Efficient search for not empty intersection (Java)

I have a method that returns an integer value or integer range (initial..final) and I want to know if values are all disjoint.

Is there a more efficient solution than the following one:

``````ArrayList<Integer> list = new ArrayList<Integer>();

// For single value
int value;
if(!list.contains(value))
else
error("",null);

// Range
int initialValue,finalValue;
for(int i = initialValue; i <= finalValue; i++){
if(!list.contains(i))
else
error("",null);
}
``````
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`error("",null);` seems pretty useless... –  Brendan Long Dec 10 '12 at 16:59
How large are the ranges? If they're small, then it will probably be efficient to deal with them as a series of individual values, but if they're large (hundreds), then it might be better to deal with them as ranges, and handle individual values as a special case of a range, containing one value. –  Tom Anderson Dec 10 '12 at 17:36
@BrendanLong Obviusly, that error is only an example. Tom Anderson :Ranges are very difficult to forecast (this constrol is for a dsl) but I think they are about one or two hundreds. –  Tommaso DS Dec 11 '12 at 8:13

Finding a value (`contains`) in `HashSet` is a constant-time operation (O(1)) on average, which is better than a `List`, where `contains` is linear (O(n)). So, if your lists are large enough, it may be worthwhile to replace your first line with:

``````HashSet<Integer> list = new HashSet<Integer>();
``````

The reason for this is that to find a value in an (unsorted) list, you need to check every index in the list until you find the one you want or run out of indexes to check. On average you'll check half the list before finding a value if the value is in the list, or the whole list if it's not. For a hash table, you generate an index from the value you want to find, then you check that one index (it's possible you need to check more than one, but it should be uncommon in a well-designed hash table).

Also, if you use a Set, you get a guarantee that each value is unique, so if you try to add a value that already exists, `add` will return `false`. You can use that to slightly simplify the code (note: This will not work if you use a List, because `add` always returns `true` on a List):

``````HashSet<Integer> list = new HashSet<Integer>();

int value;
error("",null);
``````
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This is perfect solution, very thank you. –  Tommaso DS Dec 11 '12 at 9:57

Problems involving ranges often lend themselves to the use of a tree. Here's a way to do that using `TreeSet`:

``````public class DisjointChecker {

private final NavigableSet<Integer> integers = new TreeSet<Integer>();

public boolean check(int value) {
}

public boolean check(int from, int to) {
NavigableSet<Integer> range = integers.subSet(from, true, to, true);
if (range.isEmpty()) {
return true;
}
else {
return false;
}
}

private void addRange(int from, int to) {
for (int i = from; i <= to; ++i) {
}
}

}
``````

Here, rather than calling an error handler, the `check` methods return a boolean indicating whether the arguments were disjoint from all previous arguments. The semantics of the range version are different to in the original code; if the range is not disjoint, none of the elements are added, whereas in the original, any below the first non-disjoint element are added.

A few points may deserve elaboration:

• `Set::add` returns a boolean indicating whether the addition modified the set; we can use that as the return value from the method.
• `NavigableSet` is an obscure but standard subinterface of `SortedSet` which is sadly neglected. Although you could actually use a plain `SortedSet` here with only minor modifications.
• The `NavigableSet::subSet` method (like `SortedSet::subSet`) returns a lightweight view on the underlying set which is restricted to a given range. This provides a very efficient way to query the tree for any overlap with the whole range in one operation.
• The `addRange` method here is very simple, and runs in O(m log n) when adding m items to a checker which has seen n items previously. It would be possible to make a version which ran in O(m) by writing an implementation of `SortedSet` which described a range of integers and then using `Set::addAll`, because `TreeSet`'s implementation of this contains a special case for adding other `SortedSet`s in linear time. The code for that special set implementation is very simple, but involves a lot of boilerplate, so i leave it as an exercise for the reader!
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