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:

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".'''
self.children.append(child)
def remove_child(self, child):
'''Removes the supplied child element from the list of children elements "children".'''
self.children.remove(child)
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]
e.component_method()
```

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?