#ifndef AL_MAIN_H #define AL_MAIN_H #include #include #ifdef HAVE_FENV_H #include #endif #include "AL/al.h" #include "AL/alc.h" #include "AL/alext.h" #ifdef _WIN32 #ifndef _WIN32_WINNT #define _WIN32_WINNT 0x0500 #endif #include #else #include #include #ifdef HAVE_PTHREAD_NP_H #include #endif #include #include #include #define IsBadWritePtr(a,b) (0) typedef pthread_mutex_t CRITICAL_SECTION; static inline void EnterCriticalSection(CRITICAL_SECTION *cs) { int ret; ret = pthread_mutex_lock(cs); assert(ret == 0); } static inline void LeaveCriticalSection(CRITICAL_SECTION *cs) { int ret; ret = pthread_mutex_unlock(cs); assert(ret == 0); } static inline void InitializeCriticalSection(CRITICAL_SECTION *cs) { pthread_mutexattr_t attrib; int ret; ret = pthread_mutexattr_init(&attrib); assert(ret == 0); ret = pthread_mutexattr_settype(&attrib, PTHREAD_MUTEX_RECURSIVE); #ifdef HAVE_PTHREAD_NP_H if(ret != 0) ret = pthread_mutexattr_setkind_np(&attrib, PTHREAD_MUTEX_RECURSIVE); #endif assert(ret == 0); ret = pthread_mutex_init(cs, &attrib); assert(ret == 0); pthread_mutexattr_destroy(&attrib); } static inline void DeleteCriticalSection(CRITICAL_SECTION *cs) { int ret; ret = pthread_mutex_destroy(cs); assert(ret == 0); } /* NOTE: This wrapper isn't quite accurate as it returns an ALuint, as opposed * to the expected DWORD. Both are defined as unsigned 32-bit types, however. * Additionally, Win32 is supposed to measure the time since Windows started, * as opposed to the actual time. */ static inline ALuint timeGetTime(void) { struct timeval tv; int ret; ret = gettimeofday(&tv, NULL); assert(ret == 0); return tv.tv_usec/1000 + tv.tv_sec*1000; } static inline void Sleep(ALuint t) { struct timespec tv, rem; tv.tv_nsec = (t*1000000)%1000000000; tv.tv_sec = t/1000; while(nanosleep(&tv, &rem) == -1 && errno == EINTR) tv = rem; } #define min(x,y) (((x)<(y))?(x):(y)) #define max(x,y) (((x)>(y))?(x):(y)) #endif #include "alListener.h" #include "alu.h" #ifdef __cplusplus extern "C" { #endif extern char _alDebug[256]; #define AL_PRINT(...) do { \ int _al_print_i; \ const char *_al_print_fn = strrchr(__FILE__, '/'); \ if(!_al_print_fn) _al_print_fn = __FILE__; \ else _al_print_fn += 1; \ _al_print_i = snprintf(_alDebug, sizeof(_alDebug), "AL lib: %s:%d: ", _al_print_fn, __LINE__); \ if(_al_print_i < (int)sizeof(_alDebug) && _al_print_i > 0) \ snprintf(_alDebug+_al_print_i, sizeof(_alDebug)-_al_print_i, __VA_ARGS__); \ _alDebug[sizeof(_alDebug)-1] = 0; \ fprintf(stderr, "%s", _alDebug); \ } while(0) #define SWMIXER_OUTPUT_RATE 44100 #define SPEEDOFSOUNDMETRESPERSEC (343.3f) #define AIRABSORBGAINDBHF (-0.05f) #define LOWPASSFREQCUTOFF (5000) #define QUADRANT_NUM 128 #define LUT_NUM (4 * QUADRANT_NUM) typedef struct { ALCboolean (*OpenPlayback)(ALCdevice*, const ALCchar*); void (*ClosePlayback)(ALCdevice*); ALCboolean (*OpenCapture)(ALCdevice*, const ALCchar*, ALCuint, ALCenum, ALCsizei); void (*CloseCapture)(ALCdevice*); void (*StartCapture)(ALCdevice*); void (*StopCapture)(ALCdevice*); void (*CaptureSamples)(ALCdevice*, void*, ALCuint); ALCuint (*AvailableSamples)(ALCdevice*); } BackendFuncs; void alc_alsa_init(BackendFuncs *func_list); void alc_oss_init(BackendFuncs *func_list); void alc_solaris_init(BackendFuncs *func_list); void alcDSoundInit(BackendFuncs *func_list); void alcWinMMInit(BackendFuncs *FuncList); void alc_pa_init(BackendFuncs *func_list); void alc_wave_init(BackendFuncs *func_list); void alc_pulse_init(BackendFuncs *func_list); struct ALCdevice_struct { ALboolean IsCaptureDevice; ALuint Frequency; ALuint UpdateSize; ALenum Format; ALCchar *szDeviceName; // Maximum number of sources that can be created ALuint MaxNoOfSources; // Context created on this device ALCcontext *Context; BackendFuncs *Funcs; void *ExtraData; // For the backend's use ALCdevice *next; }; #define ALCdevice_OpenPlayback(a,b) ((a)->Funcs->OpenPlayback((a), (b))) #define ALCdevice_ClosePlayback(a) ((a)->Funcs->ClosePlayback((a))) #define ALCdevice_OpenCapture(a,b,c,d,e) ((a)->Funcs->OpenCapture((a), (b), (c), (d), (e))) #define ALCdevice_CloseCapture(a) ((a)->Funcs->CloseCapture((a))) #define ALCdevice_StartCapture(a) ((a)->Funcs->StartCapture((a))) #define ALCdevice_StopCapture(a) ((a)->Funcs->StopCapture((a))) #define ALCdevice_CaptureSamples(a,b,c) ((a)->Funcs->CaptureSamples((a), (b), (c))) #define ALCdevice_AvailableSamples(a) ((a)->Funcs->AvailableSamples((a))) struct ALCcontext_struct { ALlistener Listener; struct ALsource *Source; ALuint SourceCount; struct ALeffectslot *AuxiliaryEffectSlot; ALuint AuxiliaryEffectSlotCount; // Maximum number of slots that can be created ALuint AuxiliaryEffectSlotMax; ALenum LastError; ALboolean InUse; ALuint Frequency; ALenum DistanceModel; ALfloat DopplerFactor; ALfloat DopplerVelocity; ALfloat flSpeedOfSound; ALint lNumMonoSources; ALint lNumStereoSources; ALuint NumSends; ALfloat PanningLUT[OUTPUTCHANNELS * LUT_NUM]; ALint NumChan; ALfloat ChannelMatrix[OUTPUTCHANNELS][OUTPUTCHANNELS]; ALCdevice *Device; const ALCchar *ExtensionList; struct bs2b *bs2b; ALCcontext *next; }; ALCvoid ReleaseALC(ALCvoid); ALCchar *AppendDeviceList(char *name); ALCchar *AppendAllDeviceList(char *name); ALCchar *AppendCaptureDeviceList(char *name); ALCvoid SetALCError(ALenum errorCode); ALCvoid SuspendContext(ALCcontext *context); ALCvoid ProcessContext(ALCcontext *context); ALvoid *StartThread(ALuint (*func)(ALvoid*), ALvoid *ptr); ALuint StopThread(ALvoid *thread); typedef struct RingBuffer RingBuffer; RingBuffer *CreateRingBuffer(ALsizei frame_size, ALsizei length); void DestroyRingBuffer(RingBuffer *ring); ALsizei RingBufferSize(RingBuffer *ring); void WriteRingBuffer(RingBuffer *ring, const ALubyte *data, ALsizei len); void ReadRingBuffer(RingBuffer *ring, ALubyte *data, ALsizei len); void ReadALConfig(void); void FreeALConfig(void); const char *GetConfigValue(const char *blockName, const char *keyName, const char *def); int GetConfigValueInt(const char *blockName, const char *keyName, int def); float GetConfigValueFloat(const char *blockName, const char *keyName, float def); #ifdef __cplusplus } #endif #endif