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core_list.ml
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module List = StdLabels.List
module String = StdLabels.String
open Typerep_lib.Std
open Sexplib.Std
open Bin_prot.Std
module Random = Core_random
let invalid_argf = Core_printf.invalid_argf
module T = struct
type 'a t = 'a list with sexp, bin_io, typerep
end
include T
let of_list t = t
let range ?(stride=1) ?(start=`inclusive) ?(stop=`exclusive) start_i stop_i =
if stride = 0 then
invalid_arg "Core_list.range: stride must be non-zero";
(* Generate the range from the last element, so that we do not need to rev it *)
let rec loop last counter accum =
if counter <= 0 then accum
else loop (last - stride) (counter - 1) (last :: accum)
in
let stride_sign = if stride > 0 then 1 else -1 in
let start =
match start with
| `inclusive -> start_i
| `exclusive -> start_i + stride
in
let stop =
match stop with
| `inclusive -> stop_i + stride_sign
| `exclusive -> stop_i
in
let num_elts = (stop - start + stride - stride_sign) / stride in
loop (start + (stride * (num_elts - 1))) num_elts []
;;
TEST_MODULE "range symmetries" = struct
let basic ~stride ~start ~stop ~start_n ~stop_n ~result =
range ~stride ~start ~stop start_n stop_n = result
let test stride (start_n, start) (stop_n, stop) result =
basic ~stride ~start ~stop ~start_n ~stop_n ~result
&& (* works for negative [start] and [stop] *)
basic ~stride:(-stride)
~start_n:(-start_n)
~stop_n:(-stop_n)
~start
~stop
~result:(List.map result ~f:(fun x -> -x))
TEST = test 1 ( 3, `inclusive) ( 1, `exclusive) []
TEST = test 1 ( 3, `inclusive) ( 3, `exclusive) []
TEST = test 1 ( 3, `inclusive) ( 4, `exclusive) [3]
TEST = test 1 ( 3, `inclusive) ( 8, `exclusive) [3;4;5;6;7]
TEST = test 3 ( 4, `inclusive) (10, `exclusive) [4;7]
TEST = test 3 ( 4, `inclusive) (11, `exclusive) [4;7;10]
TEST = test 3 ( 4, `inclusive) (12, `exclusive) [4;7;10]
TEST = test 3 ( 4, `inclusive) (13, `exclusive) [4;7;10]
TEST = test 3 ( 4, `inclusive) (14, `exclusive) [4;7;10;13]
TEST = test (-1) ( 1, `inclusive) ( 3, `exclusive) []
TEST = test (-1) ( 3, `inclusive) ( 3, `exclusive) []
TEST = test (-1) ( 4, `inclusive) ( 3, `exclusive) [4]
TEST = test (-1) ( 8, `inclusive) ( 3, `exclusive) [8;7;6;5;4]
TEST = test (-3) (10, `inclusive) ( 4, `exclusive) [10;7]
TEST = test (-3) (10, `inclusive) ( 3, `exclusive) [10;7;4]
TEST = test (-3) (10, `inclusive) ( 2, `exclusive) [10;7;4]
TEST = test (-3) (10, `inclusive) ( 1, `exclusive) [10;7;4]
TEST = test (-3) (10, `inclusive) ( 0, `exclusive) [10;7;4;1]
TEST = test 1 ( 3, `exclusive) ( 1, `exclusive) []
TEST = test 1 ( 3, `exclusive) ( 3, `exclusive) []
TEST = test 1 ( 3, `exclusive) ( 4, `exclusive) []
TEST = test 1 ( 3, `exclusive) ( 8, `exclusive) [4;5;6;7]
TEST = test 3 ( 4, `exclusive) (10, `exclusive) [7]
TEST = test 3 ( 4, `exclusive) (11, `exclusive) [7;10]
TEST = test 3 ( 4, `exclusive) (12, `exclusive) [7;10]
TEST = test 3 ( 4, `exclusive) (13, `exclusive) [7;10]
TEST = test 3 ( 4, `exclusive) (14, `exclusive) [7;10;13]
TEST = test (-1) ( 1, `exclusive) ( 3, `exclusive) []
TEST = test (-1) ( 3, `exclusive) ( 3, `exclusive) []
TEST = test (-1) ( 4, `exclusive) ( 3, `exclusive) []
TEST = test (-1) ( 8, `exclusive) ( 3, `exclusive) [7;6;5;4]
TEST = test (-3) (10, `exclusive) ( 4, `exclusive) [7]
TEST = test (-3) (10, `exclusive) ( 3, `exclusive) [7;4]
TEST = test (-3) (10, `exclusive) ( 2, `exclusive) [7;4]
TEST = test (-3) (10, `exclusive) ( 1, `exclusive) [7;4]
TEST = test (-3) (10, `exclusive) ( 0, `exclusive) [7;4;1]
TEST = test 1 ( 3, `inclusive) ( 1, `inclusive) []
TEST = test 1 ( 3, `inclusive) ( 3, `inclusive) [3]
TEST = test 1 ( 3, `inclusive) ( 4, `inclusive) [3;4]
TEST = test 1 ( 3, `inclusive) ( 8, `inclusive) [3;4;5;6;7;8]
TEST = test 3 ( 4, `inclusive) (10, `inclusive) [4;7;10]
TEST = test 3 ( 4, `inclusive) (11, `inclusive) [4;7;10]
TEST = test 3 ( 4, `inclusive) (12, `inclusive) [4;7;10]
TEST = test 3 ( 4, `inclusive) (13, `inclusive) [4;7;10;13]
TEST = test 3 ( 4, `inclusive) (14, `inclusive) [4;7;10;13]
TEST = test (-1) ( 1, `inclusive) ( 3, `inclusive) []
TEST = test (-1) ( 3, `inclusive) ( 3, `inclusive) [3]
TEST = test (-1) ( 4, `inclusive) ( 3, `inclusive) [4;3]
TEST = test (-1) ( 8, `inclusive) ( 3, `inclusive) [8;7;6;5;4;3]
TEST = test (-3) (10, `inclusive) ( 4, `inclusive) [10;7;4]
TEST = test (-3) (10, `inclusive) ( 3, `inclusive) [10;7;4]
TEST = test (-3) (10, `inclusive) ( 2, `inclusive) [10;7;4]
TEST = test (-3) (10, `inclusive) ( 1, `inclusive) [10;7;4;1]
TEST = test (-3) (10, `inclusive) ( 0, `inclusive) [10;7;4;1]
TEST = test 1 ( 3, `exclusive) ( 1, `inclusive) []
TEST = test 1 ( 3, `exclusive) ( 3, `inclusive) []
TEST = test 1 ( 3, `exclusive) ( 4, `inclusive) [4]
TEST = test 1 ( 3, `exclusive) ( 8, `inclusive) [4;5;6;7;8]
TEST = test 3 ( 4, `exclusive) (10, `inclusive) [7;10]
TEST = test 3 ( 4, `exclusive) (11, `inclusive) [7;10]
TEST = test 3 ( 4, `exclusive) (12, `inclusive) [7;10]
TEST = test 3 ( 4, `exclusive) (13, `inclusive) [7;10;13]
TEST = test 3 ( 4, `exclusive) (14, `inclusive) [7;10;13]
TEST = test (-1) ( 1, `exclusive) ( 3, `inclusive) []
TEST = test (-1) ( 3, `exclusive) ( 3, `inclusive) []
TEST = test (-1) ( 4, `exclusive) ( 3, `inclusive) [3]
TEST = test (-1) ( 8, `exclusive) ( 3, `inclusive) [7;6;5;4;3]
TEST = test (-3) (10, `exclusive) ( 4, `inclusive) [7;4]
TEST = test (-3) (10, `exclusive) ( 3, `inclusive) [7;4]
TEST = test (-3) (10, `exclusive) ( 2, `inclusive) [7;4]
TEST = test (-3) (10, `exclusive) ( 1, `inclusive) [7;4;1]
TEST = test (-3) (10, `exclusive) ( 0, `inclusive) [7;4;1]
let test_start_inc_exc stride start (stop, stop_inc_exc) result =
test stride (start, `inclusive) (stop, stop_inc_exc) result
&& begin
match result with
| [] -> true
| head :: tail ->
head = start && test stride (start, `exclusive) (stop, stop_inc_exc) tail
end
let test_inc_exc stride start stop result =
test_start_inc_exc stride start (stop, `inclusive) result
&& begin
match List.rev result with
| [] -> true
| last :: all_but_last ->
let all_but_last = List.rev all_but_last in
if last = stop then
test_start_inc_exc stride start (stop, `exclusive) all_but_last
else
true
end
TEST = test_inc_exc 1 4 10 [4;5;6;7;8;9;10]
TEST = test_inc_exc 3 4 10 [4;7;10]
TEST = test_inc_exc 3 4 11 [4;7;10]
TEST = test_inc_exc 3 4 12 [4;7;10]
TEST = test_inc_exc 3 4 13 [4;7;10;13]
TEST = test_inc_exc 3 4 14 [4;7;10;13]
end
module Test_values = struct
let long1 =
let v = lazy (range 1 100_000) in
fun () -> Lazy.force v
let l1 = [1;2;3;4;5;6;7;8;9;10]
end
(* Standard functions *)
let length = List.length
let hd_exn = List.hd
let tl_exn = List.tl
let hd t =
match t with
| [] -> None
| x :: _ -> Some x
;;
let tl t =
match t with
| [] -> None
| _ :: t' -> Some t'
;;
let nth t n =
if n < 0 then None else
let rec nth_aux t n =
match t with
| [] -> None
| a :: t -> if n = 0 then Some a else nth_aux t (n-1)
in nth_aux t n
;;
let nth_exn t n =
match nth t n with
| None ->
invalid_argf "List.nth_exn %d called on list of length %d"
n (length t) ()
| Some a -> a
;;
let rev_append = List.rev_append
TEST = rev_append [1;2;3] [4;5;6] = [3;2;1;4;5;6]
TEST = rev_append [] [4;5;6] = [4;5;6]
TEST = rev_append [1;2;3] [] = [3;2;1]
TEST = rev_append [1] [2;3] = [1;2;3]
TEST = rev_append [1;2] [3] = [2;1;3]
TEST =
let long = Test_values.long1 () in
ignore (rev_append long long:int list);
true
let rev = function
| [] | [_] as res -> res
| x :: y :: rest -> rev_append rest [y; x]
let unordered_append l1 l2 =
match l1, l2 with
| [], l | l, [] -> l
| _ -> List.rev_append l1 l2
let rev_map t ~f = List.rev_map t ~f
exception Length_mismatch of string * int * int with sexp
let check_length2 name l1 l2 =
let n1 = length l1 in
let n2 = length l2 in
if n1 <> n2 then
raise (invalid_argf "length mismatch in %s: %d <> %d " name n1 n2 ())
;;
let check_length3 name l1 l2 l3 =
let n1 = length l1 in
let n2 = length l2 in
let n3 = length l3 in
if n1 <> n2 || n2 <> n3 then
raise (invalid_argf "length mismatch in %s: %d <> %d || %d <> %d"
name n1 n2 n2 n3 ())
;;
let iter2_exn l1 l2 ~f =
check_length2 "iter2_exn" l1 l2;
List.iter2 l1 l2 ~f;
;;
let rev_map2_exn l1 l2 ~f =
check_length2 "rev_map2_exn" l1 l2;
List.rev_map2 l1 l2 ~f;
;;
let fold2_exn l1 l2 ~init ~f =
check_length2 "fold2_exn" l1 l2;
List.fold_left2 l1 l2 ~init ~f;
;;
let for_all2_exn l1 l2 ~f =
check_length2 "for_all2_exn" l1 l2;
List.for_all2 l1 l2 ~f;
;;
TEST = for_all2_exn [] [] ~f:(fun _ _ -> assert false)
let exists2_exn l1 l2 ~f =
check_length2 "exists2_exn" l1 l2;
List.exists2 l1 l2 ~f;
;;
let mem ?(equal = (=)) t a = List.exists t ~f:(equal a)
(* This is a copy of the code from the standard library, with an extra eta-expansion to
avoid creating partial closures (showed up for List.filter in profiling). *)
let rev_filter t ~f =
let rec find ~f accu = function
| [] -> accu
| x :: l -> if f x then find ~f (x :: accu) l else find ~f accu l
in
find ~f [] t
;;
let filter t ~f = rev (rev_filter t ~f)
let sort = List.sort
let stable_sort = List.stable_sort
let find_map t ~f =
let rec loop = function
| [] -> None
| x :: l ->
match f x with
| None -> loop l
| Some _ as r -> r
in
loop t
;;
let find t ~f =
let rec loop = function
| [] -> None
| x :: l -> if f x then Some x else loop l
in
loop t
;;
let find_exn t ~f = List.find t ~f
let findi t ~f =
let rec loop i t =
match t with
| [] -> None
| x :: l -> if f i x then Some (i, x) else loop (i + 1) l
in
loop 0 t
;;
(** changing the order of arguments on some standard [List] functions. *)
let exists t ~f = List.exists t ~f
let for_all t ~f = List.for_all t ~f
let iter t ~f = List.iter t ~f
(** For the container interface. *)
let fold t ~init ~f = List.fold_left t ~f ~init
let fold_left = fold
let to_array = Caml.Array.of_list
let to_list t = t
(** Tail recursive versions of standard [List] module *)
let slow_append l1 l2 = List.rev_append (List.rev l1) l2
(* There are a few optimized list operations here, including append and map. There are
basically two optimizations in play: loop unrolling, and dynamic switching between
stack and heap allocation.
The loop-unrolling is straightforward, we just unroll 5 levels of the loop. This makes
each iteration faster, and also reduces the number of stack frames consumed per list
element.
The dynamic switching is done by counting the number of stack frames, and then
switching to the "slow" implementation when we exceed a given limit. This means that
short lists use the fast stack-allocation method, and long lists use a slower one that
doesn't require stack space.
*)
let rec count_append l1 l2 count =
match l2 with
| [] -> l1
| _ ->
match l1 with
| [] -> l2
| [x1] -> x1 :: l2
| [x1; x2] -> x1 :: x2 :: l2
| [x1; x2; x3] -> x1 :: x2 :: x3 :: l2
| [x1; x2; x3; x4] -> x1 :: x2 :: x3 :: x4 :: l2
| x1 :: x2 :: x3 :: x4 :: x5 :: tl ->
x1 :: x2 :: x3 :: x4 :: x5 ::
(if count > 1000
then slow_append tl l2
else count_append tl l2 (count + 1))
let append l1 l2 = count_append l1 l2 0
TEST = append [1;2;3] [4;5;6] = [1;2;3;4;5;6]
TEST = append [] [4;5;6] = [4;5;6]
TEST = append [1;2;3] [] = [1;2;3]
TEST = append [1] [2;3] = [1;2;3]
TEST = append [1;2] [3] = [1;2;3]
TEST_UNIT =
let long = Test_values.long1 () in
ignore (append long long:int list)
let map_slow l ~f = List.rev (List.rev_map ~f l)
let rec count_map ~f l ctr =
match l with
| [] -> []
| [x1] ->
let f1 = f x1 in
[f1]
| [x1; x2] ->
let f1 = f x1 in
let f2 = f x2 in
[f1; f2]
| [x1; x2; x3] ->
let f1 = f x1 in
let f2 = f x2 in
let f3 = f x3 in
[f1; f2; f3]
| [x1; x2; x3; x4] ->
let f1 = f x1 in
let f2 = f x2 in
let f3 = f x3 in
let f4 = f x4 in
[f1; f2; f3; f4]
| x1 :: x2 :: x3 :: x4 :: x5 :: tl ->
let f1 = f x1 in
let f2 = f x2 in
let f3 = f x3 in
let f4 = f x4 in
let f5 = f x5 in
f1 :: f2 :: f3 :: f4 :: f5 ::
(if ctr > 1000
then map_slow ~f tl
else count_map ~f tl (ctr + 1))
let map l ~f = count_map ~f l 0
TEST = map ~f:(fun x -> x) Test_values.l1 = Test_values.l1
TEST = map ~f:(fun x -> x) [] = []
TEST = map ~f:(fun x -> x +. 5.) [1.;2.;3.] = [6.;7.;8.]
TEST_UNIT =
ignore (map ~f:(fun x -> x) (Test_values.long1 ()):int list)
let (>>|) l f = map l ~f
let map2_exn l1 l2 ~f = List.rev (rev_map2_exn l1 l2 ~f)
TEST = map2_exn ~f:(fun a b -> a, b) [1;2;3] ['a';'b';'c']
= [(1,'a'); (2,'b'); (3,'c')]
TEST = map2_exn ~f:(fun _ _ -> ()) [] [] = []
TEST_UNIT =
let long = Test_values.long1 () in
ignore (map2_exn ~f:(fun _ _ -> ()) long long:unit list)
let rev_map3_exn l1 l2 l3 ~f =
check_length3 "rev_map3" l1 l2 l3;
let rec loop l1 l2 l3 ac =
match (l1, l2, l3) with
| ([], [], []) -> ac
| (x1 :: l1, x2 :: l2, x3 :: l3) -> loop l1 l2 l3 (f x1 x2 x3 :: ac)
| _ -> assert false
in
loop l1 l2 l3 []
;;
let map3_exn l1 l2 l3 ~f = List.rev (rev_map3_exn l1 l2 l3 ~f)
let rec rev_map_append l1 l2 ~f =
match l1 with
| [] -> l2
| h :: t -> rev_map_append ~f t (f h :: l2)
TEST = rev_map_append [1;2;3;4;5] [6] ~f:(fun x -> x) = [5;4;3;2;1;6]
TEST = rev_map_append [1;2;3;4;5] [6] ~f:(fun x -> 2 * x) = [10;8;6;4;2;6]
TEST = rev_map_append [] [6] ~f:(fun _ -> failwith "bug!") = [6]
let fold_right l ~f ~init =
fold ~f:(fun a b -> f b a) ~init (List.rev l)
TEST = fold_right ~f:(fun e acc -> e :: acc) Test_values.l1 ~init:[] =
Test_values.l1
TEST = fold_right ~f:(fun e acc -> e ^ acc) ["1";"2"] ~init:"3" = "123"
TEST = fold_right ~f:(fun _ _ -> ()) [] ~init:() = ()
TEST_UNIT =
let long = Test_values.long1 () in
ignore (fold_right ~f:(fun e acc -> e :: acc) long ~init:[])
let unzip list =
let rec loop list l1 l2 =
match list with
| [] -> (List.rev l1, List.rev l2)
| (x, y) :: tl -> loop tl (x :: l1) (y :: l2)
in
loop list [] []
let zip_exn l1 l2 = map2_exn ~f:(fun a b -> (a, b)) l1 l2
TEST =
let l1 = Test_values.l1 in
unzip (zip_exn l1 (List.rev l1)) = (l1, List.rev l1)
;;
TEST_UNIT =
let long = Test_values.long1 () in
ignore (unzip (zip_exn long long))
;;
let zip l1 l2 = try Some (zip_exn l1 l2) with _ -> None
TEST = zip [1;2;3] [4;5;6] = Some [1,4;2,5;3,6]
TEST = zip [1] [4;5;6] = None
(** Additional list operations *)
let rev_mapi l ~f =
let rec loop i acc = function
| [] -> acc
| h :: t -> loop (i + 1) (f i h :: acc) t
in
loop 0 [] l
let mapi l ~f = List.rev (rev_mapi l ~f)
TEST = mapi ~f:(fun i x -> (i,x))
["one";"two";"three";"four"] = [0,"one";1,"two";2,"three";3,"four"]
TEST = mapi ~f:(fun i x -> (i,x)) [] = []
let iteri l ~f =
ignore (fold l ~init:0 ~f:(fun i x -> f i x; i + 1));
;;
let foldi t ~f ~init =
snd (fold t ~init:(0, init) ~f:(fun (i, acc) v -> (i + 1, f i acc v)))
;;
let filteri l ~f =
List.rev (foldi l
~f:(fun pos acc x ->
if f pos x then x :: acc else acc)
~init:[])
let reduce l ~f = match l with
| [] -> None
| hd :: tl -> Some (fold ~init:hd ~f tl)
let reduce_exn l ~f =
match reduce l ~f with
| None -> raise (Invalid_argument "List.reduce_exn")
| Some v -> v
let groupi l ~break =
let groups =
foldi l ~init:[] ~f:(fun i acc x ->
match acc with
| [] -> [[x]]
| current_group :: tl ->
if break i (hd_exn current_group) x then
[x] :: current_group :: tl (* start new group *)
else
(x :: current_group) :: tl) (* extend current group *)
in
match groups with
| [] -> []
| l -> rev_map l ~f:rev
let group l ~break = groupi l ~break:(fun _ x y -> break x y)
TEST_MODULE "group" = struct
TEST = (group [1;2;3;4] ~break:(fun _ x -> x = 3) = [[1;2];[3;4]])
TEST = (group [] ~break:(fun _ -> assert false)) = []
let mis = ['M';'i';'s';'s';'i';'s';'s';'i';'p';'p';'i']
let equal_letters =
[['M'];['i'];['s';'s'];['i'];['s';'s'];['i'];['p';'p'];['i']]
let single_letters =
[['M';'i';'s';'s';'i';'s';'s';'i';'p';'p';'i']]
let every_three =
[['M'; 'i'; 's']; ['s'; 'i'; 's']; ['s'; 'i'; 'p']; ['p'; 'i' ]]
TEST = (group ~break:(<>) mis) = equal_letters
TEST = (group ~break:(fun _ _ -> false) mis) = single_letters
TEST = (groupi ~break:(fun i _ _ -> i mod 3 = 0) mis) = every_three
end
let concat_map l ~f =
let rec aux acc = function
| [] -> List.rev acc
| hd :: tl -> aux (rev_append (f hd) acc) tl
in
aux [] l
let concat_mapi l ~f =
let rec aux cont acc = function
| [] -> List.rev acc
| hd :: tl -> aux (cont + 1) (rev_append (f cont hd) acc) tl
in
aux 0 [] l
let merge l1 l2 ~cmp =
let rec loop acc l1 l2 =
match l1,l2 with
| [], l2 -> rev_append acc l2
| l1, [] -> rev_append acc l1
| h1 :: t1, h2 :: t2 ->
if cmp h1 h2 <= 0
then loop (h1 :: acc) t1 l2
else loop (h2 :: acc) l1 t2
in
loop [] l1 l2
;;
include struct
(* We are explicit about what we import from the general Monad functor so that
* we don't accidentally rebind more efficient list-specific functions.
*)
module Monad = Monad.Make (struct
type 'a t = 'a list
let bind x f = concat_map x ~f
let map = `Custom map
let return x = [x]
end)
open Monad
module Monad_infix = Monad_infix
let ignore = ignore
let join = join
let bind = bind
let (>>=) = bind
let return = return
let all = all
let all_ignore = all_ignore
end
(** returns final element of list *)
let rec last_exn list = match list with
| [x] -> x
| _ :: tl -> last_exn tl
| [] -> raise (Invalid_argument "Core_list.last")
TEST = last_exn [1;2;3] = 3
TEST = last_exn [1] = 1
TEST = last_exn (Test_values.long1 ()) = 99_999
(** optionally returns final element of list *)
let rec last list = match list with
| [x] -> Some x
| _ :: tl -> last tl
| [] -> None
let find_consecutive_duplicate t ~equal =
match t with
| [] -> None
| a1 :: t ->
let rec loop a1 t =
match t with
| [] -> None
| a2 :: t -> if equal a1 a2 then Some (a1, a2) else loop a2 t
in
loop a1 t
;;
TEST_UNIT =
List.iter ~f:(fun (t, expect) ->
assert (Poly.equal expect (find_consecutive_duplicate t ~equal:Poly.equal)))
[ [] , None
; [ 1 ] , None
; [ 1; 1 ] , Some (1, 1)
; [ 1; 2 ] , None
; [ 1; 2; 1 ] , None
; [ 1; 2; 2 ] , Some (2, 2)
; [ 1; 1; 2; 2 ], Some (1, 1)
]
;;
TEST = find_consecutive_duplicate [(0,'a');(1,'b');(2,'b')]
~equal:(fun (_, a) (_, b) -> Pervasives.(=) a b) = Some ((1, 'b'), (2, 'b'))
;;
(* returns list without adjacent duplicates *)
let remove_consecutive_duplicates list ~equal =
let rec loop list accum = match list with
| [] -> accum
| hd :: [] -> hd :: accum
| hd1 :: hd2 :: tl ->
if equal hd1 hd2
then loop (hd2 :: tl) accum
else loop (hd2 :: tl) (hd1 :: accum)
in
rev (loop list [])
TEST = remove_consecutive_duplicates ~equal:Pervasives.(=) [] = []
TEST = remove_consecutive_duplicates ~equal:Pervasives.(=) [5;5;5;5;5] = [5]
TEST = remove_consecutive_duplicates ~equal:Pervasives.(=) [5;6;5;6;5;6] = [5;6;5;6;5;6]
TEST = remove_consecutive_duplicates ~equal:Pervasives.(=) [5;5;6;6;5;5;8;8] = [5;6;5;8]
TEST = length (remove_consecutive_duplicates [(0,1);(0,2);(2,2);(4,1)]
~equal:(fun (a,_) (b,_) -> Pervasives.(=) a b)) = 3
TEST = length (remove_consecutive_duplicates [(0,1);(2,2);(0,2);(4,1)]
~equal:(fun (a,_) (b,_) -> Pervasives.(=) a b)) = 4
TEST = length (remove_consecutive_duplicates [(0,1);(2,1);(0,2);(4,2)]
~equal:(fun (_,a) (_,b) -> Pervasives.(=) a b)) = 2
TEST = length (remove_consecutive_duplicates [(0,1);(2,2);(0,2);(4,1)]
~equal:(fun (_,a) (_,b) -> Pervasives.(=) a b)) = 3
(** returns sorted version of list with duplicates removed *)
let dedup ?(compare=Pervasives.compare) list =
match list with
| [] -> [] (* performance hack *)
| _ ->
let equal x x' = compare x x' = 0 in
let sorted = List.sort ~cmp:compare list in
remove_consecutive_duplicates ~equal sorted
TEST = dedup [] = []
TEST = dedup [5;5;5;5;5] = [5]
TEST = length (dedup [2;1;5;3;4]) = 5
TEST = length (dedup [2;3;5;3;4]) = 4
TEST = length (dedup [(0,1);(2,2);(0,2);(4,1)] ~compare:(fun (a,_) (b,_) ->
Pervasives.compare a b)) = 3
TEST = length (dedup [(0,1);(2,2);(0,2);(4,1)] ~compare:(fun (_,a) (_,b) ->
Pervasives.compare a b)) = 2
let contains_dup ?compare lst = length (dedup ?compare lst) <> length lst
let find_a_dup ?(compare=Pervasives.compare) l =
let sorted = List.sort ~cmp:compare l in
let rec loop l = match l with
[] | [_] -> None
| hd1 :: hd2 :: tl ->
if compare hd1 hd2 = 0 then Some (hd1) else loop (hd2 :: tl)
in
loop sorted
TEST = find_a_dup [] = None
TEST = find_a_dup [3] = None
TEST = find_a_dup [3;4] = None
TEST = find_a_dup [3;3] = Some 3
TEST = find_a_dup [3;5;4;6;12] = None
TEST = find_a_dup [3;5;4;5;12] = Some 5
TEST = find_a_dup [3;5;12;5;12] = Some 5
TEST = find_a_dup [(0,1);(2,2);(0,2);(4,1)] = None
TEST = (find_a_dup [(0,1);(2,2);(0,2);(4,1)]
~compare:(fun (_,a) (_,b) -> Pervasives.compare a b)) <> None
TEST = let dup = find_a_dup [(0,1);(2,2);(0,2);(4,1)]
~compare:(fun (a,_) (b,_) -> Pervasives.compare a b)
in
match dup with
| Some (0, _) -> true
| _ -> false
type sexp_thunk = unit -> Sexplib.Sexp.t
let sexp_of_sexp_thunk x = x ()
exception Duplicate_found of sexp_thunk * string with sexp
let exn_if_dup ?compare ?(context="exn_if_dup") t ~to_sexp =
match find_a_dup ?compare t with
| None -> ()
| Some dup ->
raise (Duplicate_found ((fun () -> to_sexp dup),context))
let count t ~f = Container.fold_count fold t ~f
let sum m t ~f = Container.fold_sum m fold t ~f
let min_elt t ~cmp = Container.fold_min fold t ~cmp
let max_elt t ~cmp = Container.fold_max fold t ~cmp
let init n ~f =
if n < 0 then invalid_argf "List.init %d" n ();
let rec loop i accum =
assert (i >= 0);
if i = 0 then accum
else loop (i-1) (f (i-1) :: accum)
in
loop n []
;;
let rev_filter_map l ~f =
let rec loop l accum =
match l with
| [] -> accum
| hd :: tl ->
match f hd with
| Some x -> loop tl (x :: accum)
| None -> loop tl accum
in
loop l []
;;
let filter_map l ~f = List.rev (rev_filter_map l ~f)
TEST = filter_map ~f:(fun x -> Some x) Test_values.l1 = Test_values.l1
TEST = filter_map ~f:(fun x -> Some x) [] = []
TEST = filter_map ~f:(fun _x -> None) [1.;2.;3.] = []
TEST = filter_map
~f:(fun x -> if (x > 0) then Some x else None) [1;-1;3] = [1;3]
let rev_filter_mapi l ~f =
let rec loop i l accum =
match l with
| [] -> accum
| hd :: tl ->
match f i hd with
| Some x -> loop (i + 1) tl (x :: accum)
| None -> loop (i + 1) tl accum
in
loop 0 l []
;;
let filter_mapi l ~f = List.rev (rev_filter_mapi l ~f)
TEST = filter_mapi ~f:(fun _i x -> Some x) Test_values.l1 = Test_values.l1
TEST = filter_mapi ~f:(fun _i x -> Some x) [] = []
TEST = filter_mapi ~f:(fun _i _x -> None) [1.;2.;3.] = []
TEST = filter_mapi ~f:(fun _i x -> if (x > 0) then Some x else None) [1;-1;3]
= [1;3]
TEST = filter_mapi ~f:(fun i x -> if (i mod 2=0) then Some x else None)
[1;-1;3] = [1;3]
let filter_opt l = filter_map l ~f:(fun x -> x)
let partition_map t ~f =
let rec loop t fst snd =
match t with
| [] -> (rev fst, rev snd)
| x :: t ->
match f x with
| `Fst y -> loop t (y :: fst) snd
| `Snd y -> loop t fst (y :: snd)
in
loop t [] []
;;
let partition_tf t ~f =
let f x = if f x then `Fst x else `Snd x in
partition_map t ~f
;;
module Assoc = struct
type ('a, 'b) t = ('a * 'b) list with bin_io, sexp, compare
let find t ?(equal=Poly.equal) key =
match find t ~f:(fun (key', _) -> equal key key') with
| None -> None
| Some x -> Some (snd x)
let find_exn t ?(equal=Poly.equal) key =
match find t key ~equal with
| None -> raise Not_found
| Some value -> value
let mem t ?(equal=Poly.equal) key = (find t ~equal key) <> None
let remove t ?(equal=Poly.equal) key =
filter t ~f:(fun (key', _) -> not (equal key key'))
let add t ?(equal=Poly.equal) key value =
(* the remove doesn't change the map semantics, but keeps the list small *)
(key, value) :: remove t ~equal key
let inverse t = map t ~f:(fun (x, y) -> (y, x))
let map t ~f = List.map t ~f:(fun (key, value) -> (key, f value))
end
let sub l ~pos ~len =
(* We use [pos > length l - len] rather than [pos + len > length l] to avoid the
possibility of overflow. *)
if pos < 0 || len < 0 || pos > length l - len then invalid_arg "List.sub";
List.rev
(foldi l ~init:[]
~f:(fun i acc el ->
if i >= pos && i < (pos + len)
then el :: acc
else acc
)
)
;;
let slice a start stop =
Ordered_collection_common.slice ~length_fun:length ~sub_fun:sub
a start stop
let split_n t_orig n =
if n <= 0 then
([], t_orig)
else
let rec loop n t accum =
if n = 0 then
(List.rev accum, t)
else
match t with
| [] -> (t_orig, []) (* in this case, t_orig = List.rev accum *)
| hd :: tl -> loop (n - 1) tl (hd :: accum)
in
loop n t_orig []
TEST = split_n [1;2;3;4;5;6] 3 = ([1;2;3],[4;5;6])
TEST = split_n [1;2;3;4;5;6] 100 = ([1;2;3;4;5;6],[])
TEST = split_n [1;2;3;4;5;6] 0 = ([],[1;2;3;4;5;6])
TEST = split_n [1;2;3;4;5;6] (-5) = ([],[1;2;3;4;5;6])
let take t n = fst (split_n t n)
let drop t n = snd (split_n t n)
let split_while xs ~f =
let rec loop acc = function
| hd :: tl when f hd -> loop (hd :: acc) tl
| t -> (rev acc, t)
in
loop [] xs
;;
let take_while t ~f = fst (split_while t ~f)
let drop_while t ~f = snd (split_while t ~f)
TEST_MODULE "{take,drop,split}_while" = struct
let pred = function
| '0' .. '9' -> true
| _ -> false
let test xs prefix suffix =
let (prefix1, suffix1) = split_while ~f:pred xs in
let prefix2 = take_while xs ~f:pred in
let suffix2 = drop_while xs ~f:pred in
xs = prefix @ suffix
&& prefix = prefix1 && prefix = prefix2
&& suffix = suffix1 && suffix = suffix2
TEST = test ['1';'2';'3';'a';'b';'c'] ['1';'2';'3'] ['a';'b';'c']
TEST = test ['1';'2'; 'a';'b';'c'] ['1';'2' ] ['a';'b';'c']
TEST = test ['1'; 'a';'b';'c'] ['1' ] ['a';'b';'c']
TEST = test [ 'a';'b';'c'] [ ] ['a';'b';'c']
TEST = test ['1';'2';'3' ] ['1';'2';'3'] [ ]
TEST = test [ ] [ ] [ ]
end
let cartesian_product list1 list2 =
if list2 = [] then [] else
let rec loop l1 l2 accum = match l1 with
| [] -> accum
| (hd :: tl) ->
loop tl l2
(List.rev_append
(map ~f:(fun x -> (hd,x)) l2)
accum)
in
List.rev (loop list1 list2 [])
let concat l = fold_right l ~init:[] ~f:append
TEST = concat [] = []
TEST = concat [[]] = []
TEST = concat [[3]] = [3]
TEST = concat [[1;2;3;4]] = [1;2;3;4]
TEST = concat
[[1;2;3;4];[5;6;7];[8;9;10];[];[11;12]]
= [1;2;3;4;5;6;7;8;9;10;11;12]
let concat_no_order l = fold l ~init:[] ~f:(fun acc l -> rev_append l acc)
let cons x l = x :: l
let is_empty l = match l with [] -> true | _ -> false
let is_sorted l ~compare =
let rec loop l =
match l with
| [] | [_] -> true
| x1 :: ((x2 :: _) as rest) ->
compare x1 x2 <= 0 && loop rest
in loop l
TEST = is_sorted [] ~compare
TEST = is_sorted [1] ~compare
TEST = is_sorted [1; 2; 3; 4] ~compare
TEST = not (is_sorted [2; 1] ~compare)
TEST = not (is_sorted [1; 3; 2] ~compare)
let is_sorted_strictly l ~compare =
let rec loop l =
match l with
| [] | [_] -> true
| x1 :: ((x2 :: _) as rest) ->
compare x1 x2 < 0 && loop rest
in loop l
;;
TEST_UNIT =
List.iter
~f:(fun (t, expect) -> assert (expect = is_sorted_strictly t ~compare))
[ [] , true;
[ 1 ] , true;
[ 1; 2 ] , true;
[ 1; 1 ] , false;
[ 2; 1 ] , false;
[ 1; 2; 3 ], true;
[ 1; 1; 3 ], false;
[ 1; 2; 2 ], false;
]
;;
module Infix = struct
let ( @ ) = append
end
let permute ?(random_state = Random.State.default) list =
match list with
(* special cases to speed things up in trivial cases *)
| [] | [_] -> list
| [ x; y ] -> if Random.State.bool random_state then [ y; x ] else list
| _ ->
let arr = Array.of_list list in
Array_permute.permute arr ~random_state;
Array.to_list arr;
;;
let to_string ~f t =
Sexplib.Sexp.to_string