The list type

nil is []

nil_e is Ok []

nil_s is Lwt.return_nil

nil_es is Lwt.return (Ok [])

cons x xs is x :: xs

is_empty xs is true iff xs is []

hd xs is the head (first element) of the list or None if the list is empty.

tl xs is the tail of the list (the whole list except the first element) or None if the list is empty.

nth xs n is the nth element of the list or None if the list has fewer than n elements.

For example, nth xs 0 = hd xs and nth ['x'; 'y'] 1 = Some 'y'.

nth_opt is an alias for nth provided for compatibility with Stdlib.List.

last x xs is the last element of the list xs or x if xs is empty.

The primary intended use for last is after destructing a list: match l with | [] -> … | x :: xs -> last x xs but it can also be used for a default value: last default_value_if_empty xs.

last_opt xs is the last element of the list xs or None if the list xs is empty.

find predicate xs is the first element x of the list xs such that predicate x is true or None if the list xs has no such element.

find_opt is an alias for find provided for compatibility with Stdlib.List.

find_map f xs applies f to each of the elements of xs until it returns Some _ at which point it is returned. If no such elements are found then it returns None.

Note that it only applies f to a prefix of xs. It doesn't apply f to the elements of xs which are after the found element. Consequently, find_map f xs has better performance and a different semantic than calling map and find separately.

mem ~equal a l is true iff there is an element e of l such that equal a e.

memq a l is the same as mem ~equal:Stdlib.( == ) a l: it uses the physical equality.

assoc ~equal k kvs is Some v such that (k', v) is the first pair in the list such that equal k' k or None if the list contains no such pair.

assoc_opt is an alias for assoc provided for compatibility with Stdlib.List.

assq k kvs is the same as assoc ~equal:Stdlib.( == ) k kvs: it uses the physical equality.

assq_opt is an alias for assq provided for compatibility with Stdlib.List.

mem_assoc ~equal k l is equivalent to Option.is_some @@ assoc ~equal k l.

mem_assq k l is mem_assoc ~equal:Stdlib.( == ) k l.

remove_assoc ~equal k l is l without the first element (k', _) such that equal k k'.

remove_assoq k l is remove_assoc ~equal:Stdlib.( == ) k l.

init ~when_negative_length n f is a list of n elements f 0, f 1, etc.

If n is negative, it is Error when_negative_length instead.

length xs is the number of elements in xs.

length [] is 0, length ['x'] is 1, etc.

rev xs is a list with the elements appearing in the reverse order as in xs.

rev ['x'; 'y'] is 'y'; 'x'

concat xs is a list containing the elements of the elements of xs.

concat [['x'; 'y']; ['a'; 'b']] is ['x'; 'y'; 'a'; 'b']

append xs ys is a list containing the elements of xs and the elements of ys, in this order.

concat ['x'; 'y'] ['a'; 'b'] is ['x'; 'y'; 'a'; 'b']

rev_append xs ys is append (rev xs) ys but more efficient. In other words, rev_append xs ys is a list containing the elements of xs in reverse order followed by the elements of ys.

There are two main use-cases for rev_append. First, you should use rev_append when the order of elements is unimportant. In this case you simply replace append xs ys with rev_append xs ys.

Second, you can use rev_append on an already reversed list. You may obtain an already reversed list from any of the other rev_* functions of this module, or simply via your own traversal. In this case, you replace, say, append (map f xs) ys with rev_append (rev_map f xs) ys.

flatten is an alias for concat.

combine ~when_different_lengths l1 l2 is either

• Error when_different_lengths if List.length l1 <> List.length l2
• a list of pairs of elements from l1 and l2

E.g., combine ~when_different_lengths [] [] is Ok []

E.g., combine ~when_different_lengths [1; 2] ['a'; 'b'] is Ok [(1,'a'); (2, 'b')]

E.g., combine ~when_different_lengths:"wrong" [1] [] is Error "wrong"

Note: combine ~when_different_lengths l1 l2 is equivalent to try Ok (Stdlib.List.combine l1 l2) with Invalid_argument _ -> when_different_lengths

The same equivalence almost holds for the other double traversors below. The notable difference is if the functions passed as argument to the traversors raise the Invalid_argument _ exception.

rev_combine ~when_different_lengths xs ys is rev (combine ~when_different_lengths xs ys) but more efficient.

split xs is (List.map fst xs, List.map snd xs) but more efficient.

iter2 ~when_different_lengths f xs ys is f x0 y0; f x1 y1; ….

Remember that, even if the lists are of different lengths, the function f is applied to the common prefix of xs and ys. This is true for other traversals, but especially relevant to iter which is commonly used for side-effects.

map2 ~when_different_lengths f xs ys is a list with elements f x0 y0, f x1 y1, etc.

Remember that, even if the lists are of different lengths, the function f is applied to the common prefix of xs and ys. Beware of side-effects and computational cost.

rev_map2 ~when_different_lengths f xs ys is Result.map rev @@ map2 ~when_different_lengths f xs ys but more efficient.

Remember that, even if the lists are of different lengths, the function f is applied to the common prefix of xs and ys. Beware of side-effects and computational cost.

fold_left2 ~when_different_lengths f init xs ys is … (f (f init x0 y0) x1 y1).

Remember that, even if the lists are of different lengths, the function f is applied to the common prefix of xs and ys. Beware of side-effects and computational cost.

fold_right2 ~when_different_lengths f xs ys init is f x0 y0 (f x1 y1 (…)).

This function is not tail-recursive.

Note that unlike the left-to-right double-list traversors, fold_right2 only calls f if the lists are of the same length.

for_all2 ~when_different_lengths f xs ys is f x0 y0 && f x1 y1 && ….

The function stops early if it encounters elements xn, yn such that f xn yn is false. (This is consistent with the short-circuit, lazy evaluation strategy of && in the description above.)

Also note that, if such an element is found in the common prefix of xs and ys, then the function returns Ok false even if xs and ys are of different lengths.

Examples:

for_all2 ~when_different_lengths (=) [] [] is Ok true

for_all2 ~when_different_lengths (=) ['x'] ['a'] is Ok false

for_all2 ~when_different_lengths (=) ['x'; 'y'] ['a'] is Ok false

for_all2 ~when_different_lengths (=) ['x'] ['x'] is Ok true

for_all2 ~when_different_lengths (=) ['x'; 'y'] ['x'] is Error when_different_lengths

for_all2 ~when_different_lengths (=) ['x'; 'y'] ['x'; 'b'] is Ok false

for_all2 ~when_different_lengths (=) ['x'; 'y'] ['x'; 'y'; 'c'] is Error when_different_lengths

Remember that, when it returns Error when_different_lengths, the function f has already been applied to the common prefix of xs and ys. Beware of side-effects and computational cost.

exists2 ~when_different_lengths f xs ys is f x0 y0 || f x1 y1 || ….

The function stops early if it encounters elements xn, yn such that f xn yn is true. (This is consistent with the short-circuit, lazy evaluation strategy of || in the description above.)

Also note that, if such an element is found in the common prefix of xs and ys, then the function returns Ok true even if xs and ys are of different lengths.

Examples:

exists2 ~when_different_lengths (=) [] [] is Ok false

exists2 ~when_different_lengths (=) ['x'] ['a'] is Ok false

exists2 ~when_different_lengths (=) ['x'; 'y'] ['a'] is Error when_different_lengths

exists2 ~when_different_lengths (=) ['x'] ['x'] is Ok true

exists2 ~when_different_lengths (=) ['x'; 'y'] ['x'] is Ok true

Remember that, when it returns Error when_different_lengths, the function f has already been applied to the common prefix of xs and ys. Beware of side-effects and computational cost.

init_e is a Result-aware variant of init.

init_s is an Lwt-aware variant of init.

init_es is an Lwt-Result-aware variant of init.

init_p is a variant of init_s where the promises are evaluated concurrently.

find_e is a Result-aware variant of find.

find_s is an Lwt-aware variant of find.

find_es is an Lwt-Result-aware variant of find.

find_map_e is a Result-aware variant of find_map.

find_map_s is an Lwt-aware variant of find_map.

find_map_es is an Lwt-Result-aware variant of find_map.

filter f xs is the list of all the elements xn of xs such that f xn is true.

filter (fun x -> x > 10) [0; 2; 19; 22; -1; 3; 11] is [19; 22; 11]

filteri is similar to filter but the predicate also receives the element's index as an argument.

find_all is an alias for filter.

rev_filter f l is rev (filter f l) but more efficient.

rev_filteri f l is rev (filteri f l) but more efficient.

rev_filter_some xs is rev @@ filter_some xs but more efficient.

filter_some extracts all the payloads of the Some variants. The order is preserved.

filter_some [None; Some 'a'; None; None; Some 'z'; Some 'u'] is ['a'; 'z'; 'u'].

rev_filter_ok rs is rev @@ filter_ok rs but more efficient.

filter_ok extracts all the payloads of the Ok variants. The order is preserved.

filter_ok [Error 3; Ok 'a'; Error 3; Error 5; Ok 'z'; Ok 'u'] is ['a'; 'z'; 'u'].

rev_filter_error rs is rev @@ filter_error rs but more efficient.

filter_error extracts all the payloads of the Error variants. The order is preserved.

filter_ok [Error 3; Ok 'a'; Error 3; Error 5; Ok 'z'; Ok 'u'] is [3; 3; 5].

rev_filter_left es is rev @@ filter_left es but more efficient.

filter_left extracts all the payloads of the Left variants. The order is preserved.

filter_left [Right 3; Left 'a'; Right 3; Right 5; Left 'z'; Left 'u'] is ['a'; 'z'; 'u'].

rev_filter_right es is rev @@ filter_right es but more efficient.

filter_right extracts all the payloads of the Right variants. The order is preserved.

filter_right [Right 3; Left 'a'; Right 3; Right 5; Left 'z'; Left 'u'] is [3; 3; 5].

rev_filter_e is a Result-aware variant of rev_filter.

filter_e is a Result-aware variant of filter.

rev_filter_s is an Lwt-aware variant of rev_filter.

filter_s is an Lwt-aware variant of filter.

rev_filter_es is an Lwt-Result-aware variant of rev_filter.

filter_es is an Lwt-Result-aware variant of filter.

filter_p is a variant of filter_s where the promises are evaluated concurrently.

rev_filteri_e is a Result-aware variant of rev_filteri.

filteri_e is a Result-aware variant of filteri.

rev_filteri_s is an Lwt-aware variant of rev_filteri.

filteri_s is an Lwt-aware variant of filteri.

rev_filteri_es is an Lwt-Result-aware variant of rev_filteri.

filteri_es is an Lwt-Result-aware variant of filteri.

filteri_p is a variant of filteri_s where the promises are evaluated concurrently.

rev_partition f xs is let rt, rf = partition f xs in (rev rt, rev rf) but more efficient.

partition f xs is a couple of lists (ts, fs) where ts contains all the elements of xs such that f x is true and fs contains all the elements of xs such that f x is false.

The function f is applied once to each element of xs.

rev_partition_map f xs is let rt, rf = partition_map f xs in (rev rt, rev rf) but more efficient.

partition_map f xs applies f to each of the element of xs and returns a couple of lists (ls, rs) where ls contains all the l such that f x is Left l and rs contains all the r such that f x is Right r.

rev_partition_result rs is partition_result @@ rev rs but more efficient.

partition_result rs is a tuple of lists (os, es) where os contains all the payloads of Ok variants of rs and es contains all the payloads of Error variants of rs.

partition_result rs is (filter_ok rs, filter_error rs) but more efficient.

rev_partition_either rs is partition_either @@ rev rs but more efficient.

partition_either es is a tuple of lists (ls, rs) where ls contains all the payloads of Left variants of ls and rs contains all the payloads of Right variants of es.

partition_either es is (filter_left es, filter_right es) but more efficient.

rev_partition_e is a Result-aware variant of rev_partition.

partition_e is a Result-aware variant of partition.

rev_partition_s is an Lwt-aware variant of rev_partition.

partition_s is an Lwt-aware variant of partition.

rev_partition_es is an Lwt-Result-aware variant of rev_partition.

partition_es is an Lwt-Result-aware variant of partition.

partition_p is a variant of partition_s where the promises are evaluated concurrently.

rev_partition_map_e is a Result-aware variant of rev_partition_map.

partition_map_e is a Result-aware variant of partition_map.

rev_partition_map_s is an Lwt-aware variant of rev_partition_map.

partition_map_s is an Lwt-aware variant of partition_map.

rev_partition_map_es is an Lwt-Result-aware variant of rev_partition_map.

partition_map_es is an Lwt-Result-aware variant of partition_map.

partition_map_p is a variant of partition_map_s where the promises are evaluated concurrently.

iter f xs is f x0; f x1; ….

iter_e is a Result-aware variant of iter.

iter_s is an Lwt-aware variant of iter.

iter_es is an Lwt-Result-aware variant of iter.

iter_p is a variant of iter_s where the promises are evaluated concurrently.

iteri f xs is f 0 x0; f 1 x1; ….

iteri_e is a Result-aware variant of iteri.

iteri_s is an Lwt-aware variant of iteri.

iteri_es is an Lwt-Result-aware variant of iteri.

iteri_p is a variant of iteri_s where the promises are evaluated concurrently.

map f xs is the list [f x0; f x1; …].

map_e is a Result-aware variant of map.

map_s is an Lwt-aware variant of map.

map_es is an Lwt-Result-aware variant of map.

map_p is a variant of map_s where the promises are evaluated concurrently.

mapi f xs is the list [f 0 x0; f 1 x1; …].

mapi_e is a Result-aware variant of mapi.

mapi_s is an Lwt-aware variant of mapi.

mapi_es is an Lwt-Result-aware variant of mapi.

mapi_p is a variant of mapi_s where the promises are evaluated concurrently.

rev_map f xs is rev @@ map f xs but more efficient.

rev_mapi f xs is rev @@ mapi f xs but more efficient.

rev_map_e is a Result-aware variant of rev_map.

rev_map_s is an Lwt-aware variant of rev_map.

rev_map_es is an Lwt-Result-aware variant of rev_map.

rev_map_p is a variant of rev_map_s where the promises are evaluated concurrently.

rev_mapi_e is a Result-aware variant of rev_mapi.

rev_mapi_s is an Lwt-aware variant of rev_mapi.

rev_mapi_es is an Lwt-Result-aware variant of rev_mapi.

rev_mapi_p is a variant of rev_mapi_s where the promises are evaluated concurrently.

rev_filter_map f xs is rev @@ filter_map f xs but more efficient.

rev_filter_map_e is a Result-aware variant of rev_filter_map.

filter_map_e is a Result-aware variant of filter_map.

rev_filter_map_s is an Lwt-aware variant of rev_filter_map.

filter_map f xs is filter_some @@ map f xs but more efficient.

filter_map_s is an Lwt-aware variant of filter_map.

rev_filter_map_es is an Lwt-Result-aware variant of rev_filter_map.

filter_map_es is an Lwt-Result-aware variant of filter_map.

filter_map_p is a variant of filter_map_s where the promises are evaluated concurrently.

concat_map f xs is concat (map f xs) but more efficient.

concat_map_s is an Lwt-aware variant of concat_map.

concat_map_e is a Result-aware variant of concat_map.

concat_map_es is an Lwt-Result-aware variant of concat_map.

concat_map_p is a variant of concat_map_s where the promises are evaluated concurrently.

rev_concat_map f xs is rev (concat_map f xs) but more efficient.

rev_concat_map_s is an Lwt-aware variant of rev_concat_map.

rev_concat_map_e is a Result-aware variant of rev_concat_map.

rev_concat_map_es is an Lwt-Result-aware variant of rev_concat_map.

fold_left_e is a Result-aware variant of fold_left.

fold_left_s is an Lwt-aware variant of fold_left.

fold_left_es is an Lwt-Result-aware variant of fold_left.

fold_left_map f a xs is a combination of fold_left and map that maps over all elements of xs and threads an accumulator with initial value a through calls to f.

fold_left_map_e f a xs is a combination of fold_left_e and map_e that maps over all elements of xs and threads an accumulator with initial value a through calls to f. The list is traversed from left to right and the first encountered error is returned.

fold_left_map_s f a xs is a combination of fold_left_s and map_s that maps over all elements of xs and threads an accumulator with initial value a through calls to f.

fold_left_map_es f a xs is a combination of fold_left_es and map_es that maps over all elements of xs and threads an accumulator with initial value a through calls to f. The list is traversed from left to right and the first encountered error is returned.

This function is not tail-recursive

This function is not tail-recursive

This function is not tail-recursive

This function is not tail-recursive

This function is not tail-recursive

This function is not tail-recursive

This function is not tail-recursive

combine_drop ll lr is a list l of pairs of elements taken from the common-length prefix of ll and lr. The suffix of whichever list is longer (if any) is dropped.

More formally nth l n is:

• None if n >= min (length ll) (length lr)
• Some (Option.get @@ nth ll n, Option.get @@ nth lr n) otherwise

combine_with_leftovers ll lr is a tuple (combined, leftover) where combined is combine_drop ll lr and leftover is either Either.Left lsuffix or Either.Right rsuffix depending on which of ll or lr is longer. leftover is None if the two lists have the same length.

product xs ys is the cartesian product of xs and ys.

In other words product xs ys is a list containing all the pairs (x, y) where x is an element of xs and y is an element of ys.

The order of the elements in the returned list is unspecified.

shuffle l is a list that contains the same elements as l but in a random order.

merge compare xs ys merges the lists xs and ys.

merge assumes that xs and ys are sorted according to the order defined by compare. If xs and ys are not sorted, the returned value of merge compare xs ys is unspecified.

Assuming that xs and ys are sorted, merge compare xs ys is a list

• containing all the elements of xs and of ys, and
• sorted according to the order defined by compare.

merge is not tail-recursive.