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While Although serialization allows an object's state to be saved as a sequence of bytes and then reconstituted at a later time, it provides no mechanism to protect the serialized data. An attacker who gains access to the serialized data can use it to discover sensitive information and to determine implementation details of the objects. An attacker can also modify the serialized data in an attempt to compromise the system when the malicious data is deserialized. Consequently, sensitive data that is serialized is potentially exposed, without regard to the access qualifiers (such as the private keyword) that were used in the original code. Moreover, the security manager cannot guarantee the integrity of the deserialized data.

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This rule is meant to prevent the unintentional serialization of sensitive information. Rule SER02-J. Sign then seal sensitive objects before sending them outside a trust boundary applies to the intentional serialization of sensitive information.

Noncompliant Code Example

The data members of class Point are private. Assuming the coordinates are sensitive, their presence in the data stream would expose them to malicious tampering.

Code Block
bgColor#FFcccc

public class Point implements Serializable {
  private double x;
  private double y;

  public Point(double x, double y) {
    this.x = x;
    this.y = y;
  }

  public Point() {
    // noNo-argument constructor
  }
}

public class Coordinates extends Point implements Serializable {
  public static void main(String[] args) {
    FileOutputStream fout = null;
    try {
      Point p = new Point(5, 2);
      fout = new FileOutputStream("point.ser");
      ObjectOutputStream oout = new ObjectOutputStream(fout);
      oout.writeObject(p);
    } catch (Throwable t) { 
      // Forward to handler 
    } finally {
      if (fout != null) {
        try {
          fout.close();
        } catch (IOException x) {
          // handleHandle error
        }
      }
    }
  }
}

In the absence of sensitive data, classes can be serialized by simply implementing the java.io.Serializable interface. By doing so, the class indicates that no security issues may result from the object's serialization. Note that any derived subclasses also inherit this interface and are consequently serializable. This approach is inappropriate for any class that contains sensitive data.

Compliant Solution

When serializing a class that contains sensitive data, programs must ensure that sensitive data is omitted from the serialized form. This includes suppressing both serialization of data members that contain sensitive data and serialization of references to non-serializable nonserializable or sensitive objects.

This compliant solution both avoids the possibility of incorrect serialization and protects sensitive data members from accidental serialization by declaring the relevant members as transient so that they are omitted from the list of fields to be serialized by the default serialization mechanism.

Code Block
bgColor#ccccff

public class Point implements Serializable {
 private transient double x; // declaredDeclared transient
 private transient double y; // declaredDeclared transient

 public Point(double x, double y) {
  this.x = x;
  this.y = y;
 }

 public Point() {
   // noNo-argument constructor
 }
}

public class Coordinates extends Point implements Serializable {
  public static void main(String[] args) {
    FileOutputStream fout = null;
    try {
      Point p = new Point(5,2);
      fout = new FileOutputStream("point.ser");
      ObjectOutputStream oout = new ObjectOutputStream(fout);
      oout.writeObject(p);
      oout.close();
    } catch (Exception e) {
      // Forward to handler
    } finally {
      if (fout != null) {
        try {
          fout.close();
        } catch (IOException x) {
          // handleHandle error
        }
      }
    }
  }
}

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Other compliant solutions include: *developing

  • Developing custom implementations of the writeObject(), writeReplace(), and writeExternal() methods that prevent sensitive fields from being written to the serialized stream.

...

  • Defining the serialPersistentFields array field and ensuring that sensitive fields are omitted from the array

...

  • (

...

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Noncompliant Code Example

Serialization can be used maliciously, for example, to return multiple instances of a singleton class object. In this noncompliant code example (based on [Bloch 2005]), a subclass SensitiveClass inadvertently becomes serializable because it extends the java.lang.Number class, which implements Serializable.:

Code Block
bgColor#FFcccc

public class SensitiveClass extends Number {
  // ..implement. Implement abstract methods, such as Number.doubleValue()â�����€š�š�¦â€¦

  private static final SensitiveClass INSTANCE = new SensitiveClass();
  public static SensitiveClass getInstance() {
    return INSTANCE;
  }

  private SensitiveClass() {
    // Perform security checks and parameter validation
  }

  protectedprivate int getBalance() {balance = 1000;
   protected int balance = 1000;getBalance() {
    return balance;
  }
}

class Malicious {
  public static void main(String[] args) {
    SensitiveClass sc =
       (SensitiveClass) deepCopy(SensitiveClass.getInstance());
    // Prints false; indicates new instance
    System.out.println(sc == SensitiveClass.getInstance());  
    System.out.println("Balance = " + sc.getBalance());
  }

  // This method should not be used in production code
  static public Object deepCopy(Object obj) {
    try {
      ByteArrayOutputStream bos = new ByteArrayOutputStream();
      new ObjectOutputStream(bos).writeObject(obj);
      ByteArrayInputStream bin =
          new ByteArrayInputStream(bos.toByteArray());
      return new ObjectInputStream(bin).readObject();
    } catch (Exception e) { 
      throw new IllegalArgumentException(e);
    }
  }
}

See rule MSC07-J. Prevent multiple instantiations of singleton objects for more information about singleton classes.

Compliant Solution

Extending a class or interface that implements Serializable should be avoided whenever possible. For instance, a nonserializable class could contain an instance of a serializable class , and delegate method calls to the serializable class.

When extension of a serializable class by an unserializable class is necessary, inappropriate serialization of the subclass can be prohibited by throwing NotSerializableException from custom writeObject(), readObject(), and readObjectNoData() methods, defined in the nonserializable subclass. These custom methods must be declared private or final to prevent a malicious subclass from overriding them(see SER01-J. Do not deviate from the proper signatures of serialization methods for more information).

Code Block
bgColor#ccccff

class SensitiveClass extends Number {
  // ...

  protectedprivate final Object writeObject(java.io.ObjectOutputStream out) throws NotSerializableException {
    throw new NotSerializableException();
  }
  protectedprivate final Object readObject(java.io.ObjectInputStream in) throws NotSerializableException {
    throw new NotSerializableException();
  }
  protectedprivate final Object readObjectNoData(java.io.ObjectInputStream in) throws NotSerializableException {
    throw new NotSerializableException();
  }
}

It is still possible for an attacker to obtain uninitialized instances of SensitiveClass by catching NotSerializableException or by using a finalizer attack , (see OBJ11-J. Be wary of letting constructors throw exceptions for more information). Therefore Consequently, an unserializable class that extends a serializable class must always validate its invariants before executing any methods. That is, any object of such a class must inspect its fields, its actual type (to prevent it being a malicious subclass), and any invariants it possess possesses (such as being a malicious second object of a singleton class).

Exceptions

SER03-J-EX0: Sensitive data that has been properly encrypted may be serialized.

Risk Assessment

If sensitive data can be serialized, it may be transmitted over an insecure connection, stored in an insecure location, or disclosed inappropriately.

Rule

Severity

Likelihood

Remediation Cost

Priority

Level

SER03-J

medium

Medium

likely

Likely

high

High

P6

L2

Automated Detection

Tool
Version
Checker
Description
CodeSonar
Include Page
CodeSonar_V
CodeSonar_V

JAVA.CLASS.SER.ND

Serialization Not Disabled (Java)

Coverity7.5UNSAFE_DESERIALIZATIONImplemented
Parasoft Jtest
Include Page
Parasoft_V
Parasoft_V
CERT.SER03.SIFInspect instance fields of serializable objects to make sure they will not expose sensitive information

Related Guidelines

MITRE CWE

CWE-499

. Serializable class containing sensitive data

 

, Serializable Class Containing Sensitive Data
CWE-502

.

, Deserialization of

untrusted data

Untrusted Data

Secure Coding Guidelines for

the

Java

Programming Language

SE, Version

3

5.0

Guideline

5

8-2 / SERIAL-2

.

: Guard sensitive data during serialization

Bibliography

[Bloch 2005]

Puzzle 83

.

, "Dyslexic monotheism"

[Bloch 2001]

Item 1

.

, "Enforce the

singleton property

Singleton Property with a

private constructor

[JLS 2005]

Transient Modifier

Private Constructor"

[Greanier 2000]

Discover the Secrets of the Java Serialization API

[Harold 1999]

 


[Long 2005]

Section 2.4, "Serialization"

[Sun 2006]

Serialization Specification, A.4, Preventing Serialization of Sensitive Data


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SER02-J. Sign then seal sensitive objects before sending them outside a trust boundary      13. Serialization (SER)      Image Added Image Added