I'm working on a code to solve this problem:

You and your friends are in New York and are planning to go see a Broadway musical. Unfortunately, New York being New York, the tickets are just a tiny bit expensive. But one of the shows has a ticket lottery each night where impecunious people such as you have a chance to win the right to buy slightly less expensive tickets to good seats. The lottery operates as follows. First, everyone interested enters the lottery. Then, n lucky winners are drawn, and each of these is offered to buy up to t tickets.

Given the number of people p in your group (all of which entered the lottery) and the total number of people m that entered the lottery, what is the probability that you will be able to get tickets for your entire group? Assume that the n lucky winners are chosen uniformly at random from the m people that entered the lottery, and that each person can win at most once.

Here's my code:

```
import math
def lottery():
m = int(raw_input('The number of people who entered the lottery: '))
n = int(raw_input('The number of winner drawn from the total: '))
t = int(raw_input('The number of tickets each winner can purchase: '))
p = int(raw_input('The number of people in your group: '))
def combinations(n, k):
if 0 <= k <= n:
ntok = 1
ktok = 1
for t in xrange(1, min(k, n - k) + 1):
ntok *= n
ktok *= t
n -= 1
return ntok // ktok
else:
return 0
needed_wins = int(math.ceil(p/t))
others = m - p
loss = 0
for i in range(needed_wins):
loss += combinations(others, n-i) * combinations(p, i)
total = combinations(m, n)
prob = 1 - loss / total
print(prob)
```

I tried to run it but the result came out wrong. For example, if the combination is (100,10,2,1), the result should be 0.1; instead it returned 1. I really appreciate it if anyone can help me out here.

`itertools.combinations`

– jdotjdot Dec 24 '12 at 2:30`itertools.combinations()`

is not referring to anything relating to division. – Matt Dec 24 '12 at 3:16`itertools.combination()`

but it returned that`int`

objects are not iterable. – Long Pham Dec 24 '12 at 4:16