#ifndef FILTERS_BIQUAD_H #define FILTERS_BIQUAD_H #include #include #include "AL/al.h" #include "math_defs.h" /* Filters implementation is based on the "Cookbook formulae for audio * EQ biquad filter coefficients" by Robert Bristow-Johnson * http://www.musicdsp.org/files/Audio-EQ-Cookbook.txt */ /* Implementation note: For the shelf filters, the specified gain is for the * reference frequency, which is the centerpoint of the transition band. This * better matches EFX filter design. To set the gain for the shelf itself, use * the square root of the desired linear gain (or halve the dB gain). */ enum class BiquadType { /** EFX-style low-pass filter, specifying a gain and reference frequency. */ HighShelf, /** EFX-style high-pass filter, specifying a gain and reference frequency. */ LowShelf, /** Peaking filter, specifying a gain and reference frequency. */ Peaking, /** Low-pass cut-off filter, specifying a cut-off frequency. */ LowPass, /** High-pass cut-off filter, specifying a cut-off frequency. */ HighPass, /** Band-pass filter, specifying a center frequency. */ BandPass, }; class BiquadFilter { /* Last two delayed components for direct form II. */ float z1{0.0f}, z2{0.0f}; /* Transfer function coefficients "b" (numerator) */ float b0{1.0f}, b1{0.0f}, b2{0.0f}; /* Transfer function coefficients "a" (denominator; a0 is pre-applied). */ float a1{0.0f}, a2{0.0f}; public: void clear() noexcept { z1 = z2 = 0.0f; } /** * Sets the filter state for the specified filter type and its parameters. * * \param type The type of filter to apply. * \param gain The gain for the reference frequency response. Only used by * the Shelf and Peaking filter types. * \param f0norm The reference frequency normal (ref_freq / sample_rate). * This is the center point for the Shelf, Peaking, and * BandPass filter types, or the cutoff frequency for the * LowPass and HighPass filter types. * \param rcpQ The reciprocal of the Q coefficient for the filter's * transition band. Can be generated from calc_rcpQ_from_slope * or calc_rcpQ_from_bandwidth as needed. */ void setParams(BiquadType type, float gain, float f0norm, float rcpQ); void copyParamsFrom(const BiquadFilter &other) { b0 = other.b0; b1 = other.b1; b2 = other.b2; a1 = other.a1; a2 = other.a2; } void process(float *RESTRICT dst, const float *RESTRICT src, int numsamples); void passthru(int numsamples) noexcept { if(LIKELY(numsamples >= 2)) { z1 = 0.0f; z2 = 0.0f; } else if(numsamples == 1) { z1 = z2; z2 = 0.0f; } } /* Rather hacky. It's just here to support "manual" processing. */ std::pair getComponents() const noexcept { return {z1, z2}; } void setComponents(float z1_, float z2_) noexcept { z1 = z1_; z2 = z2_; } float processOne(const float in, float &z1_, float &z2_) const noexcept { float out{in*b0 + z1_}; z1_ = in*b1 - out*a1 + z2_; z2_ = in*b2 - out*a2; return out; } }; /** * Calculates the rcpQ (i.e. 1/Q) coefficient for shelving filters, using the * reference gain and shelf slope parameter. * \param gain 0 < gain * \param slope 0 < slope <= 1 */ inline float calc_rcpQ_from_slope(float gain, float slope) { return std::sqrt((gain + 1.0f/gain)*(1.0f/slope - 1.0f) + 2.0f); } /** * Calculates the rcpQ (i.e. 1/Q) coefficient for filters, using the normalized * reference frequency and bandwidth. * \param f0norm 0 < f0norm < 0.5. * \param bandwidth 0 < bandwidth */ inline ALfloat calc_rcpQ_from_bandwidth(float f0norm, float bandwidth) { float w0 = F_TAU * f0norm; return 2.0f*std::sinh(std::log(2.0f)/2.0f*bandwidth*w0/std::sin(w0)); } #endif /* FILTERS_BIQUAD_H */