I want to find out all eigenvalues and relevant right eigenvectors using lapack. However, the code could just work in small matrix size. While the size of my matrix is over some specific number like 300, it collapsed and all I got is segmentation fault (core dumped). I checked my code several times and still could not find out where the problem is. Following is my code.

```
program Eigenvalue
! finding the eigenvalues of a complex matrix using LAPACK
! http://www.netlib.org/lapack/complex16/zgeev.f
!find out the inverse complex matrix in fortran
Implicit none
!matrix dimension
integer, parameter::N=300
integer,parameter::M=3*(N-1)
! declarations, notice double precision
! A and B are matrices with given value while inver is inverse matrix of A
! S is to check whether inverse matrix is right or not
real*8,allocatable,dimension(:,:)::A
real*8,allocatable,dimension(:,:)::Inver
real*8,allocatable,dimension(:,:)::B
real*8,allocatable,dimension(:,:)::S
!Mul is the matrix to be calculated in the subroutine and its values are
!product of inverse matrix and B
!eigval represents eigenvalues while Vec are eigenvectors
complex*16,allocatable,dimension(:,:):: Mul,DUMMY,Vec
complex*16,allocatable,dimension(:)::eigval,WORK1
double precision::WORK2(2*M)
integer i,j,ok,temp,error
!specific parameters in this case to define A and B
real*8 ky,k,lb,ln,kz,ni,to
real*8 x,dx
real*8::x0=-30.d0,x1=30.d0
real*8 co1,co2,co3,co4
allocate(A(M,M),B(M,M),Inver(M,M),S(M,M),stat=error)
if (error.ne.0)then
print *,"error:not enough memory"
stop
end if
allocate(Mul(M,M),DUMMY(M,M),Vec(M,M),eigval(M),WORK1(2*M),stat=error)
if (error.ne.0)then
print *,"error:not enough memory"
stop
end if
!values of parameters
ni=5
to=1
ln=10.d0
lb=50.d0
ky=0.4d0
kz=0.002d0
k=(1.d0+ni)/to
dx=(x1-x0)/N
x=x1-dx
co1=(1+ky*ky)*dx*dx-2
co2=ky*(-2*k+(1-k*ky*ky)*dx*dx)
co3=dx*dx*(kz-ky*(x/lb)**2)
co4=ky*k
call mkl_set_num_threads( 2 )
!definition of the initial matrix A
do i=1,M
do j=1,N-1
if(j.eq.i)then
A(i,j)=-2+(1+ky*ky)*dx*dx
else if (j.eq.(i+1)) then
A(i,j)=-1
else if (j.eq.(i-1).and.j.ne.(N-1)) then
A(i,j)=-1
else if(j.eq.(i-1).and.j.eq.(N-1))then
A(i,j)=0
else
A(i,j)=(0,0)
end if
end do
do j=N,M
if(j.eq.i)then
A(i,j)=1
else
A(i,j)=0
end if
end do
end do
call inverse(A,Inver,M)
!definition of matrix B and the multiplication Mul
do i=1,M
do j=1,N-1
if(j.eq.i)then
B(i,j)=ky*((1-k*ky*ky)*dx*dx-2*k)
else if (j.eq.(i+1)) then
B(i,j)=ky*k
else if (j.eq.(i-1).and.j.ne.(N-1)) then
B(i,j)=ky*k
else if (j.eq.(i-1).and.j.eq.(N-1))then
B(i,j)=0
else if(j.eq.(i-N+1)) then
B(i,j)=kz-((x0+j*dx)**2)*ky/(lb*lb)
else if (j.eq.(i-2*N+2)) then
B(i,j)=k*ky
else
B(i,j)=0
end if
end do
do j=N,2*(N-1)
if(j.eq.(i+N-1))then
B(i,j)=(kz-((x0+i*dx)**2)*ky/(lb*lb))*dx*dx
else
B(i,j)=0
end if
end do
do j=2*N-1,M
if(j.eq.(i+N-1)) then
B(i,j)=kz-((x0+(i-N+1)*dx)**2)*ky/(lb*lb)
else
B(i,j)=0
end if
end do
end do
Mul=matmul(Inver,B)
call ZGEEV('N', 'V', M,Mul, M, eigval, DUMMY, M, Vec, M, WORK1, 2*M, WORK2, ok)
deallocate(A,B,Inver,S,stat=error)
if (error.ne.0)then
print *,"error:fail to release"
stop
end if
deallocate(Mul,DUMMY,Vec,eigval,WORK1,stat=error)
if (error.ne.0)then
print *,"error:failed to release"
stop
end if
end
subroutine inverse(a,c,n)
!============================================================
! Inverse matrix
! Method: Based on Doolittle LU factorization for Ax=b
! Alex G. December 2009
!this is for real numbers
!-----------------------------------------------------------
! input ...
! a(n,n) - array of coefficients for matrix A
! n - dimension
! output ...
! c(n,n) - inverse matrix of A
! comments ...
! the original matrix a(n,n) will be destroyed
! during the calculation
!===========================================================
implicit none
integer n
double precision a(n,n), c(n,n)
double precision,allocatable,dimension(:,:):: L, U
double precision,allocatable,dimension(:):: b, d, x
double precision coeff
integer i, j, k,error
allocate(L(n,n),U(n,n),b(n),d(n),x(n),stat=error)
if (error.ne.0)then
print *,"error:not enough memory"
stop
end if
! step 0: initialization for matrices L and U and b
! Fortran 90/95 allows such operations on matrices
L=0.0
U=0.0
b=0.0
! step 1: forward elimination
do k=1, n-1
do i=k+1,n
coeff=a(i,k)/a(k,k)
L(i,k) = coeff
do j=k+1,n
a(i,j) = a(i,j)-coeff*a(k,j)
end do
end do
end do
! Step 2: prepare L and U matrices
! L matrix is a matrix of the elimination coefficient
! + the diagonal elements are 1.0
do i=1,n
L(i,i) = 1.0
end do
! U matrix is the upper triangular part of A
do j=1,n
do i=1,j
U(i,j) = a(i,j)
end do
end do
! Step 3: compute columns of the inverse matrix C
do k=1,n
b(k)=1.0
d(1) = b(1)
! Step 3a: Solve Ld=b using the forward substitution
do i=2,n
d(i)=b(i)
do j=1,i-1
d(i) = d(i) - L(i,j)*d(j)
end do
end do
! Step 3b: Solve Ux=d using the back substitution
x(n)=d(n)/U(n,n)
do i = n-1,1,-1
x(i) = d(i)
do j=n,i+1,-1
x(i)=x(i)-U(i,j)*x(j)
end do
x(i) = x(i)/u(i,i)
end do
! Step 3c: fill the solutions x(n) into column k of C
do i=1,n
c(i,k) = x(i)
end do
b(k)=0.0
end do
deallocate(L,U,b,d,x,stat=error)
if (error.ne.0)then
print *,"error:failed to deallocate"
stop
end if
end subroutine inverse
```

Hope someone can give me a tip or advice about why the segmentation fault occurs when N is over 300.