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I'm writing a program which reads and writes images that supports multiple pixel types (i.e. RGB, CMYK, greyscale etc.). These pixel types can use different types of components, sort of like this:

class (Storable c) => PixelComponent c where
    blackWhite :: c -> (c, c)
    toInt :: c -> Int
    toRealFrac :: (RealFrac a) => c -> a
    fromComponent :: (PixelComponent a) => a -> c

instance PixelComponent CUChar where
    blackWhite x = (minBound x, maxBound x)
    toInt = id
    toRealFrac = fromIntegral
    fromComponent x = ???

instance PixelComponent CFloat where
    black = 0.0
    white = 1.0
    toInt = truncate
    toReal = id
    fromComponent x = ???

class (Storable pix) => Pixel pix where
    red :: pix c -> c
    green :: pix c -> c
    blue :: pix c -> c
    alpha :: pix c -> c
    luminance :: pix c -> c
    fromPixel :: (Pixel a) => a c -> pix c

The idea is that you should be able to do getPixel myImage (10, 23) :: RGB CUChar or getPixel myImage (10, 23) :: RGB CFloat depending on the pixel format you want. The problem is that I don't know how to implement fromComponent in an efficient manner. Essentially, I would like unnecessary conversions such as fromComponent (1 :: CUChar) :: CUChar and fromComponent (0.5 :: CFloat) :: CFloat to be no-ops. I guessing that I'll have to rely on optimizations in any case.

Note: This might not be a good design anyway so if someone has a better suggestion I'm open to this. I'd still like to know how to make this solution work.

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1  
I'm wondering if fromComponent should be part of a different, multi-parameter type class dependent on both a and c. Then it seems it would be easier to defined fromComponent to be id in the case when both a and c are CUChar or CFloat, etc. –  user5402 Feb 13 '14 at 7:50
    
@user5402: that approach would certainly work. I hate having to change a design to accommodate seemingly minor optimizations though. –  John L Feb 13 '14 at 8:23
    
Have you checked whether the compiler really doesn’t optimize them away already? –  Joachim Breitner Feb 13 '14 at 9:10
    
How would I check this? @user5402: Seems like a nice solution! –  Emil Eriksson Feb 13 '14 at 9:12
1  
Compile with -ddump-simpl and read the Core – sorry, no easier way. –  Joachim Breitner Feb 13 '14 at 9:43

2 Answers 2

up vote 6 down vote accepted

I'd suggest that handle this the same way as GHC handles numeric conversions (e.g. fromIntegral), which is via rewrite rules.

If you look in GHC.Real, you find

-- | general coercion from integral types
fromIntegral :: (Integral a, Num b) => a -> b
fromIntegral = fromInteger . toInteger

{-# RULES
"fromIntegral/Int->Int" fromIntegral = id :: Int -> Int
    #-}

The default is a lot of round-tripping for integral types, but fortunately that never happens because there are RULEs for all library-provided integral types.

There are many more RULEs specified in GHC.Int for example to handle the rest of the conversions. You'll find a similar setup for other similar functions (e.g. realToFrac).

Now there's one major problem with your use-case, which is that it's often difficult for RULEs to match on class methods. There are two ways around this. The first is to define a common type (e.g. Integer in GHC's code), and provide class methods to convert to and from that type. Then write a general-purpose conversion function (e.g. fromIntegral), use that everywhere, and have your RULEs match on it.

The other approach is to do something like this:

instance PixelComponent CUChar where
    blackWhite x = (minBound x, maxBound x)
    toInt = id
    toRealFrac = fromIntegral
    {-# INLINE fromComponent #-}
    fromComponent = toCUChar

toCUChar :: PixelComponent a => a -> CUChar
toCUChar = ...

{-# RULES "fromComponent/CUChar->CUChar" toCUChar = id :: CUChar -> CUChar #-}

The former is what GHC does, so it's likely to work well. I've been using the latter approach recently and haven't had any issues though, so either one should work.

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Multi-parameter type classes might be your friend here, but keep in mind you're going to have to type out things n^2 times here.

Here's a trivial example, lets say we have separate types for lower case strings, upper case strings, and mixed strings. Obviously, converting a string to it's own type shouldn't require any work, nor should converting to a mixed string. Only conversions to an upper or lower string not from itself should require a conversion.

The code below (ideone) illustrates this approach:

{-# LANGUAGE MultiParamTypeClasses #-}

import Data.Char (toUpper, toLower)

data Lower = Lower String deriving Show
data Mixed = Mixed String deriving Show
data Upper = Upper String deriving Show

toUpperStr = map toUpper
toLowerStr = map toLower

class Make a where
  make :: String -> a

instance Make Lower where
  make s = Lower (toLowerStr s)

instance Make Mixed where
  make s = Mixed s

instance Make Upper where
  make s = Upper (toUpperStr s)

class Convert a b where
  convert :: a -> b

instance Convert Lower Lower where
  convert = id

instance Convert Lower Mixed where
  convert (Lower s) = Mixed s

instance Convert Lower Upper where
  convert (Lower s) = Upper (toUpperStr s)

instance Convert Mixed Lower where
  convert (Mixed s) = Lower (toLowerStr s)

instance Convert Mixed Mixed where
  convert = id

instance Convert Mixed Upper where
  convert (Mixed s) = Upper (toUpperStr s)

instance Convert Upper Lower where
  convert (Upper s) = Lower (toLowerStr s)

instance Convert Upper Mixed where
  convert (Upper s) = Mixed s

instance Convert Upper Upper where
  convert = id

main = print (convert ((make "Hello World") :: Lower) :: Upper)
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