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Ok, I will confess I've not dug out reflector to look at what's going on here, but I'm hoping someone can tell me.

How do Microsoft make adding and fetching so fast, I can make adding fast by just sticking items in an array, and I can make fetching fast by sorting the array and using a binary search. If however, I was to do a quicksort every time an item was added to make fetching data fast, adding would slow down massively, and if I had to sort the data every time I tried to fetch something, adding items would slow massively.

Does anyone know the internal workings of a dictionary? It is a fair bit more memory hungry than an array, so there's clearly something other than clever algorithms going on behind the scenes.

I'm trying to understand the magic and learn from it!

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Very simply: It depends on the concept that, in order to compare two objects every time, you could instead just compare their "fingerprints", which is immensely faster. Only if there's a collision do you actually need to compare the objects, hence the speed. –  Mehrdad Mar 22 '11 at 10:18

4 Answers 4

up vote 12 down vote accepted

The dictionary<T,T> in .Net is a data structure called a hash table:

On Hash Table and .Net Dictionary:

On Binary Search:

You're right, it uses more memory than an array to retrieve data. That's the trade off you pay for faster access. (This is true in most cases, when you start taking into account the setup time to build a hash table vs an array, at times a sorted array could be faster for setup time and access. In general this is a valid assumption though.)

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One more link, referring to the concept you mentioned: The space-time tradeoff is a classic concept in CS. –  jason Mar 21 '11 at 15:49
@Jason thanks for the link! –  Kevin Mar 21 '11 at 15:51

The basic principle is:

  1. Set up empty array.
  2. Obtain hash-code.
  3. Re-hash hash to fit size of array (e.g. if the array is 31 items in size, we can do hash % 31) and use this as an index.

Retrieval is then a matter of finding the index in the same way, obtaining the key if it's there, and calling Equals on that item.

The obvious issue here is what to do if there are two items that belong at the same index. One approach is that you store a list or similar in the array rather than the key-value pair itself, another is "reprobing" into a different index. Both approaches have advantages and disadvantages, and Microsoft use reprobing a list.

Above a certain size, the amount of reprobing (or the size of the stored lists if you took that approach) gets too large and the near-O(1) behaviour is lost, at which point the table is resized so as to improve this.

Clearly though, a really poor hash algorithm can destroy this, you can demonstrate this to yourself by building a dictionary of objects where the hashcode method is the following:

public override int GetHashCode()
  return 0;

This is valid, but horrible, and turns your near-O(1) behaviour into O(n) (and bad even as O(n) goes.

There are plenty of other details and optimisations, but the above is the basic principle.


Incidentally, if you have a perfect hash (you know all possible values, and have a hash method that gives each such value a unique hash in a small range) it's possible to avoid the issues of reprobing that occur with more general-purpose hash-tables, and just treat the hash as an index into an array. This gives both the O(1) behaviour, and minimal memory use, but only applies when all possible values are in a small range.

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I'm pretty sure that Dictionary<K,V> handles collisions using chaining (with a linked list of some kind) rather than probing. –  LukeH Mar 21 '11 at 16:10
@LukeH, yes taking a look I see that you are correct. Glad I explained both methods so :) –  Jon Hanna Mar 21 '11 at 16:27
In .net 4 there are two arrays, one for the buckets another for the entries, and each entry is a pseudo linked list in that it can contain the index to the next entry in the same bucket. This is an index to the same entries array. So it feels to me like it's a hybrid between probing and a linked list. –  Slugart Aug 6 '14 at 17:37

It uses a hash like practically every other dictionary implementation.

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This question got me curious, so I wrote an ultra-fast, optimized version of a dictionary lookup thats 5x (five times) faster than the default .NET dictionary implementation.

I've left out error checking for brevity, however, this would be trivial to add. I've also left it un-templated to make it easier to understand.

It creates a number of nested arrays, so a lookup is a matter of chaining through object references in memory. It navigates straight to the correct object in memory, without using loops or hash tables of any description. Its reasonably memory efficient, as it only allocates memory for what it needs. Unlike hash tables, there is never any problem with unintentional bucket collisions (unless the key is the same, of course). If you want to run the comparison yourself, I can provide the complete test project.

/// <summary>
/// Ultra fast dictionary, optimized for retrieval of keys consisting of 3-letter uppercase strings, where each string is 'A' to 'Z'.
/// This is 5 times faster than the default Dictionary<> implementation, but not as flexible.
/// ----start output from tester---
/// Ultra Fast Dictionary.
///   Total time for 2,000,000,000 key retrievals: 19,892 milliseconds. 0.00994600 nanoseconds per retrieval. Sum -1958822656.
/// Normal Dictionary.
///   Total time for 2,000,000,000 key retrievals: 98,397 milliseconds. 0.04919850 nanoseconds per retrieval. Sum -1958822656.
/// ----end output from tester---
/// </summary>
public class DictionaryUltraFast
    string[][][] dictionary;

    /// <summary>
    /// Add a string to the dictionary.
    /// </summary>
    public void Add(string key, string value)
        key = key.ToUpper();
        if (dictionary == null)
            dictionary = new string['Z' - 'A' + 1][][];
        if (dictionary[key[0] - 'A'] == null)
            dictionary[key[0] - 'A'] = new string['Z' - 'A' + 1][];
        if (dictionary[key[0] - 'A'][key[1] - 'A'] == null)
            dictionary[key[0] - 'A'][key[1] - 'A'] = new string['Z' - 'A' + 1];
        dictionary[key[0] - 'A'][key[1] - 'A'][key[2] - 'A'] = value;

    public string Get(string key)
        return dictionary[key[0] - 'A'][key[1] - 'A'][key[2] - 'A'];
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This is a specialized data structure. It can potentially use much more memory than the usual hash table, given how the arrays are allocated. Since it is so specialized, I don't think we can compare it to a general purpose dictionary. Bucket sorting is generally a good alternative to hashing (you are using a bucket sort here). –  Frank Hileman Jul 13 '12 at 20:23
@Gravitas wrong thread to post an excellent answer, +1 still.. Could you tell me as to what the array of array of arrays is doing here? Also how can I implement a Clear method? Do you have the complete source somewhere? You can make this generic, but I wonder if your approach does any good if string keys are of length less than 3 –  nawfal Dec 2 '12 at 17:46
I also wonder how much of the 5X improvement is lost once you add error checking. This special case requires several extra checks that you are skipping (e.g., a key of "A" will cause a crash). –  Brian Jun 13 '13 at 18:30

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