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

 /*
  * Copyright 2019 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.
  */

 #pragma once

 #include <algorithm>
 #include <cstdint>
 #include <limits>
 #include <ostream>
 #include <type_traits>
 #include <utility>

 namespace android {
 namespace ui {

 // Forward declare a few things.
 struct Size;
 bool operator==(const Size& lhs, const Size& rhs);

 /**
  * A simple value type representing a two-dimensional size
  */
 struct Size {
     int32_t width;
     int32_t height;

     // Special values
     static const Size INVALID;
     static const Size EMPTY;

     // ------------------------------------------------------------------------
     // Construction
     // ------------------------------------------------------------------------

     Size() : Size(INVALID) {}
     template <typename T>
     Size(T&& w, T&& h)
           : width(Size::clamp<int32_t, T>(std::forward<T>(w))),
             height(Size::clamp<int32_t, T>(std::forward<T>(h))) {}

     // ------------------------------------------------------------------------
     // Accessors
     // ------------------------------------------------------------------------

     int32_t getWidth() const { return width; }
     int32_t getHeight() const { return height; }

     template <typename T>
     void setWidth(T&& v) {
         width = Size::clamp<int32_t, T>(std::forward<T>(v));
     }
     template <typename T>
     void setHeight(T&& v) {
         height = Size::clamp<int32_t, T>(std::forward<T>(v));
     }

     // ------------------------------------------------------------------------
     // Assignment
     // ------------------------------------------------------------------------

     void set(const Size& size) { *this = size; }
     template <typename T>
     void set(T&& w, T&& h) {
         set(Size(std::forward<T>(w), std::forward<T>(h)));
     }

     // Sets the value to INVALID
     void makeInvalid() { set(INVALID); }

     // Sets the value to EMPTY
     void clear() { set(EMPTY); }

     // ------------------------------------------------------------------------
     // Semantic checks
     // ------------------------------------------------------------------------

     // Valid means non-negative width and height
     bool isValid() const { return width >= 0 && height >= 0; }

     // Empty means zero width and height
     bool isEmpty() const { return *this == EMPTY; }

     // ------------------------------------------------------------------------
     // Clamp Helpers
     // ------------------------------------------------------------------------

     // Note: We use only features available in C++11 here for compatibility with
     // external targets which include this file directly or indirectly and which
     // themselves use C++11.

     // C++11 compatible replacement for std::remove_cv_reference_t [C++20]
     template <typename T>
     using remove_cv_reference_t =
             typename std::remove_cv<typename std::remove_reference<T>::type>::type;

     // Takes a value of type FromType, and ensures it can be represented as a value of type ToType,
     // clamping the input value to the output range if necessary.
     template <typename ToType, typename FromType>
     static Size::remove_cv_reference_t<ToType>
     clamp(typename std::enable_if<
             std::numeric_limits<Size::remove_cv_reference_t<ToType>>::is_specialized &&
                     std::numeric_limits<Size::remove_cv_reference_t<FromType>>::is_specialized,
             FromType>::type v) {
         using BareToType = remove_cv_reference_t<ToType>;
         using BareFromType = remove_cv_reference_t<FromType>;
         static constexpr auto toHighest = std::numeric_limits<BareToType>::max();
         static constexpr auto toLowest = std::numeric_limits<BareToType>::lowest();
         static constexpr auto fromHighest = std::numeric_limits<BareFromType>::max();
         static constexpr auto fromLowest = std::numeric_limits<BareFromType>::lowest();

         // Get the closest representation of [toLowest, toHighest] in type
         // FromType to use to clamp the input value before conversion.

         // std::common_type<...> is used to get a value-preserving type for the
         // top end of the range.
         using CommonHighestType = std::common_type_t<BareToType, BareFromType>;

         // std::make_signed<std::common_type<...>> is used to get a
         // value-preserving type for the bottom end of the range, except this is
         // a bit trickier for non-integer types like float.
         using CommonLowestType =
                 std::conditional_t<std::numeric_limits<CommonHighestType>::is_integer,
                                    std::make_signed_t<std::conditional_t<
                                            std::numeric_limits<CommonHighestType>::is_integer,
                                            CommonHighestType, int /* not used */>>,
                                    CommonHighestType>;

         // We can then compute the clamp range in a way that can be later
         // trivially converted to either the 'from' or 'to' types, and be
         // representabile in either.
         static constexpr auto commonClampHighest =
                 std::min(static_cast<CommonHighestType>(fromHighest),
                          static_cast<CommonHighestType>(toHighest));
         static constexpr auto commonClampLowest =
                 std::max(static_cast<CommonLowestType>(fromLowest),
                          static_cast<CommonLowestType>(toLowest));

         static constexpr auto fromClampHighest = static_cast<BareFromType>(commonClampHighest);
         static constexpr auto fromClampLowest = static_cast<BareFromType>(commonClampLowest);

         // A clamp is needed only if the range we are clamping to is not the
         // same as the range of the input.
         static constexpr bool isClampNeeded =
                 (fromLowest != fromClampLowest) || (fromHighest != fromClampHighest);

         // If a clamp is not needed, the conversion is just a trivial cast.
         if (!isClampNeeded) {
             return static_cast<BareToType>(v);
         }

         // Note: Clang complains about the value of INT32_MAX not being
         // convertible back to int32_t from float if this is made "constexpr",
         // when clamping a float value to an int32_t value. This is however
         // covered by a test case to ensure the run-time cast works correctly.
         const auto toClampHighest = static_cast<BareToType>(commonClampHighest);
         const auto toClampLowest = static_cast<BareToType>(commonClampLowest);

         // Otherwise clamping is done by using the already computed endpoints
         // for each type.
         return (v <= fromClampLowest)
                 ? toClampLowest
                 : ((v >= fromClampHighest) ? toClampHighest : static_cast<BareToType>(v));
     }
 };

 // ------------------------------------------------------------------------
 // Comparisons
 // ------------------------------------------------------------------------

 inline bool operator==(const Size& lhs, const Size& rhs) {
     return lhs.width == rhs.width && lhs.height == rhs.height;
 }

 inline bool operator!=(const Size& lhs, const Size& rhs) {
     return !operator==(lhs, rhs);
 }

 inline bool operator<(const Size& lhs, const Size& rhs) {
     // Orders by increasing width, then height.
     if (lhs.width != rhs.width) return lhs.width < rhs.width;
     return lhs.height < rhs.height;
 }

 // Defining PrintTo helps with Google Tests.
 static inline void PrintTo(const Size& size, ::std::ostream* os) {
     *os << "Size(" << size.width << ", " << size.height << ")";
 }

 } // namespace ui
 } // namespace android
	/*
	* Copyright 2019 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.
	*/

	#pragma once

	#include <algorithm>
	#include <cstdint>
	#include <limits>
	#include <ostream>
	#include <type_traits>
	#include <utility>

	namespace android {
	namespace ui {

	// Forward declare a few things.
	struct Size;
	bool operator==(const Size& lhs, const Size& rhs);

	/**
	* A simple value type representing a two-dimensional size
	*/
	struct Size {
	int32_t width;
	int32_t height;

	// Special values
	static const Size INVALID;
	static const Size EMPTY;

	// ------------------------------------------------------------------------
	// Construction
	// ------------------------------------------------------------------------

	Size() : Size(INVALID) {}
	template <typename T>
	Size(T&& w, T&& h)
	: width(Size::clamp<int32_t, T>(std::forward<T>(w))),
	height(Size::clamp<int32_t, T>(std::forward<T>(h))) {}

	// ------------------------------------------------------------------------
	// Accessors
	// ------------------------------------------------------------------------

	int32_t getWidth() const { return width; }
	int32_t getHeight() const { return height; }

	template <typename T>
	void setWidth(T&& v) {
	width = Size::clamp<int32_t, T>(std::forward<T>(v));
	}
	template <typename T>
	void setHeight(T&& v) {
	height = Size::clamp<int32_t, T>(std::forward<T>(v));
	}

	// ------------------------------------------------------------------------
	// Assignment
	// ------------------------------------------------------------------------

	void set(const Size& size) { *this = size; }
	template <typename T>
	void set(T&& w, T&& h) {
	set(Size(std::forward<T>(w), std::forward<T>(h)));
	}

	// Sets the value to INVALID
	void makeInvalid() { set(INVALID); }

	// Sets the value to EMPTY
	void clear() { set(EMPTY); }

	// ------------------------------------------------------------------------
	// Semantic checks
	// ------------------------------------------------------------------------

	// Valid means non-negative width and height
	bool isValid() const { return width >= 0 && height >= 0; }

	// Empty means zero width and height
	bool isEmpty() const { return *this == EMPTY; }

	// ------------------------------------------------------------------------
	// Clamp Helpers
	// ------------------------------------------------------------------------

	// Note: We use only features available in C++11 here for compatibility with
	// external targets which include this file directly or indirectly and which
	// themselves use C++11.

	// C++11 compatible replacement for std::remove_cv_reference_t [C++20]
	template <typename T>
	using remove_cv_reference_t =
	typename std::remove_cv<typename std::remove_reference<T>::type>::type;

	// Takes a value of type FromType, and ensures it can be represented as a value of type ToType,
	// clamping the input value to the output range if necessary.
	template <typename ToType, typename FromType>
	static Size::remove_cv_reference_t<ToType>
	clamp(typename std::enable_if<
	std::numeric_limits<Size::remove_cv_reference_t<ToType>>::is_specialized &&
	std::numeric_limits<Size::remove_cv_reference_t<FromType>>::is_specialized,
	FromType>::type v) {
	using BareToType = remove_cv_reference_t<ToType>;
	using BareFromType = remove_cv_reference_t<FromType>;
	static constexpr auto toHighest = std::numeric_limits<BareToType>::max();
	static constexpr auto toLowest = std::numeric_limits<BareToType>::lowest();
	static constexpr auto fromHighest = std::numeric_limits<BareFromType>::max();
	static constexpr auto fromLowest = std::numeric_limits<BareFromType>::lowest();

	// Get the closest representation of [toLowest, toHighest] in type
	// FromType to use to clamp the input value before conversion.

	// std::common_type<...> is used to get a value-preserving type for the
	// top end of the range.
	using CommonHighestType = std::common_type_t<BareToType, BareFromType>;

	// std::make_signed<std::common_type<...>> is used to get a
	// value-preserving type for the bottom end of the range, except this is
	// a bit trickier for non-integer types like float.
	using CommonLowestType =
	std::conditional_t<std::numeric_limits<CommonHighestType>::is_integer,
	std::make_signed_t<std::conditional_t<
	std::numeric_limits<CommonHighestType>::is_integer,
	CommonHighestType, int /* not used */>>,
	CommonHighestType>;

	// We can then compute the clamp range in a way that can be later
	// trivially converted to either the 'from' or 'to' types, and be
	// representabile in either.
	static constexpr auto commonClampHighest =
	std::min(static_cast<CommonHighestType>(fromHighest),
	static_cast<CommonHighestType>(toHighest));
	static constexpr auto commonClampLowest =
	std::max(static_cast<CommonLowestType>(fromLowest),
	static_cast<CommonLowestType>(toLowest));

	static constexpr auto fromClampHighest = static_cast<BareFromType>(commonClampHighest);
	static constexpr auto fromClampLowest = static_cast<BareFromType>(commonClampLowest);

	// A clamp is needed only if the range we are clamping to is not the
	// same as the range of the input.
	static constexpr bool isClampNeeded =
	(fromLowest != fromClampLowest) \|\| (fromHighest != fromClampHighest);

	// If a clamp is not needed, the conversion is just a trivial cast.
	if (!isClampNeeded) {
	return static_cast<BareToType>(v);
	}

	// Note: Clang complains about the value of INT32_MAX not being
	// convertible back to int32_t from float if this is made "constexpr",
	// when clamping a float value to an int32_t value. This is however
	// covered by a test case to ensure the run-time cast works correctly.
	const auto toClampHighest = static_cast<BareToType>(commonClampHighest);
	const auto toClampLowest = static_cast<BareToType>(commonClampLowest);

	// Otherwise clamping is done by using the already computed endpoints
	// for each type.
	return (v <= fromClampLowest)
	? toClampLowest
	: ((v >= fromClampHighest) ? toClampHighest : static_cast<BareToType>(v));
	}
	};

	// ------------------------------------------------------------------------
	// Comparisons
	// ------------------------------------------------------------------------

	inline bool operator==(const Size& lhs, const Size& rhs) {
	return lhs.width == rhs.width && lhs.height == rhs.height;
	}

	inline bool operator!=(const Size& lhs, const Size& rhs) {
	return !operator==(lhs, rhs);
	}

	inline bool operator<(const Size& lhs, const Size& rhs) {
	// Orders by increasing width, then height.
	if (lhs.width != rhs.width) return lhs.width < rhs.width;
	return lhs.height < rhs.height;
	}

	// Defining PrintTo helps with Google Tests.
	static inline void PrintTo(const Size& size, ::std::ostream* os) {
	*os << "Size(" << size.width << ", " << size.height << ")";
	}

	} // namespace ui
	} // namespace android