How many random elements before MD5 produces collisions?

I've got an image library on Amazon S3. For each image, I md5 the source URL on my server plus a timestamp to get a unique filename. Since S3 can't have subdirectories, I need to store all of these images in a single flat folder.

Do I need to worry about collisions in the MD5 hash value that gets produced?

Bonus: How many files could I have before I'd start seeing collisions in the hash value that MD5 produces?

• Mar 1, 2018 at 16:47
• The literal answer is that the second file could have the same MD5 as the first. However the odds are extremely small. Mar 15, 2018 at 12:23

Probability of just two hashes accidentally colliding is 1/2128 which is 1 in 340 undecillion 282 decillion 366 nonillion 920 octillion 938 septillion 463 sextillion 463 quintillion 374 quadrillion 607 trillion 431 billion 768 million 211 thousand 456.

However if you keep all the hashes then the probability is a bit higher thanks to birthday paradox. To have a 50% chance of any hash colliding with any other hash you need 264 hashes. This means that to get a collision, on average, you'll need to hash 6 billion files per second for 100 years.

• Not strictly true. The probability of a collision is much higher than this as a new URL could potentially collide with any existing item in the table. See This posting (disclaimer, I wrote it) for a run-down on the maths, and a small python script that can be adapted to compute the probability for a particular number of URLs. Apr 15, 2011 at 14:43
• "probability of collision is 1/2^64" - what? The probability of collision is dependent on the number of items already hashed, it's not a fixed number. In fact, it's equal to exactly `1 - sPn/s^n`, where `s` is the size of the search space (`2^128` in this case), and `n` is the number of items hashed. What you are probably thinking of is `2^64`, which is the approximate number of items you'd need to MD5 hash to have a 50% chance of collision. May 20, 2013 at 18:34
• Unfortunately, you are still not correct. You are assuming that the hash function is truly random. It is not. This means that the collision probability is higher. Feb 16, 2015 at 13:09
• JørgenFogh: And all laws of physics are "not correct" either. Such level of pedantism is unnecessary because it doesn't change the answer in any meaningful way. Feb 16, 2015 at 23:56
• So you’re saying there’s a chance! May 18, 2018 at 8:49

S3 can have subdirectories. Just put a "/" in the key name, and you can access the files as if they were in separate directories. I use this to store user files in separate folders based on their user ID in S3.

For example: "mybucket/users/1234/somefile.jpg". It's not exactly the same as a directory in a file system, but the S3 API has some features that let it work almost the same. I can ask it to list all files that begin with "users/1234/" and it will show me all the files in that "directory".

So wait, is it:

``````md5(filename) + timestamp
``````

or:

``````md5(filename + timestamp)
``````

If the former, you are most of the way to a GUID, and I wouldn't worry about it. If the latter, then see Karg's post about how you will run into collisions eventually.

• Please elaborate on how including the timestamp increases the chance of collision Sep 23, 2014 at 3:34
• @BradThomas : It does not. The MD5 risk of collision is the same whether it is on the filename or the combination of filename+timestamp. But in the first scenario, you would need to have both a MD5 collision and a timestamp collision. Nov 13, 2014 at 15:10
• This still leaves a 2^(128^60) chance of a collission with two users per minute. Literally unusable. Nov 29, 2016 at 12:47
• @BradThomas To be clearer: `md5(filename) + timestamp` reduces the collision risk massively because you would need to have an md5 collision for exactly the same timestamp to have a collision overall. `md5(filename + timestamp)` is the same as `md5(filename)`, assuming that filename is random to start with (because adding more randomness to something random only changes the individual md5 result and the birthday problem still exists across all the md5 hashes). Mar 15, 2018 at 1:38

A rough rule of thumb for collisions is the square-root of the range of values. Your MD5 sig is presumably 128 bits long, so you're going to be likely to see collisions above and beyond 2^64 images.

Although random MD5 collisions are exceedingly rare, if your users can provide files (that will be stored verbatim) then they can engineer collisions to occur. That is, they can deliberately create two files with the same MD5sum but different data. Make sure your application can handle this case in a sensible way, or perhaps use a stronger hash like SHA-256.

• using a salt would take care of the user engineering problem, no? Oct 13, 2014 at 16:45
• It depends on how the salt is applied. It would need to be a prefix of the user-supplied data, or better yet the key for an HMAC. It's still probably a good idea to practice defense in depth though. Dec 8, 2014 at 6:56
• Note although SHA256 is 256 bits long, you can trade off the risk of collisions with the length of the key you are storing by truncating the SHA256 to fewer bits e.g. use SHA256 but truncate it to 128 bits (which is more secure than using MD5 even though they have the same number of bits). Mar 15, 2018 at 1:57

While there have been well publicized problems with MD5 due to collisions, UNINTENTIONAL collisions among random data are exceedingly rare. On the other hand, if you are hashing on the file name, that's not random data, and I would expect collisions quickly.

• The only problem I have with taylors example is that if someone gets a copy of your database they could probably figure out the credit card numbers using a rainbow table ... May 4, 2009 at 2:42
• While I wouldn't choose to use MD5 for credit cards, a Rainbow table of all valid credit card numbers between 10,000,000 (8 digits being the smallest length credit card I've seen) and 9,999,999,999,999,999 (largest 16 digit number) is still a big table to generate. There are probably easier ways to steal those numbers. May 4, 2009 at 14:01

Doesn't really matter how likely it is; it is possible. It could happen on the first two things you hash (very unlikely, but possible), so you'll need to support collisions from the beginning.

• There may of course be many other bad things which can happen with a probability of 1/2^128. You might not want to single-out this one to worry about. Oct 14, 2008 at 15:47
• The worst thing that can happen here is you can get a photo. For a relatively small number I would not worry. Now if your software is controlling an autopilot landing an aircraft, thats another story. Oct 14, 2008 at 15:54
• You can't be serious. You'll need to hash 6 billion files per second, every second for 100 years to get good chance of collision. Even if you're very very unlucky, it would probably take more than entire capacity of S3 used for longer than a human lifetime. Nov 13, 2008 at 22:36
• It's billions of times more likely that your database and its backups will all fail. Collisions are not worth worrying about. Sep 7, 2009 at 1:31
• Use the collision prevention time building a bunker to put your server! Those pesky meteors can hit you (very unlikely, but possible), so you'll need to support meteor shelter from the begging. May 22, 2018 at 21:12

MD5 collision is extremely unlikely. If you have 9 trillion MD5s, there is only one chance in 9 trillion that there will be a collision.

• Many of the other Answers talk about the probability of a collision when adding one more item. I think my Answer are more useful because it talks about the probably of the entire table having a dup. Sep 5, 2017 at 12:23
• This has nothing to do with MD5 and is not correct. It's like saying that if you have 9 trillion cats there is a 1 in 9 trillion chance that someone else has a identical cat. The key problem here is that you can get same hash with more than one value. Jan 24, 2019 at 13:07
• @JoonasAlhonen - Yes, that is true. And a lot of poor people use that as an excuse to buy yet another Lottery ticket they cannot afford. Jan 25, 2019 at 6:38