# Calculating an NxN matrix determinant in C#

How do you calculate the determinant of an NxN matrix C# ?

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Is this homework? – Aryabhatta May 27 '10 at 15:58
Isn't the definition sufficient: en.wikipedia.org/wiki/Determinant? When you tried to implement it on C# did you encounter some particular problems you might ask about? – Darin Dimitrov May 27 '10 at 15:59
Give us the code you made so far and we will help you. But we won't code it for you. – Philippe Carriere May 27 '10 at 16:19
Whilst I agree that this isn't a very well written question, and it certainly smacks of being homework, I came across this question via a Google search, needing and answer to the very same thing. SO is a place I usually turn to for answering these kinds of things, and this does indeed seem to be the only question on here on this topic. I don't see a reason not to answer it properly, if not for the elusive @vj4u then at least for Joe Coder like me. – Drew Noakes Jun 5 '10 at 15:41
I've posted an answer that caters for the 4x4 case (which is what I needed). It raises the question of whether a hardcoded solution beats a generic NxN one when the matrix size is known. – Drew Noakes Jun 5 '10 at 15:42

The OP posted another question asking specifically about 4x4 matrices, which has been closed as an exact duplicate of this question. Well, if you're not looking for a general solution but instead are constrained to 4x4 matrices alone, then you can use this ugly looking but tried-and-true code:

``````public double GetDeterminant() {
var m = _values;
return
m[12] * m[9]  * m[6]  * m[3]   -  m[8] * m[13] * m[6]  * m[3]   -
m[12] * m[5]  * m[10] * m[3]   +  m[4] * m[13] * m[10] * m[3]   +
m[8]  * m[5]  * m[14] * m[3]   -  m[4] * m[9]  * m[14] * m[3]   -
m[12] * m[9]  * m[2]  * m[7]   +  m[8] * m[13] * m[2]  * m[7]   +
m[12] * m[1]  * m[10] * m[7]   -  m[0] * m[13] * m[10] * m[7]   -
m[8]  * m[1]  * m[14] * m[7]   +  m[0] * m[9]  * m[14] * m[7]   +
m[12] * m[5]  * m[2]  * m[11]  -  m[4] * m[13] * m[2]  * m[11]  -
m[12] * m[1]  * m[6]  * m[11]  +  m[0] * m[13] * m[6]  * m[11]  +
m[4]  * m[1]  * m[14] * m[11]  -  m[0] * m[5]  * m[14] * m[11]  -
m[8]  * m[5]  * m[2]  * m[15]  +  m[4] * m[9]  * m[2]  * m[15]  +
m[8]  * m[1]  * m[6]  * m[15]  -  m[0] * m[9]  * m[6]  * m[15]  -
m[4]  * m[1]  * m[10] * m[15]  +  m[0] * m[5]  * m[10] * m[15];
}
``````

It assumes you store your vector data in a 16-element array called `_values` (of `double` in this case, but `float` would work too), in the following order:

``````0, 1, 2, 3,
4, 5, 6, 7,
8, 9, 10, 11,
12, 13, 14, 15
``````
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Reduce to upper triangular form, then make a nested loop where you multiply all the values at position i == j together. There you have it.

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It doesn't even need to be a nested loop, because if you're doing it for positions (i, j) where i == j you can just do it for all positions (i, i). – JAB May 27 '10 at 16:15
Good point, +1. – Brandi May 27 '10 at 16:21
The result you calculate may be the negative of the determinant. You need to take the product of the primary diagonal and then multiply by (-1)^[number of row swaps used to get to upper triangular form] – Kevin May 27 '10 at 16:58
Another good point. Man its been too long since college. :) – Brandi May 27 '10 at 17:11

The standard method is LU decomposition. You may want to use a library instead of coding it yourself. I don't know about C#, but the 40-year standard is LAPACK.

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