I am attempting to demonstrate a simple proof of concept with respect to a vulnerability in a piece of code in a game written in C.

Let's say that we want to validate a character login. The login is handled by the user choosing `n`

items, (let's just assume `n=5`

for now) from a graphical menu. The items are all medieval themed:

eg:

```
_______________________________
| | | |
| Bow | Sword | Staff |
|-----------|-----------|-------|
| Shield | Potion | Gold |
|___________|___________|_______|
```

The user must click on each item, then choose a number for each item.

The validation algorithm then does the following:

- Determines which items were selected
- Drops each string to lowercase (ie:
`Bow`

becomes`bow`

, etc) - Calculates a simple string hash for each string (ie: `bow => b=2, o=15, w=23, sum = (2+15+23=40)
- Multiplies the hash by the value the user selected for the corresponding item; This new value is called the
`key`

- Sums together the
`keys`

for each of the selected items; this is the final validation hash - IMPORTANT: The validator will accept this hash, along with non-zero multiples of it (ie: if the final hash equals 1111, then 2222, 3333, 8888, etc are also valid).

So, for example, let's say I select:

```
Bow (1)
Sword (2)
Staff (10)
Shield (1)
Potion (6)
```

The algorithm drops each of these strings to lowercase, calculates their string hashes, multiplies that hash by the number selected for each string, then sums these keys together.

eg:

`Final_Validation_Hash = 1*HASH(Bow) + 2*HASH(Sword) + 10*HASH(Staff) + 1*HASH(Shield) + 6*HASH(Potion)`

By application of Euler's Method, I plan to demonstrate that these hashes are not unique, and want to devise a simple application to prove it.

in my case, for 5 items, I would essentially be trying to calculate:

`(B)(y) = (A_1)(x_1) + (A_2)(x_2) + (A_3)(x_3) + (A_4)(x_4) + (A_5)(x_5)`

Where:

```
B is arbitrary
A_j are the selected coefficients/values for each string/category
x_j are the hash values for each string/category
y is the final validation hash (eg: 1111 above)
B,y,A_j,x_j are all discrete-valued, positive, and non-zero (ie: natural numbers)
```

Can someone either assist me in solving this problem or point me to a similar example (ie: code, worked out equations, etc)? I just need to solve the final step (ie: (B)(Y) = ...).

In the end, I wrote a recursive algorithm that goes `n`

levels deep, then handles incrementing, testing, etc, for all remaining possible combinations. Not very efficient, but it works. I could provide it upon request (too large to post here).