Programs must not catch java.lang.NullPointerException. A NullPointerException exception thrown at runtime indicates the existence of an underlying null pointer dereference that must be fixed in the application code (see rule [EXP01-J. Never dereference null pointers] for more information). Handling the underlying null pointer dereference by catching the NullPointerException rather than fixing the underlying problem is inappropriate for several reasons. First, catching NullPointerException adds significantly more performance overhead than simply adding the necessary checks [[Bloch 2008]]. Second, when multiple expressions in a try block are capable of throwing a NullPointerException, it is difficult or impossible to determine which expression is responsible for the exception because the NullPointerException catch block handles any NullPointerException thrown from any location in the try block. Third, programs rarely remain in an expected and usable state after a NullPointerException has been thrown. Attempts to continue execution after first catching and logging (or worse, suppressing) the exception rarely succeed.
Likewise, programs must not catch RuntimeException or its ancestors, Exception or Throwable. Few, if any, methods are capable of handling all possible runtime exceptions. When a method catches RuntimeException, it may receive exceptions unanticipated by the designer, including NullPointerException and ArrayIndexOutOfBoundsException. Many catch clauses simply log or ignore the enclosed exceptional condition and attempt to resume normal execution; this practice often violates rule ERR00-J. Do not suppress or ignore checked exceptions. Runtime exceptions often indicate bugs in the program that should be fixed by the developer and often cause control flow vulnerabilities.
Noncompliant Code Example (NullPointerException)
This noncompliant code example defines an isName() method that takes a String argument and returns true if the given string is a valid name. A valid name is defined as two capitalized words separated by one or more spaces. Rather than checking to see whether the given string is null, the method catches NullPointerException and returns false.
boolean isName(String s) {
try {
String names[] = s.split(" ");
if (names.length != 2) {
return false;
}
return (isCapitalized(names[0]) && isCapitalized(names[1]));
} catch (NullPointerException e) {
return false;
}
}
Compliant Solution
This compliant solution explicitly checks the String argument for null rather than catching NullPointerException.
boolean isName(String s) {
if (s == null) {
return false;
}
String names[] = s.split(" ");
if (names.length != 2) {
return false;
}
return (isCapitalized(names[0]) && isCapitalized(names[1]));
}
Compliant Solution
This compliant solution omits an explicit check for a null reference and permits a NullPointerException to be thrown.
boolean isName(String s) /* throws NullPointerException */ {
String names[] = s.split(" ");
if (names.length != 2) {
return false;
}
return (isCapitalized(names[0]) && isCapitalized(names[1]));
}
Omitting the null check means that the program fails more quickly than if the program had returned false and lets an invoking method discover the null value. A method that throws a NullPointerException without a null check must provide a precondition that the argument being passed to it is not null.
Noncompliant Code Example (Explicit Null Checks)
This noncompliant code example is derived from the logging service null object design pattern described by Henney [[Henney 2003]]. The logging service is composed of two classes: one that prints the triggering activity's details to a disk file using the FileLog class and another that prints to the console using the ConsoleLog class. An interface, Log, defines a write() method that is implemented by the respective log classes. Method selection occurs polymorphically at runtime. The logging infrastructure is subsequently used by a Service class.
public interface Log {
void write(String messageToLog);
}
public class FileLog implements Log {
private final FileWriter out;
FileLog(String logFileName) throws IOException {
out = new FileWriter(logFileName, true);
}
public void write(String messageToLog) {
// write message to file
}
}
public class ConsoleLog implements Log {
public void write(String messageToLog) {
System.out.println(messageToLog); // write message to console
}
}
class Service {
private Log log;
Service() {
this.log = null; // no logger
}
Service(Log log) {
this.log = log; // set the specified logger
}
public void handle() {
try {
log.write("Request received and handled");
} catch (NullPointerException npe) {
// Ignore
}
}
public static void main(String[] args) throws IOException {
Service s = new Service(new FileLog("logfile.log"));
s.handle();
s = new Service(new ConsoleLog());
s.handle();
}
}
Each Service object must support the possibility that a Log object may be null because clients may choose not to perform logging. This noncompliant code example eliminates null checks by using a try-catch block that ignores NullPointerException.
This design choice suppresses genuine occurrences of NullPointerException. It also violates the design principle that exceptions should be used only for exceptional conditions; ignoring a null Log object is part of the ordinary operation of a server.
Compliant Solution (Null Object Pattern)
The null object design pattern provides an alternative to the use of explicit null checks in code. It reduces the need for explicit null checks through the use of an explicit, safe null object rather than a null reference.
This compliant solution modifies the no-argument constructor of class Service to use the do nothing behavior provided by an additional class, Log.NULL; it leaves the other classes unchanged.
public interface Log {
public static final Log NULL = new Log() {
public void write(String messageToLog) {
// do nothing
}
};
void write(String messageToLog);
}
class Service {
private final Log log = Log.NULL;
// ...
}
Declaring the log reference final ensures that its value is assigned during initialization.
An acceptable alternative implementation uses a setter method and a getter method to control all interaction with the reference to the current log. The setter ensures use of the null object in place of a null reference. The getter ensures that any retrieved instance is either an actual logger or a null object (but never a null reference). Instances of the null object are immutable and are inherently thread-safe.
Some system designs require returning a value from a method rather than implementing do-nothing behavior. One acceptable approach is use of an exceptional value object that throws an exception before the method returns [[Cunningham 1995]]. This can be a useful alternative to returning null.
In distributed environments, the null object must be passed by copy to ensure that remote systems avoid the overhead of a remote call argument evaluation on every access to the null object. Null object code for distributed environments must also implement the Serializable interface.
Code that uses this pattern must be clearly documented to ensure that security-critical messages are never discarded because the pattern has been misapplied.
Noncompliant Code Example (Division)
In this noncompliant code example, the original version of the division() method is declared to throw only ArithmeticException. However, the caller catches the more general Exception type to report arithmetic problems rather than catching the specific exception ArithmeticException type. This practice is insecure because future changes to the method signature could add to the list of potential exceptions the caller must handle. In this example, a newer version of the division() method can potentially throw IOException in addition to ArithmeticException. However, the compiler cannot inform the caller's developer to provide a corresponding handler because his or her existing code already catches IOException as a result of catching Exception. Consequently, the recovery process might be inappropriate for the specific exception type that is thrown. Furthermore, the developer has failed to anticipate that catching Exception also catches unchecked exceptions.
public class DivideException {
public static void main(String[] args) {
try {
division(200, 5);
division(200, 0); // Divide by zero
} catch (Exception e) {
System.out.println("Divide by zero exception : "
+ e.getMessage());
}
}
public static void division(int totalSum, int totalNumber)
throws ArithmeticException, IOException {
int average = totalSum / totalNumber;
// Additional operations that may throw IOException...
System.out.println("Average: " + average);
}
}
Noncompliant Code Example
This noncompliant code example attempts improvement by specifically catching ArithmeticException. However, it continues to catch Exception and consequently catches both unanticipated checked exceptions and unanticipated runtime exceptions.
try {
division(200, 5);
division(200, 0); // Divide by zero
} catch (ArithmeticException ae) {
throw new DivideByZeroException();
} catch (Exception e) {
System.out.println("Exception occurred :" + e.getMessage());
}
Note that DivideByZeroException is a custom exception type that extends Exception.
Compliant Solution
This compliant solution catches only the specific anticipated exceptions (ArithmeticException and IOException). All other exceptions are permitted to propagate up the call stack.
import java.io.IOException;
public class DivideException {
public static void main(String[] args) {
try {
division(200, 5);
division(200, 0); // Divide by zero
} catch (ArithmeticException ae) {
// DivideByZeroException extends Exception so is checked
throw new DivideByZeroException();
} catch (IOException ex) {
ExceptionReporter.report(ex);
}
}
public static void division(int totalSum, int totalNumber)
throws ArithmeticException, IOException {
int average = totalSum / totalNumber;
// Additional operations that may throw IOException...
System.out.println("Average: "+ average);
}
}
The ExceptionReporter class is documented in rule ERR00-J. Do not suppress or ignore checked exceptions.
Compliant Solution (Java 1.7)
Java 1.7 allows a single catch block to catch multiple exceptions of different types, which prevents redundant code. This compliant solution catches the specific anticipated exceptions (ArithmeticException and IOException) and handles them with one catch clause. All other exceptions are permitted to propagate to the next catch clause of a try statement on the stack.
import java.io.IOException;
public class DivideException {
public static void main(String[] args) {
try {
division(200, 5);
division(200, 0); // Divide by zero
} catch (ArithmeticException|IOException ex) {
ExceptionReporter.report(ex);
}
}
public static void division(int totalSum, int totalNumber)
throws ArithmeticException, IOException {
int average = totalSum / totalNumber;
// Additional operations that may throw IOException...
System.out.println("Average: "+ average);
}
}
Exceptions
ERR08-EX0: A catch block may catch all exceptions to process them before rethrowing them (filtering sensitive information from exceptions before the call stack leaves a trust boundary, for example). Refer to ruleERR01-J. Do not allow exceptions to expose sensitive information and weaknesses CWE 7 and CWE 388. In such cases, a catch block should catch Throwable rather than Exception or RuntimeException.
This code sample catches all exceptions and wraps them in a custom DoSomethingException before rethrowing them.
class DoSomethingException extends Exception {
public DoSomethingException(Throwable cause) {
super(cause);
}
// other methods
};
private void doSomething() throws DoSomethingException {
try {
// code that might throw an Exception
} catch (Throwable t) {
throw new DoSomethingException(t);
}
}
Exception wrapping is a common technique to safely handle unknown exceptions. For another example, see rule ERR06-J. Do not throw undeclared checked exceptions.
ERR08-EX1: Task processing threads such as worker threads in a thread pool or the Swing event dispatch thread are permitted to catch RuntimeException when they call untrusted code through an abstraction such as Runnable [[Goetz 2006], p. 161].
EXC08-EX2: Systems that require substantial fault tolerance or graceful degradation are permitted to catch and log general exceptions such as Throwable at appropriate levels of abstraction. For example:
- A real-time control system that catches and logs all exceptions at the outermost layer, followed by warm-starting the system so that real-time control can continue. Such approaches are clearly justified when program termination would have safety-critical or mission-critical consequences.
- A system that catches all exceptions that propagate out of each major subsystem, logs the exceptions for later debugging, and subsequently shuts down the failing subsystem (perhaps replacing it with a much simpler, limited-functionality version) while continuing other services.
Risk Assessment
Catching NullPointerException may mask an underlying null dereference, degrade application performance, and result in code that is hard to understand and maintain. Likewise, catching RuntimeException may unintentionally trap other exception types and prevent them from being handled properly.
Rule |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
|---|---|---|---|---|---|
ERR08-J |
medium |
likely |
medium |
P12 |
L1 |