FORTRAN was designed to solve scientific and engineering problems. Column-major storage is more natural from a scientific point of view, since the general linear algebra convention uses column-vectors and often treats matrices as concatenations of column-vectors. In matrix-vector multiplications, column-vectors reside on the right side (post-multiplication), with successive matrices added further on the left side, e.g. `B*(A*x)`

. Languages such as COBOL, PL/1, and C treat matrices as collections of row-records, hence for them the row-major order is more natural.

In linear algebra, a vector is represented by its coordinates: `x = x[1]*e1 + x[2]*e2 + ... + x[n]*en`

where `x[i]`

are the vector coordinates and `ei`

is the `i`

-th basis vector. In matrix representation, the basis vectors are column-vectors. A linear operator `A`

then, acting on `x`

, gives:

```
y = A*x = A*{x[1]*e1 + x[2]*e2 + ... x[n]*en}
= x[1]*(A*e1) + x[2]*(A*e2) + ... x[n]*(A*en)
```

In matrix representation, the linear operator `A`

consists of `n`

columns, with column `i`

being the result of `A`

acting on the `i`

-th basis vector, and `A*x`

is then simply the linear combination of the columns of `A`

with coefficients coming for the coordinates of `x`

. In FORTRAN this would be:

```
! Zero out the result vector
DO k = 1,n
y(k) = 0.0
END DO
! Iterate over the columns of A
DO i = 1,n
! Add the i-th column to the linear combination with a weight of x(i)
w = x(i)
DO k = 1,n
y(k) = y(k) + w*A(k,i)
END DO
END DO
```

This automatically gives preference to column-major storage of `A`

. It might seem awkward, but back in the 50's, when FORTRAN was born, FMAC hardware and register optimisations were not at all that popular like they are now.