# Pass Module Name as Function Input in Fortran

I am interested in writing a function that takes as one of its inputs a module name to use. For instance, I've written a Runge Kutta 4th order integrator that is used to solve a system of ODEs. I would prefer to write the actual Runge Kutta integration function so that there is an input to the function that defines the system of ODEs.

Here's an example module containing a function defining a system of ODEs

``````MODULE DIFF_EQ
! Description: This module contains the function that defines the
!              system of ODEs to be solved.

CONTAINS

FUNCTION YDOT(t, y, PP) RESULT(yd)
! Description: This function defines the system of ODEs to be
!              solved.
!
! Inputs:   t - current independent variable value (real, scalar)
!           y - current dependent variable value (real, array)
!          PP - passed parameters/constants (real, array)
!
! Outputs: yd - current value of ODE (real, array)

IMPLICIT NONE

REAL*8, INTENT(IN)               :: t
REAL*8, DIMENSION(2), INTENT(IN) :: y
REAL*8, DIMENSION(3), INTENT(IN) :: PP
REAL*8, DIMENSION(2)             :: yd

yd = [y(2), &
-PP(1)*SIN(y(1)) + SIN(PP(2)*t) + PP(3)]

END FUNCTION YDOT

END MODULE DIFF_EQ
``````

And here is the Runge Kutta integration module

``````MODULE RUNGE_KUTTA
! Description: This module contains the function that implements the Runge Kutta 4th
!              order integration scheme.

CONTAINS

FUNCTION RK4(Neq, tspan, y0, dt, DEQ, PP) RESULT(t_y)
! Description: This function implements the Runge Kutta 4th order integration scheme.
!
! Inputs: Neq   - number of equations in system of ODEs (integer, scalar)
!         tspan - [t0, tF] where t0 is start time and tF is end time (real, array - 2)
!         y0    - [y1, y2, ..., yNeq] @ t0 (real, array - Neq)
!         dt    - time step size such that t1 = t0 + dt (real, scalar)
!         PP    - passed parameters/constants (real, array - variable)
!
! Outputs: t_y  - time and solution (real, matrix - n x Neq + 1)

USE DIFF_EQ

IMPLICIT NONE

INTEGER, INTENT(IN)                  :: Neq
REAL*8, DIMENSION(2), INTENT(IN)     :: tspan
REAL*8, DIMENSION(Neq), INTENT(IN)   :: y0
REAL*8                               :: dt
REAL*8, EXTERNAL                     :: DEQ
REAL*8, DIMENSION(:), INTENT(IN)     :: PP
INTEGER                              :: n, i
REAL*8, DIMENSION(:,:), ALLOCATABLE  :: t_y
REAL*8, DIMENSION(Neq)               :: k1, k2, k3, k4

n = CEILING((tspan(2) - tspan(1))/dt + 1.0D0)
ALLOCATE(t_y(n, Neq+1))

IF (MOD(tspan(2) - tspan(1), dt) .LT. 0.000000000000001D0) THEN
t_y(1:n, 1) = [(tspan(1) + dt*(i-1), i = 1, n)]
ELSE
t_y(1:n, 1) = [(tspan(1) + dt*(i-1), i = 1, n-1), tspan(2)]
ENDIF

t_y(1, 2:Neq+1) = y0

PRINT *, t_y(1, 1:Neq+1)

DO i = 2, n
dt = t_y(i, 1) - t_y(i-1, 1)
k1 = DEQ(t_y(i-1, 1),            t_y(i-1, 2:Neq+1),               PP)
k2 = DEQ(t_y(i-1, 1) + 0.5D0*dt, t_y(i-1, 2:Neq+1) + 0.5D0*dt*k1, PP)
k3 = DEQ(t_y(i-1, 1) + 0.5D0*dt, t_y(i-1, 2:Neq+1) + 0.5D0*dt*k2, PP)
k4 = DEQ(t_y(i-1, 1) + dt,       t_y(i-1, 2:Neq+1) + dt*k3,       PP)
t_y(i, 2:Neq+1) = t_y(i-1, 2:Neq+1) + 0.16666666666666667D0*dt*(k1 + 2.0D0*k2 + 2.0D0*k3 + k4)

PRINT *, t_y(i, 1:Neq+1)
ENDDO

END FUNCTION RK4

END MODULE RUNGE_KUTTA
``````

And the main program that takes the inputs and calls the functions

``````PROGRAM RK4_TEST

USE DIFF_EQ
USE RUNGE_KUTTA

IMPLICIT NONE

INTEGER                             :: Neq
REAL*8, DIMENSION(2)                :: tspan
REAL*8, DIMENSION(2)                :: y0
REAL*8                              :: dt
REAL*8, DIMENSION(3)                :: PP
INTEGER                             :: n
REAL*8, DIMENSION(:,:), ALLOCATABLE :: t_y

Neq   = 2
tspan = [0.0D0, 1.0D0]
y0    = [1.0D0, 0.0D0]
dt    = 0.1D0
PP    = [1.0D0, 5.0D0, 0.0D0]

n = CEILING((tspan(2) - tspan(1))/dt + 1.0D0)

ALLOCATE(t_y(n, Neq+1))

t_y = RK4(Neq, tspan, y0, dt, YDOT, PP)

END PROGRAM RK4_TEST
``````

Using gfortran, this is compiled by

``````gfortran DIFF_EQ.f90 RUNGE_KUTTA.f90 RK4_TEST.f90 -o MAIN.exe
``````

It compiles without error but I receive a `Segmentation fault (core dumped)` message when I try to run it.

Thanks for any help provided.

-

You can pass a function to your solver. That should be sufficient for making your solver general, able to handle various functions. Make your solver take a function as an argument, then call it with actual argument of the particular function that you wish to solve. Or you can call it with a function pointer, with each call having the pointer pointing to the function that you wish to solve. In your example, you don't pass modules similar to `DIFF_EQ`, you pass functions similar to `YDOT`. Here is an example with function pointers: Function pointer arrays in Fortran

EDIT: OK, here is a code sample. I have shown how a second function can be passed to the solver. By using an interface statement to declare the function in the solver, the module doesn't have to be used in the solver. The functions could easily be in different modules and the source code of the solver would not need to be modified, just the source code of the calling program.

``````MODULE DIFF_EQ

use ISO_FORTRAN_ENV

! Description: This module contains the function that defines the
!              system of ODEs to be solved.

CONTAINS

FUNCTION YDOT(t, y, PP) RESULT(yd)
! Description: This function defines the system of ODEs to be
!              solved.
!
! Inputs:   t - current independent variable value (real, scalar)
!           y - current dependent variable value (real, array)
!          PP - passed parameters/constants (real, array)
!
! Outputs: yd - current value of ODE (real, array)

IMPLICIT NONE

real (real64), INTENT(IN) :: t
real (real64), INTENT(IN) :: y(2)
real (real64), INTENT(IN) :: PP(3)
real (real64)             :: yd(2)

yd = [y(2), -PP(1)*SIN(y(1)) + SIN(PP(2)*t) + PP(3)]

END FUNCTION YDOT

FUNCTION YDOT2 (t, y, PP) RESULT(yd)
! Description: This function defines the system of ODEs to be
!              solved.
!
! Inputs:   t - current independent variable value (real, scalar)
!           y - current dependent variable value (real, array)
!          PP - passed parameters/constants (real, array)
!
! Outputs: yd - current value of ODE (real, array)

IMPLICIT NONE

real (real64), INTENT(IN) :: t
real (real64), INTENT(IN) :: y(2)
real (real64), INTENT(IN) :: PP(3)
real (real64)             :: yd(2)

yd = [y(2), -PP(1)*cos(y(1)) + cos(PP(2)*t) + PP(3)]

END FUNCTION YDOT2

END MODULE DIFF_EQ

!+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

MODULE RUNGE_KUTTA

use ISO_FORTRAN_ENV
! Description: This module contains the function that implements the Runge Kutta 4th
!              order integration scheme.

CONTAINS

FUNCTION RK4(DEQ_func, Neq, tspan, y0, dt, PP) RESULT(t_y)
! Description: This function implements the Runge Kutta 4th order integration scheme.
!
! Inputs: Neq   - number of equations in system of ODEs (integer, scalar)
!         tspan - [t0, tF] where t0 is start time and tF is end time (real, array - 2)
!         y0    - [y1, y2, ..., yNeq] @ t0 (real, array - Neq)
!         dt    - time step size such that t1 = t0 + dt (real, scalar)
!         PP    - passed parameters/constants (real, array - variable)
!
! Outputs: t_y  - time and solution (real, matrix - n x Neq + 1)

IMPLICIT NONE

interface

function  DEQ_func ( t, y, pp )  result (yd)

use ISO_FORTRAN_ENV
real (real64), INTENT(IN) :: t
real (real64), dimension (2), INTENT(IN) :: y
real (real64), dimension (3), INTENT(IN) :: PP
real (real64), dimension (2)             :: yd

end function DEQ_func

end interface

INTEGER, INTENT(IN)                  :: Neq
real (real64), DIMENSION(2), INTENT(IN)     :: tspan
real (real64), INTENT(IN)                   :: y0(Neq)
real (real64)                               :: dt
real (real64), INTENT(IN)                   :: PP(:)
INTEGER                              :: n, i
real (real64), DIMENSION(:,:), ALLOCATABLE  :: t_y
real (real64)                               :: k1(Neq), k2(Neq), k3(Neq), k4(Neq)

n = CEILING((tspan(2) - tspan(1))/dt + 1.0D0)
ALLOCATE(t_y(n, Neq+1))

IF (MOD(tspan(2) - tspan(1), dt) .LT. 0.000000000000001D0) THEN
t_y(1:n, 1) = [(tspan(1) + dt*(i-1), i = 1, n)]
ELSE
t_y(1:n, 1) = [(tspan(1) + dt*(i-1), i = 1, n-1), tspan(2)]
ENDIF

t_y(1, 2:Neq+1) = y0

PRINT *, t_y(1, 1:Neq+1)
DO i = 2, n
dt = t_y(i, 1) - t_y(i-1, 1)
k1 = DEQ_func(t_y(i-1, 1),              t_y(i-1, 2:Neq+1),                 PP)
k2 = DEQ_func(t_y(i-1, 1) + 0.5D0*dt, t_y(i-1, 2:Neq+1) + 0.5D0*dt*k1, PP)
k3 = DEQ_func(t_y(i-1, 1) + 0.5D0*dt, t_y(i-1, 2:Neq+1) + 0.5D0*dt*k2, PP)
k4 = DEQ_func(t_y(i-1, 1) + dt,         t_y(i-1, 2:Neq+1) + dt*k3,         PP)
t_y(i, 2:Neq+1) = t_y(i-1, 2:Neq+1) + 0.16666666666666667D0*dt*(k1 + 2.0D0*k2 + 2.0D0*k3 + k4)

PRINT *, t_y(i, 1:Neq+1)
ENDDO

END FUNCTION RK4

END MODULE RUNGE_KUTTA

!+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

PROGRAM RK4_TEST

USE RUNGE_KUTTA
use DIFF_EQ

IMPLICIT NONE

INTEGER                             :: Neq
real (real64), DIMENSION(2)                :: tspan
real (real64), DIMENSION(2)                :: y0
real (real64)                              :: dt
real (real64), DIMENSION(3)                :: PP
INTEGER                             :: n
real (real64), DIMENSION(:,:), ALLOCATABLE :: t_y

Neq   = 2
tspan = [0.0D0, 1.0D0]
y0    = [1.0D0, 0.0D0]
dt     = 0.1D0
PP    = [1.0D0, 5.0D0, 0.0D0]

n = CEILING((tspan(2) - tspan(1))/dt + 1.0D0)

ALLOCATE(t_y(n, Neq+1))

write (*, '( // "calling to solve ydot:")' )
t_y = RK4( ydot, Neq, tspan, y0, dt, PP)

write (*, '( // "calling to solve ydot2:")' )
t_y = RK4( ydot2, Neq, tspan, y0, dt, PP)

END PROGRAM RK4_TEST
``````
-
So would you suggest that I contain all of my functions defining systems of ODEs such as `YDOT` within the `DIFF_EQ` module and then pass the function of ODEs I want to solve at that time? For instance, `DIFF_EQ` would contain `YDOT_1`, `YDOT_2`, ...., `YDOT_N`. That way, my Runge Kutta solver would always `USE DIFF_EQ` but the function I pass to the solver would be different. –  Stephen Jul 4 at 6:24
Yes. One or more modules containing the functions. Pass whichever function you wish to solve to the Runge Kutta solver, either directly or via a function pointer. The Runge Kutta solver can either `use` the module, or it can have an interface statement declaring the function is solves. The second way it is more general, if later you wish to solve functions in a different module. –  M. S. B. Jul 4 at 13:35
thanks so much for the code sample. I had read about the interface block but didn't quite understand how it fit in for my needs. Your code sample should clear a lot of things up for me. –  Stephen Jul 6 at 6:47