#ifndef ALC_HRTF_H #define ALC_HRTF_H #include #include #include #include #include "AL/al.h" #include "almalloc.h" #include "alspan.h" #include "ambidefs.h" #include "atomic.h" #include "vector.h" struct HrtfHandle; #define HRTF_HISTORY_BITS (6) #define HRTF_HISTORY_LENGTH (1<; using HrirArray = std::array; struct HrtfState { alignas(16) std::array History; alignas(16) HrirArray Values; }; struct HrtfFilter { alignas(16) HrirArray Coeffs; ALsizei Delay[2]; ALfloat Gain; }; struct DirectHrtfState { /* HRTF filter state for dry buffer content */ ALuint IrSize{0}; alignas(16) HrirArray Values; al::FlexArray Coeffs; DirectHrtfState(size_t numchans) : Coeffs{numchans} { } static std::unique_ptr Create(size_t num_chans); DEF_FAM_NEWDEL(DirectHrtfState, Coeffs) }; struct AngularPoint { ALfloat Elev; ALfloat Azim; }; al::vector EnumerateHrtf(const char *devname); HrtfEntry *GetLoadedHrtf(HrtfHandle *handle); void GetHrtfCoeffs(const HrtfEntry *Hrtf, ALfloat elevation, ALfloat azimuth, ALfloat distance, ALfloat spread, HrirArray &coeffs, ALsizei (&delays)[2]); /** * Produces HRTF filter coefficients for decoding B-Format, given a set of * virtual speaker positions, a matching decoding matrix, and per-order high- * frequency gains for the decoder. The calculated impulse responses are * ordered and scaled according to the matrix input. */ void BuildBFormatHrtf(const HrtfEntry *Hrtf, DirectHrtfState *state, const al::span AmbiPoints, const ALfloat (*AmbiMatrix)[MAX_AMBI_CHANNELS], const ALfloat *AmbiOrderHFGain); #endif /* ALC_HRTF_H */