The comparative operators that start with `@`

are more general than the ones that don't. With operators such as `</2`

, you can only compare numeric values and expressions (involving literal numerics and variables that are instantiated with numeric values). So, with `</2`

you can do this:

```
?- X = 2, Y = 3, X + Y < 2*Y.
X = 2,
Y = 3.
?- X = 2, Y = 3, X + Y > 2*Y.
false.
?-
```

But you will get an error in the following cases if the expressions don't evaluate to a known numeric:

```
?- Y = 3, X + Y < 2*Y.
ERROR: </2: Arguments are not sufficiently instantiated
```

Or:

```
?- a < b.
ERROR: </2: Arithmetic: `a/0' is not a function
```

However, using `@</2`

you can compare lots of different types of objects in prolog. The comparison evaluation follows the rules described in the link that @Ankur gave. To understand these rules, you'll need to know what Prolog terminology means, such as `term`

, `functor`

, `atom`

, etc (see, for example, Prolog Terms)

Looking at some examples:

```
?- a @< b.
true.
?- a(1) @< a(2).
true.
?- b(1) @< a(2).
false.
?- 20 @< a.
true.
```

These are pretty straight-forward, following the rules. Here's a more interesting case (from above):

```
?- Y = 3, X + Y @< 2*Y.
false.
```

Why would `X + Y`

be considered "not less than" `2*Y`

? Prolog would internally look at this as:

```
`+(X,3) @< *(2,3).`
```

(Note `Y`

is instantiated to `3`

.) These are compound terms (they aren't individual atoms or variables). If we look through the comparison rules, the matching rule is:

Compound terms are first checked on their *arity*, then on their *functor*
name (alphabetically) and finally recursively on their arguments,
leftmost argument first.

The *arity* of both *terms* is 2. The *functor* names are `+`

and `*`

respectively. Those are different. And in teh ASCII collating sequence, `+`

comes after `*`

. Therefore it is not true that `+`

"is less than" `*`

, and therefore not true that `+(X,3) @< *(2,3).`

Thus, it is not true that `Y = 3, X + Y @< 2 * Y.`

Note also that `@</2`

doesn't evaluate numeric expressions. So even with `X`

and `Y`

instantiated as values, you will get:

```
?- X = 2, Y = 3, X + Y @< 2*Y.
false.
```

Whereas, when we had `</2`

here, this is true, since the expression `X + Y < 2*Y`

, when evaluated, is true. When variables are simply unified, it understands that, however, so you would have:

```
| ?- X @< Y.
yes
```

But on the other hand:

```
| ?- X = 2, Y = 1, X @< Y.
no
```

In this case `X @< Y`

is seen as `1 @< 2`

due to the unification of `X`

with `1`

and `Y`

with `2`

and the numeric rule kicks in.

Having said all that, the use of `@</2`

in the predicate `select_one_or_two`

enables that predicate to be usable on lists of all sorts of objects, not just numbers or fully instantiated numeric expressions. If it had used `</2`

, then the following would work:

```
?- select_one_or_two([2,1,3], X, Y).
X = [2, 3],
Y = [1] ;
X = [1, 2],
Y = [3] ;
X = [1, 3],
Y = [2] ;
false.
```

But the following fails:

```
?- select_one_or_two([b,a,c], X, Y).
ERROR: </2: Arithmetic: `b/0' is not a function
?-
```

However, with the `@<`

operator, it works:

```
?- select_one_or_two([b,a,c], X, Y).
X = [b, c],
Y = [a] ;
X = [a, b],
Y = [c] ;
X = [a, c],
Y = [b] ;
false.
```