# Numpy ‘smart’ symmetric matrix

Is there a smart and space-efficient symmetric matrix in numpy which automatically (and transparently) fills the position at `[j][i]` when `[i][j]` is written to?

``````a = numpy.symmetric((3, 3))
a[0][1] = 1
a[1][0] == a[0][1]
# True
print a
# [[0 1 0], [1 0 0], [0 0 0]]

assert numpy.all(a == a.T) # for any symmetric matrix
``````

An automatic Hermitian would also be nice, although I won’t need that at the time of writing.

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You might consider marking the answer as accepted, if it solves your problem. :) –  EOL Apr 8 '10 at 7:24
I wanted to wait for a better (i.e. built-in and memory-efficient) answer to come. There’s nothing wrong with your answer, of course, so I’ll accept it anyway. –  Debilski Apr 9 '10 at 19:46

If you can afford to symmetrize the matrix just before doing calculations, the following should be reasonably fast:

``````def symmetrize(a):
return a + a.T - numpy.diag(a.diagonal())
``````

This works under reasonable assumptions (such as not doing both `a[0, 1] = 42` and the contradictory `a[1, 0] = 123` before running `symmetrize`).

If you really need a transparent symmetrization, you might consider subclassing numpy.ndarray and simply redefining `__setitem__`:

``````class SymNDArray(numpy.ndarray):
def __setitem__(self, (i, j), value):
super(SymNDArray, self).__setitem__((i, j), value)
super(SymNDArray, self).__setitem__((j, i), value)

def symarray(input_array):
"""
Returns a symmetrized version of the array-like input_array.
Further assignments to the array are automatically symmetrized.
"""
return symmetrize(numpy.asarray(input_array)).view(SymNDArray)

# Example:
a = symarray(numpy.zeros((3, 3)))
a[0, 1] = 42
print a  # a[1, 0] == 42 too!
``````

(or the equivalent with matrices instead of arrays, depending on your needs). This approach even handles more complicated assignments, like `a[:, 1] = -1`, which correctly sets `a[1, :]` elements.

Note that Python 3 removed the possibility of writing `def …(…, (i, j),…)`, so the code has to be slightly adapted before running with Python 3: `def __setitem__(self, indexes, value): (i, j) = indexes`

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Actually, if you do subclass it, you should not overwrite setitem, but rather getitem so that you do not cause more overhead on creating the matrix. –  Markus Jul 16 '13 at 18:07
This is a very interesting idea, but writing this as the equivalent `__getitem__(self, (i, j))` fails when one does a simple `print` on a subclass instance array. The reason is that `print` calls `__getitem__()` with an integer index, so more work is required even for a simple `print`. The solution with `__setitem__()` works with `print` (obviously), but suffers from a similar problem: `a[0] = [1, 2, 3]` does not work, for the same reason (this is not a perfect solution). A `__setitem__()` solution has the advantage of being more robust, since the in-memory array is correct. Not too bad. :) –  EOL Jul 17 '13 at 8:43

The more general issue of optimal treatment of symmetric matrices in numpy bugged me too.

After looking into it, I think the answer is probably that numpy is somewhat constrained by the memory layout supportd by the underlying BLAS routines for symmetric matrices.

While some BLAS routines do exploit symmetry to speed up computations on symmetric matrices, they still use the same memory structure as a full matrix, that is, n^2 space rather than n(n+1)/2. Just they get told that the matrix is symmetric and to use only the values in either the upper or the lower triangle.

Some of the scipy.linalg routines do accept flags (like sym_pos=True on linalg.solve) which get passed on to BLAS routines, although more support for this in numpy would be nice, in particular wrappers for routines like DSYRK (symmetric rank k update), which would allow a Gram matrix to be computed a fair bit quicker than dot(M.T, M).

(Might seem nitpicky to worry about optimising for a 2x constant factor on time and/or space, but it can make a difference to that threshold of how big a problem you can manage on a single machine...)

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The question is about how to automatically create a symmetric matrix through the assignment of a single entry (not about how BLAS can be instructed to use symmetric matrices in its calculations or how symmetric matrices could in principle be stored more efficiently). –  EOL Apr 27 '13 at 6:48
The question is also about space-efficiency, so BLAS issues are on-topic. –  jmmcd Sep 16 '13 at 10:41

This is plain python and not numpy, but I just threw together a routine to fill a symmetric matrix (and a test program to make sure it is correct):

``````import random

# fill a symmetric matrix with costs (i.e. m[x][y] == m[y][x]
# For demonstration purposes, this routine connect each node to all the others
# Since a matrix stores the costs, numbers are used to represent the nodes
# so the row and column indices can represent nodes

def fillCostMatrix(dim):        # square array of arrays
# Create zero matrix
new_square = [[0 for row in range(dim)] for col in range(dim)]
# fill in main diagonal
for v in range(0,dim):
new_square[v][v] = random.randrange(1,10)

# fill upper and lower triangles symmetrically by replicating diagonally
for v in range(1,dim):
iterations = dim - v
x = v
y = 0
while iterations > 0:
new_square[x][y] = new_square[y][x] = random.randrange(1,10)
x += 1
y += 1
iterations -= 1
return new_square

# sanity test
def test_symmetry(square):
dim = len(square[0])
isSymmetric = ''
for x in range(0, dim):
for y in range(0, dim):
if square[x][y] != square[y][x]:
isSymmetric = 'NOT'
print "Matrix is", isSymmetric, "symmetric"

def showSquare(square):
# Print out square matrix
for i in range(len(square)):
columnHeader += '  ' + str(i)

i = 0;
for col in square:
print i, col    # print row number and data
i += 1

def myMain(argv):
if len(argv) == 1:
nodeCount = 6
else:
try:
nodeCount = int(argv[1])
except:
print  "argument must be numeric"
quit()

# keep nodeCount <= 9 to keep the cost matrix pretty
costMatrix = fillCostMatrix(nodeCount)
print  "Cost Matrix"
showSquare(costMatrix)
test_symmetry(costMatrix)   # sanity test
if __name__ == "__main__":
import sys
myMain(sys.argv)

# vim:tabstop=8:shiftwidth=4:expandtab
``````
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There are a number of well-known ways of storing symmetric matrices so they don't need to occupy n^2 storage elements. Moreover, it is feasible to rewrite common operations to access these revised means of storage. The definitive work is Golub and Van Loan, Matrix Computations, 3rd edition 1996, Johns Hopkins University Press, sections 1.27-1.2.9. For example, quoting them from form (1.2.2), in a symmetric matrix only need to store

A = [a_{i,j} ]

for i >= j. Then, assuming the vector holding the matrix is denoted V, and that A is n-by-n, put a_{i,j} in

V[(j-1)n - j(j-1)/2 + i]

This assumes 1-indexing.

Golub and Van Loan offer an Algorithm 1.2.3 which shows how to access such a stored V to calculate y = V x + y.

Golub and Van Loan also provide a way of storing a matrix in diagonal dominant form. This does not save storage, but supports ready access for certain other kinds of operations.

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