(************************************************************************) (* * The Rocq Prover / The Rocq Development Team *) (* v * Copyright INRIA, CNRS and contributors *) (* <O___,, * (see version control and CREDITS file for authors & dates) *) (* \VV/ **************************************************************) (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (* * (see LICENSE file for the text of the license) *) (************************************************************************)
module type OrderedType = sig type t val compare : t -> t -> int end
module type MonadS = sig type +'a t val return : 'a -> 'a t val (>>=) : 'a t -> ('a -> 'b t) -> 'b t end
module type S = Map.S
module type UExtS = sig
include CSig.UMapS
module Set : CSig.USetS withtype elt = key val get : key -> 'a t -> 'a valset : key -> 'a -> 'a t -> 'a t val modify : key -> (key -> 'a -> 'a) -> 'a t -> 'a t val domain : 'a t -> Set.t val bind : (key -> 'a) -> Set.t -> 'a t val height : 'a t -> int val filter_range : (key -> int) -> 'a t -> 'a t val of_list : (key * 'a) list -> 'a t val symmetric_diff_fold :
(key -> 'a option -> 'a option -> 'b -> 'b) -> 'a t -> 'a t -> 'b -> 'b
module Smart : sig valmap : ('a -> 'a) -> 'a t -> 'a t val mapi : (key -> 'a -> 'a) -> 'a t -> 'a t end
module Monad(M : MonadS) : sig val fold : (key -> 'a -> 'b -> 'b M.t) -> 'a t -> 'b -> 'b M.t val mapi : (key -> 'a -> 'b M.t) -> 'a t -> 'b t M.t end end
module type ExtS = sig
include CSig.MapS
module Set : CSig.SetS withtype elt = key
include UExtS withtype key := key andtype'a t := 'a t and module Set := Set
module Monad(M:MonadS) : sig
include module typeof Monad(M) val fold_left : (key -> 'a -> 'b -> 'b M.t) -> 'a t -> 'b -> 'b M.t val fold_right : (key -> 'a -> 'b -> 'b M.t) -> 'a t -> 'b -> 'b M.t end
val fold_left : (key -> 'a -> 'b -> 'b) -> 'a t -> 'b -> 'b val fold_right : (key -> 'a -> 'b -> 'b) -> 'a t -> 'b -> 'b val fold_left_map : (key -> 'a -> 'b -> 'b * 'c) -> 'a t -> 'b -> 'b * 'c t val fold_right_map : (key -> 'a -> 'b -> 'b * 'c) -> 'a t -> 'b -> 'b * 'c t end
module MapExt (M : Map.OrderedType) : sig type'a map = 'a Map.Make(M).t valset : M.t -> 'a -> 'a map -> 'a map val get : M.t -> 'a map -> 'a val modify : M.t -> (M.t -> 'a -> 'a) -> 'a map -> 'a map val domain : 'a map -> Set.Make(M).t val bind : (M.t -> 'a) -> Set.Make(M).t -> 'a map val fold_left : (M.t -> 'a -> 'b -> 'b) -> 'a map -> 'b -> 'b val fold_right : (M.t -> 'a -> 'b -> 'b) -> 'a map -> 'b -> 'b val fold_left_map : (M.t -> 'a -> 'b -> 'b * 'c) -> 'a map -> 'b -> 'b * 'c map val fold_right_map : (M.t -> 'a -> 'b -> 'b * 'c) -> 'a map -> 'b -> 'b * 'c map val height : 'a map -> int val filter_range : (M.t -> int) -> 'a map -> 'a map val symmetric_diff_fold :
(M.t -> 'a option -> 'a option -> 'b -> 'b) -> 'a map -> 'a map -> 'b -> 'b val of_list : (M.t * 'a) list -> 'a map
module Smart : sig valmap : ('a -> 'a) -> 'a map -> 'a map val mapi : (M.t -> 'a -> 'a) -> 'a map -> 'a map end
module Monad(MS : MonadS) : sig val fold : (M.t -> 'a -> 'b -> 'b MS.t) -> 'a map -> 'b -> 'b MS.t val fold_left : (M.t -> 'a -> 'b -> 'b MS.t) -> 'a map -> 'b -> 'b MS.t val fold_right : (M.t -> 'a -> 'b -> 'b MS.t) -> 'a map -> 'b -> 'b MS.t val mapi : (M.t -> 'a -> 'b MS.t) -> 'a map -> 'b map MS.t end end = struct (** This unsafe module is a way to access to the actual implementations of OCaml sets and maps without reimplementing them ourselves. It is quite dubious that these implementations will ever be changed... Nonetheless, if this happens, we can still implement a less clever version of [domain].
*)
type _set =
| SEmpty
| SNode ofset * M.t * set * int
let map_prj : 'a map -> 'a _map = Obj.magic let map_inj : 'a _map -> 'a map = Obj.magic let set_prj : set -> _set = Obj.magic let set_inj : _set -> set = Obj.magic
let rec set k v (s : 'a map) : 'a map = match map_prj s with
| MEmpty -> raise Not_found
| MNode {l; v=k'; d=v'; r; h} -> let c = M.compare k k' in if c < 0 then let l' = set k v l in if l == l' then s else map_inj (MNode {l=l'; v=k'; d=v'; r; h}) elseif c = 0 then if v' == v then s else map_inj (MNode {l; v=k'; d=v; r; h}) else let r' = set k v r in if r == r' then s else map_inj (MNode {l; v=k'; d=v'; r=r'; h})
let rec get k (s:'a map) : 'a = match map_prj s with
| MEmpty -> assert false
| MNode {l; v=k'; d=v; r; h} -> let c = M.compare k k' in if c < 0 then get k l elseif c = 0 then v else get k r
let rec modify k f (s : 'a map) : 'a map = match map_prj s with
| MEmpty -> raise Not_found
| MNode {l; v; d; r; h} -> let c = M.compare k v in if c < 0 then let l' = modify k f l in if l == l' then s else map_inj (MNode {l=l'; v; d; r; h}) elseif c = 0 then let d' = f v d in if d' == d then s else map_inj (MNode {l; v; d=d'; r; h}) else let r' = modify k f r in if r == r' then s else map_inj (MNode {l; v; d; r=r'; h})
let rec domain (s : 'a map) : set = match map_prj s with
| MEmpty -> set_inj SEmpty
| MNode {l; v; r; h; _} ->
set_inj (SNode (domain l, v, domain r, h)) (** This function is essentially identity, but OCaml current stdlib does not take advantage of the similarity of the two structures, so we introduce
this unsafe loophole. *)
let rec bind f (s : set) : 'a map = match set_prj s with
| SEmpty -> map_inj MEmpty
| SNode (l, k, r, h) ->
map_inj (MNode { l=bind f l; v=k; d=f k; r=bind f r; h}) (** Dual operation of [domain]. *)
let rec fold_left f (s : 'a map) accu = match map_prj s with
| MEmpty -> accu
| MNode {l; v=k; d=v; r; h} -> let accu = f k v (fold_left f l accu) in
fold_left f r accu
let rec fold_right f (s : 'a map) accu = match map_prj s with
| MEmpty -> accu
| MNode {l; v=k; d=v; r; h} -> let accu = f k v (fold_right f r accu) in
fold_right f l accu
let rec fold_left_map f (s : 'a map) accu = match map_prj s with
| MEmpty -> accu, map_inj MEmpty
| MNode {l; v=k; d=v; r; h} -> let accu, l = fold_left_map f l accu in let accu, v = f k v accu in let accu, r = fold_left_map f r accu in
accu, map_inj (MNode {l; v=k; d=v; r; h})
let rec fold_right_map f (s : 'a map) accu = match map_prj s with
| MEmpty -> accu, map_inj MEmpty
| MNode {l; v=k; d=v; r; h} -> let accu, r = fold_right_map f r accu in let accu, v = f k v accu in let accu, l = fold_right_map f l accu in
accu, map_inj (MNode {l; v=k; d=v; r; h})
let height s = match map_prj s with
| MEmpty -> 0
| MNode {h;_} -> h
(* Filter based on a range *) let filter_range in_range m = let rec aux m = function
| MEmpty -> m
| MNode {l; v; d; r; _} -> let vr = in_range v in (* the range is below the current value *) if vr < 0 then aux m (map_prj l) (* the range is above the current value *) elseif vr > 0 then aux m (map_prj r) (* The current value is in the range *) else let m = aux m (map_prj l) in let m = aux m (map_prj r) in
F.add v d m in aux F.empty (map_prj m)
let of_list l = let fold accu (x, v) = F.add x v accu in List.fold_left fold F.empty l
type'a sequenced =
| End
| More of M.t * 'a * 'a F.t * 'a sequenced
let rec seq_cons m rest = match map_prj m with
| MEmpty -> rest
| MNode {l; v; d; r; _ } -> seq_cons l (More (v, d, r, rest))
let rec fold_seq f acc = function
| End -> acc
| More (k, v, m, r) -> f k v @@ fold_seq f (F.fold f m acc) r
let move_to_acc (m, acc) = match map_prj m with
| MEmpty -> assert false
| MNode {l; v; d; r; _ } -> l, More (v, d, r, acc)
let rec symmetric_cons ((lm, la) as l) ((rm, ra) as r) = if lm == rm then la, ra else let lh = height lm in let rh = height rm in if lh == rh then
symmetric_cons (move_to_acc l) (move_to_acc r) elseif lh < rh then
symmetric_cons l (move_to_acc r) else
symmetric_cons (move_to_acc l) r
let symmetric_diff_fold f lm rm acc = let rec aux s acc = match s with
| End, rs -> fold_seq (fun k v -> f k None (Some v)) acc rs
| ls, End -> fold_seq (fun k v -> f k (Some v) None) acc ls
| (More (kl, vl, tl, rl) as ls), (More (kr, vr, tr, rr) as rs) -> let cmp = M.compare kl kr in if cmp == 0 then let rem = aux (symmetric_cons (tl, rl) (tr, rr)) acc in if vl == vr then rem else f kl (Some vl) (Some vr) rem elseif cmp < 0 then
f kl (Some vl) None @@ aux (seq_cons tl rl, rs) acc else
f kr None (Some vr) @@ aux (ls, seq_cons tr rr) acc in aux (symmetric_cons (lm, End) (rm, End)) acc
module Smart = struct
let rec map f (s : 'a map) = match map_prj s with
| MEmpty -> map_inj MEmpty
| MNode {l; v=k; d=v; r; h} -> let l' = map f l in let r' = map f r in let v' = f v in if l == l' && r == r' && v == v' then s else map_inj (MNode {l=l'; v=k; d=v'; r=r'; h})
let rec mapi f (s : 'a map) = match map_prj s with
| MEmpty -> map_inj MEmpty
| MNode {l; v=k; d=v; r; h} -> let l' = mapi f l in let r' = mapi f r in let v' = f k v in if l == l' && r == r' && v == v' then s else map_inj (MNode {l=l'; v=k; d=v'; r=r'; h})
end
module Monad(M : MonadS) = struct
open M
let rec fold_left f s accu = match map_prj s with
| MEmpty -> return accu
| MNode {l; v=k; d=v; r; h} ->
fold_left f l accu >>= fun accu ->
f k v accu >>= fun accu ->
fold_left f r accu
let rec fold_right f s accu = match map_prj s with
| MEmpty -> return accu
| MNode {l; v=k; d=v; r; h} ->
fold_right f r accu >>= fun accu ->
f k v accu >>= fun accu ->
fold_right f l accu
let fold = fold_left
let rec mapi f s = match map_prj s with
| MEmpty -> return (map_inj MEmpty)
| MNode {l; v=k; d=v; r; h} ->
mapi f l >>= fun l ->
mapi f r >>= fun r ->
f k v >>= fun v ->
return (map_inj (MNode {l; v=k; d=v; r; h}))
end
end
module Make(M : Map.OrderedType) = struct
include Map.Make(M)
include MapExt(M) end
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