/* * Common bit i/o utils * Copyright (c) 2000, 2001 Gerard Lantau. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include #include #include #ifdef __FreeBSD__ #include #endif #include #include #include "common.h" #define NDEBUG #include #include "../bswap.h" void init_put_bits(PutBitContext *s, UINT8 *buffer, int buffer_size, void *opaque, void (*write_data)(void *, UINT8 *, int)) { s->buf = buffer; s->buf_ptr = s->buf; s->buf_end = s->buf + buffer_size; s->bit_cnt=0; s->bit_buf=0; s->data_out_size = 0; s->write_data = write_data; s->opaque = opaque; } static void flush_buffer(PutBitContext *s) { int size; if (s->write_data) { size = s->buf_ptr - s->buf; if (size > 0) s->write_data(s->opaque, s->buf, size); s->buf_ptr = s->buf; s->data_out_size += size; } } void put_bits(PutBitContext *s, int n, unsigned int value) { unsigned int bit_buf; int bit_cnt; #ifdef STATS st_out_bit_counts[st_current_index] += n; #endif // printf("put_bits=%d %x\n", n, value); assert(n == 32 || value < (1U << n)); bit_buf = s->bit_buf; bit_cnt = s->bit_cnt; // printf("n=%d value=%x cnt=%d buf=%x\n", n, value, bit_cnt, bit_buf); /* XXX: optimize */ if (n < (32-bit_cnt)) { bit_buf |= value << (32 - n - bit_cnt); bit_cnt+=n; } else { bit_buf |= value >> (n + bit_cnt - 32); *(UINT32 *)s->buf_ptr = htonl(bit_buf); //printf("bitbuf = %08x\n", bit_buf); s->buf_ptr+=4; if (s->buf_ptr >= s->buf_end) flush_buffer(s); bit_cnt=bit_cnt + n - 32; if (bit_cnt == 0) { bit_buf = 0; } else { bit_buf = value << (32 - bit_cnt); } } s->bit_buf = bit_buf; s->bit_cnt = bit_cnt; } /* return the number of bits output */ long long get_bit_count(PutBitContext *s) { return (s->buf_ptr - s->buf + s->data_out_size) * 8 + (long long)s->bit_cnt; } void align_put_bits(PutBitContext *s) { put_bits(s,(8 - s->bit_cnt) & 7,0); } /* pad the end of the output stream with zeros */ void flush_put_bits(PutBitContext *s) { while (s->bit_cnt > 0) { /* XXX: should test end of buffer */ *s->buf_ptr++=s->bit_buf >> 24; s->bit_buf<<=8; s->bit_cnt-=8; } flush_buffer(s); s->bit_cnt=0; s->bit_buf=0; } /* for jpeg : espace 0xff with 0x00 after it */ void jput_bits(PutBitContext *s, int n, unsigned int value) { unsigned int bit_buf, b; int bit_cnt, i; assert(n == 32 || value < (1U << n)); bit_buf = s->bit_buf; bit_cnt = s->bit_cnt; //printf("n=%d value=%x cnt=%d buf=%x\n", n, value, bit_cnt, bit_buf); /* XXX: optimize */ if (n < (32-bit_cnt)) { bit_buf |= value << (32 - n - bit_cnt); bit_cnt+=n; } else { bit_buf |= value >> (n + bit_cnt - 32); /* handle escape */ for(i=0;i<4;i++) { b = (bit_buf >> 24); *(s->buf_ptr++) = b; if (b == 0xff) *(s->buf_ptr++) = 0; bit_buf <<= 8; } /* we flush the buffer sooner to handle worst case */ if (s->buf_ptr >= (s->buf_end - 8)) flush_buffer(s); bit_cnt=bit_cnt + n - 32; if (bit_cnt == 0) { bit_buf = 0; } else { bit_buf = value << (32 - bit_cnt); } } s->bit_buf = bit_buf; s->bit_cnt = bit_cnt; } /* pad the end of the output stream with zeros */ void jflush_put_bits(PutBitContext *s) { unsigned int b; while (s->bit_cnt > 0) { b = s->bit_buf >> 24; *s->buf_ptr++ = b; if (b == 0xff) *s->buf_ptr++ = 0; s->bit_buf<<=8; s->bit_cnt-=8; } flush_buffer(s); s->bit_cnt=0; s->bit_buf=0; } /* bit input functions */ void init_get_bits(GetBitContext *s, UINT8 *buffer, int buffer_size) { s->buf = buffer; s->buf_ptr = buffer; s->buf_end = buffer + buffer_size; s->bit_cnt = 0; s->bit_buf = 0; while (s->buf_ptr < s->buf_end && s->bit_cnt < 32) { s->bit_buf |= (*s->buf_ptr++ << (24 - s->bit_cnt)); s->bit_cnt += 8; } } /* n must be >= 1 and <= 32 */ unsigned int get_bits(GetBitContext *s, int n) { unsigned int val; int bit_cnt; unsigned int bit_buf; UINT8 *buf_ptr; #ifdef STATS st_bit_counts[st_current_index] += n; #endif bit_cnt = s->bit_cnt; bit_buf = s->bit_buf; bit_cnt -= n; if (bit_cnt >= 0) { /* most common case here */ val = bit_buf >> (32 - n); bit_buf <<= n; } else { val = bit_buf >> (32 - n); buf_ptr = s->buf_ptr; buf_ptr += 4; /* handle common case: we can read everything */ if (buf_ptr <= s->buf_end) { #if ARCH_X86 bit_buf = bswap_32(*((unsigned long*)(&buf_ptr[-4]))); #else bit_buf = (buf_ptr[-4] << 24) | (buf_ptr[-3] << 16) | (buf_ptr[-2] << 8) | (buf_ptr[-1]); #endif } else { buf_ptr -= 4; bit_buf = 0; if (buf_ptr < s->buf_end) bit_buf |= *buf_ptr++ << 24; if (buf_ptr < s->buf_end) bit_buf |= *buf_ptr++ << 16; if (buf_ptr < s->buf_end) bit_buf |= *buf_ptr++ << 8; if (buf_ptr < s->buf_end) bit_buf |= *buf_ptr++; } s->buf_ptr = buf_ptr; val |= bit_buf >> (32 + bit_cnt); bit_buf <<= - bit_cnt; bit_cnt += 32; } s->bit_buf = bit_buf; s->bit_cnt = bit_cnt; return val; } void align_get_bits(GetBitContext *s) { int n; n = s->bit_cnt & 7; if (n > 0) { get_bits(s, n); } } /* VLC decoding */ //#define DEBUG_VLC #define GET_DATA(v, table, i, wrap, size) \ {\ UINT8 *ptr = (UINT8 *)table + i * wrap;\ switch(size) {\ case 1:\ v = *(UINT8 *)ptr;\ break;\ case 2:\ v = *(UINT16 *)ptr;\ break;\ default:\ v = *(UINT32 *)ptr;\ break;\ }\ } static int alloc_table(VLC *vlc, int size) { int index; index = vlc->table_size; vlc->table_size += size; if (vlc->table_size > vlc->table_allocated) { vlc->table_allocated += (1 << vlc->bits); vlc->table_bits = realloc(vlc->table_bits, sizeof(INT8) * vlc->table_allocated); vlc->table_codes = realloc(vlc->table_codes, sizeof(INT16) * vlc->table_allocated); if (!vlc->table_bits || !vlc->table_codes) return -1; } return index; } static int build_table(VLC *vlc, int table_nb_bits, int nb_codes, const void *bits, int bits_wrap, int bits_size, const void *codes, int codes_wrap, int codes_size, UINT32 code_prefix, int n_prefix) { int i, j, k, n, table_size, table_index, nb, n1, index; UINT32 code; INT8 *table_bits; INT16 *table_codes; table_size = 1 << table_nb_bits; table_index = alloc_table(vlc, table_size); #ifdef DEBUG_VLC printf("new table index=%d size=%d code_prefix=%x n=%d\n", table_index, table_size, code_prefix, n_prefix); #endif if (table_index < 0) return -1; table_bits = &vlc->table_bits[table_index]; table_codes = &vlc->table_codes[table_index]; for(i=0;i 0 && (code >> n) == code_prefix) { if (n <= table_nb_bits) { /* no need to add another table */ j = (code << (table_nb_bits - n)) & (table_size - 1); nb = 1 << (table_nb_bits - n); for(k=0;k> n) & ((1 << table_nb_bits) - 1); #ifdef DEBUG_VLC printf("%4x: n=%d (subtable)\n", j, n); #endif /* compute table size */ n1 = -table_bits[j]; if (n > n1) n1 = n; table_bits[j] = -n1; } } } /* second pass : fill auxillary tables recursively */ for(i=0;i table_nb_bits) { n = table_nb_bits; table_bits[i] = -n; } index = build_table(vlc, n, nb_codes, bits, bits_wrap, bits_size, codes, codes_wrap, codes_size, (code_prefix << table_nb_bits) | i, n_prefix + table_nb_bits); if (index < 0) return -1; /* note: realloc has been done, so reload tables */ table_bits = &vlc->table_bits[table_index]; table_codes = &vlc->table_codes[table_index]; table_codes[i] = index; } } return table_index; } /* wrap and size allow to handle most types of storage. */ int init_vlc(VLC *vlc, int nb_bits, int nb_codes, const void *bits, int bits_wrap, int bits_size, const void *codes, int codes_wrap, int codes_size) { vlc->bits = nb_bits; vlc->table_bits = NULL; vlc->table_codes = NULL; vlc->table_allocated = 0; vlc->table_size = 0; #ifdef DEBUG_VLC printf("build table nb_codes=%d\n", nb_codes); #endif if (build_table(vlc, nb_bits, nb_codes, bits, bits_wrap, bits_size, codes, codes_wrap, codes_size, 0, 0) < 0) { if (vlc->table_bits) free(vlc->table_bits); if (vlc->table_codes) free(vlc->table_codes); return -1; } return 0; } void free_vlc(VLC *vlc) { free(vlc->table_bits); free(vlc->table_codes); } int get_vlc(GetBitContext *s, VLC *vlc) { int bit_cnt, code, n, nb_bits, index; UINT32 bit_buf; INT16 *table_codes; INT8 *table_bits; UINT8 *buf_ptr; SAVE_BITS(s); nb_bits = vlc->bits; table_codes = vlc->table_codes; table_bits = vlc->table_bits; for(;;) { SHOW_BITS(s, index, nb_bits); code = table_codes[index]; n = table_bits[index]; if (n > 0) { /* most common case */ FLUSH_BITS(n); #ifdef STATS st_bit_counts[st_current_index] += n; #endif break; } else if (n == 0) { return -1; } else { FLUSH_BITS(nb_bits); #ifdef STATS st_bit_counts[st_current_index] += nb_bits; #endif nb_bits = -n; table_codes = vlc->table_codes + code; table_bits = vlc->table_bits + code; } } RESTORE_BITS(s); return code; }