Never mind why I'm doing this  this is mainly theoretical.
If I were MD5 hashing string representations of integers, how high would I have to count before two of the hashes collide?
Never mind why I'm doing this  this is mainly theoretical. If I were MD5 hashing string representations of integers, how high would I have to count before two of the hashes collide? 


This problem (in generic case) is known as Birthday Paradox The probability of collision in generic case can be computed easily. However, in your particular case, you have to actually compute (and store!) each MD5. EDIT @Scott : not really. The Pigeonhole principle (being just a particular case of Birthday problem) would say that having 2^128 possible MD5 values, we surely will have a collision after 1 + 2^128 tries. The birthday paradox says that the probability of collision will be grater than 0.5 for about 2^70 MD5 values. With these estimates for storage requirements, it's up to you to decide if the problem worth it. By me it does not. 


Apparently, one can base a thesis on this very thing (or similar problems, anyway). I haven't read it, but maybe something in Stevens' thesis will help you (it's apparently linked from the Wikipedia article). 


In a perfect world, to 


Here is a scientific way to find out an estimate of how high you would have to count. Make MD5 hash that is cut down to say 4 bits. Calculate that (make sure you calculate until you reach say 100 collisions so you get a good average) Then make the same thing at 8 bits (again, wait for many collisions so you can calculate an average). Do it again and again until you have averages for 4, 8, 12, 16 bits and then see if you can find a trend. Follow that trend up to 128 bits You may want to xor all 128 bits to come up with your shorter version. Taking the first or last part may not be the best test. 

