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Assume you have some objects which have several fields they can be compared by:

public class Person {

    private String firstName;
    private String lastName;
    private String age;

    /* Constructors */

    /* Methods */


So in this example, when you ask if:

a.compareTo(b) > 0

you might be asking if a's last name comes before b's, or if a is older than b, etc...

What is the cleanest way to enable multiple comparison between these kinds of objects without adding unnecessary clutter or overhead?

  • java.lang.Comparable interface allows comparison by one field only
  • Adding numerous compare methods (i.e. compareByFirstName(), compareByAge(), etc...) is cluttered in my opinion.

So what is the best way to go about this?

share|improve this question
why is this a cw? It's a perfectly valid programming question. – Elie Dec 15 '08 at 20:42
Are you aware that Comparable allows comparison by as many fields as you like? – DJClayworth Dec 15 '08 at 20:47
CW by mistake :) – Yuval Adam Dec 15 '08 at 22:48
possible duplicate of Using Comparable for multiple dynamic fields of VO in java – eugenevd Feb 27 '14 at 11:51

17 Answers 17

up vote 41 down vote accepted

You can write a comparator class which compares two Person objects, and you can examine as many of the fields as you like. You can put in a variable in your comparator that tells it which field to compare to, although it would probably be simpler to just write multiple comparators.

share|improve this answer
I Actually prefer the idea of using a single Comparator. I don't think this answer is wrong, but anyone reading it should definitely check Steve Kuo answer below. – Felipe Leão Nov 13 '14 at 12:15
The multiple comparators was only if you want different comparison methods that are not a function of the data itself - i.e. sometimes you want to compare by name, other times by age, etc. To compare by multiple fields at the same time, only one comparator would be necessary. – Elie Nov 13 '14 at 17:13

You should implement Comparable <Person>. Assuming all fields will not be null (for simplicity sake), that age is an int, and compare ranking is last, first, age, the compareTo method is quite simple:

public int compareTo(Person other) {
    int i = firstName.compareTo(other.firstName);
    if (i != 0) return i;

    i = lastName.compareTo(other.lastName);
    if (i != 0) return i;

    return, other.age);
share|improve this answer
if you implement Comparable<Person> then the method is compareTo(Person p).. it seems that this answer was mixed up with Comparator's compare<T o1, T o2> method – Mike Dec 14 '12 at 12:59
This is not recommended. Use Comparator when you have multiple fields. – indika Apr 20 '14 at 4:09
that's the best solution at the moment, (better than more comparators) – Vasile Surdu Jun 6 '14 at 18:41
@indika, I'm curious: why is this not recommended? Comparing using more than one property seems perfectly fine to me. – ars-longa-vita-brevis Sep 25 '14 at 22:31
@ars-longa-vita-brevis, If you are using Comparable then sorting logic must be in the same class whose objects are being sorted so this is called natural ordering of objects. With the use of Comparator you can write custom sorting logic outside the Person class. If you want to compare Person objects only by its first name or last name, you cant use this logic. You have to write it again, – indika Sep 26 '14 at 6:38

@Patrick To sort more than one field consecutively try ComparatorChain

A ComparatorChain is a Comparator that wraps one or more Comparators in sequence. The ComparatorChain calls each Comparator in sequence until either 1) any single Comparator returns a non-zero result (and that result is then returned), or 2) the ComparatorChain is exhausted (and zero is returned). This type of sorting is very similar to multi-column sorting in SQL, and this class allows Java classes to emulate that kind of behaviour when sorting a List.

To further facilitate SQL-like sorting, the order of any single Comparator in the list can >be reversed.

Calling a method that adds new Comparators or changes the ascend/descend sort after compare(Object, Object) has been called will result in an UnsupportedOperationException. However, take care to not alter the underlying List of Comparators or the BitSet that defines the sort order.

Instances of ComparatorChain are not synchronized. The class is not thread-safe at construction time, but it is thread-safe to perform multiple comparisons after all the setup operations are complete.

share|improve this answer

With Java 8:


If you have accessor methods:

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Comparator.comparing((Person p)->p.firstName).thenComparingInt(p->p.age); – Cosmin Vasii Oct 5 at 15:52
Comparator.comparing((Person p)->p.firstName).thenComparingInt(p->p.age); I don't know how to format comments, so I'll just leave like this. Java performs type inference like from left to right, so the compiler won't delay the first link in the chain. Need to add (Person p)->p.firstName and will work – Cosmin Vasii Oct 5 at 16:00

You can also have a look at Enum that implements Comparator.

e.g. Collections.sort(myChildren, Child.Order.ByAge.descending());

share|improve this answer
This method looks really nice. – Bent André Solheim Dec 16 '08 at 0:08

Another option you can always consider is Apache Commons. It provides a lot of options.

import org.apache.commons.lang3.builder.CompareToBuilder;


public int compare(Person a, Person b){

   return new CompareToBuilder()
     .append(a.getName(), b.getName())
     .append(a.getAddress(), b.getAddress())
share|improve this answer
perfect for my situation! – Mar 9 at 18:33

(from House of Code)

Messy and convoluted: Sorting by hand

Collections.sort(pizzas, new Comparator<Pizza>() {  
    public int compare(Pizza p1, Pizza p2) {  
        int sizeCmp = p1.size.compareTo(p2.size);  
        if (sizeCmp != 0) {  
            return sizeCmp;  
        int nrOfToppingsCmp = p1.nrOfToppings.compareTo(p2.nrOfToppings);  
        if (nrOfToppingsCmp != 0) {  
            return nrOfToppingsCmp;  

This requires a lot of typing, maintenance and is error prone.

The reflective way: Sorting with BeanComparator

Collections.sort(pizzas, new BeanComparator("size", new BeanComparator("nrOfToppings", new BeanComparator("name"))));  

Obviously this is is more concise, but even more error prone as you loose your direct reference to the fields by using Strings instead. Now if a field is renamed, the compiler won’t even report a problem. Moreover, because this solution uses reflection, the sorting is much slower.

Getting there: Sorting with Google Guava’s ComparisonChain

Collections.sort(pizzas, new Comparator<Pizza>() {  
    public int compare(Pizza p1, Pizza p2) {  
        return ComparisonChain.start().compare(p1.size, p2.size).compare(p1.nrOfToppings, p2.nrOfToppings).compare(,;  
        // or in case the fields can be null:  
        return ComparisonChain.start() 
           .compare(p1.size, p2.size, Ordering.natural().nullsLast()) 
           .compare(p1.nrOfToppings, p2.nrOfToppings, Ordering.natural().nullsLast()) 
           .compare(,, Ordering.natural().nullsLast()) 

This is much better, but requires some boiler plate code for the most common use case: null-values should be values less by default. For null-fields, you have to provide an extra directive to Guava what to do in that case. This is a flexible mechanism if you want to do something specific, but often you want the default case (ie. 1, a, b, z, null).

Sorting with Apache Commons CompareToBuilder

Collections.sort(pizzas, new Comparator<Pizza>() {  
    public int compare(Pizza p1, Pizza p2) {  
        return new CompareToBuilder().append(p1.size, p2.size).append(p1.nrOfToppings, p2.nrOfToppings).append(,;  

Like Guava’s ComparisonChain, this library class sorts easily on multiple fields, but also defines default behavior for null values (ie. 1, a, b, z, null). However, you can’t specify anything else either, unless you provide your own Comparator.


Ultimately it comes down to flavor and the need for flexibility (Guava’s ComparisonChain) vs. concise code (Apache’s CompareToBuilder).

share|improve this answer

Writing a Comparator manually for such an use case is a terrible solution IMO. Such ad hoc approaches have many drawbacks:

  • No code reuse. Violates DRY.
  • Boilerplate.
  • Increased possibility of errors.

So what's the solution?

First some theory.

Let us denote the proposition "type A supports comparison" by Ord A. (From program perspective, you can think of Ord A as an object containing logic for comparing two As. Yes, just like Comparator.)

Now, if Ord A and Ord B, then their composite (A, B) should also support comparison. i.e. Ord (A, B). If Ord A, Ord B, and Ord C, then Ord (A, B, C).

We can extend this argument to arbitrary arity, and say:

Ord A, Ord B, Ord C, ..., Ord ZOrd (A, B, C, .., Z)

Let's call this statement 1.

The comparison of the composites will work just as you described in your question: the first comparison will be tried first, then the next one, then the next, and so on.

That's the first part of our solution. Now the second part.

If you know that Ord A, and know how to transform B to A (call that transformation function f), then you can also have Ord B. How? Well, when the two B instances are to be compared, you first transform them to A using f and then apply Ord A.

Here, we are mapping the transformation B → A to Ord A → Ord B. This is known as contravariant mapping (or comap for short).

Ord A, (B → A)comap Ord B

Let's call this statement 2.

Now let's apply this to your example.

You have a data type named Person that comprises three fields of type String.

  • We know that Ord String. By statement 1, Ord (String, String, String).

  • We can easily write a function from Person to (String, String, String). (Just return the three fields.) Since we know Ord (String, String, String) and Person → (String, String, String), by statement 2, we can use comap to get Ord Person.


How do I implement all these concepts?

The good news is you don't have to. There already exists a library which implements all the ideas described in this post. (If you are curious how these are implemented, you can look under the hood.)

This is how the code will look with it:

Ord<Person> personOrd = 
 p3Ord(stringOrd, stringOrd, stringOrd).comap(
   new F<Person, P3<String, String, String>>() {
     public P3<String, String, String> f(Person x) {
       return p(x.getFirstName(), x.getLastname(), x.getAge());


  • stringOrd is an object of type Ord<String>. This corresponds to our original "supports comparison" proposition.
  • p3Ord is a method that takes Ord<A>, Ord<B>, Ord<C>, and returns Ord<P3<A, B, C>>. This corresponds to statement 1. (P3 stands for product with three elements. Product is an algebraic term for composites.)
  • comap corresponds to well, comap.
  • F<A, B> represents a transformation function A → B.
  • p is a factory method for creating products.
  • The whole expression corresponds to statement 2.

Hope that helps.

share|improve this answer
ye total gangster – L̲̳o̲̳̳n̲̳̳g̲̳̳p̲̳o̲̳̳k̲̳̳e̲̳̳ Mar 15 '13 at 3:13

Instead of comparison methods you may want to just define several types of "Comparator" subclasses inside the Person class. That way you can pass them into standard Collections sorting methods.

share|improve this answer

For those able to use the Java 8 streaming API, there is a neater approach that is well documented here: Lambdas and sorting

I was looking for the equivalent of the C# LINQ:


I found the mechanism in Java 8 on the Comparator:


So here is the snippet that demonstrates the algorithm.

    Comparator<Person> comparator = Comparator.comparing(person ->;
    comparator = comparator.thenComparing(Comparator.comparing(person -> person.age));

Check out the link above for a neater way and an explanation about how Java's type inference makes it a bit more clunky to define compared to LINQ.

Here is the full unit test for reference:

public void testChainedSorting()
    // Create the collection of people:
    ArrayList<Person> people = new ArrayList<>();
    people.add(new Person("Dan", 4));
    people.add(new Person("Andi", 2));
    people.add(new Person("Bob", 42));
    people.add(new Person("Debby", 3));
    people.add(new Person("Bob", 72));
    people.add(new Person("Barry", 20));
    people.add(new Person("Cathy", 40));
    people.add(new Person("Bob", 40));
    people.add(new Person("Barry", 50));

    // Define chained comparators:
    // Great article explaining this and how to make it even neater:
    Comparator<Person> comparator = Comparator.comparing(person ->;
    comparator = comparator.thenComparing(Comparator.comparing(person -> person.age));

    // Sort the stream:
    Stream<Person> personStream =;

    // Make sure that the output is as expected:
    List<Person> sortedPeople = personStream.collect(Collectors.toList());
    Assert.assertEquals("Andi",  sortedPeople.get(0).name); Assert.assertEquals(2,  sortedPeople.get(0).age);
    Assert.assertEquals("Barry", sortedPeople.get(1).name); Assert.assertEquals(20, sortedPeople.get(1).age);
    Assert.assertEquals("Barry", sortedPeople.get(2).name); Assert.assertEquals(50, sortedPeople.get(2).age);
    Assert.assertEquals("Bob",   sortedPeople.get(3).name); Assert.assertEquals(40, sortedPeople.get(3).age);
    Assert.assertEquals("Bob",   sortedPeople.get(4).name); Assert.assertEquals(42, sortedPeople.get(4).age);
    Assert.assertEquals("Bob",   sortedPeople.get(5).name); Assert.assertEquals(72, sortedPeople.get(5).age);
    Assert.assertEquals("Cathy", sortedPeople.get(6).name); Assert.assertEquals(40, sortedPeople.get(6).age);
    Assert.assertEquals("Dan",   sortedPeople.get(7).name); Assert.assertEquals(4,  sortedPeople.get(7).age);
    Assert.assertEquals("Debby", sortedPeople.get(8).name); Assert.assertEquals(3,  sortedPeople.get(8).age);
    // Andi     : 2
    // Barry    : 20
    // Barry    : 50
    // Bob      : 40
    // Bob      : 42
    // Bob      : 72
    // Cathy    : 40
    // Dan      : 4
    // Debby    : 3

 * A person in our system.
public static class Person
     * Creates a new person.
     * @param name The name of the person.
     * @param age The age of the person.
    public Person(String name, int age)
        this.age = age; = name;

     * The name of the person.
    public String name;

     * The age of the person.
    public int age;

    public String toString()
        if (name == null) return super.toString();
        else return String.format("%s : %d",, this.age);
share|improve this answer

I think it'd be more confusing if your comparison algorithm were "clever". I'd go with the numerous comparison methods you suggested.

The only exception for me would be equality. For unit testing, it's been useful to me to override the .Equals (in .net) in order to determine if several fields are equal between two objects (and not that the references are equal).

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If there are multiple ways a user might order person, you could also have multiple Comparators setup as constants somewhere. Most of the sort operations and sorted collections take a comparator as a parameter.

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 * @author radler
 * Class Description ...
public class Attribute implements Comparable<Attribute>{

    private String type;
    private String value;

    public String getType() {
        return type;
    public void setType(String type) {
        this.type = type;
    public String getValue() {
        return value;
    public void setValue(String value) {
        this.value = value;

    public String toString() {
        return "Attribute [type=" + type + ", value=" + value + "]";

    public int compareTo(Attribute that) {
        return ComparisonChain.start()
        .compare(this.type, that.type)
        .compare(this.value, that.value)

share|improve this answer

If you implement the Comparable interface, you'll want to choose one simple property to order by. This is known as natural ordering. Think of it as the default. It's always used when no specific comparator is supplied. Usually this is name, but your use case may call for something different. You are free to use any number of other Comparators you can supply to various collections APIs to override the natural ordering.

Also note that typically if a.compareTo(b) == 0, then a.equals(b) == true. It's ok if not but there are side effects to be aware of. See the excellent javadocs on the Comparable interface and you'll find lots of great information on this.

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//here threshold,buyRange,targetPercentage are three keys on that i have sorted my arraylist 
final Comparator<BasicDBObject> 

    sortOrder = new Comparator<BasicDBObject>() {
                    public int compare(BasicDBObject e1, BasicDBObject e2) {
                        int threshold = new Double(e1.getDouble("threshold"))
                        .compareTo(new Double(e2.getDouble("threshold")));
                        if (threshold != 0)
                            return threshold;

                        int buyRange = new Double(e1.getDouble("buyRange"))
                        .compareTo(new Double(e2.getDouble("buyRange")));
                        if (buyRange != 0)
                            return buyRange;

                        return (new Double(e1.getDouble("targetPercentage")) < new Double(
                                e2.getDouble("targetPercentage")) ? -1 : (new Double(
                                        e1.getDouble("targetPercentage")) == new Double(
                                                e2.getDouble("targetPercentage")) ? 0 : 1));
                Collections.sort(objectList, sortOrder);
share|improve this answer
I came to this question because my code started to like your answer ;) – jan groth Jan 6 at 10:36

Its easy to do using Google's Guava library.

e.g. Objects.equal(name, name2) && Objects.equal(age, age2) && ...

More examples:

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