Earlier this week I asked a generic question in a related SO community regarding constructing mathematical trees using OOP. The main takeaway was that the Composite and Interpreter patterns were the go-to patterns for this kind of application.

I then spent several days looking around online for resources on how these are constructed. I'm still convinced that I do not need to construct an entire interpreter and that a composite might be sufficient for my purposes.

From the other question I was trying to construct this tree:

enter image description here

Without using OOP, I'd probably do something like this:

import numpy as np

def root(B, A):
    return B+A

def A(x,y,z):
    return x*np.log(y)+y**z

def B(alpha, y):
    return alpha*y

def alpha(x,y,w):
    return x*y+w

if __name__=='__main__':

    x,y,z,w = 1,2,3,4
    result = root(B(alpha(x,y,w),y), A(x,y,z))

This would give a correct result of 20.693147180559947. I tried to use the composite pattern to do something similar:

class ChildElement:
    '''Class representing objects at the bottom of the hierarchy tree.'''
    def __init__(self, value):
        self.value = value
    def __repr__(self):
        return "class ChildElement with value"+str(self.value)
    def component_method(self):
        return self.value

class CompositeElement:
    '''Class representing objects at any level of the hierarchy tree except for the bottom level.
      Maintains the child objects by adding and removing them from the tree structure.'''
    def __init__(self, func):
        self.func = func
        self.children = []
    def __repr__(self):
        return "class Composite element"
    def append_child(self, child):
        '''Adds the supplied child element to the list of children elements "children".'''
    def remove_child(self, child):
        '''Removes the supplied child element from the list of children elements "children".'''
    def component_method(self):
        '''WHAT TO INCLUDE HERE?'''

if __name__=='__main__':

    import numpy as np
    def e_func(A, B):
        return A+B
    def A_func(x,y,z):
        return x*np.log(y)+y**z
    def B_func(alpha,y):
        return alpha*y
    def alpha_func(x,y,w):
        return x*y+w

    x = ChildElement(1)
    y = ChildElement(2)
    z = ChildElement(3)
    w = ChildElement(4)
    e = CompositeElement(e_func)
    A = CompositeElement(A_func)
    B = CompositeElement(B_func)
    alpha = CompositeElement(alpha_func)
    e.children = [A, B]
    A.children = [x, y, z]
    B.children = [alpha, y]
    alpha.children = [x, y, w]

I got stuck in the last line, however. It seems that if I call the component_method at the level of composite class instance e, it will not work, since the architecture is not built to handle adding two Child or Composite objects.

How can I get this to work? What should the component_method for my CompositeElement class contain?

def component_method(self):
    values = [child.component_method() for child in self.children]
    return self.func(*values)

This will evaluate the child nodes and pass the values to the function of the node itself, returning the value.

  • Nice. It works. Is there a way to enforce that the number of children for each composite object be equal to the number of arguments provided in its respective component method? – user32882 Oct 26 '19 at 16:54
  • There is a python module called inspect. It provides a function called getargspec. You can pass a function into the function and get information about the arguments. – M. Spiller Oct 26 '19 at 19:39
  • I was looking for a more "structural" way to enforce it. That is without use of external libraries. – user32882 Oct 27 '19 at 8:31
  • @user32882 inspect is part of the python standard library. What do you mean by "structural"? something that looks at the syntax of your defs? That's not how python works – Caleth Mar 17 '20 at 10:26

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.