL);
// Set active context.
alcMakeContextCurrent(pContext);
// Check for an error.
if (alcGetError(pDevice) != ALC_NO_ERROR)
fprintf(stderr, "Warning: cannot initialize sound environment.");
alDistanceModel(AL_LINEAR_DISTANCE);
}
void Init(int frequency, int resolution, int sources)
{
(void)resolution;
--sources; // one spare source for music
ALCint attribs[] = {
ALC_FREQUENCY, frequency,
/*ALC_MONO_SOURCES, sources,
ALC_STEREO_SOURCES, 1,*/
0
};
alureInitDevice(NULL, attribs);
soundSources = new ALuint[sources];
alGenSources(sources, soundSources);
alGenSources(1, &musicSource);
//alGenBuffers(2, musicBufs);
soundSourceCount = sources;
alDistanceModel(AL_INVERSE_DISTANCE_CLAMPED);
alSpeedOfSound(1400.0);
alDopplerFactor(0.7);
alureUpdateInterval(0.03333f);
}
