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

 /*
  * Copyright 2006 The Android Open Source Project
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/core/SkBlurMaskFilterImpl.h"

 #include "include/core/SkBlendMode.h"
 #include "include/core/SkBlurTypes.h"
 #include "include/core/SkFlattenable.h"
 #include "include/core/SkImageFilter.h"
 #include "include/core/SkImageInfo.h"
 #include "include/core/SkMaskFilter.h"
 #include "include/core/SkMatrix.h"
 #include "include/core/SkPaint.h"
 #include "include/core/SkPath.h"
 #include "include/core/SkPathBuilder.h"
 #include "include/core/SkPathTypes.h"
 #include "include/core/SkPixmap.h"
 #include "include/core/SkPoint.h"
 #include "include/core/SkRRect.h"
 #include "include/core/SkRect.h"
 #include "include/core/SkRefCnt.h"
 #include "include/core/SkScalar.h"
 #include "include/effects/SkImageFilters.h"
 #include "include/private/base/SkAlign.h"
 #include "include/private/base/SkAssert.h"
 #include "include/private/base/SkFloatingPoint.h"
 #include "include/private/base/SkTemplates.h"
 #include "src/base/SkTLazy.h"
 #include "src/core/SkBlitter_A8.h"
 #include "src/core/SkBlurMask.h"
 #include "src/core/SkCachedData.h"
 #include "src/core/SkDrawBase.h"
 #include "src/core/SkMask.h"
 #include "src/core/SkMaskCache.h"
 #include "src/core/SkMaskFilterBase.h"
 #include "src/core/SkRasterClip.h"
 #include "src/core/SkReadBuffer.h"
 #include "src/core/SkResourceCache.h"
 #include "src/core/SkWriteBuffer.h"

 #include <algorithm>
 #include <cstdint>
 #include <cstring>
 #include <utility>

 SkBlurMaskFilterImpl::SkBlurMaskFilterImpl(SkScalar sigma, SkBlurStyle style, bool respectCTM)
     : fSigma(sigma)
     , fBlurStyle(style)
     , fRespectCTM(respectCTM) {
     SkASSERT(fSigma > 0);
     SkASSERT((unsigned)style <= kLastEnum_SkBlurStyle);
 }

 SkMask::Format SkBlurMaskFilterImpl::getFormat() const {
     return SkMask::kA8_Format;
 }

 bool SkBlurMaskFilterImpl::asABlur(BlurRec* rec) const {
     if (this->ignoreXform()) {
         return false;
     }

     if (rec) {
         rec->fSigma = fSigma;
         rec->fStyle = fBlurStyle;
     }
     return true;
 }

 sk_sp<SkImageFilter> SkBlurMaskFilterImpl::asImageFilter(const SkMatrix& ctm) const {
     float sigma = fSigma;
     if (this->ignoreXform()) {
         // This is analogous to computeXformedSigma(), but it might be more correct to wrap the
         // blur image filter in a local matrix with ctm^-1, or to control the skif::Mapping when
         // the mask filter layer is restored. This is inaccurate when 'ctm' has skew or perspective
         const float ctmScaleFactor = fSigma / ctm.mapRadius(fSigma);
         sigma *= ctmScaleFactor;
     }

     // The null input image filter will be bound to the original coverage mask.
     sk_sp<SkImageFilter> filter = SkImageFilters::Blur(sigma, sigma, nullptr);
     // Combine the original coverage mask (src) and the blurred coverage mask (dst)
     switch(fBlurStyle) {
         case kInner_SkBlurStyle: //  dst = dst * src
                                  //      = 0 * src + src * dst
             return SkImageFilters::Blend(SkBlendMode::kDstIn, std::move(filter), nullptr);
         case kSolid_SkBlurStyle: //  dst = src + dst - src * dst
                                  //      = 1 * src + (1 - src) * dst
             return SkImageFilters::Blend(SkBlendMode::kSrcOver, std::move(filter), nullptr);
         case kOuter_SkBlurStyle: //  dst = dst * (1 - src)
                                  //      = 0 * src + (1 - src) * dst
             return SkImageFilters::Blend(SkBlendMode::kDstOut, std::move(filter), nullptr);
         case kNormal_SkBlurStyle:
             return filter;
     }
     SkUNREACHABLE;
 }

 SkScalar SkBlurMaskFilterImpl::computeXformedSigma(const SkMatrix& ctm) const {
     constexpr SkScalar kMaxBlurSigma = SkIntToScalar(128);
     SkScalar xformedSigma = this->ignoreXform() ? fSigma : ctm.mapRadius(fSigma);
     return std::min(xformedSigma, kMaxBlurSigma);
 }

 bool SkBlurMaskFilterImpl::filterMask(SkMaskBuilder* dst, const SkMask& src,
                                       const SkMatrix& matrix,
                                       SkIPoint* margin) const {
     SkScalar sigma = this->computeXformedSigma(matrix);
     return SkBlurMask::BoxBlur(dst, src, sigma, fBlurStyle, margin);
 }

 bool SkBlurMaskFilterImpl::filterRectMask(SkMaskBuilder* dst, const SkRect& r,
                                           const SkMatrix& matrix,
                                           SkIPoint* margin,
                                           SkMaskBuilder::CreateMode createMode) const {
     SkScalar sigma = computeXformedSigma(matrix);

     return SkBlurMask::BlurRect(sigma, dst, r, fBlurStyle, margin, createMode);
 }

 bool SkBlurMaskFilterImpl::filterRRectMask(SkMaskBuilder* dst, const SkRRect& r,
                                            const SkMatrix& matrix,
                                            SkIPoint* margin,
                                            SkMaskBuilder::CreateMode createMode) const {
     SkScalar sigma = computeXformedSigma(matrix);

     return SkBlurMask::BlurRRect(sigma, dst, r, fBlurStyle, margin, createMode);
 }

 static bool prepare_to_draw_into_mask(const SkRect& bounds, SkMaskBuilder* mask) {
     SkASSERT(mask != nullptr);

     mask->bounds() = bounds.roundOut();
     mask->rowBytes() = SkAlign4(mask->fBounds.width());
     mask->format() = SkMask::kA8_Format;
     const size_t size = mask->computeImageSize();
     mask->image() = SkMaskBuilder::AllocImage(size, SkMaskBuilder::kZeroInit_Alloc);
     if (nullptr == mask->fImage) {
         return false;
     }
     return true;
 }

 template <typename Proc> bool draw_into_mask(SkMaskBuilder* mask, const SkRect& bounds, Proc proc) {
     if (!prepare_to_draw_into_mask(bounds, mask)) {
         return false;
     }

     const int dx = mask->fBounds.fLeft;
     const int dy = mask->fBounds.fTop;
     SkRasterClip rclip(mask->fBounds);
     rclip.setRect(mask->fBounds.makeOffset(-dx, -dy));

     SkASSERT(mask->fFormat == SkMask::kA8_Format);
     auto info = SkImageInfo::MakeA8(mask->fBounds.width(), mask->fBounds.height());
     auto pm = SkPixmap(info, mask->fImage, mask->fRowBytes);

     SkMatrix ctm = SkMatrix::Translate(-SkIntToScalar(dx), -SkIntToScalar(dy));

     SkDrawBase draw;
     draw.fBlitterChooser = SkA8Blitter_Choose;
     draw.fCTM = &ctm;
     draw.fDst = pm;
     draw.fRC  = &rclip;

     SkPaint paint;
     paint.setAntiAlias(true);

     proc(draw, paint);
     return true;
 }

 static bool draw_rects_into_mask(const SkRect rects[], int count, SkMaskBuilder* mask) {
     return draw_into_mask(mask, rects[0], [&](SkDrawBase& draw, const SkPaint& paint) {
         if (1 == count) {
             draw.drawRect(rects[0], paint);
         } else {
             // todo: do I need a fast way to do this?
             SkPath path = SkPathBuilder().addRect(rects[0])
                                          .addRect(rects[1])
                                          .setFillType(SkPathFillType::kEvenOdd)
                                          .detach();
             draw.drawPath(path, paint);
         }
     });
 }

 static bool draw_rrect_into_mask(const SkRRect rrect, SkMaskBuilder* mask) {
     return draw_into_mask(mask, rrect.rect(), [&](SkDrawBase& draw, const SkPaint& paint) {
         draw.drawRRect(rrect, paint);
     });
 }

 static bool rect_exceeds(const SkRect& r, SkScalar v) {
     return r.fLeft < -v || r.fTop < -v || r.fRight > v || r.fBottom > v ||
            r.width() > v || r.height() > v;
 }

 static SkCachedData* copy_mask_to_cacheddata(SkMaskBuilder* mask) {
     const size_t size = mask->computeTotalImageSize();
     SkCachedData* data = SkResourceCache::NewCachedData(size);
     if (data) {
         memcpy(data->writable_data(), mask->fImage, size);
         SkMaskBuilder::FreeImage(mask->image());
         mask->image() = (uint8_t*)data->writable_data();
     }
     return data;
 }

 static SkCachedData* find_cached_rrect(SkTLazy<SkMask>* mask, SkScalar sigma, SkBlurStyle style,
                                        const SkRRect& rrect) {
     return SkMaskCache::FindAndRef(sigma, style, rrect, mask);
 }

 static SkCachedData* add_cached_rrect(SkMaskBuilder* mask, SkScalar sigma, SkBlurStyle style,
                                       const SkRRect& rrect) {
     SkCachedData* cache = copy_mask_to_cacheddata(mask);
     if (cache) {
         SkMaskCache::Add(sigma, style, rrect, *mask, cache);
     }
     return cache;
 }

 static SkCachedData* find_cached_rects(SkTLazy<SkMask>* mask, SkScalar sigma, SkBlurStyle style,
                                        const SkRect rects[], int count) {
     return SkMaskCache::FindAndRef(sigma, style, rects, count, mask);
 }

 static SkCachedData* add_cached_rects(SkMaskBuilder* mask, SkScalar sigma, SkBlurStyle style,
                                       const SkRect rects[], int count) {
     SkCachedData* cache = copy_mask_to_cacheddata(mask);
     if (cache) {
         SkMaskCache::Add(sigma, style, rects, count, *mask, cache);
     }
     return cache;
 }

 static const bool c_analyticBlurRRect{true};

 SkMaskFilterBase::FilterReturn
 SkBlurMaskFilterImpl::filterRRectToNine(const SkRRect& rrect, const SkMatrix& matrix,
                                         const SkIRect& clipBounds,
                                         SkTLazy<NinePatch>* patch) const {
     SkASSERT(patch != nullptr);
     switch (rrect.getType()) {
         case SkRRect::kEmpty_Type:
             // Nothing to draw.
             return kFalse_FilterReturn;

         case SkRRect::kRect_Type:
             // We should have caught this earlier.
             SkASSERT(false);
             [[fallthrough]];
         case SkRRect::kOval_Type:
             // The nine patch special case does not handle ovals, and we
             // already have code for rectangles.
             return kUnimplemented_FilterReturn;

         // These three can take advantage of this fast path.
         case SkRRect::kSimple_Type:
         case SkRRect::kNinePatch_Type:
         case SkRRect::kComplex_Type:
             break;
     }

     // TODO: report correct metrics for innerstyle, where we do not grow the
     // total bounds, but we do need an inset the size of our blur-radius
     if (kInner_SkBlurStyle == fBlurStyle) {
         return kUnimplemented_FilterReturn;
     }

     // TODO: take clipBounds into account to limit our coordinates up front
     // for now, just skip too-large src rects (to take the old code path).
     if (rect_exceeds(rrect.rect(), SkIntToScalar(32767))) {
         return kUnimplemented_FilterReturn;
     }

     SkIPoint margin;
     SkMaskBuilder srcM(nullptr, rrect.rect().roundOut(), 0, SkMask::kA8_Format), dstM;

     bool filterResult = false;
     if (c_analyticBlurRRect) {
         // special case for fast round rect blur
         // don't actually do the blur the first time, just compute the correct size
         filterResult = this->filterRRectMask(&dstM, rrect, matrix, &margin,
                                              SkMaskBuilder::kJustComputeBounds_CreateMode);
     }

     if (!filterResult) {
         filterResult = this->filterMask(&dstM, srcM, matrix, &margin);
     }

     if (!filterResult) {
         return kFalse_FilterReturn;
     }

     // Now figure out the appropriate width and height of the smaller round rectangle
     // to stretch. It will take into account the larger radius per side as well as double
     // the margin, to account for inner and outer blur.
     const SkVector& UL = rrect.radii(SkRRect::kUpperLeft_Corner);
     const SkVector& UR = rrect.radii(SkRRect::kUpperRight_Corner);
     const SkVector& LR = rrect.radii(SkRRect::kLowerRight_Corner);
     const SkVector& LL = rrect.radii(SkRRect::kLowerLeft_Corner);

     const SkScalar leftUnstretched = std::max(UL.fX, LL.fX) + SkIntToScalar(2 * margin.fX);
     const SkScalar rightUnstretched = std::max(UR.fX, LR.fX) + SkIntToScalar(2 * margin.fX);

     // Extra space in the middle to ensure an unchanging piece for stretching. Use 3 to cover
     // any fractional space on either side plus 1 for the part to stretch.
     const SkScalar stretchSize = SkIntToScalar(3);

     const SkScalar totalSmallWidth = leftUnstretched + rightUnstretched + stretchSize;
     if (totalSmallWidth >= rrect.rect().width()) {
         // There is no valid piece to stretch.
         return kUnimplemented_FilterReturn;
     }

     const SkScalar topUnstretched = std::max(UL.fY, UR.fY) + SkIntToScalar(2 * margin.fY);
     const SkScalar bottomUnstretched = std::max(LL.fY, LR.fY) + SkIntToScalar(2 * margin.fY);

     const SkScalar totalSmallHeight = topUnstretched + bottomUnstretched + stretchSize;
     if (totalSmallHeight >= rrect.rect().height()) {
         // There is no valid piece to stretch.
         return kUnimplemented_FilterReturn;
     }

     SkRect smallR = SkRect::MakeWH(totalSmallWidth, totalSmallHeight);

     SkRRect smallRR;
     SkVector radii[4];
     radii[SkRRect::kUpperLeft_Corner] = UL;
     radii[SkRRect::kUpperRight_Corner] = UR;
     radii[SkRRect::kLowerRight_Corner] = LR;
     radii[SkRRect::kLowerLeft_Corner] = LL;
     smallRR.setRectRadii(smallR, radii);

     const SkScalar sigma = this->computeXformedSigma(matrix);
     SkTLazy<SkMask> cachedMask;
     SkCachedData* cache = find_cached_rrect(&cachedMask, sigma, fBlurStyle, smallRR);
     if (!cache) {
         SkMaskBuilder filterM;
         bool analyticBlurWorked = false;
         if (c_analyticBlurRRect) {
             analyticBlurWorked =
                 this->filterRRectMask(&filterM, smallRR, matrix, &margin,
                                       SkMaskBuilder::kComputeBoundsAndRenderImage_CreateMode);
         }

         if (!analyticBlurWorked) {
             if (!draw_rrect_into_mask(smallRR, &srcM)) {
                 return kFalse_FilterReturn;
             }
             SkAutoMaskFreeImage amf(srcM.image());

             if (!this->filterMask(&filterM, srcM, matrix, &margin)) {
                 return kFalse_FilterReturn;
             }
         }
         cache = add_cached_rrect(&filterM, sigma, fBlurStyle, smallRR);
         cachedMask.init(filterM);
     }

     SkIRect bounds = cachedMask->fBounds;
     bounds.offsetTo(0, 0);
     patch->init(SkMask{cachedMask->fImage, bounds, cachedMask->fRowBytes, cachedMask->fFormat},
                 dstM.fBounds,
                 SkIPoint{SkScalarCeilToInt(leftUnstretched) + 1,
                          SkScalarCeilToInt(topUnstretched) + 1},
                 cache); // transfer ownership to patch
     return kTrue_FilterReturn;
 }

 // Use the faster analytic blur approach for ninepatch rects
 static const bool c_analyticBlurNinepatch{true};

 SkMaskFilterBase::FilterReturn
 SkBlurMaskFilterImpl::filterRectsToNine(const SkRect rects[], int count,
                                         const SkMatrix& matrix,
                                         const SkIRect& clipBounds,
                                         SkTLazy<NinePatch>* patch) const {
     if (count < 1 || count > 2) {
         return kUnimplemented_FilterReturn;
     }

     // TODO: report correct metrics for innerstyle, where we do not grow the
     // total bounds, but we do need an inset the size of our blur-radius
     if (kInner_SkBlurStyle == fBlurStyle || kOuter_SkBlurStyle == fBlurStyle) {
         return kUnimplemented_FilterReturn;
     }

     // TODO: take clipBounds into account to limit our coordinates up front
     // for now, just skip too-large src rects (to take the old code path).
     if (rect_exceeds(rects[0], SkIntToScalar(32767))) {
         return kUnimplemented_FilterReturn;
     }

     SkIPoint margin;
     SkMaskBuilder srcM(nullptr, rects[0].roundOut(), 0, SkMask::kA8_Format), dstM;

     bool filterResult = false;
     if (count == 1 && c_analyticBlurNinepatch) {
         // special case for fast rect blur
         // don't actually do the blur the first time, just compute the correct size
         filterResult = this->filterRectMask(&dstM, rects[0], matrix, &margin,
                                             SkMaskBuilder::kJustComputeBounds_CreateMode);
     } else {
         filterResult = this->filterMask(&dstM, srcM, matrix, &margin);
     }

     if (!filterResult) {
         return kFalse_FilterReturn;
     }

     /*
      *  smallR is the smallest version of 'rect' that will still guarantee that
      *  we get the same blur results on all edges, plus 1 center row/col that is
      *  representative of the extendible/stretchable edges of the ninepatch.
      *  Since our actual edge may be fractional we inset 1 more to be sure we
      *  don't miss any interior blur.
      *  x is an added pixel of blur, and { and } are the (fractional) edge
      *  pixels from the original rect.
      *
      *   x x { x x .... x x } x x
      *
      *  Thus, in this case, we inset by a total of 5 (on each side) beginning
      *  with our outer-rect (dstM.fBounds)
      */
     SkRect smallR[2];
     SkIPoint center;

     // +2 is from +1 for each edge (to account for possible fractional edges
     int smallW = dstM.fBounds.width() - srcM.fBounds.width() + 2;
     int smallH = dstM.fBounds.height() - srcM.fBounds.height() + 2;
     SkIRect innerIR;

     if (1 == count) {
         innerIR = srcM.fBounds;
         center.set(smallW, smallH);
     } else {
         SkASSERT(2 == count);
         rects[1].roundIn(&innerIR);
         center.set(smallW + (innerIR.left() - srcM.fBounds.left()),
                    smallH + (innerIR.top() - srcM.fBounds.top()));
     }

     // +1 so we get a clean, stretchable, center row/col
     smallW += 1;
     smallH += 1;

     // we want the inset amounts to be integral, so we don't change any
     // fractional phase on the fRight or fBottom of our smallR.
     const SkScalar dx = SkIntToScalar(innerIR.width() - smallW);
     const SkScalar dy = SkIntToScalar(innerIR.height() - smallH);
     if (dx < 0 || dy < 0) {
         // we're too small, relative to our blur, to break into nine-patch,
         // so we ask to have our normal filterMask() be called.
         return kUnimplemented_FilterReturn;
     }

     smallR[0].setLTRB(rects[0].left(),       rects[0].top(),
                       rects[0].right() - dx, rects[0].bottom() - dy);
     if (smallR[0].width() < 2 || smallR[0].height() < 2) {
         return kUnimplemented_FilterReturn;
     }
     if (2 == count) {
         smallR[1].setLTRB(rects[1].left(), rects[1].top(),
                           rects[1].right() - dx, rects[1].bottom() - dy);
         SkASSERT(!smallR[1].isEmpty());
     }

     const SkScalar sigma = this->computeXformedSigma(matrix);
     SkTLazy<SkMask> cachedMask;
     SkCachedData* cache = find_cached_rects(&cachedMask, sigma, fBlurStyle, smallR, count);
     if (!cache) {
         SkMaskBuilder filterM;
         if (count > 1 || !c_analyticBlurNinepatch) {
             if (!draw_rects_into_mask(smallR, count, &srcM)) {
                 return kFalse_FilterReturn;
             }

             SkAutoMaskFreeImage amf(srcM.image());

             if (!this->filterMask(&filterM, srcM, matrix, &margin)) {
                 return kFalse_FilterReturn;
             }
         } else {
             if (!this->filterRectMask(&filterM, smallR[0], matrix, &margin,
                                       SkMaskBuilder::kComputeBoundsAndRenderImage_CreateMode)) {
                 return kFalse_FilterReturn;
             }
         }
         cache = add_cached_rects(&filterM, sigma, fBlurStyle, smallR, count);
         cachedMask.init(filterM);
     }
     SkIRect bounds = cachedMask->fBounds;
     bounds.offsetTo(0, 0);
     patch->init(SkMask{cachedMask->fImage, bounds, cachedMask->fRowBytes, cachedMask->fFormat},
                 dstM.fBounds, center, cache); // transfer ownership to patch
     return kTrue_FilterReturn;
 }

 void SkBlurMaskFilterImpl::computeFastBounds(const SkRect& src,
                                              SkRect* dst) const {
     // TODO: if we're doing kInner blur, should we return a different outset?
     //       i.e. pad == 0 ?

     SkScalar pad = 3.0f * fSigma;

     dst->setLTRB(src.fLeft  - pad, src.fTop    - pad,
                  src.fRight + pad, src.fBottom + pad);
 }

 sk_sp<SkFlattenable> SkBlurMaskFilterImpl::CreateProc(SkReadBuffer& buffer) {
     const SkScalar sigma = buffer.readScalar();
     SkBlurStyle style = buffer.read32LE(kLastEnum_SkBlurStyle);

     uint32_t flags = buffer.read32LE(0x3);  // historically we only recorded 2 bits
     bool respectCTM = !(flags & 1); // historically we stored ignoreCTM in low bit

     return SkMaskFilter::MakeBlur((SkBlurStyle)style, sigma, respectCTM);
 }

 void SkBlurMaskFilterImpl::flatten(SkWriteBuffer& buffer) const {
     buffer.writeScalar(fSigma);
     buffer.writeUInt(fBlurStyle);
     buffer.writeUInt(!fRespectCTM); // historically we recorded ignoreCTM
 }

 void sk_register_blur_maskfilter_createproc() { SK_REGISTER_FLATTENABLE(SkBlurMaskFilterImpl); }

 sk_sp<SkMaskFilter> SkMaskFilter::MakeBlur(SkBlurStyle style, SkScalar sigma, bool respectCTM) {
     if (SkIsFinite(sigma) && sigma > 0) {
         return sk_sp<SkMaskFilter>(new SkBlurMaskFilterImpl(sigma, style, respectCTM));
     }
     return nullptr;
 }
	/*
	* Copyright 2006 The Android Open Source Project
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/core/SkBlurMaskFilterImpl.h"

	#include "include/core/SkBlendMode.h"
	#include "include/core/SkBlurTypes.h"
	#include "include/core/SkFlattenable.h"
	#include "include/core/SkImageFilter.h"
	#include "include/core/SkImageInfo.h"
	#include "include/core/SkMaskFilter.h"
	#include "include/core/SkMatrix.h"
	#include "include/core/SkPaint.h"
	#include "include/core/SkPath.h"
	#include "include/core/SkPathBuilder.h"
	#include "include/core/SkPathTypes.h"
	#include "include/core/SkPixmap.h"
	#include "include/core/SkPoint.h"
	#include "include/core/SkRRect.h"
	#include "include/core/SkRect.h"
	#include "include/core/SkRefCnt.h"
	#include "include/core/SkScalar.h"
	#include "include/effects/SkImageFilters.h"
	#include "include/private/base/SkAlign.h"
	#include "include/private/base/SkAssert.h"
	#include "include/private/base/SkFloatingPoint.h"
	#include "include/private/base/SkTemplates.h"
	#include "src/base/SkTLazy.h"
	#include "src/core/SkBlitter_A8.h"
	#include "src/core/SkBlurMask.h"
	#include "src/core/SkCachedData.h"
	#include "src/core/SkDrawBase.h"
	#include "src/core/SkMask.h"
	#include "src/core/SkMaskCache.h"
	#include "src/core/SkMaskFilterBase.h"
	#include "src/core/SkRasterClip.h"
	#include "src/core/SkReadBuffer.h"
	#include "src/core/SkResourceCache.h"
	#include "src/core/SkWriteBuffer.h"

	#include <algorithm>
	#include <cstdint>
	#include <cstring>
	#include <utility>

	SkBlurMaskFilterImpl::SkBlurMaskFilterImpl(SkScalar sigma, SkBlurStyle style, bool respectCTM)
	: fSigma(sigma)
	, fBlurStyle(style)
	, fRespectCTM(respectCTM) {
	SkASSERT(fSigma > 0);
	SkASSERT((unsigned)style <= kLastEnum_SkBlurStyle);
	}

	SkMask::Format SkBlurMaskFilterImpl::getFormat() const {
	return SkMask::kA8_Format;
	}

	bool SkBlurMaskFilterImpl::asABlur(BlurRec* rec) const {
	if (this->ignoreXform()) {
	return false;
	}

	if (rec) {
	rec->fSigma = fSigma;
	rec->fStyle = fBlurStyle;
	}
	return true;
	}

	sk_sp<SkImageFilter> SkBlurMaskFilterImpl::asImageFilter(const SkMatrix& ctm) const {
	float sigma = fSigma;
	if (this->ignoreXform()) {
	// This is analogous to computeXformedSigma(), but it might be more correct to wrap the
	// blur image filter in a local matrix with ctm^-1, or to control the skif::Mapping when
	// the mask filter layer is restored. This is inaccurate when 'ctm' has skew or perspective
	const float ctmScaleFactor = fSigma / ctm.mapRadius(fSigma);
	sigma *= ctmScaleFactor;
	}

	// The null input image filter will be bound to the original coverage mask.
	sk_sp<SkImageFilter> filter = SkImageFilters::Blur(sigma, sigma, nullptr);
	// Combine the original coverage mask (src) and the blurred coverage mask (dst)
	switch(fBlurStyle) {
	case kInner_SkBlurStyle: // dst = dst * src
	// = 0 * src + src * dst
	return SkImageFilters::Blend(SkBlendMode::kDstIn, std::move(filter), nullptr);
	case kSolid_SkBlurStyle: // dst = src + dst - src * dst
	// = 1 * src + (1 - src) * dst
	return SkImageFilters::Blend(SkBlendMode::kSrcOver, std::move(filter), nullptr);
	case kOuter_SkBlurStyle: // dst = dst * (1 - src)
	// = 0 * src + (1 - src) * dst
	return SkImageFilters::Blend(SkBlendMode::kDstOut, std::move(filter), nullptr);
	case kNormal_SkBlurStyle:
	return filter;
	}
	SkUNREACHABLE;
	}

	SkScalar SkBlurMaskFilterImpl::computeXformedSigma(const SkMatrix& ctm) const {
	constexpr SkScalar kMaxBlurSigma = SkIntToScalar(128);
	SkScalar xformedSigma = this->ignoreXform() ? fSigma : ctm.mapRadius(fSigma);
	return std::min(xformedSigma, kMaxBlurSigma);
	}

	bool SkBlurMaskFilterImpl::filterMask(SkMaskBuilder* dst, const SkMask& src,
	const SkMatrix& matrix,
	SkIPoint* margin) const {
	SkScalar sigma = this->computeXformedSigma(matrix);
	return SkBlurMask::BoxBlur(dst, src, sigma, fBlurStyle, margin);
	}

	bool SkBlurMaskFilterImpl::filterRectMask(SkMaskBuilder* dst, const SkRect& r,
	const SkMatrix& matrix,
	SkIPoint* margin,
	SkMaskBuilder::CreateMode createMode) const {
	SkScalar sigma = computeXformedSigma(matrix);

	return SkBlurMask::BlurRect(sigma, dst, r, fBlurStyle, margin, createMode);
	}

	bool SkBlurMaskFilterImpl::filterRRectMask(SkMaskBuilder* dst, const SkRRect& r,
	const SkMatrix& matrix,
	SkIPoint* margin,
	SkMaskBuilder::CreateMode createMode) const {
	SkScalar sigma = computeXformedSigma(matrix);

	return SkBlurMask::BlurRRect(sigma, dst, r, fBlurStyle, margin, createMode);
	}

	static bool prepare_to_draw_into_mask(const SkRect& bounds, SkMaskBuilder* mask) {
	SkASSERT(mask != nullptr);

	mask->bounds() = bounds.roundOut();
	mask->rowBytes() = SkAlign4(mask->fBounds.width());
	mask->format() = SkMask::kA8_Format;
	const size_t size = mask->computeImageSize();
	mask->image() = SkMaskBuilder::AllocImage(size, SkMaskBuilder::kZeroInit_Alloc);
	if (nullptr == mask->fImage) {
	return false;
	}
	return true;
	}

	template <typename Proc> bool draw_into_mask(SkMaskBuilder* mask, const SkRect& bounds, Proc proc) {
	if (!prepare_to_draw_into_mask(bounds, mask)) {
	return false;
	}

	const int dx = mask->fBounds.fLeft;
	const int dy = mask->fBounds.fTop;
	SkRasterClip rclip(mask->fBounds);
	rclip.setRect(mask->fBounds.makeOffset(-dx, -dy));

	SkASSERT(mask->fFormat == SkMask::kA8_Format);
	auto info = SkImageInfo::MakeA8(mask->fBounds.width(), mask->fBounds.height());
	auto pm = SkPixmap(info, mask->fImage, mask->fRowBytes);

	SkMatrix ctm = SkMatrix::Translate(-SkIntToScalar(dx), -SkIntToScalar(dy));

	SkDrawBase draw;
	draw.fBlitterChooser = SkA8Blitter_Choose;
	draw.fCTM = &ctm;
	draw.fDst = pm;
	draw.fRC = &rclip;

	SkPaint paint;
	paint.setAntiAlias(true);

	proc(draw, paint);
	return true;
	}

	static bool draw_rects_into_mask(const SkRect rects[], int count, SkMaskBuilder* mask) {
	return draw_into_mask(mask, rects[0], [&](SkDrawBase& draw, const SkPaint& paint) {
	if (1 == count) {
	draw.drawRect(rects[0], paint);
	} else {
	// todo: do I need a fast way to do this?
	SkPath path = SkPathBuilder().addRect(rects[0])
	.addRect(rects[1])
	.setFillType(SkPathFillType::kEvenOdd)
	.detach();
	draw.drawPath(path, paint);
	}
	});
	}

	static bool draw_rrect_into_mask(const SkRRect rrect, SkMaskBuilder* mask) {
	return draw_into_mask(mask, rrect.rect(), [&](SkDrawBase& draw, const SkPaint& paint) {
	draw.drawRRect(rrect, paint);
	});
	}

	static bool rect_exceeds(const SkRect& r, SkScalar v) {
	return r.fLeft < -v \|\| r.fTop < -v \|\| r.fRight > v \|\| r.fBottom > v \|\|
	r.width() > v \|\| r.height() > v;
	}

	static SkCachedData* copy_mask_to_cacheddata(SkMaskBuilder* mask) {
	const size_t size = mask->computeTotalImageSize();
	SkCachedData* data = SkResourceCache::NewCachedData(size);
	if (data) {
	memcpy(data->writable_data(), mask->fImage, size);
	SkMaskBuilder::FreeImage(mask->image());
	mask->image() = (uint8_t*)data->writable_data();
	}
	return data;
	}

	static SkCachedData* find_cached_rrect(SkTLazy<SkMask>* mask, SkScalar sigma, SkBlurStyle style,
	const SkRRect& rrect) {
	return SkMaskCache::FindAndRef(sigma, style, rrect, mask);
	}

	static SkCachedData* add_cached_rrect(SkMaskBuilder* mask, SkScalar sigma, SkBlurStyle style,
	const SkRRect& rrect) {
	SkCachedData* cache = copy_mask_to_cacheddata(mask);
	if (cache) {
	SkMaskCache::Add(sigma, style, rrect, *mask, cache);
	}
	return cache;
	}

	static SkCachedData* find_cached_rects(SkTLazy<SkMask>* mask, SkScalar sigma, SkBlurStyle style,
	const SkRect rects[], int count) {
	return SkMaskCache::FindAndRef(sigma, style, rects, count, mask);
	}

	static SkCachedData* add_cached_rects(SkMaskBuilder* mask, SkScalar sigma, SkBlurStyle style,
	const SkRect rects[], int count) {
	SkCachedData* cache = copy_mask_to_cacheddata(mask);
	if (cache) {
	SkMaskCache::Add(sigma, style, rects, count, *mask, cache);
	}
	return cache;
	}

	static const bool c_analyticBlurRRect{true};

	SkMaskFilterBase::FilterReturn
	SkBlurMaskFilterImpl::filterRRectToNine(const SkRRect& rrect, const SkMatrix& matrix,
	const SkIRect& clipBounds,
	SkTLazy<NinePatch>* patch) const {
	SkASSERT(patch != nullptr);
	switch (rrect.getType()) {
	case SkRRect::kEmpty_Type:
	// Nothing to draw.
	return kFalse_FilterReturn;

	case SkRRect::kRect_Type:
	// We should have caught this earlier.
	SkASSERT(false);
	[[fallthrough]];
	case SkRRect::kOval_Type:
	// The nine patch special case does not handle ovals, and we
	// already have code for rectangles.
	return kUnimplemented_FilterReturn;

	// These three can take advantage of this fast path.
	case SkRRect::kSimple_Type:
	case SkRRect::kNinePatch_Type:
	case SkRRect::kComplex_Type:
	break;
	}

	// TODO: report correct metrics for innerstyle, where we do not grow the
	// total bounds, but we do need an inset the size of our blur-radius
	if (kInner_SkBlurStyle == fBlurStyle) {
	return kUnimplemented_FilterReturn;
	}

	// TODO: take clipBounds into account to limit our coordinates up front
	// for now, just skip too-large src rects (to take the old code path).
	if (rect_exceeds(rrect.rect(), SkIntToScalar(32767))) {
	return kUnimplemented_FilterReturn;
	}

	SkIPoint margin;
	SkMaskBuilder srcM(nullptr, rrect.rect().roundOut(), 0, SkMask::kA8_Format), dstM;

	bool filterResult = false;
	if (c_analyticBlurRRect) {
	// special case for fast round rect blur
	// don't actually do the blur the first time, just compute the correct size
	filterResult = this->filterRRectMask(&dstM, rrect, matrix, &margin,
	SkMaskBuilder::kJustComputeBounds_CreateMode);
	}

	if (!filterResult) {
	filterResult = this->filterMask(&dstM, srcM, matrix, &margin);
	}

	if (!filterResult) {
	return kFalse_FilterReturn;
	}

	// Now figure out the appropriate width and height of the smaller round rectangle
	// to stretch. It will take into account the larger radius per side as well as double
	// the margin, to account for inner and outer blur.
	const SkVector& UL = rrect.radii(SkRRect::kUpperLeft_Corner);
	const SkVector& UR = rrect.radii(SkRRect::kUpperRight_Corner);
	const SkVector& LR = rrect.radii(SkRRect::kLowerRight_Corner);
	const SkVector& LL = rrect.radii(SkRRect::kLowerLeft_Corner);

	const SkScalar leftUnstretched = std::max(UL.fX, LL.fX) + SkIntToScalar(2 * margin.fX);
	const SkScalar rightUnstretched = std::max(UR.fX, LR.fX) + SkIntToScalar(2 * margin.fX);

	// Extra space in the middle to ensure an unchanging piece for stretching. Use 3 to cover
	// any fractional space on either side plus 1 for the part to stretch.
	const SkScalar stretchSize = SkIntToScalar(3);

	const SkScalar totalSmallWidth = leftUnstretched + rightUnstretched + stretchSize;
	if (totalSmallWidth >= rrect.rect().width()) {
	// There is no valid piece to stretch.
	return kUnimplemented_FilterReturn;
	}

	const SkScalar topUnstretched = std::max(UL.fY, UR.fY) + SkIntToScalar(2 * margin.fY);
	const SkScalar bottomUnstretched = std::max(LL.fY, LR.fY) + SkIntToScalar(2 * margin.fY);

	const SkScalar totalSmallHeight = topUnstretched + bottomUnstretched + stretchSize;
	if (totalSmallHeight >= rrect.rect().height()) {
	// There is no valid piece to stretch.
	return kUnimplemented_FilterReturn;
	}

	SkRect smallR = SkRect::MakeWH(totalSmallWidth, totalSmallHeight);

	SkRRect smallRR;
	SkVector radii[4];
	radii[SkRRect::kUpperLeft_Corner] = UL;
	radii[SkRRect::kUpperRight_Corner] = UR;
	radii[SkRRect::kLowerRight_Corner] = LR;
	radii[SkRRect::kLowerLeft_Corner] = LL;
	smallRR.setRectRadii(smallR, radii);

	const SkScalar sigma = this->computeXformedSigma(matrix);
	SkTLazy<SkMask> cachedMask;
	SkCachedData* cache = find_cached_rrect(&cachedMask, sigma, fBlurStyle, smallRR);
	if (!cache) {
	SkMaskBuilder filterM;
	bool analyticBlurWorked = false;
	if (c_analyticBlurRRect) {
	analyticBlurWorked =
	this->filterRRectMask(&filterM, smallRR, matrix, &margin,
	SkMaskBuilder::kComputeBoundsAndRenderImage_CreateMode);
	}

	if (!analyticBlurWorked) {
	if (!draw_rrect_into_mask(smallRR, &srcM)) {
	return kFalse_FilterReturn;
	}
	SkAutoMaskFreeImage amf(srcM.image());

	if (!this->filterMask(&filterM, srcM, matrix, &margin)) {
	return kFalse_FilterReturn;
	}
	}
	cache = add_cached_rrect(&filterM, sigma, fBlurStyle, smallRR);
	cachedMask.init(filterM);
	}

	SkIRect bounds = cachedMask->fBounds;
	bounds.offsetTo(0, 0);
	patch->init(SkMask{cachedMask->fImage, bounds, cachedMask->fRowBytes, cachedMask->fFormat},
	dstM.fBounds,
	SkIPoint{SkScalarCeilToInt(leftUnstretched) + 1,
	SkScalarCeilToInt(topUnstretched) + 1},
	cache); // transfer ownership to patch
	return kTrue_FilterReturn;
	}

	// Use the faster analytic blur approach for ninepatch rects
	static const bool c_analyticBlurNinepatch{true};

	SkMaskFilterBase::FilterReturn
	SkBlurMaskFilterImpl::filterRectsToNine(const SkRect rects[], int count,
	const SkMatrix& matrix,
	const SkIRect& clipBounds,
	SkTLazy<NinePatch>* patch) const {
	if (count < 1 \|\| count > 2) {
	return kUnimplemented_FilterReturn;
	}

	// TODO: report correct metrics for innerstyle, where we do not grow the
	// total bounds, but we do need an inset the size of our blur-radius
	if (kInner_SkBlurStyle == fBlurStyle \|\| kOuter_SkBlurStyle == fBlurStyle) {
	return kUnimplemented_FilterReturn;
	}

	// TODO: take clipBounds into account to limit our coordinates up front
	// for now, just skip too-large src rects (to take the old code path).
	if (rect_exceeds(rects[0], SkIntToScalar(32767))) {
	return kUnimplemented_FilterReturn;
	}

	SkIPoint margin;
	SkMaskBuilder srcM(nullptr, rects[0].roundOut(), 0, SkMask::kA8_Format), dstM;

	bool filterResult = false;
	if (count == 1 && c_analyticBlurNinepatch) {
	// special case for fast rect blur
	// don't actually do the blur the first time, just compute the correct size
	filterResult = this->filterRectMask(&dstM, rects[0], matrix, &margin,
	SkMaskBuilder::kJustComputeBounds_CreateMode);
	} else {
	filterResult = this->filterMask(&dstM, srcM, matrix, &margin);
	}

	if (!filterResult) {
	return kFalse_FilterReturn;
	}

	/*
	* smallR is the smallest version of 'rect' that will still guarantee that
	* we get the same blur results on all edges, plus 1 center row/col that is
	* representative of the extendible/stretchable edges of the ninepatch.
	* Since our actual edge may be fractional we inset 1 more to be sure we
	* don't miss any interior blur.
	* x is an added pixel of blur, and { and } are the (fractional) edge
	* pixels from the original rect.
	*
	* x x { x x .... x x } x x
	*
	* Thus, in this case, we inset by a total of 5 (on each side) beginning
	* with our outer-rect (dstM.fBounds)
	*/
	SkRect smallR[2];
	SkIPoint center;

	// +2 is from +1 for each edge (to account for possible fractional edges
	int smallW = dstM.fBounds.width() - srcM.fBounds.width() + 2;
	int smallH = dstM.fBounds.height() - srcM.fBounds.height() + 2;
	SkIRect innerIR;

	if (1 == count) {
	innerIR = srcM.fBounds;
	center.set(smallW, smallH);
	} else {
	SkASSERT(2 == count);
	rects[1].roundIn(&innerIR);
	center.set(smallW + (innerIR.left() - srcM.fBounds.left()),
	smallH + (innerIR.top() - srcM.fBounds.top()));
	}

	// +1 so we get a clean, stretchable, center row/col
	smallW += 1;
	smallH += 1;

	// we want the inset amounts to be integral, so we don't change any
	// fractional phase on the fRight or fBottom of our smallR.
	const SkScalar dx = SkIntToScalar(innerIR.width() - smallW);
	const SkScalar dy = SkIntToScalar(innerIR.height() - smallH);
	if (dx < 0 \|\| dy < 0) {
	// we're too small, relative to our blur, to break into nine-patch,
	// so we ask to have our normal filterMask() be called.
	return kUnimplemented_FilterReturn;
	}

	smallR[0].setLTRB(rects[0].left(), rects[0].top(),
	rects[0].right() - dx, rects[0].bottom() - dy);
	if (smallR[0].width() < 2 \|\| smallR[0].height() < 2) {
	return kUnimplemented_FilterReturn;
	}
	if (2 == count) {
	smallR[1].setLTRB(rects[1].left(), rects[1].top(),
	rects[1].right() - dx, rects[1].bottom() - dy);
	SkASSERT(!smallR[1].isEmpty());
	}

	const SkScalar sigma = this->computeXformedSigma(matrix);
	SkTLazy<SkMask> cachedMask;
	SkCachedData* cache = find_cached_rects(&cachedMask, sigma, fBlurStyle, smallR, count);
	if (!cache) {
	SkMaskBuilder filterM;
	if (count > 1 \|\| !c_analyticBlurNinepatch) {
	if (!draw_rects_into_mask(smallR, count, &srcM)) {
	return kFalse_FilterReturn;
	}

	SkAutoMaskFreeImage amf(srcM.image());

	if (!this->filterMask(&filterM, srcM, matrix, &margin)) {
	return kFalse_FilterReturn;
	}
	} else {
	if (!this->filterRectMask(&filterM, smallR[0], matrix, &margin,
	SkMaskBuilder::kComputeBoundsAndRenderImage_CreateMode)) {
	return kFalse_FilterReturn;
	}
	}
	cache = add_cached_rects(&filterM, sigma, fBlurStyle, smallR, count);
	cachedMask.init(filterM);
	}
	SkIRect bounds = cachedMask->fBounds;
	bounds.offsetTo(0, 0);
	patch->init(SkMask{cachedMask->fImage, bounds, cachedMask->fRowBytes, cachedMask->fFormat},
	dstM.fBounds, center, cache); // transfer ownership to patch
	return kTrue_FilterReturn;
	}

	void SkBlurMaskFilterImpl::computeFastBounds(const SkRect& src,
	SkRect* dst) const {
	// TODO: if we're doing kInner blur, should we return a different outset?
	// i.e. pad == 0 ?

	SkScalar pad = 3.0f * fSigma;

	dst->setLTRB(src.fLeft - pad, src.fTop - pad,
	src.fRight + pad, src.fBottom + pad);
	}

	sk_sp<SkFlattenable> SkBlurMaskFilterImpl::CreateProc(SkReadBuffer& buffer) {
	const SkScalar sigma = buffer.readScalar();
	SkBlurStyle style = buffer.read32LE(kLastEnum_SkBlurStyle);

	uint32_t flags = buffer.read32LE(0x3); // historically we only recorded 2 bits
	bool respectCTM = !(flags & 1); // historically we stored ignoreCTM in low bit

	return SkMaskFilter::MakeBlur((SkBlurStyle)style, sigma, respectCTM);
	}

	void SkBlurMaskFilterImpl::flatten(SkWriteBuffer& buffer) const {
	buffer.writeScalar(fSigma);
	buffer.writeUInt(fBlurStyle);
	buffer.writeUInt(!fRespectCTM); // historically we recorded ignoreCTM
	}

	void sk_register_blur_maskfilter_createproc() { SK_REGISTER_FLATTENABLE(SkBlurMaskFilterImpl); }

	sk_sp<SkMaskFilter> SkMaskFilter::MakeBlur(SkBlurStyle style, SkScalar sigma, bool respectCTM) {
	if (SkIsFinite(sigma) && sigma > 0) {
	return sk_sp<SkMaskFilter>(new SkBlurMaskFilterImpl(sigma, style, respectCTM));
	}
	return nullptr;
	}