media/libeffects/testlibs/AudioEqualizer.cpp - third_party/android/platform/frameworks/av - Git at Google

 /*
  * 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.
  */

 #define LOG_TAG "AudioEqualizer"

 #include <assert.h>
 #include <stdlib.h>
 #include <new>
 #include <utils/Log.h>

 #include "AudioEqualizer.h"
 #include "AudioPeakingFilter.h"
 #include "AudioShelvingFilter.h"
 #include "EffectsMath.h"

 namespace android {

 size_t AudioEqualizer::GetInstanceSize(int nBands) {
     assert(nBands >= 2);
     return sizeof(AudioEqualizer) +
            sizeof(AudioShelvingFilter) * 2 +
            sizeof(AudioPeakingFilter) * (nBands - 2);
 }

 AudioEqualizer * AudioEqualizer::CreateInstance(void * pMem, int nBands,
                                                 int nChannels, int sampleRate,
                                                 const PresetConfig * presets,
                                                 int nPresets) {
     ALOGV("AudioEqualizer::CreateInstance(pMem=%p, nBands=%d, nChannels=%d, "
          "sampleRate=%d, nPresets=%d)",
          pMem, nBands, nChannels, sampleRate, nPresets);
     assert(nBands >= 2);
     bool ownMem = false;
     if (pMem == NULL) {
         pMem = malloc(GetInstanceSize(nBands));
         if (pMem == NULL) {
             return NULL;
         }
         ownMem = true;
     }
     return new (pMem) AudioEqualizer(pMem, nBands, nChannels, sampleRate,
                                      ownMem, presets, nPresets);
 }

 void AudioEqualizer::configure(int nChannels, int sampleRate) {
     ALOGV("AudioEqualizer::configure(nChannels=%d, sampleRate=%d)", nChannels,
          sampleRate);
     mpLowShelf->configure(nChannels, sampleRate);
     for (int i = 0; i < mNumPeaking; ++i) {
         mpPeakingFilters[i].configure(nChannels, sampleRate);
     }
     mpHighShelf->configure(nChannels, sampleRate);
 }

 void AudioEqualizer::clear() {
     ALOGV("AudioEqualizer::clear()");
     mpLowShelf->clear();
     for (int i = 0; i < mNumPeaking; ++i) {
         mpPeakingFilters[i].clear();
     }
     mpHighShelf->clear();
 }

 void AudioEqualizer::free() {
     ALOGV("AudioEqualizer::free()");
     if (mpMem != NULL) {
         ::free(mpMem);
     }
 }

 void AudioEqualizer::reset() {
     ALOGV("AudioEqualizer::reset()");
     const int32_t bottom = Effects_log2(kMinFreq);
     const int32_t top = Effects_log2(mSampleRate * 500);
     const int32_t jump = (top - bottom) / (mNumPeaking + 2);
     int32_t centerFreq = bottom + jump/2;

     mpLowShelf->reset();
     mpLowShelf->setFrequency(Effects_exp2(centerFreq));
     centerFreq += jump;
     for (int i = 0; i < mNumPeaking; ++i) {
         mpPeakingFilters[i].reset();
         mpPeakingFilters[i].setFrequency(Effects_exp2(centerFreq));
         centerFreq += jump;
     }
     mpHighShelf->reset();
     mpHighShelf->setFrequency(Effects_exp2(centerFreq));
     commit(true);
     mCurPreset = PRESET_CUSTOM;
 }

 void AudioEqualizer::setGain(int band, int32_t millibel) {
     ALOGV("AudioEqualizer::setGain(band=%d, millibel=%d)", band, millibel);
     assert(band >= 0 && band < mNumPeaking + 2);
     if (band == 0) {
         mpLowShelf->setGain(millibel);
     } else if (band == mNumPeaking + 1) {
         mpHighShelf->setGain(millibel);
     } else {
         mpPeakingFilters[band - 1].setGain(millibel);
     }
     mCurPreset = PRESET_CUSTOM;
 }

 void AudioEqualizer::setFrequency(int band, uint32_t millihertz) {
     ALOGV("AudioEqualizer::setFrequency(band=%d, millihertz=%d)", band,
          millihertz);
     assert(band >= 0 && band < mNumPeaking + 2);
     if (band == 0) {
         mpLowShelf->setFrequency(millihertz);
     } else if (band == mNumPeaking + 1) {
         mpHighShelf->setFrequency(millihertz);
     } else {
         mpPeakingFilters[band - 1].setFrequency(millihertz);
     }
     mCurPreset = PRESET_CUSTOM;
 }

 void AudioEqualizer::setBandwidth(int band, uint32_t cents) {
     ALOGV("AudioEqualizer::setBandwidth(band=%d, cents=%d)", band, cents);
     assert(band >= 0 && band < mNumPeaking + 2);
     if (band > 0 && band < mNumPeaking + 1) {
         mpPeakingFilters[band - 1].setBandwidth(cents);
         mCurPreset = PRESET_CUSTOM;
     }
 }

 int32_t AudioEqualizer::getGain(int band) const {
     assert(band >= 0 && band < mNumPeaking + 2);
     if (band == 0) {
         return mpLowShelf->getGain();
     } else if (band == mNumPeaking + 1) {
         return mpHighShelf->getGain();
     } else {
         return mpPeakingFilters[band - 1].getGain();
     }
 }

 uint32_t AudioEqualizer::getFrequency(int band) const {
     assert(band >= 0 && band < mNumPeaking + 2);
     if (band == 0) {
         return mpLowShelf->getFrequency();
     } else if (band == mNumPeaking + 1) {
         return mpHighShelf->getFrequency();
     } else {
         return mpPeakingFilters[band - 1].getFrequency();
     }
 }

 uint32_t AudioEqualizer::getBandwidth(int band) const {
     assert(band >= 0 && band < mNumPeaking + 2);
     if (band == 0 || band == mNumPeaking + 1) {
         return 0;
     } else {
         return mpPeakingFilters[band - 1].getBandwidth();
     }
 }

 void AudioEqualizer::getBandRange(int band, uint32_t & low,
                                   uint32_t & high) const {
     assert(band >= 0 && band < mNumPeaking + 2);
     if (band == 0) {
         low = 0;
         high = mpLowShelf->getFrequency();
     } else if (band == mNumPeaking + 1) {
         low = mpHighShelf->getFrequency();
         high = mSampleRate * 500;
     } else {
         mpPeakingFilters[band - 1].getBandRange(low, high);
     }
 }

 const char * AudioEqualizer::getPresetName(int preset) const {
     assert(preset < mNumPresets && preset >= PRESET_CUSTOM);
     if (preset == PRESET_CUSTOM) {
         return "Custom";
     } else {
         return mpPresets[preset].name;
     }
 }

 int AudioEqualizer::getNumPresets() const {
     return mNumPresets;
 }

 int AudioEqualizer::getPreset() const {
     return mCurPreset;
 }

 void AudioEqualizer::setPreset(int preset) {
     ALOGV("AudioEqualizer::setPreset(preset=%d)", preset);
     assert(preset < mNumPresets && preset >= 0);
     const PresetConfig &presetCfg = mpPresets[preset];
     for (int band = 0; band < (mNumPeaking + 2); ++band) {
         const BandConfig & bandCfg = presetCfg.bandConfigs[band];
         setGain(band, bandCfg.gain);
         setFrequency(band, bandCfg.freq);
         setBandwidth(band, bandCfg.bandwidth);
     }
     mCurPreset = preset;
 }

 void AudioEqualizer::commit(bool immediate) {
     ALOGV("AudioEqualizer::commit(immediate=%d)", immediate);
     mpLowShelf->commit(immediate);
     for (int i = 0; i < mNumPeaking; ++i) {
         mpPeakingFilters[i].commit(immediate);
     }
     mpHighShelf->commit(immediate);
 }

 void AudioEqualizer::process(const audio_sample_t * pIn,
                              audio_sample_t * pOut,
                              int frameCount) {
 //    ALOGV("AudioEqualizer::process(frameCount=%d)", frameCount);
     mpLowShelf->process(pIn, pOut, frameCount);
     for (int i = 0; i < mNumPeaking; ++i) {
         mpPeakingFilters[i].process(pIn, pOut, frameCount);
     }
     mpHighShelf->process(pIn, pOut, frameCount);
 }

 void AudioEqualizer::enable(bool immediate) {
     ALOGV("AudioEqualizer::enable(immediate=%d)", immediate);
     mpLowShelf->enable(immediate);
     for (int i = 0; i < mNumPeaking; ++i) {
         mpPeakingFilters[i].enable(immediate);
     }
     mpHighShelf->enable(immediate);
 }

 void AudioEqualizer::disable(bool immediate) {
     ALOGV("AudioEqualizer::disable(immediate=%d)", immediate);
     mpLowShelf->disable(immediate);
     for (int i = 0; i < mNumPeaking; ++i) {
         mpPeakingFilters[i].disable(immediate);
     }
     mpHighShelf->disable(immediate);
 }

 int AudioEqualizer::getMostRelevantBand(uint32_t targetFreq) const {
     // First, find the two bands that the target frequency is between.
     uint32_t low = mpLowShelf->getFrequency();
     if (targetFreq <= low) {
         return 0;
     }
     uint32_t high = mpHighShelf->getFrequency();
     if (targetFreq >= high) {
         return mNumPeaking + 1;
     }
     int band = mNumPeaking;
     for (int i = 0; i < mNumPeaking; ++i) {
         uint32_t freq = mpPeakingFilters[i].getFrequency();
         if (freq >= targetFreq) {
             high = freq;
             band = i;
             break;
         }
         low = freq;
     }
     // Now, low is right below the target and high is right above. See which one
     // is closer on a log scale.
     low = Effects_log2(low);
     high = Effects_log2(high);
     targetFreq = Effects_log2(targetFreq);
     if (high - targetFreq < targetFreq - low) {
         return band + 1;
     } else {
         return band;
     }
 }


 AudioEqualizer::AudioEqualizer(void * pMem, int nBands, int nChannels,
                                int sampleRate, bool ownMem,
                                const PresetConfig * presets, int nPresets)
                                : mSampleRate(sampleRate)
                                , mpPresets(presets)
                                , mNumPresets(nPresets) {
     assert(pMem != NULL);
     assert(nPresets == 0 || nPresets > 0 && presets != NULL);
     mpMem = ownMem ? pMem : NULL;

     pMem = (char *) pMem + sizeof(AudioEqualizer);
     mpLowShelf = new (pMem) AudioShelvingFilter(AudioShelvingFilter::kLowShelf,
                                                 nChannels, sampleRate);
     pMem = (char *) pMem + sizeof(AudioShelvingFilter);
     mpHighShelf = new (pMem) AudioShelvingFilter(AudioShelvingFilter::kHighShelf,
                                                  nChannels, sampleRate);
     pMem = (char *) pMem + sizeof(AudioShelvingFilter);
     mNumPeaking = nBands - 2;
     if (mNumPeaking > 0) {
         mpPeakingFilters = reinterpret_cast<AudioPeakingFilter *>(pMem);
         for (int i = 0; i < mNumPeaking; ++i) {
             new (&mpPeakingFilters[i]) AudioPeakingFilter(nChannels,
                                                           sampleRate);
         }
     }
     reset();
 }

 }
	/*
	* 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.
	*/

	#define LOG_TAG "AudioEqualizer"

	#include <assert.h>
	#include <stdlib.h>
	#include <new>
	#include <utils/Log.h>

	#include "AudioEqualizer.h"
	#include "AudioPeakingFilter.h"
	#include "AudioShelvingFilter.h"
	#include "EffectsMath.h"

	namespace android {

	size_t AudioEqualizer::GetInstanceSize(int nBands) {
	assert(nBands >= 2);
	return sizeof(AudioEqualizer) +
	sizeof(AudioShelvingFilter) * 2 +
	sizeof(AudioPeakingFilter) * (nBands - 2);
	}

	AudioEqualizer * AudioEqualizer::CreateInstance(void * pMem, int nBands,
	int nChannels, int sampleRate,
	const PresetConfig * presets,
	int nPresets) {
	ALOGV("AudioEqualizer::CreateInstance(pMem=%p, nBands=%d, nChannels=%d, "
	"sampleRate=%d, nPresets=%d)",
	pMem, nBands, nChannels, sampleRate, nPresets);
	assert(nBands >= 2);
	bool ownMem = false;
	if (pMem == NULL) {
	pMem = malloc(GetInstanceSize(nBands));
	if (pMem == NULL) {
	return NULL;
	}
	ownMem = true;
	}
	return new (pMem) AudioEqualizer(pMem, nBands, nChannels, sampleRate,
	ownMem, presets, nPresets);
	}

	void AudioEqualizer::configure(int nChannels, int sampleRate) {
	ALOGV("AudioEqualizer::configure(nChannels=%d, sampleRate=%d)", nChannels,
	sampleRate);
	mpLowShelf->configure(nChannels, sampleRate);
	for (int i = 0; i < mNumPeaking; ++i) {
	mpPeakingFilters[i].configure(nChannels, sampleRate);
	}
	mpHighShelf->configure(nChannels, sampleRate);
	}

	void AudioEqualizer::clear() {
	ALOGV("AudioEqualizer::clear()");
	mpLowShelf->clear();
	for (int i = 0; i < mNumPeaking; ++i) {
	mpPeakingFilters[i].clear();
	}
	mpHighShelf->clear();
	}

	void AudioEqualizer::free() {
	ALOGV("AudioEqualizer::free()");
	if (mpMem != NULL) {
	::free(mpMem);
	}
	}

	void AudioEqualizer::reset() {
	ALOGV("AudioEqualizer::reset()");
	const int32_t bottom = Effects_log2(kMinFreq);
	const int32_t top = Effects_log2(mSampleRate * 500);
	const int32_t jump = (top - bottom) / (mNumPeaking + 2);
	int32_t centerFreq = bottom + jump/2;

	mpLowShelf->reset();
	mpLowShelf->setFrequency(Effects_exp2(centerFreq));
	centerFreq += jump;
	for (int i = 0; i < mNumPeaking; ++i) {
	mpPeakingFilters[i].reset();
	mpPeakingFilters[i].setFrequency(Effects_exp2(centerFreq));
	centerFreq += jump;
	}
	mpHighShelf->reset();
	mpHighShelf->setFrequency(Effects_exp2(centerFreq));
	commit(true);
	mCurPreset = PRESET_CUSTOM;
	}

	void AudioEqualizer::setGain(int band, int32_t millibel) {
	ALOGV("AudioEqualizer::setGain(band=%d, millibel=%d)", band, millibel);
	assert(band >= 0 && band < mNumPeaking + 2);
	if (band == 0) {
	mpLowShelf->setGain(millibel);
	} else if (band == mNumPeaking + 1) {
	mpHighShelf->setGain(millibel);
	} else {
	mpPeakingFilters[band - 1].setGain(millibel);
	}
	mCurPreset = PRESET_CUSTOM;
	}

	void AudioEqualizer::setFrequency(int band, uint32_t millihertz) {
	ALOGV("AudioEqualizer::setFrequency(band=%d, millihertz=%d)", band,
	millihertz);
	assert(band >= 0 && band < mNumPeaking + 2);
	if (band == 0) {
	mpLowShelf->setFrequency(millihertz);
	} else if (band == mNumPeaking + 1) {
	mpHighShelf->setFrequency(millihertz);
	} else {
	mpPeakingFilters[band - 1].setFrequency(millihertz);
	}
	mCurPreset = PRESET_CUSTOM;
	}

	void AudioEqualizer::setBandwidth(int band, uint32_t cents) {
	ALOGV("AudioEqualizer::setBandwidth(band=%d, cents=%d)", band, cents);
	assert(band >= 0 && band < mNumPeaking + 2);
	if (band > 0 && band < mNumPeaking + 1) {
	mpPeakingFilters[band - 1].setBandwidth(cents);
	mCurPreset = PRESET_CUSTOM;
	}
	}

	int32_t AudioEqualizer::getGain(int band) const {
	assert(band >= 0 && band < mNumPeaking + 2);
	if (band == 0) {
	return mpLowShelf->getGain();
	} else if (band == mNumPeaking + 1) {
	return mpHighShelf->getGain();
	} else {
	return mpPeakingFilters[band - 1].getGain();
	}
	}

	uint32_t AudioEqualizer::getFrequency(int band) const {
	assert(band >= 0 && band < mNumPeaking + 2);
	if (band == 0) {
	return mpLowShelf->getFrequency();
	} else if (band == mNumPeaking + 1) {
	return mpHighShelf->getFrequency();
	} else {
	return mpPeakingFilters[band - 1].getFrequency();
	}
	}

	uint32_t AudioEqualizer::getBandwidth(int band) const {
	assert(band >= 0 && band < mNumPeaking + 2);
	if (band == 0 \|\| band == mNumPeaking + 1) {
	return 0;
	} else {
	return mpPeakingFilters[band - 1].getBandwidth();
	}
	}

	void AudioEqualizer::getBandRange(int band, uint32_t & low,
	uint32_t & high) const {
	assert(band >= 0 && band < mNumPeaking + 2);
	if (band == 0) {
	low = 0;
	high = mpLowShelf->getFrequency();
	} else if (band == mNumPeaking + 1) {
	low = mpHighShelf->getFrequency();
	high = mSampleRate * 500;
	} else {
	mpPeakingFilters[band - 1].getBandRange(low, high);
	}
	}

	const char * AudioEqualizer::getPresetName(int preset) const {
	assert(preset < mNumPresets && preset >= PRESET_CUSTOM);
	if (preset == PRESET_CUSTOM) {
	return "Custom";
	} else {
	return mpPresets[preset].name;
	}
	}

	int AudioEqualizer::getNumPresets() const {
	return mNumPresets;
	}

	int AudioEqualizer::getPreset() const {
	return mCurPreset;
	}

	void AudioEqualizer::setPreset(int preset) {
	ALOGV("AudioEqualizer::setPreset(preset=%d)", preset);
	assert(preset < mNumPresets && preset >= 0);
	const PresetConfig &presetCfg = mpPresets[preset];
	for (int band = 0; band < (mNumPeaking + 2); ++band) {
	const BandConfig & bandCfg = presetCfg.bandConfigs[band];
	setGain(band, bandCfg.gain);
	setFrequency(band, bandCfg.freq);
	setBandwidth(band, bandCfg.bandwidth);
	}
	mCurPreset = preset;
	}

	void AudioEqualizer::commit(bool immediate) {
	ALOGV("AudioEqualizer::commit(immediate=%d)", immediate);
	mpLowShelf->commit(immediate);
	for (int i = 0; i < mNumPeaking; ++i) {
	mpPeakingFilters[i].commit(immediate);
	}
	mpHighShelf->commit(immediate);
	}

	void AudioEqualizer::process(const audio_sample_t * pIn,
	audio_sample_t * pOut,
	int frameCount) {
	// ALOGV("AudioEqualizer::process(frameCount=%d)", frameCount);
	mpLowShelf->process(pIn, pOut, frameCount);
	for (int i = 0; i < mNumPeaking; ++i) {
	mpPeakingFilters[i].process(pIn, pOut, frameCount);
	}
	mpHighShelf->process(pIn, pOut, frameCount);
	}

	void AudioEqualizer::enable(bool immediate) {
	ALOGV("AudioEqualizer::enable(immediate=%d)", immediate);
	mpLowShelf->enable(immediate);
	for (int i = 0; i < mNumPeaking; ++i) {
	mpPeakingFilters[i].enable(immediate);
	}
	mpHighShelf->enable(immediate);
	}

	void AudioEqualizer::disable(bool immediate) {
	ALOGV("AudioEqualizer::disable(immediate=%d)", immediate);
	mpLowShelf->disable(immediate);
	for (int i = 0; i < mNumPeaking; ++i) {
	mpPeakingFilters[i].disable(immediate);
	}
	mpHighShelf->disable(immediate);
	}

	int AudioEqualizer::getMostRelevantBand(uint32_t targetFreq) const {
	// First, find the two bands that the target frequency is between.
	uint32_t low = mpLowShelf->getFrequency();
	if (targetFreq <= low) {
	return 0;
	}
	uint32_t high = mpHighShelf->getFrequency();
	if (targetFreq >= high) {
	return mNumPeaking + 1;
	}
	int band = mNumPeaking;
	for (int i = 0; i < mNumPeaking; ++i) {
	uint32_t freq = mpPeakingFilters[i].getFrequency();
	if (freq >= targetFreq) {
	high = freq;
	band = i;
	break;
	}
	low = freq;
	}
	// Now, low is right below the target and high is right above. See which one
	// is closer on a log scale.
	low = Effects_log2(low);
	high = Effects_log2(high);
	targetFreq = Effects_log2(targetFreq);
	if (high - targetFreq < targetFreq - low) {
	return band + 1;
	} else {
	return band;
	}
	}


	AudioEqualizer::AudioEqualizer(void * pMem, int nBands, int nChannels,
	int sampleRate, bool ownMem,
	const PresetConfig * presets, int nPresets)
	: mSampleRate(sampleRate)
	, mpPresets(presets)
	, mNumPresets(nPresets) {
	assert(pMem != NULL);
	assert(nPresets == 0 \|\| nPresets > 0 && presets != NULL);
	mpMem = ownMem ? pMem : NULL;

	pMem = (char *) pMem + sizeof(AudioEqualizer);
	mpLowShelf = new (pMem) AudioShelvingFilter(AudioShelvingFilter::kLowShelf,
	nChannels, sampleRate);
	pMem = (char *) pMem + sizeof(AudioShelvingFilter);
	mpHighShelf = new (pMem) AudioShelvingFilter(AudioShelvingFilter::kHighShelf,
	nChannels, sampleRate);
	pMem = (char *) pMem + sizeof(AudioShelvingFilter);
	mNumPeaking = nBands - 2;
	if (mNumPeaking > 0) {
	mpPeakingFilters = reinterpret_cast<AudioPeakingFilter *>(pMem);
	for (int i = 0; i < mNumPeaking; ++i) {
	new (&mpPeakingFilters[i]) AudioPeakingFilter(nChannels,
	sampleRate);
	}
	}
	reset();
	}

	}