示例#1
0
    /**
     * Returns a <code>ThrowableSet</code> representing the set of exceptions included in <code>
     * include</code> minus the set of exceptions included in <code>exclude</code>. Creates a new
     * <code>ThrowableSet</code> only if there was not already one whose contents correspond to
     * <code>include</code> - <code>exclude</code>.
     *
     * @param include A set of {@link RefLikeType} objects representing exception types included in
     *     the result; may be <code>null</code> if there are no included types.
     * @param exclude A set of {@link AnySubType} objects representing exception types excluded from
     *     the result; may be <code>null</code> if there are no excluded types.
     * @return a <code>ThrowableSet</code> representing the set of exceptions corresponding to
     *     <code>include</code> - <code>exclude</code>.
     */
    private ThrowableSet registerSetIfNew(Set include, Set exclude) {
      if (INSTRUMENTING) {
        registrationCalls++;
      }
      if (include == null) {
        include = Collections.EMPTY_SET;
      }
      if (exclude == null) {
        exclude = Collections.EMPTY_SET;
      }
      int size = include.size() + exclude.size();
      Integer sizeKey = new Integer(size);

      List sizeList = (List) sizeToSets.get(sizeKey);
      if (sizeList == null) {
        sizeList = new LinkedList();
        sizeToSets.put(sizeKey, sizeList);
      }
      for (Iterator i = sizeList.iterator(); i.hasNext(); ) {
        ThrowableSet set = (ThrowableSet) i.next();
        if (set.exceptionsIncluded.equals(include) && set.exceptionsExcluded.equals(exclude)) {
          return set;
        }
      }
      if (INSTRUMENTING) {
        registeredSets++;
      }
      ThrowableSet result = new ThrowableSet(include, exclude);
      sizeList.add(result);
      return result;
    }
示例#2
0
  /**
   * Indicates whether this ThrowableSet includes some exception that might be caught by a handler
   * argument of the type <code>catcher</code>.
   *
   * @param catcher type of the handler parameter to be tested.
   * @return <code>true</code> if this set contains an exception type that might be caught by <code>
   *     catcher</code>, false if it does not.
   */
  public boolean catchableAs(RefType catcher) {
    if (INSTRUMENTING) {
      Manager.v().catchableAsQueries++;
    }

    FastHierarchy h = Scene.v().getOrMakeFastHierarchy();

    if (exceptionsExcluded.size() > 0) {
      if (INSTRUMENTING) {
        Manager.v().catchableAsFromSearch++;
      }
      for (Iterator i = exceptionsExcluded.iterator(); i.hasNext(); ) {
        AnySubType exclusion = (AnySubType) i.next();
        if (h.canStoreType(catcher, exclusion.getBase())) {
          return false;
        }
      }
    }

    if (exceptionsIncluded.contains(catcher)) {
      if (INSTRUMENTING) {
        if (exceptionsExcluded.size() == 0) {
          Manager.v().catchableAsFromMap++;
        } else {
          Manager.v().catchableAsFromSearch++;
        }
      }
      return true;
    } else {
      if (INSTRUMENTING) {
        if (exceptionsExcluded.size() == 0) {
          Manager.v().catchableAsFromSearch++;
        }
      }
      for (Iterator i = exceptionsIncluded.iterator(); i.hasNext(); ) {
        RefLikeType thrownType = (RefLikeType) i.next();
        if (thrownType instanceof RefType) {
          if (thrownType == catcher) {
            // assertion failure.
            throw new IllegalStateException(
                "ThrowableSet.catchableAs(RefType): exceptions.contains() failed to match contained RefType "
                    + catcher);
          } else if (h.canStoreType(thrownType, catcher)) {
            return true;
          }
        } else {
          RefType thrownBase = ((AnySubType) thrownType).getBase();
          // At runtime, thrownType might be instantiated by any
          // of thrownBase's subtypes, so:
          if (h.canStoreType(thrownBase, catcher) || h.canStoreType(catcher, thrownBase)) {
            return true;
          }
        }
      }
      return false;
    }
  }
示例#3
0
 /**
  * Returns a <code>ThrowableSet</code> which contains all the exceptions in <code>s</code> in
  * addition to those in this <code>ThrowableSet</code>.
  *
  * @param s set of exceptions to add to this set.
  * @return the union of this set with <code>s</code>
  * @throws ThrowableSet.AlreadyHasExclusionsException if this <code>ThrowableSet</code> or <code>s
  *     </code> is the result of a {@link #whichCatchableAs(RefType)} operation, so that it is not
  *     possible to represent the addition of <code>s</code> to this <code>ThrowableSet</code>.
  */
 public ThrowableSet add(ThrowableSet s) throws ThrowableSet.AlreadyHasExclusionsException {
   if (INSTRUMENTING) {
     Manager.v().addsOfSet++;
   }
   if (exceptionsExcluded.size() > 0 || s.exceptionsExcluded.size() > 0) {
     throw new AlreadyHasExclusionsException(
         "ThrowableSet.Add(ThrowableSet): attempt to add to ["
             + this.toString()
             + "] after removals recorded.");
   }
   ThrowableSet result = getMemoizedAdds(s);
   if (result == null) {
     if (INSTRUMENTING) {
       Manager.v().addsInclusionFromSearch++;
       Manager.v().addsExclusionWithoutSearch++;
     }
     result = this.add(s.exceptionsIncluded);
     memoizedAdds.put(s, result);
   } else if (INSTRUMENTING) {
     Manager.v().addsInclusionFromMemo++;
     Manager.v().addsExclusionWithoutSearch++;
   }
   return result;
 }
示例#4
0
  /**
   * Returns a <code>ThrowableSet</code> which contains <code>e</code> and all of its subclasses as
   * well as the exceptions in this set.
   *
   * <p><code>e</code> should be an instance of {@link AnySubType} if you know that the compile-time
   * type of the exception you are representing is <code>e</code>, but the exception may be
   * instantiated at run-time by a subclass of <code>e</code>.
   *
   * <p>For example, if you were recording the type of the exception thrown by
   *
   * <pre>
   * catch (IOException e) {
   *    throw e;
   * }
   * </pre>
   *
   * you would call
   *
   * <pre>
   * <code>add(AnySubtype.v(Scene.v().getRefType("java.lang.Exception.IOException")))</code>
   * </pre>
   *
   * since the handler might rethrow any subclass of <code>IOException</code>.
   *
   * @param e represents a subtree of the exception class hierarchy to add to this set.
   * @return a set containing <code>e</code> and all its subclasses, as well as the exceptions
   *     represented by this set.
   * @throws ThrowableSet.AlreadyHasExclusionsException if this <code>ThrowableSet</code> is the
   *     result of a {@link #whichCatchableAs(RefType)} operation and, thus, unable to represent the
   *     addition of <code>e</code>.
   */
  public ThrowableSet add(AnySubType e) throws ThrowableSet.AlreadyHasExclusionsException {
    if (INSTRUMENTING) {
      Manager.v().addsOfAnySubType++;
    }

    ThrowableSet result = getMemoizedAdds(e);
    if (result != null) {
      if (INSTRUMENTING) {
        Manager.v().addsInclusionFromMemo++;
        Manager.v().addsExclusionWithoutSearch++;
      }
      return result;
    } else {
      FastHierarchy hierarchy = Scene.v().getOrMakeFastHierarchy();
      RefType newBase = e.getBase();

      if (INSTRUMENTING) {
        if (exceptionsExcluded.size() != 0) {
          Manager.v().addsExclusionWithSearch++;
        } else {
          Manager.v().addsExclusionWithoutSearch++;
        }
      }
      for (Iterator i = exceptionsExcluded.iterator(); i.hasNext(); ) {
        RefType exclusionBase = ((AnySubType) i.next()).getBase();
        if (hierarchy.canStoreType(newBase, exclusionBase)
            || hierarchy.canStoreType(exclusionBase, newBase)) {
          if (INSTRUMENTING) {
            // To ensure that the subcategories total properly:
            Manager.v().addsInclusionInterrupted++;
          }
          throw new AlreadyHasExclusionsException(
              "ThrowableSet.add("
                  + e.toString()
                  + ") to the set [ "
                  + this.toString()
                  + "] where "
                  + exclusionBase.toString()
                  + " is excluded.");
        }
      }

      if (this.exceptionsIncluded.contains(e)) {
        if (INSTRUMENTING) {
          Manager.v().addsInclusionFromMap++;
        }
        return this;

      } else {
        if (INSTRUMENTING) {
          Manager.v().addsInclusionFromSearch++;
        }

        int changes = 0;
        boolean addNewException = true;
        Set resultSet = new HashSet();

        for (Iterator i = this.exceptionsIncluded.iterator(); i.hasNext(); ) {
          RefLikeType incumbent = (RefLikeType) i.next();
          if (incumbent instanceof RefType) {
            if (hierarchy.canStoreType(incumbent, newBase)) {
              // Omit incumbent from result.
              changes++;
            } else {
              resultSet.add(incumbent);
            }
          } else if (incumbent instanceof AnySubType) {
            RefType incumbentBase = ((AnySubType) incumbent).getBase();
            // We have to use the base types in these hierarchy calls
            // because we want to know if _all_ possible
            // types represented by e can be represented by
            // the incumbent, or vice versa.
            if (hierarchy.canStoreType(newBase, incumbentBase)) {
              addNewException = false;
              resultSet.add(incumbent);
            } else if (hierarchy.canStoreType(incumbentBase, newBase)) {
              // Omit incumbent from result;
              changes++;
            } else {
              resultSet.add(incumbent);
            }
          } else { // assertion failure.
            throw new IllegalStateException(
                "ThrowableSet.add(AnySubType): Set element "
                    + incumbent.toString()
                    + " is neither a RefType nor an AnySubType.");
          }
        }
        if (addNewException) {
          resultSet.add(e);
          changes++;
        }
        if (changes > 0) {
          result = Manager.v().registerSetIfNew(resultSet, this.exceptionsExcluded);
        } else {
          result = this;
        }
        memoizedAdds.put(e, result);
        return result;
      }
    }
  }
示例#5
0
  /**
   * Returns a <code>ThrowableSet</code> which contains <code>e</code> in addition to the exceptions
   * in this <code>ThrowableSet</code>.
   *
   * <p>Add <code>e</code> as a {@link RefType} when you know that the run-time class of the
   * exception you are representing is necessarily <code>e</code> and cannot be a subclass of <code>
   * e</code>.
   *
   * <p>For example, if you were recording the type of the exception thrown by
   *
   * <pre>
   * throw new IOException("Permission denied");
   * </pre>
   *
   * you would call
   *
   * <pre>
   * <code>add(Scene.v().getRefType("java.lang.Exception.IOException"))</code>
   * </pre>
   *
   * since the class of the exception is necessarily <code>IOException</code>.
   *
   * @param e the exception class
   * @return a set containing <code>e</code> as well as the exceptions in this set.
   * @throws {@link ThrowableSet.IllegalStateException} if this <code>ThrowableSet</code> is the
   *     result of a {@link #whichCatchableAs(RefType)} operation and, thus, unable to represent the
   *     addition of <code>e</code>.
   */
  public ThrowableSet add(RefType e) throws ThrowableSet.AlreadyHasExclusionsException {
    if (INSTRUMENTING) {
      Manager.v().addsOfRefType++;
    }
    if (this.exceptionsIncluded.contains(e)) {
      if (INSTRUMENTING) {
        Manager.v().addsInclusionFromMap++;
        Manager.v().addsExclusionWithoutSearch++;
      }
      return this;
    } else {
      ThrowableSet result = getMemoizedAdds(e);
      if (result != null) {
        if (INSTRUMENTING) {
          Manager.v().addsInclusionFromMemo++;
          Manager.v().addsExclusionWithoutSearch++;
        }
        return result;
      } else {
        if (INSTRUMENTING) {
          Manager.v().addsInclusionFromSearch++;
          if (exceptionsExcluded.size() != 0) {
            Manager.v().addsExclusionWithSearch++;
          } else {
            Manager.v().addsExclusionWithoutSearch++;
          }
        }
        FastHierarchy hierarchy = Scene.v().getOrMakeFastHierarchy();

        for (Iterator i = exceptionsExcluded.iterator(); i.hasNext(); ) {
          RefType exclusionBase = ((AnySubType) i.next()).getBase();
          if (hierarchy.canStoreType(e, exclusionBase)) {
            throw new AlreadyHasExclusionsException(
                "ThrowableSet.add(RefType): adding"
                    + e.toString()
                    + " to the set [ "
                    + this.toString()
                    + "] where "
                    + exclusionBase.toString()
                    + " is excluded.");
          }
        }

        for (Iterator i = exceptionsIncluded.iterator(); i.hasNext(); ) {
          RefLikeType incumbent = (RefLikeType) i.next();
          if (incumbent instanceof AnySubType) {
            // Need to use incumbent.getBase() because
            // hierarchy.canStoreType() assumes that parent
            // is not an AnySubType.
            RefType incumbentBase = ((AnySubType) incumbent).getBase();
            if (hierarchy.canStoreType(e, incumbentBase)) {
              memoizedAdds.put(e, this);
              return this;
            }
          } else if (!(incumbent instanceof RefType)) {
            // assertion failure.
            throw new IllegalStateException(
                "ThrowableSet.add(RefType): Set element "
                    + incumbent.toString()
                    + " is neither a RefType nor an AnySubType.");
          }
        }
        Set resultSet = new HashSet(this.exceptionsIncluded);
        resultSet.add(e);
        result = Manager.v().registerSetIfNew(resultSet, this.exceptionsExcluded);
        memoizedAdds.put(e, result);
        return result;
      }
    }
  }
示例#6
0
  // This method adds the monitorenter/exit statements into whichever pegChain contains the
  // corresponding node statement
  protected void addMonitorStmt() {
    // System.out.println("====entering addMonitorStmt");
    if (synch.size() > 0) {
      // System.out.println("synch: "+synch);
      Iterator<List> it = synch.iterator();
      while (it.hasNext()) {
        List list = it.next();

        JPegStmt node = (JPegStmt) list.get(0);
        JPegStmt enter = (JPegStmt) list.get(1);
        JPegStmt exit = (JPegStmt) list.get(2);
        //		System.out.println("monitor node: "+node);
        // System.out.println("monitor enter: "+enter);
        // System.out.println("monitor exit: "+exit);
        // add for test
        // System.out.println("allNodes contains node: "+allNodes.contains(node));
        // end add for test

        {
          if (!mainPegChain.contains(node)) {

            boolean find = false;
            // System.out.println("main chain does not contain node");
            Set maps = startToThread.entrySet();
            // System.out.println("size of startToThread: "+startToThread.size());
            for (Iterator iter = maps.iterator(); iter.hasNext(); ) {
              Map.Entry entry = (Map.Entry) iter.next();
              Object startNode = entry.getKey();
              Iterator runIt = ((List) entry.getValue()).iterator();
              while (runIt.hasNext()) {
                Chain chain = (Chain) runIt.next();
                //	testPegChain(chain);
                if (chain.contains(node)) {
                  find = true;
                  // System.out.println("---find it---");
                  chain.add(enter);
                  chain.add(exit);
                  break;
                }
              }
            }
            if (find == false) {
              System.err.println("fail to find stmt: " + node + " in chains!");
              System.exit(1);
            }

            // this.toString();
          } else {
            mainPegChain.add(enter);
            mainPegChain.add(exit);
          }
        }

        allNodes.add(enter);
        allNodes.add(exit);

        insertBefore(node, enter);
        insertAfter(node, exit);
      }
    }
    // add for test
    /*
    {
    // System.out.println("===main peg chain===");
     //testPegChain(mainPegChain);
      //System.out.println("===end main peg chain===");
       Set maps = startToThread.entrySet();
       for(Iterator iter=maps.iterator(); iter.hasNext();){
       Map.Entry entry = (Map.Entry)iter.next();
       Object startNode = entry.getKey();
       Iterator runIt  = ((List)entry.getValue()).iterator();
       while (runIt.hasNext()){
       Chain chain=(Chain)runIt.next();
       testPegChain(chain);
       }
       }
       }
       */
    //	System.out.println(this.toString());
    // end add for test
  }
示例#7
0
  /**
   * @param annotations
   * @return
   */
  private List<Tag> handleAnnotation(
      Set<? extends org.jf.dexlib2.iface.Annotation> annotations, String classType) {
    if (annotations == null || annotations.size() == 0) return null;

    List<Tag> tags = new ArrayList<Tag>();
    VisibilityAnnotationTag[] vatg =
        new VisibilityAnnotationTag[3]; // RUNTIME_VISIBLE, RUNTIME_INVISIBLE, SOURCE_VISIBLE, see
    // soot.tagkit.AnnotationConstants

    for (Annotation a : annotations) {
      int v = getVisibility(a.getVisibility());

      Tag t = null;
      Type atype = DexType.toSoot(a.getType());
      String atypes = atype.toString();
      int eSize = a.getElements().size();
      Debug.printDbg("annotation type: ", atypes, " elements: ", eSize);

      if (atypes.equals("dalvik.annotation.AnnotationDefault")) {
        if (eSize != 1)
          throw new RuntimeException(
              "error: expected 1 element for annotation Default. Got " + eSize + " instead.");
        // get element
        AnnotationElem e = getElements(a.getElements()).get(0);
        AnnotationTag adt = new AnnotationTag(a.getType());
        adt.addElem(e);
        if (vatg[v] == null) vatg[v] = new VisibilityAnnotationTag(v);
        vatg[v].addAnnotation(adt);

      } else if (atypes.equals("dalvik.annotation.EnclosingClass")) {
        if (eSize != 1)
          throw new RuntimeException(
              "error: expected 1 element for annotation EnclosingClass. Got "
                  + eSize
                  + " instead.");

        for (AnnotationElement elem : a.getElements()) {
          String outerClass = ((TypeEncodedValue) elem.getValue()).getValue();
          outerClass = Util.dottedClassName(outerClass);
          deps.typesToSignature.add(RefType.v(outerClass));
          clazz.setOuterClass(SootResolver.v().makeClassRef(outerClass));
          assert clazz.getOuterClass() != clazz;
        }

        // EnclosingClass comes in pair with InnerClass.
        // Those are generated from a single InnerClassTag,
        // that is re-constructed only for the InnerClass Dalvik
        // annotation.
        continue;

      } else if (atypes.equals("dalvik.annotation.EnclosingMethod")) {
        if (eSize != 1)
          throw new RuntimeException(
              "error: expected 1 element for annotation EnclosingMethod. Got "
                  + eSize
                  + " instead.");
        AnnotationStringElem e = (AnnotationStringElem) getElements(a.getElements()).get(0);
        String[] split1 = e.getValue().split("\\ \\|");
        String classString = split1[0];
        String methodString = split1[1];
        String parameters = split1[2];
        String returnType = split1[3];
        String methodSigString = "(" + parameters + ")" + returnType;
        t = new EnclosingMethodTag(classString, methodString, methodSigString);

        String outerClass = classString.replace("/", ".");
        deps.typesToSignature.add(RefType.v(outerClass));
        clazz.setOuterClass(SootResolver.v().makeClassRef(outerClass));
        assert clazz.getOuterClass() != clazz;

      } else if (atypes.equals("dalvik.annotation.InnerClass")) {
        int accessFlags = -1; // access flags of the inner class
        String name = null; // name of the inner class

        for (AnnotationElem ele : getElements(a.getElements())) {
          if (ele instanceof AnnotationIntElem && ele.getName().equals("accessFlags"))
            accessFlags = ((AnnotationIntElem) ele).getValue();
          else if (ele instanceof AnnotationStringElem && ele.getName().equals("name"))
            name = ((AnnotationStringElem) ele).getValue();
          else throw new RuntimeException("Unexpected inner class annotation element");
        }

        String outerClass; // outer class name
        if (name == null) outerClass = classType.replaceAll("\\$[0-9,a-z,A-Z]*;$", ";");
        else outerClass = classType.replaceFirst("\\$" + name + ";$", ";");

        // Make sure that no funny business is going on if the
        // annotation is broken and does not end in $nn.
        if (outerClass.equals(classType)) {
          outerClass = null;
        }

        Tag innerTag =
            new InnerClassTag(
                DexType.toSootICAT(classType),
                outerClass == null ? null : DexType.toSootICAT(outerClass),
                name,
                accessFlags);
        tags.add(innerTag);

        if (outerClass != null && !clazz.hasOuterClass()) {
          String sootOuterClass = Util.dottedClassName(outerClass);
          deps.typesToSignature.add(RefType.v(sootOuterClass));
          clazz.setOuterClass(SootResolver.v().makeClassRef(sootOuterClass));
          assert clazz.getOuterClass() != clazz;
        }

        continue;

      } else if (atypes.equals("dalvik.annotation.MemberClasses")) {
        AnnotationArrayElem e = (AnnotationArrayElem) getElements(a.getElements()).get(0);
        for (AnnotationElem ae : e.getValues()) {
          AnnotationClassElem c = (AnnotationClassElem) ae;
          String innerClass = c.getDesc();
          String outerClass = innerClass.replaceAll("\\$[^\\$]*$", "");
          String name = innerClass.replaceAll("^.*\\$", "").replaceAll(";$", "");
          if (name.replaceAll("[0-9].*", "").equals("")) { // anonymous or local inner classes
            name = null;
          }
          int accessFlags =
              0; // seems like this information is lost during the .class -- dx --> .dex process.
          Tag innerTag =
              new InnerClassTag(
                  DexType.toSootICAT(innerClass),
                  DexType.toSootICAT(outerClass),
                  name,
                  accessFlags);
          tags.add(innerTag);
        }
        continue;

      } else if (atypes.equals("dalvik.annotation.Signature")) {
        if (eSize != 1)
          throw new RuntimeException(
              "error: expected 1 element for annotation Signature. Got " + eSize + " instead.");
        AnnotationArrayElem e = (AnnotationArrayElem) getElements(a.getElements()).get(0);
        String sig = "";
        for (AnnotationElem ae : e.getValues()) {
          AnnotationStringElem s = (AnnotationStringElem) ae;
          sig += s.getValue();
        }
        t = new SignatureTag(sig);

      } else if (atypes.equals("dalvik.annotation.Throws")) {
        // this is handled in soot.dexpler.DexMethod
        continue;

      } else if (atypes.equals("java.lang.Deprecated")) {
        if (eSize != 0)
          throw new RuntimeException(
              "error: expected 1 element for annotation Deprecated. Got " + eSize + " instead.");

        t = new DeprecatedTag();

        AnnotationTag adt = new AnnotationTag("Ljava/lang/Deprecated;");
        if (vatg[v] == null) vatg[v] = new VisibilityAnnotationTag(v);
        vatg[v].addAnnotation(adt);

      } else {
        Debug.printDbg("read visibility tag: ", a.getType());

        if (vatg[v] == null) vatg[v] = new VisibilityAnnotationTag(v);

        AnnotationTag tag = new AnnotationTag(a.getType());
        for (AnnotationElem e : getElements(a.getElements())) tag.addElem(e);
        vatg[v].addAnnotation(tag);
      }

      tags.add(t);
    }

    for (VisibilityAnnotationTag vat : vatg) if (vat != null) tags.add(vat);

    return tags;
  }