/* * H.265 video codec. * Copyright (c) 2013-2014 struktur AG, Dirk Farin * * This file is part of libde265. * * libde265 is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as * published by the Free Software Foundation, either version 3 of * the License, or (at your option) any later version. * * libde265 is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with libde265. If not, see . */ #include "cabac.h" #include "util.h" #include #include #include #include #define INITIAL_CABAC_BUFFER_CAPACITY 4096 static const uint8_t LPS_table[64][4] = { { 128, 176, 208, 240}, { 128, 167, 197, 227}, { 128, 158, 187, 216}, { 123, 150, 178, 205}, { 116, 142, 169, 195}, { 111, 135, 160, 185}, { 105, 128, 152, 175}, { 100, 122, 144, 166}, { 95, 116, 137, 158}, { 90, 110, 130, 150}, { 85, 104, 123, 142}, { 81, 99, 117, 135}, { 77, 94, 111, 128}, { 73, 89, 105, 122}, { 69, 85, 100, 116}, { 66, 80, 95, 110}, { 62, 76, 90, 104}, { 59, 72, 86, 99}, { 56, 69, 81, 94}, { 53, 65, 77, 89}, { 51, 62, 73, 85}, { 48, 59, 69, 80}, { 46, 56, 66, 76}, { 43, 53, 63, 72}, { 41, 50, 59, 69}, { 39, 48, 56, 65}, { 37, 45, 54, 62}, { 35, 43, 51, 59}, { 33, 41, 48, 56}, { 32, 39, 46, 53}, { 30, 37, 43, 50}, { 29, 35, 41, 48}, { 27, 33, 39, 45}, { 26, 31, 37, 43}, { 24, 30, 35, 41}, { 23, 28, 33, 39}, { 22, 27, 32, 37}, { 21, 26, 30, 35}, { 20, 24, 29, 33}, { 19, 23, 27, 31}, { 18, 22, 26, 30}, { 17, 21, 25, 28}, { 16, 20, 23, 27}, { 15, 19, 22, 25}, { 14, 18, 21, 24}, { 14, 17, 20, 23}, { 13, 16, 19, 22}, { 12, 15, 18, 21}, { 12, 14, 17, 20}, { 11, 14, 16, 19}, { 11, 13, 15, 18}, { 10, 12, 15, 17}, { 10, 12, 14, 16}, { 9, 11, 13, 15}, { 9, 11, 12, 14}, { 8, 10, 12, 14}, { 8, 9, 11, 13}, { 7, 9, 11, 12}, { 7, 9, 10, 12}, { 7, 8, 10, 11}, { 6, 8, 9, 11}, { 6, 7, 9, 10}, { 6, 7, 8, 9}, { 2, 2, 2, 2} }; static const uint8_t renorm_table[32] = { 6, 5, 4, 4, 3, 3, 3, 3, 2, 2, 2, 2, 2, 2, 2, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 }; static const uint8_t next_state_MPS[64] = { 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, 17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32, 33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48, 49,50,51,52,53,54,55,56,57,58,59,60,61,62,62,63 }; static const uint8_t next_state_LPS[64] = { 0,0,1,2,2,4,4,5,6,7,8,9,9,11,11,12, 13,13,15,15,16,16,18,18,19,19,21,21,22,22,23,24, 24,25,26,26,27,27,28,29,29,30,30,30,31,32,32,33, 33,33,34,34,35,35,35,36,36,36,37,37,37,38,38,63 }; #ifdef DE265_LOG_TRACE int logcnt=1; #endif void init_CABAC_decoder(CABAC_decoder* decoder, uint8_t* bitstream, int length) { assert(length >= 0); decoder->bitstream_start = bitstream; decoder->bitstream_curr = bitstream; decoder->bitstream_end = bitstream+length; } void init_CABAC_decoder_2(CABAC_decoder* decoder) { int length = decoder->bitstream_end - decoder->bitstream_curr; decoder->range = 510; decoder->bits_needed = 8; decoder->value = 0; if (length>0) { decoder->value = (*decoder->bitstream_curr++) << 8; decoder->bits_needed-=8; } if (length>1) { decoder->value |= (*decoder->bitstream_curr++); decoder->bits_needed-=8; } logtrace(LogCABAC,"[%3d] init_CABAC_decode_2 r:%x v:%x\n", logcnt, decoder->range, decoder->value); } int decode_CABAC_bit(CABAC_decoder* decoder, context_model* model) { logtrace(LogCABAC,"[%3d] decodeBin r:%x v:%x state:%d\n",logcnt,decoder->range, decoder->value, model->state); int decoded_bit; int LPS = LPS_table[model->state][ ( decoder->range >> 6 ) - 4 ]; decoder->range -= LPS; uint32_t scaled_range = decoder->range << 7; logtrace(LogCABAC,"[%3d] sr:%x v:%x\n",logcnt,scaled_range, decoder->value); if (decoder->value < scaled_range) { logtrace(LogCABAC,"[%3d] MPS\n",logcnt); // MPS path decoded_bit = model->MPSbit; model->state = next_state_MPS[model->state]; if (scaled_range < ( 256 << 7 ) ) { // scaled range, highest bit (15) not set decoder->range = scaled_range >> 6; // shift range by one bit decoder->value <<= 1; // shift value by one bit decoder->bits_needed++; if (decoder->bits_needed == 0) { decoder->bits_needed = -8; if (decoder->bitstream_curr < decoder->bitstream_end) { decoder->value |= *decoder->bitstream_curr++; } } } } else { logtrace(LogCABAC,"[%3d] LPS\n",logcnt); //printf("%d %d\n", model->state, 0); // LPS path decoder->value = (decoder->value - scaled_range); int num_bits = renorm_table[ LPS >> 3 ]; decoder->value <<= num_bits; decoder->range = LPS << num_bits; /* this is always >= 0x100 except for state 63, but state 63 is never used */ int num_bitsTab = renorm_table[ LPS >> 3 ]; assert(num_bits == num_bitsTab); decoded_bit = 1 - model->MPSbit; if (model->state==0) { model->MPSbit = 1-model->MPSbit; } model->state = next_state_LPS[model->state]; decoder->bits_needed += num_bits; if (decoder->bits_needed >= 0) { logtrace(LogCABAC,"bits_needed: %d\n", decoder->bits_needed); if (decoder->bitstream_curr < decoder->bitstream_end) { decoder->value |= (*decoder->bitstream_curr++) << decoder->bits_needed; } decoder->bits_needed -= 8; } } logtrace(LogCABAC,"[%3d] -> bit %d r:%x v:%x\n", logcnt, decoded_bit, decoder->range, decoder->value); #ifdef DE265_LOG_TRACE logcnt++; #endif return decoded_bit; } int decode_CABAC_term_bit(CABAC_decoder* decoder) { logtrace(LogCABAC,"CABAC term: range=%x\n", decoder->range); decoder->range -= 2; uint32_t scaledRange = decoder->range << 7; if (decoder->value >= scaledRange) { return 1; } else { // there is a while loop in the standard, but it will always be executed only once if (scaledRange < (256<<7)) { decoder->range = scaledRange >> 6; decoder->value *= 2; decoder->bits_needed++; if (decoder->bits_needed==0) { decoder->bits_needed = -8; if (decoder->bitstream_curr < decoder->bitstream_end) { decoder->value += (*decoder->bitstream_curr++); } } } return 0; } } int decode_CABAC_bypass(CABAC_decoder* decoder) { logtrace(LogCABAC,"[%3d] bypass r:%x v:%x\n",logcnt,decoder->range, decoder->value); decoder->value <<= 1; decoder->bits_needed++; if (decoder->bits_needed >= 0) { if (decoder->bitstream_end > decoder->bitstream_curr) { decoder->bits_needed = -8; decoder->value |= *decoder->bitstream_curr++; } } int bit; uint32_t scaled_range = decoder->range << 7; if (decoder->value >= scaled_range) { decoder->value -= scaled_range; bit=1; } else { bit=0; } logtrace(LogCABAC,"[%3d] -> bit %d r:%x v:%x\n", logcnt, bit, decoder->range, decoder->value); #ifdef DE265_LOG_TRACE logcnt++; #endif return bit; } int decode_CABAC_TU_bypass(CABAC_decoder* decoder, int cMax) { for (int i=0;irange, decoder->value, nBits); decoder->value <<= nBits; decoder->bits_needed+=nBits; if (decoder->bits_needed >= 0) { if (decoder->bitstream_end > decoder->bitstream_curr) { int input = *decoder->bitstream_curr++; input <<= decoder->bits_needed; decoder->bits_needed -= 8; decoder->value |= input; } } uint32_t scaled_range = decoder->range << 7; int value = decoder->value / scaled_range; if (unlikely(value>=(1<value -= value * scaled_range; logtrace(LogCABAC,"[%3d] -> value %d r:%x v:%x\n", logcnt+nBits-1, value, decoder->range, decoder->value); #ifdef DE265_LOG_TRACE logcnt+=nBits; #endif return value; } int decode_CABAC_FL_bypass(CABAC_decoder* decoder, int nBits) { int value=0; if (likely(nBits<=8)) { if (nBits==0) { return 0; } // we could use decode_CABAC_bypass() for a single bit, but this seems to be slower #if 0 else if (nBits==1) { value = decode_CABAC_bypass(decoder); } #endif else { value = decode_CABAC_FL_bypass_parallel(decoder,nBits); } } else { value = decode_CABAC_FL_bypass_parallel(decoder,8); nBits-=8; while (nBits--) { value <<= 1; value |= decode_CABAC_bypass(decoder); } } logtrace(LogCABAC," -> FL: %d\n", value); return value; } int decode_CABAC_TR_bypass(CABAC_decoder* decoder, int cRiceParam, int cTRMax) { int prefix = decode_CABAC_TU_bypass(decoder, cTRMax>>cRiceParam); if (prefix==4) { // TODO check: constant 4 only works for coefficient decoding return cTRMax; } int suffix = decode_CABAC_FL_bypass(decoder, cRiceParam); return (prefix << cRiceParam) | suffix; } #define MAX_PREFIX 32 int decode_CABAC_EGk_bypass(CABAC_decoder* decoder, int k) { int base=0; int n=k; for (;;) { int bit = decode_CABAC_bypass(decoder); if (bit==0) break; else { base += 1<=8) { append_byte((vlc_buffer >> (vlc_buffer_len-8)) & 0xFF); vlc_buffer_len -= 8; } } void CABAC_encoder::write_uvlc(int value) { assert(value>=0); int nLeadingZeros=0; int base=0; int range=1; while (value>=base+range) { base += range; range <<= 1; nLeadingZeros++; } write_bits((1<0) write_uvlc(2*value-1); else write_uvlc(-2*value); } void CABAC_encoder_bitstream::flush_VLC() { while (vlc_buffer_len>=8) { append_byte((vlc_buffer >> (vlc_buffer_len-8)) & 0xFF); vlc_buffer_len -= 8; } if (vlc_buffer_len>0) { append_byte(vlc_buffer << (8-vlc_buffer_len)); vlc_buffer_len = 0; } vlc_buffer = 0; } void CABAC_encoder_bitstream::skip_bits(int nBits) { while (nBits>=8) { write_bits(0,8); nBits-=8; } if (nBits>0) { write_bits(0,nBits); } } int CABAC_encoder_bitstream::number_free_bits_in_byte() const { if ((vlc_buffer_len % 8)==0) return 0; return 8- (vlc_buffer_len % 8); } void CABAC_encoder_bitstream::check_size_and_resize(int nBytes) { if (data_size+nBytes > data_capacity) { // 1 extra byte for stuffing if (data_capacity==0) { data_capacity = INITIAL_CABAC_BUFFER_CAPACITY; } else { data_capacity *= 2; } data_mem = (uint8_t*)realloc(data_mem,data_capacity); } } void CABAC_encoder_bitstream::append_byte(int byte) { check_size_and_resize(2); // --- emulation prevention --- /* These byte sequences may never occur in the bitstream: 0x000000 / 0x000001 / 0x000002 Hence, we have to add a 0x03 before the third byte. We also have to add a 0x03 for this sequence: 0x000003, because the escape byte itself also has to be escaped. */ // S0 --(0)--> S1 --(0)--> S2 --(0,1,2,3)--> add stuffing if (byte<=3) { /**/ if (state< 2 && byte==0) { state++; } else if (state==2 && byte<=3) { data_mem[ data_size++ ] = 3; if (byte==0) state=1; else state=0; } else { state=0; } } else { state=0; } // write actual data byte data_mem[ data_size++ ] = byte; } void CABAC_encoder_bitstream::write_startcode() { check_size_and_resize(3); data_mem[ data_size+0 ] = 0; data_mem[ data_size+1 ] = 0; data_mem[ data_size+2 ] = 1; data_size+=3; } void CABAC_encoder_bitstream::init_CABAC() { range = 510; low = 0; bits_left = 23; buffered_byte = 0xFF; num_buffered_bytes = 0; } void CABAC_encoder_bitstream::flush_CABAC() { if (low >> (32 - bits_left)) { append_byte(buffered_byte + 1); while (num_buffered_bytes > 1) { append_byte(0x00); num_buffered_bytes--; } low -= 1 << (32 - bits_left); } else { if (num_buffered_bytes > 0) { append_byte(buffered_byte); } while (num_buffered_bytes > 1) { append_byte(0xff); num_buffered_bytes--; } } // printf("low: %08x nbits left:%d filled:%d\n",low,bits_left,32-bits_left); write_bits(low >> 8, 24-bits_left); } void CABAC_encoder_bitstream::write_out() { //logtrace(LogCABAC,"low = %08x (bits_left=%d)\n",low,bits_left); int leadByte = low >> (24 - bits_left); bits_left += 8; low &= 0xffffffffu >> bits_left; //logtrace(LogCABAC,"write byte %02x\n",leadByte); //logtrace(LogCABAC,"-> low = %08x\n",low); if (leadByte == 0xff) { num_buffered_bytes++; } else { if (num_buffered_bytes > 0) { int carry = leadByte >> 8; int byte = buffered_byte + carry; buffered_byte = leadByte & 0xff; append_byte(byte); byte = ( 0xff + carry ) & 0xff; while ( num_buffered_bytes > 1 ) { append_byte(byte); num_buffered_bytes--; } } else { num_buffered_bytes = 1; buffered_byte = leadByte; } } } void CABAC_encoder_bitstream::testAndWriteOut() { // logtrace(LogCABAC,"bits_left = %d\n",bits_left); if (bits_left < 12) { write_out(); } } #ifdef DE265_LOG_TRACE int encBinCnt=1; #endif void CABAC_encoder_bitstream::write_CABAC_bit(int modelIdx, int bin) { context_model* model = &(*mCtxModels)[modelIdx]; //m_uiBinsCoded += m_binCountIncrement; //rcCtxModel.setBinsCoded( 1 ); logtrace(LogCABAC,"[%d] range=%x low=%x state=%d, bin=%d\n", encBinCnt, range,low, model->state,bin); /* printf("[%d] range=%x low=%x state=%d, bin=%d\n", encBinCnt, range,low, model->state,bin); printf("%d %d X\n",model->state,bin != model->MPSbit); */ #ifdef DE265_LOG_TRACE encBinCnt++; #endif uint32_t LPS = LPS_table[model->state][ ( range >> 6 ) - 4 ]; range -= LPS; if (bin != model->MPSbit) { //logtrace(LogCABAC,"LPS\n"); int num_bits = renorm_table[ LPS >> 3 ]; low = (low + range) << num_bits; range = LPS << num_bits; if (model->state==0) { model->MPSbit = 1-model->MPSbit; } model->state = next_state_LPS[model->state]; bits_left -= num_bits; } else { //logtrace(LogCABAC,"MPS\n"); model->state = next_state_MPS[model->state]; // renorm if (range >= 256) { return; } low <<= 1; range <<= 1; bits_left--; } testAndWriteOut(); } void CABAC_encoder_bitstream::write_CABAC_bypass(int bin) { logtrace(LogCABAC,"[%d] bypass = %d, range=%x\n",encBinCnt,bin,range); /* printf("[%d] bypass = %d, range=%x\n",encBinCnt,bin,range); printf("%d %d X\n",64, -1); */ #ifdef DE265_LOG_TRACE encBinCnt++; #endif // BinsCoded += m_binCountIncrement; low <<= 1; if (bin) { low += range; } bits_left--; testAndWriteOut(); } void CABAC_encoder::write_CABAC_TU_bypass(int value, int cMax) { for (int i=0;i0) { n--; write_CABAC_bypass(value & (1<= 256) { return; } else { low <<= 1; range <<= 1; bits_left--; } testAndWriteOut(); } static const uint32_t entropy_table[128] = { // -------------------- 200 -------------------- /* state= 0 */ 0x07d13 /* 0.977164 */, 0x08255 /* 1.018237 */, /* state= 1 */ 0x07738 /* 0.931417 */, 0x086ef /* 1.054179 */, /* state= 2 */ 0x0702b /* 0.876323 */, 0x0935a /* 1.151195 */, /* state= 3 */ 0x069e6 /* 0.827333 */, 0x09c7f /* 1.222650 */, /* state= 4 */ 0x062e8 /* 0.772716 */, 0x0a2c7 /* 1.271708 */, /* state= 5 */ 0x05c18 /* 0.719488 */, 0x0ae25 /* 1.360532 */, /* state= 6 */ 0x05632 /* 0.673414 */, 0x0b724 /* 1.430793 */, /* state= 7 */ 0x05144 /* 0.634904 */, 0x0c05d /* 1.502850 */, /* state= 8 */ 0x04bdf /* 0.592754 */, 0x0ccf2 /* 1.601145 */, /* state= 9 */ 0x0478d /* 0.559012 */, 0x0d57b /* 1.667843 */, /* state=10 */ 0x042ad /* 0.520924 */, 0x0de81 /* 1.738336 */, /* state=11 */ 0x03f4d /* 0.494564 */, 0x0e4b8 /* 1.786871 */, /* state=12 */ 0x03a9d /* 0.457945 */, 0x0f471 /* 1.909721 */, /* state=13 */ 0x037d5 /* 0.436201 */, 0x0fc56 /* 1.971385 */, /* state=14 */ 0x034c2 /* 0.412177 */, 0x10236 /* 2.017284 */, /* state=15 */ 0x031a6 /* 0.387895 */, 0x10d5c /* 2.104394 */, /* state=16 */ 0x02e62 /* 0.362383 */, 0x11b34 /* 2.212552 */, /* state=17 */ 0x02c20 /* 0.344752 */, 0x120b4 /* 2.255512 */, /* state=18 */ 0x029b8 /* 0.325943 */, 0x1294d /* 2.322672 */, /* state=19 */ 0x02791 /* 0.309143 */, 0x135e1 /* 2.420959 */, /* state=20 */ 0x02562 /* 0.292057 */, 0x13e37 /* 2.486077 */, /* state=21 */ 0x0230d /* 0.273846 */, 0x144fd /* 2.539000 */, /* state=22 */ 0x02193 /* 0.262308 */, 0x150c9 /* 2.631150 */, /* state=23 */ 0x01f5d /* 0.245026 */, 0x15ca0 /* 2.723641 */, /* state=24 */ 0x01de7 /* 0.233617 */, 0x162f9 /* 2.773246 */, /* state=25 */ 0x01c2f /* 0.220208 */, 0x16d99 /* 2.856259 */, /* state=26 */ 0x01a8e /* 0.207459 */, 0x17a93 /* 2.957634 */, /* state=27 */ 0x0195a /* 0.198065 */, 0x18051 /* 3.002477 */, /* state=28 */ 0x01809 /* 0.187778 */, 0x18764 /* 3.057759 */, /* state=29 */ 0x0164a /* 0.174144 */, 0x19460 /* 3.159206 */, /* state=30 */ 0x01539 /* 0.165824 */, 0x19f20 /* 3.243181 */, /* state=31 */ 0x01452 /* 0.158756 */, 0x1a465 /* 3.284334 */, /* state=32 */ 0x0133b /* 0.150261 */, 0x1b422 /* 3.407303 */, /* state=33 */ 0x0120c /* 0.140995 */, 0x1bce5 /* 3.475767 */, /* state=34 */ 0x01110 /* 0.133315 */, 0x1c394 /* 3.527962 */, /* state=35 */ 0x0104d /* 0.127371 */, 0x1d059 /* 3.627736 */, /* state=36 */ 0x00f8b /* 0.121451 */, 0x1d74b /* 3.681983 */, /* state=37 */ 0x00ef4 /* 0.116829 */, 0x1dfd0 /* 3.748540 */, /* state=38 */ 0x00e10 /* 0.109864 */, 0x1e6d3 /* 3.803335 */, /* state=39 */ 0x00d3f /* 0.103507 */, 0x1f925 /* 3.946462 */, /* state=40 */ 0x00cc4 /* 0.099758 */, 0x1fda7 /* 3.981667 */, /* state=41 */ 0x00c42 /* 0.095792 */, 0x203f8 /* 4.031012 */, /* state=42 */ 0x00b78 /* 0.089610 */, 0x20f7d /* 4.121014 */, /* state=43 */ 0x00afc /* 0.085830 */, 0x21dd6 /* 4.233102 */, /* state=44 */ 0x00a5e /* 0.081009 */, 0x22419 /* 4.282016 */, /* state=45 */ 0x00a1b /* 0.078950 */, 0x22a5e /* 4.331015 */, /* state=46 */ 0x00989 /* 0.074514 */, 0x23756 /* 4.432323 */, /* state=47 */ 0x0091b /* 0.071166 */, 0x24225 /* 4.516775 */, /* state=48 */ 0x008cf /* 0.068837 */, 0x2471a /* 4.555487 */, /* state=49 */ 0x00859 /* 0.065234 */, 0x25313 /* 4.649048 */, /* state=50 */ 0x00814 /* 0.063140 */, 0x25d67 /* 4.729721 */, /* state=51 */ 0x007b6 /* 0.060272 */, 0x2651f /* 4.790028 */, /* state=52 */ 0x0076e /* 0.058057 */, 0x2687c /* 4.816294 */, /* state=53 */ 0x00707 /* 0.054924 */, 0x27da7 /* 4.981661 */, /* state=54 */ 0x006d5 /* 0.053378 */, 0x28172 /* 5.011294 */, /* state=55 */ 0x00659 /* 0.049617 */, 0x28948 /* 5.072512 */, /* state=56 */ 0x00617 /* 0.047598 */, 0x297c5 /* 5.185722 */, /* state=57 */ 0x005dd /* 0.045814 */, 0x2a2df /* 5.272434 */, /* state=58 */ 0x005c1 /* 0.044965 */, 0x2a581 /* 5.293019 */, /* state=59 */ 0x00574 /* 0.042619 */, 0x2ad59 /* 5.354304 */, /* state=60 */ 0x0053b /* 0.040882 */, 0x2bba5 /* 5.465973 */, /* state=61 */ 0x0050c /* 0.039448 */, 0x2c596 /* 5.543651 */, /* state=62 */ 0x004e9 /* 0.038377 */, 0x2cd88 /* 5.605741 */, 0x00400 , 0x2d000 /* dummy, should never be used */ }; static const uint32_t entropy_table_orig[128] = { 0x07b23, 0x085f9, 0x074a0, 0x08cbc, 0x06ee4, 0x09354, 0x067f4, 0x09c1b, 0x060b0, 0x0a62a, 0x05a9c, 0x0af5b, 0x0548d, 0x0b955, 0x04f56, 0x0c2a9, 0x04a87, 0x0cbf7, 0x045d6, 0x0d5c3, 0x04144, 0x0e01b, 0x03d88, 0x0e937, 0x039e0, 0x0f2cd, 0x03663, 0x0fc9e, 0x03347, 0x10600, 0x03050, 0x10f95, 0x02d4d, 0x11a02, 0x02ad3, 0x12333, 0x0286e, 0x12cad, 0x02604, 0x136df, 0x02425, 0x13f48, 0x021f4, 0x149c4, 0x0203e, 0x1527b, 0x01e4d, 0x15d00, 0x01c99, 0x166de, 0x01b18, 0x17017, 0x019a5, 0x17988, 0x01841, 0x18327, 0x016df, 0x18d50, 0x015d9, 0x19547, 0x0147c, 0x1a083, 0x0138e, 0x1a8a3, 0x01251, 0x1b418, 0x01166, 0x1bd27, 0x01068, 0x1c77b, 0x00f7f, 0x1d18e, 0x00eda, 0x1d91a, 0x00e19, 0x1e254, 0x00d4f, 0x1ec9a, 0x00c90, 0x1f6e0, 0x00c01, 0x1fef8, 0x00b5f, 0x208b1, 0x00ab6, 0x21362, 0x00a15, 0x21e46, 0x00988, 0x2285d, 0x00934, 0x22ea8, 0x008a8, 0x239b2, 0x0081d, 0x24577, 0x007c9, 0x24ce6, 0x00763, 0x25663, 0x00710, 0x25e8f, 0x006a0, 0x26a26, 0x00672, 0x26f23, 0x005e8, 0x27ef8, 0x005ba, 0x284b5, 0x0055e, 0x29057, 0x0050c, 0x29bab, 0x004c1, 0x2a674, 0x004a7, 0x2aa5e, 0x0046f, 0x2b32f, 0x0041f, 0x2c0ad, 0x003e7, 0x2ca8d, 0x003ba, 0x2d323, 0x0010c, 0x3bfbb }; const uint32_t entropy_table_theory[128] = { 0x08000, 0x08000, 0x076da, 0x089a0, 0x06e92, 0x09340, 0x0670a, 0x09cdf, 0x06029, 0x0a67f, 0x059dd, 0x0b01f, 0x05413, 0x0b9bf, 0x04ebf, 0x0c35f, 0x049d3, 0x0ccff, 0x04546, 0x0d69e, 0x0410d, 0x0e03e, 0x03d22, 0x0e9de, 0x0397d, 0x0f37e, 0x03619, 0x0fd1e, 0x032ee, 0x106be, 0x02ffa, 0x1105d, 0x02d37, 0x119fd, 0x02aa2, 0x1239d, 0x02836, 0x12d3d, 0x025f2, 0x136dd, 0x023d1, 0x1407c, 0x021d2, 0x14a1c, 0x01ff2, 0x153bc, 0x01e2f, 0x15d5c, 0x01c87, 0x166fc, 0x01af7, 0x1709b, 0x0197f, 0x17a3b, 0x0181d, 0x183db, 0x016d0, 0x18d7b, 0x01595, 0x1971b, 0x0146c, 0x1a0bb, 0x01354, 0x1aa5a, 0x0124c, 0x1b3fa, 0x01153, 0x1bd9a, 0x01067, 0x1c73a, 0x00f89, 0x1d0da, 0x00eb7, 0x1da79, 0x00df0, 0x1e419, 0x00d34, 0x1edb9, 0x00c82, 0x1f759, 0x00bda, 0x200f9, 0x00b3c, 0x20a99, 0x00aa5, 0x21438, 0x00a17, 0x21dd8, 0x00990, 0x22778, 0x00911, 0x23118, 0x00898, 0x23ab8, 0x00826, 0x24458, 0x007ba, 0x24df7, 0x00753, 0x25797, 0x006f2, 0x26137, 0x00696, 0x26ad7, 0x0063f, 0x27477, 0x005ed, 0x27e17, 0x0059f, 0x287b6, 0x00554, 0x29156, 0x0050e, 0x29af6, 0x004cc, 0x2a497, 0x0048d, 0x2ae35, 0x00451, 0x2b7d6, 0x00418, 0x2c176, 0x003e2, 0x2cb15, 0x003af, 0x2d4b5, 0x0037f, 0x2de55 }; void CABAC_encoder_estim::write_CABAC_bit(int modelIdx, int bit) { context_model* model = &(*mCtxModels)[modelIdx]; //printf("[%d] state=%d, bin=%d\n", encBinCnt, model->state,bit); //encBinCnt++; int idx = model->state<<1; if (bit==model->MPSbit) { model->state = next_state_MPS[model->state]; } else { idx++; if (model->state==0) { model->MPSbit = 1-model->MPSbit; } model->state = next_state_LPS[model->state]; } mFracBits += entropy_table[idx]; //printf("-> %08lx %f\n",entropy_table[idx], entropy_table[idx] / float(1<<15)); } float CABAC_encoder::RDBits_for_CABAC_bin(int modelIdx, int bit) { context_model* model = &(*mCtxModels)[modelIdx]; int idx = model->state<<1; if (bit!=model->MPSbit) { idx++; } return entropy_table[idx] / float(1<<15); } void CABAC_encoder::write_CABAC_EGk(int val, int k) { while (val >= ( 1 << k ) ) { write_CABAC_bypass(1); val = val - ( 1 << k ); k++; } write_CABAC_bypass(0); while (k) { k--; write_CABAC_bypass((val >> k) & 1); } } void CABAC_encoder_estim_constant::write_CABAC_bit(int modelIdx, int bit) { context_model* model = &(*mCtxModels)[modelIdx]; int idx = model->state<<1; if (bit!=model->MPSbit) { idx++; } mFracBits += entropy_table[idx]; } #if 0 void printtab(int idx,int s) { printf("%d %f %f %f\n", s, double(entropy_table[idx])/0x8000, double(entropy_table_orig[idx])/0x8000, double(entropy_table_f265[idx])/0x8000); } void plot_tables() { for (int i=-62;i<=0;i++) { int idx = -i *2; int s = i; printtab(idx,s); } for (int i=0;i<=62;i++) { int idx = 2*i +1; int s = i; printtab(idx,s); } } #endif