Esempio n. 1
0
File: F2L.java Progetto: null3/jpf
  public Instruction execute(SystemState ss, KernelState ks, ThreadInfo th) {
    RealExpression sym_fval = (RealExpression) th.getTopFrame().getOperandAttr();

    if (sym_fval == null) {
      return super.execute(ss, ks, th);
    } else {

      // System.out.println("Execute symbolic F2L");

      // here we get a hold of the current path condition and
      // add an extra mixed constraint sym_dval==sym_ival

      ChoiceGenerator<?> cg;
      if (!th.isFirstStepInsn()) { // first time around
        cg = new PCChoiceGenerator(1); // only one choice
        ss.setNextChoiceGenerator(cg);
        return this;
      } else { // this is what really returns results
        cg = ss.getChoiceGenerator();
        assert (cg instanceof PCChoiceGenerator) : "expected PCChoiceGenerator, got: " + cg;
      }

      // get the path condition from the
      // previous choice generator of the same type

      PathCondition pc;
      ChoiceGenerator<?> prev_cg = cg.getPreviousChoiceGenerator();
      while (!((prev_cg == null) || (prev_cg instanceof PCChoiceGenerator))) {
        prev_cg = prev_cg.getPreviousChoiceGenerator();
      }

      if (prev_cg == null)
        pc = new PathCondition(); // TODO: handling of preconditions needs to be changed
      else pc = ((PCChoiceGenerator) prev_cg).getCurrentPC();
      assert pc != null;

      th.pop();
      th.longPush(0); // for symbolic expressions, the concrete value does not matter
      SymbolicInteger sym_lval = new SymbolicInteger();
      StackFrame sf = th.getTopFrame();
      sf.setLongOperandAttr(sym_lval);

      pc._addDet(Comparator.EQ, sym_fval, sym_lval);

      if (!pc.simplify()) { // not satisfiable
        ss.setIgnored(true);
      } else {
        // pc.solve();
        ((PCChoiceGenerator) cg).setCurrentPC(pc);
        // System.out.println(((PCChoiceGenerator) cg).getCurrentPC());
      }

      // System.out.println("Execute D2I: " + sf.getLongOperandAttr());
      return getNext(th);
    }
  }
  // the purpose of this method is to set the PCheap to the "eq null" constraint for the input
  // specified w/ stringRef
  public static int makeSymbolicNull(MJIEnv env, int objRef, int stringRef) {

    // introduce a heap choice generator for the element in the heap
    ThreadInfo ti = env.getVM().getCurrentThread();
    SystemState ss = env.getVM().getSystemState();
    ChoiceGenerator<?> cg;

    if (!ti.isFirstStepInsn()) {
      cg = new HeapChoiceGenerator(1); // new
      ss.setNextChoiceGenerator(cg);
      env.repeatInvocation();
      return -1; // not used anyways
    }
    // else this is what really returns results

    cg = ss.getChoiceGenerator();
    assert (cg instanceof HeapChoiceGenerator) : "expected HeapChoiceGenerator, got: " + cg;

    // see if there were more inputs added before
    ChoiceGenerator<?> prevHeapCG = cg.getPreviousChoiceGenerator();
    while (!((prevHeapCG == null) || (prevHeapCG instanceof HeapChoiceGenerator))) {
      prevHeapCG = prevHeapCG.getPreviousChoiceGenerator();
    }

    PathCondition pcHeap;
    SymbolicInputHeap symInputHeap;
    if (prevHeapCG == null) {

      pcHeap = new PathCondition();
      symInputHeap = new SymbolicInputHeap();
    } else {
      pcHeap = ((HeapChoiceGenerator) prevHeapCG).getCurrentPCheap();
      symInputHeap = ((HeapChoiceGenerator) prevHeapCG).getCurrentSymInputHeap();
    }

    String name = env.getStringObject(stringRef);
    String refChain =
        name + "[-1]"; // why is the type used here? should use the name of the field instead

    SymbolicInteger newSymRef = new SymbolicInteger(refChain);

    // create new HeapNode based on above info
    // update associated symbolic input heap

    pcHeap._addDet(Comparator.EQ, newSymRef, new IntegerConstant(-1));
    ((HeapChoiceGenerator) cg).setCurrentPCheap(pcHeap);
    ((HeapChoiceGenerator) cg).setCurrentSymInputHeap(symInputHeap);
    // System.out.println(">>>>>>>>>>>> initial pcHeap: " + pcHeap.toString());
    return -1;
  }
  public static PathCondition getPC(MJIEnv env) {
    JVM vm = env.getVM();
    ChoiceGenerator<?> cg = vm.getChoiceGenerator();
    PathCondition pc = null;

    if (!(cg instanceof PCChoiceGenerator)) {
      ChoiceGenerator<?> prev_cg = cg.getPreviousChoiceGenerator();
      while (!((prev_cg == null) || (prev_cg instanceof PCChoiceGenerator))) {
        prev_cg = prev_cg.getPreviousChoiceGenerator();
      }
      cg = prev_cg;
    }

    if ((cg instanceof PCChoiceGenerator) && cg != null) {
      pc = ((PCChoiceGenerator) cg).getCurrentPC();
    }
    return pc;
  }
  public static void printHeapPC(MJIEnv env, int objRef, int msgRef) {
    // should first solve the pc's!!!!

    JVM vm = env.getVM();
    ChoiceGenerator<?> cg = vm.getChoiceGenerator();
    PathCondition pc = null;

    if (!(cg instanceof HeapChoiceGenerator)) {
      ChoiceGenerator<?> prev_cg = cg.getPreviousChoiceGenerator();
      while (!((prev_cg == null) || (prev_cg instanceof HeapChoiceGenerator))) {
        prev_cg = prev_cg.getPreviousChoiceGenerator();
      }
      cg = prev_cg;
    }

    if ((cg instanceof HeapChoiceGenerator) && cg != null)
      pc = ((HeapChoiceGenerator) cg).getCurrentPCheap();

    if (pc != null) System.out.println(env.getStringObject(msgRef) + pc);
    else System.out.println(env.getStringObject(msgRef) + "HeapPC is null");
  }
Esempio n. 5
0
  @Override
  public Instruction execute(SystemState ss, KernelState ks, ThreadInfo ti) {

    StackFrame sf = ti.getTopFrame();

    IntegerExpression sym_v1 = (IntegerExpression) sf.getOperandAttr(1);
    IntegerExpression sym_v2 = (IntegerExpression) sf.getOperandAttr(0);

    if ((sym_v1 == null) && (sym_v2 == null)) { // both conditions are concrete
      // System.out.println("Execute IF_ICMPEQ: The conditions are concrete");
      return super.execute(ss, ks, ti);
    } else { // at least one condition is symbolic
      ChoiceGenerator<?> cg;

      if (!ti.isFirstStepInsn()) { // first time around
        cg = new PCChoiceGenerator(2);
        ss.setNextChoiceGenerator(cg);
        return this;
      } else { // this is what really returns results
        cg = ss.getChoiceGenerator();
        assert (cg instanceof PCChoiceGenerator) : "expected PCChoiceGenerator, got: " + cg;
        conditionValue = (Integer) cg.getNextChoice() == 0 ? false : true;
      }

      int v2 = ti.pop();
      int v1 = ti.pop();
      // System.out.println("Execute IF_ICMPEQ: "+ conditionValue);
      PathCondition pc;

      // pc is updated with the pc stored in the choice generator above
      // get the path condition from the
      // previous choice generator of the same type

      ChoiceGenerator<?> prev_cg = cg.getPreviousChoiceGenerator();
      while (!((prev_cg == null) || (prev_cg instanceof PCChoiceGenerator))) {
        prev_cg = prev_cg.getPreviousChoiceGenerator();
      }

      if (prev_cg == null) pc = new PathCondition();
      else pc = ((PCChoiceGenerator) prev_cg).getCurrentPC();

      assert pc != null;

      if (conditionValue) {
        if (sym_v1 != null) {
          if (sym_v2 != null) { // both are symbolic values
            pc._addDet(Comparator.EQ, sym_v1, sym_v2);
          } else pc._addDet(Comparator.EQ, sym_v1, v2);
        } else pc._addDet(Comparator.EQ, v1, sym_v2);
        if (!pc.simplify()) { // not satisfiable
          ss.setIgnored(true);
        } else {
          // pc.solve();
          ((PCChoiceGenerator) cg).setCurrentPC(pc);
          //	System.out.println(((PCChoiceGenerator) cg).getCurrentPC());
        }
        return getTarget();
      } else {
        if (sym_v1 != null) {
          if (sym_v2 != null) { // both are symbolic values
            pc._addDet(Comparator.NE, sym_v1, sym_v2);
          } else pc._addDet(Comparator.NE, sym_v1, v2);
        } else pc._addDet(Comparator.NE, v1, sym_v2);
        if (!pc.simplify()) { // not satisfiable
          ss.setIgnored(true);
        } else {
          // pc.solve();
          ((PCChoiceGenerator) cg).setCurrentPC(pc);
          // System.out.println(((PCChoiceGenerator) cg).getCurrentPC());
        }
        return getNext(ti);
      }
    }
  }
  public static void makeFieldsSymbolic(MJIEnv env, int objRef, int stringRef, int objvRef) {
    // makes all the fields of obj v symbolic and adds obj v to the symbolic heap to kick off lazy
    // initialization
    if (objvRef == -1) throw new RuntimeException("## Error: null object");
    // introduce a heap choice generator for the element in the heap
    ThreadInfo ti = env.getVM().getCurrentThread();
    SystemState ss = env.getVM().getSystemState();
    ChoiceGenerator<?> cg;

    if (!ti.isFirstStepInsn()) {
      cg = new HeapChoiceGenerator(1); // new
      ss.setNextChoiceGenerator(cg);
      env.repeatInvocation();
      return; // not used anyways
    }
    // else this is what really returns results

    cg = ss.getChoiceGenerator();
    assert (cg instanceof HeapChoiceGenerator) : "expected HeapChoiceGenerator, got: " + cg;

    // see if there were more inputs added before
    ChoiceGenerator<?> prevHeapCG = cg.getPreviousChoiceGenerator();
    while (!((prevHeapCG == null) || (prevHeapCG instanceof HeapChoiceGenerator))) {
      prevHeapCG = prevHeapCG.getPreviousChoiceGenerator();
    }

    PathCondition pcHeap;
    SymbolicInputHeap symInputHeap;
    if (prevHeapCG == null) {

      pcHeap = new PathCondition();
      symInputHeap = new SymbolicInputHeap();
    } else {
      pcHeap = ((HeapChoiceGenerator) prevHeapCG).getCurrentPCheap();
      symInputHeap = ((HeapChoiceGenerator) prevHeapCG).getCurrentSymInputHeap();
    }

    // set all the fields to be symbolic
    ClassInfo ci = env.getClassInfo(objvRef);
    FieldInfo[] fields = ci.getDeclaredInstanceFields();
    FieldInfo[] staticFields = ci.getDeclaredStaticFields();

    String name = env.getStringObject(stringRef);
    String refChain =
        name + "[" + objvRef
            + "]"; // why is the type used here? should use the name of the field instead

    SymbolicInteger newSymRef = new SymbolicInteger(refChain);
    // ElementInfo eiRef = DynamicArea.getHeap().get(objvRef);
    ElementInfo eiRef = JVM.getVM().getHeap().get(objvRef);
    Helper.initializeInstanceFields(fields, eiRef, refChain);
    Helper.initializeStaticFields(staticFields, ci, ti);

    // create new HeapNode based on above info
    // update associated symbolic input heap

    ClassInfo typeClassInfo = eiRef.getClassInfo();

    HeapNode n = new HeapNode(objvRef, typeClassInfo, newSymRef);
    symInputHeap._add(n);
    pcHeap._addDet(Comparator.NE, newSymRef, new IntegerConstant(-1));
    ((HeapChoiceGenerator) cg).setCurrentPCheap(pcHeap);
    ((HeapChoiceGenerator) cg).setCurrentSymInputHeap(symInputHeap);
    // System.out.println(">>>>>>>>>>>> initial pcHeap: " + pcHeap.toString());
    return;
  }