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# Differential Operator usable in Matrix form, in Python module Sympy

We need two matrices of differential operators `[B]` and `[C]` such as:

``````B = sympy.Matrix([[ D(x), D(y) ],
[ D(y), D(x) ]])

C = sympy.Matrix([[ D(x), D(y) ]])

ans = B * sympy.Matrix([[x*y**2],
[x**2*y]])
print ans
[x**2 + y**2]
[      4*x*y]

ans2 = ans * C
print ans2
[2*x, 2*y]
[4*y, 4*x]
``````

This could also be applied to calculate the curl of a vector field like:

``````culr  = sympy.Matrix([[ D(x), D(y), D(z) ]])
field = sympy.Matrix([[ x**2*y, x*y*z, -x**2*y**2 ]])
``````

To solve this using Sympy the following Python class had to be created:

``````import sympy

class D( sympy.Derivative ):
def __init__( self, var ):
super( D, self ).__init__()
self.var = var

def __mul__(self, other):
return sympy.diff( other, self.var )
``````

This class alone solves when the matrix of differential operators is multiplying on the left. Here `diff` is executed only when the function to be differentiated is known.

To workaround when the matrix of differential operators is multiplying on the right, the `__mul__` method in the core class `Expr` had to be changed in the following way:

``````class Expr(Basic, EvalfMixin):
# ...
def __mul__(self, other):
import sympy
if other.__class__.__name__ == 'D':
return sympy.diff( self, other.var )
else:
return Mul(self, other)
#...
``````

It works pretty well, but there should be a better native solution in Sympy to handle this. Does anybody know what it might be?

-
Your problem is not with the matrices or with the model that you are implementing, but only about the creation of a differential operator object. The question will be much more valuable if you remove the unnecessary discussion about the model and the matrix. – Krastanov Mar 17 '13 at 19:44
@Krastanov, thank you, the question has been updated – Saullo Castro Mar 17 '13 at 19:50
Multiplying on the right side by D class would work if it was possible to force Python to execute `__rmul__` from the right object first than `__mul__` from the left object. See question: stackoverflow.com/questions/5181320/… – Saullo Castro Mar 18 '13 at 9:06
Wy do you include `EvalfMixin`? – asmeurer Mar 18 '13 at 16:54
To really work completely, you would need code.google.com/p/sympy/issues/detail?id=1941. See also github.com/sympy/sympy/wiki/Canonicalization (feel free to edit that page). – asmeurer Mar 18 '13 at 17:01

Differential operators do not exist in the core of SymPy, and even if they existed "multiplication by an operator" instead of "application of an operator" is an abuse of notation that is not supported by SymPy.

[1] Another problem is that SymPy expressions can be build only from subclasses of `sympy.Basic`, so it is probable that your `class D` simply raises an error when entered as `sympy_expr+D(z)`. This is the reason why `(expression*D(z)) * (another_expr)` fails. `(expression*D(z))` can not be built.

In addition if the argument of `D` is not a single `Symbol` it is not clear what you expect from this operator.

Finally, `diff(f(x), x)` (where `f` is a symbolic unknown function) returns an unevaluated expressions as you observed simply because when `f` is unknown there is nothing else that can sensibly returned. Later, when you substitute `expr.subs(f(x), sin(x))` the derivative will be evaluate (at worst you might need to call `expr.doit()`).

[2] There is no elegant and short solution to your problem. A way that I would suggest for solving your problem is to override the `__mul__` method of `Expr`: instead of just multiplying the expression trees it will check if the left expression tree contains instances of `D` and it will apply them. Obviously this does not scale if you want to add new objects. This is a longstanding known issue with the design of sympy.

EDIT: [1] is necessary simply to permit creation of expressions containing `D`. [2] is necessary for expressions that containing something more that only one `D` to work.

-
Using the D class as a subclass of sympy.Derivative worked for this case (please, see the updated question) – Saullo Castro Mar 18 '13 at 7:47
Just subclass `Expr`, there is no reason (it is actually confusing) to subclass `Derivative`. – Krastanov Mar 18 '13 at 10:30
And as I already mentioned, your solution will not work for `stuff+D`. You should have added an answer, not modified the question, so it is easier to comment. – Krastanov Mar 18 '13 at 10:33
The updated question is not the answer, just some more information was included to give some insight about what is needed. The issue that you have pointed out with `stuff+D` was also verified here. Thank you! – Saullo Castro Mar 18 '13 at 11:37
subclassing `Expr` does really make much more sense. In this way `stuff+D` does not raise an error, for example, the result of `sympy.expand( (D(x)+1/x)*x**2 )` is `x**2*D(x) + x`. Now I am studying a way to re-make the multiplication in order to call `diff` again. – Saullo Castro Mar 18 '13 at 13:44

If you want right multiplication to work, you'll need to subclass from just `object`. That will cause `x*D` to fall back to `D.__rmul__`. I can't imagine this is high priority, though, as operators are never applied from the right.

-
there is a way to force `__mul__` and `__rmul__` to be used, as explained by Julien Rioux here – Saullo Castro Apr 26 '13 at 13:15

Making an operator that works automatically always is not currently possible. To really work completely, you would need http://code.google.com/p/sympy/issues/detail?id=1941. See also https://github.com/sympy/sympy/wiki/Canonicalization (feel free to edit that page).

However, you could make a class that works most of the time using the ideas from that stackoverflow question, and for the cases it doesn't handle, write a simple function that goes through an expression and applies the operator where it hasn't been applied yet.

By the way, one thing to consider with a differential operator as "multiplication" is that it's nonassociative. Namely, `(D*f)*g` = `g*Df`, whereas `D*(f*g)` = `g*Df + f*Dg`. So you need to be careful when you do stuff that it doesn't "eat" some part of an expression and not the whole thing. For example, `D*2*x` would give `0` because of this. SymPy everywhere assumes that multiplication is associative, so it's likely to do that incorrectly at some point.

If that becomes an issue, I would recommend dumping the automatic application, and just working with a function that goes through and applies it (which as I noted above, you will need anyway).

-
Thank you! I will work on that an then post the news! – Saullo Castro Mar 18 '13 at 22:24

This solution applies the tips from the other answers and from here. The `D` operator can be defined as follows:

• considered only when multiplied from the left, so that `D(t)*2*t**3 = 6*t**2` but `2*t**3*D(t)` does nothing
• all the expressions ans symbols used with `D` must have `is_commutative = False`
• is evaluated in the context of a given expression using `evaluateExpr()`
• which goes from the right to the left along the expression finding the `D` opperators and applying `mydiff()`* to the corresponding right portion

*:`mydiff` is used instead of `diff` to allow a higher order `D` to be created, like `mydiff(D(t), t) = D(t,t)`

The `diff` inside `__mul__()` in `D` was kept for reference only, since in the current solution the `evaluateExpr()` actually does the differentiation job. A python mudule was created and saved as `d.py`.

``````import sympy
from sympy.core.decorators import call_highest_priority
from sympy import Expr, Matrix, Mul, Add, diff
from sympy.core.numbers import Zero

class D(Expr):
_op_priority = 11.
is_commutative = False
def __init__(self, *variables, **assumptions):
super(D, self).__init__()
self.evaluate = False
self.variables = variables

def __repr__(self):
return 'D%s' % str(self.variables)

def __str__(self):
return self.__repr__()

@call_highest_priority('__mul__')
def __rmul__(self, other):
return Mul(other, self)

@call_highest_priority('__rmul__')
def __mul__(self, other):
if isinstance(other, D):
variables = self.variables + other.variables
return D(*variables)
if isinstance(other, Matrix):
other_copy = other.copy()
for i, elem in enumerate(other):
other_copy[i] = self * elem
return other_copy

if self.evaluate:
return diff(other, *self.variables)
else:
return Mul(self, other)

def __pow__(self, other):
variables = self.variables
for i in range(other-1):
variables += self.variables
return D(*variables)

def mydiff(expr, *variables):
if isinstance(expr, D):
expr.variables += variables
return D(*expr.variables)
if isinstance(expr, Matrix):
expr_copy = expr.copy()
for i, elem in enumerate(expr):
expr_copy[i] = diff(elem, *variables)
return expr_copy
return diff(expr, *variables)

def evaluateMul(expr):
end = 0
if expr.args <> ():
if isinstance(expr.args[-1], D):
if len(expr.args[:-1])==1:
cte = expr.args[0]
return Zero()
end = -1
for i in range(len(expr.args)-1+end, -1, -1):
arg = expr.args[i]
if isinstance(arg, Mul):
arg = evaluateMul(arg)
if isinstance(arg, D):
left = Mul(*expr.args[:i])
right = Mul(*expr.args[i+1:])
right = mydiff(right, *arg.variables)
ans = left * right
return evaluateMul(ans)
return expr

newargs = []
for arg in expr.args:
if isinstance(arg, Mul):
arg = evaluateMul(arg)
if isinstance(arg, D):
arg = Zero()
newargs.append(arg)

def evaluateExpr(expr):
if isinstance(expr, Matrix):
for i, elem in enumerate(expr):
elem = elem.expand()
expr[i] = evaluateExpr(elem)
return expr
expr = expr.expand()
if isinstance(expr, Mul):
expr = evaluateMul(expr)
elif isinstance(expr, D):
expr = Zero()
return expr
``````

Example 1: curl of a vector field. Note that it is important to define the variables with `commutative=False` since their order in `Mul().args` will affect the results, see this other question.

``````from d import D, evaluateExpr
from sympy import Matrix
sympy.var(x, y, z, commutative=False)
curl  = Matrix( [[ D(x), D(y), D(z) ]] )
field = Matrix( [[ x**2*y, x*y*z, -x**2*y**2 ]] )
evaluateExpr( curl.cross( field ) )
# [-x*y - 2*x**2*y, 2*x*y**2, -x**2 + y*z]
``````

Example 2: Typical Ritz approximation used in structural analysis.

``````from d import D, evaluateExpr
from sympy import sin, cos, Matrix
sin.is_commutative = False
cos.is_commutative = False
g1 = []
g2 = []
g3 = []
var('x,t,r,A', commutative=False)
m=5
n=5
for j in xrange(1,n+1):
for i in xrange(1,m+1):
g1 += [sin(i*x)*sin(j*t),                 0,                 0]
g2 += [                0, cos(i*x)*sin(j*t),                 0]
g3 += [                0,                 0, sin(i*x)*cos(j*t)]
g = Matrix( [g1, g2, g3] )

B = Matrix(\
[[     D(x),        0,        0],
[    1/r*A,        0,        0],
[ 1/r*D(t),        0,        0],
[        0,     D(x),        0],
[        0,    1/r*A, 1/r*D(t)],
[        0, 1/r*D(t), D(x)-1/x],
[        0,        0,        1],
[        0,        1,        0]])

ans = evaluateExpr(B*g)
``````

A `print_to_file()` function has been created to quickly check big expressions.

``````import sympy
import subprocess
def print_to_file( guy, append=False ):
flag = 'w'
if append: flag = 'a'
outfile = open(r'print.txt', flag)
outfile.write('\n')
outfile.write( sympy.pretty(guy, wrap_line=False) )
outfile.write('\n')
outfile.close()
Why do you call `expand`? – asmeurer Apr 26 '13 at 17:02
Without the `expand` I was left with grouped terms that made harder to apply the `treatAdd()` and `treatMul()` – Saullo Castro Apr 26 '13 at 17:05
@asmeurer Do you know how to avoid `args` to be sorted? I posted a question for this issue too... – Saullo Castro Apr 26 '13 at 17:07