Coverage Report

Created: 2026-07-16 06:55

next uncovered line (L), next uncovered region (R), next uncovered branch (B)
/src/aac/libFDK/include/FDK_trigFcts.h
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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 - 2018 Fraunhofer-Gesellschaft zur Förderung der angewandten
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Forschung e.V. All rights reserved.
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7
 1.    INTRODUCTION
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The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software
9
that implements the MPEG Advanced Audio Coding ("AAC") encoding and decoding
10
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
14
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
16
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
20
those of Fraunhofer) may be obtained through Via Licensing
21
(www.vialicensing.com) or through the respective patent owners individually for
22
the purpose of encoding or decoding bit streams in products that are compliant
23
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
25
directly from the patent owners, and therefore FDK AAC Codec software may
26
already be covered under those patent licenses when it is used for those
27
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
32
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,
37
are permitted without payment of copyright license fees provided that you
38
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
44
and/or other materials provided with redistributions of the FDK AAC Codec or
45
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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49
The name of Fraunhofer may not be used to endorse or promote products derived
50
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
57
of the FDK AAC Codec, the term "Fraunhofer FDK AAC Codec Library for Android"
58
must be replaced by the term "Third-Party Modified Version of the Fraunhofer FDK
59
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
64
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
66
software.
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You may use this FDK AAC Codec software or modifications thereto only for
69
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
74
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
76
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
79
goods or services; loss of use, data, or profits, or business interruption,
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however caused and on any theory of liability, whether in contract, strict
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liability, or tort (including negligence), arising in any way out of the use of
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this software, even if advised of the possibility of such damage.
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5.    CONTACT INFORMATION
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Fraunhofer Institute for Integrated Circuits IIS
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Attention: Audio and Multimedia Departments - FDK AAC LL
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Am Wolfsmantel 33
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91058 Erlangen, Germany
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www.iis.fraunhofer.de/amm
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amm-info@iis.fraunhofer.de
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----------------------------------------------------------------------------- */
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/******************* Library for basic calculation routines ********************
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   Author(s):   Haricharan Lakshman, Manuel Jander
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   Description: Trigonometric functions fixed point fractional implementation.
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*******************************************************************************/
102
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#if !defined(FDK_TRIGFCTS_H)
104
#define FDK_TRIGFCTS_H
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#include "common_fix.h"
107
108
#include "FDK_tools_rom.h"
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/* Fixed point precision definitions */
111
#define Q(format) ((FIXP_DBL)(((LONG)1) << (format)))
112
113
#ifndef M_PI
114
#define M_PI (3.14159265358979323846f)
115
#endif
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/*!
118
 * Inverse tangent function.
119
 */
120
121
/* --- fixp_atan() ----    */
122
0
#define Q_ATANINP (25)  // Input in q25, Output in q30
123
0
#define Q_ATANOUT (30)
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0
#define ATI_SF ((DFRACT_BITS - 1) - Q_ATANINP) /* 6  */
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#define ATI_SCALE ((float)(1 << ATI_SF))
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0
#define ATO_SF ((DFRACT_BITS - 1) - Q_ATANOUT) /* 1   ] -pi/2 .. pi/2 [ */
127
#define ATO_SCALE ((float)(1 << ATO_SF))
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/* --- fixp_atan2() ---    */
129
0
#define Q_ATAN2OUT (29)
130
0
#define AT2O_SF ((DFRACT_BITS - 1) - Q_ATAN2OUT) /* 2   ] -pi   .. pi   ] */
131
#define AT2O_SCALE ((float)(1 << AT2O_SF))
132
// --------------------
133
134
FIXP_DBL fixp_atan(FIXP_DBL x);
135
FIXP_DBL fixp_atan2(FIXP_DBL y, FIXP_DBL x);
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FIXP_DBL fixp_cos(FIXP_DBL x, int scale);
138
FIXP_DBL fixp_sin(FIXP_DBL x, int scale);
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#define FIXP_COS_SIN
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#include "FDK_tools_rom.h"
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144
13.3M
#define SINETAB SineTable512
145
98.8M
#define LD 9
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#ifndef FUNCTION_inline_fixp_cos_sin
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#define FUNCTION_inline_fixp_cos_sin
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151
/*
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 * Calculates coarse lookup index and sign for sine.
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 * Returns delta x residual.
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 */
155
static inline FIXP_DBL fixp_sin_cos_residual_inline(FIXP_DBL x, int scale,
156
                                                    FIXP_DBL *sine,
157
13.3M
                                                    FIXP_DBL *cosine) {
158
13.3M
  FIXP_DBL residual;
159
13.3M
  int s;
160
13.3M
  int shift = (31 - scale - LD - 1);
161
13.3M
  int ssign = 1;
162
13.3M
  int csign = 1;
163
164
13.3M
  residual = fMult(x, FL2FXCONST_DBL(1.0 / M_PI));
165
13.3M
  s = ((LONG)residual) >> shift;
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167
13.3M
  residual &= ((1 << shift) - 1);
168
13.3M
  residual = fMult(residual, FL2FXCONST_DBL(M_PI / 4.0)) << 2;
169
13.3M
  residual <<= scale;
170
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  /* Sine sign symmetry */
172
13.3M
  if (s & ((1 << LD) << 1)) {
173
484k
    ssign = -ssign;
174
484k
  }
175
  /* Cosine sign symmetry */
176
13.3M
  if ((s + (1 << LD)) & ((1 << LD) << 1)) {
177
2.27M
    csign = -csign;
178
2.27M
  }
179
180
13.3M
  s = fAbs(s);
181
182
13.3M
  s &= (((1 << LD) << 1) - 1); /* Modulo PI */
183
184
13.3M
  if (s > (1 << LD)) {
185
2.53M
    s = ((1 << LD) << 1) - s;
186
2.53M
  }
187
188
13.3M
  {
189
13.3M
    LONG sl, cl;
190
    /* Because of packed table */
191
13.3M
    if (s > (1 << (LD - 1))) {
192
2.55M
      FIXP_STP tmp;
193
      /* Cosine/Sine simetry for angles greater than PI/4 */
194
2.55M
      s = (1 << LD) - s;
195
2.55M
      tmp = SINETAB[s];
196
2.55M
      sl = (LONG)tmp.v.re;
197
2.55M
      cl = (LONG)tmp.v.im;
198
10.8M
    } else {
199
10.8M
      FIXP_STP tmp;
200
10.8M
      tmp = SINETAB[s];
201
10.8M
      sl = (LONG)tmp.v.im;
202
10.8M
      cl = (LONG)tmp.v.re;
203
10.8M
    }
204
205
13.3M
#ifdef SINETABLE_16BIT
206
13.3M
    *sine = (FIXP_DBL)((sl * ssign) << (DFRACT_BITS - FRACT_BITS));
207
13.3M
    *cosine = (FIXP_DBL)((cl * csign) << (DFRACT_BITS - FRACT_BITS));
208
#else
209
    /* scale down by 1 for overflow prevention. This is undone at the calling
210
     * function. */
211
    *sine = (FIXP_DBL)(sl * ssign) >> 1;
212
    *cosine = (FIXP_DBL)(cl * csign) >> 1;
213
#endif
214
13.3M
  }
215
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13.3M
  return residual;
217
13.3M
}
FDK_trigFcts.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
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157
4.56M
                                                    FIXP_DBL *cosine) {
158
4.56M
  FIXP_DBL residual;
159
4.56M
  int s;
160
4.56M
  int shift = (31 - scale - LD - 1);
161
4.56M
  int ssign = 1;
162
4.56M
  int csign = 1;
163
164
4.56M
  residual = fMult(x, FL2FXCONST_DBL(1.0 / M_PI));
165
4.56M
  s = ((LONG)residual) >> shift;
166
167
4.56M
  residual &= ((1 << shift) - 1);
168
4.56M
  residual = fMult(residual, FL2FXCONST_DBL(M_PI / 4.0)) << 2;
169
4.56M
  residual <<= scale;
170
171
  /* Sine sign symmetry */
172
4.56M
  if (s & ((1 << LD) << 1)) {
173
0
    ssign = -ssign;
174
0
  }
175
  /* Cosine sign symmetry */
176
4.56M
  if ((s + (1 << LD)) & ((1 << LD) << 1)) {
177
2.17M
    csign = -csign;
178
2.17M
  }
179
180
4.56M
  s = fAbs(s);
181
182
4.56M
  s &= (((1 << LD) << 1) - 1); /* Modulo PI */
183
184
4.56M
  if (s > (1 << LD)) {
185
2.17M
    s = ((1 << LD) << 1) - s;
186
2.17M
  }
187
188
4.56M
  {
189
4.56M
    LONG sl, cl;
190
    /* Because of packed table */
191
4.56M
    if (s > (1 << (LD - 1))) {
192
2.36M
      FIXP_STP tmp;
193
      /* Cosine/Sine simetry for angles greater than PI/4 */
194
2.36M
      s = (1 << LD) - s;
195
2.36M
      tmp = SINETAB[s];
196
2.36M
      sl = (LONG)tmp.v.re;
197
2.36M
      cl = (LONG)tmp.v.im;
198
2.36M
    } else {
199
2.19M
      FIXP_STP tmp;
200
2.19M
      tmp = SINETAB[s];
201
2.19M
      sl = (LONG)tmp.v.im;
202
2.19M
      cl = (LONG)tmp.v.re;
203
2.19M
    }
204
205
4.56M
#ifdef SINETABLE_16BIT
206
4.56M
    *sine = (FIXP_DBL)((sl * ssign) << (DFRACT_BITS - FRACT_BITS));
207
4.56M
    *cosine = (FIXP_DBL)((cl * csign) << (DFRACT_BITS - FRACT_BITS));
208
#else
209
    /* scale down by 1 for overflow prevention. This is undone at the calling
210
     * function. */
211
    *sine = (FIXP_DBL)(sl * ssign) >> 1;
212
    *cosine = (FIXP_DBL)(cl * csign) >> 1;
213
#endif
214
4.56M
  }
215
216
4.56M
  return residual;
217
4.56M
}
Unexecuted instantiation: block.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
psdec.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
Line
Count
Source
157
794k
                                                    FIXP_DBL *cosine) {
158
794k
  FIXP_DBL residual;
159
794k
  int s;
160
794k
  int shift = (31 - scale - LD - 1);
161
794k
  int ssign = 1;
162
794k
  int csign = 1;
163
164
794k
  residual = fMult(x, FL2FXCONST_DBL(1.0 / M_PI));
165
794k
  s = ((LONG)residual) >> shift;
166
167
794k
  residual &= ((1 << shift) - 1);
168
794k
  residual = fMult(residual, FL2FXCONST_DBL(M_PI / 4.0)) << 2;
169
794k
  residual <<= scale;
170
171
  /* Sine sign symmetry */
172
794k
  if (s & ((1 << LD) << 1)) {
173
13.6k
    ssign = -ssign;
174
13.6k
  }
175
  /* Cosine sign symmetry */
176
794k
  if ((s + (1 << LD)) & ((1 << LD) << 1)) {
177
3.69k
    csign = -csign;
178
3.69k
  }
179
180
794k
  s = fAbs(s);
181
182
794k
  s &= (((1 << LD) << 1) - 1); /* Modulo PI */
183
184
794k
  if (s > (1 << LD)) {
185
3.21k
    s = ((1 << LD) << 1) - s;
186
3.21k
  }
187
188
794k
  {
189
794k
    LONG sl, cl;
190
    /* Because of packed table */
191
794k
    if (s > (1 << (LD - 1))) {
192
5.89k
      FIXP_STP tmp;
193
      /* Cosine/Sine simetry for angles greater than PI/4 */
194
5.89k
      s = (1 << LD) - s;
195
5.89k
      tmp = SINETAB[s];
196
5.89k
      sl = (LONG)tmp.v.re;
197
5.89k
      cl = (LONG)tmp.v.im;
198
788k
    } else {
199
788k
      FIXP_STP tmp;
200
788k
      tmp = SINETAB[s];
201
788k
      sl = (LONG)tmp.v.im;
202
788k
      cl = (LONG)tmp.v.re;
203
788k
    }
204
205
794k
#ifdef SINETABLE_16BIT
206
794k
    *sine = (FIXP_DBL)((sl * ssign) << (DFRACT_BITS - FRACT_BITS));
207
794k
    *cosine = (FIXP_DBL)((cl * csign) << (DFRACT_BITS - FRACT_BITS));
208
#else
209
    /* scale down by 1 for overflow prevention. This is undone at the calling
210
     * function. */
211
    *sine = (FIXP_DBL)(sl * ssign) >> 1;
212
    *cosine = (FIXP_DBL)(cl * csign) >> 1;
213
#endif
214
794k
  }
215
216
794k
  return residual;
217
794k
}
Unexecuted instantiation: psy_configuration.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
Unexecuted instantiation: qmf.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
Unexecuted instantiation: sac_calcM1andM2.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
Unexecuted instantiation: sac_dec.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
sac_process.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
Line
Count
Source
157
8.04M
                                                    FIXP_DBL *cosine) {
158
8.04M
  FIXP_DBL residual;
159
8.04M
  int s;
160
8.04M
  int shift = (31 - scale - LD - 1);
161
8.04M
  int ssign = 1;
162
8.04M
  int csign = 1;
163
164
8.04M
  residual = fMult(x, FL2FXCONST_DBL(1.0 / M_PI));
165
8.04M
  s = ((LONG)residual) >> shift;
166
167
8.04M
  residual &= ((1 << shift) - 1);
168
8.04M
  residual = fMult(residual, FL2FXCONST_DBL(M_PI / 4.0)) << 2;
169
8.04M
  residual <<= scale;
170
171
  /* Sine sign symmetry */
172
8.04M
  if (s & ((1 << LD) << 1)) {
173
471k
    ssign = -ssign;
174
471k
  }
175
  /* Cosine sign symmetry */
176
8.04M
  if ((s + (1 << LD)) & ((1 << LD) << 1)) {
177
101k
    csign = -csign;
178
101k
  }
179
180
8.04M
  s = fAbs(s);
181
182
8.04M
  s &= (((1 << LD) << 1) - 1); /* Modulo PI */
183
184
8.04M
  if (s > (1 << LD)) {
185
361k
    s = ((1 << LD) << 1) - s;
186
361k
  }
187
188
8.04M
  {
189
8.04M
    LONG sl, cl;
190
    /* Because of packed table */
191
8.04M
    if (s > (1 << (LD - 1))) {
192
187k
      FIXP_STP tmp;
193
      /* Cosine/Sine simetry for angles greater than PI/4 */
194
187k
      s = (1 << LD) - s;
195
187k
      tmp = SINETAB[s];
196
187k
      sl = (LONG)tmp.v.re;
197
187k
      cl = (LONG)tmp.v.im;
198
7.85M
    } else {
199
7.85M
      FIXP_STP tmp;
200
7.85M
      tmp = SINETAB[s];
201
7.85M
      sl = (LONG)tmp.v.im;
202
7.85M
      cl = (LONG)tmp.v.re;
203
7.85M
    }
204
205
8.04M
#ifdef SINETABLE_16BIT
206
8.04M
    *sine = (FIXP_DBL)((sl * ssign) << (DFRACT_BITS - FRACT_BITS));
207
8.04M
    *cosine = (FIXP_DBL)((cl * csign) << (DFRACT_BITS - FRACT_BITS));
208
#else
209
    /* scale down by 1 for overflow prevention. This is undone at the calling
210
     * function. */
211
    *sine = (FIXP_DBL)(sl * ssign) >> 1;
212
    *cosine = (FIXP_DBL)(cl * csign) >> 1;
213
#endif
214
8.04M
  }
215
216
8.04M
  return residual;
217
8.04M
}
Unexecuted instantiation: sacenc_dmx_tdom_enh.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
Unexecuted instantiation: usacdec_lpc.cpp:fixp_sin_cos_residual_inline(int, int, int*, int*)
218
219
/**
220
 * \brief Calculate cosine and sine value each of 2 angles different angle
221
 * values.
222
 * \param x1 first angle value
223
 * \param x2 second angle value
224
 * \param scale exponent of x1 and x2
225
 * \param out pointer to 4 FIXP_DBL locations, were the values cos(x1), sin(x1),
226
 * cos(x2), sin(x2) will be stored into.
227
 */
228
static inline void inline_fixp_cos_sin(FIXP_DBL x1, FIXP_DBL x2,
229
4.41M
                                       const int scale, FIXP_DBL *out) {
230
4.41M
  FIXP_DBL residual, error0, error1, sine, cosine;
231
4.41M
  residual = fixp_sin_cos_residual_inline(x1, scale, &sine, &cosine);
232
4.41M
  error0 = fMultDiv2(sine, residual);
233
4.41M
  error1 = fMultDiv2(cosine, residual);
234
235
4.41M
#ifdef SINETABLE_16BIT
236
4.41M
  *out++ = cosine - (error0 << 1);
237
4.41M
  *out++ = sine + (error1 << 1);
238
#else
239
  /* Undo downscaling by 1 which was done at fixp_sin_cos_residual_inline */
240
  *out++ = SATURATE_LEFT_SHIFT(cosine - (error0 << 1), 1, DFRACT_BITS);
241
  *out++ = SATURATE_LEFT_SHIFT(sine + (error1 << 1), 1, DFRACT_BITS);
242
#endif
243
244
4.41M
  residual = fixp_sin_cos_residual_inline(x2, scale, &sine, &cosine);
245
4.41M
  error0 = fMultDiv2(sine, residual);
246
4.41M
  error1 = fMultDiv2(cosine, residual);
247
248
4.41M
#ifdef SINETABLE_16BIT
249
4.41M
  *out++ = cosine - (error0 << 1);
250
4.41M
  *out++ = sine + (error1 << 1);
251
#else
252
  *out++ = SATURATE_LEFT_SHIFT(cosine - (error0 << 1), 1, DFRACT_BITS);
253
  *out++ = SATURATE_LEFT_SHIFT(sine + (error1 << 1), 1, DFRACT_BITS);
254
#endif
255
4.41M
}
Unexecuted instantiation: FDK_trigFcts.cpp:inline_fixp_cos_sin(int, int, int, int*)
Unexecuted instantiation: block.cpp:inline_fixp_cos_sin(int, int, int, int*)
psdec.cpp:inline_fixp_cos_sin(int, int, int, int*)
Line
Count
Source
229
397k
                                       const int scale, FIXP_DBL *out) {
230
397k
  FIXP_DBL residual, error0, error1, sine, cosine;
231
397k
  residual = fixp_sin_cos_residual_inline(x1, scale, &sine, &cosine);
232
397k
  error0 = fMultDiv2(sine, residual);
233
397k
  error1 = fMultDiv2(cosine, residual);
234
235
397k
#ifdef SINETABLE_16BIT
236
397k
  *out++ = cosine - (error0 << 1);
237
397k
  *out++ = sine + (error1 << 1);
238
#else
239
  /* Undo downscaling by 1 which was done at fixp_sin_cos_residual_inline */
240
  *out++ = SATURATE_LEFT_SHIFT(cosine - (error0 << 1), 1, DFRACT_BITS);
241
  *out++ = SATURATE_LEFT_SHIFT(sine + (error1 << 1), 1, DFRACT_BITS);
242
#endif
243
244
397k
  residual = fixp_sin_cos_residual_inline(x2, scale, &sine, &cosine);
245
397k
  error0 = fMultDiv2(sine, residual);
246
397k
  error1 = fMultDiv2(cosine, residual);
247
248
397k
#ifdef SINETABLE_16BIT
249
397k
  *out++ = cosine - (error0 << 1);
250
397k
  *out++ = sine + (error1 << 1);
251
#else
252
  *out++ = SATURATE_LEFT_SHIFT(cosine - (error0 << 1), 1, DFRACT_BITS);
253
  *out++ = SATURATE_LEFT_SHIFT(sine + (error1 << 1), 1, DFRACT_BITS);
254
#endif
255
397k
}
Unexecuted instantiation: psy_configuration.cpp:inline_fixp_cos_sin(int, int, int, int*)
Unexecuted instantiation: qmf.cpp:inline_fixp_cos_sin(int, int, int, int*)
Unexecuted instantiation: sac_calcM1andM2.cpp:inline_fixp_cos_sin(int, int, int, int*)
Unexecuted instantiation: sac_dec.cpp:inline_fixp_cos_sin(int, int, int, int*)
sac_process.cpp:inline_fixp_cos_sin(int, int, int, int*)
Line
Count
Source
229
4.02M
                                       const int scale, FIXP_DBL *out) {
230
4.02M
  FIXP_DBL residual, error0, error1, sine, cosine;
231
4.02M
  residual = fixp_sin_cos_residual_inline(x1, scale, &sine, &cosine);
232
4.02M
  error0 = fMultDiv2(sine, residual);
233
4.02M
  error1 = fMultDiv2(cosine, residual);
234
235
4.02M
#ifdef SINETABLE_16BIT
236
4.02M
  *out++ = cosine - (error0 << 1);
237
4.02M
  *out++ = sine + (error1 << 1);
238
#else
239
  /* Undo downscaling by 1 which was done at fixp_sin_cos_residual_inline */
240
  *out++ = SATURATE_LEFT_SHIFT(cosine - (error0 << 1), 1, DFRACT_BITS);
241
  *out++ = SATURATE_LEFT_SHIFT(sine + (error1 << 1), 1, DFRACT_BITS);
242
#endif
243
244
4.02M
  residual = fixp_sin_cos_residual_inline(x2, scale, &sine, &cosine);
245
4.02M
  error0 = fMultDiv2(sine, residual);
246
4.02M
  error1 = fMultDiv2(cosine, residual);
247
248
4.02M
#ifdef SINETABLE_16BIT
249
4.02M
  *out++ = cosine - (error0 << 1);
250
4.02M
  *out++ = sine + (error1 << 1);
251
#else
252
  *out++ = SATURATE_LEFT_SHIFT(cosine - (error0 << 1), 1, DFRACT_BITS);
253
  *out++ = SATURATE_LEFT_SHIFT(sine + (error1 << 1), 1, DFRACT_BITS);
254
#endif
255
4.02M
}
Unexecuted instantiation: sacenc_dmx_tdom_enh.cpp:inline_fixp_cos_sin(int, int, int, int*)
Unexecuted instantiation: usacdec_lpc.cpp:inline_fixp_cos_sin(int, int, int, int*)
256
#endif
257
258
#endif /* !defined(FDK_TRIGFCTS_H) */