# Different results for similar C and Fortran code

This is an observation from a homework (past deadline) for which we had to use Eulers explicit scheme to investigate a predator-prey model. I compare the Fortran and C code (given below), and I cannot explain why there is a difference in the result, when I compare the Fortran code and the C code.

C code:

``````#include <stdio.h>

//Functions for Euler Explicit
float FR(float R,float F,float alpha)
{
return (2*R - alpha*R*F);
}

float FF(float R,float F,float alpha)
{
return (-F + alpha*R*F);
}

int main()
{
int N;
float alpha,initR,initF,bigR,h;

/* Data Setup */
alpha   = 0.001;
initR   = 15;
initF   = 22;
N       = 50;
bigR    = 400;
h       = 0.01;

float R0,F0,R1,F1;
int i;

R0 = initR;
F0 = initF;

for (i = 0; i < N; i++)
{
R1 = R0 + h*FR(R0,F0,alpha);
F1 = F0 + h*FF(R0,F0,alpha);
printf("%d\t%f\t%f\n",i,R1,F1);
R0 = R1;
F0 = F1;
}

return 0;
}
``````

Now the Fortran version, the initialization parameters are exactly identical to the C version above.

``````! EULER EXPLICIT
SUBROUTINE eulers_explicit (initR,initF,N,alpha,h)
IMPLICIT NONE
REAL    :: R0,F0,R1,F1,initF,initR,alpha,h
INTEGER I,N

R0 = initR
F0 = initF

DO I=1,N
R1 = R0 + h*FR(R0,F0,alpha)
F1 = F0 + h*FF(R0,F0,alpha)
PRINT *,I,R1,F1
R0 = R1
F0 = F1
END DO
END SUBROUTINE eulers_explicit
! EULER EXPLICIT

REAL FUNCTION FR(R,F,alpha)
REAL, INTENT(IN)        :: F,alpha
REAL, INTENT(INOUT)     :: R

R = 2*R - alpha*R*F
FR = R
END FUNCTION FR

REAL FUNCTION FF(R,F,alpha)
REAL, INTENT(IN)        :: R,alpha
REAL, INTENT(INOUT)     :: F

F = -F + alpha*R*F
FF = F
END FUNCTION FF

PROGRAM solve
USE usual_routines
IMPLICIT NONE
INTEGER :: N
REAL :: alpha,initR,initF,h

alpha   = 0.001
initR   = 15
initF   = 22
N       = 50
h       = 0.01

PRINT *, "Eulers explicit method: "
CALL eulers_explicit (initR,initF,N,alpha,h)

END PROGRAM solve
``````

Now the results, snapshot of results from C code:

``````   0    15.296700   21.783300
1    15.599301   21.568800
2    15.907923   21.356476
3    16.222683   21.146309
4    16.543707   20.938276
5    16.871117   20.732357
6    17.205042   20.528532
7    17.545610   20.326778
8    17.892956   20.127077
9    18.247213   19.929407
10   18.608521   19.733749
``````

Results from Fortran code:

``````       0   29.9666996      -21.5607319
1   61.1852989       20.4571381
2   122.330109      -18.1591854
3   249.350449       13.8127756
4   500.209259      -7.04162502
5   1013.98022      -2.80275159E-02
6   2048.26880      -2.91000959E-02
7   4137.56299      -9.10123810E-02
8   8358.25781     -0.668782473
9   16889.3262      -10.6198158
10   34297.5977      -353.508148
``````

Why do I see this divergence? I am using gfortran (v4.7.2), and running this on my laptop having Arch Linux on Intel i7.

EDIT:

This is the fix.

``````REAL FUNCTION FR(R,F,alpha)
REAL, VALUE :: F,alpha
REAL, VALUE :: R

R = 2*R - alpha*R*F
FR = R
END FUNCTION FR
``````

Note the `VALUE` for pointer-disassociation.

-
I suggest you add some more debugging points, in order to track down where in the code the discrepancy occurs. –  Oli Charlesworth Mar 26 '13 at 21:51
why `float`? Without a very good reason otherwise, always prefer `double` for floating-point values in C. –  pmg Mar 26 '13 at 21:52
Please post an SSCCE. I am sure you can reduce this code and still reproduce the issue. –  djechlin Mar 26 '13 at 21:58
Note that Fortran procedures that have a dummy argument with the VALUE attribute must have an explicit interface - your fix is not valid in isolation of other changes. –  IanH Mar 26 '13 at 22:51
This is indeed an important factor as I learned, thanks for pointing this out. –  Sayan Mar 27 '13 at 14:16

In `FF`, pass `F` by reference. In `FR`, pass `R` by reference. Update `F` and `R` like the fortran code does.