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baseMap.ml
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baseMap.ml
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(*
Copyright © 2011 MLstate
This file is part of OPA.
OPA is free software: you can redistribute it and/or modify it under the
terms of the GNU Affero General Public License, version 3, as published by
the Free Software Foundation.
OPA is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
FOR A PARTICULAR PURPOSE. See the GNU Affero General Public License for
more details.
You should have received a copy of the GNU Affero General Public License
along with OPA. If not, see <http://www.gnu.org/licenses/>.
*)
(* depends *)
module Set = BaseSet
(* -- *)
exception IteratorEnd
module Make (Ord: OrderedTypeSig.S) : (BaseMapSig.S with type key = Ord.t) =
struct
type key = Ord.t
type 'a t =
| Empty
| Node of 'a t * key * 'a * 'a t * int
let decons = function
| Empty -> invalid_arg "Map.decons"
| Node (left, key, val_, right, _) -> left, key, val_, right
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, x, d, r, (if hl >= hr then hl + 1 else hr + 1))
(*
Balance the tree such that the difference between the heights of
the two branches is at most one
*)
let bal l x d r =
let hl = height l
and hr = height r in
if hl > hr + 2 then begin
match l with
| Empty -> assert false
| Node(ll, lv, ld, lr, _) ->
if height ll >= height lr then
create ll lv ld (create lr x d r)
else begin
match lr with
Empty -> assert false
| Node(lrl, lrv, lrd, 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 -> assert false
| Node(rl, rv, rd, rr, _) ->
if height rr >= height rl then
create (create l x d rl) rv rd rr
else begin
match rl with
Empty -> assert false
| Node(rll, rlv, rld, rlr, _) ->
create (create l x d rll) rlv rld (create rlr rv rd rr)
end
end else
Node(l, x, d, r, (if hl >= hr then hl + 1 else hr + 1))
let empty = Empty
let is_empty = function Empty -> true | _ -> false
let singleton x data = Node (Empty, x, data, Empty, 1)
let rec add x data = function
| Empty -> Node (Empty, x, data, Empty, 1)
| Node (l, v, d, r, h) ->
let c = Ord.compare x v in
if c = 0 then Node(l, x, data, r, h)
else if c < 0 then bal (add x data l) v d r
else bal l v d (add x data r)
let replace x replace map =
let rec aux = function
| Empty -> Node (Empty, x, replace None, Empty, 1)
| Node (l, v, d, r, h) ->
let c = Ord.compare x v in
if c = 0 then Node (l, x, replace (Some d), r, h)
else if c < 0 then bal (aux l) v d r
else bal l v d (aux r)
in
aux map
let update key f map =
let f = function
| None -> raise Not_found
| Some a -> f a
in
replace key f map
let update_default key f default map =
let f = function
| None -> default
| Some a -> f a
in
replace key f map
let rec safe_add x data = function
| Empty -> Node (Empty, x, data, Empty, 1)
| Node (l, v, d, r, _h) ->
let c = Ord.compare x v in
if c = 0 then raise (Invalid_argument "Base.Map.safe_add")
else if c < 0 then bal (safe_add x data l) v d r
else bal l v d (safe_add x data r)
let rec findi_opt x = function
| Empty -> None
| Node(l, v, d, r, _) ->
let c = Ord.compare x v in
if c = 0 then Some (v,d)
else findi_opt x (if c < 0 then l else r)
let find_opt x m = Option.map snd (findi_opt x m)
(** @raise Not_found. *)
let find x m = Option.get_exn (Not_found) (find_opt x m)
(** @raise Not_found. *)
let findi x m = Option.get_exn (Not_found) (findi_opt x m)
let rec size = function
| Empty -> 0
| Node (l, _, _, r, _) -> 1 + size l + size r
(* let random m =
let rec aux height = function
| Empty -> raise Not_found
| Node (Empty, v, d, Empty, _) -> v, d
| Node (Empty, v, d, r, _) ->
| Node (l, v, d, r, _) ->
match Random.int height with
| 0 -> (v, d)
| i when i mod 2 = 0 -> random (pred height)
let c = Ord.compare x v in
if c = 0 then (v, d)
else if c < 0 then
if l = Empty then (v, d)
else nearest x l
else (* c > 0 *)
if r = Empty then (v, d)
else nearest x r *)
(* FIXME: slow *)
let rec random = function
| Empty -> raise Not_found
| Node (l, v, d, r, _) ->
let sl = size l
and sr = size r in
if sl = 0 then
if sr = 0 or Random.int (sr + 1) = 0 then v, d
else random r
else if sr = 0 then
if sl = 0 or Random.int (sl + 1) = 0 then v, d
else random l
else
match Random.int (sl + sr + 1) with
| 0 -> v, d
| i -> random (if i mod 2 = 0 then l else r)
let rec nearest x = function
| Empty -> raise Not_found
| Node (l, v, d, r, _) ->
let c = Ord.compare x v in
if c = 0 then (v, d)
else if c < 0 then
if l = Empty then (v, d)
else nearest x l
else (* c > 0 *)
if r = Empty then (v, d)
else nearest x r
let return = function
| Some r -> r
| _ -> raise Not_found
let find_inf x t =
let rec aux res = function
| Empty -> return res
| Node (l, v, d, r, _) ->
let c = Ord.compare x v in
if c = 0 then (v, d)
else if c < 0 then
if l = Empty then return res
else aux res l
else (* c > 0 *)
let res = match res with
| Some (rv, _rd) when rv < v -> Some (v, d)
| None -> Some (v, d)
| _ -> res in
if r = Empty then return res
else aux res r
in aux None t
let find_sup x t =
let rec aux res = function
| Empty -> return res
| Node (l, v, d, r, _) ->
let c = Ord.compare x v in
if c = 0 then (v, d)
else if c < 0 then
let res = match res with
| Some (rv, _rd) when rv > v -> Some (v, d)
| None -> Some (v, d)
| _ -> res in
if l = Empty then return res
else aux res l
else (* c > 0 *)
if r = Empty then return res
else aux res r
in aux None t
let min t =
let rec aux = function
| Empty -> raise Not_found
| Node (Empty, v, d, _, _) -> v, d
| Node (l, _, _, _, _) -> aux l
in aux t
let choose = function
| Empty -> raise Not_found
| Node (_,v,d,_,_) -> v,d
let max t =
let rec aux = function
| Empty -> raise Not_found
| Node (_, v, d, Empty, _) -> v, d
| Node (_, _, _, r, _) -> aux r
in aux t
let rec mem x = function
| Empty -> false
| Node(l, v, _d, r, _) ->
let c = Ord.compare x v in
(* FIXME : benchmark *)
(* if c < 0 then mem x l *)
(* else if c > 0 then mem x r *)
(* else true *)
c = 0 || mem x (if c < 0 then l else r)
let rec min_binding = function
Empty -> raise Not_found
| Node(Empty, x, d, _r, _) -> (x, d)
| Node(l, _x, _d, _r, _) -> min_binding l
let rec remove_min_binding = function
Empty -> invalid_arg "Map.remove_min_elt"
| Node(Empty, _x, _d, r, _) -> r
| Node(l, x, d, r, _) -> bal (remove_min_binding l) x d r
let _merge t1 t2 =
match t1, t2 with
| (Empty, 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, _h) ->
let c = Ord.compare x v in
if c = 0 then _merge l r
else if c < 0 then bal (remove x l) v d r
else bal l v d (remove x r)
let rec iter f = function
Empty -> ()
| Node(l, v, d, r, _) ->
iter f l; f v d; iter f r
let rec rev_iter f = function
Empty -> ()
| Node(l, v, d, r, _) ->
rev_iter f r; f v d; rev_iter f l
let rec map f = function
Empty -> Empty
| Node(l, v, d, r, h) -> Node(map f l, v, f d, map f r, h)
let rec mapi f = function
Empty -> Empty
| Node(l, v, d, r, h) -> Node(mapi f l, v, f v d, mapi f r, h)
let rec fold_map f m acc =
match m with
| Empty -> (acc, Empty)
| Node (l, v, d, r, h) ->
let (acc, l) = fold_map f l acc in
let (acc, d) = f v d acc in
let (acc, r) = fold_map f r acc in
(acc, Node (l, v, d, r, h))
let rec fold f m acc = match m with
| Empty -> acc
| Node (l, v, d, r, _) -> fold f r (f v d (fold f l acc))
let fold_range_compare compare f m kmin kmax acc =
(* if compare kmin kmax = 1 then *)
(* invalid_arg "[Map.fold_range] kmin > kmax"; *)
(* Fold until find kmax. *)
let rec fold_max m acc = match m with
| Empty -> acc
| Node (l, k, v, r, _) ->
match compare kmax k with
| -1 -> aux_range l acc
| 0 -> f k v (fold f l acc)
| 1 -> fold_max r (f k v (fold f l acc))
| x -> invalid_arg
(Printf.sprintf
"[Map.fold_range_compare] Unexpected result of compare (%d)" x)
(* Fold until find kmin. *)
and fold_min m acc = match m with
| Empty -> acc
| Node (l, k, v, r, _) ->
match compare kmin k with
| -1 -> fold f r (f k v (fold_min l acc))
| 0 -> fold f r (f k v acc)
| 1 -> aux_range r acc
| x -> invalid_arg
(Printf.sprintf
"[Map.fold_range_compare] Unexpected result of compare (%d)" x)
(* Fold in range. *)
and aux_range m acc =
match m with
| Empty -> acc
| Node (l, k, v, r, _) ->
match compare kmin k, compare kmax k with
| -1, 1 -> fold_max r (f k v (fold_min l acc))
| -1, 0 -> f k v (fold_min l acc)
| -1, -1 -> aux_range l acc
| 0, 1 -> fold_max r (f k v acc)
| 0, 0 -> f k v acc
| 1, 1 -> aux_range r acc
| 1, 0 (* Smaller than kmin and equals to kmax!? *)
| 1, -1 (* Smaller than kmin and smaller than kmax!? *)
| 0, -1 -> (* Equals to kmin and higher to kmax!? *)
assert false
| x, y -> invalid_arg
(Printf.sprintf
"[Map.fold_range_compare] Unexpected result of compare (%d, %d)" x y)
in aux_range m acc
let fold_range x = fold_range_compare Ord.compare x
let fold_length ~start ~length f m acc =
(* Different tool functions used depending on the sign of [length],
to avoid code duplication. Probably not more readable, though. *)
let (cmp, length, pr_l, pr_r) =
if length >= 0 then
(Ord.compare, length, fst, snd)
else
((fun x y -> 0 - Ord.compare x y), 0 - length, snd, fst)
in
(* [n] is the number of applications of [f] so far *)
let rec aux n f m acc =
if n = length then (acc, n) else
match m with
| Empty -> (acc, n)
| Node (l, v, d, r, _) ->
let l = pr_l (l, r) in
let r = pr_r (l, r) in
match cmp start v with
| -1 ->
let (acc, n) = aux n f l acc in
if n = length then (acc, n) else
let (acc, n) = (f v d acc, n + 1) in
aux n f r acc
| 0 ->
let (acc, n) = (f v d acc, n + 1) in
aux n f r acc
| 1 ->
aux n f r acc
| _ -> assert false
in
let (acc, n) = aux 0 f m acc in
assert (n <= length);
(* Value of [n] is the number of elements that we managed to gather;
it's equal to [length], unless not enough elements in the tree. *)
acc
(* let rec fold2 f m1 m2 acc = match m1, m2 with *)
(* | Empty, Empty -> acc *)
(* | Node (l, v, d, r, _) -> fold f r (f v d (fold f l acc)) *)
let rec fold_rev f m acc = match m with
| Empty -> acc
| Node (l, v, d, r, _) -> fold_rev f l (f v d (fold_rev f r acc))
let filter_val f t =
fold (fun k v acc -> if f v then add k v acc else acc) t empty
let filter_keys f m =
let rec aux = function
| Empty -> Empty
| Node (l, v, d, r, _h) ->
if f v
then bal (aux l) v d (aux r)
else _merge (aux l) (aux r)
in aux m
module Iter : (IterSig.S with type +'a element = key * 'a and type +'a structure = 'a t and type +'a t = ((key *'a ) * 'a t) list) =
struct
type 'a structure = 'a t
type 'a element = key * 'a
type 'a t = ('a element * 'a structure) list
let rec aux_make acc= function
| Empty -> acc
| Node (l, v, d, r, _) ->
let acc=((v,d),r)::acc in
aux_make acc l
let make m = aux_make [] m
(* let make_iterator m = let rec aux = function | Empty ->
[] | Node (l, v, d, r, _) -> (v, d, r) :: aux l in List.rev (aux
m) *)
let get = function
| ((v, d), _) :: _ -> v, d
| _ -> raise IteratorEnd
let next = function
| (_, Empty) :: tl -> tl
| (_, r) :: tl -> aux_make tl r
| _ -> raise IteratorEnd
let at_end i = i = []
(* TODO change failwith to raise NotImplemented *)
let remaining _i = failwith ("NotImplemented BaseMap.Make.Iter.remaining")
end
let rec fold_map2 f m m' acc =
let iter' = Iter.make m' in
(* the result of the map, the accumulator and the iterator*)
let rec aux iter acc = function
| Empty -> Empty, acc, iter
| Node (l, v, d, r, h) ->
let l, acc, iter = aux iter acc l in
let () = if Iter.at_end iter then invalid_arg "baseMap.fold_map2: not enough element in second map" in
let v',e = Iter.get iter in
let () = if not (v'=v) then invalid_arg "baseMap.fold_map2: map with different elements" in
let iter = Iter.next iter in
let acc, e = f v d e acc in
let r, acc, iter = aux iter acc r in
let m = Node (l, v, e, r, h) in
m, acc, iter
in
let m, result, iter'=aux iter' acc m in
if Iter.at_end iter' then result, m
else invalid_arg "baseMap.fold_map2 not enough element in first map"
module RevIter : (IterSig.S with type +'a element = key * 'a and type +'a structure = 'a t) =
struct
type 'a structure = 'a t
type 'a element = key * 'a
type 'a t = ('a structure * 'a element ) list
let rec make = function
| Empty -> []
| Node (l, v, d, r, _) -> make r @ [l, (v, d)]
(* let make_iterator m = let rec aux = function | Empty ->
[] | Node (l, v, d, r, _) -> (v, d, r) :: aux l in List.rev (aux
m) *)
let get = function
| (_, (v, d)) :: _ -> v, d
| _ -> raise IteratorEnd
let next = function
| (Empty, _) :: tl -> tl
| (r, _) :: tl -> make r @ tl
| _ -> raise IteratorEnd
let at_end i = i = []
(* TODO change failwith to raise NotImplemented *)
let remaining _i = failwith ("NotImplemented BaseMap.Make.Iter.remaining")
end
type 'a enumeration = End | More of key * 'a * 'a t * 'a 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 cmp 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 = Ord.compare v1 v2 in
if c <> 0 then c else
let c = cmp 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)
let equal cmp 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)) ->
Ord.compare v1 v2 = 0 && cmp d1 d2 &&
equal_aux (cons_enum r1 e1) (cons_enum r2 e2)
in equal_aux (cons_enum m1 End) (cons_enum m2 End)
let from_list l = List.fold_left (fun acc (k, v) -> add k v acc) empty l
let fold_assoc k v acc = (k, v) :: acc
let to_list t = fold fold_assoc t []
let keys t = fold (fun k _ acc -> k :: acc) t []
let elts t = fold (fun _ el acc -> el :: acc) t []
let ordered_list t = fold_rev fold_assoc t []
let rev_ordered_list t = fold fold_assoc t []
let merge_i f m1 m2 = (* warning: [f] may be not commutative! *)
let add_merge x y acc =
add x (
match find_opt x acc with
| Some v -> f x y v
| _ -> y
) acc
in
let add_merge2 x y acc =
add x (
match find_opt x acc with
| Some v -> f x v y
| _ -> y
) acc
in
if height m1 <= height m2 then
fold add_merge m1 m2
else
fold add_merge2 m2 m1
let merge f m1 m2 = merge_i (fun _ x y -> f x y) m1 m2
let safe_merge m1 m2 =
let m1, m2 = if height m1 <= height m2 then m1, m2 else m2, m1 in
try fold safe_add m1 m2 with
| Invalid_argument "Base.Map.safe_add" ->
raise (Invalid_argument "Base.Map.safe_merge")
(* Heritage of old unused functions *)
let of_set f s =
let module S = Set.Make(Ord) in
S.fold (fun x acc -> add x (f x) acc) s empty
let incr ?(step=1) k m =
add k ((Option.default 0 (find_opt k m)) + step) m
let rename f m =
fold (fun k elt acc -> add (f k) elt acc) m empty
(* cf doc *)
let pp sep ppe fmt t =
let fiter elt val_ =
ppe fmt elt val_ ;
Format.fprintf fmt sep
in
iter fiter t
let compare_key = Ord.compare
let diff map1 map2 =
fold (fun k v acc ->
if mem k map2 then
acc
else
add k v acc
) map1 empty
let diff2 map1 map2 map3 =
fold (fun k v acc ->
if mem k map2 && not (mem k map3) then
acc
else
add k v acc
) map1 empty
let rec choose_opt = function
| Empty -> None
| Node(_, k, v, _r, _) -> Some (k, v)
let example_diff s1 s2 =
let diff_ = diff s1 s2 in
match choose_opt diff_ with
| Some elt -> Some elt
| None ->
let diff = diff s2 s1 in
match choose_opt diff with
| Some elt -> Some elt
| None -> None
let from_sorted_array keys vals =
let len_keys = Array.length keys in
let len_vals = Array.length vals in
if len_keys <> len_vals then assert false ;
let rec aux left right =
if left > right
then Empty
else
let midle = (left + right) lsr 1 in
let left_tree = aux left (pred midle) in
let right_tree = aux (succ midle) right in
let key = Array.unsafe_get keys midle in
let value = Array.unsafe_get vals midle in
create left_tree key value right_tree
in
aux 0 (pred len_keys)
end