module Tree : sig ... endtype 'elt t = ('a, 'b) t
include Bin_prot.Binable.S1 with type 'elt t := 'elt t
val bin_shape_t : Bin_prot.Shape.t -> Bin_prot.Shape.tval bin_size_t : ('a, 'elt t) Bin_prot.Size.sizer1val bin_write_t : ('a, 'elt t) Bin_prot.Write.writer1val bin_read_t : ('a, 'elt t) Bin_prot.Read.reader1val __bin_read_t__ : ('a, int -> 'elt t) Bin_prot.Read.reader1val bin_writer_t : ('a, 'elt t) Bin_prot.Type_class.S1.writerval bin_reader_t : ('a, 'elt t) Bin_prot.Type_class.S1.readerval bin_t : ('a, 'elt t) Bin_prot.Type_class.S1.t
val compare : ('elt -> 'elt -> Base.Int.t) -> 'elt t -> 'elt t -> Base.Int.t
include Ppx_sexp_conv_lib.Sexpable.S1 with type 'elt t := 'elt t
val t_of_sexp : (Sexplib0.Sexp.t -> 'a) -> Sexplib0.Sexp.t -> 'elt tval sexp_of_t : ('a -> Sexplib0.Sexp.t) -> 'elt t -> Sexplib0.Sexp.t
type 'a named = ('a, Comparator.Poly.comparator_witness) Named.t
include Set_intf.Creators_and_accessors1 with type ('a, 'b) set := ('a, 'b) t with type 'elt t := 'elt t with type 'elt tree := 'elt Tree.t with type 'a named := 'a named with type comparator_witness := Comparator.Poly.comparator_witness
include Set_intf.Accessors1 with type comparator_witness := Comparator.Poly.comparator_witness and type 'a named := 'a named and type 'elt tree := 'elt Tree.t and type 'elt t := 'elt t
include Set_intf.Set.Accessors1 with type 'elt t := 'elt t and type 'elt tree := 'elt Tree.t and type 'a named := 'a named and type comparator_witness := Comparator.Poly.comparator_witness
include Base.Container.S1 with type 'elt t := 'elt t
val mem : 'elt t -> 'a -> equal:('a -> 'a -> bool) -> boolChecks whether the provided element is there, using
equal.
val length : 'elt t -> intval is_empty : 'elt t -> boolval iter : 'elt t -> f:('a -> unit) -> unitval fold : 'elt t -> init:'accum -> f:('accum -> 'a -> 'accum) -> 'accumfold t ~init ~freturnsf (... f (f (f init e1) e2) e3 ...) en, wheree1..enare the elements oft
val fold_result : 'elt t -> init:'accum -> f:('accum -> 'a -> ('accum, 'e) Base.Result.t) -> ('accum, 'e) Base.Result.tfold_result t ~init ~fis a short-circuiting version offoldthat runs in theResultmonad. Iffreturns anError _, that value is returned without any additional invocations off.
val fold_until : 'elt t -> init:'accum -> f:('accum -> 'a -> ('accum, 'final) Base__Container_intf.Export.Continue_or_stop.t) -> finish:('accum -> 'final) -> 'finalfold_until t ~init ~f ~finishis a short-circuiting version offold. IffreturnsStop _the computation ceases and results in that value. IffreturnsContinue _, the fold will proceed. Iffnever returnsStop _, the final result is computed byfinish.Example:
type maybe_negative = | Found_negative of int | All_nonnegative of { sum : int } (** [first_neg_or_sum list] returns the first negative number in [list], if any, otherwise returns the sum of the list. *) let first_neg_or_sum = List.fold_until ~init:0 ~f:(fun sum x -> if x < 0 then Stop (Found_negative x) else Continue (sum + x)) ~finish:(fun sum -> All_nonnegative { sum }) ;; let x = first_neg_or_sum [1; 2; 3; 4; 5] val x : maybe_negative = All_nonnegative {sum = 15} let y = first_neg_or_sum [1; 2; -3; 4; 5] val y : maybe_negative = Found_negative -3
val exists : 'elt t -> f:('a -> bool) -> boolReturns
trueif and only if there exists an element for which the provided function evaluates totrue. This is a short-circuiting operation.
val for_all : 'elt t -> f:('a -> bool) -> boolReturns
trueif and only if the provided function evaluates totruefor all elements. This is a short-circuiting operation.
val count : 'elt t -> f:('a -> bool) -> intReturns the number of elements for which the provided function evaluates to true.
val sum : (module Base__Container_intf.Summable with type t = 'sum) -> 'elt t -> f:('a -> 'sum) -> 'sumReturns the sum of
f ifor alliin the container.
val find : 'elt t -> f:('a -> bool) -> 'a optionReturns as an
optionthe first element for whichfevaluates to true.
val find_map : 'elt t -> f:('a -> 'b option) -> 'b optionReturns the first evaluation of
fthat returnsSome, and returnsNoneif there is no such element.
val to_list : 'elt t -> 'a listval to_array : 'elt t -> 'a arrayval min_elt : 'elt t -> compare:('a -> 'a -> int) -> 'a optionReturns a minimum (resp maximum) element from the collection using the provided
comparefunction, orNoneif the collection is empty. In case of a tie, the first element encountered while traversing the collection is returned. The implementation usesfoldso it has the same complexity asfold.
val max_elt : 'elt t -> compare:('a -> 'a -> int) -> 'a option
val invariants : 'elt t -> boolval mem : 'elt t -> 'a -> boolval add : 'elt t -> 'a -> 'elt tval remove : 'elt t -> 'a -> 'elt tval union : 'elt t -> 'elt t -> 'elt tval inter : 'elt t -> 'elt t -> 'elt tval diff : 'elt t -> 'elt t -> 'elt tval symmetric_diff : 'elt t -> 'elt t -> ('a, 'a) Base.Either.t Base.Sequence.tval compare_direct : 'elt t -> 'elt t -> intval equal : 'elt t -> 'elt t -> boolval is_subset : 'elt t -> of_:'elt t -> boolval are_disjoint : 'elt t -> 'elt t -> bool
module Named : sig ... endval fold_until : 'elt t -> init:'b -> f:('b -> 'a -> ('b, 'final) Base__Set_intf.Continue_or_stop.t) -> finish:('b -> 'final) -> 'finalval fold_right : 'elt t -> init:'b -> f:('a -> 'b -> 'b) -> 'bval iter2 : 'elt t -> 'elt t -> f:([ `Left of 'a | `Right of 'a | `Both of 'a * 'a ] -> unit) -> unitval filter : 'elt t -> f:('a -> bool) -> 'elt tval partition_tf : 'elt t -> f:('a -> bool) -> 'elt t * 'elt tval elements : 'elt t -> 'a listval min_elt : 'elt t -> 'a optionval min_elt_exn : 'elt t -> 'aval max_elt : 'elt t -> 'a optionval max_elt_exn : 'elt t -> 'aval choose : 'elt t -> 'a optionval choose_exn : 'elt t -> 'aval split : 'elt t -> 'a -> 'elt t * 'a option * 'elt tval group_by : 'elt t -> equiv:('a -> 'a -> bool) -> 'elt t listval find_exn : 'elt t -> f:('a -> bool) -> 'aval nth : 'elt t -> int -> 'a optionval remove_index : 'elt t -> int -> 'elt tval to_tree : 'elt t -> 'elt Tree.tval to_sequence : ?order:[ `Increasing | `Decreasing ] -> ?greater_or_equal_to:'a -> ?less_or_equal_to:'a -> 'elt t -> 'a Base.Sequence.tval binary_search : 'elt t -> compare:('a -> 'key -> int) -> [ `Last_strictly_less_than | `Last_less_than_or_equal_to | `Last_equal_to | `First_equal_to | `First_greater_than_or_equal_to | `First_strictly_greater_than ] -> 'key -> 'a optionval binary_search_segmented : 'elt t -> segment_of:('a -> [ `Left | `Right ]) -> [ `Last_on_left | `First_on_right ] -> 'a optionval merge_to_sequence : ?order:[ `Increasing | `Decreasing ] -> ?greater_or_equal_to:'a -> ?less_or_equal_to:'a -> 'elt t -> 'elt t -> ('a, 'a) Base.Sequence.Merge_with_duplicates_element.t Base.Sequence.t
val to_map : 'elt t -> f:('a -> 'b) -> ('a, 'b, Comparator.Poly.comparator_witness) Base.Map.tval quickcheck_observer : 'a Quickcheck.Observer.t -> 'elt t Quickcheck.Observer.tval quickcheck_shrinker : 'a Quickcheck.Shrinker.t -> 'elt t Quickcheck.Shrinker.t
include Set_intf.Creators1 with type 'a t := 'elt t with type 'a tree := 'elt Tree.t with type ('a, 'b) set := ('a, 'b) t and type comparator_witness := Comparator.Poly.comparator_witness
include Set_intf.Set.Creators1 with type comparator_witness := Comparator.Poly.comparator_witness and type ('a, 'b) set := ('a, 'b) t and type 'a tree := 'elt Tree.t and type 'a t := 'elt t
val empty : 'elt tval singleton : 'a -> 'elt tval union_list : 'elt t list -> 'elt tval of_list : 'a list -> 'elt tval of_array : 'a array -> 'elt tval of_sorted_array : 'a array -> 'elt t Base.Or_error.tval of_sorted_array_unchecked : 'a array -> 'elt tval of_increasing_iterator_unchecked : len:int -> f:(int -> 'a) -> 'elt tval stable_dedup_list : 'a list -> 'a listval map : ('a, 'b) t -> f:('a -> 'b) -> 'elt tval filter_map : ('a, 'b) t -> f:('a -> 'b option) -> 'elt tval of_tree : 'elt Tree.t -> 'elt t
val of_hash_set : 'a Hash_set.t -> 'elt tval of_hashtbl_keys : ('a, _) Hashtbl.t -> 'elt tval of_map_keys : ('a, _, Comparator.Poly.comparator_witness) Base.Map.t -> 'elt tval quickcheck_generator : 'a Quickcheck.Generator.t -> 'elt t Quickcheck.Generator.t