As pointed out by Daniel (and explained in Leonid's book) `Null == 0`

does not evaluate to either `True`

or `False`

, so the `If`

statement (as written) also does not evaluate.
`Null`

is a special `Symbol`

that does not display in output, but in all other ways acts like a normal, everyday symbol.

```
In[1]:= Head[Null]
Out[1]= Symbol
```

For some undefined symbol `x`

, you don't want `x == 0`

to return `False`

, since `x`

could be zero later on. This is why `Null == 0`

also doesn't evaluate.

There are two possible fixes for this:

**1)** Force the test to evaluate using `TrueQ`

or `SameQ`

.

For the `n == Null`

test, the following will equivalent, but when testing numerical objects they will not. (This is because `Equal`

uses an approximate test for numerical equivalence.)

```
f[n_] := If[TrueQ[n == Null], 1, 2] (* TrueQ *)
f[n_] := If[n === Null, 1, 2] (* SameQ *)
```

Using the above, the conditional statement works as you wanted:

```
In[3]:= {f[Null], f[0]}
Out[3]= {1, 2}
```

**2)** Use the optional 4th argument of `If`

that is returned if the test remains unevaluated (i.e. if it is neither `True`

nor `False`

)

```
g[n_] := If[n == Null, 1, 2, 3]
```

Then

```
In[5]:= {g[Null], g[0]}
Out[5]= {1, 3}
```