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#include "config.h"
#include <cassert>
#include <cmath>
#include <limits>
#include "alnumeric.h"
#include "core/bsinc_defs.h"
#include "core/cubic_defs.h"
#include "defs.h"
#include "hrtfbase.h"
struct CTag;
struct PointTag;
struct LerpTag;
struct CubicTag;
struct BSincTag;
struct FastBSincTag;
namespace {
constexpr uint BsincPhaseDiffBits{MixerFracBits - BSincPhaseBits};
constexpr uint BsincPhaseDiffOne{1 << BsincPhaseDiffBits};
constexpr uint BsincPhaseDiffMask{BsincPhaseDiffOne - 1u};
constexpr uint CubicPhaseDiffBits{MixerFracBits - CubicPhaseBits};
constexpr uint CubicPhaseDiffOne{1 << CubicPhaseDiffBits};
constexpr uint CubicPhaseDiffMask{CubicPhaseDiffOne - 1u};
inline float do_point(const float *RESTRICT vals, const uint)
{ return vals[0]; }
inline float do_lerp(const float *RESTRICT vals, const uint frac)
{ return lerpf(vals[0], vals[1], static_cast<float>(frac)*(1.0f/MixerFracOne)); }
inline float do_cubic(const CubicState &istate, const float *RESTRICT vals, const uint frac)
{
/* Calculate the phase index and factor. */
const uint pi{frac >> CubicPhaseDiffBits};
const float pf{static_cast<float>(frac&CubicPhaseDiffMask) * (1.0f/CubicPhaseDiffOne)};
const float *RESTRICT fil{al::assume_aligned<16>(istate.filter[pi].mCoeffs.data())};
const float *RESTRICT phd{al::assume_aligned<16>(istate.filter[pi].mDeltas.data())};
/* Apply the phase interpolated filter. */
return (fil[0] + pf*phd[0])*vals[0] + (fil[1] + pf*phd[1])*vals[1]
+ (fil[2] + pf*phd[2])*vals[2] + (fil[3] + pf*phd[3])*vals[3];
}
inline float do_bsinc(const BsincState &istate, const float *RESTRICT vals, const uint frac)
{
const size_t m{istate.m};
ASSUME(m > 0);
/* Calculate the phase index and factor. */
const uint pi{frac >> BsincPhaseDiffBits};
const float pf{static_cast<float>(frac&BsincPhaseDiffMask) * (1.0f/BsincPhaseDiffOne)};
const float *RESTRICT fil{istate.filter + m*pi*2_uz};
const float *RESTRICT phd{fil + m};
const float *RESTRICT scd{fil + BSincPhaseCount*2_uz*m};
const float *RESTRICT spd{scd + m};
/* Apply the scale and phase interpolated filter. */
float r{0.0f};
for(size_t j_f{0};j_f < m;j_f++)
r += (fil[j_f] + istate.sf*scd[j_f] + pf*(phd[j_f] + istate.sf*spd[j_f])) * vals[j_f];
return r;
}
inline float do_fastbsinc(const BsincState &istate, const float *RESTRICT vals, const uint frac)
{
const size_t m{istate.m};
ASSUME(m > 0);
/* Calculate the phase index and factor. */
const uint pi{frac >> BsincPhaseDiffBits};
const float pf{static_cast<float>(frac&BsincPhaseDiffMask) * (1.0f/BsincPhaseDiffOne)};
const float *RESTRICT fil{istate.filter + m*pi*2_uz};
const float *RESTRICT phd{fil + m};
/* Apply the phase interpolated filter. */
float r{0.0f};
for(size_t j_f{0};j_f < m;j_f++)
r += (fil[j_f] + pf*phd[j_f]) * vals[j_f];
return r;
}
using SamplerT = float(&)(const float*RESTRICT, const uint);
template<SamplerT Sampler>
void DoResample(const float *RESTRICT src, uint frac, const uint increment,
const al::span<float> dst)
{
ASSUME(frac < MixerFracOne);
for(float &out : dst)
{
out = Sampler(src, frac);
frac += increment;
src += frac>>MixerFracBits;
frac &= MixerFracMask;
}
}
template<typename T, typename U>
void DoResample(T sampler, const U istate, const float *RESTRICT src, uint frac,
const uint increment, const al::span<float> dst)
{
ASSUME(frac < MixerFracOne);
for(float &out : dst)
{
out = sampler(istate, src, frac);
frac += increment;
src += frac>>MixerFracBits;
frac &= MixerFracMask;
}
}
inline void ApplyCoeffs(float2 *RESTRICT Values, const size_t IrSize, const ConstHrirSpan Coeffs,
const float left, const float right)
{
ASSUME(IrSize >= MinIrLength);
for(size_t c{0};c < IrSize;++c)
{
Values[c][0] += Coeffs[c][0] * left;
Values[c][1] += Coeffs[c][1] * right;
}
}
force_inline void MixLine(const al::span<const float> InSamples, float *RESTRICT dst,
float &CurrentGain, const float TargetGain, const float delta, const size_t min_len,
size_t Counter)
{
float gain{CurrentGain};
const float step{(TargetGain-gain) * delta};
size_t pos{0};
if(!(std::abs(step) > std::numeric_limits<float>::epsilon()))
gain = TargetGain;
else
{
float step_count{0.0f};
for(;pos != min_len;++pos)
{
dst[pos] += InSamples[pos] * (gain + step*step_count);
step_count += 1.0f;
}
if(pos == Counter)
gain = TargetGain;
else
gain += step*step_count;
}
CurrentGain = gain;
if(!(std::abs(gain) > GainSilenceThreshold))
return;
for(;pos != InSamples.size();++pos)
dst[pos] += InSamples[pos] * gain;
}
} // namespace
template<>
void Resample_<PointTag,CTag>(const InterpState*, const float *RESTRICT src, uint frac,
const uint increment, const al::span<float> dst)
{ DoResample<do_point>(src, frac, increment, dst); }
template<>
void Resample_<LerpTag,CTag>(const InterpState*, const float *RESTRICT src, uint frac,
const uint increment, const al::span<float> dst)
{ DoResample<do_lerp>(src, frac, increment, dst); }
template<>
void Resample_<CubicTag,CTag>(const InterpState *state, const float *RESTRICT src, uint frac,
const uint increment, const al::span<float> dst)
{ DoResample(do_cubic, std::get<CubicState>(*state), src-1, frac, increment, dst); }
template<>
void Resample_<BSincTag,CTag>(const InterpState *state, const float *RESTRICT src, uint frac,
const uint increment, const al::span<float> dst)
{
const auto istate = std::get<BsincState>(*state);
DoResample(do_bsinc, istate, src-istate.l, frac, increment, dst);
}
template<>
void Resample_<FastBSincTag,CTag>(const InterpState *state, const float *RESTRICT src, uint frac,
const uint increment, const al::span<float> dst)
{
const auto istate = std::get<BsincState>(*state);
DoResample(do_fastbsinc, istate, src-istate.l, frac, increment, dst);
}
template<>
void MixHrtf_<CTag>(const float *InSamples, float2 *AccumSamples, const uint IrSize,
const MixHrtfFilter *hrtfparams, const size_t BufferSize)
{ MixHrtfBase<ApplyCoeffs>(InSamples, AccumSamples, IrSize, hrtfparams, BufferSize); }
template<>
void MixHrtfBlend_<CTag>(const float *InSamples, float2 *AccumSamples, const uint IrSize,
const HrtfFilter *oldparams, const MixHrtfFilter *newparams, const size_t BufferSize)
{
MixHrtfBlendBase<ApplyCoeffs>(InSamples, AccumSamples, IrSize, oldparams, newparams,
BufferSize);
}
template<>
void MixDirectHrtf_<CTag>(const FloatBufferSpan LeftOut, const FloatBufferSpan RightOut,
const al::span<const FloatBufferLine> InSamples, float2 *AccumSamples,
float *TempBuf, HrtfChannelState *ChanState, const size_t IrSize, const size_t BufferSize)
{
MixDirectHrtfBase<ApplyCoeffs>(LeftOut, RightOut, InSamples, AccumSamples, TempBuf, ChanState,
IrSize, BufferSize);
}
template<>
void Mix_<CTag>(const al::span<const float> InSamples, const al::span<FloatBufferLine> OutBuffer,
float *CurrentGains, const float *TargetGains, const size_t Counter, const size_t OutPos)
{
const float delta{(Counter > 0) ? 1.0f / static_cast<float>(Counter) : 0.0f};
const auto min_len = minz(Counter, InSamples.size());
for(FloatBufferLine &output : OutBuffer)
MixLine(InSamples, al::assume_aligned<16>(output.data()+OutPos), *CurrentGains++,
*TargetGains++, delta, min_len, Counter);
}
template<>
void Mix_<CTag>(const al::span<const float> InSamples, float *OutBuffer, float &CurrentGain,
const float TargetGain, const size_t Counter)
{
const float delta{(Counter > 0) ? 1.0f / static_cast<float>(Counter) : 0.0f};
const auto min_len = minz(Counter, InSamples.size());
MixLine(InSamples, al::assume_aligned<16>(OutBuffer), CurrentGain,
TargetGain, delta, min_len, Counter);
}
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