In my example code below, will every `$hash`

be unique?

*Almost.* (Which, I guess, means "no, but in a way that's easily fixed".) Your function consists of a sequence of independent steps; the overall function is bijective (reversible) if and only if every single one of those steps is. (Do you see why?)

Now, each step has one of the following forms:

```
$key = ($key ^ CONSTANT) ^ ($key >> NUM_BITS);
$key = ($key ^ CONSTANT) ^ ($key << NUM_BITS);
```

with `NUM_BITS != 0`

.

We can actually treat these as variants of a single form, by viewing the former as *almost* equivalent to this:

```
$key = invert_order_of_bits($key); # clearly bijective
$constant = invert_order_of_bits(CONSTANT);
$key = ($key ^ $constant) ^ ($key << NUM_BITS);
$key = invert_order_of_bits($key); # clearly bijective
```

So all we need is to show that this:

```
$key = ($key ^ CONSTANT) ^ ($key << NUM_BITS);
```

is bijective. Now, XOR is commutative and associative, so the above is equivalent to this:

```
$key = $key ^ ($key << NUM_BITS);
$key = $key ^ CONSTANT;
```

and `(x ^ y) ^ y == x ^ (y ^ y) == x ^ 0 == x`

, so clearly XOR-ing with a constant value is reversible (by re-XOR-ing with the same value); so all we have to show is that this is bijective:

```
$key = $key ^ ($key << NUM_BITS);
```

whenever `NUM_BITS != 0`

.

Now, I'm not writing a rigorous proof, so I'll just give a *single* reasoned-out example of how to reverse this. Suppose that `$key ^ ($key << 9)`

is

```
0010 1010 1101 1110 0010 0101 0000 1100
```

How do we obtain `$key`

? Well, we know that the last nine bits of `$key << 9`

are all zeroes, so we know that the last nine bits of `$key ^ ($key << 9)`

are the same as the last nine bits of `$key`

. So `$key`

looks like

```
bbbb bbbb bbbb bbbb bbbb bbb1 0000 1100
```

so `$key << 9`

looks like

```
bbbb bbbb bbbb bb10 0001 1000 0000 0000
```

so `$key`

looks like

```
bbbb bbbb bbbb bb00 0011 1101 0000 1100
```

(by XOR-ing `$key ^ ($key << 9)`

with `$key << 9`

), so `$key << 9`

looks like

```
bbbb b000 0111 1010 0001 1000 0000 0000
```

so `$key`

looks like

```
bbbb b010 1010 0100 0011 1101 0000 1100
```

so `$key << 9`

looks like

```
0101 1000 0111 1010 0001 1000 0000 0000
```

so `$key`

looks like

```
0111 0010 1010 0100 0011 1101 0000 1100
```

So . . . why do I say "almost" rather than "yes"? Why is your hash-function not *perfectly* bijective? It's because in PHP, the bitwise shift operators `>>`

and `<<`

are not *quite* symmetric, and while `$key = $key ^ ($key << NUM_BITS)`

is completely reversible, `$key = $key ^ ($key >> NUM_BITS)`

is not. (Above, when I wrote that the two types of steps were "*almost* equivalent", I really *meant* that "almost". It makes a difference!) You see, whereas `<<`

treats the sign bit just like any other bit, and shifts it out of existence (bringing in a zero-bit on the right), `>>`

treats the sign bit specially, and "extends" it: the bit that it brings in on the left is equal to the sign bit. (N.B. Your question mentions "unsigned 32bit" values, but PHP doesn't actually support that; its bitwise operations are always on *signed* integers.)

Due to this sign extension, if `$key`

starts with a `0`

, then `$key >> NUM_BITS`

starts with a `0`

, and if `$key`

starts with a `1`

, then `$key >> NUM_BITS`

also starts with a `1`

. In either case, `$key ^ ($key >> NUM_BITS)`

will start with a `0`

. You've lost exactly one bit of entropy. If you give me `$key ^ ($key >> 9)`

, and don't tell me whether `$key`

is negative, then the best I can do is compute two possible values for `$key`

: one negative, one positive-or-zero.

You perform two steps that use right-shift instead of left-shift, so you lose two bits of entropy. (I'm hand-waving slightly — all I've actually demonstrated is that you lose *at least* one bit and *at most* two bits — but I'm confident that, due to the nature of the steps between those right-shift steps, you do actually lose two full bits.) For any given output value, there are exactly four distinct input-values that could yield it. So it's not unique, but it's *almost* unique; and it's easily fixed, by either:

- changing the two right-shift steps to use left-shifts instead; or
- moving both of the right-shift steps to the start of the function, before any left-shift steps, and saying that outputs are unique for inputs between 0 and 2
^{31}−1 rather than inputs between 0 and 2^{32}−1.