tests/GrTextBlobTest.cpp - platform/external/skia - Gitiles

 /*
  * Copyright 2020 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "include/core/SkBitmap.h"
 #include "include/core/SkCanvas.h"
 #include "include/core/SkSurface.h"
 #include "include/core/SkTextBlob.h"
 #include "src/core/SkSurfacePriv.h"
 #include "src/gpu/text/GrTextBlob.h"
 #include "tests/Test.h"
 #include "tools/ToolUtils.h"

 SkBitmap rasterize_blob(SkTextBlob* blob,
                         const SkPaint& paint,
                         GrRecordingContext* rContext,
                         const SkMatrix& matrix) {
     const SkImageInfo info =
             SkImageInfo::Make(500, 500, kN32_SkColorType, kPremul_SkAlphaType);
     auto surface = SkSurface::MakeRenderTarget(rContext, SkBudgeted::kNo, info);
     auto canvas = surface->getCanvas();
     canvas->drawColor(SK_ColorWHITE);
     canvas->concat(matrix);
     canvas->drawTextBlob(blob, 10, 250, paint);
     SkBitmap bitmap;
     bitmap.allocN32Pixels(500, 500);
     surface->readPixels(bitmap, 0, 0);
     return bitmap;
 }

 bool check_for_black(const SkBitmap& bm) {
     for (int y = 0; y < bm.height(); y++) {
         for (int x = 0; x < bm.width(); x++) {
             if (bm.getColor(x, y) == SK_ColorBLACK) {
                 return true;
             }
         }
     }
     return false;
 }

 DEF_GPUTEST_FOR_RENDERING_CONTEXTS(GrTextBlobScaleAnimation, reporter, ctxInfo) {
     auto tf = ToolUtils::create_portable_typeface("Mono", SkFontStyle());
     SkFont font{tf};
     font.setHinting(SkFontHinting::kNormal);
     font.setSize(12);
     font.setEdging(SkFont::Edging::kAntiAlias);
     font.setSubpixel(true);

     SkTextBlobBuilder builder;
     const auto& runBuffer = builder.allocRunPosH(font, 30, 0, nullptr);

     for (int i = 0; i < 30; i++) {
         runBuffer.glyphs[i] = static_cast<SkGlyphID>(i);
         runBuffer.pos[i] = SkIntToScalar(i);
     }
     auto blob = builder.make();

     auto dContext = ctxInfo.directContext();
     bool anyBlack = false;
     for (int n = -13; n < 5; n++) {
         SkMatrix m = SkMatrix::Scale(std::exp2(n), std::exp2(n));
         auto bm = rasterize_blob(blob.get(), SkPaint(), dContext, m);
         anyBlack |= check_for_black(bm);
     }
     REPORTER_ASSERT(reporter, anyBlack);
 }

 // Test extreme positions for all combinations of positions, origins, and translation matrices.
 DEF_GPUTEST_FOR_RENDERING_CONTEXTS(GrTextBlobMoveAround, reporter, ctxInfo) {
     auto tf = ToolUtils::create_portable_typeface("Mono", SkFontStyle());
     SkFont font{tf};
     font.setHinting(SkFontHinting::kNormal);
     font.setSize(12);
     font.setEdging(SkFont::Edging::kAntiAlias);
     font.setSubpixel(true);

     auto makeBlob = [&](SkPoint delta) {
         SkTextBlobBuilder builder;
         const auto& runBuffer = builder.allocRunPos(font, 30, nullptr);

         for (int i = 0; i < 30; i++) {
             runBuffer.glyphs[i] = static_cast<SkGlyphID>(i);
             runBuffer.points()[i] = SkPoint::Make(SkIntToScalar(i*10) + delta.x(), 50 + delta.y());
         }
         return builder.make();
     };

     auto dContext = ctxInfo.directContext();
     auto rasterizeBlob = [&](SkTextBlob* blob, SkPoint origin, const SkMatrix& matrix) {
         SkPaint paint;
         const SkImageInfo info =
                 SkImageInfo::Make(350, 80, kN32_SkColorType, kPremul_SkAlphaType);
         auto surface = SkSurface::MakeRenderTarget(dContext, SkBudgeted::kNo, info);
         auto canvas = surface->getCanvas();
         canvas->drawColor(SK_ColorWHITE);
         canvas->concat(matrix);
         canvas->drawTextBlob(blob, 10 + origin.x(), 40 + origin.y(), paint);
         SkBitmap bitmap;
         bitmap.allocN32Pixels(350, 80);
         surface->readPixels(bitmap, 0, 0);
         return bitmap;
     };

     SkBitmap benchMark;
     {
         auto blob = makeBlob({0, 0});
         benchMark = rasterizeBlob(blob.get(), {0,0}, SkMatrix::I());
     }

     auto checkBitmap = [&](const SkBitmap& bitmap) {
         REPORTER_ASSERT(reporter, benchMark.width() == bitmap.width());
         REPORTER_ASSERT(reporter, benchMark.width() == bitmap.width());

         for (int y = 0; y < benchMark.height(); y++) {
             for (int x = 0; x < benchMark.width(); x++) {
                 if (benchMark.getColor(x, y) != bitmap.getColor(x, y)) {
                     return false;
                 }
             }
         }
         return true;
     };

     SkScalar interestingNumbers[] = {-10'000'000, -1'000'000, -1, 0, +1, +1'000'000, +10'000'000};
     for (auto originX : interestingNumbers) {
         for (auto originY : interestingNumbers) {
             for (auto translateX : interestingNumbers) {
                 for (auto translateY : interestingNumbers) {
                     // Make sure everything adds to zero.
                     SkScalar deltaPosX = -(originX + translateX);
                     SkScalar deltaPosY = -(originY + translateY);
                     auto blob = makeBlob({deltaPosX, deltaPosY});
                     SkMatrix t = SkMatrix::Translate(translateX, translateY);
                     auto bitmap = rasterizeBlob(blob.get(), {originX, originY}, t);
                     REPORTER_ASSERT(reporter, checkBitmap(bitmap));
                 }
             }
         }
     }
 }

 DEF_TEST(GrBagOfBytesBasic, r) {
     const int k4K = 1 << 12;
     {
         // GrBagOfBytes::MinimumSizeWithOverhead(-1); // This should fail
         GrBagOfBytes::PlatformMinimumSizeWithOverhead(0, 16);
         GrBagOfBytes::PlatformMinimumSizeWithOverhead(
                 std::numeric_limits<int>::max() - k4K - 1, 16);
         // GrBagOfBytes::MinimumSizeWithOverhead(std::numeric_limits<int>::max() - k4K);  // Fail
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 1, 16, 16) == 31);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 1, 16, 16) == 32);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 1, 16, 16) == 94);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 8, 16, 16) == 24);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 8, 16, 16) == 32);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 8, 16, 16) == 88);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 16, 16, 16) == 16);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 16, 16, 16) == 32);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 16, 16, 16) == 80);

         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 1, 8, 16) == 23);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 1, 8, 16) == 24);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 1, 8, 16) == 86);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 8, 8, 16) == 16);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 8, 8, 16) == 24);
         REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 8, 8, 16) == 80);
     }

     {
         GrBagOfBytes bob;
         // bob.alignedBytes(0, 1);  // This should fail
         // bob.alignedBytes(1, 0);  // This should fail
         // bob.alignedBytes(1, 3);  // This should fail

         struct Big {
             char stuff[std::numeric_limits<int>::max()];
         };
         // bob.alignedBytes(sizeof(Big), 1);  // this should fail
         // bob.allocateBytesFor<Big>();  // this should not compile
         // The following should run, but should not be regularly tested.
         // bob.allocateBytesFor<int>((std::numeric_limits<int>::max() - (1<<12)) / sizeof(int) - 1);
         // The following should fail
         // bob.allocateBytesFor<int>((std::numeric_limits<int>::max() - (1<<12)) / sizeof(int));
         bob.alignedBytes(1, 1);  // To avoid unused variable problems.
     }

     // Force multiple block allocation
     {
         GrBagOfBytes bob;
         const int k64K = 1 << 16;
         // By default allocation block sizes start at 1K and go up with fib. This should allocate
         // 10 individual blocks.
         for (int i = 0; i < 10; i++) {
             bob.alignedBytes(k64K, 1);
         }
     }
 }

 // Helper for defining allocators with inline/reserved storage.
 // For argument declarations, stick to the base type (GrSubRunAllocator).
 // Note: Inheriting from the storage first means the storage will outlive the
 // GrSubRunAllocator, letting ~GrSubRunAllocator read it as it calls destructors.
 // (This is mostly only relevant for strict tools like MSAN.)

 template <size_t inlineSize>
 class GrSTSubRunAllocator : private GrBagOfBytes::Storage<inlineSize>, public GrSubRunAllocator {
 public:
     explicit GrSTSubRunAllocator(int firstHeapAllocation =
                                     GrBagOfBytes::PlatformMinimumSizeWithOverhead(inlineSize, 1))
             : GrSubRunAllocator{this->data(), SkTo<int>(this->size()), firstHeapAllocation} {}
 };

 DEF_TEST(GrSubRunAllocator, r) {
     static int created = 0;
     static int destroyed = 0;
     struct Foo {
         Foo() : fI{-2}, fX{-3} { created++; }
         Foo(int i, float x) : fI{i}, fX{x} { created++; }
         ~Foo() { destroyed++; }
         int fI;
         float fX;
     };

     struct alignas(8) OddAlignment {
         char buf[10];
     };

     auto exercise = [&](GrSubRunAllocator* alloc) {
         created = 0;
         destroyed = 0;
         {
             int* p = alloc->makePOD<int>(3);
             REPORTER_ASSERT(r, *p == 3);
             int* q = alloc->makePOD<int>(7);
             REPORTER_ASSERT(r, *q == 7);

             REPORTER_ASSERT(r, *alloc->makePOD<int>(3) == 3);
             auto foo = alloc->makeUnique<Foo>(3, 4.0f);
             REPORTER_ASSERT(r, foo->fI == 3);
             REPORTER_ASSERT(r, foo->fX == 4.0f);
             REPORTER_ASSERT(r, created == 1);
             REPORTER_ASSERT(r, destroyed == 0);

             alloc->makePODArray<int>(10);

             auto fooArray = alloc->makeUniqueArray<Foo>(10);
             REPORTER_ASSERT(r, fooArray[3].fI == -2);
             REPORTER_ASSERT(r, fooArray[4].fX == -3.0f);
             REPORTER_ASSERT(r, created == 11);
             REPORTER_ASSERT(r, destroyed == 0);
             alloc->makePOD<OddAlignment>();
         }

         REPORTER_ASSERT(r, created == 11);
         REPORTER_ASSERT(r, destroyed == 11);
     };

     // Exercise default arena
     {
         GrSubRunAllocator arena{0};
         exercise(&arena);
     }

     // Exercise on stack arena
     {
         GrSTSubRunAllocator<64> arena;
         exercise(&arena);
     }

     // Exercise arena with a heap allocated starting block
     {
         std::unique_ptr<char[]> block{new char[1024]};
         GrSubRunAllocator arena{block.get(), 1024, 0};
         exercise(&arena);
     }

     // Exercise the singly-link list of unique_ptrs use case
     {
         created = 0;
         destroyed = 0;
         GrSubRunAllocator arena;

         struct Node {
             Node(std::unique_ptr<Node, GrSubRunAllocator::Destroyer> next)
                     : fNext{std::move(next)} { created++; }
             ~Node() { destroyed++; }
             std::unique_ptr<Node, GrSubRunAllocator::Destroyer> fNext;
         };

         std::unique_ptr<Node, GrSubRunAllocator::Destroyer> current = nullptr;
         for (int i = 0; i < 128; i++) {
             current = arena.makeUnique<Node>(std::move(current));
         }
         REPORTER_ASSERT(r, created == 128);
         REPORTER_ASSERT(r, destroyed == 0);
     }
     REPORTER_ASSERT(r, created == 128);
     REPORTER_ASSERT(r, destroyed == 128);

     // Exercise the array ctor w/ a mapping function
     {
         struct I {
             I(int v) : i{v} {}
             ~I() {}
             int i;
         };
         GrSTSubRunAllocator<64> arena;
         auto a = arena.makeUniqueArray<I>(8, [](size_t i) { return i; });
         for (size_t i = 0; i < 8; i++) {
             REPORTER_ASSERT(r, a[i].i == (int)i);
         }
     }

     {
         GrSubRunAllocator arena(4096);
         void* ptr = arena.alignedBytes(4081, 8);
         REPORTER_ASSERT(r, ((intptr_t)ptr & 7) == 0);
     }
 }
	/*
	* Copyright 2020 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/core/SkBitmap.h"
	#include "include/core/SkCanvas.h"
	#include "include/core/SkSurface.h"
	#include "include/core/SkTextBlob.h"
	#include "src/core/SkSurfacePriv.h"
	#include "src/gpu/text/GrTextBlob.h"
	#include "tests/Test.h"
	#include "tools/ToolUtils.h"

	SkBitmap rasterize_blob(SkTextBlob* blob,
	const SkPaint& paint,
	GrRecordingContext* rContext,
	const SkMatrix& matrix) {
	const SkImageInfo info =
	SkImageInfo::Make(500, 500, kN32_SkColorType, kPremul_SkAlphaType);
	auto surface = SkSurface::MakeRenderTarget(rContext, SkBudgeted::kNo, info);
	auto canvas = surface->getCanvas();
	canvas->drawColor(SK_ColorWHITE);
	canvas->concat(matrix);
	canvas->drawTextBlob(blob, 10, 250, paint);
	SkBitmap bitmap;
	bitmap.allocN32Pixels(500, 500);
	surface->readPixels(bitmap, 0, 0);
	return bitmap;
	}

	bool check_for_black(const SkBitmap& bm) {
	for (int y = 0; y < bm.height(); y++) {
	for (int x = 0; x < bm.width(); x++) {
	if (bm.getColor(x, y) == SK_ColorBLACK) {
	return true;
	}
	}
	}
	return false;
	}

	DEF_GPUTEST_FOR_RENDERING_CONTEXTS(GrTextBlobScaleAnimation, reporter, ctxInfo) {
	auto tf = ToolUtils::create_portable_typeface("Mono", SkFontStyle());
	SkFont font{tf};
	font.setHinting(SkFontHinting::kNormal);
	font.setSize(12);
	font.setEdging(SkFont::Edging::kAntiAlias);
	font.setSubpixel(true);

	SkTextBlobBuilder builder;
	const auto& runBuffer = builder.allocRunPosH(font, 30, 0, nullptr);

	for (int i = 0; i < 30; i++) {
	runBuffer.glyphs[i] = static_cast<SkGlyphID>(i);
	runBuffer.pos[i] = SkIntToScalar(i);
	}
	auto blob = builder.make();

	auto dContext = ctxInfo.directContext();
	bool anyBlack = false;
	for (int n = -13; n < 5; n++) {
	SkMatrix m = SkMatrix::Scale(std::exp2(n), std::exp2(n));
	auto bm = rasterize_blob(blob.get(), SkPaint(), dContext, m);
	anyBlack \|= check_for_black(bm);
	}
	REPORTER_ASSERT(reporter, anyBlack);
	}

	// Test extreme positions for all combinations of positions, origins, and translation matrices.
	DEF_GPUTEST_FOR_RENDERING_CONTEXTS(GrTextBlobMoveAround, reporter, ctxInfo) {
	auto tf = ToolUtils::create_portable_typeface("Mono", SkFontStyle());
	SkFont font{tf};
	font.setHinting(SkFontHinting::kNormal);
	font.setSize(12);
	font.setEdging(SkFont::Edging::kAntiAlias);
	font.setSubpixel(true);

	auto makeBlob = [&](SkPoint delta) {
	SkTextBlobBuilder builder;
	const auto& runBuffer = builder.allocRunPos(font, 30, nullptr);

	for (int i = 0; i < 30; i++) {
	runBuffer.glyphs[i] = static_cast<SkGlyphID>(i);
	runBuffer.points()[i] = SkPoint::Make(SkIntToScalar(i*10) + delta.x(), 50 + delta.y());
	}
	return builder.make();
	};

	auto dContext = ctxInfo.directContext();
	auto rasterizeBlob = [&](SkTextBlob* blob, SkPoint origin, const SkMatrix& matrix) {
	SkPaint paint;
	const SkImageInfo info =
	SkImageInfo::Make(350, 80, kN32_SkColorType, kPremul_SkAlphaType);
	auto surface = SkSurface::MakeRenderTarget(dContext, SkBudgeted::kNo, info);
	auto canvas = surface->getCanvas();
	canvas->drawColor(SK_ColorWHITE);
	canvas->concat(matrix);
	canvas->drawTextBlob(blob, 10 + origin.x(), 40 + origin.y(), paint);
	SkBitmap bitmap;
	bitmap.allocN32Pixels(350, 80);
	surface->readPixels(bitmap, 0, 0);
	return bitmap;
	};

	SkBitmap benchMark;
	{
	auto blob = makeBlob({0, 0});
	benchMark = rasterizeBlob(blob.get(), {0,0}, SkMatrix::I());
	}

	auto checkBitmap = [&](const SkBitmap& bitmap) {
	REPORTER_ASSERT(reporter, benchMark.width() == bitmap.width());
	REPORTER_ASSERT(reporter, benchMark.width() == bitmap.width());

	for (int y = 0; y < benchMark.height(); y++) {
	for (int x = 0; x < benchMark.width(); x++) {
	if (benchMark.getColor(x, y) != bitmap.getColor(x, y)) {
	return false;
	}
	}
	}
	return true;
	};

	SkScalar interestingNumbers[] = {-10'000'000, -1'000'000, -1, 0, +1, +1'000'000, +10'000'000};
	for (auto originX : interestingNumbers) {
	for (auto originY : interestingNumbers) {
	for (auto translateX : interestingNumbers) {
	for (auto translateY : interestingNumbers) {
	// Make sure everything adds to zero.
	SkScalar deltaPosX = -(originX + translateX);
	SkScalar deltaPosY = -(originY + translateY);
	auto blob = makeBlob({deltaPosX, deltaPosY});
	SkMatrix t = SkMatrix::Translate(translateX, translateY);
	auto bitmap = rasterizeBlob(blob.get(), {originX, originY}, t);
	REPORTER_ASSERT(reporter, checkBitmap(bitmap));
	}
	}
	}
	}
	}

	DEF_TEST(GrBagOfBytesBasic, r) {
	const int k4K = 1 << 12;
	{
	// GrBagOfBytes::MinimumSizeWithOverhead(-1); // This should fail
	GrBagOfBytes::PlatformMinimumSizeWithOverhead(0, 16);
	GrBagOfBytes::PlatformMinimumSizeWithOverhead(
	std::numeric_limits<int>::max() - k4K - 1, 16);
	// GrBagOfBytes::MinimumSizeWithOverhead(std::numeric_limits<int>::max() - k4K); // Fail
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 1, 16, 16) == 31);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 1, 16, 16) == 32);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 1, 16, 16) == 94);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 8, 16, 16) == 24);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 8, 16, 16) == 32);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 8, 16, 16) == 88);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 16, 16, 16) == 16);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 16, 16, 16) == 32);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 16, 16, 16) == 80);

	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 1, 8, 16) == 23);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 1, 8, 16) == 24);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 1, 8, 16) == 86);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(0, 8, 8, 16) == 16);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(1, 8, 8, 16) == 24);
	REPORTER_ASSERT(r, GrBagOfBytes::MinimumSizeWithOverhead(63, 8, 8, 16) == 80);
	}

	{
	GrBagOfBytes bob;
	// bob.alignedBytes(0, 1); // This should fail
	// bob.alignedBytes(1, 0); // This should fail
	// bob.alignedBytes(1, 3); // This should fail

	struct Big {
	char stuff[std::numeric_limits<int>::max()];
	};
	// bob.alignedBytes(sizeof(Big), 1); // this should fail
	// bob.allocateBytesFor<Big>(); // this should not compile
	// The following should run, but should not be regularly tested.
	// bob.allocateBytesFor<int>((std::numeric_limits<int>::max() - (1<<12)) / sizeof(int) - 1);
	// The following should fail
	// bob.allocateBytesFor<int>((std::numeric_limits<int>::max() - (1<<12)) / sizeof(int));
	bob.alignedBytes(1, 1); // To avoid unused variable problems.
	}

	// Force multiple block allocation
	{
	GrBagOfBytes bob;
	const int k64K = 1 << 16;
	// By default allocation block sizes start at 1K and go up with fib. This should allocate
	// 10 individual blocks.
	for (int i = 0; i < 10; i++) {
	bob.alignedBytes(k64K, 1);
	}
	}
	}

	// Helper for defining allocators with inline/reserved storage.
	// For argument declarations, stick to the base type (GrSubRunAllocator).
	// Note: Inheriting from the storage first means the storage will outlive the
	// GrSubRunAllocator, letting ~GrSubRunAllocator read it as it calls destructors.
	// (This is mostly only relevant for strict tools like MSAN.)

	template <size_t inlineSize>
	class GrSTSubRunAllocator : private GrBagOfBytes::Storage<inlineSize>, public GrSubRunAllocator {
	public:
	explicit GrSTSubRunAllocator(int firstHeapAllocation =
	GrBagOfBytes::PlatformMinimumSizeWithOverhead(inlineSize, 1))
	: GrSubRunAllocator{this->data(), SkTo<int>(this->size()), firstHeapAllocation} {}
	};

	DEF_TEST(GrSubRunAllocator, r) {
	static int created = 0;
	static int destroyed = 0;
	struct Foo {
	Foo() : fI{-2}, fX{-3} { created++; }
	Foo(int i, float x) : fI{i}, fX{x} { created++; }
	~Foo() { destroyed++; }
	int fI;
	float fX;
	};

	struct alignas(8) OddAlignment {
	char buf[10];
	};

	auto exercise = [&](GrSubRunAllocator* alloc) {
	created = 0;
	destroyed = 0;
	{
	int* p = alloc->makePOD<int>(3);
	REPORTER_ASSERT(r, *p == 3);
	int* q = alloc->makePOD<int>(7);
	REPORTER_ASSERT(r, *q == 7);

	REPORTER_ASSERT(r, *alloc->makePOD<int>(3) == 3);
	auto foo = alloc->makeUnique<Foo>(3, 4.0f);
	REPORTER_ASSERT(r, foo->fI == 3);
	REPORTER_ASSERT(r, foo->fX == 4.0f);
	REPORTER_ASSERT(r, created == 1);
	REPORTER_ASSERT(r, destroyed == 0);

	alloc->makePODArray<int>(10);

	auto fooArray = alloc->makeUniqueArray<Foo>(10);
	REPORTER_ASSERT(r, fooArray[3].fI == -2);
	REPORTER_ASSERT(r, fooArray[4].fX == -3.0f);
	REPORTER_ASSERT(r, created == 11);
	REPORTER_ASSERT(r, destroyed == 0);
	alloc->makePOD<OddAlignment>();
	}

	REPORTER_ASSERT(r, created == 11);
	REPORTER_ASSERT(r, destroyed == 11);
	};

	// Exercise default arena
	{
	GrSubRunAllocator arena{0};
	exercise(&arena);
	}

	// Exercise on stack arena
	{
	GrSTSubRunAllocator<64> arena;
	exercise(&arena);
	}

	// Exercise arena with a heap allocated starting block
	{
	std::unique_ptr<char[]> block{new char[1024]};
	GrSubRunAllocator arena{block.get(), 1024, 0};
	exercise(&arena);
	}

	// Exercise the singly-link list of unique_ptrs use case
	{
	created = 0;
	destroyed = 0;
	GrSubRunAllocator arena;

	struct Node {
	Node(std::unique_ptr<Node, GrSubRunAllocator::Destroyer> next)
	: fNext{std::move(next)} { created++; }
	~Node() { destroyed++; }
	std::unique_ptr<Node, GrSubRunAllocator::Destroyer> fNext;
	};

	std::unique_ptr<Node, GrSubRunAllocator::Destroyer> current = nullptr;
	for (int i = 0; i < 128; i++) {
	current = arena.makeUnique<Node>(std::move(current));
	}
	REPORTER_ASSERT(r, created == 128);
	REPORTER_ASSERT(r, destroyed == 0);
	}
	REPORTER_ASSERT(r, created == 128);
	REPORTER_ASSERT(r, destroyed == 128);

	// Exercise the array ctor w/ a mapping function
	{
	struct I {
	I(int v) : i{v} {}
	~I() {}
	int i;
	};
	GrSTSubRunAllocator<64> arena;
	auto a = arena.makeUniqueArray<I>(8, [](size_t i) { return i; });
	for (size_t i = 0; i < 8; i++) {
	REPORTER_ASSERT(r, a[i].i == (int)i);
	}
	}

	{
	GrSubRunAllocator arena(4096);
	void* ptr = arena.alignedBytes(4081, 8);
	REPORTER_ASSERT(r, ((intptr_t)ptr & 7) == 0);
	}
	}