# how to create a collection with O(1) complexity

I would like to create a data structure or collection which will have O(1) complexity in adding, removing and calculating no. of elements. How am I supposed to start?

I have thought of a solution: I will use a Hashtable and for each key / value pair inserted, I will have only one hash code, that is: my hash code algorithm will generate a unique hash value every time, so the index at which the value is stored will be unique (i.e. no collisions).

Will that give me O(1) complexity?

-
"my hashcode algorithm will generate unique hash value every time" - I think a lot of people would be interested to see the source code of such a hashcode algorithm ;-) Note that in real life, you are mapping a potentially infinite number of different objects to a finite number of hash codes so the chance of collision is practically never 0 (except some special cases). – Péter Török Jul 28 '10 at 13:05
I have a unique hash algorithm for storing 32-bit integers. Hash(i)==i :) – SWeko Jul 28 '10 at 13:08
I know of such an algorithm too. The problem is that it takes `O(N)` space :-) – Stephen C Jul 28 '10 at 13:12
Do you know all possible keys in advance? You can build a perfect hash if you do. – Constantin Jul 28 '10 at 13:24
@Constantin, as Stephen says. I know all the possible values of a long. Does that mean I can build a non-colliding 32-bit hash for Long? – Mark Peters Jul 28 '10 at 15:26

Yes that will work, but as you mentioned your hashing function needs to be 100% unique. Any duplicates will result in you having to use some sort of conflict resolution. I would recommend linear chaining.

edit: Hashmap.size() allows for O(1) access

edit 2: Respopnse to the confusion Larry has caused =P

Yes, Hashing is O(k) where k is the keylength. Everyone can agree on that. However, if you do not have a perfect hash, you simply cannot get O(1) time. Your claim was that you do not need uniqueness to acheive O(1) deletion of a specific element. I guarantee you that is wrong.

Consider a worst case scenario: every element hashes to the same thing. You end up with a single linked list which as everyone knows does not have O(1) deletion. I would hope, as you mentioned, nobody is dumb enough to make a hash like this.

Point is, uniqueness of the hash is a prerequisite for O(1) runtime.

Even then, though, it is technically not O(1) Big O efficiency. Only using amortized analysis you will acheive constant time efficiency in the worst case. As noted on wikipedia's article on amortized analysis

The basic idea is that a worst case operation can alter the state in such a way that the worst case cannot occur again for a long time, thus "amortizing" its cost.

That is referring to the idea that resizing your hashtable (altering the state of your data structure) at certain load factors can ensure a smaller chance of collisions etc.

I hope this clears everything up.

-
Good thing there isn't such a thing as a `size()` method, no sirree! And it would definitely not have been in there since the creation of the `HashMap` type back in Java 1.2. After all, that would prove you wrong… – Donal Fellows Jul 28 '10 at 13:21
– NickHalden Jul 28 '10 at 13:34
Why not edit your answer than, so everyone can see that directly... ;-) – dertoni Jul 28 '10 at 14:27
hashing doesn't need to be 100% unique -- I think the questioner doesn't understand O(1) or hashing because it is O(1) even without uniqueness – Larry Watanabe Jul 28 '10 at 15:12
@Larry: you've posted this nonsense in a few different places, but I don't think YOU understand how a hash table will function as you approach 100% probability of collisions. – Mark Peters Jul 28 '10 at 15:31

Adding, Removing and Size (provided it is tracked separately, using a simple counter) can be provided by a linked list. Unless you need to remove a specific item. You should be more specific about your requirements.

-

Doing a totally non-clashing hash function is quite tricky even when you know exactly the space of things being hashed, and it's impossible in general. It also depends deeply on the size of the array that you're hashing into. That is, you need to know exactly what you're doing to make that work.

But if you instead relax that a bit so that identical hash codes don't imply equality1, then you can use the existing Java `HashMap` framework for all the other parts. All you need to do is to plug in your own `hashCode()` implementation in your key class, which is something that Java has always supported. And make sure that you've got equality defined right too. At that point, you've got the various operations being not much more expensive than O(1), especially if you've got a good initial estimation for the capacity and load factor.

1 Equality must imply equal hash codes, of course.

-
it isn't "not much more expensive than O(1)", it is exactly O(1). But +1 because everything else is correct. – Larry Watanabe Jul 28 '10 at 15:11
@Larry: That depends on your hashCode implementation, really. You will not get O(1) efficiency out of a hashCode that is defined as `return 42;`. But in the OP's case apparently it's well distributed so not an issue here. – Mark Peters Jul 28 '10 at 15:22
@Larry: It's not exactly O(1) but the difference is really complicated and the net effect is pretty similar. With a good hash function and a not too heavily loaded hash, it's good enough. – Donal Fellows Jul 28 '10 at 15:44
@Donal: I think hashing is exactly O(1) – Larry Watanabe Jul 29 '10 at 0:47
@Larry: It's actually O(k) where k is the key length (for short keys, no big deal, for long keys, important) plus a complicated term that depends on the exact nature of the hash table and which takes into account collisions. Basically, rebuilding the hash table to be bigger is a win once collisions become frequent enough, but it is quite a costly operation. – Donal Fellows Jul 29 '10 at 12:21

Even if your hashcodes are unique this doesn't guarentee a collision free collection. This is because your hash map is not of an unlimited size. The hashcode has to be reduced to the number of buckets in your hash map and after this reduction you can still get collisions.

e.g. Say I have three objects A (hash: 2), B (hash: 18), C (hash: 66) All unique. Say you put them in a HashMap of with a capacity of 16 (the default). If they were mapped to a bucket with % 16 (actually is more complex that this) after reducing the hash codes we now have A (hash: 2 % 16 = 2), B (hash: 18 % 16 = 2), C (hash: 66 % 16 = 2)

HashMap is likely to be faster than Hashtable, unless you need thread safety. (In which case I suggest you use CopncurrentHashMap) IMHO, Hashtable has been a legacy collection for 12 years, and I would suggest you only use it if you have to.

-

What functionality do you need that a linked list won't give you?

-
Removing in O(1) time? -1. – Mark Peters Jul 28 '10 at 15:23
A linked list which stores a reference to the head can act as a stack with O(1) for push/pop/size. Add a reference to the tail and it can be a queue with O(1) for enqueue/dequeue/size. OP did not specify random access, just O(1) for add/remove/size. – Brian S Jul 28 '10 at 16:22
Alright, I see where you're coming from though I don't think that remove operation is what the OP was going for. I would have specifically said queue or stack in that case though. Unfortunately can't remove the d/v. – Mark Peters Jul 28 '10 at 17:12

Surprisingly, your idea will work, if you know all the keys you want to put in the collection in advance. The idea is to generate a special hash function which maps each key to a unique value in the range `(1, n)`. Then our "hash table" is just a simple array (+ an integer to cache the number of elements)

Implementing this is not trivial, but it's not rocket science either. I'll leave it to Steve Hanov to explain the ins-and-outs, as he gives a much better explanation than I ever could.

-

It's simple. Just use a hash map. You don't need to do anything special. Hashmap itself is O(1) for insertion, deletion, calculating number of elements.

Even if the keys are not unique, the algorithm will still be O(1) as long as the Hashmap is automatically expanded in size if the collection gets too large (most implementations will do this for you automatically).

So, just use the Hash map according to the given documentation, and all will be well. Don't think up anything more complicated, it will just be a waste of time.

Avoiding collisions is really impossible with a hash .. if it was possible, then it would basically just be an array or a mapping to an array, not a hash. But it isn't necessary to avoid collisions, it will still be O(1) with collisions.

-
It isn't necessary to avoid collisions? Everything collides and you degenerate to `O(N)` searches. Making hash tables collision-resistant is definitely important. – Justin Ardini Jul 28 '10 at 15:21
With respect to automatically increasing the size, I could be wrong but isn't that only O(1) using amortized analysis? Also, if you are using linear chaining as your collision system and you do not have a unique hash function, how can you claim it's still O(1) to remove a specific element? Your buckets would essentially devolve into linked lists. Unless I'm missing something about the Java Hashmap implementation removing would not be O(1) without a 100% unique hashing function. – NickHalden Jul 28 '10 at 15:32
-1. It has everything to do with the quality of your hash. – Mark Peters Jul 28 '10 at 15:32
unless you do something pretty dumb, like use a mod function, it isn't hard to come up with a good hash. The defaults used in the libraries should be good enough @JGord - try looking up Aho's algorithms book - actually any algorithm book - they will clearly tell you that hashing is O(1). – Larry Watanabe Jul 29 '10 at 0:49
@Larry: It's not difficult to make a good hash, but it's also really simple to make a really bad one. I once saw an implementation of a point class (int x, int y) that internally stored a long using the high bits for x, low bits for y. They thought, "oh, why not use Long's implementation of hashCode?" Trouble is, when there is correspondence between the high bits and low bits it's a terrible hash. Hashing every point between 0 and 1000 for x and y produces a 1024 unique hashes out of 1000000 combinations...a collision rate of 99.9% – Mark Peters Jul 29 '10 at 14:02