skia/ext/image_operations.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 <stddef.h>
 #include <stdint.h>

 #include <algorithm>
 #include <limits>

 #include "skia/ext/image_operations.h"

 #include "base/containers/stack_container.h"
 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/metrics/histogram_macros.h"
 #include "base/numerics/math_constants.h"
 #include "base/time/time.h"
 #include "base/trace_event/trace_event.h"
 #include "build/build_config.h"
 #include "skia/ext/convolver.h"
 #include "third_party/skia/include/core/SkColorPriv.h"
 #include "third_party/skia/include/core/SkRect.h"

 namespace skia {

 namespace {

 // Returns the ceiling/floor as an integer.
 inline int CeilInt(float val) {
   return static_cast<int>(ceil(val));
 }
 inline int FloorInt(float val) {
   return static_cast<int>(floor(val));
 }

 // Filter function computation -------------------------------------------------

 // Evaluates the box filter, which goes from -0.5 to +0.5.
 float EvalBox(float x) {
   return (x >= -0.5f && x < 0.5f) ? 1.0f : 0.0f;
 }

 // Evaluates the Lanczos filter of the given filter size window for the given
 // position.
 //
 // |filter_size| is the width of the filter (the "window"), outside of which
 // the value of the function is 0. Inside of the window, the value is the
 // normalized sinc function:
 //   lanczos(x) = sinc(x) * sinc(x / filter_size);
 // where
 //   sinc(x) = sin(pi*x) / (pi*x);
 float EvalLanczos(int filter_size, float x) {
   if (x <= -filter_size || x >= filter_size)
     return 0.0f;  // Outside of the window.
   if (x > -std::numeric_limits<float>::epsilon() &&
       x < std::numeric_limits<float>::epsilon())
     return 1.0f;  // Special case the discontinuity at the origin.
   float xpi = x * base::kPiFloat;
   return (sin(xpi) / xpi) *  // sinc(x)
           sin(xpi / filter_size) / (xpi / filter_size);  // sinc(x/filter_size)
 }

 // Evaluates the Hamming filter of the given filter size window for the given
 // position.
 //
 // The filter covers [-filter_size, +filter_size]. Outside of this window
 // the value of the function is 0. Inside of the window, the value is sinus
 // cardinal multiplied by a recentered Hamming function. The traditional
 // Hamming formula for a window of size N and n ranging in [0, N-1] is:
 //   hamming(n) = 0.54 - 0.46 * cos(2 * pi * n / (N-1)))
 // In our case we want the function centered for x == 0 and at its minimum
 // on both ends of the window (x == +/- filter_size), hence the adjusted
 // formula:
 //   hamming(x) = (0.54 -
 //                 0.46 * cos(2 * pi * (x - filter_size)/ (2 * filter_size)))
 //              = 0.54 - 0.46 * cos(pi * x / filter_size - pi)
 //              = 0.54 + 0.46 * cos(pi * x / filter_size)
 float EvalHamming(int filter_size, float x) {
   if (x <= -filter_size || x >= filter_size)
     return 0.0f;  // Outside of the window.
   if (x > -std::numeric_limits<float>::epsilon() &&
       x < std::numeric_limits<float>::epsilon())
     return 1.0f;  // Special case the sinc discontinuity at the origin.
   const float xpi = x * base::kPiFloat;

   return ((sin(xpi) / xpi) *  // sinc(x)
           (0.54f + 0.46f * cos(xpi / filter_size)));  // hamming(x)
 }

 // ResizeFilter ----------------------------------------------------------------

 // Encapsulates computation and storage of the filters required for one complete
 // resize operation.
 class ResizeFilter {
  public:
   ResizeFilter(ImageOperations::ResizeMethod method,
                int src_full_width, int src_full_height,
                int dest_width, int dest_height,
                const SkIRect& dest_subset);

   // Returns the filled filter values.
   const ConvolutionFilter1D& x_filter() { return x_filter_; }
   const ConvolutionFilter1D& y_filter() { return y_filter_; }

  private:
   // Returns the number of pixels that the filer spans, in filter space (the
   // destination image).
   float GetFilterSupport(float scale) {
     switch (method_) {
       case ImageOperations::RESIZE_BOX:
         // The box filter just scales with the image scaling.
         return 0.5f;  // Only want one side of the filter = /2.
       case ImageOperations::RESIZE_HAMMING1:
         // The Hamming filter takes as much space in the source image in
         // each direction as the size of the window = 1 for Hamming1.
         return 1.0f;
       case ImageOperations::RESIZE_LANCZOS3:
         // The Lanczos filter takes as much space in the source image in
         // each direction as the size of the window = 3 for Lanczos3.
         return 3.0f;
       default:
         NOTREACHED();
         return 1.0f;
     }
   }

   // Computes one set of filters either horizontally or vertically. The caller
   // will specify the "min" and "max" rather than the bottom/top and
   // right/bottom so that the same code can be re-used in each dimension.
   //
   // |src_depend_lo| and |src_depend_size| gives the range for the source
   // depend rectangle (horizontally or vertically at the caller's discretion
   // -- see above for what this means).
   //
   // Likewise, the range of destination values to compute and the scale factor
   // for the transform is also specified.
   void ComputeFilters(int src_size,
                       int dest_subset_lo, int dest_subset_size,
                       float scale,
                       ConvolutionFilter1D* output);

   // Computes the filter value given the coordinate in filter space.
   inline float ComputeFilter(float pos) {
     switch (method_) {
       case ImageOperations::RESIZE_BOX:
         return EvalBox(pos);
       case ImageOperations::RESIZE_HAMMING1:
         return EvalHamming(1, pos);
       case ImageOperations::RESIZE_LANCZOS3:
         return EvalLanczos(3, pos);
       default:
         NOTREACHED();
         return 0;
     }
   }

   ImageOperations::ResizeMethod method_;

   ConvolutionFilter1D x_filter_;
   ConvolutionFilter1D y_filter_;

   DISALLOW_COPY_AND_ASSIGN(ResizeFilter);
 };

 ResizeFilter::ResizeFilter(ImageOperations::ResizeMethod method,
                            int src_full_width,
                            int src_full_height,
                            int dest_width,
                            int dest_height,
                            const SkIRect& dest_subset)
     : method_(method) {
   // method_ will only ever refer to an "algorithm method".
   SkASSERT((ImageOperations::RESIZE_FIRST_ALGORITHM_METHOD <= method) &&
            (method <= ImageOperations::RESIZE_LAST_ALGORITHM_METHOD));

   float scale_x = static_cast<float>(dest_width) /
                   static_cast<float>(src_full_width);
   float scale_y = static_cast<float>(dest_height) /
                   static_cast<float>(src_full_height);

   ComputeFilters(src_full_width, dest_subset.fLeft, dest_subset.width(),
                  scale_x, &x_filter_);
   ComputeFilters(src_full_height, dest_subset.fTop, dest_subset.height(),
                  scale_y, &y_filter_);
 }

 // TODO(egouriou): Take advantage of periods in the convolution.
 // Practical resizing filters are periodic outside of the border area.
 // For Lanczos, a scaling by a (reduced) factor of p/q (q pixels in the
 // source become p pixels in the destination) will have a period of p.
 // A nice consequence is a period of 1 when downscaling by an integral
 // factor. Downscaling from typical display resolutions is also bound
 // to produce interesting periods as those are chosen to have multiple
 // small factors.
 // Small periods reduce computational load and improve cache usage if
 // the coefficients can be shared. For periods of 1 we can consider
 // loading the factors only once outside the borders.
 void ResizeFilter::ComputeFilters(int src_size,
                                   int dest_subset_lo, int dest_subset_size,
                                   float scale,
                                   ConvolutionFilter1D* output) {
   int dest_subset_hi = dest_subset_lo + dest_subset_size;  // [lo, hi)

   // When we're doing a magnification, the scale will be larger than one. This
   // means the destination pixels are much smaller than the source pixels, and
   // that the range covered by the filter won't necessarily cover any source
   // pixel boundaries. Therefore, we use these clamped values (max of 1) for
   // some computations.
   float clamped_scale = std::min(1.0f, scale);

   // This is how many source pixels from the center we need to count
   // to support the filtering function.
   float src_support = GetFilterSupport(clamped_scale) / clamped_scale;

   // Speed up the divisions below by turning them into multiplies.
   float inv_scale = 1.0f / scale;

   base::StackVector<float, 64> filter_values;
   base::StackVector<int16_t, 64> fixed_filter_values;

   // Loop over all pixels in the output range. We will generate one set of
   // filter values for each one. Those values will tell us how to blend the
   // source pixels to compute the destination pixel.
   for (int dest_subset_i = dest_subset_lo; dest_subset_i < dest_subset_hi;
        dest_subset_i++) {
     // Reset the arrays. We don't declare them inside so they can re-use the
     // same malloc-ed buffer.
     filter_values->clear();
     fixed_filter_values->clear();

     // This is the pixel in the source directly under the pixel in the dest.
     // Note that we base computations on the "center" of the pixels. To see
     // why, observe that the destination pixel at coordinates (0, 0) in a 5.0x
     // downscale should "cover" the pixels around the pixel with *its center*
     // at coordinates (2.5, 2.5) in the source, not those around (0, 0).
     // Hence we need to scale coordinates (0.5, 0.5), not (0, 0).
     float src_pixel = (static_cast<float>(dest_subset_i) + 0.5f) * inv_scale;

     // Compute the (inclusive) range of source pixels the filter covers.
     int src_begin = std::max(0, FloorInt(src_pixel - src_support));
     int src_end = std::min(src_size - 1, CeilInt(src_pixel + src_support));

     // Compute the unnormalized filter value at each location of the source
     // it covers.
     float filter_sum = 0.0f;  // Sub of the filter values for normalizing.
     for (int cur_filter_pixel = src_begin; cur_filter_pixel <= src_end;
          cur_filter_pixel++) {
       // Distance from the center of the filter, this is the filter coordinate
       // in source space. We also need to consider the center of the pixel
       // when comparing distance against 'src_pixel'. In the 5x downscale
       // example used above the distance from the center of the filter to
       // the pixel with coordinates (2, 2) should be 0, because its center
       // is at (2.5, 2.5).
       float src_filter_dist =
           ((static_cast<float>(cur_filter_pixel) + 0.5f) - src_pixel);

       // Since the filter really exists in dest space, map it there.
       float dest_filter_dist = src_filter_dist * clamped_scale;

       // Compute the filter value at that location.
       float filter_value = ComputeFilter(dest_filter_dist);
       filter_values->push_back(filter_value);

       filter_sum += filter_value;
     }
     DCHECK(!filter_values->empty()) << "We should always get a filter!";

     // The filter must be normalized so that we don't affect the brightness of
     // the image. Convert to normalized fixed point.
     int16_t fixed_sum = 0;
     for (size_t i = 0; i < filter_values->size(); i++) {
       int16_t cur_fixed = output->FloatToFixed(filter_values[i] / filter_sum);
       fixed_sum += cur_fixed;
       fixed_filter_values->push_back(cur_fixed);
     }

     // The conversion to fixed point will leave some rounding errors, which
     // we add back in to avoid affecting the brightness of the image. We
     // arbitrarily add this to the center of the filter array (this won't always
     // be the center of the filter function since it could get clipped on the
     // edges, but it doesn't matter enough to worry about that case).
     int16_t leftovers = output->FloatToFixed(1.0f) - fixed_sum;
     fixed_filter_values[fixed_filter_values->size() / 2] += leftovers;

     // Now it's ready to go.
     output->AddFilter(src_begin, &fixed_filter_values[0],
                       static_cast<int>(fixed_filter_values->size()));
   }

   output->PaddingForSIMD();
 }

 ImageOperations::ResizeMethod ResizeMethodToAlgorithmMethod(
     ImageOperations::ResizeMethod method) {
   // Convert any "Quality Method" into an "Algorithm Method"
   if (method >= ImageOperations::RESIZE_FIRST_ALGORITHM_METHOD &&
       method <= ImageOperations::RESIZE_LAST_ALGORITHM_METHOD) {
     return method;
   }
   // The call to ImageOperationsGtv::Resize() above took care of
   // GPU-acceleration in the cases where it is possible. So now we just
   // pick the appropriate software method for each resize quality.
   switch (method) {
     // Users of RESIZE_GOOD are willing to trade a lot of quality to
     // get speed, allowing the use of linear resampling to get hardware
     // acceleration (SRB). Hence any of our "good" software filters
     // will be acceptable, and we use the fastest one, Hamming-1.
     case ImageOperations::RESIZE_GOOD:
       // Users of RESIZE_BETTER are willing to trade some quality in order
       // to improve performance, but are guaranteed not to devolve to a linear
       // resampling. In visual tests we see that Hamming-1 is not as good as
       // Lanczos-2, however it is about 40% faster and Lanczos-2 itself is
       // about 30% faster than Lanczos-3. The use of Hamming-1 has been deemed
       // an acceptable trade-off between quality and speed.
     case ImageOperations::RESIZE_BETTER:
       return ImageOperations::RESIZE_HAMMING1;
     default:
       return ImageOperations::RESIZE_LANCZOS3;
   }
 }

 }  // namespace

 // Resize ----------------------------------------------------------------------

 // static
 SkBitmap ImageOperations::Resize(const SkPixmap& source,
                                  ResizeMethod method,
                                  int dest_width,
                                  int dest_height,
                                  const SkIRect& dest_subset,
                                  SkBitmap::Allocator* allocator) {
   TRACE_EVENT2("disabled-by-default-skia", "ImageOperations::Resize",
                "src_pixels", source.width() * source.height(), "dst_pixels",
                dest_width * dest_height);
   // Ensure that the ResizeMethod enumeration is sound.
   SkASSERT(((RESIZE_FIRST_QUALITY_METHOD <= method) &&
             (method <= RESIZE_LAST_QUALITY_METHOD)) ||
            ((RESIZE_FIRST_ALGORITHM_METHOD <= method) &&
             (method <= RESIZE_LAST_ALGORITHM_METHOD)));

   // Time how long this takes to see if it's a problem for users.
   base::TimeTicks resize_start = base::TimeTicks::Now();

   // If the size of source or destination is 0, i.e. 0x0, 0xN or Nx0, just
   // return empty.
   if (source.width() < 1 || source.height() < 1 ||
       dest_width < 1 || dest_height < 1)
     return SkBitmap();

   SkIRect dest = {0, 0, dest_width, dest_height};
   DCHECK(dest.contains(dest_subset))
       << "The supplied subset does not fall within the destination image.";

   method = ResizeMethodToAlgorithmMethod(method);
   // Check that we deal with an "algorithm methods" from this point onward.
   SkASSERT((ImageOperations::RESIZE_FIRST_ALGORITHM_METHOD <= method) &&
            (method <= ImageOperations::RESIZE_LAST_ALGORITHM_METHOD));

   if (!source.addr() || source.colorType() != kN32_SkColorType)
     return SkBitmap();

   ResizeFilter filter(method, source.width(), source.height(),
                       dest_width, dest_height, dest_subset);

   // Get a source bitmap encompassing this touched area. We construct the
   // offsets and row strides such that it looks like a new bitmap, while
   // referring to the old data.
   const uint8_t* source_subset =
       reinterpret_cast<const uint8_t*>(source.addr());

   // Convolve into the result.
   SkBitmap result;
   result.setInfo(
       source.info().makeWH(dest_subset.width(), dest_subset.height()));
   result.allocPixels(allocator);
   if (!result.readyToDraw())
     return SkBitmap();

   BGRAConvolve2D(source_subset, static_cast<int>(source.rowBytes()),
                  !source.isOpaque(), filter.x_filter(), filter.y_filter(),
                  static_cast<int>(result.rowBytes()),
                  static_cast<unsigned char*>(result.getPixels()),
                  true);

   base::TimeDelta delta = base::TimeTicks::Now() - resize_start;
   UMA_HISTOGRAM_TIMES("Image.ResampleMS", delta);

   return result;
 }

 // static
 SkBitmap ImageOperations::Resize(const SkBitmap& source,
                                  ResizeMethod method,
                                  int dest_width,
                                  int dest_height,
                                  const SkIRect& dest_subset,
                                  SkBitmap::Allocator* allocator) {
   SkPixmap pixmap;
   if (!source.peekPixels(&pixmap))
     return SkBitmap();
   return Resize(pixmap, method, dest_width, dest_height, dest_subset,
                 allocator);
 }

 // static
 SkBitmap ImageOperations::Resize(const SkBitmap& source,
                                  ResizeMethod method,
                                  int dest_width, int dest_height,
                                  SkBitmap::Allocator* allocator) {
   SkIRect dest_subset = { 0, 0, dest_width, dest_height };
   return Resize(source, method, dest_width, dest_height, dest_subset,
                 allocator);
 }

 }  // namespace skia
	// 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 <stddef.h>
	#include <stdint.h>

	#include <algorithm>
	#include <limits>

	#include "skia/ext/image_operations.h"

	#include "base/containers/stack_container.h"
	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/metrics/histogram_macros.h"
	#include "base/numerics/math_constants.h"
	#include "base/time/time.h"
	#include "base/trace_event/trace_event.h"
	#include "build/build_config.h"
	#include "skia/ext/convolver.h"
	#include "third_party/skia/include/core/SkColorPriv.h"
	#include "third_party/skia/include/core/SkRect.h"

	namespace skia {

	namespace {

	// Returns the ceiling/floor as an integer.
	inline int CeilInt(float val) {
	return static_cast<int>(ceil(val));
	}
	inline int FloorInt(float val) {
	return static_cast<int>(floor(val));
	}

	// Filter function computation -------------------------------------------------

	// Evaluates the box filter, which goes from -0.5 to +0.5.
	float EvalBox(float x) {
	return (x >= -0.5f && x < 0.5f) ? 1.0f : 0.0f;
	}

	// Evaluates the Lanczos filter of the given filter size window for the given
	// position.
	//
	// \|filter_size\| is the width of the filter (the "window"), outside of which
	// the value of the function is 0. Inside of the window, the value is the
	// normalized sinc function:
	// lanczos(x) = sinc(x) * sinc(x / filter_size);
	// where
	// sinc(x) = sin(pix) / (pix);
	float EvalLanczos(int filter_size, float x) {
	if (x <= -filter_size \|\| x >= filter_size)
	return 0.0f; // Outside of the window.
	if (x > -std::numeric_limits<float>::epsilon() &&
	x < std::numeric_limits<float>::epsilon())
	return 1.0f; // Special case the discontinuity at the origin.
	float xpi = x * base::kPiFloat;
	return (sin(xpi) / xpi) * // sinc(x)
	sin(xpi / filter_size) / (xpi / filter_size); // sinc(x/filter_size)
	}

	// Evaluates the Hamming filter of the given filter size window for the given
	// position.
	//
	// The filter covers [-filter_size, +filter_size]. Outside of this window
	// the value of the function is 0. Inside of the window, the value is sinus
	// cardinal multiplied by a recentered Hamming function. The traditional
	// Hamming formula for a window of size N and n ranging in [0, N-1] is:
	// hamming(n) = 0.54 - 0.46 * cos(2 * pi * n / (N-1)))
	// In our case we want the function centered for x == 0 and at its minimum
	// on both ends of the window (x == +/- filter_size), hence the adjusted
	// formula:
	// hamming(x) = (0.54 -
	// 0.46 * cos(2 * pi * (x - filter_size)/ (2 * filter_size)))
	// = 0.54 - 0.46 * cos(pi * x / filter_size - pi)
	// = 0.54 + 0.46 * cos(pi * x / filter_size)
	float EvalHamming(int filter_size, float x) {
	if (x <= -filter_size \|\| x >= filter_size)
	return 0.0f; // Outside of the window.
	if (x > -std::numeric_limits<float>::epsilon() &&
	x < std::numeric_limits<float>::epsilon())
	return 1.0f; // Special case the sinc discontinuity at the origin.
	const float xpi = x * base::kPiFloat;

	return ((sin(xpi) / xpi) * // sinc(x)
	(0.54f + 0.46f * cos(xpi / filter_size))); // hamming(x)
	}

	// ResizeFilter ----------------------------------------------------------------

	// Encapsulates computation and storage of the filters required for one complete
	// resize operation.
	class ResizeFilter {
	public:
	ResizeFilter(ImageOperations::ResizeMethod method,
	int src_full_width, int src_full_height,
	int dest_width, int dest_height,
	const SkIRect& dest_subset);

	// Returns the filled filter values.
	const ConvolutionFilter1D& x_filter() { return x_filter_; }
	const ConvolutionFilter1D& y_filter() { return y_filter_; }

	private:
	// Returns the number of pixels that the filer spans, in filter space (the
	// destination image).
	float GetFilterSupport(float scale) {
	switch (method_) {
	case ImageOperations::RESIZE_BOX:
	// The box filter just scales with the image scaling.
	return 0.5f; // Only want one side of the filter = /2.
	case ImageOperations::RESIZE_HAMMING1:
	// The Hamming filter takes as much space in the source image in
	// each direction as the size of the window = 1 for Hamming1.
	return 1.0f;
	case ImageOperations::RESIZE_LANCZOS3:
	// The Lanczos filter takes as much space in the source image in
	// each direction as the size of the window = 3 for Lanczos3.
	return 3.0f;
	default:
	NOTREACHED();
	return 1.0f;
	}
	}

	// Computes one set of filters either horizontally or vertically. The caller
	// will specify the "min" and "max" rather than the bottom/top and
	// right/bottom so that the same code can be re-used in each dimension.
	//
	// \|src_depend_lo\| and \|src_depend_size\| gives the range for the source
	// depend rectangle (horizontally or vertically at the caller's discretion
	// -- see above for what this means).
	//
	// Likewise, the range of destination values to compute and the scale factor
	// for the transform is also specified.
	void ComputeFilters(int src_size,
	int dest_subset_lo, int dest_subset_size,
	float scale,
	ConvolutionFilter1D* output);

	// Computes the filter value given the coordinate in filter space.
	inline float ComputeFilter(float pos) {
	switch (method_) {
	case ImageOperations::RESIZE_BOX:
	return EvalBox(pos);
	case ImageOperations::RESIZE_HAMMING1:
	return EvalHamming(1, pos);
	case ImageOperations::RESIZE_LANCZOS3:
	return EvalLanczos(3, pos);
	default:
	NOTREACHED();
	return 0;
	}
	}

	ImageOperations::ResizeMethod method_;

	ConvolutionFilter1D x_filter_;
	ConvolutionFilter1D y_filter_;

	DISALLOW_COPY_AND_ASSIGN(ResizeFilter);
	};

	ResizeFilter::ResizeFilter(ImageOperations::ResizeMethod method,
	int src_full_width,
	int src_full_height,
	int dest_width,
	int dest_height,
	const SkIRect& dest_subset)
	: method_(method) {
	// method_ will only ever refer to an "algorithm method".
	SkASSERT((ImageOperations::RESIZE_FIRST_ALGORITHM_METHOD <= method) &&
	(method <= ImageOperations::RESIZE_LAST_ALGORITHM_METHOD));

	float scale_x = static_cast<float>(dest_width) /
	static_cast<float>(src_full_width);
	float scale_y = static_cast<float>(dest_height) /
	static_cast<float>(src_full_height);

	ComputeFilters(src_full_width, dest_subset.fLeft, dest_subset.width(),
	scale_x, &x_filter_);
	ComputeFilters(src_full_height, dest_subset.fTop, dest_subset.height(),
	scale_y, &y_filter_);
	}

	// TODO(egouriou): Take advantage of periods in the convolution.
	// Practical resizing filters are periodic outside of the border area.
	// For Lanczos, a scaling by a (reduced) factor of p/q (q pixels in the
	// source become p pixels in the destination) will have a period of p.
	// A nice consequence is a period of 1 when downscaling by an integral
	// factor. Downscaling from typical display resolutions is also bound
	// to produce interesting periods as those are chosen to have multiple
	// small factors.
	// Small periods reduce computational load and improve cache usage if
	// the coefficients can be shared. For periods of 1 we can consider
	// loading the factors only once outside the borders.
	void ResizeFilter::ComputeFilters(int src_size,
	int dest_subset_lo, int dest_subset_size,
	float scale,
	ConvolutionFilter1D* output) {
	int dest_subset_hi = dest_subset_lo + dest_subset_size; // [lo, hi)

	// When we're doing a magnification, the scale will be larger than one. This
	// means the destination pixels are much smaller than the source pixels, and
	// that the range covered by the filter won't necessarily cover any source
	// pixel boundaries. Therefore, we use these clamped values (max of 1) for
	// some computations.
	float clamped_scale = std::min(1.0f, scale);

	// This is how many source pixels from the center we need to count
	// to support the filtering function.
	float src_support = GetFilterSupport(clamped_scale) / clamped_scale;

	// Speed up the divisions below by turning them into multiplies.
	float inv_scale = 1.0f / scale;

	base::StackVector<float, 64> filter_values;
	base::StackVector<int16_t, 64> fixed_filter_values;

	// Loop over all pixels in the output range. We will generate one set of
	// filter values for each one. Those values will tell us how to blend the
	// source pixels to compute the destination pixel.
	for (int dest_subset_i = dest_subset_lo; dest_subset_i < dest_subset_hi;
	dest_subset_i++) {
	// Reset the arrays. We don't declare them inside so they can re-use the
	// same malloc-ed buffer.
	filter_values->clear();
	fixed_filter_values->clear();

	// This is the pixel in the source directly under the pixel in the dest.
	// Note that we base computations on the "center" of the pixels. To see
	// why, observe that the destination pixel at coordinates (0, 0) in a 5.0x
	// downscale should "cover" the pixels around the pixel with its center
	// at coordinates (2.5, 2.5) in the source, not those around (0, 0).
	// Hence we need to scale coordinates (0.5, 0.5), not (0, 0).
	float src_pixel = (static_cast<float>(dest_subset_i) + 0.5f) * inv_scale;

	// Compute the (inclusive) range of source pixels the filter covers.
	int src_begin = std::max(0, FloorInt(src_pixel - src_support));
	int src_end = std::min(src_size - 1, CeilInt(src_pixel + src_support));

	// Compute the unnormalized filter value at each location of the source
	// it covers.
	float filter_sum = 0.0f; // Sub of the filter values for normalizing.
	for (int cur_filter_pixel = src_begin; cur_filter_pixel <= src_end;
	cur_filter_pixel++) {
	// Distance from the center of the filter, this is the filter coordinate
	// in source space. We also need to consider the center of the pixel
	// when comparing distance against 'src_pixel'. In the 5x downscale
	// example used above the distance from the center of the filter to
	// the pixel with coordinates (2, 2) should be 0, because its center
	// is at (2.5, 2.5).
	float src_filter_dist =
	((static_cast<float>(cur_filter_pixel) + 0.5f) - src_pixel);

	// Since the filter really exists in dest space, map it there.
	float dest_filter_dist = src_filter_dist * clamped_scale;

	// Compute the filter value at that location.
	float filter_value = ComputeFilter(dest_filter_dist);
	filter_values->push_back(filter_value);

	filter_sum += filter_value;
	}
	DCHECK(!filter_values->empty()) << "We should always get a filter!";

	// The filter must be normalized so that we don't affect the brightness of
	// the image. Convert to normalized fixed point.
	int16_t fixed_sum = 0;
	for (size_t i = 0; i < filter_values->size(); i++) {
	int16_t cur_fixed = output->FloatToFixed(filter_values[i] / filter_sum);
	fixed_sum += cur_fixed;
	fixed_filter_values->push_back(cur_fixed);
	}

	// The conversion to fixed point will leave some rounding errors, which
	// we add back in to avoid affecting the brightness of the image. We
	// arbitrarily add this to the center of the filter array (this won't always
	// be the center of the filter function since it could get clipped on the
	// edges, but it doesn't matter enough to worry about that case).
	int16_t leftovers = output->FloatToFixed(1.0f) - fixed_sum;
	fixed_filter_values[fixed_filter_values->size() / 2] += leftovers;

	// Now it's ready to go.
	output->AddFilter(src_begin, &fixed_filter_values[0],
	static_cast<int>(fixed_filter_values->size()));
	}

	output->PaddingForSIMD();
	}

	ImageOperations::ResizeMethod ResizeMethodToAlgorithmMethod(
	ImageOperations::ResizeMethod method) {
	// Convert any "Quality Method" into an "Algorithm Method"
	if (method >= ImageOperations::RESIZE_FIRST_ALGORITHM_METHOD &&
	method <= ImageOperations::RESIZE_LAST_ALGORITHM_METHOD) {
	return method;
	}
	// The call to ImageOperationsGtv::Resize() above took care of
	// GPU-acceleration in the cases where it is possible. So now we just
	// pick the appropriate software method for each resize quality.
	switch (method) {
	// Users of RESIZE_GOOD are willing to trade a lot of quality to
	// get speed, allowing the use of linear resampling to get hardware
	// acceleration (SRB). Hence any of our "good" software filters
	// will be acceptable, and we use the fastest one, Hamming-1.
	case ImageOperations::RESIZE_GOOD:
	// Users of RESIZE_BETTER are willing to trade some quality in order
	// to improve performance, but are guaranteed not to devolve to a linear
	// resampling. In visual tests we see that Hamming-1 is not as good as
	// Lanczos-2, however it is about 40% faster and Lanczos-2 itself is
	// about 30% faster than Lanczos-3. The use of Hamming-1 has been deemed
	// an acceptable trade-off between quality and speed.
	case ImageOperations::RESIZE_BETTER:
	return ImageOperations::RESIZE_HAMMING1;
	default:
	return ImageOperations::RESIZE_LANCZOS3;
	}
	}

	} // namespace

	// Resize ----------------------------------------------------------------------

	// static
	SkBitmap ImageOperations::Resize(const SkPixmap& source,
	ResizeMethod method,
	int dest_width,
	int dest_height,
	const SkIRect& dest_subset,
	SkBitmap::Allocator* allocator) {
	TRACE_EVENT2("disabled-by-default-skia", "ImageOperations::Resize",
	"src_pixels", source.width() * source.height(), "dst_pixels",
	dest_width * dest_height);
	// Ensure that the ResizeMethod enumeration is sound.
	SkASSERT(((RESIZE_FIRST_QUALITY_METHOD <= method) &&
	(method <= RESIZE_LAST_QUALITY_METHOD)) \|\|
	((RESIZE_FIRST_ALGORITHM_METHOD <= method) &&
	(method <= RESIZE_LAST_ALGORITHM_METHOD)));

	// Time how long this takes to see if it's a problem for users.
	base::TimeTicks resize_start = base::TimeTicks::Now();

	// If the size of source or destination is 0, i.e. 0x0, 0xN or Nx0, just
	// return empty.
	if (source.width() < 1 \|\| source.height() < 1 \|\|
	dest_width < 1 \|\| dest_height < 1)
	return SkBitmap();

	SkIRect dest = {0, 0, dest_width, dest_height};
	DCHECK(dest.contains(dest_subset))
	<< "The supplied subset does not fall within the destination image.";

	method = ResizeMethodToAlgorithmMethod(method);
	// Check that we deal with an "algorithm methods" from this point onward.
	SkASSERT((ImageOperations::RESIZE_FIRST_ALGORITHM_METHOD <= method) &&
	(method <= ImageOperations::RESIZE_LAST_ALGORITHM_METHOD));

	if (!source.addr() \|\| source.colorType() != kN32_SkColorType)
	return SkBitmap();

	ResizeFilter filter(method, source.width(), source.height(),
	dest_width, dest_height, dest_subset);

	// Get a source bitmap encompassing this touched area. We construct the
	// offsets and row strides such that it looks like a new bitmap, while
	// referring to the old data.
	const uint8_t* source_subset =
	reinterpret_cast<const uint8_t*>(source.addr());

	// Convolve into the result.
	SkBitmap result;
	result.setInfo(
	source.info().makeWH(dest_subset.width(), dest_subset.height()));
	result.allocPixels(allocator);
	if (!result.readyToDraw())
	return SkBitmap();

	BGRAConvolve2D(source_subset, static_cast<int>(source.rowBytes()),
	!source.isOpaque(), filter.x_filter(), filter.y_filter(),
	static_cast<int>(result.rowBytes()),
	static_cast<unsigned char*>(result.getPixels()),
	true);

	base::TimeDelta delta = base::TimeTicks::Now() - resize_start;
	UMA_HISTOGRAM_TIMES("Image.ResampleMS", delta);

	return result;
	}

	// static
	SkBitmap ImageOperations::Resize(const SkBitmap& source,
	ResizeMethod method,
	int dest_width,
	int dest_height,
	const SkIRect& dest_subset,
	SkBitmap::Allocator* allocator) {
	SkPixmap pixmap;
	if (!source.peekPixels(&pixmap))
	return SkBitmap();
	return Resize(pixmap, method, dest_width, dest_height, dest_subset,
	allocator);
	}

	// static
	SkBitmap ImageOperations::Resize(const SkBitmap& source,
	ResizeMethod method,
	int dest_width, int dest_height,
	SkBitmap::Allocator* allocator) {
	SkIRect dest_subset = { 0, 0, dest_width, dest_height };
	return Resize(source, method, dest_width, dest_height, dest_subset,
	allocator);
	}

	} // namespace skia