9

How do I implement a good hashcode if there are two boolean fields? Usually people just add the integer values to their hashcode values. But if I simply add 1 or 0 to my hashcode, I do not think it is good. Because if I have two objects of class A:

obj1.b = true, obj1.c = false.

obj2.b = false, obj2.c = true.

Everyting else is the same. Then the hashcode for these two unequal objects are the same. I know this situation is okay. But imagine if there are 100 boolean fields, then there would be too much collision right? I do not want so many different objects to fall in the same bucket.

What I did below is to assign different numbers to different truth values for each field so objects hashcodes can be very different.

public class A {

    private final String a;
    private final boolean b;
    private final boolean c;

...

@Override public int hashCode(){
            int i,j;
            if(b) {
                    i = 10;
            }
            else {
                    i = 0;
            }
            if(c) {
                    j = 88;
            }
            else {
                    j = 3;
            }
            int result = 0;
            result = 31*result + i + j;
            result = 31*result + (a != null ? a.hashCode() : 0);
            return result;
    }
}
4

3 Answers 3

9

You have a couple of options:

Option 1: Bit flagging

The best way to guarantee that there can never be collisions between boolean hashes is to use a technique similar to the one used in bit flagging, whereby you have each boolean occupy its own bit. For example:

// `byte` can be replaced with `short`, `int`, or `long` to fit all of your variables.
byte booleans = 0;
if(bool1) booleans += 1;  // 0001
if(bool2) booleans += 2;  // 0010
if(bool3) booleans += 4;  // 0100
if(bool4) booleans += 8;  // 1000
...

However, this approach quickly becomes inefficient with a large number of booleans and is highly dependent on the size of the target array. For example, if you have a target array of size 16, only the first 4 have an effect on the hash value (since the maximum index is 1111).

The two solutions to this are to either increase the size of your target array (which might not be under your control), or ensure that the order of your booleans goes from most to least variadic. Neither of these are optimal, and so this method is quick and easy, but not very effective in practice.

Option 2: Base-changing hash

The design that Pham Trung shows in his answer expands on Option 1 as an easier way to accomodate multiple fields. As Adrian Shum commented, this answer provides an overview of a "general hashing algorithm" which is designed to be effective independent of what you are trying to hash.

The basic idea is to multiply a simplified hash value for each type by some arbitrarily large prime number to ensure that each hash is unique (though the proof for this eludes me). For example:

int result = 0;
result = 31*result + bool1 ? 1 : 0;
result = 31*result + bool2 ? 1 : 0;
...

For an even more sparse hash distribution, you can combine this with Boolean.hashCode, as the other answers show:

int result = 0;
result += 31*result + bool1.hashCode();
result += 31*result + bool2.hashCode();
...

What's great about this solution is that it can be applied to other types, like you already have in your sample code:

...
result = 31*result + i;
result = 31*result + (a != null ? a.hashCode() : 0);
result = 31*result + my_complex_object.hashCode();

Note: In these examples, 31 is just some arbitrary prime. You could just have easily used 37, 113, or 23456789. However, there are trade-offs for using larger multiplicands, namely that your hash will more quickly exceed Integer.MAX_VALUE and invalidate your hash.

7
  • 1
    -1 for option 1, which is not helping in OP's concern. i.e. if there are two boolean values involved in hashcode calculation, true+false and false+true will give same hashcode. Option 2 is not optimal either, given will easily goes to same bucket (for example, for hash map with capacity of 16, hashcode with the "result bitmap" being 00100001 and 11110001 will fall into same bucket). In short, option1 and 2 are example of poorly designed hashing algorithm Feb 25, 2015 at 1:18
  • @AdrianShum you're right. I had it in my mind that the values it used incremented every time it was called. I'll remove it. Feb 25, 2015 at 1:20
  • "option 2" in my original comment becomes the new "option 1", sorry for editing the comment not quick enough ;) Feb 25, 2015 at 1:27
  • @AdrianShum I see your point about the bitflagging option. However, you run into the same issue using the "base-changing" option as well. In that case with a hash of size 16, and a prime value of 31, you could end up with (F,F,T)=00000001 and (T,T,F)=11100001, both of which would again fall into the same bucket. Simply put, you will always have collisions if your range of potential values exceeds the size of the target array. If you want, I can add a note about the dependence of the success of the hash on the size of the target. Feb 25, 2015 at 3:40
  • I think you missed the point. Assuming you have 100 booleans in the hashcode calculation, with the "bitset" approach, only the least significant 5 booleans will determine which bucket it will go (in case of a hashmap of capacity of 16). That means, for some reason, if most data is having same value for that 5booleans, but very different for the other 95 booleans, they will still go to same bucket. That's why it is a poor hashing algorithm. However with the so-called base-changing approach, such effect is insignificant Feb 25, 2015 at 3:51
5

When you have two or even more booleans, the hashcode algorithm is already taken care of that.

Look a little bit closer:

// Very simple example
public int hashCode() {
    int result = 31;

    for(boolean val : booleanList) {
        // This is the important part:
        result = 31 * result + Boolean.hashCode(val);
    }

    return result;
}

Notice the main part of the for loop, in this case, we treat each boolean differently, as we always multiply the result by 31 (or any good prime number) before adding it into the result.

If we visualize the whole hashcode as a number of base 31, so we can understand that the position and the value of each boolean are all taken into account in the final result. Each boolean can be treated as a digit in the hashcode, so for case (true, false) and case (false, true), they will have two different hashcodes.

2
  • "Boolean.hashCode(val)": Non-static method 'hashCode()' cannot be referenced from a static context. Jan 22, 2018 at 14:40
  • @NagabhushanSN the static method Boolean.hashCode(boolean) was introduced in Java 8. Likely when you commented, you were using Java 7 or earlier. Oct 16, 2023 at 9:35
1

When combining multiple fields, a good practice is to start with the first field hashCode then multiply the current result by a prime number before adding each field hashcode:

@Override public int hashCode() {
  int result = 0;
  result = b1.hashCode();
  result = result * 37 + b2.hashCode();
  result = result * 37 + b3.hashCode();
  // ...
  // result = result * 37 + bn.hashCode();
  return result;
}

You can see a real world example in code generated by Wire (a Prococol Buffers implementation).

References:

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