audio_utils/Balance.cpp - platform/system/media - Git at Google

 /*
  * Copyright (C) 2019 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 <audio_utils/Balance.h>

 namespace android::audio_utils {

 void Balance::setChannelMask(audio_channel_mask_t channelMask)
 {
     using namespace ::android::audio_utils::channels;
     channelMask = static_cast<audio_channel_mask_t>(channelMask & ~AUDIO_CHANNEL_HAPTIC_ALL);
     if (!audio_is_output_channel(channelMask) // invalid mask
             || mChannelMask == channelMask) { // no need to do anything
         return;
     }

     mChannelMask = channelMask;
     mChannelCount = audio_channel_count_from_out_mask(channelMask);

     // save mBalance into balance for later restoring, then reset
     const float balance = mBalance;
     mBalance = 0.f;

     // reset mVolumes
     mVolumes.resize(mChannelCount);
     std::fill(mVolumes.begin(), mVolumes.end(), 1.f);

     // reset ramping variables
     mRampBalance = 0.f;
     mRampVolumes.clear();

     if (audio_channel_mask_get_representation(mChannelMask)
             == AUDIO_CHANNEL_REPRESENTATION_INDEX) {
         mSides.clear();       // mSides unused for channel index masks.
         setBalance(balance);  // recompute balance
         return;
     }

     mSides.resize(mChannelCount);
     // If LFE and LFE2 both exist, it should be L and R in 22.2
     int lfe = -1;
     int lfe2 = -1;
     constexpr unsigned LFE_CHANNEL_INDEX = 3;
     constexpr unsigned LFE2_CHANNEL_INDEX = 23;
     for (unsigned i = 0, channel = channelMask; channel != 0; ++i) {
         const int index = __builtin_ctz(channel);
         mSides[i] = sideFromChannelIdx(index);
         // Keep track of LFE indices
         if (index == LFE_CHANNEL_INDEX) {
             lfe = i;
         } else if (index == LFE2_CHANNEL_INDEX) {
             lfe2 = i;
         }
         channel &= ~(1 << index);
     }
     if (lfe >= 0 && lfe2 >= 0) { // if both LFEs exist assign to L and R.
         mSides[lfe] = AUDIO_GEOMETRY_SIDE_LEFT;
         mSides[lfe2] = AUDIO_GEOMETRY_SIDE_RIGHT;
     }
     setBalance(balance); // recompute balance
 }

 void Balance::process(float *buffer, size_t frames)
 {
     if (mBalance == 0.f || mChannelCount < 2) {
         return;
     }

     if (mRamp) {
         if (mRampVolumes.size() != mVolumes.size()) {
             // If mRampVolumes is empty, we do not ramp in this process() but directly
             // apply the existing mVolumes. We save the balance and volume state here
             // and fall through to non-ramping code below. The next process() will ramp if needed.
             mRampBalance = mBalance;
             mRampVolumes = mVolumes;
         } else if (mRampBalance != mBalance) {
             if (frames > 0) {
                 std::vector<float> mDeltas(mVolumes.size());
                 const float r = 1.f / frames;
                 for (size_t j = 0; j < mChannelCount; ++j) {
                     mDeltas[j] = (mVolumes[j] - mRampVolumes[j]) * r;
                 }

                 // ramped balance
                 for (size_t i = 0; i < frames; ++i) {
                     const float findex = i;
                     for (size_t j = 0; j < mChannelCount; ++j) { // better precision: delta * i
                         *buffer++ *= mRampVolumes[j] + mDeltas[j] * findex;
                     }
                 }
             }
             mRampBalance = mBalance;
             mRampVolumes = mVolumes;
             return;
         }
         // fall through
     }

     // non-ramped balance
     for (size_t i = 0; i < frames; ++i) {
         for (size_t j = 0; j < mChannelCount; ++j) {
             *buffer++ *= mVolumes[j];
         }
     }
 }

 void Balance::computeStereoBalance(float balance, float *left, float *right) const
 {
     if (balance > 0.f) {
         *left = mCurve(1.f - balance);
         *right = 1.f;
     } else if (balance < 0.f) {
         *left = 1.f;
         *right = mCurve(1.f + balance);
     } else {
         *left = 1.f;
         *right = 1.f;
     }

     // Functionally:
     // *left = balance > 0.f ? mCurve(1.f - balance) : 1.f;
     // *right = balance < 0.f ? mCurve(1.f + balance) : 1.f;
 }

 std::string Balance::toString() const
 {
     std::stringstream ss;
     ss << "balance " << mBalance << " channelCount " << mChannelCount << " volumes:";
     for (float volume : mVolumes) {
         ss << " " << volume;
     }
     // we do not show mSides, which is only valid for channel position masks.
     return ss.str();
 }

 void Balance::setBalance(float balance)
 {
     using namespace ::android::audio_utils::channels;
     if (mBalance == balance                         // no change
         || isnan(balance) || fabs(balance) > 1.f) { // balance out of range
         return;
     }

     mBalance = balance;

     if (mChannelCount < 2) { // if channel count is 1, mVolumes[0] is already set to 1.f
         return;              // and if channel count < 2, we don't do anything in process().
     }

     // Handle the common cases:
     // stereo and channel index masks only affect the first two channels as left and right.
     if (mChannelMask == AUDIO_CHANNEL_OUT_STEREO
             || audio_channel_mask_get_representation(mChannelMask)
                     == AUDIO_CHANNEL_REPRESENTATION_INDEX) {
         computeStereoBalance(balance, &mVolumes[0], &mVolumes[1]);
         return;
     }

     // For position masks with more than 2 channels, we consider which side the
     // speaker position is on to figure the volume used.
     float balanceVolumes[3]; // left, right, center (we don't care the order)
     static_assert(AUDIO_GEOMETRY_SIDE_LEFT >= 0
             && AUDIO_GEOMETRY_SIDE_LEFT <= std::size(balanceVolumes));
     static_assert(AUDIO_GEOMETRY_SIDE_RIGHT >= 0
             && AUDIO_GEOMETRY_SIDE_RIGHT <= std::size(balanceVolumes));
     static_assert(AUDIO_GEOMETRY_SIDE_CENTER >= 0
             && AUDIO_GEOMETRY_SIDE_CENTER <= std::size(balanceVolumes));
     computeStereoBalance(balance, &balanceVolumes[AUDIO_GEOMETRY_SIDE_LEFT],
             &balanceVolumes[AUDIO_GEOMETRY_SIDE_RIGHT]);
     balanceVolumes[AUDIO_GEOMETRY_SIDE_CENTER] = 1.f; // center  TODO: consider center scaling.

     for (size_t i = 0; i < mVolumes.size(); ++i) {
         mVolumes[i] = balanceVolumes[mSides[i]];
     }
 }

 } // namespace android::audio_utils
	/*
	* Copyright (C) 2019 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 <audio_utils/Balance.h>

	namespace android::audio_utils {

	void Balance::setChannelMask(audio_channel_mask_t channelMask)
	{
	using namespace ::android::audio_utils::channels;
	channelMask = static_cast<audio_channel_mask_t>(channelMask & ~AUDIO_CHANNEL_HAPTIC_ALL);
	if (!audio_is_output_channel(channelMask) // invalid mask
	\|\| mChannelMask == channelMask) { // no need to do anything
	return;
	}

	mChannelMask = channelMask;
	mChannelCount = audio_channel_count_from_out_mask(channelMask);

	// save mBalance into balance for later restoring, then reset
	const float balance = mBalance;
	mBalance = 0.f;

	// reset mVolumes
	mVolumes.resize(mChannelCount);
	std::fill(mVolumes.begin(), mVolumes.end(), 1.f);

	// reset ramping variables
	mRampBalance = 0.f;
	mRampVolumes.clear();

	if (audio_channel_mask_get_representation(mChannelMask)
	== AUDIO_CHANNEL_REPRESENTATION_INDEX) {
	mSides.clear(); // mSides unused for channel index masks.
	setBalance(balance); // recompute balance
	return;
	}

	mSides.resize(mChannelCount);
	// If LFE and LFE2 both exist, it should be L and R in 22.2
	int lfe = -1;
	int lfe2 = -1;
	constexpr unsigned LFE_CHANNEL_INDEX = 3;
	constexpr unsigned LFE2_CHANNEL_INDEX = 23;
	for (unsigned i = 0, channel = channelMask; channel != 0; ++i) {
	const int index = __builtin_ctz(channel);
	mSides[i] = sideFromChannelIdx(index);
	// Keep track of LFE indices
	if (index == LFE_CHANNEL_INDEX) {
	lfe = i;
	} else if (index == LFE2_CHANNEL_INDEX) {
	lfe2 = i;
	}
	channel &= ~(1 << index);
	}
	if (lfe >= 0 && lfe2 >= 0) { // if both LFEs exist assign to L and R.
	mSides[lfe] = AUDIO_GEOMETRY_SIDE_LEFT;
	mSides[lfe2] = AUDIO_GEOMETRY_SIDE_RIGHT;
	}
	setBalance(balance); // recompute balance
	}

	void Balance::process(float *buffer, size_t frames)
	{
	if (mBalance == 0.f \|\| mChannelCount < 2) {
	return;
	}

	if (mRamp) {
	if (mRampVolumes.size() != mVolumes.size()) {
	// If mRampVolumes is empty, we do not ramp in this process() but directly
	// apply the existing mVolumes. We save the balance and volume state here
	// and fall through to non-ramping code below. The next process() will ramp if needed.
	mRampBalance = mBalance;
	mRampVolumes = mVolumes;
	} else if (mRampBalance != mBalance) {
	if (frames > 0) {
	std::vector<float> mDeltas(mVolumes.size());
	const float r = 1.f / frames;
	for (size_t j = 0; j < mChannelCount; ++j) {
	mDeltas[j] = (mVolumes[j] - mRampVolumes[j]) * r;
	}

	// ramped balance
	for (size_t i = 0; i < frames; ++i) {
	const float findex = i;
	for (size_t j = 0; j < mChannelCount; ++j) { // better precision: delta * i
	buffer++ = mRampVolumes[j] + mDeltas[j] * findex;
	}
	}
	}
	mRampBalance = mBalance;
	mRampVolumes = mVolumes;
	return;
	}
	// fall through
	}

	// non-ramped balance
	for (size_t i = 0; i < frames; ++i) {
	for (size_t j = 0; j < mChannelCount; ++j) {
	buffer++ = mVolumes[j];
	}
	}
	}

	void Balance::computeStereoBalance(float balance, float left, float right) const
	{
	if (balance > 0.f) {
	*left = mCurve(1.f - balance);
	*right = 1.f;
	} else if (balance < 0.f) {
	*left = 1.f;
	*right = mCurve(1.f + balance);
	} else {
	*left = 1.f;
	*right = 1.f;
	}

	// Functionally:
	// *left = balance > 0.f ? mCurve(1.f - balance) : 1.f;
	// *right = balance < 0.f ? mCurve(1.f + balance) : 1.f;
	}

	std::string Balance::toString() const
	{
	std::stringstream ss;
	ss << "balance " << mBalance << " channelCount " << mChannelCount << " volumes:";
	for (float volume : mVolumes) {
	ss << " " << volume;
	}
	// we do not show mSides, which is only valid for channel position masks.
	return ss.str();
	}

	void Balance::setBalance(float balance)
	{
	using namespace ::android::audio_utils::channels;
	if (mBalance == balance // no change
	\|\| isnan(balance) \|\| fabs(balance) > 1.f) { // balance out of range
	return;
	}

	mBalance = balance;

	if (mChannelCount < 2) { // if channel count is 1, mVolumes[0] is already set to 1.f
	return; // and if channel count < 2, we don't do anything in process().
	}

	// Handle the common cases:
	// stereo and channel index masks only affect the first two channels as left and right.
	if (mChannelMask == AUDIO_CHANNEL_OUT_STEREO
	\|\| audio_channel_mask_get_representation(mChannelMask)
	== AUDIO_CHANNEL_REPRESENTATION_INDEX) {
	computeStereoBalance(balance, &mVolumes[0], &mVolumes[1]);
	return;
	}

	// For position masks with more than 2 channels, we consider which side the
	// speaker position is on to figure the volume used.
	float balanceVolumes[3]; // left, right, center (we don't care the order)
	static_assert(AUDIO_GEOMETRY_SIDE_LEFT >= 0
	&& AUDIO_GEOMETRY_SIDE_LEFT <= std::size(balanceVolumes));
	static_assert(AUDIO_GEOMETRY_SIDE_RIGHT >= 0
	&& AUDIO_GEOMETRY_SIDE_RIGHT <= std::size(balanceVolumes));
	static_assert(AUDIO_GEOMETRY_SIDE_CENTER >= 0
	&& AUDIO_GEOMETRY_SIDE_CENTER <= std::size(balanceVolumes));
	computeStereoBalance(balance, &balanceVolumes[AUDIO_GEOMETRY_SIDE_LEFT],
	&balanceVolumes[AUDIO_GEOMETRY_SIDE_RIGHT]);
	balanceVolumes[AUDIO_GEOMETRY_SIDE_CENTER] = 1.f; // center TODO: consider center scaling.

	for (size_t i = 0; i < mVolumes.size(); ++i) {
	mVolumes[i] = balanceVolumes[mSides[i]];
	}
	}

	} // namespace android::audio_utils