# Segmentation fault when passing a function as argument in a subroutine

I try to illustrate how to pass a function to a Newton Raphson procedure. I succeed with a very simple function (called unefonction see below) but it does not work with a function which has got parameters. This second fonction is called gaussienne and it takes one argument, x, and two optional arguments mu and sig. In my newton raphson procedure I called the fonction in this way : f(x). What is strange for me is that during the execution, the program does as if the optional parameters sig and mu were present but they don't... Thus I do not understand ...

Here is the module which contains the functions

module fonction

implicit none

! parametre pour la gaussienne
double precision :: f_sigma = 1.d0, f_mu = 0.d0

! pi accessible uniquement en interne
double precision, parameter :: pi = 3.14159265359d0

contains

double precision function unefonction(x)
! fonction : unefonction
! renvoie
!    $\frac{e^x - 10}{x + 2}$

implicit none

! arguments
double precision, intent(in) :: x

unefonction = (exp(x) - 10.) / (x + 2.)

end function unefonction

! * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *

double precision function gaussienne(x, mu, sig)
! fonction gaussienne
! utilise les parametres definis dans le module si
! mu et sig ne sont pas passes en argument

implicit none

! arguments
double precision, intent(in)           :: x
double precision, intent(in), optional :: mu, sig

! variables locales
double precision :: norme, moy, sigma

! sigma
if (present(sig)) then
write(*,*)"sig present"
sigma = sig
else
sigma = f_sigma
end if

! mu
if (present(mu)) then
write(*,*)"mu present"
moy = mu
else
moy = f_mu
end if

! calcul de la gaussienne
norme = 1.d0 / (sigma * sqrt(2.d0 * pi))
gaussienne = norme * exp(-(x - moy)**2 / (2.d0 * sigma**2))

end function gaussienne

end module fonction


Here is the module which contains the newton raphson procedure

module rechercheRacine

implicit none

contains

subroutine newtonRaphson(racine, f, eps, cible)

! recherche l'antecedant de cible

implicit none

! arguments
double precision, intent(inout)        :: racine
double precision, intent(in), optional :: cible, eps

! fonction dont on cherche la racine
double precision, external :: f

! variables locales
integer          :: compteur
double precision :: xold, xnew, delta, valcible
double precision :: threshold, fprim, fdex

! precision
if (present(eps)) then
threshold = eps
else
threshold = 1.d-10
end if

! valeur cible
if (present(cible)) then
valcible = cible
else
valcible = 0.d0
end if

write(*,*) "--------------------------------------------------------"
write(*,*) "                      NEWTON RAPHSON"
write(*,*) "--------------------------------------------------------"
write(*,"('x0    = ',e16.6)") racine
write(*,"('seuil = ',e16.6)") threshold
write(*,"('cible = ',e16.6)") valcible
write(*,*) "--------------------------------------------------------"
write(*,*) "                        ITERATIONS"
write(*,*) "--------------------------------------------------------"

! initialisation
compteur = 0
delta    = 1.d0
xold     = racine
write(*, '(i4,4e16.6)') compteur, f(xold), xold, 0., threshold

! iterations
do while (delta > threshold .and. compteur <= 100)

! calcul de la fonction en xold
fdex = f(xold) - valcible

! calcul de la derivee numerique
fprim  = (f(xold + threshold) - f(xold - threshold)) / (2.d0 * threshold)

! application de l'iteration de Newton Raphson
xnew = xold - fdex / fprim
delta = abs(xnew - xold)
compteur = compteur + 1

! affichage de la convergence
write(*, '(i4,4e16.6)') compteur, fdex, xnew, delta, threshold

! mise a jour de xstart
xold = xnew
end do

if (delta < threshold) then
racine = xnew
write(*, *) '--------------------------------------------------------'
write(*, *) '                        CONVERGE'
write(*, *) '--------------------------------------------------------'
write(*, *) 'A la convergence demandee, une solution est:'
write(*, "('x = ',e20.10,'    f(x) = ', e20.10)") racine, f(racine)
write(*, *)
else
write(*, *) '--------------------------------------------------------'
write(*, *) '                      NON CONVERGE'
write(*, *) '--------------------------------------------------------'
end if

end subroutine newtonRaphson

end module rechercheRacine


Here is the main program :

program main

! contient la subroutine newtonRaphson
use rechercheRacine

! contient la fonction
use fonction

implicit none

double precision :: racine, eps, cible

! appel de la subroutine newtonRaphson
! sans la valeur cible : cible (defaut = 0)
! sans la precision : eps (defaut 1d-10)
racine = 1.d0
call newtonRaphson(racine, unefonction)

! --------------------------------------------------------

! appel de la subroutine newtonRaphson
! avec pour cible 10
racine = 1.d0
eps    = 1.d-14
cible  = 10.d0
call newtonRaphson(racine, unefonction, eps, cible)

! --------------------------------------------------------

! parametre de la gaussienne
f_sigma = 2.d0
f_mu = 5.d0
! appel de la subroutine newtonRaphson
! passage des arguments sous la forme clef = valeur
cible = 0.1d0
racine = 2.d0
call newtonRaphson(cible = cible, f = gaussienne, racine = racine)

end program main


The main program works for the function called unefonction but it doesn't work for the gaussienne function.

Here is the error message :

Program received signal SIGSEGV: Segmentation fault - invalid memory reference.

Backtrace for this error:
#0  0x7F1B6F5890F7
#1  0x7F1B6F5896D4
#2  0x7F1B6EEEB49F
#3  0x4009D2 in __fonction_MOD_gaussienne at mod_fonction.f90:54
#4  0x40104D in __rechercheracine_MOD_newtonraphson at mod_racine.f90:59
#5  0x4016BA in MAIN__ at main.f90:40
Erreur de segmentation (core dumped)


I think that the invalid memory reference is due to the fact that the program does as if optional parameters sig and mu were present and thus looks for them while they are not.

-

Yes, the problem is that the function you pass indeed expects three arguments instead of one only. If you change the external declaration of f in the subroutine newtonRaphson

double precision, external :: f


to an explicit interface (which describes, how you really use it):

interface
double precision function f(x)
double precision, intent(in) :: x
end function f
end interface


your code won't even compile due to the mismatch in the number of parameters.

They are different ways to pass "parameters" to the function f which is called from the routine newtonRaphson:

• You could expect f to have two intent(in) arguments instead of one: Additional to the value x, it could take also a real array, which may be of arbitrary size and may contain the necessary parameters. That would require following interface:

interface
double precision function f(x, params)
double precision, intent(in) :: x
double precision, intent(in) :: params(:)
end function f
end interface


Those functions, which do not need parameters (like unefonction) would just not use the content of the second parameter, while others (like gaussienne) would take their parameters from it.

• You could make newtonRaphson to expect a given extensible type (class) with a type bound procedure returning the value for a given x-value. You can then create abritrary extensions of this type, which may calculate the value for the given x-value based on some parameters stored as fields in the extended type. Then the program could look like below (I stripped several parts), but it would require Fortran 2003 compiler:

module rechercheRacine
implicit none

type, abstract :: calculator
contains
procedure(getvalue_iface), deferred :: getvalue
end type calculator

interface
double precision function getvalue_iface(self, x)
import :: calculator
class(calculator), intent(in) :: self
double precision, intent(in) :: x
end function getvalue_iface
end interface

contains

subroutine newtonRaphson(racine, f, eps, cible)
double precision, intent(inout)        :: racine
class(calculator), intent(in)          :: f
double precision, intent(in), optional :: cible, eps

do while (delta > threshold .and. compteur <= 100)
fdex = f%getvalue(xold) - valcible
:
end do

end subroutine newtonRaphson

end module rechercheRacine

module fonction
use rechercheRacine
implicit none

type, extends(calculator) :: unefonction
contains
procedure :: getvalue => unefonction_getvalue
end type unefonction

type, extends(calculator) :: gaussienne
double precision :: mu = 0.0d0, sigma = 1.0d0
contains
procedure :: getvalue => gaussienne_getvalue
end type gaussienne

contains

double precision function unefonction_getvalue(self, x)
class(unefonction), intent(in) :: self
double precision, intent(in) :: x
unefonction_getvalue = (exp(x) - 10.) / (x + 2.)
end function unefonction_getvalue

double precision function gaussienne_getvalue(self, x)
class(gaussienne), intent(in) :: self
double precision, intent(in) :: x

:
gaussienne_getvalue = norme * exp(-(x - moy)**2 / (2.d0 * self%sigma**2))

end function gaussienne_getvalue

end module fonction

program main
use rechercheRacine
use fonction
implicit none

type(unefonction) :: fone
type(gaussienne) :: fgauss

:
call newtonRaphson(racine, fone)
call newtonRaphson(cible = cible, f = fgauss, racine = racine)

end program main

-
Nice answer. Actually, the external declaration was just a test that I forgave to delete. I thought that if a function/subroutine was in a module an explicit interface was automatically created. Am I wrong ? But I understand that the external declaration will remove the interface. I thought that the optional declaration of the parameters sig and mu was the reason why I did not get error at the compilation. – Ger Feb 25 '13 at 22:11