class IO::Handle

Opened file or stream

class IO::Handle { }

Methods

method get

Reads a single line from the input stream (usually the Standard Input or a file).

Read one line from the standard input:

$*IN.get;

Read one line from a file:

my $fh = open 'filename';
my $line = $fh.get;

method getc

Read a single character from the input stream or return Nil. The operation will block for at least one character to be available, but there are a few caveats for this:

Buffering terminals

Using getc to get a single keypress from a terminal will only work properly if you've set the terminal to "unbuffered". Otherwise the terminal will wait for the return key to be struck or the buffer to be filled up before perl6 gets even a single byte of data.

Waiting for potential combiners

If your handler's encoding allows combining characters to be read, perl6 will wait for more data to be available before it provides a character. This means that inputting an "e" followed by a combining acute will give you an e with an acute rather than giving an "e" and letting the next reading function give you a dangling combiner. However, it also means that when the user inputs just an "e" and has no intention to also input a combining acute, your program will be waiting for another keypress before the initial "e" is returned.

method eof

Returns True if the read operations have exhausted the content of the file.

method lines

method lines($limit = Inf)

Return a lazy list of the file's lines read via get, limited to $limit lines. The new line separator (i.e., $*IN.nl-in) will be excluded.

my @data;
my $data-file = open 'readings.csv';
for $data-file.lines -> $line {
    @data.push($line.split(','))
}

method lock

method lock(IO::Handle:D: Bool:D :$non-blocking = FalseBool:D :$shared = False --> True)

Places an advisory lock on the filehandle. If :$non-blocking is True will fail with X::IO::Lock if lock could not be obtained, otherwise will block until the lock can be placed. If :$shared is True will place a shared (read) lock, otherwise will place an exclusive (read) lock. On success, returns True; fails with X::IO::Lock if lock cannot be placed (e.g. when trying to place a shared lock on a filehandle opened in write mode or trying to place an exclusive lock on a filehandle opened in read mode).

You can use lock again to replace an existing lock with another one. Use close the filehandle or use unlock to remove a lock.

# One program writes, the other reads, and thanks to locks either 
# will wait for the other to finish before proceeding to read/write 

# Writer with "foo".IO.open(:w) { .lock; .spurt: "I ♥ Perl 6!"; .close; }

# Reader with "foo".IO.open { .lock: :shared; .slurp.say; # OUTPUT: «I ♥ Perl 6!␤» .close; }

method unlock

method unlock(IO::Handle:D: --> True)

Removes a lock from the filehandle.

method words

method words($count = Inf)

Return a lazy list of the file's words (separated on whitespace), limited to $count words.

my %dict;
++%dict{$_} for $*IN.words;
say "Most common words: "%dict.sort(*.value).reverse.[^5];

method split

multi method split(IO::Handle:D: :$close = False:$COMB)
multi method split(IO::Handle:D: $splitter:$close = False:$COMB)

Returns a lazy list of strings found between the splitter, just like split on strings.

my $fh = open 'path/to/file':r;
$fn.split(' 'close => True); # Returns file content split by a space and closes file; 

method spurt

multi method spurt(IO::Handle:D: Blob $data:$close = False)
multi method spurt(IO::Handle:D: Cool $data:$close = False)

Writes all of the $data into the filehandle, closing it when finished, if $close is True. For Cool $data, will use the encoding the handle is set to use (IO::Handle.open or IO::Handle.encoding).

Behaviour for spurting a Cool when the handle is in binary mode or spurting a Blob when the handle is NOT in binary mode is undefined.

method comb

multi method comb(IO::Handle:D: :$close = False)
multi method comb(IO::Handle:D: Int:D $size:$close = False)
multi method comb(IO::Handle:D: $comber:$close = False)

Returns a lazy list of strings combed from the handle, just like comb on strings.

my $fh = open 'path/to/file':r;
$fn.comb(/A+/); # Comb file contents by a regex. 

or

my $fh = open 'path/to/file':r;
$fn.comb(3close => True); # Comb file contents by 3 characters and close after. 

method print

method print(*@text --> Bool)

Text writing; writes the given @text to the filehandle. See write to write bytes.

my $fh = open 'path/to/file':w;
$fh.print("some text\n");
$fh.close;

method print-nl

method print-nl(IO::Handle:D: --> True)

Writes a newline to the filehandle. The newline marker, which is stored in the attribute $.nl-out, defaults to \n unless another marker has been specified in the call to open.

my $fh = open 'path/to/file':wnl-out => "\r\n";
$fh.print("some text");
$fh.print-nl;                                        # \r\n 
$fh.close;

method printf

method printf(IO::Handle:D: Cool $format*@args)

Formats a string based on the given format and arguments and .prints the result into the filehandle. See sub sprintf for details on acceptable format directives.

my $fh = open 'path/to/file':w;
$fh.printf: "The value is %d\n"32;
$fh.close;

method say

method say(IO::Handle:D: |)

This method is identical to print except that it stringifies its arguments by calling .gist on them and auto-appends a newline, with a call to print-nl, after the final argument.

my $fh = open 'path/to/file':w;
$fh.say(Complex.new(34));        # RESULT: «3+4i\n» 
$fh.close;

method read

method read(IO::Handle:D: Int(Cool:D$bytes --> Blob)

Binary reading; reads and returns up to $bytes bytes from the filehandle.

method readchars

method readchars(IO::Handle:D: Int(Cool:D$chars --> Str)

Reading chars; reads and returns up to $chars chars (graphemes) from the filehandle.

method write

method write(IO::Handle:D: Blob:D $buf)

Binary writing; writes $buf to the filehandle. See print to write characters.

method seek

method seek(IO::Handle:D: Int:D $offsetSeekType:D $whence --> True)

Move the file pointer (that is, the position at which any subsequent read or write operations will begin) to the byte position specified by $offset relative to the location specified by $whence which may be one of:

The beginning of the file.

The current position in the file.

The end of the file. Please note that you need to specify a negative offset if you want to position before the end of the file.

method tell

method tell(IO::Handle:D: --> Int)

Return the current position of the file pointer in bytes.

method slurp-rest

multi method slurp-rest(IO::Handle:D: :$bin! --> Buf)
multi method slurp-rest(IO::Handle:D: :$enc --> Str)

DEPRECATION NOTICE: this method will be deprecated in 6.d language. Do not use it for new code. Use .slurp method method instead.

Return the remaining content of the file from the current file position (which may have been set by previous reads or by seek.) If the adverb :bin is provided a Buf will be returned, otherwise the return will be a Str with the optional encoding :enc.

method slurp

method slurp(IO::Handle:D: :$close = False)

Returns all the content from the current file position to the end. If the invocant is in binary mode, will return Buf, otherwise will decode the content using invocant's current .encoding and return a Str.

If :$close is set to True, will close the handle when finished reading.

method Supply

multi method Supply(IO::Handle:D: :$size = 65536)

Returns a Supply that will emit the contents of the handle in chunks. The chunks will be Buf if the handle is in binary mode or, if it isn't, Str decoded using same encoding as IO::Handle.encoding.

The size of the chunks is determined by the optional :size named parameter and 65536 bytes in binary mode or 65536 characters in non-binary mode.

    "foo".IO.open(:bin).Supply(:size<10>).tap: *.perl.say;
    # OUTPUT: 
    # Buf[uint8].new(73,32,226,153,165,32,80,101,114,108) 
    # Buf[uint8].new(32,54,33,10) 
"foo".IO.open.Supply(:size<10>).tap: *.perl.say;
# OUTPUT: 
# "I ♥ Perl 6" 
# "!\n" 

method path

For a handle opened on a file this returns the IO::Path that represents the file. For the standard I/O handles $*IN, $*OUT, and $*ERR it returns an IO::Special object.

method IO

Alias for .path

method Str

Returns the value of .path, coerced to Str.

    say "foo".IO.open.path# OUTPUT: «"foo".IO␤» 

method close

Will close a previously opened filehandle.

$fh.close;

method flush

Will flush the filehandle to disk.

$fh.flush;

method native-descriptor

method native-descriptor()

This returns a value that the operating system would understand as a "file descriptor" and is suitable for passing to a native function that requires a file descriptor as an argument such as fcntl or ioctl.

method opened

method opened(IO::Handle:D: --> Bool)

Returns True if the handle is open.

method t

method t(IO::Handle:D: --> Bool)

Returns True if the handle is opened to a tty.

Related roles and classes

See also the related role IO and the related class IO::Path.

Type graph

Type relations for IO::Handle
perl6-type-graph IO::Handle IO::Handle Any Any IO::Handle->Any Mu Mu Any->Mu IO::Pipe IO::Pipe IO::Pipe->IO::Handle IO::ArgFiles IO::ArgFiles IO::ArgFiles->IO::Handle

Stand-alone image: vector

Routines supplied by class Any

IO::Handle inherits from class Any, which provides the following methods:

(Any) method ACCEPTS

Defined as:

multi method ACCEPTS(Any:D: Mu $other)

Usage:

EXPR.ACCEPTS(EXPR);

Returns True if $other === self (i.e. it checks object identity).

Many built-in types override this for more specific comparisons

(Any) method any

Defined as:

method any(--> Junction:D)

Interprets the invocant as a list and creates an any-Junction from it.

say so 2 == <1 2 3>.any;        # OUTPUT: «True␤» 
say so 5 == <1 2 3>.any;        # OUTPUT: «False␤» 

(Any) method all

Defined as:

method all(--> Junction:D)

Interprets the invocant as a list and creates an all-Junction from it.

say so 1 < <2 3 4>.all;         # OUTPUT: «True␤» 
say so 3 < <2 3 4>.all;         # OUTPUT: «False␤» 

(Any) method one

Defined as:

method one(--> Junction:D)

Interprets the invocant as a list and creates a one-Junction from it.

say so 1 == (123).one;      # OUTPUT: «True␤» 
say so 1 == (121).one;      # OUTPUT: «False␤» 

(Any) method none

Defined as:

method none(--> Junction:D)

Interprets the invocant as a list and creates a none-Junction from it.

say so 1 == (123).none;     # OUTPUT: «False␤» 
say so 4 == (123).none;     # OUTPUT: «True␤» 

(Any) method list

Defined as:

method list(--> List:D)

Interprets the invocant as a list, and returns that List.

say 42.list.^name;           # OUTPUT: «List␤» 
say 42.list.elems;           # OUTPUT: «1␤» 

(Any) method push

Defined as:

method push(|values --> Positional:D)

The method push is defined for undefined invocants and allows for autovivifying undefined to an empty Array, unless the undefined value implements Positional already. The argument provided will then be pushed into the newly created Array.

my %h;
dd %h<a>;      # Any (and therefore undefined) 
%h<a>.push(1); # .push on Any 
dd %h;         # «Hash %h = {:a($[1])}␤» # please note the Array 

(Any) routine reverse

Defined as:

multi sub    reverse(*@list  --> Seq:D)
multi method reverse(List:D: --> Seq:D)

Returns a Seq say reverse ^10; # OUTPUT: «(9 8 7 6 5 4 3 2 1 0)␤»

(Any) method sort

Sorts iterables with infix:<cmp> or given code object and returns a new List.

Examples:

say <b c a>.sort;                           # OUTPUT: «(a b c)␤» 
say 'bca'.comb.sort.join;                   # OUTPUT: «abc␤» 
say 'bca'.comb.sort({$^b cmp $^a}).join;    # OUTPUT: «cba␤» 
say '231'.comb.sort(&infix:«<=>»).join;     # OUTPUT: «123␤» 

(Any) method map

Defined as:

multi method map(\SELF: &block;; :$label:$item)
multi method map(HyperIterable:D: &block;; :$label)

map will iterate over the invocant and apply the number of positional parameters of the code object from the invocant per call. The returned values of the code object will become elements of the returned Seq.

The :$label and :$item are useful only internally, since for loops get converted to maps. The :$label takes an existing Label to label the .map's loop with and :$item controls whether the iteration will occur over (SELF,) (if :$item is set) or SELF.

(Any) method deepmap

Defined as:

method deepmap(&block --> Listis nodal

deepmap will apply &block to each element and return a new List with the return values of &block, unless the element does the Iterable role. For those elements deepmap will descend recursively into the sublist.

dd [[1,2,3],[[4,5],6,7]].deepmap(*+1);
# OUTPUT: «[[2, 3, 4], [[5, 6], 7, 8]]␤» 

(Any) method duckmap

Defined as:

method duckmap(&blockis rw is nodal

duckmap will apply &block on each element and return a new list with defined return values of the block. For undefined return values, duckmap will try to descend into the element if that element implements Iterable.

my @a = [1,[2,3],4];
dd @a.duckmap({ $_ ~~ Int ?? $_++ !! Any });
# OUTPUT: «(1, (2, 3), 4)␤» 

(Any) method flat

Defined as:

method flat(--> Seq:Dis nodal

Interprets the invocant as a list, flattens it, and returns that list. Please note that .flat will not solve the halting problem for you. If you flat an infinite list .flat may return that infinite list, eating all your RAM in the process.

say ((12), (3)).elems;        # OUTPUT: «2␤» 
say ((12), (3)).flat.elems;   # OUTPUT: «3␤» 

Please note that flat does not recurse into sub lists. You have to recurse by hand or reconsider your data structures. A single level of nesting can often be handled with destructuring in signatures. For deeper structures you may consider gather/take to create a lazy list.

my @a = [[1,2,3],[[4,5],6,7]];
say gather deepmap *.take@a# OUTPUT: «(1 2 3 4 5 6 7)␤» 

(Any) method eager

Defined as:

method eager(--> Seq:Dis nodal

Interprets the invocant as a list, evaluates it eagerly, and returns that list.

say (1..10).eager;              # OUTPUT: «(1 2 3 4 5 6 7 8 9 10)␤» 

(Any) method elems

Defined as:

method elems(--> Int:Dis nodal

Interprets the invocant as a list, and returns the number of elements in the list.

say 42.elems;                   # OUTPUT: «1␤» 
say <a b c>.elems;              # OUTPUT: «3␤» 

(Any) method end

method end(--> Any:Dis nodal

Interprets the invocant as a list, and returns the last index of that list.

say 6.end;                      # OUTPUT: «0␤» 
say <a b c>.end;                # OUTPUT: «2␤» 

(Any) method pairup

Defined as:

method pairup(--> Seq:Dis nodal

Interprets the invocant as a list, and constructs a list of pairs from it, in the same way that assignment to a Hash does. That is, it takes two consecutive elements and constructs a pair from them, unless the item in the key position already is a pair (in which case the pair is passed is passed through, and the next list item, if any, is considered to be a key again).

say (=> 1'b''c').pairup.perl;     # OUTPUT: «(:a(1), :b("c")).Seq␤» 

(Any) sub exit

Defined as:

sub exit(Int() $status = 0)

Exits the current process with return code $status.

(Any) sub item

Defined as:

proto sub item(|) is pure
multi sub item(\x)
multi sub item(|c)
multi sub item(Mu $a)

Forces given object to be evaluated in item context and returns the value of it.

say item([1,2,3]).perl;              # OUTPUT: «$[1, 2, 3]␤» 
say item({ apple => 10 }).perl;      # OUTPUT: «${:apple(10)}␤» 
say item("abc").perl;                # OUTPUT: «"abc"␤» 

You can also use $ as item contextualizer.

say $[1,2,3].perl;                   # OUTPUT: «$[1, 2, 3]␤» 
say $("abc").perl;                   # OUTPUT: «"abc"␤» 

(Any) method Array

Defined as:

method Array(--> Array:Dis nodal

Coerce the invocant to Array.

(Any) method List

Defined as:

method List(--> List:Dis nodal

Coerce the invocant to List.

(Any) method Hash

Defined as:

method Hash(--> Hash:Dis nodal

Coerce the invocant to Hash.

(Any) method hash

Defined as:

method hash(--> Hash:Dis nodal

Coerce the invocant to Hash.

(Any) method Slip

Defined as:

method Slip(--> Slip:Dis nodal

Coerce the invocant to Slip.

(Any) method Map

Defined as:

method Map(--> Map:Dis nodal

Coerce the invocant to Map.

(Any) method Bag

Defined as:

method Bag(--> Bag:Dis nodal

Coerce the invocant to Bag, whereby Positionals are treated as lists of values.

(Any) method BagHash

Defined as:

method BagHash(--> BagHash:Dis nodal

Coerce the invocant to BagHash, whereby Positionals are treated as lists of values.

(Any) method Set

Defined as:

method Set(--> Set:Dis nodal

Coerce the invocant to Set, whereby Positionals are treated as lists of values.

(Any) method SetHash

Defined as:

method SetHash(--> SetHash:Dis nodal

Coerce the invocant to SetHash, whereby Positionals are treated as lists of values.

(Any) method Mix

Defined as:

method Mix(--> Mix:Dis nodal

Coerce the invocant to Mix, whereby Positionals are treated as lists of values.

(Any) method MixHash

Defined as:

method MixHash(--> MixHash:Dis nodal

Coerce the invocant to MixHash, whereby Positionals are treated as lists of values.

(Any) method Supply

Defined as:

method Supply(--> Supply:Dis nodal

Coerce the invocant first to a List and then to a Supply.

(Any) method min

Defined As:

multi method min(--> Any:D)
multi method min(&by --> Any:D)

Coerces to Iterable and returns the numerically smallest element. If a Callable is provided it is called with each element and its smallest return values is returned.

(Any) method max

Defined As:

multi method max(--> Any:D)
multi method min(&by --> Any:D)

Coerces to Iterable and returns the numerically biggest element. If a Callable is provided it is called with each element and its biggest return values is returned.

(Any) method minmax

Defined As:

multi method minmax(--> List:D)
multi method minmax(&by --> List:D)

Returns a list containing the smallest and the biggest element. If a Callable is provided each element is filtered and then numerically compared.

TODO

(Any) method minpairs

Defined As:

multi method minpairs(Any:D: --> Seq:D)

Calls .pairs and returns a Seq with all of the Pairs with minimum values, as judged by the cmp operator:

<a b c a b c>.minpairs.perl.put# OUTPUT: «(0 => "a", 3 => "a").Seq␤» 
%(:42a, :75b).minpairs.perl.put# OUTPUT: «(:a(42),).Seq␤» 

(Any) method maxpairs

Defined As:

multi method maxpairs(Any:D: --> Seq:D)

Calls .pairs and returns a Seq with all of the Pairs with maximum values, as judged by the cmp operator:

<a b c a b c>.maxpairs.perl.put# OUTPUT: «(2 => "c", 5 => "c").Seq␤» 
%(:42a, :75b).maxpairs.perl.put# OUTPUT: «(:b(75),).Seq␤» 

(Any) method sum

Defined As:

    method sum(--> TODO)

TODO

(Any) method keys

Defined As:

    method keys(--> TODO)

TODO

(Any) method flatmap

Defined As:

    method flatmap(--> TODO)

TODO

(Any) method roll

Defined As:

    method roll(--> TODO)

TODO

(Any) method pick

Defined As:

    method pick(--> TODO)

TODO

(Any) method head

Defined As:

    method head(--> TODO)

TODO

(Any) method tail

Defined As:

    method tail(--> TODO)

TODO

(Any) method skip

Defined As:

    method skip(--> TODO)

TODO

(Any) method prepend

Defined As:

    method prepend(--> TODO)

TODO

(Any) method unshift

Defined As:

    method unshift(--> TODO)

TODO

(Any) method first

Defined As:

    method first(--> TODO)

TODO

(Any) method unique

Defined As:

    method unique

Treats the Any as a 1-item list and uses List.unique on it.

(Any) method repeated

Defined As:

    method repeated(--> TODO)

TODO

(Any) method squish

Defined As:

    method squish(--> TODO)

TODO

(Any) method reduce

Defined As:

    method reduce(--> TODO)

TODO

(Any) method permutations

Defined As:

    method permutations(--> TODO)

TODO

(Any) method categorize

Defined As:

    method categorize(--> TODO)

TODO

(Any) method classify

Defined As:

    method classify(--> TODO)

TODO

(Any) method produce

Defined As:

    method produce(--> TODO)

TODO

(Any) method rotor

Defined As:

    method rotor(--> TODO)

TODO

(Any) method pairs

Defined As:

    method pairs(--> TODO)

TODO

(Any) method antipairs

Defined As:

    method antipairs(--> TODO)

TODO

(Any) method kv

Defined As:

    method kv(--> TODO)

TODO

(Any) method tree

Defined As:

    method tree(--> TODO)

TODO

(Any) method nl-out

Defined As:

    method nl-out(--> TODO)

TODO

(Any) method invert

Defined As:

    method invert(--> TODO)

TODO

(Any) method combinations

Defined As:

    method combinations(--> TODO)

TODO

(Any) method print-nl

Defined As:

    method print-nl(--> TODO)

TODO

(Any) method nodemap

Defined As:

    method nodemap(--> TODO)

TODO

(Any) method iterator

Defined As:

    method iterator(--> TODO)

TODO

(Any) method grep

Defined As:

    method grep(--> TODO)

TODO

(Any) method match

Defined As:

    method match(--> TODO)

TODO

(Any) method append

Defined As:

    method append(--> TODO)

TODO

(Any) method join

Defined As:

    method join(--> TODO)

TODO

(Any) method values

Defined As:

    method values(--> TODO)

TODO

(Any) method collate

Defined As:

    method collate(--> TODO)

TODO

(Any) method batch

Defined As:

    method batch(--> TODO)

TODO

(Any) method cache

Defined As:

    method cache(--> TODO)

TODO

Routines supplied by class Mu

IO::Handle inherits from class Mu, which provides the following methods:

(Mu) routine defined

multi sub    defined(Mu --> Bool:D)
multi method defined(   --> Bool:D)

Returns False on the type object, and True otherwise.

say Int.defined;                # OUTPUT: «False␤» 
say 42.defined;                 # OUTPUT: «True␤» 

Very few types (like Failure) override defined to return False even for instances:

sub fails() { fail 'oh noe' };
say fails().defined;            # OUTPUT: «False␤» 

(Mu) routine isa

multi method isa(Mu $type     --> Bool:D)
multi method isa(Str:D $type  --> Bool:D)

Returns True if the invocant is an instance of class $type, a subset type or a derived class (through inheritance) of $type.

my $i = 17;
say $i.isa("Int");   # OUTPUT: «True␤» 
say $i.isa(Any);     # OUTPUT: «True␤» 

A more idiomatic way to do this is to use the smartmatch operator ~~ instead.

my $s = "String";
say $s ~~ Str;       # OUTPUT: «True␤» 

(Mu) routine does

method does(Mu $type --> Bool:D)

Returns True if and only if the invocant conforms to type $type.

my $d = Date.new('2016-06-03');
say $d.does(Dateish);             # True    (Date does role Dateish) 
say $d.does(Any);                 # True    (Date is a subclass of Any) 
say $d.does(DateTime);            # False   (Date is not a subclass of DateTime) 

Using the smart match operator ~~ is a more idiomatic alternative.

my $d = Date.new('2016-06-03');
say $d ~~ Dateish;                # OUTPUT: «True␤» 
say $d ~~ Any;                    # OUTPUT: «True␤» 
say $d ~~ DateTime;               # OUTPUT: «False␤» 

(Mu) routine Bool

multi sub    Bool(Mu --> Bool:D)
multi method Bool(   --> Bool:D)

Returns False on the type object, and True otherwise.

Many built-in types override this to be False for empty collections, the empty string or numerical zeros

say Mu.Bool;                    # OUTPUT: «False␤» 
say Mu.new.Bool;                # OUTPUT: «True␤» 
say [123].Bool;             # OUTPUT: «True␤» 
say [].Bool;                    # OUTPUT: «False␤» 
say { 'hash' => 'full' }.Bool;  # OUTPUT: «True␤» 
say {}.Bool;                    # OUTPUT: «False␤» 
say "".Bool;                    # OUTPUT: «False␤» 
say 0.Bool;                     # OUTPUT: «False␤» 
say 1.Bool;                     # OUTPUT: «True␤» 
say "0".Bool;                   # OUTPUT: «True␤» 

(Mu) method Str

multi method Str(--> Str)

Returns a string representation of the invocant, intended to be machine readable. Method Str warns on type objects, and produces the empty string.

say Mu.Str;                     # Use of uninitialized value of type Mu in string context. 

(Mu) routine gist

multi sub    gist(Mu --> Str)
multi method gist(   --> Str)

Returns a string representation of the invocant, optimized for fast recognition by humans. As such lists will be truncated at 100 elements. Use .perl to get all elements.

The default gist method in Mu re-dispatches to the perl method for defined invocants, and returns the type name in parenthesis for type object invocants. Many built-in classes override the case of instances to something more specific that may truncate output.

gist is the method that say calls implicitly, so say $something and say $something.gist generally produce the same output.

say Mu.gist;        # OUTPUT: «(Mu)␤» 
say Mu.new.gist;    # OUTPUT: «Mu.new␤» 

(Mu) routine perl

multi sub    perl(Mu --> Str)
multi method perl(   --> Str)

Returns a Perlish representation of the object (i.e., can usually be re-evaluated with EVAL to regenerate the object). The exact output of perl is implementation specific, since there are generally many ways to write a Perl expression that produces a particular value

(Mu) method item

method item(Mu \item:is raw

Forces the invocant to be evaluated in item context and returns the value of it.

say [1,2,3].item.perl;         # OUTPUT: «$[1, 2, 3]␤» 
say { apple => 10 }.item.perl# OUTPUT: «${:apple(10)}␤» 
say "abc".item.perl;           # OUTPUT: «"abc"␤» 

(Mu) method self

method self(--> Mu)

Returns the object it is called on.

(Mu) method clone

method clone(*%twiddles)

Creates a shallow clone of the invocant. Alternative values for public attributes can be provided via named arguments with names matching the attributes' names.

class Point2D {
    has ($.x$.y);
    multi method gist(Point2D:D:{
        "Point($.x$.y)";
    }
}
 
my $p = Point2D.new(x => 2=> 3);
 
say $p;                     # OUTPUT: «Point(2, 3)␤» 
say $p.clone(=> -5);      # OUTPUT: «Point(2, -5)␤» 

(Mu) method new

multi method new(*%attrinit)

Default method for constructing (create + initialize) new objects of a class. This method expects only named arguments which are then used to initialize attributes with accessors of the same name.

Classes may provide their own new method to override this default.

new triggers an object construction mechanism that calls submethods named BUILD in each class of an inheritance hierarchy, if they exist. See the documentation on object construction for more information.

(Mu) method bless

method bless(*%attrinit --> Mu:D)

Lower-level object construction method than new.

Creates a new object of the same type as the invocant, uses the named arguments to initialize attributes, and returns the created object.

You can use this method when writing custom constructors:

class Point {
    has $.x;
    has $.y;
    multi method new($x$y{
        self.bless(:$x:$y);
    }
}
my $p = Point.new(-11);

(Though each time you write a custom constructor, remember that it makes subclassing harder).

(Mu) method CREATE

method CREATE(--> Mu:D)

Allocates a new object of the same type as the invocant, without initializing any attributes.

say Mu.CREATE.defined;  # OUTPUT: «True␤» 

(Mu) method print

multi method print(--> Bool:D)

Prints value to $*OUT after stringification using .Str method without adding a newline at end.

"abc\n".print;          # RESULT: «abc␤» 

(Mu) method put

multi method put(--> Bool:D)

Prints value to $*OUT, adding a newline at end, and if necessary, stringifying non-Str object using the .Str method.

"abc".put;              # RESULT: «abc␤» 

(Mu) method say

multi method say(--> Bool:D)

Prints value to $*OUT after stringification using .gist method with newline at end. To produce machine readable output use .put.

say 42;                 # OUTPUT: «42␤» 

(Mu) method ACCEPTS

multi method ACCEPTS(Mu:U: $other)

ACCEPTS is the method that smart matching with the infix ~~ operator and given/when invokes on the right-hand side (the matcher).

The Mu:U multi performs a type check. Returns True if $other conforms to the invocant (which is always a type object or failure).

say 42 ~~ Mu;           # OUTPUT: «True␤» 
say 42 ~~ Int;          # OUTPUT: «True␤» 
say 42 ~~ Str;          # OUTPUT: «False␤» 

Note that there is no multi for defined invocants; this is to allow autothreading of junctions, which happens as a fallback mechanism when no direct candidate is available to dispatch to.

(Mu) method WHICH

multi method WHICH(--> ObjAt:D)

Returns an object of type ObjAt which uniquely identifies the object. Value types override this method which makes sure that two equivalent objects return the same return value from WHICH.

say 42.WHICH eq 42.WHICH;       # OUTPUT: «True␤» 

(Mu) method WHERE

method WHERE(--> Int)

Returns an Int representing the memory address of the object.

(Mu) method WHY

multi method WHY()

Returns the attached Pod value. For instance,

sub cast(Spell $s)
#= Initiate a specified spell normally 
#= (do not use for class 7 spells) 
{
do-raw-magic($s);
}
say &cast.WHY;

prints

Initiate a specified spell normally (do not use for class 7 spells)

See the documentation specification for details about attaching Pod to variables, classes, functions, methods, etc.

(Mu) trait is export

multi sub trait_mod:<is>(Mu:U \type:$export!)

Marks a type as being exported, that is, available to external users.

my class SomeClass is export { }

A user of a module or class automatically gets all the symbols imported that are marked as is export.

See Exporting and Selective Importing Modules for more details.

(Mu) method return

method return()

The method return will stop execution of a subroutine or method, run all relevant phasers and provide invocant as a return value to the caller. If a return type constraint is provided it will be checked unless the return value is Nil. A control exception is raised and can be caught with CONTROL.

sub f { (1|2|3).return };
dd f(); # OUTPUT: «any(1, 2, 3)␤» 

(Mu) method return-rw

Same as method return except that return-rw returns a writable container to the invocant (see more details here: return-rw).

(Mu) method emit

method emit()

Emits the invocant into the enclosing supply or react block.

react { whenever supply { .emit for "foo"42.5 } {
    say "received {.^name} ($_)";
}}
 
# OUTPUT: 
# received Str (foo) 
# received Int (42) 
# received Rat (0.5) 

(Mu) method take

method take()

Returns the invocant in the enclosing gather block.

sub insert($sep+@list{
    gather for @list {
        FIRST .takenext;
        take slip $sep.item
    }
}
 
say insert ':', <a b c>;
# OUTPUT: «(a : b : c)␤» 

(Mu) routine take

sub take(\item)

Takes the given item and passes it to the enclosing gather block.

#| randomly select numbers for lotto 
my $num-selected-numbers = 6;
my $max-lotto-numbers = 49;
gather for ^$num-selected-numbers {
    take (1 .. $max-lotto-numbers).pick(1);
}.say;    # six random values 

(Mu) routine take-rw

sub take-rw(\item)

Returns the given item to the enclosing gather block, without introducing a new container.

my @a = 1...3;
sub f(@list){ gather for @list { take-rw $_ } };
for f(@a{ $_++ };
say @a;
# OUTPUT: «[2 3 4]␤» 

(Mu) method so

method so()

Returns a Bool value representing the logical non-negation of an expression. One can use this method similarly to the English sentence: "If that is so, then do this thing". For instance,

my @args = <-a -e -b -v>;
my $verbose-selected = any(@argseq '-v' | '-V';
if $verbose-selected.so {
    say "Verbose option detected in arguments";
} # OUTPUT: «Verbose option detected in arguments␤» 

(Mu) method not

method not()

Returns a Bool value representing the logical negation of an expression. Thus it is the opposite of so.

my @args = <-a -e -b>;
my $verbose-selected = any(@argseq '-v' | '-V';
if $verbose-selected.not {
    say "Verbose option not present in arguments";
} # OUTPUT: «Verbose option not present in arguments␤» 

Since there is also a prefix version of not, the above code reads better like so:

my @args = <-a -e -b>;
my $verbose-selected = any(@argseq '-v' | '-V';
if not $verbose-selected {
    say "Verbose option not present in arguments";
} # OUTPUT: «Verbose option not present in arguments␤»