media/libeffects/testlibs/AudioPeakingFilter.h - platform/frameworks/av - Git at Google

 /* //device/include/server/AudioFlinger/AudioPeakingFilter.h
 **
 ** Copyright 2009, The Android Open Source Project
 **
 ** Licensed under the Apache License, Version 2.0 (the "License");
 ** you may not use this file except in compliance with the License.
 ** You may obtain a copy of the License at
 **
 **     http://www.apache.org/licenses/LICENSE-2.0
 **
 ** Unless required by applicable law or agreed to in writing, software
 ** distributed under the License is distributed on an "AS IS" BASIS,
 ** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 ** See the License for the specific language governing permissions and
 ** limitations under the License.
 */

 #ifndef ANDROID_AUDIO_PEAKING_FILTER_H
 #define ANDROID_AUDIO_PEAKING_FILTER_H

 #include "AudioBiquadFilter.h"
 #include "AudioCoefInterpolator.h"

 namespace android {

 // A peaking audio filter, with unity skirt gain, and controllable peak
 // frequency, gain and bandwidth.
 // This filter is able to suppress introduce discontinuities and other artifacts
 // in the output, even when changing parameters abruptly.
 // Parameters can be set to any value - this class will make sure to clip them
 // when they are out of supported range.
 //
 // Implementation notes:
 // This class uses an underlying biquad filter whose parameters are determined
 // using a linear interpolation from a coefficient table, using a
 // AudioCoefInterpolator.
 // All is left for this class to do is mapping between high-level parameters to
 // fractional indices into the coefficient table.
 class AudioPeakingFilter {
 public:
     // Constructor. Resets the filter (see reset()).
     // nChannels  Number of input/output channels (interlaced).
     // sampleRate The input/output sample rate, in Hz.
     AudioPeakingFilter(int nChannels, int sampleRate);

     // Reconfiguration of the filter. Changes input/output format, but does not
     // alter current parameter values. Clears delay lines.
     // nChannels  Number of input/output channels (interlaced).
     // sampleRate The input/output sample rate, in Hz.
     void configure(int nChannels, int sampleRate);

     // Resets the filter parameters to the following values:
     // frequency: 0
     // gain: 0
     // bandwidth: 1200 cents.
     // It also disables the filter. Does not clear the delay lines.
     void reset();

     // Clears delay lines. Does not alter parameter values.
     void clear() { mBiquad.clear(); }

     // Sets gain value. Actual change will only take place upon commit().
     // This value will be remembered even if the filter is in disabled() state.
     // millibel Gain value in millibel (1/100 of decibel).
     void setGain(int32_t millibel);

     // Gets the gain, in millibel, as set.
     int32_t getGain() const { return mGain - 9600; }

     // Sets bandwidth value. Actual change will only take place upon commit().
     // This value will be remembered even if the filter is in disabled() state.
     // cents Bandwidth value in cents (1/1200 octave).
     void setBandwidth(uint32_t cents);

     // Gets the gain, in cents, as set.
     uint32_t getBandwidth() const { return mBandwidth + 1; }

     // Sets frequency value. Actual change will only take place upon commit().
     // This value will be remembered even if the filter is in disabled() state.
     // millihertz Frequency value in mHz.
     void setFrequency(uint32_t millihertz);

     // Gets the frequency, in mHz, as set.
     uint32_t getFrequency() const { return mNominalFrequency; }

     // Gets gain[dB]/2 points.
     // Results in mHz, and are computed based on the nominal values set, not on
     // possibly rounded or truncated actual values.
     void getBandRange(uint32_t & low, uint32_t & high) const;

     // Applies all parameter changes done to this point in time.
     // If the filter is disabled, the new parameters will take place when it is
     // enabled again. Does not introduce artifacts, unless immediate is set.
     // immediate    Whether to apply change abruptly (ignored if filter is
     // disabled).
    void commit(bool immediate = false);

     // Process a buffer of input data. The input and output should contain
     // frameCount * nChannels interlaced samples. Processing can be done
     // in-place, by passing the same buffer as both arguments.
     // in           Input buffer.
     // out          Output buffer.
     // frameCount   Number of frames to produce.
     void process(const audio_sample_t in[], audio_sample_t out[],
                  int frameCount) { mBiquad.process(in, out, frameCount); }

     // Enables the filter, so it would start processing input. Does not
     // introduce artifacts, unless immediate is set.
     // immediate    Whether to apply change abruptly.
     void enable(bool immediate = false) { mBiquad.enable(immediate); }

     // Disabled (bypasses) the filter. Does not introduce artifacts, unless
     // immediate is set.
     // immediate    Whether to apply change abruptly.
     void disable(bool immediate = false) { mBiquad.disable(immediate); }

 private:
     // Precision for the mFrequency member.
     static const int FREQ_PRECISION_BITS = 26;
     // Precision for the mGain member.
     static const int GAIN_PRECISION_BITS = 10;
     // Precision for the mBandwidth member.
     static const int BANDWIDTH_PRECISION_BITS = 10;

     // Nyquist, in mHz.
     uint32_t mNiquistFreq;
     // Fractional index into the gain dimension of the coef table in
     // GAIN_PRECISION_BITS precision.
     int32_t mGain;
     // Fractional index into the bandwidth dimension of the coef table in
     // BANDWIDTH_PRECISION_BITS precision.
     uint32_t mBandwidth;
     // Fractional index into the frequency dimension of the coef table in
     // FREQ_PRECISION_BITS precision.
     uint32_t mFrequency;
     // Nominal value of frequency, as set.
     uint32_t mNominalFrequency;
     // 1/Nyquist[mHz], in 42-bit precision (very small).
     // Used for scaling the frequency.
     uint32_t mFrequencyFactor;

     // A biquad filter, used for the actual processing.
     AudioBiquadFilter mBiquad;
     // A coefficient interpolator, used for mapping the high level parameters to
     // the low-level biquad coefficients.
     static AudioCoefInterpolator mCoefInterp;
 };

 }

 #endif // ANDROID_AUDIO_PEAKING_FILTER_H
	/* //device/include/server/AudioFlinger/AudioPeakingFilter.h
	**
	** Copyright 2009, The Android Open Source Project
	**
	** Licensed under the Apache License, Version 2.0 (the "License");
	** you may not use this file except in compliance with the License.
	** You may obtain a copy of the License at
	**
	** http://www.apache.org/licenses/LICENSE-2.0
	**
	** Unless required by applicable law or agreed to in writing, software
	** distributed under the License is distributed on an "AS IS" BASIS,
	** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	** See the License for the specific language governing permissions and
	** limitations under the License.
	*/

	#ifndef ANDROID_AUDIO_PEAKING_FILTER_H
	#define ANDROID_AUDIO_PEAKING_FILTER_H

	#include "AudioBiquadFilter.h"
	#include "AudioCoefInterpolator.h"

	namespace android {

	// A peaking audio filter, with unity skirt gain, and controllable peak
	// frequency, gain and bandwidth.
	// This filter is able to suppress introduce discontinuities and other artifacts
	// in the output, even when changing parameters abruptly.
	// Parameters can be set to any value - this class will make sure to clip them
	// when they are out of supported range.
	//
	// Implementation notes:
	// This class uses an underlying biquad filter whose parameters are determined
	// using a linear interpolation from a coefficient table, using a
	// AudioCoefInterpolator.
	// All is left for this class to do is mapping between high-level parameters to
	// fractional indices into the coefficient table.
	class AudioPeakingFilter {
	public:
	// Constructor. Resets the filter (see reset()).
	// nChannels Number of input/output channels (interlaced).
	// sampleRate The input/output sample rate, in Hz.
	AudioPeakingFilter(int nChannels, int sampleRate);

	// Reconfiguration of the filter. Changes input/output format, but does not
	// alter current parameter values. Clears delay lines.
	// nChannels Number of input/output channels (interlaced).
	// sampleRate The input/output sample rate, in Hz.
	void configure(int nChannels, int sampleRate);

	// Resets the filter parameters to the following values:
	// frequency: 0
	// gain: 0
	// bandwidth: 1200 cents.
	// It also disables the filter. Does not clear the delay lines.
	void reset();

	// Clears delay lines. Does not alter parameter values.
	void clear() { mBiquad.clear(); }

	// Sets gain value. Actual change will only take place upon commit().
	// This value will be remembered even if the filter is in disabled() state.
	// millibel Gain value in millibel (1/100 of decibel).
	void setGain(int32_t millibel);

	// Gets the gain, in millibel, as set.
	int32_t getGain() const { return mGain - 9600; }

	// Sets bandwidth value. Actual change will only take place upon commit().
	// This value will be remembered even if the filter is in disabled() state.
	// cents Bandwidth value in cents (1/1200 octave).
	void setBandwidth(uint32_t cents);

	// Gets the gain, in cents, as set.
	uint32_t getBandwidth() const { return mBandwidth + 1; }

	// Sets frequency value. Actual change will only take place upon commit().
	// This value will be remembered even if the filter is in disabled() state.
	// millihertz Frequency value in mHz.
	void setFrequency(uint32_t millihertz);

	// Gets the frequency, in mHz, as set.
	uint32_t getFrequency() const { return mNominalFrequency; }

	// Gets gain[dB]/2 points.
	// Results in mHz, and are computed based on the nominal values set, not on
	// possibly rounded or truncated actual values.
	void getBandRange(uint32_t & low, uint32_t & high) const;

	// Applies all parameter changes done to this point in time.
	// If the filter is disabled, the new parameters will take place when it is
	// enabled again. Does not introduce artifacts, unless immediate is set.
	// immediate Whether to apply change abruptly (ignored if filter is
	// disabled).
	void commit(bool immediate = false);

	// Process a buffer of input data. The input and output should contain
	// frameCount * nChannels interlaced samples. Processing can be done
	// in-place, by passing the same buffer as both arguments.
	// in Input buffer.
	// out Output buffer.
	// frameCount Number of frames to produce.
	void process(const audio_sample_t in[], audio_sample_t out[],
	int frameCount) { mBiquad.process(in, out, frameCount); }

	// Enables the filter, so it would start processing input. Does not
	// introduce artifacts, unless immediate is set.
	// immediate Whether to apply change abruptly.
	void enable(bool immediate = false) { mBiquad.enable(immediate); }

	// Disabled (bypasses) the filter. Does not introduce artifacts, unless
	// immediate is set.
	// immediate Whether to apply change abruptly.
	void disable(bool immediate = false) { mBiquad.disable(immediate); }

	private:
	// Precision for the mFrequency member.
	static const int FREQ_PRECISION_BITS = 26;
	// Precision for the mGain member.
	static const int GAIN_PRECISION_BITS = 10;
	// Precision for the mBandwidth member.
	static const int BANDWIDTH_PRECISION_BITS = 10;

	// Nyquist, in mHz.
	uint32_t mNiquistFreq;
	// Fractional index into the gain dimension of the coef table in
	// GAIN_PRECISION_BITS precision.
	int32_t mGain;
	// Fractional index into the bandwidth dimension of the coef table in
	// BANDWIDTH_PRECISION_BITS precision.
	uint32_t mBandwidth;
	// Fractional index into the frequency dimension of the coef table in
	// FREQ_PRECISION_BITS precision.
	uint32_t mFrequency;
	// Nominal value of frequency, as set.
	uint32_t mNominalFrequency;
	// 1/Nyquist[mHz], in 42-bit precision (very small).
	// Used for scaling the frequency.
	uint32_t mFrequencyFactor;

	// A biquad filter, used for the actual processing.
	AudioBiquadFilter mBiquad;
	// A coefficient interpolator, used for mapping the high level parameters to
	// the low-level biquad coefficients.
	static AudioCoefInterpolator mCoefInterp;
	};

	}

	#endif // ANDROID_AUDIO_PEAKING_FILTER_H