mirror of
https://github.com/ethereum/solidity
synced 2023-10-03 13:03:40 +00:00
512 lines
14 KiB
C++
512 lines
14 KiB
C++
/*
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This file is part of cpp-ethereum.
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cpp-ethereum is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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cpp-ethereum is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with cpp-ethereum. If not, see <http://www.gnu.org/licenses/>.
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*/
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/**
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* @author Christian <c@ethdev.com>
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* @date 2014
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* Solidity abstract syntax tree.
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*/
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#include <algorithm>
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#include <libsolidity/AST.h>
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#include <libsolidity/ASTVisitor.h>
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#include <libsolidity/Exceptions.h>
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using namespace std;
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namespace dev
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{
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namespace solidity
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{
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void ContractDefinition::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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listAccept(m_definedStructs, _visitor);
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listAccept(m_stateVariables, _visitor);
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listAccept(m_definedFunctions, _visitor);
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}
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_visitor.endVisit(*this);
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}
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void StructDefinition::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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listAccept(m_members, _visitor);
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_visitor.endVisit(*this);
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}
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void ParameterList::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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listAccept(m_parameters, _visitor);
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_visitor.endVisit(*this);
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}
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void FunctionDefinition::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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m_parameters->accept(_visitor);
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if (m_returnParameters)
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m_returnParameters->accept(_visitor);
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m_body->accept(_visitor);
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}
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_visitor.endVisit(*this);
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}
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void VariableDeclaration::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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if (m_typeName)
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m_typeName->accept(_visitor);
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_visitor.endVisit(*this);
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}
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void TypeName::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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void ElementaryTypeName::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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void UserDefinedTypeName::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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void Mapping::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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m_keyType->accept(_visitor);
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m_valueType->accept(_visitor);
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}
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_visitor.endVisit(*this);
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}
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void Statement::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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void Block::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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listAccept(m_statements, _visitor);
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_visitor.endVisit(*this);
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}
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void IfStatement::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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m_condition->accept(_visitor);
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m_trueBody->accept(_visitor);
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if (m_falseBody)
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m_falseBody->accept(_visitor);
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}
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_visitor.endVisit(*this);
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}
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void BreakableStatement::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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void WhileStatement::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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m_condition->accept(_visitor);
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m_body->accept(_visitor);
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}
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_visitor.endVisit(*this);
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}
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void Continue::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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void Break::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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void Return::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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if (m_expression)
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m_expression->accept(_visitor);
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_visitor.endVisit(*this);
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}
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void ExpressionStatement::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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if (m_expression)
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m_expression->accept(_visitor);
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_visitor.endVisit(*this);
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}
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void VariableDefinition::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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m_variable->accept(_visitor);
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if (m_value)
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m_value->accept(_visitor);
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}
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_visitor.endVisit(*this);
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}
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void Assignment::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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m_leftHandSide->accept(_visitor);
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m_rightHandSide->accept(_visitor);
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}
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_visitor.endVisit(*this);
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}
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void UnaryOperation::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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m_subExpression->accept(_visitor);
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_visitor.endVisit(*this);
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}
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void BinaryOperation::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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m_left->accept(_visitor);
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m_right->accept(_visitor);
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}
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_visitor.endVisit(*this);
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}
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void FunctionCall::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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m_expression->accept(_visitor);
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listAccept(m_arguments, _visitor);
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}
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_visitor.endVisit(*this);
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}
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void MemberAccess::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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m_expression->accept(_visitor);
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_visitor.endVisit(*this);
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}
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void IndexAccess::accept(ASTVisitor& _visitor)
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{
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if (_visitor.visit(*this))
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{
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m_base->accept(_visitor);
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m_index->accept(_visitor);
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}
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_visitor.endVisit(*this);
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}
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void Identifier::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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void ElementaryTypeNameExpression::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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void Literal::accept(ASTVisitor& _visitor)
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{
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_visitor.visit(*this);
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_visitor.endVisit(*this);
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}
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TypeError ASTNode::createTypeError(string const& _description)
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{
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return TypeError() << errinfo_sourceLocation(getLocation()) << errinfo_comment(_description);
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}
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void Block::checkTypeRequirements()
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{
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for (shared_ptr<Statement> const& statement: m_statements)
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statement->checkTypeRequirements();
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}
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void IfStatement::checkTypeRequirements()
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{
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m_condition->expectType(BoolType());
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m_trueBody->checkTypeRequirements();
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if (m_falseBody)
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m_falseBody->checkTypeRequirements();
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}
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void WhileStatement::checkTypeRequirements()
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{
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m_condition->expectType(BoolType());
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m_body->checkTypeRequirements();
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}
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void Continue::checkTypeRequirements()
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{
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}
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void Break::checkTypeRequirements()
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{
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}
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void Return::checkTypeRequirements()
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{
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if (!m_expression)
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return;
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if (asserts(m_returnParameters))
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BOOST_THROW_EXCEPTION(InternalCompilerError() << errinfo_comment("Return parameters not assigned."));
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if (m_returnParameters->getParameters().size() != 1)
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BOOST_THROW_EXCEPTION(createTypeError("Different number of arguments in return statement "
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"than in returns declaration."));
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// this could later be changed such that the paramaters type is an anonymous struct type,
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// but for now, we only allow one return parameter
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m_expression->expectType(*m_returnParameters->getParameters().front()->getType());
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}
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void VariableDefinition::checkTypeRequirements()
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{
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// Variables can be declared without type (with "var"), in which case the first assignment
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// setsthe type.
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// Note that assignments before the first declaration are legal because of the special scoping
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// rules inherited from JavaScript.
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if (m_value)
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{
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if (m_variable->getType())
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m_value->expectType(*m_variable->getType());
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else
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{
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// no type declared and no previous assignment, infer the type
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m_value->checkTypeRequirements();
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m_variable->setType(m_value->getType());
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}
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}
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}
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void Assignment::checkTypeRequirements()
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{
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//@todo lefthandside actually has to be assignable
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// add a feature to the type system to check that
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m_leftHandSide->checkTypeRequirements();
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if (!m_leftHandSide->isLvalue())
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BOOST_THROW_EXCEPTION(createTypeError("Expression has to be an lvalue."));
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m_rightHandSide->expectType(*m_leftHandSide->getType());
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m_type = m_leftHandSide->getType();
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if (m_assigmentOperator != Token::ASSIGN)
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// compound assignment
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if (!m_type->acceptsBinaryOperator(Token::AssignmentToBinaryOp(m_assigmentOperator)))
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BOOST_THROW_EXCEPTION(createTypeError("Operator not compatible with type."));
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}
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void ExpressionStatement::checkTypeRequirements()
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{
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m_expression->checkTypeRequirements();
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}
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void Expression::expectType(Type const& _expectedType)
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{
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checkTypeRequirements();
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const Type& type = *getType();
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if (!type.isImplicitlyConvertibleTo(_expectedType))
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BOOST_THROW_EXCEPTION(createTypeError("Type " + type.toString() +
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" not implicitly convertible to expected type "
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+ _expectedType.toString() + "."));
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}
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void UnaryOperation::checkTypeRequirements()
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{
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// INC, DEC, ADD, SUB, NOT, BIT_NOT, DELETE
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m_subExpression->checkTypeRequirements();
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if (m_operator == Token::Value::INC || m_operator == Token::Value::DEC || m_operator == Token::Value::DELETE)
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if (!m_subExpression->isLvalue())
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BOOST_THROW_EXCEPTION(createTypeError("Expression has to be an lvalue."));
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m_type = m_subExpression->getType();
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if (!m_type->acceptsUnaryOperator(m_operator))
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BOOST_THROW_EXCEPTION(createTypeError("Unary operator not compatible with type."));
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}
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void BinaryOperation::checkTypeRequirements()
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{
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m_right->checkTypeRequirements();
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m_left->checkTypeRequirements();
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if (m_right->getType()->isImplicitlyConvertibleTo(*m_left->getType()))
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m_commonType = m_left->getType();
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else if (m_left->getType()->isImplicitlyConvertibleTo(*m_right->getType()))
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m_commonType = m_right->getType();
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else
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BOOST_THROW_EXCEPTION(createTypeError("No common type found in binary operation: " +
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m_left->getType()->toString() + " vs. " +
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m_right->getType()->toString()));
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if (Token::isCompareOp(m_operator))
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m_type = make_shared<BoolType>();
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else
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{
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m_type = m_commonType;
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if (!m_commonType->acceptsBinaryOperator(m_operator))
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BOOST_THROW_EXCEPTION(createTypeError("Operator " + string(Token::toString(m_operator)) +
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" not compatible with type " +
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m_commonType->toString()));
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}
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}
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void FunctionCall::checkTypeRequirements()
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{
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m_expression->checkTypeRequirements();
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for (ASTPointer<Expression> const& argument: m_arguments)
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argument->checkTypeRequirements();
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Type const* expressionType = m_expression->getType().get();
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if (isTypeConversion())
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{
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TypeType const& type = dynamic_cast<TypeType const&>(*expressionType);
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//@todo for structs, we have to check the number of arguments to be equal to the
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// number of non-mapping members
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if (m_arguments.size() != 1)
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BOOST_THROW_EXCEPTION(createTypeError("More than one argument for "
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"explicit type conersion."));
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if (!m_arguments.front()->getType()->isExplicitlyConvertibleTo(*type.getActualType()))
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BOOST_THROW_EXCEPTION(createTypeError("Explicit type conversion not allowed."));
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m_type = type.getActualType();
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}
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else
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{
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//@todo would be nice to create a struct type from the arguments
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// and then ask if that is implicitly convertible to the struct represented by the
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// function parameters
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FunctionDefinition const& fun = dynamic_cast<FunctionType const&>(*expressionType).getFunction();
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vector<ASTPointer<VariableDeclaration>> const& parameters = fun.getParameters();
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if (parameters.size() != m_arguments.size())
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BOOST_THROW_EXCEPTION(createTypeError("Wrong argument count for function call."));
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for (size_t i = 0; i < m_arguments.size(); ++i)
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if (!m_arguments[i]->getType()->isImplicitlyConvertibleTo(*parameters[i]->getType()))
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BOOST_THROW_EXCEPTION(createTypeError("Invalid type for argument in function call."));
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// @todo actually the return type should be an anonymous struct,
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// but we change it to the type of the first return value until we have structs
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if (fun.getReturnParameters().empty())
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m_type = make_shared<VoidType>();
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else
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m_type = fun.getReturnParameters().front()->getType();
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}
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}
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bool FunctionCall::isTypeConversion() const
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{
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return m_expression->getType()->getCategory() == Type::Category::TYPE;
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}
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void MemberAccess::checkTypeRequirements()
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{
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BOOST_THROW_EXCEPTION(InternalCompilerError() << errinfo_comment("Member access not yet implemented."));
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// m_type = ;
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}
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void IndexAccess::checkTypeRequirements()
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{
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BOOST_THROW_EXCEPTION(InternalCompilerError() << errinfo_comment("Index access not yet implemented."));
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// m_type = ;
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}
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void Identifier::checkTypeRequirements()
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{
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if (asserts(m_referencedDeclaration))
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BOOST_THROW_EXCEPTION(InternalCompilerError() << errinfo_comment("Identifier not resolved."));
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//@todo these dynamic casts here are not really nice...
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// is i useful to have an AST visitor here?
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// or can this already be done in NameAndTypeResolver?
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// the only problem we get there is that in
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// var x;
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// x = 2;
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// var y = x;
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// the type of x is not yet determined.
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VariableDeclaration* variable = dynamic_cast<VariableDeclaration*>(m_referencedDeclaration);
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if (variable)
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{
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if (!variable->getType())
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BOOST_THROW_EXCEPTION(createTypeError("Variable referenced before type could be determined."));
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m_type = variable->getType();
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m_isLvalue = true;
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return;
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}
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//@todo can we unify these with TypeName::toType()?
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StructDefinition* structDef = dynamic_cast<StructDefinition*>(m_referencedDeclaration);
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if (structDef)
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{
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// note that we do not have a struct type here
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m_type = make_shared<TypeType>(make_shared<StructType>(*structDef));
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return;
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}
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FunctionDefinition* functionDef = dynamic_cast<FunctionDefinition*>(m_referencedDeclaration);
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if (functionDef)
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{
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// a function reference is not a TypeType, because calling a TypeType converts to the type.
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// Calling a function (e.g. function(12), otherContract.function(34)) does not do a type
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// conversion.
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m_type = make_shared<FunctionType>(*functionDef);
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return;
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}
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ContractDefinition* contractDef = dynamic_cast<ContractDefinition*>(m_referencedDeclaration);
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if (contractDef)
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{
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m_type = make_shared<TypeType>(make_shared<ContractType>(*contractDef));
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return;
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}
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BOOST_THROW_EXCEPTION(InternalCompilerError() << errinfo_comment("Declaration reference of unknown/forbidden type."));
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}
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void ElementaryTypeNameExpression::checkTypeRequirements()
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{
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m_type = make_shared<TypeType>(Type::fromElementaryTypeName(m_typeToken));
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}
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void Literal::checkTypeRequirements()
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{
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m_type = Type::forLiteral(*this);
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if (!m_type)
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BOOST_THROW_EXCEPTION(createTypeError("Literal value too large."));
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}
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}
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}
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