What is the proper type for the rowversion (timestamp) data type?

I know it is 8 bytes but i cannot find a link in MSDN which tell if it is a signed or unsigned long.

which code should I use, does it even matter?

byte[] SqlTimeStamp;

long longConversion;
longConversion = BitConverter.ToInt64(SqlTimeStamp,0);
TimeStamp = BitConverter.GetBytes(longConversion);

ulong ulongConversion;
ulongConversion = BitConverter.ToUInt64(SqlTimeStamp,0);
TimeStamp = BitConverter.GetBytes(ulongConversion);
  • 1
    I'm a bit concerned that folks may get some subtly incorrect answers here on both the unsigned issue and the big-endian issue. Please see my answer.
    – jnm2
    Jul 1, 2016 at 16:21

4 Answers 4


It does matter. You want your comparison to have the same result as SQL Server's comparison. SQL Server uses unsigned comparisons on binary types:

select case when 0x0FFFFFFFFFFFFFFF < 0xFFFFFFFFFFFFFFFF then 'unsigned' else 'signed' end

If you do the same thing with long which is signed, 0xFFFFFFFFFFFFFFFF represents -1. That means your comparison will be incorrect; it won't match with the same comparison done in SQL Server.

What you definitely want is to use ulong where 0xFFFFFFFFFFFFFFFF is ulong.MaxValue.

Endianness is also important

Additionally, as Mark pointed out, BitConverter.GetUInt64 is not converting properly. Mark is not completely right- BitConverter is either big-endian or little-endian depending on the system it's running on. You can see this for yourself. Also, even if BitConverter was always little-endian, Array.Reverse is less performant with a heap allocation and byte-by-byte copying. BitConverter is just not semantically or practically the right tool for the job.

This is what you want:

static ulong BigEndianToUInt64(byte[] bigEndianBinary)
    return ((ulong)bigEndianBinary[0] << 56) |
           ((ulong)bigEndianBinary[1] << 48) |
           ((ulong)bigEndianBinary[2] << 40) |
           ((ulong)bigEndianBinary[3] << 32) |
           ((ulong)bigEndianBinary[4] << 24) |
           ((ulong)bigEndianBinary[5] << 16) |
           ((ulong)bigEndianBinary[6] <<  8) |

The cleanest solution

Update: If you use .NET Core 2.1 or later (or .NET Standard 2.1), you can use BinaryPrimitives.ReadUInt64BigEndian which is a perfect fit.

On .NET Framework, here is the solution I use: Timestamp.cs. Basically once you cast to Timestamp, you can't go wrong.

  • I did qualify it with "if you're running on an x86 family CPU...", all of which are little endian. Jul 3, 2016 at 16:40
  • I would hate for someone to assume it was the right idiom though. It's less efficient memory and CPU and less elegant. Plus someone will copy it on a big endian CPU one of these days- better just not to couple it to the CPU in the first place.
    – jnm2
    Jul 3, 2016 at 19:34
  • 1
    @jnm2 my +1, you're right, rowversion is stored as big-endian and your Timestamp class is pretty tidy for this purpose. I still wonder why rowversion is b.e. while bigint is obviously not... Jul 4, 2016 at 7:48
  • Thanks, good conversation. I have a guess at the reason, already replied here.
    – jnm2
    Jul 4, 2016 at 13:49
  • 1
    It's big endian and not CPU-dependent which is precisely what is wanted here. It's purer. And it's also not possible to do everything server-side. For example, comparing loaded entities.
    – jnm2
    Jul 4, 2016 at 20:45

Neither will work correctly for purposes of comparing timestamp/rowversion values, if you're running on an x86 family CPU, because of endian. The first byte of a timestamp is most significant, but not so for little endian integer types.

Call Array.Reverse(ts) before calling BitConverter.ToUInt64(ts), and for the other direction, after calling BitConverter.GetBytes(tsUInt64)

  • They are not in order of significance on a little endian CPU. These values are incremented for each row that's updated, therefore if you persist MAX(rowversion) for a given set of rows after performing updates, you can determine which rows have been updated by testing rowversion > persistedrowversion. As long as you leave the values in SQL the comparison evaluates correctly, but if you need to compare them in app code, like say a linq query, then you have to fixup the byte order to match CPU endian. Jun 10, 2015 at 23:07
  • Someone in another thread had a much more elegant solution, define a computed column in SQL that converts bin(8) to big_int. Likely somewhat faster and definitely less convoluted app code. Jun 12, 2015 at 18:32
  • Nice! Maybe not always applicable but pretty solution. If you still can find it please add link in your post Jun 12, 2015 at 19:17
  • BitConverter.ToUInt64 is little-endian or big-endian depending on the system. Better to do it in a portable way. Also more performant. See this answer.
    – jnm2
    Jul 1, 2016 at 16:18

Short answer: it doesn't matter but I'd choose UInt64.

Details: semantically it's equivalent to binary(8) so, strictly speaking, it's neither UInt64 nor Int64 but just a chunk of bytes (and in that way it should be managed). That said I'd choose UInt64 because it's an incrementing number to hold row version then (from a logic point of view) 0xFFFFFFFFFFFFFFFF should be greater than 0 and it's not true for Int64 (because 64 bits set to 1 give -1 and it's less than 0).

Edit: note that, for reasons known only in the innest SQL Server designers circle, ROWVERSION is big-endian (while - obviously - bigint is not) then you first need to reverse bytes, see this answer for a nice implementation.

  • It actually does matter! If you don't get this right, the result of your comparison will not match SQL Server's comparison. See this answer.
    – jnm2
    Jul 1, 2016 at 16:20
  • Sorry, that is not true. SQL Server allows < and > on binary. Your client-side logic should match SQL Server's logic exactly or it is buggy. Also, plenty of people filter on timestamp (binary(8)). It's an established practice. I just came from answering a different question about it and I'm in the middle of using it for the third time in an enterprise project.
    – jnm2
    Jul 1, 2016 at 17:18
  • Also, even if the fact that SQL Server has well-defined unsigned big-endian binary comparison operators doesn't convince you, what about the fact that SQL Server increments a binary(8) as though it was an unsigned big-endian int64? That's something you definitely need explicit knowledge of any time you deal with a timestamp column.
    – jnm2
    Jul 1, 2016 at 17:26
  • You saying that reminds me of a guy who said that numeric IDs in C# should disallow any operator except == and !=. I appreciated what he was after. Only problem is, < and > are still very useful for IDs if you ever need to get every unique pair of IDs. And using those comparisons in that case is absolutely legitimate. It's the purest thing to do. (Wish I could find the link to the blog post.)
    – jnm2
    Jul 1, 2016 at 17:28
  • 1
    Here's one possible logical reason. Big-endian binary and strings can be treated the same and compared lexicographically. On top of that, if rowversion was bigint instead, it would be signed which is a problem for simple comparisons on rowversions. That makes binary (lexicographical comparison) the perfect choice, and lexicographical comparison is what makes things big-endian.
    – jnm2
    Jul 4, 2016 at 13:44

I use this (updated):

private UInt64 GetUInt64ForRowVersion(byte[] rowVersion)
    byte[] rr = (byte[])rowVersion.Clone();
    if (BitConverter.IsLittleEndian) { Array.Reverse(rr); }
    return BitConverter.ToUInt64(rr, 0);
  • The most simplest and useful answer. Jul 17, 2018 at 11:01
  • DANGER: rowVersion getting mutated when using proposed solution, which tricks ChangeTracker to think that item got modified!
    – Igor B
    Jun 27, 2019 at 18:36
  • @IgorB the array is clone. What is the danager?
    – Assaf S.
    Jan 17, 2021 at 14:49

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