# SymPy : creating a numpy function from diagonal matrix that takes a numpy array

Building on an example I've found here, I am trying to create a function from a diagonal matrix that was created using `sumpy.diag`

``````myM = Matrix([
[x1, 4, 4],
[4, x2, 4],
[4, 4, x3]])
``````

Where this was created using this routine for example:

``````import sympy as sp
import numpy as np

x1 = sp.Symbol('x1')
x2 = sp.Symbol('x2')
x3 = sp.Symbol('x3')
X = sp.Matrix([x1, x2, x3])

myM = 4 * sp.ones(3, 3)
sp.diag(*X) + myM - sp.diag(*np.diag(myM))
``````

now I will like to create a function, using `lambdify` of `ufuncify`, that takes a `numpy.array` or length 3 (like `np.array([0.1,0.2,0.3])`)as an input, and gives the output as a matrix according to `myM`

``````myM = Matrix([
[0.1, 4, 4],
[4, 0.2, 4],
[4, 4, 0.3]])
``````

Eventually I need to create a Jacobian matrix symbolically using this method: And as the functional form may change during the calculation, then having the Jacobian calculated symbolically would be very useful.

The creation of a numeric 3 by 3 matrix from a numeric vector is not really a SymPy thing, since no symbols are involved. Consider the following, where the argument d is an array holding the diagonal elements.

``````def mat(d):
return np.diag(d-4) + 4
``````

The above function returns a 2d NumPy array. To return a SymPy matrix instead, use

``````def mat(d):
return sp.Matrix(np.diag(d-4) + 4)
``````

When d has extremely small values, the subtraction followed by addition may cause loss of precision: for example, `(1e-20 - 4) + 4` evaluates to zero. A safer alternative is

``````def mat(d):
diagmat = np.diag(d)
return diagmat + np.fromfunction(lambda i, j: (i != j)*4, diagmat.shape)
``````
• Not exactly what I had in mind, but I'll use it, so thanks – Ohm Feb 1 '17 at 10:10

you can .subs() float values into the respective symbols:

``````import sympy as sp
import numpy as np

x1 = sp.Symbol('x1')
x2 = sp.Symbol('x2')
x3 = sp.Symbol('x3')
X = sp.Matrix([x1, x2, x3])

myM = 4 * sp.ones(3, 3)
smyM=sp.diag(*X) + myM - sp.diag(*np.diag(myM))

fcoefs = [(a, f) for a, f in (zip([x1, x2, x3], np.array([0.1,0.2,0.3])))]

fmyM = smyM.subs(fcoefs)

smyM
Out:
Matrix([
[x1,  4,  4],
[ 4, x2,  4],
[ 4,  4, x3]])

fmyM
Out:
Matrix([
[0.1,   4,   4],
[  4, 0.2,   4],
[  4,   4, 0.3]])
``````

seems to be a fine `sympy.matrices.dense.MutableDenseMatrix` Matrix after:

``````fmyM @ myM
Out:
Matrix([
[32.4, 32.4, 32.4],
[32.8, 32.8, 32.8],
[33.2, 33.2, 33.2]])
``````

may need conversion to a np.array for full use with numpy

below is some of my code showing more of the pattern I used:

``````def ysolv(coeffs):
x,y,a,b,c,d,e = symbols('x y a b c d e')
ellipse = a*y**2 + b*x*y + c*x + d*y + e - x**2
y_sols = solve(ellipse, y)
print(*y_sols, sep='\n')

num_coefs = [(a, f) for a, f in (zip([a,b,c,d,e], coeffs))]
y_solsf0 = y_sols.subs(num_coefs)
y_solsf1 = y_sols.subs(num_coefs)

f0 = lambdify([x], y_solsf0)
f1 = lambdify([x], y_solsf1)
return f0, f1

f0, f1 = ysolv(t)

y0 = [f0(x) for x in xs]
y1 = [f1(x) for x in xs]
...
``````

from: https://stackoverflow.com/a/41232062/6876009 (yes, my "feeloutXrange" there is a hack so bad it had to be shown)