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how can I change the values of the diagonal of a matrix in numpy?

I checked Numpy modify ndarray diagonal, but the function there is not implemented in numpy v 1.3.0.

lets say we have a np.array X and I want to set all values of the diagonal to 0.

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1  
What version of numpy are you using? np.diag_indices_from was added in v1.4 –  JoshAdel Mar 31 '12 at 19:21
    
yep, you are right, I am currently using python v 1.3.0 –  pacodelumberg Mar 31 '12 at 20:57
    
@LangerHansIslands Hopefully you mean numpy 1.3, not python 1.3 (which came out in the mid-nineties... :p) –  Dougal Mar 31 '12 at 20:59
    
upps yeah :D you are right –  pacodelumberg Apr 2 '12 at 14:44

8 Answers 8

up vote 26 down vote accepted

Did you try numpy.fill_diagonal? See the following answer and this discussion. Or the following from the documentation (although currently broken):

http://docs.scipy.org/doc/numpy/reference/generated/numpy.fill_diagonal.html

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Thank you @JoshAdel –  Mellkor Mar 31 '12 at 19:27
    
+1 This is the proper way to do this in numpy. The built-in is always preferable to iterating the array one element at a time using two for loops. –  JoshAdel Mar 31 '12 at 19:29
def replaceDiagonal(matrix, replacementList):
    for i in range(len(replacementList)):
        matrix[i][i] = replacementList[i]

Where size is n in an n x n matrix.

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2  
Or n = len(replacement_list); matrix[:n, :n] = replacement_list. This does the loop in C instead of in Python and so will be much faster. –  Dougal Mar 31 '12 at 19:37
    
@Dougal: Awesome, I didn't know that. Can you post it as an answer? –  Joel Cornett Mar 31 '12 at 19:51
    
Sure, just did. –  Dougal Mar 31 '12 at 21:10

If A is your matrix, the following will set its diagonal to zero:

A = A - np.diag(A)
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1  
doesn't numpy.diag just return a one-dimensional array? –  steabert Sep 4 '12 at 20:10

If you're using a version of numpy that doesn't have fill_diagonal (the right way to set the diagonal to a constant) or diag_indices_from, you can do this pretty easily with array slicing:

# assuming a 2d square array
n = mat.shape[0]
mat[range(n), range(n)] = 0

This is much faster than an explicit loop in Python, because the looping happens in C and is potentially vectorized.

One nice thing about this is that you can also fill a diagonal with a list of elements, rather than a constant value (like diagflat, but for modifying an existing matrix rather than making a new one). For example, this will set the diagonal of your matrix to 0, 1, 2, ...:

# again assuming 2d square array
n = mat.shape[0]
mat[range(n), range(n)] = range(n)

If you need to support more array shapes, this is more complicated (which is why fill_diagonal is nice...):

m[list(zip(*map(range, m.shape)))] = 0

(The list call is only necessary in Python 3, where zip returns an iterator.)

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To make it clear for future readers, mat[:n, :n] = 0 sets the whole array / matrix to 0, not just the diagonal elements. zip version indeed does the diag. –  gorlum0 Jan 20 '13 at 11:58
    
@gorlum0 Whoops - thanks for pointing that out. I just edited to fix it (the zip isn't actually necessary there)`. –  Dougal Jan 20 '13 at 15:28
    
Cool, even bare ranges. This implicit stuff is hard to get to know. –  gorlum0 Jan 21 '13 at 6:07

Here's another good way to do this. If you want a one-dimensional view of the array's main diagonal use:

A.ravel()[:A.shape[1]**2:A.shape[1]+1]

For the i'th superdiagonal use:

A.ravel()[i:max(0,A.shape[1]-i)*A.shape[1]:A.shape[1]+1]

For the i'th subdiagonal use:

A.ravel()[A.shape[1]*i:A.shape[1]*(i+A.shape[1]):A.shape[1]+1]

Or in general, for the i'th diagonal where the main diagonal is 0, the subdiagonals are negative and the superdiagonals are positive, use:

A.ravel()[max(i,-A.shape[1]*i):max(0,(A.shape[1]-i))*A.shape[1]:A.shape[1]+1]

These are views and not copies, so they will run faster for extracting a diagonal, but any changes made to the new array object will apply to the original array. On my machine these run faster than the fill_diagonal function when setting the main diagonal to a constant, but that may not always be the case. They can also be used to assign an array of values to a diagonal instead of just a constant.

Notes: for small arrays it may be faster to use the flat attribute of the NumPy array. If speed is a major issue it could be worth it to make A.shape[1] a local variable. Also, if the array is not contiguous, ravel() will return a copy, so, in order to assign values to a strided slice, it will be necessary to creatively slice the original array used to generate the strided slice (if it is contiguous) or to use the flat attribute.

Also, in NumPy 1.10 and later the 'diagonal' method of arrays will return a view instead of a copy, so this trick to get a view will no longer be necessary. In NumPy 1.9 it will return a read-only view. See http://docs.scipy.org/doc/numpy-dev/reference/generated/numpy.diagonal.html

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Nice and hacky, I like it! Only caveat is I think you would get the wrap=True behavior described in the np.fill_diagonal docs. You can probably solve that adding an adequate stop value to your slices. –  Jaime Jul 23 '13 at 4:41
    
Thank you, good catch. I just edited it to fix that and a few other things. –  IanH Jul 23 '13 at 5:28
>>> a = numpy.random.rand(2,2)
>>> a
array([[ 0.41668355,  0.07982691], 
       [ 0.60790982,  0.0314224 ]])
>>> a - numpy.diag(numpy.diag(a))
array([[ 0.        ,  0.07982691],
       [ 0.60790982,  0.        ]])
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This would also work:

A[np.diag_indices_from(A)] = 0.
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You can do the following.

Assuming your matrix is 4 * 4 matrix.

indices_diagonal = np.diag_indices(4)

yourarray[indices_diagonal] = Val
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