The best solution is to use the STL functional library. By deriving your predicate from `unary_function<SomeType, bool>`

, you'll then be able to use the `not1`

function, which does precisely what you need (i.e. negating a unary predicate).

Here is how you could do that :

```
struct FindPredicate : public unary_function<SomeType, bool>
{
FindPredicate(const SomeType& t) : _t(t) {}
bool operator()(const SomeType& t) const {
return t == _t;
}
private:
const SomeType& _t;
};
bool AllSatisfy(std::vector<SomeType>& v, SomeType& valueToFind)
{
return find_if(v.begin(),
v.end(),
not1(FindPredicate(valueToFind))) == v.end();
}
```

If you want to roll your own solution (which is, IMHO, not the best option...), well, you could write another predicate that is the negation of the first one :

```
struct NotFindPredicate
{
NotFindPredicate(const SomeType& t) : _t(t) {
}
bool operator()(SomeType& t) {
return t != _t;
}
private:
const SomeType& _t;
};
bool AllSatisfy(std::vector<SomeType>& v) {
return find_if(v.begin(),
v.end(),
NotFindPredicate(valueToFind)) == v.end();
}
```

Or you could do better and write a template functor negator, like :

```
template <class Functor>
struct Not
{
Not(Functor & f) : func(f) {}
template <typename ArgType>
bool operator()(ArgType & arg) { return ! func(arg); }
private:
Functor & func;
};
```

that you could use as follow :

```
bool AllSatisfy(std::vector<SomeType>& v, SomeType& valueToFind)
{
FindPredicate f(valueToFind);
return find_if(v.begin(), v.end(), Not<FindPredicate>(f)) == v.end();
}
```

Of course, the latter solution is better because you can reuse the *Not* struct with every functor you want.