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I'm working on the exercises in Erlang Programming.

The question is

Write a function that, given a list of nested lists, will return a flat list.

Example: flatten([[1,[2,[3],[]]], [[[4]]], [5,6]]) ⇒ [1,2,3,4,5,6].

Hint: use concatenate to solve flatten.

And here is my concatenate function

%% concatenate([[1,2,3], [], [4, five]]) ⇒ [1,2,3,4,five].
concatenate([X|Xs]) -> concat(X, Xs, []).
concat([X|Xs], T, L) -> concat(Xs, T, [X|L]);
concat([], [X|Xs], L) -> concat(X, Xs, L);
concat([], [], L) -> reverse(L).

I really want to know an elegant way to implement flatten. I've spent hours solving this exercise.

UPDATE: I forget most important prerequisite. Is it possible solving this problem with only recursion and pattern matching?

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Yes, it is possible! –  rvirding Feb 19 '12 at 15:45

5 Answers 5

up vote 8 down vote accepted

I would try this way

flatten(X) -> lists:reverse(flatten(X,[])).

flatten([],Acc) -> Acc;
flatten([H|T],Acc) when is_list(H) -> flatten(T, flatten(H,Acc));
flatten([H|T],Acc) -> flatten(T,[H|Acc]).

testing

my:flatten([[1,[2,[3],[]]], [[[4]]], [5,6]]).
[1,2,3,4,5,6]

UPD: or this way, without guards and reverse, only recursive calls and pattern matching.

flatten(X)               -> flatten(X,[]).

flatten([],Acc)          -> Acc;
flatten([[]|T],Acc)      -> flatten(T, Acc);
flatten([[_|_]=H|T],Acc) -> flatten(T, flatten(H,Acc));
flatten([H|T],Acc)       -> flatten(T,Acc++[H]) .
share|improve this answer
    
Is it possible solving this problem with only recursion and pattern matching? –  Vayn Feb 19 '12 at 4:16
    
The hint totally misled me. Thank you! –  Vayn Feb 19 '12 at 11:07
    
Using ++ is inefficient as it copies the whole list. –  rvirding Feb 19 '12 at 16:14
    
@rvirding thats correct. That is why in real life a would prefer first variant. But as exercise ++ is ok. –  Odobenus Rosmarus Feb 19 '12 at 20:22
    
True, that it is –  rvirding Feb 19 '12 at 22:31

Some different solutions, getting smarter and smarter:

%% Lift nested lists to the front of the list.
flatten1([[H|T1]|T2]) -> flatten1([H,T1|T2]);
flatten1([[]|T]) -> flatten1(T);
flatten1([E|T]) -> [E|flatten1(T)];
flatten1([]) -> [].

or

%% Keep a list of things todo and put tails onto it.
flatten2(L) -> flatten2(L, []).

flatten2([H|T], Todo) ->
    flatten2(H, [T|Todo]);
flatten2([], [H|Todo]) -> flatten2(H, Todo);
flatten2([], []) -> [];
flatten2(E, Todo) -> [E|flatten2(Todo, [])].

or

%% Work from the back and keep a tail of things done.
flatten3(L) -> flatten3(L, []).

flatten3([H|T], Tail) ->
    flatten3(H, flatten3(T, Tail));
flatten3([], Tail) -> Tail;
flatten3(E, Tail) -> [E|Tail].

These are all with only pattern matching and recursion, but they can be improved with some guard type tests. Using ++ is inefficient as it copies the list every time. The lists module uses a version of the last one with a guard type test instead of the last clause.

share|improve this answer
    
I found this. So when should I use ++ operator? –  Vayn Feb 19 '12 at 17:13
    
And now I think use list comprehension and ++ operator to implement quicksort is not a good idea :( –  Vayn Feb 19 '12 at 17:30
2  
@Vayn what you should try and avoid is to append elements to the end of a list with ++, or any other way for that matter. Appending is not the best operation on a list. Joining two lists together is a another matter. One way of getting around it is to carry around a tail as in my third example. –  rvirding Feb 19 '12 at 22:34

concatenate/1 as defined in the book works as a flatten function which flattens down only one level. ([[1],[2]] becomes [1,2], [[[1]],[[2]]] becomes [[1],[2]], etc.) The strategy suggested in the hint is to flatten completely not by defining new logic in flatten/1 but by using concatenate/1 in flatten/1's recursive calls.

concatenate(Ls) ->
    reverse(concatenate(Ls, [])).

concatenate([], Acc) ->
    Acc;
concatenate([[]|Rest], Acc) ->
    concatenate(Rest, Acc);
concatenate([[H|T]|Rest], Acc) ->
    concatenate([T|Rest], [H|Acc]);
concatenate([H|T], Acc) ->
    concatenate(T, [H|Acc]).

flatten(L) ->
    flatten(L, []).

flatten([], Acc) ->
    Acc;
flatten(L, Acc) ->
    Concatted = concatenate(L),
    [Non_lists|Remainder] = find_sublist(Concatted),
    flatten(Remainder, concatenate([Acc, Non_lists])).

find_sublist(L) ->
    find_sublist(L, []).

find_sublist([], Acc) ->
    reverse(Acc);
find_sublist(L = [[_|_]|_], Acc) ->
    [reverse(Acc)|L];
find_sublist([H|T], Acc) ->
    find_sublist(T, [H|Acc]).

tests() ->
    [1,2,3,4,4,5,6,7,8] = flatten([[1,[2,[3],[]]], [[[4,[4]]]], [[5],6], [[[]]], [], [[]], [[[7, 8]]]]),
    [1,2] = flatten([[1,2]]),
    [1,2,3] = flatten([[1],[2],[3]]),
    [1,2,3,4,5,6] = flatten([[1,[2,[3],[]]], [[[4]]], [5,6]]),
    tests_successful.
share|improve this answer

Pretty concise and straightforward version:

append([H | T], L) -> [H | append(T, L)];
append([], L) -> L.

flatten([[_|_]=H|T]) -> append(flatten(H), flatten(T));
flatten([[]|T]) -> flatten(T);
flatten([H|T]) -> [H|flatten(T)];
flatten([]) -> [].
share|improve this answer
    
Thank you. I was about to supply this solution myself after seeing that other solutions use ++ in a bad way. –  Daniel Luna Feb 22 '12 at 20:21
    
@DanielLuna, append is equivalent of ++ –  Odobenus Rosmarus Feb 23 '12 at 22:26
    
@OdobenusRosmarus: neither ++ nor append is problem but use in bad way is. I'm applying append with traversal of flattened head but you are using it to growing Acc which is simply terribly wrong. I think it is wrong even for exercise. –  Hynek -Pichi- Vychodil Feb 24 '12 at 10:33
    
@Hynek-Pichi-Vychodil 1) without context it just doesnt make any sense to count cpu ticks -it's just premature optimization. 2) But if you want to count ticks - just trace your and my program for example for data [1,[2,[3,4,5]]], and you'll see that ++ invokes 5 times with short data, and your append() invokes 9 times (including cases with full list). And 3) (last but not least) -- nice nickname :-) –  Odobenus Rosmarus Feb 24 '12 at 11:40
1  
@OdobenusRosmarus: Implementing something in quadratic way when you easily can do ti in linear is simply stupid thing. It is not about counting clock ticks, it is about algorithms and has nothing common with 'pecularities of erlang VM implementation'. –  Hynek -Pichi- Vychodil Mar 9 '12 at 16:35

The question's key is "divide and conquer".

Another extra function "lists:reverse" and an operator "++" are used for saving programing time.

my_flat([],Result)-> lists:reverse(Result); my_flat([H|T],Result) when is_atom(H) -> case T of []-> my_flat([],[H|Result]); _Else -> my_flat(T,[H|Result]) end; my_flat([H|T],Result) when is_number(H)-> case T of []-> my_flat([],[H|Result]); _Else -> my_flat(T,[H|Result]) end; my_flat([H|T],Result) -> my_flat(H,Result)++my_flat(T,[]).

for your test: test:my_flat([[1,[2,[3],[]]], [[[4]]], [5,6]],[]).

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