Comparing two byte arrays in .NET

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.

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

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

• "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. Aug 9 '09 at 20:45
• return a1.Length == a2.Length && !a1.Where((t, i) => t != a2[i]).Any(); Aug 31 '12 at 12:10

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.

• But doesn't SequenceEqual take longer to process than an unsafe comparison? Especially when your doing 1000's of comparisons? Jan 20 '11 at 18:18
• Yes, this runs about 50x slower than the unsafe comparison. Feb 3 '11 at 2:53
• This is really raising the dead here, but slow is really a bad word to use here. 50x slower sounds bad, but it's not often you're comparing enough data for it to make a difference, and if you are, you really need to benchmark this for your own case, for a myriad of reasons. For example, note the creator of the unsafe answer notes a difference of 7x slow, as opposed to 50x slower (the unsafe method's speed also depends on the alignment of data). In the rare cases where these numbers matter, P/Invoke is even faster. Sep 17 '14 at 22:47
• So the slower implementation gets over 300 likes? I would suggest hooking the msvcrt.dll as that would be the fastest way to get the job done. May 14 '15 at 13:49
• Fastest is not the most important thing to a business. Maintainability is much "faster" than the savings on this code will amount to in 99% of cases. I am using SequenceEqual and my entire code is < 1ms. Those µs you are saving will never add up to the 5 minutes of lack of readability of P/Invoke. Sep 25 '15 at 23:54

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;
}
• P/Invoke yaay - this proved to be fastest by far on bitmaps at least: stackoverflow.com/questions/2031217/… Jan 10 '10 at 20:48
• Pinning is not necessary in this case. The marshaller performs automatic pinning when calling native code with PInvoke. Reference: stackoverflow.com/questions/2218444/… Mar 16 '10 at 8:55
• 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
• 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. Oct 2 '11 at 6:55
• Nitpick: MSVCR.dll is not supposed to be used by user code. To use the MSVCR, you would have to distribute the runtime use the version you distribute. (msdn.microsoft.com/en-us/library/… and blogs.msdn.com/b/oldnewthing/archive/2014/04/11/10516280.aspx) Dec 12 '14 at 4:55

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);
}
• According to this blog post that's actually very slow. Dec 17 '12 at 23:23
• Crazy slow. About 180x slower than simple for loop. Dec 21 '12 at 5:47
• Why not just StructuralComparisons.StructuralEqualityComparer.Equals(a1, a2). No NullReferenceExceptions here. Mar 24 '14 at 23:51
• @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. Mar 25 '14 at 11:39

Span<T> offers an extremely competitive alternative without having to throw confusing and/or non-portable fluff into your own application's code base:

// byte[] is implicitly convertible to ReadOnlySpan<byte>
{
return a1.SequenceEqual(a2);
}

The (guts of the) implementation as of .NET 5.0.0 can be found here.

I've revised @EliArbel's gist to add this method as SpansEqual, drop most of the less interesting performers in others' benchmarks, run it with different array sizes, output graphs, and mark SpansEqual as the baseline so that it reports how the different methods compare to SpansEqual.

The below numbers are from the results, lightly edited to remove "Error" column.

|        Method |  ByteCount |               Mean |            StdDev | Ratio | RatioSD |
|-------------- |----------- |-------------------:|------------------:|------:|--------:|
|    SpansEqual |         15 |           4.629 ns |         0.0289 ns |  1.00 |    0.00 |
|  LongPointers |         15 |           4.598 ns |         0.0416 ns |  0.99 |    0.01 |
|      Unrolled |         15 |          18.199 ns |         0.0291 ns |  3.93 |    0.02 |
| PInvokeMemcmp |         15 |           9.872 ns |         0.0441 ns |  2.13 |    0.02 |
|               |            |                    |                   |       |         |
|    SpansEqual |       1026 |          19.965 ns |         0.0880 ns |  1.00 |    0.00 |
|  LongPointers |       1026 |          63.005 ns |         0.5217 ns |  3.16 |    0.04 |
|      Unrolled |       1026 |          38.731 ns |         0.0166 ns |  1.94 |    0.01 |
| PInvokeMemcmp |       1026 |          40.355 ns |         0.0202 ns |  2.02 |    0.01 |
|               |            |                    |                   |       |         |
|    SpansEqual |    1048585 |      43,761.339 ns |        30.8744 ns |  1.00 |    0.00 |
|  LongPointers |    1048585 |      59,585.479 ns |        17.3907 ns |  1.36 |    0.00 |
|      Unrolled |    1048585 |      54,646.243 ns |        35.7638 ns |  1.25 |    0.00 |
| PInvokeMemcmp |    1048585 |      55,198.289 ns |        23.9732 ns |  1.26 |    0.00 |
|               |            |                    |                   |       |         |
|    SpansEqual | 2147483591 | 240,607,692.857 ns | 2,733,489.4894 ns |  1.00 |    0.00 |
|  LongPointers | 2147483591 | 238,223,478.571 ns | 2,033,769.5979 ns |  0.99 |    0.02 |
|      Unrolled | 2147483591 | 236,227,340.000 ns | 2,189,627.0164 ns |  0.98 |    0.00 |
| PInvokeMemcmp | 2147483591 | 238,724,660.000 ns | 3,726,140.4720 ns |  0.99 |    0.02 |

I was surprised to see SpansEqual not come out on top for the max-array-size methods, but the difference is so minor that I don't think it'll ever matter.

My system info:

BenchmarkDotNet=v0.12.1, OS=Windows 10.0.19042
Intel Core i7-6850K CPU 3.60GHz (Skylake), 1 CPU, 12 logical and 6 physical cores
.NET Core SDK=5.0.100
[Host]     : .NET Core 5.0.0 (CoreCLR 5.0.20.51904, CoreFX 5.0.20.51904), X64 RyuJIT
DefaultJob : .NET Core 5.0.0 (CoreCLR 5.0.20.51904, CoreFX 5.0.20.51904), X64 RyuJIT
• I'd never thought I will be using Span<T> or something close to it in all the stuff that I do. Thanks to you I can now brag about this to my co-workers. Feb 20 '18 at 3:14
• Is SequenceEqual especially implemented as a Span method? Thought it was just one of the IEnumerable extension methods. Apr 6 '18 at 9:26
• @Zastai yes, {ReadOnly,}Span<T> has its own version of SequenceEqual (same name because it has the same contract as the corresponding IEnumerable<T> extension method, it's just faster). Note that {ReadOnly,}Span<T> can't use IEnumerable<T> extension methods because of the restrictions on ref struct types. Apr 6 '18 at 10:33
• @Sentinel the System.Memory package has "portable" / "slow" Span<T> implementations for netstandard1.1 and above (so play with this interactive chart to see which those are). "Fast" Span<T> is only available in .NET Core 2.1, at this moment, but note that for SequenceEqual<T> specifically, there should be very little difference between "fast" and "slow" / "portable" (though netstandard2.0 targets should see a slight improvement because they have the vectorized code path). Jun 26 '18 at 10:14
• install-package system.memory Oct 16 '18 at 14:15

User gil suggested unsafe code which spawned this solution:

// Copyright (c) 2008-2013 Hafthor Stefansson
static unsafe bool UnsafeCompare(byte[] a1, byte[] a2) {
if(a1==a2) return true;
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 kind of 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 seven timers faster than the simple for loop. Using the J# library performed equivalently to the original for loop. Using .SequenceEqual runs around seven times slower; I think just because it is using IEnumerator.MoveNext. I imagine LINQ-based solutions being at least that slow or worse.

• 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. Dec 20 '12 at 13:34
• 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. Dec 21 '12 at 5:46
• 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. Jan 10 '13 at 16:28
• wouldnt this give false when both a1 and a2 are null? Apr 14 '13 at 10:26
• @CristiDiaconescu I loopified KevinDriedger's answer. What I should probably do is make the test suite and my results available on github and link to it on my answer. Jun 27 '13 at 17:06

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;
}

.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 :-|.

I posted a similar question about checking if byte[] is full of zeroes. (SIMD code was beaten so I removed it from this answer.) Here is fastest code from my comparisons:

static unsafe bool EqualBytesLongUnrolled (byte[] data1, byte[] data2)
{
if (data1 == data2)
return true;
if (data1.Length != data2.Length)
return false;

fixed (byte* bytes1 = data1, bytes2 = data2) {
int len = data1.Length;
int rem = len % (sizeof(long) * 16);
long* b1 = (long*)bytes1;
long* b2 = (long*)bytes2;
long* e1 = (long*)(bytes1 + len - rem);

while (b1 < e1) {
if (*(b1) != *(b2) || *(b1 + 1) != *(b2 + 1) ||
*(b1 + 2) != *(b2 + 2) || *(b1 + 3) != *(b2 + 3) ||
*(b1 + 4) != *(b2 + 4) || *(b1 + 5) != *(b2 + 5) ||
*(b1 + 6) != *(b2 + 6) || *(b1 + 7) != *(b2 + 7) ||
*(b1 + 8) != *(b2 + 8) || *(b1 + 9) != *(b2 + 9) ||
*(b1 + 10) != *(b2 + 10) || *(b1 + 11) != *(b2 + 11) ||
*(b1 + 12) != *(b2 + 12) || *(b1 + 13) != *(b2 + 13) ||
*(b1 + 14) != *(b2 + 14) || *(b1 + 15) != *(b2 + 15))
return false;
b1 += 16;
b2 += 16;
}

for (int i = 0; i < rem; i++)
if (data1 [len - 1 - i] != data2 [len - 1 - i])
return false;

return true;
}
}

Measured on two 256MB byte arrays:

UnsafeCompare                           : 86,8784 ms
EqualBytesSimd                          : 71,5125 ms
EqualBytesSimdUnrolled                  : 73,1917 ms
EqualBytesLongUnrolled                  : 39,8623 ms
• I confirm. I also ran the tests. This is faster than the answer that uses memcmp unsafe call. Nov 19 '15 at 17:31
• @AmberdeBlack Are you sure? Did you test with tiny arrays? Mar 31 '16 at 11:49
• @ArekBulski Are you sure this is faster than memcmp, cause my testing shows otherwise? Apr 3 '16 at 0:39
• I got virtually identical performance between this and memcmp, so +1 for a fully managed solution. Oct 26 '18 at 13:46

Recently Microsoft released a special NuGet package, System.Runtime.CompilerServices.Unsafe. It's special because it's written in IL, and provides low-level functionality not directly available in C#.

One of its methods, Unsafe.As<T>(object) allows casting any reference type to another reference type, skipping any safety checks. This is usually a very bad idea, but if both types have the same structure, it can work. So we can use this to cast a byte[] to a long[]:

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

var longSize = (int)Math.Floor(a1.Length / 8.0);
var long1 = Unsafe.As<long[]>(a1);
var long2 = Unsafe.As<long[]>(a2);

for (var i = 0; i < longSize; i++)
{
if (long1[i] != long2[i]) return false;
}

for (var i = longSize * 8; i < a1.Length; i++)
{
if (a1[i] != a2[i]) return false;
}

return true;
}

Note that long1.Length would still return the original array's length, since it's stored in a field in the array's memory structure.

This method is not quite as fast as other methods demonstrated here, but it is a lot faster than the naive method, doesn't use unsafe code or P/Invoke or pinning, and the implementation is quite straightforward (IMO). Here are some BenchmarkDotNet results from my machine:

BenchmarkDotNet=v0.10.3.0, OS=Microsoft Windows NT 6.2.9200.0
Processor=Intel(R) Core(TM) i7-4870HQ CPU 2.50GHz, ProcessorCount=8
Frequency=2435775 Hz, Resolution=410.5470 ns, Timer=TSC
[Host]     : Clr 4.0.30319.42000, 64bit RyuJIT-v4.6.1637.0
DefaultJob : Clr 4.0.30319.42000, 64bit RyuJIT-v4.6.1637.0

Method |          Mean |    StdDev |
----------------------- |-------------- |---------- |
UnsafeLibrary |   125.8229 ns | 0.3588 ns |
UnsafeCompare |    89.9036 ns | 0.8243 ns |
JSharpEquals | 1,432.1717 ns | 1.3161 ns |
EqualBytesLongUnrolled |    43.7863 ns | 0.8923 ns |
NewMemCmp |    65.4108 ns | 0.2202 ns |
ArraysEqual |   910.8372 ns | 2.6082 ns |
PInvokeMemcmp |    52.7201 ns | 0.1105 ns |

I've also created a gist with all the tests.

• It doesn't use the unsafe keyword, yet it calls unsafe code anyways by using the System.Runtime.CompilerServices.Unsafe Jul 3 '18 at 21:36
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");
}
• 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. Jan 6 '11 at 20:33
• Yes, but already mentioned in the accepted answer. btw, you could remove the type specification there. Jun 2 '13 at 15:19

I developed a method that slightly beats memcmp() (plinth's answer) and very slighly beats EqualBytesLongUnrolled() (Arek Bulski's answer) on my PC. Basically, it unrolls the loop by 4 instead of 8.

Update 30 Mar. 2019:

Starting in .NET core 3.0, we have SIMD support!

This solution is fastest by a considerable margin on my PC:

#if NETCOREAPP3_0
using System.Runtime.Intrinsics.X86;
#endif
…

public static unsafe bool Compare(byte[] arr0, byte[] arr1)
{
if (arr0 == arr1)
{
return true;
}
if (arr0 == null || arr1 == null)
{
return false;
}
if (arr0.Length != arr1.Length)
{
return false;
}
if (arr0.Length == 0)
{
return true;
}
fixed (byte* b0 = arr0, b1 = arr1)
{
#if NETCOREAPP3_0
if (Avx2.IsSupported)
{
return Compare256(b0, b1, arr0.Length);
}
else if (Sse2.IsSupported)
{
return Compare128(b0, b1, arr0.Length);
}
else
#endif
{
return Compare64(b0, b1, arr0.Length);
}
}
}
#if NETCOREAPP3_0
public static unsafe bool Compare256(byte* b0, byte* b1, int length)
{
byte* lastAddr = b0 + length;
while (b0 < lastAddrMinus128) // unroll the loop so that we are comparing 128 bytes at a time.
{
{
return false;
}
{
return false;
}
{
return false;
}
{
return false;
}
b0 += 128;
b1 += 128;
}
{
if (*b0 != *b1) return false;
b0++;
b1++;
}
return true;
}
public static unsafe bool Compare128(byte* b0, byte* b1, int length)
{
byte* lastAddr = b0 + length;
while (b0 < lastAddrMinus64) // unroll the loop so that we are comparing 64 bytes at a time.
{
{
return false;
}
{
return false;
}
{
return false;
}
{
return false;
}
b0 += 64;
b1 += 64;
}
{
if (*b0 != *b1) return false;
b0++;
b1++;
}
return true;
}
#endif
public static unsafe bool Compare64(byte* b0, byte* b1, int length)
{
byte* lastAddr = b0 + length;
while (b0 < lastAddrMinus32) // unroll the loop so that we are comparing 32 bytes at a time.
{
if (*(ulong*)b0 != *(ulong*)b1) return false;
if (*(ulong*)(b0 + 8) != *(ulong*)(b1 + 8)) return false;
if (*(ulong*)(b0 + 16) != *(ulong*)(b1 + 16)) return false;
if (*(ulong*)(b0 + 24) != *(ulong*)(b1 + 24)) return false;
b0 += 32;
b1 += 32;
}
{
if (*b0 != *b1) return false;
b0++;
b1++;
}
return true;
}
• My measurements differs for .NET 462 can the NETCORE: Sep 26 '16 at 10:55
• The code crashes when comparing two 0-length arrays, because pinning returns null. Apr 17 '17 at 12:53
• memcmp is not just an equity comparer. It provides infomation which object is bigger or smaller. Can you adopt your algorithm for this purpose and check the performance? Jan 24 '18 at 11:48
• Is it faster than Span and memcpy? Mar 9 '20 at 15:20
• @silkfire On .NET core 3 and modern CPU, it should be 2-3 times faster for large arrays. Mar 9 '20 at 15:44

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.

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. .NET 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 blog post Fast byte array comparison in C#. 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 fr loop comparison.

I did some measurements using attached program .net 4.7 release build without the debugger attached. I think people have been using the wrong metric since what you are about if you care about speed here is how long it takes to figure out if two byte arrays are equal. i.e. throughput in bytes.

StructuralComparison :              4.6 MiB/s
for                  :            274.5 MiB/s
ToUInt32             :            263.6 MiB/s
ToUInt64             :            474.9 MiB/s
memcmp               :           8500.8 MiB/s

As you can see, there's no better way than memcmp and it's orders of magnitude faster. A simple for loop is the second best option. And it still boggles my mind why Microsoft cannot simply include a Buffer.Compare method.

[Program.cs]:

using System;
using System.Collections;
using System.Collections.Generic;
using System.Diagnostics;
using System.Linq;
using System.Runtime.InteropServices;
using System.Text;

namespace memcmp
{
class Program
{
static byte[] TestVector(int size)
{
var data = new byte[size];
using (var rng = new System.Security.Cryptography.RNGCryptoServiceProvider())
{
rng.GetBytes(data);
}
return data;
}

static TimeSpan Measure(string testCase, TimeSpan offset, Action action, bool ignore = false)
{
var t = Stopwatch.StartNew();
var n = 0L;
while (t.Elapsed < TimeSpan.FromSeconds(10))
{
action();
n++;
}
var elapsed = t.Elapsed - offset;
if (!ignore)
{
Console.WriteLine(\$"{testCase,-16} : {n / elapsed.TotalSeconds,16:0.0} MiB/s");
}
return elapsed;
}

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

static void Main(string[] args)
{
// how quickly can we establish if two sequences of bytes are equal?

// note that we are testing the speed of different comparsion methods

var a = TestVector(1024 * 1024); // 1 MiB
var b = (byte[])a.Clone();

// was meant to offset the overhead of everything but copying but my attempt was a horrible mistake... should have reacted sooner due to the initially ridiculous throughput values...
// Measure("offset", new TimeSpan(), () => { return; }, ignore: true);
var offset = TimeZone.Zero

Measure("StructuralComparison", offset, () =>
{
StructuralComparisons.StructuralEqualityComparer.Equals(a, b);
});

Measure("for", offset, () =>
{
for (int i = 0; i < a.Length; i++)
{
if (a[i] != b[i]) break;
}
});

Measure("ToUInt32", offset, () =>
{
for (int i = 0; i < a.Length; i += 4)
{
if (BitConverter.ToUInt32(a, i) != BitConverter.ToUInt32(b, i)) break;
}
});

Measure("ToUInt64", offset, () =>
{
for (int i = 0; i < a.Length; i += 8)
{
if (BitConverter.ToUInt64(a, i) != BitConverter.ToUInt64(b, i)) break;
}
});

Measure("memcmp", offset, () =>
{
memcmp(a, b, a.Length);
});
}
}
}
• is the memcmp call dependent on msvc something tied to Visual C++ or can it use clang too ? May 15 '21 at 9:16
• You can import almost any function as long as there's some metadata to bind to it. The reason I use msvcrt is that it ships with the CLR. But there's nothing special about it. You can DllImport anything. Just make sure the marshalling and calling conventions match. May 17 '21 at 11:01

For those of you that care about order (i.e. want your memcmp to return an int like it should instead of nothing), .NET Core 3.0 (and presumably .NET Standard 2.1 aka .NET 5.0) will include a Span.SequenceCompareTo(...) extension method (plus a Span.SequenceEqualTo) that can be used to compare two ReadOnlySpan<T> instances (where T: IComparable<T>).

In the original GitHub proposal, the discussion included approach comparisons with jump table calculations, reading a byte[] as long[], SIMD usage, and p/invoke to the CLR implementation's memcmp.

Going forward, this should be your go-to method for comparing byte arrays or byte ranges (as should using Span<byte> instead of byte[] for your .NET Standard 2.1 APIs), and it is sufficiently fast enough that you should no longer care about optimizing it (and no, despite the similarities in name it does not perform as abysmally as the horrid Enumerable.SequenceEqual).

#if NETCOREAPP3_0_OR_GREATER
// Using the platform-native Span<T>.SequenceEqual<T>(..)
public static int Compare(byte[] range1, int offset1, byte[] range2, int offset2, int count)
{
var span1 = range1.AsSpan(offset1, count);
var span2 = range2.AsSpan(offset2, count);

return span1.SequenceCompareTo(span2);
// or, if you don't care about ordering
// return span1.SequenceEqual(span2);
}
#else
// The most basic implementation, in platform-agnostic, safe C#
public static bool Compare(byte[] range1, int offset1, byte[] range2, int offset2, int count)
{
// Working backwards lets the compiler optimize away bound checking after the first loop
for (int i = count - 1; i >= 0; --i)
{
if (range1[offset1 + i] != range2[offset2 + i])
{
return false;
}
}

return true;
}
#endif

Couldn't find a solution I'm completely happy with (reasonable performance, but no unsafe code/pinvoke) so I came up with this, nothing really original, but works:

/// <summary>
///
/// </summary>
/// <param name="array1"></param>
/// <param name="array2"></param>
/// <param name="bytesToCompare"> 0 means compare entire arrays</param>
/// <returns></returns>
public static bool ArraysEqual(byte[] array1, byte[] array2, int bytesToCompare = 0)
{
if (array1.Length != array2.Length) return false;

var length = (bytesToCompare == 0) ? array1.Length : bytesToCompare;
var tailIdx = length - length % sizeof(Int64);

//check in 8 byte chunks
for (var i = 0; i < tailIdx; i += sizeof(Int64))
{
if (BitConverter.ToInt64(array1, i) != BitConverter.ToInt64(array2, i)) return false;
}

//check the remainder of the array, always shorter than 8 bytes
for (var i = tailIdx; i < length; i++)
{
if (array1[i] != array2[i]) return false;
}

return true;
}

Simple Loop: 19837 ticks, 1.00

*BitConverter: 4886 ticks, 4.06

UnsafeCompare: 1636 ticks, 12.12

EqualBytesLongUnrolled: 637 ticks, 31.09

P/Invoke memcmp: 369 ticks, 53.67

Tested in linqpad, 1000000 bytes identical arrays (worst case scenario), 500 iterations each.

• yeah, I noted that in the comment of stackoverflow.com/a/1445280/4489 that my testing shows this is actually a little bit slower than the simple for loop I had in the original question. Mar 30 '16 at 23:25
• are you sure? In my testing it is 4 times faster? Nothing beats good old native code though, even with marshaling overhead. Mar 31 '16 at 11:43

It seems that EqualBytesLongUnrolled is the best from the above suggested.

Skipped methods (Enumerable.SequenceEqual,StructuralComparisons.StructuralEqualityComparer.Equals), were not-patient-for-slow. On 265MB arrays I have measured this:

Host Process Environment Information:
BenchmarkDotNet.Core=v0.9.9.0
OS=Microsoft Windows NT 6.2.9200.0
Processor=Intel(R) Core(TM) i7-3770 CPU 3.40GHz, ProcessorCount=8
Frequency=3323582 ticks, Resolution=300.8802 ns, Timer=TSC
CLR=MS.NET 4.0.30319.42000, Arch=64-bit RELEASE [RyuJIT]
GC=Concurrent Workstation
JitModules=clrjit-v4.6.1590.0

Type=CompareMemoriesBenchmarks  Mode=Throughput

Method |      Median |    StdDev | Scaled | Scaled-SD |
----------------------- |------------ |---------- |------- |---------- |
NewMemCopy |  30.0443 ms | 1.1880 ms |   1.00 |      0.00 |
EqualBytesLongUnrolled |  29.9917 ms | 0.7480 ms |   0.99 |      0.04 |
msvcrt_memcmp |  30.0930 ms | 0.2964 ms |   1.00 |      0.03 |
UnsafeCompare |  31.0520 ms | 0.7072 ms |   1.03 |      0.04 |
ByteArrayCompare | 212.9980 ms | 2.0776 ms |   7.06 |      0.25 |

OS=Windows
Processor=?, ProcessorCount=8
Frequency=3323582 ticks, Resolution=300.8802 ns, Timer=TSC
CLR=CORE, Arch=64-bit ? [RyuJIT]
GC=Concurrent Workstation
dotnet cli version: 1.0.0-preview2-003131

Type=CompareMemoriesBenchmarks  Mode=Throughput

Method |      Median |    StdDev | Scaled | Scaled-SD |
----------------------- |------------ |---------- |------- |---------- |
NewMemCopy |  30.1789 ms | 0.0437 ms |   1.00 |      0.00 |
EqualBytesLongUnrolled |  30.1985 ms | 0.1782 ms |   1.00 |      0.01 |
msvcrt_memcmp |  30.1084 ms | 0.0660 ms |   1.00 |      0.00 |
UnsafeCompare |  31.1845 ms | 0.4051 ms |   1.03 |      0.01 |
ByteArrayCompare | 212.0213 ms | 0.1694 ms |   7.03 |      0.01 |

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.

• 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. Dec 21 '12 at 5:49

I have not seen many linq solutions here.

I am not sure of the performance implications, however I generally stick to linq as rule of thumb and then optimize later if necessary.

public bool CompareTwoArrays(byte[] array1, byte[] array2)
{
return !array1.Where((t, i) => t != array2[i]).Any();
}

Please do note this only works if they are the same size arrays. an extension could look like so

public bool CompareTwoArrays(byte[] array1, byte[] array2)
{
if (array1.Length != array2.Length) return false;
return !array1.Where((t, i) => t != array2[i]).Any();
}
• The whole point of the question is a faster solution that the function posted in the question. Feb 3 '18 at 15:57

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...

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

I settled on a solution inspired by the EqualBytesLongUnrolled method posted by ArekBulski with an additional optimization. In my instance, array differences in arrays tend to be near the tail of the arrays. In testing, I found that when this is the case for large arrays, being able to compare array elements in reverse order gives this solution a huge performance gain over the memcmp based solution. Here is that solution:

public enum CompareDirection { Forward, Backward }

private static unsafe bool UnsafeEquals(byte[] a, byte[] b, CompareDirection direction = CompareDirection.Forward)
{
// returns when a and b are same array or both null
if (a == b) return true;

// if either is null or different lengths, can't be equal
if (a == null || b == null || a.Length != b.Length)
return false;

const int UNROLLED = 16;                // count of longs 'unrolled' in optimization
int size = sizeof(long) * UNROLLED;     // 128 bytes (min size for 'unrolled' optimization)
int len = a.Length;
int n = len / size;         // count of full 128 byte segments
int r = len % size;         // count of remaining 'unoptimized' bytes

// pin the arrays and access them via pointers
fixed (byte* pb_a = a, pb_b = b)
{
if (r > 0 && direction == CompareDirection.Backward)
{
byte* pa = pb_a + len - 1;
byte* pb = pb_b + len - 1;
byte* phead = pb_a + len - r;
{
if (*pa != *pb) return false;
pa--;
pb--;
}
}

if (n > 0)
{
int nOffset = n * size;
if (direction == CompareDirection.Forward)
{
long* pa = (long*)pb_a;
long* pb = (long*)pb_b;
long* ptail = (long*)(pb_a + nOffset);
while (pa < ptail)
{
if (*(pa + 0) != *(pb + 0) || *(pa + 1) != *(pb + 1) ||
*(pa + 2) != *(pb + 2) || *(pa + 3) != *(pb + 3) ||
*(pa + 4) != *(pb + 4) || *(pa + 5) != *(pb + 5) ||
*(pa + 6) != *(pb + 6) || *(pa + 7) != *(pb + 7) ||
*(pa + 8) != *(pb + 8) || *(pa + 9) != *(pb + 9) ||
*(pa + 10) != *(pb + 10) || *(pa + 11) != *(pb + 11) ||
*(pa + 12) != *(pb + 12) || *(pa + 13) != *(pb + 13) ||
*(pa + 14) != *(pb + 14) || *(pa + 15) != *(pb + 15)
)
{
return false;
}
pa += UNROLLED;
pb += UNROLLED;
}
}
else
{
long* pa = (long*)(pb_a + nOffset);
long* pb = (long*)(pb_b + nOffset);
{
if (*(pa - 1) != *(pb - 1) || *(pa - 2) != *(pb - 2) ||
*(pa - 3) != *(pb - 3) || *(pa - 4) != *(pb - 4) ||
*(pa - 5) != *(pb - 5) || *(pa - 6) != *(pb - 6) ||
*(pa - 7) != *(pb - 7) || *(pa - 8) != *(pb - 8) ||
*(pa - 9) != *(pb - 9) || *(pa - 10) != *(pb - 10) ||
*(pa - 11) != *(pb - 11) || *(pa - 12) != *(pb - 12) ||
*(pa - 13) != *(pb - 13) || *(pa - 14) != *(pb - 14) ||
*(pa - 15) != *(pb - 15) || *(pa - 16) != *(pb - 16)
)
{
return false;
}
pa -= UNROLLED;
pb -= UNROLLED;
}
}
}

if (r > 0 && direction == CompareDirection.Forward)
{
byte* pa = pb_a + len - r;
byte* pb = pb_b + len - r;
byte* ptail = pb_a + len;
while(pa < ptail)
{
if (*pa != *pb) return false;
pa++;
pb++;
}
}
}

return true;
}

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.

• You were right when you wrote that, however in 2010 (.NET 4.0) a BCL method came, see Ohad Schneider's answer. At the time of the question, .NET 3.5 had Linq (see aku's answer). Jul 13 '16 at 9:04

This is almost certainly much slower than any other version given here, but it was fun to write.

static bool ByteArrayEquals(byte[] a1, byte[] a2)
{
return a1.Zip(a2, (l, r) => l == r).All(x => x);
}

This is similar to others, but the difference here is that there is no falling through to the next highest number of bytes I can check at once, e.g. if I have 63 bytes (in my SIMD example) I can check the equality of the first 32 bytes, and then the last 32 bytes, which is faster than checking 32 bytes, 16 bytes, 8 bytes, and so on. The first check you enter is the only check you will need to compare all of the bytes.

This does come out on top in my tests, but just by a hair.

The following code is exactly how I tested it in airbreather/ArrayComparePerf.cs.

public unsafe bool SIMDNoFallThrough()    #requires  System.Runtime.Intrinsics.X86
{
if (a1 == null || a2 == null)
return false;

int length0 = a1.Length;

if (length0 != a2.Length) return false;

fixed (byte* b00 = a1, b01 = a2)
{
byte* b0 = b00, b1 = b01, last0 = b0 + length0, last1 = b1 + length0, last32 = last0 - 31;

if (length0 > 31)
{
while (b0 < last32)
{
return false;
b0 += 32;
b1 += 32;
}
}

if (length0 > 15)
{
return false;
}

if (length0 > 7)
{
if (*(ulong*)b0 != *(ulong*)b1)
return false;
return *(ulong*)(last0 - 8) == *(ulong*)(last1 - 8);
}

if (length0 > 3)
{
if (*(uint*)b0 != *(uint*)b1)
return false;
return *(uint*)(last0 - 4) == *(uint*)(last1 - 4);
}

if (length0 > 1)
{
if (*(ushort*)b0 != *(ushort*)b1)
return false;
return *(ushort*)(last0 - 2) == *(ushort*)(last1 - 2);
}

return *b0 == *b1;
}
}

If no SIMD is preferred, the same method applied to the the existing LongPointers algorithm:

public unsafe bool LongPointersNoFallThrough()
{
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;
if ((l & 8) != 0)
{
for (int i = 0; i < l / 8; i++, x1 += 8, x2 += 8)
if (*(long*)x1 != *(long*)x2) return false;
return *(long*)(x1 + (l - 8)) == *(long*)(x2 + (l - 8));
}
if ((l & 4) != 0)
{
if (*(int*)x1 != *(int*)x2) return false; x1 += 4; x2 += 4;
return *(int*)(x1 + (l - 4)) == *(int*)(x2 + (l - 4));
}
if ((l & 2) != 0)
{
if (*(short*)x1 != *(short*)x2) return false; x1 += 2; x2 += 2;
return *(short*)(x1 + (l - 2)) == *(short*)(x2 + (l - 2));
}
return *x1 == *x2;
}
}

Use SequenceEquals for this to comparison.

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)

public bool Compare(byte[] b1, byte[] b2)
{
return Encoding.ASCII.GetString(b1) == Encoding.ASCII.GetString(b2);
}

In such a way you can use the optimized .NET string compare to make a byte array compare without the need to write unsafe code. This is how it is done in the background:

private unsafe static bool EqualsHelper(String strA, String strB)
{
Contract.Requires(strA != null);
Contract.Requires(strB != null);
Contract.Requires(strA.Length == strB.Length);

int length = strA.Length;

fixed (char* ap = &strA.m_firstChar) fixed (char* bp = &strB.m_firstChar)
{
char* a = ap;
char* b = bp;

// Unroll the loop

#if AMD64
// For the AMD64 bit platform we unroll by 12 and
// check three qwords at a time. This is less code
// than the 32 bit case and is shorter
// pathlength.

while (length >= 12)
{
if (*(long*)a     != *(long*)b)     return false;
if (*(long*)(a+4) != *(long*)(b+4)) return false;
if (*(long*)(a+8) != *(long*)(b+8)) return false;
a += 12; b += 12; length -= 12;
}
#else
while (length >= 10)
{
if (*(int*)a != *(int*)b) return false;
if (*(int*)(a+2) != *(int*)(b+2)) return false;
if (*(int*)(a+4) != *(int*)(b+4)) return false;
if (*(int*)(a+6) != *(int*)(b+6)) return false;
if (*(int*)(a+8) != *(int*)(b+8)) return false;
a += 10; b += 10; length -= 10;
}
#endif

// This depends on the fact that the String objects are
// always zero terminated and that the terminating zero is not included
// in the length. For odd string sizes, the last compare will include
// the zero terminator.
while (length > 0)
{
if (*(int*)a != *(int*)b) break;
a += 2; b += 2; length -= 2;
}

return (length <= 0);
}
}
• In my tests, the conversion to a string destroys the advantage of the faster compare. This was about 2.5 times slower than a simple for loop. Jul 15 '15 at 15:06
• When i did the same the simple for was about 8 times slower. Can you write your code here?
– Alon
Jul 16 '15 at 15:55
• Will this break if a byte contains a null (0) value? Sep 22 '15 at 16:52
• -1 As well as being slow because of the conversion to string as pointed out by @DougClutter, this will fail if the byte array contains non-ASCII data. To get the right result it would need to use iso-8859-1.
– Joe
Jan 19 '17 at 10:33
• Compare(new byte[]{128}, new byte[]{ 255 }) == true not buggy at all... Feb 3 '18 at 15:57

Since many of the fancy solutions above don't work with UWP and because I love Linq and functional approaches I pressent you my version to this problem. To escape the comparison when the first difference occures, I chose .FirstOrDefault()

public static bool CompareByteArrays(byte[] ba0, byte[] ba1) =>
!(ba0.Length != ba1.Length || Enumerable.Range(1,ba0.Length)
.FirstOrDefault(n => ba0[n] != ba1[n]) > 0);
• -1 because this code is broken and apparently untested. This throws an IndexOutOfRangeException when comparing non-empty arrays because you're accessing elements 1 through ba0.Length when it should be 0 through ba0.Length - 1. If you fix that with Enumerable.Range(0, ba0.Length) it still incorrectly returns true for arrays of equal length where only the first elements differ because you can't distinguish between the first elements satisfying predicate and no elements satisfying predicate; FirstOrDefault<int>() returns 0 in both cases. Apr 27 '18 at 0:19
• The lesson here kids: don't bring a knife to a gun fight Mar 8 '19 at 14:04