The function derivate_leaf takes as argument an expression that is a leaf, and a variable, and returns the symbolic derivative of the leaf writh respect to the variable. (code should be in python).

 

def derivate_leaf(e, x):

"""This function takes as input an expression e and a variable x,

and returns the symbolic derivative of e wrt. x, as an expression."""

# YOUR CODE HERE

 

 

should pass these test cases:

assert derivate_leaf("x", "x") == 1

assert derivate_leaf("x", "y") == 0

assert derivate_leaf("y", "z") == 0

assert derivate_leaf(4, "x") == 0

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[8] def simplify(e): if isinstance(e, tuple): op, l, r = e # We simplify the children expressions. 11 = simplify( Add text cell simplify(r) rr = # We compute the expression if we can. if isnumber(ll) and isnumber(rr) : return calc(op, ll, rr) else: return (op, l1, rr) else: # Leaf. No simplification is possible. return e

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[2] Os class IllegalOperator(Exception): pass Let us define a helper function calc,which takes as argument an operator and two numbers, and computes the required operation. It will make it easier to write the rest of the code. def calc(op, left, right): if op == "+": return left + right elif op == "_": return left - right elif op == "*": return left * right elif op == "/": return left / right else: raise IllegalOperator(op) With this, we can write our compute method as follows. [ 4] def compute(e): if isinstance(e, tuple): # We have an expression. op, 1, r = e # We compute the subexpressions. 1l = compute(1) rr = compute(r) # And on the basis of those, the whole expression. return calc (op, 11, rr) else: # base expression; just return the number. return e