solidity/libsolidity/formal/SMTChecker.cpp

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/*
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 <http://www.gnu.org/licenses/>.
*/
#include <libsolidity/formal/SMTChecker.h>
#include <libsolidity/formal/SMTPortfolio.h>
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#include <libsolidity/formal/SSAVariable.h>
#include <libsolidity/formal/SymbolicIntVariable.h>
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#include <libsolidity/formal/VariableUsage.h>
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#include <libsolidity/interface/ErrorReporter.h>
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#include <boost/range/adaptor/map.hpp>
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#include <boost/algorithm/string/replace.hpp>
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using namespace std;
using namespace dev;
using namespace dev::solidity;
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SMTChecker::SMTChecker(ErrorReporter& _errorReporter, ReadCallback::Callback const& _readFileCallback):
m_interface(make_shared<smt::SMTPortfolio>(_readFileCallback)),
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m_errorReporter(_errorReporter)
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{
}
void SMTChecker::analyze(SourceUnit const& _source)
{
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m_variableUsage = make_shared<VariableUsage>(_source);
if (_source.annotation().experimentalFeatures.count(ExperimentalFeature::SMTChecker))
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_source.accept(*this);
}
bool SMTChecker::visit(ContractDefinition const& _contract)
{
for (auto _var : _contract.stateVariables())
if (_var->type()->isValueType())
createVariable(*_var);
return true;
}
void SMTChecker::endVisit(ContractDefinition const&)
{
m_variables.clear();
}
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void SMTChecker::endVisit(VariableDeclaration const& _varDecl)
{
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if (_varDecl.isLocalVariable() && _varDecl.type()->isValueType() &&_varDecl.value())
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assignment(_varDecl, *_varDecl.value(), _varDecl.location());
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}
bool SMTChecker::visit(FunctionDefinition const& _function)
{
if (!_function.modifiers().empty() || _function.isConstructor())
m_errorReporter.warning(
_function.location(),
"Assertion checker does not yet support constructors and functions with modifiers."
);
m_currentFunction = &_function;
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m_interface->reset();
m_pathConditions.clear();
m_loopExecutionHappened = false;
resetStateVariables();
initializeLocalVariables(_function);
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return true;
}
void SMTChecker::endVisit(FunctionDefinition const&)
{
// TODO we could check for "reachability", i.e. satisfiability here.
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// We only handle local variables, so we clear at the beginning of the function.
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// If we add storage variables, those should be cleared differently.
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removeLocalVariables();
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m_currentFunction = nullptr;
}
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bool SMTChecker::visit(IfStatement const& _node)
{
_node.condition().accept(*this);
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checkBooleanNotConstant(_node.condition(), "Condition is always $VALUE.");
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auto countersEndTrue = visitBranch(_node.trueStatement(), expr(_node.condition()));
vector<VariableDeclaration const*> touchedVariables = m_variableUsage->touchedVariables(_node.trueStatement());
decltype(countersEndTrue) countersEndFalse;
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if (_node.falseStatement())
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{
countersEndFalse = visitBranch(*_node.falseStatement(), !expr(_node.condition()));
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touchedVariables += m_variableUsage->touchedVariables(*_node.falseStatement());
}
else
{
countersEndFalse = m_variables;
}
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mergeVariables(touchedVariables, expr(_node.condition()), countersEndTrue, countersEndFalse);
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return false;
}
bool SMTChecker::visit(WhileStatement const& _node)
{
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auto touchedVariables = m_variableUsage->touchedVariables(_node);
resetVariables(touchedVariables);
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if (_node.isDoWhile())
{
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visitBranch(_node.body());
// TODO the assertions generated in the body should still be active in the condition
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_node.condition().accept(*this);
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checkBooleanNotConstant(_node.condition(), "Do-while loop condition is always $VALUE.");
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}
else
{
_node.condition().accept(*this);
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checkBooleanNotConstant(_node.condition(), "While loop condition is always $VALUE.");
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visitBranch(_node.body(), expr(_node.condition()));
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}
m_loopExecutionHappened = true;
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resetVariables(touchedVariables);
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return false;
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}
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bool SMTChecker::visit(ForStatement const& _node)
{
if (_node.initializationExpression())
_node.initializationExpression()->accept(*this);
// Do not reset the init expression part.
auto touchedVariables =
m_variableUsage->touchedVariables(_node.body());
if (_node.condition())
touchedVariables += m_variableUsage->touchedVariables(*_node.condition());
if (_node.loopExpression())
touchedVariables += m_variableUsage->touchedVariables(*_node.loopExpression());
// Remove duplicates
std::sort(touchedVariables.begin(), touchedVariables.end());
touchedVariables.erase(std::unique(touchedVariables.begin(), touchedVariables.end()), touchedVariables.end());
resetVariables(touchedVariables);
if (_node.condition())
{
_node.condition()->accept(*this);
checkBooleanNotConstant(*_node.condition(), "For loop condition is always $VALUE.");
}
VariableSequenceCounters sequenceCountersStart = m_variables;
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m_interface->push();
if (_node.condition())
m_interface->addAssertion(expr(*_node.condition()));
_node.body().accept(*this);
if (_node.loopExpression())
_node.loopExpression()->accept(*this);
m_interface->pop();
m_loopExecutionHappened = true;
std::swap(sequenceCountersStart, m_variables);
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resetVariables(touchedVariables);
return false;
}
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void SMTChecker::endVisit(VariableDeclarationStatement const& _varDecl)
{
if (_varDecl.declarations().size() != 1)
m_errorReporter.warning(
_varDecl.location(),
"Assertion checker does not yet support such variable declarations."
);
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else if (knownVariable(*_varDecl.declarations()[0]))
{
if (_varDecl.initialValue())
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assignment(*_varDecl.declarations()[0], *_varDecl.initialValue(), _varDecl.location());
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}
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else
m_errorReporter.warning(
_varDecl.location(),
"Assertion checker does not yet implement such variable declarations."
);
}
void SMTChecker::endVisit(ExpressionStatement const&)
{
}
void SMTChecker::endVisit(Assignment const& _assignment)
{
if (_assignment.assignmentOperator() != Token::Value::Assign)
m_errorReporter.warning(
_assignment.location(),
"Assertion checker does not yet implement compound assignment."
);
else if (!SSAVariable::isSupportedType(_assignment.annotation().type->category()))
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m_errorReporter.warning(
_assignment.location(),
"Assertion checker does not yet implement type " + _assignment.annotation().type->toString()
);
else if (Identifier const* identifier = dynamic_cast<Identifier const*>(&_assignment.leftHandSide()))
{
VariableDeclaration const& decl = dynamic_cast<VariableDeclaration const&>(*identifier->annotation().referencedDeclaration);
if (knownVariable(decl))
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{
assignment(decl, _assignment.rightHandSide(), _assignment.location());
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defineExpr(_assignment, expr(_assignment.rightHandSide()));
}
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else
m_errorReporter.warning(
_assignment.location(),
"Assertion checker does not yet implement such assignments."
);
}
else
m_errorReporter.warning(
_assignment.location(),
"Assertion checker does not yet implement such assignments."
);
}
void SMTChecker::endVisit(TupleExpression const& _tuple)
{
if (_tuple.isInlineArray() || _tuple.components().size() != 1)
m_errorReporter.warning(
_tuple.location(),
"Assertion checker does not yet implement tules and inline arrays."
);
else
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defineExpr(_tuple, expr(*_tuple.components()[0]));
}
void SMTChecker::checkUnderOverflow(smt::Expression _value, IntegerType const& _type, SourceLocation const& _location)
{
checkCondition(
_value < SymbolicIntVariable::minValue(_type),
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_location,
"Underflow (resulting value less than " + formatNumber(_type.minValue()) + ")",
"<result>",
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&_value
);
checkCondition(
_value > SymbolicIntVariable::maxValue(_type),
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_location,
"Overflow (resulting value larger than " + formatNumber(_type.maxValue()) + ")",
"<result>",
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&_value
);
}
void SMTChecker::endVisit(UnaryOperation const& _op)
{
switch (_op.getOperator())
{
case Token::Not: // !
{
solAssert(SSAVariable::isBool(_op.annotation().type->category()), "");
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defineExpr(_op, !expr(_op.subExpression()));
break;
}
case Token::Inc: // ++ (pre- or postfix)
case Token::Dec: // -- (pre- or postfix)
{
solAssert(SSAVariable::isInteger(_op.annotation().type->category()), "");
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solAssert(_op.subExpression().annotation().lValueRequested, "");
if (Identifier const* identifier = dynamic_cast<Identifier const*>(&_op.subExpression()))
{
VariableDeclaration const& decl = dynamic_cast<VariableDeclaration const&>(*identifier->annotation().referencedDeclaration);
if (knownVariable(decl))
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{
auto innerValue = currentValue(decl);
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auto newValue = _op.getOperator() == Token::Inc ? innerValue + 1 : innerValue - 1;
assignment(decl, newValue, _op.location());
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defineExpr(_op, _op.isPrefixOperation() ? newValue : innerValue);
}
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement such assignments."
);
}
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement such increments / decrements."
);
break;
}
case Token::Add: // +
defineExpr(_op, expr(_op.subExpression()));
break;
case Token::Sub: // -
{
defineExpr(_op, 0 - expr(_op.subExpression()));
if (auto intType = dynamic_cast<IntegerType const*>(_op.annotation().type.get()))
checkUnderOverflow(expr(_op), *intType, _op.location());
break;
}
default:
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement this operator."
);
}
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}
void SMTChecker::endVisit(BinaryOperation const& _op)
{
if (Token::isArithmeticOp(_op.getOperator()))
arithmeticOperation(_op);
else if (Token::isCompareOp(_op.getOperator()))
compareOperation(_op);
else if (Token::isBooleanOp(_op.getOperator()))
booleanOperation(_op);
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement this operator."
);
}
void SMTChecker::endVisit(FunctionCall const& _funCall)
{
solAssert(_funCall.annotation().kind != FunctionCallKind::Unset, "");
if (_funCall.annotation().kind != FunctionCallKind::FunctionCall)
{
m_errorReporter.warning(
_funCall.location(),
"Assertion checker does not yet implement this expression."
);
return;
}
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FunctionType const& funType = dynamic_cast<FunctionType const&>(*_funCall.expression().annotation().type);
std::vector<ASTPointer<Expression const>> const args = _funCall.arguments();
if (funType.kind() == FunctionType::Kind::Assert)
{
solAssert(args.size() == 1, "");
solAssert(args[0]->annotation().type->category() == Type::Category::Bool, "");
checkCondition(!(expr(*args[0])), _funCall.location(), "Assertion violation");
addPathImpliedExpression(expr(*args[0]));
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}
else if (funType.kind() == FunctionType::Kind::Require)
{
solAssert(args.size() == 1, "");
solAssert(args[0]->annotation().type->category() == Type::Category::Bool, "");
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checkBooleanNotConstant(*args[0], "Condition is always $VALUE.");
addPathImpliedExpression(expr(*args[0]));
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}
}
void SMTChecker::endVisit(Identifier const& _identifier)
{
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if (_identifier.annotation().lValueRequested)
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{
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// Will be translated as part of the node that requested the lvalue.
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}
else if (SSAVariable::isSupportedType(_identifier.annotation().type->category()))
{
if (VariableDeclaration const* decl = dynamic_cast<VariableDeclaration const*>(_identifier.annotation().referencedDeclaration))
defineExpr(_identifier, currentValue(*decl));
else
// TODO: handle MagicVariableDeclaration here
m_errorReporter.warning(
_identifier.location(),
"Assertion checker does not yet support the type of this variable."
);
}
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else if (FunctionType const* fun = dynamic_cast<FunctionType const*>(_identifier.annotation().type.get()))
{
if (fun->kind() == FunctionType::Kind::Assert || fun->kind() == FunctionType::Kind::Require)
return;
}
}
void SMTChecker::endVisit(Literal const& _literal)
{
Type const& type = *_literal.annotation().type;
if (type.category() == Type::Category::Integer || type.category() == Type::Category::RationalNumber)
{
if (RationalNumberType const* rational = dynamic_cast<RationalNumberType const*>(&type))
solAssert(!rational->isFractional(), "");
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defineExpr(_literal, smt::Expression(type.literalValue(&_literal)));
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}
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else if (type.category() == Type::Category::Bool)
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defineExpr(_literal, smt::Expression(_literal.token() == Token::TrueLiteral ? true : false));
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else
m_errorReporter.warning(
_literal.location(),
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"Assertion checker does not yet support the type of this literal (" +
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_literal.annotation().type->toString() +
")."
);
}
void SMTChecker::arithmeticOperation(BinaryOperation const& _op)
{
switch (_op.getOperator())
{
case Token::Add:
case Token::Sub:
case Token::Mul:
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case Token::Div:
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{
solAssert(_op.annotation().commonType, "");
if (_op.annotation().commonType->category() != Type::Category::Integer)
{
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement this operator on non-integer types."
);
break;
}
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auto const& intType = dynamic_cast<IntegerType const&>(*_op.annotation().commonType);
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smt::Expression left(expr(_op.leftExpression()));
smt::Expression right(expr(_op.rightExpression()));
Token::Value op = _op.getOperator();
smt::Expression value(
op == Token::Add ? left + right :
op == Token::Sub ? left - right :
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op == Token::Div ? division(left, right, intType) :
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/*op == Token::Mul*/ left * right
);
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if (_op.getOperator() == Token::Div)
{
checkCondition(right == 0, _op.location(), "Division by zero", "<result>", &right);
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m_interface->addAssertion(right != 0);
}
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checkUnderOverflow(value, intType, _op.location());
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defineExpr(_op, value);
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break;
}
default:
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement this operator."
);
}
}
void SMTChecker::compareOperation(BinaryOperation const& _op)
{
solAssert(_op.annotation().commonType, "");
if (SSAVariable::isSupportedType(_op.annotation().commonType->category()))
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{
smt::Expression left(expr(_op.leftExpression()));
smt::Expression right(expr(_op.rightExpression()));
Token::Value op = _op.getOperator();
shared_ptr<smt::Expression> value;
if (SSAVariable::isInteger(_op.annotation().commonType->category()))
{
value = make_shared<smt::Expression>(
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(SSAVariable::isBool(_op.annotation().commonType->category()), "Operation not yet supported");
value = make_shared<smt::Expression>(
op == Token::Equal ? (left == right) :
/*op == Token::NotEqual*/ (left != right)
);
}
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// TODO: check that other values for op are not possible.
defineExpr(_op, *value);
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}
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement the type " + _op.annotation().commonType->toString() + " for comparisons"
);
}
void SMTChecker::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)
{
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// @TODO check that both of them are not constant
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if (_op.getOperator() == Token::And)
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defineExpr(_op, expr(_op.leftExpression()) && expr(_op.rightExpression()));
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else
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defineExpr(_op, expr(_op.leftExpression()) || expr(_op.rightExpression()));
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}
else
m_errorReporter.warning(
_op.location(),
"Assertion checker does not yet implement the type " + _op.annotation().commonType->toString() + " for boolean operations"
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);
}
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smt::Expression SMTChecker::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 SMTChecker::assignment(VariableDeclaration const& _variable, Expression const& _value, SourceLocation const& _location)
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{
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assignment(_variable, expr(_value), _location);
}
void SMTChecker::assignment(VariableDeclaration const& _variable, smt::Expression const& _value, SourceLocation const& _location)
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{
TypePointer type = _variable.type();
if (auto const* intType = dynamic_cast<IntegerType const*>(type.get()))
checkUnderOverflow(_value, *intType, _location);
m_interface->addAssertion(newValue(_variable) == _value);
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}
SMTChecker::VariableSequenceCounters SMTChecker::visitBranch(Statement const& _statement, smt::Expression _condition)
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{
return visitBranch(_statement, &_condition);
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}
SMTChecker::VariableSequenceCounters SMTChecker::visitBranch(Statement const& _statement, smt::Expression const* _condition)
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{
VariableSequenceCounters beforeVars = m_variables;
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if (_condition)
pushPathCondition(*_condition);
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_statement.accept(*this);
if (_condition)
popPathCondition();
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std::swap(m_variables, beforeVars);
return beforeVars;
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}
void SMTChecker::checkCondition(
smt::Expression _condition,
SourceLocation const& _location,
string const& _description,
string const& _additionalValueName,
smt::Expression* _additionalValue
)
{
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m_interface->push();
addPathConjoinedExpression(_condition);
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vector<smt::Expression> expressionsToEvaluate;
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vector<string> expressionNames;
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if (m_currentFunction)
{
if (_additionalValue)
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{
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expressionsToEvaluate.emplace_back(*_additionalValue);
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expressionNames.push_back(_additionalValueName);
}
for (auto const& var: m_variables)
if (knownVariable(*var.first))
{
expressionsToEvaluate.emplace_back(currentValue(*var.first));
expressionNames.push_back(var.first->name());
}
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}
smt::CheckResult result;
vector<string> values;
tie(result, values) = checkSatisfiableAndGenerateModel(expressionsToEvaluate);
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string loopComment;
if (m_loopExecutionHappened)
loopComment =
"\nNote that some information is erased after the execution of loops.\n"
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"You can re-introduce information using require().";
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switch (result)
{
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case smt::CheckResult::SATISFIABLE:
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{
std::ostringstream message;
message << _description << " happens here";
if (m_currentFunction)
{
std::ostringstream modelMessage;
modelMessage << " for:\n";
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solAssert(values.size() == expressionNames.size(), "");
map<string, string> sortedModel;
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for (size_t i = 0; i < values.size(); ++i)
if (expressionsToEvaluate.at(i).name != values.at(i))
sortedModel[expressionNames.at(i)] = values.at(i);
for (auto const& eval: sortedModel)
modelMessage << " " << eval.first << " = " << eval.second << "\n";
m_errorReporter.warning(_location, message.str() + loopComment, SecondarySourceLocation().append(modelMessage.str(), SourceLocation()));
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}
else
{
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message << ".";
m_errorReporter.warning(_location, message.str() + loopComment);
}
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break;
}
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case smt::CheckResult::UNSATISFIABLE:
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break;
case smt::CheckResult::UNKNOWN:
m_errorReporter.warning(_location, _description + " might happen here." + loopComment);
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break;
case smt::CheckResult::CONFLICTING:
m_errorReporter.warning(_location, "At least two SMT solvers provided conflicting answers. Results might not be sound.");
break;
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case smt::CheckResult::ERROR:
m_errorReporter.warning(_location, "Error trying to invoke SMT solver.");
break;
default:
solAssert(false, "");
}
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m_interface->pop();
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}
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void SMTChecker::checkBooleanNotConstant(Expression const& _condition, string const& _description)
{
// Do not check for const-ness if this is a constant.
if (dynamic_cast<Literal const*>(&_condition))
return;
m_interface->push();
addPathConjoinedExpression(expr(_condition));
auto positiveResult = checkSatisfiable();
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m_interface->pop();
m_interface->push();
addPathConjoinedExpression(!expr(_condition));
auto negatedResult = checkSatisfiable();
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m_interface->pop();
if (positiveResult == smt::CheckResult::ERROR || negatedResult == smt::CheckResult::ERROR)
m_errorReporter.warning(_condition.location(), "Error trying to invoke SMT solver.");
else if (positiveResult == smt::CheckResult::CONFLICTING || negatedResult == smt::CheckResult::CONFLICTING)
m_errorReporter.warning(_condition.location(), "At least two SMT solvers provided conflicting answers. Results might not be sound.");
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else if (positiveResult == smt::CheckResult::SATISFIABLE && negatedResult == smt::CheckResult::SATISFIABLE)
{
// everything fine.
}
else if (positiveResult == smt::CheckResult::UNSATISFIABLE && negatedResult == smt::CheckResult::UNSATISFIABLE)
m_errorReporter.warning(_condition.location(), "Condition unreachable.");
else
{
string value;
if (positiveResult == smt::CheckResult::SATISFIABLE)
{
solAssert(negatedResult == smt::CheckResult::UNSATISFIABLE, "");
value = "true";
}
else
{
solAssert(positiveResult == smt::CheckResult::UNSATISFIABLE, "");
solAssert(negatedResult == smt::CheckResult::SATISFIABLE, "");
value = "false";
}
m_errorReporter.warning(_condition.location(), boost::algorithm::replace_all_copy(_description, "$VALUE", value));
}
}
pair<smt::CheckResult, vector<string>>
SMTChecker::checkSatisfiableAndGenerateModel(vector<smt::Expression> const& _expressionsToEvaluate)
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{
smt::CheckResult result;
vector<string> values;
try
{
tie(result, values) = m_interface->check(_expressionsToEvaluate);
}
catch (smt::SolverError const& _e)
{
string description("Error querying SMT solver");
if (_e.comment())
description += ": " + *_e.comment();
m_errorReporter.warning(description);
result = smt::CheckResult::ERROR;
}
for (string& value: values)
{
try
{
// Parse and re-format nicely
value = formatNumber(bigint(value));
}
catch (...) { }
}
return make_pair(result, values);
}
smt::CheckResult SMTChecker::checkSatisfiable()
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{
return checkSatisfiableAndGenerateModel({}).first;
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}
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void SMTChecker::initializeLocalVariables(FunctionDefinition const& _function)
{
for (auto const& variable: _function.localVariables())
if (createVariable(*variable))
setZeroValue(*variable);
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for (auto const& param: _function.parameters())
if (createVariable(*param))
setUnknownValue(*param);
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if (_function.returnParameterList())
for (auto const& retParam: _function.returnParameters())
if (createVariable(*retParam))
setZeroValue(*retParam);
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}
void SMTChecker::resetStateVariables()
{
for (auto const& variable: m_variables)
{
if (variable.first->isStateVariable())
{
newValue(*variable.first);
setUnknownValue(*variable.first);
}
}
}
void SMTChecker::resetVariables(vector<VariableDeclaration const*> _variables)
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{
for (auto const* decl: _variables)
{
newValue(*decl);
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setUnknownValue(*decl);
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}
}
void SMTChecker::mergeVariables(vector<VariableDeclaration const*> const& _variables, smt::Expression const& _condition, VariableSequenceCounters const& _countersEndTrue, VariableSequenceCounters const& _countersEndFalse)
{
set<VariableDeclaration const*> uniqueVars(_variables.begin(), _variables.end());
for (auto const* decl: uniqueVars)
{
solAssert(_countersEndTrue.count(decl) && _countersEndFalse.count(decl), "");
int trueCounter = _countersEndTrue.at(decl).index();
int falseCounter = _countersEndFalse.at(decl).index();
solAssert(trueCounter != falseCounter, "");
m_interface->addAssertion(newValue(*decl) == smt::Expression::ite(
_condition,
valueAtSequence(*decl, trueCounter),
valueAtSequence(*decl, falseCounter))
);
}
}
bool SMTChecker::createVariable(VariableDeclaration const& _varDecl)
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{
if (SSAVariable::isSupportedType(_varDecl.type()->category()))
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{
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solAssert(m_variables.count(&_varDecl) == 0, "");
m_variables.emplace(&_varDecl, SSAVariable(_varDecl, *m_interface));
return true;
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}
else
{
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m_errorReporter.warning(
_varDecl.location(),
"Assertion checker does not yet support the type of this variable."
);
return false;
}
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}
string SMTChecker::uniqueSymbol(Expression const& _expr)
{
return "expr_" + to_string(_expr.id());
}
bool SMTChecker::knownVariable(VariableDeclaration const& _decl)
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{
return m_variables.count(&_decl);
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}
smt::Expression SMTChecker::currentValue(VariableDeclaration const& _decl)
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{
solAssert(knownVariable(_decl), "");
return m_variables.at(&_decl)();
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}
smt::Expression SMTChecker::valueAtSequence(VariableDeclaration const& _decl, int _sequence)
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{
solAssert(knownVariable(_decl), "");
return m_variables.at(&_decl)(_sequence);
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}
smt::Expression SMTChecker::newValue(VariableDeclaration const& _decl)
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{
solAssert(knownVariable(_decl), "");
++m_variables.at(&_decl);
return m_variables.at(&_decl)();
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}
void SMTChecker::setZeroValue(VariableDeclaration const& _decl)
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{
solAssert(knownVariable(_decl), "");
m_variables.at(&_decl).setZeroValue();
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}
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void SMTChecker::setUnknownValue(VariableDeclaration const& _decl)
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{
solAssert(knownVariable(_decl), "");
m_variables.at(&_decl).setUnknownValue();
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}
smt::Expression SMTChecker::expr(Expression const& _e)
{
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if (!m_expressions.count(&_e))
{
m_errorReporter.warning(_e.location(), "Internal error: Expression undefined for SMT solver." );
createExpr(_e);
}
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return m_expressions.at(&_e);
}
void SMTChecker::createExpr(Expression const& _e)
{
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if (m_expressions.count(&_e))
m_errorReporter.warning(_e.location(), "Internal error: Expression created twice in SMT solver." );
else
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{
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solAssert(_e.annotation().type, "");
switch (_e.annotation().type->category())
{
case Type::Category::RationalNumber:
{
if (RationalNumberType const* rational = dynamic_cast<RationalNumberType const*>(_e.annotation().type.get()))
solAssert(!rational->isFractional(), "");
m_expressions.emplace(&_e, m_interface->newInteger(uniqueSymbol(_e)));
break;
}
case Type::Category::Integer:
m_expressions.emplace(&_e, m_interface->newInteger(uniqueSymbol(_e)));
break;
case Type::Category::Bool:
m_expressions.emplace(&_e, m_interface->newBool(uniqueSymbol(_e)));
break;
default:
solUnimplementedAssert(false, "Type not implemented.");
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}
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}
}
void SMTChecker::defineExpr(Expression const& _e, smt::Expression _value)
{
createExpr(_e);
m_interface->addAssertion(expr(_e) == _value);
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}
void SMTChecker::popPathCondition()
{
solAssert(m_pathConditions.size() > 0, "Cannot pop path condition, empty.");
m_pathConditions.pop_back();
}
void SMTChecker::pushPathCondition(smt::Expression const& _e)
{
m_pathConditions.push_back(currentPathConditions() && _e);
}
smt::Expression SMTChecker::currentPathConditions()
{
if (m_pathConditions.size() == 0)
return smt::Expression(true);
return m_pathConditions.back();
}
void SMTChecker::addPathConjoinedExpression(smt::Expression const& _e)
{
m_interface->addAssertion(currentPathConditions() && _e);
}
void SMTChecker::addPathImpliedExpression(smt::Expression const& _e)
{
m_interface->addAssertion(smt::Expression::implies(currentPathConditions(), _e));
}
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void SMTChecker::removeLocalVariables()
{
for (auto it = m_variables.begin(); it != m_variables.end(); )
{
if (it->first->isLocalVariable())
it = m_variables.erase(it);
else
++it;
}
}