src/sksl/ir/SkSLProgram.h - skia.git - Git at Google

 /*
  * Copyright 2016 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SKSL_PROGRAM
 #define SKSL_PROGRAM

 #include <vector>
 #include <memory>

 #include "SkSLBoolLiteral.h"
 #include "SkSLExpression.h"
 #include "SkSLFloatLiteral.h"
 #include "SkSLIntLiteral.h"
 #include "SkSLModifiers.h"
 #include "SkSLProgramElement.h"
 #include "SkSLSymbolTable.h"

 // name of the render target width uniform
 #define SKSL_RTWIDTH_NAME "u_skRTWidth"

 // name of the render target height uniform
 #define SKSL_RTHEIGHT_NAME "u_skRTHeight"

 namespace SkSL {

 class Context;

 /**
  * Represents a fully-digested program, ready for code generation.
  */
 struct Program {
     struct Settings {
         struct Value {
             Value(bool b)
             : fKind(kBool_Kind)
             , fValue(b) {}

             Value(int i)
             : fKind(kInt_Kind)
             , fValue(i) {}

             Value(unsigned int i)
             : fKind(kInt_Kind)
             , fValue(i) {}

             Value(float f)
             : fKind(kFloat_Kind)
             , fValue(f) {}

             std::unique_ptr<Expression> literal(const Context& context, int offset) const {
                 switch (fKind) {
                     case Program::Settings::Value::kBool_Kind:
                         return std::unique_ptr<Expression>(new BoolLiteral(context,
                                                                            offset,
                                                                            fValue));
                     case Program::Settings::Value::kInt_Kind:
                         return std::unique_ptr<Expression>(new IntLiteral(context,
                                                                           offset,
                                                                           fValue));
                     case Program::Settings::Value::kFloat_Kind:
                         return std::unique_ptr<Expression>(new FloatLiteral(context,
                                                                           offset,
                                                                           fValue));
                     default:
                         SkASSERT(false);
                         return nullptr;
                 }
             }

             enum {
                 kBool_Kind,
                 kInt_Kind,
                 kFloat_Kind,
             } fKind;

             int fValue;
         };

 #ifdef SKSL_STANDALONE
         const StandaloneShaderCaps* fCaps = &standaloneCaps;
 #else
         const GrShaderCaps* fCaps = nullptr;
 #endif
         // if false, sk_FragCoord is exactly the same as gl_FragCoord. If true, the y coordinate
         // must be flipped.
         bool fFlipY = false;
         // If true the destination fragment color is read sk_FragColor. It must be declared inout.
         bool fFragColorIsInOut = false;
         // if true, Setting objects (e.g. sk_Caps.fbFetchSupport) should be replaced with their
         // constant equivalents during compilation
         bool fReplaceSettings = true;
         // if true, all halfs are forced to be floats
         bool fForceHighPrecision = false;
         // if true, add -0.5 bias to LOD of all texture lookups
         bool fSharpenTextures = false;
         std::unordered_map<String, Value> fArgs;
     };

     struct Inputs {
         // if true, this program requires the render target width uniform to be defined
         bool fRTWidth;

         // if true, this program requires the render target height uniform to be defined
         bool fRTHeight;

         // if true, this program must be recompiled if the flipY setting changes. If false, the
         // program will compile to the same code regardless of the flipY setting.
         bool fFlipY;

         void reset() {
             fRTWidth = false;
             fRTHeight = false;
             fFlipY = false;
         }

         bool isEmpty() {
             return !fRTWidth && !fRTHeight && !fFlipY;
         }
     };

     class iterator {
     public:
         ProgramElement& operator*() {
             if (fIter1 != fEnd1) {
                 return **fIter1;
             }
             return **fIter2;
         }

         iterator& operator++() {
             if (fIter1 != fEnd1) {
                 ++fIter1;
                 return *this;
             }
             ++fIter2;
             return *this;
         }

         bool operator==(const iterator& other) const {
             return fIter1 == other.fIter1 && fIter2 == other.fIter2;
         }

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

     private:
         using inner = std::vector<std::unique_ptr<ProgramElement>>::iterator;

         iterator(inner begin1, inner end1, inner begin2, inner end2)
         : fIter1(begin1)
         , fEnd1(end1)
         , fIter2(begin2)
         , fEnd2(end2) {}

         inner fIter1;
         inner fEnd1;
         inner fIter2;
         inner fEnd2;

         friend struct Program;
     };

     class const_iterator {
     public:
         const ProgramElement& operator*() {
             if (fIter1 != fEnd1) {
                 return **fIter1;
             }
             return **fIter2;
         }

         const_iterator& operator++() {
             if (fIter1 != fEnd1) {
                 ++fIter1;
                 return *this;
             }
             ++fIter2;
             return *this;
         }

         bool operator==(const const_iterator& other) const {
             return fIter1 == other.fIter1 && fIter2 == other.fIter2;
         }

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

     private:
         using inner = std::vector<std::unique_ptr<ProgramElement>>::const_iterator;

         const_iterator(inner begin1, inner end1, inner begin2, inner end2)
         : fIter1(begin1)
         , fEnd1(end1)
         , fIter2(begin2)
         , fEnd2(end2) {}

         inner fIter1;
         inner fEnd1;
         inner fIter2;
         inner fEnd2;

         friend struct Program;
     };

     enum Kind {
         kFragment_Kind,
         kVertex_Kind,
         kGeometry_Kind,
         kFragmentProcessor_Kind,
         kPipelineStage_Kind,
         kMixer_Kind
     };

     Program(Kind kind,
             std::unique_ptr<String> source,
             Settings settings,
             std::shared_ptr<Context> context,
             std::vector<std::unique_ptr<ProgramElement>>* inheritedElements,
             std::vector<std::unique_ptr<ProgramElement>> elements,
             std::shared_ptr<SymbolTable> symbols,
             Inputs inputs)
     : fKind(kind)
     , fSource(std::move(source))
     , fSettings(settings)
     , fContext(context)
     , fSymbols(symbols)
     , fInputs(inputs)
     , fInheritedElements(inheritedElements)
     , fElements(std::move(elements)) {}

     iterator begin() {
         if (fInheritedElements) {
             return iterator(fInheritedElements->begin(), fInheritedElements->end(),
                             fElements.begin(), fElements.end());
         }
         return iterator(fElements.begin(), fElements.end(), fElements.end(), fElements.end());
     }

     iterator end() {
         if (fInheritedElements) {
             return iterator(fInheritedElements->end(), fInheritedElements->end(),
                             fElements.end(), fElements.end());
         }
         return iterator(fElements.end(), fElements.end(), fElements.end(), fElements.end());
     }

     const_iterator begin() const {
         if (fInheritedElements) {
             return const_iterator(fInheritedElements->begin(), fInheritedElements->end(),
                                   fElements.begin(), fElements.end());
         }
         return const_iterator(fElements.begin(), fElements.end(), fElements.end(), fElements.end());
     }

     const_iterator end() const {
         if (fInheritedElements) {
             return const_iterator(fInheritedElements->end(), fInheritedElements->end(),
                                   fElements.end(), fElements.end());
         }
         return const_iterator(fElements.end(), fElements.end(), fElements.end(), fElements.end());
     }

     Kind fKind;
     std::unique_ptr<String> fSource;
     Settings fSettings;
     std::shared_ptr<Context> fContext;
     // it's important to keep fElements defined after (and thus destroyed before) fSymbols,
     // because destroying elements can modify reference counts in symbols
     std::shared_ptr<SymbolTable> fSymbols;
     Inputs fInputs;
     bool fIsOptimized = false;

 private:
     std::vector<std::unique_ptr<ProgramElement>>* fInheritedElements;
     std::vector<std::unique_ptr<ProgramElement>> fElements;

     friend class Compiler;
 };

 } // namespace

 #endif
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SKSL_PROGRAM
	#define SKSL_PROGRAM

	#include <vector>
	#include <memory>

	#include "SkSLBoolLiteral.h"
	#include "SkSLExpression.h"
	#include "SkSLFloatLiteral.h"
	#include "SkSLIntLiteral.h"
	#include "SkSLModifiers.h"
	#include "SkSLProgramElement.h"
	#include "SkSLSymbolTable.h"

	// name of the render target width uniform
	#define SKSL_RTWIDTH_NAME "u_skRTWidth"

	// name of the render target height uniform
	#define SKSL_RTHEIGHT_NAME "u_skRTHeight"

	namespace SkSL {

	class Context;

	/**
	* Represents a fully-digested program, ready for code generation.
	*/
	struct Program {
	struct Settings {
	struct Value {
	Value(bool b)
	: fKind(kBool_Kind)
	, fValue(b) {}

	Value(int i)
	: fKind(kInt_Kind)
	, fValue(i) {}

	Value(unsigned int i)
	: fKind(kInt_Kind)
	, fValue(i) {}

	Value(float f)
	: fKind(kFloat_Kind)
	, fValue(f) {}

	std::unique_ptr<Expression> literal(const Context& context, int offset) const {
	switch (fKind) {
	case Program::Settings::Value::kBool_Kind:
	return std::unique_ptr<Expression>(new BoolLiteral(context,
	offset,
	fValue));
	case Program::Settings::Value::kInt_Kind:
	return std::unique_ptr<Expression>(new IntLiteral(context,
	offset,
	fValue));
	case Program::Settings::Value::kFloat_Kind:
	return std::unique_ptr<Expression>(new FloatLiteral(context,
	offset,
	fValue));
	default:
	SkASSERT(false);
	return nullptr;
	}
	}

	enum {
	kBool_Kind,
	kInt_Kind,
	kFloat_Kind,
	} fKind;

	int fValue;
	};

	#ifdef SKSL_STANDALONE
	const StandaloneShaderCaps* fCaps = &standaloneCaps;
	#else
	const GrShaderCaps* fCaps = nullptr;
	#endif
	// if false, sk_FragCoord is exactly the same as gl_FragCoord. If true, the y coordinate
	// must be flipped.
	bool fFlipY = false;
	// If true the destination fragment color is read sk_FragColor. It must be declared inout.
	bool fFragColorIsInOut = false;
	// if true, Setting objects (e.g. sk_Caps.fbFetchSupport) should be replaced with their
	// constant equivalents during compilation
	bool fReplaceSettings = true;
	// if true, all halfs are forced to be floats
	bool fForceHighPrecision = false;
	// if true, add -0.5 bias to LOD of all texture lookups
	bool fSharpenTextures = false;
	std::unordered_map<String, Value> fArgs;
	};

	struct Inputs {
	// if true, this program requires the render target width uniform to be defined
	bool fRTWidth;

	// if true, this program requires the render target height uniform to be defined
	bool fRTHeight;

	// if true, this program must be recompiled if the flipY setting changes. If false, the
	// program will compile to the same code regardless of the flipY setting.
	bool fFlipY;

	void reset() {
	fRTWidth = false;
	fRTHeight = false;
	fFlipY = false;
	}

	bool isEmpty() {
	return !fRTWidth && !fRTHeight && !fFlipY;
	}
	};

	class iterator {
	public:
	ProgramElement& operator*() {
	if (fIter1 != fEnd1) {
	return **fIter1;
	}
	return **fIter2;
	}

	iterator& operator++() {
	if (fIter1 != fEnd1) {
	++fIter1;
	return *this;
	}
	++fIter2;
	return *this;
	}

	bool operator==(const iterator& other) const {
	return fIter1 == other.fIter1 && fIter2 == other.fIter2;
	}

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

	private:
	using inner = std::vector<std::unique_ptr<ProgramElement>>::iterator;

	iterator(inner begin1, inner end1, inner begin2, inner end2)
	: fIter1(begin1)
	, fEnd1(end1)
	, fIter2(begin2)
	, fEnd2(end2) {}

	inner fIter1;
	inner fEnd1;
	inner fIter2;
	inner fEnd2;

	friend struct Program;
	};

	class const_iterator {
	public:
	const ProgramElement& operator*() {
	if (fIter1 != fEnd1) {
	return **fIter1;
	}
	return **fIter2;
	}

	const_iterator& operator++() {
	if (fIter1 != fEnd1) {
	++fIter1;
	return *this;
	}
	++fIter2;
	return *this;
	}

	bool operator==(const const_iterator& other) const {
	return fIter1 == other.fIter1 && fIter2 == other.fIter2;
	}

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

	private:
	using inner = std::vector<std::unique_ptr<ProgramElement>>::const_iterator;

	const_iterator(inner begin1, inner end1, inner begin2, inner end2)
	: fIter1(begin1)
	, fEnd1(end1)
	, fIter2(begin2)
	, fEnd2(end2) {}

	inner fIter1;
	inner fEnd1;
	inner fIter2;
	inner fEnd2;

	friend struct Program;
	};

	enum Kind {
	kFragment_Kind,
	kVertex_Kind,
	kGeometry_Kind,
	kFragmentProcessor_Kind,
	kPipelineStage_Kind,
	kMixer_Kind
	};

	Program(Kind kind,
	std::unique_ptr<String> source,
	Settings settings,
	std::shared_ptr<Context> context,
	std::vector<std::unique_ptr<ProgramElement>>* inheritedElements,
	std::vector<std::unique_ptr<ProgramElement>> elements,
	std::shared_ptr<SymbolTable> symbols,
	Inputs inputs)
	: fKind(kind)
	, fSource(std::move(source))
	, fSettings(settings)
	, fContext(context)
	, fSymbols(symbols)
	, fInputs(inputs)
	, fInheritedElements(inheritedElements)
	, fElements(std::move(elements)) {}

	iterator begin() {
	if (fInheritedElements) {
	return iterator(fInheritedElements->begin(), fInheritedElements->end(),
	fElements.begin(), fElements.end());
	}
	return iterator(fElements.begin(), fElements.end(), fElements.end(), fElements.end());
	}

	iterator end() {
	if (fInheritedElements) {
	return iterator(fInheritedElements->end(), fInheritedElements->end(),
	fElements.end(), fElements.end());
	}
	return iterator(fElements.end(), fElements.end(), fElements.end(), fElements.end());
	}

	const_iterator begin() const {
	if (fInheritedElements) {
	return const_iterator(fInheritedElements->begin(), fInheritedElements->end(),
	fElements.begin(), fElements.end());
	}
	return const_iterator(fElements.begin(), fElements.end(), fElements.end(), fElements.end());
	}

	const_iterator end() const {
	if (fInheritedElements) {
	return const_iterator(fInheritedElements->end(), fInheritedElements->end(),
	fElements.end(), fElements.end());
	}
	return const_iterator(fElements.end(), fElements.end(), fElements.end(), fElements.end());
	}

	Kind fKind;
	std::unique_ptr<String> fSource;
	Settings fSettings;
	std::shared_ptr<Context> fContext;
	// it's important to keep fElements defined after (and thus destroyed before) fSymbols,
	// because destroying elements can modify reference counts in symbols
	std::shared_ptr<SymbolTable> fSymbols;
	Inputs fInputs;
	bool fIsOptimized = false;

	private:
	std::vector<std::unique_ptr<ProgramElement>>* fInheritedElements;
	std::vector<std::unique_ptr<ProgramElement>> fElements;

	friend class Compiler;
	};

	} // namespace

	#endif