Returning references to internal mutable members of a class can compromise an application's security, both by breaking encapsulation and also by providing the opportunity to corrupt the internal state of the class (whether accidentally or maliciously). Therefore, programs must not return references to internal mutable classes.
Returning a defensive copy of a reference to a mutable internal state ensures that the caller can only modify the copy and not the original internal state.
Noncompliant Code Example
This noncompliant code example shows a getDate()
accessor method that returns the sole instance of the private
Date
object.
class MutableClass { private Date d; public MutableClass() { d = new Date(); } public Date getDate() { return d; } }
An untrusted caller can manipulate a private Date
object because returning the reference exposes the internal mutable component beyond the trust boundaries of MutableClass
.
Compliant Solution (clone()
)
This compliant solution returns a clone of the Date
object from the getDate()
accessor method. This is safe because while Date
can be extended by an attacker, the Date
object returned by getDate()
is controlled by MutableClass
and is known not to be a malicious subclass.
protected Date getDate() { return (Date)d.clone(); }
Note that defensive copies performed during execution of a constructor must avoid use of the clone()
method when the class could be subclassed by untrusted code. This restriction prevents execution of a maliciously crafted overriding of the clone()
method. For more details, see rule "OBJ00-J. Limit extensibility of classes and methods with invariants to trusted subclasses only."
Classes that have public
setter methods must follow the related advice found in rule "FIO00-J. Defensively copy mutable inputs and mutable internal components." Note that setter methods can (and usually should) perform input validation and sanitization before setting internal fields.
Noncompliant Code Example (Mutable Member Array)
In this noncompliant code example, the getDate()
accessor method returns an array of Date
objects. The method fails to make a defensive copy of the array before returning it. Because the array contains references to Date
objects that are mutable, a shallow copy of the array would be insufficient because an attacker can modify the Date
objects in the array.
class MutableClass { private Date[] date; public MutableClass() { for (int i = 0; i < 20; i++) date[i] = new Date(); } public Date[] getDate() { return date; // or return date.clone() } }
Compliant Solution (Deep Copy)
This compliant solution creates a deep copy of the date
array and returns the copy, thereby protecting both the date
array and the individual Date
objects.
class MutableClass { private Date[] date; public MutableClass() { for(int i = 0; i < 20; i++) { date[i] = new Date(); } } public Date[] getDate() { Date[] dates = new Date[20]; for (int i = 0; i < 20; i++) { dates[i] = (Date) date[i].clone(); } return dates; } }
Noncompliant Code Example (Mutable Member Containing Immutable Objects)
In this noncompliant code example, class ReturnRef
contains a private
Hashtable
instance field. The hash table stores immutable but sensitive data (SSNs). A getter method getValues()
gives the caller access to the hash table by returning a reference to it. An untrusted caller can use the getter method to gain access to the hash table; as a result, hash table entries can be maliciously added, removed, or replaced. Furthermore, these modifications can be performed by multiple threads, providing ample opportunities for race conditions.
class ReturnRef { // Internal state, may contain sensitive data private Hashtable<Integer,String> ht = new Hashtable<Integer,String>(); private ReturnRef() { ht.put(1, "123-45-6666"); } public Hashtable<Integer,String> getValues(){ return ht; } public static void main(String[] args) { ReturnRef rr = new ReturnRef(); Hashtable<Integer, String> ht1 = rr.getValues(); // Prints sensitive data 123-45-6666 ht1.remove(1); // Untrusted caller can remove entries Hashtable<Integer, String> ht2 = rr.getValues(); // Now prints null, original entry is removed } }
In returning a reference to the ht
hash table, this example also hinders efficient garbage collection. See rule "OBJ11-J. Write garbage-collection-friendly code" for more information.
Compliant Solution (Shallow Copy)
Make defensive copies of private internal mutable object state. For mutable fields that contain immutable data, a shallow copy is sufficient. Fields that refer to mutable data generally require a deep copy.
This compliant solution creates and returns a shallow copy of the hash table containing immutable SSNs. Consequently, the original hash table remains private, and any attempts to modify it are ineffective.
class ReturnRef { // ... private Hashtable<Integer,String> getValues(){ return (Hashtable<Integer, String>)ht.clone(); // shallow copy } public static void main(String[] args) { ReturnRef rr = new ReturnRef(); Hashtable<Integer,String> ht1 = rr.getValues(); // prints non-sensitive data ht1.remove(1); // untrusted caller can only modify copy Hashtable<Integer,String> ht2 = rr.getValues(); // prints non-sensitive data } }
When a hash table contains references to mutable data such as a series of Date
objects, each of those objects must also be copied by using a copy constructor or method. For further details, refer to rules "FIO00-J. Defensively copy mutable inputs and mutable internal components" and "OBJ08-J. Provide mutable classes with copy functionality to allow passing instances to untrusted code safely."
Note that the keys of a hash table do not need to be deep copied; shallow copying of the references suffices because a hash table's contract dictates that its keys must produce consistent results to the equals()
and hashCode()
functions. Mutable objects whose equals()
or hashCode()
method results may be modified are not suitable keys.
This example is also more amenable to efficient garbage collection, as described in rule "OBJ11-J. Write garbage-collection-friendly code."
Exceptions
OBJ05-EX0: When callers expose only unmodifiable views of an object to a method, the method may freely use the unmodifiable view without defensive copying. This decision should be made early in the design of the API. Note that new callers of such methods must also expose only unmodifiable views. (See rule "SEC14-J. Provide sensitive mutable classes with unmodifiable wrappers.")
Risk Assessment
Returning references to internal object state (mutable or immutable) can render an application susceptible to information leaks and corruption of its objects' states, which, consequently, violates class invariants. Control flow can also be affected in some cases.
Rule |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
---|---|---|---|---|---|
OBJ05-J |
high |
probable |
medium |
P12 |
L1 |
Automated Detection
Sound automated detection is infeasible; heuristic checks could be useful.
Related Vulnerabilities
Pugh [[Pugh 2009]] cites a vulnerability discovered by the Findbugs static analysis tool in the early betas of JDK 1.7 where the sun.security.x509.InvalidityDateExtension
class returned a Date
instance through a public
accessor without creating defensive copies.
Related Guidelines
CWE ID 375, "Returning a Mutable Object to an Untrusted Caller" |
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OBJ04-J. Provide mutable classes with copy functionality to allow passing instances to untrusted code safely 04. Object Orientation (OBJ)