media/libeffects/testlibs/AudioBiquadFilter.cpp - platform/frameworks/av - Git at Google

 /* //device/servers/AudioFlinger/AudioBiquadFilter.cpp
 **
 ** 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.
 */

 #include <string.h>
 #include <assert.h>
 #include <cutils/compiler.h>

 #include "AudioBiquadFilter.h"

 namespace android {

 const audio_coef_t AudioBiquadFilter::IDENTITY_COEFS[AudioBiquadFilter::NUM_COEFS] = { AUDIO_COEF_ONE, 0, 0, 0, 0 };

 AudioBiquadFilter::AudioBiquadFilter(int nChannels, int sampleRate) {
     configure(nChannels, sampleRate);
     reset();
 }

 void AudioBiquadFilter::configure(int nChannels, int sampleRate) {
     assert(nChannels > 0 && nChannels <= MAX_CHANNELS);
     assert(sampleRate > 0);
     mNumChannels  = nChannels;
     mMaxDelta = static_cast<int64_t>(MAX_DELTA_PER_SEC)
                 * AUDIO_COEF_ONE
                 / sampleRate;
     clear();
 }

 void AudioBiquadFilter::reset() {
     memcpy(mCoefs, IDENTITY_COEFS, sizeof(mCoefs));
     mCoefDirtyBits = 0;
     setState(STATE_BYPASS);
 }

 void AudioBiquadFilter::clear() {
     memset(mDelays, 0, sizeof(mDelays));
 }

 void AudioBiquadFilter::setCoefs(const audio_coef_t coefs[NUM_COEFS], bool immediate) {
     memcpy(mTargetCoefs, coefs, sizeof(mTargetCoefs));
     if (mState & STATE_ENABLED_MASK) {
         if (CC_UNLIKELY(immediate)) {
             memcpy(mCoefs, coefs, sizeof(mCoefs));
             setState(STATE_NORMAL);
         } else {
             setState(STATE_TRANSITION_TO_NORMAL);
         }
     }
 }

 void AudioBiquadFilter::process(const audio_sample_t in[], audio_sample_t out[],
                                 int frameCount) {
     (this->*mCurProcessFunc)(in, out, frameCount);
 }

 void AudioBiquadFilter::enable(bool immediate) {
     if (CC_UNLIKELY(immediate)) {
         memcpy(mCoefs, mTargetCoefs, sizeof(mCoefs));
         setState(STATE_NORMAL);
     } else {
         setState(STATE_TRANSITION_TO_NORMAL);
     }
 }

 void AudioBiquadFilter::disable(bool immediate) {
     if (CC_UNLIKELY(immediate)) {
         memcpy(mCoefs, IDENTITY_COEFS, sizeof(mCoefs));
         setState(STATE_BYPASS);
     } else {
         setState(STATE_TRANSITION_TO_BYPASS);
     }
 }

 void AudioBiquadFilter::setState(state_t state) {
     switch (state) {
     case STATE_BYPASS:
       mCurProcessFunc = &AudioBiquadFilter::process_bypass;
       break;
     case STATE_TRANSITION_TO_BYPASS:
       if (mNumChannels == 1) {
         mCurProcessFunc = &AudioBiquadFilter::process_transition_bypass_mono;
       } else {
         mCurProcessFunc = &AudioBiquadFilter::process_transition_bypass_multi;
       }
       mCoefDirtyBits = (1 << NUM_COEFS) - 1;
       break;
     case STATE_TRANSITION_TO_NORMAL:
       if (mNumChannels == 1) {
         mCurProcessFunc = &AudioBiquadFilter::process_transition_normal_mono;
       } else {
         mCurProcessFunc = &AudioBiquadFilter::process_transition_normal_multi;
       }
       mCoefDirtyBits = (1 << NUM_COEFS) - 1;
       break;
     case STATE_NORMAL:
       if (mNumChannels == 1) {
         mCurProcessFunc = &AudioBiquadFilter::process_normal_mono;
       } else {
         mCurProcessFunc = &AudioBiquadFilter::process_normal_multi;
       }
       break;
     }
     mState = state;
 }

 bool AudioBiquadFilter::updateCoefs(const audio_coef_t coefs[NUM_COEFS],
                                     int frameCount) {
     int64_t maxDelta = mMaxDelta * frameCount;
     for (int i = 0; i < NUM_COEFS; ++i) {
         if (mCoefDirtyBits & (1<<i)) {
             audio_coef_t diff = coefs[i] - mCoefs[i];
             if (diff > maxDelta) {
                 mCoefs[i] += maxDelta;
             } else if (diff < -maxDelta) {
                 mCoefs[i] -= maxDelta;
             } else {
                 mCoefs[i] = coefs[i];
                 mCoefDirtyBits ^= (1<<i);
             }
         }
     }
     return mCoefDirtyBits == 0;
 }

 void AudioBiquadFilter::process_bypass(const audio_sample_t * in,
                                        audio_sample_t * out,
                                        int frameCount) {
     // The common case is in-place processing, because this is what the EQ does.
     if (CC_UNLIKELY(in != out)) {
         memcpy(out, in, frameCount * mNumChannels * sizeof(audio_sample_t));
     }
 }

 void AudioBiquadFilter::process_normal_mono(const audio_sample_t * in,
                                             audio_sample_t * out,
                                             int frameCount) {
     size_t nFrames = frameCount;
     audio_sample_t x1 = mDelays[0][0];
     audio_sample_t x2 = mDelays[0][1];
     audio_sample_t y1 = mDelays[0][2];
     audio_sample_t y2 = mDelays[0][3];
     const audio_coef_t b0 = mCoefs[0];
     const audio_coef_t b1 = mCoefs[1];
     const audio_coef_t b2 = mCoefs[2];
     const audio_coef_t a1 = mCoefs[3];
     const audio_coef_t a2 = mCoefs[4];
     while (nFrames-- > 0) {
         audio_sample_t x0 = *(in++);
         audio_coef_sample_acc_t acc;
         acc = mul_coef_sample(b0, x0);
         acc = mac_coef_sample(b1, x1, acc);
         acc = mac_coef_sample(b2, x2, acc);
         acc = mac_coef_sample(a1, y1, acc);
         acc = mac_coef_sample(a2, y2, acc);
         audio_sample_t y0 = coef_sample_acc_to_sample(acc);
         y2 = y1;
         y1 = y0;
         x2 = x1;
         x1 = x0;
         (*out++) = y0;
     }
     mDelays[0][0] = x1;
     mDelays[0][1] = x2;
     mDelays[0][2] = y1;
     mDelays[0][3] = y2;
 }

 void AudioBiquadFilter::process_transition_normal_mono(const audio_sample_t * in,
                                                        audio_sample_t * out,
                                                        int frameCount) {
     if (updateCoefs(mTargetCoefs, frameCount)) {
         setState(STATE_NORMAL);
     }
     process_normal_mono(in, out, frameCount);
 }

 void AudioBiquadFilter::process_transition_bypass_mono(const audio_sample_t * in,
                                                        audio_sample_t * out,
                                                        int frameCount)  {
   if (updateCoefs(IDENTITY_COEFS, frameCount)) {
       setState(STATE_NORMAL);
   }
   process_normal_mono(in, out, frameCount);
 }

 void AudioBiquadFilter::process_normal_multi(const audio_sample_t * in,
                                              audio_sample_t * out,
                                              int frameCount) {
     const audio_coef_t b0 = mCoefs[0];
     const audio_coef_t b1 = mCoefs[1];
     const audio_coef_t b2 = mCoefs[2];
     const audio_coef_t a1 = mCoefs[3];
     const audio_coef_t a2 = mCoefs[4];
     for (int ch = 0; ch < mNumChannels; ++ch) {
         size_t nFrames = frameCount;
         audio_sample_t x1 = mDelays[ch][0];
         audio_sample_t x2 = mDelays[ch][1];
         audio_sample_t y1 = mDelays[ch][2];
         audio_sample_t y2 = mDelays[ch][3];
         while (nFrames-- > 0) {
             audio_sample_t x0 = *in;
             audio_coef_sample_acc_t acc;
             acc = mul_coef_sample(b0, x0);
             acc = mac_coef_sample(b1, x1, acc);
             acc = mac_coef_sample(b2, x2, acc);
             acc = mac_coef_sample(a1, y1, acc);
             acc = mac_coef_sample(a2, y2, acc);
             audio_sample_t y0 = coef_sample_acc_to_sample(acc);
             y2 = y1;
             y1 = y0;
             x2 = x1;
             x1 = x0;
             *out = y0;
             in += mNumChannels;
             out += mNumChannels;
         }
         mDelays[ch][0] = x1;
         mDelays[ch][1] = x2;
         mDelays[ch][2] = y1;
         mDelays[ch][3] = y2;
         in -= frameCount * mNumChannels - 1;
         out -= frameCount * mNumChannels - 1;
     }
 }

 void AudioBiquadFilter::process_transition_normal_multi(const audio_sample_t * in,
                                                         audio_sample_t * out,
                                                         int frameCount) {
     if (updateCoefs(mTargetCoefs, frameCount)) {
         setState(STATE_NORMAL);
     }
     process_normal_multi(in, out, frameCount);
 }

 void AudioBiquadFilter::process_transition_bypass_multi(const audio_sample_t * in,
                                                         audio_sample_t * out,
                                                         int frameCount)  {
     if (updateCoefs(IDENTITY_COEFS, frameCount)) {
         setState(STATE_NORMAL);
     }
     process_normal_multi(in, out, frameCount);
 }

 }
	/* //device/servers/AudioFlinger/AudioBiquadFilter.cpp
	**
	** 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.
	*/

	#include <string.h>
	#include <assert.h>
	#include <cutils/compiler.h>

	#include "AudioBiquadFilter.h"

	namespace android {

	const audio_coef_t AudioBiquadFilter::IDENTITY_COEFS[AudioBiquadFilter::NUM_COEFS] = { AUDIO_COEF_ONE, 0, 0, 0, 0 };

	AudioBiquadFilter::AudioBiquadFilter(int nChannels, int sampleRate) {
	configure(nChannels, sampleRate);
	reset();
	}

	void AudioBiquadFilter::configure(int nChannels, int sampleRate) {
	assert(nChannels > 0 && nChannels <= MAX_CHANNELS);
	assert(sampleRate > 0);
	mNumChannels = nChannels;
	mMaxDelta = static_cast<int64_t>(MAX_DELTA_PER_SEC)
	* AUDIO_COEF_ONE
	/ sampleRate;
	clear();
	}

	void AudioBiquadFilter::reset() {
	memcpy(mCoefs, IDENTITY_COEFS, sizeof(mCoefs));
	mCoefDirtyBits = 0;
	setState(STATE_BYPASS);
	}

	void AudioBiquadFilter::clear() {
	memset(mDelays, 0, sizeof(mDelays));
	}

	void AudioBiquadFilter::setCoefs(const audio_coef_t coefs[NUM_COEFS], bool immediate) {
	memcpy(mTargetCoefs, coefs, sizeof(mTargetCoefs));
	if (mState & STATE_ENABLED_MASK) {
	if (CC_UNLIKELY(immediate)) {
	memcpy(mCoefs, coefs, sizeof(mCoefs));
	setState(STATE_NORMAL);
	} else {
	setState(STATE_TRANSITION_TO_NORMAL);
	}
	}
	}

	void AudioBiquadFilter::process(const audio_sample_t in[], audio_sample_t out[],
	int frameCount) {
	(this->*mCurProcessFunc)(in, out, frameCount);
	}

	void AudioBiquadFilter::enable(bool immediate) {
	if (CC_UNLIKELY(immediate)) {
	memcpy(mCoefs, mTargetCoefs, sizeof(mCoefs));
	setState(STATE_NORMAL);
	} else {
	setState(STATE_TRANSITION_TO_NORMAL);
	}
	}

	void AudioBiquadFilter::disable(bool immediate) {
	if (CC_UNLIKELY(immediate)) {
	memcpy(mCoefs, IDENTITY_COEFS, sizeof(mCoefs));
	setState(STATE_BYPASS);
	} else {
	setState(STATE_TRANSITION_TO_BYPASS);
	}
	}

	void AudioBiquadFilter::setState(state_t state) {
	switch (state) {
	case STATE_BYPASS:
	mCurProcessFunc = &AudioBiquadFilter::process_bypass;
	break;
	case STATE_TRANSITION_TO_BYPASS:
	if (mNumChannels == 1) {
	mCurProcessFunc = &AudioBiquadFilter::process_transition_bypass_mono;
	} else {
	mCurProcessFunc = &AudioBiquadFilter::process_transition_bypass_multi;
	}
	mCoefDirtyBits = (1 << NUM_COEFS) - 1;
	break;
	case STATE_TRANSITION_TO_NORMAL:
	if (mNumChannels == 1) {
	mCurProcessFunc = &AudioBiquadFilter::process_transition_normal_mono;
	} else {
	mCurProcessFunc = &AudioBiquadFilter::process_transition_normal_multi;
	}
	mCoefDirtyBits = (1 << NUM_COEFS) - 1;
	break;
	case STATE_NORMAL:
	if (mNumChannels == 1) {
	mCurProcessFunc = &AudioBiquadFilter::process_normal_mono;
	} else {
	mCurProcessFunc = &AudioBiquadFilter::process_normal_multi;
	}
	break;
	}
	mState = state;
	}

	bool AudioBiquadFilter::updateCoefs(const audio_coef_t coefs[NUM_COEFS],
	int frameCount) {
	int64_t maxDelta = mMaxDelta * frameCount;
	for (int i = 0; i < NUM_COEFS; ++i) {
	if (mCoefDirtyBits & (1<<i)) {
	audio_coef_t diff = coefs[i] - mCoefs[i];
	if (diff > maxDelta) {
	mCoefs[i] += maxDelta;
	} else if (diff < -maxDelta) {
	mCoefs[i] -= maxDelta;
	} else {
	mCoefs[i] = coefs[i];
	mCoefDirtyBits ^= (1<<i);
	}
	}
	}
	return mCoefDirtyBits == 0;
	}

	void AudioBiquadFilter::process_bypass(const audio_sample_t * in,
	audio_sample_t * out,
	int frameCount) {
	// The common case is in-place processing, because this is what the EQ does.
	if (CC_UNLIKELY(in != out)) {
	memcpy(out, in, frameCount * mNumChannels * sizeof(audio_sample_t));
	}
	}

	void AudioBiquadFilter::process_normal_mono(const audio_sample_t * in,
	audio_sample_t * out,
	int frameCount) {
	size_t nFrames = frameCount;
	audio_sample_t x1 = mDelays[0][0];
	audio_sample_t x2 = mDelays[0][1];
	audio_sample_t y1 = mDelays[0][2];
	audio_sample_t y2 = mDelays[0][3];
	const audio_coef_t b0 = mCoefs[0];
	const audio_coef_t b1 = mCoefs[1];
	const audio_coef_t b2 = mCoefs[2];
	const audio_coef_t a1 = mCoefs[3];
	const audio_coef_t a2 = mCoefs[4];
	while (nFrames-- > 0) {
	audio_sample_t x0 = *(in++);
	audio_coef_sample_acc_t acc;
	acc = mul_coef_sample(b0, x0);
	acc = mac_coef_sample(b1, x1, acc);
	acc = mac_coef_sample(b2, x2, acc);
	acc = mac_coef_sample(a1, y1, acc);
	acc = mac_coef_sample(a2, y2, acc);
	audio_sample_t y0 = coef_sample_acc_to_sample(acc);
	y2 = y1;
	y1 = y0;
	x2 = x1;
	x1 = x0;
	(*out++) = y0;
	}
	mDelays[0][0] = x1;
	mDelays[0][1] = x2;
	mDelays[0][2] = y1;
	mDelays[0][3] = y2;
	}

	void AudioBiquadFilter::process_transition_normal_mono(const audio_sample_t * in,
	audio_sample_t * out,
	int frameCount) {
	if (updateCoefs(mTargetCoefs, frameCount)) {
	setState(STATE_NORMAL);
	}
	process_normal_mono(in, out, frameCount);
	}

	void AudioBiquadFilter::process_transition_bypass_mono(const audio_sample_t * in,
	audio_sample_t * out,
	int frameCount) {
	if (updateCoefs(IDENTITY_COEFS, frameCount)) {
	setState(STATE_NORMAL);
	}
	process_normal_mono(in, out, frameCount);
	}

	void AudioBiquadFilter::process_normal_multi(const audio_sample_t * in,
	audio_sample_t * out,
	int frameCount) {
	const audio_coef_t b0 = mCoefs[0];
	const audio_coef_t b1 = mCoefs[1];
	const audio_coef_t b2 = mCoefs[2];
	const audio_coef_t a1 = mCoefs[3];
	const audio_coef_t a2 = mCoefs[4];
	for (int ch = 0; ch < mNumChannels; ++ch) {
	size_t nFrames = frameCount;
	audio_sample_t x1 = mDelays[ch][0];
	audio_sample_t x2 = mDelays[ch][1];
	audio_sample_t y1 = mDelays[ch][2];
	audio_sample_t y2 = mDelays[ch][3];
	while (nFrames-- > 0) {
	audio_sample_t x0 = *in;
	audio_coef_sample_acc_t acc;
	acc = mul_coef_sample(b0, x0);
	acc = mac_coef_sample(b1, x1, acc);
	acc = mac_coef_sample(b2, x2, acc);
	acc = mac_coef_sample(a1, y1, acc);
	acc = mac_coef_sample(a2, y2, acc);
	audio_sample_t y0 = coef_sample_acc_to_sample(acc);
	y2 = y1;
	y1 = y0;
	x2 = x1;
	x1 = x0;
	*out = y0;
	in += mNumChannels;
	out += mNumChannels;
	}
	mDelays[ch][0] = x1;
	mDelays[ch][1] = x2;
	mDelays[ch][2] = y1;
	mDelays[ch][3] = y2;
	in -= frameCount * mNumChannels - 1;
	out -= frameCount * mNumChannels - 1;
	}
	}

	void AudioBiquadFilter::process_transition_normal_multi(const audio_sample_t * in,
	audio_sample_t * out,
	int frameCount) {
	if (updateCoefs(mTargetCoefs, frameCount)) {
	setState(STATE_NORMAL);
	}
	process_normal_multi(in, out, frameCount);
	}

	void AudioBiquadFilter::process_transition_bypass_multi(const audio_sample_t * in,
	audio_sample_t * out,
	int frameCount) {
	if (updateCoefs(IDENTITY_COEFS, frameCount)) {
	setState(STATE_NORMAL);
	}
	process_normal_multi(in, out, frameCount);
	}

	}