If it "doesn't make sense" for one `Airport`

to come before another `Airport`

then the use of `std::set<Airport>`

doesn't make sense, either. This container leverages the order amount elements to locate objects in `O(log(n))`

operations (where `n`

is the size of the container). If you can identify object by identity only, the best complexity you can achieve is `O(n)`

. You can use a combination of `std::find()`

or `std::find_if()`

and one of the sequence containers, e.g., `std::vector<Airport>`

or `std::deque<Airport>`

.

Since you don't need to define an order in terms of `operator<()`

, it may be reasonable to just bring the `Airport`

s into some order for the purpose of locating them in a `std::set<Airport>`

which is done by using a different comparison function object than `std::less<Airport>`

. The attribute you currently have in your `Airport`

object don't really look like suitable keys, though. In fact, they all look as if they would be mutable, i.e., you probably wouldn't want a `std::set<Airport>`

anyway because you can't modify the elements in an `std::set<T>`

(well, at least, you shouldn't; yes, I realize that you can play tricks with `mutable`

but this is bound to break the order of the elements).

Based on this, I'd recommend to use a `std::map<std:string, Airport>`

: the `std::string`

is used to identify the airport, e.g., using the airport codes like `"JFK"`

for the John F. Kennedy Airport in New York or `"LHR"`

for London Heathrow. Conveniently, there is already a strict weak order defined on strings.

That said, to define a strict weak order on a set of objects `O`

, you need to a binary relation `r(x, y)`

such that the following conditions hold for elements `x`

, `y`

, and `z`

from `O`

:

- irreflexive:
`r(x, x) == false`

- asymmetric:
`r(x, y) == true`

implies `r(y, x) == false`

- transitive:
`r(x, y) == true`

and `r(y, z) == true`

implies `r(x, z) == true`

- incomparability:
`r(x, y) == false`

and `r(y, x) == false`

and `r(y, z) == false`

and `r(z, y) == false`

implies `r(x, z) == false`

and `r(z, x) == false`

The first three should be simple enough. The last one is a bit odd at first but actually not that hard either: The basic idea is that the relation doesn't entirely order element but groups them into equivalent classes. If you think of the relation `r`

to be "smaller than" it just says that if neither `x`

is smaller than `y`

nor `y`

is smaller than `x`

, then `x`

and `y`

are equivalent. The incomparable elements are just equivalent.

The standard containers work with a strict weak order but, e.g., `std::set<T>`

and `std::map<K, V>`

keep just one version of equivalent keys. It is nice that this is sufficient but it is often simpler to just use a total order which is a strict weak order where for each pair of element `x`

and `y`

either `r(x, y) == true`

or `r(y, x) == true`

(but, due to the asymmetry not both).