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1 
2 /* -----------------------------------------------------------------------------------------------------------
3 Software License for The Fraunhofer FDK AAC Codec Library for Android
4 
5 � Copyright  1995 - 2015 Fraunhofer-Gesellschaft zur F�rderung der angewandten Forschung e.V.
6   All rights reserved.
7 
8  1.    INTRODUCTION
9 The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software that implements
10 the MPEG Advanced Audio Coding ("AAC") encoding and decoding scheme for digital audio.
11 This FDK AAC Codec software is intended to be used on a wide variety of Android devices.
12 
13 AAC's HE-AAC and HE-AAC v2 versions are regarded as today's most efficient general perceptual
14 audio codecs. AAC-ELD is considered the best-performing full-bandwidth communications codec by
15 independent studies and is widely deployed. AAC has been standardized by ISO and IEC as part
16 of the MPEG specifications.
17 
18 Patent licenses for necessary patent claims for the FDK AAC Codec (including those of Fraunhofer)
19 may be obtained through Via Licensing (www.vialicensing.com) or through the respective patent owners
20 individually for the purpose of encoding or decoding bit streams in products that are compliant with
21 the ISO/IEC MPEG audio standards. Please note that most manufacturers of Android devices already license
22 these patent claims through Via Licensing or directly from the patent owners, and therefore FDK AAC Codec
23 software may already be covered under those patent licenses when it is used for those licensed purposes only.
24 
25 Commercially-licensed AAC software libraries, including floating-point versions with enhanced sound quality,
26 are also available from Fraunhofer. Users are encouraged to check the Fraunhofer website for additional
27 applications information and documentation.
28 
29 2.    COPYRIGHT LICENSE
30 
31 Redistribution and use in source and binary forms, with or without modification, are permitted without
32 payment of copyright license fees provided that you satisfy the following conditions:
33 
34 You must retain the complete text of this software license in redistributions of the FDK AAC Codec or
35 your modifications thereto in source code form.
36 
37 You must retain the complete text of this software license in the documentation and/or other materials
38 provided with redistributions of the FDK AAC Codec or your modifications thereto in binary form.
39 You must make available free of charge copies of the complete source code of the FDK AAC Codec and your
40 modifications thereto to recipients of copies in binary form.
41 
42 The name of Fraunhofer may not be used to endorse or promote products derived from this library without
43 prior written permission.
44 
45 You may not charge copyright license fees for anyone to use, copy or distribute the FDK AAC Codec
46 software or your modifications thereto.
47 
48 Your modified versions of the FDK AAC Codec must carry prominent notices stating that you changed the software
49 and the date of any change. For modified versions of the FDK AAC Codec, the term
50 "Fraunhofer FDK AAC Codec Library for Android" must be replaced by the term
51 "Third-Party Modified Version of the Fraunhofer FDK AAC Codec Library for Android."
52 
53 3.    NO PATENT LICENSE
54 
55 NO EXPRESS OR IMPLIED LICENSES TO ANY PATENT CLAIMS, including without limitation the patents of Fraunhofer,
56 ARE GRANTED BY THIS SOFTWARE LICENSE. Fraunhofer provides no warranty of patent non-infringement with
57 respect to this software.
58 
59 You may use this FDK AAC Codec software or modifications thereto only for purposes that are authorized
60 by appropriate patent licenses.
61 
62 4.    DISCLAIMER
63 
64 This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors
65 "AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, including but not limited to the implied warranties
66 of merchantability and fitness for a particular purpose. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
67 CONTRIBUTORS BE LIABLE for any direct, indirect, incidental, special, exemplary, or consequential damages,
68 including but not limited to procurement of substitute goods or services; loss of use, data, or profits,
69 or business interruption, however caused and on any theory of liability, whether in contract, strict
70 liability, or tort (including negligence), arising in any way out of the use of this software, even if
71 advised of the possibility of such damage.
72 
73 5.    CONTACT INFORMATION
74 
75 Fraunhofer Institute for Integrated Circuits IIS
76 Attention: Audio and Multimedia Departments - FDK AAC LL
77 Am Wolfsmantel 33
78 91058 Erlangen, Germany
79 
80 www.iis.fraunhofer.de/amm
81 amm-info@iis.fraunhofer.de
82 ----------------------------------------------------------------------------------------------------------- */
83 
84 /*****************************  MPEG Audio Encoder  ***************************
85 
86    Initial author:       N. Rettelbach
87    contents/description: Parametric Stereo bitstream encoder
88 
89 ******************************************************************************/
90 
91 #include "ps_main.h"
92 
93 
94 #include "ps_const.h"
95 #include "ps_bitenc.h"
96 
97 static
FDKsbrEnc_WriteBits_ps(HANDLE_FDK_BITSTREAM hBitStream,UINT value,const UINT numberOfBits)98 inline UCHAR FDKsbrEnc_WriteBits_ps(HANDLE_FDK_BITSTREAM hBitStream, UINT value,
99                                     const UINT numberOfBits)
100 {
101   /* hBitStream == NULL happens here intentionally */
102   if(hBitStream!=NULL){
103     FDKwriteBits(hBitStream, value, numberOfBits);
104   }
105   return numberOfBits;
106 }
107 
108 #define SI_SBR_EXTENSION_SIZE_BITS              4
109 #define SI_SBR_EXTENSION_ESC_COUNT_BITS         8
110 #define SI_SBR_EXTENSION_ID_BITS                2
111 #define EXTENSION_ID_PS_CODING                  2
112 #define PS_EXT_ID_V0                            0
113 
114 static const INT iidDeltaCoarse_Offset = 14;
115 static const INT iidDeltaCoarse_MaxVal = 28;
116 static const INT iidDeltaFine_Offset = 30;
117 static const INT iidDeltaFine_MaxVal = 60;
118 
119 /* PS Stereo Huffmantable: iidDeltaFreqCoarse */
120 static const UINT iidDeltaFreqCoarse_Length[] =
121 {
122   17,    17,    17,    17,    16,  15,    13,    10,     9,     7,
123    6,     5,     4,     3,     1,   3,     4,     5,     6,     6,
124    8,    11,    13,    14,    14,  15,    17,    18,    18
125 };
126 static const UINT iidDeltaFreqCoarse_Code[]  =
127 {
128   0x0001fffb,  0x0001fffc,  0x0001fffd,  0x0001fffa,  0x0000fffc,  0x00007ffc,  0x00001ffd,  0x000003fe,  0x000001fe,  0x0000007e,
129   0x0000003c,  0x0000001d,  0x0000000d,  0x00000005,  0000000000,  0x00000004,  0x0000000c,  0x0000001c,  0x0000003d,  0x0000003e,
130   0x000000fe,  0x000007fe,  0x00001ffc,  0x00003ffc,  0x00003ffd,  0x00007ffd,  0x0001fffe,  0x0003fffe,  0x0003ffff
131 };
132 
133 /* PS Stereo Huffmantable: iidDeltaFreqFine */
134 static const UINT iidDeltaFreqFine_Length[] =
135 {
136   18,    18,    18,    18,    18,  18,    18,    18,    18,    17,
137   18,    17,    17,    16,    16,  15,    14,    14,    13,    12,
138   12,    11,    10,    10,     8,   7,     6,     5,     4,     3,
139    1,     3,     4,     5,     6,   7,     8,     9,    10,    11,
140   11,    12,    13,    14,    14,  15,    16,    16,    17,    17,
141   18,    17,    18,    18,    18,  18,    18,    18,    18,    18,
142   18
143 };
144 static const UINT iidDeltaFreqFine_Code[] =
145 {
146   0x0001feb4,  0x0001feb5,  0x0001fd76,  0x0001fd77,  0x0001fd74,  0x0001fd75,  0x0001fe8a,  0x0001fe8b,  0x0001fe88,  0x0000fe80,
147   0x0001feb6,  0x0000fe82,  0x0000feb8,  0x00007f42,  0x00007fae,  0x00003faf,  0x00001fd1,  0x00001fe9,  0x00000fe9,  0x000007ea,
148   0x000007fb,  0x000003fb,  0x000001fb,  0x000001ff,  0x0000007c,  0x0000003c,  0x0000001c,  0x0000000c,  0000000000,  0x00000001,
149   0x00000001,  0x00000002,  0x00000001,  0x0000000d,  0x0000001d,  0x0000003d,  0x0000007d,  0x000000fc,  0x000001fc,  0x000003fc,
150   0x000003f4,  0x000007eb,  0x00000fea,  0x00001fea,  0x00001fd6,  0x00003fd0,  0x00007faf,  0x00007f43,  0x0000feb9,  0x0000fe83,
151   0x0001feb7,  0x0000fe81,  0x0001fe89,  0x0001fe8e,  0x0001fe8f,  0x0001fe8c,  0x0001fe8d,  0x0001feb2,  0x0001feb3,  0x0001feb0,
152   0x0001feb1
153 };
154 
155 /* PS Stereo Huffmantable: iidDeltaTimeCoarse */
156 static const UINT iidDeltaTimeCoarse_Length[] =
157 {
158   19,    19,    19,    20,    20,  20,    17,    15,    12,    10,
159    8,     6,     4,     2,     1,   3,     5,     7,     9,    11,
160   13,    14,    17,    19,    20,  20,    20,    20,    20
161 };
162 static const UINT iidDeltaTimeCoarse_Code[] =
163 {
164   0x0007fff9,  0x0007fffa,  0x0007fffb,  0x000ffff8,  0x000ffff9,  0x000ffffa,  0x0001fffd,  0x00007ffe,  0x00000ffe,  0x000003fe,
165   0x000000fe,  0x0000003e,  0x0000000e,  0x00000002,  0000000000,  0x00000006,  0x0000001e,  0x0000007e,  0x000001fe,  0x000007fe,
166   0x00001ffe,  0x00003ffe,  0x0001fffc,  0x0007fff8,  0x000ffffb,  0x000ffffc,  0x000ffffd,  0x000ffffe,  0x000fffff
167 };
168 
169 /* PS Stereo Huffmantable: iidDeltaTimeFine */
170 static const UINT iidDeltaTimeFine_Length[] =
171 {
172   16,    16,    16,    16,    16,  16,    16,    16,    16,    15,
173   15,    15,    15,    15,    15,  14,    14,    13,    13,    13,
174   12,    12,    11,    10,     9,   9,     7,     6,     5,     3,
175    1,     2,     5,     6,     7,   8,     9,    10,    11,    11,
176   12,    12,    13,    13,    14,  14,    15,    15,    15,    15,
177   16,    16,    16,    16,    16,  16,    16,    16,    16,    16,
178   16
179 };
180 static const UINT iidDeltaTimeFine_Code[] =
181 {
182   0x00004ed4,  0x00004ed5,  0x00004ece,  0x00004ecf,  0x00004ecc,  0x00004ed6,  0x00004ed8,  0x00004f46,  0x00004f60,  0x00002718,
183   0x00002719,  0x00002764,  0x00002765,  0x0000276d,  0x000027b1,  0x000013b7,  0x000013d6,  0x000009c7,  0x000009e9,  0x000009ed,
184   0x000004ee,  0x000004f7,  0x00000278,  0x00000139,  0x0000009a,  0x0000009f,  0x00000020,  0x00000011,  0x0000000a,  0x00000003,
185   0x00000001,  0000000000,  0x0000000b,  0x00000012,  0x00000021,  0x0000004c,  0x0000009b,  0x0000013a,  0x00000279,  0x00000270,
186   0x000004ef,  0x000004e2,  0x000009ea,  0x000009d8,  0x000013d7,  0x000013d0,  0x000027b2,  0x000027a2,  0x0000271a,  0x0000271b,
187   0x00004f66,  0x00004f67,  0x00004f61,  0x00004f47,  0x00004ed9,  0x00004ed7,  0x00004ecd,  0x00004ed2,  0x00004ed3,  0x00004ed0,
188   0x00004ed1
189 };
190 
191 static const INT iccDelta_Offset =  7;
192 static const INT iccDelta_MaxVal = 14;
193 /* PS Stereo Huffmantable: iccDeltaFreq */
194 static const UINT iccDeltaFreq_Length[] =
195 {
196   14,    14,    12,    10,     7,   5,     3,     1,     2,     4,
197    6,     8,     9,    11,    13
198 };
199 static const UINT iccDeltaFreq_Code[] =
200 {
201   0x00003fff,  0x00003ffe,  0x00000ffe,  0x000003fe,  0x0000007e,  0x0000001e,  0x00000006,  0000000000,  0x00000002,  0x0000000e,
202   0x0000003e,  0x000000fe,  0x000001fe,  0x000007fe,  0x00001ffe
203 };
204 
205 /* PS Stereo Huffmantable: iccDeltaTime */
206 static const UINT iccDeltaTime_Length[] =
207 {
208   14,    13,    11,     9,     7,   5,     3,     1,     2,     4,
209    6,     8,    10,    12,    14
210 };
211 static const UINT iccDeltaTime_Code[] =
212 {
213   0x00003ffe,  0x00001ffe,  0x000007fe,  0x000001fe,  0x0000007e,  0x0000001e,  0x00000006,  0000000000,  0x00000002,  0x0000000e,
214   0x0000003e,  0x000000fe,  0x000003fe,  0x00000ffe,  0x00003fff
215 };
216 
217 
218 
219 static const INT ipdDelta_Offset = 0;
220 static const INT ipdDelta_MaxVal = 7;
221 /* PS Stereo Huffmantable: ipdDeltaFreq */
222 static const UINT ipdDeltaFreq_Length[] =
223 {
224    1,     3,     4,     4,     4,   4,     4,     4
225 };
226 static const UINT ipdDeltaFreq_Code[] =
227 {
228   0x00000001,  0000000000,  0x00000006,  0x00000004,  0x00000002,  0x00000003,  0x00000005,  0x00000007
229 };
230 
231 /* PS Stereo Huffmantable: ipdDeltaTime */
232 static const UINT ipdDeltaTime_Length[] =
233 {
234    1,     3,     4,     5,     5,   4,     4,     3
235 };
236 static const UINT ipdDeltaTime_Code[] =
237 {
238   0x00000001,  0x00000002,  0x00000002,  0x00000003,  0x00000002,  0000000000,  0x00000003,  0x00000003
239 };
240 
241 
242 static const INT opdDelta_Offset = 0;
243 static const INT opdDelta_MaxVal = 7;
244 /* PS Stereo Huffmantable: opdDeltaFreq */
245 static const UINT opdDeltaFreq_Length[] =
246 {
247    1,     3,     4,     4,     5,   5,     4,     3
248 };
249 static const UINT opdDeltaFreq_Code[] =
250 {
251   0x00000001,  0x00000001,  0x00000006,  0x00000004,  0x0000000f,  0x0000000e,  0x00000005,  0000000000,
252 };
253 
254 /* PS Stereo Huffmantable: opdDeltaTime */
255 static const UINT opdDeltaTime_Length[] =
256 {
257    1,     3,     4,     5,     5,   4,     4,     3
258 };
259 static const UINT opdDeltaTime_Code[] =
260 {
261   0x00000001,  0x00000002,  0x00000001,  0x00000007,  0x00000006,  0000000000,  0x00000002,  0x00000003
262 };
263 
getNoBands(const INT mode)264 static INT getNoBands(const INT mode)
265 {
266   INT noBands = 0;
267 
268   switch (mode) {
269     case 0: case 3: /* coarse */
270       noBands = PS_BANDS_COARSE;
271       break;
272     case 1: case 4: /* mid */
273       noBands = PS_BANDS_MID;
274       break;
275     case 2: case 5: /* fine not supported */
276     default:        /* coarse as default */
277       noBands = PS_BANDS_COARSE;
278   }
279 
280   return noBands;
281 }
282 
getIIDRes(INT iidMode)283 static INT getIIDRes(INT iidMode)
284 {
285   if(iidMode<3)
286     return PS_IID_RES_COARSE;
287   else
288     return PS_IID_RES_FINE;
289 }
290 
291 static INT
encodeDeltaFreq(HANDLE_FDK_BITSTREAM hBitBuf,const INT * val,const INT nBands,const UINT * codeTable,const UINT * lengthTable,const INT tableOffset,const INT maxVal,INT * error)292 encodeDeltaFreq(HANDLE_FDK_BITSTREAM hBitBuf,
293                 const INT          *val,
294                 const INT           nBands,
295                 const UINT *codeTable,
296                 const UINT *lengthTable,
297                 const INT           tableOffset,
298                 const INT           maxVal,
299                 INT                *error)
300 {
301   INT bitCnt = 0;
302   INT lastVal = 0;
303   INT band;
304 
305   for(band=0;band<nBands;band++) {
306     INT delta = (val[band] - lastVal) + tableOffset;
307     lastVal = val[band];
308     if( (delta>maxVal) || (delta<0) ) {
309       *error = 1;
310       delta = delta>0?maxVal:0;
311     }
312     bitCnt += FDKsbrEnc_WriteBits_ps(hBitBuf, codeTable[delta], lengthTable[delta]);
313   }
314 
315   return bitCnt;
316 }
317 
318 static INT
encodeDeltaTime(HANDLE_FDK_BITSTREAM hBitBuf,const INT * val,const INT * valLast,const INT nBands,const UINT * codeTable,const UINT * lengthTable,const INT tableOffset,const INT maxVal,INT * error)319 encodeDeltaTime(HANDLE_FDK_BITSTREAM hBitBuf,
320                 const INT          *val,
321                 const INT          *valLast,
322                 const INT           nBands,
323                 const UINT *codeTable,
324                 const UINT *lengthTable,
325                 const INT           tableOffset,
326                 const INT           maxVal,
327                 INT                *error)
328 {
329   INT bitCnt = 0;
330   INT band;
331 
332   for(band=0;band<nBands;band++) {
333     INT delta = (val[band] - valLast[band]) + tableOffset;
334     if( (delta>maxVal) || (delta<0) ) {
335       *error = 1;
336       delta = delta>0?maxVal:0;
337     }
338     bitCnt += FDKsbrEnc_WriteBits_ps(hBitBuf, codeTable[delta], lengthTable[delta]);
339   }
340 
341   return bitCnt;
342 }
343 
FDKsbrEnc_EncodeIid(HANDLE_FDK_BITSTREAM hBitBuf,const INT * iidVal,const INT * iidValLast,const INT nBands,const PS_IID_RESOLUTION res,const PS_DELTA mode,INT * error)344 INT FDKsbrEnc_EncodeIid(HANDLE_FDK_BITSTREAM     hBitBuf,
345               const INT               *iidVal,
346               const INT               *iidValLast,
347               const INT                nBands,
348               const PS_IID_RESOLUTION  res,
349               const PS_DELTA           mode,
350               INT                     *error)
351 {
352   const UINT *codeTable;
353   const UINT *lengthTable;
354   INT bitCnt = 0;
355 
356   bitCnt = 0;
357 
358   switch(mode) {
359   case PS_DELTA_FREQ:
360     switch(res) {
361     case PS_IID_RES_COARSE:
362       codeTable   = iidDeltaFreqCoarse_Code;
363       lengthTable = iidDeltaFreqCoarse_Length;
364       bitCnt += encodeDeltaFreq(hBitBuf, iidVal, nBands, codeTable,
365                                 lengthTable, iidDeltaCoarse_Offset,
366                                 iidDeltaCoarse_MaxVal, error);
367     break;
368     case PS_IID_RES_FINE:
369       codeTable   = iidDeltaFreqFine_Code;
370       lengthTable = iidDeltaFreqFine_Length;
371       bitCnt += encodeDeltaFreq(hBitBuf, iidVal, nBands, codeTable,
372                                 lengthTable, iidDeltaFine_Offset,
373                                 iidDeltaFine_MaxVal, error);
374     break;
375     default:
376       *error = 1;
377     }
378     break;
379 
380   case PS_DELTA_TIME:
381     switch(res) {
382     case PS_IID_RES_COARSE:
383       codeTable   = iidDeltaTimeCoarse_Code;
384       lengthTable = iidDeltaTimeCoarse_Length;
385       bitCnt += encodeDeltaTime(hBitBuf, iidVal, iidValLast, nBands, codeTable,
386                                 lengthTable, iidDeltaCoarse_Offset,
387                                 iidDeltaCoarse_MaxVal, error);
388     break;
389     case PS_IID_RES_FINE:
390       codeTable   = iidDeltaTimeFine_Code;
391       lengthTable = iidDeltaTimeFine_Length;
392       bitCnt += encodeDeltaTime(hBitBuf, iidVal, iidValLast, nBands, codeTable,
393                                 lengthTable, iidDeltaFine_Offset,
394                                 iidDeltaFine_MaxVal, error);
395     break;
396     default:
397       *error = 1;
398     }
399     break;
400 
401   default:
402     *error = 1;
403   }
404 
405   return bitCnt;
406 }
407 
408 
FDKsbrEnc_EncodeIcc(HANDLE_FDK_BITSTREAM hBitBuf,const INT * iccVal,const INT * iccValLast,const INT nBands,const PS_DELTA mode,INT * error)409 INT FDKsbrEnc_EncodeIcc(HANDLE_FDK_BITSTREAM hBitBuf,
410               const INT      *iccVal,
411               const INT      *iccValLast,
412               const INT       nBands,
413               const PS_DELTA  mode,
414               INT            *error)
415 {
416   const UINT *codeTable;
417   const UINT *lengthTable;
418   INT bitCnt = 0;
419 
420   switch(mode) {
421   case PS_DELTA_FREQ:
422     codeTable   = iccDeltaFreq_Code;
423     lengthTable = iccDeltaFreq_Length;
424     bitCnt += encodeDeltaFreq(hBitBuf, iccVal, nBands, codeTable,
425                               lengthTable, iccDelta_Offset, iccDelta_MaxVal, error);
426     break;
427 
428   case PS_DELTA_TIME:
429     codeTable   = iccDeltaTime_Code;
430     lengthTable = iccDeltaTime_Length;
431 
432     bitCnt += encodeDeltaTime(hBitBuf, iccVal, iccValLast, nBands, codeTable,
433                               lengthTable, iccDelta_Offset, iccDelta_MaxVal, error);
434     break;
435 
436   default:
437     *error = 1;
438   }
439 
440   return bitCnt;
441 }
442 
FDKsbrEnc_EncodeIpd(HANDLE_FDK_BITSTREAM hBitBuf,const INT * ipdVal,const INT * ipdValLast,const INT nBands,const PS_DELTA mode,INT * error)443 INT FDKsbrEnc_EncodeIpd(HANDLE_FDK_BITSTREAM hBitBuf,
444               const INT      *ipdVal,
445               const INT      *ipdValLast,
446               const INT       nBands,
447               const PS_DELTA  mode,
448               INT            *error)
449 {
450   const UINT *codeTable;
451   const UINT *lengthTable;
452   INT bitCnt = 0;
453 
454   switch(mode) {
455   case PS_DELTA_FREQ:
456     codeTable   = ipdDeltaFreq_Code;
457     lengthTable = ipdDeltaFreq_Length;
458     bitCnt += encodeDeltaFreq(hBitBuf, ipdVal, nBands, codeTable,
459                               lengthTable, ipdDelta_Offset, ipdDelta_MaxVal, error);
460     break;
461 
462   case PS_DELTA_TIME:
463     codeTable   = ipdDeltaTime_Code;
464     lengthTable = ipdDeltaTime_Length;
465 
466     bitCnt += encodeDeltaTime(hBitBuf, ipdVal, ipdValLast, nBands, codeTable,
467                               lengthTable, ipdDelta_Offset, ipdDelta_MaxVal, error);
468     break;
469 
470   default:
471     *error = 1;
472   }
473 
474   return bitCnt;
475 }
476 
FDKsbrEnc_EncodeOpd(HANDLE_FDK_BITSTREAM hBitBuf,const INT * opdVal,const INT * opdValLast,const INT nBands,const PS_DELTA mode,INT * error)477 INT FDKsbrEnc_EncodeOpd(HANDLE_FDK_BITSTREAM hBitBuf,
478               const INT      *opdVal,
479               const INT      *opdValLast,
480               const INT       nBands,
481               const PS_DELTA  mode,
482               INT            *error)
483 {
484   const UINT *codeTable;
485   const UINT *lengthTable;
486   INT bitCnt = 0;
487 
488   switch(mode) {
489   case PS_DELTA_FREQ:
490     codeTable   = opdDeltaFreq_Code;
491     lengthTable = opdDeltaFreq_Length;
492     bitCnt += encodeDeltaFreq(hBitBuf, opdVal, nBands, codeTable,
493                               lengthTable, opdDelta_Offset, opdDelta_MaxVal, error);
494     break;
495 
496   case PS_DELTA_TIME:
497     codeTable   = opdDeltaTime_Code;
498     lengthTable = opdDeltaTime_Length;
499 
500     bitCnt += encodeDeltaTime(hBitBuf, opdVal, opdValLast, nBands, codeTable,
501                               lengthTable, opdDelta_Offset, opdDelta_MaxVal, error);
502     break;
503 
504   default:
505     *error = 1;
506   }
507 
508   return bitCnt;
509 }
510 
encodeIpdOpd(HANDLE_PS_OUT psOut,HANDLE_FDK_BITSTREAM hBitBuf)511 static INT encodeIpdOpd(HANDLE_PS_OUT        psOut,
512                         HANDLE_FDK_BITSTREAM hBitBuf )
513 {
514   INT bitCnt = 0;
515   INT error  = 0;
516   INT env;
517 
518   FDKsbrEnc_WriteBits_ps(hBitBuf, psOut->enableIpdOpd, 1);
519 
520   if(psOut->enableIpdOpd==1) {
521     INT *ipdLast = psOut->ipdLast;
522     INT *opdLast = psOut->opdLast;
523 
524     for(env=0; env<psOut->nEnvelopes; env++) {
525       bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->deltaIPD[env], 1);
526       bitCnt += FDKsbrEnc_EncodeIpd( hBitBuf,
527                            psOut->ipd[env],
528                            ipdLast,
529                            getNoBands(psOut->iidMode),
530                            psOut->deltaIPD[env],
531                            &error);
532 
533       bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->deltaOPD[env], 1);
534       bitCnt += FDKsbrEnc_EncodeOpd( hBitBuf,
535                            psOut->opd[env],
536                            opdLast,
537                            getNoBands(psOut->iidMode),
538                            psOut->deltaOPD[env],
539                            &error );
540     }
541     /* reserved bit */
542     bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, 0, 1);
543   }
544 
545 
546   return bitCnt;
547 }
548 
getEnvIdx(const INT nEnvelopes,const INT frameClass)549 static INT getEnvIdx(const INT nEnvelopes, const INT frameClass)
550 {
551   INT envIdx = 0;
552 
553   switch(nEnvelopes) {
554   case 0:
555     envIdx = 0;
556     break;
557 
558   case 1:
559     if (frameClass==0)
560       envIdx = 1;
561     else
562       envIdx = 0;
563     break;
564 
565   case 2:
566     if (frameClass==0)
567       envIdx = 2;
568     else
569       envIdx = 1;
570     break;
571 
572   case 3:
573     envIdx = 2;
574     break;
575 
576   case 4:
577     envIdx = 3;
578     break;
579 
580   default:
581     /* unsupported number of envelopes */
582     envIdx = 0;
583   }
584 
585   return envIdx;
586 }
587 
588 
encodePSExtension(const HANDLE_PS_OUT psOut,HANDLE_FDK_BITSTREAM hBitBuf)589 static INT encodePSExtension(const HANDLE_PS_OUT   psOut,
590                              HANDLE_FDK_BITSTREAM  hBitBuf )
591 {
592   INT bitCnt = 0;
593 
594   if(psOut->enableIpdOpd==1) {
595     INT ipdOpdBits = 0;
596     INT extSize = (2 + encodeIpdOpd(psOut,NULL)+7)>>3;
597 
598     if(extSize<15) {
599       bitCnt += FDKsbrEnc_WriteBits_ps(hBitBuf,  extSize, 4);
600     }
601     else {
602       bitCnt += FDKsbrEnc_WriteBits_ps(hBitBuf,          15 , 4);
603       bitCnt += FDKsbrEnc_WriteBits_ps(hBitBuf, (extSize-15), 8);
604     }
605 
606     /* write ipd opd data */
607     ipdOpdBits += FDKsbrEnc_WriteBits_ps(hBitBuf, PS_EXT_ID_V0, 2);
608     ipdOpdBits += encodeIpdOpd(psOut, hBitBuf );
609 
610     /* byte align the ipd opd data  */
611     if(ipdOpdBits%8)
612       ipdOpdBits += FDKsbrEnc_WriteBits_ps(hBitBuf, 0, (8-(ipdOpdBits%8)) );
613 
614     bitCnt += ipdOpdBits;
615   }
616 
617   return (bitCnt);
618 }
619 
FDKsbrEnc_WritePSBitstream(const HANDLE_PS_OUT psOut,HANDLE_FDK_BITSTREAM hBitBuf)620 INT FDKsbrEnc_WritePSBitstream(const HANDLE_PS_OUT   psOut,
621                                HANDLE_FDK_BITSTREAM  hBitBuf )
622 {
623   INT psExtEnable = 0;
624   INT bitCnt = 0;
625   INT error = 0;
626   INT env;
627 
628   if(psOut != NULL){
629 
630     /* PS HEADER */
631     bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->enablePSHeader, 1);
632 
633     if(psOut->enablePSHeader) {
634 
635       bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->enableIID, 1);
636       if(psOut->enableIID) {
637         bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->iidMode, 3);
638       }
639       bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->enableICC, 1);
640       if(psOut->enableICC) {
641         bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->iccMode, 3);
642       }
643       if(psOut->enableIpdOpd) {
644         psExtEnable = 1;
645       }
646       bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psExtEnable, 1);
647     }
648 
649     /* Frame class, number of envelopes */
650     bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->frameClass, 1);
651     bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, getEnvIdx(psOut->nEnvelopes, psOut->frameClass), 2);
652 
653     if(psOut->frameClass==1) {
654       for(env=0; env<psOut->nEnvelopes; env++) {
655         bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->frameBorder[env], 5);
656       }
657     }
658 
659     if(psOut->enableIID==1) {
660       INT *iidLast = psOut->iidLast;
661       for(env=0; env<psOut->nEnvelopes; env++) {
662         bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->deltaIID[env], 1);
663         bitCnt += FDKsbrEnc_EncodeIid( hBitBuf,
664                              psOut->iid[env],
665                              iidLast,
666                              getNoBands(psOut->iidMode),
667                              (PS_IID_RESOLUTION)getIIDRes(psOut->iidMode),
668                              psOut->deltaIID[env],
669                              &error );
670 
671         iidLast = psOut->iid[env];
672       }
673     }
674 
675     if(psOut->enableICC==1) {
676       INT *iccLast = psOut->iccLast;
677       for(env=0; env<psOut->nEnvelopes; env++) {
678         bitCnt += FDKsbrEnc_WriteBits_ps( hBitBuf, psOut->deltaICC[env], 1);
679         bitCnt += FDKsbrEnc_EncodeIcc( hBitBuf,
680                              psOut->icc[env],
681                              iccLast,
682                              getNoBands(psOut->iccMode),
683                              psOut->deltaICC[env],
684                              &error);
685 
686         iccLast = psOut->icc[env];
687       }
688     }
689 
690     if(psExtEnable!=0) {
691       bitCnt += encodePSExtension(psOut, hBitBuf);
692     }
693 
694   } /* if(psOut != NULL) */
695 
696   return bitCnt;
697 }
698 
699