X-Git-Url: https://git.xandkar.net/?a=blobdiff_plain;f=src%2Fhope_list.erl;h=b5edf42cee87533dc8d630334a175c78b7326756;hb=fcfc097ab895201de0cf21ebd89a8039b37bf25a;hp=9ce451e927d454940d3dca236266492dd6b61051;hpb=17b5d686d1b6c608c8fab801f44701bb0c6cccf3;p=hope.git diff --git a/src/hope_list.erl b/src/hope_list.erl index 9ce451e..b5edf42 100644 --- a/src/hope_list.erl +++ b/src/hope_list.erl @@ -6,12 +6,104 @@ -export( [ unique_preserve_order/1 + , map/2 + , map/3 % Tunable recursion limit + , map_rev/2 + , map_slow/2 + , map_result/2 % Not tail-recursive + , first_match/2 + , divide/2 ]). +-define(DEFAULT_RECURSION_LIMIT, 1000). -type t(A) :: [A]. +%% @doc Tail-recursive equivalent of lists:map/2 +%% @end +-spec map([A], fun((A) -> (B))) -> + [B]. +map(Xs, F) -> + map(Xs, F, ?DEFAULT_RECURSION_LIMIT). + +-spec map([A], fun((A) -> (B)), RecursionLimit :: non_neg_integer()) -> + [B]. +map(Xs, F, RecursionLimit) -> + map(Xs, F, RecursionLimit, 0). + +map([], _, _, _) -> + []; +map([X1], F, _, _) -> + Y1 = F(X1), + [Y1]; +map([X1, X2], F, _, _) -> + Y1 = F(X1), + Y2 = F(X2), + [Y1, Y2]; +map([X1, X2, X3], F, _, _) -> + Y1 = F(X1), + Y2 = F(X2), + Y3 = F(X3), + [Y1, Y2, Y3]; +map([X1, X2, X3, X4], F, _, _) -> + Y1 = F(X1), + Y2 = F(X2), + Y3 = F(X3), + Y4 = F(X4), + [Y1, Y2, Y3, Y4]; +map([X1, X2, X3, X4, X5 | Xs], F, RecursionLimit, RecursionCount) -> + Y1 = F(X1), + Y2 = F(X2), + Y3 = F(X3), + Y4 = F(X4), + Y5 = F(X5), + Ys = + case RecursionCount > RecursionLimit + of true -> map_slow(Xs, F) + ; false -> map (Xs, F, RecursionLimit, RecursionCount + 1) + end, + [Y1, Y2, Y3, Y4, Y5 | Ys]. + +%% @doc lists:reverse(map_rev(L, F)) +%% @end +-spec map_slow([A], fun((A) -> (B))) -> + [B]. +map_slow(Xs, F) -> + lists:reverse(map_rev(Xs, F)). + +%% @doc Tail-recursive alternative to lists:map/2, which accumulates and +%% returns list in reverse order. +%% @end +-spec map_rev([A], fun((A) -> (B))) -> + [B]. +map_rev(Xs, F) -> + map_rev_acc(Xs, F, []). + +-spec map_rev_acc([A], fun((A) -> (B)), [B]) -> + [B]. +map_rev_acc([], _, Ys) -> + Ys; +map_rev_acc([X|Xs], F, Ys) -> + Y = F(X), + map_rev_acc(Xs, F, [Y|Ys]). + +-spec map_result([A], fun((A) -> (hope_result:t(B, C)))) -> + hope_result:t([B], C). +map_result([], _) -> + {ok, []}; +map_result([X | Xs], F) -> + case F(X) + of {ok, Y} -> + case map_result(Xs, F) + of {ok, Ys} -> + {ok, [Y | Ys]} + ; {error, _}=Error -> + Error + end + ; {error, _}=Error -> + Error + end. -spec unique_preserve_order(t(A)) -> t(A). @@ -24,3 +116,38 @@ unique_preserve_order(L) -> end end, lists:reverse(lists:foldl(PrependIfNew, [], L)). + +-spec first_match([{Tag, fun((A) -> boolean())}], A) -> + hope_option:t(Tag). +first_match([], _) -> + none; +first_match([{Tag, F} | Tests], X) -> + case F(X) + of true -> {some, Tag} + ; false -> first_match(Tests, X) + end. + +%% @doc Divide list into sublists of up to a requested size + a remainder. +%% Order unspecified. Size < 1 raises an error: +%% `hope_list__divide__size_must_be_a_positive_integer' +%% @end +-spec divide([A], pos_integer()) -> + [[A]]. +divide(_, Size) when Size < 1 orelse not is_integer(Size) -> + % Q: Why? + % A: For N < 0, what does it mean to have a negative-sized chunk? + % For N = 0, we can imagine that a single chunk is an empty list, but, + % how many such chunks should we produce? + % This is pretty-much equivalnet to the problem of deviding something by 0. + error(hope_list__divide__size_must_be_a_positive_integer); +divide([], _) -> + []; +divide([X1 | Xs], MaxChunkSize) -> + MoveIntoChunks = + fun (X2, {Chunk, Chunks, ChunkSize}) when ChunkSize >= MaxChunkSize -> + {[X2], [Chunk | Chunks], 1} + ; (X2, {Chunk, Chunks, ChunkSize}) -> + {[X2 | Chunk], Chunks, ChunkSize + 1} + end, + {Chunk, Chunks, _} = lists:foldl(MoveIntoChunks, {[X1], [], 1}, Xs), + [Chunk | Chunks].