If you change the initialization of `cMyConstDouble2`

to this here:

```
const double cMyConstDouble2 = 2.5*3.14;
```

Then your program should behave correct. The reason for this is that variables that

- Have POD type
- Are initialized with constant expressions
*(1)*

are initialized at static initialization time. These initializations include

- Zero initialization of
*all* objects having static storage duration
- Initializations of PODs initialized with constant expressions

Of your shown variables, only `cMyConstDouble`

satisfies both conditions of being fully initialized at static initialization time. However, `cMyConstDouble2`

does not, since its initializer does not satisfy the requirements of a constant expression. In particular, it includes a variable that doesn't have integral type (here, it has floating point type). However, floating point *literals* *are* allowed in arithmetic constant expressions. That is why `2.5*3.14`

is an arithmetic constant expression. And that is why changing the initializer to that will require it to be statically initialized.

What will happen with `cMyConstDouble2`

if you stay with the non-constant expression? The answer is, you don't know. The Standard allows that variable to be statically initialized, but does not require it to do so. In your case, it was dynamically initialized - thus its value just after static initialization time was still zero. To get a feeling for how *complicated* that is, here is an example:

```
inline double fd() { return 1.0; }
extern double d1;
double d2 = d1; // unspecified:
// may be statically initialized to 0.0 or
// dynamically initialized to 1.0
double d1 = fd(); // may be initialized statically to 1.0
```

If the dynamic initialization doesn't change any other static storage variable (satisfied in *your* code) and when the static initialization would produce the same value as would be produced by dynamic initialization when all objects not required to be statically initialized would be initialized dynamically (also satisfied in *your* code) - then the variable is allowed to be initialized statically. These two conditions are also satisfied in the above code for both variables `d2`

and `d1`

:

Analysis of `d2`

`= d1`

does not change any other static storage variable
- When both
`d2`

and `d1`

are initialized dynamically, then `d2`

would be initialized to `0.0`

, because `d2`

is defined before `d1`

, and dynamic initialization of `d2`

would grab the value of `d1`

as of the state just after static initialization (where only zero initialization of `d1`

took place).

Analysis of `d1`

`= fd()`

does not change any other static storage variable
- When both
`d2`

and `d1`

are initialized dynamically, then `= fd()`

will initialize `d1`

to `1.0`

.

So, the compiler may initialize `d1`

statically to `1.0`

, because both conditions for optional-static-initialization are met.

*If* the compiler decides to initialize `d1`

and `d2`

dynamically, then `d2`

will be initialized to `0.0`

, since it will grab the value of `d1`

as it was just after zero initialization.

*However*, *if* the compiler decides to initialize `d1`

statically and `d2`

dynamically, then `d2`

will be initialized to `1.0`

, since the dynamic initialization of `d2`

will grab the fully initialized value of `d1`

as it was just after static initialization.

I'm not sure what the value of `d2`

is when `d1`

*and* `d2`

is initialized statically, though. That is, whether `d2`

is supposed to grab the `0.0`

or the `1.0`

, since there is no order defined for static initialization.

*(1)* Constant expressions include arithmetic constant expressions too (not only integral constant expressions), when considering initialization order of objects with static storage duration.