-module(gleam@list). -compile([no_auto_import, nowarn_unused_vars]). -export([length/1, reverse/1, is_empty/1, contains/2, first/1, rest/1, filter/2, filter_map/2, map/2, map2/3, index_map/2, try_map/2, drop/2, take/2, new/0, append/2, prepend/2, concat/1, flatten/1, flat_map/2, fold/3, group/2, map_fold/3, fold_right/3, index_fold/3, try_fold/3, fold_until/3, find/2, find_map/2, all/2, any/2, zip/2, strict_zip/2, unzip/1, intersperse/2, at/2, unique/1, sort/2, range/2, repeat/2, split/2, split_while/2, key_find/2, pop/2, pop_map/2, key_pop/2, key_set/3, each/2, try_each/2, partition/2, permutations/1, window/2, window_by_2/1, drop_while/2, take_while/2, chunk/2, sized_chunk/2, reduce/2, scan/3, last/1, combinations/2, combination_pairs/1, transpose/1, interleave/1, shuffle/1]). -export_type([length_mismatch/0, continue_or_stop/1]). -type length_mismatch() :: length_mismatch. -type continue_or_stop(UA) :: {continue, UA} | {stop, UA}. -spec length(list(any())) -> integer(). length(List) -> erlang:length(List). -spec reverse(list(UF)) -> list(UF). reverse(Xs) -> lists:reverse(Xs). -spec is_empty(list(any())) -> boolean(). is_empty(List) -> List =:= []. -spec contains(list(UN), UN) -> boolean(). contains(List, Elem) -> case List of [] -> false; [First | _] when First =:= Elem -> true; [_ | Rest] -> contains(Rest, Elem) end. -spec first(list(UP)) -> {ok, UP} | {error, nil}. first(List) -> case List of [] -> {error, nil}; [X | _] -> {ok, X} end. -spec rest(list(UT)) -> {ok, list(UT)} | {error, nil}. rest(List) -> case List of [] -> {error, nil}; [_ | Xs] -> {ok, Xs} end. -spec do_filter(list(VM), fun((VM) -> boolean()), list(VM)) -> list(VM). do_filter(List, Fun, Acc) -> case List of [] -> reverse(Acc); [X | Xs] -> New_acc = case Fun(X) of true -> [X | Acc]; false -> Acc end, do_filter(Xs, Fun, New_acc) end. -spec filter(list(VQ), fun((VQ) -> boolean())) -> list(VQ). filter(List, Predicate) -> do_filter(List, Predicate, []). -spec do_filter_map(list(VT), fun((VT) -> {ok, VV} | {error, any()}), list(VV)) -> list(VV). do_filter_map(List, Fun, Acc) -> case List of [] -> reverse(Acc); [X | Xs] -> New_acc = case Fun(X) of {ok, X@1} -> [X@1 | Acc]; {error, _} -> Acc end, do_filter_map(Xs, Fun, New_acc) end. -spec filter_map(list(WB), fun((WB) -> {ok, WD} | {error, any()})) -> list(WD). filter_map(List, Fun) -> do_filter_map(List, Fun, []). -spec do_map(list(WI), fun((WI) -> WK), list(WK)) -> list(WK). do_map(List, Fun, Acc) -> case List of [] -> reverse(Acc); [X | Xs] -> do_map(Xs, Fun, [Fun(X) | Acc]) end. -spec map(list(WN), fun((WN) -> WP)) -> list(WP). map(List, Fun) -> do_map(List, Fun, []). -spec update_group(fun((UY) -> UZ)) -> fun((gleam@map:map_(UZ, list(UY)), UY) -> gleam@map:map_(UZ, list(UY))). update_group(F) -> fun(Groups, Elem) -> case gleam@map:get(Groups, F(Elem)) of {ok, Existing} -> gleam@map:insert(Groups, F(Elem), [Elem | Existing]); {error, _} -> gleam@map:insert(Groups, F(Elem), [Elem]) end end. -spec do_map2(list(WX), list(WZ), fun((WX, WZ) -> XB), list(XB)) -> list(XB). do_map2(List1, List2, Fun, Acc) -> case {List1, List2} of {[], _} -> reverse(Acc); {_, []} -> reverse(Acc); {[A | As_], [B | Bs]} -> do_map2(As_, Bs, Fun, [Fun(A, B) | Acc]) end. -spec map2(list(WR), list(WT), fun((WR, WT) -> WV)) -> list(WV). map2(List1, List2, Fun) -> do_map2(List1, List2, Fun, []). -spec do_index_map(list(XJ), fun((integer(), XJ) -> XL), integer(), list(XL)) -> list(XL). do_index_map(List, Fun, Index, Acc) -> case List of [] -> reverse(Acc); [X | Xs] -> Acc@1 = [Fun(Index, X) | Acc], do_index_map(Xs, Fun, Index + 1, Acc@1) end. -spec index_map(list(XO), fun((integer(), XO) -> XQ)) -> list(XQ). index_map(List, Fun) -> do_index_map(List, Fun, 0, []). -spec do_try_map(list(XS), fun((XS) -> {ok, XU} | {error, XV}), list(XU)) -> {ok, list(XU)} | {error, XV}. do_try_map(List, Fun, Acc) -> case List of [] -> {ok, reverse(Acc)}; [X | Xs] -> case Fun(X) of {ok, Y} -> do_try_map(Xs, Fun, [Y | Acc]); {error, Error} -> {error, Error} end end. -spec try_map(list(YC), fun((YC) -> {ok, YE} | {error, YF})) -> {ok, list(YE)} | {error, YF}. try_map(List, Fun) -> do_try_map(List, Fun, []). -spec drop(list(YL), integer()) -> list(YL). drop(List, N) -> case N =< 0 of true -> List; false -> case List of [] -> []; [_ | Xs] -> drop(Xs, N - 1) end end. -spec do_take(list(YO), integer(), list(YO)) -> list(YO). do_take(List, N, Acc) -> case N =< 0 of true -> reverse(Acc); false -> case List of [] -> reverse(Acc); [X | Xs] -> do_take(Xs, N - 1, [X | Acc]) end end. -spec take(list(YS), integer()) -> list(YS). take(List, N) -> do_take(List, N, []). -spec new() -> list(any()). new() -> []. -spec append(list(YX), list(YX)) -> list(YX). append(First, Second) -> lists:append(First, Second). -spec prepend(list(AAF), AAF) -> list(AAF). prepend(List, Item) -> [Item | List]. -spec reverse_and_prepend(list(AAI), list(AAI)) -> list(AAI). reverse_and_prepend(Prefix, Suffix) -> case Prefix of [] -> Suffix; [First | Rest] -> reverse_and_prepend(Rest, [First | Suffix]) end. -spec do_concat(list(list(AAM)), list(AAM)) -> list(AAM). do_concat(Lists, Acc) -> case Lists of [] -> reverse(Acc); [List | Further_lists] -> do_concat(Further_lists, reverse_and_prepend(List, Acc)) end. -spec concat(list(list(AAR))) -> list(AAR). concat(Lists) -> do_concat(Lists, []). -spec flatten(list(list(AAV))) -> list(AAV). flatten(Lists) -> do_concat(Lists, []). -spec flat_map(list(AAZ), fun((AAZ) -> list(ABB))) -> list(ABB). flat_map(List, Fun) -> _pipe = map(List, Fun), concat(_pipe). -spec fold(list(ABE), ABG, fun((ABG, ABE) -> ABG)) -> ABG. fold(List, Initial, Fun) -> case List of [] -> Initial; [X | Rest] -> fold(Rest, Fun(Initial, X), Fun) end. -spec group(list(VG), fun((VG) -> VI)) -> gleam@map:map_(VI, list(VG)). group(List, Key) -> fold(List, gleam@map:new(), update_group(Key)). -spec map_fold(list(XE), XG, fun((XG, XE) -> {XG, XH})) -> {XG, list(XH)}. map_fold(List, Acc, Fun) -> _pipe = fold( List, {Acc, []}, fun(Acc@1, Item) -> {Current_acc, Items} = Acc@1, {Next_acc, Next_item} = Fun(Current_acc, Item), {Next_acc, [Next_item | Items]} end ), gleam@pair:map_second(_pipe, fun reverse/1). -spec fold_right(list(ABH), ABJ, fun((ABJ, ABH) -> ABJ)) -> ABJ. fold_right(List, Initial, Fun) -> case List of [] -> Initial; [X | Rest] -> Fun(fold_right(Rest, Initial, Fun), X) end. -spec do_index_fold( list(ABK), ABM, fun((ABM, ABK, integer()) -> ABM), integer() ) -> ABM. do_index_fold(Over, Acc, With, Index) -> case Over of [] -> Acc; [First | Rest] -> do_index_fold(Rest, With(Acc, First, Index), With, Index + 1) end. -spec index_fold(list(ABN), ABP, fun((ABP, ABN, integer()) -> ABP)) -> ABP. index_fold(Over, Initial, Fun) -> do_index_fold(Over, Initial, Fun, 0). -spec try_fold(list(ABQ), ABS, fun((ABS, ABQ) -> {ok, ABS} | {error, ABT})) -> {ok, ABS} | {error, ABT}. try_fold(Collection, Accumulator, Fun) -> case Collection of [] -> {ok, Accumulator}; [First | Rest] -> case Fun(Accumulator, First) of {ok, Result} -> try_fold(Rest, Result, Fun); {error, _} = Error -> Error end end. -spec fold_until(list(ABY), ACA, fun((ACA, ABY) -> continue_or_stop(ACA))) -> ACA. fold_until(Collection, Accumulator, Fun) -> case Collection of [] -> Accumulator; [First | Rest] -> case Fun(Accumulator, First) of {continue, Next_accumulator} -> fold_until(Rest, Next_accumulator, Fun); {stop, B} -> B end end. -spec find(list(ACC), fun((ACC) -> boolean())) -> {ok, ACC} | {error, nil}. find(Haystack, Is_desired) -> case Haystack of [] -> {error, nil}; [X | Rest] -> case Is_desired(X) of true -> {ok, X}; _ -> find(Rest, Is_desired) end end. -spec find_map(list(ACG), fun((ACG) -> {ok, ACI} | {error, any()})) -> {ok, ACI} | {error, nil}. find_map(Haystack, Fun) -> case Haystack of [] -> {error, nil}; [X | Rest] -> case Fun(X) of {ok, X@1} -> {ok, X@1}; _ -> find_map(Rest, Fun) end end. -spec all(list(ACO), fun((ACO) -> boolean())) -> boolean(). all(List, Predicate) -> case List of [] -> true; [First | Rest] -> case Predicate(First) of true -> all(Rest, Predicate); false -> false end end. -spec any(list(ACQ), fun((ACQ) -> boolean())) -> boolean(). any(List, Predicate) -> case List of [] -> false; [First | Rest] -> case Predicate(First) of true -> true; false -> any(Rest, Predicate) end end. -spec do_zip(list(ACS), list(ACU), list({ACS, ACU})) -> list({ACS, ACU}). do_zip(Xs, Ys, Acc) -> case {Xs, Ys} of {[X | Xs@1], [Y | Ys@1]} -> do_zip(Xs@1, Ys@1, [{X, Y} | Acc]); {_, _} -> reverse(Acc) end. -spec zip(list(ACY), list(ADA)) -> list({ACY, ADA}). zip(List, Other) -> do_zip(List, Other, []). -spec strict_zip(list(ADD), list(ADF)) -> {ok, list({ADD, ADF})} | {error, length_mismatch()}. strict_zip(List, Other) -> case length(List) =:= length(Other) of true -> {ok, zip(List, Other)}; false -> {error, length_mismatch} end. -spec do_unzip(list({ATB, ATC}), list(ATB), list(ATC)) -> {list(ATB), list(ATC)}. do_unzip(Input, Xs, Ys) -> case Input of [] -> {reverse(Xs), reverse(Ys)}; [{X, Y} | Rest] -> do_unzip(Rest, [X | Xs], [Y | Ys]) end. -spec unzip(list({ADO, ADP})) -> {list(ADO), list(ADP)}. unzip(Input) -> do_unzip(Input, [], []). -spec do_intersperse(list(ADT), ADT, list(ADT)) -> list(ADT). do_intersperse(List, Separator, Acc) -> case List of [] -> reverse(Acc); [X | Rest] -> do_intersperse(Rest, Separator, [X, Separator | Acc]) end. -spec intersperse(list(ADX), ADX) -> list(ADX). intersperse(List, Elem) -> case List of [] -> List; [_] -> List; [X | Rest] -> do_intersperse(Rest, Elem, [X]) end. -spec at(list(AEA), integer()) -> {ok, AEA} | {error, nil}. at(List, Index) -> case Index >= 0 of true -> _pipe = List, _pipe@1 = drop(_pipe, Index), first(_pipe@1); false -> {error, nil} end. -spec unique(list(AEE)) -> list(AEE). unique(List) -> case List of [] -> []; [X | Rest] -> [X | unique(filter(Rest, fun(Y) -> Y /= X end))] end. -spec merge_up( integer(), integer(), list(AEH), list(AEH), list(AEH), fun((AEH, AEH) -> gleam@order:order()) ) -> list(AEH). merge_up(Na, Nb, A, B, Acc, Compare) -> case {Na, Nb, A, B} of {0, 0, _, _} -> Acc; {_, 0, [Ax | Ar], _} -> merge_up(Na - 1, Nb, Ar, B, [Ax | Acc], Compare); {0, _, _, [Bx | Br]} -> merge_up(Na, Nb - 1, A, Br, [Bx | Acc], Compare); {_, _, [Ax@1 | Ar@1], [Bx@1 | Br@1]} -> case Compare(Ax@1, Bx@1) of gt -> merge_up(Na, Nb - 1, A, Br@1, [Bx@1 | Acc], Compare); _ -> merge_up(Na - 1, Nb, Ar@1, B, [Ax@1 | Acc], Compare) end end. -spec merge_down( integer(), integer(), list(AEM), list(AEM), list(AEM), fun((AEM, AEM) -> gleam@order:order()) ) -> list(AEM). merge_down(Na, Nb, A, B, Acc, Compare) -> case {Na, Nb, A, B} of {0, 0, _, _} -> Acc; {_, 0, [Ax | Ar], _} -> merge_down(Na - 1, Nb, Ar, B, [Ax | Acc], Compare); {0, _, _, [Bx | Br]} -> merge_down(Na, Nb - 1, A, Br, [Bx | Acc], Compare); {_, _, [Ax@1 | Ar@1], [Bx@1 | Br@1]} -> case Compare(Bx@1, Ax@1) of lt -> merge_down(Na - 1, Nb, Ar@1, B, [Ax@1 | Acc], Compare); _ -> merge_down(Na, Nb - 1, A, Br@1, [Bx@1 | Acc], Compare) end end. -spec merge_sort( list(AER), integer(), fun((AER, AER) -> gleam@order:order()), boolean() ) -> list(AER). merge_sort(L, Ln, Compare, Down) -> N = Ln div 2, A = L, B = drop(L, N), case Ln < 3 of true -> case Down of true -> merge_down(N, Ln - N, A, B, [], Compare); false -> merge_up(N, Ln - N, A, B, [], Compare) end; false -> case Down of true -> merge_down( N, Ln - N, merge_sort(A, N, Compare, false), merge_sort(B, Ln - N, Compare, false), [], Compare ); false -> merge_up( N, Ln - N, merge_sort(A, N, Compare, true), merge_sort(B, Ln - N, Compare, true), [], Compare ) end end. -spec sort(list(AEU), fun((AEU, AEU) -> gleam@order:order())) -> list(AEU). sort(List, Compare) -> merge_sort(List, length(List), Compare, true). -spec tail_recursive_range(integer(), integer(), list(integer())) -> list(integer()). tail_recursive_range(Start, Stop, Acc) -> case gleam@int:compare(Start, Stop) of eq -> reverse([Stop | Acc]); gt -> tail_recursive_range(Start - 1, Stop, [Start | Acc]); lt -> tail_recursive_range(Start + 1, Stop, [Start | Acc]) end. -spec range(integer(), integer()) -> list(integer()). range(Start, Stop) -> tail_recursive_range(Start, Stop, []). -spec do_repeat(AFA, integer(), list(AFA)) -> list(AFA). do_repeat(A, Times, Acc) -> case Times =< 0 of true -> Acc; false -> do_repeat(A, Times - 1, [A | Acc]) end. -spec repeat(AFD, integer()) -> list(AFD). repeat(A, Times) -> do_repeat(A, Times, []). -spec do_split(list(AFF), integer(), list(AFF)) -> {list(AFF), list(AFF)}. do_split(List, N, Taken) -> case N =< 0 of true -> {reverse(Taken), List}; false -> case List of [] -> {reverse(Taken), []}; [X | Xs] -> do_split(Xs, N - 1, [X | Taken]) end end. -spec split(list(AFK), integer()) -> {list(AFK), list(AFK)}. split(List, Index) -> do_split(List, Index, []). -spec do_split_while(list(AFO), fun((AFO) -> boolean()), list(AFO)) -> {list(AFO), list(AFO)}. do_split_while(List, F, Acc) -> case List of [] -> {reverse(Acc), []}; [X | Xs] -> case F(X) of false -> {reverse(Acc), List}; _ -> do_split_while(Xs, F, [X | Acc]) end end. -spec split_while(list(AFT), fun((AFT) -> boolean())) -> {list(AFT), list(AFT)}. split_while(List, Predicate) -> do_split_while(List, Predicate, []). -spec key_find(list({AFX, AFY}), AFX) -> {ok, AFY} | {error, nil}. key_find(Keyword_list, Desired_key) -> find_map( Keyword_list, fun(Keyword) -> {Key, Value} = Keyword, case Key =:= Desired_key of true -> {ok, Value}; false -> {error, nil} end end ). -spec do_pop(list(AWM), fun((AWM) -> boolean()), list(AWM)) -> {ok, {AWM, list(AWM)}} | {error, nil}. do_pop(Haystack, Predicate, Checked) -> case Haystack of [] -> {error, nil}; [X | Rest] -> case Predicate(X) of true -> {ok, {X, append(reverse(Checked), Rest)}}; false -> do_pop(Rest, Predicate, [X | Checked]) end end. -spec pop(list(AGG), fun((AGG) -> boolean())) -> {ok, {AGG, list(AGG)}} | {error, nil}. pop(Haystack, Is_desired) -> do_pop(Haystack, Is_desired, []). -spec do_pop_map(list(AXA), fun((AXA) -> {ok, AXN} | {error, any()}), list(AXA)) -> {ok, {AXN, list(AXA)}} | {error, nil}. do_pop_map(Haystack, Mapper, Checked) -> case Haystack of [] -> {error, nil}; [X | Rest] -> case Mapper(X) of {ok, Y} -> {ok, {Y, append(reverse(Checked), Rest)}}; {error, _} -> do_pop_map(Rest, Mapper, [X | Checked]) end end. -spec pop_map(list(AGP), fun((AGP) -> {ok, AGR} | {error, any()})) -> {ok, {AGR, list(AGP)}} | {error, nil}. pop_map(Haystack, Is_desired) -> do_pop_map(Haystack, Is_desired, []). -spec key_pop(list({AGY, AGZ}), AGY) -> {ok, {AGZ, list({AGY, AGZ})}} | {error, nil}. key_pop(Haystack, Key) -> pop_map( Haystack, fun(Entry) -> {K, V} = Entry, case K of K@1 when K@1 =:= Key -> {ok, V}; _ -> {error, nil} end end ). -spec key_set(list({AHE, AHF}), AHE, AHF) -> list({AHE, AHF}). key_set(List, Key, Value) -> case List of [] -> [{Key, Value}]; [{K, _} | Rest] when K =:= Key -> [{Key, Value} | Rest]; [First | Rest@1] -> [First | key_set(Rest@1, Key, Value)] end. -spec each(list(AHI), fun((AHI) -> any())) -> nil. each(List, F) -> case List of [] -> nil; [X | Xs] -> F(X), each(Xs, F) end. -spec try_each(list(AHL), fun((AHL) -> {ok, any()} | {error, AHO})) -> {ok, nil} | {error, AHO}. try_each(List, Fun) -> case List of [] -> {ok, nil}; [X | Xs] -> case Fun(X) of {ok, _} -> try_each(Xs, Fun); {error, E} -> {error, E} end end. -spec do_partition(list(AYU), fun((AYU) -> boolean()), list(AYU), list(AYU)) -> {list(AYU), list(AYU)}. do_partition(List, Categorise, Trues, Falses) -> case List of [] -> {reverse(Trues), reverse(Falses)}; [X | Xs] -> case Categorise(X) of true -> do_partition(Xs, Categorise, [X | Trues], Falses); false -> do_partition(Xs, Categorise, Trues, [X | Falses]) end end. -spec partition(list(AHY), fun((AHY) -> boolean())) -> {list(AHY), list(AHY)}. partition(List, Categorise) -> do_partition(List, Categorise, [], []). -spec permutations(list(AIC)) -> list(list(AIC)). permutations(L) -> case L of [] -> [[]]; _ -> _pipe = L, _pipe@5 = index_map(_pipe, fun(I_idx, I) -> _pipe@1 = L, _pipe@2 = index_fold( _pipe@1, [], fun(Acc, J, J_idx) -> case I_idx =:= J_idx of true -> Acc; false -> [J | Acc] end end ), _pipe@3 = reverse(_pipe@2), _pipe@4 = permutations(_pipe@3), map(_pipe@4, fun(Permutation) -> [I | Permutation] end) end), concat(_pipe@5) end. -spec do_window(list(list(AIG)), list(AIG), integer()) -> list(list(AIG)). do_window(Acc, L, N) -> Window = take(L, N), case length(Window) =:= N of true -> do_window([Window | Acc], drop(L, 1), N); false -> Acc end. -spec window(list(AIM), integer()) -> list(list(AIM)). window(L, N) -> _pipe = do_window([], L, N), reverse(_pipe). -spec window_by_2(list(AIQ)) -> list({AIQ, AIQ}). window_by_2(L) -> zip(L, drop(L, 1)). -spec drop_while(list(AIT), fun((AIT) -> boolean())) -> list(AIT). drop_while(List, Predicate) -> case List of [] -> []; [X | Xs] -> case Predicate(X) of true -> drop_while(Xs, Predicate); false -> [X | Xs] end end. -spec do_take_while(list(AIW), fun((AIW) -> boolean()), list(AIW)) -> list(AIW). do_take_while(List, Predicate, Acc) -> case List of [] -> reverse(Acc); [First | Rest] -> case Predicate(First) of true -> do_take_while(Rest, Predicate, [First | Acc]); false -> reverse(Acc) end end. -spec take_while(list(AJA), fun((AJA) -> boolean())) -> list(AJA). take_while(List, Predicate) -> do_take_while(List, Predicate, []). -spec do_chunk(list(AJD), fun((AJD) -> AJF), AJF, list(AJD), list(list(AJD))) -> list(list(AJD)). do_chunk(List, F, Previous_key, Current_chunk, Acc) -> case List of [First | Rest] -> Key = F(First), case Key =:= Previous_key of false -> New_acc = [reverse(Current_chunk) | Acc], do_chunk(Rest, F, Key, [First], New_acc); _ -> do_chunk(Rest, F, Key, [First | Current_chunk], Acc) end; _ -> reverse([reverse(Current_chunk) | Acc]) end. -spec chunk(list(AJL), fun((AJL) -> any())) -> list(list(AJL)). chunk(List, F) -> case List of [] -> []; [First | Rest] -> do_chunk(Rest, F, F(First), [First], []) end. -spec do_sized_chunk( list(AJQ), integer(), integer(), list(AJQ), list(list(AJQ)) ) -> list(list(AJQ)). do_sized_chunk(List, Count, Left, Current_chunk, Acc) -> case List of [] -> case Current_chunk of [] -> reverse(Acc); Remaining -> reverse([reverse(Remaining) | Acc]) end; [First | Rest] -> Chunk = [First | Current_chunk], case Left > 1 of false -> do_sized_chunk( Rest, Count, Count, [], [reverse(Chunk) | Acc] ); true -> do_sized_chunk(Rest, Count, Left - 1, Chunk, Acc) end end. -spec sized_chunk(list(AJX), integer()) -> list(list(AJX)). sized_chunk(List, Count) -> do_sized_chunk(List, Count, Count, [], []). -spec reduce(list(AKB), fun((AKB, AKB) -> AKB)) -> {ok, AKB} | {error, nil}. reduce(List, Fun) -> case List of [] -> {error, nil}; [First | Rest] -> {ok, fold(Rest, First, Fun)} end. -spec do_scan(list(AKF), AKH, list(AKH), fun((AKH, AKF) -> AKH)) -> list(AKH). do_scan(List, Accumulator, Accumulated, Fun) -> case List of [] -> reverse(Accumulated); [X | Xs] -> Next = Fun(Accumulator, X), do_scan(Xs, Next, [Next | Accumulated], Fun) end. -spec scan(list(AKK), AKM, fun((AKM, AKK) -> AKM)) -> list(AKM). scan(List, Initial, Fun) -> do_scan(List, Initial, [], Fun). -spec last(list(AKO)) -> {ok, AKO} | {error, nil}. last(List) -> _pipe = List, reduce(_pipe, fun(_, Elem) -> Elem end). -spec combinations(list(AKS), integer()) -> list(list(AKS)). combinations(Items, N) -> case N of 0 -> [[]]; _ -> case Items of [] -> []; [X | Xs] -> First_combinations = begin _pipe = map( combinations(Xs, N - 1), fun(Com) -> [X | Com] end ), reverse(_pipe) end, fold( First_combinations, combinations(Xs, N), fun(Acc, C) -> [C | Acc] end ) end end. -spec do_combination_pairs(list(AKW)) -> list(list({AKW, AKW})). do_combination_pairs(Items) -> case Items of [] -> []; [X | Xs] -> First_combinations = map(Xs, fun(Other) -> {X, Other} end), [First_combinations | do_combination_pairs(Xs)] end. -spec combination_pairs(list(ALA)) -> list({ALA, ALA}). combination_pairs(Items) -> _pipe = do_combination_pairs(Items), concat(_pipe). -spec transpose(list(list(ALH))) -> list(list(ALH)). transpose(List_of_list) -> Take_first = fun(List) -> case List of [] -> []; [F] -> [F]; [F@1 | _] -> [F@1] end end, case List_of_list of [] -> []; [[] | Xss] -> transpose(Xss); Rows -> Firsts = begin _pipe = Rows, _pipe@1 = map(_pipe, Take_first), concat(_pipe@1) end, Rest = transpose(map(Rows, fun(_capture) -> drop(_capture, 1) end)), [Firsts | Rest] end. -spec interleave(list(list(ALD))) -> list(ALD). interleave(List) -> _pipe = transpose(List), concat(_pipe). -spec do_shuffle_pair_unwrap(list({float(), ALM}), list(ALM)) -> list(ALM). do_shuffle_pair_unwrap(List, Acc) -> case List of [] -> Acc; _ -> [Elem_pair | Enumerable] = List, do_shuffle_pair_unwrap( Enumerable, [erlang:element(2, Elem_pair) | Acc] ) end. -spec do_shuffle_by_pair_indexes(list({float(), ALQ})) -> list({float(), ALQ}). do_shuffle_by_pair_indexes(List_of_pairs) -> sort( List_of_pairs, fun(A_pair, B_pair) -> gleam@float:compare( erlang:element(1, A_pair), erlang:element(1, B_pair) ) end ). -spec shuffle(list(ALT)) -> list(ALT). shuffle(List) -> _pipe = List, _pipe@1 = fold( _pipe, [], fun(Acc, A) -> [{gleam@float:random(0.0, 1.0), A} | Acc] end ), _pipe@2 = do_shuffle_by_pair_indexes(_pipe@1), do_shuffle_pair_unwrap(_pipe@2, []).