What you've come across is some peculiar behavior that arises in C when handling expressions that contain both signed and unsigned quantities.

When an operation is performed where one operand is signed and the other is unsigned, C will implicitly convert the signed argument to unsigned and perform the operations assuming the numbers are nonnegative. This convention often leads to nonintuitive behavior for relational operators such as `<`

and `>`

.

Regarding your helper function, note that since `strlen`

returns type `size_t`

(an unsigned quantity), the difference and the comparison are both computed using unsigned arithmetic. When `s1`

is shorter than `s2`

, the difference `strlen(s1) - strlen(s2)`

should be negative, but instead becomes a large, unsigned number, which is greater than `0`

. Thus,

```
return strlen(s1) - strlen(s2) > 0;
```

returns `1`

even if `s1`

is shorter than `s2`

. To fix your function, use this code instead:

```
return strlen(s1) > strlen(s2);
```

Welcome to the wonderful world of C! :)

## Additional Examples

Since this question has recently received a lot of attention, I'd like to provide a few (simple) examples, just to ensure that I am getting the idea across. I will assume that we are working with a 32-bit machine using two's complement representation.

The important concept to understand when working with unsigned/signed variables in C is that *if there is a mix of unsigned and signed quantities in a single expression, signed values are implicitly cast to unsigned*.

### Example #1:

Consider the following expression:

```
-1 < 0U
```

Since the second operand is unsigned, the first one is *implicitly cast* to unsigned, and hence the expression is equivalent to the comparison,

```
4294967295U < 0U
```

which of course is false. This is probably not the behavior you were expecting.

### Example #2:

Consider the following code that attempts to sum the elements of an array `a`

, where the number of elements is given by parameter `length`

:

```
int sum_array_elements(int a[], unsigned length) {
int i;
int result = 0;
for (i = 0; i <= length-1; i++)
result += a[i];
return result;
}
```

This function is designed to demonstrate how easily bugs can arise due to implicit casting from signed to unsigned. It seems quite natural to pass parameter `length`

as unsigned; after all, who would ever want to use a negative length? The stopping criterion `i <= length-1`

also seems quite intuitive. However, when run with argument `length`

equal to `0`

, the combination of these two yields an unexpected outcome.

Since parameter `length`

is unsigned, the computation `0-1`

is performed using unsigned arithmetic, which is equivalent to modular addition. The result is then *UMax*. The `<=`

comparison is also performed using an unsigned comparison, and since any number is less than or equal to *UMax*, the comparison always holds. Thus, the code will attempt to access invalid elements of array `a`

.

The code can be fixed either by declaring `length`

to be an `int`

, or by changing the test of the `for`

loop to be `i < length`

.

### Conclusion: When Should You Use Unsigned?

I don't want to state anything too controversial here, but here are some of the rules I often adhere to when I write programs in C.

**DON'T**** use just because a number is nonnegative.** It is easy to make mistakes, and these mistakes are sometimes incredibly subtle (as illustrated in Example #2).

**DO**** use when performing modular arithmetic.**

**DO**** use when using bits to represent sets.** This is often convenient because it allows you to perform logical right shifts without sign extension.

Of course, there may be situations in which you decide to go against these "rules". But most often than not, following these suggestions will make your code easier to work with and less error-prone.

`return strlen(s1) > strlen(s2);`

. – Jonathan Leffler May 28 '12 at 0:55up-vote Alex Lockwood's answer!!:D – Adrian Monk May 29 '12 at 4:30