What data structure to use here

Hashes provide an excellent mechanism to extract values corresponding to some given key in almost `O(1)` time. But it never preserves the order in which the keys are inserted. So is there any data structure which can simulate the best of array as well as hash, that is, return the value corresponding to a given key in `O(1)` time, as well as returning the `nth` value inserted in `O(1)` time? The ordering should be maintained, i.e., if the hash is `{a:1,b:2,c:3}`, and something like `del hash[b]` has been done, `nth(2)` should return `{c,3}`.

Examples:

``````hash = {};
hash[a] = 1;
hash[b] = 2;
hash[c] = 3;
nth(2); //should return 2
hash[d] = 4;
del hash[c];
nth(3); //should return 4, as 'd' has been shifted up
``````

Using modules like `TIE::Hash` or similar stuff won't do, the onus is on me to develop it from scratch!

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It depends on how much memory may be allocated for this data structure. For O(N) space there are several choices:

• It's easy to get a data structure with O(1) time for each of these operations: "get value by key", "get nth value inserted", "insert" - but only when "delete" time is O(N). Just use combination of a hash map and an array, as explained by ppeterka.
• Less obvious, but still simple is O(sqrt N) for "delete" and O(1) for all other operations.
• A little bit more complicated is to "delete" in O(N1/4), O(N1/6), or, in general case, in O(M*N1/M) time.
• It's, most likely, impossible to decrease "delete" time to O(log N) while retaining O(1) for other operations. But it is possible if you agree to O(log N) time for every operation. Solutions, based on binary search tree or on a skip list, allow it. One option is order statistics tree. You can augment every node of a binary search tree with a counter, storing number of elements in the sub-tree under this node; then use it to find nth node. Other option is to use Indexable skiplist. One more option is to use O(M*N1/M) solution with M=log(N).
• And I don't think you can get O(1) "delete" without increasing time for other operations even more.

If unlimited space is available, you can do every operation in O(1) time.

O(sqrt N) "delete"

You can use a combination of two data structures to find value by key and to find value by its insertion order. First one is a hash map (mapping key to both value and a position in other structure). Second one is tiered vector, which maps position to both value and key.

Tiered vector is a relatively simple data structure, it may be easily developed from scratch. Main idea is to split array into sqrt(N) smaller arrays, each of size sqrt(N). Each small array needs only O(sqrt N) time to shift values after deletion. And since each small array is implemented as circular buffer, small arrays can exchange a single element in O(1) time, which allows to complete "delete" operation in O(sqrt N) time (one such exchange for each sub-array between deleted value and first/last sub-array). Tiered vector allows insertion into the middle also in O(sqrt N), but this problem does not require it, so we can just append a new element at the end in O(1) time. To access element by its position, we need to determine starting position of circular buffer for sub-array, where element is stored, then get this element from circular buffer; this needs also O(1) time.

Since hash map remembers a position in tiered vector for each of its keys, it should be updated when any element in tiered vector changes position (O(sqrt N) hash map updates for each "delete").

O(M*N1/M) "delete"

To optimize "delete" operation even more, you can use approach, described in this answer. It deletes elements lazily and uses a trie to adjust element's position, taking into account deleted elements.

O(1) for every operation

You can use a combination of three data structures to do this. First one is a hash map (mapping key to both value and a position in the array). Second one is an array, which maps position to both value and key. And third one is a bit set, one bit for each element of the array.

"Insert" operation just adds one more element to the array's end and inserts it into hash map.

"Delete" operation just unsets corresponding bit in the bit set (which is initialized with every bit = 1). Also it deletes corresponding entry from hash map. (It does not move elements of array or bit set). If, after "delete" the bit set has more than some constant proportion of elements deleted (like 10%), the whole data structure should be re-created from scratch (this allows O(1) amortized time).

"Find by key" is trivial, only hash map is used here.

"Find by position" requires some pre-processing. Prepare a 2D array. One index is the position we search. Other index is current state of our data structure, the bit set, reinterpreted as an index. Calculate population count for each prefix of every possible bit set and store prefix length, indexed by both population count and the bit set itself. Having this 2D array ready, you can perform this operation by first indexing by position and current "state" in this 2D array, then by indexing in the array with values.

Time complexity for every operation is O(1) (for insert/delete it is O(1) amortized). Space complexity is O(N 2N).

In practice, using whole bit set to index an array limits allowed value of N by pointer size (usually 64), even more it is limited by available memory. To alleviate this, we can split both the array and the bit set into sub-arrays of size N/C, where C is some constant. Now we can use a smaller 2D array to find nth element in each sub-array. And to find nth element in the whole structure, we need additional structure to record number of valid elements in each sub-array. This is a structure of constant size C, so every operation on it is also O(1). This additional structure may me implemented as an array, but it is better to use some logarithmic-time structure like indexable skiplist. After this modification, time complexity for every operation is still O(1); space complexity is O(N 2N/C).

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Looks overly complicated. It's an interview question, surely they can't expect the candidate to come up with what which took an entire paper by eminent computer scientists to devise! Any other solution, perhaps? –  Cupidvogel Oct 24 '12 at 13:35
@Cupidvogel: I don't agree this is complicated. Both solutions use well-known components and may be explained in 1 minute. Here's otner solution, simpler, O(1) time for everything, and better fit for an interview than for practical use. –  Evgeny Kluev Oct 24 '12 at 16:04
Can you give a running example of your algorithm? I understood the 2nd part, it was the first part with the tiered vector tat was putting me off. –  Cupidvogel Oct 25 '12 at 6:28
@Cupidvogel: I'm afraid I cannot give a running example. I have no time to implement tiered vector. And I cannot find a good enough existing implementation. The referred paper perfectly explains the idea of tiered vector (and even contains pseudo-code). –  Evgeny Kluev Oct 25 '12 at 9:25
Please provide some clarifications. In the partitioning of the array into `sqrt(n)` arrays for the tiered vector, do we form `sqrt(n)` separate arrays, or are they implemented in the same array just by partitioning? Each will be an array after all, so how come deletion will be faster? –  Cupidvogel Oct 27 '12 at 22:03

Now, that the question is clear for me too (better late than never...) here are my proposals:

• you could maintain two hashes: one with keys, and one with the insert order. this however is very ugly and slow to maintain when deleting, and inserting in between. This would give the same almost O(1) time needed to access the elements both ways.
• you could use a hash for the keys, and maintain an array for the insert order. this one is a lot nicer than the hash type, deleting is still not very fast, but I think still a lot quicker than with the two hash approach. This also gives true O(1) on accessing the nth element.

At first, I misunderstood the question, and gave a solution that gives O(1) key lookup, and O(n) lookup of nth element:

I think however that if someone finds this page, this might not be totally useless, so I leave it here...

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External modules are not allowed, I have to design it from scratch. –  Cupidvogel Oct 19 '12 at 8:59
Then don't be shy, and read the code of that class! The idea is clear: the elements of the map should maintain a reference to the next element (or both the next and the previous elements, if you want to traverse it backwards too). –  ppeterka Oct 19 '12 at 9:01
I'd rather consider using something like std::vector which will hold std::pair (C++). It will give you both speed and flexibility. –  Ivan0x32 Oct 19 '12 at 9:08
@Ivan0x32 But that doesn’t give you the O(1) key lookup. –  Konrad Rudolph Oct 19 '12 at 9:10
@KonradRudolph You are clearly wrong. Quote: `return the value corresponding to a given key in O(1) time, as well as returning the nth value inserted` He wants 1, return the value for a key in O(1), and 2, be able to get the nth element. These don't imply that he wants to get the nth element in O(1)! –  ppeterka Oct 19 '12 at 9:11

There is no data structure in O(1) for everything you cited. In particular any data structure with random dynamic insertion/deletion in the middle AND sorted/indexed access cannot have maintenance time lower than O(log N), to maintain such a dynamic collection you have to resort either on the operator "less than" (binary thus O(log2 N)) or some computed organization (typical O(sqrt N), by using sqrt(N) sub arrays). Note that O(sqrt N)>O(log N).

So, no.

You might reach O(1) for everything including keeping order with the linked list+hash map, and if access is mostly sequential, you could cache nth(x), to access nth(x+/-1) in O(1).

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I guess only a plain array will give you O(1), best variant is to look for solution which gives O(n) in worst scenario. You can also use a really really bad approach - using key as index in plain array. I guess there is a way to transform any key to index in plain array.

``````std::string memoryMap[0x10000];
int key = 100;
std::string value = "Hello, World!";
memoryMap[key] = value;
``````
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