infer_clone/sledge/nonstdlib/ocaml/map.ml

(**************************************************************************)
(*                                                                        *)
(*                                 OCaml                                  *)
(*                                                                        *)
(*             Xavier Leroy, projet Cristal, INRIA Rocquencourt           *)
(*                                                                        *)
(*   Copyright 1996 Institut National de Recherche en Informatique et     *)
(*     en Automatique.                                                    *)
(*                                                                        *)
(*   All rights reserved.  This file is distributed under the terms of    *)
(*   the GNU Lesser General Public License version 2.1, with the          *)
(*   special exception on linking described in the file LICENSE.          *)
(*                                                                        *)
(**************************************************************************)

open! NS0

module type OrderedType =
  sig
    type t
    val compare: t -> t -> int
  end

module type S =
  sig
    type key
    type +'a t

    include Comparer.S1 with type 'a t := 'a t

    val empty: 'a t
    val is_empty: 'a t -> bool
    val mem:  key -> 'a t -> bool
    val add: key -> 'a -> 'a t -> 'a t
    val update: key -> ('a option -> 'a option) -> 'a t -> 'a t
    val singleton: key -> 'a -> 'a t
    val is_singleton: 'a t -> bool
    val remove: key -> 'a t -> 'a t
    val merge:
          (key -> 'a option -> 'b option -> 'c option) -> 'a t -> 'b t -> 'c t
    val union: (key -> 'a -> 'a -> 'a option) -> 'a t -> 'a t -> 'a t
    val compare: ('a -> 'a -> int) -> 'a t -> 'a t -> int
  
    module Provide_equal (_ : sig
      type t = key [@@deriving equal]
    end) : sig
      type 'a t [@@deriving equal]
    end
    with type 'a t := 'a t

    val iter: (key -> 'a -> unit) -> 'a t -> unit
    val fold: (key -> 'a -> 'b -> 'b) -> 'a t -> 'b -> 'b
    val for_all: (key -> 'a -> bool) -> 'a t -> bool
    val exists: (key -> 'a -> bool) -> 'a t -> bool
    val filter: (key -> 'a -> bool) -> 'a t -> 'a t
    val filter_map: (key -> 'a -> 'b option) -> 'a t -> 'b t
    val partition: (key -> 'a -> bool) -> 'a t -> 'a t * 'a t
    val cardinal: 'a t -> int
    val bindings: 'a t -> (key * 'a) list
    val only_binding: 'a t -> (key * 'a) option
    val classify : 'a t -> (key, 'a) zero_one_many2
    val min_binding: 'a t -> (key * 'a)
    val min_binding_opt: 'a t -> (key * 'a) option
    val max_binding: 'a t -> (key * 'a)
    val max_binding_opt: 'a t -> (key * 'a) option
    val choose: 'a t -> (key * 'a)
    val choose_opt: 'a t -> (key * 'a) option
    val divide : 'a t -> ('a t * key * 'a * 'a t) option
    val divide_exn : 'a t -> ('a t * key * 'a * 'a t)
    val split: key -> 'a t -> 'a t * 'a option * 'a t
    val find: key -> 'a t -> 'a
    val find_opt: key -> 'a t -> 'a option
    val find_first: (key -> bool) -> 'a t -> key * 'a
    val find_first_opt: (key -> bool) -> 'a t -> (key * 'a) option
    val find_last: (key -> bool) -> 'a t -> key * 'a
    val find_last_opt: (key -> bool) -> 'a t -> (key * 'a) option
    val map: ('a -> 'b) -> 'a t -> 'b t
    val mapi: (key -> 'a -> 'b) -> 'a t -> 'b t
    val to_seq : 'a t -> (key * 'a) Seq.t
    val to_seq_from : key -> 'a t -> (key * 'a) Seq.t
    val add_seq : (key * 'a) Seq.t -> 'a t -> 'a t
    val of_seq : (key * 'a) Seq.t -> 'a t

    module Provide_sexp_of (_ : sig
      type t = key [@@deriving sexp_of]
    end) : sig
      type 'a t [@@deriving sexp_of]
    end
    with type 'a t := 'a t

    module Provide_of_sexp (_ : sig
      type t = key [@@deriving of_sexp]
    end) : sig
      type 'a t [@@deriving of_sexp]
    end
    with type 'a t := 'a t
  end

module T = struct
  type ('key, 'a, 'cmp) t =
      Empty
    | Node of {l:('key, 'a, 'cmp) t; v:'key; d:'a; r:('key, 'a, 'cmp) t; h:int}

  type ('key, 'a, 'cmp) enumeration =
      End
    | More of 'key * 'a * ('key, 'a, 'cmp) t * ('key, 'a, 'cmp) enumeration

  let rec cons_enum m e =
    match m with
      Empty -> e
    | Node {l; v; d; r} -> cons_enum l (More(v, d, r, e))

  let compare compare_key compare_a _ m1 m2 =
    let rec compare_aux e1 e2 =
        match (e1, e2) with
        (End, End) -> 0
      | (End, _)  -> -1
      | (_, End) -> 1
      | (More(v1, d1, r1, e1), More(v2, d2, r2, e2)) ->
          let c = compare_key v1 v2 in
          if c <> 0 then c else
          let c = compare_a d1 d2 in
          if c <> 0 then c else
          compare_aux (cons_enum r1 e1) (cons_enum r2 e2)
    in compare_aux (cons_enum m1 End) (cons_enum m2 End)

  type ('compare_key, 'compare_a) compare [@@deriving compare, equal, sexp]
end

include T

let equal equal_key equal_a _ m1 m2 =
  let rec equal_aux e1 e2 =
      match (e1, e2) with
      (End, End) -> true
    | (End, _)  -> false
    | (_, End) -> false
    | (More(v1, d1, r1, e1), More(v2, d2, r2, e2)) ->
        equal_key v1 v2 && equal_a d1 d2 &&
        equal_aux (cons_enum r1 e1) (cons_enum r2 e2)
  in equal_aux (cons_enum m1 End) (cons_enum m2 End)

let rec bindings_aux accu = function
    Empty -> accu
  | Node {l; v; d; r} -> bindings_aux ((v, d) :: bindings_aux accu r) l

let bindings s =
  bindings_aux [] s

let sexp_of_t sexp_of_key sexp_of_data _ m =
  m
  |> bindings
  |> Sexplib.Conv.sexp_of_list
       (Sexplib.Conv.sexp_of_pair sexp_of_key sexp_of_data)

let height = function
    Empty -> 0
  | Node {h} -> h

let create l x d r =
  let hl = height l and hr = height r in
  Node{l; v=x; d; r; h=(if hl >= hr then hl + 1 else hr + 1)}

let of_sorted_list l =
  let rec sub n l =
    match n, l with
    | 0, l -> Empty, l
    | 1, (v0,d0) :: l -> Node {l=Empty; v=v0; d=d0; r=Empty; h=1}, l
    | 2, (v0,d0) :: (v1,d1) :: l ->
        Node{l=Node{l=Empty; v=v0; d=d0; r=Empty; h=1}; v=v1; d=d1;
             r=Empty; h=2}, l
    | 3, (v0,d0) :: (v1,d1) :: (v2,d2) :: l ->
        Node{l=Node{l=Empty; v=v0; d=d0; r=Empty; h=1}; v=v1; d=d1;
             r=Node{l=Empty; v=v2; d=d2; r=Empty; h=1}; h=2}, l
    | n, l ->
      let nl = n / 2 in
      let left, l = sub nl l in
      match l with
      | [] -> assert false
      | (v,d) :: l ->
        let right, l = sub (n - nl - 1) l in
        create left v d right, l
  in
  fst (sub (List.length l) l)

let t_of_sexp key_of_sexp data_of_sexp _ m =
  m
  |> Sexplib.Conv.list_of_sexp
       (Sexplib.Conv.pair_of_sexp key_of_sexp data_of_sexp)
  |> of_sorted_list

module Make (Ord : Comparer.S) = struct
    module Ord = struct
      include Ord
      let compare = (comparer :> t -> t -> int)
    end

    type key = Ord.t

    include (Comparer.Apply1 (T) (Ord))

    module Provide_equal (Key : sig
      type t = Ord.t [@@deriving equal]
    end) = struct
      let equal equal_data =
        equal Key.equal equal_data Ord.equal_compare
    end

    module Provide_sexp_of (Key : sig
      type t = Ord.t [@@deriving sexp_of]
    end) = struct
      let sexp_of_t sexp_of_data m =
        sexp_of_t Key.sexp_of_t sexp_of_data Ord.sexp_of_compare m
    end

    module Provide_of_sexp (Key : sig
      type t = Ord.t [@@deriving of_sexp]
    end) = struct
      let t_of_sexp data_of_sexp s =
        t_of_sexp Key.t_of_sexp data_of_sexp Ord.compare_of_sexp s
    end

    let empty = Empty

    let is_empty = function Empty -> true | _ -> false

    let singleton x d = Node{l=Empty; v=x; d; r=Empty; h=1}

    let is_singleton = function Node {l=Empty; r=Empty} -> true | _ -> false

    let bal l x d r =
      let hl = match l with Empty -> 0 | Node {h} -> h in
      let hr = match r with Empty -> 0 | Node {h} -> h in
      if hl > hr + 2 then begin
        match l with
          Empty -> invalid_arg "Map.bal"
        | Node{l=ll; v=lv; d=ld; r=lr} ->
            if height ll >= height lr then
              create ll lv ld (create lr x d r)
            else begin
              match lr with
                Empty -> invalid_arg "Map.bal"
              | Node{l=lrl; v=lrv; d=lrd; r=lrr}->
                  create (create ll lv ld lrl) lrv lrd (create lrr x d r)
            end
      end else if hr > hl + 2 then begin
        match r with
          Empty -> invalid_arg "Map.bal"
        | Node{l=rl; v=rv; d=rd; r=rr} ->
            if height rr >= height rl then
              create (create l x d rl) rv rd rr
            else begin
              match rl with
                Empty -> invalid_arg "Map.bal"
              | Node{l=rll; v=rlv; d=rld; r=rlr} ->
                  create (create l x d rll) rlv rld (create rlr rv rd rr)
            end
      end else
        Node{l; v=x; d; r; h=(if hl >= hr then hl + 1 else hr + 1)}

    let rec add x data = function
        Empty ->
          Node{l=Empty; v=x; d=data; r=Empty; h=1}
      | Node {l; v; d; r; h} as m ->
          let c = Ord.compare x v in
          if c = 0 then
            if d == data then m else Node{l; v=x; d=data; r; h}
          else if c < 0 then
            let ll = add x data l in
            if l == ll then m else bal ll v d r
          else
            let rr = add x data r in
            if r == rr then m else bal l v d rr

    let rec find x = function
        Empty ->
          raise Not_found
      | Node {l; v; d; r} ->
          let c = Ord.compare x v in
          if c = 0 then d
          else find x (if c < 0 then l else r)

    let rec find_first_aux v0 d0 f = function
        Empty ->
          (v0, d0)
      | Node {l; v; d; r} ->
          if f v then
            find_first_aux v d f l
          else
            find_first_aux v0 d0 f r

    let rec find_first f = function
        Empty ->
          raise Not_found
      | Node {l; v; d; r} ->
          if f v then
            find_first_aux v d f l
          else
            find_first f r

    let rec find_first_opt_aux v0 d0 f = function
        Empty ->
          Some (v0, d0)
      | Node {l; v; d; r} ->
          if f v then
            find_first_opt_aux v d f l
          else
            find_first_opt_aux v0 d0 f r

    let rec find_first_opt f = function
        Empty ->
          None
      | Node {l; v; d; r} ->
          if f v then
            find_first_opt_aux v d f l
          else
            find_first_opt f r

    let rec find_last_aux v0 d0 f = function
        Empty ->
          (v0, d0)
      | Node {l; v; d; r} ->
          if f v then
            find_last_aux v d f r
          else
            find_last_aux v0 d0 f l

    let rec find_last f = function
        Empty ->
          raise Not_found
      | Node {l; v; d; r} ->
          if f v then
            find_last_aux v d f r
          else
            find_last f l

    let rec find_last_opt_aux v0 d0 f = function
        Empty ->
          Some (v0, d0)
      | Node {l; v; d; r} ->
          if f v then
            find_last_opt_aux v d f r
          else
            find_last_opt_aux v0 d0 f l

    let rec find_last_opt f = function
        Empty ->
          None
      | Node {l; v; d; r} ->
          if f v then
            find_last_opt_aux v d f r
          else
            find_last_opt f l

    let rec find_opt x = function
        Empty ->
          None
      | Node {l; v; d; r} ->
          let c = Ord.compare x v in
          if c = 0 then Some d
          else find_opt x (if c < 0 then l else r)

    let rec mem x = function
        Empty ->
          false
      | Node {l; v; r} ->
          let c = Ord.compare x v in
          c = 0 || mem x (if c < 0 then l else r)

    let classify = function
      | Empty -> Zero2
      | Node {l=Empty; v; d; r=Empty} -> One2 (v, d)
      | _ -> Many2

    let only_binding = function
        Node {l=Empty; v; d; r=Empty} -> Some (v, d)
      | _ -> None

    let rec min_binding = function
        Empty -> raise Not_found
      | Node {l=Empty; v; d} -> (v, d)
      | Node {l} -> min_binding l

    let rec min_binding_opt = function
        Empty -> None
      | Node {l=Empty; v; d} -> Some (v, d)
      | Node {l}-> min_binding_opt l

    let rec max_binding = function
        Empty -> raise Not_found
      | Node {v; d; r=Empty} -> (v, d)
      | Node {r} -> max_binding r

    let rec max_binding_opt = function
        Empty -> None
      | Node {v; d; r=Empty} -> Some (v, d)
      | Node {r} -> max_binding_opt r

    let rec remove_min_binding = function
        Empty -> invalid_arg "Map.remove_min_elt"
      | Node {l=Empty; r} -> r
      | Node {l; v; d; r} -> bal (remove_min_binding l) v d r

    let merge t1 t2 =
      match (t1, t2) with
        (Empty, t) -> t
      | (t, Empty) -> t
      | (_, _) ->
          let (x, d) = min_binding t2 in
          bal t1 x d (remove_min_binding t2)

    let rec remove x = function
        Empty ->
          Empty
      | (Node {l; v; d; r} as m) ->
          let c = Ord.compare x v in
          if c = 0 then merge l r
          else if c < 0 then
            let ll = remove x l in if l == ll then m else bal ll v d r
          else
            let rr = remove x r in if r == rr then m else bal l v d rr

    let rec update x f = function
        Empty ->
          begin match f None with
          | None -> Empty
          | Some data -> Node{l=Empty; v=x; d=data; r=Empty; h=1}
          end
      | Node {l; v; d; r; h} as m ->
          let c = Ord.compare x v in
          if c = 0 then begin
            match f (Some d) with
            | None -> merge l r
            | Some data ->
                if d == data then m else Node{l; v=x; d=data; r; h}
          end else if c < 0 then
            let ll = update x f l in
            if l == ll then m else bal ll v d r
          else
            let rr = update x f r in
            if r == rr then m else bal l v d rr

    let rec iter f = function
        Empty -> ()
      | Node {l; v; d; r} ->
          iter f l; f v d; iter f r

    let rec map f = function
        Empty ->
          Empty
      | Node {l; v; d; r; h} ->
          let l' = map f l in
          let d' = f d in
          let r' = map f r in
          Node{l=l'; v; d=d'; r=r'; h}

    let rec mapi f = function
        Empty ->
          Empty
      | Node {l; v; d; r; h} ->
          let l' = mapi f l in
          let d' = f v d in
          let r' = mapi f r in
          Node{l=l'; v; d=d'; r=r'; h}

    let rec fold f m accu =
      match m with
        Empty -> accu
      | Node {l; v; d; r} ->
          fold f r (f v d (fold f l accu))

    let rec for_all p = function
        Empty -> true
      | Node {l; v; d; r} -> p v d && for_all p l && for_all p r

    let rec exists p = function
        Empty -> false
      | Node {l; v; d; r} -> p v d || exists p l || exists p r

    (* Beware: those two functions assume that the added k is *strictly*
       smaller (or bigger) than all the present keys in the tree; it
       does not test for equality with the current min (or max) key.

       Indeed, they are only used during the "join" operation which
       respects this precondition.
    *)

    let rec add_min_binding k x = function
      | Empty -> singleton k x
      | Node {l; v; d; r} ->
        bal (add_min_binding k x l) v d r

    let rec add_max_binding k x = function
      | Empty -> singleton k x
      | Node {l; v; d; r} ->
        bal l v d (add_max_binding k x r)

    (* Same as create and bal, but no assumptions are made on the
       relative heights of l and r. *)

    let rec join l v d r =
      match (l, r) with
        (Empty, _) -> add_min_binding v d r
      | (_, Empty) -> add_max_binding v d l
      | (Node{l=ll; v=lv; d=ld; r=lr; h=lh},
         Node{l=rl; v=rv; d=rd; r=rr; h=rh}) ->
          if lh > rh + 2 then bal ll lv ld (join lr v d r) else
          if rh > lh + 2 then bal (join l v d rl) rv rd rr else
          create l v d r

    (* Merge two trees l and r into one.
       All elements of l must precede the elements of r.
       No assumption on the heights of l and r. *)

    let concat t1 t2 =
      match (t1, t2) with
        (Empty, t) -> t
      | (t, Empty) -> t
      | (_, _) ->
          let (x, d) = min_binding t2 in
          join t1 x d (remove_min_binding t2)

    let concat_or_join t1 v d t2 =
      match d with
      | Some d -> join t1 v d t2
      | None -> concat t1 t2

    let divide_exn = function
      | Node {l; v; d; r} -> (l, v, d, r)
      | Empty -> raise Not_found

    let divide = function
      | Node {l; v; d; r} -> Some (l, v, d, r)
      | Empty -> None

    let rec split x = function
        Empty ->
          (Empty, None, Empty)
      | Node {l; v; d; r} ->
          let c = Ord.compare x v in
          if c = 0 then (l, Some d, r)
          else if c < 0 then
            let (ll, pres, rl) = split x l in (ll, pres, join rl v d r)
          else
            let (lr, pres, rr) = split x r in (join l v d lr, pres, rr)

    let rec merge f s1 s2 =
      match (s1, s2) with
        (Empty, Empty) -> Empty
      | (Node {l=l1; v=v1; d=d1; r=r1; h=h1}, _) when h1 >= height s2 ->
          let (l2, d2, r2) = split v1 s2 in
          concat_or_join (merge f l1 l2) v1 (f v1 (Some d1) d2) (merge f r1 r2)
      | (_, Node {l=l2; v=v2; d=d2; r=r2}) ->
          let (l1, d1, r1) = split v2 s1 in
          concat_or_join (merge f l1 l2) v2 (f v2 d1 (Some d2)) (merge f r1 r2)
      | _ ->
          assert false

    let rec union f s1 s2 =
      match (s1, s2) with
      | (Empty, s) | (s, Empty) -> s
      | (Node {l=l1; v=v1; d=d1; r=r1; h=h1},
         Node {l=l2; v=v2; d=d2; r=r2; h=h2}) ->
          if h1 >= h2 then
            let (l2, d2, r2) = split v1 s2 in
            let l = union f l1 l2 and r = union f r1 r2 in
            match d2 with
            | None -> join l v1 d1 r
            | Some d2 -> concat_or_join l v1 (f v1 d1 d2) r
          else
            let (l1, d1, r1) = split v2 s1 in
            let l = union f l1 l2 and r = union f r1 r2 in
            match d1 with
            | None -> join l v2 d2 r
            | Some d1 -> concat_or_join l v2 (f v2 d1 d2) r

    let rec filter p = function
        Empty -> Empty
      | Node {l; v; d; r} as m ->
          (* call [p] in the expected left-to-right order *)
          let l' = filter p l in
          let pvd = p v d in
          let r' = filter p r in
          if pvd then if l==l' && r==r' then m else join l' v d r'
          else concat l' r'

    let rec filter_map f = function
        Empty -> Empty
      | Node {l; v; d; r} ->
          (* call [f] in the expected left-to-right order *)
          let l' = filter_map f l in
          let fvd = f v d in
          let r' = filter_map f r in
          begin match fvd with
            | Some d' -> join l' v d' r'
            | None -> concat l' r'
          end

    let rec partition p = function
        Empty -> (Empty, Empty)
      | Node {l; v; d; r} ->
          (* call [p] in the expected left-to-right order *)
          let (lt, lf) = partition p l in
          let pvd = p v d in
          let (rt, rf) = partition p r in
          if pvd
          then (join lt v d rt, concat lf rf)
          else (concat lt rt, join lf v d rf)

    let rec cardinal = function
        Empty -> 0
      | Node {l; r} -> cardinal l + 1 + cardinal r

    let bindings = bindings

    let choose = function
        Empty -> raise Not_found
      | Node {v; d} -> (v, d)

    let choose_opt = function
        Empty -> None
      | Node {v; d} -> Some (v, d)

    let add_seq i m =
      Seq.fold_left (fun m (k,v) -> add k v m) m i

    let of_seq i = add_seq i empty

    let rec seq_of_enum_ c () = match c with
      | End -> Seq.Nil
      | More (k,v,t,rest) -> Seq.Cons ((k,v), seq_of_enum_ (cons_enum t rest))

    let to_seq m =
      seq_of_enum_ (cons_enum m End)

    let to_seq_from low m =
      let rec aux low m c = match m with
        | Empty -> c
        | Node {l; v; d; r; _} ->
            begin match Ord.compare v low with
              | 0 -> More (v, d, r, c)
              | n when n<0 -> aux low r c
              | _ -> aux low l (More (v, d, r, c))
            end
      in
      seq_of_enum_ (aux low m End)
end