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openal-soft/alc/alc.cpp
Chris Robinson 825206bfa2 Apply the ambisonic HF scaling in real-time with HRTF 
Rather than applying the HF scale to the IRs necessitating them to be truncated
along with increasing the IR size, it can be applied to the input signal for
the same results. Consequently, the IR size can be notably shortened while
avoiding the extra truncation. In its place, the delayed reversed all-pass
technique can still be used on the input for maintaining phase when applying
the bandsplit/hfscalar filter to the input signal.
2020-05-19 10:27:52 -07:00

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/**
* OpenAL cross platform audio library
* Copyright (C) 1999-2007 by authors.
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Library General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public
* License along with this library; if not, write to the
* Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
* Or go to http://www.gnu.org/copyleft/lgpl.html
*/
#include "config.h"
#include "version.h"
#include <exception>
#include <algorithm>
#include <array>
#include <atomic>
#include <cctype>
#include <chrono>
#include <cinttypes>
#include <climits>
#include <cmath>
#include <csignal>
#include <cstdint>
#include <cstdio>
#include <cstdlib>
#include <cstring>
#include <functional>
#include <iterator>
#include <limits>
#include <memory>
#include <mutex>
#include <new>
#include <numeric>
#include <string>
#include <thread>
#include <utility>
#include "AL/al.h"
#include "AL/alc.h"
#include "AL/alext.h"
#include "AL/efx.h"
#include "al/auxeffectslot.h"
#include "al/effect.h"
#include "al/event.h"
#include "al/filter.h"
#include "al/listener.h"
#include "al/source.h"
#include "alcmain.h"
#include "albyte.h"
#include "alconfig.h"
#include "alcontext.h"
#include "alexcpt.h"
#include "almalloc.h"
#include "alnumeric.h"
#include "aloptional.h"
#include "alspan.h"
#include "alstring.h"
#include "alu.h"
#include "ambidefs.h"
#include "atomic.h"
#include "bformatdec.h"
#include "bs2b.h"
#include "compat.h"
#include "cpu_caps.h"
#include "devformat.h"
#include "effects/base.h"
#include "filters/nfc.h"
#include "filters/splitter.h"
#include "fpu_ctrl.h"
#include "front_stablizer.h"
#include "hrtf.h"
#include "inprogext.h"
#include "intrusive_ptr.h"
#include "logging.h"
#include "mastering.h"
#include "opthelpers.h"
#include "pragmadefs.h"
#include "ringbuffer.h"
#include "strutils.h"
#include "threads.h"
#include "uhjfilter.h"
#include "vecmat.h"
#include "vector.h"
#include "backends/base.h"
#include "backends/null.h"
#include "backends/loopback.h"
#ifdef HAVE_JACK
#include "backends/jack.h"
#endif
#ifdef HAVE_PULSEAUDIO
#include "backends/pulseaudio.h"
#endif
#ifdef HAVE_ALSA
#include "backends/alsa.h"
#endif
#ifdef HAVE_WASAPI
#include "backends/wasapi.h"
#endif
#ifdef HAVE_COREAUDIO
#include "backends/coreaudio.h"
#endif
#ifdef HAVE_OPENSL
#include "backends/opensl.h"
#endif
#ifdef HAVE_OBOE
#include "backends/oboe.h"
#endif
#ifdef HAVE_SOLARIS
#include "backends/solaris.h"
#endif
#ifdef HAVE_SNDIO
#include "backends/sndio.h"
#endif
#ifdef HAVE_OSS
#include "backends/oss.h"
#endif
#ifdef HAVE_DSOUND
#include "backends/dsound.h"
#endif
#ifdef HAVE_WINMM
#include "backends/winmm.h"
#endif
#ifdef HAVE_PORTAUDIO
#include "backends/portaudio.h"
#endif
#ifdef HAVE_SDL2
#include "backends/sdl2.h"
#endif
#ifdef HAVE_WAVE
#include "backends/wave.h"
#endif
namespace {
using namespace std::placeholders;
using std::chrono::seconds;
using std::chrono::nanoseconds;
/************************************************
* Backends
************************************************/
struct BackendInfo {
const char *name;
BackendFactory& (*getFactory)(void);
};
BackendInfo BackendList[] = {
#ifdef HAVE_JACK
{ "jack", JackBackendFactory::getFactory },
#endif
#ifdef HAVE_PULSEAUDIO
{ "pulse", PulseBackendFactory::getFactory },
#endif
#ifdef HAVE_ALSA
{ "alsa", AlsaBackendFactory::getFactory },
#endif
#ifdef HAVE_WASAPI
{ "wasapi", WasapiBackendFactory::getFactory },
#endif
#ifdef HAVE_COREAUDIO
{ "core", CoreAudioBackendFactory::getFactory },
#endif
#ifdef HAVE_OBOE
{ "oboe", OboeBackendFactory::getFactory },
#endif
#ifdef HAVE_OPENSL
{ "opensl", OSLBackendFactory::getFactory },
#endif
#ifdef HAVE_SOLARIS
{ "solaris", SolarisBackendFactory::getFactory },
#endif
#ifdef HAVE_SNDIO
{ "sndio", SndIOBackendFactory::getFactory },
#endif
#ifdef HAVE_OSS
{ "oss", OSSBackendFactory::getFactory },
#endif
#ifdef HAVE_DSOUND
{ "dsound", DSoundBackendFactory::getFactory },
#endif
#ifdef HAVE_WINMM
{ "winmm", WinMMBackendFactory::getFactory },
#endif
#ifdef HAVE_PORTAUDIO
{ "port", PortBackendFactory::getFactory },
#endif
#ifdef HAVE_SDL2
{ "sdl2", SDL2BackendFactory::getFactory },
#endif
{ "null", NullBackendFactory::getFactory },
#ifdef HAVE_WAVE
{ "wave", WaveBackendFactory::getFactory },
#endif
};
BackendFactory *PlaybackFactory{};
BackendFactory *CaptureFactory{};
/************************************************
* Functions, enums, and errors
************************************************/
#define DECL(x) { #x, reinterpret_cast<void*>(x) }
const struct {
const char *funcName;
void *address;
} alcFunctions[] = {
DECL(alcCreateContext),
DECL(alcMakeContextCurrent),
DECL(alcProcessContext),
DECL(alcSuspendContext),
DECL(alcDestroyContext),
DECL(alcGetCurrentContext),
DECL(alcGetContextsDevice),
DECL(alcOpenDevice),
DECL(alcCloseDevice),
DECL(alcGetError),
DECL(alcIsExtensionPresent),
DECL(alcGetProcAddress),
DECL(alcGetEnumValue),
DECL(alcGetString),
DECL(alcGetIntegerv),
DECL(alcCaptureOpenDevice),
DECL(alcCaptureCloseDevice),
DECL(alcCaptureStart),
DECL(alcCaptureStop),
DECL(alcCaptureSamples),
DECL(alcSetThreadContext),
DECL(alcGetThreadContext),
DECL(alcLoopbackOpenDeviceSOFT),
DECL(alcIsRenderFormatSupportedSOFT),
DECL(alcRenderSamplesSOFT),
DECL(alcDevicePauseSOFT),
DECL(alcDeviceResumeSOFT),
DECL(alcGetStringiSOFT),
DECL(alcResetDeviceSOFT),
DECL(alcGetInteger64vSOFT),
DECL(alEnable),
DECL(alDisable),
DECL(alIsEnabled),
DECL(alGetString),
DECL(alGetBooleanv),
DECL(alGetIntegerv),
DECL(alGetFloatv),
DECL(alGetDoublev),
DECL(alGetBoolean),
DECL(alGetInteger),
DECL(alGetFloat),
DECL(alGetDouble),
DECL(alGetError),
DECL(alIsExtensionPresent),
DECL(alGetProcAddress),
DECL(alGetEnumValue),
DECL(alListenerf),
DECL(alListener3f),
DECL(alListenerfv),
DECL(alListeneri),
DECL(alListener3i),
DECL(alListeneriv),
DECL(alGetListenerf),
DECL(alGetListener3f),
DECL(alGetListenerfv),
DECL(alGetListeneri),
DECL(alGetListener3i),
DECL(alGetListeneriv),
DECL(alGenSources),
DECL(alDeleteSources),
DECL(alIsSource),
DECL(alSourcef),
DECL(alSource3f),
DECL(alSourcefv),
DECL(alSourcei),
DECL(alSource3i),
DECL(alSourceiv),
DECL(alGetSourcef),
DECL(alGetSource3f),
DECL(alGetSourcefv),
DECL(alGetSourcei),
DECL(alGetSource3i),
DECL(alGetSourceiv),
DECL(alSourcePlayv),
DECL(alSourceStopv),
DECL(alSourceRewindv),
DECL(alSourcePausev),
DECL(alSourcePlay),
DECL(alSourceStop),
DECL(alSourceRewind),
DECL(alSourcePause),
DECL(alSourceQueueBuffers),
DECL(alSourceUnqueueBuffers),
DECL(alGenBuffers),
DECL(alDeleteBuffers),
DECL(alIsBuffer),
DECL(alBufferData),
DECL(alBufferf),
DECL(alBuffer3f),
DECL(alBufferfv),
DECL(alBufferi),
DECL(alBuffer3i),
DECL(alBufferiv),
DECL(alGetBufferf),
DECL(alGetBuffer3f),
DECL(alGetBufferfv),
DECL(alGetBufferi),
DECL(alGetBuffer3i),
DECL(alGetBufferiv),
DECL(alDopplerFactor),
DECL(alDopplerVelocity),
DECL(alSpeedOfSound),
DECL(alDistanceModel),
DECL(alGenFilters),
DECL(alDeleteFilters),
DECL(alIsFilter),
DECL(alFilteri),
DECL(alFilteriv),
DECL(alFilterf),
DECL(alFilterfv),
DECL(alGetFilteri),
DECL(alGetFilteriv),
DECL(alGetFilterf),
DECL(alGetFilterfv),
DECL(alGenEffects),
DECL(alDeleteEffects),
DECL(alIsEffect),
DECL(alEffecti),
DECL(alEffectiv),
DECL(alEffectf),
DECL(alEffectfv),
DECL(alGetEffecti),
DECL(alGetEffectiv),
DECL(alGetEffectf),
DECL(alGetEffectfv),
DECL(alGenAuxiliaryEffectSlots),
DECL(alDeleteAuxiliaryEffectSlots),
DECL(alIsAuxiliaryEffectSlot),
DECL(alAuxiliaryEffectSloti),
DECL(alAuxiliaryEffectSlotiv),
DECL(alAuxiliaryEffectSlotf),
DECL(alAuxiliaryEffectSlotfv),
DECL(alGetAuxiliaryEffectSloti),
DECL(alGetAuxiliaryEffectSlotiv),
DECL(alGetAuxiliaryEffectSlotf),
DECL(alGetAuxiliaryEffectSlotfv),
DECL(alDeferUpdatesSOFT),
DECL(alProcessUpdatesSOFT),
DECL(alSourcedSOFT),
DECL(alSource3dSOFT),
DECL(alSourcedvSOFT),
DECL(alGetSourcedSOFT),
DECL(alGetSource3dSOFT),
DECL(alGetSourcedvSOFT),
DECL(alSourcei64SOFT),
DECL(alSource3i64SOFT),
DECL(alSourcei64vSOFT),
DECL(alGetSourcei64SOFT),
DECL(alGetSource3i64SOFT),
DECL(alGetSourcei64vSOFT),
DECL(alGetStringiSOFT),
DECL(alBufferStorageSOFT),
DECL(alMapBufferSOFT),
DECL(alUnmapBufferSOFT),
DECL(alFlushMappedBufferSOFT),
DECL(alEventControlSOFT),
DECL(alEventCallbackSOFT),
DECL(alGetPointerSOFT),
DECL(alGetPointervSOFT),
DECL(alBufferCallbackSOFT),
DECL(alGetBufferPtrSOFT),
DECL(alGetBuffer3PtrSOFT),
DECL(alGetBufferPtrvSOFT),
};
#undef DECL
#define DECL(x) { #x, (x) }
constexpr struct {
const ALCchar *enumName;
ALCenum value;
} alcEnumerations[] = {
DECL(ALC_INVALID),
DECL(ALC_FALSE),
DECL(ALC_TRUE),
DECL(ALC_MAJOR_VERSION),
DECL(ALC_MINOR_VERSION),
DECL(ALC_ATTRIBUTES_SIZE),
DECL(ALC_ALL_ATTRIBUTES),
DECL(ALC_DEFAULT_DEVICE_SPECIFIER),
DECL(ALC_DEVICE_SPECIFIER),
DECL(ALC_ALL_DEVICES_SPECIFIER),
DECL(ALC_DEFAULT_ALL_DEVICES_SPECIFIER),
DECL(ALC_EXTENSIONS),
DECL(ALC_FREQUENCY),
DECL(ALC_REFRESH),
DECL(ALC_SYNC),
DECL(ALC_MONO_SOURCES),
DECL(ALC_STEREO_SOURCES),
DECL(ALC_CAPTURE_DEVICE_SPECIFIER),
DECL(ALC_CAPTURE_DEFAULT_DEVICE_SPECIFIER),
DECL(ALC_CAPTURE_SAMPLES),
DECL(ALC_CONNECTED),
DECL(ALC_EFX_MAJOR_VERSION),
DECL(ALC_EFX_MINOR_VERSION),
DECL(ALC_MAX_AUXILIARY_SENDS),
DECL(ALC_FORMAT_CHANNELS_SOFT),
DECL(ALC_FORMAT_TYPE_SOFT),
DECL(ALC_MONO_SOFT),
DECL(ALC_STEREO_SOFT),
DECL(ALC_QUAD_SOFT),
DECL(ALC_5POINT1_SOFT),
DECL(ALC_6POINT1_SOFT),
DECL(ALC_7POINT1_SOFT),
DECL(ALC_BFORMAT3D_SOFT),
DECL(ALC_BYTE_SOFT),
DECL(ALC_UNSIGNED_BYTE_SOFT),
DECL(ALC_SHORT_SOFT),
DECL(ALC_UNSIGNED_SHORT_SOFT),
DECL(ALC_INT_SOFT),
DECL(ALC_UNSIGNED_INT_SOFT),
DECL(ALC_FLOAT_SOFT),
DECL(ALC_HRTF_SOFT),
DECL(ALC_DONT_CARE_SOFT),
DECL(ALC_HRTF_STATUS_SOFT),
DECL(ALC_HRTF_DISABLED_SOFT),
DECL(ALC_HRTF_ENABLED_SOFT),
DECL(ALC_HRTF_DENIED_SOFT),
DECL(ALC_HRTF_REQUIRED_SOFT),
DECL(ALC_HRTF_HEADPHONES_DETECTED_SOFT),
DECL(ALC_HRTF_UNSUPPORTED_FORMAT_SOFT),
DECL(ALC_NUM_HRTF_SPECIFIERS_SOFT),
DECL(ALC_HRTF_SPECIFIER_SOFT),
DECL(ALC_HRTF_ID_SOFT),
DECL(ALC_AMBISONIC_LAYOUT_SOFT),
DECL(ALC_AMBISONIC_SCALING_SOFT),
DECL(ALC_AMBISONIC_ORDER_SOFT),
DECL(ALC_ACN_SOFT),
DECL(ALC_FUMA_SOFT),
DECL(ALC_N3D_SOFT),
DECL(ALC_SN3D_SOFT),
DECL(ALC_OUTPUT_LIMITER_SOFT),
DECL(ALC_NO_ERROR),
DECL(ALC_INVALID_DEVICE),
DECL(ALC_INVALID_CONTEXT),
DECL(ALC_INVALID_ENUM),
DECL(ALC_INVALID_VALUE),
DECL(ALC_OUT_OF_MEMORY),
DECL(AL_INVALID),
DECL(AL_NONE),
DECL(AL_FALSE),
DECL(AL_TRUE),
DECL(AL_SOURCE_RELATIVE),
DECL(AL_CONE_INNER_ANGLE),
DECL(AL_CONE_OUTER_ANGLE),
DECL(AL_PITCH),
DECL(AL_POSITION),
DECL(AL_DIRECTION),
DECL(AL_VELOCITY),
DECL(AL_LOOPING),
DECL(AL_BUFFER),
DECL(AL_GAIN),
DECL(AL_MIN_GAIN),
DECL(AL_MAX_GAIN),
DECL(AL_ORIENTATION),
DECL(AL_REFERENCE_DISTANCE),
DECL(AL_ROLLOFF_FACTOR),
DECL(AL_CONE_OUTER_GAIN),
DECL(AL_MAX_DISTANCE),
DECL(AL_SEC_OFFSET),
DECL(AL_SAMPLE_OFFSET),
DECL(AL_BYTE_OFFSET),
DECL(AL_SOURCE_TYPE),
DECL(AL_STATIC),
DECL(AL_STREAMING),
DECL(AL_UNDETERMINED),
DECL(AL_METERS_PER_UNIT),
DECL(AL_LOOP_POINTS_SOFT),
DECL(AL_DIRECT_CHANNELS_SOFT),
DECL(AL_DIRECT_FILTER),
DECL(AL_AUXILIARY_SEND_FILTER),
DECL(AL_AIR_ABSORPTION_FACTOR),
DECL(AL_ROOM_ROLLOFF_FACTOR),
DECL(AL_CONE_OUTER_GAINHF),
DECL(AL_DIRECT_FILTER_GAINHF_AUTO),
DECL(AL_AUXILIARY_SEND_FILTER_GAIN_AUTO),
DECL(AL_AUXILIARY_SEND_FILTER_GAINHF_AUTO),
DECL(AL_SOURCE_STATE),
DECL(AL_INITIAL),
DECL(AL_PLAYING),
DECL(AL_PAUSED),
DECL(AL_STOPPED),
DECL(AL_BUFFERS_QUEUED),
DECL(AL_BUFFERS_PROCESSED),
DECL(AL_FORMAT_MONO8),
DECL(AL_FORMAT_MONO16),
DECL(AL_FORMAT_MONO_FLOAT32),
DECL(AL_FORMAT_MONO_DOUBLE_EXT),
DECL(AL_FORMAT_STEREO8),
DECL(AL_FORMAT_STEREO16),
DECL(AL_FORMAT_STEREO_FLOAT32),
DECL(AL_FORMAT_STEREO_DOUBLE_EXT),
DECL(AL_FORMAT_MONO_IMA4),
DECL(AL_FORMAT_STEREO_IMA4),
DECL(AL_FORMAT_MONO_MSADPCM_SOFT),
DECL(AL_FORMAT_STEREO_MSADPCM_SOFT),
DECL(AL_FORMAT_QUAD8_LOKI),
DECL(AL_FORMAT_QUAD16_LOKI),
DECL(AL_FORMAT_QUAD8),
DECL(AL_FORMAT_QUAD16),
DECL(AL_FORMAT_QUAD32),
DECL(AL_FORMAT_51CHN8),
DECL(AL_FORMAT_51CHN16),
DECL(AL_FORMAT_51CHN32),
DECL(AL_FORMAT_61CHN8),
DECL(AL_FORMAT_61CHN16),
DECL(AL_FORMAT_61CHN32),
DECL(AL_FORMAT_71CHN8),
DECL(AL_FORMAT_71CHN16),
DECL(AL_FORMAT_71CHN32),
DECL(AL_FORMAT_REAR8),
DECL(AL_FORMAT_REAR16),
DECL(AL_FORMAT_REAR32),
DECL(AL_FORMAT_MONO_MULAW),
DECL(AL_FORMAT_MONO_MULAW_EXT),
DECL(AL_FORMAT_STEREO_MULAW),
DECL(AL_FORMAT_STEREO_MULAW_EXT),
DECL(AL_FORMAT_QUAD_MULAW),
DECL(AL_FORMAT_51CHN_MULAW),
DECL(AL_FORMAT_61CHN_MULAW),
DECL(AL_FORMAT_71CHN_MULAW),
DECL(AL_FORMAT_REAR_MULAW),
DECL(AL_FORMAT_MONO_ALAW_EXT),
DECL(AL_FORMAT_STEREO_ALAW_EXT),
DECL(AL_FORMAT_BFORMAT2D_8),
DECL(AL_FORMAT_BFORMAT2D_16),
DECL(AL_FORMAT_BFORMAT2D_FLOAT32),
DECL(AL_FORMAT_BFORMAT2D_MULAW),
DECL(AL_FORMAT_BFORMAT3D_8),
DECL(AL_FORMAT_BFORMAT3D_16),
DECL(AL_FORMAT_BFORMAT3D_FLOAT32),
DECL(AL_FORMAT_BFORMAT3D_MULAW),
DECL(AL_FREQUENCY),
DECL(AL_BITS),
DECL(AL_CHANNELS),
DECL(AL_SIZE),
DECL(AL_UNPACK_BLOCK_ALIGNMENT_SOFT),
DECL(AL_PACK_BLOCK_ALIGNMENT_SOFT),
DECL(AL_SOURCE_RADIUS),
DECL(AL_STEREO_ANGLES),
DECL(AL_UNUSED),
DECL(AL_PENDING),
DECL(AL_PROCESSED),
DECL(AL_NO_ERROR),
DECL(AL_INVALID_NAME),
DECL(AL_INVALID_ENUM),
DECL(AL_INVALID_VALUE),
DECL(AL_INVALID_OPERATION),
DECL(AL_OUT_OF_MEMORY),
DECL(AL_VENDOR),
DECL(AL_VERSION),
DECL(AL_RENDERER),
DECL(AL_EXTENSIONS),
DECL(AL_DOPPLER_FACTOR),
DECL(AL_DOPPLER_VELOCITY),
DECL(AL_DISTANCE_MODEL),
DECL(AL_SPEED_OF_SOUND),
DECL(AL_SOURCE_DISTANCE_MODEL),
DECL(AL_DEFERRED_UPDATES_SOFT),
DECL(AL_GAIN_LIMIT_SOFT),
DECL(AL_INVERSE_DISTANCE),
DECL(AL_INVERSE_DISTANCE_CLAMPED),
DECL(AL_LINEAR_DISTANCE),
DECL(AL_LINEAR_DISTANCE_CLAMPED),
DECL(AL_EXPONENT_DISTANCE),
DECL(AL_EXPONENT_DISTANCE_CLAMPED),
DECL(AL_FILTER_TYPE),
DECL(AL_FILTER_NULL),
DECL(AL_FILTER_LOWPASS),
DECL(AL_FILTER_HIGHPASS),
DECL(AL_FILTER_BANDPASS),
DECL(AL_LOWPASS_GAIN),
DECL(AL_LOWPASS_GAINHF),
DECL(AL_HIGHPASS_GAIN),
DECL(AL_HIGHPASS_GAINLF),
DECL(AL_BANDPASS_GAIN),
DECL(AL_BANDPASS_GAINHF),
DECL(AL_BANDPASS_GAINLF),
DECL(AL_EFFECT_TYPE),
DECL(AL_EFFECT_NULL),
DECL(AL_EFFECT_REVERB),
DECL(AL_EFFECT_EAXREVERB),
DECL(AL_EFFECT_CHORUS),
DECL(AL_EFFECT_DISTORTION),
DECL(AL_EFFECT_ECHO),
DECL(AL_EFFECT_FLANGER),
DECL(AL_EFFECT_PITCH_SHIFTER),
DECL(AL_EFFECT_FREQUENCY_SHIFTER),
DECL(AL_EFFECT_VOCAL_MORPHER),
DECL(AL_EFFECT_RING_MODULATOR),
DECL(AL_EFFECT_AUTOWAH),
DECL(AL_EFFECT_COMPRESSOR),
DECL(AL_EFFECT_EQUALIZER),
DECL(AL_EFFECT_DEDICATED_LOW_FREQUENCY_EFFECT),
DECL(AL_EFFECT_DEDICATED_DIALOGUE),
DECL(AL_EFFECTSLOT_EFFECT),
DECL(AL_EFFECTSLOT_GAIN),
DECL(AL_EFFECTSLOT_AUXILIARY_SEND_AUTO),
DECL(AL_EFFECTSLOT_NULL),
DECL(AL_EAXREVERB_DENSITY),
DECL(AL_EAXREVERB_DIFFUSION),
DECL(AL_EAXREVERB_GAIN),
DECL(AL_EAXREVERB_GAINHF),
DECL(AL_EAXREVERB_GAINLF),
DECL(AL_EAXREVERB_DECAY_TIME),
DECL(AL_EAXREVERB_DECAY_HFRATIO),
DECL(AL_EAXREVERB_DECAY_LFRATIO),
DECL(AL_EAXREVERB_REFLECTIONS_GAIN),
DECL(AL_EAXREVERB_REFLECTIONS_DELAY),
DECL(AL_EAXREVERB_REFLECTIONS_PAN),
DECL(AL_EAXREVERB_LATE_REVERB_GAIN),
DECL(AL_EAXREVERB_LATE_REVERB_DELAY),
DECL(AL_EAXREVERB_LATE_REVERB_PAN),
DECL(AL_EAXREVERB_ECHO_TIME),
DECL(AL_EAXREVERB_ECHO_DEPTH),
DECL(AL_EAXREVERB_MODULATION_TIME),
DECL(AL_EAXREVERB_MODULATION_DEPTH),
DECL(AL_EAXREVERB_AIR_ABSORPTION_GAINHF),
DECL(AL_EAXREVERB_HFREFERENCE),
DECL(AL_EAXREVERB_LFREFERENCE),
DECL(AL_EAXREVERB_ROOM_ROLLOFF_FACTOR),
DECL(AL_EAXREVERB_DECAY_HFLIMIT),
DECL(AL_REVERB_DENSITY),
DECL(AL_REVERB_DIFFUSION),
DECL(AL_REVERB_GAIN),
DECL(AL_REVERB_GAINHF),
DECL(AL_REVERB_DECAY_TIME),
DECL(AL_REVERB_DECAY_HFRATIO),
DECL(AL_REVERB_REFLECTIONS_GAIN),
DECL(AL_REVERB_REFLECTIONS_DELAY),
DECL(AL_REVERB_LATE_REVERB_GAIN),
DECL(AL_REVERB_LATE_REVERB_DELAY),
DECL(AL_REVERB_AIR_ABSORPTION_GAINHF),
DECL(AL_REVERB_ROOM_ROLLOFF_FACTOR),
DECL(AL_REVERB_DECAY_HFLIMIT),
DECL(AL_CHORUS_WAVEFORM),
DECL(AL_CHORUS_PHASE),
DECL(AL_CHORUS_RATE),
DECL(AL_CHORUS_DEPTH),
DECL(AL_CHORUS_FEEDBACK),
DECL(AL_CHORUS_DELAY),
DECL(AL_DISTORTION_EDGE),
DECL(AL_DISTORTION_GAIN),
DECL(AL_DISTORTION_LOWPASS_CUTOFF),
DECL(AL_DISTORTION_EQCENTER),
DECL(AL_DISTORTION_EQBANDWIDTH),
DECL(AL_ECHO_DELAY),
DECL(AL_ECHO_LRDELAY),
DECL(AL_ECHO_DAMPING),
DECL(AL_ECHO_FEEDBACK),
DECL(AL_ECHO_SPREAD),
DECL(AL_FLANGER_WAVEFORM),
DECL(AL_FLANGER_PHASE),
DECL(AL_FLANGER_RATE),
DECL(AL_FLANGER_DEPTH),
DECL(AL_FLANGER_FEEDBACK),
DECL(AL_FLANGER_DELAY),
DECL(AL_FREQUENCY_SHIFTER_FREQUENCY),
DECL(AL_FREQUENCY_SHIFTER_LEFT_DIRECTION),
DECL(AL_FREQUENCY_SHIFTER_RIGHT_DIRECTION),
DECL(AL_RING_MODULATOR_FREQUENCY),
DECL(AL_RING_MODULATOR_HIGHPASS_CUTOFF),
DECL(AL_RING_MODULATOR_WAVEFORM),
DECL(AL_PITCH_SHIFTER_COARSE_TUNE),
DECL(AL_PITCH_SHIFTER_FINE_TUNE),
DECL(AL_COMPRESSOR_ONOFF),
DECL(AL_EQUALIZER_LOW_GAIN),
DECL(AL_EQUALIZER_LOW_CUTOFF),
DECL(AL_EQUALIZER_MID1_GAIN),
DECL(AL_EQUALIZER_MID1_CENTER),
DECL(AL_EQUALIZER_MID1_WIDTH),
DECL(AL_EQUALIZER_MID2_GAIN),
DECL(AL_EQUALIZER_MID2_CENTER),
DECL(AL_EQUALIZER_MID2_WIDTH),
DECL(AL_EQUALIZER_HIGH_GAIN),
DECL(AL_EQUALIZER_HIGH_CUTOFF),
DECL(AL_DEDICATED_GAIN),
DECL(AL_AUTOWAH_ATTACK_TIME),
DECL(AL_AUTOWAH_RELEASE_TIME),
DECL(AL_AUTOWAH_RESONANCE),
DECL(AL_AUTOWAH_PEAK_GAIN),
DECL(AL_VOCAL_MORPHER_PHONEMEA),
DECL(AL_VOCAL_MORPHER_PHONEMEB_COARSE_TUNING),
DECL(AL_VOCAL_MORPHER_PHONEMEB),
DECL(AL_VOCAL_MORPHER_PHONEMEB_COARSE_TUNING),
DECL(AL_VOCAL_MORPHER_WAVEFORM),
DECL(AL_VOCAL_MORPHER_RATE),
DECL(AL_NUM_RESAMPLERS_SOFT),
DECL(AL_DEFAULT_RESAMPLER_SOFT),
DECL(AL_SOURCE_RESAMPLER_SOFT),
DECL(AL_RESAMPLER_NAME_SOFT),
DECL(AL_SOURCE_SPATIALIZE_SOFT),
DECL(AL_AUTO_SOFT),
DECL(AL_MAP_READ_BIT_SOFT),
DECL(AL_MAP_WRITE_BIT_SOFT),
DECL(AL_MAP_PERSISTENT_BIT_SOFT),
DECL(AL_PRESERVE_DATA_BIT_SOFT),
DECL(AL_EVENT_CALLBACK_FUNCTION_SOFT),
DECL(AL_EVENT_CALLBACK_USER_PARAM_SOFT),
DECL(AL_EVENT_TYPE_BUFFER_COMPLETED_SOFT),
DECL(AL_EVENT_TYPE_SOURCE_STATE_CHANGED_SOFT),
DECL(AL_EVENT_TYPE_ERROR_SOFT),
DECL(AL_EVENT_TYPE_PERFORMANCE_SOFT),
DECL(AL_EVENT_TYPE_DEPRECATED_SOFT),
DECL(AL_DROP_UNMATCHED_SOFT),
DECL(AL_REMIX_UNMATCHED_SOFT),
DECL(AL_AMBISONIC_LAYOUT_SOFT),
DECL(AL_AMBISONIC_SCALING_SOFT),
DECL(AL_FUMA_SOFT),
DECL(AL_ACN_SOFT),
DECL(AL_SN3D_SOFT),
DECL(AL_N3D_SOFT),
DECL(AL_BUFFER_CALLBACK_FUNCTION_SOFT),
DECL(AL_BUFFER_CALLBACK_USER_PARAM_SOFT),
DECL(AL_UNPACK_AMBISONIC_ORDER_SOFT),
};
#undef DECL
constexpr ALCchar alcNoError[] = "No Error";
constexpr ALCchar alcErrInvalidDevice[] = "Invalid Device";
constexpr ALCchar alcErrInvalidContext[] = "Invalid Context";
constexpr ALCchar alcErrInvalidEnum[] = "Invalid Enum";
constexpr ALCchar alcErrInvalidValue[] = "Invalid Value";
constexpr ALCchar alcErrOutOfMemory[] = "Out of Memory";
/************************************************
* Global variables
************************************************/
/* Enumerated device names */
constexpr ALCchar alcDefaultName[] = "OpenAL Soft\0";
std::string alcAllDevicesList;
std::string alcCaptureDeviceList;
/* Default is always the first in the list */
al::string alcDefaultAllDevicesSpecifier;
al::string alcCaptureDefaultDeviceSpecifier;
/* Default context extensions */
constexpr ALchar alExtList[] =
"AL_EXT_ALAW "
"AL_EXT_BFORMAT "
"AL_EXT_DOUBLE "
"AL_EXT_EXPONENT_DISTANCE "
"AL_EXT_FLOAT32 "
"AL_EXT_IMA4 "
"AL_EXT_LINEAR_DISTANCE "
"AL_EXT_MCFORMATS "
"AL_EXT_MULAW "
"AL_EXT_MULAW_BFORMAT "
"AL_EXT_MULAW_MCFORMATS "
"AL_EXT_OFFSET "
"AL_EXT_source_distance_model "
"AL_EXT_SOURCE_RADIUS "
"AL_EXT_STEREO_ANGLES "
"AL_LOKI_quadriphonic "
"AL_SOFT_bformat_ex "
"AL_SOFTX_bformat_hoa "
"AL_SOFT_block_alignment "
"AL_SOFTX_callback_buffer "
"AL_SOFT_deferred_updates "
"AL_SOFT_direct_channels "
"AL_SOFT_direct_channels_remix "
"AL_SOFTX_effect_target "
"AL_SOFTX_events "
"AL_SOFTX_filter_gain_ex "
"AL_SOFT_gain_clamp_ex "
"AL_SOFT_loop_points "
"AL_SOFTX_map_buffer "
"AL_SOFT_MSADPCM "
"AL_SOFT_source_latency "
"AL_SOFT_source_length "
"AL_SOFT_source_resampler "
"AL_SOFT_source_spatialize";
std::atomic<ALCenum> LastNullDeviceError{ALC_NO_ERROR};
/* Thread-local current context. The handling may look a little obtuse, but
* it's designed this way to avoid a bug with 32-bit GCC/MinGW, which causes
* thread-local object destructors to get a junk 'this' pointer. This method
* has the benefit of making LocalContext access more efficient since it's a
* a plain pointer, with the ThreadContext object used to check it at thread
* exit (and given no data fields, 'this' being junk is inconsequential since
* it's never accessed).
*/
thread_local ALCcontext *LocalContext{nullptr};
class ThreadCtx {
public:
~ThreadCtx()
{
if(ALCcontext *ctx{LocalContext})
{
const bool result{ctx->releaseIfNoDelete()};
ERR("Context %p current for thread being destroyed%s!\n",
decltype(std::declval<void*>()){ctx}, result ? "" : ", leak detected");
}
}
void set(ALCcontext *ctx) const noexcept { LocalContext = ctx; }
};
thread_local ThreadCtx ThreadContext;
/* Process-wide current context */
std::atomic<ALCcontext*> GlobalContext{nullptr};
/* Flag to trap ALC device errors */
bool TrapALCError{false};
/* One-time configuration init control */
std::once_flag alc_config_once{};
/* Default effect that applies to sources that don't have an effect on send 0 */
ALeffect DefaultEffect;
/* Flag to specify if alcSuspendContext/alcProcessContext should defer/process
* updates.
*/
bool SuspendDefers{true};
/* Initial seed for dithering. */
constexpr ALuint DitherRNGSeed{22222u};
/************************************************
* ALC information
************************************************/
constexpr ALCchar alcNoDeviceExtList[] =
"ALC_ENUMERATE_ALL_EXT "
"ALC_ENUMERATION_EXT "
"ALC_EXT_CAPTURE "
"ALC_EXT_thread_local_context "
"ALC_SOFT_loopback";
constexpr ALCchar alcExtensionList[] =
"ALC_ENUMERATE_ALL_EXT "
"ALC_ENUMERATION_EXT "
"ALC_EXT_CAPTURE "
"ALC_EXT_DEDICATED "
"ALC_EXT_disconnect "
"ALC_EXT_EFX "
"ALC_EXT_thread_local_context "
"ALC_SOFT_device_clock "
"ALC_SOFT_HRTF "
"ALC_SOFT_loopback "
"ALC_SOFT_output_limiter "
"ALC_SOFT_pause_device";
constexpr int alcMajorVersion{1};
constexpr int alcMinorVersion{1};
constexpr int alcEFXMajorVersion{1};
constexpr int alcEFXMinorVersion{0};
/* To avoid extraneous allocations, a 0-sized FlexArray<ALCcontext*> is defined
* globally as a sharable object. MSVC warns that a zero-sized array will have
* zero objects here, so silence that.
*/
DIAGNOSTIC_PUSH
msc_pragma(warning(disable : 4815))
al::FlexArray<ALCcontext*> EmptyContextArray{0u};
DIAGNOSTIC_POP
using DeviceRef = al::intrusive_ptr<ALCdevice>;
/************************************************
* Device lists
************************************************/
al::vector<ALCdevice*> DeviceList;
al::vector<ALCcontext*> ContextList;
std::recursive_mutex ListLock;
void alc_initconfig(void)
{
if(auto loglevel = al::getenv("ALSOFT_LOGLEVEL"))
{
long lvl = strtol(loglevel->c_str(), nullptr, 0);
if(lvl >= NoLog && lvl <= LogRef)
gLogLevel = static_cast<LogLevel>(lvl);
}
#ifdef _WIN32
if(const auto logfile = al::getenv(L"ALSOFT_LOGFILE"))
{
FILE *logf{_wfopen(logfile->c_str(), L"wt")};
if(logf) gLogFile = logf;
else
{
auto u8name = wstr_to_utf8(logfile->c_str());
ERR("Failed to open log file '%s'\n", u8name.c_str());
}
}
#else
if(const auto logfile = al::getenv("ALSOFT_LOGFILE"))
{
FILE *logf{fopen(logfile->c_str(), "wt")};
if(logf) gLogFile = logf;
else ERR("Failed to open log file '%s'\n", logfile->c_str());
}
#endif
TRACE("Initializing library v%s-%s %s\n", ALSOFT_VERSION, ALSOFT_GIT_COMMIT_HASH,
ALSOFT_GIT_BRANCH);
{
al::string names;
if(al::size(BackendList) < 1)
names = "(none)";
else
{
const al::span<const BackendInfo> infos{BackendList};
names = infos[0].name;
for(const auto &backend : infos.subspan<1>())
{
names += ", ";
names += backend.name;
}
}
TRACE("Supported backends: %s\n", names.c_str());
}
ReadALConfig();
if(auto suspendmode = al::getenv("__ALSOFT_SUSPEND_CONTEXT"))
{
if(al::strcasecmp(suspendmode->c_str(), "ignore") == 0)
{
SuspendDefers = false;
TRACE("Selected context suspend behavior, \"ignore\"\n");
}
else
ERR("Unhandled context suspend behavior setting: \"%s\"\n", suspendmode->c_str());
}
int capfilter{0};
#if defined(HAVE_SSE4_1)
capfilter |= CPU_CAP_SSE | CPU_CAP_SSE2 | CPU_CAP_SSE3 | CPU_CAP_SSE4_1;
#elif defined(HAVE_SSE3)
capfilter |= CPU_CAP_SSE | CPU_CAP_SSE2 | CPU_CAP_SSE3;
#elif defined(HAVE_SSE2)
capfilter |= CPU_CAP_SSE | CPU_CAP_SSE2;
#elif defined(HAVE_SSE)
capfilter |= CPU_CAP_SSE;
#endif
#ifdef HAVE_NEON
capfilter |= CPU_CAP_NEON;
#endif
if(auto cpuopt = ConfigValueStr(nullptr, nullptr, "disable-cpu-exts"))
{
const char *str{cpuopt->c_str()};
if(al::strcasecmp(str, "all") == 0)
capfilter = 0;
else
{
const char *next = str;
do {
str = next;
while(isspace(str[0]))
str++;
next = strchr(str, ',');
if(!str[0] || str[0] == ',')
continue;
size_t len{next ? static_cast<size_t>(next-str) : strlen(str)};
while(len > 0 && isspace(str[len-1]))
len--;
if(len == 3 && al::strncasecmp(str, "sse", len) == 0)
capfilter &= ~CPU_CAP_SSE;
else if(len == 4 && al::strncasecmp(str, "sse2", len) == 0)
capfilter &= ~CPU_CAP_SSE2;
else if(len == 4 && al::strncasecmp(str, "sse3", len) == 0)
capfilter &= ~CPU_CAP_SSE3;
else if(len == 6 && al::strncasecmp(str, "sse4.1", len) == 0)
capfilter &= ~CPU_CAP_SSE4_1;
else if(len == 4 && al::strncasecmp(str, "neon", len) == 0)
capfilter &= ~CPU_CAP_NEON;
else
WARN("Invalid CPU extension \"%s\"\n", str);
} while(next++);
}
}
FillCPUCaps(capfilter);
if(auto priopt = ConfigValueInt(nullptr, nullptr, "rt-prio"))
RTPrioLevel = *priopt;
aluInit();
aluInitMixer();
auto traperr = al::getenv("ALSOFT_TRAP_ERROR");
if(traperr && (al::strcasecmp(traperr->c_str(), "true") == 0
|| std::strtol(traperr->c_str(), nullptr, 0) == 1))
{
TrapALError = true;
TrapALCError = true;
}
else
{
traperr = al::getenv("ALSOFT_TRAP_AL_ERROR");
if(traperr)
TrapALError = al::strcasecmp(traperr->c_str(), "true") == 0
|| strtol(traperr->c_str(), nullptr, 0) == 1;
else
TrapALError = !!GetConfigValueBool(nullptr, nullptr, "trap-al-error", false);
traperr = al::getenv("ALSOFT_TRAP_ALC_ERROR");
if(traperr)
TrapALCError = al::strcasecmp(traperr->c_str(), "true") == 0
|| strtol(traperr->c_str(), nullptr, 0) == 1;
else
TrapALCError = !!GetConfigValueBool(nullptr, nullptr, "trap-alc-error", false);
}
if(auto boostopt = ConfigValueFloat(nullptr, "reverb", "boost"))
{
const float valf{std::isfinite(*boostopt) ? clampf(*boostopt, -24.0f, 24.0f) : 0.0f};
ReverbBoost *= std::pow(10.0f, valf / 20.0f);
}
auto BackendListEnd = std::end(BackendList);
auto devopt = al::getenv("ALSOFT_DRIVERS");
if(devopt || (devopt=ConfigValueStr(nullptr, nullptr, "drivers")))
{
auto backendlist_cur = std::begin(BackendList);
bool endlist{true};
const char *next{devopt->c_str()};
do {
const char *devs{next};
while(isspace(devs[0]))
devs++;
next = strchr(devs, ',');
const bool delitem{devs[0] == '-'};
if(devs[0] == '-') devs++;
if(!devs[0] || devs[0] == ',')
{
endlist = false;
continue;
}
endlist = true;
size_t len{next ? (static_cast<size_t>(next-devs)) : strlen(devs)};
while(len > 0 && isspace(devs[len-1])) --len;
#ifdef HAVE_WASAPI
/* HACK: For backwards compatibility, convert backend references of
* mmdevapi to wasapi. This should eventually be removed.
*/
if(len == 8 && strncmp(devs, "mmdevapi", len) == 0)
{
devs = "wasapi";
len = 6;
}
#endif
auto find_backend = [devs,len](const BackendInfo &backend) -> bool
{ return len == strlen(backend.name) && strncmp(backend.name, devs, len) == 0; };
auto this_backend = std::find_if(std::begin(BackendList), BackendListEnd,
find_backend);
if(this_backend == BackendListEnd)
continue;
if(delitem)
BackendListEnd = std::move(this_backend+1, BackendListEnd, this_backend);
else
backendlist_cur = std::rotate(backendlist_cur, this_backend, this_backend+1);
} while(next++);
if(endlist)
BackendListEnd = backendlist_cur;
}
auto init_backend = [](BackendInfo &backend) -> void
{
if(PlaybackFactory && CaptureFactory)
return;
BackendFactory &factory = backend.getFactory();
if(!factory.init())
{
WARN("Failed to initialize backend \"%s\"\n", backend.name);
return;
}
TRACE("Initialized backend \"%s\"\n", backend.name);
if(!PlaybackFactory && factory.querySupport(BackendType::Playback))
{
PlaybackFactory = &factory;
TRACE("Added \"%s\" for playback\n", backend.name);
}
if(!CaptureFactory && factory.querySupport(BackendType::Capture))
{
CaptureFactory = &factory;
TRACE("Added \"%s\" for capture\n", backend.name);
}
};
std::for_each(std::begin(BackendList), BackendListEnd, init_backend);
LoopbackBackendFactory::getFactory().init();
if(!PlaybackFactory)
WARN("No playback backend available!\n");
if(!CaptureFactory)
WARN("No capture backend available!\n");
if(auto exclopt = ConfigValueStr(nullptr, nullptr, "excludefx"))
{
const char *next{exclopt->c_str()};
do {
const char *str{next};
next = strchr(str, ',');
if(!str[0] || next == str)
continue;
size_t len{next ? static_cast<size_t>(next-str) : strlen(str)};
for(const EffectList &effectitem : gEffectList)
{
if(len == strlen(effectitem.name) &&
strncmp(effectitem.name, str, len) == 0)
DisabledEffects[effectitem.type] = true;
}
} while(next++);
}
InitEffect(&DefaultEffect);
auto defrevopt = al::getenv("ALSOFT_DEFAULT_REVERB");
if(defrevopt || (defrevopt=ConfigValueStr(nullptr, nullptr, "default-reverb")))
LoadReverbPreset(defrevopt->c_str(), &DefaultEffect);
}
#define DO_INITCONFIG() std::call_once(alc_config_once, [](){alc_initconfig();})
/************************************************
* Device enumeration
************************************************/
void ProbeAllDevicesList()
{
DO_INITCONFIG();
std::lock_guard<std::recursive_mutex> _{ListLock};
if(!PlaybackFactory)
decltype(alcAllDevicesList){}.swap(alcAllDevicesList);
else
{
std::string names{PlaybackFactory->probe(BackendType::Playback)};
if(names.empty()) names += '\0';
names.swap(alcAllDevicesList);
}
}
void ProbeCaptureDeviceList()
{
DO_INITCONFIG();
std::lock_guard<std::recursive_mutex> _{ListLock};
if(!CaptureFactory)
decltype(alcCaptureDeviceList){}.swap(alcCaptureDeviceList);
else
{
std::string names{CaptureFactory->probe(BackendType::Capture)};
if(names.empty()) names += '\0';
names.swap(alcCaptureDeviceList);
}
}
} // namespace
/* Mixing thread piority level */
int RTPrioLevel{1};
FILE *gLogFile{stderr};
#ifdef _DEBUG
LogLevel gLogLevel{LogWarning};
#else
LogLevel gLogLevel{LogError};
#endif
/************************************************
* Library initialization
************************************************/
#if defined(_WIN32) && !defined(AL_LIBTYPE_STATIC)
BOOL APIENTRY DllMain(HINSTANCE module, DWORD reason, LPVOID /*reserved*/)
{
switch(reason)
{
case DLL_PROCESS_ATTACH:
/* Pin the DLL so we won't get unloaded until the process terminates */
GetModuleHandleExW(GET_MODULE_HANDLE_EX_FLAG_PIN | GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS,
reinterpret_cast<WCHAR*>(module), &module);
break;
}
return TRUE;
}
#endif
/************************************************
* Device format information
************************************************/
const ALCchar *DevFmtTypeString(DevFmtType type) noexcept
{
switch(type)
{
case DevFmtByte: return "Int8";
case DevFmtUByte: return "UInt8";
case DevFmtShort: return "Int16";
case DevFmtUShort: return "UInt16";
case DevFmtInt: return "Int32";
case DevFmtUInt: return "UInt32";
case DevFmtFloat: return "Float32";
}
return "(unknown type)";
}
const ALCchar *DevFmtChannelsString(DevFmtChannels chans) noexcept
{
switch(chans)
{
case DevFmtMono: return "Mono";
case DevFmtStereo: return "Stereo";
case DevFmtQuad: return "Quadraphonic";
case DevFmtX51: return "5.1 Surround";
case DevFmtX51Rear: return "5.1 Surround (Rear)";
case DevFmtX61: return "6.1 Surround";
case DevFmtX71: return "7.1 Surround";
case DevFmtAmbi3D: return "Ambisonic 3D";
}
return "(unknown channels)";
}
ALuint BytesFromDevFmt(DevFmtType type) noexcept
{
switch(type)
{
case DevFmtByte: return sizeof(int8_t);
case DevFmtUByte: return sizeof(uint8_t);
case DevFmtShort: return sizeof(int16_t);
case DevFmtUShort: return sizeof(uint16_t);
case DevFmtInt: return sizeof(int32_t);
case DevFmtUInt: return sizeof(uint32_t);
case DevFmtFloat: return sizeof(float);
}
return 0;
}
ALuint ChannelsFromDevFmt(DevFmtChannels chans, ALuint ambiorder) noexcept
{
switch(chans)
{
case DevFmtMono: return 1;
case DevFmtStereo: return 2;
case DevFmtQuad: return 4;
case DevFmtX51: return 6;
case DevFmtX51Rear: return 6;
case DevFmtX61: return 7;
case DevFmtX71: return 8;
case DevFmtAmbi3D: return (ambiorder+1) * (ambiorder+1);
}
return 0;
}
namespace {
struct DevFmtPair { DevFmtChannels chans; DevFmtType type; };
al::optional<DevFmtPair> DecomposeDevFormat(ALenum format)
{
static const struct {
ALenum format;
DevFmtChannels channels;
DevFmtType type;
} list[] = {
{ AL_FORMAT_MONO8, DevFmtMono, DevFmtUByte },
{ AL_FORMAT_MONO16, DevFmtMono, DevFmtShort },
{ AL_FORMAT_MONO_FLOAT32, DevFmtMono, DevFmtFloat },
{ AL_FORMAT_STEREO8, DevFmtStereo, DevFmtUByte },
{ AL_FORMAT_STEREO16, DevFmtStereo, DevFmtShort },
{ AL_FORMAT_STEREO_FLOAT32, DevFmtStereo, DevFmtFloat },
{ AL_FORMAT_QUAD8, DevFmtQuad, DevFmtUByte },
{ AL_FORMAT_QUAD16, DevFmtQuad, DevFmtShort },
{ AL_FORMAT_QUAD32, DevFmtQuad, DevFmtFloat },
{ AL_FORMAT_51CHN8, DevFmtX51, DevFmtUByte },
{ AL_FORMAT_51CHN16, DevFmtX51, DevFmtShort },
{ AL_FORMAT_51CHN32, DevFmtX51, DevFmtFloat },
{ AL_FORMAT_61CHN8, DevFmtX61, DevFmtUByte },
{ AL_FORMAT_61CHN16, DevFmtX61, DevFmtShort },
{ AL_FORMAT_61CHN32, DevFmtX61, DevFmtFloat },
{ AL_FORMAT_71CHN8, DevFmtX71, DevFmtUByte },
{ AL_FORMAT_71CHN16, DevFmtX71, DevFmtShort },
{ AL_FORMAT_71CHN32, DevFmtX71, DevFmtFloat },
};
for(const auto &item : list)
{
if(item.format == format)
return al::make_optional(DevFmtPair{item.channels, item.type});
}
return al::nullopt;
}
bool IsValidALCType(ALCenum type)
{
switch(type)
{
case ALC_BYTE_SOFT:
case ALC_UNSIGNED_BYTE_SOFT:
case ALC_SHORT_SOFT:
case ALC_UNSIGNED_SHORT_SOFT:
case ALC_INT_SOFT:
case ALC_UNSIGNED_INT_SOFT:
case ALC_FLOAT_SOFT:
return true;
}
return false;
}
bool IsValidALCChannels(ALCenum channels)
{
switch(channels)
{
case ALC_MONO_SOFT:
case ALC_STEREO_SOFT:
case ALC_QUAD_SOFT:
case ALC_5POINT1_SOFT:
case ALC_6POINT1_SOFT:
case ALC_7POINT1_SOFT:
case ALC_BFORMAT3D_SOFT:
return true;
}
return false;
}
bool IsValidAmbiLayout(ALCenum layout)
{
switch(layout)
{
case ALC_ACN_SOFT:
case ALC_FUMA_SOFT:
return true;
}
return false;
}
bool IsValidAmbiScaling(ALCenum scaling)
{
switch(scaling)
{
case ALC_N3D_SOFT:
case ALC_SN3D_SOFT:
case ALC_FUMA_SOFT:
return true;
}
return false;
}
/* Downmixing channel arrays, to map the given format's missing channels to
* existing ones. Based on Wine's DSound downmix values, which are based on
* PulseAudio's.
*/
const std::array<InputRemixMap,7> MonoDownmix{{
{ FrontLeft, {{{FrontCenter, 0.5f}, {LFE, 0.0f}}} },
{ FrontRight, {{{FrontCenter, 0.5f}, {LFE, 0.0f}}} },
{ SideLeft, {{{FrontCenter, 0.5f/9.0f}, {LFE, 0.0f}}} },
{ SideRight, {{{FrontCenter, 0.5f/9.0f}, {LFE, 0.0f}}} },
{ BackLeft, {{{FrontCenter, 0.5f/9.0f}, {LFE, 0.0f}}} },
{ BackRight, {{{FrontCenter, 0.5f/9.0f}, {LFE, 0.0f}}} },
{ BackCenter, {{{FrontCenter, 1.0f/9.0f}, {LFE, 0.0f}}} },
}};
const std::array<InputRemixMap,6> StereoDownmix{{
{ FrontCenter, {{{FrontLeft, 0.5f}, {FrontRight, 0.5f}}} },
{ SideLeft, {{{FrontLeft, 1.0f/9.0f}, {FrontRight, 0.0f}}} },
{ SideRight, {{{FrontLeft, 0.0f}, {FrontRight, 1.0f/9.0f}}} },
{ BackLeft, {{{FrontLeft, 1.0f/9.0f}, {FrontRight, 0.0f}}} },
{ BackRight, {{{FrontLeft, 0.0f}, {FrontRight, 1.0f/9.0f}}} },
{ BackCenter, {{{FrontLeft, 0.5f/9.0f}, {FrontRight, 0.5f/9.0f}}} },
}};
const std::array<InputRemixMap,4> QuadDownmix{{
{ FrontCenter, {{{FrontLeft, 0.5f}, {FrontRight, 0.5f}}} },
{ SideLeft, {{{FrontLeft, 0.5f}, {BackLeft, 0.5f}}} },
{ SideRight, {{{FrontRight, 0.5f}, {BackRight, 0.5f}}} },
{ BackCenter, {{{BackLeft, 0.5f}, {BackRight, 0.5f}}} },
}};
const std::array<InputRemixMap,3> X51Downmix{{
{ BackLeft, {{{SideLeft, 1.0f}, {SideRight, 0.0f}}} },
{ BackRight, {{{SideLeft, 0.0f}, {SideRight, 1.0f}}} },
{ BackCenter, {{{SideLeft, 0.5f}, {SideRight, 0.5f}}} },
}};
const std::array<InputRemixMap,3> X51RearDownmix{{
{ SideLeft, {{{BackLeft, 1.0f}, {BackRight, 0.0f}}} },
{ SideRight, {{{BackLeft, 0.0f}, {BackRight, 1.0f}}} },
{ BackCenter, {{{BackLeft, 0.5f}, {BackRight, 0.5f}}} },
}};
const std::array<InputRemixMap,2> X61Downmix{{
{ BackLeft, {{{BackCenter, 0.5f}, {SideLeft, 0.5f}}} },
{ BackRight, {{{BackCenter, 0.5f}, {SideRight, 0.5f}}} },
}};
const std::array<InputRemixMap,1> X71Downmix{{
{ BackCenter, {{{BackLeft, 0.5f}, {BackRight, 0.5f}}} },
}};
} // namespace
/************************************************
* Miscellaneous ALC helpers
************************************************/
void SetDefaultWFXChannelOrder(ALCdevice *device)
{
device->RealOut.ChannelIndex.fill(INVALID_CHANNEL_INDEX);
switch(device->FmtChans)
{
case DevFmtMono:
device->RealOut.ChannelIndex[FrontCenter] = 0;
break;
case DevFmtStereo:
device->RealOut.ChannelIndex[FrontLeft] = 0;
device->RealOut.ChannelIndex[FrontRight] = 1;
break;
case DevFmtQuad:
device->RealOut.ChannelIndex[FrontLeft] = 0;
device->RealOut.ChannelIndex[FrontRight] = 1;
device->RealOut.ChannelIndex[BackLeft] = 2;
device->RealOut.ChannelIndex[BackRight] = 3;
break;
case DevFmtX51:
device->RealOut.ChannelIndex[FrontLeft] = 0;
device->RealOut.ChannelIndex[FrontRight] = 1;
device->RealOut.ChannelIndex[FrontCenter] = 2;
device->RealOut.ChannelIndex[LFE] = 3;
device->RealOut.ChannelIndex[SideLeft] = 4;
device->RealOut.ChannelIndex[SideRight] = 5;
break;
case DevFmtX51Rear:
device->RealOut.ChannelIndex[FrontLeft] = 0;
device->RealOut.ChannelIndex[FrontRight] = 1;
device->RealOut.ChannelIndex[FrontCenter] = 2;
device->RealOut.ChannelIndex[LFE] = 3;
device->RealOut.ChannelIndex[BackLeft] = 4;
device->RealOut.ChannelIndex[BackRight] = 5;
break;
case DevFmtX61:
device->RealOut.ChannelIndex[FrontLeft] = 0;
device->RealOut.ChannelIndex[FrontRight] = 1;
device->RealOut.ChannelIndex[FrontCenter] = 2;
device->RealOut.ChannelIndex[LFE] = 3;
device->RealOut.ChannelIndex[BackCenter] = 4;
device->RealOut.ChannelIndex[SideLeft] = 5;
device->RealOut.ChannelIndex[SideRight] = 6;
break;
case DevFmtX71:
device->RealOut.ChannelIndex[FrontLeft] = 0;
device->RealOut.ChannelIndex[FrontRight] = 1;
device->RealOut.ChannelIndex[FrontCenter] = 2;
device->RealOut.ChannelIndex[LFE] = 3;
device->RealOut.ChannelIndex[BackLeft] = 4;
device->RealOut.ChannelIndex[BackRight] = 5;
device->RealOut.ChannelIndex[SideLeft] = 6;
device->RealOut.ChannelIndex[SideRight] = 7;
break;
case DevFmtAmbi3D:
device->RealOut.ChannelIndex[Aux0] = 0;
if(device->mAmbiOrder > 0)
{
device->RealOut.ChannelIndex[Aux1] = 1;
device->RealOut.ChannelIndex[Aux2] = 2;
device->RealOut.ChannelIndex[Aux3] = 3;
}
if(device->mAmbiOrder > 1)
{
device->RealOut.ChannelIndex[Aux4] = 4;
device->RealOut.ChannelIndex[Aux5] = 5;
device->RealOut.ChannelIndex[Aux6] = 6;
device->RealOut.ChannelIndex[Aux7] = 7;
device->RealOut.ChannelIndex[Aux8] = 8;
}
if(device->mAmbiOrder > 2)
{
device->RealOut.ChannelIndex[Aux9] = 9;
device->RealOut.ChannelIndex[Aux10] = 10;
device->RealOut.ChannelIndex[Aux11] = 11;
device->RealOut.ChannelIndex[Aux12] = 12;
device->RealOut.ChannelIndex[Aux13] = 13;
device->RealOut.ChannelIndex[Aux14] = 14;
device->RealOut.ChannelIndex[Aux15] = 15;
}
break;
}
}
void SetDefaultChannelOrder(ALCdevice *device)
{
device->RealOut.ChannelIndex.fill(INVALID_CHANNEL_INDEX);
switch(device->FmtChans)
{
case DevFmtX51Rear:
device->RealOut.ChannelIndex[FrontLeft] = 0;
device->RealOut.ChannelIndex[FrontRight] = 1;
device->RealOut.ChannelIndex[BackLeft] = 2;
device->RealOut.ChannelIndex[BackRight] = 3;
device->RealOut.ChannelIndex[FrontCenter] = 4;
device->RealOut.ChannelIndex[LFE] = 5;
return;
case DevFmtX71:
device->RealOut.ChannelIndex[FrontLeft] = 0;
device->RealOut.ChannelIndex[FrontRight] = 1;
device->RealOut.ChannelIndex[BackLeft] = 2;
device->RealOut.ChannelIndex[BackRight] = 3;
device->RealOut.ChannelIndex[FrontCenter] = 4;
device->RealOut.ChannelIndex[LFE] = 5;
device->RealOut.ChannelIndex[SideLeft] = 6;
device->RealOut.ChannelIndex[SideRight] = 7;
return;
/* Same as WFX order */
case DevFmtMono:
case DevFmtStereo:
case DevFmtQuad:
case DevFmtX51:
case DevFmtX61:
case DevFmtAmbi3D:
SetDefaultWFXChannelOrder(device);
break;
}
}
void ALCcontext::processUpdates()
{
std::lock_guard<std::mutex> _{mPropLock};
if(mDeferUpdates.exchange(false, std::memory_order_acq_rel))
{
/* Tell the mixer to stop applying updates, then wait for any active
* updating to finish, before providing updates.
*/
mHoldUpdates.store(true, std::memory_order_release);
while((mUpdateCount.load(std::memory_order_acquire)&1) != 0) {
/* busy-wait */
}
if(!mPropsClean.test_and_set(std::memory_order_acq_rel))
UpdateContextProps(this);
if(!mListener.PropsClean.test_and_set(std::memory_order_acq_rel))
UpdateListenerProps(this);
UpdateAllEffectSlotProps(this);
UpdateAllSourceProps(this);
/* Now with all updates declared, let the mixer continue applying them
* so they all happen at once.
*/
mHoldUpdates.store(false, std::memory_order_release);
}
}
void ALCcontext::allocVoiceChanges(size_t addcount)
{
constexpr size_t clustersize{128};
/* Convert element count to cluster count. */
addcount = (addcount+(clustersize-1)) / clustersize;
while(addcount)
{
VoiceChangeCluster cluster{std::make_unique<VoiceChange[]>(clustersize)};
for(size_t i{1};i < clustersize;++i)
cluster[i-1].mNext.store(std::addressof(cluster[i]), std::memory_order_relaxed);
cluster[clustersize-1].mNext.store(mVoiceChangeTail, std::memory_order_relaxed);
mVoiceChangeClusters.emplace_back(std::move(cluster));
mVoiceChangeTail = mVoiceChangeClusters.back().get();
--addcount;
}
}
void ALCcontext::allocVoices(size_t addcount)
{
constexpr size_t clustersize{32};
/* Convert element count to cluster count. */
addcount = (addcount+(clustersize-1)) / clustersize;
if(addcount >= std::numeric_limits<int>::max()/clustersize - mVoiceClusters.size())
throw std::runtime_error{"Allocating too many voices"};
const size_t totalcount{(mVoiceClusters.size()+addcount) * clustersize};
TRACE("Increasing allocated voices to %zu\n", totalcount);
auto newarray = VoiceArray::Create(totalcount);
while(addcount)
{
mVoiceClusters.emplace_back(std::make_unique<Voice[]>(clustersize));
--addcount;
}
auto voice_iter = newarray->begin();
for(VoiceCluster &cluster : mVoiceClusters)
{
for(size_t i{0};i < clustersize;++i)
*(voice_iter++) = &cluster[i];
}
if(auto *oldvoices = mVoices.exchange(newarray.release(), std::memory_order_acq_rel))
{
mDevice->waitForMix();
delete oldvoices;
}
}
/** Stores the latest ALC device error. */
static void alcSetError(ALCdevice *device, ALCenum errorCode)
{
WARN("Error generated on device %p, code 0x%04x\n", decltype(std::declval<void*>()){device},
errorCode);
if(TrapALCError)
{
#ifdef _WIN32
/* DebugBreak() will cause an exception if there is no debugger */
if(IsDebuggerPresent())
DebugBreak();
#elif defined(SIGTRAP)
raise(SIGTRAP);
#endif
}
if(device)
device->LastError.store(errorCode);
else
LastNullDeviceError.store(errorCode);
}
static std::unique_ptr<Compressor> CreateDeviceLimiter(const ALCdevice *device, const float threshold)
{
constexpr bool AutoKnee{true};
constexpr bool AutoAttack{true};
constexpr bool AutoRelease{true};
constexpr bool AutoPostGain{true};
constexpr bool AutoDeclip{true};
constexpr float LookAheadTime{0.001f};
constexpr float HoldTime{0.002f};
constexpr float PreGainDb{0.0f};
constexpr float PostGainDb{0.0f};
constexpr float Ratio{std::numeric_limits<float>::infinity()};
constexpr float KneeDb{0.0f};
constexpr float AttackTime{0.02f};
constexpr float ReleaseTime{0.2f};
return Compressor::Create(device->RealOut.Buffer.size(), static_cast<float>(device->Frequency),
AutoKnee, AutoAttack, AutoRelease, AutoPostGain, AutoDeclip, LookAheadTime, HoldTime,
PreGainDb, PostGainDb, threshold, Ratio, KneeDb, AttackTime, ReleaseTime);
}
/**
* Updates the device's base clock time with however many samples have been
* done. This is used so frequency changes on the device don't cause the time
* to jump forward or back. Must not be called while the device is running/
* mixing.
*/
static inline void UpdateClockBase(ALCdevice *device)
{
IncrementRef(device->MixCount);
device->ClockBase += nanoseconds{seconds{device->SamplesDone}} / device->Frequency;
device->SamplesDone = 0;
IncrementRef(device->MixCount);
}
/**
* Updates device parameters according to the attribute list (caller is
* responsible for holding the list lock).
*/
static ALCenum UpdateDeviceParams(ALCdevice *device, const int *attrList)
{
HrtfRequestMode hrtf_userreq{Hrtf_Default};
HrtfRequestMode hrtf_appreq{Hrtf_Default};
ALCenum gainLimiter{device->LimiterState};
ALCuint new_sends{device->NumAuxSends};
DevFmtChannels oldChans;
DevFmtType oldType;
ALCsizei hrtf_id{-1};
ALCuint oldFreq;
if((!attrList || !attrList[0]) && device->Type == Loopback)
{
WARN("Missing attributes for loopback device\n");
return ALC_INVALID_VALUE;
}
// Check for attributes
if(attrList && attrList[0])
{
ALCenum alayout{AL_NONE};
ALCenum ascale{AL_NONE};
ALCenum schans{AL_NONE};
ALCenum stype{AL_NONE};
ALCsizei attrIdx{0};
ALCuint aorder{0};
ALCuint freq{0u};
ALuint numMono{device->NumMonoSources};
ALuint numStereo{device->NumStereoSources};
ALuint numSends{device->NumAuxSends};
#define TRACE_ATTR(a, v) TRACE("%s = %d\n", #a, v)
while(attrList[attrIdx])
{
switch(attrList[attrIdx])
{
case ALC_FORMAT_CHANNELS_SOFT:
schans = attrList[attrIdx + 1];
TRACE_ATTR(ALC_FORMAT_CHANNELS_SOFT, schans);
break;
case ALC_FORMAT_TYPE_SOFT:
stype = attrList[attrIdx + 1];
TRACE_ATTR(ALC_FORMAT_TYPE_SOFT, stype);
break;
case ALC_FREQUENCY:
freq = static_cast<ALuint>(attrList[attrIdx + 1]);
TRACE_ATTR(ALC_FREQUENCY, freq);
break;
case ALC_AMBISONIC_LAYOUT_SOFT:
alayout = attrList[attrIdx + 1];
TRACE_ATTR(ALC_AMBISONIC_LAYOUT_SOFT, alayout);
break;
case ALC_AMBISONIC_SCALING_SOFT:
ascale = attrList[attrIdx + 1];
TRACE_ATTR(ALC_AMBISONIC_SCALING_SOFT, ascale);
break;
case ALC_AMBISONIC_ORDER_SOFT:
aorder = static_cast<ALuint>(attrList[attrIdx + 1]);
TRACE_ATTR(ALC_AMBISONIC_ORDER_SOFT, aorder);
break;
case ALC_MONO_SOURCES:
numMono = static_cast<ALuint>(attrList[attrIdx + 1]);
TRACE_ATTR(ALC_MONO_SOURCES, numMono);
if(numMono > INT_MAX) numMono = 0;
break;
case ALC_STEREO_SOURCES:
numStereo = static_cast<ALuint>(attrList[attrIdx + 1]);
TRACE_ATTR(ALC_STEREO_SOURCES, numStereo);
if(numStereo > INT_MAX) numStereo = 0;
break;
case ALC_MAX_AUXILIARY_SENDS:
numSends = static_cast<ALuint>(attrList[attrIdx + 1]);
TRACE_ATTR(ALC_MAX_AUXILIARY_SENDS, numSends);
if(numSends > INT_MAX) numSends = 0;
else numSends = minu(numSends, MAX_SENDS);
break;
case ALC_HRTF_SOFT:
TRACE_ATTR(ALC_HRTF_SOFT, attrList[attrIdx + 1]);
if(attrList[attrIdx + 1] == ALC_FALSE)
hrtf_appreq = Hrtf_Disable;
else if(attrList[attrIdx + 1] == ALC_TRUE)
hrtf_appreq = Hrtf_Enable;
else
hrtf_appreq = Hrtf_Default;
break;
case ALC_HRTF_ID_SOFT:
hrtf_id = attrList[attrIdx + 1];
TRACE_ATTR(ALC_HRTF_ID_SOFT, hrtf_id);
break;
case ALC_OUTPUT_LIMITER_SOFT:
gainLimiter = attrList[attrIdx + 1];
TRACE_ATTR(ALC_OUTPUT_LIMITER_SOFT, gainLimiter);
break;
default:
TRACE("0x%04X = %d (0x%x)\n", attrList[attrIdx],
attrList[attrIdx + 1], attrList[attrIdx + 1]);
break;
}
attrIdx += 2;
}
#undef TRACE_ATTR
const bool loopback{device->Type == Loopback};
if(loopback)
{
if(!schans || !stype || !freq)
{
WARN("Missing format for loopback device\n");
return ALC_INVALID_VALUE;
}
if(!IsValidALCChannels(schans) || !IsValidALCType(stype) || freq < MIN_OUTPUT_RATE
|| freq > MAX_OUTPUT_RATE)
return ALC_INVALID_VALUE;
if(schans == ALC_BFORMAT3D_SOFT)
{
if(!alayout || !ascale || !aorder)
{
WARN("Missing ambisonic info for loopback device\n");
return ALC_INVALID_VALUE;
}
if(!IsValidAmbiLayout(alayout) || !IsValidAmbiScaling(ascale))
return ALC_INVALID_VALUE;
if(aorder < 1 || aorder > MAX_AMBI_ORDER)
return ALC_INVALID_VALUE;
if((alayout == ALC_FUMA_SOFT || ascale == ALC_FUMA_SOFT) && aorder > 3)
return ALC_INVALID_VALUE;
}
}
/* If a context is already running on the device, stop playback so the
* device attributes can be updated.
*/
if(device->Flags.get<DeviceRunning>())
device->Backend->stop();
device->Flags.unset<DeviceRunning>();
UpdateClockBase(device);
const char *devname{nullptr};
if(!loopback)
{
devname = device->DeviceName.c_str();
device->BufferSize = DEFAULT_UPDATE_SIZE * DEFAULT_NUM_UPDATES;
device->UpdateSize = DEFAULT_UPDATE_SIZE;
device->Frequency = DEFAULT_OUTPUT_RATE;
freq = ConfigValueUInt(devname, nullptr, "frequency").value_or(freq);
if(freq < 1)
device->Flags.unset<FrequencyRequest>();
else
{
freq = clampu(freq, MIN_OUTPUT_RATE, MAX_OUTPUT_RATE);
const double scale{static_cast<double>(freq) / device->Frequency};
device->UpdateSize = static_cast<ALuint>(device->UpdateSize*scale + 0.5);
device->BufferSize = static_cast<ALuint>(device->BufferSize*scale + 0.5);
device->Frequency = freq;
device->Flags.set<FrequencyRequest>();
}
if(auto persizeopt = ConfigValueUInt(devname, nullptr, "period_size"))
device->UpdateSize = clampu(*persizeopt, 64, 8192);
if(auto peropt = ConfigValueUInt(devname, nullptr, "periods"))
device->BufferSize = device->UpdateSize * clampu(*peropt, 2, 16);
else
device->BufferSize = maxu(device->BufferSize, device->UpdateSize*2);
}
else
{
device->Frequency = freq;
device->FmtChans = static_cast<DevFmtChannels>(schans);
device->FmtType = static_cast<DevFmtType>(stype);
if(schans == ALC_BFORMAT3D_SOFT)
{
device->mAmbiOrder = aorder;
device->mAmbiLayout = static_cast<AmbiLayout>(alayout);
device->mAmbiScale = static_cast<AmbiNorm>(ascale);
}
}
if(numMono > INT_MAX-numStereo)
numMono = INT_MAX-numStereo;
numMono += numStereo;
if(auto srcsopt = ConfigValueUInt(devname, nullptr, "sources"))
{
if(*srcsopt <= 0) numMono = 256;
else numMono = *srcsopt;
}
else
numMono = maxu(numMono, 256);
numStereo = minu(numStereo, numMono);
numMono -= numStereo;
device->SourcesMax = numMono + numStereo;
device->NumMonoSources = numMono;
device->NumStereoSources = numStereo;
if(auto sendsopt = ConfigValueInt(devname, nullptr, "sends"))
new_sends = minu(numSends, static_cast<ALuint>(clampi(*sendsopt, 0, MAX_SENDS)));
else
new_sends = numSends;
}
if(device->Flags.get<DeviceRunning>())
return ALC_NO_ERROR;
device->AvgSpeakerDist = 0.0f;
device->Uhj_Encoder = nullptr;
device->AmbiDecoder = nullptr;
device->Bs2b = nullptr;
device->PostProcess = nullptr;
device->Stablizer = nullptr;
device->Limiter = nullptr;
device->ChannelDelay.clear();
std::fill(std::begin(device->HrtfAccumData), std::end(device->HrtfAccumData), float2{});
device->Dry.AmbiMap.fill(BFChannelConfig{});
device->Dry.Buffer = {};
std::fill(std::begin(device->NumChannelsPerOrder), std::end(device->NumChannelsPerOrder), 0u);
device->RealOut.RemixMap = {};
device->RealOut.ChannelIndex.fill(INVALID_CHANNEL_INDEX);
device->RealOut.Buffer = {};
device->MixBuffer.clear();
device->MixBuffer.shrink_to_fit();
UpdateClockBase(device);
device->FixedLatency = nanoseconds::zero();
device->DitherDepth = 0.0f;
device->DitherSeed = DitherRNGSeed;
/*************************************************************************
* Update device format request if HRTF is requested
*/
device->HrtfStatus = ALC_HRTF_DISABLED_SOFT;
if(device->Type != Loopback)
{
if(auto hrtfopt = ConfigValueStr(device->DeviceName.c_str(), nullptr, "hrtf"))
{
const char *hrtf{hrtfopt->c_str()};
if(al::strcasecmp(hrtf, "true") == 0)
hrtf_userreq = Hrtf_Enable;
else if(al::strcasecmp(hrtf, "false") == 0)
hrtf_userreq = Hrtf_Disable;
else if(al::strcasecmp(hrtf, "auto") != 0)
ERR("Unexpected hrtf value: %s\n", hrtf);
}
if(hrtf_userreq == Hrtf_Enable || (hrtf_userreq != Hrtf_Disable && hrtf_appreq == Hrtf_Enable))
{
device->FmtChans = DevFmtStereo;
device->Flags.set<ChannelsRequest>();
}
}
oldFreq = device->Frequency;
oldChans = device->FmtChans;
oldType = device->FmtType;
TRACE("Pre-reset: %s%s, %s%s, %s%uhz, %u / %u buffer\n",
device->Flags.get<ChannelsRequest>()?"*":"", DevFmtChannelsString(device->FmtChans),
device->Flags.get<SampleTypeRequest>()?"*":"", DevFmtTypeString(device->FmtType),
device->Flags.get<FrequencyRequest>()?"*":"", device->Frequency,
device->UpdateSize, device->BufferSize);
try {
auto backend = device->Backend.get();
if(!backend->reset())
throw al::backend_exception{ALC_INVALID_DEVICE, "Device reset failure"};
}
catch(std::exception &e) {
aluHandleDisconnect(device, "%s", e.what());
return ALC_INVALID_DEVICE;
}
if(device->FmtChans != oldChans && device->Flags.get<ChannelsRequest>())
{
ERR("Failed to set %s, got %s instead\n", DevFmtChannelsString(oldChans),
DevFmtChannelsString(device->FmtChans));
device->Flags.unset<ChannelsRequest>();
}
if(device->FmtType != oldType && device->Flags.get<SampleTypeRequest>())
{
ERR("Failed to set %s, got %s instead\n", DevFmtTypeString(oldType),
DevFmtTypeString(device->FmtType));
device->Flags.unset<SampleTypeRequest>();
}
if(device->Frequency != oldFreq && device->Flags.get<FrequencyRequest>())
{
WARN("Failed to set %uhz, got %uhz instead\n", oldFreq, device->Frequency);
device->Flags.unset<FrequencyRequest>();
}
TRACE("Post-reset: %s, %s, %uhz, %u / %u buffer\n",
DevFmtChannelsString(device->FmtChans), DevFmtTypeString(device->FmtType),
device->Frequency, device->UpdateSize, device->BufferSize);
switch(device->FmtChans)
{
case DevFmtMono: device->RealOut.RemixMap = MonoDownmix; break;
case DevFmtStereo: device->RealOut.RemixMap = StereoDownmix; break;
case DevFmtQuad: device->RealOut.RemixMap = QuadDownmix; break;
case DevFmtX51: device->RealOut.RemixMap = X51Downmix; break;
case DevFmtX51Rear: device->RealOut.RemixMap = X51RearDownmix; break;
case DevFmtX61: device->RealOut.RemixMap = X61Downmix; break;
case DevFmtX71: device->RealOut.RemixMap = X71Downmix; break;
case DevFmtAmbi3D: break;
}
aluInitRenderer(device, hrtf_id, hrtf_appreq, hrtf_userreq);
device->NumAuxSends = new_sends;
TRACE("Max sources: %d (%d + %d), effect slots: %d, sends: %d\n",
device->SourcesMax, device->NumMonoSources, device->NumStereoSources,
device->AuxiliaryEffectSlotMax, device->NumAuxSends);
if(device->Uhj_Encoder)
{
/* NOTE: Don't know why this has to be "copied" into a local constexpr
* variable to avoid a reference on Uhj2Encoder::sFilterSize...
*/
constexpr size_t filter_len{Uhj2Encoder::sFilterSize};
device->FixedLatency += nanoseconds{seconds{filter_len}} / device->Frequency;
}
if(device->mHrtfState)
device->FixedLatency += nanoseconds{seconds{HRTF_DIRECT_DELAY}} / device->Frequency;
/* Enable the stablizer only for formats that have front-left, front-right,
* and front-center outputs.
*/
switch(device->FmtChans)
{
case DevFmtX51:
case DevFmtX51Rear:
case DevFmtX61:
case DevFmtX71:
if(GetConfigValueBool(device->DeviceName.c_str(), nullptr, "front-stablizer", 0))
{
auto stablizer = FrontStablizer::Create(device->channelsFromFmt());
for(auto &buf : stablizer->DelayBuf)
std::fill(buf.begin(), buf.end(), 0.0f);
/* Initialize band-splitting filter for the mid signal, with a
* crossover at 5khz (could be higher).
*/
stablizer->MidFilter.init(5000.0f / static_cast<float>(device->Frequency));
device->Stablizer = std::move(stablizer);
constexpr size_t StablizerDelay{FrontStablizer::DelayLength};
device->FixedLatency += nanoseconds{seconds{StablizerDelay}} / device->Frequency;
}
break;
case DevFmtMono:
case DevFmtStereo:
case DevFmtQuad:
case DevFmtAmbi3D:
break;
}
TRACE("Front stablizer %s\n", device->Stablizer ? "enabled" : "disabled");
if(GetConfigValueBool(device->DeviceName.c_str(), nullptr, "dither", 1))
{
int depth{ConfigValueInt(device->DeviceName.c_str(), nullptr, "dither-depth").value_or(0)};
if(depth <= 0)
{
switch(device->FmtType)
{
case DevFmtByte:
case DevFmtUByte:
depth = 8;
break;
case DevFmtShort:
case DevFmtUShort:
depth = 16;
break;
case DevFmtInt:
case DevFmtUInt:
case DevFmtFloat:
break;
}
}
if(depth > 0)
{
depth = clampi(depth, 2, 24);
device->DitherDepth = std::pow(2.0f, static_cast<float>(depth-1));
}
}
if(!(device->DitherDepth > 0.0f))
TRACE("Dithering disabled\n");
else
TRACE("Dithering enabled (%d-bit, %g)\n", float2int(std::log2(device->DitherDepth)+0.5f)+1,
device->DitherDepth);
device->LimiterState = gainLimiter;
if(auto limopt = ConfigValueBool(device->DeviceName.c_str(), nullptr, "output-limiter"))
gainLimiter = *limopt ? ALC_TRUE : ALC_FALSE;
/* Valid values for gainLimiter are ALC_DONT_CARE_SOFT, ALC_TRUE, and
* ALC_FALSE. For ALC_DONT_CARE_SOFT, use the limiter for integer-based
* output (where samples must be clamped), and don't for floating-point
* (which can take unclamped samples).
*/
if(gainLimiter == ALC_DONT_CARE_SOFT)
{
switch(device->FmtType)
{
case DevFmtByte:
case DevFmtUByte:
case DevFmtShort:
case DevFmtUShort:
case DevFmtInt:
case DevFmtUInt:
gainLimiter = ALC_TRUE;
break;
case DevFmtFloat:
gainLimiter = ALC_FALSE;
break;
}
}
if(gainLimiter == ALC_FALSE)
TRACE("Output limiter disabled\n");
else
{
float thrshld{1.0f};
switch(device->FmtType)
{
case DevFmtByte:
case DevFmtUByte:
thrshld = 127.0f / 128.0f;
break;
case DevFmtShort:
case DevFmtUShort:
thrshld = 32767.0f / 32768.0f;
break;
case DevFmtInt:
case DevFmtUInt:
case DevFmtFloat:
break;
}
if(device->DitherDepth > 0.0f)
thrshld -= 1.0f / device->DitherDepth;
const float thrshld_dB{std::log10(thrshld) * 20.0f};
auto limiter = CreateDeviceLimiter(device, thrshld_dB);
/* Convert the lookahead from samples to nanosamples to nanoseconds. */
device->FixedLatency += nanoseconds{seconds{limiter->getLookAhead()}} / device->Frequency;
device->Limiter = std::move(limiter);
TRACE("Output limiter enabled, %.4fdB limit\n", thrshld_dB);
}
TRACE("Fixed device latency: %" PRId64 "ns\n", int64_t{device->FixedLatency.count()});
FPUCtl mixer_mode{};
for(ALCcontext *context : *device->mContexts.load())
{
if(ALeffectslot *slot{context->mDefaultSlot.get()})
{
aluInitEffectPanning(slot, device);
EffectState *state{slot->Effect.State};
state->mOutTarget = device->Dry.Buffer;
state->deviceUpdate(device);
slot->updateProps(context);
}
std::unique_lock<std::mutex> proplock{context->mPropLock};
std::unique_lock<std::mutex> slotlock{context->mEffectSlotLock};
if(ALeffectslotArray *curarray{context->mActiveAuxSlots.load(std::memory_order_relaxed)})
std::fill_n(curarray->end(), curarray->size(), nullptr);
for(auto &sublist : context->mEffectSlotList)
{
uint64_t usemask{~sublist.FreeMask};
while(usemask)
{
ALsizei idx{CTZ64(usemask)};
ALeffectslot *slot{sublist.EffectSlots + idx};
usemask &= ~(1_u64 << idx);
aluInitEffectPanning(slot, device);
EffectState *state{slot->Effect.State};
state->mOutTarget = device->Dry.Buffer;
state->deviceUpdate(device);
slot->updateProps(context);
}
}
slotlock.unlock();
const ALuint num_sends{device->NumAuxSends};
std::unique_lock<std::mutex> srclock{context->mSourceLock};
for(auto &sublist : context->mSourceList)
{
uint64_t usemask{~sublist.FreeMask};
while(usemask)
{
ALsizei idx{CTZ64(usemask)};
ALsource *source{sublist.Sources + idx};
usemask &= ~(1_u64 << idx);
auto clear_send = [](ALsource::SendData &send) -> void
{
if(send.Slot)
DecrementRef(send.Slot->ref);
send.Slot = nullptr;
send.Gain = 1.0f;
send.GainHF = 1.0f;
send.HFReference = LOWPASSFREQREF;
send.GainLF = 1.0f;
send.LFReference = HIGHPASSFREQREF;
};
auto send_begin = source->Send.begin() + static_cast<ptrdiff_t>(num_sends);
std::for_each(send_begin, source->Send.end(), clear_send);
source->PropsClean.clear(std::memory_order_release);
}
}
/* Clear any pre-existing voice property structs, in case the number of
* auxiliary sends is changing. Active sources will have updates
* respecified in UpdateAllSourceProps.
*/
VoicePropsItem *vprops{context->mFreeVoiceProps.exchange(nullptr, std::memory_order_acq_rel)};
while(vprops)
{
VoicePropsItem *next = vprops->next.load(std::memory_order_relaxed);
delete vprops;
vprops = next;
}
auto voicelist = context->getVoicesSpan();
for(Voice *voice : voicelist)
{
/* Clear extraneous property set sends. */
std::fill(std::begin(voice->mProps.Send)+num_sends, std::end(voice->mProps.Send),
VoiceProps::SendData{});
std::fill(voice->mSend.begin()+num_sends, voice->mSend.end(), Voice::TargetData{});
for(auto &chandata : voice->mChans)
{
std::fill(chandata.mWetParams.begin()+num_sends, chandata.mWetParams.end(),
SendParams{});
}
delete voice->mUpdate.exchange(nullptr, std::memory_order_acq_rel);
/* Force the voice to stopped if it was stopping. */
Voice::State vstate{Voice::Stopping};
voice->mPlayState.compare_exchange_strong(vstate, Voice::Stopped,
std::memory_order_acquire, std::memory_order_acquire);
if(voice->mSourceID.load(std::memory_order_relaxed) == 0u)
continue;
voice->mStep = 0;
voice->mFlags |= VOICE_IS_FADING;
if(voice->mAmbiOrder && device->mAmbiOrder > voice->mAmbiOrder)
{
const uint8_t *OrderFromChan{(voice->mFmtChannels == FmtBFormat2D) ?
AmbiIndex::OrderFrom2DChannel.data() :
AmbiIndex::OrderFromChannel.data()};
const BandSplitter splitter{400.0f / static_cast<float>(device->Frequency)};
const auto scales = BFormatDec::GetHFOrderScales(voice->mAmbiOrder,
device->mAmbiOrder);
for(auto &chandata : voice->mChans)
{
chandata.mPrevSamples.fill(0.0f);
chandata.mAmbiScale = scales[*(OrderFromChan++)];
chandata.mAmbiSplitter = splitter;
chandata.mDryParams = DirectParams{};
std::fill_n(chandata.mWetParams.begin(), num_sends, SendParams{});
}
voice->mFlags |= VOICE_IS_AMBISONIC;
}
else
{
/* Clear previous samples. */
for(auto &chandata : voice->mChans)
{
chandata.mPrevSamples.fill(0.0f);
chandata.mDryParams = DirectParams{};
std::fill_n(chandata.mWetParams.begin(), num_sends, SendParams{});
}
voice->mFlags &= ~VOICE_IS_AMBISONIC;
}
if(device->AvgSpeakerDist > 0.0f)
{
/* Reinitialize the NFC filters for new parameters. */
const float w1{SPEEDOFSOUNDMETRESPERSEC /
(device->AvgSpeakerDist * static_cast<float>(device->Frequency))};
for(auto &chandata : voice->mChans)
chandata.mDryParams.NFCtrlFilter.init(w1);
}
}
srclock.unlock();
context->mPropsClean.test_and_set(std::memory_order_release);
UpdateContextProps(context);
context->mListener.PropsClean.test_and_set(std::memory_order_release);
UpdateListenerProps(context);
UpdateAllSourceProps(context);
}
mixer_mode.leave();
if(!device->Flags.get<DevicePaused>())
{
try {
auto backend = device->Backend.get();
backend->start();
device->Flags.set<DeviceRunning>();
}
catch(al::backend_exception& e) {
aluHandleDisconnect(device, "%s", e.what());
return ALC_INVALID_DEVICE;
}
}
return ALC_NO_ERROR;
}
ALCdevice::ALCdevice(DeviceType type) : Type{type}, mContexts{&EmptyContextArray}
{
}
ALCdevice::~ALCdevice()
{
TRACE("Freeing device %p\n", decltype(std::declval<void*>()){this});
Backend = nullptr;
size_t count{std::accumulate(BufferList.cbegin(), BufferList.cend(), size_t{0u},
[](size_t cur, const BufferSubList &sublist) noexcept -> size_t
{ return cur + static_cast<ALuint>(POPCNT64(~sublist.FreeMask)); }
)};
if(count > 0)
WARN("%zu Buffer%s not deleted\n", count, (count==1)?"":"s");
count = std::accumulate(EffectList.cbegin(), EffectList.cend(), size_t{0u},
[](size_t cur, const EffectSubList &sublist) noexcept -> size_t
{ return cur + static_cast<ALuint>(POPCNT64(~sublist.FreeMask)); }
);
if(count > 0)
WARN("%zu Effect%s not deleted\n", count, (count==1)?"":"s");
count = std::accumulate(FilterList.cbegin(), FilterList.cend(), size_t{0u},
[](size_t cur, const FilterSubList &sublist) noexcept -> size_t
{ return cur + static_cast<ALuint>(POPCNT64(~sublist.FreeMask)); }
);
if(count > 0)
WARN("%zu Filter%s not deleted\n", count, (count==1)?"":"s");
mHrtf = nullptr;
auto *oldarray = mContexts.exchange(nullptr, std::memory_order_relaxed);
if(oldarray != &EmptyContextArray) delete oldarray;
}
/** Checks if the device handle is valid, and returns a new reference if so. */
static DeviceRef VerifyDevice(ALCdevice *device)
{
std::lock_guard<std::recursive_mutex> _{ListLock};
auto iter = std::lower_bound(DeviceList.begin(), DeviceList.end(), device);
if(iter != DeviceList.end() && *iter == device)
{
(*iter)->add_ref();
return DeviceRef{*iter};
}
return nullptr;
}
ALCcontext::ALCcontext(al::intrusive_ptr<ALCdevice> device) : mDevice{std::move(device)}
{
mPropsClean.test_and_set(std::memory_order_relaxed);
}
ALCcontext::~ALCcontext()
{
TRACE("Freeing context %p\n", decltype(std::declval<void*>()){this});
size_t count{0};
ALcontextProps *cprops{mUpdate.exchange(nullptr, std::memory_order_relaxed)};
if(cprops)
{
++count;
delete cprops;
}
cprops = mFreeContextProps.exchange(nullptr, std::memory_order_acquire);
while(cprops)
{
ALcontextProps *next{cprops->next.load(std::memory_order_relaxed)};
delete cprops;
cprops = next;
++count;
}
TRACE("Freed %zu context property object%s\n", count, (count==1)?"":"s");
count = std::accumulate(mSourceList.cbegin(), mSourceList.cend(), size_t{0u},
[](size_t cur, const SourceSubList &sublist) noexcept -> size_t
{ return cur + static_cast<ALuint>(POPCNT64(~sublist.FreeMask)); }
);
if(count > 0)
WARN("%zu Source%s not deleted\n", count, (count==1)?"":"s");
mSourceList.clear();
mNumSources = 0;
count = 0;
ALeffectslotProps *eprops{mFreeEffectslotProps.exchange(nullptr, std::memory_order_acquire)};
while(eprops)
{
ALeffectslotProps *next{eprops->next.load(std::memory_order_relaxed)};
if(eprops->State) eprops->State->release();
delete eprops;
eprops = next;
++count;
}
TRACE("Freed %zu AuxiliaryEffectSlot property object%s\n", count, (count==1)?"":"s");
if(ALeffectslotArray *curarray{mActiveAuxSlots.exchange(nullptr, std::memory_order_relaxed)})
{
al::destroy_n(curarray->end(), curarray->size());
delete curarray;
}
mDefaultSlot = nullptr;
count = std::accumulate(mEffectSlotList.cbegin(), mEffectSlotList.cend(), size_t{0u},
[](size_t cur, const EffectSlotSubList &sublist) noexcept -> size_t
{ return cur + static_cast<ALuint>(POPCNT64(~sublist.FreeMask)); }
);
if(count > 0)
WARN("%zu AuxiliaryEffectSlot%s not deleted\n", count, (count==1)?"":"s");
mEffectSlotList.clear();
mNumEffectSlots = 0;
count = 0;
VoicePropsItem *vprops{mFreeVoiceProps.exchange(nullptr, std::memory_order_acquire)};
while(vprops)
{
VoicePropsItem *next{vprops->next.load(std::memory_order_relaxed)};
delete vprops;
vprops = next;
++count;
}
TRACE("Freed %zu voice property object%s\n", count, (count==1)?"":"s");
delete mVoices.exchange(nullptr, std::memory_order_relaxed);
count = 0;
ALlistenerProps *lprops{mListener.Params.Update.exchange(nullptr, std::memory_order_relaxed)};
if(lprops)
{
++count;
delete lprops;
}
lprops = mFreeListenerProps.exchange(nullptr, std::memory_order_acquire);
while(lprops)
{
ALlistenerProps *next{lprops->next.load(std::memory_order_relaxed)};
delete lprops;
lprops = next;
++count;
}
TRACE("Freed %zu listener property object%s\n", count, (count==1)?"":"s");
if(mAsyncEvents)
{
count = 0;
auto evt_vec = mAsyncEvents->getReadVector();
if(evt_vec.first.len > 0)
{
al::destroy_n(reinterpret_cast<AsyncEvent*>(evt_vec.first.buf), evt_vec.first.len);
count += evt_vec.first.len;
}
if(evt_vec.second.len > 0)
{
al::destroy_n(reinterpret_cast<AsyncEvent*>(evt_vec.second.buf), evt_vec.second.len);
count += evt_vec.second.len;
}
if(count > 0)
TRACE("Destructed %zu orphaned event%s\n", count, (count==1)?"":"s");
mAsyncEvents->readAdvance(count);
}
}
void ALCcontext::init()
{
if(DefaultEffect.type != AL_EFFECT_NULL && mDevice->Type == Playback)
{
mDefaultSlot = std::unique_ptr<ALeffectslot>{new ALeffectslot{}};
if(mDefaultSlot->init() == AL_NO_ERROR)
aluInitEffectPanning(mDefaultSlot.get(), mDevice.get());
else
{
mDefaultSlot = nullptr;
ERR("Failed to initialize the default effect slot\n");
}
}
ALeffectslotArray *auxslots;
if(!mDefaultSlot)
auxslots = ALeffectslot::CreatePtrArray(0);
else
{
auxslots = ALeffectslot::CreatePtrArray(1);
(*auxslots)[0] = mDefaultSlot.get();
}
mActiveAuxSlots.store(auxslots, std::memory_order_relaxed);
allocVoiceChanges(1);
{
VoiceChange *cur{mVoiceChangeTail};
while(VoiceChange *next{cur->mNext.load(std::memory_order_relaxed)})
cur = next;
mCurrentVoiceChange.store(cur, std::memory_order_relaxed);
}
mExtensionList = alExtList;
mListener.Params.Matrix = alu::Matrix::Identity();
mListener.Params.Velocity = alu::Vector{};
mListener.Params.Gain = mListener.Gain;
mListener.Params.MetersPerUnit = mListener.mMetersPerUnit;
mListener.Params.DopplerFactor = mDopplerFactor;
mListener.Params.SpeedOfSound = mSpeedOfSound * mDopplerVelocity;
mListener.Params.SourceDistanceModel = mSourceDistanceModel;
mListener.Params.mDistanceModel = mDistanceModel;
mAsyncEvents = RingBuffer::Create(511, sizeof(AsyncEvent), false);
StartEventThrd(this);
allocVoices(256);
mActiveVoiceCount.store(64, std::memory_order_relaxed);
}
bool ALCcontext::deinit()
{
if(LocalContext == this)
{
WARN("%p released while current on thread\n", decltype(std::declval<void*>()){this});
ThreadContext.set(nullptr);
release();
}
ALCcontext *origctx{this};
if(GlobalContext.compare_exchange_strong(origctx, nullptr))
release();
bool ret{};
/* First make sure this context exists in the device's list. */
auto *oldarray = mDevice->mContexts.load(std::memory_order_acquire);
if(auto toremove = static_cast<size_t>(std::count(oldarray->begin(), oldarray->end(), this)))
{
using ContextArray = al::FlexArray<ALCcontext*>;
auto alloc_ctx_array = [](const size_t count) -> ContextArray*
{
if(count == 0) return &EmptyContextArray;
return ContextArray::Create(count).release();
};
auto *newarray = alloc_ctx_array(oldarray->size() - toremove);
/* Copy the current/old context handles to the new array, excluding the
* given context.
*/
std::copy_if(oldarray->begin(), oldarray->end(), newarray->begin(),
std::bind(std::not_equal_to<ALCcontext*>{}, _1, this));
/* Store the new context array in the device. Wait for any current mix
* to finish before deleting the old array.
*/
mDevice->mContexts.store(newarray);
if(oldarray != &EmptyContextArray)
{
mDevice->waitForMix();
delete oldarray;
}
ret = !newarray->empty();
}
else
ret = !oldarray->empty();
StopEventThrd(this);
return ret;
}
/**
* Checks if the given context is valid, returning a new reference to it if so.
*/
static ContextRef VerifyContext(ALCcontext *context)
{
std::lock_guard<std::recursive_mutex> _{ListLock};
auto iter = std::lower_bound(ContextList.begin(), ContextList.end(), context);
if(iter != ContextList.end() && *iter == context)
{
(*iter)->add_ref();
return ContextRef{*iter};
}
return nullptr;
}
/** Returns a new reference to the currently active context for this thread. */
ContextRef GetContextRef(void)
{
ALCcontext *context{LocalContext};
if(context)
context->add_ref();
else
{
std::lock_guard<std::recursive_mutex> _{ListLock};
context = GlobalContext.load(std::memory_order_acquire);
if(context) context->add_ref();
}
return ContextRef{context};
}
/************************************************
* Standard ALC functions
************************************************/
ALC_API ALCenum ALC_APIENTRY alcGetError(ALCdevice *device)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(dev) return dev->LastError.exchange(ALC_NO_ERROR);
return LastNullDeviceError.exchange(ALC_NO_ERROR);
}
END_API_FUNC
ALC_API void ALC_APIENTRY alcSuspendContext(ALCcontext *context)
START_API_FUNC
{
if(!SuspendDefers)
return;
ContextRef ctx{VerifyContext(context)};
if(!ctx)
alcSetError(nullptr, ALC_INVALID_CONTEXT);
else
ctx->deferUpdates();
}
END_API_FUNC
ALC_API void ALC_APIENTRY alcProcessContext(ALCcontext *context)
START_API_FUNC
{
if(!SuspendDefers)
return;
ContextRef ctx{VerifyContext(context)};
if(!ctx)
alcSetError(nullptr, ALC_INVALID_CONTEXT);
else
ctx->processUpdates();
}
END_API_FUNC
ALC_API const ALCchar* ALC_APIENTRY alcGetString(ALCdevice *Device, ALCenum param)
START_API_FUNC
{
const ALCchar *value{nullptr};
switch(param)
{
case ALC_NO_ERROR:
value = alcNoError;
break;
case ALC_INVALID_ENUM:
value = alcErrInvalidEnum;
break;
case ALC_INVALID_VALUE:
value = alcErrInvalidValue;
break;
case ALC_INVALID_DEVICE:
value = alcErrInvalidDevice;
break;
case ALC_INVALID_CONTEXT:
value = alcErrInvalidContext;
break;
case ALC_OUT_OF_MEMORY:
value = alcErrOutOfMemory;
break;
case ALC_DEVICE_SPECIFIER:
value = alcDefaultName;
break;
case ALC_ALL_DEVICES_SPECIFIER:
if(DeviceRef dev{VerifyDevice(Device)})
value = dev->DeviceName.c_str();
else
{
ProbeAllDevicesList();
value = alcAllDevicesList.c_str();
}
break;
case ALC_CAPTURE_DEVICE_SPECIFIER:
if(DeviceRef dev{VerifyDevice(Device)})
value = dev->DeviceName.c_str();
else
{
ProbeCaptureDeviceList();
value = alcCaptureDeviceList.c_str();
}
break;
/* Default devices are always first in the list */
case ALC_DEFAULT_DEVICE_SPECIFIER:
value = alcDefaultName;
break;
case ALC_DEFAULT_ALL_DEVICES_SPECIFIER:
if(alcAllDevicesList.empty())
ProbeAllDevicesList();
/* Copy first entry as default. */
alcDefaultAllDevicesSpecifier = alcAllDevicesList.c_str();
value = alcDefaultAllDevicesSpecifier.c_str();
break;
case ALC_CAPTURE_DEFAULT_DEVICE_SPECIFIER:
if(alcCaptureDeviceList.empty())
ProbeCaptureDeviceList();
/* Copy first entry as default. */
alcCaptureDefaultDeviceSpecifier = alcCaptureDeviceList.c_str();
value = alcCaptureDefaultDeviceSpecifier.c_str();
break;
case ALC_EXTENSIONS:
if(VerifyDevice(Device))
value = alcExtensionList;
else
value = alcNoDeviceExtList;
break;
case ALC_HRTF_SPECIFIER_SOFT:
if(DeviceRef dev{VerifyDevice(Device)})
{
std::lock_guard<std::mutex> _{dev->StateLock};
value = (dev->mHrtf ? dev->HrtfName.c_str() : "");
}
else
alcSetError(nullptr, ALC_INVALID_DEVICE);
break;
default:
alcSetError(VerifyDevice(Device).get(), ALC_INVALID_ENUM);
break;
}
return value;
}
END_API_FUNC
static inline ALCsizei NumAttrsForDevice(ALCdevice *device)
{
if(device->Type == Capture) return 9;
if(device->Type != Loopback) return 29;
if(device->FmtChans == DevFmtAmbi3D)
return 35;
return 29;
}
static size_t GetIntegerv(ALCdevice *device, ALCenum param, const al::span<int> values)
{
size_t i;
if(values.empty())
{
alcSetError(device, ALC_INVALID_VALUE);
return 0;
}
if(!device)
{
switch(param)
{
case ALC_MAJOR_VERSION:
values[0] = alcMajorVersion;
return 1;
case ALC_MINOR_VERSION:
values[0] = alcMinorVersion;
return 1;
case ALC_ATTRIBUTES_SIZE:
case ALC_ALL_ATTRIBUTES:
case ALC_FREQUENCY:
case ALC_REFRESH:
case ALC_SYNC:
case ALC_MONO_SOURCES:
case ALC_STEREO_SOURCES:
case ALC_CAPTURE_SAMPLES:
case ALC_FORMAT_CHANNELS_SOFT:
case ALC_FORMAT_TYPE_SOFT:
case ALC_AMBISONIC_LAYOUT_SOFT:
case ALC_AMBISONIC_SCALING_SOFT:
case ALC_AMBISONIC_ORDER_SOFT:
case ALC_MAX_AMBISONIC_ORDER_SOFT:
alcSetError(nullptr, ALC_INVALID_DEVICE);
return 0;
default:
alcSetError(nullptr, ALC_INVALID_ENUM);
}
return 0;
}
if(device->Type == Capture)
{
switch(param)
{
case ALC_ATTRIBUTES_SIZE:
values[0] = NumAttrsForDevice(device);
return 1;
case ALC_ALL_ATTRIBUTES:
i = 0;
if(values.size() < static_cast<size_t>(NumAttrsForDevice(device)))
alcSetError(device, ALC_INVALID_VALUE);
else
{
std::lock_guard<std::mutex> _{device->StateLock};
values[i++] = ALC_MAJOR_VERSION;
values[i++] = alcMajorVersion;
values[i++] = ALC_MINOR_VERSION;
values[i++] = alcMinorVersion;
values[i++] = ALC_CAPTURE_SAMPLES;
values[i++] = static_cast<int>(device->Backend->availableSamples());
values[i++] = ALC_CONNECTED;
values[i++] = device->Connected.load(std::memory_order_relaxed);
values[i++] = 0;
}
return i;
case ALC_MAJOR_VERSION:
values[0] = alcMajorVersion;
return 1;
case ALC_MINOR_VERSION:
values[0] = alcMinorVersion;
return 1;
case ALC_CAPTURE_SAMPLES:
{
std::lock_guard<std::mutex> _{device->StateLock};
values[0] = static_cast<int>(device->Backend->availableSamples());
}
return 1;
case ALC_CONNECTED:
{
std::lock_guard<std::mutex> _{device->StateLock};
values[0] = device->Connected.load(std::memory_order_acquire);
}
return 1;
default:
alcSetError(device, ALC_INVALID_ENUM);
}
return 0;
}
/* render device */
switch(param)
{
case ALC_ATTRIBUTES_SIZE:
values[0] = NumAttrsForDevice(device);
return 1;
case ALC_ALL_ATTRIBUTES:
i = 0;
if(values.size() < static_cast<size_t>(NumAttrsForDevice(device)))
alcSetError(device, ALC_INVALID_VALUE);
else
{
std::lock_guard<std::mutex> _{device->StateLock};
values[i++] = ALC_MAJOR_VERSION;
values[i++] = alcMajorVersion;
values[i++] = ALC_MINOR_VERSION;
values[i++] = alcMinorVersion;
values[i++] = ALC_EFX_MAJOR_VERSION;
values[i++] = alcEFXMajorVersion;
values[i++] = ALC_EFX_MINOR_VERSION;
values[i++] = alcEFXMinorVersion;
values[i++] = ALC_FREQUENCY;
values[i++] = static_cast<int>(device->Frequency);
if(device->Type != Loopback)
{
values[i++] = ALC_REFRESH;
values[i++] = static_cast<int>(device->Frequency / device->UpdateSize);
values[i++] = ALC_SYNC;
values[i++] = ALC_FALSE;
}
else
{
if(device->FmtChans == DevFmtAmbi3D)
{
values[i++] = ALC_AMBISONIC_LAYOUT_SOFT;
values[i++] = static_cast<int>(device->mAmbiLayout);
values[i++] = ALC_AMBISONIC_SCALING_SOFT;
values[i++] = static_cast<int>(device->mAmbiScale);
values[i++] = ALC_AMBISONIC_ORDER_SOFT;
values[i++] = static_cast<int>(device->mAmbiOrder);
}
values[i++] = ALC_FORMAT_CHANNELS_SOFT;
values[i++] = device->FmtChans;
values[i++] = ALC_FORMAT_TYPE_SOFT;
values[i++] = device->FmtType;
}
values[i++] = ALC_MONO_SOURCES;
values[i++] = static_cast<int>(device->NumMonoSources);
values[i++] = ALC_STEREO_SOURCES;
values[i++] = static_cast<int>(device->NumStereoSources);
values[i++] = ALC_MAX_AUXILIARY_SENDS;
values[i++] = static_cast<int>(device->NumAuxSends);
values[i++] = ALC_HRTF_SOFT;
values[i++] = (device->mHrtf ? ALC_TRUE : ALC_FALSE);
values[i++] = ALC_HRTF_STATUS_SOFT;
values[i++] = device->HrtfStatus;
values[i++] = ALC_OUTPUT_LIMITER_SOFT;
values[i++] = device->Limiter ? ALC_TRUE : ALC_FALSE;
values[i++] = ALC_MAX_AMBISONIC_ORDER_SOFT;
values[i++] = MAX_AMBI_ORDER;
values[i++] = 0;
}
return i;
case ALC_MAJOR_VERSION:
values[0] = alcMajorVersion;
return 1;
case ALC_MINOR_VERSION:
values[0] = alcMinorVersion;
return 1;
case ALC_EFX_MAJOR_VERSION:
values[0] = alcEFXMajorVersion;
return 1;
case ALC_EFX_MINOR_VERSION:
values[0] = alcEFXMinorVersion;
return 1;
case ALC_FREQUENCY:
values[0] = static_cast<int>(device->Frequency);
return 1;
case ALC_REFRESH:
if(device->Type == Loopback)
{
alcSetError(device, ALC_INVALID_DEVICE);
return 0;
}
{
std::lock_guard<std::mutex> _{device->StateLock};
values[0] = static_cast<int>(device->Frequency / device->UpdateSize);
}
return 1;
case ALC_SYNC:
if(device->Type == Loopback)
{
alcSetError(device, ALC_INVALID_DEVICE);
return 0;
}
values[0] = ALC_FALSE;
return 1;
case ALC_FORMAT_CHANNELS_SOFT:
if(device->Type != Loopback)
{
alcSetError(device, ALC_INVALID_DEVICE);
return 0;
}
values[0] = device->FmtChans;
return 1;
case ALC_FORMAT_TYPE_SOFT:
if(device->Type != Loopback)
{
alcSetError(device, ALC_INVALID_DEVICE);
return 0;
}
values[0] = device->FmtType;
return 1;
case ALC_AMBISONIC_LAYOUT_SOFT:
if(device->Type != Loopback || device->FmtChans != DevFmtAmbi3D)
{
alcSetError(device, ALC_INVALID_DEVICE);
return 0;
}
values[0] = static_cast<int>(device->mAmbiLayout);
return 1;
case ALC_AMBISONIC_SCALING_SOFT:
if(device->Type != Loopback || device->FmtChans != DevFmtAmbi3D)
{
alcSetError(device, ALC_INVALID_DEVICE);
return 0;
}
values[0] = static_cast<int>(device->mAmbiScale);
return 1;
case ALC_AMBISONIC_ORDER_SOFT:
if(device->Type != Loopback || device->FmtChans != DevFmtAmbi3D)
{
alcSetError(device, ALC_INVALID_DEVICE);
return 0;
}
values[0] = static_cast<int>(device->mAmbiOrder);
return 1;
case ALC_MONO_SOURCES:
values[0] = static_cast<int>(device->NumMonoSources);
return 1;
case ALC_STEREO_SOURCES:
values[0] = static_cast<int>(device->NumStereoSources);
return 1;
case ALC_MAX_AUXILIARY_SENDS:
values[0] = static_cast<int>(device->NumAuxSends);
return 1;
case ALC_CONNECTED:
{
std::lock_guard<std::mutex> _{device->StateLock};
values[0] = device->Connected.load(std::memory_order_acquire);
}
return 1;
case ALC_HRTF_SOFT:
values[0] = (device->mHrtf ? ALC_TRUE : ALC_FALSE);
return 1;
case ALC_HRTF_STATUS_SOFT:
values[0] = device->HrtfStatus;
return 1;
case ALC_NUM_HRTF_SPECIFIERS_SOFT:
{
std::lock_guard<std::mutex> _{device->StateLock};
device->HrtfList = EnumerateHrtf(device->DeviceName.c_str());
values[0] = static_cast<int>(minz(device->HrtfList.size(),
std::numeric_limits<int>::max()));
}
return 1;
case ALC_OUTPUT_LIMITER_SOFT:
values[0] = device->Limiter ? ALC_TRUE : ALC_FALSE;
return 1;
case ALC_MAX_AMBISONIC_ORDER_SOFT:
values[0] = MAX_AMBI_ORDER;
return 1;
default:
alcSetError(device, ALC_INVALID_ENUM);
}
return 0;
}
ALC_API void ALC_APIENTRY alcGetIntegerv(ALCdevice *device, ALCenum param, ALCsizei size, ALCint *values)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(size <= 0 || values == nullptr)
alcSetError(dev.get(), ALC_INVALID_VALUE);
else
GetIntegerv(dev.get(), param, {values, static_cast<ALuint>(size)});
}
END_API_FUNC
ALC_API void ALC_APIENTRY alcGetInteger64vSOFT(ALCdevice *device, ALCenum pname, ALCsizei size, ALCint64SOFT *values)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(size <= 0 || values == nullptr)
{
alcSetError(dev.get(), ALC_INVALID_VALUE);
return;
}
if(!dev || dev->Type == Capture)
{
auto ivals = al::vector<int>(static_cast<ALuint>(size));
size_t got{GetIntegerv(dev.get(), pname, ivals)};
std::copy_n(ivals.begin(), got, values);
return;
}
/* render device */
switch(pname)
{
case ALC_ATTRIBUTES_SIZE:
*values = NumAttrsForDevice(dev.get())+4;
break;
case ALC_ALL_ATTRIBUTES:
if(size < NumAttrsForDevice(dev.get())+4)
alcSetError(dev.get(), ALC_INVALID_VALUE);
else
{
size_t i{0};
std::lock_guard<std::mutex> _{dev->StateLock};
values[i++] = ALC_FREQUENCY;
values[i++] = dev->Frequency;
if(dev->Type != Loopback)
{
values[i++] = ALC_REFRESH;
values[i++] = dev->Frequency / dev->UpdateSize;
values[i++] = ALC_SYNC;
values[i++] = ALC_FALSE;
}
else
{
if(dev->FmtChans == DevFmtAmbi3D)
{
values[i++] = ALC_AMBISONIC_LAYOUT_SOFT;
values[i++] = static_cast<int64_t>(dev->mAmbiLayout);
values[i++] = ALC_AMBISONIC_SCALING_SOFT;
values[i++] = static_cast<int64_t>(dev->mAmbiScale);
values[i++] = ALC_AMBISONIC_ORDER_SOFT;
values[i++] = dev->mAmbiOrder;
}
values[i++] = ALC_FORMAT_CHANNELS_SOFT;
values[i++] = dev->FmtChans;
values[i++] = ALC_FORMAT_TYPE_SOFT;
values[i++] = dev->FmtType;
}
values[i++] = ALC_MONO_SOURCES;
values[i++] = dev->NumMonoSources;
values[i++] = ALC_STEREO_SOURCES;
values[i++] = dev->NumStereoSources;
values[i++] = ALC_MAX_AUXILIARY_SENDS;
values[i++] = dev->NumAuxSends;
values[i++] = ALC_HRTF_SOFT;
values[i++] = (dev->mHrtf ? ALC_TRUE : ALC_FALSE);
values[i++] = ALC_HRTF_STATUS_SOFT;
values[i++] = dev->HrtfStatus;
values[i++] = ALC_OUTPUT_LIMITER_SOFT;
values[i++] = dev->Limiter ? ALC_TRUE : ALC_FALSE;
ClockLatency clock{GetClockLatency(dev.get())};
values[i++] = ALC_DEVICE_CLOCK_SOFT;
values[i++] = clock.ClockTime.count();
values[i++] = ALC_DEVICE_LATENCY_SOFT;
values[i++] = clock.Latency.count();
values[i++] = 0;
}
break;
case ALC_DEVICE_CLOCK_SOFT:
{
std::lock_guard<std::mutex> _{dev->StateLock};
ALuint samplecount, refcount;
nanoseconds basecount;
do {
refcount = dev->waitForMix();
basecount = dev->ClockBase;
samplecount = dev->SamplesDone;
} while(refcount != ReadRef(dev->MixCount));
basecount += nanoseconds{seconds{samplecount}} / dev->Frequency;
*values = basecount.count();
}
break;
case ALC_DEVICE_LATENCY_SOFT:
{
std::lock_guard<std::mutex> _{dev->StateLock};
ClockLatency clock{GetClockLatency(dev.get())};
*values = clock.Latency.count();
}
break;
case ALC_DEVICE_CLOCK_LATENCY_SOFT:
if(size < 2)
alcSetError(dev.get(), ALC_INVALID_VALUE);
else
{
std::lock_guard<std::mutex> _{dev->StateLock};
ClockLatency clock{GetClockLatency(dev.get())};
values[0] = clock.ClockTime.count();
values[1] = clock.Latency.count();
}
break;
default:
auto ivals = al::vector<int>(static_cast<ALuint>(size));
size_t got{GetIntegerv(dev.get(), pname, ivals)};
std::copy_n(ivals.begin(), got, values);
break;
}
}
END_API_FUNC
ALC_API ALCboolean ALC_APIENTRY alcIsExtensionPresent(ALCdevice *device, const ALCchar *extName)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(!extName)
alcSetError(dev.get(), ALC_INVALID_VALUE);
else
{
size_t len = strlen(extName);
const char *ptr = (dev ? alcExtensionList : alcNoDeviceExtList);
while(ptr && *ptr)
{
if(al::strncasecmp(ptr, extName, len) == 0 && (ptr[len] == '\0' || isspace(ptr[len])))
return ALC_TRUE;
if((ptr=strchr(ptr, ' ')) != nullptr)
{
do {
++ptr;
} while(isspace(*ptr));
}
}
}
return ALC_FALSE;
}
END_API_FUNC
ALC_API ALCvoid* ALC_APIENTRY alcGetProcAddress(ALCdevice *device, const ALCchar *funcName)
START_API_FUNC
{
if(!funcName)
{
DeviceRef dev{VerifyDevice(device)};
alcSetError(dev.get(), ALC_INVALID_VALUE);
}
else
{
for(const auto &func : alcFunctions)
{
if(strcmp(func.funcName, funcName) == 0)
return func.address;
}
}
return nullptr;
}
END_API_FUNC
ALC_API ALCenum ALC_APIENTRY alcGetEnumValue(ALCdevice *device, const ALCchar *enumName)
START_API_FUNC
{
if(!enumName)
{
DeviceRef dev{VerifyDevice(device)};
alcSetError(dev.get(), ALC_INVALID_VALUE);
}
else
{
for(const auto &enm : alcEnumerations)
{
if(strcmp(enm.enumName, enumName) == 0)
return enm.value;
}
}
return 0;
}
END_API_FUNC
ALC_API ALCcontext* ALC_APIENTRY alcCreateContext(ALCdevice *device, const ALCint *attrList)
START_API_FUNC
{
/* Explicitly hold the list lock while taking the StateLock in case the
* device is asynchronously destroyed, to ensure this new context is
* properly cleaned up after being made.
*/
std::unique_lock<std::recursive_mutex> listlock{ListLock};
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type == Capture || !dev->Connected.load(std::memory_order_relaxed))
{
listlock.unlock();
alcSetError(dev.get(), ALC_INVALID_DEVICE);
return nullptr;
}
std::unique_lock<std::mutex> statelock{dev->StateLock};
listlock.unlock();
dev->LastError.store(ALC_NO_ERROR);
ALCenum err{UpdateDeviceParams(dev.get(), attrList)};
if(err != ALC_NO_ERROR)
{
alcSetError(dev.get(), err);
return nullptr;
}
ContextRef context{new ALCcontext{dev}};
context->init();
if(auto volopt = ConfigValueFloat(dev->DeviceName.c_str(), nullptr, "volume-adjust"))
{
const float valf{*volopt};
if(!std::isfinite(valf))
ERR("volume-adjust must be finite: %f\n", valf);
else
{
const float db{clampf(valf, -24.0f, 24.0f)};
if(db != valf)
WARN("volume-adjust clamped: %f, range: +/-%f\n", valf, 24.0f);
context->mGainBoost = std::pow(10.0f, db/20.0f);
TRACE("volume-adjust gain: %f\n", context->mGainBoost);
}
}
UpdateListenerProps(context.get());
{
using ContextArray = al::FlexArray<ALCcontext*>;
/* Allocate a new context array, which holds 1 more than the current/
* old array.
*/
auto *oldarray = device->mContexts.load();
const size_t newcount{oldarray->size()+1};
std::unique_ptr<ContextArray> newarray{ContextArray::Create(newcount)};
/* Copy the current/old context handles to the new array, appending the
* new context.
*/
auto iter = std::copy(oldarray->begin(), oldarray->end(), newarray->begin());
*iter = context.get();
/* Store the new context array in the device. Wait for any current mix
* to finish before deleting the old array.
*/
dev->mContexts.store(newarray.release());
if(oldarray != &EmptyContextArray)
{
dev->waitForMix();
delete oldarray;
}
}
statelock.unlock();
{
std::lock_guard<std::recursive_mutex> _{ListLock};
auto iter = std::lower_bound(ContextList.cbegin(), ContextList.cend(), context.get());
ContextList.emplace(iter, context.get());
}
if(ALeffectslot *slot{context->mDefaultSlot.get()})
{
if(slot->initEffect(&DefaultEffect, context.get()) == AL_NO_ERROR)
slot->updateProps(context.get());
else
ERR("Failed to initialize the default effect\n");
}
TRACE("Created context %p\n", decltype(std::declval<void*>()){context.get()});
return context.release();
}
END_API_FUNC
ALC_API void ALC_APIENTRY alcDestroyContext(ALCcontext *context)
START_API_FUNC
{
std::unique_lock<std::recursive_mutex> listlock{ListLock};
auto iter = std::lower_bound(ContextList.begin(), ContextList.end(), context);
if(iter == ContextList.end() || *iter != context)
{
listlock.unlock();
alcSetError(nullptr, ALC_INVALID_CONTEXT);
return;
}
/* Hold a reference to this context so it remains valid until the ListLock
* is released.
*/
ContextRef ctx{*iter};
ContextList.erase(iter);
ALCdevice *Device{ctx->mDevice.get()};
std::lock_guard<std::mutex> _{Device->StateLock};
if(!ctx->deinit() && Device->Flags.get<DeviceRunning>())
{
Device->Backend->stop();
Device->Flags.unset<DeviceRunning>();
}
}
END_API_FUNC
ALC_API ALCcontext* ALC_APIENTRY alcGetCurrentContext(void)
START_API_FUNC
{
ALCcontext *Context{LocalContext};
if(!Context) Context = GlobalContext.load();
return Context;
}
END_API_FUNC
/** Returns the currently active thread-local context. */
ALC_API ALCcontext* ALC_APIENTRY alcGetThreadContext(void)
START_API_FUNC
{ return LocalContext; }
END_API_FUNC
ALC_API ALCboolean ALC_APIENTRY alcMakeContextCurrent(ALCcontext *context)
START_API_FUNC
{
/* context must be valid or nullptr */
ContextRef ctx;
if(context)
{
ctx = VerifyContext(context);
if(!ctx)
{
alcSetError(nullptr, ALC_INVALID_CONTEXT);
return ALC_FALSE;
}
}
/* Release this reference (if any) to store it in the GlobalContext
* pointer. Take ownership of the reference (if any) that was previously
* stored there.
*/
ctx = ContextRef{GlobalContext.exchange(ctx.release())};
/* Reset (decrement) the previous global reference by replacing it with the
* thread-local context. Take ownership of the thread-local context
* reference (if any), clearing the storage to null.
*/
ctx = ContextRef{LocalContext};
if(ctx) ThreadContext.set(nullptr);
/* Reset (decrement) the previous thread-local reference. */
return ALC_TRUE;
}
END_API_FUNC
/** Makes the given context the active context for the current thread. */
ALC_API ALCboolean ALC_APIENTRY alcSetThreadContext(ALCcontext *context)
START_API_FUNC
{
/* context must be valid or nullptr */
ContextRef ctx;
if(context)
{
ctx = VerifyContext(context);
if(!ctx)
{
alcSetError(nullptr, ALC_INVALID_CONTEXT);
return ALC_FALSE;
}
}
/* context's reference count is already incremented */
ContextRef old{LocalContext};
ThreadContext.set(ctx.release());
return ALC_TRUE;
}
END_API_FUNC
ALC_API ALCdevice* ALC_APIENTRY alcGetContextsDevice(ALCcontext *Context)
START_API_FUNC
{
ContextRef ctx{VerifyContext(Context)};
if(!ctx)
{
alcSetError(nullptr, ALC_INVALID_CONTEXT);
return nullptr;
}
return ctx->mDevice.get();
}
END_API_FUNC
ALC_API ALCdevice* ALC_APIENTRY alcOpenDevice(const ALCchar *deviceName)
START_API_FUNC
{
DO_INITCONFIG();
if(!PlaybackFactory)
{
alcSetError(nullptr, ALC_INVALID_VALUE);
return nullptr;
}
if(deviceName)
{
if(!deviceName[0] || al::strcasecmp(deviceName, alcDefaultName) == 0
#ifdef _WIN32
/* Some old Windows apps hardcode these expecting OpenAL to use a
* specific audio API, even when they're not enumerated. Creative's
* router effectively ignores them too.
*/
|| al::strcasecmp(deviceName, "DirectSound3D") == 0
|| al::strcasecmp(deviceName, "DirectSound") == 0
|| al::strcasecmp(deviceName, "MMSYSTEM") == 0
#endif
|| al::strcasecmp(deviceName, "openal-soft") == 0)
deviceName = nullptr;
}
DeviceRef device{new ALCdevice{Playback}};
/* Set output format */
device->FmtChans = DevFmtChannelsDefault;
device->FmtType = DevFmtTypeDefault;
device->Frequency = DEFAULT_OUTPUT_RATE;
device->UpdateSize = DEFAULT_UPDATE_SIZE;
device->BufferSize = DEFAULT_UPDATE_SIZE * DEFAULT_NUM_UPDATES;
device->SourcesMax = 256;
device->AuxiliaryEffectSlotMax = 64;
device->NumAuxSends = DEFAULT_SENDS;
try {
auto backend = PlaybackFactory->createBackend(device.get(), BackendType::Playback);
std::lock_guard<std::recursive_mutex> _{ListLock};
backend->open(deviceName);
device->Backend = std::move(backend);
}
catch(al::backend_exception &e) {
WARN("Failed to open playback device: %s\n", e.what());
alcSetError(nullptr, e.errorCode());
return nullptr;
}
deviceName = device->DeviceName.c_str();
if(auto chanopt = ConfigValueStr(deviceName, nullptr, "channels"))
{
static const struct ChannelMap {
const char name[16];
DevFmtChannels chans;
ALuint order;
} chanlist[] = {
{ "mono", DevFmtMono, 0 },
{ "stereo", DevFmtStereo, 0 },
{ "quad", DevFmtQuad, 0 },
{ "surround51", DevFmtX51, 0 },
{ "surround61", DevFmtX61, 0 },
{ "surround71", DevFmtX71, 0 },
{ "surround51rear", DevFmtX51Rear, 0 },
{ "ambi1", DevFmtAmbi3D, 1 },
{ "ambi2", DevFmtAmbi3D, 2 },
{ "ambi3", DevFmtAmbi3D, 3 },
};
const ALCchar *fmt{chanopt->c_str()};
auto iter = std::find_if(std::begin(chanlist), std::end(chanlist),
[fmt](const ChannelMap &entry) -> bool
{ return al::strcasecmp(entry.name, fmt) == 0; }
);
if(iter == std::end(chanlist))
ERR("Unsupported channels: %s\n", fmt);
else
{
device->FmtChans = iter->chans;
device->mAmbiOrder = iter->order;
device->Flags.set<ChannelsRequest>();
}
}
if(auto typeopt = ConfigValueStr(deviceName, nullptr, "sample-type"))
{
static const struct TypeMap {
const char name[16];
DevFmtType type;
} typelist[] = {
{ "int8", DevFmtByte },
{ "uint8", DevFmtUByte },
{ "int16", DevFmtShort },
{ "uint16", DevFmtUShort },
{ "int32", DevFmtInt },
{ "uint32", DevFmtUInt },
{ "float32", DevFmtFloat },
};
const ALCchar *fmt{typeopt->c_str()};
auto iter = std::find_if(std::begin(typelist), std::end(typelist),
[fmt](const TypeMap &entry) -> bool
{ return al::strcasecmp(entry.name, fmt) == 0; }
);
if(iter == std::end(typelist))
ERR("Unsupported sample-type: %s\n", fmt);
else
{
device->FmtType = iter->type;
device->Flags.set<SampleTypeRequest>();
}
}
if(ALuint freq{ConfigValueUInt(deviceName, nullptr, "frequency").value_or(0)})
{
if(freq < MIN_OUTPUT_RATE || freq > MAX_OUTPUT_RATE)
{
const ALuint newfreq{clampu(freq, MIN_OUTPUT_RATE, MAX_OUTPUT_RATE)};
ERR("%uhz request clamped to %uhz\n", freq, newfreq);
freq = newfreq;
}
const double scale{static_cast<double>(freq) / device->Frequency};
device->UpdateSize = static_cast<ALuint>(device->UpdateSize*scale + 0.5);
device->BufferSize = static_cast<ALuint>(device->BufferSize*scale + 0.5);
device->Frequency = freq;
device->Flags.set<FrequencyRequest>();
}
if(auto persizeopt = ConfigValueUInt(deviceName, nullptr, "period_size"))
device->UpdateSize = clampu(*persizeopt, 64, 8192);
if(auto peropt = ConfigValueUInt(deviceName, nullptr, "periods"))
device->BufferSize = device->UpdateSize * clampu(*peropt, 2, 16);
else
device->BufferSize = maxu(device->BufferSize, device->UpdateSize*2);
if(auto srcsmax = ConfigValueUInt(deviceName, nullptr, "sources").value_or(0))
device->SourcesMax = srcsmax;
if(auto slotsmax = ConfigValueUInt(deviceName, nullptr, "slots").value_or(0))
device->AuxiliaryEffectSlotMax = minu(slotsmax, INT_MAX);
if(auto sendsopt = ConfigValueInt(deviceName, nullptr, "sends"))
device->NumAuxSends = minu(DEFAULT_SENDS,
static_cast<ALuint>(clampi(*sendsopt, 0, MAX_SENDS)));
device->NumStereoSources = 1;
device->NumMonoSources = device->SourcesMax - device->NumStereoSources;
if(auto ambiopt = ConfigValueStr(deviceName, nullptr, "ambi-format"))
{
const ALCchar *fmt{ambiopt->c_str()};
if(al::strcasecmp(fmt, "fuma") == 0)
{
if(device->mAmbiOrder > 3)
ERR("FuMa is incompatible with %d%s order ambisonics (up to third-order only)\n",
device->mAmbiOrder,
(((device->mAmbiOrder%100)/10) == 1) ? "th" :
((device->mAmbiOrder%10) == 1) ? "st" :
((device->mAmbiOrder%10) == 2) ? "nd" :
((device->mAmbiOrder%10) == 3) ? "rd" : "th");
else
{
device->mAmbiLayout = AmbiLayout::FuMa;
device->mAmbiScale = AmbiNorm::FuMa;
}
}
else if(al::strcasecmp(fmt, "ambix") == 0 || al::strcasecmp(fmt, "acn+sn3d") == 0)
{
device->mAmbiLayout = AmbiLayout::ACN;
device->mAmbiScale = AmbiNorm::SN3D;
}
else if(al::strcasecmp(fmt, "acn+n3d") == 0)
{
device->mAmbiLayout = AmbiLayout::ACN;
device->mAmbiScale = AmbiNorm::N3D;
}
else
ERR("Unsupported ambi-format: %s\n", fmt);
}
{
std::lock_guard<std::recursive_mutex> _{ListLock};
auto iter = std::lower_bound(DeviceList.cbegin(), DeviceList.cend(), device.get());
DeviceList.emplace(iter, device.get());
}
TRACE("Created device %p, \"%s\"\n", decltype(std::declval<void*>()){device.get()},
device->DeviceName.c_str());
return device.release();
}
END_API_FUNC
ALC_API ALCboolean ALC_APIENTRY alcCloseDevice(ALCdevice *device)
START_API_FUNC
{
std::unique_lock<std::recursive_mutex> listlock{ListLock};
auto iter = std::lower_bound(DeviceList.begin(), DeviceList.end(), device);
if(iter == DeviceList.end() || *iter != device)
{
alcSetError(nullptr, ALC_INVALID_DEVICE);
return ALC_FALSE;
}
if((*iter)->Type == Capture)
{
alcSetError(*iter, ALC_INVALID_DEVICE);
return ALC_FALSE;
}
/* Erase the device, and any remaining contexts left on it, from their
* respective lists.
*/
DeviceRef dev{*iter};
DeviceList.erase(iter);
std::unique_lock<std::mutex> statelock{dev->StateLock};
al::vector<ContextRef> orphanctxs;
for(ALCcontext *ctx : *dev->mContexts.load())
{
auto ctxiter = std::lower_bound(ContextList.begin(), ContextList.end(), ctx);
if(ctxiter != ContextList.end() && *ctxiter == ctx)
{
orphanctxs.emplace_back(ContextRef{*ctxiter});
ContextList.erase(ctxiter);
}
}
listlock.unlock();
for(ContextRef &context : orphanctxs)
{
WARN("Releasing orphaned context %p\n", decltype(std::declval<void*>()){context.get()});
context->deinit();
}
orphanctxs.clear();
if(dev->Flags.get<DeviceRunning>())
dev->Backend->stop();
dev->Flags.unset<DeviceRunning>();
return ALC_TRUE;
}
END_API_FUNC
/************************************************
* ALC capture functions
************************************************/
ALC_API ALCdevice* ALC_APIENTRY alcCaptureOpenDevice(const ALCchar *deviceName, ALCuint frequency, ALCenum format, ALCsizei samples)
START_API_FUNC
{
DO_INITCONFIG();
if(!CaptureFactory)
{
alcSetError(nullptr, ALC_INVALID_VALUE);
return nullptr;
}
if(samples <= 0)
{
alcSetError(nullptr, ALC_INVALID_VALUE);
return nullptr;
}
if(deviceName)
{
if(!deviceName[0] || al::strcasecmp(deviceName, alcDefaultName) == 0
|| al::strcasecmp(deviceName, "openal-soft") == 0)
deviceName = nullptr;
}
DeviceRef device{new ALCdevice{Capture}};
auto decompfmt = DecomposeDevFormat(format);
if(!decompfmt)
{
alcSetError(nullptr, ALC_INVALID_ENUM);
return nullptr;
}
device->Frequency = frequency;
device->FmtChans = decompfmt->chans;
device->FmtType = decompfmt->type;
device->Flags.set<FrequencyRequest, ChannelsRequest, SampleTypeRequest>();
device->UpdateSize = static_cast<ALuint>(samples);
device->BufferSize = static_cast<ALuint>(samples);
try {
TRACE("Capture format: %s, %s, %uhz, %u / %u buffer\n",
DevFmtChannelsString(device->FmtChans), DevFmtTypeString(device->FmtType),
device->Frequency, device->UpdateSize, device->BufferSize);
auto backend = CaptureFactory->createBackend(device.get(), BackendType::Capture);
std::lock_guard<std::recursive_mutex> _{ListLock};
backend->open(deviceName);
device->Backend = std::move(backend);
}
catch(al::backend_exception &e) {
WARN("Failed to open capture device: %s\n", e.what());
alcSetError(nullptr, e.errorCode());
return nullptr;
}
{
std::lock_guard<std::recursive_mutex> _{ListLock};
auto iter = std::lower_bound(DeviceList.cbegin(), DeviceList.cend(), device.get());
DeviceList.emplace(iter, device.get());
}
TRACE("Created capture device %p, \"%s\"\n", decltype(std::declval<void*>()){device.get()},
device->DeviceName.c_str());
return device.release();
}
END_API_FUNC
ALC_API ALCboolean ALC_APIENTRY alcCaptureCloseDevice(ALCdevice *device)
START_API_FUNC
{
std::unique_lock<std::recursive_mutex> listlock{ListLock};
auto iter = std::lower_bound(DeviceList.begin(), DeviceList.end(), device);
if(iter == DeviceList.end() || *iter != device)
{
alcSetError(nullptr, ALC_INVALID_DEVICE);
return ALC_FALSE;
}
if((*iter)->Type != Capture)
{
alcSetError(*iter, ALC_INVALID_DEVICE);
return ALC_FALSE;
}
DeviceRef dev{*iter};
DeviceList.erase(iter);
listlock.unlock();
std::lock_guard<std::mutex> _{dev->StateLock};
if(dev->Flags.get<DeviceRunning>())
dev->Backend->stop();
dev->Flags.unset<DeviceRunning>();
return ALC_TRUE;
}
END_API_FUNC
ALC_API void ALC_APIENTRY alcCaptureStart(ALCdevice *device)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type != Capture)
{
alcSetError(dev.get(), ALC_INVALID_DEVICE);
return;
}
std::lock_guard<std::mutex> _{dev->StateLock};
if(!dev->Connected.load(std::memory_order_acquire))
alcSetError(dev.get(), ALC_INVALID_DEVICE);
else if(!dev->Flags.get<DeviceRunning>())
{
try {
auto backend = dev->Backend.get();
backend->start();
dev->Flags.set<DeviceRunning>();
}
catch(al::backend_exception& e) {
aluHandleDisconnect(dev.get(), "%s", e.what());
alcSetError(dev.get(), ALC_INVALID_DEVICE);
}
}
}
END_API_FUNC
ALC_API void ALC_APIENTRY alcCaptureStop(ALCdevice *device)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type != Capture)
alcSetError(dev.get(), ALC_INVALID_DEVICE);
else
{
std::lock_guard<std::mutex> _{dev->StateLock};
if(dev->Flags.get<DeviceRunning>())
dev->Backend->stop();
dev->Flags.unset<DeviceRunning>();
}
}
END_API_FUNC
ALC_API void ALC_APIENTRY alcCaptureSamples(ALCdevice *device, ALCvoid *buffer, ALCsizei samples)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type != Capture)
{
alcSetError(dev.get(), ALC_INVALID_DEVICE);
return;
}
if(samples < 0 || (samples > 0 && buffer == nullptr))
{
alcSetError(dev.get(), ALC_INVALID_VALUE);
return;
}
if(samples < 1)
return;
std::lock_guard<std::mutex> _{dev->StateLock};
BackendBase *backend{dev->Backend.get()};
const auto usamples = static_cast<ALCuint>(samples);
if(usamples > backend->availableSamples())
{
alcSetError(dev.get(), ALC_INVALID_VALUE);
return;
}
auto *bbuffer = static_cast<al::byte*>(buffer);
if(ALCenum err{backend->captureSamples(bbuffer, usamples)})
alcSetError(dev.get(), err);
}
END_API_FUNC
/************************************************
* ALC loopback functions
************************************************/
/** Open a loopback device, for manual rendering. */
ALC_API ALCdevice* ALC_APIENTRY alcLoopbackOpenDeviceSOFT(const ALCchar *deviceName)
START_API_FUNC
{
DO_INITCONFIG();
/* Make sure the device name, if specified, is us. */
if(deviceName && strcmp(deviceName, alcDefaultName) != 0)
{
alcSetError(nullptr, ALC_INVALID_VALUE);
return nullptr;
}
DeviceRef device{new ALCdevice{Loopback}};
device->SourcesMax = 256;
device->AuxiliaryEffectSlotMax = 64;
device->NumAuxSends = DEFAULT_SENDS;
//Set output format
device->BufferSize = 0;
device->UpdateSize = 0;
device->Frequency = DEFAULT_OUTPUT_RATE;
device->FmtChans = DevFmtChannelsDefault;
device->FmtType = DevFmtTypeDefault;
if(auto srcsmax = ConfigValueUInt(nullptr, nullptr, "sources").value_or(0))
device->SourcesMax = srcsmax;
if(auto slotsmax = ConfigValueUInt(nullptr, nullptr, "slots").value_or(0))
device->AuxiliaryEffectSlotMax = minu(slotsmax, INT_MAX);
if(auto sendsopt = ConfigValueInt(nullptr, nullptr, "sends"))
device->NumAuxSends = minu(DEFAULT_SENDS,
static_cast<ALuint>(clampi(*sendsopt, 0, MAX_SENDS)));
device->NumStereoSources = 1;
device->NumMonoSources = device->SourcesMax - device->NumStereoSources;
try {
auto backend = LoopbackBackendFactory::getFactory().createBackend(device.get(),
BackendType::Playback);
backend->open("Loopback");
device->Backend = std::move(backend);
}
catch(al::backend_exception &e) {
WARN("Failed to open loopback device: %s\n", e.what());
alcSetError(nullptr, e.errorCode());
return nullptr;
}
{
std::lock_guard<std::recursive_mutex> _{ListLock};
auto iter = std::lower_bound(DeviceList.cbegin(), DeviceList.cend(), device.get());
DeviceList.emplace(iter, device.get());
}
TRACE("Created loopback device %p\n", decltype(std::declval<void*>()){device.get()});
return device.release();
}
END_API_FUNC
/**
* Determines if the loopback device supports the given format for rendering.
*/
ALC_API ALCboolean ALC_APIENTRY alcIsRenderFormatSupportedSOFT(ALCdevice *device, ALCsizei freq, ALCenum channels, ALCenum type)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type != Loopback)
alcSetError(dev.get(), ALC_INVALID_DEVICE);
else if(freq <= 0)
alcSetError(dev.get(), ALC_INVALID_VALUE);
else
{
if(IsValidALCType(type) && IsValidALCChannels(channels) && freq >= MIN_OUTPUT_RATE
&& freq <= MAX_OUTPUT_RATE)
return ALC_TRUE;
}
return ALC_FALSE;
}
END_API_FUNC
/**
* Renders some samples into a buffer, using the format last set by the
* attributes given to alcCreateContext.
*/
FORCE_ALIGN ALC_API void ALC_APIENTRY alcRenderSamplesSOFT(ALCdevice *device, ALCvoid *buffer, ALCsizei samples)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type != Loopback)
alcSetError(dev.get(), ALC_INVALID_DEVICE);
else if(samples < 0 || (samples > 0 && buffer == nullptr))
alcSetError(dev.get(), ALC_INVALID_VALUE);
else
aluMixData(dev.get(), buffer, static_cast<ALuint>(samples), dev->channelsFromFmt());
}
END_API_FUNC
/************************************************
* ALC DSP pause/resume functions
************************************************/
/** Pause the DSP to stop audio processing. */
ALC_API void ALC_APIENTRY alcDevicePauseSOFT(ALCdevice *device)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type != Playback)
alcSetError(dev.get(), ALC_INVALID_DEVICE);
else
{
std::lock_guard<std::mutex> _{dev->StateLock};
if(dev->Flags.get<DeviceRunning>())
dev->Backend->stop();
dev->Flags.unset<DeviceRunning>();
dev->Flags.set<DevicePaused>();
}
}
END_API_FUNC
/** Resume the DSP to restart audio processing. */
ALC_API void ALC_APIENTRY alcDeviceResumeSOFT(ALCdevice *device)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type != Playback)
{
alcSetError(dev.get(), ALC_INVALID_DEVICE);
return;
}
std::lock_guard<std::mutex> _{dev->StateLock};
if(!dev->Flags.get<DevicePaused>())
return;
dev->Flags.unset<DevicePaused>();
if(dev->mContexts.load()->empty())
return;
try {
auto backend = dev->Backend.get();
backend->start();
dev->Flags.set<DeviceRunning>();
}
catch(al::backend_exception& e) {
aluHandleDisconnect(dev.get(), "%s", e.what());
alcSetError(dev.get(), ALC_INVALID_DEVICE);
}
}
END_API_FUNC
/************************************************
* ALC HRTF functions
************************************************/
/** Gets a string parameter at the given index. */
ALC_API const ALCchar* ALC_APIENTRY alcGetStringiSOFT(ALCdevice *device, ALCenum paramName, ALCsizei index)
START_API_FUNC
{
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type == Capture)
alcSetError(dev.get(), ALC_INVALID_DEVICE);
else switch(paramName)
{
case ALC_HRTF_SPECIFIER_SOFT:
if(index >= 0 && static_cast<size_t>(index) < dev->HrtfList.size())
return dev->HrtfList[static_cast<ALuint>(index)].c_str();
alcSetError(dev.get(), ALC_INVALID_VALUE);
break;
default:
alcSetError(dev.get(), ALC_INVALID_ENUM);
break;
}
return nullptr;
}
END_API_FUNC
/** Resets the given device output, using the specified attribute list. */
ALC_API ALCboolean ALC_APIENTRY alcResetDeviceSOFT(ALCdevice *device, const ALCint *attribs)
START_API_FUNC
{
std::unique_lock<std::recursive_mutex> listlock{ListLock};
DeviceRef dev{VerifyDevice(device)};
if(!dev || dev->Type == Capture)
{
listlock.unlock();
alcSetError(dev.get(), ALC_INVALID_DEVICE);
return ALC_FALSE;
}
std::lock_guard<std::mutex> _{dev->StateLock};
listlock.unlock();
/* Force the backend to stop mixing first since we're resetting. Also reset
* the connected state so lost devices can attempt recover.
*/
if(dev->Flags.get<DeviceRunning>())
dev->Backend->stop();
dev->Flags.unset<DeviceRunning>();
if(!dev->Connected.load(std::memory_order_relaxed))
{
/* Make sure disconnection is finished before continuing on. */
dev->waitForMix();
for(ALCcontext *ctx : *dev->mContexts.load(std::memory_order_acquire))
{
/* Clear any pending voice changes and reallocate voices to get a
* clean restart.
*/
std::lock_guard<std::mutex> __{ctx->mSourceLock};
auto *vchg = ctx->mCurrentVoiceChange.load(std::memory_order_acquire);
while(auto *next = vchg->mNext.load(std::memory_order_acquire))
vchg = next;
ctx->mCurrentVoiceChange.store(vchg, std::memory_order_release);
ctx->mVoiceClusters.clear();
ctx->allocVoices(std::max<size_t>(256,
ctx->mActiveVoiceCount.load(std::memory_order_relaxed)));
}
dev->Connected.store(true);
}
ALCenum err{UpdateDeviceParams(dev.get(), attribs)};
if LIKELY(err == ALC_NO_ERROR) return ALC_TRUE;
alcSetError(dev.get(), err);
return ALC_FALSE;
}
END_API_FUNC
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