Right now, to integrate a function fx with SymPy I would do the following:

from sympy.abc import alpha as _alpha_, beta as _beta_, x as _x_

sym_args = _alpha_, _beta_

fx_definite_integral = sympy.integrate(fx(_x_, *sym_args), (_x_, xmin, xmax))

But this requires me to know beforehand what symbols I might need for a given function. But what if I plugged in a different function, with parameters, say, A, B, Y, Z, Q, W?

Instead of manually assigning symbols in SymPy, is there a way to generically assign symbols - basically, my sym_args, based on the input function?


sym_args = sympy.all_the_symbols_I_need_for_random_function(fx)
  • What is fx here? Is it a Python function returning a SymPy expression? – jdehesa Feb 27 '18 at 11:07
  • An expression for a mathematical function, e.g. def fx(x, alpha, beta): return x+alpha**2+beta, where here I would have to manually define symbols for all the input arguments. – komodovaran_ Feb 27 '18 at 11:09
  • SymPy does not integrate functions, it integrates expressions. A symbolic expression does not need anything to be plugged in, it already contains symbols. When you write Python functions like def fx... for use in SymPy, you are probably overcomplicating. – user6655984 Feb 27 '18 at 11:45

The problem is a bit ill-defined because, after all, you need to know something about the arguments of fx, right? For example, fx should have at least one argument for the x; is it always the first argument, or the argument called x, which may or may not be the first? Should the rest of arguments be given a specific sequence of names, such as alpha, beta, etc. or instead use symbols with the name of the argument? What if the arguments have default values?

I'll give one possible approach for a simple example, then you can choose how to implement it exactly for your case. Let's have this function:

def fx(x, a, b, c):
    return x * (a + (b / c))

In order to extract information about the function arguments, you can use the inspect

import inspect
fx_args = inspect.getfullargspec(fx).args  # fx_args <- ['x', 'a', 'b', 'c']

inspect.getfullargspec returns a namedtuple with information about the function arguments, you can check the docs to see if you need something else (e.g. to ignore parameters with default values). Now you can convert those to SymPy symbols:

import sympy
fx_argsym = sympy.symbols(fx_args)  # fx_argsym <- [x, a, b, c]

Here you could use a different strategy. For example, if you wanted to have the first argument be always x and the rest of arguments be always Greek letters (as long as you don't have too many arguments) you could do:

import sympy.abc
fx_argsym = [sympy.abc.x] + list(sympy.symbols(sympy.abc.greeks[:len(fx_args) - 1]))
# fx_argsym <- [x, alpha, beta, gamma]

You can manipulate fx_argsym however you want to suit your needs. When you get get it right, you can call sympy.integrate as usual:

fx_definite_integral = sympy.integrate(fx(*fx_argsym), (_x_, xmin, xmax))

Note that if you didn't make sure that x was in fx_argsym you may get an error, but that is easy to check for example with:

assert _x_ in fx_argsym
  • PyCharm tells me that inspect.getargspec(fx).args is deprecated for Python3. Instead I had to use fx_args = [*inspect.signature(fx).parameters.keys()] to get out the parameters in a list (otherwise, returns an OrderedDict), for SymPy to take them. – komodovaran_ Mar 1 '18 at 13:01
  • @komodovaran_ Thanks, I didn't notice that. According to the docs inspect.getfullargspec should be a valid drop-in replacement, but you can do it however it works best for you. – jdehesa Mar 1 '18 at 13:04
  • Oh, you're completely right. It was because PyCharm didn't pick up the .args in the autocomplete, so I thought it didn't exist. That's what you get for not reading the manual. – komodovaran_ Mar 1 '18 at 13:48

You can use

f = Function('f')
expr.Integral(f(x), (x, xmin, xmax))

and then use expr.replace(f, your_function) to replace f with your function. You will need to curry your_function so that it accepts one parameter to match f. As far as Integral is concerned, it only needs to know that f depends on x. The rest of the (constant) variables can be "in" f.

For instance, if your expression is x + A + B, you can use expr.replace(f, lambda x: x + A + B).

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