media/libeffects/testlibs/AudioCoefInterpolator.h - third_party/android/platform/frameworks/av - Git at Google

 /* //device/include/server/AudioFlinger/AudioCoefInterpolator.h
  **
  ** Copyright 2007, 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_COEF_INTERPOLATOR_H
 #define ANDROID_AUDIO_COEF_INTERPOLATOR_H

 #include "AudioCommon.h"

 namespace android {

 // A helper class for linear interpolation of N-D -> M-D coefficient tables.
 // This class provides support for out-of-range indexes.
 // Details:
 // The purpose is efficient approximation of a N-dimensional vector to
 // M-dimensional function. The approximation is based on a table of output
 // values on a uniform grid of the input values. Values not on the grid are
 // linearly interpolated.
 // Access to values are done by specifying input values in table index units,
 // having an integer and a fractional part, e.g. retrieving a value from index
 // 1.4 will result in linear interpolation between index 1 and index 2.
 class AudioCoefInterpolator {
 public:
     // Constructor.
     // nInDims      Number of input dimensions (limited to MAX_IN_DIMS).
     // inDims       An array of size nInDims with the size of the table on each
     //              respective dimension.
     // nOutDims     Number of output dimensions (limited to MAX_OUT_DIMS).
     // table        The coefficient table. Should be of size:
     //              inDims[0]*inDims[1]*...*inDims[nInDims-1]*nOutDims, where
     //              func([i,j,k]) = table(i,j,k,:)
     AudioCoefInterpolator(size_t nInDims, const size_t inDims[],
                           size_t nOutDims, const audio_coef_t * table);

     // Get the value of the approximated function at a given point.
     // intCoord     The integer part of the input value. Should be an array of
     //              size nInDims.
     // fracCoord    The fractional part of the input value. Should be an array
     //              of size nInDims. This value is in 32-bit precision.
     // out          An array for the output value. Should be of size nOutDims.
     void getCoef(const int intCoord[], uint32_t fracCoord[], audio_coef_t out[]);

 private:
     // Maximum allowed number of input dimensions.
     static const size_t MAX_IN_DIMS = 8;
     // Maximum allowed number of output dimensions.
     static const size_t MAX_OUT_DIMS = 8;

     // Number of input dimensions.
     size_t mNumInDims;
     // Number of input dimensions.
     size_t mInDims[MAX_IN_DIMS];
     // The offset between two consecutive indexes of each dimension. This is in
     // fact a cumulative product of mInDims (done in reverse).
     size_t mInDimOffsets[MAX_IN_DIMS];
     // Number of output dimensions.
     size_t mNumOutDims;
     // The coefficient table.
     const audio_coef_t * mTable;

     // A recursive function for getting an interpolated coefficient value.
     // The recursion depth is the number of input dimensions.
     // At each step, we fetch two interpolated values of the current dimension,
     // by two recursive calls to this method for the next dimensions. We then
     // linearly interpolate these values over the current dimension.
     // index      The linear integer index of the value we need to interpolate.
     // fracCoord  A vector of fractional coordinates for each of the input
     //            dimensions.
     // out        Where the output should be written. Needs to be of size
     //            mNumOutDims.
     // dim        The input dimensions we are currently interpolating. This
     //            value will be increased on recursive calls.
     void getCoefRecurse(size_t index, const uint32_t fracCoord[],
                         audio_coef_t out[], size_t dim);

     // Scalar interpolation of two data points.
     // lo       The first data point.
     // hi       The second data point.
     // frac     A 32-bit fraction designating the weight of the second point.
     static audio_coef_t interp(audio_coef_t lo, audio_coef_t hi, uint32_t frac);
 };

 }

 #endif // ANDROID_AUDIO_COEF_INTERPOLATOR_H
	/* //device/include/server/AudioFlinger/AudioCoefInterpolator.h
	**
	** Copyright 2007, 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_COEF_INTERPOLATOR_H
	#define ANDROID_AUDIO_COEF_INTERPOLATOR_H

	#include "AudioCommon.h"

	namespace android {

	// A helper class for linear interpolation of N-D -> M-D coefficient tables.
	// This class provides support for out-of-range indexes.
	// Details:
	// The purpose is efficient approximation of a N-dimensional vector to
	// M-dimensional function. The approximation is based on a table of output
	// values on a uniform grid of the input values. Values not on the grid are
	// linearly interpolated.
	// Access to values are done by specifying input values in table index units,
	// having an integer and a fractional part, e.g. retrieving a value from index
	// 1.4 will result in linear interpolation between index 1 and index 2.
	class AudioCoefInterpolator {
	public:
	// Constructor.
	// nInDims Number of input dimensions (limited to MAX_IN_DIMS).
	// inDims An array of size nInDims with the size of the table on each
	// respective dimension.
	// nOutDims Number of output dimensions (limited to MAX_OUT_DIMS).
	// table The coefficient table. Should be of size:
	// inDims[0]inDims[1]...inDims[nInDims-1]nOutDims, where
	// func([i,j,k]) = table(i,j,k,:)
	AudioCoefInterpolator(size_t nInDims, const size_t inDims[],
	size_t nOutDims, const audio_coef_t * table);

	// Get the value of the approximated function at a given point.
	// intCoord The integer part of the input value. Should be an array of
	// size nInDims.
	// fracCoord The fractional part of the input value. Should be an array
	// of size nInDims. This value is in 32-bit precision.
	// out An array for the output value. Should be of size nOutDims.
	void getCoef(const int intCoord[], uint32_t fracCoord[], audio_coef_t out[]);

	private:
	// Maximum allowed number of input dimensions.
	static const size_t MAX_IN_DIMS = 8;
	// Maximum allowed number of output dimensions.
	static const size_t MAX_OUT_DIMS = 8;

	// Number of input dimensions.
	size_t mNumInDims;
	// Number of input dimensions.
	size_t mInDims[MAX_IN_DIMS];
	// The offset between two consecutive indexes of each dimension. This is in
	// fact a cumulative product of mInDims (done in reverse).
	size_t mInDimOffsets[MAX_IN_DIMS];
	// Number of output dimensions.
	size_t mNumOutDims;
	// The coefficient table.
	const audio_coef_t * mTable;

	// A recursive function for getting an interpolated coefficient value.
	// The recursion depth is the number of input dimensions.
	// At each step, we fetch two interpolated values of the current dimension,
	// by two recursive calls to this method for the next dimensions. We then
	// linearly interpolate these values over the current dimension.
	// index The linear integer index of the value we need to interpolate.
	// fracCoord A vector of fractional coordinates for each of the input
	// dimensions.
	// out Where the output should be written. Needs to be of size
	// mNumOutDims.
	// dim The input dimensions we are currently interpolating. This
	// value will be increased on recursive calls.
	void getCoefRecurse(size_t index, const uint32_t fracCoord[],
	audio_coef_t out[], size_t dim);

	// Scalar interpolation of two data points.
	// lo The first data point.
	// hi The second data point.
	// frac A 32-bit fraction designating the weight of the second point.
	static audio_coef_t interp(audio_coef_t lo, audio_coef_t hi, uint32_t frac);
	};

	}

	#endif // ANDROID_AUDIO_COEF_INTERPOLATOR_H