src/gpu/glsl/GrGLSLVarying.h - skia - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrGLSLVarying_DEFINED
 #define GrGLSLVarying_DEFINED

 #include "GrAllocator.h"
 #include "GrGeometryProcessor.h"
 #include "GrShaderVar.h"
 #include "GrTypesPriv.h"
 #include "glsl/GrGLSLProgramDataManager.h"

 class GrGLSLProgramBuilder;

 #ifdef SK_DEBUG
 static bool is_matrix(GrSLType type) {
     switch (type) {
         case kFloat2x2_GrSLType:
         case kFloat3x3_GrSLType:
         case kFloat4x4_GrSLType:
         case kHalf2x2_GrSLType:
         case kHalf3x3_GrSLType:
         case kHalf4x4_GrSLType:
             return true;
         default:
             return false;
     }
 }
 #endif

 class GrGLSLVarying {
 public:
     enum class Scope {
         kVertToFrag,
         kVertToGeo,
         kGeoToFrag
     };

     GrGLSLVarying() = default;
     GrGLSLVarying(GrSLType type, Scope scope = Scope::kVertToFrag)
         : fType(type)
         , fScope(scope) {
         // Metal doesn't support varying matrices, so we disallow them everywhere for consistency
         SkASSERT(!is_matrix(type));
     }

     void reset(GrSLType type, Scope scope = Scope::kVertToFrag) {
         // Metal doesn't support varying matrices, so we disallow them everywhere for consistency
         SkASSERT(!is_matrix(type));
         *this = GrGLSLVarying();
         fType = type;
         fScope = scope;
     }

     GrSLType type() const { return fType; }
     Scope scope() const { return fScope; }
     bool isInVertexShader() const { return Scope::kGeoToFrag != fScope; }
     bool isInFragmentShader() const { return Scope::kVertToGeo != fScope; }

     const char* vsOut() const { SkASSERT(this->isInVertexShader()); return fVsOut; }
     const char* gsIn() const { return fGsIn; }
     const char* gsOut() const { return fGsOut; }
     const char* fsIn() const { SkASSERT(this->isInFragmentShader()); return fFsIn; }

 private:
     GrSLType fType = kVoid_GrSLType;
     Scope fScope = Scope::kVertToFrag;
     const char* fVsOut = nullptr;
     const char* fGsIn = nullptr;
     const char* fGsOut = nullptr;
     const char* fFsIn = nullptr;

     friend class GrGLSLVaryingHandler;
 };

 static const int kVaryingsPerBlock = 8;

 class GrGLSLVaryingHandler {
 public:
     explicit GrGLSLVaryingHandler(GrGLSLProgramBuilder* program)
         : fVaryings(kVaryingsPerBlock)
         , fVertexInputs(kVaryingsPerBlock)
         , fVertexOutputs(kVaryingsPerBlock)
         , fGeomInputs(kVaryingsPerBlock)
         , fGeomOutputs(kVaryingsPerBlock)
         , fFragInputs(kVaryingsPerBlock)
         , fFragOutputs(kVaryingsPerBlock)
         , fProgramBuilder(program)
         , fDefaultInterpolationModifier(nullptr) {}

     virtual ~GrGLSLVaryingHandler() {}

     /*
      * Notifies the varying handler that this shader will never emit geometry in perspective and
      * therefore does not require perspective-correct interpolation. When supported, this allows
      * varyings to use the "noperspective" keyword, which means the GPU can use cheaper math for
      * interpolation.
      */
     void setNoPerspective();

     enum class Interpolation {
         kInterpolated,
         kCanBeFlat, // Use "flat" if it will be faster.
         kMustBeFlat // Use "flat" even if it is known to be slow.
     };

     /*
      * addVarying allows fine grained control for setting up varyings between stages. Calling this
      * function will make sure all necessary decls are setup for the client. The client however is
      * responsible for setting up all shader code (e.g "vOut = vIn;") If you just need to take an
      * attribute and pass it through to an output value in a fragment shader, use
      * addPassThroughAttribute.
      * TODO convert most uses of addVarying to addPassThroughAttribute
      */
     void addVarying(const char* name, GrGLSLVarying* varying,
                     Interpolation = Interpolation::kInterpolated);

     /*
      * The GP can use these calls to pass an attribute through all shaders directly to 'output' in
      * the fragment shader.  Though these calls affect both the vertex shader and fragment shader,
      * they expect 'output' to be defined in the fragment shader before the call is made. If there
      * is a geometry shader, we will simply take the value of the varying from the first vertex and
      * that will be set as the output varying for all emitted vertices.
      * TODO it might be nicer behavior to have a flag to declare output inside these calls
      */
     void addPassThroughAttribute(const GrGeometryProcessor::Attribute&, const char* output,
                                  Interpolation = Interpolation::kInterpolated);

     void emitAttributes(const GrGeometryProcessor& gp);

     // This should be called once all attributes and varyings have been added to the
     // GrGLSLVaryingHanlder and before getting/adding any of the declarations to the shaders.
     void finalize();

     void getVertexDecls(SkString* inputDecls, SkString* outputDecls) const;
     void getGeomDecls(SkString* inputDecls, SkString* outputDecls) const;
     void getFragDecls(SkString* inputDecls, SkString* outputDecls) const;

 protected:
     struct VaryingInfo {
         GrSLType         fType;
         bool             fIsFlat;
         SkString         fVsOut;
         SkString         fGsOut;
         GrShaderFlags    fVisibility;
     };

     typedef GrTAllocator<VaryingInfo> VaryingList;
     typedef GrTAllocator<GrShaderVar> VarArray;
     typedef GrGLSLProgramDataManager::VaryingHandle VaryingHandle;

     VaryingList    fVaryings;
     VarArray       fVertexInputs;
     VarArray       fVertexOutputs;
     VarArray       fGeomInputs;
     VarArray       fGeomOutputs;
     VarArray       fFragInputs;
     VarArray       fFragOutputs;

     // This is not owned by the class
     GrGLSLProgramBuilder* fProgramBuilder;

 private:
     void addAttribute(const GrShaderVar& var);

     virtual void onFinalize() = 0;

     // helper function for get*Decls
     void appendDecls(const VarArray& vars, SkString* out) const;

     const char* fDefaultInterpolationModifier;

     friend class GrGLSLProgramBuilder;
 };

 #endif
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrGLSLVarying_DEFINED
	#define GrGLSLVarying_DEFINED

	#include "GrAllocator.h"
	#include "GrGeometryProcessor.h"
	#include "GrShaderVar.h"
	#include "GrTypesPriv.h"
	#include "glsl/GrGLSLProgramDataManager.h"

	class GrGLSLProgramBuilder;

	#ifdef SK_DEBUG
	static bool is_matrix(GrSLType type) {
	switch (type) {
	case kFloat2x2_GrSLType:
	case kFloat3x3_GrSLType:
	case kFloat4x4_GrSLType:
	case kHalf2x2_GrSLType:
	case kHalf3x3_GrSLType:
	case kHalf4x4_GrSLType:
	return true;
	default:
	return false;
	}
	}
	#endif

	class GrGLSLVarying {
	public:
	enum class Scope {
	kVertToFrag,
	kVertToGeo,
	kGeoToFrag
	};

	GrGLSLVarying() = default;
	GrGLSLVarying(GrSLType type, Scope scope = Scope::kVertToFrag)
	: fType(type)
	, fScope(scope) {
	// Metal doesn't support varying matrices, so we disallow them everywhere for consistency
	SkASSERT(!is_matrix(type));
	}

	void reset(GrSLType type, Scope scope = Scope::kVertToFrag) {
	// Metal doesn't support varying matrices, so we disallow them everywhere for consistency
	SkASSERT(!is_matrix(type));
	*this = GrGLSLVarying();
	fType = type;
	fScope = scope;
	}

	GrSLType type() const { return fType; }
	Scope scope() const { return fScope; }
	bool isInVertexShader() const { return Scope::kGeoToFrag != fScope; }
	bool isInFragmentShader() const { return Scope::kVertToGeo != fScope; }

	const char* vsOut() const { SkASSERT(this->isInVertexShader()); return fVsOut; }
	const char* gsIn() const { return fGsIn; }
	const char* gsOut() const { return fGsOut; }
	const char* fsIn() const { SkASSERT(this->isInFragmentShader()); return fFsIn; }

	private:
	GrSLType fType = kVoid_GrSLType;
	Scope fScope = Scope::kVertToFrag;
	const char* fVsOut = nullptr;
	const char* fGsIn = nullptr;
	const char* fGsOut = nullptr;
	const char* fFsIn = nullptr;

	friend class GrGLSLVaryingHandler;
	};

	static const int kVaryingsPerBlock = 8;

	class GrGLSLVaryingHandler {
	public:
	explicit GrGLSLVaryingHandler(GrGLSLProgramBuilder* program)
	: fVaryings(kVaryingsPerBlock)
	, fVertexInputs(kVaryingsPerBlock)
	, fVertexOutputs(kVaryingsPerBlock)
	, fGeomInputs(kVaryingsPerBlock)
	, fGeomOutputs(kVaryingsPerBlock)
	, fFragInputs(kVaryingsPerBlock)
	, fFragOutputs(kVaryingsPerBlock)
	, fProgramBuilder(program)
	, fDefaultInterpolationModifier(nullptr) {}

	virtual ~GrGLSLVaryingHandler() {}

	/*
	* Notifies the varying handler that this shader will never emit geometry in perspective and
	* therefore does not require perspective-correct interpolation. When supported, this allows
	* varyings to use the "noperspective" keyword, which means the GPU can use cheaper math for
	* interpolation.
	*/
	void setNoPerspective();

	enum class Interpolation {
	kInterpolated,
	kCanBeFlat, // Use "flat" if it will be faster.
	kMustBeFlat // Use "flat" even if it is known to be slow.
	};

	/*
	* addVarying allows fine grained control for setting up varyings between stages. Calling this
	* function will make sure all necessary decls are setup for the client. The client however is
	* responsible for setting up all shader code (e.g "vOut = vIn;") If you just need to take an
	* attribute and pass it through to an output value in a fragment shader, use
	* addPassThroughAttribute.
	* TODO convert most uses of addVarying to addPassThroughAttribute
	*/
	void addVarying(const char* name, GrGLSLVarying* varying,
	Interpolation = Interpolation::kInterpolated);

	/*
	* The GP can use these calls to pass an attribute through all shaders directly to 'output' in
	* the fragment shader. Though these calls affect both the vertex shader and fragment shader,
	* they expect 'output' to be defined in the fragment shader before the call is made. If there
	* is a geometry shader, we will simply take the value of the varying from the first vertex and
	* that will be set as the output varying for all emitted vertices.
	* TODO it might be nicer behavior to have a flag to declare output inside these calls
	*/
	void addPassThroughAttribute(const GrGeometryProcessor::Attribute&, const char* output,
	Interpolation = Interpolation::kInterpolated);

	void emitAttributes(const GrGeometryProcessor& gp);

	// This should be called once all attributes and varyings have been added to the
	// GrGLSLVaryingHanlder and before getting/adding any of the declarations to the shaders.
	void finalize();

	void getVertexDecls(SkString* inputDecls, SkString* outputDecls) const;
	void getGeomDecls(SkString* inputDecls, SkString* outputDecls) const;
	void getFragDecls(SkString* inputDecls, SkString* outputDecls) const;

	protected:
	struct VaryingInfo {
	GrSLType fType;
	bool fIsFlat;
	SkString fVsOut;
	SkString fGsOut;
	GrShaderFlags fVisibility;
	};

	typedef GrTAllocator<VaryingInfo> VaryingList;
	typedef GrTAllocator<GrShaderVar> VarArray;
	typedef GrGLSLProgramDataManager::VaryingHandle VaryingHandle;

	VaryingList fVaryings;
	VarArray fVertexInputs;
	VarArray fVertexOutputs;
	VarArray fGeomInputs;
	VarArray fGeomOutputs;
	VarArray fFragInputs;
	VarArray fFragOutputs;

	// This is not owned by the class
	GrGLSLProgramBuilder* fProgramBuilder;

	private:
	void addAttribute(const GrShaderVar& var);

	virtual void onFinalize() = 0;

	// helper function for get*Decls
	void appendDecls(const VarArray& vars, SkString* out) const;

	const char* fDefaultInterpolationModifier;

	friend class GrGLSLProgramBuilder;
	};

	#endif