/*
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 .
*/
#include
#include
#include
#include
#include
using namespace std;
using namespace dev;
using namespace langutil;
using namespace dev::solidity;
SMTEncoder::SMTEncoder(smt::EncodingContext& _context):
m_errorReporter(m_smtErrors),
m_context(_context)
{
}
bool SMTEncoder::visit(ContractDefinition const& _contract)
{
solAssert(m_currentContract, "");
for (auto const& node: _contract.subNodes())
if (!dynamic_pointer_cast(node))
node->accept(*this);
vector resolvedFunctions = _contract.definedFunctions();
for (auto const& base: _contract.annotation().linearizedBaseContracts)
for (auto const& baseFunction: base->definedFunctions())
{
if (baseFunction->isConstructor())
continue;
bool overridden = false;
for (auto const& function: resolvedFunctions)
if (
function->name() == baseFunction->name() &&
FunctionType(*function).asCallableFunction(false)->
hasEqualParameterTypes(*FunctionType(*baseFunction).asCallableFunction(false))
)
{
overridden = true;
break;
}
if (!overridden)
resolvedFunctions.push_back(baseFunction);
}
for (auto const& function: resolvedFunctions)
function->accept(*this);
return false;
}
void SMTEncoder::endVisit(ContractDefinition const& _contract)
{
m_context.resetAllVariables();
solAssert(m_currentContract == &_contract, "");
m_currentContract = nullptr;
}
void SMTEncoder::endVisit(VariableDeclaration const& _varDecl)
{
if (_varDecl.isLocalVariable() && _varDecl.type()->isValueType() &&_varDecl.value())
assignment(_varDecl, *_varDecl.value());
}
bool SMTEncoder::visit(ModifierDefinition const&)
{
return false;
}
bool SMTEncoder::visit(FunctionDefinition const& _function)
{
// Not visited by a function call
if (m_callStack.empty())
initFunction(_function);
m_modifierDepthStack.push_back(-1);
if (_function.isConstructor())
{
m_errorReporter.warning(
_function.location(),
"Assertion checker does not yet support constructors."
);
}
else
{
_function.parameterList().accept(*this);
if (_function.returnParameterList())
_function.returnParameterList()->accept(*this);
visitFunctionOrModifier();
}
return false;
}
void SMTEncoder::visitFunctionOrModifier()
{
solAssert(!m_callStack.empty(), "");
solAssert(!m_modifierDepthStack.empty(), "");
++m_modifierDepthStack.back();
FunctionDefinition const& function = dynamic_cast(*m_callStack.back().first);
if (m_modifierDepthStack.back() == int(function.modifiers().size()))
{
if (function.isImplemented())
function.body().accept(*this);
}
else
{
solAssert(m_modifierDepthStack.back() < int(function.modifiers().size()), "");
ASTPointer const& modifierInvocation = function.modifiers()[m_modifierDepthStack.back()];
solAssert(modifierInvocation, "");
modifierInvocation->accept(*this);
auto const& modifierDef = dynamic_cast(
*modifierInvocation->name()->annotation().referencedDeclaration
);
vector modifierArgsExpr;
if (auto const* arguments = modifierInvocation->arguments())
{
auto const& modifierParams = modifierDef.parameters();
solAssert(modifierParams.size() == arguments->size(), "");
for (unsigned i = 0; i < arguments->size(); ++i)
modifierArgsExpr.push_back(expr(*arguments->at(i), modifierParams.at(i)->type()));
}
initializeFunctionCallParameters(modifierDef, modifierArgsExpr);
pushCallStack({&modifierDef, modifierInvocation.get()});
modifierDef.body().accept(*this);
popCallStack();
}
--m_modifierDepthStack.back();
}
bool SMTEncoder::visit(PlaceholderStatement const&)
{
solAssert(!m_callStack.empty(), "");
auto lastCall = popCallStack();
visitFunctionOrModifier();
pushCallStack(lastCall);
return true;
}
void SMTEncoder::endVisit(FunctionDefinition const&)
{
popCallStack();
solAssert(m_modifierDepthStack.back() == -1, "");
m_modifierDepthStack.pop_back();
if (m_callStack.empty())
m_context.popSolver();
}
bool SMTEncoder::visit(InlineAssembly const& _inlineAsm)
{
m_errorReporter.warning(
_inlineAsm.location(),
"Assertion checker does not support inline assembly."
);
return false;
}
bool SMTEncoder::visit(IfStatement const& _node)
{
_node.condition().accept(*this);
auto indicesEndTrue = visitBranch(&_node.trueStatement(), expr(_node.condition()));
auto touchedVars = touchedVariables(_node.trueStatement());
decltype(indicesEndTrue) indicesEndFalse;
if (_node.falseStatement())
{
indicesEndFalse = visitBranch(_node.falseStatement(), !expr(_node.condition()));
touchedVars += touchedVariables(*_node.falseStatement());
}
else
indicesEndFalse = copyVariableIndices();
mergeVariables(touchedVars, expr(_node.condition()), indicesEndTrue, indicesEndFalse);
return false;
}
void SMTEncoder::endVisit(VariableDeclarationStatement const& _varDecl)
{
if (_varDecl.declarations().size() != 1)
{
if (auto init = _varDecl.initialValue())
{
auto symbTuple = dynamic_pointer_cast(m_context.expression(*init));
solAssert(symbTuple, "");
auto const& components = symbTuple->components();
auto const& declarations = _varDecl.declarations();
solAssert(components.size() == declarations.size(), "");
for (unsigned i = 0; i < declarations.size(); ++i)
if (
components.at(i) &&
declarations.at(i) &&
m_context.knownVariable(*declarations.at(i))
)
assignment(*declarations.at(i), components.at(i)->currentValue(declarations.at(i)->type()));
}
}
else if (m_context.knownVariable(*_varDecl.declarations().front()))
{
if (_varDecl.initialValue())
assignment(*_varDecl.declarations().front(), *_varDecl.initialValue());
}
else
m_errorReporter.warning(
_varDecl.location(),
"Assertion checker does not yet implement such variable declarations."
);
}
void SMTEncoder::endVisit(Assignment const& _assignment)
{
createExpr(_assignment);
static set const compoundOps{
Token::AssignAdd,
Token::AssignSub,
Token::AssignMul,
Token::AssignDiv,
Token::AssignMod
};
Token op = _assignment.assignmentOperator();
if (op != Token::Assign && !compoundOps.count(op))
{
// Give it a new index anyway to keep the SSA scheme sound.
if (auto varDecl = identifierToVariable(_assignment.leftHandSide()))
m_context.newValue(*varDecl);
m_errorReporter.warning(
_assignment.location(),
"Assertion checker does not yet implement this assignment operator."
);
}
else if (!smt::isSupportedType(_assignment.annotation().type->category()))
{
// Give it a new index anyway to keep the SSA scheme sound.
if (auto varDecl = identifierToVariable(_assignment.leftHandSide()))
m_context.newValue(*varDecl);
}
else
{
auto const& type = _assignment.annotation().type;
vector rightArguments;
if (_assignment.rightHandSide().annotation().type->category() == Type::Category::Tuple)
{
auto symbTupleLeft = dynamic_pointer_cast(m_context.expression(_assignment.leftHandSide()));
solAssert(symbTupleLeft, "");
auto symbTupleRight = dynamic_pointer_cast(m_context.expression(_assignment.rightHandSide()));
solAssert(symbTupleRight, "");
auto const& leftComponents = symbTupleLeft->components();
auto const& rightComponents = symbTupleRight->components();
solAssert(leftComponents.size() == rightComponents.size(), "");
for (unsigned i = 0; i < leftComponents.size(); ++i)
{
auto const& left = leftComponents.at(i);
auto const& right = rightComponents.at(i);
/// Right hand side tuple component cannot be empty.
solAssert(right, "");
if (left)
rightArguments.push_back(right->currentValue(left->originalType()));
else
rightArguments.push_back(right->currentValue());
}
}
else
{
auto rightHandSide = compoundOps.count(op) ?
compoundAssignment(_assignment) :
expr(_assignment.rightHandSide(), type);
defineExpr(_assignment, rightHandSide);
rightArguments.push_back(expr(_assignment, type));
}
assignment(
_assignment.leftHandSide(),
rightArguments,
type,
_assignment.location()
);
}
}
void SMTEncoder::endVisit(TupleExpression const& _tuple)
{
createExpr(_tuple);
if (_tuple.isInlineArray())
m_errorReporter.warning(
_tuple.location(),
"Assertion checker does not yet implement inline arrays."
);
else if (_tuple.annotation().type->category() == Type::Category::Tuple)
{
auto const& symbTuple = dynamic_pointer_cast(m_context.expression(_tuple));
solAssert(symbTuple, "");
auto const& symbComponents = symbTuple->components();
auto const& tupleComponents = _tuple.components();
solAssert(symbComponents.size() == _tuple.components().size(), "");
for (unsigned i = 0; i < symbComponents.size(); ++i)
{
auto sComponent = symbComponents.at(i);
auto tComponent = tupleComponents.at(i);
if (sComponent && tComponent)
{
if (auto varDecl = identifierToVariable(*tComponent))
m_context.addAssertion(sComponent->currentValue() == currentValue(*varDecl));
else
{
solAssert(m_context.knownExpression(*tComponent), "");
m_context.addAssertion(sComponent->currentValue() == expr(*tComponent));
}
}
}
}
else
{
/// Parenthesized expressions are also TupleExpression regardless their type.
auto const& components = _tuple.components();
solAssert(components.size() == 1, "");
if (smt::isSupportedType(components.front()->annotation().type->category()))
defineExpr(_tuple, expr(*components.front()));
}
}
void SMTEncoder::endVisit(UnaryOperation const& _op)
{
if (_op.annotation().type->category() == Type::Category::RationalNumber)
return;
createExpr(_op);
switch (_op.getOperator())
{
case Token::Not: // !
{
solAssert(smt::isBool(_op.annotation().type->category()), "");
defineExpr(_op, !expr(_op.subExpression()));
break;
}
case Token::Inc: // ++ (pre- or postfix)
case Token::Dec: // -- (pre- or postfix)
{
solAssert(smt::isInteger(_op.annotation().type->category()), "");
solAssert(_op.subExpression().annotation().lValueRequested, "");
if (auto identifier = dynamic_cast(&_op.subExpression()))
{
auto decl = identifierToVariable(*identifier);
solAssert(decl, "");
auto innerValue = currentValue(*decl);
auto newValue = _op.getOperator() == Token::Inc ? innerValue + 1 : innerValue - 1;
defineExpr(_op, _op.isPrefixOperation() ? newValue : innerValue);
assignment(*decl, newValue);
}
else if (dynamic_cast(&_op.subExpression()))
{
auto innerValue = expr(_op.subExpression());
auto newValue = _op.getOperator() == Token::Inc ? innerValue + 1 : innerValue - 1;
defineExpr(_op, _op.isPrefixOperation() ? newValue : innerValue);
arrayIndexAssignment(_op.subExpression(), newValue);
}
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement such increments / decrements."
);
break;
}
case Token::Sub: // -
{
defineExpr(_op, 0 - expr(_op.subExpression()));
break;
}
case Token::Delete:
{
auto const& subExpr = _op.subExpression();
if (auto decl = identifierToVariable(subExpr))
{
m_context.newValue(*decl);
m_context.setZeroValue(*decl);
}
else
{
solAssert(m_context.knownExpression(subExpr), "");
auto const& symbVar = m_context.expression(subExpr);
symbVar->increaseIndex();
m_context.setZeroValue(*symbVar);
if (dynamic_cast(&_op.subExpression()))
arrayIndexAssignment(_op.subExpression(), symbVar->currentValue());
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement \"delete\" for this expression."
);
}
break;
}
default:
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement this operator."
);
}
}
bool SMTEncoder::visit(UnaryOperation const& _op)
{
return !shortcutRationalNumber(_op);
}
bool SMTEncoder::visit(BinaryOperation const& _op)
{
if (shortcutRationalNumber(_op))
return false;
if (TokenTraits::isBooleanOp(_op.getOperator()))
{
booleanOperation(_op);
return false;
}
return true;
}
void SMTEncoder::endVisit(BinaryOperation const& _op)
{
if (_op.annotation().type->category() == Type::Category::RationalNumber)
return;
if (TokenTraits::isBooleanOp(_op.getOperator()))
return;
createExpr(_op);
if (TokenTraits::isArithmeticOp(_op.getOperator()))
arithmeticOperation(_op);
else if (TokenTraits::isCompareOp(_op.getOperator()))
compareOperation(_op);
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement this operator."
);
}
void SMTEncoder::endVisit(FunctionCall const& _funCall)
{
solAssert(_funCall.annotation().kind != FunctionCallKind::Unset, "");
createExpr(_funCall);
if (_funCall.annotation().kind == FunctionCallKind::StructConstructorCall)
{
m_errorReporter.warning(
_funCall.location(),
"Assertion checker does not yet implement this expression."
);
return;
}
if (_funCall.annotation().kind == FunctionCallKind::TypeConversion)
{
visitTypeConversion(_funCall);
return;
}
FunctionType const& funType = dynamic_cast(*_funCall.expression().annotation().type);
std::vector> const args = _funCall.arguments();
switch (funType.kind())
{
case FunctionType::Kind::Assert:
visitAssert(_funCall);
break;
case FunctionType::Kind::Require:
visitRequire(_funCall);
break;
case FunctionType::Kind::GasLeft:
visitGasLeft(_funCall);
break;
case FunctionType::Kind::Internal:
case FunctionType::Kind::External:
case FunctionType::Kind::DelegateCall:
case FunctionType::Kind::BareCall:
case FunctionType::Kind::BareCallCode:
case FunctionType::Kind::BareDelegateCall:
case FunctionType::Kind::BareStaticCall:
case FunctionType::Kind::Creation:
break;
case FunctionType::Kind::KECCAK256:
case FunctionType::Kind::ECRecover:
case FunctionType::Kind::SHA256:
case FunctionType::Kind::RIPEMD160:
case FunctionType::Kind::BlockHash:
case FunctionType::Kind::AddMod:
case FunctionType::Kind::MulMod:
break;
case FunctionType::Kind::Send:
case FunctionType::Kind::Transfer:
{
auto const& memberAccess = dynamic_cast(_funCall.expression());
auto const& address = memberAccess.expression();
auto const& value = args.front();
solAssert(value, "");
smt::Expression thisBalance = m_context.balance();
setSymbolicUnknownValue(thisBalance, TypeProvider::uint256(), m_context);
m_context.transfer(m_context.thisAddress(), expr(address), expr(*value));
break;
}
default:
m_errorReporter.warning(
_funCall.location(),
"Assertion checker does not yet implement this type of function call."
);
}
}
void SMTEncoder::initContract(ContractDefinition const& _contract)
{
solAssert(m_currentContract == nullptr, "");
m_currentContract = &_contract;
initializeStateVariables(_contract);
}
void SMTEncoder::initFunction(FunctionDefinition const& _function)
{
solAssert(m_callStack.empty(), "");
m_context.reset();
m_context.pushSolver();
m_pathConditions.clear();
pushCallStack({&_function, nullptr});
m_uninterpretedTerms.clear();
resetStateVariables();
initializeLocalVariables(_function);
m_arrayAssignmentHappened = false;
}
void SMTEncoder::visitAssert(FunctionCall const& _funCall)
{
auto const& args = _funCall.arguments();
solAssert(args.size() == 1, "");
solAssert(args.front()->annotation().type->category() == Type::Category::Bool, "");
addPathImpliedExpression(expr(*args.front()));
}
void SMTEncoder::visitRequire(FunctionCall const& _funCall)
{
auto const& args = _funCall.arguments();
solAssert(args.size() >= 1, "");
solAssert(args.front()->annotation().type->category() == Type::Category::Bool, "");
addPathImpliedExpression(expr(*args.front()));
}
void SMTEncoder::visitGasLeft(FunctionCall const& _funCall)
{
string gasLeft = "gasleft()";
// We increase the variable index since gasleft changes
// inside a tx.
defineGlobalVariable(gasLeft, _funCall, true);
auto const& symbolicVar = m_context.globalSymbol(gasLeft);
unsigned index = symbolicVar->index();
// We set the current value to unknown anyway to add type constraints.
m_context.setUnknownValue(*symbolicVar);
if (index > 0)
m_context.addAssertion(symbolicVar->currentValue() <= symbolicVar->valueAtIndex(index - 1));
}
void SMTEncoder::endVisit(Identifier const& _identifier)
{
if (_identifier.annotation().lValueRequested)
{
// Will be translated as part of the node that requested the lvalue.
}
else if (auto decl = identifierToVariable(_identifier))
defineExpr(_identifier, currentValue(*decl));
else if (_identifier.annotation().type->category() == Type::Category::Function)
visitFunctionIdentifier(_identifier);
else if (_identifier.name() == "now")
defineGlobalVariable(_identifier.name(), _identifier);
else if (_identifier.name() == "this")
{
defineExpr(_identifier, m_context.thisAddress());
m_uninterpretedTerms.insert(&_identifier);
}
else if (
_identifier.annotation().type->category() != Type::Category::Modifier
)
createExpr(_identifier);
}
void SMTEncoder::endVisit(ElementaryTypeNameExpression const& _typeName)
{
auto const& typeType = dynamic_cast(*_typeName.annotation().type);
auto result = smt::newSymbolicVariable(
*TypeProvider::uint256(),
typeType.actualType()->toString(false),
m_context
);
solAssert(!result.first && result.second, "");
m_context.createExpression(_typeName, result.second);
}
void SMTEncoder::visitTypeConversion(FunctionCall const& _funCall)
{
solAssert(_funCall.annotation().kind == FunctionCallKind::TypeConversion, "");
solAssert(_funCall.arguments().size() == 1, "");
auto argument = _funCall.arguments().front();
unsigned argSize = argument->annotation().type->storageBytes();
unsigned castSize = _funCall.annotation().type->storageBytes();
if (argSize == castSize)
defineExpr(_funCall, expr(*argument));
else
{
m_context.setUnknownValue(*m_context.expression(_funCall));
auto const& funCallCategory = _funCall.annotation().type->category();
// TODO: truncating and bytesX needs a different approach because of right padding.
if (funCallCategory == Type::Category::Integer || funCallCategory == Type::Category::Address)
{
if (argSize < castSize)
defineExpr(_funCall, expr(*argument));
else
{
auto const& intType = dynamic_cast(*m_context.expression(_funCall)->type());
defineExpr(_funCall, smt::Expression::ite(
expr(*argument) >= smt::minValue(intType) && expr(*argument) <= smt::maxValue(intType),
expr(*argument),
expr(_funCall)
));
}
}
m_errorReporter.warning(
_funCall.location(),
"Type conversion is not yet fully supported and might yield false positives."
);
}
}
void SMTEncoder::visitFunctionIdentifier(Identifier const& _identifier)
{
auto const& fType = dynamic_cast(*_identifier.annotation().type);
if (fType.returnParameterTypes().size() == 1)
{
defineGlobalVariable(fType.identifier(), _identifier);
m_context.createExpression(_identifier, m_context.globalSymbol(fType.identifier()));
}
}
void SMTEncoder::endVisit(Literal const& _literal)
{
solAssert(_literal.annotation().type, "Expected type for AST node");
Type const& type = *_literal.annotation().type;
if (smt::isNumber(type.category()))
defineExpr(_literal, smt::Expression(type.literalValue(&_literal)));
else if (smt::isBool(type.category()))
defineExpr(_literal, smt::Expression(_literal.token() == Token::TrueLiteral ? true : false));
else if (smt::isStringLiteral(type.category()))
createExpr(_literal);
else
{
m_errorReporter.warning(
_literal.location(),
"Assertion checker does not yet support the type of this literal (" +
_literal.annotation().type->toString() +
")."
);
}
}
void SMTEncoder::endVisit(Return const& _return)
{
if (_return.expression() && m_context.knownExpression(*_return.expression()))
{
auto returnParams = m_callStack.back().first->returnParameters();
if (returnParams.size() > 1)
{
auto const& symbTuple = dynamic_pointer_cast(m_context.expression(*_return.expression()));
solAssert(symbTuple, "");
auto const& components = symbTuple->components();
solAssert(components.size() == returnParams.size(), "");
for (unsigned i = 0; i < returnParams.size(); ++i)
{
solAssert(components.at(i), "");
m_context.addAssertion(components.at(i)->currentValue(returnParams.at(i)->type()) == m_context.newValue(*returnParams.at(i)));
}
}
else if (returnParams.size() == 1)
m_context.addAssertion(expr(*_return.expression(), returnParams.front()->type()) == m_context.newValue(*returnParams.front()));
}
}
bool SMTEncoder::visit(MemberAccess const& _memberAccess)
{
auto const& accessType = _memberAccess.annotation().type;
if (accessType->category() == Type::Category::Function)
return true;
createExpr(_memberAccess);
auto const& exprType = _memberAccess.expression().annotation().type;
solAssert(exprType, "");
auto identifier = dynamic_cast(&_memberAccess.expression());
if (exprType->category() == Type::Category::Magic)
{
string accessedName;
if (identifier)
accessedName = identifier->name();
else
m_errorReporter.warning(
_memberAccess.location(),
"Assertion checker does not yet support this expression."
);
defineGlobalVariable(accessedName + "." + _memberAccess.memberName(), _memberAccess);
return false;
}
else if (exprType->category() == Type::Category::TypeType)
{
if (identifier && dynamic_cast(identifier->annotation().referencedDeclaration))
{
auto enumType = dynamic_cast(accessType);
solAssert(enumType, "");
defineExpr(_memberAccess, enumType->memberValue(_memberAccess.memberName()));
}
return false;
}
else if (exprType->category() == Type::Category::Address)
{
_memberAccess.expression().accept(*this);
if (_memberAccess.memberName() == "balance")
{
defineExpr(_memberAccess, m_context.balance(expr(_memberAccess.expression())));
setSymbolicUnknownValue(*m_context.expression(_memberAccess), m_context);
m_uninterpretedTerms.insert(&_memberAccess);
return false;
}
}
else
m_errorReporter.warning(
_memberAccess.location(),
"Assertion checker does not yet support this expression."
);
return true;
}
void SMTEncoder::endVisit(IndexAccess const& _indexAccess)
{
createExpr(_indexAccess);
shared_ptr array;
if (auto const& id = dynamic_cast(&_indexAccess.baseExpression()))
{
auto varDecl = identifierToVariable(*id);
solAssert(varDecl, "");
array = m_context.variable(*varDecl);
if (varDecl->type()->category() == Type::Category::FixedBytes)
{
m_errorReporter.warning(
_indexAccess.location(),
"Assertion checker does not yet support index accessing fixed bytes."
);
return;
}
}
else if (auto const& innerAccess = dynamic_cast(&_indexAccess.baseExpression()))
{
solAssert(m_context.knownExpression(*innerAccess), "");
array = m_context.expression(*innerAccess);
}
else
{
m_errorReporter.warning(
_indexAccess.location(),
"Assertion checker does not yet implement this expression."
);
return;
}
if (!_indexAccess.indexExpression())
{
solAssert(_indexAccess.annotation().type->category() == Type::Category::TypeType, "");
return;
}
solAssert(array, "");
defineExpr(_indexAccess, smt::Expression::select(
array->currentValue(),
expr(*_indexAccess.indexExpression())
));
setSymbolicUnknownValue(
expr(_indexAccess),
_indexAccess.annotation().type,
m_context
);
m_uninterpretedTerms.insert(&_indexAccess);
}
void SMTEncoder::arrayAssignment()
{
m_arrayAssignmentHappened = true;
}
void SMTEncoder::arrayIndexAssignment(Expression const& _expr, smt::Expression const& _rightHandSide)
{
auto toStore = _rightHandSide;
auto indexAccess = dynamic_cast(&_expr);
solAssert(indexAccess, "");
while (true)
{
if (auto const& id = dynamic_cast(&indexAccess->baseExpression()))
{
auto varDecl = identifierToVariable(*id);
solAssert(varDecl, "");
if (varDecl->hasReferenceOrMappingType())
m_context.resetVariables([&](VariableDeclaration const& _var) {
if (_var == *varDecl)
return false;
// If both are state variables no need to clear knowledge.
if (_var.isStateVariable() && varDecl->isStateVariable())
return false;
TypePointer prefix = _var.type();
TypePointer originalType = typeWithoutPointer(varDecl->type());
while (
prefix->category() == Type::Category::Mapping ||
prefix->category() == Type::Category::Array
)
{
if (*originalType == *typeWithoutPointer(prefix))
return true;
if (prefix->category() == Type::Category::Mapping)
{
auto mapPrefix = dynamic_cast(prefix);
solAssert(mapPrefix, "");
prefix = mapPrefix->valueType();
}
else
{
auto arrayPrefix = dynamic_cast(prefix);
solAssert(arrayPrefix, "");
prefix = arrayPrefix->baseType();
}
}
return false;
});
smt::Expression store = smt::Expression::store(
m_context.variable(*varDecl)->currentValue(),
expr(*indexAccess->indexExpression()),
toStore
);
m_context.addAssertion(m_context.newValue(*varDecl) == store);
// Update the SMT select value after the assignment,
// necessary for sound models.
defineExpr(*indexAccess, smt::Expression::select(
m_context.variable(*varDecl)->currentValue(),
expr(*indexAccess->indexExpression())
));
break;
}
else if (auto base = dynamic_cast(&indexAccess->baseExpression()))
{
toStore = smt::Expression::store(expr(*base), expr(*indexAccess->indexExpression()), toStore);
indexAccess = base;
}
else
{
m_errorReporter.warning(
_expr.location(),
"Assertion checker does not yet implement this expression."
);
break;
}
}
}
void SMTEncoder::defineGlobalVariable(string const& _name, Expression const& _expr, bool _increaseIndex)
{
if (!m_context.knownGlobalSymbol(_name))
{
bool abstract = m_context.createGlobalSymbol(_name, _expr);
if (abstract)
m_errorReporter.warning(
_expr.location(),
"Assertion checker does not yet support this global variable."
);
}
else if (_increaseIndex)
m_context.globalSymbol(_name)->increaseIndex();
// The default behavior is not to increase the index since
// most of the global values stay the same throughout a tx.
if (smt::isSupportedType(_expr.annotation().type->category()))
defineExpr(_expr, m_context.globalSymbol(_name)->currentValue());
}
bool SMTEncoder::shortcutRationalNumber(Expression const& _expr)
{
if (_expr.annotation().type->category() == Type::Category::RationalNumber)
{
auto rationalType = dynamic_cast(_expr.annotation().type);
solAssert(rationalType, "");
if (rationalType->isNegative())
defineExpr(_expr, smt::Expression(u2s(rationalType->literalValue(nullptr))));
else
defineExpr(_expr, smt::Expression(rationalType->literalValue(nullptr)));
return true;
}
return false;
}
void SMTEncoder::arithmeticOperation(BinaryOperation const& _op)
{
auto type = _op.annotation().commonType;
solAssert(type, "");
if (type->category() == Type::Category::Integer)
{
switch (_op.getOperator())
{
case Token::Add:
case Token::Sub:
case Token::Mul:
case Token::Div:
case Token::Mod:
{
auto values = arithmeticOperation(
_op.getOperator(),
expr(_op.leftExpression()),
expr(_op.rightExpression()),
_op.annotation().commonType,
_op
);
defineExpr(_op, values.first);
break;
}
default:
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement this operator."
);
}
}
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement this operator for type " + type->richIdentifier() + "."
);
}
pair SMTEncoder::arithmeticOperation(
Token _op,
smt::Expression const& _left,
smt::Expression const& _right,
TypePointer const& _commonType,
Expression const&
)
{
static set validOperators{
Token::Add,
Token::Sub,
Token::Mul,
Token::Div,
Token::Mod
};
solAssert(validOperators.count(_op), "");
solAssert(_commonType, "");
solAssert(_commonType->category() == Type::Category::Integer, "");
auto const& intType = dynamic_cast(*_commonType);
smt::Expression valueNoMod(
_op == Token::Add ? _left + _right :
_op == Token::Sub ? _left - _right :
_op == Token::Div ? division(_left, _right, intType) :
_op == Token::Mul ? _left * _right :
/*_op == Token::Mod*/ _left % _right
);
if (_op == Token::Div || _op == Token::Mod)
m_context.addAssertion(_right != 0);
smt::Expression intValueRange = (0 - smt::minValue(intType)) + smt::maxValue(intType) + 1;
auto value = smt::Expression::ite(
valueNoMod > smt::maxValue(intType),
valueNoMod % intValueRange,
smt::Expression::ite(
valueNoMod < smt::minValue(intType),
valueNoMod % intValueRange,
valueNoMod
)
);
if (intType.isSigned())
value = smt::Expression::ite(
value > smt::maxValue(intType),
value - intValueRange,
value
);
return {value, valueNoMod};
}
void SMTEncoder::compareOperation(BinaryOperation const& _op)
{
auto const& commonType = _op.annotation().commonType;
solAssert(commonType, "");
if (smt::isSupportedType(commonType->category()))
{
smt::Expression left(expr(_op.leftExpression(), commonType));
smt::Expression right(expr(_op.rightExpression(), commonType));
Token op = _op.getOperator();
shared_ptr value;
if (smt::isNumber(commonType->category()))
{
value = make_shared(
op == Token::Equal ? (left == right) :
op == Token::NotEqual ? (left != right) :
op == Token::LessThan ? (left < right) :
op == Token::LessThanOrEqual ? (left <= right) :
op == Token::GreaterThan ? (left > right) :
/*op == Token::GreaterThanOrEqual*/ (left >= right)
);
}
else // Bool
{
solUnimplementedAssert(smt::isBool(commonType->category()), "Operation not yet supported");
value = make_shared(
op == Token::Equal ? (left == right) :
/*op == Token::NotEqual*/ (left != right)
);
}
// TODO: check that other values for op are not possible.
defineExpr(_op, *value);
}
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement the type " + _op.annotation().commonType->toString() + " for comparisons"
);
}
void SMTEncoder::booleanOperation(BinaryOperation const& _op)
{
solAssert(_op.getOperator() == Token::And || _op.getOperator() == Token::Or, "");
solAssert(_op.annotation().commonType, "");
if (_op.annotation().commonType->category() == Type::Category::Bool)
{
// @TODO check that both of them are not constant
_op.leftExpression().accept(*this);
if (_op.getOperator() == Token::And)
{
auto indicesAfterSecond = visitBranch(&_op.rightExpression(), expr(_op.leftExpression()));
mergeVariables(touchedVariables(_op.rightExpression()), !expr(_op.leftExpression()), copyVariableIndices(), indicesAfterSecond);
defineExpr(_op, expr(_op.leftExpression()) && expr(_op.rightExpression()));
}
else
{
auto indicesAfterSecond = visitBranch(&_op.rightExpression(), !expr(_op.leftExpression()));
mergeVariables(touchedVariables(_op.rightExpression()), expr(_op.leftExpression()), copyVariableIndices(), indicesAfterSecond);
defineExpr(_op, expr(_op.leftExpression()) || expr(_op.rightExpression()));
}
}
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement the type " + _op.annotation().commonType->toString() + " for boolean operations"
);
}
smt::Expression SMTEncoder::division(smt::Expression _left, smt::Expression _right, IntegerType const& _type)
{
// Signed division in SMTLIB2 rounds differently for negative division.
if (_type.isSigned())
return (smt::Expression::ite(
_left >= 0,
smt::Expression::ite(_right >= 0, _left / _right, 0 - (_left / (0 - _right))),
smt::Expression::ite(_right >= 0, 0 - ((0 - _left) / _right), (0 - _left) / (0 - _right))
));
else
return _left / _right;
}
void SMTEncoder::assignment(
Expression const& _left,
vector const& _right,
TypePointer const& _type,
langutil::SourceLocation const& _location
)
{
if (!smt::isSupportedType(_type->category()))
{
// Give it a new index anyway to keep the SSA scheme sound.
if (auto varDecl = identifierToVariable(_left))
m_context.newValue(*varDecl);
m_errorReporter.warning(
_location,
"Assertion checker does not yet implement type " + _type->toString()
);
}
else if (auto varDecl = identifierToVariable(_left))
{
solAssert(_right.size() == 1, "");
assignment(*varDecl, _right.front());
}
else if (dynamic_cast(&_left))
{
solAssert(_right.size() == 1, "");
arrayIndexAssignment(_left, _right.front());
}
else if (auto tuple = dynamic_cast(&_left))
{
auto const& components = tuple->components();
if (!_right.empty())
{
solAssert(_right.size() == components.size(), "");
for (unsigned i = 0; i < _right.size(); ++i)
if (auto component = components.at(i))
assignment(*component, {_right.at(i)}, component->annotation().type, component->location());
}
}
else
m_errorReporter.warning(
_location,
"Assertion checker does not yet implement such assignments."
);
}
smt::Expression SMTEncoder::compoundAssignment(Assignment const& _assignment)
{
static map const compoundToArithmetic{
{Token::AssignAdd, Token::Add},
{Token::AssignSub, Token::Sub},
{Token::AssignMul, Token::Mul},
{Token::AssignDiv, Token::Div},
{Token::AssignMod, Token::Mod}
};
Token op = _assignment.assignmentOperator();
solAssert(compoundToArithmetic.count(op), "");
auto decl = identifierToVariable(_assignment.leftHandSide());
auto values = arithmeticOperation(
compoundToArithmetic.at(op),
decl ? currentValue(*decl) : expr(_assignment.leftHandSide()),
expr(_assignment.rightHandSide()),
_assignment.annotation().type,
_assignment
);
return values.first;
}
void SMTEncoder::assignment(VariableDeclaration const& _variable, Expression const& _value)
{
assignment(_variable, expr(_value, _variable.type()));
}
void SMTEncoder::assignment(VariableDeclaration const& _variable, smt::Expression const& _value)
{
TypePointer type = _variable.type();
if (type->category() == Type::Category::Mapping)
arrayAssignment();
m_context.addAssertion(m_context.newValue(_variable) == _value);
}
SMTEncoder::VariableIndices SMTEncoder::visitBranch(ASTNode const* _statement, smt::Expression _condition)
{
return visitBranch(_statement, &_condition);
}
SMTEncoder::VariableIndices SMTEncoder::visitBranch(ASTNode const* _statement, smt::Expression const* _condition)
{
auto indicesBeforeBranch = copyVariableIndices();
if (_condition)
pushPathCondition(*_condition);
_statement->accept(*this);
if (_condition)
popPathCondition();
auto indicesAfterBranch = copyVariableIndices();
resetVariableIndices(indicesBeforeBranch);
return indicesAfterBranch;
}
void SMTEncoder::initializeFunctionCallParameters(CallableDeclaration const& _function, vector const& _callArgs)
{
auto const& funParams = _function.parameters();
solAssert(funParams.size() == _callArgs.size(), "");
for (unsigned i = 0; i < funParams.size(); ++i)
if (createVariable(*funParams[i]))
{
m_context.addAssertion(_callArgs[i] == m_context.newValue(*funParams[i]));
if (funParams[i]->annotation().type->category() == Type::Category::Mapping)
m_arrayAssignmentHappened = true;
}
for (auto const& variable: _function.localVariables())
if (createVariable(*variable))
{
m_context.newValue(*variable);
m_context.setZeroValue(*variable);
}
if (_function.returnParameterList())
for (auto const& retParam: _function.returnParameters())
if (createVariable(*retParam))
{
m_context.newValue(*retParam);
m_context.setZeroValue(*retParam);
}
}
void SMTEncoder::initializeStateVariables(ContractDefinition const& _contract)
{
for (auto var: _contract.stateVariablesIncludingInherited())
createVariable(*var);
}
void SMTEncoder::initializeLocalVariables(FunctionDefinition const& _function)
{
for (auto const& variable: _function.localVariables())
if (createVariable(*variable))
m_context.setZeroValue(*variable);
for (auto const& param: _function.parameters())
if (createVariable(*param))
m_context.setUnknownValue(*param);
if (_function.returnParameterList())
for (auto const& retParam: _function.returnParameters())
if (createVariable(*retParam))
m_context.setZeroValue(*retParam);
}
void SMTEncoder::resetStateVariables()
{
m_context.resetVariables([&](VariableDeclaration const& _variable) { return _variable.isStateVariable(); });
}
TypePointer SMTEncoder::typeWithoutPointer(TypePointer const& _type)
{
if (auto refType = dynamic_cast(_type))
return TypeProvider::withLocationIfReference(refType->location(), _type);
return _type;
}
void SMTEncoder::mergeVariables(set const& _variables, smt::Expression const& _condition, VariableIndices const& _indicesEndTrue, VariableIndices const& _indicesEndFalse)
{
auto cmp = [] (VariableDeclaration const* var1, VariableDeclaration const* var2) {
return var1->id() < var2->id();
};
set sortedVars(begin(_variables), end(_variables), cmp);
/// Knowledge about references is erased if a reference is assigned,
/// so those also need their SSA's merged.
/// This does not cause scope harm since the symbolic variables
/// are kept alive.
for (auto const& var: _indicesEndTrue)
{
solAssert(_indicesEndFalse.count(var.first), "");
if (
_indicesEndFalse.at(var.first) != var.second &&
!sortedVars.count(var.first)
)
sortedVars.insert(var.first);
}
for (auto const* decl: sortedVars)
{
solAssert(_indicesEndTrue.count(decl) && _indicesEndFalse.count(decl), "");
int trueIndex = _indicesEndTrue.at(decl);
int falseIndex = _indicesEndFalse.at(decl);
solAssert(trueIndex != falseIndex, "");
m_context.addAssertion(m_context.newValue(*decl) == smt::Expression::ite(
_condition,
valueAtIndex(*decl, trueIndex),
valueAtIndex(*decl, falseIndex))
);
}
}
smt::Expression SMTEncoder::currentValue(VariableDeclaration const& _decl)
{
solAssert(m_context.knownVariable(_decl), "");
return m_context.variable(_decl)->currentValue();
}
smt::Expression SMTEncoder::valueAtIndex(VariableDeclaration const& _decl, int _index)
{
solAssert(m_context.knownVariable(_decl), "");
return m_context.variable(_decl)->valueAtIndex(_index);
}
bool SMTEncoder::createVariable(VariableDeclaration const& _varDecl)
{
if (m_context.knownVariable(_varDecl))
return true;
bool abstract = m_context.createVariable(_varDecl);
if (abstract)
{
m_errorReporter.warning(
_varDecl.location(),
"Assertion checker does not yet support the type of this variable."
);
return false;
}
return true;
}
smt::Expression SMTEncoder::expr(Expression const& _e, TypePointer _targetType)
{
if (!m_context.knownExpression(_e))
{
m_errorReporter.warning(_e.location(), "Internal error: Expression undefined for SMT solver." );
createExpr(_e);
}
return m_context.expression(_e)->currentValue(_targetType);
}
void SMTEncoder::createExpr(Expression const& _e)
{
bool abstract = m_context.createExpression(_e);
if (abstract)
m_errorReporter.warning(
_e.location(),
"Assertion checker does not yet implement type " + _e.annotation().type->toString()
);
}
void SMTEncoder::defineExpr(Expression const& _e, smt::Expression _value)
{
createExpr(_e);
solAssert(_value.sort->kind != smt::Kind::Function, "Equality operator applied to type that is not fully supported");
m_context.addAssertion(expr(_e) == _value);
}
void SMTEncoder::popPathCondition()
{
solAssert(m_pathConditions.size() > 0, "Cannot pop path condition, empty.");
m_pathConditions.pop_back();
}
void SMTEncoder::pushPathCondition(smt::Expression const& _e)
{
m_pathConditions.push_back(currentPathConditions() && _e);
}
smt::Expression SMTEncoder::currentPathConditions()
{
if (m_pathConditions.empty())
return smt::Expression(true);
return m_pathConditions.back();
}
SecondarySourceLocation SMTEncoder::callStackMessage(vector const& _callStack)
{
SecondarySourceLocation callStackLocation;
solAssert(!_callStack.empty(), "");
callStackLocation.append("Callstack: ", SourceLocation());
for (auto const& call: _callStack | boost::adaptors::reversed)
if (call.second)
callStackLocation.append("", call.second->location());
return callStackLocation;
}
pair SMTEncoder::popCallStack()
{
solAssert(!m_callStack.empty(), "");
auto lastCalled = m_callStack.back();
m_callStack.pop_back();
return lastCalled;
}
void SMTEncoder::pushCallStack(CallStackEntry _entry)
{
m_callStack.push_back(_entry);
}
void SMTEncoder::addPathImpliedExpression(smt::Expression const& _e)
{
m_context.addAssertion(smt::Expression::implies(currentPathConditions(), _e));
}
bool SMTEncoder::isRootFunction()
{
return m_callStack.size() == 1;
}
bool SMTEncoder::visitedFunction(FunctionDefinition const* _funDef)
{
for (auto const& call: m_callStack)
if (call.first == _funDef)
return true;
return false;
}
SMTEncoder::VariableIndices SMTEncoder::copyVariableIndices()
{
VariableIndices indices;
for (auto const& var: m_context.variables())
indices.emplace(var.first, var.second->index());
return indices;
}
void SMTEncoder::resetVariableIndices(VariableIndices const& _indices)
{
for (auto const& var: _indices)
m_context.variable(*var.first)->index() = var.second;
}
Expression const* SMTEncoder::leftmostBase(IndexAccess const& _indexAccess)
{
Expression const* base = &_indexAccess.baseExpression();
while (auto access = dynamic_cast(base))
base = &access->baseExpression();
return base;
}
set SMTEncoder::touchedVariables(ASTNode const& _node)
{
solAssert(!m_callStack.empty(), "");
vector callStack;
for (auto const& call: m_callStack)
callStack.push_back(call.first);
return m_variableUsage.touchedVariables(_node, callStack);
}
VariableDeclaration const* SMTEncoder::identifierToVariable(Expression const& _expr)
{
if (auto identifier = dynamic_cast(&_expr))
{
if (auto decl = dynamic_cast(identifier->annotation().referencedDeclaration))
{
solAssert(m_context.knownVariable(*decl), "");
return decl;
}
}
return nullptr;
}
string SMTEncoder::extraComment()
{
string extra;
if (m_arrayAssignmentHappened)
extra +=
"\nNote that array aliasing is not supported,"
" therefore all mapping information is erased after"
" a mapping local variable/parameter is assigned.\n"
"You can re-introduce information using require().";
return extra;
}
FunctionDefinition const* SMTEncoder::functionCallToDefinition(FunctionCall const& _funCall)
{
if (_funCall.annotation().kind != FunctionCallKind::FunctionCall)
return nullptr;
FunctionDefinition const* funDef = nullptr;
Expression const* calledExpr = &_funCall.expression();
if (TupleExpression const* fun = dynamic_cast(&_funCall.expression()))
{
solAssert(fun->components().size() == 1, "");
calledExpr = fun->components().front().get();
}
if (Identifier const* fun = dynamic_cast(calledExpr))
funDef = dynamic_cast(fun->annotation().referencedDeclaration);
else if (MemberAccess const* fun = dynamic_cast(calledExpr))
funDef = dynamic_cast(fun->annotation().referencedDeclaration);
return funDef;
}
void SMTEncoder::createReturnedExpressions(FunctionCall const& _funCall)
{
FunctionDefinition const* funDef = functionCallToDefinition(_funCall);
if (!funDef)
return;
auto const& returnParams = funDef->returnParameters();
for (auto param: returnParams)
createVariable(*param);
if (returnParams.size() > 1)
{
auto const& symbTuple = dynamic_pointer_cast(m_context.expression(_funCall));
solAssert(symbTuple, "");
auto const& symbComponents = symbTuple->components();
solAssert(symbComponents.size() == returnParams.size(), "");
for (unsigned i = 0; i < symbComponents.size(); ++i)
{
auto sComponent = symbComponents.at(i);
auto param = returnParams.at(i);
solAssert(param, "");
if (sComponent)
{
solAssert(m_context.knownVariable(*param), "");
m_context.addAssertion(sComponent->currentValue() == currentValue(*param));
}
}
}
else if (returnParams.size() == 1)
defineExpr(_funCall, currentValue(*returnParams.front()));
}