src/sksl/SkSLJIT.h - skia - Git at Google

 /*
  * Copyright 2018 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SKSL_JIT
 #define SKSL_JIT

 #ifdef SK_LLVM_AVAILABLE

 #include "ir/SkSLBinaryExpression.h"
 #include "ir/SkSLBreakStatement.h"
 #include "ir/SkSLContinueStatement.h"
 #include "ir/SkSLExpression.h"
 #include "ir/SkSLDoStatement.h"
 #include "ir/SkSLForStatement.h"
 #include "ir/SkSLFunctionCall.h"
 #include "ir/SkSLFunctionDefinition.h"
 #include "ir/SkSLIfStatement.h"
 #include "ir/SkSLIndexExpression.h"
 #include "ir/SkSLPrefixExpression.h"
 #include "ir/SkSLPostfixExpression.h"
 #include "ir/SkSLProgram.h"
 #include "ir/SkSLReturnStatement.h"
 #include "ir/SkSLStatement.h"
 #include "ir/SkSLSwizzle.h"
 #include "ir/SkSLTernaryExpression.h"
 #include "ir/SkSLVarDeclarationsStatement.h"
 #include "ir/SkSLVariableReference.h"
 #include "ir/SkSLWhileStatement.h"

 #include "llvm-c/Analysis.h"
 #include "llvm-c/Core.h"
 #include "llvm-c/OrcBindings.h"
 #include "llvm-c/Support.h"
 #include "llvm-c/Target.h"
 #include "llvm-c/Transforms/PassManagerBuilder.h"
 #include "llvm-c/Types.h"
 #include <stack>

 class SkRasterPipeline;

 namespace SkSL {

 struct AppendStage;

 /**
  * A just-in-time compiler for SkSL code which uses an LLVM backend. Only available when the
  * skia_llvm_path gn arg is set.
  *
  * Example of using SkSLJIT to set up an SkJumper pipeline stage:
  *
  * #ifdef SK_LLVM_AVAILABLE
  *   SkSL::Compiler compiler;
  *   SkSL::Program::Settings settings;
  *   std::unique_ptr<SkSL::Program> program = compiler.convertProgram(
          SkSL::Program::kPipelineStage_Kind,
  *       "void swap(int x, int y, inout float4 color) {"
  *       "    color.rb = color.br;"
  *       "}",
  *       settings);
  *   if (!program) {
  *       printf("%s\n", compiler.errorText().c_str());
  *       abort();
  *   }
  *   SkSL::JIT& jit = *scratch->make<SkSL::JIT>(&compiler);
  *   std::unique_ptr<SkSL::JIT::Module> module = jit.compile(std::move(program));
  *   void* func = module->getJumperStage("swap");
  *   p->append(func, nullptr);
  * #endif
  */
 class JIT {
     typedef int StackIndex;

 public:
     class Module {
     public:
         /**
          * Returns the address of a symbol in the module.
          */
         void* getSymbol(const char* name);

         /**
          * Returns the address of a function as an SkJumper pipeline stage. The function must have
          * the signature void <name>(int x, int y, inout float4 color). The returned function will
          * have the correct signature to function as an SkJumper stage (meaning it will actually
          * have a different signature at runtime, accepting vector parameters and operating on
          * multiple pixels simultaneously as is normal for SkJumper stages).
          */
         void* getJumperStage(const char* name);

         ~Module() {
             LLVMOrcDisposeSharedModuleRef(fSharedModule);
         }

     private:
         Module(std::unique_ptr<Program> program,
                LLVMSharedModuleRef sharedModule,
                LLVMOrcJITStackRef jitStack)
         : fProgram(std::move(program))
         , fSharedModule(sharedModule)
         , fJITStack(jitStack) {}

         std::unique_ptr<Program> fProgram;
         LLVMSharedModuleRef fSharedModule;
         LLVMOrcJITStackRef fJITStack;

         friend class JIT;
     };

     JIT(Compiler* compiler);

     ~JIT();

     /**
      * Just-in-time compiles an SkSL program and returns the resulting Module. The JIT must not be
      * destroyed before all of its Modules are destroyed.
      */
     std::unique_ptr<Module> compile(std::unique_ptr<Program> program);

 private:
     static constexpr int CHANNELS = 4;

     enum TypeKind {
         kFloat_TypeKind,
         kInt_TypeKind,
         kUInt_TypeKind,
         kBool_TypeKind
     };

     class LValue {
     public:
         virtual ~LValue() {}

         virtual LLVMValueRef load(LLVMBuilderRef builder) = 0;

         virtual void store(LLVMBuilderRef builder, LLVMValueRef value) = 0;
     };

     void addBuiltinFunction(const char* ourName, const char* realName, LLVMTypeRef returnType,
                             std::vector<LLVMTypeRef> parameters);

     void loadBuiltinFunctions();

     void setBlock(LLVMBuilderRef builder, LLVMBasicBlockRef block);

     LLVMTypeRef getType(const Type& type);

     TypeKind typeKind(const Type& type);

     std::unique_ptr<LValue> getLValue(LLVMBuilderRef builder, const Expression& expr);

     void vectorize(LLVMBuilderRef builder, LLVMValueRef* value, int columns);

     void vectorize(LLVMBuilderRef builder, const BinaryExpression& b, LLVMValueRef* left,
                    LLVMValueRef* right);

     LLVMValueRef compileBinary(LLVMBuilderRef builder, const BinaryExpression& b);

     LLVMValueRef compileConstructor(LLVMBuilderRef builder, const Constructor& c);

     LLVMValueRef compileFunctionCall(LLVMBuilderRef builder, const FunctionCall& fc);

     LLVMValueRef compileIndex(LLVMBuilderRef builder, const IndexExpression& v);

     LLVMValueRef compilePostfix(LLVMBuilderRef builder, const PostfixExpression& p);

     LLVMValueRef compilePrefix(LLVMBuilderRef builder, const PrefixExpression& p);

     LLVMValueRef compileSwizzle(LLVMBuilderRef builder, const Swizzle& s);

     LLVMValueRef compileVariableReference(LLVMBuilderRef builder, const VariableReference& v);

     LLVMValueRef compileTernary(LLVMBuilderRef builder, const TernaryExpression& t);

     LLVMValueRef compileExpression(LLVMBuilderRef builder, const Expression& expr);

     void appendStage(LLVMBuilderRef builder, const AppendStage& a);

     void compileBlock(LLVMBuilderRef builder, const Block& block);

     void compileBreak(LLVMBuilderRef builder, const BreakStatement& b);

     void compileContinue(LLVMBuilderRef builder, const ContinueStatement& c);

     void compileDo(LLVMBuilderRef builder, const DoStatement& d);

     void compileFor(LLVMBuilderRef builder, const ForStatement& f);

     void compileIf(LLVMBuilderRef builder, const IfStatement& i);

     void compileReturn(LLVMBuilderRef builder, const ReturnStatement& r);

     void compileVarDeclarations(LLVMBuilderRef builder, const VarDeclarationsStatement& decls);

     void compileWhile(LLVMBuilderRef builder, const WhileStatement& w);

     void compileStatement(LLVMBuilderRef builder, const Statement& stmt);

     // The "Vector" variants of functions attempt to compile a given expression or statement as part
     // of a vectorized SkJumper stage function - that is, with r, g, b, and a each being vectors of
     // fVectorCount floats. So a statement like "color.r = 0;" looks like it modifies a single
     // channel of a single pixel, but the compiled code will actually modify the red channel of
     // fVectorCount pixels at once.
     //
     // As not everything can be vectorized, these calls return a bool to indicate whether they were
     // successful. If anything anywhere in the function cannot be vectorized, the JIT will fall back
     // to looping over the pixels instead.
     //
     // Since we process multiple pixels at once, and each pixel consists of multiple color channels,
     // expressions may effectively result in a vector-of-vectors. We produce zero to four outputs
     // when compiling expression, each of which is a vector, so that e.g. float2(1, 0) actually
     // produces two vectors, one containing all 1s, the other all 0s. The out parameter always
     // allows for 4 channels, but the functions produce 0 to 4 channels depending on the type they
     // are operating on. Thus evaluating "color.rgb" actually fills in out[0] through out[2],
     // leaving out[3] uninitialized.
     // As the number of outputs can be inferred from the type of the expression, it is not
     // explicitly signalled anywhere.
     bool compileVectorBinary(LLVMBuilderRef builder, const BinaryExpression& b,
                              LLVMValueRef out[CHANNELS]);

     bool compileVectorConstructor(LLVMBuilderRef builder, const Constructor& c,
                                   LLVMValueRef out[CHANNELS]);

     bool compileVectorFloatLiteral(LLVMBuilderRef builder, const FloatLiteral& f,
                                    LLVMValueRef out[CHANNELS]);

     bool compileVectorSwizzle(LLVMBuilderRef builder, const Swizzle& s,
                               LLVMValueRef out[CHANNELS]);

     bool compileVectorVariableReference(LLVMBuilderRef builder, const VariableReference& v,
                                         LLVMValueRef out[CHANNELS]);

     bool compileVectorExpression(LLVMBuilderRef builder, const Expression& expr,
                                  LLVMValueRef out[CHANNELS]);

     bool getVectorLValue(LLVMBuilderRef builder, const Expression& e, LLVMValueRef out[CHANNELS]);

     /**
      * Evaluates the left and right operands of a binary operation, promoting one of them to a
      * vector if necessary to make the types match.
      */
     bool getVectorBinaryOperands(LLVMBuilderRef builder, const Expression& left,
                                  LLVMValueRef outLeft[CHANNELS], const Expression& right,
                                  LLVMValueRef outRight[CHANNELS]);

     bool compileVectorStatement(LLVMBuilderRef builder, const Statement& stmt);

     /**
      * Returns true if this function has the signature void(int, int, inout float4) and thus can be
      * used as an SkJumper stage.
      */
     bool hasStageSignature(const FunctionDeclaration& f);

     /**
      * Attempts to compile a vectorized stage function, returning true on success. A stage function
      * of e.g. "color.r = 0;" will produce code which sets the entire red vector to zeros in a
      * single instruction, thus calculating several pixels at once.
      */
     bool compileStageFunctionVector(const FunctionDefinition& f, LLVMValueRef newFunc);

     /**
      * Fallback function which loops over the pixels, for when vectorization fails. A stage function
      * of e.g. "color.r = 0;" will produce a loop which iterates over the entries in the red vector,
      * setting each one to zero individually.
      */
     void compileStageFunctionLoop(const FunctionDefinition& f, LLVMValueRef newFunc);

     /**
      * Called when compiling a function which has the signature of an SkJumper stage. Produces a
      * version of the function which can be plugged into SkJumper (thus having a signature which
      * accepts four vectors, one for each color channel, containing the color data of multiple
      * pixels at once). To go from SkSL code which operates on a single pixel at a time to CPU code
      * which operates on multiple pixels at once, the code is either vectorized using
      * compileStageFunctionVector or wrapped in a loop using compileStageFunctionLoop.
      */
     LLVMValueRef compileStageFunction(const FunctionDefinition& f);

     /**
      * Compiles an SkSL function to an LLVM function. If the function has the signature of an
      * SkJumper stage, it will *also* be compiled by compileStageFunction, resulting in both a stage
      * and non-stage version of the function.
      */
     LLVMValueRef compileFunction(const FunctionDefinition& f);

     void createModule();

     void optimize();

     bool isColorRef(const Expression& expr);

     static uint64_t resolveSymbol(const char* name, JIT* jit);

     const char* fCPU;
     int fVectorCount;
     Compiler& fCompiler;
     std::unique_ptr<Program> fProgram;
     LLVMContextRef fContext;
     LLVMModuleRef fModule;
     LLVMSharedModuleRef fSharedModule;
     LLVMOrcJITStackRef fJITStack;
     LLVMValueRef fCurrentFunction;
     LLVMBasicBlockRef fAllocaBlock;
     LLVMBasicBlockRef fCurrentBlock;
     LLVMTypeRef fVoidType;
     LLVMTypeRef fInt1Type;
     LLVMTypeRef fInt1VectorType;
     LLVMTypeRef fInt1Vector2Type;
     LLVMTypeRef fInt1Vector3Type;
     LLVMTypeRef fInt1Vector4Type;
     LLVMTypeRef fInt8Type;
     LLVMTypeRef fInt8PtrType;
     LLVMTypeRef fInt32Type;
     LLVMTypeRef fInt32VectorType;
     LLVMTypeRef fInt32Vector2Type;
     LLVMTypeRef fInt32Vector3Type;
     LLVMTypeRef fInt32Vector4Type;
     LLVMTypeRef fInt64Type;
     LLVMTypeRef fSizeTType;
     LLVMTypeRef fFloat32Type;
     LLVMTypeRef fFloat32VectorType;
     LLVMTypeRef fFloat32Vector2Type;
     LLVMTypeRef fFloat32Vector3Type;
     LLVMTypeRef fFloat32Vector4Type;
     // Our SkSL stage functions have a single float4 for color, but the actual SkJumper stage
     // function has four separate vectors, one for each channel. These four values are references to
     // the red, green, blue, and alpha vectors respectively.
     LLVMValueRef fChannels[CHANNELS];
     // when processing a stage function, this points to the SkSL color parameter (an inout float4)
     const Variable* fColorParam;
     std::unordered_map<const FunctionDeclaration*, LLVMValueRef> fFunctions;
     std::unordered_map<const Variable*, LLVMValueRef> fVariables;
     // LLVM function parameters are read-only, so when modifying function parameters we need to
     // first promote them to variables. This keeps track of which parameters have been promoted.
     std::set<const Variable*> fPromotedParameters;
     std::vector<LLVMBasicBlockRef> fBreakTarget;
     std::vector<LLVMBasicBlockRef> fContinueTarget;

     LLVMValueRef fFoldAnd2Func;
     LLVMValueRef fFoldOr2Func;
     LLVMValueRef fFoldAnd3Func;
     LLVMValueRef fFoldOr3Func;
     LLVMValueRef fFoldAnd4Func;
     LLVMValueRef fFoldOr4Func;
     LLVMValueRef fAppendFunc;
     LLVMValueRef fAppendCallbackFunc;
     LLVMValueRef fDebugFunc;
 };

 } // namespace

 #endif // SK_LLVM_AVAILABLE

 #endif // SKSL_JIT
	/*
	* Copyright 2018 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SKSL_JIT
	#define SKSL_JIT

	#ifdef SK_LLVM_AVAILABLE

	#include "ir/SkSLBinaryExpression.h"
	#include "ir/SkSLBreakStatement.h"
	#include "ir/SkSLContinueStatement.h"
	#include "ir/SkSLExpression.h"
	#include "ir/SkSLDoStatement.h"
	#include "ir/SkSLForStatement.h"
	#include "ir/SkSLFunctionCall.h"
	#include "ir/SkSLFunctionDefinition.h"
	#include "ir/SkSLIfStatement.h"
	#include "ir/SkSLIndexExpression.h"
	#include "ir/SkSLPrefixExpression.h"
	#include "ir/SkSLPostfixExpression.h"
	#include "ir/SkSLProgram.h"
	#include "ir/SkSLReturnStatement.h"
	#include "ir/SkSLStatement.h"
	#include "ir/SkSLSwizzle.h"
	#include "ir/SkSLTernaryExpression.h"
	#include "ir/SkSLVarDeclarationsStatement.h"
	#include "ir/SkSLVariableReference.h"
	#include "ir/SkSLWhileStatement.h"

	#include "llvm-c/Analysis.h"
	#include "llvm-c/Core.h"
	#include "llvm-c/OrcBindings.h"
	#include "llvm-c/Support.h"
	#include "llvm-c/Target.h"
	#include "llvm-c/Transforms/PassManagerBuilder.h"
	#include "llvm-c/Types.h"
	#include <stack>

	class SkRasterPipeline;

	namespace SkSL {

	struct AppendStage;

	/**
	* A just-in-time compiler for SkSL code which uses an LLVM backend. Only available when the
	* skia_llvm_path gn arg is set.
	*
	* Example of using SkSLJIT to set up an SkJumper pipeline stage:
	*
	* #ifdef SK_LLVM_AVAILABLE
	* SkSL::Compiler compiler;
	* SkSL::Program::Settings settings;
	* std::unique_ptr<SkSL::Program> program = compiler.convertProgram(
	SkSL::Program::kPipelineStage_Kind,
	* "void swap(int x, int y, inout float4 color) {"
	* " color.rb = color.br;"
	* "}",
	* settings);
	* if (!program) {
	* printf("%s\n", compiler.errorText().c_str());
	* abort();
	* }
	* SkSL::JIT& jit = *scratch->make<SkSL::JIT>(&compiler);
	* std::unique_ptr<SkSL::JIT::Module> module = jit.compile(std::move(program));
	* void* func = module->getJumperStage("swap");
	* p->append(func, nullptr);
	* #endif
	*/
	class JIT {
	typedef int StackIndex;

	public:
	class Module {
	public:
	/**
	* Returns the address of a symbol in the module.
	*/
	void* getSymbol(const char* name);

	/**
	* Returns the address of a function as an SkJumper pipeline stage. The function must have
	* the signature void <name>(int x, int y, inout float4 color). The returned function will
	* have the correct signature to function as an SkJumper stage (meaning it will actually
	* have a different signature at runtime, accepting vector parameters and operating on
	* multiple pixels simultaneously as is normal for SkJumper stages).
	*/
	void* getJumperStage(const char* name);

	~Module() {
	LLVMOrcDisposeSharedModuleRef(fSharedModule);
	}

	private:
	Module(std::unique_ptr<Program> program,
	LLVMSharedModuleRef sharedModule,
	LLVMOrcJITStackRef jitStack)
	: fProgram(std::move(program))
	, fSharedModule(sharedModule)
	, fJITStack(jitStack) {}

	std::unique_ptr<Program> fProgram;
	LLVMSharedModuleRef fSharedModule;
	LLVMOrcJITStackRef fJITStack;

	friend class JIT;
	};

	JIT(Compiler* compiler);

	~JIT();

	/**
	* Just-in-time compiles an SkSL program and returns the resulting Module. The JIT must not be
	* destroyed before all of its Modules are destroyed.
	*/
	std::unique_ptr<Module> compile(std::unique_ptr<Program> program);

	private:
	static constexpr int CHANNELS = 4;

	enum TypeKind {
	kFloat_TypeKind,
	kInt_TypeKind,
	kUInt_TypeKind,
	kBool_TypeKind
	};

	class LValue {
	public:
	virtual ~LValue() {}

	virtual LLVMValueRef load(LLVMBuilderRef builder) = 0;

	virtual void store(LLVMBuilderRef builder, LLVMValueRef value) = 0;
	};

	void addBuiltinFunction(const char* ourName, const char* realName, LLVMTypeRef returnType,
	std::vector<LLVMTypeRef> parameters);

	void loadBuiltinFunctions();

	void setBlock(LLVMBuilderRef builder, LLVMBasicBlockRef block);

	LLVMTypeRef getType(const Type& type);

	TypeKind typeKind(const Type& type);

	std::unique_ptr<LValue> getLValue(LLVMBuilderRef builder, const Expression& expr);

	void vectorize(LLVMBuilderRef builder, LLVMValueRef* value, int columns);

	void vectorize(LLVMBuilderRef builder, const BinaryExpression& b, LLVMValueRef* left,
	LLVMValueRef* right);

	LLVMValueRef compileBinary(LLVMBuilderRef builder, const BinaryExpression& b);

	LLVMValueRef compileConstructor(LLVMBuilderRef builder, const Constructor& c);

	LLVMValueRef compileFunctionCall(LLVMBuilderRef builder, const FunctionCall& fc);

	LLVMValueRef compileIndex(LLVMBuilderRef builder, const IndexExpression& v);

	LLVMValueRef compilePostfix(LLVMBuilderRef builder, const PostfixExpression& p);

	LLVMValueRef compilePrefix(LLVMBuilderRef builder, const PrefixExpression& p);

	LLVMValueRef compileSwizzle(LLVMBuilderRef builder, const Swizzle& s);

	LLVMValueRef compileVariableReference(LLVMBuilderRef builder, const VariableReference& v);

	LLVMValueRef compileTernary(LLVMBuilderRef builder, const TernaryExpression& t);

	LLVMValueRef compileExpression(LLVMBuilderRef builder, const Expression& expr);

	void appendStage(LLVMBuilderRef builder, const AppendStage& a);

	void compileBlock(LLVMBuilderRef builder, const Block& block);

	void compileBreak(LLVMBuilderRef builder, const BreakStatement& b);

	void compileContinue(LLVMBuilderRef builder, const ContinueStatement& c);

	void compileDo(LLVMBuilderRef builder, const DoStatement& d);

	void compileFor(LLVMBuilderRef builder, const ForStatement& f);

	void compileIf(LLVMBuilderRef builder, const IfStatement& i);

	void compileReturn(LLVMBuilderRef builder, const ReturnStatement& r);

	void compileVarDeclarations(LLVMBuilderRef builder, const VarDeclarationsStatement& decls);

	void compileWhile(LLVMBuilderRef builder, const WhileStatement& w);

	void compileStatement(LLVMBuilderRef builder, const Statement& stmt);

	// The "Vector" variants of functions attempt to compile a given expression or statement as part
	// of a vectorized SkJumper stage function - that is, with r, g, b, and a each being vectors of
	// fVectorCount floats. So a statement like "color.r = 0;" looks like it modifies a single
	// channel of a single pixel, but the compiled code will actually modify the red channel of
	// fVectorCount pixels at once.
	//
	// As not everything can be vectorized, these calls return a bool to indicate whether they were
	// successful. If anything anywhere in the function cannot be vectorized, the JIT will fall back
	// to looping over the pixels instead.
	//
	// Since we process multiple pixels at once, and each pixel consists of multiple color channels,
	// expressions may effectively result in a vector-of-vectors. We produce zero to four outputs
	// when compiling expression, each of which is a vector, so that e.g. float2(1, 0) actually
	// produces two vectors, one containing all 1s, the other all 0s. The out parameter always
	// allows for 4 channels, but the functions produce 0 to 4 channels depending on the type they
	// are operating on. Thus evaluating "color.rgb" actually fills in out[0] through out[2],
	// leaving out[3] uninitialized.
	// As the number of outputs can be inferred from the type of the expression, it is not
	// explicitly signalled anywhere.
	bool compileVectorBinary(LLVMBuilderRef builder, const BinaryExpression& b,
	LLVMValueRef out[CHANNELS]);

	bool compileVectorConstructor(LLVMBuilderRef builder, const Constructor& c,
	LLVMValueRef out[CHANNELS]);

	bool compileVectorFloatLiteral(LLVMBuilderRef builder, const FloatLiteral& f,
	LLVMValueRef out[CHANNELS]);

	bool compileVectorSwizzle(LLVMBuilderRef builder, const Swizzle& s,
	LLVMValueRef out[CHANNELS]);

	bool compileVectorVariableReference(LLVMBuilderRef builder, const VariableReference& v,
	LLVMValueRef out[CHANNELS]);

	bool compileVectorExpression(LLVMBuilderRef builder, const Expression& expr,
	LLVMValueRef out[CHANNELS]);

	bool getVectorLValue(LLVMBuilderRef builder, const Expression& e, LLVMValueRef out[CHANNELS]);

	/**
	* Evaluates the left and right operands of a binary operation, promoting one of them to a
	* vector if necessary to make the types match.
	*/
	bool getVectorBinaryOperands(LLVMBuilderRef builder, const Expression& left,
	LLVMValueRef outLeft[CHANNELS], const Expression& right,
	LLVMValueRef outRight[CHANNELS]);

	bool compileVectorStatement(LLVMBuilderRef builder, const Statement& stmt);

	/**
	* Returns true if this function has the signature void(int, int, inout float4) and thus can be
	* used as an SkJumper stage.
	*/
	bool hasStageSignature(const FunctionDeclaration& f);

	/**
	* Attempts to compile a vectorized stage function, returning true on success. A stage function
	* of e.g. "color.r = 0;" will produce code which sets the entire red vector to zeros in a
	* single instruction, thus calculating several pixels at once.
	*/
	bool compileStageFunctionVector(const FunctionDefinition& f, LLVMValueRef newFunc);

	/**
	* Fallback function which loops over the pixels, for when vectorization fails. A stage function
	* of e.g. "color.r = 0;" will produce a loop which iterates over the entries in the red vector,
	* setting each one to zero individually.
	*/
	void compileStageFunctionLoop(const FunctionDefinition& f, LLVMValueRef newFunc);

	/**
	* Called when compiling a function which has the signature of an SkJumper stage. Produces a
	* version of the function which can be plugged into SkJumper (thus having a signature which
	* accepts four vectors, one for each color channel, containing the color data of multiple
	* pixels at once). To go from SkSL code which operates on a single pixel at a time to CPU code
	* which operates on multiple pixels at once, the code is either vectorized using
	* compileStageFunctionVector or wrapped in a loop using compileStageFunctionLoop.
	*/
	LLVMValueRef compileStageFunction(const FunctionDefinition& f);

	/**
	* Compiles an SkSL function to an LLVM function. If the function has the signature of an
	* SkJumper stage, it will also be compiled by compileStageFunction, resulting in both a stage
	* and non-stage version of the function.
	*/
	LLVMValueRef compileFunction(const FunctionDefinition& f);

	void createModule();

	void optimize();

	bool isColorRef(const Expression& expr);

	static uint64_t resolveSymbol(const char* name, JIT* jit);

	const char* fCPU;
	int fVectorCount;
	Compiler& fCompiler;
	std::unique_ptr<Program> fProgram;
	LLVMContextRef fContext;
	LLVMModuleRef fModule;
	LLVMSharedModuleRef fSharedModule;
	LLVMOrcJITStackRef fJITStack;
	LLVMValueRef fCurrentFunction;
	LLVMBasicBlockRef fAllocaBlock;
	LLVMBasicBlockRef fCurrentBlock;
	LLVMTypeRef fVoidType;
	LLVMTypeRef fInt1Type;
	LLVMTypeRef fInt1VectorType;
	LLVMTypeRef fInt1Vector2Type;
	LLVMTypeRef fInt1Vector3Type;
	LLVMTypeRef fInt1Vector4Type;
	LLVMTypeRef fInt8Type;
	LLVMTypeRef fInt8PtrType;
	LLVMTypeRef fInt32Type;
	LLVMTypeRef fInt32VectorType;
	LLVMTypeRef fInt32Vector2Type;
	LLVMTypeRef fInt32Vector3Type;
	LLVMTypeRef fInt32Vector4Type;
	LLVMTypeRef fInt64Type;
	LLVMTypeRef fSizeTType;
	LLVMTypeRef fFloat32Type;
	LLVMTypeRef fFloat32VectorType;
	LLVMTypeRef fFloat32Vector2Type;
	LLVMTypeRef fFloat32Vector3Type;
	LLVMTypeRef fFloat32Vector4Type;
	// Our SkSL stage functions have a single float4 for color, but the actual SkJumper stage
	// function has four separate vectors, one for each channel. These four values are references to
	// the red, green, blue, and alpha vectors respectively.
	LLVMValueRef fChannels[CHANNELS];
	// when processing a stage function, this points to the SkSL color parameter (an inout float4)
	const Variable* fColorParam;
	std::unordered_map<const FunctionDeclaration*, LLVMValueRef> fFunctions;
	std::unordered_map<const Variable*, LLVMValueRef> fVariables;
	// LLVM function parameters are read-only, so when modifying function parameters we need to
	// first promote them to variables. This keeps track of which parameters have been promoted.
	std::set<const Variable*> fPromotedParameters;
	std::vector<LLVMBasicBlockRef> fBreakTarget;
	std::vector<LLVMBasicBlockRef> fContinueTarget;

	LLVMValueRef fFoldAnd2Func;
	LLVMValueRef fFoldOr2Func;
	LLVMValueRef fFoldAnd3Func;
	LLVMValueRef fFoldOr3Func;
	LLVMValueRef fFoldAnd4Func;
	LLVMValueRef fFoldOr4Func;
	LLVMValueRef fAppendFunc;
	LLVMValueRef fAppendCallbackFunc;
	LLVMValueRef fDebugFunc;
	};

	} // namespace

	#endif // SK_LLVM_AVAILABLE

	#endif // SKSL_JIT