937 lines
34 KiB
C
937 lines
34 KiB
C
// Copyright 2012 Google Inc. All Rights Reserved.
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//
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// Use of this source code is governed by a BSD-style license
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// that can be found in the COPYING file in the root of the source
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// tree. An additional intellectual property rights grant can be found
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// in the file PATENTS. All contributing project authors may
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// be found in the AUTHORS file in the root of the source tree.
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// -----------------------------------------------------------------------------
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//
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// Author: Jyrki Alakuijala (jyrki@google.com)
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//
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#ifdef HAVE_CONFIG_H
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#include "webp/config.h"
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#endif
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#include <math.h>
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#include "./backward_references.h"
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#include "./histogram.h"
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#include "../dsp/lossless.h"
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#include "../utils/utils.h"
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#define MAX_COST 1.e38
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// Number of partitions for the three dominant (literal, red and blue) symbol
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// costs.
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#define NUM_PARTITIONS 4
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// The size of the bin-hash corresponding to the three dominant costs.
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#define BIN_SIZE (NUM_PARTITIONS * NUM_PARTITIONS * NUM_PARTITIONS)
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// Maximum number of histograms allowed in greedy combining algorithm.
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#define MAX_HISTO_GREEDY 100
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static void HistogramClear(VP8LHistogram* const p) {
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uint32_t* const literal = p->literal_;
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const int cache_bits = p->palette_code_bits_;
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const int histo_size = VP8LGetHistogramSize(cache_bits);
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memset(p, 0, histo_size);
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p->palette_code_bits_ = cache_bits;
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p->literal_ = literal;
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}
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// Swap two histogram pointers.
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static void HistogramSwap(VP8LHistogram** const A, VP8LHistogram** const B) {
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VP8LHistogram* const tmp = *A;
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*A = *B;
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*B = tmp;
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}
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static void HistogramCopy(const VP8LHistogram* const src,
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VP8LHistogram* const dst) {
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uint32_t* const dst_literal = dst->literal_;
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const int dst_cache_bits = dst->palette_code_bits_;
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const int histo_size = VP8LGetHistogramSize(dst_cache_bits);
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assert(src->palette_code_bits_ == dst_cache_bits);
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memcpy(dst, src, histo_size);
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dst->literal_ = dst_literal;
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}
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int VP8LGetHistogramSize(int cache_bits) {
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const int literal_size = VP8LHistogramNumCodes(cache_bits);
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const size_t total_size = sizeof(VP8LHistogram) + sizeof(int) * literal_size;
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assert(total_size <= (size_t)0x7fffffff);
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return (int)total_size;
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}
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void VP8LFreeHistogram(VP8LHistogram* const histo) {
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WebPSafeFree(histo);
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}
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void VP8LFreeHistogramSet(VP8LHistogramSet* const histo) {
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WebPSafeFree(histo);
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}
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void VP8LHistogramStoreRefs(const VP8LBackwardRefs* const refs,
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VP8LHistogram* const histo) {
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VP8LRefsCursor c = VP8LRefsCursorInit(refs);
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while (VP8LRefsCursorOk(&c)) {
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VP8LHistogramAddSinglePixOrCopy(histo, c.cur_pos);
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VP8LRefsCursorNext(&c);
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}
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}
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void VP8LHistogramCreate(VP8LHistogram* const p,
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const VP8LBackwardRefs* const refs,
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int palette_code_bits) {
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if (palette_code_bits >= 0) {
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p->palette_code_bits_ = palette_code_bits;
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}
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HistogramClear(p);
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VP8LHistogramStoreRefs(refs, p);
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}
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void VP8LHistogramInit(VP8LHistogram* const p, int palette_code_bits) {
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p->palette_code_bits_ = palette_code_bits;
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HistogramClear(p);
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}
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VP8LHistogram* VP8LAllocateHistogram(int cache_bits) {
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VP8LHistogram* histo = NULL;
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const int total_size = VP8LGetHistogramSize(cache_bits);
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uint8_t* const memory = (uint8_t*)WebPSafeMalloc(total_size, sizeof(*memory));
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if (memory == NULL) return NULL;
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histo = (VP8LHistogram*)memory;
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// literal_ won't necessary be aligned.
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histo->literal_ = (uint32_t*)(memory + sizeof(VP8LHistogram));
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VP8LHistogramInit(histo, cache_bits);
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return histo;
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}
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VP8LHistogramSet* VP8LAllocateHistogramSet(int size, int cache_bits) {
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int i;
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VP8LHistogramSet* set;
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const int histo_size = VP8LGetHistogramSize(cache_bits);
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const size_t total_size =
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sizeof(*set) + size * (sizeof(*set->histograms) +
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histo_size + WEBP_ALIGN_CST);
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uint8_t* memory = (uint8_t*)WebPSafeMalloc(total_size, sizeof(*memory));
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if (memory == NULL) return NULL;
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set = (VP8LHistogramSet*)memory;
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memory += sizeof(*set);
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set->histograms = (VP8LHistogram**)memory;
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memory += size * sizeof(*set->histograms);
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set->max_size = size;
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set->size = size;
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for (i = 0; i < size; ++i) {
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memory = (uint8_t*)WEBP_ALIGN(memory);
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set->histograms[i] = (VP8LHistogram*)memory;
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// literal_ won't necessary be aligned.
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set->histograms[i]->literal_ = (uint32_t*)(memory + sizeof(VP8LHistogram));
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VP8LHistogramInit(set->histograms[i], cache_bits);
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memory += histo_size;
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}
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return set;
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}
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// -----------------------------------------------------------------------------
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void VP8LHistogramAddSinglePixOrCopy(VP8LHistogram* const histo,
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const PixOrCopy* const v) {
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if (PixOrCopyIsLiteral(v)) {
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++histo->alpha_[PixOrCopyLiteral(v, 3)];
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++histo->red_[PixOrCopyLiteral(v, 2)];
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++histo->literal_[PixOrCopyLiteral(v, 1)];
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++histo->blue_[PixOrCopyLiteral(v, 0)];
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} else if (PixOrCopyIsCacheIdx(v)) {
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const int literal_ix =
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NUM_LITERAL_CODES + NUM_LENGTH_CODES + PixOrCopyCacheIdx(v);
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++histo->literal_[literal_ix];
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} else {
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int code, extra_bits;
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VP8LPrefixEncodeBits(PixOrCopyLength(v), &code, &extra_bits);
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++histo->literal_[NUM_LITERAL_CODES + code];
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VP8LPrefixEncodeBits(PixOrCopyDistance(v), &code, &extra_bits);
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++histo->distance_[code];
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}
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}
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// -----------------------------------------------------------------------------
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// Entropy-related functions.
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static WEBP_INLINE double BitsEntropyRefine(const VP8LBitEntropy* entropy) {
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double mix;
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if (entropy->nonzeros < 5) {
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if (entropy->nonzeros <= 1) {
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return 0;
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}
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// Two symbols, they will be 0 and 1 in a Huffman code.
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// Let's mix in a bit of entropy to favor good clustering when
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// distributions of these are combined.
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if (entropy->nonzeros == 2) {
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return 0.99 * entropy->sum + 0.01 * entropy->entropy;
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}
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// No matter what the entropy says, we cannot be better than min_limit
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// with Huffman coding. I am mixing a bit of entropy into the
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// min_limit since it produces much better (~0.5 %) compression results
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// perhaps because of better entropy clustering.
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if (entropy->nonzeros == 3) {
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mix = 0.95;
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} else {
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mix = 0.7; // nonzeros == 4.
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}
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} else {
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mix = 0.627;
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}
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{
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double min_limit = 2 * entropy->sum - entropy->max_val;
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min_limit = mix * min_limit + (1.0 - mix) * entropy->entropy;
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return (entropy->entropy < min_limit) ? min_limit : entropy->entropy;
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}
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}
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double VP8LBitsEntropy(const uint32_t* const array, int n,
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uint32_t* const trivial_symbol) {
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VP8LBitEntropy entropy;
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VP8LBitsEntropyUnrefined(array, n, &entropy);
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if (trivial_symbol != NULL) {
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*trivial_symbol =
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(entropy.nonzeros == 1) ? entropy.nonzero_code : VP8L_NON_TRIVIAL_SYM;
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}
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return BitsEntropyRefine(&entropy);
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}
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static double InitialHuffmanCost(void) {
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// Small bias because Huffman code length is typically not stored in
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// full length.
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static const int kHuffmanCodeOfHuffmanCodeSize = CODE_LENGTH_CODES * 3;
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static const double kSmallBias = 9.1;
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return kHuffmanCodeOfHuffmanCodeSize - kSmallBias;
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}
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// Finalize the Huffman cost based on streak numbers and length type (<3 or >=3)
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static double FinalHuffmanCost(const VP8LStreaks* const stats) {
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double retval = InitialHuffmanCost();
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retval += stats->counts[0] * 1.5625 + 0.234375 * stats->streaks[0][1];
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retval += stats->counts[1] * 2.578125 + 0.703125 * stats->streaks[1][1];
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retval += 1.796875 * stats->streaks[0][0];
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retval += 3.28125 * stats->streaks[1][0];
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return retval;
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}
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// Get the symbol entropy for the distribution 'population'.
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// Set 'trivial_sym', if there's only one symbol present in the distribution.
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static double PopulationCost(const uint32_t* const population, int length,
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uint32_t* const trivial_sym) {
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VP8LBitEntropy bit_entropy;
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VP8LStreaks stats;
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VP8LGetEntropyUnrefined(population, length, &bit_entropy, &stats);
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if (trivial_sym != NULL) {
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*trivial_sym = (bit_entropy.nonzeros == 1) ? bit_entropy.nonzero_code
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: VP8L_NON_TRIVIAL_SYM;
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}
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return BitsEntropyRefine(&bit_entropy) + FinalHuffmanCost(&stats);
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}
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static WEBP_INLINE double GetCombinedEntropy(const uint32_t* const X,
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const uint32_t* const Y,
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int length) {
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VP8LBitEntropy bit_entropy;
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VP8LStreaks stats;
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VP8LGetCombinedEntropyUnrefined(X, Y, length, &bit_entropy, &stats);
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return BitsEntropyRefine(&bit_entropy) + FinalHuffmanCost(&stats);
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}
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// Estimates the Entropy + Huffman + other block overhead size cost.
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double VP8LHistogramEstimateBits(const VP8LHistogram* const p) {
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return
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PopulationCost(
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p->literal_, VP8LHistogramNumCodes(p->palette_code_bits_), NULL)
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+ PopulationCost(p->red_, NUM_LITERAL_CODES, NULL)
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+ PopulationCost(p->blue_, NUM_LITERAL_CODES, NULL)
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+ PopulationCost(p->alpha_, NUM_LITERAL_CODES, NULL)
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+ PopulationCost(p->distance_, NUM_DISTANCE_CODES, NULL)
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+ VP8LExtraCost(p->literal_ + NUM_LITERAL_CODES, NUM_LENGTH_CODES)
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+ VP8LExtraCost(p->distance_, NUM_DISTANCE_CODES);
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}
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// -----------------------------------------------------------------------------
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// Various histogram combine/cost-eval functions
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static int GetCombinedHistogramEntropy(const VP8LHistogram* const a,
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const VP8LHistogram* const b,
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double cost_threshold,
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double* cost) {
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const int palette_code_bits = a->palette_code_bits_;
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assert(a->palette_code_bits_ == b->palette_code_bits_);
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*cost += GetCombinedEntropy(a->literal_, b->literal_,
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VP8LHistogramNumCodes(palette_code_bits));
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*cost += VP8LExtraCostCombined(a->literal_ + NUM_LITERAL_CODES,
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b->literal_ + NUM_LITERAL_CODES,
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NUM_LENGTH_CODES);
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if (*cost > cost_threshold) return 0;
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*cost += GetCombinedEntropy(a->red_, b->red_, NUM_LITERAL_CODES);
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if (*cost > cost_threshold) return 0;
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*cost += GetCombinedEntropy(a->blue_, b->blue_, NUM_LITERAL_CODES);
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if (*cost > cost_threshold) return 0;
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*cost += GetCombinedEntropy(a->alpha_, b->alpha_, NUM_LITERAL_CODES);
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if (*cost > cost_threshold) return 0;
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*cost += GetCombinedEntropy(a->distance_, b->distance_, NUM_DISTANCE_CODES);
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*cost +=
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VP8LExtraCostCombined(a->distance_, b->distance_, NUM_DISTANCE_CODES);
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if (*cost > cost_threshold) return 0;
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return 1;
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}
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// Performs out = a + b, computing the cost C(a+b) - C(a) - C(b) while comparing
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// to the threshold value 'cost_threshold'. The score returned is
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// Score = C(a+b) - C(a) - C(b), where C(a) + C(b) is known and fixed.
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// Since the previous score passed is 'cost_threshold', we only need to compare
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// the partial cost against 'cost_threshold + C(a) + C(b)' to possibly bail-out
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// early.
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static double HistogramAddEval(const VP8LHistogram* const a,
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const VP8LHistogram* const b,
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VP8LHistogram* const out,
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double cost_threshold) {
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double cost = 0;
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const double sum_cost = a->bit_cost_ + b->bit_cost_;
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cost_threshold += sum_cost;
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if (GetCombinedHistogramEntropy(a, b, cost_threshold, &cost)) {
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VP8LHistogramAdd(a, b, out);
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out->bit_cost_ = cost;
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out->palette_code_bits_ = a->palette_code_bits_;
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out->trivial_symbol_ = (a->trivial_symbol_ == b->trivial_symbol_) ?
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a->trivial_symbol_ : VP8L_NON_TRIVIAL_SYM;
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}
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return cost - sum_cost;
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}
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// Same as HistogramAddEval(), except that the resulting histogram
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// is not stored. Only the cost C(a+b) - C(a) is evaluated. We omit
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// the term C(b) which is constant over all the evaluations.
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static double HistogramAddThresh(const VP8LHistogram* const a,
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const VP8LHistogram* const b,
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double cost_threshold) {
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double cost = -a->bit_cost_;
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GetCombinedHistogramEntropy(a, b, cost_threshold, &cost);
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return cost;
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}
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// -----------------------------------------------------------------------------
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// The structure to keep track of cost range for the three dominant entropy
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// symbols.
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// TODO(skal): Evaluate if float can be used here instead of double for
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// representing the entropy costs.
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typedef struct {
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double literal_max_;
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double literal_min_;
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double red_max_;
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double red_min_;
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double blue_max_;
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double blue_min_;
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} DominantCostRange;
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static void DominantCostRangeInit(DominantCostRange* const c) {
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c->literal_max_ = 0.;
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c->literal_min_ = MAX_COST;
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c->red_max_ = 0.;
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c->red_min_ = MAX_COST;
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c->blue_max_ = 0.;
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c->blue_min_ = MAX_COST;
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}
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static void UpdateDominantCostRange(
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const VP8LHistogram* const h, DominantCostRange* const c) {
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if (c->literal_max_ < h->literal_cost_) c->literal_max_ = h->literal_cost_;
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if (c->literal_min_ > h->literal_cost_) c->literal_min_ = h->literal_cost_;
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if (c->red_max_ < h->red_cost_) c->red_max_ = h->red_cost_;
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if (c->red_min_ > h->red_cost_) c->red_min_ = h->red_cost_;
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if (c->blue_max_ < h->blue_cost_) c->blue_max_ = h->blue_cost_;
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if (c->blue_min_ > h->blue_cost_) c->blue_min_ = h->blue_cost_;
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}
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static void UpdateHistogramCost(VP8LHistogram* const h) {
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uint32_t alpha_sym, red_sym, blue_sym;
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const double alpha_cost =
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PopulationCost(h->alpha_, NUM_LITERAL_CODES, &alpha_sym);
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const double distance_cost =
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PopulationCost(h->distance_, NUM_DISTANCE_CODES, NULL) +
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VP8LExtraCost(h->distance_, NUM_DISTANCE_CODES);
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const int num_codes = VP8LHistogramNumCodes(h->palette_code_bits_);
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h->literal_cost_ = PopulationCost(h->literal_, num_codes, NULL) +
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VP8LExtraCost(h->literal_ + NUM_LITERAL_CODES,
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NUM_LENGTH_CODES);
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h->red_cost_ = PopulationCost(h->red_, NUM_LITERAL_CODES, &red_sym);
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h->blue_cost_ = PopulationCost(h->blue_, NUM_LITERAL_CODES, &blue_sym);
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h->bit_cost_ = h->literal_cost_ + h->red_cost_ + h->blue_cost_ +
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alpha_cost + distance_cost;
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if ((alpha_sym | red_sym | blue_sym) == VP8L_NON_TRIVIAL_SYM) {
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h->trivial_symbol_ = VP8L_NON_TRIVIAL_SYM;
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} else {
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h->trivial_symbol_ =
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((uint32_t)alpha_sym << 24) | (red_sym << 16) | (blue_sym << 0);
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}
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}
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static int GetBinIdForEntropy(double min, double max, double val) {
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const double range = max - min;
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if (range > 0.) {
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const double delta = val - min;
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return (int)((NUM_PARTITIONS - 1e-6) * delta / range);
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} else {
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return 0;
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}
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}
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static int GetHistoBinIndex(const VP8LHistogram* const h,
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const DominantCostRange* const c, int low_effort) {
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int bin_id = GetBinIdForEntropy(c->literal_min_, c->literal_max_,
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h->literal_cost_);
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assert(bin_id < NUM_PARTITIONS);
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if (!low_effort) {
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bin_id = bin_id * NUM_PARTITIONS
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+ GetBinIdForEntropy(c->red_min_, c->red_max_, h->red_cost_);
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bin_id = bin_id * NUM_PARTITIONS
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+ GetBinIdForEntropy(c->blue_min_, c->blue_max_, h->blue_cost_);
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assert(bin_id < BIN_SIZE);
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}
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return bin_id;
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}
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// Construct the histograms from backward references.
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static void HistogramBuild(
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int xsize, int histo_bits, const VP8LBackwardRefs* const backward_refs,
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VP8LHistogramSet* const image_histo) {
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int x = 0, y = 0;
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const int histo_xsize = VP8LSubSampleSize(xsize, histo_bits);
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VP8LHistogram** const histograms = image_histo->histograms;
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VP8LRefsCursor c = VP8LRefsCursorInit(backward_refs);
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assert(histo_bits > 0);
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while (VP8LRefsCursorOk(&c)) {
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const PixOrCopy* const v = c.cur_pos;
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const int ix = (y >> histo_bits) * histo_xsize + (x >> histo_bits);
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VP8LHistogramAddSinglePixOrCopy(histograms[ix], v);
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x += PixOrCopyLength(v);
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while (x >= xsize) {
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x -= xsize;
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++y;
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}
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VP8LRefsCursorNext(&c);
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}
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}
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// Copies the histograms and computes its bit_cost.
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static void HistogramCopyAndAnalyze(
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VP8LHistogramSet* const orig_histo, VP8LHistogramSet* const image_histo) {
|
|
int i;
|
|
const int histo_size = orig_histo->size;
|
|
VP8LHistogram** const orig_histograms = orig_histo->histograms;
|
|
VP8LHistogram** const histograms = image_histo->histograms;
|
|
for (i = 0; i < histo_size; ++i) {
|
|
VP8LHistogram* const histo = orig_histograms[i];
|
|
UpdateHistogramCost(histo);
|
|
// Copy histograms from orig_histo[] to image_histo[].
|
|
HistogramCopy(histo, histograms[i]);
|
|
}
|
|
}
|
|
|
|
// Partition histograms to different entropy bins for three dominant (literal,
|
|
// red and blue) symbol costs and compute the histogram aggregate bit_cost.
|
|
static void HistogramAnalyzeEntropyBin(VP8LHistogramSet* const image_histo,
|
|
int16_t* const bin_map, int low_effort) {
|
|
int i;
|
|
VP8LHistogram** const histograms = image_histo->histograms;
|
|
const int histo_size = image_histo->size;
|
|
const int bin_depth = histo_size + 1;
|
|
DominantCostRange cost_range;
|
|
DominantCostRangeInit(&cost_range);
|
|
|
|
// Analyze the dominant (literal, red and blue) entropy costs.
|
|
for (i = 0; i < histo_size; ++i) {
|
|
VP8LHistogram* const histo = histograms[i];
|
|
UpdateDominantCostRange(histo, &cost_range);
|
|
}
|
|
|
|
// bin-hash histograms on three of the dominant (literal, red and blue)
|
|
// symbol costs.
|
|
for (i = 0; i < histo_size; ++i) {
|
|
const VP8LHistogram* const histo = histograms[i];
|
|
const int bin_id = GetHistoBinIndex(histo, &cost_range, low_effort);
|
|
const int bin_offset = bin_id * bin_depth;
|
|
// bin_map[n][0] for every bin 'n' maintains the counter for the number of
|
|
// histograms in that bin.
|
|
// Get and increment the num_histos in that bin.
|
|
const int num_histos = ++bin_map[bin_offset];
|
|
assert(bin_offset + num_histos < bin_depth * BIN_SIZE);
|
|
// Add histogram i'th index at num_histos (last) position in the bin_map.
|
|
bin_map[bin_offset + num_histos] = i;
|
|
}
|
|
}
|
|
|
|
// Compact the histogram set by removing unused entries.
|
|
static void HistogramCompactBins(VP8LHistogramSet* const image_histo) {
|
|
VP8LHistogram** const histograms = image_histo->histograms;
|
|
int i, j;
|
|
|
|
for (i = 0, j = 0; i < image_histo->size; ++i) {
|
|
if (histograms[i] != NULL && histograms[i]->bit_cost_ != 0.) {
|
|
if (j < i) {
|
|
histograms[j] = histograms[i];
|
|
histograms[i] = NULL;
|
|
}
|
|
++j;
|
|
}
|
|
}
|
|
image_histo->size = j;
|
|
}
|
|
|
|
static VP8LHistogram* HistogramCombineEntropyBin(
|
|
VP8LHistogramSet* const image_histo,
|
|
VP8LHistogram* cur_combo,
|
|
int16_t* const bin_map, int bin_depth, int num_bins,
|
|
double combine_cost_factor, int low_effort) {
|
|
int bin_id;
|
|
VP8LHistogram** const histograms = image_histo->histograms;
|
|
|
|
for (bin_id = 0; bin_id < num_bins; ++bin_id) {
|
|
const int bin_offset = bin_id * bin_depth;
|
|
const int num_histos = bin_map[bin_offset];
|
|
const int idx1 = bin_map[bin_offset + 1];
|
|
int num_combine_failures = 0;
|
|
int n;
|
|
for (n = 2; n <= num_histos; ++n) {
|
|
const int idx2 = bin_map[bin_offset + n];
|
|
if (low_effort) {
|
|
// Merge all histograms with the same bin index, irrespective of cost of
|
|
// the merged histograms.
|
|
VP8LHistogramAdd(histograms[idx1], histograms[idx2], histograms[idx1]);
|
|
histograms[idx2]->bit_cost_ = 0.;
|
|
} else {
|
|
const double bit_cost_idx2 = histograms[idx2]->bit_cost_;
|
|
if (bit_cost_idx2 > 0.) {
|
|
const double bit_cost_thresh = -bit_cost_idx2 * combine_cost_factor;
|
|
const double curr_cost_diff =
|
|
HistogramAddEval(histograms[idx1], histograms[idx2],
|
|
cur_combo, bit_cost_thresh);
|
|
if (curr_cost_diff < bit_cost_thresh) {
|
|
// Try to merge two histograms only if the combo is a trivial one or
|
|
// the two candidate histograms are already non-trivial.
|
|
// For some images, 'try_combine' turns out to be false for a lot of
|
|
// histogram pairs. In that case, we fallback to combining
|
|
// histograms as usual to avoid increasing the header size.
|
|
const int try_combine =
|
|
(cur_combo->trivial_symbol_ != VP8L_NON_TRIVIAL_SYM) ||
|
|
((histograms[idx1]->trivial_symbol_ == VP8L_NON_TRIVIAL_SYM) &&
|
|
(histograms[idx2]->trivial_symbol_ == VP8L_NON_TRIVIAL_SYM));
|
|
const int max_combine_failures = 32;
|
|
if (try_combine || (num_combine_failures >= max_combine_failures)) {
|
|
HistogramSwap(&cur_combo, &histograms[idx1]);
|
|
histograms[idx2]->bit_cost_ = 0.;
|
|
} else {
|
|
++num_combine_failures;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}
|
|
if (low_effort) {
|
|
// Update the bit_cost for the merged histograms (per bin index).
|
|
UpdateHistogramCost(histograms[idx1]);
|
|
}
|
|
}
|
|
HistogramCompactBins(image_histo);
|
|
return cur_combo;
|
|
}
|
|
|
|
static uint32_t MyRand(uint32_t *seed) {
|
|
*seed *= 16807U;
|
|
if (*seed == 0) {
|
|
*seed = 1;
|
|
}
|
|
return *seed;
|
|
}
|
|
|
|
// -----------------------------------------------------------------------------
|
|
// Histogram pairs priority queue
|
|
|
|
// Pair of histograms. Negative idx1 value means that pair is out-of-date.
|
|
typedef struct {
|
|
int idx1;
|
|
int idx2;
|
|
double cost_diff;
|
|
double cost_combo;
|
|
} HistogramPair;
|
|
|
|
typedef struct {
|
|
HistogramPair* queue;
|
|
int size;
|
|
int max_size;
|
|
} HistoQueue;
|
|
|
|
static int HistoQueueInit(HistoQueue* const histo_queue, const int max_index) {
|
|
histo_queue->size = 0;
|
|
// max_index^2 for the queue size is safe. If you look at
|
|
// HistogramCombineGreedy, and imagine that UpdateQueueFront always pushes
|
|
// data to the queue, you insert at most:
|
|
// - max_index*(max_index-1)/2 (the first two for loops)
|
|
// - max_index - 1 in the last for loop at the first iteration of the while
|
|
// loop, max_index - 2 at the second iteration ... therefore
|
|
// max_index*(max_index-1)/2 overall too
|
|
histo_queue->max_size = max_index * max_index;
|
|
// We allocate max_size + 1 because the last element at index "size" is
|
|
// used as temporary data (and it could be up to max_size).
|
|
histo_queue->queue = WebPSafeMalloc(histo_queue->max_size + 1,
|
|
sizeof(*histo_queue->queue));
|
|
return histo_queue->queue != NULL;
|
|
}
|
|
|
|
static void HistoQueueClear(HistoQueue* const histo_queue) {
|
|
assert(histo_queue != NULL);
|
|
WebPSafeFree(histo_queue->queue);
|
|
}
|
|
|
|
static void SwapHistogramPairs(HistogramPair *p1,
|
|
HistogramPair *p2) {
|
|
const HistogramPair tmp = *p1;
|
|
*p1 = *p2;
|
|
*p2 = tmp;
|
|
}
|
|
|
|
// Given a valid priority queue in range [0, queue_size) this function checks
|
|
// whether histo_queue[queue_size] should be accepted and swaps it with the
|
|
// front if it is smaller. Otherwise, it leaves it as is.
|
|
static void UpdateQueueFront(HistoQueue* const histo_queue) {
|
|
if (histo_queue->queue[histo_queue->size].cost_diff >= 0) return;
|
|
|
|
if (histo_queue->queue[histo_queue->size].cost_diff <
|
|
histo_queue->queue[0].cost_diff) {
|
|
SwapHistogramPairs(histo_queue->queue,
|
|
histo_queue->queue + histo_queue->size);
|
|
}
|
|
++histo_queue->size;
|
|
|
|
// We cannot add more elements than the capacity.
|
|
// The allocation adds an extra element to the official capacity so that
|
|
// histo_queue->queue[histo_queue->max_size] is read/written within bound.
|
|
assert(histo_queue->size <= histo_queue->max_size);
|
|
}
|
|
|
|
// -----------------------------------------------------------------------------
|
|
|
|
static void PreparePair(VP8LHistogram** histograms, int idx1, int idx2,
|
|
HistogramPair* const pair) {
|
|
VP8LHistogram* h1;
|
|
VP8LHistogram* h2;
|
|
double sum_cost;
|
|
|
|
if (idx1 > idx2) {
|
|
const int tmp = idx2;
|
|
idx2 = idx1;
|
|
idx1 = tmp;
|
|
}
|
|
pair->idx1 = idx1;
|
|
pair->idx2 = idx2;
|
|
h1 = histograms[idx1];
|
|
h2 = histograms[idx2];
|
|
sum_cost = h1->bit_cost_ + h2->bit_cost_;
|
|
pair->cost_combo = 0.;
|
|
GetCombinedHistogramEntropy(h1, h2, sum_cost, &pair->cost_combo);
|
|
pair->cost_diff = pair->cost_combo - sum_cost;
|
|
}
|
|
|
|
// Combines histograms by continuously choosing the one with the highest cost
|
|
// reduction.
|
|
static int HistogramCombineGreedy(VP8LHistogramSet* const image_histo) {
|
|
int ok = 0;
|
|
int image_histo_size = image_histo->size;
|
|
int i, j;
|
|
VP8LHistogram** const histograms = image_histo->histograms;
|
|
// Indexes of remaining histograms.
|
|
int* const clusters = WebPSafeMalloc(image_histo_size, sizeof(*clusters));
|
|
// Priority queue of histogram pairs.
|
|
HistoQueue histo_queue;
|
|
|
|
if (!HistoQueueInit(&histo_queue, image_histo_size) || clusters == NULL) {
|
|
goto End;
|
|
}
|
|
|
|
for (i = 0; i < image_histo_size; ++i) {
|
|
// Initialize clusters indexes.
|
|
clusters[i] = i;
|
|
for (j = i + 1; j < image_histo_size; ++j) {
|
|
// Initialize positions array.
|
|
PreparePair(histograms, i, j, &histo_queue.queue[histo_queue.size]);
|
|
UpdateQueueFront(&histo_queue);
|
|
}
|
|
}
|
|
|
|
while (image_histo_size > 1 && histo_queue.size > 0) {
|
|
HistogramPair* copy_to;
|
|
const int idx1 = histo_queue.queue[0].idx1;
|
|
const int idx2 = histo_queue.queue[0].idx2;
|
|
VP8LHistogramAdd(histograms[idx2], histograms[idx1], histograms[idx1]);
|
|
histograms[idx1]->bit_cost_ = histo_queue.queue[0].cost_combo;
|
|
// Remove merged histogram.
|
|
for (i = 0; i + 1 < image_histo_size; ++i) {
|
|
if (clusters[i] >= idx2) {
|
|
clusters[i] = clusters[i + 1];
|
|
}
|
|
}
|
|
--image_histo_size;
|
|
|
|
// Remove pairs intersecting the just combined best pair. This will
|
|
// therefore pop the head of the queue.
|
|
copy_to = histo_queue.queue;
|
|
for (i = 0; i < histo_queue.size; ++i) {
|
|
HistogramPair* const p = histo_queue.queue + i;
|
|
if (p->idx1 == idx1 || p->idx2 == idx1 ||
|
|
p->idx1 == idx2 || p->idx2 == idx2) {
|
|
// Do not copy the invalid pair.
|
|
continue;
|
|
}
|
|
if (p->cost_diff < histo_queue.queue[0].cost_diff) {
|
|
// Replace the top of the queue if we found better.
|
|
SwapHistogramPairs(histo_queue.queue, p);
|
|
}
|
|
SwapHistogramPairs(copy_to, p);
|
|
++copy_to;
|
|
}
|
|
histo_queue.size = (int)(copy_to - histo_queue.queue);
|
|
|
|
// Push new pairs formed with combined histogram to the queue.
|
|
for (i = 0; i < image_histo_size; ++i) {
|
|
if (clusters[i] != idx1) {
|
|
PreparePair(histograms, idx1, clusters[i],
|
|
&histo_queue.queue[histo_queue.size]);
|
|
UpdateQueueFront(&histo_queue);
|
|
}
|
|
}
|
|
}
|
|
// Move remaining histograms to the beginning of the array.
|
|
for (i = 0; i < image_histo_size; ++i) {
|
|
if (i != clusters[i]) { // swap the two histograms
|
|
HistogramSwap(&histograms[i], &histograms[clusters[i]]);
|
|
}
|
|
}
|
|
|
|
image_histo->size = image_histo_size;
|
|
ok = 1;
|
|
|
|
End:
|
|
WebPSafeFree(clusters);
|
|
HistoQueueClear(&histo_queue);
|
|
return ok;
|
|
}
|
|
|
|
static void HistogramCombineStochastic(VP8LHistogramSet* const image_histo,
|
|
VP8LHistogram* tmp_histo,
|
|
VP8LHistogram* best_combo,
|
|
int quality, int min_cluster_size) {
|
|
int iter;
|
|
uint32_t seed = 0;
|
|
int tries_with_no_success = 0;
|
|
int image_histo_size = image_histo->size;
|
|
const int iter_mult = (quality < 25) ? 2 : 2 + (quality - 25) / 8;
|
|
const int outer_iters = image_histo_size * iter_mult;
|
|
const int num_pairs = image_histo_size / 2;
|
|
const int num_tries_no_success = outer_iters / 2;
|
|
VP8LHistogram** const histograms = image_histo->histograms;
|
|
|
|
// Collapse similar histograms in 'image_histo'.
|
|
++min_cluster_size;
|
|
for (iter = 0;
|
|
iter < outer_iters && image_histo_size >= min_cluster_size;
|
|
++iter) {
|
|
double best_cost_diff = 0.;
|
|
int best_idx1 = -1, best_idx2 = 1;
|
|
int j;
|
|
const int num_tries =
|
|
(num_pairs < image_histo_size) ? num_pairs : image_histo_size;
|
|
seed += iter;
|
|
for (j = 0; j < num_tries; ++j) {
|
|
double curr_cost_diff;
|
|
// Choose two histograms at random and try to combine them.
|
|
const uint32_t idx1 = MyRand(&seed) % image_histo_size;
|
|
const uint32_t tmp = (j & 7) + 1;
|
|
const uint32_t diff =
|
|
(tmp < 3) ? tmp : MyRand(&seed) % (image_histo_size - 1);
|
|
const uint32_t idx2 = (idx1 + diff + 1) % image_histo_size;
|
|
if (idx1 == idx2) {
|
|
continue;
|
|
}
|
|
|
|
// Calculate cost reduction on combining.
|
|
curr_cost_diff = HistogramAddEval(histograms[idx1], histograms[idx2],
|
|
tmp_histo, best_cost_diff);
|
|
if (curr_cost_diff < best_cost_diff) { // found a better pair?
|
|
HistogramSwap(&best_combo, &tmp_histo);
|
|
best_cost_diff = curr_cost_diff;
|
|
best_idx1 = idx1;
|
|
best_idx2 = idx2;
|
|
}
|
|
}
|
|
|
|
if (best_idx1 >= 0) {
|
|
HistogramSwap(&best_combo, &histograms[best_idx1]);
|
|
// swap best_idx2 slot with last one (which is now unused)
|
|
--image_histo_size;
|
|
if (best_idx2 != image_histo_size) {
|
|
HistogramSwap(&histograms[image_histo_size], &histograms[best_idx2]);
|
|
histograms[image_histo_size] = NULL;
|
|
}
|
|
tries_with_no_success = 0;
|
|
}
|
|
if (++tries_with_no_success >= num_tries_no_success) {
|
|
break;
|
|
}
|
|
}
|
|
image_histo->size = image_histo_size;
|
|
}
|
|
|
|
// -----------------------------------------------------------------------------
|
|
// Histogram refinement
|
|
|
|
// Find the best 'out' histogram for each of the 'in' histograms.
|
|
// Note: we assume that out[]->bit_cost_ is already up-to-date.
|
|
static void HistogramRemap(const VP8LHistogramSet* const in,
|
|
const VP8LHistogramSet* const out,
|
|
uint16_t* const symbols) {
|
|
int i;
|
|
VP8LHistogram** const in_histo = in->histograms;
|
|
VP8LHistogram** const out_histo = out->histograms;
|
|
const int in_size = in->size;
|
|
const int out_size = out->size;
|
|
if (out_size > 1) {
|
|
for (i = 0; i < in_size; ++i) {
|
|
int best_out = 0;
|
|
double best_bits = MAX_COST;
|
|
int k;
|
|
for (k = 0; k < out_size; ++k) {
|
|
const double cur_bits =
|
|
HistogramAddThresh(out_histo[k], in_histo[i], best_bits);
|
|
if (k == 0 || cur_bits < best_bits) {
|
|
best_bits = cur_bits;
|
|
best_out = k;
|
|
}
|
|
}
|
|
symbols[i] = best_out;
|
|
}
|
|
} else {
|
|
assert(out_size == 1);
|
|
for (i = 0; i < in_size; ++i) {
|
|
symbols[i] = 0;
|
|
}
|
|
}
|
|
|
|
// Recompute each out based on raw and symbols.
|
|
for (i = 0; i < out_size; ++i) {
|
|
HistogramClear(out_histo[i]);
|
|
}
|
|
|
|
for (i = 0; i < in_size; ++i) {
|
|
const int idx = symbols[i];
|
|
VP8LHistogramAdd(in_histo[i], out_histo[idx], out_histo[idx]);
|
|
}
|
|
}
|
|
|
|
static double GetCombineCostFactor(int histo_size, int quality) {
|
|
double combine_cost_factor = 0.16;
|
|
if (quality < 90) {
|
|
if (histo_size > 256) combine_cost_factor /= 2.;
|
|
if (histo_size > 512) combine_cost_factor /= 2.;
|
|
if (histo_size > 1024) combine_cost_factor /= 2.;
|
|
if (quality <= 50) combine_cost_factor /= 2.;
|
|
}
|
|
return combine_cost_factor;
|
|
}
|
|
|
|
int VP8LGetHistoImageSymbols(int xsize, int ysize,
|
|
const VP8LBackwardRefs* const refs,
|
|
int quality, int low_effort,
|
|
int histo_bits, int cache_bits,
|
|
VP8LHistogramSet* const image_histo,
|
|
VP8LHistogramSet* const tmp_histos,
|
|
uint16_t* const histogram_symbols) {
|
|
int ok = 0;
|
|
const int histo_xsize = histo_bits ? VP8LSubSampleSize(xsize, histo_bits) : 1;
|
|
const int histo_ysize = histo_bits ? VP8LSubSampleSize(ysize, histo_bits) : 1;
|
|
const int image_histo_raw_size = histo_xsize * histo_ysize;
|
|
const int entropy_combine_num_bins = low_effort ? NUM_PARTITIONS : BIN_SIZE;
|
|
|
|
// The bin_map for every bin follows following semantics:
|
|
// bin_map[n][0] = num_histo; // The number of histograms in that bin.
|
|
// bin_map[n][1] = index of first histogram in that bin;
|
|
// bin_map[n][num_histo] = index of last histogram in that bin;
|
|
// bin_map[n][num_histo + 1] ... bin_map[n][bin_depth - 1] = unused indices.
|
|
const int bin_depth = image_histo_raw_size + 1;
|
|
int16_t* bin_map = NULL;
|
|
VP8LHistogramSet* const orig_histo =
|
|
VP8LAllocateHistogramSet(image_histo_raw_size, cache_bits);
|
|
VP8LHistogram* cur_combo;
|
|
const int entropy_combine =
|
|
(orig_histo->size > entropy_combine_num_bins * 2) && (quality < 100);
|
|
|
|
if (orig_histo == NULL) goto Error;
|
|
|
|
// Don't attempt linear bin-partition heuristic for:
|
|
// histograms of small sizes, as bin_map will be very sparse and;
|
|
// Maximum quality (q==100), to preserve the compression gains at that level.
|
|
if (entropy_combine) {
|
|
const int bin_map_size = bin_depth * entropy_combine_num_bins;
|
|
bin_map = (int16_t*)WebPSafeCalloc(bin_map_size, sizeof(*bin_map));
|
|
if (bin_map == NULL) goto Error;
|
|
}
|
|
|
|
// Construct the histograms from backward references.
|
|
HistogramBuild(xsize, histo_bits, refs, orig_histo);
|
|
// Copies the histograms and computes its bit_cost.
|
|
HistogramCopyAndAnalyze(orig_histo, image_histo);
|
|
|
|
cur_combo = tmp_histos->histograms[1]; // pick up working slot
|
|
if (entropy_combine) {
|
|
const double combine_cost_factor =
|
|
GetCombineCostFactor(image_histo_raw_size, quality);
|
|
HistogramAnalyzeEntropyBin(orig_histo, bin_map, low_effort);
|
|
// Collapse histograms with similar entropy.
|
|
cur_combo = HistogramCombineEntropyBin(image_histo, cur_combo, bin_map,
|
|
bin_depth, entropy_combine_num_bins,
|
|
combine_cost_factor, low_effort);
|
|
}
|
|
|
|
// Don't combine the histograms using stochastic and greedy heuristics for
|
|
// low-effort compression mode.
|
|
if (!low_effort || !entropy_combine) {
|
|
const float x = quality / 100.f;
|
|
// cubic ramp between 1 and MAX_HISTO_GREEDY:
|
|
const int threshold_size = (int)(1 + (x * x * x) * (MAX_HISTO_GREEDY - 1));
|
|
HistogramCombineStochastic(image_histo, tmp_histos->histograms[0],
|
|
cur_combo, quality, threshold_size);
|
|
if ((image_histo->size <= threshold_size) &&
|
|
!HistogramCombineGreedy(image_histo)) {
|
|
goto Error;
|
|
}
|
|
}
|
|
|
|
// TODO(vikasa): Optimize HistogramRemap for low-effort compression mode also.
|
|
// Find the optimal map from original histograms to the final ones.
|
|
HistogramRemap(orig_histo, image_histo, histogram_symbols);
|
|
|
|
ok = 1;
|
|
|
|
Error:
|
|
WebPSafeFree(bin_map);
|
|
VP8LFreeHistogramSet(orig_histo);
|
|
return ok;
|
|
}
|