There's no real need to initialize to smallest/largest possible to find the smallest/largest in the array:

```
double largest = smallest = array[0];
for (int i=1; i<array_size; i++) {
if (array[i] < smallest)
smallest = array[i];
if (array[i] > largest0
largest= array[i];
}
```

Or, if you're doing it more than once:

```
#include <utility>
template <class iter>
std::pair<typename iter::value_type, typename iter::value_type> find_extrema(iter begin, iter end) {
std::pair<typename iter::value_type, typename iter::value_type> ret;
ret.first = ret.second = *begin;
while (++begin != end) {
if (*begin < ret.first)
ret.first = *begin;
if (*begin > ret.second)
ret.second = *begin;
}
return ret;
}
```

The disadvantage of providing sample code -- I see others have already suggested the same idea.

Note that while the standard has a min_element and max_element, using these would require scanning through the data twice, which could be a problem if the array is large at all. Recent standards have addressed this by adding a `std::minmax_element`

, which does the same as the `find_extrema`

above (find both the minimum and maximum elements in a collection in a single pass).

Edit: Addressing the problem of finding the smallest non-zero value in an array of unsigned: observe that unsigned values "wrap around" when they reach an extreme. To find the smallest non-zero value, we can subtract one from each for the comparison. Any zero values will "wrap around" to the largest possible value for the type, but the *relationship* between other values will be retained. After we're done, we obviously add one back to the value we found.

```
unsigned int min_nonzero(std::vector<unsigned int> const &values) {
if (vector.size() == 0)
return 0;
unsigned int temp = values[0]-1;
for (int i=1; i<values.size(); i++)
if (values[i]-1 < temp)
temp = values[i]-1;
return temp+1;
}
```

Note this still uses the first element for the initial value, but we still don't need any "special case" code -- since that will wrap around to the largest possible value, any non-zero value will compare as being smaller. The result will be the smallest nonzero value, or 0 if and only if the vector contained no non-zero values.