libwebp: Sync with upstream 1.3.2
This commit is contained in:
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@ -417,7 +417,7 @@ Files extracted from upstream source:
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## libwebp
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- Upstream: https://chromium.googlesource.com/webm/libwebp/
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- Version: 1.3.1 (fd7bb21c0cb56e8a82e9bfa376164b842f433f3b, 2023)
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- Version: 1.3.2 (ca332209cb5567c9b249c86788cb2dbf8847e760, 2023)
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- License: BSD-3-Clause
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Files extracted from upstream source:
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@ -32,7 +32,7 @@ extern "C" {
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// version numbers
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#define DEC_MAJ_VERSION 1
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#define DEC_MIN_VERSION 3
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#define DEC_REV_VERSION 1
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#define DEC_REV_VERSION 2
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// YUV-cache parameters. Cache is 32-bytes wide (= one cacheline).
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// Constraints are: We need to store one 16x16 block of luma samples (y),
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@ -253,11 +253,11 @@ static int ReadHuffmanCodeLengths(
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int symbol;
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int max_symbol;
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int prev_code_len = DEFAULT_CODE_LENGTH;
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HuffmanCode table[1 << LENGTHS_TABLE_BITS];
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HuffmanTables tables;
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if (!VP8LBuildHuffmanTable(table, LENGTHS_TABLE_BITS,
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code_length_code_lengths,
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NUM_CODE_LENGTH_CODES)) {
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if (!VP8LHuffmanTablesAllocate(1 << LENGTHS_TABLE_BITS, &tables) ||
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!VP8LBuildHuffmanTable(&tables, LENGTHS_TABLE_BITS,
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code_length_code_lengths, NUM_CODE_LENGTH_CODES)) {
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goto End;
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}
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@ -277,7 +277,7 @@ static int ReadHuffmanCodeLengths(
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int code_len;
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if (max_symbol-- == 0) break;
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VP8LFillBitWindow(br);
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p = &table[VP8LPrefetchBits(br) & LENGTHS_TABLE_MASK];
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p = &tables.curr_segment->start[VP8LPrefetchBits(br) & LENGTHS_TABLE_MASK];
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VP8LSetBitPos(br, br->bit_pos_ + p->bits);
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code_len = p->value;
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if (code_len < kCodeLengthLiterals) {
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@ -300,6 +300,7 @@ static int ReadHuffmanCodeLengths(
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ok = 1;
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End:
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VP8LHuffmanTablesDeallocate(&tables);
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if (!ok) dec->status_ = VP8_STATUS_BITSTREAM_ERROR;
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return ok;
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}
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@ -307,7 +308,8 @@ static int ReadHuffmanCodeLengths(
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// 'code_lengths' is pre-allocated temporary buffer, used for creating Huffman
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// tree.
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static int ReadHuffmanCode(int alphabet_size, VP8LDecoder* const dec,
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int* const code_lengths, HuffmanCode* const table) {
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int* const code_lengths,
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HuffmanTables* const table) {
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int ok = 0;
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int size = 0;
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VP8LBitReader* const br = &dec->br_;
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@ -362,8 +364,7 @@ static int ReadHuffmanCodes(VP8LDecoder* const dec, int xsize, int ysize,
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VP8LMetadata* const hdr = &dec->hdr_;
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uint32_t* huffman_image = NULL;
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HTreeGroup* htree_groups = NULL;
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HuffmanCode* huffman_tables = NULL;
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HuffmanCode* huffman_table = NULL;
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HuffmanTables* huffman_tables = &hdr->huffman_tables_;
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int num_htree_groups = 1;
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int num_htree_groups_max = 1;
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int max_alphabet_size = 0;
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@ -372,6 +373,10 @@ static int ReadHuffmanCodes(VP8LDecoder* const dec, int xsize, int ysize,
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int* mapping = NULL;
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int ok = 0;
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// Check the table has been 0 initialized (through InitMetadata).
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assert(huffman_tables->root.start == NULL);
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assert(huffman_tables->curr_segment == NULL);
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if (allow_recursion && VP8LReadBits(br, 1)) {
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// use meta Huffman codes.
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const int huffman_precision = VP8LReadBits(br, 3) + 2;
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@ -434,16 +439,15 @@ static int ReadHuffmanCodes(VP8LDecoder* const dec, int xsize, int ysize,
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code_lengths = (int*)WebPSafeCalloc((uint64_t)max_alphabet_size,
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sizeof(*code_lengths));
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huffman_tables = (HuffmanCode*)WebPSafeMalloc(num_htree_groups * table_size,
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sizeof(*huffman_tables));
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htree_groups = VP8LHtreeGroupsNew(num_htree_groups);
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if (htree_groups == NULL || code_lengths == NULL || huffman_tables == NULL) {
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if (htree_groups == NULL || code_lengths == NULL ||
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!VP8LHuffmanTablesAllocate(num_htree_groups * table_size,
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huffman_tables)) {
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dec->status_ = VP8_STATUS_OUT_OF_MEMORY;
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goto Error;
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}
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huffman_table = huffman_tables;
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for (i = 0; i < num_htree_groups_max; ++i) {
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// If the index "i" is unused in the Huffman image, just make sure the
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// coefficients are valid but do not store them.
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@ -468,19 +472,20 @@ static int ReadHuffmanCodes(VP8LDecoder* const dec, int xsize, int ysize,
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int max_bits = 0;
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for (j = 0; j < HUFFMAN_CODES_PER_META_CODE; ++j) {
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int alphabet_size = kAlphabetSize[j];
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htrees[j] = huffman_table;
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if (j == 0 && color_cache_bits > 0) {
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alphabet_size += (1 << color_cache_bits);
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}
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size = ReadHuffmanCode(alphabet_size, dec, code_lengths, huffman_table);
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size =
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ReadHuffmanCode(alphabet_size, dec, code_lengths, huffman_tables);
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htrees[j] = huffman_tables->curr_segment->curr_table;
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if (size == 0) {
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goto Error;
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}
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if (is_trivial_literal && kLiteralMap[j] == 1) {
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is_trivial_literal = (huffman_table->bits == 0);
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is_trivial_literal = (htrees[j]->bits == 0);
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}
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total_size += huffman_table->bits;
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huffman_table += size;
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total_size += htrees[j]->bits;
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huffman_tables->curr_segment->curr_table += size;
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if (j <= ALPHA) {
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int local_max_bits = code_lengths[0];
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int k;
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@ -515,14 +520,13 @@ static int ReadHuffmanCodes(VP8LDecoder* const dec, int xsize, int ysize,
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hdr->huffman_image_ = huffman_image;
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hdr->num_htree_groups_ = num_htree_groups;
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hdr->htree_groups_ = htree_groups;
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hdr->huffman_tables_ = huffman_tables;
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Error:
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WebPSafeFree(code_lengths);
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WebPSafeFree(mapping);
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if (!ok) {
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WebPSafeFree(huffman_image);
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WebPSafeFree(huffman_tables);
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VP8LHuffmanTablesDeallocate(huffman_tables);
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VP8LHtreeGroupsFree(htree_groups);
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}
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return ok;
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@ -1358,7 +1362,7 @@ static void ClearMetadata(VP8LMetadata* const hdr) {
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assert(hdr != NULL);
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WebPSafeFree(hdr->huffman_image_);
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WebPSafeFree(hdr->huffman_tables_);
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VP8LHuffmanTablesDeallocate(&hdr->huffman_tables_);
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VP8LHtreeGroupsFree(hdr->htree_groups_);
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VP8LColorCacheClear(&hdr->color_cache_);
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VP8LColorCacheClear(&hdr->saved_color_cache_);
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@ -1673,7 +1677,7 @@ int VP8LDecodeImage(VP8LDecoder* const dec) {
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if (dec == NULL) return 0;
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assert(dec->hdr_.huffman_tables_ != NULL);
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assert(dec->hdr_.huffman_tables_.root.start != NULL);
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assert(dec->hdr_.htree_groups_ != NULL);
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assert(dec->hdr_.num_htree_groups_ > 0);
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@ -51,7 +51,7 @@ typedef struct {
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uint32_t* huffman_image_;
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int num_htree_groups_;
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HTreeGroup* htree_groups_;
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HuffmanCode* huffman_tables_;
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HuffmanTables huffman_tables_;
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} VP8LMetadata;
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typedef struct VP8LDecoder VP8LDecoder;
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@ -25,7 +25,7 @@
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#define DMUX_MAJ_VERSION 1
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#define DMUX_MIN_VERSION 3
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#define DMUX_REV_VERSION 1
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#define DMUX_REV_VERSION 2
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typedef struct {
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size_t start_; // start location of the data
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@ -32,7 +32,7 @@ extern "C" {
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// version numbers
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#define ENC_MAJ_VERSION 1
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#define ENC_MIN_VERSION 3
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#define ENC_REV_VERSION 1
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#define ENC_REV_VERSION 2
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enum { MAX_LF_LEVELS = 64, // Maximum loop filter level
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MAX_VARIABLE_LEVEL = 67, // last (inclusive) level with variable cost
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@ -29,7 +29,7 @@ extern "C" {
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#define MUX_MAJ_VERSION 1
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#define MUX_MIN_VERSION 3
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#define MUX_REV_VERSION 1
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#define MUX_REV_VERSION 2
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// Chunk object.
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typedef struct WebPChunk WebPChunk;
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@ -177,21 +177,24 @@ static int BuildHuffmanTable(HuffmanCode* const root_table, int root_bits,
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if (num_open < 0) {
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return 0;
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}
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if (root_table == NULL) continue;
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for (; count[len] > 0; --count[len]) {
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HuffmanCode code;
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if ((key & mask) != low) {
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table += table_size;
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if (root_table != NULL) table += table_size;
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table_bits = NextTableBitSize(count, len, root_bits);
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table_size = 1 << table_bits;
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total_size += table_size;
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low = key & mask;
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if (root_table != NULL) {
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root_table[low].bits = (uint8_t)(table_bits + root_bits);
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root_table[low].value = (uint16_t)((table - root_table) - low);
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}
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}
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if (root_table != NULL) {
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code.bits = (uint8_t)(len - root_bits);
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code.value = (uint16_t)sorted[symbol++];
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ReplicateValue(&table[key >> root_bits], step, table_size, code);
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}
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key = GetNextKey(key, len);
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}
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}
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((1 << MAX_CACHE_BITS) + NUM_LITERAL_CODES + NUM_LENGTH_CODES)
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// Cut-off value for switching between heap and stack allocation.
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#define SORTED_SIZE_CUTOFF 512
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int VP8LBuildHuffmanTable(HuffmanCode* const root_table, int root_bits,
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int VP8LBuildHuffmanTable(HuffmanTables* const root_table, int root_bits,
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const int code_lengths[], int code_lengths_size) {
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int total_size;
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const int total_size =
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BuildHuffmanTable(NULL, root_bits, code_lengths, code_lengths_size, NULL);
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assert(code_lengths_size <= MAX_CODE_LENGTHS_SIZE);
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if (root_table == NULL) {
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total_size = BuildHuffmanTable(NULL, root_bits,
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code_lengths, code_lengths_size, NULL);
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} else if (code_lengths_size <= SORTED_SIZE_CUTOFF) {
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if (total_size == 0 || root_table == NULL) return total_size;
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if (root_table->curr_segment->curr_table + total_size >=
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root_table->curr_segment->start + root_table->curr_segment->size) {
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// If 'root_table' does not have enough memory, allocate a new segment.
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// The available part of root_table->curr_segment is left unused because we
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// need a contiguous buffer.
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const int segment_size = root_table->curr_segment->size;
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struct HuffmanTablesSegment* next =
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(HuffmanTablesSegment*)WebPSafeMalloc(1, sizeof(*next));
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if (next == NULL) return 0;
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// Fill the new segment.
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// We need at least 'total_size' but if that value is small, it is better to
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// allocate a big chunk to prevent more allocations later. 'segment_size' is
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// therefore chosen (any other arbitrary value could be chosen).
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next->size = total_size > segment_size ? total_size : segment_size;
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next->start =
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(HuffmanCode*)WebPSafeMalloc(next->size, sizeof(*next->start));
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if (next->start == NULL) {
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WebPSafeFree(next);
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return 0;
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}
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next->curr_table = next->start;
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next->next = NULL;
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// Point to the new segment.
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root_table->curr_segment->next = next;
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root_table->curr_segment = next;
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}
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if (code_lengths_size <= SORTED_SIZE_CUTOFF) {
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// use local stack-allocated array.
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uint16_t sorted[SORTED_SIZE_CUTOFF];
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total_size = BuildHuffmanTable(root_table, root_bits,
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BuildHuffmanTable(root_table->curr_segment->curr_table, root_bits,
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code_lengths, code_lengths_size, sorted);
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} else { // rare case. Use heap allocation.
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uint16_t* const sorted =
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(uint16_t*)WebPSafeMalloc(code_lengths_size, sizeof(*sorted));
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if (sorted == NULL) return 0;
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total_size = BuildHuffmanTable(root_table, root_bits,
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BuildHuffmanTable(root_table->curr_segment->curr_table, root_bits,
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code_lengths, code_lengths_size, sorted);
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WebPSafeFree(sorted);
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}
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return total_size;
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}
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int VP8LHuffmanTablesAllocate(int size, HuffmanTables* huffman_tables) {
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// Have 'segment' point to the first segment for now, 'root'.
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HuffmanTablesSegment* const root = &huffman_tables->root;
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huffman_tables->curr_segment = root;
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// Allocate root.
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root->start = (HuffmanCode*)WebPSafeMalloc(size, sizeof(*root->start));
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if (root->start == NULL) return 0;
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root->curr_table = root->start;
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root->next = NULL;
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root->size = size;
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return 1;
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}
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void VP8LHuffmanTablesDeallocate(HuffmanTables* const huffman_tables) {
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HuffmanTablesSegment *current, *next;
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if (huffman_tables == NULL) return;
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// Free the root node.
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current = &huffman_tables->root;
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next = current->next;
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WebPSafeFree(current->start);
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current->start = NULL;
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current->next = NULL;
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current = next;
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// Free the following nodes.
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while (current != NULL) {
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next = current->next;
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WebPSafeFree(current->start);
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WebPSafeFree(current);
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current = next;
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}
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}
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// or non-literal symbol otherwise
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} HuffmanCode32;
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// Contiguous memory segment of HuffmanCodes.
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typedef struct HuffmanTablesSegment {
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HuffmanCode* start;
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// Pointer to where we are writing into the segment. Starts at 'start' and
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// cannot go beyond 'start' + 'size'.
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HuffmanCode* curr_table;
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// Pointer to the next segment in the chain.
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struct HuffmanTablesSegment* next;
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int size;
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} HuffmanTablesSegment;
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// Chained memory segments of HuffmanCodes.
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typedef struct HuffmanTables {
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HuffmanTablesSegment root;
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// Currently processed segment. At first, this is 'root'.
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HuffmanTablesSegment* curr_segment;
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} HuffmanTables;
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// Allocates a HuffmanTables with 'size' contiguous HuffmanCodes. Returns 0 on
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// memory allocation error, 1 otherwise.
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int VP8LHuffmanTablesAllocate(int size, HuffmanTables* huffman_tables);
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void VP8LHuffmanTablesDeallocate(HuffmanTables* const huffman_tables);
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#define HUFFMAN_PACKED_BITS 6
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#define HUFFMAN_PACKED_TABLE_SIZE (1u << HUFFMAN_PACKED_BITS)
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@ -78,9 +101,7 @@ void VP8LHtreeGroupsFree(HTreeGroup* const htree_groups);
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// the huffman table.
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// Returns built table size or 0 in case of error (invalid tree or
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// memory error).
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// If root_table is NULL, it returns 0 if a lookup cannot be built, something
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// > 0 otherwise (but not the table size).
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int VP8LBuildHuffmanTable(HuffmanCode* const root_table, int root_bits,
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int VP8LBuildHuffmanTable(HuffmanTables* const root_table, int root_bits,
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const int code_lengths[], int code_lengths_size);
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#ifdef __cplusplus
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