mirror of https://github.com/mstorsjo/fdk-aac.git
953 lines
28 KiB
C
953 lines
28 KiB
C
/* -----------------------------------------------------------------------------
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Software License for The Fraunhofer FDK AAC Codec Library for Android
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© Copyright 1995 - 2019 Fraunhofer-Gesellschaft zur Förderung der angewandten
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Forschung e.V. All rights reserved.
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1. INTRODUCTION
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The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software
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that implements the MPEG Advanced Audio Coding ("AAC") encoding and decoding
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scheme for digital audio. This FDK AAC Codec software is intended to be used on
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a wide variety of Android devices.
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AAC's HE-AAC and HE-AAC v2 versions are regarded as today's most efficient
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general perceptual audio codecs. AAC-ELD is considered the best-performing
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full-bandwidth communications codec by independent studies and is widely
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deployed. AAC has been standardized by ISO and IEC as part of the MPEG
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specifications.
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Patent licenses for necessary patent claims for the FDK AAC Codec (including
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those of Fraunhofer) may be obtained through Via Licensing
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(www.vialicensing.com) or through the respective patent owners individually for
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the purpose of encoding or decoding bit streams in products that are compliant
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with the ISO/IEC MPEG audio standards. Please note that most manufacturers of
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Android devices already license these patent claims through Via Licensing or
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directly from the patent owners, and therefore FDK AAC Codec software may
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already be covered under those patent licenses when it is used for those
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licensed purposes only.
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Commercially-licensed AAC software libraries, including floating-point versions
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with enhanced sound quality, are also available from Fraunhofer. Users are
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encouraged to check the Fraunhofer website for additional applications
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information and documentation.
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2. COPYRIGHT LICENSE
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Redistribution and use in source and binary forms, with or without modification,
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are permitted without payment of copyright license fees provided that you
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satisfy the following conditions:
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You must retain the complete text of this software license in redistributions of
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the FDK AAC Codec or your modifications thereto in source code form.
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You must retain the complete text of this software license in the documentation
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and/or other materials provided with redistributions of the FDK AAC Codec or
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your modifications thereto in binary form. You must make available free of
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charge copies of the complete source code of the FDK AAC Codec and your
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modifications thereto to recipients of copies in binary form.
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The name of Fraunhofer may not be used to endorse or promote products derived
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from this library without prior written permission.
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You may not charge copyright license fees for anyone to use, copy or distribute
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the FDK AAC Codec software or your modifications thereto.
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Your modified versions of the FDK AAC Codec must carry prominent notices stating
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that you changed the software and the date of any change. For modified versions
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of the FDK AAC Codec, the term "Fraunhofer FDK AAC Codec Library for Android"
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must be replaced by the term "Third-Party Modified Version of the Fraunhofer FDK
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AAC Codec Library for Android."
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3. NO PATENT LICENSE
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NO EXPRESS OR IMPLIED LICENSES TO ANY PATENT CLAIMS, including without
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limitation the patents of Fraunhofer, ARE GRANTED BY THIS SOFTWARE LICENSE.
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Fraunhofer provides no warranty of patent non-infringement with respect to this
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software.
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You may use this FDK AAC Codec software or modifications thereto only for
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purposes that are authorized by appropriate patent licenses.
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4. DISCLAIMER
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This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright
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holders and contributors "AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES,
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including but not limited to the implied warranties of merchantability and
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fitness for a particular purpose. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
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CONTRIBUTORS BE LIABLE for any direct, indirect, incidental, special, exemplary,
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or consequential damages, including but not limited to procurement of substitute
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goods or services; loss of use, data, or profits, or business interruption,
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however caused and on any theory of liability, whether in contract, strict
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liability, or tort (including negligence), arising in any way out of the use of
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this software, even if advised of the possibility of such damage.
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5. CONTACT INFORMATION
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Fraunhofer Institute for Integrated Circuits IIS
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Attention: Audio and Multimedia Departments - FDK AAC LL
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Am Wolfsmantel 33
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91058 Erlangen, Germany
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www.iis.fraunhofer.de/amm
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amm-info@iis.fraunhofer.de
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----------------------------------------------------------------------------- */
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/******************* Library for basic calculation routines ********************
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Author(s): M. Gayer
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Description: Fixed point specific mathematical functions
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*******************************************************************************/
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#ifndef FIXPOINT_MATH_H
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#define FIXPOINT_MATH_H
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#include "common_fix.h"
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#include "scale.h"
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/*
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* Data definitions
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*/
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#define LD_DATA_SCALING (64.0f)
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#define LD_DATA_SHIFT 6 /* pow(2, LD_DATA_SHIFT) = LD_DATA_SCALING */
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#define MAX_LD_PRECISION 10
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#define LD_PRECISION 10
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/* Taylor series coefficients for ln(1-x), centered at 0 (MacLaurin polynomial).
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*/
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#ifndef LDCOEFF_16BIT
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LNK_SECTION_CONSTDATA_L1
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static const FIXP_DBL ldCoeff[MAX_LD_PRECISION] = {
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FL2FXCONST_DBL(-1.0), FL2FXCONST_DBL(-1.0 / 2.0),
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FL2FXCONST_DBL(-1.0 / 3.0), FL2FXCONST_DBL(-1.0 / 4.0),
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FL2FXCONST_DBL(-1.0 / 5.0), FL2FXCONST_DBL(-1.0 / 6.0),
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FL2FXCONST_DBL(-1.0 / 7.0), FL2FXCONST_DBL(-1.0 / 8.0),
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FL2FXCONST_DBL(-1.0 / 9.0), FL2FXCONST_DBL(-1.0 / 10.0)};
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#else /* LDCOEFF_16BIT */
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LNK_SECTION_CONSTDATA_L1
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static const FIXP_SGL ldCoeff[MAX_LD_PRECISION] = {
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FL2FXCONST_SGL(-1.0), FL2FXCONST_SGL(-1.0 / 2.0),
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FL2FXCONST_SGL(-1.0 / 3.0), FL2FXCONST_SGL(-1.0 / 4.0),
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FL2FXCONST_SGL(-1.0 / 5.0), FL2FXCONST_SGL(-1.0 / 6.0),
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FL2FXCONST_SGL(-1.0 / 7.0), FL2FXCONST_SGL(-1.0 / 8.0),
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FL2FXCONST_SGL(-1.0 / 9.0), FL2FXCONST_SGL(-1.0 / 10.0)};
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#endif /* LDCOEFF_16BIT */
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/*****************************************************************************
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functionname: invSqrtNorm2
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description: delivers 1/sqrt(op) normalized to .5...1 and the shift value
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of the OUTPUT
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*****************************************************************************/
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#define SQRT_BITS 7
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#define SQRT_VALUES (128 + 2)
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#define SQRT_BITS_MASK 0x7f
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#define SQRT_FRACT_BITS_MASK 0x007FFFFF
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extern const FIXP_DBL invSqrtTab[SQRT_VALUES];
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/*
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* Hardware specific implementations
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*/
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#if defined(__x86__)
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#include "x86/fixpoint_math_x86.h"
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#endif /* target architecture selector */
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/*
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* Fallback implementations
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*/
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#if !defined(FUNCTION_fIsLessThan)
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/**
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* \brief Compares two fixpoint values incl. scaling.
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* \param a_m mantissa of the first input value.
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* \param a_e exponent of the first input value.
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* \param b_m mantissa of the second input value.
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* \param b_e exponent of the second input value.
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* \return non-zero if (a_m*2^a_e) < (b_m*2^b_e), 0 otherwise
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*/
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FDK_INLINE INT fIsLessThan(FIXP_DBL a_m, INT a_e, FIXP_DBL b_m, INT b_e) {
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INT n;
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n = fixnorm_D(a_m);
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a_m <<= n;
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a_e -= n;
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n = fixnorm_D(b_m);
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b_m <<= n;
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b_e -= n;
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if (a_m == (FIXP_DBL)0) a_e = b_e;
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if (b_m == (FIXP_DBL)0) b_e = a_e;
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if (a_e > b_e) {
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return ((b_m >> fMin(a_e - b_e, DFRACT_BITS - 1)) > a_m);
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} else {
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return ((a_m >> fMin(b_e - a_e, DFRACT_BITS - 1)) < b_m);
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}
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}
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FDK_INLINE INT fIsLessThan(FIXP_SGL a_m, INT a_e, FIXP_SGL b_m, INT b_e) {
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INT n;
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n = fixnorm_S(a_m);
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a_m <<= n;
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a_e -= n;
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n = fixnorm_S(b_m);
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b_m <<= n;
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b_e -= n;
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if (a_m == (FIXP_SGL)0) a_e = b_e;
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if (b_m == (FIXP_SGL)0) b_e = a_e;
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if (a_e > b_e) {
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return ((b_m >> fMin(a_e - b_e, FRACT_BITS - 1)) > a_m);
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} else {
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return ((a_m >> fMin(b_e - a_e, FRACT_BITS - 1)) < b_m);
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}
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}
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#endif
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/**
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* \brief deprecated. Use fLog2() instead.
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*/
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#define CalcLdData(op) fLog2(op, 0)
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void LdDataVector(FIXP_DBL *srcVector, FIXP_DBL *destVector, INT number);
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extern const UINT exp2_tab_long[32];
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extern const UINT exp2w_tab_long[32];
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extern const UINT exp2x_tab_long[32];
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LNK_SECTION_CODE_L1
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FDK_INLINE FIXP_DBL CalcInvLdData(const FIXP_DBL x) {
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int set_zero = (x < FL2FXCONST_DBL(-31.0 / 64.0)) ? 0 : 1;
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int set_max = (x >= FL2FXCONST_DBL(31.0 / 64.0)) | (x == FL2FXCONST_DBL(0.0));
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FIXP_SGL frac = (FIXP_SGL)((LONG)x & 0x3FF);
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UINT index3 = (UINT)(LONG)(x >> 10) & 0x1F;
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UINT index2 = (UINT)(LONG)(x >> 15) & 0x1F;
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UINT index1 = (UINT)(LONG)(x >> 20) & 0x1F;
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int exp = fMin(31, ((x > FL2FXCONST_DBL(0.0f)) ? (31 - (int)(x >> 25))
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: (int)(-(x >> 25))));
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UINT lookup1 = exp2_tab_long[index1] * set_zero;
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UINT lookup2 = exp2w_tab_long[index2];
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UINT lookup3 = exp2x_tab_long[index3];
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UINT lookup3f =
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lookup3 + (UINT)(LONG)fMultDiv2((FIXP_DBL)(0x0016302F), (FIXP_SGL)frac);
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UINT lookup12 = (UINT)(LONG)fMult((FIXP_DBL)lookup1, (FIXP_DBL)lookup2);
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UINT lookup = (UINT)(LONG)fMult((FIXP_DBL)lookup12, (FIXP_DBL)lookup3f);
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FIXP_DBL retVal = (lookup << 3) >> exp;
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if (set_max) {
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retVal = (FIXP_DBL)MAXVAL_DBL;
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}
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return retVal;
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}
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void InitLdInt();
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FIXP_DBL CalcLdInt(INT i);
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extern const USHORT sqrt_tab[49];
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inline FIXP_DBL sqrtFixp_lookup(FIXP_DBL x) {
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UINT y = (INT)x;
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UCHAR is_zero = (y == 0);
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INT zeros = fixnormz_D(y) & 0x1e;
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y <<= zeros;
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UINT idx = (y >> 26) - 16;
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USHORT frac = (y >> 10) & 0xffff;
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USHORT nfrac = 0xffff ^ frac;
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UINT t = (UINT)nfrac * sqrt_tab[idx] + (UINT)frac * sqrt_tab[idx + 1];
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t = t >> (zeros >> 1);
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return (is_zero ? 0 : t);
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}
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inline FIXP_DBL sqrtFixp_lookup(FIXP_DBL x, INT *x_e) {
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UINT y = (INT)x;
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INT e;
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if (x == (FIXP_DBL)0) {
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return x;
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}
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/* Normalize */
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e = fixnormz_D(y);
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y <<= e;
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e = *x_e - e + 2;
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/* Correct odd exponent. */
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if (e & 1) {
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y >>= 1;
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e++;
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}
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/* Get square root */
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UINT idx = (y >> 26) - 16;
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USHORT frac = (y >> 10) & 0xffff;
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USHORT nfrac = 0xffff ^ frac;
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UINT t = (UINT)nfrac * sqrt_tab[idx] + (UINT)frac * sqrt_tab[idx + 1];
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/* Write back exponent */
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*x_e = e >> 1;
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return (FIXP_DBL)(LONG)(t >> 1);
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}
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void InitInvSqrtTab();
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#ifndef FUNCTION_invSqrtNorm2
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/**
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* \brief calculate 1.0/sqrt(op)
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* \param op_m mantissa of input value.
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* \param result_e pointer to return the exponent of the result
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* \return mantissa of the result
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*/
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/*****************************************************************************
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delivers 1/sqrt(op) normalized to .5...1 and the shift value of the OUTPUT,
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i.e. the denormalized result is 1/sqrt(op) = invSqrtNorm(op) * 2^(shift)
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uses Newton-iteration for approximation
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Q(n+1) = Q(n) + Q(n) * (0.5 - 2 * V * Q(n)^2)
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with Q = 0.5* V ^-0.5; 0.5 <= V < 1.0
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*****************************************************************************/
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static FDK_FORCEINLINE FIXP_DBL invSqrtNorm2(FIXP_DBL op, INT *shift) {
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FIXP_DBL val = op;
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FIXP_DBL reg1, reg2;
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if (val == FL2FXCONST_DBL(0.0)) {
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*shift = 16;
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return ((LONG)MAXVAL_DBL); /* maximum positive value */
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}
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#define INVSQRTNORM2_LINEAR_INTERPOLATE
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#define INVSQRTNORM2_LINEAR_INTERPOLATE_HQ
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/* normalize input, calculate shift value */
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FDK_ASSERT(val > FL2FXCONST_DBL(0.0));
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*shift = fNormz(val) - 1; /* CountLeadingBits() is not necessary here since
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test value is always > 0 */
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val <<= *shift; /* normalized input V */
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*shift += 2; /* bias for exponent */
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#if defined(INVSQRTNORM2_LINEAR_INTERPOLATE)
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INT index =
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(INT)(val >> (DFRACT_BITS - 1 - (SQRT_BITS + 1))) & SQRT_BITS_MASK;
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FIXP_DBL Fract =
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(FIXP_DBL)(((INT)val & SQRT_FRACT_BITS_MASK) << (SQRT_BITS + 1));
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FIXP_DBL diff = invSqrtTab[index + 1] - invSqrtTab[index];
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reg1 = invSqrtTab[index] + (fMultDiv2(diff, Fract) << 1);
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#if defined(INVSQRTNORM2_LINEAR_INTERPOLATE_HQ)
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/* reg1 = t[i] + (t[i+1]-t[i])*fract ... already computed ...
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+ (1-fract)fract*(t[i+2]-t[i+1])/2 */
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if (Fract != (FIXP_DBL)0) {
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/* fract = fract * (1 - fract) */
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Fract = fMultDiv2(Fract, (FIXP_DBL)((ULONG)0x80000000 - (ULONG)Fract)) << 1;
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diff = diff - (invSqrtTab[index + 2] - invSqrtTab[index + 1]);
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reg1 = fMultAddDiv2(reg1, Fract, diff);
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}
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#endif /* INVSQRTNORM2_LINEAR_INTERPOLATE_HQ */
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#else
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#error \
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"Either define INVSQRTNORM2_NEWTON_ITERATE or INVSQRTNORM2_LINEAR_INTERPOLATE"
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#endif
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/* calculate the output exponent = input exp/2 */
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if (*shift & 0x00000001) { /* odd shift values ? */
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/* Note: Do not use rounded value 0x5A82799A to avoid overflow with
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* shift-by-2 */
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reg2 = (FIXP_DBL)0x5A827999;
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/* FL2FXCONST_DBL(0.707106781186547524400844362104849f);*/ /* 1/sqrt(2);
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*/
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reg1 = fMultDiv2(reg1, reg2) << 2;
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}
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*shift = *shift >> 1;
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return (reg1);
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}
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#endif /* FUNCTION_invSqrtNorm2 */
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#ifndef FUNCTION_sqrtFixp
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static FDK_FORCEINLINE FIXP_DBL sqrtFixp(FIXP_DBL op) {
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INT tmp_exp = 0;
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FIXP_DBL tmp_inv = invSqrtNorm2(op, &tmp_exp);
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FDK_ASSERT(tmp_exp > 0);
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return ((FIXP_DBL)(fMultDiv2((op << (tmp_exp - 1)), tmp_inv) << 2));
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}
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#endif /* FUNCTION_sqrtFixp */
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#ifndef FUNCTION_invFixp
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/**
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* \brief calculate 1.0/op
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* \param op mantissa of the input value.
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* \return mantissa of the result with implicit exponent of 31
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* \exceptions are provided for op=0,1 setting max. positive value
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*/
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static inline FIXP_DBL invFixp(FIXP_DBL op) {
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if ((op == (FIXP_DBL)0x00000000) || (op == (FIXP_DBL)0x00000001)) {
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return ((LONG)MAXVAL_DBL);
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}
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INT tmp_exp;
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FIXP_DBL tmp_inv = invSqrtNorm2(op, &tmp_exp);
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FDK_ASSERT((31 - (2 * tmp_exp + 1)) >= 0);
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int shift = 31 - (2 * tmp_exp + 1);
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tmp_inv = fPow2Div2(tmp_inv);
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if (shift) {
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tmp_inv = ((tmp_inv >> (shift - 1)) + (FIXP_DBL)1) >> 1;
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}
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return tmp_inv;
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}
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/**
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* \brief calculate 1.0/(op_m * 2^op_e)
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* \param op_m mantissa of the input value.
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* \param op_e pointer into were the exponent of the input value is stored, and
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* the result will be stored into.
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* \return mantissa of the result
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*/
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static inline FIXP_DBL invFixp(FIXP_DBL op_m, int *op_e) {
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if ((op_m == (FIXP_DBL)0x00000000) || (op_m == (FIXP_DBL)0x00000001)) {
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*op_e = 31 - *op_e;
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return ((LONG)MAXVAL_DBL);
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}
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INT tmp_exp;
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FIXP_DBL tmp_inv = invSqrtNorm2(op_m, &tmp_exp);
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*op_e = (tmp_exp << 1) - *op_e + 1;
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return fPow2Div2(tmp_inv);
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}
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#endif /* FUNCTION_invFixp */
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#ifndef FUNCTION_schur_div
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/**
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* \brief Divide two FIXP_DBL values with given precision.
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* \param num dividend
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* \param denum divisor
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* \param count amount of significant bits of the result (starting to the MSB)
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* \return num/divisor
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*/
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FIXP_DBL schur_div(FIXP_DBL num, FIXP_DBL denum, INT count);
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#endif /* FUNCTION_schur_div */
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FIXP_DBL mul_dbl_sgl_rnd(const FIXP_DBL op1, const FIXP_SGL op2);
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#ifndef FUNCTION_fMultNorm
|
|
/**
|
|
* \brief multiply two values with normalization, thus max precision.
|
|
* Author: Robert Weidner
|
|
*
|
|
* \param f1 first factor
|
|
* \param f2 second factor
|
|
* \param result_e pointer to an INT where the exponent of the result is stored
|
|
* into
|
|
* \return mantissa of the product f1*f2
|
|
*/
|
|
FIXP_DBL fMultNorm(FIXP_DBL f1, FIXP_DBL f2, INT *result_e);
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|
|
|
/**
|
|
* \brief Multiply 2 values using maximum precision. The exponent of the result
|
|
* is 0.
|
|
* \param f1_m mantissa of factor 1
|
|
* \param f2_m mantissa of factor 2
|
|
* \return mantissa of the result with exponent equal to 0
|
|
*/
|
|
inline FIXP_DBL fMultNorm(FIXP_DBL f1, FIXP_DBL f2) {
|
|
FIXP_DBL m;
|
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INT e;
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|
|
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m = fMultNorm(f1, f2, &e);
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|
|
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m = scaleValueSaturate(m, e);
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|
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return m;
|
|
}
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|
|
|
/**
|
|
* \brief Multiply 2 values with exponent and use given exponent for the
|
|
* mantissa of the result.
|
|
* \param f1_m mantissa of factor 1
|
|
* \param f1_e exponent of factor 1
|
|
* \param f2_m mantissa of factor 2
|
|
* \param f2_e exponent of factor 2
|
|
* \param result_e exponent for the returned mantissa of the result
|
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* \return mantissa of the result with exponent equal to result_e
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|
*/
|
|
inline FIXP_DBL fMultNorm(FIXP_DBL f1_m, INT f1_e, FIXP_DBL f2_m, INT f2_e,
|
|
INT result_e) {
|
|
FIXP_DBL m;
|
|
INT e;
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|
|
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m = fMultNorm(f1_m, f2_m, &e);
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|
|
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m = scaleValueSaturate(m, e + f1_e + f2_e - result_e);
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|
|
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return m;
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|
}
|
|
#endif /* FUNCTION_fMultNorm */
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|
|
|
#ifndef FUNCTION_fMultI
|
|
/**
|
|
* \brief Multiplies a fractional value and a integer value and performs
|
|
* rounding to nearest
|
|
* \param a fractional value
|
|
* \param b integer value
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* \return integer value
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|
*/
|
|
inline INT fMultI(FIXP_DBL a, INT b) {
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FIXP_DBL m, mi;
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INT m_e;
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|
|
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m = fMultNorm(a, (FIXP_DBL)b, &m_e);
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|
|
|
if (m_e < (INT)0) {
|
|
if (m_e > (INT)-DFRACT_BITS) {
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m = m >> ((-m_e) - 1);
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|
mi = (m + (FIXP_DBL)1) >> 1;
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} else {
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|
mi = (FIXP_DBL)0;
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|
}
|
|
} else {
|
|
mi = scaleValueSaturate(m, m_e);
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}
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|
|
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return ((INT)mi);
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}
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#endif /* FUNCTION_fMultI */
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|
|
|
#ifndef FUNCTION_fMultIfloor
|
|
/**
|
|
* \brief Multiplies a fractional value and a integer value and performs floor
|
|
* rounding
|
|
* \param a fractional value
|
|
* \param b integer value
|
|
* \return integer value
|
|
*/
|
|
inline INT fMultIfloor(FIXP_DBL a, INT b) {
|
|
FIXP_DBL m, mi;
|
|
INT m_e;
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|
|
|
m = fMultNorm(a, (FIXP_DBL)b, &m_e);
|
|
|
|
if (m_e < (INT)0) {
|
|
if (m_e > (INT)-DFRACT_BITS) {
|
|
mi = m >> (-m_e);
|
|
} else {
|
|
mi = (FIXP_DBL)0;
|
|
if (m < (FIXP_DBL)0) {
|
|
mi = (FIXP_DBL)-1;
|
|
}
|
|
}
|
|
} else {
|
|
mi = scaleValueSaturate(m, m_e);
|
|
}
|
|
|
|
return ((INT)mi);
|
|
}
|
|
#endif /* FUNCTION_fMultIfloor */
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|
|
|
#ifndef FUNCTION_fMultIceil
|
|
/**
|
|
* \brief Multiplies a fractional value and a integer value and performs ceil
|
|
* rounding
|
|
* \param a fractional value
|
|
* \param b integer value
|
|
* \return integer value
|
|
*/
|
|
inline INT fMultIceil(FIXP_DBL a, INT b) {
|
|
FIXP_DBL m, mi;
|
|
INT m_e;
|
|
|
|
m = fMultNorm(a, (FIXP_DBL)b, &m_e);
|
|
|
|
if (m_e < (INT)0) {
|
|
if (m_e > (INT) - (DFRACT_BITS - 1)) {
|
|
mi = (m >> (-m_e));
|
|
if ((LONG)m & ((1 << (-m_e)) - 1)) {
|
|
mi = mi + (FIXP_DBL)1;
|
|
}
|
|
} else {
|
|
if (m > (FIXP_DBL)0) {
|
|
mi = (FIXP_DBL)1;
|
|
} else {
|
|
if ((m_e == -(DFRACT_BITS - 1)) && (m == (FIXP_DBL)MINVAL_DBL)) {
|
|
mi = (FIXP_DBL)-1;
|
|
} else {
|
|
mi = (FIXP_DBL)0;
|
|
}
|
|
}
|
|
}
|
|
} else {
|
|
mi = scaleValueSaturate(m, m_e);
|
|
}
|
|
|
|
return ((INT)mi);
|
|
}
|
|
#endif /* FUNCTION_fMultIceil */
|
|
|
|
#ifndef FUNCTION_fDivNorm
|
|
/**
|
|
* \brief Divide 2 FIXP_DBL values with normalization of input values.
|
|
* \param num numerator
|
|
* \param denum denominator
|
|
* \param result_e pointer to an INT where the exponent of the result is stored
|
|
* into
|
|
* \return num/denum with exponent = *result_e
|
|
*/
|
|
FIXP_DBL fDivNorm(FIXP_DBL num, FIXP_DBL denom, INT *result_e);
|
|
|
|
/**
|
|
* \brief Divide 2 positive FIXP_DBL values with normalization of input values.
|
|
* \param num numerator
|
|
* \param denum denominator
|
|
* \return num/denum with exponent = 0
|
|
*/
|
|
FIXP_DBL fDivNorm(FIXP_DBL num, FIXP_DBL denom);
|
|
|
|
/**
|
|
* \brief Divide 2 signed FIXP_DBL values with normalization of input values.
|
|
* \param num numerator
|
|
* \param denum denominator
|
|
* \param result_e pointer to an INT where the exponent of the result is stored
|
|
* into
|
|
* \return num/denum with exponent = *result_e
|
|
*/
|
|
FIXP_DBL fDivNormSigned(FIXP_DBL L_num, FIXP_DBL L_denum, INT *result_e);
|
|
|
|
/**
|
|
* \brief Divide 2 signed FIXP_DBL values with normalization of input values.
|
|
* \param num numerator
|
|
* \param denum denominator
|
|
* \return num/denum with exponent = 0
|
|
*/
|
|
FIXP_DBL fDivNormSigned(FIXP_DBL num, FIXP_DBL denom);
|
|
#endif /* FUNCTION_fDivNorm */
|
|
|
|
/**
|
|
* \brief Adjust mantissa to exponent -1
|
|
* \param a_m mantissa of value to be adjusted
|
|
* \param pA_e pointer to the exponen of a_m
|
|
* \return adjusted mantissa
|
|
*/
|
|
inline FIXP_DBL fAdjust(FIXP_DBL a_m, INT *pA_e) {
|
|
INT shift;
|
|
|
|
shift = fNorm(a_m) - 1;
|
|
*pA_e -= shift;
|
|
|
|
return scaleValue(a_m, shift);
|
|
}
|
|
|
|
#ifndef FUNCTION_fAddNorm
|
|
/**
|
|
* \brief Add two values with normalization
|
|
* \param a_m mantissa of first summand
|
|
* \param a_e exponent of first summand
|
|
* \param a_m mantissa of second summand
|
|
* \param a_e exponent of second summand
|
|
* \param pResult_e pointer to where the exponent of the result will be stored
|
|
* to.
|
|
* \return mantissa of result
|
|
*/
|
|
inline FIXP_DBL fAddNorm(FIXP_DBL a_m, INT a_e, FIXP_DBL b_m, INT b_e,
|
|
INT *pResult_e) {
|
|
INT result_e;
|
|
FIXP_DBL result_m;
|
|
|
|
/* If one of the summands is zero, return the other.
|
|
This is necessary for the summation of a very small number to zero */
|
|
if (a_m == (FIXP_DBL)0) {
|
|
*pResult_e = b_e;
|
|
return b_m;
|
|
}
|
|
if (b_m == (FIXP_DBL)0) {
|
|
*pResult_e = a_e;
|
|
return a_m;
|
|
}
|
|
|
|
a_m = fAdjust(a_m, &a_e);
|
|
b_m = fAdjust(b_m, &b_e);
|
|
|
|
if (a_e > b_e) {
|
|
result_m = a_m + (b_m >> fMin(a_e - b_e, DFRACT_BITS - 1));
|
|
result_e = a_e;
|
|
} else {
|
|
result_m = (a_m >> fMin(b_e - a_e, DFRACT_BITS - 1)) + b_m;
|
|
result_e = b_e;
|
|
}
|
|
|
|
*pResult_e = result_e;
|
|
return result_m;
|
|
}
|
|
|
|
inline FIXP_DBL fAddNorm(FIXP_DBL a_m, INT a_e, FIXP_DBL b_m, INT b_e,
|
|
INT result_e) {
|
|
FIXP_DBL result_m;
|
|
|
|
a_m = scaleValue(a_m, a_e - result_e);
|
|
b_m = scaleValue(b_m, b_e - result_e);
|
|
|
|
result_m = a_m + b_m;
|
|
|
|
return result_m;
|
|
}
|
|
#endif /* FUNCTION_fAddNorm */
|
|
|
|
/**
|
|
* \brief Divide 2 FIXP_DBL values with normalization of input values.
|
|
* \param num numerator
|
|
* \param denum denomintator
|
|
* \return num/denum with exponent = 0
|
|
*/
|
|
FIXP_DBL fDivNormHighPrec(FIXP_DBL L_num, FIXP_DBL L_denum, INT *result_e);
|
|
|
|
#ifndef FUNCTION_fPow
|
|
/**
|
|
* \brief return 2 ^ (exp_m * 2^exp_e)
|
|
* \param exp_m mantissa of the exponent to 2.0f
|
|
* \param exp_e exponent of the exponent to 2.0f
|
|
* \param result_e pointer to a INT where the exponent of the result will be
|
|
* stored into
|
|
* \return mantissa of the result
|
|
*/
|
|
FIXP_DBL f2Pow(const FIXP_DBL exp_m, const INT exp_e, INT *result_e);
|
|
|
|
/**
|
|
* \brief return 2 ^ (exp_m * 2^exp_e). This version returns only the mantissa
|
|
* with implicit exponent of zero.
|
|
* \param exp_m mantissa of the exponent to 2.0f
|
|
* \param exp_e exponent of the exponent to 2.0f
|
|
* \return mantissa of the result
|
|
*/
|
|
FIXP_DBL f2Pow(const FIXP_DBL exp_m, const INT exp_e);
|
|
|
|
/**
|
|
* \brief return x ^ (exp_m * 2^exp_e), where log2(x) = baseLd_m * 2^(baseLd_e).
|
|
* This saves the need to compute log2() of constant values (when x is a
|
|
* constant).
|
|
* \param baseLd_m mantissa of log2() of x.
|
|
* \param baseLd_e exponent of log2() of x.
|
|
* \param exp_m mantissa of the exponent to 2.0f
|
|
* \param exp_e exponent of the exponent to 2.0f
|
|
* \param result_e pointer to a INT where the exponent of the result will be
|
|
* stored into
|
|
* \return mantissa of the result
|
|
*/
|
|
FIXP_DBL fLdPow(FIXP_DBL baseLd_m, INT baseLd_e, FIXP_DBL exp_m, INT exp_e,
|
|
INT *result_e);
|
|
|
|
/**
|
|
* \brief return x ^ (exp_m * 2^exp_e), where log2(x) = baseLd_m * 2^(baseLd_e).
|
|
* This saves the need to compute log2() of constant values (when x is a
|
|
* constant). This version does not return an exponent, which is
|
|
* implicitly 0.
|
|
* \param baseLd_m mantissa of log2() of x.
|
|
* \param baseLd_e exponent of log2() of x.
|
|
* \param exp_m mantissa of the exponent to 2.0f
|
|
* \param exp_e exponent of the exponent to 2.0f
|
|
* \return mantissa of the result
|
|
*/
|
|
FIXP_DBL fLdPow(FIXP_DBL baseLd_m, INT baseLd_e, FIXP_DBL exp_m, INT exp_e);
|
|
|
|
/**
|
|
* \brief return (base_m * 2^base_e) ^ (exp * 2^exp_e). Use fLdPow() instead
|
|
* whenever possible.
|
|
* \param base_m mantissa of the base.
|
|
* \param base_e exponent of the base.
|
|
* \param exp_m mantissa of power to be calculated of the base.
|
|
* \param exp_e exponent of power to be calculated of the base.
|
|
* \param result_e pointer to a INT where the exponent of the result will be
|
|
* stored into.
|
|
* \return mantissa of the result.
|
|
*/
|
|
FIXP_DBL fPow(FIXP_DBL base_m, INT base_e, FIXP_DBL exp_m, INT exp_e,
|
|
INT *result_e);
|
|
|
|
/**
|
|
* \brief return (base_m * 2^base_e) ^ N
|
|
* \param base_m mantissa of the base. Must not be negative.
|
|
* \param base_e exponent of the base
|
|
* \param N power to be calculated of the base
|
|
* \param result_e pointer to a INT where the exponent of the result will be
|
|
* stored into
|
|
* \return mantissa of the result
|
|
*/
|
|
FIXP_DBL fPowInt(FIXP_DBL base_m, INT base_e, INT N, INT *result_e);
|
|
#endif /* #ifndef FUNCTION_fPow */
|
|
|
|
#ifndef FUNCTION_fLog2
|
|
/**
|
|
* \brief Calculate log(argument)/log(2) (logarithm with base 2). deprecated.
|
|
* Use fLog2() instead.
|
|
* \param arg mantissa of the argument
|
|
* \param arg_e exponent of the argument
|
|
* \param result_e pointer to an INT to store the exponent of the result
|
|
* \return the mantissa of the result.
|
|
* \param
|
|
*/
|
|
FIXP_DBL CalcLog2(FIXP_DBL arg, INT arg_e, INT *result_e);
|
|
|
|
/**
|
|
* \brief calculate logarithm of base 2 of x_m * 2^(x_e)
|
|
* \param x_m mantissa of the input value.
|
|
* \param x_e exponent of the input value.
|
|
* \param pointer to an INT where the exponent of the result is returned into.
|
|
* \return mantissa of the result.
|
|
*/
|
|
FDK_INLINE FIXP_DBL fLog2(FIXP_DBL x_m, INT x_e, INT *result_e) {
|
|
FIXP_DBL result_m;
|
|
|
|
/* Short cut for zero and negative numbers. */
|
|
if (x_m <= FL2FXCONST_DBL(0.0f)) {
|
|
*result_e = DFRACT_BITS - 1;
|
|
return FL2FXCONST_DBL(-1.0f);
|
|
}
|
|
|
|
/* Calculate log2() */
|
|
{
|
|
FIXP_DBL x2_m;
|
|
|
|
/* Move input value x_m * 2^x_e toward 1.0, where the taylor approximation
|
|
of the function log(1-x) centered at 0 is most accurate. */
|
|
{
|
|
INT b_norm;
|
|
|
|
b_norm = fNormz(x_m) - 1;
|
|
x2_m = x_m << b_norm;
|
|
x_e = x_e - b_norm;
|
|
}
|
|
|
|
/* map x from log(x) domain to log(1-x) domain. */
|
|
x2_m = -(x2_m + FL2FXCONST_DBL(-1.0));
|
|
|
|
/* Taylor polynomial approximation of ln(1-x) */
|
|
{
|
|
FIXP_DBL px2_m;
|
|
result_m = FL2FXCONST_DBL(0.0);
|
|
px2_m = x2_m;
|
|
for (int i = 0; i < LD_PRECISION; i++) {
|
|
result_m = fMultAddDiv2(result_m, ldCoeff[i], px2_m);
|
|
px2_m = fMult(px2_m, x2_m);
|
|
}
|
|
}
|
|
/* Multiply result with 1/ln(2) = 1.0 + 0.442695040888 (get log2(x) from
|
|
* ln(x) result). */
|
|
result_m =
|
|
fMultAddDiv2(result_m, result_m,
|
|
FL2FXCONST_DBL(2.0 * 0.4426950408889634073599246810019));
|
|
|
|
/* Add exponent part. log2(x_m * 2^x_e) = log2(x_m) + x_e */
|
|
if (x_e != 0) {
|
|
int enorm;
|
|
|
|
enorm = DFRACT_BITS - fNorm((FIXP_DBL)x_e);
|
|
/* The -1 in the right shift of result_m compensates the fMultDiv2() above
|
|
* in the taylor polynomial evaluation loop.*/
|
|
result_m = (result_m >> (enorm - 1)) +
|
|
((FIXP_DBL)x_e << (DFRACT_BITS - 1 - enorm));
|
|
|
|
*result_e = enorm;
|
|
} else {
|
|
/* 1 compensates the fMultDiv2() above in the taylor polynomial evaluation
|
|
* loop.*/
|
|
*result_e = 1;
|
|
}
|
|
}
|
|
|
|
return result_m;
|
|
}
|
|
|
|
/**
|
|
* \brief calculate logarithm of base 2 of x_m * 2^(x_e)
|
|
* \param x_m mantissa of the input value.
|
|
* \param x_e exponent of the input value.
|
|
* \return mantissa of the result with implicit exponent of LD_DATA_SHIFT.
|
|
*/
|
|
FDK_INLINE FIXP_DBL fLog2(FIXP_DBL x_m, INT x_e) {
|
|
if (x_m <= FL2FXCONST_DBL(0.0f)) {
|
|
x_m = FL2FXCONST_DBL(-1.0f);
|
|
} else {
|
|
INT result_e;
|
|
x_m = fLog2(x_m, x_e, &result_e);
|
|
x_m = scaleValue(x_m, result_e - LD_DATA_SHIFT);
|
|
}
|
|
return x_m;
|
|
}
|
|
|
|
#endif /* FUNCTION_fLog2 */
|
|
|
|
#ifndef FUNCTION_fAddSaturate
|
|
/**
|
|
* \brief Add with saturation of the result.
|
|
* \param a first summand
|
|
* \param b second summand
|
|
* \return saturated sum of a and b.
|
|
*/
|
|
inline FIXP_SGL fAddSaturate(const FIXP_SGL a, const FIXP_SGL b) {
|
|
LONG sum;
|
|
|
|
sum = (LONG)(SHORT)a + (LONG)(SHORT)b;
|
|
sum = fMax(fMin((INT)sum, (INT)MAXVAL_SGL), (INT)MINVAL_SGL);
|
|
return (FIXP_SGL)(SHORT)sum;
|
|
}
|
|
|
|
/**
|
|
* \brief Add with saturation of the result.
|
|
* \param a first summand
|
|
* \param b second summand
|
|
* \return saturated sum of a and b.
|
|
*/
|
|
inline FIXP_DBL fAddSaturate(const FIXP_DBL a, const FIXP_DBL b) {
|
|
LONG sum;
|
|
|
|
sum = (LONG)(a >> 1) + (LONG)(b >> 1);
|
|
sum = fMax(fMin((INT)sum, (INT)(MAXVAL_DBL >> 1)), (INT)(MINVAL_DBL >> 1));
|
|
return (FIXP_DBL)(LONG)(sum << 1);
|
|
}
|
|
#endif /* FUNCTION_fAddSaturate */
|
|
|
|
INT fixp_floorToInt(FIXP_DBL f_inp, INT sf);
|
|
FIXP_DBL fixp_floor(FIXP_DBL f_inp, INT sf);
|
|
|
|
INT fixp_ceilToInt(FIXP_DBL f_inp, INT sf);
|
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FIXP_DBL fixp_ceil(FIXP_DBL f_inp, INT sf);
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INT fixp_truncateToInt(FIXP_DBL f_inp, INT sf);
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FIXP_DBL fixp_truncate(FIXP_DBL f_inp, INT sf);
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INT fixp_roundToInt(FIXP_DBL f_inp, INT sf);
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FIXP_DBL fixp_round(FIXP_DBL f_inp, INT sf);
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/*****************************************************************************
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array for 1/n, n=1..80
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****************************************************************************/
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extern const FIXP_DBL invCount[80];
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LNK_SECTION_INITCODE
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inline void InitInvInt(void) {}
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/**
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* \brief Calculate the value of 1/i where i is a integer value. It supports
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* input values from 1 upto (80-1).
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* \param intValue Integer input value.
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* \param FIXP_DBL representation of 1/intValue
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*/
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inline FIXP_DBL GetInvInt(int intValue) {
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return invCount[fMin(fMax(intValue, 0), 80 - 1)];
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}
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#endif /* FIXPOINT_MATH_H */
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