I wanted to demonstrate the usefulness of decorators in python to some people and failed at a simple example: Consider two functions (for sake of simplicity without arguments) `f`

and `g`

.
One can define their sum f+g as the function that returns f() + g(). Of course adding, subtracting etc. of functions is not defined in general. But it is easy to write a decorator that transforms every function into an addable function.

Now I would like to have a decorator that transforms any function into an "operable" function, that is, a function that behaves in the described way for any operator in the standard module `operator`

. My implementation looks as follows:

```
import operator
class function(object):
def __init__(self, f):
self.f = f
def __call__(self):
return self.f()
def op_to_function_op(op):
def function_op(self, operand):
def f():
return op(self(), operand())
return function(f)
return function_op
binary_op_names = ['__add__', '__and__', '__div__', '__eq__', '__floordiv__', '__ge__', '__gt__', '__le__', '__lt__', '__mod__', '__mul__', '__ne__', '__or__', '__pow__', '__sub__', '__truediv__', '__xor__']
for name in binary_op_names:
type.__setattr__(function, name, op_to_function_op(getattr(operator, name)))
```

Let's perform a little test to see if it works:

```
@function
def a():
return 4
def b():
return 7
c = a + b
print c()
print c() == operator.__add__(4, 7)
```

Output:

```
11
True
```

This is the final version I got after some experimenting. Now let's do two small, irrelevant modifications to have a look what I tried before:

*First*: In the definition of `binary_op_names`

, change the square brackets to round brackets. Suddenly, a (for me) completely unrelated error message comes out:

```
Traceback (most recent call last):
File "example.py", line 30, in <module>
c = a + b
TypeError: unsupported operand type(s) for +: 'function' and 'function'
```

Where does this come from??

*Second*: Write `op_to_function_op`

as a lambda expression:

```
op = getattr(operator, name)
type.__setattr__(function, name, lambda self, other: function(lambda: op(self(), other())))
```

Perform a slightly more involved test case:

```
@function
def a():
return 4
def b():
return 7
c = a + b
print c()
print c() == operator.__add__(4, 7)
print c() == operator.__xor__(4, 7)
```

Output:

```
3
False
True
```

This looks to me like scope leakage, but again I don't understand why this happens.

`memoize`

decorator applied to the fibonacci sequence and other cache-friendly problems might be a better application to demonstrate decorators. – Daenyth Nov 29 '11 at 20:56`name`

checks out, but`type.__setattr__`

fails to work. – Nate Nov 29 '11 at 21:09`memoize`

right before I tried to implement this. – Turion Nov 29 '11 at 21:46