They are completely different algorithms: `find_if`

looks *linearly* for the first item for which the predicate is true, `binary_search`

takes advantage that the range is sorted to test *in logarithmic time* if a given value is in it.

The predicate for `binary_search`

specifies the function according to which the range is ordered (you'd most likely want to use the same predicate you used for sorting it).

You can't take advantage of the sortedness to search for a value satisfying some completely unrelated predicate (you'd have to use `find_if`

anyway). Note however, that with a sorted range you can do more than just test for existence with `lower_bound`

, `upper_bound`

and `equal_range`

.

The question, what is the purpose of `std::binary_function`

is an interesting one.

All it does is provide typedefs for `result_type`

, `first_argument_type`

and `second_argument_type`

. These would allow the users, given a functor as a template argument, to find out and use these types, e.g

```
template <class T, class BinaryFunction>
void foo(const T& a, const T& b, BinaryFunction f)
{
//declare a variable to store the result of the function call
typename BinaryFunction::result_type result = f(a, b);
//...
}
```

However, I think the only place where they are used in the standard library is creating other functor wrappers like `bind1st`

, `bind2nd`

, `not1`

, `not2`

. (If they were used for other purposes, people would yell at you any time you used a function as a functor since it would be an unportable thing to do.)

For example, `binary_negate`

might be implemented as (GCC):

```
template<typename _Predicate>
class binary_negate
: public binary_function<typename _Predicate::first_argument_type,
typename _Predicate::second_argument_type, bool>
{
protected:
_Predicate _M_pred;
public:
explicit
binary_negate(const _Predicate& __x) : _M_pred(__x) { }
bool
operator()(const typename _Predicate::first_argument_type& __x,
const typename _Predicate::second_argument_type& __y) const
{ return !_M_pred(__x, __y); }
};
```

Of course, `operator()`

could perhaps just be a template, in which case those typedefs would be unnecessary (any downsides?). There are probably also metaprogramming techniques to find out what the argument types are without requiring the user to typedef them explicitly. I suppose it would somewhat get into the way with the power that C++0x gives - e.g when I'd like to implement a negator for a function of any arity with variadic templates...

(IMO the C++98 functors are a bit too inflexible and primitive compared for example to `std::tr1::bind`

and `std::tr1::mem_fn`

, but probably at the time compiler support for metaprogramming techniques required to make those work was not that good, and perhaps the techniques were still being discovered.)