Java template for checking that value was set - java

In Java I have a bunch of variables (of different types) that I would like to check that they have been set before using them, and if they have not then the result is always the same and I want to throw an error that'll be caught higher up. In theory the code is designed that this should NEVER happen, but the consequences of a bug making it happen are too great to leave it to just unit testing.
I was thinking of just making a template that has a get() and set() function. The set would set the value and set a boolean to let it know it has been set and the get() would check the boolean and return the value or throw an error. something like:
Class ImportantInfo<T> {
private T t;
private beenSet = false;
public T get(){
if(beenSet) return t;
else throw error;
}
public void set(T value){
t =value;
beenSet = true;
}
}
Is this the correct and best approach? Are there other, possibly better, ways? I worry I am over engineering the solution or that a template this straightforward might already exist in Java?

One approach to do this would be to use Java Optionals. Optionals represent a value that may or may not be present.
Optional.empty() represents a value that is not present
The .get() method gets a value if it is present
The isPresent() checks if a value has been set or not.
The main advantage of using Optional over simply checking for null is that optional forces you to use .get() so you don't accidentally call a null value that hasn't been set.
In your particular case, I would initialize all the values at the top of the class to Optional.empty() and then use .isPresent to make sure they were set.
Note: This will only work with Java 8
(Apparently Guava Optional will work in versions less than 8 (see Tom's comment - I have no experience with this)

there are many ways, but the approaches that I would normally find useful:
checking if its null, personally I just use this, if null I assume its not been set otherwise its been set, then you can also give the user the responsibilities (optional)
instead of having setter method, you can use the constructor. this way you ensure that the value has been set before even being able to use the get method.

Related

Java Optional params good practice [duplicate]

Having been using Java 8 now for 6+ months or so, I'm pretty happy with the new API changes. One area I'm still not confident in is when to use Optional. I seem to swing between wanting to use it everywhere something may be null, and nowhere at all.
There seem to be a lot of situations when I could use it, and I'm never sure if it adds benefits (readability / null safety) or just causes additional overhead.
So, I have a few examples, and I'd be interested in the community's thoughts on whether Optional is beneficial.
1 - As a public method return type when the method could return null:
public Optional<Foo> findFoo(String id);
2 - As a method parameter when the param may be null:
public Foo doSomething(String id, Optional<Bar> barOptional);
3 - As an optional member of a bean:
public class Book {
private List<Pages> pages;
private Optional<Index> index;
}
4 - In Collections:
In general I don't think:
List<Optional<Foo>>
adds anything - especially since one can use filter() to remove null values etc, but are there any good uses for Optional in collections?
Any cases I've missed?
The main design goal of Optional is to provide a means for a function returning a value to indicate the absence of a return value. See this discussion. This allows the caller to continue a chain of fluent method calls.
This most closely matches use case #1 in the OP's question. Although, absence of a value is a more precise formulation than null since something like IntStream.findFirst could never return null.
For use case #2, passing an optional argument to a method, this could be made to work, but it's rather clumsy. Suppose you have a method that takes a string followed by an optional second string. Accepting an Optional as the second arg would result in code like this:
foo("bar", Optional.of("baz"));
foo("bar", Optional.empty());
Even accepting null is nicer:
foo("bar", "baz");
foo("bar", null);
Probably the best is to have an overloaded method that accepts a single string argument and provides a default for the second:
foo("bar", "baz");
foo("bar");
This does have limitations, but it's much nicer than either of the above.
Use cases #3 and #4, having an Optional in a class field or in a data structure, is considered a misuse of the API. First, it goes against the main design goal of Optional as stated at the top. Second, it doesn't add any value.
There are three ways to deal with the absence of a value in an Optional: to provide a substitute value, to call a function to provide a substitute value, or to throw an exception. If you're storing into a field, you'd do this at initialization or assignment time. If you're adding values into a list, as the OP mentioned, you have the additional choice of simply not adding the value, thereby "flattening" out absent values.
I'm sure somebody could come up with some contrived cases where they really want to store an Optional in a field or a collection, but in general, it is best to avoid doing this.
I'm late to the game but for what it's worth, I want to add my 2 Cents. They go against the design goal of Optional, which is well summarized by Stuart Marks's answer, but I'm still convinced of their validity (obviously).
Use Optional Everywhere
In General
I wrote an entire blog post about using Optional but it basically comes down to this:
design your classes to avoid optionality wherever feasibly possible
in all remaining cases, the default should be to use Optional instead of null
possibly make exceptions for:
local variables
return values and arguments to private methods
performance critical code blocks (no guesses, use a profiler)
The first two exceptions can reduce the perceived overhead of wrapping and unwrapping references in Optional. They are chosen such that a null can never legally pass a boundary from one instance into another.
Note that this will almost never allow Optionals in collections which is almost as bad as nulls. Just don't do it. ;)
Regarding your questions
Yes.
If overloading is no option, yes.
If other approaches (subclassing, decorating, ...) are no option, yes.
Please no!
Advantages
Doing this reduces the presence of nulls in your code base, although it does not eradicate them. But that is not even the main point. There are other important advantages:
Clarifies Intent
Using Optional clearly expresses that the variable is, well, optional. Any reader of your code or consumer of your API will be beaten over the head with the fact that there might be nothing there and that a check is necessary before accessing the value.
Removes Uncertainty
Without Optional the meaning of a null occurrence is unclear. It could be a legal representation of a state (see Map.get) or an implementation error like a missing or failed initialization.
This changes dramatically with the persistent use of Optional. Here, already the occurrence of null signifies the presence of a bug. (Because if the value were allowed to be missing, an Optional would have been used.) This makes debugging a null pointer exception much easier as the question of the meaning of this null is already answered.
More Null Checks
Now that nothing can be null anymore, this can be enforced everywhere. Whether with annotations, assertions or plain checks, you never have to think about whether this argument or that return type can be null. It can't!
Disadvantages
Of course, there is no silver bullet...
Performance
Wrapping values (especially primitives) into an extra instance can degrade performance. In tight loops this might become noticeable or even worse.
Note that the compiler might be able to circumvent the extra reference for short lived lifetimes of Optionals. In Java 10 value types might further reduce or remove the penalty.
Serialization
Optional is not serializable but a workaround is not overly complicated.
Invariance
Due to the invariance of generic types in Java, certain operations become cumbersome when the actual value type is pushed into a generic type argument. An example is given here (see "Parametric polymorphism").
Personally, I prefer to use IntelliJ's Code Inspection Tool to use #NotNull and #Nullable checks as these are largely compile time (can have some runtime checks) This has lower overhead in terms of code readability and runtime performance. It is not as rigorous as using Optional, however this lack of rigour should be backed by decent unit tests.
public #Nullable Foo findFoo(#NotNull String id);
public #NotNull Foo doSomething(#NotNull String id, #Nullable Bar barOptional);
public class Book {
private List<Pages> pages;
private #Nullable Index index;
}
List<#Nullable Foo> list = ..
This works with Java 5 and no need to wrap and unwrap values. (or create wrapper objects)
I think the Guava Optional and their wiki page puts it quite well:
Besides the increase in readability that comes from giving null a name, the biggest advantage of Optional is its idiot-proof-ness. It forces you to actively think about the absent case if you want your program to compile at all, since you have to actively unwrap the Optional and address that case. Null makes it disturbingly easy to simply forget things, and though FindBugs helps, we don't think it addresses the issue nearly as well.
This is especially relevant when you're returning values that may or may not be "present." You (and others) are far more likely to forget that other.method(a, b) could return a null value than you're likely to forget that a could be null when you're implementing other.method. Returning Optional makes it impossible for callers to forget that case, since they have to unwrap the object themselves for their code to compile.
-- (Source: Guava Wiki - Using and Avoiding null - What's the point?)
Optional adds some overhead, but I think its clear advantage is to make it explicit
that an object might be absent and it enforces that programmers handle the situation. It prevents that someone forgets the beloved != null check.
Taking the example of 2, I think it is far more explicit code to write:
if(soundcard.isPresent()){
System.out.println(soundcard.get());
}
than
if(soundcard != null){
System.out.println(soundcard);
}
For me, the Optional better captures the fact that there is no soundcard present.
My 2¢ about your points:
public Optional<Foo> findFoo(String id); - I am not sure about this. Maybe I would return a Result<Foo> which might be empty or contain a Foo. It is a similar concept, but not really an Optional.
public Foo doSomething(String id, Optional<Bar> barOptional); - I would prefer #Nullable and a findbugs check, as in Peter Lawrey's answer - see also this discussion.
Your book example - I am not sure if I would use the Optional internally, that might depend on the complexity. For the "API" of a book, I would use an Optional<Index> getIndex() to explicitly indicate that the book might not have an index.
I would not use it in collections, rather not allowing null values in collections
In general, I would try to minimize passing around nulls. (Once burnt...)
I think it is worth to find the appropriate abstractions and indicate to the fellow programmers what a certain return value actually represents.
From Oracle tutorial:
The purpose of Optional is not to replace every single null reference in your codebase but rather to help design better APIs in which—just by reading the signature of a method—users can tell whether to expect an optional value. In addition, Optional forces you to actively unwrap an Optional to deal with the absence of a value; as a result, you protect your code against unintended null pointer exceptions.
In java, just don't use them unless you are addicted to functional programming.
They have no place as method arguments (I promess someone one day will pass you a null optional, not just an optional that is empty).
They make sense for return values but they invite the client class to keep on stretching the behavior-building chain.
FP and chains have little place in an imperative language like java because it makes it very hard to debug, not just to read. When you step to the line, you can't know the state nor intent of the program; you have to step into to figure it out (into code that often isn't yours and many stack frames deep despite step filters) and you have to add lots of breakpoints down to make sure it can stop in the code/lambda you added, instead of simply walking the if/else/call trivial lines.
If you want functional programming, pick something else than java and hope you have the tools for debugging that.
1 - As a public method return type when the method could return null:
Here is a good article that shows usefulness of usecase #1. There this code
...
if (user != null) {
Address address = user.getAddress();
if (address != null) {
Country country = address.getCountry();
if (country != null) {
String isocode = country.getIsocode();
isocode = isocode.toUpperCase();
}
}
}
...
is transformed to this
String result = Optional.ofNullable(user)
.flatMap(User::getAddress)
.flatMap(Address::getCountry)
.map(Country::getIsocode)
.orElse("default");
by using Optional as a return value of respective getter methods.
Here is an interesting usage (I believe) for... Tests.
I intend to heavily test one of my projects and I therefore build assertions; only there are things I have to verify and others I don't.
I therefore build things to assert and use an assert to verify them, like this:
public final class NodeDescriptor<V>
{
private final Optional<String> label;
private final List<NodeDescriptor<V>> children;
private NodeDescriptor(final Builder<V> builder)
{
label = Optional.fromNullable(builder.label);
final ImmutableList.Builder<NodeDescriptor<V>> listBuilder
= ImmutableList.builder();
for (final Builder<V> element: builder.children)
listBuilder.add(element.build());
children = listBuilder.build();
}
public static <E> Builder<E> newBuilder()
{
return new Builder<E>();
}
public void verify(#Nonnull final Node<V> node)
{
final NodeAssert<V> nodeAssert = new NodeAssert<V>(node);
nodeAssert.hasLabel(label);
}
public static final class Builder<V>
{
private String label;
private final List<Builder<V>> children = Lists.newArrayList();
private Builder()
{
}
public Builder<V> withLabel(#Nonnull final String label)
{
this.label = Preconditions.checkNotNull(label);
return this;
}
public Builder<V> withChildNode(#Nonnull final Builder<V> child)
{
Preconditions.checkNotNull(child);
children.add(child);
return this;
}
public NodeDescriptor<V> build()
{
return new NodeDescriptor<V>(this);
}
}
}
In the NodeAssert class, I do this:
public final class NodeAssert<V>
extends AbstractAssert<NodeAssert<V>, Node<V>>
{
NodeAssert(final Node<V> actual)
{
super(Preconditions.checkNotNull(actual), NodeAssert.class);
}
private NodeAssert<V> hasLabel(final String label)
{
final String thisLabel = actual.getLabel();
assertThat(thisLabel).overridingErrorMessage(
"node's label is null! I didn't expect it to be"
).isNotNull();
assertThat(thisLabel).overridingErrorMessage(
"node's label is not what was expected!\n"
+ "Expected: '%s'\nActual : '%s'\n", label, thisLabel
).isEqualTo(label);
return this;
}
NodeAssert<V> hasLabel(#Nonnull final Optional<String> label)
{
return label.isPresent() ? hasLabel(label.get()) : this;
}
}
Which means the assert really only triggers if I want to check the label!
Optional class lets you avoid to use null and provide a better alternative:
This encourages the developer to make checks for presence in order to avoid uncaught NullPointerException's.
API becomes better documented because it's possible to see, where to expect the values which can be absent.
Optional provides convenient API for further work with the object:
isPresent(); get(); orElse(); orElseGet(); orElseThrow(); map(); filter(); flatmap().
In addition, many frameworks actively use this data type and return it from their API.
An Optional has similar semantics to an unmodifiable instance of the Iterator design pattern:
it might or might not refer to an object (as given by isPresent())
it can be dereferenced (using get()) if it does refer to an object
but it can not be advanced to the next position in the sequence (it has no next() method).
Therefore consider returning or passing an Optional in contexts where you might previously have considered using a Java Iterator.
Here are some of the methods that you can perform on an instance of Optional<T>:
map
flatMap
orElse
orElseThrow
ifPresentOrElse
get
Here are all the methods that you can perform on null:
(there are none)
This is really an apples to oranges comparison: Optional<T> is an actual instance of an object (unless it is null… but that would probably be a bug) while null is an aborted object. All you can do with null is check whether it is in fact null, or not. So if you like to use methods on objects, Optional<T> is for you; if you like to branch on special literals, null is for you.
null does not compose. You simply can’t compose a value which you can only branch on. But Optional<T> does compose.
You can, for instance, make arbitrary long chains of “apply this function if non-empty” by using map. Or you can effectively make an imperative block of code which consumes the optional if it is non-empty by using ifPresent. Or you can make an “if/else” by using ifPresentOrElse, which consumes the non-empty optional if it is non-empty or else executes some other code.
…And it is at this point that we run into the true limitations of the language in my opinion: for very imperative code you have to wrap them in lambdas and pass them to methods:
opt.ifPresentOrElse(
string -> { // if present...
// ...
}, () -> { // or else...
// ...
}
);
That might not be good enough for some people, style-wise.
It would be more seamless if Optional<T> was an algebraic data type that we could pattern match on (this is obviously pseudo-code:
match (opt) {
Present(str) => {
// ...
}
Empty =>{
// ...
}
}
But anyway, in summary: Optional<T> is a pretty robust empty-or-present object. null is just a sentinel value.
Subjectively disregarded reasons
There seems to be a few people who effectively argue that efficiency should determine whether one should use Optional<T> or branch on the null sentinel value. That seems a bit like making hard and fast rules on when to make objects rather than primitives in the general case. I think it’s a bit ridiculous to use that as the starting point for this discussion when you’re already working in a language where it’s idiomatic to make objects left-and-right, top to bottom, all the time (in my opinion).
I do not think that Optional is a general substitute for methods that potentially return null values.
The basic idea is: The absence of a value does not mean that it potentially is available in the future. It's a difference between findById(-1) and findById(67).
The main information of Optionals for the caller is that he may not count on the value given but it may be available at some time. Maybe it will disappear again and comes back later one more time. It's like an on/off switch. You have the "option" to switch the light on or off. But you have no option if you do not have a light to switch on.
So I find it too messy to introduce Optionals everywhere where previously null was potentially returned. I will still use null, but only in restricted areas like the root of a tree, lazy initialization and explicit find-methods.
Seems Optional is only useful if the type T in Optional is a primitive type like int, long, char, etc. For "real" classes, it does not make sense to me as you can use a null value anyway.
I think it was taken from here (or from another similar language concept).
Nullable<T>
In C# this Nullable<T> was introduced long ago to wrap value types.
1 - As a public method return type when the method could return null:
This is the intended use case for Optional, as seen in the JDK API docs:
Optional is primarily intended for use as a method return type where
there is a clear need to represent "no result," and where using null
is likely to cause errors.
Optional represents one of two states:
it has a value (isPresent returns true)
it doesn't have a value (isEmpty returns true)
So if you have a method that returns either something or nothing, this is the ideal use case for Optional.
Here's an example:
Optional<Guitarist> findByLastName(String lastName);
This method takes a parameter used to search for an entity in the database. It's possible that no such entity exists, so using an Optional return type is a good idea since it forces whoever is calling the method to consider the empty scenario. This reduces chances of a NullPointerException.
2 - As a method parameter when the param may be null:
Although technically possible, this is not the intended use case of Optional.
Let's consider your proposed method signature:
public Foo doSomething(String id, Optional<Bar> barOptional);
The main problem is that we could call doSomething where barOptional has one of 3 states:
an Optional with a value e.g. doSomething("123", Optional.of(new Bar())
an empty Optional e.g. doSomething("123", Optional.empty())
null e.g. doSomething("123", null)
These 3 states would need to be handled in the method implementation appropriately.
A better solution is to implement an overloaded method.
public Foo doSomething(String id);
public Foo doSomething(String id, Bar bar);
This makes it very clear to the consumer of the API which method to call, and null does not need to be passed.
3 - As an optional member of a bean:
Given your example Book class:
public class Book {
private List<Pages> pages;
private Optional<Index> index;
}
The Optional class variable suffers from the same issue as the Optional method parameter discussed above. It can have one of 3 states: present, empty, or null.
Other possible issues include:
serialization: if you implement Serializable and try to serialize an object of this class, you will encounter a java.io.NotSerializableException since Optional was not designed for this use case
transforming to JSON: when serializing to JSON an Optional field may get mapped in an undesirable way e.g. {"empty":false,"present":true}.
Although if you use the popular Jackson library, it does provide a solution to this problem.
Despite these issues, Oracle themselves published this blog post at the time of the Java 8 Optional release in 2014. It contains code examples using Optional for class variables.
public class Computer {
private Optional<Soundcard> soundcard;
public Optional<Soundcard> getSoundcard() { ... }
...
}
In the following years though, developers have found better alternatives such as implementing a getter method to create the Optional object.
public class Book {
private List<Pages> pages;
private Index index;
public Optional<Index> getIndex() {
return Optional.ofNullable(index);
}
}
Here we use the ofNullable method to return an Optional with a value if index is non-null, or otherwise an empty Optional.
4 - In Collections:
I agree that creating a List of Optional (e.g. List<Optional<Foo>>) doesn't add anything.
Instead, just don't include the item in the List if it's not present.

How to safely handle Java's wrapped primitives

I'm writing a program which needs to handle objects with many wrapped number variables such as Long, Double, Integer etc. How can I safely perform numeric operations on these without having to put null-checks everywhere?
I expect this is something that pretty much every Java programmer must deal with sooner or later, so I'm quite surprised that there aren't hundreds of blog posts and SO questions on the topic.
My current solution is to filter all the numbers trough a method like this:
private static safelyUnbox(Integer i) {
return i == null ? 0 : i.intValue();
}
...
sumVariable += safelyUnbox(stupidObject.getNumberOfWhatever());
Java 8 provides a good alternative to checking against null. If an Integer (for example) might or might not have a value then you can declare it as Optional<Integer>. The Optional class has plenty of useful utilities for returning default values, throwing exceptions, checking if the value is present etc.
The advantage of declaring Optional<Integer> is that you are making completely clear to the reader that 'no value' is a legitimate state. Anyone maintaining your code has no choice but to use the Optional methods to decide what happens if the value is present or absent.
If, on the other hand, the argument is mandatory then the simplest option is to just assert that it is not null before using it.
The great advantage (in my view) of using Optional whenever a value might not be present is that you can start relying in your code on the assumption that null is always an error.
Optional even provides a neat way of converting a potentially null variable to an Optional (for example, if it's passed to you and you have no control over its value on entry to your code). It works like this:
Optional<Integer> optVal = Optional.ofNullable(val);
You can then use the new variable in the same way as any other Optional. For example:
optVal.ifPresent(myList::add);
Or:
return optVal.orElse(27);
You have a very specific issue and are trying to generalize it without thinking about it.
It could a precondition that null values are not valid. In your case, you state in your comments that it is not. But if it were, you should handle that instead of hidding it.
The "safe" value may differ. You chose 0 because you are adding up the numbers, what if you were multiplying (or using it as a quotient)? This is a knowledge your safelyUnbox method does not have.
Avoid generalizing everything. For your case, the best code is as simple as:
for(Integer integ : myCollection) {
if (integ != null) {
sum += integ;
}
}
Every other situation will have its own, most appropiate solution. Compare that with
for(Integer integ : myCollection) {
sum += safeUnboxThatDefaultsto0(integ);
}
or
for(Integer integ : myCollection) {
sum += safeUnbox(integ, 0);
}
What are you winning by using the method?
You can use Google's Guava Library Using and avoiding null
Optional<Integer> possible = Optional.of(5);
possible.isPresent(); // returns true
possible.get(); // returns 5
The biggest advantage of Optional isn't in readability: the advantage is its idiot-proof-ness. It forces you to actively think about the absent case if you want your program to compile at all, since you have to actively unwrap the Optional and address that case. Null makes it disturbingly easy to simply forget things .
Suppose this case :
String meterReading=getValueFromRemoteSite();
System.out.println(meterReading.toLowerCase()); //Chances for NPE
but using Optional scenario is diffrent
Optional meterReading = Optional.of(getValueFromRemoteSite(););
if( meterReading.isPresent() )
{
System.out.println( meterReading.get() );
}

Uses for Optional

Having been using Java 8 now for 6+ months or so, I'm pretty happy with the new API changes. One area I'm still not confident in is when to use Optional. I seem to swing between wanting to use it everywhere something may be null, and nowhere at all.
There seem to be a lot of situations when I could use it, and I'm never sure if it adds benefits (readability / null safety) or just causes additional overhead.
So, I have a few examples, and I'd be interested in the community's thoughts on whether Optional is beneficial.
1 - As a public method return type when the method could return null:
public Optional<Foo> findFoo(String id);
2 - As a method parameter when the param may be null:
public Foo doSomething(String id, Optional<Bar> barOptional);
3 - As an optional member of a bean:
public class Book {
private List<Pages> pages;
private Optional<Index> index;
}
4 - In Collections:
In general I don't think:
List<Optional<Foo>>
adds anything - especially since one can use filter() to remove null values etc, but are there any good uses for Optional in collections?
Any cases I've missed?
The main design goal of Optional is to provide a means for a function returning a value to indicate the absence of a return value. See this discussion. This allows the caller to continue a chain of fluent method calls.
This most closely matches use case #1 in the OP's question. Although, absence of a value is a more precise formulation than null since something like IntStream.findFirst could never return null.
For use case #2, passing an optional argument to a method, this could be made to work, but it's rather clumsy. Suppose you have a method that takes a string followed by an optional second string. Accepting an Optional as the second arg would result in code like this:
foo("bar", Optional.of("baz"));
foo("bar", Optional.empty());
Even accepting null is nicer:
foo("bar", "baz");
foo("bar", null);
Probably the best is to have an overloaded method that accepts a single string argument and provides a default for the second:
foo("bar", "baz");
foo("bar");
This does have limitations, but it's much nicer than either of the above.
Use cases #3 and #4, having an Optional in a class field or in a data structure, is considered a misuse of the API. First, it goes against the main design goal of Optional as stated at the top. Second, it doesn't add any value.
There are three ways to deal with the absence of a value in an Optional: to provide a substitute value, to call a function to provide a substitute value, or to throw an exception. If you're storing into a field, you'd do this at initialization or assignment time. If you're adding values into a list, as the OP mentioned, you have the additional choice of simply not adding the value, thereby "flattening" out absent values.
I'm sure somebody could come up with some contrived cases where they really want to store an Optional in a field or a collection, but in general, it is best to avoid doing this.
I'm late to the game but for what it's worth, I want to add my 2 Cents. They go against the design goal of Optional, which is well summarized by Stuart Marks's answer, but I'm still convinced of their validity (obviously).
Use Optional Everywhere
In General
I wrote an entire blog post about using Optional but it basically comes down to this:
design your classes to avoid optionality wherever feasibly possible
in all remaining cases, the default should be to use Optional instead of null
possibly make exceptions for:
local variables
return values and arguments to private methods
performance critical code blocks (no guesses, use a profiler)
The first two exceptions can reduce the perceived overhead of wrapping and unwrapping references in Optional. They are chosen such that a null can never legally pass a boundary from one instance into another.
Note that this will almost never allow Optionals in collections which is almost as bad as nulls. Just don't do it. ;)
Regarding your questions
Yes.
If overloading is no option, yes.
If other approaches (subclassing, decorating, ...) are no option, yes.
Please no!
Advantages
Doing this reduces the presence of nulls in your code base, although it does not eradicate them. But that is not even the main point. There are other important advantages:
Clarifies Intent
Using Optional clearly expresses that the variable is, well, optional. Any reader of your code or consumer of your API will be beaten over the head with the fact that there might be nothing there and that a check is necessary before accessing the value.
Removes Uncertainty
Without Optional the meaning of a null occurrence is unclear. It could be a legal representation of a state (see Map.get) or an implementation error like a missing or failed initialization.
This changes dramatically with the persistent use of Optional. Here, already the occurrence of null signifies the presence of a bug. (Because if the value were allowed to be missing, an Optional would have been used.) This makes debugging a null pointer exception much easier as the question of the meaning of this null is already answered.
More Null Checks
Now that nothing can be null anymore, this can be enforced everywhere. Whether with annotations, assertions or plain checks, you never have to think about whether this argument or that return type can be null. It can't!
Disadvantages
Of course, there is no silver bullet...
Performance
Wrapping values (especially primitives) into an extra instance can degrade performance. In tight loops this might become noticeable or even worse.
Note that the compiler might be able to circumvent the extra reference for short lived lifetimes of Optionals. In Java 10 value types might further reduce or remove the penalty.
Serialization
Optional is not serializable but a workaround is not overly complicated.
Invariance
Due to the invariance of generic types in Java, certain operations become cumbersome when the actual value type is pushed into a generic type argument. An example is given here (see "Parametric polymorphism").
Personally, I prefer to use IntelliJ's Code Inspection Tool to use #NotNull and #Nullable checks as these are largely compile time (can have some runtime checks) This has lower overhead in terms of code readability and runtime performance. It is not as rigorous as using Optional, however this lack of rigour should be backed by decent unit tests.
public #Nullable Foo findFoo(#NotNull String id);
public #NotNull Foo doSomething(#NotNull String id, #Nullable Bar barOptional);
public class Book {
private List<Pages> pages;
private #Nullable Index index;
}
List<#Nullable Foo> list = ..
This works with Java 5 and no need to wrap and unwrap values. (or create wrapper objects)
I think the Guava Optional and their wiki page puts it quite well:
Besides the increase in readability that comes from giving null a name, the biggest advantage of Optional is its idiot-proof-ness. It forces you to actively think about the absent case if you want your program to compile at all, since you have to actively unwrap the Optional and address that case. Null makes it disturbingly easy to simply forget things, and though FindBugs helps, we don't think it addresses the issue nearly as well.
This is especially relevant when you're returning values that may or may not be "present." You (and others) are far more likely to forget that other.method(a, b) could return a null value than you're likely to forget that a could be null when you're implementing other.method. Returning Optional makes it impossible for callers to forget that case, since they have to unwrap the object themselves for their code to compile.
-- (Source: Guava Wiki - Using and Avoiding null - What's the point?)
Optional adds some overhead, but I think its clear advantage is to make it explicit
that an object might be absent and it enforces that programmers handle the situation. It prevents that someone forgets the beloved != null check.
Taking the example of 2, I think it is far more explicit code to write:
if(soundcard.isPresent()){
System.out.println(soundcard.get());
}
than
if(soundcard != null){
System.out.println(soundcard);
}
For me, the Optional better captures the fact that there is no soundcard present.
My 2¢ about your points:
public Optional<Foo> findFoo(String id); - I am not sure about this. Maybe I would return a Result<Foo> which might be empty or contain a Foo. It is a similar concept, but not really an Optional.
public Foo doSomething(String id, Optional<Bar> barOptional); - I would prefer #Nullable and a findbugs check, as in Peter Lawrey's answer - see also this discussion.
Your book example - I am not sure if I would use the Optional internally, that might depend on the complexity. For the "API" of a book, I would use an Optional<Index> getIndex() to explicitly indicate that the book might not have an index.
I would not use it in collections, rather not allowing null values in collections
In general, I would try to minimize passing around nulls. (Once burnt...)
I think it is worth to find the appropriate abstractions and indicate to the fellow programmers what a certain return value actually represents.
From Oracle tutorial:
The purpose of Optional is not to replace every single null reference in your codebase but rather to help design better APIs in which—just by reading the signature of a method—users can tell whether to expect an optional value. In addition, Optional forces you to actively unwrap an Optional to deal with the absence of a value; as a result, you protect your code against unintended null pointer exceptions.
In java, just don't use them unless you are addicted to functional programming.
They have no place as method arguments (I promess someone one day will pass you a null optional, not just an optional that is empty).
They make sense for return values but they invite the client class to keep on stretching the behavior-building chain.
FP and chains have little place in an imperative language like java because it makes it very hard to debug, not just to read. When you step to the line, you can't know the state nor intent of the program; you have to step into to figure it out (into code that often isn't yours and many stack frames deep despite step filters) and you have to add lots of breakpoints down to make sure it can stop in the code/lambda you added, instead of simply walking the if/else/call trivial lines.
If you want functional programming, pick something else than java and hope you have the tools for debugging that.
1 - As a public method return type when the method could return null:
Here is a good article that shows usefulness of usecase #1. There this code
...
if (user != null) {
Address address = user.getAddress();
if (address != null) {
Country country = address.getCountry();
if (country != null) {
String isocode = country.getIsocode();
isocode = isocode.toUpperCase();
}
}
}
...
is transformed to this
String result = Optional.ofNullable(user)
.flatMap(User::getAddress)
.flatMap(Address::getCountry)
.map(Country::getIsocode)
.orElse("default");
by using Optional as a return value of respective getter methods.
Here is an interesting usage (I believe) for... Tests.
I intend to heavily test one of my projects and I therefore build assertions; only there are things I have to verify and others I don't.
I therefore build things to assert and use an assert to verify them, like this:
public final class NodeDescriptor<V>
{
private final Optional<String> label;
private final List<NodeDescriptor<V>> children;
private NodeDescriptor(final Builder<V> builder)
{
label = Optional.fromNullable(builder.label);
final ImmutableList.Builder<NodeDescriptor<V>> listBuilder
= ImmutableList.builder();
for (final Builder<V> element: builder.children)
listBuilder.add(element.build());
children = listBuilder.build();
}
public static <E> Builder<E> newBuilder()
{
return new Builder<E>();
}
public void verify(#Nonnull final Node<V> node)
{
final NodeAssert<V> nodeAssert = new NodeAssert<V>(node);
nodeAssert.hasLabel(label);
}
public static final class Builder<V>
{
private String label;
private final List<Builder<V>> children = Lists.newArrayList();
private Builder()
{
}
public Builder<V> withLabel(#Nonnull final String label)
{
this.label = Preconditions.checkNotNull(label);
return this;
}
public Builder<V> withChildNode(#Nonnull final Builder<V> child)
{
Preconditions.checkNotNull(child);
children.add(child);
return this;
}
public NodeDescriptor<V> build()
{
return new NodeDescriptor<V>(this);
}
}
}
In the NodeAssert class, I do this:
public final class NodeAssert<V>
extends AbstractAssert<NodeAssert<V>, Node<V>>
{
NodeAssert(final Node<V> actual)
{
super(Preconditions.checkNotNull(actual), NodeAssert.class);
}
private NodeAssert<V> hasLabel(final String label)
{
final String thisLabel = actual.getLabel();
assertThat(thisLabel).overridingErrorMessage(
"node's label is null! I didn't expect it to be"
).isNotNull();
assertThat(thisLabel).overridingErrorMessage(
"node's label is not what was expected!\n"
+ "Expected: '%s'\nActual : '%s'\n", label, thisLabel
).isEqualTo(label);
return this;
}
NodeAssert<V> hasLabel(#Nonnull final Optional<String> label)
{
return label.isPresent() ? hasLabel(label.get()) : this;
}
}
Which means the assert really only triggers if I want to check the label!
Optional class lets you avoid to use null and provide a better alternative:
This encourages the developer to make checks for presence in order to avoid uncaught NullPointerException's.
API becomes better documented because it's possible to see, where to expect the values which can be absent.
Optional provides convenient API for further work with the object:
isPresent(); get(); orElse(); orElseGet(); orElseThrow(); map(); filter(); flatmap().
In addition, many frameworks actively use this data type and return it from their API.
An Optional has similar semantics to an unmodifiable instance of the Iterator design pattern:
it might or might not refer to an object (as given by isPresent())
it can be dereferenced (using get()) if it does refer to an object
but it can not be advanced to the next position in the sequence (it has no next() method).
Therefore consider returning or passing an Optional in contexts where you might previously have considered using a Java Iterator.
Here are some of the methods that you can perform on an instance of Optional<T>:
map
flatMap
orElse
orElseThrow
ifPresentOrElse
get
Here are all the methods that you can perform on null:
(there are none)
This is really an apples to oranges comparison: Optional<T> is an actual instance of an object (unless it is null… but that would probably be a bug) while null is an aborted object. All you can do with null is check whether it is in fact null, or not. So if you like to use methods on objects, Optional<T> is for you; if you like to branch on special literals, null is for you.
null does not compose. You simply can’t compose a value which you can only branch on. But Optional<T> does compose.
You can, for instance, make arbitrary long chains of “apply this function if non-empty” by using map. Or you can effectively make an imperative block of code which consumes the optional if it is non-empty by using ifPresent. Or you can make an “if/else” by using ifPresentOrElse, which consumes the non-empty optional if it is non-empty or else executes some other code.
…And it is at this point that we run into the true limitations of the language in my opinion: for very imperative code you have to wrap them in lambdas and pass them to methods:
opt.ifPresentOrElse(
string -> { // if present...
// ...
}, () -> { // or else...
// ...
}
);
That might not be good enough for some people, style-wise.
It would be more seamless if Optional<T> was an algebraic data type that we could pattern match on (this is obviously pseudo-code:
match (opt) {
Present(str) => {
// ...
}
Empty =>{
// ...
}
}
But anyway, in summary: Optional<T> is a pretty robust empty-or-present object. null is just a sentinel value.
Subjectively disregarded reasons
There seems to be a few people who effectively argue that efficiency should determine whether one should use Optional<T> or branch on the null sentinel value. That seems a bit like making hard and fast rules on when to make objects rather than primitives in the general case. I think it’s a bit ridiculous to use that as the starting point for this discussion when you’re already working in a language where it’s idiomatic to make objects left-and-right, top to bottom, all the time (in my opinion).
I do not think that Optional is a general substitute for methods that potentially return null values.
The basic idea is: The absence of a value does not mean that it potentially is available in the future. It's a difference between findById(-1) and findById(67).
The main information of Optionals for the caller is that he may not count on the value given but it may be available at some time. Maybe it will disappear again and comes back later one more time. It's like an on/off switch. You have the "option" to switch the light on or off. But you have no option if you do not have a light to switch on.
So I find it too messy to introduce Optionals everywhere where previously null was potentially returned. I will still use null, but only in restricted areas like the root of a tree, lazy initialization and explicit find-methods.
Seems Optional is only useful if the type T in Optional is a primitive type like int, long, char, etc. For "real" classes, it does not make sense to me as you can use a null value anyway.
I think it was taken from here (or from another similar language concept).
Nullable<T>
In C# this Nullable<T> was introduced long ago to wrap value types.
1 - As a public method return type when the method could return null:
This is the intended use case for Optional, as seen in the JDK API docs:
Optional is primarily intended for use as a method return type where
there is a clear need to represent "no result," and where using null
is likely to cause errors.
Optional represents one of two states:
it has a value (isPresent returns true)
it doesn't have a value (isEmpty returns true)
So if you have a method that returns either something or nothing, this is the ideal use case for Optional.
Here's an example:
Optional<Guitarist> findByLastName(String lastName);
This method takes a parameter used to search for an entity in the database. It's possible that no such entity exists, so using an Optional return type is a good idea since it forces whoever is calling the method to consider the empty scenario. This reduces chances of a NullPointerException.
2 - As a method parameter when the param may be null:
Although technically possible, this is not the intended use case of Optional.
Let's consider your proposed method signature:
public Foo doSomething(String id, Optional<Bar> barOptional);
The main problem is that we could call doSomething where barOptional has one of 3 states:
an Optional with a value e.g. doSomething("123", Optional.of(new Bar())
an empty Optional e.g. doSomething("123", Optional.empty())
null e.g. doSomething("123", null)
These 3 states would need to be handled in the method implementation appropriately.
A better solution is to implement an overloaded method.
public Foo doSomething(String id);
public Foo doSomething(String id, Bar bar);
This makes it very clear to the consumer of the API which method to call, and null does not need to be passed.
3 - As an optional member of a bean:
Given your example Book class:
public class Book {
private List<Pages> pages;
private Optional<Index> index;
}
The Optional class variable suffers from the same issue as the Optional method parameter discussed above. It can have one of 3 states: present, empty, or null.
Other possible issues include:
serialization: if you implement Serializable and try to serialize an object of this class, you will encounter a java.io.NotSerializableException since Optional was not designed for this use case
transforming to JSON: when serializing to JSON an Optional field may get mapped in an undesirable way e.g. {"empty":false,"present":true}.
Although if you use the popular Jackson library, it does provide a solution to this problem.
Despite these issues, Oracle themselves published this blog post at the time of the Java 8 Optional release in 2014. It contains code examples using Optional for class variables.
public class Computer {
private Optional<Soundcard> soundcard;
public Optional<Soundcard> getSoundcard() { ... }
...
}
In the following years though, developers have found better alternatives such as implementing a getter method to create the Optional object.
public class Book {
private List<Pages> pages;
private Index index;
public Optional<Index> getIndex() {
return Optional.ofNullable(index);
}
}
Here we use the ofNullable method to return an Optional with a value if index is non-null, or otherwise an empty Optional.
4 - In Collections:
I agree that creating a List of Optional (e.g. List<Optional<Foo>>) doesn't add anything.
Instead, just don't include the item in the List if it's not present.

Non-Void Method invoking without assigning return value

I tend to think that most of the time that variable returning methods are invoked to assign the return value to a variable, e.g.:
return1 = object.DoSomething();
Nevertheless, Apart from executing the method: What happens when a returning method is invoked and the return value is not assigned to a variable? e.g:
object.DoSomething();
Is this a good practice? Where does the return goes?
JB Nizet made a remarkable comment stating that methods are implemented for most cases. Kind of explains why this situation occurs often.
People do it all the time. If you don't need the variable that the method returns, than you don't have to assign it to anything.
Bear in mind, that sometimes the return variable has some meaning, like whether or not the operation was successful, and you might want to do something with that information
I think this is valid. Unless you have a need to use the return value further down, it is better to ignore (You can save from code review tools flag as un-used variables).
Method execution and flow stays same, only thing is you are ignoring return value.
It is good practice or not depends on situation, for example if you have requirement like how many rows update on executing query, you need to capture return value, but most of the times developers ignore this because they don't need to track how many records were updated.
The method is invoked in the same fashion as it would when the return value is assigned to a variable.
This is a perfectly acceptable practice, and is a necessity when invoking void methods, which do not return values (and therefore cannot be assigned to objects).
- Its always better to use void as a return type where you don't want to assign or use the returned value.
- It won't cause any problem in its efficiency but will be considered as loose programming.
That code will compile and run perfectly normal.

how to return two values(1.Collection, 2.Single Boolean value) from a method in java with less expense?

I have one Main class and VOCollection Class.
in main class there is a method called getStatus(), from this method only i am getting some status(true,false), if the status is true, i need to return a collection.
at present i have two ideas, but both are expensive.
return map, it's expensive because setting Boolean for collection make confusion in code, and only one Boolean value is enough (but we are returning multiple).
creating an instance variable in VOCollection class, and having getter & setter to get & set the Boolean value. this is also expensive. (creating a variable in another class).
give me less expensive solution.
There are a number of ways to do this:
Return null to indicate that there is nothing present like java.util.Map.get()
Create a custom class to return both parameters. (See other answer)
Use a 1 element array for one of the return values.
boolean method(List[] result) {
result[0] = answer;
return flag;
}
Use a library like Google Guava that has a Pair/Tuple class:
Pair method() {
return new Pair(flag, answer);
}
Change your code so that it isn't necesssary, this is usually the right answer. See the exception comment or change the way things are passed around.
The desire to return either an object or a boolean is smelly. You see this kind of "flag" very often in code of starters who don't fully understand how to handle exceptional or "nothing" outcomes.
If the boolean represents an exception, just let it go or rethrow it in another exception. E.g. IllegalArgumentException, IllegalStateException, UnsupportedOperationException, etc depending on the functional requirement. You can put the calling code in a try-catch and handle it accordingly.
Or if the boolean represents a state of "nothing", just return null or an empty collection. You can handle it by testing the return value after calling the method.
You can introduce an class like this
class StatusResult
{
public final bool status;
public final VOCollection result;
...
}
and change the signature of getStatus() to
StatusResult getStatus()
I have come across the same situation in my past.
Both the solutions which you have mentioned are feasible as you said they may be expensive.
In fact, Java doesnot support the multiple return values from a method.
Solution Which I implemented was
I will try to parse/create/encode the string in such a way, after decoding i should be able to know what i need to do.
In your case, I would have choosen the following path
Create a string like returnValue, let that string start with either 0 or 1, if its 1 its true, else false.
and append the second return value to that.
For example you are trying to return like "returnValue1" and "true"
for true let us keep it 1 and for false lets keep it 2
when you do this, your return value will become "1returnValue1"
Simply return the collection when 'status is true'. Otherwise return null.
But:
Getting a collection with calling a method named "getStatus()" is not what I would expect.
"getStatus()" sounds getting some constant value indicating internal state. (like enum constant, int status code whatever)
In your scenario I would recommend having one method returning a boolean indicating that "i have something or not" and another method returning the collection - that what you have or null when not.
The boolean-method can then be easy implemented by calling the collection-method checking != null.
public boolean isXyz() {
return getXyz() != null;
}
public Collection getXyz() {
return yourCollection; //maybe null
}
The simplest approach may be to always return a VOCollection. For the situation where there is no data you could return a collection with no data i.e. isEmpty() is true, or a collection which has a flag (but I prefer the first option).
To avoid creating an object each time, create a single instance of an immutable VOCollection with no entries. This is what you can return when you have no data.

Categories