You can basically do that (as also mentioned in Vladimir's answer) with defining functor objects. They have one specific function returning the value (e.g. `getvalue()`

), and depending on their initialization, they may return customized function values.

The example below demonstrates that in detail. The general functor is defined in `functor_module`

, in `expfunc_module`

a concrete realization for the exponential function family is derived. Then, in the main program then you initialize different instances with different prefactors in the exponents and can use their `getvalue()`

method to obtain the appropriate function values.:

```
module functor_module
implicit none
integer, parameter :: wp = kind(1.0d0)
type, abstract :: functor
contains
procedure(getvalue_iface), deferred :: getvalue
end type functor
interface
function getvalue_iface(self, xx) result(yy)
import
class(functor), intent(in) :: self
real(wp), intent(in) :: xx
real(wp) :: yy
end function getvalue_iface
end interface
end module functor_module
module expfunc_module
use functor_module
implicit none
type, extends(functor) :: expfunc
real(wp) :: aa
contains
procedure :: getvalue
end type expfunc
contains
function getvalue(self, xx) result(yy)
class(expfunc), intent(in) :: self
real(wp), intent(in) :: xx
real(wp) :: yy
yy = exp(self%aa * xx)
end function getvalue
end module expfunc_module
program test_functors
use expfunc_module
implicit none
type(expfunc) :: func1, func2
real(wp) :: xx
func1 = expfunc(1.0_wp)
func2 = expfunc(2.0_wp)
xx = 1.0_wp
print *, func1%getvalue(xx) ! gives exp(1.0 * xx) = 2.718...
print *, func2%getvalue(xx) ! gives exp(2.0 * xx) = 7.389...
end program test_functors
```