Exemple #1
0
 /**
  * Returns the subroutine object associated with the given instruction. This is a costly
  * operation, you should consider using getSubroutine(InstructionHandle). Returns 'null' if the
  * given InstructionHandle lies in so-called 'dead code', i.e. code that can never be executed.
  *
  * @see #getSubroutine(InstructionHandle)
  * @see #getTopLevel()
  */
 public Subroutine subroutineOf(InstructionHandle any) {
   Iterator i = subroutines.values().iterator();
   while (i.hasNext()) {
     Subroutine s = (Subroutine) i.next();
     if (s.contains(any)) return s;
   }
   System.err.println("DEBUG: Please verify '" + any + "' lies in dead code.");
   return null;
   // throw new AssertionViolatedException("No subroutine for InstructionHandle found (DEAD
   // CODE?).");
 }
Exemple #2
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  /**
   * This (recursive) utility method makes sure that no subroutine is calling a subroutine that uses
   * the same local variable for the RET as themselves (recursively). This includes that subroutines
   * may not call themselves recursively, even not through intermediate calls to other subroutines.
   *
   * @throws StructuralCodeConstraintException if the above constraint is not satisfied.
   */
  private void noRecursiveCalls(Subroutine sub, HashSet<Integer> set) {
    Subroutine[] subs = sub.subSubs();

    for (int i = 0; i < subs.length; i++) {
      int index = ((RET) (subs[i].getLeavingRET().getInstruction())).getIndex();

      if (!set.add(new Integer(index))) {
        // Don't use toString() here because of possibly infinite recursive subSubs() calls then.
        SubroutineImpl si = (SubroutineImpl) subs[i];
        throw new StructuralCodeConstraintException(
            "Subroutine with local variable '"
                + si.localVariable
                + "', JSRs '"
                + si.theJSRs
                + "', RET '"
                + si.theRET
                + "' is called by a subroutine which uses the same local variable index as itself; maybe even a recursive call? JustIce's clean definition of a subroutine forbids both.");
      }

      noRecursiveCalls(subs[i], set);

      set.remove(new Integer(index));
    }
  }
Exemple #3
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  /**
   * Constructor.
   *
   * @param il A MethodGen object representing method to create the Subroutine objects of.
   */
  public Subroutines(MethodGen mg) {

    InstructionHandle[] all = mg.getInstructionList().getInstructionHandles();
    CodeExceptionGen[] handlers = mg.getExceptionHandlers();

    // Define our "Toplevel" fake subroutine.
    TOPLEVEL = new SubroutineImpl();

    // Calculate "real" subroutines.
    HashSet<InstructionHandle> sub_leaders =
        new HashSet<InstructionHandle>(); // Elements: InstructionHandle
    for (int i = 0; i < all.length; i++) {
      Instruction inst = all[i].getInstruction();
      if (inst instanceof JsrInstruction) {
        sub_leaders.add(((JsrInstruction) inst).getTarget());
      }
    }

    // Build up the database.
    Iterator iter = sub_leaders.iterator();
    while (iter.hasNext()) {
      SubroutineImpl sr = new SubroutineImpl();
      InstructionHandle astore = (InstructionHandle) (iter.next());
      sr.setLocalVariable(((ASTORE) (astore.getInstruction())).getIndex());
      subroutines.put(astore, sr);
    }

    // Fake it a bit. We want a virtual "TopLevel" subroutine.
    subroutines.put(all[0], TOPLEVEL);
    sub_leaders.add(all[0]);

    // Tell the subroutines about their JsrInstructions.
    // Note that there cannot be a JSR targeting the top-level
    // since "Jsr 0" is disallowed in Pass 3a.
    // Instructions shared by a subroutine and the toplevel are
    // disallowed and checked below, after the BFS.
    for (int i = 0; i < all.length; i++) {
      Instruction inst = all[i].getInstruction();
      if (inst instanceof JsrInstruction) {
        InstructionHandle leader = ((JsrInstruction) inst).getTarget();
        ((SubroutineImpl) getSubroutine(leader)).addEnteringJsrInstruction(all[i]);
      }
    }

    // Now do a BFS from every subroutine leader to find all the
    // instructions that belong to a subroutine.
    HashSet<InstructionHandle> instructions_assigned =
        new HashSet<InstructionHandle>(); // we don't want to assign an instruction to two or more
    // Subroutine objects.

    Hashtable<InstructionHandle, Color> colors =
        new Hashtable<
            InstructionHandle,
            Color>(); // Graph colouring. Key: InstructionHandle, Value: java.awt.Color .

    iter = sub_leaders.iterator();
    while (iter.hasNext()) {
      // Do some BFS with "actual" as the root of the graph.
      InstructionHandle actual = (InstructionHandle) (iter.next());
      // Init colors
      for (int i = 0; i < all.length; i++) {
        colors.put(all[i], Color.white);
      }
      colors.put(actual, Color.gray);
      // Init Queue
      ArrayList<InstructionHandle> Q = new ArrayList<InstructionHandle>();
      Q.add(actual); // add(Obj) adds to the end, remove(0) removes from the start.

      /* BFS ALGORITHM MODIFICATION: Start out with multiple "root" nodes, as exception handlers are starting points of top-level code, too. [why top-level? TODO: Refer to the special JustIce notion of subroutines.]*/
      if (actual == all[0]) {
        for (int j = 0; j < handlers.length; j++) {
          colors.put(handlers[j].getHandlerPC(), Color.gray);
          Q.add(handlers[j].getHandlerPC());
        }
      }
      /* CONTINUE NORMAL BFS ALGORITHM */

      // Loop until Queue is empty
      while (Q.size() != 0) {
        InstructionHandle u = (InstructionHandle) Q.remove(0);
        InstructionHandle[] successors = getSuccessors(u);
        for (int i = 0; i < successors.length; i++) {
          if (((Color) colors.get(successors[i])) == Color.white) {
            colors.put(successors[i], Color.gray);
            Q.add(successors[i]);
          }
        }
        colors.put(u, Color.black);
      }
      // BFS ended above.
      for (int i = 0; i < all.length; i++) {
        if (colors.get(all[i]) == Color.black) {
          ((SubroutineImpl) (actual == all[0] ? getTopLevel() : getSubroutine(actual)))
              .addInstruction(all[i]);
          if (instructions_assigned.contains(all[i])) {
            throw new StructuralCodeConstraintException(
                "Instruction '"
                    + all[i]
                    + "' is part of more than one subroutine (or of the top level and a subroutine).");
          } else {
            instructions_assigned.add(all[i]);
          }
        }
      }
      if (actual != all[0]) { // If we don't deal with the top-level 'subroutine'
        ((SubroutineImpl) getSubroutine(actual)).setLeavingRET();
      }
    }

    // Now make sure no instruction of a Subroutine is protected by exception handling code
    // as is mandated by JustIces notion of subroutines.
    for (int i = 0; i < handlers.length; i++) {
      InstructionHandle _protected = handlers[i].getStartPC();
      while (_protected
          != handlers[i]
              .getEndPC()
              .getNext()) { // Note the inclusive/inclusive notation of "generic API" exception
        // handlers!
        Enumeration subs = subroutines.elements();
        while (subs.hasMoreElements()) {
          Subroutine sub = (Subroutine) subs.nextElement();
          if (sub
              != subroutines.get(all[0])) { // We don't want to forbid top-level exception handlers.
            if (sub.contains(_protected)) {
              throw new StructuralCodeConstraintException(
                  "Subroutine instruction '"
                      + _protected
                      + "' is protected by an exception handler, '"
                      + handlers[i]
                      + "'. This is forbidden by the JustIce verifier due to its clear definition of subroutines.");
            }
          }
        }
        _protected = _protected.getNext();
      }
    }

    // Now make sure no subroutine is calling a subroutine
    // that uses the same local variable for the RET as themselves
    // (recursively).
    // This includes that subroutines may not call themselves
    // recursively, even not through intermediate calls to other
    // subroutines.
    noRecursiveCalls(getTopLevel(), new HashSet<Integer>());
  }