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,
-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
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 << 56) |
((ulong)bigEndianBinary << 48) |
((ulong)bigEndianBinary << 40) |
((ulong)bigEndianBinary << 32) |
((ulong)bigEndianBinary << 24) |
((ulong)bigEndianBinary << 16) |
((ulong)bigEndianBinary << 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.