src/gpu/effects/GrBicubicEffect.cpp - platform/external/skia - Gitiles

 /*
  * Copyright 2014 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "gl/builders/GrGLProgramBuilder.h"
 #include "GrBicubicEffect.h"


 #define DS(x) SkDoubleToScalar(x)

 const SkScalar GrBicubicEffect::gMitchellCoefficients[16] = {
     DS( 1.0 / 18.0), DS(-9.0 / 18.0), DS( 15.0 / 18.0), DS( -7.0 / 18.0),
     DS(16.0 / 18.0), DS( 0.0 / 18.0), DS(-36.0 / 18.0), DS( 21.0 / 18.0),
     DS( 1.0 / 18.0), DS( 9.0 / 18.0), DS( 27.0 / 18.0), DS(-21.0 / 18.0),
     DS( 0.0 / 18.0), DS( 0.0 / 18.0), DS( -6.0 / 18.0), DS(  7.0 / 18.0),
 };


 class GrGLBicubicEffect : public GrGLEffect {
 public:
     GrGLBicubicEffect(const GrBackendEffectFactory& factory,
                       const GrDrawEffect&);

     virtual void emitCode(GrGLProgramBuilder*,
                           const GrDrawEffect&,
                           const GrEffectKey&,
                           const char* outputColor,
                           const char* inputColor,
                           const TransformedCoordsArray&,
                           const TextureSamplerArray&) SK_OVERRIDE;

     virtual void setData(const GrGLProgramDataManager&, const GrDrawEffect&) SK_OVERRIDE;

     static inline void GenKey(const GrDrawEffect& drawEffect, const GrGLCaps&,
                               GrEffectKeyBuilder* b) {
         const GrTextureDomain& domain = drawEffect.castEffect<GrBicubicEffect>().domain();
         b->add32(GrTextureDomain::GLDomain::DomainKey(domain));
     }

 private:
     typedef GrGLProgramDataManager::UniformHandle UniformHandle;

     UniformHandle               fCoefficientsUni;
     UniformHandle               fImageIncrementUni;
     GrTextureDomain::GLDomain   fDomain;

     typedef GrGLEffect INHERITED;
 };

 GrGLBicubicEffect::GrGLBicubicEffect(const GrBackendEffectFactory& factory, const GrDrawEffect&)
     : INHERITED(factory) {
 }

 void GrGLBicubicEffect::emitCode(GrGLProgramBuilder* builder,
                                  const GrDrawEffect& drawEffect,
                                  const GrEffectKey& key,
                                  const char* outputColor,
                                  const char* inputColor,
                                  const TransformedCoordsArray& coords,
                                  const TextureSamplerArray& samplers) {
     const GrTextureDomain& domain = drawEffect.castEffect<GrBicubicEffect>().domain();

     fCoefficientsUni = builder->addUniform(GrGLProgramBuilder::kFragment_Visibility,
                                            kMat44f_GrSLType, "Coefficients");
     fImageIncrementUni = builder->addUniform(GrGLProgramBuilder::kFragment_Visibility,
                                              kVec2f_GrSLType, "ImageIncrement");

     const char* imgInc = builder->getUniformCStr(fImageIncrementUni);
     const char* coeff = builder->getUniformCStr(fCoefficientsUni);

     SkString cubicBlendName;

     static const GrGLShaderVar gCubicBlendArgs[] = {
         GrGLShaderVar("coefficients",  kMat44f_GrSLType),
         GrGLShaderVar("t",             kFloat_GrSLType),
         GrGLShaderVar("c0",            kVec4f_GrSLType),
         GrGLShaderVar("c1",            kVec4f_GrSLType),
         GrGLShaderVar("c2",            kVec4f_GrSLType),
         GrGLShaderVar("c3",            kVec4f_GrSLType),
     };
     GrGLFragmentShaderBuilder* fsBuilder = builder->getFragmentShaderBuilder();
     SkString coords2D = fsBuilder->ensureFSCoords2D(coords, 0);
     fsBuilder->emitFunction(kVec4f_GrSLType,
                             "cubicBlend",
                             SK_ARRAY_COUNT(gCubicBlendArgs),
                             gCubicBlendArgs,
                             "\tvec4 ts = vec4(1.0, t, t * t, t * t * t);\n"
                             "\tvec4 c = coefficients * ts;\n"
                             "\treturn c.x * c0 + c.y * c1 + c.z * c2 + c.w * c3;\n",
                             &cubicBlendName);
     fsBuilder->codeAppendf("\tvec2 coord = %s - %s * vec2(0.5);\n", coords2D.c_str(), imgInc);
     // We unnormalize the coord in order to determine our fractional offset (f) within the texel
     // We then snap coord to a texel center and renormalize. The snap prevents cases where the
     // starting coords are near a texel boundary and accumulations of imgInc would cause us to skip/
     // double hit a texel.
     fsBuilder->codeAppendf("\tcoord /= %s;\n", imgInc);
     fsBuilder->codeAppend("\tvec2 f = fract(coord);\n");
     fsBuilder->codeAppendf("\tcoord = (coord - f + vec2(0.5)) * %s;\n", imgInc);
     fsBuilder->codeAppend("\tvec4 rowColors[4];\n");
     for (int y = 0; y < 4; ++y) {
         for (int x = 0; x < 4; ++x) {
             SkString coord;
             coord.printf("coord + %s * vec2(%d, %d)", imgInc, x - 1, y - 1);
             SkString sampleVar;
             sampleVar.printf("rowColors[%d]", x);
             fDomain.sampleTexture(fsBuilder, domain, sampleVar.c_str(), coord, samplers[0]);
         }
         fsBuilder->codeAppendf("\tvec4 s%d = %s(%s, f.x, rowColors[0], rowColors[1], rowColors[2], rowColors[3]);\n", y, cubicBlendName.c_str(), coeff);
     }
     SkString bicubicColor;
     bicubicColor.printf("%s(%s, f.y, s0, s1, s2, s3)", cubicBlendName.c_str(), coeff);
     fsBuilder->codeAppendf("\t%s = %s;\n", outputColor, (GrGLSLExpr4(bicubicColor.c_str()) * GrGLSLExpr4(inputColor)).c_str());
 }

 void GrGLBicubicEffect::setData(const GrGLProgramDataManager& pdman,
                                 const GrDrawEffect& drawEffect) {
     const GrBicubicEffect& effect = drawEffect.castEffect<GrBicubicEffect>();
     const GrTexture& texture = *effect.texture(0);
     float imageIncrement[2];
     imageIncrement[0] = 1.0f / texture.width();
     imageIncrement[1] = 1.0f / texture.height();
     pdman.set2fv(fImageIncrementUni, 1, imageIncrement);
     pdman.setMatrix4f(fCoefficientsUni, effect.coefficients());
     fDomain.setData(pdman, effect.domain(), texture.origin());
 }

 static inline void convert_row_major_scalar_coeffs_to_column_major_floats(float dst[16],
                                                                           const SkScalar src[16]) {
     for (int y = 0; y < 4; y++) {
         for (int x = 0; x < 4; x++) {
             dst[x * 4 + y] = SkScalarToFloat(src[y * 4 + x]);
         }
     }
 }

 GrBicubicEffect::GrBicubicEffect(GrTexture* texture,
                                  const SkScalar coefficients[16],
                                  const SkMatrix &matrix,
                                  const SkShader::TileMode tileModes[2])
   : INHERITED(texture, matrix, GrTextureParams(tileModes, GrTextureParams::kNone_FilterMode))
   , fDomain(GrTextureDomain::IgnoredDomain()) {
     convert_row_major_scalar_coeffs_to_column_major_floats(fCoefficients, coefficients);
 }

 GrBicubicEffect::GrBicubicEffect(GrTexture* texture,
                                  const SkScalar coefficients[16],
                                  const SkMatrix &matrix,
                                  const SkRect& domain)
   : INHERITED(texture, matrix, GrTextureParams(SkShader::kClamp_TileMode,
                                                GrTextureParams::kNone_FilterMode))
   , fDomain(domain, GrTextureDomain::kClamp_Mode) {
     convert_row_major_scalar_coeffs_to_column_major_floats(fCoefficients, coefficients);
 }

 GrBicubicEffect::~GrBicubicEffect() {
 }

 const GrBackendEffectFactory& GrBicubicEffect::getFactory() const {
     return GrTBackendEffectFactory<GrBicubicEffect>::getInstance();
 }

 bool GrBicubicEffect::onIsEqual(const GrEffect& sBase) const {
     const GrBicubicEffect& s = CastEffect<GrBicubicEffect>(sBase);
     return this->textureAccess(0) == s.textureAccess(0) &&
            !memcmp(fCoefficients, s.coefficients(), 16) &&
            fDomain == s.fDomain;
 }

 void GrBicubicEffect::getConstantColorComponents(GrColor* color, uint32_t* validFlags) const {
     // FIXME: Perhaps we can do better.
     *validFlags = 0;
     return;
 }

 GR_DEFINE_EFFECT_TEST(GrBicubicEffect);

 GrEffect* GrBicubicEffect::TestCreate(SkRandom* random,
                                       GrContext* context,
                                       const GrDrawTargetCaps&,
                                       GrTexture* textures[]) {
     int texIdx = random->nextBool() ? GrEffectUnitTest::kSkiaPMTextureIdx :
                                       GrEffectUnitTest::kAlphaTextureIdx;
     SkScalar coefficients[16];
     for (int i = 0; i < 16; i++) {
         coefficients[i] = random->nextSScalar1();
     }
     return GrBicubicEffect::Create(textures[texIdx], coefficients);
 }

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

 bool GrBicubicEffect::ShouldUseBicubic(const SkMatrix& matrix,
                                        GrTextureParams::FilterMode* filterMode) {
     if (matrix.isIdentity()) {
         *filterMode = GrTextureParams::kNone_FilterMode;
         return false;
     }

     SkScalar scales[2];
     if (!matrix.getMinMaxScales(scales) || scales[0] < SK_Scalar1) {
         // Bicubic doesn't handle arbitrary minimization well, as src texels can be skipped
         // entirely,
         *filterMode = GrTextureParams::kMipMap_FilterMode;
         return false;
     }
     // At this point if scales[1] == SK_Scalar1 then the matrix doesn't do any scaling.
     if (scales[1] == SK_Scalar1) {
         if (matrix.rectStaysRect() && SkScalarIsInt(matrix.getTranslateX()) &&
             SkScalarIsInt(matrix.getTranslateY())) {
             *filterMode = GrTextureParams::kNone_FilterMode;
         } else {
             // Use bilerp to handle rotation or fractional translation.
             *filterMode = GrTextureParams::kBilerp_FilterMode;
         }
         return false;
     }
     // When we use the bicubic filtering effect each sample is read from the texture using
     // nearest neighbor sampling.
     *filterMode = GrTextureParams::kNone_FilterMode;
     return true;
 }
	/*
	* Copyright 2014 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "gl/builders/GrGLProgramBuilder.h"
	#include "GrBicubicEffect.h"


	#define DS(x) SkDoubleToScalar(x)

	const SkScalar GrBicubicEffect::gMitchellCoefficients[16] = {
	DS( 1.0 / 18.0), DS(-9.0 / 18.0), DS( 15.0 / 18.0), DS( -7.0 / 18.0),
	DS(16.0 / 18.0), DS( 0.0 / 18.0), DS(-36.0 / 18.0), DS( 21.0 / 18.0),
	DS( 1.0 / 18.0), DS( 9.0 / 18.0), DS( 27.0 / 18.0), DS(-21.0 / 18.0),
	DS( 0.0 / 18.0), DS( 0.0 / 18.0), DS( -6.0 / 18.0), DS( 7.0 / 18.0),
	};


	class GrGLBicubicEffect : public GrGLEffect {
	public:
	GrGLBicubicEffect(const GrBackendEffectFactory& factory,
	const GrDrawEffect&);

	virtual void emitCode(GrGLProgramBuilder*,
	const GrDrawEffect&,
	const GrEffectKey&,
	const char* outputColor,
	const char* inputColor,
	const TransformedCoordsArray&,
	const TextureSamplerArray&) SK_OVERRIDE;

	virtual void setData(const GrGLProgramDataManager&, const GrDrawEffect&) SK_OVERRIDE;

	static inline void GenKey(const GrDrawEffect& drawEffect, const GrGLCaps&,
	GrEffectKeyBuilder* b) {
	const GrTextureDomain& domain = drawEffect.castEffect<GrBicubicEffect>().domain();
	b->add32(GrTextureDomain::GLDomain::DomainKey(domain));
	}

	private:
	typedef GrGLProgramDataManager::UniformHandle UniformHandle;

	UniformHandle fCoefficientsUni;
	UniformHandle fImageIncrementUni;
	GrTextureDomain::GLDomain fDomain;

	typedef GrGLEffect INHERITED;
	};

	GrGLBicubicEffect::GrGLBicubicEffect(const GrBackendEffectFactory& factory, const GrDrawEffect&)
	: INHERITED(factory) {
	}

	void GrGLBicubicEffect::emitCode(GrGLProgramBuilder* builder,
	const GrDrawEffect& drawEffect,
	const GrEffectKey& key,
	const char* outputColor,
	const char* inputColor,
	const TransformedCoordsArray& coords,
	const TextureSamplerArray& samplers) {
	const GrTextureDomain& domain = drawEffect.castEffect<GrBicubicEffect>().domain();

	fCoefficientsUni = builder->addUniform(GrGLProgramBuilder::kFragment_Visibility,
	kMat44f_GrSLType, "Coefficients");
	fImageIncrementUni = builder->addUniform(GrGLProgramBuilder::kFragment_Visibility,
	kVec2f_GrSLType, "ImageIncrement");

	const char* imgInc = builder->getUniformCStr(fImageIncrementUni);
	const char* coeff = builder->getUniformCStr(fCoefficientsUni);

	SkString cubicBlendName;

	static const GrGLShaderVar gCubicBlendArgs[] = {
	GrGLShaderVar("coefficients", kMat44f_GrSLType),
	GrGLShaderVar("t", kFloat_GrSLType),
	GrGLShaderVar("c0", kVec4f_GrSLType),
	GrGLShaderVar("c1", kVec4f_GrSLType),
	GrGLShaderVar("c2", kVec4f_GrSLType),
	GrGLShaderVar("c3", kVec4f_GrSLType),
	};
	GrGLFragmentShaderBuilder* fsBuilder = builder->getFragmentShaderBuilder();
	SkString coords2D = fsBuilder->ensureFSCoords2D(coords, 0);
	fsBuilder->emitFunction(kVec4f_GrSLType,
	"cubicBlend",
	SK_ARRAY_COUNT(gCubicBlendArgs),
	gCubicBlendArgs,
	"\tvec4 ts = vec4(1.0, t, t * t, t * t * t);\n"
	"\tvec4 c = coefficients * ts;\n"
	"\treturn c.x * c0 + c.y * c1 + c.z * c2 + c.w * c3;\n",
	&cubicBlendName);
	fsBuilder->codeAppendf("\tvec2 coord = %s - %s * vec2(0.5);\n", coords2D.c_str(), imgInc);
	// We unnormalize the coord in order to determine our fractional offset (f) within the texel
	// We then snap coord to a texel center and renormalize. The snap prevents cases where the
	// starting coords are near a texel boundary and accumulations of imgInc would cause us to skip/
	// double hit a texel.
	fsBuilder->codeAppendf("\tcoord /= %s;\n", imgInc);
	fsBuilder->codeAppend("\tvec2 f = fract(coord);\n");
	fsBuilder->codeAppendf("\tcoord = (coord - f + vec2(0.5)) * %s;\n", imgInc);
	fsBuilder->codeAppend("\tvec4 rowColors[4];\n");
	for (int y = 0; y < 4; ++y) {
	for (int x = 0; x < 4; ++x) {
	SkString coord;
	coord.printf("coord + %s * vec2(%d, %d)", imgInc, x - 1, y - 1);
	SkString sampleVar;
	sampleVar.printf("rowColors[%d]", x);
	fDomain.sampleTexture(fsBuilder, domain, sampleVar.c_str(), coord, samplers[0]);
	}
	fsBuilder->codeAppendf("\tvec4 s%d = %s(%s, f.x, rowColors[0], rowColors[1], rowColors[2], rowColors[3]);\n", y, cubicBlendName.c_str(), coeff);
	}
	SkString bicubicColor;
	bicubicColor.printf("%s(%s, f.y, s0, s1, s2, s3)", cubicBlendName.c_str(), coeff);
	fsBuilder->codeAppendf("\t%s = %s;\n", outputColor, (GrGLSLExpr4(bicubicColor.c_str()) * GrGLSLExpr4(inputColor)).c_str());
	}

	void GrGLBicubicEffect::setData(const GrGLProgramDataManager& pdman,
	const GrDrawEffect& drawEffect) {
	const GrBicubicEffect& effect = drawEffect.castEffect<GrBicubicEffect>();
	const GrTexture& texture = *effect.texture(0);
	float imageIncrement[2];
	imageIncrement[0] = 1.0f / texture.width();
	imageIncrement[1] = 1.0f / texture.height();
	pdman.set2fv(fImageIncrementUni, 1, imageIncrement);
	pdman.setMatrix4f(fCoefficientsUni, effect.coefficients());
	fDomain.setData(pdman, effect.domain(), texture.origin());
	}

	static inline void convert_row_major_scalar_coeffs_to_column_major_floats(float dst[16],
	const SkScalar src[16]) {
	for (int y = 0; y < 4; y++) {
	for (int x = 0; x < 4; x++) {
	dst[x * 4 + y] = SkScalarToFloat(src[y * 4 + x]);
	}
	}
	}

	GrBicubicEffect::GrBicubicEffect(GrTexture* texture,
	const SkScalar coefficients[16],
	const SkMatrix &matrix,
	const SkShader::TileMode tileModes[2])
	: INHERITED(texture, matrix, GrTextureParams(tileModes, GrTextureParams::kNone_FilterMode))
	, fDomain(GrTextureDomain::IgnoredDomain()) {
	convert_row_major_scalar_coeffs_to_column_major_floats(fCoefficients, coefficients);
	}

	GrBicubicEffect::GrBicubicEffect(GrTexture* texture,
	const SkScalar coefficients[16],
	const SkMatrix &matrix,
	const SkRect& domain)
	: INHERITED(texture, matrix, GrTextureParams(SkShader::kClamp_TileMode,
	GrTextureParams::kNone_FilterMode))
	, fDomain(domain, GrTextureDomain::kClamp_Mode) {
	convert_row_major_scalar_coeffs_to_column_major_floats(fCoefficients, coefficients);
	}

	GrBicubicEffect::~GrBicubicEffect() {
	}

	const GrBackendEffectFactory& GrBicubicEffect::getFactory() const {
	return GrTBackendEffectFactory<GrBicubicEffect>::getInstance();
	}

	bool GrBicubicEffect::onIsEqual(const GrEffect& sBase) const {
	const GrBicubicEffect& s = CastEffect<GrBicubicEffect>(sBase);
	return this->textureAccess(0) == s.textureAccess(0) &&
	!memcmp(fCoefficients, s.coefficients(), 16) &&
	fDomain == s.fDomain;
	}

	void GrBicubicEffect::getConstantColorComponents(GrColor* color, uint32_t* validFlags) const {
	// FIXME: Perhaps we can do better.
	*validFlags = 0;
	return;
	}

	GR_DEFINE_EFFECT_TEST(GrBicubicEffect);

	GrEffect* GrBicubicEffect::TestCreate(SkRandom* random,
	GrContext* context,
	const GrDrawTargetCaps&,
	GrTexture* textures[]) {
	int texIdx = random->nextBool() ? GrEffectUnitTest::kSkiaPMTextureIdx :
	GrEffectUnitTest::kAlphaTextureIdx;
	SkScalar coefficients[16];
	for (int i = 0; i < 16; i++) {
	coefficients[i] = random->nextSScalar1();
	}
	return GrBicubicEffect::Create(textures[texIdx], coefficients);
	}

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

	bool GrBicubicEffect::ShouldUseBicubic(const SkMatrix& matrix,
	GrTextureParams::FilterMode* filterMode) {
	if (matrix.isIdentity()) {
	*filterMode = GrTextureParams::kNone_FilterMode;
	return false;
	}

	SkScalar scales[2];
	if (!matrix.getMinMaxScales(scales) \|\| scales[0] < SK_Scalar1) {
	// Bicubic doesn't handle arbitrary minimization well, as src texels can be skipped
	// entirely,
	*filterMode = GrTextureParams::kMipMap_FilterMode;
	return false;
	}
	// At this point if scales[1] == SK_Scalar1 then the matrix doesn't do any scaling.
	if (scales[1] == SK_Scalar1) {
	if (matrix.rectStaysRect() && SkScalarIsInt(matrix.getTranslateX()) &&
	SkScalarIsInt(matrix.getTranslateY())) {
	*filterMode = GrTextureParams::kNone_FilterMode;
	} else {
	// Use bilerp to handle rotation or fractional translation.
	*filterMode = GrTextureParams::kBilerp_FilterMode;
	}
	return false;
	}
	// When we use the bicubic filtering effect each sample is read from the texture using
	// nearest neighbor sampling.
	*filterMode = GrTextureParams::kNone_FilterMode;
	return true;
	}