The TreeSet
class of the Java collections framework provides the functionality of a tree data structure.
It extends the NavigableSet interface.
Creating a TreeSet
In order to create a tree set, we must import the java.util.TreeSet
package first.
Once we import the package, here is how we can create a TreeSet
in Java.
TreeSet<Integer> numbers = new TreeSet<>();
Here, we have created a TreeSet
without any arguments. In this case, the elements in TreeSet
are sorted naturally (ascending order).
However, we can customize the sorting of elements by using the Comparator
interface. We will learn about it later in this tutorial.
Methods of TreeSet
The TreeSet
class provides various methods that allow us to perform various operations on the set.
Insert Elements to TreeSet
add()
- inserts the specified element to the setaddAll()
- inserts all the elements of the specified collection to the set
For example,
import java.util.TreeSet;
class Main {
public static void main(String[] args) {
TreeSet<Integer> evenNumbers = new TreeSet<>();
// Using the add() method
evenNumbers.add(2);
evenNumbers.add(4);
evenNumbers.add(6);
System.out.println("TreeSet: " + evenNumbers);
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(1);
// Using the addAll() method
numbers.addAll(evenNumbers);
System.out.println("New TreeSet: " + numbers);
}
}
Output
TreeSet: [2, 4, 6] New TreeSet: [1, 2, 4, 6]
Access TreeSet Elements
To access the elements of a tree set, we can use the iterator() method. In order to use this method, we must import java.util.Iterator
package. For example,
import java.util.TreeSet;
import java.util.Iterator;
class Main {
public static void main(String[] args) {
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(2);
numbers.add(5);
numbers.add(6);
System.out.println("TreeSet: " + numbers);
// Calling iterator() method
Iterator<Integer> iterate = numbers.iterator();
System.out.print("TreeSet using Iterator: ");
// Accessing elements
while(iterate.hasNext()) {
System.out.print(iterate.next());
System.out.print(", ");
}
}
}
Output
TreeSet: [2, 5, 6] TreeSet using Iterator: 2, 5, 6,
Remove Elements
remove()
- removes the specified element from the setremoveAll()
- removes all the elements from the set
For example,
import java.util.TreeSet;
class Main {
public static void main(String[] args) {
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(2);
numbers.add(5);
numbers.add(6);
System.out.println("TreeSet: " + numbers);
// Using the remove() method
boolean value1 = numbers.remove(5);
System.out.println("Is 5 removed? " + value1);
// Using the removeAll() method
boolean value2 = numbers.removeAll(numbers);
System.out.println("Are all elements removed? " + value2);
}
}
Output
TreeSet: [2, 5, 6] Is 5 removed? true Are all elements removed? true
Methods for Navigation
Since the TreeSet
class implements NavigableSet
, it provides various methods to navigate over the elements of the tree set.
1. first() and last() Methods
first()
- returns the first element of the setlast()
- returns the last element of the set
For example,
import java.util.TreeSet;
class Main {
public static void main(String[] args) {
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(2);
numbers.add(5);
numbers.add(6);
System.out.println("TreeSet: " + numbers);
// Using the first() method
int first = numbers.first();
System.out.println("First Number: " + first);
// Using the last() method
int last = numbers.last();
System.out.println("Last Number: " + last);
}
}
Output
TreeSet: [2, 5, 6] First Number: 2 Last Number: 6
2. ceiling(), floor(), higher() and lower() Methods
- higher(element) - Returns the lowest element among those elements that are greater than the specified
element
. - lower(element) - Returns the greatest element among those elements that are less than the specified
element
. - ceiling(element) - Returns the lowest element among those elements that are greater than the specified element. If the element passed exists in a tree set, it returns the
element
passed as an argument. - floor(element) - Returns the greatest element among those elements that are less than the specified
element
. If the element passed exists in a tree set, it returns theelement
passed as an argument.
For example,
import java.util.TreeSet;
class Main {
public static void main(String[] args) {
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(2);
numbers.add(5);
numbers.add(4);
numbers.add(6);
System.out.println("TreeSet: " + numbers);
// Using higher()
System.out.println("Using higher: " + numbers.higher(4));
// Using lower()
System.out.println("Using lower: " + numbers.lower(4));
// Using ceiling()
System.out.println("Using ceiling: " + numbers.ceiling(4));
// Using floor()
System.out.println("Using floor: " + numbers.floor(3));
}
}
Output
TreeSet: [2, 4, 5, 6] Using higher: 5 Using lower: 2 Using ceiling: 4 Using floor: 2
3. pollfirst() and pollLast() Methods
pollFirst()
- returns and removes the first element from the setpollLast()
- returns and removes the last element from the set
For example,
import java.util.TreeSet;
class Main {
public static void main(String[] args) {
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(2);
numbers.add(5);
numbers.add(4);
numbers.add(6);
System.out.println("TreeSet: " + numbers);
// Using pollFirst()
System.out.println("Removed First Element: " + numbers.pollFirst());
// Using pollLast()
System.out.println("Removed Last Element: " + numbers.pollLast());
System.out.println("New TreeSet: " + numbers);
}
}
Output
TreeSet: [2, 4, 5, 6] Removed First Element: 2 Removed Last Element: 6 New TreeSet: [4, 5]
4. headSet(), tailSet() and subSet() Methods
headSet(element, booleanValue)
The headSet()
method returns all the elements of a tree set before the specified element (which is passed as an argument).
The booleanValue parameter is optional. Its default value is false
.
If true
is passed as a booleanValue, the method returns all the elements before the specified element including the specified element.
For example,
import java.util.TreeSet;
class Main {
public static void main(String[] args) {
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(2);
numbers.add(5);
numbers.add(4);
numbers.add(6);
System.out.println("TreeSet: " + numbers);
// Using headSet() with default boolean value
System.out.println("Using headSet without boolean value: " + numbers.headSet(5));
// Using headSet() with specified boolean value
System.out.println("Using headSet with boolean value: " + numbers.headSet(5, true));
}
}
Output
TreeSet: [2, 4, 5, 6] Using headSet without boolean value: [2, 4] Using headSet with boolean value: [2, 4, 5]
tailSet(element, booleanValue)
The tailSet()
method returns all the elements of a tree set after the specified element (which is passed as a parameter) including the specified element.
The booleanValue parameter is optional. Its default value is true
.
If false
is passed as a booleanValue, the method returns all the elements after the specified element without including the specified element.
For example,
import java.util.TreeSet;
class Main {
public static void main(String[] args) {
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(2);
numbers.add(5);
numbers.add(4);
numbers.add(6);
System.out.println("TreeSet: " + numbers);
// Using tailSet() with default boolean value
System.out.println("Using tailSet without boolean value: " + numbers.tailSet(4));
// Using tailSet() with specified boolean value
System.out.println("Using tailSet with boolean value: " + numbers.tailSet(4, false));
}
}
Output
TreeSet: [2, 4, 5, 6] Using tailSet without boolean value: [4, 5, 6] Using tailSet with boolean value: [5, 6]
subSet(e1, bv1, e2, bv2)
The subSet()
method returns all the elements between e1 and e2 including e1.
The bv1 and bv2 are optional parameters. The default value of bv1 is true
, and the default value of bv2 is false
.
If false
is passed as bv1, the method returns all the elements between e1 and e2 without including e1
.
If true
is passed as bv2, the method returns all the elements between e1 and e2, including e1.
For example,
import java.util.TreeSet;
class Main {
public static void main(String[] args) {
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(2);
numbers.add(5);
numbers.add(4);
numbers.add(6);
System.out.println("TreeSet: " + numbers);
// Using subSet() with default boolean value
System.out.println("Using subSet without boolean value: " + numbers.subSet(4, 6));
// Using subSet() with specified boolean value
System.out.println("Using subSet with boolean value: " + numbers.subSet(4, false, 6, true));
}
}
Output
TreeSet: [2, 4, 5, 6] Using subSet without boolean value: [4, 5] Using subSet with boolean value: [5, 6]
Set Operations
The methods of the TreeSet
class can also be used to perform various set operations.
Union of Sets
To perform the union between two sets, we use the addAll()
method. For example,
import java.util.TreeSet;;
class Main {
public static void main(String[] args) {
TreeSet<Integer> evenNumbers = new TreeSet<>();
evenNumbers.add(2);
evenNumbers.add(4);
System.out.println("TreeSet1: " + evenNumbers);
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(1);
numbers.add(2);
numbers.add(3);
System.out.println("TreeSet2: " + numbers);
// Union of two sets
numbers.addAll(evenNumbers);
System.out.println("Union is: " + numbers);
}
}
Output
TreeSet1: [2, 4] TreeSet2: [1, 2, 3] Union is: [1, 2, 3, 4]
Intersection of Sets
To perform the intersection between two sets, we use the retainAll()
method. For example,
import java.util.TreeSet;;
class Main {
public static void main(String[] args) {
TreeSet<Integer> evenNumbers = new TreeSet<>();
evenNumbers.add(2);
evenNumbers.add(4);
System.out.println("TreeSet1: " + evenNumbers);
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(1);
numbers.add(2);
numbers.add(3);
System.out.println("TreeSet2: " + numbers);
// Intersection of two sets
numbers.retainAll(evenNumbers);
System.out.println("Intersection is: " + numbers);
}
}
Output
TreeSet1: [2, 4] TreeSet2: [1, 2, 3] Intersection is: [2]
Difference of Sets
To calculate the difference between the two sets, we can use the removeAll()
method. For example,
import java.util.TreeSet;;
class Main {
public static void main(String[] args) {
TreeSet<Integer> evenNumbers = new TreeSet<>();
evenNumbers.add(2);
evenNumbers.add(4);
System.out.println("TreeSet1: " + evenNumbers);
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(1);
numbers.add(2);
numbers.add(3);
numbers.add(4);
System.out.println("TreeSet2: " + numbers);
// Difference between two sets
numbers.removeAll(evenNumbers);
System.out.println("Difference is: " + numbers);
}
}
Output
TreeSet1: [2, 4] TreeSet2: [1, 2, 3, 4] Difference is: [1, 3]
Subset of a Set
To check if a set is a subset of another set or not, we use the containsAll()
method. For example,
import java.util.TreeSet;
class Main {
public static void main(String[] args) {
TreeSet<Integer> numbers = new TreeSet<>();
numbers.add(1);
numbers.add(2);
numbers.add(3);
numbers.add(4);
System.out.println("TreeSet1: " + numbers);
TreeSet<Integer> primeNumbers = new TreeSet<>();
primeNumbers.add(2);
primeNumbers.add(3);
System.out.println("TreeSet2: " + primeNumbers);
// Check if primeNumbers is subset of numbers
boolean result = numbers.containsAll(primeNumbers);
System.out.println("Is TreeSet2 subset of TreeSet1? " + result);
}
}
Output
TreeSet1: [1, 2, 3, 4] TreeSet2: [2, 3] Is TreeSet2 subset of TreeSet1? True
Other Methods of TreeSet
Method | Description |
---|---|
clone() |
Creates a copy of the TreeSet |
contains() |
Searches the TreeSet for the specified element and returns a boolean result |
isEmpty() |
Checks if the TreeSet is empty |
size() |
Returns the size of the TreeSet |
clear() |
Removes all the elements from the TreeSet |
To learn more, visit Java TreeSet (official Java documentation).
TreeSet Vs. HashSet
Both the TreeSet
as well as the HashSet
implements the Set
interface. However, there exist some differences between them.
- Unlike
HashSet
, elements inTreeSet
are stored in some order. It is becauseTreeSet
implements theSortedSet
interface as well. TreeSet
provides some methods for easy navigation. For example,first()
,last()
,headSet(
),tailSet()
, etc. It is becauseTreeSet
also implements theNavigableSet
interface.HashSet
is faster than theTreeSet
for basic operations like add, remove, contains and size.
TreeSet Comparator
In all the examples above, tree set elements are sorted naturally. However, we can also customize the ordering of elements.
For this, we need to create our own comparator class based on which elements in a tree set are sorted. For example,
import java.util.TreeSet;
import java.util.Comparator;
class Main {
public static void main(String[] args) {
// Creating a tree set with a customized comparator
TreeSet<String> animals = new TreeSet<>(new CustomComparator());
animals.add("Dog");
animals.add("Zebra");
animals.add("Cat");
animals.add("Horse");
System.out.println("TreeSet: " + animals);
}
// Creating a comparator class
public static class CustomComparator implements Comparator<String> {
@Override
public int compare(String animal1, String animal2) {
int value = animal1.compareTo(animal2);
// elements are sorted in reverse order
if (value > 0) {
return -1;
}
else if (value < 0) {
return 1;
}
else {
return 0;
}
}
}
}
Output
TreeSet: [Zebra, Horse, Dog, Cat]
In the above example, we have created a tree set passing CustomComparator class as an argument.
The CustomComparator class implements the Comparator
interface.
We then override the compare()
method. The method will now sort elements in reverse order.
To learn more, visit Java Comparator (official Java documentation).