gm/compressed_textures.cpp - skia - Git at Google

 /*
  * 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/SkTypes.h" // IWYU pragma: keep

 #if !defined(SK_BUILD_FOR_GOOGLE3)  // Google3 doesn't have etc1.h

 #include "gm/gm.h"
 #include "include/core/SkBitmap.h"
 #include "include/core/SkCanvas.h"
 #include "include/core/SkColor.h"
 #include "include/core/SkData.h"
 #include "include/core/SkImage.h"
 #include "include/core/SkImageInfo.h"
 #include "include/core/SkPath.h"
 #include "include/core/SkRect.h"
 #include "include/core/SkRefCnt.h"
 #include "include/core/SkSize.h"
 #include "include/core/SkString.h"
 #include "src/core/SkCompressedDataUtils.h"
 #include "src/core/SkMipMap.h"
 #include "src/gpu/GrContextPriv.h"
 #include "src/gpu/GrDataUtils.h"
 #include "src/image/SkImage_Base.h"
 #include "third_party/etc1/etc1.h"

 class GrContext;
 class GrRenderTargetContext;

 static SkPoint gen_pt(float angle, const SkVector& scale) {
     SkScalar s = SkScalarSin(angle);
     SkScalar c = SkScalarCos(angle);

     return { scale.fX * c, scale.fY * s };
 }

 // The resulting path will be centered at (0,0) and its size will match 'dimensions'
 static SkPath make_gear(SkISize dimensions, int numTeeth) {
     SkVector outerRad{ dimensions.fWidth / 2.0f, dimensions.fHeight / 2.0f };
     SkVector innerRad{ dimensions.fWidth / 2.5f, dimensions.fHeight / 2.5f };
     const float kAnglePerTooth = 2.0f * SK_ScalarPI / (3 * numTeeth);

     float angle = 0.0f;

     SkPath tmp;
     tmp.setFillType(SkPathFillType::kWinding);

     tmp.moveTo(gen_pt(angle, outerRad));

     for (int i = 0; i < numTeeth; ++i, angle += 3*kAnglePerTooth) {
         tmp.lineTo(gen_pt(angle+kAnglePerTooth, outerRad));
         tmp.lineTo(gen_pt(angle+(1.5f*kAnglePerTooth), innerRad));
         tmp.lineTo(gen_pt(angle+(2.5f*kAnglePerTooth), innerRad));
         tmp.lineTo(gen_pt(angle+(3.0f*kAnglePerTooth), outerRad));
     }

     tmp.close();

     float fInnerRad = 0.1f * std::min(dimensions.fWidth, dimensions.fHeight);
     if (fInnerRad > 0.5f) {
         tmp.addCircle(0.0f, 0.0f, fInnerRad, SkPathDirection::kCCW);
     }

     return tmp;
 }

 // Render one level of a mipmap
 SkBitmap render_level(SkISize dimensions, SkColor color, SkColorType colorType, bool opaque) {
     SkPath path = make_gear(dimensions, 9);

     SkImageInfo ii = SkImageInfo::Make(dimensions.width(), dimensions.height(),
                                        colorType, opaque ? kOpaque_SkAlphaType
                                                          : kPremul_SkAlphaType);
     SkBitmap bm;
     bm.allocPixels(ii);

     bm.eraseColor(opaque ? SK_ColorBLACK : SK_ColorTRANSPARENT);

     SkCanvas c(bm);

     SkPaint paint;
     paint.setColor(color | 0xFF000000);
     paint.setAntiAlias(false);

     c.translate(dimensions.width() / 2.0f, dimensions.height() / 2.0f);
     c.drawPath(path, paint);

     return bm;
 }

 // Create the compressed data blob needed to represent a mipmapped 2-color texture of the specified
 // compression format. In this case 2-color means either opaque black or transparent black plus
 // one other color.
 // Note that ETC1/ETC2_RGB8_UNORM only supports 565 opaque textures.
 static sk_sp<SkData> make_compressed_data(SkISize dimensions,
                                           SkColorType colorType,
                                           bool opaque,
                                           SkImage::CompressionType compression) {
     size_t totalSize = SkCompressedDataSize(compression, dimensions, nullptr, true);

     sk_sp<SkData> tmp = SkData::MakeUninitialized(totalSize);
     char* pixels = (char*) tmp->writable_data();

     int numMipLevels = SkMipMap::ComputeLevelCount(dimensions.width(), dimensions.height()) + 1;

     size_t offset = 0;

     // Use a different color for each mipmap level so we can visually evaluate the draws
     static const SkColor kColors[] = {
         SK_ColorRED,
         SK_ColorGREEN,
         SK_ColorBLUE,
         SK_ColorCYAN,
         SK_ColorMAGENTA,
         SK_ColorYELLOW,
         SK_ColorWHITE,
     };

     for (int i = 0; i < numMipLevels; ++i) {
         size_t levelSize = SkCompressedDataSize(compression, dimensions, nullptr, false);

         SkBitmap bm = render_level(dimensions, kColors[i%7], colorType, opaque);
         if (compression == SkImage::CompressionType::kETC2_RGB8_UNORM) {
             SkASSERT(bm.colorType() == kRGB_565_SkColorType);
             SkASSERT(opaque);

             if (etc1_encode_image((unsigned char*)bm.getAddr16(0, 0),
                                   bm.width(), bm.height(), 2, bm.rowBytes(),
                                   (unsigned char*) &pixels[offset])) {
                 return nullptr;
             }
         } else {
             GrTwoColorBC1Compress(bm.pixmap(), kColors[i%7], &pixels[offset]);
         }

         offset += levelSize;
         dimensions = {std::max(1, dimensions.width()/2), std::max(1, dimensions.height()/2)};
     }

     return tmp;
 }

 // Basic test of Ganesh's ETC1 and BC1 support
 // The layout is:
 //               ETC2                BC1
 //         --------------------------------------
 //  RGB8  | kETC2_RGB8_UNORM  | kBC1_RGB8_UNORM  |
 //        |--------------------------------------|
 //  RGBA8 |                   | kBC1_RGBA8_UNORM |
 //         --------------------------------------
 //
 // The nonPowerOfTwo and nonMultipleOfFour cases exercise some compression edge cases.
 class CompressedTexturesGM : public skiagm::GM {
 public:
     enum class Type {
         kNormal,
         kNonPowerOfTwo,
         kNonMultipleOfFour
     };

     CompressedTexturesGM(Type type) : fType(type) {
         this->setBGColor(0xFFCCCCCC);

         switch (fType) {
             case Type::kNonPowerOfTwo:
                 // These dimensions force the top two mip levels to be 1x3 and 1x1
                 fImgDimensions.set(20, 60);
                 break;
             case Type::kNonMultipleOfFour:
                 // These dimensions force the top three mip levels to be 1x7, 1x3 and 1x1
                 fImgDimensions.set(13, 61); // prime numbers - just bc
                 break;
             default:
                 fImgDimensions.set(kBaseTexWidth, kBaseTexHeight);
                 break;
         }

     }

 protected:
     SkString onShortName() override {
         SkString name("compressed_textures");

         if (fType == Type::kNonPowerOfTwo) {
             name.append("_npot");
         } else if (fType == Type::kNonMultipleOfFour) {
             name.append("_nmof");
         }

         return name;
     }

     SkISize onISize() override {
         return SkISize::Make(2*kCellWidth + 3*kPad, 2*kBaseTexHeight + 3*kPad);
     }

     void onOnceBeforeDraw() override {
         fOpaqueETC2Data = make_compressed_data(fImgDimensions, kRGB_565_SkColorType, true,
                                                SkImage::CompressionType::kETC2_RGB8_UNORM);

         fOpaqueBC1Data = make_compressed_data(fImgDimensions, kRGBA_8888_SkColorType, true,
                                               SkImage::CompressionType::kBC1_RGB8_UNORM);

         fTransparentBC1Data = make_compressed_data(fImgDimensions, kRGBA_8888_SkColorType, false,
                                                    SkImage::CompressionType::kBC1_RGBA8_UNORM);
     }

     void onDraw(SkCanvas* canvas) override {
         GrContext* context = canvas->getGrContext();

         this->drawCell(context, canvas, fOpaqueETC2Data,
                        SkImage::CompressionType::kETC2_RGB8_UNORM, { kPad, kPad });

         this->drawCell(context, canvas, fOpaqueBC1Data,
                        SkImage::CompressionType::kBC1_RGB8_UNORM, { 2*kPad + kCellWidth, kPad });

         this->drawCell(context, canvas, fTransparentBC1Data,
                        SkImage::CompressionType::kBC1_RGBA8_UNORM,
                        { 2*kPad + kCellWidth, 2*kPad + kBaseTexHeight });
     }

 private:
     void drawCell(GrContext* context, SkCanvas* canvas, sk_sp<SkData> data,
                   SkImage::CompressionType compression, SkIVector offset) {

         sk_sp<SkImage> image;
         if (context) {
             image = SkImage::MakeTextureFromCompressed(context, std::move(data),
                                                        fImgDimensions.width(),
                                                        fImgDimensions.height(),
                                                        compression, GrMipMapped::kYes);
         } else {
             image = SkImage::MakeRasterFromCompressed(std::move(data),
                                                       fImgDimensions.width(),
                                                       fImgDimensions.height(),
                                                       compression);
         }
         if (!image) {
             return;
         }

         SkISize levelDimensions = fImgDimensions;
         int numMipLevels = SkMipMap::ComputeLevelCount(levelDimensions.width(),
                                                        levelDimensions.height()) + 1;

         SkPaint imagePaint;
         imagePaint.setFilterQuality(kHigh_SkFilterQuality); // to force mipmapping

         bool isCompressed = false;
         if (image->isTextureBacked()) {
             const GrCaps* caps = context->priv().caps();

             GrTextureProxy* proxy = as_IB(image)->peekProxy();
             isCompressed = caps->isFormatCompressed(proxy->backendFormat());
         }

         SkPaint redStrokePaint;
         redStrokePaint.setColor(SK_ColorRED);
         redStrokePaint.setStyle(SkPaint::kStroke_Style);

         for (int i = 0; i < numMipLevels; ++i) {
             SkRect r = SkRect::MakeXYWH(offset.fX, offset.fY,
                                         levelDimensions.width(), levelDimensions.height());

             canvas->drawImageRect(image, r, &imagePaint);
             if (!isCompressed) {
                 // Make it obvious which drawImages used decompressed images
                 canvas->drawRect(r, redStrokePaint);
             }

             if (i == 0) {
                 offset.fX += levelDimensions.width()+1;
             } else {
                 offset.fY += levelDimensions.height()+1;
             }

             levelDimensions = {std::max(1, levelDimensions.width()/2),
                                std::max(1, levelDimensions.height()/2)};
         }
     }

     static const int kPad = 8;
     static const int kBaseTexWidth = 64;
     static const int kCellWidth = 1.5f * kBaseTexWidth;
     static const int kBaseTexHeight = 64;

     Type          fType;
     SkISize       fImgDimensions;
     sk_sp<SkData> fOpaqueETC2Data;
     sk_sp<SkData> fOpaqueBC1Data;
     sk_sp<SkData> fTransparentBC1Data;

     typedef GM INHERITED;
 };

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

 DEF_GM(return new CompressedTexturesGM(CompressedTexturesGM::Type::kNormal);)
 DEF_GM(return new CompressedTexturesGM(CompressedTexturesGM::Type::kNonPowerOfTwo);)
 DEF_GM(return new CompressedTexturesGM(CompressedTexturesGM::Type::kNonMultipleOfFour);)

 #endif
	/*
	* 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/SkTypes.h" // IWYU pragma: keep

	#if !defined(SK_BUILD_FOR_GOOGLE3) // Google3 doesn't have etc1.h

	#include "gm/gm.h"
	#include "include/core/SkBitmap.h"
	#include "include/core/SkCanvas.h"
	#include "include/core/SkColor.h"
	#include "include/core/SkData.h"
	#include "include/core/SkImage.h"
	#include "include/core/SkImageInfo.h"
	#include "include/core/SkPath.h"
	#include "include/core/SkRect.h"
	#include "include/core/SkRefCnt.h"
	#include "include/core/SkSize.h"
	#include "include/core/SkString.h"
	#include "src/core/SkCompressedDataUtils.h"
	#include "src/core/SkMipMap.h"
	#include "src/gpu/GrContextPriv.h"
	#include "src/gpu/GrDataUtils.h"
	#include "src/image/SkImage_Base.h"
	#include "third_party/etc1/etc1.h"

	class GrContext;
	class GrRenderTargetContext;

	static SkPoint gen_pt(float angle, const SkVector& scale) {
	SkScalar s = SkScalarSin(angle);
	SkScalar c = SkScalarCos(angle);

	return { scale.fX * c, scale.fY * s };
	}

	// The resulting path will be centered at (0,0) and its size will match 'dimensions'
	static SkPath make_gear(SkISize dimensions, int numTeeth) {
	SkVector outerRad{ dimensions.fWidth / 2.0f, dimensions.fHeight / 2.0f };
	SkVector innerRad{ dimensions.fWidth / 2.5f, dimensions.fHeight / 2.5f };
	const float kAnglePerTooth = 2.0f * SK_ScalarPI / (3 * numTeeth);

	float angle = 0.0f;

	SkPath tmp;
	tmp.setFillType(SkPathFillType::kWinding);

	tmp.moveTo(gen_pt(angle, outerRad));

	for (int i = 0; i < numTeeth; ++i, angle += 3*kAnglePerTooth) {
	tmp.lineTo(gen_pt(angle+kAnglePerTooth, outerRad));
	tmp.lineTo(gen_pt(angle+(1.5f*kAnglePerTooth), innerRad));
	tmp.lineTo(gen_pt(angle+(2.5f*kAnglePerTooth), innerRad));
	tmp.lineTo(gen_pt(angle+(3.0f*kAnglePerTooth), outerRad));
	}

	tmp.close();

	float fInnerRad = 0.1f * std::min(dimensions.fWidth, dimensions.fHeight);
	if (fInnerRad > 0.5f) {
	tmp.addCircle(0.0f, 0.0f, fInnerRad, SkPathDirection::kCCW);
	}

	return tmp;
	}

	// Render one level of a mipmap
	SkBitmap render_level(SkISize dimensions, SkColor color, SkColorType colorType, bool opaque) {
	SkPath path = make_gear(dimensions, 9);

	SkImageInfo ii = SkImageInfo::Make(dimensions.width(), dimensions.height(),
	colorType, opaque ? kOpaque_SkAlphaType
	: kPremul_SkAlphaType);
	SkBitmap bm;
	bm.allocPixels(ii);

	bm.eraseColor(opaque ? SK_ColorBLACK : SK_ColorTRANSPARENT);

	SkCanvas c(bm);

	SkPaint paint;
	paint.setColor(color \| 0xFF000000);
	paint.setAntiAlias(false);

	c.translate(dimensions.width() / 2.0f, dimensions.height() / 2.0f);
	c.drawPath(path, paint);

	return bm;
	}

	// Create the compressed data blob needed to represent a mipmapped 2-color texture of the specified
	// compression format. In this case 2-color means either opaque black or transparent black plus
	// one other color.
	// Note that ETC1/ETC2_RGB8_UNORM only supports 565 opaque textures.
	static sk_sp<SkData> make_compressed_data(SkISize dimensions,
	SkColorType colorType,
	bool opaque,
	SkImage::CompressionType compression) {
	size_t totalSize = SkCompressedDataSize(compression, dimensions, nullptr, true);

	sk_sp<SkData> tmp = SkData::MakeUninitialized(totalSize);
	char* pixels = (char*) tmp->writable_data();

	int numMipLevels = SkMipMap::ComputeLevelCount(dimensions.width(), dimensions.height()) + 1;

	size_t offset = 0;

	// Use a different color for each mipmap level so we can visually evaluate the draws
	static const SkColor kColors[] = {
	SK_ColorRED,
	SK_ColorGREEN,
	SK_ColorBLUE,
	SK_ColorCYAN,
	SK_ColorMAGENTA,
	SK_ColorYELLOW,
	SK_ColorWHITE,
	};

	for (int i = 0; i < numMipLevels; ++i) {
	size_t levelSize = SkCompressedDataSize(compression, dimensions, nullptr, false);

	SkBitmap bm = render_level(dimensions, kColors[i%7], colorType, opaque);
	if (compression == SkImage::CompressionType::kETC2_RGB8_UNORM) {
	SkASSERT(bm.colorType() == kRGB_565_SkColorType);
	SkASSERT(opaque);

	if (etc1_encode_image((unsigned char*)bm.getAddr16(0, 0),
	bm.width(), bm.height(), 2, bm.rowBytes(),
	(unsigned char*) &pixels[offset])) {
	return nullptr;
	}
	} else {
	GrTwoColorBC1Compress(bm.pixmap(), kColors[i%7], &pixels[offset]);
	}

	offset += levelSize;
	dimensions = {std::max(1, dimensions.width()/2), std::max(1, dimensions.height()/2)};
	}

	return tmp;
	}

	// Basic test of Ganesh's ETC1 and BC1 support
	// The layout is:
	// ETC2 BC1
	// --------------------------------------
	// RGB8 \| kETC2_RGB8_UNORM \| kBC1_RGB8_UNORM \|
	// \|--------------------------------------\|
	// RGBA8 \| \| kBC1_RGBA8_UNORM \|
	// --------------------------------------
	//
	// The nonPowerOfTwo and nonMultipleOfFour cases exercise some compression edge cases.
	class CompressedTexturesGM : public skiagm::GM {
	public:
	enum class Type {
	kNormal,
	kNonPowerOfTwo,
	kNonMultipleOfFour
	};

	CompressedTexturesGM(Type type) : fType(type) {
	this->setBGColor(0xFFCCCCCC);

	switch (fType) {
	case Type::kNonPowerOfTwo:
	// These dimensions force the top two mip levels to be 1x3 and 1x1
	fImgDimensions.set(20, 60);
	break;
	case Type::kNonMultipleOfFour:
	// These dimensions force the top three mip levels to be 1x7, 1x3 and 1x1
	fImgDimensions.set(13, 61); // prime numbers - just bc
	break;
	default:
	fImgDimensions.set(kBaseTexWidth, kBaseTexHeight);
	break;
	}

	}

	protected:
	SkString onShortName() override {
	SkString name("compressed_textures");

	if (fType == Type::kNonPowerOfTwo) {
	name.append("_npot");
	} else if (fType == Type::kNonMultipleOfFour) {
	name.append("_nmof");
	}

	return name;
	}

	SkISize onISize() override {
	return SkISize::Make(2kCellWidth + 3kPad, 2kBaseTexHeight + 3kPad);
	}

	void onOnceBeforeDraw() override {
	fOpaqueETC2Data = make_compressed_data(fImgDimensions, kRGB_565_SkColorType, true,
	SkImage::CompressionType::kETC2_RGB8_UNORM);

	fOpaqueBC1Data = make_compressed_data(fImgDimensions, kRGBA_8888_SkColorType, true,
	SkImage::CompressionType::kBC1_RGB8_UNORM);

	fTransparentBC1Data = make_compressed_data(fImgDimensions, kRGBA_8888_SkColorType, false,
	SkImage::CompressionType::kBC1_RGBA8_UNORM);
	}

	void onDraw(SkCanvas* canvas) override {
	GrContext* context = canvas->getGrContext();

	this->drawCell(context, canvas, fOpaqueETC2Data,
	SkImage::CompressionType::kETC2_RGB8_UNORM, { kPad, kPad });

	this->drawCell(context, canvas, fOpaqueBC1Data,
	SkImage::CompressionType::kBC1_RGB8_UNORM, { 2*kPad + kCellWidth, kPad });

	this->drawCell(context, canvas, fTransparentBC1Data,
	SkImage::CompressionType::kBC1_RGBA8_UNORM,
	{ 2kPad + kCellWidth, 2kPad + kBaseTexHeight });
	}

	private:
	void drawCell(GrContext* context, SkCanvas* canvas, sk_sp<SkData> data,
	SkImage::CompressionType compression, SkIVector offset) {

	sk_sp<SkImage> image;
	if (context) {
	image = SkImage::MakeTextureFromCompressed(context, std::move(data),
	fImgDimensions.width(),
	fImgDimensions.height(),
	compression, GrMipMapped::kYes);
	} else {
	image = SkImage::MakeRasterFromCompressed(std::move(data),
	fImgDimensions.width(),
	fImgDimensions.height(),
	compression);
	}
	if (!image) {
	return;
	}

	SkISize levelDimensions = fImgDimensions;
	int numMipLevels = SkMipMap::ComputeLevelCount(levelDimensions.width(),
	levelDimensions.height()) + 1;

	SkPaint imagePaint;
	imagePaint.setFilterQuality(kHigh_SkFilterQuality); // to force mipmapping

	bool isCompressed = false;
	if (image->isTextureBacked()) {
	const GrCaps* caps = context->priv().caps();

	GrTextureProxy* proxy = as_IB(image)->peekProxy();
	isCompressed = caps->isFormatCompressed(proxy->backendFormat());
	}

	SkPaint redStrokePaint;
	redStrokePaint.setColor(SK_ColorRED);
	redStrokePaint.setStyle(SkPaint::kStroke_Style);

	for (int i = 0; i < numMipLevels; ++i) {
	SkRect r = SkRect::MakeXYWH(offset.fX, offset.fY,
	levelDimensions.width(), levelDimensions.height());

	canvas->drawImageRect(image, r, &imagePaint);
	if (!isCompressed) {
	// Make it obvious which drawImages used decompressed images
	canvas->drawRect(r, redStrokePaint);
	}

	if (i == 0) {
	offset.fX += levelDimensions.width()+1;
	} else {
	offset.fY += levelDimensions.height()+1;
	}

	levelDimensions = {std::max(1, levelDimensions.width()/2),
	std::max(1, levelDimensions.height()/2)};
	}
	}

	static const int kPad = 8;
	static const int kBaseTexWidth = 64;
	static const int kCellWidth = 1.5f * kBaseTexWidth;
	static const int kBaseTexHeight = 64;

	Type fType;
	SkISize fImgDimensions;
	sk_sp<SkData> fOpaqueETC2Data;
	sk_sp<SkData> fOpaqueBC1Data;
	sk_sp<SkData> fTransparentBC1Data;

	typedef GM INHERITED;
	};

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

	DEF_GM(return new CompressedTexturesGM(CompressedTexturesGM::Type::kNormal);)
	DEF_GM(return new CompressedTexturesGM(CompressedTexturesGM::Type::kNonPowerOfTwo);)
	DEF_GM(return new CompressedTexturesGM(CompressedTexturesGM::Type::kNonMultipleOfFour);)

	#endif