#ifndef AL_MAIN_H #define AL_MAIN_H #include #include #include #include #include #include #ifdef HAVE_STRINGS_H #include #endif #ifdef HAVE_FENV_H #include #endif #include "AL/al.h" #include "AL/alc.h" #include "AL/alext.h" #include "static_assert.h" #include "align.h" #include "atomic.h" #include "uintmap.h" #include "vector.h" #include "alstring.h" #include "almalloc.h" #include "threads.h" #ifndef ALC_SOFT_device_clock #define ALC_SOFT_device_clock 1 typedef int64_t ALCint64SOFT; typedef uint64_t ALCuint64SOFT; #define ALC_DEVICE_CLOCK_SOFT 0x1600 #define ALC_DEVICE_LATENCY_SOFT 0x1601 #define ALC_DEVICE_CLOCK_LATENCY_SOFT 0x1602 typedef void (ALC_APIENTRY*LPALCGETINTEGER64VSOFT)(ALCdevice *device, ALCenum pname, ALsizei size, ALCint64SOFT *values); #ifdef AL_ALEXT_PROTOTYPES ALC_API void ALC_APIENTRY alcGetInteger64vSOFT(ALCdevice *device, ALCenum pname, ALsizei size, ALCint64SOFT *values); #endif #endif #ifndef AL_SOFT_buffer_samples2 #define AL_SOFT_buffer_samples2 1 /* Channel configurations */ #define AL_MONO_SOFT 0x1500 #define AL_STEREO_SOFT 0x1501 #define AL_REAR_SOFT 0x1502 #define AL_QUAD_SOFT 0x1503 #define AL_5POINT1_SOFT 0x1504 #define AL_6POINT1_SOFT 0x1505 #define AL_7POINT1_SOFT 0x1506 #define AL_BFORMAT2D_SOFT 0x1507 #define AL_BFORMAT3D_SOFT 0x1508 /* Sample types */ #define AL_BYTE_SOFT 0x1400 #define AL_UNSIGNED_BYTE_SOFT 0x1401 #define AL_SHORT_SOFT 0x1402 #define AL_UNSIGNED_SHORT_SOFT 0x1403 #define AL_INT_SOFT 0x1404 #define AL_UNSIGNED_INT_SOFT 0x1405 #define AL_FLOAT_SOFT 0x1406 #define AL_DOUBLE_SOFT 0x1407 #define AL_BYTE3_SOFT 0x1408 #define AL_UNSIGNED_BYTE3_SOFT 0x1409 #define AL_MULAW_SOFT 0x140A /* Storage formats */ #define AL_MONO8_SOFT 0x1100 #define AL_MONO16_SOFT 0x1101 #define AL_MONO32F_SOFT 0x10010 #define AL_STEREO8_SOFT 0x1102 #define AL_STEREO16_SOFT 0x1103 #define AL_STEREO32F_SOFT 0x10011 #define AL_QUAD8_SOFT 0x1204 #define AL_QUAD16_SOFT 0x1205 #define AL_QUAD32F_SOFT 0x1206 #define AL_REAR8_SOFT 0x1207 #define AL_REAR16_SOFT 0x1208 #define AL_REAR32F_SOFT 0x1209 #define AL_5POINT1_8_SOFT 0x120A #define AL_5POINT1_16_SOFT 0x120B #define AL_5POINT1_32F_SOFT 0x120C #define AL_6POINT1_8_SOFT 0x120D #define AL_6POINT1_16_SOFT 0x120E #define AL_6POINT1_32F_SOFT 0x120F #define AL_7POINT1_8_SOFT 0x1210 #define AL_7POINT1_16_SOFT 0x1211 #define AL_7POINT1_32F_SOFT 0x1212 #define AL_BFORMAT2D_8_SOFT 0x20021 #define AL_BFORMAT2D_16_SOFT 0x20022 #define AL_BFORMAT2D_32F_SOFT 0x20023 #define AL_BFORMAT3D_8_SOFT 0x20031 #define AL_BFORMAT3D_16_SOFT 0x20032 #define AL_BFORMAT3D_32F_SOFT 0x20033 /* Buffer attributes */ #define AL_INTERNAL_FORMAT_SOFT 0x2008 #define AL_BYTE_LENGTH_SOFT 0x2009 #define AL_SAMPLE_LENGTH_SOFT 0x200A #define AL_SEC_LENGTH_SOFT 0x200B #if 0 typedef void (AL_APIENTRY*LPALBUFFERSAMPLESSOFT)(ALuint,ALuint,ALenum,ALsizei,ALenum,ALenum,const ALvoid*); typedef void (AL_APIENTRY*LPALGETBUFFERSAMPLESSOFT)(ALuint,ALsizei,ALsizei,ALenum,ALenum,ALvoid*); typedef ALboolean (AL_APIENTRY*LPALISBUFFERFORMATSUPPORTEDSOFT)(ALenum); #ifdef AL_ALEXT_PROTOTYPES AL_API void AL_APIENTRY alBufferSamplesSOFT(ALuint buffer, ALuint samplerate, ALenum internalformat, ALsizei samples, ALenum channels, ALenum type, const ALvoid *data); AL_API void AL_APIENTRY alGetBufferSamplesSOFT(ALuint buffer, ALsizei offset, ALsizei samples, ALenum channels, ALenum type, ALvoid *data); AL_API ALboolean AL_APIENTRY alIsBufferFormatSupportedSOFT(ALenum format); #endif #endif #endif #if defined(_WIN64) #define SZFMT "%I64u" #elif defined(_WIN32) #define SZFMT "%u" #else #define SZFMT "%zu" #endif #ifdef __GNUC__ /* Because of a long-standing deficiency in C, you're not allowed to implicitly * cast a pointer-to-type-array to a pointer-to-const-type-array. For example, * * int (*ptr)[10]; * const int (*cptr)[10] = ptr; * * is not allowed and most compilers will generate noisy warnings about * incompatible types, even though it just makes the array elements const. * Clang will allow it if you make the array type a typedef, like this: * * typedef int int10[10]; * int10 *ptr; * const int10 *cptr = ptr; * * however GCC does not and still issues the incompatible type warning. The * "proper" way to fix it is to add an explicit cast for the constified type, * but that removes the vast majority of otherwise useful type-checking you'd * get, and runs the risk of improper casts if types are later changed. Leaving * it non-const can also be an issue if you use it as a function parameter, and * happen to have a const type as input (and also reduce the capabilities of * the compiler to better optimize the function). * * So to work around the problem, we use a macro. The macro first assigns the * incoming variable to the specified non-const type to ensure it's the correct * type, then casts the variable as the desired constified type. Very ugly, but * I'd rather not have hundreds of lines of warnings because I want to tell the * compiler that some array(s) can't be changed by the code, or have lots of * error-prone casts. */ #define SAFE_CONST(T, var) __extension__({ \ T _tmp = (var); \ (const T)_tmp; \ }) #else /* Non-GNU-compatible compilers have to use a straight cast with no extra * checks, due to the lack of multi-statement expressions. */ #define SAFE_CONST(T, var) ((const T)(var)) #endif typedef ALint64SOFT ALint64; typedef ALuint64SOFT ALuint64; #ifndef U64 #if defined(_MSC_VER) #define U64(x) ((ALuint64)(x##ui64)) #elif SIZEOF_LONG == 8 #define U64(x) ((ALuint64)(x##ul)) #elif SIZEOF_LONG_LONG == 8 #define U64(x) ((ALuint64)(x##ull)) #endif #endif #ifndef UINT64_MAX #define UINT64_MAX U64(18446744073709551615) #endif #ifndef UNUSED #if defined(__cplusplus) #define UNUSED(x) #elif defined(__GNUC__) #define UNUSED(x) UNUSED_##x __attribute__((unused)) #elif defined(__LCLINT__) #define UNUSED(x) /*@unused@*/ x #else #define UNUSED(x) x #endif #endif #ifdef __GNUC__ #define DECL_FORMAT(x, y, z) __attribute__((format(x, (y), (z)))) #else #define DECL_FORMAT(x, y, z) #endif #if defined(__GNUC__) && defined(__i386__) /* force_align_arg_pointer is required for proper function arguments aligning * when SSE code is used. Some systems (Windows, QNX) do not guarantee our * thread functions will be properly aligned on the stack, even though GCC may * generate code with the assumption that it is. */ #define FORCE_ALIGN __attribute__((force_align_arg_pointer)) #else #define FORCE_ALIGN #endif #ifdef HAVE_C99_VLA #define DECL_VLA(T, _name, _size) T _name[(_size)] #else #define DECL_VLA(T, _name, _size) T *_name = alloca((_size) * sizeof(T)) #endif #ifndef PATH_MAX #ifdef MAX_PATH #define PATH_MAX MAX_PATH #else #define PATH_MAX 4096 #endif #endif static const union { ALuint u; ALubyte b[sizeof(ALuint)]; } EndianTest = { 1 }; #define IS_LITTLE_ENDIAN (EndianTest.b[0] == 1) #define COUNTOF(x) (sizeof((x))/sizeof((x)[0])) #define DERIVE_FROM_TYPE(t) t t##_parent #define STATIC_CAST(to, obj) (&(obj)->to##_parent) #ifdef __GNUC__ #define STATIC_UPCAST(to, from, obj) __extension__({ \ static_assert(__builtin_types_compatible_p(from, __typeof(*(obj))), \ "Invalid upcast object from type"); \ (to*)((char*)(obj) - offsetof(to, from##_parent)); \ }) #else #define STATIC_UPCAST(to, from, obj) ((to*)((char*)(obj) - offsetof(to, from##_parent))) #endif #define DECLARE_FORWARD(T1, T2, rettype, func) \ rettype T1##_##func(T1 *obj) \ { return T2##_##func(STATIC_CAST(T2, obj)); } #define DECLARE_FORWARD1(T1, T2, rettype, func, argtype1) \ rettype T1##_##func(T1 *obj, argtype1 a) \ { return T2##_##func(STATIC_CAST(T2, obj), a); } #define DECLARE_FORWARD2(T1, T2, rettype, func, argtype1, argtype2) \ rettype T1##_##func(T1 *obj, argtype1 a, argtype2 b) \ { return T2##_##func(STATIC_CAST(T2, obj), a, b); } #define DECLARE_FORWARD3(T1, T2, rettype, func, argtype1, argtype2, argtype3) \ rettype T1##_##func(T1 *obj, argtype1 a, argtype2 b, argtype3 c) \ { return T2##_##func(STATIC_CAST(T2, obj), a, b, c); } #define GET_VTABLE1(T1) (&(T1##_vtable)) #define GET_VTABLE2(T1, T2) (&(T1##_##T2##_vtable)) #define SET_VTABLE1(T1, obj) ((obj)->vtbl = GET_VTABLE1(T1)) #define SET_VTABLE2(T1, T2, obj) (STATIC_CAST(T2, obj)->vtbl = GET_VTABLE2(T1, T2)) #define DECLARE_THUNK(T1, T2, rettype, func) \ static rettype T1##_##T2##_##func(T2 *obj) \ { return T1##_##func(STATIC_UPCAST(T1, T2, obj)); } #define DECLARE_THUNK1(T1, T2, rettype, func, argtype1) \ static rettype T1##_##T2##_##func(T2 *obj, argtype1 a) \ { return T1##_##func(STATIC_UPCAST(T1, T2, obj), a); } #define DECLARE_THUNK2(T1, T2, rettype, func, argtype1, argtype2) \ static rettype T1##_##T2##_##func(T2 *obj, argtype1 a, argtype2 b) \ { return T1##_##func(STATIC_UPCAST(T1, T2, obj), a, b); } #define DECLARE_THUNK3(T1, T2, rettype, func, argtype1, argtype2, argtype3) \ static rettype T1##_##T2##_##func(T2 *obj, argtype1 a, argtype2 b, argtype3 c) \ { return T1##_##func(STATIC_UPCAST(T1, T2, obj), a, b, c); } #define DECLARE_THUNK4(T1, T2, rettype, func, argtype1, argtype2, argtype3, argtype4) \ static rettype T1##_##T2##_##func(T2 *obj, argtype1 a, argtype2 b, argtype3 c, argtype4 d) \ { return T1##_##func(STATIC_UPCAST(T1, T2, obj), a, b, c, d); } #define DECLARE_DEFAULT_ALLOCATORS(T) \ static void* T##_New(size_t size) { return al_malloc(16, size); } \ static void T##_Delete(void *ptr) { al_free(ptr); } /* Helper to extract an argument list for VCALL. Not used directly. */ #define EXTRACT_VCALL_ARGS(...) __VA_ARGS__)) /* Call a "virtual" method on an object, with arguments. */ #define V(obj, func) ((obj)->vtbl->func((obj), EXTRACT_VCALL_ARGS /* Call a "virtual" method on an object, with no arguments. */ #define V0(obj, func) ((obj)->vtbl->func((obj) EXTRACT_VCALL_ARGS #define DELETE_OBJ(obj) do { \ if((obj) != NULL) \ { \ V0((obj),Destruct)(); \ V0((obj),Delete)(); \ } \ } while(0) #define EXTRACT_NEW_ARGS(...) __VA_ARGS__); \ } \ } while(0) #define NEW_OBJ(_res, T) do { \ _res = T##_New(sizeof(T)); \ if(_res) \ { \ memset(_res, 0, sizeof(T)); \ T##_Construct(_res, EXTRACT_NEW_ARGS #define NEW_OBJ0(_res, T) do { \ _res = T##_New(sizeof(T)); \ if(_res) \ { \ memset(_res, 0, sizeof(T)); \ T##_Construct(_res EXTRACT_NEW_ARGS #ifdef __cplusplus extern "C" { #endif struct Hrtf; #define DEFAULT_OUTPUT_RATE (44100) #define MIN_OUTPUT_RATE (8000) /* Find the next power-of-2 for non-power-of-2 numbers. */ inline ALuint NextPowerOf2(ALuint value) { if(value > 0) { value--; value |= value>>1; value |= value>>2; value |= value>>4; value |= value>>8; value |= value>>16; } return value+1; } /* Fast float-to-int conversion. Assumes the FPU is already in round-to-zero * mode. */ inline ALint fastf2i(ALfloat f) { #ifdef HAVE_LRINTF return lrintf(f); #elif defined(_MSC_VER) && defined(_M_IX86) ALint i; __asm fld f __asm fistp i return i; #else return (ALint)f; #endif } /* Fast float-to-uint conversion. Assumes the FPU is already in round-to-zero * mode. */ inline ALuint fastf2u(ALfloat f) { return fastf2i(f); } enum DevProbe { ALL_DEVICE_PROBE, CAPTURE_DEVICE_PROBE }; typedef struct { ALCenum (*OpenPlayback)(ALCdevice*, const ALCchar*); void (*ClosePlayback)(ALCdevice*); ALCboolean (*ResetPlayback)(ALCdevice*); ALCboolean (*StartPlayback)(ALCdevice*); void (*StopPlayback)(ALCdevice*); ALCenum (*OpenCapture)(ALCdevice*, const ALCchar*); void (*CloseCapture)(ALCdevice*); void (*StartCapture)(ALCdevice*); void (*StopCapture)(ALCdevice*); ALCenum (*CaptureSamples)(ALCdevice*, void*, ALCuint); ALCuint (*AvailableSamples)(ALCdevice*); } BackendFuncs; ALCboolean alc_ca_init(BackendFuncs *func_list); void alc_ca_deinit(void); void alc_ca_probe(enum DevProbe type); ALCboolean alc_opensl_init(BackendFuncs *func_list); void alc_opensl_deinit(void); void alc_opensl_probe(enum DevProbe type); ALCboolean alc_qsa_init(BackendFuncs *func_list); void alc_qsa_deinit(void); void alc_qsa_probe(enum DevProbe type); struct ALCbackend; enum DistanceModel { InverseDistanceClamped = AL_INVERSE_DISTANCE_CLAMPED, LinearDistanceClamped = AL_LINEAR_DISTANCE_CLAMPED, ExponentDistanceClamped = AL_EXPONENT_DISTANCE_CLAMPED, InverseDistance = AL_INVERSE_DISTANCE, LinearDistance = AL_LINEAR_DISTANCE, ExponentDistance = AL_EXPONENT_DISTANCE, DisableDistance = AL_NONE, DefaultDistanceModel = InverseDistanceClamped }; enum Channel { FrontLeft = 0, FrontRight, FrontCenter, LFE, BackLeft, BackRight, BackCenter, SideLeft, SideRight, UpperFrontLeft, UpperFrontRight, UpperBackLeft, UpperBackRight, LowerFrontLeft, LowerFrontRight, LowerBackLeft, LowerBackRight, Aux0, Aux1, Aux2, Aux3, Aux4, Aux5, Aux6, Aux7, Aux8, Aux9, Aux10, Aux11, Aux12, Aux13, Aux14, Aux15, InvalidChannel }; /* Device formats */ enum DevFmtType { DevFmtByte = ALC_BYTE_SOFT, DevFmtUByte = ALC_UNSIGNED_BYTE_SOFT, DevFmtShort = ALC_SHORT_SOFT, DevFmtUShort = ALC_UNSIGNED_SHORT_SOFT, DevFmtInt = ALC_INT_SOFT, DevFmtUInt = ALC_UNSIGNED_INT_SOFT, DevFmtFloat = ALC_FLOAT_SOFT, DevFmtTypeDefault = DevFmtFloat }; enum DevFmtChannels { DevFmtMono = ALC_MONO_SOFT, DevFmtStereo = ALC_STEREO_SOFT, DevFmtQuad = ALC_QUAD_SOFT, DevFmtX51 = ALC_5POINT1_SOFT, DevFmtX61 = ALC_6POINT1_SOFT, DevFmtX71 = ALC_7POINT1_SOFT, /* Similar to 5.1, except using rear channels instead of sides */ DevFmtX51Rear = 0x80000000, /* Ambisonic formats should be kept together */ DevFmtAmbi1, DevFmtAmbi2, DevFmtAmbi3, DevFmtChannelsDefault = DevFmtStereo }; #define MAX_OUTPUT_CHANNELS (16) ALsizei BytesFromDevFmt(enum DevFmtType type); ALsizei ChannelsFromDevFmt(enum DevFmtChannels chans); inline ALsizei FrameSizeFromDevFmt(enum DevFmtChannels chans, enum DevFmtType type) { return ChannelsFromDevFmt(chans) * BytesFromDevFmt(type); } enum AmbiFormat { AmbiFormat_FuMa, /* FuMa channel order and normalization */ AmbiFormat_ACN_SN3D, /* ACN channel order and SN3D normalization */ AmbiFormat_ACN_N3D, /* ACN channel order and N3D normalization */ AmbiFormat_Default = AmbiFormat_ACN_SN3D }; extern const struct EffectList { const char *name; int type; const char *ename; ALenum val; } EffectList[]; enum DeviceType { Playback, Capture, Loopback }; enum RenderMode { NormalRender, StereoPair, HrtfRender }; /* The maximum number of Ambisonics coefficients. For a given order (o), the * size needed will be (o+1)**2, thus zero-order has 1, first-order has 4, * second-order has 9, third-order has 16, and fourth-order has 25. */ #define MAX_AMBI_ORDER 3 #define MAX_AMBI_COEFFS ((MAX_AMBI_ORDER+1) * (MAX_AMBI_ORDER+1)) /* A bitmask of ambisonic channels with height information. If none of these * channels are used/needed, there's no height (e.g. with most surround sound * speaker setups). This only specifies up to 4th order, which is the highest * order a 32-bit mask value can specify (a 64-bit mask could handle up to 7th * order). This is ACN ordering, with bit 0 being ACN 0, etc. */ #define AMBI_PERIPHONIC_MASK (0xfe7ce4) /* The maximum number of Ambisonic coefficients for 2D (non-periphonic) * representation. This is 2 per each order above zero-order, plus 1 for zero- * order. Or simply, o*2 + 1. */ #define MAX_AMBI2D_COEFFS (MAX_AMBI_ORDER*2 + 1) typedef ALfloat ChannelConfig[MAX_AMBI_COEFFS]; typedef struct BFChannelConfig { ALfloat Scale; ALsizei Index; } BFChannelConfig; typedef union AmbiConfig { /* Ambisonic coefficients for mixing to the dry buffer. */ ChannelConfig Coeffs[MAX_OUTPUT_CHANNELS]; /* Coefficient channel mapping for mixing to the dry buffer. */ BFChannelConfig Map[MAX_OUTPUT_CHANNELS]; } AmbiConfig; #define HRTF_HISTORY_BITS (6) #define HRTF_HISTORY_LENGTH (1<Device); } inline void UnlockContext(ALCcontext *context) { ALCdevice_Unlock(context->Device); } enum { DeferOff = AL_FALSE, DeferAll, DeferAllowPlay }; typedef struct { #ifdef HAVE_FENV_H DERIVE_FROM_TYPE(fenv_t); #else int state; #endif #ifdef HAVE_SSE int sse_state; #endif } FPUCtl; void SetMixerFPUMode(FPUCtl *ctl); void RestoreFPUMode(const FPUCtl *ctl); typedef struct ll_ringbuffer ll_ringbuffer_t; typedef struct ll_ringbuffer_data { char *buf; size_t len; } ll_ringbuffer_data_t; ll_ringbuffer_t *ll_ringbuffer_create(size_t sz, size_t elem_sz); void ll_ringbuffer_free(ll_ringbuffer_t *rb); void ll_ringbuffer_get_read_vector(const ll_ringbuffer_t *rb, ll_ringbuffer_data_t *vec); void ll_ringbuffer_get_write_vector(const ll_ringbuffer_t *rb, ll_ringbuffer_data_t *vec); size_t ll_ringbuffer_read(ll_ringbuffer_t *rb, char *dest, size_t cnt); size_t ll_ringbuffer_peek(ll_ringbuffer_t *rb, char *dest, size_t cnt); void ll_ringbuffer_read_advance(ll_ringbuffer_t *rb, size_t cnt); size_t ll_ringbuffer_read_space(const ll_ringbuffer_t *rb); int ll_ringbuffer_mlock(ll_ringbuffer_t *rb); void ll_ringbuffer_reset(ll_ringbuffer_t *rb); size_t ll_ringbuffer_write(ll_ringbuffer_t *rb, const char *src, size_t cnt); void ll_ringbuffer_write_advance(ll_ringbuffer_t *rb, size_t cnt); size_t ll_ringbuffer_write_space(const ll_ringbuffer_t *rb); void ReadALConfig(void); void FreeALConfig(void); int ConfigValueExists(const char *devName, const char *blockName, const char *keyName); const char *GetConfigValue(const char *devName, const char *blockName, const char *keyName, const char *def); int GetConfigValueBool(const char *devName, const char *blockName, const char *keyName, int def); int ConfigValueStr(const char *devName, const char *blockName, const char *keyName, const char **ret); int ConfigValueInt(const char *devName, const char *blockName, const char *keyName, int *ret); int ConfigValueUInt(const char *devName, const char *blockName, const char *keyName, unsigned int *ret); int ConfigValueFloat(const char *devName, const char *blockName, const char *keyName, float *ret); int ConfigValueBool(const char *devName, const char *blockName, const char *keyName, int *ret); void SetRTPriority(void); void SetDefaultChannelOrder(ALCdevice *device); void SetDefaultWFXChannelOrder(ALCdevice *device); const ALCchar *DevFmtTypeString(enum DevFmtType type); const ALCchar *DevFmtChannelsString(enum DevFmtChannels chans); /** * GetChannelIdxByName * * Returns the index for the given channel name (e.g. FrontCenter), or -1 if it * doesn't exist. */ inline ALint GetChannelIndex(const enum Channel names[MAX_OUTPUT_CHANNELS], enum Channel chan) { ALint i; for(i = 0;i < MAX_OUTPUT_CHANNELS;i++) { if(names[i] == chan) return i; } return -1; } #define GetChannelIdxByName(x, c) GetChannelIndex((x).ChannelName, (c)) extern FILE *LogFile; #if defined(__GNUC__) && !defined(_WIN32) && !defined(IN_IDE_PARSER) #define AL_PRINT(T, MSG, ...) fprintf(LogFile, "AL lib: %s %s: "MSG, T, __FUNCTION__ , ## __VA_ARGS__) #else void al_print(const char *type, const char *func, const char *fmt, ...) DECL_FORMAT(printf, 3,4); #define AL_PRINT(T, ...) al_print((T), __FUNCTION__, __VA_ARGS__) #endif #ifdef __ANDROID__ #include #define LOG_ANDROID(T, MSG, ...) __android_log_print(T, "openal", "AL lib: %s: "MSG, __FUNCTION__ , ## __VA_ARGS__) #else #define LOG_ANDROID(T, MSG, ...) ((void)0) #endif enum LogLevel { NoLog, LogError, LogWarning, LogTrace, LogRef }; extern enum LogLevel LogLevel; #define TRACEREF(...) do { \ if(LogLevel >= LogRef) \ AL_PRINT("(--)", __VA_ARGS__); \ } while(0) #define TRACE(...) do { \ if(LogLevel >= LogTrace) \ AL_PRINT("(II)", __VA_ARGS__); \ LOG_ANDROID(ANDROID_LOG_DEBUG, __VA_ARGS__); \ } while(0) #define WARN(...) do { \ if(LogLevel >= LogWarning) \ AL_PRINT("(WW)", __VA_ARGS__); \ LOG_ANDROID(ANDROID_LOG_WARN, __VA_ARGS__); \ } while(0) #define ERR(...) do { \ if(LogLevel >= LogError) \ AL_PRINT("(EE)", __VA_ARGS__); \ LOG_ANDROID(ANDROID_LOG_ERROR, __VA_ARGS__); \ } while(0) extern ALint RTPrioLevel; extern ALuint CPUCapFlags; enum { CPU_CAP_SSE = 1<<0, CPU_CAP_SSE2 = 1<<1, CPU_CAP_SSE3 = 1<<2, CPU_CAP_SSE4_1 = 1<<3, CPU_CAP_NEON = 1<<4, }; void FillCPUCaps(ALuint capfilter); vector_al_string SearchDataFiles(const char *match, const char *subdir); /* Small hack to use a pointer-to-array type as a normal argument type. * Shouldn't be used directly. */ typedef ALfloat ALfloatBUFFERSIZE[BUFFERSIZE]; #ifdef __cplusplus } #endif #endif