Writing Applications
Lets write the classic “Hello world!” program.
For example, in Python you may write:
def main():
print "hello, world!"
main()
and then you can run it:
python hello.py
$ hello world!
Haskell is a Pure language.
Not a value judgment, but a precise technical statement:
The “Immutability Principle”:
A function must always return the same output for a given input
A function’s behavior should never change
No Side Effects
Haskell’s most radical idea: expression =*> value
When you evaluate an expression you get a value and
Nothing else happens
Specifically, evaluation must not have an side effects
change a global variable or
print to screen or
read a file or
send an email or
launch a missile.
But… how to write “Hello, world!”
But, we want to …
- print to screen
- read a file
- send an email
Thankfully, you can do all the above via a very clever idea: Recipe
Recipes
This analogy is due to Joachim Brietner
Haskell has a special type called IO
– which you can think of as Recipe
type Recipe a = IO a
A value of type Recipe a
is a description of a computation that can have side-effects
which when executed performs some effectful I/O operations
to produce a value of type
a
.
Recipes have No Side Effects
A value of type Recipe a
is
- A description of a computation that can have side-effects
(L) chocolate cake, (R) a sequence of instructions on how to make a cake.
They are different (Hint: only one of them is delicious.)
Merely having a Recipe Cake
has no effects! The recipe
Does not make your oven hot
Does not make your your floor dirty
Only One Way to Execute Recipes
Haskell looks for a special value
main :: Recipe ()
The value associated with main
is handed to the runtime system and executed
The Haskell runtime is a master chef who is the only one allowed to cook!
How to write an App in Haskell
Make a Recipe ()
that is handed off to the master chef main
.
main
can be arbitrarily complicatedcomposed of smaller sub-recipes
A Recipe to Print to Screen
putStrLn :: String -> Recipe ()
The function putStrLn
- takes as input a
String
- returns as output a
Recipe ()
putStrLn msg
is a Recipe ()
- when executed prints out msg
on the screen.
main :: Recipe ()
= putStrLn "Hello, world!" main
… and we can compile and run it
ghc --make hello.hs
$ ./hello
$ Hello, world!
QUIZ: How to Print Multiple Things?
Suppose I want to print two things e.g.
ghc --make hello.hs
$ ./hello2
$ Hello!
World!
Can we try to compile and run this:
= (putStrLn "Hello!", putStrLn "World!") main
A. Yes!
B. No, there is a type error!
C. No, it compiles but produces a different result!
A Collection of Recipes
Is just … a collection of Recipes!
recPair :: (Recipe (), Recipe ())
= (putStrLn "Hello!", putStrLn "World!")
recPair
recList :: [Recipe ()]
= [putStrLn "Hello!", putStrLn "World!"] recList
… we need a way to combine recipes!
Combining? Just do
it!
We can combine many recipes into a single one using a do
block
foo :: Recipe a3
= do r1 -- r1 :: Recipe a1
foo -- r2 :: Recipe a2
r2 -- r3 :: Recipe a3 r3
(or if you prefer curly braces to indentation)
= do { r1; -- r1 :: Recipe a1
foo -- r2 :: Recipe a2
r2; -- r3 :: Recipe a3
r3 }
The do
block combines sub-recipes r1
, r2
and r3
into a new recipe that
- Will execute each sub-recipe in sequence and
- Return the value of type
a3
produced by the last reciper3
Combining? Just do
it!
So we can write
= do putStrLn "Hello!"
main putStrLn "World!"
or if you prefer
= do { putStrLn "Hello!";
main putStrLn "World!"
}
EXERCISE: Combining Many Recipes
Write a function called sequence
that
- Takes a non-empty list of recipes
[r1,...,rn]
as input and - Returns a single recipe equivalent to
do {r1; ...; rn}
sequence :: [Recipe a] -> Recipe a
sequence rs = ???
When you are done you should see the following behavior
-- Hello.hs
= sequence [putStrLn "Hello!", putStrLn "World!"] main
and then
ghc --make Hello.hs
$ ./hello
$ Hello!
World!
Using the Results of (Sub-) Recipes
Suppose we want a function that asks for the user’s name
./hello
$ What is your name?
Ranjit # <<<<< user enters
Hello Ranjit!
We can use the following sub-recipes
-- | read and return a line from stdin as String
getLine :: Recipe String
-- take a string s, return a recipe that prints s
putStrLn :: String -> Recipe ()
But how to
- Combine the two sub-recipes while
- Passing the result of the first sub-recipe to the second.
Naming Recipe Results via “Assignment”
You can write
<- recipe x
to name the result of executing recipe
x
can be used to refer to the result in later code
Naming Recipe Results via “Assignment”
Lets, write a function that asks for the user’s name
= ask
main
ask :: Recipe ()
= do name <- getLine;
ask putStrLn ("Hello " ++ name ++ "!")
Which produces the desired result
./hello
$ What is your name?
Ranjit # user enters
Hello Ranjit!
EXERCISE
Modify the above code so that the program repeatedly asks for the users’s name until they provide a non-empty string.
-- Hello.hs
= repeatAsk
main
repeatAsk :: Recipe ()
= _fill_this_in
repeatAsk
isEmpty :: String -> Bool
= length s == 0 isEmpty s
When you are done you should get the following behavior
ghc --make hello.hs
$
./hello
$ What is your name?
# user hits return
What is your name?
# user hits return
What is your name?
# user hits return
What is your name?
Ranjit # user enters
Hello Ranjit!
EXERCISE
Modify your code to also print out a count in the prompt
ghc --make hello.hs
$
./hello
$ (0) What is your name?
# user hits return
(1) What is your name?
# user hits return
(2) What is your name?
# user hits return
(3) What is your name?
Ranjit # user enters
Hello Ranjit!
That’s all about IO
You should be able to implement build
from Directory.hs
Using these library functions imported at the top of the file
import System.FilePath (takeDirectory, takeFileName, (</>))
import System.Directory (doesFileExist, listDirectory)
The functions are
takeDirectory
takeFileName
(</>)
doesFileExist
listDirectory
hoogle
the documentation to learn about how to use them.