I like @TesselatingHeckler's answer because it puts the finger on the heart of the matter. You might still be wondering, what that means for Prolog in more concrete terms. Consider a simple predicate definition:

```
p(something).
```

On ground terms, we get the expected answers to our queries:

```
?- p(something).
true.
?- \+ p(something).
false.
?- p(nothing).
false.
?- \+ p(nothing).
true.
```

The problems start, when variables and substitution come into play:

```
?- \+ p(X).
false.
```

`p(X)`

is not always false because `p(something)`

is true. So far so good. Let's use equality to express substitution and check if we can derive `\+ p(nothing)`

that way:

```
?- X = nothing, \+ p(X).
X = nothing.
```

In logic, the order of goals does not matter. But when we want to derive a reordered version, it fails:

```
?- \+ p(X), X = nothing.
false.
```

The difference to `X = nothing, \+ p(X)`

is that when we reach the negation there, we have already unified `X`

such that Prolog tries to derive `\+p(nothing)`

which we know is true. But in the other order the first goal is the more general `\+ p(X)`

which we saw was false, letting the whole query fail.

This should certainly not happen - in the worst case we would expect non-termination but never failure instead of success.

As a consequence, we cannot rely on our logical interpretation of a clause anymore but have to take Prolog's execution strategy into account as soon as negation is involved.