Means of expression
Programming languages have different types of means of expression:
- Primary means of expression: variables, types, parentheses, modules, etc. in general all things that are relevant to the compiler
- Secondary means of expression: language irrelevant layout and spacing, comments, conventions, etc. that is language elements that are irrelevant for the compiler, and thus are made exclusively for the human reader
It is generally good style to remember the rule:
- Prefer primary means of expression to secondary ones!
The reason is, that elements that are relevant to the compiler are checked by the compiler and can be processed by documentation, analysis and refactoring tools. Thus it is not good style to comment intensively if the language provides primary ways to express our ideas.
1.1 Expressive names instead of comments
I recently saw code like
-- | first name fn :: Person -> String -- | surname sn :: Person -> String
It was hard to read the program because there were several other two-character function names to remember, and the comment was only attached to the function definition, not the calls. The comments would be better replaced by expressive function names like
firstName :: Person -> String surname :: Person -> String
1.2 Functions instead of comments
solveSLE2 :: Fractional a => ((a,a), (a,a)) -> (a,a) -> (a,a) solveSLE2 ((a00,a10),(a01,a11)) (b0,b1) = let det = a00*a11 - a10*a01 in (-- determinant with first column replaced by b (b0*a11 - b1*a01) / det, -- determinant with second column replaced by b (a00*b1 - a10*b0) / det)
It is likely that logical units like the 2x2 determinant are reused later (e.g. for the vector product) or that they should be tested separately. Thus it is better to factor them out into separate functions.
solveSLE2 :: Fractional a => ((a,a), (a,a)) -> (a,a) -> (a,a) solveSLE2 a@(a0,a1) b = let det = det2 a in (det2 (b, a1) / det, det2 (a0, b) / det) det2 :: Num a => ((a,a), (a,a)) -> a det2 ((a00,a10),(a01,a11)) = a00*a11 - a10*a01
1.3 Types instead of comments
-- | returned list contains at most one element foo :: [a] -> [a]
This can be expressed without comments more safely and concisely
foo :: [a] -> Maybe a
1.4 Proper types instead of special values
In languages like C you often see declarations like
/* This function returns the number of objects or -1 if there was an I/O error. */ int count (description d);
It is very easy to miss an error indicated by the
and the language let you do arithmetic even with the error indicating value
-1 as in
c = count(d0)+count(d1);
But C only allows one return value per function. Further results have to be written to a pointer argument (cumbersome) or to a global variable (easy to miss, too, and not thread-safe). Haskells type system supports such situations much better and you should use this support. Try hard to avoid values that have a special meaning by using appropriate types for indicating special conditions as in
count :: Description -> IO (Maybe Int)
1.5 Qualification instead of identifier prefix/suffix conventions
You may define
module File where openFile :: FilePath -> IO Handle
and intend to import that unqualified
import File main :: IO () main = do h <- openFile "myfile" ...
in other modules, or you can define
module File where open :: FilePath -> IO Handle
that would fit for qualified import as in
import qualified File main :: IO () main = do h <- File.open "myfile" ...
The second way would use primary means of the language (modules and qualified imports) whereas the first way uses secondary means of the language (naming convention). The naming convention cannot be checked,that is
would be accepted by any Haskell compiler and it forces the user to follow this convention, leading to respect different conventions from different packages that are imported in one module, e.g. type name in the identifier as prefix vs. suffix. Using qualified imports, the importer can choose an abbreviation that he likes, say:
import qualified File as F main :: IO () main = do h <- F.open "myfile" ...
and thus assert a consistent naming style in his module.
2 See also
Johannes Waldmann: Haskell mit Stil