# Why is init a partial function?

according to the Haskell 2010 report, init is defined as the following:

init             :: [a] -> [a]
init [x]         =  []
init (x:xs)      =  x : init xs
init []          =  error "Prelude.init: empty list"

base-4.4.1.0 defines it similarly. To me, it seems that it would be perfectly acceptable and intuitive to have:

init [] = []

wich would make init a total function. Since this definition made it into the haskell 2010 report I guess that there are arguments for it. Is that the case or is it defined that way because of tradition and backwards compatibility?

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init should return all but the last element of a list. Empty lists don't have a last element, so no init as well. Plus, the invariant xs == init xs ++ [last xs] would no longer hold if init were defined in the way you describe. –  Niklas B. Dec 21 '11 at 14:27
@Niklas But, similarly you could say, init should return all the elements that are not the last element, there are no such elements so we should return the empty list. –  HaskellElephant Dec 21 '11 at 14:29
@Niklas, wouldn't it still hold? I mean if last [] = [] –  Magnus Kronqvist Dec 21 '11 at 17:36
@Magnus: No, as last wouldn't have a defined type then. Plus, [] ++ [[]] != []. Maybe you confused last with tail? –  Niklas B. Dec 21 '11 at 17:41
@Niklas yes, that is correct –  Magnus Kronqvist Dec 21 '11 at 17:42

The same reason tail [] isn't []; it breaks the invariants that define these functions. We can define head and tail by saying that if head and tail are defined for a value xs, then xs ≡ head xs : tail xs.

As Niklas pointed out, the invariant we want to define init and last is xs ≡ init xs ++ [last xs]. It's true that last isn't defined on empty lists either, but why should last be defined if init can't be? Just like it would be wrong if one of head or tail was defined on an input while the other wasn't, init and last are two sides of the same coin, splitting a list into two values that together are equivalent to the original.

For a more "practical" view (although being able to reason about programs in terms of useful invariants about the operations they use has very practical benefit!), an algorithm that uses init will probably not behave correctly on an empty list, and if init worked that way, it would work to hide the errors produced. It's better for init to be conservative about its inputs so that consideration has to be given for edge-cases like empty list when it is used, especially when it isn't at all clear that the proposed value for it to return in those cases is reasonable.

Here's a previous Stack Overflow question about head and tail, including why tail [] doesn't just return []; the answers there should help to explain why these invariants are so important.

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I think you meant "why should init be defined when last can't be?". –  HaskellElephant Oct 1 '12 at 15:42

It's traditional. At the time, they made an arbitrary choice, and now people are used to it.

They made init similar to last, so that they both fail on empty lists. (tail and head are another pair like that.)

But they could have chosen the opposite, as you suggest. Prelude could easily contain a function tail' = drop 1, as well as a matching init' function, allowing empty lists. I don't think this would be any problem—I'm unconvinced by all the talk of invariants and free theorems. It would just mean init' was a little dissimilar to its companion last; that's all.

(last and head are another story: Their signature is [a] -> a, so they must give back an element, and they can't make one out of thin air. In contrast, the type of init and tail is of course [a] -> [a], which means they can and do yield empty lists.)

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The real issue here is that init, as defined, can't possibly work; it's an inherently partial function, just like head and tail. I'm not thrilled about how many deliberately partial functions exist in the standard libraries, but that's another matter.

Since init as given cannot be salvaged, we have two options:

• Take the interpretation that it's a filter on the given list, keeping all elements which are not the last element, and abandoning the invariants with respect to length and last. This can be written as reverse . drop 1 . reverse, which suggests an obvious generalization. We could introduce a similar counterpart for take if desired, as well.

• Recognize that init defines a partial function, and give it the correct type, [a] -> Maybe [a]. The error can then be correctly replaced with Nothing.

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An obvious generalisation like inits :) –  ehird Dec 21 '11 at 22:27
@ehird , well inits is more in line with init [] = [] since inits [] == [[]]. In a way its saying that the only init of [] is [], if it where to stick with init [] = undefined, it should be inits [] == []. –  HaskellElephant Dec 21 '11 at 22:41
Hmm, I don't agree. length (inits xs) ≡ length xs + 1, so length (inits []) ≡ 1, and the only element it can possibly have is []. –  ehird Dec 21 '11 at 22:45
Another way to explain the behaviour of inits is that it starts with the empty list, and adds more elements until there aren't any left. I suppose that aligns fairly well with your definition of init as "every element that isn't the last". –  ehird Dec 21 '11 at 22:49
@ehird: Actually, the generalization I had in mind was something equivalent to \n -> reverse . drop n . reverse, but inits is a good example as well. –  C. A. McCann Dec 21 '11 at 22:58
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Because I find the question interesting, I decided to write down my thoughts on the subject:

Logical

Say we define init xs as "the list, that, if you put last xs on its end, is equal to xs. This is equivalent to: init xs is the list without its last element. For xs == [], there exists no last element, so init [] has to be undefined.

You could add a special case for this, like in "if xs is the empty list, then init xs is the empty list, otherwise init xs is the list, that, if you put last xs on its end, is equal to xs". Notice how this is much more verbose and less clean. We introduce additional complexity, but what for?

Intuitive

init [1,2,3,4] == [1,2,3]
init [1,2,3]   == [1,2]
init [1,2]     == [1]
init [1]       == []
init []        == ??

Note how the length of the lists on the right-hand side of the equations decreases along with the length of the left-hand side. To me, this series cannot be continued in a sensible way, because the list on the right side would have to have a negative size!

Practical

As others have pointed out, defining a special case handling for init or tail for the empty list as an argument, can introduce hard-to-spot errors in situations where functions can have no sensible result for the empty list, but still don't produce an exception for it!

Furthermore, I can think of no algorithm were it would actually be of advantage to have init [] evaluate to [], so why introduce that extra complexity? Programming is all about simplicity and especially Haskell is all about purity, wouldn't you agree?

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There is one obvious and sensible continuation of your intuitive series, and that is to recognize that an explicitly undefined case needs to be represented as such. The correct type for init is thus [a] -> Maybe [a], with init [] = Nothing. –  C. A. McCann Dec 21 '11 at 20:15
Yeah, but that would mean that we need to handle the special case whenever we call init (e.g. by wrapping every call into a fromJust)... I don't like this very much. –  Niklas B. Dec 21 '11 at 20:32
What? No, fromJust is an absolutely terrible function and shouldn't exist at all. The correct thing to do is handle every case and not write partial functions in the first place. –  C. A. McCann Dec 21 '11 at 20:41
@C.A.McCann: I absolutely agree that fromJust is darn ugly. However, I have never tried to avoid every single partial function, always thought it would just blow up the code unnecessarily. Maybe this is because I come from an imperative background :P –  Niklas B. Dec 21 '11 at 20:45
It doesn't bloat the code that much. For one thing, if a function isn't defined on some arguments it might just have the wrong type signature. If the argument types only include the values you want, the code won't be any bigger than otherwise. When that's not possible, you can use the Monad instances for Maybe and Either to let errors automatically propagate upward, much like exceptions in other languages. –  C. A. McCann Dec 21 '11 at 21:02