include/gpu/GrTypes.h - skia - Git at Google

 /*
  * Copyright 2010 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrTypes_DEFINED
 #define GrTypes_DEFINED

 #include "SkMath.h"
 #include "SkTypes.h"
 #include "GrConfig.h"

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

 /**
  * Defines overloaded bitwise operators to make it easier to use an enum as a
  * bitfield.
  */
 #define GR_MAKE_BITFIELD_OPS(X) \
     inline X operator |(X a, X b) { \
         return (X) (+a | +b); \
     } \
     inline X& operator |=(X& a, X b) { \
         return (a = a | b); \
     } \
     inline X operator &(X a, X b) { \
         return (X) (+a & +b); \
     } \
     inline X& operator &=(X& a, X b) { \
         return (a = a & b); \
     } \
     template <typename T> \
     inline X operator &(T a, X b) { \
         return (X) (+a & +b); \
     } \
     template <typename T> \
     inline X operator &(X a, T b) { \
         return (X) (+a & +b); \
     } \

 #define GR_DECL_BITFIELD_OPS_FRIENDS(X) \
     friend X operator |(X a, X b); \
     friend X& operator |=(X& a, X b); \
     \
     friend X operator &(X a, X b); \
     friend X& operator &=(X& a, X b); \
     \
     template <typename T> \
     friend X operator &(T a, X b); \
     \
     template <typename T> \
     friend X operator &(X a, T b); \

 /**
  * Wraps a C++11 enum that we use as a bitfield, and enables a limited amount of
  * masking with type safety. Instantiated with the ~ operator.
  */
 template<typename TFlags> class GrTFlagsMask {
 public:
     constexpr explicit GrTFlagsMask(TFlags value) : GrTFlagsMask(static_cast<int>(value)) {}
     constexpr explicit GrTFlagsMask(int value) : fValue(value) {}
     constexpr int value() const { return fValue; }
 private:
     const int fValue;
 };

 // Or-ing a mask always returns another mask.
 template<typename TFlags> constexpr GrTFlagsMask<TFlags> operator|(GrTFlagsMask<TFlags> a,
                                                                    GrTFlagsMask<TFlags> b) {
     return GrTFlagsMask<TFlags>(a.value() | b.value());
 }
 template<typename TFlags> constexpr GrTFlagsMask<TFlags> operator|(GrTFlagsMask<TFlags> a,
                                                                    TFlags b) {
     return GrTFlagsMask<TFlags>(a.value() | static_cast<int>(b));
 }
 template<typename TFlags> constexpr GrTFlagsMask<TFlags> operator|(TFlags a,
                                                                    GrTFlagsMask<TFlags> b) {
     return GrTFlagsMask<TFlags>(static_cast<int>(a) | b.value());
 }
 template<typename TFlags> inline GrTFlagsMask<TFlags>& operator|=(GrTFlagsMask<TFlags>& a,
                                                                   GrTFlagsMask<TFlags> b) {
     return (a = a | b);
 }

 // And-ing two masks returns another mask; and-ing one with regular flags returns flags.
 template<typename TFlags> constexpr GrTFlagsMask<TFlags> operator&(GrTFlagsMask<TFlags> a,
                                                                    GrTFlagsMask<TFlags> b) {
     return GrTFlagsMask<TFlags>(a.value() & b.value());
 }
 template<typename TFlags> constexpr TFlags operator&(GrTFlagsMask<TFlags> a, TFlags b) {
     return static_cast<TFlags>(a.value() & static_cast<int>(b));
 }
 template<typename TFlags> constexpr TFlags operator&(TFlags a, GrTFlagsMask<TFlags> b) {
     return static_cast<TFlags>(static_cast<int>(a) & b.value());
 }
 template<typename TFlags> inline TFlags& operator&=(TFlags& a, GrTFlagsMask<TFlags> b) {
     return (a = a & b);
 }

 /**
  * Defines bitwise operators that make it possible to use an enum class as a
  * basic bitfield.
  */
 #define GR_MAKE_BITFIELD_CLASS_OPS(X) \
     constexpr GrTFlagsMask<X> operator~(X a) { \
         return GrTFlagsMask<X>(~static_cast<int>(a)); \
     } \
     constexpr X operator|(X a, X b) { \
         return static_cast<X>(static_cast<int>(a) | static_cast<int>(b)); \
     } \
     inline X& operator|=(X& a, X b) { \
         return (a = a | b); \
     } \
     constexpr bool operator&(X a, X b) { \
         return SkToBool(static_cast<int>(a) & static_cast<int>(b)); \
     } \

 #define GR_DECL_BITFIELD_CLASS_OPS_FRIENDS(X) \
     friend constexpr GrTFlagsMask<X> operator ~(X); \
     friend constexpr X operator |(X, X); \
     friend X& operator |=(X&, X); \
     friend constexpr bool operator &(X, X)

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

 // compile time versions of min/max
 #define GR_CT_MAX(a, b) (((b) < (a)) ? (a) : (b))
 #define GR_CT_MIN(a, b) (((b) < (a)) ? (b) : (a))

 /**
  *  divide, rounding up
  */
 static inline int32_t GrIDivRoundUp(int x, int y) {
     SkASSERT(y > 0);
     return (x + (y-1)) / y;
 }
 static inline uint32_t GrUIDivRoundUp(uint32_t x, uint32_t y) {
     return (x + (y-1)) / y;
 }
 static inline size_t GrSizeDivRoundUp(size_t x, size_t y) {
     return (x + (y-1)) / y;
 }

 // compile time, evaluates Y multiple times
 #define GR_CT_DIV_ROUND_UP(X, Y) (((X) + ((Y)-1)) / (Y))

 /**
  *  align up
  */
 static inline uint32_t GrUIAlignUp(uint32_t x, uint32_t alignment) {
     return GrUIDivRoundUp(x, alignment) * alignment;
 }
 static inline size_t GrSizeAlignUp(size_t x, size_t alignment) {
     return GrSizeDivRoundUp(x, alignment) * alignment;
 }

 // compile time, evaluates A multiple times
 #define GR_CT_ALIGN_UP(X, A) (GR_CT_DIV_ROUND_UP((X),(A)) * (A))

 /**
  * amount of pad needed to align up
  */
 static inline uint32_t GrUIAlignUpPad(uint32_t x, uint32_t alignment) {
     return (alignment - x % alignment) % alignment;
 }
 static inline size_t GrSizeAlignUpPad(size_t x, size_t alignment) {
     return (alignment - x % alignment) % alignment;
 }

 /**
  *  align down
  */
 static inline uint32_t GrUIAlignDown(uint32_t x, uint32_t alignment) {
     return (x / alignment) * alignment;
 }
 static inline size_t GrSizeAlignDown(size_t x, uint32_t alignment) {
     return (x / alignment) * alignment;
 }

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

 /**
  * Possible 3D APIs that may be used by Ganesh.
  */
 enum class GrBackendApi : unsigned {
     kMetal,
     kOpenGL,
     kVulkan,
     /**
      * Mock is a backend that does not draw anything. It is used for unit tests
      * and to measure CPU overhead.
      */
     kMock,

     /**
      * Added here to support the legacy GrBackend enum value and clients who referenced it using
      * GrBackend::kOpenGL_GrBackend.
      */
     kOpenGL_GrBackend = kOpenGL,
 };

 /**
  * Previously the above enum was not an enum class but a normal enum. To support the legacy use of
  * the enum values we define them below so that no clients break.
  */
 typedef GrBackendApi GrBackend;

 static constexpr GrBackendApi kMetal_GrBackend = GrBackendApi::kMetal;
 static constexpr GrBackendApi kVulkan_GrBackend = GrBackendApi::kVulkan;
 static constexpr GrBackendApi kMock_GrBackend = GrBackendApi::kMock;

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

 /**
  * Used to say whether a texture has mip levels allocated or not.
  */
 enum class GrMipMapped : bool {
     kNo = false,
     kYes = true
 };

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

 /**
  * GPU SkImage and SkSurfaces can be stored such that (0, 0) in texture space may correspond to
  * either the top-left or bottom-left content pixel.
  */
 enum GrSurfaceOrigin : int {
     kTopLeft_GrSurfaceOrigin,
     kBottomLeft_GrSurfaceOrigin,
 };

 /**
  * A GrContext's cache of backend context state can be partially invalidated.
  * These enums are specific to the GL backend and we'd add a new set for an alternative backend.
  */
 enum GrGLBackendState {
     kRenderTarget_GrGLBackendState     = 1 << 0,
     // Also includes samplers bound to texture units.
     kTextureBinding_GrGLBackendState   = 1 << 1,
     // View state stands for scissor and viewport
     kView_GrGLBackendState             = 1 << 2,
     kBlend_GrGLBackendState            = 1 << 3,
     kMSAAEnable_GrGLBackendState       = 1 << 4,
     kVertex_GrGLBackendState           = 1 << 5,
     kStencil_GrGLBackendState          = 1 << 6,
     kPixelStore_GrGLBackendState       = 1 << 7,
     kProgram_GrGLBackendState          = 1 << 8,
     kFixedFunction_GrGLBackendState    = 1 << 9,
     kMisc_GrGLBackendState             = 1 << 10,
     kPathRendering_GrGLBackendState    = 1 << 11,
     kALL_GrGLBackendState              = 0xffff
 };

 /**
  * This value translates to reseting all the context state for any backend.
  */
 static const uint32_t kAll_GrBackendState = 0xffffffff;

 enum GrFlushFlags {
     kNone_GrFlushFlags = 0,
     // flush will wait till all submitted GPU work is finished before returning.
     kSyncCpu_GrFlushFlag = 0x1,
 };

 typedef void* GrGpuFinishedContext;
 typedef void (*GrGpuFinishedProc)(GrGpuFinishedContext finishedContext);

 /**
  * Enum used as return value when flush with semaphores so the client knows whether the semaphores
  * were submitted to GPU or not.
  */
 enum class GrSemaphoresSubmitted : bool {
     kNo = false,
     kYes = true
 };

 #endif
	/*
	* Copyright 2010 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrTypes_DEFINED
	#define GrTypes_DEFINED

	#include "SkMath.h"
	#include "SkTypes.h"
	#include "GrConfig.h"

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

	/**
	* Defines overloaded bitwise operators to make it easier to use an enum as a
	* bitfield.
	*/
	#define GR_MAKE_BITFIELD_OPS(X) \
	inline X operator \|(X a, X b) { \
	return (X) (+a \| +b); \
	} \
	inline X& operator \|=(X& a, X b) { \
	return (a = a \| b); \
	} \
	inline X operator &(X a, X b) { \
	return (X) (+a & +b); \
	} \
	inline X& operator &=(X& a, X b) { \
	return (a = a & b); \
	} \
	template <typename T> \
	inline X operator &(T a, X b) { \
	return (X) (+a & +b); \
	} \
	template <typename T> \
	inline X operator &(X a, T b) { \
	return (X) (+a & +b); \
	} \

	#define GR_DECL_BITFIELD_OPS_FRIENDS(X) \
	friend X operator \|(X a, X b); \
	friend X& operator \|=(X& a, X b); \
	\
	friend X operator &(X a, X b); \
	friend X& operator &=(X& a, X b); \
	\
	template <typename T> \
	friend X operator &(T a, X b); \
	\
	template <typename T> \
	friend X operator &(X a, T b); \

	/**
	* Wraps a C++11 enum that we use as a bitfield, and enables a limited amount of
	* masking with type safety. Instantiated with the ~ operator.
	*/
	template<typename TFlags> class GrTFlagsMask {
	public:
	constexpr explicit GrTFlagsMask(TFlags value) : GrTFlagsMask(static_cast<int>(value)) {}
	constexpr explicit GrTFlagsMask(int value) : fValue(value) {}
	constexpr int value() const { return fValue; }
	private:
	const int fValue;
	};

	// Or-ing a mask always returns another mask.
	template<typename TFlags> constexpr GrTFlagsMask<TFlags> operator\|(GrTFlagsMask<TFlags> a,
	GrTFlagsMask<TFlags> b) {
	return GrTFlagsMask<TFlags>(a.value() \| b.value());
	}
	template<typename TFlags> constexpr GrTFlagsMask<TFlags> operator\|(GrTFlagsMask<TFlags> a,
	TFlags b) {
	return GrTFlagsMask<TFlags>(a.value() \| static_cast<int>(b));
	}
	template<typename TFlags> constexpr GrTFlagsMask<TFlags> operator\|(TFlags a,
	GrTFlagsMask<TFlags> b) {
	return GrTFlagsMask<TFlags>(static_cast<int>(a) \| b.value());
	}
	template<typename TFlags> inline GrTFlagsMask<TFlags>& operator\|=(GrTFlagsMask<TFlags>& a,
	GrTFlagsMask<TFlags> b) {
	return (a = a \| b);
	}

	// And-ing two masks returns another mask; and-ing one with regular flags returns flags.
	template<typename TFlags> constexpr GrTFlagsMask<TFlags> operator&(GrTFlagsMask<TFlags> a,
	GrTFlagsMask<TFlags> b) {
	return GrTFlagsMask<TFlags>(a.value() & b.value());
	}
	template<typename TFlags> constexpr TFlags operator&(GrTFlagsMask<TFlags> a, TFlags b) {
	return static_cast<TFlags>(a.value() & static_cast<int>(b));
	}
	template<typename TFlags> constexpr TFlags operator&(TFlags a, GrTFlagsMask<TFlags> b) {
	return static_cast<TFlags>(static_cast<int>(a) & b.value());
	}
	template<typename TFlags> inline TFlags& operator&=(TFlags& a, GrTFlagsMask<TFlags> b) {
	return (a = a & b);
	}

	/**
	* Defines bitwise operators that make it possible to use an enum class as a
	* basic bitfield.
	*/
	#define GR_MAKE_BITFIELD_CLASS_OPS(X) \
	constexpr GrTFlagsMask<X> operator~(X a) { \
	return GrTFlagsMask<X>(~static_cast<int>(a)); \
	} \
	constexpr X operator\|(X a, X b) { \
	return static_cast<X>(static_cast<int>(a) \| static_cast<int>(b)); \
	} \
	inline X& operator\|=(X& a, X b) { \
	return (a = a \| b); \
	} \
	constexpr bool operator&(X a, X b) { \
	return SkToBool(static_cast<int>(a) & static_cast<int>(b)); \
	} \

	#define GR_DECL_BITFIELD_CLASS_OPS_FRIENDS(X) \
	friend constexpr GrTFlagsMask<X> operator ~(X); \
	friend constexpr X operator \|(X, X); \
	friend X& operator \|=(X&, X); \
	friend constexpr bool operator &(X, X)

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

	// compile time versions of min/max
	#define GR_CT_MAX(a, b) (((b) < (a)) ? (a) : (b))
	#define GR_CT_MIN(a, b) (((b) < (a)) ? (b) : (a))

	/**
	* divide, rounding up
	*/
	static inline int32_t GrIDivRoundUp(int x, int y) {
	SkASSERT(y > 0);
	return (x + (y-1)) / y;
	}
	static inline uint32_t GrUIDivRoundUp(uint32_t x, uint32_t y) {
	return (x + (y-1)) / y;
	}
	static inline size_t GrSizeDivRoundUp(size_t x, size_t y) {
	return (x + (y-1)) / y;
	}

	// compile time, evaluates Y multiple times
	#define GR_CT_DIV_ROUND_UP(X, Y) (((X) + ((Y)-1)) / (Y))

	/**
	* align up
	*/
	static inline uint32_t GrUIAlignUp(uint32_t x, uint32_t alignment) {
	return GrUIDivRoundUp(x, alignment) * alignment;
	}
	static inline size_t GrSizeAlignUp(size_t x, size_t alignment) {
	return GrSizeDivRoundUp(x, alignment) * alignment;
	}

	// compile time, evaluates A multiple times
	#define GR_CT_ALIGN_UP(X, A) (GR_CT_DIV_ROUND_UP((X),(A)) * (A))

	/**
	* amount of pad needed to align up
	*/
	static inline uint32_t GrUIAlignUpPad(uint32_t x, uint32_t alignment) {
	return (alignment - x % alignment) % alignment;
	}
	static inline size_t GrSizeAlignUpPad(size_t x, size_t alignment) {
	return (alignment - x % alignment) % alignment;
	}

	/**
	* align down
	*/
	static inline uint32_t GrUIAlignDown(uint32_t x, uint32_t alignment) {
	return (x / alignment) * alignment;
	}
	static inline size_t GrSizeAlignDown(size_t x, uint32_t alignment) {
	return (x / alignment) * alignment;
	}

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

	/**
	* Possible 3D APIs that may be used by Ganesh.
	*/
	enum class GrBackendApi : unsigned {
	kMetal,
	kOpenGL,
	kVulkan,
	/**
	* Mock is a backend that does not draw anything. It is used for unit tests
	* and to measure CPU overhead.
	*/
	kMock,

	/**
	* Added here to support the legacy GrBackend enum value and clients who referenced it using
	* GrBackend::kOpenGL_GrBackend.
	*/
	kOpenGL_GrBackend = kOpenGL,
	};

	/**
	* Previously the above enum was not an enum class but a normal enum. To support the legacy use of
	* the enum values we define them below so that no clients break.
	*/
	typedef GrBackendApi GrBackend;

	static constexpr GrBackendApi kMetal_GrBackend = GrBackendApi::kMetal;
	static constexpr GrBackendApi kVulkan_GrBackend = GrBackendApi::kVulkan;
	static constexpr GrBackendApi kMock_GrBackend = GrBackendApi::kMock;

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

	/**
	* Used to say whether a texture has mip levels allocated or not.
	*/
	enum class GrMipMapped : bool {
	kNo = false,
	kYes = true
	};

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

	/**
	* GPU SkImage and SkSurfaces can be stored such that (0, 0) in texture space may correspond to
	* either the top-left or bottom-left content pixel.
	*/
	enum GrSurfaceOrigin : int {
	kTopLeft_GrSurfaceOrigin,
	kBottomLeft_GrSurfaceOrigin,
	};

	/**
	* A GrContext's cache of backend context state can be partially invalidated.
	* These enums are specific to the GL backend and we'd add a new set for an alternative backend.
	*/
	enum GrGLBackendState {
	kRenderTarget_GrGLBackendState = 1 << 0,
	// Also includes samplers bound to texture units.
	kTextureBinding_GrGLBackendState = 1 << 1,
	// View state stands for scissor and viewport
	kView_GrGLBackendState = 1 << 2,
	kBlend_GrGLBackendState = 1 << 3,
	kMSAAEnable_GrGLBackendState = 1 << 4,
	kVertex_GrGLBackendState = 1 << 5,
	kStencil_GrGLBackendState = 1 << 6,
	kPixelStore_GrGLBackendState = 1 << 7,
	kProgram_GrGLBackendState = 1 << 8,
	kFixedFunction_GrGLBackendState = 1 << 9,
	kMisc_GrGLBackendState = 1 << 10,
	kPathRendering_GrGLBackendState = 1 << 11,
	kALL_GrGLBackendState = 0xffff
	};

	/**
	* This value translates to reseting all the context state for any backend.
	*/
	static const uint32_t kAll_GrBackendState = 0xffffffff;

	enum GrFlushFlags {
	kNone_GrFlushFlags = 0,
	// flush will wait till all submitted GPU work is finished before returning.
	kSyncCpu_GrFlushFlag = 0x1,
	};

	typedef void* GrGpuFinishedContext;
	typedef void (*GrGpuFinishedProc)(GrGpuFinishedContext finishedContext);

	/**
	* Enum used as return value when flush with semaphores so the client knows whether the semaphores
	* were submitted to GPU or not.
	*/
	enum class GrSemaphoresSubmitted : bool {
	kNo = false,
	kYes = true
	};

	#endif