# HashMap implementation in Java. How does the bucket index calculation work?

I am looking at the implementation of `HashMap` in Java and am stuck at one point.
How is the `indexFor` function calculated?

``````static int indexFor(int h, int length) {
return h & (length-1);
}
``````

Thanks

It's not calculating the hash, it's calculating the bucket.

The expression `h & (length-1)` does a bit-wise `AND` on `h` using `length-1`, which is like a bit-mask, to return only the low-order bits of `h`, thereby making for a super-fast variant of `h % length`.

• Can you please explain this calculation here ? – gnreddy Jun 4 '12 at 9:48
• Does this assume that `length` is a power of 2? – LarsH Sep 14 '12 at 18:00
• @LarsH Well, it would be far better if it was a power of 2, then you'd get a clean chop off of the high-order bits. As it happens, the implementation of HashMap starts with size 16 and does indeed multiply by two when resizing. It would still work if not a power of two, but you would want as many bits "on" as possible for `length -1` to balance the spread between buckets – Bohemian Sep 15 '12 at 2:07

The hash itself is calculated by the `hashCode()` method of the object you're trying to store.

What you see here is calculating the "bucket" to store the object based on the hash `h`. Ideally, to evade collisions, you would have the same number of buckets as is the maximum achievable value of `h` - but that could be too memory demanding. Therefore, you usually have a lower number of buckets with a danger of collisions.

If `h` is, say, 1000, but you only have 512 buckets in your underlying array, you need to know where to put the object. Usually, a `mod` operation on `h` would be enough, but that's too slow. Given the internal property of `HashMap` that the underlying array always has number of buckets equal to `2^n`, the Sun's engineers could use the idea of `h & (length-1)`, it does a bitwise AND with a number consisting of all `1`'s, practically reading only the `n` lowest bits of the hash (which is the same as doing `h mod 2^n`, only much faster).

Example:

``````     hash h: 11 1110 1000  -- (1000 in decimal)
length l: 10 0000 0000  -- ( 512 in decimal)
(l-1): 01 1111 1111  -- ( 511 in decimal - it will always be all ONEs)
h AND (l-1): 01 1110 1000  -- ( 488 in decimal which is a result of 1000 mod 512)
``````
• Does it make sense now, or should I elaborate more on the internals? – Petr Janeček Jun 4 '12 at 10:16
• Very well explained. I'm impressed. – Louis Wasserman Jun 4 '12 at 11:29
• got it .... thanks – gnreddy Jun 4 '12 at 11:39
• Amazing explanation – JavaDeveloper Oct 13 '13 at 20:08
• Does this mean that a hash bucket could contain keys with different `hashCodes` if the lowest 9 or so bits agree, but the higher bits are different? – Paul Boddington Apr 15 '15 at 11:17

It is calculating the bucket of the hash map where the entry (key-value pair) will be stored. The bucket id is `hashvalue/buckets length`.

A hash map consists of buckets; objects will be placed in these buckets based on the bucket id.

Any number of objects can actually fall into the same bucket based on their `hash code / buckets length` value. This is called a 'collision'.

If many objects fall into the same bucket, while searching their equals() method will be called to disambiguate.

The number of collisions is indirectly proportional to the bucket's length.

The above answer is very good but I want to explain more why Java can use `indexFor` for create index

Example, I have a `HashMap` like this (this test is on Java7, I see Java8 change HashMap a lot but I think this logic still very good)

``````// Default length of "budget" (table.length) after create is 16 (HashMap#DEFAULT_INITIAL_CAPACITY)
HashMap<String, Integer> hashMap = new HashMap<>();
hashMap.put("A",1); // hash("A")=69, indexFor(hash,table.length)=69&(16-1) = 5
hashMap.put("B",2); // hash("B")=70, indexFor(hash,table.length)=70&(16-1) = 6
hashMap.put("P",3); // hash("P")=85, indexFor(hash,table.length)=85&(16-1) = 5
hashMap.put("A",4); // hash("A")=69, indexFor(hash,table.length)=69&(16-1) = 5
hashMap.put("r", 4);// hash("r")=117, indexFor(hash,table.length)=117&(16-1) = 5
``````

You can see the index of entry with key `"A"` and object with key `"P"` and object with key `"r"` have same index (= 5). And here is the debug result after I execute code above

Table in the image is here

``````public class HashMap<K, V> extends AbstractMap<K, V> implements Map<K, V>, Cloneable, Serializable {
transient HashMap.Entry<K, V>[] table;
...
}
``````

=> I see
If index are different, new entry will add to table
If index is same and `hash` is same, new value will update
If index is same and `hash` is different, new entry will point to old entry (like a `LinkedList`). Then you know why `Map.Entry` have field `next`

``````static class Entry<K, V> implements java.util.Map.Entry<K, V> {
...
HashMap.Entry<K, V> next;
}
``````

You can verify it again by read the code in `HashMap`.

As now, you can think that `HashMap` will never need to change the size (16) because `indexFor()` always return value <= 15 but it not correct.
If you look at `HashMap` code

`````` if (this.size >= this.threshold ...) {
this.resize(2 * this.table.length);
``````

`HashMap` will resize table (double table length) when `size` >= `threadhold`

What is `threadhold`? `threadhold` is calculated below

``````static final int DEFAULT_INITIAL_CAPACITY = 16;
static final float DEFAULT_LOAD_FACTOR = 0.75F;
...
this.threshold = (int)Math.min((float)capacity * this.loadFactor, 1.07374182E9F); // if capacity(table.length) = 16 => threadhold = 12
``````

What is the `size`? `size` is calculated below.
Of course, `size` here is not `table.length` .
Any time you put new entry to `HashMap` and `HashMap` need to create new entry (note that `HashMap` don't create new entry when the key is same, it just override new value for existed entry) then `size++`

``````void createEntry(int hash, K key, V value, int bucketIndex) {
...
++this.size;
}
``````

Hope it help

bucket_index = (i.hashCode() && 0x7FFFFFFFF) % hashmap_size does the trick