modules/skottie/src/effects/BrightnessContrastEffect.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 "modules/skottie/src/effects/Effects.h"

 #include "include/core/SkColorFilter.h"
 #include "include/effects/SkRuntimeEffect.h"
 #include "modules/skottie/src/Adapter.h"
 #include "modules/skottie/src/SkottieJson.h"
 #include "modules/skottie/src/SkottieValue.h"
 #include "modules/sksg/include/SkSGColorFilter.h"

 namespace skottie::internal {

 namespace  {

 // The contrast effect transfer function can be approximated with the following
 // 3rd degree polynomial:
 //
 //   f(x) = -2πC/3 * x³ + πC * x² + (1 - πC/3) * x
 //
 // where C is the normalized contrast value [-1..1].
 //
 // Derivation:
 //
 //   - start off with sampling the AE contrast effect for various contrast/input values [1]
 //
 //   - apply cubic polynomial curve fitting to determine best-fit coefficients for given
 //     contrast values [2]
 //
 //   - observations:
 //       * negative contrast appears clamped at -0.5 (-50)
 //       * a,b coefficients vary linearly vs. contrast
 //       * the b coefficient for max contrast (1.0) looks kinda familiar: 3.14757 - coincidence?
 //         probably not.  let's run with it: b == πC
 //
 //   - additionally, we expect the following to hold:
 //       * f(0  ) = 0   \     | d = 0
 //       * f(1  ) = 1    | => | a = -2b/3
 //       * f(0.5) = 0.5 /     | c = 1 - b/3
 //
 //   - this yields a pretty decent approximation: [3]
 //
 //
 // Note (courtesy of mtklein, reed): [4] seems to yield a closer approximation, but requires
 // a more expensive sin
 //
 //   f(x) = x + a * sin(2πx)/2π
 //
 // [1] https://www.desmos.com/calculator/oksptqpo8z
 // [2] https://www.desmos.com/calculator/oukrf6yahn
 // [3] https://www.desmos.com/calculator/ehem0vy3ft
 // [4] https://www.desmos.com/calculator/5t4xi10q4v
 //

 #ifndef SKOTTIE_ACCURATE_CONTRAST_APPROXIMATION
 static sk_sp<SkData> make_contrast_coeffs(float contrast) {
     struct { float a, b, c; } coeffs;

     coeffs.b = SK_ScalarPI * contrast;
     coeffs.a = -2 * coeffs.b / 3;
     coeffs.c =  1 - coeffs.b / 3;

     return SkData::MakeWithCopy(&coeffs, sizeof(coeffs));
 }

 static constexpr char CONTRAST_EFFECT[] = R"(
     uniform half a;
     uniform half b;
     uniform half c;

     void main(inout half4 color) {
         // C' = a*C^3 + b*C^2 + c*C
         color.rgb = ((a*color.rgb + b)*color.rgb + c)*color.rgb;
     }
 )";
 #else
 // More accurate (but slower) approximation:
 //
 //   f(x) = x + a * sin(2πx)
 //
 //   a = -contrast/3π
 //
 static sk_sp<SkData> make_contrast_coeffs(float contrast) {
     const auto coeff_a = -contrast / (3 * SK_ScalarPI);

     return SkData::MakeWithCopy(&coeff_a, sizeof(coeff_a));
 }

 static constexpr char CONTRAST_EFFECT[] = R"(
     uniform half a;

     void main(inout half4 color) {
         color.rgb += a * sin(color.rgb * 6.283185);
     }
 )";

 #endif

 // Brightness transfer function approximation:
 //
 //   f(x) = 1 - (1 - x)^(2^(1.8*B))
 //
 // where B is the normalized [-1..1] brightness value
 //
 // Visualization: https://www.desmos.com/calculator/wuyqa2wtol
 //
 static sk_sp<SkData> make_brightness_coeffs(float brightness) {
     const float coeff_a = std::pow(2.0f, brightness * 1.8f);

     return SkData::MakeWithCopy(&coeff_a, sizeof(coeff_a));
 }

 static constexpr char BRIGHTNESS_EFFECT[] = R"(
     uniform half a;

     void main(inout half4 color) {
         color.rgb = 1 - pow(1 - color.rgb, half3(a));
     }
 )";

 class BrightnessContrastAdapter final : public DiscardableAdapterBase<BrightnessContrastAdapter,
                                                                       sksg::ExternalColorFilter> {
 public:
     BrightnessContrastAdapter(const skjson::ArrayValue& jprops,
                               const AnimationBuilder& abuilder,
                               sk_sp<sksg::RenderNode> layer)
         : INHERITED(sksg::ExternalColorFilter::Make(std::move(layer)))
         , fBrightnessEffect(std::get<0>(SkRuntimeEffect::Make(SkString(BRIGHTNESS_EFFECT))))
         , fContrastEffect(std::get<0>(SkRuntimeEffect::Make(SkString(CONTRAST_EFFECT)))) {
         SkASSERT(fBrightnessEffect);
         SkASSERT(fContrastEffect);

         enum : size_t {
             kBrightness_Index = 0,
               kContrast_Index = 1,
              kUseLegacy_Index = 2,
         };

         EffectBinder(jprops, abuilder, this)
             .bind(kBrightness_Index, fBrightness)
             .bind(  kContrast_Index, fContrast  )
             .bind( kUseLegacy_Index, fUseLegacy );
     }

 private:
     void onSync() override {
         this->node()->setColorFilter(SkScalarRoundToInt(fUseLegacy)
                                         ? this->makeLegacyCF()
                                         : this->makeCF());
     }

     sk_sp<SkColorFilter> makeLegacyCF() const {
         // In 'legacy' mode, brightness is
         //
         //   - in the [-100..100] range
         //   - applied component-wise as a direct offset (255-based)
         //   - (neutral value: 0)
         //   - transfer function: https://www.desmos.com/calculator/zne0oqwwzb
         //
         // while contrast is
         //
         //   - in the [-100..100] range
         //   - applied as a component-wise linear transformation (scale+offset), such that
         //
         //       -100 always yields mid-gray: contrast(x, -100) == 0.5
         //          0 is the neutral value:   contrast(x,    0) == x
         //        100 always yields white:    contrast(x,  100) == 1
         //
         //   - transfer function: https://www.desmos.com/calculator/x5rxzhowhs
         //

         // Normalize to [-1..1]
         const auto brightness = SkTPin(fBrightness, -100.0f, 100.0f) / 255, // [-100/255 .. 100/255]
                    contrast   = SkTPin(fContrast  , -100.0f, 100.0f) / 100; // [      -1 ..       1]

         // The component scale is derived from contrast:
         //
         //   Contrast[-1 .. 0] -> Scale[0 .. 1]
         //   Contrast( 0 .. 1] -> Scale(1 .. +inf)
         const auto S = contrast > 0
             ? 1 / std::max(1 - contrast, SK_ScalarNearlyZero)
             : 1 + contrast;

         // The component offset is derived from both brightness and contrast:
         //
         //   Brightness[-100/255 .. 100/255] -> Offset[-100/255 .. 100/255]
         //   Contrast  [      -1 ..       0] -> Offset[     0.5 ..       0]
         //   Contrast  (       0 ..       1] -> Offset(       0 ..    -inf)
         //
         // Why do these pre/post compose depending on contrast scale, you ask?
         // Because AE - that's why!
         const auto B = 0.5f * (1 - S) + brightness * std::max(S, 1.0f);

         const float cm[] = {
             S, 0, 0, 0, B,
             0, S, 0, 0, B,
             0, 0, S, 0, B,
             0, 0, 0, 1, 0,
         };

         return SkColorFilters::Matrix(cm);
     }

     sk_sp<SkColorFilter> makeCF() const {
         const auto brightness = SkTPin(fBrightness, -150.0f, 150.0f) / 150, // [-1.0 .. 1]
                      contrast = SkTPin(fContrast  ,  -50.0f, 100.0f) / 100; // [-0.5 .. 1]


         auto b_eff = SkScalarNearlyZero(brightness)
                    ? nullptr
                    : fBrightnessEffect->makeColorFilter(make_brightness_coeffs(brightness)),
              c_eff = SkScalarNearlyZero(fContrast)
                    ? nullptr
                    : fContrastEffect->makeColorFilter(make_contrast_coeffs(contrast));

         return SkColorFilters::Compose(std::move(c_eff), std::move(b_eff));
     }

     const sk_sp<SkRuntimeEffect> fBrightnessEffect,
                                    fContrastEffect;

     ScalarValue fBrightness = 0,
                 fContrast   = 0,
                 fUseLegacy  = 0;

     using INHERITED = DiscardableAdapterBase<BrightnessContrastAdapter, sksg::ExternalColorFilter>;
 };

 } // namespace

 sk_sp<sksg::RenderNode> EffectBuilder::attachBrightnessContrastEffect(
         const skjson::ArrayValue& jprops, sk_sp<sksg::RenderNode> layer) const {
     return fBuilder->attachDiscardableAdapter<BrightnessContrastAdapter>(jprops,
                                                                          *fBuilder,
                                                                          std::move(layer));
 }

 } // namespace skottie::internal
	/*
	* 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 "modules/skottie/src/effects/Effects.h"

	#include "include/core/SkColorFilter.h"
	#include "include/effects/SkRuntimeEffect.h"
	#include "modules/skottie/src/Adapter.h"
	#include "modules/skottie/src/SkottieJson.h"
	#include "modules/skottie/src/SkottieValue.h"
	#include "modules/sksg/include/SkSGColorFilter.h"

	namespace skottie::internal {

	namespace {

	// The contrast effect transfer function can be approximated with the following
	// 3rd degree polynomial:
	//
	// f(x) = -2πC/3 * x³ + πC * x² + (1 - πC/3) * x
	//
	// where C is the normalized contrast value [-1..1].
	//
	// Derivation:
	//
	// - start off with sampling the AE contrast effect for various contrast/input values [1]
	//
	// - apply cubic polynomial curve fitting to determine best-fit coefficients for given
	// contrast values [2]
	//
	// - observations:
	// * negative contrast appears clamped at -0.5 (-50)
	// * a,b coefficients vary linearly vs. contrast
	// * the b coefficient for max contrast (1.0) looks kinda familiar: 3.14757 - coincidence?
	// probably not. let's run with it: b == πC
	//
	// - additionally, we expect the following to hold:
	// * f(0 ) = 0 \ \| d = 0
	// * f(1 ) = 1 \| => \| a = -2b/3
	// * f(0.5) = 0.5 / \| c = 1 - b/3
	//
	// - this yields a pretty decent approximation: [3]
	//
	//
	// Note (courtesy of mtklein, reed): [4] seems to yield a closer approximation, but requires
	// a more expensive sin
	//
	// f(x) = x + a * sin(2πx)/2π
	//
	// [1] https://www.desmos.com/calculator/oksptqpo8z
	// [2] https://www.desmos.com/calculator/oukrf6yahn
	// [3] https://www.desmos.com/calculator/ehem0vy3ft
	// [4] https://www.desmos.com/calculator/5t4xi10q4v
	//

	#ifndef SKOTTIE_ACCURATE_CONTRAST_APPROXIMATION
	static sk_sp<SkData> make_contrast_coeffs(float contrast) {
	struct { float a, b, c; } coeffs;

	coeffs.b = SK_ScalarPI * contrast;
	coeffs.a = -2 * coeffs.b / 3;
	coeffs.c = 1 - coeffs.b / 3;

	return SkData::MakeWithCopy(&coeffs, sizeof(coeffs));
	}

	static constexpr char CONTRAST_EFFECT[] = R"(
	uniform half a;
	uniform half b;
	uniform half c;

	void main(inout half4 color) {
	// C' = aC^3 + bC^2 + c*C
	color.rgb = ((acolor.rgb + b)color.rgb + c)*color.rgb;
	}
	)";
	#else
	// More accurate (but slower) approximation:
	//
	// f(x) = x + a * sin(2πx)
	//
	// a = -contrast/3π
	//
	static sk_sp<SkData> make_contrast_coeffs(float contrast) {
	const auto coeff_a = -contrast / (3 * SK_ScalarPI);

	return SkData::MakeWithCopy(&coeff_a, sizeof(coeff_a));
	}

	static constexpr char CONTRAST_EFFECT[] = R"(
	uniform half a;

	void main(inout half4 color) {
	color.rgb += a * sin(color.rgb * 6.283185);
	}
	)";

	#endif

	// Brightness transfer function approximation:
	//
	// f(x) = 1 - (1 - x)^(2^(1.8*B))
	//
	// where B is the normalized [-1..1] brightness value
	//
	// Visualization: https://www.desmos.com/calculator/wuyqa2wtol
	//
	static sk_sp<SkData> make_brightness_coeffs(float brightness) {
	const float coeff_a = std::pow(2.0f, brightness * 1.8f);

	return SkData::MakeWithCopy(&coeff_a, sizeof(coeff_a));
	}

	static constexpr char BRIGHTNESS_EFFECT[] = R"(
	uniform half a;

	void main(inout half4 color) {
	color.rgb = 1 - pow(1 - color.rgb, half3(a));
	}
	)";

	class BrightnessContrastAdapter final : public DiscardableAdapterBase<BrightnessContrastAdapter,
	sksg::ExternalColorFilter> {
	public:
	BrightnessContrastAdapter(const skjson::ArrayValue& jprops,
	const AnimationBuilder& abuilder,
	sk_sp<sksg::RenderNode> layer)
	: INHERITED(sksg::ExternalColorFilter::Make(std::move(layer)))
	, fBrightnessEffect(std::get<0>(SkRuntimeEffect::Make(SkString(BRIGHTNESS_EFFECT))))
	, fContrastEffect(std::get<0>(SkRuntimeEffect::Make(SkString(CONTRAST_EFFECT)))) {
	SkASSERT(fBrightnessEffect);
	SkASSERT(fContrastEffect);

	enum : size_t {
	kBrightness_Index = 0,
	kContrast_Index = 1,
	kUseLegacy_Index = 2,
	};

	EffectBinder(jprops, abuilder, this)
	.bind(kBrightness_Index, fBrightness)
	.bind( kContrast_Index, fContrast )
	.bind( kUseLegacy_Index, fUseLegacy );
	}

	private:
	void onSync() override {
	this->node()->setColorFilter(SkScalarRoundToInt(fUseLegacy)
	? this->makeLegacyCF()
	: this->makeCF());
	}

	sk_sp<SkColorFilter> makeLegacyCF() const {
	// In 'legacy' mode, brightness is
	//
	// - in the [-100..100] range
	// - applied component-wise as a direct offset (255-based)
	// - (neutral value: 0)
	// - transfer function: https://www.desmos.com/calculator/zne0oqwwzb
	//
	// while contrast is
	//
	// - in the [-100..100] range
	// - applied as a component-wise linear transformation (scale+offset), such that
	//
	// -100 always yields mid-gray: contrast(x, -100) == 0.5
	// 0 is the neutral value: contrast(x, 0) == x
	// 100 always yields white: contrast(x, 100) == 1
	//
	// - transfer function: https://www.desmos.com/calculator/x5rxzhowhs
	//

	// Normalize to [-1..1]
	const auto brightness = SkTPin(fBrightness, -100.0f, 100.0f) / 255, // [-100/255 .. 100/255]
	contrast = SkTPin(fContrast , -100.0f, 100.0f) / 100; // [ -1 .. 1]

	// The component scale is derived from contrast:
	//
	// Contrast[-1 .. 0] -> Scale[0 .. 1]
	// Contrast( 0 .. 1] -> Scale(1 .. +inf)
	const auto S = contrast > 0
	? 1 / std::max(1 - contrast, SK_ScalarNearlyZero)
	: 1 + contrast;

	// The component offset is derived from both brightness and contrast:
	//
	// Brightness[-100/255 .. 100/255] -> Offset[-100/255 .. 100/255]
	// Contrast [ -1 .. 0] -> Offset[ 0.5 .. 0]
	// Contrast ( 0 .. 1] -> Offset( 0 .. -inf)
	//
	// Why do these pre/post compose depending on contrast scale, you ask?
	// Because AE - that's why!
	const auto B = 0.5f * (1 - S) + brightness * std::max(S, 1.0f);

	const float cm[] = {
	S, 0, 0, 0, B,
	0, S, 0, 0, B,
	0, 0, S, 0, B,
	0, 0, 0, 1, 0,
	};

	return SkColorFilters::Matrix(cm);
	}

	sk_sp<SkColorFilter> makeCF() const {
	const auto brightness = SkTPin(fBrightness, -150.0f, 150.0f) / 150, // [-1.0 .. 1]
	contrast = SkTPin(fContrast , -50.0f, 100.0f) / 100; // [-0.5 .. 1]


	auto b_eff = SkScalarNearlyZero(brightness)
	? nullptr
	: fBrightnessEffect->makeColorFilter(make_brightness_coeffs(brightness)),
	c_eff = SkScalarNearlyZero(fContrast)
	? nullptr
	: fContrastEffect->makeColorFilter(make_contrast_coeffs(contrast));

	return SkColorFilters::Compose(std::move(c_eff), std::move(b_eff));
	}

	const sk_sp<SkRuntimeEffect> fBrightnessEffect,
	fContrastEffect;

	ScalarValue fBrightness = 0,
	fContrast = 0,
	fUseLegacy = 0;

	using INHERITED = DiscardableAdapterBase<BrightnessContrastAdapter, sksg::ExternalColorFilter>;
	};

	} // namespace

	sk_sp<sksg::RenderNode> EffectBuilder::attachBrightnessContrastEffect(
	const skjson::ArrayValue& jprops, sk_sp<sksg::RenderNode> layer) const {
	return fBuilder->attachDiscardableAdapter<BrightnessContrastAdapter>(jprops,
	*fBuilder,
	std::move(layer));
	}

	} // namespace skottie::internal