• Home
  • Line#
  • Scopes#
  • Navigate#
  • Raw
  • Download
1 /******************************************************************************
2  *
3  * Copyright (C) 2015 The Android Open Source Project
4  *
5  * Licensed under the Apache License, Version 2.0 (the "License");
6  * you may not use this file except in compliance with the License.
7  * You may obtain a copy of the License at:
8  *
9  * http://www.apache.org/licenses/LICENSE-2.0
10  *
11  * Unless required by applicable law or agreed to in writing, software
12  * distributed under the License is distributed on an "AS IS" BASIS,
13  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
14  * See the License for the specific language governing permissions and
15  * limitations under the License.
16  *
17  *****************************************************************************
18  * Originally developed and contributed by Ittiam Systems Pvt. Ltd, Bangalore
19 */
20 
21 /**
22 *******************************************************************************
23 * @file
24 *  ih264e_cabac.c
25 *
26 * @brief
27 *  Contains all leaf level functions for CABAC entropy coding.
28 *
29 *
30 * @author
31 * Doney Alex
32 *
33 * @par List of Functions:
34 *
35 *
36 * @remarks
37 *  None
38 *
39 *******************************************************************************
40 */
41 
42 /*****************************************************************************/
43 /* File Includes                                                             */
44 /*****************************************************************************/
45 
46 /* System include files */
47 #include <stdio.h>
48 #include <assert.h>
49 #include <limits.h>
50 #include <string.h>
51 
52 /* User include files */
53 #include "ih264e_config.h"
54 #include "ih264_typedefs.h"
55 #include "iv2.h"
56 #include "ive2.h"
57 #include "ih264_debug.h"
58 #include "ih264_defs.h"
59 #include "ih264e_defs.h"
60 #include "ih264_macros.h"
61 #include "ih264e_error.h"
62 #include "ih264e_bitstream.h"
63 #include "ime_distortion_metrics.h"
64 #include "ime_defs.h"
65 #include "ime_structs.h"
66 #include "ih264_error.h"
67 #include "ih264_structs.h"
68 #include "ih264_trans_quant_itrans_iquant.h"
69 #include "ih264_inter_pred_filters.h"
70 #include "ih264_mem_fns.h"
71 #include "ih264_padding.h"
72 #include "ih264_platform_macros.h"
73 #include "ih264_intra_pred_filters.h"
74 #include "ih264_deblk_edge_filters.h"
75 #include "ih264_cabac_tables.h"
76 #include "irc_cntrl_param.h"
77 #include "irc_frame_info_collector.h"
78 #include "ih264e_rate_control.h"
79 #include "ih264e_cabac_structs.h"
80 #include "ih264e_structs.h"
81 #include "ih264e_cabac.h"
82 #include "ih264e_encode_header.h"
83 #include "ih264_cavlc_tables.h"
84 #include "ih264e_statistics.h"
85 #include "ih264e_trace.h"
86 
87 
88 /*****************************************************************************/
89 /* Function Definitions                                                      */
90 /*****************************************************************************/
91 
92 
93 /**
94  *******************************************************************************
95  *
96  * @brief
97  *  k-th order Exp-Golomb (UEGk) binarization process: Implements concatenated
98  *   unary/ k-th order Exp-Golomb  (UEGk) binarization process,
99  *   where k = 0 as defined in 9.3.2.3 of  ITU_T_H264-201402
100  *
101  * @param[in] i2_sufs
102  *  Suffix bit string
103  *
104  * @param[in] pi1_bins_len
105  *  Pointer to length of tthe string
106  *
107  * @returns Binarized value
108  *
109  * @remarks
110  *  None
111  *
112  *******************************************************************************
113  */
114 
ih264e_cabac_UEGk0_binarization(WORD16 i2_sufs,WORD8 * pi1_bins_len)115 UWORD32 ih264e_cabac_UEGk0_binarization(WORD16 i2_sufs, WORD8 *pi1_bins_len)
116 {
117     WORD32 unary_length;
118     UWORD32 u4_sufs_shiftk_plus1, u4_egk, u4_unary_bins;
119 
120     u4_sufs_shiftk_plus1 = i2_sufs + 1;
121 
122     unary_length = (32 - CLZ(u4_sufs_shiftk_plus1) + (0 == u4_sufs_shiftk_plus1));
123 
124     /* unary code with (unary_length-1) '1's and terminating '0' bin */
125     u4_unary_bins = (1 << unary_length) - 2;
126 
127     /* insert the symbol prefix of (unary length - 1)  bins */
128     u4_egk = (u4_unary_bins << (unary_length - 1))
129                     | (u4_sufs_shiftk_plus1 & ((1 << (unary_length - 1)) - 1));
130 
131     /* length of the code = 2 *(unary_length - 1) + 1 + k */
132     *pi1_bins_len = (2 * unary_length) - 1;
133 
134     return (u4_egk);
135 }
136 
137 /**
138  *******************************************************************************
139  *
140  * @brief
141  *  Get cabac context for the MB :calculates the pointers to Top and   left
142  *          cabac neighbor context depending upon neighbor  availability.
143  *
144  * @param[in] ps_ent_ctxt
145  *  Pointer to entropy context structure
146  *
147  * @param[in] u4_mb_type
148  *  Type of MB
149  *
150  * @returns
151  *
152  * @remarks
153  *  None
154  *
155  *******************************************************************************
156  */
ih264e_get_cabac_context(entropy_ctxt_t * ps_ent_ctxt,WORD32 u4_mb_type)157 void ih264e_get_cabac_context(entropy_ctxt_t *ps_ent_ctxt, WORD32 u4_mb_type)
158 {
159 
160     /* CABAC context */
161     cabac_ctxt_t *ps_cabac_ctxt = ps_ent_ctxt->ps_cabac;
162     mb_info_ctxt_t *ps_ctx_inc_mb_map;
163     cab_csbp_t *ps_lft_csbp;
164 
165     WORD32 i4_lft_avail, i4_top_avail, i4_is_intra;
166     WORD32 i4_mb_x, i4_mb_y;
167     UWORD8 *pu1_slice_idx = ps_ent_ctxt->pu1_slice_idx;
168 
169     i4_is_intra = ((u4_mb_type == I16x16) || (u4_mb_type == I8x8)
170                     || (u4_mb_type == I4x4));
171 
172     /* derive neighbor availability */
173     i4_mb_x = ps_ent_ctxt->i4_mb_x;
174     i4_mb_y = ps_ent_ctxt->i4_mb_y;
175     pu1_slice_idx += (i4_mb_y * ps_ent_ctxt->i4_wd_mbs);
176     /* left macroblock availability */
177     i4_lft_avail = (i4_mb_x == 0
178                     || (pu1_slice_idx[i4_mb_x - 1] != pu1_slice_idx[i4_mb_x])) ?
179                     0 : 1;
180     /* top macroblock availability */
181     i4_top_avail = (i4_mb_y == 0
182                     || (pu1_slice_idx[i4_mb_x - ps_ent_ctxt->i4_wd_mbs]
183                                     != pu1_slice_idx[i4_mb_x])) ? 0 : 1;
184     i4_mb_x = ps_ent_ctxt->i4_mb_x;
185     ps_ctx_inc_mb_map = ps_cabac_ctxt->ps_mb_map_ctxt_inc;
186     ps_cabac_ctxt->ps_curr_ctxt_mb_info = ps_ctx_inc_mb_map + i4_mb_x;
187     ps_cabac_ctxt->ps_left_ctxt_mb_info = ps_cabac_ctxt->ps_def_ctxt_mb_info;
188     ps_cabac_ctxt->ps_top_ctxt_mb_info = ps_cabac_ctxt->ps_def_ctxt_mb_info;
189     ps_lft_csbp = ps_cabac_ctxt->ps_lft_csbp;
190     ps_cabac_ctxt->pu1_left_y_ac_csbp = &ps_lft_csbp->u1_y_ac_csbp_top_mb;
191     ps_cabac_ctxt->pu1_left_uv_ac_csbp = &ps_lft_csbp->u1_uv_ac_csbp_top_mb;
192     ps_cabac_ctxt->pu1_left_yuv_dc_csbp = &ps_lft_csbp->u1_yuv_dc_csbp_top_mb;
193     ps_cabac_ctxt->pi1_left_ref_idx_ctxt_inc =
194                     &ps_cabac_ctxt->i1_left_ref_idx_ctx_inc_arr[0][0];
195     ps_cabac_ctxt->pu1_left_mv_ctxt_inc =
196                     ps_cabac_ctxt->u1_left_mv_ctxt_inc_arr[0];
197 
198     if (i4_lft_avail)
199         ps_cabac_ctxt->ps_left_ctxt_mb_info =
200                         ps_cabac_ctxt->ps_curr_ctxt_mb_info - 1;
201     if (i4_top_avail)
202         ps_cabac_ctxt->ps_top_ctxt_mb_info =
203                         ps_cabac_ctxt->ps_curr_ctxt_mb_info;
204 
205     if (!i4_lft_avail)
206     {
207         UWORD8 u1_def_csbp = i4_is_intra ? 0xf : 0;
208         *(ps_cabac_ctxt->pu1_left_y_ac_csbp) = u1_def_csbp;
209         *(ps_cabac_ctxt->pu1_left_uv_ac_csbp) = u1_def_csbp;
210         *(ps_cabac_ctxt->pu1_left_yuv_dc_csbp) = u1_def_csbp;
211         *((UWORD32 *) ps_cabac_ctxt->pi1_left_ref_idx_ctxt_inc) = 0;
212         memset(ps_cabac_ctxt->pu1_left_mv_ctxt_inc, 0, 16);
213     }
214     if (!i4_top_avail)
215     {
216         UWORD8 u1_def_csbp = i4_is_intra ? 0xff : 0;
217         ps_cabac_ctxt->ps_top_ctxt_mb_info->u1_yuv_ac_csbp = u1_def_csbp;
218         ps_cabac_ctxt->ps_top_ctxt_mb_info->u1_yuv_dc_csbp = u1_def_csbp;
219         ps_cabac_ctxt->ps_curr_ctxt_mb_info->i1_ref_idx[0] =
220         ps_cabac_ctxt->ps_curr_ctxt_mb_info->i1_ref_idx[1] =
221         ps_cabac_ctxt->ps_curr_ctxt_mb_info->i1_ref_idx[2] =
222         ps_cabac_ctxt->ps_curr_ctxt_mb_info->i1_ref_idx[3] = 0;
223         memset(ps_cabac_ctxt->ps_curr_ctxt_mb_info->u1_mv, 0, 16);
224     }
225 
226 }
227 
228 
229 
230 /**
231  *******************************************************************************
232  * @brief
233  *  flushing at termination: Explained in flowchart 9-12(ITU_T_H264-201402).
234  *
235  *  @param[in]   ps_cabac_ctxt
236  *  pointer to cabac context (handle)
237  *
238  * @returns  none
239  *
240  * @remarks
241  *  None
242  *
243  *******************************************************************************
244  */
ih264e_cabac_flush(cabac_ctxt_t * ps_cabac_ctxt)245 IH264E_ERROR_T ih264e_cabac_flush(cabac_ctxt_t *ps_cabac_ctxt)
246 {
247     /* bit stream ptr */
248     bitstrm_t *ps_stream = ps_cabac_ctxt->ps_bitstrm;
249     encoding_envirnoment_t *ps_cab_enc_env = &(ps_cabac_ctxt->s_cab_enc_env);
250     UWORD32 u4_low = ps_cab_enc_env->u4_code_int_low;
251     UWORD32 u4_bits_gen = ps_cab_enc_env->u4_bits_gen;
252     UWORD8 *pu1_strm_buf = ps_stream->pu1_strm_buffer;
253     UWORD32 u4_out_standing_bytes = ps_cab_enc_env->u4_out_standing_bytes;
254     IH264E_ERROR_T status = IH264E_SUCCESS;
255 
256     /************************************************************************/
257     /* Insert the carry (propogated in previous byte) along with            */
258     /* outstanding bytes (if any) and flush remaining bits                  */
259     /************************************************************************/
260     {
261         /* carry = 1 => putbit(1); carry propogated due to L renorm */
262         WORD32 carry = (u4_low >> (u4_bits_gen + CABAC_BITS)) & 0x1;
263         WORD32 last_byte;
264         WORD32 bits_left;
265         WORD32 rem_bits;
266 
267         if (carry)
268         {
269             /* CORNER CASE: if the previous data is 0x000003, then EPB will be inserted
270              and the data will become 0x00000303 and if the carry is present, it will
271              be added with the last byte and it will become 0x00000304 which is not correct
272              as per standard */
273             /* so check for previous four bytes and if it is equal to 0x00000303
274              then subtract u4_strm_buf_offset by 1 */
275             if (pu1_strm_buf[ps_stream->u4_strm_buf_offset - 1] == 0x03
276                             && pu1_strm_buf[ps_stream->u4_strm_buf_offset - 2] == 0x03
277                             && pu1_strm_buf[ps_stream->u4_strm_buf_offset - 3] == 0x00
278                             && pu1_strm_buf[ps_stream->u4_strm_buf_offset - 4] == 0x00)
279             {
280                 ps_stream->u4_strm_buf_offset -= 1;
281             }
282             /* previous byte carry add will not result in overflow to        */
283             /* u4_strm_buf_offset - 2 as we track 0xff as outstanding bytes  */
284             pu1_strm_buf[ps_stream->u4_strm_buf_offset - 1] += carry;
285             ps_stream->i4_zero_bytes_run = 0;
286         }
287 
288         /*        Insert outstanding bytes (if any)         */
289         while (u4_out_standing_bytes)
290         {
291             UWORD8 u1_0_or_ff = carry ? 0 : 0xFF;
292 
293             status |= ih264e_put_byte_epb(ps_stream, u1_0_or_ff);
294             u4_out_standing_bytes--;
295         }
296 
297         /*  clear the carry in low */
298         u4_low &= ((1 << (u4_bits_gen + CABAC_BITS)) - 1);
299 
300         /* extract the remaining bits;                                   */
301         /* includes additional msb bit of low as per Figure 9-12      */
302         bits_left = u4_bits_gen + 1;
303         rem_bits = (u4_low >> (u4_bits_gen + CABAC_BITS - bits_left));
304 
305         if (bits_left >= 8)
306         {
307             last_byte = (rem_bits >> (bits_left - 8)) & 0xFF;
308             status |= ih264e_put_byte_epb(ps_stream, last_byte);
309             bits_left -= 8;
310         }
311 
312         /* insert last byte along with rbsp stop bit(1) and 0's in the end */
313         last_byte = (rem_bits << (8 - bits_left))
314                         | (1 << (7 - bits_left) | (1 << (7 - bits_left - 1)));
315         last_byte &= 0xFF;
316         status |= ih264e_put_byte_epb(ps_stream, last_byte);
317 
318         /* update the state variables and return success */
319         ps_stream->i4_zero_bytes_run = 0;
320         /* Default init values for scratch variables of bitstream context */
321         ps_stream->u4_cur_word = 0;
322         ps_stream->i4_bits_left_in_cw = WORD_SIZE;
323 
324     }
325     return status;
326 }
327 
328 /**
329  ******************************************************************************
330  *
331  *  @brief Puts new byte (and outstanding bytes) into bitstream after cabac
332  *         renormalization
333  *
334  *  @par   Description
335  *  1. Extract the leading byte of low(L)
336  *  2. If leading byte=0xff increment outstanding bytes and return
337  *     (as the actual bits depend on carry propogation later)
338  *  3. If leading byte is not 0xff check for any carry propogation
339  *  4. Insert the carry (propogated in previous byte) along with outstanding
340  *     bytes (if any) and leading byte
341  *
342  *
343  *  @param[in]   ps_cabac_ctxt
344  *  pointer to cabac context (handle)
345  *
346  *  @return
347  *
348  ******************************************************************************
349  */
ih264e_cabac_put_byte(cabac_ctxt_t * ps_cabac_ctxt)350 IH264E_ERROR_T ih264e_cabac_put_byte(cabac_ctxt_t *ps_cabac_ctxt)
351 {
352     /* bit stream ptr */
353     bitstrm_t *ps_stream = ps_cabac_ctxt->ps_bitstrm;
354     encoding_envirnoment_t *ps_cab_enc_env = &(ps_cabac_ctxt->s_cab_enc_env);
355     UWORD32 u4_low = ps_cab_enc_env->u4_code_int_low;
356     UWORD32 u4_bits_gen = ps_cab_enc_env->u4_bits_gen;
357     UWORD8 *pu1_strm_buf = ps_stream->pu1_strm_buffer;
358     WORD32 lead_byte = u4_low >> (u4_bits_gen + CABAC_BITS - 8);
359     IH264E_ERROR_T status = IH264E_SUCCESS;
360 
361     /* Sanity checks */
362     ASSERT((ps_cab_enc_env->u4_code_int_range >= 256)
363                     && (ps_cab_enc_env->u4_code_int_range < 512));
364     ASSERT((u4_bits_gen >= 8));
365 
366     /* update bits generated and low after extracting leading byte */
367     u4_bits_gen -= 8;
368     ps_cab_enc_env->u4_code_int_low &= ((1 << (CABAC_BITS + u4_bits_gen)) - 1);
369     ps_cab_enc_env->u4_bits_gen = u4_bits_gen;
370 
371     /************************************************************************/
372     /* 1. Extract the leading byte of low(L)                                */
373     /* 2. If leading byte=0xff increment outstanding bytes and return       */
374     /*      (as the actual bits depend on carry propogation later)          */
375     /* 3. If leading byte is not 0xff check for any carry propogation       */
376     /* 4. Insert the carry (propogated in previous byte) along with         */
377     /*    outstanding bytes (if any) and leading byte                       */
378     /************************************************************************/
379     if (lead_byte == 0xff)
380     {
381         /* actual bits depend on carry propogration     */
382         ps_cab_enc_env->u4_out_standing_bytes++;
383     }
384     else
385     {
386         /* carry = 1 => putbit(1); carry propogated due to L renorm */
387         WORD32 carry = (lead_byte >> 8) & 0x1;
388         UWORD32 u4_out_standing_bytes = ps_cab_enc_env->u4_out_standing_bytes;
389 
390 
391         /*********************************************************************/
392         /*        Insert the carry propogated in previous byte               */
393         /*                                                                   */
394         /* Note : Do not worry about corruption into slice header align byte */
395         /*        This is because the first bin cannot result in overflow    */
396         /*********************************************************************/
397         if (carry)
398         {
399             /* CORNER CASE: if the previous data is 0x000003, then EPB will be inserted
400              and the data will become 0x00000303 and if the carry is present, it will
401              be added with the last byte and it will become 0x00000304 which is not correct
402              as per standard */
403             /* so check for previous four bytes and if it is equal to 0x00000303
404              then subtract u4_strm_buf_offset by 1 */
405             if (pu1_strm_buf[ps_stream->u4_strm_buf_offset - 1] == 0x03
406                             && pu1_strm_buf[ps_stream->u4_strm_buf_offset - 2] == 0x03
407                             && pu1_strm_buf[ps_stream->u4_strm_buf_offset - 3] == 0x00
408                             && pu1_strm_buf[ps_stream->u4_strm_buf_offset - 4] == 0x00)
409             {
410                 ps_stream->u4_strm_buf_offset -= 1;
411             }
412             /* previous byte carry add will not result in overflow to        */
413             /* u4_strm_buf_offset - 2 as we track 0xff as outstanding bytes  */
414             pu1_strm_buf[ps_stream->u4_strm_buf_offset - 1] += carry;
415             ps_stream->i4_zero_bytes_run = 0;
416         }
417 
418         /*        Insert outstanding bytes (if any)         */
419         while (u4_out_standing_bytes)
420         {
421             UWORD8 u1_0_or_ff = carry ? 0 : 0xFF;
422 
423             status |= ih264e_put_byte_epb(ps_stream, u1_0_or_ff);
424 
425             u4_out_standing_bytes--;
426         }
427         ps_cab_enc_env->u4_out_standing_bytes = 0;
428 
429         /*        Insert the leading byte                   */
430         lead_byte &= 0xFF;
431         status |= ih264e_put_byte_epb(ps_stream, lead_byte);
432     }
433     return status;
434 }
435 
436 
437 
438 
439  /**
440  ******************************************************************************
441  *
442  *  @brief Codes a bin based on probablilty and mps packed context model
443  *
444  *  @par   Description
445  *  1. Apart from encoding bin, context model is updated as per state transition
446  *  2. Range and Low renormalization is done based on bin and original state
447  *  3. After renorm bistream is updated (if required)
448  *
449  *  @param[in]   ps_cabac
450  *  pointer to cabac context (handle)
451  *
452  *  @param[in]   bin
453  *  bin(boolean) to be encoded
454  *
455  *  @param[in]  pu1_bin_ctxts
456  *  index of cabac context model containing pState[bits 5-0] | MPS[bit6]
457  *
458  *  @return
459  *
460  ******************************************************************************
461   */
ih264e_cabac_encode_bin(cabac_ctxt_t * ps_cabac,WORD32 bin,bin_ctxt_model * pu1_bin_ctxts)462 void ih264e_cabac_encode_bin(cabac_ctxt_t *ps_cabac, WORD32 bin,
463                              bin_ctxt_model *pu1_bin_ctxts)
464 {
465 
466     encoding_envirnoment_t *ps_cab_enc_env = &(ps_cabac->s_cab_enc_env);
467     UWORD32 u4_range = ps_cab_enc_env->u4_code_int_range;
468     UWORD32 u4_low = ps_cab_enc_env->u4_code_int_low;
469     UWORD32 u4_rlps;
470     UWORD8 state_mps = (*pu1_bin_ctxts) & 0x3F;
471     UWORD8 u1_mps = !!((*pu1_bin_ctxts) & (0x40));
472     WORD32 shift;
473     UWORD32 u4_table_val;
474     /* Sanity checks */
475     ASSERT((bin == 0) || (bin == 1));
476     ASSERT((u4_range >= 256) && (u4_range < 512));
477 
478     /* Get the lps range from LUT based on quantized range and state */
479     u4_table_val= gau4_ih264_cabac_table[state_mps][(u4_range >> 6) & 0x3];
480     u4_rlps = u4_table_val & 0xFF;
481     u4_range -= u4_rlps;
482 
483     /* check if bin is mps or lps */
484     if (u1_mps ^ bin)
485     {
486         /* lps path;  L= L + R; R = RLPS */
487         u4_low += u4_range;
488         u4_range = u4_rlps;
489         if (state_mps == 0)
490         {
491             /* MPS(CtxIdx) = 1 - MPS(CtxIdx) */
492             u1_mps = 1 - u1_mps;
493         } /* update the context model from state transition LUT */
494 
495         state_mps =  (u4_table_val >> 15) & 0x3F;
496     }
497     else
498     { /* update the context model from state transition LUT */
499         state_mps =  (u4_table_val >> 8) & 0x3F;
500     }
501 
502     (*pu1_bin_ctxts) = (u1_mps << 6) | state_mps;
503 
504         /*****************************************************************/
505         /* Renormalization; calculate bits generated based on range(R)   */
506         /* Note : 6 <= R < 512; R is 2 only for terminating encode       */
507         /*****************************************************************/
508         GETRANGE(shift, u4_range);
509         shift   = 9 - shift;
510         u4_low   <<= shift;
511         u4_range <<= shift;
512 
513         /* bits to be inserted in the bitstream */
514         ps_cab_enc_env->u4_bits_gen += shift;
515         ps_cab_enc_env->u4_code_int_range = u4_range;
516         ps_cab_enc_env->u4_code_int_low   = u4_low;
517 
518         /* generate stream when a byte is ready */
519         if (ps_cab_enc_env->u4_bits_gen > CABAC_BITS)
520         {
521             ih264e_cabac_put_byte(ps_cabac);
522         }
523 
524 }
525 
526 
527 
528 
529  /**
530  *******************************************************************************
531  *
532  * @brief
533  *  Encoding process for a binary decision :implements encoding process of a decision
534  *  as defined in 9.3.4.2 . This function encodes multiple bins, of a symbol. Implements
535  *  flowchart Figure 9-7( ITU_T_H264-201402)
536  *
537  * @param[in] u4_bins
538  * array of bin values
539  *
540  * @param[in] i1_bins_len
541  *  Length of bins, maximum 32
542  *
543  * @param[in] u4_ctx_inc
544  *  CtxInc, byte0- bin0, byte1-bin1 ..
545  *
546  * @param[in] i1_valid_len
547  *  valid length of bins, after that CtxInc is constant
548  *
549  * @param[in] pu1_bin_ctxt_type
550  *  Pointer to binary contexts
551 
552  * @param[in] ps_cabac
553  *  Pointer to cabac_context_structure
554  *
555  * @returns
556  *
557  * @remarks
558  *  None
559  *
560  *******************************************************************************
561  */
ih264e_encode_decision_bins(UWORD32 u4_bins,WORD8 i1_bins_len,UWORD32 u4_ctx_inc,WORD8 i1_valid_len,bin_ctxt_model * pu1_bin_ctxt_type,cabac_ctxt_t * ps_cabac)562 void ih264e_encode_decision_bins(UWORD32 u4_bins, WORD8 i1_bins_len,
563                                  UWORD32 u4_ctx_inc, WORD8 i1_valid_len,
564                                  bin_ctxt_model *pu1_bin_ctxt_type,
565                                  cabac_ctxt_t *ps_cabac)
566 {
567     WORD8 i;
568     UWORD8 u1_ctx_inc, u1_bin;
569 
570     for (i = 0; i < i1_bins_len; i++)
571     {
572         u1_bin = (u4_bins & 0x01);
573         u4_bins = u4_bins >> 1;
574         u1_ctx_inc = u4_ctx_inc & 0x0f;
575         if (i < i1_valid_len)
576             u4_ctx_inc = u4_ctx_inc >> 4;
577         /* Encode the bin */
578         ih264e_cabac_encode_bin(ps_cabac, u1_bin,
579                                 pu1_bin_ctxt_type + u1_ctx_inc);
580     }
581 
582 }
583 
584 
585 
586 
587 
588 
589 /**
590  *******************************************************************************
591  * @brief
592  *  Encoding process for a binary decision before termination:Encoding process
593  *  of a termination(9.3.4.5 :ITU_T_H264-201402) . Explained in flowchart 9-11.
594  *
595  * @param[in] ps_cabac
596  *  Pointer to cabac structure
597  *
598  * @param[in] term_bin
599  *  Symbol value, end of slice or not, term_bin is binary
600  *
601  * @returns
602  *
603  * @remarks
604  *  None
605  *
606  *******************************************************************************
607  */
ih264e_cabac_encode_terminate(cabac_ctxt_t * ps_cabac,WORD32 term_bin)608 void ih264e_cabac_encode_terminate(cabac_ctxt_t *ps_cabac, WORD32 term_bin)
609 {
610 
611     encoding_envirnoment_t *ps_cab_enc_env = &(ps_cabac->s_cab_enc_env);
612 
613     UWORD32 u4_range = ps_cab_enc_env->u4_code_int_range;
614     UWORD32 u4_low = ps_cab_enc_env->u4_code_int_low;
615     UWORD32 u4_rlps;
616     WORD32 shift;
617 
618     /* Sanity checks */
619     ASSERT((u4_range >= 256) && (u4_range < 512));
620     ASSERT((term_bin == 0) || (term_bin == 1));
621 
622     /*  term_bin = 1 has lps range = 2 */
623     u4_rlps = 2;
624     u4_range -= u4_rlps;
625 
626     /* if terminate L is incremented by curR and R=2 */
627     if (term_bin)
628     {
629         /* lps path;  L= L + R; R = RLPS */
630         u4_low += u4_range;
631         u4_range = u4_rlps;
632     }
633 
634     /*****************************************************************/
635     /* Renormalization; calculate bits generated based on range(R)   */
636     /* Note : 6 <= R < 512; R is 2 only for terminating encode       */
637     /*****************************************************************/
638     GETRANGE(shift, u4_range);
639     shift = 9 - shift;
640     u4_low <<= shift;
641     u4_range <<= shift;
642 
643     /* bits to be inserted in the bitstream */
644     ps_cab_enc_env->u4_bits_gen += shift;
645     ps_cab_enc_env->u4_code_int_range = u4_range;
646     ps_cab_enc_env->u4_code_int_low = u4_low;
647 
648     /* generate stream when a byte is ready */
649     if (ps_cab_enc_env->u4_bits_gen > CABAC_BITS)
650     {
651         ih264e_cabac_put_byte(ps_cabac);
652     }
653 
654     if (term_bin)
655     {
656         ih264e_cabac_flush(ps_cabac);
657     }
658 
659 }
660 
661 
662 /**
663  *******************************************************************************
664  * @brief
665  * Bypass encoding process for binary decisions:  Explained (9.3.4.4 :ITU_T_H264-201402)
666  * , flowchart 9-10.
667  *
668  *  @param[ino]  ps_cabac : pointer to cabac context (handle)
669  *
670  *  @param[in]   bin :  bypass bin(0/1) to be encoded
671  *
672  *  @returns
673  *
674  *  @remarks
675  *  None
676  *
677  *******************************************************************************
678  */
679 
ih264e_cabac_encode_bypass_bin(cabac_ctxt_t * ps_cabac,WORD32 bin)680 void ih264e_cabac_encode_bypass_bin(cabac_ctxt_t *ps_cabac, WORD32 bin)
681 {
682 
683     encoding_envirnoment_t *ps_cab_enc_env = &(ps_cabac->s_cab_enc_env);
684 
685     UWORD32 u4_range = ps_cab_enc_env->u4_code_int_range;
686     UWORD32 u4_low = ps_cab_enc_env->u4_code_int_low;
687 
688     /* Sanity checks */
689     ASSERT((u4_range >= 256) && (u4_range < 512));
690     ASSERT((bin == 0) || (bin == 1));
691 
692     u4_low <<= 1;
693     /* add range if bin is 1 */
694     if (bin)
695     {
696         u4_low += u4_range;
697     }
698 
699     /* 1 bit to be inserted in the bitstream */
700     ps_cab_enc_env->u4_bits_gen++;
701     ps_cab_enc_env->u4_code_int_low = u4_low;
702 
703     /* generate stream when a byte is ready */
704     if (ps_cab_enc_env->u4_bits_gen > CABAC_BITS)
705     {
706         ih264e_cabac_put_byte(ps_cabac);
707     }
708 
709 }
710 
711 
712  /**
713  ******************************************************************************
714  *
715  *  @brief Encodes a series of bypass bins (FLC bypass bins)
716  *
717  *  @par   Description
718  *  This function is more optimal than calling ih264e_cabac_encode_bypass_bin()
719  *  in a loop as cabac low, renorm and generating the stream (8bins at a time)
720  *  can be done in one operation
721  *
722  *  @param[inout]ps_cabac
723  *   pointer to cabac context (handle)
724  *
725  *  @param[in]   u4_bins
726  *   syntax element to be coded (as FLC bins)
727  *
728  *  @param[in]   num_bins
729  *   This is the FLC length for u4_sym
730  *
731  *  @return
732  *
733  ******************************************************************************
734  */
735 
ih264e_cabac_encode_bypass_bins(cabac_ctxt_t * ps_cabac,UWORD32 u4_bins,WORD32 num_bins)736 void ih264e_cabac_encode_bypass_bins(cabac_ctxt_t *ps_cabac, UWORD32 u4_bins,
737                                      WORD32 num_bins)
738 {
739 
740     encoding_envirnoment_t *ps_cab_enc_env = &(ps_cabac->s_cab_enc_env);
741 
742     UWORD32 u4_range = ps_cab_enc_env->u4_code_int_range;
743     WORD32 next_byte;
744 
745     /* Sanity checks */
746     ASSERT((num_bins < 33) && (num_bins > 0));
747     ASSERT((u4_range >= 256) && (u4_range < 512));
748 
749     /* Compute bit always to populate the trace */
750     /* increment bits generated by num_bins */
751 
752     /* Encode 8bins at a time and put in the bit-stream */
753     while (num_bins > 8)
754     {
755         num_bins -= 8;
756 
757         next_byte = (u4_bins >> (num_bins)) & 0xff;
758 
759         /*  L = (L << 8) +  (R * next_byte) */
760         ps_cab_enc_env->u4_code_int_low <<= 8;
761         ps_cab_enc_env->u4_code_int_low += (next_byte * u4_range);
762         ps_cab_enc_env->u4_bits_gen += 8;
763 
764         if (ps_cab_enc_env->u4_bits_gen > CABAC_BITS)
765         {
766             /*  insert the leading byte of low into stream */
767             ih264e_cabac_put_byte(ps_cabac);
768         }
769     }
770 
771     /* Update low with remaining bins and return */
772     next_byte = (u4_bins & ((1 << num_bins) - 1));
773 
774     ps_cab_enc_env->u4_code_int_low <<= num_bins;
775     ps_cab_enc_env->u4_code_int_low += (next_byte * u4_range);
776     ps_cab_enc_env->u4_bits_gen += num_bins;
777 
778     if (ps_cab_enc_env->u4_bits_gen > CABAC_BITS)
779     {
780         /*  insert the leading byte of low into stream */
781         ih264e_cabac_put_byte(ps_cabac);
782     }
783 
784 }
785