After my initial comment, I got to thinking about the math behind it. Here's what I came up with. I'm no expert so feel free to jump in with corrections. Note: This all assumes your hash function is uniformly distributed, as it should be.

Basically, the more bits in your checksum, the lower the chance of collision. The more files, the higher.

First, let's find the odds of a collision with a single pair of files XOR'd together. We'll work with small numbers at first, so let's assume our checksum is 4 bits(0-15), and we'll call it `n`

.

With two sums, the total number of bits `2n`

(8), so there are `2^(2n)`

(256) possibilities total. However, we're only interested in the collisions. To collide an XOR, you need to flip the *same* bits in both sums. There are only `2^n`

(16) ways to do that, since we're using `n`

bits.

So, the overall probability of a collision is `16/256`

, which is `(2^n) / (2^(2n))`

, or simply `1/(n^2)`

. That means the probability of a *non-collision* is `1 - (1/(n^2))`

. So, for our sample `n`

, that means that it's only `15/16`

secure, or 93.75%. Of course, for bigger checksums, it's better. Even for a puny `n=16`

, you get 99.998%

That's for a single comparison, of course. Since you're rolling them all together, you're doing `f-1`

comparisons, where `f`

is the number of files. To get the total odds of a collision that way, you take the `f-1`

power of the odds we got in the first step.

So, for ten files with a 4-bit checksum, we get pretty terrible results:

(15/16) ^ 9 = 55.92% chance of **non-collision**

This rapidly gets better as we add bits, even when we increase the number of files.

For 10 files with a 8-bit checksum:

(255/256) ^ 9 = 96.54%

For 100/1000 files with 16 bits:

(65536/65536) ^ 99 = 99.85%

(65536/65536) ^ 999 = 98.49%

As you can see, we're still working with small checksums. If you're using anything >= 32 bits, my calculator gets off into floating-point rounding errors when I try to do the math on it.

## TL,DR:

Where `n`

is the number of checksum bits and `f`

is the number of files in each set:

```
nonCollisionChance = ( ((2^n)-1) / (2^n) ) ^ (f-1)
collisionChance = 1 - ( ((2^n)-1) / (2^n) ) ^ (f-1)
```

Your method of XOR'ing a bunch of checksums together is probably just fine.