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Objects that serve as keys in ordered sets and maps should be immutable. When some fields must be mutable, the equals(), hashCode() and compareTo() methods must consider only immutable state when comparing objects. Violations of this rule can produce inconsistent orderings in collections. The documentation of java.util.Interface Set<E> and java.util.Interface Map<K,V> warns against this. For example, the documentation for the Interface Map states [[API 2006]]:

Note: great care must be exercised [when] mutable objects are used as map keys. The behavior of a map is not specified if the value of an object is changed in a manner that affects equals comparisons while the object is a key in the map. A special case of this prohibition is that it is not permissible for a map to contain itself as a key. While it is permissible for a map to contain itself as a value, extreme caution is advised: the equals and hashCode methods are no longer well defined on such a map.

Noncompliant Code Example

This noncompliant code example defines a mutable class Employee that consists of the fields name and salary, whose values can be changed using the respective setters. The equals() method is overridden to provide a comparison facility by employee name.

// Mutable class Employee
class Employee {
  private String name;
  private double salary;
 
  Employee(String empName, double empSalary) {
    this.name = empName;
    this.salary = empSalary;
  }
  
  public void setEmployeeName(String empName) {
    this.name = empName;   
  }

  // ... including a hashCode implementation

  @Override public boolean equals(Object o) {
    if (!(o instanceof Employee)) {
      return false;
    }
      
    Employee emp = (Employee)o;
    return emp.name.equals(name);
  } 
}

// Client code
Map<Employee, Calendar> map = new ConcurrentHashMap<Employee, Calendar>();
// ...

Use of the Employee object as a key to the map is insecure because the properties of the object may change after an ordering has been established. For example, a client may modify the name field when the last name of an employee changes. As a result, clients may observe non-deterministic behavior.

Compliant Solution

This compliant solution adds a final field employeeID that is immutable after initialization. The equals() method compares Employee objects on the basis of this field.

// Mutable class Employee
class Employee {
  private String name;
  private double salary;
  private final long employeeID;  // Unique for each Employee

  Employee(String name, double salary, long empID) {
    this.name = name;
    this.salary = salary;
    this.employeeID = empID;
  }
 
  // ... including a hashCode implementation

  @Override public boolean equals(Object o) {
    if (!(o instanceof Employee)) {
      return false;
    }
      
    Employee emp = (Employee)o;
    return emp.employeeID == employeeID;
  } 
}

// Client code remains same
Map<Employee, Calendar> map = new ConcurrentHashMap<Employee, Calendar>();
// ... 

The Employee class can now be safely used as a key for the map in the client code.

Noncompliant Code Example

Many programmers are surprised by an instance of hash code mutability that arises because of serialization. The contract for the hashCode() method lacks any requirement that hash codes remain consistent across different executions of an application. Similarly, when an object is serialized and subsequently deserialized, its hashcode after deserialization may be inconsistent with its original hashcode.

This noncompliant code example uses the Key class as the key index for the Hashtable. The Key class may or may not override Object.equals() but it distinctly does not override Object.hashCode(). According to the Java API [[API 2006]] class Hashtable documentation

To successfully store and retrieve objects from a hash table, the objects used as keys must implement the hashCode method and the equals method.

This noncompliant code example follows the above advice, but can nevertheless fail after serialization and deserialization. Consequently, it may be impossible to retrieve the value of the object after deserialization by using the original key.

class Key implements Serializable {
  // Does not override hashCode()
}

class HashSer {
  public static void main(String[] args) throws IOException, ClassNotFoundException {
    Hashtable<Key,String> ht = new Hashtable<Key, String>();
    Key key = new Key();
    ht.put(key, "Value");
    System.out.println("Entry: " + ht.get(key)); // Retrieve using the key, works
	 
    // Serialize the Hashtable object
    FileOutputStream fos = new FileOutputStream("hashdata.ser");
    ObjectOutputStream oos = new ObjectOutputStream(fos);
    oos.writeObject(ht);
    oos.close();
	 
    // Deserialize the Hashtable object
    FileInputStream fis = new FileInputStream("hashdata.ser");
    ObjectInputStream ois = new ObjectInputStream(fis);
    Hashtable<Key, String> ht_in = (Hashtable<Key, String>)(ois.readObject());
    ois.close();
	 
    if (ht_in.contains("Value")) // Check whether the object actually exists in the hash table
      System.out.println("Value was found in deserialized object.");
	 
    if (ht_in.get(key) == null) // Gets printed
      System.out.println("Object was not found when retrieved using the key.");	 
  }
}

Compliant Solution

This compliant solution changes the type of the key value to be an Integer object. Consequently, key values remain consistent across multiple runs of the program, across serialization and deserialization, and also across multiple JVMs.

class HashSer {
  public static void main(String[] args) throws IOException, ClassNotFoundException {
    Hashtable<Integer, String> ht = new Hashtable<Integer, String>();
    ht.put(new Integer(1), "Value");
    System.out.println("Entry: " + ht.get(1)); // Retrieve using the key
	 
    // Serialize the Hashtable object
    FileOutputStream fos = new FileOutputStream("hashdata.ser");
    ObjectOutputStream oos = new ObjectOutputStream(fos);
    oos.writeObject(ht);
    oos.close();
	 
    // Deserialize the Hashtable object
    FileInputStream fis = new FileInputStream("hashdata.ser");
    ObjectInputStream ois = new ObjectInputStream(fis);
    Hashtable<Integer, String> ht_in = (Hashtable<Integer, String>)(ois.readObject());
    ois.close();
	 
    if (ht_in.contains("Value")) // Check whether the object actually exists in the Hashtable
      System.out.println("Value was found in deserialized object.");
	 
    if (ht_in.get(1) == null)  // Not printed
      System.out.println("Object was not found when retrieved using the key.");	 
  }
}

This problem can also be avoided by overriding the the hashcode() method in the Key class, though it is best to avoid serializing hash tables that are known to use implementation defined parameters.

Risk Assessment

Failure to ensure that the keys used in a comparison operation are immutable can lead to non-deterministic behavior.

Recommendation

Severity

Likelihood

Remediation Cost

Priority

Level

MET19-J

low

probable

high

P2

L3

Automated Detection

The Coverity Prevent Version 5.0 MUTABLE_COMPARISON checker can detect the instances where compareTo method is reading from a non constant field. If the non-constant field is modified, the value of compareTo might change, which may break program invariants.

Related Vulnerabilities

Search for vulnerabilities resulting from the violation of this rule on the CERT website.

Bibliography

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[[API 2006

AA. Bibliography#API 06]]

java.util.Interface Set<E> and java.util.Interface Map<K,V>

]]></ac:plain-text-body></ac:structured-macro>


      05. Methods (MET)      06. Exceptional Behavior (ERR)

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