mirror of
https://github.com/ethereum/solidity
synced 2023-10-03 13:03:40 +00:00
409 lines
11 KiB
C++
409 lines
11 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 AST to EVM bytecode compiler.
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*/
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#include <boost/assert.hpp>
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#include <utility>
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#include <libsolidity/AST.h>
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#include <libsolidity/Compiler.h>
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namespace dev {
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namespace solidity {
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void CompilerContext::setLabelPosition(uint32_t _label, uint32_t _position)
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{
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BOOST_ASSERT(m_labelPositions.find(_label) == m_labelPositions.end());
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m_labelPositions[_label] = _position;
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}
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uint32_t CompilerContext::getLabelPosition(uint32_t _label) const
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{
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auto iter = m_labelPositions.find(_label);
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BOOST_ASSERT(iter != m_labelPositions.end());
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return iter->second;
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}
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void ExpressionCompiler::compile(Expression& _expression)
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{
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m_assemblyItems.clear();
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_expression.accept(*this);
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}
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bytes ExpressionCompiler::getAssembledBytecode() const
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{
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bytes assembled;
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assembled.reserve(m_assemblyItems.size());
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// resolve label references
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for (uint32_t pos = 0; pos < m_assemblyItems.size(); ++pos)
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{
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AssemblyItem const& item = m_assemblyItems[pos];
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if (item.getType() == AssemblyItem::Type::LABEL)
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m_context.setLabelPosition(item.getLabel(), pos + 1);
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}
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for (AssemblyItem const& item: m_assemblyItems)
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{
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if (item.getType() == AssemblyItem::Type::LABELREF)
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assembled.push_back(m_context.getLabelPosition(item.getLabel()));
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else
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assembled.push_back(item.getData());
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}
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return assembled;
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}
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AssemblyItems ExpressionCompiler::compileExpression(CompilerContext& _context,
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Expression& _expression)
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{
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ExpressionCompiler compiler(_context);
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compiler.compile(_expression);
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return compiler.getAssemblyItems();
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}
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void ExpressionCompiler::endVisit(Assignment& _assignment)
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{
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Expression& rightHandSide = _assignment.getRightHandSide();
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Token::Value op = _assignment.getAssignmentOperator();
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if (op != Token::ASSIGN)
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{
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// compound assignment
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// @todo retrieve lvalue value
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rightHandSide.accept(*this);
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Type const& resultType = *_assignment.getType();
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cleanHigherOrderBitsIfNeeded(*rightHandSide.getType(), resultType);
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appendOrdinaryBinaryOperatorCode(Token::AssignmentToBinaryOp(op), resultType);
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}
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else
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rightHandSide.accept(*this);
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// @todo store value
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}
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void ExpressionCompiler::endVisit(UnaryOperation& _unaryOperation)
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{
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//@todo type checking and creating code for an operator should be in the same place:
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// the operator should know how to convert itself and to which types it applies, so
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// put this code together with "Type::acceptsBinary/UnaryOperator" into a class that
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// represents the operator
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switch (_unaryOperation.getOperator())
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{
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case Token::NOT: // !
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append(eth::Instruction::NOT);
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break;
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case Token::BIT_NOT: // ~
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// ~a modeled as "a xor (0 - 1)" for now
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append(eth::Instruction::PUSH1);
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append(1);
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append(eth::Instruction::PUSH1);
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append(0);
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append(eth::Instruction::SUB);
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append(eth::Instruction::XOR);
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break;
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case Token::DELETE: // delete
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// a -> a xor a (= 0).
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// @todo this should also be an assignment
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// @todo semantics change for complex types
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append(eth::Instruction::DUP1);
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append(eth::Instruction::XOR);
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break;
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case Token::INC: // ++ (pre- or postfix)
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// @todo this should also be an assignment
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if (_unaryOperation.isPrefixOperation())
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{
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append(eth::Instruction::PUSH1);
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append(1);
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append(eth::Instruction::ADD);
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}
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break;
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case Token::DEC: // -- (pre- or postfix)
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// @todo this should also be an assignment
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if (_unaryOperation.isPrefixOperation())
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{
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append(eth::Instruction::PUSH1);
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append(1);
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append(eth::Instruction::SWAP1); //@todo avoid this
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append(eth::Instruction::SUB);
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}
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break;
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case Token::ADD: // +
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// unary add, so basically no-op
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break;
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case Token::SUB: // -
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append(eth::Instruction::NEG);
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break;
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default:
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BOOST_ASSERT(false); // invalid operation
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}
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}
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bool ExpressionCompiler::visit(BinaryOperation& _binaryOperation)
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{
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Expression& leftExpression = _binaryOperation.getLeftExpression();
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Expression& rightExpression = _binaryOperation.getRightExpression();
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Type const& resultType = *_binaryOperation.getType();
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Token::Value const op = _binaryOperation.getOperator();
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if (op == Token::AND || op == Token::OR)
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{
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// special case: short-circuiting
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appendAndOrOperatorCode(_binaryOperation);
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}
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else if (Token::isCompareOp(op))
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{
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leftExpression.accept(*this);
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rightExpression.accept(*this);
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// the types to compare have to be the same, but the resulting type is always bool
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BOOST_ASSERT(*leftExpression.getType() == *rightExpression.getType());
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appendCompareOperatorCode(op, *leftExpression.getType());
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}
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else
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{
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leftExpression.accept(*this);
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cleanHigherOrderBitsIfNeeded(*leftExpression.getType(), resultType);
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rightExpression.accept(*this);
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cleanHigherOrderBitsIfNeeded(*rightExpression.getType(), resultType);
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appendOrdinaryBinaryOperatorCode(op, resultType);
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}
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// do not visit the child nodes, we already did that explicitly
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return false;
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}
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void ExpressionCompiler::endVisit(FunctionCall& _functionCall)
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{
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if (_functionCall.isTypeConversion())
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{
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//@todo binary representation for all supported types (bool and int) is the same, so no-op
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// here for now.
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}
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else
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{
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//@todo
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}
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}
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void ExpressionCompiler::endVisit(MemberAccess& _memberAccess)
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{
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}
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void ExpressionCompiler::endVisit(IndexAccess& _indexAccess)
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{
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}
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void ExpressionCompiler::endVisit(Identifier& _identifier)
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{
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}
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void ExpressionCompiler::endVisit(Literal& _literal)
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{
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switch (_literal.getType()->getCategory())
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{
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case Type::Category::INTEGER:
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case Type::Category::BOOL:
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{
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bytes value = _literal.getType()->literalToBigEndian(_literal);
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BOOST_ASSERT(value.size() <= 32);
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BOOST_ASSERT(!value.empty());
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append(static_cast<byte>(eth::Instruction::PUSH1) + static_cast<byte>(value.size() - 1));
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append(value);
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break;
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}
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default:
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BOOST_ASSERT(false); // @todo
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}
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}
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void ExpressionCompiler::cleanHigherOrderBitsIfNeeded(const Type& _typeOnStack, const Type& _targetType)
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{
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// If the type of one of the operands is extended, we need to remove all
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// higher-order bits that we might have ignored in previous operations.
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// @todo: store in the AST whether the operand might have "dirty" higher
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// order bits
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if (_typeOnStack == _targetType)
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return;
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if (_typeOnStack.getCategory() == Type::Category::INTEGER &&
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_targetType.getCategory() == Type::Category::INTEGER)
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{
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//@todo
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}
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else
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{
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// If we get here, there is either an implementation missing to clean higher oder bits
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// for non-integer types that are explicitly convertible or we got here in error.
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BOOST_ASSERT(!_typeOnStack.isExplicitlyConvertibleTo(_targetType));
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BOOST_ASSERT(false); // these types should not be convertible.
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}
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}
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void ExpressionCompiler::appendAndOrOperatorCode(BinaryOperation& _binaryOperation)
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{
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Token::Value const op = _binaryOperation.getOperator();
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BOOST_ASSERT(op == Token::OR || op == Token::AND);
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_binaryOperation.getLeftExpression().accept(*this);
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append(eth::Instruction::DUP1);
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if (op == Token::AND)
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append(eth::Instruction::NOT);
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uint32_t endLabel = appendConditionalJump();
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_binaryOperation.getRightExpression().accept(*this);
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appendLabel(endLabel);
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}
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void ExpressionCompiler::appendCompareOperatorCode(Token::Value _operator, Type const& _type)
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{
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if (_operator == Token::EQ || _operator == Token::NE)
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{
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append(eth::Instruction::EQ);
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if (_operator == Token::NE)
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append(eth::Instruction::NOT);
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}
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else
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{
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IntegerType const* type = dynamic_cast<IntegerType const*>(&_type);
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BOOST_ASSERT(type != nullptr);
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bool const isSigned = type->isSigned();
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// note that EVM opcodes compare like "stack[0] < stack[1]",
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// but our left value is at stack[1], so everyhing is reversed.
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switch (_operator)
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{
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case Token::GTE:
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append(isSigned ? eth::Instruction::SGT : eth::Instruction::GT);
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append(eth::Instruction::NOT);
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break;
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case Token::LTE:
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append(isSigned ? eth::Instruction::SLT : eth::Instruction::LT);
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append(eth::Instruction::NOT);
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break;
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case Token::GT:
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append(isSigned ? eth::Instruction::SLT : eth::Instruction::LT);
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break;
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case Token::LT:
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append(isSigned ? eth::Instruction::SGT : eth::Instruction::GT);
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break;
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default:
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BOOST_ASSERT(false);
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}
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}
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}
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void ExpressionCompiler::appendOrdinaryBinaryOperatorCode(Token::Value _operator, Type const& _type)
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{
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if (Token::isArithmeticOp(_operator))
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appendArithmeticOperatorCode(_operator, _type);
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else if (Token::isBitOp(_operator))
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appendBitOperatorCode(_operator);
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else if (Token::isShiftOp(_operator))
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appendShiftOperatorCode(_operator);
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else
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BOOST_ASSERT(false); // unknown binary operator
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}
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void ExpressionCompiler::appendArithmeticOperatorCode(Token::Value _operator, Type const& _type)
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{
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IntegerType const* type = dynamic_cast<IntegerType const*>(&_type);
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BOOST_ASSERT(type != nullptr);
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bool const isSigned = type->isSigned();
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switch (_operator)
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{
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case Token::ADD:
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append(eth::Instruction::ADD);
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break;
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case Token::SUB:
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append(eth::Instruction::SWAP1);
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append(eth::Instruction::SUB);
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break;
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case Token::MUL:
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append(eth::Instruction::MUL);
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break;
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case Token::DIV:
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append(isSigned ? eth::Instruction::SDIV : eth::Instruction::DIV);
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break;
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case Token::MOD:
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append(isSigned ? eth::Instruction::SMOD : eth::Instruction::MOD);
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break;
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default:
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BOOST_ASSERT(false);
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}
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}
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void ExpressionCompiler::appendBitOperatorCode(Token::Value _operator)
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{
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switch (_operator)
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{
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case Token::BIT_OR:
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append(eth::Instruction::OR);
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break;
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case Token::BIT_AND:
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append(eth::Instruction::AND);
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break;
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case Token::BIT_XOR:
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append(eth::Instruction::XOR);
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break;
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default:
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BOOST_ASSERT(false);
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}
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}
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void ExpressionCompiler::appendShiftOperatorCode(Token::Value _operator)
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{
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switch (_operator)
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{
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case Token::SHL:
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BOOST_ASSERT(false); //@todo
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break;
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case Token::SAR:
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BOOST_ASSERT(false); //@todo
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break;
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default:
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BOOST_ASSERT(false);
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}
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}
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uint32_t ExpressionCompiler::appendConditionalJump()
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{
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uint32_t label = m_context.dispenseNewLabel();
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append(eth::Instruction::PUSH1);
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appendLabelref(label);
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append(eth::Instruction::JUMPI);
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return label;
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}
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void ExpressionCompiler::append(bytes const& _data)
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{
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m_assemblyItems.reserve(m_assemblyItems.size() + _data.size());
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for (byte b: _data)
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append(b);
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}
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}
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}
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