Mercurial > games > semicongine
comparison semiconginev2/old/resources/stb_vorbis.c @ 1218:56781cc0fc7c compiletime-tests
did: renamge main package
author | sam <sam@basx.dev> |
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date | Wed, 17 Jul 2024 21:01:37 +0700 |
parents | semicongine/old/resources/stb_vorbis.c@a3eb305bcac2 |
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1 // Ogg Vorbis audio decoder - v1.22 - public domain | |
2 // http://nothings.org/stb_vorbis/ | |
3 // | |
4 // Original version written by Sean Barrett in 2007. | |
5 // | |
6 // Originally sponsored by RAD Game Tools. Seeking implementation | |
7 // sponsored by Phillip Bennefall, Marc Andersen, Aaron Baker, | |
8 // Elias Software, Aras Pranckevicius, and Sean Barrett. | |
9 // | |
10 // LICENSE | |
11 // | |
12 // See end of file for license information. | |
13 // | |
14 // Limitations: | |
15 // | |
16 // - floor 0 not supported (used in old ogg vorbis files pre-2004) | |
17 // - lossless sample-truncation at beginning ignored | |
18 // - cannot concatenate multiple vorbis streams | |
19 // - sample positions are 32-bit, limiting seekable 192Khz | |
20 // files to around 6 hours (Ogg supports 64-bit) | |
21 // | |
22 // Feature contributors: | |
23 // Dougall Johnson (sample-exact seeking) | |
24 // | |
25 // Bugfix/warning contributors: | |
26 // Terje Mathisen Niklas Frykholm Andy Hill | |
27 // Casey Muratori John Bolton Gargaj | |
28 // Laurent Gomila Marc LeBlanc Ronny Chevalier | |
29 // Bernhard Wodo Evan Balster github:alxprd | |
30 // Tom Beaumont Ingo Leitgeb Nicolas Guillemot | |
31 // Phillip Bennefall Rohit Thiago Goulart | |
32 // github:manxorist Saga Musix github:infatum | |
33 // Timur Gagiev Maxwell Koo Peter Waller | |
34 // github:audinowho Dougall Johnson David Reid | |
35 // github:Clownacy Pedro J. Estebanez Remi Verschelde | |
36 // AnthoFoxo github:morlat Gabriel Ravier | |
37 // | |
38 // Partial history: | |
39 // 1.22 - 2021-07-11 - various small fixes | |
40 // 1.21 - 2021-07-02 - fix bug for files with no comments | |
41 // 1.20 - 2020-07-11 - several small fixes | |
42 // 1.19 - 2020-02-05 - warnings | |
43 // 1.18 - 2020-02-02 - fix seek bugs; parse header comments; misc warnings etc. | |
44 // 1.17 - 2019-07-08 - fix CVE-2019-13217..CVE-2019-13223 (by ForAllSecure) | |
45 // 1.16 - 2019-03-04 - fix warnings | |
46 // 1.15 - 2019-02-07 - explicit failure if Ogg Skeleton data is found | |
47 // 1.14 - 2018-02-11 - delete bogus dealloca usage | |
48 // 1.13 - 2018-01-29 - fix truncation of last frame (hopefully) | |
49 // 1.12 - 2017-11-21 - limit residue begin/end to blocksize/2 to avoid large temp allocs in bad/corrupt files | |
50 // 1.11 - 2017-07-23 - fix MinGW compilation | |
51 // 1.10 - 2017-03-03 - more robust seeking; fix negative ilog(); clear error in open_memory | |
52 // 1.09 - 2016-04-04 - back out 'truncation of last frame' fix from previous version | |
53 // 1.08 - 2016-04-02 - warnings; setup memory leaks; truncation of last frame | |
54 // 1.07 - 2015-01-16 - fixes for crashes on invalid files; warning fixes; const | |
55 // 1.06 - 2015-08-31 - full, correct support for seeking API (Dougall Johnson) | |
56 // some crash fixes when out of memory or with corrupt files | |
57 // fix some inappropriately signed shifts | |
58 // 1.05 - 2015-04-19 - don't define __forceinline if it's redundant | |
59 // 1.04 - 2014-08-27 - fix missing const-correct case in API | |
60 // 1.03 - 2014-08-07 - warning fixes | |
61 // 1.02 - 2014-07-09 - declare qsort comparison as explicitly _cdecl in Windows | |
62 // 1.01 - 2014-06-18 - fix stb_vorbis_get_samples_float (interleaved was correct) | |
63 // 1.0 - 2014-05-26 - fix memory leaks; fix warnings; fix bugs in >2-channel; | |
64 // (API change) report sample rate for decode-full-file funcs | |
65 // | |
66 // See end of file for full version history. | |
67 | |
68 | |
69 ////////////////////////////////////////////////////////////////////////////// | |
70 // | |
71 // HEADER BEGINS HERE | |
72 // | |
73 | |
74 #ifndef STB_VORBIS_INCLUDE_STB_VORBIS_H | |
75 #define STB_VORBIS_INCLUDE_STB_VORBIS_H | |
76 | |
77 #if defined(STB_VORBIS_NO_CRT) && !defined(STB_VORBIS_NO_STDIO) | |
78 #define STB_VORBIS_NO_STDIO 1 | |
79 #endif | |
80 | |
81 #ifndef STB_VORBIS_NO_STDIO | |
82 #include <stdio.h> | |
83 #endif | |
84 | |
85 #ifdef __cplusplus | |
86 extern "C" { | |
87 #endif | |
88 | |
89 /////////// THREAD SAFETY | |
90 | |
91 // Individual stb_vorbis* handles are not thread-safe; you cannot decode from | |
92 // them from multiple threads at the same time. However, you can have multiple | |
93 // stb_vorbis* handles and decode from them independently in multiple thrads. | |
94 | |
95 | |
96 /////////// MEMORY ALLOCATION | |
97 | |
98 // normally stb_vorbis uses malloc() to allocate memory at startup, | |
99 // and alloca() to allocate temporary memory during a frame on the | |
100 // stack. (Memory consumption will depend on the amount of setup | |
101 // data in the file and how you set the compile flags for speed | |
102 // vs. size. In my test files the maximal-size usage is ~150KB.) | |
103 // | |
104 // You can modify the wrapper functions in the source (setup_malloc, | |
105 // setup_temp_malloc, temp_malloc) to change this behavior, or you | |
106 // can use a simpler allocation model: you pass in a buffer from | |
107 // which stb_vorbis will allocate _all_ its memory (including the | |
108 // temp memory). "open" may fail with a VORBIS_outofmem if you | |
109 // do not pass in enough data; there is no way to determine how | |
110 // much you do need except to succeed (at which point you can | |
111 // query get_info to find the exact amount required. yes I know | |
112 // this is lame). | |
113 // | |
114 // If you pass in a non-NULL buffer of the type below, allocation | |
115 // will occur from it as described above. Otherwise just pass NULL | |
116 // to use malloc()/alloca() | |
117 | |
118 typedef struct | |
119 { | |
120 char *alloc_buffer; | |
121 int alloc_buffer_length_in_bytes; | |
122 } stb_vorbis_alloc; | |
123 | |
124 | |
125 /////////// FUNCTIONS USEABLE WITH ALL INPUT MODES | |
126 | |
127 typedef struct stb_vorbis stb_vorbis; | |
128 | |
129 typedef struct | |
130 { | |
131 unsigned int sample_rate; | |
132 int channels; | |
133 | |
134 unsigned int setup_memory_required; | |
135 unsigned int setup_temp_memory_required; | |
136 unsigned int temp_memory_required; | |
137 | |
138 int max_frame_size; | |
139 } stb_vorbis_info; | |
140 | |
141 typedef struct | |
142 { | |
143 char *vendor; | |
144 | |
145 int comment_list_length; | |
146 char **comment_list; | |
147 } stb_vorbis_comment; | |
148 | |
149 // get general information about the file | |
150 extern stb_vorbis_info stb_vorbis_get_info(stb_vorbis *f); | |
151 | |
152 // get ogg comments | |
153 extern stb_vorbis_comment stb_vorbis_get_comment(stb_vorbis *f); | |
154 | |
155 // get the last error detected (clears it, too) | |
156 extern int stb_vorbis_get_error(stb_vorbis *f); | |
157 | |
158 // close an ogg vorbis file and free all memory in use | |
159 extern void stb_vorbis_close(stb_vorbis *f); | |
160 | |
161 // this function returns the offset (in samples) from the beginning of the | |
162 // file that will be returned by the next decode, if it is known, or -1 | |
163 // otherwise. after a flush_pushdata() call, this may take a while before | |
164 // it becomes valid again. | |
165 // NOT WORKING YET after a seek with PULLDATA API | |
166 extern int stb_vorbis_get_sample_offset(stb_vorbis *f); | |
167 | |
168 // returns the current seek point within the file, or offset from the beginning | |
169 // of the memory buffer. In pushdata mode it returns 0. | |
170 extern unsigned int stb_vorbis_get_file_offset(stb_vorbis *f); | |
171 | |
172 /////////// PUSHDATA API | |
173 | |
174 #ifndef STB_VORBIS_NO_PUSHDATA_API | |
175 | |
176 // this API allows you to get blocks of data from any source and hand | |
177 // them to stb_vorbis. you have to buffer them; stb_vorbis will tell | |
178 // you how much it used, and you have to give it the rest next time; | |
179 // and stb_vorbis may not have enough data to work with and you will | |
180 // need to give it the same data again PLUS more. Note that the Vorbis | |
181 // specification does not bound the size of an individual frame. | |
182 | |
183 extern stb_vorbis *stb_vorbis_open_pushdata( | |
184 const unsigned char * datablock, int datablock_length_in_bytes, | |
185 int *datablock_memory_consumed_in_bytes, | |
186 int *error, | |
187 const stb_vorbis_alloc *alloc_buffer); | |
188 // create a vorbis decoder by passing in the initial data block containing | |
189 // the ogg&vorbis headers (you don't need to do parse them, just provide | |
190 // the first N bytes of the file--you're told if it's not enough, see below) | |
191 // on success, returns an stb_vorbis *, does not set error, returns the amount of | |
192 // data parsed/consumed on this call in *datablock_memory_consumed_in_bytes; | |
193 // on failure, returns NULL on error and sets *error, does not change *datablock_memory_consumed | |
194 // if returns NULL and *error is VORBIS_need_more_data, then the input block was | |
195 // incomplete and you need to pass in a larger block from the start of the file | |
196 | |
197 extern int stb_vorbis_decode_frame_pushdata( | |
198 stb_vorbis *f, | |
199 const unsigned char *datablock, int datablock_length_in_bytes, | |
200 int *channels, // place to write number of float * buffers | |
201 float ***output, // place to write float ** array of float * buffers | |
202 int *samples // place to write number of output samples | |
203 ); | |
204 // decode a frame of audio sample data if possible from the passed-in data block | |
205 // | |
206 // return value: number of bytes we used from datablock | |
207 // | |
208 // possible cases: | |
209 // 0 bytes used, 0 samples output (need more data) | |
210 // N bytes used, 0 samples output (resynching the stream, keep going) | |
211 // N bytes used, M samples output (one frame of data) | |
212 // note that after opening a file, you will ALWAYS get one N-bytes,0-sample | |
213 // frame, because Vorbis always "discards" the first frame. | |
214 // | |
215 // Note that on resynch, stb_vorbis will rarely consume all of the buffer, | |
216 // instead only datablock_length_in_bytes-3 or less. This is because it wants | |
217 // to avoid missing parts of a page header if they cross a datablock boundary, | |
218 // without writing state-machiney code to record a partial detection. | |
219 // | |
220 // The number of channels returned are stored in *channels (which can be | |
221 // NULL--it is always the same as the number of channels reported by | |
222 // get_info). *output will contain an array of float* buffers, one per | |
223 // channel. In other words, (*output)[0][0] contains the first sample from | |
224 // the first channel, and (*output)[1][0] contains the first sample from | |
225 // the second channel. | |
226 // | |
227 // *output points into stb_vorbis's internal output buffer storage; these | |
228 // buffers are owned by stb_vorbis and application code should not free | |
229 // them or modify their contents. They are transient and will be overwritten | |
230 // once you ask for more data to get decoded, so be sure to grab any data | |
231 // you need before then. | |
232 | |
233 extern void stb_vorbis_flush_pushdata(stb_vorbis *f); | |
234 // inform stb_vorbis that your next datablock will not be contiguous with | |
235 // previous ones (e.g. you've seeked in the data); future attempts to decode | |
236 // frames will cause stb_vorbis to resynchronize (as noted above), and | |
237 // once it sees a valid Ogg page (typically 4-8KB, as large as 64KB), it | |
238 // will begin decoding the _next_ frame. | |
239 // | |
240 // if you want to seek using pushdata, you need to seek in your file, then | |
241 // call stb_vorbis_flush_pushdata(), then start calling decoding, then once | |
242 // decoding is returning you data, call stb_vorbis_get_sample_offset, and | |
243 // if you don't like the result, seek your file again and repeat. | |
244 #endif | |
245 | |
246 | |
247 ////////// PULLING INPUT API | |
248 | |
249 #ifndef STB_VORBIS_NO_PULLDATA_API | |
250 // This API assumes stb_vorbis is allowed to pull data from a source-- | |
251 // either a block of memory containing the _entire_ vorbis stream, or a | |
252 // FILE * that you or it create, or possibly some other reading mechanism | |
253 // if you go modify the source to replace the FILE * case with some kind | |
254 // of callback to your code. (But if you don't support seeking, you may | |
255 // just want to go ahead and use pushdata.) | |
256 | |
257 #if !defined(STB_VORBIS_NO_STDIO) && !defined(STB_VORBIS_NO_INTEGER_CONVERSION) | |
258 extern int stb_vorbis_decode_filename(const char *filename, int *channels, int *sample_rate, short **output); | |
259 #endif | |
260 #if !defined(STB_VORBIS_NO_INTEGER_CONVERSION) | |
261 extern int stb_vorbis_decode_memory(const unsigned char *mem, int len, int *channels, int *sample_rate, short **output); | |
262 #endif | |
263 // decode an entire file and output the data interleaved into a malloc()ed | |
264 // buffer stored in *output. The return value is the number of samples | |
265 // decoded, or -1 if the file could not be opened or was not an ogg vorbis file. | |
266 // When you're done with it, just free() the pointer returned in *output. | |
267 | |
268 extern stb_vorbis * stb_vorbis_open_memory(const unsigned char *data, int len, | |
269 int *error, const stb_vorbis_alloc *alloc_buffer); | |
270 // create an ogg vorbis decoder from an ogg vorbis stream in memory (note | |
271 // this must be the entire stream!). on failure, returns NULL and sets *error | |
272 | |
273 #ifndef STB_VORBIS_NO_STDIO | |
274 extern stb_vorbis * stb_vorbis_open_filename(const char *filename, | |
275 int *error, const stb_vorbis_alloc *alloc_buffer); | |
276 // create an ogg vorbis decoder from a filename via fopen(). on failure, | |
277 // returns NULL and sets *error (possibly to VORBIS_file_open_failure). | |
278 | |
279 extern stb_vorbis * stb_vorbis_open_file(FILE *f, int close_handle_on_close, | |
280 int *error, const stb_vorbis_alloc *alloc_buffer); | |
281 // create an ogg vorbis decoder from an open FILE *, looking for a stream at | |
282 // the _current_ seek point (ftell). on failure, returns NULL and sets *error. | |
283 // note that stb_vorbis must "own" this stream; if you seek it in between | |
284 // calls to stb_vorbis, it will become confused. Moreover, if you attempt to | |
285 // perform stb_vorbis_seek_*() operations on this file, it will assume it | |
286 // owns the _entire_ rest of the file after the start point. Use the next | |
287 // function, stb_vorbis_open_file_section(), to limit it. | |
288 | |
289 extern stb_vorbis * stb_vorbis_open_file_section(FILE *f, int close_handle_on_close, | |
290 int *error, const stb_vorbis_alloc *alloc_buffer, unsigned int len); | |
291 // create an ogg vorbis decoder from an open FILE *, looking for a stream at | |
292 // the _current_ seek point (ftell); the stream will be of length 'len' bytes. | |
293 // on failure, returns NULL and sets *error. note that stb_vorbis must "own" | |
294 // this stream; if you seek it in between calls to stb_vorbis, it will become | |
295 // confused. | |
296 #endif | |
297 | |
298 extern int stb_vorbis_seek_frame(stb_vorbis *f, unsigned int sample_number); | |
299 extern int stb_vorbis_seek(stb_vorbis *f, unsigned int sample_number); | |
300 // these functions seek in the Vorbis file to (approximately) 'sample_number'. | |
301 // after calling seek_frame(), the next call to get_frame_*() will include | |
302 // the specified sample. after calling stb_vorbis_seek(), the next call to | |
303 // stb_vorbis_get_samples_* will start with the specified sample. If you | |
304 // do not need to seek to EXACTLY the target sample when using get_samples_*, | |
305 // you can also use seek_frame(). | |
306 | |
307 extern int stb_vorbis_seek_start(stb_vorbis *f); | |
308 // this function is equivalent to stb_vorbis_seek(f,0) | |
309 | |
310 extern unsigned int stb_vorbis_stream_length_in_samples(stb_vorbis *f); | |
311 extern float stb_vorbis_stream_length_in_seconds(stb_vorbis *f); | |
312 // these functions return the total length of the vorbis stream | |
313 | |
314 extern int stb_vorbis_get_frame_float(stb_vorbis *f, int *channels, float ***output); | |
315 // decode the next frame and return the number of samples. the number of | |
316 // channels returned are stored in *channels (which can be NULL--it is always | |
317 // the same as the number of channels reported by get_info). *output will | |
318 // contain an array of float* buffers, one per channel. These outputs will | |
319 // be overwritten on the next call to stb_vorbis_get_frame_*. | |
320 // | |
321 // You generally should not intermix calls to stb_vorbis_get_frame_*() | |
322 // and stb_vorbis_get_samples_*(), since the latter calls the former. | |
323 | |
324 #ifndef STB_VORBIS_NO_INTEGER_CONVERSION | |
325 extern int stb_vorbis_get_frame_short_interleaved(stb_vorbis *f, int num_c, short *buffer, int num_shorts); | |
326 extern int stb_vorbis_get_frame_short (stb_vorbis *f, int num_c, short **buffer, int num_samples); | |
327 #endif | |
328 // decode the next frame and return the number of *samples* per channel. | |
329 // Note that for interleaved data, you pass in the number of shorts (the | |
330 // size of your array), but the return value is the number of samples per | |
331 // channel, not the total number of samples. | |
332 // | |
333 // The data is coerced to the number of channels you request according to the | |
334 // channel coercion rules (see below). You must pass in the size of your | |
335 // buffer(s) so that stb_vorbis will not overwrite the end of the buffer. | |
336 // The maximum buffer size needed can be gotten from get_info(); however, | |
337 // the Vorbis I specification implies an absolute maximum of 4096 samples | |
338 // per channel. | |
339 | |
340 // Channel coercion rules: | |
341 // Let M be the number of channels requested, and N the number of channels present, | |
342 // and Cn be the nth channel; let stereo L be the sum of all L and center channels, | |
343 // and stereo R be the sum of all R and center channels (channel assignment from the | |
344 // vorbis spec). | |
345 // M N output | |
346 // 1 k sum(Ck) for all k | |
347 // 2 * stereo L, stereo R | |
348 // k l k > l, the first l channels, then 0s | |
349 // k l k <= l, the first k channels | |
350 // Note that this is not _good_ surround etc. mixing at all! It's just so | |
351 // you get something useful. | |
352 | |
353 extern int stb_vorbis_get_samples_float_interleaved(stb_vorbis *f, int channels, float *buffer, int num_floats); | |
354 extern int stb_vorbis_get_samples_float(stb_vorbis *f, int channels, float **buffer, int num_samples); | |
355 // gets num_samples samples, not necessarily on a frame boundary--this requires | |
356 // buffering so you have to supply the buffers. DOES NOT APPLY THE COERCION RULES. | |
357 // Returns the number of samples stored per channel; it may be less than requested | |
358 // at the end of the file. If there are no more samples in the file, returns 0. | |
359 | |
360 #ifndef STB_VORBIS_NO_INTEGER_CONVERSION | |
361 extern int stb_vorbis_get_samples_short_interleaved(stb_vorbis *f, int channels, short *buffer, int num_shorts); | |
362 extern int stb_vorbis_get_samples_short(stb_vorbis *f, int channels, short **buffer, int num_samples); | |
363 #endif | |
364 // gets num_samples samples, not necessarily on a frame boundary--this requires | |
365 // buffering so you have to supply the buffers. Applies the coercion rules above | |
366 // to produce 'channels' channels. Returns the number of samples stored per channel; | |
367 // it may be less than requested at the end of the file. If there are no more | |
368 // samples in the file, returns 0. | |
369 | |
370 #endif | |
371 | |
372 //////// ERROR CODES | |
373 | |
374 enum STBVorbisError | |
375 { | |
376 VORBIS__no_error, | |
377 | |
378 VORBIS_need_more_data=1, // not a real error | |
379 | |
380 VORBIS_invalid_api_mixing, // can't mix API modes | |
381 VORBIS_outofmem, // not enough memory | |
382 VORBIS_feature_not_supported, // uses floor 0 | |
383 VORBIS_too_many_channels, // STB_VORBIS_MAX_CHANNELS is too small | |
384 VORBIS_file_open_failure, // fopen() failed | |
385 VORBIS_seek_without_length, // can't seek in unknown-length file | |
386 | |
387 VORBIS_unexpected_eof=10, // file is truncated? | |
388 VORBIS_seek_invalid, // seek past EOF | |
389 | |
390 // decoding errors (corrupt/invalid stream) -- you probably | |
391 // don't care about the exact details of these | |
392 | |
393 // vorbis errors: | |
394 VORBIS_invalid_setup=20, | |
395 VORBIS_invalid_stream, | |
396 | |
397 // ogg errors: | |
398 VORBIS_missing_capture_pattern=30, | |
399 VORBIS_invalid_stream_structure_version, | |
400 VORBIS_continued_packet_flag_invalid, | |
401 VORBIS_incorrect_stream_serial_number, | |
402 VORBIS_invalid_first_page, | |
403 VORBIS_bad_packet_type, | |
404 VORBIS_cant_find_last_page, | |
405 VORBIS_seek_failed, | |
406 VORBIS_ogg_skeleton_not_supported | |
407 }; | |
408 | |
409 | |
410 #ifdef __cplusplus | |
411 } | |
412 #endif | |
413 | |
414 #endif // STB_VORBIS_INCLUDE_STB_VORBIS_H | |
415 // | |
416 // HEADER ENDS HERE | |
417 // | |
418 ////////////////////////////////////////////////////////////////////////////// | |
419 | |
420 #ifndef STB_VORBIS_HEADER_ONLY | |
421 | |
422 // global configuration settings (e.g. set these in the project/makefile), | |
423 // or just set them in this file at the top (although ideally the first few | |
424 // should be visible when the header file is compiled too, although it's not | |
425 // crucial) | |
426 | |
427 // STB_VORBIS_NO_PUSHDATA_API | |
428 // does not compile the code for the various stb_vorbis_*_pushdata() | |
429 // functions | |
430 // #define STB_VORBIS_NO_PUSHDATA_API | |
431 | |
432 // STB_VORBIS_NO_PULLDATA_API | |
433 // does not compile the code for the non-pushdata APIs | |
434 // #define STB_VORBIS_NO_PULLDATA_API | |
435 | |
436 // STB_VORBIS_NO_STDIO | |
437 // does not compile the code for the APIs that use FILE *s internally | |
438 // or externally (implied by STB_VORBIS_NO_PULLDATA_API) | |
439 // #define STB_VORBIS_NO_STDIO | |
440 | |
441 // STB_VORBIS_NO_INTEGER_CONVERSION | |
442 // does not compile the code for converting audio sample data from | |
443 // float to integer (implied by STB_VORBIS_NO_PULLDATA_API) | |
444 // #define STB_VORBIS_NO_INTEGER_CONVERSION | |
445 | |
446 // STB_VORBIS_NO_FAST_SCALED_FLOAT | |
447 // does not use a fast float-to-int trick to accelerate float-to-int on | |
448 // most platforms which requires endianness be defined correctly. | |
449 //#define STB_VORBIS_NO_FAST_SCALED_FLOAT | |
450 | |
451 | |
452 // STB_VORBIS_MAX_CHANNELS [number] | |
453 // globally define this to the maximum number of channels you need. | |
454 // The spec does not put a restriction on channels except that | |
455 // the count is stored in a byte, so 255 is the hard limit. | |
456 // Reducing this saves about 16 bytes per value, so using 16 saves | |
457 // (255-16)*16 or around 4KB. Plus anything other memory usage | |
458 // I forgot to account for. Can probably go as low as 8 (7.1 audio), | |
459 // 6 (5.1 audio), or 2 (stereo only). | |
460 #ifndef STB_VORBIS_MAX_CHANNELS | |
461 #define STB_VORBIS_MAX_CHANNELS 16 // enough for anyone? | |
462 #endif | |
463 | |
464 // STB_VORBIS_PUSHDATA_CRC_COUNT [number] | |
465 // after a flush_pushdata(), stb_vorbis begins scanning for the | |
466 // next valid page, without backtracking. when it finds something | |
467 // that looks like a page, it streams through it and verifies its | |
468 // CRC32. Should that validation fail, it keeps scanning. But it's | |
469 // possible that _while_ streaming through to check the CRC32 of | |
470 // one candidate page, it sees another candidate page. This #define | |
471 // determines how many "overlapping" candidate pages it can search | |
472 // at once. Note that "real" pages are typically ~4KB to ~8KB, whereas | |
473 // garbage pages could be as big as 64KB, but probably average ~16KB. | |
474 // So don't hose ourselves by scanning an apparent 64KB page and | |
475 // missing a ton of real ones in the interim; so minimum of 2 | |
476 #ifndef STB_VORBIS_PUSHDATA_CRC_COUNT | |
477 #define STB_VORBIS_PUSHDATA_CRC_COUNT 4 | |
478 #endif | |
479 | |
480 // STB_VORBIS_FAST_HUFFMAN_LENGTH [number] | |
481 // sets the log size of the huffman-acceleration table. Maximum | |
482 // supported value is 24. with larger numbers, more decodings are O(1), | |
483 // but the table size is larger so worse cache missing, so you'll have | |
484 // to probe (and try multiple ogg vorbis files) to find the sweet spot. | |
485 #ifndef STB_VORBIS_FAST_HUFFMAN_LENGTH | |
486 #define STB_VORBIS_FAST_HUFFMAN_LENGTH 10 | |
487 #endif | |
488 | |
489 // STB_VORBIS_FAST_BINARY_LENGTH [number] | |
490 // sets the log size of the binary-search acceleration table. this | |
491 // is used in similar fashion to the fast-huffman size to set initial | |
492 // parameters for the binary search | |
493 | |
494 // STB_VORBIS_FAST_HUFFMAN_INT | |
495 // The fast huffman tables are much more efficient if they can be | |
496 // stored as 16-bit results instead of 32-bit results. This restricts | |
497 // the codebooks to having only 65535 possible outcomes, though. | |
498 // (At least, accelerated by the huffman table.) | |
499 #ifndef STB_VORBIS_FAST_HUFFMAN_INT | |
500 #define STB_VORBIS_FAST_HUFFMAN_SHORT | |
501 #endif | |
502 | |
503 // STB_VORBIS_NO_HUFFMAN_BINARY_SEARCH | |
504 // If the 'fast huffman' search doesn't succeed, then stb_vorbis falls | |
505 // back on binary searching for the correct one. This requires storing | |
506 // extra tables with the huffman codes in sorted order. Defining this | |
507 // symbol trades off space for speed by forcing a linear search in the | |
508 // non-fast case, except for "sparse" codebooks. | |
509 // #define STB_VORBIS_NO_HUFFMAN_BINARY_SEARCH | |
510 | |
511 // STB_VORBIS_DIVIDES_IN_RESIDUE | |
512 // stb_vorbis precomputes the result of the scalar residue decoding | |
513 // that would otherwise require a divide per chunk. you can trade off | |
514 // space for time by defining this symbol. | |
515 // #define STB_VORBIS_DIVIDES_IN_RESIDUE | |
516 | |
517 // STB_VORBIS_DIVIDES_IN_CODEBOOK | |
518 // vorbis VQ codebooks can be encoded two ways: with every case explicitly | |
519 // stored, or with all elements being chosen from a small range of values, | |
520 // and all values possible in all elements. By default, stb_vorbis expands | |
521 // this latter kind out to look like the former kind for ease of decoding, | |
522 // because otherwise an integer divide-per-vector-element is required to | |
523 // unpack the index. If you define STB_VORBIS_DIVIDES_IN_CODEBOOK, you can | |
524 // trade off storage for speed. | |
525 //#define STB_VORBIS_DIVIDES_IN_CODEBOOK | |
526 | |
527 #ifdef STB_VORBIS_CODEBOOK_SHORTS | |
528 #error "STB_VORBIS_CODEBOOK_SHORTS is no longer supported as it produced incorrect results for some input formats" | |
529 #endif | |
530 | |
531 // STB_VORBIS_DIVIDE_TABLE | |
532 // this replaces small integer divides in the floor decode loop with | |
533 // table lookups. made less than 1% difference, so disabled by default. | |
534 | |
535 // STB_VORBIS_NO_INLINE_DECODE | |
536 // disables the inlining of the scalar codebook fast-huffman decode. | |
537 // might save a little codespace; useful for debugging | |
538 // #define STB_VORBIS_NO_INLINE_DECODE | |
539 | |
540 // STB_VORBIS_NO_DEFER_FLOOR | |
541 // Normally we only decode the floor without synthesizing the actual | |
542 // full curve. We can instead synthesize the curve immediately. This | |
543 // requires more memory and is very likely slower, so I don't think | |
544 // you'd ever want to do it except for debugging. | |
545 // #define STB_VORBIS_NO_DEFER_FLOOR | |
546 | |
547 | |
548 | |
549 | |
550 ////////////////////////////////////////////////////////////////////////////// | |
551 | |
552 #ifdef STB_VORBIS_NO_PULLDATA_API | |
553 #define STB_VORBIS_NO_INTEGER_CONVERSION | |
554 #define STB_VORBIS_NO_STDIO | |
555 #endif | |
556 | |
557 #if defined(STB_VORBIS_NO_CRT) && !defined(STB_VORBIS_NO_STDIO) | |
558 #define STB_VORBIS_NO_STDIO 1 | |
559 #endif | |
560 | |
561 #ifndef STB_VORBIS_NO_INTEGER_CONVERSION | |
562 #ifndef STB_VORBIS_NO_FAST_SCALED_FLOAT | |
563 | |
564 // only need endianness for fast-float-to-int, which we don't | |
565 // use for pushdata | |
566 | |
567 #ifndef STB_VORBIS_BIG_ENDIAN | |
568 #define STB_VORBIS_ENDIAN 0 | |
569 #else | |
570 #define STB_VORBIS_ENDIAN 1 | |
571 #endif | |
572 | |
573 #endif | |
574 #endif | |
575 | |
576 | |
577 #ifndef STB_VORBIS_NO_STDIO | |
578 #include <stdio.h> | |
579 #endif | |
580 | |
581 #ifndef STB_VORBIS_NO_CRT | |
582 #include <stdlib.h> | |
583 #include <string.h> | |
584 #include <assert.h> | |
585 #include <math.h> | |
586 | |
587 // find definition of alloca if it's not in stdlib.h: | |
588 #if defined(_MSC_VER) || defined(__MINGW32__) | |
589 #include <malloc.h> | |
590 #endif | |
591 #if defined(__linux__) || defined(__linux) || defined(__sun__) || defined(__EMSCRIPTEN__) || defined(__NEWLIB__) | |
592 #include <alloca.h> | |
593 #endif | |
594 #else // STB_VORBIS_NO_CRT | |
595 #define NULL 0 | |
596 #define malloc(s) 0 | |
597 #define free(s) ((void) 0) | |
598 #define realloc(s) 0 | |
599 #endif // STB_VORBIS_NO_CRT | |
600 | |
601 #include <limits.h> | |
602 | |
603 #ifdef __MINGW32__ | |
604 // eff you mingw: | |
605 // "fixed": | |
606 // http://sourceforge.net/p/mingw-w64/mailman/message/32882927/ | |
607 // "no that broke the build, reverted, who cares about C": | |
608 // http://sourceforge.net/p/mingw-w64/mailman/message/32890381/ | |
609 #ifdef __forceinline | |
610 #undef __forceinline | |
611 #endif | |
612 #define __forceinline | |
613 #ifndef alloca | |
614 #define alloca __builtin_alloca | |
615 #endif | |
616 #elif !defined(_MSC_VER) | |
617 #if __GNUC__ | |
618 #define __forceinline inline | |
619 #else | |
620 #define __forceinline | |
621 #endif | |
622 #endif | |
623 | |
624 #if STB_VORBIS_MAX_CHANNELS > 256 | |
625 #error "Value of STB_VORBIS_MAX_CHANNELS outside of allowed range" | |
626 #endif | |
627 | |
628 #if STB_VORBIS_FAST_HUFFMAN_LENGTH > 24 | |
629 #error "Value of STB_VORBIS_FAST_HUFFMAN_LENGTH outside of allowed range" | |
630 #endif | |
631 | |
632 | |
633 #if 0 | |
634 #include <crtdbg.h> | |
635 #define CHECK(f) _CrtIsValidHeapPointer(f->channel_buffers[1]) | |
636 #else | |
637 #define CHECK(f) ((void) 0) | |
638 #endif | |
639 | |
640 #define MAX_BLOCKSIZE_LOG 13 // from specification | |
641 #define MAX_BLOCKSIZE (1 << MAX_BLOCKSIZE_LOG) | |
642 | |
643 | |
644 typedef unsigned char uint8; | |
645 typedef signed char int8; | |
646 typedef unsigned short uint16; | |
647 typedef signed short int16; | |
648 typedef unsigned int uint32; | |
649 typedef signed int int32; | |
650 | |
651 #ifndef TRUE | |
652 #define TRUE 1 | |
653 #define FALSE 0 | |
654 #endif | |
655 | |
656 typedef float codetype; | |
657 | |
658 #ifdef _MSC_VER | |
659 #define STBV_NOTUSED(v) (void)(v) | |
660 #else | |
661 #define STBV_NOTUSED(v) (void)sizeof(v) | |
662 #endif | |
663 | |
664 // @NOTE | |
665 // | |
666 // Some arrays below are tagged "//varies", which means it's actually | |
667 // a variable-sized piece of data, but rather than malloc I assume it's | |
668 // small enough it's better to just allocate it all together with the | |
669 // main thing | |
670 // | |
671 // Most of the variables are specified with the smallest size I could pack | |
672 // them into. It might give better performance to make them all full-sized | |
673 // integers. It should be safe to freely rearrange the structures or change | |
674 // the sizes larger--nothing relies on silently truncating etc., nor the | |
675 // order of variables. | |
676 | |
677 #define FAST_HUFFMAN_TABLE_SIZE (1 << STB_VORBIS_FAST_HUFFMAN_LENGTH) | |
678 #define FAST_HUFFMAN_TABLE_MASK (FAST_HUFFMAN_TABLE_SIZE - 1) | |
679 | |
680 typedef struct | |
681 { | |
682 int dimensions, entries; | |
683 uint8 *codeword_lengths; | |
684 float minimum_value; | |
685 float delta_value; | |
686 uint8 value_bits; | |
687 uint8 lookup_type; | |
688 uint8 sequence_p; | |
689 uint8 sparse; | |
690 uint32 lookup_values; | |
691 codetype *multiplicands; | |
692 uint32 *codewords; | |
693 #ifdef STB_VORBIS_FAST_HUFFMAN_SHORT | |
694 int16 fast_huffman[FAST_HUFFMAN_TABLE_SIZE]; | |
695 #else | |
696 int32 fast_huffman[FAST_HUFFMAN_TABLE_SIZE]; | |
697 #endif | |
698 uint32 *sorted_codewords; | |
699 int *sorted_values; | |
700 int sorted_entries; | |
701 } Codebook; | |
702 | |
703 typedef struct | |
704 { | |
705 uint8 order; | |
706 uint16 rate; | |
707 uint16 bark_map_size; | |
708 uint8 amplitude_bits; | |
709 uint8 amplitude_offset; | |
710 uint8 number_of_books; | |
711 uint8 book_list[16]; // varies | |
712 } Floor0; | |
713 | |
714 typedef struct | |
715 { | |
716 uint8 partitions; | |
717 uint8 partition_class_list[32]; // varies | |
718 uint8 class_dimensions[16]; // varies | |
719 uint8 class_subclasses[16]; // varies | |
720 uint8 class_masterbooks[16]; // varies | |
721 int16 subclass_books[16][8]; // varies | |
722 uint16 Xlist[31*8+2]; // varies | |
723 uint8 sorted_order[31*8+2]; | |
724 uint8 neighbors[31*8+2][2]; | |
725 uint8 floor1_multiplier; | |
726 uint8 rangebits; | |
727 int values; | |
728 } Floor1; | |
729 | |
730 typedef union | |
731 { | |
732 Floor0 floor0; | |
733 Floor1 floor1; | |
734 } Floor; | |
735 | |
736 typedef struct | |
737 { | |
738 uint32 begin, end; | |
739 uint32 part_size; | |
740 uint8 classifications; | |
741 uint8 classbook; | |
742 uint8 **classdata; | |
743 int16 (*residue_books)[8]; | |
744 } Residue; | |
745 | |
746 typedef struct | |
747 { | |
748 uint8 magnitude; | |
749 uint8 angle; | |
750 uint8 mux; | |
751 } MappingChannel; | |
752 | |
753 typedef struct | |
754 { | |
755 uint16 coupling_steps; | |
756 MappingChannel *chan; | |
757 uint8 submaps; | |
758 uint8 submap_floor[15]; // varies | |
759 uint8 submap_residue[15]; // varies | |
760 } Mapping; | |
761 | |
762 typedef struct | |
763 { | |
764 uint8 blockflag; | |
765 uint8 mapping; | |
766 uint16 windowtype; | |
767 uint16 transformtype; | |
768 } Mode; | |
769 | |
770 typedef struct | |
771 { | |
772 uint32 goal_crc; // expected crc if match | |
773 int bytes_left; // bytes left in packet | |
774 uint32 crc_so_far; // running crc | |
775 int bytes_done; // bytes processed in _current_ chunk | |
776 uint32 sample_loc; // granule pos encoded in page | |
777 } CRCscan; | |
778 | |
779 typedef struct | |
780 { | |
781 uint32 page_start, page_end; | |
782 uint32 last_decoded_sample; | |
783 } ProbedPage; | |
784 | |
785 struct stb_vorbis | |
786 { | |
787 // user-accessible info | |
788 unsigned int sample_rate; | |
789 int channels; | |
790 | |
791 unsigned int setup_memory_required; | |
792 unsigned int temp_memory_required; | |
793 unsigned int setup_temp_memory_required; | |
794 | |
795 char *vendor; | |
796 int comment_list_length; | |
797 char **comment_list; | |
798 | |
799 // input config | |
800 #ifndef STB_VORBIS_NO_STDIO | |
801 FILE *f; | |
802 uint32 f_start; | |
803 int close_on_free; | |
804 #endif | |
805 | |
806 uint8 *stream; | |
807 uint8 *stream_start; | |
808 uint8 *stream_end; | |
809 | |
810 uint32 stream_len; | |
811 | |
812 uint8 push_mode; | |
813 | |
814 // the page to seek to when seeking to start, may be zero | |
815 uint32 first_audio_page_offset; | |
816 | |
817 // p_first is the page on which the first audio packet ends | |
818 // (but not necessarily the page on which it starts) | |
819 ProbedPage p_first, p_last; | |
820 | |
821 // memory management | |
822 stb_vorbis_alloc alloc; | |
823 int setup_offset; | |
824 int temp_offset; | |
825 | |
826 // run-time results | |
827 int eof; | |
828 enum STBVorbisError error; | |
829 | |
830 // user-useful data | |
831 | |
832 // header info | |
833 int blocksize[2]; | |
834 int blocksize_0, blocksize_1; | |
835 int codebook_count; | |
836 Codebook *codebooks; | |
837 int floor_count; | |
838 uint16 floor_types[64]; // varies | |
839 Floor *floor_config; | |
840 int residue_count; | |
841 uint16 residue_types[64]; // varies | |
842 Residue *residue_config; | |
843 int mapping_count; | |
844 Mapping *mapping; | |
845 int mode_count; | |
846 Mode mode_config[64]; // varies | |
847 | |
848 uint32 total_samples; | |
849 | |
850 // decode buffer | |
851 float *channel_buffers[STB_VORBIS_MAX_CHANNELS]; | |
852 float *outputs [STB_VORBIS_MAX_CHANNELS]; | |
853 | |
854 float *previous_window[STB_VORBIS_MAX_CHANNELS]; | |
855 int previous_length; | |
856 | |
857 #ifndef STB_VORBIS_NO_DEFER_FLOOR | |
858 int16 *finalY[STB_VORBIS_MAX_CHANNELS]; | |
859 #else | |
860 float *floor_buffers[STB_VORBIS_MAX_CHANNELS]; | |
861 #endif | |
862 | |
863 uint32 current_loc; // sample location of next frame to decode | |
864 int current_loc_valid; | |
865 | |
866 // per-blocksize precomputed data | |
867 | |
868 // twiddle factors | |
869 float *A[2],*B[2],*C[2]; | |
870 float *window[2]; | |
871 uint16 *bit_reverse[2]; | |
872 | |
873 // current page/packet/segment streaming info | |
874 uint32 serial; // stream serial number for verification | |
875 int last_page; | |
876 int segment_count; | |
877 uint8 segments[255]; | |
878 uint8 page_flag; | |
879 uint8 bytes_in_seg; | |
880 uint8 first_decode; | |
881 int next_seg; | |
882 int last_seg; // flag that we're on the last segment | |
883 int last_seg_which; // what was the segment number of the last seg? | |
884 uint32 acc; | |
885 int valid_bits; | |
886 int packet_bytes; | |
887 int end_seg_with_known_loc; | |
888 uint32 known_loc_for_packet; | |
889 int discard_samples_deferred; | |
890 uint32 samples_output; | |
891 | |
892 // push mode scanning | |
893 int page_crc_tests; // only in push_mode: number of tests active; -1 if not searching | |
894 #ifndef STB_VORBIS_NO_PUSHDATA_API | |
895 CRCscan scan[STB_VORBIS_PUSHDATA_CRC_COUNT]; | |
896 #endif | |
897 | |
898 // sample-access | |
899 int channel_buffer_start; | |
900 int channel_buffer_end; | |
901 }; | |
902 | |
903 #if defined(STB_VORBIS_NO_PUSHDATA_API) | |
904 #define IS_PUSH_MODE(f) FALSE | |
905 #elif defined(STB_VORBIS_NO_PULLDATA_API) | |
906 #define IS_PUSH_MODE(f) TRUE | |
907 #else | |
908 #define IS_PUSH_MODE(f) ((f)->push_mode) | |
909 #endif | |
910 | |
911 typedef struct stb_vorbis vorb; | |
912 | |
913 static int error(vorb *f, enum STBVorbisError e) | |
914 { | |
915 f->error = e; | |
916 if (!f->eof && e != VORBIS_need_more_data) { | |
917 f->error=e; // breakpoint for debugging | |
918 } | |
919 return 0; | |
920 } | |
921 | |
922 | |
923 // these functions are used for allocating temporary memory | |
924 // while decoding. if you can afford the stack space, use | |
925 // alloca(); otherwise, provide a temp buffer and it will | |
926 // allocate out of those. | |
927 | |
928 #define array_size_required(count,size) (count*(sizeof(void *)+(size))) | |
929 | |
930 #define temp_alloc(f,size) (f->alloc.alloc_buffer ? setup_temp_malloc(f,size) : alloca(size)) | |
931 #define temp_free(f,p) (void)0 | |
932 #define temp_alloc_save(f) ((f)->temp_offset) | |
933 #define temp_alloc_restore(f,p) ((f)->temp_offset = (p)) | |
934 | |
935 #define temp_block_array(f,count,size) make_block_array(temp_alloc(f,array_size_required(count,size)), count, size) | |
936 | |
937 // given a sufficiently large block of memory, make an array of pointers to subblocks of it | |
938 static void *make_block_array(void *mem, int count, int size) | |
939 { | |
940 int i; | |
941 void ** p = (void **) mem; | |
942 char *q = (char *) (p + count); | |
943 for (i=0; i < count; ++i) { | |
944 p[i] = q; | |
945 q += size; | |
946 } | |
947 return p; | |
948 } | |
949 | |
950 static void *setup_malloc(vorb *f, int sz) | |
951 { | |
952 sz = (sz+7) & ~7; // round up to nearest 8 for alignment of future allocs. | |
953 f->setup_memory_required += sz; | |
954 if (f->alloc.alloc_buffer) { | |
955 void *p = (char *) f->alloc.alloc_buffer + f->setup_offset; | |
956 if (f->setup_offset + sz > f->temp_offset) return NULL; | |
957 f->setup_offset += sz; | |
958 return p; | |
959 } | |
960 return sz ? malloc(sz) : NULL; | |
961 } | |
962 | |
963 static void setup_free(vorb *f, void *p) | |
964 { | |
965 if (f->alloc.alloc_buffer) return; // do nothing; setup mem is a stack | |
966 free(p); | |
967 } | |
968 | |
969 static void *setup_temp_malloc(vorb *f, int sz) | |
970 { | |
971 sz = (sz+7) & ~7; // round up to nearest 8 for alignment of future allocs. | |
972 if (f->alloc.alloc_buffer) { | |
973 if (f->temp_offset - sz < f->setup_offset) return NULL; | |
974 f->temp_offset -= sz; | |
975 return (char *) f->alloc.alloc_buffer + f->temp_offset; | |
976 } | |
977 return malloc(sz); | |
978 } | |
979 | |
980 static void setup_temp_free(vorb *f, void *p, int sz) | |
981 { | |
982 if (f->alloc.alloc_buffer) { | |
983 f->temp_offset += (sz+7)&~7; | |
984 return; | |
985 } | |
986 free(p); | |
987 } | |
988 | |
989 #define CRC32_POLY 0x04c11db7 // from spec | |
990 | |
991 static uint32 crc_table[256]; | |
992 static void crc32_init(void) | |
993 { | |
994 int i,j; | |
995 uint32 s; | |
996 for(i=0; i < 256; i++) { | |
997 for (s=(uint32) i << 24, j=0; j < 8; ++j) | |
998 s = (s << 1) ^ (s >= (1U<<31) ? CRC32_POLY : 0); | |
999 crc_table[i] = s; | |
1000 } | |
1001 } | |
1002 | |
1003 static __forceinline uint32 crc32_update(uint32 crc, uint8 byte) | |
1004 { | |
1005 return (crc << 8) ^ crc_table[byte ^ (crc >> 24)]; | |
1006 } | |
1007 | |
1008 | |
1009 // used in setup, and for huffman that doesn't go fast path | |
1010 static unsigned int bit_reverse(unsigned int n) | |
1011 { | |
1012 n = ((n & 0xAAAAAAAA) >> 1) | ((n & 0x55555555) << 1); | |
1013 n = ((n & 0xCCCCCCCC) >> 2) | ((n & 0x33333333) << 2); | |
1014 n = ((n & 0xF0F0F0F0) >> 4) | ((n & 0x0F0F0F0F) << 4); | |
1015 n = ((n & 0xFF00FF00) >> 8) | ((n & 0x00FF00FF) << 8); | |
1016 return (n >> 16) | (n << 16); | |
1017 } | |
1018 | |
1019 static float square(float x) | |
1020 { | |
1021 return x*x; | |
1022 } | |
1023 | |
1024 // this is a weird definition of log2() for which log2(1) = 1, log2(2) = 2, log2(4) = 3 | |
1025 // as required by the specification. fast(?) implementation from stb.h | |
1026 // @OPTIMIZE: called multiple times per-packet with "constants"; move to setup | |
1027 static int ilog(int32 n) | |
1028 { | |
1029 static signed char log2_4[16] = { 0,1,2,2,3,3,3,3,4,4,4,4,4,4,4,4 }; | |
1030 | |
1031 if (n < 0) return 0; // signed n returns 0 | |
1032 | |
1033 // 2 compares if n < 16, 3 compares otherwise (4 if signed or n > 1<<29) | |
1034 if (n < (1 << 14)) | |
1035 if (n < (1 << 4)) return 0 + log2_4[n ]; | |
1036 else if (n < (1 << 9)) return 5 + log2_4[n >> 5]; | |
1037 else return 10 + log2_4[n >> 10]; | |
1038 else if (n < (1 << 24)) | |
1039 if (n < (1 << 19)) return 15 + log2_4[n >> 15]; | |
1040 else return 20 + log2_4[n >> 20]; | |
1041 else if (n < (1 << 29)) return 25 + log2_4[n >> 25]; | |
1042 else return 30 + log2_4[n >> 30]; | |
1043 } | |
1044 | |
1045 #ifndef M_PI | |
1046 #define M_PI 3.14159265358979323846264f // from CRC | |
1047 #endif | |
1048 | |
1049 // code length assigned to a value with no huffman encoding | |
1050 #define NO_CODE 255 | |
1051 | |
1052 /////////////////////// LEAF SETUP FUNCTIONS ////////////////////////// | |
1053 // | |
1054 // these functions are only called at setup, and only a few times | |
1055 // per file | |
1056 | |
1057 static float float32_unpack(uint32 x) | |
1058 { | |
1059 // from the specification | |
1060 uint32 mantissa = x & 0x1fffff; | |
1061 uint32 sign = x & 0x80000000; | |
1062 uint32 exp = (x & 0x7fe00000) >> 21; | |
1063 double res = sign ? -(double)mantissa : (double)mantissa; | |
1064 return (float) ldexp((float)res, (int)exp-788); | |
1065 } | |
1066 | |
1067 | |
1068 // zlib & jpeg huffman tables assume that the output symbols | |
1069 // can either be arbitrarily arranged, or have monotonically | |
1070 // increasing frequencies--they rely on the lengths being sorted; | |
1071 // this makes for a very simple generation algorithm. | |
1072 // vorbis allows a huffman table with non-sorted lengths. This | |
1073 // requires a more sophisticated construction, since symbols in | |
1074 // order do not map to huffman codes "in order". | |
1075 static void add_entry(Codebook *c, uint32 huff_code, int symbol, int count, int len, uint32 *values) | |
1076 { | |
1077 if (!c->sparse) { | |
1078 c->codewords [symbol] = huff_code; | |
1079 } else { | |
1080 c->codewords [count] = huff_code; | |
1081 c->codeword_lengths[count] = len; | |
1082 values [count] = symbol; | |
1083 } | |
1084 } | |
1085 | |
1086 static int compute_codewords(Codebook *c, uint8 *len, int n, uint32 *values) | |
1087 { | |
1088 int i,k,m=0; | |
1089 uint32 available[32]; | |
1090 | |
1091 memset(available, 0, sizeof(available)); | |
1092 // find the first entry | |
1093 for (k=0; k < n; ++k) if (len[k] < NO_CODE) break; | |
1094 if (k == n) { assert(c->sorted_entries == 0); return TRUE; } | |
1095 assert(len[k] < 32); // no error return required, code reading lens checks this | |
1096 // add to the list | |
1097 add_entry(c, 0, k, m++, len[k], values); | |
1098 // add all available leaves | |
1099 for (i=1; i <= len[k]; ++i) | |
1100 available[i] = 1U << (32-i); | |
1101 // note that the above code treats the first case specially, | |
1102 // but it's really the same as the following code, so they | |
1103 // could probably be combined (except the initial code is 0, | |
1104 // and I use 0 in available[] to mean 'empty') | |
1105 for (i=k+1; i < n; ++i) { | |
1106 uint32 res; | |
1107 int z = len[i], y; | |
1108 if (z == NO_CODE) continue; | |
1109 assert(z < 32); // no error return required, code reading lens checks this | |
1110 // find lowest available leaf (should always be earliest, | |
1111 // which is what the specification calls for) | |
1112 // note that this property, and the fact we can never have | |
1113 // more than one free leaf at a given level, isn't totally | |
1114 // trivial to prove, but it seems true and the assert never | |
1115 // fires, so! | |
1116 while (z > 0 && !available[z]) --z; | |
1117 if (z == 0) { return FALSE; } | |
1118 res = available[z]; | |
1119 available[z] = 0; | |
1120 add_entry(c, bit_reverse(res), i, m++, len[i], values); | |
1121 // propagate availability up the tree | |
1122 if (z != len[i]) { | |
1123 for (y=len[i]; y > z; --y) { | |
1124 assert(available[y] == 0); | |
1125 available[y] = res + (1 << (32-y)); | |
1126 } | |
1127 } | |
1128 } | |
1129 return TRUE; | |
1130 } | |
1131 | |
1132 // accelerated huffman table allows fast O(1) match of all symbols | |
1133 // of length <= STB_VORBIS_FAST_HUFFMAN_LENGTH | |
1134 static void compute_accelerated_huffman(Codebook *c) | |
1135 { | |
1136 int i, len; | |
1137 for (i=0; i < FAST_HUFFMAN_TABLE_SIZE; ++i) | |
1138 c->fast_huffman[i] = -1; | |
1139 | |
1140 len = c->sparse ? c->sorted_entries : c->entries; | |
1141 #ifdef STB_VORBIS_FAST_HUFFMAN_SHORT | |
1142 if (len > 32767) len = 32767; // largest possible value we can encode! | |
1143 #endif | |
1144 for (i=0; i < len; ++i) { | |
1145 if (c->codeword_lengths[i] <= STB_VORBIS_FAST_HUFFMAN_LENGTH) { | |
1146 uint32 z = c->sparse ? bit_reverse(c->sorted_codewords[i]) : c->codewords[i]; | |
1147 // set table entries for all bit combinations in the higher bits | |
1148 while (z < FAST_HUFFMAN_TABLE_SIZE) { | |
1149 c->fast_huffman[z] = i; | |
1150 z += 1 << c->codeword_lengths[i]; | |
1151 } | |
1152 } | |
1153 } | |
1154 } | |
1155 | |
1156 #ifdef _MSC_VER | |
1157 #define STBV_CDECL __cdecl | |
1158 #else | |
1159 #define STBV_CDECL | |
1160 #endif | |
1161 | |
1162 static int STBV_CDECL uint32_compare(const void *p, const void *q) | |
1163 { | |
1164 uint32 x = * (uint32 *) p; | |
1165 uint32 y = * (uint32 *) q; | |
1166 return x < y ? -1 : x > y; | |
1167 } | |
1168 | |
1169 static int include_in_sort(Codebook *c, uint8 len) | |
1170 { | |
1171 if (c->sparse) { assert(len != NO_CODE); return TRUE; } | |
1172 if (len == NO_CODE) return FALSE; | |
1173 if (len > STB_VORBIS_FAST_HUFFMAN_LENGTH) return TRUE; | |
1174 return FALSE; | |
1175 } | |
1176 | |
1177 // if the fast table above doesn't work, we want to binary | |
1178 // search them... need to reverse the bits | |
1179 static void compute_sorted_huffman(Codebook *c, uint8 *lengths, uint32 *values) | |
1180 { | |
1181 int i, len; | |
1182 // build a list of all the entries | |
1183 // OPTIMIZATION: don't include the short ones, since they'll be caught by FAST_HUFFMAN. | |
1184 // this is kind of a frivolous optimization--I don't see any performance improvement, | |
1185 // but it's like 4 extra lines of code, so. | |
1186 if (!c->sparse) { | |
1187 int k = 0; | |
1188 for (i=0; i < c->entries; ++i) | |
1189 if (include_in_sort(c, lengths[i])) | |
1190 c->sorted_codewords[k++] = bit_reverse(c->codewords[i]); | |
1191 assert(k == c->sorted_entries); | |
1192 } else { | |
1193 for (i=0; i < c->sorted_entries; ++i) | |
1194 c->sorted_codewords[i] = bit_reverse(c->codewords[i]); | |
1195 } | |
1196 | |
1197 qsort(c->sorted_codewords, c->sorted_entries, sizeof(c->sorted_codewords[0]), uint32_compare); | |
1198 c->sorted_codewords[c->sorted_entries] = 0xffffffff; | |
1199 | |
1200 len = c->sparse ? c->sorted_entries : c->entries; | |
1201 // now we need to indicate how they correspond; we could either | |
1202 // #1: sort a different data structure that says who they correspond to | |
1203 // #2: for each sorted entry, search the original list to find who corresponds | |
1204 // #3: for each original entry, find the sorted entry | |
1205 // #1 requires extra storage, #2 is slow, #3 can use binary search! | |
1206 for (i=0; i < len; ++i) { | |
1207 int huff_len = c->sparse ? lengths[values[i]] : lengths[i]; | |
1208 if (include_in_sort(c,huff_len)) { | |
1209 uint32 code = bit_reverse(c->codewords[i]); | |
1210 int x=0, n=c->sorted_entries; | |
1211 while (n > 1) { | |
1212 // invariant: sc[x] <= code < sc[x+n] | |
1213 int m = x + (n >> 1); | |
1214 if (c->sorted_codewords[m] <= code) { | |
1215 x = m; | |
1216 n -= (n>>1); | |
1217 } else { | |
1218 n >>= 1; | |
1219 } | |
1220 } | |
1221 assert(c->sorted_codewords[x] == code); | |
1222 if (c->sparse) { | |
1223 c->sorted_values[x] = values[i]; | |
1224 c->codeword_lengths[x] = huff_len; | |
1225 } else { | |
1226 c->sorted_values[x] = i; | |
1227 } | |
1228 } | |
1229 } | |
1230 } | |
1231 | |
1232 // only run while parsing the header (3 times) | |
1233 static int vorbis_validate(uint8 *data) | |
1234 { | |
1235 static uint8 vorbis[6] = { 'v', 'o', 'r', 'b', 'i', 's' }; | |
1236 return memcmp(data, vorbis, 6) == 0; | |
1237 } | |
1238 | |
1239 // called from setup only, once per code book | |
1240 // (formula implied by specification) | |
1241 static int lookup1_values(int entries, int dim) | |
1242 { | |
1243 int r = (int) floor(exp((float) log((float) entries) / dim)); | |
1244 if ((int) floor(pow((float) r+1, dim)) <= entries) // (int) cast for MinGW warning; | |
1245 ++r; // floor() to avoid _ftol() when non-CRT | |
1246 if (pow((float) r+1, dim) <= entries) | |
1247 return -1; | |
1248 if ((int) floor(pow((float) r, dim)) > entries) | |
1249 return -1; | |
1250 return r; | |
1251 } | |
1252 | |
1253 // called twice per file | |
1254 static void compute_twiddle_factors(int n, float *A, float *B, float *C) | |
1255 { | |
1256 int n4 = n >> 2, n8 = n >> 3; | |
1257 int k,k2; | |
1258 | |
1259 for (k=k2=0; k < n4; ++k,k2+=2) { | |
1260 A[k2 ] = (float) cos(4*k*M_PI/n); | |
1261 A[k2+1] = (float) -sin(4*k*M_PI/n); | |
1262 B[k2 ] = (float) cos((k2+1)*M_PI/n/2) * 0.5f; | |
1263 B[k2+1] = (float) sin((k2+1)*M_PI/n/2) * 0.5f; | |
1264 } | |
1265 for (k=k2=0; k < n8; ++k,k2+=2) { | |
1266 C[k2 ] = (float) cos(2*(k2+1)*M_PI/n); | |
1267 C[k2+1] = (float) -sin(2*(k2+1)*M_PI/n); | |
1268 } | |
1269 } | |
1270 | |
1271 static void compute_window(int n, float *window) | |
1272 { | |
1273 int n2 = n >> 1, i; | |
1274 for (i=0; i < n2; ++i) | |
1275 window[i] = (float) sin(0.5 * M_PI * square((float) sin((i - 0 + 0.5) / n2 * 0.5 * M_PI))); | |
1276 } | |
1277 | |
1278 static void compute_bitreverse(int n, uint16 *rev) | |
1279 { | |
1280 int ld = ilog(n) - 1; // ilog is off-by-one from normal definitions | |
1281 int i, n8 = n >> 3; | |
1282 for (i=0; i < n8; ++i) | |
1283 rev[i] = (bit_reverse(i) >> (32-ld+3)) << 2; | |
1284 } | |
1285 | |
1286 static int init_blocksize(vorb *f, int b, int n) | |
1287 { | |
1288 int n2 = n >> 1, n4 = n >> 2, n8 = n >> 3; | |
1289 f->A[b] = (float *) setup_malloc(f, sizeof(float) * n2); | |
1290 f->B[b] = (float *) setup_malloc(f, sizeof(float) * n2); | |
1291 f->C[b] = (float *) setup_malloc(f, sizeof(float) * n4); | |
1292 if (!f->A[b] || !f->B[b] || !f->C[b]) return error(f, VORBIS_outofmem); | |
1293 compute_twiddle_factors(n, f->A[b], f->B[b], f->C[b]); | |
1294 f->window[b] = (float *) setup_malloc(f, sizeof(float) * n2); | |
1295 if (!f->window[b]) return error(f, VORBIS_outofmem); | |
1296 compute_window(n, f->window[b]); | |
1297 f->bit_reverse[b] = (uint16 *) setup_malloc(f, sizeof(uint16) * n8); | |
1298 if (!f->bit_reverse[b]) return error(f, VORBIS_outofmem); | |
1299 compute_bitreverse(n, f->bit_reverse[b]); | |
1300 return TRUE; | |
1301 } | |
1302 | |
1303 static void neighbors(uint16 *x, int n, int *plow, int *phigh) | |
1304 { | |
1305 int low = -1; | |
1306 int high = 65536; | |
1307 int i; | |
1308 for (i=0; i < n; ++i) { | |
1309 if (x[i] > low && x[i] < x[n]) { *plow = i; low = x[i]; } | |
1310 if (x[i] < high && x[i] > x[n]) { *phigh = i; high = x[i]; } | |
1311 } | |
1312 } | |
1313 | |
1314 // this has been repurposed so y is now the original index instead of y | |
1315 typedef struct | |
1316 { | |
1317 uint16 x,id; | |
1318 } stbv__floor_ordering; | |
1319 | |
1320 static int STBV_CDECL point_compare(const void *p, const void *q) | |
1321 { | |
1322 stbv__floor_ordering *a = (stbv__floor_ordering *) p; | |
1323 stbv__floor_ordering *b = (stbv__floor_ordering *) q; | |
1324 return a->x < b->x ? -1 : a->x > b->x; | |
1325 } | |
1326 | |
1327 // | |
1328 /////////////////////// END LEAF SETUP FUNCTIONS ////////////////////////// | |
1329 | |
1330 | |
1331 #if defined(STB_VORBIS_NO_STDIO) | |
1332 #define USE_MEMORY(z) TRUE | |
1333 #else | |
1334 #define USE_MEMORY(z) ((z)->stream) | |
1335 #endif | |
1336 | |
1337 static uint8 get8(vorb *z) | |
1338 { | |
1339 if (USE_MEMORY(z)) { | |
1340 if (z->stream >= z->stream_end) { z->eof = TRUE; return 0; } | |
1341 return *z->stream++; | |
1342 } | |
1343 | |
1344 #ifndef STB_VORBIS_NO_STDIO | |
1345 { | |
1346 int c = fgetc(z->f); | |
1347 if (c == EOF) { z->eof = TRUE; return 0; } | |
1348 return c; | |
1349 } | |
1350 #endif | |
1351 } | |
1352 | |
1353 static uint32 get32(vorb *f) | |
1354 { | |
1355 uint32 x; | |
1356 x = get8(f); | |
1357 x += get8(f) << 8; | |
1358 x += get8(f) << 16; | |
1359 x += (uint32) get8(f) << 24; | |
1360 return x; | |
1361 } | |
1362 | |
1363 static int getn(vorb *z, uint8 *data, int n) | |
1364 { | |
1365 if (USE_MEMORY(z)) { | |
1366 if (z->stream+n > z->stream_end) { z->eof = 1; return 0; } | |
1367 memcpy(data, z->stream, n); | |
1368 z->stream += n; | |
1369 return 1; | |
1370 } | |
1371 | |
1372 #ifndef STB_VORBIS_NO_STDIO | |
1373 if (fread(data, n, 1, z->f) == 1) | |
1374 return 1; | |
1375 else { | |
1376 z->eof = 1; | |
1377 return 0; | |
1378 } | |
1379 #endif | |
1380 } | |
1381 | |
1382 static void skip(vorb *z, int n) | |
1383 { | |
1384 if (USE_MEMORY(z)) { | |
1385 z->stream += n; | |
1386 if (z->stream >= z->stream_end) z->eof = 1; | |
1387 return; | |
1388 } | |
1389 #ifndef STB_VORBIS_NO_STDIO | |
1390 { | |
1391 long x = ftell(z->f); | |
1392 fseek(z->f, x+n, SEEK_SET); | |
1393 } | |
1394 #endif | |
1395 } | |
1396 | |
1397 static int set_file_offset(stb_vorbis *f, unsigned int loc) | |
1398 { | |
1399 #ifndef STB_VORBIS_NO_PUSHDATA_API | |
1400 if (f->push_mode) return 0; | |
1401 #endif | |
1402 f->eof = 0; | |
1403 if (USE_MEMORY(f)) { | |
1404 if (f->stream_start + loc >= f->stream_end || f->stream_start + loc < f->stream_start) { | |
1405 f->stream = f->stream_end; | |
1406 f->eof = 1; | |
1407 return 0; | |
1408 } else { | |
1409 f->stream = f->stream_start + loc; | |
1410 return 1; | |
1411 } | |
1412 } | |
1413 #ifndef STB_VORBIS_NO_STDIO | |
1414 if (loc + f->f_start < loc || loc >= 0x80000000) { | |
1415 loc = 0x7fffffff; | |
1416 f->eof = 1; | |
1417 } else { | |
1418 loc += f->f_start; | |
1419 } | |
1420 if (!fseek(f->f, loc, SEEK_SET)) | |
1421 return 1; | |
1422 f->eof = 1; | |
1423 fseek(f->f, f->f_start, SEEK_END); | |
1424 return 0; | |
1425 #endif | |
1426 } | |
1427 | |
1428 | |
1429 static uint8 ogg_page_header[4] = { 0x4f, 0x67, 0x67, 0x53 }; | |
1430 | |
1431 static int capture_pattern(vorb *f) | |
1432 { | |
1433 if (0x4f != get8(f)) return FALSE; | |
1434 if (0x67 != get8(f)) return FALSE; | |
1435 if (0x67 != get8(f)) return FALSE; | |
1436 if (0x53 != get8(f)) return FALSE; | |
1437 return TRUE; | |
1438 } | |
1439 | |
1440 #define PAGEFLAG_continued_packet 1 | |
1441 #define PAGEFLAG_first_page 2 | |
1442 #define PAGEFLAG_last_page 4 | |
1443 | |
1444 static int start_page_no_capturepattern(vorb *f) | |
1445 { | |
1446 uint32 loc0,loc1,n; | |
1447 if (f->first_decode && !IS_PUSH_MODE(f)) { | |
1448 f->p_first.page_start = stb_vorbis_get_file_offset(f) - 4; | |
1449 } | |
1450 // stream structure version | |
1451 if (0 != get8(f)) return error(f, VORBIS_invalid_stream_structure_version); | |
1452 // header flag | |
1453 f->page_flag = get8(f); | |
1454 // absolute granule position | |
1455 loc0 = get32(f); | |
1456 loc1 = get32(f); | |
1457 // @TODO: validate loc0,loc1 as valid positions? | |
1458 // stream serial number -- vorbis doesn't interleave, so discard | |
1459 get32(f); | |
1460 //if (f->serial != get32(f)) return error(f, VORBIS_incorrect_stream_serial_number); | |
1461 // page sequence number | |
1462 n = get32(f); | |
1463 f->last_page = n; | |
1464 // CRC32 | |
1465 get32(f); | |
1466 // page_segments | |
1467 f->segment_count = get8(f); | |
1468 if (!getn(f, f->segments, f->segment_count)) | |
1469 return error(f, VORBIS_unexpected_eof); | |
1470 // assume we _don't_ know any the sample position of any segments | |
1471 f->end_seg_with_known_loc = -2; | |
1472 if (loc0 != ~0U || loc1 != ~0U) { | |
1473 int i; | |
1474 // determine which packet is the last one that will complete | |
1475 for (i=f->segment_count-1; i >= 0; --i) | |
1476 if (f->segments[i] < 255) | |
1477 break; | |
1478 // 'i' is now the index of the _last_ segment of a packet that ends | |
1479 if (i >= 0) { | |
1480 f->end_seg_with_known_loc = i; | |
1481 f->known_loc_for_packet = loc0; | |
1482 } | |
1483 } | |
1484 if (f->first_decode) { | |
1485 int i,len; | |
1486 len = 0; | |
1487 for (i=0; i < f->segment_count; ++i) | |
1488 len += f->segments[i]; | |
1489 len += 27 + f->segment_count; | |
1490 f->p_first.page_end = f->p_first.page_start + len; | |
1491 f->p_first.last_decoded_sample = loc0; | |
1492 } | |
1493 f->next_seg = 0; | |
1494 return TRUE; | |
1495 } | |
1496 | |
1497 static int start_page(vorb *f) | |
1498 { | |
1499 if (!capture_pattern(f)) return error(f, VORBIS_missing_capture_pattern); | |
1500 return start_page_no_capturepattern(f); | |
1501 } | |
1502 | |
1503 static int start_packet(vorb *f) | |
1504 { | |
1505 while (f->next_seg == -1) { | |
1506 if (!start_page(f)) return FALSE; | |
1507 if (f->page_flag & PAGEFLAG_continued_packet) | |
1508 return error(f, VORBIS_continued_packet_flag_invalid); | |
1509 } | |
1510 f->last_seg = FALSE; | |
1511 f->valid_bits = 0; | |
1512 f->packet_bytes = 0; | |
1513 f->bytes_in_seg = 0; | |
1514 // f->next_seg is now valid | |
1515 return TRUE; | |
1516 } | |
1517 | |
1518 static int maybe_start_packet(vorb *f) | |
1519 { | |
1520 if (f->next_seg == -1) { | |
1521 int x = get8(f); | |
1522 if (f->eof) return FALSE; // EOF at page boundary is not an error! | |
1523 if (0x4f != x ) return error(f, VORBIS_missing_capture_pattern); | |
1524 if (0x67 != get8(f)) return error(f, VORBIS_missing_capture_pattern); | |
1525 if (0x67 != get8(f)) return error(f, VORBIS_missing_capture_pattern); | |
1526 if (0x53 != get8(f)) return error(f, VORBIS_missing_capture_pattern); | |
1527 if (!start_page_no_capturepattern(f)) return FALSE; | |
1528 if (f->page_flag & PAGEFLAG_continued_packet) { | |
1529 // set up enough state that we can read this packet if we want, | |
1530 // e.g. during recovery | |
1531 f->last_seg = FALSE; | |
1532 f->bytes_in_seg = 0; | |
1533 return error(f, VORBIS_continued_packet_flag_invalid); | |
1534 } | |
1535 } | |
1536 return start_packet(f); | |
1537 } | |
1538 | |
1539 static int next_segment(vorb *f) | |
1540 { | |
1541 int len; | |
1542 if (f->last_seg) return 0; | |
1543 if (f->next_seg == -1) { | |
1544 f->last_seg_which = f->segment_count-1; // in case start_page fails | |
1545 if (!start_page(f)) { f->last_seg = 1; return 0; } | |
1546 if (!(f->page_flag & PAGEFLAG_continued_packet)) return error(f, VORBIS_continued_packet_flag_invalid); | |
1547 } | |
1548 len = f->segments[f->next_seg++]; | |
1549 if (len < 255) { | |
1550 f->last_seg = TRUE; | |
1551 f->last_seg_which = f->next_seg-1; | |
1552 } | |
1553 if (f->next_seg >= f->segment_count) | |
1554 f->next_seg = -1; | |
1555 assert(f->bytes_in_seg == 0); | |
1556 f->bytes_in_seg = len; | |
1557 return len; | |
1558 } | |
1559 | |
1560 #define EOP (-1) | |
1561 #define INVALID_BITS (-1) | |
1562 | |
1563 static int get8_packet_raw(vorb *f) | |
1564 { | |
1565 if (!f->bytes_in_seg) { // CLANG! | |
1566 if (f->last_seg) return EOP; | |
1567 else if (!next_segment(f)) return EOP; | |
1568 } | |
1569 assert(f->bytes_in_seg > 0); | |
1570 --f->bytes_in_seg; | |
1571 ++f->packet_bytes; | |
1572 return get8(f); | |
1573 } | |
1574 | |
1575 static int get8_packet(vorb *f) | |
1576 { | |
1577 int x = get8_packet_raw(f); | |
1578 f->valid_bits = 0; | |
1579 return x; | |
1580 } | |
1581 | |
1582 static int get32_packet(vorb *f) | |
1583 { | |
1584 uint32 x; | |
1585 x = get8_packet(f); | |
1586 x += get8_packet(f) << 8; | |
1587 x += get8_packet(f) << 16; | |
1588 x += (uint32) get8_packet(f) << 24; | |
1589 return x; | |
1590 } | |
1591 | |
1592 static void flush_packet(vorb *f) | |
1593 { | |
1594 while (get8_packet_raw(f) != EOP); | |
1595 } | |
1596 | |
1597 // @OPTIMIZE: this is the secondary bit decoder, so it's probably not as important | |
1598 // as the huffman decoder? | |
1599 static uint32 get_bits(vorb *f, int n) | |
1600 { | |
1601 uint32 z; | |
1602 | |
1603 if (f->valid_bits < 0) return 0; | |
1604 if (f->valid_bits < n) { | |
1605 if (n > 24) { | |
1606 // the accumulator technique below would not work correctly in this case | |
1607 z = get_bits(f, 24); | |
1608 z += get_bits(f, n-24) << 24; | |
1609 return z; | |
1610 } | |
1611 if (f->valid_bits == 0) f->acc = 0; | |
1612 while (f->valid_bits < n) { | |
1613 int z = get8_packet_raw(f); | |
1614 if (z == EOP) { | |
1615 f->valid_bits = INVALID_BITS; | |
1616 return 0; | |
1617 } | |
1618 f->acc += z << f->valid_bits; | |
1619 f->valid_bits += 8; | |
1620 } | |
1621 } | |
1622 | |
1623 assert(f->valid_bits >= n); | |
1624 z = f->acc & ((1 << n)-1); | |
1625 f->acc >>= n; | |
1626 f->valid_bits -= n; | |
1627 return z; | |
1628 } | |
1629 | |
1630 // @OPTIMIZE: primary accumulator for huffman | |
1631 // expand the buffer to as many bits as possible without reading off end of packet | |
1632 // it might be nice to allow f->valid_bits and f->acc to be stored in registers, | |
1633 // e.g. cache them locally and decode locally | |
1634 static __forceinline void prep_huffman(vorb *f) | |
1635 { | |
1636 if (f->valid_bits <= 24) { | |
1637 if (f->valid_bits == 0) f->acc = 0; | |
1638 do { | |
1639 int z; | |
1640 if (f->last_seg && !f->bytes_in_seg) return; | |
1641 z = get8_packet_raw(f); | |
1642 if (z == EOP) return; | |
1643 f->acc += (unsigned) z << f->valid_bits; | |
1644 f->valid_bits += 8; | |
1645 } while (f->valid_bits <= 24); | |
1646 } | |
1647 } | |
1648 | |
1649 enum | |
1650 { | |
1651 VORBIS_packet_id = 1, | |
1652 VORBIS_packet_comment = 3, | |
1653 VORBIS_packet_setup = 5 | |
1654 }; | |
1655 | |
1656 static int codebook_decode_scalar_raw(vorb *f, Codebook *c) | |
1657 { | |
1658 int i; | |
1659 prep_huffman(f); | |
1660 | |
1661 if (c->codewords == NULL && c->sorted_codewords == NULL) | |
1662 return -1; | |
1663 | |
1664 // cases to use binary search: sorted_codewords && !c->codewords | |
1665 // sorted_codewords && c->entries > 8 | |
1666 if (c->entries > 8 ? c->sorted_codewords!=NULL : !c->codewords) { | |
1667 // binary search | |
1668 uint32 code = bit_reverse(f->acc); | |
1669 int x=0, n=c->sorted_entries, len; | |
1670 | |
1671 while (n > 1) { | |
1672 // invariant: sc[x] <= code < sc[x+n] | |
1673 int m = x + (n >> 1); | |
1674 if (c->sorted_codewords[m] <= code) { | |
1675 x = m; | |
1676 n -= (n>>1); | |
1677 } else { | |
1678 n >>= 1; | |
1679 } | |
1680 } | |
1681 // x is now the sorted index | |
1682 if (!c->sparse) x = c->sorted_values[x]; | |
1683 // x is now sorted index if sparse, or symbol otherwise | |
1684 len = c->codeword_lengths[x]; | |
1685 if (f->valid_bits >= len) { | |
1686 f->acc >>= len; | |
1687 f->valid_bits -= len; | |
1688 return x; | |
1689 } | |
1690 | |
1691 f->valid_bits = 0; | |
1692 return -1; | |
1693 } | |
1694 | |
1695 // if small, linear search | |
1696 assert(!c->sparse); | |
1697 for (i=0; i < c->entries; ++i) { | |
1698 if (c->codeword_lengths[i] == NO_CODE) continue; | |
1699 if (c->codewords[i] == (f->acc & ((1 << c->codeword_lengths[i])-1))) { | |
1700 if (f->valid_bits >= c->codeword_lengths[i]) { | |
1701 f->acc >>= c->codeword_lengths[i]; | |
1702 f->valid_bits -= c->codeword_lengths[i]; | |
1703 return i; | |
1704 } | |
1705 f->valid_bits = 0; | |
1706 return -1; | |
1707 } | |
1708 } | |
1709 | |
1710 error(f, VORBIS_invalid_stream); | |
1711 f->valid_bits = 0; | |
1712 return -1; | |
1713 } | |
1714 | |
1715 #ifndef STB_VORBIS_NO_INLINE_DECODE | |
1716 | |
1717 #define DECODE_RAW(var, f,c) \ | |
1718 if (f->valid_bits < STB_VORBIS_FAST_HUFFMAN_LENGTH) \ | |
1719 prep_huffman(f); \ | |
1720 var = f->acc & FAST_HUFFMAN_TABLE_MASK; \ | |
1721 var = c->fast_huffman[var]; \ | |
1722 if (var >= 0) { \ | |
1723 int n = c->codeword_lengths[var]; \ | |
1724 f->acc >>= n; \ | |
1725 f->valid_bits -= n; \ | |
1726 if (f->valid_bits < 0) { f->valid_bits = 0; var = -1; } \ | |
1727 } else { \ | |
1728 var = codebook_decode_scalar_raw(f,c); \ | |
1729 } | |
1730 | |
1731 #else | |
1732 | |
1733 static int codebook_decode_scalar(vorb *f, Codebook *c) | |
1734 { | |
1735 int i; | |
1736 if (f->valid_bits < STB_VORBIS_FAST_HUFFMAN_LENGTH) | |
1737 prep_huffman(f); | |
1738 // fast huffman table lookup | |
1739 i = f->acc & FAST_HUFFMAN_TABLE_MASK; | |
1740 i = c->fast_huffman[i]; | |
1741 if (i >= 0) { | |
1742 f->acc >>= c->codeword_lengths[i]; | |
1743 f->valid_bits -= c->codeword_lengths[i]; | |
1744 if (f->valid_bits < 0) { f->valid_bits = 0; return -1; } | |
1745 return i; | |
1746 } | |
1747 return codebook_decode_scalar_raw(f,c); | |
1748 } | |
1749 | |
1750 #define DECODE_RAW(var,f,c) var = codebook_decode_scalar(f,c); | |
1751 | |
1752 #endif | |
1753 | |
1754 #define DECODE(var,f,c) \ | |
1755 DECODE_RAW(var,f,c) \ | |
1756 if (c->sparse) var = c->sorted_values[var]; | |
1757 | |
1758 #ifndef STB_VORBIS_DIVIDES_IN_CODEBOOK | |
1759 #define DECODE_VQ(var,f,c) DECODE_RAW(var,f,c) | |
1760 #else | |
1761 #define DECODE_VQ(var,f,c) DECODE(var,f,c) | |
1762 #endif | |
1763 | |
1764 | |
1765 | |
1766 | |
1767 | |
1768 | |
1769 // CODEBOOK_ELEMENT_FAST is an optimization for the CODEBOOK_FLOATS case | |
1770 // where we avoid one addition | |
1771 #define CODEBOOK_ELEMENT(c,off) (c->multiplicands[off]) | |
1772 #define CODEBOOK_ELEMENT_FAST(c,off) (c->multiplicands[off]) | |
1773 #define CODEBOOK_ELEMENT_BASE(c) (0) | |
1774 | |
1775 static int codebook_decode_start(vorb *f, Codebook *c) | |
1776 { | |
1777 int z = -1; | |
1778 | |
1779 // type 0 is only legal in a scalar context | |
1780 if (c->lookup_type == 0) | |
1781 error(f, VORBIS_invalid_stream); | |
1782 else { | |
1783 DECODE_VQ(z,f,c); | |
1784 if (c->sparse) assert(z < c->sorted_entries); | |
1785 if (z < 0) { // check for EOP | |
1786 if (!f->bytes_in_seg) | |
1787 if (f->last_seg) | |
1788 return z; | |
1789 error(f, VORBIS_invalid_stream); | |
1790 } | |
1791 } | |
1792 return z; | |
1793 } | |
1794 | |
1795 static int codebook_decode(vorb *f, Codebook *c, float *output, int len) | |
1796 { | |
1797 int i,z = codebook_decode_start(f,c); | |
1798 if (z < 0) return FALSE; | |
1799 if (len > c->dimensions) len = c->dimensions; | |
1800 | |
1801 #ifdef STB_VORBIS_DIVIDES_IN_CODEBOOK | |
1802 if (c->lookup_type == 1) { | |
1803 float last = CODEBOOK_ELEMENT_BASE(c); | |
1804 int div = 1; | |
1805 for (i=0; i < len; ++i) { | |
1806 int off = (z / div) % c->lookup_values; | |
1807 float val = CODEBOOK_ELEMENT_FAST(c,off) + last; | |
1808 output[i] += val; | |
1809 if (c->sequence_p) last = val + c->minimum_value; | |
1810 div *= c->lookup_values; | |
1811 } | |
1812 return TRUE; | |
1813 } | |
1814 #endif | |
1815 | |
1816 z *= c->dimensions; | |
1817 if (c->sequence_p) { | |
1818 float last = CODEBOOK_ELEMENT_BASE(c); | |
1819 for (i=0; i < len; ++i) { | |
1820 float val = CODEBOOK_ELEMENT_FAST(c,z+i) + last; | |
1821 output[i] += val; | |
1822 last = val + c->minimum_value; | |
1823 } | |
1824 } else { | |
1825 float last = CODEBOOK_ELEMENT_BASE(c); | |
1826 for (i=0; i < len; ++i) { | |
1827 output[i] += CODEBOOK_ELEMENT_FAST(c,z+i) + last; | |
1828 } | |
1829 } | |
1830 | |
1831 return TRUE; | |
1832 } | |
1833 | |
1834 static int codebook_decode_step(vorb *f, Codebook *c, float *output, int len, int step) | |
1835 { | |
1836 int i,z = codebook_decode_start(f,c); | |
1837 float last = CODEBOOK_ELEMENT_BASE(c); | |
1838 if (z < 0) return FALSE; | |
1839 if (len > c->dimensions) len = c->dimensions; | |
1840 | |
1841 #ifdef STB_VORBIS_DIVIDES_IN_CODEBOOK | |
1842 if (c->lookup_type == 1) { | |
1843 int div = 1; | |
1844 for (i=0; i < len; ++i) { | |
1845 int off = (z / div) % c->lookup_values; | |
1846 float val = CODEBOOK_ELEMENT_FAST(c,off) + last; | |
1847 output[i*step] += val; | |
1848 if (c->sequence_p) last = val; | |
1849 div *= c->lookup_values; | |
1850 } | |
1851 return TRUE; | |
1852 } | |
1853 #endif | |
1854 | |
1855 z *= c->dimensions; | |
1856 for (i=0; i < len; ++i) { | |
1857 float val = CODEBOOK_ELEMENT_FAST(c,z+i) + last; | |
1858 output[i*step] += val; | |
1859 if (c->sequence_p) last = val; | |
1860 } | |
1861 | |
1862 return TRUE; | |
1863 } | |
1864 | |
1865 static int codebook_decode_deinterleave_repeat(vorb *f, Codebook *c, float **outputs, int ch, int *c_inter_p, int *p_inter_p, int len, int total_decode) | |
1866 { | |
1867 int c_inter = *c_inter_p; | |
1868 int p_inter = *p_inter_p; | |
1869 int i,z, effective = c->dimensions; | |
1870 | |
1871 // type 0 is only legal in a scalar context | |
1872 if (c->lookup_type == 0) return error(f, VORBIS_invalid_stream); | |
1873 | |
1874 while (total_decode > 0) { | |
1875 float last = CODEBOOK_ELEMENT_BASE(c); | |
1876 DECODE_VQ(z,f,c); | |
1877 #ifndef STB_VORBIS_DIVIDES_IN_CODEBOOK | |
1878 assert(!c->sparse || z < c->sorted_entries); | |
1879 #endif | |
1880 if (z < 0) { | |
1881 if (!f->bytes_in_seg) | |
1882 if (f->last_seg) return FALSE; | |
1883 return error(f, VORBIS_invalid_stream); | |
1884 } | |
1885 | |
1886 // if this will take us off the end of the buffers, stop short! | |
1887 // we check by computing the length of the virtual interleaved | |
1888 // buffer (len*ch), our current offset within it (p_inter*ch)+(c_inter), | |
1889 // and the length we'll be using (effective) | |
1890 if (c_inter + p_inter*ch + effective > len * ch) { | |
1891 effective = len*ch - (p_inter*ch - c_inter); | |
1892 } | |
1893 | |
1894 #ifdef STB_VORBIS_DIVIDES_IN_CODEBOOK | |
1895 if (c->lookup_type == 1) { | |
1896 int div = 1; | |
1897 for (i=0; i < effective; ++i) { | |
1898 int off = (z / div) % c->lookup_values; | |
1899 float val = CODEBOOK_ELEMENT_FAST(c,off) + last; | |
1900 if (outputs[c_inter]) | |
1901 outputs[c_inter][p_inter] += val; | |
1902 if (++c_inter == ch) { c_inter = 0; ++p_inter; } | |
1903 if (c->sequence_p) last = val; | |
1904 div *= c->lookup_values; | |
1905 } | |
1906 } else | |
1907 #endif | |
1908 { | |
1909 z *= c->dimensions; | |
1910 if (c->sequence_p) { | |
1911 for (i=0; i < effective; ++i) { | |
1912 float val = CODEBOOK_ELEMENT_FAST(c,z+i) + last; | |
1913 if (outputs[c_inter]) | |
1914 outputs[c_inter][p_inter] += val; | |
1915 if (++c_inter == ch) { c_inter = 0; ++p_inter; } | |
1916 last = val; | |
1917 } | |
1918 } else { | |
1919 for (i=0; i < effective; ++i) { | |
1920 float val = CODEBOOK_ELEMENT_FAST(c,z+i) + last; | |
1921 if (outputs[c_inter]) | |
1922 outputs[c_inter][p_inter] += val; | |
1923 if (++c_inter == ch) { c_inter = 0; ++p_inter; } | |
1924 } | |
1925 } | |
1926 } | |
1927 | |
1928 total_decode -= effective; | |
1929 } | |
1930 *c_inter_p = c_inter; | |
1931 *p_inter_p = p_inter; | |
1932 return TRUE; | |
1933 } | |
1934 | |
1935 static int predict_point(int x, int x0, int x1, int y0, int y1) | |
1936 { | |
1937 int dy = y1 - y0; | |
1938 int adx = x1 - x0; | |
1939 // @OPTIMIZE: force int division to round in the right direction... is this necessary on x86? | |
1940 int err = abs(dy) * (x - x0); | |
1941 int off = err / adx; | |
1942 return dy < 0 ? y0 - off : y0 + off; | |
1943 } | |
1944 | |
1945 // the following table is block-copied from the specification | |
1946 static float inverse_db_table[256] = | |
1947 { | |
1948 1.0649863e-07f, 1.1341951e-07f, 1.2079015e-07f, 1.2863978e-07f, | |
1949 1.3699951e-07f, 1.4590251e-07f, 1.5538408e-07f, 1.6548181e-07f, | |
1950 1.7623575e-07f, 1.8768855e-07f, 1.9988561e-07f, 2.1287530e-07f, | |
1951 2.2670913e-07f, 2.4144197e-07f, 2.5713223e-07f, 2.7384213e-07f, | |
1952 2.9163793e-07f, 3.1059021e-07f, 3.3077411e-07f, 3.5226968e-07f, | |
1953 3.7516214e-07f, 3.9954229e-07f, 4.2550680e-07f, 4.5315863e-07f, | |
1954 4.8260743e-07f, 5.1396998e-07f, 5.4737065e-07f, 5.8294187e-07f, | |
1955 6.2082472e-07f, 6.6116941e-07f, 7.0413592e-07f, 7.4989464e-07f, | |
1956 7.9862701e-07f, 8.5052630e-07f, 9.0579828e-07f, 9.6466216e-07f, | |
1957 1.0273513e-06f, 1.0941144e-06f, 1.1652161e-06f, 1.2409384e-06f, | |
1958 1.3215816e-06f, 1.4074654e-06f, 1.4989305e-06f, 1.5963394e-06f, | |
1959 1.7000785e-06f, 1.8105592e-06f, 1.9282195e-06f, 2.0535261e-06f, | |
1960 2.1869758e-06f, 2.3290978e-06f, 2.4804557e-06f, 2.6416497e-06f, | |
1961 2.8133190e-06f, 2.9961443e-06f, 3.1908506e-06f, 3.3982101e-06f, | |
1962 3.6190449e-06f, 3.8542308e-06f, 4.1047004e-06f, 4.3714470e-06f, | |
1963 4.6555282e-06f, 4.9580707e-06f, 5.2802740e-06f, 5.6234160e-06f, | |
1964 5.9888572e-06f, 6.3780469e-06f, 6.7925283e-06f, 7.2339451e-06f, | |
1965 7.7040476e-06f, 8.2047000e-06f, 8.7378876e-06f, 9.3057248e-06f, | |
1966 9.9104632e-06f, 1.0554501e-05f, 1.1240392e-05f, 1.1970856e-05f, | |
1967 1.2748789e-05f, 1.3577278e-05f, 1.4459606e-05f, 1.5399272e-05f, | |
1968 1.6400004e-05f, 1.7465768e-05f, 1.8600792e-05f, 1.9809576e-05f, | |
1969 2.1096914e-05f, 2.2467911e-05f, 2.3928002e-05f, 2.5482978e-05f, | |
1970 2.7139006e-05f, 2.8902651e-05f, 3.0780908e-05f, 3.2781225e-05f, | |
1971 3.4911534e-05f, 3.7180282e-05f, 3.9596466e-05f, 4.2169667e-05f, | |
1972 4.4910090e-05f, 4.7828601e-05f, 5.0936773e-05f, 5.4246931e-05f, | |
1973 5.7772202e-05f, 6.1526565e-05f, 6.5524908e-05f, 6.9783085e-05f, | |
1974 7.4317983e-05f, 7.9147585e-05f, 8.4291040e-05f, 8.9768747e-05f, | |
1975 9.5602426e-05f, 0.00010181521f, 0.00010843174f, 0.00011547824f, | |
1976 0.00012298267f, 0.00013097477f, 0.00013948625f, 0.00014855085f, | |
1977 0.00015820453f, 0.00016848555f, 0.00017943469f, 0.00019109536f, | |
1978 0.00020351382f, 0.00021673929f, 0.00023082423f, 0.00024582449f, | |
1979 0.00026179955f, 0.00027881276f, 0.00029693158f, 0.00031622787f, | |
1980 0.00033677814f, 0.00035866388f, 0.00038197188f, 0.00040679456f, | |
1981 0.00043323036f, 0.00046138411f, 0.00049136745f, 0.00052329927f, | |
1982 0.00055730621f, 0.00059352311f, 0.00063209358f, 0.00067317058f, | |
1983 0.00071691700f, 0.00076350630f, 0.00081312324f, 0.00086596457f, | |
1984 0.00092223983f, 0.00098217216f, 0.0010459992f, 0.0011139742f, | |
1985 0.0011863665f, 0.0012634633f, 0.0013455702f, 0.0014330129f, | |
1986 0.0015261382f, 0.0016253153f, 0.0017309374f, 0.0018434235f, | |
1987 0.0019632195f, 0.0020908006f, 0.0022266726f, 0.0023713743f, | |
1988 0.0025254795f, 0.0026895994f, 0.0028643847f, 0.0030505286f, | |
1989 0.0032487691f, 0.0034598925f, 0.0036847358f, 0.0039241906f, | |
1990 0.0041792066f, 0.0044507950f, 0.0047400328f, 0.0050480668f, | |
1991 0.0053761186f, 0.0057254891f, 0.0060975636f, 0.0064938176f, | |
1992 0.0069158225f, 0.0073652516f, 0.0078438871f, 0.0083536271f, | |
1993 0.0088964928f, 0.009474637f, 0.010090352f, 0.010746080f, | |
1994 0.011444421f, 0.012188144f, 0.012980198f, 0.013823725f, | |
1995 0.014722068f, 0.015678791f, 0.016697687f, 0.017782797f, | |
1996 0.018938423f, 0.020169149f, 0.021479854f, 0.022875735f, | |
1997 0.024362330f, 0.025945531f, 0.027631618f, 0.029427276f, | |
1998 0.031339626f, 0.033376252f, 0.035545228f, 0.037855157f, | |
1999 0.040315199f, 0.042935108f, 0.045725273f, 0.048696758f, | |
2000 0.051861348f, 0.055231591f, 0.058820850f, 0.062643361f, | |
2001 0.066714279f, 0.071049749f, 0.075666962f, 0.080584227f, | |
2002 0.085821044f, 0.091398179f, 0.097337747f, 0.10366330f, | |
2003 0.11039993f, 0.11757434f, 0.12521498f, 0.13335215f, | |
2004 0.14201813f, 0.15124727f, 0.16107617f, 0.17154380f, | |
2005 0.18269168f, 0.19456402f, 0.20720788f, 0.22067342f, | |
2006 0.23501402f, 0.25028656f, 0.26655159f, 0.28387361f, | |
2007 0.30232132f, 0.32196786f, 0.34289114f, 0.36517414f, | |
2008 0.38890521f, 0.41417847f, 0.44109412f, 0.46975890f, | |
2009 0.50028648f, 0.53279791f, 0.56742212f, 0.60429640f, | |
2010 0.64356699f, 0.68538959f, 0.72993007f, 0.77736504f, | |
2011 0.82788260f, 0.88168307f, 0.9389798f, 1.0f | |
2012 }; | |
2013 | |
2014 | |
2015 // @OPTIMIZE: if you want to replace this bresenham line-drawing routine, | |
2016 // note that you must produce bit-identical output to decode correctly; | |
2017 // this specific sequence of operations is specified in the spec (it's | |
2018 // drawing integer-quantized frequency-space lines that the encoder | |
2019 // expects to be exactly the same) | |
2020 // ... also, isn't the whole point of Bresenham's algorithm to NOT | |
2021 // have to divide in the setup? sigh. | |
2022 #ifndef STB_VORBIS_NO_DEFER_FLOOR | |
2023 #define LINE_OP(a,b) a *= b | |
2024 #else | |
2025 #define LINE_OP(a,b) a = b | |
2026 #endif | |
2027 | |
2028 #ifdef STB_VORBIS_DIVIDE_TABLE | |
2029 #define DIVTAB_NUMER 32 | |
2030 #define DIVTAB_DENOM 64 | |
2031 int8 integer_divide_table[DIVTAB_NUMER][DIVTAB_DENOM]; // 2KB | |
2032 #endif | |
2033 | |
2034 static __forceinline void draw_line(float *output, int x0, int y0, int x1, int y1, int n) | |
2035 { | |
2036 int dy = y1 - y0; | |
2037 int adx = x1 - x0; | |
2038 int ady = abs(dy); | |
2039 int base; | |
2040 int x=x0,y=y0; | |
2041 int err = 0; | |
2042 int sy; | |
2043 | |
2044 #ifdef STB_VORBIS_DIVIDE_TABLE | |
2045 if (adx < DIVTAB_DENOM && ady < DIVTAB_NUMER) { | |
2046 if (dy < 0) { | |
2047 base = -integer_divide_table[ady][adx]; | |
2048 sy = base-1; | |
2049 } else { | |
2050 base = integer_divide_table[ady][adx]; | |
2051 sy = base+1; | |
2052 } | |
2053 } else { | |
2054 base = dy / adx; | |
2055 if (dy < 0) | |
2056 sy = base - 1; | |
2057 else | |
2058 sy = base+1; | |
2059 } | |
2060 #else | |
2061 base = dy / adx; | |
2062 if (dy < 0) | |
2063 sy = base - 1; | |
2064 else | |
2065 sy = base+1; | |
2066 #endif | |
2067 ady -= abs(base) * adx; | |
2068 if (x1 > n) x1 = n; | |
2069 if (x < x1) { | |
2070 LINE_OP(output[x], inverse_db_table[y&255]); | |
2071 for (++x; x < x1; ++x) { | |
2072 err += ady; | |
2073 if (err >= adx) { | |
2074 err -= adx; | |
2075 y += sy; | |
2076 } else | |
2077 y += base; | |
2078 LINE_OP(output[x], inverse_db_table[y&255]); | |
2079 } | |
2080 } | |
2081 } | |
2082 | |
2083 static int residue_decode(vorb *f, Codebook *book, float *target, int offset, int n, int rtype) | |
2084 { | |
2085 int k; | |
2086 if (rtype == 0) { | |
2087 int step = n / book->dimensions; | |
2088 for (k=0; k < step; ++k) | |
2089 if (!codebook_decode_step(f, book, target+offset+k, n-offset-k, step)) | |
2090 return FALSE; | |
2091 } else { | |
2092 for (k=0; k < n; ) { | |
2093 if (!codebook_decode(f, book, target+offset, n-k)) | |
2094 return FALSE; | |
2095 k += book->dimensions; | |
2096 offset += book->dimensions; | |
2097 } | |
2098 } | |
2099 return TRUE; | |
2100 } | |
2101 | |
2102 // n is 1/2 of the blocksize -- | |
2103 // specification: "Correct per-vector decode length is [n]/2" | |
2104 static void decode_residue(vorb *f, float *residue_buffers[], int ch, int n, int rn, uint8 *do_not_decode) | |
2105 { | |
2106 int i,j,pass; | |
2107 Residue *r = f->residue_config + rn; | |
2108 int rtype = f->residue_types[rn]; | |
2109 int c = r->classbook; | |
2110 int classwords = f->codebooks[c].dimensions; | |
2111 unsigned int actual_size = rtype == 2 ? n*2 : n; | |
2112 unsigned int limit_r_begin = (r->begin < actual_size ? r->begin : actual_size); | |
2113 unsigned int limit_r_end = (r->end < actual_size ? r->end : actual_size); | |
2114 int n_read = limit_r_end - limit_r_begin; | |
2115 int part_read = n_read / r->part_size; | |
2116 int temp_alloc_point = temp_alloc_save(f); | |
2117 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2118 uint8 ***part_classdata = (uint8 ***) temp_block_array(f,f->channels, part_read * sizeof(**part_classdata)); | |
2119 #else | |
2120 int **classifications = (int **) temp_block_array(f,f->channels, part_read * sizeof(**classifications)); | |
2121 #endif | |
2122 | |
2123 CHECK(f); | |
2124 | |
2125 for (i=0; i < ch; ++i) | |
2126 if (!do_not_decode[i]) | |
2127 memset(residue_buffers[i], 0, sizeof(float) * n); | |
2128 | |
2129 if (rtype == 2 && ch != 1) { | |
2130 for (j=0; j < ch; ++j) | |
2131 if (!do_not_decode[j]) | |
2132 break; | |
2133 if (j == ch) | |
2134 goto done; | |
2135 | |
2136 for (pass=0; pass < 8; ++pass) { | |
2137 int pcount = 0, class_set = 0; | |
2138 if (ch == 2) { | |
2139 while (pcount < part_read) { | |
2140 int z = r->begin + pcount*r->part_size; | |
2141 int c_inter = (z & 1), p_inter = z>>1; | |
2142 if (pass == 0) { | |
2143 Codebook *c = f->codebooks+r->classbook; | |
2144 int q; | |
2145 DECODE(q,f,c); | |
2146 if (q == EOP) goto done; | |
2147 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2148 part_classdata[0][class_set] = r->classdata[q]; | |
2149 #else | |
2150 for (i=classwords-1; i >= 0; --i) { | |
2151 classifications[0][i+pcount] = q % r->classifications; | |
2152 q /= r->classifications; | |
2153 } | |
2154 #endif | |
2155 } | |
2156 for (i=0; i < classwords && pcount < part_read; ++i, ++pcount) { | |
2157 int z = r->begin + pcount*r->part_size; | |
2158 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2159 int c = part_classdata[0][class_set][i]; | |
2160 #else | |
2161 int c = classifications[0][pcount]; | |
2162 #endif | |
2163 int b = r->residue_books[c][pass]; | |
2164 if (b >= 0) { | |
2165 Codebook *book = f->codebooks + b; | |
2166 #ifdef STB_VORBIS_DIVIDES_IN_CODEBOOK | |
2167 if (!codebook_decode_deinterleave_repeat(f, book, residue_buffers, ch, &c_inter, &p_inter, n, r->part_size)) | |
2168 goto done; | |
2169 #else | |
2170 // saves 1% | |
2171 if (!codebook_decode_deinterleave_repeat(f, book, residue_buffers, ch, &c_inter, &p_inter, n, r->part_size)) | |
2172 goto done; | |
2173 #endif | |
2174 } else { | |
2175 z += r->part_size; | |
2176 c_inter = z & 1; | |
2177 p_inter = z >> 1; | |
2178 } | |
2179 } | |
2180 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2181 ++class_set; | |
2182 #endif | |
2183 } | |
2184 } else if (ch > 2) { | |
2185 while (pcount < part_read) { | |
2186 int z = r->begin + pcount*r->part_size; | |
2187 int c_inter = z % ch, p_inter = z/ch; | |
2188 if (pass == 0) { | |
2189 Codebook *c = f->codebooks+r->classbook; | |
2190 int q; | |
2191 DECODE(q,f,c); | |
2192 if (q == EOP) goto done; | |
2193 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2194 part_classdata[0][class_set] = r->classdata[q]; | |
2195 #else | |
2196 for (i=classwords-1; i >= 0; --i) { | |
2197 classifications[0][i+pcount] = q % r->classifications; | |
2198 q /= r->classifications; | |
2199 } | |
2200 #endif | |
2201 } | |
2202 for (i=0; i < classwords && pcount < part_read; ++i, ++pcount) { | |
2203 int z = r->begin + pcount*r->part_size; | |
2204 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2205 int c = part_classdata[0][class_set][i]; | |
2206 #else | |
2207 int c = classifications[0][pcount]; | |
2208 #endif | |
2209 int b = r->residue_books[c][pass]; | |
2210 if (b >= 0) { | |
2211 Codebook *book = f->codebooks + b; | |
2212 if (!codebook_decode_deinterleave_repeat(f, book, residue_buffers, ch, &c_inter, &p_inter, n, r->part_size)) | |
2213 goto done; | |
2214 } else { | |
2215 z += r->part_size; | |
2216 c_inter = z % ch; | |
2217 p_inter = z / ch; | |
2218 } | |
2219 } | |
2220 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2221 ++class_set; | |
2222 #endif | |
2223 } | |
2224 } | |
2225 } | |
2226 goto done; | |
2227 } | |
2228 CHECK(f); | |
2229 | |
2230 for (pass=0; pass < 8; ++pass) { | |
2231 int pcount = 0, class_set=0; | |
2232 while (pcount < part_read) { | |
2233 if (pass == 0) { | |
2234 for (j=0; j < ch; ++j) { | |
2235 if (!do_not_decode[j]) { | |
2236 Codebook *c = f->codebooks+r->classbook; | |
2237 int temp; | |
2238 DECODE(temp,f,c); | |
2239 if (temp == EOP) goto done; | |
2240 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2241 part_classdata[j][class_set] = r->classdata[temp]; | |
2242 #else | |
2243 for (i=classwords-1; i >= 0; --i) { | |
2244 classifications[j][i+pcount] = temp % r->classifications; | |
2245 temp /= r->classifications; | |
2246 } | |
2247 #endif | |
2248 } | |
2249 } | |
2250 } | |
2251 for (i=0; i < classwords && pcount < part_read; ++i, ++pcount) { | |
2252 for (j=0; j < ch; ++j) { | |
2253 if (!do_not_decode[j]) { | |
2254 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2255 int c = part_classdata[j][class_set][i]; | |
2256 #else | |
2257 int c = classifications[j][pcount]; | |
2258 #endif | |
2259 int b = r->residue_books[c][pass]; | |
2260 if (b >= 0) { | |
2261 float *target = residue_buffers[j]; | |
2262 int offset = r->begin + pcount * r->part_size; | |
2263 int n = r->part_size; | |
2264 Codebook *book = f->codebooks + b; | |
2265 if (!residue_decode(f, book, target, offset, n, rtype)) | |
2266 goto done; | |
2267 } | |
2268 } | |
2269 } | |
2270 } | |
2271 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2272 ++class_set; | |
2273 #endif | |
2274 } | |
2275 } | |
2276 done: | |
2277 CHECK(f); | |
2278 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
2279 temp_free(f,part_classdata); | |
2280 #else | |
2281 temp_free(f,classifications); | |
2282 #endif | |
2283 temp_alloc_restore(f,temp_alloc_point); | |
2284 } | |
2285 | |
2286 | |
2287 #if 0 | |
2288 // slow way for debugging | |
2289 void inverse_mdct_slow(float *buffer, int n) | |
2290 { | |
2291 int i,j; | |
2292 int n2 = n >> 1; | |
2293 float *x = (float *) malloc(sizeof(*x) * n2); | |
2294 memcpy(x, buffer, sizeof(*x) * n2); | |
2295 for (i=0; i < n; ++i) { | |
2296 float acc = 0; | |
2297 for (j=0; j < n2; ++j) | |
2298 // formula from paper: | |
2299 //acc += n/4.0f * x[j] * (float) cos(M_PI / 2 / n * (2 * i + 1 + n/2.0)*(2*j+1)); | |
2300 // formula from wikipedia | |
2301 //acc += 2.0f / n2 * x[j] * (float) cos(M_PI/n2 * (i + 0.5 + n2/2)*(j + 0.5)); | |
2302 // these are equivalent, except the formula from the paper inverts the multiplier! | |
2303 // however, what actually works is NO MULTIPLIER!?! | |
2304 //acc += 64 * 2.0f / n2 * x[j] * (float) cos(M_PI/n2 * (i + 0.5 + n2/2)*(j + 0.5)); | |
2305 acc += x[j] * (float) cos(M_PI / 2 / n * (2 * i + 1 + n/2.0)*(2*j+1)); | |
2306 buffer[i] = acc; | |
2307 } | |
2308 free(x); | |
2309 } | |
2310 #elif 0 | |
2311 // same as above, but just barely able to run in real time on modern machines | |
2312 void inverse_mdct_slow(float *buffer, int n, vorb *f, int blocktype) | |
2313 { | |
2314 float mcos[16384]; | |
2315 int i,j; | |
2316 int n2 = n >> 1, nmask = (n << 2) -1; | |
2317 float *x = (float *) malloc(sizeof(*x) * n2); | |
2318 memcpy(x, buffer, sizeof(*x) * n2); | |
2319 for (i=0; i < 4*n; ++i) | |
2320 mcos[i] = (float) cos(M_PI / 2 * i / n); | |
2321 | |
2322 for (i=0; i < n; ++i) { | |
2323 float acc = 0; | |
2324 for (j=0; j < n2; ++j) | |
2325 acc += x[j] * mcos[(2 * i + 1 + n2)*(2*j+1) & nmask]; | |
2326 buffer[i] = acc; | |
2327 } | |
2328 free(x); | |
2329 } | |
2330 #elif 0 | |
2331 // transform to use a slow dct-iv; this is STILL basically trivial, | |
2332 // but only requires half as many ops | |
2333 void dct_iv_slow(float *buffer, int n) | |
2334 { | |
2335 float mcos[16384]; | |
2336 float x[2048]; | |
2337 int i,j; | |
2338 int n2 = n >> 1, nmask = (n << 3) - 1; | |
2339 memcpy(x, buffer, sizeof(*x) * n); | |
2340 for (i=0; i < 8*n; ++i) | |
2341 mcos[i] = (float) cos(M_PI / 4 * i / n); | |
2342 for (i=0; i < n; ++i) { | |
2343 float acc = 0; | |
2344 for (j=0; j < n; ++j) | |
2345 acc += x[j] * mcos[((2 * i + 1)*(2*j+1)) & nmask]; | |
2346 buffer[i] = acc; | |
2347 } | |
2348 } | |
2349 | |
2350 void inverse_mdct_slow(float *buffer, int n, vorb *f, int blocktype) | |
2351 { | |
2352 int i, n4 = n >> 2, n2 = n >> 1, n3_4 = n - n4; | |
2353 float temp[4096]; | |
2354 | |
2355 memcpy(temp, buffer, n2 * sizeof(float)); | |
2356 dct_iv_slow(temp, n2); // returns -c'-d, a-b' | |
2357 | |
2358 for (i=0; i < n4 ; ++i) buffer[i] = temp[i+n4]; // a-b' | |
2359 for ( ; i < n3_4; ++i) buffer[i] = -temp[n3_4 - i - 1]; // b-a', c+d' | |
2360 for ( ; i < n ; ++i) buffer[i] = -temp[i - n3_4]; // c'+d | |
2361 } | |
2362 #endif | |
2363 | |
2364 #ifndef LIBVORBIS_MDCT | |
2365 #define LIBVORBIS_MDCT 0 | |
2366 #endif | |
2367 | |
2368 #if LIBVORBIS_MDCT | |
2369 // directly call the vorbis MDCT using an interface documented | |
2370 // by Jeff Roberts... useful for performance comparison | |
2371 typedef struct | |
2372 { | |
2373 int n; | |
2374 int log2n; | |
2375 | |
2376 float *trig; | |
2377 int *bitrev; | |
2378 | |
2379 float scale; | |
2380 } mdct_lookup; | |
2381 | |
2382 extern void mdct_init(mdct_lookup *lookup, int n); | |
2383 extern void mdct_clear(mdct_lookup *l); | |
2384 extern void mdct_backward(mdct_lookup *init, float *in, float *out); | |
2385 | |
2386 mdct_lookup M1,M2; | |
2387 | |
2388 void inverse_mdct(float *buffer, int n, vorb *f, int blocktype) | |
2389 { | |
2390 mdct_lookup *M; | |
2391 if (M1.n == n) M = &M1; | |
2392 else if (M2.n == n) M = &M2; | |
2393 else if (M1.n == 0) { mdct_init(&M1, n); M = &M1; } | |
2394 else { | |
2395 if (M2.n) __asm int 3; | |
2396 mdct_init(&M2, n); | |
2397 M = &M2; | |
2398 } | |
2399 | |
2400 mdct_backward(M, buffer, buffer); | |
2401 } | |
2402 #endif | |
2403 | |
2404 | |
2405 // the following were split out into separate functions while optimizing; | |
2406 // they could be pushed back up but eh. __forceinline showed no change; | |
2407 // they're probably already being inlined. | |
2408 static void imdct_step3_iter0_loop(int n, float *e, int i_off, int k_off, float *A) | |
2409 { | |
2410 float *ee0 = e + i_off; | |
2411 float *ee2 = ee0 + k_off; | |
2412 int i; | |
2413 | |
2414 assert((n & 3) == 0); | |
2415 for (i=(n>>2); i > 0; --i) { | |
2416 float k00_20, k01_21; | |
2417 k00_20 = ee0[ 0] - ee2[ 0]; | |
2418 k01_21 = ee0[-1] - ee2[-1]; | |
2419 ee0[ 0] += ee2[ 0];//ee0[ 0] = ee0[ 0] + ee2[ 0]; | |
2420 ee0[-1] += ee2[-1];//ee0[-1] = ee0[-1] + ee2[-1]; | |
2421 ee2[ 0] = k00_20 * A[0] - k01_21 * A[1]; | |
2422 ee2[-1] = k01_21 * A[0] + k00_20 * A[1]; | |
2423 A += 8; | |
2424 | |
2425 k00_20 = ee0[-2] - ee2[-2]; | |
2426 k01_21 = ee0[-3] - ee2[-3]; | |
2427 ee0[-2] += ee2[-2];//ee0[-2] = ee0[-2] + ee2[-2]; | |
2428 ee0[-3] += ee2[-3];//ee0[-3] = ee0[-3] + ee2[-3]; | |
2429 ee2[-2] = k00_20 * A[0] - k01_21 * A[1]; | |
2430 ee2[-3] = k01_21 * A[0] + k00_20 * A[1]; | |
2431 A += 8; | |
2432 | |
2433 k00_20 = ee0[-4] - ee2[-4]; | |
2434 k01_21 = ee0[-5] - ee2[-5]; | |
2435 ee0[-4] += ee2[-4];//ee0[-4] = ee0[-4] + ee2[-4]; | |
2436 ee0[-5] += ee2[-5];//ee0[-5] = ee0[-5] + ee2[-5]; | |
2437 ee2[-4] = k00_20 * A[0] - k01_21 * A[1]; | |
2438 ee2[-5] = k01_21 * A[0] + k00_20 * A[1]; | |
2439 A += 8; | |
2440 | |
2441 k00_20 = ee0[-6] - ee2[-6]; | |
2442 k01_21 = ee0[-7] - ee2[-7]; | |
2443 ee0[-6] += ee2[-6];//ee0[-6] = ee0[-6] + ee2[-6]; | |
2444 ee0[-7] += ee2[-7];//ee0[-7] = ee0[-7] + ee2[-7]; | |
2445 ee2[-6] = k00_20 * A[0] - k01_21 * A[1]; | |
2446 ee2[-7] = k01_21 * A[0] + k00_20 * A[1]; | |
2447 A += 8; | |
2448 ee0 -= 8; | |
2449 ee2 -= 8; | |
2450 } | |
2451 } | |
2452 | |
2453 static void imdct_step3_inner_r_loop(int lim, float *e, int d0, int k_off, float *A, int k1) | |
2454 { | |
2455 int i; | |
2456 float k00_20, k01_21; | |
2457 | |
2458 float *e0 = e + d0; | |
2459 float *e2 = e0 + k_off; | |
2460 | |
2461 for (i=lim >> 2; i > 0; --i) { | |
2462 k00_20 = e0[-0] - e2[-0]; | |
2463 k01_21 = e0[-1] - e2[-1]; | |
2464 e0[-0] += e2[-0];//e0[-0] = e0[-0] + e2[-0]; | |
2465 e0[-1] += e2[-1];//e0[-1] = e0[-1] + e2[-1]; | |
2466 e2[-0] = (k00_20)*A[0] - (k01_21) * A[1]; | |
2467 e2[-1] = (k01_21)*A[0] + (k00_20) * A[1]; | |
2468 | |
2469 A += k1; | |
2470 | |
2471 k00_20 = e0[-2] - e2[-2]; | |
2472 k01_21 = e0[-3] - e2[-3]; | |
2473 e0[-2] += e2[-2];//e0[-2] = e0[-2] + e2[-2]; | |
2474 e0[-3] += e2[-3];//e0[-3] = e0[-3] + e2[-3]; | |
2475 e2[-2] = (k00_20)*A[0] - (k01_21) * A[1]; | |
2476 e2[-3] = (k01_21)*A[0] + (k00_20) * A[1]; | |
2477 | |
2478 A += k1; | |
2479 | |
2480 k00_20 = e0[-4] - e2[-4]; | |
2481 k01_21 = e0[-5] - e2[-5]; | |
2482 e0[-4] += e2[-4];//e0[-4] = e0[-4] + e2[-4]; | |
2483 e0[-5] += e2[-5];//e0[-5] = e0[-5] + e2[-5]; | |
2484 e2[-4] = (k00_20)*A[0] - (k01_21) * A[1]; | |
2485 e2[-5] = (k01_21)*A[0] + (k00_20) * A[1]; | |
2486 | |
2487 A += k1; | |
2488 | |
2489 k00_20 = e0[-6] - e2[-6]; | |
2490 k01_21 = e0[-7] - e2[-7]; | |
2491 e0[-6] += e2[-6];//e0[-6] = e0[-6] + e2[-6]; | |
2492 e0[-7] += e2[-7];//e0[-7] = e0[-7] + e2[-7]; | |
2493 e2[-6] = (k00_20)*A[0] - (k01_21) * A[1]; | |
2494 e2[-7] = (k01_21)*A[0] + (k00_20) * A[1]; | |
2495 | |
2496 e0 -= 8; | |
2497 e2 -= 8; | |
2498 | |
2499 A += k1; | |
2500 } | |
2501 } | |
2502 | |
2503 static void imdct_step3_inner_s_loop(int n, float *e, int i_off, int k_off, float *A, int a_off, int k0) | |
2504 { | |
2505 int i; | |
2506 float A0 = A[0]; | |
2507 float A1 = A[0+1]; | |
2508 float A2 = A[0+a_off]; | |
2509 float A3 = A[0+a_off+1]; | |
2510 float A4 = A[0+a_off*2+0]; | |
2511 float A5 = A[0+a_off*2+1]; | |
2512 float A6 = A[0+a_off*3+0]; | |
2513 float A7 = A[0+a_off*3+1]; | |
2514 | |
2515 float k00,k11; | |
2516 | |
2517 float *ee0 = e +i_off; | |
2518 float *ee2 = ee0+k_off; | |
2519 | |
2520 for (i=n; i > 0; --i) { | |
2521 k00 = ee0[ 0] - ee2[ 0]; | |
2522 k11 = ee0[-1] - ee2[-1]; | |
2523 ee0[ 0] = ee0[ 0] + ee2[ 0]; | |
2524 ee0[-1] = ee0[-1] + ee2[-1]; | |
2525 ee2[ 0] = (k00) * A0 - (k11) * A1; | |
2526 ee2[-1] = (k11) * A0 + (k00) * A1; | |
2527 | |
2528 k00 = ee0[-2] - ee2[-2]; | |
2529 k11 = ee0[-3] - ee2[-3]; | |
2530 ee0[-2] = ee0[-2] + ee2[-2]; | |
2531 ee0[-3] = ee0[-3] + ee2[-3]; | |
2532 ee2[-2] = (k00) * A2 - (k11) * A3; | |
2533 ee2[-3] = (k11) * A2 + (k00) * A3; | |
2534 | |
2535 k00 = ee0[-4] - ee2[-4]; | |
2536 k11 = ee0[-5] - ee2[-5]; | |
2537 ee0[-4] = ee0[-4] + ee2[-4]; | |
2538 ee0[-5] = ee0[-5] + ee2[-5]; | |
2539 ee2[-4] = (k00) * A4 - (k11) * A5; | |
2540 ee2[-5] = (k11) * A4 + (k00) * A5; | |
2541 | |
2542 k00 = ee0[-6] - ee2[-6]; | |
2543 k11 = ee0[-7] - ee2[-7]; | |
2544 ee0[-6] = ee0[-6] + ee2[-6]; | |
2545 ee0[-7] = ee0[-7] + ee2[-7]; | |
2546 ee2[-6] = (k00) * A6 - (k11) * A7; | |
2547 ee2[-7] = (k11) * A6 + (k00) * A7; | |
2548 | |
2549 ee0 -= k0; | |
2550 ee2 -= k0; | |
2551 } | |
2552 } | |
2553 | |
2554 static __forceinline void iter_54(float *z) | |
2555 { | |
2556 float k00,k11,k22,k33; | |
2557 float y0,y1,y2,y3; | |
2558 | |
2559 k00 = z[ 0] - z[-4]; | |
2560 y0 = z[ 0] + z[-4]; | |
2561 y2 = z[-2] + z[-6]; | |
2562 k22 = z[-2] - z[-6]; | |
2563 | |
2564 z[-0] = y0 + y2; // z0 + z4 + z2 + z6 | |
2565 z[-2] = y0 - y2; // z0 + z4 - z2 - z6 | |
2566 | |
2567 // done with y0,y2 | |
2568 | |
2569 k33 = z[-3] - z[-7]; | |
2570 | |
2571 z[-4] = k00 + k33; // z0 - z4 + z3 - z7 | |
2572 z[-6] = k00 - k33; // z0 - z4 - z3 + z7 | |
2573 | |
2574 // done with k33 | |
2575 | |
2576 k11 = z[-1] - z[-5]; | |
2577 y1 = z[-1] + z[-5]; | |
2578 y3 = z[-3] + z[-7]; | |
2579 | |
2580 z[-1] = y1 + y3; // z1 + z5 + z3 + z7 | |
2581 z[-3] = y1 - y3; // z1 + z5 - z3 - z7 | |
2582 z[-5] = k11 - k22; // z1 - z5 + z2 - z6 | |
2583 z[-7] = k11 + k22; // z1 - z5 - z2 + z6 | |
2584 } | |
2585 | |
2586 static void imdct_step3_inner_s_loop_ld654(int n, float *e, int i_off, float *A, int base_n) | |
2587 { | |
2588 int a_off = base_n >> 3; | |
2589 float A2 = A[0+a_off]; | |
2590 float *z = e + i_off; | |
2591 float *base = z - 16 * n; | |
2592 | |
2593 while (z > base) { | |
2594 float k00,k11; | |
2595 float l00,l11; | |
2596 | |
2597 k00 = z[-0] - z[ -8]; | |
2598 k11 = z[-1] - z[ -9]; | |
2599 l00 = z[-2] - z[-10]; | |
2600 l11 = z[-3] - z[-11]; | |
2601 z[ -0] = z[-0] + z[ -8]; | |
2602 z[ -1] = z[-1] + z[ -9]; | |
2603 z[ -2] = z[-2] + z[-10]; | |
2604 z[ -3] = z[-3] + z[-11]; | |
2605 z[ -8] = k00; | |
2606 z[ -9] = k11; | |
2607 z[-10] = (l00+l11) * A2; | |
2608 z[-11] = (l11-l00) * A2; | |
2609 | |
2610 k00 = z[ -4] - z[-12]; | |
2611 k11 = z[ -5] - z[-13]; | |
2612 l00 = z[ -6] - z[-14]; | |
2613 l11 = z[ -7] - z[-15]; | |
2614 z[ -4] = z[ -4] + z[-12]; | |
2615 z[ -5] = z[ -5] + z[-13]; | |
2616 z[ -6] = z[ -6] + z[-14]; | |
2617 z[ -7] = z[ -7] + z[-15]; | |
2618 z[-12] = k11; | |
2619 z[-13] = -k00; | |
2620 z[-14] = (l11-l00) * A2; | |
2621 z[-15] = (l00+l11) * -A2; | |
2622 | |
2623 iter_54(z); | |
2624 iter_54(z-8); | |
2625 z -= 16; | |
2626 } | |
2627 } | |
2628 | |
2629 static void inverse_mdct(float *buffer, int n, vorb *f, int blocktype) | |
2630 { | |
2631 int n2 = n >> 1, n4 = n >> 2, n8 = n >> 3, l; | |
2632 int ld; | |
2633 // @OPTIMIZE: reduce register pressure by using fewer variables? | |
2634 int save_point = temp_alloc_save(f); | |
2635 float *buf2 = (float *) temp_alloc(f, n2 * sizeof(*buf2)); | |
2636 float *u=NULL,*v=NULL; | |
2637 // twiddle factors | |
2638 float *A = f->A[blocktype]; | |
2639 | |
2640 // IMDCT algorithm from "The use of multirate filter banks for coding of high quality digital audio" | |
2641 // See notes about bugs in that paper in less-optimal implementation 'inverse_mdct_old' after this function. | |
2642 | |
2643 // kernel from paper | |
2644 | |
2645 | |
2646 // merged: | |
2647 // copy and reflect spectral data | |
2648 // step 0 | |
2649 | |
2650 // note that it turns out that the items added together during | |
2651 // this step are, in fact, being added to themselves (as reflected | |
2652 // by step 0). inexplicable inefficiency! this became obvious | |
2653 // once I combined the passes. | |
2654 | |
2655 // so there's a missing 'times 2' here (for adding X to itself). | |
2656 // this propagates through linearly to the end, where the numbers | |
2657 // are 1/2 too small, and need to be compensated for. | |
2658 | |
2659 { | |
2660 float *d,*e, *AA, *e_stop; | |
2661 d = &buf2[n2-2]; | |
2662 AA = A; | |
2663 e = &buffer[0]; | |
2664 e_stop = &buffer[n2]; | |
2665 while (e != e_stop) { | |
2666 d[1] = (e[0] * AA[0] - e[2]*AA[1]); | |
2667 d[0] = (e[0] * AA[1] + e[2]*AA[0]); | |
2668 d -= 2; | |
2669 AA += 2; | |
2670 e += 4; | |
2671 } | |
2672 | |
2673 e = &buffer[n2-3]; | |
2674 while (d >= buf2) { | |
2675 d[1] = (-e[2] * AA[0] - -e[0]*AA[1]); | |
2676 d[0] = (-e[2] * AA[1] + -e[0]*AA[0]); | |
2677 d -= 2; | |
2678 AA += 2; | |
2679 e -= 4; | |
2680 } | |
2681 } | |
2682 | |
2683 // now we use symbolic names for these, so that we can | |
2684 // possibly swap their meaning as we change which operations | |
2685 // are in place | |
2686 | |
2687 u = buffer; | |
2688 v = buf2; | |
2689 | |
2690 // step 2 (paper output is w, now u) | |
2691 // this could be in place, but the data ends up in the wrong | |
2692 // place... _somebody_'s got to swap it, so this is nominated | |
2693 { | |
2694 float *AA = &A[n2-8]; | |
2695 float *d0,*d1, *e0, *e1; | |
2696 | |
2697 e0 = &v[n4]; | |
2698 e1 = &v[0]; | |
2699 | |
2700 d0 = &u[n4]; | |
2701 d1 = &u[0]; | |
2702 | |
2703 while (AA >= A) { | |
2704 float v40_20, v41_21; | |
2705 | |
2706 v41_21 = e0[1] - e1[1]; | |
2707 v40_20 = e0[0] - e1[0]; | |
2708 d0[1] = e0[1] + e1[1]; | |
2709 d0[0] = e0[0] + e1[0]; | |
2710 d1[1] = v41_21*AA[4] - v40_20*AA[5]; | |
2711 d1[0] = v40_20*AA[4] + v41_21*AA[5]; | |
2712 | |
2713 v41_21 = e0[3] - e1[3]; | |
2714 v40_20 = e0[2] - e1[2]; | |
2715 d0[3] = e0[3] + e1[3]; | |
2716 d0[2] = e0[2] + e1[2]; | |
2717 d1[3] = v41_21*AA[0] - v40_20*AA[1]; | |
2718 d1[2] = v40_20*AA[0] + v41_21*AA[1]; | |
2719 | |
2720 AA -= 8; | |
2721 | |
2722 d0 += 4; | |
2723 d1 += 4; | |
2724 e0 += 4; | |
2725 e1 += 4; | |
2726 } | |
2727 } | |
2728 | |
2729 // step 3 | |
2730 ld = ilog(n) - 1; // ilog is off-by-one from normal definitions | |
2731 | |
2732 // optimized step 3: | |
2733 | |
2734 // the original step3 loop can be nested r inside s or s inside r; | |
2735 // it's written originally as s inside r, but this is dumb when r | |
2736 // iterates many times, and s few. So I have two copies of it and | |
2737 // switch between them halfway. | |
2738 | |
2739 // this is iteration 0 of step 3 | |
2740 imdct_step3_iter0_loop(n >> 4, u, n2-1-n4*0, -(n >> 3), A); | |
2741 imdct_step3_iter0_loop(n >> 4, u, n2-1-n4*1, -(n >> 3), A); | |
2742 | |
2743 // this is iteration 1 of step 3 | |
2744 imdct_step3_inner_r_loop(n >> 5, u, n2-1 - n8*0, -(n >> 4), A, 16); | |
2745 imdct_step3_inner_r_loop(n >> 5, u, n2-1 - n8*1, -(n >> 4), A, 16); | |
2746 imdct_step3_inner_r_loop(n >> 5, u, n2-1 - n8*2, -(n >> 4), A, 16); | |
2747 imdct_step3_inner_r_loop(n >> 5, u, n2-1 - n8*3, -(n >> 4), A, 16); | |
2748 | |
2749 l=2; | |
2750 for (; l < (ld-3)>>1; ++l) { | |
2751 int k0 = n >> (l+2), k0_2 = k0>>1; | |
2752 int lim = 1 << (l+1); | |
2753 int i; | |
2754 for (i=0; i < lim; ++i) | |
2755 imdct_step3_inner_r_loop(n >> (l+4), u, n2-1 - k0*i, -k0_2, A, 1 << (l+3)); | |
2756 } | |
2757 | |
2758 for (; l < ld-6; ++l) { | |
2759 int k0 = n >> (l+2), k1 = 1 << (l+3), k0_2 = k0>>1; | |
2760 int rlim = n >> (l+6), r; | |
2761 int lim = 1 << (l+1); | |
2762 int i_off; | |
2763 float *A0 = A; | |
2764 i_off = n2-1; | |
2765 for (r=rlim; r > 0; --r) { | |
2766 imdct_step3_inner_s_loop(lim, u, i_off, -k0_2, A0, k1, k0); | |
2767 A0 += k1*4; | |
2768 i_off -= 8; | |
2769 } | |
2770 } | |
2771 | |
2772 // iterations with count: | |
2773 // ld-6,-5,-4 all interleaved together | |
2774 // the big win comes from getting rid of needless flops | |
2775 // due to the constants on pass 5 & 4 being all 1 and 0; | |
2776 // combining them to be simultaneous to improve cache made little difference | |
2777 imdct_step3_inner_s_loop_ld654(n >> 5, u, n2-1, A, n); | |
2778 | |
2779 // output is u | |
2780 | |
2781 // step 4, 5, and 6 | |
2782 // cannot be in-place because of step 5 | |
2783 { | |
2784 uint16 *bitrev = f->bit_reverse[blocktype]; | |
2785 // weirdly, I'd have thought reading sequentially and writing | |
2786 // erratically would have been better than vice-versa, but in | |
2787 // fact that's not what my testing showed. (That is, with | |
2788 // j = bitreverse(i), do you read i and write j, or read j and write i.) | |
2789 | |
2790 float *d0 = &v[n4-4]; | |
2791 float *d1 = &v[n2-4]; | |
2792 while (d0 >= v) { | |
2793 int k4; | |
2794 | |
2795 k4 = bitrev[0]; | |
2796 d1[3] = u[k4+0]; | |
2797 d1[2] = u[k4+1]; | |
2798 d0[3] = u[k4+2]; | |
2799 d0[2] = u[k4+3]; | |
2800 | |
2801 k4 = bitrev[1]; | |
2802 d1[1] = u[k4+0]; | |
2803 d1[0] = u[k4+1]; | |
2804 d0[1] = u[k4+2]; | |
2805 d0[0] = u[k4+3]; | |
2806 | |
2807 d0 -= 4; | |
2808 d1 -= 4; | |
2809 bitrev += 2; | |
2810 } | |
2811 } | |
2812 // (paper output is u, now v) | |
2813 | |
2814 | |
2815 // data must be in buf2 | |
2816 assert(v == buf2); | |
2817 | |
2818 // step 7 (paper output is v, now v) | |
2819 // this is now in place | |
2820 { | |
2821 float *C = f->C[blocktype]; | |
2822 float *d, *e; | |
2823 | |
2824 d = v; | |
2825 e = v + n2 - 4; | |
2826 | |
2827 while (d < e) { | |
2828 float a02,a11,b0,b1,b2,b3; | |
2829 | |
2830 a02 = d[0] - e[2]; | |
2831 a11 = d[1] + e[3]; | |
2832 | |
2833 b0 = C[1]*a02 + C[0]*a11; | |
2834 b1 = C[1]*a11 - C[0]*a02; | |
2835 | |
2836 b2 = d[0] + e[ 2]; | |
2837 b3 = d[1] - e[ 3]; | |
2838 | |
2839 d[0] = b2 + b0; | |
2840 d[1] = b3 + b1; | |
2841 e[2] = b2 - b0; | |
2842 e[3] = b1 - b3; | |
2843 | |
2844 a02 = d[2] - e[0]; | |
2845 a11 = d[3] + e[1]; | |
2846 | |
2847 b0 = C[3]*a02 + C[2]*a11; | |
2848 b1 = C[3]*a11 - C[2]*a02; | |
2849 | |
2850 b2 = d[2] + e[ 0]; | |
2851 b3 = d[3] - e[ 1]; | |
2852 | |
2853 d[2] = b2 + b0; | |
2854 d[3] = b3 + b1; | |
2855 e[0] = b2 - b0; | |
2856 e[1] = b1 - b3; | |
2857 | |
2858 C += 4; | |
2859 d += 4; | |
2860 e -= 4; | |
2861 } | |
2862 } | |
2863 | |
2864 // data must be in buf2 | |
2865 | |
2866 | |
2867 // step 8+decode (paper output is X, now buffer) | |
2868 // this generates pairs of data a la 8 and pushes them directly through | |
2869 // the decode kernel (pushing rather than pulling) to avoid having | |
2870 // to make another pass later | |
2871 | |
2872 // this cannot POSSIBLY be in place, so we refer to the buffers directly | |
2873 | |
2874 { | |
2875 float *d0,*d1,*d2,*d3; | |
2876 | |
2877 float *B = f->B[blocktype] + n2 - 8; | |
2878 float *e = buf2 + n2 - 8; | |
2879 d0 = &buffer[0]; | |
2880 d1 = &buffer[n2-4]; | |
2881 d2 = &buffer[n2]; | |
2882 d3 = &buffer[n-4]; | |
2883 while (e >= v) { | |
2884 float p0,p1,p2,p3; | |
2885 | |
2886 p3 = e[6]*B[7] - e[7]*B[6]; | |
2887 p2 = -e[6]*B[6] - e[7]*B[7]; | |
2888 | |
2889 d0[0] = p3; | |
2890 d1[3] = - p3; | |
2891 d2[0] = p2; | |
2892 d3[3] = p2; | |
2893 | |
2894 p1 = e[4]*B[5] - e[5]*B[4]; | |
2895 p0 = -e[4]*B[4] - e[5]*B[5]; | |
2896 | |
2897 d0[1] = p1; | |
2898 d1[2] = - p1; | |
2899 d2[1] = p0; | |
2900 d3[2] = p0; | |
2901 | |
2902 p3 = e[2]*B[3] - e[3]*B[2]; | |
2903 p2 = -e[2]*B[2] - e[3]*B[3]; | |
2904 | |
2905 d0[2] = p3; | |
2906 d1[1] = - p3; | |
2907 d2[2] = p2; | |
2908 d3[1] = p2; | |
2909 | |
2910 p1 = e[0]*B[1] - e[1]*B[0]; | |
2911 p0 = -e[0]*B[0] - e[1]*B[1]; | |
2912 | |
2913 d0[3] = p1; | |
2914 d1[0] = - p1; | |
2915 d2[3] = p0; | |
2916 d3[0] = p0; | |
2917 | |
2918 B -= 8; | |
2919 e -= 8; | |
2920 d0 += 4; | |
2921 d2 += 4; | |
2922 d1 -= 4; | |
2923 d3 -= 4; | |
2924 } | |
2925 } | |
2926 | |
2927 temp_free(f,buf2); | |
2928 temp_alloc_restore(f,save_point); | |
2929 } | |
2930 | |
2931 #if 0 | |
2932 // this is the original version of the above code, if you want to optimize it from scratch | |
2933 void inverse_mdct_naive(float *buffer, int n) | |
2934 { | |
2935 float s; | |
2936 float A[1 << 12], B[1 << 12], C[1 << 11]; | |
2937 int i,k,k2,k4, n2 = n >> 1, n4 = n >> 2, n8 = n >> 3, l; | |
2938 int n3_4 = n - n4, ld; | |
2939 // how can they claim this only uses N words?! | |
2940 // oh, because they're only used sparsely, whoops | |
2941 float u[1 << 13], X[1 << 13], v[1 << 13], w[1 << 13]; | |
2942 // set up twiddle factors | |
2943 | |
2944 for (k=k2=0; k < n4; ++k,k2+=2) { | |
2945 A[k2 ] = (float) cos(4*k*M_PI/n); | |
2946 A[k2+1] = (float) -sin(4*k*M_PI/n); | |
2947 B[k2 ] = (float) cos((k2+1)*M_PI/n/2); | |
2948 B[k2+1] = (float) sin((k2+1)*M_PI/n/2); | |
2949 } | |
2950 for (k=k2=0; k < n8; ++k,k2+=2) { | |
2951 C[k2 ] = (float) cos(2*(k2+1)*M_PI/n); | |
2952 C[k2+1] = (float) -sin(2*(k2+1)*M_PI/n); | |
2953 } | |
2954 | |
2955 // IMDCT algorithm from "The use of multirate filter banks for coding of high quality digital audio" | |
2956 // Note there are bugs in that pseudocode, presumably due to them attempting | |
2957 // to rename the arrays nicely rather than representing the way their actual | |
2958 // implementation bounces buffers back and forth. As a result, even in the | |
2959 // "some formulars corrected" version, a direct implementation fails. These | |
2960 // are noted below as "paper bug". | |
2961 | |
2962 // copy and reflect spectral data | |
2963 for (k=0; k < n2; ++k) u[k] = buffer[k]; | |
2964 for ( ; k < n ; ++k) u[k] = -buffer[n - k - 1]; | |
2965 // kernel from paper | |
2966 // step 1 | |
2967 for (k=k2=k4=0; k < n4; k+=1, k2+=2, k4+=4) { | |
2968 v[n-k4-1] = (u[k4] - u[n-k4-1]) * A[k2] - (u[k4+2] - u[n-k4-3])*A[k2+1]; | |
2969 v[n-k4-3] = (u[k4] - u[n-k4-1]) * A[k2+1] + (u[k4+2] - u[n-k4-3])*A[k2]; | |
2970 } | |
2971 // step 2 | |
2972 for (k=k4=0; k < n8; k+=1, k4+=4) { | |
2973 w[n2+3+k4] = v[n2+3+k4] + v[k4+3]; | |
2974 w[n2+1+k4] = v[n2+1+k4] + v[k4+1]; | |
2975 w[k4+3] = (v[n2+3+k4] - v[k4+3])*A[n2-4-k4] - (v[n2+1+k4]-v[k4+1])*A[n2-3-k4]; | |
2976 w[k4+1] = (v[n2+1+k4] - v[k4+1])*A[n2-4-k4] + (v[n2+3+k4]-v[k4+3])*A[n2-3-k4]; | |
2977 } | |
2978 // step 3 | |
2979 ld = ilog(n) - 1; // ilog is off-by-one from normal definitions | |
2980 for (l=0; l < ld-3; ++l) { | |
2981 int k0 = n >> (l+2), k1 = 1 << (l+3); | |
2982 int rlim = n >> (l+4), r4, r; | |
2983 int s2lim = 1 << (l+2), s2; | |
2984 for (r=r4=0; r < rlim; r4+=4,++r) { | |
2985 for (s2=0; s2 < s2lim; s2+=2) { | |
2986 u[n-1-k0*s2-r4] = w[n-1-k0*s2-r4] + w[n-1-k0*(s2+1)-r4]; | |
2987 u[n-3-k0*s2-r4] = w[n-3-k0*s2-r4] + w[n-3-k0*(s2+1)-r4]; | |
2988 u[n-1-k0*(s2+1)-r4] = (w[n-1-k0*s2-r4] - w[n-1-k0*(s2+1)-r4]) * A[r*k1] | |
2989 - (w[n-3-k0*s2-r4] - w[n-3-k0*(s2+1)-r4]) * A[r*k1+1]; | |
2990 u[n-3-k0*(s2+1)-r4] = (w[n-3-k0*s2-r4] - w[n-3-k0*(s2+1)-r4]) * A[r*k1] | |
2991 + (w[n-1-k0*s2-r4] - w[n-1-k0*(s2+1)-r4]) * A[r*k1+1]; | |
2992 } | |
2993 } | |
2994 if (l+1 < ld-3) { | |
2995 // paper bug: ping-ponging of u&w here is omitted | |
2996 memcpy(w, u, sizeof(u)); | |
2997 } | |
2998 } | |
2999 | |
3000 // step 4 | |
3001 for (i=0; i < n8; ++i) { | |
3002 int j = bit_reverse(i) >> (32-ld+3); | |
3003 assert(j < n8); | |
3004 if (i == j) { | |
3005 // paper bug: original code probably swapped in place; if copying, | |
3006 // need to directly copy in this case | |
3007 int i8 = i << 3; | |
3008 v[i8+1] = u[i8+1]; | |
3009 v[i8+3] = u[i8+3]; | |
3010 v[i8+5] = u[i8+5]; | |
3011 v[i8+7] = u[i8+7]; | |
3012 } else if (i < j) { | |
3013 int i8 = i << 3, j8 = j << 3; | |
3014 v[j8+1] = u[i8+1], v[i8+1] = u[j8 + 1]; | |
3015 v[j8+3] = u[i8+3], v[i8+3] = u[j8 + 3]; | |
3016 v[j8+5] = u[i8+5], v[i8+5] = u[j8 + 5]; | |
3017 v[j8+7] = u[i8+7], v[i8+7] = u[j8 + 7]; | |
3018 } | |
3019 } | |
3020 // step 5 | |
3021 for (k=0; k < n2; ++k) { | |
3022 w[k] = v[k*2+1]; | |
3023 } | |
3024 // step 6 | |
3025 for (k=k2=k4=0; k < n8; ++k, k2 += 2, k4 += 4) { | |
3026 u[n-1-k2] = w[k4]; | |
3027 u[n-2-k2] = w[k4+1]; | |
3028 u[n3_4 - 1 - k2] = w[k4+2]; | |
3029 u[n3_4 - 2 - k2] = w[k4+3]; | |
3030 } | |
3031 // step 7 | |
3032 for (k=k2=0; k < n8; ++k, k2 += 2) { | |
3033 v[n2 + k2 ] = ( u[n2 + k2] + u[n-2-k2] + C[k2+1]*(u[n2+k2]-u[n-2-k2]) + C[k2]*(u[n2+k2+1]+u[n-2-k2+1]))/2; | |
3034 v[n-2 - k2] = ( u[n2 + k2] + u[n-2-k2] - C[k2+1]*(u[n2+k2]-u[n-2-k2]) - C[k2]*(u[n2+k2+1]+u[n-2-k2+1]))/2; | |
3035 v[n2+1+ k2] = ( u[n2+1+k2] - u[n-1-k2] + C[k2+1]*(u[n2+1+k2]+u[n-1-k2]) - C[k2]*(u[n2+k2]-u[n-2-k2]))/2; | |
3036 v[n-1 - k2] = (-u[n2+1+k2] + u[n-1-k2] + C[k2+1]*(u[n2+1+k2]+u[n-1-k2]) - C[k2]*(u[n2+k2]-u[n-2-k2]))/2; | |
3037 } | |
3038 // step 8 | |
3039 for (k=k2=0; k < n4; ++k,k2 += 2) { | |
3040 X[k] = v[k2+n2]*B[k2 ] + v[k2+1+n2]*B[k2+1]; | |
3041 X[n2-1-k] = v[k2+n2]*B[k2+1] - v[k2+1+n2]*B[k2 ]; | |
3042 } | |
3043 | |
3044 // decode kernel to output | |
3045 // determined the following value experimentally | |
3046 // (by first figuring out what made inverse_mdct_slow work); then matching that here | |
3047 // (probably vorbis encoder premultiplies by n or n/2, to save it on the decoder?) | |
3048 s = 0.5; // theoretically would be n4 | |
3049 | |
3050 // [[[ note! the s value of 0.5 is compensated for by the B[] in the current code, | |
3051 // so it needs to use the "old" B values to behave correctly, or else | |
3052 // set s to 1.0 ]]] | |
3053 for (i=0; i < n4 ; ++i) buffer[i] = s * X[i+n4]; | |
3054 for ( ; i < n3_4; ++i) buffer[i] = -s * X[n3_4 - i - 1]; | |
3055 for ( ; i < n ; ++i) buffer[i] = -s * X[i - n3_4]; | |
3056 } | |
3057 #endif | |
3058 | |
3059 static float *get_window(vorb *f, int len) | |
3060 { | |
3061 len <<= 1; | |
3062 if (len == f->blocksize_0) return f->window[0]; | |
3063 if (len == f->blocksize_1) return f->window[1]; | |
3064 return NULL; | |
3065 } | |
3066 | |
3067 #ifndef STB_VORBIS_NO_DEFER_FLOOR | |
3068 typedef int16 YTYPE; | |
3069 #else | |
3070 typedef int YTYPE; | |
3071 #endif | |
3072 static int do_floor(vorb *f, Mapping *map, int i, int n, float *target, YTYPE *finalY, uint8 *step2_flag) | |
3073 { | |
3074 int n2 = n >> 1; | |
3075 int s = map->chan[i].mux, floor; | |
3076 floor = map->submap_floor[s]; | |
3077 if (f->floor_types[floor] == 0) { | |
3078 return error(f, VORBIS_invalid_stream); | |
3079 } else { | |
3080 Floor1 *g = &f->floor_config[floor].floor1; | |
3081 int j,q; | |
3082 int lx = 0, ly = finalY[0] * g->floor1_multiplier; | |
3083 for (q=1; q < g->values; ++q) { | |
3084 j = g->sorted_order[q]; | |
3085 #ifndef STB_VORBIS_NO_DEFER_FLOOR | |
3086 STBV_NOTUSED(step2_flag); | |
3087 if (finalY[j] >= 0) | |
3088 #else | |
3089 if (step2_flag[j]) | |
3090 #endif | |
3091 { | |
3092 int hy = finalY[j] * g->floor1_multiplier; | |
3093 int hx = g->Xlist[j]; | |
3094 if (lx != hx) | |
3095 draw_line(target, lx,ly, hx,hy, n2); | |
3096 CHECK(f); | |
3097 lx = hx, ly = hy; | |
3098 } | |
3099 } | |
3100 if (lx < n2) { | |
3101 // optimization of: draw_line(target, lx,ly, n,ly, n2); | |
3102 for (j=lx; j < n2; ++j) | |
3103 LINE_OP(target[j], inverse_db_table[ly]); | |
3104 CHECK(f); | |
3105 } | |
3106 } | |
3107 return TRUE; | |
3108 } | |
3109 | |
3110 // The meaning of "left" and "right" | |
3111 // | |
3112 // For a given frame: | |
3113 // we compute samples from 0..n | |
3114 // window_center is n/2 | |
3115 // we'll window and mix the samples from left_start to left_end with data from the previous frame | |
3116 // all of the samples from left_end to right_start can be output without mixing; however, | |
3117 // this interval is 0-length except when transitioning between short and long frames | |
3118 // all of the samples from right_start to right_end need to be mixed with the next frame, | |
3119 // which we don't have, so those get saved in a buffer | |
3120 // frame N's right_end-right_start, the number of samples to mix with the next frame, | |
3121 // has to be the same as frame N+1's left_end-left_start (which they are by | |
3122 // construction) | |
3123 | |
3124 static int vorbis_decode_initial(vorb *f, int *p_left_start, int *p_left_end, int *p_right_start, int *p_right_end, int *mode) | |
3125 { | |
3126 Mode *m; | |
3127 int i, n, prev, next, window_center; | |
3128 f->channel_buffer_start = f->channel_buffer_end = 0; | |
3129 | |
3130 retry: | |
3131 if (f->eof) return FALSE; | |
3132 if (!maybe_start_packet(f)) | |
3133 return FALSE; | |
3134 // check packet type | |
3135 if (get_bits(f,1) != 0) { | |
3136 if (IS_PUSH_MODE(f)) | |
3137 return error(f,VORBIS_bad_packet_type); | |
3138 while (EOP != get8_packet(f)); | |
3139 goto retry; | |
3140 } | |
3141 | |
3142 if (f->alloc.alloc_buffer) | |
3143 assert(f->alloc.alloc_buffer_length_in_bytes == f->temp_offset); | |
3144 | |
3145 i = get_bits(f, ilog(f->mode_count-1)); | |
3146 if (i == EOP) return FALSE; | |
3147 if (i >= f->mode_count) return FALSE; | |
3148 *mode = i; | |
3149 m = f->mode_config + i; | |
3150 if (m->blockflag) { | |
3151 n = f->blocksize_1; | |
3152 prev = get_bits(f,1); | |
3153 next = get_bits(f,1); | |
3154 } else { | |
3155 prev = next = 0; | |
3156 n = f->blocksize_0; | |
3157 } | |
3158 | |
3159 // WINDOWING | |
3160 | |
3161 window_center = n >> 1; | |
3162 if (m->blockflag && !prev) { | |
3163 *p_left_start = (n - f->blocksize_0) >> 2; | |
3164 *p_left_end = (n + f->blocksize_0) >> 2; | |
3165 } else { | |
3166 *p_left_start = 0; | |
3167 *p_left_end = window_center; | |
3168 } | |
3169 if (m->blockflag && !next) { | |
3170 *p_right_start = (n*3 - f->blocksize_0) >> 2; | |
3171 *p_right_end = (n*3 + f->blocksize_0) >> 2; | |
3172 } else { | |
3173 *p_right_start = window_center; | |
3174 *p_right_end = n; | |
3175 } | |
3176 | |
3177 return TRUE; | |
3178 } | |
3179 | |
3180 static int vorbis_decode_packet_rest(vorb *f, int *len, Mode *m, int left_start, int left_end, int right_start, int right_end, int *p_left) | |
3181 { | |
3182 Mapping *map; | |
3183 int i,j,k,n,n2; | |
3184 int zero_channel[256]; | |
3185 int really_zero_channel[256]; | |
3186 | |
3187 // WINDOWING | |
3188 | |
3189 STBV_NOTUSED(left_end); | |
3190 n = f->blocksize[m->blockflag]; | |
3191 map = &f->mapping[m->mapping]; | |
3192 | |
3193 // FLOORS | |
3194 n2 = n >> 1; | |
3195 | |
3196 CHECK(f); | |
3197 | |
3198 for (i=0; i < f->channels; ++i) { | |
3199 int s = map->chan[i].mux, floor; | |
3200 zero_channel[i] = FALSE; | |
3201 floor = map->submap_floor[s]; | |
3202 if (f->floor_types[floor] == 0) { | |
3203 return error(f, VORBIS_invalid_stream); | |
3204 } else { | |
3205 Floor1 *g = &f->floor_config[floor].floor1; | |
3206 if (get_bits(f, 1)) { | |
3207 short *finalY; | |
3208 uint8 step2_flag[256]; | |
3209 static int range_list[4] = { 256, 128, 86, 64 }; | |
3210 int range = range_list[g->floor1_multiplier-1]; | |
3211 int offset = 2; | |
3212 finalY = f->finalY[i]; | |
3213 finalY[0] = get_bits(f, ilog(range)-1); | |
3214 finalY[1] = get_bits(f, ilog(range)-1); | |
3215 for (j=0; j < g->partitions; ++j) { | |
3216 int pclass = g->partition_class_list[j]; | |
3217 int cdim = g->class_dimensions[pclass]; | |
3218 int cbits = g->class_subclasses[pclass]; | |
3219 int csub = (1 << cbits)-1; | |
3220 int cval = 0; | |
3221 if (cbits) { | |
3222 Codebook *c = f->codebooks + g->class_masterbooks[pclass]; | |
3223 DECODE(cval,f,c); | |
3224 } | |
3225 for (k=0; k < cdim; ++k) { | |
3226 int book = g->subclass_books[pclass][cval & csub]; | |
3227 cval = cval >> cbits; | |
3228 if (book >= 0) { | |
3229 int temp; | |
3230 Codebook *c = f->codebooks + book; | |
3231 DECODE(temp,f,c); | |
3232 finalY[offset++] = temp; | |
3233 } else | |
3234 finalY[offset++] = 0; | |
3235 } | |
3236 } | |
3237 if (f->valid_bits == INVALID_BITS) goto error; // behavior according to spec | |
3238 step2_flag[0] = step2_flag[1] = 1; | |
3239 for (j=2; j < g->values; ++j) { | |
3240 int low, high, pred, highroom, lowroom, room, val; | |
3241 low = g->neighbors[j][0]; | |
3242 high = g->neighbors[j][1]; | |
3243 //neighbors(g->Xlist, j, &low, &high); | |
3244 pred = predict_point(g->Xlist[j], g->Xlist[low], g->Xlist[high], finalY[low], finalY[high]); | |
3245 val = finalY[j]; | |
3246 highroom = range - pred; | |
3247 lowroom = pred; | |
3248 if (highroom < lowroom) | |
3249 room = highroom * 2; | |
3250 else | |
3251 room = lowroom * 2; | |
3252 if (val) { | |
3253 step2_flag[low] = step2_flag[high] = 1; | |
3254 step2_flag[j] = 1; | |
3255 if (val >= room) | |
3256 if (highroom > lowroom) | |
3257 finalY[j] = val - lowroom + pred; | |
3258 else | |
3259 finalY[j] = pred - val + highroom - 1; | |
3260 else | |
3261 if (val & 1) | |
3262 finalY[j] = pred - ((val+1)>>1); | |
3263 else | |
3264 finalY[j] = pred + (val>>1); | |
3265 } else { | |
3266 step2_flag[j] = 0; | |
3267 finalY[j] = pred; | |
3268 } | |
3269 } | |
3270 | |
3271 #ifdef STB_VORBIS_NO_DEFER_FLOOR | |
3272 do_floor(f, map, i, n, f->floor_buffers[i], finalY, step2_flag); | |
3273 #else | |
3274 // defer final floor computation until _after_ residue | |
3275 for (j=0; j < g->values; ++j) { | |
3276 if (!step2_flag[j]) | |
3277 finalY[j] = -1; | |
3278 } | |
3279 #endif | |
3280 } else { | |
3281 error: | |
3282 zero_channel[i] = TRUE; | |
3283 } | |
3284 // So we just defer everything else to later | |
3285 | |
3286 // at this point we've decoded the floor into buffer | |
3287 } | |
3288 } | |
3289 CHECK(f); | |
3290 // at this point we've decoded all floors | |
3291 | |
3292 if (f->alloc.alloc_buffer) | |
3293 assert(f->alloc.alloc_buffer_length_in_bytes == f->temp_offset); | |
3294 | |
3295 // re-enable coupled channels if necessary | |
3296 memcpy(really_zero_channel, zero_channel, sizeof(really_zero_channel[0]) * f->channels); | |
3297 for (i=0; i < map->coupling_steps; ++i) | |
3298 if (!zero_channel[map->chan[i].magnitude] || !zero_channel[map->chan[i].angle]) { | |
3299 zero_channel[map->chan[i].magnitude] = zero_channel[map->chan[i].angle] = FALSE; | |
3300 } | |
3301 | |
3302 CHECK(f); | |
3303 // RESIDUE DECODE | |
3304 for (i=0; i < map->submaps; ++i) { | |
3305 float *residue_buffers[STB_VORBIS_MAX_CHANNELS]; | |
3306 int r; | |
3307 uint8 do_not_decode[256]; | |
3308 int ch = 0; | |
3309 for (j=0; j < f->channels; ++j) { | |
3310 if (map->chan[j].mux == i) { | |
3311 if (zero_channel[j]) { | |
3312 do_not_decode[ch] = TRUE; | |
3313 residue_buffers[ch] = NULL; | |
3314 } else { | |
3315 do_not_decode[ch] = FALSE; | |
3316 residue_buffers[ch] = f->channel_buffers[j]; | |
3317 } | |
3318 ++ch; | |
3319 } | |
3320 } | |
3321 r = map->submap_residue[i]; | |
3322 decode_residue(f, residue_buffers, ch, n2, r, do_not_decode); | |
3323 } | |
3324 | |
3325 if (f->alloc.alloc_buffer) | |
3326 assert(f->alloc.alloc_buffer_length_in_bytes == f->temp_offset); | |
3327 CHECK(f); | |
3328 | |
3329 // INVERSE COUPLING | |
3330 for (i = map->coupling_steps-1; i >= 0; --i) { | |
3331 int n2 = n >> 1; | |
3332 float *m = f->channel_buffers[map->chan[i].magnitude]; | |
3333 float *a = f->channel_buffers[map->chan[i].angle ]; | |
3334 for (j=0; j < n2; ++j) { | |
3335 float a2,m2; | |
3336 if (m[j] > 0) | |
3337 if (a[j] > 0) | |
3338 m2 = m[j], a2 = m[j] - a[j]; | |
3339 else | |
3340 a2 = m[j], m2 = m[j] + a[j]; | |
3341 else | |
3342 if (a[j] > 0) | |
3343 m2 = m[j], a2 = m[j] + a[j]; | |
3344 else | |
3345 a2 = m[j], m2 = m[j] - a[j]; | |
3346 m[j] = m2; | |
3347 a[j] = a2; | |
3348 } | |
3349 } | |
3350 CHECK(f); | |
3351 | |
3352 // finish decoding the floors | |
3353 #ifndef STB_VORBIS_NO_DEFER_FLOOR | |
3354 for (i=0; i < f->channels; ++i) { | |
3355 if (really_zero_channel[i]) { | |
3356 memset(f->channel_buffers[i], 0, sizeof(*f->channel_buffers[i]) * n2); | |
3357 } else { | |
3358 do_floor(f, map, i, n, f->channel_buffers[i], f->finalY[i], NULL); | |
3359 } | |
3360 } | |
3361 #else | |
3362 for (i=0; i < f->channels; ++i) { | |
3363 if (really_zero_channel[i]) { | |
3364 memset(f->channel_buffers[i], 0, sizeof(*f->channel_buffers[i]) * n2); | |
3365 } else { | |
3366 for (j=0; j < n2; ++j) | |
3367 f->channel_buffers[i][j] *= f->floor_buffers[i][j]; | |
3368 } | |
3369 } | |
3370 #endif | |
3371 | |
3372 // INVERSE MDCT | |
3373 CHECK(f); | |
3374 for (i=0; i < f->channels; ++i) | |
3375 inverse_mdct(f->channel_buffers[i], n, f, m->blockflag); | |
3376 CHECK(f); | |
3377 | |
3378 // this shouldn't be necessary, unless we exited on an error | |
3379 // and want to flush to get to the next packet | |
3380 flush_packet(f); | |
3381 | |
3382 if (f->first_decode) { | |
3383 // assume we start so first non-discarded sample is sample 0 | |
3384 // this isn't to spec, but spec would require us to read ahead | |
3385 // and decode the size of all current frames--could be done, | |
3386 // but presumably it's not a commonly used feature | |
3387 f->current_loc = 0u - n2; // start of first frame is positioned for discard (NB this is an intentional unsigned overflow/wrap-around) | |
3388 // we might have to discard samples "from" the next frame too, | |
3389 // if we're lapping a large block then a small at the start? | |
3390 f->discard_samples_deferred = n - right_end; | |
3391 f->current_loc_valid = TRUE; | |
3392 f->first_decode = FALSE; | |
3393 } else if (f->discard_samples_deferred) { | |
3394 if (f->discard_samples_deferred >= right_start - left_start) { | |
3395 f->discard_samples_deferred -= (right_start - left_start); | |
3396 left_start = right_start; | |
3397 *p_left = left_start; | |
3398 } else { | |
3399 left_start += f->discard_samples_deferred; | |
3400 *p_left = left_start; | |
3401 f->discard_samples_deferred = 0; | |
3402 } | |
3403 } else if (f->previous_length == 0 && f->current_loc_valid) { | |
3404 // we're recovering from a seek... that means we're going to discard | |
3405 // the samples from this packet even though we know our position from | |
3406 // the last page header, so we need to update the position based on | |
3407 // the discarded samples here | |
3408 // but wait, the code below is going to add this in itself even | |
3409 // on a discard, so we don't need to do it here... | |
3410 } | |
3411 | |
3412 // check if we have ogg information about the sample # for this packet | |
3413 if (f->last_seg_which == f->end_seg_with_known_loc) { | |
3414 // if we have a valid current loc, and this is final: | |
3415 if (f->current_loc_valid && (f->page_flag & PAGEFLAG_last_page)) { | |
3416 uint32 current_end = f->known_loc_for_packet; | |
3417 // then let's infer the size of the (probably) short final frame | |
3418 if (current_end < f->current_loc + (right_end-left_start)) { | |
3419 if (current_end < f->current_loc) { | |
3420 // negative truncation, that's impossible! | |
3421 *len = 0; | |
3422 } else { | |
3423 *len = current_end - f->current_loc; | |
3424 } | |
3425 *len += left_start; // this doesn't seem right, but has no ill effect on my test files | |
3426 if (*len > right_end) *len = right_end; // this should never happen | |
3427 f->current_loc += *len; | |
3428 return TRUE; | |
3429 } | |
3430 } | |
3431 // otherwise, just set our sample loc | |
3432 // guess that the ogg granule pos refers to the _middle_ of the | |
3433 // last frame? | |
3434 // set f->current_loc to the position of left_start | |
3435 f->current_loc = f->known_loc_for_packet - (n2-left_start); | |
3436 f->current_loc_valid = TRUE; | |
3437 } | |
3438 if (f->current_loc_valid) | |
3439 f->current_loc += (right_start - left_start); | |
3440 | |
3441 if (f->alloc.alloc_buffer) | |
3442 assert(f->alloc.alloc_buffer_length_in_bytes == f->temp_offset); | |
3443 *len = right_end; // ignore samples after the window goes to 0 | |
3444 CHECK(f); | |
3445 | |
3446 return TRUE; | |
3447 } | |
3448 | |
3449 static int vorbis_decode_packet(vorb *f, int *len, int *p_left, int *p_right) | |
3450 { | |
3451 int mode, left_end, right_end; | |
3452 if (!vorbis_decode_initial(f, p_left, &left_end, p_right, &right_end, &mode)) return 0; | |
3453 return vorbis_decode_packet_rest(f, len, f->mode_config + mode, *p_left, left_end, *p_right, right_end, p_left); | |
3454 } | |
3455 | |
3456 static int vorbis_finish_frame(stb_vorbis *f, int len, int left, int right) | |
3457 { | |
3458 int prev,i,j; | |
3459 // we use right&left (the start of the right- and left-window sin()-regions) | |
3460 // to determine how much to return, rather than inferring from the rules | |
3461 // (same result, clearer code); 'left' indicates where our sin() window | |
3462 // starts, therefore where the previous window's right edge starts, and | |
3463 // therefore where to start mixing from the previous buffer. 'right' | |
3464 // indicates where our sin() ending-window starts, therefore that's where | |
3465 // we start saving, and where our returned-data ends. | |
3466 | |
3467 // mixin from previous window | |
3468 if (f->previous_length) { | |
3469 int i,j, n = f->previous_length; | |
3470 float *w = get_window(f, n); | |
3471 if (w == NULL) return 0; | |
3472 for (i=0; i < f->channels; ++i) { | |
3473 for (j=0; j < n; ++j) | |
3474 f->channel_buffers[i][left+j] = | |
3475 f->channel_buffers[i][left+j]*w[ j] + | |
3476 f->previous_window[i][ j]*w[n-1-j]; | |
3477 } | |
3478 } | |
3479 | |
3480 prev = f->previous_length; | |
3481 | |
3482 // last half of this data becomes previous window | |
3483 f->previous_length = len - right; | |
3484 | |
3485 // @OPTIMIZE: could avoid this copy by double-buffering the | |
3486 // output (flipping previous_window with channel_buffers), but | |
3487 // then previous_window would have to be 2x as large, and | |
3488 // channel_buffers couldn't be temp mem (although they're NOT | |
3489 // currently temp mem, they could be (unless we want to level | |
3490 // performance by spreading out the computation)) | |
3491 for (i=0; i < f->channels; ++i) | |
3492 for (j=0; right+j < len; ++j) | |
3493 f->previous_window[i][j] = f->channel_buffers[i][right+j]; | |
3494 | |
3495 if (!prev) | |
3496 // there was no previous packet, so this data isn't valid... | |
3497 // this isn't entirely true, only the would-have-overlapped data | |
3498 // isn't valid, but this seems to be what the spec requires | |
3499 return 0; | |
3500 | |
3501 // truncate a short frame | |
3502 if (len < right) right = len; | |
3503 | |
3504 f->samples_output += right-left; | |
3505 | |
3506 return right - left; | |
3507 } | |
3508 | |
3509 static int vorbis_pump_first_frame(stb_vorbis *f) | |
3510 { | |
3511 int len, right, left, res; | |
3512 res = vorbis_decode_packet(f, &len, &left, &right); | |
3513 if (res) | |
3514 vorbis_finish_frame(f, len, left, right); | |
3515 return res; | |
3516 } | |
3517 | |
3518 #ifndef STB_VORBIS_NO_PUSHDATA_API | |
3519 static int is_whole_packet_present(stb_vorbis *f) | |
3520 { | |
3521 // make sure that we have the packet available before continuing... | |
3522 // this requires a full ogg parse, but we know we can fetch from f->stream | |
3523 | |
3524 // instead of coding this out explicitly, we could save the current read state, | |
3525 // read the next packet with get8() until end-of-packet, check f->eof, then | |
3526 // reset the state? but that would be slower, esp. since we'd have over 256 bytes | |
3527 // of state to restore (primarily the page segment table) | |
3528 | |
3529 int s = f->next_seg, first = TRUE; | |
3530 uint8 *p = f->stream; | |
3531 | |
3532 if (s != -1) { // if we're not starting the packet with a 'continue on next page' flag | |
3533 for (; s < f->segment_count; ++s) { | |
3534 p += f->segments[s]; | |
3535 if (f->segments[s] < 255) // stop at first short segment | |
3536 break; | |
3537 } | |
3538 // either this continues, or it ends it... | |
3539 if (s == f->segment_count) | |
3540 s = -1; // set 'crosses page' flag | |
3541 if (p > f->stream_end) return error(f, VORBIS_need_more_data); | |
3542 first = FALSE; | |
3543 } | |
3544 for (; s == -1;) { | |
3545 uint8 *q; | |
3546 int n; | |
3547 | |
3548 // check that we have the page header ready | |
3549 if (p + 26 >= f->stream_end) return error(f, VORBIS_need_more_data); | |
3550 // validate the page | |
3551 if (memcmp(p, ogg_page_header, 4)) return error(f, VORBIS_invalid_stream); | |
3552 if (p[4] != 0) return error(f, VORBIS_invalid_stream); | |
3553 if (first) { // the first segment must NOT have 'continued_packet', later ones MUST | |
3554 if (f->previous_length) | |
3555 if ((p[5] & PAGEFLAG_continued_packet)) return error(f, VORBIS_invalid_stream); | |
3556 // if no previous length, we're resynching, so we can come in on a continued-packet, | |
3557 // which we'll just drop | |
3558 } else { | |
3559 if (!(p[5] & PAGEFLAG_continued_packet)) return error(f, VORBIS_invalid_stream); | |
3560 } | |
3561 n = p[26]; // segment counts | |
3562 q = p+27; // q points to segment table | |
3563 p = q + n; // advance past header | |
3564 // make sure we've read the segment table | |
3565 if (p > f->stream_end) return error(f, VORBIS_need_more_data); | |
3566 for (s=0; s < n; ++s) { | |
3567 p += q[s]; | |
3568 if (q[s] < 255) | |
3569 break; | |
3570 } | |
3571 if (s == n) | |
3572 s = -1; // set 'crosses page' flag | |
3573 if (p > f->stream_end) return error(f, VORBIS_need_more_data); | |
3574 first = FALSE; | |
3575 } | |
3576 return TRUE; | |
3577 } | |
3578 #endif // !STB_VORBIS_NO_PUSHDATA_API | |
3579 | |
3580 static int start_decoder(vorb *f) | |
3581 { | |
3582 uint8 header[6], x,y; | |
3583 int len,i,j,k, max_submaps = 0; | |
3584 int longest_floorlist=0; | |
3585 | |
3586 // first page, first packet | |
3587 f->first_decode = TRUE; | |
3588 | |
3589 if (!start_page(f)) return FALSE; | |
3590 // validate page flag | |
3591 if (!(f->page_flag & PAGEFLAG_first_page)) return error(f, VORBIS_invalid_first_page); | |
3592 if (f->page_flag & PAGEFLAG_last_page) return error(f, VORBIS_invalid_first_page); | |
3593 if (f->page_flag & PAGEFLAG_continued_packet) return error(f, VORBIS_invalid_first_page); | |
3594 // check for expected packet length | |
3595 if (f->segment_count != 1) return error(f, VORBIS_invalid_first_page); | |
3596 if (f->segments[0] != 30) { | |
3597 // check for the Ogg skeleton fishead identifying header to refine our error | |
3598 if (f->segments[0] == 64 && | |
3599 getn(f, header, 6) && | |
3600 header[0] == 'f' && | |
3601 header[1] == 'i' && | |
3602 header[2] == 's' && | |
3603 header[3] == 'h' && | |
3604 header[4] == 'e' && | |
3605 header[5] == 'a' && | |
3606 get8(f) == 'd' && | |
3607 get8(f) == '\0') return error(f, VORBIS_ogg_skeleton_not_supported); | |
3608 else | |
3609 return error(f, VORBIS_invalid_first_page); | |
3610 } | |
3611 | |
3612 // read packet | |
3613 // check packet header | |
3614 if (get8(f) != VORBIS_packet_id) return error(f, VORBIS_invalid_first_page); | |
3615 if (!getn(f, header, 6)) return error(f, VORBIS_unexpected_eof); | |
3616 if (!vorbis_validate(header)) return error(f, VORBIS_invalid_first_page); | |
3617 // vorbis_version | |
3618 if (get32(f) != 0) return error(f, VORBIS_invalid_first_page); | |
3619 f->channels = get8(f); if (!f->channels) return error(f, VORBIS_invalid_first_page); | |
3620 if (f->channels > STB_VORBIS_MAX_CHANNELS) return error(f, VORBIS_too_many_channels); | |
3621 f->sample_rate = get32(f); if (!f->sample_rate) return error(f, VORBIS_invalid_first_page); | |
3622 get32(f); // bitrate_maximum | |
3623 get32(f); // bitrate_nominal | |
3624 get32(f); // bitrate_minimum | |
3625 x = get8(f); | |
3626 { | |
3627 int log0,log1; | |
3628 log0 = x & 15; | |
3629 log1 = x >> 4; | |
3630 f->blocksize_0 = 1 << log0; | |
3631 f->blocksize_1 = 1 << log1; | |
3632 if (log0 < 6 || log0 > 13) return error(f, VORBIS_invalid_setup); | |
3633 if (log1 < 6 || log1 > 13) return error(f, VORBIS_invalid_setup); | |
3634 if (log0 > log1) return error(f, VORBIS_invalid_setup); | |
3635 } | |
3636 | |
3637 // framing_flag | |
3638 x = get8(f); | |
3639 if (!(x & 1)) return error(f, VORBIS_invalid_first_page); | |
3640 | |
3641 // second packet! | |
3642 if (!start_page(f)) return FALSE; | |
3643 | |
3644 if (!start_packet(f)) return FALSE; | |
3645 | |
3646 if (!next_segment(f)) return FALSE; | |
3647 | |
3648 if (get8_packet(f) != VORBIS_packet_comment) return error(f, VORBIS_invalid_setup); | |
3649 for (i=0; i < 6; ++i) header[i] = get8_packet(f); | |
3650 if (!vorbis_validate(header)) return error(f, VORBIS_invalid_setup); | |
3651 //file vendor | |
3652 len = get32_packet(f); | |
3653 f->vendor = (char*)setup_malloc(f, sizeof(char) * (len+1)); | |
3654 if (f->vendor == NULL) return error(f, VORBIS_outofmem); | |
3655 for(i=0; i < len; ++i) { | |
3656 f->vendor[i] = get8_packet(f); | |
3657 } | |
3658 f->vendor[len] = (char)'\0'; | |
3659 //user comments | |
3660 f->comment_list_length = get32_packet(f); | |
3661 f->comment_list = NULL; | |
3662 if (f->comment_list_length > 0) | |
3663 { | |
3664 f->comment_list = (char**) setup_malloc(f, sizeof(char*) * (f->comment_list_length)); | |
3665 if (f->comment_list == NULL) return error(f, VORBIS_outofmem); | |
3666 } | |
3667 | |
3668 for(i=0; i < f->comment_list_length; ++i) { | |
3669 len = get32_packet(f); | |
3670 f->comment_list[i] = (char*)setup_malloc(f, sizeof(char) * (len+1)); | |
3671 if (f->comment_list[i] == NULL) return error(f, VORBIS_outofmem); | |
3672 | |
3673 for(j=0; j < len; ++j) { | |
3674 f->comment_list[i][j] = get8_packet(f); | |
3675 } | |
3676 f->comment_list[i][len] = (char)'\0'; | |
3677 } | |
3678 | |
3679 // framing_flag | |
3680 x = get8_packet(f); | |
3681 if (!(x & 1)) return error(f, VORBIS_invalid_setup); | |
3682 | |
3683 | |
3684 skip(f, f->bytes_in_seg); | |
3685 f->bytes_in_seg = 0; | |
3686 | |
3687 do { | |
3688 len = next_segment(f); | |
3689 skip(f, len); | |
3690 f->bytes_in_seg = 0; | |
3691 } while (len); | |
3692 | |
3693 // third packet! | |
3694 if (!start_packet(f)) return FALSE; | |
3695 | |
3696 #ifndef STB_VORBIS_NO_PUSHDATA_API | |
3697 if (IS_PUSH_MODE(f)) { | |
3698 if (!is_whole_packet_present(f)) { | |
3699 // convert error in ogg header to write type | |
3700 if (f->error == VORBIS_invalid_stream) | |
3701 f->error = VORBIS_invalid_setup; | |
3702 return FALSE; | |
3703 } | |
3704 } | |
3705 #endif | |
3706 | |
3707 crc32_init(); // always init it, to avoid multithread race conditions | |
3708 | |
3709 if (get8_packet(f) != VORBIS_packet_setup) return error(f, VORBIS_invalid_setup); | |
3710 for (i=0; i < 6; ++i) header[i] = get8_packet(f); | |
3711 if (!vorbis_validate(header)) return error(f, VORBIS_invalid_setup); | |
3712 | |
3713 // codebooks | |
3714 | |
3715 f->codebook_count = get_bits(f,8) + 1; | |
3716 f->codebooks = (Codebook *) setup_malloc(f, sizeof(*f->codebooks) * f->codebook_count); | |
3717 if (f->codebooks == NULL) return error(f, VORBIS_outofmem); | |
3718 memset(f->codebooks, 0, sizeof(*f->codebooks) * f->codebook_count); | |
3719 for (i=0; i < f->codebook_count; ++i) { | |
3720 uint32 *values; | |
3721 int ordered, sorted_count; | |
3722 int total=0; | |
3723 uint8 *lengths; | |
3724 Codebook *c = f->codebooks+i; | |
3725 CHECK(f); | |
3726 x = get_bits(f, 8); if (x != 0x42) return error(f, VORBIS_invalid_setup); | |
3727 x = get_bits(f, 8); if (x != 0x43) return error(f, VORBIS_invalid_setup); | |
3728 x = get_bits(f, 8); if (x != 0x56) return error(f, VORBIS_invalid_setup); | |
3729 x = get_bits(f, 8); | |
3730 c->dimensions = (get_bits(f, 8)<<8) + x; | |
3731 x = get_bits(f, 8); | |
3732 y = get_bits(f, 8); | |
3733 c->entries = (get_bits(f, 8)<<16) + (y<<8) + x; | |
3734 ordered = get_bits(f,1); | |
3735 c->sparse = ordered ? 0 : get_bits(f,1); | |
3736 | |
3737 if (c->dimensions == 0 && c->entries != 0) return error(f, VORBIS_invalid_setup); | |
3738 | |
3739 if (c->sparse) | |
3740 lengths = (uint8 *) setup_temp_malloc(f, c->entries); | |
3741 else | |
3742 lengths = c->codeword_lengths = (uint8 *) setup_malloc(f, c->entries); | |
3743 | |
3744 if (!lengths) return error(f, VORBIS_outofmem); | |
3745 | |
3746 if (ordered) { | |
3747 int current_entry = 0; | |
3748 int current_length = get_bits(f,5) + 1; | |
3749 while (current_entry < c->entries) { | |
3750 int limit = c->entries - current_entry; | |
3751 int n = get_bits(f, ilog(limit)); | |
3752 if (current_length >= 32) return error(f, VORBIS_invalid_setup); | |
3753 if (current_entry + n > (int) c->entries) { return error(f, VORBIS_invalid_setup); } | |
3754 memset(lengths + current_entry, current_length, n); | |
3755 current_entry += n; | |
3756 ++current_length; | |
3757 } | |
3758 } else { | |
3759 for (j=0; j < c->entries; ++j) { | |
3760 int present = c->sparse ? get_bits(f,1) : 1; | |
3761 if (present) { | |
3762 lengths[j] = get_bits(f, 5) + 1; | |
3763 ++total; | |
3764 if (lengths[j] == 32) | |
3765 return error(f, VORBIS_invalid_setup); | |
3766 } else { | |
3767 lengths[j] = NO_CODE; | |
3768 } | |
3769 } | |
3770 } | |
3771 | |
3772 if (c->sparse && total >= c->entries >> 2) { | |
3773 // convert sparse items to non-sparse! | |
3774 if (c->entries > (int) f->setup_temp_memory_required) | |
3775 f->setup_temp_memory_required = c->entries; | |
3776 | |
3777 c->codeword_lengths = (uint8 *) setup_malloc(f, c->entries); | |
3778 if (c->codeword_lengths == NULL) return error(f, VORBIS_outofmem); | |
3779 memcpy(c->codeword_lengths, lengths, c->entries); | |
3780 setup_temp_free(f, lengths, c->entries); // note this is only safe if there have been no intervening temp mallocs! | |
3781 lengths = c->codeword_lengths; | |
3782 c->sparse = 0; | |
3783 } | |
3784 | |
3785 // compute the size of the sorted tables | |
3786 if (c->sparse) { | |
3787 sorted_count = total; | |
3788 } else { | |
3789 sorted_count = 0; | |
3790 #ifndef STB_VORBIS_NO_HUFFMAN_BINARY_SEARCH | |
3791 for (j=0; j < c->entries; ++j) | |
3792 if (lengths[j] > STB_VORBIS_FAST_HUFFMAN_LENGTH && lengths[j] != NO_CODE) | |
3793 ++sorted_count; | |
3794 #endif | |
3795 } | |
3796 | |
3797 c->sorted_entries = sorted_count; | |
3798 values = NULL; | |
3799 | |
3800 CHECK(f); | |
3801 if (!c->sparse) { | |
3802 c->codewords = (uint32 *) setup_malloc(f, sizeof(c->codewords[0]) * c->entries); | |
3803 if (!c->codewords) return error(f, VORBIS_outofmem); | |
3804 } else { | |
3805 unsigned int size; | |
3806 if (c->sorted_entries) { | |
3807 c->codeword_lengths = (uint8 *) setup_malloc(f, c->sorted_entries); | |
3808 if (!c->codeword_lengths) return error(f, VORBIS_outofmem); | |
3809 c->codewords = (uint32 *) setup_temp_malloc(f, sizeof(*c->codewords) * c->sorted_entries); | |
3810 if (!c->codewords) return error(f, VORBIS_outofmem); | |
3811 values = (uint32 *) setup_temp_malloc(f, sizeof(*values) * c->sorted_entries); | |
3812 if (!values) return error(f, VORBIS_outofmem); | |
3813 } | |
3814 size = c->entries + (sizeof(*c->codewords) + sizeof(*values)) * c->sorted_entries; | |
3815 if (size > f->setup_temp_memory_required) | |
3816 f->setup_temp_memory_required = size; | |
3817 } | |
3818 | |
3819 if (!compute_codewords(c, lengths, c->entries, values)) { | |
3820 if (c->sparse) setup_temp_free(f, values, 0); | |
3821 return error(f, VORBIS_invalid_setup); | |
3822 } | |
3823 | |
3824 if (c->sorted_entries) { | |
3825 // allocate an extra slot for sentinels | |
3826 c->sorted_codewords = (uint32 *) setup_malloc(f, sizeof(*c->sorted_codewords) * (c->sorted_entries+1)); | |
3827 if (c->sorted_codewords == NULL) return error(f, VORBIS_outofmem); | |
3828 // allocate an extra slot at the front so that c->sorted_values[-1] is defined | |
3829 // so that we can catch that case without an extra if | |
3830 c->sorted_values = ( int *) setup_malloc(f, sizeof(*c->sorted_values ) * (c->sorted_entries+1)); | |
3831 if (c->sorted_values == NULL) return error(f, VORBIS_outofmem); | |
3832 ++c->sorted_values; | |
3833 c->sorted_values[-1] = -1; | |
3834 compute_sorted_huffman(c, lengths, values); | |
3835 } | |
3836 | |
3837 if (c->sparse) { | |
3838 setup_temp_free(f, values, sizeof(*values)*c->sorted_entries); | |
3839 setup_temp_free(f, c->codewords, sizeof(*c->codewords)*c->sorted_entries); | |
3840 setup_temp_free(f, lengths, c->entries); | |
3841 c->codewords = NULL; | |
3842 } | |
3843 | |
3844 compute_accelerated_huffman(c); | |
3845 | |
3846 CHECK(f); | |
3847 c->lookup_type = get_bits(f, 4); | |
3848 if (c->lookup_type > 2) return error(f, VORBIS_invalid_setup); | |
3849 if (c->lookup_type > 0) { | |
3850 uint16 *mults; | |
3851 c->minimum_value = float32_unpack(get_bits(f, 32)); | |
3852 c->delta_value = float32_unpack(get_bits(f, 32)); | |
3853 c->value_bits = get_bits(f, 4)+1; | |
3854 c->sequence_p = get_bits(f,1); | |
3855 if (c->lookup_type == 1) { | |
3856 int values = lookup1_values(c->entries, c->dimensions); | |
3857 if (values < 0) return error(f, VORBIS_invalid_setup); | |
3858 c->lookup_values = (uint32) values; | |
3859 } else { | |
3860 c->lookup_values = c->entries * c->dimensions; | |
3861 } | |
3862 if (c->lookup_values == 0) return error(f, VORBIS_invalid_setup); | |
3863 mults = (uint16 *) setup_temp_malloc(f, sizeof(mults[0]) * c->lookup_values); | |
3864 if (mults == NULL) return error(f, VORBIS_outofmem); | |
3865 for (j=0; j < (int) c->lookup_values; ++j) { | |
3866 int q = get_bits(f, c->value_bits); | |
3867 if (q == EOP) { setup_temp_free(f,mults,sizeof(mults[0])*c->lookup_values); return error(f, VORBIS_invalid_setup); } | |
3868 mults[j] = q; | |
3869 } | |
3870 | |
3871 #ifndef STB_VORBIS_DIVIDES_IN_CODEBOOK | |
3872 if (c->lookup_type == 1) { | |
3873 int len, sparse = c->sparse; | |
3874 float last=0; | |
3875 // pre-expand the lookup1-style multiplicands, to avoid a divide in the inner loop | |
3876 if (sparse) { | |
3877 if (c->sorted_entries == 0) goto skip; | |
3878 c->multiplicands = (codetype *) setup_malloc(f, sizeof(c->multiplicands[0]) * c->sorted_entries * c->dimensions); | |
3879 } else | |
3880 c->multiplicands = (codetype *) setup_malloc(f, sizeof(c->multiplicands[0]) * c->entries * c->dimensions); | |
3881 if (c->multiplicands == NULL) { setup_temp_free(f,mults,sizeof(mults[0])*c->lookup_values); return error(f, VORBIS_outofmem); } | |
3882 len = sparse ? c->sorted_entries : c->entries; | |
3883 for (j=0; j < len; ++j) { | |
3884 unsigned int z = sparse ? c->sorted_values[j] : j; | |
3885 unsigned int div=1; | |
3886 for (k=0; k < c->dimensions; ++k) { | |
3887 int off = (z / div) % c->lookup_values; | |
3888 float val = mults[off]*c->delta_value + c->minimum_value + last; | |
3889 c->multiplicands[j*c->dimensions + k] = val; | |
3890 if (c->sequence_p) | |
3891 last = val; | |
3892 if (k+1 < c->dimensions) { | |
3893 if (div > UINT_MAX / (unsigned int) c->lookup_values) { | |
3894 setup_temp_free(f, mults,sizeof(mults[0])*c->lookup_values); | |
3895 return error(f, VORBIS_invalid_setup); | |
3896 } | |
3897 div *= c->lookup_values; | |
3898 } | |
3899 } | |
3900 } | |
3901 c->lookup_type = 2; | |
3902 } | |
3903 else | |
3904 #endif | |
3905 { | |
3906 float last=0; | |
3907 CHECK(f); | |
3908 c->multiplicands = (codetype *) setup_malloc(f, sizeof(c->multiplicands[0]) * c->lookup_values); | |
3909 if (c->multiplicands == NULL) { setup_temp_free(f, mults,sizeof(mults[0])*c->lookup_values); return error(f, VORBIS_outofmem); } | |
3910 for (j=0; j < (int) c->lookup_values; ++j) { | |
3911 float val = mults[j] * c->delta_value + c->minimum_value + last; | |
3912 c->multiplicands[j] = val; | |
3913 if (c->sequence_p) | |
3914 last = val; | |
3915 } | |
3916 } | |
3917 #ifndef STB_VORBIS_DIVIDES_IN_CODEBOOK | |
3918 skip:; | |
3919 #endif | |
3920 setup_temp_free(f, mults, sizeof(mults[0])*c->lookup_values); | |
3921 | |
3922 CHECK(f); | |
3923 } | |
3924 CHECK(f); | |
3925 } | |
3926 | |
3927 // time domain transfers (notused) | |
3928 | |
3929 x = get_bits(f, 6) + 1; | |
3930 for (i=0; i < x; ++i) { | |
3931 uint32 z = get_bits(f, 16); | |
3932 if (z != 0) return error(f, VORBIS_invalid_setup); | |
3933 } | |
3934 | |
3935 // Floors | |
3936 f->floor_count = get_bits(f, 6)+1; | |
3937 f->floor_config = (Floor *) setup_malloc(f, f->floor_count * sizeof(*f->floor_config)); | |
3938 if (f->floor_config == NULL) return error(f, VORBIS_outofmem); | |
3939 for (i=0; i < f->floor_count; ++i) { | |
3940 f->floor_types[i] = get_bits(f, 16); | |
3941 if (f->floor_types[i] > 1) return error(f, VORBIS_invalid_setup); | |
3942 if (f->floor_types[i] == 0) { | |
3943 Floor0 *g = &f->floor_config[i].floor0; | |
3944 g->order = get_bits(f,8); | |
3945 g->rate = get_bits(f,16); | |
3946 g->bark_map_size = get_bits(f,16); | |
3947 g->amplitude_bits = get_bits(f,6); | |
3948 g->amplitude_offset = get_bits(f,8); | |
3949 g->number_of_books = get_bits(f,4) + 1; | |
3950 for (j=0; j < g->number_of_books; ++j) | |
3951 g->book_list[j] = get_bits(f,8); | |
3952 return error(f, VORBIS_feature_not_supported); | |
3953 } else { | |
3954 stbv__floor_ordering p[31*8+2]; | |
3955 Floor1 *g = &f->floor_config[i].floor1; | |
3956 int max_class = -1; | |
3957 g->partitions = get_bits(f, 5); | |
3958 for (j=0; j < g->partitions; ++j) { | |
3959 g->partition_class_list[j] = get_bits(f, 4); | |
3960 if (g->partition_class_list[j] > max_class) | |
3961 max_class = g->partition_class_list[j]; | |
3962 } | |
3963 for (j=0; j <= max_class; ++j) { | |
3964 g->class_dimensions[j] = get_bits(f, 3)+1; | |
3965 g->class_subclasses[j] = get_bits(f, 2); | |
3966 if (g->class_subclasses[j]) { | |
3967 g->class_masterbooks[j] = get_bits(f, 8); | |
3968 if (g->class_masterbooks[j] >= f->codebook_count) return error(f, VORBIS_invalid_setup); | |
3969 } | |
3970 for (k=0; k < 1 << g->class_subclasses[j]; ++k) { | |
3971 g->subclass_books[j][k] = (int16)get_bits(f,8)-1; | |
3972 if (g->subclass_books[j][k] >= f->codebook_count) return error(f, VORBIS_invalid_setup); | |
3973 } | |
3974 } | |
3975 g->floor1_multiplier = get_bits(f,2)+1; | |
3976 g->rangebits = get_bits(f,4); | |
3977 g->Xlist[0] = 0; | |
3978 g->Xlist[1] = 1 << g->rangebits; | |
3979 g->values = 2; | |
3980 for (j=0; j < g->partitions; ++j) { | |
3981 int c = g->partition_class_list[j]; | |
3982 for (k=0; k < g->class_dimensions[c]; ++k) { | |
3983 g->Xlist[g->values] = get_bits(f, g->rangebits); | |
3984 ++g->values; | |
3985 } | |
3986 } | |
3987 // precompute the sorting | |
3988 for (j=0; j < g->values; ++j) { | |
3989 p[j].x = g->Xlist[j]; | |
3990 p[j].id = j; | |
3991 } | |
3992 qsort(p, g->values, sizeof(p[0]), point_compare); | |
3993 for (j=0; j < g->values-1; ++j) | |
3994 if (p[j].x == p[j+1].x) | |
3995 return error(f, VORBIS_invalid_setup); | |
3996 for (j=0; j < g->values; ++j) | |
3997 g->sorted_order[j] = (uint8) p[j].id; | |
3998 // precompute the neighbors | |
3999 for (j=2; j < g->values; ++j) { | |
4000 int low = 0,hi = 0; | |
4001 neighbors(g->Xlist, j, &low,&hi); | |
4002 g->neighbors[j][0] = low; | |
4003 g->neighbors[j][1] = hi; | |
4004 } | |
4005 | |
4006 if (g->values > longest_floorlist) | |
4007 longest_floorlist = g->values; | |
4008 } | |
4009 } | |
4010 | |
4011 // Residue | |
4012 f->residue_count = get_bits(f, 6)+1; | |
4013 f->residue_config = (Residue *) setup_malloc(f, f->residue_count * sizeof(f->residue_config[0])); | |
4014 if (f->residue_config == NULL) return error(f, VORBIS_outofmem); | |
4015 memset(f->residue_config, 0, f->residue_count * sizeof(f->residue_config[0])); | |
4016 for (i=0; i < f->residue_count; ++i) { | |
4017 uint8 residue_cascade[64]; | |
4018 Residue *r = f->residue_config+i; | |
4019 f->residue_types[i] = get_bits(f, 16); | |
4020 if (f->residue_types[i] > 2) return error(f, VORBIS_invalid_setup); | |
4021 r->begin = get_bits(f, 24); | |
4022 r->end = get_bits(f, 24); | |
4023 if (r->end < r->begin) return error(f, VORBIS_invalid_setup); | |
4024 r->part_size = get_bits(f,24)+1; | |
4025 r->classifications = get_bits(f,6)+1; | |
4026 r->classbook = get_bits(f,8); | |
4027 if (r->classbook >= f->codebook_count) return error(f, VORBIS_invalid_setup); | |
4028 for (j=0; j < r->classifications; ++j) { | |
4029 uint8 high_bits=0; | |
4030 uint8 low_bits=get_bits(f,3); | |
4031 if (get_bits(f,1)) | |
4032 high_bits = get_bits(f,5); | |
4033 residue_cascade[j] = high_bits*8 + low_bits; | |
4034 } | |
4035 r->residue_books = (short (*)[8]) setup_malloc(f, sizeof(r->residue_books[0]) * r->classifications); | |
4036 if (r->residue_books == NULL) return error(f, VORBIS_outofmem); | |
4037 for (j=0; j < r->classifications; ++j) { | |
4038 for (k=0; k < 8; ++k) { | |
4039 if (residue_cascade[j] & (1 << k)) { | |
4040 r->residue_books[j][k] = get_bits(f, 8); | |
4041 if (r->residue_books[j][k] >= f->codebook_count) return error(f, VORBIS_invalid_setup); | |
4042 } else { | |
4043 r->residue_books[j][k] = -1; | |
4044 } | |
4045 } | |
4046 } | |
4047 // precompute the classifications[] array to avoid inner-loop mod/divide | |
4048 // call it 'classdata' since we already have r->classifications | |
4049 r->classdata = (uint8 **) setup_malloc(f, sizeof(*r->classdata) * f->codebooks[r->classbook].entries); | |
4050 if (!r->classdata) return error(f, VORBIS_outofmem); | |
4051 memset(r->classdata, 0, sizeof(*r->classdata) * f->codebooks[r->classbook].entries); | |
4052 for (j=0; j < f->codebooks[r->classbook].entries; ++j) { | |
4053 int classwords = f->codebooks[r->classbook].dimensions; | |
4054 int temp = j; | |
4055 r->classdata[j] = (uint8 *) setup_malloc(f, sizeof(r->classdata[j][0]) * classwords); | |
4056 if (r->classdata[j] == NULL) return error(f, VORBIS_outofmem); | |
4057 for (k=classwords-1; k >= 0; --k) { | |
4058 r->classdata[j][k] = temp % r->classifications; | |
4059 temp /= r->classifications; | |
4060 } | |
4061 } | |
4062 } | |
4063 | |
4064 f->mapping_count = get_bits(f,6)+1; | |
4065 f->mapping = (Mapping *) setup_malloc(f, f->mapping_count * sizeof(*f->mapping)); | |
4066 if (f->mapping == NULL) return error(f, VORBIS_outofmem); | |
4067 memset(f->mapping, 0, f->mapping_count * sizeof(*f->mapping)); | |
4068 for (i=0; i < f->mapping_count; ++i) { | |
4069 Mapping *m = f->mapping + i; | |
4070 int mapping_type = get_bits(f,16); | |
4071 if (mapping_type != 0) return error(f, VORBIS_invalid_setup); | |
4072 m->chan = (MappingChannel *) setup_malloc(f, f->channels * sizeof(*m->chan)); | |
4073 if (m->chan == NULL) return error(f, VORBIS_outofmem); | |
4074 if (get_bits(f,1)) | |
4075 m->submaps = get_bits(f,4)+1; | |
4076 else | |
4077 m->submaps = 1; | |
4078 if (m->submaps > max_submaps) | |
4079 max_submaps = m->submaps; | |
4080 if (get_bits(f,1)) { | |
4081 m->coupling_steps = get_bits(f,8)+1; | |
4082 if (m->coupling_steps > f->channels) return error(f, VORBIS_invalid_setup); | |
4083 for (k=0; k < m->coupling_steps; ++k) { | |
4084 m->chan[k].magnitude = get_bits(f, ilog(f->channels-1)); | |
4085 m->chan[k].angle = get_bits(f, ilog(f->channels-1)); | |
4086 if (m->chan[k].magnitude >= f->channels) return error(f, VORBIS_invalid_setup); | |
4087 if (m->chan[k].angle >= f->channels) return error(f, VORBIS_invalid_setup); | |
4088 if (m->chan[k].magnitude == m->chan[k].angle) return error(f, VORBIS_invalid_setup); | |
4089 } | |
4090 } else | |
4091 m->coupling_steps = 0; | |
4092 | |
4093 // reserved field | |
4094 if (get_bits(f,2)) return error(f, VORBIS_invalid_setup); | |
4095 if (m->submaps > 1) { | |
4096 for (j=0; j < f->channels; ++j) { | |
4097 m->chan[j].mux = get_bits(f, 4); | |
4098 if (m->chan[j].mux >= m->submaps) return error(f, VORBIS_invalid_setup); | |
4099 } | |
4100 } else | |
4101 // @SPECIFICATION: this case is missing from the spec | |
4102 for (j=0; j < f->channels; ++j) | |
4103 m->chan[j].mux = 0; | |
4104 | |
4105 for (j=0; j < m->submaps; ++j) { | |
4106 get_bits(f,8); // discard | |
4107 m->submap_floor[j] = get_bits(f,8); | |
4108 m->submap_residue[j] = get_bits(f,8); | |
4109 if (m->submap_floor[j] >= f->floor_count) return error(f, VORBIS_invalid_setup); | |
4110 if (m->submap_residue[j] >= f->residue_count) return error(f, VORBIS_invalid_setup); | |
4111 } | |
4112 } | |
4113 | |
4114 // Modes | |
4115 f->mode_count = get_bits(f, 6)+1; | |
4116 for (i=0; i < f->mode_count; ++i) { | |
4117 Mode *m = f->mode_config+i; | |
4118 m->blockflag = get_bits(f,1); | |
4119 m->windowtype = get_bits(f,16); | |
4120 m->transformtype = get_bits(f,16); | |
4121 m->mapping = get_bits(f,8); | |
4122 if (m->windowtype != 0) return error(f, VORBIS_invalid_setup); | |
4123 if (m->transformtype != 0) return error(f, VORBIS_invalid_setup); | |
4124 if (m->mapping >= f->mapping_count) return error(f, VORBIS_invalid_setup); | |
4125 } | |
4126 | |
4127 flush_packet(f); | |
4128 | |
4129 f->previous_length = 0; | |
4130 | |
4131 for (i=0; i < f->channels; ++i) { | |
4132 f->channel_buffers[i] = (float *) setup_malloc(f, sizeof(float) * f->blocksize_1); | |
4133 f->previous_window[i] = (float *) setup_malloc(f, sizeof(float) * f->blocksize_1/2); | |
4134 f->finalY[i] = (int16 *) setup_malloc(f, sizeof(int16) * longest_floorlist); | |
4135 if (f->channel_buffers[i] == NULL || f->previous_window[i] == NULL || f->finalY[i] == NULL) return error(f, VORBIS_outofmem); | |
4136 memset(f->channel_buffers[i], 0, sizeof(float) * f->blocksize_1); | |
4137 #ifdef STB_VORBIS_NO_DEFER_FLOOR | |
4138 f->floor_buffers[i] = (float *) setup_malloc(f, sizeof(float) * f->blocksize_1/2); | |
4139 if (f->floor_buffers[i] == NULL) return error(f, VORBIS_outofmem); | |
4140 #endif | |
4141 } | |
4142 | |
4143 if (!init_blocksize(f, 0, f->blocksize_0)) return FALSE; | |
4144 if (!init_blocksize(f, 1, f->blocksize_1)) return FALSE; | |
4145 f->blocksize[0] = f->blocksize_0; | |
4146 f->blocksize[1] = f->blocksize_1; | |
4147 | |
4148 #ifdef STB_VORBIS_DIVIDE_TABLE | |
4149 if (integer_divide_table[1][1]==0) | |
4150 for (i=0; i < DIVTAB_NUMER; ++i) | |
4151 for (j=1; j < DIVTAB_DENOM; ++j) | |
4152 integer_divide_table[i][j] = i / j; | |
4153 #endif | |
4154 | |
4155 // compute how much temporary memory is needed | |
4156 | |
4157 // 1. | |
4158 { | |
4159 uint32 imdct_mem = (f->blocksize_1 * sizeof(float) >> 1); | |
4160 uint32 classify_mem; | |
4161 int i,max_part_read=0; | |
4162 for (i=0; i < f->residue_count; ++i) { | |
4163 Residue *r = f->residue_config + i; | |
4164 unsigned int actual_size = f->blocksize_1 / 2; | |
4165 unsigned int limit_r_begin = r->begin < actual_size ? r->begin : actual_size; | |
4166 unsigned int limit_r_end = r->end < actual_size ? r->end : actual_size; | |
4167 int n_read = limit_r_end - limit_r_begin; | |
4168 int part_read = n_read / r->part_size; | |
4169 if (part_read > max_part_read) | |
4170 max_part_read = part_read; | |
4171 } | |
4172 #ifndef STB_VORBIS_DIVIDES_IN_RESIDUE | |
4173 classify_mem = f->channels * (sizeof(void*) + max_part_read * sizeof(uint8 *)); | |
4174 #else | |
4175 classify_mem = f->channels * (sizeof(void*) + max_part_read * sizeof(int *)); | |
4176 #endif | |
4177 | |
4178 // maximum reasonable partition size is f->blocksize_1 | |
4179 | |
4180 f->temp_memory_required = classify_mem; | |
4181 if (imdct_mem > f->temp_memory_required) | |
4182 f->temp_memory_required = imdct_mem; | |
4183 } | |
4184 | |
4185 | |
4186 if (f->alloc.alloc_buffer) { | |
4187 assert(f->temp_offset == f->alloc.alloc_buffer_length_in_bytes); | |
4188 // check if there's enough temp memory so we don't error later | |
4189 if (f->setup_offset + sizeof(*f) + f->temp_memory_required > (unsigned) f->temp_offset) | |
4190 return error(f, VORBIS_outofmem); | |
4191 } | |
4192 | |
4193 // @TODO: stb_vorbis_seek_start expects first_audio_page_offset to point to a page | |
4194 // without PAGEFLAG_continued_packet, so this either points to the first page, or | |
4195 // the page after the end of the headers. It might be cleaner to point to a page | |
4196 // in the middle of the headers, when that's the page where the first audio packet | |
4197 // starts, but we'd have to also correctly skip the end of any continued packet in | |
4198 // stb_vorbis_seek_start. | |
4199 if (f->next_seg == -1) { | |
4200 f->first_audio_page_offset = stb_vorbis_get_file_offset(f); | |
4201 } else { | |
4202 f->first_audio_page_offset = 0; | |
4203 } | |
4204 | |
4205 return TRUE; | |
4206 } | |
4207 | |
4208 static void vorbis_deinit(stb_vorbis *p) | |
4209 { | |
4210 int i,j; | |
4211 | |
4212 setup_free(p, p->vendor); | |
4213 for (i=0; i < p->comment_list_length; ++i) { | |
4214 setup_free(p, p->comment_list[i]); | |
4215 } | |
4216 setup_free(p, p->comment_list); | |
4217 | |
4218 if (p->residue_config) { | |
4219 for (i=0; i < p->residue_count; ++i) { | |
4220 Residue *r = p->residue_config+i; | |
4221 if (r->classdata) { | |
4222 for (j=0; j < p->codebooks[r->classbook].entries; ++j) | |
4223 setup_free(p, r->classdata[j]); | |
4224 setup_free(p, r->classdata); | |
4225 } | |
4226 setup_free(p, r->residue_books); | |
4227 } | |
4228 } | |
4229 | |
4230 if (p->codebooks) { | |
4231 CHECK(p); | |
4232 for (i=0; i < p->codebook_count; ++i) { | |
4233 Codebook *c = p->codebooks + i; | |
4234 setup_free(p, c->codeword_lengths); | |
4235 setup_free(p, c->multiplicands); | |
4236 setup_free(p, c->codewords); | |
4237 setup_free(p, c->sorted_codewords); | |
4238 // c->sorted_values[-1] is the first entry in the array | |
4239 setup_free(p, c->sorted_values ? c->sorted_values-1 : NULL); | |
4240 } | |
4241 setup_free(p, p->codebooks); | |
4242 } | |
4243 setup_free(p, p->floor_config); | |
4244 setup_free(p, p->residue_config); | |
4245 if (p->mapping) { | |
4246 for (i=0; i < p->mapping_count; ++i) | |
4247 setup_free(p, p->mapping[i].chan); | |
4248 setup_free(p, p->mapping); | |
4249 } | |
4250 CHECK(p); | |
4251 for (i=0; i < p->channels && i < STB_VORBIS_MAX_CHANNELS; ++i) { | |
4252 setup_free(p, p->channel_buffers[i]); | |
4253 setup_free(p, p->previous_window[i]); | |
4254 #ifdef STB_VORBIS_NO_DEFER_FLOOR | |
4255 setup_free(p, p->floor_buffers[i]); | |
4256 #endif | |
4257 setup_free(p, p->finalY[i]); | |
4258 } | |
4259 for (i=0; i < 2; ++i) { | |
4260 setup_free(p, p->A[i]); | |
4261 setup_free(p, p->B[i]); | |
4262 setup_free(p, p->C[i]); | |
4263 setup_free(p, p->window[i]); | |
4264 setup_free(p, p->bit_reverse[i]); | |
4265 } | |
4266 #ifndef STB_VORBIS_NO_STDIO | |
4267 if (p->close_on_free) fclose(p->f); | |
4268 #endif | |
4269 } | |
4270 | |
4271 void stb_vorbis_close(stb_vorbis *p) | |
4272 { | |
4273 if (p == NULL) return; | |
4274 vorbis_deinit(p); | |
4275 setup_free(p,p); | |
4276 } | |
4277 | |
4278 static void vorbis_init(stb_vorbis *p, const stb_vorbis_alloc *z) | |
4279 { | |
4280 memset(p, 0, sizeof(*p)); // NULL out all malloc'd pointers to start | |
4281 if (z) { | |
4282 p->alloc = *z; | |
4283 p->alloc.alloc_buffer_length_in_bytes &= ~7; | |
4284 p->temp_offset = p->alloc.alloc_buffer_length_in_bytes; | |
4285 } | |
4286 p->eof = 0; | |
4287 p->error = VORBIS__no_error; | |
4288 p->stream = NULL; | |
4289 p->codebooks = NULL; | |
4290 p->page_crc_tests = -1; | |
4291 #ifndef STB_VORBIS_NO_STDIO | |
4292 p->close_on_free = FALSE; | |
4293 p->f = NULL; | |
4294 #endif | |
4295 } | |
4296 | |
4297 int stb_vorbis_get_sample_offset(stb_vorbis *f) | |
4298 { | |
4299 if (f->current_loc_valid) | |
4300 return f->current_loc; | |
4301 else | |
4302 return -1; | |
4303 } | |
4304 | |
4305 stb_vorbis_info stb_vorbis_get_info(stb_vorbis *f) | |
4306 { | |
4307 stb_vorbis_info d; | |
4308 d.channels = f->channels; | |
4309 d.sample_rate = f->sample_rate; | |
4310 d.setup_memory_required = f->setup_memory_required; | |
4311 d.setup_temp_memory_required = f->setup_temp_memory_required; | |
4312 d.temp_memory_required = f->temp_memory_required; | |
4313 d.max_frame_size = f->blocksize_1 >> 1; | |
4314 return d; | |
4315 } | |
4316 | |
4317 stb_vorbis_comment stb_vorbis_get_comment(stb_vorbis *f) | |
4318 { | |
4319 stb_vorbis_comment d; | |
4320 d.vendor = f->vendor; | |
4321 d.comment_list_length = f->comment_list_length; | |
4322 d.comment_list = f->comment_list; | |
4323 return d; | |
4324 } | |
4325 | |
4326 int stb_vorbis_get_error(stb_vorbis *f) | |
4327 { | |
4328 int e = f->error; | |
4329 f->error = VORBIS__no_error; | |
4330 return e; | |
4331 } | |
4332 | |
4333 static stb_vorbis * vorbis_alloc(stb_vorbis *f) | |
4334 { | |
4335 stb_vorbis *p = (stb_vorbis *) setup_malloc(f, sizeof(*p)); | |
4336 return p; | |
4337 } | |
4338 | |
4339 #ifndef STB_VORBIS_NO_PUSHDATA_API | |
4340 | |
4341 void stb_vorbis_flush_pushdata(stb_vorbis *f) | |
4342 { | |
4343 f->previous_length = 0; | |
4344 f->page_crc_tests = 0; | |
4345 f->discard_samples_deferred = 0; | |
4346 f->current_loc_valid = FALSE; | |
4347 f->first_decode = FALSE; | |
4348 f->samples_output = 0; | |
4349 f->channel_buffer_start = 0; | |
4350 f->channel_buffer_end = 0; | |
4351 } | |
4352 | |
4353 static int vorbis_search_for_page_pushdata(vorb *f, uint8 *data, int data_len) | |
4354 { | |
4355 int i,n; | |
4356 for (i=0; i < f->page_crc_tests; ++i) | |
4357 f->scan[i].bytes_done = 0; | |
4358 | |
4359 // if we have room for more scans, search for them first, because | |
4360 // they may cause us to stop early if their header is incomplete | |
4361 if (f->page_crc_tests < STB_VORBIS_PUSHDATA_CRC_COUNT) { | |
4362 if (data_len < 4) return 0; | |
4363 data_len -= 3; // need to look for 4-byte sequence, so don't miss | |
4364 // one that straddles a boundary | |
4365 for (i=0; i < data_len; ++i) { | |
4366 if (data[i] == 0x4f) { | |
4367 if (0==memcmp(data+i, ogg_page_header, 4)) { | |
4368 int j,len; | |
4369 uint32 crc; | |
4370 // make sure we have the whole page header | |
4371 if (i+26 >= data_len || i+27+data[i+26] >= data_len) { | |
4372 // only read up to this page start, so hopefully we'll | |
4373 // have the whole page header start next time | |
4374 data_len = i; | |
4375 break; | |
4376 } | |
4377 // ok, we have it all; compute the length of the page | |
4378 len = 27 + data[i+26]; | |
4379 for (j=0; j < data[i+26]; ++j) | |
4380 len += data[i+27+j]; | |
4381 // scan everything up to the embedded crc (which we must 0) | |
4382 crc = 0; | |
4383 for (j=0; j < 22; ++j) | |
4384 crc = crc32_update(crc, data[i+j]); | |
4385 // now process 4 0-bytes | |
4386 for ( ; j < 26; ++j) | |
4387 crc = crc32_update(crc, 0); | |
4388 // len is the total number of bytes we need to scan | |
4389 n = f->page_crc_tests++; | |
4390 f->scan[n].bytes_left = len-j; | |
4391 f->scan[n].crc_so_far = crc; | |
4392 f->scan[n].goal_crc = data[i+22] + (data[i+23] << 8) + (data[i+24]<<16) + (data[i+25]<<24); | |
4393 // if the last frame on a page is continued to the next, then | |
4394 // we can't recover the sample_loc immediately | |
4395 if (data[i+27+data[i+26]-1] == 255) | |
4396 f->scan[n].sample_loc = ~0; | |
4397 else | |
4398 f->scan[n].sample_loc = data[i+6] + (data[i+7] << 8) + (data[i+ 8]<<16) + (data[i+ 9]<<24); | |
4399 f->scan[n].bytes_done = i+j; | |
4400 if (f->page_crc_tests == STB_VORBIS_PUSHDATA_CRC_COUNT) | |
4401 break; | |
4402 // keep going if we still have room for more | |
4403 } | |
4404 } | |
4405 } | |
4406 } | |
4407 | |
4408 for (i=0; i < f->page_crc_tests;) { | |
4409 uint32 crc; | |
4410 int j; | |
4411 int n = f->scan[i].bytes_done; | |
4412 int m = f->scan[i].bytes_left; | |
4413 if (m > data_len - n) m = data_len - n; | |
4414 // m is the bytes to scan in the current chunk | |
4415 crc = f->scan[i].crc_so_far; | |
4416 for (j=0; j < m; ++j) | |
4417 crc = crc32_update(crc, data[n+j]); | |
4418 f->scan[i].bytes_left -= m; | |
4419 f->scan[i].crc_so_far = crc; | |
4420 if (f->scan[i].bytes_left == 0) { | |
4421 // does it match? | |
4422 if (f->scan[i].crc_so_far == f->scan[i].goal_crc) { | |
4423 // Houston, we have page | |
4424 data_len = n+m; // consumption amount is wherever that scan ended | |
4425 f->page_crc_tests = -1; // drop out of page scan mode | |
4426 f->previous_length = 0; // decode-but-don't-output one frame | |
4427 f->next_seg = -1; // start a new page | |
4428 f->current_loc = f->scan[i].sample_loc; // set the current sample location | |
4429 // to the amount we'd have decoded had we decoded this page | |
4430 f->current_loc_valid = f->current_loc != ~0U; | |
4431 return data_len; | |
4432 } | |
4433 // delete entry | |
4434 f->scan[i] = f->scan[--f->page_crc_tests]; | |
4435 } else { | |
4436 ++i; | |
4437 } | |
4438 } | |
4439 | |
4440 return data_len; | |
4441 } | |
4442 | |
4443 // return value: number of bytes we used | |
4444 int stb_vorbis_decode_frame_pushdata( | |
4445 stb_vorbis *f, // the file we're decoding | |
4446 const uint8 *data, int data_len, // the memory available for decoding | |
4447 int *channels, // place to write number of float * buffers | |
4448 float ***output, // place to write float ** array of float * buffers | |
4449 int *samples // place to write number of output samples | |
4450 ) | |
4451 { | |
4452 int i; | |
4453 int len,right,left; | |
4454 | |
4455 if (!IS_PUSH_MODE(f)) return error(f, VORBIS_invalid_api_mixing); | |
4456 | |
4457 if (f->page_crc_tests >= 0) { | |
4458 *samples = 0; | |
4459 return vorbis_search_for_page_pushdata(f, (uint8 *) data, data_len); | |
4460 } | |
4461 | |
4462 f->stream = (uint8 *) data; | |
4463 f->stream_end = (uint8 *) data + data_len; | |
4464 f->error = VORBIS__no_error; | |
4465 | |
4466 // check that we have the entire packet in memory | |
4467 if (!is_whole_packet_present(f)) { | |
4468 *samples = 0; | |
4469 return 0; | |
4470 } | |
4471 | |
4472 if (!vorbis_decode_packet(f, &len, &left, &right)) { | |
4473 // save the actual error we encountered | |
4474 enum STBVorbisError error = f->error; | |
4475 if (error == VORBIS_bad_packet_type) { | |
4476 // flush and resynch | |
4477 f->error = VORBIS__no_error; | |
4478 while (get8_packet(f) != EOP) | |
4479 if (f->eof) break; | |
4480 *samples = 0; | |
4481 return (int) (f->stream - data); | |
4482 } | |
4483 if (error == VORBIS_continued_packet_flag_invalid) { | |
4484 if (f->previous_length == 0) { | |
4485 // we may be resynching, in which case it's ok to hit one | |
4486 // of these; just discard the packet | |
4487 f->error = VORBIS__no_error; | |
4488 while (get8_packet(f) != EOP) | |
4489 if (f->eof) break; | |
4490 *samples = 0; | |
4491 return (int) (f->stream - data); | |
4492 } | |
4493 } | |
4494 // if we get an error while parsing, what to do? | |
4495 // well, it DEFINITELY won't work to continue from where we are! | |
4496 stb_vorbis_flush_pushdata(f); | |
4497 // restore the error that actually made us bail | |
4498 f->error = error; | |
4499 *samples = 0; | |
4500 return 1; | |
4501 } | |
4502 | |
4503 // success! | |
4504 len = vorbis_finish_frame(f, len, left, right); | |
4505 for (i=0; i < f->channels; ++i) | |
4506 f->outputs[i] = f->channel_buffers[i] + left; | |
4507 | |
4508 if (channels) *channels = f->channels; | |
4509 *samples = len; | |
4510 *output = f->outputs; | |
4511 return (int) (f->stream - data); | |
4512 } | |
4513 | |
4514 stb_vorbis *stb_vorbis_open_pushdata( | |
4515 const unsigned char *data, int data_len, // the memory available for decoding | |
4516 int *data_used, // only defined if result is not NULL | |
4517 int *error, const stb_vorbis_alloc *alloc) | |
4518 { | |
4519 stb_vorbis *f, p; | |
4520 vorbis_init(&p, alloc); | |
4521 p.stream = (uint8 *) data; | |
4522 p.stream_end = (uint8 *) data + data_len; | |
4523 p.push_mode = TRUE; | |
4524 if (!start_decoder(&p)) { | |
4525 if (p.eof) | |
4526 *error = VORBIS_need_more_data; | |
4527 else | |
4528 *error = p.error; | |
4529 vorbis_deinit(&p); | |
4530 return NULL; | |
4531 } | |
4532 f = vorbis_alloc(&p); | |
4533 if (f) { | |
4534 *f = p; | |
4535 *data_used = (int) (f->stream - data); | |
4536 *error = 0; | |
4537 return f; | |
4538 } else { | |
4539 vorbis_deinit(&p); | |
4540 return NULL; | |
4541 } | |
4542 } | |
4543 #endif // STB_VORBIS_NO_PUSHDATA_API | |
4544 | |
4545 unsigned int stb_vorbis_get_file_offset(stb_vorbis *f) | |
4546 { | |
4547 #ifndef STB_VORBIS_NO_PUSHDATA_API | |
4548 if (f->push_mode) return 0; | |
4549 #endif | |
4550 if (USE_MEMORY(f)) return (unsigned int) (f->stream - f->stream_start); | |
4551 #ifndef STB_VORBIS_NO_STDIO | |
4552 return (unsigned int) (ftell(f->f) - f->f_start); | |
4553 #endif | |
4554 } | |
4555 | |
4556 #ifndef STB_VORBIS_NO_PULLDATA_API | |
4557 // | |
4558 // DATA-PULLING API | |
4559 // | |
4560 | |
4561 static uint32 vorbis_find_page(stb_vorbis *f, uint32 *end, uint32 *last) | |
4562 { | |
4563 for(;;) { | |
4564 int n; | |
4565 if (f->eof) return 0; | |
4566 n = get8(f); | |
4567 if (n == 0x4f) { // page header candidate | |
4568 unsigned int retry_loc = stb_vorbis_get_file_offset(f); | |
4569 int i; | |
4570 // check if we're off the end of a file_section stream | |
4571 if (retry_loc - 25 > f->stream_len) | |
4572 return 0; | |
4573 // check the rest of the header | |
4574 for (i=1; i < 4; ++i) | |
4575 if (get8(f) != ogg_page_header[i]) | |
4576 break; | |
4577 if (f->eof) return 0; | |
4578 if (i == 4) { | |
4579 uint8 header[27]; | |
4580 uint32 i, crc, goal, len; | |
4581 for (i=0; i < 4; ++i) | |
4582 header[i] = ogg_page_header[i]; | |
4583 for (; i < 27; ++i) | |
4584 header[i] = get8(f); | |
4585 if (f->eof) return 0; | |
4586 if (header[4] != 0) goto invalid; | |
4587 goal = header[22] + (header[23] << 8) + (header[24]<<16) + ((uint32)header[25]<<24); | |
4588 for (i=22; i < 26; ++i) | |
4589 header[i] = 0; | |
4590 crc = 0; | |
4591 for (i=0; i < 27; ++i) | |
4592 crc = crc32_update(crc, header[i]); | |
4593 len = 0; | |
4594 for (i=0; i < header[26]; ++i) { | |
4595 int s = get8(f); | |
4596 crc = crc32_update(crc, s); | |
4597 len += s; | |
4598 } | |
4599 if (len && f->eof) return 0; | |
4600 for (i=0; i < len; ++i) | |
4601 crc = crc32_update(crc, get8(f)); | |
4602 // finished parsing probable page | |
4603 if (crc == goal) { | |
4604 // we could now check that it's either got the last | |
4605 // page flag set, OR it's followed by the capture | |
4606 // pattern, but I guess TECHNICALLY you could have | |
4607 // a file with garbage between each ogg page and recover | |
4608 // from it automatically? So even though that paranoia | |
4609 // might decrease the chance of an invalid decode by | |
4610 // another 2^32, not worth it since it would hose those | |
4611 // invalid-but-useful files? | |
4612 if (end) | |
4613 *end = stb_vorbis_get_file_offset(f); | |
4614 if (last) { | |
4615 if (header[5] & 0x04) | |
4616 *last = 1; | |
4617 else | |
4618 *last = 0; | |
4619 } | |
4620 set_file_offset(f, retry_loc-1); | |
4621 return 1; | |
4622 } | |
4623 } | |
4624 invalid: | |
4625 // not a valid page, so rewind and look for next one | |
4626 set_file_offset(f, retry_loc); | |
4627 } | |
4628 } | |
4629 } | |
4630 | |
4631 | |
4632 #define SAMPLE_unknown 0xffffffff | |
4633 | |
4634 // seeking is implemented with a binary search, which narrows down the range to | |
4635 // 64K, before using a linear search (because finding the synchronization | |
4636 // pattern can be expensive, and the chance we'd find the end page again is | |
4637 // relatively high for small ranges) | |
4638 // | |
4639 // two initial interpolation-style probes are used at the start of the search | |
4640 // to try to bound either side of the binary search sensibly, while still | |
4641 // working in O(log n) time if they fail. | |
4642 | |
4643 static int get_seek_page_info(stb_vorbis *f, ProbedPage *z) | |
4644 { | |
4645 uint8 header[27], lacing[255]; | |
4646 int i,len; | |
4647 | |
4648 // record where the page starts | |
4649 z->page_start = stb_vorbis_get_file_offset(f); | |
4650 | |
4651 // parse the header | |
4652 getn(f, header, 27); | |
4653 if (header[0] != 'O' || header[1] != 'g' || header[2] != 'g' || header[3] != 'S') | |
4654 return 0; | |
4655 getn(f, lacing, header[26]); | |
4656 | |
4657 // determine the length of the payload | |
4658 len = 0; | |
4659 for (i=0; i < header[26]; ++i) | |
4660 len += lacing[i]; | |
4661 | |
4662 // this implies where the page ends | |
4663 z->page_end = z->page_start + 27 + header[26] + len; | |
4664 | |
4665 // read the last-decoded sample out of the data | |
4666 z->last_decoded_sample = header[6] + (header[7] << 8) + (header[8] << 16) + (header[9] << 24); | |
4667 | |
4668 // restore file state to where we were | |
4669 set_file_offset(f, z->page_start); | |
4670 return 1; | |
4671 } | |
4672 | |
4673 // rarely used function to seek back to the preceding page while finding the | |
4674 // start of a packet | |
4675 static int go_to_page_before(stb_vorbis *f, unsigned int limit_offset) | |
4676 { | |
4677 unsigned int previous_safe, end; | |
4678 | |
4679 // now we want to seek back 64K from the limit | |
4680 if (limit_offset >= 65536 && limit_offset-65536 >= f->first_audio_page_offset) | |
4681 previous_safe = limit_offset - 65536; | |
4682 else | |
4683 previous_safe = f->first_audio_page_offset; | |
4684 | |
4685 set_file_offset(f, previous_safe); | |
4686 | |
4687 while (vorbis_find_page(f, &end, NULL)) { | |
4688 if (end >= limit_offset && stb_vorbis_get_file_offset(f) < limit_offset) | |
4689 return 1; | |
4690 set_file_offset(f, end); | |
4691 } | |
4692 | |
4693 return 0; | |
4694 } | |
4695 | |
4696 // implements the search logic for finding a page and starting decoding. if | |
4697 // the function succeeds, current_loc_valid will be true and current_loc will | |
4698 // be less than or equal to the provided sample number (the closer the | |
4699 // better). | |
4700 static int seek_to_sample_coarse(stb_vorbis *f, uint32 sample_number) | |
4701 { | |
4702 ProbedPage left, right, mid; | |
4703 int i, start_seg_with_known_loc, end_pos, page_start; | |
4704 uint32 delta, stream_length, padding, last_sample_limit; | |
4705 double offset = 0.0, bytes_per_sample = 0.0; | |
4706 int probe = 0; | |
4707 | |
4708 // find the last page and validate the target sample | |
4709 stream_length = stb_vorbis_stream_length_in_samples(f); | |
4710 if (stream_length == 0) return error(f, VORBIS_seek_without_length); | |
4711 if (sample_number > stream_length) return error(f, VORBIS_seek_invalid); | |
4712 | |
4713 // this is the maximum difference between the window-center (which is the | |
4714 // actual granule position value), and the right-start (which the spec | |
4715 // indicates should be the granule position (give or take one)). | |
4716 padding = ((f->blocksize_1 - f->blocksize_0) >> 2); | |
4717 if (sample_number < padding) | |
4718 last_sample_limit = 0; | |
4719 else | |
4720 last_sample_limit = sample_number - padding; | |
4721 | |
4722 left = f->p_first; | |
4723 while (left.last_decoded_sample == ~0U) { | |
4724 // (untested) the first page does not have a 'last_decoded_sample' | |
4725 set_file_offset(f, left.page_end); | |
4726 if (!get_seek_page_info(f, &left)) goto error; | |
4727 } | |
4728 | |
4729 right = f->p_last; | |
4730 assert(right.last_decoded_sample != ~0U); | |
4731 | |
4732 // starting from the start is handled differently | |
4733 if (last_sample_limit <= left.last_decoded_sample) { | |
4734 if (stb_vorbis_seek_start(f)) { | |
4735 if (f->current_loc > sample_number) | |
4736 return error(f, VORBIS_seek_failed); | |
4737 return 1; | |
4738 } | |
4739 return 0; | |
4740 } | |
4741 | |
4742 while (left.page_end != right.page_start) { | |
4743 assert(left.page_end < right.page_start); | |
4744 // search range in bytes | |
4745 delta = right.page_start - left.page_end; | |
4746 if (delta <= 65536) { | |
4747 // there's only 64K left to search - handle it linearly | |
4748 set_file_offset(f, left.page_end); | |
4749 } else { | |
4750 if (probe < 2) { | |
4751 if (probe == 0) { | |
4752 // first probe (interpolate) | |
4753 double data_bytes = right.page_end - left.page_start; | |
4754 bytes_per_sample = data_bytes / right.last_decoded_sample; | |
4755 offset = left.page_start + bytes_per_sample * (last_sample_limit - left.last_decoded_sample); | |
4756 } else { | |
4757 // second probe (try to bound the other side) | |
4758 double error = ((double) last_sample_limit - mid.last_decoded_sample) * bytes_per_sample; | |
4759 if (error >= 0 && error < 8000) error = 8000; | |
4760 if (error < 0 && error > -8000) error = -8000; | |
4761 offset += error * 2; | |
4762 } | |
4763 | |
4764 // ensure the offset is valid | |
4765 if (offset < left.page_end) | |
4766 offset = left.page_end; | |
4767 if (offset > right.page_start - 65536) | |
4768 offset = right.page_start - 65536; | |
4769 | |
4770 set_file_offset(f, (unsigned int) offset); | |
4771 } else { | |
4772 // binary search for large ranges (offset by 32K to ensure | |
4773 // we don't hit the right page) | |
4774 set_file_offset(f, left.page_end + (delta / 2) - 32768); | |
4775 } | |
4776 | |
4777 if (!vorbis_find_page(f, NULL, NULL)) goto error; | |
4778 } | |
4779 | |
4780 for (;;) { | |
4781 if (!get_seek_page_info(f, &mid)) goto error; | |
4782 if (mid.last_decoded_sample != ~0U) break; | |
4783 // (untested) no frames end on this page | |
4784 set_file_offset(f, mid.page_end); | |
4785 assert(mid.page_start < right.page_start); | |
4786 } | |
4787 | |
4788 // if we've just found the last page again then we're in a tricky file, | |
4789 // and we're close enough (if it wasn't an interpolation probe). | |
4790 if (mid.page_start == right.page_start) { | |
4791 if (probe >= 2 || delta <= 65536) | |
4792 break; | |
4793 } else { | |
4794 if (last_sample_limit < mid.last_decoded_sample) | |
4795 right = mid; | |
4796 else | |
4797 left = mid; | |
4798 } | |
4799 | |
4800 ++probe; | |
4801 } | |
4802 | |
4803 // seek back to start of the last packet | |
4804 page_start = left.page_start; | |
4805 set_file_offset(f, page_start); | |
4806 if (!start_page(f)) return error(f, VORBIS_seek_failed); | |
4807 end_pos = f->end_seg_with_known_loc; | |
4808 assert(end_pos >= 0); | |
4809 | |
4810 for (;;) { | |
4811 for (i = end_pos; i > 0; --i) | |
4812 if (f->segments[i-1] != 255) | |
4813 break; | |
4814 | |
4815 start_seg_with_known_loc = i; | |
4816 | |
4817 if (start_seg_with_known_loc > 0 || !(f->page_flag & PAGEFLAG_continued_packet)) | |
4818 break; | |
4819 | |
4820 // (untested) the final packet begins on an earlier page | |
4821 if (!go_to_page_before(f, page_start)) | |
4822 goto error; | |
4823 | |
4824 page_start = stb_vorbis_get_file_offset(f); | |
4825 if (!start_page(f)) goto error; | |
4826 end_pos = f->segment_count - 1; | |
4827 } | |
4828 | |
4829 // prepare to start decoding | |
4830 f->current_loc_valid = FALSE; | |
4831 f->last_seg = FALSE; | |
4832 f->valid_bits = 0; | |
4833 f->packet_bytes = 0; | |
4834 f->bytes_in_seg = 0; | |
4835 f->previous_length = 0; | |
4836 f->next_seg = start_seg_with_known_loc; | |
4837 | |
4838 for (i = 0; i < start_seg_with_known_loc; i++) | |
4839 skip(f, f->segments[i]); | |
4840 | |
4841 // start decoding (optimizable - this frame is generally discarded) | |
4842 if (!vorbis_pump_first_frame(f)) | |
4843 return 0; | |
4844 if (f->current_loc > sample_number) | |
4845 return error(f, VORBIS_seek_failed); | |
4846 return 1; | |
4847 | |
4848 error: | |
4849 // try to restore the file to a valid state | |
4850 stb_vorbis_seek_start(f); | |
4851 return error(f, VORBIS_seek_failed); | |
4852 } | |
4853 | |
4854 // the same as vorbis_decode_initial, but without advancing | |
4855 static int peek_decode_initial(vorb *f, int *p_left_start, int *p_left_end, int *p_right_start, int *p_right_end, int *mode) | |
4856 { | |
4857 int bits_read, bytes_read; | |
4858 | |
4859 if (!vorbis_decode_initial(f, p_left_start, p_left_end, p_right_start, p_right_end, mode)) | |
4860 return 0; | |
4861 | |
4862 // either 1 or 2 bytes were read, figure out which so we can rewind | |
4863 bits_read = 1 + ilog(f->mode_count-1); | |
4864 if (f->mode_config[*mode].blockflag) | |
4865 bits_read += 2; | |
4866 bytes_read = (bits_read + 7) / 8; | |
4867 | |
4868 f->bytes_in_seg += bytes_read; | |
4869 f->packet_bytes -= bytes_read; | |
4870 skip(f, -bytes_read); | |
4871 if (f->next_seg == -1) | |
4872 f->next_seg = f->segment_count - 1; | |
4873 else | |
4874 f->next_seg--; | |
4875 f->valid_bits = 0; | |
4876 | |
4877 return 1; | |
4878 } | |
4879 | |
4880 int stb_vorbis_seek_frame(stb_vorbis *f, unsigned int sample_number) | |
4881 { | |
4882 uint32 max_frame_samples; | |
4883 | |
4884 if (IS_PUSH_MODE(f)) return error(f, VORBIS_invalid_api_mixing); | |
4885 | |
4886 // fast page-level search | |
4887 if (!seek_to_sample_coarse(f, sample_number)) | |
4888 return 0; | |
4889 | |
4890 assert(f->current_loc_valid); | |
4891 assert(f->current_loc <= sample_number); | |
4892 | |
4893 // linear search for the relevant packet | |
4894 max_frame_samples = (f->blocksize_1*3 - f->blocksize_0) >> 2; | |
4895 while (f->current_loc < sample_number) { | |
4896 int left_start, left_end, right_start, right_end, mode, frame_samples; | |
4897 if (!peek_decode_initial(f, &left_start, &left_end, &right_start, &right_end, &mode)) | |
4898 return error(f, VORBIS_seek_failed); | |
4899 // calculate the number of samples returned by the next frame | |
4900 frame_samples = right_start - left_start; | |
4901 if (f->current_loc + frame_samples > sample_number) { | |
4902 return 1; // the next frame will contain the sample | |
4903 } else if (f->current_loc + frame_samples + max_frame_samples > sample_number) { | |
4904 // there's a chance the frame after this could contain the sample | |
4905 vorbis_pump_first_frame(f); | |
4906 } else { | |
4907 // this frame is too early to be relevant | |
4908 f->current_loc += frame_samples; | |
4909 f->previous_length = 0; | |
4910 maybe_start_packet(f); | |
4911 flush_packet(f); | |
4912 } | |
4913 } | |
4914 // the next frame should start with the sample | |
4915 if (f->current_loc != sample_number) return error(f, VORBIS_seek_failed); | |
4916 return 1; | |
4917 } | |
4918 | |
4919 int stb_vorbis_seek(stb_vorbis *f, unsigned int sample_number) | |
4920 { | |
4921 if (!stb_vorbis_seek_frame(f, sample_number)) | |
4922 return 0; | |
4923 | |
4924 if (sample_number != f->current_loc) { | |
4925 int n; | |
4926 uint32 frame_start = f->current_loc; | |
4927 stb_vorbis_get_frame_float(f, &n, NULL); | |
4928 assert(sample_number > frame_start); | |
4929 assert(f->channel_buffer_start + (int) (sample_number-frame_start) <= f->channel_buffer_end); | |
4930 f->channel_buffer_start += (sample_number - frame_start); | |
4931 } | |
4932 | |
4933 return 1; | |
4934 } | |
4935 | |
4936 int stb_vorbis_seek_start(stb_vorbis *f) | |
4937 { | |
4938 if (IS_PUSH_MODE(f)) { return error(f, VORBIS_invalid_api_mixing); } | |
4939 set_file_offset(f, f->first_audio_page_offset); | |
4940 f->previous_length = 0; | |
4941 f->first_decode = TRUE; | |
4942 f->next_seg = -1; | |
4943 return vorbis_pump_first_frame(f); | |
4944 } | |
4945 | |
4946 unsigned int stb_vorbis_stream_length_in_samples(stb_vorbis *f) | |
4947 { | |
4948 unsigned int restore_offset, previous_safe; | |
4949 unsigned int end, last_page_loc; | |
4950 | |
4951 if (IS_PUSH_MODE(f)) return error(f, VORBIS_invalid_api_mixing); | |
4952 if (!f->total_samples) { | |
4953 unsigned int last; | |
4954 uint32 lo,hi; | |
4955 char header[6]; | |
4956 | |
4957 // first, store the current decode position so we can restore it | |
4958 restore_offset = stb_vorbis_get_file_offset(f); | |
4959 | |
4960 // now we want to seek back 64K from the end (the last page must | |
4961 // be at most a little less than 64K, but let's allow a little slop) | |
4962 if (f->stream_len >= 65536 && f->stream_len-65536 >= f->first_audio_page_offset) | |
4963 previous_safe = f->stream_len - 65536; | |
4964 else | |
4965 previous_safe = f->first_audio_page_offset; | |
4966 | |
4967 set_file_offset(f, previous_safe); | |
4968 // previous_safe is now our candidate 'earliest known place that seeking | |
4969 // to will lead to the final page' | |
4970 | |
4971 if (!vorbis_find_page(f, &end, &last)) { | |
4972 // if we can't find a page, we're hosed! | |
4973 f->error = VORBIS_cant_find_last_page; | |
4974 f->total_samples = 0xffffffff; | |
4975 goto done; | |
4976 } | |
4977 | |
4978 // check if there are more pages | |
4979 last_page_loc = stb_vorbis_get_file_offset(f); | |
4980 | |
4981 // stop when the last_page flag is set, not when we reach eof; | |
4982 // this allows us to stop short of a 'file_section' end without | |
4983 // explicitly checking the length of the section | |
4984 while (!last) { | |
4985 set_file_offset(f, end); | |
4986 if (!vorbis_find_page(f, &end, &last)) { | |
4987 // the last page we found didn't have the 'last page' flag | |
4988 // set. whoops! | |
4989 break; | |
4990 } | |
4991 //previous_safe = last_page_loc+1; // NOTE: not used after this point, but note for debugging | |
4992 last_page_loc = stb_vorbis_get_file_offset(f); | |
4993 } | |
4994 | |
4995 set_file_offset(f, last_page_loc); | |
4996 | |
4997 // parse the header | |
4998 getn(f, (unsigned char *)header, 6); | |
4999 // extract the absolute granule position | |
5000 lo = get32(f); | |
5001 hi = get32(f); | |
5002 if (lo == 0xffffffff && hi == 0xffffffff) { | |
5003 f->error = VORBIS_cant_find_last_page; | |
5004 f->total_samples = SAMPLE_unknown; | |
5005 goto done; | |
5006 } | |
5007 if (hi) | |
5008 lo = 0xfffffffe; // saturate | |
5009 f->total_samples = lo; | |
5010 | |
5011 f->p_last.page_start = last_page_loc; | |
5012 f->p_last.page_end = end; | |
5013 f->p_last.last_decoded_sample = lo; | |
5014 | |
5015 done: | |
5016 set_file_offset(f, restore_offset); | |
5017 } | |
5018 return f->total_samples == SAMPLE_unknown ? 0 : f->total_samples; | |
5019 } | |
5020 | |
5021 float stb_vorbis_stream_length_in_seconds(stb_vorbis *f) | |
5022 { | |
5023 return stb_vorbis_stream_length_in_samples(f) / (float) f->sample_rate; | |
5024 } | |
5025 | |
5026 | |
5027 | |
5028 int stb_vorbis_get_frame_float(stb_vorbis *f, int *channels, float ***output) | |
5029 { | |
5030 int len, right,left,i; | |
5031 if (IS_PUSH_MODE(f)) return error(f, VORBIS_invalid_api_mixing); | |
5032 | |
5033 if (!vorbis_decode_packet(f, &len, &left, &right)) { | |
5034 f->channel_buffer_start = f->channel_buffer_end = 0; | |
5035 return 0; | |
5036 } | |
5037 | |
5038 len = vorbis_finish_frame(f, len, left, right); | |
5039 for (i=0; i < f->channels; ++i) | |
5040 f->outputs[i] = f->channel_buffers[i] + left; | |
5041 | |
5042 f->channel_buffer_start = left; | |
5043 f->channel_buffer_end = left+len; | |
5044 | |
5045 if (channels) *channels = f->channels; | |
5046 if (output) *output = f->outputs; | |
5047 return len; | |
5048 } | |
5049 | |
5050 #ifndef STB_VORBIS_NO_STDIO | |
5051 | |
5052 stb_vorbis * stb_vorbis_open_file_section(FILE *file, int close_on_free, int *error, const stb_vorbis_alloc *alloc, unsigned int length) | |
5053 { | |
5054 stb_vorbis *f, p; | |
5055 vorbis_init(&p, alloc); | |
5056 p.f = file; | |
5057 p.f_start = (uint32) ftell(file); | |
5058 p.stream_len = length; | |
5059 p.close_on_free = close_on_free; | |
5060 if (start_decoder(&p)) { | |
5061 f = vorbis_alloc(&p); | |
5062 if (f) { | |
5063 *f = p; | |
5064 vorbis_pump_first_frame(f); | |
5065 return f; | |
5066 } | |
5067 } | |
5068 if (error) *error = p.error; | |
5069 vorbis_deinit(&p); | |
5070 return NULL; | |
5071 } | |
5072 | |
5073 stb_vorbis * stb_vorbis_open_file(FILE *file, int close_on_free, int *error, const stb_vorbis_alloc *alloc) | |
5074 { | |
5075 unsigned int len, start; | |
5076 start = (unsigned int) ftell(file); | |
5077 fseek(file, 0, SEEK_END); | |
5078 len = (unsigned int) (ftell(file) - start); | |
5079 fseek(file, start, SEEK_SET); | |
5080 return stb_vorbis_open_file_section(file, close_on_free, error, alloc, len); | |
5081 } | |
5082 | |
5083 stb_vorbis * stb_vorbis_open_filename(const char *filename, int *error, const stb_vorbis_alloc *alloc) | |
5084 { | |
5085 FILE *f; | |
5086 #if defined(_WIN32) && defined(__STDC_WANT_SECURE_LIB__) | |
5087 if (0 != fopen_s(&f, filename, "rb")) | |
5088 f = NULL; | |
5089 #else | |
5090 f = fopen(filename, "rb"); | |
5091 #endif | |
5092 if (f) | |
5093 return stb_vorbis_open_file(f, TRUE, error, alloc); | |
5094 if (error) *error = VORBIS_file_open_failure; | |
5095 return NULL; | |
5096 } | |
5097 #endif // STB_VORBIS_NO_STDIO | |
5098 | |
5099 stb_vorbis * stb_vorbis_open_memory(const unsigned char *data, int len, int *error, const stb_vorbis_alloc *alloc) | |
5100 { | |
5101 stb_vorbis *f, p; | |
5102 if (!data) { | |
5103 if (error) *error = VORBIS_unexpected_eof; | |
5104 return NULL; | |
5105 } | |
5106 vorbis_init(&p, alloc); | |
5107 p.stream = (uint8 *) data; | |
5108 p.stream_end = (uint8 *) data + len; | |
5109 p.stream_start = (uint8 *) p.stream; | |
5110 p.stream_len = len; | |
5111 p.push_mode = FALSE; | |
5112 if (start_decoder(&p)) { | |
5113 f = vorbis_alloc(&p); | |
5114 if (f) { | |
5115 *f = p; | |
5116 vorbis_pump_first_frame(f); | |
5117 if (error) *error = VORBIS__no_error; | |
5118 return f; | |
5119 } | |
5120 } | |
5121 if (error) *error = p.error; | |
5122 vorbis_deinit(&p); | |
5123 return NULL; | |
5124 } | |
5125 | |
5126 #ifndef STB_VORBIS_NO_INTEGER_CONVERSION | |
5127 #define PLAYBACK_MONO 1 | |
5128 #define PLAYBACK_LEFT 2 | |
5129 #define PLAYBACK_RIGHT 4 | |
5130 | |
5131 #define L (PLAYBACK_LEFT | PLAYBACK_MONO) | |
5132 #define C (PLAYBACK_LEFT | PLAYBACK_RIGHT | PLAYBACK_MONO) | |
5133 #define R (PLAYBACK_RIGHT | PLAYBACK_MONO) | |
5134 | |
5135 static int8 channel_position[7][6] = | |
5136 { | |
5137 { 0 }, | |
5138 { C }, | |
5139 { L, R }, | |
5140 { L, C, R }, | |
5141 { L, R, L, R }, | |
5142 { L, C, R, L, R }, | |
5143 { L, C, R, L, R, C }, | |
5144 }; | |
5145 | |
5146 | |
5147 #ifndef STB_VORBIS_NO_FAST_SCALED_FLOAT | |
5148 typedef union { | |
5149 float f; | |
5150 int i; | |
5151 } float_conv; | |
5152 typedef char stb_vorbis_float_size_test[sizeof(float)==4 && sizeof(int) == 4]; | |
5153 #define FASTDEF(x) float_conv x | |
5154 // add (1<<23) to convert to int, then divide by 2^SHIFT, then add 0.5/2^SHIFT to round | |
5155 #define MAGIC(SHIFT) (1.5f * (1 << (23-SHIFT)) + 0.5f/(1 << SHIFT)) | |
5156 #define ADDEND(SHIFT) (((150-SHIFT) << 23) + (1 << 22)) | |
5157 #define FAST_SCALED_FLOAT_TO_INT(temp,x,s) (temp.f = (x) + MAGIC(s), temp.i - ADDEND(s)) | |
5158 #define check_endianness() | |
5159 #else | |
5160 #define FAST_SCALED_FLOAT_TO_INT(temp,x,s) ((int) ((x) * (1 << (s)))) | |
5161 #define check_endianness() | |
5162 #define FASTDEF(x) | |
5163 #endif | |
5164 | |
5165 static void copy_samples(short *dest, float *src, int len) | |
5166 { | |
5167 int i; | |
5168 check_endianness(); | |
5169 for (i=0; i < len; ++i) { | |
5170 FASTDEF(temp); | |
5171 int v = FAST_SCALED_FLOAT_TO_INT(temp, src[i],15); | |
5172 if ((unsigned int) (v + 32768) > 65535) | |
5173 v = v < 0 ? -32768 : 32767; | |
5174 dest[i] = v; | |
5175 } | |
5176 } | |
5177 | |
5178 static void compute_samples(int mask, short *output, int num_c, float **data, int d_offset, int len) | |
5179 { | |
5180 #define STB_BUFFER_SIZE 32 | |
5181 float buffer[STB_BUFFER_SIZE]; | |
5182 int i,j,o,n = STB_BUFFER_SIZE; | |
5183 check_endianness(); | |
5184 for (o = 0; o < len; o += STB_BUFFER_SIZE) { | |
5185 memset(buffer, 0, sizeof(buffer)); | |
5186 if (o + n > len) n = len - o; | |
5187 for (j=0; j < num_c; ++j) { | |
5188 if (channel_position[num_c][j] & mask) { | |
5189 for (i=0; i < n; ++i) | |
5190 buffer[i] += data[j][d_offset+o+i]; | |
5191 } | |
5192 } | |
5193 for (i=0; i < n; ++i) { | |
5194 FASTDEF(temp); | |
5195 int v = FAST_SCALED_FLOAT_TO_INT(temp,buffer[i],15); | |
5196 if ((unsigned int) (v + 32768) > 65535) | |
5197 v = v < 0 ? -32768 : 32767; | |
5198 output[o+i] = v; | |
5199 } | |
5200 } | |
5201 #undef STB_BUFFER_SIZE | |
5202 } | |
5203 | |
5204 static void compute_stereo_samples(short *output, int num_c, float **data, int d_offset, int len) | |
5205 { | |
5206 #define STB_BUFFER_SIZE 32 | |
5207 float buffer[STB_BUFFER_SIZE]; | |
5208 int i,j,o,n = STB_BUFFER_SIZE >> 1; | |
5209 // o is the offset in the source data | |
5210 check_endianness(); | |
5211 for (o = 0; o < len; o += STB_BUFFER_SIZE >> 1) { | |
5212 // o2 is the offset in the output data | |
5213 int o2 = o << 1; | |
5214 memset(buffer, 0, sizeof(buffer)); | |
5215 if (o + n > len) n = len - o; | |
5216 for (j=0; j < num_c; ++j) { | |
5217 int m = channel_position[num_c][j] & (PLAYBACK_LEFT | PLAYBACK_RIGHT); | |
5218 if (m == (PLAYBACK_LEFT | PLAYBACK_RIGHT)) { | |
5219 for (i=0; i < n; ++i) { | |
5220 buffer[i*2+0] += data[j][d_offset+o+i]; | |
5221 buffer[i*2+1] += data[j][d_offset+o+i]; | |
5222 } | |
5223 } else if (m == PLAYBACK_LEFT) { | |
5224 for (i=0; i < n; ++i) { | |
5225 buffer[i*2+0] += data[j][d_offset+o+i]; | |
5226 } | |
5227 } else if (m == PLAYBACK_RIGHT) { | |
5228 for (i=0; i < n; ++i) { | |
5229 buffer[i*2+1] += data[j][d_offset+o+i]; | |
5230 } | |
5231 } | |
5232 } | |
5233 for (i=0; i < (n<<1); ++i) { | |
5234 FASTDEF(temp); | |
5235 int v = FAST_SCALED_FLOAT_TO_INT(temp,buffer[i],15); | |
5236 if ((unsigned int) (v + 32768) > 65535) | |
5237 v = v < 0 ? -32768 : 32767; | |
5238 output[o2+i] = v; | |
5239 } | |
5240 } | |
5241 #undef STB_BUFFER_SIZE | |
5242 } | |
5243 | |
5244 static void convert_samples_short(int buf_c, short **buffer, int b_offset, int data_c, float **data, int d_offset, int samples) | |
5245 { | |
5246 int i; | |
5247 if (buf_c != data_c && buf_c <= 2 && data_c <= 6) { | |
5248 static int channel_selector[3][2] = { {0}, {PLAYBACK_MONO}, {PLAYBACK_LEFT, PLAYBACK_RIGHT} }; | |
5249 for (i=0; i < buf_c; ++i) | |
5250 compute_samples(channel_selector[buf_c][i], buffer[i]+b_offset, data_c, data, d_offset, samples); | |
5251 } else { | |
5252 int limit = buf_c < data_c ? buf_c : data_c; | |
5253 for (i=0; i < limit; ++i) | |
5254 copy_samples(buffer[i]+b_offset, data[i]+d_offset, samples); | |
5255 for ( ; i < buf_c; ++i) | |
5256 memset(buffer[i]+b_offset, 0, sizeof(short) * samples); | |
5257 } | |
5258 } | |
5259 | |
5260 int stb_vorbis_get_frame_short(stb_vorbis *f, int num_c, short **buffer, int num_samples) | |
5261 { | |
5262 float **output = NULL; | |
5263 int len = stb_vorbis_get_frame_float(f, NULL, &output); | |
5264 if (len > num_samples) len = num_samples; | |
5265 if (len) | |
5266 convert_samples_short(num_c, buffer, 0, f->channels, output, 0, len); | |
5267 return len; | |
5268 } | |
5269 | |
5270 static void convert_channels_short_interleaved(int buf_c, short *buffer, int data_c, float **data, int d_offset, int len) | |
5271 { | |
5272 int i; | |
5273 check_endianness(); | |
5274 if (buf_c != data_c && buf_c <= 2 && data_c <= 6) { | |
5275 assert(buf_c == 2); | |
5276 for (i=0; i < buf_c; ++i) | |
5277 compute_stereo_samples(buffer, data_c, data, d_offset, len); | |
5278 } else { | |
5279 int limit = buf_c < data_c ? buf_c : data_c; | |
5280 int j; | |
5281 for (j=0; j < len; ++j) { | |
5282 for (i=0; i < limit; ++i) { | |
5283 FASTDEF(temp); | |
5284 float f = data[i][d_offset+j]; | |
5285 int v = FAST_SCALED_FLOAT_TO_INT(temp, f,15);//data[i][d_offset+j],15); | |
5286 if ((unsigned int) (v + 32768) > 65535) | |
5287 v = v < 0 ? -32768 : 32767; | |
5288 *buffer++ = v; | |
5289 } | |
5290 for ( ; i < buf_c; ++i) | |
5291 *buffer++ = 0; | |
5292 } | |
5293 } | |
5294 } | |
5295 | |
5296 int stb_vorbis_get_frame_short_interleaved(stb_vorbis *f, int num_c, short *buffer, int num_shorts) | |
5297 { | |
5298 float **output; | |
5299 int len; | |
5300 if (num_c == 1) return stb_vorbis_get_frame_short(f,num_c,&buffer, num_shorts); | |
5301 len = stb_vorbis_get_frame_float(f, NULL, &output); | |
5302 if (len) { | |
5303 if (len*num_c > num_shorts) len = num_shorts / num_c; | |
5304 convert_channels_short_interleaved(num_c, buffer, f->channels, output, 0, len); | |
5305 } | |
5306 return len; | |
5307 } | |
5308 | |
5309 int stb_vorbis_get_samples_short_interleaved(stb_vorbis *f, int channels, short *buffer, int num_shorts) | |
5310 { | |
5311 float **outputs; | |
5312 int len = num_shorts / channels; | |
5313 int n=0; | |
5314 while (n < len) { | |
5315 int k = f->channel_buffer_end - f->channel_buffer_start; | |
5316 if (n+k >= len) k = len - n; | |
5317 if (k) | |
5318 convert_channels_short_interleaved(channels, buffer, f->channels, f->channel_buffers, f->channel_buffer_start, k); | |
5319 buffer += k*channels; | |
5320 n += k; | |
5321 f->channel_buffer_start += k; | |
5322 if (n == len) break; | |
5323 if (!stb_vorbis_get_frame_float(f, NULL, &outputs)) break; | |
5324 } | |
5325 return n; | |
5326 } | |
5327 | |
5328 int stb_vorbis_get_samples_short(stb_vorbis *f, int channels, short **buffer, int len) | |
5329 { | |
5330 float **outputs; | |
5331 int n=0; | |
5332 while (n < len) { | |
5333 int k = f->channel_buffer_end - f->channel_buffer_start; | |
5334 if (n+k >= len) k = len - n; | |
5335 if (k) | |
5336 convert_samples_short(channels, buffer, n, f->channels, f->channel_buffers, f->channel_buffer_start, k); | |
5337 n += k; | |
5338 f->channel_buffer_start += k; | |
5339 if (n == len) break; | |
5340 if (!stb_vorbis_get_frame_float(f, NULL, &outputs)) break; | |
5341 } | |
5342 return n; | |
5343 } | |
5344 | |
5345 #ifndef STB_VORBIS_NO_STDIO | |
5346 int stb_vorbis_decode_filename(const char *filename, int *channels, int *sample_rate, short **output) | |
5347 { | |
5348 int data_len, offset, total, limit, error; | |
5349 short *data; | |
5350 stb_vorbis *v = stb_vorbis_open_filename(filename, &error, NULL); | |
5351 if (v == NULL) return -1; | |
5352 limit = v->channels * 4096; | |
5353 *channels = v->channels; | |
5354 if (sample_rate) | |
5355 *sample_rate = v->sample_rate; | |
5356 offset = data_len = 0; | |
5357 total = limit; | |
5358 data = (short *) malloc(total * sizeof(*data)); | |
5359 if (data == NULL) { | |
5360 stb_vorbis_close(v); | |
5361 return -2; | |
5362 } | |
5363 for (;;) { | |
5364 int n = stb_vorbis_get_frame_short_interleaved(v, v->channels, data+offset, total-offset); | |
5365 if (n == 0) break; | |
5366 data_len += n; | |
5367 offset += n * v->channels; | |
5368 if (offset + limit > total) { | |
5369 short *data2; | |
5370 total *= 2; | |
5371 data2 = (short *) realloc(data, total * sizeof(*data)); | |
5372 if (data2 == NULL) { | |
5373 free(data); | |
5374 stb_vorbis_close(v); | |
5375 return -2; | |
5376 } | |
5377 data = data2; | |
5378 } | |
5379 } | |
5380 *output = data; | |
5381 stb_vorbis_close(v); | |
5382 return data_len; | |
5383 } | |
5384 #endif // NO_STDIO | |
5385 | |
5386 int stb_vorbis_decode_memory(const uint8 *mem, int len, int *channels, int *sample_rate, short **output) | |
5387 { | |
5388 int data_len, offset, total, limit, error; | |
5389 short *data; | |
5390 stb_vorbis *v = stb_vorbis_open_memory(mem, len, &error, NULL); | |
5391 if (v == NULL) return -1; | |
5392 limit = v->channels * 4096; | |
5393 *channels = v->channels; | |
5394 if (sample_rate) | |
5395 *sample_rate = v->sample_rate; | |
5396 offset = data_len = 0; | |
5397 total = limit; | |
5398 data = (short *) malloc(total * sizeof(*data)); | |
5399 if (data == NULL) { | |
5400 stb_vorbis_close(v); | |
5401 return -2; | |
5402 } | |
5403 for (;;) { | |
5404 int n = stb_vorbis_get_frame_short_interleaved(v, v->channels, data+offset, total-offset); | |
5405 if (n == 0) break; | |
5406 data_len += n; | |
5407 offset += n * v->channels; | |
5408 if (offset + limit > total) { | |
5409 short *data2; | |
5410 total *= 2; | |
5411 data2 = (short *) realloc(data, total * sizeof(*data)); | |
5412 if (data2 == NULL) { | |
5413 free(data); | |
5414 stb_vorbis_close(v); | |
5415 return -2; | |
5416 } | |
5417 data = data2; | |
5418 } | |
5419 } | |
5420 *output = data; | |
5421 stb_vorbis_close(v); | |
5422 return data_len; | |
5423 } | |
5424 #endif // STB_VORBIS_NO_INTEGER_CONVERSION | |
5425 | |
5426 int stb_vorbis_get_samples_float_interleaved(stb_vorbis *f, int channels, float *buffer, int num_floats) | |
5427 { | |
5428 float **outputs; | |
5429 int len = num_floats / channels; | |
5430 int n=0; | |
5431 int z = f->channels; | |
5432 if (z > channels) z = channels; | |
5433 while (n < len) { | |
5434 int i,j; | |
5435 int k = f->channel_buffer_end - f->channel_buffer_start; | |
5436 if (n+k >= len) k = len - n; | |
5437 for (j=0; j < k; ++j) { | |
5438 for (i=0; i < z; ++i) | |
5439 *buffer++ = f->channel_buffers[i][f->channel_buffer_start+j]; | |
5440 for ( ; i < channels; ++i) | |
5441 *buffer++ = 0; | |
5442 } | |
5443 n += k; | |
5444 f->channel_buffer_start += k; | |
5445 if (n == len) | |
5446 break; | |
5447 if (!stb_vorbis_get_frame_float(f, NULL, &outputs)) | |
5448 break; | |
5449 } | |
5450 return n; | |
5451 } | |
5452 | |
5453 int stb_vorbis_get_samples_float(stb_vorbis *f, int channels, float **buffer, int num_samples) | |
5454 { | |
5455 float **outputs; | |
5456 int n=0; | |
5457 int z = f->channels; | |
5458 if (z > channels) z = channels; | |
5459 while (n < num_samples) { | |
5460 int i; | |
5461 int k = f->channel_buffer_end - f->channel_buffer_start; | |
5462 if (n+k >= num_samples) k = num_samples - n; | |
5463 if (k) { | |
5464 for (i=0; i < z; ++i) | |
5465 memcpy(buffer[i]+n, f->channel_buffers[i]+f->channel_buffer_start, sizeof(float)*k); | |
5466 for ( ; i < channels; ++i) | |
5467 memset(buffer[i]+n, 0, sizeof(float) * k); | |
5468 } | |
5469 n += k; | |
5470 f->channel_buffer_start += k; | |
5471 if (n == num_samples) | |
5472 break; | |
5473 if (!stb_vorbis_get_frame_float(f, NULL, &outputs)) | |
5474 break; | |
5475 } | |
5476 return n; | |
5477 } | |
5478 #endif // STB_VORBIS_NO_PULLDATA_API | |
5479 | |
5480 /* Version history | |
5481 1.17 - 2019-07-08 - fix CVE-2019-13217, -13218, -13219, -13220, -13221, -13222, -13223 | |
5482 found with Mayhem by ForAllSecure | |
5483 1.16 - 2019-03-04 - fix warnings | |
5484 1.15 - 2019-02-07 - explicit failure if Ogg Skeleton data is found | |
5485 1.14 - 2018-02-11 - delete bogus dealloca usage | |
5486 1.13 - 2018-01-29 - fix truncation of last frame (hopefully) | |
5487 1.12 - 2017-11-21 - limit residue begin/end to blocksize/2 to avoid large temp allocs in bad/corrupt files | |
5488 1.11 - 2017-07-23 - fix MinGW compilation | |
5489 1.10 - 2017-03-03 - more robust seeking; fix negative ilog(); clear error in open_memory | |
5490 1.09 - 2016-04-04 - back out 'avoid discarding last frame' fix from previous version | |
5491 1.08 - 2016-04-02 - fixed multiple warnings; fix setup memory leaks; | |
5492 avoid discarding last frame of audio data | |
5493 1.07 - 2015-01-16 - fixed some warnings, fix mingw, const-correct API | |
5494 some more crash fixes when out of memory or with corrupt files | |
5495 1.06 - 2015-08-31 - full, correct support for seeking API (Dougall Johnson) | |
5496 some crash fixes when out of memory or with corrupt files | |
5497 1.05 - 2015-04-19 - don't define __forceinline if it's redundant | |
5498 1.04 - 2014-08-27 - fix missing const-correct case in API | |
5499 1.03 - 2014-08-07 - Warning fixes | |
5500 1.02 - 2014-07-09 - Declare qsort compare function _cdecl on windows | |
5501 1.01 - 2014-06-18 - fix stb_vorbis_get_samples_float | |
5502 1.0 - 2014-05-26 - fix memory leaks; fix warnings; fix bugs in multichannel | |
5503 (API change) report sample rate for decode-full-file funcs | |
5504 0.99996 - bracket #include <malloc.h> for macintosh compilation by Laurent Gomila | |
5505 0.99995 - use union instead of pointer-cast for fast-float-to-int to avoid alias-optimization problem | |
5506 0.99994 - change fast-float-to-int to work in single-precision FPU mode, remove endian-dependence | |
5507 0.99993 - remove assert that fired on legal files with empty tables | |
5508 0.99992 - rewind-to-start | |
5509 0.99991 - bugfix to stb_vorbis_get_samples_short by Bernhard Wodo | |
5510 0.9999 - (should have been 0.99990) fix no-CRT support, compiling as C++ | |
5511 0.9998 - add a full-decode function with a memory source | |
5512 0.9997 - fix a bug in the read-from-FILE case in 0.9996 addition | |
5513 0.9996 - query length of vorbis stream in samples/seconds | |
5514 0.9995 - bugfix to another optimization that only happened in certain files | |
5515 0.9994 - bugfix to one of the optimizations that caused significant (but inaudible?) errors | |
5516 0.9993 - performance improvements; runs in 99% to 104% of time of reference implementation | |
5517 0.9992 - performance improvement of IMDCT; now performs close to reference implementation | |
5518 0.9991 - performance improvement of IMDCT | |
5519 0.999 - (should have been 0.9990) performance improvement of IMDCT | |
5520 0.998 - no-CRT support from Casey Muratori | |
5521 0.997 - bugfixes for bugs found by Terje Mathisen | |
5522 0.996 - bugfix: fast-huffman decode initialized incorrectly for sparse codebooks; fixing gives 10% speedup - found by Terje Mathisen | |
5523 0.995 - bugfix: fix to 'effective' overrun detection - found by Terje Mathisen | |
5524 0.994 - bugfix: garbage decode on final VQ symbol of a non-multiple - found by Terje Mathisen | |
5525 0.993 - bugfix: pushdata API required 1 extra byte for empty page (failed to consume final page if empty) - found by Terje Mathisen | |
5526 0.992 - fixes for MinGW warning | |
5527 0.991 - turn fast-float-conversion on by default | |
5528 0.990 - fix push-mode seek recovery if you seek into the headers | |
5529 0.98b - fix to bad release of 0.98 | |
5530 0.98 - fix push-mode seek recovery; robustify float-to-int and support non-fast mode | |
5531 0.97 - builds under c++ (typecasting, don't use 'class' keyword) | |
5532 0.96 - somehow MY 0.95 was right, but the web one was wrong, so here's my 0.95 rereleased as 0.96, fixes a typo in the clamping code | |
5533 0.95 - clamping code for 16-bit functions | |
5534 0.94 - not publically released | |
5535 0.93 - fixed all-zero-floor case (was decoding garbage) | |
5536 0.92 - fixed a memory leak | |
5537 0.91 - conditional compiles to omit parts of the API and the infrastructure to support them: STB_VORBIS_NO_PULLDATA_API, STB_VORBIS_NO_PUSHDATA_API, STB_VORBIS_NO_STDIO, STB_VORBIS_NO_INTEGER_CONVERSION | |
5538 0.90 - first public release | |
5539 */ | |
5540 | |
5541 #endif // STB_VORBIS_HEADER_ONLY | |
5542 | |
5543 | |
5544 /* | |
5545 ------------------------------------------------------------------------------ | |
5546 This software is available under 2 licenses -- choose whichever you prefer. | |
5547 ------------------------------------------------------------------------------ | |
5548 ALTERNATIVE A - MIT License | |
5549 Copyright (c) 2017 Sean Barrett | |
5550 Permission is hereby granted, free of charge, to any person obtaining a copy of | |
5551 this software and associated documentation files (the "Software"), to deal in | |
5552 the Software without restriction, including without limitation the rights to | |
5553 use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies | |
5554 of the Software, and to permit persons to whom the Software is furnished to do | |
5555 so, subject to the following conditions: | |
5556 The above copyright notice and this permission notice shall be included in all | |
5557 copies or substantial portions of the Software. | |
5558 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR | |
5559 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, | |
5560 FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE | |
5561 AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER | |
5562 LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, | |
5563 OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE | |
5564 SOFTWARE. | |
5565 ------------------------------------------------------------------------------ | |
5566 ALTERNATIVE B - Public Domain (www.unlicense.org) | |
5567 This is free and unencumbered software released into the public domain. | |
5568 Anyone is free to copy, modify, publish, use, compile, sell, or distribute this | |
5569 software, either in source code form or as a compiled binary, for any purpose, | |
5570 commercial or non-commercial, and by any means. | |
5571 In jurisdictions that recognize copyright laws, the author or authors of this | |
5572 software dedicate any and all copyright interest in the software to the public | |
5573 domain. We make this dedication for the benefit of the public at large and to | |
5574 the detriment of our heirs and successors. We intend this dedication to be an | |
5575 overt act of relinquishment in perpetuity of all present and future rights to | |
5576 this software under copyright law. | |
5577 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR | |
5578 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, | |
5579 FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE | |
5580 AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN | |
5581 ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION | |
5582 WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. | |
5583 ------------------------------------------------------------------------------ | |
5584 */ |