# How to implement Decimal to Binary function in Haskell

I implemented a binary to decimal function in Haskell and am currently working on a function that would convert a decimal into a binary value. (I'm aware that these functionalities are available somewhere although they're not part of Prelude.hs)

I came up with the following code for a C-type procedural language, but I have trouble adapting it into the functional paradigm.

``````while (n > 0)
{
if (n % 2 == 1)
str = str + "1";
else
str = str + "0";
n = n / 2;
}
``````

I ventured into functional programming in Haskell only recently so I'm quite new to the functional way of thinking. I attempted the above using both recursion and list comprehension, but I'm not sure on how to place the guards and the logic properly since this involves multiple conditions. I use an Int list to hold the separate binary bits.

``````--Decimal to binary
toBin:: Int -> [Int]
toBin 0 = [0]
toBin n | (n % 2 == 1) =
|(n % 2 == 0) =
``````

I've understood that the above pattern would let the program choose either guard and end evaluating the function. Am I on the wrong track here?

Below is what I came up with primitive recursion to convert any base (less than 10, in place of the 2) to decimal.

``````toDecimal :: [Int] -> Int
toDecimal [] = 0
toDecimal (x:xs) = (x * 2 ^(length xs)) + bin xs
``````

Thanks in advanced.

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## 4 Answers

There's no `%` operator; you're probably looking for ``mod`` instead:

``````toBin 0 = [0]
toBin n | n `mod` 2 == 1 = ...
| n `mod` 2 == 0 = ...
``````

Guards let you choose between multiple branches of a function. In this case, each `...` will be the result of `toBin n` if its corresponding condition is true. To append two lists together, you can use the `++` operator, and ``div`` corresponds to integer division:

``````toBin 0 = [0]
toBin n | n `mod` 2 == 1 = toBin (n `div` 2) ++ [1]
| n `mod` 2 == 0 = toBin (n `div` 2) ++ [0]
``````

However, this has a few problems. For a start, it always starts the result with `0`, which is redundant; additionally, using `++ [1]` is slow, since it has to go through the entire list to add an element on to the end; it would be better to prepend each element as we go, and then reverse the result at the end.

To fix both these things, we'll split `toBin` up into a main function and a helper function:

``````toBin 0 = [0]
toBin n = reverse (helper n)

helper 0 = []
helper n | n `mod` 2 == 1 = 1 : helper (n `div` 2)
| n `mod` 2 == 0 = 0 : helper (n `div` 2)
``````

In this version, we use the `:` operator, which takes a value and a list, and returns the list with the value prepended to the beginning. We also return an empty result for 0 in our helper, and handle the 0 case in `toBin` instead, so that there's no more 0s than necessary in the result.

We can simplify `helper`'s code by skipping the guards altogether, since we just write the result of `n `mod` 2` again on the right-hand side:

``````helper 0 = []
helper n = (n `mod` 2) : helper (n `div` 2)
``````

Finally, there's a function that does a `div` and a `mod` in one go, which can be more efficient:

``````helper 0 = []
helper n = let (q,r) = n `divMod` 2 in r : helper q
``````

As an additional note, this doesn't really convert decimal to binary, it converts an integer to binary; Haskell implementations are unlikely to store integers in decimal format, although they are written and printed in that format. To write a full conversion of decimal to binary, a function that parses a decimal string into an integer would be required.

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"a function that parses a decimal string into an integer would be required" - like, erm, `read`? –  Daniel Fischer Feb 6 '12 at 20:02
@DanielFischer: Yes, but presumably the OP is trying to implement this from scratch :) After all, `showIntAtBase` exists too. –  ehird Feb 6 '12 at 20:04
``````toBinary :: Int -> [ Int ]

toBinary 0 = [ 0 ]

toBinary n = toBinary ( n `quot` 2 ) ++ [ n `rem` 2 ]
``````
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``````toBin :: Int -> [Int]
toBin 0 = [0]
toBin 1 = [1]
toBin n
| n `mod` 2 == 0 = toBin (n `div` 2) ++ [0]
| otherwise = toBin (n `div` 2) ++ [1]
``````

0 and 1 are trivial cases. if n is even then you should append zero to the end, otherwise you append one. It's good practise to catch everything in your last guard expression (that's why I used otherwise which is the same as True)

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You can use the `unfoldr` function from the `Data.List` module and `intToDigit` from `Data.Char`:

``````dec2bin :: Int -> [Char]
dec2bin = reverse . map intToDigit . unfoldr (\x -> if x==0 then Nothing else Just(rem x 2, div x 2))
``````

What happens here is the `unfoldr` function processes the input with the supplied anonymous function until it returns `Nothing`, while aggregating the first value from `Just` in a list. This list contains `Int`s, so they need to be converted to `Char`s using `intToDigit` and then reversed, since they are collected in a reverse order. A list of `Char`s is a string in Haskell, so you're done.

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