/*
* SemiOptimisticStateTransformerFactory.java - This file is part of the Jakstab project.
* Copyright 2007-2012 Johannes Kinder <jk@jakstab.org>
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code 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
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, see <http://www.gnu.org/licenses/>.
*/
package org.jakstab.cfa;
import java.util.Set;
import org.jakstab.analysis.AbstractState;
import org.jakstab.asm.AbsoluteAddress;
import org.jakstab.rtl.Context;
import org.jakstab.cfa.Location;
import org.jakstab.rtl.expressions.ExpressionFactory;
import org.jakstab.rtl.expressions.RTLExpression;
import org.jakstab.rtl.expressions.RTLNumber;
import org.jakstab.rtl.statements.*;
import org.jakstab.util.FastSet;
import org.jakstab.util.Logger;
import org.jakstab.util.Tuple;
/**
* Provides CFAEdges using a medium level of assumptions. If the target of a
* call instruction cannot be resolved, assumes that the call returns to the
* instruction following the callsite.
*
* @author Johannes Kinder
*/
public class SemiOptimisticStateTransformerFactory extends ResolvingTransformerFactory {
@SuppressWarnings("unused")
private static final Logger logger = Logger.getLogger(SemiOptimisticStateTransformerFactory.class);
@Override
public Set<CFAEdge> resolveGoto(final AbstractState a, final RTLGoto stmt) {
assert stmt.getCondition() != null;
Set<CFAEdge> results = new FastSet<CFAEdge>();
Set<Tuple<RTLNumber>> valuePairs = a.projectionFromConcretization(
stmt.getCondition(), stmt.getTargetExpression());
for (Tuple<RTLNumber> pair : valuePairs) {
RTLNumber conditionValue = pair.get(0);
RTLNumber targetValue = pair.get(1);
Location nextLabel;
// assume correct condition case
assert conditionValue != null;
RTLExpression assumption =
ExpressionFactory.createEqual(stmt.getCondition(), conditionValue);
if (conditionValue.equals(ExpressionFactory.FALSE)) {
// assume (condition = false), and set next statement to fallthrough
nextLabel = stmt.getNextLabel();
} else {
if (targetValue == null) {
if (stmt.getType() == RTLGoto.Type.CALL) {
// if it's a call TOP, add an unknown call edge if we're allowing unsound analysis
RTLUnknownProcedureCall unknownCallEdge = new RTLUnknownProcedureCall(stmt);
unknownCallEdge.setLabel(stmt.getLabel());
unknownCallEdge.setNextLabel(stmt.getNextLabel());
results.add(new CFAEdge(stmt.getLabel(), stmt.getNextLabel(), unknownCallEdge));
logger.info(stmt.getLabel() + ": Cannot resolve target expression " +
stmt.getTargetExpression() + " of call. Adding unknown call edge.");
logger.debug("State is: " + a);
} else {
// if target could not be resolved, just leave the edge out for now
logger.info(stmt.getLabel() + ": Cannot resolve target expression " +
stmt.getTargetExpression() + ". Continuing with unsound underapproximation.");
logger.debug("State is: " + a);
unresolvedBranches.add(stmt.getLabel());
}
sound = false;
continue;
} else {
// assume (condition = true AND targetExpression = targetValue)
assumption = ExpressionFactory.createAnd(
assumption,
ExpressionFactory.createEqual(
stmt.getTargetExpression(),
targetValue)
);
// set next label to jump target
nextLabel = new Location(new AbsoluteAddress(targetValue));
}
}
assumption = assumption.evaluate(new Context());
RTLAssume assume = new RTLAssume(assumption, stmt);
assume.setLabel(stmt.getLabel());
assume.setNextLabel(nextLabel);
results.add(new CFAEdge(stmt.getLabel(), nextLabel, assume));
}
return results;
}
}