# What is an algorithm to enumerate lambda terms?

What is an algorithm that will enumerate expressions for the lambda calculus by order of length? For example, `(λx.x), (λx.(x x)), (λx.(λy.x))` and so on?

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How do you define length? – Kristopher Micinski Jan 9 '14 at 5:56
@KristopherMicinski any order will do it, I did not mean to be strict on this word. I just wanted to avoid obvious disasters such as generating `(λx.(λy.(λz.((z x) (y x) x y y))))` before `(λx.λy.y)`, which is obviously wrong. – Viclib Jan 9 '14 at 6:04

As length I would choose the number of `T`-expansions ("depth") in this BNF of (untyped) lambda expressions:

``````V ::= x | y
T ::= V    |
λV.T |
(T T)
``````

In python you can define a generator following the above generation rules for given variables and a given depth like this:

``````def lBNF(vars, depth):
if depth == 1:
for var in vars:
yield var
elif depth > 1:
for var in vars:
for lTerm in lBNF(vars,depth-1):
yield 'l%s.%s' % (var,lTerm)
for i in range(1,depth):
for lTerm1 in lBNF(vars,i):
for lTerm2 in lBNF(vars,depth-i):
yield '(%s %s)' % (lTerm1,lTerm2)
``````

Now you can enumerate the lambda terms for/up to a given depth:

``````vars = ['x','y']
for i in range(1,5):
for lTerm in lBNF(vars,i):
print lTerm
``````
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Great answer, thanks! Is it possible to modify it so it generates only closed terms, using bruijn indices? – Viclib Jan 9 '14 at 15:55
@viclib you mean that there are no unbound variables? (never heard of bruijn indices) That would require some postprocessing - or some other smart adaption ... – coproc Jan 10 '14 at 10:11
Uh huh, it is just a way to throw the strings of. (λ(λ(0 1))) - here, 0 is bound to the second λ and 1 is bound to the fist. – Viclib Jan 10 '14 at 16:48