/*
This file is part of cpp-ethereum.
cpp-ethereum is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
cpp-ethereum is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with cpp-ethereum. If not, see .
*/
/**
* @author Christian
* @date 2014
* Solidity parser.
*/
#include
#include
#include
#include
#include
namespace dev {
namespace solidity {
ptr Parser::parse(std::shared_ptr const& _scanner)
{
m_scanner = _scanner;
return parseContractDefinition();
}
/// AST node factory that also tracks the begin and end position of an AST node
/// while it is being parsed
class Parser::ASTNodeFactory
{
public:
ASTNodeFactory(const Parser& _parser)
: m_parser(_parser), m_location(_parser.getPosition(), -1)
{}
void markEndPosition() { m_location.end = m_parser.getEndPosition(); }
void setLocationEmpty() { m_location.end = m_location.start; }
/// Set the end position to the one of the given node.
void setEndPositionFromNode(const ptr& _node)
{
m_location.end = _node->getLocation().end;
}
/// @todo: check that this actually uses perfect forwarding
template
ptr createNode(Args&&... _args)
{
if (m_location.end < 0)
markEndPosition();
return std::make_shared(m_location, std::forward(_args)...);
}
private:
const Parser& m_parser;
Location m_location;
};
int Parser::getPosition() const
{
return m_scanner->getCurrentLocation().start;
}
int Parser::getEndPosition() const
{
return m_scanner->getCurrentLocation().end;
}
ptr Parser::parseContractDefinition()
{
ASTNodeFactory nodeFactory(*this);
expectToken(Token::CONTRACT);
ptr name = expectIdentifierToken();
expectToken(Token::LBRACE);
vecptr structs;
vecptr stateVariables;
vecptr functions;
bool visibilityIsPublic = true;
while (true) {
Token::Value currentToken = m_scanner->getCurrentToken();
if (currentToken == Token::RBRACE) {
break;
} else if (currentToken == Token::PUBLIC || currentToken == Token::PRIVATE) {
visibilityIsPublic = (m_scanner->getCurrentToken() == Token::PUBLIC);
m_scanner->next();
expectToken(Token::COLON);
} else if (currentToken == Token::FUNCTION) {
functions.push_back(parseFunctionDefinition(visibilityIsPublic));
} else if (currentToken == Token::STRUCT) {
structs.push_back(parseStructDefinition());
} else if (currentToken == Token::IDENTIFIER || currentToken == Token::MAPPING ||
Token::IsElementaryTypeName(currentToken)) {
bool const allowVar = false;
stateVariables.push_back(parseVariableDeclaration(allowVar));
expectToken(Token::SEMICOLON);
} else {
throwExpectationError("Function, variable or struct declaration expected.");
}
}
nodeFactory.markEndPosition();
expectToken(Token::RBRACE);
expectToken(Token::EOS);
return nodeFactory.createNode(name, structs, stateVariables, functions);
}
ptr Parser::parseFunctionDefinition(bool _isPublic)
{
ASTNodeFactory nodeFactory(*this);
expectToken(Token::FUNCTION);
ptr name(expectIdentifierToken());
ptr parameters(parseParameterList());
bool isDeclaredConst = false;
if (m_scanner->getCurrentToken() == Token::CONST) {
isDeclaredConst = true;
m_scanner->next();
}
ptr returnParameters;
if (m_scanner->getCurrentToken() == Token::RETURNS) {
const bool permitEmptyParameterList = false;
m_scanner->next();
returnParameters = parseParameterList(permitEmptyParameterList);
} else {
// create an empty parameter list at a zero-length location
ASTNodeFactory nodeFactory(*this);
nodeFactory.setLocationEmpty();
returnParameters = nodeFactory.createNode(vecptr());
}
ptr block = parseBlock();
nodeFactory.setEndPositionFromNode(block);
return nodeFactory.createNode(name, _isPublic, parameters,
isDeclaredConst, returnParameters, block);
}
ptr Parser::parseStructDefinition()
{
ASTNodeFactory nodeFactory(*this);
expectToken(Token::STRUCT);
ptr name = expectIdentifierToken();
vecptr members;
expectToken(Token::LBRACE);
while (m_scanner->getCurrentToken() != Token::RBRACE) {
bool const allowVar = false;
members.push_back(parseVariableDeclaration(allowVar));
expectToken(Token::SEMICOLON);
}
nodeFactory.markEndPosition();
expectToken(Token::RBRACE);
return nodeFactory.createNode(name, members);
}
ptr Parser::parseVariableDeclaration(bool _allowVar)
{
ASTNodeFactory nodeFactory(*this);
ptr type = parseTypeName(_allowVar);
nodeFactory.markEndPosition();
return nodeFactory.createNode(type, expectIdentifierToken());
}
ptr Parser::parseTypeName(bool _allowVar)
{
ptr type;
Token::Value token = m_scanner->getCurrentToken();
if (Token::IsElementaryTypeName(token)) {
type = ASTNodeFactory(*this).createNode(token);
m_scanner->next();
} else if (token == Token::VAR) {
if (!_allowVar)
throwExpectationError("Expected explicit type name.");
m_scanner->next();
} else if (token == Token::MAPPING) {
type = parseMapping();
} else if (token == Token::IDENTIFIER) {
ASTNodeFactory nodeFactory(*this);
nodeFactory.markEndPosition();
type = nodeFactory.createNode(expectIdentifierToken());
} else {
throwExpectationError("Expected type name");
}
return type;
}
ptr Parser::parseMapping()
{
ASTNodeFactory nodeFactory(*this);
expectToken(Token::MAPPING);
expectToken(Token::LPAREN);
if (!Token::IsElementaryTypeName(m_scanner->getCurrentToken()))
throwExpectationError("Expected elementary type name for mapping key type");
ptr keyType;
keyType = ASTNodeFactory(*this).createNode(m_scanner->getCurrentToken());
m_scanner->next();
expectToken(Token::ARROW);
bool const allowVar = false;
ptr valueType = parseTypeName(allowVar);
nodeFactory.markEndPosition();
expectToken(Token::RPAREN);
return nodeFactory.createNode(keyType, valueType);
}
ptr Parser::parseParameterList(bool _allowEmpty)
{
ASTNodeFactory nodeFactory(*this);
vecptr parameters;
expectToken(Token::LPAREN);
if (!_allowEmpty || m_scanner->getCurrentToken() != Token::RPAREN) {
bool const allowVar = false;
parameters.push_back(parseVariableDeclaration(allowVar));
while (m_scanner->getCurrentToken() != Token::RPAREN) {
expectToken(Token::COMMA);
parameters.push_back(parseVariableDeclaration(allowVar));
}
}
nodeFactory.markEndPosition();
m_scanner->next();
return nodeFactory.createNode(parameters);
}
ptr Parser::parseBlock()
{
ASTNodeFactory nodeFactory(*this);
expectToken(Token::LBRACE);
vecptr statements;
while (m_scanner->getCurrentToken() != Token::RBRACE) {
statements.push_back(parseStatement());
}
nodeFactory.markEndPosition();
expectToken(Token::RBRACE);
return nodeFactory.createNode(statements);
}
ptr Parser::parseStatement()
{
ptr statement;
switch (m_scanner->getCurrentToken()) {
case Token::IF:
return parseIfStatement();
case Token::WHILE:
return parseWhileStatement();
case Token::LBRACE:
return parseBlock();
// starting from here, all statements must be terminated by a semicolon
case Token::CONTINUE:
statement = ASTNodeFactory(*this).createNode();
break;
case Token::BREAK:
statement = ASTNodeFactory(*this).createNode();
break;
case Token::RETURN:
{
ASTNodeFactory nodeFactory(*this);
ptr expression;
if (m_scanner->next() != Token::SEMICOLON) {
expression = parseExpression();
nodeFactory.setEndPositionFromNode(expression);
}
statement = nodeFactory.createNode(expression);
}
break;
default:
// distinguish between variable definition (and potentially assignment) and expressions
// (which include assignments to other expressions and pre-declared variables)
// We have a variable definition if we ge a keyword that specifies a type name, or
// in the case of a user-defined type, we have two identifiers following each other.
if (m_scanner->getCurrentToken() == Token::MAPPING ||
m_scanner->getCurrentToken() == Token::VAR ||
Token::IsElementaryTypeName(m_scanner->getCurrentToken()) ||
(m_scanner->getCurrentToken() == Token::IDENTIFIER &&
m_scanner->peek() == Token::IDENTIFIER)) {
statement = parseVariableDefinition();
} else {
// "ordinary" expression
statement = parseExpression();
}
}
expectToken(Token::SEMICOLON);
return statement;
}
ptr Parser::parseIfStatement()
{
ASTNodeFactory nodeFactory(*this);
expectToken(Token::IF);
expectToken(Token::LPAREN);
ptr condition = parseExpression();
expectToken(Token::RPAREN);
ptr trueBody = parseStatement();
ptr falseBody;
if (m_scanner->getCurrentToken() == Token::ELSE) {
m_scanner->next();
falseBody = parseStatement();
nodeFactory.setEndPositionFromNode(falseBody);
} else {
nodeFactory.setEndPositionFromNode(trueBody);
}
return nodeFactory.createNode(condition, trueBody, falseBody);
}
ptr Parser::parseWhileStatement()
{
ASTNodeFactory nodeFactory(*this);
expectToken(Token::WHILE);
expectToken(Token::LPAREN);
ptr condition = parseExpression();
expectToken(Token::RPAREN);
ptr body = parseStatement();
nodeFactory.setEndPositionFromNode(body);
return nodeFactory.createNode(condition, body);
}
ptr Parser::parseVariableDefinition()
{
ASTNodeFactory nodeFactory(*this);
bool const allowVar = true;
ptr variable = parseVariableDeclaration(allowVar);
ptr value;
if (m_scanner->getCurrentToken() == Token::ASSIGN) {
m_scanner->next();
value = parseExpression();
nodeFactory.setEndPositionFromNode(value);
} else {
nodeFactory.setEndPositionFromNode(variable);
}
return nodeFactory.createNode(variable, value);
}
ptr Parser::parseExpression()
{
ASTNodeFactory nodeFactory(*this);
ptr expression = parseBinaryExpression();
if (!Token::IsAssignmentOp(m_scanner->getCurrentToken()))
return expression;
Token::Value assignmentOperator = expectAssignmentOperator();
ptr rightHandSide = parseExpression();
nodeFactory.setEndPositionFromNode(rightHandSide);
return nodeFactory.createNode(expression, assignmentOperator, rightHandSide);
}
ptr Parser::parseBinaryExpression(int _minPrecedence)
{
ASTNodeFactory nodeFactory(*this);
ptr expression = parseUnaryExpression();
int precedence = Token::Precedence(m_scanner->getCurrentToken());
for (; precedence >= _minPrecedence; --precedence) {
while (Token::Precedence(m_scanner->getCurrentToken()) == precedence) {
Token::Value op = m_scanner->getCurrentToken();
m_scanner->next();
ptr right = parseBinaryExpression(precedence + 1);
nodeFactory.setEndPositionFromNode(right);
expression = nodeFactory.createNode(expression, op, right);
}
}
return expression;
}
ptr Parser::parseUnaryExpression()
{
ASTNodeFactory nodeFactory(*this);
Token::Value token = m_scanner->getCurrentToken();
if (Token::IsUnaryOp(token) || Token::IsCountOp(token)) {
// prefix expression
m_scanner->next();
ptr subExpression = parseUnaryExpression();
nodeFactory.setEndPositionFromNode(subExpression);
return nodeFactory.createNode(token, subExpression, true);
} else {
// potential postfix expression
ptr subExpression = parseLeftHandSideExpression();
token = m_scanner->getCurrentToken();
if (!Token::IsCountOp(token))
return subExpression;
nodeFactory.markEndPosition();
m_scanner->next();
return nodeFactory.createNode(token, subExpression, false);
}
}
ptr Parser::parseLeftHandSideExpression()
{
ASTNodeFactory nodeFactory(*this);
ptr expression = parsePrimaryExpression();
while (true) {
switch (m_scanner->getCurrentToken()) {
case Token::LBRACK:
{
m_scanner->next();
ptr index = parseExpression();
nodeFactory.markEndPosition();
expectToken(Token::RBRACK);
expression = nodeFactory.createNode(expression, index);
}
break;
case Token::PERIOD:
{
m_scanner->next();
nodeFactory.markEndPosition();
expression = nodeFactory.createNode(expression, expectIdentifierToken());
}
break;
case Token::LPAREN:
{
m_scanner->next();
vecptr arguments = parseFunctionCallArguments();
nodeFactory.markEndPosition();
expectToken(Token::RPAREN);
expression = nodeFactory.createNode(expression, arguments);
}
break;
default:
return expression;
}
}
}
ptr Parser::parsePrimaryExpression()
{
ASTNodeFactory nodeFactory(*this);
Token::Value token = m_scanner->getCurrentToken();
ptr expression;
switch (token) {
case Token::TRUE_LITERAL:
case Token::FALSE_LITERAL:
expression = nodeFactory.createNode(token, ptr());
m_scanner->next();
break;
case Token::NUMBER:
case Token::STRING_LITERAL:
nodeFactory.markEndPosition();
expression = nodeFactory.createNode(token, getLiteralAndAdvance());
break;
case Token::IDENTIFIER:
nodeFactory.markEndPosition();
expression = nodeFactory.createNode(getLiteralAndAdvance());
break;
case Token::LPAREN:
{
m_scanner->next();
ptr expression = parseExpression();
expectToken(Token::RPAREN);
return expression;
}
default:
if (Token::IsElementaryTypeName(token)) {
// used for casts
expression = nodeFactory.createNode(token);
m_scanner->next();
} else {
throwExpectationError("Expected primary expression.");
return ptr(); // this is not reached
}
}
return expression;
}
vecptr Parser::parseFunctionCallArguments()
{
vecptr arguments;
if (m_scanner->getCurrentToken() != Token::RPAREN) {
arguments.push_back(parseExpression());
while (m_scanner->getCurrentToken() != Token::RPAREN) {
expectToken(Token::COMMA);
arguments.push_back(parseExpression());
}
}
return arguments;
}
void Parser::expectToken(Token::Value _value)
{
if (m_scanner->getCurrentToken() != _value)
throwExpectationError(std::string("Expected token ") + std::string(Token::Name(_value)));
m_scanner->next();
}
Token::Value Parser::expectAssignmentOperator()
{
Token::Value op = m_scanner->getCurrentToken();
if (!Token::IsAssignmentOp(op))
throwExpectationError(std::string("Expected assignment operator"));
m_scanner->next();
return op;
}
ptr Parser::expectIdentifierToken()
{
if (m_scanner->getCurrentToken() != Token::IDENTIFIER)
throwExpectationError("Expected identifier");
return getLiteralAndAdvance();
}
ptr Parser::getLiteralAndAdvance()
{
ptr identifier = std::make_shared(m_scanner->getCurrentLiteral());
m_scanner->next();
return identifier;
}
void Parser::throwExpectationError(const std::string& _description)
{
//@todo put some of this stuff into ParserError
int line, column;
std::tie(line, column) = m_scanner->translatePositionToLineColumn(getPosition());
std::stringstream buf;
buf << "Solidity parser error: " << _description
<< " at line " << (line + 1)
<< ", column " << (column + 1) << "\n"
<< m_scanner->getLineAtPosition(getPosition()) << "\n"
<< std::string(column, ' ') << "^";
BOOST_THROW_EXCEPTION(ParserError() << errinfo_comment(buf.str()));
}
} }