1565

How can you convert a byte array to a hexadecimal string and vice versa?

1
  • 10
    The accepted answer below appear to allocate a horrible amount of strings in the string to bytes conversion. I'm wondering how this impacts performance
    – Wim Coenen
    Mar 6, 2009 at 16:41

52 Answers 52

1620

You can use Convert.ToHexString starting with .NET 5.
There's also a method for the reverse operation: Convert.FromHexString.


For older versions of .NET you can either use:

public static string ByteArrayToString(byte[] ba)
{
  StringBuilder hex = new StringBuilder(ba.Length * 2);
  foreach (byte b in ba)
    hex.AppendFormat("{0:x2}", b);
  return hex.ToString();
}

or:

public static string ByteArrayToString(byte[] ba)
{
  return BitConverter.ToString(ba).Replace("-","");
}

There are even more variants of doing it, for example here.

The reverse conversion would go like this:

public static byte[] StringToByteArray(String hex)
{
  int NumberChars = hex.Length;
  byte[] bytes = new byte[NumberChars / 2];
  for (int i = 0; i < NumberChars; i += 2)
    bytes[i / 2] = Convert.ToByte(hex.Substring(i, 2), 16);
  return bytes;
}

Using Substring is the best option in combination with Convert.ToByte. See this answer for more information. If you need better performance, you must avoid Convert.ToByte before you can drop SubString.

19
  • 30
    You're using SubString. Doesn't this loop allocate a horrible amount of string objects?
    – Wim Coenen
    Mar 6, 2009 at 16:36
  • 33
    Honestly - until it tears down performance dramatically, I would tend to ignore this and trust the Runtime and the GC to take care of it.
    – Tomalak
    Mar 6, 2009 at 17:11
  • 94
    Because a byte is two nibbles, any hex string that validly represents a byte array must have an even character count. A 0 should not be added anywhere - to add one would be making an assumption about invalid data that is potentially dangerous. If anything, the StringToByteArray method should throw a FormatException if the hex string contains an odd number of characters. Mar 9, 2010 at 19:01
  • 8
    @00jt You must make an assumption that F == 0F. Either it is the same as 0F, or the input was clipped and F is actually the start of something you have not received. It is up to your context to make those assumptions, but I believe a general purpose function should reject odd characters as invalid instead of making that assumption for the calling code. Jan 28, 2013 at 15:35
  • 12
    @DavidBoike The question had NOTHING to do with "how to handle possibly clipped stream values" Its talking about a String. String myValue = 10.ToString("X"); myValue is "A" not "0A". Now go read that string back into bytes, oops you broke it.
    – 00jt
    Jan 30, 2013 at 19:25
535

Performance Analysis

Note: new leader as of 2015-08-20.

I ran each of the various conversion methods through some crude Stopwatch performance testing, a run with a random sentence (n=61, 1000 iterations) and a run with a Project Gutenburg text (n=1,238,957, 150 iterations). Here are the results, roughly from fastest to slowest. All measurements are in ticks (10,000 ticks = 1 ms) and all relative notes are compared to the [slowest] StringBuilder implementation. For the code used, see below or the test framework repo where I now maintain the code for running this.

Disclaimer

WARNING: Do not rely on these stats for anything concrete; they are simply a sample run of sample data. If you really need top-notch performance, please test these methods in an environment representative of your production needs with data representative of what you will use.

Results

Lookup tables have taken the lead over byte manipulation. Basically, there is some form of precomputing what any given nibble or byte will be in hex. Then, as you rip through the data, you simply look up the next portion to see what hex string it would be. That value is then added to the resulting string output in some fashion. For a long time byte manipulation, potentially harder to read by some developers, was the top-performing approach.

Your best bet is still going to be finding some representative data and trying it out in a production-like environment. If you have different memory constraints, you may prefer a method with fewer allocations to one that would be faster but consume more memory.

Testing Code

Feel free to play with the testing code I used. A version is included here but feel free to clone the repo and add your own methods. Please submit a pull request if you find anything interesting or want to help improve the testing framework it uses.

  1. Add the new static method (Func<byte[], string>) to /Tests/ConvertByteArrayToHexString/Test.cs.
  2. Add that method's name to the TestCandidates return value in that same class.
  3. Make sure you are running the input version you want, sentence or text, by toggling the comments in GenerateTestInput in that same class.
  4. Hit F5 and wait for the output (an HTML dump is also generated in the /bin folder).
static string ByteArrayToHexStringViaStringJoinArrayConvertAll(byte[] bytes) {
    return string.Join(string.Empty, Array.ConvertAll(bytes, b => b.ToString("X2")));
}
static string ByteArrayToHexStringViaStringConcatArrayConvertAll(byte[] bytes) {
    return string.Concat(Array.ConvertAll(bytes, b => b.ToString("X2")));
}
static string ByteArrayToHexStringViaBitConverter(byte[] bytes) {
    string hex = BitConverter.ToString(bytes);
    return hex.Replace("-", "");
}
static string ByteArrayToHexStringViaStringBuilderAggregateByteToString(byte[] bytes) {
    return bytes.Aggregate(new StringBuilder(bytes.Length * 2), (sb, b) => sb.Append(b.ToString("X2"))).ToString();
}
static string ByteArrayToHexStringViaStringBuilderForEachByteToString(byte[] bytes) {
    StringBuilder hex = new StringBuilder(bytes.Length * 2);
    foreach (byte b in bytes)
        hex.Append(b.ToString("X2"));
    return hex.ToString();
}
static string ByteArrayToHexStringViaStringBuilderAggregateAppendFormat(byte[] bytes) {
    return bytes.Aggregate(new StringBuilder(bytes.Length * 2), (sb, b) => sb.AppendFormat("{0:X2}", b)).ToString();
}
static string ByteArrayToHexStringViaStringBuilderForEachAppendFormat(byte[] bytes) {
    StringBuilder hex = new StringBuilder(bytes.Length * 2);
    foreach (byte b in bytes)
        hex.AppendFormat("{0:X2}", b);
    return hex.ToString();
}
static string ByteArrayToHexViaByteManipulation(byte[] bytes) {
    char[] c = new char[bytes.Length * 2];
    byte b;
    for (int i = 0; i < bytes.Length; i++) {
        b = ((byte)(bytes[i] >> 4));
        c[i * 2] = (char)(b > 9 ? b + 0x37 : b + 0x30);
        b = ((byte)(bytes[i] & 0xF));
        c[i * 2 + 1] = (char)(b > 9 ? b + 0x37 : b + 0x30);
    }
    return new string(c);
}
static string ByteArrayToHexViaByteManipulation2(byte[] bytes) {
    char[] c = new char[bytes.Length * 2];
    int b;
    for (int i = 0; i < bytes.Length; i++) {
        b = bytes[i] >> 4;
        c[i * 2] = (char)(55 + b + (((b - 10) >> 31) & -7));
        b = bytes[i] & 0xF;
        c[i * 2 + 1] = (char)(55 + b + (((b - 10) >> 31) & -7));
    }
    return new string(c);
}
static string ByteArrayToHexViaSoapHexBinary(byte[] bytes) {
    SoapHexBinary soapHexBinary = new SoapHexBinary(bytes);
    return soapHexBinary.ToString();
}
static string ByteArrayToHexViaLookupAndShift(byte[] bytes) {
    StringBuilder result = new StringBuilder(bytes.Length * 2);
    string hexAlphabet = "0123456789ABCDEF";
    foreach (byte b in bytes) {
        result.Append(hexAlphabet[(int)(b >> 4)]);
        result.Append(hexAlphabet[(int)(b & 0xF)]);
    }
    return result.ToString();
}
static readonly uint* _lookup32UnsafeP = (uint*)GCHandle.Alloc(_Lookup32, GCHandleType.Pinned).AddrOfPinnedObject();
static string ByteArrayToHexViaLookup32UnsafeDirect(byte[] bytes) {
    var lookupP = _lookup32UnsafeP;
    var result = new string((char)0, bytes.Length * 2);
    fixed (byte* bytesP = bytes)
    fixed (char* resultP = result) {
        uint* resultP2 = (uint*)resultP;
        for (int i = 0; i < bytes.Length; i++) {
            resultP2[i] = lookupP[bytesP[i]];
        }
    }
    return result;
}
static uint[] _Lookup32 = Enumerable.Range(0, 255).Select(i => {
    string s = i.ToString("X2");
    return ((uint)s[0]) + ((uint)s[1] << 16);
}).ToArray();
static string ByteArrayToHexViaLookupPerByte(byte[] bytes) {
    var result = new char[bytes.Length * 2];
    for (int i = 0; i < bytes.Length; i++)
    {
        var val = _Lookup32[bytes[i]];
        result[2*i] = (char)val;
        result[2*i + 1] = (char) (val >> 16);
    }
    return new string(result);
}
static string ByteArrayToHexViaLookup(byte[] bytes) {
    string[] hexStringTable = new string[] {
        "00", "01", "02", "03", "04", "05", "06", "07", "08", "09", "0A", "0B", "0C", "0D", "0E", "0F",
        "10", "11", "12", "13", "14", "15", "16", "17", "18", "19", "1A", "1B", "1C", "1D", "1E", "1F",
        "20", "21", "22", "23", "24", "25", "26", "27", "28", "29", "2A", "2B", "2C", "2D", "2E", "2F",
        "30", "31", "32", "33", "34", "35", "36", "37", "38", "39", "3A", "3B", "3C", "3D", "3E", "3F",
        "40", "41", "42", "43", "44", "45", "46", "47", "48", "49", "4A", "4B", "4C", "4D", "4E", "4F",
        "50", "51", "52", "53", "54", "55", "56", "57", "58", "59", "5A", "5B", "5C", "5D", "5E", "5F",
        "60", "61", "62", "63", "64", "65", "66", "67", "68", "69", "6A", "6B", "6C", "6D", "6E", "6F",
        "70", "71", "72", "73", "74", "75", "76", "77", "78", "79", "7A", "7B", "7C", "7D", "7E", "7F",
        "80", "81", "82", "83", "84", "85", "86", "87", "88", "89", "8A", "8B", "8C", "8D", "8E", "8F",
        "90", "91", "92", "93", "94", "95", "96", "97", "98", "99", "9A", "9B", "9C", "9D", "9E", "9F",
        "A0", "A1", "A2", "A3", "A4", "A5", "A6", "A7", "A8", "A9", "AA", "AB", "AC", "AD", "AE", "AF",
        "B0", "B1", "B2", "B3", "B4", "B5", "B6", "B7", "B8", "B9", "BA", "BB", "BC", "BD", "BE", "BF",
        "C0", "C1", "C2", "C3", "C4", "C5", "C6", "C7", "C8", "C9", "CA", "CB", "CC", "CD", "CE", "CF",
        "D0", "D1", "D2", "D3", "D4", "D5", "D6", "D7", "D8", "D9", "DA", "DB", "DC", "DD", "DE", "DF",
        "E0", "E1", "E2", "E3", "E4", "E5", "E6", "E7", "E8", "E9", "EA", "EB", "EC", "ED", "EE", "EF",
        "F0", "F1", "F2", "F3", "F4", "F5", "F6", "F7", "F8", "F9", "FA", "FB", "FC", "FD", "FE", "FF",
    };
    StringBuilder result = new StringBuilder(bytes.Length * 2);
    foreach (byte b in bytes) {
        result.Append(hexStringTable[b]);
    }
    return result.ToString();
}

Update (2010-01-13)

Added Waleed's answer to analysis. Quite fast.

Update (2011-10-05)

Added string.Concat Array.ConvertAll variant for completeness (requires .NET 4.0). On par with string.Join version.

Update (2012-02-05)

Test repo includes more variants such as StringBuilder.Append(b.ToString("X2")). None upset the results any. foreach is faster than {IEnumerable}.Aggregate, for instance, but BitConverter still wins.

Update (2012-04-03)

Added Mykroft's SoapHexBinary answer to analysis, which took over third place.

Update (2013-01-15)

Added CodesInChaos's byte manipulation answer, which took over first place (by a large margin on large blocks of text).

Update (2013-05-23)

Added Nathan Moinvaziri's lookup answer and the variant from Brian Lambert's blog. Both rather fast, but not taking the lead on the test machine I used (AMD Phenom 9750).

Update (2014-07-31)

Added @CodesInChaos's new byte-based lookup answer. It appears to have taken the lead on both the sentence tests and the full-text tests.

Update (2015-08-20)

Added airbreather's optimizations and unsafe variant to this answer's repo. If you want to play in the unsafe game, you can get some huge performance gains over any of the prior top winners on both short strings and large texts.

21
  • 7
    Despite making the code available for you to do the very thing you requested on your own, I updated the testing code to include Waleed answer. All grumpiness aside, it is much faster.
    – patridge
    Jan 13, 2010 at 16:29
  • 2
    @CodesInChaos Done. And it won in my tests by quite a bit as well. I don't pretend to fully understand either of the top methods yet, but they are easily hidden from direct interaction.
    – patridge
    Jan 15, 2013 at 18:01
  • 6
    This answer has no intention of answering the question of what is "natural" or commonplace. The goal is to give people some basic performance benchmarks since, when you need to do these conversion, you tend to do them a lot. If someone needs raw speed, they just run the benchmarks with some appropriate test data in their desired computing environment. Then, tuck that method away into an extension method where you never look its implementation again (e.g., bytes.ToHexStringAtLudicrousSpeed()).
    – patridge
    Apr 8, 2013 at 20:37
  • 2
    Just produced a high performance lookup table based implementation. Its safe variant is about 30% faster than the current leader on my CPU. The unsafe variants are even faster. stackoverflow.com/a/24343727/445517 Jun 21, 2014 at 17:12
  • 2
    @Goodies I've discovered that the simple Convert.ToBase64String() is VERY fast (faster than Lookup by byte (via CodesInChaos) ) in my testing - so if anyone doesn't care about the output being hexadecimal, that's a quick one-line replacement. Aug 10, 2018 at 9:44
260

There's a class called SoapHexBinary that does exactly what you want.

using System.Runtime.Remoting.Metadata.W3cXsd2001;

public static byte[] GetStringToBytes(string value)
{
    SoapHexBinary shb = SoapHexBinary.Parse(value);
    return shb.Value;
}

public static string GetBytesToString(byte[] value)
{
    SoapHexBinary shb = new SoapHexBinary(value);
    return shb.ToString();
}
8
  • 38
    SoapHexBinary is available from .NET 1.0 and is in mscorlib. Despite it's funny namespace, it does exactly what the question asked. Jun 28, 2011 at 6:48
  • 4
    Great find! Note that you will need to pad odd strings with a leading 0 for GetStringToBytes, like the other solution. Oct 31, 2011 at 17:10
  • Have you seen the implementation thought? The accepted answer has a better one IMHO.
    – mfloryan
    Jan 26, 2012 at 13:42
  • 6
    Interesting to see the Mono implementation here: github.com/mono/mono/blob/master/mcs/class/corlib/…
    – Jeremy
    Apr 29, 2012 at 4:40
  • 10
    SoapHexBinary is not supported in .NET Core/ .NET Standard...
    – juFo
    Mar 11, 2020 at 9:12
156

When writing crypto code it's common to avoid data dependent branches and table lookups to ensure the runtime doesn't depend on the data, since data dependent timing can lead to side-channel attacks.

It's also pretty fast.

static string ByteToHexBitFiddle(byte[] bytes)
{
    char[] c = new char[bytes.Length * 2];
    int b;
    for (int i = 0; i < bytes.Length; i++) {
        b = bytes[i] >> 4;
        c[i * 2] = (char)(55 + b + (((b-10)>>31)&-7));
        b = bytes[i] & 0xF;
        c[i * 2 + 1] = (char)(55 + b + (((b-10)>>31)&-7));
    }
    return new string(c);
}

Ph'nglui mglw'nafh Cthulhu R'lyeh wgah'nagl fhtagn


Abandon all hope, ye who enter here

An explanation of the weird bit fiddling:

  1. bytes[i] >> 4 extracts the high nibble of a byte
    bytes[i] & 0xF extracts the low nibble of a byte
  2. b - 10
    is < 0 for values b < 10, which will become a decimal digit
    is >= 0 for values b > 10, which will become a letter from A to F.
  3. Using i >> 31 on a signed 32 bit integer extracts the sign, thanks to sign extension. It will be -1 for i < 0 and 0 for i >= 0.
  4. Combining 2) and 3), shows that (b-10)>>31 will be 0 for letters and -1 for digits.
  5. Looking at the case for letters, the last summand becomes 0, and b is in the range 10 to 15. We want to map it to A(65) to F(70), which implies adding 55 ('A'-10).
  6. Looking at the case for digits, we want to adapt the last summand so it maps b from the range 0 to 9 to the range 0(48) to 9(57). This means it needs to become -7 ('0' - 55).
    Now we could just multiply with 7. But since -1 is represented by all bits being 1, we can instead use & -7 since (0 & -7) == 0 and (-1 & -7) == -7.

Some further considerations:

  • I didn't use a second loop variable to index into c, since measurement shows that calculating it from i is cheaper.
  • Using exactly i < bytes.Length as upper bound of the loop allows the JITter to eliminate bounds checks on bytes[i], so I chose that variant.
  • Making b an int allows unnecessary conversions from and to byte.
15
  • 11
    And hex string to byte[] array?
    – AaA
    Jan 18, 2013 at 7:56
  • 17
    +1 for properly citing your source after invoking that bit of black magic. All hail Cthulhu.
    – Edward
    Aug 2, 2013 at 20:41
  • 6
    What about string to byte[]? Nov 6, 2013 at 10:14
  • 10
    Nice! For those who need lowercase output, the expression obviously changes to 87 + b + (((b-10)>>31)&-39)
    – eXavier
    Jan 6, 2014 at 17:36
  • 2
    @AaA You said "byte[] array", which literally means an array of byte arrays, or byte[][]. I was just poking fun.
    – CoolOppo
    Jun 10, 2015 at 3:09
115

If you want more flexibility than BitConverter, but don't want those clunky 1990s-style explicit loops, then you can do:

String.Join(String.Empty, Array.ConvertAll(bytes, x => x.ToString("X2")));

Or, if you're using .NET 4.0:

String.Concat(Array.ConvertAll(bytes, x => x.ToString("X2")));

(The latter from a comment on the original post.)

6
  • 22
    Even shorter: String.Concat(Array.ConvertAll(bytes, x => x.ToString("X2"))
    – Nestor
    Nov 25, 2009 at 15:04
  • 16
    Even shorter: String.Concat(bytes.Select(b => b.ToString("X2"))) [.NET4] Jun 16, 2011 at 6:39
  • 14
    Only answers half the question. Jun 28, 2011 at 6:50
  • 2
    Why does the second one need .Net 4? String.Concat is in .Net 2.0.
    – Polyfun
    Oct 17, 2014 at 11:42
  • 5
    those "90's style" loops are generally faster, but by a negligible enough amount that it wont matter in most contexts. Still worth mentioning though Oct 24, 2017 at 19:47
83

Another lookup table based approach. This one uses only one lookup table for each byte, instead of a lookup table per nibble.

private static readonly uint[] _lookup32 = CreateLookup32();

private static uint[] CreateLookup32()
{
    var result = new uint[256];
    for (int i = 0; i < 256; i++)
    {
        string s=i.ToString("X2");
        result[i] = ((uint)s[0]) + ((uint)s[1] << 16);
    }
    return result;
}

private static string ByteArrayToHexViaLookup32(byte[] bytes)
{
    var lookup32 = _lookup32;
    var result = new char[bytes.Length * 2];
    for (int i = 0; i < bytes.Length; i++)
    {
        var val = lookup32[bytes[i]];
        result[2*i] = (char)val;
        result[2*i + 1] = (char) (val >> 16);
    }
    return new string(result);
}

I also tested variants of this using ushort, struct{char X1, X2}, struct{byte X1, X2} in the lookup table.

Depending on the compilation target (x86, X64) those either had the approximately same performance or were slightly slower than this variant.


And for even higher performance, its unsafe sibling:

private static readonly uint[] _lookup32Unsafe = CreateLookup32Unsafe();
private static readonly uint* _lookup32UnsafeP = (uint*)GCHandle.Alloc(_lookup32Unsafe,GCHandleType.Pinned).AddrOfPinnedObject();

private static uint[] CreateLookup32Unsafe()
{
    var result = new uint[256];
    for (int i = 0; i < 256; i++)
    {
        string s=i.ToString("X2");
        if(BitConverter.IsLittleEndian)
            result[i] = ((uint)s[0]) + ((uint)s[1] << 16);
        else
            result[i] = ((uint)s[1]) + ((uint)s[0] << 16);
    }
    return result;
}

public static string ByteArrayToHexViaLookup32Unsafe(byte[] bytes)
{
    var lookupP = _lookup32UnsafeP;
    var result = new char[bytes.Length * 2];
    fixed(byte* bytesP = bytes)
    fixed (char* resultP = result)
    {
        uint* resultP2 = (uint*)resultP;
        for (int i = 0; i < bytes.Length; i++)
        {
            resultP2[i] = lookupP[bytesP[i]];
        }
    }
    return new string(result);
}

Or if you consider it acceptable to write into the string directly:

public static string ByteArrayToHexViaLookup32UnsafeDirect(byte[] bytes)
{
    var lookupP = _lookup32UnsafeP;
    var result = new string((char)0, bytes.Length * 2);
    fixed (byte* bytesP = bytes)
    fixed (char* resultP = result)
    {
        uint* resultP2 = (uint*)resultP;
        for (int i = 0; i < bytes.Length; i++)
        {
            resultP2[i] = lookupP[bytesP[i]];
        }
    }
    return result;
}
10
  • 1
    Why does creating the lookup table in the unsafe version swap the nibbles of the precomputed byte ? I thought endianness only changed ordering of entities that were formed of multiple bytes.
    – Raif Atef
    Nov 5, 2014 at 13:13
  • 1
    @RaifAtef What matters here isn't the order of the nibbles. But the order of 16 bit words in a 32 bit integer. But I'm considering rewriting it so the same code can run regardless of endianness. Nov 7, 2014 at 12:09
  • 2
    All right, I'll bite -- what advantage is there to pinning _lookup32Unsafe indefinitely instead of just doing a third fixed statement and letting the GC relocate the array to its heart's content whenever this method isn't running?
    – Joe Amenta
    Jan 9, 2016 at 12:24
  • 7
    This just answer half of the question... How about from hex string to bytes?
    – Narvalex
    Mar 8, 2017 at 17:28
  • 8
    @CodesInChaos I wonder if Span can be used now instead of unsafe ??
    – Konrad
    Dec 4, 2019 at 13:12
72

You can use the BitConverter.ToString method:

byte[] bytes = {0, 1, 2, 4, 8, 16, 32, 64, 128, 256}
Console.WriteLine( BitConverter.ToString(bytes));

Output:

00-01-02-04-08-10-20-40-80-FF

More information: BitConverter.ToString Method (Byte[])

3
  • 17
    Only answers half the question. Jun 28, 2011 at 6:49
  • 4
    Where is the second part of the answer?
    – Saw
    Dec 25, 2012 at 9:12
  • 2
    I hope the fact that 256 is converted to "FF" is just a typo...
    – Franz D.
    May 13, 2021 at 16:10
60

I just encountered the very same problem today, and I came across this code:

private static string ByteArrayToHex(byte[] barray)
{
    char[] c = new char[barray.Length * 2];
    byte b;
    for (int i = 0; i < barray.Length; ++i)
    {
        b = ((byte)(barray[i] >> 4));
        c[i * 2] = (char)(b > 9 ? b + 0x37 : b + 0x30);
        b = ((byte)(barray[i] & 0xF));
        c[i * 2 + 1] = (char)(b > 9 ? b + 0x37 : b + 0x30);
    }
    return new string(c);
}

Source: Forum post byte[] Array to Hex String (see the post by PZahra). I modified the code a little to remove the 0x prefix.

I did some performance testing to the code and it was almost eight times faster than using BitConverter.ToString() (the fastest according to patridge's post).

7
  • not to mention that this uses the least memory. No intermediate strings created whatsoever.
    – Chochos
    Oct 16, 2009 at 17:36
  • 9
    Only answers half the question. Jun 28, 2011 at 6:50
  • This is great because it works on basically any version of NET, including NETMF. A winner! Feb 6, 2012 at 4:26
  • 2
    The accepted answer provides 2 excellent HexToByteArray methods, which represent the other half of the question. Waleed's solution answers the running question of how to do this without creating a huge number of strings in the process. Oct 10, 2012 at 16:08
  • Does new string(c) copy and re-allocate or is it smart enough to know when it can simply wrap the char[]?
    – jjxtra
    Oct 15, 2013 at 17:24
30

As of .NET 5 RC2 you can use:

Overloads are available that take span parameters.

1
  • 2
    In .NET 6, Convert.ToHexString uses SSSE3 instruction set on CPU, so it is not only convenient to use as in .NET 5, but also more performant for inputs more than 3 bytes. Performance difference is more clear as the input size increases.
    – MÇT
    Aug 26, 2021 at 9:04
25

This is an answer to revision 4 of Tomalak's highly popular answer (and subsequent edits).

I'll make the case that this edit is wrong, and explain why it could be reverted. Along the way, you might learn a thing or two about some internals, and see yet another example of what premature optimization really is and how it can bite you.

tl;dr: Just use Convert.ToByte and String.Substring if you're in a hurry ("Original code" below), it's the best combination if you don't want to re-implement Convert.ToByte. Use something more advanced (see other answers) that doesn't use Convert.ToByte if you need performance. Do not use anything else other than String.Substring in combination with Convert.ToByte, unless someone has something interesting to say about this in the comments of this answer.

warning: This answer may become obsolete if a Convert.ToByte(char[], Int32) overload is implemented in the framework. This is unlikely to happen soon.

As a general rule, I don't much like to say "don't optimize prematurely", because nobody knows when "premature" is. The only thing you must consider when deciding whether to optimize or not is: "Do I have the time and resources to investigate optimization approaches properly?". If you don't, then it's too soon, wait until your project is more mature or until you need the performance (if there is a real need, then you will make the time). In the meantime, do the simplest thing that could possibly work instead.

Original code:

    public static byte[] HexadecimalStringToByteArray_Original(string input)
    {
        var outputLength = input.Length / 2;
        var output = new byte[outputLength];
        for (var i = 0; i < outputLength; i++)
            output[i] = Convert.ToByte(input.Substring(i * 2, 2), 16);
        return output;
    }

Revision 4:

    public static byte[] HexadecimalStringToByteArray_Rev4(string input)
    {
        var outputLength = input.Length / 2;
        var output = new byte[outputLength];
        using (var sr = new StringReader(input))
        {
            for (var i = 0; i < outputLength; i++)
                output[i] = Convert.ToByte(new string(new char[2] { (char)sr.Read(), (char)sr.Read() }), 16);
        }
        return output;
    }

The revision avoids String.Substring and uses a StringReader instead. The given reason is:

Edit: you can improve performance for long strings by using a single pass parser, like so:

Well, looking at the reference code for String.Substring, it's clearly "single-pass" already; and why shouldn't it be? It operates at byte-level, not on surrogate pairs.

It does allocate a new string however, but then you need to allocate one to pass to Convert.ToByte anyway. Furthermore, the solution provided in the revision allocates yet another object on every iteration (the two-char array); you can safely put that allocation outside the loop and reuse the array to avoid that.

    public static byte[] HexadecimalStringToByteArray(string input)
    {
        var outputLength = input.Length / 2;
        var output = new byte[outputLength];
        var numeral = new char[2];
        using (var sr = new StringReader(input))
        {
            for (var i = 0; i < outputLength; i++)
            {
                numeral[0] = (char)sr.Read();
                numeral[1] = (char)sr.Read();
                output[i] = Convert.ToByte(new string(numeral), 16);
            }
        }
        return output;
    }

Each hexadecimal numeral represents a single octet using two digits (symbols).

But then, why call StringReader.Read twice? Just call its second overload and ask it to read two characters in the two-char array at once; and reduce the amount of calls by two.

    public static byte[] HexadecimalStringToByteArray(string input)
    {
        var outputLength = input.Length / 2;
        var output = new byte[outputLength];
        var numeral = new char[2];
        using (var sr = new StringReader(input))
        {
            for (var i = 0; i < outputLength; i++)
            {
                var read = sr.Read(numeral, 0, 2);
                Debug.Assert(read == 2);
                output[i] = Convert.ToByte(new string(numeral), 16);
            }
        }
        return output;
    }

What you're left with is a string reader whose only added "value" is a parallel index (internal _pos) which you could have declared yourself (as j for example), a redundant length variable (internal _length), and a redundant reference to the input string (internal _s). In other words, it's useless.

If you wonder how Read "reads", just look at the code, all it does is call String.CopyTo on the input string. The rest is just book-keeping overhead to maintain values we don't need.

So, remove the string reader already, and call CopyTo yourself; it's simpler, clearer, and more efficient.

    public static byte[] HexadecimalStringToByteArray(string input)
    {
        var outputLength = input.Length / 2;
        var output = new byte[outputLength];
        var numeral = new char[2];
        for (int i = 0, j = 0; i < outputLength; i++, j += 2)
        {
            input.CopyTo(j, numeral, 0, 2);
            output[i] = Convert.ToByte(new string(numeral), 16);
        }
        return output;
    }

Do you really need a j index that increments in steps of two parallel to i? Of course not, just multiply i by two (which the compiler should be able to optimize to an addition).

    public static byte[] HexadecimalStringToByteArray_BestEffort(string input)
    {
        var outputLength = input.Length / 2;
        var output = new byte[outputLength];
        var numeral = new char[2];
        for (int i = 0; i < outputLength; i++)
        {
            input.CopyTo(i * 2, numeral, 0, 2);
            output[i] = Convert.ToByte(new string(numeral), 16);
        }
        return output;
    }

What does the solution look like now? Exactly like it was at the beginning, only instead of using String.Substring to allocate the string and copy the data to it, you're using an intermediary array to which you copy the hexadecimal numerals to, then allocate the string yourself and copy the data again from the array and into the string (when you pass it in the string constructor). The second copy might be optimized-out if the string is already in the intern pool, but then String.Substring will also be able to avoid it in these cases.

In fact, if you look at String.Substring again, you see that it uses some low-level internal knowledge of how strings are constructed to allocate the string faster than you could normally do it, and it inlines the same code used by CopyTo directly in there to avoid the call overhead.

String.Substring

  • Worst-case: One fast allocation, one fast copy.
  • Best-case: No allocation, no copy.

Manual method

  • Worst-case: Two normal allocations, one normal copy, one fast copy.
  • Best-case: One normal allocation, one normal copy.

Conclusion? If you want to use Convert.ToByte(String, Int32) (because you don't want to re-implement that functionality yourself), there doesn't seem to be a way to beat String.Substring; all you do is run in circles, re-inventing the wheel (only with sub-optimal materials).

Note that using Convert.ToByte and String.Substring is a perfectly valid choice if you don't need extreme performance. Remember: only opt for an alternative if you have the time and resources to investigate how it works properly.

If there was a Convert.ToByte(char[], Int32), things would be different of course (it would be possible to do what I described above and completely avoid String).

I suspect that people who report better performance by "avoiding String.Substring" also avoid Convert.ToByte(String, Int32), which you should really be doing if you need the performance anyway. Look at the countless other answers to discover all the different approaches to do that.

Disclaimer: I haven't decompiled the latest version of the framework to verify that the reference source is up-to-date, I assume it is.

Now, it all sounds good and logical, hopefully even obvious if you've managed to get so far. But is it true?

Intel(R) Core(TM) i7-3720QM CPU @ 2.60GHz
    Cores: 8
    Current Clock Speed: 2600
    Max Clock Speed: 2600
--------------------
Parsing hexadecimal string into an array of bytes
--------------------
HexadecimalStringToByteArray_Original: 7,777.09 average ticks (over 10000 runs), 1.2X
HexadecimalStringToByteArray_BestEffort: 8,550.82 average ticks (over 10000 runs), 1.1X
HexadecimalStringToByteArray_Rev4: 9,218.03 average ticks (over 10000 runs), 1.0X

Yes!

Props to Partridge for the bench framework, it's easy to hack. The input used is the following SHA-1 hash repeated 5000 times to make a 100,000 bytes long string.

209113288F93A9AB8E474EA78D899AFDBB874355

Have fun! (But optimize with moderation.)

1
  • 1
    error : {"Could not find any recognizable digits."} Apr 21, 2020 at 20:09
20

Complement to answer by @CodesInChaos (reversed method)

public static byte[] HexToByteUsingByteManipulation(string s)
{
    byte[] bytes = new byte[s.Length / 2];
    for (int i = 0; i < bytes.Length; i++)
    {
        int hi = s[i*2] - 65;
        hi = hi + 10 + ((hi >> 31) & 7);

        int lo = s[i*2 + 1] - 65;
        lo = lo + 10 + ((lo >> 31) & 7) & 0x0f;

        bytes[i] = (byte) (lo | hi << 4);
    }
    return bytes;
}

Explanation:

& 0x0f is to support also lower case letters

hi = hi + 10 + ((hi >> 31) & 7); is the same as:

hi = ch-65 + 10 + (((ch-65) >> 31) & 7);

For '0'..'9' it is the same as hi = ch - 65 + 10 + 7; which is hi = ch - 48 (this is because of 0xffffffff & 7).

For 'A'..'F' it is hi = ch - 65 + 10; (this is because of 0x00000000 & 7).

For 'a'..'f' we have to big numbers so we must subtract 32 from default version by making some bits 0 by using & 0x0f.

65 is code for 'A'

48 is code for '0'

7 is the number of letters between '9' and 'A' in the ASCII table (...456789:;<=>?@ABCD...).

20

This problem could also be solved using a look-up table. This would require a small amount of static memory for both the encoder and decoder. This method will however be fast:

  • Encoder table 512 bytes or 1024 bytes (twice the size if both upper and lower case is needed)
  • Decoder table 256 bytes or 64 KiB (either a single char look-up or dual char look-up)

My solution uses 1024 bytes for the encoding table, and 256 bytes for decoding.

Decoding

private static readonly byte[] LookupTable = new byte[] {
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF
};

private static byte Lookup(char c)
{
  var b = LookupTable[c];
  if (b == 255)
    throw new IOException("Expected a hex character, got " + c);
  return b;
}

public static byte ToByte(char[] chars, int offset)
{
  return (byte)(Lookup(chars[offset]) << 4 | Lookup(chars[offset + 1]));
}

Encoding

private static readonly char[][] LookupTableUpper;
private static readonly char[][] LookupTableLower;

static Hex()
{
  LookupTableLower = new char[256][];
  LookupTableUpper = new char[256][];
  for (var i = 0; i < 256; i++)
  {
    LookupTableLower[i] = i.ToString("x2").ToCharArray();
    LookupTableUpper[i] = i.ToString("X2").ToCharArray();
  }
}

public static char[] ToCharLower(byte[] b, int bOffset)
{
  return LookupTableLower[b[bOffset]];
}

public static char[] ToCharUpper(byte[] b, int bOffset)
{
  return LookupTableUpper[b[bOffset]];
}

Comparison

StringBuilderToStringFromBytes:   106148
BitConverterToStringFromBytes:     15783
ArrayConvertAllToStringFromBytes:  54290
ByteManipulationToCharArray:        8444
TableBasedToCharArray:              5651 *

* this solution

Note

During decoding IOException and IndexOutOfRangeException could occur (if a character has a too high value > 256). Methods for de/encoding streams or arrays should be implemented, this is just a proof of concept.

1
  • 2
    Memory usage of 256 bytes is negligible when you run code on the CLR.
    – dolmen
    Aug 21, 2013 at 0:05
19

Dotnet 5 Update

To convert from byte[] (byte array) to hexadecimal string, use:

System.Convert.ToHexString

var myBytes = new byte[100];
var myString = System.Convert.ToHexString(myBytes);

To convert from hexadecimal string to byte[], use:

System.Convert.FromHexString

var myString  = "E10B116E8530A340BCC7B3EAC208487B";
var myBytes = System.Convert.FromHexString(myString);
13

Why make it complex? This is simple in Visual Studio 2008:

C#:

string hex = BitConverter.ToString(YourByteArray).Replace("-", "");

VB:

Dim hex As String = BitConverter.ToString(YourByteArray).Replace("-", "")
1
  • 3
    the reason is performance, when you need high performance solution. :)
    – Ricky
    Aug 4, 2016 at 6:28
11

This is a great post. I like Waleed's solution. I haven't run it through patridge's test but it seems to be quite fast. I also needed the reverse process, converting a hex string to a byte array, so I wrote it as a reversal of Waleed's solution. Not sure if it's any faster than Tomalak's original solution. Again, I did not run the reverse process through patridge's test either.

private byte[] HexStringToByteArray(string hexString)
{
    int hexStringLength = hexString.Length;
    byte[] b = new byte[hexStringLength / 2];
    for (int i = 0; i < hexStringLength; i += 2)
    {
        int topChar = (hexString[i] > 0x40 ? hexString[i] - 0x37 : hexString[i] - 0x30) << 4;
        int bottomChar = hexString[i + 1] > 0x40 ? hexString[i + 1] - 0x37 : hexString[i + 1] - 0x30;
        b[i / 2] = Convert.ToByte(topChar + bottomChar);
    }
    return b;
}
4
  • 1
    This code assumes the hex string uses upper case alpha chars, and blows up if the hex string uses lower case alpha. Might want to do a "uppercase" conversion on the input string to be safe. Jan 26, 2010 at 19:17
  • That's an astute observation Marc. The code was written to reverse Waleed's solution. The ToUpper call would slow down the algorithm some, but would allow it to handle lower case alpha chars.
    – Chris F
    Jan 26, 2010 at 20:27
  • 3
    Convert.ToByte(topChar + bottomChar) can be written as (byte)(topChar + bottomChar) Feb 12, 2011 at 21:17
  • To handle both cases without a large performance penalty, hexString[i] &= ~0x20;
    – Ben Voigt
    Jul 31, 2014 at 22:31
9

Not to pile on to the many answers here, but I found a fairly optimal (~4.5x better than accepted), straightforward implementation of the hex string parser. First, output from my tests (the first batch is my implementation):

Give me that string:
04c63f7842740c77e545bb0b2ade90b384f119f6ab57b680b7aa575a2f40939f

Time to parse 100,000 times: 50.4192 ms
Result as base64: BMY/eEJ0DHflRbsLKt6Qs4TxGfarV7aAt6pXWi9Ak58=
BitConverter'd: 04-C6-3F-78-42-74-0C-77-E5-45-BB-0B-2A-DE-90-B3-84-F1-19-F6-AB-5
7-B6-80-B7-AA-57-5A-2F-40-93-9F

Accepted answer: (StringToByteArray)
Time to parse 100000 times: 233.1264ms
Result as base64: BMY/eEJ0DHflRbsLKt6Qs4TxGfarV7aAt6pXWi9Ak58=
BitConverter'd: 04-C6-3F-78-42-74-0C-77-E5-45-BB-0B-2A-DE-90-B3-84-F1-19-F6-AB-5
7-B6-80-B7-AA-57-5A-2F-40-93-9F

With Mono's implementation:
Time to parse 100000 times: 777.2544ms
Result as base64: BMY/eEJ0DHflRbsLKt6Qs4TxGfarV7aAt6pXWi9Ak58=
BitConverter'd: 04-C6-3F-78-42-74-0C-77-E5-45-BB-0B-2A-DE-90-B3-84-F1-19-F6-AB-5
7-B6-80-B7-AA-57-5A-2F-40-93-9F

With SoapHexBinary:
Time to parse 100000 times: 845.1456ms
Result as base64: BMY/eEJ0DHflRbsLKt6Qs4TxGfarV7aAt6pXWi9Ak58=
BitConverter'd: 04-C6-3F-78-42-74-0C-77-E5-45-BB-0B-2A-DE-90-B3-84-F1-19-F6-AB-5
7-B6-80-B7-AA-57-5A-2F-40-93-9F

The base64 and 'BitConverter'd' lines are there to test for correctness. Note that they are equal.

The implementation:

public static byte[] ToByteArrayFromHex(string hexString)
{
  if (hexString.Length % 2 != 0) throw new ArgumentException("String must have an even length");
  var array = new byte[hexString.Length / 2];
  for (int i = 0; i < hexString.Length; i += 2)
  {
    array[i/2] = ByteFromTwoChars(hexString[i], hexString[i + 1]);
  }
  return array;
}

private static byte ByteFromTwoChars(char p, char p_2)
{
  byte ret;
  if (p <= '9' && p >= '0')
  {
    ret = (byte) ((p - '0') << 4);
  }
  else if (p <= 'f' && p >= 'a')
  {
    ret = (byte) ((p - 'a' + 10) << 4);
  }
  else if (p <= 'F' && p >= 'A')
  {
    ret = (byte) ((p - 'A' + 10) << 4);
  } else throw new ArgumentException("Char is not a hex digit: " + p,"p");

  if (p_2 <= '9' && p_2 >= '0')
  {
    ret |= (byte) ((p_2 - '0'));
  }
  else if (p_2 <= 'f' && p_2 >= 'a')
  {
    ret |= (byte) ((p_2 - 'a' + 10));
  }
  else if (p_2 <= 'F' && p_2 >= 'A')
  {
    ret |= (byte) ((p_2 - 'A' + 10));
  } else throw new ArgumentException("Char is not a hex digit: " + p_2, "p_2");

  return ret;
}

I tried some stuff with unsafe and moving the (clearly redundant) character-to-nibble if sequence to another method, but this was the fastest it got.

(I concede that this answers half the question. I felt that the string->byte[] conversion was underrepresented, while the byte[]->string angle seems to be well covered. Thus, this answer.)

1
  • 1
    For the followers of Knuth: I did this because I need to parse a few thousand hex strings every few minutes or so, so it's important that it be as fast as possible (in the inner loop, as it were). Tomalak's solution is not notably slower if many such parses are not occurring.
    – Ben Mosher
    May 22, 2012 at 17:01
8

Safe versions:

public static class HexHelper
{
    [System.Diagnostics.Contracts.Pure]
    public static string ToHex(this byte[] value)
    {
        if (value == null)
            throw new ArgumentNullException("value");

        const string hexAlphabet = @"0123456789ABCDEF";

        var chars = new char[checked(value.Length * 2)];
        unchecked
        {
            for (int i = 0; i < value.Length; i++)
            {
                chars[i * 2] = hexAlphabet[value[i] >> 4];
                chars[i * 2 + 1] = hexAlphabet[value[i] & 0xF];
            }
        }
        return new string(chars);
    }

    [System.Diagnostics.Contracts.Pure]
    public static byte[] FromHex(this string value)
    {
        if (value == null)
            throw new ArgumentNullException("value");
        if (value.Length % 2 != 0)
            throw new ArgumentException("Hexadecimal value length must be even.", "value");

        unchecked
        {
            byte[] result = new byte[value.Length / 2];
            for (int i = 0; i < result.Length; i++)
            {
                // 0(48) - 9(57) -> 0 - 9
                // A(65) - F(70) -> 10 - 15
                int b = value[i * 2]; // High 4 bits.
                int val = ((b - '0') + ((('9' - b) >> 31) & -7)) << 4;
                b = value[i * 2 + 1]; // Low 4 bits.
                val += (b - '0') + ((('9' - b) >> 31) & -7);
                result[i] = checked((byte)val);
            }
            return result;
        }
    }
}

Unsafe versions For those who prefer performance and do not afraid of unsafeness. About 35% faster ToHex and 10% faster FromHex.

public static class HexUnsafeHelper
{
    [System.Diagnostics.Contracts.Pure]
    public static unsafe string ToHex(this byte[] value)
    {
        if (value == null)
            throw new ArgumentNullException("value");

        const string alphabet = @"0123456789ABCDEF";

        string result = new string(' ', checked(value.Length * 2));
        fixed (char* alphabetPtr = alphabet)
        fixed (char* resultPtr = result)
        {
            char* ptr = resultPtr;
            unchecked
            {
                for (int i = 0; i < value.Length; i++)
                {
                    *ptr++ = *(alphabetPtr + (value[i] >> 4));
                    *ptr++ = *(alphabetPtr + (value[i] & 0xF));
                }
            }
        }
        return result;
    }

    [System.Diagnostics.Contracts.Pure]
    public static unsafe byte[] FromHex(this string value)
    {
        if (value == null)
            throw new ArgumentNullException("value");
        if (value.Length % 2 != 0)
            throw new ArgumentException("Hexadecimal value length must be even.", "value");

        unchecked
        {
            byte[] result = new byte[value.Length / 2];
            fixed (char* valuePtr = value)
            {
                char* valPtr = valuePtr;
                for (int i = 0; i < result.Length; i++)
                {
                    // 0(48) - 9(57) -> 0 - 9
                    // A(65) - F(70) -> 10 - 15
                    int b = *valPtr++; // High 4 bits.
                    int val = ((b - '0') + ((('9' - b) >> 31) & -7)) << 4;
                    b = *valPtr++; // Low 4 bits.
                    val += (b - '0') + ((('9' - b) >> 31) & -7);
                    result[i] = checked((byte)val);
                }
            }
            return result;
        }
    }
}

BTW For benchmark testing initializing alphabet every time convert function called is wrong, alphabet must be const (for string) or static readonly (for char[]). Then alphabet-based conversion of byte[] to string becomes as fast as byte manipulation versions.

And of course test must be compiled in Release (with optimization) and with debug option "Suppress JIT optimization" turned off (same for "Enable Just My Code" if code must be debuggable).

8

From Microsoft's developers, a nice, simple conversion:

public static string ByteArrayToString(byte[] ba) 
{
    // Concatenate the bytes into one long string
    return ba.Aggregate(new StringBuilder(32),
                            (sb, b) => sb.Append(b.ToString("X2"))
                            ).ToString();
}

While the above is clean and compact, performance junkies will scream about it using enumerators. You can get peak performance with an improved version of Tomalak's original answer:

public static string ByteArrayToString(byte[] ba)   
{   
   StringBuilder hex = new StringBuilder(ba.Length * 2);   

   for(int i=0; i < ba.Length; i++)       // <-- Use for loop is faster than foreach   
       hex.Append(ba[i].ToString("X2"));   // <-- ToString is faster than AppendFormat   

   return hex.ToString();   
} 

This is the fastest of all the routines I've seen posted here so far. Don't just take my word for it... performance test each routine and inspect its CIL code for yourself.

1
  • 3
    The iterator is not the main problem of this code. You should benchmark b.ToSting("X2").
    – dolmen
    Aug 20, 2013 at 23:49
7

Inverse function for Waleed Eissa code (Hex String To Byte Array):

    public static byte[] HexToBytes(this string hexString)        
    {
        byte[] b = new byte[hexString.Length / 2];            
        char c;
        for (int i = 0; i < hexString.Length / 2; i++)
        {
            c = hexString[i * 2];
            b[i] = (byte)((c < 0x40 ? c - 0x30 : (c < 0x47 ? c - 0x37 : c - 0x57)) << 4);
            c = hexString[i * 2 + 1];
            b[i] += (byte)(c < 0x40 ? c - 0x30 : (c < 0x47 ? c - 0x37 : c - 0x57));
        }

        return b;
    }

Waleed Eissa function with lower case support:

    public static string BytesToHex(this byte[] barray, bool toLowerCase = true)
    {
        byte addByte = 0x37;
        if (toLowerCase) addByte = 0x57;
        char[] c = new char[barray.Length * 2];
        byte b;
        for (int i = 0; i < barray.Length; ++i)
        {
            b = ((byte)(barray[i] >> 4));
            c[i * 2] = (char)(b > 9 ? b + addByte : b + 0x30);
            b = ((byte)(barray[i] & 0xF));
            c[i * 2 + 1] = (char)(b > 9 ? b + addByte : b + 0x30);
        }

        return new string(c);
    }
7

.NET 5 has added the Convert.ToHexString method.

For those using an older version of .NET

internal static class ByteArrayExtensions
{
    
    public static string ToHexString(this byte[] bytes, Casing casing = Casing.Upper)
    {
        Span<char> result = stackalloc char[0];
        if (bytes.Length > 16)
        {
            var array = new char[bytes.Length * 2];
            result = array.AsSpan();
        }
        else
        {
            result = stackalloc char[bytes.Length * 2];
        }

        int pos = 0;
        foreach (byte b in bytes)
        {
            ToCharsBuffer(b, result, pos, casing);
            pos += 2;
        }

        return result.ToString();
    }

    private static void ToCharsBuffer(byte value, Span<char> buffer, int startingIndex = 0, Casing casing = Casing.Upper)
    {
        uint difference = (((uint)value & 0xF0U) << 4) + ((uint)value & 0x0FU) - 0x8989U;
        uint packedResult = ((((uint)(-(int)difference) & 0x7070U) >> 4) + difference + 0xB9B9U) | (uint)casing;

        buffer[startingIndex + 1] = (char)(packedResult & 0xFF);
        buffer[startingIndex] = (char)(packedResult >> 8);
    }
}

public enum Casing : uint
{
    // Output [ '0' .. '9' ] and [ 'A' .. 'F' ].
    Upper = 0,

    // Output [ '0' .. '9' ] and [ 'a' .. 'f' ].
    Lower = 0x2020U,
}

Adapted from the .NET repository https://github.com/dotnet/runtime/blob/v5.0.3/src/libraries/System.Private.CoreLib/src/System/Convert.cs https://github.com/dotnet/runtime/blob/v5.0.3/src/libraries/Common/src/System/HexConverter.cs

7

Converting byte[] to a hexadecimal string - performance analysis

Updated on: 2022-04-17

Since .NET 5 you should use Convert.ToHexString(bytes[])!

using System;
string result = Convert.ToHexString(bytesToConvert);

About this leaderboard and the benchmark

The comparison from Thymine seems to be outdated and incomplete, especially after .NET 5 with its Convert.ToHexString, so I decided to ~~fall into the bytes to hex string rabbit hole~~ create a new, updated comparison with more methods from answers to both of these two questions.

I went with BenchamrkDotNet instead of a custom-made benchmarking script, which will, hopefully, make the result more accurate.
Remember that micro-benchmarking won't ever represent the actual situation, and you should do your tests.

I ran these benchmarks on a Linux with Kernel 5.15.32 on an AMD Ryzen 5800H with 2x8 GB DDR4 @ 2133 MHz.
Be aware that the whole benchmark might take a lot of time to complete - around 40 minutes on my machine.

UPPERCASE (capitalized) vs lowercase output

All methods mentioned (unless stated otherwise) focus on UPPERCASE output only. That means the output will look like B33F69, not b33f69.

The output from Convert.ToHexString is always uppercase. Still, thankfully there isn't any significant performance drop when paired with ToLower(), although both unsafe methods will be faster if that's your concern.

Making the string lowercase efficiently might be a challenge in some methods (especially the ones with bit operators magic), but in most, it's enough to change a parameter X2 to x2 or change the letters from uppercase to lowercase in a mapping.

Leaderboard

It is sorted by Mean N=100. The reference point is the StringBuilderForEachByte method.

Method (means are in nanoseconds) Mean N=10 Ratio N=10 Mean N=100 Ratio N=100 Mean N=500 Ratio N=500 Mean N=1k Ratio N=1k Mean N=10k Ratio N=10k Mean N=100k Ratio N=100k
StringBuilderAggregateBytesAppendFormat 364.92 1.48 3,680.00 1.74 18,928.33 1.86 38,362.94 1.87 380,994.74 1.72 42,618,861.57 1.62
StringBuilderForEachAppendFormat 309.59 1.26 3,203.11 1.52 20,775.07 2.04 41,398.07 2.02 426,839.96 1.93 37,220,750.15 1.41
StringJoinSelect 310.84 1.26 2,765.91 1.31 13,549.12 1.33 28,691.16 1.40 304,163.97 1.38 63,541,601.12 2.41
StringConcatSelect 301.34 1.22 2,733.64 1.29 14,449.53 1.42 29,174.83 1.42 307,196.94 1.39 32,877,994.95 1.25
StringJoinArrayConvertAll 279.21 1.13 2,608.71 1.23 13,305.96 1.30 27,207.12 1.32 295,589.61 1.34 62,950,871.38 2.39
StringBuilderAggregateBytesAppend 276.18 1.12 2,599.62 1.23 12,788.11 1.25 26,043.54 1.27 255,389.06 1.16 27,664,344.41 1.05
StringConcatArrayConvertAll 244.81 0.99 2,361.08 1.12 11,881.18 1.16 23,709.21 1.15 265,197.33 1.20 56,044,744.44 2.12
StringBuilderForEachByte 246.09 1.00 2,112.77 1.00 10,200.36 1.00 20,540.77 1.00 220,993.95 1.00 26,387,941.13 1.00
StringBuilderForEachBytePreAllocated 213.85 0.87 1,897.19 0.90 9,340.66 0.92 19,142.27 0.93 204,968.88 0.93 24,902,075.81 0.94
BitConverterReplace 140.09 0.57 1,207.74 0.57 6,170.46 0.60 12,438.23 0.61 145,022.35 0.66 17,719,082.72 0.67
LookupPerNibble 63.78 0.26 421.75 0.20 1,978.22 0.19 3,957.58 0.19 35,358.21 0.16 4,993,649.91 0.19
LookupAndShift 53.22 0.22 311.56 0.15 1,461.15 0.14 2,924.11 0.14 26,180.11 0.12 3,771,827.62 0.14
WhilePropertyLookup 41.83 0.17 308.59 0.15 1,473.10 0.14 2,925.66 0.14 28,440.28 0.13 5,060,341.10 0.19
LookupAndShiftAlphabetArray 37.06 0.15 290.96 0.14 1,387.01 0.14 3,087.86 0.15 29,883.54 0.14 5,136,607.61 0.19
ByteManipulationDecimal 35.29 0.14 251.69 0.12 1,180.38 0.12 2,347.56 0.11 22,731.55 0.10 4,645,593.05 0.18
ByteManipulationHexMultiply 35.45 0.14 235.22 0.11 1,342.50 0.13 2,661.25 0.13 25,810.54 0.12 7,833,116.68 0.30
ByteManipulationHexIncrement 36.43 0.15 234.31 0.11 1,345.38 0.13 2,737.89 0.13 26,413.92 0.12 7,820,224.57 0.30
WhileLocalLookup 42.03 0.17 223.59 0.11 1,016.93 0.10 1,979.24 0.10 19,360.07 0.09 4,150,234.71 0.16
LookupAndShiftAlphabetSpan 30.00 0.12 216.51 0.10 1,020.65 0.10 2,316.99 0.11 22,357.13 0.10 4,580,277.95 0.17
LookupAndShiftAlphabetSpanMultiply 29.04 0.12 207.38 0.10 985.94 0.10 2,259.29 0.11 22,287.12 0.10 4,563,518.13 0.17
LookupPerByte 32.45 0.13 205.84 0.10 951.30 0.09 1,906.27 0.09 18,311.03 0.08 3,908,692.66 0.15
LookupSpanPerByteSpan 25.69 0.10 184.29 0.09 863.79 0.08 2,035.55 0.10 19,448.30 0.09 4,086,961.29 0.15
LookupPerByteSpan 27.03 0.11 184.26 0.09 866.03 0.08 2,005.34 0.10 19,760.55 0.09 4,192,457.14 0.16
Lookup32SpanUnsafeDirect 16.90 0.07 99.20 0.05 436.66 0.04 895.23 0.04 8,266.69 0.04 1,506,058.05 0.06
Lookup32UnsafeDirect 16.51 0.07 98.64 0.05 436.49 0.04 878.28 0.04 8,278.18 0.04 1,753,655.67 0.07
ConvertToHexString 19.27 0.08 64.83 0.03 295.15 0.03 585.86 0.03 5,445.73 0.02 1,478,363.32 0.06
ConvertToHexString.ToLower() 45.66 - 175.16 - 787.86 - 1,516.65 - 13,939.71 - 2,620,046.76 -

Conclusion

The method ConvertToHexString is undoubtedly the fastest out there, and in my perspective, it should always be used if you have the option - it's swift and clean.

using System;

string result = Convert.ToHexString(bytesToConvert);

If not, I decided to highlight two other methods I consider worthy below. I decided not to highlight unsafe methods since such code might be not only, well, unsafe, but most projects I've worked with don't allow such code.

Worthy mentions

The first one is LookupPerByteSpan.
The code is almost identical to the code in LookupPerByte by CodesInChaos from this answer. This one is the fastest not-unsafe method benchmarked. The difference between the original and this one is using stack allocation for shorter inputs (up to 512 bytes). This makes this method around 10 % faster on these inputs but around 5 % slower on larger ones. Since most of the data I work with is shorter than larger, I opted for this one. LookupSpanPerByteSpan is also very fast, but the code size of its ReadOnlySpan<byte> mapping is too large compared to all other methods.

private static readonly uint[] Lookup32 = Enumerable.Range(0, 256).Select(i =>
{
    string s = i.ToString("X2");
    return s[0] + ((uint)s[1] << 16);
}).ToArray();

public string ToHexString(byte[] bytes)
{
    var result = bytes.Length * 2 <= 1024
        ? stackalloc char[bytes.Length * 2]
        : new char[bytes.Length * 2];

    for (int i = 0; i < bytes.Length; i++)
    {
        var val = Lookup32[bytes[i]];
        result[2 * i] = (char)val;
        result[2 * i + 1] = (char)(val >> 16);
    }

    return new string(result);
}

The second one is LookupAndShiftAlphabetSpanMultiply. First, I would like to mention that this one is my creation. However, I believe this method is not only pretty fast but also simple to understand. The speed comes from a change that happened in C# 7.3, where declared ReadOnlySpan<byte> methods returning a constant array initialization - new byte {1, 2, 3, ...} - are compiled as the program's static data, therefore omitting a redundant memory. [source]

private static ReadOnlySpan<byte> HexAlphabetSpan => new[]
{
    (byte)'0', (byte)'1', (byte)'2', (byte)'3',
    (byte)'4', (byte)'5', (byte)'6', (byte)'7',
    (byte)'8', (byte)'9', (byte)'A', (byte)'B',
    (byte)'C', (byte)'D', (byte)'E', (byte)'F'
};

public static string ToHexString(byte[] bytes)
{
    var res = bytes.Length * 2 <= 1024 ? stackalloc char[bytes.Length * 2] : new char[bytes.Length * 2];

    for (var i = 0; i < bytes.Length; ++i)
    {
        var j = i * 2;
        res[j] = (char)HexAlphabetSpan[bytes[i] >> 4];
        res[j + 1] = (char)HexAlphabetSpan[bytes[i] & 0xF];
    }

    return new string(res);
}

Source code

The source code for all methods, the benchmark, and this answer can be found here as a Gist on my GitHub.

1
  • 1
    The ToHexString method is very useful. It seems FromHexString does the reverse operation
    – user4779
    Jun 20 at 15:30
6

Extension methods (disclaimer: completely untested code, BTW...):

public static class ByteExtensions
{
    public static string ToHexString(this byte[] ba)
    {
        StringBuilder hex = new StringBuilder(ba.Length * 2);

        foreach (byte b in ba)
        {
            hex.AppendFormat("{0:x2}", b);
        }
        return hex.ToString();
    }
}

etc.. Use either of Tomalak's three solutions (with the last one being an extension method on a string).

1
  • You should probably test the code before you offer it up for a question like this.
    – jww
    Feb 16, 2017 at 19:08
6

Fastest method for old school people... miss you pointers

    static public byte[] HexStrToByteArray(string str)
    {
        byte[] res = new byte[(str.Length % 2 != 0 ? 0 : str.Length / 2)]; //check and allocate memory
        for (int i = 0, j = 0; j < res.Length; i += 2, j++) //convert loop
            res[j] = (byte)((str[i] % 32 + 9) % 25 * 16 + (str[i + 1] % 32 + 9) % 25);
        return res;
    }
4

And for inserting into an SQL string (if you're not using command parameters):

public static String ByteArrayToSQLHexString(byte[] Source)
{
    return = "0x" + BitConverter.ToString(Source).Replace("-", "");
}
1
  • if Source == null or Source.Length == 0 we have a problem sir! Jun 7, 2019 at 17:37
4

In terms of speed, this seems to be better than anything here:

  public static string ToHexString(byte[] data) {
    byte b;
    int i, j, k;
    int l = data.Length;
    char[] r = new char[l * 2];
    for (i = 0, j = 0; i < l; ++i) {
      b = data[i];
      k = b >> 4;
      r[j++] = (char)(k > 9 ? k + 0x37 : k + 0x30);
      k = b & 15;
      r[j++] = (char)(k > 9 ? k + 0x37 : k + 0x30);
    }
    return new string(r);
  }
4

I did not get the code you suggested to work, Olipro. hex[i] + hex[i+1] apparently returned an int.

I did, however have some success by taking some hints from Waleeds code and hammering this together. It's ugly as hell but it seems to work and performs at 1/3 of the time compared to the others according to my tests (using patridges testing mechanism). Depending on input size. Switching around the ?:s to separate out 0-9 first would probably yield a slightly faster result since there are more numbers than letters.

public static byte[] StringToByteArray2(string hex)
{
    byte[] bytes = new byte[hex.Length/2];
    int bl = bytes.Length;
    for (int i = 0; i < bl; ++i)
    {
        bytes[i] = (byte)((hex[2 * i] > 'F' ? hex[2 * i] - 0x57 : hex[2 * i] > '9' ? hex[2 * i] - 0x37 : hex[2 * i] - 0x30) << 4);
        bytes[i] |= (byte)(hex[2 * i + 1] > 'F' ? hex[2 * i + 1] - 0x57 : hex[2 * i + 1] > '9' ? hex[2 * i + 1] - 0x37 : hex[2 * i + 1] - 0x30);
    }
    return bytes;
}
4

This version of ByteArrayToHexViaByteManipulation could be faster.

From my reports:

  • ByteArrayToHexViaByteManipulation3: 1,68 average ticks (over 1000 runs), 17,5X
  • ByteArrayToHexViaByteManipulation2: 1,73 average ticks (over 1000 runs), 16,9X
  • ByteArrayToHexViaByteManipulation: 2,90 average ticks (over 1000 runs), 10,1X
  • ByteArrayToHexViaLookupAndShift: 3,22 average ticks (over 1000 runs), 9,1X
  • ...

    static private readonly char[] hexAlphabet = new char[]
        {'0','1','2','3','4','5','6','7','8','9','A','B','C','D','E','F'};
    static string ByteArrayToHexViaByteManipulation3(byte[] bytes)
    {
        char[] c = new char[bytes.Length * 2];
        byte b;
        for (int i = 0; i < bytes.Length; i++)
        {
            b = ((byte)(bytes[i] >> 4));
            c[i * 2] = hexAlphabet[b];
            b = ((byte)(bytes[i] & 0xF));
            c[i * 2 + 1] = hexAlphabet[b];
        }
        return new string(c);
    }
    

And I think this one is an optimization:

    static private readonly char[] hexAlphabet = new char[]
        {'0','1','2','3','4','5','6','7','8','9','A','B','C','D','E','F'};
    static string ByteArrayToHexViaByteManipulation4(byte[] bytes)
    {
        char[] c = new char[bytes.Length * 2];
        for (int i = 0, ptr = 0; i < bytes.Length; i++, ptr += 2)
        {
            byte b = bytes[i];
            c[ptr] = hexAlphabet[b >> 4];
            c[ptr + 1] = hexAlphabet[b & 0xF];
        }
        return new string(c);
    }
4

I'll enter this bit fiddling competition as I have an answer that also uses bit-fiddling to decode hexadecimals. Note that using character arrays may be even faster as calling StringBuilder methods will take time as well.

public static String ToHex (byte[] data)
{
    int dataLength = data.Length;
    // pre-create the stringbuilder using the length of the data * 2, precisely enough
    StringBuilder sb = new StringBuilder (dataLength * 2);
    for (int i = 0; i < dataLength; i++) {
        int b = data [i];

        // check using calculation over bits to see if first tuple is a letter
        // isLetter is zero if it is a digit, 1 if it is a letter
        int isLetter = (b >> 7) & ((b >> 6) | (b >> 5)) & 1;

        // calculate the code using a multiplication to make up the difference between
        // a digit character and an alphanumerical character
        int code = '0' + ((b >> 4) & 0xF) + isLetter * ('A' - '9' - 1);
        // now append the result, after casting the code point to a character
        sb.Append ((Char)code);

        // do the same with the lower (less significant) tuple
        isLetter = (b >> 3) & ((b >> 2) | (b >> 1)) & 1;
        code = '0' + (b & 0xF) + isLetter * ('A' - '9' - 1);
        sb.Append ((Char)code);
    }
    return sb.ToString ();
}

public static byte[] FromHex (String hex)
{

    // pre-create the array
    int resultLength = hex.Length / 2;
    byte[] result = new byte[resultLength];
    // set validity = 0 (0 = valid, anything else is not valid)
    int validity = 0;
    int c, isLetter, value, validDigitStruct, validDigit, validLetterStruct, validLetter;
    for (int i = 0, hexOffset = 0; i < resultLength; i++, hexOffset += 2) {
        c = hex [hexOffset];

        // check using calculation over bits to see if first char is a letter
        // isLetter is zero if it is a digit, 1 if it is a letter (upper & lowercase)
        isLetter = (c >> 6) & 1;

        // calculate the tuple value using a multiplication to make up the difference between
        // a digit character and an alphanumerical character
        // minus 1 for the fact that the letters are not zero based
        value = ((c & 0xF) + isLetter * (-1 + 10)) << 4;

        // check validity of all the other bits
        validity |= c >> 7; // changed to >>, maybe not OK, use UInt?

        validDigitStruct = (c & 0x30) ^ 0x30;
        validDigit = ((c & 0x8) >> 3) * (c & 0x6);
        validity |= (isLetter ^ 1) * (validDigitStruct | validDigit);

        validLetterStruct = c & 0x18;
        validLetter = (((c - 1) & 0x4) >> 2) * ((c - 1) & 0x2);
        validity |= isLetter * (validLetterStruct | validLetter);

        // do the same with the lower (less significant) tuple
        c = hex [hexOffset + 1];
        isLetter = (c >> 6) & 1;
        value ^= (c & 0xF) + isLetter * (-1 + 10);
        result [i] = (byte)value;

        // check validity of all the other bits
        validity |= c >> 7; // changed to >>, maybe not OK, use UInt?

        validDigitStruct = (c & 0x30) ^ 0x30;
        validDigit = ((c & 0x8) >> 3) * (c & 0x6);
        validity |= (isLetter ^ 1) * (validDigitStruct | validDigit);

        validLetterStruct = c & 0x18;
        validLetter = (((c - 1) & 0x4) >> 2) * ((c - 1) & 0x2);
        validity |= isLetter * (validLetterStruct | validLetter);
    }

    if (validity != 0) {
        throw new ArgumentException ("Hexadecimal encoding incorrect for input " + hex);
    }

    return result;
}

Converted from Java code.

2
  • 1
    Hmm, I really should optimize this for Char[] and use Char internally instead of ints... Jan 20, 2014 at 23:46
  • 1
    For C#, initializing the variables where they are used, instead of outside the loop, is probably preferred to let the compiler optimize. I get equivalent performance either way.
    – Peteter
    Jun 12, 2019 at 16:50
4

For performance I would go with drphrozens solution. A tiny optimization for the decoder could be to use a table for either char to get rid of the "<< 4".

Clearly the two method calls are costly. If some kind of check is made either on input or output data (could be CRC, checksum or whatever) the if (b == 255)... could be skipped and thereby also the method calls altogether.

Using offset++ and offset instead of offset and offset + 1 might give some theoretical benefit but I suspect the compiler handles this better than me.

private static readonly byte[] LookupTableLow = new byte[] {
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF
};

private static readonly byte[] LookupTableHigh = new byte[] {
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0x00, 0x10, 0x20, 0x30, 0x40, 0x50, 0x60, 0x70, 0x80, 0x90, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xA0, 0xB0, 0xC0, 0xD0, 0xE0, 0xF0, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xA0, 0xB0, 0xC0, 0xD0, 0xE0, 0xF0, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF
};

private static byte LookupLow(char c)
{
  var b = LookupTableLow[c];
  if (b == 255)
    throw new IOException("Expected a hex character, got " + c);
  return b;
}

private static byte LookupHigh(char c)
{
  var b = LookupTableHigh[c];
  if (b == 255)
    throw new IOException("Expected a hex character, got " + c);
  return b;
}

public static byte ToByte(char[] chars, int offset)
{
  return (byte)(LookupHigh(chars[offset++]) | LookupLow(chars[offset]));
}

This is just off the top of my head and has not been tested or benchmarked.

4

Tests: Hex String To Byte Array

I noticed that most of tests were performed on functions that convert Bytes array to Hex string. So, in this post I will focus on the other side: functions that convert Hex String To Byte Array. If you are interested in result only, you could skip down to Summary section. The test code file is supplied at the end of the post.

Labels

I would like to name the function from the accepted answer (by Tomalak) StringToByteArrayV1, or to shortcut it to V1. rest of functions will be named in same way: V2, V3, V4, ..., etc.

Index of Participating Functions

Correctness Test

I have tested correctness by passing all 256 possible values of 1 byte, then checking output to see if correct. Result:

  • V18 has issue with strings start with "00" (see Roger Stewart comment on it ). other than that it passes all tests.
  • if hex string alphabet letters are uppercase: all functions successfully passed
  • if hex string alphabet letters are lowercase then the following functions failed: V5_1, V5_2, v7, V8, V15, V19

note: V5_3 solves this issue (of V5_1 and V5_2)

Performance Test

I have done performance tests using Stopwatch class.

  • Performance for long strings
input length: 10,000,000 bytes
runs: 100
average elapsed time per run:
V1 = 136.4ms
V2 = 104.5ms
V3 = 22.0ms
V4 = 9.9ms
V5_1 = 10.2ms
V5_2 = 9.0ms
V5_3 = 9.3ms
V6 = 18.3ms
V7 = 9.8ms
V8 = 8.8ms
V9 = 10.2ms
V10 = 19.0ms
V11 = 12.2ms
V12 = 27.4ms
V13 = 21.8ms
V14 = 12.0ms
V15 = 14.9ms
V16 = 15.3ms
V17 = 9.5ms
V18 got excluded from this test, because it was very slow when using very long string
V19 = 222.8ms
V20 = 66.0ms
V21 = 15.4ms

V1 average ticks per run: 1363529.4
V2 is more fast than V1 by: 1.3 times (ticks ratio)
V3 is more fast than V1 by: 6.2 times (ticks ratio)
V4 is more fast than V1 by: 13.8 times (ticks ratio)
V5_1 is more fast than V1 by: 13.3 times (ticks ratio)
V5_2 is more fast than V1 by: 15.2 times (ticks ratio)
V5_3 is more fast than V1 by: 14.8 times (ticks ratio)
V6 is more fast than V1 by: 7.4 times (ticks ratio)
V7 is more fast than V1 by: 13.9 times (ticks ratio)
V8 is more fast than V1 by: 15.4 times (ticks ratio)
V9 is more fast than V1 by: 13.4 times (ticks ratio)
V10 is more fast than V1 by: 7.2 times (ticks ratio)
V11 is more fast than V1 by: 11.1 times (ticks ratio)
V12 is more fast than V1 by: 5.0 times (ticks ratio)
V13 is more fast than V1 by: 6.3 times (ticks ratio)
V14 is more fast than V1 by: 11.4 times (ticks ratio)
V15 is more fast than V1 by: 9.2 times (ticks ratio)
V16 is more fast than V1 by: 8.9 times (ticks ratio)
V17 is more fast than V1 by: 14.4 times (ticks ratio)
V19 is more SLOW than V1 by: 1.6 times (ticks ratio)
V20 is more fast than V1 by: 2.1 times (ticks ratio)
V21 is more fast than V1 by: 8.9 times (ticks ratio)
  • Performance of V18 for long strings
V18 took long time at the previous test, 
so let's decrease length for it:  
input length: 1,000,000 bytes
runs: 100
average elapsed time per run: V1 = 14.1ms , V18 = 146.7ms
V1 average ticks per run: 140630.3
V18 is more SLOW than V1 by: 10.4 times (ticks ratio)
  • Performance for short strings
input length: 100 byte
runs: 1,000,000
V1 average ticks per run: 14.6
V2 is more fast than V1 by: 1.4 times (ticks ratio)
V3 is more fast than V1 by: 5.9 times (ticks ratio)
V4 is more fast than V1 by: 15.7 times (ticks ratio)
V5_1 is more fast than V1 by: 15.1 times (ticks ratio)
V5_2 is more fast than V1 by: 18.4 times (ticks ratio)
V5_3 is more fast than V1 by: 16.3 times (ticks ratio)
V6 is more fast than V1 by: 5.3 times (ticks ratio)
V7 is more fast than V1 by: 15.7 times (ticks ratio)
V8 is more fast than V1 by: 18.0 times (ticks ratio)
V9 is more fast than V1 by: 15.5 times (ticks ratio)
V10 is more fast than V1 by: 7.8 times (ticks ratio)
V11 is more fast than V1 by: 12.4 times (ticks ratio)
V12 is more fast than V1 by: 5.3 times (ticks ratio)
V13 is more fast than V1 by: 5.2 times (ticks ratio)
V14 is more fast than V1 by: 13.4 times (ticks ratio)
V15 is more fast than V1 by: 9.9 times (ticks ratio)
V16 is more fast than V1 by: 9.2 times (ticks ratio)
V17 is more fast than V1 by: 16.2 times (ticks ratio)
V18 is more fast than V1 by: 1.1 times (ticks ratio)
V19 is more SLOW than V1 by: 1.6 times (ticks ratio)
V20 is more fast than V1 by: 1.9 times (ticks ratio)
V21 is more fast than V1 by: 11.4 times (ticks ratio)

Testing Code

It is good idea to read Disclaimer section down here in this post, before using any from the following code https://github.com/Ghosticollis/performance-tests/blob/main/MTestPerformance.cs

Summary

I recommend using one of the following functions, because of the good performance, and support both upper and lower case:

Here is the final shape of V5_3:

static byte[] HexStringToByteArrayV5_3(string hexString) {
    int hexStringLength = hexString.Length;
    byte[] b = new byte[hexStringLength / 2];
    for (int i = 0; i < hexStringLength; i += 2) {
        int topChar = hexString[i];
        topChar = (topChar > 0x40 ? (topChar & ~0x20) - 0x37 : topChar - 0x30) << 4;
        int bottomChar = hexString[i + 1];
        bottomChar = bottomChar > 0x40 ? (bottomChar & ~0x20) - 0x37 : bottomChar - 0x30;
        b[i / 2] = (byte)(topChar + bottomChar);
    }
    return b;
}

Disclaimer

WARNING: I don't have proper knowledge in testing. The main purpose of these primitive tests is to give quick overview on what might be good from all of posted functions. If you need accurate results, please use proper testing tools.

Finally, I would like to say I am new to be active at stackoverflow, sorry if my post is lacking. comments to enhance this post would be appreciated.

1
  • 1
    Wow, that's a lot of effort! Jul 7, 2021 at 16:55

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