I'm about to write some code that computes the determinant of a square matrix (nxn), using the Laplace algorithm (Meaning recursive algorithm) as written Wikipedia's **Laplace Expansion**.

I already have the class `Matrix`

, which includes **init**, **setitem**, **getitem**, **repr** and all the things I need to compute the determinant (including `minor(i,j)`

).

So I've tried the code below:

```
def determinant(self,i=0) # i can be any of the matrix's rows
assert isinstance(self,Matrix)
n,m = self.dim() # Q.dim() returns the size of the matrix Q
assert n == m
if (n,m) == (1,1):
return self[0,0]
det = 0
for j in range(n):
det += ((-1)**(i+j))*(self[i,j])*((self.minor(i,j)).determinant())
return det
```

As expected, in every recursive call, `self`

turns into an appropriate minor. But when coming back from the recursive call, it doesn't change back to it's original matrix.
This causes trouble when in the `for`

loop (when the function arrives at `(n,m)==(1,1)`

, this one value of the matrix is returned, but in the `for`

loop, `self`

is still a 1x1 matrix - why?)

`self.minor(i,j)`

actually transform`self`

? – Radio- May 12 '13 at 17:43`assert`

s like this. The first one (`assert isinstance(self, Matrix)`

) doesn't do anything - it's a method on`Matrix`

, so you know for certain that`self`

is a`Matrix`

. The second one would work better with something like`if n != m: raise ValueError("Matrix is not square")`

because the exception is more specific about the problem (and can be caught more easily). – Benjamin Hodgson May 12 '13 at 18:32`i`

as a parameter? The determinant is a property of a matrix, independent of which row or column you take it along. So it doesn't really make sense to let the user choose (since the result will be the same no matter what they pick). – Benjamin Hodgson May 12 '13 at 18:34