# Writing a recursive function with condition In Haskell:

I want a function `f::[type]->[type]` that is recursive defined roughly like this :

It starts with a list with 1 element `x`. Then it applies 3 "generator functions" lets call them `generatorA`, `generatorB`, and `generator C`, all functions `::type->type`, and adds those to the list IF they accept some condition. for each accepted generated number, it repeats applying generator `A`, `B` and `C` and test conditions until condition test is false. So for each element accepted to the list, 3 new elements will be generated and tested for list.

An example would be:

``````f::[int]->[Int]

generatorA x = x+1

generatorB x = 2x+1

generatorC x = 3x+1
``````

Condition: Must be composite number (not prime).

computing `f [10]` it should start `generatorA 10 = 11`, discard that.

`generatorB 10 = 21` accept and then:

• `generatorA 21 = 22` accept and then:
• `generatorA 22 = 23` prime discard.
• `generatorB 21 = 43` discard
• `generatorC 21 = 64` accept and etc. etc. etc.

Question is: How do i code the function `f`? I have no idea how to even begin. my best guess was

`````` f (x:xs)
|condition==True   = (something something)
|otherwise         = xs
where
a=generatorA x
b=generatorB x
c=generatorC x
``````

thanks for your help.

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If it starts with a singleton list it might as well start with a single value as its argument.

``````ga x = [y | let y=x+1, composite y] >>= (\x-> x:f x)
gb x = [y | let y=2*x+1, composite y] >>= (\x-> x:f x)
gc x = [y | let y=3*x+1, composite y] >>= (\x-> x:f x)

f :: Integer -> [Integer]
f x = ga x ++ gb x ++ gc x
``````

I use `Integer`s to avoid overflow issues. Testing:

``````*Main> take 40 \$ f 10
[21,22,45,46,93,94,95,96,289,290,291,292,585,586,1173,1174,1175,1176,1177,1178,1
179,1180,2361,2362,2363,2364,2365,2366,2367,2368,2369,2370,4741,4742,4743,4744,4
745,4746,4747,4748]
``````

`f` can also be implemented to produce the results in shallower fashion,

``````import Data.List

f x = concat \$ transpose [ga x, gb x, gc x]
``````

Testing:

``````*Main> take 80 \$ h 10
[21,22,64,45,65,46,129,91,66,136,130,93,196,92,259,273,133,94,388,183,393,274,26
1,187,134,274,260,820,589,280,777,93,267,275,391,95,394,184,519,1641,400,188,116
5,275,590,549,262,561,135,185,778,2461,1180,189,778,550,268,276,392,375,1179,549
,261,1642,801,841,1166,94,395,550,784,96,403,185,520,2462,1768,562,1555,276]
``````
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use `Data.Tree.unfoldTree :: (b -> (a, [b])) -> b -> Tree a` to build your list of values. then use `flatten` if you want preorder, or `concat . Data.Tree.levels` to have a breadth first order.

``````f x = flatten \$ unfoldTree (\b -> (b, filter composite (map (\$ b) [ga, gb, gc]))) x
``````

this list will include the initial seed element, if you don't want that element. just call `tail`.

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