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I'm just wondering about a recursion function I'm laying out in Haskell. Is it generally better to use guards than patterns for recursion functions?

I'm just not sure on what the best layout is but I do know that patterns are better when defining functions such as this:

units :: Int -> String

units 0 = "zero"
units 1 = "one"

is much preferred to

units n
    | n == 0 = "zero"
    | n == 1 = "one"

I'm just not sure though when it comes to recursion as to whether this is the same or different.

Just not quite sure on terminology: I'm using something like this:

f y [] = [] 
f y (x:xs) 
    | y == 0 = ...... 
    | otherwise = ...... 

or would this be better?

f y [] = [] 
f 0 (x:xs) = 
f y (x:xs) =
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5 Answers 5

up vote 6 down vote accepted

My general rule of thumb would be this:

  • Use pattern matching when the guard would be a simple == check.

With recursion, you usually are checking for a base case. So if your base case is a simple == check, then use pattern matching.

So I'd generally do this:

map f [] = []
map f (x:xs) = f x : map f xs

Instead of this (null simply checks if a list is empty. It's basically == []):

map f xs | null xs   = []
         | otherwise = f (head xs) : map f (tail xs)

Pattern matching is meant to make your life easier, imho, so in the end you should do what makes sense to you. If you work with a group, then do what makes sense to the group.


For your particular case, I'd do something like this:

f _ []      = []
f 0 _       = ...
f y (x:xs)  = ...

Pattern matches, like guards, fall from top to bottom, stopping at the first definition that matches the input. I used the underscore symbol to indicate that for the first pattern match, I didn't care what the y argument was, and for the second pattern match, I didn't care what the list argument was (although, if you do use the list in that computation, then you should not use the underscore). Since it's still fairly simple ==-like checks, I'd personally stick with pattern matching.

But I think it's a matter of personal preference; your code is perfectly readable and correct as it is. If I'm not mistaken, when the code is compiled, both guards and pattern matches get turned into case statements in the end.

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Just updated my question to make it a bit more clear. The first part is right, I'm aware of that. Just a little less certain on the second part (i.e. map f (x:xs) and if f==0? – maclunian May 20 '11 at 20:41

A simple rule

  • If you are recursing on a data structure, use pattern matching
  • If your recursive condition is more complex, use guards.


Fundamentally, it depends on the test you wish to do to guard the recursion. If it is a test on the structure of a data type, use pattern matching, as it will be more efficient than redundant testing for equality.

For your example, pattern matching on the integers is obviously cleaner and more efficient:

units 0 = "zero"
units 1 = "one"

The same goes for recursive calls on any data type, where you distinguish cases via the shape of the data.

Now, if you had more complicated logical conditions, then guards would make sense.

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I know the how the units aspect of it works. – maclunian May 20 '11 at 20:25
Good. What's the problem then? – Don Stewart May 20 '11 at 20:27
just not quite sure on terminology: I'm using something like this: f y [] = [] f y (x:xs) | x == 0 = ...... | otherwise = ...... would this be better by using pattern matching than through guards? – maclunian May 20 '11 at 20:31
Sort of irrelevant, but doesn't pattern patching on numeric literals desugar into something like guards anyway? If I load units in GHCi with NoImplicitPrelude active, GHC complains about (==) not being in scope. Or does it handle patterns like that differently because of NoImplicitPrelude? – C. A. McCann May 20 '11 at 20:32
If you have a custom ADT and want to match constructors, then pattern matching is the way to go, it also applies for simple conditions (like eq). Pattern matching won't work on more complex conditions check, that's why you have guards, you may also use pattern matching and guards combined. – Roman Gonzalez May 20 '11 at 20:33

There aren't really hard and fast rules on this, which is why the answers you've gotten were a bit hazy. Some decisions are easy, like pattern matching on [] instead of guarding with f xs | null xs = ... or, heaven forbid, f xs | length xs == 0 = ... which is terrible in multiple ways. But when there's no compelling practical issue, just use whichever makes the code clearer.

As an example, consider these functions (that aren't really doing anything useful, just serving as illustrations):

f1 _ [] = [] 
f1 0 (x:xs) = [[x], xs]
f1 y (x:xs) = [x] : f1 (y - 1) xs

f2 _ [] = []
f2 y (x:xs) | y == 0    = calc 1 : f2 (- x) xs
            | otherwise = calc (1 / y) : f2 (y * x) xs
  where calc z = x * ...

In f1, the separate patterns emphasize that the recursion has two base cases. In f2, the guards emphasize that 0 is merely a special case for some calculations (most of which are done by calc, defined in a where clause shared by both branches of the guard) and doesn't change the structure of the computation.

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+1 shared where is a good reason to prefer guards over pattern matching. Also note that due to laziness, if you enter a guard that doesn't use some of the where expressions, those unused expressions will never be evaluated (because they don't need to be). – Dan Burton May 20 '11 at 22:05

@Dan is correct: it's basically a matter of personal preferences and doesn't affect the generated code. This module:

module Test where

units :: Int -> String
units 0 = "zero"
units 1 = "one"

unitGuarded :: Int -> String
unitGuarded n
  | n == 0 = "zero"
  | n == 1 = "one"

produced the following core:

Test.units =
  \ (ds_dkU :: GHC.Types.Int) ->
    case ds_dkU of _ { GHC.Types.I# ds1_dkV ->
    case ds1_dkV of _ {
      __DEFAULT -> Test.units3;
      0 -> Test.unitGuarded2;
      1 -> Test.unitGuarded1

Test.unitGuarded =
  \ (n_abw :: GHC.Types.Int) ->
    case n_abw of _ { GHC.Types.I# x_ald ->
    case x_ald of _ {
      __DEFAULT -> Test.unitGuarded3;
      0 -> Test.unitGuarded2;
      1 -> Test.unitGuarded1

Exactly the same, except for the different default case, which in both instances is a pattern match error. GHC even commoned-up the strings for the matched cases.

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The answers so far do not mention the advantage of pattern matching which is the most important for me: ability to safely implement total functions.

When doing pattern matching you can safely access the internal structure of the object without the fear of this object being something else. In case you forget some of the patterns, the compiler can warn you (unfortunately this warning is off by default in GHC).

For example, when writing this:

map f xs | null xs   = []
         | otherwise = f (head xs) : map f (tail xs)

You are forced to use non-total functions head and tail, thus risking the life of your program. If you make a mistake in guard conditions, the compiler can't help you.

On the other hand, if you make an error with pattern matching, the compiler can give you an error or a warning depending on how bad your error was.

Some examples:

-- compiles, crashes in runtime
map f xs | not (null xs)   = []
         | otherwise = f (head xs) : map f (tail xs)

-- does not have any way to compile
map f (h:t) = []
map f [] = f h : map f t

-- does not give any warnings
map f xs = f (head xs) : map f (tail xs)

-- can give a warning of non-exhaustive pattern match
map f (h:t) = f h : map f t
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