**Update:** This is a pure **Fortran question now**; I put the maths stuff on M.SE.

Consider a `P`

x`P`

symmetric and positive definite matrix `A`

(P=70000, i.e. `A`

is roughly 40 GB using 8-byte doubles). We want to calculate the first three diagonal elements of the inverse matrix `inv(A)[1,1]`

, `inv(A)[2,2]`

and `inv(A)[3,3]`

.

I have found this paper by James R. Bunch who seems to solve this exact problem without calculating the full inverse `inv(A)`

; **unfortunately he uses Fortran and LINPACK, both of which I've never used**.

I'm trying to understand this function:

```
SUBROUTINE SOLVEJ(A,LDA,P,Y,J)
INTEGER LDA,P,J
REAL A(LDA,1),Y(1)
C
INTEGER K
Y(J) = 1/A(J,J)
DO 10 K = J + 1,P
Y(K) = - SDOT(K - J,A(J,K),1,Y(J),1)/A(K,K)
10 CONTINUE
RETURN
END
```

where `A`

is a matrix of size LDA x P and `Y`

is a vector of length P.

Can you explain **why he defines Y(1) in the function head but then assigns to Y(J)?** Does Fortran just not care about the size of the defined array and lets you access beyond its end? Why not define

`Y(P)`

, which seems possible according to this Fortran Primer?
`mldivide`

`lu`

,`qr`

, etc, are called from LAPACK. – Dang Khoa Sep 13 '11 at 21:49theyare part of LAPACK. I have searched the docs but not found them, so I fear the answer in no. – Jonas Heidelberg Sep 13 '11 at 21:58