What is the most efficient way to find the size of the intersection of two non-sparse Sets in Java? This is an operation I will be calling on large sets a very large number of times, so optimisation is important. I cannot modify the original sets.

I have looked at Apache Commons CollectionUtils.intersection which appears to be quite slow. My current approach is to take the smaller of the two sets, clone it, and then call .retainAll on the larger of the two sets.

public static int getIntersection(Set<Long> set1, Set<Long> set2) {
    boolean set1IsLarger = set1.size() > set2.size();
    Set<Long> cloneSet = new HashSet<Long>(set1IsLarger ? set2 : set1);
    cloneSet.retainAll(set1IsLarger ? set1 : set2);
    return cloneSet.size();
  • As far as I know CollectionUtils.Intersection is a more general method (which can be applied to lists aswell), thats why it doesn't shine on sets. And you should check: stackoverflow.com/questions/2851938/…
    – frail
    Sep 27, 2011 at 19:10
  • 2
    What is the size() of a boolean? :-)
    – rsp
    Sep 27, 2011 at 19:17
  • This would perhaps be slightly faster (extreme micro-optimization) by making one if statement in stead of the three ?: statements. This way it only has to branch (which can be 'expensive') once instead of three times.
    – corsiKa
    Sep 27, 2011 at 19:57
  • I tested with both and couldn't see a difference - perhaps the compiler or runtime is taking care of that for me.
    – Ina
    Sep 27, 2011 at 20:41
  • Without any information WHAT kind of set we're talking about, that question is hard to answer definitely. Different sets have quite different costs for different actions.
    – Voo
    Sep 27, 2011 at 22:39

10 Answers 10


Run some tests with the posted approach and versus constructing a new HashSet. That is, let A be the smaller of the sets and B be the larger set and then, for each item in A, if it also exists in B then add it to C (a new HashSet) -- for just counting, the intermediate C set can be skipped.

Just as the posted approach, this should be a O(|A|) in cost as the iteration is O(|A|) and probe into B is O(1). I have no idea how it will compare vs. the clone-and-remove approach.

Happy coding -- and post some results ;-)

Actually, on further thinking, I believe this has slightly better bounds than the method in the post: O(|A|) vs O(|A| + |B|). I have no idea if this will make any difference (or improvement) in actuality and I would only expect it to be relevant when |A| <<< |B|.

Okay, so I was really bored. At least on JDK 7 (Windows 7 x64), it appears the method in presented in the post is slower than the above approach -- by a good (albeit what appears to be mostly constant) factor. My eye-ball guesstimate says it is about four times as slow than the above suggestion that just uses a counter and twice as slow of when creating a new HashSet. This seems to be "roughly consistent" across the different initial set sizes.

(Please keep in mind that, as Voo pointed out, the numbers above and this micro-benchmark assume a HashSet is being used! And, as always, there are dangers with micro-benchmarks. YMMV.)

Here are the ugly results (times in milliseconds):

Running tests for 1x1
IntersectTest$PostMethod@6cc2060e took 13.9808544 count=1000000
IntersectTest$MyMethod1@7d38847d took 2.9893732 count=1000000
IntersectTest$MyMethod2@9826ac5 took 7.775945 count=1000000
Running tests for 1x10
IntersectTest$PostMethod@67fc9fee took 12.4647712 count=734000
IntersectTest$MyMethod1@7a67f797 took 3.1567252 count=734000
IntersectTest$MyMethod2@3fb01949 took 6.483941 count=734000
Running tests for 1x100
IntersectTest$PostMethod@16675039 took 11.3069326 count=706000
IntersectTest$MyMethod1@58c3d9ac took 2.3482693 count=706000
IntersectTest$MyMethod2@2207d8bb took 4.8687103 count=706000
Running tests for 1x1000
IntersectTest$PostMethod@33d626a4 took 10.28656 count=729000
IntersectTest$MyMethod1@3082f392 took 2.3478658 count=729000
IntersectTest$MyMethod2@65450f1f took 4.109205 count=729000
Running tests for 10x2
IntersectTest$PostMethod@55c4d594 took 10.4137618 count=736000
IntersectTest$MyMethod1@6da21389 took 2.374206 count=736000
IntersectTest$MyMethod2@2bb0bf9a took 4.9802039 count=736000
Running tests for 10x10
IntersectTest$PostMethod@7930ebb took 25.811083 count=4370000
IntersectTest$MyMethod1@47ac1adf took 6.9409306 count=4370000
IntersectTest$MyMethod2@74184b3b took 14.2603248 count=4370000
Running tests for 10x100
IntersectTest$PostMethod@7f423820 took 25.0577691 count=4251000
IntersectTest$MyMethod1@5472fe25 took 6.1376042 count=4251000
IntersectTest$MyMethod2@498b5a73 took 13.9880385 count=4251000
Running tests for 10x1000
IntersectTest$PostMethod@3033b503 took 25.0312716 count=4138000
IntersectTest$MyMethod1@12b0f0ae took 6.0932898 count=4138000
IntersectTest$MyMethod2@1e893918 took 13.8332505 count=4138000
Running tests for 100x1
IntersectTest$PostMethod@6366de01 took 9.4531628 count=700000
IntersectTest$MyMethod1@767946a2 took 2.4284762 count=700000
IntersectTest$MyMethod2@140c7272 took 4.7580235 count=700000
Running tests for 100x10
IntersectTest$PostMethod@3351e824 took 24.9788668 count=4192000
IntersectTest$MyMethod1@465fadce took 6.1462852 count=4192000
IntersectTest$MyMethod2@338bd37a took 13.1742654 count=4192000
Running tests for 100x100
IntersectTest$PostMethod@297630d5 took 193.0121077 count=41047000
IntersectTest$MyMethod1@e800537 took 45.2652397 count=41047000
IntersectTest$MyMethod2@76d66550 took 120.8494766 count=41047000
Running tests for 100x1000
IntersectTest$PostMethod@33576738 took 199.6269531 count=40966000
IntersectTest$MyMethod1@2f39a7dd took 45.5255814 count=40966000
IntersectTest$MyMethod2@723bb663 took 122.1704975 count=40966000
Running tests for 1x1
IntersectTest$PostMethod@35e3bdb5 took 9.5598373 count=1000000
IntersectTest$MyMethod1@7abbd1b6 took 2.6359174 count=1000000
IntersectTest$MyMethod2@40c542ad took 6.1091794 count=1000000
Running tests for 1x10
IntersectTest$PostMethod@3c33a0c5 took 9.4648528 count=733000
IntersectTest$MyMethod1@61800463 took 2.302116 count=733000
IntersectTest$MyMethod2@1ba03197 took 5.4803628 count=733000
Running tests for 1x100
IntersectTest$PostMethod@71b8da5 took 9.4971057 count=719000
IntersectTest$MyMethod1@21f04f48 took 2.2983538 count=719000
IntersectTest$MyMethod2@27e51160 took 5.3926902 count=719000
Running tests for 1x1000
IntersectTest$PostMethod@2fe7106a took 9.4702331 count=692000
IntersectTest$MyMethod1@6ae6b7b7 took 2.3013066 count=692000
IntersectTest$MyMethod2@51278635 took 5.4488882 count=692000
Running tests for 10x2
IntersectTest$PostMethod@223b2d85 took 9.5660879 count=743000
IntersectTest$MyMethod1@5b298851 took 2.3481445 count=743000
IntersectTest$MyMethod2@3b4ac99 took 4.8268489 count=743000
Running tests for 10x10
IntersectTest$PostMethod@51c700a0 took 23.0709476 count=4326000
IntersectTest$MyMethod1@5ffa3251 took 5.5460785 count=4326000
IntersectTest$MyMethod2@22fd9511 took 13.4853948 count=4326000
Running tests for 10x100
IntersectTest$PostMethod@46b49793 took 25.1295491 count=4256000
IntersectTest$MyMethod1@7a4b5828 took 5.8520418 count=4256000
IntersectTest$MyMethod2@6888e8d1 took 14.0856942 count=4256000
Running tests for 10x1000
IntersectTest$PostMethod@5339af0d took 25.1752685 count=4158000
IntersectTest$MyMethod1@7013a92a took 5.7978328 count=4158000
IntersectTest$MyMethod2@1ac73de2 took 13.8914112 count=4158000
Running tests for 100x1
IntersectTest$PostMethod@3d1344c8 took 9.5123442 count=717000
IntersectTest$MyMethod1@3c08c5cb took 2.34665 count=717000
IntersectTest$MyMethod2@63f1b137 took 4.907277 count=717000
Running tests for 100x10
IntersectTest$PostMethod@71695341 took 24.9830339 count=4180000
IntersectTest$MyMethod1@39d90a92 took 5.8467864 count=4180000
IntersectTest$MyMethod2@584514e9 took 13.2197964 count=4180000
Running tests for 100x100
IntersectTest$PostMethod@21b8dc91 took 195.1796213 count=41060000
IntersectTest$MyMethod1@6f98c4e2 took 44.5775162 count=41060000
IntersectTest$MyMethod2@16a60aab took 121.1754402 count=41060000
Running tests for 100x1000
IntersectTest$PostMethod@20b37d62 took 200.973133 count=40940000
IntersectTest$MyMethod1@67ecbdb3 took 45.4832226 count=40940000
IntersectTest$MyMethod2@679a6812 took 121.791293 count=40940000
Running tests for 1x1
IntersectTest$PostMethod@237aa07b took 9.2210288 count=1000000
IntersectTest$MyMethod1@47bdfd6f took 2.3394042 count=1000000
IntersectTest$MyMethod2@a49a735 took 6.1688936 count=1000000
Running tests for 1x10
IntersectTest$PostMethod@2b25ffba took 9.4103967 count=736000
IntersectTest$MyMethod1@4bb82277 took 2.2976994 count=736000
IntersectTest$MyMethod2@25ded977 took 5.3310813 count=736000
Running tests for 1x100
IntersectTest$PostMethod@7154a6d5 took 9.3818786 count=704000
IntersectTest$MyMethod1@6c952413 took 2.3014931 count=704000
IntersectTest$MyMethod2@33739316 took 5.3307998 count=704000
Running tests for 1x1000
IntersectTest$PostMethod@58334198 took 9.3831841 count=736000
IntersectTest$MyMethod1@d178f65 took 2.3071236 count=736000
IntersectTest$MyMethod2@5c7369a took 5.4062184 count=736000
Running tests for 10x2
IntersectTest$PostMethod@7c4bdf7c took 9.4040537 count=735000
IntersectTest$MyMethod1@593d85a4 took 2.3584088 count=735000
IntersectTest$MyMethod2@5610ffc1 took 4.8318229 count=735000
Running tests for 10x10
IntersectTest$PostMethod@46bd9fb8 took 23.004925 count=4331000
IntersectTest$MyMethod1@4b410d50 took 5.5678172 count=4331000
IntersectTest$MyMethod2@1bd125c9 took 14.6517184 count=4331000
Running tests for 10x100
IntersectTest$PostMethod@75d6ecff took 25.0114913 count=4223000
IntersectTest$MyMethod1@716195c9 took 5.798676 count=4223000
IntersectTest$MyMethod2@3db0f946 took 13.8064737 count=4223000
Running tests for 10x1000
IntersectTest$PostMethod@761d8e2a took 25.1910652 count=4292000
IntersectTest$MyMethod1@e60a3fb took 5.8621189 count=4292000
IntersectTest$MyMethod2@6aadbb1c took 13.8150282 count=4292000
Running tests for 100x1
IntersectTest$PostMethod@48a50a6e took 9.4141906 count=736000
IntersectTest$MyMethod1@4b4fe104 took 2.3507252 count=736000
IntersectTest$MyMethod2@693df43c took 4.7506854 count=736000
Running tests for 100x10
IntersectTest$PostMethod@4f7d29df took 24.9574096 count=4219000
IntersectTest$MyMethod1@2248183e took 5.8628954 count=4219000
IntersectTest$MyMethod2@2b2fa007 took 12.9836817 count=4219000
Running tests for 100x100
IntersectTest$PostMethod@545d7b6a took 193.2436192 count=40987000
IntersectTest$MyMethod1@4551976b took 44.634367 count=40987000
IntersectTest$MyMethod2@6fac155a took 119.2478037 count=40987000
Running tests for 100x1000
IntersectTest$PostMethod@7b6c238d took 200.4385174 count=40817000
IntersectTest$MyMethod1@78923d48 took 45.6225227 count=40817000
IntersectTest$MyMethod2@48f57fcf took 121.0602757 count=40817000
Running tests for 1x1
IntersectTest$PostMethod@102c79f4 took 9.0931408 count=1000000
IntersectTest$MyMethod1@57fa8a77 took 2.3309466 count=1000000
IntersectTest$MyMethod2@198b7c1 took 5.7627226 count=1000000
Running tests for 1x10
IntersectTest$PostMethod@8c646d0 took 9.3208571 count=726000
IntersectTest$MyMethod1@11530630 took 2.3123797 count=726000
IntersectTest$MyMethod2@61bb4232 took 5.405318 count=726000
Running tests for 1x100
IntersectTest$PostMethod@1a137105 took 9.387384 count=710000
IntersectTest$MyMethod1@72610ca2 took 2.2938749 count=710000
IntersectTest$MyMethod2@41849a58 took 5.3865938 count=710000
Running tests for 1x1000
IntersectTest$PostMethod@100001c8 took 9.4289031 count=696000
IntersectTest$MyMethod1@7074f9ac took 2.2977923 count=696000
IntersectTest$MyMethod2@fb3c4e2 took 5.3724119 count=696000
Running tests for 10x2
IntersectTest$PostMethod@52c638d6 took 9.4074124 count=775000
IntersectTest$MyMethod1@53bd940e took 2.3544881 count=775000
IntersectTest$MyMethod2@43434e15 took 4.9228549 count=775000
Running tests for 10x10
IntersectTest$PostMethod@73b7628d took 23.2110252 count=4374000
IntersectTest$MyMethod1@ca75255 took 5.5877838 count=4374000
IntersectTest$MyMethod2@3d0e50f0 took 13.5902641 count=4374000
Running tests for 10x100
IntersectTest$PostMethod@6d6bbba9 took 25.1999918 count=4227000
IntersectTest$MyMethod1@3bed8c5e took 5.7879144 count=4227000
IntersectTest$MyMethod2@689a8e0e took 13.9617882 count=4227000
Running tests for 10x1000
IntersectTest$PostMethod@3da3b0a2 took 25.1627329 count=4222000
IntersectTest$MyMethod1@45a17b4b took 5.8319523 count=4222000
IntersectTest$MyMethod2@6ca59ca3 took 13.8885479 count=4222000
Running tests for 100x1
IntersectTest$PostMethod@360202a5 took 9.5115367 count=705000
IntersectTest$MyMethod1@3dfbba56 took 2.3470254 count=705000
IntersectTest$MyMethod2@598683e4 took 4.8955489 count=705000
Running tests for 100x10
IntersectTest$PostMethod@21426d0d took 25.8234298 count=4231000
IntersectTest$MyMethod1@1005818a took 5.8832067 count=4231000
IntersectTest$MyMethod2@597b933d took 13.3676148 count=4231000
Running tests for 100x100
IntersectTest$PostMethod@6d59b81a took 193.676662 count=41015000
IntersectTest$MyMethod1@1d45eb0c took 44.6519088 count=41015000
IntersectTest$MyMethod2@594a6fd7 took 119.1646115 count=41015000
Running tests for 100x1000
IntersectTest$PostMethod@6d57d9ac took 200.1651432 count=40803000
IntersectTest$MyMethod1@2293e349 took 45.5311168 count=40803000
IntersectTest$MyMethod2@1b2edf5b took 120.1697135 count=40803000

And here is the ugly (and possibly flawed) micro-benchmark:

import java.util.*;

public class IntersectTest {

    static Random rng = new Random();

    static abstract class RunIt {
        public long count;
        public long nsTime;
        abstract int Run (Set<Long> s1, Set<Long> s2);

    // As presented in the post
    static class PostMethod extends RunIt {
        public int Run(Set<Long> set1, Set<Long> set2) {
            boolean set1IsLarger = set1.size() > set2.size();
            Set<Long> cloneSet = new HashSet<Long>(set1IsLarger ? set2 : set1);
            cloneSet.retainAll(set1IsLarger ? set1 : set2);
            return cloneSet.size();

    // No intermediate HashSet
    static class MyMethod1 extends RunIt {
        public int Run (Set<Long> set1, Set<Long> set2) {
            Set<Long> a;
            Set<Long> b;
            if (set1.size() <= set2.size()) {
                a = set1;
                b = set2;           
            } else {
                a = set2;
                b = set1;
            int count = 0;
            for (Long e : a) {
                if (b.contains(e)) {
            return count;

    // With intermediate HashSet
    static class MyMethod2 extends RunIt {
        public int Run (Set<Long> set1, Set<Long> set2) {
            Set<Long> a;
            Set<Long> b;
            Set<Long> res = new HashSet<Long>();
            if (set1.size() <= set2.size()) {
                a = set1;
                b = set2;           
            } else {
                a = set2;
                b = set1;
            for (Long e : a) {
                if (b.contains(e)) {
            return res.size();

    static Set<Long> makeSet (int count, float load) {
        Set<Long> s = new HashSet<Long>();
        for (int i = 0; i < count; i++) {
            s.add((long)rng.nextInt(Math.max(1, (int)(count * load))));                     
        return s;

    // really crummy ubench stuff
    public static void main(String[] args) {
        int[][] bounds = {
                {1, 1},
                {1, 10},
                {1, 100},
                {1, 1000},
                {10, 2},
                {10, 10},
                {10, 100},
                {10, 1000},
                {100, 1},
                {100, 10},
                {100, 100},
                {100, 1000},
        int totalReps = 4;
        int cycleReps = 1000;
        int subReps = 1000;
        float load = 0.8f;
        for (int tc = 0; tc < totalReps; tc++) {
            for (int[] bound : bounds) {
                int set1size = bound[0];
                int set2size = bound[1];
                System.out.println("Running tests for " + set1size + "x" + set2size);               
                ArrayList<RunIt> allRuns = new ArrayList<RunIt>(
                                new PostMethod(),
                                new MyMethod1(),
                                new MyMethod2()));
                for (int r = 0; r < cycleReps; r++) {
                    ArrayList<RunIt> runs = new ArrayList<RunIt>(allRuns);
                    Set<Long> set1 = makeSet(set1size, load);
                    Set<Long> set2 = makeSet(set2size, load);
                    while (runs.size() > 0) {
                        int runIdx = rng.nextInt(runs.size());
                        RunIt run = runs.remove(runIdx);
                        long start = System.nanoTime();
                        int count = 0;
                        for (int s = 0; s < subReps; s++) {
                            count += run.Run(set1, set2); 
                        long time = System.nanoTime() - start;
                        run.nsTime += time;
                        run.count += count;
                for (RunIt run : allRuns) {
                    double sec = run.nsTime / (10e6);
                    System.out.println(run + " took " + sec + " count=" + run.count);
  • Well depends on what kind of set we're talking about. Your complexities seem to assume a HashSet in which case I agree that we can't get more efficient than that
    – Voo
    Sep 27, 2011 at 22:43
  • @Voo Yes, I did assume a HashSet -- good call. (All of the above post assumes a HashSet.)
    – user166390
    Sep 27, 2011 at 23:14
  • 9
    Thanks for doing all this analysis. But to improve your answer, can you actually post the method which won in your benchmarks (ie. MyMethod1) This will save people from having to read through all of the benchmark results. THanks!
    – jasop
    Jul 19, 2012 at 7:46

Just use Google Guava's Sets#intersection(Set, Set) method.

  • +1 Agree, though behind the scenes it pretty much does what the OP's approach does, albeit without copying. Sep 27, 2011 at 19:07
  • Do you have any knowledge of the efficiency of this?
    – Ina
    Sep 27, 2011 at 19:12
  • 2
    @Ina it's open source, so you can see for yourself: code.google.com/p/guava-libraries/source/browse/src/com/google/…
    – Matt Ball
    Sep 27, 2011 at 19:19
  • 16
    Oh, Google. How many SO questions begin with "what is the most efficient way to do X" and end with Google Guava? Aug 20, 2013 at 1:55

Can the members of the sets be easily mapped into a relatively small range of integers? If so, consider using BitSets. Intersection then is just bitwise and's - 32 potential members at a time.


You can avoid all manual work by using the Set method retainAll().

From docs:

s1.retainAll(s2) — transforms s1 into the intersection of s1 and s2. (The intersection of two sets is the set containing only the elements common to both sets.)

  • 3
    set.retainAll() is present in my question, and called alone would modify the original sets, which is why I present the approach of first cloning the smaller set, then calling .retainAll() on the larger set. I was looking for alternative solutions, see other answers for some useful ones.
    – Ina
    Jan 29, 2013 at 19:13
  • yeah, sorry about that. I didn't realize that retainAll was in your original question. I'm currently having an issue when the set passed to retainAll is empty, it results in a no-op (i.e the "this" set is unmodified after the call. :(
    – Joel
    Jan 29, 2013 at 19:25
  • Really? I can't reproduce that. Set<String> a = new HashSet<String>(); a.add("Hello"); a.retainAll(new HashSet<String>()); System.out.println(a.size()); // prints 0
    – Ina
    Jan 29, 2013 at 20:04

If both sets can be sorted, like TreeSet running both iterators could be a faster way to count the number of shared objects.

If you do this operation often, it might bring a lot if you can wrap the sets so that you can cache the result of the intersection operation keeping a dirty flag to track validity of the cached result, calculating again if needed.


Using Java 8 stream:

set1.stream().filter(s -> set2.contains(s)).collect(Collectors.toList());

If you are computing the intersection just for the sake of counting how many elements are there in the set, I suggest you just need to count the intersection directly instead of building the set and then calling size().

My function for counting:

 * Computes the size of intersection of two sets
 * @param small first set. preferably smaller than the second argument
 * @param large second set;
 * @param <T> the type
 * @return size of intersection of sets
public <T> int countIntersection(Set<T> small, Set<T> large){
    //assuming first argument to be smaller than the later;
    //however double checking to be sure
    if (small.size() > large.size()) {
        //swap the references;
        Set<T> tmp = small;
        small = large;
        large = tmp;
    int result = 0;
    for (T item : small) {
        if (large.contains(item)){
            //item found in both the sets
    return result;

That is a good approach. You should be getting O(n) performance from your current solution.

  • Not O(n), O(n*m) where n,m sizes of sets Sep 28, 2011 at 8:18
  • 2
    Population of initial set = O(n). Iterate that for O(n) and look up in the HASH SET for O(1). Result is O(n) + (O(n) * O(1)) = O(2n) = O(n). You're thinking of the simplistic solution to list intersection @Artiom. Sep 28, 2011 at 14:05

FYI, if any collection of sets are all sorted using the same comparision relation, then you can iterate their intersection in time N * M, where N is the size of the smallest set and M is the number of sets.

Implementation left as exercise to reader. Here's an example.


Intersection counting through streams/reduce (it assumes you figure out which set is larger before calling it):

public int countIntersect(Set<Integer> largerSet, Set<Integer> smallerSet){
    return smallerSet.stream().reduce(0, (a,b) ->  largerSet.contains(b)?a+1:a);

However somewhere else I have read that no java code can be faster than the Set methods for set operations because they are implemented as native code instead of java code. Therefore I back up the suggestion to try BitSet to achieve faster results.

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