tests/DetermineDomainModeTest.cpp - platform/external/skqp - Gitiles

 /*
  * Copyright 2017 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "Test.h"

 #if SK_SUPPORT_GPU

 #include "GrSurfaceProxy.h"
 #include "GrTextureProducer.h"
 #include "GrTextureProxy.h"

 // For DetermineDomainMode (in the MDB world) we have 3 rects:
 //      1) the final instantiated backing storage (i.e., the actual GrTexture's extent)
 //      2) the proxy's extent, which may or may not match the GrTexture's extent
 //      3) the constraint rect, which can optionally be hard or soft
 // This test "fuzzes" all the combinations of these rects.
 class GrTextureProducer_TestAccess {
 public:
     using DomainMode = GrTextureProducer::DomainMode;

     static DomainMode DetermineDomainMode(const SkRect& constraintRect,
                                           GrTextureProducer::FilterConstraint filterConstraint,
                                           bool coordsLimitedToConstraintRect,
                                           GrTextureProxy* proxy,
                                           const GrSamplerState::Filter* filterModeOrNullForBicubic,
                                           SkRect* domainRect) {
         return GrTextureProducer::DetermineDomainMode(constraintRect,
                                                       filterConstraint,
                                                       coordsLimitedToConstraintRect,
                                                       proxy,
                                                       filterModeOrNullForBicubic,
                                                       domainRect);
     }
 };

 using DomainMode = GrTextureProducer_TestAccess::DomainMode;

 class RectInfo {
 public:
     enum Side { kLeft = 0, kTop = 1, kRight = 2, kBot = 3 };

     enum EdgeType {
         kSoft = 0,   // there is data on the other side of this edge that we are allowed to sample
         kHard = 1,   // the backing resource ends at this edge
         kBad  = 2    // we can't sample across this edge
     };

     void set(const SkRect& rect, EdgeType left, EdgeType top, EdgeType right, EdgeType bot,
              const char* name) {
         fRect = rect;
         fTypes[kLeft]  = left;
         fTypes[kTop]   = top;
         fTypes[kRight] = right;
         fTypes[kBot]   = bot;
         fName = name;
     }

     const SkRect& rect() const { return fRect; }
     EdgeType edgeType(Side side) const { return fTypes[side]; }
     const char* name() const { return fName; }

 #ifdef SK_DEBUG
     bool isHardOrBadAllAround() const {
         for (int i = 0; i < 4; ++i) {
             if (kHard != fTypes[i] && kBad != fTypes[i]) {
                 return false;
             }
         }
         return true;
     }
 #endif

     bool hasABad() const {
         for (int i = 0; i < 4; ++i) {
             if (kBad == fTypes[i]) {
                 return true;
             }
         }
         return false;
     }

 #ifdef SK_DEBUG
     void print(const char* label) const {
         SkDebugf("%s: %s (%.1f, %.1f, %.1f, %.1f), L: %s T: %s R: %s B: %s\n",
                  label, fName,
                  fRect.fLeft, fRect.fTop, fRect.fRight, fRect.fBottom,
                  ToStr(fTypes[kLeft]), ToStr(fTypes[kTop]),
                  ToStr(fTypes[kRight]), ToStr(fTypes[kBot]));
     }
 #endif

 private:
 #ifdef SK_DEBUG
     static const char* ToStr(EdgeType type) {
         static const char* names[] = { "soft", "hard", "bad" };
         return names[type];
     }
 #endif

     RectInfo operator=(const RectInfo& other); // disallow

     SkRect      fRect;
     EdgeType    fTypes[4];
     const char* fName;

 };

 static sk_sp<GrTextureProxy> create_proxy(GrResourceProvider* resourceProvider,
                                           bool isPowerOfTwo,
                                           bool isExact,
                                           RectInfo* rect) {
     int size = isPowerOfTwo ? 128 : 100;
     SkBackingFit fit = isExact ? SkBackingFit::kExact : SkBackingFit::kApprox;

     GrSurfaceDesc desc;
     desc.fOrigin = kTopLeft_GrSurfaceOrigin;
     desc.fWidth = size;
     desc.fHeight = size;
     desc.fConfig = kRGBA_8888_GrPixelConfig;

     static const char* name = "proxy";

     // Proxies are always hard on the left and top but can be bad on the right and bottom
     rect->set(SkRect::MakeWH(size, size),
               RectInfo::kHard,
               RectInfo::kHard,
               (isPowerOfTwo || isExact) ? RectInfo::kHard : RectInfo::kBad,
               (isPowerOfTwo || isExact) ? RectInfo::kHard : RectInfo::kBad,
               name);

     sk_sp<GrTextureProxy> proxy = GrSurfaceProxy::MakeDeferred(resourceProvider,
                                                                desc, fit,
                                                                SkBudgeted::kYes);
     return proxy;
 }

 static RectInfo::EdgeType compute_inset_edgetype(RectInfo::EdgeType previous,
                                                  bool isInsetHard, bool coordsAreLimitedToRect,
                                                  float insetAmount, float halfFilterWidth) {
     if (isInsetHard) {
         if (coordsAreLimitedToRect) {
             SkASSERT(halfFilterWidth >= 0.0f);
             if (0.0f == halfFilterWidth) {
                 return RectInfo::kSoft;
             }
         }

         if (0.0f == insetAmount && RectInfo::kHard == previous) {
             return RectInfo::kHard;
         }

         return RectInfo::kBad;
     }

     if (RectInfo::kHard == previous) {
         return RectInfo::kHard;
     }

     if (coordsAreLimitedToRect) {
         SkASSERT(halfFilterWidth >= 0.0f);
         if (0.0 == halfFilterWidth || insetAmount > halfFilterWidth) {
             return RectInfo::kSoft;
         }
     }

     return previous;
 }

 static const int kInsetLeft_Flag  = 0x1;
 static const int kInsetTop_Flag   = 0x2;
 static const int kInsetRight_Flag = 0x4;
 static const int kInsetBot_Flag   = 0x8;

 // If 'isInsetHard' is true we can't sample across the inset boundary.
 // If 'areCoordsLimitedToRect' is true the client promises to never sample outside the inset.
 static const SkRect* generic_inset(const RectInfo& enclosing,
                                    RectInfo* result,
                                    bool isInsetHard,
                                    bool areCoordsLimitedToRect,
                                    float insetAmount,
                                    float halfFilterWidth,
                                    uint32_t flags,
                                    const char* name) {
     SkRect newR = enclosing.rect();

     RectInfo::EdgeType left = enclosing.edgeType(RectInfo::kLeft);
     if (flags & kInsetLeft_Flag) {
         newR.fLeft += insetAmount;
         left = compute_inset_edgetype(left, isInsetHard, areCoordsLimitedToRect,
                                       insetAmount, halfFilterWidth);
     } else {
         left = compute_inset_edgetype(left, isInsetHard, areCoordsLimitedToRect,
                                       0.0f, halfFilterWidth);
     }

     RectInfo::EdgeType top = enclosing.edgeType(RectInfo::kTop);
     if (flags & kInsetTop_Flag) {
         newR.fTop += insetAmount;
         top = compute_inset_edgetype(top, isInsetHard, areCoordsLimitedToRect,
                                      insetAmount, halfFilterWidth);
     } else {
         top = compute_inset_edgetype(top, isInsetHard, areCoordsLimitedToRect,
                                      0.0f, halfFilterWidth);
     }

     RectInfo::EdgeType right = enclosing.edgeType(RectInfo::kRight);
     if (flags & kInsetRight_Flag) {
         newR.fRight -= insetAmount;
         right = compute_inset_edgetype(right, isInsetHard, areCoordsLimitedToRect,
                                        insetAmount, halfFilterWidth);
     } else {
         right = compute_inset_edgetype(right, isInsetHard, areCoordsLimitedToRect,
                                        0.0f, halfFilterWidth);
     }

     RectInfo::EdgeType bot = enclosing.edgeType(RectInfo::kBot);
     if (flags & kInsetBot_Flag) {
         newR.fBottom -= insetAmount;
         bot = compute_inset_edgetype(bot, isInsetHard, areCoordsLimitedToRect,
                                      insetAmount, halfFilterWidth);
     } else {
         bot = compute_inset_edgetype(bot, isInsetHard, areCoordsLimitedToRect,
                                      0.0f, halfFilterWidth);
     }

     result->set(newR, left, top, right, bot, name);
     return &result->rect();
 }

 // Make a rect that only touches the enclosing rect on the left.
 static const SkRect* left_only(const RectInfo& enclosing,
                                RectInfo* result,
                                bool isInsetHard,
                                bool areCoordsLimitedToRect,
                                float insetAmount,
                                float halfFilterWidth) {
     static const char* name = "left";
     return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
                          insetAmount, halfFilterWidth,
                          kInsetTop_Flag|kInsetRight_Flag|kInsetBot_Flag, name);
 }

 // Make a rect that only touches the enclosing rect on the top.
 static const SkRect* top_only(const RectInfo& enclosing,
                                RectInfo* result,
                                bool isInsetHard,
                                bool areCoordsLimitedToRect,
                                float insetAmount,
                                float halfFilterWidth) {
     static const char* name = "top";
     return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
                          insetAmount, halfFilterWidth,
                          kInsetLeft_Flag|kInsetRight_Flag|kInsetBot_Flag, name);
 }

 // Make a rect that only touches the enclosing rect on the right.
 static const SkRect* right_only(const RectInfo& enclosing,
                                 RectInfo* result,
                                 bool isInsetHard,
                                 bool areCoordsLimitedToRect,
                                 float insetAmount,
                                 float halfFilterWidth) {
     static const char* name = "right";
     return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
                          insetAmount, halfFilterWidth,
                          kInsetLeft_Flag|kInsetTop_Flag|kInsetBot_Flag, name);
 }

 // Make a rect that only touches the enclosing rect on the bottom.
 static const SkRect* bot_only(const RectInfo& enclosing,
                               RectInfo* result,
                               bool isInsetHard,
                               bool areCoordsLimitedToRect,
                               float insetAmount,
                               float halfFilterWidth) {
     static const char* name = "bot";
     return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
                          insetAmount, halfFilterWidth,
                          kInsetLeft_Flag|kInsetTop_Flag|kInsetRight_Flag, name);
 }

 // Make a rect that is inset all around.
 static const SkRect* full_inset(const RectInfo& enclosing,
                                 RectInfo* result,
                                 bool isInsetHard,
                                 bool areCoordsLimitedToRect,
                                 float insetAmount,
                                 float halfFilterWidth) {
     static const char* name = "all";
     return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
                          insetAmount, halfFilterWidth,
                          kInsetLeft_Flag|kInsetTop_Flag|kInsetRight_Flag|kInsetBot_Flag, name);
 }

 // Make a rect with no inset. This is only used for constraint rect creation.
 static const SkRect* no_inset(const RectInfo& enclosing,
                               RectInfo* result,
                               bool isInsetHard,
                               bool areCoordsLimitedToRect,
                               float insetAmount,
                               float halfFilterWidth) {
     static const char* name = "none";
     return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
                          insetAmount, halfFilterWidth, 0, name);
 }

 static void proxy_test(skiatest::Reporter* reporter, GrResourceProvider* resourceProvider) {
     GrTextureProducer_TestAccess::DomainMode actualMode, expectedMode;
     SkRect actualDomainRect;

     static const GrSamplerState::Filter gModes[] = {
             GrSamplerState::Filter::kNearest,
             GrSamplerState::Filter::kBilerp,
             GrSamplerState::Filter::kMipMap,
     };

     static const GrSamplerState::Filter* gModePtrs[] = {&gModes[0], &gModes[1], nullptr,
                                                         &gModes[2]};

     static const float gHalfFilterWidth[] = { 0.0f, 0.5f, 1.5f, 10000.0f };

     for (auto isPowerOfTwoSized : { true, false }) {
         for (auto isExact : { true, false }) {
             RectInfo outermost;

             sk_sp<GrTextureProxy> proxy = create_proxy(resourceProvider, isPowerOfTwoSized,
                                                        isExact, &outermost);
             SkASSERT(outermost.isHardOrBadAllAround());

             for (auto isConstraintRectHard : { true, false }) {
                 for (auto areCoordsLimitedToConstraintRect : { true, false }) {
                     for (int filterMode = 0; filterMode < 4; ++filterMode) {
                         for (auto constraintRectMaker : { left_only, top_only, right_only,
                             bot_only, full_inset, no_inset }) {
                             for (auto insetAmt : { 0.25f, 0.75f, 1.25f, 1.75f, 5.0f }) {
                                 RectInfo constraintRectStorage;
                                 const SkRect* constraintRect = (*constraintRectMaker)(
                                         outermost,
                                         &constraintRectStorage,
                                         isConstraintRectHard,
                                         areCoordsLimitedToConstraintRect,
                                         insetAmt,
                                         gHalfFilterWidth[filterMode]);
                                 SkASSERT(constraintRect); // always need one of these
                                 SkASSERT(outermost.rect().contains(*constraintRect));

                                 actualMode = GrTextureProducer_TestAccess::DetermineDomainMode(
                                         *constraintRect,
                                         isConstraintRectHard
                                             ? GrTextureProducer::kYes_FilterConstraint
                                             : GrTextureProducer::kNo_FilterConstraint,
                                         areCoordsLimitedToConstraintRect,
                                         proxy.get(),
                                         gModePtrs[filterMode],
                                         &actualDomainRect);

                                 expectedMode = DomainMode::kNoDomain_DomainMode;
                                 if (constraintRectStorage.hasABad()) {
                                     if (3 == filterMode) {
                                         expectedMode = DomainMode::kTightCopy_DomainMode;
                                     } else {
                                         expectedMode = DomainMode::kDomain_DomainMode;
                                     }
                                 }

                                 REPORTER_ASSERT(reporter, expectedMode == actualMode);
                                 // TODO: add a check that the returned domain rect is correct
                             }
                         }
                     }
                 }
             }
         }
     }
 }

 DEF_GPUTEST_FOR_RENDERING_CONTEXTS(DetermineDomainModeTest, reporter, ctxInfo) {
     GrContext* context = ctxInfo.grContext();

     proxy_test(reporter, context->resourceProvider());
 }

 #endif
	/*
	* Copyright 2017 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "Test.h"

	#if SK_SUPPORT_GPU

	#include "GrSurfaceProxy.h"
	#include "GrTextureProducer.h"
	#include "GrTextureProxy.h"

	// For DetermineDomainMode (in the MDB world) we have 3 rects:
	// 1) the final instantiated backing storage (i.e., the actual GrTexture's extent)
	// 2) the proxy's extent, which may or may not match the GrTexture's extent
	// 3) the constraint rect, which can optionally be hard or soft
	// This test "fuzzes" all the combinations of these rects.
	class GrTextureProducer_TestAccess {
	public:
	using DomainMode = GrTextureProducer::DomainMode;

	static DomainMode DetermineDomainMode(const SkRect& constraintRect,
	GrTextureProducer::FilterConstraint filterConstraint,
	bool coordsLimitedToConstraintRect,
	GrTextureProxy* proxy,
	const GrSamplerState::Filter* filterModeOrNullForBicubic,
	SkRect* domainRect) {
	return GrTextureProducer::DetermineDomainMode(constraintRect,
	filterConstraint,
	coordsLimitedToConstraintRect,
	proxy,
	filterModeOrNullForBicubic,
	domainRect);
	}
	};

	using DomainMode = GrTextureProducer_TestAccess::DomainMode;

	class RectInfo {
	public:
	enum Side { kLeft = 0, kTop = 1, kRight = 2, kBot = 3 };

	enum EdgeType {
	kSoft = 0, // there is data on the other side of this edge that we are allowed to sample
	kHard = 1, // the backing resource ends at this edge
	kBad = 2 // we can't sample across this edge
	};

	void set(const SkRect& rect, EdgeType left, EdgeType top, EdgeType right, EdgeType bot,
	const char* name) {
	fRect = rect;
	fTypes[kLeft] = left;
	fTypes[kTop] = top;
	fTypes[kRight] = right;
	fTypes[kBot] = bot;
	fName = name;
	}

	const SkRect& rect() const { return fRect; }
	EdgeType edgeType(Side side) const { return fTypes[side]; }
	const char* name() const { return fName; }

	#ifdef SK_DEBUG
	bool isHardOrBadAllAround() const {
	for (int i = 0; i < 4; ++i) {
	if (kHard != fTypes[i] && kBad != fTypes[i]) {
	return false;
	}
	}
	return true;
	}
	#endif

	bool hasABad() const {
	for (int i = 0; i < 4; ++i) {
	if (kBad == fTypes[i]) {
	return true;
	}
	}
	return false;
	}

	#ifdef SK_DEBUG
	void print(const char* label) const {
	SkDebugf("%s: %s (%.1f, %.1f, %.1f, %.1f), L: %s T: %s R: %s B: %s\n",
	label, fName,
	fRect.fLeft, fRect.fTop, fRect.fRight, fRect.fBottom,
	ToStr(fTypes[kLeft]), ToStr(fTypes[kTop]),
	ToStr(fTypes[kRight]), ToStr(fTypes[kBot]));
	}
	#endif

	private:
	#ifdef SK_DEBUG
	static const char* ToStr(EdgeType type) {
	static const char* names[] = { "soft", "hard", "bad" };
	return names[type];
	}
	#endif

	RectInfo operator=(const RectInfo& other); // disallow

	SkRect fRect;
	EdgeType fTypes[4];
	const char* fName;

	};

	static sk_sp<GrTextureProxy> create_proxy(GrResourceProvider* resourceProvider,
	bool isPowerOfTwo,
	bool isExact,
	RectInfo* rect) {
	int size = isPowerOfTwo ? 128 : 100;
	SkBackingFit fit = isExact ? SkBackingFit::kExact : SkBackingFit::kApprox;

	GrSurfaceDesc desc;
	desc.fOrigin = kTopLeft_GrSurfaceOrigin;
	desc.fWidth = size;
	desc.fHeight = size;
	desc.fConfig = kRGBA_8888_GrPixelConfig;

	static const char* name = "proxy";

	// Proxies are always hard on the left and top but can be bad on the right and bottom
	rect->set(SkRect::MakeWH(size, size),
	RectInfo::kHard,
	RectInfo::kHard,
	(isPowerOfTwo \|\| isExact) ? RectInfo::kHard : RectInfo::kBad,
	(isPowerOfTwo \|\| isExact) ? RectInfo::kHard : RectInfo::kBad,
	name);

	sk_sp<GrTextureProxy> proxy = GrSurfaceProxy::MakeDeferred(resourceProvider,
	desc, fit,
	SkBudgeted::kYes);
	return proxy;
	}

	static RectInfo::EdgeType compute_inset_edgetype(RectInfo::EdgeType previous,
	bool isInsetHard, bool coordsAreLimitedToRect,
	float insetAmount, float halfFilterWidth) {
	if (isInsetHard) {
	if (coordsAreLimitedToRect) {
	SkASSERT(halfFilterWidth >= 0.0f);
	if (0.0f == halfFilterWidth) {
	return RectInfo::kSoft;
	}
	}

	if (0.0f == insetAmount && RectInfo::kHard == previous) {
	return RectInfo::kHard;
	}

	return RectInfo::kBad;
	}

	if (RectInfo::kHard == previous) {
	return RectInfo::kHard;
	}

	if (coordsAreLimitedToRect) {
	SkASSERT(halfFilterWidth >= 0.0f);
	if (0.0 == halfFilterWidth \|\| insetAmount > halfFilterWidth) {
	return RectInfo::kSoft;
	}
	}

	return previous;
	}

	static const int kInsetLeft_Flag = 0x1;
	static const int kInsetTop_Flag = 0x2;
	static const int kInsetRight_Flag = 0x4;
	static const int kInsetBot_Flag = 0x8;

	// If 'isInsetHard' is true we can't sample across the inset boundary.
	// If 'areCoordsLimitedToRect' is true the client promises to never sample outside the inset.
	static const SkRect* generic_inset(const RectInfo& enclosing,
	RectInfo* result,
	bool isInsetHard,
	bool areCoordsLimitedToRect,
	float insetAmount,
	float halfFilterWidth,
	uint32_t flags,
	const char* name) {
	SkRect newR = enclosing.rect();

	RectInfo::EdgeType left = enclosing.edgeType(RectInfo::kLeft);
	if (flags & kInsetLeft_Flag) {
	newR.fLeft += insetAmount;
	left = compute_inset_edgetype(left, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth);
	} else {
	left = compute_inset_edgetype(left, isInsetHard, areCoordsLimitedToRect,
	0.0f, halfFilterWidth);
	}

	RectInfo::EdgeType top = enclosing.edgeType(RectInfo::kTop);
	if (flags & kInsetTop_Flag) {
	newR.fTop += insetAmount;
	top = compute_inset_edgetype(top, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth);
	} else {
	top = compute_inset_edgetype(top, isInsetHard, areCoordsLimitedToRect,
	0.0f, halfFilterWidth);
	}

	RectInfo::EdgeType right = enclosing.edgeType(RectInfo::kRight);
	if (flags & kInsetRight_Flag) {
	newR.fRight -= insetAmount;
	right = compute_inset_edgetype(right, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth);
	} else {
	right = compute_inset_edgetype(right, isInsetHard, areCoordsLimitedToRect,
	0.0f, halfFilterWidth);
	}

	RectInfo::EdgeType bot = enclosing.edgeType(RectInfo::kBot);
	if (flags & kInsetBot_Flag) {
	newR.fBottom -= insetAmount;
	bot = compute_inset_edgetype(bot, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth);
	} else {
	bot = compute_inset_edgetype(bot, isInsetHard, areCoordsLimitedToRect,
	0.0f, halfFilterWidth);
	}

	result->set(newR, left, top, right, bot, name);
	return &result->rect();
	}

	// Make a rect that only touches the enclosing rect on the left.
	static const SkRect* left_only(const RectInfo& enclosing,
	RectInfo* result,
	bool isInsetHard,
	bool areCoordsLimitedToRect,
	float insetAmount,
	float halfFilterWidth) {
	static const char* name = "left";
	return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth,
	kInsetTop_Flag\|kInsetRight_Flag\|kInsetBot_Flag, name);
	}

	// Make a rect that only touches the enclosing rect on the top.
	static const SkRect* top_only(const RectInfo& enclosing,
	RectInfo* result,
	bool isInsetHard,
	bool areCoordsLimitedToRect,
	float insetAmount,
	float halfFilterWidth) {
	static const char* name = "top";
	return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth,
	kInsetLeft_Flag\|kInsetRight_Flag\|kInsetBot_Flag, name);
	}

	// Make a rect that only touches the enclosing rect on the right.
	static const SkRect* right_only(const RectInfo& enclosing,
	RectInfo* result,
	bool isInsetHard,
	bool areCoordsLimitedToRect,
	float insetAmount,
	float halfFilterWidth) {
	static const char* name = "right";
	return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth,
	kInsetLeft_Flag\|kInsetTop_Flag\|kInsetBot_Flag, name);
	}

	// Make a rect that only touches the enclosing rect on the bottom.
	static const SkRect* bot_only(const RectInfo& enclosing,
	RectInfo* result,
	bool isInsetHard,
	bool areCoordsLimitedToRect,
	float insetAmount,
	float halfFilterWidth) {
	static const char* name = "bot";
	return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth,
	kInsetLeft_Flag\|kInsetTop_Flag\|kInsetRight_Flag, name);
	}

	// Make a rect that is inset all around.
	static const SkRect* full_inset(const RectInfo& enclosing,
	RectInfo* result,
	bool isInsetHard,
	bool areCoordsLimitedToRect,
	float insetAmount,
	float halfFilterWidth) {
	static const char* name = "all";
	return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth,
	kInsetLeft_Flag\|kInsetTop_Flag\|kInsetRight_Flag\|kInsetBot_Flag, name);
	}

	// Make a rect with no inset. This is only used for constraint rect creation.
	static const SkRect* no_inset(const RectInfo& enclosing,
	RectInfo* result,
	bool isInsetHard,
	bool areCoordsLimitedToRect,
	float insetAmount,
	float halfFilterWidth) {
	static const char* name = "none";
	return generic_inset(enclosing, result, isInsetHard, areCoordsLimitedToRect,
	insetAmount, halfFilterWidth, 0, name);
	}

	static void proxy_test(skiatest::Reporter* reporter, GrResourceProvider* resourceProvider) {
	GrTextureProducer_TestAccess::DomainMode actualMode, expectedMode;
	SkRect actualDomainRect;

	static const GrSamplerState::Filter gModes[] = {
	GrSamplerState::Filter::kNearest,
	GrSamplerState::Filter::kBilerp,
	GrSamplerState::Filter::kMipMap,
	};

	static const GrSamplerState::Filter* gModePtrs[] = {&gModes[0], &gModes[1], nullptr,
	&gModes[2]};

	static const float gHalfFilterWidth[] = { 0.0f, 0.5f, 1.5f, 10000.0f };

	for (auto isPowerOfTwoSized : { true, false }) {
	for (auto isExact : { true, false }) {
	RectInfo outermost;

	sk_sp<GrTextureProxy> proxy = create_proxy(resourceProvider, isPowerOfTwoSized,
	isExact, &outermost);
	SkASSERT(outermost.isHardOrBadAllAround());

	for (auto isConstraintRectHard : { true, false }) {
	for (auto areCoordsLimitedToConstraintRect : { true, false }) {
	for (int filterMode = 0; filterMode < 4; ++filterMode) {
	for (auto constraintRectMaker : { left_only, top_only, right_only,
	bot_only, full_inset, no_inset }) {
	for (auto insetAmt : { 0.25f, 0.75f, 1.25f, 1.75f, 5.0f }) {
	RectInfo constraintRectStorage;
	const SkRect* constraintRect = (*constraintRectMaker)(
	outermost,
	&constraintRectStorage,
	isConstraintRectHard,
	areCoordsLimitedToConstraintRect,
	insetAmt,
	gHalfFilterWidth[filterMode]);
	SkASSERT(constraintRect); // always need one of these
	SkASSERT(outermost.rect().contains(*constraintRect));

	actualMode = GrTextureProducer_TestAccess::DetermineDomainMode(
	*constraintRect,
	isConstraintRectHard
	? GrTextureProducer::kYes_FilterConstraint
	: GrTextureProducer::kNo_FilterConstraint,
	areCoordsLimitedToConstraintRect,
	proxy.get(),
	gModePtrs[filterMode],
	&actualDomainRect);

	expectedMode = DomainMode::kNoDomain_DomainMode;
	if (constraintRectStorage.hasABad()) {
	if (3 == filterMode) {
	expectedMode = DomainMode::kTightCopy_DomainMode;
	} else {
	expectedMode = DomainMode::kDomain_DomainMode;
	}
	}

	REPORTER_ASSERT(reporter, expectedMode == actualMode);
	// TODO: add a check that the returned domain rect is correct
	}
	}
	}
	}
	}
	}
	}
	}

	DEF_GPUTEST_FOR_RENDERING_CONTEXTS(DetermineDomainModeTest, reporter, ctxInfo) {
	GrContext* context = ctxInfo.grContext();

	proxy_test(reporter, context->resourceProvider());
	}

	#endif