src/opts/SkXfermode_opts.h - skia - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef Sk4pxXfermode_DEFINED
 #define Sk4pxXfermode_DEFINED

 #include "include/private/SkNx.h"
 #include "src/core/Sk4px.h"
 #include "src/core/SkMSAN.h"
 #include "src/core/SkXfermodePriv.h"

 #ifdef SK_FORCE_RASTER_PIPELINE_BLITTER

 namespace SK_OPTS_NS {
     /*not static*/ inline SkXfermode* create_xfermode(SkBlendMode) { return nullptr; }
 }

 #else

 namespace {  // NOLINT(google-build-namespaces)

 // Most xfermodes can be done most efficiently 4 pixels at a time in 8 or 16-bit fixed point.
 #define XFERMODE(Xfermode) \
     struct Xfermode { Sk4px operator()(const Sk4px&, const Sk4px&) const; }; \
     inline Sk4px Xfermode::operator()(const Sk4px& d, const Sk4px& s) const

 XFERMODE(Clear) { return Sk4px::DupPMColor(0); }
 XFERMODE(Src)   { return s; }
 XFERMODE(Dst)   { return d; }
 XFERMODE(SrcIn)   { return     s.approxMulDiv255(d.alphas()      ); }
 XFERMODE(SrcOut)  { return     s.approxMulDiv255(d.alphas().inv()); }
 XFERMODE(SrcOver) { return s + d.approxMulDiv255(s.alphas().inv()); }
 XFERMODE(DstIn)   { return SrcIn  ()(s,d); }
 XFERMODE(DstOut)  { return SrcOut ()(s,d); }
 XFERMODE(DstOver) { return SrcOver()(s,d); }

 // [ S * Da + (1 - Sa) * D]
 XFERMODE(SrcATop) { return (s * d.alphas() + d * s.alphas().inv()).div255(); }
 XFERMODE(DstATop) { return SrcATop()(s,d); }
 //[ S * (1 - Da) + (1 - Sa) * D ]
 XFERMODE(Xor) { return (s * d.alphas().inv() + d * s.alphas().inv()).div255(); }
 // [S + D ]
 XFERMODE(Plus) { return s.saturatedAdd(d); }
 // [S * D ]
 XFERMODE(Modulate) { return s.approxMulDiv255(d); }
 // [S + D - S * D]
 XFERMODE(Screen) {
     // Doing the math as S + (1-S)*D or S + (D - S*D) means the add and subtract can be done
     // in 8-bit space without overflow.  S + (1-S)*D is a touch faster because inv() is cheap.
     return s + d.approxMulDiv255(s.inv());
 }

 #undef XFERMODE

 // A reasonable fallback mode for doing AA is to simply apply the transfermode first,
 // then linearly interpolate the AA.
 template <typename Xfermode>
 static Sk4px xfer_aa(const Sk4px& d, const Sk4px& s, const Sk4px& aa) {
     Sk4px bw = Xfermode()(d, s);
     return (bw * aa + d * aa.inv()).div255();
 }

 // For some transfermodes we specialize AA, either for correctness or performance.
 #define XFERMODE_AA(Xfermode) \
     template <> inline Sk4px xfer_aa<Xfermode>(const Sk4px& d, const Sk4px& s, const Sk4px& aa)

 // Plus' clamp needs to happen after AA.  skia:3852
 XFERMODE_AA(Plus) {  // [ clamp( (1-AA)D + (AA)(S+D) ) == clamp(D + AA*S) ]
     return d.saturatedAdd(s.approxMulDiv255(aa));
 }

 #undef XFERMODE_AA

 // Src and Clear modes are safe to use with uninitialized dst buffers,
 // even if the implementation branches based on bytes from dst (e.g. asserts in Debug mode).
 // For those modes, just lie to MSAN that dst is always intialized.
 template <typename Xfermode> static void mark_dst_initialized_if_safe(void*, void*) {}
 template <> inline void mark_dst_initialized_if_safe<Src>(void* dst, void* end) {
     sk_msan_mark_initialized(dst, end, "Src doesn't read dst.");
 }
 template <> inline void mark_dst_initialized_if_safe<Clear>(void* dst, void* end) {
     sk_msan_mark_initialized(dst, end, "Clear doesn't read dst.");
 }

 template <typename Xfermode>
 class Sk4pxXfermode : public SkXfermode {
 public:
     Sk4pxXfermode() {}

     void xfer32(SkPMColor dst[], const SkPMColor src[], int n, const SkAlpha aa[]) const override {
         mark_dst_initialized_if_safe<Xfermode>(dst, dst+n);
         if (nullptr == aa) {
             Sk4px::MapDstSrc(n, dst, src, Xfermode());
         } else {
             Sk4px::MapDstSrcAlpha(n, dst, src, aa, xfer_aa<Xfermode>);
         }
     }
 };

 } // namespace

 namespace SK_OPTS_NS {

 /*not static*/ inline SkXfermode* create_xfermode(SkBlendMode mode) {
     switch (mode) {
 #define CASE(Xfermode) \
     case SkBlendMode::k##Xfermode: return new Sk4pxXfermode<Xfermode>()
         CASE(Clear);
         CASE(Src);
         CASE(Dst);
         CASE(SrcOver);
         CASE(DstOver);
         CASE(SrcIn);
         CASE(DstIn);
         CASE(SrcOut);
         CASE(DstOut);
         CASE(SrcATop);
         CASE(DstATop);
         CASE(Xor);
         CASE(Plus);
         CASE(Modulate);
         CASE(Screen);
     #undef CASE

         default: break;
     }
     return nullptr;
 }

 } // namespace SK_OPTS_NS

 #endif // #ifdef SK_FORCE_RASTER_PIPELINE_BLITTER

 #endif//Sk4pxXfermode_DEFINED
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef Sk4pxXfermode_DEFINED
	#define Sk4pxXfermode_DEFINED

	#include "include/private/SkNx.h"
	#include "src/core/Sk4px.h"
	#include "src/core/SkMSAN.h"
	#include "src/core/SkXfermodePriv.h"

	#ifdef SK_FORCE_RASTER_PIPELINE_BLITTER

	namespace SK_OPTS_NS {
	/not static/ inline SkXfermode* create_xfermode(SkBlendMode) { return nullptr; }
	}

	#else

	namespace { // NOLINT(google-build-namespaces)

	// Most xfermodes can be done most efficiently 4 pixels at a time in 8 or 16-bit fixed point.
	#define XFERMODE(Xfermode) \
	struct Xfermode { Sk4px operator()(const Sk4px&, const Sk4px&) const; }; \
	inline Sk4px Xfermode::operator()(const Sk4px& d, const Sk4px& s) const

	XFERMODE(Clear) { return Sk4px::DupPMColor(0); }
	XFERMODE(Src) { return s; }
	XFERMODE(Dst) { return d; }
	XFERMODE(SrcIn) { return s.approxMulDiv255(d.alphas() ); }
	XFERMODE(SrcOut) { return s.approxMulDiv255(d.alphas().inv()); }
	XFERMODE(SrcOver) { return s + d.approxMulDiv255(s.alphas().inv()); }
	XFERMODE(DstIn) { return SrcIn ()(s,d); }
	XFERMODE(DstOut) { return SrcOut ()(s,d); }
	XFERMODE(DstOver) { return SrcOver()(s,d); }

	// [ S * Da + (1 - Sa) * D]
	XFERMODE(SrcATop) { return (s * d.alphas() + d * s.alphas().inv()).div255(); }
	XFERMODE(DstATop) { return SrcATop()(s,d); }
	//[ S * (1 - Da) + (1 - Sa) * D ]
	XFERMODE(Xor) { return (s * d.alphas().inv() + d * s.alphas().inv()).div255(); }
	// [S + D ]
	XFERMODE(Plus) { return s.saturatedAdd(d); }
	// [S * D ]
	XFERMODE(Modulate) { return s.approxMulDiv255(d); }
	// [S + D - S * D]
	XFERMODE(Screen) {
	// Doing the math as S + (1-S)D or S + (D - SD) means the add and subtract can be done
	// in 8-bit space without overflow. S + (1-S)*D is a touch faster because inv() is cheap.
	return s + d.approxMulDiv255(s.inv());
	}

	#undef XFERMODE

	// A reasonable fallback mode for doing AA is to simply apply the transfermode first,
	// then linearly interpolate the AA.
	template <typename Xfermode>
	static Sk4px xfer_aa(const Sk4px& d, const Sk4px& s, const Sk4px& aa) {
	Sk4px bw = Xfermode()(d, s);
	return (bw * aa + d * aa.inv()).div255();
	}

	// For some transfermodes we specialize AA, either for correctness or performance.
	#define XFERMODE_AA(Xfermode) \
	template <> inline Sk4px xfer_aa<Xfermode>(const Sk4px& d, const Sk4px& s, const Sk4px& aa)

	// Plus' clamp needs to happen after AA. skia:3852
	XFERMODE_AA(Plus) { // [ clamp( (1-AA)D + (AA)(S+D) ) == clamp(D + AA*S) ]
	return d.saturatedAdd(s.approxMulDiv255(aa));
	}

	#undef XFERMODE_AA

	// Src and Clear modes are safe to use with uninitialized dst buffers,
	// even if the implementation branches based on bytes from dst (e.g. asserts in Debug mode).
	// For those modes, just lie to MSAN that dst is always intialized.
	template <typename Xfermode> static void mark_dst_initialized_if_safe(void, void) {}
	template <> inline void mark_dst_initialized_if_safe<Src>(void* dst, void* end) {
	sk_msan_mark_initialized(dst, end, "Src doesn't read dst.");
	}
	template <> inline void mark_dst_initialized_if_safe<Clear>(void* dst, void* end) {
	sk_msan_mark_initialized(dst, end, "Clear doesn't read dst.");
	}

	template <typename Xfermode>
	class Sk4pxXfermode : public SkXfermode {
	public:
	Sk4pxXfermode() {}

	void xfer32(SkPMColor dst[], const SkPMColor src[], int n, const SkAlpha aa[]) const override {
	mark_dst_initialized_if_safe<Xfermode>(dst, dst+n);
	if (nullptr == aa) {
	Sk4px::MapDstSrc(n, dst, src, Xfermode());
	} else {
	Sk4px::MapDstSrcAlpha(n, dst, src, aa, xfer_aa<Xfermode>);
	}
	}
	};

	} // namespace

	namespace SK_OPTS_NS {

	/not static/ inline SkXfermode* create_xfermode(SkBlendMode mode) {
	switch (mode) {
	#define CASE(Xfermode) \
	case SkBlendMode::k##Xfermode: return new Sk4pxXfermode<Xfermode>()
	CASE(Clear);
	CASE(Src);
	CASE(Dst);
	CASE(SrcOver);
	CASE(DstOver);
	CASE(SrcIn);
	CASE(DstIn);
	CASE(SrcOut);
	CASE(DstOut);
	CASE(SrcATop);
	CASE(DstATop);
	CASE(Xor);
	CASE(Plus);
	CASE(Modulate);
	CASE(Screen);
	#undef CASE

	default: break;
	}
	return nullptr;
	}

	} // namespace SK_OPTS_NS

	#endif // #ifdef SK_FORCE_RASTER_PIPELINE_BLITTER

	#endif//Sk4pxXfermode_DEFINED