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

 /* /android/src/frameworks/base/media/libeffects/AudioFormatAdapter.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 AUDIOFORMATADAPTER_H_
 #define AUDIOFORMATADAPTER_H_

 #include <hardware/audio_effect.h>


 #define min(x,y) (((x) < (y)) ? (x) : (y))

 namespace android {

 // An adapter for an audio processor working on audio_sample_t samples with a
 // buffer override behavior to arbitrary sample formats and buffer behaviors.
 // The adapter may work on any processing class which has a processing function
 // with the following signature:
 // void process(const audio_sample_t * pIn,
 //              audio_sample_t * pOut,
 //              int frameCount);
 // It is assumed that the underlying processor works in S7.24 format and an
 // overwrite behavior.
 //
 // Usage is simple: just work with the processor normally, but instead of
 // calling its process() function directly, work with the process() function of
 // the adapter.
 // The adapter supports re-configuration to a different format on the fly.
 //
 // T        The processor class.
 // bufSize  The maximum number of samples (single channel) to process on a
 //          single call to the underlying processor. Setting this to a small
 //          number will save a little memory, but will cost function call
 //          overhead, resulting from multiple calls to the underlying process()
 //          per a single call to this class's process().
 template<class T, size_t bufSize>
 class AudioFormatAdapter {
 public:
     // Configure the adapter.
     // processor    The underlying audio processor.
     // nChannels    Number of input and output channels. The adapter does not do
     //              channel conversion - this parameter must be in sync with the
     //              actual processor.
     // pcmFormat    The desired input/output sample format.
     // behavior     The desired behavior (overwrite or accumulate).
     void configure(T & processor, int nChannels, uint8_t pcmFormat,
                    uint32_t behavior) {
         mpProcessor = &processor;
         mNumChannels = nChannels;
         mPcmFormat = pcmFormat;
         mBehavior = behavior;
         mMaxSamplesPerCall = bufSize / nChannels;
     }

     // Process a block of samples.
     // pIn          A buffer of samples with the format specified on
     //              configure().
     // pOut         A buffer of samples with the format specified on
     //              configure(). May be the same as pIn.
     // numSamples   The number of multi-channel samples to process.
     void process(const void * pIn, void * pOut, uint32_t numSamples) {
         while (numSamples > 0) {
             uint32_t numSamplesIter = min(numSamples, mMaxSamplesPerCall);
             uint32_t nSamplesChannels = numSamplesIter * mNumChannels;
             // This branch of "if" is untested
             if (mPcmFormat == AUDIO_FORMAT_PCM_8_24_BIT) {
                 if (mBehavior == EFFECT_BUFFER_ACCESS_WRITE) {
                     mpProcessor->process(
                         reinterpret_cast<const audio_sample_t *> (pIn),
                         reinterpret_cast<audio_sample_t *> (pOut),
                         numSamplesIter);
                 } else if (mBehavior == EFFECT_BUFFER_ACCESS_ACCUMULATE) {
                     mpProcessor->process(
                         reinterpret_cast<const audio_sample_t *> (pIn),
                         mBuffer, numSamplesIter);
                     MixOutput(pOut, numSamplesIter);
                 } else {
                     assert(false);
                 }
                 pIn = reinterpret_cast<const audio_sample_t *> (pIn)
                         + nSamplesChannels;
                 pOut = reinterpret_cast<audio_sample_t *> (pOut)
                         + nSamplesChannels;
             } else {
                 ConvertInput(pIn, nSamplesChannels);
                 mpProcessor->process(mBuffer, mBuffer, numSamplesIter);
                 ConvertOutput(pOut, nSamplesChannels);
             }
             numSamples -= numSamplesIter;
         }
     }

 private:
     // The underlying processor.
     T * mpProcessor;
     // The number of input/output channels.
     int mNumChannels;
     // The desired PCM format.
     uint8_t mPcmFormat;
     // The desired buffer behavior.
     uint32_t mBehavior;
     // An intermediate buffer for processing.
     audio_sample_t mBuffer[bufSize];
     // The buffer size, divided by the number of channels - represents the
     // maximum number of multi-channel samples that can be stored in the
     // intermediate buffer.
     size_t mMaxSamplesPerCall;

     // Converts a buffer of input samples to audio_sample_t format.
     // Output is written to the intermediate buffer.
     // pIn          The input buffer with the format designated in configure().
     //              When function exist will point to the next unread input
     //              sample.
     // numSamples   The number of single-channel samples to process.
     void ConvertInput(const void *& pIn, uint32_t numSamples) {
         if (mPcmFormat == AUDIO_FORMAT_PCM_16_BIT) {
             const int16_t * pIn16 = reinterpret_cast<const int16_t *>(pIn);
             audio_sample_t * pOut = mBuffer;
             while (numSamples-- > 0) {
                 *(pOut++) = s15_to_audio_sample_t(*(pIn16++));
             }
             pIn = pIn16;
         } else {
             assert(false);
         }
     }

     // Converts audio_sample_t samples from the intermediate buffer to the
     // output buffer, converting to the desired format and buffer behavior.
     // pOut         The buffer to write the output to.
     //              When function exist will point to the next output sample.
     // numSamples   The number of single-channel samples to process.
     void ConvertOutput(void *& pOut, uint32_t numSamples) {
         if (mPcmFormat == AUDIO_FORMAT_PCM_16_BIT) {
             const audio_sample_t * pIn = mBuffer;
             int16_t * pOut16 = reinterpret_cast<int16_t *>(pOut);
             if (mBehavior == EFFECT_BUFFER_ACCESS_WRITE) {
                 while (numSamples-- > 0) {
                     *(pOut16++) = audio_sample_t_to_s15_clip(*(pIn++));
                 }
             } else if (mBehavior == EFFECT_BUFFER_ACCESS_ACCUMULATE) {
                 while (numSamples-- > 0) {
                     *(pOut16++) += audio_sample_t_to_s15_clip(*(pIn++));
                 }
             } else {
                 assert(false);
             }
             pOut = pOut16;
         } else {
             assert(false);
         }
     }

     // Accumulate data from the intermediate buffer to the output. Output is
     // assumed to be of audio_sample_t type.
     // pOut         The buffer to mix the output to.
     //              When function exist will point to the next output sample.
     // numSamples   The number of single-channel samples to process.
     void MixOutput(void *& pOut, uint32_t numSamples) {
         const audio_sample_t * pIn = mBuffer;
         audio_sample_t * pOut24 = reinterpret_cast<audio_sample_t *>(pOut);
         numSamples *= mNumChannels;
         while (numSamples-- > 0) {
             *(pOut24++) += *(pIn++);
         }
         pOut = pOut24;
     }
 };

 }

 #endif // AUDIOFORMATADAPTER_H_
	/* /android/src/frameworks/base/media/libeffects/AudioFormatAdapter.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 AUDIOFORMATADAPTER_H_
	#define AUDIOFORMATADAPTER_H_

	#include <hardware/audio_effect.h>


	#define min(x,y) (((x) < (y)) ? (x) : (y))

	namespace android {

	// An adapter for an audio processor working on audio_sample_t samples with a
	// buffer override behavior to arbitrary sample formats and buffer behaviors.
	// The adapter may work on any processing class which has a processing function
	// with the following signature:
	// void process(const audio_sample_t * pIn,
	// audio_sample_t * pOut,
	// int frameCount);
	// It is assumed that the underlying processor works in S7.24 format and an
	// overwrite behavior.
	//
	// Usage is simple: just work with the processor normally, but instead of
	// calling its process() function directly, work with the process() function of
	// the adapter.
	// The adapter supports re-configuration to a different format on the fly.
	//
	// T The processor class.
	// bufSize The maximum number of samples (single channel) to process on a
	// single call to the underlying processor. Setting this to a small
	// number will save a little memory, but will cost function call
	// overhead, resulting from multiple calls to the underlying process()
	// per a single call to this class's process().
	template<class T, size_t bufSize>
	class AudioFormatAdapter {
	public:
	// Configure the adapter.
	// processor The underlying audio processor.
	// nChannels Number of input and output channels. The adapter does not do
	// channel conversion - this parameter must be in sync with the
	// actual processor.
	// pcmFormat The desired input/output sample format.
	// behavior The desired behavior (overwrite or accumulate).
	void configure(T & processor, int nChannels, uint8_t pcmFormat,
	uint32_t behavior) {
	mpProcessor = &processor;
	mNumChannels = nChannels;
	mPcmFormat = pcmFormat;
	mBehavior = behavior;
	mMaxSamplesPerCall = bufSize / nChannels;
	}

	// Process a block of samples.
	// pIn A buffer of samples with the format specified on
	// configure().
	// pOut A buffer of samples with the format specified on
	// configure(). May be the same as pIn.
	// numSamples The number of multi-channel samples to process.
	void process(const void * pIn, void * pOut, uint32_t numSamples) {
	while (numSamples > 0) {
	uint32_t numSamplesIter = min(numSamples, mMaxSamplesPerCall);
	uint32_t nSamplesChannels = numSamplesIter * mNumChannels;
	// This branch of "if" is untested
	if (mPcmFormat == AUDIO_FORMAT_PCM_8_24_BIT) {
	if (mBehavior == EFFECT_BUFFER_ACCESS_WRITE) {
	mpProcessor->process(
	reinterpret_cast<const audio_sample_t *> (pIn),
	reinterpret_cast<audio_sample_t *> (pOut),
	numSamplesIter);
	} else if (mBehavior == EFFECT_BUFFER_ACCESS_ACCUMULATE) {
	mpProcessor->process(
	reinterpret_cast<const audio_sample_t *> (pIn),
	mBuffer, numSamplesIter);
	MixOutput(pOut, numSamplesIter);
	} else {
	assert(false);
	}
	pIn = reinterpret_cast<const audio_sample_t *> (pIn)
	+ nSamplesChannels;
	pOut = reinterpret_cast<audio_sample_t *> (pOut)
	+ nSamplesChannels;
	} else {
	ConvertInput(pIn, nSamplesChannels);
	mpProcessor->process(mBuffer, mBuffer, numSamplesIter);
	ConvertOutput(pOut, nSamplesChannels);
	}
	numSamples -= numSamplesIter;
	}
	}

	private:
	// The underlying processor.
	T * mpProcessor;
	// The number of input/output channels.
	int mNumChannels;
	// The desired PCM format.
	uint8_t mPcmFormat;
	// The desired buffer behavior.
	uint32_t mBehavior;
	// An intermediate buffer for processing.
	audio_sample_t mBuffer[bufSize];
	// The buffer size, divided by the number of channels - represents the
	// maximum number of multi-channel samples that can be stored in the
	// intermediate buffer.
	size_t mMaxSamplesPerCall;

	// Converts a buffer of input samples to audio_sample_t format.
	// Output is written to the intermediate buffer.
	// pIn The input buffer with the format designated in configure().
	// When function exist will point to the next unread input
	// sample.
	// numSamples The number of single-channel samples to process.
	void ConvertInput(const void *& pIn, uint32_t numSamples) {
	if (mPcmFormat == AUDIO_FORMAT_PCM_16_BIT) {
	const int16_t * pIn16 = reinterpret_cast<const int16_t *>(pIn);
	audio_sample_t * pOut = mBuffer;
	while (numSamples-- > 0) {
	(pOut++) = s15_to_audio_sample_t((pIn16++));
	}
	pIn = pIn16;
	} else {
	assert(false);
	}
	}

	// Converts audio_sample_t samples from the intermediate buffer to the
	// output buffer, converting to the desired format and buffer behavior.
	// pOut The buffer to write the output to.
	// When function exist will point to the next output sample.
	// numSamples The number of single-channel samples to process.
	void ConvertOutput(void *& pOut, uint32_t numSamples) {
	if (mPcmFormat == AUDIO_FORMAT_PCM_16_BIT) {
	const audio_sample_t * pIn = mBuffer;
	int16_t * pOut16 = reinterpret_cast<int16_t *>(pOut);
	if (mBehavior == EFFECT_BUFFER_ACCESS_WRITE) {
	while (numSamples-- > 0) {
	(pOut16++) = audio_sample_t_to_s15_clip((pIn++));
	}
	} else if (mBehavior == EFFECT_BUFFER_ACCESS_ACCUMULATE) {
	while (numSamples-- > 0) {
	(pOut16++) += audio_sample_t_to_s15_clip((pIn++));
	}
	} else {
	assert(false);
	}
	pOut = pOut16;
	} else {
	assert(false);
	}
	}

	// Accumulate data from the intermediate buffer to the output. Output is
	// assumed to be of audio_sample_t type.
	// pOut The buffer to mix the output to.
	// When function exist will point to the next output sample.
	// numSamples The number of single-channel samples to process.
	void MixOutput(void *& pOut, uint32_t numSamples) {
	const audio_sample_t * pIn = mBuffer;
	audio_sample_t * pOut24 = reinterpret_cast<audio_sample_t *>(pOut);
	numSamples *= mNumChannels;
	while (numSamples-- > 0) {
	(pOut24++) += (pIn++);
	}
	pOut = pOut24;
	}
	};

	}

	#endif // AUDIOFORMATADAPTER_H_