# Sorted hash table (map, dictionary) data structure design

Here's a description of the data structure:

It operates like a regular map with `get`, `put`, and `remove` methods, but has a `sort` method that can be called to sorts the map. However, the map remembers its sorted structure, so subsequent calls to sort can be much quicker (if the structure doesn't change too much between calls to `sort`).

For example:

• I call the `put` method 1,000,000 times.
• I call the `sort` method.
• I call the `put` method 100 more times.
• I call the `sort` method.

The second time I call the `sort` method should be a much quicker operation, as the map's structure hasn't changed much. Note that the map doesn't have to maintain sorted order between calls to `sort`.

I understand that it might not be possible, but I'm hoping for O(1) `get`, `put`, and `remove` operations. Something like TreeMap provides guaranteed O(log(n)) time cost for these operations, but always maintains a sorted order (no `sort` method).

So what's the design of this data structure?

Edit 1 - returning the top-K entries

Alhough I'd enjoy hearing the answer to the general case above, my use case has gotten more specific: I don't need the whole thing sorted; just the top K elements.

Data structure for efficiently returning the top-K entries of a hash table (map, dictionary)

Thanks!

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Why exactly do you need a sort() function ?
What do you perhaps want and need is a Red-Black Tree.

http://en.wikipedia.org/wiki/Red-black_tree

These trees are automatically sorting your input by a comparator you give. They are complex, but have excellent O(n) characteristics. Couple your tree entries as key with a hash map as dictionary and you get your datastructure.

In Java it is implemented as TreeMap as instance of SortedMap.

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For "O(1) get, put, and remove operations" you essentially need O(1) lookup, which implies a hash function (as you know), but the requirements of a good hash function often break the requirement to be easily sorted. (If you had a hash table where adjacent values mapped to the same bucket, it would degenerate to O(N) on lots of common data, which is a worse case you typically want a hash function to avoid.)

I can think of how to get you 90% of the way there. Set up a hashtable alongside a parallel index that is sorted. The index has a clean part (ordered) and a dirty part (unordered). The index would map keys to the values (or references to the values stored in the hashtable - whichever suits you in terms of performance or memory use). When you add to the hashtable, the new entry is pushed onto the back of the dirty list. When you remove from the hashtable, the entry is nulled/removed from the clean and dirty parts of the index. You can sort the index, which sorts the dirty entries only, then merges them into the already sorted 'clean' part of the index. And obviously you can iterate over the index.

As far as I can see, this gives you the O(1) everywhere except on the remove operation and is still fairly simple to implement with standard containers (at least as provided by C++, Java, or Python). It also gives you the "second sort is cheaper" condition by only needing to sort the dirty index entries and then letting you do an O(N) merge. The cost of all this is obviously extra memory for the index and extra indirection when using it.

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You could get O(1) on the remove too, by having the hashtable entry include a link back to the corresponding location in the index. –  caf Jan 20 '10 at 2:03
Sounds reasonable! –  Kylotan Jan 20 '10 at 11:11

I don't know if there's a name, but you could store the current index of each item on the hash.

That is, you have a `HashMap< Object, Pair( Integer, Object ) >` and a `List<Object>` objects

When you `put`, add to the tail or head of the list and insert into the hashmap with your data and the index of insertion. This is `O(1)`.

When you `get`, pull from the hashmap and ignore the index. This is `O(1)`.

When you `remove`, you pull from the map. Take the index and remove from the list as well. This is `O(1)`

When you `sort`, just sort the list. Either update the indexes in the map during the sort, or update after the sort is complete. This does not affect the `O(nlgn)` sort, as it's a linear step. `O(nlgn + n) == O(nlgn)`

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I don't think `remove` is `O(1)`... When you call `remove`, it removes from the list and messes up the indexes. –  Rudiger Jan 19 '10 at 23:49
Just because you `remove` an object from a sorted list doesn't mean it's still not sorted... ie. [3, 5, 6]. There's not a 4 in the list, but it's still sorted properly... So the sort would only have to occur after the `put`. –  max Apr 12 '12 at 6:00

Ordered Dictionary

Recent versions of Python (2.7, 3.1) have "ordered dictionaries" which sound like what you're describing.

The official Python "ordered dictionary" implementation is inspired by previous 3rd-party implementations, as described in the PEP 372.

References:

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OrderedDict maintains entries in insertion order, not natural key sort order. –  Geoff Reedy Jan 20 '10 at 17:29
True, but it is sortable, as described in the Python documentation. It seems like a pretty reasonable fit to the description in the question. –  Craig McQueen Jan 21 '10 at 0:19

What you're looking at is a hashtable with pointers in the entries to the next entry in sorted order. It's a lot like the LinkedHashMap in java except that the links are tracking a sort order rather than the insertion order. You can actually implement this totally by wrapping a LinkedHashMap and having the implementation of sort transfer the entries from the LinkedHashMap into a TreeMap and then back into a LinkedHashMap.

Here's an implementation that sorts the entries in an array list rather than transferring to a tree map. I think the sort algorithm used by Collection.sort will do a good job of merging the new entries into the already sorted portion.

``````public class SortaSortedMap<K extends Comparable<K>,V> implements Map<K,V> {

public SortaSortedMap() {
}

public SortaSortedMap(Map<K,V> map) {
}

public Collection<V> values() {
return innerMap.values();
}

public int size() {
return innerMap.size();
}

public V remove(Object key) {
return innerMap.remove(key);
}

public V put(K key, V value) {
return innerMap.put(key, value);
}

public Set<K> keySet() {
return innerMap.keySet();
}

public boolean isEmpty() {
return innerMap.isEmpty();
}

public Set<Entry<K, V>> entrySet() {
return innerMap.entrySet();
}

public boolean containsKey(Object key) {
return innerMap.containsKey(key);
}

public V get(Object key) {
return innerMap.get(key);
}

public boolean containsValue(Object value) {
return innerMap.containsValue(value);
}

public void clear() {
innerMap.clear();
}

public void putAll(Map<? extends K, ? extends V> m) {
innerMap.putAll(m);
}

public void sort() {
List<Map.Entry<K,V>> entries = new ArrayList<Map.Entry<K,V>>(innerMap.entrySet());
Collections.sort(entries, new KeyComparator());
for (Map.Entry<K,V> e: entries) {
newMap.put(e.getKey(), e.getValue());
}
innerMap = newMap;
}

private class KeyComparator implements Comparator<Map.Entry<K,V>> {

public int compare(Entry<K, V> o1, Entry<K, V> o2) {
return o1.getKey().compareTo(o2.getKey());
}

}

}
``````
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I'm not aware of a data structure classification with that exact behavior, at least not in Java Collections (or from nonlinear data structures class). Perhaps you can implement it, and it will henceforth be known as the `RudigerMap`.

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Some sort of hybrid hashmap/treemap perhaps? Inserts go into the hashmap, sort then transfers hashmap items into the treemap. Not sure how you would get O(1) for removals as well though...hmmm.. –  Paolo Jan 5 '10 at 16:13