/*
* 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_IRGENERATOR
#define SKSL_IRGENERATOR
#include "SkSLErrorReporter.h"
#include "ast/SkSLASTBinaryExpression.h"
#include "ast/SkSLASTBlock.h"
#include "ast/SkSLASTBreakStatement.h"
#include "ast/SkSLASTCallSuffix.h"
#include "ast/SkSLASTContinueStatement.h"
#include "ast/SkSLASTDiscardStatement.h"
#include "ast/SkSLASTDoStatement.h"
#include "ast/SkSLASTEnum.h"
#include "ast/SkSLASTExpression.h"
#include "ast/SkSLASTExpressionStatement.h"
#include "ast/SkSLASTExtension.h"
#include "ast/SkSLASTForStatement.h"
#include "ast/SkSLASTFunction.h"
#include "ast/SkSLASTIdentifier.h"
#include "ast/SkSLASTIfStatement.h"
#include "ast/SkSLASTInterfaceBlock.h"
#include "ast/SkSLASTModifiersDeclaration.h"
#include "ast/SkSLASTPrefixExpression.h"
#include "ast/SkSLASTReturnStatement.h"
#include "ast/SkSLASTSection.h"
#include "ast/SkSLASTStatement.h"
#include "ast/SkSLASTSuffixExpression.h"
#include "ast/SkSLASTSwitchStatement.h"
#include "ast/SkSLASTTernaryExpression.h"
#include "ast/SkSLASTVarDeclaration.h"
#include "ast/SkSLASTVarDeclarationStatement.h"
#include "ast/SkSLASTWhileStatement.h"
#include "ir/SkSLBlock.h"
#include "ir/SkSLExpression.h"
#include "ir/SkSLExtension.h"
#include "ir/SkSLFunctionDefinition.h"
#include "ir/SkSLInterfaceBlock.h"
#include "ir/SkSLModifiers.h"
#include "ir/SkSLModifiersDeclaration.h"
#include "ir/SkSLProgram.h"
#include "ir/SkSLSection.h"
#include "ir/SkSLSymbolTable.h"
#include "ir/SkSLStatement.h"
#include "ir/SkSLType.h"
#include "ir/SkSLTypeReference.h"
#include "ir/SkSLVarDeclarations.h"
namespace SkSL {
/**
* Performs semantic analysis on an abstract syntax tree (AST) and produces the corresponding
* (unoptimized) intermediate representation (IR).
*/
class IRGenerator {
public:
IRGenerator(const Context* context, std::shared_ptr<SymbolTable> root,
ErrorReporter& errorReporter);
void convertProgram(Program::Kind kind,
const char* text,
size_t length,
SymbolTable& types,
std::vector<std::unique_ptr<ProgramElement>>* result);
/**
* If both operands are compile-time constants and can be folded, returns an expression
* representing the folded value. Otherwise, returns null. Note that unlike most other functions
* here, null does not represent a compilation error.
*/
std::unique_ptr<Expression> constantFold(const Expression& left,
Token::Kind op,
const Expression& right) const;
Program::Inputs fInputs;
const Program::Settings* fSettings;
const Context& fContext;
private:
/**
* Prepare to compile a program. Resets state, pushes a new symbol table, and installs the
* settings.
*/
void start(const Program::Settings* settings);
/**
* Performs cleanup after compilation is complete.
*/
void finish();
void pushSymbolTable();
void popSymbolTable();
std::unique_ptr<VarDeclarations> convertVarDeclarations(const ASTVarDeclarations& decl,
Variable::Storage storage);
void convertFunction(const ASTFunction& f);
std::unique_ptr<Statement> convertStatement(const ASTStatement& statement);
std::unique_ptr<Expression> convertExpression(const ASTExpression& expression);
std::unique_ptr<ModifiersDeclaration> convertModifiersDeclaration(
const ASTModifiersDeclaration& m);
const Type* convertType(const ASTType& type);
std::unique_ptr<Expression> call(int offset,
const FunctionDeclaration& function,
std::vector<std::unique_ptr<Expression>> arguments);
int callCost(const FunctionDeclaration& function,
const std::vector<std::unique_ptr<Expression>>& arguments);
std::unique_ptr<Expression> call(int offset, std::unique_ptr<Expression> function,
std::vector<std::unique_ptr<Expression>> arguments);
int coercionCost(const Expression& expr, const Type& type);
std::unique_ptr<Expression> coerce(std::unique_ptr<Expression> expr, const Type& type);
std::unique_ptr<Block> convertBlock(const ASTBlock& block);
std::unique_ptr<Statement> convertBreak(const ASTBreakStatement& b);
std::unique_ptr<Expression> convertNumberConstructor(
int offset,
const Type& type,
std::vector<std::unique_ptr<Expression>> params);
std::unique_ptr<Expression> convertCompoundConstructor(
int offset,
const Type& type,
std::vector<std::unique_ptr<Expression>> params);
std::unique_ptr<Expression> convertConstructor(int offset,
const Type& type,
std::vector<std::unique_ptr<Expression>> params);
std::unique_ptr<Statement> convertContinue(const ASTContinueStatement& c);
std::unique_ptr<Statement> convertDiscard(const ASTDiscardStatement& d);
std::unique_ptr<Statement> convertDo(const ASTDoStatement& d);
std::unique_ptr<Statement> convertSwitch(const ASTSwitchStatement& s);
std::unique_ptr<Expression> convertBinaryExpression(const ASTBinaryExpression& expression);
std::unique_ptr<Extension> convertExtension(const ASTExtension& e);
std::unique_ptr<Statement> convertExpressionStatement(const ASTExpressionStatement& s);
std::unique_ptr<Statement> convertFor(const ASTForStatement& f);
std::unique_ptr<Expression> convertIdentifier(const ASTIdentifier& identifier);
std::unique_ptr<Statement> convertIf(const ASTIfStatement& s);
std::unique_ptr<Expression> convertIndex(std::unique_ptr<Expression> base,
const ASTExpression& index);
std::unique_ptr<InterfaceBlock> convertInterfaceBlock(const ASTInterfaceBlock& s);
Modifiers convertModifiers(const Modifiers& m);
std::unique_ptr<Expression> convertPrefixExpression(const ASTPrefixExpression& expression);
std::unique_ptr<Statement> convertReturn(const ASTReturnStatement& r);
std::unique_ptr<Section> convertSection(const ASTSection& e);
std::unique_ptr<Expression> getCap(int offset, String name);
std::unique_ptr<Expression> getArg(int offset, String name);
std::unique_ptr<Expression> convertSuffixExpression(const ASTSuffixExpression& expression);
std::unique_ptr<Expression> convertTypeField(int offset, const Type& type,
StringFragment field);
std::unique_ptr<Expression> convertField(std::unique_ptr<Expression> base,
StringFragment field);
std::unique_ptr<Expression> convertSwizzle(std::unique_ptr<Expression> base,
StringFragment fields);
std::unique_ptr<Expression> convertTernaryExpression(const ASTTernaryExpression& expression);
std::unique_ptr<Statement> convertVarDeclarationStatement(const ASTVarDeclarationStatement& s);
std::unique_ptr<Statement> convertWhile(const ASTWhileStatement& w);
void convertEnum(const ASTEnum& e);
std::unique_ptr<Block> applyInvocationIDWorkaround(std::unique_ptr<Block> main);
// returns a statement which converts sk_Position from device to normalized coordinates
std::unique_ptr<Statement> getNormalizeSkPositionCode();
void fixRectSampling(std::vector<std::unique_ptr<Expression>>& arguments);
void checkValid(const Expression& expr);
void markWrittenTo(const Expression& expr, bool readWrite);
void getConstantInt(const Expression& value, int64_t* out);
Program::Kind fKind;
const FunctionDeclaration* fCurrentFunction;
std::unordered_map<String, Program::Settings::Value> fCapsMap;
std::shared_ptr<SymbolTable> fRootSymbolTable;
std::shared_ptr<SymbolTable> fSymbolTable;
// holds extra temp variable declarations needed for the current function
std::vector<std::unique_ptr<Statement>> fExtraVars;
int fLoopLevel;
int fSwitchLevel;
// count of temporary variables we have created
int fTmpCount;
ErrorReporter& fErrors;
int fInvocations;
std::vector<std::unique_ptr<ProgramElement>>* fProgramElements;
Variable* fSkPerVertex;
Variable* fRTAdjust;
Variable* fRTAdjustInterfaceBlock;
int fRTAdjustFieldIndex;
friend class AutoSymbolTable;
friend class AutoLoopLevel;
friend class AutoSwitchLevel;
friend class Compiler;
};
}
#endif