This is another variation of an old theme: The initialization order of static objects in different translation units is not defined.

Below is a stripped-down example of my particular scenario. The classes G and F are non-POD types. F depends on G is the sense that to construct an instance of F you need some number of instances of G. (For example, F could be some message an application emits, and instances of G would be components of such messages.)

**G.hpp**

```
#ifndef G_HPP
#define G_HPP
struct G
{
G() {} // ...
};
inline G operator+(G, G) { return G(); }
#endif
```

**Gs.hpp**

```
#ifndef GS_HPP
#define GS_HPP
#include "G.hpp"
extern const G g1;
extern const G g2;
extern const G g3;
extern const G g4;
extern const G g5;
extern const G g6;
extern const G g7;
extern const G g8;
extern const G g9;
#endif
```

**Gs.cpp**

```
#include "Gs.hpp"
const G g1;
const G g2;
const G g3;
const G g4;
const G g5;
const G g6;
const G g7;
const G g8;
const G g9;
```

**F.hpp**

```
#ifndef F_HPP
#define F_HPP
#include "G.hpp"
struct F
{
F(G) {} // ...
};
#endif
```

**Fs.hpp**

```
#ifndef FS_HPP
#define FS_HPP
#include "F.hpp"
extern const F f1;
extern const F f2;
extern const F f3;
#endif
```

**Fs.cpp**

```
#include "Fs.hpp"
#include "Gs.hpp"
const F f1(g1 + g2 + g3);
const F f2(g4 + g5 + g6);
const F f3(g7 + g8 + g9);
```

F's constructor takes an argument which is the result of applying
`operator+`

to instances of G. Since the instances of both F and G are
global variables, there is not guarantee that the instances of G have
been initialized when the constructor of F needs them.

The particularity here is that there are many Gs and Fs all over the place, and I would like to keep the syntax as much as possibly close to the code posted above, while still enforcing the construction of a G whenever an F needs it.