src/core/SkRasterPipelineBlitter.cpp - skia - Git at Google

 /*
  * Copyright 2016 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "include/core/SkColor.h"
 #include "include/core/SkColorFilter.h"
 #include "include/core/SkPaint.h"
 #include "include/core/SkShader.h"
 #include "include/private/SkTo.h"
 #include "src/core/SkArenaAlloc.h"
 #include "src/core/SkBlendModePriv.h"
 #include "src/core/SkBlitter.h"
 #include "src/core/SkColorSpacePriv.h"
 #include "src/core/SkColorSpaceXformSteps.h"
 #include "src/core/SkOpts.h"
 #include "src/core/SkRasterPipeline.h"
 #include "src/core/SkUtils.h"
 #include "src/shaders/SkShaderBase.h"

 class SkRasterPipelineBlitter final : public SkBlitter {
 public:
     // This is our common entrypoint for creating the blitter once we've sorted out shaders.
     static SkBlitter* Create(const SkPixmap&, const SkPaint&, SkArenaAlloc*,
                              const SkRasterPipeline& shaderPipeline,
                              bool is_opaque, bool is_constant);

     SkRasterPipelineBlitter(SkPixmap dst,
                             SkBlendMode blend,
                             SkArenaAlloc* alloc)
         : fDst(dst)
         , fBlend(blend)
         , fAlloc(alloc)
         , fColorPipeline(alloc)
     {}

     void blitH     (int x, int y, int w)                            override;
     void blitAntiH (int x, int y, const SkAlpha[], const int16_t[]) override;
     void blitAntiH2(int x, int y, U8CPU a0, U8CPU a1)               override;
     void blitAntiV2(int x, int y, U8CPU a0, U8CPU a1)               override;
     void blitMask  (const SkMask&, const SkIRect& clip)             override;
     void blitRect  (int x, int y, int width, int height)            override;
     void blitV     (int x, int y, int height, SkAlpha alpha)        override;

 private:
     void append_load_dst      (SkRasterPipeline*) const;
     void append_store         (SkRasterPipeline*) const;

     SkPixmap               fDst;
     SkBlendMode            fBlend;
     SkArenaAlloc*          fAlloc;
     SkRasterPipeline       fColorPipeline;

     SkRasterPipeline_MemoryCtx
         fDstPtr       = {nullptr,0},  // Always points to the top-left of fDst.
         fMaskPtr      = {nullptr,0};  // Updated each call to blitMask().
     SkRasterPipeline_EmbossCtx fEmbossCtx;  // Used only for k3D_Format masks.

     // We may be able to specialize blitH() or blitRect() into a memset.
     void   (*fMemset2D)(SkPixmap*, int x,int y, int w,int h, uint64_t color) = nullptr;
     uint64_t fMemsetColor = 0;   // Big enough for largest memsettable dst format, F16.

     // Built lazily on first use.
     std::function<void(size_t, size_t, size_t, size_t)> fBlitRect,
                                                         fBlitAntiH,
                                                         fBlitMaskA8,
                                                         fBlitMaskLCD16,
                                                         fBlitMask3D;

     // These values are pointed to by the blit pipelines above,
     // which allows us to adjust them from call to call.
     float fCurrentCoverage = 0.0f;
     float fDitherRate      = 0.0f;

     typedef SkBlitter INHERITED;
 };

 SkBlitter* SkCreateRasterPipelineBlitter(const SkPixmap& dst,
                                          const SkPaint& paint,
                                          const SkMatrix& ctm,
                                          SkArenaAlloc* alloc) {
     // For legacy to keep working, we need to sometimes still distinguish null dstCS from sRGB.
 #if 0
     SkColorSpace* dstCS = dst.colorSpace() ? dst.colorSpace()
                                            : sk_srgb_singleton();
 #else
     SkColorSpace* dstCS = dst.colorSpace();
 #endif
     SkColorType dstCT = dst.colorType();
     SkColor4f paintColor = paint.getColor4f();
     SkColorSpaceXformSteps(sk_srgb_singleton(), kUnpremul_SkAlphaType,
                            dstCS,               kUnpremul_SkAlphaType).apply(paintColor.vec());

     auto shader = as_SB(paint.getShader());

     SkRasterPipeline_<256> shaderPipeline;
     if (!shader) {
         // Having no shader makes things nice and easy... just use the paint color.
         shaderPipeline.append_constant_color(alloc, paintColor.premul().vec());
         bool is_opaque    = paintColor.fA == 1.0f,
              is_constant  = true;
         return SkRasterPipelineBlitter::Create(dst, paint, alloc,
                                                shaderPipeline, is_opaque, is_constant);
     }

     bool is_opaque    = shader->isOpaque() && paintColor.fA == 1.0f;
     bool is_constant  = shader->isConstant();

     if (shader->appendStages({&shaderPipeline, alloc, dstCT, dstCS, paint, nullptr, ctm})) {
         if (paintColor.fA != 1.0f) {
             shaderPipeline.append(SkRasterPipeline::scale_1_float,
                                   alloc->make<float>(paintColor.fA));
         }
         return SkRasterPipelineBlitter::Create(dst, paint, alloc,
                                                shaderPipeline, is_opaque, is_constant);
     }

     // The shader has opted out of drawing anything.
     return alloc->make<SkNullBlitter>();
 }

 SkBlitter* SkCreateRasterPipelineBlitter(const SkPixmap& dst,
                                          const SkPaint& paint,
                                          const SkRasterPipeline& shaderPipeline,
                                          bool is_opaque,
                                          SkArenaAlloc* alloc) {
     bool is_constant = false;  // If this were the case, it'd be better to just set a paint color.
     return SkRasterPipelineBlitter::Create(dst, paint, alloc,
                                            shaderPipeline, is_opaque, is_constant);
 }

 SkBlitter* SkRasterPipelineBlitter::Create(const SkPixmap& dst,
                                            const SkPaint& paint,
                                            SkArenaAlloc* alloc,
                                            const SkRasterPipeline& shaderPipeline,
                                            bool is_opaque,
                                            bool is_constant) {
     auto blitter = alloc->make<SkRasterPipelineBlitter>(dst,
                                                         paint.getBlendMode(),
                                                         alloc);

     // Our job in this factory is to fill out the blitter's color pipeline.
     // This is the common front of the full blit pipelines, each constructed lazily on first use.
     // The full blit pipelines handle reading and writing the dst, blending, coverage, dithering.
     auto colorPipeline = &blitter->fColorPipeline;

     // Let's get the shader in first.
     colorPipeline->extend(shaderPipeline);

     // If there's a color filter it comes next.
     if (auto colorFilter = paint.getColorFilter()) {
         SkStageRec rec = {
             colorPipeline, alloc, dst.colorType(), dst.colorSpace(), paint, nullptr, SkMatrix::I()
         };
         colorFilter->appendStages(rec, is_opaque);
         is_opaque = is_opaque && (colorFilter->getFlags() & SkColorFilter::kAlphaUnchanged_Flag);
     }

     // Not all formats make sense to dither (think, F16).  We set their dither rate
     // to zero.  We need to decide if we're going to dither now to keep is_constant accurate.
     if (paint.isDither()) {
         switch (dst.info().colorType()) {
             default:                        blitter->fDitherRate =      0.0f; break;
             case kARGB_4444_SkColorType:    blitter->fDitherRate =   1/15.0f; break;
             case   kRGB_565_SkColorType:    blitter->fDitherRate =   1/63.0f; break;
             case    kGray_8_SkColorType:
             case  kRGB_888x_SkColorType:
             case kRGBA_8888_SkColorType:
             case kBGRA_8888_SkColorType:    blitter->fDitherRate =  1/255.0f; break;
             case kRGB_101010x_SkColorType:
             case kRGBA_1010102_SkColorType: blitter->fDitherRate = 1/1023.0f; break;
         }
         // TODO: for constant colors, we could try to measure the effect of dithering, and if
         //       it has no value (i.e. all variations result in the same 32bit color, then we
         //       could disable it (for speed, by not adding the stage).
     }
     is_constant = is_constant && (blitter->fDitherRate == 0.0f);

     // We're logically done here.  The code between here and return blitter is all optimization.

     // A pipeline that's still constant here can collapse back into a constant color.
     if (is_constant) {
         SkColor4f constantColor;
         SkRasterPipeline_MemoryCtx constantColorPtr = { &constantColor, 0 };
         colorPipeline->append_gamut_clamp_if_normalized(dst.info());
         colorPipeline->append(SkRasterPipeline::store_f32, &constantColorPtr);
         colorPipeline->run(0,0,1,1);
         colorPipeline->reset();
         colorPipeline->append_constant_color(alloc, constantColor);

         is_opaque = constantColor.fA == 1.0f;
     }

     // We can strength-reduce SrcOver into Src when opaque.
     if (is_opaque && blitter->fBlend == SkBlendMode::kSrcOver) {
         blitter->fBlend = SkBlendMode::kSrc;
     }

     // When we're drawing a constant color in Src mode, we can sometimes just memset.
     // (The previous two optimizations help find more opportunities for this one.)
     if (is_constant && blitter->fBlend == SkBlendMode::kSrc) {
         // Run our color pipeline all the way through to produce what we'd memset when we can.
         // Not all blits can memset, so we need to keep colorPipeline too.
         SkRasterPipeline_<256> p;
         p.extend(*colorPipeline);
         p.append_gamut_clamp_if_normalized(dst.info());
         blitter->fDstPtr = SkRasterPipeline_MemoryCtx{&blitter->fMemsetColor, 0};
         blitter->append_store(&p);
         p.run(0,0,1,1);

         switch (blitter->fDst.shiftPerPixel()) {
             case 0: blitter->fMemset2D = [](SkPixmap* dst, int x,int y, int w,int h, uint64_t c) {
                 void* p = dst->writable_addr(x,y);
                 while (h --> 0) {
                     memset(p, c, w);
                     p = SkTAddOffset<void>(p, dst->rowBytes());
                 }
             }; break;

             case 1: blitter->fMemset2D = [](SkPixmap* dst, int x,int y, int w,int h, uint64_t c) {
                 SkOpts::rect_memset16(dst->writable_addr16(x,y), c, w, dst->rowBytes(), h);
             }; break;

             case 2: blitter->fMemset2D = [](SkPixmap* dst, int x,int y, int w,int h, uint64_t c) {
                 SkOpts::rect_memset32(dst->writable_addr32(x,y), c, w, dst->rowBytes(), h);
             }; break;

             case 3: blitter->fMemset2D = [](SkPixmap* dst, int x,int y, int w,int h, uint64_t c) {
                 SkOpts::rect_memset64(dst->writable_addr64(x,y), c, w, dst->rowBytes(), h);
             }; break;

             // TODO(F32)?
         }
     }

     blitter->fDstPtr = SkRasterPipeline_MemoryCtx{
         blitter->fDst.writable_addr(),
         blitter->fDst.rowBytesAsPixels(),
     };

     return blitter;
 }

 void SkRasterPipelineBlitter::append_load_dst(SkRasterPipeline* p) const {
     p->append_load_dst(fDst.info().colorType(), &fDstPtr);
     if (fDst.info().alphaType() == kUnpremul_SkAlphaType) {
         p->append(SkRasterPipeline::premul_dst);
     }
 }

 void SkRasterPipelineBlitter::append_store(SkRasterPipeline* p) const {
     if (fDst.info().alphaType() == kUnpremul_SkAlphaType) {
         p->append(SkRasterPipeline::unpremul);
     }
     if (fDitherRate > 0.0f) {
         p->append(SkRasterPipeline::dither, &fDitherRate);
     }

     p->append_store(fDst.info().colorType(), &fDstPtr);
 }

 void SkRasterPipelineBlitter::blitH(int x, int y, int w) {
     this->blitRect(x,y,w,1);
 }

 void SkRasterPipelineBlitter::blitRect(int x, int y, int w, int h) {
     if (fMemset2D) {
         fMemset2D(&fDst, x,y, w,h, fMemsetColor);
         return;
     }

     if (!fBlitRect) {
         SkRasterPipeline p(fAlloc);
         p.extend(fColorPipeline);
         p.append_gamut_clamp_if_normalized(fDst.info());
         if (fBlend == SkBlendMode::kSrcOver
                 && (fDst.info().colorType() == kRGBA_8888_SkColorType ||
                     fDst.info().colorType() == kBGRA_8888_SkColorType)
                 && !fDst.colorSpace()
                 && fDst.info().alphaType() != kUnpremul_SkAlphaType
                 && fDitherRate == 0.0f) {
             if (fDst.info().colorType() == kBGRA_8888_SkColorType) {
                 p.append(SkRasterPipeline::swap_rb);
             }
             p.append(SkRasterPipeline::srcover_rgba_8888, &fDstPtr);
         } else {
             if (fBlend != SkBlendMode::kSrc) {
                 this->append_load_dst(&p);
                 SkBlendMode_AppendStages(fBlend, &p);
             }
             this->append_store(&p);
         }
         fBlitRect = p.compile();
     }

     fBlitRect(x,y,w,h);
 }

 void SkRasterPipelineBlitter::blitAntiH(int x, int y, const SkAlpha aa[], const int16_t runs[]) {
     if (!fBlitAntiH) {
         SkRasterPipeline p(fAlloc);
         p.extend(fColorPipeline);
         p.append_gamut_clamp_if_normalized(fDst.info());
         if (SkBlendMode_ShouldPreScaleCoverage(fBlend, /*rgb_coverage=*/false)) {
             p.append(SkRasterPipeline::scale_1_float, &fCurrentCoverage);
             this->append_load_dst(&p);
             SkBlendMode_AppendStages(fBlend, &p);
         } else {
             this->append_load_dst(&p);
             SkBlendMode_AppendStages(fBlend, &p);
             p.append(SkRasterPipeline::lerp_1_float, &fCurrentCoverage);
         }

         this->append_store(&p);
         fBlitAntiH = p.compile();
     }

     for (int16_t run = *runs; run > 0; run = *runs) {
         switch (*aa) {
             case 0x00:                       break;
             case 0xff: this->blitH(x,y,run); break;
             default:
                 fCurrentCoverage = *aa * (1/255.0f);
                 fBlitAntiH(x,y,run,1);
         }
         x    += run;
         runs += run;
         aa   += run;
     }
 }

 void SkRasterPipelineBlitter::blitAntiH2(int x, int y, U8CPU a0, U8CPU a1) {
     SkIRect clip = {x,y, x+2,y+1};
     uint8_t coverage[] = { (uint8_t)a0, (uint8_t)a1 };

     SkMask mask;
     mask.fImage    = coverage;
     mask.fBounds   = clip;
     mask.fRowBytes = 2;
     mask.fFormat   = SkMask::kA8_Format;

     this->blitMask(mask, clip);
 }

 void SkRasterPipelineBlitter::blitAntiV2(int x, int y, U8CPU a0, U8CPU a1) {
     SkIRect clip = {x,y, x+1,y+2};
     uint8_t coverage[] = { (uint8_t)a0, (uint8_t)a1 };

     SkMask mask;
     mask.fImage    = coverage;
     mask.fBounds   = clip;
     mask.fRowBytes = 1;
     mask.fFormat   = SkMask::kA8_Format;

     this->blitMask(mask, clip);
 }

 void SkRasterPipelineBlitter::blitV(int x, int y, int height, SkAlpha alpha) {
     SkIRect clip = {x,y, x+1,y+height};

     SkMask mask;
     mask.fImage    = &alpha;
     mask.fBounds   = clip;
     mask.fRowBytes = 0;     // so we reuse the 1 "row" for all of height
     mask.fFormat   = SkMask::kA8_Format;

     this->blitMask(mask, clip);
 }

 void SkRasterPipelineBlitter::blitMask(const SkMask& mask, const SkIRect& clip) {
     if (mask.fFormat == SkMask::kBW_Format) {
         // TODO: native BW masks?
         return INHERITED::blitMask(mask, clip);
     }

     // ARGB and SDF masks shouldn't make it here.
     SkASSERT(mask.fFormat == SkMask::kA8_Format
           || mask.fFormat == SkMask::kLCD16_Format
           || mask.fFormat == SkMask::k3D_Format);

     auto extract_mask_plane = [&mask](int plane, SkRasterPipeline_MemoryCtx* ctx) {
         // LCD is 16-bit per pixel; A8 and 3D are 8-bit per pixel.
         size_t bpp = mask.fFormat == SkMask::kLCD16_Format ? 2 : 1;

         // Select the right mask plane.  Usually plane == 0 and this is just mask.fImage.
         auto ptr = (uintptr_t)mask.fImage
                  + plane * mask.computeImageSize();

         // Update ctx to point "into" this current mask, but lined up with fDstPtr at (0,0).
         // This sort of trickery upsets UBSAN (pointer-overflow) so our ptr must be a uintptr_t.
         // mask.fRowBytes is a uint32_t, which would break our addressing math on 64-bit builds.
         size_t rowBytes = mask.fRowBytes;
         ctx->stride = rowBytes / bpp;
         ctx->pixels = (void*)(ptr - mask.fBounds.left() * bpp
                                   - mask.fBounds.top()  * rowBytes);
     };

     extract_mask_plane(0, &fMaskPtr);
     if (mask.fFormat == SkMask::k3D_Format) {
         extract_mask_plane(1, &fEmbossCtx.mul);
         extract_mask_plane(2, &fEmbossCtx.add);
     }

     // Lazily build whichever pipeline we need, specialized for each mask format.
     if (mask.fFormat == SkMask::kA8_Format && !fBlitMaskA8) {
         SkRasterPipeline p(fAlloc);
         p.extend(fColorPipeline);
         p.append_gamut_clamp_if_normalized(fDst.info());
         if (SkBlendMode_ShouldPreScaleCoverage(fBlend, /*rgb_coverage=*/false)) {
             p.append(SkRasterPipeline::scale_u8, &fMaskPtr);
             this->append_load_dst(&p);
             SkBlendMode_AppendStages(fBlend, &p);
         } else {
             this->append_load_dst(&p);
             SkBlendMode_AppendStages(fBlend, &p);
             p.append(SkRasterPipeline::lerp_u8, &fMaskPtr);
         }
         this->append_store(&p);
         fBlitMaskA8 = p.compile();
     }
     if (mask.fFormat == SkMask::kLCD16_Format && !fBlitMaskLCD16) {
         SkRasterPipeline p(fAlloc);
         p.extend(fColorPipeline);
         p.append_gamut_clamp_if_normalized(fDst.info());
         if (SkBlendMode_ShouldPreScaleCoverage(fBlend, /*rgb_coverage=*/true)) {
             // Somewhat unusually, scale_565 needs dst loaded first.
             this->append_load_dst(&p);
             p.append(SkRasterPipeline::scale_565, &fMaskPtr);
             SkBlendMode_AppendStages(fBlend, &p);
         } else {
             this->append_load_dst(&p);
             SkBlendMode_AppendStages(fBlend, &p);
             p.append(SkRasterPipeline::lerp_565, &fMaskPtr);
         }
         this->append_store(&p);
         fBlitMaskLCD16 = p.compile();
     }
     if (mask.fFormat == SkMask::k3D_Format && !fBlitMask3D) {
         SkRasterPipeline p(fAlloc);
         p.extend(fColorPipeline);
         // This bit is where we differ from kA8_Format:
         p.append(SkRasterPipeline::emboss, &fEmbossCtx);
         // Now onward just as kA8.
         p.append_gamut_clamp_if_normalized(fDst.info());
         if (SkBlendMode_ShouldPreScaleCoverage(fBlend, /*rgb_coverage=*/false)) {
             p.append(SkRasterPipeline::scale_u8, &fMaskPtr);
             this->append_load_dst(&p);
             SkBlendMode_AppendStages(fBlend, &p);
         } else {
             this->append_load_dst(&p);
             SkBlendMode_AppendStages(fBlend, &p);
             p.append(SkRasterPipeline::lerp_u8, &fMaskPtr);
         }
         this->append_store(&p);
         fBlitMask3D = p.compile();
     }

     std::function<void(size_t,size_t,size_t,size_t)>* blitter = nullptr;
     switch (mask.fFormat) {
         case SkMask::kA8_Format:    blitter = &fBlitMaskA8;    break;
         case SkMask::kLCD16_Format: blitter = &fBlitMaskLCD16; break;
         case SkMask::k3D_Format:    blitter = &fBlitMask3D;    break;
         default:
             SkASSERT(false);
             return;
     }

     SkASSERT(blitter);
     (*blitter)(clip.left(),clip.top(), clip.width(),clip.height());
 }
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/core/SkColor.h"
	#include "include/core/SkColorFilter.h"
	#include "include/core/SkPaint.h"
	#include "include/core/SkShader.h"
	#include "include/private/SkTo.h"
	#include "src/core/SkArenaAlloc.h"
	#include "src/core/SkBlendModePriv.h"
	#include "src/core/SkBlitter.h"
	#include "src/core/SkColorSpacePriv.h"
	#include "src/core/SkColorSpaceXformSteps.h"
	#include "src/core/SkOpts.h"
	#include "src/core/SkRasterPipeline.h"
	#include "src/core/SkUtils.h"
	#include "src/shaders/SkShaderBase.h"

	class SkRasterPipelineBlitter final : public SkBlitter {
	public:
	// This is our common entrypoint for creating the blitter once we've sorted out shaders.
	static SkBlitter* Create(const SkPixmap&, const SkPaint&, SkArenaAlloc*,
	const SkRasterPipeline& shaderPipeline,
	bool is_opaque, bool is_constant);

	SkRasterPipelineBlitter(SkPixmap dst,
	SkBlendMode blend,
	SkArenaAlloc* alloc)
	: fDst(dst)
	, fBlend(blend)
	, fAlloc(alloc)
	, fColorPipeline(alloc)
	{}

	void blitH (int x, int y, int w) override;
	void blitAntiH (int x, int y, const SkAlpha[], const int16_t[]) override;
	void blitAntiH2(int x, int y, U8CPU a0, U8CPU a1) override;
	void blitAntiV2(int x, int y, U8CPU a0, U8CPU a1) override;
	void blitMask (const SkMask&, const SkIRect& clip) override;
	void blitRect (int x, int y, int width, int height) override;
	void blitV (int x, int y, int height, SkAlpha alpha) override;

	private:
	void append_load_dst (SkRasterPipeline*) const;
	void append_store (SkRasterPipeline*) const;

	SkPixmap fDst;
	SkBlendMode fBlend;
	SkArenaAlloc* fAlloc;
	SkRasterPipeline fColorPipeline;

	SkRasterPipeline_MemoryCtx
	fDstPtr = {nullptr,0}, // Always points to the top-left of fDst.
	fMaskPtr = {nullptr,0}; // Updated each call to blitMask().
	SkRasterPipeline_EmbossCtx fEmbossCtx; // Used only for k3D_Format masks.

	// We may be able to specialize blitH() or blitRect() into a memset.
	void (fMemset2D)(SkPixmap, int x,int y, int w,int h, uint64_t color) = nullptr;
	uint64_t fMemsetColor = 0; // Big enough for largest memsettable dst format, F16.

	// Built lazily on first use.
	std::function<void(size_t, size_t, size_t, size_t)> fBlitRect,
	fBlitAntiH,
	fBlitMaskA8,
	fBlitMaskLCD16,
	fBlitMask3D;

	// These values are pointed to by the blit pipelines above,
	// which allows us to adjust them from call to call.
	float fCurrentCoverage = 0.0f;
	float fDitherRate = 0.0f;

	typedef SkBlitter INHERITED;
	};

	SkBlitter* SkCreateRasterPipelineBlitter(const SkPixmap& dst,
	const SkPaint& paint,
	const SkMatrix& ctm,
	SkArenaAlloc* alloc) {
	// For legacy to keep working, we need to sometimes still distinguish null dstCS from sRGB.
	#if 0
	SkColorSpace* dstCS = dst.colorSpace() ? dst.colorSpace()
	: sk_srgb_singleton();
	#else
	SkColorSpace* dstCS = dst.colorSpace();
	#endif
	SkColorType dstCT = dst.colorType();
	SkColor4f paintColor = paint.getColor4f();
	SkColorSpaceXformSteps(sk_srgb_singleton(), kUnpremul_SkAlphaType,
	dstCS, kUnpremul_SkAlphaType).apply(paintColor.vec());

	auto shader = as_SB(paint.getShader());

	SkRasterPipeline_<256> shaderPipeline;
	if (!shader) {
	// Having no shader makes things nice and easy... just use the paint color.
	shaderPipeline.append_constant_color(alloc, paintColor.premul().vec());
	bool is_opaque = paintColor.fA == 1.0f,
	is_constant = true;
	return SkRasterPipelineBlitter::Create(dst, paint, alloc,
	shaderPipeline, is_opaque, is_constant);
	}

	bool is_opaque = shader->isOpaque() && paintColor.fA == 1.0f;
	bool is_constant = shader->isConstant();

	if (shader->appendStages({&shaderPipeline, alloc, dstCT, dstCS, paint, nullptr, ctm})) {
	if (paintColor.fA != 1.0f) {
	shaderPipeline.append(SkRasterPipeline::scale_1_float,
	alloc->make<float>(paintColor.fA));
	}
	return SkRasterPipelineBlitter::Create(dst, paint, alloc,
	shaderPipeline, is_opaque, is_constant);
	}

	// The shader has opted out of drawing anything.
	return alloc->make<SkNullBlitter>();
	}

	SkBlitter* SkCreateRasterPipelineBlitter(const SkPixmap& dst,
	const SkPaint& paint,
	const SkRasterPipeline& shaderPipeline,
	bool is_opaque,
	SkArenaAlloc* alloc) {
	bool is_constant = false; // If this were the case, it'd be better to just set a paint color.
	return SkRasterPipelineBlitter::Create(dst, paint, alloc,
	shaderPipeline, is_opaque, is_constant);
	}

	SkBlitter* SkRasterPipelineBlitter::Create(const SkPixmap& dst,
	const SkPaint& paint,
	SkArenaAlloc* alloc,
	const SkRasterPipeline& shaderPipeline,
	bool is_opaque,
	bool is_constant) {
	auto blitter = alloc->make<SkRasterPipelineBlitter>(dst,
	paint.getBlendMode(),
	alloc);

	// Our job in this factory is to fill out the blitter's color pipeline.
	// This is the common front of the full blit pipelines, each constructed lazily on first use.
	// The full blit pipelines handle reading and writing the dst, blending, coverage, dithering.
	auto colorPipeline = &blitter->fColorPipeline;

	// Let's get the shader in first.
	colorPipeline->extend(shaderPipeline);

	// If there's a color filter it comes next.
	if (auto colorFilter = paint.getColorFilter()) {
	SkStageRec rec = {
	colorPipeline, alloc, dst.colorType(), dst.colorSpace(), paint, nullptr, SkMatrix::I()
	};
	colorFilter->appendStages(rec, is_opaque);
	is_opaque = is_opaque && (colorFilter->getFlags() & SkColorFilter::kAlphaUnchanged_Flag);
	}

	// Not all formats make sense to dither (think, F16). We set their dither rate
	// to zero. We need to decide if we're going to dither now to keep is_constant accurate.
	if (paint.isDither()) {
	switch (dst.info().colorType()) {
	default: blitter->fDitherRate = 0.0f; break;
	case kARGB_4444_SkColorType: blitter->fDitherRate = 1/15.0f; break;
	case kRGB_565_SkColorType: blitter->fDitherRate = 1/63.0f; break;
	case kGray_8_SkColorType:
	case kRGB_888x_SkColorType:
	case kRGBA_8888_SkColorType:
	case kBGRA_8888_SkColorType: blitter->fDitherRate = 1/255.0f; break;
	case kRGB_101010x_SkColorType:
	case kRGBA_1010102_SkColorType: blitter->fDitherRate = 1/1023.0f; break;
	}
	// TODO: for constant colors, we could try to measure the effect of dithering, and if
	// it has no value (i.e. all variations result in the same 32bit color, then we
	// could disable it (for speed, by not adding the stage).
	}
	is_constant = is_constant && (blitter->fDitherRate == 0.0f);

	// We're logically done here. The code between here and return blitter is all optimization.

	// A pipeline that's still constant here can collapse back into a constant color.
	if (is_constant) {
	SkColor4f constantColor;
	SkRasterPipeline_MemoryCtx constantColorPtr = { &constantColor, 0 };
	colorPipeline->append_gamut_clamp_if_normalized(dst.info());
	colorPipeline->append(SkRasterPipeline::store_f32, &constantColorPtr);
	colorPipeline->run(0,0,1,1);
	colorPipeline->reset();
	colorPipeline->append_constant_color(alloc, constantColor);

	is_opaque = constantColor.fA == 1.0f;
	}

	// We can strength-reduce SrcOver into Src when opaque.
	if (is_opaque && blitter->fBlend == SkBlendMode::kSrcOver) {
	blitter->fBlend = SkBlendMode::kSrc;
	}

	// When we're drawing a constant color in Src mode, we can sometimes just memset.
	// (The previous two optimizations help find more opportunities for this one.)
	if (is_constant && blitter->fBlend == SkBlendMode::kSrc) {
	// Run our color pipeline all the way through to produce what we'd memset when we can.
	// Not all blits can memset, so we need to keep colorPipeline too.
	SkRasterPipeline_<256> p;
	p.extend(*colorPipeline);
	p.append_gamut_clamp_if_normalized(dst.info());
	blitter->fDstPtr = SkRasterPipeline_MemoryCtx{&blitter->fMemsetColor, 0};
	blitter->append_store(&p);
	p.run(0,0,1,1);

	switch (blitter->fDst.shiftPerPixel()) {
	case 0: blitter->fMemset2D = [](SkPixmap* dst, int x,int y, int w,int h, uint64_t c) {
	void* p = dst->writable_addr(x,y);
	while (h --> 0) {
	memset(p, c, w);
	p = SkTAddOffset<void>(p, dst->rowBytes());
	}
	}; break;

	case 1: blitter->fMemset2D = [](SkPixmap* dst, int x,int y, int w,int h, uint64_t c) {
	SkOpts::rect_memset16(dst->writable_addr16(x,y), c, w, dst->rowBytes(), h);
	}; break;

	case 2: blitter->fMemset2D = [](SkPixmap* dst, int x,int y, int w,int h, uint64_t c) {
	SkOpts::rect_memset32(dst->writable_addr32(x,y), c, w, dst->rowBytes(), h);
	}; break;

	case 3: blitter->fMemset2D = [](SkPixmap* dst, int x,int y, int w,int h, uint64_t c) {
	SkOpts::rect_memset64(dst->writable_addr64(x,y), c, w, dst->rowBytes(), h);
	}; break;

	// TODO(F32)?
	}
	}

	blitter->fDstPtr = SkRasterPipeline_MemoryCtx{
	blitter->fDst.writable_addr(),
	blitter->fDst.rowBytesAsPixels(),
	};

	return blitter;
	}

	void SkRasterPipelineBlitter::append_load_dst(SkRasterPipeline* p) const {
	p->append_load_dst(fDst.info().colorType(), &fDstPtr);
	if (fDst.info().alphaType() == kUnpremul_SkAlphaType) {
	p->append(SkRasterPipeline::premul_dst);
	}
	}

	void SkRasterPipelineBlitter::append_store(SkRasterPipeline* p) const {
	if (fDst.info().alphaType() == kUnpremul_SkAlphaType) {
	p->append(SkRasterPipeline::unpremul);
	}
	if (fDitherRate > 0.0f) {
	p->append(SkRasterPipeline::dither, &fDitherRate);
	}

	p->append_store(fDst.info().colorType(), &fDstPtr);
	}

	void SkRasterPipelineBlitter::blitH(int x, int y, int w) {
	this->blitRect(x,y,w,1);
	}

	void SkRasterPipelineBlitter::blitRect(int x, int y, int w, int h) {
	if (fMemset2D) {
	fMemset2D(&fDst, x,y, w,h, fMemsetColor);
	return;
	}

	if (!fBlitRect) {
	SkRasterPipeline p(fAlloc);
	p.extend(fColorPipeline);
	p.append_gamut_clamp_if_normalized(fDst.info());
	if (fBlend == SkBlendMode::kSrcOver
	&& (fDst.info().colorType() == kRGBA_8888_SkColorType \|\|
	fDst.info().colorType() == kBGRA_8888_SkColorType)
	&& !fDst.colorSpace()
	&& fDst.info().alphaType() != kUnpremul_SkAlphaType
	&& fDitherRate == 0.0f) {
	if (fDst.info().colorType() == kBGRA_8888_SkColorType) {
	p.append(SkRasterPipeline::swap_rb);
	}
	p.append(SkRasterPipeline::srcover_rgba_8888, &fDstPtr);
	} else {
	if (fBlend != SkBlendMode::kSrc) {
	this->append_load_dst(&p);
	SkBlendMode_AppendStages(fBlend, &p);
	}
	this->append_store(&p);
	}
	fBlitRect = p.compile();
	}

	fBlitRect(x,y,w,h);
	}

	void SkRasterPipelineBlitter::blitAntiH(int x, int y, const SkAlpha aa[], const int16_t runs[]) {
	if (!fBlitAntiH) {
	SkRasterPipeline p(fAlloc);
	p.extend(fColorPipeline);
	p.append_gamut_clamp_if_normalized(fDst.info());
	if (SkBlendMode_ShouldPreScaleCoverage(fBlend, /rgb_coverage=/false)) {
	p.append(SkRasterPipeline::scale_1_float, &fCurrentCoverage);
	this->append_load_dst(&p);
	SkBlendMode_AppendStages(fBlend, &p);
	} else {
	this->append_load_dst(&p);
	SkBlendMode_AppendStages(fBlend, &p);
	p.append(SkRasterPipeline::lerp_1_float, &fCurrentCoverage);
	}

	this->append_store(&p);
	fBlitAntiH = p.compile();
	}

	for (int16_t run = runs; run > 0; run = runs) {
	switch (*aa) {
	case 0x00: break;
	case 0xff: this->blitH(x,y,run); break;
	default:
	fCurrentCoverage = aa (1/255.0f);
	fBlitAntiH(x,y,run,1);
	}
	x += run;
	runs += run;
	aa += run;
	}
	}

	void SkRasterPipelineBlitter::blitAntiH2(int x, int y, U8CPU a0, U8CPU a1) {
	SkIRect clip = {x,y, x+2,y+1};
	uint8_t coverage[] = { (uint8_t)a0, (uint8_t)a1 };

	SkMask mask;
	mask.fImage = coverage;
	mask.fBounds = clip;
	mask.fRowBytes = 2;
	mask.fFormat = SkMask::kA8_Format;

	this->blitMask(mask, clip);
	}

	void SkRasterPipelineBlitter::blitAntiV2(int x, int y, U8CPU a0, U8CPU a1) {
	SkIRect clip = {x,y, x+1,y+2};
	uint8_t coverage[] = { (uint8_t)a0, (uint8_t)a1 };

	SkMask mask;
	mask.fImage = coverage;
	mask.fBounds = clip;
	mask.fRowBytes = 1;
	mask.fFormat = SkMask::kA8_Format;

	this->blitMask(mask, clip);
	}

	void SkRasterPipelineBlitter::blitV(int x, int y, int height, SkAlpha alpha) {
	SkIRect clip = {x,y, x+1,y+height};

	SkMask mask;
	mask.fImage = α
	mask.fBounds = clip;
	mask.fRowBytes = 0; // so we reuse the 1 "row" for all of height
	mask.fFormat = SkMask::kA8_Format;

	this->blitMask(mask, clip);
	}

	void SkRasterPipelineBlitter::blitMask(const SkMask& mask, const SkIRect& clip) {
	if (mask.fFormat == SkMask::kBW_Format) {
	// TODO: native BW masks?
	return INHERITED::blitMask(mask, clip);
	}

	// ARGB and SDF masks shouldn't make it here.
	SkASSERT(mask.fFormat == SkMask::kA8_Format
	\|\| mask.fFormat == SkMask::kLCD16_Format
	\|\| mask.fFormat == SkMask::k3D_Format);

	auto extract_mask_plane = [&mask](int plane, SkRasterPipeline_MemoryCtx* ctx) {
	// LCD is 16-bit per pixel; A8 and 3D are 8-bit per pixel.
	size_t bpp = mask.fFormat == SkMask::kLCD16_Format ? 2 : 1;

	// Select the right mask plane. Usually plane == 0 and this is just mask.fImage.
	auto ptr = (uintptr_t)mask.fImage
	+ plane * mask.computeImageSize();

	// Update ctx to point "into" this current mask, but lined up with fDstPtr at (0,0).
	// This sort of trickery upsets UBSAN (pointer-overflow) so our ptr must be a uintptr_t.
	// mask.fRowBytes is a uint32_t, which would break our addressing math on 64-bit builds.
	size_t rowBytes = mask.fRowBytes;
	ctx->stride = rowBytes / bpp;
	ctx->pixels = (void)(ptr - mask.fBounds.left() bpp
	- mask.fBounds.top() * rowBytes);
	};

	extract_mask_plane(0, &fMaskPtr);
	if (mask.fFormat == SkMask::k3D_Format) {
	extract_mask_plane(1, &fEmbossCtx.mul);
	extract_mask_plane(2, &fEmbossCtx.add);
	}

	// Lazily build whichever pipeline we need, specialized for each mask format.
	if (mask.fFormat == SkMask::kA8_Format && !fBlitMaskA8) {
	SkRasterPipeline p(fAlloc);
	p.extend(fColorPipeline);
	p.append_gamut_clamp_if_normalized(fDst.info());
	if (SkBlendMode_ShouldPreScaleCoverage(fBlend, /rgb_coverage=/false)) {
	p.append(SkRasterPipeline::scale_u8, &fMaskPtr);
	this->append_load_dst(&p);
	SkBlendMode_AppendStages(fBlend, &p);
	} else {
	this->append_load_dst(&p);
	SkBlendMode_AppendStages(fBlend, &p);
	p.append(SkRasterPipeline::lerp_u8, &fMaskPtr);
	}
	this->append_store(&p);
	fBlitMaskA8 = p.compile();
	}
	if (mask.fFormat == SkMask::kLCD16_Format && !fBlitMaskLCD16) {
	SkRasterPipeline p(fAlloc);
	p.extend(fColorPipeline);
	p.append_gamut_clamp_if_normalized(fDst.info());
	if (SkBlendMode_ShouldPreScaleCoverage(fBlend, /rgb_coverage=/true)) {
	// Somewhat unusually, scale_565 needs dst loaded first.
	this->append_load_dst(&p);
	p.append(SkRasterPipeline::scale_565, &fMaskPtr);
	SkBlendMode_AppendStages(fBlend, &p);
	} else {
	this->append_load_dst(&p);
	SkBlendMode_AppendStages(fBlend, &p);
	p.append(SkRasterPipeline::lerp_565, &fMaskPtr);
	}
	this->append_store(&p);
	fBlitMaskLCD16 = p.compile();
	}
	if (mask.fFormat == SkMask::k3D_Format && !fBlitMask3D) {
	SkRasterPipeline p(fAlloc);
	p.extend(fColorPipeline);
	// This bit is where we differ from kA8_Format:
	p.append(SkRasterPipeline::emboss, &fEmbossCtx);
	// Now onward just as kA8.
	p.append_gamut_clamp_if_normalized(fDst.info());
	if (SkBlendMode_ShouldPreScaleCoverage(fBlend, /rgb_coverage=/false)) {
	p.append(SkRasterPipeline::scale_u8, &fMaskPtr);
	this->append_load_dst(&p);
	SkBlendMode_AppendStages(fBlend, &p);
	} else {
	this->append_load_dst(&p);
	SkBlendMode_AppendStages(fBlend, &p);
	p.append(SkRasterPipeline::lerp_u8, &fMaskPtr);
	}
	this->append_store(&p);
	fBlitMask3D = p.compile();
	}

	std::function<void(size_t,size_t,size_t,size_t)>* blitter = nullptr;
	switch (mask.fFormat) {
	case SkMask::kA8_Format: blitter = &fBlitMaskA8; break;
	case SkMask::kLCD16_Format: blitter = &fBlitMaskLCD16; break;
	case SkMask::k3D_Format: blitter = &fBlitMask3D; break;
	default:
	SkASSERT(false);
	return;
	}

	SkASSERT(blitter);
	(*blitter)(clip.left(),clip.top(), clip.width(),clip.height());
	}