1676

In .NET, the GetHashCode method is used in a lot of places throughout the .NET base class libraries. Implementing it properly is especially important to find items quickly in a collection or when determining equality.

Is there a standard algorithm or best practice on how to implement GetHashCode for my custom classes so I don't degrade performance?

7
  • 48
    After reading this question and the article below, i could implement override of GetHashCode. I hope it would be helpful for others. Guidelines and rules for GetHashCode written by Eric Lippert
    – rene
    Mar 22, 2012 at 21:59
  • 6
    "or to determine equality": no! Two objects with the same hashcode are not necessarily equal. Sep 2, 2015 at 22:03
  • 4
    @ThomasLevesque You are right, two objects with the same hash code are not necessarily equal. But still GetHashCode() is used in very many implementations of Equals(). That's what I meant with that statement. GetHashCode() inside Equals() is often used as a shortcut to determine inequality, because if two objects have a different hash code they have to be objects that are not equal and the rest of the equality-check doesn't have to executed.
    – bitbonk
    Sep 2, 2015 at 22:27
  • 7
    @bitbonk Usually, both GetHashCode() and Equals() need to look at all fields of both objects (Equals has to do this if it the hashcodes are equal or not-checked). Because of this, a call to GetHashCode() inside Equals() is often redundant and could reduce performance. Equals() may also be able to short circuit, making it much faster - however in some cases the hashcodes may be cached, making the GetHashCode() check faster and so worthwhile. See this question for more. Apr 2, 2017 at 3:52
  • 12
    UPDATE JAN 2020: Eric Lippert's blog located at: learn.microsoft.com/en-us/archive/blogs/ericlippert/…
    – Rick Davin
    Jan 15, 2020 at 14:06

22 Answers 22

1808

I usually go with something like the implementation given in Josh Bloch's fabulous Effective Java. It's fast and creates a pretty good hash which is unlikely to cause collisions. Pick two different prime numbers, e.g. 17 and 23, and do:

public override int GetHashCode()
{
    unchecked // Overflow is fine, just wrap
    {
        int hash = 17;
        // Suitable nullity checks etc, of course :)
        hash = hash * 23 + field1.GetHashCode();
        hash = hash * 23 + field2.GetHashCode();
        hash = hash * 23 + field3.GetHashCode();
        return hash;
    }
}

As noted in comments, you may find it's better to pick a large prime to multiply by instead. Apparently 486187739 is good... and although most examples I've seen with small numbers tend to use primes, there are at least similar algorithms where non-prime numbers are often used. In the not-quite-FNV example later, for example, I've used numbers which apparently work well - but the initial value isn't a prime. (The multiplication constant is prime though. I don't know quite how important that is.)

This is better than the common practice of XORing hashcodes for two main reasons. Suppose we have a type with two int fields:

XorHash(x, x) == XorHash(y, y) == 0 for all x, y
XorHash(x, y) == XorHash(y, x) for all x, y

By the way, the earlier algorithm is the one currently used by the C# compiler for anonymous types.

This page gives quite a few options. I think for most cases the above is "good enough" and it's incredibly easy to remember and get right. The FNV alternative is similarly simple, but uses different constants and XOR instead of ADD as a combining operation. It looks something like the code below, but the normal FNV algorithm operates on individual bytes, so this would require modifying to perform one iteration per byte, instead of per 32-bit hash value. FNV is also designed for variable lengths of data, whereas the way we're using it here is always for the same number of field values. Comments on this answer suggest that the code here doesn't actually work as well (in the sample case tested) as the addition approach above.

// Note: Not quite FNV!
public override int GetHashCode()
{
    unchecked // Overflow is fine, just wrap
    {
        int hash = (int) 2166136261;
        // Suitable nullity checks etc, of course :)
        hash = (hash * 16777619) ^ field1.GetHashCode();
        hash = (hash * 16777619) ^ field2.GetHashCode();
        hash = (hash * 16777619) ^ field3.GetHashCode();
        return hash;
    }
}

Note that one thing to be aware of is that ideally you should prevent your equality-sensitive (and thus hashcode-sensitive) state from changing after adding it to a collection that depends on the hash code.

As per the documentation:

You can override GetHashCode for immutable reference types. In general, for mutable reference types, you should override GetHashCode only if:

  • You can compute the hash code from fields that are not mutable; or
  • You can ensure that the hash code of a mutable object does not change while the object is contained in a collection that relies on its hash code.

The link to the FNV article is broken but here is a copy in the Internet Archive: Eternally Confuzzled - The Art of Hashing

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  • 9
    The algorithm described in the book you mention is infact a little more detailed it especailly describes what to do for different data types of the fields. E.g.: for fields of type long use (int)(field ^ f >>> 32) instead of simply calling GetHashcode. Is long.GetHashCodes implemented that way ?
    – bitbonk
    Nov 4, 2008 at 21:44
  • 15
    Yup, Int64.GetHashCode does exactly that. In Java that would require boxing, of course. That reminds me - time to add a link to the book...
    – Jon Skeet
    Nov 4, 2008 at 21:51
  • 85
    23 is no good choice, since(as of .net 3.5 SP1) Dictionary<TKey,TValue> assumes good distribution modulo certain primes. And 23 is one of them. So if you have a dictionary with Capacity 23 only the last contribution to GetHashCode influences the compound hashcode. So I'd rather use 29 instead of 23. Nov 21, 2010 at 22:41
  • 28
    @CodeInChaos: Only the last contribution influences the bucket - so it might, at worst, have to look through all 23 entries in the dictionary. It's still going to check the actual hash code of each entry, which will be cheap. If you've got a dictionary that small, it's unlikely to matter much.
    – Jon Skeet
    Nov 21, 2010 at 23:14
  • 25
    @Vajda: I usually use 0 as the effective hash code for null - which isn't the same as ignoring the field.
    – Jon Skeet
    Jan 22, 2013 at 16:49
552

ValueTuple - Update for C# 7

As @cactuaroid mentions in the comments, a value tuple can be used. This saves a few keystrokes and more importantly executes purely on the stack (no Garbage):

(PropA, PropB, PropC, PropD).GetHashCode();

(Note: The original technique using anonymous types seems to create an object on the heap, i.e. garbage, since anonymous types are implemented as classes, though this might be optimized out by the compiler. It would be interesting to benchmark these options, but the tuple option should be superior.)

Anonymous Type (Original Answer)

Microsoft already provides a good generic HashCode generator: Just copy your property/field values to an anonymous type and hash it:

new { PropA, PropB, PropC, PropD }.GetHashCode();

This will work for any number of properties. It does not use boxing. It just uses the algorithm already implemented in the framework for anonymous types.

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  • 90
    Yes, anonymous GetHashCode implementation is very effective (BTW it's the same as the one in the Jon Skeet's answer), but the only problem with this solution is that you generate a new instance at any GetHashCode call. It can be a bit overhead-ish in particular in case of intensive access to big hashed collections...
    – digEmAll
    Jan 8, 2011 at 9:50
  • 5
    @digEmAll Good point, I didn't think about the overhead of creating an new object. Jon Skeet's answer is the most efficient and won't use boxing. (@Kumba To solve the unchecked in VB, just use a Int64 (long) and truncate it after the calculations.)
    – Rick Love
    Apr 2, 2011 at 17:30
  • 20
    VB.NET must use Key in anonymous type creation: New With {Key PropA}.GetHashCode() Otherwise GetHashCode will not return the same hashcode for different objects with the same 'identifying' properties. Aug 20, 2014 at 15:58
  • 4
    @Keith in that case, I would consider saving the IEnumerable as a list value somewhere instead of enumerating it each time the hashcode is calculated. Caclulating ToList each time inside GetHashCode could hurt performance in many situations.
    – Rick Love
    Oct 20, 2015 at 20:40
  • 9
    For those who like this, (PropA, PropB, PropC, PropD).GetHashCode() is now available on C#7 without GC pressure @digEmAll concerns. Quick and Simple Hash Code Combinations
    – cactuaroid
    Aug 16, 2018 at 11:59
153

Using System.HashCode

If you are using .NET Standard 2.1 or above, you can use the System.HashCode struct. On earlier frameworks it is available from the Microsoft.Bcl.HashCode package. There are two methods of using it:

HashCode.Combine

The Combine method can be used to create a hash code, given up to eight objects.

public override int GetHashCode() => HashCode.Combine(this.object1, this.object2);

HashCode.Add

The Add method helps you to deal with collections:

public override int GetHashCode()
{
    var hashCode = new HashCode();
    hashCode.Add(this.object1);
    foreach (var item in this.collection)
    {
        hashCode.Add(item);
    }
    return hashCode.ToHashCode();
}

GetHashCode Made Easy

An alternative to System.HashCode that is super easy to use while still being fast. You can read the full blog post 'GetHashCode Made Easy' for more details and comments.

Usage Example

public class SuperHero
{
    public int Age { get; set; }
    public string Name { get; set; }
    public List<string> Powers { get; set; }

    public override int GetHashCode() =>
        HashCode.Of(this.Name).And(this.Age).AndEach(this.Powers);
}

Implementation

public struct HashCode : IEquatable<HashCode>
{
    private const int EmptyCollectionPrimeNumber = 19;
    private readonly int value;

    private HashCode(int value) => this.value = value;

    public static implicit operator int(HashCode hashCode) => hashCode.value;

    public static bool operator ==(HashCode left, HashCode right) => left.Equals(right);

    public static bool operator !=(HashCode left, HashCode right) => !(left == right);

    public static HashCode Of<T>(T item) => new HashCode(GetHashCode(item));

    public static HashCode OfEach<T>(IEnumerable<T> items) =>
        items == null ? new HashCode(0) : new HashCode(GetHashCode(items, 0));

    public HashCode And<T>(T item) => 
        new HashCode(CombineHashCodes(this.value, GetHashCode(item)));

    public HashCode AndEach<T>(IEnumerable<T> items)
    {
        if (items == null)
        {
            return new HashCode(this.value);
        }

        return new HashCode(GetHashCode(items, this.value));
    }

    public bool Equals(HashCode other) => this.value.Equals(other.value);

    public override bool Equals(object obj)
    {
        if (obj is HashCode)
        {
            return this.Equals((HashCode)obj);
        }

        return false;
    }

    public override int GetHashCode() => this.value.GetHashCode();

    private static int CombineHashCodes(int h1, int h2)
    {
        unchecked
        {
            // Code copied from System.Tuple a good way to combine hashes.
            return ((h1 << 5) + h1) ^ h2;
        }
    }

    private static int GetHashCode<T>(T item) => item?.GetHashCode() ?? 0;

    private static int GetHashCode<T>(IEnumerable<T> items, int startHashCode)
    {
        var temp = startHashCode;

        var enumerator = items.GetEnumerator();
        if (enumerator.MoveNext())
        {
            temp = CombineHashCodes(temp, GetHashCode(enumerator.Current));

            while (enumerator.MoveNext())
            {
                temp = CombineHashCodes(temp, GetHashCode(enumerator.Current));
            }
        }
        else
        {
            temp = CombineHashCodes(temp, EmptyCollectionPrimeNumber);
        }

        return temp;
    }
}

What Makes a Good Algorithm?

Performance

The algorithm that calculates a hash code needs to be fast. A simple algorithm is usually going to be a faster one. One that does not allocate extra memory will also reduce need for garbage collection, which will in turn also improve performance.

In C# hash functions specifically, you often use the unchecked keyword which stops overflow checking to improve performance.

Deterministic

The hashing algorithm needs to be deterministic i.e. given the same input it must always produce the same output.

Reduce Collisions

The algorithm that calculates a hash code needs to keep hash collisions to a minumum. A hash collision is a situation that occurs when two calls to GetHashCode on two different objects produce identical hash codes. Note that collisions are allowed (some have the misconceptions that they are not) but they should be kept to a minimum.

A lot of hash functions contain magic numbers like 17 or 23. These are special prime numbers which due to their mathematical properties help to reduce hash collisions as compared to using non-prime numbers.

Hash Uniformity

A good hash function should map the expected inputs as evenly as possible over its output range i.e. it should output a wide range of hashes based on its inputs that are evenly spread. It should have hash uniformity.

Prevent's DoS

In .NET Core each time you restart an application you will get different hash codes. This is a security feature to prevent Denial of Service attacks (DoS). For .NET Framework you should enable this feature by adding the following App.config file:

<?xml version ="1.0"?>  
<configuration>  
   <runtime>  
      <UseRandomizedStringHashAlgorithm enabled="1" />  
   </runtime>  
</configuration>

Because of this feature, hash codes should never be used outside of the application domain in which they were created, they should never be used as key fields in a collection and they should never be persisted.

Read more about this here.

Cryptographically Secure?

The algorithm does not have to be a Cryptographic hash function. Meaning it does not have to satisfy the following conditions:

  • It is infeasible to generate a message that yields a given hash value.
  • It is infeasible to find two different messages with the same hash value.
  • A small change to a message should change the hash value so extensively that the new hash value appears uncorrelated with the old hash value (avalanche effect).
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  • 4
    This is very good answer. As an addition, you could consider changing "speed" to "performance" and adding the property of being allocation-free. The built-in HashCode type satisfies that too.
    – Timo
    Jul 10, 2020 at 15:22
  • How does this compare to the ValueTuple.GetHashCode() answer recently updated by @ricklove above? Feb 18, 2021 at 3:10
  • 3
    The HashCode.Combine is a static method which will not allocate anything, while ValueTuple will start with allocating on the stack. Feb 18, 2021 at 8:35
  • 3
    HashCode.Of(this.Name).And(this.Age).AndEach(this.Powers) - that is nice syntax :)
    – Amos Egel
    Mar 9, 2021 at 8:14
  • they should never be used as key fields in a collection, Isn't that the whole point of hash codes though? And the existence of hash tables, hash sets, dictionaries? Dec 30, 2021 at 20:54
111

Here is my hashcode helper.
It's advantage is that it uses generic type arguments and therefore will not cause boxing:

public static class HashHelper
{
    public static int GetHashCode<T1, T2>(T1 arg1, T2 arg2)
    {
         unchecked
         {
             return 31 * arg1.GetHashCode() + arg2.GetHashCode();
         }
    }

    public static int GetHashCode<T1, T2, T3>(T1 arg1, T2 arg2, T3 arg3)
    {
        unchecked
        {
            int hash = arg1.GetHashCode();
            hash = 31 * hash + arg2.GetHashCode();
            return 31 * hash + arg3.GetHashCode();
        }
    }

    public static int GetHashCode<T1, T2, T3, T4>(T1 arg1, T2 arg2, T3 arg3, 
        T4 arg4)
    {
        unchecked
        {
            int hash = arg1.GetHashCode();
            hash = 31 * hash + arg2.GetHashCode();
            hash = 31 * hash + arg3.GetHashCode();
            return 31 * hash + arg4.GetHashCode();
        }
    }

    public static int GetHashCode<T>(T[] list)
    {
        unchecked
        {
            int hash = 0;
            foreach (var item in list)
            {
                hash = 31 * hash + item.GetHashCode();
            }
            return hash;
        }
    }

    public static int GetHashCode<T>(IEnumerable<T> list)
    {
        unchecked
        {
            int hash = 0;
            foreach (var item in list)
            {
                hash = 31 * hash + item.GetHashCode();
            }
            return hash;
        }
    }

    /// <summary>
    /// Gets a hashcode for a collection for that the order of items 
    /// does not matter.
    /// So {1, 2, 3} and {3, 2, 1} will get same hash code.
    /// </summary>
    public static int GetHashCodeForOrderNoMatterCollection<T>(
        IEnumerable<T> list)
    {
        unchecked
        {
            int hash = 0;
            int count = 0;
            foreach (var item in list)
            {
                hash += item.GetHashCode();
                count++;
            }
            return 31 * hash + count.GetHashCode();
        }
    }

    /// <summary>
    /// Alternative way to get a hashcode is to use a fluent 
    /// interface like this:<br />
    /// return 0.CombineHashCode(field1).CombineHashCode(field2).
    ///     CombineHashCode(field3);
    /// </summary>
    public static int CombineHashCode<T>(this int hashCode, T arg)
    {
        unchecked
        {
            return 31 * hashCode + arg.GetHashCode();   
        }
    }

Also it has extension method to provide a fluent interface, so you can use it like this:

public override int GetHashCode()
{
    return HashHelper.GetHashCode(Manufacturer, PartN, Quantity);
}

or like this:

public override int GetHashCode()
{
    return 0.CombineHashCode(Manufacturer)
        .CombineHashCode(PartN)
        .CombineHashCode(Quantity);
}
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    No need for T[] separately as it is already IEnumerable<T>
    – nawfal
    Apr 14, 2013 at 12:43
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    You could refactor those methods and restrict the core logic to one function
    – nawfal
    Apr 14, 2013 at 13:06
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    Incidentally, 31 is a shift and subtract on the CPU, which is exceedingly fast.
    – Chui Tey
    Aug 22, 2013 at 23:14
  • 5
    @nightcoder you could use params.
    – ANeves
    Feb 9, 2015 at 13:54
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    @ChuiTey This is something all Mersenne Primes have in common.
    – Pharap
    Jun 12, 2015 at 3:11
67

I have a Hashing class in Helper library that I use it for this purpose.

/// <summary> 
/// This is a simple hashing function from Robert Sedgwicks Hashing in C book.
/// Also, some simple optimizations to the algorithm in order to speed up
/// its hashing process have been added. from: www.partow.net
/// </summary>
/// <param name="input">array of objects, parameters combination that you need
/// to get a unique hash code for them</param>
/// <returns>Hash code</returns>
public static int RSHash(params object[] input)
{
    const int b = 378551;
    int a = 63689;
    int hash = 0;

    // If it overflows then just wrap around
    unchecked
    {
        for (int i = 0; i < input.Length; i++)
        {
            if (input[i] != null)
            {
                hash = hash * a + input[i].GetHashCode();
                a = a * b;
            }
        }
    }

    return hash;
}

Then, simply you can use it as:

public override int GetHashCode()
{
    return Hashing.RSHash(_field1, _field2, _field3);
}

I didn't assess its performance, so any feedback is welcomed.

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    Well, it will cause boxing, if fields are value types.
    – nightcoder
    Apr 4, 2010 at 15:39
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    "can be enhanced later by catching the OverflowException" The whole point of the unchecked is to avoid exceptions on overflow which is desired on GetHashCode. So it's not incorrect if the value overflows int and it does not hurt at all. Feb 24, 2014 at 13:06
  • 2
    One issue with this algorithm is that any array full of nulls will always return 0, regardless of it's length Apr 17, 2015 at 12:12
  • 3
    This helper method also allocates a new object[] Jul 20, 2016 at 12:35
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    As @NathanAdams mentions, the fact that null is skipped entirely could give you unexpected results. Instead of skipping them, you should just use some constant value instead of input[i].GetHashCode() when input[i] is null. Oct 28, 2016 at 19:04
59

Here's my helper class using Jon Skeet's implementation.

public static class HashCode
{
    public const int Start = 17;

    public static int Hash<T>(this int hash, T obj)
    {
        var h = EqualityComparer<T>.Default.GetHashCode(obj);
        return unchecked((hash * 31) + h);
    }
}

Usage:

public override int GetHashCode()
{
    return HashCode.Start
        .Hash(_field1)
        .Hash(_field2)
        .Hash(_field3);
}

If you want to avoid writing an extension method for System.Int32:

public readonly struct HashCode
{
    private readonly int _value;

    public HashCode(int value) => _value = value;

    public static HashCode Start { get; } = new HashCode(17);

    public static implicit operator int(HashCode hash) => hash._value;

    public HashCode Hash<T>(T obj)
    {
        var h = EqualityComparer<T>.Default.GetHashCode(obj);
        return unchecked(new HashCode((_value * 31) + h));
    }

    public override int GetHashCode() => _value;
}

It still avoids any heap allocation and is used exactly the same way:

public override int GetHashCode()
{
    // This time `HashCode.Start` is not an `Int32`, it's a `HashCode` instance.
    // And the result is implicitly converted to `Int32`.
    return HashCode.Start
        .Hash(_field1)
        .Hash(_field2)     
        .Hash(_field3);
}

Edit (May 2018): EqualityComparer<T>.Default getter is now a JIT intrinsic - the pull request is mentioned by Stephen Toub in this blog post.

6
  • 1
    I would change the line with the tertiary operator to be: var h = Equals(obj, default(T)) ? 0 : obj.GetHashCode();
    – Bill Barry
    Sep 5, 2014 at 17:12
  • I believe that the ternary operator with obj != null will compile to a box instruction which will allocate memory if T is a value type. Instead you can use obj.Equals(null) which will compile to a virtual call of the Equals method. Sep 13, 2014 at 23:00
  • Because this.hashCode != h. It wouldn't return the same value. Jun 15, 2015 at 8:01
  • Sorry, manage to remove my comment instead of editing it. Is it more beneficial to create a new struct then change the hashCode to non-readonly and do: "unchecked { this.hashCode ^= h * 397; } return this;" for example? Jun 15, 2015 at 8:28
  • Immutability has its benefits (Why are mutable structs evil?). About performance, what I do is pretty cheap since it does not allocate any space in the heap. Jun 15, 2015 at 10:35
31

In most cases where Equals() compares multiple fields it doesn't really matter if your GetHash() hashes on one field or on many. You just have to make sure that calculating the hash is really cheap (No allocations, please) and fast (No heavy computations and certainly no database connections) and provides a good distribution.

The heavy lifting should be part of the Equals() method; the hash should be a very cheap operation to enable calling Equals() on as few items as possible.

And one final tip: Don't rely on GetHashCode() being stable over multiple aplication runs. Many .Net types don't guarantee their hash codes to stay the same after a restart, so you should only use the value of GetHashCode() for in memory data structures.

5
  • 12
    "In most cases where Equals() compares multiple fields it doesn't really matter if your GetHash() hashes on one field or on many." This is dangerous advice, because for objects which only differ in the un-hashed fields, you will get hash collisions. If this happens frequently, the performance of hash-based collections (HashMap, HashSet etc.) will degrade (up to O(n) in the worst case).
    – sleske
    Apr 15, 2010 at 15:44
  • 12
    This actually happened in Java: In early versions of the JDK String.hashCode() only considered the beginning of the string; this lead to performance problems if you used Strings as keys in HashMaps which only differed at the end (which is common e.g. for URLs). The algorithm was therefore changed ( in JDK 1.2 or 1.3 I believe).
    – sleske
    Apr 15, 2010 at 15:51
  • 4
    If that one field 'provides a good distribution' (last part of my answer), then one field is enough.. If it doesn't provide a good distribution, then (and just then) you need another calculation. (E.g. just use another field that does provide a good distribution, or use multiple fields) Apr 16, 2010 at 9:12
  • I don't think there's a problem with having GetHashCode perform memory allocations, provided that it only does so the first time it's used (with subsequent invocations simply returning a cached result). The important thing is not that one should go to great lengths to avoid collisions, but rather that one should avoid "systemic" collisions. If a type has two int fields oldX and newX which frequently differ by one, a hash value of oldX^newX would assign 90% of such records hash values of 1, 2, 4, or 8. Using oldX+newX [unchecked arithmetic] might generate more collisions...
    – supercat
    Sep 7, 2013 at 21:02
  • 1
    ...than would more sophisticated function, but a collection of 1,000,000 things that have 500,000 different hash values will very well if each hash value has two associated things, and very badly if one hash value has 500,001 things and the others have one each.
    – supercat
    Sep 7, 2013 at 21:04
27

Up until recently my answer would have been very close to Jon Skeet's here. However, I recently started a project which used power-of-two hash tables, that is hash tables where the size of the internal table is 8, 16, 32, etc. There's a good reason for favouring prime-number sizes, but there are some advantages to power-of-two sizes too.

And it pretty much sucked. So after a bit of experimentation and research I started re-hashing my hashes with the following:

public static int ReHash(int source)
{
  unchecked
  {
    ulong c = 0xDEADBEEFDEADBEEF + (ulong)source;
    ulong d = 0xE2ADBEEFDEADBEEF ^ c;
    ulong a = d += c = c << 15 | c >> -15;
    ulong b = a += d = d << 52 | d >> -52;
    c ^= b += a = a << 26 | a >> -26;
    d ^= c += b = b << 51 | b >> -51;
    a ^= d += c = c << 28 | c >> -28;
    b ^= a += d = d << 9 | d >> -9;
    c ^= b += a = a << 47 | a >> -47;
    d ^= c += b << 54 | b >> -54;
    a ^= d += c << 32 | c >> 32;
    a += d << 25 | d >> -25;
    return (int)(a >> 1);
  }
}

And then my power-of-two hash table didn't suck any more.

This disturbed me though, because the above shouldn't work. Or more precisely, it shouldn't work unless the original GetHashCode() was poor in a very particular way.

Re-mixing a hashcode can't improve a great hashcode, because the only possible effect is that we introduce a few more collisions.

Re-mixing a hash code can't improve a terrible hash code, because the only possible effect is we change e.g. a large number of collisions on value 53 to a large number of value 18,3487,291.

Re-mixing a hash code can only improve a hash code that did at least fairly well in avoiding absolute collisions throughout its range (232 possible values) but badly at avoiding collisions when modulo'd down for actual use in a hash table. While the simpler modulo of a power-of-two table made this more apparent, it was also having a negative effect with the more common prime-number tables, that just wasn't as obvious (the extra work in rehashing would outweigh the benefit, but the benefit would still be there).

Edit: I was also using open-addressing, which would also have increased the sensitivity to collision, perhaps more so than the fact it was power-of-two.

And well, it was disturbing how much the string.GetHashCode() implementations in .NET (or study here) could be improved this way (on the order of tests running about 20-30 times faster due to fewer collisions) and more disturbing how much my own hash codes could be improved (much more than that).

All the GetHashCode() implementations I'd coded in the past, and indeed used as the basis of answers on this site, were much worse than I'd throught. Much of the time it was "good enough" for much of the uses, but I wanted something better.

So I put that project to one side (it was a pet project anyway) and started looking at how to produce a good, well-distributed hash code in .NET quickly.

In the end I settled on porting SpookyHash to .NET. Indeed the code above is a fast-path version of using SpookyHash to produce a 32-bit output from a 32-bit input.

Now, SpookyHash is not a nice quick to remember piece of code. My port of it is even less so because I hand-inlined a lot of it for better speed*. But that's what code reuse is for.

Then I put that project to one side, because just as the original project had produced the question of how to produce a better hash code, so that project produced the question of how to produce a better .NET memcpy.

Then I came back, and produced a lot of overloads to easily feed just about all of the native types (except decimal†) into a hash code.

It's fast, for which Bob Jenkins deserves most of the credit because his original code I ported from is faster still, especially on 64-bit machines which the algorithm is optimised for‡.

The full code can be seen at https://bitbucket.org/JonHanna/spookilysharp/src but consider that the code above is a simplified version of it.

However, since it's now already written, one can make use of it more easily:

public override int GetHashCode()
{
  var hash = new SpookyHash();
  hash.Update(field1);
  hash.Update(field2);
  hash.Update(field3);
  return hash.Final().GetHashCode();
}

It also takes seed values, so if you need to deal with untrusted input and want to protect against Hash DoS attacks you can set a seed based on uptime or similar, and make the results unpredictable by attackers:

private static long hashSeed0 = Environment.TickCount;
private static long hashSeed1 = DateTime.Now.Ticks;
public override int GetHashCode()
{
  //produce different hashes ever time this application is restarted
  //but remain consistent in each run, so attackers have a harder time
  //DoSing the hash tables.
  var hash = new SpookyHash(hashSeed0, hashSeed1);
  hash.Update(field1);
  hash.Update(field2);
  hash.Update(field3);
  return hash.Final().GetHashCode();
}

*A big surprise in this is that hand-inlining a rotation method that returned (x << n) | (x >> -n) improved things. I would have been sure that the jitter would have inlined that for me, but profiling showed otherwise.

decimal isn't native from the .NET perspective though it is from the C#. The problem with it is that its own GetHashCode() treats precision as significant while its own Equals() does not. Both are valid choices, but not mixed like that. In implementing your own version, you need to choose to do one, or the other, but I can't know which you'd want.

‡By way of comparison. If used on a string, the SpookyHash on 64 bits is considerably faster than string.GetHashCode() on 32 bits which is slightly faster than string.GetHashCode() on 64 bits, which is considerably faster than SpookyHash on 32 bits, though still fast enough to be a reasonable choice.

7
  • When combining multiple hash values into one, I tend to use long values for the intermediate results, and then munge the final result down to an int. Does that seem like a good idea? My concern is that one uses e.g. hash=(hash*31)+nextField, then pairs of matching values will only affect the upper 27 bits of the hash. Letting the calculation extend to a long and wrapping stuff in would minimize that danger.
    – supercat
    Apr 24, 2014 at 21:31
  • @supercat it depends on the distribution of your final munging. The SpookilySharp library would ensure that the distribution was good, ideally (because it won't need object creation) by passing a pointer to a blittable type, or passing one of the enumerables it handles directly, but if you don't already have blittable data or a suitable enumeration, then calling .Update() with the multiple values as per the answer above will do the trick.
    – Jon Hanna
    Apr 24, 2014 at 22:48
  • @JonHanna would you be willing to be more precise with the problematic behavior you encountered? I'm trying to implement a library that makes implementing value objects trivial (ValueUtils) and I'd love a testset demonstrating poor hash miscibility in power-of-two hashtables. Jun 1, 2014 at 14:19
  • @EamonNerbonne I don't really have anything more precise than "overall time was slower that way". As I added in an edit, the fact that I was using open-addressing may have been more important than the power-of-two factor. I do plan to do some test cases on a particular project where I'll be comparing a few different approaches, so I may have a better answer for you after that, though that's not a high-priority (a personal project with no pressing need, so I'll get to it when I get to it...)
    – Jon Hanna
    Jun 2, 2014 at 14:01
  • @JonHanna: yeah I know how the personal project schedule goes - good luck! In any case, I see I didn't phrase that last comment well: I meant to ask for the problematic input, and not necessarily the details of the problems that resulted. I'd love to use that as a test set (or inspiration for a test set). In any case - good luck with your pet project :-). Jun 2, 2014 at 15:23
26

As of https://github.com/dotnet/coreclr/pull/14863, there is a new way to generate hash codes that is super simple! Just write

public override int GetHashCode()
    => HashCode.Combine(field1, field2, field3);

This will generate a quality hash code without you having to worry about the implementation details.

6
  • That looks like a sweet addition... any way to know what version of .NET Core that'll ship in?
    – Dan J
    Dec 14, 2017 at 0:37
  • 1
    @DanJ What a happy coincidence, the HashCode changes for corefx were merged just a couple of hours before your comment :) The type is slated to ship in .NET Core 2.1.
    – James Ko
    Dec 14, 2017 at 0:41
  • That is awesome - and quite the turnaround time. Upvoted. :)
    – Dan J
    Dec 14, 2017 at 0:48
  • @DanJ Even better news-- it should be available right now on the nightly builds of CoreFX hosted on the dotnet-core MyGet feed.
    – James Ko
    Dec 15, 2017 at 23:44
  • Sweet - that doesn't help me at work, since we're not quite that bleeding-edge, but good to know. Cheers!
    – Dan J
    Dec 17, 2017 at 22:18
13

This is a good one:

/// <summary>
/// Helper class for generating hash codes suitable 
/// for use in hashing algorithms and data structures like a hash table. 
/// </summary>
public static class HashCodeHelper
{
    private static int GetHashCodeInternal(int key1, int key2)
    {
        unchecked
        {
           var num = 0x7e53a269;
           num = (-1521134295 * num) + key1;
           num += (num << 10);
           num ^= (num >> 6);

           num = ((-1521134295 * num) + key2);
           num += (num << 10);
           num ^= (num >> 6);

           return num;
        }
    }

    /// <summary>
    /// Returns a hash code for the specified objects
    /// </summary>
    /// <param name="arr">An array of objects used for generating the 
    /// hash code.</param>
    /// <returns>
    /// A hash code, suitable for use in hashing algorithms and data 
    /// structures like a hash table. 
    /// </returns>
    public static int GetHashCode(params object[] arr)
    {
        int hash = 0;
        foreach (var item in arr)
            hash = GetHashCodeInternal(hash, item.GetHashCode());
        return hash;
    }

    /// <summary>
    /// Returns a hash code for the specified objects
    /// </summary>
    /// <param name="obj1">The first object.</param>
    /// <param name="obj2">The second object.</param>
    /// <param name="obj3">The third object.</param>
    /// <param name="obj4">The fourth object.</param>
    /// <returns>
    /// A hash code, suitable for use in hashing algorithms and
    /// data structures like a hash table.
    /// </returns>
    public static int GetHashCode<T1, T2, T3, T4>(T1 obj1, T2 obj2, T3 obj3,
        T4 obj4)
    {
        return GetHashCode(obj1, GetHashCode(obj2, obj3, obj4));
    }

    /// <summary>
    /// Returns a hash code for the specified objects
    /// </summary>
    /// <param name="obj1">The first object.</param>
    /// <param name="obj2">The second object.</param>
    /// <param name="obj3">The third object.</param>
    /// <returns>
    /// A hash code, suitable for use in hashing algorithms and data 
    /// structures like a hash table. 
    /// </returns>
    public static int GetHashCode<T1, T2, T3>(T1 obj1, T2 obj2, T3 obj3)
    {
        return GetHashCode(obj1, GetHashCode(obj2, obj3));
    }

    /// <summary>
    /// Returns a hash code for the specified objects
    /// </summary>
    /// <param name="obj1">The first object.</param>
    /// <param name="obj2">The second object.</param>
    /// <returns>
    /// A hash code, suitable for use in hashing algorithms and data 
    /// structures like a hash table. 
    /// </returns>
    public static int GetHashCode<T1, T2>(T1 obj1, T2 obj2)
    {
        return GetHashCodeInternal(obj1.GetHashCode(), obj2.GetHashCode());
    }
}

And here is how to use it:

private struct Key
{
    private Type _type;
    private string _field;

    public Type Type { get { return _type; } }
    public string Field { get { return _field; } }

    public Key(Type type, string field)
    {
        _type = type;
        _field = field;
    }

    public override int GetHashCode()
    {
        return HashCodeHelper.GetHashCode(_field, _type);
    }

    public override bool Equals(object obj)
    {
        if (!(obj is Key))
            return false;
        var tf = (Key)obj;
        return tf._field.Equals(_field) && tf._type.Equals(_type);
    }
}
10
  • 1
    How are the Keys determined? GetHashCode() doesn't take any parameters, so it needs to call this one with two Keys that need to be determined somehow. Sorry, without further explanation this only looks clever, but not that good. Oct 7, 2010 at 17:28
  • And why do you need the generic overloads? The type is not important (and not used in your code) since all objects have a GetHashCode() method, so you can always use the method with the params array parameter. Or am I missing something here?
    – gehho
    Oct 8, 2010 at 9:31
  • 4
    When you'd use object instead of generics you'd get boxing and memory allocations, which you don't want in GetHashCode. So generics are the way to go. Nov 21, 2010 at 22:26
  • 1
    The trailing shift/xor steps (h += (h << 10); h ^= (h >> 6); h += (h << 3); h ^= (h >> 11); h += (h << 15); have a codesmell: they do not depend on any of the input and look awfully redundant to me.
    – sehe
    Apr 22, 2011 at 19:54
  • 1
    @Magnus yes right, I'll delete my original comment. Just a little note that this may not be as fast as some other solutions here, but as you say shouldn't matter. The distribution is great, better than most solutions here, so +1 from me! :)
    – nawfal
    Dec 25, 2012 at 11:28
11

Here is another fluent implementation of the algorithm posted above by Jon Skeet, but which includes no allocations or boxing operations:

public static class Hash
{
    public const int Base = 17;

    public static int HashObject(this int hash, object obj)
    {
        unchecked { return hash * 23 + (obj == null ? 0 : obj.GetHashCode()); }
    }

    public static int HashValue<T>(this int hash, T value)
        where T : struct
    {
        unchecked { return hash * 23 + value.GetHashCode(); }
    }
}

Usage:

public class MyType<T>
{
    public string Name { get; set; }

    public string Description { get; set; }

    public int Value { get; set; }

    public IEnumerable<T> Children { get; set; }

    public override int GetHashCode()
    {
        return Hash.Base
            .HashObject(this.Name)
            .HashObject(this.Description)
            .HashValue(this.Value)
            .HashObject(this.Children);
    }
}

The compiler will ensure HashValue is not called with a class due to the generic type constraint. But there is no compiler support for HashObject since adding a generic argument also adds a boxing operation.

0
8

Here is my simplistic approach. I am using the classic builder pattern for this. It is typesafe (no boxing/unboxing) and also compatbile with .NET 2.0 (no extension methods etc.).

It is used like this:

public override int GetHashCode()
{
    HashBuilder b = new HashBuilder();
    b.AddItems(this.member1, this.member2, this.member3);
    return b.Result;
} 

And here is the acutal builder class:

internal class HashBuilder
{
    private const int Prime1 = 17;
    private const int Prime2 = 23;
    private int result = Prime1;

    public HashBuilder()
    {
    }

    public HashBuilder(int startHash)
    {
        this.result = startHash;
    }

    public int Result
    {
        get
        {
            return this.result;
        }
    }

    public void AddItem<T>(T item)
    {
        unchecked
        {
            this.result = this.result * Prime2 + item.GetHashCode();
        }
    }

    public void AddItems<T1, T2>(T1 item1, T2 item2)
    {
        this.AddItem(item1);
        this.AddItem(item2);
    }

    public void AddItems<T1, T2, T3>(T1 item1, T2 item2, T3 item3)
    {
        this.AddItem(item1);
        this.AddItem(item2);
        this.AddItem(item3);
    }

    public void AddItems<T1, T2, T3, T4>(T1 item1, T2 item2, T3 item3, 
        T4 item4)
    {
        this.AddItem(item1);
        this.AddItem(item2);
        this.AddItem(item3);
        this.AddItem(item4);
    }

    public void AddItems<T1, T2, T3, T4, T5>(T1 item1, T2 item2, T3 item3, 
        T4 item4, T5 item5)
    {
        this.AddItem(item1);
        this.AddItem(item2);
        this.AddItem(item3);
        this.AddItem(item4);
        this.AddItem(item5);
    }        

    public void AddItems<T>(params T[] items)
    {
        foreach (T item in items)
        {
            this.AddItem(item);
        }
    }
}
3
  • you can avoid the object creation inside gethashcode function as in Mangus's answer. Just call the damn static hash functions (who cares about starter hash). Also, you could use AddItems<T>(params T[] items) method more often in the helper class (than calling AddItem(T) each time).
    – nawfal
    Apr 14, 2013 at 12:52
  • And what benefit do you find doing this.result * Prime2 * item.GetHashCode() when often used is this.result * Prime2 + item.GetHashCode()?
    – nawfal
    Apr 14, 2013 at 12:54
  • I can't use AddItems<T>(params T[] items) more often because typeof(T1) != typeof(T2) etc.
    – bitbonk
    Apr 15, 2013 at 6:25
7

If we have no more than 8 properties (hopefully), here is another alternative.

ValueTuple is a struct and appears to have a solid GetHashCode implementation.

That means we could simply do this:

// Yay, no allocations and no custom implementations!
public override int GetHashCode() => (this.PropA, this.PropB).GetHashCode();

Let's take a look at .NET Core's current implementation for ValueTuple's GetHashCode.

This is from ValueTuple:

    internal static int CombineHashCodes(int h1, int h2)
    {
        return HashHelpers.Combine(HashHelpers.Combine(HashHelpers.RandomSeed, h1), h2);
    }

    internal static int CombineHashCodes(int h1, int h2, int h3)
    {
        return HashHelpers.Combine(CombineHashCodes(h1, h2), h3);
    }

And this is from HashHelper:

    public static readonly int RandomSeed = Guid.NewGuid().GetHashCode();

    public static int Combine(int h1, int h2)
    {
        unchecked
        {
            // RyuJIT optimizes this to use the ROL instruction
            // Related GitHub pull request: dotnet/coreclr#1830
            uint rol5 = ((uint)h1 << 5) | ((uint)h1 >> 27);
            return ((int)rol5 + h1) ^ h2;
        }
    }

In English:

  • Left rotate (circular shift) h1 by 5 positions.
  • Add the result and h1 together.
  • XOR the result with h2.
  • Start by performing the above operation on { static random seed, h1 }.
  • For each further item, perform the operation on the previous result and the next item (e.g. h2).

It would be nice to know more about the properties of this ROL-5 hash code algorithm.

Regrettably, deferring to ValueTuple for our own GetHashCode may not be as fast as we would like and expect. This comment in a related discussion illustrates that directly calling HashHelpers.Combine is more performant. On the flip side, that one is internal, so we'd have to copy the code, sacrificing much of what we had gained here. Also, we'd be responsible for remembering to first Combine with the random seed. I don't know what the consequences are if we skip that step.

1
  • 1
    Assuming h1 >> 27 is 0 to ignore it, h1 << 5 equals h1 * 32 therefore it is same as h1 * 33 ^ h2. According to this page, it is called "Modified Bernstein".
    – cactuaroid
    Aug 17, 2018 at 14:28
6

ReSharper users can generate GetHashCode, Equals, and others with ReSharper -> Edit -> Generate Code -> Equality Members.

// ReSharper's GetHashCode looks like this
public override int GetHashCode() {
    unchecked {
        int hashCode = Id;
        hashCode = (hashCode * 397) ^ IntMember;
        hashCode = (hashCode * 397) ^ OtherIntMember;
        hashCode = (hashCode * 397) ^ (RefMember != null ? RefMember.GetHashCode() : 0);
        // ...
        return hashCode;
    }
}
4

Most of my work is done with database connectivity which means that my classes all have a unique identifier from the database. I always use the ID from the database to generate the hashcode.

// Unique ID from database
private int _id;

...    
{
  return _id.GetHashCode();
}
6
  • 1
    That means that if you have objects Person and Account and they both have and ID = 1, they will have the same hash code. And that is not ok.
    – pero
    Mar 22, 2010 at 15:28
  • 18
    Actually the comment above is incorrect. There will always be the possibility of hash-code collisions (a hash code only locates the bucket, not the individual object). So such an implementation - for a hashcode containing mixed objects - would lead to a lot of collisions, which is undesirable, but it would be absolutely fine if you only ever had objects of a single type in your hashtables. Also it doesn't distribute evenly, however neither does the base implementation on system.object, so I wouldn't worry about it too much...
    – piers7
    Mar 29, 2010 at 2:14
  • 3
    The hash code can just be the id, since the id is an integer. There's no need to call GetHashCode on an integer (it's an identity function)
    – Darrel Lee
    Nov 23, 2012 at 19:18
  • 3
    @DarrelLee but tomo his _id could be a Guid. It's a good coding practice to do _id.GetHashCode as the intent is clear.
    – nawfal
    Apr 14, 2013 at 12:57
  • 3
    @1224 depending on use patterns it can be horrible for the reason you give, but it can also be great; if you've a sequence of such numbers with no holes, then you've a perfect hash, better than any algorithm can produce. If you know that's the case you can even count on it and skip the equality check.
    – Jon Hanna
    Jan 14, 2014 at 18:29
3

Pretty much similar to nightcoder's solution except it's easier to raise primes if you want to.

PS: This is one of those times where you puke a little in your mouth, knowing that this could be refactored into one method with 9 default's but it would be slower, so you just close your eyes and try to forget about it.

/// <summary>
/// Try not to look at the source code. It works. Just rely on it.
/// </summary>
public static class HashHelper
{
    private const int PrimeOne = 17;
    private const int PrimeTwo = 23;

    public static int GetHashCode<T1, T2, T3, T4, T5, T6, T7, T8, T9, T10>(T1 arg1, T2 arg2, T3 arg3, T4 arg4, T5 arg5, T6 arg6, T7 arg7, T8 arg8, T9 arg9, T10 arg10)
    {
        unchecked
        {
            int hash = PrimeOne;
            hash = hash * PrimeTwo + arg1.GetHashCode();
            hash = hash * PrimeTwo + arg2.GetHashCode();
            hash = hash * PrimeTwo + arg3.GetHashCode();
            hash = hash * PrimeTwo + arg4.GetHashCode();
            hash = hash * PrimeTwo + arg5.GetHashCode();
            hash = hash * PrimeTwo + arg6.GetHashCode();
            hash = hash * PrimeTwo + arg7.GetHashCode();
            hash = hash * PrimeTwo + arg8.GetHashCode();
            hash = hash * PrimeTwo + arg9.GetHashCode();
            hash = hash * PrimeTwo + arg10.GetHashCode();

            return hash;
        }
    }

    public static int GetHashCode<T1, T2, T3, T4, T5, T6, T7, T8, T9>(T1 arg1, T2 arg2, T3 arg3, T4 arg4, T5 arg5, T6 arg6, T7 arg7, T8 arg8, T9 arg9)
    {
        unchecked
        {
            int hash = PrimeOne;
            hash = hash * PrimeTwo + arg1.GetHashCode();
            hash = hash * PrimeTwo + arg2.GetHashCode();
            hash = hash * PrimeTwo + arg3.GetHashCode();
            hash = hash * PrimeTwo + arg4.GetHashCode();
            hash = hash * PrimeTwo + arg5.GetHashCode();
            hash = hash * PrimeTwo + arg6.GetHashCode();
            hash = hash * PrimeTwo + arg7.GetHashCode();
            hash = hash * PrimeTwo + arg8.GetHashCode();
            hash = hash * PrimeTwo + arg9.GetHashCode();

            return hash;
        }
    }

    public static int GetHashCode<T1, T2, T3, T4, T5, T6, T7, T8>(T1 arg1, T2 arg2, T3 arg3, T4 arg4, T5 arg5, T6 arg6, T7 arg7, T8 arg8)
    {
        unchecked
        {
            int hash = PrimeOne;
            hash = hash * PrimeTwo + arg1.GetHashCode();
            hash = hash * PrimeTwo + arg2.GetHashCode();
            hash = hash * PrimeTwo + arg3.GetHashCode();
            hash = hash * PrimeTwo + arg4.GetHashCode();
            hash = hash * PrimeTwo + arg5.GetHashCode();
            hash = hash * PrimeTwo + arg6.GetHashCode();
            hash = hash * PrimeTwo + arg7.GetHashCode();
            hash = hash * PrimeTwo + arg8.GetHashCode();

            return hash;
        }
    }

    public static int GetHashCode<T1, T2, T3, T4, T5, T6, T7>(T1 arg1, T2 arg2, T3 arg3, T4 arg4, T5 arg5, T6 arg6, T7 arg7)
    {
        unchecked
        {
            int hash = PrimeOne;
            hash = hash * PrimeTwo + arg1.GetHashCode();
            hash = hash * PrimeTwo + arg2.GetHashCode();
            hash = hash * PrimeTwo + arg3.GetHashCode();
            hash = hash * PrimeTwo + arg4.GetHashCode();
            hash = hash * PrimeTwo + arg5.GetHashCode();
            hash = hash * PrimeTwo + arg6.GetHashCode();
            hash = hash * PrimeTwo + arg7.GetHashCode();

            return hash;
        }
    }

    public static int GetHashCode<T1, T2, T3, T4, T5, T6>(T1 arg1, T2 arg2, T3 arg3, T4 arg4, T5 arg5, T6 arg6)
    {
        unchecked
        {
            int hash = PrimeOne;
            hash = hash * PrimeTwo + arg1.GetHashCode();
            hash = hash * PrimeTwo + arg2.GetHashCode();
            hash = hash * PrimeTwo + arg3.GetHashCode();
            hash = hash * PrimeTwo + arg4.GetHashCode();
            hash = hash * PrimeTwo + arg5.GetHashCode();
            hash = hash * PrimeTwo + arg6.GetHashCode();

            return hash;
        }
    }

    public static int GetHashCode<T1, T2, T3, T4, T5>(T1 arg1, T2 arg2, T3 arg3, T4 arg4, T5 arg5)
    {
        unchecked
        {
            int hash = PrimeOne;
            hash = hash * PrimeTwo + arg1.GetHashCode();
            hash = hash * PrimeTwo + arg2.GetHashCode();
            hash = hash * PrimeTwo + arg3.GetHashCode();
            hash = hash * PrimeTwo + arg4.GetHashCode();
            hash = hash * PrimeTwo + arg5.GetHashCode();

            return hash;
        }
    }

    public static int GetHashCode<T1, T2, T3, T4>(T1 arg1, T2 arg2, T3 arg3, T4 arg4)
    {
        unchecked
        {
            int hash = PrimeOne;
            hash = hash * PrimeTwo + arg1.GetHashCode();
            hash = hash * PrimeTwo + arg2.GetHashCode();
            hash = hash * PrimeTwo + arg3.GetHashCode();
            hash = hash * PrimeTwo + arg4.GetHashCode();

            return hash;
        }
    }

    public static int GetHashCode<T1, T2, T3>(T1 arg1, T2 arg2, T3 arg3)
    {
        unchecked
        {
            int hash = PrimeOne;
            hash = hash * PrimeTwo + arg1.GetHashCode();
            hash = hash * PrimeTwo + arg2.GetHashCode();
            hash = hash * PrimeTwo + arg3.GetHashCode();

            return hash;
        }
    }

    public static int GetHashCode<T1, T2>(T1 arg1, T2 arg2)
    {
        unchecked
        {
            int hash = PrimeOne;
            hash = hash * PrimeTwo + arg1.GetHashCode();
            hash = hash * PrimeTwo + arg2.GetHashCode();

            return hash;
        }
    }
}
1
  • 2
    Doesn't handle nulls.
    – JJS
    Dec 27, 2016 at 17:09
2

Microsoft lead for several way of hashing...

//for classes that contain a single int value
return this.value;

//for classes that contain multiple int value
return x ^ y;

//for classes that contain single number bigger than int    
return ((int)value ^ (int)(value >> 32)); 

//for classes that contain class instance fields which inherit from object
return obj1.GetHashCode();

//for classes that contain multiple class instance fields which inherit from object
return obj1.GetHashCode() ^ obj2.GetHashCode() ^ obj3.GetHashCode(); 

I can guess that for multiple big int you can use this:

int a=((int)value1 ^ (int)(value1 >> 32));
int b=((int)value2 ^ (int)(value2 >> 32));
int c=((int)value3 ^ (int)(value3 >> 32));
return a ^ b ^ c;

And same for multi-type: all converted first to int using GetHashCode() then the int values will be xor'ed and the result is your hash.

For those who use hash as ID (I mean an unique value), hash is naturally limited to a number of digits, I think it was 5 bytes for hashing algorithm, at least MD5.

You may turn multiple values to a hashed value and some of them be same, so don't use it as an identifier. (maybe some day I am going to use your component)

7
  • 8
    Xoring integers to make a hashcode is a well-known antipattern that tends to result in a particularly high number of collisions with real-world values.
    – Jon Hanna
    Jan 14, 2014 at 9:36
  • Every one here use integer, and there been never any kind of guarantee for hash to be same, it just tried to be as much vary as there are few collisions to happen. Sep 16, 2015 at 5:59
  • Yes, but your second and fifth don't try to avoid collisions.
    – Jon Hanna
    Sep 16, 2015 at 8:44
  • 1
    Yes, that antipattern is quite common.
    – Jon Hanna
    Sep 19, 2015 at 14:06
  • 2
    There's a balance to reach. Use a really good hash code like Spookyhash and you'll get much, much better collision avoidance but it will have much more calculation time than any of these (but when it comes to hashing very large amounts of data, Spookyhash is extremely quick). A simple shift on one of the values before xoring is only marginal extra cost for a good reduction in collision. Prime-number multiplication increasing both time and quality again. Which is better between shift or mult is hence debatable. Plain xor though very often has a lot of collisions on real data and is best avoided
    – Jon Hanna
    Sep 20, 2015 at 16:57
1

This is a static helper class that implements Josh Bloch's implementation; and provides explicit overloads to "prevent" boxing, and also to implement the hash specifically for the long primitives.

You can pass a string comparison that matches your equals implementation.

Because the Hash output is always an int, you can just chain Hash calls.

using System;
using System.Collections;
using System.Collections.Generic;
using System.Reflection;
using System.Runtime.CompilerServices;


namespace Sc.Util.System
{
    /// <summary>
    /// Static methods that allow easy implementation of hashCode. Example usage:
    /// <code>
    /// public override int GetHashCode()
    ///     => HashCodeHelper.Seed
    ///         .Hash(primitiveField)
    ///         .Hsh(objectField)
    ///         .Hash(iEnumerableField);
    /// </code>
    /// </summary>
    public static class HashCodeHelper
    {
        /// <summary>
        /// An initial value for a hashCode, to which is added contributions from fields.
        /// Using a non-zero value decreases collisions of hashCode values.
        /// </summary>
        public const int Seed = 23;

        private const int oddPrimeNumber = 37;


        /// <summary>
        /// Rotates the seed against a prime number.
        /// </summary>
        /// <param name="aSeed">The hash's first term.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        private static int rotateFirstTerm(int aSeed)
        {
            unchecked {
                return HashCodeHelper.oddPrimeNumber * aSeed;
            }
        }


        /// <summary>
        /// Contributes a boolean to the developing HashCode seed.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aBoolean">The value to contribute.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash(this int aSeed, bool aBoolean)
        {
            unchecked {
                return HashCodeHelper.rotateFirstTerm(aSeed)
                        + (aBoolean
                                ? 1
                                : 0);
            }
        }

        /// <summary>
        /// Contributes a char to the developing HashCode seed.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aChar">The value to contribute.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash(this int aSeed, char aChar)
        {
            unchecked {
                return HashCodeHelper.rotateFirstTerm(aSeed)
                        + aChar;
            }
        }

        /// <summary>
        /// Contributes an int to the developing HashCode seed.
        /// Note that byte and short are handled by this method, through implicit conversion.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aInt">The value to contribute.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash(this int aSeed, int aInt)
        {
            unchecked {
                return HashCodeHelper.rotateFirstTerm(aSeed)
                        + aInt;
            }
        }

        /// <summary>
        /// Contributes a long to the developing HashCode seed.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aLong">The value to contribute.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash(this int aSeed, long aLong)
        {
            unchecked {
                return HashCodeHelper.rotateFirstTerm(aSeed)
                        + (int)(aLong ^ (aLong >> 32));
            }
        }

        /// <summary>
        /// Contributes a float to the developing HashCode seed.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aFloat">The value to contribute.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash(this int aSeed, float aFloat)
        {
            unchecked {
                return HashCodeHelper.rotateFirstTerm(aSeed)
                        + Convert.ToInt32(aFloat);
            }
        }

        /// <summary>
        /// Contributes a double to the developing HashCode seed.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aDouble">The value to contribute.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash(this int aSeed, double aDouble)
            => aSeed.Hash(Convert.ToInt64(aDouble));

        /// <summary>
        /// Contributes a string to the developing HashCode seed.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aString">The value to contribute.</param>
        /// <param name="stringComparison">Optional comparison that creates the hash.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash(
                this int aSeed,
                string aString,
                StringComparison stringComparison = StringComparison.Ordinal)
        {
            if (aString == null)
                return aSeed.Hash(0);
            switch (stringComparison) {
                case StringComparison.CurrentCulture :
                    return StringComparer.CurrentCulture.GetHashCode(aString);
                case StringComparison.CurrentCultureIgnoreCase :
                    return StringComparer.CurrentCultureIgnoreCase.GetHashCode(aString);
                case StringComparison.InvariantCulture :
                    return StringComparer.InvariantCulture.GetHashCode(aString);
                case StringComparison.InvariantCultureIgnoreCase :
                    return StringComparer.InvariantCultureIgnoreCase.GetHashCode(aString);
                case StringComparison.OrdinalIgnoreCase :
                    return StringComparer.OrdinalIgnoreCase.GetHashCode(aString);
                default :
                    return StringComparer.Ordinal.GetHashCode(aString);
            }
        }

        /// <summary>
        /// Contributes a possibly-null array to the developing HashCode seed.
        /// Each element may be a primitive, a reference, or a possibly-null array.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aArray">CAN be null.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash(this int aSeed, IEnumerable aArray)
        {
            if (aArray == null)
                return aSeed.Hash(0);
            int countPlusOne = 1; // So it differs from null
            foreach (object item in aArray) {
                ++countPlusOne;
                if (item is IEnumerable arrayItem) {
                    if (!object.ReferenceEquals(aArray, arrayItem))
                        aSeed = aSeed.Hash(arrayItem); // recursive call!
                } else
                    aSeed = aSeed.Hash(item);
            }
            return aSeed.Hash(countPlusOne);
        }

        /// <summary>
        /// Contributes a possibly-null array to the developing HashCode seed.
        /// You must provide the hash function for each element.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aArray">CAN be null.</param>
        /// <param name="hashElement">Required: yields the hash for each element
        /// in <paramref name="aArray"/>.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash<T>(this int aSeed, IEnumerable<T> aArray, Func<T, int> hashElement)
        {
            if (aArray == null)
                return aSeed.Hash(0);
            int countPlusOne = 1; // So it differs from null
            foreach (T item in aArray) {
                ++countPlusOne;
                aSeed = aSeed.Hash(hashElement(item));
            }
            return aSeed.Hash(countPlusOne);
        }

        /// <summary>
        /// Contributes a possibly-null object to the developing HashCode seed.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="aObject">CAN be null.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int Hash(this int aSeed, object aObject)
        {
            switch (aObject) {
                case null :
                    return aSeed.Hash(0);
                case bool b :
                    return aSeed.Hash(b);
                case char c :
                    return aSeed.Hash(c);
                case int i :
                    return aSeed.Hash(i);
                case long l :
                    return aSeed.Hash(l);
                case float f :
                    return aSeed.Hash(f);
                case double d :
                    return aSeed.Hash(d);
                case string s :
                    return aSeed.Hash(s);
                case IEnumerable iEnumerable :
                    return aSeed.Hash(iEnumerable);
            }
            return aSeed.Hash(aObject.GetHashCode());
        }


        /// <summary>
        /// This utility method uses reflection to iterate all specified properties that are readable
        /// on the given object, excluding any property names given in the params arguments, and
        /// generates a hashcode.
        /// </summary>
        /// <param name="aSeed">The developing hash code, or the seed: if you have no seed, use
        /// the <see cref="Seed"/>.</param>
        /// <param name="aObject">CAN be null.</param>
        /// <param name="propertySelector"><see cref="BindingFlags"/> to select the properties to hash.</param>
        /// <param name="ignorePropertyNames">Optional.</param>
        /// <returns>A hash from the properties contributed to <c>aSeed</c>.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int HashAllProperties(
                this int aSeed,
                object aObject,
                BindingFlags propertySelector
                        = BindingFlags.Instance
                        | BindingFlags.Public
                        | BindingFlags.GetProperty,
                params string[] ignorePropertyNames)
        {
            if (aObject == null)
                return aSeed.Hash(0);
            if ((ignorePropertyNames != null)
                    && (ignorePropertyNames.Length != 0)) {
                foreach (PropertyInfo propertyInfo in aObject.GetType()
                        .GetProperties(propertySelector)) {
                    if (!propertyInfo.CanRead
                            || (Array.IndexOf(ignorePropertyNames, propertyInfo.Name) >= 0))
                        continue;
                    aSeed = aSeed.Hash(propertyInfo.GetValue(aObject));
                }
            } else {
                foreach (PropertyInfo propertyInfo in aObject.GetType()
                        .GetProperties(propertySelector)) {
                    if (propertyInfo.CanRead)
                        aSeed = aSeed.Hash(propertyInfo.GetValue(aObject));
                }
            }
            return aSeed;
        }


        /// <summary>
        /// NOTICE: this method is provided to contribute a <see cref="KeyValuePair{TKey,TValue}"/> to
        /// the developing HashCode seed; by hashing the key and the value independently. HOWEVER,
        /// this method has a different name since it will not be automatically invoked by
        /// <see cref="Hash(int,object)"/>, <see cref="Hash(int,IEnumerable)"/>,
        /// or <see cref="HashAllProperties"/> --- you MUST NOT mix this method with those unless
        /// you are sure that no KeyValuePair instances will be passed to those methods; or otherwise
        /// the generated hash code will not be consistent. This method itself ALSO will not invoke
        /// this method on the Key or Value here if that itself is a KeyValuePair.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="keyValuePair">The value to contribute.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int HashKeyAndValue<TKey, TValue>(this int aSeed, KeyValuePair<TKey, TValue> keyValuePair)
            => aSeed.Hash(keyValuePair.Key)
                    .Hash(keyValuePair.Value);

        /// <summary>
        /// NOTICE: this method is provided to contribute a collection of <see cref="KeyValuePair{TKey,TValue}"/>
        /// to the developing HashCode seed; by hashing the key and the value independently. HOWEVER,
        /// this method has a different name since it will not be automatically invoked by
        /// <see cref="Hash(int,object)"/>, <see cref="Hash(int,IEnumerable)"/>,
        /// or <see cref="HashAllProperties"/> --- you MUST NOT mix this method with those unless
        /// you are sure that no KeyValuePair instances will be passed to those methods; or otherwise
        /// the generated hash code will not be consistent. This method itself ALSO will not invoke
        /// this method on a Key or Value here if that itself is a KeyValuePair or an Enumerable of
        /// KeyValuePair.
        /// </summary>
        /// <param name="aSeed">The developing HashCode value or seed.</param>
        /// <param name="keyValuePairs">The values to contribute.</param>
        /// <returns>The new hash code.</returns>
        [MethodImpl(MethodImplOptions.AggressiveInlining)]
        public static int HashKeysAndValues<TKey, TValue>(
                this int aSeed,
                IEnumerable<KeyValuePair<TKey, TValue>> keyValuePairs)
        {
            if (keyValuePairs == null)
                return aSeed.Hash(null);
            foreach (KeyValuePair<TKey, TValue> keyValuePair in keyValuePairs) {
                aSeed = aSeed.HashKeyAndValue(keyValuePair);
            }
            return aSeed;
        }
    }
}
1
  • Yipes: I found a bug! The HashKeysAndValues method has been fixed: it invokes HashKeyAndValue. May 9, 2019 at 0:14
0

I ran into an issue with floats and decimals using the implementation selected as the answer above.

This test fails (floats; hash is the same even though I switched 2 values to be negative):

        var obj1 = new { A = 100m, B = 100m, C = 100m, D = 100m};
        var obj2 = new { A = 100m, B = 100m, C = -100m, D = -100m};
        var hash1 = ComputeHash(obj1.A, obj1.B, obj1.C, obj1.D);
        var hash2 = ComputeHash(obj2.A, obj2.B, obj2.C, obj2.D);
        Assert.IsFalse(hash1 == hash2, string.Format("Hashcode values should be different   hash1:{0}  hash2:{1}",hash1,hash2));

But this test passes (with ints):

        var obj1 = new { A = 100m, B = 100m, C = 100, D = 100};
        var obj2 = new { A = 100m, B = 100m, C = -100, D = -100};
        var hash1 = ComputeHash(obj1.A, obj1.B, obj1.C, obj1.D);
        var hash2 = ComputeHash(obj2.A, obj2.B, obj2.C, obj2.D);
        Assert.IsFalse(hash1 == hash2, string.Format("Hashcode values should be different   hash1:{0}  hash2:{1}",hash1,hash2));

I changed my implementation to not use GetHashCode for the primitive types and it seems to work better

    private static int InternalComputeHash(params object[] obj)
    {
        unchecked
        {
            var result = (int)SEED_VALUE_PRIME;
            for (uint i = 0; i < obj.Length; i++)
            {
                var currval = result;
                var nextval = DetermineNextValue(obj[i]);
                result = (result * MULTIPLIER_VALUE_PRIME) + nextval;

            }
            return result;
        }
    }



    private static int DetermineNextValue(object value)
    {
        unchecked
        {

                int hashCode;
                if (value is short
                    || value is int
                    || value is byte
                    || value is sbyte
                    || value is uint
                    || value is ushort
                    || value is ulong
                    || value is long
                    || value is float
                    || value is double
                    || value is decimal)
                {
                    return Convert.ToInt32(value);
                }
                else
                {
                    return value != null ? value.GetHashCode() : 0;
                }
        }
    }
1
  • 2
    In case you intended otherwise unchecked does NOT affect Convert.ToInt32: uint, long, float, double and decimal can all overflow here.
    – Mark Hurd
    Sep 30, 2014 at 4:28
0

In case you want to polyfill HashCode from netstandard2.1

public static class HashCode
{
    public static int Combine(params object[] instances)
    {
        int hash = 17;

        foreach (var i in instances)
        {
            hash = unchecked((hash * 31) + (i?.GetHashCode() ?? 0));
        }

        return hash;
    }
}

Note: If used with struct, it will allocate memory due to boxing

0

Can try to adopt approach from C++ Boost libraries. Something like this:

class HashUtil
{
  public static int HashCombine(int seed, int other)
  {
    unchecked
    {
      return other + 0x9e3779b9 + (seed << 6) + (seed >> 2);
    }
  }
}

and then:

class MyClass
{
  private string _field1;
  private int _field2;
  private AnotherClass _field3;
  private YetAnotherClass _field4;

  public override int GetHashCode()
  {
    int result = HashUtil.HashCombine(_field1.GetHashCode(), _field2);
    result = HashUtil.HashCombine(result, _field3.GetHashCode());
    return HashUtil.HashCombine(result, _field4.GetHashCode());
  }
}
-1

I want to add my newest findings to this thread I came back to so often.

My current visual studio / project setup provides the functionallity to automatically refactors tuples to structs. This will generate a GetHashCode function like so:

        public override int GetHashCode()
        {
            int hashCode = -2088324004;
            hashCode = hashCode * -1521134295 + AuftragGesperrt.GetHashCode();
            hashCode = hashCode * -1521134295 + Auftrag_gesperrt_von.GetHashCode();
            hashCode = hashCode * -1521134295 + Auftrag_gesperrt_am.GetHashCode();
            return hashCode;
        }

EDIT: to clarify AuftragGesperrt, Auftrag_gesperrt_von and Auftrag_gesperrt_am are properties. If the microsoft devs use this function its probably not too bad of a solution.

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