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type 'a fmt = Format.formatter -> 'a -> unit
let pf = Format.fprintf
module type Ordered = sig type t val compare : t -> t -> int end
module type S = sig
type t
type k
type p
val empty : t
val sg : k -> p -> t
val is_empty : t -> bool
val size : t -> int
val mem : k -> t -> bool
val find : k -> t -> p option
val add : k -> p -> t -> t
val remove : k -> t -> t
val adjust: (p -> p) -> k -> t -> t
val min : t -> (k * p) option
val rest : t -> t option
val pop : t -> ((k * p) * t) option
val fold_at_most : p -> (k -> p -> 'a -> 'a) -> 'a -> t -> 'a
val iter_at_most : p -> (k -> p -> unit) -> t -> unit
val seq_at_most : p -> t -> (k * p) Seq.t
val fold : (k -> p -> 'a -> 'a) -> 'a -> t -> 'a
val filter : (k -> p -> bool) -> t -> t
val partition : (k -> p -> bool) -> t -> t * t
val iter : (k -> p -> unit) -> t -> unit
val to_list : t -> (k * p) list
val of_list : (k * p) list -> t
val of_sorted_list : (k * p) list -> t
val to_seq : t -> (k * p) Seq.t
val of_seq : (k * p) Seq.t -> t
val pp : ?sep:(unit fmt) -> (k * p) fmt -> t fmt
val depth : t -> int
val pp_dump : k fmt -> p fmt -> t fmt
end
module L = struct
include List
let rec take n = function
x::xs when n > 0 -> x :: take (pred n) xs | _ -> []
let rec drop n = function
_::xs when n > 0 -> drop (pred n) xs | xs -> xs
end
module Make (K: Ordered) (P: Ordered) :
S with type k = K.t and type p = P.t =
struct
type k = K.t
type p = P.t
type t =
N
| T of (k * p) * k * tree
and tree =
Lf
| NdL of (k * p) * tree * k * tree * int
| NdR of (k * p) * tree * k * tree * int
let empty = N
let sg (k, _ as kp) = T (kp, k, Lf)
let is_empty = function N -> true | _ -> false
let size_t = function
Lf -> 0
| NdL (_, _, _, _, w)
| NdR (_, _, _, _, w) -> w
let size = function N -> 0 | T (_, _, t) -> size_t t + 1
let nd_l kp t1 sk t2 = NdL (kp, t1, sk, t2, size_t t1 + size_t t2 + 1)
let nd_r kp t1 sk t2 = NdR (kp, t1, sk, t2, size_t t1 + size_t t2 + 1)
let nd (k, _ as kp) t1 sk t2 =
if K.compare k sk <= 0 then nd_l kp t1 sk t2 else nd_r kp t1 sk t2
let outweighs s1 s2 = s1 * 100 > s2 * 375
let (@<=@) (k1, p1) (k2, p2) =
let c = P.compare p1 p2 in
if c = 0 then K.compare k1 k2 <= 0 else c < 0 [@@inline]
let rot_l kp1 t1 sk1 = function
NdL (kp2, t2, sk2, t3, _) when kp1 @<=@ kp2 ->
nd kp1 (nd kp2 t1 sk1 t2) sk2 t3
| NdL (kp2, t2, sk2, t3, _) | NdR (kp2, t2, sk2, t3, _) ->
nd kp2 (nd kp1 t1 sk1 t2) sk2 t3
| Lf -> assert false
let rot_r kp1 tt sk2 t3 = match tt with
NdR (kp2, t1, sk1, t2, _) when kp1 @<=@ kp2 ->
nd kp1 t1 sk1 (nd kp2 t2 sk2 t3)
| NdL (kp2, t1, sk1, t2, _) | NdR (kp2, t1, sk1, t2, _) ->
nd kp2 t1 sk1 (nd kp1 t2 sk2 t3)
| Lf -> assert false
let rot_ll kp1 t1 sk1 = function
NdL (kp2, t2, sk2, t3, _) | NdR (kp2, t2, sk2, t3, _) ->
rot_l kp1 t1 sk1 (rot_r kp2 t2 sk2 t3)
| Lf -> assert false
let rot_rr kp1 tt sk2 t3 = match tt with
NdL (kp2, t1, sk1, t2, _) | NdR (kp2, t1, sk1, t2, _) ->
rot_r kp1 (rot_l kp2 t1 sk1 t2) sk2 t3
| Lf -> assert false
let nd_bal kp t1 sk t2 =
let s1 = size_t t1 and s2 = size_t t2 in
match (t1, t2) with
((NdL (_, t11, _, t12, _) | NdR (_, t11, _, t12, _)), _)
when s1 > 1 && outweighs s1 s2 ->
if size_t t11 > size_t t12 then
rot_r kp t1 sk t2
else rot_rr kp t1 sk t2
| (_, (NdL (_, t21, _, t22, _) | NdR (_, t21, _, t22, _)))
when s2 > 1 && outweighs s2 s1 ->
if size_t t21 < size_t t22 then
rot_l kp t1 sk t2
else rot_ll kp t1 sk t2
| _ -> nd kp t1 sk t2
let (><) t1 t2 = match (t1, t2) with
(N, t) | (t, N) -> t
| (T (kp1, sk1, t1), T (kp2, sk2, t2)) ->
if kp1 @<=@ kp2 then
T (kp1, sk2, nd_bal kp2 t1 sk1 t2)
else T (kp2, sk2, nd_bal kp1 t1 sk1 t2)
let (>|<) t1 t2 = match (t1, t2) with
(N, t) | (t, N) -> t
| (T (kp1, sk1, t1), T (kp2, sk2, t2)) ->
if kp1 @<=@ kp2 then
T (kp1, sk2, nd_r kp2 t1 sk1 t2)
else T (kp2, sk2, nd_l kp1 t1 sk1 t2)
let rec promote sk0 = function
Lf -> N
| NdL (kp, t1, sk, t2, _) -> T (kp, sk, t1) >< promote sk0 t2
| NdR (kp, t1, sk, t2, _) -> promote sk t1 >< T (kp, sk0, t2)
let min = function N -> None | T (kp, _, _) -> Some kp
let rest = function N -> None | T (_, sk, t) -> Some (promote sk t)
let pop = function N -> None | T (kp, sk, t) -> Some (kp, promote sk t)
let find k0 t =
let rec go k0 = function
Lf -> None
| NdL ((k, p), t1, sk, t2, _)
| NdR ((k, p), t1, sk, t2, _) ->
if K.compare k0 k = 0 then Some p else
if K.compare k0 sk <= 0 then go k0 t1 else
go k0 t2 in
match t with
N -> None
| T ((k, p), _, t) -> if K.compare k0 k = 0 then Some p else go k0 t
let mem k0 t =
let rec go k0 = function
Lf -> false
| NdL ((k, _), t1, sk, t2, _)
| NdR ((k, _), t1, sk, t2, _) ->
K.compare k0 k = 0 ||
if K.compare k0 sk <= 0 then go k0 t1 else go k0 t2 in
match t with N -> false | T ((k, _), _, t) -> K.compare k0 k = 0 || go k0 t
let foldr_at_most p0 f t z =
let rec f1 p0 (_, p as kp) f z t =
if P.compare p p0 <= 0 then f2 p0 kp f z t else z ()
and f2 p0 kp0 f z = function
Lf -> f kp0 z
| NdL (kp, t1, _, t2, _) -> f1 p0 kp f (fun () -> f2 p0 kp0 f z t2) t1
| NdR (kp, t1, _, t2, _) -> f2 p0 kp0 f (fun () -> f1 p0 kp f z t2) t1 in
match t with T (kp0, _, t) -> f1 p0 kp0 f z t | _ -> z ()
let fold_at_most p0 f z t =
foldr_at_most p0 (fun (k, p) a -> f k p (a ())) t (fun () -> z)
let iter_at_most p0 f t =
foldr_at_most p0 (fun (k, p) i -> f k p; i ()) t ignore
let seq_at_most p0 t () =
foldr_at_most p0 (fun kp seq -> Seq.Cons (kp, seq)) t Seq.empty
type view = Nv | Sgv of (k * p) | Binv of t * K.t * t
let view = function
N -> Nv
| T (kp, _, Lf) -> Sgv kp
| T (kp1, sk1, NdL (kp2, t1, sk2, t2, _)) ->
Binv (T (kp2, sk2, t1), sk2, T (kp1, sk1, t2))
| T (kp1, sk1, NdR (kp2, t1, sk2, t2, _)) ->
Binv (T (kp1, sk2, t1), sk2, T (kp2, sk1, t2))
let rec add (k0, _ as kp0) = function
N -> sg kp0
| T ((k, _), _, Lf) as t ->
let t0 = sg kp0 and c = K.compare k0 k in
if c < 0 then t0 >|< t else if c > 0 then t >|< t0 else t0
| T (kp1, sk1, NdL (kp2, t1, sk2, t2, _)) ->
let t = T (kp2, sk2, t1) and t' = T (kp1, sk1, t2) in
if K.compare k0 sk2 <= 0 then add kp0 t >< t' else t >< add kp0 t'
| T (kp1, sk1, NdR (kp2, t1, sk2, t2, _)) ->
let t = T (kp1, sk2, t1) and t' = T (kp2, sk1, t2) in
if K.compare k0 sk2 <= 0 then add kp0 t >< t' else t >< add kp0 t'
let remove k0 t =
let rec go k0 t = match view t with
Binv (t1, sk, t2) ->
if K.compare k0 sk <= 0 then go k0 t1 >< t2 else t1 >< go k0 t2
| Sgv (k, _) when K.compare k k0 = 0 -> N
| Sgv _ | Nv -> raise_notrace Exit in
try go k0 t with Exit -> t
let adjust f k0 t =
let rec go f k0 t = match view t with
Binv (t1, sk, t2) ->
if K.compare k0 sk <= 0 then go f k0 t1 >|< t2 else t1 >|< go f k0 t2
| Sgv (k, p) when K.compare k k0 = 0 -> sg (k, f p)
| Sgv _ | Nv -> raise_notrace Exit in
try go f k0 t with Exit -> t
let rec filter pf t = match view t with
Nv -> N
| Sgv (k, p as kp) -> if pf k p then sg kp else N
| Binv (t1, _, t2) -> filter pf t1 >< filter pf t2
let rec partition pf t = match view t with
Nv -> (N, N)
| Sgv (k, p as kp) -> if pf k p then (sg kp, N) else (N, sg kp)
| Binv (t1, _, t2) ->
let (y1, n1) = partition pf t1
and (y2, n2) = partition pf t2 in
(y1 >< y2, n1 >< n2)
let of_sorted_list xs =
let rec go n = function
[] -> N
| [x] -> sg x
| [x;y] -> sg x >|< sg y
| [x;y;z] -> (sg x >|< sg y) >|< sg z
| [x;y;z;w] -> (sg x >|< sg y) >|< (sg z >|< sg w)
| xs -> let m = n / 2 in go m L.(take m xs) >|< go (n - m) L.(drop m xs) in
go (L.length xs) xs
let of_list xs =
let cmp (k1, _) (k2, _) = K.compare k1 k2 in
List.sort_uniq cmp xs |> of_sorted_list
let of_seq xs = Seq.fold_left (fun xs a -> a::xs) [] xs |> List.rev |> of_list
let iter f t =
let rec go (p0, k0 as pk0) f = function
Lf -> f p0 k0
| NdL (pk, t1, _, t2, _) -> go pk f t1; go pk0 f t2
| NdR (pk, t1, _, t2, _) -> go pk0 f t1; go pk f t2 in
match t with N -> () | T (pk, _, t) -> go pk f t
let foldr f t z =
let rec go kp0 f z = function
Lf -> f kp0 z
| NdL (kp, t1, _, t2, _) -> go kp f (fun () -> go kp0 f z t2) t1
| NdR (kp, t1, _, t2, _) -> go kp0 f (fun () -> go kp f z t2) t1 in
match t with T (kp, _, t) -> go kp f z t | N -> z ()
let nil () = []
let fold f z t = foldr (fun (k, p) z -> f k p (z ())) t (fun () -> z)
let to_list t = foldr (fun kp xs -> kp :: xs ()) t nil
let to_seq t () = foldr (fun kp xs -> Seq.Cons (kp, xs)) t Seq.empty
let add k p = add (k, p)
let sg k p = sg (k, p)
let depth t =
let rec go = function
Lf -> 0
| NdL (_, t1, _, t2, _) | NdR (_, t1, _, t2, _) ->
max (go t1) (go t2) + 1 in
match t with N -> 0 | T (_, _, t) -> go t + 1
let pp ?(sep = Format.pp_print_space) pp ppf t =
let rec go pk0 cont ppf = function
Lf -> pf ppf "@[%a@]" pp pk0; if cont then sep ppf ()
| NdL (pk, t1, _, t2, _) -> go pk true ppf t1; go pk0 cont ppf t2
| NdR (pk, t1, _, t2, _) -> go pk0 true ppf t1; go pk cont ppf t2 in
match t with N -> () | T (pk, _, t) -> pf ppf "@[%a@]" (go pk false) t
let pp_dump ppk ppp ppf t =
let rec go ppf = function
Lf -> Format.pp_print_string ppf "*"
| NdL ((k, p), t1, sk, t2, w)
| NdR ((k, p), t1, sk, t2, w) ->
pf ppf " @[<v>%a@]@,%a/%a -> %a #%d@, @[<v>%a@]"
go t1 ppk k ppk sk ppp p w go t2 in
match t with
N -> ()
| T ((k, p), sk, t1) ->
pf ppf "%a/%a -> %a@, @[<v>%a@]" ppk k ppk sk ppp p go t1
end