src/gpu/gl/GrGLProgramDesc.h - skia - Git at Google

 /*
  * Copyright 2013 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrGLProgramDesc_DEFINED
 #define GrGLProgramDesc_DEFINED

 #include "GrGLEffect.h"
 #include "GrDrawState.h"
 #include "GrGLShaderBuilder.h"
 #include "GrGpu.h"

 class GrGpuGL;

 #ifdef SK_DEBUG
   // Optionally compile the experimental GS code. Set to SK_DEBUG so that debug build bots will
   // execute the code.
   #define GR_GL_EXPERIMENTAL_GS 1
 #else
   #define GR_GL_EXPERIMENTAL_GS 0
 #endif


 /** This class describes a program to generate. It also serves as a program cache key. Very little
     of this is GL-specific. There is the generation of GrGLEffect::EffectKeys and the dst-read part
     of the key set by GrGLShaderBuilder. If the interfaces that set those portions were abstracted
     to be API-neutral then so could this class. */
 class GrGLProgramDesc {
 public:
     GrGLProgramDesc() : fInitialized(false) {}
     GrGLProgramDesc(const GrGLProgramDesc& desc) { *this = desc; }

     // Returns this as a uint32_t array to be used as a key in the program cache.
     const uint32_t* asKey() const {
         SkASSERT(fInitialized);
         return reinterpret_cast<const uint32_t*>(fKey.get());
     }

     // Gets the number of bytes in asKey(). It will be a 4-byte aligned value. When comparing two
     // keys the size of either key can be used with memcmp() since the lengths themselves begin the
     // keys and thus the memcmp will exit early if the keys are of different lengths.
     uint32_t keyLength() const { return *this->atOffset<uint32_t, kLengthOffset>(); }

     // Gets the a checksum of the key. Can be used as a hash value for a fast lookup in a cache.
     uint32_t getChecksum() const { return *this->atOffset<uint32_t, kChecksumOffset>(); }

     // For unit testing.
     void setRandom(SkRandom*,
                    const GrGpuGL* gpu,
                    const GrRenderTarget* dummyDstRenderTarget,
                    const GrTexture* dummyDstCopyTexture,
                    const GrEffectStage* stages[],
                    int numColorStages,
                    int numCoverageStages,
                    int currAttribIndex);

     /**
      * Builds a program descriptor from a GrDrawState. Whether the primitive type is points, the
      * output of GrDrawState::getBlendOpts, and the caps of the GrGpuGL are also inputs. It also
      * outputs the color and coverage stages referenced by the generated descriptor. This may
      * not contain all stages from the draw state and coverage stages from the drawState may
      * be treated as color stages in the output.
      */
     static void Build(const GrDrawState&,
                       GrGpu::DrawType drawType,
                       GrDrawState::BlendOptFlags,
                       GrBlendCoeff srcCoeff,
                       GrBlendCoeff dstCoeff,
                       const GrGpuGL* gpu,
                       const GrDeviceCoordTexture* dstCopy,
                       SkTArray<const GrEffectStage*, true>* outColorStages,
                       SkTArray<const GrEffectStage*, true>* outCoverageStages,
                       GrGLProgramDesc* outDesc);

     int numColorEffects() const {
         SkASSERT(fInitialized);
         return this->getHeader().fColorEffectCnt;
     }

     int numCoverageEffects() const {
         SkASSERT(fInitialized);
         return this->getHeader().fCoverageEffectCnt;
     }

     int numTotalEffects() const { return this->numColorEffects() + this->numCoverageEffects(); }

     GrGLProgramDesc& operator= (const GrGLProgramDesc& other);

     bool operator== (const GrGLProgramDesc& other) const {
         SkASSERT(fInitialized && other.fInitialized);
         // The length is masked as a hint to the compiler that the address will be 4 byte aligned.
         return 0 == memcmp(this->asKey(), other.asKey(), this->keyLength() & ~0x3);
     }

     bool operator!= (const GrGLProgramDesc& other) const {
         return !(*this == other);
     }

     static bool Less(const GrGLProgramDesc& a, const GrGLProgramDesc& b) {
         return memcmp(a.asKey(), b.asKey(), a.keyLength() & ~0x3) < 0;
     }

 private:
     // Specifies where the initial color comes from before the stages are applied.
     enum ColorInput {
         kSolidWhite_ColorInput,
         kTransBlack_ColorInput,
         kAttribute_ColorInput,
         kUniform_ColorInput,

         kColorInputCnt
     };

     enum CoverageOutput {
         // modulate color and coverage, write result as the color output.
         kModulate_CoverageOutput,
         // Writes color*coverage as the primary color output and also writes coverage as the
         // secondary output. Only set if dual source blending is supported.
         kSecondaryCoverage_CoverageOutput,
         // Writes color*coverage as the primary color output and also writes coverage * (1 - colorA)
         // as the secondary output. Only set if dual source blending is supported.
         kSecondaryCoverageISA_CoverageOutput,
         // Writes color*coverage as the primary color output and also writes coverage *
         // (1 - colorRGB) as the secondary output. Only set if dual source blending is supported.
         kSecondaryCoverageISC_CoverageOutput,
         // Combines the coverage, dst, and color as coverage * color + (1 - coverage) * dst. This
         // can only be set if fDstReadKey is non-zero.
         kCombineWithDst_CoverageOutput,

         kCoverageOutputCnt
     };

     static bool CoverageOutputUsesSecondaryOutput(CoverageOutput co) {
         switch (co) {
             case kSecondaryCoverage_CoverageOutput: //  fallthru
             case kSecondaryCoverageISA_CoverageOutput:
             case kSecondaryCoverageISC_CoverageOutput:
                 return true;
             default:
                 return false;
         }
     }

     struct KeyHeader {
         GrGLShaderBuilder::DstReadKey fDstReadKey;      // set by GrGLShaderBuilder if there
                                                         // are effects that must read the dst.
                                                         // Otherwise, 0.
         GrGLShaderBuilder::FragPosKey fFragPosKey;      // set by GrGLShaderBuilder if there are
                                                         // effects that read the fragment position.
                                                         // Otherwise, 0.

         ColorInput                  fColorInput : 8;
         ColorInput                  fCoverageInput : 8;
         CoverageOutput              fCoverageOutput : 8;

         SkBool8                     fHasVertexCode;
         SkBool8                     fEmitsPointSize;

         // To enable experimental geometry shader code (not for use in
         // production)
 #if GR_GL_EXPERIMENTAL_GS
         SkBool8                     fExperimentalGS;
 #endif

         int8_t                      fPositionAttributeIndex;
         int8_t                      fLocalCoordAttributeIndex;
         int8_t                      fColorAttributeIndex;
         int8_t                      fCoverageAttributeIndex;

         int8_t                      fColorEffectCnt;
         int8_t                      fCoverageEffectCnt;
     };

     // The key is 1 uint32_t for the length, followed another for the checksum, the header, and then
     // the effect keys. Everything is fixed length except the effect key array.
     enum {
         kLengthOffset = 0,
         kChecksumOffset = kLengthOffset + sizeof(uint32_t),
         kHeaderOffset = kChecksumOffset + sizeof(uint32_t),
         kHeaderSize = SkAlign4(sizeof(KeyHeader)),
         kEffectKeyOffset = kHeaderOffset + kHeaderSize,
     };

     template<typename T, size_t OFFSET> T* atOffset() {
         return reinterpret_cast<T*>(reinterpret_cast<intptr_t>(fKey.get()) + OFFSET);
     }

     template<typename T, size_t OFFSET> const T* atOffset() const {
         return reinterpret_cast<const T*>(reinterpret_cast<intptr_t>(fKey.get()) + OFFSET);
     }

     typedef GrGLEffect::EffectKey EffectKey;

     uint32_t* checksum() { return this->atOffset<uint32_t, kChecksumOffset>(); }
     KeyHeader* header() { return this->atOffset<KeyHeader, kHeaderOffset>(); }
     EffectKey* effectKeys() { return this->atOffset<EffectKey, kEffectKeyOffset>(); }

     const KeyHeader& getHeader() const { return *this->atOffset<KeyHeader, kHeaderOffset>(); }
     const EffectKey* getEffectKeys() const { return this->atOffset<EffectKey, kEffectKeyOffset>(); }

     static size_t KeyLength(int effectCnt) {
         GR_STATIC_ASSERT(!(sizeof(EffectKey) & 0x3));
         return kEffectKeyOffset + effectCnt * sizeof(EffectKey);
     }

     enum {
         kMaxPreallocEffects = 16,
         kPreAllocSize = kEffectKeyOffset +  kMaxPreallocEffects * sizeof(EffectKey),
     };

     SkAutoSMalloc<kPreAllocSize> fKey;
     bool fInitialized;

     // GrGLProgram and GrGLShaderBuilder read the private fields to generate code. TODO: Move all
     // code generation to GrGLShaderBuilder (and maybe add getters rather than friending).
     friend class GrGLProgram;
     friend class GrGLShaderBuilder;
     friend class GrGLFullShaderBuilder;
     friend class GrGLFragmentOnlyShaderBuilder;
 };

 #endif
	/*
	* Copyright 2013 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrGLProgramDesc_DEFINED
	#define GrGLProgramDesc_DEFINED

	#include "GrGLEffect.h"
	#include "GrDrawState.h"
	#include "GrGLShaderBuilder.h"
	#include "GrGpu.h"

	class GrGpuGL;

	#ifdef SK_DEBUG
	// Optionally compile the experimental GS code. Set to SK_DEBUG so that debug build bots will
	// execute the code.
	#define GR_GL_EXPERIMENTAL_GS 1
	#else
	#define GR_GL_EXPERIMENTAL_GS 0
	#endif


	/** This class describes a program to generate. It also serves as a program cache key. Very little
	of this is GL-specific. There is the generation of GrGLEffect::EffectKeys and the dst-read part
	of the key set by GrGLShaderBuilder. If the interfaces that set those portions were abstracted
	to be API-neutral then so could this class. */
	class GrGLProgramDesc {
	public:
	GrGLProgramDesc() : fInitialized(false) {}
	GrGLProgramDesc(const GrGLProgramDesc& desc) { *this = desc; }

	// Returns this as a uint32_t array to be used as a key in the program cache.
	const uint32_t* asKey() const {
	SkASSERT(fInitialized);
	return reinterpret_cast<const uint32_t*>(fKey.get());
	}

	// Gets the number of bytes in asKey(). It will be a 4-byte aligned value. When comparing two
	// keys the size of either key can be used with memcmp() since the lengths themselves begin the
	// keys and thus the memcmp will exit early if the keys are of different lengths.
	uint32_t keyLength() const { return *this->atOffset<uint32_t, kLengthOffset>(); }

	// Gets the a checksum of the key. Can be used as a hash value for a fast lookup in a cache.
	uint32_t getChecksum() const { return *this->atOffset<uint32_t, kChecksumOffset>(); }

	// For unit testing.
	void setRandom(SkRandom*,
	const GrGpuGL* gpu,
	const GrRenderTarget* dummyDstRenderTarget,
	const GrTexture* dummyDstCopyTexture,
	const GrEffectStage* stages[],
	int numColorStages,
	int numCoverageStages,
	int currAttribIndex);

	/**
	* Builds a program descriptor from a GrDrawState. Whether the primitive type is points, the
	* output of GrDrawState::getBlendOpts, and the caps of the GrGpuGL are also inputs. It also
	* outputs the color and coverage stages referenced by the generated descriptor. This may
	* not contain all stages from the draw state and coverage stages from the drawState may
	* be treated as color stages in the output.
	*/
	static void Build(const GrDrawState&,
	GrGpu::DrawType drawType,
	GrDrawState::BlendOptFlags,
	GrBlendCoeff srcCoeff,
	GrBlendCoeff dstCoeff,
	const GrGpuGL* gpu,
	const GrDeviceCoordTexture* dstCopy,
	SkTArray<const GrEffectStage, true> outColorStages,
	SkTArray<const GrEffectStage, true> outCoverageStages,
	GrGLProgramDesc* outDesc);

	int numColorEffects() const {
	SkASSERT(fInitialized);
	return this->getHeader().fColorEffectCnt;
	}

	int numCoverageEffects() const {
	SkASSERT(fInitialized);
	return this->getHeader().fCoverageEffectCnt;
	}

	int numTotalEffects() const { return this->numColorEffects() + this->numCoverageEffects(); }

	GrGLProgramDesc& operator= (const GrGLProgramDesc& other);

	bool operator== (const GrGLProgramDesc& other) const {
	SkASSERT(fInitialized && other.fInitialized);
	// The length is masked as a hint to the compiler that the address will be 4 byte aligned.
	return 0 == memcmp(this->asKey(), other.asKey(), this->keyLength() & ~0x3);
	}

	bool operator!= (const GrGLProgramDesc& other) const {
	return !(*this == other);
	}

	static bool Less(const GrGLProgramDesc& a, const GrGLProgramDesc& b) {
	return memcmp(a.asKey(), b.asKey(), a.keyLength() & ~0x3) < 0;
	}

	private:
	// Specifies where the initial color comes from before the stages are applied.
	enum ColorInput {
	kSolidWhite_ColorInput,
	kTransBlack_ColorInput,
	kAttribute_ColorInput,
	kUniform_ColorInput,

	kColorInputCnt
	};

	enum CoverageOutput {
	// modulate color and coverage, write result as the color output.
	kModulate_CoverageOutput,
	// Writes color*coverage as the primary color output and also writes coverage as the
	// secondary output. Only set if dual source blending is supported.
	kSecondaryCoverage_CoverageOutput,
	// Writes colorcoverage as the primary color output and also writes coverage (1 - colorA)
	// as the secondary output. Only set if dual source blending is supported.
	kSecondaryCoverageISA_CoverageOutput,
	// Writes colorcoverage as the primary color output and also writes coverage
	// (1 - colorRGB) as the secondary output. Only set if dual source blending is supported.
	kSecondaryCoverageISC_CoverageOutput,
	// Combines the coverage, dst, and color as coverage * color + (1 - coverage) * dst. This
	// can only be set if fDstReadKey is non-zero.
	kCombineWithDst_CoverageOutput,

	kCoverageOutputCnt
	};

	static bool CoverageOutputUsesSecondaryOutput(CoverageOutput co) {
	switch (co) {
	case kSecondaryCoverage_CoverageOutput: // fallthru
	case kSecondaryCoverageISA_CoverageOutput:
	case kSecondaryCoverageISC_CoverageOutput:
	return true;
	default:
	return false;
	}
	}

	struct KeyHeader {
	GrGLShaderBuilder::DstReadKey fDstReadKey; // set by GrGLShaderBuilder if there
	// are effects that must read the dst.
	// Otherwise, 0.
	GrGLShaderBuilder::FragPosKey fFragPosKey; // set by GrGLShaderBuilder if there are
	// effects that read the fragment position.
	// Otherwise, 0.

	ColorInput fColorInput : 8;
	ColorInput fCoverageInput : 8;
	CoverageOutput fCoverageOutput : 8;

	SkBool8 fHasVertexCode;
	SkBool8 fEmitsPointSize;

	// To enable experimental geometry shader code (not for use in
	// production)
	#if GR_GL_EXPERIMENTAL_GS
	SkBool8 fExperimentalGS;
	#endif

	int8_t fPositionAttributeIndex;
	int8_t fLocalCoordAttributeIndex;
	int8_t fColorAttributeIndex;
	int8_t fCoverageAttributeIndex;

	int8_t fColorEffectCnt;
	int8_t fCoverageEffectCnt;
	};

	// The key is 1 uint32_t for the length, followed another for the checksum, the header, and then
	// the effect keys. Everything is fixed length except the effect key array.
	enum {
	kLengthOffset = 0,
	kChecksumOffset = kLengthOffset + sizeof(uint32_t),
	kHeaderOffset = kChecksumOffset + sizeof(uint32_t),
	kHeaderSize = SkAlign4(sizeof(KeyHeader)),
	kEffectKeyOffset = kHeaderOffset + kHeaderSize,
	};

	template<typename T, size_t OFFSET> T* atOffset() {
	return reinterpret_cast<T*>(reinterpret_cast<intptr_t>(fKey.get()) + OFFSET);
	}

	template<typename T, size_t OFFSET> const T* atOffset() const {
	return reinterpret_cast<const T*>(reinterpret_cast<intptr_t>(fKey.get()) + OFFSET);
	}

	typedef GrGLEffect::EffectKey EffectKey;

	uint32_t* checksum() { return this->atOffset<uint32_t, kChecksumOffset>(); }
	KeyHeader* header() { return this->atOffset<KeyHeader, kHeaderOffset>(); }
	EffectKey* effectKeys() { return this->atOffset<EffectKey, kEffectKeyOffset>(); }

	const KeyHeader& getHeader() const { return *this->atOffset<KeyHeader, kHeaderOffset>(); }
	const EffectKey* getEffectKeys() const { return this->atOffset<EffectKey, kEffectKeyOffset>(); }

	static size_t KeyLength(int effectCnt) {
	GR_STATIC_ASSERT(!(sizeof(EffectKey) & 0x3));
	return kEffectKeyOffset + effectCnt * sizeof(EffectKey);
	}

	enum {
	kMaxPreallocEffects = 16,
	kPreAllocSize = kEffectKeyOffset + kMaxPreallocEffects * sizeof(EffectKey),
	};

	SkAutoSMalloc<kPreAllocSize> fKey;
	bool fInitialized;

	// GrGLProgram and GrGLShaderBuilder read the private fields to generate code. TODO: Move all
	// code generation to GrGLShaderBuilder (and maybe add getters rather than friending).
	friend class GrGLProgram;
	friend class GrGLShaderBuilder;
	friend class GrGLFullShaderBuilder;
	friend class GrGLFragmentOnlyShaderBuilder;
	};

	#endif