Decoding a Cryptic Python statement

I saw this on a job ad (on SO):

``````lambda f: (lambda a: a(a))(lambda b: f(lambda *args: b(b)(*args)))
``````

So what I understand is it is an anonymous (unnamed) function, which is composed of two further nested anonymous functions. The innermost function takes a variable list of arguements (*args).

I can't work out what is it supposed to do. Is this something that would actually work or is it impossible to tell without seeing the actual list of args?

• Are you sure it's supposed to do anything? – Some programmer dude Jan 15 '14 at 7:52
• I would second @mhlester's suggestion that it is a sick joke. With a potential to cause endless recursion?! – volcano Jan 15 '14 at 8:07
• It might not be clear what the code does but it's clear what the manager has to do: Fire the programmer and get someone who writes readable code. – Matthias Jan 15 '14 at 8:25
• Perhaps they are expecting a potential candidate to say this is rubbish code... – ardochhigh Jan 15 '14 at 8:32

I've undone the lambdas just to make it a little easier to read. Here's the code using nested functions:

``````def f1(f):
def f2(a):
return a(a)

def f3(b):
def f4(*args):
return b(b)(*args)

return f(f4)

return f2(f3)
``````

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:

1. f2 gets called with f3
2. f2 returns f3 called with itself as a parameter
3. Now we're inside f3 with b being f3
4. f3 return f (the parameter you called f1 with) with f4 as the parameter
5. f is a callback that gets called with a function as its only parameter
6. 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:

``````def f1(f):
def f3():
def f4(*args):
return f3()(*args)
return f(f4)

return f3()
``````

Now I've come up with a way to call f1 that doesn't end in infinite recursion:

``````called = False

def g1(func):
def g2(*args):
print args
return None

global called

if not called:
called = True
func(5)
else:
return g2

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:

``````import random

def g3(func):
def g4(a):
def g5(b):
print a
return a+b
return g5

if random.random() < 0.1:
return g4(1)
else:
return g4(func(1))

f1(g3)
``````

And finally something deterministic, not depending on a global, and actually somewhat interesting:

``````def g6(func):
def g7(n):
if n > 0:
return n*func(n-1)
else:
return 1

return g7

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.

• `function` should be replaced with `def`. – falsetru Jan 15 '14 at 8:08
• wow, yes, I am stupid here – CrazyCasta Jan 15 '14 at 8:09
• You should define `f3` outside `f2` but inside `f1`. – justhalf Jan 15 '14 at 8:18

The code is creating Y-combinator in Python. This is merely an excercise, not a real world code; don't try to decrypt it.

To understand what Y-combinator itself does, you may refer to this SO question: What is a y-combinator? and to its wikipedia page: Fixed-point combinator.

Maybe this ad is looking for people that know functional programming and/or advanced computer science topics like Lambda calculus and Combinatory logic, which are primary theoretical foundation behind functional programming.

Or maybe their company is Y Combinator winner startup, and they are merely looking for Python programmers with CS background.

Not just *args, it's hard to tell what it is without knowing what `a`, `b`, `f`, and `*args` are.

The rabbit hole goes especially deep when b is passed as argument to function b, and that result is a function to which args is passed.

This is quite equivalent, without too much nesting:

``````def f1(f):
def f2(a): return a(a)
def f3(b):
def f4(*args): return b(b)(*args)
return f(f4)
return f2(f3)
``````

`f2` can be replaced, so we get

``````def f1(f):
def f3(b):
def f4(*args): return b(b)(*args)
return f(f4)
return f3(f3) # was f2(f3)
``````

`f3` is always called with itself, so we replace `b` with `f3`:

``````def f1(f):
def f3():
def f4(*args): return f3()(*args)
return f(f4)
return f3()
``````

So what does it do?

We see `f3()` returns whatever `f` returns, and this is supposed to be called with an arbitrary number of arguments.

`f` is supposed to take a function taking another function with `*args` and returning such a function.

Calling `f1(f)` returns whatever `f(f4)` returns.

Let's test it:

• With `f=lambda ff: lambda *args: ff(*args)`, `f1(f)()` gives us an infinite recursion.
• `f=lambda ff: lambda *args: (ff, args)` doesn't call the given function, so we can safely play with it:
• `f1(f)(4)` gives us a tuple `(f4, (4,))`.
• If we use that tuple's 0th element: `f1(f)(4)(1)`, we get `(f4, (1,))`.