c0bd9f9fe5
Current strategy: everything from the top Things to look at first are the manual changes: - added tools/rewrite_includes.py - removed -Idirectives from BUILD.gn - various compile.sh simplifications - tweak tools/embed_resources.py - update gn/find_headers.py to write paths from the top - update gn/gn_to_bp.py SkUserConfig.h layout so that #include "include/config/SkUserConfig.h" always gets the header we want. No-Presubmit: true Change-Id: I73a4b181654e0e38d229bc456c0d0854bae3363e Reviewed-on: https://skia-review.googlesource.com/c/skia/+/209706 Commit-Queue: Mike Klein <mtklein@google.com> Reviewed-by: Hal Canary <halcanary@google.com> Reviewed-by: Brian Osman <brianosman@google.com> Reviewed-by: Florin Malita <fmalita@chromium.org>
445 lines
15 KiB
C++
445 lines
15 KiB
C++
/*
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* Copyright 2006 The Android Open Source Project
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*
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* Use of this source code is governed by a BSD-style license that can be
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* found in the LICENSE file.
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*/
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#ifndef SkColorData_DEFINED
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#define SkColorData_DEFINED
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#include "include/core/SkColor.h"
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#include "include/core/SkColorPriv.h"
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#include "include/private/SkNx.h"
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#include "include/private/SkTo.h"
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////////////////////////////////////////////////////////////////////////////////////////////
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// Convert a 16bit pixel to a 32bit pixel
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#define SK_R16_BITS 5
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#define SK_G16_BITS 6
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#define SK_B16_BITS 5
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#define SK_R16_SHIFT (SK_B16_BITS + SK_G16_BITS)
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#define SK_G16_SHIFT (SK_B16_BITS)
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#define SK_B16_SHIFT 0
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#define SK_R16_MASK ((1 << SK_R16_BITS) - 1)
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#define SK_G16_MASK ((1 << SK_G16_BITS) - 1)
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#define SK_B16_MASK ((1 << SK_B16_BITS) - 1)
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#define SkGetPackedR16(color) (((unsigned)(color) >> SK_R16_SHIFT) & SK_R16_MASK)
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#define SkGetPackedG16(color) (((unsigned)(color) >> SK_G16_SHIFT) & SK_G16_MASK)
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#define SkGetPackedB16(color) (((unsigned)(color) >> SK_B16_SHIFT) & SK_B16_MASK)
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static inline unsigned SkR16ToR32(unsigned r) {
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return (r << (8 - SK_R16_BITS)) | (r >> (2 * SK_R16_BITS - 8));
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}
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static inline unsigned SkG16ToG32(unsigned g) {
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return (g << (8 - SK_G16_BITS)) | (g >> (2 * SK_G16_BITS - 8));
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}
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static inline unsigned SkB16ToB32(unsigned b) {
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return (b << (8 - SK_B16_BITS)) | (b >> (2 * SK_B16_BITS - 8));
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}
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#define SkPacked16ToR32(c) SkR16ToR32(SkGetPackedR16(c))
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#define SkPacked16ToG32(c) SkG16ToG32(SkGetPackedG16(c))
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#define SkPacked16ToB32(c) SkB16ToB32(SkGetPackedB16(c))
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//////////////////////////////////////////////////////////////////////////////
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#define SkASSERT_IS_BYTE(x) SkASSERT(0 == ((x) & ~0xFF))
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// Reverse the bytes coorsponding to RED and BLUE in a packed pixels. Note the
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// pair of them are in the same 2 slots in both RGBA and BGRA, thus there is
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// no need to pass in the colortype to this function.
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static inline uint32_t SkSwizzle_RB(uint32_t c) {
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static const uint32_t kRBMask = (0xFF << SK_R32_SHIFT) | (0xFF << SK_B32_SHIFT);
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unsigned c0 = (c >> SK_R32_SHIFT) & 0xFF;
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unsigned c1 = (c >> SK_B32_SHIFT) & 0xFF;
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return (c & ~kRBMask) | (c0 << SK_B32_SHIFT) | (c1 << SK_R32_SHIFT);
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}
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static inline uint32_t SkPackARGB_as_RGBA(U8CPU a, U8CPU r, U8CPU g, U8CPU b) {
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SkASSERT_IS_BYTE(a);
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SkASSERT_IS_BYTE(r);
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SkASSERT_IS_BYTE(g);
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SkASSERT_IS_BYTE(b);
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return (a << SK_RGBA_A32_SHIFT) | (r << SK_RGBA_R32_SHIFT) |
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(g << SK_RGBA_G32_SHIFT) | (b << SK_RGBA_B32_SHIFT);
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}
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static inline uint32_t SkPackARGB_as_BGRA(U8CPU a, U8CPU r, U8CPU g, U8CPU b) {
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SkASSERT_IS_BYTE(a);
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SkASSERT_IS_BYTE(r);
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SkASSERT_IS_BYTE(g);
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SkASSERT_IS_BYTE(b);
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return (a << SK_BGRA_A32_SHIFT) | (r << SK_BGRA_R32_SHIFT) |
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(g << SK_BGRA_G32_SHIFT) | (b << SK_BGRA_B32_SHIFT);
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}
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static inline SkPMColor SkSwizzle_RGBA_to_PMColor(uint32_t c) {
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#ifdef SK_PMCOLOR_IS_RGBA
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return c;
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#else
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return SkSwizzle_RB(c);
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#endif
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}
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static inline SkPMColor SkSwizzle_BGRA_to_PMColor(uint32_t c) {
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#ifdef SK_PMCOLOR_IS_BGRA
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return c;
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#else
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return SkSwizzle_RB(c);
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#endif
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}
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//////////////////////////////////////////////////////////////////////////////
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///@{
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/** See ITU-R Recommendation BT.709 at http://www.itu.int/rec/R-REC-BT.709/ .*/
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#define SK_ITU_BT709_LUM_COEFF_R (0.2126f)
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#define SK_ITU_BT709_LUM_COEFF_G (0.7152f)
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#define SK_ITU_BT709_LUM_COEFF_B (0.0722f)
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///@}
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///@{
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/** A float value which specifies this channel's contribution to luminance. */
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#define SK_LUM_COEFF_R SK_ITU_BT709_LUM_COEFF_R
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#define SK_LUM_COEFF_G SK_ITU_BT709_LUM_COEFF_G
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#define SK_LUM_COEFF_B SK_ITU_BT709_LUM_COEFF_B
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///@}
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/** Computes the luminance from the given r, g, and b in accordance with
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SK_LUM_COEFF_X. For correct results, r, g, and b should be in linear space.
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*/
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static inline U8CPU SkComputeLuminance(U8CPU r, U8CPU g, U8CPU b) {
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//The following is
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//r * SK_LUM_COEFF_R + g * SK_LUM_COEFF_G + b * SK_LUM_COEFF_B
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//with SK_LUM_COEFF_X in 1.8 fixed point (rounding adjusted to sum to 256).
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return (r * 54 + g * 183 + b * 19) >> 8;
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}
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/** Calculates 256 - (value * alpha256) / 255 in range [0,256],
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* for [0,255] value and [0,256] alpha256.
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*/
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static inline U16CPU SkAlphaMulInv256(U16CPU value, U16CPU alpha256) {
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unsigned prod = 0xFFFF - value * alpha256;
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return (prod + (prod >> 8)) >> 8;
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}
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// The caller may want negative values, so keep all params signed (int)
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// so we don't accidentally slip into unsigned math and lose the sign
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// extension when we shift (in SkAlphaMul)
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static inline int SkAlphaBlend(int src, int dst, int scale256) {
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SkASSERT((unsigned)scale256 <= 256);
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return dst + SkAlphaMul(src - dst, scale256);
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}
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static inline uint16_t SkPackRGB16(unsigned r, unsigned g, unsigned b) {
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SkASSERT(r <= SK_R16_MASK);
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SkASSERT(g <= SK_G16_MASK);
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SkASSERT(b <= SK_B16_MASK);
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return SkToU16((r << SK_R16_SHIFT) | (g << SK_G16_SHIFT) | (b << SK_B16_SHIFT));
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}
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#define SK_R16_MASK_IN_PLACE (SK_R16_MASK << SK_R16_SHIFT)
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#define SK_G16_MASK_IN_PLACE (SK_G16_MASK << SK_G16_SHIFT)
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#define SK_B16_MASK_IN_PLACE (SK_B16_MASK << SK_B16_SHIFT)
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///////////////////////////////////////////////////////////////////////////////
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/**
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* Abstract 4-byte interpolation, implemented on top of SkPMColor
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* utility functions. Third parameter controls blending of the first two:
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* (src, dst, 0) returns dst
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* (src, dst, 0xFF) returns src
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* srcWeight is [0..256], unlike SkFourByteInterp which takes [0..255]
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*/
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static inline SkPMColor SkFourByteInterp256(SkPMColor src, SkPMColor dst,
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unsigned scale) {
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unsigned a = SkAlphaBlend(SkGetPackedA32(src), SkGetPackedA32(dst), scale);
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unsigned r = SkAlphaBlend(SkGetPackedR32(src), SkGetPackedR32(dst), scale);
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unsigned g = SkAlphaBlend(SkGetPackedG32(src), SkGetPackedG32(dst), scale);
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unsigned b = SkAlphaBlend(SkGetPackedB32(src), SkGetPackedB32(dst), scale);
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return SkPackARGB32(a, r, g, b);
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}
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/**
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* Abstract 4-byte interpolation, implemented on top of SkPMColor
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* utility functions. Third parameter controls blending of the first two:
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* (src, dst, 0) returns dst
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* (src, dst, 0xFF) returns src
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*/
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static inline SkPMColor SkFourByteInterp(SkPMColor src, SkPMColor dst,
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U8CPU srcWeight) {
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unsigned scale = SkAlpha255To256(srcWeight);
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return SkFourByteInterp256(src, dst, scale);
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}
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/**
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* 0xAARRGGBB -> 0x00AA00GG, 0x00RR00BB
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*/
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static inline void SkSplay(uint32_t color, uint32_t* ag, uint32_t* rb) {
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const uint32_t mask = 0x00FF00FF;
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*ag = (color >> 8) & mask;
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*rb = color & mask;
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}
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/**
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* 0xAARRGGBB -> 0x00AA00GG00RR00BB
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* (note, ARGB -> AGRB)
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*/
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static inline uint64_t SkSplay(uint32_t color) {
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const uint32_t mask = 0x00FF00FF;
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uint64_t agrb = (color >> 8) & mask; // 0x0000000000AA00GG
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agrb <<= 32; // 0x00AA00GG00000000
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agrb |= color & mask; // 0x00AA00GG00RR00BB
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return agrb;
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}
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/**
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* 0xAAxxGGxx, 0xRRxxBBxx-> 0xAARRGGBB
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*/
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static inline uint32_t SkUnsplay(uint32_t ag, uint32_t rb) {
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const uint32_t mask = 0xFF00FF00;
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return (ag & mask) | ((rb & mask) >> 8);
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}
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/**
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* 0xAAxxGGxxRRxxBBxx -> 0xAARRGGBB
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* (note, AGRB -> ARGB)
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*/
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static inline uint32_t SkUnsplay(uint64_t agrb) {
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const uint32_t mask = 0xFF00FF00;
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return SkPMColor(
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((agrb & mask) >> 8) | // 0x00RR00BB
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((agrb >> 32) & mask)); // 0xAARRGGBB
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}
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static inline SkPMColor SkFastFourByteInterp256_32(SkPMColor src, SkPMColor dst, unsigned scale) {
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SkASSERT(scale <= 256);
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// Two 8-bit blends per two 32-bit registers, with space to make sure the math doesn't collide.
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uint32_t src_ag, src_rb, dst_ag, dst_rb;
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SkSplay(src, &src_ag, &src_rb);
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SkSplay(dst, &dst_ag, &dst_rb);
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const uint32_t ret_ag = src_ag * scale + (256 - scale) * dst_ag;
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const uint32_t ret_rb = src_rb * scale + (256 - scale) * dst_rb;
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return SkUnsplay(ret_ag, ret_rb);
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}
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static inline SkPMColor SkFastFourByteInterp256_64(SkPMColor src, SkPMColor dst, unsigned scale) {
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SkASSERT(scale <= 256);
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// Four 8-bit blends in one 64-bit register, with space to make sure the math doesn't collide.
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return SkUnsplay(SkSplay(src) * scale + (256-scale) * SkSplay(dst));
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}
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// TODO(mtklein): Replace slow versions with fast versions, using scale + (scale>>7) everywhere.
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/**
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* Same as SkFourByteInterp256, but faster.
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*/
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static inline SkPMColor SkFastFourByteInterp256(SkPMColor src, SkPMColor dst, unsigned scale) {
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// On a 64-bit machine, _64 is about 10% faster than _32, but ~40% slower on a 32-bit machine.
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if (sizeof(void*) == 4) {
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return SkFastFourByteInterp256_32(src, dst, scale);
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} else {
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return SkFastFourByteInterp256_64(src, dst, scale);
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}
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}
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/**
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* Nearly the same as SkFourByteInterp, but faster and a touch more accurate, due to better
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* srcWeight scaling to [0, 256].
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*/
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static inline SkPMColor SkFastFourByteInterp(SkPMColor src,
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SkPMColor dst,
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U8CPU srcWeight) {
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SkASSERT(srcWeight <= 255);
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// scale = srcWeight + (srcWeight >> 7) is more accurate than
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// scale = srcWeight + 1, but 7% slower
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return SkFastFourByteInterp256(src, dst, srcWeight + (srcWeight >> 7));
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}
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/**
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* Interpolates between colors src and dst using [0,256] scale.
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*/
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static inline SkPMColor SkPMLerp(SkPMColor src, SkPMColor dst, unsigned scale) {
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return SkFastFourByteInterp256(src, dst, scale);
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}
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static inline SkPMColor SkBlendARGB32(SkPMColor src, SkPMColor dst, U8CPU aa) {
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SkASSERT((unsigned)aa <= 255);
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unsigned src_scale = SkAlpha255To256(aa);
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unsigned dst_scale = SkAlphaMulInv256(SkGetPackedA32(src), src_scale);
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const uint32_t mask = 0xFF00FF;
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uint32_t src_rb = (src & mask) * src_scale;
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uint32_t src_ag = ((src >> 8) & mask) * src_scale;
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uint32_t dst_rb = (dst & mask) * dst_scale;
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uint32_t dst_ag = ((dst >> 8) & mask) * dst_scale;
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return (((src_rb + dst_rb) >> 8) & mask) | ((src_ag + dst_ag) & ~mask);
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}
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////////////////////////////////////////////////////////////////////////////////////////////
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// Convert a 32bit pixel to a 16bit pixel (no dither)
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#define SkR32ToR16_MACRO(r) ((unsigned)(r) >> (SK_R32_BITS - SK_R16_BITS))
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#define SkG32ToG16_MACRO(g) ((unsigned)(g) >> (SK_G32_BITS - SK_G16_BITS))
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#define SkB32ToB16_MACRO(b) ((unsigned)(b) >> (SK_B32_BITS - SK_B16_BITS))
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#ifdef SK_DEBUG
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static inline unsigned SkR32ToR16(unsigned r) {
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SkR32Assert(r);
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return SkR32ToR16_MACRO(r);
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}
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static inline unsigned SkG32ToG16(unsigned g) {
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SkG32Assert(g);
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return SkG32ToG16_MACRO(g);
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}
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static inline unsigned SkB32ToB16(unsigned b) {
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SkB32Assert(b);
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return SkB32ToB16_MACRO(b);
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}
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#else
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#define SkR32ToR16(r) SkR32ToR16_MACRO(r)
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#define SkG32ToG16(g) SkG32ToG16_MACRO(g)
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#define SkB32ToB16(b) SkB32ToB16_MACRO(b)
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#endif
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static inline U16CPU SkPixel32ToPixel16(SkPMColor c) {
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unsigned r = ((c >> (SK_R32_SHIFT + (8 - SK_R16_BITS))) & SK_R16_MASK) << SK_R16_SHIFT;
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unsigned g = ((c >> (SK_G32_SHIFT + (8 - SK_G16_BITS))) & SK_G16_MASK) << SK_G16_SHIFT;
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unsigned b = ((c >> (SK_B32_SHIFT + (8 - SK_B16_BITS))) & SK_B16_MASK) << SK_B16_SHIFT;
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return r | g | b;
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}
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static inline U16CPU SkPack888ToRGB16(U8CPU r, U8CPU g, U8CPU b) {
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return (SkR32ToR16(r) << SK_R16_SHIFT) |
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(SkG32ToG16(g) << SK_G16_SHIFT) |
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(SkB32ToB16(b) << SK_B16_SHIFT);
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}
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/////////////////////////////////////////////////////////////////////////////////////////
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/* SrcOver the 32bit src color with the 16bit dst, returning a 16bit value
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(with dirt in the high 16bits, so caller beware).
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*/
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static inline U16CPU SkSrcOver32To16(SkPMColor src, uint16_t dst) {
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unsigned sr = SkGetPackedR32(src);
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unsigned sg = SkGetPackedG32(src);
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unsigned sb = SkGetPackedB32(src);
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unsigned dr = SkGetPackedR16(dst);
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unsigned dg = SkGetPackedG16(dst);
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unsigned db = SkGetPackedB16(dst);
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unsigned isa = 255 - SkGetPackedA32(src);
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dr = (sr + SkMul16ShiftRound(dr, isa, SK_R16_BITS)) >> (8 - SK_R16_BITS);
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dg = (sg + SkMul16ShiftRound(dg, isa, SK_G16_BITS)) >> (8 - SK_G16_BITS);
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db = (sb + SkMul16ShiftRound(db, isa, SK_B16_BITS)) >> (8 - SK_B16_BITS);
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return SkPackRGB16(dr, dg, db);
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}
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static inline SkColor SkPixel16ToColor(U16CPU src) {
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SkASSERT(src == SkToU16(src));
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unsigned r = SkPacked16ToR32(src);
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unsigned g = SkPacked16ToG32(src);
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unsigned b = SkPacked16ToB32(src);
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SkASSERT((r >> (8 - SK_R16_BITS)) == SkGetPackedR16(src));
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SkASSERT((g >> (8 - SK_G16_BITS)) == SkGetPackedG16(src));
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SkASSERT((b >> (8 - SK_B16_BITS)) == SkGetPackedB16(src));
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return SkColorSetRGB(r, g, b);
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}
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///////////////////////////////////////////////////////////////////////////////
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typedef uint16_t SkPMColor16;
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// Put in OpenGL order (r g b a)
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#define SK_A4444_SHIFT 0
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#define SK_R4444_SHIFT 12
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#define SK_G4444_SHIFT 8
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#define SK_B4444_SHIFT 4
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static inline U8CPU SkReplicateNibble(unsigned nib) {
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SkASSERT(nib <= 0xF);
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return (nib << 4) | nib;
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}
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#define SkGetPackedA4444(c) (((unsigned)(c) >> SK_A4444_SHIFT) & 0xF)
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#define SkGetPackedR4444(c) (((unsigned)(c) >> SK_R4444_SHIFT) & 0xF)
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#define SkGetPackedG4444(c) (((unsigned)(c) >> SK_G4444_SHIFT) & 0xF)
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#define SkGetPackedB4444(c) (((unsigned)(c) >> SK_B4444_SHIFT) & 0xF)
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#define SkPacked4444ToA32(c) SkReplicateNibble(SkGetPackedA4444(c))
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static inline SkPMColor SkPixel4444ToPixel32(U16CPU c) {
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uint32_t d = (SkGetPackedA4444(c) << SK_A32_SHIFT) |
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(SkGetPackedR4444(c) << SK_R32_SHIFT) |
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(SkGetPackedG4444(c) << SK_G32_SHIFT) |
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(SkGetPackedB4444(c) << SK_B32_SHIFT);
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return d | (d << 4);
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}
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static inline Sk4f swizzle_rb(const Sk4f& x) {
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return SkNx_shuffle<2, 1, 0, 3>(x);
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}
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static inline Sk4f swizzle_rb_if_bgra(const Sk4f& x) {
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#ifdef SK_PMCOLOR_IS_BGRA
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return swizzle_rb(x);
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#else
|
|
return x;
|
|
#endif
|
|
}
|
|
|
|
static inline Sk4f Sk4f_fromL32(uint32_t px) {
|
|
return SkNx_cast<float>(Sk4b::Load(&px)) * (1 / 255.0f);
|
|
}
|
|
|
|
static inline uint32_t Sk4f_toL32(const Sk4f& px) {
|
|
Sk4f v = px;
|
|
|
|
#if !defined(SKNX_NO_SIMD) && SK_CPU_SSE_LEVEL >= SK_CPU_SSE_LEVEL_SSE2
|
|
// SkNx_cast<uint8_t, int32_t>() pins, and we don't anticipate giant floats
|
|
#elif !defined(SKNX_NO_SIMD) && defined(SK_ARM_HAS_NEON)
|
|
// SkNx_cast<uint8_t, int32_t>() pins, and so does Sk4f_round().
|
|
#else
|
|
// No guarantee of a pin.
|
|
v = Sk4f::Max(0, Sk4f::Min(v, 1));
|
|
#endif
|
|
|
|
uint32_t l32;
|
|
SkNx_cast<uint8_t>(Sk4f_round(v * 255.0f)).store(&l32);
|
|
return l32;
|
|
}
|
|
|
|
using SkPMColor4f = SkRGBA4f<kPremul_SkAlphaType>;
|
|
|
|
constexpr SkPMColor4f SK_PMColor4fTRANSPARENT = { 0, 0, 0, 0 };
|
|
constexpr SkPMColor4f SK_PMColor4fWHITE = { 1, 1, 1, 1 };
|
|
constexpr SkPMColor4f SK_PMColor4fILLEGAL = { SK_FloatNegativeInfinity,
|
|
SK_FloatNegativeInfinity,
|
|
SK_FloatNegativeInfinity,
|
|
SK_FloatNegativeInfinity };
|
|
|
|
#endif
|