[perl5.git] / pod / perlpragma.pod

=head1 NAME

perlpragma - how to write a user pragma

=head1 DESCRIPTION

A pragma is a module which influences some aspect of the compile time or run
time behaviour of Perl, such as C<strict> or C<warnings>. With Perl 5.10 you
are no longer limited to the built in pragmata; you can now create user
pragmata that modify the behaviour of user functions within a lexical scope.

=head1 A basic example

For example, say you need to create a class implementing overloaded
mathematical operators, and would like to provide your own pragma that
functions much like C<use integer;> You'd like this code

    use MyMaths;
    
    my $l = MyMaths->new(1.2);
    my $r = MyMaths->new(3.4);
    
    print "A: ", $l + $r, "\n";
    
    use myint;
    print "B: ", $l + $r, "\n";
    
    {
        no myint;
        print "C: ", $l + $r, "\n";
    }
    
    print "D: ", $l + $r, "\n";
    
    no myint;
    print "E: ", $l + $r, "\n";

to give the output

    A: 4.6
    B: 4
    C: 4.6
    D: 4
    E: 4.6

I<i.e.>, where C<use myint;> is in effect, addition operations are forced
to integer, whereas by default they are not, with the default behaviour being
restored via C<no myint;>

The minimal implementation of the package C<MyMaths> would be something like
this:

    package MyMaths;
    use warnings;
    use strict;
    use myint();
    use overload '+' => sub {
        my ($l, $r) = @_;
	# Pass 1 to check up one call level from here
        if (myint::in_effect(1)) {
            int($$l) + int($$r);
        } else {
            $$l + $$r;
        }
    };
    
    sub new {
        my ($class, $value) = @_;
        bless \$value, $class;
    }
    
    1;

Note how we load the user pragma C<myint> with an empty list C<()> to
prevent its C<import> being called.

The interaction with the Perl compilation happens inside package C<myint>:

    package myint;
    
    use strict;
    use warnings;
    
    sub import {
        $^H{"myint/in_effect"} = 1;
    }
    
    sub unimport {
        $^H{"myint/in_effect"} = 0;
    }
    
    sub in_effect {
        my $level = shift // 0;
        my $hinthash = (caller($level))[10];
        return $hinthash->{"myint/in_effect"};
    }
    
    1;

As pragmata are implemented as modules, like any other module, C<use myint;>
becomes

    BEGIN {
        require myint;
        myint->import();
    }

and C<no myint;> is

    BEGIN {
        require myint;
        myint->unimport();
    }

Hence the C<import> and C<unimport> routines are called at B<compile time>
for the user's code.

User pragmata store their state by writing to the magical hash C<%^H>,
hence these two routines manipulate it. The state information in C<%^H> is
stored in the optree, and can be retrieved read-only at runtime with C<caller()>,
at index 10 of the list of returned results. In the example pragma, retrieval
is encapsulated into the routine C<in_effect()>, which takes as parameter
the number of call frames to go up to find the value of the pragma in the
user's script. This uses C<caller()> to determine the value of
C<$^H{"myint/in_effect"}> when each line of the user's script was called, and
therefore provide the correct semantics in the subroutine implementing the
overloaded addition.

=head1 Key naming

There is only a single C<%^H>, but arbitrarily many modules that want
to use its scoping semantics.  To avoid stepping on each other's toes,
they need to be sure to use different keys in the hash.  It is therefore
conventional for a module to use only keys that begin with the module's
name (the name of its main package) and a "/" character.  After this
module-identifying prefix, the rest of the key is entirely up to the
module: it may include any characters whatsoever.  For example, a module
C<Foo::Bar> should use keys such as C<Foo::Bar/baz> and C<Foo::Bar/$%/_!>.
Modules following this convention all play nicely with each other.

The Perl core uses a handful of keys in C<%^H> which do not follow this
convention, because they predate it.  Keys that follow the convention
won't conflict with the core's historical keys.

=head1 Implementation details

The optree is shared between threads.  This means there is a possibility that
the optree will outlive the particular thread (and therefore the interpreter
instance) that created it, so true Perl scalars cannot be stored in the
optree.  Instead a compact form is used, which can only store values that are
integers (signed and unsigned), strings or C<undef> - references and
floating point values are stringified.  If you need to store multiple values
or complex structures, you should serialise them, for example with C<pack>.
The deletion of a hash key from C<%^H> is recorded, and as ever can be
distinguished from the existence of a key with value C<undef> with
C<exists>.

B<Don't> attempt to store references to data structures as integers which
are retrieved via C<caller> and converted back, as this will not be threadsafe.
Accesses would be to the structure without locking (which is not safe for
Perl's scalars), and either the structure has to leak, or it has to be
freed when its creating thread terminates, which may be before the optree
referencing it is deleted, if other threads outlive it.
Commit	Line	Data
a550ee30 NC	1	=head1 NAME
	2
	3	perlpragma - how to write a user pragma
	4
	5	=head1 DESCRIPTION
	6
	7	A pragma is a module which influences some aspect of the compile time or run
	8	time behaviour of Perl, such as C<strict> or C<warnings>. With Perl 5.10 you
	9	are no longer limited to the built in pragmata; you can now create user
	10	pragmata that modify the behaviour of user functions within a lexical scope.
	11
	12	=head1 A basic example
	13
	14	For example, say you need to create a class implementing overloaded
	15	mathematical operators, and would like to provide your own pragma that
	16	functions much like C<use integer;> You'd like this code
	17
	18	use MyMaths;
	19
	20	my $l = MyMaths->new(1.2);
	21	my $r = MyMaths->new(3.4);
	22
	23	print "A: ", $l + $r, "\n";
	24
	25	use myint;
	26	print "B: ", $l + $r, "\n";
	27
	28	{
	29	no myint;
	30	print "C: ", $l + $r, "\n";
	31	}
	32
	33	print "D: ", $l + $r, "\n";
	34
	35	no myint;
	36	print "E: ", $l + $r, "\n";
02e1e451	37
a550ee30 NC	38	to give the output
	39
	40	A: 4.6
	41	B: 4
	42	C: 4.6
	43	D: 4
	44	E: 4.6
	45
	46	I<i.e.>, where C<use myint;> is in effect, addition operations are forced
	47	to integer, whereas by default they are not, with the default behaviour being
	48	restored via C<no myint;>
	49
	50	The minimal implementation of the package C<MyMaths> would be something like
	51	this:
	52
	53	package MyMaths;
	54	use warnings;
	55	use strict;
	56	use myint();
	57	use overload '+' => sub {
	58	my ($l, $r) = @_;
	59	# Pass 1 to check up one call level from here
	60	if (myint::in_effect(1)) {
	61	int($$l) + int($$r);
	62	} else {
	63	$$l + $$r;
	64	}
	65	};
	66
	67	sub new {
	68	my ($class, $value) = @_;
	69	bless \$value, $class;
	70	}
	71
	72	1;
	73
02e1e451 RGS	74	Note how we load the user pragma C<myint> with an empty list C<()> to
02e1e451 RGS	75	prevent its C<import> being called.
a550ee30	76
02e1e451	77	The interaction with the Perl compilation happens inside package C<myint>:
a550ee30	78
02e1e451 RGS	79	package myint;
02e1e451 RGS	80
a550ee30 NC	81	use strict;
	82	use warnings;
	83
	84	sub import {
09f1e2c2	85	$^H{"myint/in_effect"} = 1;
a550ee30 NC	86	}
	87
	88	sub unimport {
09f1e2c2	89	$^H{"myint/in_effect"} = 0;
a550ee30 NC	90	}
	91
	92	sub in_effect {
	93	my $level = shift // 0;
	94	my $hinthash = (caller($level))[10];
09f1e2c2	95	return $hinthash->{"myint/in_effect"};
a550ee30 NC	96	}
	97
	98	1;
	99
	100	As pragmata are implemented as modules, like any other module, C<use myint;>
	101	becomes
	102
	103	BEGIN {
	104	require myint;
	105	myint->import();
	106	}
	107
	108	and C<no myint;> is
	109
	110	BEGIN {
	111	require myint;
	112	myint->unimport();
	113	}
	114
	115	Hence the C<import> and C<unimport> routines are called at B<compile time>
	116	for the user's code.
	117
46e5f5f4 RGS	118	User pragmata store their state by writing to the magical hash C<%^H>,
46e5f5f4 RGS	119	hence these two routines manipulate it. The state information in C<%^H> is
5ff2e4c0 KW	120	stored in the optree, and can be retrieved read-only at runtime with C<caller()>,
5ff2e4c0 KW	121	at index 10 of the list of returned results. In the example pragma, retrieval
46e5f5f4 RGS	122	is encapsulated into the routine C<in_effect()>, which takes as parameter
	123	the number of call frames to go up to find the value of the pragma in the
	124	user's script. This uses C<caller()> to determine the value of
09f1e2c2	125	C<$^H{"myint/in_effect"}> when each line of the user's script was called, and
a550ee30 NC	126	therefore provide the correct semantics in the subroutine implementing the
	127	overloaded addition.
	128
09f1e2c2 Z	129	=head1 Key naming
	130
	131	There is only a single C<%^H>, but arbitrarily many modules that want
	132	to use its scoping semantics. To avoid stepping on each other's toes,
	133	they need to be sure to use different keys in the hash. It is therefore
	134	conventional for a module to use only keys that begin with the module's
	135	name (the name of its main package) and a "/" character. After this
	136	module-identifying prefix, the rest of the key is entirely up to the
	137	module: it may include any characters whatsoever. For example, a module
	138	C<Foo::Bar> should use keys such as C<Foo::Bar/baz> and C<Foo::Bar/$%/_!>.
	139	Modules following this convention all play nicely with each other.
	140
	141	The Perl core uses a handful of keys in C<%^H> which do not follow this
	142	convention, because they predate it. Keys that follow the convention
	143	won't conflict with the core's historical keys.
	144
a550ee30 NC	145	=head1 Implementation details
a550ee30 NC	146
260ebcb6 SP	147	The optree is shared between threads. This means there is a possibility that
260ebcb6 SP	148	the optree will outlive the particular thread (and therefore the interpreter
a550ee30	149	instance) that created it, so true Perl scalars cannot be stored in the
260ebcb6	150	optree. Instead a compact form is used, which can only store values that are
a550ee30 NC	151	integers (signed and unsigned), strings or C<undef> - references and
	152	floating point values are stringified. If you need to store multiple values
	153	or complex structures, you should serialise them, for example with C<pack>.
	154	The deletion of a hash key from C<%^H> is recorded, and as ever can be
	155	distinguished from the existence of a key with value C<undef> with
	156	C<exists>.
83a47afd NC	157
	158	B<Don't> attempt to store references to data structures as integers which
	159	are retrieved via C<caller> and converted back, as this will not be threadsafe.
	160	Accesses would be to the structure without locking (which is not safe for
	161	Perl's scalars), and either the structure has to leak, or it has to be
	162	freed when its creating thread terminates, which may be before the optree
	163	referencing it is deleted, if other threads outlive it.