Coverage Report

Created: 2026-07-16 06:55

next uncovered line (L), next uncovered region (R), next uncovered branch (B)
/src/aac/libSBRdec/src/hbe.cpp
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/* -----------------------------------------------------------------------------
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Software License for The Fraunhofer FDK AAC Codec Library for Android
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© Copyright  1995 - 2021 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
41
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
47
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
53
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
56
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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/**************************** SBR decoder library ******************************
96
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   Author(s):
98
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   Description:
100
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*******************************************************************************/
102
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/*!
104
  \file
105
  \brief  Fast FFT routines prototypes
106
  \author Fabian Haussel
107
*/
108
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#include "hbe.h"
110
#include "qmf.h"
111
#include "env_extr.h"
112
113
#define HBE_MAX_QMF_BANDS (40)
114
115
30.4M
#define HBE_MAX_OUT_SLOTS (11)
116
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#define QMF_WIN_LEN                                                          \
118
36.6M
  (12 + 6 - 4 - 1) /* 6 subband slots extra delay to align with HQ - 4 slots \
119
                      to compensate for critical sampling delay - 1 slot to  \
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                      align critical sampling exactly (w additional time     \
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                      domain delay)*/
122
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#ifndef PI
124
#define PI 3.14159265358979323846
125
#endif
126
127
static const int xProducts[MAX_STRETCH_HBE - 1] = {
128
    1, 1, 1}; /* Cross products on(1)/off(0) for T=2,3,4. */
129
static const int startSubband2kL[33] = {
130
    0, 0, 0, 0, 0, 0, 0,  2,  2,  2,  4,  4,  4,  4,  4,  6, 6,
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    6, 8, 8, 8, 8, 8, 10, 10, 10, 12, 12, 12, 12, 12, 12, 12};
132
133
static const int pmin = 12;
134
135
static const FIXP_DBL hintReal_F[4][3] = {
136
    {FL2FXCONST_DBL(0.39840335f), FL2FXCONST_DBL(0.39840335f),
137
     FL2FXCONST_DBL(-0.39840335f)},
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    {FL2FXCONST_DBL(0.39840335f), FL2FXCONST_DBL(-0.39840335f),
139
     FL2FXCONST_DBL(-0.39840335f)},
140
    {FL2FXCONST_DBL(-0.39840335f), FL2FXCONST_DBL(-0.39840335f),
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     FL2FXCONST_DBL(0.39840335f)},
142
    {FL2FXCONST_DBL(-0.39840335f), FL2FXCONST_DBL(0.39840335f),
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     FL2FXCONST_DBL(0.39840335f)}};
144
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static const FIXP_DBL factors[4] = {
146
    FL2FXCONST_DBL(0.39840335f), FL2FXCONST_DBL(-0.39840335f),
147
    FL2FXCONST_DBL(-0.39840335f), FL2FXCONST_DBL(0.39840335f)};
148
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#define PSCALE 32
150
151
static const FIXP_DBL p_F[128] = {FL2FXCONST_DBL(0.f / (PSCALE * 12.f)),
152
                                  FL2FXCONST_DBL(1.f / (PSCALE * 12.f)),
153
                                  FL2FXCONST_DBL(2.f / (PSCALE * 12.f)),
154
                                  FL2FXCONST_DBL(3.f / (PSCALE * 12.f)),
155
                                  FL2FXCONST_DBL(4.f / (PSCALE * 12.f)),
156
                                  FL2FXCONST_DBL(5.f / (PSCALE * 12.f)),
157
                                  FL2FXCONST_DBL(6.f / (PSCALE * 12.f)),
158
                                  FL2FXCONST_DBL(7.f / (PSCALE * 12.f)),
159
                                  FL2FXCONST_DBL(8.f / (PSCALE * 12.f)),
160
                                  FL2FXCONST_DBL(9.f / (PSCALE * 12.f)),
161
                                  FL2FXCONST_DBL(10.f / (PSCALE * 12.f)),
162
                                  FL2FXCONST_DBL(11.f / (PSCALE * 12.f)),
163
                                  FL2FXCONST_DBL(12.f / (PSCALE * 12.f)),
164
                                  FL2FXCONST_DBL(13.f / (PSCALE * 12.f)),
165
                                  FL2FXCONST_DBL(14.f / (PSCALE * 12.f)),
166
                                  FL2FXCONST_DBL(15.f / (PSCALE * 12.f)),
167
                                  FL2FXCONST_DBL(16.f / (PSCALE * 12.f)),
168
                                  FL2FXCONST_DBL(17.f / (PSCALE * 12.f)),
169
                                  FL2FXCONST_DBL(18.f / (PSCALE * 12.f)),
170
                                  FL2FXCONST_DBL(19.f / (PSCALE * 12.f)),
171
                                  FL2FXCONST_DBL(20.f / (PSCALE * 12.f)),
172
                                  FL2FXCONST_DBL(21.f / (PSCALE * 12.f)),
173
                                  FL2FXCONST_DBL(22.f / (PSCALE * 12.f)),
174
                                  FL2FXCONST_DBL(23.f / (PSCALE * 12.f)),
175
                                  FL2FXCONST_DBL(24.f / (PSCALE * 12.f)),
176
                                  FL2FXCONST_DBL(25.f / (PSCALE * 12.f)),
177
                                  FL2FXCONST_DBL(26.f / (PSCALE * 12.f)),
178
                                  FL2FXCONST_DBL(27.f / (PSCALE * 12.f)),
179
                                  FL2FXCONST_DBL(28.f / (PSCALE * 12.f)),
180
                                  FL2FXCONST_DBL(29.f / (PSCALE * 12.f)),
181
                                  FL2FXCONST_DBL(30.f / (PSCALE * 12.f)),
182
                                  FL2FXCONST_DBL(31.f / (PSCALE * 12.f)),
183
                                  FL2FXCONST_DBL(32.f / (PSCALE * 12.f)),
184
                                  FL2FXCONST_DBL(33.f / (PSCALE * 12.f)),
185
                                  FL2FXCONST_DBL(34.f / (PSCALE * 12.f)),
186
                                  FL2FXCONST_DBL(35.f / (PSCALE * 12.f)),
187
                                  FL2FXCONST_DBL(36.f / (PSCALE * 12.f)),
188
                                  FL2FXCONST_DBL(37.f / (PSCALE * 12.f)),
189
                                  FL2FXCONST_DBL(38.f / (PSCALE * 12.f)),
190
                                  FL2FXCONST_DBL(39.f / (PSCALE * 12.f)),
191
                                  FL2FXCONST_DBL(40.f / (PSCALE * 12.f)),
192
                                  FL2FXCONST_DBL(41.f / (PSCALE * 12.f)),
193
                                  FL2FXCONST_DBL(42.f / (PSCALE * 12.f)),
194
                                  FL2FXCONST_DBL(43.f / (PSCALE * 12.f)),
195
                                  FL2FXCONST_DBL(44.f / (PSCALE * 12.f)),
196
                                  FL2FXCONST_DBL(45.f / (PSCALE * 12.f)),
197
                                  FL2FXCONST_DBL(46.f / (PSCALE * 12.f)),
198
                                  FL2FXCONST_DBL(47.f / (PSCALE * 12.f)),
199
                                  FL2FXCONST_DBL(48.f / (PSCALE * 12.f)),
200
                                  FL2FXCONST_DBL(49.f / (PSCALE * 12.f)),
201
                                  FL2FXCONST_DBL(50.f / (PSCALE * 12.f)),
202
                                  FL2FXCONST_DBL(51.f / (PSCALE * 12.f)),
203
                                  FL2FXCONST_DBL(52.f / (PSCALE * 12.f)),
204
                                  FL2FXCONST_DBL(53.f / (PSCALE * 12.f)),
205
                                  FL2FXCONST_DBL(54.f / (PSCALE * 12.f)),
206
                                  FL2FXCONST_DBL(55.f / (PSCALE * 12.f)),
207
                                  FL2FXCONST_DBL(56.f / (PSCALE * 12.f)),
208
                                  FL2FXCONST_DBL(57.f / (PSCALE * 12.f)),
209
                                  FL2FXCONST_DBL(58.f / (PSCALE * 12.f)),
210
                                  FL2FXCONST_DBL(59.f / (PSCALE * 12.f)),
211
                                  FL2FXCONST_DBL(60.f / (PSCALE * 12.f)),
212
                                  FL2FXCONST_DBL(61.f / (PSCALE * 12.f)),
213
                                  FL2FXCONST_DBL(62.f / (PSCALE * 12.f)),
214
                                  FL2FXCONST_DBL(63.f / (PSCALE * 12.f)),
215
                                  FL2FXCONST_DBL(64.f / (PSCALE * 12.f)),
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                                  FL2FXCONST_DBL(65.f / (PSCALE * 12.f)),
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                                  FL2FXCONST_DBL(66.f / (PSCALE * 12.f)),
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                                  FL2FXCONST_DBL(67.f / (PSCALE * 12.f)),
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                                  FL2FXCONST_DBL(68.f / (PSCALE * 12.f)),
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                                  FL2FXCONST_DBL(69.f / (PSCALE * 12.f)),
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                                  FL2FXCONST_DBL(70.f / (PSCALE * 12.f)),
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                                  FL2FXCONST_DBL(71.f / (PSCALE * 12.f)),
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                                  FL2FXCONST_DBL(72.f / (PSCALE * 12.f)),
224
                                  FL2FXCONST_DBL(73.f / (PSCALE * 12.f)),
225
                                  FL2FXCONST_DBL(74.f / (PSCALE * 12.f)),
226
                                  FL2FXCONST_DBL(75.f / (PSCALE * 12.f)),
227
                                  FL2FXCONST_DBL(76.f / (PSCALE * 12.f)),
228
                                  FL2FXCONST_DBL(77.f / (PSCALE * 12.f)),
229
                                  FL2FXCONST_DBL(78.f / (PSCALE * 12.f)),
230
                                  FL2FXCONST_DBL(79.f / (PSCALE * 12.f)),
231
                                  FL2FXCONST_DBL(80.f / (PSCALE * 12.f)),
232
                                  FL2FXCONST_DBL(81.f / (PSCALE * 12.f)),
233
                                  FL2FXCONST_DBL(82.f / (PSCALE * 12.f)),
234
                                  FL2FXCONST_DBL(83.f / (PSCALE * 12.f)),
235
                                  FL2FXCONST_DBL(84.f / (PSCALE * 12.f)),
236
                                  FL2FXCONST_DBL(85.f / (PSCALE * 12.f)),
237
                                  FL2FXCONST_DBL(86.f / (PSCALE * 12.f)),
238
                                  FL2FXCONST_DBL(87.f / (PSCALE * 12.f)),
239
                                  FL2FXCONST_DBL(88.f / (PSCALE * 12.f)),
240
                                  FL2FXCONST_DBL(89.f / (PSCALE * 12.f)),
241
                                  FL2FXCONST_DBL(90.f / (PSCALE * 12.f)),
242
                                  FL2FXCONST_DBL(91.f / (PSCALE * 12.f)),
243
                                  FL2FXCONST_DBL(92.f / (PSCALE * 12.f)),
244
                                  FL2FXCONST_DBL(93.f / (PSCALE * 12.f)),
245
                                  FL2FXCONST_DBL(94.f / (PSCALE * 12.f)),
246
                                  FL2FXCONST_DBL(95.f / (PSCALE * 12.f)),
247
                                  FL2FXCONST_DBL(96.f / (PSCALE * 12.f)),
248
                                  FL2FXCONST_DBL(97.f / (PSCALE * 12.f)),
249
                                  FL2FXCONST_DBL(98.f / (PSCALE * 12.f)),
250
                                  FL2FXCONST_DBL(99.f / (PSCALE * 12.f)),
251
                                  FL2FXCONST_DBL(100.f / (PSCALE * 12.f)),
252
                                  FL2FXCONST_DBL(101.f / (PSCALE * 12.f)),
253
                                  FL2FXCONST_DBL(102.f / (PSCALE * 12.f)),
254
                                  FL2FXCONST_DBL(103.f / (PSCALE * 12.f)),
255
                                  FL2FXCONST_DBL(104.f / (PSCALE * 12.f)),
256
                                  FL2FXCONST_DBL(105.f / (PSCALE * 12.f)),
257
                                  FL2FXCONST_DBL(106.f / (PSCALE * 12.f)),
258
                                  FL2FXCONST_DBL(107.f / (PSCALE * 12.f)),
259
                                  FL2FXCONST_DBL(108.f / (PSCALE * 12.f)),
260
                                  FL2FXCONST_DBL(109.f / (PSCALE * 12.f)),
261
                                  FL2FXCONST_DBL(110.f / (PSCALE * 12.f)),
262
                                  FL2FXCONST_DBL(111.f / (PSCALE * 12.f)),
263
                                  FL2FXCONST_DBL(112.f / (PSCALE * 12.f)),
264
                                  FL2FXCONST_DBL(113.f / (PSCALE * 12.f)),
265
                                  FL2FXCONST_DBL(114.f / (PSCALE * 12.f)),
266
                                  FL2FXCONST_DBL(115.f / (PSCALE * 12.f)),
267
                                  FL2FXCONST_DBL(116.f / (PSCALE * 12.f)),
268
                                  FL2FXCONST_DBL(117.f / (PSCALE * 12.f)),
269
                                  FL2FXCONST_DBL(118.f / (PSCALE * 12.f)),
270
                                  FL2FXCONST_DBL(119.f / (PSCALE * 12.f)),
271
                                  FL2FXCONST_DBL(120.f / (PSCALE * 12.f)),
272
                                  FL2FXCONST_DBL(121.f / (PSCALE * 12.f)),
273
                                  FL2FXCONST_DBL(122.f / (PSCALE * 12.f)),
274
                                  FL2FXCONST_DBL(123.f / (PSCALE * 12.f)),
275
                                  FL2FXCONST_DBL(124.f / (PSCALE * 12.f)),
276
                                  FL2FXCONST_DBL(125.f / (PSCALE * 12.f)),
277
                                  FL2FXCONST_DBL(126.f / (PSCALE * 12.f)),
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                                  FL2FXCONST_DBL(127.f / (PSCALE * 12.f))};
279
280
static const FIXP_DBL band_F[64] = {
281
    FL2FXCONST_DBL((0.f * 2.f + 1) / (PSCALE << 2)),
282
    FL2FXCONST_DBL((1.f * 2.f + 1) / (PSCALE << 2)),
283
    FL2FXCONST_DBL((2.f * 2.f + 1) / (PSCALE << 2)),
284
    FL2FXCONST_DBL((3.f * 2.f + 1) / (PSCALE << 2)),
285
    FL2FXCONST_DBL((4.f * 2.f + 1) / (PSCALE << 2)),
286
    FL2FXCONST_DBL((5.f * 2.f + 1) / (PSCALE << 2)),
287
    FL2FXCONST_DBL((6.f * 2.f + 1) / (PSCALE << 2)),
288
    FL2FXCONST_DBL((7.f * 2.f + 1) / (PSCALE << 2)),
289
    FL2FXCONST_DBL((8.f * 2.f + 1) / (PSCALE << 2)),
290
    FL2FXCONST_DBL((9.f * 2.f + 1) / (PSCALE << 2)),
291
    FL2FXCONST_DBL((10.f * 2.f + 1) / (PSCALE << 2)),
292
    FL2FXCONST_DBL((11.f * 2.f + 1) / (PSCALE << 2)),
293
    FL2FXCONST_DBL((12.f * 2.f + 1) / (PSCALE << 2)),
294
    FL2FXCONST_DBL((13.f * 2.f + 1) / (PSCALE << 2)),
295
    FL2FXCONST_DBL((14.f * 2.f + 1) / (PSCALE << 2)),
296
    FL2FXCONST_DBL((15.f * 2.f + 1) / (PSCALE << 2)),
297
    FL2FXCONST_DBL((16.f * 2.f + 1) / (PSCALE << 2)),
298
    FL2FXCONST_DBL((17.f * 2.f + 1) / (PSCALE << 2)),
299
    FL2FXCONST_DBL((18.f * 2.f + 1) / (PSCALE << 2)),
300
    FL2FXCONST_DBL((19.f * 2.f + 1) / (PSCALE << 2)),
301
    FL2FXCONST_DBL((20.f * 2.f + 1) / (PSCALE << 2)),
302
    FL2FXCONST_DBL((21.f * 2.f + 1) / (PSCALE << 2)),
303
    FL2FXCONST_DBL((22.f * 2.f + 1) / (PSCALE << 2)),
304
    FL2FXCONST_DBL((23.f * 2.f + 1) / (PSCALE << 2)),
305
    FL2FXCONST_DBL((24.f * 2.f + 1) / (PSCALE << 2)),
306
    FL2FXCONST_DBL((25.f * 2.f + 1) / (PSCALE << 2)),
307
    FL2FXCONST_DBL((26.f * 2.f + 1) / (PSCALE << 2)),
308
    FL2FXCONST_DBL((27.f * 2.f + 1) / (PSCALE << 2)),
309
    FL2FXCONST_DBL((28.f * 2.f + 1) / (PSCALE << 2)),
310
    FL2FXCONST_DBL((29.f * 2.f + 1) / (PSCALE << 2)),
311
    FL2FXCONST_DBL((30.f * 2.f + 1) / (PSCALE << 2)),
312
    FL2FXCONST_DBL((31.f * 2.f + 1) / (PSCALE << 2)),
313
    FL2FXCONST_DBL((32.f * 2.f + 1) / (PSCALE << 2)),
314
    FL2FXCONST_DBL((33.f * 2.f + 1) / (PSCALE << 2)),
315
    FL2FXCONST_DBL((34.f * 2.f + 1) / (PSCALE << 2)),
316
    FL2FXCONST_DBL((35.f * 2.f + 1) / (PSCALE << 2)),
317
    FL2FXCONST_DBL((36.f * 2.f + 1) / (PSCALE << 2)),
318
    FL2FXCONST_DBL((37.f * 2.f + 1) / (PSCALE << 2)),
319
    FL2FXCONST_DBL((38.f * 2.f + 1) / (PSCALE << 2)),
320
    FL2FXCONST_DBL((39.f * 2.f + 1) / (PSCALE << 2)),
321
    FL2FXCONST_DBL((40.f * 2.f + 1) / (PSCALE << 2)),
322
    FL2FXCONST_DBL((41.f * 2.f + 1) / (PSCALE << 2)),
323
    FL2FXCONST_DBL((42.f * 2.f + 1) / (PSCALE << 2)),
324
    FL2FXCONST_DBL((43.f * 2.f + 1) / (PSCALE << 2)),
325
    FL2FXCONST_DBL((44.f * 2.f + 1) / (PSCALE << 2)),
326
    FL2FXCONST_DBL((45.f * 2.f + 1) / (PSCALE << 2)),
327
    FL2FXCONST_DBL((46.f * 2.f + 1) / (PSCALE << 2)),
328
    FL2FXCONST_DBL((47.f * 2.f + 1) / (PSCALE << 2)),
329
    FL2FXCONST_DBL((48.f * 2.f + 1) / (PSCALE << 2)),
330
    FL2FXCONST_DBL((49.f * 2.f + 1) / (PSCALE << 2)),
331
    FL2FXCONST_DBL((50.f * 2.f + 1) / (PSCALE << 2)),
332
    FL2FXCONST_DBL((51.f * 2.f + 1) / (PSCALE << 2)),
333
    FL2FXCONST_DBL((52.f * 2.f + 1) / (PSCALE << 2)),
334
    FL2FXCONST_DBL((53.f * 2.f + 1) / (PSCALE << 2)),
335
    FL2FXCONST_DBL((54.f * 2.f + 1) / (PSCALE << 2)),
336
    FL2FXCONST_DBL((55.f * 2.f + 1) / (PSCALE << 2)),
337
    FL2FXCONST_DBL((56.f * 2.f + 1) / (PSCALE << 2)),
338
    FL2FXCONST_DBL((57.f * 2.f + 1) / (PSCALE << 2)),
339
    FL2FXCONST_DBL((58.f * 2.f + 1) / (PSCALE << 2)),
340
    FL2FXCONST_DBL((59.f * 2.f + 1) / (PSCALE << 2)),
341
    FL2FXCONST_DBL((60.f * 2.f + 1) / (PSCALE << 2)),
342
    FL2FXCONST_DBL((61.f * 2.f + 1) / (PSCALE << 2)),
343
    FL2FXCONST_DBL((62.f * 2.f + 1) / (PSCALE << 2)),
344
    FL2FXCONST_DBL((63.f * 2.f + 1) / (PSCALE << 2))};
345
346
static const FIXP_DBL tr_str[3] = {FL2FXCONST_DBL(1.f / 4.f),
347
                                   FL2FXCONST_DBL(2.f / 4.f),
348
                                   FL2FXCONST_DBL(3.f / 4.f)};
349
350
static const FIXP_DBL stretchfac[3] = {FL2FXCONST_DBL(1.f / 2.f),
351
                                       FL2FXCONST_DBL(1.f / 3.f),
352
                                       FL2FXCONST_DBL(1.f / 4.f)};
353
354
static const FIXP_DBL cos_F[64] = {
355
    26353028,   -79043208,   131685776,  -184244944,  236697216,  -289006912,
356
    341142496,  -393072608,  444773984,  -496191392,  547325824,  -598114752,
357
    648559104,  -698597248,  748230016,  -797411904,  846083200,  -894275136,
358
    941928192,  -989013760,  1035474624, -1081340672, 1126555136, -1171063296,
359
    1214893696, -1257992192, 1300332544, -1341889408, 1382612736, -1422503808,
360
    1461586944, -1499741440, 1537039104, -1573364864, 1608743808, -1643196672,
361
    1676617344, -1709028992, 1740450560, -1770784896, 1800089472, -1828273536,
362
    1855357440, -1881356288, 1906190080, -1929876608, 1952428928, -1973777664,
363
    1993962880, -2012922240, 2030670208, -2047216000, 2062508288, -2076559488,
364
    2089376128, -2100932224, 2111196800, -2120214784, 2127953792, -2134394368,
365
    2139565056, -2143444864, 2146026624, -2147321856};
366
367
static const FIXP_DBL twiddle[121] = {1073741824,
368
                                      1071442860,
369
                                      1064555814,
370
                                      1053110176,
371
                                      1037154959,
372
                                      1016758484,
373
                                      992008094,
374
                                      963009773,
375
                                      929887697,
376
                                      892783698,
377
                                      851856663,
378
                                      807281846,
379
                                      759250125,
380
                                      707967178,
381
                                      653652607,
382
                                      596538995,
383
                                      536870912,
384
                                      474903865,
385
                                      410903207,
386
                                      345142998,
387
                                      277904834,
388
                                      209476638,
389
                                      140151432,
390
                                      70226075,
391
                                      0,
392
                                      -70226075,
393
                                      -140151432,
394
                                      -209476638,
395
                                      -277904834,
396
                                      -345142998,
397
                                      -410903207,
398
                                      -474903865,
399
                                      -536870912,
400
                                      -596538995,
401
                                      -653652607,
402
                                      -707967178,
403
                                      -759250125,
404
                                      -807281846,
405
                                      -851856663,
406
                                      -892783698,
407
                                      -929887697,
408
                                      -963009773,
409
                                      -992008094,
410
                                      -1016758484,
411
                                      -1037154959,
412
                                      -1053110176,
413
                                      -1064555814,
414
                                      -1071442860,
415
                                      -1073741824,
416
                                      -1071442860,
417
                                      -1064555814,
418
                                      -1053110176,
419
                                      -1037154959,
420
                                      -1016758484,
421
                                      -992008094,
422
                                      -963009773,
423
                                      -929887697,
424
                                      -892783698,
425
                                      -851856663,
426
                                      -807281846,
427
                                      -759250125,
428
                                      -707967178,
429
                                      -653652607,
430
                                      -596538995,
431
                                      -536870912,
432
                                      -474903865,
433
                                      -410903207,
434
                                      -345142998,
435
                                      -277904834,
436
                                      -209476638,
437
                                      -140151432,
438
                                      -70226075,
439
                                      0,
440
                                      70226075,
441
                                      140151432,
442
                                      209476638,
443
                                      277904834,
444
                                      345142998,
445
                                      410903207,
446
                                      474903865,
447
                                      536870912,
448
                                      596538995,
449
                                      653652607,
450
                                      707967178,
451
                                      759250125,
452
                                      807281846,
453
                                      851856663,
454
                                      892783698,
455
                                      929887697,
456
                                      963009773,
457
                                      992008094,
458
                                      1016758484,
459
                                      1037154959,
460
                                      1053110176,
461
                                      1064555814,
462
                                      1071442860,
463
                                      1073741824,
464
                                      1071442860,
465
                                      1064555814,
466
                                      1053110176,
467
                                      1037154959,
468
                                      1016758484,
469
                                      992008094,
470
                                      963009773,
471
                                      929887697,
472
                                      892783698,
473
                                      851856663,
474
                                      807281846,
475
                                      759250125,
476
                                      707967178,
477
                                      653652607,
478
                                      596538995,
479
                                      536870912,
480
                                      474903865,
481
                                      410903207,
482
                                      345142998,
483
                                      277904834,
484
                                      209476638,
485
                                      140151432,
486
                                      70226075,
487
                                      0};
488
489
#if FIXP_QTW == FIXP_SGL
490
#define HTW(x) (x)
491
#else
492
#define HTW(x) FX_DBL2FX_QTW(FX_SGL2FX_DBL((const FIXP_SGL)x))
493
#endif
494
495
static const FIXP_QTW post_twiddle_cos_8[8] = {
496
    HTW(-1606),  HTW(4756),  HTW(-7723),  HTW(10394),
497
    HTW(-12665), HTW(14449), HTW(-15679), HTW(16305)};
498
499
static const FIXP_QTW post_twiddle_cos_16[16] = {
500
    HTW(-804),   HTW(2404),  HTW(-3981),  HTW(5520),  HTW(-7005),  HTW(8423),
501
    HTW(-9760),  HTW(11003), HTW(-12140), HTW(13160), HTW(-14053), HTW(14811),
502
    HTW(-15426), HTW(15893), HTW(-16207), HTW(16364)};
503
504
static const FIXP_QTW post_twiddle_cos_24[24] = {
505
    HTW(-536),   HTW(1606),  HTW(-2669),  HTW(3720),  HTW(-4756),  HTW(5771),
506
    HTW(-6762),  HTW(7723),  HTW(-8652),  HTW(9543),  HTW(-10394), HTW(11200),
507
    HTW(-11958), HTW(12665), HTW(-13318), HTW(13913), HTW(-14449), HTW(14924),
508
    HTW(-15334), HTW(15679), HTW(-15956), HTW(16165), HTW(-16305), HTW(16375)};
509
510
static const FIXP_QTW post_twiddle_cos_32[32] = {
511
    HTW(-402),   HTW(1205),  HTW(-2006),  HTW(2801),  HTW(-3590),  HTW(4370),
512
    HTW(-5139),  HTW(5897),  HTW(-6639),  HTW(7366),  HTW(-8076),  HTW(8765),
513
    HTW(-9434),  HTW(10080), HTW(-10702), HTW(11297), HTW(-11866), HTW(12406),
514
    HTW(-12916), HTW(13395), HTW(-13842), HTW(14256), HTW(-14635), HTW(14978),
515
    HTW(-15286), HTW(15557), HTW(-15791), HTW(15986), HTW(-16143), HTW(16261),
516
    HTW(-16340), HTW(16379)};
517
518
static const FIXP_QTW post_twiddle_cos_40[40] = {
519
    HTW(-322),   HTW(965),   HTW(-1606),  HTW(2245),  HTW(-2880),  HTW(3511),
520
    HTW(-4137),  HTW(4756),  HTW(-5368),  HTW(5971),  HTW(-6566),  HTW(7150),
521
    HTW(-7723),  HTW(8285),  HTW(-8833),  HTW(9368),  HTW(-9889),  HTW(10394),
522
    HTW(-10883), HTW(11356), HTW(-11810), HTW(12247), HTW(-12665), HTW(13063),
523
    HTW(-13441), HTW(13799), HTW(-14135), HTW(14449), HTW(-14741), HTW(15011),
524
    HTW(-15257), HTW(15480), HTW(-15679), HTW(15853), HTW(-16003), HTW(16129),
525
    HTW(-16229), HTW(16305), HTW(-16356), HTW(16381)};
526
527
static const FIXP_QTW post_twiddle_sin_8[8] = {
528
    HTW(16305), HTW(-15679), HTW(14449), HTW(-12665),
529
    HTW(10394), HTW(-7723),  HTW(4756),  HTW(-1606)};
530
531
static const FIXP_QTW post_twiddle_sin_16[16] = {
532
    HTW(16364), HTW(-16207), HTW(15893), HTW(-15426), HTW(14811), HTW(-14053),
533
    HTW(13160), HTW(-12140), HTW(11003), HTW(-9760),  HTW(8423),  HTW(-7005),
534
    HTW(5520),  HTW(-3981),  HTW(2404),  HTW(-804)};
535
536
static const FIXP_QTW post_twiddle_sin_24[24] = {
537
    HTW(16375), HTW(-16305), HTW(16165), HTW(-15956), HTW(15679), HTW(-15334),
538
    HTW(14924), HTW(-14449), HTW(13913), HTW(-13318), HTW(12665), HTW(-11958),
539
    HTW(11200), HTW(-10394), HTW(9543),  HTW(-8652),  HTW(7723),  HTW(-6762),
540
    HTW(5771),  HTW(-4756),  HTW(3720),  HTW(-2669),  HTW(1606),  HTW(-536)};
541
542
static const FIXP_QTW post_twiddle_sin_32[32] = {
543
    HTW(16379), HTW(-16340), HTW(16261), HTW(-16143), HTW(15986), HTW(-15791),
544
    HTW(15557), HTW(-15286), HTW(14978), HTW(-14635), HTW(14256), HTW(-13842),
545
    HTW(13395), HTW(-12916), HTW(12406), HTW(-11866), HTW(11297), HTW(-10702),
546
    HTW(10080), HTW(-9434),  HTW(8765),  HTW(-8076),  HTW(7366),  HTW(-6639),
547
    HTW(5897),  HTW(-5139),  HTW(4370),  HTW(-3590),  HTW(2801),  HTW(-2006),
548
    HTW(1205),  HTW(-402)};
549
550
static const FIXP_QTW post_twiddle_sin_40[40] = {
551
    HTW(16381), HTW(-16356), HTW(16305), HTW(-16229), HTW(16129), HTW(-16003),
552
    HTW(15853), HTW(-15679), HTW(15480), HTW(-15257), HTW(15011), HTW(-14741),
553
    HTW(14449), HTW(-14135), HTW(13799), HTW(-13441), HTW(13063), HTW(-12665),
554
    HTW(12247), HTW(-11810), HTW(11356), HTW(-10883), HTW(10394), HTW(-9889),
555
    HTW(9368),  HTW(-8833),  HTW(8285),  HTW(-7723),  HTW(7150),  HTW(-6566),
556
    HTW(5971),  HTW(-5368),  HTW(4756),  HTW(-4137),  HTW(3511),  HTW(-2880),
557
    HTW(2245),  HTW(-1606),  HTW(965),   HTW(-322)};
558
559
static const FIXP_DBL preModCos[32] = {
560
    -749875776, 786681536,   711263552,  -821592064,  -670937792, 854523392,
561
    628995648,  -885396032,  -585538240, 914135680,   540670208,  -940673088,
562
    -494499680, 964944384,   447137824,  -986891008,  -398698816, 1006460096,
563
    349299264,  -1023604544, -299058240, 1038283072,  248096752,  -1050460288,
564
    -196537584, 1060106816,  144504928,  -1067199488, -92124160,  1071721152,
565
    39521456,   -1073660992};
566
567
static const FIXP_DBL preModSin[32] = {
568
    768510144,   730789760,  -804379072,  -691308864, 838310208,   650162560,
569
    -870221760,  -607449920, 900036928,   563273856,  -927683776,  -517740896,
570
    953095808,   470960608,  -976211712,  -423045728, 996975808,   374111712,
571
    -1015338112, -324276416, 1031254400,  273659904,  -1044686336, -222384144,
572
    1055601472,  170572640,  -1063973632, -118350192, 1069782528,  65842640,
573
    -1073014208, -13176464};
574
575
/* The cube root function */
576
/*****************************************************************************
577
578
    functionname: invCubeRootNorm2
579
    description:  delivers 1/cuberoot(op) in Q1.31 format and modified exponent
580
581
*****************************************************************************/
582
317M
#define CUBE_ROOT_BITS 7
583
#define CUBE_ROOT_VALUES (128 + 2)
584
158M
#define CUBE_ROOT_BITS_MASK 0x7f
585
158M
#define CUBE_ROOT_FRACT_BITS_MASK 0x007FFFFF
586
/* Inverse cube root table for operands running from 0.5 to 1.0 */
587
/* (INT) (1.0/cuberoot((op)));                    */
588
/* Implicit exponent is 1.                        */
589
590
LNK_SECTION_CONSTDATA
591
static const FIXP_DBL invCubeRootTab[CUBE_ROOT_VALUES] = {
592
    (0x50a28be6), (0x506d1172), (0x503823c4), (0x5003c05a), (0x4fcfe4c0),
593
    (0x4f9c8e92), (0x4f69bb7d), (0x4f37693b), (0x4f059594), (0x4ed43e5f),
594
    (0x4ea36181), (0x4e72fcea), (0x4e430e98), (0x4e139495), (0x4de48cf5),
595
    (0x4db5f5db), (0x4d87cd73), (0x4d5a11f2), (0x4d2cc19c), (0x4cffdabb),
596
    (0x4cd35ba4), (0x4ca742b7), (0x4c7b8e5c), (0x4c503d05), (0x4c254d2a),
597
    (0x4bfabd50), (0x4bd08c00), (0x4ba6b7cd), (0x4b7d3f53), (0x4b542134),
598
    (0x4b2b5c18), (0x4b02eeb1), (0x4adad7b8), (0x4ab315ea), (0x4a8ba80d),
599
    (0x4a648cec), (0x4a3dc35b), (0x4a174a30), (0x49f1204a), (0x49cb448d),
600
    (0x49a5b5e2), (0x49807339), (0x495b7b86), (0x4936cdc2), (0x491268ec),
601
    (0x48ee4c08), (0x48ca761f), (0x48a6e63e), (0x48839b76), (0x486094de),
602
    (0x483dd190), (0x481b50ad), (0x47f91156), (0x47d712b3), (0x47b553f0),
603
    (0x4793d43c), (0x477292c9), (0x47518ece), (0x4730c785), (0x47103c2d),
604
    (0x46efec06), (0x46cfd655), (0x46affa61), (0x46905777), (0x4670ece4),
605
    (0x4651b9f9), (0x4632be0b), (0x4613f871), (0x45f56885), (0x45d70da5),
606
    (0x45b8e72f), (0x459af487), (0x457d3511), (0x455fa835), (0x45424d5d),
607
    (0x452523f6), (0x45082b6e), (0x44eb6337), (0x44cecac5), (0x44b2618d),
608
    (0x44962708), (0x447a1ab1), (0x445e3c02), (0x44428a7c), (0x4427059e),
609
    (0x440bacec), (0x43f07fe9), (0x43d57e1c), (0x43baa70e), (0x439ffa48),
610
    (0x43857757), (0x436b1dc8), (0x4350ed2b), (0x4336e511), (0x431d050c),
611
    (0x43034cb2), (0x42e9bb98), (0x42d05156), (0x42b70d85), (0x429defc0),
612
    (0x4284f7a2), (0x426c24cb), (0x425376d8), (0x423aed6a), (0x42228823),
613
    (0x420a46a6), (0x41f22898), (0x41da2d9f), (0x41c25561), (0x41aa9f86),
614
    (0x41930bba), (0x417b99a5), (0x416448f5), (0x414d1956), (0x41360a76),
615
    (0x411f1c06), (0x41084db5), (0x40f19f35), (0x40db1039), (0x40c4a074),
616
    (0x40ae4f9b), (0x40981d64), (0x40820985), (0x406c13b6), (0x40563bb1),
617
    (0x4040812e), (0x402ae3e7), (0x40156399), (0x40000000), (0x3FEAB8D9)};
618
/*  n.a.  */
619
static const FIXP_DBL invCubeRootCorrection[3] = {0x40000000, 0x50A28BE6,
620
                                                  0x6597FA95};
621
622
/*****************************************************************************
623
 * \brief calculate 1.0/cube_root(op), op contains mantissa and exponent
624
 * \param op_m: (i) mantissa of operand, must not be zero (0x0000.0000) or
625
 * negative
626
 * \param op_e: (i) pointer to the exponent of the operand (must be initialized)
627
 * and .. (o) pointer to the exponent of the result
628
 * \return:     (o) mantissa of the result
629
 * \description:
630
 *  This routine calculates the cube root of the input operand, that is
631
 *  given with its mantissa in Q31 format (FIXP_DBL) and its exponent (INT).
632
 *  The resulting mantissa is returned in format Q31. The exponent (*op_e)
633
 *  is modified accordingly. It is not assured, that the result is fully
634
 * left-aligned but assumed to have not more than 2 bits headroom. There is one
635
 * macro to activate the use of this algorithm: FUNCTION_invCubeRootNorm2 By
636
 * means of activating the macro INVCUBEROOTNORM2_LINEAR_INTERPOLATE_HQ, a
637
 * slightly higher precision is reachable (by default, not active). For DEBUG
638
 * purpose only: a FDK_ASSERT macro validates, if the input mantissa is greater
639
 * zero.
640
 *
641
 */
642
static
643
#ifdef __arm__
644
    FIXP_DBL __attribute__((always_inline))
645
    invCubeRootNorm2(FIXP_DBL op_m, INT* op_e)
646
#else
647
    FIXP_DBL
648
    invCubeRootNorm2(FIXP_DBL op_m, INT* op_e)
649
#endif
650
158M
{
651
158M
  FDK_ASSERT(op_m > FIXP_DBL(0));
652
653
  /* normalize input, calculate shift value */
654
158M
  INT exponent = (INT)fNormz(op_m) - 1;
655
158M
  op_m <<= exponent;
656
657
158M
  INT index = (INT)(op_m >> (DFRACT_BITS - 1 - (CUBE_ROOT_BITS + 1))) &
658
158M
              CUBE_ROOT_BITS_MASK;
659
158M
  FIXP_DBL fract = (FIXP_DBL)(((INT)op_m & CUBE_ROOT_FRACT_BITS_MASK)
660
158M
                              << (CUBE_ROOT_BITS + 1));
661
158M
  FIXP_DBL diff = invCubeRootTab[index + 1] - invCubeRootTab[index];
662
158M
  op_m = fMultAddDiv2(invCubeRootTab[index], diff << 1, fract);
663
#if defined(INVCUBEROOTNORM2_LINEAR_INTERPOLATE_HQ)
664
  /* reg1 = t[i] + (t[i+1]-t[i])*fract ... already computed ... +
665
   * (1-fract)fract*(t[i+2]-t[i+1])/2 */
666
  if (fract != (FIXP_DBL)0) {
667
    /* fract = fract * (1 - fract) */
668
    fract = fMultDiv2(fract, (FIXP_DBL)((LONG)0x80000000 - (LONG)fract)) << 1;
669
    diff = diff - (invCubeRootTab[index + 2] - invCubeRootTab[index + 1]);
670
    op_m = fMultAddDiv2(op_m, fract, diff);
671
  }
672
#endif /* INVCUBEROOTNORM2_LINEAR_INTERPOLATE_HQ */
673
674
  /* calculate the output exponent = input * exp/3 = cubicroot(m)*2^(exp/3)
675
   * where 2^(exp/3) = 2^k'*2 or 2^k'*2^(1/3) or 2^k'*2^(2/3) */
676
158M
  exponent = exponent - *op_e + 3;
677
158M
  INT shift_tmp =
678
158M
      ((INT)fMultDiv2((FIXP_SGL)fAbs(exponent), (FIXP_SGL)0x5556)) >> 16;
679
158M
  if (exponent < 0) {
680
103M
    shift_tmp = -shift_tmp;
681
103M
  }
682
158M
  INT rem = exponent - 3 * shift_tmp;
683
158M
  if (rem < 0) {
684
69.4M
    rem += 3;
685
69.4M
    shift_tmp--;
686
69.4M
  }
687
688
158M
  *op_e = shift_tmp;
689
158M
  op_m = fMultDiv2(op_m, invCubeRootCorrection[rem]) << 2;
690
691
158M
  return (op_m);
692
158M
}
693
694
  /*****************************************************************************
695
696
      functionname: invFourthRootNorm2
697
      description:  delivers 1/FourthRoot(op) in Q1.31 format and modified
698
  exponent
699
700
  *****************************************************************************/
701
702
335M
#define FOURTHROOT_BITS 7
703
#define FOURTHROOT_VALUES (128 + 2)
704
167M
#define FOURTHROOT_BITS_MASK 0x7f
705
167M
#define FOURTHROOT_FRACT_BITS_MASK 0x007FFFFF
706
707
LNK_SECTION_CONSTDATA
708
static const FIXP_DBL invFourthRootTab[FOURTHROOT_VALUES] = {
709
    (0x4c1bf829), (0x4bf61977), (0x4bd09843), (0x4bab72ef), (0x4b86a7eb),
710
    (0x4b6235ac), (0x4b3e1ab6), (0x4b1a5592), (0x4af6e4d4), (0x4ad3c718),
711
    (0x4ab0fb03), (0x4a8e7f42), (0x4a6c5288), (0x4a4a7393), (0x4a28e126),
712
    (0x4a079a0c), (0x49e69d16), (0x49c5e91f), (0x49a57d04), (0x498557ac),
713
    (0x49657802), (0x4945dcf9), (0x49268588), (0x490770ac), (0x48e89d6a),
714
    (0x48ca0ac9), (0x48abb7d6), (0x488da3a6), (0x486fcd4f), (0x485233ed),
715
    (0x4834d6a3), (0x4817b496), (0x47faccf0), (0x47de1ee0), (0x47c1a999),
716
    (0x47a56c51), (0x47896643), (0x476d96af), (0x4751fcd6), (0x473697ff),
717
    (0x471b6773), (0x47006a81), (0x46e5a079), (0x46cb08ae), (0x46b0a279),
718
    (0x46966d34), (0x467c683d), (0x466292f4), (0x4648ecbc), (0x462f74fe),
719
    (0x46162b20), (0x45fd0e91), (0x45e41ebe), (0x45cb5b19), (0x45b2c315),
720
    (0x459a562a), (0x458213cf), (0x4569fb81), (0x45520cbc), (0x453a4701),
721
    (0x4522a9d1), (0x450b34b0), (0x44f3e726), (0x44dcc0ba), (0x44c5c0f7),
722
    (0x44aee768), (0x4498339e), (0x4481a527), (0x446b3b96), (0x4454f67e),
723
    (0x443ed576), (0x4428d815), (0x4412fdf3), (0x43fd46ad), (0x43e7b1de),
724
    (0x43d23f23), (0x43bcee1e), (0x43a7be6f), (0x4392afb8), (0x437dc19d),
725
    (0x4368f3c5), (0x435445d6), (0x433fb779), (0x432b4856), (0x4316f81a),
726
    (0x4302c66f), (0x42eeb305), (0x42dabd8a), (0x42c6e5ad), (0x42b32b21),
727
    (0x429f8d96), (0x428c0cc2), (0x4278a859), (0x42656010), (0x4252339e),
728
    (0x423f22bc), (0x422c2d23), (0x4219528b), (0x420692b2), (0x41f3ed51),
729
    (0x41e16228), (0x41cef0f2), (0x41bc9971), (0x41aa5b62), (0x41983687),
730
    (0x41862aa2), (0x41743775), (0x41625cc3), (0x41509a50), (0x413eefe2),
731
    (0x412d5d3e), (0x411be22b), (0x410a7e70), (0x40f931d5), (0x40e7fc23),
732
    (0x40d6dd24), (0x40c5d4a2), (0x40b4e268), (0x40a40642), (0x40933ffc),
733
    (0x40828f64), (0x4071f447), (0x40616e73), (0x4050fdb9), (0x4040a1e6),
734
    (0x40305acc), (0x4020283c), (0x40100a08), (0x40000000), (0x3ff009f9),
735
};
736
737
static const FIXP_DBL invFourthRootCorrection[4] = {0x40000000, 0x4C1BF829,
738
                                                    0x5A82799A, 0x6BA27E65};
739
740
/* The fourth root function */
741
/*****************************************************************************
742
 * \brief calculate 1.0/fourth_root(op), op contains mantissa and exponent
743
 * \param op_m: (i) mantissa of operand, must not be zero (0x0000.0000) or
744
 * negative
745
 * \param op_e: (i) pointer to the exponent of the operand (must be initialized)
746
 * and .. (o) pointer to the exponent of the result
747
 * \return:     (o) mantissa of the result
748
 * \description:
749
 *  This routine calculates the cube root of the input operand, that is
750
 *  given with its mantissa in Q31 format (FIXP_DBL) and its exponent (INT).
751
 *  The resulting mantissa is returned in format Q31. The exponent (*op_e)
752
 *  is modified accordingly. It is not assured, that the result is fully
753
 * left-aligned but assumed to have not more than 2 bits headroom. There is one
754
 * macro to activate the use of this algorithm: FUNCTION_invFourthRootNorm2 By
755
 * means of activating the macro INVFOURTHROOTNORM2_LINEAR_INTERPOLATE_HQ, a
756
 * slightly higher precision is reachable (by default, not active). For DEBUG
757
 * purpose only: a FDK_ASSERT macro validates, if the input mantissa is greater
758
 * zero.
759
 *
760
 */
761
762
/* #define INVFOURTHROOTNORM2_LINEAR_INTERPOLATE_HQ */
763
764
static
765
#ifdef __arm__
766
    FIXP_DBL __attribute__((always_inline))
767
    invFourthRootNorm2(FIXP_DBL op_m, INT* op_e)
768
#else
769
    FIXP_DBL
770
    invFourthRootNorm2(FIXP_DBL op_m, INT* op_e)
771
#endif
772
167M
{
773
167M
  FDK_ASSERT(op_m > FL2FXCONST_DBL(0.0));
774
775
  /* normalize input, calculate shift value */
776
167M
  INT exponent = (INT)fNormz(op_m) - 1;
777
167M
  op_m <<= exponent;
778
779
167M
  INT index = (INT)(op_m >> (DFRACT_BITS - 1 - (FOURTHROOT_BITS + 1))) &
780
167M
              FOURTHROOT_BITS_MASK;
781
167M
  FIXP_DBL fract = (FIXP_DBL)(((INT)op_m & FOURTHROOT_FRACT_BITS_MASK)
782
167M
                              << (FOURTHROOT_BITS + 1));
783
167M
  FIXP_DBL diff = invFourthRootTab[index + 1] - invFourthRootTab[index];
784
167M
  op_m = invFourthRootTab[index] + (fMultDiv2(diff, fract) << 1);
785
786
#if defined(INVFOURTHROOTNORM2_LINEAR_INTERPOLATE_HQ)
787
  /* reg1 = t[i] + (t[i+1]-t[i])*fract ... already computed ... +
788
   * (1-fract)fract*(t[i+2]-t[i+1])/2 */
789
  if (fract != (FIXP_DBL)0) {
790
    /* fract = fract * (1 - fract) */
791
    fract = fMultDiv2(fract, (FIXP_DBL)((LONG)0x80000000 - (LONG)fract)) << 1;
792
    diff = diff - (invFourthRootTab[index + 2] - invFourthRootTab[index + 1]);
793
    op_m = fMultAddDiv2(op_m, fract, diff);
794
  }
795
#endif /* INVFOURTHROOTNORM2_LINEAR_INTERPOLATE_HQ */
796
797
167M
  exponent = exponent - *op_e + 4;
798
167M
  INT rem = exponent & 0x00000003;
799
167M
  INT shift_tmp = (exponent >> 2);
800
801
167M
  *op_e = shift_tmp;
802
167M
  op_m = fMultDiv2(op_m, invFourthRootCorrection[rem]) << 2;
803
804
167M
  return (op_m);
805
167M
}
806
807
/*****************************************************************************
808
809
    functionname: inv3EigthRootNorm2
810
    description:  delivers 1/cubert(op) normalized to .5...1 and the shift value
811
of the OUTPUT
812
813
*****************************************************************************/
814
120M
#define THREEIGTHROOT_BITS 7
815
#define THREEIGTHROOT_VALUES (128 + 2)
816
60.2M
#define THREEIGTHROOT_BITS_MASK 0x7f
817
60.2M
#define THREEIGTHROOT_FRACT_BITS_MASK 0x007FFFFF
818
819
LNK_SECTION_CONSTDATA
820
static const FIXP_DBL inv3EigthRootTab[THREEIGTHROOT_VALUES] = {
821
    (0x45cae0f2), (0x45b981bf), (0x45a8492a), (0x45973691), (0x45864959),
822
    (0x457580e6), (0x4564dca4), (0x45545c00), (0x4543fe6b), (0x4533c35a),
823
    (0x4523aa44), (0x4513b2a4), (0x4503dbf7), (0x44f425be), (0x44e48f7b),
824
    (0x44d518b6), (0x44c5c0f7), (0x44b687c8), (0x44a76cb8), (0x44986f58),
825
    (0x44898f38), (0x447acbef), (0x446c2514), (0x445d9a3f), (0x444f2b0d),
826
    (0x4440d71a), (0x44329e07), (0x44247f73), (0x44167b04), (0x4408905e),
827
    (0x43fabf28), (0x43ed070b), (0x43df67b0), (0x43d1e0c5), (0x43c471f7),
828
    (0x43b71af6), (0x43a9db71), (0x439cb31c), (0x438fa1ab), (0x4382a6d2),
829
    (0x4375c248), (0x4368f3c5), (0x435c3b03), (0x434f97bc), (0x434309ac),
830
    (0x43369091), (0x432a2c28), (0x431ddc30), (0x4311a06c), (0x4305789c),
831
    (0x42f96483), (0x42ed63e5), (0x42e17688), (0x42d59c30), (0x42c9d4a6),
832
    (0x42be1fb1), (0x42b27d1a), (0x42a6ecac), (0x429b6e2f), (0x42900172),
833
    (0x4284a63f), (0x42795c64), (0x426e23b0), (0x4262fbf2), (0x4257e4f9),
834
    (0x424cde96), (0x4241e89a), (0x423702d8), (0x422c2d23), (0x4221674d),
835
    (0x4216b12c), (0x420c0a94), (0x4201735b), (0x41f6eb57), (0x41ec725f),
836
    (0x41e2084b), (0x41d7acf3), (0x41cd6030), (0x41c321db), (0x41b8f1ce),
837
    (0x41aecfe5), (0x41a4bbf8), (0x419ab5e6), (0x4190bd89), (0x4186d2bf),
838
    (0x417cf565), (0x41732558), (0x41696277), (0x415faca1), (0x415603b4),
839
    (0x414c6792), (0x4142d818), (0x4139552a), (0x412fdea6), (0x41267470),
840
    (0x411d1668), (0x4113c472), (0x410a7e70), (0x41014445), (0x40f815d4),
841
    (0x40eef302), (0x40e5dbb4), (0x40dccfcd), (0x40d3cf33), (0x40cad9cb),
842
    (0x40c1ef7b), (0x40b9102a), (0x40b03bbd), (0x40a7721c), (0x409eb32e),
843
    (0x4095feda), (0x408d5508), (0x4084b5a0), (0x407c208b), (0x407395b2),
844
    (0x406b14fd), (0x40629e56), (0x405a31a6), (0x4051ced8), (0x404975d5),
845
    (0x40412689), (0x4038e0dd), (0x4030a4bd), (0x40287215), (0x402048cf),
846
    (0x401828d7), (0x4010121a), (0x40080483), (0x40000000), (0x3ff8047d),
847
};
848
849
/* The last value is rounded in order to avoid any overflow due to the values
850
 * range of the root table */
851
static const FIXP_DBL inv3EigthRootCorrection[8] = {
852
    0x40000000, 0x45CAE0F2, 0x4C1BF829, 0x52FF6B55,
853
    0x5A82799A, 0x62B39509, 0x6BA27E65, 0x75606373};
854
855
/* The 3/8 root function */
856
/*****************************************************************************
857
 * \brief calculate 1.0/3Eigth_root(op) = 1.0/(x)^(3/8), op contains mantissa
858
 * and exponent
859
 * \param op_m: (i) mantissa of operand, must not be zero (0x0000.0000) or
860
 * negative
861
 * \param op_e: (i) pointer to the exponent of the operand (must be initialized)
862
 * and .. (o) pointer to the exponent of the result
863
 * \return:     (o) mantissa of the result
864
 * \description:
865
 *  This routine calculates the cube root of the input operand, that is
866
 *  given with its mantissa in Q31 format (FIXP_DBL) and its exponent (INT).
867
 *  The resulting mantissa is returned in format Q31. The exponent (*op_e)
868
 *  is modified accordingly. It is not assured, that the result is fully
869
 * left-aligned but assumed to have not more than 2 bits headroom. There is one
870
 * macro to activate the use of this algorithm: FUNCTION_inv3EigthRootNorm2 By
871
 * means of activating the macro INVTHREEIGTHROOTNORM2_LINEAR_INTERPOLATE_HQ, a
872
 * slightly higher precision is reachable (by default, not active). For DEBUG
873
 * purpose only: a FDK_ASSERT macro validates, if the input mantissa is greater
874
 * zero.
875
 *
876
 */
877
878
/* #define INVTHREEIGTHROOTNORM2_LINEAR_INTERPOLATE_HQ */
879
880
static
881
#ifdef __arm__
882
    FIXP_DBL __attribute__((always_inline))
883
    inv3EigthRootNorm2(FIXP_DBL op_m, INT* op_e)
884
#else
885
    FIXP_DBL
886
    inv3EigthRootNorm2(FIXP_DBL op_m, INT* op_e)
887
#endif
888
60.2M
{
889
60.2M
  FDK_ASSERT(op_m > FL2FXCONST_DBL(0.0));
890
891
  /* normalize input, calculate shift op_mue */
892
60.2M
  INT exponent = (INT)fNormz(op_m) - 1;
893
60.2M
  op_m <<= exponent;
894
895
60.2M
  INT index = (INT)(op_m >> (DFRACT_BITS - 1 - (THREEIGTHROOT_BITS + 1))) &
896
60.2M
              THREEIGTHROOT_BITS_MASK;
897
60.2M
  FIXP_DBL fract = (FIXP_DBL)(((INT)op_m & THREEIGTHROOT_FRACT_BITS_MASK)
898
60.2M
                              << (THREEIGTHROOT_BITS + 1));
899
60.2M
  FIXP_DBL diff = inv3EigthRootTab[index + 1] - inv3EigthRootTab[index];
900
60.2M
  op_m = inv3EigthRootTab[index] + (fMultDiv2(diff, fract) << 1);
901
902
#if defined(INVTHREEIGTHROOTNORM2_LINEAR_INTERPOLATE_HQ)
903
  /* op_m = t[i] + (t[i+1]-t[i])*fract ... already computed ... +
904
   * (1-fract)fract*(t[i+2]-t[i+1])/2 */
905
  if (fract != (FIXP_DBL)0) {
906
    /* fract = fract * (1 - fract) */
907
    fract = fMultDiv2(fract, (FIXP_DBL)((LONG)0x80000000 - (LONG)fract)) << 1;
908
    diff = diff - (inv3EigthRootTab[index + 2] - inv3EigthRootTab[index + 1]);
909
    op_m = fMultAddDiv2(op_m, fract, diff);
910
  }
911
#endif /* INVTHREEIGTHROOTNORM2_LINEAR_INTERPOLATE_HQ */
912
913
60.2M
  exponent = exponent - *op_e + 8;
914
60.2M
  INT rem = exponent & 0x00000007;
915
60.2M
  INT shift_tmp = (exponent >> 3);
916
917
60.2M
  *op_e = shift_tmp * 3;
918
60.2M
  op_m = fMultDiv2(op_m, inv3EigthRootCorrection[rem]) << 2;
919
920
60.2M
  return (fMult(op_m, fMult(op_m, op_m)));
921
60.2M
}
922
923
SBR_ERROR
924
QmfTransposerCreate(HANDLE_HBE_TRANSPOSER* hQmfTransposer, const int frameSize,
925
23.1k
                    int bDisableCrossProducts, int bSbr41) {
926
23.1k
  HANDLE_HBE_TRANSPOSER hQmfTran = NULL;
927
928
23.1k
  int i;
929
930
23.1k
  if (hQmfTransposer != NULL) {
931
    /* Memory allocation */
932
    /*--------------------------------------------------------------------------------------------*/
933
23.1k
    hQmfTran =
934
23.1k
        (HANDLE_HBE_TRANSPOSER)FDKcalloc(1, sizeof(struct hbeTransposer));
935
23.1k
    if (hQmfTran == NULL) {
936
0
      return SBRDEC_MEM_ALLOC_FAILED;
937
0
    }
938
939
92.5k
    for (i = 0; i < MAX_STRETCH_HBE - 1; i++) {
940
69.3k
      hQmfTran->bXProducts[i] = (bDisableCrossProducts ? 0 : xProducts[i]);
941
69.3k
    }
942
943
23.1k
    hQmfTran->timeDomainWinLen = frameSize;
944
23.1k
    if (frameSize == 768) {
945
6.15k
      hQmfTran->noCols =
946
6.15k
          (8 * frameSize / 3) / QMF_SYNTH_CHANNELS; /* 32 for 24:64 */
947
16.9k
    } else {
948
16.9k
      hQmfTran->noCols =
949
16.9k
          (bSbr41 + 1) * 2 * frameSize /
950
16.9k
          QMF_SYNTH_CHANNELS; /* 32 for 32:64 and 64 for 16:64 -> identical to
951
                                 sbrdec->no_cols */
952
16.9k
    }
953
954
23.1k
    hQmfTran->noChannels = frameSize / hQmfTran->noCols;
955
956
23.1k
    hQmfTran->qmfInBufSize = QMF_WIN_LEN;
957
23.1k
    hQmfTran->qmfOutBufSize = 2 * (hQmfTran->noCols / 2 + QMF_WIN_LEN - 1);
958
959
23.1k
    hQmfTran->inBuf_F =
960
23.1k
        (LONG*)FDKcalloc(QMF_SYNTH_CHANNELS + 20 + 1, sizeof(LONG));
961
    /* buffered time signal needs to be delayed by synthesis_size; max
962
     * synthesis_size = 20; */
963
23.1k
    if (hQmfTran->inBuf_F == NULL) {
964
0
      QmfTransposerClose(hQmfTran);
965
0
      return SBRDEC_MEM_ALLOC_FAILED;
966
0
    }
967
968
23.1k
    hQmfTran->qmfInBufReal_F =
969
23.1k
        (FIXP_DBL**)FDKcalloc(hQmfTran->qmfInBufSize, sizeof(FIXP_DBL*));
970
23.1k
    hQmfTran->qmfInBufImag_F =
971
23.1k
        (FIXP_DBL**)FDKcalloc(hQmfTran->qmfInBufSize, sizeof(FIXP_DBL*));
972
973
23.1k
    if (hQmfTran->qmfInBufReal_F == NULL) {
974
0
      QmfTransposerClose(hQmfTran);
975
0
      return SBRDEC_MEM_ALLOC_FAILED;
976
0
    }
977
23.1k
    if (hQmfTran->qmfInBufImag_F == NULL) {
978
0
      QmfTransposerClose(hQmfTran);
979
0
      return SBRDEC_MEM_ALLOC_FAILED;
980
0
    }
981
982
323k
    for (i = 0; i < hQmfTran->qmfInBufSize; i++) {
983
300k
      hQmfTran->qmfInBufReal_F[i] = (FIXP_DBL*)FDKaalloc(
984
300k
          QMF_SYNTH_CHANNELS * sizeof(FIXP_DBL), ALIGNMENT_DEFAULT);
985
300k
      hQmfTran->qmfInBufImag_F[i] = (FIXP_DBL*)FDKaalloc(
986
300k
          QMF_SYNTH_CHANNELS * sizeof(FIXP_DBL), ALIGNMENT_DEFAULT);
987
300k
      if (hQmfTran->qmfInBufReal_F[i] == NULL) {
988
0
        QmfTransposerClose(hQmfTran);
989
0
        return SBRDEC_MEM_ALLOC_FAILED;
990
0
      }
991
300k
      if (hQmfTran->qmfInBufImag_F[i] == NULL) {
992
0
        QmfTransposerClose(hQmfTran);
993
0
        return SBRDEC_MEM_ALLOC_FAILED;
994
0
      }
995
300k
    }
996
997
23.1k
    hQmfTran->qmfHBEBufReal_F =
998
23.1k
        (FIXP_DBL**)FDKcalloc(HBE_MAX_OUT_SLOTS, sizeof(FIXP_DBL*));
999
23.1k
    hQmfTran->qmfHBEBufImag_F =
1000
23.1k
        (FIXP_DBL**)FDKcalloc(HBE_MAX_OUT_SLOTS, sizeof(FIXP_DBL*));
1001
1002
23.1k
    if (hQmfTran->qmfHBEBufReal_F == NULL) {
1003
0
      QmfTransposerClose(hQmfTran);
1004
0
      return SBRDEC_MEM_ALLOC_FAILED;
1005
0
    }
1006
23.1k
    if (hQmfTran->qmfHBEBufImag_F == NULL) {
1007
0
      QmfTransposerClose(hQmfTran);
1008
0
      return SBRDEC_MEM_ALLOC_FAILED;
1009
0
    }
1010
1011
277k
    for (i = 0; i < HBE_MAX_OUT_SLOTS; i++) {
1012
254k
      hQmfTran->qmfHBEBufReal_F[i] =
1013
254k
          (FIXP_DBL*)FDKcalloc(QMF_SYNTH_CHANNELS, sizeof(FIXP_DBL));
1014
254k
      hQmfTran->qmfHBEBufImag_F[i] =
1015
254k
          (FIXP_DBL*)FDKcalloc(QMF_SYNTH_CHANNELS, sizeof(FIXP_DBL));
1016
254k
      if (hQmfTran->qmfHBEBufReal_F[i] == NULL) {
1017
0
        QmfTransposerClose(hQmfTran);
1018
0
        return SBRDEC_MEM_ALLOC_FAILED;
1019
0
      }
1020
254k
      if (hQmfTran->qmfHBEBufImag_F[i] == NULL) {
1021
0
        QmfTransposerClose(hQmfTran);
1022
0
        return SBRDEC_MEM_ALLOC_FAILED;
1023
0
      }
1024
254k
    }
1025
1026
23.1k
    hQmfTran->qmfBufferCodecTempSlot_F =
1027
23.1k
        (FIXP_DBL*)FDKcalloc(QMF_SYNTH_CHANNELS / 2, sizeof(FIXP_DBL));
1028
23.1k
    if (hQmfTran->qmfBufferCodecTempSlot_F == NULL) {
1029
0
      QmfTransposerClose(hQmfTran);
1030
0
      return SBRDEC_MEM_ALLOC_FAILED;
1031
0
    }
1032
1033
23.1k
    hQmfTran->bSbr41 = bSbr41;
1034
1035
23.1k
    hQmfTran->highband_exp[0] = 0;
1036
23.1k
    hQmfTran->highband_exp[1] = 0;
1037
23.1k
    hQmfTran->target_exp[0] = 0;
1038
23.1k
    hQmfTran->target_exp[1] = 0;
1039
1040
23.1k
    *hQmfTransposer = hQmfTran;
1041
23.1k
  }
1042
1043
23.1k
  return SBRDEC_OK;
1044
23.1k
}
1045
1046
SBR_ERROR QmfTransposerReInit(HANDLE_HBE_TRANSPOSER hQmfTransposer,
1047
                              UCHAR* FreqBandTable[2], UCHAR NSfb[2])
1048
/* removed bSbr41 from parameterlist:
1049
   don't know where to get this value from
1050
   at call-side */
1051
32.3k
{
1052
32.3k
  int L, sfb, patch, stopPatch, qmfErr;
1053
1054
32.3k
  if (hQmfTransposer != NULL) {
1055
32.3k
    const FIXP_QTW* tmp_t_cos;
1056
32.3k
    const FIXP_QTW* tmp_t_sin;
1057
1058
32.3k
    hQmfTransposer->startBand = FreqBandTable[0][0];
1059
32.3k
    FDK_ASSERT((!hQmfTransposer->bSbr41 && hQmfTransposer->startBand <= 32) ||
1060
32.3k
               (hQmfTransposer->bSbr41 &&
1061
32.3k
                hQmfTransposer->startBand <=
1062
32.3k
                    16)); /* is checked by resetFreqBandTables() */
1063
32.3k
    hQmfTransposer->stopBand = FreqBandTable[0][NSfb[0]];
1064
1065
32.3k
    hQmfTransposer->synthSize =
1066
32.3k
        4 * ((hQmfTransposer->startBand + 4) / 8 + 1); /* 8, 12, 16, 20 */
1067
32.3k
    hQmfTransposer->kstart = startSubband2kL[hQmfTransposer->startBand];
1068
1069
    /* don't know where to take this information from */
1070
    /* hQmfTransposer->bSbr41 = bSbr41;               */
1071
1072
32.3k
    if (hQmfTransposer->bSbr41) {
1073
6.86k
      if (hQmfTransposer->kstart + hQmfTransposer->synthSize > 16)
1074
3.31k
        hQmfTransposer->kstart = 16 - hQmfTransposer->synthSize;
1075
25.4k
    } else if (hQmfTransposer->timeDomainWinLen == 768) {
1076
24.8k
      if (hQmfTransposer->kstart + hQmfTransposer->synthSize > 24)
1077
12.6k
        hQmfTransposer->kstart = 24 - hQmfTransposer->synthSize;
1078
24.8k
    }
1079
1080
32.3k
    hQmfTransposer->synthesisQmfPreModCos_F =
1081
32.3k
        &preModCos[hQmfTransposer->kstart];
1082
32.3k
    hQmfTransposer->synthesisQmfPreModSin_F =
1083
32.3k
        &preModSin[hQmfTransposer->kstart];
1084
1085
32.3k
    L = 2 * hQmfTransposer->synthSize; /* 8, 16, 24, 32, 40 */
1086
                                       /* Change analysis post twiddles */
1087
1088
32.3k
    switch (L) {
1089
0
      case 8:
1090
0
        tmp_t_cos = post_twiddle_cos_8;
1091
0
        tmp_t_sin = post_twiddle_sin_8;
1092
0
        break;
1093
3.18k
      case 16:
1094
3.18k
        tmp_t_cos = post_twiddle_cos_16;
1095
3.18k
        tmp_t_sin = post_twiddle_sin_16;
1096
3.18k
        break;
1097
15.8k
      case 24:
1098
15.8k
        tmp_t_cos = post_twiddle_cos_24;
1099
15.8k
        tmp_t_sin = post_twiddle_sin_24;
1100
15.8k
        break;
1101
11.6k
      case 32:
1102
11.6k
        tmp_t_cos = post_twiddle_cos_32;
1103
11.6k
        tmp_t_sin = post_twiddle_sin_32;
1104
11.6k
        break;
1105
1.64k
      case 40:
1106
1.64k
        tmp_t_cos = post_twiddle_cos_40;
1107
1.64k
        tmp_t_sin = post_twiddle_sin_40;
1108
1.64k
        break;
1109
0
      default:
1110
0
        return SBRDEC_UNSUPPORTED_CONFIG;
1111
32.3k
    }
1112
1113
32.3k
    qmfErr = qmfInitSynthesisFilterBank(
1114
32.3k
        &hQmfTransposer->HBESynthesisQMF, hQmfTransposer->synQmfStates,
1115
32.3k
        hQmfTransposer->noCols, 0, hQmfTransposer->synthSize,
1116
32.3k
        hQmfTransposer->synthSize, 1);
1117
32.3k
    if (qmfErr != 0) {
1118
0
      return SBRDEC_UNSUPPORTED_CONFIG;
1119
0
    }
1120
1121
32.3k
    qmfErr = qmfInitAnalysisFilterBank(
1122
32.3k
        &hQmfTransposer->HBEAnalysiscQMF, hQmfTransposer->anaQmfStates,
1123
32.3k
        hQmfTransposer->noCols / 2, 0, 2 * hQmfTransposer->synthSize,
1124
32.3k
        2 * hQmfTransposer->synthSize, 0);
1125
1126
32.3k
    if (qmfErr != 0) {
1127
0
      return SBRDEC_UNSUPPORTED_CONFIG;
1128
0
    }
1129
1130
32.3k
    hQmfTransposer->HBEAnalysiscQMF.t_cos = tmp_t_cos;
1131
32.3k
    hQmfTransposer->HBEAnalysiscQMF.t_sin = tmp_t_sin;
1132
1133
32.3k
    FDKmemset(hQmfTransposer->xOverQmf, 0,
1134
32.3k
              MAX_NUM_PATCHES * sizeof(int)); /* global */
1135
32.3k
    sfb = 0;
1136
32.3k
    if (hQmfTransposer->bSbr41) {
1137
6.86k
      stopPatch = MAX_NUM_PATCHES;
1138
6.86k
      hQmfTransposer->maxStretch = MAX_STRETCH_HBE;
1139
25.4k
    } else {
1140
25.4k
      stopPatch = MAX_STRETCH_HBE;
1141
25.4k
    }
1142
1143
111k
    for (patch = 1; patch <= stopPatch; patch++) {
1144
400k
      while (sfb <= NSfb[0] &&
1145
367k
             FreqBandTable[0][sfb] <= patch * hQmfTransposer->startBand)
1146
288k
        sfb++;
1147
111k
      if (sfb <= NSfb[0]) {
1148
        /* If the distance is larger than three QMF bands - try aligning to high
1149
         * resolution frequency bands instead. */
1150
79.3k
        if ((patch * hQmfTransposer->startBand - FreqBandTable[0][sfb - 1]) <=
1151
79.3k
            3) {
1152
73.0k
          hQmfTransposer->xOverQmf[patch - 1] = FreqBandTable[0][sfb - 1];
1153
73.0k
        } else {
1154
6.30k
          int sfb_tmp = 0;
1155
96.8k
          while (sfb_tmp <= NSfb[1] &&
1156
96.8k
                 FreqBandTable[1][sfb_tmp] <= patch * hQmfTransposer->startBand)
1157
90.5k
            sfb_tmp++;
1158
6.30k
          hQmfTransposer->xOverQmf[patch - 1] = FreqBandTable[1][sfb_tmp - 1];
1159
6.30k
        }
1160
79.3k
      } else {
1161
32.2k
        hQmfTransposer->xOverQmf[patch - 1] = hQmfTransposer->stopBand;
1162
32.2k
        hQmfTransposer->maxStretch = fMin(patch, MAX_STRETCH_HBE);
1163
32.2k
        break;
1164
32.2k
      }
1165
111k
    }
1166
1167
32.3k
    hQmfTransposer->highband_exp[0] = 0;
1168
32.3k
    hQmfTransposer->highband_exp[1] = 0;
1169
32.3k
    hQmfTransposer->target_exp[0] = 0;
1170
32.3k
    hQmfTransposer->target_exp[1] = 0;
1171
32.3k
  }
1172
1173
32.3k
  return SBRDEC_OK;
1174
32.3k
}
1175
1176
23.1k
void QmfTransposerClose(HANDLE_HBE_TRANSPOSER hQmfTransposer) {
1177
23.1k
  int i;
1178
1179
23.1k
  if (hQmfTransposer != NULL) {
1180
23.1k
    if (hQmfTransposer->inBuf_F) FDKfree(hQmfTransposer->inBuf_F);
1181
1182
23.1k
    if (hQmfTransposer->qmfInBufReal_F) {
1183
323k
      for (i = 0; i < hQmfTransposer->qmfInBufSize; i++) {
1184
300k
        FDKafree(hQmfTransposer->qmfInBufReal_F[i]);
1185
300k
      }
1186
23.1k
      FDKfree(hQmfTransposer->qmfInBufReal_F);
1187
23.1k
    }
1188
1189
23.1k
    if (hQmfTransposer->qmfInBufImag_F) {
1190
323k
      for (i = 0; i < hQmfTransposer->qmfInBufSize; i++) {
1191
300k
        FDKafree(hQmfTransposer->qmfInBufImag_F[i]);
1192
300k
      }
1193
23.1k
      FDKfree(hQmfTransposer->qmfInBufImag_F);
1194
23.1k
    }
1195
1196
23.1k
    if (hQmfTransposer->qmfHBEBufReal_F) {
1197
277k
      for (i = 0; i < HBE_MAX_OUT_SLOTS; i++) {
1198
254k
        FDKfree(hQmfTransposer->qmfHBEBufReal_F[i]);
1199
254k
      }
1200
23.1k
      FDKfree(hQmfTransposer->qmfHBEBufReal_F);
1201
23.1k
    }
1202
1203
23.1k
    if (hQmfTransposer->qmfHBEBufImag_F) {
1204
277k
      for (i = 0; i < HBE_MAX_OUT_SLOTS; i++) {
1205
254k
        FDKfree(hQmfTransposer->qmfHBEBufImag_F[i]);
1206
254k
      }
1207
23.1k
      FDKfree(hQmfTransposer->qmfHBEBufImag_F);
1208
23.1k
    }
1209
1210
23.1k
    FDKfree(hQmfTransposer->qmfBufferCodecTempSlot_F);
1211
1212
23.1k
    FDKfree(hQmfTransposer);
1213
23.1k
  }
1214
23.1k
}
1215
1216
551M
inline void scaleUp(FIXP_DBL* real_m, FIXP_DBL* imag_m, INT* _e) {
1217
551M
  INT reserve;
1218
  /* shift gc_r and gc_i up if possible */
1219
551M
  reserve = CntLeadingZeros((INT(*real_m) ^ INT((*real_m >> 31))) |
1220
551M
                            (INT(*imag_m) ^ INT((*imag_m >> 31)))) -
1221
551M
            1;
1222
551M
  reserve = fMax(reserve - 1,
1223
551M
                 0); /* Leave one bit headroom such that (real_m^2 + imag_m^2)
1224
                        does not overflow later if both are 0x80000000. */
1225
551M
  reserve = fMin(reserve, *_e);
1226
551M
  FDK_ASSERT(reserve >= 0);
1227
551M
  *real_m <<= reserve;
1228
551M
  *imag_m <<= reserve;
1229
551M
  *_e -= reserve;
1230
551M
}
1231
1232
static void calculateCenterFIXP(FIXP_DBL gammaVecReal, FIXP_DBL gammaVecImag,
1233
                                FIXP_DBL* centerReal, FIXP_DBL* centerImag,
1234
79.3M
                                INT* exponent, int stretch, int mult) {
1235
79.3M
  scaleUp(&gammaVecReal, &gammaVecImag, exponent);
1236
79.3M
  FIXP_DBL energy = fPow2Div2(gammaVecReal) + fPow2Div2(gammaVecImag);
1237
1238
79.3M
  if (energy != FL2FXCONST_DBL(0.f)) {
1239
46.5M
    FIXP_DBL gc_r_m, gc_i_m, factor_m = (FIXP_DBL)0;
1240
46.5M
    INT factor_e, gc_e;
1241
46.5M
    factor_e = 2 * (*exponent) + 1;
1242
1243
46.5M
    switch (stretch) {
1244
16.8M
      case 2:
1245
16.8M
        factor_m = invFourthRootNorm2(energy, &factor_e);
1246
16.8M
        break;
1247
19.6M
      case 3:
1248
19.6M
        factor_m = invCubeRootNorm2(energy, &factor_e);
1249
19.6M
        break;
1250
10.0M
      case 4:
1251
10.0M
        factor_m = inv3EigthRootNorm2(energy, &factor_e);
1252
10.0M
        break;
1253
46.5M
    }
1254
1255
46.5M
    gc_r_m = fMultDiv2(gammaVecReal,
1256
46.5M
                       factor_m); /* exponent = HBE_SCALE + factor_e + 1 */
1257
46.5M
    gc_i_m = fMultDiv2(gammaVecImag,
1258
46.5M
                       factor_m); /* exponent = HBE_SCALE + factor_e + 1*/
1259
46.5M
    gc_e = *exponent + factor_e + 1;
1260
1261
46.5M
    scaleUp(&gc_r_m, &gc_i_m, &gc_e);
1262
1263
46.5M
    switch (mult) {
1264
18.9M
      case 0:
1265
18.9M
        *centerReal = gc_r_m;
1266
18.9M
        *centerImag = gc_i_m;
1267
18.9M
        break;
1268
18.7M
      case 1:
1269
18.7M
        *centerReal = fPow2Div2(gc_r_m) - fPow2Div2(gc_i_m);
1270
18.7M
        *centerImag = fMult(gc_r_m, gc_i_m);
1271
18.7M
        gc_e = 2 * gc_e + 1;
1272
18.7M
        break;
1273
8.75M
      case 2:
1274
8.75M
        FIXP_DBL tmp_r = gc_r_m;
1275
8.75M
        FIXP_DBL tmp_i = gc_i_m;
1276
8.75M
        gc_r_m = fPow2Div2(gc_r_m) - fPow2Div2(gc_i_m);
1277
8.75M
        gc_i_m = fMult(tmp_r, gc_i_m);
1278
8.75M
        gc_e = 3 * gc_e + 1 + 1;
1279
8.75M
        cplxMultDiv2(&centerReal[0], &centerImag[0], gc_r_m, gc_i_m, tmp_r,
1280
8.75M
                     tmp_i);
1281
8.75M
        break;
1282
46.5M
    }
1283
1284
46.5M
    scaleUp(centerReal, centerImag, &gc_e);
1285
1286
46.5M
    FDK_ASSERT(gc_e >= 0);
1287
46.5M
    *exponent = gc_e;
1288
46.5M
  } else {
1289
32.8M
    *centerReal = energy; /* energy = 0 */
1290
32.8M
    *centerImag = energy; /* energy = 0 */
1291
32.8M
    *exponent = (INT)energy;
1292
32.8M
  }
1293
79.3M
}
1294
1295
static int getHBEScaleFactorFrame(const int bSbr41, const int maxStretch,
1296
115k
                                  const int pitchInBins) {
1297
115k
  if (pitchInBins >= pmin * (1 + bSbr41)) {
1298
    /* crossproducts enabled */
1299
12.0k
    return 26;
1300
103k
  } else {
1301
103k
    return (maxStretch == 2) ? 24 : 25;
1302
103k
  }
1303
115k
}
1304
1305
static void addHighBandPart(FIXP_DBL g_r_m, FIXP_DBL g_i_m, INT g_e,
1306
                            FIXP_DBL mult, FIXP_DBL gammaCenterReal_m,
1307
                            FIXP_DBL gammaCenterImag_m, INT gammaCenter_e,
1308
                            INT stretch, INT scale_factor_hbe,
1309
                            FIXP_DBL* qmfHBEBufReal_F,
1310
611M
                            FIXP_DBL* qmfHBEBufImag_F) {
1311
611M
  if ((g_r_m | g_i_m) != FL2FXCONST_DBL(0.f)) {
1312
339M
    FIXP_DBL factor_m = (FIXP_DBL)0;
1313
339M
    INT factor_e;
1314
339M
    INT add = (stretch == 4) ? 1 : 0;
1315
339M
    INT shift = (stretch == 4) ? 1 : 2;
1316
1317
339M
    scaleUp(&g_r_m, &g_i_m, &g_e);
1318
339M
    FIXP_DBL energy = fPow2AddDiv2(fPow2Div2(g_r_m), g_i_m);
1319
339M
    factor_e = 2 * g_e + 1;
1320
1321
339M
    switch (stretch) {
1322
150M
      case 2:
1323
150M
        factor_m = invFourthRootNorm2(energy, &factor_e);
1324
150M
        break;
1325
138M
      case 3:
1326
138M
        factor_m = invCubeRootNorm2(energy, &factor_e);
1327
138M
        break;
1328
50.2M
      case 4:
1329
50.2M
        factor_m = inv3EigthRootNorm2(energy, &factor_e);
1330
50.2M
        break;
1331
339M
    }
1332
1333
339M
    factor_m = fMult(factor_m, mult);
1334
1335
339M
    FIXP_DBL tmp_r, tmp_i;
1336
339M
    cplxMultDiv2(&tmp_r, &tmp_i, g_r_m, g_i_m, gammaCenterReal_m,
1337
339M
                 gammaCenterImag_m);
1338
1339
339M
    g_r_m = fMultDiv2(tmp_r, factor_m) << shift;
1340
339M
    g_i_m = fMultDiv2(tmp_i, factor_m) << shift;
1341
339M
    g_e = scale_factor_hbe - (g_e + factor_e + gammaCenter_e + add);
1342
339M
    g_e = fMax((INT)0, g_e);
1343
339M
    *qmfHBEBufReal_F += g_r_m >> g_e;
1344
339M
    *qmfHBEBufImag_F += g_i_m >> g_e;
1345
339M
  }
1346
611M
}
1347
1348
void QmfTransposerApply(HANDLE_HBE_TRANSPOSER hQmfTransposer,
1349
                        FIXP_DBL** qmfBufferCodecReal,
1350
                        FIXP_DBL** qmfBufferCodecImag, int nColsIn,
1351
                        FIXP_DBL** ppQmfBufferOutReal_F,
1352
                        FIXP_DBL** ppQmfBufferOutImag_F,
1353
                        FIXP_DBL lpcFilterStatesReal[2 + (3 * (4))][(64)],
1354
                        FIXP_DBL lpcFilterStatesImag[2 + (3 * (4))][(64)],
1355
                        int pitchInBins, int scale_lb, int scale_hbe,
1356
                        int* scale_hb, int timeStep, int firstSlotOffsset,
1357
                        int ov_len,
1358
115k
                        KEEP_STATES_SYNCED_MODE keepStatesSyncedMode) {
1359
115k
  int i, j, stretch, band, sourceband, r, s;
1360
115k
  int qmfVocoderColsIn = hQmfTransposer->noCols / 2;
1361
115k
  int bSbr41 = hQmfTransposer->bSbr41;
1362
1363
115k
  const int winLength[3] = {10, 8, 6};
1364
115k
  const int slotOffset = 6; /* hQmfTransposer->winLen-6; */
1365
1366
115k
  int qmfOffset = 2 * hQmfTransposer->kstart;
1367
115k
  int scale_border = (nColsIn == 64) ? 32 : nColsIn;
1368
1369
115k
  INT slot_stretch4[9] = {0, 0, 0, 0, 2, 4, 6, 8, 10};
1370
115k
  INT slot_stretch2[11] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10};
1371
115k
  INT slot_stretch3[10] = {0, 0, 0, 1, 3, 4, 6, 7, 9, 10};
1372
115k
  INT filt_stretch3[10] = {0, 0, 0, 1, 0, 1, 0, 1, 0, 1};
1373
115k
  INT filt_dummy[11] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
1374
115k
  INT* pSlotStretch;
1375
115k
  INT* pFilt;
1376
1377
115k
  int offset = 0; /* where to take  QmfTransposer data */
1378
1379
115k
  int signPreMod =
1380
115k
      (hQmfTransposer->synthesisQmfPreModCos_F[0] < FL2FXCONST_DBL(0.f)) ? 1
1381
115k
                                                                         : -1;
1382
1383
115k
  int scale_factor_hbe =
1384
115k
      getHBEScaleFactorFrame(bSbr41, hQmfTransposer->maxStretch, pitchInBins);
1385
1386
115k
  if (keepStatesSyncedMode != KEEP_STATES_SYNCED_OFF) {
1387
75.5k
    offset = hQmfTransposer->noCols - ov_len - LPC_ORDER;
1388
75.5k
  }
1389
1390
115k
  hQmfTransposer->highband_exp[0] = hQmfTransposer->highband_exp[1];
1391
115k
  hQmfTransposer->target_exp[0] = hQmfTransposer->target_exp[1];
1392
1393
115k
  hQmfTransposer->highband_exp[1] = scale_factor_hbe;
1394
115k
  hQmfTransposer->target_exp[1] =
1395
115k
      fixMax(hQmfTransposer->highband_exp[1], hQmfTransposer->highband_exp[0]);
1396
1397
115k
  scale_factor_hbe = hQmfTransposer->target_exp[1];
1398
1399
115k
  int shift_ov = hQmfTransposer->target_exp[0] - hQmfTransposer->target_exp[1];
1400
1401
115k
  if (shift_ov != 0) {
1402
471k
    for (i = 0; i < HBE_MAX_OUT_SLOTS; i++) {
1403
432k
      scaleValuesSaturate(&hQmfTransposer->qmfHBEBufReal_F[i][0],
1404
432k
                          QMF_SYNTH_CHANNELS, shift_ov);
1405
432k
      scaleValuesSaturate(&hQmfTransposer->qmfHBEBufImag_F[i][0],
1406
432k
                          QMF_SYNTH_CHANNELS, shift_ov);
1407
432k
    }
1408
1409
39.3k
    if (keepStatesSyncedMode == KEEP_STATES_SYNCED_OFF) {
1410
4.75k
      int nBands =
1411
4.75k
          fMax(0, hQmfTransposer->stopBand - hQmfTransposer->startBand);
1412
1413
23.2k
      for (i = timeStep * firstSlotOffsset; i < ov_len; i++) {
1414
18.5k
        scaleValuesSaturate(&ppQmfBufferOutReal_F[i][hQmfTransposer->startBand],
1415
18.5k
                            nBands, shift_ov);
1416
18.5k
        scaleValuesSaturate(&ppQmfBufferOutImag_F[i][hQmfTransposer->startBand],
1417
18.5k
                            nBands, shift_ov);
1418
18.5k
      }
1419
1420
      /* shift lpc filterstates */
1421
27.8k
      for (i = 0; i < timeStep * firstSlotOffsset + LPC_ORDER; i++) {
1422
23.0k
        scaleValuesSaturate(&lpcFilterStatesReal[i][0], (64), shift_ov);
1423
23.0k
        scaleValuesSaturate(&lpcFilterStatesImag[i][0], (64), shift_ov);
1424
23.0k
      }
1425
4.75k
    }
1426
39.3k
  }
1427
1428
115k
  FIXP_DBL twid_m_new[3][2]; /* [stretch][cos/sin] */
1429
115k
  INT stepsize = 1 + !bSbr41, sine_offset = 24, mod = 96;
1430
115k
  INT mult[3] = {1, 2, 3};
1431
1432
463k
  for (s = 0; s <= MAX_STRETCH_HBE - 2; s++) {
1433
347k
    twid_m_new[s][0] = twiddle[(mult[s] * (stepsize * pitchInBins)) % mod];
1434
347k
    twid_m_new[s][1] =
1435
347k
        twiddle[((mult[s] * (stepsize * pitchInBins)) + sine_offset) % mod];
1436
347k
  }
1437
1438
  /* Time-stretch */
1439
2.51M
  for (j = 0; j < qmfVocoderColsIn; j++) {
1440
2.39M
    int sign = -1, k, z, addrshift, codecTemp_e;
1441
    /* update inbuf */
1442
32.7M
    for (i = 0; i < hQmfTransposer->synthSize; i++) {
1443
30.3M
      hQmfTransposer->inBuf_F[i] =
1444
30.3M
          hQmfTransposer->inBuf_F[i + 2 * hQmfTransposer->synthSize];
1445
30.3M
    }
1446
1447
    /* run synthesis for two sbr slots as transposer uses
1448
    half slots double bands representation */
1449
7.18M
    for (z = 0; z < 2; z++) {
1450
4.79M
      int scale_factor = ((nColsIn == 64) && ((2 * j + z) < scale_border))
1451
4.79M
                             ? scale_lb
1452
4.79M
                             : scale_hbe;
1453
4.79M
      codecTemp_e = scale_factor - 1; /* -2 for Div2 and cos/sin scale of 1 */
1454
1455
65.4M
      for (k = 0; k < hQmfTransposer->synthSize; k++) {
1456
60.6M
        int ki = hQmfTransposer->kstart + k;
1457
60.6M
        hQmfTransposer->qmfBufferCodecTempSlot_F[k] =
1458
60.6M
            fMultDiv2(signPreMod * hQmfTransposer->synthesisQmfPreModCos_F[k],
1459
60.6M
                      qmfBufferCodecReal[2 * j + z][ki]);
1460
60.6M
        hQmfTransposer->qmfBufferCodecTempSlot_F[k] +=
1461
60.6M
            fMultDiv2(signPreMod * hQmfTransposer->synthesisQmfPreModSin_F[k],
1462
60.6M
                      qmfBufferCodecImag[2 * j + z][ki]);
1463
60.6M
      }
1464
1465
4.79M
      C_AALLOC_SCRATCH_START(pWorkBuffer, FIXP_DBL, (HBE_MAX_QMF_BANDS << 1));
1466
1467
4.79M
      qmfSynthesisFilteringSlot(
1468
4.79M
          &hQmfTransposer->HBESynthesisQMF,
1469
4.79M
          hQmfTransposer->qmfBufferCodecTempSlot_F, NULL, 0,
1470
4.79M
          -7 - hQmfTransposer->HBESynthesisQMF.filterScale - codecTemp_e + 1,
1471
4.79M
          hQmfTransposer->inBuf_F + hQmfTransposer->synthSize * (z + 1), 1,
1472
4.79M
          pWorkBuffer);
1473
1474
4.79M
      C_AALLOC_SCRATCH_END(pWorkBuffer, FIXP_DBL, (HBE_MAX_QMF_BANDS << 1));
1475
4.79M
    }
1476
1477
2.39M
    C_AALLOC_SCRATCH_START(pWorkBuffer, FIXP_DBL, (HBE_MAX_QMF_BANDS << 1));
1478
1479
2.39M
    qmfAnalysisFilteringSlot(&hQmfTransposer->HBEAnalysiscQMF,
1480
2.39M
                             hQmfTransposer->qmfInBufReal_F[QMF_WIN_LEN - 1],
1481
2.39M
                             hQmfTransposer->qmfInBufImag_F[QMF_WIN_LEN - 1],
1482
2.39M
                             hQmfTransposer->inBuf_F + 1, 1, pWorkBuffer);
1483
1484
2.39M
    C_AALLOC_SCRATCH_END(pWorkBuffer, FIXP_DBL, (HBE_MAX_QMF_BANDS << 1));
1485
1486
2.39M
    if ((keepStatesSyncedMode == KEEP_STATES_SYNCED_NORMAL) &&
1487
620k
        j <= qmfVocoderColsIn - ((LPC_ORDER + ov_len + QMF_WIN_LEN - 1) >> 1)) {
1488
      /* update in buffer */
1489
4.13M
      for (i = 0; i < QMF_WIN_LEN - 1; i++) {
1490
3.81M
        FDKmemcpy(
1491
3.81M
            hQmfTransposer->qmfInBufReal_F[i],
1492
3.81M
            hQmfTransposer->qmfInBufReal_F[i + 1],
1493
3.81M
            sizeof(FIXP_DBL) * hQmfTransposer->HBEAnalysiscQMF.no_channels);
1494
3.81M
        FDKmemcpy(
1495
3.81M
            hQmfTransposer->qmfInBufImag_F[i],
1496
3.81M
            hQmfTransposer->qmfInBufImag_F[i + 1],
1497
3.81M
            sizeof(FIXP_DBL) * hQmfTransposer->HBEAnalysiscQMF.no_channels);
1498
3.81M
      }
1499
318k
      continue;
1500
318k
    }
1501
1502
6.97M
    for (stretch = 2; stretch <= hQmfTransposer->maxStretch; stretch++) {
1503
4.89M
      int start = slotOffset - winLength[stretch - 2] / 2;
1504
4.89M
      int stop = slotOffset + winLength[stretch - 2] / 2;
1505
1506
4.89M
      FIXP_DBL factor = FL2FXCONST_DBL(1.f / 3.f);
1507
1508
4.89M
      for (band = hQmfTransposer->xOverQmf[stretch - 2];
1509
70.8M
           band < hQmfTransposer->xOverQmf[stretch - 1]; band++) {
1510
65.9M
        FIXP_DBL gammaCenterReal_m[2] = {(FIXP_DBL)0, (FIXP_DBL)0},
1511
65.9M
                 gammaCenterImag_m[2] = {(FIXP_DBL)0, (FIXP_DBL)0};
1512
65.9M
        INT gammaCenter_e[2] = {0, 0};
1513
1514
65.9M
        FIXP_DBL gammaVecReal_m[2] = {(FIXP_DBL)0, (FIXP_DBL)0},
1515
65.9M
                 gammaVecImag_m[2] = {(FIXP_DBL)0, (FIXP_DBL)0};
1516
65.9M
        INT gammaVec_e[2] = {0, 0};
1517
1518
65.9M
        FIXP_DBL wingain = (FIXP_DBL)0;
1519
1520
65.9M
        gammaCenter_e[0] =
1521
65.9M
            SCALE2EXP(-hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1522
65.9M
        gammaCenter_e[1] =
1523
65.9M
            SCALE2EXP(-hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1524
1525
        /* interpolation filters for 3rd order */
1526
65.9M
        sourceband = 2 * band / stretch - qmfOffset;
1527
65.9M
        FDK_ASSERT(sourceband >= 0);
1528
1529
        /* maximum gammaCenter_e == 20 */
1530
65.9M
        calculateCenterFIXP(
1531
65.9M
            hQmfTransposer->qmfInBufReal_F[slotOffset][sourceband],
1532
65.9M
            hQmfTransposer->qmfInBufImag_F[slotOffset][sourceband],
1533
65.9M
            &gammaCenterReal_m[0], &gammaCenterImag_m[0], &gammaCenter_e[0],
1534
65.9M
            stretch, stretch - 2);
1535
1536
65.9M
        if (stretch == 4) {
1537
16.0M
          r = band - 2 * (band / 2);
1538
16.0M
          sourceband += (r == 0) ? -1 : 1;
1539
16.0M
          pSlotStretch = slot_stretch4;
1540
16.0M
          factor = FL2FXCONST_DBL(2.f / 3.f);
1541
16.0M
          pFilt = filt_dummy;
1542
49.9M
        } else if (stretch == 2) {
1543
26.7M
          r = 0;
1544
26.7M
          sourceband = 2 * band / stretch - qmfOffset;
1545
26.7M
          pSlotStretch = slot_stretch2;
1546
26.7M
          factor = FL2FXCONST_DBL(1.f / 3.f);
1547
26.7M
          pFilt = filt_dummy;
1548
26.7M
        } else {
1549
23.1M
          r = 2 * band - 3 * (2 * band / 3);
1550
23.1M
          sourceband = 2 * band / stretch - qmfOffset;
1551
23.1M
          pSlotStretch = slot_stretch3;
1552
23.1M
          factor = FL2FXCONST_DBL(1.4142f / 3.0f);
1553
23.1M
          pFilt = filt_stretch3;
1554
23.1M
        }
1555
1556
65.9M
        if (r == 2) {
1557
7.77M
          calculateCenterFIXP(
1558
7.77M
              hQmfTransposer->qmfInBufReal_F[slotOffset][sourceband + 1],
1559
7.77M
              hQmfTransposer->qmfInBufImag_F[slotOffset][sourceband + 1],
1560
7.77M
              &gammaCenterReal_m[1], &gammaCenterImag_m[1], &gammaCenter_e[1],
1561
7.77M
              stretch, stretch - 2);
1562
1563
7.77M
          factor = FL2FXCONST_DBL(1.4142f / 6.0f);
1564
7.77M
        }
1565
1566
65.9M
        if (r == 2) {
1567
69.9M
          for (k = start; k < stop; k++) {
1568
62.2M
            gammaVecReal_m[0] =
1569
62.2M
                hQmfTransposer->qmfInBufReal_F[pSlotStretch[k]][sourceband];
1570
62.2M
            gammaVecReal_m[1] =
1571
62.2M
                hQmfTransposer->qmfInBufReal_F[pSlotStretch[k]][sourceband + 1];
1572
62.2M
            gammaVecImag_m[0] =
1573
62.2M
                hQmfTransposer->qmfInBufImag_F[pSlotStretch[k]][sourceband];
1574
62.2M
            gammaVecImag_m[1] =
1575
62.2M
                hQmfTransposer->qmfInBufImag_F[pSlotStretch[k]][sourceband + 1];
1576
62.2M
            gammaVec_e[0] = gammaVec_e[1] =
1577
62.2M
                SCALE2EXP(-hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1578
1579
62.2M
            if (pFilt[k] == 1) {
1580
31.1M
              FIXP_DBL tmpRealF = gammaVecReal_m[0], tmpImagF;
1581
31.1M
              gammaVecReal_m[0] =
1582
31.1M
                  (fMult(gammaVecReal_m[0], hintReal_F[sourceband % 4][1]) -
1583
31.1M
                   fMult(gammaVecImag_m[0],
1584
31.1M
                         hintReal_F[(sourceband + 3) % 4][1])) >>
1585
31.1M
                  1; /* sum should be <= 1 because of sin/cos multiplication */
1586
31.1M
              gammaVecImag_m[0] =
1587
31.1M
                  (fMult(tmpRealF, hintReal_F[(sourceband + 3) % 4][1]) +
1588
31.1M
                   fMult(gammaVecImag_m[0], hintReal_F[sourceband % 4][1])) >>
1589
31.1M
                  1; /* sum should be <= 1 because of sin/cos multiplication */
1590
1591
31.1M
              tmpRealF = hQmfTransposer
1592
31.1M
                             ->qmfInBufReal_F[pSlotStretch[k] + 1][sourceband];
1593
31.1M
              tmpImagF = hQmfTransposer
1594
31.1M
                             ->qmfInBufImag_F[pSlotStretch[k] + 1][sourceband];
1595
1596
31.1M
              gammaVecReal_m[0] +=
1597
31.1M
                  (fMult(tmpRealF, hintReal_F[sourceband % 4][1]) -
1598
31.1M
                   fMult(tmpImagF, hintReal_F[(sourceband + 1) % 4][1])) >>
1599
31.1M
                  1; /* sum should be <= 1 because of sin/cos multiplication */
1600
31.1M
              gammaVecImag_m[0] +=
1601
31.1M
                  (fMult(tmpRealF, hintReal_F[(sourceband + 1) % 4][1]) +
1602
31.1M
                   fMult(tmpImagF, hintReal_F[sourceband % 4][1])) >>
1603
31.1M
                  1; /* sum should be <= 1 because of sin/cos multiplication */
1604
31.1M
              gammaVec_e[0]++;
1605
1606
31.1M
              tmpRealF = gammaVecReal_m[1];
1607
1608
31.1M
              gammaVecReal_m[1] =
1609
31.1M
                  (fMult(gammaVecReal_m[1], hintReal_F[sourceband % 4][2]) -
1610
31.1M
                   fMult(gammaVecImag_m[1],
1611
31.1M
                         hintReal_F[(sourceband + 3) % 4][2])) >>
1612
31.1M
                  1;
1613
31.1M
              gammaVecImag_m[1] =
1614
31.1M
                  (fMult(tmpRealF, hintReal_F[(sourceband + 3) % 4][2]) +
1615
31.1M
                   fMult(gammaVecImag_m[1], hintReal_F[sourceband % 4][2])) >>
1616
31.1M
                  1;
1617
1618
31.1M
              tmpRealF =
1619
31.1M
                  hQmfTransposer
1620
31.1M
                      ->qmfInBufReal_F[pSlotStretch[k] + 1][sourceband + 1];
1621
31.1M
              tmpImagF =
1622
31.1M
                  hQmfTransposer
1623
31.1M
                      ->qmfInBufImag_F[pSlotStretch[k] + 1][sourceband + 1];
1624
1625
31.1M
              gammaVecReal_m[1] +=
1626
31.1M
                  (fMult(tmpRealF, hintReal_F[sourceband % 4][2]) -
1627
31.1M
                   fMult(tmpImagF, hintReal_F[(sourceband + 1) % 4][2])) >>
1628
31.1M
                  1;
1629
31.1M
              gammaVecImag_m[1] +=
1630
31.1M
                  (fMult(tmpRealF, hintReal_F[(sourceband + 1) % 4][2]) +
1631
31.1M
                   fMult(tmpImagF, hintReal_F[sourceband % 4][2])) >>
1632
31.1M
                  1;
1633
31.1M
              gammaVec_e[1]++;
1634
31.1M
            }
1635
1636
62.2M
            addHighBandPart(gammaVecReal_m[1], gammaVecImag_m[1], gammaVec_e[1],
1637
62.2M
                            factor, gammaCenterReal_m[0], gammaCenterImag_m[0],
1638
62.2M
                            gammaCenter_e[0], stretch, scale_factor_hbe,
1639
62.2M
                            &hQmfTransposer->qmfHBEBufReal_F[k][band],
1640
62.2M
                            &hQmfTransposer->qmfHBEBufImag_F[k][band]);
1641
1642
62.2M
            addHighBandPart(gammaVecReal_m[0], gammaVecImag_m[0], gammaVec_e[0],
1643
62.2M
                            factor, gammaCenterReal_m[1], gammaCenterImag_m[1],
1644
62.2M
                            gammaCenter_e[1], stretch, scale_factor_hbe,
1645
62.2M
                            &hQmfTransposer->qmfHBEBufReal_F[k][band],
1646
62.2M
                            &hQmfTransposer->qmfHBEBufImag_F[k][band]);
1647
62.2M
          }
1648
58.2M
        } else {
1649
545M
          for (k = start; k < stop; k++) {
1650
487M
            gammaVecReal_m[0] =
1651
487M
                hQmfTransposer->qmfInBufReal_F[pSlotStretch[k]][sourceband];
1652
487M
            gammaVecImag_m[0] =
1653
487M
                hQmfTransposer->qmfInBufImag_F[pSlotStretch[k]][sourceband];
1654
487M
            gammaVec_e[0] =
1655
487M
                SCALE2EXP(-hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1656
1657
487M
            if (pFilt[k] == 1) {
1658
61.6M
              FIXP_DBL tmpRealF = gammaVecReal_m[0], tmpImagF;
1659
61.6M
              gammaVecReal_m[0] =
1660
61.6M
                  (fMult(gammaVecReal_m[0], hintReal_F[sourceband % 4][1]) -
1661
61.6M
                   fMult(gammaVecImag_m[0],
1662
61.6M
                         hintReal_F[(sourceband + 3) % 4][1])) >>
1663
61.6M
                  1; /* sum should be <= 1 because of sin/cos multiplication */
1664
61.6M
              gammaVecImag_m[0] =
1665
61.6M
                  (fMult(tmpRealF, hintReal_F[(sourceband + 3) % 4][1]) +
1666
61.6M
                   fMult(gammaVecImag_m[0], hintReal_F[sourceband % 4][1])) >>
1667
61.6M
                  1; /* sum should be <= 1 because of sin/cos multiplication */
1668
1669
61.6M
              tmpRealF = hQmfTransposer
1670
61.6M
                             ->qmfInBufReal_F[pSlotStretch[k] + 1][sourceband];
1671
61.6M
              tmpImagF = hQmfTransposer
1672
61.6M
                             ->qmfInBufImag_F[pSlotStretch[k] + 1][sourceband];
1673
1674
61.6M
              gammaVecReal_m[0] +=
1675
61.6M
                  (fMult(tmpRealF, hintReal_F[sourceband % 4][1]) -
1676
61.6M
                   fMult(tmpImagF, hintReal_F[(sourceband + 1) % 4][1])) >>
1677
61.6M
                  1; /* sum should be <= 1 because of sin/cos multiplication */
1678
61.6M
              gammaVecImag_m[0] +=
1679
61.6M
                  (fMult(tmpRealF, hintReal_F[(sourceband + 1) % 4][1]) +
1680
61.6M
                   fMult(tmpImagF, hintReal_F[sourceband % 4][1])) >>
1681
61.6M
                  1; /* sum should be <= 1 because of sin/cos multiplication */
1682
61.6M
              gammaVec_e[0]++;
1683
61.6M
            }
1684
1685
487M
            addHighBandPart(gammaVecReal_m[0], gammaVecImag_m[0], gammaVec_e[0],
1686
487M
                            factor, gammaCenterReal_m[0], gammaCenterImag_m[0],
1687
487M
                            gammaCenter_e[0], stretch, scale_factor_hbe,
1688
487M
                            &hQmfTransposer->qmfHBEBufReal_F[k][band],
1689
487M
                            &hQmfTransposer->qmfHBEBufImag_F[k][band]);
1690
487M
          }
1691
58.2M
        }
1692
1693
        /* pitchInBins is given with the resolution of a 768 bins FFT and we
1694
         * need 64 QMF units so factor 768/64 = 12 */
1695
65.9M
        if (pitchInBins >= pmin * (1 + bSbr41)) {
1696
8.19M
          int tr, ti1, ti2, mTr = 0, ts1 = 0, ts2 = 0, mVal_e = 0, temp_e = 0;
1697
8.19M
          int sqmag0_e =
1698
8.19M
              SCALE2EXP(-hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1699
1700
8.19M
          FIXP_DBL mVal_F = FL2FXCONST_DBL(0.f), sqmag0_F, sqmag1_F, sqmag2_F,
1701
8.19M
                   temp_F, f1_F; /* all equal exponent */
1702
8.19M
          sign = -1;
1703
1704
8.19M
          sourceband = 2 * band / stretch - qmfOffset; /* consistent with the
1705
                                                          already computed for
1706
                                                          stretch = 3,4. */
1707
8.19M
          FDK_ASSERT(sourceband >= 0);
1708
1709
8.19M
          FIXP_DBL sqmag0R_F =
1710
8.19M
              hQmfTransposer->qmfInBufReal_F[slotOffset][sourceband];
1711
8.19M
          FIXP_DBL sqmag0I_F =
1712
8.19M
              hQmfTransposer->qmfInBufImag_F[slotOffset][sourceband];
1713
8.19M
          scaleUp(&sqmag0R_F, &sqmag0I_F, &sqmag0_e);
1714
1715
8.19M
          sqmag0_F = fPow2Div2(sqmag0R_F);
1716
8.19M
          sqmag0_F += fPow2Div2(sqmag0I_F);
1717
8.19M
          sqmag0_e = 2 * sqmag0_e + 1;
1718
1719
22.2M
          for (tr = 1; tr < stretch; tr++) {
1720
14.0M
            int sqmag1_e =
1721
14.0M
                SCALE2EXP(-hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1722
14.0M
            int sqmag2_e =
1723
14.0M
                SCALE2EXP(-hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1724
1725
14.0M
            FIXP_DBL tmp_band = band_F[band];
1726
14.0M
            FIXP_DBL tr_p =
1727
14.0M
                fMult(p_F[pitchInBins] >> bSbr41, tr_str[tr - 1]); /* scale 7 */
1728
14.0M
            f1_F =
1729
14.0M
                fMult(tmp_band - tr_p, stretchfac[stretch - 2]); /* scale 7 */
1730
14.0M
            ti1 = (INT)(f1_F >> (DFRACT_BITS - 1 - 7)) - qmfOffset;
1731
14.0M
            ti2 = (INT)(((f1_F) + ((p_F[pitchInBins] >> bSbr41) >> 2)) >>
1732
14.0M
                        (DFRACT_BITS - 1 - 7)) -
1733
14.0M
                  qmfOffset;
1734
1735
14.0M
            if (ti1 >= 0 && ti2 < 2 * hQmfTransposer->synthSize) {
1736
13.6M
              FIXP_DBL sqmag1R_F =
1737
13.6M
                  hQmfTransposer->qmfInBufReal_F[slotOffset][ti1];
1738
13.6M
              FIXP_DBL sqmag1I_F =
1739
13.6M
                  hQmfTransposer->qmfInBufImag_F[slotOffset][ti1];
1740
13.6M
              scaleUp(&sqmag1R_F, &sqmag1I_F, &sqmag1_e);
1741
13.6M
              sqmag1_F = fPow2Div2(sqmag1R_F);
1742
13.6M
              sqmag1_F += fPow2Div2(sqmag1I_F);
1743
13.6M
              sqmag1_e = 2 * sqmag1_e + 1;
1744
1745
13.6M
              FIXP_DBL sqmag2R_F =
1746
13.6M
                  hQmfTransposer->qmfInBufReal_F[slotOffset][ti2];
1747
13.6M
              FIXP_DBL sqmag2I_F =
1748
13.6M
                  hQmfTransposer->qmfInBufImag_F[slotOffset][ti2];
1749
13.6M
              scaleUp(&sqmag2R_F, &sqmag2I_F, &sqmag2_e);
1750
13.6M
              sqmag2_F = fPow2Div2(sqmag2R_F);
1751
13.6M
              sqmag2_F += fPow2Div2(sqmag2I_F);
1752
13.6M
              sqmag2_e = 2 * sqmag2_e + 1;
1753
1754
13.6M
              int shift1 = fMin(fMax(sqmag1_e, sqmag2_e) - sqmag1_e, 31);
1755
13.6M
              int shift2 = fMin(fMax(sqmag1_e, sqmag2_e) - sqmag2_e, 31);
1756
1757
13.6M
              temp_F = fMin((sqmag1_F >> shift1), (sqmag2_F >> shift2));
1758
13.6M
              temp_e = fMax(sqmag1_e, sqmag2_e);
1759
1760
13.6M
              int shift3 = fMin(fMax(temp_e, mVal_e) - temp_e, 31);
1761
13.6M
              int shift4 = fMin(fMax(temp_e, mVal_e) - mVal_e, 31);
1762
1763
13.6M
              if ((temp_F >> shift3) > (mVal_F >> shift4)) {
1764
6.41M
                mVal_F = temp_F;
1765
6.41M
                mVal_e = temp_e; /* equals sqmag2_e + shift2 */
1766
6.41M
                mTr = tr;
1767
6.41M
                ts1 = ti1;
1768
6.41M
                ts2 = ti2;
1769
6.41M
              }
1770
13.6M
            }
1771
14.0M
          }
1772
1773
8.19M
          int shift1 = fMin(fMax(sqmag0_e, mVal_e) - sqmag0_e, 31);
1774
8.19M
          int shift2 = fMin(fMax(sqmag0_e, mVal_e) - mVal_e, 31);
1775
1776
8.19M
          if ((mVal_F >> shift2) > (sqmag0_F >> shift1) && ts1 >= 0 &&
1777
1.85M
              ts2 < 2 * hQmfTransposer->synthSize) {
1778
1.85M
            INT gammaOut_e[2];
1779
1.85M
            FIXP_DBL gammaOutReal_m[2], gammaOutImag_m[2];
1780
1.85M
            FIXP_DBL tmpReal_m = (FIXP_DBL)0, tmpImag_m = (FIXP_DBL)0;
1781
1782
1.85M
            int Tcenter, Tvec;
1783
1784
1.85M
            Tcenter = stretch - mTr; /* default phase power parameters */
1785
1.85M
            Tvec = mTr;
1786
1.85M
            switch (stretch) /* 2 tap block creation design depends on stretch
1787
                                order */
1788
1.85M
            {
1789
553k
              case 2:
1790
553k
                wingain =
1791
553k
                    FL2FXCONST_DBL(5.f / 12.f); /* sum of taps divided by two */
1792
1793
553k
                if (hQmfTransposer->bXProducts[0]) {
1794
553k
                  gammaCenterReal_m[0] =
1795
553k
                      hQmfTransposer->qmfInBufReal_F[slotOffset][ts1];
1796
553k
                  gammaCenterImag_m[0] =
1797
553k
                      hQmfTransposer->qmfInBufImag_F[slotOffset][ts1];
1798
1799
1.65M
                  for (k = 0; k < 2; k++) {
1800
1.10M
                    gammaVecReal_m[k] =
1801
1.10M
                        hQmfTransposer->qmfInBufReal_F[slotOffset - 1 + k][ts2];
1802
1.10M
                    gammaVecImag_m[k] =
1803
1.10M
                        hQmfTransposer->qmfInBufImag_F[slotOffset - 1 + k][ts2];
1804
1.10M
                  }
1805
1806
553k
                  gammaCenter_e[0] = SCALE2EXP(
1807
553k
                      -hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1808
553k
                  gammaVec_e[0] = gammaVec_e[1] = SCALE2EXP(
1809
553k
                      -hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1810
553k
                }
1811
553k
                break;
1812
1813
549k
              case 4:
1814
549k
                wingain =
1815
549k
                    FL2FXCONST_DBL(6.f / 12.f); /* sum of taps divided by two */
1816
549k
                if (hQmfTransposer->bXProducts[2]) {
1817
549k
                  if (mTr == 1) {
1818
182k
                    gammaCenterReal_m[0] =
1819
182k
                        hQmfTransposer->qmfInBufReal_F[slotOffset][ts1];
1820
182k
                    gammaCenterImag_m[0] =
1821
182k
                        hQmfTransposer->qmfInBufImag_F[slotOffset][ts1];
1822
1823
547k
                    for (k = 0; k < 2; k++) {
1824
364k
                      gammaVecReal_m[k] =
1825
364k
                          hQmfTransposer
1826
364k
                              ->qmfInBufReal_F[slotOffset + 2 * (k - 1)][ts2];
1827
364k
                      gammaVecImag_m[k] =
1828
364k
                          hQmfTransposer
1829
364k
                              ->qmfInBufImag_F[slotOffset + 2 * (k - 1)][ts2];
1830
364k
                    }
1831
366k
                  } else if (mTr == 2) {
1832
203k
                    gammaCenterReal_m[0] =
1833
203k
                        hQmfTransposer->qmfInBufReal_F[slotOffset][ts1];
1834
203k
                    gammaCenterImag_m[0] =
1835
203k
                        hQmfTransposer->qmfInBufImag_F[slotOffset][ts1];
1836
1837
611k
                    for (k = 0; k < 2; k++) {
1838
407k
                      gammaVecReal_m[k] =
1839
407k
                          hQmfTransposer
1840
407k
                              ->qmfInBufReal_F[slotOffset + (k - 1)][ts2];
1841
407k
                      gammaVecImag_m[k] =
1842
407k
                          hQmfTransposer
1843
407k
                              ->qmfInBufImag_F[slotOffset + (k - 1)][ts2];
1844
407k
                    }
1845
203k
                  } else /* (mTr == 3) */
1846
162k
                  {
1847
162k
                    sign = 1;
1848
162k
                    Tcenter = mTr; /* opposite phase power parameters as ts2 is
1849
                                      center */
1850
162k
                    Tvec = stretch - mTr;
1851
1852
162k
                    gammaCenterReal_m[0] =
1853
162k
                        hQmfTransposer->qmfInBufReal_F[slotOffset][ts2];
1854
162k
                    gammaCenterImag_m[0] =
1855
162k
                        hQmfTransposer->qmfInBufImag_F[slotOffset][ts2];
1856
1857
488k
                    for (k = 0; k < 2; k++) {
1858
325k
                      gammaVecReal_m[k] =
1859
325k
                          hQmfTransposer
1860
325k
                              ->qmfInBufReal_F[slotOffset + 2 * (k - 1)][ts1];
1861
325k
                      gammaVecImag_m[k] =
1862
325k
                          hQmfTransposer
1863
325k
                              ->qmfInBufImag_F[slotOffset + 2 * (k - 1)][ts1];
1864
325k
                    }
1865
162k
                  }
1866
1867
549k
                  gammaCenter_e[0] = SCALE2EXP(
1868
549k
                      -hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1869
549k
                  gammaVec_e[0] = gammaVec_e[1] = SCALE2EXP(
1870
549k
                      -hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1871
549k
                }
1872
549k
                break;
1873
1874
748k
              case 3:
1875
748k
                wingain = FL2FXCONST_DBL(5.6568f /
1876
748k
                                         12.f); /* sum of taps divided by two */
1877
1878
748k
                if (hQmfTransposer->bXProducts[1]) {
1879
748k
                  FIXP_DBL tmpReal_F, tmpImag_F;
1880
748k
                  if (mTr == 1) {
1881
341k
                    gammaCenterReal_m[0] =
1882
341k
                        hQmfTransposer->qmfInBufReal_F[slotOffset][ts1];
1883
341k
                    gammaCenterImag_m[0] =
1884
341k
                        hQmfTransposer->qmfInBufImag_F[slotOffset][ts1];
1885
341k
                    gammaVecReal_m[1] =
1886
341k
                        hQmfTransposer->qmfInBufReal_F[slotOffset][ts2];
1887
341k
                    gammaVecImag_m[1] =
1888
341k
                        hQmfTransposer->qmfInBufImag_F[slotOffset][ts2];
1889
1890
341k
                    addrshift = -2;
1891
341k
                    tmpReal_F =
1892
341k
                        hQmfTransposer
1893
341k
                            ->qmfInBufReal_F[addrshift + slotOffset][ts2];
1894
341k
                    tmpImag_F =
1895
341k
                        hQmfTransposer
1896
341k
                            ->qmfInBufImag_F[addrshift + slotOffset][ts2];
1897
1898
341k
                    gammaVecReal_m[0] =
1899
341k
                        (fMult(factors[ts2 % 4], tmpReal_F) -
1900
341k
                         fMult(factors[(ts2 + 3) % 4], tmpImag_F)) >>
1901
341k
                        1;
1902
341k
                    gammaVecImag_m[0] =
1903
341k
                        (fMult(factors[(ts2 + 3) % 4], tmpReal_F) +
1904
341k
                         fMult(factors[ts2 % 4], tmpImag_F)) >>
1905
341k
                        1;
1906
1907
341k
                    tmpReal_F =
1908
341k
                        hQmfTransposer
1909
341k
                            ->qmfInBufReal_F[addrshift + 1 + slotOffset][ts2];
1910
341k
                    tmpImag_F =
1911
341k
                        hQmfTransposer
1912
341k
                            ->qmfInBufImag_F[addrshift + 1 + slotOffset][ts2];
1913
1914
341k
                    gammaVecReal_m[0] +=
1915
341k
                        (fMult(factors[ts2 % 4], tmpReal_F) -
1916
341k
                         fMult(factors[(ts2 + 1) % 4], tmpImag_F)) >>
1917
341k
                        1;
1918
341k
                    gammaVecImag_m[0] +=
1919
341k
                        (fMult(factors[(ts2 + 1) % 4], tmpReal_F) +
1920
341k
                         fMult(factors[ts2 % 4], tmpImag_F)) >>
1921
341k
                        1;
1922
1923
341k
                  } else /* (mTr == 2) */
1924
407k
                  {
1925
407k
                    sign = 1;
1926
407k
                    Tcenter = mTr; /* opposite phase power parameters as ts2 is
1927
                                      center */
1928
407k
                    Tvec = stretch - mTr;
1929
1930
407k
                    gammaCenterReal_m[0] =
1931
407k
                        hQmfTransposer->qmfInBufReal_F[slotOffset][ts2];
1932
407k
                    gammaCenterImag_m[0] =
1933
407k
                        hQmfTransposer->qmfInBufImag_F[slotOffset][ts2];
1934
407k
                    gammaVecReal_m[1] =
1935
407k
                        hQmfTransposer->qmfInBufReal_F[slotOffset][ts1];
1936
407k
                    gammaVecImag_m[1] =
1937
407k
                        hQmfTransposer->qmfInBufImag_F[slotOffset][ts1];
1938
1939
407k
                    addrshift = -2;
1940
407k
                    tmpReal_F =
1941
407k
                        hQmfTransposer
1942
407k
                            ->qmfInBufReal_F[addrshift + slotOffset][ts1];
1943
407k
                    tmpImag_F =
1944
407k
                        hQmfTransposer
1945
407k
                            ->qmfInBufImag_F[addrshift + slotOffset][ts1];
1946
1947
407k
                    gammaVecReal_m[0] =
1948
407k
                        (fMult(factors[ts1 % 4], tmpReal_F) -
1949
407k
                         fMult(factors[(ts1 + 3) % 4], tmpImag_F)) >>
1950
407k
                        1;
1951
407k
                    gammaVecImag_m[0] =
1952
407k
                        (fMult(factors[(ts1 + 3) % 4], tmpReal_F) +
1953
407k
                         fMult(factors[ts1 % 4], tmpImag_F)) >>
1954
407k
                        1;
1955
1956
407k
                    tmpReal_F =
1957
407k
                        hQmfTransposer
1958
407k
                            ->qmfInBufReal_F[addrshift + 1 + slotOffset][ts1];
1959
407k
                    tmpImag_F =
1960
407k
                        hQmfTransposer
1961
407k
                            ->qmfInBufImag_F[addrshift + 1 + slotOffset][ts1];
1962
1963
407k
                    gammaVecReal_m[0] +=
1964
407k
                        (fMult(factors[ts1 % 4], tmpReal_F) -
1965
407k
                         fMult(factors[(ts1 + 1) % 4], tmpImag_F)) >>
1966
407k
                        1;
1967
407k
                    gammaVecImag_m[0] +=
1968
407k
                        (fMult(factors[(ts1 + 1) % 4], tmpReal_F) +
1969
407k
                         fMult(factors[ts1 % 4], tmpImag_F)) >>
1970
407k
                        1;
1971
407k
                  }
1972
1973
748k
                  gammaCenter_e[0] = gammaVec_e[1] = SCALE2EXP(
1974
748k
                      -hQmfTransposer->HBEAnalysiscQMF.outScalefactor);
1975
748k
                  gammaVec_e[0] =
1976
748k
                      SCALE2EXP(
1977
748k
                          -hQmfTransposer->HBEAnalysiscQMF.outScalefactor) +
1978
748k
                      1;
1979
748k
                }
1980
748k
                break;
1981
0
              default:
1982
0
                FDK_ASSERT(0);
1983
0
                break;
1984
1.85M
            } /* stretch cases */
1985
1986
            /* parameter controlled phase modification parts */
1987
            /* maximum *_e == 20 */
1988
1.85M
            calculateCenterFIXP(gammaCenterReal_m[0], gammaCenterImag_m[0],
1989
1.85M
                                &gammaCenterReal_m[0], &gammaCenterImag_m[0],
1990
1.85M
                                &gammaCenter_e[0], stretch, Tcenter - 1);
1991
1.85M
            calculateCenterFIXP(gammaVecReal_m[0], gammaVecImag_m[0],
1992
1.85M
                                &gammaVecReal_m[0], &gammaVecImag_m[0],
1993
1.85M
                                &gammaVec_e[0], stretch, Tvec - 1);
1994
1.85M
            calculateCenterFIXP(gammaVecReal_m[1], gammaVecImag_m[1],
1995
1.85M
                                &gammaVecReal_m[1], &gammaVecImag_m[1],
1996
1.85M
                                &gammaVec_e[1], stretch, Tvec - 1);
1997
1998
            /*    Final multiplication of prepared parts  */
1999
5.55M
            for (k = 0; k < 2; k++) {
2000
3.70M
              gammaOutReal_m[k] =
2001
3.70M
                  fMultDiv2(gammaVecReal_m[k], gammaCenterReal_m[0]) -
2002
3.70M
                  fMultDiv2(gammaVecImag_m[k], gammaCenterImag_m[0]);
2003
3.70M
              gammaOutImag_m[k] =
2004
3.70M
                  fMultDiv2(gammaVecReal_m[k], gammaCenterImag_m[0]) +
2005
3.70M
                  fMultDiv2(gammaVecImag_m[k], gammaCenterReal_m[0]);
2006
3.70M
              gammaOut_e[k] = gammaCenter_e[0] + gammaVec_e[k] + 1;
2007
3.70M
            }
2008
2009
1.85M
            scaleUp(&gammaOutReal_m[0], &gammaOutImag_m[0], &gammaOut_e[0]);
2010
1.85M
            scaleUp(&gammaOutReal_m[1], &gammaOutImag_m[1], &gammaOut_e[1]);
2011
1.85M
            FDK_ASSERT(gammaOut_e[0] >= 0);
2012
1.85M
            FDK_ASSERT(gammaOut_e[0] < 32);
2013
2014
1.85M
            tmpReal_m = gammaOutReal_m[0];
2015
1.85M
            tmpImag_m = gammaOutImag_m[0];
2016
2017
1.85M
            INT modstretch4 = ((stretch == 4) && (mTr == 2));
2018
2019
1.85M
            FIXP_DBL cos_twid = twid_m_new[stretch - 2 - modstretch4][0];
2020
1.85M
            FIXP_DBL sin_twid = sign * twid_m_new[stretch - 2 - modstretch4][1];
2021
2022
1.85M
            gammaOutReal_m[0] =
2023
1.85M
                fMult(tmpReal_m, cos_twid) -
2024
1.85M
                fMult(tmpImag_m, sin_twid); /* sum should be <= 1 because of
2025
                                               sin/cos multiplication */
2026
1.85M
            gammaOutImag_m[0] =
2027
1.85M
                fMult(tmpImag_m, cos_twid) +
2028
1.85M
                fMult(tmpReal_m, sin_twid); /* sum should be <= 1 because of
2029
                                               sin/cos multiplication */
2030
2031
            /* wingain */
2032
5.55M
            for (k = 0; k < 2; k++) {
2033
3.70M
              gammaOutReal_m[k] = (fMult(gammaOutReal_m[k], wingain) << 1);
2034
3.70M
              gammaOutImag_m[k] = (fMult(gammaOutImag_m[k], wingain) << 1);
2035
3.70M
            }
2036
2037
1.85M
            gammaOutReal_m[1] >>= 1;
2038
1.85M
            gammaOutImag_m[1] >>= 1;
2039
1.85M
            gammaOut_e[0] += 2;
2040
1.85M
            gammaOut_e[1] += 2;
2041
2042
            /* OLA including window scaling by wingain/3 */
2043
5.55M
            for (k = 0; k < 2; k++) /* need k=1 to correspond to
2044
                                       grainModImag[slotOffset] -> out to
2045
                                       j*2+(slotOffset-offset)  */
2046
3.70M
            {
2047
3.70M
              hQmfTransposer->qmfHBEBufReal_F[(k + slotOffset - 1)][band] +=
2048
3.70M
                  gammaOutReal_m[k] >> (scale_factor_hbe - gammaOut_e[k]);
2049
3.70M
              hQmfTransposer->qmfHBEBufImag_F[(k + slotOffset - 1)][band] +=
2050
3.70M
                  gammaOutImag_m[k] >> (scale_factor_hbe - gammaOut_e[k]);
2051
3.70M
            }
2052
1.85M
          } /* mVal > qThrQMF * qThrQMF * sqmag0 && ts1 > 0 && ts2 < 64 */
2053
8.19M
        }   /* p >= pmin */
2054
65.9M
      }     /* for band */
2055
4.89M
    }       /* for stretch */
2056
2057
27.0M
    for (i = 0; i < QMF_WIN_LEN - 1; i++) {
2058
24.9M
      FDKmemcpy(hQmfTransposer->qmfInBufReal_F[i],
2059
24.9M
                hQmfTransposer->qmfInBufReal_F[i + 1],
2060
24.9M
                sizeof(FIXP_DBL) * hQmfTransposer->HBEAnalysiscQMF.no_channels);
2061
24.9M
      FDKmemcpy(hQmfTransposer->qmfInBufImag_F[i],
2062
24.9M
                hQmfTransposer->qmfInBufImag_F[i + 1],
2063
24.9M
                sizeof(FIXP_DBL) * hQmfTransposer->HBEAnalysiscQMF.no_channels);
2064
24.9M
    }
2065
2066
2.07M
    if (keepStatesSyncedMode != KEEP_STATES_SYNCED_NOOUT) {
2067
1.87M
      if (2 * j >= offset) {
2068
        /* copy first two slots of internal buffer to output */
2069
1.25M
        if (keepStatesSyncedMode == KEEP_STATES_SYNCED_OUTDIFF) {
2070
438k
          for (i = 0; i < 2; i++) {
2071
292k
            FDKmemcpy(&ppQmfBufferOutReal_F[2 * j - offset + i]
2072
292k
                                           [hQmfTransposer->xOverQmf[0]],
2073
292k
                      &hQmfTransposer
2074
292k
                           ->qmfHBEBufReal_F[i][hQmfTransposer->xOverQmf[0]],
2075
292k
                      (QMF_SYNTH_CHANNELS - hQmfTransposer->xOverQmf[0]) *
2076
292k
                          sizeof(FIXP_DBL));
2077
292k
            FDKmemcpy(&ppQmfBufferOutImag_F[2 * j - offset + i]
2078
292k
                                           [hQmfTransposer->xOverQmf[0]],
2079
292k
                      &hQmfTransposer
2080
292k
                           ->qmfHBEBufImag_F[i][hQmfTransposer->xOverQmf[0]],
2081
292k
                      (QMF_SYNTH_CHANNELS - hQmfTransposer->xOverQmf[0]) *
2082
292k
                          sizeof(FIXP_DBL));
2083
292k
          }
2084
1.10M
        } else {
2085
3.32M
          for (i = 0; i < 2; i++) {
2086
2.21M
            FDKmemcpy(&ppQmfBufferOutReal_F[2 * j + i + ov_len]
2087
2.21M
                                           [hQmfTransposer->xOverQmf[0]],
2088
2.21M
                      &hQmfTransposer
2089
2.21M
                           ->qmfHBEBufReal_F[i][hQmfTransposer->xOverQmf[0]],
2090
2.21M
                      (QMF_SYNTH_CHANNELS - hQmfTransposer->xOverQmf[0]) *
2091
2.21M
                          sizeof(FIXP_DBL));
2092
2.21M
            FDKmemcpy(&ppQmfBufferOutImag_F[2 * j + i + ov_len]
2093
2.21M
                                           [hQmfTransposer->xOverQmf[0]],
2094
2.21M
                      &hQmfTransposer
2095
2.21M
                           ->qmfHBEBufImag_F[i][hQmfTransposer->xOverQmf[0]],
2096
2.21M
                      (QMF_SYNTH_CHANNELS - hQmfTransposer->xOverQmf[0]) *
2097
2.21M
                          sizeof(FIXP_DBL));
2098
2.21M
          }
2099
1.10M
        }
2100
1.25M
      }
2101
1.87M
    }
2102
2103
    /* move slots up */
2104
20.7M
    for (i = 0; i < HBE_MAX_OUT_SLOTS - 2; i++) {
2105
18.7M
      FDKmemcpy(
2106
18.7M
          &hQmfTransposer->qmfHBEBufReal_F[i][hQmfTransposer->xOverQmf[0]],
2107
18.7M
          &hQmfTransposer->qmfHBEBufReal_F[i + 2][hQmfTransposer->xOverQmf[0]],
2108
18.7M
          (QMF_SYNTH_CHANNELS - hQmfTransposer->xOverQmf[0]) *
2109
18.7M
              sizeof(FIXP_DBL));
2110
18.7M
      FDKmemcpy(
2111
18.7M
          &hQmfTransposer->qmfHBEBufImag_F[i][hQmfTransposer->xOverQmf[0]],
2112
18.7M
          &hQmfTransposer->qmfHBEBufImag_F[i + 2][hQmfTransposer->xOverQmf[0]],
2113
18.7M
          (QMF_SYNTH_CHANNELS - hQmfTransposer->xOverQmf[0]) *
2114
18.7M
              sizeof(FIXP_DBL));
2115
18.7M
    }
2116
2117
    /* finally set last two slot to zero */
2118
6.23M
    for (i = 0; i < 2; i++) {
2119
4.15M
      FDKmemset(&hQmfTransposer->qmfHBEBufReal_F[HBE_MAX_OUT_SLOTS - 1 - i]
2120
4.15M
                                                [hQmfTransposer->xOverQmf[0]],
2121
4.15M
                0,
2122
4.15M
                (QMF_SYNTH_CHANNELS - hQmfTransposer->xOverQmf[0]) *
2123
4.15M
                    sizeof(FIXP_DBL));
2124
4.15M
      FDKmemset(&hQmfTransposer->qmfHBEBufImag_F[HBE_MAX_OUT_SLOTS - 1 - i]
2125
4.15M
                                                [hQmfTransposer->xOverQmf[0]],
2126
4.15M
                0,
2127
4.15M
                (QMF_SYNTH_CHANNELS - hQmfTransposer->xOverQmf[0]) *
2128
4.15M
                    sizeof(FIXP_DBL));
2129
4.15M
    }
2130
2.07M
  } /* qmfVocoderColsIn */
2131
2132
115k
  if (keepStatesSyncedMode != KEEP_STATES_SYNCED_NOOUT) {
2133
103k
    if (keepStatesSyncedMode == KEEP_STATES_SYNCED_OUTDIFF) {
2134
323k
      for (i = 0; i < ov_len + LPC_ORDER; i++) {
2135
10.3M
        for (band = hQmfTransposer->startBand; band < hQmfTransposer->stopBand;
2136
10.0M
             band++) {
2137
10.0M
          FIXP_DBL tmpR = ppQmfBufferOutReal_F[i][band];
2138
10.0M
          FIXP_DBL tmpI = ppQmfBufferOutImag_F[i][band];
2139
2140
10.0M
          ppQmfBufferOutReal_F[i][band] =
2141
10.0M
              fMult(tmpR, cos_F[band]) -
2142
10.0M
              fMult(tmpI, (-cos_F[64 - band - 1])); /* sum should be <= 1
2143
                                                       because of sin/cos
2144
                                                       multiplication */
2145
10.0M
          ppQmfBufferOutImag_F[i][band] =
2146
10.0M
              fMult(tmpR, (-cos_F[64 - band - 1])) +
2147
10.0M
              fMult(tmpI, cos_F[band]); /* sum should by <= 1 because of sin/cos
2148
                                           multiplication */
2149
10.0M
        }
2150
292k
      }
2151
71.2k
    } else {
2152
2.28M
      for (i = offset; i < hQmfTransposer->noCols; i++) {
2153
75.2M
        for (band = hQmfTransposer->startBand; band < hQmfTransposer->stopBand;
2154
73.0M
             band++) {
2155
73.0M
          FIXP_DBL tmpR = ppQmfBufferOutReal_F[i + ov_len][band];
2156
73.0M
          FIXP_DBL tmpI = ppQmfBufferOutImag_F[i + ov_len][band];
2157
2158
73.0M
          ppQmfBufferOutReal_F[i + ov_len][band] =
2159
73.0M
              fMult(tmpR, cos_F[band]) -
2160
73.0M
              fMult(tmpI, (-cos_F[64 - band - 1])); /* sum should be <= 1
2161
                                                       because of sin/cos
2162
                                                       multiplication */
2163
73.0M
          ppQmfBufferOutImag_F[i + ov_len][band] =
2164
73.0M
              fMult(tmpR, (-cos_F[64 - band - 1])) +
2165
73.0M
              fMult(tmpI, cos_F[band]); /* sum should by <= 1 because of sin/cos
2166
                                           multiplication */
2167
73.0M
        }
2168
2.21M
      }
2169
71.2k
    }
2170
103k
  }
2171
2172
115k
  *scale_hb = EXP2SCALE(scale_factor_hbe);
2173
115k
}
2174
2175
299k
int* GetxOverBandQmfTransposer(HANDLE_HBE_TRANSPOSER hQmfTransposer) {
2176
299k
  if (hQmfTransposer)
2177
86.6k
    return hQmfTransposer->xOverQmf;
2178
212k
  else
2179
212k
    return NULL;
2180
299k
}
2181
2182
272k
int Get41SbrQmfTransposer(HANDLE_HBE_TRANSPOSER hQmfTransposer) {
2183
272k
  if (hQmfTransposer != NULL)
2184
59.7k
    return hQmfTransposer->bSbr41;
2185
212k
  else
2186
212k
    return 0;
2187
272k
}