Array.Copy and Buffer.BlockCopy both do the same thing, but BlockCopy is aimed at fast byte-level primitive array copying, whereas Copy is the general-purpose implementation. My question is - under what circumstances should you use BlockCopy? Should you use it at any time when you are copying primitive type arrays, or should you only use it if you're coding for performance? Is there anything inherently dangerous about using Buffer.BlockCopy over Array.Copy?

  • 2
    Don't forget Marshal.Copy :-) . Well, use Array.Copy for reference types, complex value types and if the type doesn't change, Buffer.BlockCopy for "conversion" between value types, byte arrays and byte magic. F.ex. the combination with StructLayout is quite powerful if you know what you're doing. As for performance, it seems an unmanaged call to memcpy/cpblk is the fastest for that - see code4k.blogspot.nl/2010/10/… . – atlaste Dec 13 '13 at 15:54
  • I did some benchmark tests with byte[]. There was no difference in Release version. Sometimes Array.Copy, sometimes Buffer.BlockCopy (slightly) faster. – Bitterblue Jul 15 '14 at 11:31
  • New comprehensive answer just posted below. Note that in cases with small buffer sizes, explicit loop copying is usually best. – Special Sauce Nov 23 '15 at 7:31
  • I don't think they do always do the same thing - you can't use Array.Copy to copy an array of Ints to an array of Bytes for instance – mcmillab Sep 4 '16 at 23:45
  • Array.Copy is rather a specialized version -- for example it can copy only the same rank arrays. – astrowalker Oct 11 at 10:56
up vote 47 down vote accepted

Since the parameters to Buffer.BlockCopy are byte-based rather than index-based, you're more likely to screw up your code than if you use Array.Copy, so I would only use Buffer.BlockCopy in a performance-critical section of my code.

  • 6
    Completely agree. There's too much room for error with Buffer.BlockCopy. Keep it simple, and don't try to squeeze any juice out of your program until you know where the juice is (profiling). – Stephen Sep 7 '09 at 19:36
  • 3
    What if you're dealing with a byte[]? Are there any other gotchas with BlockCopy? – thecoop Sep 9 '09 at 9:52
  • 4
    @thecoop: if you're dealing with a byte[] then it's probably fine to use BlockCopy, unless the definition of "byte" is later changed to something other than a byte, which would probably have a pretty negative effect on other parts of your code anyway. :) The only other potential gotcha is that BlockCopy just does straight bytes, so it doesn't take endianness into account, but this would only come into play on a non-Windows machine, and only if you'd screwed up the code in the first place. Also, there might be some weird difference if you're using mono. – MusiGenesis Sep 9 '09 at 13:46
  • 5
    In my own testing, Array.Copy() is very similar in performance to Buffer.BlockCopy(). Buffer.BlockCopy is consistently < 10% faster for me when dealing with 640 element byte arrays (which is the sort I'm most interested in). But you should do your own testing with your own data, because it'll presumably vary depending on the data, data types, array sizes, and so forth. I should note that both methods are roughly 3x faster than using Array.Clone(), and maybe 20x faster than copying it in a for loop. – Ken Smith Sep 20 '11 at 22:12
  • 2
    @KevinMiller: uh, UInt16 is two bytes per element. If you pass this array to BlockCopy along with the number of elements in the array, of course only half the array will be copied. For this to work properly, you would need to pass the number of elements times the size of each element (2) as the length parameter. msdn.microsoft.com/en-us/library/… and search for INT_SIZE in the examples. – MusiGenesis Aug 7 '16 at 18:45

Prelude

I'm joining the party late, but with 32k views, it's worth getting this right. Most of the microbenchmarking code in the posted answers thus far suffer from one or more severe technical flaws, including not moving memory allocations out of the test loops (which introduces severe GC artifacts), not testing variable vs. deterministic execution flows, JIT warmup, and not tracking intra-test variability. In addition, most answers did not test the effects of varying buffer sizes and varying primitive types (with respect to either 32-bit or 64-bit systems). To address this question more comprehensively, I hooked it up to a custom microbenchmarking framework I developed that reduces most of the common "gotchas" to the extent possible. Tests were run in .NET 4.0 Release mode on both a 32-bit machine and a 64-bit machine. Results were averaged over 20 testing runs, in which each run had 1 million trials per method. Primitive types tested were byte (1 byte), int (4 bytes), and double (8 bytes). Three methods were tested: Array.Copy(), Buffer.BlockCopy(), and simple per-index assignment in a loop. The data is too voluminous to post here, so I will summarize the important points.

The Takeaways

  • If your buffer length is about 75-100 or less, an explicit loop copy routine is usually faster (by about 5%) than either Array.Copy() or Buffer.BlockCopy() for all 3 primitive types tested on both 32-bit and 64-bit machines. Additionly, the explicit loop copy routine has noticeably lower variability in performance compared to the two alternatives. The good performance is almost surely due to locality of reference exploited by CPU L1/L2/L3 memory caching in conjunction with no method call overhead.
    • For double buffers on 32-bit machines only: The explicit loop copy routine is better than both alternatives for all buffer sizes tested up to 100k. The improvement is 3-5% better than the other methods. This is because the performance of Array.Copy() and Buffer.BlockCopy() become totally degraded upon passing the native 32-bit width. Thus I assume the same effect would apply to long buffers as well.
  • For buffer sizes exceeding ~100, explicit loop copying quickly becomes much slower than the other 2 methods (with the one particular exception just noted). The difference is most noticeable with byte[], where explicit loop copying can become 7x or more slower at large buffer sizes.
  • In general, for all 3 primitive types tested and across all buffer sizes, Array.Copy() and Buffer.BlockCopy() performed almost identically. On average, Array.Copy() seems to have a very slight edge of about 2% or less time taken (but 0.2% - 0.5% better is typical), although Buffer.BlockCopy() did occasionally beat it. For unknown reasons, Buffer.BlockCopy() has noticeably higher intra-test variability than Array.Copy(). This effect could not be eliminated despite me trying multiple mitigations and not having an operable theory on why.
  • Because Array.Copy() is a "smarter", more general, and much safer method, in addition to being very slightly faster and having less variability on average, it should be preferred to Buffer.BlockCopy() in almost all common cases. The only use case where Buffer.BlockCopy() will be significantly better is when the source and destination array value types are different (as pointed out in Ken Smith's answer). While this scenario is not common, Array.Copy() can perform very poorly here due to the continual "safe" value type casting, compared to the direct casting of Buffer.BlockCopy().
  • Additional evidence from outside StackOverflow that Array.Copy() is faster than Buffer.BlockCopy() for same-type array copying can be found here.
  • As an aside, it also turns out that around an array length of 100 is when .NET's Array.Clear() first begins to beat an explicit loop assignment clearing of an array (setting to false, 0, or null). This is consistent with my similar findings above. These separate benchmarks were discovered online here: manski.net/2012/12/net-array-clear-vs-arrayx-0-performance – Special Sauce Dec 7 '15 at 22:20
  • When you say buffer size; do you mean in bytes, or element count? – dmarra Jul 8 '16 at 18:53
  • In my above answer, both "buffer length" and "buffer size" generally refer to element count. – Special Sauce Nov 16 '16 at 7:27

Another example of when it makes sense to use Buffer.BlockCopy() is when you're provided with an array of primitives (say, shorts), and need to convert it to an array of bytes (say, for transmission over a network). I use this method frequently when dealing with audio from the Silverlight AudioSink. It provides the sample as a short[] array, but you need to convert it to a byte[] array when you're building the packet that you submit to Socket.SendAsync(). You could use BitConverter, and iterate through the array one-by-one, but it's a lot faster (about 20x in my testing) just to do this:

Buffer.BlockCopy(shortSamples, 0, packetBytes, 0, shortSamples.Length * sizeof(short)).  

And the same trick works in reverse as well:

Buffer.BlockCopy(packetBytes, readPosition, shortSamples, 0, payloadLength);

This is about as close as you get in safe C# to the (void *) sort of memory management that's so common in C and C++.

  • 3
    That's a cool idea - do you ever run into issues with endianness? – Phillip Nov 10 '11 at 21:44
  • Yeah, I think that you could run into that problem, depending on your scenario. My own scenarios have typically been either (a) I need to switch back-and-forth between byte arrays and short arrays on the same machine, or (b) I happen to know that I'm sending my data to machines of the same endianness, and which I control the remote side. But if you were using a protocol for which the remote machine expected data to be sent in network order rather than host order, yeah, this approach would give you problems. – Ken Smith Nov 11 '11 at 0:37
  • Ken also has an article about BlockCopy on his blog: blog.wouldbetheologian.com/2011/11/… – Drew Noakes Feb 27 '15 at 22:05

Based on my testing, performance is not a reason to prefer Buffer.BlockCopy over Array.Copy. From my testing Array.Copy is actually faster than Buffer.BlockCopy.

var buffer = File.ReadAllBytes(...);

var length = buffer.Length;
var copy = new byte[length];

var stopwatch = new Stopwatch();

TimeSpan blockCopyTotal = TimeSpan.Zero, arrayCopyTotal = TimeSpan.Zero;

const int times = 20;

for (int i = 0; i < times; ++i)
{
    stopwatch.Start();
    Buffer.BlockCopy(buffer, 0, copy, 0, length);
    stopwatch.Stop();

    blockCopyTotal += stopwatch.Elapsed;

    stopwatch.Reset();

    stopwatch.Start();
    Array.Copy(buffer, 0, copy, 0, length);
    stopwatch.Stop();

    arrayCopyTotal += stopwatch.Elapsed;

    stopwatch.Reset();
}

Console.WriteLine("bufferLength: {0}", length);
Console.WriteLine("BlockCopy: {0}", blockCopyTotal);
Console.WriteLine("ArrayCopy: {0}", arrayCopyTotal);
Console.WriteLine("BlockCopy (average): {0}", TimeSpan.FromMilliseconds(blockCopyTotal.TotalMilliseconds / times));
Console.WriteLine("ArrayCopy (average): {0}", TimeSpan.FromMilliseconds(arrayCopyTotal.TotalMilliseconds / times));

Example Output:

bufferLength: 396011520
BlockCopy: 00:00:02.0441855
ArrayCopy: 00:00:01.8876299
BlockCopy (average): 00:00:00.1020000
ArrayCopy (average): 00:00:00.0940000
  • 1
    Sorry about this answer being more of a comment, but it was too long for a comment. Since the consensus seemed to be that Buffer.BlockCopy was better for performace, I thought everyone should be aware that I was not able to confirm that consensus with testing. – Kevin Aug 15 '11 at 19:22
  • 7
    I think there's a problem with your testing methodology. Most of the time difference you're noting is the result of the application spinning up, caching itself, running the JIT, that sort of thing. Try it with a smaller buffer, but a few thousand times; and then repeat the whole test within a loop half a dozen times, and only pay attention to the last run. My own testing has Buffer.BlockCopy() running maybe 5% faster than Array.Copy() for 640 byte arrays. Not much faster, but a little. – Ken Smith Sep 20 '11 at 22:14
  • 2
    I measured the same for a specific problem, I could see no performance difference between Array.Copy() and Buffer.BlockCopy(). If anything, BlockCopy introduced unsafey which actually killed my app in one instance. – gatopeich May 30 '12 at 15:36
  • 1
    Just like to add Array.Copy supports long for the source position so breaking into big byte arrays it won't throw an out of range exception. – Alxwest Sep 26 '12 at 20:37
  • 2
    Based on the test's I've just made (bitbucket.org/breki74/tutis/commits/…) I would say there's no practical performance difference between the two methods when you're dealing with byte arrays. – Igor Brejc Mar 22 '14 at 21:33

ArrayCopy is smarter than BlockCopy. It figures out how to copy elements if the source and destination are the same array.

If we populate an int array with 0,1,2,3,4 and apply:

Array.Copy(array, 0, array, 1, array.Length - 1);

we end up with 0,0,1,2,3 as expected.

Try this with BlockCopy and we get: 0,0,2,3,4. If I assign array[0]=-1 after that, it becomes -1,0,2,3,4 as expected, but if the array length is even, like 6, we get -1,256,2,3,4,5. Dangerous stuff. Don't use BlockCopy other than for copying one byte array into another.

There is another case where you can only use Array.Copy: if the array size is longer than 2^31. Array.Copy has an overload with a long size parameter. BlockCopy does not have that.

  • 2
    The results of your tests with BlockCopy are not unexpected. It's because Block copy tries to copy chunks of data at a time rather than one byte at a time. On a 32 bit system it copies 4 bytes at a time, on a 64 bit system it copies 8 bytes at a time. – Pharap May 20 '15 at 11:10
  • So expected undefined behavior. – binki Dec 7 '15 at 0:07

To weigh in on this argument, if one is not careful how they author this benchmark they could be easily misled. I wrote a very simple test to illustrate this. In my test below if I swap the order of my tests between starting Buffer.BlockCopy first or Array.Copy the one that goes first is almost always the slowest (although its a close one). This means for a bunch of reasons which I wont go into simply running the tests multiple times esp one after the other will not give accurate results.

I resorted to maintaining the test as is with 1000000 tries each for an array of 1000000 sequential doubles. However in I then disregard the first 900000 cycles and average the remainder. In that case the Buffer is superior.

private static void BenchmarkArrayCopies()
        {
            long[] bufferRes = new long[1000000];
            long[] arrayCopyRes = new long[1000000];
            long[] manualCopyRes = new long[1000000];

            double[] src = Enumerable.Range(0, 1000000).Select(x => (double)x).ToArray();

            for (int i = 0; i < 1000000; i++)
            {
                bufferRes[i] = ArrayCopyTests.ArrayBufferBlockCopy(src).Ticks;
            }

            for (int i = 0; i < 1000000; i++)
            {
                arrayCopyRes[i] = ArrayCopyTests.ArrayCopy(src).Ticks;
            }

            for (int i = 0; i < 1000000; i++)
            {
                manualCopyRes[i] = ArrayCopyTests.ArrayManualCopy(src).Ticks;
            }

            Console.WriteLine("Loop Copy: {0}", manualCopyRes.Average());
            Console.WriteLine("Array.Copy Copy: {0}", arrayCopyRes.Average());
            Console.WriteLine("Buffer.BlockCopy Copy: {0}", bufferRes.Average());

            //more accurate results - average last 1000

            Console.WriteLine();
            Console.WriteLine("----More accurate comparisons----");

            Console.WriteLine("Loop Copy: {0}", manualCopyRes.Where((l, i) => i > 900000).ToList().Average());
            Console.WriteLine("Array.Copy Copy: {0}", arrayCopyRes.Where((l, i) => i > 900000).ToList().Average());
            Console.WriteLine("Buffer.BlockCopy Copy: {0}", bufferRes.Where((l, i) => i > 900000).ToList().Average());
            Console.ReadLine();
        }

public class ArrayCopyTests
    {
        private const int byteSize = sizeof(double);

        public static TimeSpan ArrayBufferBlockCopy(double[] original)
        {
            Stopwatch watch = new Stopwatch();
            double[] copy = new double[original.Length];
            watch.Start();
            Buffer.BlockCopy(original, 0 * byteSize, copy, 0 * byteSize, original.Length * byteSize);
            watch.Stop();
            return watch.Elapsed;
        }

        public static TimeSpan ArrayCopy(double[] original)
        {
            Stopwatch watch = new Stopwatch();
            double[] copy = new double[original.Length];
            watch.Start();
            Array.Copy(original, 0, copy, 0, original.Length);
            watch.Stop();
            return watch.Elapsed;
        }

        public static TimeSpan ArrayManualCopy(double[] original)
        {
            Stopwatch watch = new Stopwatch();
            double[] copy = new double[original.Length];
            watch.Start();
            for (int i = 0; i < original.Length; i++)
            {
                copy[i] = original[i];
            }
            watch.Stop();
            return watch.Elapsed;
        }
    }

https://github.com/chivandikwa/Random-Benchmarks

  • 1
    I don't see any timing results in your answer. Please include the console output. – ToolmakerSteve Mar 3 at 2:50

Did benchmarking of both methods copying byte array and found no significant differences. Though if array type was changed to int, performance of Buffer.BlockCopy was 4x greater than Array.CopyTo.

Array.CopyTo (Mb/s): 2188,034

Buffer.BlockCopy (Mb/s): 8827,586

Core i5, Windows 10 64 bit, .NET Core, 1Gb array

    private static void ArrayCopy4Byte(Stopwatch sw, int size, int[] src)
    {
        var dst = new int[size];

        sw.Restart();
        src.CopyTo(dst, 0);
        sw.Stop();

        Console.WriteLine("Array.CopyTo (Mb/s): " + (float)size / 1024 / 1024 / sw.ElapsedMilliseconds * 1000 * sizeof(int));
    }

and

     private static void BufferCopy4Byte(Stopwatch sw, int size, int[] src)
    {
        var dst = new int[size];

        sw.Restart();
        Buffer.BlockCopy(src, 0, dst, 0, src.Length);
        sw.Stop();

        Console.Write("Buffer.BlockCopy (Mb/s): " + (float)size / 1024 / 1024 / sw.ElapsedMilliseconds * 1000 * sizeof(int));
        WriteFirst10(src);
    }

Just want to add my testing case which shows again BlockCopy has no 'PERFORMANCE' benefit over Array.Copy. They seem to have the same performance under release mode on my machine (both take about 66ms to copy 50 million integers). Under debug mode, BlockCopy is just marginally faster.

    private static T[] CopyArray<T>(T[] a) where T:struct 
    {
        T[] res = new T[a.Length];
        int size = Marshal.SizeOf(typeof(T));
        DateTime time1 = DateTime.Now;
        Buffer.BlockCopy(a,0,res,0, size*a.Length);
        Console.WriteLine("Using Buffer blockcopy: {0}", (DateTime.Now - time1).Milliseconds);
        return res;
    }

    static void Main(string[] args)
    {
        int simulation_number = 50000000;
        int[] testarray1 = new int[simulation_number];

        int begin = 0;
        Random r = new Random();
        while (begin != simulation_number)
        {
            testarray1[begin++] = r.Next(0, 10000);
        }

        var copiedarray = CopyArray(testarray1);

        var testarray2 = new int[testarray1.Length];
        DateTime time2 = DateTime.Now;
        Array.Copy(testarray1, testarray2, testarray1.Length);
        Console.WriteLine("Using Array.Copy(): {0}", (DateTime.Now - time2).Milliseconds);
    }
  • 2
    No offence but your test result isn't really helpful ;) First of all "20ms faster" tells you nothing without knowing the overall time. You also carried out those two test in a very differeny manner. The BlockCopy case has an additional method call and the allocation of your target array which you don't have in your Array.Copy case. Due to multithreading fluctuations (possible task switch, core switch) you can easily get different results everytime you execute the test. – Bunny83 Nov 4 '14 at 17:35
  • @Bunny83 thanks for the comment. I have slightly modified the timer location which should give a fairer comparison now. And I am a bit surprised that blockcopy is not faster than array.copy at all. – stt106 Nov 5 '14 at 21:17

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