Complementing the existing answers, I would like to state a few additional points:

# An operator is an operator

First of all, the *operator* `=:=`

is, as the name indicates, an **operator**. In Prolog, we can use the predicate `current_op/3`

to learn more about operators. For example:

**?- current_op(Prec, Type, =:=).**
Prec = 700,
Type = xfx.

This means that the operator `=:=`

has **precedence** 700 and is of **type** `xfx`

. This means that it is a binary **infix** operator.

This means that you *can*, if you *want*, write a term like `=:=(X, Y)`

**equivalently** as `X =:= Y`

. In *both cases*, the *functor* of the term is `=:=`

, and the *arity* of the term is 2. You can use `write_canonical/1`

to verify this:

?- write_canonical(a =:= b).
**=:=(a,b)**

# A predicate is not an operator

So far, so good! This has all been a purely *syntactical* feature. However, what you are *actually* asking about is the **predicate** `(=:=)/2`

, whose name is `=:=`

and which takes 2 *arguments*.

As others have already explained, the predicate `(=:=)/2`

denotes **arithmetic equality** of two arithmetic expressions. It is *true* *iff* its arguments *evaluate* to the same number.

For example, let us try the most general query, by which we ask for any solution whatsoever, using *variables* as arguments:

?- X =:= Y.
**ERROR: Arguments are not sufficiently instantiated**

Hence, this predicate is *not* a true relation, since we cannot use it for *generating* results! This is a quite severe drawback of this predicate, clashing with what you commonly call "declarative programming".

The predicate only works in the very *specific* situation that both arguments are fully instantiated. For example:

?- 1 + 2 **=:=** 3.
**true.**

We call such predicates *moded* because they can only be used in particular *modes* of usage. For the vast majority of beginners, moded predicates are a *nightmare* to use, because they require you to think about your programs *procedurally*, which is quite hard at first and remains hard also later. Also, moded predicates severely *limit the generality* of your programs, because you cannot use them on all directions in which you *could* use pure predicates.

# Constraints are a more general alternative

Prolog also provides much *more general* arithmetic predicates in the form of arithmetic **constraints**.

For example, in the case of *integers*, try your Prolog system's **CLP(FD) constraints**. One of the most important CLP(FD) constraints denotes arithmetic *equality* and is called `(#=)/2`

. In complete analogy to `(=:=)/2`

, the *operator* `(#=)/2`

is also defined as an **infix** operator, and so you can write for example:

**| ?- 1 + 2 #= 3.**
yes

I am using GNU Prolog as one particular example, and many other Prolog systems also provide CLP(FD) implementations.

A major attraction of constraints is found in their **generality**. For example, in contrast to `(=:=)/2`

, we get with the **predicate** `(#=)/2`

:

**| ?- X + 2 #= 3.**
X = 1
**| ?- 1 + Y #= 3.**
Y = 2

*And* we can even ask the **most general** query:

**| ?- X #= Y.**
X = _#0(0..268435455)
Y = _#0(0..268435455)

Note how naturally these predicates blend into Prolog and act as **relations** between integer expressions that can be queried in *all directions*.

Depending on the domain of interest, my recommendition is to use CLP(FD), CLP(Q), CLP(B) etc. *instead* of using more low-level arithmetic predicates.

Also see clpfd, clpq and clpb for more information.

Coincidentally, the *operator* `=:=`

is used by CLP(B) with a *completely* different meaning:

?- sat(A =:= B+1).
**A = 1,
sat(B=:=B).**

This shows that you must distinguish between *operators* and *predicates*. In the above case, the **predicate** `sat/1`

has interpreted the given expression as a propositional formula, and in this context, `=:=`

denotes equality of Boolean expressions.