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How can I do this fast? Sure I can do this:

static bool ByteArrayCompare(byte[] a1, byte[] a2) 
{
  if(a1.Length!=a2.Length)
    return false;

  for(int i=0; i<a1.Length; i++)
    if(a1[i]!=a2[i])
      return false;

  return true;
}

but I'm looking for either a BCL function or some highly optimized proven way to do this.

[Edit]Thanks to JasonBunting and aku for their input.

java.util.Arrays.equals((sbyte[])(Array)a1, (sbyte[])(Array)a2);

works nicely, but it doesn't look like that would work for x64.

[Edit] Note my super-fast answer here.

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1  
"This kinda counts on the fact that the arrays start qword aligned." That's a big if. You should fix the code to reflect that. –  Joe Chung Aug 9 '09 at 20:45
    
return a1.Length == a2.Length && !a1.Where((t, i) => t != a2[i]).Any(); –  alerya Aug 31 '12 at 12:10
    
I liked @OhadSchneider answer about IStructuralEquatable –  Lijo Mar 1 '13 at 7:01

14 Answers 14

You can use Enumerable.SequenceEqual method.

using System;
using System.Linq;
...
var a1 = new int[] { 1, 2, 3};
var a2 = new int[] { 1, 2, 3};
var a3 = new int[] { 1, 2, 4};
var x = a1.SequenceEqual(a2); // true
var y = a1.SequenceEqual(a3); // false

If you can't use .NET 3.5 for some reason, your method is OK.
Compiler\run-time environment will optimize your loop so you don't need to worry about performance.

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1  
I love it. Works for all collections –  Sameer Alibhai Sep 1 '10 at 17:30
    
But doesn't SequenceEqual take longer to process than an unsafe comparison? Especially when your doing 1000's of comparisons? –  tcables Jan 20 '11 at 18:18
29  
Yes, this runs about 50x slower than the unsafe comparison. –  Hafthor Feb 3 '11 at 2:53
    
thank you @aku and thank you LINQ - still finding useful methods! –  iagosabel Sep 21 '12 at 15:06

P/Invoke Powers activate!

[DllImport("msvcrt.dll", CallingConvention=CallingConvention.Cdecl)]
static extern int memcmp(byte[] b1, byte[] b2, long count);

static bool ByteArrayCompare(byte[] b1, byte[] b2)
{
    // Validate buffers are the same length.
    // This also ensures that the count does not exceed the length of either buffer.  
    return b1.Length == b2.Length && memcmp(b1, b2, b1.Length) == 0;
}
share|improve this answer
11  
P/Invoke... booo... –  Andrei Rînea Dec 5 '09 at 1:45
15  
P/Invoke yaay - this proved to be fastest by far on bitmaps at least: stackoverflow.com/questions/2031217/… –  BrightUmbra Jan 10 '10 at 20:48
18  
Pinning is not necessary in this case. The marshaller performs automatic pinning when calling native code with PInvoke. Reference: stackoverflow.com/questions/2218444/… –  Mark Glasgow Mar 16 '10 at 8:55
7  
P/Invoke may elicit boos but it is by far the fastest of all the solutions presented, including an implementation I came up with that uses unsafe pointer-sized comparisons. There are a few optimizations you can make though before calling out to native code including reference equality and comparing the first and last elements. –  Josh Sep 1 '11 at 19:44
7  
Why the boo? Poster wanted a fast implementation and an optimized assembly language compare can't be beat. I don't know how to get a "REPE CMPSD" out of .NET without P/INVOKE. –  Jason Goemaat Oct 2 '11 at 6:55

There's a new built-in solution for this in .NET 4 - IStructuralEquatable

static bool ByteArrayCompare(byte[] a1, byte[] a2) 
{
    return StructuralComparisons.StructuralEqualityComparer.Equals(a1, a2);
}
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1  
Thanks a lot, exactly what I was looking for! –  Raphyboy Mar 17 '12 at 0:29
    
Really good tip, thanks a million! –  noonand Oct 25 '12 at 16:51
9  
According to this blog post that's actually very slow. –  Matt Johnson Dec 17 '12 at 23:23
10  
Crazy slow. About 180x slower than simple for loop. –  Hafthor Dec 21 '12 at 5:47
1  
@ta.speot.is Thanks, Can't argue with a one liner ! The previous solution was slightly more efficient since it saved the cast to IStructuralEquatable (an array is statically known to be IStructuralEquatable), but indeed your suggestions makes the method work for null arguments as well. –  Ohad Schneider Mar 25 at 11:39
up vote 27 down vote accepted

ebil gil suggested unsafe code which spawned this solution:

// Copyright (c) 2008-2013 Hafthor Stefansson
// Distributed under the MIT/X11 software license
// Ref: http://www.opensource.org/licenses/mit-license.php.
static unsafe bool UnsafeCompare(byte[] a1, byte[] a2) {
  if(a1==null || a2==null || a1.Length!=a2.Length)
    return false;
  fixed (byte* p1=a1, p2=a2) {
    byte* x1=p1, x2=p2;
    int l = a1.Length;
    for (int i=0; i < l/8; i++, x1+=8, x2+=8)
      if (*((long*)x1) != *((long*)x2)) return false;
    if ((l & 4)!=0) { if (*((int*)x1)!=*((int*)x2)) return false; x1+=4; x2+=4; }
    if ((l & 2)!=0) { if (*((short*)x1)!=*((short*)x2)) return false; x1+=2; x2+=2; }
    if ((l & 1)!=0) if (*((byte*)x1) != *((byte*)x2)) return false;
    return true;
  }
}

which does 64-bit based comparison for as much of the array as possible. This kinda counts on the fact that the arrays start qword aligned. It'll work if not qword aligned, just not as fast as if it were.

It performs about 7x faster than the simple for loop. Using the J# library performed equivalently to the original for loop. Using .SequenceEqual runs around 7x slower, I think just because it is using IEnumerator.MoveNext. I imagine LINQ-based solutions being at least that slow or worse.

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3  
Nice solution. But one (small) hint: A compare if references a1 and a2 are equal may speed up things if one gives the same array for a1 and b1. –  Rüdiger Stevens Dec 20 '12 at 13:34
2  
New test data on .NET 4 x64 release: IStructualEquatable.equals ~180x slower, SequenceEqual 15x slower, SHA1 hash compare 11x slower, bitconverter ~same, unsafe 7x faster, pinvoke 11x faster. Pretty cool that unsafe is only a little bit slower than P/Invoke on memcmp. –  Hafthor Dec 21 '12 at 5:46
2  
This link gives good detail about why memory alignment matters ibm.com/developerworks/library/pa-dalign - so, an optimization could be to check alignment and if both arrays are off alignment by the same amount, do byte compares until they are both on a qword boundary. –  Hafthor Jan 10 '13 at 16:28
1  
wouldnt this give false when both a1 and a2 are null? –  nawfal Apr 14 '13 at 10:26
2  
@Robear en.wikipedia.org/wiki/Short-circuit_evaluation –  Hafthor Sep 25 '13 at 15:47

If you are not opposed to doing it, you can import the J# assembly "vjslib.dll" and use its Arrays.equals(byte[], byte[]) method...

Don't blame me if someone laughs at you though...


EDIT: For what little it is worth, I used Reflector to disassemble the code for that, and here is what it looks like:

public static bool equals(sbyte[] a1, sbyte[] a2)
{
  if (a1 == a2)
  {
    return true;
  }
  if ((a1 != null) && (a2 != null))
  {
    if (a1.Length != a2.Length)
    {
      return false;
    }
    for (int i = 0; i < a1.Length; i++)
    {
      if (a1[i] != a2[i])
      {
        return false;
      }
    }
    return true;
  }
  return false;
}
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.NET 3.5 and newer have a new public type, System.Data.Linq.Binary that encapsulates byte[]. It implements IEquatable<Binary> that (in effect) compares two byte arrays. Note that System.Data.Linq.Binary also has implicit conversion operator from byte[].

MSDN documentation:System.Data.Linq.Binary

Reflector decompile of the Equals method:

private bool EqualsTo(Binary binary)
{
    if (this != binary)
    {
        if (binary == null)
        {
            return false;
        }
        if (this.bytes.Length != binary.bytes.Length)
        {
            return false;
        }
        if (this.hashCode != binary.hashCode)
        {
            return false;
        }
        int index = 0;
        int length = this.bytes.Length;
        while (index < length)
        {
            if (this.bytes[index] != binary.bytes[index])
            {
                return false;
            }
            index++;
        }
    }
    return true;
}

Interesting twist is that they only proceed to byte-by-byte comparison loop if hashes of the two Binary objects are the same. This, however, comes at the cost of computing the hash in constructor of Binary objects (by traversing the array with for loop :-) ).

The above implementation means that in the worst case you may have to traverse the arrays three times: first to compute hash of array1, then to compute hash of array2 and finally (because this is the worst case scenario, lengths and hashes equal) to compare bytes in array1 with bytes in array 2.

Overall, even though System.Data.Linq.Binary is built into BCL, I don't think it is the fastest way to compare two byte arrays :-|.

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 using System.Linq; //SequenceEqual

 byte[] ByteArray1 = null;
 byte[] ByteArray2 = null;

 ByteArray1 = MyFunct1();
 ByteArray2 = MyFunct2();

 if (ByteArray1.SequenceEqual<byte>(ByteArray2) == true)
 {
    MessageBox.Show("Match");
 }
 else
 {
   MessageBox.Show("Don't match");
 }
share|improve this answer
1  
That's what I've been using. But it umm... sounds like a sequential comparison you'd otherwise do using a simple loop, hence not very fast. It'd be nice to reflect it and see what's actually doing. Judging by the name, it's nothing fancy. –  Sergey Akopov Jan 6 '11 at 20:33
1  
Yes, but already mentioned in the accepted answer. btw, you could remove the type specification there. –  nawfal Jun 2 '13 at 15:19

I would use unsafe code and run the for loop comparing Int32 pointers.

maybe you should also consider checking the arrays to be non-null.

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If you look at how .Net does string.Equals, you see that it uses a private method called EqualsHelper which has an "unsafe" pointer implementation. Reflector is your friend to see how things are done internally.

This can be used as a template for byte array comparison which I did an implementation on in a blog post. I also did some rudimentary benchmarks to see when a safe implementation is faster than the unsafe.

That said, unless you really need killer performance, I'd go for a simple for loop comparison.

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For comparing short byte arrays the following is an interesting hack:

if(myByteArray1.Length != myByteArray2.Length) return false;
if(myByteArray1.Length == 8)
   return BitConverter.ToInt64(myByteArray1, 0) == BitConverter.ToInt64(myByteArray2, 0); 
else if(myByteArray.Length == 4)
   return BitConverter.ToInt32(myByteArray2, 0) == BitConverter.ToInt32(myByteArray2, 0);

Then I would probably fall out to the solution listed in the question.

It'd be interesting to do a performance analysis of this code.

share|improve this answer
    
int i=0; for(;i<a1.Length-7;i+=8) if(BitConverter.ToInt64(a1,i)!=BitConverter.ToInt64(a2,i)) return false; for(;i<a1.Length;i++) if(a1[i]!=a2[i]) return false; return true; // a little bit slower than simple for loop. –  Hafthor Dec 21 '12 at 5:49

I thought about block-transfer acceleration methods built into many graphics cards. But then you would have to copy over all the data byte-wise, so this doesn't help you much if you don't want to implement a whole portion of your logic in unmanaged and hardware-dependent code...

Another way of optimization similar to the approach shown above would be to store as much of your data as possible in a long[] rather than a byte[] right from the start, for example if you are reading it sequentially from a binary file, or if you use a memory mapped file, read in data as long[] or single long values. Then, your comparison loop will only need 1/8th of the number of iterations it would have to do for a byte[] containing the same amount of data. It is a matter of when and how often you need to compare vs. when and how often you need to access the data in a byte-by-byte manner, e.g. to use it in an API call as a parameter in a method that expects a byte[]. In the end, you only can tell if you really know the use case...

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The accepted answer recasts the byte buffer as a long buffer and compares it as you describe. –  Hafthor Dec 18 '12 at 17:18

Sorry, if you're looking for a managed way you're already doing it correctly and to my knowledge there's no built in method in the BCL for doing this.

You should add some initial null checks and then just reuse it as if it where in BCL.

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If you are looking for a very fast byte array equality comparer, I suggest you take a look at this STSdb Labs article: Byte array equality comparer. It features some of the fastest implementations for byte[] array equality comparing, which are presented, performance tested and summarized.

You can also focus on these implementations:

BigEndianByteArrayComparer - fast byte[] array comparer from left to right (BigEndian) BigEndianByteArrayEqualityComparer - - fast byte[] equality comparer from left to right (BigEndian) LittleEndianByteArrayComparer - fast byte[] array comparer from right to left (LittleEndian) LittleEndianByteArrayEqualityComparer - fast byte[] equality comparer from right to left (LittleEndian)

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In case you have a huge byte array, you can compare them by converting them to string.

You can use something like

byte[] b1 = // Your array
byte[] b2 = // Your array
string s1 = Encoding.Default.GetString( b1 );
string s2 = Encoding.Default.GetString( b2 );

I have used this and I have seen a huge performance impact.

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This may or may not work depending on your local string encoding and which code points it supports. –  LonelyPixel Mar 29 at 9:46
    
But since the byte array is the independent factor here, it should not be a problem. –  pratikv Jun 17 at 8:24
    
You didn't understand what an Encoding is. If an encoding does not support to map certain bytes to characters, they are not mapped correctly. Most of the time you get a question mark ('?') character instead. Then you have multiple bytes mapped to the same character and your comparison is wrong. With multi-byte encodings like UTF-8 you may even get exceptions for invalid byte sequences. Don't mix bytes and characters, they're essentially different things and as such not comparable. Often-quoted article, great read: joelonsoftware.com/articles/Unicode.html –  LonelyPixel Jun 17 at 12:30

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