(**************************************************************************) (* *) (* OCaml *) (* *) (* Simon Cruanes *) (* *) (* Copyright 2017 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. *) (* *) (**************************************************************************) (* Module [Seq]: functional iterators *) type +'a node = | Nil | Cons of 'a * 'a t and 'a t = unit -> 'a node let empty () = Nil let return x () = Cons (x, empty) let cons x next () = Cons (x, next) let singleton x () = Cons (x, empty) let rec append seq1 seq2 () = match seq1() with | Nil -> seq2() | Cons (x, next) -> Cons (x, append next seq2) let rec map f seq () = match seq() with | Nil -> Nil | Cons (x, next) -> Cons (f x, map f next) let rec filter_map f seq () = match seq() with | Nil -> Nil | Cons (x, next) -> match f x with | None -> filter_map f next () | Some y -> Cons (y, filter_map f next) let rec filter f seq () = match seq() with | Nil -> Nil | Cons (x, next) -> if f x then Cons (x, filter f next) else filter f next () let rec filteri_aux f i seq () = match seq() with | Nil -> Nil | Cons (x, next) -> let i' = i + 1 in if f i x then Cons (x, filteri_aux f i' next) else filteri_aux f i' next () let[@inline] filteri f seq () = filteri_aux f 0 seq () let rec concat seq () = match seq () with | Nil -> Nil | Cons (x, next) -> append x (concat next) () let rec flat_map f seq () = match seq () with | Nil -> Nil | Cons (x, next) -> append (f x) (flat_map f next) () let concat_map = flat_map let rec fold_left f acc seq = match seq () with | Nil -> acc | Cons (x, next) -> let acc = f acc x in fold_left f acc next let rec iter f seq = match seq () with | Nil -> () | Cons (x, next) -> f x; iter f next let rec unfold f u () = match f u with | None -> Nil | Some (x, u') -> Cons (x, unfold f u') let is_empty xs = match xs() with | Nil -> true | Cons (_, _) -> false let uncons xs = match xs() with | Cons (x, xs) -> Some (x, xs) | Nil -> None let rec length_aux accu xs = match xs() with | Nil -> accu | Cons (_, xs) -> length_aux (accu + 1) xs let[@inline] length xs = length_aux 0 xs let rec iteri_aux f i xs = match xs() with | Nil -> () | Cons (x, xs) -> f i x; iteri_aux f (i+1) xs let[@inline] iteri f xs = iteri_aux f 0 xs let rec fold_lefti_aux f accu i xs = match xs() with | Nil -> accu | Cons (x, xs) -> let accu = f accu i x in fold_lefti_aux f accu (i+1) xs let[@inline] fold_lefti f accu xs = fold_lefti_aux f accu 0 xs let rec for_all p xs = match xs() with | Nil -> true | Cons (x, xs) -> p x && for_all p xs let rec exists p xs = match xs() with | Nil -> false | Cons (x, xs) -> p x || exists p xs let rec find p xs = match xs() with | Nil -> None | Cons (x, xs) -> if p x then Some x else find p xs let find_index p xs = let rec aux i xs = match xs() with | Nil -> None | Cons (x, xs) -> if p x then Some i else aux (i+1) xs in aux 0 xs let rec find_map f xs = match xs() with | Nil -> None | Cons (x, xs) -> match f x with | None -> find_map f xs | Some _ as result -> result let find_mapi f xs = let rec aux i xs = match xs() with | Nil -> None | Cons (x, xs) -> match f i x with | None -> aux (i+1) xs | Some _ as result -> result in aux 0 xs (* [iter2], [fold_left2], [for_all2], [exists2], [map2], [zip] work also in the case where the two sequences have different lengths. They stop as soon as one sequence is exhausted. Their behavior is slightly asymmetric: when [xs] is empty, they do not force [ys]; however, when [ys] is empty, [xs] is forced, even though the result of the function application [xs()] turns out to be useless. *) let rec iter2 f xs ys = match xs() with | Nil -> () | Cons (x, xs) -> match ys() with | Nil -> () | Cons (y, ys) -> f x y; iter2 f xs ys let rec fold_left2 f accu xs ys = match xs() with | Nil -> accu | Cons (x, xs) -> match ys() with | Nil -> accu | Cons (y, ys) -> let accu = f accu x y in fold_left2 f accu xs ys let rec for_all2 f xs ys = match xs() with | Nil -> true | Cons (x, xs) -> match ys() with | Nil -> true | Cons (y, ys) -> f x y && for_all2 f xs ys let rec exists2 f xs ys = match xs() with | Nil -> false | Cons (x, xs) -> match ys() with | Nil -> false | Cons (y, ys) -> f x y || exists2 f xs ys let rec equal eq xs ys = match xs(), ys() with | Nil, Nil -> true | Cons (x, xs), Cons (y, ys) -> eq x y && equal eq xs ys | Nil, Cons (_, _) | Cons (_, _), Nil -> false let rec compare cmp xs ys = match xs(), ys() with | Nil, Nil -> 0 | Cons (x, xs), Cons (y, ys) -> let c = cmp x y in if c <> 0 then c else compare cmp xs ys | Nil, Cons (_, _) -> -1 | Cons (_, _), Nil -> +1 (* [init_aux f i j] is the sequence [f i, ..., f (j-1)]. *) let rec init_aux f i j () = if i < j then begin Cons (f i, init_aux f (i + 1) j) end else Nil let init n f = if n < 0 then invalid_arg "Seq.init" else init_aux f 0 n let rec repeat x () = Cons (x, repeat x) let rec forever f () = Cons (f(), forever f) (* This preliminary definition of [cycle] requires the sequence [xs] to be nonempty. Applying it to an empty sequence would produce a sequence that diverges when it is forced. *) let rec cycle_nonempty xs () = append xs (cycle_nonempty xs) () (* [cycle xs] checks whether [xs] is empty and, if so, returns an empty sequence. Otherwise, [cycle xs] produces one copy of [xs] followed with the infinite sequence [cycle_nonempty xs]. Thus, the nonemptiness check is performed just once. *) let cycle xs () = match xs() with | Nil -> Nil | Cons (x, xs') -> Cons (x, append xs' (cycle_nonempty xs)) (* [iterate1 f x] is the sequence [f x, f (f x), ...]. It is equivalent to [tail (iterate f x)]. [iterate1] is used as a building block in the definition of [iterate]. *) let rec iterate1 f x () = let y = f x in Cons (y, iterate1 f y) (* [iterate f x] is the sequence [x, f x, ...]. *) (* The reason why we give this slightly indirect definition of [iterate], as opposed to the more naive definition that may come to mind, is that we are careful to avoid evaluating [f x] until this function call is actually necessary. The naive definition (not shown here) computes the second argument of the sequence, [f x], when the first argument is requested by the user. *) let iterate f x = cons x (iterate1 f x) let rec mapi_aux f i xs () = match xs() with | Nil -> Nil | Cons (x, xs) -> Cons (f i x, mapi_aux f (i+1) xs) let[@inline] mapi f xs = mapi_aux f 0 xs (* [tail_scan f s xs] is equivalent to [tail (scan f s xs)]. [tail_scan] is used as a building block in the definition of [scan]. *) (* This slightly indirect definition of [scan] is meant to avoid computing elements too early; see the above comment about [iterate1] and [iterate]. *) let rec tail_scan f s xs () = match xs() with | Nil -> Nil | Cons (x, xs) -> let s = f s x in Cons (s, tail_scan f s xs) let scan f s xs = cons s (tail_scan f s xs) (* [take] is defined in such a way that [take 0 xs] returns [empty] immediately, without allocating any memory. *) let rec take_aux n xs = if n = 0 then empty else fun () -> match xs() with | Nil -> Nil | Cons (x, xs) -> Cons (x, take_aux (n-1) xs) let take n xs = if n < 0 then invalid_arg "Seq.take"; take_aux n xs (* [force_drop n xs] is equivalent to [drop n xs ()]. [force_drop n xs] requires [n > 0]. [force_drop] is used as a building block in the definition of [drop]. *) let rec force_drop n xs = match xs() with | Nil -> Nil | Cons (_, xs) -> let n = n - 1 in if n = 0 then xs() else force_drop n xs (* [drop] is defined in such a way that [drop 0 xs] returns [xs] immediately, without allocating any memory. *) let drop n xs = if n < 0 then invalid_arg "Seq.drop" else if n = 0 then xs else fun () -> force_drop n xs let rec take_while p xs () = match xs() with | Nil -> Nil | Cons (x, xs) -> if p x then Cons (x, take_while p xs) else Nil let rec drop_while p xs () = match xs() with | Nil -> Nil | Cons (x, xs) as node -> if p x then drop_while p xs () else node let rec group eq xs () = match xs() with | Nil -> Nil | Cons (x, xs) -> Cons (cons x (take_while (eq x) xs), group eq (drop_while (eq x) xs)) exception Forced_twice module Suspension = struct type 'a suspension = unit -> 'a (* Conversions. *) let to_lazy : 'a suspension -> 'a Lazy.t = Lazy.from_fun (* fun s -> lazy (s()) *) let from_lazy (s : 'a Lazy.t) : 'a suspension = fun () -> Lazy.force s (* [memoize] turns an arbitrary suspension into a persistent suspension. *) let memoize (s : 'a suspension) : 'a suspension = from_lazy (to_lazy s) (* [failure] is a suspension that fails when forced. *) let failure : _ suspension = fun () -> (* A suspension created by [once] has been forced twice. *) raise Forced_twice (* If [f] is a suspension, then [once f] is a suspension that can be forced at most once. If it is forced more than once, then [Forced_twice] is raised. *) let once (f : 'a suspension) : 'a suspension = let action = Atomic.make f in fun () -> (* Get the function currently stored in [action], and write the function [failure] in its place, so the next access will result in a call to [failure()]. *) let f = Atomic.exchange action failure in f() end (* Suspension *) let rec memoize xs = Suspension.memoize (fun () -> match xs() with | Nil -> Nil | Cons (x, xs) -> Cons (x, memoize xs) ) let rec once xs = Suspension.once (fun () -> match xs() with | Nil -> Nil | Cons (x, xs) -> Cons (x, once xs) ) let rec zip xs ys () = match xs() with | Nil -> Nil | Cons (x, xs) -> match ys() with | Nil -> Nil | Cons (y, ys) -> Cons ((x, y), zip xs ys) let rec map2 f xs ys () = match xs() with | Nil -> Nil | Cons (x, xs) -> match ys() with | Nil -> Nil | Cons (y, ys) -> Cons (f x y, map2 f xs ys) let rec interleave xs ys () = match xs() with | Nil -> ys() | Cons (x, xs) -> Cons (x, interleave ys xs) (* [sorted_merge1l cmp x xs ys] is equivalent to [sorted_merge cmp (cons x xs) ys]. [sorted_merge1r cmp xs y ys] is equivalent to [sorted_merge cmp xs (cons y ys)]. [sorted_merge1 cmp x xs y ys] is equivalent to [sorted_merge cmp (cons x xs) (cons y ys)]. These three functions are used as building blocks in the definition of [sorted_merge]. *) let rec sorted_merge1l cmp x xs ys () = match ys() with | Nil -> Cons (x, xs) | Cons (y, ys) -> sorted_merge1 cmp x xs y ys and sorted_merge1r cmp xs y ys () = match xs() with | Nil -> Cons (y, ys) | Cons (x, xs) -> sorted_merge1 cmp x xs y ys and sorted_merge1 cmp x xs y ys = if cmp x y <= 0 then Cons (x, sorted_merge1r cmp xs y ys) else Cons (y, sorted_merge1l cmp x xs ys) let sorted_merge cmp xs ys () = match xs(), ys() with | Nil, Nil -> Nil | Nil, c | c, Nil -> c | Cons (x, xs), Cons (y, ys) -> sorted_merge1 cmp x xs y ys let rec map_fst xys () = match xys() with | Nil -> Nil | Cons ((x, _), xys) -> Cons (x, map_fst xys) let rec map_snd xys () = match xys() with | Nil -> Nil | Cons ((_, y), xys) -> Cons (y, map_snd xys) let unzip xys = map_fst xys, map_snd xys let split = unzip (* [filter_map_find_left_map f xs] is equivalent to [filter_map Either.find_left (map f xs)]. *) let rec filter_map_find_left_map f xs () = match xs() with | Nil -> Nil | Cons (x, xs) -> match f x with | Either.Left y -> Cons (y, filter_map_find_left_map f xs) | Either.Right _ -> filter_map_find_left_map f xs () let rec filter_map_find_right_map f xs () = match xs() with | Nil -> Nil | Cons (x, xs) -> match f x with | Either.Left _ -> filter_map_find_right_map f xs () | Either.Right z -> Cons (z, filter_map_find_right_map f xs) let partition_map f xs = filter_map_find_left_map f xs, filter_map_find_right_map f xs let partition p xs = filter p xs, filter (fun x -> not (p x)) xs (* If [xss] is a matrix (a sequence of rows), then [peel xss] is a pair of the first column (a sequence of elements) and of the remainder of the matrix (a sequence of shorter rows). These two sequences have the same length. The rows of the matrix [xss] are not required to have the same length. An empty row is ignored. *) (* Because [peel] uses [unzip], its argument must be persistent. The same remark applies to [transpose], [diagonals], [product], etc. *) let peel xss = unzip (filter_map uncons xss) let rec transpose xss () = let heads, tails = peel xss in if is_empty heads then begin assert (is_empty tails); Nil end else Cons (heads, transpose tails) (* The internal function [diagonals] takes an extra argument, [remainders], which contains the remainders of the rows that have already been discovered. *) let rec diagonals remainders xss () = match xss() with | Cons (xs, xss) -> begin match xs() with | Cons (x, xs) -> (* We discover a new nonempty row [x :: xs]. Thus, the next diagonal is [x :: heads]: this diagonal begins with [x] and continues with the first element of every row in [remainders]. In the recursive call, the argument [remainders] is instantiated with [xs :: tails], which means that we have one more remaining row, [xs], and that we keep the tails of the pre-existing remaining rows. *) let heads, tails = peel remainders in Cons (cons x heads, diagonals (cons xs tails) xss) | Nil -> (* We discover a new empty row. In this case, the new diagonal is just [heads], and [remainders] is instantiated with just [tails], as we do not have one more remaining row. *) let heads, tails = peel remainders in Cons (heads, diagonals tails xss) end | Nil -> (* There are no more rows to be discovered. There remains to exhaust the remaining rows. *) transpose remainders () (* If [xss] is a matrix (a sequence of rows), then [diagonals xss] is the sequence of its diagonals. The first diagonal contains just the first element of the first row. The second diagonal contains the first element of the second row and the second element of the first row; and so on. This kind of diagonal is in fact sometimes known as an antidiagonal. - Every diagonal is a finite sequence. - The rows of the matrix [xss] are not required to have the same length. - The matrix [xss] is not required to be finite (in either direction). - The matrix [xss] must be persistent. *) let diagonals xss = diagonals empty xss let map_product f xs ys = concat (diagonals ( map (fun x -> map (fun y -> f x y ) ys ) xs )) let product xs ys = map_product (fun x y -> (x, y)) xs ys let of_dispenser it = let rec c () = match it() with | None -> Nil | Some x -> Cons (x, c) in c let to_dispenser xs = let s = ref xs in fun () -> match (!s)() with | Nil -> None | Cons (x, xs) -> s := xs; Some x let rec ints i () = Cons (i, ints (i + 1))