include module type of struct include BatPervasives end
Additional functions.
The initially opened module.
This module provides the basic operations over the built-in types (numbers, booleans, strings, exceptions, references, lists, arrays, input-output channels, ...)
This module is automatically opened at the beginning of each compilation. All components of this module can therefore be referred by their short name, without prefixing them by BatPervasives
.
Returns an enumeration over lines of an input channel, as read by the input_line
function.
Returns an enumeration over characters of an input channel.
Returns the list of lines read from an input channel.
Return the whole contents of an input channel as a single string.
Attempt to convert a value to a string.
Works well for a lot of cases such as non-empty lists, algebraic datatype, and records.
However, since types are lost at compile-time, the representation might not match your type. (0, 1) will be printed as expected, but (1, 0) and 1
have the same representation and will get printed in the same way. The result of dump
is unspecified and may change in future versions, so you should only use it for debugging and never have program behavior depend on the output.
Here is a list of some of the surprising corner cases of the current implementation:
- (3, 0) is printed
3
, (0.5, 0) is printed 0.5
, etc. - None, false and are printed 0
dump
may fail for ill-formed values, such as obtained from a faulty C binding or crazy uses of Obj.set_tag
.
Attempt to print a value to an output.
Uses dump
to convert the value to a string and prints that string to the output.
List operations
More list operations are provided in module List
.
val (@) : 'a list -> 'a list -> 'a list
This section only contains the most common input/output operations. More operations may be found in modules BatIO
and File
.
Standard input, as per Unix/Windows conventions (by default, keyboard).
Use this input to read what the user is writing on the keyboard.
Standard output, as per Unix/Windows conventions (by default, console).
Use this output to display regular messages.
Standard error output, as per Unix/Windows conventions.
Use this output to display warnings and error messages.
An output which discards everything written to it.
Use this output to ignore messages.
val flush_all : unit -> unit
Write all pending data to output channels, ignore all errors.
It is normally not necessary to call this function, as all pending data is written when an output channel is closed or when the program itself terminates, either normally or because of an uncaught exception. However, this function is useful for debugging, as it forces pending data to be written immediately.
Output functions on standard output
val print_bool : bool -> unit
Print a boolean on standard output.
Attempt to print the representation of a runtime value on the standard output. See remarks for dump
. This function is useful mostly for debugging. As a general rule, it should not be used in production code.
Print the contents of an input to the standard output.
Output functions on standard error
val prerr_bool : bool -> unit
Print a boolean to stderr.
val prerr_guess : 'a -> unit
Attempt to print the representation of a runtime value on the error output. See remarks for dump
. This function is useful mostly for debugging.
Print the contents of an input to the error output.
General output functions
val output_file : filename:string -> text:string -> unit
creates a filename, write text into it and close it.
Open the named file for writing, and return a new output channel on that file. You will need to close the file once you have finished using it.
You may use optional argument mode
to decide whether the output will overwrite the contents of the file (by default) or to add things at the end of the file, whether the file should be created if it does not exist yet (the default) or not, whether this operation should proceed if the file exists already (the default) or not, whether the file should be opened as text (the default) or as binary, and whether the file should be opened for non-blocking operations.
You may use optional argument perm
to specify the permissions of the file, as per Unix conventions. By default, files are created with default permissions (which depend on your setup).
Same as open_out
, but the file is opened in binary mode, so that no translation takes place during writes. On operating systems that do not distinguish between text mode and binary mode, this function behaves like open_out
without any mode
or perm
.
open_out_gen mode perm filename
opens the named file for writing, as described above. The extra argument mode
specifies the opening mode. The extra argument perm
specifies the file permissions, in case the file must be created.
Flush the buffer associated with the given output, performing all pending writes on that channel. Interactive programs must be careful about flushing standard output and standard error at the right time.
Write the character on the given output channel.
Write the string on the given output channel.
output oc buf pos len
writes len
characters from byte sequence buf
, starting at offset pos
, to the given output channel oc
.
val output_substring : unit BatIO.output -> string -> int -> int -> unit
output_substring oc buf pos len
writes len
characters from string buf
, starting at offset pos
, to the given output channel oc
.
Write one 8-bit integer (as the single character with that code) on the given output channel. The given integer is taken modulo 256.
Write one integer in binary format (4 bytes, big-endian) on the given output channel. The given integer is taken modulo 232. The only reliable way to read it back is through the Pervasives.input_binary_int
function. The format is compatible across all machines for a given version of OCaml.
val output_binary_float : unit BatIO.output -> float -> unit
Write one float in binary format (8 bytes, IEEE 754 double format) on the given output channel. The only reliable way to read it back is through the Pervasives.input_binary_float
function. The format is compatible across all machines for a given version of OCaml.
Write the representation of a structured value of any type to a channel. Circularities and sharing inside the value are detected and preserved. The object can be read back, by the function input_value
. See the description of module Marshal
for more information. output_value
is equivalent to Marshal.output
with an empty list of flags.
Close the given channel, flushing all buffered write operations. Output functions raise a Sys_error
exception when they are applied to a closed output channel, except close_out
and flush
, which do nothing when applied to an already closed channel.
Same as close_out
, but ignore all errors.
returns the data of a given filename.
Open the named file for reading. You will need to close the file once you have finished using it.
You may use optional argument mode
to decide whether the opening should fail if the file doesn't exist yet (by default) or whether the file should be created if it doesn't exist yet, whether the opening should fail if the file already exists or not (by default), whether the file should be read as binary (by default) or as text, and whether reading should be non-blocking.
You may use optional argument perm
to specify the permissions of the file, should it be created, as per Unix conventions. By default, files are created with default permissions (which depend on your setup).
Same as Pervasives.open_in
, but the file is opened in binary mode, so that no translation takes place during reads. On operating systems that do not distinguish between text mode and binary mode, this function behaves like Pervasives.open_in
.
open_in_gen mode perm filename
opens the named file for reading, as described above. The extra arguments mode
and perm
specify the opening mode and file permissions. Pervasives.open_in
and Pervasives.open_in_bin
are special cases of this function.
Read one character from the given input channel.
Read characters from the given input channel, until a newline character is encountered. Return the string of all characters read, without the newline character at the end.
input ic buf pos len
reads up to len
characters from the given channel ic
, storing them in byte sequence buf
, starting at character number pos
. It returns the actual number of characters read, between 0 and len
(inclusive). A return value of 0 means that the end of file was reached. A return value between 0 and len
exclusive means that not all requested len
characters were read, either because no more characters were available at that time, or because the implementation found it convenient to do a partial read; input
must be called again to read the remaining characters, if desired. (See also Pervasives.really_input
for reading exactly len
characters.)
really_input ic buf pos len
reads len
characters from channel ic
, storing them in byte sequence buf
, starting at character number pos
.
Read a float encoded in binary format (8 bytes, IEEE 754 double format) from the given input channel. See Pervasives.output_binary_float
.
Read the representation of a structured value, as produced by output_value
, and return the corresponding value. This function is identical to Marshal.input
; see the description of module Marshal
for more information, in particular concerning the lack of type safety.
Close the given channel. Input functions raise a Sys_error
exception when they are applied to a closed input channel, except close_in
, which does nothing when applied to an already closed channel.
Same as close_in
, but ignore all errors.
Fundamental functions and operators
val undefined : ?message:string -> 'a -> 'b
The undefined function.
Evaluating undefined x
always fails and raises an exception "Undefined". Optional argument message
permits the customization of the error message.
val (@@) : ('a -> 'b) -> 'a -> 'b
Function application. f @@ x
is equivalent to f x
. However, it binds less tightly (between ::
and =
,<
,>
,etc) and is right-associative, which makes it useful for composing sequences of function calls without too many parentheses. It is similar to Haskell's $
. Note that it replaces pre-2.0 **>
and <|
.
val (%) : ('a -> 'b) -> ('c -> 'a) -> 'c -> 'b
Function composition: the mathematical o
operator. f % g
is fun x -> f (g x)
. It is similar to Haskell's .
.
Examples: the following are equivalent: f (g (h x))
, f @@ g @@ h x
, f % g % h @@ x
.
val (|>) : 'a -> ('a -> 'b) -> 'b
The "pipe": function application. x |> f
is equivalent to f x
.
This operator is commonly used to write a function composition by order of evaluation (the order used in object-oriented programming) rather than by inverse order (the order typically used in functional programming).
For instance, g (f x)
means "apply f
to x
, then apply g
to the result." The corresponding notation in most object-oriented programming languages would be somewhere along the lines of x.f.g.h()
, or "starting from x
, apply f
, then apply g
." In OCaml, using the ( |> ) operator, this is written x |> f |> g |> h
.
This operator may also be useful for composing sequences of function calls without too many parentheses.
val (%>) : ('a -> 'b) -> ('b -> 'c) -> 'a -> 'c
Piping function composition. f %> g
is fun x -> g (f x)
. Whereas f % g
applies g
first and f
second, f %> g
applies f
, then g
. Note that it plays well with pipes, so for instance x |> f %> g %> h |> i %> j
yields the expected result... but in such cases it's still recommended to use |>
only. Note that it replaces pre-2.0 |-
, which didn't integrate with pipes.
val (|?) : 'a option -> 'a -> 'a
Like BatOption.default
, with the arguments reversed. None |? 10
returns 10
, while Some "foo" |? "bar"
returns "foo"
.
Note This operator does not short circuit like ( || )
and ( && )
. Both arguments will be evaluated.
val flip : ('a -> 'b -> 'c) -> 'b -> 'a -> 'c
Argument flipping.
flip f x y
is f y x
. Don't abuse this function, it may shorten considerably your code but it also has the nasty habit of making it harder to read.
val curry : (('a * 'b) -> 'c) -> 'a -> 'b -> 'c
Convert a function which accepts a pair of arguments into a function which accepts two arguments.
curry f
is fun x y -> f (x,y)
val uncurry : ('a -> 'b -> 'c) -> ('a * 'b) -> 'c
Convert a function which accepts two arguments into a function which accepts a pair of arguments.
uncurry f
is fun (x, y) -> f x y
val neg : ('a -> bool) -> 'a -> bool
neg p
returns a new predicate that is the negation of the given predicate. That is, the new predicate returns false
when the input predicate returns true
and vice versa. This is for predicates with one argument.
neg p
is fun x -> not (p x)
val neg2 : ('a -> 'b -> bool) -> 'a -> 'b -> bool
as neg
but for predicates with two arguments
val const : 'a -> _ -> 'a
Ignore its second argument.
const x
is the function which always returns x
.
Returns an unique identifier every time it is called.
Note This is thread-safe.
val tap : ('a -> unit) -> 'a -> 'a
Allows application of a function in the middle of a pipe sequence without disturbing the sequence. x |> tap f
evaluates to x
, but has the side effect of f x
. Useful for debugging.
val finally : (unit -> unit) -> ('a -> 'b) -> 'a -> 'b
finally fend f x
calls f x
and then fend()
even if f x
raised an exception.
val with_dispose : dispose:('a -> unit) -> ('a -> 'b) -> 'a -> 'b
with_dispose dispose f x
invokes f
on x
, calling dispose x
when f
terminates (either with a return value or an exception).
val forever : ('a -> 'b) -> 'a -> unit
forever f x
invokes f
on x
repeatedly (until an exception occurs).
val ignore_exceptions : ('a -> 'b) -> 'a -> unit
ignore_exceptions f x
invokes f
on x
, ignoring both the returned value and the exceptions that may be raised.
val verify_arg : bool -> string -> unit
verify_arg condition message
will raise Invalid_argument message
if condition
is false, otherwise it does nothing.
An enumeration of the arguments passed to this program through the command line.
args ()
is given by the elements of Sys.argv
, minus the first element.
The name of the current executable.
exe
is given by the first argument of Sys.argv
Enumerations
In OCaml Batteries Included, all data structures are enumerable, which means that they support a number of standard operations, transformations, etc. The general manner of enumerating the contents of a data structure is to invoke the enum
function of your data structure.
For instance, you may use the foreach
loop to apply a function f
to all the consecutive elements of a string s
. For this purpose, you may write either foreach (String.enum s) f
or open
String in foreach (enum s) f
. Either possibility states that you are enumerating through a character string s
. Should you prefer your enumeration to proceed from the end of the string to the beginning, you may replace String.enum
with
String.backwards
. Therefore, either foreach (String.backwards s)
f
or open String in foreach (backwards s) f
will apply f
to all the consecutive elements of string s
, from the last to the first.
Similarly, you may use List.enum
instead of String.enum
to visit the elements of a list in the usual order, or List.backwards
instead of String.backwards
to visit them in the opposite order, or Hashtbl.enum
for hash tables, etc.
More operations on enumerations are defined in module BatEnum
, including the necessary constructors to make your own structures enumerable.
The various kinds of loops are detailed further in this documentation.
val foreach : 'a BatEnum.t -> ('a -> unit) -> unit
Imperative loop on an enumeration.
foreach e f
applies function f
to each successive element of e
. For instance, foreach (1 -- 10) print_int
invokes function print_int
on 1
, 2
, ..., 10
, printing 12345678910
.
Note This function is one of the many loops available on enumerations. Other commonly used loops are iter
(same usage scenario as foreach
, but with different notations), map
(convert an enumeration to another enumeration) or fold
(flatten an enumeration by applying an operation to each element).
General-purpose loops
The following functions are the three main general-purpose loops available in OCaml. By opposition to the loops available in imperative languages, OCaml loops are regular functions, which may be passed, composed, currified, etc. In particular, each of these loops may be considered either as a manner of applying a function to a data structure or as transforming a function into another function which will act on a whole data structure.
For instance, if f
is a function operating on one value, you may lift this function to operate on all values of an enumeration (and consequently on all values of any data structure of OCaml Batteries Included) by applying iter
, map
or fold
to this function.
val iter : ('a -> unit) -> 'a BatEnum.t -> unit
Imperative loop on an enumeration. This loop is typically used to lift a function with an effect but no meaningful result and get it to work on enumerations.
If f
is a function iter f
is a function which behaves as f
but acts upon enumerations rather than individual elements. As indicated in the type of iter
, f
must produce values of type unit
(i.e. f
has no meaningful result) the resulting function produces no meaningful result either.
In other words, iter f
is a function which, when applied upon an enumeration e
, calls f
with each element of e
in turn.
For instance, iter f (1 -- 10)
invokes function f
on 1
, 2
, ..., 10
and produces value ()
.
Transformation loop on an enumeration, used to build an enumeration from another enumeration. This loop is typically used to transform an enumeration into another enumeration with the same number of elements, in the same order.
If f
is a function, map f e
is a function which behaves as f
but acts upon enumerations rather than individual elements -- and builds a new enumeration from the results of each application.
In other words, map f
is a function which, when applied upon an enumeration containing elements e0
, e1
, ..., produces enumeration f e0
, f e1
, ...
For instance, if odd
is the function which returns true
when applied to an odd number or false
when applied to an even number, map odd (1 -- 10)
produces enumeration true
, false
, true
, ..., false
.
Similarly, if square
is the function fun x -> x * x
, map square (1 -- 10)
produces the enumeration of the square numbers of all numbers between 1
and 10
.
Similar to a map, except that you can skip over some items of the incoming enumeration by returning None instead of Some value. Think of it as a filter
combined with a map
.
val reduce : ('a -> 'a -> 'a) -> 'a BatEnum.t -> 'a
Transformation loop on an enumeration, used to build a single value from an enumeration.
If f
is a function and e
is an enumeration, reduce f e
applies function f
to the first two elements of e
, then to the result of this expression and to the third element of e
, then to the result of this new expression and to the fourth element of e
...
In other words, reduce f e
returns a0
if e
contains only one element a0
, otherwise f (... (f (f a0) a1) ...) aN
where a0,a1..aN
are the elements of e
.
val fold : ('b -> 'a -> 'b) -> 'b -> 'a BatEnum.t -> 'b
Transformation loop on an enumeration, used to build a single value from an enumeration. This is the most powerful general-purpose loop and also the most complex.
If f
is a function, fold f v e
applies f v
to the first element of e
, then, calling acc_1
the result of this operation, applies f acc_1
to the second element of e
, then, calling acc_2
the result of this operation, applies f acc_2
to the third element of e
...
In other words, fold f v e
returns v
if e
is empty, otherwise f (... (f (f v a0) a1) ...) aN
where a0,a1..aN are the elements of e
.
For instance, if add
is the function fun x y -> x + y
, fold add 0
is the function which computes the sum of the elements of an enumeration. Therefore, fold add 0 (1 -- 10)
produces result 55
.
Functional loop on an enumeration, used to build an enumeration from both an enumeration and an initial value. This function may be seen as a variant of fold
which returns not only the final result of fold
but the enumeration of all the intermediate results of fold
.
If f
is a function, scanl f v e
is applies f v
to the first element of e
, then, calling acc_1
the result of this operation, applies f acc_1
to the second element of e
, then, calling acc_2
the result of this operation, applies f acc_2
to the third element of e
...
For instance, if add
is the function fun x y -> x + y
, scanl add 0
is the function which computes the sum of the elements of an enumeration. Therefore, scanl add 0 (1 -- 10)
produces result the enumeration with elements 0, 1, 3, 6, 10,
15, 21, 28, 36, 45, 55
.
Mapping operators.
These operators have the same meaning as function map
but are sometimes more readable than this function, when chaining several transformations in a row.
Other operations on enumerations
val exists : ('a -> bool) -> 'a BatEnum.t -> bool
exists f e
returns true
if there is some x
in e
such that f x
val for_all : ('a -> bool) -> 'a BatEnum.t -> bool
for_all f e
returns true
if for every x
in e
, f x
is true
val find : ('a -> bool) -> 'a BatEnum.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, or, raises Not_found
if no such element exists in the enumeration, consuming the whole enumeration in the search.
Since find
consumes a prefix of the enumeration, it can be used several times on the same enumeration to find the next element.
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.
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.
push e x
will add x
at the beginning of e
.
junk e
removes the first element from the enumeration, if any.
filter f e
returns an enumeration over all elements x
of e
such as f x
returns true
.
Filtering (pronounce this operator name "such that").
For instance, (1 -- 37) // odd
is the enumeration of all odd numbers between 1 and 37.
concat e
returns an enumeration over all elements of all enumerations of e
.
Enumerate numbers.
5 -- 10
is the enumeration 5,6,7,8,9,10. 10 -- 5
is the empty enumeration
Enumerate numbers, without the right endpoint
5 -- 10
is the enumeration 5,6,7,8,9.
val (--.) : (float * float) -> float -> float BatEnum.t
(a, step) --. b)
creates a float enumeration from a
to b
with an increment of step
between elements.
(5.0, 1.0) --. 10.0
is the enumeration 5.0,6.0,7.0,8.0,9.0,10.0. (10.0, -1.0) --. 5.0
is the enumeration 10.0,9.0,8.0,7.0,6.0,5.0. (10.0, 1.0) --. 1.0
is the empty enumeration.
As --
, but accepts enumerations in reverse order.
5 --- 10
is the enumeration 5,6,7,8,9,10. 10 --- 5
is the enumeration 10,9,8,7,6,5.
As ( -- ), but for characters.
Print and consume the contents of an enumeration.
Results
type ('a, 'e) result = ('a, 'e) BatInnerPervasives.result =
| Ok of 'a
| Error of 'e
The result of a computation - either an Ok
with the normal result or a Error
with some value (often an exception) containing failure information
This type represents the outcome of a function which has the possibility of failure. Normal results of type 'a
are marked with Ok
, while failure values of type 'b
are marked with Error
.
This is intended to be a safer alternative to functions raising exceptions to signal failure. It is safer in that the possibility of failure has to be handled before the result of that computation can be used.
For more functions related to this type, see the BatResult
module.
val ignore_ok : ('a, exn) result -> unit
ignore_ok (f x)
ignores the result of f x
if it's ok, but throws the exception contained if Error
is returned.
val ok : ('a, exn) result -> 'a
f x |> ok
unwraps the Ok
result of f x
and returns it, or throws the exception contained if Error
is returned.
val wrap : ('a -> 'b) -> 'a -> ('b, exn) result
wrap f x
wraps a function that would normally throw an exception on failure such that it now returns a result with either the Ok
return value or the Error
exception.
Thread-safety internals
Unless you are attempting to adapt Batteries Included to a new model of concurrency, you probably won't need this.
A lock used to synchronize internal operations.
By default, this is BatConcurrent.nolock
. However, if you're using a version of Batteries compiled in threaded mode, this uses BatMutex
. If you're attempting to use Batteries with another concurrency model, set the lock appropriately.