# calculate a row of numbers(see context for details)

there are two rows of numbers, row 1 is consecutive numbers starting from 0, now ask you to fill out row 2 to make sure the number in row 2 is the times of correspoding number in row 1 appearing in row 2.

For example:

`0 1 2 3 4 5 6 7 8 9`

`_ _ _ _ _ _ _ _ _ _`

To be more specific, we use `row1` for row 1 and `row2` for row 2, we fill out `row2` to make sure it satisies: `row2[i] = count(row2, row1[i])`. `count(row2, row1[i])` means frequency count of `row1[i]` among `row2`.

-
Do you want to generate all possible solutions for row 2? –  Jacob Jul 24 '13 at 2:14
@Jacob, there is only ONE solution. –  hiway Jul 24 '13 at 2:14
This might be a problem for math.stackexchange.com –  scohe001 Jul 24 '13 at 2:16
There isn't only one solution. M0=8, M1=1, M9=1 is a solution. So is M0=8, M2=1, M8=1, and so on... –  Oliver Charlesworth Jul 24 '13 at 2:16
What you are describing is known as a system of linear Diophantine equations. –  duskwuff Jul 24 '13 at 2:18

Out of 1000 runs this solution had to run the loop an average of 3.608 times

``````import random

def f(x):
l = []
for i in range(10):
l.append(x.count(i))
return l

fast = list(range(10))

while f(fast) != fast:
fast = []
slow = []
for i in range(10):
r = random.randint(0,9)
fast.append(r)
slow.append(r)
while True:
fast = f(f(fast))
slow = f(slow)
if fast == slow:
break

print(fast)
``````

f(x) takes a guess, x, and returns the counts. We are essentially looking for a solution such that f(x) = x.

We first choose 10 random integers from 0-9 and make a list. Our goal is to repeatedly set this list equal to itself until we either find a solution or run into a cycle. To check for cycles, we use the Tortoise and the Hair algorithm, which move at 2 speeds. A fast speed which is twice as quick as the slow speed. If these are equal, we have run into a cycle and start from a new random scenario.

I ran through this a few times, and found the general solution for n>6 (where in this case n = 10). It is of the form [n-4,2,1,0...,0,1,0,0,0]

-
Why not make it more general so that the "first row" can be from 0 to n? We've already found the single solution when n is 9. –  scohe001 Jul 24 '13 at 4:02
The code is very easy to edit to work for other n; however, not all n have a solution. For example, 6 does not. I tested this on 12 and got the correct solution [8, 2, 1, 0, 0, 0, 0, 0, 1, 0, 0, 0]. –  enderx1x Jul 24 '13 at 4:05
+1^ it'd be interesting to see which numbers n produce solutions. Logically I'd think anything under a certain n wouldn't have any solutions (n=1, 2, 3...) –  scohe001 Jul 24 '13 at 4:08
All n>6 have a fairly simple solution (I edited to add this solution). n=4 has a solution of [1, 2, 1, 0], and n = 5 has [2, 1, 2, 0, 0]. n = 1, 2, 3, or 6 have no solutions –  enderx1x Jul 24 '13 at 4:12
I missed another solution for n=4: [2,0,2,0]. I believe n=4 is the only number with more than 1 solution. At least it is for all n < 50 –  enderx1x Jul 24 '13 at 23:04

We can solve this mathematically.

Let's call our solution `s`, and `p` the subset of `s`, where `s[i] > 0`, that is, the set of represented numbers (any zero is a number or index that is not represented).

We can say that `n = sum of all frequencies = sum p`

Now let's call `p'` the subset of `p` without `s[0]`, which are frequencies only of numbers greater than zero.

Clearly `sum p' = sum p - s[0] = length p`, which is simply the count of how many numbers in `s` are greater than zero.

Remember that `length p = length p' + 1`. Now if `length p > 4`, we know that `sum p' > 4` and we are left with an `m` length partition (`p'`) that must sum to `m+1`, where `m > 3`. The only way this can be done is with `(m-1)` 1's and one 2, e.g., `[1,1,1,2]` in the case of `m=4` (by definition there are no zeros in `p'`). Such a partition could not make sense as a solution to our problem, and so we see that `p`, or the subset of numbers greater than zero in our solution, must have less than 5 elements.

Now we can solve for specific cases:

Every solution must have `s[0] > 0` since a zero in the zero column would invalidate the solution.

`length p = 1` would only be possible if `s[0]` could be both zero and greater than zero at the same time.

`length p = 2` implies `p' = [2]`, and so there are two zeros and two 2's, `s=[2,0,2,0]`

`length p = 3` implies `p' = [1,2]`. Since we know there is only one more `s[i]`, which is `s[0] > 0`, the 2 in `p'` must either refer to itself, in which case we have `s=[2,1,2,0,0]`; or to two 1's and therefore `s=[1,2,1,0]`

`length p = 4, p' = [2,1,1]`. In this case the 2 could only be referring to the two 1's and we must assume `s[0] > 2`, which also means `sum p >= (3+2+1+1 = 7)`. This is the final / general case that user1125600 found: `s[1]=2, s[2]=1`. The last 1 refers to `s[0]` and so its index equals `s[0]`. Remembering that `sum p - s[0] = length p`, we get, `s[0] = n - 4`, and the solution, for p = 4, n > 6: `s=[n - 4,2,1...1,0,0,0]`

-
how do you conclude that: `sum p'= length p` or `sum p -s[0]=length p` ? –  hiway Jul 26 '13 at 0:27
I understand now, `sum p'` is `n` minus frequencies of `0`, that is just `length p` –  hiway Jul 26 '13 at 1:16
Does `p = 2` mean `p` is the set containing the single element `2`, or `p` is a set of two elements? –  aschepler Jul 26 '13 at 4:43
@aschepler good point, it's the length (a set of two elements), sorry about that. –  גלעד ברקן Jul 26 '13 at 14:43

Solution: brute force. There are only 42 integer partitions of 10. Try them all and see which one works.

-