/proc/self/cwd/libfaad/hcr.c

Source
/*
** FAAD2 - Freeware Advanced Audio (AAC) Decoder including SBR decoding
** Copyright (C) 2003-2005 M. Bakker, Nero AG, http://www.nero.com
**
** 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
**
** Any non-GPL usage of this software or parts of this software is strictly
** forbidden.
**
** The "appropriate copyright message" mentioned in section 2c of the GPLv2
** must read: "Code from FAAD2 is copyright (c) Nero AG, www.nero.com"
**
** Commercial non-GPL licensing of this software is possible.
** For more info contact Nero AG through Mpeg4AAClicense@nero.com.
**
** $Id: hcr.c,v 1.26 2009/01/26 23:51:15 menno Exp $
**/

#include "common.h"
#include "structs.h"

#include <stdlib.h>

#include "specrec.h"
#include "huffman.h"

/* ISO/IEC 14496-3/Amd.1
 * 8.5.3.3: Huffman Codeword Reordering for AAC spectral data (HCR)
 *
 * HCR devides the spectral data in known fixed size segments, and
 * sorts it by the importance of the data. The importance is firstly
 * the (lower) position in the spectrum, and secondly the largest
 * value in the used codebook.
 * The most important data is written at the start of each segment
 * (at known positions), the remaining data is interleaved inbetween,
 * with the writing direction alternating.
 * Data length is not increased.
*/

#ifdef ERROR_RESILIENCE

/* 8.5.3.3.1 Pre-sorting */

#define NUM_CB      6
#define NUM_CB_ER   22
#define MAX_CB      32
#define VCB11_FIRST 16
#define VCB11_LAST  31

static const uint8_t PreSortCB_STD[NUM_CB] =
    { 11, 9, 7, 5, 3, 1};

static const uint8_t PreSortCB_ER[NUM_CB_ER] =
    { 11, 31, 30, 29, 28, 27, 26, 25, 24, 23, 22, 21, 20, 19, 18, 17, 16, 9, 7, 5, 3, 1};

/* 8.5.3.3.2 Derivation of segment width */

static const uint8_t maxCwLen[MAX_CB] = {0, 11, 9, 20, 16, 13, 11, 14, 12, 17, 14, 49,
    0, 0, 0, 0, 14, 17, 21, 21, 25, 25, 29, 29, 29, 29, 33, 33, 33, 37, 37, 41};

#define segmentWidth(cb)    min(maxCwLen[cb], ics->length_of_longest_codeword)

/* bit-twiddling helpers */
static const uint8_t  S[] = {1, 2, 4, 8, 16};
static const uint32_t B[] = {0x55555555, 0x33333333, 0x0F0F0F0F, 0x00FF00FF, 0x0000FFFF};

typedef struct
{
    uint8_t     cb;
    uint8_t     decoded;
    uint16_t  sp_offset;
    bits_t      bits;
} codeword_t;

static uint32_t reverse_word(uint32_t v)
{
    v = ((v >> S[0]) & B[0]) | ((v << S[0]) & ~B[0]);
    v = ((v >> S[1]) & B[1]) | ((v << S[1]) & ~B[1]);
    v = ((v >> S[2]) & B[2]) | ((v << S[2]) & ~B[2]);
    v = ((v >> S[3]) & B[3]) | ((v << S[3]) & ~B[3]);
    v = ((v >> S[4]) & B[4]) | ((v << S[4]) & ~B[4]);
    return v;
}

/* bits_t version */
static void rewrev_bits(bits_t *bits)
{
    if (bits->len == 0) return;
    if (bits->len <= 32) {
        bits->bufb = 0;
        bits->bufa = reverse_word(bits->bufa) >> (32 - bits->len);
    } else {
        /* last 32<>32 bit swap via rename */
        uint32_t lo = reverse_word(bits->bufb);
        uint32_t hi = reverse_word(bits->bufa);

        if (bits->len == 64) {
            bits->bufb = hi;
            bits->bufa = lo;
        } else {
            /* shift off low bits (this is really only one 64 bit shift) */
            bits->bufb = hi >> (64 - bits->len);
            bits->bufa = (lo >> (64 - bits->len)) | (hi << (bits->len - 32));
        }
    }
}


/* merge bits of a to b */
/* precondition: a->len + b->len <= 64 */
static void concat_bits(bits_t *b, bits_t *a)
{
    uint32_t bl, bh, al, ah;

    /* empty addend */
    if (a->len == 0) return;

    /* addend becomes result */
    if (b->len == 0)
    {
        *b = *a;
        return;
    }

    al = a->bufa;
    ah = a->bufb;

    if (b->len > 32)
    {
        /* (b->len - 32) is 1..31 */
        /* maskoff superfluous high b bits */
        bl = b->bufa;
        bh = b->bufb & ((1u << (b->len-32)) - 1);
        /* left shift a b->len bits */
        ah = al << (b->len - 32);
        al = 0;
    } else if (b->len == 32) {
        bl = b->bufa;
        bh = 0;
        ah = al;
        al = 0;
    } else {
        /* b->len is 1..31, (32 - b->len) is 1..31 */
        bl = b->bufa & ((1u << (b->len)) - 1);
        bh = 0;
        ah = (ah << (b->len)) | (al >> (32 - b->len));
        al = al << b->len;
    }

    /* merge */
    b->bufa = bl | al;
    b->bufb = bh | ah;

    b->len += a->len;
}

static uint8_t is_good_cb(uint8_t this_CB, uint8_t this_sec_CB)
{
    /* only want spectral data CB's */
    if ((this_sec_CB > ZERO_HCB && this_sec_CB <= ESC_HCB) || (this_sec_CB >= VCB11_FIRST && this_sec_CB <= VCB11_LAST))
    {
        if (this_CB < ESC_HCB)
        {
            /* normal codebook pairs */
            return ((this_sec_CB == this_CB) || (this_sec_CB == this_CB + 1));
        } else
        {
            /* escape codebook */
            return (this_sec_CB == this_CB);
        }
    }
    return 0;
}

static void read_segment(bits_t *segment, uint8_t segwidth, bitfile *ld)
{
    segment->len = segwidth;

     if (segwidth > 32)
     {
        segment->bufb = faad_getbits(ld, segwidth - 32);
        segment->bufa = faad_getbits(ld, 32);

    } else {
        segment->bufb = 0;
        segment->bufa = faad_getbits(ld, segwidth);
    }
}

static void fill_in_codeword(codeword_t *codeword, uint16_t index, uint16_t sp, uint8_t cb)
{
    codeword[index].sp_offset = sp;
    codeword[index].cb = cb;
    codeword[index].decoded = 0;
    codeword[index].bits.len = 0;
}

uint8_t reordered_spectral_data(NeAACDecStruct *hDecoder, ic_stream *ics,
                                bitfile *ld, int16_t *spectral_data)
{
    uint16_t PCWs_done;
    uint16_t numberOfSegments, numberOfSets, numberOfCodewords;

    codeword_t codeword[512];
    bits_t segment[512];

    uint16_t sp_offset[8];
    uint16_t g, i, sortloop, set, bitsread;
    /*uint16_t bitsleft, codewordsleft*/;
    uint8_t w_idx, sfb, this_CB, last_CB, this_sec_CB;

    const uint16_t nshort = hDecoder->frameLength/8;
    const uint16_t sp_data_len = ics->length_of_reordered_spectral_data;

    const uint8_t *PreSortCb;

    /* no data (e.g. silence) */
    if (sp_data_len == 0)
        return 0;

    /* since there is spectral data, at least one codeword has nonzero length */
    if (ics->length_of_longest_codeword == 0)
        return 10;

    if (sp_data_len < ics->length_of_longest_codeword)
        return 10;

    sp_offset[0] = 0;
    for (g = 1; g < ics->num_window_groups; g++)
    {
        sp_offset[g] = sp_offset[g-1] + nshort*ics->window_group_length[g-1];
    }

    PCWs_done = 0;
    numberOfSegments = 0;
    numberOfCodewords = 0;
    bitsread = 0;

    /* VCB11 code books in use */
    if (hDecoder->aacSectionDataResilienceFlag)
    {
        PreSortCb = PreSortCB_ER;
        last_CB = NUM_CB_ER;
    } else
    {
        PreSortCb = PreSortCB_STD;
        last_CB = NUM_CB;
    }

    /* step 1: decode PCW's (set 0), and stuff data in easier-to-use format */
    for (sortloop = 0; sortloop < last_CB; sortloop++)
    {
        /* select codebook to process this pass */
        this_CB = PreSortCb[sortloop];

        /* loop over sfbs */
        for (sfb = 0; sfb < ics->max_sfb; sfb++)
        {
            /* loop over all in this sfb, 4 lines per loop */
            for (w_idx = 0; 4*w_idx < (min(ics->swb_offset[sfb+1], ics->swb_offset_max) - ics->swb_offset[sfb]); w_idx++)
            {
                for(g = 0; g < ics->num_window_groups; g++)
                {
                    for (i = 0; i < ics->num_sec[g]; i++)
                    {
                        /* check whether sfb used here is the one we want to process */
                        if ((ics->sect_start[g][i] <= sfb) && (ics->sect_end[g][i] > sfb))
                        {
                            /* check whether codebook used here is the one we want to process */
                            this_sec_CB = ics->sect_cb[g][i];

                            if (is_good_cb(this_CB, this_sec_CB))
                            {
                                /* precalculate some stuff */
                                uint16_t sect_sfb_size = ics->sect_sfb_offset[g][sfb+1] - ics->sect_sfb_offset[g][sfb];
                                uint8_t inc = (this_sec_CB < FIRST_PAIR_HCB) ? QUAD_LEN : PAIR_LEN;
                                uint16_t group_cws_count = (4*ics->window_group_length[g])/inc;
                                uint8_t segwidth = segmentWidth(this_sec_CB);
                                uint16_t cws;

                                /* read codewords until end of sfb or end of window group (shouldn't only 1 trigger?) */
                                for (cws = 0; (cws < group_cws_count) && ((cws + w_idx*group_cws_count) < sect_sfb_size); cws++)
                                {
                                    uint16_t sp = sp_offset[g] + ics->sect_sfb_offset[g][sfb] + inc * (cws + w_idx*group_cws_count);

                                    /* read and decode PCW */
                                    if (!PCWs_done)
                                    {
                                        /* read in normal segments */
                                        if (bitsread + segwidth <= sp_data_len)
                                        {
                                            read_segment(&segment[numberOfSegments], segwidth, ld);
                                            bitsread += segwidth;

                                            huffman_spectral_data_2(this_sec_CB, &segment[numberOfSegments], &spectral_data[sp]);

                                            /* keep leftover bits */
                                            rewrev_bits(&segment[numberOfSegments]);

                                            numberOfSegments++;
                                        } else {  // sp_data_len - bitsread < segwidth
                                            /* remaining stuff after last segment, we unfortunately couldn't read
                                               this in earlier because it might not fit in 64 bits. since we already
                                               decoded (and removed) the PCW it is now should fit */
                                            if (bitsread < sp_data_len)
                                            {
                                                const uint8_t additional_bits = (uint8_t)(sp_data_len - bitsread);

                                                read_segment(&segment[numberOfSegments], additional_bits, ld);
                                                segment[numberOfSegments].len += segment[numberOfSegments-1].len;
                                                if (segment[numberOfSegments].len > 64)
                                                    return 10;
                                                rewrev_bits(&segment[numberOfSegments]);

                                                if (segment[numberOfSegments-1].len > 32)
                                                {
                                                    segment[numberOfSegments-1].bufb = segment[numberOfSegments].bufb +
                                                        showbits_hcr(&segment[numberOfSegments-1], segment[numberOfSegments-1].len - 32);
                                                    segment[numberOfSegments-1].bufa = segment[numberOfSegments].bufa +
                                                        showbits_hcr(&segment[numberOfSegments-1], 32);
                                                } else {
                                                    segment[numberOfSegments-1].bufa = segment[numberOfSegments].bufa +
                                                        showbits_hcr(&segment[numberOfSegments-1], segment[numberOfSegments-1].len);
                                                    segment[numberOfSegments-1].bufb = segment[numberOfSegments].bufb;
                                                }
                                                segment[numberOfSegments-1].len += additional_bits;
                                            }
                                            bitsread = sp_data_len;
                                            PCWs_done = 1;

                                            fill_in_codeword(codeword, 0, sp, this_sec_CB);
                                        }
                                    } else {
                                        fill_in_codeword(codeword, numberOfCodewords - numberOfSegments, sp, this_sec_CB);
                                    }
                                    numberOfCodewords++;
                                }
                            }
                        }
                    }
                 }
             }
         }
    }

    if (numberOfSegments == 0)
        return 10;

    numberOfSets = numberOfCodewords / numberOfSegments;

    /* step 2: decode nonPCWs */
    for (set = 1; set <= numberOfSets; set++)
    {
        uint16_t trial;

        for (trial = 0; trial < numberOfSegments; trial++)
        {
            uint16_t codewordBase;

            for (codewordBase = 0; codewordBase < numberOfSegments; codewordBase++)
            {
                const uint16_t segment_idx = (trial + codewordBase) % numberOfSegments;
                const uint16_t codeword_idx = codewordBase + set*numberOfSegments - numberOfSegments;

                /* data up */
                if (codeword_idx >= numberOfCodewords - numberOfSegments) break;

                if (!codeword[codeword_idx].decoded && segment[segment_idx].len > 0)
                {
                    uint8_t tmplen = segment[segment_idx].len + codeword[codeword_idx].bits.len;

                    if (tmplen > 64)
                    {
                      // Drop bits that do not fit concatenation result.
                      flushbits_hcr(&codeword[codeword_idx].bits, tmplen - 64);
                    }

                    if (codeword[codeword_idx].bits.len != 0)
                        concat_bits(&segment[segment_idx], &codeword[codeword_idx].bits);

                    tmplen = segment[segment_idx].len;

                    if (huffman_spectral_data_2(codeword[codeword_idx].cb, &segment[segment_idx],
                                               &spectral_data[codeword[codeword_idx].sp_offset]) >= 0)
                    {
                        codeword[codeword_idx].decoded = 1;
                    } else
                    {
                        codeword[codeword_idx].bits = segment[segment_idx];
                        codeword[codeword_idx].bits.len = tmplen;
                    }

                }
            }
        }
        for (i = 0; i < numberOfSegments; i++)
            rewrev_bits(&segment[i]);
    }

#if 0 // Seems to give false errors
    bitsleft = 0;

    for (i = 0; i < numberOfSegments && !bitsleft; i++)
        bitsleft += segment[i].len;

    if (bitsleft) return 10;

    codewordsleft = 0;

    for (i = 0; (i < numberOfCodewords - numberOfSegments) && (!codewordsleft); i++)
        if (!codeword[i].decoded)
                codewordsleft++;

    if (codewordsleft) return 10;
#endif


    return 0;

}
#endif

Coverage Report

Created: 2026-03-20 06:59

Line	Count	Source
1		/*
2		** FAAD2 - Freeware Advanced Audio (AAC) Decoder including SBR decoding
3		** Copyright (C) 2003-2005 M. Bakker, Nero AG, http://www.nero.com
4		**
5		** This program is free software; you can redistribute it and/or modify
6		** it under the terms of the GNU General Public License as published by
7		** the Free Software Foundation; either version 2 of the License, or
8		** (at your option) any later version.
9		**
10		** This program is distributed in the hope that it will be useful,
11		** but WITHOUT ANY WARRANTY; without even the implied warranty of
12		** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
13		** GNU General Public License for more details.
14		**
15		** You should have received a copy of the GNU General Public License
16		** along with this program; if not, write to the Free Software
17		** Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
18		**
19		** Any non-GPL usage of this software or parts of this software is strictly
20		** forbidden.
21		**
22		** The "appropriate copyright message" mentioned in section 2c of the GPLv2
23		** must read: "Code from FAAD2 is copyright (c) Nero AG, www.nero.com"
24		**
25		** Commercial non-GPL licensing of this software is possible.
26		** For more info contact Nero AG through Mpeg4AAClicense@nero.com.
27		**
28		** $Id: hcr.c,v 1.26 2009/01/26 23:51:15 menno Exp $
29		**/
30
31		#include "common.h"
32		#include "structs.h"
33
34		#include <stdlib.h>
35
36		#include "specrec.h"
37		#include "huffman.h"
38
39		/* ISO/IEC 14496-3/Amd.1
40		* 8.5.3.3: Huffman Codeword Reordering for AAC spectral data (HCR)
41		*
42		* HCR devides the spectral data in known fixed size segments, and
43		* sorts it by the importance of the data. The importance is firstly
44		* the (lower) position in the spectrum, and secondly the largest
45		* value in the used codebook.
46		* The most important data is written at the start of each segment
47		* (at known positions), the remaining data is interleaved inbetween,
48		* with the writing direction alternating.
49		* Data length is not increased.
50		*/
51
52		#ifdef ERROR_RESILIENCE
53
54		/* 8.5.3.3.1 Pre-sorting */
55
56	72	#define NUM_CB 6
57	1.83k	#define NUM_CB_ER 22
58		#define MAX_CB 32
59	325k	#define VCB11_FIRST 16
60	89.2k	#define VCB11_LAST 31
61
62		static const uint8_t PreSortCB_STD[NUM_CB] =
63		{ 11, 9, 7, 5, 3, 1};
64
65		static const uint8_t PreSortCB_ER[NUM_CB_ER] =
66		{ 11, 31, 30, 29, 28, 27, 26, 25, 24, 23, 22, 21, 20, 19, 18, 17, 16, 9, 7, 5, 3, 1};
67
68		/* 8.5.3.3.2 Derivation of segment width */
69
70		static const uint8_t maxCwLen[MAX_CB] = {0, 11, 9, 20, 16, 13, 11, 14, 12, 17, 14, 49,
71		0, 0, 0, 0, 14, 17, 21, 21, 25, 25, 29, 29, 29, 29, 33, 33, 33, 37, 37, 41};
72
73	32.5k	#define segmentWidth(cb) min(maxCwLen[cb], ics->length_of_longest_codeword)
74
75		/* bit-twiddling helpers */
76		static const uint8_t S[] = {1, 2, 4, 8, 16};
77		static const uint32_t B[] = {0x55555555, 0x33333333, 0x0F0F0F0F, 0x00FF00FF, 0x0000FFFF};
78
79		typedef struct
80		{
81		uint8_t cb;
82		uint8_t decoded;
83		uint16_t sp_offset;
84		bits_t bits;
85		} codeword_t;
86
87		static uint32_t reverse_word(uint32_t v)
88	107k	{
89	107k	v = ((v >> S[0]) & B[0]) \| ((v << S[0]) & ~B[0]);
90	107k	v = ((v >> S[1]) & B[1]) \| ((v << S[1]) & ~B[1]);
91	107k	v = ((v >> S[2]) & B[2]) \| ((v << S[2]) & ~B[2]);
92	107k	v = ((v >> S[3]) & B[3]) \| ((v << S[3]) & ~B[3]);
93	107k	v = ((v >> S[4]) & B[4]) \| ((v << S[4]) & ~B[4]);
94	107k	return v;
95	107k	}
96
97		/* bits_t version */
98		static void rewrev_bits(bits_t *bits)
99	135k	{
100	135k	if (bits->len == 0) return;
101	93.9k	if (bits->len <= 32) {
102	80.1k	bits->bufb = 0;
103	80.1k	bits->bufa = reverse_word(bits->bufa) >> (32 - bits->len);
104	80.1k	} else {
105		/* last 32<>32 bit swap via rename */
106	13.8k	uint32_t lo = reverse_word(bits->bufb);
107	13.8k	uint32_t hi = reverse_word(bits->bufa);
108
109	13.8k	if (bits->len == 64) {
110	20	bits->bufb = hi;
111	20	bits->bufa = lo;
112	13.8k	} else {
113		/* shift off low bits (this is really only one 64 bit shift) */
114	13.8k	bits->bufb = hi >> (64 - bits->len);
115	13.8k	bits->bufa = (lo >> (64 - bits->len)) \| (hi << (bits->len - 32));
116	13.8k	}
117	13.8k	}
118	93.9k	}
119
120
121		/* merge bits of a to b */
122		/* precondition: a->len + b->len <= 64 */
123		static void concat_bits(bits_t b, bits_t a)
124	4.84k	{
125	4.84k	uint32_t bl, bh, al, ah;
126
127		/* empty addend */
128	4.84k	if (a->len == 0) return;
129
130		/* addend becomes result */
131	4.84k	if (b->len == 0)
132	0	{
133	0	b = a;
134	0	return;
135	0	}
136
137	4.84k	al = a->bufa;
138	4.84k	ah = a->bufb;
139
140	4.84k	if (b->len > 32)
141	321	{
142		/* (b->len - 32) is 1..31 */
143		/* maskoff superfluous high b bits */
144	321	bl = b->bufa;
145	321	bh = b->bufb & ((1u << (b->len-32)) - 1);
146		/* left shift a b->len bits */
147	321	ah = al << (b->len - 32);
148	321	al = 0;
149	4.52k	} else if (b->len == 32) {
150	74	bl = b->bufa;
151	74	bh = 0;
152	74	ah = al;
153	74	al = 0;
154	4.45k	} else {
155		/* b->len is 1..31, (32 - b->len) is 1..31 */
156	4.45k	bl = b->bufa & ((1u << (b->len)) - 1);
157	4.45k	bh = 0;
158	4.45k	ah = (ah << (b->len)) \| (al >> (32 - b->len));
159	4.45k	al = al << b->len;
160	4.45k	}
161
162		/* merge */
163	4.84k	b->bufa = bl \| al;
164	4.84k	b->bufb = bh \| ah;
165
166	4.84k	b->len += a->len;
167	4.84k	}
168
169		static uint8_t is_good_cb(uint8_t this_CB, uint8_t this_sec_CB)
170	688k	{
171		/* only want spectral data CB's */
172	688k	if ((this_sec_CB > ZERO_HCB && this_sec_CB <= ESC_HCB) \|\| (this_sec_CB >= VCB11_FIRST && this_sec_CB <= VCB11_LAST))
173	615k	{
174	615k	if (this_CB < ESC_HCB)
175	162k	{
176		/* normal codebook pairs */
177	162k	return ((this_sec_CB == this_CB) \|\| (this_sec_CB == this_CB + 1));
178	162k	} else
179	453k	{
180		/* escape codebook */
181	453k	return (this_sec_CB == this_CB);
182	453k	}
183	615k	}
184	73.4k	return 0;
185	688k	}
186
187		static void read_segment(bits_t segment, uint8_t segwidth, bitfile ld)
188	56.3k	{
189	56.3k	segment->len = segwidth;
190
191	56.3k	if (segwidth > 32)
192	9.69k	{
193	9.69k	segment->bufb = faad_getbits(ld, segwidth - 32);
194	9.69k	segment->bufa = faad_getbits(ld, 32);
195
196	46.6k	} else {
197	46.6k	segment->bufb = 0;
198	46.6k	segment->bufa = faad_getbits(ld, segwidth);
199	46.6k	}
200	56.3k	}
201
202		static void fill_in_codeword(codeword_t *codeword, uint16_t index, uint16_t sp, uint8_t cb)
203	34.3k	{
204	34.3k	codeword[index].sp_offset = sp;
205	34.3k	codeword[index].cb = cb;
206	34.3k	codeword[index].decoded = 0;
207	34.3k	codeword[index].bits.len = 0;
208	34.3k	}
209
210		uint8_t reordered_spectral_data(NeAACDecStruct hDecoder, ic_stream ics,
211		bitfile ld, int16_t spectral_data)
212	4.92k	{
213	4.92k	uint16_t PCWs_done;
214	4.92k	uint16_t numberOfSegments, numberOfSets, numberOfCodewords;
215
216	4.92k	codeword_t codeword[512];
217	4.92k	bits_t segment[512];
218
219	4.92k	uint16_t sp_offset[8];
220	4.92k	uint16_t g, i, sortloop, set, bitsread;
221	4.92k	/uint16_t bitsleft, codewordsleft/;
222	4.92k	uint8_t w_idx, sfb, this_CB, last_CB, this_sec_CB;
223
224	4.92k	const uint16_t nshort = hDecoder->frameLength/8;
225	4.92k	const uint16_t sp_data_len = ics->length_of_reordered_spectral_data;
226
227	4.92k	const uint8_t *PreSortCb;
228
229		/* no data (e.g. silence) */
230	4.92k	if (sp_data_len == 0)
231	2.98k	return 0;
232
233		/* since there is spectral data, at least one codeword has nonzero length */
234	1.94k	if (ics->length_of_longest_codeword == 0)
235	27	return 10;
236
237	1.91k	if (sp_data_len < ics->length_of_longest_codeword)
238	4	return 10;
239
240	1.91k	sp_offset[0] = 0;
241	2.30k	for (g = 1; g < ics->num_window_groups; g++)
242	394	{
243	394	sp_offset[g] = sp_offset[g-1] + nshort*ics->window_group_length[g-1];
244	394	}
245
246	1.91k	PCWs_done = 0;
247	1.91k	numberOfSegments = 0;
248	1.91k	numberOfCodewords = 0;
249	1.91k	bitsread = 0;
250
251		/* VCB11 code books in use */
252	1.91k	if (hDecoder->aacSectionDataResilienceFlag)
253	1.83k	{
254	1.83k	PreSortCb = PreSortCB_ER;
255	1.83k	last_CB = NUM_CB_ER;
256	1.83k	} else
257	72	{
258	72	PreSortCb = PreSortCB_STD;
259	72	last_CB = NUM_CB;
260	72	}
261
262		/* step 1: decode PCW's (set 0), and stuff data in easier-to-use format */
263	42.0k	for (sortloop = 0; sortloop < last_CB; sortloop++)
264	40.1k	{
265		/* select codebook to process this pass */
266	40.1k	this_CB = PreSortCb[sortloop];
267
268		/* loop over sfbs */
269	388k	for (sfb = 0; sfb < ics->max_sfb; sfb++)
270	347k	{
271		/* loop over all in this sfb, 4 lines per loop */
272	989k	for (w_idx = 0; 4*w_idx < (min(ics->swb_offset[sfb+1], ics->swb_offset_max) - ics->swb_offset[sfb]); w_idx++)
273	641k	{
274	1.33M	for(g = 0; g < ics->num_window_groups; g++)
275	688k	{
276	3.06M	for (i = 0; i < ics->num_sec[g]; i++)
277	2.37M	{
278		/* check whether sfb used here is the one we want to process */
279	2.37M	if ((ics->sect_start[g][i] <= sfb) && (ics->sect_end[g][i] > sfb))
280	688k	{
281		/* check whether codebook used here is the one we want to process */
282	688k	this_sec_CB = ics->sect_cb[g][i];
283
284	688k	if (is_good_cb(this_CB, this_sec_CB))
285	32.5k	{
286		/* precalculate some stuff */
287	32.5k	uint16_t sect_sfb_size = ics->sect_sfb_offset[g][sfb+1] - ics->sect_sfb_offset[g][sfb];
288	32.5k	uint8_t inc = (this_sec_CB < FIRST_PAIR_HCB) ? QUAD_LEN : PAIR_LEN;
289	32.5k	uint16_t group_cws_count = (4*ics->window_group_length[g])/inc;
290	32.5k	uint8_t segwidth = segmentWidth(this_sec_CB);
291	32.5k	uint16_t cws;
292
293		/* read codewords until end of sfb or end of window group (shouldn't only 1 trigger?) */
294	122k	for (cws = 0; (cws < group_cws_count) && ((cws + w_idx*group_cws_count) < sect_sfb_size); cws++)
295	90.3k	{
296	90.3k	uint16_t sp = sp_offset[g] + ics->sect_sfb_offset[g][sfb] + inc * (cws + w_idx*group_cws_count);
297
298		/* read and decode PCW */
299	90.3k	if (!PCWs_done)
300	56.4k	{
301		/* read in normal segments */
302	56.4k	if (bitsread + segwidth <= sp_data_len)
303	55.9k	{
304	55.9k	read_segment(&segment[numberOfSegments], segwidth, ld);
305	55.9k	bitsread += segwidth;
306
307	55.9k	huffman_spectral_data_2(this_sec_CB, &segment[numberOfSegments], &spectral_data[sp]);
308
309		/* keep leftover bits */
310	55.9k	rewrev_bits(&segment[numberOfSegments]);
311
312	55.9k	numberOfSegments++;
313	55.9k	} else { // sp_data_len - bitsread < segwidth
314		/* remaining stuff after last segment, we unfortunately couldn't read
315		this in earlier because it might not fit in 64 bits. since we already
316		decoded (and removed) the PCW it is now should fit */
317	484	if (bitsread < sp_data_len)
318	394	{
319	394	const uint8_t additional_bits = (uint8_t)(sp_data_len - bitsread);
320
321	394	read_segment(&segment[numberOfSegments], additional_bits, ld);
322	394	segment[numberOfSegments].len += segment[numberOfSegments-1].len;
323	394	if (segment[numberOfSegments].len > 64)
324	39	return 10;
325	355	rewrev_bits(&segment[numberOfSegments]);
326
327	355	if (segment[numberOfSegments-1].len > 32)
328	46	{
329	46	segment[numberOfSegments-1].bufb = segment[numberOfSegments].bufb +
330	46	showbits_hcr(&segment[numberOfSegments-1], segment[numberOfSegments-1].len - 32);
331	46	segment[numberOfSegments-1].bufa = segment[numberOfSegments].bufa +
332	46	showbits_hcr(&segment[numberOfSegments-1], 32);
333	309	} else {
334	309	segment[numberOfSegments-1].bufa = segment[numberOfSegments].bufa +
335	309	showbits_hcr(&segment[numberOfSegments-1], segment[numberOfSegments-1].len);
336	309	segment[numberOfSegments-1].bufb = segment[numberOfSegments].bufb;
337	309	}
338	355	segment[numberOfSegments-1].len += additional_bits;
339	355	}
340	445	bitsread = sp_data_len;
341	445	PCWs_done = 1;
342
343	445	fill_in_codeword(codeword, 0, sp, this_sec_CB);
344	445	}
345	56.4k	} else {
346	33.9k	fill_in_codeword(codeword, numberOfCodewords - numberOfSegments, sp, this_sec_CB);
347	33.9k	}
348	90.2k	numberOfCodewords++;
349	90.2k	}
350	32.5k	}
351	688k	}
352	2.37M	}
353	688k	}
354	641k	}
355	347k	}
356	40.1k	}
357
358	1.87k	if (numberOfSegments == 0)
359	45	return 10;
360
361	1.82k	numberOfSets = numberOfCodewords / numberOfSegments;
362
363		/* step 2: decode nonPCWs */
364	8.11k	for (set = 1; set <= numberOfSets; set++)
365	6.29k	{
366	6.29k	uint16_t trial;
367
368	85.6k	for (trial = 0; trial < numberOfSegments; trial++)
369	79.3k	{
370	79.3k	uint16_t codewordBase;
371
372	3.32M	for (codewordBase = 0; codewordBase < numberOfSegments; codewordBase++)
373	3.30M	{
374	3.30M	const uint16_t segment_idx = (trial + codewordBase) % numberOfSegments;
375	3.30M	const uint16_t codeword_idx = codewordBase + set*numberOfSegments - numberOfSegments;
376
377		/* data up */
378	3.30M	if (codeword_idx >= numberOfCodewords - numberOfSegments) break;
379
380	3.24M	if (!codeword[codeword_idx].decoded && segment[segment_idx].len > 0)
381	29.2k	{
382	29.2k	uint8_t tmplen = segment[segment_idx].len + codeword[codeword_idx].bits.len;
383
384	29.2k	if (tmplen > 64)
385	266	{
386		// Drop bits that do not fit concatenation result.
387	266	flushbits_hcr(&codeword[codeword_idx].bits, tmplen - 64);
388	266	}
389
390	29.2k	if (codeword[codeword_idx].bits.len != 0)
391	4.84k	concat_bits(&segment[segment_idx], &codeword[codeword_idx].bits);
392
393	29.2k	tmplen = segment[segment_idx].len;
394
395	29.2k	if (huffman_spectral_data_2(codeword[codeword_idx].cb, &segment[segment_idx],
396	29.2k	&spectral_data[codeword[codeword_idx].sp_offset]) >= 0)
397	23.8k	{
398	23.8k	codeword[codeword_idx].decoded = 1;
399	23.8k	} else
400	5.36k	{
401	5.36k	codeword[codeword_idx].bits = segment[segment_idx];
402	5.36k	codeword[codeword_idx].bits.len = tmplen;
403	5.36k	}
404
405	29.2k	}
406	3.24M	}
407	79.3k	}
408	85.6k	for (i = 0; i < numberOfSegments; i++)
409	79.3k	rewrev_bits(&segment[i]);
410	6.29k	}
411
412		#if 0 // Seems to give false errors
413		bitsleft = 0;
414
415		for (i = 0; i < numberOfSegments && !bitsleft; i++)
416		bitsleft += segment[i].len;
417
418		if (bitsleft) return 10;
419
420		codewordsleft = 0;
421
422		for (i = 0; (i < numberOfCodewords - numberOfSegments) && (!codewordsleft); i++)
423		if (!codeword[i].decoded)
424		codewordsleft++;
425
426		if (codewordsleft) return 10;
427		#endif
428
429
430	1.82k	return 0;
431
432	1.87k	}
433		#endif