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I'm trying to understand how the internals of C#'s generic Dictionary work. I decompiled and got the dictionary code. I re-wrote it slightly separating the keys/values/hashcodes to separate arrays (I omitted the enumerator and interface implementations because they're irrelevant)

using System;
using System.Linq;
using System.Collections;
using System.Collections.Generic;
using System.Diagnostics;

public class Dictionary<TKey, TValue> {
    int[] _Buckets;
    int[] _HashCodes;
    int[] _Next;
    int _Count;
    int _FreeList;
    int _FreeCount;
    TKey[] _Keys;
    TValue[] _Values;

    readonly IEqualityComparer<TKey> _Comparer;

    public int Count {
        get { return _Count - _FreeCount; }
    }

    public TValue this[TKey key] {
        get {
            int index = FindIndex(key);
            if (index >= 0)
                return _Values[index];
            throw new KeyNotFoundException(key.ToString());
        }
        set { Insert(key, value, false); }
    }

    public Dictionary() : this(0, null) {
    }

    public Dictionary(int capacity) : this(capacity, null) {
    }

    public Dictionary(IEqualityComparer<TKey> comparer) : this(0, comparer) {
    }

    public Dictionary(int capacity, IEqualityComparer<TKey> comparer) {
        if (capacity < 0)
            throw new ArgumentOutOfRangeException("capacity");
        Initialize(capacity);
        _Comparer = (comparer ?? EqualityComparer<TKey>.Default);
    }

    public Dictionary(IDictionary<TKey, TValue> dictionary) : this(dictionary, null)
    {
    }

    public Dictionary(IDictionary<TKey, TValue> dictionary, IEqualityComparer<TKey> comparer)
        : this((dictionary != null) ? dictionary.Count : 0, comparer)
    {
        if (dictionary == null)
            throw new ArgumentNullException("dictionary");

        foreach (KeyValuePair<TKey, TValue> current in dictionary)
            Add(current.Key, current.Value);
    }

    public bool ContainsValue(TValue value) {
        if (value == null) {
            for (int i = 0; i < _Count; i++) {
                if (_HashCodes[i] >= 0 && _Values[i] == null)
                    return true;
            }
        } else {
            var defaultComparer = EqualityComparer<TValue>.Default;
            for (int i = 0; i < _Count; i++) {
                if (_HashCodes[i] >= 0 && defaultComparer.Equals(_Values[i], value))
                    return true;
            }
        }
        return false;
    }

    public bool ContainsKey(TKey key) {
        return FindIndex(key) >= 0;
    }

    public void Clear() {
        if (_Count <= 0)
            return;

        for (int i = 0; i < _Buckets.Length; i++)
            _Buckets[i] = -1;

        Array.Clear(_Keys, 0, _Count);
        Array.Clear(_Values, 0, _Count);
        Array.Clear(_HashCodes, 0, _Count);
        Array.Clear(_Next, 0, _Count);

        _FreeList = -1;
        _Count = 0;
        _FreeCount = 0;
    }

    public void Add(TKey key, TValue value) {
        Insert(key, value, true);
    }

    private void Resize(int newSize, bool forceNewHashCodes) {
        int[] bucketsCopy = new int[newSize];
        for (int i = 0; i < bucketsCopy.Length; i++)
            bucketsCopy[i] = -1;

        var keysCopy = new TKey[newSize];
        var valuesCopy = new TValue[newSize];
        var hashCodesCopy = new int[newSize];
        var nextCopy = new int[newSize];

        Array.Copy(_Values, 0, valuesCopy, 0, _Count);
        Array.Copy(_Keys, 0, keysCopy, 0, _Count);
        Array.Copy(_HashCodes, 0, hashCodesCopy, 0, _Count);
        Array.Copy(_Next, 0, nextCopy, 0, _Count);

        if (forceNewHashCodes) {
            for (int i = 0; i < _Count; i++) {
                if (hashCodesCopy[i] != -1)
                    hashCodesCopy[i] = (_Comparer.GetHashCode(keysCopy[i]) & 2147483647);
            }
        }
        for (int i = 0; i < _Count; i++) {
            int index = hashCodesCopy[i] % newSize;
            nextCopy[i] = bucketsCopy[index];
            bucketsCopy[index] = i;
        }
        _Buckets = bucketsCopy;
        _Keys = keysCopy;
        _Values = valuesCopy;
        _HashCodes = hashCodesCopy;
        _Next = nextCopy;
    }

    private void Resize()
    {
        Resize(PrimeHelper.ExpandPrime(_Count), false);
    }

    public bool Remove(TKey key)
    {
        if (key == null)
            throw new ArgumentNullException("key");

        int hash = _Comparer.GetHashCode(key) & 2147483647;
        int index = hash % _Buckets.Length;
        int num = -1;
        for (int i = _Buckets[index]; i >= 0; i = _Next[i]) {
            if (_HashCodes[i] == hash && _Comparer.Equals(_Keys[i], key)) {
                if (num < 0)
                    _Buckets[index] = _Next[i];
                else
                    _Next[num] = _Next[i];

                _HashCodes[i] = -1;
                _Next[i] = _FreeList;
                _Keys[i] = default(TKey);
                _Values[i] = default(TValue);
                _FreeList = i;
                _FreeCount++;
                return true;
            }
            num = i;
        }
        return false;
    }

    private void Insert(TKey key, TValue value, bool add) {
        if (key == null)
            throw new ArgumentNullException("key");
        if (_Buckets == null)
            Initialize(0);
        int hash = _Comparer.GetHashCode(key) & 2147483647;
        int index = hash % _Buckets.Length;
        for (int i = _Buckets[index]; i >= 0; i = _Next[i]) {
            if (_HashCodes[i] == hash && _Comparer.Equals(_Keys[i], key)) {
                if (add)
                    throw new ArgumentException("Key already exists: " + key);
                _Values[i] = value;
                return;
            }
        }
        int num;
        if (_FreeCount > 0) {
            num = _FreeList;
            _FreeList = _Next[num];
            _FreeCount--;
        } else {
            if (_Count == _Keys.Length) {
                Resize();
                index = hash % _Buckets.Length;
            }
            num = _Count;
            _Count++;
        }
        _HashCodes[num] = hash;
        _Next[num] = _Buckets[index];
        _Keys[num] = key;
        _Values[num] = value;
        _Buckets[index] = num;
    }

    private void Initialize(int capacity) {
        int prime = PrimeHelper.GetPrime(capacity);
        _Buckets = new int[prime];
        for (int i = 0; i < _Buckets.Length; i++)
            _Buckets[i] = -1;

        _Keys = new TKey[prime];
        _Values = new TValue[prime];
        _HashCodes = new int[prime];
        _Next = new int[prime];

        _FreeList = -1;
    }

    private int FindIndex(TKey key) {
        if (key == null)
            throw new ArgumentNullException("key");

        if (_Buckets != null) {
            int hash = _Comparer.GetHashCode(key) & 2147483647;
            for (int i = _Buckets[hash % _Buckets.Length]; i >= 0; i = _Next[i]) {
                if (_HashCodes[i] == hash && _Comparer.Equals(_Keys[i], key))
                    return i;
            }
        }
        return -1;
    }

    public bool TryGetValue(TKey key, out TValue value) {
        int index = FindIndex(key);
        if (index >= 0) {
            value = _Values[index];
            return true;
        }
        value = default(TValue);
        return false;
    }

    public TValue ValueOrDefault(TKey key) {
        return ValueOrDefault(key, default(TValue));
    }

    public TValue ValueOrDefault(TKey key, TValue defaultValue) {
        //return this[key, defaultValue];
        int index = FindIndex(key);
        if (index >= 0)
            return _Values[index];
        return defaultValue;
    }

    private static class PrimeHelper {

        public static readonly int[] Primes = new int[] {
            3, 7, 11, 17,
            23, 29, 37, 47,
            59, 71, 89, 107,
            131, 163, 197, 239,
            293, 353, 431, 521,
            631, 761, 919, 1103,
            1327, 1597, 1931, 2333,
            2801, 3371, 4049, 4861,
            5839, 7013, 8419, 10103,
            12143, 14591, 17519, 21023,
            25229, 30293, 36353, 43627,
            52361, 62851, 75431, 90523,
            108631, 130363, 156437, 187751,
            225307, 270371, 324449, 389357,
            467237, 560689, 672827, 807403,
            968897, 1162687, 1395263, 1674319,
            2009191, 2411033, 2893249, 3471899,
            4166287, 4999559, 5999471, 7199369
        };

        public static bool IsPrime(int candidate) {
            if ((candidate & 1) != 0) {
                int num = (int)Math.Sqrt((double)candidate);
                for (int i = 3; i <= num; i += 2) {
                    if (candidate % i == 0) {
                        return false;
                    }
                }
                return true;
            }
            return candidate == 2;
        }

        public static int GetPrime(int min) {
            if (min < 0)
                throw new ArgumentException("min < 0");

            for (int i = 0; i < PrimeHelper.Primes.Length; i++) {
                int prime = PrimeHelper.Primes[i];
                if (prime >= min)
                    return prime;
            }
            for (int i = min | 1; i < 2147483647; i += 2) {
                if (PrimeHelper.IsPrime(i) && (i - 1) % 101 != 0)
                    return i;
            }
            return min;
        }

        public static int ExpandPrime(int oldSize) {
            int num = 2 * oldSize;
            if (num > 2146435069 && 2146435069 > oldSize) {
                return 2146435069;
            }
            return PrimeHelper.GetPrime(num);
        }
    }
}

What's confusing me is:

  • The _FreeList and _FreeCount variables: what do they represent?
  • What's the difference between Count and _Count?
  • So _Next seems to be related to hash collision, does it store the next index of the key/value that has the same hash?
  • What's num doing in Remove?
  • So given a Key we compute Index = GetHashCode(Key) % Buckets.Length; which gives us an index that we could use in the _Keys/_Values/_HashCodes arrays. Why do we need to compare _HashCodes[i] == hash? I mean we got the index by computing the hash, so of course _Keys[i] hash the same hash right?

Note that there was an actual use case for decompiling the code and using it. Unity3D doesn't know how to serialize dictionaries and the ways you get around it normally is not so great, so I took the actual code of Dictionary and annotated the necessary fields with [SerializeField], now Unity can serialize the class without any wrappers.

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    As a small side note, the actual source code is available from Microsoft, you don't have to decompile it. referencesource.microsoft.com/#mscorlib/system/collections/…
    – amg-argh
    Nov 10, 2015 at 19:38
  • I know but I wanted a version that took the less amount of modifications to get it working in an external environment. I looked at the source from MS but they had a lot of internal calls that required reflection to be used externally.
    – vexe
    Nov 10, 2015 at 19:41
  • I think it's worst code you could analyze, see github.com/dotnet/coreclr/blob/master/src/mscorlib/src/System/…, see MONO implementation github.com/mosa/Mono-Class-Libraries/blob/master/mcs/class/… both are readable and understandable
    – comdiv
    Nov 10, 2015 at 19:45
  • Also not knowing 100% what you are trying to achieve, wouldn't it make more sense to derive a subclass from Dictionary, say SerializableDictionary that implements the serialization behavior you desire rather than starting from scratch?
    – amg-argh
    Nov 10, 2015 at 19:50
  • @ФагимСадыков actually the first link is the same implementation you see in this post.
    – vexe
    Nov 10, 2015 at 19:54

1 Answer 1

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The implementation that you show uses arrays _Keys to store keys and _Values to store their corresponding values. Only the portion of these arrays from index zero, inclusive, to index _Count, exclusive, is occupied. The elements at _Count and above are not used.

_Keys and _Values arrays are populated sequentially on addition. When a removal occurs, the corresponding elements are placed on free list. When the next addition occurs, the last element returned to free list is used before considering the expansion to the element at _Count.

_Next seems to be related to hash collision, does it store the next index of the key/value that has the same hash?

_Next has two purposes, depending on whether the corresponding item is used or is on a free list.

  • When the item iis used, _Next[i] represents the index of the next element with colliding hash code (it is not necessarily the same hash code!)
  • When the item i is on a free list, _Next[i] represents the next item on the free list (i.e. the item that was placed on free list before i-th, if any).

What's the difference between Count and _Count?

_Count is the high watermark of the _Keys and _Values arrays; Count is the actual count, which is computed as high watermark less the number of items placed on the free list (i.e. max added minus currently removed).

So given a Key we compute Index = GetHashCode(Key) % Buckets.Length; which gives us an index that we could use in the _Keys/_Values/_HashCodes arrays. Why do we need to compare _HashCodes[i] == hash?

Because GetHashCode(Key) % Buckets.Length remainder may be the same for different values of hash code. You can optimize the code by comparing hash code before invoking Equals, although this step is not necessary.

What's num doing in Remove?

An item that we are removing may be part of a list of items with colliding hash codes. The item may be at the head of the list, or it may be somewhere else on the list. The code uses num to treat these situations differently:

  • When the item is at the head of its list, the next item needs to be "promoted" to the head by adjusting _Buckets[]
  • When the item is not at the head of the list, its _Next[] index needs to be adjusted without promoting to the head.

next starts at a negative number, and switches to a non-negative number after the initial iteration. The check if (num < 0) means "are we on the first iteration?"

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    Regarding hashcode compare, if there are several items in the list of entries that map to the same bucket, initially comparing hashcodes, and only then comparing keys can be much faster than comparing keys for each item in the list. I don't think they have to compare hashcodes, I think it's an optimization. Nov 10, 2015 at 19:56
  • Great answer! Just to make sure I also understand _Buckets: If I iterate over each value in it and use it as an index in the _Keys and _Values arrays, I would be basically iterating over the keys/values of the dictionary correct?
    – vexe
    Nov 10, 2015 at 20:05
  • 1
    @vexe Not exactly: when _Buckets[i] is non-negative, _Keys[_Buckets[i]] contains the first key in the chain of items with colliding hash codes. When there are collisions, iterating over _Buckets with non-negative values would yield fewer key/value pairs than there are in the dictionary. If you want to get all keys/values in bucket order, you need to follow the chain of _Nexts for each bucket that has one.' Nov 10, 2015 at 20:23
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    @vexe You are right on the first point. On the second point, there is a tiny correction: it's the number of elements used in _Buckets plus the ones used in _Next minus _FreeCount, because some of the _Nexts may be on free list. Nov 10, 2015 at 20:45
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    @vexe I agree, _FreeList is not the best name for the variable. I think _FreeListHead would have been a better name for it. This is the index of the first_Key/_Value pair on the free list. The rest of the list can be traversed by following the corresponding _Next indexes. Nov 11, 2015 at 3:31

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