I agree with:

- the general amortized complexity of O(1)
- a bad
`hashCode()`

implementation could result to multiple collisions, which means that in the worst case every object goes to the same bucket, thus O(*N*) if each bucket is backed by a `List`

.
- since Java 8,
`HashMap`

dynamically replaces the Nodes (linked list) used in each bucket with TreeNodes (red-black tree when a list gets bigger than 8 elements) resulting to a worst performance of O(*logN*).

But, this is **not** the full truth if we want to be 100% precise. The implementation of `hashCode()`

and the type of key `Object`

(immutable/cached or being a Collection) might also affect real time complexity in strict terms.

Let's assume the following three cases:

`HashMap<Integer, V>`

`HashMap<String, V>`

`HashMap<List<E>, V>`

Do they have the same complexity? Well, the amortised complexity of the 1st one is, as expected, O(1). But, for the rest, we also need to compute `hashCode()`

of the lookup element, which means we might have to traverse arrays and lists in our algorithm.

Lets assume that the size of all of the above arrays/lists is *k*.
Then, `HashMap<String, V>`

and `HashMap<List<E>, V>`

will have O(k) amortised complexity and similarly, O(*k + logN*) worst case in Java8.

*Note that using a `String`

key is a more complex case, because it is immutable and Java caches the result of `hashCode()`

in a private variable `hash`

, so it's only computed once.

```
/** Cache the hash code for the string */
private int hash; // Default to 0
```

But, the above is also having its own worst case, because Java's `String.hashCode()`

implementation is checking if `hash == 0`

before computing `hashCode`

. But hey, there are non-empty Strings that output a `hashcode`

of zero, such as "f5a5a608", see here, in which case memoization might not be helpful.

amortizedO(1) -- never forget that first part and you won't have these kinds of questions :) – Engineer Jan 3 '14 at 10:52