I've undone the lambdas just to make it a little easier to read. Here's the code using nested functions:
This would be equivalent basically to:
f1 = lambda f: (lambda a: a(a))(lambda b: f(lambda *args: b(b)(*args)))
Now let's follow the function calls. First you're going to call f1 with some argument. Then the following is going to happen:
- f2 gets called with f3
- f2 returns f3 called with itself as a parameter
- Now we're inside f3 with b being f3
- f3 return f (the parameter you called f1 with) with f4 as the parameter
- f is a callback that gets called with a function as its only parameter
- If f calls this function then its call will be applied to the result of b called with b. b is f3, so f would essentially be calling the result of f3(f3) which is what f is going to return
Therefore f1 can be reduced to:
Now I've come up with a way to call f1 that doesn't end in infinite recursion:
called = False
if not called:
called = True
f1(g1) # prints "(5,)"
As you can see, it uses a global to stop the recursion.
Here's another example that runs trials of a Poisson distribution with lambda (lambda is a parameter to the Poisson distribution, not the lambda operator) of 10:
if random.random() < 0.1:
And finally something deterministic, not depending on a global, and actually somewhat interesting:
if n > 0:
print f1(g6)(5) # 120
print f1(g6)(6) # 720
I'm sure everyone can guess what this function is, but pretty interesting that you can actually get this strange lambda expression to do something useful.