I found this statement while studying Functional Reactive Programming, from "Plugging a Space Leak with an Arrow" by Hai Liu and Paul Hudak ( page 5) :

`Suppose we wish to deﬁne a function that repeats its argument indeﬁnitely: repeat x = x : repeat x or, in lambdas: repeat = λx → x : repeat x This requires O(n) space. But we can achieve O(1) space by writing instead: repeat = λx → let xs = x : xs in xs`

The difference here seems small but it hugely prompts the space efficiency. Why and how it happens ? The best guess I've made is to evaluate them by hand:

```
r = \x -> x: r x
r 3
-> 3: r 3
-> 3: 3: 3: ........
-> [3,3,3,......]
```

As above, we will need to create infinite new thunks for these recursion. Then I try to evaluate the second one:

```
r = \x -> let xs = x:xs in xs
r 3
-> let xs = 3:xs in xs
-> xs, according to the definition above:
-> 3:xs, where xs = 3:xs
-> 3:xs:xs, where xs = 3:xs
```

In the second form the `xs`

appears and can be shared between every places it occurring, so I guess that's why we can only require `O(1)`

spaces rather than `O(n)`

. But I'm not sure whether I'm right or not.

BTW: The keyword "shared" comes from the same paper's page 4:

The problem here is that the standard call-by-need evaluation rules are unable to recognize that the function:

`f = λdt → integralC (1 + dt) (f dt)`

is the same as:

`f = λdt → let x = integralC (1 + dt) x in x`

The former deﬁnition causes work to be repeated in the recursive call to f, whereas in the latter case the computation is shared.