1cabdff1aSopenharmony_ci/*
2cabdff1aSopenharmony_ci * MJPEG encoder
3cabdff1aSopenharmony_ci * Copyright (c) 2016 William Ma, Ted Ying, Jerry Jiang
4cabdff1aSopenharmony_ci *
5cabdff1aSopenharmony_ci * This file is part of FFmpeg.
6cabdff1aSopenharmony_ci *
7cabdff1aSopenharmony_ci * FFmpeg is free software; you can redistribute it and/or
8cabdff1aSopenharmony_ci * modify it under the terms of the GNU Lesser General Public
9cabdff1aSopenharmony_ci * License as published by the Free Software Foundation; either
10cabdff1aSopenharmony_ci * version 2.1 of the License, or (at your option) any later version.
11cabdff1aSopenharmony_ci *
12cabdff1aSopenharmony_ci * FFmpeg is distributed in the hope that it will be useful,
13cabdff1aSopenharmony_ci * but WITHOUT ANY WARRANTY; without even the implied warranty of
14cabdff1aSopenharmony_ci * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
15cabdff1aSopenharmony_ci * Lesser General Public License for more details.
16cabdff1aSopenharmony_ci *
17cabdff1aSopenharmony_ci * You should have received a copy of the GNU Lesser General Public
18cabdff1aSopenharmony_ci * License along with FFmpeg; if not, write to the Free Software
19cabdff1aSopenharmony_ci * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
20cabdff1aSopenharmony_ci */
21cabdff1aSopenharmony_ci
22cabdff1aSopenharmony_ci#include <string.h>
23cabdff1aSopenharmony_ci#include <stdint.h>
24cabdff1aSopenharmony_ci#include "libavutil/avassert.h"
25cabdff1aSopenharmony_ci#include "libavutil/qsort.h"
26cabdff1aSopenharmony_ci#include "mjpegenc_huffman.h"
27cabdff1aSopenharmony_ci
28cabdff1aSopenharmony_ci/**
29cabdff1aSopenharmony_ci * Comparison function for two PTables by prob
30cabdff1aSopenharmony_ci *
31cabdff1aSopenharmony_ci * @param a First PTable to compare
32cabdff1aSopenharmony_ci * @param b Second PTable to compare
33cabdff1aSopenharmony_ci * @return < 0 for less than, 0 for equals, > 0 for greater than
34cabdff1aSopenharmony_ci */
35cabdff1aSopenharmony_cistatic int compare_by_prob(const void *a, const void *b)
36cabdff1aSopenharmony_ci{
37cabdff1aSopenharmony_ci    PTable a_val = *(PTable *) a;
38cabdff1aSopenharmony_ci    PTable b_val = *(PTable *) b;
39cabdff1aSopenharmony_ci    return a_val.prob - b_val.prob;
40cabdff1aSopenharmony_ci}
41cabdff1aSopenharmony_ci
42cabdff1aSopenharmony_ci/**
43cabdff1aSopenharmony_ci * Comparison function for two HuffTables by length
44cabdff1aSopenharmony_ci *
45cabdff1aSopenharmony_ci * @param a First HuffTable to compare
46cabdff1aSopenharmony_ci * @param b Second HuffTable to compare
47cabdff1aSopenharmony_ci * @return < 0 for less than, 0 for equals, > 0 for greater than
48cabdff1aSopenharmony_ci */
49cabdff1aSopenharmony_cistatic int compare_by_length(const void *a, const void *b)
50cabdff1aSopenharmony_ci{
51cabdff1aSopenharmony_ci    HuffTable a_val = *(HuffTable *) a;
52cabdff1aSopenharmony_ci    HuffTable b_val = *(HuffTable *) b;
53cabdff1aSopenharmony_ci    return a_val.length - b_val.length;
54cabdff1aSopenharmony_ci}
55cabdff1aSopenharmony_ci
56cabdff1aSopenharmony_ci/**
57cabdff1aSopenharmony_ci * Computes the length of the Huffman encoding for each distinct input value.
58cabdff1aSopenharmony_ci * Uses package merge algorithm as follows:
59cabdff1aSopenharmony_ci * 1. start with an empty list, lets call it list(0), set i = 0
60cabdff1aSopenharmony_ci * 2. add 1 entry to list(i) for each symbol we have and give each a score equal to the probability of the respective symbol
61cabdff1aSopenharmony_ci * 3. merge the 2 symbols of least score and put them in list(i+1), and remove them from list(i). The new score will be the sum of the 2 scores
62cabdff1aSopenharmony_ci * 4. if there is more than 1 symbol left in the current list(i), then goto 3
63cabdff1aSopenharmony_ci * 5. i++
64cabdff1aSopenharmony_ci * 6. if i < 16 goto 2
65cabdff1aSopenharmony_ci * 7. select the n-1 elements in the last list with the lowest score (n = the number of symbols)
66cabdff1aSopenharmony_ci * 8. the length of the huffman code for symbol s will be equal to the number of times the symbol occurs in the select elements
67cabdff1aSopenharmony_ci * Go to guru.multimedia.cx/small-tasks-for-ffmpeg/ for more details
68cabdff1aSopenharmony_ci *
69cabdff1aSopenharmony_ci * All probabilities should be positive integers. The output is sorted by code,
70cabdff1aSopenharmony_ci * not by length.
71cabdff1aSopenharmony_ci *
72cabdff1aSopenharmony_ci * @param prob_table input array of a PTable for each distinct input value
73cabdff1aSopenharmony_ci * @param distincts  output array of a HuffTable that will be populated by this function
74cabdff1aSopenharmony_ci * @param size       size of the prob_table array
75cabdff1aSopenharmony_ci * @param max_length max length of an encoding
76cabdff1aSopenharmony_ci */
77cabdff1aSopenharmony_civoid ff_mjpegenc_huffman_compute_bits(PTable *prob_table, HuffTable *distincts, int size, int max_length)
78cabdff1aSopenharmony_ci{
79cabdff1aSopenharmony_ci    PackageMergerList list_a, list_b, *to = &list_a, *from = &list_b, *temp;
80cabdff1aSopenharmony_ci
81cabdff1aSopenharmony_ci    int times, i, j, k;
82cabdff1aSopenharmony_ci
83cabdff1aSopenharmony_ci    int nbits[257] = {0};
84cabdff1aSopenharmony_ci
85cabdff1aSopenharmony_ci    int min;
86cabdff1aSopenharmony_ci
87cabdff1aSopenharmony_ci    av_assert0(max_length > 0);
88cabdff1aSopenharmony_ci
89cabdff1aSopenharmony_ci    to->nitems = 0;
90cabdff1aSopenharmony_ci    from->nitems = 0;
91cabdff1aSopenharmony_ci    to->item_idx[0] = 0;
92cabdff1aSopenharmony_ci    from->item_idx[0] = 0;
93cabdff1aSopenharmony_ci    AV_QSORT(prob_table, size, PTable, compare_by_prob);
94cabdff1aSopenharmony_ci
95cabdff1aSopenharmony_ci    for (times = 0; times <= max_length; times++) {
96cabdff1aSopenharmony_ci        to->nitems = 0;
97cabdff1aSopenharmony_ci        to->item_idx[0] = 0;
98cabdff1aSopenharmony_ci
99cabdff1aSopenharmony_ci        j = 0;
100cabdff1aSopenharmony_ci        k = 0;
101cabdff1aSopenharmony_ci
102cabdff1aSopenharmony_ci        if (times < max_length) {
103cabdff1aSopenharmony_ci            i = 0;
104cabdff1aSopenharmony_ci        }
105cabdff1aSopenharmony_ci        while (i < size || j + 1 < from->nitems) {
106cabdff1aSopenharmony_ci            to->nitems++;
107cabdff1aSopenharmony_ci            to->item_idx[to->nitems] = to->item_idx[to->nitems - 1];
108cabdff1aSopenharmony_ci            if (i < size &&
109cabdff1aSopenharmony_ci                (j + 1 >= from->nitems ||
110cabdff1aSopenharmony_ci                 prob_table[i].prob <
111cabdff1aSopenharmony_ci                     from->probability[j] + from->probability[j + 1])) {
112cabdff1aSopenharmony_ci                to->items[to->item_idx[to->nitems]++] = prob_table[i].value;
113cabdff1aSopenharmony_ci                to->probability[to->nitems - 1] = prob_table[i].prob;
114cabdff1aSopenharmony_ci                i++;
115cabdff1aSopenharmony_ci            } else {
116cabdff1aSopenharmony_ci                for (k = from->item_idx[j]; k < from->item_idx[j + 2]; k++) {
117cabdff1aSopenharmony_ci                    to->items[to->item_idx[to->nitems]++] = from->items[k];
118cabdff1aSopenharmony_ci                }
119cabdff1aSopenharmony_ci                to->probability[to->nitems - 1] =
120cabdff1aSopenharmony_ci                    from->probability[j] + from->probability[j + 1];
121cabdff1aSopenharmony_ci                j += 2;
122cabdff1aSopenharmony_ci            }
123cabdff1aSopenharmony_ci        }
124cabdff1aSopenharmony_ci        temp = to;
125cabdff1aSopenharmony_ci        to = from;
126cabdff1aSopenharmony_ci        from = temp;
127cabdff1aSopenharmony_ci    }
128cabdff1aSopenharmony_ci
129cabdff1aSopenharmony_ci    min = (size - 1 < from->nitems) ? size - 1 : from->nitems;
130cabdff1aSopenharmony_ci    for (i = 0; i < from->item_idx[min]; i++) {
131cabdff1aSopenharmony_ci        nbits[from->items[i]]++;
132cabdff1aSopenharmony_ci    }
133cabdff1aSopenharmony_ci    // we don't want to return the 256 bit count (it was just in here to prevent
134cabdff1aSopenharmony_ci    // all 1s encoding)
135cabdff1aSopenharmony_ci    j = 0;
136cabdff1aSopenharmony_ci    for (i = 0; i < 256; i++) {
137cabdff1aSopenharmony_ci        if (nbits[i] > 0) {
138cabdff1aSopenharmony_ci            distincts[j].code = i;
139cabdff1aSopenharmony_ci            distincts[j].length = nbits[i];
140cabdff1aSopenharmony_ci            j++;
141cabdff1aSopenharmony_ci        }
142cabdff1aSopenharmony_ci    }
143cabdff1aSopenharmony_ci}
144cabdff1aSopenharmony_ci
145cabdff1aSopenharmony_civoid ff_mjpeg_encode_huffman_init(MJpegEncHuffmanContext *s)
146cabdff1aSopenharmony_ci{
147cabdff1aSopenharmony_ci    memset(s->val_count, 0, sizeof(s->val_count));
148cabdff1aSopenharmony_ci}
149cabdff1aSopenharmony_ci
150cabdff1aSopenharmony_ci/**
151cabdff1aSopenharmony_ci * Produces a Huffman encoding with a given input
152cabdff1aSopenharmony_ci *
153cabdff1aSopenharmony_ci * @param s         input to encode
154cabdff1aSopenharmony_ci * @param bits      output array where the ith character represents how many input values have i length encoding
155cabdff1aSopenharmony_ci * @param val       output array of input values sorted by their encoded length
156cabdff1aSopenharmony_ci * @param max_nval  maximum number of distinct input values
157cabdff1aSopenharmony_ci */
158cabdff1aSopenharmony_civoid ff_mjpeg_encode_huffman_close(MJpegEncHuffmanContext *s, uint8_t bits[17],
159cabdff1aSopenharmony_ci                                   uint8_t val[], int max_nval)
160cabdff1aSopenharmony_ci{
161cabdff1aSopenharmony_ci    int i, j;
162cabdff1aSopenharmony_ci    int nval = 0;
163cabdff1aSopenharmony_ci    PTable val_counts[257];
164cabdff1aSopenharmony_ci    HuffTable distincts[256];
165cabdff1aSopenharmony_ci
166cabdff1aSopenharmony_ci    for (i = 0; i < 256; i++) {
167cabdff1aSopenharmony_ci        if (s->val_count[i]) nval++;
168cabdff1aSopenharmony_ci    }
169cabdff1aSopenharmony_ci    av_assert0 (nval <= max_nval);
170cabdff1aSopenharmony_ci
171cabdff1aSopenharmony_ci    j = 0;
172cabdff1aSopenharmony_ci    for (i = 0; i < 256; i++) {
173cabdff1aSopenharmony_ci        if (s->val_count[i]) {
174cabdff1aSopenharmony_ci            val_counts[j].value = i;
175cabdff1aSopenharmony_ci            val_counts[j].prob = s->val_count[i];
176cabdff1aSopenharmony_ci            j++;
177cabdff1aSopenharmony_ci        }
178cabdff1aSopenharmony_ci    }
179cabdff1aSopenharmony_ci    val_counts[j].value = 256;
180cabdff1aSopenharmony_ci    val_counts[j].prob = 0;
181cabdff1aSopenharmony_ci    ff_mjpegenc_huffman_compute_bits(val_counts, distincts, nval + 1, 16);
182cabdff1aSopenharmony_ci    AV_QSORT(distincts, nval, HuffTable, compare_by_length);
183cabdff1aSopenharmony_ci
184cabdff1aSopenharmony_ci    memset(bits, 0, sizeof(bits[0]) * 17);
185cabdff1aSopenharmony_ci    for (i = 0; i < nval; i++) {
186cabdff1aSopenharmony_ci        val[i] = distincts[i].code;
187cabdff1aSopenharmony_ci        bits[distincts[i].length]++;
188cabdff1aSopenharmony_ci    }
189cabdff1aSopenharmony_ci}
190