Your use of parentheses in your code sample and your emphasis on tail recursion suggests you're coming to Haskell from Lisp or Scheme. If you're coming to Haskell from an eager language like Scheme, be warned: tail calls are not nearly as predictive of performance in Haskell as they are in an eager language. You can have tail-recursive functions that execute in linear space because of laziness, *and* you can have non-tail recursive functions that execute in constant space because of laziness. (Confused already?)

First flaw in your definition is the use of the `length theList == 0`

. This forces evaluation of the whole spine of the list, and is O(n) time. It's better to use pattern matching, like in this naïve `foldl`

definition in Haskell:

```
foldl :: (b -> a -> b) -> b -> [a] -> b
foldl f z [] = z
foldl f z (x:xs) = foldl f (f z x) xs
```

This, however, performs infamously badly in Haskell, because we don't actually compute the `f z x`

part until the caller of `foldl`

demands the result; so this `foldl`

accumulates unevaluated thunks in memory for each list element, and gains no benefit from being tail recursive. In fact, despite being tail-recursive, this naïve `foldl`

over a long list can lead to a stack overflow! (The `Data.List`

module has a `foldl'`

function that doesn't have this problem.)

As a converse to this, many Haskell non-tail recursive functions perform very well. For example, take this definition of `find`

, based on the accompanying non-tail recursive definition of `foldr`

:

```
find :: (a -> Boolean) -> [a] -> Maybe a
find pred xs = foldr find' Nothing xs
where find' elem rest = if pred elem then Just elem else rest
foldr :: (a -> b -> b) -> b -> [a] -> b
foldr f z [] = z
foldr f z (x:xs) = f x (subfold xs)
where subfold = foldr f z
```

This actually executes in linear time and constant space, thanks to laziness. Why?

- Once you find an element that satisfies the predicate, there is no need to traverse the rest of the list to compute the value of
`rest`

.
- Once you look at an element and decide that it doesn't match, there's no need to keep any data about that element.

The lesson I'd impart right now is: don't bring in your performance assumptions from eager languages into Haskell. You're just two days in; concentrate first on understanding the syntax and semantics of the language, and don't contort yourself into writing optimized versions of functions just yet. You're going to get hit with the `foldl`

-style stack overflow from time to time at first, but you'll master it in time.

**EDIT [9/5/2012]:** Simpler demonstration that lazy `find`

runs in constant space despite not being tail recursive. First, simplified definitions:

```
foldr :: (a -> b -> b) -> b -> [a] -> b
foldr f z [] = z
foldr f z (x:xs) = f x (foldr f z xs)
find :: (a -> Bool) -> [a] -> Maybe a
find p xs = let step x rest = if p x then Just x else rest
in foldr step Nothing xs
```

Now, using equational reasoning (i.e., substituting equals with equals, based on the definition above), and evaluating in a lazy order (outermost first), let's calculate `find (==400) [1..]`

:

```
find (==400) [1..]
-- Definition of `find`:
=> let step x rest = if x == 400 then Just x else rest
in foldr step Nothing [1..]
-- `[x, y, ...]` is the same as `x:[y, ...]`:
=> let step x rest = if x == 400 then Just x else rest
in foldr step Nothing (1:[2..])
-- Using the second equation in the definition of `foldr`:
=> let step x rest = if x == 400 then Just x else rest
in step 1 (foldr step Nothing [2..])
-- Applying `step`:
=> let step x rest = if x == 400 then Just x else rest
in if 1 == 400 then Just 1 else foldr step Nothing [2..]
-- `1 == 400` is `False`
=> let step x rest = if x == 400 then Just x else rest
in if False then Just 1 else foldr step Nothing [2..]
-- `if False then a else b` is the same as `b`
=> let step x rest = if x == 400 then Just x else rest
in foldr step Nothing [2..]
-- Repeat the same reasoning steps as above
=> let step x rest = if x == 400 then Just x else rest
in foldr step Nothing (2:[3..])
=> let step x rest = if x == 400 then Just x else rest
in step 2 (foldr step Nothing [3..])
=> let step x rest = if x == 400 then Just x else rest
in if 2 == 400 then Just 2 else foldr step Nothing [3..]
=> let step x rest = if x == 400 then Just x else rest
in if False then Just 2 else foldr step Nothing [3..]
=> let step x rest = if x == 400 then Just x else rest
in foldr step Nothing [3..]
.
.
.
=> let step x rest = if x == 400 then Just x else rest
in foldr step Nothing [400..]
=> let step x rest = if x == 400 then Just x else rest
in foldr step Nothing (400:[401..])
=> let step x rest = if x == 400 then Just x else rest
in step 400 (foldr step Nothing [401..])
=> let step x rest = if x == 400 then Just x else rest
in if 400 == 400 then Just 400 else foldr step Nothing [401..]
=> let step x rest = if x == 400 then Just x else rest
in if True then Just 400 else foldr step Nothing [401..]
-- `if True then a else b` is the same as `a`
=> let step x rest = if x == 400 then Just x else rest
in Just 400
-- We can eliminate the `let ... in ...` here:
=> Just 400
```

Note that the expressions in the successive evaluation steps don't get progressively more complex or longer as we proceed through the list; the length or depth of the expression at step *n* is not proportional to *n*, it's basically fixed. This in fact demonstrates how `find (==400) [1..]`

can be lazily executed in constant space.

Neveruse`if length list == 0`

to check for an empty list. Use`if null list`

for that. If the list is long or even infinite, asking for the length is a really bad idea.`init`

sparingly too. It is O(n), you know.thatis what I'd call "premature optimization". Take some quality time to learn the basic concepts of Haskell and pure functional programming before you worry about optimization.2more comments