In this question Will's answer states that the following code (let's call it code A
):
reverse2lines :: IO ()
reverse2lines =
do line1 <- getLine
line2 <- getLine
putStrLn (reverse line2)
putStrLn (reverse line1)
can be transformed into the following (let's call it code B
) :
reverse2lines =
do { line1 <- getLine ;
do { line2 <- getLine ;
do { putStrLn (reverse line2) ;
do { putStrLn (reverse line1) } } } }
I am confused. I understand, for example, that
addOneInt :: IO ()
addOneInt = do line <- getLine
putStrLn (show (1 + read line :: Int))
can be transformed into:
addOneInt' :: IO ()
addOneInt' = getLine >>= \line ->
putStrLn (show ( 1 + read line :: Int))
But I don't understand how the nested do
transformation works. In other words, I don't understand how one arrives from code A
to code B
? What are the rules governing this transformation ?
Where are these rules described / explained / specified ?
Could someone please explain what is going on here with this (codeA
to codeB
) transformation ?
For example, what does do { command1; do {command2 } }
mean ? How should I interpret that ? What is its definition ?
In other words,
what is the difference between
do {command1;command2}
and
do {command1; do {command2}}
?
Furthermore, what is the difference between
do {command1; do{command2};command3}
and
do {command1;do {command2; do {command3}}}
?
Thanks for reading.
do single_expr
is exactly the same assingle_expr
. Sodo { cmd1; cmd2 }
anddo { cmd1; do {cmd2} }
are identical. To put it another way, thehlint
tool that checks your code for stylistic problems will flagdo single_expr
as a redundantdo
, and tell you to remove it since it is unnecessary.do { cmd1; cmd2 }
is the same ascmd1 >> cmd2
, which is the same ascmd1 >>= \_ -> cmd2
. So that means thatdo { cmd1; do { cmd2 } } === do { cmd1; cmd2 } === cmd1 >> cmd2 === cmd1 >>= \_ -> cmd2
.