I want to sum a list of Integers. It works as follows, but the syntax does not feel right. Could the code be optimized?
Map<String, Integer> integers;
integers.values().stream().mapToInt(i -> i).sum();
I want to sum a list of Integers. It works as follows, but the syntax does not feel right. Could the code be optimized?
Map<String, Integer> integers;
integers.values().stream().mapToInt(i -> i).sum();
This will work, but the i -> i
is doing some automatic unboxing which is why it "feels" strange. mapToInt
converts the stream to an IntStream
"of primitive int-valued elements". Either of the following will work and better explain what the compiler is doing under the hood with your original syntax:
integers.values().stream().mapToInt(i -> i.intValue()).sum();
integers.values().stream().mapToInt(Integer::intValue).sum();
BigDecimal sum = numbers.stream().reduce(BigDecimal.ZERO, BigDecimal::add);
I suggest 2 more options:
integers.values().stream().mapToInt(Integer::intValue).sum();
integers.values().stream().collect(Collectors.summingInt(Integer::intValue));
The second one uses Collectors.summingInt()
collector, there is also a summingLong()
collector which you would use with mapToLong
.
And a third option: Java 8 introduces a very effective LongAdder
accumulator designed to speed-up summarizing in parallel streams and multi-thread environments. Here, here's an example use:
LongAdder a = new LongAdder();
map.values().parallelStream().forEach(a::add);
sum = a.intValue();
From the docs
Reduction operations A reduction operation (also called a fold) takes a sequence of input elements and combines them into a single summary result by repeated application of a combining operation, such as finding the sum or maximum of a set of numbers, or accumulating elements into a list. The streams classes have multiple forms of general reduction operations, called reduce() and collect(), as well as multiple specialized reduction forms such as sum(), max(), or count().
Of course, such operations can be readily implemented as simple sequential loops, as in:
int sum = 0; for (int x : numbers) { sum += x; }
However, there are good reasons to prefer a reduce operation over a mutative accumulation such as the above. Not only is a reduction "more abstract" -- it operates on the stream as a whole rather than individual elements -- but a properly constructed reduce operation is inherently parallelizable, so long as the function(s) used to process the elements are associative and stateless. For example, given a stream of numbers for which we want to find the sum, we can write:
int sum = numbers.stream().reduce(0, (x,y) -> x+y);
or:
int sum = numbers.stream().reduce(0, Integer::sum);
These reduction operations can run safely in parallel with almost no modification:
int sum = numbers.parallelStream().reduce(0, Integer::sum);
So, for a map you would use:
integers.values().stream().mapToInt(i -> i).reduce(0, (x,y) -> x+y);
Or:
integers.values().stream().reduce(0, Integer::sum);
You can use reduce method:
long sum = result.stream().map(e -> e.getCreditAmount()).reduce(0L, (x, y) -> x + y);
or
long sum = result.stream().map(e -> e.getCreditAmount()).reduce(0L, Integer::sum);
Long::sum
than Integer::sum
.
Mar 12 '19 at 8:46
You can use reduce()
to sum a list of integers.
int sum = integers.values().stream().reduce(0, Integer::sum);
You can use collect method to add list of integers.
List<Integer> list = Arrays.asList(2, 4, 5, 6);
int sum = list.stream().collect(Collectors.summingInt(Integer::intValue));
I have declared a list of Integers.
ArrayList<Integer> numberList = new ArrayList<Integer>(Arrays.asList(1, 2, 3, 4, 5));
You can try using these different ways below.
Using mapToInt
int sum = numberList.stream().mapToInt(Integer::intValue).sum();
Using summarizingInt
int sum = numberList.stream().collect(Collectors.summarizingInt(Integer::intValue)).getSum();
Using reduce
int sum = numberList.stream().reduce(Integer::sum).get().intValue();
This would be the shortest way to sum up int
type array (for long
array LongStream
, for double
array DoubleStream
and so forth). Not all the primitive integer or floating point types have the Stream
implementation though.
IntStream.of(integers).sum();
IntStream.of()
won't work for this problem, unless we're making something spooky like this: IntStream.of( integers.values().stream().mapToInt( Integer::intValue ).toArray() ).sum();
integers.values().stream().mapToInt( Integer::intValue ).sum()
.
Sep 25 '19 at 13:47
May this help those who have objects on the list.
If you have a list of objects and wanted to sum specific fields of this object use the below.
List<ResultSom> somList = MyUtil.getResultSom();
BigDecimal result= somList.stream().map(ResultSom::getNetto).reduce(
BigDecimal.ZERO, BigDecimal::add);
Unfortunately looks like the Stream API only returns normal streams from, say, List<Integer>#stream()
. Guess they're pretty much forced to because of how generics work.
These normal Streams are of generic objects so don't have specialized methods like sum()
etc. so you have to use the weird re-stream "looks like a no-op" conversion by default to get to those methods... .mapToInt(i -> i)
.
Another option is using "Eclipse Collections" which are like an expanded java Stream API
IntLists.immutable.ofAll(integers.values()).sum();
List < Integer > listOfIntegers = List.of(1, 2, 10, 3, 4, 8, 5, 9, 6, 7);
Optional < Integer > maxValue = listOfIntegers
.stream().reduce((partialResult, currentValue) -> Math.max(partialResult, currentValue));
System.out.println("Maximum value : " + maxValue);
Output: Maximum value: Optional[10]
class Pojo{
int num;
public Pojo(int num) {
super();
this.num = num;
}
public int getNum() {
return num;
}
public void setNum(int num) {
this.num = num;
}
}
List<Pojo> list = new ArrayList<Pojo>();
list.add(new Pojo(1));
list.add(new Pojo(5));
list.add(new Pojo(3));
list.add(new Pojo(4));
list.add(new Pojo(5));
int totalSum = list.stream().mapToInt(pojo -> pojo.getNum()).sum();
System.out.println(totalSum);
Most of the aspects are covered. But there could be a requirement to find the aggregation of other data types apart from Integer, Long(for which specialized stream support is already present). For e.g. stram with BigInteger For such a type we can use reduce operation like
list.stream().reduce((bigInteger1, bigInteger2) -> bigInteger1.add(bigInteger2))
mapToLong
to avoid overflows, depending on the values your map can have.i -> i
very clear, personally. Well, yes you need to know that the value will be automatically unboxed, but it's true since Java 5...foo(int i)
do not writefoo(myInteger.intValue());
each time they call it (or at least I expect not!!). I agree with you thatInteger::intValue
is more explicit but I think the same applies here. People should just learn it once and then you're done :-). It's not like if it was some magic obfuscation.i -> i
looks like a no-op and conceptionally, it is a no-op. Sure, under the hoodInteger.intValue()
gets called, but even deeper under the hood, that methods gets inlined to become exactly the no-op that it looks like in the source code.Integer::intValue
has the bonus point of not creating a synthetic method in the byte code but it’s not what should drive your decision of how to organize your source code.