This seems like an incredibly simple and silly question to ask

Not at all. This is a very good question, and it has unfortunately a complex answer. Let's solve

```
a * x + b * y = u
c * x + d * y = v
```

I stick to the 2x2 case here. More complex cases will require you to use a library.

The first thing to note is that Cramer formulas are not good to use. When you compute the determinant

```
a * d - b * c
```

as soon as you have `a * d ~ b * c`

, then you have catastrophic cancellation. This case is typical, and you *must* guard against it.

The best tradeoff between simplicity / stability is partial pivoting. Suppose that `|a| > |c|`

. Then the system is equivalent to

```
a * c/a * x + bc/a * y = uc/a
c * x + d * y = v
```

which is

```
cx + bc/a * y = uc/a
cx + dy = v
```

and now, substracting the first to the second yields

```
cx + bc/a * y = uc/a
(d - bc/a) * y = v - uc/a
```

which is now straightforward to solve: `y = (v - uc/a) / (d - bc/a)`

and `x = (uc/a - bc/a * y) / c`

. Computing `d - bc/a`

is stabler than `ad - bc`

, because we divide by the biggest number (it is not very obvious, but it holds -- do the computation with very close coefficients, you'll see why it works).

Now, if `|c| > |a|`

, you just swap the rows and proceed similarly.

In code (please check the Python syntax):

```
def solve(a, b, c, d, u, v):
if abs(a) > abs(c):
f = u * c / a
g = b * c / a
y = (v - f) / (d - g)
return ((f - g * y) / c, y)
else
f = v * a / c
g = d * a / c
x = (u - f) / (b - g)
return (x, (f - g * x) / a)
```

You can use full pivoting (requires you to swap x and y so that the first division is always by the largest coefficient), but this is more cumbersome to write, and almost never required for the 2x2 case.

For the n x n case, all the pivoting stuff is encapsulated into the LU decomposition, and you should use a library for this.