# How to Generate Unique Number of 8 digits?

I am using this code to generate a 8 digit unique number.

``````byte[] buffer = Guid.NewGuid().ToByteArray();
return BitConverter.ToUInt32(buffer, 8).ToString();
``````

Does this code really generate a unique number or might it repeat the same number again?

• You might need to discuss your requirements further; why won't `static counter=0; counter++; sprintf(buffer,"%8d", counter);` kind of code do the job? Does it have to be generated from a GUID? Should there be any kind of distribution of numbers? May 23, 2011 at 22:13
• it's not necessary to use GUID. Only reason i use GUID becasue i have find some good articale about GUID and that's why i use GUID.But if you have any other way to generate unique number please let me know.
– dev
May 23, 2011 at 22:18
• A GUID is not unique, it's just very very unlikely to produce two identical sequences. By reducing the GUID to an 8-digit number you significantly increase the chance of a repeat. Please further explain your need for a unique number; if you want a random number you should not use GUID, and if you want a primary key value you should probably just increase a counter to make sure you use the maximum range of numbers available before having to repeat yourself (which you will know because it will throw an OverflowException). May 23, 2011 at 22:21
• None of the answers thus far seem to address the uniqueness requirement of the question. May 23, 2011 at 22:30
• using jeff.aaron.ca/cgi-bin/birthday, you get 40% chance of a collision with only 10,000 entries in a number space of 8 digits. But still, we don't know what the intention for the digits are. May 23, 2011 at 22:43

A GUID is not just a random number; it's composed of segments. Some of the segments will not change at all if the guid is generated on the same computer. By using only 64-bits of the original 128-bits you are breaking the structure of the guid and most likely breaking the uniqueness of the generated number.

This question has more info on uniqueness of guids, check this link as well for more info on why it's bad to use only part of a guid if you need a unique number.

If you need to limit duplication to an absolute minimum, an incremental counter will give you what you need. If your application is using multiple threads or processes, a counter may be hard (or even impossible) to implement correctly.

This is the realm that guids were designed for, to be unique across multiple machines. So if uniqueness across machines is a requirement you should use guids. The whole guid.

• You'll hit the same random number again sooner than just counting from 0 to 99999999. May 23, 2011 at 22:40
• That's not exactly right. Version 4 GUIDs (which are generated by `Guid.NewGuid()`) have exactly 6 bits fixed, the rest is pseudo-random. The old version of GUIDs behaved the way you describe. May 23, 2011 at 22:44
• I won't vote this down, but a random number generator will still yield duplicates. Either you need a function that guarantees non-duplicate enumeration of all values, or you need memory. May 23, 2011 at 23:12

Any random sequence is bound to have some collisions. It's just a matter of when. Using the birthday paradox formula, with 100,000,000 possible values (8 digits), the chance that you will have a collision with only 10,000 elements is around 40% and 99% with 30,000 elements. (see here for a calculator).

If you really need a random sequence, you should not use a GUID for this purpose. GUIDs have very specific structure and should only be taken as a whole. It is easy enough to create a random 8 digit sequence generator. This should give you an 8 digit sequence:

`````` public string Get8Digits()
{
var bytes = new byte[4];
var rng = RandomNumberGenerator.Create();
rng.GetBytes(bytes);
uint random = BitConverter.ToUInt32(bytes, 0) % 100000000;
return String.Format("{0:D8}", random);
}
``````

You can also take the RandomNumberGenerator and place it somewhere to avoid creating a new one everytime.

• Really this is never repeative. or it repeat after 2 or 4 year...... please tell.... Jul 9, 2015 at 8:08

Here is another version

``````public static string GetFormNumber()
{
byte[] buffer = Guid.NewGuid().ToByteArray();
var FormNumber = BitConverter.ToUInt32(buffer, 0) ^ BitConverter.ToUInt32(buffer, 4) ^ BitConverter.ToUInt32(buffer, 8) ^ BitConverter.ToUInt32(buffer, 12);
return FormNumber.ToString("X");

}
``````

it assures to be unique!

• Generated it for 1000000 records using linqpad and got 119 duplicates. Generated it a few more times for the same number of records and the duplicate count is often with 110 and 200. Still impressive though. If only there was a way to remove the duplicates without the need to compare with the previously saved values. Code used is `Enumerable.Range(1,1000000).Select(x=>GetFormNumber()).GroupBy (x => x).Where(x=>x.Count()>1).Dump();` May 30, 2015 at 19:47

My first answer did not address the uniqueness problem. My second one does:

``````static int counter;
public static int GetUniqueNumber()
{
return counter++;
}
``````

If you want to have unique numbers across app restarts, you need to persist the value of counter to a database or somewhere else after each and every GetUniqueNumber call.

• To further explain Hans comment, interlock is necessary in a multithreaded environment because 2 threads could wind up with the same unique number as addition is not an atomic operation. Declaring counter volatile would also solve this problem. Feb 8, 2013 at 15:55
• @WilliamMorrison if i `lock` the counter that would prevent the threads, wouldn't it?
– Sid
Jun 22, 2017 at 16:29
• @Sid You are correct, that would also prevent the issue. Jun 23, 2017 at 18:08

The range of values is too small. An incrementing counter is the best solution, like in an ERP system - you set the first customer number to 1000 and the next one is 1001, 1002,...,99999999. Otherwise, if you get a random number (or part of GUID) from these, you'll hit the same number again. Depending on your app, sooner or later but it's guaranteed to happen sooner than just iterating over them.

This method will generate a random string, it doesn't rely on the Random method and also is far better than the guid approch :

``````public static string gen_Digits(int length)
{
var rndDigits = new System.Text.StringBuilder().Insert(0, "0123456789", length).ToString().ToCharArray();
return string.Join("", rndDigits.OrderBy(o => Guid.NewGuid()).Take(length));
}
``````

you can increase the length for less collision chance, but to have a 100% unique sequence you have to persist the old generated values and check the newly created value for uniquness.

If you want a unique number between 10000000 and 99999999, start an integer from 10000000 and just start incrementing it. Generating sequentially ordered numbers is no less random than any other generated sequence, and a whole lot easier to generate.

If you express the no as a combination of day( 2digit), hour(2digit), minute(2digit), second(2digit) and year ( 4 digit) , then it will be 12 digit but always unique no.

`````` DateTime _now = DateTime.Now;
string _dd = _now.ToString("dd"); //
string _mm = _now.ToString("MM");
string _yy = _now.ToString("yyyy");
string _hh = _now.Hour.ToString();
string _min = _now.Minute.ToString();
string _ss = _now.Second.ToString();

string _uniqueId= _dd+ _hh+ _mm+_min+_ss + _yy;
``````
• Year can be made of 2 digit , making the the total no. of 10 digit as there are a chance of matching 2 no. after 100 years. Jan 26, 2017 at 16:22
• Wonderful, but the OP said 8 digits Jan 26, 2017 at 16:29
• Calling this multiple times in the same second won't give you a unique id. Even adding microseconds will not guarantee this. Aug 21, 2018 at 9:13
• Yes that's true then you have to think of micro or nano according to the probability but if the unique no. is generated by a user click then I think one second is fine. Aug 23, 2018 at 8:42
``````System.Threading.Thread.Sleep(1);
long code = (long)DateTime.UtcNow.Subtract(new DateTime(2018, 1, 1, 0, 0, 0, DateTimeKind.Utc)).TotalMilliseconds;
``````

OR

``````System.Threading.Thread.Sleep(1000);
long code = (long)DateTime.UtcNow.Subtract(new DateTime(2018, 1, 1, 0, 0, 0, DateTimeKind.Utc)).TotalSeconds;
``````