Recall that immutability offers several benefits such as thread-safety, prevention against inadvertent modification of fields and malicious tampering. Class invariants and state are always consistent with the requirements and no defensive copying is necessary. However, sometimes it is not possible to make sensitive classes immutable. Fortunately, there is a mechanism that allows code to expose mutable classes to untrusted code by granting read-only access. This is largely achieved through unmodifiable wrappers. For example, in the Collection classes a set of wrappers allow clients to observe an unmodifiable view of the particular Collection object.
Noncompliant Code Example
This noncompliant code example consists of class Modifiable which allows the internal ArrayList object to be modified. An untrusted invoker may call the mutator method listIt() and violate the object's immutability property.
class Modifiable {
private List<Integer> list = new ArrayList<Integer>();
public void listIt() {
addSomething(list);
// ...
}
private void addSomething(Collection<Integer> collection) {
collection.add(1);
}
}
Compliant Solution
This compliant solution recommends an unmodifiable wrapper to shield the mutator method(s) and provide an unmodifiable view to the caller. Internally, the unmodifiable Collection's mutator methods are designed to throw an UnsupportedOperationException in such events.
// ...
public void listIt() {
addSomething(Collections.unmodifiableCollection(list));
// ...
}
private void addSomething(Collection<Integer> collection) {
collection.add(1); // throws java.lang.UnsupportedOperationException
}
It should be noted that objects present within the Collection may not be thread-safe, making them mutable in multithreaded contexts. Consider for example, an ArrayList of ArrayLists wherein the contained ArrayList is still susceptible to modification.
Noncompliant Code Example
This noncompliant code example shows an interface MutableInterface which declares an accessor and a mutator method. This class does not expose an unmodifiable view to implementing clients.
interface MutableInterface {
int[] getArray(); // accessor
void setArray(int[] i); //mutator
}
class SensitiveMutable implements MutableInterface {
int[] array = new int[10]; // mutable array
public int[] getArray() {
return array.clone();
}
public void setArray(int[] i) {
array = i;
}
}
Compliant Solution
In general, sensitive classes can be transformed into safe-view objects by implementing all the methods defined by the core interface, including the mutator methods. In this case, the difference is that the mutators need to throw an UnsupportedOperationException so that clients cannot carry out operations that affect the immutability property of the object.
This compliant solution constructs an UnmodifiableSensitiveMutable by extending the class SensitiveMutable. An interface UnmodifiableInterface consists of the method unmodifiableView() which accepts a SensitiveMutable object as the sole parameter. It returns an equivalent object that is a subtype of the same class, and which is unmodifiable. An exception is thrown if the caller attempts to use the mutator method on the returned object. This object can be passed to untrusted code as required.
interface UnmodifiableInterface {
SensitiveMutable unmodifiableView(SensitiveMutable sm);
}
class UnmodifiableSensitiveMutable extends SensitiveMutable {
int[] array = new int[10];
public void setArray(int[] i) {
throw new UnsupportedOperationException();
}
}
class UnmodifiableWrapper extends UnmodifiableSensitiveMutable implements UnmodifiableInterface {
public SensitiveMutable unmodifiableView(SensitiveMutable sm) {
return new UnmodifiableWrapper(); // subtype of SensitiveMutable
}
}
class Invoker {
public static void main(String[] args) {
UnmodifiableWrapper uw = new UnmodifiableWrapper();
SensitiveMutable s = uw.unmodifiableView(sm);
s.setArray(new int[10]); // throws UnsupportedOperationException unlike s.getArray()
}
}
Risk Assessment
Failure to provide an unmodifiable safe-view of a sensitive mutable object to untrusted code can lead to malicious tampering and corruption of the object.
Rule |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
|---|---|---|---|---|---|
SEC14- J |
medium |
probable |
high |
P4 |
L3 |
Automated Detection
TODO
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
References
[[Tutorials 08]] Unmodifiable Wrappers
SEC00-J. Follow the principle of least privilege 02. Platform Security (SEC) SEC04-J. Do not expose standard APIs that may bypass Security Manager checks to untrusted code