libs/vr/libvrflinger/hwc_types.h - third_party/android/platform/frameworks/native - Git at Google

 #ifndef ANDROID_LIBVRFLINGER_HWCTYPES_H
 #define ANDROID_LIBVRFLINGER_HWCTYPES_H

 // General HWC type support. Hardware composer type support is a bit of a mess
 // between HWC1, HWC2 C/C++11, and HIDL types. Particularly bothersome is the
 // use of enum classes, which make analogous types between versions much
 // harder to deal with in a uniform way.
 //
 // These utilities help address some of these pains by providing a type-safe,
 // flexible interface to translate between different type spaces.

 #define HWC2_INCLUDE_STRINGIFICATION
 #define HWC2_USE_CPP11
 #include <hardware/hwcomposer2.h>
 #undef HWC2_INCLUDE_STRINGIFICATION
 #undef HWC2_USE_CPP11

 #include <string>
 #include <type_traits>

 namespace HWC {

 // Value types derived from HWC HAL types. Some of these are stand-alone,
 // while others are also wrapped in translator classes below.
 using ColorMode = int32_t;  // android_color_mode_t;
 using Config = hwc2_config_t;
 using ColorTransform =
     std::underlying_type<android_color_transform_t>::type;          // int32_t;
 using Dataspace = std::underlying_type<android_dataspace_t>::type;  // int32_t;
 using DisplayId = hwc2_display_t;
 using DisplayRequest = std::underlying_type<HWC2::DisplayRequest>::type;
 using Hdr = std::underlying_type<android_hdr_t>::type;  // int32_t;
 using Layer = hwc2_layer_t;
 using PixelFormat =
     std::underlying_type<android_pixel_format_t>::type;  // int32_t;

 // Type traits and casting utilities.

 // SFINAE utility to evaluate type expressions.
 template <typename...>
 using TestTypeExpression = void;

 // Traits type to determine the underlying type of an enum, integer,
 // or wrapper class.
 template <typename T, typename = typename std::is_enum<T>::type,
           typename = typename std::is_integral<T>::type, typename = void>
 struct UnderlyingType {
   using Type = T;
 };
 // Partial specialization that matches enum types. Captures the underlying type
 // of the enum in member type Type.
 template <typename T>
 struct UnderlyingType<T, std::true_type, std::false_type> {
   using Type = typename std::underlying_type<T>::type;
 };
 // Partial specialization that matches integral types. Captures the type of the
 // integer in member type Type.
 template <typename T>
 struct UnderlyingType<T, std::false_type, std::true_type> {
   using Type = T;
 };
 // Partial specialization that matches the wrapper types below. Captures
 // wrapper member type ValueType in member type Type.
 template <typename T>
 struct UnderlyingType<T, std::false_type, std::false_type,
                       TestTypeExpression<typename T::ValueType>> {
   using Type = typename T::ValueType;
 };

 // Enable if T is an enum with underlying type U.
 template <typename T, typename U, typename ReturnType = void>
 using EnableIfMatchingEnum = typename std::enable_if<
     std::is_enum<T>::value &&
         std::is_same<U, typename UnderlyingType<T>::Type>::value,
     ReturnType>::type;

 // Enable if T and U are the same size/alignment and have the same underlying
 // type. Handles enum, integral, and wrapper classes below.
 template <typename T, typename U, typename Return = void>
 using EnableIfSafeCast = typename std::enable_if<
     sizeof(T) == sizeof(U) && alignof(T) == alignof(U) &&
         std::is_same<typename UnderlyingType<T>::Type,
                      typename UnderlyingType<U>::Type>::value,
     Return>::type;

 // Safely cast between std::vectors of matching enum/integer/wraper types.
 // Normally this is not possible with pendantic compiler type checks. However,
 // given the same size, alignment, and underlying type this is safe due to
 // allocator requirements and array-like element access guarantees.
 template <typename T, typename U>
 EnableIfSafeCast<T, U, std::vector<T>*> VectorCast(std::vector<U>* in) {
   return reinterpret_cast<std::vector<T>*>(in);
 }

 // Translator classes that wrap specific HWC types to make translating
 // between different types (especially enum class) in code cleaner.

 // Base type for the enum wrappers below. This type provides type definitions
 // and implicit conversion logic common to each wrapper type.
 template <typename EnumType>
 struct Wrapper {
   // Alias type of this instantiantion of Wrapper. Useful for inheriting
   // constructors in subclasses via "using Base::Base;" statements.
   using Base = Wrapper<EnumType>;

   // The enum type wrapped by this instantiation of Wrapper.
   using BaseType = EnumType;

   // The underlying type of the base enum type.
   using ValueType = typename UnderlyingType<BaseType>::Type;

   // A default constructor is not defined here. Subclasses should define one
   // as appropriate to define the correct inital value for the enum type.

   // Default copy constructor.
   Wrapper(const Wrapper&) = default;

   // Implicit conversion from ValueType.
   Wrapper(ValueType value) : value(value) {}

   // Implicit conversion from BaseType.
   Wrapper(BaseType value) : value(static_cast<ValueType>(value)) {}

   // Implicit conversion from an enum type of the same underlying type.
   template <typename T, typename = EnableIfMatchingEnum<T, ValueType>>
   Wrapper(const T& value) : value(static_cast<ValueType>(value)) {}

   // Implicit conversion to BaseType.
   operator BaseType() const { return static_cast<BaseType>(value); }

   // Implicit conversion to ValueType.
   operator ValueType() const { return value; }

   template <typename T, typename = EnableIfMatchingEnum<T, ValueType>>
   T cast() const {
     return static_cast<T>(value);
   }

   // Converts to string using HWC2 stringification of BaseType.
   std::string to_string() const {
     return HWC2::to_string(static_cast<BaseType>(value));
   }

   bool operator!=(const Wrapper& other) const { return value != other.value; }
   bool operator!=(ValueType other_value) const { return value != other_value; }
   bool operator!=(BaseType other_value) const {
     return static_cast<BaseType>(value) != other_value;
   }
   bool operator==(const Wrapper& other) const { return value == other.value; }
   bool operator==(ValueType other_value) const { return value == other_value; }
   bool operator==(BaseType other_value) const {
     return static_cast<BaseType>(value) == other_value;
   }

   ValueType value;
 };

 struct Attribute final : public Wrapper<HWC2::Attribute> {
   enum : ValueType {
     Invalid = HWC2_ATTRIBUTE_INVALID,
     Width = HWC2_ATTRIBUTE_WIDTH,
     Height = HWC2_ATTRIBUTE_HEIGHT,
     VsyncPeriod = HWC2_ATTRIBUTE_VSYNC_PERIOD,
     DpiX = HWC2_ATTRIBUTE_DPI_X,
     DpiY = HWC2_ATTRIBUTE_DPI_Y,
   };

   Attribute() : Base(Invalid) {}
   using Base::Base;
 };

 struct BlendMode final : public Wrapper<HWC2::BlendMode> {
   enum : ValueType {
     Invalid = HWC2_BLEND_MODE_INVALID,
     None = HWC2_BLEND_MODE_NONE,
     Premultiplied = HWC2_BLEND_MODE_PREMULTIPLIED,
     Coverage = HWC2_BLEND_MODE_COVERAGE,
   };

   BlendMode() : Base(Invalid) {}
   using Base::Base;
 };

 struct Composition final : public Wrapper<HWC2::Composition> {
   enum : ValueType {
     Invalid = HWC2_COMPOSITION_INVALID,
     Client = HWC2_COMPOSITION_CLIENT,
     Device = HWC2_COMPOSITION_DEVICE,
     SolidColor = HWC2_COMPOSITION_SOLID_COLOR,
     Cursor = HWC2_COMPOSITION_CURSOR,
     Sideband = HWC2_COMPOSITION_SIDEBAND,
   };

   Composition() : Base(Invalid) {}
   using Base::Base;
 };

 struct DisplayType final : public Wrapper<HWC2::DisplayType> {
   enum : ValueType {
     Invalid = HWC2_DISPLAY_TYPE_INVALID,
     Physical = HWC2_DISPLAY_TYPE_PHYSICAL,
     Virtual = HWC2_DISPLAY_TYPE_VIRTUAL,
   };

   DisplayType() : Base(Invalid) {}
   using Base::Base;
 };

 struct Error final : public Wrapper<HWC2::Error> {
   enum : ValueType {
     None = HWC2_ERROR_NONE,
     BadConfig = HWC2_ERROR_BAD_CONFIG,
     BadDisplay = HWC2_ERROR_BAD_DISPLAY,
     BadLayer = HWC2_ERROR_BAD_LAYER,
     BadParameter = HWC2_ERROR_BAD_PARAMETER,
     HasChanges = HWC2_ERROR_HAS_CHANGES,
     NoResources = HWC2_ERROR_NO_RESOURCES,
     NotValidated = HWC2_ERROR_NOT_VALIDATED,
     Unsupported = HWC2_ERROR_UNSUPPORTED,
   };

   Error() : Base(None) {}
   using Base::Base;
 };

 struct LayerRequest final : public Wrapper<HWC2::LayerRequest> {
   enum : ValueType {
     ClearClientTarget = HWC2_LAYER_REQUEST_CLEAR_CLIENT_TARGET,
   };

   LayerRequest() : Base(0) {}
   using Base::Base;
 };

 struct PowerMode final : public Wrapper<HWC2::PowerMode> {
   enum : ValueType {
     Off = HWC2_POWER_MODE_OFF,
     DozeSuspend = HWC2_POWER_MODE_DOZE_SUSPEND,
     Doze = HWC2_POWER_MODE_DOZE,
     On = HWC2_POWER_MODE_ON,
   };

   PowerMode() : Base(Off) {}
   using Base::Base;
 };

 struct Transform final : public Wrapper<HWC2::Transform> {
   enum : ValueType {
     None = 0,
     FlipH = HWC_TRANSFORM_FLIP_H,
     FlipV = HWC_TRANSFORM_FLIP_V,
     Rotate90 = HWC_TRANSFORM_ROT_90,
     Rotate180 = HWC_TRANSFORM_ROT_180,
     Rotate270 = HWC_TRANSFORM_ROT_270,
     FlipHRotate90 = HWC_TRANSFORM_FLIP_H_ROT_90,
     FlipVRotate90 = HWC_TRANSFORM_FLIP_V_ROT_90,
   };

   Transform() : Base(None) {}
   using Base::Base;
 };

 struct Vsync final : public Wrapper<HWC2::Vsync> {
   enum : ValueType {
     Invalid = HWC2_VSYNC_INVALID,
     Enable = HWC2_VSYNC_ENABLE,
     Disable = HWC2_VSYNC_DISABLE,
   };

   Vsync() : Base(Invalid) {}
   using Base::Base;
 };

 // Utility color type.
 struct Color final {
   Color(const Color&) = default;
   Color(uint8_t r, uint8_t g, uint8_t b, uint8_t a) : r(r), g(g), b(b), a(a) {}
   Color(hwc_color_t color) : r(color.r), g(color.g), b(color.b), a(color.a) {}

   operator hwc_color_t() const { return {r, g, b, a}; }

   uint8_t r __attribute__((aligned(1)));
   uint8_t g __attribute__((aligned(1)));
   uint8_t b __attribute__((aligned(1)));
   uint8_t a __attribute__((aligned(1)));
 };

 // Utility rectangle type.
 struct Rect final {
   // TODO(eieio): Implicit conversion to/from Android rect types.

   int32_t left __attribute__((aligned(4)));
   int32_t top __attribute__((aligned(4)));
   int32_t right __attribute__((aligned(4)));
   int32_t bottom __attribute__((aligned(4)));
 };

 }  // namespace HWC

 #endif  // ANDROID_LIBVRFLINGER_HWCTYPES_H
	#ifndef ANDROID_LIBVRFLINGER_HWCTYPES_H
	#define ANDROID_LIBVRFLINGER_HWCTYPES_H

	// General HWC type support. Hardware composer type support is a bit of a mess
	// between HWC1, HWC2 C/C++11, and HIDL types. Particularly bothersome is the
	// use of enum classes, which make analogous types between versions much
	// harder to deal with in a uniform way.
	//
	// These utilities help address some of these pains by providing a type-safe,
	// flexible interface to translate between different type spaces.

	#define HWC2_INCLUDE_STRINGIFICATION
	#define HWC2_USE_CPP11
	#include <hardware/hwcomposer2.h>
	#undef HWC2_INCLUDE_STRINGIFICATION
	#undef HWC2_USE_CPP11

	#include <string>
	#include <type_traits>

	namespace HWC {

	// Value types derived from HWC HAL types. Some of these are stand-alone,
	// while others are also wrapped in translator classes below.
	using ColorMode = int32_t; // android_color_mode_t;
	using Config = hwc2_config_t;
	using ColorTransform =
	std::underlying_type<android_color_transform_t>::type; // int32_t;
	using Dataspace = std::underlying_type<android_dataspace_t>::type; // int32_t;
	using DisplayId = hwc2_display_t;
	using DisplayRequest = std::underlying_type<HWC2::DisplayRequest>::type;
	using Hdr = std::underlying_type<android_hdr_t>::type; // int32_t;
	using Layer = hwc2_layer_t;
	using PixelFormat =
	std::underlying_type<android_pixel_format_t>::type; // int32_t;

	// Type traits and casting utilities.

	// SFINAE utility to evaluate type expressions.
	template <typename...>
	using TestTypeExpression = void;

	// Traits type to determine the underlying type of an enum, integer,
	// or wrapper class.
	template <typename T, typename = typename std::is_enum<T>::type,
	typename = typename std::is_integral<T>::type, typename = void>
	struct UnderlyingType {
	using Type = T;
	};
	// Partial specialization that matches enum types. Captures the underlying type
	// of the enum in member type Type.
	template <typename T>
	struct UnderlyingType<T, std::true_type, std::false_type> {
	using Type = typename std::underlying_type<T>::type;
	};
	// Partial specialization that matches integral types. Captures the type of the
	// integer in member type Type.
	template <typename T>
	struct UnderlyingType<T, std::false_type, std::true_type> {
	using Type = T;
	};
	// Partial specialization that matches the wrapper types below. Captures
	// wrapper member type ValueType in member type Type.
	template <typename T>
	struct UnderlyingType<T, std::false_type, std::false_type,
	TestTypeExpression<typename T::ValueType>> {
	using Type = typename T::ValueType;
	};

	// Enable if T is an enum with underlying type U.
	template <typename T, typename U, typename ReturnType = void>
	using EnableIfMatchingEnum = typename std::enable_if<
	std::is_enum<T>::value &&
	std::is_same<U, typename UnderlyingType<T>::Type>::value,
	ReturnType>::type;

	// Enable if T and U are the same size/alignment and have the same underlying
	// type. Handles enum, integral, and wrapper classes below.
	template <typename T, typename U, typename Return = void>
	using EnableIfSafeCast = typename std::enable_if<
	sizeof(T) == sizeof(U) && alignof(T) == alignof(U) &&
	std::is_same<typename UnderlyingType<T>::Type,
	typename UnderlyingType<U>::Type>::value,
	Return>::type;

	// Safely cast between std::vectors of matching enum/integer/wraper types.
	// Normally this is not possible with pendantic compiler type checks. However,
	// given the same size, alignment, and underlying type this is safe due to
	// allocator requirements and array-like element access guarantees.
	template <typename T, typename U>
	EnableIfSafeCast<T, U, std::vector<T>> VectorCast(std::vector<U> in) {
	return reinterpret_cast<std::vector<T>*>(in);
	}

	// Translator classes that wrap specific HWC types to make translating
	// between different types (especially enum class) in code cleaner.

	// Base type for the enum wrappers below. This type provides type definitions
	// and implicit conversion logic common to each wrapper type.
	template <typename EnumType>
	struct Wrapper {
	// Alias type of this instantiantion of Wrapper. Useful for inheriting
	// constructors in subclasses via "using Base::Base;" statements.
	using Base = Wrapper<EnumType>;

	// The enum type wrapped by this instantiation of Wrapper.
	using BaseType = EnumType;

	// The underlying type of the base enum type.
	using ValueType = typename UnderlyingType<BaseType>::Type;

	// A default constructor is not defined here. Subclasses should define one
	// as appropriate to define the correct inital value for the enum type.

	// Default copy constructor.
	Wrapper(const Wrapper&) = default;

	// Implicit conversion from ValueType.
	Wrapper(ValueType value) : value(value) {}

	// Implicit conversion from BaseType.
	Wrapper(BaseType value) : value(static_cast<ValueType>(value)) {}

	// Implicit conversion from an enum type of the same underlying type.
	template <typename T, typename = EnableIfMatchingEnum<T, ValueType>>
	Wrapper(const T& value) : value(static_cast<ValueType>(value)) {}

	// Implicit conversion to BaseType.
	operator BaseType() const { return static_cast<BaseType>(value); }

	// Implicit conversion to ValueType.
	operator ValueType() const { return value; }

	template <typename T, typename = EnableIfMatchingEnum<T, ValueType>>
	T cast() const {
	return static_cast<T>(value);
	}

	// Converts to string using HWC2 stringification of BaseType.
	std::string to_string() const {
	return HWC2::to_string(static_cast<BaseType>(value));
	}

	bool operator!=(const Wrapper& other) const { return value != other.value; }
	bool operator!=(ValueType other_value) const { return value != other_value; }
	bool operator!=(BaseType other_value) const {
	return static_cast<BaseType>(value) != other_value;
	}
	bool operator==(const Wrapper& other) const { return value == other.value; }
	bool operator==(ValueType other_value) const { return value == other_value; }
	bool operator==(BaseType other_value) const {
	return static_cast<BaseType>(value) == other_value;
	}

	ValueType value;
	};

	struct Attribute final : public Wrapper<HWC2::Attribute> {
	enum : ValueType {
	Invalid = HWC2_ATTRIBUTE_INVALID,
	Width = HWC2_ATTRIBUTE_WIDTH,
	Height = HWC2_ATTRIBUTE_HEIGHT,
	VsyncPeriod = HWC2_ATTRIBUTE_VSYNC_PERIOD,
	DpiX = HWC2_ATTRIBUTE_DPI_X,
	DpiY = HWC2_ATTRIBUTE_DPI_Y,
	};

	Attribute() : Base(Invalid) {}
	using Base::Base;
	};

	struct BlendMode final : public Wrapper<HWC2::BlendMode> {
	enum : ValueType {
	Invalid = HWC2_BLEND_MODE_INVALID,
	None = HWC2_BLEND_MODE_NONE,
	Premultiplied = HWC2_BLEND_MODE_PREMULTIPLIED,
	Coverage = HWC2_BLEND_MODE_COVERAGE,
	};

	BlendMode() : Base(Invalid) {}
	using Base::Base;
	};

	struct Composition final : public Wrapper<HWC2::Composition> {
	enum : ValueType {
	Invalid = HWC2_COMPOSITION_INVALID,
	Client = HWC2_COMPOSITION_CLIENT,
	Device = HWC2_COMPOSITION_DEVICE,
	SolidColor = HWC2_COMPOSITION_SOLID_COLOR,
	Cursor = HWC2_COMPOSITION_CURSOR,
	Sideband = HWC2_COMPOSITION_SIDEBAND,
	};

	Composition() : Base(Invalid) {}
	using Base::Base;
	};

	struct DisplayType final : public Wrapper<HWC2::DisplayType> {
	enum : ValueType {
	Invalid = HWC2_DISPLAY_TYPE_INVALID,
	Physical = HWC2_DISPLAY_TYPE_PHYSICAL,
	Virtual = HWC2_DISPLAY_TYPE_VIRTUAL,
	};

	DisplayType() : Base(Invalid) {}
	using Base::Base;
	};

	struct Error final : public Wrapper<HWC2::Error> {
	enum : ValueType {
	None = HWC2_ERROR_NONE,
	BadConfig = HWC2_ERROR_BAD_CONFIG,
	BadDisplay = HWC2_ERROR_BAD_DISPLAY,
	BadLayer = HWC2_ERROR_BAD_LAYER,
	BadParameter = HWC2_ERROR_BAD_PARAMETER,
	HasChanges = HWC2_ERROR_HAS_CHANGES,
	NoResources = HWC2_ERROR_NO_RESOURCES,
	NotValidated = HWC2_ERROR_NOT_VALIDATED,
	Unsupported = HWC2_ERROR_UNSUPPORTED,
	};

	Error() : Base(None) {}
	using Base::Base;
	};

	struct LayerRequest final : public Wrapper<HWC2::LayerRequest> {
	enum : ValueType {
	ClearClientTarget = HWC2_LAYER_REQUEST_CLEAR_CLIENT_TARGET,
	};

	LayerRequest() : Base(0) {}
	using Base::Base;
	};

	struct PowerMode final : public Wrapper<HWC2::PowerMode> {
	enum : ValueType {
	Off = HWC2_POWER_MODE_OFF,
	DozeSuspend = HWC2_POWER_MODE_DOZE_SUSPEND,
	Doze = HWC2_POWER_MODE_DOZE,
	On = HWC2_POWER_MODE_ON,
	};

	PowerMode() : Base(Off) {}
	using Base::Base;
	};

	struct Transform final : public Wrapper<HWC2::Transform> {
	enum : ValueType {
	None = 0,
	FlipH = HWC_TRANSFORM_FLIP_H,
	FlipV = HWC_TRANSFORM_FLIP_V,
	Rotate90 = HWC_TRANSFORM_ROT_90,
	Rotate180 = HWC_TRANSFORM_ROT_180,
	Rotate270 = HWC_TRANSFORM_ROT_270,
	FlipHRotate90 = HWC_TRANSFORM_FLIP_H_ROT_90,
	FlipVRotate90 = HWC_TRANSFORM_FLIP_V_ROT_90,
	};

	Transform() : Base(None) {}
	using Base::Base;
	};

	struct Vsync final : public Wrapper<HWC2::Vsync> {
	enum : ValueType {
	Invalid = HWC2_VSYNC_INVALID,
	Enable = HWC2_VSYNC_ENABLE,
	Disable = HWC2_VSYNC_DISABLE,
	};

	Vsync() : Base(Invalid) {}
	using Base::Base;
	};

	// Utility color type.
	struct Color final {
	Color(const Color&) = default;
	Color(uint8_t r, uint8_t g, uint8_t b, uint8_t a) : r(r), g(g), b(b), a(a) {}
	Color(hwc_color_t color) : r(color.r), g(color.g), b(color.b), a(color.a) {}

	operator hwc_color_t() const { return {r, g, b, a}; }

	uint8_t r __attribute__((aligned(1)));
	uint8_t g __attribute__((aligned(1)));
	uint8_t b __attribute__((aligned(1)));
	uint8_t a __attribute__((aligned(1)));
	};

	// Utility rectangle type.
	struct Rect final {
	// TODO(eieio): Implicit conversion to/from Android rect types.

	int32_t left __attribute__((aligned(4)));
	int32_t top __attribute__((aligned(4)));
	int32_t right __attribute__((aligned(4)));
	int32_t bottom __attribute__((aligned(4)));
	};

	} // namespace HWC

	#endif // ANDROID_LIBVRFLINGER_HWCTYPES_H