Lets construct such a function from the requirements:

You want a function that outputs a 16 byte hash. So you will have collisions. You can't preserve perfect order and you don't want to. Best you can do is:

H(x) < H(y) => x < y

H(x) > H(y) => x > y

Values close to each other will have the same hash.

- For each x there is an i_x > 0 so that
`H(x) = H(x + i_x) < H(x + i_x + 1)`

. (Except for the end where `x + i_x + 1`

would overflow your 1MB chunks.)

Extending that you get: `H(x) < H(x + i_x + n)`

for any `n > 0`

.

Same argument works for j_x > 0 in the other direction. Combine them and you get:

```
H(x - j_x) == H(x - j_x + 1) == ... == H(x + i_x - 1) == H(x + i_x)
```

Or in other words for each hash value there is a single segment [a, b] mapping to the same value. No value outside this segment can have the same hash value or the ordering would be violated.

Your hash function can then be described by the segments you choose:

Let a_i be 1MB chunks with `0 <= i < 256^16`

and `a_i <= a_i+1`

. Then

```
H(x) = i where a_i <= x < a_i+1
```

- You want an more of less uniform distribution of hash values. Otherwise one would get far more collisions than another and you would spend all the time doing a full compare when that value is hit. So all the segments [a, b] should be about the same size.

The only way to have exact the same size for each segment is to have

```
a_i = i * 2 ^ (1MB - 16)
```

or in other words: H(x) = first 16 bytes of x.

Any other order preserving hash function with a 16 byte output would be less efficient for a random set of input blocks.

And yes, if all but the last few bits of each input block are the same then every test will be a collision. That's a worst case scenario that always exists. If you know your inputs aren't uniformly random then you can adjust the size of each segment to have the same probability to be hit. But that requires knowledge of likely inputs.

Note: If you really want to sort 1'000'000 1MB chunks where you fear such a worst case then you can use bucket sort, resulting in 1,000,000 * 1'048'576 (byte) compares every time. Half of that if you compare 16 bit values at a time, which still has a reasonable number of buckets (65536).