src/effects/imagefilters/SkMagnifierImageFilter.cpp - skia - Git at Google

 /*
  * Copyright 2012 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 "include/effects/SkImageFilters.h"

 #include "include/core/SkFlattenable.h"
 #include "include/core/SkImageFilter.h"
 #include "include/core/SkM44.h"
 #include "include/core/SkMatrix.h"
 #include "include/core/SkPoint.h"
 #include "include/core/SkRect.h"
 #include "include/core/SkRefCnt.h"
 #include "include/core/SkSamplingOptions.h"
 #include "include/core/SkScalar.h"
 #include "include/core/SkShader.h"
 #include "include/core/SkSize.h"
 #include "include/core/SkSpan.h"
 #include "include/core/SkTypes.h"
 #include "include/effects/SkRuntimeEffect.h"
 #include "include/private/base/SkFloatingPoint.h"
 #include "src/core/SkImageFilterTypes.h"
 #include "src/core/SkImageFilter_Base.h"
 #include "src/core/SkKnownRuntimeEffects.h"
 #include "src/core/SkPicturePriv.h"
 #include "src/core/SkReadBuffer.h"
 #include "src/core/SkWriteBuffer.h"

 #include <algorithm>
 #include <optional>
 #include <utility>

 namespace {

 class SkMagnifierImageFilter final : public SkImageFilter_Base {
 public:
     SkMagnifierImageFilter(const SkRect& lensBounds,
                            float zoomAmount,
                            float inset,
                            const SkSamplingOptions& sampling,
                            sk_sp<SkImageFilter> input)
         : SkImageFilter_Base(&input, 1)
         , fLensBounds(lensBounds)
         , fZoomAmount(zoomAmount)
         , fInset(inset)
         , fSampling(sampling) {}

     SkRect computeFastBounds(const SkRect&) const override;

 protected:
     void flatten(SkWriteBuffer&) const override;

 private:
     friend void ::SkRegisterMagnifierImageFilterFlattenable();
     SK_FLATTENABLE_HOOKS(SkMagnifierImageFilter)

     skif::FilterResult onFilterImage(const skif::Context& context) const override;

     skif::LayerSpace<SkIRect> onGetInputLayerBounds(
             const skif::Mapping& mapping,
             const skif::LayerSpace<SkIRect>& desiredOutput,
             std::optional<skif::LayerSpace<SkIRect>> contentBounds) const override;

     std::optional<skif::LayerSpace<SkIRect>> onGetOutputLayerBounds(
             const skif::Mapping& mapping,
             std::optional<skif::LayerSpace<SkIRect>> contentBounds) const override;

     skif::ParameterSpace<SkRect> fLensBounds;
     // Zoom is relative so does not belong to a coordinate space, see note in onFilterImage().
     float fZoomAmount;
     // Inset is really a ParameterSpace<SkSize> where width = height = fInset, but we store just the
     // float here for easier serialization and convert to a size in onFilterImage().
     float fInset;
     SkSamplingOptions fSampling;
 };

 } // end namespace

 sk_sp<SkImageFilter> SkImageFilters::Magnifier(const SkRect& lensBounds,
                                                SkScalar zoomAmount,
                                                SkScalar inset,
                                                const SkSamplingOptions& sampling,
                                                sk_sp<SkImageFilter> input,
                                                const CropRect& cropRect) {
     if (lensBounds.isEmpty() || !lensBounds.isFinite() ||
         zoomAmount <= 0.f || inset < 0.f ||
         !SkIsFinite(zoomAmount, inset)) {
         return nullptr; // invalid
     }
     // The magnifier automatically restricts its output based on the size of the image it receives
     // as input, so 'cropRect' only applies to its input.
     if (cropRect) {
         input = SkImageFilters::Crop(*cropRect, std::move(input));
     }

     if (zoomAmount > 1.f) {
         return sk_sp<SkImageFilter>(new SkMagnifierImageFilter(lensBounds, zoomAmount, inset,
                                                                sampling, std::move(input)));
     } else {
         // Zooming with a value less than 1 is technically a downscaling, which "works" but the
         // non-linear distortion behaves unintuitively. At zoomAmount = 1, this filter is an
         // expensive identity function so treat zoomAmount <= 1 as a no-op.
         return input;
     }
 }

 void SkRegisterMagnifierImageFilterFlattenable() {
     SK_REGISTER_FLATTENABLE(SkMagnifierImageFilter);
 }

 sk_sp<SkFlattenable> SkMagnifierImageFilter::CreateProc(SkReadBuffer& buffer) {
     if (buffer.isVersionLT(SkPicturePriv::kRevampMagnifierFilter)) {
         // This was actually a legacy magnifier image filter that was serialized. Chrome is the
         // only known client of the magnifier and its not used on webpages, so there shouldn't be
         // SKPs that actually contain a flattened magnifier filter (legacy or new).
         return nullptr;
     }

     SK_IMAGEFILTER_UNFLATTEN_COMMON(common, 1);

     SkRect lensBounds;
     buffer.readRect(&lensBounds);
     SkScalar zoomAmount = buffer.readScalar();
     SkScalar inset = buffer.readScalar();
     SkSamplingOptions sampling = buffer.readSampling();
     return SkImageFilters::Magnifier(lensBounds, zoomAmount, inset, sampling, common.getInput(0));
 }

 void SkMagnifierImageFilter::flatten(SkWriteBuffer& buffer) const {
     this->SkImageFilter_Base::flatten(buffer);
     buffer.writeRect(SkRect(fLensBounds));
     buffer.writeScalar(fZoomAmount);
     buffer.writeScalar(fInset);
     buffer.writeSampling(fSampling);
 }

 ////////////////////////////////////////////////////////////////////////////////

 static sk_sp<SkShader> make_magnifier_shader(
         sk_sp<SkShader> input,
         const skif::LayerSpace<SkRect>& lensBounds,
         const skif::LayerSpace<SkMatrix>& zoomXform,
         const skif::LayerSpace<SkSize>& inset) {
     const SkRuntimeEffect* magEffect =
             GetKnownRuntimeEffect(SkKnownRuntimeEffects::StableKey::kMagnifier);

     SkRuntimeShaderBuilder builder(sk_ref_sp(magEffect));
     builder.child("src") = std::move(input);

     SkASSERT(inset.width() > 0.f && inset.height() > 0.f);
     builder.uniform("lensBounds") = SkRect(lensBounds);
     builder.uniform("zoomXform") = SkV4{/*Tx*/zoomXform.rc(0, 2), /*Ty*/zoomXform.rc(1, 2),
                                         /*Sx*/zoomXform.rc(0, 0), /*Sy*/zoomXform.rc(1, 1)};
     builder.uniform("invInset") = SkV2{1.f / inset.width(),
                                        1.f / inset.height()};

     return builder.makeShader();
 }

 ////////////////////////////////////////////////////////////////////////////////

 skif::FilterResult SkMagnifierImageFilter::onFilterImage(const skif::Context& context) const {
     // These represent the full lens bounds and the ideal zoom center if everything is visible.
     skif::LayerSpace<SkRect> lensBounds = context.mapping().paramToLayer(fLensBounds);
     skif::LayerSpace<SkPoint> zoomCenter = lensBounds.center();

     // When magnifying near the edge of the screen, it's common for part of the lens bounds to be
     // offscreen, which also means its input filter cannot provide the full required input.
     // The magnifier's auto-sizing's goal is to cover the visible portion of the lens bounds.
     skif::LayerSpace<SkRect> visibleLensBounds = lensBounds;
     if (!visibleLensBounds.intersect(skif::LayerSpace<SkRect>(context.desiredOutput()))) {
         return {};
     }

     // We pre-emptively fit the zoomed-in src rect to what we expect the child input filter to
     // produce. This should be correct in all cases except for failure to create an offscreen image,
     // at which point there's nothing to be done anyway.
     skif::LayerSpace<SkRect> expectedChildOutput = lensBounds;
     if (std::optional<skif::LayerSpace<SkIRect>> output =
             this->getChildOutputLayerBounds(0, context.mapping(), context.source().layerBounds())) {
         expectedChildOutput = skif::LayerSpace<SkRect>(*output);
     }

     // Clamp the zoom center to be within the childOutput image
     zoomCenter = expectedChildOutput.clamp(zoomCenter);

     // The zoom we want to apply in layer-space is equal to
     // mapping.paramToLayer(SkMatrix::Scale(fZoomAmount)).decomposeScale(&layerZoom).
     // Because this filter only supports scale+translate matrices, the paramToLayer transform of
     // the parameter-space scale matrix is a no-op. Thus layerZoom == fZoomAmount and we can avoid
     // all of that math. This assumption is invalid if the matrix complexity is more than S+T.
     SkASSERT(this->getCTMCapability() == MatrixCapability::kScaleTranslate);
     float invZoom = 1.f / fZoomAmount;

     // The srcRect is the bounding box of the pixels that are linearly scaled up, about zoomCenter.
     // This is not the visual bounds of this upscaled region, but the bounds of the source pixels
     // that will fill the main magnified region (which is simply the inset of lensBounds). When
     // lensBounds has not been cropped by the actual input image, these equations are identical to
     // the more intuitive L/R = center.x -/+ width/(2*zoom) and T/B = center.y -/+ height/(2*zoom).
     // However, when lensBounds is cropped this automatically shifts the source rectangle away from
     // the original zoom center such that the upscaled area is contained within the input image.
     skif::LayerSpace<SkRect> srcRect{{
             lensBounds.left()  * invZoom + zoomCenter.x()*(1.f - invZoom),
             lensBounds.top()   * invZoom + zoomCenter.y()*(1.f - invZoom),
             lensBounds.right() * invZoom + zoomCenter.x()*(1.f - invZoom),
             lensBounds.bottom()* invZoom + zoomCenter.y()*(1.f - invZoom)}};

     // The above adjustment helps to account for offscreen, but when the magnifier is combined with
     // backdrop offsets, more significant fitting needs to be performed to pin the visible src
     // rect to what's available.
     auto zoomXform = skif::LayerSpace<SkMatrix>::RectToRect(lensBounds, srcRect);
     if (!expectedChildOutput.contains(visibleLensBounds)) {
         // We need to pick a new srcRect such that srcRect is contained within fitRect and fills
         // visibleLens, while maintaining the aspect ratio of the original srcRect -> lensBounds.
         srcRect = zoomXform.mapRect(visibleLensBounds);

         if (expectedChildOutput.width() >= srcRect.width() &&
             expectedChildOutput.height() >= srcRect.height()) {
             float left = srcRect.left() < expectedChildOutput.left() ?
                     expectedChildOutput.left() :
                     std::min(srcRect.right(), expectedChildOutput.right()) - srcRect.width();
             float top = srcRect.top() < expectedChildOutput.top() ?
                     expectedChildOutput.top() :
                     std::min(srcRect.bottom(), expectedChildOutput.bottom()) - srcRect.height();

             // Update transform to reflect fitted src
             srcRect = skif::LayerSpace<SkRect>(
                     SkRect::MakeXYWH(left, top, srcRect.width(), srcRect.height()));
             zoomXform = skif::LayerSpace<SkMatrix>::RectToRect(visibleLensBounds, srcRect);
         } // Else not enough of the target is available to cover, so don't try adjusting
     }

     // When there is no SkSL support, or there's a 0 inset, the magnifier is equivalent to a
     // rect->rect transform and crop.
     skif::LayerSpace<SkSize> inset = context.mapping().paramToLayer(
             skif::ParameterSpace<SkSize>({fInset, fInset}));
     if (inset.width() <= 0.f || inset.height() <= 0.f)
     {
         // When applying the zoom as a direct transform, we only require the visibleSrcRect as
         // input from the child filter, and transform it by the inverse of zoomXform (to go from
         // src to lens bounds, since it was constructed to go from lens to src).
         skif::LayerSpace<SkMatrix> invZoomXform;
         SkAssertResult(zoomXform.invert(&invZoomXform));
         skif::FilterResult childOutput =
                 this->getChildOutput(0, context.withNewDesiredOutput(srcRect.roundOut()));
         return childOutput.applyTransform(context, invZoomXform, fSampling)
                           .applyCrop(context, lensBounds.roundOut());
     }

     using ShaderFlags = skif::FilterResult::ShaderFlags;
     skif::FilterResult::Builder builder{context};
     builder.add(this->getChildOutput(0, context.withNewDesiredOutput(visibleLensBounds.roundOut())),
                 {}, ShaderFlags::kNonTrivialSampling, fSampling);
     return builder.eval([&](SkSpan<sk_sp<SkShader>> inputs) {
             // If the input resolved to a null shader, the magnified output will be transparent too
             return inputs[0] ? make_magnifier_shader(inputs[0], lensBounds, zoomXform, inset)
                              : nullptr;
         }, lensBounds.roundOut());
 }

 skif::LayerSpace<SkIRect> SkMagnifierImageFilter::onGetInputLayerBounds(
         const skif::Mapping& mapping,
         const skif::LayerSpace<SkIRect>& desiredOutput,
         std::optional<skif::LayerSpace<SkIRect>> contentBounds) const {
     // The required input is always the lens bounds. The filter distorts the pixels contained within
     // these bounds to zoom in on a portion of it, depending on the inset and zoom amount. However,
     // it adjusts the region based on cropping that occurs between what's requested and what's
     // provided. Theoretically it's possible that we could restrict the required input by the
     // desired output, but that cropping should not adjust the zoom region or inset. This is non
     // trivial to separate and is an unlikely use case so for now just require fLensBounds.
     skif::LayerSpace<SkIRect> requiredInput = mapping.paramToLayer(fLensBounds).roundOut();
     // Our required input is the desired output for our child image filter.
     return this->getChildInputLayerBounds(0, mapping, requiredInput, contentBounds);
 }

 std::optional<skif::LayerSpace<SkIRect>> SkMagnifierImageFilter::onGetOutputLayerBounds(
         const skif::Mapping& mapping,
         std::optional<skif::LayerSpace<SkIRect>> contentBounds) const {
     // The output of this filter is fLensBounds intersected with its child's output.
     auto output = this->getChildOutputLayerBounds(0, mapping, contentBounds);
     skif::LayerSpace<SkIRect> lensBounds = mapping.paramToLayer(fLensBounds).roundOut();
     if (!output || lensBounds.intersect(*output)) {
         return lensBounds;
     } else {
         // Nothing to magnify
         return skif::LayerSpace<SkIRect>::Empty();
     }
 }

 SkRect SkMagnifierImageFilter::computeFastBounds(const SkRect& src) const {
     SkRect bounds = this->getInput(0) ? this->getInput(0)->computeFastBounds(src) : src;
     if (bounds.intersect(SkRect(fLensBounds))) {
         return bounds;
     } else {
         return SkRect::MakeEmpty();
     }
 }
	/*
	* Copyright 2012 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 "include/effects/SkImageFilters.h"

	#include "include/core/SkFlattenable.h"
	#include "include/core/SkImageFilter.h"
	#include "include/core/SkM44.h"
	#include "include/core/SkMatrix.h"
	#include "include/core/SkPoint.h"
	#include "include/core/SkRect.h"
	#include "include/core/SkRefCnt.h"
	#include "include/core/SkSamplingOptions.h"
	#include "include/core/SkScalar.h"
	#include "include/core/SkShader.h"
	#include "include/core/SkSize.h"
	#include "include/core/SkSpan.h"
	#include "include/core/SkTypes.h"
	#include "include/effects/SkRuntimeEffect.h"
	#include "include/private/base/SkFloatingPoint.h"
	#include "src/core/SkImageFilterTypes.h"
	#include "src/core/SkImageFilter_Base.h"
	#include "src/core/SkKnownRuntimeEffects.h"
	#include "src/core/SkPicturePriv.h"
	#include "src/core/SkReadBuffer.h"
	#include "src/core/SkWriteBuffer.h"

	#include <algorithm>
	#include <optional>
	#include <utility>

	namespace {

	class SkMagnifierImageFilter final : public SkImageFilter_Base {
	public:
	SkMagnifierImageFilter(const SkRect& lensBounds,
	float zoomAmount,
	float inset,
	const SkSamplingOptions& sampling,
	sk_sp<SkImageFilter> input)
	: SkImageFilter_Base(&input, 1)
	, fLensBounds(lensBounds)
	, fZoomAmount(zoomAmount)
	, fInset(inset)
	, fSampling(sampling) {}

	SkRect computeFastBounds(const SkRect&) const override;

	protected:
	void flatten(SkWriteBuffer&) const override;

	private:
	friend void ::SkRegisterMagnifierImageFilterFlattenable();
	SK_FLATTENABLE_HOOKS(SkMagnifierImageFilter)

	skif::FilterResult onFilterImage(const skif::Context& context) const override;

	skif::LayerSpace<SkIRect> onGetInputLayerBounds(
	const skif::Mapping& mapping,
	const skif::LayerSpace<SkIRect>& desiredOutput,
	std::optional<skif::LayerSpace<SkIRect>> contentBounds) const override;

	std::optional<skif::LayerSpace<SkIRect>> onGetOutputLayerBounds(
	const skif::Mapping& mapping,
	std::optional<skif::LayerSpace<SkIRect>> contentBounds) const override;

	skif::ParameterSpace<SkRect> fLensBounds;
	// Zoom is relative so does not belong to a coordinate space, see note in onFilterImage().
	float fZoomAmount;
	// Inset is really a ParameterSpace<SkSize> where width = height = fInset, but we store just the
	// float here for easier serialization and convert to a size in onFilterImage().
	float fInset;
	SkSamplingOptions fSampling;
	};

	} // end namespace

	sk_sp<SkImageFilter> SkImageFilters::Magnifier(const SkRect& lensBounds,
	SkScalar zoomAmount,
	SkScalar inset,
	const SkSamplingOptions& sampling,
	sk_sp<SkImageFilter> input,
	const CropRect& cropRect) {
	if (lensBounds.isEmpty() \|\| !lensBounds.isFinite() \|\|
	zoomAmount <= 0.f \|\| inset < 0.f \|\|
	!SkIsFinite(zoomAmount, inset)) {
	return nullptr; // invalid
	}
	// The magnifier automatically restricts its output based on the size of the image it receives
	// as input, so 'cropRect' only applies to its input.
	if (cropRect) {
	input = SkImageFilters::Crop(*cropRect, std::move(input));
	}

	if (zoomAmount > 1.f) {
	return sk_sp<SkImageFilter>(new SkMagnifierImageFilter(lensBounds, zoomAmount, inset,
	sampling, std::move(input)));
	} else {
	// Zooming with a value less than 1 is technically a downscaling, which "works" but the
	// non-linear distortion behaves unintuitively. At zoomAmount = 1, this filter is an
	// expensive identity function so treat zoomAmount <= 1 as a no-op.
	return input;
	}
	}

	void SkRegisterMagnifierImageFilterFlattenable() {
	SK_REGISTER_FLATTENABLE(SkMagnifierImageFilter);
	}

	sk_sp<SkFlattenable> SkMagnifierImageFilter::CreateProc(SkReadBuffer& buffer) {
	if (buffer.isVersionLT(SkPicturePriv::kRevampMagnifierFilter)) {
	// This was actually a legacy magnifier image filter that was serialized. Chrome is the
	// only known client of the magnifier and its not used on webpages, so there shouldn't be
	// SKPs that actually contain a flattened magnifier filter (legacy or new).
	return nullptr;
	}

	SK_IMAGEFILTER_UNFLATTEN_COMMON(common, 1);

	SkRect lensBounds;
	buffer.readRect(&lensBounds);
	SkScalar zoomAmount = buffer.readScalar();
	SkScalar inset = buffer.readScalar();
	SkSamplingOptions sampling = buffer.readSampling();
	return SkImageFilters::Magnifier(lensBounds, zoomAmount, inset, sampling, common.getInput(0));
	}

	void SkMagnifierImageFilter::flatten(SkWriteBuffer& buffer) const {
	this->SkImageFilter_Base::flatten(buffer);
	buffer.writeRect(SkRect(fLensBounds));
	buffer.writeScalar(fZoomAmount);
	buffer.writeScalar(fInset);
	buffer.writeSampling(fSampling);
	}

	////////////////////////////////////////////////////////////////////////////////

	static sk_sp<SkShader> make_magnifier_shader(
	sk_sp<SkShader> input,
	const skif::LayerSpace<SkRect>& lensBounds,
	const skif::LayerSpace<SkMatrix>& zoomXform,
	const skif::LayerSpace<SkSize>& inset) {
	const SkRuntimeEffect* magEffect =
	GetKnownRuntimeEffect(SkKnownRuntimeEffects::StableKey::kMagnifier);

	SkRuntimeShaderBuilder builder(sk_ref_sp(magEffect));
	builder.child("src") = std::move(input);

	SkASSERT(inset.width() > 0.f && inset.height() > 0.f);
	builder.uniform("lensBounds") = SkRect(lensBounds);
	builder.uniform("zoomXform") = SkV4{/Tx/zoomXform.rc(0, 2), /Ty/zoomXform.rc(1, 2),
	/Sx/zoomXform.rc(0, 0), /Sy/zoomXform.rc(1, 1)};
	builder.uniform("invInset") = SkV2{1.f / inset.width(),
	1.f / inset.height()};

	return builder.makeShader();
	}

	////////////////////////////////////////////////////////////////////////////////

	skif::FilterResult SkMagnifierImageFilter::onFilterImage(const skif::Context& context) const {
	// These represent the full lens bounds and the ideal zoom center if everything is visible.
	skif::LayerSpace<SkRect> lensBounds = context.mapping().paramToLayer(fLensBounds);
	skif::LayerSpace<SkPoint> zoomCenter = lensBounds.center();

	// When magnifying near the edge of the screen, it's common for part of the lens bounds to be
	// offscreen, which also means its input filter cannot provide the full required input.
	// The magnifier's auto-sizing's goal is to cover the visible portion of the lens bounds.
	skif::LayerSpace<SkRect> visibleLensBounds = lensBounds;
	if (!visibleLensBounds.intersect(skif::LayerSpace<SkRect>(context.desiredOutput()))) {
	return {};
	}

	// We pre-emptively fit the zoomed-in src rect to what we expect the child input filter to
	// produce. This should be correct in all cases except for failure to create an offscreen image,
	// at which point there's nothing to be done anyway.
	skif::LayerSpace<SkRect> expectedChildOutput = lensBounds;
	if (std::optional<skif::LayerSpace<SkIRect>> output =
	this->getChildOutputLayerBounds(0, context.mapping(), context.source().layerBounds())) {
	expectedChildOutput = skif::LayerSpace<SkRect>(*output);
	}

	// Clamp the zoom center to be within the childOutput image
	zoomCenter = expectedChildOutput.clamp(zoomCenter);

	// The zoom we want to apply in layer-space is equal to
	// mapping.paramToLayer(SkMatrix::Scale(fZoomAmount)).decomposeScale(&layerZoom).
	// Because this filter only supports scale+translate matrices, the paramToLayer transform of
	// the parameter-space scale matrix is a no-op. Thus layerZoom == fZoomAmount and we can avoid
	// all of that math. This assumption is invalid if the matrix complexity is more than S+T.
	SkASSERT(this->getCTMCapability() == MatrixCapability::kScaleTranslate);
	float invZoom = 1.f / fZoomAmount;

	// The srcRect is the bounding box of the pixels that are linearly scaled up, about zoomCenter.
	// This is not the visual bounds of this upscaled region, but the bounds of the source pixels
	// that will fill the main magnified region (which is simply the inset of lensBounds). When
	// lensBounds has not been cropped by the actual input image, these equations are identical to
	// the more intuitive L/R = center.x -/+ width/(2zoom) and T/B = center.y -/+ height/(2zoom).
	// However, when lensBounds is cropped this automatically shifts the source rectangle away from
	// the original zoom center such that the upscaled area is contained within the input image.
	skif::LayerSpace<SkRect> srcRect{{
	lensBounds.left() * invZoom + zoomCenter.x()*(1.f - invZoom),
	lensBounds.top() * invZoom + zoomCenter.y()*(1.f - invZoom),
	lensBounds.right() * invZoom + zoomCenter.x()*(1.f - invZoom),
	lensBounds.bottom()* invZoom + zoomCenter.y()*(1.f - invZoom)}};

	// The above adjustment helps to account for offscreen, but when the magnifier is combined with
	// backdrop offsets, more significant fitting needs to be performed to pin the visible src
	// rect to what's available.
	auto zoomXform = skif::LayerSpace<SkMatrix>::RectToRect(lensBounds, srcRect);
	if (!expectedChildOutput.contains(visibleLensBounds)) {
	// We need to pick a new srcRect such that srcRect is contained within fitRect and fills
	// visibleLens, while maintaining the aspect ratio of the original srcRect -> lensBounds.
	srcRect = zoomXform.mapRect(visibleLensBounds);

	if (expectedChildOutput.width() >= srcRect.width() &&
	expectedChildOutput.height() >= srcRect.height()) {
	float left = srcRect.left() < expectedChildOutput.left() ?
	expectedChildOutput.left() :
	std::min(srcRect.right(), expectedChildOutput.right()) - srcRect.width();
	float top = srcRect.top() < expectedChildOutput.top() ?
	expectedChildOutput.top() :
	std::min(srcRect.bottom(), expectedChildOutput.bottom()) - srcRect.height();

	// Update transform to reflect fitted src
	srcRect = skif::LayerSpace<SkRect>(
	SkRect::MakeXYWH(left, top, srcRect.width(), srcRect.height()));
	zoomXform = skif::LayerSpace<SkMatrix>::RectToRect(visibleLensBounds, srcRect);
	} // Else not enough of the target is available to cover, so don't try adjusting
	}

	// When there is no SkSL support, or there's a 0 inset, the magnifier is equivalent to a
	// rect->rect transform and crop.
	skif::LayerSpace<SkSize> inset = context.mapping().paramToLayer(
	skif::ParameterSpace<SkSize>({fInset, fInset}));
	if (inset.width() <= 0.f \|\| inset.height() <= 0.f)
	{
	// When applying the zoom as a direct transform, we only require the visibleSrcRect as
	// input from the child filter, and transform it by the inverse of zoomXform (to go from
	// src to lens bounds, since it was constructed to go from lens to src).
	skif::LayerSpace<SkMatrix> invZoomXform;
	SkAssertResult(zoomXform.invert(&invZoomXform));
	skif::FilterResult childOutput =
	this->getChildOutput(0, context.withNewDesiredOutput(srcRect.roundOut()));
	return childOutput.applyTransform(context, invZoomXform, fSampling)
	.applyCrop(context, lensBounds.roundOut());
	}

	using ShaderFlags = skif::FilterResult::ShaderFlags;
	skif::FilterResult::Builder builder{context};
	builder.add(this->getChildOutput(0, context.withNewDesiredOutput(visibleLensBounds.roundOut())),
	{}, ShaderFlags::kNonTrivialSampling, fSampling);
	return builder.eval([&](SkSpan<sk_sp<SkShader>> inputs) {
	// If the input resolved to a null shader, the magnified output will be transparent too
	return inputs[0] ? make_magnifier_shader(inputs[0], lensBounds, zoomXform, inset)
	: nullptr;
	}, lensBounds.roundOut());
	}

	skif::LayerSpace<SkIRect> SkMagnifierImageFilter::onGetInputLayerBounds(
	const skif::Mapping& mapping,
	const skif::LayerSpace<SkIRect>& desiredOutput,
	std::optional<skif::LayerSpace<SkIRect>> contentBounds) const {
	// The required input is always the lens bounds. The filter distorts the pixels contained within
	// these bounds to zoom in on a portion of it, depending on the inset and zoom amount. However,
	// it adjusts the region based on cropping that occurs between what's requested and what's
	// provided. Theoretically it's possible that we could restrict the required input by the
	// desired output, but that cropping should not adjust the zoom region or inset. This is non
	// trivial to separate and is an unlikely use case so for now just require fLensBounds.
	skif::LayerSpace<SkIRect> requiredInput = mapping.paramToLayer(fLensBounds).roundOut();
	// Our required input is the desired output for our child image filter.
	return this->getChildInputLayerBounds(0, mapping, requiredInput, contentBounds);
	}

	std::optional<skif::LayerSpace<SkIRect>> SkMagnifierImageFilter::onGetOutputLayerBounds(
	const skif::Mapping& mapping,
	std::optional<skif::LayerSpace<SkIRect>> contentBounds) const {
	// The output of this filter is fLensBounds intersected with its child's output.
	auto output = this->getChildOutputLayerBounds(0, mapping, contentBounds);
	skif::LayerSpace<SkIRect> lensBounds = mapping.paramToLayer(fLensBounds).roundOut();
	if (!output \|\| lensBounds.intersect(*output)) {
	return lensBounds;
	} else {
	// Nothing to magnify
	return skif::LayerSpace<SkIRect>::Empty();
	}
	}

	SkRect SkMagnifierImageFilter::computeFastBounds(const SkRect& src) const {
	SkRect bounds = this->getInput(0) ? this->getInput(0)->computeFastBounds(src) : src;
	if (bounds.intersect(SkRect(fLensBounds))) {
	return bounds;
	} else {
	return SkRect::MakeEmpty();
	}
	}