For numbers, 2x4 = 4x2 because they're commutative. Matrices don't commute so commutativity of the underlaying numbers really has nothing to do with it.

The idea is that a vector (by which I'll mean a column vector with the entries written vertically) is an entity in a vector space. This vector space has addition and scalar multiplication defined on it. It also comes with a basis, {e_n}. e_i is just the vector with 1 in the i'th component and 0's elsewhere. Any vector can be written as a linear combination of the {e_n}. For example, in a 2-dimensional space,

```
|x_1| |1| |0|
|x_2| = x_1 |0| + x_2 |1|
```

A matrix acts on this vector as a linear transformation and yields a new vector. A linear transformation is just a function, **T**, with **T**(x + y) = **T**(x) + **T**(y) and c **T**(x) = **T**(c x) for any vectors, x and y and any real number c (though we can take it over other fields). So a matrix **A** acts on a vector x and yields another vector y. **A** x = y.

```
|a_11 a_12| |x_1| |y_2| |x_1 a_11 + x_2 a_12|
|a_21 a_22| |x_2| = |y_1| = |x_1 a_21 + x_2 a_22|
```

But we can view the matrix as a set of the vectors made of it's columns so that's just the same as

```
x_11 |a_11| + x_2*|a_12|
|a_22| |a_22|
```

So we've re-expressed the definition for the action of a matrix on a vector (m*n matrix times a n*1 matrix) as a linear combination of the columns of the matrix.

This is what allows for us to conflate a matrix with a linear transformation. To express a given linear transformation, **T**, as a matrix, we just put **T**(e_i) in the i'th column of the matrix. Call this matrix **A_T**. Then **A_T** x = x_1 **T**(e1) + x_2 **T**(e2) + ... + x_n **T**(en). But by linearity of **T**, if x = x_1 e_1 + x_2 e_2 + ... + x_n e_n, then **T**(x) = x_1 **T**(e_1) + x_2 **T**(e_2) + ... + x_n **T**(e_n). But this is exactly what we wrote before for **A_T**. So the law for multiplying a vector by a matrix is required to allow us to represent linear transformations as matrices.

Now let's consider multiplying general matrices. The idea here is composition of linear functions, that is first do **T**_1 and then do **T**_2. That is **T**_2(**T**_1(x)) for some vector x. We know from above that we can view these as matrix multiplications. That is
**A_T2** (**A_T1** x). Let's look at it in two dimensions because anything else is masochistic and that suffices to get all the ideas across. Let's relabel the matrices as **A_t2** = **A** and **A_T1** = **B**. Then we have

```
A(B x) = |a_11 a_12| (|b_11 b_12| |x_1|)
|a_21 a_22| (|b_21 b_22| |x_2|)
= |a_11 a_12| |x_1 b_11 + x_2 b_12|
|a_21 a_22| |x_1 b_21 + x_2 b_22|
= |(x_1 b_11 + x_2 b_12) a_11 + (x_1 b_21 + x_2 b_22) a_12|
|(x_1 b_11 + x_2 b_12) a_21 + (x_1 b_21 + x_2 b_22) a_22|
= |x_1 (a_11 b_11 + a_12 b_21) + x_2 (a_11 b_12 + a_12 b_22)|
|x_1 (a_21 b_11 + a_22 b+21) + x_2 (a_21 b_12 + a_22 b_22)|
= |(a_11 b_11 + a_12 b_21) (a_11 b_12 + a_12 b_22)| |x1|
|(a_21 b_11 + a_22 b+21) (a_21 b_12 + a_22 b_22)| |x2|
```

Which is just matrix multiplication.

PS. Also probably belongs on Math.SO but I'm not voting to close because I answered. It might be too basic for there as well.