solidity/libsolidity/formal/BMC.cpp

1057 lines
30 KiB
C++

/*
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/>.
*/
// SPDX-License-Identifier: GPL-3.0
#include <libsolidity/formal/BMC.h>
#include <libsolidity/formal/SymbolicState.h>
#include <libsolidity/formal/SymbolicTypes.h>
#include <libsmtutil/SMTPortfolio.h>
#ifdef HAVE_Z3_DLOPEN
#include <z3_version.h>
#endif
using namespace std;
using namespace solidity;
using namespace solidity::util;
using namespace solidity::langutil;
using namespace solidity::frontend;
BMC::BMC(
smt::EncodingContext& _context,
ErrorReporter& _errorReporter,
map<h256, string> const& _smtlib2Responses,
ReadCallback::Callback const& _smtCallback,
smtutil::SMTSolverChoice _enabledSolvers,
ModelCheckerSettings const& _settings
):
SMTEncoder(_context),
m_interface(make_unique<smtutil::SMTPortfolio>(_smtlib2Responses, _smtCallback, _enabledSolvers, _settings.timeout)),
m_outerErrorReporter(_errorReporter),
m_settings(_settings)
{
#if defined (HAVE_Z3) || defined (HAVE_CVC4)
if (_enabledSolvers.some())
if (!_smtlib2Responses.empty())
m_errorReporter.warning(
5622_error,
"SMT-LIB2 query responses were given in the auxiliary input, "
"but this Solidity binary uses an SMT solver (Z3/CVC4) directly."
"These responses will be ignored."
"Consider disabling Z3/CVC4 at compilation time in order to use SMT-LIB2 responses."
);
#endif
}
void BMC::analyze(SourceUnit const& _source, map<ASTNode const*, set<VerificationTargetType>> _solvedTargets)
{
solAssert(_source.annotation().experimentalFeatures.count(ExperimentalFeature::SMTChecker), "");
/// This is currently used to abort analysis of SourceUnits
/// containing file level functions or constants.
if (SMTEncoder::analyze(_source))
{
m_solvedTargets = move(_solvedTargets);
m_context.setSolver(m_interface.get());
m_context.clear();
m_context.setAssertionAccumulation(true);
m_variableUsage.setFunctionInlining(shouldInlineFunctionCall);
_source.accept(*this);
}
solAssert(m_interface->solvers() > 0, "");
// If this check is true, Z3 and CVC4 are not available
// and the query answers were not provided, since SMTPortfolio
// guarantees that SmtLib2Interface is the first solver.
if (!m_interface->unhandledQueries().empty() && m_interface->solvers() == 1)
{
if (!m_noSolverWarning)
{
m_noSolverWarning = true;
m_outerErrorReporter.warning(
8084_error,
SourceLocation(),
"BMC analysis was not possible since no SMT solver (Z3 or CVC4) was found."
#ifdef HAVE_Z3_DLOPEN
" Install libz3.so." + to_string(Z3_MAJOR_VERSION) + "." + to_string(Z3_MINOR_VERSION) + " to enable Z3."
#endif
);
}
}
else
m_outerErrorReporter.append(m_errorReporter.errors());
m_errorReporter.clear();
}
bool BMC::shouldInlineFunctionCall(
FunctionCall const& _funCall,
ContractDefinition const* _scopeContract,
ContractDefinition const* _contextContract
)
{
auto funDef = functionCallToDefinition(_funCall, _scopeContract, _contextContract);
if (!funDef || !funDef->isImplemented())
return false;
FunctionType const& funType = dynamic_cast<FunctionType const&>(*_funCall.expression().annotation().type);
if (funType.kind() == FunctionType::Kind::External)
return isTrustedExternalCall(&_funCall.expression());
else if (funType.kind() != FunctionType::Kind::Internal)
return false;
return true;
}
/// AST visitors.
bool BMC::visit(ContractDefinition const& _contract)
{
initContract(_contract);
SMTEncoder::visit(_contract);
return false;
}
void BMC::endVisit(ContractDefinition const& _contract)
{
if (auto constructor = _contract.constructor())
constructor->accept(*this);
else
{
/// Visiting implicit constructor - we need a dummy callstack frame
pushCallStack({nullptr, nullptr});
inlineConstructorHierarchy(_contract);
popCallStack();
/// Check targets created by state variable initialization.
checkVerificationTargets();
m_verificationTargets.clear();
}
SMTEncoder::endVisit(_contract);
}
bool BMC::visit(FunctionDefinition const& _function)
{
auto contract = dynamic_cast<ContractDefinition const*>(_function.scope());
solAssert(contract, "");
solAssert(m_currentContract, "");
auto const& hierarchy = m_currentContract->annotation().linearizedBaseContracts;
if (find(hierarchy.begin(), hierarchy.end(), contract) == hierarchy.end())
createStateVariables(*contract);
if (m_callStack.empty())
{
reset();
initFunction(_function);
m_context.addAssertion(state().txTypeConstraints() && state().txFunctionConstraints(_function));
resetStateVariables();
}
if (_function.isConstructor())
inlineConstructorHierarchy(dynamic_cast<ContractDefinition const&>(*_function.scope()));
/// Already visits the children.
SMTEncoder::visit(_function);
return false;
}
void BMC::endVisit(FunctionDefinition const& _function)
{
if (isRootFunction())
{
checkVerificationTargets();
m_verificationTargets.clear();
m_pathConditions.clear();
}
SMTEncoder::endVisit(_function);
}
bool BMC::visit(IfStatement const& _node)
{
// This check needs to be done in its own context otherwise
// constraints from the If body might influence it.
m_context.pushSolver();
_node.condition().accept(*this);
// We ignore called functions here because they have
// specific input values.
if (isRootFunction())
addVerificationTarget(
VerificationTargetType::ConstantCondition,
expr(_node.condition()),
&_node.condition()
);
m_context.popSolver();
_node.condition().accept(*this);
auto conditionExpr = expr(_node.condition());
// visit true branch
auto [indicesEndTrue, trueEndPathCondition] = visitBranch(&_node.trueStatement(), conditionExpr);
auto touchedVars = touchedVariables(_node.trueStatement());
// visit false branch
decltype(indicesEndTrue) indicesEndFalse;
auto falseEndPathCondition = currentPathConditions() && !conditionExpr;
if (_node.falseStatement())
{
std::tie(indicesEndFalse, falseEndPathCondition) = visitBranch(_node.falseStatement(), !conditionExpr);
touchedVars += touchedVariables(*_node.falseStatement());
}
else
indicesEndFalse = copyVariableIndices();
// merge the information from branches
setPathCondition(trueEndPathCondition || falseEndPathCondition);
mergeVariables(touchedVars, expr(_node.condition()), indicesEndTrue, indicesEndFalse);
return false;
}
bool BMC::visit(Conditional const& _op)
{
m_context.pushSolver();
_op.condition().accept(*this);
if (isRootFunction())
addVerificationTarget(
VerificationTargetType::ConstantCondition,
expr(_op.condition()),
&_op.condition()
);
m_context.popSolver();
SMTEncoder::visit(_op);
return false;
}
// Here we consider the execution of two branches:
// Branch 1 assumes the loop condition to be true and executes the loop once,
// after resetting touched variables.
// Branch 2 assumes the loop condition to be false and skips the loop after
// visiting the condition (it might contain side-effects, they need to be considered)
// and does not erase knowledge.
// If the loop is a do-while, condition side-effects are lost since the body,
// executed once before the condition, might reassign variables.
// Variables touched by the loop are merged with Branch 2.
bool BMC::visit(WhileStatement const& _node)
{
auto indicesBeforeLoop = copyVariableIndices();
auto touchedVars = touchedVariables(_node);
m_context.resetVariables(touchedVars);
decltype(indicesBeforeLoop) indicesAfterLoop;
if (_node.isDoWhile())
{
indicesAfterLoop = visitBranch(&_node.body()).first;
// TODO the assertions generated in the body should still be active in the condition
_node.condition().accept(*this);
if (isRootFunction())
addVerificationTarget(
VerificationTargetType::ConstantCondition,
expr(_node.condition()),
&_node.condition()
);
}
else
{
_node.condition().accept(*this);
if (isRootFunction())
addVerificationTarget(
VerificationTargetType::ConstantCondition,
expr(_node.condition()),
&_node.condition()
);
indicesAfterLoop = visitBranch(&_node.body(), expr(_node.condition())).first;
}
// We reset the execution to before the loop
// and visit the condition in case it's not a do-while.
// A do-while's body might have non-precise information
// in its first run about variables that are touched.
resetVariableIndices(indicesBeforeLoop);
if (!_node.isDoWhile())
_node.condition().accept(*this);
mergeVariables(touchedVars, expr(_node.condition()), indicesAfterLoop, copyVariableIndices());
m_loopExecutionHappened = true;
return false;
}
// Here we consider the execution of two branches similar to WhileStatement.
bool BMC::visit(ForStatement const& _node)
{
if (_node.initializationExpression())
_node.initializationExpression()->accept(*this);
auto indicesBeforeLoop = copyVariableIndices();
// Do not reset the init expression part.
auto touchedVars = touchedVariables(_node.body());
if (_node.condition())
touchedVars += touchedVariables(*_node.condition());
if (_node.loopExpression())
touchedVars += touchedVariables(*_node.loopExpression());
m_context.resetVariables(touchedVars);
if (_node.condition())
{
_node.condition()->accept(*this);
if (isRootFunction())
addVerificationTarget(
VerificationTargetType::ConstantCondition,
expr(*_node.condition()),
_node.condition()
);
}
m_context.pushSolver();
if (_node.condition())
m_context.addAssertion(expr(*_node.condition()));
_node.body().accept(*this);
if (_node.loopExpression())
_node.loopExpression()->accept(*this);
m_context.popSolver();
auto indicesAfterLoop = copyVariableIndices();
// We reset the execution to before the loop
// and visit the condition.
resetVariableIndices(indicesBeforeLoop);
if (_node.condition())
_node.condition()->accept(*this);
auto forCondition = _node.condition() ? expr(*_node.condition()) : smtutil::Expression(true);
mergeVariables(touchedVars, forCondition, indicesAfterLoop, copyVariableIndices());
m_loopExecutionHappened = true;
return false;
}
bool BMC::visit(TryStatement const& _tryStatement)
{
FunctionCall const* externalCall = dynamic_cast<FunctionCall const*>(&_tryStatement.externalCall());
solAssert(externalCall && externalCall->annotation().tryCall, "");
externalCall->accept(*this);
if (_tryStatement.successClause()->parameters())
expressionToTupleAssignment(_tryStatement.successClause()->parameters()->parameters(), *externalCall);
smtutil::Expression clauseId = m_context.newVariable("clause_choice_" + to_string(m_context.newUniqueId()), smtutil::SortProvider::uintSort);
auto const& clauses = _tryStatement.clauses();
m_context.addAssertion(clauseId >= 0 && clauseId < clauses.size());
solAssert(clauses[0].get() == _tryStatement.successClause(), "First clause of TryStatement should be the success clause");
vector<set<VariableDeclaration const*>> touchedVars;
vector<pair<VariableIndices, smtutil::Expression>> clausesVisitResults;
for (size_t i = 0; i < clauses.size(); ++i)
{
clausesVisitResults.push_back(visitBranch(clauses[i].get()));
touchedVars.push_back(touchedVariables(*clauses[i]));
}
// merge the information from all clauses
smtutil::Expression pathCondition = clausesVisitResults.front().second;
auto currentIndices = clausesVisitResults[0].first;
for (size_t i = 1; i < clauses.size(); ++i)
{
mergeVariables(touchedVars[i - 1] + touchedVars[i], clauseId == i, clausesVisitResults[i].first, currentIndices);
currentIndices = copyVariableIndices();
pathCondition = pathCondition || clausesVisitResults[i].second;
}
setPathCondition(pathCondition);
return false;
}
void BMC::endVisit(UnaryOperation const& _op)
{
SMTEncoder::endVisit(_op);
if (
_op.annotation().type->category() == Type::Category::RationalNumber ||
_op.annotation().type->category() == Type::Category::FixedPoint
)
return;
if (_op.getOperator() == Token::Sub && smt::isInteger(*_op.annotation().type))
addVerificationTarget(
VerificationTargetType::UnderOverflow,
expr(_op),
&_op
);
}
void BMC::endVisit(FunctionCall const& _funCall)
{
auto functionCallKind = *_funCall.annotation().kind;
if (functionCallKind != FunctionCallKind::FunctionCall)
{
SMTEncoder::endVisit(_funCall);
return;
}
FunctionType const& funType = dynamic_cast<FunctionType const&>(*_funCall.expression().annotation().type);
switch (funType.kind())
{
case FunctionType::Kind::Assert:
visitAssert(_funCall);
SMTEncoder::endVisit(_funCall);
break;
case FunctionType::Kind::Require:
visitRequire(_funCall);
SMTEncoder::endVisit(_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:
SMTEncoder::endVisit(_funCall);
internalOrExternalFunctionCall(_funCall);
break;
case FunctionType::Kind::Send:
case FunctionType::Kind::Transfer:
{
auto value = _funCall.arguments().front();
solAssert(value, "");
smtutil::Expression thisBalance = state().balance();
addVerificationTarget(
VerificationTargetType::Balance,
thisBalance < expr(*value),
&_funCall
);
SMTEncoder::endVisit(_funCall);
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:
[[fallthrough]];
default:
SMTEncoder::endVisit(_funCall);
break;
}
}
void BMC::endVisit(Return const& _return)
{
SMTEncoder::endVisit(_return);
setPathCondition(smtutil::Expression(false));
}
/// Visitor helpers.
void BMC::visitAssert(FunctionCall const& _funCall)
{
auto const& args = _funCall.arguments();
solAssert(args.size() == 1, "");
solAssert(args.front()->annotation().type->category() == Type::Category::Bool, "");
addVerificationTarget(
VerificationTargetType::Assert,
expr(*args.front()),
&_funCall
);
}
void BMC::visitRequire(FunctionCall const& _funCall)
{
auto const& args = _funCall.arguments();
solAssert(args.size() >= 1, "");
solAssert(args.front()->annotation().type->category() == Type::Category::Bool, "");
if (isRootFunction())
addVerificationTarget(
VerificationTargetType::ConstantCondition,
expr(*args.front()),
args.front().get()
);
}
void BMC::visitAddMulMod(FunctionCall const& _funCall)
{
solAssert(_funCall.arguments().at(2), "");
addVerificationTarget(
VerificationTargetType::DivByZero,
expr(*_funCall.arguments().at(2)),
&_funCall
);
SMTEncoder::visitAddMulMod(_funCall);
}
void BMC::inlineFunctionCall(FunctionCall const& _funCall)
{
solAssert(shouldInlineFunctionCall(_funCall, currentScopeContract(), m_currentContract), "");
auto funDef = functionCallToDefinition(_funCall, currentScopeContract(), m_currentContract);
solAssert(funDef, "");
if (visitedFunction(funDef))
{
auto const& returnParams = funDef->returnParameters();
for (auto param: returnParams)
{
m_context.newValue(*param);
m_context.setUnknownValue(*param);
}
}
else
{
initializeFunctionCallParameters(*funDef, symbolicArguments(_funCall, m_currentContract));
// The reason why we need to pushCallStack here instead of visit(FunctionDefinition)
// is that there we don't have `_funCall`.
pushCallStack({funDef, &_funCall});
pushPathCondition(currentPathConditions());
auto oldChecked = std::exchange(m_checked, true);
funDef->accept(*this);
m_checked = oldChecked;
popPathCondition();
}
createReturnedExpressions(_funCall, m_currentContract);
}
void BMC::internalOrExternalFunctionCall(FunctionCall const& _funCall)
{
auto const& funType = dynamic_cast<FunctionType const&>(*_funCall.expression().annotation().type);
if (shouldInlineFunctionCall(_funCall, currentScopeContract(), m_currentContract))
inlineFunctionCall(_funCall);
else if (isPublicGetter(_funCall.expression()))
{
// Do nothing here.
// The processing happens in SMT Encoder, but we need to prevent the resetting of the state variables.
}
else if (funType.kind() == FunctionType::Kind::Internal)
m_errorReporter.warning(
5729_error,
_funCall.location(),
"BMC does not yet implement this type of function call."
);
else
{
m_externalFunctionCallHappened = true;
resetStorageVariables();
}
}
pair<smtutil::Expression, smtutil::Expression> BMC::arithmeticOperation(
Token _op,
smtutil::Expression const& _left,
smtutil::Expression const& _right,
Type const* _commonType,
Expression const& _expression
)
{
// Unchecked does not disable div by 0 checks.
if (_op == Token::Div || _op == Token::Mod)
addVerificationTarget(
VerificationTargetType::DivByZero,
_right,
&_expression
);
auto values = SMTEncoder::arithmeticOperation(_op, _left, _right, _commonType, _expression);
if (!m_checked)
return values;
auto const* intType = dynamic_cast<IntegerType const*>(_commonType);
if (!intType)
intType = TypeProvider::uint256();
// Mod does not need underflow/overflow checks.
if (_op == Token::Mod)
return values;
VerificationTargetType type;
// The order matters here:
// If _op is Div and intType is signed, we only care about overflow.
if (_op == Token::Div)
{
if (intType->isSigned())
// Signed division can only overflow.
type = VerificationTargetType::Overflow;
else
// Unsigned division cannot underflow/overflow.
return values;
}
else if (intType->isSigned())
type = VerificationTargetType::UnderOverflow;
else if (_op == Token::Sub)
type = VerificationTargetType::Underflow;
else if (_op == Token::Add || _op == Token::Mul)
type = VerificationTargetType::Overflow;
else
solAssert(false, "");
addVerificationTarget(
type,
values.second,
&_expression
);
return values;
}
void BMC::reset()
{
m_externalFunctionCallHappened = false;
m_loopExecutionHappened = false;
}
pair<vector<smtutil::Expression>, vector<string>> BMC::modelExpressions()
{
vector<smtutil::Expression> expressionsToEvaluate;
vector<string> expressionNames;
for (auto const& var: m_context.variables())
if (var.first->type()->isValueType())
{
expressionsToEvaluate.emplace_back(currentValue(*var.first));
expressionNames.push_back(var.first->name());
}
for (auto const& var: m_context.globalSymbols())
{
auto const& type = var.second->type();
if (
type->isValueType() &&
smt::smtKind(*type) != smtutil::Kind::Function
)
{
expressionsToEvaluate.emplace_back(var.second->currentValue());
expressionNames.push_back(var.first);
}
}
for (auto const& uf: m_uninterpretedTerms)
if (uf->annotation().type->isValueType())
{
expressionsToEvaluate.emplace_back(expr(*uf));
expressionNames.push_back(uf->location().text());
}
return {expressionsToEvaluate, expressionNames};
}
/// Verification targets.
void BMC::checkVerificationTargets()
{
for (auto& target: m_verificationTargets)
checkVerificationTarget(target);
}
void BMC::checkVerificationTarget(BMCVerificationTarget& _target)
{
switch (_target.type)
{
case VerificationTargetType::ConstantCondition:
checkConstantCondition(_target);
break;
case VerificationTargetType::Underflow:
checkUnderflow(_target);
break;
case VerificationTargetType::Overflow:
checkOverflow(_target);
break;
case VerificationTargetType::UnderOverflow:
checkUnderflow(_target);
checkOverflow(_target);
break;
case VerificationTargetType::DivByZero:
checkDivByZero(_target);
break;
case VerificationTargetType::Balance:
checkBalance(_target);
break;
case VerificationTargetType::Assert:
checkAssert(_target);
break;
default:
solAssert(false, "");
}
}
void BMC::checkConstantCondition(BMCVerificationTarget& _target)
{
checkBooleanNotConstant(
*_target.expression,
_target.constraints,
_target.value,
_target.callStack
);
}
void BMC::checkUnderflow(BMCVerificationTarget& _target)
{
solAssert(
_target.type == VerificationTargetType::Underflow ||
_target.type == VerificationTargetType::UnderOverflow,
""
);
if (
m_solvedTargets.count(_target.expression) && (
m_solvedTargets.at(_target.expression).count(VerificationTargetType::Underflow) ||
m_solvedTargets.at(_target.expression).count(VerificationTargetType::UnderOverflow)
)
)
return;
auto const* intType = dynamic_cast<IntegerType const*>(_target.expression->annotation().type);
if (!intType)
intType = TypeProvider::uint256();
checkCondition(
_target.constraints && _target.value < smt::minValue(*intType),
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
4144_error,
8312_error,
"Underflow (resulting value less than " + formatNumberReadable(intType->minValue()) + ")",
"<result>",
&_target.value
);
}
void BMC::checkOverflow(BMCVerificationTarget& _target)
{
solAssert(
_target.type == VerificationTargetType::Overflow ||
_target.type == VerificationTargetType::UnderOverflow,
""
);
if (
m_solvedTargets.count(_target.expression) && (
m_solvedTargets.at(_target.expression).count(VerificationTargetType::Overflow) ||
m_solvedTargets.at(_target.expression).count(VerificationTargetType::UnderOverflow)
)
)
return;
auto const* intType = dynamic_cast<IntegerType const*>(_target.expression->annotation().type);
if (!intType)
intType = TypeProvider::uint256();
checkCondition(
_target.constraints && _target.value > smt::maxValue(*intType),
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
2661_error,
8065_error,
"Overflow (resulting value larger than " + formatNumberReadable(intType->maxValue()) + ")",
"<result>",
&_target.value
);
}
void BMC::checkDivByZero(BMCVerificationTarget& _target)
{
solAssert(_target.type == VerificationTargetType::DivByZero, "");
if (
m_solvedTargets.count(_target.expression) &&
m_solvedTargets.at(_target.expression).count(VerificationTargetType::DivByZero)
)
return;
checkCondition(
_target.constraints && (_target.value == 0),
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
3046_error,
5272_error,
"Division by zero",
"<result>",
&_target.value
);
}
void BMC::checkBalance(BMCVerificationTarget& _target)
{
solAssert(_target.type == VerificationTargetType::Balance, "");
checkCondition(
_target.constraints && _target.value,
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
1236_error,
4010_error,
"Insufficient funds",
"address(this).balance"
);
}
void BMC::checkAssert(BMCVerificationTarget& _target)
{
solAssert(_target.type == VerificationTargetType::Assert, "");
if (
m_solvedTargets.count(_target.expression) &&
m_solvedTargets.at(_target.expression).count(_target.type)
)
return;
checkCondition(
_target.constraints && !_target.value,
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
4661_error,
7812_error,
"Assertion violation"
);
}
void BMC::addVerificationTarget(
VerificationTargetType _type,
smtutil::Expression const& _value,
Expression const* _expression
)
{
if (!m_settings.targets.has(_type) || (m_currentContract && !m_currentContract->canBeDeployed()))
return;
BMCVerificationTarget target{
{
_type,
_value,
currentPathConditions() && m_context.assertions()
},
_expression,
m_callStack,
modelExpressions()
};
if (_type == VerificationTargetType::ConstantCondition)
checkVerificationTarget(target);
else
m_verificationTargets.emplace_back(move(target));
}
/// Solving.
void BMC::checkCondition(
smtutil::Expression _condition,
vector<SMTEncoder::CallStackEntry> const& _callStack,
pair<vector<smtutil::Expression>, vector<string>> const& _modelExpressions,
SourceLocation const& _location,
ErrorId _errorHappens,
ErrorId _errorMightHappen,
string const& _description,
string const& _additionalValueName,
smtutil::Expression const* _additionalValue
)
{
m_interface->push();
m_interface->addAssertion(_condition);
vector<smtutil::Expression> expressionsToEvaluate;
vector<string> expressionNames;
tie(expressionsToEvaluate, expressionNames) = _modelExpressions;
if (_callStack.size())
if (_additionalValue)
{
expressionsToEvaluate.emplace_back(*_additionalValue);
expressionNames.push_back(_additionalValueName);
}
smtutil::CheckResult result;
vector<string> values;
tie(result, values) = checkSatisfiableAndGenerateModel(expressionsToEvaluate);
string extraComment = SMTEncoder::extraComment();
if (m_loopExecutionHappened)
extraComment +=
"\nNote that some information is erased after the execution of loops.\n"
"You can re-introduce information using require().";
if (m_externalFunctionCallHappened)
extraComment +=
"\nNote that external function calls are not inlined,"
" even if the source code of the function is available."
" This is due to the possibility that the actual called contract"
" has the same ABI but implements the function differently.";
SecondarySourceLocation secondaryLocation{};
secondaryLocation.append(extraComment, SourceLocation{});
switch (result)
{
case smtutil::CheckResult::SATISFIABLE:
{
solAssert(!_callStack.empty(), "");
std::ostringstream message;
message << "BMC: " << _description << " happens here.";
std::ostringstream modelMessage;
modelMessage << "Counterexample:\n";
solAssert(values.size() == expressionNames.size(), "");
map<string, string> sortedModel;
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(
_errorHappens,
_location,
message.str(),
SecondarySourceLocation().append(modelMessage.str(), SourceLocation{})
.append(SMTEncoder::callStackMessage(_callStack))
.append(move(secondaryLocation))
);
break;
}
case smtutil::CheckResult::UNSATISFIABLE:
break;
case smtutil::CheckResult::UNKNOWN:
m_errorReporter.warning(_errorMightHappen, _location, "BMC: " + _description + " might happen here.", secondaryLocation);
break;
case smtutil::CheckResult::CONFLICTING:
m_errorReporter.warning(1584_error, _location, "BMC: At least two SMT solvers provided conflicting answers. Results might not be sound.");
break;
case smtutil::CheckResult::ERROR:
m_errorReporter.warning(1823_error, _location, "BMC: Error trying to invoke SMT solver.");
break;
}
m_interface->pop();
}
void BMC::checkBooleanNotConstant(
Expression const& _condition,
smtutil::Expression const& _constraints,
smtutil::Expression const& _value,
vector<SMTEncoder::CallStackEntry> const& _callStack
)
{
// Do not check for const-ness if this is a constant.
if (dynamic_cast<Literal const*>(&_condition))
return;
m_interface->push();
m_interface->addAssertion(_constraints && _value);
auto positiveResult = checkSatisfiable();
m_interface->pop();
m_interface->push();
m_interface->addAssertion(_constraints && !_value);
auto negatedResult = checkSatisfiable();
m_interface->pop();
if (positiveResult == smtutil::CheckResult::ERROR || negatedResult == smtutil::CheckResult::ERROR)
m_errorReporter.warning(8592_error, _condition.location(), "BMC: Error trying to invoke SMT solver.");
else if (positiveResult == smtutil::CheckResult::CONFLICTING || negatedResult == smtutil::CheckResult::CONFLICTING)
m_errorReporter.warning(3356_error, _condition.location(), "BMC: At least two SMT solvers provided conflicting answers. Results might not be sound.");
else if (positiveResult == smtutil::CheckResult::SATISFIABLE && negatedResult == smtutil::CheckResult::SATISFIABLE)
{
// everything fine.
}
else if (positiveResult == smtutil::CheckResult::UNKNOWN || negatedResult == smtutil::CheckResult::UNKNOWN)
{
// can't do anything.
}
else if (positiveResult == smtutil::CheckResult::UNSATISFIABLE && negatedResult == smtutil::CheckResult::UNSATISFIABLE)
m_errorReporter.warning(2512_error, _condition.location(), "BMC: Condition unreachable.", SMTEncoder::callStackMessage(_callStack));
else
{
string description;
if (positiveResult == smtutil::CheckResult::SATISFIABLE)
{
solAssert(negatedResult == smtutil::CheckResult::UNSATISFIABLE, "");
description = "BMC: Condition is always true.";
}
else
{
solAssert(positiveResult == smtutil::CheckResult::UNSATISFIABLE, "");
solAssert(negatedResult == smtutil::CheckResult::SATISFIABLE, "");
description = "BMC: Condition is always false.";
}
m_errorReporter.warning(
6838_error,
_condition.location(),
description,
SMTEncoder::callStackMessage(_callStack)
);
}
}
pair<smtutil::CheckResult, vector<string>>
BMC::checkSatisfiableAndGenerateModel(vector<smtutil::Expression> const& _expressionsToEvaluate)
{
smtutil::CheckResult result;
vector<string> values;
try
{
tie(result, values) = m_interface->check(_expressionsToEvaluate);
}
catch (smtutil::SolverError const& _e)
{
string description("BMC: Error querying SMT solver");
if (_e.comment())
description += ": " + *_e.comment();
m_errorReporter.warning(8140_error, description);
result = smtutil::CheckResult::ERROR;
}
for (string& value: values)
{
try
{
// Parse and re-format nicely
value = formatNumberReadable(bigint(value));
}
catch (...) { }
}
return make_pair(result, values);
}
smtutil::CheckResult BMC::checkSatisfiable()
{
return checkSatisfiableAndGenerateModel({}).first;
}
void BMC::assignment(smt::SymbolicVariable& _symVar, smtutil::Expression const& _value)
{
auto oldVar = _symVar.currentValue();
auto newVar = _symVar.increaseIndex();
m_context.addAssertion(smtutil::Expression::ite(
currentPathConditions(),
newVar == _value,
newVar == oldVar
));
}