Enumeration over abstract collection of elements.
Enumerations are a representation of finite or infinite sequences of elements. In Batteries Included, enumerations are used pervasively, both as a uniform manner of reading and manipulating the contents of a data structure, or as a simple manner of reading or writing sequences of characters, numbers, strings, etc. from/to files, network connections or other inputs/outputs.
Enumerations are typically computed as needed, which allows the definition and manipulation of huge (possibly infinite) sequences. Manipulating an enumeration is a uniform and often comfortable way of extracting subsequences (function filter
or operator //
et al), converting sequences into other sequences (function map
or operators /@
and @/
et al), gathering information (function scanl
et al) or performing loops (functions iter
and map
).
For instance, function BatRandom.enum_int
creates an infinite enumeration of random numbers. Combined with //
and map
, we may turn this into an infinite enumeration of squares of random even numbers: map (fun x -> x * x) ( (Random.enum_int 100) // even )
Similarly, to obtain an enumeration of 50 random integers, we may use take
, as follows: take 50 (Random.enum_int 100)
As most data structures in Batteries can be enumerated and built from enumerations, these operations may be used also on lists, arrays, hashtables, etc. When designing a new data structure, it is usuallly a good idea to allow enumeration and construction from an enumeration.
Note Enumerations are not thread-safe. You should not attempt to access one enumeration from different threads.
A signature for data structures which may be converted to and from enum
.
Final functions
These functions consume the enumeration until it ends or an exception is raised by the first argument function.
val iter : ('a -> unit) -> 'a t -> unit
iter f e
calls the function f
with each elements of e
in turn.
val iter2 : ('a -> 'b -> unit) -> 'a t -> 'b t -> unit
iter2 f e1 e2
calls the function f
with the next elements of e1
and e2
repeatedly until one of the two enumerations ends.
val exists : ('a -> bool) -> 'a t -> bool
exists f e
returns true
if there is some x
in e
such that f x
val for_all : ('a -> bool) -> 'a t -> bool
for_all f e
returns true
if for every x
in e
, f x
is true
val fold : ('b -> 'a -> 'b) -> 'b -> 'a t -> 'b
A general loop on an enumeration.
If e
is empty, fold f v e
returns v
. Otherwise, fold v e
returns f (... (f (f v a0) a1) ...) aN
where a0,a1..aN
are the elements of e
. This function may be used, for instance, to compute the sum of all elements of an enumeration e
as follows: fold ( + ) 0 e
. Eager.
val reduce : ('a -> 'a -> 'a) -> 'a t -> 'a
A simplified version of fold
, which uses the first element of the enumeration as a default value.
reduce f e
throws Not_found
if e
is empty, returns its only element if e is a singleton, otherwise f (... (f (f a0 a1)
a2)...) aN
where a0,a1..aN
are the elements of e
.
sum
returns the sum of the given int enum. If the argument is empty, returns 0. Eager
val fsum : float t -> float
val kahan_sum : float t -> float
kahan_sum l
returns a numerically-accurate sum of the floats of l
. See BatArray.fsum
for more details.
val fold2 : ('a -> 'b -> 'c -> 'c) -> 'c -> 'a t -> 'b t -> 'c
fold2
is similar to fold
but will fold over two enumerations at the same time until one of the two enumerations ends.
val scanl : ('b -> 'a -> 'b) -> 'b -> 'a t -> 'b t
A variant of fold
producing an enumeration of its intermediate values. If e
contains x0
, x1
, ..., scanl f init e
is the enumeration containing init
, f init x0
, f (f init x0) x1
... Lazy.
val scan : ('a -> 'a -> 'a) -> 'a t -> 'a t
scan
is similar to scanl
but without the init
value: if e
contains x0
, x1
, x2
..., scan f e
is the enumeration containing x0
, f x0 x1
, f (f x0 x1) x2
...
For instance, scan ( * ) (1 -- 10)
will produce an enumeration containing the successive values of the factorial function.
Indexed functions : these functions are similar to previous ones except that they call the function with one additional argument which is an index starting at 0 and incremented after each call to the function.
val iteri : (int -> 'a -> unit) -> 'a t -> unit
val iter2i : (int -> 'a -> 'b -> unit) -> 'a t -> 'b t -> unit
val foldi : (int -> 'a -> 'b -> 'b) -> 'b -> 'a t -> 'b
val fold2i : (int -> 'a -> 'b -> 'c -> 'c) -> 'c -> 'a t -> 'b t -> 'c
Useful functions
val find : ('a -> bool) -> 'a t -> 'a
find f e
returns the first element x
of e
such that f x
returns true
, consuming the enumeration up to and including the found element.
val find_map : ('a -> 'b option) -> 'a t -> 'b
find_map f e
finds the first element x
of e
such that f x
returns Some r
, then returns r. It consumes the enumeration up to and including the found element.
val is_empty : 'a t -> bool
is_empty e
returns true if e
does not contains any element. Forces at most one element.
val peek : 'a t -> 'a option
peek e
returns None
if e
is empty or Some x
where x
is the next element of e
. The element is not removed from the enumeration.
val get : 'a t -> 'a option
get e
returns None
if e
is empty or Some x
where x
is the next element of e
, in which case the element is removed from the enumeration.
get_exn e
returns the first element of e
.
val push : 'a t -> 'a -> unit
push e x
will add x
at the beginning of e
.
junk e
removes the first element from the enumeration, if any.
clone e
creates a new enumeration that is copy of e
. If e
is consumed by later operations, the clone will not get affected.
force e
forces the application of all lazy functions and the enumeration of all elements, exhausting the enumeration.
An efficient intermediate data structure of enumerated elements is constructed and e
will now enumerate over that data structure.
val take : int -> 'a t -> 'a t
take n e
returns the prefix of e
of length n
, or e
itself if n
is greater than the length of e
val drop : int -> 'a t -> unit
drop n e
removes the first n
element from the enumeration, if any.
val skip : int -> 'a t -> 'a t
skip n e
removes the first n
element from the enumeration, if any, then returns e
.
This function has the same behavior as drop
but is often easier to compose with, e.g., skip 5 %> take 3
is a new function which skips 5 elements and then returns the next 3 elements.
val take_while : ('a -> bool) -> 'a t -> 'a t
take_while f e
produces a new enumeration in which only remain the first few elements x
of e
such that f x
val drop_while : ('a -> bool) -> 'a t -> 'a t
drop_while p e
produces a new enumeration in which only all the first elements such that f e
have been junked.
val span : ('a -> bool) -> 'a t -> 'a t * 'a t
span test e
produces two enumerations (hd, tl)
, such that hd
is the same as take_while test e
and tl
is the same as drop_while test e
.
val break : ('a -> bool) -> 'a t -> 'a t * 'a t
Negated span. break test e
is equivalent to span (fun x -> not (test x)) e
val group : ('a -> 'b) -> 'a t -> 'a t t
group test e
divides e
into an enumeration of enumerations, where each sub-enumeration is the longest continuous enumeration of elements whose test
results are the same.
Enum.group (x -> x mod 2) [1;2;4;1] = [[1];[2;4];[1]]
Enum.group (fun x -> x mod 3) [1;2;4;1] = [[1];[2];[4;1]]
Enum.group (fun s -> s.[0]) ["cat"; "canary"; "dog"; "dodo"; "ant"; "cow"] = [["cat"; "canary"];["dog";"dodo"];["ant"];["cow"]]
Warning: The result of this operation cannot be directly cloned safely; instead, reify to a non-lazy structure and read from that structure multiple times.
val group_by : ('a -> 'a -> bool) -> 'a t -> 'a t t
group_by eq e
divides e
into an enumeration of enumerations, where each sub-enumeration is the longest continuous enumeration of elements that are equal, as judged by eq
.
Warning: The result of this operation cannot be directly cloned safely; instead, reify to a non-lazy structure and read from that structure multiple times.
val clump : int -> ('a -> unit) -> (unit -> 'b) -> 'a t -> 'b t
clump size add get e
runs add
on size
(or less at the end) elements of e
and then runs get
to produce value for the result enumeration. Useful to convert a char enum into string enum.
val cartesian_product : 'a t -> 'b t -> ('a * 'b) t
cartesian_product e1 e2
computes the cartesian product of e1
and e2
. Pairs are enumerated in a non-specified order, but in fair enough an order so that it works on infinite enums (i.e. even then, any pair is eventually returned)
Lazy constructors
These functions are lazy which means that they will create a new modified enumeration without actually enumerating any element until they are asked to do so by the programmer (using one of the functions above).
When the resulting enumerations of these functions are consumed, the underlying enumerations they were created from are also consumed.
val map : ('a -> 'b) -> 'a t -> 'b t
map f e
returns an enumeration over (f a0, f a1, ...)
where a0,a1...
are the elements of e
. Lazy.
val mapi : (int -> 'a -> 'b) -> 'a t -> 'b t
mapi
is similar to map
except that f
is passed one extra argument which is the index of the element in the enumeration, starting from 0 : mapi f e returns an enumeration over (f 0 a0, f 1 a1, ...)
where a0,a1...
are the elements of e
.
val filter : ('a -> bool) -> 'a t -> 'a t
filter f e
returns an enumeration over all elements x
of e
such as f x
returns true
. Lazy.
Note filter is lazy in that it returns a lazy enumeration, but each element in the result is eagerly searched in the input enumeration. Therefore, the access to a given element in the result will diverge if it is preceded, in the input enumeration, by infinitely many false elements (elements on which the predicate p
returns false
).
Other functions that may drop an unbound number of elements (filter_map
, take_while
, etc.) have the same behavior.
val filter_map : ('a -> 'b option) -> 'a t -> 'b t
filter_map f e
returns an enumeration over all elements x
such as f y
returns Some x
, where y
is an element of e
.
filter_map
works on infinite enumerations; see filter
.
val append : 'a t -> 'a t -> 'a t
append e1 e2
returns an enumeration that will enumerate over all elements of e1
followed by all elements of e2
. Lazy.
Note The behavior of appending e
to itself or to something derived from e
is not specified. In particular, cloning append e e
may destroy any sharing between the first and the second argument.
val prefix_action : (unit -> unit) -> 'a t -> 'a t
prefix_action f e
will behave as e
but guarantees that f ()
will be invoked exactly once before the current first element of e
is read.
If prefix_action f e
is cloned, f
is invoked only once, during the cloning. If prefix_action f e
is counted, f
is invoked only once, during the counting.
May be used for signalling that reading starts or for performing delayed evaluations.
val suffix_action : (unit -> unit) -> 'a t -> 'a t
suffix_action f e
will behave as e
but guarantees that f ()
will be invoked after the contents of e
are exhausted.
If suffix_action f e
is cloned, f
is invoked only once, when the original enumeration is exhausted. If suffix_action f e
is counted, f
is only invoked if the act of counting requires a call to force
.
May be used for signalling that reading stopped or for performing delayed evaluations.
val concat : 'a t t -> 'a t
concat e
returns an enumeration over all elements of all enumerations of e
.
val flatten : 'a t t -> 'a t
val concat_map : ('a -> 'b t) -> 'a t -> 'b t
Synonym of Monad.bind
, with flipped arguments. concat_map f e
is the same as concat (map f e)
.
Constructors
In this section the word shall denotes a semantic requirement. The correct operation of the functions in this interface are conditional on the client meeting these requirements.
exception No_more_elements
This exception shall be raised by the next
function of make
or from
when no more elements can be enumerated, it shall not be raised by any function which is an argument to any other function specified in the interface.
As a convenience for debugging, this exception may be raised by the count
function of make
when attempting to count an infinite enum.
The empty enumeration : contains no element
val make :
next:(unit -> 'a) ->
count:(unit -> int) ->
clone:(unit -> 'a t) ->
'a t
This function creates a fully defined enumeration.
- the
next
function shall return the next element of the enumeration or raise No_more_elements
if the underlying data structure does not have any more elements to enumerate. - the
count
function shall return the actual number of remaining elements in the enumeration or may raise Infinite_enum
if it is known that the enumeration is infinite. - the
clone
function shall create a clone of the enumeration such as operations on the original enumeration will not affect the clone.
For some samples on how to correctly use make
, you can have a look at implementation of BatList.enum
.
val from : (unit -> 'a) -> 'a t
from next
creates an enumeration from the next
function. next
shall return the next element of the enumeration or raise No_more_elements
when no more elements can be enumerated. Since the enumeration definition is incomplete, a call to count
will result in a call to force
that will enumerate all elements in order to return a correct value.
val from_while : (unit -> 'a option) -> 'a t
from_while next
creates an enumeration from the next
function. next
shall return Some x
where x
is the next element of the enumeration or None
when no more elements can be enumerated. Since the enumeration definition is incomplete, a call to clone
or count
will result in a call to force
that will enumerate all elements in order to return a correct value.
val from_loop : 'b -> ('b -> 'a * 'b) -> 'a t
from_loop data next
creates a (possibly infinite) enumeration from the successive results of applying next
to data
, then to the result, etc. The list ends whenever the function raises BatEnum.No_more_elements
.
val seq : 'a -> ('a -> 'a) -> ('a -> bool) -> 'a t
seq init step cond
creates a sequence of data, which starts from init
, extends by step
, until the condition cond
fails. E.g. seq 1 ((+) 1) ((>) 100)
returns 1, 2, ... 99
. If cond
init
is false, the result is empty.
val unfold : 'b -> ('b -> ('a * 'b) option) -> 'a t
As from_loop
, except uses option type to signal the end of the enumeration.
unfold data next
creates a (possibly infinite) enumeration from the successive results of applying next
to data
, then to the result, etc. The enumeration ends whenever the function returns None
Example: Enum.unfold n (fun x -> if x = 1 then None else Some
(x, if x land 1 = 1 then 3 * x + 1 else x / 2))
returns the hailstone sequence starting at n
.
val init : int -> (int -> 'a) -> 'a t
init n f
creates a new enumeration over elements f 0, f 1, ..., f (n-1)
val singleton : 'a -> 'a t
Create an enumeration consisting of exactly one element.
val repeat : ?times:int -> 'a -> 'a t
repeat ~times:n x
creates a enum sequence filled with n
times of x
. It return infinite enum when ~times
is absent. It returns empty enum when times <= 0
val cycle : ?times:int -> 'a t -> 'a t
cycle
is similar to repeat
, except that the content to fill is a subenum rather than a single element. Note that times
represents the times of repeating not the length of enum. When ~times
is absent the result is an infinite enum.
val delay : (unit -> 'a t) -> 'a t
delay (fun () -> e)
produces an enumeration which behaves as e
. The enumeration itself will only be computed when consumed.
A typical use of this function is to explore lazily non-trivial data structures, as follows:
type 'a tree = Leaf
| Node of 'a * 'a tree * 'a tree
let enum_tree =
let rec aux = function
| Leaf -> BatEnum.empty ()
| Node (n, l, r) -> BatEnum.append (BatEnum.singleton n)
(BatEnum.append (delay (fun () -> aux l))
(delay (fun () -> aux r)))
val to_object : 'a t -> < next : 'a ; count : int ; clone : 'b > as 'b
to_object e
returns a representation of e
as an object.
val of_object : < next : 'a ; count : int ; clone : 'b > as 'b -> 'a t
of_object e
returns a representation of an object as an enumeration
identity : added for consistency with the other data structures
val of_enum : 'a t -> 'a t
identity : added for consistency with the other data structures
identity : added for consistency with the other data structures
Counting
count e
returns the number of remaining elements in e
without consuming the enumeration.
Depending of the underlying data structure that is implementing the enumeration functions, the count operation can be costly, and even sometimes can cause a call to force
.
val fast_count : 'a t -> bool
For users worried about the speed of count
you can call the fast_count
function that will give an hint about count
implementation. Basically, if the enumeration has been created with make
or init
or if force
has been called on it, then fast_count
will return true.
val hard_count : 'a t -> int
hard_count
returns the number of remaining in elements in e
, consuming the whole enumeration somewhere along the way. This function is always at least as fast as the fastest of either count
or a fold
on the elements of t
.
This function is useful when you have opened an enumeration for the sole purpose of counting its elements (e.g. the number of lines in a file).
Utilities
val range : ?until:int -> int -> int t
range p until:q
creates an enumeration of integers [p, p+1, ..., q]
. If until
is omitted, the enumeration is not bounded. Behaviour is not-specified once max_int
has been reached.
val dup : 'a t -> 'a t * 'a t
dup stream
returns a pair of streams which are identical to stream
. Note that stream is a destructive data structure, the point of dup
is to return two streams can be used independently.
val combine : ('a t * 'b t) -> ('a * 'b) t
combine
transform a pair of stream into a stream of pairs of corresponding elements. If one stream is short, excess elements of the longer stream are ignored.
val uncombine : ('a * 'b) t -> 'a t * 'b t
uncombine
is the opposite of combine
val merge : ('a -> 'a -> bool) -> 'a t -> 'a t -> 'a t
merge test a b
merge the elements from a
and b
into a single enumeration. At each step, test
is applied to the first element xa
of a
and the first element xb
of b
to determine which should get first into resulting enumeration. If test xa xb
returns true
, xa
(the first element of a
) is used, otherwise xb
is used. If a
or b
runs out of elements, the process will append all elements of the other enumeration to the result.
For example, if a
and b
are enumerations of integers sorted in increasing order, then merge (<) a b
will also be sorted.
val interleave : 'a t array -> 'a t
interleave enums
creates a new enumeration from an array of enumerations. The new enumeration first yields the first elements of the enumerations in the supplied order, then second elements, etc. Thus, a sequence [| [x11 ; x12 ; ...] ; [x21 ; x22, ...] , ... [xN1 ; xN2 ; ...] |]
becomes [ x11 ; x12 ; ... ; xN1 ; x21 ; x22 ; ... ; xN2 ; x31 ; ... ]
.
uniq e
returns a duplicate of e
with repeated values omitted (similar to unix's uniq
command). It uses structural equality to compare consecutive elements.
uniqq e
behaves as uniq e
except it uses physical equality to compare consecutive elements.
val uniq_by : ('a -> 'a -> bool) -> 'a t -> 'a t
uniq_by cmp e
behaves as uniq e
except it allows to specify a comparison function.
val switch : ('a -> bool) -> 'a t -> 'a t * 'a t
switch test enum
splits enum
into two enums, where the first enum have all the elements satisfying test
, the second enum is opposite. The order of elements in the source enum is preserved.
val partition : ('a -> bool) -> 'a t -> 'a t * 'a t
val arg_min : ('a -> 'b) -> 'a t -> 'a
val arg_max : ('a -> 'b) -> 'a t -> 'a
arg_min f xs
returns the x
in xs
for which f x
is minimum. Similarly for arg_max
, except it returns the maximum. If multiple values reach the maximum, one of them is returned. (currently the first, but this is not guaranteed)
Example: -5 -- 5 |> arg_min (fun x -> x * x + 6 * x - 5) = -3
Example: List.enum ["cat"; "canary"; "dog"; "dodo"; "ant"; "cow"] |> arg_max String.length = "canary"
@added v1.4.0
Trampolining
val while_do : ('a -> bool) -> ('a t -> 'a t) -> 'a t -> 'a t
while_do cont f e
is a loop on e
using f
as body and cont
as condition for continuing.
If e
contains elements x0
, x1
, x2
..., then if cont x0
is false
, x0
is returned as such and treatment stops. On the other hand, if cont x0
is true
, f x0
is returned and the loop proceeds with x1
...
Note that f is used as halting condition after the corresponding element has been added to the result stream.
Infix operators
Infix versions of some functions
This module groups together all infix operators so that you can open it without opening the whole batEnum module.
module Infix : sig ... end
val (--) : int -> int -> int t
val (--^) : int -> int -> int t
val (--.) : (float * float) -> float -> float t
val (---) : int -> int -> int t
val (--~) : char -> char -> char t
val (//) : 'a t -> ('a -> bool) -> 'a t
val (/@) : 'a t -> ('a -> 'b) -> 'b t
val (@/) : ('a -> 'b) -> 'a t -> 'b t
val (//@) : 'a t -> ('a -> 'b option) -> 'b t
val (@//) : ('a -> 'b option) -> 'a t -> 'b t
Monadic operations on Enumerations containing monadic elements
module Monad : sig ... end
Boilerplate code
Print and consume the contents of an enumeration.
print_at_most pp limit out enum
consumes enum
to print its elements into out
(using pp
to print individual elements). At most limit
arguments are printed, if more elements are available an ellipsis "..." is added.
val compare : ('a -> 'a -> int) -> 'a t -> 'a t -> int
compare cmp a b
compares enumerations a
and b
by lexicographical order using comparison cmp
.
Same as compare
but returning a BatOrd.order
instead of an interger.
val equal : ('a -> 'a -> bool) -> 'a t -> 'a t -> bool
equal eq a b
returns true
when a
and b
contain the same sequence of elements.
Override modules
The following modules replace functions defined in BatEnum
with functions behaving slightly differently but having the same name. This is by design: the functions meant to override the corresponding functions of BatEnum
.
Operations on BatEnum
without exceptions.