I want to add Haskell to my toolbox so I'm working my way through Real World Haskell.
In the chapter in Input and Output, in the section on
hGetContents, I came across this example:
import System.IO import Data.Char(toUpper) main :: IO () main = do inh <- openFile "input.txt" ReadMode outh <- openFile "output.txt" WriteMode inpStr <- hGetContents inh let result = processData inpStr hPutStr outh result hClose inh hClose outh processData :: String -> String processData = map toUpper
Following this code sample, the authors go on to say:
hGetContentshandled all of the reading for us. Also, take a look at
processData. It's a pure function since it has no side effects and always returns the same result each time it is called. It has no need to know—and no way to tell—that its input is being read lazily from a file in this case. It can work perfectly well with a 20-character literal or a 500GB data dump on disk. (N.B. Emphasis is mine)
My question is: how does
hGetContents or its resultant values achieve this memory efficiency without – in this example –
processData "being able to tell", and still maintain all benefits that accrue to pure code (i.e.
processData), specifically memoization?
<- hGetContents inh returns a string so
inpStr is bound to a value of type
String, which is exactly the type that
processData accepts. But if I understand the authors of Real World Haskell correctly, then this string isn't quite like other strings, in that it's not fully loaded into memory (or fully evaluated, if such a things as not-fully-evaluated strings exists...) by the time of the call to
Therefore, another way to ask my question is: if
inpStr is not fully evaluated or loaded into memory at the time of the call to
processData, then how can it be used to lookup if a memoized call to
processData exists, without first fully evaluating
Are there instances of type
String that each behave differently but cannot be told apart at this level of abstraction?