import IR.Tree.OpNode;
import IR.Tree.ReturnNode;
import IR.Tree.SubBlockNode;
+import IR.Tree.SwitchBlockNode;
import IR.Tree.SwitchStatementNode;
import IR.Tree.TertiaryNode;
import IR.Tree.TreeNode;
// map a method descriptor to a method lattice
private Map<MethodDescriptor, SSJavaLattice<String>> md2lattice;
+ // map a method/class descriptor to a hierarchy graph
+ private Map<Descriptor, HierarchyGraph> mapDescriptorToHierarchyGraph;
+
+ // map a method/class descriptor to a skeleton hierarchy graph
+ private Map<Descriptor, HierarchyGraph> mapDescriptorToSkeletonHierarchyGraph;
+
+ private Map<Descriptor, HierarchyGraph> mapDescriptorToSimpleHierarchyGraph;
+
+ // map a method/class descriptor to a skeleton hierarchy graph with combination nodes
+ private Map<Descriptor, HierarchyGraph> mapDescriptorToCombineSkeletonHierarchyGraph;
+
+ // map a method descriptor to a method summary
+ private Map<MethodDescriptor, MethodSummary> mapMethodDescToMethodSummary;
+
+ // map a descriptor to a simple lattice
+ private Map<Descriptor, SSJavaLattice<String>> mapDescriptorToSimpleLattice;
+
// map a method descriptor to the set of method invocation nodes which are
// invoked by the method descriptor
private Map<MethodDescriptor, Set<MethodInvokeNode>> mapMethodDescriptorToMethodInvokeNodeSet;
private Map<MethodInvokeNode, Map<Integer, NodeTupleSet>> mapMethodInvokeNodeToArgIdxMap;
+ private Map<MethodInvokeNode, NTuple<Descriptor>> mapMethodInvokeNodeToBaseTuple;
+
private Map<MethodDescriptor, MethodLocationInfo> mapMethodDescToMethodLocationInfo;
private Map<ClassDescriptor, LocationInfo> mapClassToLocationInfo;
private Map<MethodDescriptor, Set<MethodDescriptor>> mapMethodToCalleeSet;
+ private Map<MethodDescriptor, Set<FlowNode>> mapMethodDescToParamNodeFlowsToReturnValue;
+
private Map<String, Vector<String>> mapFileNameToLineVector;
private Map<Descriptor, Integer> mapDescToDefinitionLine;
public static final String TOPLOC = "TOPLOC";
+ public static final String INTERLOC = "INTERLOC";
+
public static final Descriptor GLOBALDESC = new NameDescriptor(GLOBALLOC);
public static final Descriptor TOPDESC = new NameDescriptor(TOPLOC);
boolean debug = true;
+ private static int locSeed = 0;
+
public LocationInference(SSJavaAnalysis ssjava, State state) {
this.ssjava = ssjava;
this.state = state;
this.mapFileNameToLineVector = new HashMap<String, Vector<String>>();
this.mapDescToDefinitionLine = new HashMap<Descriptor, Integer>();
+ this.mapMethodDescToParamNodeFlowsToReturnValue =
+ new HashMap<MethodDescriptor, Set<FlowNode>>();
+
+ this.mapDescriptorToHierarchyGraph = new HashMap<Descriptor, HierarchyGraph>();
+ this.mapMethodDescToMethodSummary = new HashMap<MethodDescriptor, MethodSummary>();
+ this.mapMethodInvokeNodeToBaseTuple = new HashMap<MethodInvokeNode, NTuple<Descriptor>>();
+
+ this.mapDescriptorToSkeletonHierarchyGraph = new HashMap<Descriptor, HierarchyGraph>();
+ this.mapDescriptorToCombineSkeletonHierarchyGraph = new HashMap<Descriptor, HierarchyGraph>();
+ this.mapDescriptorToSimpleHierarchyGraph = new HashMap<Descriptor, HierarchyGraph>();
+
+ this.mapDescriptorToSimpleLattice = new HashMap<Descriptor, SSJavaLattice<String>>();
+
}
public void setupToAnalyze() {
SymbolTable classtable = state.getClassSymbolTable();
toanalyzeList.clear();
toanalyzeList.addAll(classtable.getValueSet());
- Collections.sort(toanalyzeList, new Comparator<ClassDescriptor>() {
- public int compare(ClassDescriptor o1, ClassDescriptor o2) {
- return o1.getClassName().compareToIgnoreCase(o2.getClassName());
- }
- });
+ // Collections.sort(toanalyzeList, new Comparator<ClassDescriptor>() {
+ // public int compare(ClassDescriptor o1, ClassDescriptor o2) {
+ // return o1.getClassName().compareToIgnoreCase(o2.getClassName());
+ // }
+ // });
}
public void setupToAnalazeMethod(ClassDescriptor cd) {
// 1) construct value flow graph
constructFlowGraph();
+ constructHierarchyGraph();
+
+ debug_writeHierarchyDotFiles();
+
+ simplifyHierarchyGraph();
+
+ debug_writeSimpleHierarchyDotFiles();
+
+ constructSkeletonHierarchyGraph();
+
+ debug_writeSkeletonHierarchyDotFiles();
+
+ insertCombinationNodes();
+
+ debug_writeSkeletonCombinationHierarchyDotFiles();
+
+ buildLattice();
+
+ debug_writeLattices();
+
+ System.exit(0);
+
// 2) construct lattices
inferLattices();
simplifyLattices();
- debug_writeLatticeDotFile();
-
// 3) check properties
checkLattices();
+ // calculate RETURNLOC,PCLOC
+ calculateExtraLocations();
+
+ debug_writeLatticeDotFile();
+
// 4) generate annotated source codes
generateAnnoatedCode();
}
+ private void debug_writeLattices() {
+
+ Set<Descriptor> keySet = mapDescriptorToSimpleLattice.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ Descriptor key = (Descriptor) iterator.next();
+ SSJavaLattice<String> simpleLattice = mapDescriptorToSimpleLattice.get(key);
+ if (key instanceof ClassDescriptor) {
+ ssjava.writeLatticeDotFile((ClassDescriptor) key, null, simpleLattice, "_SIMPLE");
+ } else if (key instanceof MethodDescriptor) {
+ MethodDescriptor md = (MethodDescriptor) key;
+ ssjava.writeLatticeDotFile(md.getClassDesc(), md, simpleLattice, "_SIMPLE");
+ }
+ }
+
+ Set<ClassDescriptor> cdKeySet = cd2lattice.keySet();
+ for (Iterator iterator = cdKeySet.iterator(); iterator.hasNext();) {
+ ClassDescriptor cd = (ClassDescriptor) iterator.next();
+ ssjava.writeLatticeDotFile(cd, null, cd2lattice.get(cd));
+ }
+
+ Set<MethodDescriptor> mdKeySet = md2lattice.keySet();
+ for (Iterator iterator = mdKeySet.iterator(); iterator.hasNext();) {
+ MethodDescriptor md = (MethodDescriptor) iterator.next();
+ ssjava.writeLatticeDotFile(md.getClassDesc(), md, md2lattice.get(md));
+ }
+
+ }
+
+ private void buildLattice() {
+
+ BuildLattice buildLattice = new BuildLattice(this);
+
+ Set<Descriptor> keySet = mapDescriptorToCombineSkeletonHierarchyGraph.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ Descriptor desc = (Descriptor) iterator.next();
+
+ HierarchyGraph graph = getSkeletonCombinationHierarchyGraph(desc);
+ SSJavaLattice<String> simpleLattice = buildLattice.buildLattice(graph);
+
+ addMapDescToSimpleLattice(desc, simpleLattice);
+
+ HierarchyGraph simpleHierarchyGraph = getSimpleHierarchyGraph(desc);
+ System.out.println("## insertIntermediateNodesToStraightLine:"
+ + simpleHierarchyGraph.getName());
+ SSJavaLattice<String> lattice =
+ buildLattice.insertIntermediateNodesToStraightLine(desc, simpleLattice);
+ lattice.removeRedundantEdges();
+
+ if (desc instanceof ClassDescriptor) {
+ // field lattice
+ cd2lattice.put((ClassDescriptor) desc, lattice);
+ // ssjava.writeLatticeDotFile((ClassDescriptor) desc, null, lattice);
+ } else if (desc instanceof MethodDescriptor) {
+ // method lattice
+ md2lattice.put((MethodDescriptor) desc, lattice);
+ MethodDescriptor md = (MethodDescriptor) desc;
+ ClassDescriptor cd = md.getClassDesc();
+ // ssjava.writeLatticeDotFile(cd, md, lattice);
+ }
+
+ // System.out.println("\nSSJAVA: Insering Combination Nodes:" + desc);
+ // HierarchyGraph skeletonGraph = getSkeletonHierarchyGraph(desc);
+ // HierarchyGraph skeletonGraphWithCombinationNode = skeletonGraph.clone();
+ // skeletonGraphWithCombinationNode.setName(desc + "_SC");
+ //
+ // HierarchyGraph simpleHierarchyGraph = getSimpleHierarchyGraph(desc);
+ // System.out.println("Identifying Combination Nodes:");
+ // skeletonGraphWithCombinationNode.insertCombinationNodesToGraph(simpleHierarchyGraph);
+ // skeletonGraphWithCombinationNode.simplifySkeletonCombinationHierarchyGraph();
+ // mapDescriptorToCombineSkeletonHierarchyGraph.put(desc, skeletonGraphWithCombinationNode);
+ }
+
+ }
+
+ public void addMapDescToSimpleLattice(Descriptor desc, SSJavaLattice<String> lattice) {
+ mapDescriptorToSimpleLattice.put(desc, lattice);
+ }
+
+ public SSJavaLattice<String> getSimpleLattice(Descriptor desc) {
+ return mapDescriptorToSimpleLattice.get(desc);
+ }
+
+ private void simplifyHierarchyGraph() {
+ Set<Descriptor> keySet = mapDescriptorToHierarchyGraph.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ Descriptor desc = (Descriptor) iterator.next();
+ HierarchyGraph simpleHierarchyGraph = getHierarchyGraph(desc).clone();
+ simpleHierarchyGraph.setName(desc + "_SIMPLE");
+ simpleHierarchyGraph.simplifyHierarchyGraph();
+ mapDescriptorToSimpleHierarchyGraph.put(desc, simpleHierarchyGraph);
+ }
+ }
+
+ private void insertCombinationNodes() {
+ Set<Descriptor> keySet = mapDescriptorToSkeletonHierarchyGraph.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ Descriptor desc = (Descriptor) iterator.next();
+ System.out.println("\nSSJAVA: Insering Combination Nodes:" + desc);
+ HierarchyGraph skeletonGraph = getSkeletonHierarchyGraph(desc);
+ HierarchyGraph skeletonGraphWithCombinationNode = skeletonGraph.clone();
+ skeletonGraphWithCombinationNode.setName(desc + "_SC");
+
+ HierarchyGraph simpleHierarchyGraph = getSimpleHierarchyGraph(desc);
+ System.out.println("Identifying Combination Nodes:");
+ skeletonGraphWithCombinationNode.insertCombinationNodesToGraph(simpleHierarchyGraph);
+ skeletonGraphWithCombinationNode.simplifySkeletonCombinationHierarchyGraph();
+ mapDescriptorToCombineSkeletonHierarchyGraph.put(desc, skeletonGraphWithCombinationNode);
+ }
+ }
+
+ private void constructSkeletonHierarchyGraph() {
+ Set<Descriptor> keySet = mapDescriptorToHierarchyGraph.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ Descriptor desc = (Descriptor) iterator.next();
+ HierarchyGraph simpleGraph = getSimpleHierarchyGraph(desc);
+ HierarchyGraph skeletonGraph = simpleGraph.generateSkeletonGraph();
+ skeletonGraph.setMapDescToHNode(simpleGraph.getMapDescToHNode());
+ skeletonGraph.setMapHNodeToDescSet(simpleGraph.getMapHNodeToDescSet());
+ skeletonGraph.removeRedundantEdges();
+ mapDescriptorToSkeletonHierarchyGraph.put(desc, skeletonGraph);
+ }
+ }
+
+ private void debug_writeHierarchyDotFiles() {
+
+ Set<Descriptor> keySet = mapDescriptorToHierarchyGraph.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ Descriptor desc = (Descriptor) iterator.next();
+ getHierarchyGraph(desc).writeGraph();
+ }
+
+ }
+
+ private void debug_writeSimpleHierarchyDotFiles() {
+
+ Set<Descriptor> keySet = mapDescriptorToHierarchyGraph.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ Descriptor desc = (Descriptor) iterator.next();
+ getHierarchyGraph(desc).writeGraph();
+ getSimpleHierarchyGraph(desc).writeGraph();
+ }
+
+ }
+
+ private void debug_writeSkeletonHierarchyDotFiles() {
+
+ Set<Descriptor> keySet = mapDescriptorToHierarchyGraph.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ Descriptor desc = (Descriptor) iterator.next();
+ getSkeletonHierarchyGraph(desc).writeGraph();
+ }
+
+ }
+
+ private void debug_writeSkeletonCombinationHierarchyDotFiles() {
+
+ Set<Descriptor> keySet = mapDescriptorToHierarchyGraph.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ Descriptor desc = (Descriptor) iterator.next();
+ getSkeletonCombinationHierarchyGraph(desc).writeGraph();
+ }
+
+ }
+
+ public HierarchyGraph getSimpleHierarchyGraph(Descriptor d) {
+ return mapDescriptorToSimpleHierarchyGraph.get(d);
+ }
+
+ private HierarchyGraph getSkeletonHierarchyGraph(Descriptor d) {
+ if (!mapDescriptorToSkeletonHierarchyGraph.containsKey(d)) {
+ mapDescriptorToSkeletonHierarchyGraph.put(d, new HierarchyGraph(d));
+ }
+ return mapDescriptorToSkeletonHierarchyGraph.get(d);
+ }
+
+ public HierarchyGraph getSkeletonCombinationHierarchyGraph(Descriptor d) {
+ if (!mapDescriptorToCombineSkeletonHierarchyGraph.containsKey(d)) {
+ mapDescriptorToCombineSkeletonHierarchyGraph.put(d, new HierarchyGraph(d));
+ }
+ return mapDescriptorToCombineSkeletonHierarchyGraph.get(d);
+ }
+
+ private void constructHierarchyGraph() {
+
+ // do fixed-point analysis
+
+ ssjava.init();
+ LinkedList<MethodDescriptor> descriptorListToAnalyze = ssjava.getSortedDescriptors();
+
+ // Collections.sort(descriptorListToAnalyze, new
+ // Comparator<MethodDescriptor>() {
+ // public int compare(MethodDescriptor o1, MethodDescriptor o2) {
+ // return o1.getSymbol().compareToIgnoreCase(o2.getSymbol());
+ // }
+ // });
+
+ // current descriptors to visit in fixed-point interprocedural analysis,
+ // prioritized by dependency in the call graph
+ methodDescriptorsToVisitStack.clear();
+
+ Set<MethodDescriptor> methodDescriptorToVistSet = new HashSet<MethodDescriptor>();
+ methodDescriptorToVistSet.addAll(descriptorListToAnalyze);
+
+ while (!descriptorListToAnalyze.isEmpty()) {
+ MethodDescriptor md = descriptorListToAnalyze.removeFirst();
+ methodDescriptorsToVisitStack.add(md);
+ }
+
+ // analyze scheduled methods until there are no more to visit
+ while (!methodDescriptorsToVisitStack.isEmpty()) {
+ // start to analyze leaf node
+ MethodDescriptor md = methodDescriptorsToVisitStack.pop();
+
+ HierarchyGraph methodGraph = new HierarchyGraph(md);
+ MethodSummary methodSummary = new MethodSummary();
+
+ MethodLocationInfo methodInfo = new MethodLocationInfo(md);
+ curMethodInfo = methodInfo;
+
+ System.out.println();
+ System.out.println("SSJAVA: Construcing the hierarchy graph from " + md);
+
+ constructHierarchyGraph(md, methodGraph, methodSummary);
+
+ HierarchyGraph prevMethodGraph = getHierarchyGraph(md);
+ MethodSummary prevMethodSummary = getMethodSummary(md);
+
+ if ((!methodGraph.equals(prevMethodGraph)) || (!methodSummary.equals(prevMethodSummary))) {
+
+ mapDescriptorToHierarchyGraph.put(md, methodGraph);
+ mapMethodDescToMethodSummary.put(md, methodSummary);
+
+ // results for callee changed, so enqueue dependents caller for
+ // further analysis
+ Iterator<MethodDescriptor> depsItr = ssjava.getDependents(md).iterator();
+ while (depsItr.hasNext()) {
+ MethodDescriptor methodNext = depsItr.next();
+ if (!methodDescriptorsToVisitStack.contains(methodNext)
+ && methodDescriptorToVistSet.contains(methodNext)) {
+ methodDescriptorsToVisitStack.add(methodNext);
+ }
+ }
+
+ }
+
+ }
+
+ }
+
+ private HierarchyGraph getHierarchyGraph(Descriptor d) {
+ if (!mapDescriptorToHierarchyGraph.containsKey(d)) {
+ mapDescriptorToHierarchyGraph.put(d, new HierarchyGraph(d));
+ }
+ return mapDescriptorToHierarchyGraph.get(d);
+ }
+
+ private void constructHierarchyGraph(MethodDescriptor md, HierarchyGraph methodGraph,
+ MethodSummary methodSummary) {
+
+ // visit each node of method flow graph
+ FlowGraph fg = getFlowGraph(md);
+ Set<FlowNode> nodeSet = fg.getNodeSet();
+
+ Set<Descriptor> paramDescSet = fg.getMapParamDescToIdx().keySet();
+ for (Iterator iterator = paramDescSet.iterator(); iterator.hasNext();) {
+ Descriptor desc = (Descriptor) iterator.next();
+ methodGraph.getHNode(desc).setSkeleton(true);
+ }
+
+ // for the method lattice, we need to look at the first element of
+ // NTuple<Descriptor>
+ for (Iterator iterator = nodeSet.iterator(); iterator.hasNext();) {
+ FlowNode srcNode = (FlowNode) iterator.next();
+
+ Set<FlowEdge> outEdgeSet = srcNode.getOutEdgeSet();
+ for (Iterator iterator2 = outEdgeSet.iterator(); iterator2.hasNext();) {
+ FlowEdge outEdge = (FlowEdge) iterator2.next();
+ FlowNode dstNode = outEdge.getDst();
+
+ NTuple<Descriptor> srcNodeTuple = srcNode.getDescTuple();
+ NTuple<Descriptor> dstNodeTuple = dstNode.getDescTuple();
+
+ if (outEdge.getInitTuple().equals(srcNodeTuple)
+ && outEdge.getEndTuple().equals(dstNodeTuple)) {
+
+ NTuple<Descriptor> srcCurTuple = srcNode.getCurrentDescTuple();
+ NTuple<Descriptor> dstCurTuple = dstNode.getCurrentDescTuple();
+
+ if ((srcCurTuple.size() > 1 && dstCurTuple.size() > 1)
+ && srcCurTuple.get(0).equals(dstCurTuple.get(0))) {
+
+ // value flows between fields
+ Descriptor desc = srcCurTuple.get(0);
+ ClassDescriptor classDesc;
+
+ if (desc.equals(GLOBALDESC)) {
+ classDesc = md.getClassDesc();
+ } else {
+ VarDescriptor varDesc = (VarDescriptor) srcCurTuple.get(0);
+ classDesc = varDesc.getType().getClassDesc();
+ }
+ extractFlowsBetweenFields(classDesc, srcNode, dstNode, 1);
+
+ } else {
+ // value flow between local var - local var or local var - field
+
+ Descriptor srcDesc = srcCurTuple.get(0);
+ Descriptor dstDesc = dstCurTuple.get(0);
+
+ methodGraph.addEdge(srcDesc, dstDesc);
+
+ if (fg.isParamDesc(srcDesc)) {
+ methodGraph.setParamHNode(srcDesc);
+ }
+ if (fg.isParamDesc(dstDesc)) {
+ methodGraph.setParamHNode(dstDesc);
+ }
+
+ }
+
+ }
+ }
+ }
+
+ }
+
+ private MethodSummary getMethodSummary(MethodDescriptor md) {
+ if (!mapMethodDescToMethodSummary.containsKey(md)) {
+ mapMethodDescToMethodSummary.put(md, new MethodSummary());
+ }
+ return mapMethodDescToMethodSummary.get(md);
+ }
+
private void addMapClassDefinitionToLineNum(ClassDescriptor cd, String strLine, int lineNum) {
String classSymbol = cd.getSymbol();
if (desc instanceof MethodDescriptor) {
TypeDescriptor returnType = ((MethodDescriptor) desc).getReturnType();
+
+ MethodLocationInfo methodLocInfo = getMethodLocationInfo((MethodDescriptor) desc);
+
if (returnType != null && (!returnType.isVoid())) {
- rtr += "\n@RETURNLOC(\"RETURNLOC\")";
+ rtr +=
+ "\n@RETURNLOC(\"" + generateLocationAnnoatation(methodLocInfo.getReturnLoc()) + "\")";
+ }
+
+ rtr += "\n@THISLOC(\"this\")";
+ rtr += "\n@GLOBALLOC(\"GLOBALLOC\")";
+
+ CompositeLocation pcLoc = methodLocInfo.getPCLoc();
+ if ((pcLoc != null) && (!pcLoc.get(0).isTop())) {
+ rtr += "\n@PCLOC(\"" + generateLocationAnnoatation(pcLoc) + "\")";
}
- rtr += "\n@THISLOC(\"this\")\n@PCLOC(\"PCLOC\")\n@GLOBALLOC(\"GLOBALLOC\")";
}
}
for (Iterator iter = cd.getFields(); iter.hasNext();) {
- Descriptor fieldDesc = (Descriptor) iter.next();
- String locIdentifier = locInfo.getFieldInferLocation(fieldDesc).getLocIdentifier();
- if (!getLattice(cd).containsKey(locIdentifier)) {
- getLattice(cd).put(locIdentifier);
+ FieldDescriptor fieldDesc = (FieldDescriptor) iter.next();
+ if (!(fieldDesc.isStatic() && fieldDesc.isFinal())) {
+ String locIdentifier = locInfo.getFieldInferLocation(fieldDesc).getLocIdentifier();
+ if (!getLattice(cd).getElementSet().contains(locIdentifier)) {
+ getLattice(cd).put(locIdentifier);
+ }
}
}
FieldDescriptor fd = (FieldDescriptor) iter.next();
String locAnnotationStr;
- if (inferLocMap.containsKey(fd)) {
- CompositeLocation inferLoc = inferLocMap.get(fd);
- locAnnotationStr = generateLocationAnnoatation(inferLoc);
- } else {
- // if the field is not accssed by SS part, just assigns dummy
- // location
- locAnnotationStr = "@LOC(\"LOC\")";
+ CompositeLocation inferLoc = inferLocMap.get(fd);
+
+ if (inferLoc != null) {
+ // infer loc is null if the corresponding field is static and final
+ locAnnotationStr = "@LOC(\"" + generateLocationAnnoatation(inferLoc) + "\")";
+ int fdLineNum = fd.getLineNum();
+ String orgFieldDeclarationStr = sourceVec.get(fdLineNum);
+ String fieldDeclaration = fd.toString();
+ fieldDeclaration = fieldDeclaration.substring(0, fieldDeclaration.length() - 1);
+ String annoatedStr = locAnnotationStr + " " + orgFieldDeclarationStr;
+ sourceVec.set(fdLineNum, annoatedStr);
}
- int fdLineNum = fd.getLineNum();
- String orgFieldDeclarationStr = sourceVec.get(fdLineNum);
- String fieldDeclaration = fd.toString();
- fieldDeclaration = fieldDeclaration.substring(0, fieldDeclaration.length() - 1);
-
- String annoatedStr = locAnnotationStr + " " + orgFieldDeclarationStr;
- sourceVec.set(fdLineNum, annoatedStr);
}
while (!toAnalyzeMethodIsEmpty()) {
MethodDescriptor md = toAnalyzeMethodNext();
+
+ if (!ssjava.needTobeAnnotated(md)) {
+ continue;
+ }
+
SSJavaLattice<String> methodLattice = md2lattice.get(md);
if (methodLattice != null) {
methodLocInfo.getMapDescToInferLocation();
Set<Descriptor> localVarDescSet = methodInferLocMap.keySet();
+ Set<String> localLocElementSet = methodLattice.getElementSet();
+
for (Iterator iterator = localVarDescSet.iterator(); iterator.hasNext();) {
Descriptor localVarDesc = (Descriptor) iterator.next();
CompositeLocation inferLoc = methodInferLocMap.get(localVarDesc);
- String locAnnotationStr = generateLocationAnnoatation(inferLoc);
+ String localLocIdentifier = inferLoc.get(0).getLocIdentifier();
+ if (!localLocElementSet.contains(localLocIdentifier)) {
+ methodLattice.put(localLocIdentifier);
+ }
+
+ String locAnnotationStr = "@LOC(\"" + generateLocationAnnoatation(inferLoc) + "\")";
if (!isParameter(md, localVarDesc)) {
if (mapDescToDefinitionLine.containsKey(localVarDesc)) {
}
} else {
String methodDefStr = sourceVec.get(methodDefLine);
- int idx = methodDefStr.indexOf(generateVarDeclaration((VarDescriptor) localVarDesc));
+
+ int idx =
+ getParamLocation(methodDefStr,
+ generateVarDeclaration((VarDescriptor) localVarDesc));
+
assert (idx != -1);
+
String annoatedStr =
methodDefStr.substring(0, idx) + locAnnotationStr + " "
+ methodDefStr.substring(idx);
}
+ // check if the lattice has to have the location type for the this
+ // reference...
+
+ // boolean needToAddthisRef = hasThisReference(md);
+ if (localLocElementSet.contains("this")) {
+ methodLattice.put("this");
+ }
+
String methodLatticeDefStr = generateLatticeDefinition(md);
String annoatedStr = methodLatticeDefStr + newline + sourceVec.get(methodDefLine);
sourceVec.set(methodDefLine, annoatedStr);
codeGen();
}
- private String generateVarDeclaration(VarDescriptor varDesc) {
+ private boolean hasThisReference(MethodDescriptor md) {
- TypeDescriptor td = varDesc.getType();
- String rtr = td.toString();
- if (td.isArray()) {
- for (int i = 0; i < td.getArrayCount(); i++) {
- rtr += "[]";
+ FlowGraph fg = getFlowGraph(md);
+ Set<FlowNode> nodeSet = fg.getNodeSet();
+ for (Iterator iterator = nodeSet.iterator(); iterator.hasNext();) {
+ FlowNode flowNode = (FlowNode) iterator.next();
+ if (flowNode.getDescTuple().get(0).equals(md.getThis())) {
+ return true;
}
}
- rtr += " " + varDesc.getName();
- return rtr;
+ return false;
}
- private String generateLocationAnnoatation(CompositeLocation loc) {
- String rtr = "@LOC(\"";
+ private int getParamLocation(String methodStr, String paramStr) {
+
+ String pattern = paramStr + ",";
+
+ int idx = methodStr.indexOf(pattern);
+ if (idx != -1) {
+ return idx;
+ } else {
+ pattern = paramStr + ")";
+ return methodStr.indexOf(pattern);
+ }
+
+ }
+
+ private String generateVarDeclaration(VarDescriptor varDesc) {
+
+ TypeDescriptor td = varDesc.getType();
+ String rtr = td.toString();
+ if (td.isArray()) {
+ for (int i = 0; i < td.getArrayCount(); i++) {
+ rtr += "[]";
+ }
+ }
+ rtr += " " + varDesc.getName();
+ return rtr;
+
+ }
+ private String generateLocationAnnoatation(CompositeLocation loc) {
+ String rtr = "";
// method location
Location methodLoc = loc.get(0);
rtr += methodLoc.getLocIdentifier();
rtr += "," + element.getDescriptor().getSymbol() + "." + element.getLocIdentifier();
}
- rtr += "\")";
return rtr;
}
private void simplifyLattices() {
- // generate lattice dot file
+ setupToAnalyze();
+
+ while (!toAnalyzeIsEmpty()) {
+ ClassDescriptor cd = toAnalyzeNext();
+ setupToAnalazeMethod(cd);
+
+ SSJavaLattice<String> classLattice = cd2lattice.get(cd);
+ if (classLattice != null) {
+ System.out.println("@@@check lattice=" + cd);
+ checkLatticeProperty(cd, classLattice);
+ }
+
+ while (!toAnalyzeMethodIsEmpty()) {
+ MethodDescriptor md = toAnalyzeMethodNext();
+ SSJavaLattice<String> methodLattice = md2lattice.get(md);
+ if (methodLattice != null) {
+ System.out.println("@@@check lattice=" + md);
+ checkLatticeProperty(md, methodLattice);
+ }
+ }
+ }
+
setupToAnalyze();
while (!toAnalyzeIsEmpty()) {
}
+ private boolean checkLatticeProperty(Descriptor d, SSJavaLattice<String> lattice) {
+ // if two elements has the same incoming node set,
+ // we need to merge two elements ...
+
+ boolean isUpdated;
+ boolean isModified = false;
+ do {
+ isUpdated = removeNodeSharingSameIncomingNodes(d, lattice);
+ if (!isModified && isUpdated) {
+ isModified = true;
+ }
+ } while (isUpdated);
+
+ return isModified;
+ }
+
+ private boolean removeNodeSharingSameIncomingNodes(Descriptor d, SSJavaLattice<String> lattice) {
+ LocationInfo locInfo = getLocationInfo(d);
+ Map<String, Set<String>> map = lattice.getIncomingElementMap();
+ Set<String> keySet = map.keySet();
+ for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
+ String key = (String) iterator.next();
+ Set<String> incomingSetKey = map.get(key);
+
+ // System.out.println("key=" + key + " incomingSetKey=" +
+ // incomingSetKey);
+ if (incomingSetKey.size() > 0) {
+ for (Iterator iterator2 = keySet.iterator(); iterator2.hasNext();) {
+ String cur = (String) iterator2.next();
+ if (!cur.equals(key)) {
+ Set<String> incomingSetCur = map.get(cur);
+ if (incomingSetCur.equals(incomingSetKey)) {
+ if (!(incomingSetCur.size() == 1 && incomingSetCur.contains(lattice.getTopItem()))) {
+ // NEED TO MERGE HERE!!!!
+ System.out.println("@@@Try merge=" + cur + " " + key);
+
+ Set<String> mergeSet = new HashSet<String>();
+ mergeSet.add(cur);
+ mergeSet.add(key);
+
+ String newMergeLoc = "MLoc" + (SSJavaLattice.seed++);
+
+ System.out.println("---ASSIGN NEW MERGE LOC=" + newMergeLoc + " to " + mergeSet);
+ lattice.mergeIntoNewLocation(mergeSet, newMergeLoc);
+
+ for (Iterator miterator = mergeSet.iterator(); miterator.hasNext();) {
+ String oldLocSymbol = (String) miterator.next();
+
+ Set<Pair<Descriptor, Descriptor>> inferLocSet =
+ locInfo.getRelatedInferLocSet(oldLocSymbol);
+ System.out.println("---update related locations=" + inferLocSet
+ + " oldLocSymbol=" + oldLocSymbol);
+
+ for (Iterator miterator2 = inferLocSet.iterator(); miterator2.hasNext();) {
+ Pair<Descriptor, Descriptor> pair =
+ (Pair<Descriptor, Descriptor>) miterator2.next();
+ Descriptor enclosingDesc = pair.getFirst();
+ Descriptor desc = pair.getSecond();
+
+ System.out.println("---inferLoc pair=" + pair);
+
+ CompositeLocation inferLoc =
+ getLocationInfo(enclosingDesc).getInferLocation(desc);
+ System.out.println("oldLoc=" + inferLoc);
+ // if (curMethodInfo.md.equals(enclosingDesc)) {
+ // inferLoc = curMethodInfo.getInferLocation(desc);
+ // } else {
+ // inferLoc =
+ // getLocationInfo(enclosingDesc).getInferLocation(desc);
+ // }
+
+ Location locElement = inferLoc.get(inferLoc.getSize() - 1);
+
+ locElement.setLocIdentifier(newMergeLoc);
+ locInfo.addMapLocSymbolToRelatedInferLoc(newMergeLoc, enclosingDesc, desc);
+
+ // if (curMethodInfo.md.equals(enclosingDesc)) {
+ // inferLoc = curMethodInfo.getInferLocation(desc);
+ // } else {
+ // inferLoc =
+ // getLocationInfo(enclosingDesc).getInferLocation(desc);
+ // }
+
+ inferLoc = getLocationInfo(enclosingDesc).getInferLocation(desc);
+ System.out.println("---New Infer Loc=" + inferLoc);
+
+ }
+
+ locInfo.removeRelatedInferLocSet(oldLocSymbol, newMergeLoc);
+
+ }
+
+ for (Iterator iterator3 = mergeSet.iterator(); iterator3.hasNext();) {
+ String oldLoc = (String) iterator3.next();
+ lattice.remove(oldLoc);
+ }
+ return true;
+ }
+ }
+ }
+ }
+ }
+
+ }
+ return false;
+ }
+
private void checkLattices() {
LinkedList<MethodDescriptor> descriptorListToAnalyze = ssjava.getSortedDescriptors();
// dependency in the call graph
methodDescriptorsToVisitStack.clear();
- descriptorListToAnalyze.removeFirst();
+ // descriptorListToAnalyze.removeFirst();
Set<MethodDescriptor> methodDescriptorToVistSet = new HashSet<MethodDescriptor>();
methodDescriptorToVistSet.addAll(descriptorListToAnalyze);
// do fixed-point analysis
+ ssjava.init();
LinkedList<MethodDescriptor> descriptorListToAnalyze = ssjava.getSortedDescriptors();
- Collections.sort(descriptorListToAnalyze, new Comparator<MethodDescriptor>() {
- public int compare(MethodDescriptor o1, MethodDescriptor o2) {
- return o1.getSymbol().compareToIgnoreCase(o2.getSymbol());
- }
- });
+ // Collections.sort(descriptorListToAnalyze, new
+ // Comparator<MethodDescriptor>() {
+ // public int compare(MethodDescriptor o1, MethodDescriptor o2) {
+ // return o1.getSymbol().compareToIgnoreCase(o2.getSymbol());
+ // }
+ // });
// current descriptors to visit in fixed-point interprocedural analysis,
// prioritized by
}
}
+
+ }
+
+ private void calculateExtraLocations() {
+ LinkedList<MethodDescriptor> descriptorListToAnalyze = ssjava.getSortedDescriptors();
+ for (Iterator iterator = descriptorListToAnalyze.iterator(); iterator.hasNext();) {
+ MethodDescriptor md = (MethodDescriptor) iterator.next();
+ calculateExtraLocations(md);
+ }
}
private void setMethodLocInfo(MethodDescriptor md, MethodLocationInfo methodInfo) {
if (!md1.getReturnType().isVoid()) {
// add return value location
- CompositeLocation rtrLoc1 =
- new CompositeLocation(new Location(md1, locInfo1.getReturnLocName()));
- CompositeLocation rtrLoc2 =
- new CompositeLocation(new Location(md2, locInfo2.getReturnLocName()));
+ CompositeLocation rtrLoc1 = getMethodLocationInfo(md1).getReturnLoc();
+ CompositeLocation rtrLoc2 = getMethodLocationInfo(md2).getReturnLoc();
list1.add(rtrLoc1);
list2.add(rtrLoc2);
}
// value flow between local var - local var or local var - field
addRelationToLattice(md, methodLattice, methodInfo, srcNode, dstNode);
}
-
- // else if (srcNodeTuple.size() == 1 || dstNodeTuple.size() == 1) {
- // // for the method lattice, we need to look at the first element of
- // // NTuple<Descriptor>
- // // in this case, take a look at connected nodes at the local level
- // addRelationToLattice(md, methodLattice, methodInfo, srcNode,
- // dstNode);
- // } else {
- // if
- // (!srcNode.getDescTuple().get(0).equals(dstNode.getDescTuple().get(0)))
- // {
- // // in this case, take a look at connected nodes at the local level
- // addRelationToLattice(md, methodLattice, methodInfo, srcNode,
- // dstNode);
- // } else {
- // Descriptor srcDesc = srcNode.getDescTuple().get(0);
- // Descriptor dstDesc = dstNode.getDescTuple().get(0);
- // recursivelyAddCompositeRelation(md, fg, methodInfo, srcNode,
- // dstNode, srcDesc,
- // dstDesc);
- // // recursiveAddRelationToLattice(1, md, srcNode, dstNode);
- // }
- // }
-
- }
- }
- }
-
- for (Iterator iterator = nodeSet.iterator(); iterator.hasNext();) {
- FlowNode flowNode = (FlowNode) iterator.next();
- if (flowNode.isDeclaratonNode()) {
- CompositeLocation inferLoc = methodInfo.getInferLocation(flowNode.getDescTuple().get(0));
- String locIdentifier = inferLoc.get(0).getLocIdentifier();
- if (!methodLattice.containsKey(locIdentifier)) {
- methodLattice.put(locIdentifier);
}
-
}
}
methodInfo.addMapParamIdxToInferLoc(idx + offset, inferParamLoc);
}
- // calculate the initial program counter location
- // PC location is higher than location types of all parameters
- String pcLocSymbol = "PCLOC";
- Map<Integer, CompositeLocation> mapParamToLoc = methodInfo.getMapParamIdxToInferLoc();
- Set<Integer> keySet = mapParamToLoc.keySet();
- for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
- Integer paramIdx = (Integer) iterator.next();
- CompositeLocation inferLoc = mapParamToLoc.get(paramIdx);
- String paramLocLocalSymbol = inferLoc.get(0).getLocIdentifier();
- if (!methodLattice.isGreaterThan(pcLocSymbol, paramLocLocalSymbol)) {
- addRelationHigherToLower(methodLattice, methodInfo, pcLocSymbol, paramLocLocalSymbol);
+ }
+
+ private void calculateExtraLocations(MethodDescriptor md) {
+ // calcualte pcloc, returnloc,...
+
+ SSJavaLattice<String> methodLattice = getMethodLattice(md);
+ MethodLocationInfo methodInfo = getMethodLocationInfo(md);
+ FlowGraph fg = getFlowGraph(md);
+ Set<FlowNode> nodeSet = fg.getNodeSet();
+
+ for (Iterator iterator = nodeSet.iterator(); iterator.hasNext();) {
+ FlowNode flowNode = (FlowNode) iterator.next();
+ if (flowNode.isDeclaratonNode()) {
+ CompositeLocation inferLoc = methodInfo.getInferLocation(flowNode.getDescTuple().get(0));
+ String locIdentifier = inferLoc.get(0).getLocIdentifier();
+ if (!methodLattice.containsKey(locIdentifier)) {
+ methodLattice.put(locIdentifier);
+ }
+
}
}
- // calculate a return location
- // the return location type is lower than all parameters
- if (!md.getReturnType().isVoid()) {
+ Map<Integer, CompositeLocation> mapParamToLoc = methodInfo.getMapParamIdxToInferLoc();
+ Set<Integer> paramIdxSet = mapParamToLoc.keySet();
+
+ try {
+ if (!ssjava.getMethodContainingSSJavaLoop().equals(md)) {
+ // calculate the initial program counter location
+ // PC location is higher than location types of all parameters
+ String pcLocSymbol = "PCLOC";
+
+ Set<CompositeLocation> paramInFlowSet = new HashSet<CompositeLocation>();
+
+ for (Iterator iterator = paramIdxSet.iterator(); iterator.hasNext();) {
+ Integer paramIdx = (Integer) iterator.next();
+
+ FlowNode paramFlowNode = fg.getParamFlowNode(paramIdx);
+
+ if (fg.getIncomingFlowNodeSet(paramFlowNode).size() > 0) {
+ // parameter has in-value flows
+ CompositeLocation inferLoc = mapParamToLoc.get(paramIdx);
+ paramInFlowSet.add(inferLoc);
+ }
+ }
+
+ if (paramInFlowSet.size() > 0) {
+ CompositeLocation lowestLoc = getLowest(methodLattice, paramInFlowSet);
+ assert (lowestLoc != null);
+ methodInfo.setPCLoc(lowestLoc);
+ }
+
+ }
+
+ // calculate a return location
+ // the return location type is lower than all parameters and location
+ // types
+ // of return values
+ if (!md.getReturnType().isVoid()) {
+ // first, generate the set of return value location types that starts
+ // with
+ // 'this' reference
+
+ Set<CompositeLocation> inferFieldReturnLocSet = new HashSet<CompositeLocation>();
+
+ Set<FlowNode> paramFlowNode = getParamNodeFlowingToReturnValue(md);
+ Set<CompositeLocation> inferParamLocSet = new HashSet<CompositeLocation>();
+ if (paramFlowNode != null) {
+ for (Iterator iterator = paramFlowNode.iterator(); iterator.hasNext();) {
+ FlowNode fn = (FlowNode) iterator.next();
+ CompositeLocation inferLoc =
+ generateInferredCompositeLocation(methodInfo, getFlowGraph(md).getLocationTuple(fn));
+ inferParamLocSet.add(inferLoc);
+ }
+ }
+
+ Set<FlowNode> returnNodeSet = fg.getReturnNodeSet();
+
+ skip: for (Iterator iterator = returnNodeSet.iterator(); iterator.hasNext();) {
+ FlowNode returnNode = (FlowNode) iterator.next();
+ CompositeLocation inferReturnLoc =
+ generateInferredCompositeLocation(methodInfo, fg.getLocationTuple(returnNode));
+ if (inferReturnLoc.get(0).getLocIdentifier().equals("this")) {
+ // if the location type of the return value matches "this" reference
+ // then, check whether this return value is equal to/lower than all
+ // of
+ // parameters that possibly flow into the return values
+ for (Iterator iterator2 = inferParamLocSet.iterator(); iterator2.hasNext();) {
+ CompositeLocation paramInferLoc = (CompositeLocation) iterator2.next();
+
+ if ((!paramInferLoc.equals(inferReturnLoc))
+ && !isGreaterThan(methodLattice, paramInferLoc, inferReturnLoc)) {
+ continue skip;
+ }
+ }
+ inferFieldReturnLocSet.add(inferReturnLoc);
+
+ }
+ }
+
+ if (inferFieldReturnLocSet.size() > 0) {
+
+ CompositeLocation returnLoc = getLowest(methodLattice, inferFieldReturnLocSet);
+ if (returnLoc == null) {
+ // in this case, assign <'this',bottom> to the RETURNLOC
+ returnLoc = new CompositeLocation(new Location(md, md.getThis().getSymbol()));
+ returnLoc.addLocation(new Location(md.getClassDesc(), getLattice(md.getClassDesc())
+ .getBottomItem()));
+ }
+ methodInfo.setReturnLoc(returnLoc);
+
+ } else {
+ String returnLocSymbol = "RETURNLOC";
+ CompositeLocation returnLocInferLoc =
+ new CompositeLocation(new Location(md, returnLocSymbol));
+ methodInfo.setReturnLoc(returnLocInferLoc);
+
+ for (Iterator iterator = paramIdxSet.iterator(); iterator.hasNext();) {
+ Integer paramIdx = (Integer) iterator.next();
+ CompositeLocation inferLoc = mapParamToLoc.get(paramIdx);
+ String paramLocLocalSymbol = inferLoc.get(0).getLocIdentifier();
+ if (!methodLattice.isGreaterThan(paramLocLocalSymbol, returnLocSymbol)) {
+ addRelationHigherToLower(methodLattice, methodInfo, paramLocLocalSymbol,
+ returnLocSymbol);
+ }
+ }
- String returnLocSymbol = "RETURNLOC";
+ for (Iterator iterator = returnNodeSet.iterator(); iterator.hasNext();) {
+ FlowNode returnNode = (FlowNode) iterator.next();
+ CompositeLocation inferLoc =
+ generateInferredCompositeLocation(methodInfo, fg.getLocationTuple(returnNode));
+ if (!isGreaterThan(methodLattice, inferLoc, returnLocInferLoc)) {
+ addRelation(methodLattice, methodInfo, inferLoc, returnLocInferLoc);
+ }
+ }
- for (Iterator iterator = keySet.iterator(); iterator.hasNext();) {
- Integer paramIdx = (Integer) iterator.next();
- CompositeLocation inferLoc = mapParamToLoc.get(paramIdx);
- String paramLocLocalSymbol = inferLoc.get(0).getLocIdentifier();
- if (!methodLattice.isGreaterThan(paramLocLocalSymbol, returnLocSymbol)) {
- addRelationHigherToLower(methodLattice, methodInfo, paramLocLocalSymbol, returnLocSymbol);
}
+
}
+ } catch (CyclicFlowException e) {
+ e.printStackTrace();
}
}
+ private Set<String> getHigherLocSymbolThan(SSJavaLattice<String> lattice, String loc) {
+ Set<String> higherLocSet = new HashSet<String>();
+
+ Set<String> locSet = lattice.getTable().keySet();
+ for (Iterator iterator = locSet.iterator(); iterator.hasNext();) {
+ String element = (String) iterator.next();
+ if (lattice.isGreaterThan(element, loc) && (!element.equals(lattice.getTopItem()))) {
+ higherLocSet.add(element);
+ }
+ }
+ return higherLocSet;
+ }
+
+ private CompositeLocation getLowest(SSJavaLattice<String> methodLattice,
+ Set<CompositeLocation> set) {
+
+ CompositeLocation lowest = set.iterator().next();
+
+ if (set.size() == 1) {
+ return lowest;
+ }
+
+ for (Iterator iterator = set.iterator(); iterator.hasNext();) {
+ CompositeLocation loc = (CompositeLocation) iterator.next();
+
+ if ((!loc.equals(lowest)) && (!isComparable(methodLattice, lowest, loc))) {
+ // if there is a case where composite locations are incomparable, just
+ // return null
+ return null;
+ }
+
+ if ((!loc.equals(lowest)) && isGreaterThan(methodLattice, lowest, loc)) {
+ lowest = loc;
+ }
+ }
+ return lowest;
+ }
+
+ private boolean isComparable(SSJavaLattice<String> methodLattice, CompositeLocation comp1,
+ CompositeLocation comp2) {
+
+ int size = comp1.getSize() >= comp2.getSize() ? comp2.getSize() : comp1.getSize();
+
+ for (int idx = 0; idx < size; idx++) {
+ Location loc1 = comp1.get(idx);
+ Location loc2 = comp2.get(idx);
+
+ Descriptor desc1 = loc1.getDescriptor();
+ Descriptor desc2 = loc2.getDescriptor();
+
+ if (!desc1.equals(desc2)) {
+ throw new Error("Fail to compare " + comp1 + " and " + comp2);
+ }
+
+ String symbol1 = loc1.getLocIdentifier();
+ String symbol2 = loc2.getLocIdentifier();
+
+ SSJavaLattice<String> lattice;
+ if (idx == 0) {
+ lattice = methodLattice;
+ } else {
+ lattice = getLattice(desc1);
+ }
+
+ if (symbol1.equals(symbol2)) {
+ continue;
+ } else if (!lattice.isComparable(symbol1, symbol2)) {
+ return false;
+ }
+
+ }
+
+ return true;
+ }
+
private boolean isGreaterThan(SSJavaLattice<String> methodLattice, CompositeLocation comp1,
CompositeLocation comp2) {
throw new Error("Fail to compare " + comp1 + " and " + comp2);
}
- String symbol1 = loc1.getLocIdentifier();
- String symbol2 = loc2.getLocIdentifier();
+ String symbol1 = loc1.getLocIdentifier();
+ String symbol2 = loc2.getLocIdentifier();
+
+ SSJavaLattice<String> lattice;
+ if (idx == 0) {
+ lattice = methodLattice;
+ } else {
+ lattice = getLattice(desc1);
+ }
+
+ if (symbol1.equals(symbol2)) {
+ continue;
+ } else if (lattice.isGreaterThan(symbol1, symbol2)) {
+ return true;
+ } else {
+ return false;
+ }
+
+ }
+
+ return false;
+ }
+
+ private void recursiveAddRelationToLattice(int idx, MethodDescriptor md,
+ CompositeLocation srcInferLoc, CompositeLocation dstInferLoc) throws CyclicFlowException {
+
+ String srcLocSymbol = srcInferLoc.get(idx).getLocIdentifier();
+ String dstLocSymbol = dstInferLoc.get(idx).getLocIdentifier();
+
+ if (srcLocSymbol.equals(dstLocSymbol)) {
+ recursiveAddRelationToLattice(idx + 1, md, srcInferLoc, dstInferLoc);
+ } else {
+
+ Descriptor parentDesc = srcInferLoc.get(idx).getDescriptor();
+ LocationInfo locInfo = getLocationInfo(parentDesc);
+
+ addRelationHigherToLower(getLattice(parentDesc), getLocationInfo(parentDesc), srcLocSymbol,
+ dstLocSymbol);
+ }
+
+ }
+
+ private void propagateFlowsFromCallee(MethodInvokeNode min, MethodDescriptor mdCaller,
+ MethodDescriptor mdCallee) {
+
+ // the transformation for a call site propagates all relations between
+ // parameters from the callee
+ // if the method is virtual, it also grab all relations from any possible
+ // callees
+
+ Set<MethodDescriptor> setPossibleCallees = new HashSet<MethodDescriptor>();
+ if (mdCallee.isStatic()) {
+ setPossibleCallees.add(mdCallee);
+ } else {
+ Set<MethodDescriptor> calleeSet = ssjava.getCallGraph().getMethods(mdCallee);
+ // removes method descriptors that are not invoked by the caller
+ calleeSet.retainAll(mapMethodToCalleeSet.get(mdCaller));
+ setPossibleCallees.addAll(calleeSet);
+ }
+
+ for (Iterator iterator2 = setPossibleCallees.iterator(); iterator2.hasNext();) {
+ MethodDescriptor possibleMdCallee = (MethodDescriptor) iterator2.next();
+ propagateFlowsToCaller(min, mdCaller, possibleMdCallee);
+ }
+
+ }
+
+ private void propagateFlowsToCaller(MethodInvokeNode min, MethodDescriptor mdCaller,
+ MethodDescriptor mdCallee) {
+
+ // if the parameter A reaches to the parameter B
+ // then, add an edge the argument A -> the argument B to the caller's flow
+ // graph
+
+ FlowGraph calleeFlowGraph = getFlowGraph(mdCallee);
+ FlowGraph callerFlowGraph = getFlowGraph(mdCaller);
+ int numParam = calleeFlowGraph.getNumParameters();
+
+ for (int i = 0; i < numParam; i++) {
+ for (int k = 0; k < numParam; k++) {
+
+ if (i != k) {
+
+ FlowNode paramNode1 = calleeFlowGraph.getParamFlowNode(i);
+ FlowNode paramNode2 = calleeFlowGraph.getParamFlowNode(k);
+
+ NodeTupleSet tupleSetArg1 = getNodeTupleSetByArgIdx(min, i);
+ NodeTupleSet tupleSetArg2 = getNodeTupleSetByArgIdx(min, k);
+
+ for (Iterator<NTuple<Descriptor>> iter1 = tupleSetArg1.iterator(); iter1.hasNext();) {
+ NTuple<Descriptor> arg1Tuple = iter1.next();
+
+ for (Iterator<NTuple<Descriptor>> iter2 = tupleSetArg2.iterator(); iter2.hasNext();) {
+ NTuple<Descriptor> arg2Tuple = iter2.next();
+
+ // check if the callee propagates an ordering constraints through
+ // parameters
+
+ Set<FlowNode> localReachSet =
+ calleeFlowGraph.getLocalReachFlowNodeSetFrom(paramNode1);
+
+ if (localReachSet.contains(paramNode2)) {
+ // need to propagate an ordering relation s.t. arg1 is higher
+ // than arg2
+
+ if (!min.getMethod().isStatic()) {
+ // check if this is the case that values flow to/from the
+ // current object reference 'this'
+
+ NTuple<Descriptor> baseTuple = mapMethodInvokeNodeToBaseTuple.get(min);
+ Descriptor baseRef = baseTuple.get(baseTuple.size() - 1);
+
+ // calculate the prefix of the argument
+ if (arg2Tuple.size() == 1 && arg2Tuple.get(0).equals(baseRef)) {
+
+ if (!paramNode1.getCurrentDescTuple().startsWith(mdCallee.getThis())) {
+
+ NTuple<Descriptor> param1Prefix =
+ calculatePrefixForParam(callerFlowGraph, calleeFlowGraph, min, arg1Tuple,
+ paramNode1);
+
+ if (param1Prefix != null && param1Prefix.startsWith(mdCallee.getThis())) {
+ // in this case, we need to create a new edge
+ // 'this.FIELD'->'this'
+ // but we couldn't... instead we assign the
+ // corresponding
+ // parameter a new composite location started with
+ // 'this'
+ // reference
+
+ CompositeLocation compLocForParam1 =
+ generateCompositeLocation(mdCallee, param1Prefix);
+
+ // System.out.println("set comp loc=" + compLocForParam1
+ // +
+ // " to " + paramNode1);
+ paramNode1.setCompositeLocation(compLocForParam1);
+ continue;
+ }
+ }
+
+ } else if (arg1Tuple.size() == 1 && arg1Tuple.get(0).equals(baseRef)) {
+
+ if (!paramNode2.getCurrentDescTuple().startsWith(mdCallee.getThis())) {
+
+ NTuple<Descriptor> param2Prefix =
+ calculatePrefixForParam(callerFlowGraph, calleeFlowGraph, min, arg1Tuple,
+ paramNode1);
+
+ if (param2Prefix != null && param2Prefix.startsWith(mdCallee.getThis())) {
+ // in this case, we need to create a new edge 'this' ->
+ // 'this.FIELD'
+ // but we couldn't... instead we assign the
+ // corresponding
+ // parameter a new composite location started with
+ // 'this'
+ // reference
+
+ CompositeLocation compLocForParam2 =
+ generateCompositeLocation(mdCallee, param2Prefix);
+
+ // System.out.println("set comp loc=" + compLocForParam2
+ // +
+ // " to " + paramNode2);
+ paramNode1.setCompositeLocation(compLocForParam2);
+ continue;
+ }
+ }
+
+ }
+ }
+
+ // otherwise, flows between method/field locations...
+ callerFlowGraph.addValueFlowEdge(arg1Tuple, arg2Tuple);
+ // System.out.println("arg1=" + arg1Tuple + " arg2=" +
+ // arg2Tuple);
+
+ }
+
+ }
+
+ }
+ }
+ }
+ }
+
+ }
+
+ private CompositeLocation generateCompositeLocation(MethodDescriptor md,
+ NTuple<Descriptor> param1Prefix) {
+
+ CompositeLocation newCompLoc = convertToCompositeLocation(md, param1Prefix);
+
+ LocationDescriptor newLocDescriptor = generateNewLocationDescriptor();
+
+ Descriptor enclosingDescriptor = param1Prefix.get(param1Prefix.size() - 1);
+ Location newLoc = new Location(enclosingDescriptor, newLocDescriptor.getSymbol());
+ newLoc.setLocDescriptor(newLocDescriptor);
+ newCompLoc.addLocation(newLoc);
+
+ System.out.println("newCompLoc=" + newCompLoc);
+ return newCompLoc;
+ }
+
+ private NTuple<Descriptor> calculatePrefixForParam(FlowGraph callerFlowGraph,
+ FlowGraph calleeFlowGraph, MethodInvokeNode min, NTuple<Descriptor> arg1Tuple,
+ FlowNode paramNode1) {
+
+ NTuple<Descriptor> baseTuple = mapMethodInvokeNodeToBaseTuple.get(min);
+ Descriptor baseRef = baseTuple.get(baseTuple.size() - 1);
+ System.out.println("baseRef=" + baseRef);
+
+ FlowNode flowNodeArg1 = callerFlowGraph.getFlowNode(arg1Tuple);
+ List<NTuple<Descriptor>> callerPrefixList = calculatePrefixList(callerFlowGraph, flowNodeArg1);
+ System.out.println("callerPrefixList=" + callerPrefixList);
+
+ List<NTuple<Descriptor>> calleePrefixList =
+ translatePrefixListToCallee(baseRef, min.getMethod(), callerPrefixList);
+
+ System.out.println("calleePrefixList=" + calleePrefixList);
+
+ Set<FlowNode> reachNodeSetFromParam1 = calleeFlowGraph.getReachFlowNodeSetFrom(paramNode1);
+ System.out.println("reachNodeSetFromParam1=" + reachNodeSetFromParam1);
+
+ for (int i = 0; i < calleePrefixList.size(); i++) {
+ NTuple<Descriptor> curPrefix = calleePrefixList.get(i);
+ Set<NTuple<Descriptor>> reachableCommonPrefixSet = new HashSet<NTuple<Descriptor>>();
+
+ for (Iterator iterator2 = reachNodeSetFromParam1.iterator(); iterator2.hasNext();) {
+ FlowNode reachNode = (FlowNode) iterator2.next();
+ if (reachNode.getCurrentDescTuple().startsWith(curPrefix)) {
+ reachableCommonPrefixSet.add(reachNode.getCurrentDescTuple());
+ }
+ }
+
+ if (!reachableCommonPrefixSet.isEmpty()) {
+ System.out.println("###REACHABLECOMONPREFIX=" + reachableCommonPrefixSet
+ + " with curPreFix=" + curPrefix);
+ return curPrefix;
+ }
+
+ }
+
+ return null;
+ }
+
+ private List<NTuple<Descriptor>> translatePrefixListToCallee(Descriptor baseRef,
+ MethodDescriptor mdCallee, List<NTuple<Descriptor>> callerPrefixList) {
+
+ List<NTuple<Descriptor>> calleePrefixList = new ArrayList<NTuple<Descriptor>>();
+
+ for (int i = 0; i < callerPrefixList.size(); i++) {
+ NTuple<Descriptor> prefix = callerPrefixList.get(i);
+ if (prefix.startsWith(baseRef)) {
+ NTuple<Descriptor> calleePrefix = new NTuple<Descriptor>();
+ calleePrefix.add(mdCallee.getThis());
+ for (int k = 1; k < prefix.size(); k++) {
+ calleePrefix.add(prefix.get(k));
+ }
+ calleePrefixList.add(calleePrefix);
+ }
+ }
+
+ return calleePrefixList;
+
+ }
+
+ private List<NTuple<Descriptor>> calculatePrefixList(FlowGraph flowGraph, FlowNode flowNode) {
+
+ Set<FlowNode> inNodeSet = flowGraph.getIncomingFlowNodeSet(flowNode);
+ inNodeSet.add(flowNode);
+
+ List<NTuple<Descriptor>> prefixList = new ArrayList<NTuple<Descriptor>>();
+
+ for (Iterator iterator = inNodeSet.iterator(); iterator.hasNext();) {
+ FlowNode inNode = (FlowNode) iterator.next();
+
+ NTuple<Descriptor> inNodeTuple = inNode.getCurrentDescTuple();
+
+ // CompositeLocation inNodeInferredLoc =
+ // generateInferredCompositeLocation(methodInfo, inNodeTuple);
+ // NTuple<Location> inNodeInferredLocTuple = inNodeInferredLoc.getTuple();
+
+ for (int i = 1; i < inNodeTuple.size(); i++) {
+ NTuple<Descriptor> prefix = inNodeTuple.subList(0, i);
+ if (!prefixList.contains(prefix)) {
+ prefixList.add(prefix);
+ }
+ }
+ }
+
+ Collections.sort(prefixList, new Comparator<NTuple<Descriptor>>() {
+ public int compare(NTuple<Descriptor> arg0, NTuple<Descriptor> arg1) {
+ int s0 = arg0.size();
+ int s1 = arg1.size();
+ if (s0 > s1) {
+ return -1;
+ } else if (s0 == s1) {
+ return 0;
+ } else {
+ return 1;
+ }
+ }
+ });
+
+ return prefixList;
+
+ }
+
+ public CompositeLocation convertToCompositeLocation(MethodDescriptor md, NTuple<Descriptor> tuple) {
+
+ CompositeLocation compLoc = new CompositeLocation();
+
+ Descriptor enclosingDescriptor = md;
- SSJavaLattice<String> lattice;
- if (idx == 0) {
- lattice = methodLattice;
- } else {
- lattice = getLattice(desc1);
- }
- if (symbol1.equals(symbol2)) {
- continue;
- } else if (lattice.isGreaterThan(symbol1, symbol2)) {
- return true;
+ for (int i = 0; i < tuple.size(); i++) {
+ Descriptor curDescriptor = tuple.get(i);
+ Location locElement = new Location(enclosingDescriptor, curDescriptor.getSymbol());
+ locElement.setLocDescriptor(curDescriptor);
+ compLoc.addLocation(locElement);
+
+ if (curDescriptor instanceof VarDescriptor) {
+ enclosingDescriptor = md.getClassDesc();
+ } else if (curDescriptor instanceof NameDescriptor) {
+ // it is "GLOBAL LOC" case!
+ enclosingDescriptor = GLOBALDESC;
} else {
- return false;
+ enclosingDescriptor = ((FieldDescriptor) curDescriptor).getClassDescriptor();
}
}
- return false;
+ System.out.println("convertToCompositeLocation from=" + tuple + " to " + compLoc);
+
+ return compLoc;
}
- private void recursiveAddRelationToLattice(int idx, MethodDescriptor md,
- CompositeLocation srcInferLoc, CompositeLocation dstInferLoc) throws CyclicFlowException {
+ private LocationDescriptor generateNewLocationDescriptor() {
+ return new LocationDescriptor("Loc" + (locSeed++));
+ }
- String srcLocSymbol = srcInferLoc.get(idx).getLocIdentifier();
- String dstLocSymbol = dstInferLoc.get(idx).getLocIdentifier();
+ private int getPrefixIndex(NTuple<Descriptor> tuple1, NTuple<Descriptor> tuple2) {
- if (srcLocSymbol.equals(dstLocSymbol)) {
- recursiveAddRelationToLattice(idx + 1, md, srcInferLoc, dstInferLoc);
- } else {
+ // return the index where the prefix shared by tuple1 and tuple2 is ended
+ // if there is no prefix shared by both of them, return -1
- Descriptor parentDesc = srcInferLoc.get(idx).getDescriptor();
- LocationInfo locInfo = getLocationInfo(parentDesc);
+ int minSize = tuple1.size();
+ if (minSize > tuple2.size()) {
+ minSize = tuple2.size();
+ }
- addRelationHigherToLower(getLattice(parentDesc), getLocationInfo(parentDesc), srcLocSymbol,
- dstLocSymbol);
+ int idx = -1;
+ for (int i = 0; i < minSize; i++) {
+ if (!tuple1.get(i).equals(tuple2.get(i))) {
+ break;
+ } else {
+ idx++;
+ }
}
+ return idx;
}
private void analyzeLatticeMethodInvocationNode(MethodDescriptor mdCaller,
for (int k = 0; k < numParam; k++) {
if (i != k) {
CompositeLocation param2 = calleeLocInfo.getParamCompositeLocation(k);
+
if (isGreaterThan(getLattice(possibleMdCallee), param1, param2)) {
NodeTupleSet argDescTupleSet1 = getNodeTupleSetByArgIdx(min, i);
NodeTupleSet argDescTupleSet2 = getNodeTupleSetByArgIdx(min, k);
for (int i = 0; i < localVarInferLoc.getSize(); i++) {
inferLoc.addLocation(localVarInferLoc.get(i));
}
- // System.out.println("@@@@@localVarInferLoc=" + localVarInferLoc);
for (int i = 1; i < tuple.size(); i++) {
Location cur = tuple.get(i);
Location inferLocElement;
if (curDesc == null) {
// in this case, we have a newly generated location.
- // System.out.println("!!! generated location=" +
- // cur.getLocIdentifier());
inferLocElement = new Location(enclosingDesc, cur.getLocIdentifier());
} else {
String fieldLocSymbol =
FlowGraph flowGraph = getFlowGraph(md);
try {
System.out.println("***** src composite case::");
- calculateCompositeLocation(flowGraph, methodLattice, methodInfo, srcNode);
+ calculateCompositeLocation(flowGraph, methodLattice, methodInfo, srcNode, null);
CompositeLocation srcInferLoc =
generateInferredCompositeLocation(methodInfo, flowGraph.getLocationTuple(srcNode));
// there is a cyclic value flow... try to calculate a composite location
// for the destination node
System.out.println("***** dst composite case::");
- calculateCompositeLocation(flowGraph, methodLattice, methodInfo, dstNode);
+ calculateCompositeLocation(flowGraph, methodLattice, methodInfo, dstNode, srcNode);
CompositeLocation srcInferLoc =
generateInferredCompositeLocation(methodInfo, flowGraph.getLocationTuple(srcNode));
CompositeLocation dstInferLoc =
}
private boolean calculateCompositeLocation(FlowGraph flowGraph,
- SSJavaLattice<String> methodLattice, MethodLocationInfo methodInfo, FlowNode flowNode)
- throws CyclicFlowException {
+ SSJavaLattice<String> methodLattice, MethodLocationInfo methodInfo, FlowNode flowNode,
+ FlowNode srcNode) throws CyclicFlowException {
Descriptor localVarDesc = flowNode.getDescTuple().get(0);
NTuple<Location> flowNodelocTuple = flowGraph.getLocationTuple(flowNode);
}
Set<FlowNode> inNodeSet = flowGraph.getIncomingFlowNodeSet(flowNode);
- Set<FlowNode> reachableNodeSet = flowGraph.getReachableFlowNodeSet(flowNode);
+ Set<FlowNode> reachableNodeSet = flowGraph.getReachFlowNodeSetFrom(flowNode);
Map<NTuple<Location>, Set<NTuple<Location>>> mapPrefixToIncomingLocTupleSet =
new HashMap<NTuple<Location>, Set<NTuple<Location>>>();
}
});
+ // System.out.println("prefixList=" + prefixList);
+ // System.out.println("reachableNodeSet=" + reachableNodeSet);
+
// find out reachable nodes that have the longest common prefix
for (int i = 0; i < prefixList.size(); i++) {
NTuple<Location> curPrefix = prefixList.get(i);
if (inferLocation.getTuple().startsWith(curPrefix)) {
// the same infer location is already existed. no need to do
// anything
+ System.out.println("NO ATTEMPT TO MAKE A COMPOSITE LOCATION curPrefix=" + curPrefix);
+
+ // TODO: refactoring!
+ if (srcNode != null) {
+ CompositeLocation newLoc = new CompositeLocation();
+ String newLocSymbol = "Loc" + (SSJavaLattice.seed++);
+ for (int locIdx = 0; locIdx < curPrefix.size(); locIdx++) {
+ newLoc.addLocation(curPrefix.get(locIdx));
+ }
+ Location newLocationElement = new Location(desc, newLocSymbol);
+ newLoc.addLocation(newLocationElement);
+
+ Descriptor srcLocalVar = srcNode.getDescTuple().get(0);
+ methodInfo.mapDescriptorToLocation(srcLocalVar, newLoc.clone());
+ addMapLocSymbolToInferredLocation(methodInfo.getMethodDesc(), srcLocalVar, newLoc);
+ methodInfo.removeMaplocalVarToLocSet(srcLocalVar);
+
+ // add the field/var descriptor to the set of the location symbol
+ int lastIdx = srcNode.getDescTuple().size() - 1;
+ Descriptor lastFlowNodeDesc = srcNode.getDescTuple().get(lastIdx);
+ NTuple<Location> srcNodelocTuple = flowGraph.getLocationTuple(srcNode);
+ Descriptor enclosinglastLastFlowNodeDesc = srcNodelocTuple.get(lastIdx).getDescriptor();
+
+ CompositeLocation newlyInferredLocForFlowNode =
+ generateInferredCompositeLocation(methodInfo, srcNodelocTuple);
+ Location lastInferLocElement =
+ newlyInferredLocForFlowNode.get(newlyInferredLocForFlowNode.getSize() - 1);
+ Descriptor enclosingLastInferLocElement = lastInferLocElement.getDescriptor();
+
+ // getLocationInfo(enclosingLastInferLocElement).addMapLocSymbolToDescSet(
+ // lastInferLocElement.getLocIdentifier(), lastFlowNodeDesc);
+ getLocationInfo(enclosingLastInferLocElement).addMapLocSymbolToRelatedInferLoc(
+ lastInferLocElement.getLocIdentifier(), enclosinglastLastFlowNodeDesc,
+ lastFlowNodeDesc);
+
+ System.out.println("@@@@@@@ ASSIGN " + newLoc + " to SRC=" + srcNode);
+ }
+
return true;
} else {
// assign a new composite location
}
+ System.out.println("curPrefix=" + curPrefix);
System.out.println("ASSIGN NEW COMPOSITE LOCATION =" + newInferLocation + " to "
+ flowNode);
String newSharedLoc = "SharedLoc" + (SSJavaLattice.seed++);
System.out.println("---ASSIGN NEW SHARED LOC=" + newSharedLoc + " to " + cycleElementSet);
- lattice.mergeIntoSharedLocation(cycleElementSet, newSharedLoc);
+ lattice.mergeIntoNewLocation(cycleElementSet, newSharedLoc);
+ lattice.addSharedLoc(newSharedLoc);
for (Iterator iterator = cycleElementSet.iterator(); iterator.hasNext();) {
String oldLocSymbol = (String) iterator.next();
md2lattice.put(md, lattice);
}
+ private void extractFlowsBetweenFields(ClassDescriptor cd, FlowNode srcNode, FlowNode dstNode,
+ int idx) {
+
+ NTuple<Descriptor> srcCurTuple = srcNode.getCurrentDescTuple();
+ NTuple<Descriptor> dstCurTuple = dstNode.getCurrentDescTuple();
+
+ if (srcCurTuple.get(idx).equals(dstCurTuple.get(idx)) && srcCurTuple.size() > (idx + 1)
+ && dstCurTuple.size() > (idx + 1)) {
+ // value flow between fields: we don't need to add a binary relation
+ // for this case
+
+ Descriptor desc = srcCurTuple.get(idx);
+ ClassDescriptor classDesc;
+
+ if (idx == 0) {
+ classDesc = ((VarDescriptor) desc).getType().getClassDesc();
+ } else {
+ classDesc = ((FieldDescriptor) desc).getType().getClassDesc();
+ }
+
+ extractFlowsBetweenFields(classDesc, srcNode, dstNode, idx + 1);
+
+ } else {
+
+ Descriptor srcFieldDesc = srcCurTuple.get(idx);
+ Descriptor dstFieldDesc = dstCurTuple.get(idx);
+
+ // add a new edge
+ getHierarchyGraph(cd).addEdge(srcFieldDesc, dstFieldDesc);
+
+ }
+
+ }
+
private void extractRelationFromFieldFlows(ClassDescriptor cd, FlowNode srcNode,
FlowNode dstNode, int idx) throws CyclicFlowException {
return cd2lattice.get(cd);
}
- public void constructFlowGraph() {
+ public LinkedList<MethodDescriptor> computeMethodList() {
+
+ Set<MethodDescriptor> toSort = new HashSet<MethodDescriptor>();
setupToAnalyze();
MethodDescriptor md = toAnalyzeMethodNext();
if ((!visited.contains(md))
&& (ssjava.needTobeAnnotated(md) || reachableCallee.contains(md))) {
- if (state.SSJAVADEBUG) {
- System.out.println();
- System.out.println("SSJAVA: Constructing a flow graph: " + md);
- }
// creates a mapping from a method descriptor to virtual methods
Set<MethodDescriptor> setPossibleCallees = new HashSet<MethodDescriptor>();
mapMethodToCalleeSet.put(md, needToAnalyzeCalleeSet);
- // creates a mapping from a parameter descriptor to its index
- Map<Descriptor, Integer> mapParamDescToIdx = new HashMap<Descriptor, Integer>();
- int offset = md.isStatic() ? 0 : 1;
- for (int i = 0; i < md.numParameters(); i++) {
- Descriptor paramDesc = (Descriptor) md.getParameter(i);
- mapParamDescToIdx.put(paramDesc, new Integer(i + offset));
+ visited.add(md);
+
+ toSort.add(md);
+ }
+ }
+ }
+
+ return ssjava.topologicalSort(toSort);
+
+ }
+
+ public void constructFlowGraph() {
+
+ System.out.println("");
+ LinkedList<MethodDescriptor> methodDescList = computeMethodList();
+
+ System.out.println("@@@methodDescList=" + methodDescList);
+ // System.exit(0);
+
+ while (!methodDescList.isEmpty()) {
+ MethodDescriptor md = methodDescList.removeLast();
+ if (state.SSJAVADEBUG) {
+ System.out.println();
+ System.out.println("SSJAVA: Constructing a flow graph: " + md);
+
+ // creates a mapping from a parameter descriptor to its index
+ Map<Descriptor, Integer> mapParamDescToIdx = new HashMap<Descriptor, Integer>();
+ int offset = 0;
+ if (!md.isStatic()) {
+ offset = 1;
+ mapParamDescToIdx.put(md.getThis(), 0);
+ }
+
+ for (int i = 0; i < md.numParameters(); i++) {
+ Descriptor paramDesc = (Descriptor) md.getParameter(i);
+ mapParamDescToIdx.put(paramDesc, new Integer(i + offset));
+ }
+
+ FlowGraph fg = new FlowGraph(md, mapParamDescToIdx);
+ mapMethodDescriptorToFlowGraph.put(md, fg);
+
+ analyzeMethodBody(md.getClassDesc(), md);
+ propagateFlowsFromCallees(md);
+ assignCompositeLocation(md);
+
+ }
+ }
+ _debug_printGraph();
+
+ }
+
+ private void assignCompositeLocation(MethodDescriptor md) {
+
+ FlowGraph flowGraph = getFlowGraph(md);
+
+ Set<FlowNode> nodeSet = flowGraph.getNodeSet();
+
+ next: for (Iterator iterator = nodeSet.iterator(); iterator.hasNext();) {
+ FlowNode flowNode = (FlowNode) iterator.next();
+
+ // assign a composite location only to the local variable
+ if (flowNode.getCurrentDescTuple().size() == 1) {
+
+ List<NTuple<Descriptor>> prefixList = calculatePrefixList(flowGraph, flowNode);
+ Set<FlowNode> reachSet = flowGraph.getReachFlowNodeSetFrom(flowNode);
+
+ for (int i = 0; i < prefixList.size(); i++) {
+ NTuple<Descriptor> curPrefix = prefixList.get(i);
+ Set<NTuple<Descriptor>> reachableCommonPrefixSet = new HashSet<NTuple<Descriptor>>();
+
+ for (Iterator iterator2 = reachSet.iterator(); iterator2.hasNext();) {
+ FlowNode reachNode = (FlowNode) iterator2.next();
+ if (reachNode.getCurrentDescTuple().startsWith(curPrefix)) {
+ reachableCommonPrefixSet.add(reachNode.getCurrentDescTuple());
+ }
}
- FlowGraph fg = new FlowGraph(md, mapParamDescToIdx);
- mapMethodDescriptorToFlowGraph.put(md, fg);
+ if (!reachableCommonPrefixSet.isEmpty()) {
+ System.out.println("NEED TO ASSIGN COMP LOC TO " + flowNode + " with prefix="
+ + curPrefix);
+ CompositeLocation newCompLoc = generateCompositeLocation(md, curPrefix);
+ flowNode.setCompositeLocation(newCompLoc);
+ continue next;
+ }
- visited.add(md);
- analyzeMethodBody(cd, md);
+ }
+ }
+
+ }
+
+ }
+
+ private void propagateFlowsFromCallees(MethodDescriptor mdCaller) {
+
+ // the transformation for a call site propagates flows through parameters
+ // if the method is virtual, it also grab all relations from any possible
+ // callees
+
+ Set<MethodInvokeNode> setMethodInvokeNode =
+ mapMethodDescriptorToMethodInvokeNodeSet.get(mdCaller);
+
+ if (setMethodInvokeNode != null) {
+
+ for (Iterator iterator = setMethodInvokeNode.iterator(); iterator.hasNext();) {
+ MethodInvokeNode min = (MethodInvokeNode) iterator.next();
+ MethodDescriptor mdCallee = min.getMethod();
+ Set<MethodDescriptor> setPossibleCallees = new HashSet<MethodDescriptor>();
+ if (mdCallee.isStatic()) {
+ setPossibleCallees.add(mdCallee);
+ } else {
+ Set<MethodDescriptor> calleeSet = ssjava.getCallGraph().getMethods(mdCallee);
+ // removes method descriptors that are not invoked by the caller
+ calleeSet.retainAll(mapMethodToCalleeSet.get(mdCaller));
+ setPossibleCallees.addAll(calleeSet);
+ }
+ for (Iterator iterator2 = setPossibleCallees.iterator(); iterator2.hasNext();) {
+ MethodDescriptor possibleMdCallee = (MethodDescriptor) iterator2.next();
+ propagateFlowsToCaller(min, mdCaller, possibleMdCallee);
}
+
}
}
- _debug_printGraph();
}
private void analyzeMethodBody(ClassDescriptor cd, MethodDescriptor md) {
break;
case Kind.SwitchStatementNode:
- analyzeSwitchStatementNode(md, nametable, (SwitchStatementNode) bsn);
+ analyzeSwitchStatementNode(md, nametable, (SwitchStatementNode) bsn, implicitFlowTupleSet);
break;
}
}
+ private void analyzeSwitchBlockNode(MethodDescriptor md, SymbolTable nametable,
+ SwitchBlockNode sbn, NodeTupleSet implicitFlowTupleSet) {
+
+ analyzeFlowBlockNode(md, nametable, sbn.getSwitchBlockStatement(), implicitFlowTupleSet);
+
+ }
+
private void analyzeSwitchStatementNode(MethodDescriptor md, SymbolTable nametable,
- SwitchStatementNode bsn) {
- // TODO Auto-generated method stub
+ SwitchStatementNode ssn, NodeTupleSet implicitFlowTupleSet) {
+
+ NodeTupleSet condTupleNode = new NodeTupleSet();
+ analyzeFlowExpressionNode(md, nametable, ssn.getCondition(), condTupleNode, null,
+ implicitFlowTupleSet, false);
+
+ NodeTupleSet newImplicitTupleSet = new NodeTupleSet();
+
+ newImplicitTupleSet.addTupleSet(implicitFlowTupleSet);
+ newImplicitTupleSet.addTupleSet(condTupleNode);
+
+ if (newImplicitTupleSet.size() > 1) {
+ // need to create an intermediate node for the GLB of conditional locations & implicit flows
+ NTuple<Descriptor> interTuple = getFlowGraph(md).createIntermediateNode().getDescTuple();
+ for (Iterator<NTuple<Descriptor>> idxIter = newImplicitTupleSet.iterator(); idxIter.hasNext();) {
+ NTuple<Descriptor> tuple = idxIter.next();
+ addFlowGraphEdge(md, tuple, interTuple);
+ }
+ newImplicitTupleSet.clear();
+ newImplicitTupleSet.addTuple(interTuple);
+ }
+
+ BlockNode sbn = ssn.getSwitchBody();
+ for (int i = 0; i < sbn.size(); i++) {
+ analyzeSwitchBlockNode(md, nametable, (SwitchBlockNode) sbn.get(i), newImplicitTupleSet);
+ }
+
}
private void analyzeFlowSubBlockNode(MethodDescriptor md, SymbolTable nametable,
if (returnExp != null) {
NodeTupleSet nodeSet = new NodeTupleSet();
+ // if a return expression returns a literal value, nodeSet is empty
analyzeFlowExpressionNode(md, nametable, returnExp, nodeSet, false);
-
FlowGraph fg = getFlowGraph(md);
- // annotate the elements of the node set as the return location
- for (Iterator iterator = nodeSet.iterator(); iterator.hasNext();) {
- NTuple<Descriptor> returnDescTuple = (NTuple<Descriptor>) iterator.next();
- fg.setReturnFlowNode(returnDescTuple);
- for (Iterator iterator2 = implicitFlowTupleSet.iterator(); iterator2.hasNext();) {
- NTuple<Descriptor> implicitFlowDescTuple = (NTuple<Descriptor>) iterator2.next();
- fg.addValueFlowEdge(implicitFlowDescTuple, returnDescTuple);
+ // if (implicitFlowTupleSet.size() == 1
+ // && fg.getFlowNode(implicitFlowTupleSet.iterator().next()).isIntermediate()) {
+ //
+ // // since there is already an intermediate node for the GLB of implicit flows
+ // // we don't need to create another intermediate node.
+ // // just re-use the intermediate node for implicit flows.
+ //
+ // FlowNode meetNode = fg.getFlowNode(implicitFlowTupleSet.iterator().next());
+ //
+ // for (Iterator iterator = nodeSet.iterator(); iterator.hasNext();) {
+ // NTuple<Descriptor> returnNodeTuple = (NTuple<Descriptor>) iterator.next();
+ // fg.addValueFlowEdge(returnNodeTuple, meetNode.getDescTuple());
+ // }
+ //
+ // }
+
+ NodeTupleSet currentFlowTupleSet = new NodeTupleSet();
+
+ // add tuples from return node
+ currentFlowTupleSet.addTupleSet(nodeSet);
+
+ // add tuples corresponding to the current implicit flows
+ currentFlowTupleSet.addTupleSet(implicitFlowTupleSet);
+
+ if (currentFlowTupleSet.size() > 1) {
+ FlowNode meetNode = fg.createIntermediateNode();
+ for (Iterator iterator = currentFlowTupleSet.iterator(); iterator.hasNext();) {
+ NTuple<Descriptor> currentFlowTuple = (NTuple<Descriptor>) iterator.next();
+ fg.addValueFlowEdge(currentFlowTuple, meetNode.getDescTuple());
}
+ fg.addReturnFlowNode(meetNode.getDescTuple());
+ } else if (currentFlowTupleSet.size() == 1) {
+ NTuple<Descriptor> tuple = currentFlowTupleSet.iterator().next();
+ fg.addReturnFlowNode(tuple);
}
+
}
}
NodeTupleSet condTupleNode = new NodeTupleSet();
analyzeFlowExpressionNode(md, nametable, ln.getCondition(), condTupleNode, null,
implicitFlowTupleSet, false);
- condTupleNode.addTupleSet(implicitFlowTupleSet);
+
+ NodeTupleSet newImplicitTupleSet = new NodeTupleSet();
+
+ newImplicitTupleSet.addTupleSet(implicitFlowTupleSet);
+ newImplicitTupleSet.addTupleSet(condTupleNode);
+
+ if (newImplicitTupleSet.size() > 1) {
+ // need to create an intermediate node for the GLB of conditional locations & implicit flows
+ NTuple<Descriptor> interTuple = getFlowGraph(md).createIntermediateNode().getDescTuple();
+ for (Iterator<NTuple<Descriptor>> idxIter = newImplicitTupleSet.iterator(); idxIter
+ .hasNext();) {
+ NTuple<Descriptor> tuple = idxIter.next();
+ addFlowGraphEdge(md, tuple, interTuple);
+ }
+ newImplicitTupleSet.clear();
+ newImplicitTupleSet.addTuple(interTuple);
+
+ }
+
+ // ///////////
+ // System.out.println("condTupleNode="+condTupleNode);
+ // NTuple<Descriptor> interTuple = getFlowGraph(md).createIntermediateNode().getDescTuple();
+ //
+ // for (Iterator<NTuple<Descriptor>> idxIter = condTupleNode.iterator(); idxIter.hasNext();) {
+ // NTuple<Descriptor> tuple = idxIter.next();
+ // addFlowGraphEdge(md, tuple, interTuple);
+ // }
+
+ // for (Iterator<NTuple<Descriptor>> idxIter = implicitFlowTupleSet.iterator(); idxIter
+ // .hasNext();) {
+ // NTuple<Descriptor> tuple = idxIter.next();
+ // addFlowGraphEdge(md, tuple, interTuple);
+ // }
+
+ // NodeTupleSet newImplicitSet = new NodeTupleSet();
+ // newImplicitSet.addTuple(interTuple);
+ analyzeFlowBlockNode(md, nametable, ln.getBody(), newImplicitTupleSet);
+ // ///////////
+
+ // condTupleNode.addTupleSet(implicitFlowTupleSet);
// add edges from condNodeTupleSet to all nodes of conditional nodes
- analyzeFlowBlockNode(md, nametable, ln.getBody(), condTupleNode);
+ // analyzeFlowBlockNode(md, nametable, ln.getBody(), condTupleNode);
} else {
// check 'for loop' case
NodeTupleSet condTupleNode = new NodeTupleSet();
analyzeFlowExpressionNode(md, bn.getVarTable(), ln.getCondition(), condTupleNode, null,
implicitFlowTupleSet, false);
- condTupleNode.addTupleSet(implicitFlowTupleSet);
- analyzeFlowBlockNode(md, bn.getVarTable(), ln.getUpdate(), condTupleNode);
- analyzeFlowBlockNode(md, bn.getVarTable(), ln.getBody(), condTupleNode);
+ // ///////////
+ NTuple<Descriptor> interTuple = getFlowGraph(md).createIntermediateNode().getDescTuple();
+
+ for (Iterator<NTuple<Descriptor>> idxIter = condTupleNode.iterator(); idxIter.hasNext();) {
+ NTuple<Descriptor> tuple = idxIter.next();
+ addFlowGraphEdge(md, tuple, interTuple);
+ }
+
+ for (Iterator<NTuple<Descriptor>> idxIter = implicitFlowTupleSet.iterator(); idxIter
+ .hasNext();) {
+ NTuple<Descriptor> tuple = idxIter.next();
+ addFlowGraphEdge(md, tuple, interTuple);
+ }
+
+ NodeTupleSet newImplicitSet = new NodeTupleSet();
+ newImplicitSet.addTuple(interTuple);
+ analyzeFlowBlockNode(md, bn.getVarTable(), ln.getUpdate(), newImplicitSet);
+ analyzeFlowBlockNode(md, bn.getVarTable(), ln.getBody(), newImplicitSet);
+ // ///////////
+
+ // condTupleNode.addTupleSet(implicitFlowTupleSet);
+ //
+ // analyzeFlowBlockNode(md, bn.getVarTable(), ln.getUpdate(),
+ // condTupleNode);
+ // analyzeFlowBlockNode(md, bn.getVarTable(), ln.getBody(),
+ // condTupleNode);
}
private void analyzeFlowIfStatementNode(MethodDescriptor md, SymbolTable nametable,
IfStatementNode isn, NodeTupleSet implicitFlowTupleSet) {
+ System.out.println("analyzeFlowIfStatementNode=" + isn.printNode(0));
+
NodeTupleSet condTupleNode = new NodeTupleSet();
analyzeFlowExpressionNode(md, nametable, isn.getCondition(), condTupleNode, null,
implicitFlowTupleSet, false);
- // add edges from condNodeTupleSet to all nodes of conditional nodes
- condTupleNode.addTupleSet(implicitFlowTupleSet);
- analyzeFlowBlockNode(md, nametable, isn.getTrueBlock(), condTupleNode);
+ NodeTupleSet newImplicitTupleSet = new NodeTupleSet();
+
+ newImplicitTupleSet.addTupleSet(implicitFlowTupleSet);
+ newImplicitTupleSet.addTupleSet(condTupleNode);
+
+ System.out.println("condTupleNode=" + condTupleNode);
+ System.out.println("implicitFlowTupleSet=" + implicitFlowTupleSet);
+ System.out.println("newImplicitTupleSet=" + newImplicitTupleSet);
+
+ if (newImplicitTupleSet.size() > 1) {
+
+ // need to create an intermediate node for the GLB of conditional locations & implicit flows
+ NTuple<Descriptor> interTuple = getFlowGraph(md).createIntermediateNode().getDescTuple();
+ for (Iterator<NTuple<Descriptor>> idxIter = newImplicitTupleSet.iterator(); idxIter.hasNext();) {
+ NTuple<Descriptor> tuple = idxIter.next();
+ addFlowGraphEdge(md, tuple, interTuple);
+ }
+ newImplicitTupleSet.clear();
+ newImplicitTupleSet.addTuple(interTuple);
+ }
+
+ analyzeFlowBlockNode(md, nametable, isn.getTrueBlock(), newImplicitTupleSet);
if (isn.getFalseBlock() != null) {
- analyzeFlowBlockNode(md, nametable, isn.getFalseBlock(), condTupleNode);
+ analyzeFlowBlockNode(md, nametable, isn.getFalseBlock(), newImplicitTupleSet);
}
}
if (dn.getExpression() != null) {
- NodeTupleSet tupleSetRHS = new NodeTupleSet();
- analyzeFlowExpressionNode(md, nametable, dn.getExpression(), tupleSetRHS, null,
+ NodeTupleSet nodeSetRHS = new NodeTupleSet();
+ analyzeFlowExpressionNode(md, nametable, dn.getExpression(), nodeSetRHS, null,
implicitFlowTupleSet, false);
- // add a new flow edge from rhs to lhs
- for (Iterator<NTuple<Descriptor>> iter = tupleSetRHS.iterator(); iter.hasNext();) {
- NTuple<Descriptor> from = iter.next();
- addFlowGraphEdge(md, from, tupleLHS);
+ // creates edges from RHS to LHS
+ NTuple<Descriptor> interTuple = null;
+ if (nodeSetRHS.size() > 1) {
+ interTuple = getFlowGraph(md).createIntermediateNode().getDescTuple();
+ }
+
+ for (Iterator<NTuple<Descriptor>> iter = nodeSetRHS.iterator(); iter.hasNext();) {
+ NTuple<Descriptor> fromTuple = iter.next();
+ addFlowGraphEdge(md, fromTuple, interTuple, tupleLHS);
+ }
+
+ // creates edges from implicitFlowTupleSet to LHS
+ for (Iterator<NTuple<Descriptor>> iter = implicitFlowTupleSet.iterator(); iter.hasNext();) {
+ NTuple<Descriptor> implicitTuple = iter.next();
+ addFlowGraphEdge(md, implicitTuple, tupleLHS);
}
}
break;
case Kind.MethodInvokeNode:
- analyzeFlowMethodInvokeNode(md, nametable, (MethodInvokeNode) en, implicitFlowTupleSet);
+ analyzeFlowMethodInvokeNode(md, nametable, (MethodInvokeNode) en, nodeSet,
+ implicitFlowTupleSet);
break;
case Kind.TertiaryNode:
set.add(min);
}
+ private void addParamNodeFlowingToReturnValue(MethodDescriptor md, FlowNode fn) {
+
+ if (!mapMethodDescToParamNodeFlowsToReturnValue.containsKey(md)) {
+ mapMethodDescToParamNodeFlowsToReturnValue.put(md, new HashSet<FlowNode>());
+ }
+ mapMethodDescToParamNodeFlowsToReturnValue.get(md).add(fn);
+ }
+
+ private Set<FlowNode> getParamNodeFlowingToReturnValue(MethodDescriptor md) {
+ return mapMethodDescToParamNodeFlowsToReturnValue.get(md);
+ }
+
private void analyzeFlowMethodInvokeNode(MethodDescriptor md, SymbolTable nametable,
- MethodInvokeNode min, NodeTupleSet implicitFlowTupleSet) {
+ MethodInvokeNode min, NodeTupleSet nodeSet, NodeTupleSet implicitFlowTupleSet) {
- addMapCallerMethodDescToMethodInvokeNodeSet(md, min);
+ if (nodeSet == null) {
+ nodeSet = new NodeTupleSet();
+ }
- MethodDescriptor calleeMD = min.getMethod();
+ MethodDescriptor calleeMethodDesc = min.getMethod();
NameDescriptor baseName = min.getBaseName();
boolean isSystemout = false;
isSystemout = baseName.getSymbol().equals("System.out");
}
- if (!ssjava.isSSJavaUtil(calleeMD.getClassDesc()) && !ssjava.isTrustMethod(calleeMD)
- && !calleeMD.getModifiers().isNative() && !isSystemout) {
+ if (!ssjava.isSSJavaUtil(calleeMethodDesc.getClassDesc())
+ && !ssjava.isTrustMethod(calleeMethodDesc) && !isSystemout) {
+
+ addMapCallerMethodDescToMethodInvokeNodeSet(md, min);
+
+ FlowGraph calleeFlowGraph = getFlowGraph(calleeMethodDesc);
+ Set<FlowNode> calleeReturnSet = calleeFlowGraph.getReturnNodeSet();
+
+ System.out.println("#calleeReturnSet=" + calleeReturnSet);
- // CompositeLocation baseLocation = null;
if (min.getExpression() != null) {
NodeTupleSet baseNodeSet = new NodeTupleSet();
analyzeFlowExpressionNode(md, nametable, min.getExpression(), baseNodeSet, null,
implicitFlowTupleSet, false);
- } else {
- if (min.getMethod().isStatic()) {
- // String globalLocId = ssjava.getMethodLattice(md).getGlobalLoc();
- // if (globalLocId == null) {
- // throw new
- // Error("Method lattice does not define global variable location at "
- // + generateErrorMessage(md.getClassDesc(), min));
- // }
- // baseLocation = new CompositeLocation(new Location(md,
- // globalLocId));
- } else {
- // 'this' var case
- // String thisLocId = ssjava.getMethodLattice(md).getThisLoc();
- // baseLocation = new CompositeLocation(new Location(md, thisLocId));
+ assert (baseNodeSet.size() == 1);
+ mapMethodInvokeNodeToBaseTuple.put(min, baseNodeSet.iterator().next());
+
+ if (!min.getMethod().isStatic()) {
+ addArgIdxMap(min, 0, baseNodeSet);
+
+ for (Iterator iterator = calleeReturnSet.iterator(); iterator.hasNext();) {
+ FlowNode returnNode = (FlowNode) iterator.next();
+ NTuple<Descriptor> returnDescTuple = returnNode.getDescTuple();
+ if (returnDescTuple.startsWith(calleeMethodDesc.getThis())) {
+ // the location type of the return value is started with 'this'
+ // reference
+ for (Iterator<NTuple<Descriptor>> baseIter = baseNodeSet.iterator(); baseIter
+ .hasNext();) {
+ NTuple<Descriptor> baseTuple = baseIter.next();
+ NTuple<Descriptor> inFlowTuple = new NTuple<Descriptor>(baseTuple.getList());
+ inFlowTuple.addAll(returnDescTuple.subList(1, returnDescTuple.size()));
+ nodeSet.addTuple(inFlowTuple);
+ }
+ } else {
+ Set<FlowNode> inFlowSet = calleeFlowGraph.getIncomingFlowNodeSet(returnNode);
+ for (Iterator iterator2 = inFlowSet.iterator(); iterator2.hasNext();) {
+ FlowNode inFlowNode = (FlowNode) iterator2.next();
+ if (inFlowNode.getDescTuple().startsWith(calleeMethodDesc.getThis())) {
+ nodeSet.addTupleSet(baseNodeSet);
+ }
+ }
+ }
+ }
}
+
}
- // constraint case:
- // if (constraint != null) {
- // int compareResult =
- // CompositeLattice.compare(constraint, baseLocation, true,
- // generateErrorMessage(cd, min));
- // if (compareResult != ComparisonResult.GREATER) {
- // // if the current constraint is higher than method's THIS location
- // // no need to check constraints!
- // CompositeLocation calleeConstraint =
- // translateCallerLocToCalleeLoc(calleeMD, baseLocation, constraint);
- // // System.out.println("check method body for constraint:" + calleeMD +
- // // " calleeConstraint="
- // // + calleeConstraint);
- // checkMethodBody(calleeMD.getClassDesc(), calleeMD, calleeConstraint);
- // }
- // }
+ // analyze parameter flows
- analyzeFlowMethodParameters(md, nametable, min);
+ if (min.numArgs() > 0) {
- // checkCalleeConstraints(md, nametable, min, baseLocation, constraint);
+ int offset;
+ if (min.getMethod().isStatic()) {
+ offset = 0;
+ } else {
+ offset = 1;
+ }
- // checkCallerArgumentLocationConstraints(md, nametable, min,
- // baseLocation, constraint);
+ for (int i = 0; i < min.numArgs(); i++) {
+ ExpressionNode en = min.getArg(i);
+ int idx = i + offset;
+ NodeTupleSet argTupleSet = new NodeTupleSet();
+ analyzeFlowExpressionNode(md, nametable, en, argTupleSet, false);
+ // if argument is liternal node, argTuple is set to NULL.
+ addArgIdxMap(min, idx, argTupleSet);
+ FlowNode paramNode = calleeFlowGraph.getParamFlowNode(idx);
+ if (hasInFlowTo(calleeFlowGraph, paramNode, calleeReturnSet)
+ || calleeMethodDesc.getModifiers().isNative()) {
+ addParamNodeFlowingToReturnValue(calleeMethodDesc, paramNode);
+ nodeSet.addTupleSet(argTupleSet);
+ }
+ }
- if (min.getMethod().getReturnType() != null && !min.getMethod().getReturnType().isVoid()) {
- // If method has a return value, compute the highest possible return
- // location in the caller's perspective
- // CompositeLocation ceilingLoc =
- // computeCeilingLocationForCaller(md, nametable, min, baseLocation,
- // constraint);
- // return ceilingLoc;
}
+
+ // propagateFlowsFromCallee(min, md, min.getMethod());
+
}
- // return new CompositeLocation(Location.createTopLocation(md));
+ }
+ private boolean hasInFlowTo(FlowGraph fg, FlowNode inNode, Set<FlowNode> nodeSet) {
+ // return true if inNode has in-flows to nodeSet
+ Set<FlowNode> reachableSet = fg.getReachFlowNodeSetFrom(inNode);
+ for (Iterator iterator = reachableSet.iterator(); iterator.hasNext();) {
+ FlowNode fn = (FlowNode) iterator.next();
+ if (nodeSet.contains(fn)) {
+ return true;
+ }
+ }
+ return false;
}
private NodeTupleSet getNodeTupleSetByArgIdx(MethodInvokeNode min, int idx) {
}
private void analyzeFlowMethodParameters(MethodDescriptor callermd, SymbolTable nametable,
- MethodInvokeNode min) {
+ MethodInvokeNode min, NodeTupleSet nodeSet) {
if (min.numArgs() > 0) {
offset = 0;
} else {
offset = 1;
- NTuple<Descriptor> thisArgTuple = new NTuple<Descriptor>();
- thisArgTuple.add(callermd.getThis());
- NodeTupleSet argTupleSet = new NodeTupleSet();
- argTupleSet.addTuple(thisArgTuple);
- addArgIdxMap(min, 0, argTupleSet);
+ // NTuple<Descriptor> thisArgTuple = new NTuple<Descriptor>();
+ // thisArgTuple.add(callermd.getThis());
+ // NodeTupleSet argTupleSet = new NodeTupleSet();
+ // argTupleSet.addTuple(thisArgTuple);
+ // addArgIdxMap(min, 0, argTupleSet);
+ // nodeSet.addTuple(thisArgTuple);
}
for (int i = 0; i < min.numArgs(); i++) {
analyzeFlowExpressionNode(callermd, nametable, en, argTupleSet, false);
// if argument is liternal node, argTuple is set to NULL.
addArgIdxMap(min, i + offset, argTupleSet);
+ nodeSet.addTupleSet(argTupleSet);
}
}
ArrayAccessNode aan, NodeTupleSet nodeSet, boolean isLHS) {
NodeTupleSet expNodeTupleSet = new NodeTupleSet();
- analyzeFlowExpressionNode(md, nametable, aan.getExpression(), expNodeTupleSet, isLHS);
+ NTuple<Descriptor> base =
+ analyzeFlowExpressionNode(md, nametable, aan.getExpression(), expNodeTupleSet, isLHS);
NodeTupleSet idxNodeTupleSet = new NodeTupleSet();
analyzeFlowExpressionNode(md, nametable, aan.getIndex(), idxNodeTupleSet, isLHS);
private NTuple<Descriptor> analyzeFlowNameNode(MethodDescriptor md, SymbolTable nametable,
NameNode nn, NodeTupleSet nodeSet, NTuple<Descriptor> base, NodeTupleSet implicitFlowTupleSet) {
+ // System.out.println("analyzeFlowNameNode=" + nn.printNode(0));
+
if (base == null) {
base = new NTuple<Descriptor>();
}
} else if (d == null) {
// access static field
base.add(GLOBALDESC);
- // base.add(nn.getField());
+ base.add(nn.getField());
return base;
// FieldDescriptor fd = nn.getField();addFlowGraphEdge
}
}
-
getFlowGraph(md).createNewFlowNode(base);
return base;
}
NodeTupleSet idxNodeTupleSet = new NodeTupleSet();
+
if (left instanceof ArrayAccessNode) {
ArrayAccessNode aan = (ArrayAccessNode) left;
left = aan.getExpression();
analyzeFlowExpressionNode(md, nametable, aan.getIndex(), idxNodeTupleSet, base,
implicitFlowTupleSet, isLHS);
+
nodeSet.addTupleSet(idxNodeTupleSet);
}
base =
getFlowGraph(md).addValueFlowEdge(idxTuple, flowFieldTuple);
}
}
-
return flowFieldTuple;
}
analyzeFlowExpressionNode(md, nametable, an.getSrc(), nodeSetRHS, null, implicitFlowTupleSet,
false);
- // System.out.println("-analyzeFlowAssignmentNode=" + an.printNode(0));
- // System.out.println("-nodeSetLHS=" + nodeSetLHS);
- // System.out.println("-nodeSetRHS=" + nodeSetRHS);
- // System.out.println("-implicitFlowTupleSet=" + implicitFlowTupleSet);
- // System.out.println("-");
+ System.out.println("-analyzeFlowAssignmentNode=" + an.printNode(0));
+ System.out.println("-nodeSetLHS=" + nodeSetLHS);
+ System.out.println("-nodeSetRHS=" + nodeSetRHS);
+ System.out.println("-implicitFlowTupleSet=" + implicitFlowTupleSet);
+ System.out.println("-");
if (an.getOperation().getOp() >= 2 && an.getOperation().getOp() <= 12) {
// if assignment contains OP+EQ operator, creates edges from LHS to LHS
+
for (Iterator<NTuple<Descriptor>> iter = nodeSetLHS.iterator(); iter.hasNext();) {
NTuple<Descriptor> fromTuple = iter.next();
for (Iterator<NTuple<Descriptor>> iter2 = nodeSetLHS.iterator(); iter2.hasNext();) {
}
// creates edges from RHS to LHS
+ NTuple<Descriptor> interTuple = null;
+ if (nodeSetRHS.size() > 1) {
+ interTuple = getFlowGraph(md).createIntermediateNode().getDescTuple();
+ }
+
for (Iterator<NTuple<Descriptor>> iter = nodeSetRHS.iterator(); iter.hasNext();) {
NTuple<Descriptor> fromTuple = iter.next();
for (Iterator<NTuple<Descriptor>> iter2 = nodeSetLHS.iterator(); iter2.hasNext();) {
NTuple<Descriptor> toTuple = iter2.next();
- addFlowGraphEdge(md, fromTuple, toTuple);
+ addFlowGraphEdge(md, fromTuple, interTuple, toTuple);
}
}
} else {
// postinc case
+
for (Iterator<NTuple<Descriptor>> iter2 = nodeSetLHS.iterator(); iter2.hasNext();) {
NTuple<Descriptor> tuple = iter2.next();
addFlowGraphEdge(md, tuple, tuple);
private boolean addFlowGraphEdge(MethodDescriptor md, NTuple<Descriptor> from,
NTuple<Descriptor> to) {
- // TODO
- // return true if it adds a new edge
FlowGraph graph = getFlowGraph(md);
graph.addValueFlowEdge(from, to);
return true;
}
+ private void addFlowGraphEdge(MethodDescriptor md, NTuple<Descriptor> from,
+ NTuple<Descriptor> inter, NTuple<Descriptor> to) {
+
+ FlowGraph graph = getFlowGraph(md);
+
+ if (inter != null) {
+ graph.addValueFlowEdge(from, inter);
+ graph.addValueFlowEdge(inter, to);
+ } else {
+ graph.addValueFlowEdge(from, to);
+ }
+
+ }
+
public void _debug_printGraph() {
Set<MethodDescriptor> keySet = mapMethodDescriptorToFlowGraph.keySet();
class CyclicFlowException extends Exception {
}
+
+class InterDescriptor extends Descriptor {
+
+ public InterDescriptor(String name) {
+ super(name);
+ }
+
+}