# Simple proof that GUID is not unique [closed]

I'd like to prove that a GUID is not unique in a simple test program. I expected the following code to run for hours, but it's not working. How can I make it work?

``````BigInteger begin = new BigInteger((long)0);
BigInteger end = new BigInteger("340282366920938463463374607431768211456",10);  //2^128
for(begin; begin<end; begin++)
Console.WriteLine(System.Guid.NewGuid().ToString());
``````

I'm using C#.

• As a software developer, what would you say if a user came to you and said "it's not working"? Nov 10, 2009 at 0:57
• Wait several trillion years. Nov 10, 2009 at 0:57
• Upmodded because this is the most amusing thing I've seen online today. Nov 10, 2009 at 1:06
• @jrockway - lol. I'm having troubling finding anything about this question that isn't fundamentally wrong. The longer I look at it, the funnier it gets. Nov 10, 2009 at 1:10
• It's only globally unique, so it's only unique on our planet. If you want a truly unique id you need to use a universally unique id (UUID). I assume that you're only interested in uniqueness within our universe. :-) Nov 10, 2009 at 1:40

Kai, I have provided a program that will do what you want using threads. It is licensed under the following terms: you must pay me \$0.0001 per hour per CPU core you run it on. Fees are payable at the end of each calendar month. Please contact me for my paypal account details at your earliest convenience.

``````using System;
using System.Collections.Generic;
using System.Linq;

namespace GuidCollisionDetector
{
class Program
{
static void Main(string[] args)
{
//var reserveSomeRam = new byte[1024 * 1024 * 100];     // This indeed has no effect.

Console.WriteLine("{0:u} - Building a bigHeapOGuids.", DateTime.Now);
// Fill up memory with guids.
var bigHeapOGuids = new HashSet<Guid>();
try
{
do
{
} while (true);
}
catch (OutOfMemoryException)
{
// Release the ram we allocated up front.
// Actually, these are pointless too.
//GC.KeepAlive(reserveSomeRam);
//GC.Collect();
}
Console.WriteLine("{0:u} - Built bigHeapOGuids, contains {1} of them.", DateTime.Now, bigHeapOGuids.LongCount());

// Spool up some threads to keep checking if there's a match.
// Keep running until the heat death of the universe.
for (long k = 0; k < Int64.MaxValue; k++)
{
for (long j = 0; j < Int64.MaxValue; j++)
{
Console.WriteLine("{0:u} - Looking for collisions with {1} thread(s)....", DateTime.Now, Environment.ProcessorCount);
{
if (bigHeapOGuids.Contains(Guid.NewGuid()))
throw new ApplicationException("Guids collided! Oh my gosh!");
}
);
Console.WriteLine("{0:u} - That was another {1} attempts without a collision.", DateTime.Now, ((long)Int32.MaxValue) * Environment.ProcessorCount);
}
}
Console.WriteLine("Umm... why hasn't the universe ended yet?");
}
}
}
``````

PS: I wanted to try out the Parallel extensions library. That was easy.

And using OutOfMemoryException as control flow just feels wrong.

EDIT

Well, it seems this still attracts votes. So I've fixed the GC.KeepAlive() issue. And changed it to run with C# 4.

And to clarify my support terms: support is only available on the 28/Feb/2010. Please use a time machine to make support requests on that day only.

EDIT 2 As always, the GC does a better job than I do at managing memory; any previous attempts at doing it myself were doomed to failure.

• That last Console.WriteLine made me laugh real hard. I think you should throw a `CommonlyAcceptedCosmologicTheoriesWrongException` instead. Dec 6, 2009 at 7:36
• does marking this as Accepted also means that @Kai accepts the terms stipulated by @ligos?
– kb.
May 31, 2010 at 8:13
• Setting `reserveSomeRam = null;` doesn't actually accomplish anything. May 31, 2010 at 12:16
• @devinb please explain? it looks like it is freeing the bytes it was previously allocated so that the GC can `Collect()` it. Why doesn't it accomplish anything? May 31, 2010 at 12:50
• GuidCollisionDetector. The name has potential Jul 31, 2010 at 3:15

This will run for a lot more than hours. Assuming it loops at 1 GHz (which it won't - it will be a lot slower than that), it will run for 10790283070806014188970 years. Which is about 83 billion times longer than the age of the universe.

Assuming Moores law holds, it would be a lot quicker to not run this program, wait several hundred years and run it on a computer that is billions of times faster. In fact, any program that takes longer to run than it takes CPU speeds to double (about 18 months) will complete sooner if you wait until the CPU speeds have increased and buy a new CPU before running it (unless you write it so that it can be suspended and resumed on new hardware).

• damn - so maybe serveral threads generating guids is a better idea?
– Kai
Nov 10, 2009 at 1:05
• 4 threads on a quad core processor would make it run in 20 billion times the age of the universe - so yeah, that would help a lot. Nov 10, 2009 at 1:10
• I am suspicious that this is a troll, but on the off chance that it isn't: threads are not magical. If you can do a billion operations per second on one thread, then going to ten threads means that each one runs 1/10th as often. Each thread does 100 M operations per second; the total number of operations per second is not increased. The way to increase number of operations per second is to buy more computers. Suppose you bought a billion more computers. That would reduce the problem to only taking 10790283070806 years, which is still more than four hours. Nov 10, 2009 at 1:15
• I think rjmunro is assuming each thread would run on a separate core; 83 billion universes / 4 cores indeed approximately equals 20 billion universes. Time to buy Intel stock! Nov 10, 2009 at 1:20
• @Erik 83 billion processors means that you will be able to do it in about the amount of time the universe has existed so far. So even that's not nearly enough. Nov 12, 2009 at 10:59

A GUID is theoretically non-unique. Here's your proof:

• GUID is a 128 bit number
• You cannot generate 2^128 + 1 or more GUIDs without re-using old GUIDs

However, if the entire power output of the sun was directed at performing this task, it would go cold long before it finished.

GUIDs can be generated using a number of different tactics, some of which take special measures to guarantee that a given machine will not generate the same GUID twice. Finding collisions in a particular algorithm would show that your particular method for generating GUIDs is bad, but would not prove anything about GUIDs in general.

• Pigeonhole Principle to the rescue! Nov 10, 2009 at 4:28
• +1 for the sun going cold comment. There was an interesting comment somewhere about the pointlessness of encryption keys > 256 bits. To iterate over all possible key values would take more energy than the entire universe holds. Toggling a bit in the CPU requires a small amount energy (it's what generates the heat) which, when multiplied up 2^256 times is a really massive number exceeding the energy stored in the universe, using E=mc2 the universe would need mass of 2^227kg, our sun is 2^101kg so thats 2^126 suns! Nov 10, 2009 at 16:15
• @Skizz: This is true for brute force attacks only. When an encryption scheme is "broken", it means that it can be solved in less time than brute force, but the solve time remains proportional to the key size. May 19, 2010 at 19:39
• @StevenSudit: proportional to exponent of the key size (unless P==NP) Feb 21, 2012 at 12:37
• @Orlangur Proportional to the key size measured in bits. Mar 20, 2012 at 21:33

Of course GUIDs can collide. Since GUIDs are 128-bits, just generate `2^128 + 1` of them and by the pigeonhole principle there must be a collision.

But when we say that a GUID is a unique, what we really mean is that the key space is so large that it is practically impossible to accidentally generate the same GUID twice (assuming that we are generating GUIDs randomly).

If you generate a sequence of `n` GUIDs randomly, then the probability of at least one collision is approximately `p(n) = 1 - exp(-n^2 / 2 * 2^128)` (this is the birthday problem with the number of possible birthdays being `2^128`).

``````   n     p(n)
2^30 1.69e-21
2^40 1.77e-15
2^50 1.86e-10
2^60 1.95e-03
``````

To make these numbers concrete, `2^60 = 1.15e+18`. So, if you generate one billion GUIDs per second, it will take you 36 years to generate `2^60` random GUIDs and even then the probability that you have a collision is still `1.95e-03`. You're more likely to be murdered at some point in your life (`4.76e-03`) than you are to find a collision over the next 36 years. Good luck.

• If you're murdered at some point in your life, odds are it'll be at the end. Nov 10, 2009 at 22:48
• @mmyers: Excellent point. That means that my chances of being murdered right now are absurdly low, since this isn't the end of my life. Oh, wait... May 19, 2010 at 19:41
• Also, if two GUIDs happen to be created within a short period, the chances they are used within the same system is slight. Therefore, this increases uniqueness. Jun 3, 2010 at 11:37
• These numbers and reference to the birthday problem are meaningless. GUID generation algorithms don't generate values over the entire range with equal probability. In fact IIRC the original algorithm used the MAC address of the generating PC + the current time as part of the result - which reduces the risk of collision with Guids generated on other PCs, but of course reduces the key space.
– Joe
Jun 4, 2010 at 21:04
• You're assuming that the probability of being murdered is a constant for all human beings. But clearly people who write snide remarks in forum posts are the kind of people who are more likely to be murdered than the average person.
– Jay
Jul 15, 2011 at 16:58

If you're worried about uniqueness you can always purchase new GUIDs so you can throw away your old ones. I'll put some up on eBay if you'd like.

• Cool - how much for the complete set, from 0 to (2^128)-1 ?
– user180247
Nov 10, 2009 at 4:06
• On sale, \$0.01 per 1k GUIDs. I'll throw in some bamboo wind chimes if you order in the next 60 minutes. Nov 10, 2009 at 5:31
• My set is more exclusive and of higher quality. They are double checked and verified which makes them worth the \$1 per GUID. You can even buy them in batches if you don't want to make the full investment in one go. I will have to charge an extra \$10 per batch though. May 31, 2010 at 12:37
• I'll set you up on a monthly plan and give you unlimited guids for the right price. ^ Those guys are trying to scam you and sell you overpriced guids. I'll sell you quality guids made in China! Oct 19, 2011 at 14:37

Personally, I think the "Big Bang" was caused when two GUIDs collided.

• Just remember It takes a "special" kind of programmer to do that... Mar 29, 2011 at 15:33
• I'd like to hear your reasoning to your theory. I think we could start a new religion based on this and recruit T.Cruise! Oct 19, 2011 at 14:02
• @ErocM; See "Brane cosmology" (en.wikipedia.org/wiki/Brane_cosmology) and "Membrane (M-Theory)" (en.wikipedia.org/wiki/Membrane_(M-Theory)). The idea is if two branes touch a new universe is created. Therefore, you can infer that if two GUIDs touch, a new universe is thus created. Oct 19, 2011 at 20:12
• If Timecop taught us anything is that the same matter cannot occupy the same space at any given time. So if two GUIDs where to collide, they would consume each other and the resulting implosion would generate a black hole, gobbling up the entire universe. So in reality, it wouldn't create a Universe, it'll destroy it.
– AJC
Nov 16, 2011 at 15:10

You can show that in O(1) time with a variant of the quantum bogosort algorithm.

``````Guid g1 = Guid.NewGuid();
Guid g2 = Guid.NewGuid();
if(g1 != g2) Universe.Current.Destroy();
``````
• I'm getting an exception when calling Destroy(). Based on the text, I think my computer lacks the necessary hardware to destroy the current universe. Do you know where I might be able to obtain it? May 19, 2010 at 19:46
• @Steven: Nah, some management guys got too worried about how bad that API would look to the public, and dictated it to always fail for "security reasons". If you look at the method's source there's just that one line: `throw new MundaneHardwareException();`. Anyway, I heard the guys at CERN have some kind of Big Hadron Thingy that might do the trick... May 20, 2010 at 10:03
• @Martinho: Ah, ok. I'll look into replacing `Universe.Current.Destroy()` with `Cern.Lhc.DestroyThisUniverse()`. May 20, 2010 at 16:14
• I knew there was a reason I programmed in Haskell. These side effects are getting scary. May 31, 2010 at 14:58
• "There is a theory which states that if ever anyone ever discovers exactly what the Universe is for and why it is here, it will instantly disappear and be replaced by something even more bizarrely inexplicable. There is another theory that states that this has already happened." -- Douglas Adams, The Hitchhiker's Guide to the Galaxy Jun 3, 2010 at 3:52

Any two GUIDs are very likely unique (not equal).

See this SO entry, and from Wikipedia

While each generated GUID is not guaranteed to be unique, the total number of unique keys (2^128 or 3.4×10^38) is so large that the probability of the same number being generated twice is very small. For example, consider the observable universe, which contains about 5×10^22 stars; every star could then have 6.8×10^15 universally unique GUIDs.

So probably you have to wait for many more billion of years, and hope that you hit one before the universe as we know it comes to an end.

• so is 2^128 not the correct number of possible guids?
– Kai
Nov 10, 2009 at 1:02
• It is. Why do you think 2^128 is a small number? Nov 10, 2009 at 1:05
• Yes, 2^128 is the correct number of possible guids. Nov 10, 2009 at 1:06
• That's a hell of a number. `\$ irb >> 2**128 => 340282366920938463463374607431768211456` Mar 2, 2010 at 19:24
• @Infinity - Even to you? Jun 1, 2010 at 19:31

[Update:] As the comments below point out, newer MS GUIDs are V4 and do not use the MAC address as part of the GUID generation (I haven't seen any indication of a V5 implementation from MS though, so if anyone has a link confirming that let me know). WIth V4 though, time is still a factor though, and the odds against duplication of GUIDs remains so small as to be irrelevant for any practical usage. You certainly would not be likely to ever generate a duplicate GUID from just a single system test such as the OP was trying to do.

Most of these answers are missing one vital point about Microsoft's GUID implementation. The first part of the GUID is based on a timestamp and another part is based on the MAC address of the network card (or a random number if no NIC is installed).

If I understand this correctly, it means that the only reliable way to duplicate a GUID would be to run simultainous GUID generations on multiple machines where the MAC addresses were the same AND where the clocks on both systems were at the same exact time when the generation occured (the timestamp is based on milliseconds if I understand it correctly).... even then there are a lot of other bits in the number that are random, so the odds are still vanishingly small.

For all practical purposes the GUIDs are universally unique.

There is a pretty good description of the MS GUID over at "The Old New Thing" blog

• Thats actually doable when using virtualization. You can and you do get duplicate guids. Dec 6, 2009 at 8:58
• Raymond is outdated on the MAC Address part though, Microsoft doesn't use these anymore. See en.wikipedia.org/wiki/GUID#Algorithm for the difference between V1 and V4 Guids. Dec 7, 2009 at 3:29
• This is no longer the case. The current V5 scheme is just 128 bits of pure pseudorandom goodness. May 31, 2010 at 14:57
• funny how you state everything I did a month later than me and you get 16 points and I still have 0? Jun 3, 2010 at 14:45
• Ya Tony, there is something odd with that. Back when I answered the post, there were only 3 or 4 answers, and I didn't remember seeing yours... if I had, I'd just have upvoted it. I typically don't answer questions when there are other answers already that cover it well enough (which is why I have a rather low overall rep probably). Jun 3, 2010 at 22:28

Here's a nifty little extension method that you can use if you want to check guid uniqueness in many places in your code.

``````internal static class GuidExt
{
public static bool IsUnique(this Guid guid)
{
while (guid != Guid.NewGuid())
{ }
return false;
}
}
``````

To call it, simply call Guid.IsUnique whenever you generate a new guid...

``````Guid g = Guid.NewGuid();
if (!g.IsUnique())
{
throw new GuidIsNotUniqueException();
}
``````

...heck, I'd even recommend calling it twice to make sure it got it right in the first round.

• How does this ensure that `this guid` has never been generated anywhere else in this world? :p Heck we need a world guid pool. :) Apr 1, 2012 at 7:26

Counting to 2^128 - ambitious.

Lets imagine that we can count 2^32 IDs per second per machine - not that ambitious, since it's not even 4.3 billion per second. Lets dedicate 2^32 machines to that task. Furthermore, lets get 2^32 civilisations to each dedicate the same resources to the task.

So far, we can count 2^96 IDs per second, meaning we will be counting for 2^32 seconds (a little over 136 years).

Now, all we need is to get 4,294,967,296 civilisations to each dedicate 4,294,967,296 machines, each machine capable of counting 4,294,967,296 IDs per second, purely to this task for the next 136 years or so - I suggest we get started on this essential task right now ;-)

Well if the running time of 83 billion years does not scare you, think that you will also need to store the generated GUIDs somewhere to check if you have a duplicate; storing 2^128 16-byte numbers would only require you to allocate 4951760157141521099596496896 terabytes of RAM upfront, so imagining you have a computer which could fit all that and that you somehow find a place to buy terabyte DIMMs at 10 grams each, combined they will weigh more than 8 Earth masses, so you can seriously shift it off the current orbit, before you even press "Run". Think twice!

``````for(begin; begin<end; begin)
Console.WriteLine(System.Guid.NewGuid().ToString());
``````

You aren't incrementing `begin` so the condition `begin < end` is always true.

• no - cause i can't iterate bigint
– Kai
Nov 10, 2009 at 1:06
• Does it really matter if he loops forever versus looping 340282366920938463463374607431768211456 times?
– Jay
Jul 15, 2011 at 17:02
• so... would you rather be punched 340282366920938463463374607431768211456 times or forever!?!?!? Nov 11, 2011 at 17:12
• actually this is what really answers to the question! and no votes at all :p Apr 1, 2012 at 7:42

If GUID collisions are a concern, I would recommend using the ScottGuID instead.

Presumably you have reason to be believe that the algorithm for producing Guids is not producing truly random numbers, but is in fact cycling with a period << 2^128.

e.g. RFC4122 method used to derive GUIDs which fixes the values of some bits.

Proof of cycling is going to depend upon the possible size of the period.

For small periods, hash table of hash(GUID) -> GUID with replacement on collision if GUIDs do not match (terminate if they do) might be an approach. Consider also only doing the replacement a random fraction of the time.

Ultimately if the maximum period between collisions is large enough (and isn't known in advance) any method is only going to yield a probability that the collision would be found if it existed.

Note that if the method of generating Guids is clock based (see the RFC), then it may not be possible to determine if collisions exist because either (a) you won't be able to wait long enough for the clock to wrap round, or (b) you can't request enough Guids within a clock tick to force a collision.

Alternatively you might be able to show a statistical relationship between the bits in the Guid, or a correlation of bits between Guids. Such a relationship might make it highly probable that the algorithm is flawed without necessarily being able to find an actual collision.

Of course, if you just want to prove that Guids can collide, then a mathematical proof, not a program, is the answer.

I don't understand why no one has mentioned upgrading your graphics card... Surely if you got a high-end NVIDIA Quadro FX 4800 or something (192 CUDA cores) this would go faster...

Of course if you could afford a few NVIDIA Qadro Plex 2200 S4s (at 960 CUDA cores each), this calculation would really scream. Perhaps NVIDIA would be willing to loan you a few for a "Technology Demonstration" as a PR stunt?

Surely they'd want to be part of this historic calculation...

• hmmmm..... I could run it on our 10,000 node grid at work. Aug 11, 2010 at 9:10

But do you have to be sure you have a duplicate, or do you only care if there can be a duplicate. To be sure that you have two people with the same birthday, you need 366 people (not counting leap year). For there to be a greater than 50% chance of having two people with the same birthday you only need 23 people. That's the birthday problem.

If you have 32 bits, you only need 77,163 values to have a greater than 50% chance of a duplicate. Try it out:

``````Random baseRandom = new Random(0);

int DuplicateIntegerTest(int interations)
{
Random r = new Random(baseRandom.Next());
int[] ints = new int[interations];
for (int i = 0; i < ints.Length; i++)
{
ints[i] = r.Next();
}
Array.Sort(ints);
for (int i = 1; i < ints.Length; i++)
{
if (ints[i] == ints[i - 1])
return 1;
}
return 0;
}

void DoTest()
{
baseRandom = new Random(0);
int count = 0;
int duplicates = 0;
for (int i = 0; i < 1000; i++)
{
count++;
duplicates += DuplicateIntegerTest(77163);
}
Console.WriteLine("{0} iterations had {1} with duplicates", count, duplicates);
}

1000 iterations had 737 with duplicates
``````

Now 128 bits is a lot, so you are still talking a large number of items still giving you a low chance of collision. You would need the following number of records for the given odds using an approximation:

• 0.8 billion billion for a 1/1000 chance of a collision occurring
• 21.7 billion billion for 50% chance of a collision occurring
• 39.6 billion billion for 90% chance of a collision occurring

There are about 1E14 emails sent per year so it would be about 400,000 years at this level before you would have a 90% chance of having two with the same GUID, but that is a lot different than saying you need to run a computer 83 billion times the age of the universe or that the sun would go cold before finding a duplicate.

Aren't you all missing a major point?

I thought GUIDs were generated using two things which make the chances of them being Globally unique quite high. One is they are seeded with the MAC address of the machine that you are on and two they use the time that they were generated plus a random number.

So unless you run it on the actual machine and run all you guesses within the smallest amount of time that the machine uses to represent a time in the GUID you will never generate the same number no matter how many guesses you take using the system call.

I guess if you know the actual way a GUID is made would actually shorten the time to guess quite substantially.

Tony

• Not all GUIDs are created this way. Even if they were, Kai need only wait until the timestamp used to create the GUID wraps around enough times for one he used to create a GUID is used again. Nov 10, 2009 at 18:36
• Guids have not been based on the mac address since 2000 or 2001. As of one of the service packs for NT4 and/or Win2k they changed the algorithm altogether. They are now generated by a random number generator, minus a few bits that identify what kind of guid it is. Nov 11, 2009 at 4:05
• not all GUIDs come from windows platforms... Nov 11, 2009 at 10:03
• OP mentions C#, so it's Windows. Besides, are V4 GUID's a Windows-only thing? May 19, 2010 at 21:51
• @Martinho: Ah, but Mono's unit test for Guid, in GuidTest.cs, contains a method which creates two new GUID's and checks them for equality, failing if they are equal. As Mono builds successfully, we can be absolutely certain that its GUIDs are unique! :-) May 20, 2010 at 16:50

You could hash the GUIDs. That way, you should get a result much faster.

Oh, of course, running multiple threads at the same time is also a good idea, that way you'll increase the chance of a race condition generating the same GUID twice on different threads.

GUIDs are 124 bits because 4 bits hold the version number.

• the reason for not adding this as a comment:no one mentioned it, and i don't know who i should tell this to.:) Aug 25, 2010 at 18:05
• Hooooraaaay i did it.In some "real" app i wrote, I got a Guid collision in a table with ~260k Rows. (MSSQL 2008 R2 Express). Feb 27, 2012 at 15:58
1. Go to the cryogenics lab in the New York City.
2. Freeze yourself for (roughly) 1990 years.
3. Get a job at Planet Express.
4. Buy a brand-new CPU. Build a computer, run the program, and place it in the safe place with an pseudo-perpetual motion machine like the doomsday machine.
5. Wait until the time machine is invented.
6. Jump to the future using the time machine. If you bought 1YHz 128bit CPU, go to `3,938,453,320 days 20 hours 15 minutes 38 seconds 463 ms 463 μs 374 ns 607 ps` after when you started to run the program.
7. ...?
8. PROFIT!!!

... It takes at least `10,783,127` years even if you had 1YHz CPU which is `1,000,000,000,000,000` (or `1,125,899,906,842,624` if you prefer to use binary prefix) times faster than 1GHz CPU.

So rather than waiting for the compute finished, it would be better to feed pigeons which lost their home because other `n` pigeons took their home. :(

Or, you can wait until 128-bit quantum computer is invented. Then you may prove that GUID is not unique, by using your program in reasonable time(maybe).

• I was waiting for a super hero reference in this answer - fail by poster : p - awesome none the less. Feb 22, 2012 at 17:04

Have you tried `begin = begin + new BigInteger((long)1)` in place of begin++?

• nobody has voted for the answer that really answers the question :P Apr 1, 2012 at 7:41

If the number of UUID being generated follows Moore's law, the impression of never running out of GUID in the foreseeable future is false.

With 2 ^ 128 UUIDs, it will only take 18 months * Log2(2^128) ~= 192 years, before we run out of all UUIDs.

And I believe (with no statistical proof what-so-ever) in the past few years since mass adoption of UUID, the speed we are generating UUID is increasing way faster than Moore's law dictates. In other words, we probably have less than 192 years until we have to deal with UUID crisis, that's a lot sooner than end of universe.

But since we definitely won't be running them out by the end of 2012, we'll leave it to other species to worry about the problem.

The odds of a bug in the GUID generating code are much higher than the odds of the algorithm generating a collision. The odds of a bug in your code to test the GUIDs is even greater. Give up.

The program, albeit its errors, shows proof that a GUID is not unique. Those that try to prove the contrary are missing the point. This statement just proves the weak implementation of some of the GUID variations.

A GUID is not necessary unique by definition, it is highly unique by definition. You just refined the meaning of highly. Depending on the version, the implementator (MS or others), use of VM's, etc your definition of highly changes. (see link in earlier post)

You can shorten your 128 bit table to prove your point. The best solution is to use a hash formula to shorten your table with duplicates, and then use the full value once the hash collides and based on that re-generate a GUID. If running from different locations, you would be storing your hash/full key pairs in a central location.

Ps: If the goal is just to generate x number of different values, create a hash table of this width and just check on the hash value.

Not to p**s on the bonfire here, but it does actually happen, and yes, I understand the joking you have been giving this guy, but the GUID is unique only in principle, I bumped into this thread because there is a bug in the WP7 emulator which means every time it boots it gives out the SAME GUID the first time it is called! So, where in theory you cannot have a conflict, if there is a problem generating said GUI, then you can get duplicates

http://forums.create.msdn.com/forums/p/92086/597310.aspx#597310

Since part of Guid generation is based on the current machine's time, my theory to get a duplicate Guid is:

1. Perform a clean installation of Windows
2. Create a startup script that resets the time to 2010-01-01 12:00:00 just as Windows boots up.
3. Just after the startup script, it triggers your application to generate a Guid.
4. Clone this Windows installation, so that you rule out any subtle differences that may occur in subsequent boot-ups.
5. Re-image the hard drive with this image and boot-up the machine a few times.

For me.. the time it takes for a single core to generate a UUIDv1 guarantees it will be unique. Even in a multi core situation if the UUID generator only allows one UUID to be generated at a time for your specific resource (keep in mind that multiple resources can totally utilize the same UUIDs however unlikely since the resource inherently part of the address) then you will have more than enough UUIDs to last you until the timestamp burns out. At which point I really doubt you would care.

Here's a solution, too:

``````int main()
{
QUuid uuid;
while ( (uuid = QUuid::createUuid()) != QUuid::createUuid() ) { }
std::cout << "Aha! I've found one! " << qPrintable( uuid.toString() ) << std::endl;
}
``````

Note: requires Qt, but I guarantee that if you let it run long enough, it might find one.

(Note note: actually, now that I'm looking at it, there may be something about the generation algorithm that prevents two subsequently generated uuids that collide--but I kinda doubt it).

The only solution to prove GUIDs are not unique would be by having a World GUID Pool. Each time a GUID is generated somewhere, it should be registered to the organization. Or heck, we might include a standardization that all GUID generators needs to register it automatically and for that it needs an active internet connection!