package brotli /* NOLINT(build/header_guard) */ /* Copyright 2015 Google Inc. All Rights Reserved. Distributed under MIT license. See file LICENSE for detail or copy at https://opensource.org/licenses/MIT */ /* Greedy block splitter for one block category (literal, command or distance). */ type blockSplitterDistance struct { alphabet_size_ uint min_block_size_ uint split_threshold_ float64 num_blocks_ uint split_ *blockSplit histograms_ []histogramDistance histograms_size_ *uint target_block_size_ uint block_size_ uint curr_histogram_ix_ uint last_histogram_ix_ [2]uint last_entropy_ [2]float64 merge_last_count_ uint } func initBlockSplitterDistance(self *blockSplitterDistance, alphabet_size uint, min_block_size uint, split_threshold float64, num_symbols uint, split *blockSplit, histograms *[]histogramDistance, histograms_size *uint) { var max_num_blocks uint = num_symbols/min_block_size + 1 var max_num_types uint = brotli_min_size_t(max_num_blocks, maxNumberOfBlockTypes+1) /* We have to allocate one more histogram than the maximum number of block types for the current histogram when the meta-block is too big. */ self.alphabet_size_ = alphabet_size self.min_block_size_ = min_block_size self.split_threshold_ = split_threshold self.num_blocks_ = 0 self.split_ = split self.histograms_size_ = histograms_size self.target_block_size_ = min_block_size self.block_size_ = 0 self.curr_histogram_ix_ = 0 self.merge_last_count_ = 0 brotli_ensure_capacity_uint8_t(&split.types, &split.types_alloc_size, max_num_blocks) brotli_ensure_capacity_uint32_t(&split.lengths, &split.lengths_alloc_size, max_num_blocks) self.split_.num_blocks = max_num_blocks assert(*histograms == nil) *histograms_size = max_num_types *histograms = make([]histogramDistance, (*histograms_size)) self.histograms_ = *histograms /* Clear only current histogram. */ histogramClearDistance(&self.histograms_[0]) self.last_histogram_ix_[1] = 0 self.last_histogram_ix_[0] = self.last_histogram_ix_[1] } /* Does either of three things: (1) emits the current block with a new block type; (2) emits the current block with the type of the second last block; (3) merges the current block with the last block. */ func blockSplitterFinishBlockDistance(self *blockSplitterDistance, is_final bool) { var split *blockSplit = self.split_ var last_entropy []float64 = self.last_entropy_[:] var histograms []histogramDistance = self.histograms_ self.block_size_ = brotli_max_size_t(self.block_size_, self.min_block_size_) if self.num_blocks_ == 0 { /* Create first block. */ split.lengths[0] = uint32(self.block_size_) split.types[0] = 0 last_entropy[0] = bitsEntropy(histograms[0].data_[:], self.alphabet_size_) last_entropy[1] = last_entropy[0] self.num_blocks_++ split.num_types++ self.curr_histogram_ix_++ if self.curr_histogram_ix_ < *self.histograms_size_ { histogramClearDistance(&histograms[self.curr_histogram_ix_]) } self.block_size_ = 0 } else if self.block_size_ > 0 { var entropy float64 = bitsEntropy(histograms[self.curr_histogram_ix_].data_[:], self.alphabet_size_) var combined_histo [2]histogramDistance var combined_entropy [2]float64 var diff [2]float64 var j uint for j = 0; j < 2; j++ { var last_histogram_ix uint = self.last_histogram_ix_[j] combined_histo[j] = histograms[self.curr_histogram_ix_] histogramAddHistogramDistance(&combined_histo[j], &histograms[last_histogram_ix]) combined_entropy[j] = bitsEntropy(combined_histo[j].data_[0:], self.alphabet_size_) diff[j] = combined_entropy[j] - entropy - last_entropy[j] } if split.num_types < maxNumberOfBlockTypes && diff[0] > self.split_threshold_ && diff[1] > self.split_threshold_ { /* Create new block. */ split.lengths[self.num_blocks_] = uint32(self.block_size_) split.types[self.num_blocks_] = byte(split.num_types) self.last_histogram_ix_[1] = self.last_histogram_ix_[0] self.last_histogram_ix_[0] = uint(byte(split.num_types)) last_entropy[1] = last_entropy[0] last_entropy[0] = entropy self.num_blocks_++ split.num_types++ self.curr_histogram_ix_++ if self.curr_histogram_ix_ < *self.histograms_size_ { histogramClearDistance(&histograms[self.curr_histogram_ix_]) } self.block_size_ = 0 self.merge_last_count_ = 0 self.target_block_size_ = self.min_block_size_ } else if diff[1] < diff[0]-20.0 { split.lengths[self.num_blocks_] = uint32(self.block_size_) split.types[self.num_blocks_] = split.types[self.num_blocks_-2] /* Combine this block with second last block. */ var tmp uint = self.last_histogram_ix_[0] self.last_histogram_ix_[0] = self.last_histogram_ix_[1] self.last_histogram_ix_[1] = tmp histograms[self.last_histogram_ix_[0]] = combined_histo[1] last_entropy[1] = last_entropy[0] last_entropy[0] = combined_entropy[1] self.num_blocks_++ self.block_size_ = 0 histogramClearDistance(&histograms[self.curr_histogram_ix_]) self.merge_last_count_ = 0 self.target_block_size_ = self.min_block_size_ } else { /* Combine this block with last block. */ split.lengths[self.num_blocks_-1] += uint32(self.block_size_) histograms[self.last_histogram_ix_[0]] = combined_histo[0] last_entropy[0] = combined_entropy[0] if split.num_types == 1 { last_entropy[1] = last_entropy[0] } self.block_size_ = 0 histogramClearDistance(&histograms[self.curr_histogram_ix_]) self.merge_last_count_++ if self.merge_last_count_ > 1 { self.target_block_size_ += self.min_block_size_ } } } if is_final { *self.histograms_size_ = split.num_types split.num_blocks = self.num_blocks_ } } /* Adds the next symbol to the current histogram. When the current histogram reaches the target size, decides on merging the block. */ func blockSplitterAddSymbolDistance(self *blockSplitterDistance, symbol uint) { histogramAddDistance(&self.histograms_[self.curr_histogram_ix_], symbol) self.block_size_++ if self.block_size_ == self.target_block_size_ { blockSplitterFinishBlockDistance(self, false) /* is_final = */ } }