24

Java 9 comes with convenience factory methods for creating immutable lists. Finally a list creation is as simple as:

List<String> list = List.of("foo", "bar");

But there are 12 overloaded versions of this method, 11 with 0 to 10 elements, and one with var args.

static <E> List<E>  of(E... elements)

Same is the case with Set and Map.

Since there is a var args method, what is the point of having extra 11 methods?

What I think is that var-args create an array, so the other 11 methods can skip creation of an extra object and in most cases 0 - 10 elements will do. Is there any other reason for this?

  • 9
    You just answered your own question already - overloading it with 0-10 arguments skips unnecessary array creations. – luk2302 Jan 29 '17 at 8:24
  • 3
    @Marco13 I am voting to reopen based on the idea that there are plenty of questions out there that transcend technologies. Also voting to reopen because given that these features are now available in java, people would search for "java 9 collection.of" more than "Guava colleciton.of". – CKing Jan 29 '17 at 15:45
  • 3
    @Marco13 I believe creating a canonical question and pointing these two questions to it as duplicates would make sense. Until we do that, I feel this question should remain open. I wouldn't want to hog on the comment space of this question for this discussion so let's see what others say. – CKing Jan 29 '17 at 16:30
  • 9
    I am voting to reopen. The justification for similar overloads in other APIs (Guava, EnumSet) was different - they provided the overloads because @SafeVarargs did not exist at the time whereas the driver for the overloads in JEP 269 was performance. – Stefan Zobel Jan 29 '17 at 17:28
  • 2
    @StefanZobel agree; especially since the general discussion point is that this is a micro-optimization to exclude the array creation and at the same time all methods (except the 2 parameters) delegate to this: @SafeVarargs @SuppressWarnings("unchecked") SetN(E... input) { – Eugene Jan 30 '17 at 21:26
26

From the JEP docs itself -

Description -

These will include varargs overloads, so that there is no fixed limit on the collection size. However, the collection instances so created may be tuned for smaller sizes. Special-case APIs (fixed-argument overloads) for up to ten of elements will be provided. While this introduces some clutter in the API, it avoids array allocation, initialization, and garbage collection overhead that is incurred by varargs calls. Significantly, the source code of the call site is the same regardless of whether a fixed-arg or varargs overload is called.


Edit - To add motivation and as already mentioned in the comments by @CKing too :

Non-Goals -

It is not a goal to support high-performance, scalable collections with arbitrary numbers of elements. The focus is on small collections.

Motivation -

Creating a small, unmodifiable collection (say, a set) involves constructing it, storing it in a local variable, and invoking add() on it several times, and then wrapping it.

Set<String> set = Collections.unmodifiableSet(new HashSet<>(Arrays.asList("a", "b", "c")));

The Java 8 Stream API can be used to construct small collections, by combining stream factory methods and collectors.

// Java 8
Set<String> set1 = Collections.unmodifiableSet(Stream.of("a", "b", "c").collect(Collectors.toSet()));

Much of the benefit of collection literals can be gained by providing library APIs for creating small collection instances, at significantly reduced cost and risk compared to changing the language. For example, the code to create a small Set instance might look like this:

// Java 9 
Set set2 = Set.of("a", "b", "c");
  • 1
    Isn't this a micro-optimization in an era of ample hardware at your disposal in a high level language such as Java? I so wish there was another reason to it but can't think of one – CKing Jan 29 '17 at 8:30
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    @CKing Yes, this is a micro-optimization. The performance criteria for the JDK libraries are much more stringent than for most applications. These APIs are used in the JDK itself, and they impact startup time, so even apparently tiny optimizations are worth it. – Stuart Marks Jan 30 '17 at 17:21
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    @StuartMarks but then they all (except the two arguments method) delegate to this: @SafeVarargs @SuppressWarnings("unchecked") SetN(E... input) { – Eugene Jan 30 '17 at 21:20
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    @Eugene Yes, that's buried within the implementation, and it can be change compatibly. It just hasn't been fully optimized yet. – Stuart Marks Jan 30 '17 at 22:47
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    @CKing The APIs are intended for general use. But we wanted to be able to use them within the JDK without sacrificing performance. Regarding general usage of the new APIs, it generally isn't necessary for source code to know or care whether it's calling a fixed-arg or varargs method. If you have Set.of(a1, a2, ... a10) and you add another arg, it ends up switching from the fixed to the varargs call, but otherwise it behaves exactly the same. So, just go ahead and use the new APIs. – Stuart Marks Jan 30 '17 at 22:53
10

As you suspected, this is a performance enhancement. Vararg methods create an array "under the hood", and having method which take 1-10 arguments directly avoids this redundant array creation.

  • 1
    Isn't this a micro-optimization in an era of ample hardware at your disposal in a high level language such as Java? I so wish there was another reason to it but can't think of one. – CKing Jan 29 '17 at 8:26
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    @CKing Language/library designers need to consider performance of their code not just in code that is run infrequently; but also what happens when someone uses it in a hot loop of a computationally intensive application. In those cases things that could otherwise be dismissed as "pointless micro-optimizations" do have significant performance impacts. – Dan Neely Jan 29 '17 at 15:35
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    @DanNeely Is that argument valid in this case? How expensive is it to create an array of 10 elements? – CKing Jan 29 '17 at 15:38
  • @CKing My interest levels don't rise to the point of writing a benchmark, but the book cited in @JuBobs answer implies that there are cases where it can become significant. My assumption would be that the impact was indirect - from additional garbage collections - rather then due to the direct time spent moving data through a temporary array. – Dan Neely Jan 29 '17 at 16:44
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    @DanNeely & @ares : Ironically, hot loops scenarios were definitely considered irrelevant for this optimization. – Stefan Zobel Jan 29 '17 at 17:44
6

You may find the following passage of item 42 of Josh Bloch's Effective Java (2nd ed.) enlightening:

Every invocation of a varargs method causes an array allocation and initialization. If you have determined empirically that you can’t afford this cost but you need the flexibility of varargs, there is a pattern that lets you have your cake and eat it too. Suppose you’ve determined that 95 percent of the calls to a method have three or fewer parameters. Then declare five overloadings of the method, one each with zero through three ordinary parameters, and a single varargs method for use when the number of arguments exceeds three [...]

  • Okay, so the implementation was copied right from the Josh Bolch's text. – ares Jan 29 '17 at 15:42
  • The most important two words to take a note of : determined emprically. Micro-optimizations most definitely require empirical proof. – CKing Jan 29 '17 at 15:47
3

You can also look at it the other way around. Since varargs methods can accept arrays, such a method would serve as an alternative means to convert an array to a List.

String []strArr = new String[]{"1","2"};
List<String> list = List.of(strArr);

The alternative to this approach is to use Arrays.asList but any changes made to the List in this case would reflect in the array which is not the case with List.of. You can therefore use List.of when you don't want the List and the array to be in sync.

Note The justification given in the spec seems like a micro-optimzation to me. (This has now been confirmed by the owner of the API himself in the comments to another answer)

  • It's like instead of the compiler creating an array for me, I'm creating one myself. – ares Jan 29 '17 at 8:36
  • @ares Think of it this way. You sometimes talk to code that returns an array. When you want to convert this array into a list, you can directly pass this to the List.of method. Also, the List and the array won't be in sync as compared to the Arrays.asList method so that's another use case for this method. – CKing Jan 29 '17 at 9:02
2

This pattern is used for optimization of methods which accept varargs parameters.

If you can figure out that the most time you're using only couple of them, you probably would like to define a method overloadings with the amount of most used parameters:

public void foo(int num1);
public void foo(int num1, int num2);
public void foo(int num1, int num2, int num3);
public void foo(int... nums);

This will help you to avoid array creation while calling varargs method. The pattern used for performance optimization:

List<String> list = List.of("foo", "bar");
// Delegates call here
static <E> List<E> of(E e1, E e2) { 
    return new ImmutableCollections.List2<>(e1, e2); // Constructor with 2 parameters, varargs avoided!
}

More interesting thing behind this is that starting from 3 parameters we are delegating to varargs constructor again:

static <E> List<E> of(E e1, E e2, E e3) { 
    return new ImmutableCollections.ListN<>(e1, e2, e3); // varargs constructor
}

This seems strange for now, but as I may guess - this is reserved for future improvements and as an option, potential overloading of all constructors List3(3 params), List7(7 params)... and etc.

-1

As per Java doc: The collections returned by the convenience factory methods are more space efficient than their mutable equivalents.

Before Java 9:

Set<String> set = new HashSet<>(3);   // 3 buckets

set.add("Hello");
set.add("World");
set = Collections.unmodifiableSet(set);

In above implementation of Set, there are 6 objects are creating : the unmodifiable wrapper; the HashSet, which contains a HashMap; the table of buckets (an array); and two Node instances (one for each element). If a VM take 12-byte per object then there are 72 bytes are consuming as overhead, plus 28*2 = 56 bytes for 2 elements. Here the large amount is consumed by overhead as compared to the data stored in collection. But in Java 9 this overhead is very less.

After Java 9:

Set<String> set = Set.of("Hello", "World");

In above implementation of Set, only one object is creating and this will take very less space to hold data due to minimal overhead.

  • 3
    While this answer might be correct, it's not relevant to the asked question. – ares Oct 3 '17 at 7:44

protected by Nilesh Rathod Apr 19 '18 at 9:07

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