#ifndef VOICE_H #define VOICE_H #include "AL/al.h" #include "AL/alext.h" #include "al/buffer.h" #include "alspan.h" #include "alu.h" #include "filters/biquad.h" #include "filters/nfc.h" #include "filters/splitter.h" #include "hrtf.h" enum class DistanceModel; enum SpatializeMode { SpatializeOff = AL_FALSE, SpatializeOn = AL_TRUE, SpatializeAuto = AL_AUTO_SOFT }; enum class Resampler { Point, Linear, Cubic, FastBSinc12, BSinc12, FastBSinc24, BSinc24, Max = BSinc24 }; extern Resampler ResamplerDefault; /* The number of distinct scale and phase intervals within the bsinc filter * table. */ #define BSINC_SCALE_BITS 4 #define BSINC_SCALE_COUNT (1< dst); ResamplerFunc PrepareResampler(Resampler resampler, ALuint increment, InterpState *state); enum { AF_None = 0, AF_LowPass = 1, AF_HighPass = 2, AF_BandPass = AF_LowPass | AF_HighPass }; struct MixHrtfFilter { const HrirArray *Coeffs; ALsizei Delay[2]; float Gain; float GainStep; }; struct DirectParams { BiquadFilter LowPass; BiquadFilter HighPass; NfcFilter NFCtrlFilter; struct { HrtfFilter Old; HrtfFilter Target; HrtfState State; } Hrtf; struct { float Current[MAX_OUTPUT_CHANNELS]; float Target[MAX_OUTPUT_CHANNELS]; } Gains; }; struct SendParams { BiquadFilter LowPass; BiquadFilter HighPass; struct { float Current[MAX_OUTPUT_CHANNELS]; float Target[MAX_OUTPUT_CHANNELS]; } Gains; }; struct ALvoicePropsBase { float Pitch; float Gain; float OuterGain; float MinGain; float MaxGain; float InnerAngle; float OuterAngle; float RefDistance; float MaxDistance; float RolloffFactor; std::array Position; std::array Velocity; std::array Direction; std::array OrientAt; std::array OrientUp; bool HeadRelative; DistanceModel mDistanceModel; Resampler mResampler; bool DirectChannels; SpatializeMode mSpatializeMode; bool DryGainHFAuto; bool WetGainAuto; bool WetGainHFAuto; float OuterGainHF; float AirAbsorptionFactor; float RoomRolloffFactor; float DopplerFactor; std::array StereoPan; float Radius; /** Direct filter and auxiliary send info. */ struct { float Gain; float GainHF; float HFReference; float GainLF; float LFReference; } Direct; struct SendData { ALeffectslot *Slot; float Gain; float GainHF; float HFReference; float GainLF; float LFReference; } Send[MAX_SENDS]; }; struct ALvoiceProps : public ALvoicePropsBase { std::atomic next{nullptr}; DEF_NEWDEL(ALvoiceProps) }; #define VOICE_IS_STATIC (1u<<0) #define VOICE_IS_FADING (1u<<1) /* Fading sources use gain stepping for smooth transitions. */ #define VOICE_IS_AMBISONIC (1u<<2) /* Voice needs HF scaling for ambisonic upsampling. */ #define VOICE_HAS_HRTF (1u<<3) #define VOICE_HAS_NFC (1u<<4) struct ALvoice { enum State { Stopped = 0, Playing = 1, Stopping = 2 }; std::atomic mUpdate{nullptr}; std::atomic mSourceID{0u}; std::atomic mPlayState{Stopped}; ALvoicePropsBase mProps; /** * Source offset in samples, relative to the currently playing buffer, NOT * the whole queue. */ std::atomic mPosition; /** Fractional (fixed-point) offset to the next sample. */ std::atomic mPositionFrac; /* Current buffer queue item being played. */ std::atomic mCurrentBuffer; /* Buffer queue item to loop to at end of queue (will be NULL for non- * looping voices). */ std::atomic mLoopBuffer; /* Properties for the attached buffer(s). */ FmtChannels mFmtChannels; ALuint mFrequency; ALuint mNumChannels; ALuint mSampleSize; /** Current target parameters used for mixing. */ ALuint mStep; ResamplerFunc mResampler; InterpState mResampleState; ALuint mFlags; struct DirectData { int FilterType; al::span Buffer; }; DirectData mDirect; struct SendData { int FilterType; al::span Buffer; }; std::array mSend; struct ChannelData { alignas(16) std::array mPrevSamples; float mAmbiScale; BandSplitter mAmbiSplitter; DirectParams mDryParams; std::array mWetParams; }; std::array mChans; ALvoice() = default; ALvoice(const ALvoice&) = delete; ALvoice(ALvoice&& rhs) noexcept { *this = std::move(rhs); } ~ALvoice() { delete mUpdate.exchange(nullptr, std::memory_order_acq_rel); } ALvoice& operator=(const ALvoice&) = delete; ALvoice& operator=(ALvoice&& rhs) noexcept { ALvoiceProps *old_update{mUpdate.load(std::memory_order_relaxed)}; mUpdate.store(rhs.mUpdate.exchange(old_update, std::memory_order_relaxed), std::memory_order_relaxed); mSourceID.store(rhs.mSourceID.load(std::memory_order_relaxed), std::memory_order_relaxed); mPlayState.store(rhs.mPlayState.load(std::memory_order_relaxed), std::memory_order_relaxed); mProps = rhs.mProps; mPosition.store(rhs.mPosition.load(std::memory_order_relaxed), std::memory_order_relaxed); mPositionFrac.store(rhs.mPositionFrac.load(std::memory_order_relaxed), std::memory_order_relaxed); mCurrentBuffer.store(rhs.mCurrentBuffer.load(std::memory_order_relaxed), std::memory_order_relaxed); mLoopBuffer.store(rhs.mLoopBuffer.load(std::memory_order_relaxed), std::memory_order_relaxed); mFmtChannels = rhs.mFmtChannels; mFrequency = rhs.mFrequency; mNumChannels = rhs.mNumChannels; mSampleSize = rhs.mSampleSize; mStep = rhs.mStep; mResampler = rhs.mResampler; mResampleState = rhs.mResampleState; mFlags = rhs.mFlags; mDirect = rhs.mDirect; mSend = rhs.mSend; mChans = rhs.mChans; return *this; } void mix(ALvoice::State vstate, ALCcontext *Context, const ALuint SamplesToDo); }; #endif /* VOICE_H */