include/ui/ColorSpace.h - third_party/android/platform/frameworks/native - Git at Google

 /*
  * Copyright (C) 2016 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #ifndef ANDROID_UI_COLOR_SPACE
 #define ANDROID_UI_COLOR_SPACE

 #include <array>
 #include <cmath>
 #include <functional>
 #include <memory>
 #include <string>

 #include <math/mat3.h>
 #include <math/scalar.h>
 #include <math/vec2.h>
 #include <math/vec3.h>

 namespace android {

 class ColorSpace {
 public:
     typedef std::function<float(float)> transfer_function;
     typedef std::function<float(float)> clamping_function;

     struct TransferParameters {
         float g = 0.0f;
         float a = 0.0f;
         float b = 0.0f;
         float c = 0.0f;
         float d = 0.0f;
         float e = 0.0f;
         float f = 0.0f;
     };

     /**
      * Creates a named color space with the specified RGB->XYZ
      * conversion matrix. The white point and primaries will be
      * computed from the supplied matrix.
      *
      * The default transfer functions are a linear response x->x
      * and the default clamping function is a simple saturate
      * (clamp(x, 0, 1)).
      */
     ColorSpace(
             const std::string& name,
             const mat3& rgbToXYZ,
             transfer_function OETF = linearResponse,
             transfer_function EOTF = linearResponse,
             clamping_function clamper = saturate<float>
     ) noexcept;

     /**
      * Creates a named color space with the specified RGB->XYZ
      * conversion matrix. The white point and primaries will be
      * computed from the supplied matrix.
      *
      * The transfer functions are defined by the set of supplied
      * transfer parameters. The default clamping function is a
      * simple saturate (clamp(x, 0, 1)).
      */
     ColorSpace(
             const std::string& name,
             const mat3& rgbToXYZ,
             const TransferParameters parameters,
             clamping_function clamper = saturate<float>
     ) noexcept;

     /**
      * Creates a named color space with the specified RGB->XYZ
      * conversion matrix. The white point and primaries will be
      * computed from the supplied matrix.
      *
      * The transfer functions are defined by a simple gamma value.
      * The default clamping function is a saturate (clamp(x, 0, 1)).
      */
     ColorSpace(
             const std::string& name,
             const mat3& rgbToXYZ,
             float gamma,
             clamping_function clamper = saturate<float>
     ) noexcept;

     /**
      * Creates a named color space with the specified primaries
      * and white point. The RGB<>XYZ conversion matrices are
      * computed from the primaries and white point.
      *
      * The default transfer functions are a linear response x->x
      * and the default clamping function is a simple saturate
      * (clamp(x, 0, 1)).
      */
     ColorSpace(
             const std::string& name,
             const std::array<float2, 3>& primaries,
             const float2& whitePoint,
             transfer_function OETF = linearResponse,
             transfer_function EOTF = linearResponse,
             clamping_function clamper = saturate<float>
     ) noexcept;

     /**
      * Creates a named color space with the specified primaries
      * and white point. The RGB<>XYZ conversion matrices are
      * computed from the primaries and white point.
      *
      * The transfer functions are defined by the set of supplied
      * transfer parameters. The default clamping function is a
      * simple saturate (clamp(x, 0, 1)).
      */
     ColorSpace(
             const std::string& name,
             const std::array<float2, 3>& primaries,
             const float2& whitePoint,
             const TransferParameters parameters,
             clamping_function clamper = saturate<float>
     ) noexcept;

     /**
      * Creates a named color space with the specified primaries
      * and white point. The RGB<>XYZ conversion matrices are
      * computed from the primaries and white point.
      *
      * The transfer functions are defined by a single gamma value.
      * The default clamping function is a saturate (clamp(x, 0, 1)).
      */
     ColorSpace(
             const std::string& name,
             const std::array<float2, 3>& primaries,
             const float2& whitePoint,
             float gamma,
             clamping_function clamper = saturate<float>
     ) noexcept;

     ColorSpace() noexcept = delete;

     /**
      * Encodes the supplied RGB value using this color space's
      * opto-electronic transfer function.
      */
     constexpr float3 fromLinear(const float3& v) const noexcept {
         return apply(v, mOETF);
     }

     /**
      * Decodes the supplied RGB value using this color space's
      * electro-optical transfer function.
      */
     constexpr float3 toLinear(const float3& v) const noexcept {
         return apply(v, mEOTF);
     }

     /**
      * Converts the supplied XYZ value to RGB. The returned value
      * is encoded with this color space's opto-electronic transfer
      * function and clamped by this color space's clamping function.
      */
     constexpr float3 xyzToRGB(const float3& xyz) const noexcept {
         return apply(fromLinear(mXYZtoRGB * xyz), mClamper);
     }

     /**
      * Converts the supplied RGB value to XYZ. The input RGB value
      * is decoded using this color space's electro-optical function
      * before being converted to XYZ.
      */
     constexpr float3 rgbToXYZ(const float3& rgb) const noexcept {
         return mRGBtoXYZ * toLinear(rgb);
     }

     constexpr const std::string& getName() const noexcept {
         return mName;
     }

     constexpr const mat3& getRGBtoXYZ() const noexcept {
         return mRGBtoXYZ;
     }

     constexpr const mat3& getXYZtoRGB() const noexcept {
         return mXYZtoRGB;
     }

     constexpr const transfer_function& getOETF() const noexcept {
         return mOETF;
     }

     constexpr const transfer_function& getEOTF() const noexcept {
         return mEOTF;
     }

     constexpr const clamping_function& getClamper() const noexcept {
         return mClamper;
     }

     constexpr const std::array<float2, 3>& getPrimaries() const noexcept {
         return mPrimaries;
     }

     constexpr const float2& getWhitePoint() const noexcept {
         return mWhitePoint;
     }

     constexpr const TransferParameters& getTransferParameters() const noexcept {
         return mParameters;
     }

     /**
      * Converts the supplied XYZ value to xyY.
      */
     static constexpr float2 xyY(const float3& XYZ) {
         return XYZ.xy / dot(XYZ, float3{1});
     }

     /**
      * Converts the supplied xyY value to XYZ.
      */
     static constexpr float3 XYZ(const float3& xyY) {
         return float3{(xyY.x * xyY.z) / xyY.y, xyY.z, ((1 - xyY.x - xyY.y) * xyY.z) / xyY.y};
     }

     static const ColorSpace sRGB();
     static const ColorSpace linearSRGB();
     static const ColorSpace extendedSRGB();
     static const ColorSpace linearExtendedSRGB();
     static const ColorSpace NTSC();
     static const ColorSpace BT709();
     static const ColorSpace BT2020();
     static const ColorSpace AdobeRGB();
     static const ColorSpace ProPhotoRGB();
     static const ColorSpace DisplayP3();
     static const ColorSpace DCIP3();
     static const ColorSpace ACES();
     static const ColorSpace ACEScg();

     // Creates a NxNxN 3D LUT, where N is the specified size (min=2, max=256)
     // The 3D lookup coordinates map to the RGB components: u=R, v=G, w=B
     // The generated 3D LUT is meant to be used as a 3D texture and its Y
     // axis is thus already flipped
     // The source color space must define its values in the domain [0..1]
     // The generated LUT transforms from gamma space to gamma space
     static std::unique_ptr<float3> createLUT(uint32_t size,
             const ColorSpace& src, const ColorSpace& dst);

 private:
     static constexpr mat3 computeXYZMatrix(
             const std::array<float2, 3>& primaries, const float2& whitePoint);

     static constexpr float linearResponse(float v) {
         return v;
     }

     std::string mName;

     mat3 mRGBtoXYZ;
     mat3 mXYZtoRGB;

     TransferParameters mParameters;
     transfer_function mOETF;
     transfer_function mEOTF;
     clamping_function mClamper;

     std::array<float2, 3> mPrimaries;
     float2 mWhitePoint;
 };

 class ColorSpaceConnector {
 public:
     ColorSpaceConnector(const ColorSpace& src, const ColorSpace& dst) noexcept;

     constexpr const ColorSpace& getSource() const noexcept { return mSource; }
     constexpr const ColorSpace& getDestination() const noexcept { return mDestination; }

     constexpr const mat3& getTransform() const noexcept { return mTransform; }

     constexpr float3 transform(const float3& v) const noexcept {
         float3 linear = mSource.toLinear(apply(v, mSource.getClamper()));
         return apply(mDestination.fromLinear(mTransform * linear), mDestination.getClamper());
     }

     constexpr float3 transformLinear(const float3& v) const noexcept {
         float3 linear = apply(v, mSource.getClamper());
         return apply(mTransform * linear, mDestination.getClamper());
     }

 private:
     ColorSpace mSource;
     ColorSpace mDestination;
     mat3 mTransform;
 };

 }; // namespace android

 #endif // ANDROID_UI_COLOR_SPACE
	/*
	* Copyright (C) 2016 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#ifndef ANDROID_UI_COLOR_SPACE
	#define ANDROID_UI_COLOR_SPACE

	#include <array>
	#include <cmath>
	#include <functional>
	#include <memory>
	#include <string>

	#include <math/mat3.h>
	#include <math/scalar.h>
	#include <math/vec2.h>
	#include <math/vec3.h>

	namespace android {

	class ColorSpace {
	public:
	typedef std::function<float(float)> transfer_function;
	typedef std::function<float(float)> clamping_function;

	struct TransferParameters {
	float g = 0.0f;
	float a = 0.0f;
	float b = 0.0f;
	float c = 0.0f;
	float d = 0.0f;
	float e = 0.0f;
	float f = 0.0f;
	};

	/**
	* Creates a named color space with the specified RGB->XYZ
	* conversion matrix. The white point and primaries will be
	* computed from the supplied matrix.
	*
	* The default transfer functions are a linear response x->x
	* and the default clamping function is a simple saturate
	* (clamp(x, 0, 1)).
	*/
	ColorSpace(
	const std::string& name,
	const mat3& rgbToXYZ,
	transfer_function OETF = linearResponse,
	transfer_function EOTF = linearResponse,
	clamping_function clamper = saturate<float>
	) noexcept;

	/**
	* Creates a named color space with the specified RGB->XYZ
	* conversion matrix. The white point and primaries will be
	* computed from the supplied matrix.
	*
	* The transfer functions are defined by the set of supplied
	* transfer parameters. The default clamping function is a
	* simple saturate (clamp(x, 0, 1)).
	*/
	ColorSpace(
	const std::string& name,
	const mat3& rgbToXYZ,
	const TransferParameters parameters,
	clamping_function clamper = saturate<float>
	) noexcept;

	/**
	* Creates a named color space with the specified RGB->XYZ
	* conversion matrix. The white point and primaries will be
	* computed from the supplied matrix.
	*
	* The transfer functions are defined by a simple gamma value.
	* The default clamping function is a saturate (clamp(x, 0, 1)).
	*/
	ColorSpace(
	const std::string& name,
	const mat3& rgbToXYZ,
	float gamma,
	clamping_function clamper = saturate<float>
	) noexcept;

	/**
	* Creates a named color space with the specified primaries
	* and white point. The RGB<>XYZ conversion matrices are
	* computed from the primaries and white point.
	*
	* The default transfer functions are a linear response x->x
	* and the default clamping function is a simple saturate
	* (clamp(x, 0, 1)).
	*/
	ColorSpace(
	const std::string& name,
	const std::array<float2, 3>& primaries,
	const float2& whitePoint,
	transfer_function OETF = linearResponse,
	transfer_function EOTF = linearResponse,
	clamping_function clamper = saturate<float>
	) noexcept;

	/**
	* Creates a named color space with the specified primaries
	* and white point. The RGB<>XYZ conversion matrices are
	* computed from the primaries and white point.
	*
	* The transfer functions are defined by the set of supplied
	* transfer parameters. The default clamping function is a
	* simple saturate (clamp(x, 0, 1)).
	*/
	ColorSpace(
	const std::string& name,
	const std::array<float2, 3>& primaries,
	const float2& whitePoint,
	const TransferParameters parameters,
	clamping_function clamper = saturate<float>
	) noexcept;

	/**
	* Creates a named color space with the specified primaries
	* and white point. The RGB<>XYZ conversion matrices are
	* computed from the primaries and white point.
	*
	* The transfer functions are defined by a single gamma value.
	* The default clamping function is a saturate (clamp(x, 0, 1)).
	*/
	ColorSpace(
	const std::string& name,
	const std::array<float2, 3>& primaries,
	const float2& whitePoint,
	float gamma,
	clamping_function clamper = saturate<float>
	) noexcept;

	ColorSpace() noexcept = delete;

	/**
	* Encodes the supplied RGB value using this color space's
	* opto-electronic transfer function.
	*/
	constexpr float3 fromLinear(const float3& v) const noexcept {
	return apply(v, mOETF);
	}

	/**
	* Decodes the supplied RGB value using this color space's
	* electro-optical transfer function.
	*/
	constexpr float3 toLinear(const float3& v) const noexcept {
	return apply(v, mEOTF);
	}

	/**
	* Converts the supplied XYZ value to RGB. The returned value
	* is encoded with this color space's opto-electronic transfer
	* function and clamped by this color space's clamping function.
	*/
	constexpr float3 xyzToRGB(const float3& xyz) const noexcept {
	return apply(fromLinear(mXYZtoRGB * xyz), mClamper);
	}

	/**
	* Converts the supplied RGB value to XYZ. The input RGB value
	* is decoded using this color space's electro-optical function
	* before being converted to XYZ.
	*/
	constexpr float3 rgbToXYZ(const float3& rgb) const noexcept {
	return mRGBtoXYZ * toLinear(rgb);
	}

	constexpr const std::string& getName() const noexcept {
	return mName;
	}

	constexpr const mat3& getRGBtoXYZ() const noexcept {
	return mRGBtoXYZ;
	}

	constexpr const mat3& getXYZtoRGB() const noexcept {
	return mXYZtoRGB;
	}

	constexpr const transfer_function& getOETF() const noexcept {
	return mOETF;
	}

	constexpr const transfer_function& getEOTF() const noexcept {
	return mEOTF;
	}

	constexpr const clamping_function& getClamper() const noexcept {
	return mClamper;
	}

	constexpr const std::array<float2, 3>& getPrimaries() const noexcept {
	return mPrimaries;
	}

	constexpr const float2& getWhitePoint() const noexcept {
	return mWhitePoint;
	}

	constexpr const TransferParameters& getTransferParameters() const noexcept {
	return mParameters;
	}

	/**
	* Converts the supplied XYZ value to xyY.
	*/
	static constexpr float2 xyY(const float3& XYZ) {
	return XYZ.xy / dot(XYZ, float3{1});
	}

	/**
	* Converts the supplied xyY value to XYZ.
	*/
	static constexpr float3 XYZ(const float3& xyY) {
	return float3{(xyY.x * xyY.z) / xyY.y, xyY.z, ((1 - xyY.x - xyY.y) * xyY.z) / xyY.y};
	}

	static const ColorSpace sRGB();
	static const ColorSpace linearSRGB();
	static const ColorSpace extendedSRGB();
	static const ColorSpace linearExtendedSRGB();
	static const ColorSpace NTSC();
	static const ColorSpace BT709();
	static const ColorSpace BT2020();
	static const ColorSpace AdobeRGB();
	static const ColorSpace ProPhotoRGB();
	static const ColorSpace DisplayP3();
	static const ColorSpace DCIP3();
	static const ColorSpace ACES();
	static const ColorSpace ACEScg();

	// Creates a NxNxN 3D LUT, where N is the specified size (min=2, max=256)
	// The 3D lookup coordinates map to the RGB components: u=R, v=G, w=B
	// The generated 3D LUT is meant to be used as a 3D texture and its Y
	// axis is thus already flipped
	// The source color space must define its values in the domain [0..1]
	// The generated LUT transforms from gamma space to gamma space
	static std::unique_ptr<float3> createLUT(uint32_t size,
	const ColorSpace& src, const ColorSpace& dst);

	private:
	static constexpr mat3 computeXYZMatrix(
	const std::array<float2, 3>& primaries, const float2& whitePoint);

	static constexpr float linearResponse(float v) {
	return v;
	}

	std::string mName;

	mat3 mRGBtoXYZ;
	mat3 mXYZtoRGB;

	TransferParameters mParameters;
	transfer_function mOETF;
	transfer_function mEOTF;
	clamping_function mClamper;

	std::array<float2, 3> mPrimaries;
	float2 mWhitePoint;
	};

	class ColorSpaceConnector {
	public:
	ColorSpaceConnector(const ColorSpace& src, const ColorSpace& dst) noexcept;

	constexpr const ColorSpace& getSource() const noexcept { return mSource; }
	constexpr const ColorSpace& getDestination() const noexcept { return mDestination; }

	constexpr const mat3& getTransform() const noexcept { return mTransform; }

	constexpr float3 transform(const float3& v) const noexcept {
	float3 linear = mSource.toLinear(apply(v, mSource.getClamper()));
	return apply(mDestination.fromLinear(mTransform * linear), mDestination.getClamper());
	}

	constexpr float3 transformLinear(const float3& v) const noexcept {
	float3 linear = apply(v, mSource.getClamper());
	return apply(mTransform * linear, mDestination.getClamper());
	}

	private:
	ColorSpace mSource;
	ColorSpace mDestination;
	mat3 mTransform;
	};

	}; // namespace android

	#endif // ANDROID_UI_COLOR_SPACE