In clang's implementation of `tgmath.h`

it appears that `__tg_promote`

is in fact a *function*, and not a macro. The definition can be found here.

```
typedef void _Argument_type_is_not_arithmetic;
static _Argument_type_is_not_arithmetic __tg_promote(...)
__attribute__((__unavailable__,__overloadable__));
static double _TG_ATTRSp __tg_promote(int);
static double _TG_ATTRSp __tg_promote(unsigned int);
static double _TG_ATTRSp __tg_promote(long);
static double _TG_ATTRSp __tg_promote(unsigned long);
static double _TG_ATTRSp __tg_promote(long long);
static double _TG_ATTRSp __tg_promote(unsigned long long);
static float _TG_ATTRSp __tg_promote(float);
static double _TG_ATTRSp __tg_promote(double);
static long double _TG_ATTRSp __tg_promote(long double);
static float _Complex _TG_ATTRSp __tg_promote(float _Complex);
static double _Complex _TG_ATTRSp __tg_promote(double _Complex);
static long double _Complex _TG_ATTRSp __tg_promote(long double _Complex);
```

It's a function with multiple overloads (not allowed in C in general) and no definition, which is fine because it's never actually called! `__tg_promote`

is only used to determine the type that a numeric type should be promoted to. (Integral types to `double`

; floating point types to themselves.) This is clear when you look at the next few macros:

```
#define __tg_promote1(__x) (__typeof__(__tg_promote(__x)))
#define __tg_promote2(__x, __y) (__typeof__(__tg_promote(__x) + \
__tg_promote(__y)))
#define __tg_promote3(__x, __y, __z) (__typeof__(__tg_promote(__x) + \
__tg_promote(__y) + \
__tg_promote(__z)))
```

The `__tg_promote`

function isn't being called because it occurs inside the compiler-specific `__typeof__`

macro. The `__tg_promote1`

macro simply expands to the *promoted type* of its argument, within parentheses. `__tg_promote2`

expands to the type (again parenthesis-enclosed) that would result if two values of the promoted types of its arguments were added. So for example, `__tg_promote2(0.0f, 0)`

would be `(double)`

, since adding a `float`

and a `double`

(result of promoting `int`

) gives a `double`

. `__tg_promote3`

is similar.

The remainder of the header consists of overloaded definitions of functions that delegate to the respective ordinary C functions:

```
// atan2
static float
_TG_ATTRS
__tg_atan2(float __x, float __y) {return atan2f(__x, __y);}
static double
_TG_ATTRS
__tg_atan2(double __x, double __y) {return atan2(__x, __y);}
static long double
_TG_ATTRS
__tg_atan2(long double __x, long double __y) {return atan2l(__x, __y);}
```

In order to be able to call, say, `atan2(1.0f, 1)`

we need to be able to delegate to `__tg_atan2(double, double)`

. This is where `__tg_promote2`

comes in to determine that when we have one `float`

argument and one `int`

argument, both should be converted to `double`

:

```
#define atan2(__x, __y) __tg_atan2(__tg_promote2((__x), (__y))(__x), \
__tg_promote2((__x), (__y))(__y))
```

So in this case `__tg_promote2((__x), (__y))`

expands to `(double)`

and we get `__tg_atan2((double)(__x), (double)(__y))`

, which is exactly what we want.