I'm coming late to the party, with an accepted answer and all, but I want to point out that definitions of the form:

```
f[...] := Module[... /; ...]
```

are very useful in this context. Definitions of this kind can perform complex calculations before finally bailing out and deciding that the definition was not applicable after all.

I will illustrate how this can be used to implement various error-handling strategies in the context of a specific case from another SO question. The problem is to search a fixed list of pairs:

```
data = {{0, 1}, {1, 2}, {2, 4}, {3, 8}, {4, 15}, {5, 29}, {6, 50}, {7,
88}, {8, 130}, {9, 157}, {10, 180}, {11, 191}, {12, 196}, {13,
199}, {14, 200}};
```

to find the first pair whose second component is greater than or equal to a specified value. Once that pair is found, its first component is to be returned. There are lots of ways to write this in Mathematica, but here is one:

```
f0[x_] := First @ Cases[data, {t_, p_} /; p >= x :> t, {1}, 1]
f0[100] (* returns 8 *)
```

The question, now, is what happens if the function is called with a value that cannot be found?

```
f0[1000]
error: First::first: {} has a length of zero and no first element.
```

The error message is cryptic, at best, offering no clues as to what the problem is. If this function was called deep in a call chain, then a cascade of similarly opaque errors is likely to occur.

There are various strategies to deal with such exceptional cases. One is to change the return value so that a success case can be distinguished from a failure case:

```
f1[x_] := Cases[data, {t_, p_} /; p >= x :> t, {1}, 1]
f1[100] (* returns {8} *)
f1[1000] (* returns {} *)
```

However, there is a strong Mathematica tradition to leave the original expression unmodified whenever a function is evaluated with arguments outside of its domain. This is where the Module[... /; ...] pattern can help out:

```
f2[x_] :=
Module[{m},
m = Cases[data, {t_, p_} /; p >= x :> t, {1}, 1];
First[m] /; m =!= {}
]
f2[100] (* returns 8 *)
f2[1000] (* returns f2[1000] *)
```

Note that the *f2* bails out completely if the final result is the empty list and the original expression is returned unevaluated -- achieved by the simple expedient of adding a /; condition to the final expression.

One might decide to issue a meaningful warning if the "not found" case occurs:

```
f2[x_] := Null /; Message[f2::err, x]
f2::err = "Could not find a value for ``.";
```

With this change the same values will be returned, but a warning message will be issued in the "not found" case. The *Null* return value in the new definition can be anything -- it is not used.

One might further decide that the "not found" case just cannot occur at all except in the case of buggy client code. In that case, one should cause the computation to abort:

```
f2[x_] := (Message[f2::err, x]; Abort[])
```

In conclusion, these patterns are easy enough to apply so that one can deal with function arguments that are outside the defined domain. When defining functions, it pays to take a few moments to decide how to handle domain errors. It pays in reduced debugging time. After all, virtually *all* functions are partial functions in Mathematica. Consider: a function might be called with a string, an image, a song or roving swarms of nanobots (in Mathematica 9, maybe).

A final cautionary note... I should point out that when defining and redefining functions using multiple definitions, it is very easy to get unexpected results due to "left over" definitions. As a general principle, I highly recommend preceding multiply-defined functions with *Clear*:

```
Clear[f]
f[x_] := ...
f[x_] := Module[... /; ...]
f[x_] := ... /; ...
```

Beep! – Simon Nov 13 '10 at 22:27`$AssertFunction`

to`Abort[]`

then it will have basically the same behaviour as the one in your question. – Simon Nov 15 '10 at 13:491more comment