Difference between revisions of "Do notation considered harmful"
RickyElrod (talk | contribs) (Clarify wording of do-notation downsides list, slightly) |
(→Library design: mention and link to Functor-Applicative-Monad Proposal) |
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return (x-y) |
return (x-y) |
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</haskell> |
</haskell> |
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| − | where <hask>3+5</hask> is probably not evaluated at all, because |
+ | where <hask>3+5</hask> is probably not evaluated at all, because its result is not necessary to find out that the entire <hask>do</hask> describes a <hask>Nothing</hask>. |
| − | that the entire <hask>do</hask> describes a <hask>Nothing</hask>. |
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=== Library design === |
=== Library design === |
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| − | Unfortunately, the <hask>do</hask> notation is so popular that people write more things with monads than necessary. |
+ | Unfortunately, the <hask>do</hask> notation is so popular that people write more things with monads than necessary. See for instance the [http://hackage.haskell.org/cgi-bin/hackage-scripts/package/binary-0.4.1 Binary] package. It contains the <hask>Put</hask> monad, which in principle [http://www.haskell.org/pipermail/haskell-cafe/2009-January/053317.html has nothing to do with a monad]. |
| − | See for instance the [http://hackage.haskell.org/cgi-bin/hackage-scripts/package/binary-0.4.1 Binary] package. |
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| − | It contains the <hask>Put</hask> monad, which has in principle [http://www.haskell.org/pipermail/haskell-cafe/2009-January/053317.html nothing to do with a monad]. |
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All "put" operations have the monadic result <hask>()</hask>. |
All "put" operations have the monadic result <hask>()</hask>. |
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In fact it is a <hask>Writer</hask> monad using the <hask>Builder</hask> type, and all you need is just the <hask>Builder</hask> monoid. |
In fact it is a <hask>Writer</hask> monad using the <hask>Builder</hask> type, and all you need is just the <hask>Builder</hask> monoid. |
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| + | Even more unfortunate, the [[applicative functor]]s were introduced to Haskell's standard libraries only after [[monad]]s and [[arrow]]s, thus many types were instances of the <hask>Monad</hask> and <hask>Arrow</hask> classes, but not instances of <hask>Applicative</hask>. Fortunately, since GHC 7.10 the [[Functor-Applicative-Monad Proposal]] is implemented and now <hask>Applicative</hask> ''is'' a superclass of <hask>Monad</hask>. There is no special syntax for applicative functors because it is hardly necessary. |
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| − | Even more unfortunate, |
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| − | the [[applicative functor]]s were introduced to Haskell's standard libraries only after [[monad]]s and [[arrow]]s, |
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| − | thus many types are instances of <hask>Monad</hask> and <hask>Arrow</hask> classes, |
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| − | but not as much are instances of <hask>Applicative</hask>. |
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| − | There is no special syntax for applicative functors because it is hardly necessary. |
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You just write |
You just write |
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<haskell> |
<haskell> |
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| − | data Header = Header Char Int Bool |
+ | data Header = Header Char Int Bool |
| − | readHeader :: Get Header |
+ | readHeader :: Get Header |
| − | readHeader = liftA3 Header get get get |
+ | readHeader = liftA3 Header get get get |
</haskell> |
</haskell> |
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or |
or |
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<haskell> |
<haskell> |
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| − | readHeader = Header <$> get <*> get <*> get |
+ | readHeader = Header <$> get <*> get <*> get |
</haskell> |
</haskell> |
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| − | Not using monads |
+ | <br>Not using monads, along with the <hask>do</hask> notation, can have advantages. |
| − | Consider a generator of unique identifiers. |
+ | Consider a generator of unique identifiers. First you might think of a <hask>State</hask> monad which increments a counter each time an identifier is requested. |
| + | |||
| − | First you might think of a <hask>State</hask> monad which increments a counter each time an identifier is requested. |
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<haskell> |
<haskell> |
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run :: State Int a -> a |
run :: State Int a -> a |
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| Line 107: | Line 100: | ||
</haskell> |
</haskell> |
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| ⚫ | |||
| − | |||
| ⚫ | |||
that you will not combine blocks of code using the counter |
that you will not combine blocks of code using the counter |
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(where the second block needs the state at the end of the first block), |
(where the second block needs the state at the end of the first block), |
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| + | you can enforce a more strict scheme of usage. The following is like a <hask>Reader</hask> monad, where we call <hask>local</hask> on an incremented counter for each generated identifier. Alternatively you can view it as [[Continuation]] monad. |
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| − | you can enforce a more strict scheme of usage. |
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| − | The following is like a <hask>Reader</hask> monad, |
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| − | where we call <hask>local</hask> on an incremented counter for each generated identifier. |
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| − | Alternatively you can view it as [[Continuation]] monad. |
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<haskell> |
<haskell> |
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| Line 135: | Line 124: | ||
This way users cannot accidentally place a <hask>return</hask> |
This way users cannot accidentally place a <hask>return</hask> |
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somewhere in a <hask>do</hask> block where it has no effect. |
somewhere in a <hask>do</hask> block where it has no effect. |
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| − | |||
=== Safety === |
=== Safety === |
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| Line 144: | Line 132: | ||
In an imperative language it is common to return an error code and provide the real work by side effects. |
In an imperative language it is common to return an error code and provide the real work by side effects. |
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In Haskell this cannot happen, because functions have no side effects. |
In Haskell this cannot happen, because functions have no side effects. |
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| − | If you ignore the result of a Haskell function the function will |
+ | If you ignore the result of a Haskell function, the function will not even be evaluated. |
The situation is different for <hask>IO</hask>: |
The situation is different for <hask>IO</hask>: |
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| − | While processing the <hask>IO</hask> you might still ignore the contained return value. |
+ | While processing the <hask>IO</hask>, you might still ignore the contained return value. |
You can write |
You can write |
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| Line 161: | Line 149: | ||
Is this behaviour wanted? |
Is this behaviour wanted? |
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| − | + | There are possibilities to explicitly ignore return values in safety oriented languages |
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(e.g. <code>EVAL</code> in [http://www.modula3.org/ Modula-3]). |
(e.g. <code>EVAL</code> in [http://www.modula3.org/ Modula-3]). |
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Haskell does not need this, because you can already write |
Haskell does not need this, because you can already write |
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| Line 208: | Line 196: | ||
=== Alternative combinators === |
=== Alternative combinators === |
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| − | If you are used to |
+ | If you are used to writing monadic functions using infix combinators <hask>(>>)</hask> and <hask>(>>=)</hask> |
you can easily switch to a different set of combinators. |
you can easily switch to a different set of combinators. |
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| − | This is useful when there is a monadic structure that does not fit into the current <hask>Monad</hask> type constructor class, |
+ | This is useful when there is a monadic structure that does not fit into the current <hask>Monad</hask> type constructor class, where the monadic result type cannot be constrained. |
| ⚫ | |||
| − | where the monadic result type cannot be constrained. |
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| ⚫ | |||
| − | where the element type must have a total order. |
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== Useful applications == |
== Useful applications == |
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| − | It shall be mentioned that the <hask>do</hask> sometimes takes the burden from you |
+ | It shall be mentioned that the <hask>do</hask> sometimes takes the burden away from you of writing boring things. |
E.g. in |
E.g. in |
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<haskell> |
<haskell> |
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getRight :: Either a b -> Maybe b |
getRight :: Either a b -> Maybe b |
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getRight y = |
getRight y = |
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| − | do Right x <- |
+ | do Right x <- y |
return x |
return x |
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</haskell> |
</haskell> |
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| − | a <hask>case</hask> on <hask>y</hask> is included, |
+ | a <hask>case</hask> on <hask>y</hask> is included, which calls <hask>fail</hask> if <hask>y</hask> is not a <hask>Right</hask> (i.e. <hask>Left</hask>), and thus returns <hask>Nothing</hask> in this case. |
| − | which calls <hask>fail</hask> if <hask>y</hask> is not a <hask>Right</hask> (i.e. <hask>Left</hask>), |
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| − | and thus returns <hask>Nothing</hask> in this case. |
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Also the <hask>mdo</hask> notation proves useful, since it maintains a set of variables for you in a safe manner. |
Also the <hask>mdo</hask> notation proves useful, since it maintains a set of variables for you in a safe manner. |
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Revision as of 14:28, 29 April 2020
Criticism
Haskell's do notation is popular and ubiquitous. However we shall not ignore that there are several problems. Here we like to shed some light on aspects you may not have thought about, so far.
Didactics
The do notation hides functional details.
This is wanted in order to simplify writing imperative style code fragments.
The downsides are that:
- Since
donotation is used almost everywhereIOtakes place, newcomers quickly believe that thedonotation is necessary for doingIO, - Newcomers might think that
IOis somehow special and non-functional, in contrast to the advertisement for Haskell being purely functional, - Newcomers might think that the order of statements determines the order of execution.
These misunderstandings let people write clumsy code like
do putStrLn "text"
instead of
putStrLn "text"
or
do text <- getLine
return text
instead of
getLine
or
do
text <- readFile "foo"
writeFile "bar" text
instead of
readFile "foo" >>= writeFile "bar"
.
The order of statements is also not the criterion for the evaluation order. Also here only the data dependencies count. See for instance
do x <- Just (3+5)
y <- Just (5*7)
return (x-y)
where 3+5 and 5*7 can be evaluated in any order, also in parallel.
Or consider
do x <- Just (3+5)
y <- Nothing
return (x-y)
where 3+5 is probably not evaluated at all, because its result is not necessary to find out that the entire do describes a Nothing.
Library design
Unfortunately, the do notation is so popular that people write more things with monads than necessary. See for instance the Binary package. It contains the Put monad, which in principle has nothing to do with a monad.
All "put" operations have the monadic result ().
In fact it is a Writer monad using the Builder type, and all you need is just the Builder monoid.
Even more unfortunate, the applicative functors were introduced to Haskell's standard libraries only after monads and arrows, thus many types were instances of the Monad and Arrow classes, but not instances of Applicative. Fortunately, since GHC 7.10 the Functor-Applicative-Monad Proposal is implemented and now Applicative is a superclass of Monad. There is no special syntax for applicative functors because it is hardly necessary.
You just write
data Header = Header Char Int Bool
readHeader :: Get Header
readHeader = liftA3 Header get get get
or
readHeader = Header <$> get <*> get <*> get
Not using monads, along with the do notation, can have advantages.
Consider a generator of unique identifiers. First you might think of a State monad which increments a counter each time an identifier is requested.
run :: State Int a -> a
run m = evalState m 0
newId :: State Int Int
newId =
do n <- get
modify succ
return n
example :: (Int -> Int -> a) -> a
example f =
run $
do x <- newId
y <- newId
return (f x y)
If you are confident that you will not need the counter state at the end and
that you will not combine blocks of code using the counter
(where the second block needs the state at the end of the first block),
you can enforce a more strict scheme of usage. The following is like a Reader monad, where we call local on an incremented counter for each generated identifier. Alternatively you can view it as Continuation monad.
newtype T a = T (Int -> a)
run :: T a -> a
run (T f) = f 0
newId :: (Int -> T a) -> T a
newId f = T $ \i -> case f i of T g -> g (succ i)
example :: (Int -> Int -> T a) -> a
example f =
run $
newId $ \a ->
newId $ \b ->
f a b
This way users cannot accidentally place a return
somewhere in a do block where it has no effect.
Safety
- This page addresses an aspect of Haskell style, which is to some extent a matter of taste. Just pick what you find appropriate for you and ignore the rest.
With do notation we have kept alive a dark side of the C programming language:
The silent neglect of return values of functions.
In an imperative language it is common to return an error code and provide the real work by side effects.
In Haskell this cannot happen, because functions have no side effects.
If you ignore the result of a Haskell function, the function will not even be evaluated.
The situation is different for IO:
While processing the IO, you might still ignore the contained return value.
You can write
do getLine
putStrLn "text"
and thus silently ignore the result of getLine.
The same applies to
do System.Cmd.system "echo foo >bar"
where you ignore the ExitCode.
Is this behaviour wanted?
There are possibilities to explicitly ignore return values in safety oriented languages
(e.g. EVAL in Modula-3).
Haskell does not need this, because you can already write
do _ <- System.Cmd.system "echo foo >bar"
return ()
Writing _ <- should always make you cautious whether ignoring the result is the right thing to do.
The possibility for silently ignoring monadic return values is not entirely the fault of the do notation.
It would suffice to restrict the type of the (>>) combinator to
(>>) :: m () -> m a -> m a
This way, you can omit _ <- only if the monadic return value has type ().
New developments:
- GHC since version 6.12 emits a warning when you silently ignore a return value
- There is a new function called
voidthat makes ignoring of return values explicit: GHC ticket 3292
Happy with less sugar
Additional combinators
Using the infix combinators for writing functions simplifies the addition of new combinators.
Consider for instance a monad for random distributions.
This monad cannot be an instance of MonadPlus,
because there is no mzero (it would be an empty list of events, but their probabilities do not sum up to 1)
and mplus is not associative because we have to normalize the sum of probabilities to 1.
Thus we cannot use standard guard for this monad.
However we would like to write the following:
do f <- family
guard (existsBoy f)
return f
Given a custom combinator which performs a filtering with subsequent normalization called (>>=?) :: Distribution a -> (a -> Bool) -> Distribution a
we can rewrite this easily:
family >>=? existsBoy
Note that the (>>=?) combinator introduces the risk of returning an invalid distribution (empty list of events),
but it seems that we have to live with that problem.
Alternative combinators
If you are used to writing monadic functions using infix combinators (>>) and (>>=)
you can easily switch to a different set of combinators.
This is useful when there is a monadic structure that does not fit into the current Monad type constructor class, where the monadic result type cannot be constrained.
This is e.g. useful for the Set data type, where the element type must have a total order.
Useful applications
It shall be mentioned that the do sometimes takes the burden away from you of writing boring things.
E.g. in
getRight :: Either a b -> Maybe b
getRight y =
do Right x <- y
return x
a case on y is included, which calls fail if y is not a Right (i.e. Left), and thus returns Nothing in this case.
Also the mdo notation proves useful, since it maintains a set of variables for you in a safe manner.
Compare
mdo x <- f x y z
y <- g x y z
z <- h x y z
return (x+y+z)
and
mfix
(\ ~( ~(x,y,z), _) ->
do x <- f x y z
y <- g x y z
z <- h x y z
return ((x,y,z),x+y+z))
See also
- Paul Hudak in Haskell-Cafe: A regressive view of support for imperative programming in Haskell
- Data.Syntaxfree on Wordpress: Do-notation considered harmful
- Things to avoid#do notation