// Copyright 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "components/favicon_base/select_favicon_frames.h" #include #include #include #include #include #include "components/favicon_base/favicon_util.h" #include "skia/ext/image_operations.h" #include "third_party/skia/include/core/SkCanvas.h" #include "ui/gfx/image/image.h" #include "ui/gfx/image/image_skia.h" #include "ui/gfx/image/image_skia_source.h" #include "ui/gfx/size.h" namespace { size_t BiggestCandidate(const std::vector& candidate_sizes) { size_t max_index = 0; int max_area = candidate_sizes[0].GetArea(); for (size_t i = 1; i < candidate_sizes.size(); ++i) { int area = candidate_sizes[i].GetArea(); if (area > max_area) { max_area = area; max_index = i; } } return max_index; } SkBitmap SampleNearestNeighbor(const SkBitmap& contents, int desired_size) { SkBitmap bitmap; bitmap.setConfig(SkBitmap::kARGB_8888_Config, desired_size, desired_size); bitmap.allocPixels(); if (!contents.isOpaque()) bitmap.eraseARGB(0, 0, 0, 0); { SkCanvas canvas(bitmap); SkRect dest(SkRect::MakeWH(desired_size, desired_size)); canvas.drawBitmapRect(contents, NULL, dest); } return bitmap; } size_t GetCandidateIndexWithBestScore( const std::vector& candidate_sizes, int desired_size, float* score) { DCHECK_NE(desired_size, 0); // Try to find an exact match. for (size_t i = 0; i < candidate_sizes.size(); ++i) { if (candidate_sizes[i].width() == desired_size && candidate_sizes[i].height() == desired_size) { *score = 1; return i; } } // Huge favicon bitmaps often have a completely different visual style from // smaller favicon bitmaps. Avoid them. const int kHugeEdgeSize = desired_size * 8; // Order of preference: // 1) Bitmaps with width and height smaller than |kHugeEdgeSize|. // 2) Bitmaps which need to be scaled down instead of up. // 3) Bitmaps which do not need to be scaled as much. size_t candidate_index = std::numeric_limits::max(); float candidate_score = 0; for (size_t i = 0; i < candidate_sizes.size(); ++i) { float average_edge = (candidate_sizes[i].width() + candidate_sizes[i].height()) / 2.0f; float score = 0; if (candidate_sizes[i].width() >= kHugeEdgeSize || candidate_sizes[i].height() >= kHugeEdgeSize) { score = std::min(1.0f, desired_size / average_edge) * 0.01f; } else if (candidate_sizes[i].width() >= desired_size && candidate_sizes[i].height() >= desired_size) { score = desired_size / average_edge * 0.01f + 0.15f; } else { score = std::min(1.0f, average_edge / desired_size) * 0.01f + 0.1f; } if (candidate_index == std::numeric_limits::max() || score > candidate_score) { candidate_index = i; candidate_score = score; } } *score = candidate_score; return candidate_index; } // Represents the index of the best candidate for |desired_size| from the // |candidate_sizes| passed into GetCandidateIndicesWithBestScores(). struct SelectionResult { // index in |candidate_sizes| of the best candidate. size_t index; // The desired size for which |index| is the best candidate. int desired_size; }; void GetCandidateIndicesWithBestScores( const std::vector& candidate_sizes, const std::vector& desired_sizes, float* match_score, std::vector* results) { if (candidate_sizes.empty() || desired_sizes.empty()) { if (match_score) *match_score = 0.0f; return; } std::vector::const_iterator zero_size_it = std::find(desired_sizes.begin(), desired_sizes.end(), 0); if (zero_size_it != desired_sizes.end()) { // Just return the biggest image available. SelectionResult result; result.index = BiggestCandidate(candidate_sizes); result.desired_size = 0; results->push_back(result); if (match_score) *match_score = 1.0f; return; } float total_score = 0; for (size_t i = 0; i < desired_sizes.size(); ++i) { float score; SelectionResult result; result.desired_size = desired_sizes[i]; result.index = GetCandidateIndexWithBestScore( candidate_sizes, result.desired_size, &score); results->push_back(result); total_score += score; } if (match_score) *match_score = total_score / desired_sizes.size(); } // Resize |source_bitmap| SkBitmap GetResizedBitmap(const SkBitmap& source_bitmap, gfx::Size original_size, int desired_size_in_pixel) { if (desired_size_in_pixel == 0 || (original_size.width() == desired_size_in_pixel && original_size.height() == desired_size_in_pixel)) { return source_bitmap; } if (desired_size_in_pixel % original_size.width() == 0 && desired_size_in_pixel % original_size.height() == 0) { return SampleNearestNeighbor(source_bitmap, desired_size_in_pixel); } return skia::ImageOperations::Resize(source_bitmap, skia::ImageOperations::RESIZE_LANCZOS3, desired_size_in_pixel, desired_size_in_pixel); } class FaviconImageSource : public gfx::ImageSkiaSource { public: FaviconImageSource() {} virtual ~FaviconImageSource() {} // gfx::ImageSkiaSource: virtual gfx::ImageSkiaRep GetImageForScale(float scale) OVERRIDE { const gfx::ImageSkiaRep* rep = NULL; // gfx::ImageSkia passes one of the resource scale factors. The source // should return: // 1) The ImageSkiaRep with the highest scale if all available // scales are smaller than |scale|. // 2) The ImageSkiaRep with the smallest one that is larger than |scale|. // Note: Keep this logic consistent with the PNGImageSource in // ui/gfx/image.cc. // TODO(oshima): consolidate these logic into one place. for (std::vector::const_iterator iter = image_skia_reps_.begin(); iter != image_skia_reps_.end(); ++iter) { if ((*iter).scale() == scale) return (*iter); if (!rep || rep->scale() < (*iter).scale()) rep = &(*iter); if (rep->scale() >= scale) break; } DCHECK(rep); return rep ? *rep : gfx::ImageSkiaRep(); } void AddImageSkiaRep(const gfx::ImageSkiaRep& rep) { image_skia_reps_.push_back(rep); } private: std::vector image_skia_reps_; DISALLOW_COPY_AND_ASSIGN(FaviconImageSource); }; } // namespace const float kSelectFaviconFramesInvalidScore = -1.0f; gfx::ImageSkia CreateFaviconImageSkia( const std::vector& bitmaps, const std::vector& original_sizes, int desired_size_in_dip, float* score) { const std::vector& favicon_scales = favicon_base::GetFaviconScales(); std::vector desired_sizes; if (desired_size_in_dip == 0) { desired_sizes.push_back(0); } else { for (std::vector::const_iterator iter = favicon_scales.begin(); iter != favicon_scales.end(); ++iter) { desired_sizes.push_back(ceil(desired_size_in_dip * (*iter))); } } std::vector results; GetCandidateIndicesWithBestScores(original_sizes, desired_sizes, score, &results); if (results.size() == 0) return gfx::ImageSkia(); if (desired_size_in_dip == 0) { size_t index = results[0].index; return gfx::ImageSkia(gfx::ImageSkiaRep(bitmaps[index], 1.0f)); } FaviconImageSource* image_source = new FaviconImageSource; for (size_t i = 0; i < results.size(); ++i) { size_t index = results[i].index; image_source->AddImageSkiaRep( gfx::ImageSkiaRep(GetResizedBitmap(bitmaps[index], original_sizes[index], desired_sizes[i]), favicon_scales[i])); } return gfx::ImageSkia(image_source, gfx::Size(desired_size_in_dip, desired_size_in_dip)); } void SelectFaviconFrameIndices(const std::vector& frame_pixel_sizes, const std::vector& desired_sizes, std::vector* best_indices, float* match_score) { std::vector results; GetCandidateIndicesWithBestScores( frame_pixel_sizes, desired_sizes, match_score, &results); std::set already_added; for (size_t i = 0; i < results.size(); ++i) { size_t index = results[i].index; // GetCandidateIndicesWithBestScores() will return duplicate indices if the // bitmap data with |frame_pixel_sizes[index]| should be used for multiple // scale factors. Remove duplicates here such that |best_indices| contains // no duplicates. if (already_added.find(index) == already_added.end()) { already_added.insert(index); best_indices->push_back(index); } } }