/*
This file is part of solidity.
solidity 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.
solidity 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 solidity. If not, see .
*/
/**
* @author Christian
* @date 2016
* Code-generating part of inline assembly.
*/
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
using namespace std;
using namespace dev;
using namespace dev::solidity;
using namespace dev::solidity::assembly;
struct GeneratorState
{
GeneratorState(ErrorList& _errors, eth::Assembly& _assembly):
errors(_errors), assembly(_assembly) {}
void addError(Error::Type _type, std::string const& _description, SourceLocation const& _location = SourceLocation())
{
errors.push_back(make_shared(_type, _description, _location));
}
size_t newLabelId()
{
return assemblyTagToIdentifier(assembly.newTag());
}
size_t assemblyTagToIdentifier(eth::AssemblyItem const& _tag) const
{
u256 id = _tag.data();
solAssert(id <= std::numeric_limits::max(), "Tag id too large.");
return size_t(id);
}
std::map> scopes;
ErrorList& errors;
eth::Assembly& assembly;
};
class CodeTransform: public boost::static_visitor<>
{
public:
/// Create the code transformer which appends assembly to _state.assembly when called
/// with parsed assembly data.
/// @param _identifierAccess used to resolve identifiers external to the inline assembly
explicit CodeTransform(
GeneratorState& _state,
assembly::Block const& _block,
assembly::CodeGenerator::IdentifierAccess const& _identifierAccess = assembly::CodeGenerator::IdentifierAccess()
):
m_state(_state),
m_scope(*m_state.scopes.at(&_block)),
m_initialDeposit(m_state.assembly.deposit()),
m_identifierAccess(_identifierAccess)
{
std::for_each(_block.statements.begin(), _block.statements.end(), boost::apply_visitor(*this));
m_state.assembly.setSourceLocation(_block.location);
// pop variables
for (auto const& identifier: m_scope.identifiers)
if (identifier.second.type() == typeid(Scope::Variable))
m_state.assembly.append(solidity::Instruction::POP);
int deposit = m_state.assembly.deposit() - m_initialDeposit;
// issue warnings for stack height discrepancies
if (deposit < 0)
{
m_state.addError(
Error::Type::Warning,
"Inline assembly block is not balanced. It takes " + toString(-deposit) + " item(s) from the stack.",
_block.location
);
}
else if (deposit > 0)
{
m_state.addError(
Error::Type::Warning,
"Inline assembly block is not balanced. It leaves " + toString(deposit) + " item(s) on the stack.",
_block.location
);
}
}
void operator()(assembly::Instruction const& _instruction)
{
m_state.assembly.setSourceLocation(_instruction.location);
m_state.assembly.append(_instruction.instruction);
}
void operator()(assembly::Literal const& _literal)
{
m_state.assembly.setSourceLocation(_literal.location);
if (_literal.isNumber)
m_state.assembly.append(u256(_literal.value));
else
{
solAssert(_literal.value.size() <= 32, "");
m_state.assembly.append(u256(h256(_literal.value, h256::FromBinary, h256::AlignLeft)));
}
}
void operator()(assembly::Identifier const& _identifier)
{
m_state.assembly.setSourceLocation(_identifier.location);
// First search internals, then externals.
if (m_scope.lookup(_identifier.name, Scope::NonconstVisitor(
[=](Scope::Variable& _var)
{
if (int heightDiff = variableHeightDiff(_var, _identifier.location, false))
m_state.assembly.append(solidity::dupInstruction(heightDiff));
else
// Store something to balance the stack
m_state.assembly.append(u256(0));
},
[=](Scope::Label& _label)
{
assignLabelIdIfUnset(_label);
m_state.assembly.append(eth::AssemblyItem(eth::PushTag, _label.id));
},
[=](Scope::Function&)
{
solAssert(false, "Not yet implemented");
}
)))
{
}
else if (!m_identifierAccess || !m_identifierAccess(_identifier, m_state.assembly, CodeGenerator::IdentifierContext::RValue))
{
m_state.addError(
Error::Type::DeclarationError,
"Identifier not found or not unique",
_identifier.location
);
m_state.assembly.append(u256(0));
}
}
void operator()(FunctionalInstruction const& _instr)
{
for (auto it = _instr.arguments.rbegin(); it != _instr.arguments.rend(); ++it)
{
int height = m_state.assembly.deposit();
boost::apply_visitor(*this, *it);
expectDeposit(1, height, locationOf(*it));
}
(*this)(_instr.instruction);
}
void operator()(assembly::FunctionCall const&)
{
solAssert(false, "Function call not removed during desugaring phase.");
}
void operator()(Label const& _label)
{
m_state.assembly.setSourceLocation(_label.location);
solAssert(m_scope.identifiers.count(_label.name), "");
Scope::Label& label = boost::get(m_scope.identifiers[_label.name]);
assignLabelIdIfUnset(label);
m_state.assembly.append(eth::AssemblyItem(eth::Tag, label.id));
}
void operator()(assembly::Assignment const& _assignment)
{
m_state.assembly.setSourceLocation(_assignment.location);
generateAssignment(_assignment.variableName, _assignment.location);
}
void operator()(FunctionalAssignment const& _assignment)
{
int height = m_state.assembly.deposit();
boost::apply_visitor(*this, *_assignment.value);
expectDeposit(1, height, locationOf(*_assignment.value));
m_state.assembly.setSourceLocation(_assignment.location);
generateAssignment(_assignment.variableName, _assignment.location);
}
void operator()(assembly::VariableDeclaration const& _varDecl)
{
int height = m_state.assembly.deposit();
boost::apply_visitor(*this, *_varDecl.value);
expectDeposit(1, height, locationOf(*_varDecl.value));
solAssert(m_scope.identifiers.count(_varDecl.name), "");
auto& var = boost::get(m_scope.identifiers[_varDecl.name]);
var.stackHeight = height;
var.active = true;
}
void operator()(assembly::Block const& _block)
{
CodeTransform(m_state, _block, m_identifierAccess);
}
void operator()(assembly::FunctionDefinition const&)
{
solAssert(false, "Function definition not removed during desugaring phase.");
}
private:
void generateAssignment(assembly::Identifier const& _variableName, SourceLocation const& _location)
{
if (m_scope.lookup(_variableName.name, Scope::Visitor(
[=](Scope::Variable const& _var)
{
if (int heightDiff = variableHeightDiff(_var, _location, true))
m_state.assembly.append(solidity::swapInstruction(heightDiff - 1));
m_state.assembly.append(solidity::Instruction::POP);
},
[=](Scope::Label const&)
{
m_state.addError(
Error::Type::DeclarationError,
"Label \"" + string(_variableName.name) + "\" used as variable."
);
},
[=](Scope::Function const&)
{
m_state.addError(
Error::Type::DeclarationError,
"Function \"" + string(_variableName.name) + "\" used as variable."
);
}
)))
{
}
else if (!m_identifierAccess || !m_identifierAccess(_variableName, m_state.assembly, CodeGenerator::IdentifierContext::LValue))
m_state.addError(
Error::Type::DeclarationError,
"Identifier \"" + string(_variableName.name) + "\" not found, not unique or not lvalue."
);
}
/// Determines the stack height difference to the given variables. Automatically generates
/// errors if it is not yet in scope or the height difference is too large. Returns 0 on
/// errors and the (positive) stack height difference otherwise.
int variableHeightDiff(Scope::Variable const& _var, SourceLocation const& _location, bool _forSwap)
{
if (!_var.active)
{
m_state.addError( Error::Type::TypeError, "Variable used before it was declared", _location);
return 0;
}
int heightDiff = m_state.assembly.deposit() - _var.stackHeight;
if (heightDiff <= (_forSwap ? 1 : 0) || heightDiff > (_forSwap ? 17 : 16))
{
m_state.addError(
Error::Type::TypeError,
"Variable inaccessible, too deep inside stack (" + boost::lexical_cast(heightDiff) + ")",
_location
);
return 0;
}
else
return heightDiff;
}
void expectDeposit(int _deposit, int _oldHeight, SourceLocation const& _location)
{
if (m_state.assembly.deposit() != _oldHeight + 1)
m_state.addError(Error::Type::TypeError,
"Expected instruction(s) to deposit " +
boost::lexical_cast(_deposit) +
" item(s) to the stack, but did deposit " +
boost::lexical_cast(m_state.assembly.deposit() - _oldHeight) +
" item(s).",
_location
);
}
/// Assigns the label's id to a value taken from eth::Assembly if it has not yet been set.
void assignLabelIdIfUnset(Scope::Label& _label)
{
if (_label.id == Scope::Label::unassignedLabelId)
_label.id = m_state.newLabelId();
else if (_label.id == Scope::Label::errorLabelId)
_label.id = size_t(m_state.assembly.errorTag().data());
}
GeneratorState& m_state;
Scope& m_scope;
int const m_initialDeposit;
assembly::CodeGenerator::IdentifierAccess m_identifierAccess;
};
bool assembly::CodeGenerator::typeCheck(assembly::CodeGenerator::IdentifierAccess const& _identifierAccess)
{
size_t initialErrorLen = m_errors.size();
eth::Assembly assembly;
GeneratorState state(m_errors, assembly);
if (!(AsmAnalyzer(state.scopes, m_errors))(m_parsedData))
return false;
CodeTransform(state, m_parsedData, _identifierAccess);
return m_errors.size() == initialErrorLen;
}
eth::Assembly assembly::CodeGenerator::assemble(assembly::CodeGenerator::IdentifierAccess const& _identifierAccess)
{
eth::Assembly assembly;
GeneratorState state(m_errors, assembly);
if (!(AsmAnalyzer(state.scopes, m_errors))(m_parsedData))
solAssert(false, "Assembly error");
CodeTransform(state, m_parsedData, _identifierAccess);
return assembly;
}
void assembly::CodeGenerator::assemble(eth::Assembly& _assembly, assembly::CodeGenerator::IdentifierAccess const& _identifierAccess)
{
GeneratorState state(m_errors, _assembly);
if (!(AsmAnalyzer(state.scopes, m_errors))(m_parsedData))
solAssert(false, "Assembly error");
CodeTransform(state, m_parsedData, _identifierAccess);
}