# Receiving NaN value in Fortran app

I'm developing an Fortran application for numerically solving Boundary Value Problem for second order ODE of the type: -y''+q(x)*y=r(x). In this application I use Gauss-ellimination algorithm to solve the linear system of equations and write the solution in file. But for the solution vector I receive NaN. Why is that happen? Here is some code.

``````      subroutine gaussian_solve(s, c, error)

double precision, dimension(:,:), intent(in out) :: s
double precision, dimension(:),   intent(in out) :: c
integer        :: error

if(error == 0) then
call back_substitution(s, c)
end if

end subroutine gaussian_solve
!=========================================================================================

!================= Subroutine gaussian_ellimination ===============================
subroutine gaussion_ellimination(s, c, error)

double precision, dimension(:,:), intent(in out) :: s
double precision, dimension(:),   intent(in out) :: c
integer,            intent(out)  :: error

real, dimension(size(s, 1)) :: temp_array
integer, dimension(1)       :: ksave
integer                     :: i, j, k, n
real                        :: temp, m

n = size(s, 1)

if(n == 0) then
error = -1
return
end if

if(n /= size(s, 2)) then
error = -2
return
end if

if(n /= size(s, 2)) then
error = -3
return
end if

error = 0
do i = 1, n-1
ksave = maxloc(abs(s(i:n, i)))
k = ksave(1) + i - 1
if(s(k, i) == 0) then
error = -4
return
end if

if(k /= i) then
temp_array = s(i, :)
s(i, :) = s(k, :)
s(k, :) = temp_array
temp = c(i)
c(i) = c(k)
c(k) = temp
end if

do j = i + 1, n
m = s(j, i)/s(i, i)
s(j, :) = s(j, :) - m*s(i, :)
c(j) = c(j) - m*c(i)
end do
end do

end subroutine gaussion_ellimination
!==========================================================================================

!================= Subroutine back_substitution ========================================
subroutine back_substitution(s, c)

double precision, dimension(:,:), intent(in) :: s
double precision, dimension(:),   intent(in out) :: c

real    :: w
integer :: i, j, n

n = size(c)

do i = n, 1, -1
w = c(i)
do j = i + 1, n
w = w - s(i, j)*c(j)
end do
c(i) = w/s(i, i)
end do

end subroutine back_substitution
``````

Where s(i, j) is the matrix of coefficients of the system and c(i) is the solution vector.

-

In the code above, there should presumably be a `call gaussion_ellimination(s, c, error)` near the start of your `gaussian_solve` routine, your `temp_array` (and `temp` and `m` and `w`) should also be double precision to avoid losing precision from your double precision matrix, checking for exact equality to floating point zero is a risky strategy, and I'd check your input matrix - if there are any linear degeneracies you will get all NaNs (particularly if it's the last row vector which is linearly degenerate with any of the earlier ones).