solidity/libsolidity/formal/BMC.cpp
Martin Blicha 3599c8c6b9 SMTChecker: Fix generation of smtlib scripts
When both CHC and BMC engines are used, the type of state variable
changes when trusted mode for external calls is used. This is because in
CHC engine, trusted mode means we pack more information into the
symbolic state. In BMC this type is always simple.

However, if BMC is run after CHC, in the current code state variables
are reset (and their declaration dumped into SMT-LIB script) before BMC
resets the type of the state variable.

The proposed solution is to simply reset the variable type before the
first variable of this type is created.
2023-06-30 15:57:51 +02:00

1251 lines
35 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/SymbolicTypes.h>
#include <libsmtutil/SMTPortfolio.h>
#include <liblangutil/CharStream.h>
#include <liblangutil/CharStreamProvider.h>
#include <utility>
#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,
UniqueErrorReporter& _errorReporter,
UniqueErrorReporter& _unsupportedErrorReporter,
map<h256, string> const& _smtlib2Responses,
ReadCallback::Callback const& _smtCallback,
ModelCheckerSettings _settings,
CharStreamProvider const& _charStreamProvider
):
SMTEncoder(_context, _settings, _errorReporter, _unsupportedErrorReporter, _charStreamProvider),
m_interface(make_unique<smtutil::SMTPortfolio>(
_smtlib2Responses, _smtCallback, _settings.solvers, _settings.timeout, _settings.printQuery
))
{
solAssert(!_settings.printQuery || _settings.solvers == smtutil::SMTSolverChoice::SMTLIB2(), "Only SMTLib2 solver can be enabled to print queries");
#if defined (HAVE_Z3) || defined (HAVE_CVC4)
if (m_settings.solvers.cvc4 || m_settings.solvers.z3)
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>, smt::EncodingContext::IdCompare> _solvedTargets)
{
// At this point every enabled solver is available.
if (!m_settings.solvers.cvc4 && !m_settings.solvers.smtlib2 && !m_settings.solvers.z3)
{
m_errorReporter.warning(
7710_error,
SourceLocation(),
"BMC analysis was not possible since no SMT solver was found and enabled."
" The accepted solvers for BMC are cvc4 and z3."
);
return;
}
SMTEncoder::resetSourceAnalysis();
state().prepareForSourceUnit(_source, false);
m_solvedTargets = std::move(_solvedTargets);
m_context.setSolver(m_interface.get());
m_context.reset();
m_context.setAssertionAccumulation(true);
m_variableUsage.setFunctionInlining(shouldInlineFunctionCall);
createFreeConstants(sourceDependencies(_source));
m_unprovedAmt = 0;
_source.accept(*this);
if (m_unprovedAmt > 0 && !m_settings.showUnproved)
m_errorReporter.warning(
2788_error,
{},
"BMC: " +
to_string(m_unprovedAmt) +
" verification condition(s) could not be proved." +
" Enable the model checker option \"show unproved\" to see all of them." +
" Consider choosing a specific contract to be verified in order to reduce the solving problems." +
" Consider increasing the timeout per query."
);
if (!m_settings.showProvedSafe && !m_safeTargets.empty())
m_errorReporter.info(
6002_error,
"BMC: " +
to_string(m_safeTargets.size()) +
" verification condition(s) proved safe!" +
" Enable the model checker option \"show proved safe\" to see all of them."
);
else if (m_settings.showProvedSafe)
for (auto const& [node, targets]: m_safeTargets)
for (auto const& target: targets)
m_errorReporter.info(
2961_error,
node->location(),
"BMC: " +
targetDescription(target) +
" check is safe!"
);
// 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 enabled.
if (
!m_interface->unhandledQueries().empty() &&
m_interface->solvers() == 1 &&
m_settings.solvers.smtlib2
)
m_errorReporter.warning(
8084_error,
SourceLocation(),
"BMC analysis was not possible. No SMT solver (Z3 or CVC4) was available."
" None of the installed solvers was enabled."
#ifdef HAVE_Z3_DLOPEN
" Install libz3.so." + to_string(Z3_MAJOR_VERSION) + "." + to_string(Z3_MINOR_VERSION) + " to enable Z3."
#endif
);
}
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 isExternalCallToThis(&_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)
{
// Free functions need to be visited in the context of a contract.
if (!m_currentContract)
return false;
auto contract = dynamic_cast<ContractDefinition const*>(_function.scope());
auto const& hierarchy = m_currentContract->annotation().linearizedBaseContracts;
if (contract && find(hierarchy.begin(), hierarchy.end(), contract) == hierarchy.end())
createStateVariables(*contract);
if (m_callStack.empty())
{
reset();
initFunction(_function);
if (_function.isConstructor() || _function.isPublic())
m_context.addAssertion(state().txTypeConstraints() && state().txFunctionConstraints(_function));
resetStateVariables();
}
if (_function.isConstructor())
{
solAssert(contract, "");
inlineConstructorHierarchy(*contract);
}
/// Already visits the children.
SMTEncoder::visit(_function);
return false;
}
void BMC::endVisit(FunctionDefinition const& _function)
{
// Free functions need to be visited in the context of a contract.
if (!m_currentContract)
return;
if (isRootFunction())
{
checkVerificationTargets();
m_verificationTargets.clear();
m_pathConditions.clear();
}
SMTEncoder::endVisit(_function);
}
bool BMC::visit(IfStatement const& _node)
{
auto indicesBeforePush = copyVariableIndices();
// 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() && !isInsideLoop())
addVerificationTarget(
VerificationTargetType::ConstantCondition,
expr(_node.condition()),
&_node.condition()
);
m_context.popSolver();
resetVariableIndices(std::move(indicesBeforePush));
_node.condition().accept(*this);
auto conditionExpr = expr(_node.condition());
// visit true branch
auto [indicesEndTrue, trueEndPathCondition] = visitBranch(&_node.trueStatement(), conditionExpr);
// visit false branch
decltype(indicesEndTrue) indicesEndFalse;
auto falseEndPathCondition = currentPathConditions() && !conditionExpr;
if (_node.falseStatement())
std::tie(indicesEndFalse, falseEndPathCondition) = visitBranch(_node.falseStatement(), !conditionExpr);
else
indicesEndFalse = copyVariableIndices();
// merge the information from branches
setPathCondition(trueEndPathCondition || falseEndPathCondition);
mergeVariables(expr(_node.condition()), indicesEndTrue, indicesEndFalse);
return false;
}
bool BMC::visit(Conditional const& _op)
{
auto indicesBeforePush = copyVariableIndices();
m_context.pushSolver();
_op.condition().accept(*this);
if (isRootFunction() && !isInsideLoop())
addVerificationTarget(
VerificationTargetType::ConstantCondition,
expr(_op.condition()),
&_op.condition()
);
m_context.popSolver();
resetVariableIndices(std::move(indicesBeforePush));
SMTEncoder::visit(_op);
return false;
}
// Unrolls while or do-while loop
bool BMC::visit(WhileStatement const& _node)
{
unsigned int bmcLoopIterations = m_settings.bmcLoopIterations.value_or(1);
smtutil::Expression broke(false);
smtutil::Expression loopCondition(true);
if (_node.isDoWhile())
{
for (unsigned int i = 0; i < bmcLoopIterations; ++i)
{
m_loopCheckpoints.emplace();
auto indicesBefore = copyVariableIndices();
_node.body().accept(*this);
auto [continues, brokeInCurrentIteration] = mergeVariablesFromLoopCheckpoints();
auto indicesBreak = copyVariableIndices();
_node.condition().accept(*this);
mergeVariables(
!brokeInCurrentIteration,
copyVariableIndices(),
indicesBreak
);
mergeVariables(
broke || !loopCondition,
indicesBefore,
copyVariableIndices()
);
loopCondition = expr(_node.condition());
broke = broke || brokeInCurrentIteration;
m_loopCheckpoints.pop();
}
}
else {
smtutil::Expression loopConditionOnPreviousIteration(true);
for (unsigned int i = 0; i < bmcLoopIterations; ++i)
{
m_loopCheckpoints.emplace();
auto indicesBefore = copyVariableIndices();
_node.condition().accept(*this);
loopCondition = expr(_node.condition());
auto indicesAfterCondition = copyVariableIndices();
pushPathCondition(loopCondition);
_node.body().accept(*this);
popPathCondition();
auto [continues, brokeInCurrentIteration] = mergeVariablesFromLoopCheckpoints();
// merges indices modified when accepting loop condition that no longer holds
mergeVariables(
!loopCondition,
indicesAfterCondition,
copyVariableIndices()
);
// handles breaks in previous iterations
// breaks in current iterations are handled when traversing loop checkpoints
// handles case when the loop condition no longer holds but bmc loop iterations still unrolls the loop
mergeVariables(
broke || !loopConditionOnPreviousIteration,
indicesBefore,
copyVariableIndices()
);
m_loopCheckpoints.pop();
broke = broke || brokeInCurrentIteration;
loopConditionOnPreviousIteration = loopCondition;
}
}
if (bmcLoopIterations > 0)
m_context.addAssertion(not(loopCondition) || broke);
m_loopExecutionHappened = true;
return false;
}
// Unrolls for loop
bool BMC::visit(ForStatement const& _node)
{
if (_node.initializationExpression())
_node.initializationExpression()->accept(*this);
smtutil::Expression broke(false);
smtutil::Expression forCondition(true);
smtutil::Expression forConditionOnPreviousIteration(true);
unsigned int bmcLoopIterations = m_settings.bmcLoopIterations.value_or(1);
for (unsigned int i = 0; i < bmcLoopIterations; ++i)
{
auto indicesBefore = copyVariableIndices();
if (_node.condition())
{
_node.condition()->accept(*this);
// values in loop condition might change during loop iteration
forCondition = expr(*_node.condition());
}
m_loopCheckpoints.emplace();
auto indicesAfterCondition = copyVariableIndices();
pushPathCondition(forCondition);
_node.body().accept(*this);
auto [continues, brokeInCurrentIteration] = mergeVariablesFromLoopCheckpoints();
// accept loop expression if there was no break
if (_node.loopExpression())
{
auto indicesBreak = copyVariableIndices();
_node.loopExpression()->accept(*this);
mergeVariables(
!brokeInCurrentIteration,
copyVariableIndices(),
indicesBreak
);
}
popPathCondition();
// merges indices modified when accepting loop condition that does no longer hold
mergeVariables(
!forCondition,
indicesAfterCondition,
copyVariableIndices()
);
// handles breaks in previous iterations
// breaks in current iterations are handled when traversing loop checkpoints
// handles case when the loop condition no longer holds but bmc loop iterations still unrolls the loop
mergeVariables(
broke || !forConditionOnPreviousIteration,
indicesBefore,
copyVariableIndices()
);
m_loopCheckpoints.pop();
broke = broke || brokeInCurrentIteration;
forConditionOnPreviousIteration = forCondition;
}
if (bmcLoopIterations > 0)
m_context.addAssertion(not(forCondition) || broke);
m_loopExecutionHappened = true;
return false;
}
std::tuple<smtutil::Expression, smtutil::Expression> BMC::mergeVariablesFromLoopCheckpoints()
{
smtutil::Expression continues(false);
smtutil::Expression brokeInCurrentIteration(false);
for (auto const& loopControl: m_loopCheckpoints.top())
{
// use SSAs associated with this break statement only if
// loop didn't break or continue earlier in the iteration
// loop condition is included in break path conditions
mergeVariables(
!brokeInCurrentIteration && !continues && loopControl.pathConditions,
loopControl.variableIndices,
copyVariableIndices()
);
if (loopControl.kind == LoopControlKind::Break)
brokeInCurrentIteration =
brokeInCurrentIteration || loopControl.pathConditions;
else if (loopControl.kind == LoopControlKind::Continue)
continues = continues || loopControl.pathConditions;
}
return std::pair(continues, brokeInCurrentIteration);
}
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<pair<VariableIndices, smtutil::Expression>> clausesVisitResults;
for (size_t i = 0; i < clauses.size(); ++i)
clausesVisitResults.push_back(visitBranch(clauses[i].get()));
// 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(clauseId == i, clausesVisitResults[i].first, currentIndices);
currentIndices = copyVariableIndices();
pathCondition = pathCondition || clausesVisitResults[i].second;
}
setPathCondition(pathCondition);
return false;
}
bool BMC::visit(Break const&)
{
LoopControl control = {
LoopControlKind::Break,
currentPathConditions(),
copyVariableIndices()
};
m_loopCheckpoints.top().emplace_back(control);
return false;
}
bool BMC::visit(Continue const&)
{
LoopControl control = {
LoopControlKind::Continue,
currentPathConditions(),
copyVariableIndices()
};
m_loopCheckpoints.top().emplace_back(control);
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:
case FunctionType::Kind::Unwrap:
case FunctionType::Kind::Wrap:
[[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() && !isInsideLoop())
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 (publicGetter(_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_unsupportedErrors.warning(
5729_error,
_funCall.location(),
"BMC does not yet implement this type of function call."
);
else if (funType.kind() == FunctionType::Kind::BareStaticCall)
{
// Do nothing here.
// Neither storage nor balances should be modified.
}
else
{
m_externalFunctionCallHappened = true;
resetStorageVariables();
resetBalances();
}
}
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));
string expressionName;
if (uf->location().hasText())
expressionName = m_charStreamProvider.charStream(*uf->location().sourceName).text(
uf->location()
);
expressionNames.push_back(std::move(expressionName));
}
return {expressionsToEvaluate, expressionNames};
}
/// Verification targets.
string BMC::targetDescription(BMCVerificationTarget const& _target)
{
if (
_target.type == VerificationTargetType::Underflow ||
_target.type == VerificationTargetType::Overflow
)
{
auto const* intType = dynamic_cast<IntegerType const*>(_target.expression->annotation().type);
if (!intType)
intType = TypeProvider::uint256();
if (_target.type == VerificationTargetType::Underflow)
return "Underflow (resulting value less than " + formatNumberReadable(intType->minValue()) + ")";
return "Overflow (resulting value larger than " + formatNumberReadable(intType->maxValue()) + ")";
}
else if (_target.type == VerificationTargetType::DivByZero)
return "Division by zero";
else if (_target.type == VerificationTargetType::Assert)
return "Assertion violation";
else if (_target.type == VerificationTargetType::Balance)
return "Insufficient funds";
solAssert(false);
}
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,
_target.constraints && _target.value < smt::minValue(*intType),
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
4144_error,
8312_error,
"<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,
_target.constraints && _target.value > smt::maxValue(*intType),
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
2661_error,
8065_error,
"<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,
_target.constraints && (_target.value == 0),
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
3046_error,
5272_error,
"<result>",
&_target.value
);
}
void BMC::checkBalance(BMCVerificationTarget& _target)
{
solAssert(_target.type == VerificationTargetType::Balance, "");
checkCondition(
_target,
_target.constraints && _target.value,
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
1236_error,
4010_error,
"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,
_target.constraints && !_target.value,
_target.callStack,
_target.modelExpressions,
_target.expression->location(),
4661_error,
7812_error
);
}
void BMC::addVerificationTarget(
VerificationTargetType _type,
smtutil::Expression const& _value,
Expression const* _expression
)
{
if (!m_settings.targets.has(_type) || (m_currentContract && !shouldAnalyze(*m_currentContract)))
return;
BMCVerificationTarget target{
{
_type,
_value,
currentPathConditions() && m_context.assertions()
},
_expression,
m_callStack,
modelExpressions()
};
if (_type == VerificationTargetType::ConstantCondition)
checkVerificationTarget(target);
else
m_verificationTargets.emplace_back(std::move(target));
}
/// Solving.
void BMC::checkCondition(
BMCVerificationTarget const& _target,
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& _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.empty())
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 +=
"False negatives are possible when unrolling loops.\n"
"This is due to the possibility that the BMC loop iteration setting is"
" smaller than the actual number of iterations needed to complete a loop.";
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: " << targetDescription(_target) << " happens here.";
std::ostringstream modelMessage;
// Sometimes models have complex smtlib2 expressions that SMTLib2Interface fails to parse.
if (values.size() == expressionNames.size())
{
modelMessage << "Counterexample:\n";
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(std::move(secondaryLocation))
);
break;
}
case smtutil::CheckResult::UNSATISFIABLE:
{
m_safeTargets[_target.expression].insert(_target);
break;
}
case smtutil::CheckResult::UNKNOWN:
{
++m_unprovedAmt;
if (m_settings.showUnproved)
m_errorReporter.warning(_errorMightHappen, _location, "BMC: " + targetDescription(_target) + " 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
{
if (m_settings.printQuery)
{
auto portfolio = dynamic_cast<smtutil::SMTPortfolio*>(m_interface.get());
string smtlibCode = portfolio->dumpQuery(_expressionsToEvaluate);
m_errorReporter.info(
6240_error,
"BMC: Requested query:\n" + smtlibCode
);
}
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
));
}
bool BMC::isInsideLoop() const
{
return !m_loopCheckpoints.empty();
}