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1 // Copyright (c) 2011 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
5 #ifndef SKIA_EXT_IMAGE_OPERATIONS_H_
6 #define SKIA_EXT_IMAGE_OPERATIONS_H_
18 //
19 // Quality Methods
20 //
21 // Those enumeration values express a desired quality/speed tradeoff.
22 // They are translated into an algorithm-specific method that depends
23 // on the capabilities (CPU, GPU) of the underlying platform.
24 // It is possible for all three methods to be mapped to the same
25 // algorithm on a given platform.
27 // Good quality resizing. Fastest resizing with acceptable visual quality.
28 // This is typically intended for use during interactive layouts
29 // where slower platforms may want to trade image quality for large
30 // increase in resizing performance.
31 //
32 // For example the resizing implementation may devolve to linear
33 // filtering if this enables GPU acceleration to be used.
34 //
35 // Note that the underlying resizing method may be determined
36 // on the fly based on the parameters for a given resize call.
37 // For example an implementation using a GPU-based linear filter
38 // in the common case may still use a higher-quality software-based
39 // filter in cases where using the GPU would actually be slower - due
40 // to too much latency - or impossible - due to image format or size
41 // constraints.
42 RESIZE_GOOD,
44 // Medium quality resizing. Close to high quality resizing (better
45 // than linear interpolation) with potentially some quality being
46 // traded-off for additional speed compared to RESIZE_BEST.
47 //
48 // This is intended, for example, for generation of large thumbnails
49 // (hundreds of pixels in each dimension) from large sources, where
50 // a linear filter would produce too many artifacts but where
51 // a RESIZE_HIGH might be too costly time-wise.
52 RESIZE_BETTER,
54 // High quality resizing. The algorithm is picked to favor image quality.
55 RESIZE_BEST,
57 //
58 // Algorithm-specific enumerations
59 //
61 // Box filter. This is a weighted average of all of the pixels touching
62 // the destination pixel. For enlargement, this is nearest neighbor.
63 //
64 // You probably don't want this, it is here for testing since it is easy to
65 // compute. Use RESIZE_LANCZOS3 instead.
66 RESIZE_BOX,
68 // 1-cycle Hamming filter. This is tall is the middle and falls off towards
69 // the window edges but without going to 0. This is about 40% faster than
70 // a 2-cycle Lanczos.
71 RESIZE_HAMMING1,
73 // 2-cycle Lanczos filter. This is tall in the middle, goes negative on
74 // each side, then returns to zero. Does not provide as good a frequency
75 // response as a 3-cycle Lanczos but is roughly 30% faster.
76 RESIZE_LANCZOS2,
78 // 3-cycle Lanczos filter. This is tall in the middle, goes negative on
79 // each side, then oscillates 2 more times. It gives nice sharp edges.
80 RESIZE_LANCZOS3,
82 // Lanczos filter + subpixel interpolation. If subpixel rendering is not
83 // appropriate we automatically fall back to Lanczos.
84 RESIZE_SUBPIXEL,
86 // enum aliases for first and last methods by algorithm or by quality.
91 };
93 // Resizes the given source bitmap using the specified resize method, so that
94 // the entire image is (dest_size) big. The dest_subset is the rectangle in
95 // this destination image that should actually be returned.
96 //
97 // The output image will be (dest_subset.width(), dest_subset.height()). This
98 // will save work if you do not need the entire bitmap.
99 //
100 // The destination subset must be smaller than the destination image.
102 ResizeMethod method,
107 // Alternate version for resizing and returning the entire bitmap rather than
108 // a subset.
110 ResizeMethod method,
117 // Supports all methods except RESIZE_SUBPIXEL.
119 ResizeMethod method,
124 // Subpixel renderer.
129 };