// Copyright (c) 2012 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. #ifndef UI_GFX_COLOR_ANALYSIS_H_ #define UI_GFX_COLOR_ANALYSIS_H_ #include #include "base/compiler_specific.h" #include "base/memory/ref_counted.h" #include "base/memory/ref_counted_memory.h" #include "third_party/skia/include/core/SkColor.h" #include "ui/gfx/geometry/matrix3_f.h" #include "ui/gfx/gfx_export.h" class SkBitmap; namespace color_utils { struct HSL; // This class exposes the sampling method to the caller, which allows // stubbing out for things like unit tests. Might be useful to pass more // arguments into the GetSample method in the future (such as which // cluster is being worked on, etc.). // // Note: Samplers should be deterministic, as the same image may be analyzed // twice with two sampler instances and the results displayed side-by-side // to the user. class GFX_EXPORT KMeanImageSampler { public: virtual int GetSample(int width, int height) = 0; protected: KMeanImageSampler(); virtual ~KMeanImageSampler(); }; // This sampler will pick pixels from an evenly spaced grid. class GFX_EXPORT GridSampler : public KMeanImageSampler { public: GridSampler(); ~GridSampler() override; int GetSample(int width, int height) override; private: // The number of times GetSample has been called. int calls_; }; // Returns the color in an ARGB |image| that is closest in RGB-space to the // provided |color|. Exported for testing. GFX_EXPORT SkColor FindClosestColor(const uint8_t* image, int width, int height, SkColor color); // Returns an SkColor that represents the calculated dominant color in the // image. This uses a KMean clustering algorithm to find clusters of pixel // colors in RGB space. // |png|/|bitmap| represents the data of a png/bitmap encoded image. // |lower_bound| represents the minimum bound of HSL values to allow. // |upper_bound| represents the maximum bound of HSL values to allow. // See color_utils::IsWithinHSLRange() for description of these bounds. // // RGB KMean Algorithm (N clusters, M iterations): // 1.Pick N starting colors by randomly sampling the pixels. If you see a // color you already saw keep sampling. After a certain number of tries // just remove the cluster and continue with N = N-1 clusters (for an image // with just one color this should devolve to N=1). These colors are the // centers of your N clusters. // 2.For each pixel in the image find the cluster that it is closest to in RGB // space. Add that pixel's color to that cluster (we keep a sum and a count // of all of the pixels added to the space, so just add it to the sum and // increment count). // 3.Calculate the new cluster centroids by getting the average color of all of // the pixels in each cluster (dividing the sum by the count). // 4.See if the new centroids are the same as the old centroids. // a) If this is the case for all N clusters than we have converged and // can move on. // b) If any centroid moved, repeat step 2 with the new centroids for up // to M iterations. // 5.Once the clusters have converged or M iterations have been tried, sort // the clusters by weight (where weight is the number of pixels that make up // this cluster). // 6.Going through the sorted list of clusters, pick the first cluster with the // largest weight that's centroid falls between |lower_bound| and // |upper_bound|. Return that color. // If no color fulfills that requirement return the color with the largest // weight regardless of whether or not it fulfills the equation above. GFX_EXPORT SkColor CalculateKMeanColorOfPNG(scoped_refptr png, const HSL& lower_bound, const HSL& upper_bound, KMeanImageSampler* sampler); // Computes a dominant color using the above algorithm and reasonable defaults // for |lower_bound|, |upper_bound| and |sampler|. GFX_EXPORT SkColor CalculateKMeanColorOfPNG( scoped_refptr png); // Returns an SkColor that represents the calculated dominant color in the // image. See CalculateKMeanColorOfPNG() for details. GFX_EXPORT SkColor CalculateKMeanColorOfBitmap(const SkBitmap& bitmap, const HSL& lower_bound, const HSL& upper_bound, KMeanImageSampler* sampler); // Computes a dominant color using the above algorithm and reasonable defaults // for |lower_bound|, |upper_bound| and |sampler|. GFX_EXPORT SkColor CalculateKMeanColorOfBitmap(const SkBitmap& bitmap); // Compute color covariance matrix for the input bitmap. GFX_EXPORT gfx::Matrix3F ComputeColorCovariance(const SkBitmap& bitmap); // Apply a color reduction transform defined by |color_transform| vector to // |source_bitmap|. The result is put into |target_bitmap|, which is expected // to be initialized to the required size and type (SkBitmap::kA8_Config). // If |fit_to_range|, result is transfored linearly to fit 0-0xFF range. // Otherwise, data is clipped. // Returns true if the target has been computed. GFX_EXPORT bool ApplyColorReduction(const SkBitmap& source_bitmap, const gfx::Vector3dF& color_transform, bool fit_to_range, SkBitmap* target_bitmap); // Compute a monochrome image representing the principal color component of // the |source_bitmap|. The result is stored in |target_bitmap|, which must be // initialized to the required size and type (SkBitmap::kA8_Config). // Returns true if the conversion succeeded. Note that there might be legitimate // reasons for the process to fail even if all input was correct. This is a // condition the caller must be able to handle. GFX_EXPORT bool ComputePrincipalComponentImage(const SkBitmap& source_bitmap, SkBitmap* target_bitmap); } // namespace color_utils #endif // UI_GFX_COLOR_ANALYSIS_H_