# Can a lambda function call itself recursively in Python?

A regular function can contain a call to itself in its definition, no problem. I can't figure out how to do it with a lambda function though for the simple reason that the lambda function has no name to refer back to. Is there a way to do it? How?

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I'm tempted to tag this what-the-heck or you-dont-want-to-do-this. Why don't you just use a normal function? –  phihag Jan 26 '09 at 22:48
I want to do is to run reduce() on an tree. The lambda works great on a 1-D list and recursion felt like a natural way to make it work on a tree. That said, the real reason is that I'm just learning Python, so I'm kicking the tires. –  dsimard Jan 26 '09 at 23:12
Reduce works fine with named functions. Guido wanted to remove lambda expressions from the language for a while. They survived, but there's still no reason why you need to use them in any situation. –  John Fouhy Jan 26 '09 at 23:34
please don't use reduce. Reduce with a recursive function is crazy complex. It will take forever. I think it's O(n**3) or something –  S.Lott Jan 27 '09 at 0:21
@S.Lott bummer. Is that a problem with the Python interpreter or something more fundamental that I don't understand yet? –  dsimard Jan 27 '09 at 7:42
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## 7 Answers

The only way I can think of to do this amounts to giving the function a name:

``````fact = lambda x: 1 if x == 0 else x * fact(x-1)
``````

or alternately, for earlier versions of python:

``````fact = lambda x: x == 0 and 1 or x * fact(x-1)
``````

Update: using the ideas from the other answers, I was able to wedge the factorial function into a single unnamed lambda:

``````>>> map(lambda n: (lambda f, *a: f(f, *a))(lambda rec, n: 1 if n == 0 else n*rec(rec, n-1), n), range(10))
[1, 1, 2, 6, 24, 120, 720, 5040, 40320, 362880]
``````

So it's possible, but not really recommended!

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`map(lambda n: (lambda f, n: f(f, n))(lambda f, n: n*f(f, n-1) if n > 0 else 1, n), range(10))` –  J.F. Sebastian Jan 27 '09 at 12:39
Useless and fun. That's why I love computing. –  e-satis Nov 18 '09 at 13:23
FWIW, here's how to generate numbers in the Fibonacci series with the same technique (assigning it a name): `fibonacci = lambda n: 0 if n == 0 else 1 if n == 1 else fibonacci(n-1)+fibonacci(n-2) `. –  martineau Nov 1 '10 at 19:52
Another way of genreating Fibonacci numbers using lambdas and recusivity: `f = lambda x: 1 if x in (1,2) else f(x-1)+f(x-2)` –  Juan Gallostra Nov 26 '13 at 14:25
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I have never used Python, but this is probably what you are looking for.

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You can't directly do it, because it has no name. But with a helper function like the Y-combinator Lemmy pointed to, you can create recursion by passing the function as a parameter to itself (as strange as that sounds):

``````# helper function
def recursive(f, *p, **kw):
return f(f, *p, **kw)

def fib(n):
# The rec parameter will be the lambda function itself
return recursive((lambda rec, n: rec(rec, n-1) + rec(rec, n-2) if n>1 else 1), n)

# using map since we already started to do black functional programming magic
print map(fib, range(10))
``````

This prints the first ten Fibonacci numbers: `[1, 1, 2, 3, 5, 8, 13, 21, 34, 55]`,

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I think I finally understand what the Y combinator is for. But I think that in Python it would generally be easier to just use "def" and give the function a name... –  pdc Jan 28 '09 at 13:59
Funny thing is, your Fibonacci example is a great example of something more naturally done with a generator. :-) –  pdc Jan 28 '09 at 13:59
A much better answer than "No". –  new123456 Jul 28 '11 at 22:19
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If you were truly masochistic, you might be able to do it using C extensions, but to echo Greg (hi Greg!), this exceeds the capability of a lambda (unnamed, anonymous) functon.

No. (for most values of no).

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( > this exceeds the capability of a lambda ) --- No, it doesn't. The Y combinator is like the most famous abstract construct there is and it does do that without any hacks. –  Danny Milosavljevic Jul 3 '12 at 15:34
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Yes. I have two ways to do it, and one was already covered. This is my preferred way.

``````(lambda v: (lambda n: n * __import__('types').FunctionType(
__import__('inspect').stack()[0][0].f_code,
dict(__import__=__import__, dict=dict)
)(n - 1) if n > 1 else 1)(v))(5)
``````
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I don't know Python, but that looks terrible. There's really got to be a better way. –  Kyle Cronin Jan 27 '09 at 3:41
You have to learn to appreciate obsfucated code, man. :( –  habnabit Jan 27 '09 at 4:56
+1 for teaching me a new way to abuse Python. –  Deestan Jan 27 '09 at 10:14
nobody - the point is that this looks horrible for a reason. Python isn't designed for it, and it's bad practice (in Python). Lambdas are limited by design. –  Gregg Lind Jan 27 '09 at 22:11
Yeah, +1 for the worst Python code ever. When Perl people say "You can write maintainable code in Perl if you know what you are doing", I say "Yeah, and you can write unmaintainable code in Python if you know what you are doing". :-) –  Lennart Regebro Jul 29 '09 at 22:11
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without reduce, map, named lambdas or python internals:

``````(lambda a:lambda v:a(a,v))(lambda s,x:1 if x==0 else x*s(s,x-1))(10)
``````
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Contrary to what sth said, you CAN directly do this.

``````(lambda f: (lambda x: f(lambda v: x(x)(v)))(lambda x: f(lambda v: x(x)(v))))(lambda f: (lambda i: 1 if (i == 0) else i * f(i - 1)))(n)
``````

The first part is the fixed-point combinator Y that facilitates recursion in lambda calculus

``````Y = (lambda f: (lambda x: f(lambda v: x(x)(v)))(lambda x: f(lambda v: x(x)(v))))
``````

the second part is the factorial function fact defined recursively

``````fact = (lambda f: (lambda i: 1 if (i == 0) else i * f(i - 1)))
``````

Y is applied to fact to form another lambda expression

``````F = Y(fact)
``````

which is applied to the third part, n, which evaulates to the nth factorial

``````>>> n = 5
>>> F(n)
120
``````

or equivalently

``````>>> (lambda f: (lambda x: f(lambda v: x(x)(v)))(lambda x: f(lambda v: x(x)(v))))(lambda f: (lambda i: 1 if (i == 0) else i * f(i - 1)))(5)
120
``````

If however you prefer fibs to facts you can do that too using the same combinator

``````>>> (lambda f: (lambda x: f(lambda v: x(x)(v)))(lambda x: f(lambda v: x(x)(v))))(lambda f: (lambda i: f(i - 1) + f(i - 2) if i > 1 else 1))(5)
8
``````
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