ui/gfx/image/image_skia_unittest.cc - chromium/src - Git at Google

 // 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.

 #include "ui/gfx/image/image_skia.h"

 #include <stddef.h>

 #include "base/command_line.h"
 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/memory/ptr_util.h"
 #include "base/threading/simple_thread.h"
 #include "testing/gtest/include/gtest/gtest.h"
 #include "third_party/skia/include/core/SkBitmap.h"
 #include "ui/gfx/geometry/size.h"
 #include "ui/gfx/image/image_skia_rep.h"
 #include "ui/gfx/image/image_skia_source.h"
 #include "ui/gfx/switches.h"

 namespace gfx {

 namespace {

 class FixedSource : public ImageSkiaSource {
  public:
   explicit FixedSource(const ImageSkiaRep& image) : image_(image) {}

   ~FixedSource() override {}

   ImageSkiaRep GetImageForScale(float scale) override { return image_; }

  private:
   ImageSkiaRep image_;

   DISALLOW_COPY_AND_ASSIGN(FixedSource);
 };

 class FixedScaleSource : public ImageSkiaSource {
  public:
   explicit FixedScaleSource(const ImageSkiaRep& image) : image_(image) {}

   ~FixedScaleSource() override {}

   ImageSkiaRep GetImageForScale(float scale) override {
     if (!image_.unscaled() && image_.scale() != scale)
       return ImageSkiaRep();
     return image_;
   }

  private:
   ImageSkiaRep image_;

   DISALLOW_COPY_AND_ASSIGN(FixedScaleSource);
 };

 class DynamicSource : public ImageSkiaSource {
  public:
   explicit DynamicSource(const gfx::Size& size)
       : size_(size),
         last_requested_scale_(0.0f) {}

   ~DynamicSource() override {}

   ImageSkiaRep GetImageForScale(float scale) override {
     last_requested_scale_ = scale;
     return gfx::ImageSkiaRep(size_, scale);
   }

   float GetLastRequestedScaleAndReset() {
     float result = last_requested_scale_;
     last_requested_scale_ = 0.0f;
     return result;
   }

  private:
   gfx::Size size_;
   float last_requested_scale_;

   DISALLOW_COPY_AND_ASSIGN(DynamicSource);
 };

 class NullSource: public ImageSkiaSource {
  public:
   NullSource() {
   }

   ~NullSource() override {}

   ImageSkiaRep GetImageForScale(float scale) override {
     return gfx::ImageSkiaRep();
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(NullSource);
 };

 }  // namespace

 namespace test {
 class TestOnThread : public base::SimpleThread {
  public:
   explicit TestOnThread(ImageSkia* image_skia)
       : SimpleThread("image_skia_on_thread"),
         image_skia_(image_skia),
         can_read_(false),
         can_modify_(false) {
   }

   void Run() override {
     can_read_ = image_skia_->CanRead();
     can_modify_ = image_skia_->CanModify();
     if (can_read_)
       image_skia_->image_reps();
   }

   void StartAndJoin() {
     Start();
     Join();
   }

   bool can_read() const { return can_read_; }

   bool can_modify() const { return can_modify_; }

  private:
   ImageSkia* image_skia_;

   bool can_read_;
   bool can_modify_;

   DISALLOW_COPY_AND_ASSIGN(TestOnThread);
 };

 }  // namespace test

 class ImageSkiaTest : public testing::Test {
  public:
   ImageSkiaTest() {
     // In the test, we assume that we support 1.0f and 2.0f DSFs.
     old_scales_ = ImageSkia::GetSupportedScales();

     // Sets the list of scale factors supported by resource bundle.
     std::vector<float> supported_scales;
     supported_scales.push_back(1.0f);
     supported_scales.push_back(2.0f);
     ImageSkia::SetSupportedScales(supported_scales);
   }
   ~ImageSkiaTest() override { ImageSkia::SetSupportedScales(old_scales_); }

  private:
   std::vector<float> old_scales_;
   DISALLOW_COPY_AND_ASSIGN(ImageSkiaTest);
 };

 TEST_F(ImageSkiaTest, FixedSource) {
   ImageSkiaRep image(Size(100, 200), 0.0f);
   ImageSkia image_skia(std::make_unique<FixedSource>(image), Size(100, 200));
   EXPECT_EQ(0U, image_skia.image_reps().size());

   const ImageSkiaRep& result_100p = image_skia.GetRepresentation(1.0f);
   EXPECT_EQ(100, result_100p.GetWidth());
   EXPECT_EQ(200, result_100p.GetHeight());
   EXPECT_EQ(1.0f, result_100p.scale());
   EXPECT_EQ(1U, image_skia.image_reps().size());

   const ImageSkiaRep& result_200p = image_skia.GetRepresentation(2.0f);

   EXPECT_EQ(100, result_200p.GetWidth());
   EXPECT_EQ(200, result_200p.GetHeight());
   EXPECT_EQ(100, result_200p.pixel_width());
   EXPECT_EQ(200, result_200p.pixel_height());
   EXPECT_EQ(1.0f, result_200p.scale());
   EXPECT_EQ(1U, image_skia.image_reps().size());

   const ImageSkiaRep& result_300p = image_skia.GetRepresentation(3.0f);

   EXPECT_EQ(100, result_300p.GetWidth());
   EXPECT_EQ(200, result_300p.GetHeight());
   EXPECT_EQ(100, result_300p.pixel_width());
   EXPECT_EQ(200, result_300p.pixel_height());
   EXPECT_EQ(1.0f, result_300p.scale());
   EXPECT_EQ(1U, image_skia.image_reps().size());

   // Get the representation again and make sure it doesn't
   // generate new image skia rep.
   image_skia.GetRepresentation(1.0f);
   image_skia.GetRepresentation(2.0f);
   image_skia.GetRepresentation(3.0f);
   EXPECT_EQ(1U, image_skia.image_reps().size());
 }

 TEST_F(ImageSkiaTest, FixedScaledSource) {
   ImageSkiaRep image(Size(100, 200), 1.0f);
   ImageSkia image_skia(std::make_unique<FixedScaleSource>(image),
                        Size(100, 200));
   EXPECT_EQ(0U, image_skia.image_reps().size());

   const ImageSkiaRep& result_100p = image_skia.GetRepresentation(1.0f);
   EXPECT_EQ(100, result_100p.GetWidth());
   EXPECT_EQ(200, result_100p.GetHeight());
   EXPECT_EQ(1.0f, result_100p.scale());
   EXPECT_EQ(1U, image_skia.image_reps().size());

   // 2.0f data doesn't exist, then it falls back to 1.0f and rescale it.
   const ImageSkiaRep& result_200p = image_skia.GetRepresentation(2.0f);

   EXPECT_EQ(100, result_200p.GetWidth());
   EXPECT_EQ(200, result_200p.GetHeight());
   EXPECT_EQ(200, result_200p.pixel_width());
   EXPECT_EQ(400, result_200p.pixel_height());
   EXPECT_EQ(2.0f, result_200p.scale());
   EXPECT_EQ(2U, image_skia.image_reps().size());

   // Get the representation again and make sure it doesn't
   // generate new image skia rep.
   image_skia.GetRepresentation(1.0f);
   image_skia.GetRepresentation(2.0f);
   EXPECT_EQ(2U, image_skia.image_reps().size());
 }

 TEST_F(ImageSkiaTest, FixedUnscaledSource) {
   ImageSkiaRep image(Size(100, 200), 0.0f);
   ImageSkia image_skia(std::make_unique<FixedScaleSource>(image),
                        Size(100, 200));
   EXPECT_EQ(0U, image_skia.image_reps().size());

   const ImageSkiaRep& result_100p = image_skia.GetRepresentation(1.0f);
   EXPECT_EQ(100, result_100p.pixel_width());
   EXPECT_EQ(200, result_100p.pixel_height());
   EXPECT_TRUE(result_100p.unscaled());
   EXPECT_EQ(1U, image_skia.image_reps().size());

   // 2.0f data doesn't exist, but unscaled ImageSkiaRep shouldn't be rescaled.
   const ImageSkiaRep& result_200p = image_skia.GetRepresentation(2.0f);

   EXPECT_EQ(100, result_200p.pixel_width());
   EXPECT_EQ(200, result_200p.pixel_height());
   EXPECT_TRUE(result_200p.unscaled());
   EXPECT_EQ(1U, image_skia.image_reps().size());

   // Get the representation again and make sure it doesn't
   // generate new image skia rep.
   image_skia.GetRepresentation(1.0f);
   image_skia.GetRepresentation(2.0f);
   EXPECT_EQ(1U, image_skia.image_reps().size());
 }

 TEST_F(ImageSkiaTest, DynamicSource) {
   ImageSkia image_skia(std::make_unique<DynamicSource>(Size(100, 200)),
                        Size(100, 200));
   EXPECT_EQ(0U, image_skia.image_reps().size());
   const ImageSkiaRep& result_100p = image_skia.GetRepresentation(1.0f);
   EXPECT_EQ(100, result_100p.GetWidth());
   EXPECT_EQ(200, result_100p.GetHeight());
   EXPECT_EQ(1.0f, result_100p.scale());
   EXPECT_EQ(1U, image_skia.image_reps().size());

   const ImageSkiaRep& result_200p =
       image_skia.GetRepresentation(2.0f);
   EXPECT_EQ(100, result_200p.GetWidth());
   EXPECT_EQ(200, result_200p.GetHeight());
   EXPECT_EQ(200, result_200p.pixel_width());
   EXPECT_EQ(400, result_200p.pixel_height());
   EXPECT_EQ(2.0f, result_200p.scale());
   EXPECT_EQ(2U, image_skia.image_reps().size());

   // Get the representation again and make sure it doesn't
   // generate new image skia rep.
   image_skia.GetRepresentation(1.0f);
   EXPECT_EQ(2U, image_skia.image_reps().size());
   image_skia.GetRepresentation(2.0f);
   EXPECT_EQ(2U, image_skia.image_reps().size());
 }

 // Tests that image_reps returns all of the representations in the
 // image when there are multiple representations for a scale factor.
 // This currently is the case with ImageLoader::LoadImages.
 TEST_F(ImageSkiaTest, ManyRepsPerScaleFactor) {
   const int kSmallIcon1x = 16;
   const int kSmallIcon2x = 32;
   const int kLargeIcon1x = 32;

   ImageSkia image(std::make_unique<NullSource>(),
                   gfx::Size(kSmallIcon1x, kSmallIcon1x));
   // Simulate a source which loads images on a delay. Upon
   // GetImageForScaleFactor, it immediately returns null and starts loading
   // image reps slowly.
   image.GetRepresentation(1.0f);
   image.GetRepresentation(2.0f);

   // After a lengthy amount of simulated time, finally loaded image reps.
   image.AddRepresentation(ImageSkiaRep(
       gfx::Size(kSmallIcon1x, kSmallIcon1x), 1.0f));
   image.AddRepresentation(ImageSkiaRep(
       gfx::Size(kSmallIcon2x, kSmallIcon2x), 2.0f));
   image.AddRepresentation(ImageSkiaRep(
       gfx::Size(kLargeIcon1x, kLargeIcon1x), 1.0f));

   std::vector<ImageSkiaRep> image_reps = image.image_reps();
   EXPECT_EQ(3u, image_reps.size());

   int num_1x = 0;
   int num_2x = 0;
   for (size_t i = 0; i < image_reps.size(); ++i) {
     if (image_reps[i].scale() == 1.0f)
       num_1x++;
     else if (image_reps[i].scale() == 2.0f)
       num_2x++;
   }
   EXPECT_EQ(2, num_1x);
   EXPECT_EQ(1, num_2x);
 }

 TEST_F(ImageSkiaTest, GetBitmap) {
   ImageSkia image_skia(std::make_unique<DynamicSource>(Size(100, 200)),
                        Size(100, 200));
   const SkBitmap* bitmap = image_skia.bitmap();
   EXPECT_NE(static_cast<SkBitmap*>(NULL), bitmap);
   EXPECT_FALSE(bitmap->isNull());
 }

 TEST_F(ImageSkiaTest, GetBitmapFromEmpty) {
   // Create an image with 1 representation and remove it so the ImageSkiaStorage
   // is left with no representations.
   ImageSkia empty_image(ImageSkiaRep(Size(100, 200), 1.0f));
   ImageSkia empty_image_copy(empty_image);
   empty_image.RemoveRepresentation(1.0f);

   // Check that ImageSkia::bitmap() still returns a valid SkBitmap pointer for
   // the image and all its copies.
   const SkBitmap* bitmap = empty_image_copy.bitmap();
   ASSERT_NE(static_cast<SkBitmap*>(NULL), bitmap);
   EXPECT_TRUE(bitmap->isNull());
   EXPECT_TRUE(bitmap->empty());
 }

 TEST_F(ImageSkiaTest, BackedBySameObjectAs) {
   // Null images should all be backed by the same object (NULL).
   ImageSkia image;
   ImageSkia unrelated;
   EXPECT_TRUE(image.BackedBySameObjectAs(unrelated));

   image.AddRepresentation(gfx::ImageSkiaRep(gfx::Size(10, 10),
                                             1.0f));
   ImageSkia copy = image;
   copy.AddRepresentation(gfx::ImageSkiaRep(gfx::Size(10, 10),
                                            2.0f));
   unrelated.AddRepresentation(gfx::ImageSkiaRep(gfx::Size(10, 10),
                                                 1.0f));
   EXPECT_TRUE(image.BackedBySameObjectAs(copy));
   EXPECT_FALSE(image.BackedBySameObjectAs(unrelated));
   EXPECT_FALSE(copy.BackedBySameObjectAs(unrelated));
 }

 #if DCHECK_IS_ON()
 TEST_F(ImageSkiaTest, EmptyOnThreadTest) {
   ImageSkia empty;
   test::TestOnThread empty_on_thread(&empty);
   empty_on_thread.Start();
   empty_on_thread.Join();
   EXPECT_TRUE(empty_on_thread.can_read());
   EXPECT_TRUE(empty_on_thread.can_modify());
 }

 TEST_F(ImageSkiaTest, StaticOnThreadTest) {
   ImageSkia image(ImageSkiaRep(Size(100, 200), 1.0f));
   EXPECT_FALSE(image.IsThreadSafe());

   test::TestOnThread image_on_thread(&image);
   // an image that was never accessed on this thread can be
   // read by other thread.
   image_on_thread.StartAndJoin();
   EXPECT_TRUE(image_on_thread.can_read());
   EXPECT_TRUE(image_on_thread.can_modify());
   EXPECT_FALSE(image.CanRead());
   EXPECT_FALSE(image.CanModify());

   image.DetachStorageFromSequence();
   // An image is accessed by this thread,
   // so other thread cannot read/modify it.
   image.image_reps();
   test::TestOnThread image_on_thread2(&image);
   image_on_thread2.StartAndJoin();
   EXPECT_FALSE(image_on_thread2.can_read());
   EXPECT_FALSE(image_on_thread2.can_modify());
   EXPECT_TRUE(image.CanRead());
   EXPECT_TRUE(image.CanModify());

   image.DetachStorageFromSequence();
   ImageSkia deep_copy(image.DeepCopy());
   EXPECT_FALSE(deep_copy.IsThreadSafe());
   test::TestOnThread deepcopy_on_thread(&deep_copy);
   deepcopy_on_thread.StartAndJoin();
   EXPECT_TRUE(deepcopy_on_thread.can_read());
   EXPECT_TRUE(deepcopy_on_thread.can_modify());
   EXPECT_FALSE(deep_copy.CanRead());
   EXPECT_FALSE(deep_copy.CanModify());

   ImageSkia deep_copy2(image.DeepCopy());
   EXPECT_EQ(1U, deep_copy2.image_reps().size());
   // Access it from current thread so that it can't be
   // accessed from another thread.
   deep_copy2.image_reps();
   EXPECT_FALSE(deep_copy2.IsThreadSafe());
   test::TestOnThread deepcopy2_on_thread(&deep_copy2);
   deepcopy2_on_thread.StartAndJoin();
   EXPECT_FALSE(deepcopy2_on_thread.can_read());
   EXPECT_FALSE(deepcopy2_on_thread.can_modify());
   EXPECT_TRUE(deep_copy2.CanRead());
   EXPECT_TRUE(deep_copy2.CanModify());

   image.DetachStorageFromSequence();
   image.SetReadOnly();
   // A read-only ImageSkia with no source is thread safe.
   EXPECT_TRUE(image.IsThreadSafe());
   test::TestOnThread readonly_on_thread(&image);
   readonly_on_thread.StartAndJoin();
   EXPECT_TRUE(readonly_on_thread.can_read());
   EXPECT_FALSE(readonly_on_thread.can_modify());
   EXPECT_TRUE(image.CanRead());
   EXPECT_FALSE(image.CanModify());

   image.DetachStorageFromSequence();
   image.MakeThreadSafe();
   EXPECT_TRUE(image.IsThreadSafe());
   test::TestOnThread threadsafe_on_thread(&image);
   threadsafe_on_thread.StartAndJoin();
   EXPECT_TRUE(threadsafe_on_thread.can_read());
   EXPECT_FALSE(threadsafe_on_thread.can_modify());
   EXPECT_TRUE(image.CanRead());
   EXPECT_FALSE(image.CanModify());
 }

 TEST_F(ImageSkiaTest, SourceOnThreadTest) {
   ImageSkia image(std::make_unique<DynamicSource>(Size(100, 200)),
                   Size(100, 200));
   EXPECT_FALSE(image.IsThreadSafe());

   test::TestOnThread image_on_thread(&image);
   image_on_thread.StartAndJoin();
   // an image that was never accessed on this thread can be
   // read by other thread.
   EXPECT_TRUE(image_on_thread.can_read());
   EXPECT_TRUE(image_on_thread.can_modify());
   EXPECT_FALSE(image.CanRead());
   EXPECT_FALSE(image.CanModify());

   image.DetachStorageFromSequence();
   // An image is accessed by this thread,
   // so other thread cannot read/modify it.
   image.image_reps();
   test::TestOnThread image_on_thread2(&image);
   image_on_thread2.StartAndJoin();
   EXPECT_FALSE(image_on_thread2.can_read());
   EXPECT_FALSE(image_on_thread2.can_modify());
   EXPECT_TRUE(image.CanRead());
   EXPECT_TRUE(image.CanModify());

   image.DetachStorageFromSequence();
   image.SetReadOnly();
   EXPECT_FALSE(image.IsThreadSafe());
   test::TestOnThread readonly_on_thread(&image);
   readonly_on_thread.StartAndJoin();
   EXPECT_TRUE(readonly_on_thread.can_read());
   EXPECT_FALSE(readonly_on_thread.can_modify());
   EXPECT_FALSE(image.CanRead());
   EXPECT_FALSE(image.CanModify());

   image.DetachStorageFromSequence();
   image.MakeThreadSafe();
   EXPECT_TRUE(image.IsThreadSafe());
   // Check if image reps are generated for supported scale factors.
   EXPECT_EQ(ImageSkia::GetSupportedScales().size(),
            image.image_reps().size());
   test::TestOnThread threadsafe_on_thread(&image);
   threadsafe_on_thread.StartAndJoin();
   EXPECT_TRUE(threadsafe_on_thread.can_read());
   EXPECT_FALSE(threadsafe_on_thread.can_modify());
   EXPECT_TRUE(image.CanRead());
   EXPECT_FALSE(image.CanModify());
 }
 #endif  // DCHECK_IS_ON()

 TEST_F(ImageSkiaTest, Unscaled) {
   SkBitmap bitmap;

   // An ImageSkia created with 1x bitmap is unscaled.
   ImageSkia image_skia = ImageSkia::CreateFrom1xBitmap(bitmap);
   EXPECT_TRUE(image_skia.GetRepresentation(1.0f).unscaled());
   ImageSkiaRep rep_2x(Size(100, 100), 2.0f);

   // When reps for other scales are added, the unscaled image
   // becomes scaled.
   image_skia.AddRepresentation(rep_2x);
   EXPECT_FALSE(image_skia.GetRepresentation(1.0f).unscaled());
   EXPECT_FALSE(image_skia.GetRepresentation(2.0f).unscaled());
 }

 namespace {

 std::vector<float> GetSortedScaleFactors(const gfx::ImageSkia& image) {
   const std::vector<ImageSkiaRep>& image_reps = image.image_reps();
   std::vector<float> scale_factors;
   for (size_t i = 0; i < image_reps.size(); ++i) {
     scale_factors.push_back(image_reps[i].scale());
   }
   std::sort(scale_factors.begin(), scale_factors.end());
   return scale_factors;
 }

 }  // namespace

 TEST_F(ImageSkiaTest, ArbitraryScaleFactor) {
   // source is owned by |image|
   DynamicSource* source = new DynamicSource(Size(100, 200));
   ImageSkia image(base::WrapUnique(source), gfx::Size(100, 200));

   image.GetRepresentation(1.5f);
   EXPECT_EQ(2.0f, source->GetLastRequestedScaleAndReset());
   std::vector<ImageSkiaRep> image_reps = image.image_reps();
   EXPECT_EQ(2u, image_reps.size());

   std::vector<float> scale_factors = GetSortedScaleFactors(image);
   EXPECT_EQ(1.5f, scale_factors[0]);
   EXPECT_EQ(2.0f, scale_factors[1]);

   // Requesting 1.75 scale factor also falls back to 2.0f and rescale.
   // However, the image already has the 2.0f data, so it won't fetch again.
   image.GetRepresentation(1.75f);
   EXPECT_EQ(0.0f, source->GetLastRequestedScaleAndReset());
   image_reps = image.image_reps();
   EXPECT_EQ(3u, image_reps.size());

   scale_factors = GetSortedScaleFactors(image);
   EXPECT_EQ(1.5f, scale_factors[0]);
   EXPECT_EQ(1.75f, scale_factors[1]);
   EXPECT_EQ(2.0f, scale_factors[2]);

   // Requesting 1.25 scale factor also falls back to 2.0f and rescale.
   // However, the image already has the 2.0f data, so it won't fetch again.
   image.GetRepresentation(1.25f);
   EXPECT_EQ(0.0f, source->GetLastRequestedScaleAndReset());
   image_reps = image.image_reps();
   EXPECT_EQ(4u, image_reps.size());
   scale_factors = GetSortedScaleFactors(image);
   EXPECT_EQ(1.25f, scale_factors[0]);
   EXPECT_EQ(1.5f, scale_factors[1]);
   EXPECT_EQ(1.75f, scale_factors[2]);
   EXPECT_EQ(2.0f, scale_factors[3]);

   // 1.20 is falled back to 1.0.
   image.GetRepresentation(1.20f);
   EXPECT_EQ(1.0f, source->GetLastRequestedScaleAndReset());
   image_reps = image.image_reps();
   EXPECT_EQ(6u, image_reps.size());
   scale_factors = GetSortedScaleFactors(image);
   EXPECT_EQ(1.0f, scale_factors[0]);
   EXPECT_EQ(1.2f, scale_factors[1]);
   EXPECT_EQ(1.25f, scale_factors[2]);
   EXPECT_EQ(1.5f, scale_factors[3]);
   EXPECT_EQ(1.75f, scale_factors[4]);
   EXPECT_EQ(2.0f, scale_factors[5]);

   // Scale factor less than 1.0f will be falled back to 1.0f
   image.GetRepresentation(0.75f);
   EXPECT_EQ(0.0f, source->GetLastRequestedScaleAndReset());
   image_reps = image.image_reps();
   EXPECT_EQ(7u, image_reps.size());

   scale_factors = GetSortedScaleFactors(image);
   EXPECT_EQ(0.75f, scale_factors[0]);
   EXPECT_EQ(1.0f, scale_factors[1]);
   EXPECT_EQ(1.2f, scale_factors[2]);
   EXPECT_EQ(1.25f, scale_factors[3]);
   EXPECT_EQ(1.5f, scale_factors[4]);
   EXPECT_EQ(1.75f, scale_factors[5]);
   EXPECT_EQ(2.0f, scale_factors[6]);

   // Scale factor greater than 2.0f is falled back to 2.0f because it's not
   // supported.
   image.GetRepresentation(3.0f);
   EXPECT_EQ(0.0f, source->GetLastRequestedScaleAndReset());
   image_reps = image.image_reps();
   EXPECT_EQ(8u, image_reps.size());
 }

 TEST_F(ImageSkiaTest, ArbitraryScaleFactorWithMissingResource) {
   ImageSkia image(
       std::make_unique<FixedScaleSource>(ImageSkiaRep(Size(100, 200), 1.0f)),
       Size(100, 200));

   // Requesting 1.5f -- falls back to 2.0f, but couldn't find. It should
   // look up 1.0f and then rescale it. Note that the rescaled ImageSkiaRep will
   // have 2.0f scale.
   const ImageSkiaRep& rep = image.GetRepresentation(1.5f);
   EXPECT_EQ(1.5f, rep.scale());
   EXPECT_EQ(2U, image.image_reps().size());
   EXPECT_EQ(2.0f, image.image_reps()[0].scale());
   EXPECT_EQ(1.5f, image.image_reps()[1].scale());
 }

 TEST_F(ImageSkiaTest, UnscaledImageForArbitraryScaleFactor) {
   // 0.0f means unscaled.
   ImageSkia image(
       std::make_unique<FixedScaleSource>(ImageSkiaRep(Size(100, 200), 0.0f)),
       Size(100, 200));

   // Requesting 2.0f, which should return 1.0f unscaled image.
   const ImageSkiaRep& rep = image.GetRepresentation(2.0f);
   EXPECT_EQ(1.0f, rep.scale());
   EXPECT_EQ("100x200", rep.pixel_size().ToString());
   EXPECT_TRUE(rep.unscaled());
   EXPECT_EQ(1U, image.image_reps().size());

   // Same for any other scale factors.
   const ImageSkiaRep& rep15 = image.GetRepresentation(1.5f);
   EXPECT_EQ(1.0f, rep15.scale());
   EXPECT_EQ("100x200", rep15.pixel_size().ToString());
   EXPECT_TRUE(rep15.unscaled());
   EXPECT_EQ(1U, image.image_reps().size());

   const ImageSkiaRep& rep12 = image.GetRepresentation(1.2f);
   EXPECT_EQ(1.0f, rep12.scale());
   EXPECT_EQ("100x200", rep12.pixel_size().ToString());
   EXPECT_TRUE(rep12.unscaled());
   EXPECT_EQ(1U, image.image_reps().size());
 }

 }  // namespace gfx
	// 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.

	#include "ui/gfx/image/image_skia.h"

	#include <stddef.h>

	#include "base/command_line.h"
	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/memory/ptr_util.h"
	#include "base/threading/simple_thread.h"
	#include "testing/gtest/include/gtest/gtest.h"
	#include "third_party/skia/include/core/SkBitmap.h"
	#include "ui/gfx/geometry/size.h"
	#include "ui/gfx/image/image_skia_rep.h"
	#include "ui/gfx/image/image_skia_source.h"
	#include "ui/gfx/switches.h"

	namespace gfx {

	namespace {

	class FixedSource : public ImageSkiaSource {
	public:
	explicit FixedSource(const ImageSkiaRep& image) : image_(image) {}

	~FixedSource() override {}

	ImageSkiaRep GetImageForScale(float scale) override { return image_; }

	private:
	ImageSkiaRep image_;

	DISALLOW_COPY_AND_ASSIGN(FixedSource);
	};

	class FixedScaleSource : public ImageSkiaSource {
	public:
	explicit FixedScaleSource(const ImageSkiaRep& image) : image_(image) {}

	~FixedScaleSource() override {}

	ImageSkiaRep GetImageForScale(float scale) override {
	if (!image_.unscaled() && image_.scale() != scale)
	return ImageSkiaRep();
	return image_;
	}

	private:
	ImageSkiaRep image_;

	DISALLOW_COPY_AND_ASSIGN(FixedScaleSource);
	};

	class DynamicSource : public ImageSkiaSource {
	public:
	explicit DynamicSource(const gfx::Size& size)
	: size_(size),
	last_requested_scale_(0.0f) {}

	~DynamicSource() override {}

	ImageSkiaRep GetImageForScale(float scale) override {
	last_requested_scale_ = scale;
	return gfx::ImageSkiaRep(size_, scale);
	}

	float GetLastRequestedScaleAndReset() {
	float result = last_requested_scale_;
	last_requested_scale_ = 0.0f;
	return result;
	}

	private:
	gfx::Size size_;
	float last_requested_scale_;

	DISALLOW_COPY_AND_ASSIGN(DynamicSource);
	};

	class NullSource: public ImageSkiaSource {
	public:
	NullSource() {
	}

	~NullSource() override {}

	ImageSkiaRep GetImageForScale(float scale) override {
	return gfx::ImageSkiaRep();
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(NullSource);
	};

	} // namespace

	namespace test {
	class TestOnThread : public base::SimpleThread {
	public:
	explicit TestOnThread(ImageSkia* image_skia)
	: SimpleThread("image_skia_on_thread"),
	image_skia_(image_skia),
	can_read_(false),
	can_modify_(false) {
	}

	void Run() override {
	can_read_ = image_skia_->CanRead();
	can_modify_ = image_skia_->CanModify();
	if (can_read_)
	image_skia_->image_reps();
	}

	void StartAndJoin() {
	Start();
	Join();
	}

	bool can_read() const { return can_read_; }

	bool can_modify() const { return can_modify_; }

	private:
	ImageSkia* image_skia_;

	bool can_read_;
	bool can_modify_;

	DISALLOW_COPY_AND_ASSIGN(TestOnThread);
	};

	} // namespace test

	class ImageSkiaTest : public testing::Test {
	public:
	ImageSkiaTest() {
	// In the test, we assume that we support 1.0f and 2.0f DSFs.
	old_scales_ = ImageSkia::GetSupportedScales();

	// Sets the list of scale factors supported by resource bundle.
	std::vector<float> supported_scales;
	supported_scales.push_back(1.0f);
	supported_scales.push_back(2.0f);
	ImageSkia::SetSupportedScales(supported_scales);
	}
	~ImageSkiaTest() override { ImageSkia::SetSupportedScales(old_scales_); }

	private:
	std::vector<float> old_scales_;
	DISALLOW_COPY_AND_ASSIGN(ImageSkiaTest);
	};

	TEST_F(ImageSkiaTest, FixedSource) {
	ImageSkiaRep image(Size(100, 200), 0.0f);
	ImageSkia image_skia(std::make_unique<FixedSource>(image), Size(100, 200));
	EXPECT_EQ(0U, image_skia.image_reps().size());

	const ImageSkiaRep& result_100p = image_skia.GetRepresentation(1.0f);
	EXPECT_EQ(100, result_100p.GetWidth());
	EXPECT_EQ(200, result_100p.GetHeight());
	EXPECT_EQ(1.0f, result_100p.scale());
	EXPECT_EQ(1U, image_skia.image_reps().size());

	const ImageSkiaRep& result_200p = image_skia.GetRepresentation(2.0f);

	EXPECT_EQ(100, result_200p.GetWidth());
	EXPECT_EQ(200, result_200p.GetHeight());
	EXPECT_EQ(100, result_200p.pixel_width());
	EXPECT_EQ(200, result_200p.pixel_height());
	EXPECT_EQ(1.0f, result_200p.scale());
	EXPECT_EQ(1U, image_skia.image_reps().size());

	const ImageSkiaRep& result_300p = image_skia.GetRepresentation(3.0f);

	EXPECT_EQ(100, result_300p.GetWidth());
	EXPECT_EQ(200, result_300p.GetHeight());
	EXPECT_EQ(100, result_300p.pixel_width());
	EXPECT_EQ(200, result_300p.pixel_height());
	EXPECT_EQ(1.0f, result_300p.scale());
	EXPECT_EQ(1U, image_skia.image_reps().size());

	// Get the representation again and make sure it doesn't
	// generate new image skia rep.
	image_skia.GetRepresentation(1.0f);
	image_skia.GetRepresentation(2.0f);
	image_skia.GetRepresentation(3.0f);
	EXPECT_EQ(1U, image_skia.image_reps().size());
	}

	TEST_F(ImageSkiaTest, FixedScaledSource) {
	ImageSkiaRep image(Size(100, 200), 1.0f);
	ImageSkia image_skia(std::make_unique<FixedScaleSource>(image),
	Size(100, 200));
	EXPECT_EQ(0U, image_skia.image_reps().size());

	const ImageSkiaRep& result_100p = image_skia.GetRepresentation(1.0f);
	EXPECT_EQ(100, result_100p.GetWidth());
	EXPECT_EQ(200, result_100p.GetHeight());
	EXPECT_EQ(1.0f, result_100p.scale());
	EXPECT_EQ(1U, image_skia.image_reps().size());

	// 2.0f data doesn't exist, then it falls back to 1.0f and rescale it.
	const ImageSkiaRep& result_200p = image_skia.GetRepresentation(2.0f);

	EXPECT_EQ(100, result_200p.GetWidth());
	EXPECT_EQ(200, result_200p.GetHeight());
	EXPECT_EQ(200, result_200p.pixel_width());
	EXPECT_EQ(400, result_200p.pixel_height());
	EXPECT_EQ(2.0f, result_200p.scale());
	EXPECT_EQ(2U, image_skia.image_reps().size());

	// Get the representation again and make sure it doesn't
	// generate new image skia rep.
	image_skia.GetRepresentation(1.0f);
	image_skia.GetRepresentation(2.0f);
	EXPECT_EQ(2U, image_skia.image_reps().size());
	}

	TEST_F(ImageSkiaTest, FixedUnscaledSource) {
	ImageSkiaRep image(Size(100, 200), 0.0f);
	ImageSkia image_skia(std::make_unique<FixedScaleSource>(image),
	Size(100, 200));
	EXPECT_EQ(0U, image_skia.image_reps().size());

	const ImageSkiaRep& result_100p = image_skia.GetRepresentation(1.0f);
	EXPECT_EQ(100, result_100p.pixel_width());
	EXPECT_EQ(200, result_100p.pixel_height());
	EXPECT_TRUE(result_100p.unscaled());
	EXPECT_EQ(1U, image_skia.image_reps().size());

	// 2.0f data doesn't exist, but unscaled ImageSkiaRep shouldn't be rescaled.
	const ImageSkiaRep& result_200p = image_skia.GetRepresentation(2.0f);

	EXPECT_EQ(100, result_200p.pixel_width());
	EXPECT_EQ(200, result_200p.pixel_height());
	EXPECT_TRUE(result_200p.unscaled());
	EXPECT_EQ(1U, image_skia.image_reps().size());

	// Get the representation again and make sure it doesn't
	// generate new image skia rep.
	image_skia.GetRepresentation(1.0f);
	image_skia.GetRepresentation(2.0f);
	EXPECT_EQ(1U, image_skia.image_reps().size());
	}

	TEST_F(ImageSkiaTest, DynamicSource) {
	ImageSkia image_skia(std::make_unique<DynamicSource>(Size(100, 200)),
	Size(100, 200));
	EXPECT_EQ(0U, image_skia.image_reps().size());
	const ImageSkiaRep& result_100p = image_skia.GetRepresentation(1.0f);
	EXPECT_EQ(100, result_100p.GetWidth());
	EXPECT_EQ(200, result_100p.GetHeight());
	EXPECT_EQ(1.0f, result_100p.scale());
	EXPECT_EQ(1U, image_skia.image_reps().size());

	const ImageSkiaRep& result_200p =
	image_skia.GetRepresentation(2.0f);
	EXPECT_EQ(100, result_200p.GetWidth());
	EXPECT_EQ(200, result_200p.GetHeight());
	EXPECT_EQ(200, result_200p.pixel_width());
	EXPECT_EQ(400, result_200p.pixel_height());
	EXPECT_EQ(2.0f, result_200p.scale());
	EXPECT_EQ(2U, image_skia.image_reps().size());

	// Get the representation again and make sure it doesn't
	// generate new image skia rep.
	image_skia.GetRepresentation(1.0f);
	EXPECT_EQ(2U, image_skia.image_reps().size());
	image_skia.GetRepresentation(2.0f);
	EXPECT_EQ(2U, image_skia.image_reps().size());
	}

	// Tests that image_reps returns all of the representations in the
	// image when there are multiple representations for a scale factor.
	// This currently is the case with ImageLoader::LoadImages.
	TEST_F(ImageSkiaTest, ManyRepsPerScaleFactor) {
	const int kSmallIcon1x = 16;
	const int kSmallIcon2x = 32;
	const int kLargeIcon1x = 32;

	ImageSkia image(std::make_unique<NullSource>(),
	gfx::Size(kSmallIcon1x, kSmallIcon1x));
	// Simulate a source which loads images on a delay. Upon
	// GetImageForScaleFactor, it immediately returns null and starts loading
	// image reps slowly.
	image.GetRepresentation(1.0f);
	image.GetRepresentation(2.0f);

	// After a lengthy amount of simulated time, finally loaded image reps.
	image.AddRepresentation(ImageSkiaRep(
	gfx::Size(kSmallIcon1x, kSmallIcon1x), 1.0f));
	image.AddRepresentation(ImageSkiaRep(
	gfx::Size(kSmallIcon2x, kSmallIcon2x), 2.0f));
	image.AddRepresentation(ImageSkiaRep(
	gfx::Size(kLargeIcon1x, kLargeIcon1x), 1.0f));

	std::vector<ImageSkiaRep> image_reps = image.image_reps();
	EXPECT_EQ(3u, image_reps.size());

	int num_1x = 0;
	int num_2x = 0;
	for (size_t i = 0; i < image_reps.size(); ++i) {
	if (image_reps[i].scale() == 1.0f)
	num_1x++;
	else if (image_reps[i].scale() == 2.0f)
	num_2x++;
	}
	EXPECT_EQ(2, num_1x);
	EXPECT_EQ(1, num_2x);
	}

	TEST_F(ImageSkiaTest, GetBitmap) {
	ImageSkia image_skia(std::make_unique<DynamicSource>(Size(100, 200)),
	Size(100, 200));
	const SkBitmap* bitmap = image_skia.bitmap();
	EXPECT_NE(static_cast<SkBitmap*>(NULL), bitmap);
	EXPECT_FALSE(bitmap->isNull());
	}

	TEST_F(ImageSkiaTest, GetBitmapFromEmpty) {
	// Create an image with 1 representation and remove it so the ImageSkiaStorage
	// is left with no representations.
	ImageSkia empty_image(ImageSkiaRep(Size(100, 200), 1.0f));
	ImageSkia empty_image_copy(empty_image);
	empty_image.RemoveRepresentation(1.0f);

	// Check that ImageSkia::bitmap() still returns a valid SkBitmap pointer for
	// the image and all its copies.
	const SkBitmap* bitmap = empty_image_copy.bitmap();
	ASSERT_NE(static_cast<SkBitmap*>(NULL), bitmap);
	EXPECT_TRUE(bitmap->isNull());
	EXPECT_TRUE(bitmap->empty());
	}

	TEST_F(ImageSkiaTest, BackedBySameObjectAs) {
	// Null images should all be backed by the same object (NULL).
	ImageSkia image;
	ImageSkia unrelated;
	EXPECT_TRUE(image.BackedBySameObjectAs(unrelated));

	image.AddRepresentation(gfx::ImageSkiaRep(gfx::Size(10, 10),
	1.0f));
	ImageSkia copy = image;
	copy.AddRepresentation(gfx::ImageSkiaRep(gfx::Size(10, 10),
	2.0f));
	unrelated.AddRepresentation(gfx::ImageSkiaRep(gfx::Size(10, 10),
	1.0f));
	EXPECT_TRUE(image.BackedBySameObjectAs(copy));
	EXPECT_FALSE(image.BackedBySameObjectAs(unrelated));
	EXPECT_FALSE(copy.BackedBySameObjectAs(unrelated));
	}

	#if DCHECK_IS_ON()
	TEST_F(ImageSkiaTest, EmptyOnThreadTest) {
	ImageSkia empty;
	test::TestOnThread empty_on_thread(&empty);
	empty_on_thread.Start();
	empty_on_thread.Join();
	EXPECT_TRUE(empty_on_thread.can_read());
	EXPECT_TRUE(empty_on_thread.can_modify());
	}

	TEST_F(ImageSkiaTest, StaticOnThreadTest) {
	ImageSkia image(ImageSkiaRep(Size(100, 200), 1.0f));
	EXPECT_FALSE(image.IsThreadSafe());

	test::TestOnThread image_on_thread(&image);
	// an image that was never accessed on this thread can be
	// read by other thread.
	image_on_thread.StartAndJoin();
	EXPECT_TRUE(image_on_thread.can_read());
	EXPECT_TRUE(image_on_thread.can_modify());
	EXPECT_FALSE(image.CanRead());
	EXPECT_FALSE(image.CanModify());

	image.DetachStorageFromSequence();
	// An image is accessed by this thread,
	// so other thread cannot read/modify it.
	image.image_reps();
	test::TestOnThread image_on_thread2(&image);
	image_on_thread2.StartAndJoin();
	EXPECT_FALSE(image_on_thread2.can_read());
	EXPECT_FALSE(image_on_thread2.can_modify());
	EXPECT_TRUE(image.CanRead());
	EXPECT_TRUE(image.CanModify());

	image.DetachStorageFromSequence();
	ImageSkia deep_copy(image.DeepCopy());
	EXPECT_FALSE(deep_copy.IsThreadSafe());
	test::TestOnThread deepcopy_on_thread(&deep_copy);
	deepcopy_on_thread.StartAndJoin();
	EXPECT_TRUE(deepcopy_on_thread.can_read());
	EXPECT_TRUE(deepcopy_on_thread.can_modify());
	EXPECT_FALSE(deep_copy.CanRead());
	EXPECT_FALSE(deep_copy.CanModify());

	ImageSkia deep_copy2(image.DeepCopy());
	EXPECT_EQ(1U, deep_copy2.image_reps().size());
	// Access it from current thread so that it can't be
	// accessed from another thread.
	deep_copy2.image_reps();
	EXPECT_FALSE(deep_copy2.IsThreadSafe());
	test::TestOnThread deepcopy2_on_thread(&deep_copy2);
	deepcopy2_on_thread.StartAndJoin();
	EXPECT_FALSE(deepcopy2_on_thread.can_read());
	EXPECT_FALSE(deepcopy2_on_thread.can_modify());
	EXPECT_TRUE(deep_copy2.CanRead());
	EXPECT_TRUE(deep_copy2.CanModify());

	image.DetachStorageFromSequence();
	image.SetReadOnly();
	// A read-only ImageSkia with no source is thread safe.
	EXPECT_TRUE(image.IsThreadSafe());
	test::TestOnThread readonly_on_thread(&image);
	readonly_on_thread.StartAndJoin();
	EXPECT_TRUE(readonly_on_thread.can_read());
	EXPECT_FALSE(readonly_on_thread.can_modify());
	EXPECT_TRUE(image.CanRead());
	EXPECT_FALSE(image.CanModify());

	image.DetachStorageFromSequence();
	image.MakeThreadSafe();
	EXPECT_TRUE(image.IsThreadSafe());
	test::TestOnThread threadsafe_on_thread(&image);
	threadsafe_on_thread.StartAndJoin();
	EXPECT_TRUE(threadsafe_on_thread.can_read());
	EXPECT_FALSE(threadsafe_on_thread.can_modify());
	EXPECT_TRUE(image.CanRead());
	EXPECT_FALSE(image.CanModify());
	}

	TEST_F(ImageSkiaTest, SourceOnThreadTest) {
	ImageSkia image(std::make_unique<DynamicSource>(Size(100, 200)),
	Size(100, 200));
	EXPECT_FALSE(image.IsThreadSafe());

	test::TestOnThread image_on_thread(&image);
	image_on_thread.StartAndJoin();
	// an image that was never accessed on this thread can be
	// read by other thread.
	EXPECT_TRUE(image_on_thread.can_read());
	EXPECT_TRUE(image_on_thread.can_modify());
	EXPECT_FALSE(image.CanRead());
	EXPECT_FALSE(image.CanModify());

	image.DetachStorageFromSequence();
	// An image is accessed by this thread,
	// so other thread cannot read/modify it.
	image.image_reps();
	test::TestOnThread image_on_thread2(&image);
	image_on_thread2.StartAndJoin();
	EXPECT_FALSE(image_on_thread2.can_read());
	EXPECT_FALSE(image_on_thread2.can_modify());
	EXPECT_TRUE(image.CanRead());
	EXPECT_TRUE(image.CanModify());

	image.DetachStorageFromSequence();
	image.SetReadOnly();
	EXPECT_FALSE(image.IsThreadSafe());
	test::TestOnThread readonly_on_thread(&image);
	readonly_on_thread.StartAndJoin();
	EXPECT_TRUE(readonly_on_thread.can_read());
	EXPECT_FALSE(readonly_on_thread.can_modify());
	EXPECT_FALSE(image.CanRead());
	EXPECT_FALSE(image.CanModify());

	image.DetachStorageFromSequence();
	image.MakeThreadSafe();
	EXPECT_TRUE(image.IsThreadSafe());
	// Check if image reps are generated for supported scale factors.
	EXPECT_EQ(ImageSkia::GetSupportedScales().size(),
	image.image_reps().size());
	test::TestOnThread threadsafe_on_thread(&image);
	threadsafe_on_thread.StartAndJoin();
	EXPECT_TRUE(threadsafe_on_thread.can_read());
	EXPECT_FALSE(threadsafe_on_thread.can_modify());
	EXPECT_TRUE(image.CanRead());
	EXPECT_FALSE(image.CanModify());
	}
	#endif // DCHECK_IS_ON()

	TEST_F(ImageSkiaTest, Unscaled) {
	SkBitmap bitmap;

	// An ImageSkia created with 1x bitmap is unscaled.
	ImageSkia image_skia = ImageSkia::CreateFrom1xBitmap(bitmap);
	EXPECT_TRUE(image_skia.GetRepresentation(1.0f).unscaled());
	ImageSkiaRep rep_2x(Size(100, 100), 2.0f);

	// When reps for other scales are added, the unscaled image
	// becomes scaled.
	image_skia.AddRepresentation(rep_2x);
	EXPECT_FALSE(image_skia.GetRepresentation(1.0f).unscaled());
	EXPECT_FALSE(image_skia.GetRepresentation(2.0f).unscaled());
	}

	namespace {

	std::vector<float> GetSortedScaleFactors(const gfx::ImageSkia& image) {
	const std::vector<ImageSkiaRep>& image_reps = image.image_reps();
	std::vector<float> scale_factors;
	for (size_t i = 0; i < image_reps.size(); ++i) {
	scale_factors.push_back(image_reps[i].scale());
	}
	std::sort(scale_factors.begin(), scale_factors.end());
	return scale_factors;
	}

	} // namespace

	TEST_F(ImageSkiaTest, ArbitraryScaleFactor) {
	// source is owned by \|image\|
	DynamicSource* source = new DynamicSource(Size(100, 200));
	ImageSkia image(base::WrapUnique(source), gfx::Size(100, 200));

	image.GetRepresentation(1.5f);
	EXPECT_EQ(2.0f, source->GetLastRequestedScaleAndReset());
	std::vector<ImageSkiaRep> image_reps = image.image_reps();
	EXPECT_EQ(2u, image_reps.size());

	std::vector<float> scale_factors = GetSortedScaleFactors(image);
	EXPECT_EQ(1.5f, scale_factors[0]);
	EXPECT_EQ(2.0f, scale_factors[1]);

	// Requesting 1.75 scale factor also falls back to 2.0f and rescale.
	// However, the image already has the 2.0f data, so it won't fetch again.
	image.GetRepresentation(1.75f);
	EXPECT_EQ(0.0f, source->GetLastRequestedScaleAndReset());
	image_reps = image.image_reps();
	EXPECT_EQ(3u, image_reps.size());

	scale_factors = GetSortedScaleFactors(image);
	EXPECT_EQ(1.5f, scale_factors[0]);
	EXPECT_EQ(1.75f, scale_factors[1]);
	EXPECT_EQ(2.0f, scale_factors[2]);

	// Requesting 1.25 scale factor also falls back to 2.0f and rescale.
	// However, the image already has the 2.0f data, so it won't fetch again.
	image.GetRepresentation(1.25f);
	EXPECT_EQ(0.0f, source->GetLastRequestedScaleAndReset());
	image_reps = image.image_reps();
	EXPECT_EQ(4u, image_reps.size());
	scale_factors = GetSortedScaleFactors(image);
	EXPECT_EQ(1.25f, scale_factors[0]);
	EXPECT_EQ(1.5f, scale_factors[1]);
	EXPECT_EQ(1.75f, scale_factors[2]);
	EXPECT_EQ(2.0f, scale_factors[3]);

	// 1.20 is falled back to 1.0.
	image.GetRepresentation(1.20f);
	EXPECT_EQ(1.0f, source->GetLastRequestedScaleAndReset());
	image_reps = image.image_reps();
	EXPECT_EQ(6u, image_reps.size());
	scale_factors = GetSortedScaleFactors(image);
	EXPECT_EQ(1.0f, scale_factors[0]);
	EXPECT_EQ(1.2f, scale_factors[1]);
	EXPECT_EQ(1.25f, scale_factors[2]);
	EXPECT_EQ(1.5f, scale_factors[3]);
	EXPECT_EQ(1.75f, scale_factors[4]);
	EXPECT_EQ(2.0f, scale_factors[5]);

	// Scale factor less than 1.0f will be falled back to 1.0f
	image.GetRepresentation(0.75f);
	EXPECT_EQ(0.0f, source->GetLastRequestedScaleAndReset());
	image_reps = image.image_reps();
	EXPECT_EQ(7u, image_reps.size());

	scale_factors = GetSortedScaleFactors(image);
	EXPECT_EQ(0.75f, scale_factors[0]);
	EXPECT_EQ(1.0f, scale_factors[1]);
	EXPECT_EQ(1.2f, scale_factors[2]);
	EXPECT_EQ(1.25f, scale_factors[3]);
	EXPECT_EQ(1.5f, scale_factors[4]);
	EXPECT_EQ(1.75f, scale_factors[5]);
	EXPECT_EQ(2.0f, scale_factors[6]);

	// Scale factor greater than 2.0f is falled back to 2.0f because it's not
	// supported.
	image.GetRepresentation(3.0f);
	EXPECT_EQ(0.0f, source->GetLastRequestedScaleAndReset());
	image_reps = image.image_reps();
	EXPECT_EQ(8u, image_reps.size());
	}

	TEST_F(ImageSkiaTest, ArbitraryScaleFactorWithMissingResource) {
	ImageSkia image(
	std::make_unique<FixedScaleSource>(ImageSkiaRep(Size(100, 200), 1.0f)),
	Size(100, 200));

	// Requesting 1.5f -- falls back to 2.0f, but couldn't find. It should
	// look up 1.0f and then rescale it. Note that the rescaled ImageSkiaRep will
	// have 2.0f scale.
	const ImageSkiaRep& rep = image.GetRepresentation(1.5f);
	EXPECT_EQ(1.5f, rep.scale());
	EXPECT_EQ(2U, image.image_reps().size());
	EXPECT_EQ(2.0f, image.image_reps()[0].scale());
	EXPECT_EQ(1.5f, image.image_reps()[1].scale());
	}

	TEST_F(ImageSkiaTest, UnscaledImageForArbitraryScaleFactor) {
	// 0.0f means unscaled.
	ImageSkia image(
	std::make_unique<FixedScaleSource>(ImageSkiaRep(Size(100, 200), 0.0f)),
	Size(100, 200));

	// Requesting 2.0f, which should return 1.0f unscaled image.
	const ImageSkiaRep& rep = image.GetRepresentation(2.0f);
	EXPECT_EQ(1.0f, rep.scale());
	EXPECT_EQ("100x200", rep.pixel_size().ToString());
	EXPECT_TRUE(rep.unscaled());
	EXPECT_EQ(1U, image.image_reps().size());

	// Same for any other scale factors.
	const ImageSkiaRep& rep15 = image.GetRepresentation(1.5f);
	EXPECT_EQ(1.0f, rep15.scale());
	EXPECT_EQ("100x200", rep15.pixel_size().ToString());
	EXPECT_TRUE(rep15.unscaled());
	EXPECT_EQ(1U, image.image_reps().size());

	const ImageSkiaRep& rep12 = image.GetRepresentation(1.2f);
	EXPECT_EQ(1.0f, rep12.scale());
	EXPECT_EQ("100x200", rep12.pixel_size().ToString());
	EXPECT_TRUE(rep12.unscaled());
	EXPECT_EQ(1U, image.image_reps().size());
	}

	} // namespace gfx