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type ('a, -'p) t =
{ mutable data: 'a array
; mutable length: int
}
let[@inline] array_uninit n = Array.make n (Obj.magic 0)
let[@inline] make_unsafe capacity length = { data = array_uninit capacity; length }
let[@inline] make ?capacity:(c=0) () =
if c < 0 then
raise (Invalid_argument "Negative capacity")
else
make_unsafe c 0
let as_read_only v = (v :> ('a, [`R]) t)
let as_write_only v = (v :> ('a, [`W]) t)
let[@inline] length v = v.length
let[@inline] capacity v = Array.length v.data
let[@inline] clear v =
v.data <- [||];
v.length <- 0
let[@inline] get v i =
if i < 0 || i >= v.length then
raise (Invalid_argument "Index out of range")
else
v.data.(i)
let[@inline] set v i a =
if i < 0 || i >= v.length then
raise (Invalid_argument "Index out of range")
else
v.data.(i) <- a
let try_get v i =
if i < 0 || i >= v.length then
None
else
Some v.data.(i)
let[@inline] try_set v i a = i >= 0 && i < v.length && (v.data.(i) <- a; true)
let reserve c v =
let old_c = capacity v in
if c > old_c then
let new_c = ref (old_c + (old_c lsr 1) + 2) in
while !new_c < c do
new_c := !new_c + (!new_c lsr 1) + 2
done;
let data = array_uninit !new_c in
Array.blit v.data 0 data 0 v.length;
v.data <- data
let[@inline] shrink_to_fit v =
if capacity v > v.length then
let data = array_uninit v.length in
Array.blit v.data 0 data 0 v.length;
v.data <- data
let[@inline] push a v =
let old_length = v.length in
let new_length = old_length + 1 in
reserve new_length v;
v.length <- new_length;
v.data.(old_length) <- a
let[@inline] try_pop v =
if v.length = 0 then
None
else
let last = v.length - 1 in
let a = v.data.(last) in
v.data.(last) <- Obj.magic 0;
v.length <- last;
Some a
let[@inline] pop v =
match try_pop v with
| None -> raise (Invalid_argument "Empty vector")
| Some a -> a
let[@inline] singleton a =
{ data = [|a|]
; length = 1
}
let try_find f v =
let rec go i =
if i = v.length then
None
else
let a = v.data.(i) in
if f a then
Some a
else
go (i + 1)
in
go 0
let[@inline] find f v =
match try_find f v with
| None -> raise Not_found
| Some a -> a
let try_insert_at i a v =
if i < 0 || i > v.length then
false
else
let new_length = v.length + 1 in
reserve new_length v;
Array.blit v.data i v.data (i + 1) (v.length - i);
v.data.(i) <- a;
v.length <- new_length;
true
let[@inline] insert_at i a v =
if not (try_insert_at i a v) then
raise (Invalid_argument "Index out of range")
let try_remove_at i v =
if i < 0 || i >= v.length then
None
else
let a = v.data.(i) in
Array.blit v.data (i + 1) v.data i (v.length - i - 1);
v.length <- v.length - 1;
v.data.(v.length) <- Obj.magic 0;
Some a
let[@inline] remove_at i v =
match try_remove_at i v with
| None -> raise (Invalid_argument "Index out of range")
| Some a -> a
let map f v =
let v2 = make_unsafe v.length v.length in
for i = 0 to v.length - 1 do
v2.data.(i) <- f v.data.(i)
done;
v2
let mapi f v =
let v2 = make_unsafe v.length v.length in
for i = 0 to v.length - 1 do
v2.data.(i) <- f i v.data.(i)
done;
v2
let map_in_place f v =
for i = 0 to v.length - 1 do
v.data.(i) <- f v.data.(i)
done
let map2 f v1 v2 =
let total_length = v1.length * v2.length in
let v = make_unsafe total_length total_length in
let idx = ref 0 in
for i = 0 to v1.length - 1 do
for j = 0 to v2.length - 1 do
v.data.(!idx) <- f v1.data.(i) v2.data.(j);
incr idx
done
done;
v
let[@inline] apply f v = map2 (@@) f v
let flatten vs =
let total_length = ref 0 in
for i = 0 to vs.length - 1 do
total_length := !total_length + vs.data.(i).length
done;
let vec = make_unsafe !total_length !total_length in
let idx = ref 0 in
for i = 0 to vs.length - 1 do
let v = vs.data.(i) in
Array.blit v.data 0 vec.data !idx v.length;
idx := !idx + v.length
done;
vec
let[@inline] append_in_place v v2 =
let total_length = v.length + v2.length in
reserve total_length v;
Array.blit v2.data 0 v.data v.length v2.length;
v.length <- total_length
let flat_map f v =
let v2 = make_unsafe v.length 0 in
for i = 0 to v.length - 1 do
append_in_place v2 (f v.data.(i))
done;
v2
let[@inline] cartesian_product a b = map2 (fun a b -> a, b) a b
let iter f v =
for i = 0 to v.length - 1 do
f v.data.(i)
done
let iteri f v =
for i = 0 to v.length - 1 do
f i v.data.(i)
done
let filter f v =
let v2 = make_unsafe v.length 0 in
let l = ref 0 in
for i = 0 to v.length - 1 do
let a = v.data.(i) in
if f a then
(v2.data.(!l) <- a; incr l)
done;
v2.length <- !l;
v2
let filteri f v =
let v2 = make_unsafe v.length 0 in
let l = ref 0 in
for i = 0 to v.length - 1 do
let a = v.data.(i) in
if f i a then
(v2.data.(!l) <- a; incr l)
done;
v2.length <- !l;
v2
let filter_in_place f v =
let old_length = v.length in
let l = ref 0 in
for i = 0 to old_length - 1 do
let a = v.data.(i) in
if f a then
(v.data.(!l) <- a; incr l)
done;
Array.fill v.data !l (old_length - !l) (Obj.magic 0);
v.length <- !l
let[@inline] of_array_unsafe a =
{ data = a
; length = Array.length a
}
let[@inline] to_array_unsafe v = v.data
let[@inline] of_array a = of_array_unsafe (Array.copy a)
let[@inline] to_array v = Array.sub v.data 0 v.length
let[@inline] of_list l = of_array_unsafe (Array.of_list l)
let to_list v =
let rec go acc = function
| -1 -> acc
| i -> go (v.data.(i) :: acc) (i - 1)
in
go [] (v.length - 1)
let[@inline] copy v = of_array_unsafe (to_array v)
let[@inline] append v v2 =
let v' = copy v in
append_in_place v' v2;
v'
let rev_in_place v =
let rec go i j =
if i < j then
let tmp = v.data.(i) in
v.data.(i) <- v.data.(j);
v.data.(j) <- tmp;
go (i + 1) (j - 1)
in
go 0 (v.length - 1)
let[@inline] rev v =
let v' = copy v in
rev_in_place v';
v'
let[@inline] exists f v =
let rec go i = i < v.length && (f v.data.(i) || go (i + 1))
in go 0
let[@inline] for_all f v =
let rec go i = i = v.length || (f v.data.(i) && go (i + 1))
in go 0
let[@inline] mem e = exists ((=) e)
let[@inline] memq e = exists ((==) e)
let fold_left f z v =
let rec go acc i =
if i = v.length then
acc
else
go (f acc v.data.(i)) (i + 1)
in
go z 0
let fold_right f v z =
let rec go acc i =
if i <= 0 then
acc
else
go (f v.data.(i) acc) (i - 1)
in
go z (v.length - 1)
let zip_with f v1 v2 =
let min_length = min v1.length v2.length in
let v = make_unsafe min_length min_length in
for i = 0 to min_length - 1 do
v.data.(i) <- f v1.data.(i) v2.data.(i)
done;
v
let[@inline] zip v1 v2 = zip_with (fun a b -> (a, b)) v1 v2
let[@inline] sort_by f v =
shrink_to_fit v;
Array.fast_sort f v.data
let[@inline] sort v = sort_by compare v
let[@inline] equal_by f a b =
if a.length <> b.length then
false
else
let rec go i = i = a.length || (f a.data.(i) b.data.(i) && go (i + 1))
in go 0
let[@inline] equal a b = equal_by (=) a b
let compare_by f a b =
let min_l, min_l_ord =
match a.length - b.length with
| 0 -> a.length, 0
| l when l < 0 -> a.length, -1
| _ -> b.length, 1
in
let rec go i =
if i = min_l then
min_l_ord
else
let ord = f a.data.(i) b.data.(i) in
if ord <> 0 then
ord
else
go (i + 1)
in
go 0
let[@inline] compare a b = compare_by compare a b
let pretty_print fmt v =
if v.length = 0 then
"[]"
else
let buf = Buffer.create 2 in
Buffer.add_char buf '[';
Buffer.add_string buf (fmt v.data.(0));
for i = 1 to v.length - 1 do
Buffer.add_string buf "; ";
Buffer.add_string buf (fmt v.data.(i))
done;
Buffer.add_char buf ']';
Buffer.contents buf
let[@inline] range start end' =
let l = (abs (end' - start) + 1) in
let d = if start <= end' then 1 else -1 in
of_array_unsafe (Array.init l (fun i -> start + i * d))
module Infix = struct
let (.![]) = get
let (.![]<-) = set
let (.?[]) = try_get
let (.?[]<-) = try_set
let[@inline] (let+) v f = map f v
let (and+) = cartesian_product
let[@inline] (let*) v f = flat_map f v
let (and*) = cartesian_product
let (@) = append
let (=|<) = map
let[@inline] (>|=) v f = f =|< v
let (<$>) = map
let (<*>) = apply
let (=<<) = flat_map
let (>>=) v f = f =<< v
let (--) = range
end