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Programming errors can prevent garbage collection of objects that are no longer relevant to program operation. The garbage collector collects only unreachable objects; consequently, the presence of reachable objects that remain unused indicates memory mismanagement. Consumption of all available heap space can cause an OutOfMemoryError, which usually results in program failure. Memory leaks afford adversaries with a potentially exploitable denial of service attack, and consequently are forbidden.

Excessive memory leaks can lead to memory exhaustion and denial of service. For more information, see [MSC11-J. Do not assume infinite heap space].

Noncompliant Code Example (Off-By-One Programming Error)

This noncompliant code example shows a leaking Vector object. The condition for removing the vector element is mistakenly written as n > 0 instead of n >= 0. Consequently, the method grows the vector by one element per invocation, and quickly exhausts the available heap space.

public class Leak {
  static Vector vector = new Vector();

  public void useVector(int count) { 	
    for (int n = 0; n < count; n++) {
      vector.add(Integer.toString(n));
    }
    // ...
    for (int n = count - 1; n > 0; n--) { // Free the memory
      vector.removeElementAt(n);
    }	
  }

  public static void main(String[] args) throws IOException {
    Leak le = new Leak();
    int i = 1;
    while (true) {
      System.out.println("Iteration: " + i);
      le.useVector(1);
      i++;
    }
  }
}

Compliant Solution (>=)

This compliant solution corrects the mistake by changing the loop condition to n >= 0.

public void useVector(int count) { 	
  for (int n = 0; n < count; n++) {
    vector.add(Integer.toString(n));
  }
  // ...
  for (int n = count - 1; n >= 0; n--) {
    vector.removeElementAt(n);
  }
}	

Compliant Solution (clear())

Prefer the use of standard language semantics where possible. This compliant solution uses the vector.clear() method, which removes all elements.

public void useVector(int count) { 	
  for (int n = 0; n < count; n++) {
    vector.add(Integer.toString(n));
  }
  // ...
  vector.clear(); // Clear the vector
}

Use the vector.subList(fromIndex, toIndex).clear() method to remove a subrange of elements from the vector. Note that the fromIndex and the toIndex can both be 0 as the count variable is 1 on each iteration [[API 2006]].

Noncompliant Code Example (Non-Local Instance Field)

This noncompliant code example declares and allocates a HashMap instance field that is used only in the doSomething() method.

public class Storer {
  private HashMap<Integer,String> hm = new HashMap<Integer, String>();
  
  private void doSomething() {
    hm.put(1, "java");  // hm is used only here and never referenced again
    // ...
  }
}

Programmers may be surprised that the HashMap will persist for the entire lifetime of the Storer instance.

Compliant Solution (Reduce Scope of Instance Field)

This compliant solution declares the HashMap as a local variable within the doSomething() method, eliminating the memory link.

public class Storer {
  private void doSomething() {
    HashMap<Integer,String> hm = new HashMap<Integer,String>();
    hm.put(1,"java");
    // ...
  }
}

Localizing or confining the instance field to a narrower scope simplifies garbage collection; today's generational garbage collectors perform well with short-lived objects.

Noncompliant Code Example (Lapsed Listener)

This noncompliant code example, known as the Lapsed Listener ([Goetz 2005]), demonstrates unintentional object retention. The button continues to hold a reference of the reader object after completion of the readSomething() method, even though the reader object will never be used again.

public class LapseEvent extends JApplet {
  JButton button;
  public void init() {
    button = new JButton("Click Me");
    getContentPane().add(button, BorderLayout.CENTER);
    Reader reader = new Reader();
    button.addActionListener(reader);
    try {
      reader.readSomething();
    } catch (IOException e) { 
      // Handle exception 
    }		 
  }
}

class Reader implements ActionListener {
  public void actionPerformed(ActionEvent e)  {
    Toolkit.getDefaultToolkit().beep();
  }
  public void readSomething() throws IOException {
    // Read from file
  }
}

Consequently, the garbage collector cannot collect the reader object. A similar problem occurs with inner classes, because they hold an implicit reference to the enclosing class.

Noncompliant Code Example (Exception Before Remove)

Unknown macro: {mc}

Bloch 08 says: The best way to ensure that callbacks are garbage collected promptly is to store only weak references to them, for instance, by storing them only as keys in a WeakHashMap.

This noncompliant code example attempts to remove the reader through use of the removeActionListener() method.

Reader reader = new Reader();
button.addActionListener(reader);
try {
  reader.readSomething();  // Can skip next line
  button.removeActionListener(reader);  // Dereferenced, but control flow can change
} catch (IOException e) { 
  // Forward to handler 
}		 

However, the removeActionListener() statement is never executed if an exception is thrown by the readSomething() method.

Compliant Solution (finally Block)

This compliant solution uses a finally block to ensure that the reader object's reference is unregistered.

Reader reader = new Reader();
button.addActionListener(reader);
try {
  reader.readSomething();
} catch (IOException e) { 
  // Handle exception 
} finally {
  button.removeActionListener(reader);  // Always executed
}

Noncompliant Code Example (Member Object Leaks)

This noncompliant code example implements a stack data structure [[Bloch 2008]] that continues to hold references to elements after thay have been popped from the stack.

public class Stack {
  private Object[] elements;
  private int size = 0;

  public Stack(int initialCapacity) {
    this.elements = new Object[initialCapacity];
  }

  public void push(Object e) {
    ensureCapacity();
    elements[size++] = e;
  }

  public Object pop() { // This method causes memory leaks
    if (size == 0) {
      throw new EmptyStackException();
    }
    return elements[--size];
  }
  /**
  * Ensure space for at least one more element, roughly
  * doubling the capacity each time the array needs to grow.
  */
  private void ensureCapacity() {
    if (elements.length == size) {
      Object[] oldElements = elements;
      elements = new Object[2 * elements.length + 1];
      System.arraycopy(oldElements, 0, elements, 0, size);
    }
  }
}

The object references are retained on the stack even after the element is popped. Such obsolete references remain live, and consequently cannot be garbage collected.

Compliant Solution (null)

This compliant solution assigns null values to all obsolete references.

public Object pop() {
  if (size == 0)
    throw new EmptyStackException(); // Ensures object consistency
  Object result = elements[--size];
  elements[size] = null; // Eliminate obsolete reference
  return result;
} 

The garbage collector can then include individual objects formerly on the stack in its list of objects to free.

Although these examples appear trivial, and may fail to model production scenarios, obsolete references remain common when dealing with data structures such as hash tables containing many large records. It is prudent to assign null to array-like custom data structures; doing so with individual objects or local variables is unnecessary, because the garbage collector handles these cases automatically [[Commes 2007]].

Noncompliant Code Example (Strong References)

A common variation of the obsolete object fallacy is unintentional retention of objects in collections such as maps. In this noncompliant code example, a server maintains temporary metadata about all committed secure connections.

class HashMetaData {
  private Map<SSLSocket, InetAddress> m = Collections.synchronizedMap(new HashMap<SSLSocket, InetAddress>());
  public void storeTempConnection(SSLSocket sock, InetAddress ip) {
    m.put(sock, ip);  
  }
  public void removeTempConnection(SSLSocket sock) {
    m.remove(sock);  
  }	
}

It is possible to close a socket without removing it from this map. Consequently, this map can contain dead sockets, until removeTempConnection() is invoked on them. In the absence of notification logic, it is impossible to determine when to call removeTempConnection(). Moreover, nulling out original objects or referents (Socket connections) is unwieldy.

Compliant Solution (Weak References)

This compliant solution uses weak references to allow timely garbage collection.

// ...
private Map<SSLSocket, InetAddress> m = Collections.synchronizedMap(new WeakHashMap<SSLSocket, InetAddress>());

Strong references prevent the garbage collector from reclaiming objects that are stored compositely, such as in a Map. According to the Java API [[API 2006]], weak reference objects: "... do not prevent their referents from being made finalizable, finalized, and then reclaimed." A referent is the object that is being referred to.

Keys held in WeakHashMap objects are referenced through weak references. Objects become eligible for garbage collection when they lack strong references. Consequently, use of weak references allows the code to refer to the referent without delaying garbage collection of the referent. This approach is suitable only when the lifetime of the object is required to be the same as the lifetime of the key.

Simply facilitating garbage collection of unneeded objects through use of weak references is insufficient. Programs must also prune the data structure so that additional live entries can be accommodated. One pruning technique is to call the get() method of WeakHashMap and removing any entry that corresponds to a null return value (polling). Use of reference queues is a more efficient method [[Goetz 2005b]].

Compliant Solution (Reference Queue)

Reference queues provide a way to receive notifications when a referent is garbage collected. When the referent is eventually garbage collected, the HashMap continues to strongly reference both the WeakReference object and the corresponding map value (for each entry in the HashMap).

When the GC clears the reference that referred to the referent, it adds the corresponding WeakReference object to the reference queue. The WeakReference object remains in the reference queue until some operation is performed on the queue (such as a put() or remove()). After such an operation, the WeakReference object in the hashmap is also garbage collected. Alternatively, this two-step procedure can be carried out manually by using the following code:

class HashMetaData {
  private Map<WeakReference<SSLSocket>, InetAddress> m = 
    Collections.synchronizedMap(new HashMap<WeakReference<SSLSocket>, InetAddress>());
  ReferenceQueue queue = new ReferenceQueue();
  
  public void storeTempConnection(SSLSocket sock, InetAddress ip) {
    WeakReference<SSLSocket> wr = new WeakReference<SSLSocket>(sock, queue);

    while ((wr = (WeakReference) queue.poll()) != null) { // poll for dead entries before adding more
      m.remove(wr); // Removes the WeakReference object and the value (not the referent)
    }  
    m.put(wr, ip);
  }

  public void removeTempConnection(SSLSocket sock) {
    m.remove(sock);  
  }	
}

Note that the two-argument constructor of WeakReference takes a Queue argument and must be used to perform direct queue processing. Dead entries should be pruned prior to insertion.

Compliant Solution (Soft References)

Use of soft references is also permitted. Soft references guarantee that the referent will be reclaimed before an OutOfMemoryError results, and also that the referent will remain live until memory begins to run out.

class HashMetaData {
  private Map<SoftReference<SSLSocket>, InetAddress> m = 
    Collections.synchronizedMap(new HashMap<SoftReference<SSLSocket>, InetAddress>());
  ReferenceQueue queue = new ReferenceQueue();

  public void storeTempConnection(SSLSocket sock, InetAddress ip) {
    SoftReference<SSLSocket> sr = new SoftReference<SSLSocket>(sock, queue);
    while ((sr = (SoftReference) queue.poll()) != null) {
      m.remove(sr); // Removes the WeakReference object and the value (not the referent)
    }  
    m.put(sr, ip);
  }

  public void removeTempConnection(SSLSocket sock) {
    m.remove(sock);  
  }	
}

Weak references are garbage-collected more aggressively than soft references. Consequently weak references should be preferred in applications where efficient memory usage is critical, and soft references should be preferred in applications that rely heavily on caching.

Risk Assessment

Memory leaks in Java applications may be exploited to cause denial of service.

Rule

Severity

Likelihood

Remediation Cost

Priority

Level

MSC06-J

low

unlikely

high

P1

L3

Related Vulnerabilities

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

Bibliography

[[API 2006]] Class Vector, Class WeakReference
[[Bloch 2008]] Item 6: Eliminate obsolete object references
[[Commes 2007]] Memory Leak Avoidance
[[Goetz 2005]] Lapsed listeners
[[Goetz 2005b]] "Memory leaks with global Maps" and "Reference queues"
[[Gupta 2005]]
[[MITRE 2009]] CWE ID 401 "Improper Release of Memory Before Removing Last Reference ('Memory Leak')"


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