# Expected number of hash collisions

I feel like I'm way overthinking this problem, but here goes anyway...

I have a hash table with M slots in its internal array. I need to insert N elements into the hash table. Assuming that I have a hash function that randomly inserts am element into a slot with equal probability for each slot, what's the expected value of the total number of hash collisions?

(Sorry that this is more of a math question than a programming question).

Edit: Here's some code I have to simulate it using Python. I'm getting numerical answers, but having trouble generalizing it to a formula and explaining it.

``````import random
import pdb

N = 5
M = 8

NUM_ITER = 100000

def get_collisions(table):
col = 0
for item in table:
if item > 1:
col += (item-1)
return col

def run():
table = [0 for x in range(M)]

for i in range(N):
table[int(random.random() * M)] += 1

#print table
return get_collisions(table)

# Main

total = 0
for i in range(NUM_ITER):
total += run()

print float(total)/NUM_ITER
``````
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how do you want "triplet" collisions measured ? –  wildplasser Feb 1 '12 at 22:47
Whatever makes the most sense I guess. So I'll go with counting it as two collisions (one per new element added after the first) –  numegil Feb 1 '12 at 22:48
The best measure appears to be the amount of work to retrieve all items, which is `SUM(x * (x+1) /2)` with X is the number of items in a bucket, and the sum is over all buckets. –  wildplasser Feb 1 '12 at 22:55

You'll find the answer here: Quora.com. The expected number of collisions for m buckets and n inserts is

`n - m * (1 - ((m-1)/m)^n)`.

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+1 for referencing a source. –  lumberjack4 Oct 11 '12 at 22:23
There is also a proof of this on the Math StackExchange. –  ShreevatsaR Dec 6 '13 at 9:14
The formula for the SUM(x*(x+1)/2) metric can be found here, and the expected value appears to be `(n/2m)* (n+2m -1)`. Don't know about the variance, IANAM.