# Why use 1<<4 instead of 16?

The OpenJDK code for `java.util.HashMap` includes the following line:

``````static final int DEFAULT_INITIAL_CAPACITY = 1 << 4; // aka 16
``````

Why is `1 << 4` used here, and not `16`? I'm curious.

• To explicitly show that it is a power of two, as the comment above it in `HashMap.java` says: `/* The default initial capacity - MUST be a power of two. */` Commented Mar 16, 2016 at 15:22
• When working with bit operations, it can be useful. It makes it more obvious that the binary representation is `0b10000`. Commented Mar 16, 2016 at 15:23
• And there's no other bit-flags being set like that? It's a very easy way to write bit-flags, especially when you come to higher bit-numbers For example, what would you rather write, `1 << 31` or `2147483648`? Commented Mar 16, 2016 at 15:24
• Also often used to indicate the constant is meant as a bit in a bitmask. Though this is not the reason here. Commented Mar 16, 2016 at 15:24

Writing `1 << 4` instead of 16 doesn't change the behavior here. It's done to emphasize that the number is a power of two, and not a completely arbitrary choice. It thus reminds developers experimenting with different numbers that they should stick to the pattern (e.g., use `1 << 3` or `1 << 5`, not `20`) so they don't break all the methods which rely on it being a power of two. There is a comment just above:

``````/**
* The default initial capacity - MUST be a power of two.
*/
static final int DEFAULT_INITIAL_CAPACITY = 1 << 4; // aka 16
``````

No matter how big a `java.util.HashMap` grows, its table capacity (array length) is maintained as a power of two. This allows the use of a fast bitwise AND operation (`&`) to select the bucket index where an object is stored, as seen in methods that access the table:

``````final Node<K,V> getNode(int hash, Object key) {
Node<K,V>[] tab; Node<K,V> first, e; int n; K k;
if ((tab = table) != null && (n = tab.length) > 0 &&
(first = tab[(n - 1) & hash]) != null) { /// <-- bitwise 'AND' here
...
``````

There, `n` is the table capacity, and `(n - 1) & hash` wraps the hash value to fit that range.

### More detail

A hash table has an array of 'buckets' (`HashMap` calls them `Node`), where each bucket stores zero or more key-value pairs of the map.

Every time we `get` or `put` a key-value pair, we compute the hash of the key. The hash is some arbitrary (maybe huge) number. Then we compute a bucket index from the hash, to select where the object is stored.

Hash values bigger than the number of buckets are "wrapped around" to fit the table. For example, with a table capacity of 100 buckets, the hash values 5, 105, 205, would all be stored in bucket 5. Think of it like degrees around a circle, or hours on a clock face.

(Hashes can also be negative. A value of -95 could correspond to bucket 5, or 95, depending on how it was implemented. The exact formula doesn't matter, so long as it distributes hashes roughly evenly among the buckets.)

If our table capacity `n` were not a power of two, the formula for the bucket would be `Math.abs(hash % n)`, which uses the modulo operator to calculate the remainder after division by `n`, and uses `abs` to fix negative values. That would work, but be slower.

Why slower? Imagine an example in decimal, where you have some random hash value 12,459,217, and an arbitrary table length of 1,234. It's not obvious that `12459217 % 1234` happens to be 753. It's a lot of long division. But if your table length is an exact power of ten, the result of `12459217 % 1000` is simply the last 3 digits: 217.

Written in binary, a power of two is a 1 followed by some number of 0s, so the equivalent trick is possible. For example, if the capacity `n` is decimal 16, that's binary 10000. So, `n - 1` is binary 1111, and `(n - 1) & hash` keeps only the last bits of the hash corresponding to those 1s, zeroing the rest. This also zeroes the sign bit, so the result cannot be negative. The result is from 0 to n-1, inclusive. That's the bucket index.

Even as CPUs get faster and their multimedia capabilities have improved, integer division is still one of the most expensive single-instruction operations you can do. It can be 50 times slower than a bitwise AND, and avoiding it in frequently executed loops can give real improvements.

• I would add that this type of best practice is related to produce a more self-explaining code, and avoid further more the use of magic numbers (stackoverflow.com/questions/47882/…). While here there is a constant use with an appropriate name, the value is also more reveiling this way. Commented Mar 20, 2016 at 16:32
• But why not instead do it the other way around?: `int value = 16; // 2^4`
– Lii
Commented Mar 20, 2019 at 12:59
• @Lii You can if you want to. It makes no difference to the compiler. Commented Mar 20, 2019 at 13:01

I can't read the developer's mind, but we do things like that to indicate a relationship between the numbers.

Compare this:

`int day = 86400;`

vs

`int day = 60 * 60 * 24; // 86400`

The second example clearly shows the relationship between the numbers, and Java is smart enough to compile that as a constant.

I think the reason is that the developer can very easy change the value (according to JavaDoc '/* The default initial capacity - MUST be a power of two. */') for example to `1 << 5` or `1 << 3` and he doesn't need to do any calculations.