I use x != null
to avoid NullPointerException
. Is there an alternative?
if (x != null) {
// ...
}
All in all to avoid statement
if (object != null) {
....
}
since java 7 you can use Objects
methods:
Objects.isNull(object)
Objects.nonNull(object)
Objects.requireNonNull(object)
Objects.equals(object1, object2)
since java 8 you can use Optional class (when to use)
object.ifPresent(obj -> ...);
java 8
object.ifPresentOrElse(obj -> ..., () -> ...);
java 9
rely on method contract (JSR 305) and use Find Bugs. Mark your code with annotations @javax.annotation.Nullable
and @javax.annotation.Nonnnul
. Also Preconditions are available.
Preconditions.checkNotNull(object);
In special cases (for example for Strings and Collections) you can use apache-commons (or Google guava) utility methods:
public static boolean isEmpty(CharSequence cs) //apache CollectionUtils
public static boolean isEmpty(Collection coll) //apache StringUtils
public static boolean isEmpty(Map map) //apache MapUtils
public static boolean isNullOrEmpty(@Nullable String string) //Guava Strings
public static Object defaultIfNull(Object object, Object defaultValue)
public static <T> T ifNull(T toCheck, T ifNull) {
if (toCheck == null) {
return ifNull;
}
return toCheck;
}
ObjectUtils.defaultIfNull()
. There is one more general: ObjectUtils.firstNonNull()
, which can be used to implement a degrading strategy: firstNonNull(bestChoice, secondBest, thirdBest, fallBack);
You can use FindBugs. They also have an Eclipse plugin) that helps you find duplicate null checks (among other things), but keep in mind that sometimes you should opt for defensive programming. There is also Contracts for Java which may be helpful.
I follow below guidelines to avoid null checks.
Avoid lazy initialization of member variables as much as possible. Initialize the variables in declaration itself. This will handle NullPointerExceptions.
Decide on mutability of member variables early in the cycle. Use language constructs like final
keyword effectively.
If you know that augments for method won't be changed, declare them as final
.
Limit the mutation of data as much as possible. Some variables can be created in a constructor and can never be changed. Remove public setter methods unless they are really required.
E.g. Assume that one class in your application (A.java
) is maintaining a collection like HashMap
. Don't provide public
getter method in A.java and allow B.java
to directly add an element in Map
. Instead provide an API in A.java
, which adds an element into collection.
// Avoid
a.getMap().put(key,value)
//recommended
public void addElement(Object key, Object value){
// Have null checks for both key and value here : single place
map.put(key,value);
}
And finally, use try{} catch{} finally{}
blocks at right places effectively.
You can avoid most a lot to avoid NullPointerException
by just following most of the others answers to the Question, I just want to add few more ways which have been introduced in Java 9
to handle this scenario gracefully and also showcase a few of the older ones can also be used and thus reducing your efforts.
public static boolean isNull(Object obj)
Returns true if the provided reference is null otherwise returns false.
Since Java 1.8
public static boolean nonNull(Object obj)
Returns true if the provided reference is non-null otherwise returns false.
Since Java 1.8
public static <T> T requireNonNullElse(T obj, T defaultObj)
Returns the first argument if it is non-null and otherwise returns the non-null second argument.
Since Java 9
public static <T> T requireNonNullElseGet(T obj, Supplier<? extends T> supplier)
Returns the first argument if it is non-null and otherwise returns the non-null value of supplier.get().
Since Java 9
public static <T> T requireNonNull(T obj, Supplier<String> messageSupplier)
Checks that the specified object reference is not null and throws a customized NullPointerException otherwise.
Since Java 1.8
Further details about the above functions can be found here.
Java 8 has introduced a new class Optional in java.util
package. It is used to represent a value is present or absent. The main advantage of this new construct is that No more too many null checks and NullPointerException
. It avoids any runtime NullPointerExceptions
and supports us in developing clean and neat Java APIs or Applications. Like Collections
and arrays
, it is also a Container to hold at most one value.
Below are some useful link you can follow
Since Java 7
the class java.util.Objects
exists.
But since Java 8
, you can use Objects.isNull(var)
and Objects.nonNull(var)
methods of Objects
class to do the null pointer check.
For example,
String var1 = null;
Date var2 = null;
Long var3 = null;
if(Objects.isNull(var1) && Objects.isNull(var2) && Objects.isNull(var3))
System.out.println("All Null");
else if (Objects.nonNull(var1) && Objects.nonNull(var2) && Objects.nonNull(var3))
System.out.println("All Not Null");
Wherever you pass an array or a Vector, initialise these to empty ones, instead of null. - This way you can avoid lots of checking for null and all is good :)
public class NonNullThing {
Vector vectorField = new Vector();
int[] arrayField = new int[0];
public NonNullThing() {
// etc
}
}
One more alternative:
The following simple function helps to hide the null-check (I don't know why, but I haven't found it as part of the same common library):
public static <T> boolean isNull(T argument) {
return (argument == null);
}
You could now write
if (!isNull(someobject)) {
someobject.doCalc();
}
which is IMO a better way of expressing != null
.
isNotNull
? Doesn't that more clearly indicate your intent?
isNull
and isNotNull
method.
I find Guava Preconditions to be very useful in this case. I don't like leaving nulls to null pointer exception since the only way to understand an NPE is by locating the line number. Line numbers in production version and development version can be different.
Using Guava Preconditions, I can check null parameters and define a meaningful exception message in one line.
For example,
Preconditions.checkNotNull(paramVal, "Method foo received null paramVal");
In Java 8 you can use type T
for local-variable/field/method-argument/method-return-type if it never assigned null
(and do not check for null
) or type Optional<T>
if it can be null
. Then use method map
for processing T ->
and method flatMap
for processing T -> Optional<R>
:
class SomeService {
@Inject
private CompanyDao companyDao;
// return Optional<String>
public Optional<String> selectCeoCityByCompanyId0(int companyId) {
return companyDao.selectById(companyId)
.map(Company::getCeo)
.flatMap(Person::getHomeAddress)
.flatMap(Address::getCity);
}
// return String + default value
public String selectCeoCityByCompanyId1(int companyId) {
return companyDao.selectById(companyId)
.map(Company::getCeo)
.flatMap(Person::getHomeAddress)
.flatMap(Address::getCity)
.orElse("UNKNOWN");
}
// return String + exception
public String selectCeoCityByCompanyId2(int companyId) throws NoSuchElementException {
return companyDao.selectById(companyId)
.map(Company::getCeo)
.flatMap(Person::getHomeAddress)
.flatMap(Address::getCity)
.orElseThrow(NoSuchElementException::new);
}
}
interface CompanyDao {
// real situation: no company for such id -> use Optional<Company>
Optional<Company> selectById(int id);
}
class Company {
// company always has ceo -> use Person
Person ceo;
public Person getCeo() {return ceo;}
}
class Person {
// person always has name -> use String
String firstName;
// person can be without address -> use Optional<Address>
Optional<Address> homeAddress = Optional.empty();
public String getFirstName() {return firstName;}
public Optional<Address> getHomeAddress() {return homeAddress;}
}
class Address {
// address always contains country -> use String
String country;
// city field is optional -> use Optional<String>
Optional<String> city = Optional.empty();
String getCountry() {return country;}
Optional<String> getCity() {return city;}
}
If you are using java8 or later go for the isNull(yourObject)
from java.util.Objects
.
Example:-
String myObject = null;
Objects.isNull(myObject); //will return true
Usage: The below code returns a non null value (if the name is not null then that value will be returned else the default value will be returned).
final String name = "Jobin";
String nonNullValue = Optional.ofNullable(name).orElse("DefaultName");
myObject == null
and was introduced in Java8 for Predicates
in the lambda feature.
Objects
is introduced in java7, isNull
added to it later.
Objects.isNull
. The filter
here is superfluous. Optional.ofNullable()
will return Optional.empty()
if name
is null
, so you could just do: String nonNullValue = Optional.ofNullable(name).orElse("DefaultName");
You can use an interceptor before the method call. That is what aspect-oriented programming focus on.
Suppose M1(Object test) is a method and M2 is a method where we apply an aspect before a method call, M2(Object test2)
. If test2 != null
then call M1, otherwise do another thing. It works for all methods with whom you want to apply an aspect for. If you want to apply an aspect for an instance field and constructor you can use AspectJ. Spring can also be the best choice for a method aspect.
Another alternative to the != null check is (if you can't get rid of it design-wise):
Optional.ofNullable(someobject).ifPresent(someobject -> someobject.doCalc());
or
Optional.ofNullable(someobject).ifPresent(SomeClass::doCalc);
With SomeClass being someobject's type.
You can't get a return value back from doCalc() though, so only useful for void methods.
map
combined with get
or any of the other methods for getting the value in the Optional, instead of ifPresent
.
Aug 5, 2019 at 20:24
OK, I now this has been technically answered a million times but I have to say this because this is an un-ending discussion with Java programmers.
Sorry but I disagree will almost all of above. The reason we have to be testing for null in Java is because must Java programmers don’t know how to handle memory.
I say this because I have a long experience programming in C++ and we don’t do this. In other words, you don’t need to. And note that, in Java, if you hit a dangling pointer you get a normal exception; in C++ this exception normally is not caught and terminates the program.
Don’t want to do this? Then follow some simple rules ala C/C++.
Don’t instantiate things so easily, think that every "new" can get you in lots of trouble and FOLLOW these simple rules.
A class shall access memory in only 3 ways ->
It can "HAVE" class members, and they will follow these rules:
This means that you need to have in mind (just like Java does) who is the owner or parent of each resource and respect that ownership. An object is only deleted by the class who created it. Also ->
Some members will be "USED" but not own or "HAVE". This are "OWN" in another class and passed as arguments to the constructor. Since these are owned by another class, we will NEVER delete or close this, only the parent can.
A method in a class can also instantiate local objects for internal use which will NEVER pass out side of the class, or they should have been normal "has" objects.
Finally for all this to work, you need to have a disciplined design with classes in hierarchy form and making no cycles.
Under this design, AND following the above rules, there is no way that a child class in a hierarchy design will ever access a pointer which was destroyed, because that means that a parent was destroyed before a child, which the hierarchical acyclic design will not allow it.
Finally, also remember when starting your system you should build from top to bottom of the hierarchy and destroy bottom to top. You will never have a null pointer anywhere, or someone is violating the rules.
Java 8 now has Optional class that wraps the object in consideration and if a value is present, isPresent() will return true and get() will return the value.
http://www.oracle.com/technetwork/articles/java/java8-optional-2175753.html
You can also use the Checker Framework (with JDK 7 and beyond) to statically check for null values. This might solve a lot of problems, but requires running an extra tool that currently only works with OpenJDK AFAIK. https://checkerframework.org/
With Java 8, you could pass a supplier to a helper method like below,
if(CommonUtil.resolve(()-> a.b().c()).isPresent()) {
}
Above replaces boiler plate code like below,
if(a!=null && a.b()!=null && a.b().c()!=null) {
}
//CommonUtil.java
public static <T> Optional<T> resolve(Supplier<T> resolver) {
try {
T result = resolver.get();
return Optional.ofNullable(result);
} catch (NullPointerException var2) {
return Optional.empty();
}
}
public class Null {
public static void main(String[] args) {
String str1 = null;
String str2 = "";
if(isNullOrEmpty(str1))
System.out.println("First string is null or empty.");
else
System.out.println("First string is not null or empty.");
if(isNullOrEmpty(str2))
System.out.println("Second string is null or empty.");
else
System.out.println("Second string is not null or empty.");
}
public static boolean isNullOrEmpty(String str) {
if(str != null && !str.isEmpty())
return false;
return true;
}
}
Output
str1 is null or empty.
str2 is null or empty.
In the above program, we've two strings str1 and str2. str1 contains null value and str2 is an empty string.
We've also created a function isNullOrEmpty() which checks, as the name suggests, whether the string is null or empty. It checks it using a null check using != null and isEmpty() method of string.
In plain terms, if a string isn't a null and isEmpty() returns false, it's not either null or empty. Else, it is.
However, the above program doesn't return empty if a string contains only whitespace characters (spaces). Technically, isEmpty() sees it contains spaces and returns false. For string with spaces, we use the string method trim() to trim out all the leading and trailing whitespace characters.
There has a good way to check the null value from JDK. It is Optional.java that has a sea of methods to resolve these problems. Such as follow:
/**
* Returns an {@code Optional} describing the specified value, if non-null,
* otherwise returns an empty {@code Optional}.
*
* @param <T> the class of the value
* @param value the possibly-null value to describe
* @return an {@code Optional} with a present value if the specified value
* is non-null, otherwise an empty {@code Optional}
*/
public static <T> Optional<T> ofNullable(T value) {
return value == null ? empty() : of(value);
}
/**
* Return {@code true} if there is a value present, otherwise {@code false}.
*
* @return {@code true} if there is a value present, otherwise {@code false}
*/
public boolean isPresent() {
return value != null;
}
/**
* If a value is present, invoke the specified consumer with the value,
* otherwise do nothing.
*
* @param consumer block to be executed if a value is present
* @throws NullPointerException if value is present and {@code consumer} is
* null
*/
public void ifPresent(Consumer<? super T> consumer) {
if (value != null)
consumer.accept(value);
}
It is really, really useful to help javer.
The way to avoid unnecessary null-checks
is simple to state:
You need to know which variables can be null, and which cannot, and you need to be confident about which category a given variable fall into.
But, although it can be stated simply enough, achieving it is harder. The key lies in the confident
part, because how can you be sure that a variable can't be null?
There are no quick-fix, easy answers to this, but here are some pointers:
Clean code. The most important thing for being able to reason about the behaviour of a piece of code is that it is written in a matter that is easy to understand. Name your variables based on what they represent, name your methods after what they do, apply the Single responsibility principle
(the S
in SOLID
: http://en.wikipedia.org/wiki/SOLID_(object-oriented_design), it means that each piece of code should have a single responsibility, and do this and nothing else). Once your code is clean, it is much easier to reason about it, also across multiple tiers/layers of code. With messy code, trying to understand what a method does might make you forget why you are reading the method in the first place. (Tip: Read "Clean Code" by Robert C. Martin)
Avoid returning null
values. If a null
value would keep your program from functioning correctly, throw an exception
instead (make sure to add the appropriate error-handling.) Cases where returning a null
value might be acceptable is for instance trying to fetch an object from the database. In these cases, write code that handles the null
values, and make a note behind your ear that here we have something that might return null
. Handle returned null
values as close to the caller of the method returning null
as possible (don't just blindly pass it back up the call-chain.)
Never EVER pass explicit null
values as parameters (at least not across classes). If you are ever in a position where passing a null
-parameter is the only option, creating a new method that does not have this parameter is the way to go.
Validate your input! Identify the "entry-points" to your application. They can everything from webservices, REST-services, remote EJB classes, controllers, etc. For each method in these entry-points, ask yourself: "Will this method execute correctly if this parameter is null?" If the answer is no, add Validate.notNull(someParam, "Can't function when someParam is null!");
. This will throw an IllegalArgumentException
if the required parameter is missing. The good thing about this type of validation in the entry-points, is that you can then easily assume in the code being executed from the entry-point, that this variable will never be null! Also, if this fails, being at the entry-point, debugging is made a lot easier than it would if you just got a NullPointerException
deep down in your code, since a failure like this can only mean one thing: The client didn't send you all the required information. In most cases you want to validate all input parameters, if you find yourself in a position where you need to allow a lot of null
-values, it might be a sign of a badly designed interface, which needs refactoring/additions to suite the needs of the clients.
When working with Collection
s, return an empty one rather than null!
When working with a database, utilize not null
-constraints. In that way, you'll know that a value read from the database cannot be null, and you won't have to check for it.
Structure your code and stick with it. Doing this allows you to make assumptions about the behaviour of the code, for instance if all input to your application is validated, then you can assume that these values will never be null.
If you are not already doing it, write automated tests of your code. By writing tests, you will reason about your code, and you will also become more confident that it does what it's supposed to. Also, automated tests guards you from blunders during refactoring, by letting you know immediatly that this piece of code is not doing what it used to.
You still have to null-check of course, but it can trimmed down to the bare minimum (i.e. the situation where know you might be getting a null-value, instead of everywhere just to be sure.) When it comes to null-checks, i actually prefer to use the ternary operator (but use with care, when you start nesting them they come really messy.)
public String nullSafeToString(final Object o) {
return o != null ? o.toString() : "null";
}
First of all, we can't really remove all null conditions. We can reduce them using @NotNull
and @Nullable
annotations (as mentioned already). But this needs to be backed by some framework. This is where OVal can help.
The basic idea is object/parameters/constructor should always satisfy preconditions. You can have a whole lot of preconditions such as Nullable
, NotNull
and OVal would take care that an object should be in a consistent state when invoked.
I guess OVal internally uses AspectJ to validate the preconditions.
@Guarded
public class BusinessObject
{
public BusinessObject(@NotNull String name)
{
this.name = name;
}
...
}
For example,
// Throws a ConstraintsViolatedException because parameter name is null
BusinessObject bo = new BusinessObject(null);
I prefer this
public void simpleFunc(SomeObject someObject){
someObject = someObject != null ? someObject : new SomeObject(null);
someObject.doSomething();
}
Of course in my example SomeObject handles gracefully a null parameter. For example logging such event and doing nothing more.
We have been using Apache libraries (Apache Commons) for this issue.
ObjectUtils.equals(object, null)
or
CollectionUtils.isEmpty(myCollection);
or
StringUtils.isEmpty("string");
I like the previous answer before, as a practice, of providing initial default values or empty sets for collections to minimize the need.
These can be simple uses that keep you from having NullPointerException or using an empty collection. This doesnt answer the question for what to do with the null object, but these provide some checks for basic validations of the object or collection.
Hope this helps.
CollectionUtils.isEmpty
and StringUtils.isEmpty
as they also do a null check, which is not implied by the method name.
Jul 10, 2014 at 19:27
It is possible to define util methods which handles nested null-checks in an almost pretty way with Java 8 lambdas.
void example() {
Entry entry = new Entry();
// This is the same as H-MANs solution
Person person = getNullsafe(entry, e -> e.getPerson());
// Get object in several steps
String givenName = getNullsafe(entry, e -> e.getPerson(), p -> p.getName(), n -> n.getGivenName());
// Call void methods
doNullsafe(entry, e -> e.getPerson(), p -> p.getName(), n -> n.nameIt());
}
/** Return result of call to f1 with o1 if it is non-null, otherwise return null. */
public static <R, T1> R getNullsafe(T1 o1, Function<T1, R> f1) {
if (o1 != null) return f1.apply(o1);
return null;
}
public static <R, T0, T1> R getNullsafe(T0 o0, Function<T0, T1> f1, Function<T1, R> f2) {
return getNullsafe(getNullsafe(o0, f1), f2);
}
public static <R, T0, T1, T2> R getNullsafe(T0 o0, Function<T0, T1> f1, Function<T1, T2> f2, Function<T2, R> f3) {
return getNullsafe(getNullsafe(o0, f1, f2), f3);
}
/** Call consumer f1 with o1 if it is non-null, otherwise do nothing. */
public static <T1> void doNullsafe(T1 o1, Consumer<T1> f1) {
if (o1 != null) f1.accept(o1);
}
public static <T0, T1> void doNullsafe(T0 o0, Function<T0, T1> f1, Consumer<T1> f2) {
doNullsafe(getNullsafe(o0, f1), f2);
}
public static <T0, T1, T2> void doNullsafe(T0 o0, Function<T0, T1> f1, Function<T1, T2> f2, Consumer<T2> f3) {
doNullsafe(getNullsafe(o0, f1, f2), f3);
}
class Entry {
Person getPerson() { return null; }
}
class Person {
Name getName() { return null; }
}
class Name {
void nameIt() {}
String getGivenName() { return null; }
}
(This answer was first posted here.)
One Option you have
Use checker framework's @RequiresNonNull on methods. for ex you get this if you call a method annotated as such, with a null argument. It will fail during compile, even before your code runs! since at runtime it will be NullPointerException
@RequiresNonNull(value = { "#1" })
static void check( Boolean x) {
if (x) System.out.println("true");
else System.out.println("false");
}
public static void main(String[] args) {
check(null);
}
gets
[ERROR] found : null
[ERROR] required: @Initialized @NonNull Boolean
[ERROR] -> [Help 1]
There are other methods like Use Java 8's Optional, Guava Annotations, Null Object pattern etc. Does not matter as long as you obtain your goal of avoiding !=null
Objects.isNull(null)
If you are using Java8 then you can try this code.
Try using below code if you are not using Java8
Object ob=null;
if(ob==null){ **do something}
Personally, I would either go with jim-nelson's answer or if I do find a null check is convenient for a specific context I would incorporate lombok into my project and use the @NonNull annotation.
Example:
import lombok.NonNull;
public class NonNullExample extends Something {
private String name;
public NonNullExample(@NonNull Person person) {
super("Hello");
this.name = person.getName();
}
}
Even the @NonNull preface mention:
For utility classes, you can check that parameters are not null.
In all other cases, you may not have to. Use encapsulation as much as possible, thus reducing the places you feel tempted to check for null.
final
keyword and you'll live in a even better world.