To my eyes, these two are using the same format, in that in both the first index is treated as the row, the second index is the column.
The looks may be deceiving, but in fact the first index in linmath.h is the column. C and C++ specify that in a multidimensional array defined like this
there are n times m elements of sometype in succession. If it is row or column major order solely depends on how you interpret the indices. Now OpenGL defines 4×4 matrices to be indexed in the following linear scheme
0 4 8 c
1 5 9 d
2 6 a e
3 7 b f
If you apply the rules of C++ multidimensional arrays you'd add the following column row designation
| 0 4 8 c
| 1 5 9 d
V 2 6 a e
m 3 7 b f
Which remaps the linear indices into 2-tuples of
0 -> 0,0
1 -> 0,1
2 -> 0,2
3 -> 0,3
4 -> 1,0
5 -> 1,1
6 -> 1,2
7 -> 1,3
8 -> 2,0
9 -> 2,1
a -> 2,2
b -> 2,3
c -> 3,0
d -> 3,1
e -> 3,2
f -> 3,3
Okay, OpenGL and some math libraries use column major ordering, fine. But why do it this way and break with the usual mathematical convention that in Mi,j the index i designates the row and j the column? Because it is make things look nicer. You see, matrix is just a bunch of vectors. Vectors that can and usually do form a coordinate base system.
Have a look at this picture:
The axes X, Y and Z are essentially vectors. They are defined as
X = (1,0,0)
Y = (0,1,0)
Z = (0,0,1)
Moment, does't that up there look like a identity matrix? Indeed it does and in fact it is!
However written as it is the matrix has been formed by stacking row vectors. And the rules for matrix multiplication essentially tell, that a matrix formed by row vectors, transforms row vectors into row vectors by left associative multiplication. Column major matrices transform column vectors into column vectors by right associative multiplication.
Now this is not really a problem, because left associative can do the same stuff as right associative can, you just have to swap rows for columns (i.e. transpose) everything and reverse the order of operands. However left<>right row<>column are just notational conventions in which we write things.
And the typical mathematical notation is (for example)
v_clip = P · V · M · v_local
This notation makes it intuitively visible what's going on. Furthermore in programming the key character
= usually designates assignment from right to left. Some programming languages are more mathematically influenced, like Pascal or Delphi and write it
:=. Anyway with row major ordering we'd have to write it
v_clip = v_local · M · V · P
and to the majority of mathematical folks this looks unnatural. Because, technically M, V and P are in fact linear operators (yes they're also matrices and linear transforms) and operators always go between the equality / assignment and the variable.
So that's why we use column major format: It looks nicer. Technically it could be done using row major format as well. And what does this have to do with the memory layout of matrices? Well, When you want to use a column major order notation, then you want direct access to the base vectors of the transformation matrices, without having them to extract them element by element. With storing numbers in a column major format, all it takes to access a certain base vector of a matrix is a simple offset in linear memory.
I can't speak for the code example of the other library, but I'd strongly assume, that it treats first index as the slower incrementing index as well, which makes it work in column major if subjected to the notations of OpenGL. Remember: column major & right associativity == row major & left associativity.