#ifndef UHJFILTER_H #define UHJFILTER_H #include "AL/al.h" #include "alcmain.h" #include "almalloc.h" struct AllPassState { ALfloat z[2]{0.0f, 0.0f}; }; /* Encoding 2-channel UHJ from B-Format is done as: * * S = 0.9396926*W + 0.1855740*X * D = j(-0.3420201*W + 0.5098604*X) + 0.6554516*Y * * Left = (S + D)/2.0 * Right = (S - D)/2.0 * * where j is a wide-band +90 degree phase shift. * * The phase shift is done using a Hilbert transform, described here: * https://web.archive.org/web/20060708031958/http://www.biochem.oulu.fi/~oniemita/dsp/hilbert/ * It works using 2 sets of 4 chained filters. The first filter chain produces * a phase shift of varying magnitude over a wide range of frequencies, while * the second filter chain produces a phase shift 90 degrees ahead of the * first over the same range. * * Combining these two stages requires the use of three filter chains. S- * channel output uses a Filter1 chain on the W and X channel mix, while the D- * channel output uses a Filter1 chain on the Y channel plus a Filter2 chain on * the W and X channel mix. This results in the W and X input mix on the D- * channel output having the required +90 degree phase shift relative to the * other inputs. */ struct Uhj2Encoder { AllPassState mFilter1_Y[4]; AllPassState mFilter2_WX[4]; AllPassState mFilter1_WX[4]; ALfloat mLastY{0.0f}, mLastWX{0.0f}; /* Encodes a 2-channel UHJ (stereo-compatible) signal from a B-Format input * signal. The input must use FuMa channel ordering and scaling. */ void encode(FloatBufferLine &LeftOut, FloatBufferLine &RightOut, FloatBufferLine *InSamples, const size_t SamplesToDo); DEF_NEWDEL(Uhj2Encoder) }; #endif /* UHJFILTER_H */