зеркало из https://github.com/mozilla/gecko-dev.git
330 строки
13 KiB
C
330 строки
13 KiB
C
/* NOLINT(build/header_guard) */
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/* Copyright 2016 Google Inc. All Rights Reserved.
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Distributed under MIT license.
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See file LICENSE for detail or copy at https://opensource.org/licenses/MIT
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*/
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/* template parameters: FN, BUCKET_BITS, MAX_TREE_COMP_LENGTH,
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MAX_TREE_SEARCH_DEPTH */
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/* A (forgetful) hash table where each hash bucket contains a binary tree of
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sequences whose first 4 bytes share the same hash code.
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Each sequence is MAX_TREE_COMP_LENGTH long and is identified by its starting
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position in the input data. The binary tree is sorted by the lexicographic
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order of the sequences, and it is also a max-heap with respect to the
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starting positions. */
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#define HashToBinaryTree HASHER()
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#define BUCKET_SIZE (1 << BUCKET_BITS)
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static BROTLI_INLINE size_t FN(HashTypeLength)(void) { return 4; }
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static BROTLI_INLINE size_t FN(StoreLookahead)(void) {
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return MAX_TREE_COMP_LENGTH;
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}
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static uint32_t FN(HashBytes)(const uint8_t* BROTLI_RESTRICT data) {
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uint32_t h = BROTLI_UNALIGNED_LOAD32LE(data) * kHashMul32;
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/* The higher bits contain more mixture from the multiplication,
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so we take our results from there. */
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return h >> (32 - BUCKET_BITS);
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}
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typedef struct HashToBinaryTree {
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/* The window size minus 1 */
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size_t window_mask_;
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/* Hash table that maps the 4-byte hashes of the sequence to the last
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position where this hash was found, which is the root of the binary
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tree of sequences that share this hash bucket. */
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uint32_t* buckets_; /* uint32_t[BUCKET_SIZE]; */
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/* A position used to mark a non-existent sequence, i.e. a tree is empty if
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its root is at invalid_pos_ and a node is a leaf if both its children
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are at invalid_pos_. */
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uint32_t invalid_pos_;
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/* --- Dynamic size members --- */
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/* The union of the binary trees of each hash bucket. The root of the tree
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corresponding to a hash is a sequence starting at buckets_[hash] and
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the left and right children of a sequence starting at pos are
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forest_[2 * pos] and forest_[2 * pos + 1]. */
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uint32_t* forest_; /* uint32_t[2 * num_nodes] */
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} HashToBinaryTree;
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static void FN(Initialize)(
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HasherCommon* common, HashToBinaryTree* BROTLI_RESTRICT self,
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const BrotliEncoderParams* params) {
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self->buckets_ = (uint32_t*)common->extra;
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self->forest_ = &self->buckets_[BUCKET_SIZE];
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self->window_mask_ = (1u << params->lgwin) - 1u;
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self->invalid_pos_ = (uint32_t)(0 - self->window_mask_);
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}
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static void FN(Prepare)
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(HashToBinaryTree* BROTLI_RESTRICT self, BROTLI_BOOL one_shot,
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size_t input_size, const uint8_t* BROTLI_RESTRICT data) {
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uint32_t invalid_pos = self->invalid_pos_;
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uint32_t i;
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uint32_t* BROTLI_RESTRICT buckets = self->buckets_;
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BROTLI_UNUSED(data);
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BROTLI_UNUSED(one_shot);
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BROTLI_UNUSED(input_size);
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for (i = 0; i < BUCKET_SIZE; i++) {
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buckets[i] = invalid_pos;
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}
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}
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static BROTLI_INLINE size_t FN(HashMemAllocInBytes)(
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const BrotliEncoderParams* params, BROTLI_BOOL one_shot,
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size_t input_size) {
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size_t num_nodes = (size_t)1 << params->lgwin;
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if (one_shot && input_size < num_nodes) {
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num_nodes = input_size;
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}
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return sizeof(uint32_t) * BUCKET_SIZE + 2 * sizeof(uint32_t) * num_nodes;
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}
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static BROTLI_INLINE size_t FN(LeftChildIndex)(
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HashToBinaryTree* BROTLI_RESTRICT self,
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const size_t pos) {
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return 2 * (pos & self->window_mask_);
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}
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static BROTLI_INLINE size_t FN(RightChildIndex)(
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HashToBinaryTree* BROTLI_RESTRICT self,
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const size_t pos) {
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return 2 * (pos & self->window_mask_) + 1;
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}
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/* Stores the hash of the next 4 bytes and in a single tree-traversal, the
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hash bucket's binary tree is searched for matches and is re-rooted at the
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current position.
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If less than MAX_TREE_COMP_LENGTH data is available, the hash bucket of the
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current position is searched for matches, but the state of the hash table
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is not changed, since we can not know the final sorting order of the
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current (incomplete) sequence.
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This function must be called with increasing cur_ix positions. */
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static BROTLI_INLINE BackwardMatch* FN(StoreAndFindMatches)(
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HashToBinaryTree* BROTLI_RESTRICT self, const uint8_t* BROTLI_RESTRICT data,
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const size_t cur_ix, const size_t ring_buffer_mask, const size_t max_length,
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const size_t max_backward, size_t* const BROTLI_RESTRICT best_len,
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BackwardMatch* BROTLI_RESTRICT matches) {
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const size_t cur_ix_masked = cur_ix & ring_buffer_mask;
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const size_t max_comp_len =
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BROTLI_MIN(size_t, max_length, MAX_TREE_COMP_LENGTH);
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const BROTLI_BOOL should_reroot_tree =
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TO_BROTLI_BOOL(max_length >= MAX_TREE_COMP_LENGTH);
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const uint32_t key = FN(HashBytes)(&data[cur_ix_masked]);
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uint32_t* BROTLI_RESTRICT buckets = self->buckets_;
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uint32_t* BROTLI_RESTRICT forest = self->forest_;
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size_t prev_ix = buckets[key];
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/* The forest index of the rightmost node of the left subtree of the new
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root, updated as we traverse and re-root the tree of the hash bucket. */
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size_t node_left = FN(LeftChildIndex)(self, cur_ix);
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/* The forest index of the leftmost node of the right subtree of the new
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root, updated as we traverse and re-root the tree of the hash bucket. */
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size_t node_right = FN(RightChildIndex)(self, cur_ix);
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/* The match length of the rightmost node of the left subtree of the new
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root, updated as we traverse and re-root the tree of the hash bucket. */
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size_t best_len_left = 0;
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/* The match length of the leftmost node of the right subtree of the new
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root, updated as we traverse and re-root the tree of the hash bucket. */
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size_t best_len_right = 0;
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size_t depth_remaining;
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if (should_reroot_tree) {
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buckets[key] = (uint32_t)cur_ix;
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}
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for (depth_remaining = MAX_TREE_SEARCH_DEPTH; ; --depth_remaining) {
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const size_t backward = cur_ix - prev_ix;
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const size_t prev_ix_masked = prev_ix & ring_buffer_mask;
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if (backward == 0 || backward > max_backward || depth_remaining == 0) {
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if (should_reroot_tree) {
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forest[node_left] = self->invalid_pos_;
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forest[node_right] = self->invalid_pos_;
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}
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break;
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}
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{
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const size_t cur_len = BROTLI_MIN(size_t, best_len_left, best_len_right);
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size_t len;
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BROTLI_DCHECK(cur_len <= MAX_TREE_COMP_LENGTH);
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len = cur_len +
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FindMatchLengthWithLimit(&data[cur_ix_masked + cur_len],
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&data[prev_ix_masked + cur_len],
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max_length - cur_len);
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BROTLI_DCHECK(
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0 == memcmp(&data[cur_ix_masked], &data[prev_ix_masked], len));
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if (matches && len > *best_len) {
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*best_len = len;
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InitBackwardMatch(matches++, backward, len);
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}
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if (len >= max_comp_len) {
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if (should_reroot_tree) {
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forest[node_left] = forest[FN(LeftChildIndex)(self, prev_ix)];
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forest[node_right] = forest[FN(RightChildIndex)(self, prev_ix)];
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}
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break;
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}
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if (data[cur_ix_masked + len] > data[prev_ix_masked + len]) {
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best_len_left = len;
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if (should_reroot_tree) {
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forest[node_left] = (uint32_t)prev_ix;
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}
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node_left = FN(RightChildIndex)(self, prev_ix);
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prev_ix = forest[node_left];
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} else {
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best_len_right = len;
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if (should_reroot_tree) {
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forest[node_right] = (uint32_t)prev_ix;
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}
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node_right = FN(LeftChildIndex)(self, prev_ix);
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prev_ix = forest[node_right];
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}
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}
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}
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return matches;
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}
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/* Finds all backward matches of &data[cur_ix & ring_buffer_mask] up to the
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length of max_length and stores the position cur_ix in the hash table.
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Sets *num_matches to the number of matches found, and stores the found
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matches in matches[0] to matches[*num_matches - 1]. The matches will be
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sorted by strictly increasing length and (non-strictly) increasing
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distance. */
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static BROTLI_INLINE size_t FN(FindAllMatches)(
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HashToBinaryTree* BROTLI_RESTRICT self,
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const BrotliEncoderDictionary* dictionary,
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const uint8_t* BROTLI_RESTRICT data,
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const size_t ring_buffer_mask, const size_t cur_ix,
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const size_t max_length, const size_t max_backward,
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const size_t dictionary_distance, const BrotliEncoderParams* params,
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BackwardMatch* matches) {
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BackwardMatch* const orig_matches = matches;
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const size_t cur_ix_masked = cur_ix & ring_buffer_mask;
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size_t best_len = 1;
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const size_t short_match_max_backward =
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params->quality != HQ_ZOPFLIFICATION_QUALITY ? 16 : 64;
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size_t stop = cur_ix - short_match_max_backward;
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uint32_t dict_matches[BROTLI_MAX_STATIC_DICTIONARY_MATCH_LEN + 1];
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size_t i;
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if (cur_ix < short_match_max_backward) { stop = 0; }
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for (i = cur_ix - 1; i > stop && best_len <= 2; --i) {
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size_t prev_ix = i;
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const size_t backward = cur_ix - prev_ix;
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if (BROTLI_PREDICT_FALSE(backward > max_backward)) {
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break;
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}
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prev_ix &= ring_buffer_mask;
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if (data[cur_ix_masked] != data[prev_ix] ||
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data[cur_ix_masked + 1] != data[prev_ix + 1]) {
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continue;
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}
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{
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const size_t len =
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FindMatchLengthWithLimit(&data[prev_ix], &data[cur_ix_masked],
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max_length);
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if (len > best_len) {
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best_len = len;
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InitBackwardMatch(matches++, backward, len);
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}
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}
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}
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if (best_len < max_length) {
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matches = FN(StoreAndFindMatches)(self, data, cur_ix,
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ring_buffer_mask, max_length, max_backward, &best_len, matches);
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}
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for (i = 0; i <= BROTLI_MAX_STATIC_DICTIONARY_MATCH_LEN; ++i) {
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dict_matches[i] = kInvalidMatch;
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}
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{
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size_t minlen = BROTLI_MAX(size_t, 4, best_len + 1);
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if (BrotliFindAllStaticDictionaryMatches(dictionary,
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&data[cur_ix_masked], minlen, max_length, &dict_matches[0])) {
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size_t maxlen = BROTLI_MIN(
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size_t, BROTLI_MAX_STATIC_DICTIONARY_MATCH_LEN, max_length);
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size_t l;
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for (l = minlen; l <= maxlen; ++l) {
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uint32_t dict_id = dict_matches[l];
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if (dict_id < kInvalidMatch) {
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size_t distance = dictionary_distance + (dict_id >> 5) + 1;
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if (distance <= params->dist.max_distance) {
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InitDictionaryBackwardMatch(matches++, distance, l, dict_id & 31);
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}
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}
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}
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}
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}
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return (size_t)(matches - orig_matches);
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}
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/* Stores the hash of the next 4 bytes and re-roots the binary tree at the
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current sequence, without returning any matches.
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REQUIRES: ix + MAX_TREE_COMP_LENGTH <= end-of-current-block */
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static BROTLI_INLINE void FN(Store)(HashToBinaryTree* BROTLI_RESTRICT self,
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const uint8_t* BROTLI_RESTRICT data,
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const size_t mask, const size_t ix) {
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/* Maximum distance is window size - 16, see section 9.1. of the spec. */
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const size_t max_backward = self->window_mask_ - BROTLI_WINDOW_GAP + 1;
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FN(StoreAndFindMatches)(self, data, ix, mask, MAX_TREE_COMP_LENGTH,
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max_backward, NULL, NULL);
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}
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static BROTLI_INLINE void FN(StoreRange)(HashToBinaryTree* BROTLI_RESTRICT self,
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const uint8_t* BROTLI_RESTRICT data, const size_t mask,
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const size_t ix_start, const size_t ix_end) {
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size_t i = ix_start;
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size_t j = ix_start;
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if (ix_start + 63 <= ix_end) {
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i = ix_end - 63;
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}
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if (ix_start + 512 <= i) {
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for (; j < i; j += 8) {
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FN(Store)(self, data, mask, j);
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}
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}
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for (; i < ix_end; ++i) {
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FN(Store)(self, data, mask, i);
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}
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}
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static BROTLI_INLINE void FN(StitchToPreviousBlock)(
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HashToBinaryTree* BROTLI_RESTRICT self,
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size_t num_bytes, size_t position, const uint8_t* ringbuffer,
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size_t ringbuffer_mask) {
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if (num_bytes >= FN(HashTypeLength)() - 1 &&
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position >= MAX_TREE_COMP_LENGTH) {
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/* Store the last `MAX_TREE_COMP_LENGTH - 1` positions in the hasher.
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These could not be calculated before, since they require knowledge
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of both the previous and the current block. */
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const size_t i_start = position - MAX_TREE_COMP_LENGTH + 1;
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const size_t i_end = BROTLI_MIN(size_t, position, i_start + num_bytes);
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size_t i;
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for (i = i_start; i < i_end; ++i) {
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/* Maximum distance is window size - 16, see section 9.1. of the spec.
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Furthermore, we have to make sure that we don't look further back
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from the start of the next block than the window size, otherwise we
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could access already overwritten areas of the ring-buffer. */
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const size_t max_backward =
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self->window_mask_ - BROTLI_MAX(size_t,
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BROTLI_WINDOW_GAP - 1,
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position - i);
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/* We know that i + MAX_TREE_COMP_LENGTH <= position + num_bytes, i.e. the
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end of the current block and that we have at least
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MAX_TREE_COMP_LENGTH tail in the ring-buffer. */
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FN(StoreAndFindMatches)(self, ringbuffer, i, ringbuffer_mask,
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MAX_TREE_COMP_LENGTH, max_backward, NULL, NULL);
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}
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}
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}
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#undef BUCKET_SIZE
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#undef HashToBinaryTree
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