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=head1 NAME

perlxs - XS language reference manual

=head1 DESCRIPTION

=head2 Introduction

XS is an interface description file format used to create an extension
interface between Perl and C code (or a C library) which one wishes
to use with Perl.  The XS interface is combined with the library to
create a new library which can then be either dynamically loaded
or statically linked into perl.  The XS interface description is
written in the XS language and is the core component of the Perl
extension interface.

An B<XSUB> forms the basic unit of the XS interface.  After compilation
by the B<xsubpp> compiler, each XSUB amounts to a C function definition
which will provide the glue between Perl calling conventions and C
calling conventions.

The glue code pulls the arguments from the Perl stack, converts these
Perl values to the formats expected by a C function, call this C function,
transfers the return values of the C function back to Perl.
Return values here may be a conventional C return value or any C
function arguments that may serve as output parameters.  These return
values may be passed back to Perl either by putting them on the
Perl stack, or by modifying the arguments supplied from the Perl side.

The above is a somewhat simplified view of what really happens.  Since
Perl allows more flexible calling conventions than C, XSUBs may do much
more in practice, such as checking input parameters for validity,
throwing exceptions (or returning undef/empty list) if the return value
from the C function indicates failure, calling different C functions
based on numbers and types of the arguments, providing an object-oriented
interface, etc.

Of course, one could write such glue code directly in C.  However, this
would be a tedious task, especially if one needs to write glue for
multiple C functions, and/or one is not familiar enough with the Perl
stack discipline and other such arcana.  XS comes to the rescue here:
instead of writing this glue C code in long-hand, one can write
a more concise short-hand I<description> of what should be done by
the glue, and let the XS compiler B<xsubpp> handle the rest.

The XS language allows one to describe the mapping between how the C
routine is used, and how the corresponding Perl routine is used.  It
also allows creation of Perl routines which are directly translated to
C code and which are not related to a pre-existing C function.  In cases
when the C interface coincides with the Perl interface, the XSUB
declaration is almost identical to a declaration of a C function (in K&R
style).  In such circumstances, there is another tool called C<h2xs>
that is able to translate an entire C header file into a corresponding
XS file that will provide glue to the functions/macros described in
the header file.

The XS compiler is called B<xsubpp>.  This compiler creates
the constructs necessary to let an XSUB manipulate Perl values, and
creates the glue necessary to let Perl call the XSUB.  The compiler
uses B<typemaps> to determine how to map C function parameters
and output values to Perl values and back.  The default typemap
(which comes with Perl) handles many common C types.  A supplementary
typemap may also be needed to handle any special structures and types
for the library being linked.

A file in XS format starts with a C language section which goes until the
first C<MODULE =Z<>> directive.  Other XS directives and XSUB definitions
may follow this line.  The "language" used in this part of the file
is usually referred to as the XS language.  B<xsubpp> recognizes and
skips POD (see L<perlpod>) in both the C and XS language sections, which
allows the XS file to contain embedded documentation. 

See L<perlxstut> for a tutorial on the whole extension creation process.

Note: For some extensions, Dave Beazley's SWIG system may provide a
significantly more convenient mechanism for creating the extension
glue code.  See http://www.swig.org/ for more information.

=head2 On The Road

Many of the examples which follow will concentrate on creating an interface
between Perl and the ONC+ RPC bind library functions.  The rpcb_gettime()
function is used to demonstrate many features of the XS language.  This
function has two parameters; the first is an input parameter and the second
is an output parameter.  The function also returns a status value.

        bool_t rpcb_gettime(const char *host, time_t *timep);

From C this function will be called with the following
statements.

     #include <rpc/rpc.h>
     bool_t status;
     time_t timep;
     status = rpcb_gettime( "localhost", &timep );

If an XSUB is created to offer a direct translation between this function
and Perl, then this XSUB will be used from Perl with the following code.
The $status and $timep variables will contain the output of the function.

     use RPC;
     $status = rpcb_gettime( "localhost", $timep );

The following XS file shows an XS subroutine, or XSUB, which
demonstrates one possible interface to the rpcb_gettime()
function.  This XSUB represents a direct translation between
C and Perl and so preserves the interface even from Perl.
This XSUB will be invoked from Perl with the usage shown
above.  Note that the first three #include statements, for
C<EXTERN.h>, C<perl.h>, and C<XSUB.h>, will always be present at the
beginning of an XS file.  This approach and others will be
expanded later in this document.

     #include "EXTERN.h"
     #include "perl.h"
     #include "XSUB.h"
     #include <rpc/rpc.h>

     MODULE = RPC  PACKAGE = RPC

     bool_t
     rpcb_gettime(host,timep)
          char *host
          time_t &timep
        OUTPUT:
          timep

Any extension to Perl, including those containing XSUBs,
should have a Perl module to serve as the bootstrap which
pulls the extension into Perl.  This module will export the
extension's functions and variables to the Perl program and
will cause the extension's XSUBs to be linked into Perl.
The following module will be used for most of the examples
in this document and should be used from Perl with the C<use>
command as shown earlier.  Perl modules are explained in
more detail later in this document.

     package RPC;

     require Exporter;
     require DynaLoader;
     @ISA = qw(Exporter DynaLoader);
     @EXPORT = qw( rpcb_gettime );

     bootstrap RPC;
     1;

Throughout this document a variety of interfaces to the rpcb_gettime()
XSUB will be explored.  The XSUBs will take their parameters in different
orders or will take different numbers of parameters.  In each case the
XSUB is an abstraction between Perl and the real C rpcb_gettime()
function, and the XSUB must always ensure that the real rpcb_gettime()
function is called with the correct parameters.  This abstraction will
allow the programmer to create a more Perl-like interface to the C
function.

=head2 The Anatomy of an XSUB

The simplest XSUBs consist of 3 parts: a description of the return
value, the name of the XSUB routine and the names of its arguments,
and a description of types or formats of the arguments.

The following XSUB allows a Perl program to access a C library function
called sin().  The XSUB will imitate the C function which takes a single
argument and returns a single value.

     double
     sin(x)
       double x

Optionally, one can merge the description of types and the list of
argument names, rewriting this as

     double
     sin(double x)

This makes this XSUB look similar to an ANSI C declaration.  An optional
semicolon is allowed after the argument list, as in

     double
     sin(double x);

Parameters with C pointer types can have different semantic: C functions
with similar declarations

     bool string_looks_as_a_number(char *s);
     bool make_char_uppercase(char *c);

are used in absolutely incompatible manner.  Parameters to these functions
could be described B<xsubpp> like this:

     char *  s
     char    &c

Both these XS declarations correspond to the C<char*> C type, but they have
different semantics, see L<"The & Unary Operator">.

It is convenient to think that the indirection operator
C<*> should be considered as a part of the type and the address operator C<&>
should be considered part of the variable.  See L<"The Typemap">
for more info about handling qualifiers and unary operators in C types.

The function name and the return type must be placed on
separate lines and should be flush left-adjusted.

  INCORRECT                        CORRECT

  double sin(x)                    double
    double x                       sin(x)
                                     double x

The rest of the function description may be indented or left-adjusted. The
following example shows a function with its body left-adjusted.  Most
examples in this document will indent the body for better readability.

  CORRECT

  double
  sin(x)
  double x

More complicated XSUBs may contain many other sections.  Each section of
an XSUB starts with the corresponding keyword, such as INIT: or CLEANUP:.
However, the first two lines of an XSUB always contain the same data:
descriptions of the return type and the names of the function and its
parameters.  Whatever immediately follows these is considered to be
an INPUT: section unless explicitly marked with another keyword.
(See L<The INPUT: Keyword>.)

An XSUB section continues until another section-start keyword is found.

=head2 The Argument Stack

The Perl argument stack is used to store the values which are
sent as parameters to the XSUB and to store the XSUB's
return value(s).  In reality all Perl functions (including non-XSUB
ones) keep their values on this stack all the same time, each limited
to its own range of positions on the stack.  In this document the
first position on that stack which belongs to the active
function will be referred to as position 0 for that function.

XSUBs refer to their stack arguments with the macro B<ST(x)>, where I<x>
refers to a position in this XSUB's part of the stack.  Position 0 for that
function would be known to the XSUB as ST(0).  The XSUB's incoming
parameters and outgoing return values always begin at ST(0).  For many
simple cases the B<xsubpp> compiler will generate the code necessary to
handle the argument stack by embedding code fragments found in the
typemaps.  In more complex cases the programmer must supply the code.

=head2 The RETVAL Variable

The RETVAL variable is a special C variable that is declared automatically
for you.  The C type of RETVAL matches the return type of the C library
function.  The B<xsubpp> compiler will declare this variable in each XSUB
with non-C<void> return type.  By default the generated C function
will use RETVAL to hold the return value of the C library function being
called.  In simple cases the value of RETVAL will be placed in ST(0) of
the argument stack where it can be received by Perl as the return value
of the XSUB.

If the XSUB has a return type of C<void> then the compiler will
not declare a RETVAL variable for that function.  When using
a PPCODE: section no manipulation of the RETVAL variable is required, the
section may use direct stack manipulation to place output values on the stack.

If PPCODE: directive is not used, C<void> return value should be used
only for subroutines which do not return a value, I<even if> CODE:
directive is used which sets ST(0) explicitly.

Older versions of this document recommended to use C<void> return
value in such cases. It was discovered that this could lead to
segfaults in cases when XSUB was I<truly> C<void>. This practice is
now deprecated, and may be not supported at some future version. Use
the return value C<SV *> in such cases. (Currently C<xsubpp> contains
some heuristic code which tries to disambiguate between "truly-void"
and "old-practice-declared-as-void" functions. Hence your code is at
mercy of this heuristics unless you use C<SV *> as return value.)

=head2 The MODULE Keyword

The MODULE keyword is used to start the XS code and to specify the package
of the functions which are being defined.  All text preceding the first
MODULE keyword is considered C code and is passed through to the output with
POD stripped, but otherwise untouched.  Every XS module will have a
bootstrap function which is used to hook the XSUBs into Perl.  The package
name of this bootstrap function will match the value of the last MODULE
statement in the XS source files.  The value of MODULE should always remain
constant within the same XS file, though this is not required.

The following example will start the XS code and will place
all functions in a package named RPC.

     MODULE = RPC

=head2 The PACKAGE Keyword

When functions within an XS source file must be separated into packages
the PACKAGE keyword should be used.  This keyword is used with the MODULE
keyword and must follow immediately after it when used.

     MODULE = RPC  PACKAGE = RPC

     [ XS code in package RPC ]

     MODULE = RPC  PACKAGE = RPCB

     [ XS code in package RPCB ]

     MODULE = RPC  PACKAGE = RPC

     [ XS code in package RPC ]

Although this keyword is optional and in some cases provides redundant
information it should always be used.  This keyword will ensure that the
XSUBs appear in the desired package.

=head2 The PREFIX Keyword

The PREFIX keyword designates prefixes which should be
removed from the Perl function names.  If the C function is
C<rpcb_gettime()> and the PREFIX value is C<rpcb_> then Perl will
see this function as C<gettime()>.

This keyword should follow the PACKAGE keyword when used.
If PACKAGE is not used then PREFIX should follow the MODULE
keyword.

     MODULE = RPC  PREFIX = rpc_

     MODULE = RPC  PACKAGE = RPCB  PREFIX = rpcb_

=head2 The OUTPUT: Keyword

The OUTPUT: keyword indicates that certain function parameters should be
updated (new values made visible to Perl) when the XSUB terminates or that
certain values should be returned to the calling Perl function.  For
simple functions which have no CODE: or PPCODE: section,
such as the sin() function above, the RETVAL variable is
automatically designated as an output value.  For more complex functions
the B<xsubpp> compiler will need help to determine which variables are output
variables.

This keyword will normally be used to complement the CODE:  keyword.
The RETVAL variable is not recognized as an output variable when the
CODE: keyword is present.  The OUTPUT:  keyword is used in this
situation to tell the compiler that RETVAL really is an output
variable.

The OUTPUT: keyword can also be used to indicate that function parameters
are output variables.  This may be necessary when a parameter has been
modified within the function and the programmer would like the update to
be seen by Perl.

     bool_t
     rpcb_gettime(host,timep)
          char *host
          time_t &timep
        OUTPUT:
          timep

The OUTPUT: keyword will also allow an output parameter to
be mapped to a matching piece of code rather than to a
typemap.

     bool_t
     rpcb_gettime(host,timep)
          char *host
          time_t &timep
        OUTPUT:
          timep sv_setnv(ST(1), (double)timep);

B<xsubpp> emits an automatic C<SvSETMAGIC()> for all parameters in the
OUTPUT section of the XSUB, except RETVAL.  This is the usually desired
behavior, as it takes care of properly invoking 'set' magic on output
parameters (needed for hash or array element parameters that must be
created if they didn't exist).  If for some reason, this behavior is
not desired, the OUTPUT section may contain a C<SETMAGIC: DISABLE> line
to disable it for the remainder of the parameters in the OUTPUT section.
Likewise,  C<SETMAGIC: ENABLE> can be used to reenable it for the
remainder of the OUTPUT section.  See L<perlguts> for more details
about 'set' magic.

=head2 The NO_OUTPUT Keyword

The NO_OUTPUT can be placed as the first token of the XSUB.  This keyword
indicates that while the C subroutine we provide an interface to has
a non-C<void> return type, the return value of this C subroutine should not
be returned from the generated Perl subroutine.

With this keyword present L<The RETVAL Variable> is created, and in the
generated call to the subroutine this variable is assigned to, but the value
of this variable is not going to be used in the auto-generated code.

This keyword makes sense only if C<RETVAL> is going to be accessed by the
user-supplied code.  It is especially useful to make a function interface
more Perl-like, especially when the C return value is just an error condition
indicator.  For example,

  NO_OUTPUT int
  delete_file(char *name)
    POSTCALL:
      if (RETVAL != 0)
          croak("Error %d while deleting file '%s'", RETVAL, name);

Here the generated XS function returns nothing on success, and will die()
with a meaningful error message on error.

=head2 The CODE: Keyword

This keyword is used in more complicated XSUBs which require
special handling for the C function.  The RETVAL variable is
still declared, but it will not be returned unless it is specified
in the OUTPUT: section.

The following XSUB is for a C function which requires special handling of
its parameters.  The Perl usage is given first.

     $status = rpcb_gettime( "localhost", $timep );

The XSUB follows.

     bool_t
     rpcb_gettime(host,timep)
          char *host
          time_t timep
        CODE:
               RETVAL = rpcb_gettime( host, &timep );
        OUTPUT:
          timep
          RETVAL

=head2 The INIT: Keyword

The INIT: keyword allows initialization to be inserted into the XSUB before
the compiler generates the call to the C function.  Unlike the CODE: keyword
above, this keyword does not affect the way the compiler handles RETVAL.

    bool_t
    rpcb_gettime(host,timep)
          char *host
          time_t &timep
        INIT:
          printf("# Host is %s\n", host );
        OUTPUT:
          timep

Another use for the INIT: section is to check for preconditions before
making a call to the C function:

    long long
    lldiv(a,b)
        long long a
        long long b
      INIT:
        if (a == 0 && b == 0)
            XSRETURN_UNDEF;
        if (b == 0)
            croak("lldiv: cannot divide by 0");

=head2 The NO_INIT Keyword

The NO_INIT keyword is used to indicate that a function
parameter is being used only as an output value.  The B<xsubpp>
compiler will normally generate code to read the values of
all function parameters from the argument stack and assign
them to C variables upon entry to the function.  NO_INIT
will tell the compiler that some parameters will be used for
output rather than for input and that they will be handled
before the function terminates.

The following example shows a variation of the rpcb_gettime() function.
This function uses the timep variable only as an output variable and does
not care about its initial contents.

     bool_t
     rpcb_gettime(host,timep)
          char *host
          time_t &timep = NO_INIT
        OUTPUT:
          timep

=head2 Initializing Function Parameters

C function parameters are normally initialized with their values from
the argument stack (which in turn contains the parameters that were
passed to the XSUB from Perl).  The typemaps contain the
code segments which are used to translate the Perl values to
the C parameters.  The programmer, however, is allowed to
override the typemaps and supply alternate (or additional)
initialization code.  Initialization code starts with the first
C<=>, C<;> or C<+> on a line in the INPUT: section.  The only
exception happens if this C<;> terminates the line, then this C<;>
is quietly ignored.

The following code demonstrates how to supply initialization code for
function parameters.  The initialization code is eval'd within double
quotes by the compiler before it is added to the output so anything
which should be interpreted literally [mainly C<$>, C<@>, or C<\\>]
must be protected with backslashes.  The variables $var, $arg,
and $type can be used as in typemaps.

     bool_t
     rpcb_gettime(host,timep)
          char *host = (char *)SvPV($arg,PL_na);
          time_t &timep = 0;
        OUTPUT:
          timep

This should not be used to supply default values for parameters.  One
would normally use this when a function parameter must be processed by
another library function before it can be used.  Default parameters are
covered in the next section.

If the initialization begins with C<=>, then it is output in
the declaration for the input variable, replacing the initialization
supplied by the typemap.  If the initialization
begins with C<;> or C<+>, then it is performed after
all of the input variables have been declared.  In the C<;>
case the initialization normally supplied by the typemap is not performed.
For the C<+> case, the declaration for the variable will include the
initialization from the typemap.  A global
variable, C<%v>, is available for the truly rare case where
information from one initialization is needed in another
initialization.

Here's a truly obscure example:

     bool_t
     rpcb_gettime(host,timep)
          time_t &timep ; /* \$v{timep}=@{[$v{timep}=$arg]} */
          char *host + SvOK($v{timep}) ? SvPV($arg,PL_na) : NULL;
        OUTPUT:
          timep

The construct C<\$v{timep}=@{[$v{timep}=$arg]}> used in the above
example has a two-fold purpose: first, when this line is processed by
B<xsubpp>, the Perl snippet C<$v{timep}=$arg> is evaluated.  Second,
the text of the evaluated snippet is output into the generated C file
(inside a C comment)!  During the processing of C<char *host> line,
$arg will evaluate to C<ST(0)>, and C<$v{timep}> will evaluate to
C<ST(1)>.

=head2 Default Parameter Values

Default values for XSUB arguments can be specified by placing an
assignment statement in the parameter list.  The default value may
be a number, a string or the special string C<NO_INIT>.  Defaults should
always be used on the right-most parameters only.

To allow the XSUB for rpcb_gettime() to have a default host
value the parameters to the XSUB could be rearranged.  The
XSUB will then call the real rpcb_gettime() function with
the parameters in the correct order.  This XSUB can be called
from Perl with either of the following statements:

     $status = rpcb_gettime( $timep, $host );

     $status = rpcb_gettime( $timep );

The XSUB will look like the code  which  follows.   A  CODE:
block  is used to call the real rpcb_gettime() function with
the parameters in the correct order for that function.

     bool_t
     rpcb_gettime(timep,host="localhost")
          char *host
          time_t timep = NO_INIT
        CODE:
               RETVAL = rpcb_gettime( host, &timep );
        OUTPUT:
          timep
          RETVAL

=head2 The PREINIT: Keyword

The PREINIT: keyword allows extra variables to be declared immediately
before or after the declarations of the parameters from the INPUT: section
are emitted.

If a variable is declared inside a CODE: section it will follow any typemap
code that is emitted for the input parameters.  This may result in the
declaration ending up after C code, which is C syntax error.  Similar
errors may happen with an explicit C<;>-type or C<+>-type initialization of
parameters is used (see L<"Initializing Function Parameters">).  Declaring
these variables in an INIT: section will not help.

In such cases, to force an additional variable to be declared together
with declarations of other variables, place the declaration into a
PREINIT: section.  The PREINIT: keyword may be used one or more times
within an XSUB.

The following examples are equivalent, but if the code is using complex
typemaps then the first example is safer.

     bool_t
     rpcb_gettime(timep)
          time_t timep = NO_INIT
        PREINIT:
          char *host = "localhost";
        CODE:
          RETVAL = rpcb_gettime( host, &timep );
        OUTPUT:
          timep
          RETVAL

For this particular case an INIT: keyword would generate the
same C code as the PREINIT: keyword.  Another correct, but error-prone example:

     bool_t
     rpcb_gettime(timep)
          time_t timep = NO_INIT
        CODE:
          char *host = "localhost";
          RETVAL = rpcb_gettime( host, &timep );
        OUTPUT:
          timep
          RETVAL

Another way to declare C<host> is to use a C block in the CODE: section:

     bool_t
     rpcb_gettime(timep)
          time_t timep = NO_INIT
        CODE:
          {
            char *host = "localhost";
            RETVAL = rpcb_gettime( host, &timep );
          }
        OUTPUT:
          timep
          RETVAL

The ability to put additional declarations before the typemap entries are
processed is very handy in the cases when typemap conversions manipulate
some global state:

    MyObject
    mutate(o)
        PREINIT:
            MyState st = global_state;
        INPUT:
            MyObject o;
        CLEANUP:
            reset_to(global_state, st);

Here we suppose that conversion to C<MyObject> in the INPUT: section and from
MyObject when processing RETVAL will modify a global variable C<global_state>.
After these conversions are performed, we restore the old value of
C<global_state> (to avoid memory leaks, for example).

There is another way to trade clarity for compactness: INPUT sections allow
declaration of C variables which do not appear in the parameter list of
a subroutine.  Thus the above code for mutate() can be rewritten as

    MyObject
    mutate(o)
          MyState st = global_state;
          MyObject o;
        CLEANUP:
          reset_to(global_state, st);

and the code for rpcb_gettime() can be rewritten as

     bool_t
     rpcb_gettime(timep)
          time_t timep = NO_INIT
          char *host = "localhost";
        C_ARGS:
          host, &timep
        OUTPUT:
          timep
          RETVAL

=head2 The SCOPE: Keyword

The SCOPE: keyword allows scoping to be enabled for a particular XSUB. If
enabled, the XSUB will invoke ENTER and LEAVE automatically.

To support potentially complex type mappings, if a typemap entry used
by an XSUB contains a comment like C</*scope*/> then scoping will
be automatically enabled for that XSUB.

To enable scoping:

    SCOPE: ENABLE

To disable scoping:

    SCOPE: DISABLE

=head2 The INPUT: Keyword

The XSUB's parameters are usually evaluated immediately after entering the
XSUB.  The INPUT: keyword can be used to force those parameters to be
evaluated a little later.  The INPUT: keyword can be used multiple times
within an XSUB and can be used to list one or more input variables.  This
keyword is used with the PREINIT: keyword.

The following example shows how the input parameter C<timep> can be
evaluated late, after a PREINIT.

    bool_t
    rpcb_gettime(host,timep)
          char *host
        PREINIT:
          time_t tt;
        INPUT:
          time_t timep
        CODE:
               RETVAL = rpcb_gettime( host, &tt );
               timep = tt;
        OUTPUT:
          timep
          RETVAL

The next example shows each input parameter evaluated late.

    bool_t
    rpcb_gettime(host,timep)
        PREINIT:
          time_t tt;
        INPUT:
          char *host
        PREINIT:
          char *h;
        INPUT:
          time_t timep
        CODE:
               h = host;
               RETVAL = rpcb_gettime( h, &tt );
               timep = tt;
        OUTPUT:
          timep
          RETVAL

Since INPUT sections allow declaration of C variables which do not appear
in the parameter list of a subroutine, this may be shortened to:

    bool_t
    rpcb_gettime(host,timep)
          time_t tt;
          char *host;
          char *h = host;
          time_t timep;
        CODE:
          RETVAL = rpcb_gettime( h, &tt );
          timep = tt;
        OUTPUT:
          timep
          RETVAL

(We used our knowledge that input conversion for C<char *> is a "simple" one,
thus C<host> is initialized on the declaration line, and our assignment
C<h = host> is not performed too early.  Otherwise one would need to have the
assignment C<h = host> in a CODE: or INIT: section.)

=head2 The IN/OUTLIST/IN_OUTLIST/OUT/IN_OUT Keywords

In the list of parameters for an XSUB, one can precede parameter names
by the C<IN>/C<OUTLIST>/C<IN_OUTLIST>/C<OUT>/C<IN_OUT> keywords.
C<IN> keyword is the default, the other keywords indicate how the Perl
interface should differ from the C interface.

Parameters preceded by C<OUTLIST>/C<IN_OUTLIST>/C<OUT>/C<IN_OUT>
keywords are considered to be used by the C subroutine I<via
pointers>.  C<OUTLIST>/C<OUT> keywords indicate that the C subroutine
does not inspect the memory pointed by this parameter, but will write
through this pointer to provide additional return values.

Parameters preceded by C<OUTLIST> keyword do not appear in the usage
signature of the generated Perl function.

Parameters preceded by C<IN_OUTLIST>/C<IN_OUT>/C<OUT> I<do> appear as
parameters to the Perl function.  With the exception of
C<OUT>-parameters, these parameters are converted to the corresponding
C type, then pointers to these data are given as arguments to the C
function.  It is expected that the C function will write through these
pointers.

The return list of the generated Perl function consists of the C return value
from the function (unless the XSUB is of C<void> return type or
C<The NO_OUTPUT Keyword> was used) followed by all the C<OUTLIST>
and C<IN_OUTLIST> parameters (in the order of appearance).  On the
return from the XSUB the C<IN_OUT>/C<OUT> Perl parameter will be
modified to have the values written by the C function.

For example, an XSUB

  void
  day_month(OUTLIST day, IN unix_time, OUTLIST month)
    int day
    int unix_time
    int month

should be used from Perl as

  my ($day, $month) = day_month(time);

The C signature of the corresponding function should be

  void day_month(int *day, int unix_time, int *month);

The C<IN>/C<OUTLIST>/C<IN_OUTLIST>/C<IN_OUT>/C<OUT> keywords can be
mixed with ANSI-style declarations, as in

  void
  day_month(OUTLIST int day, int unix_time, OUTLIST int month)

(here the optional C<IN> keyword is omitted).

The C<IN_OUT> parameters are identical with parameters introduced with
L<The & Unary Operator> and put into the C<OUTPUT:> section (see
L<The OUTPUT: Keyword>).  The C<IN_OUTLIST> parameters are very similar,
the only difference being that the value C function writes through the
pointer would not modify the Perl parameter, but is put in the output
list.

The C<OUTLIST>/C<OUT> parameter differ from C<IN_OUTLIST>/C<IN_OUT>
parameters only by the initial value of the Perl parameter not
being read (and not being given to the C function - which gets some
garbage instead).  For example, the same C function as above can be
interfaced with as

  void day_month(OUT int day, int unix_time, OUT int month);

or

  void
  day_month(day, unix_time, month)
      int &day = NO_INIT
      int  unix_time
      int &month = NO_INIT
    OUTPUT:
      day
      month

However, the generated Perl function is called in very C-ish style:

  my ($day, $month);
  day_month($day, time, $month);

=head2 Variable-length Parameter Lists

XSUBs can have variable-length parameter lists by specifying an ellipsis
C<(...)> in the parameter list.  This use of the ellipsis is similar to that
found in ANSI C.  The programmer is able to determine the number of
arguments passed to the XSUB by examining the C<items> variable which the
B<xsubpp> compiler supplies for all XSUBs.  By using this mechanism one can
create an XSUB which accepts a list of parameters of unknown length.

The I<host> parameter for the rpcb_gettime() XSUB can be
optional so the ellipsis can be used to indicate that the
XSUB will take a variable number of parameters.  Perl should
be able to call this XSUB with either of the following statements.

     $status = rpcb_gettime( $timep, $host );

     $status = rpcb_gettime( $timep );

The XS code, with ellipsis, follows.

     bool_t
     rpcb_gettime(timep, ...)
          time_t timep = NO_INIT
        PREINIT:
          char *host = "localhost";
          STRLEN n_a;
        CODE:
          if( items > 1 )
               host = (char *)SvPV(ST(1), n_a);
          RETVAL = rpcb_gettime( host, &timep );
        OUTPUT:
          timep
          RETVAL

=head2 The C_ARGS: Keyword

The C_ARGS: keyword allows creating of XSUBS which have different
calling sequence from Perl than from C, without a need to write
CODE: or PPCODE: section.  The contents of the C_ARGS: paragraph is
put as the argument to the called C function without any change.

For example, suppose that a C function is declared as

    symbolic nth_derivative(int n, symbolic function, int flags);

and that the default flags are kept in a global C variable
C<default_flags>.  Suppose that you want to create an interface which
is called as

    $second_deriv = $function->nth_derivative(2);

To do this, declare the XSUB as

    symbolic
    nth_derivative(function, n)
        symbolic        function
        int             n
      C_ARGS:
        n, function, default_flags

=head2 The PPCODE: Keyword

The PPCODE: keyword is an alternate form of the CODE: keyword and is used
to tell the B<xsubpp> compiler that the programmer is supplying the code to
control the argument stack for the XSUBs return values.  Occasionally one
will want an XSUB to return a list of values rather than a single value.
In these cases one must use PPCODE: and then explicitly push the list of
values on the stack.  The PPCODE: and CODE:  keywords should not be used
together within the same XSUB.

The actual difference between PPCODE: and CODE: sections is in the
initialization of C<SP> macro (which stands for the I<current> Perl
stack pointer), and in the handling of data on the stack when returning
from an XSUB.  In CODE: sections SP preserves the value which was on
entry to the XSUB: SP is on the function pointer (which follows the
last parameter).  In PPCODE: sections SP is moved backward to the
beginning of the parameter list, which allows C<PUSH*()> macros
to place output values in the place Perl expects them to be when
the XSUB returns back to Perl.

The generated trailer for a CODE: section ensures that the number of return
values Perl will see is either 0 or 1 (depending on the C<void>ness of the
return value of the C function, and heuristics mentioned in
L<"The RETVAL Variable">).  The trailer generated for a PPCODE: section
is based on the number of return values and on the number of times
C<SP> was updated by C<[X]PUSH*()> macros.

Note that macros C<ST(i)>, C<XST_m*()> and C<XSRETURN*()> work equally
well in CODE: sections and PPCODE: sections.

The following XSUB will call the C rpcb_gettime() function
and will return its two output values, timep and status, to
Perl as a single list.

     void
     rpcb_gettime(host)
          char *host
        PREINIT:
          time_t  timep;
          bool_t  status;
        PPCODE:
          status = rpcb_gettime( host, &timep );
          EXTEND(SP, 2);
          PUSHs(sv_2mortal(newSViv(status)));
          PUSHs(sv_2mortal(newSViv(timep)));

Notice that the programmer must supply the C code necessary
to have the real rpcb_gettime() function called and to have
the return values properly placed on the argument stack.

The C<void> return type for this function tells the B<xsubpp> compiler that
the RETVAL variable is not needed or used and that it should not be created.
In most scenarios the void return type should be used with the PPCODE:
directive.

The EXTEND() macro is used to make room on the argument
stack for 2 return values.  The PPCODE: directive causes the
B<xsubpp> compiler to create a stack pointer available as C<SP>, and it
is this pointer which is being used in the EXTEND() macro.
The values are then pushed onto the stack with the PUSHs()
macro.

Now the rpcb_gettime() function can be used from Perl with
the following statement.

     ($status, $timep) = rpcb_gettime("localhost");

When handling output parameters with a PPCODE section, be sure to handle
'set' magic properly.  See L<perlguts> for details about 'set' magic.

=head2 Returning Undef And Empty Lists

Occasionally the programmer will want to return simply
C<undef> or an empty list if a function fails rather than a
separate status value.  The rpcb_gettime() function offers
just this situation.  If the function succeeds we would like
to have it return the time and if it fails we would like to
have undef returned.  In the following Perl code the value
of $timep will either be undef or it will be a valid time.

     $timep = rpcb_gettime( "localhost" );

The following XSUB uses the C<SV *> return type as a mnemonic only,
and uses a CODE: block to indicate to the compiler
that the programmer has supplied all the necessary code.  The
sv_newmortal() call will initialize the return value to undef, making that
the default return value.

     SV *
     rpcb_gettime(host)
          char *  host
        PREINIT:
          time_t  timep;
          bool_t x;
        CODE:
          ST(0) = sv_newmortal();
          if( rpcb_gettime( host, &timep ) )
               sv_setnv( ST(0), (double)timep);

The next example demonstrates how one would place an explicit undef in the
return value, should the need arise.

     SV *
     rpcb_gettime(host)
          char *  host
        PREINIT:
          time_t  timep;
          bool_t x;
        CODE:
          ST(0) = sv_newmortal();
          if( rpcb_gettime( host, &timep ) ){
               sv_setnv( ST(0), (double)timep);
          }
          else{
               ST(0) = &PL_sv_undef;
          }

To return an empty list one must use a PPCODE: block and
then not push return values on the stack.

     void
     rpcb_gettime(host)
          char *host
        PREINIT:
          time_t  timep;
        PPCODE:
          if( rpcb_gettime( host, &timep ) )
               PUSHs(sv_2mortal(newSViv(timep)));
          else{
              /* Nothing pushed on stack, so an empty
               * list is implicitly returned. */
          }

Some people may be inclined to include an explicit C<return> in the above
XSUB, rather than letting control fall through to the end.  In those
situations C<XSRETURN_EMPTY> should be used, instead.  This will ensure that
the XSUB stack is properly adjusted.  Consult L<perlguts/"API LISTING"> for
other C<XSRETURN> macros.

Since C<XSRETURN_*> macros can be used with CODE blocks as well, one can
rewrite this example as:

     int
     rpcb_gettime(host)
          char *host
        PREINIT:
          time_t  timep;
        CODE:
          RETVAL = rpcb_gettime( host, &timep );
          if (RETVAL == 0)
                XSRETURN_UNDEF;
        OUTPUT:
          RETVAL

In fact, one can put this check into a POSTCALL: section as well.  Together
with PREINIT: simplifications, this leads to:

     int
     rpcb_gettime(host)
          char *host
          time_t  timep;
        POSTCALL:
          if (RETVAL == 0)
                XSRETURN_UNDEF;

=head2 The REQUIRE: Keyword

The REQUIRE: keyword is used to indicate the minimum version of the
B<xsubpp> compiler needed to compile the XS module.  An XS module which
contains the following statement will compile with only B<xsubpp> version
1.922 or greater:

        REQUIRE: 1.922

=head2 The CLEANUP: Keyword

This keyword can be used when an XSUB requires special cleanup procedures
before it terminates.  When the CLEANUP:  keyword is used it must follow
any CODE:, PPCODE:, or OUTPUT: blocks which are present in the XSUB.  The
code specified for the cleanup block will be added as the last statements
in the XSUB.

=head2 The POSTCALL: Keyword

This keyword can be used when an XSUB requires special procedures
executed after the C subroutine call is performed.  When the POSTCALL:
keyword is used it must precede OUTPUT: and CLEANUP: blocks which are
present in the XSUB.

See examples in L<"The NO_OUTPUT Keyword"> and L<"Returning Undef And Empty Lists">.

The POSTCALL: block does not make a lot of sense when the C subroutine
call is supplied by user by providing either CODE: or PPCODE: section.

=head2 The BOOT: Keyword

The BOOT: keyword is used to add code to the extension's bootstrap
function.  The bootstrap function is generated by the B<xsubpp> compiler and
normally holds the statements necessary to register any XSUBs with Perl.
With the BOOT: keyword the programmer can tell the compiler to add extra
statements to the bootstrap function.

This keyword may be used any time after the first MODULE keyword and should
appear on a line by itself.  The first blank line after the keyword will
terminate the code block.

     BOOT:
     # The following message will be printed when the
     # bootstrap function executes.
     printf("Hello from the bootstrap!\n");

=head2 The VERSIONCHECK: Keyword

The VERSIONCHECK: keyword corresponds to B<xsubpp>'s C<-versioncheck> and
C<-noversioncheck> options.  This keyword overrides the command line
options.  Version checking is enabled by default.  When version checking is
enabled the XS module will attempt to verify that its version matches the
version of the PM module.

To enable version checking:

    VERSIONCHECK: ENABLE

To disable version checking:

    VERSIONCHECK: DISABLE

=head2 The PROTOTYPES: Keyword

The PROTOTYPES: keyword corresponds to B<xsubpp>'s C<-prototypes> and
C<-noprototypes> options.  This keyword overrides the command line options.
Prototypes are enabled by default.  When prototypes are enabled XSUBs will
be given Perl prototypes.  This keyword may be used multiple times in an XS
module to enable and disable prototypes for different parts of the module.

To enable prototypes:

    PROTOTYPES: ENABLE

To disable prototypes:

    PROTOTYPES: DISABLE

=head2 The PROTOTYPE: Keyword

This keyword is similar to the PROTOTYPES: keyword above but can be used to
force B<xsubpp> to use a specific prototype for the XSUB.  This keyword
overrides all other prototype options and keywords but affects only the
current XSUB.  Consult L<perlsub/Prototypes> for information about Perl
prototypes.

    bool_t
    rpcb_gettime(timep, ...)
          time_t timep = NO_INIT
        PROTOTYPE: $;$
        PREINIT:
          char *host = "localhost";
          STRLEN n_a;
        CODE:
                  if( items > 1 )
                       host = (char *)SvPV(ST(1), n_a);
                  RETVAL = rpcb_gettime( host, &timep );
        OUTPUT:
          timep
          RETVAL

=head2 The ALIAS: Keyword

The ALIAS: keyword allows an XSUB to have two or more unique Perl names
and to know which of those names was used when it was invoked.  The Perl
names may be fully-qualified with package names.  Each alias is given an
index.  The compiler will setup a variable called C<ix> which contain the
index of the alias which was used.  When the XSUB is called with its
declared name C<ix> will be 0.

The following example will create aliases C<FOO::gettime()> and
C<BAR::getit()> for this function.

    bool_t
    rpcb_gettime(host,timep)
          char *host
          time_t &timep
        ALIAS:
            FOO::gettime = 1
            BAR::getit = 2
        INIT:
          printf("# ix = %d\n", ix );
        OUTPUT:
          timep

=head2 The INTERFACE: Keyword

This keyword declares the current XSUB as a keeper of the given
calling signature.  If some text follows this keyword, it is
considered as a list of functions which have this signature, and
should be attached to the current XSUB.

For example, if you have 4 C functions multiply(), divide(), add(),
subtract() all having the signature:

    symbolic f(symbolic, symbolic);

you can make them all to use the same XSUB using this:

    symbolic
    interface_s_ss(arg1, arg2)  
        symbolic        arg1
        symbolic        arg2
    INTERFACE:
        multiply divide 
        add subtract

(This is the complete XSUB code for 4 Perl functions!)  Four generated
Perl function share names with corresponding C functions.

The advantage of this approach comparing to ALIAS: keyword is that there
is no need to code a switch statement, each Perl function (which shares
the same XSUB) knows which C function it should call.  Additionally, one
can attach an extra function remainder() at runtime by using

    CV *mycv = newXSproto("Symbolic::remainder", 
                          XS_Symbolic_interface_s_ss, __FILE__, "$$");
    XSINTERFACE_FUNC_SET(mycv, remainder);

say, from another XSUB.  (This example supposes that there was no
INTERFACE_MACRO: section, otherwise one needs to use something else instead of
C<XSINTERFACE_FUNC_SET>, see the next section.)

=head2 The INTERFACE_MACRO: Keyword

This keyword allows one to define an INTERFACE using a different way
to extract a function pointer from an XSUB.  The text which follows
this keyword should give the name of macros which would extract/set a
function pointer.  The extractor macro is given return type, C<CV*>,
and C<XSANY.any_dptr> for this C<CV*>.  The setter macro is given cv,
and the function pointer.

The default value is C<XSINTERFACE_FUNC> and C<XSINTERFACE_FUNC_SET>.
An INTERFACE keyword with an empty list of functions can be omitted if
INTERFACE_MACRO keyword is used.

Suppose that in the previous example functions pointers for 
multiply(), divide(), add(), subtract() are kept in a global C array
C<fp[]> with offsets being C<multiply_off>, C<divide_off>, C<add_off>,
C<subtract_off>.  Then one can use 

    #define XSINTERFACE_FUNC_BYOFFSET(ret,cv,f) \
        ((XSINTERFACE_CVT(ret,))fp[CvXSUBANY(cv).any_i32])
    #define XSINTERFACE_FUNC_BYOFFSET_set(cv,f) \
        CvXSUBANY(cv).any_i32 = CAT2( f, _off )

in C section,

    symbolic
    interface_s_ss(arg1, arg2)  
        symbolic        arg1
        symbolic        arg2
      INTERFACE_MACRO: 
        XSINTERFACE_FUNC_BYOFFSET
        XSINTERFACE_FUNC_BYOFFSET_set
      INTERFACE:
        multiply divide 
        add subtract

in XSUB section.

=head2 The INCLUDE: Keyword

This keyword can be used to pull other files into the XS module.  The other
files may have XS code.  INCLUDE: can also be used to run a command to
generate the XS code to be pulled into the module.

The file F<Rpcb1.xsh> contains our C<rpcb_gettime()> function:

    bool_t
    rpcb_gettime(host,timep)
          char *host
          time_t &timep
        OUTPUT:
          timep

The XS module can use INCLUDE: to pull that file into it.

    INCLUDE: Rpcb1.xsh

If the parameters to the INCLUDE: keyword are followed by a pipe (C<|>) then
the compiler will interpret the parameters as a command.

    INCLUDE: cat Rpcb1.xsh |

=head2 The CASE: Keyword

The CASE: keyword allows an XSUB to have multiple distinct parts with each
part acting as a virtual XSUB.  CASE: is greedy and if it is used then all
other XS keywords must be contained within a CASE:.  This means nothing may
precede the first CASE: in the XSUB and anything following the last CASE: is
included in that case.

A CASE: might switch via a parameter of the XSUB, via the C<ix> ALIAS:
variable (see L<"The ALIAS: Keyword">), or maybe via the C<items> variable
(see L<"Variable-length Parameter Lists">).  The last CASE: becomes the
B<default> case if it is not associated with a conditional.  The following
example shows CASE switched via C<ix> with a function C<rpcb_gettime()>
having an alias C<x_gettime()>.  When the function is called as
C<rpcb_gettime()> its parameters are the usual C<(char *host, time_t *timep)>,
but when the function is called as C<x_gettime()> its parameters are
reversed, C<(time_t *timep, char *host)>.

    long
    rpcb_gettime(a,b)
      CASE: ix == 1
        ALIAS:
          x_gettime = 1
        INPUT:
          # 'a' is timep, 'b' is host
          char *b
          time_t a = NO_INIT
        CODE:
               RETVAL = rpcb_gettime( b, &a );
        OUTPUT:
          a
          RETVAL
      CASE:
          # 'a' is host, 'b' is timep
          char *a
          time_t &b = NO_INIT
        OUTPUT:
          b
          RETVAL

That function can be called with either of the following statements.  Note
the different argument lists.

        $status = rpcb_gettime( $host, $timep );

        $status = x_gettime( $timep, $host );

=head2 The & Unary Operator

The C<&> unary operator in the INPUT: section is used to tell B<xsubpp>
that it should convert a Perl value to/from C using the C type to the left
of C<&>, but provide a pointer to this value when the C function is called.

This is useful to avoid a CODE: block for a C function which takes a parameter
by reference.  Typically, the parameter should be not a pointer type (an
C<int> or C<long> but not an C<int*> or C<long*>).

The following XSUB will generate incorrect C code.  The B<xsubpp> compiler will
turn this into code which calls C<rpcb_gettime()> with parameters C<(char
*host, time_t timep)>, but the real C<rpcb_gettime()> wants the C<timep>
parameter to be of type C<time_t*> rather than C<time_t>.

    bool_t
    rpcb_gettime(host,timep)
          char *host
          time_t timep
        OUTPUT:
          timep

That problem is corrected by using the C<&> operator.  The B<xsubpp> compiler
will now turn this into code which calls C<rpcb_gettime()> correctly with
parameters C<(char *host, time_t *timep)>.  It does this by carrying the
C<&> through, so the function call looks like C<rpcb_gettime(host, &timep)>.

    bool_t
    rpcb_gettime(host,timep)
          char *host
          time_t &timep
        OUTPUT:
          timep

=head2 Inserting POD, Comments and C Preprocessor Directives

C preprocessor directives are allowed within BOOT:, PREINIT: INIT:, CODE:,
PPCODE:, POSTCALL:, and CLEANUP: blocks, as well as outside the functions.
Comments are allowed anywhere after the MODULE keyword.  The compiler will
pass the preprocessor directives through untouched and will remove the
commented lines. POD documentation is allowed at any point, both in the
C and XS language sections. POD must be terminated with a C<=cut> command;
C<xsubpp> will exit with an error if it does not. It is very unlikely that
human generated C code will be mistaken for POD, as most indenting styles
result in whitespace in front of any line starting with C<=>. Machine
generated XS files may fall into this trap unless care is taken to
ensure that a space breaks the sequence "\n=".

Comments can be added to XSUBs by placing a C<#> as the first
non-whitespace of a line.  Care should be taken to avoid making the
comment look like a C preprocessor directive, lest it be interpreted as
such.  The simplest way to prevent this is to put whitespace in front of
the C<#>.

If you use preprocessor directives to choose one of two
versions of a function, use

    #if ... version1
    #else /* ... version2  */
    #endif

and not

    #if ... version1
    #endif
    #if ... version2
    #endif

because otherwise B<xsubpp> will believe that you made a duplicate
definition of the function.  Also, put a blank line before the
#else/#endif so it will not be seen as part of the function body.

=head2 Using XS With C++

If an XSUB name contains C<::>, it is considered to be a C++ method.
The generated Perl function will assume that
its first argument is an object pointer.  The object pointer
will be stored in a variable called THIS.  The object should
have been created by C++ with the new() function and should
be blessed by Perl with the sv_setref_pv() macro.  The
blessing of the object by Perl can be handled by a typemap.  An example
typemap is shown at the end of this section.

If the return type of the XSUB includes C<static>, the method is considered
to be a static method.  It will call the C++
function using the class::method() syntax.  If the method is not static
the function will be called using the THIS-E<gt>method() syntax.

The next examples will use the following C++ class.

     class color {
          public:
          color();
          ~color();
          int blue();
          void set_blue( int );

          private:
          int c_blue;
     };

The XSUBs for the blue() and set_blue() methods are defined with the class
name but the parameter for the object (THIS, or "self") is implicit and is
not listed.

     int
     color::blue()

     void
     color::set_blue( val )
          int val

Both Perl functions will expect an object as the first parameter.  In the 
generated C++ code the object is called C<THIS>, and the method call will
be performed on this object.  So in the C++ code the blue() and set_blue()
methods will be called as this:

     RETVAL = THIS->blue();

     THIS->set_blue( val );

You could also write a single get/set method using an optional argument:

     int
     color::blue( val = NO_INIT )
         int val
         PROTOTYPE $;$
         CODE:
             if (items > 1)
                 THIS->set_blue( val );
             RETVAL = THIS->blue();
         OUTPUT:
             RETVAL

If the function's name is B<DESTROY> then the C++ C<delete> function will be
called and C<THIS> will be given as its parameter.  The generated C++ code for

     void
     color::DESTROY()

will look like this:

     color *THIS = ...; // Initialized as in typemap

     delete THIS;

If the function's name is B<new> then the C++ C<new> function will be called
to create a dynamic C++ object.  The XSUB will expect the class name, which
will be kept in a variable called C<CLASS>, to be given as the first
argument.

     color *
     color::new()

The generated C++ code will call C<new>.

     RETVAL = new color();

The following is an example of a typemap that could be used for this C++
example.

    TYPEMAP
    color *             O_OBJECT

    OUTPUT
    # The Perl object is blessed into 'CLASS', which should be a
    # char* having the name of the package for the blessing.
    O_OBJECT
        sv_setref_pv( $arg, CLASS, (void*)$var );

    INPUT
    O_OBJECT
        if( sv_isobject($arg) && (SvTYPE(SvRV($arg)) == SVt_PVMG) )
                $var = ($type)SvIV((SV*)SvRV( $arg ));
        else{
                warn( \"${Package}::$func_name() -- $var is not a blessed SV reference\" );
                XSRETURN_UNDEF;
        }

=head2 Interface Strategy

When designing an interface between Perl and a C library a straight
translation from C to XS (such as created by C<h2xs -x>) is often sufficient.
However, sometimes the interface will look
very C-like and occasionally nonintuitive, especially when the C function
modifies one of its parameters, or returns failure inband (as in "negative
return values mean failure").  In cases where the programmer wishes to
create a more Perl-like interface the following strategy may help to
identify the more critical parts of the interface.

Identify the C functions with input/output or output parameters.  The XSUBs for
these functions may be able to return lists to Perl.

Identify the C functions which use some inband info as an indication
of failure.  They may be
candidates to return undef or an empty list in case of failure.  If the
failure may be detected without a call to the C function, you may want to use
an INIT: section to report the failure.  For failures detectable after the C
function returns one may want to use a POSTCALL: section to process the
failure.  In more complicated cases use CODE: or PPCODE: sections.

If many functions use the same failure indication based on the return value,
you may want to create a special typedef to handle this situation.  Put

  typedef int negative_is_failure;

near the beginning of XS file, and create an OUTPUT typemap entry
for C<negative_is_failure> which converts negative values to C<undef>, or
maybe croak()s.  After this the return value of type C<negative_is_failure>
will create more Perl-like interface.

Identify which values are used by only the C and XSUB functions
themselves, say, when a parameter to a function should be a contents of a
global variable.  If Perl does not need to access the contents of the value
then it may not be necessary to provide a translation for that value
from C to Perl.

Identify the pointers in the C function parameter lists and return
values.  Some pointers may be used to implement input/output or
output parameters, they can be handled in XS with the C<&> unary operator,
and, possibly, using the NO_INIT keyword.
Some others will require handling of types like C<int *>, and one needs
to decide what a useful Perl translation will do in such a case.  When
the semantic is clear, it is advisable to put the translation into a typemap
file.

Identify the structures used by the C functions.  In many
cases it may be helpful to use the T_PTROBJ typemap for
these structures so they can be manipulated by Perl as
blessed objects.  (This is handled automatically by C<h2xs -x>.)

If the same C type is used in several different contexts which require
different translations, C<typedef> several new types mapped to this C type,
and create separate F<typemap> entries for these new types.  Use these
types in declarations of return type and parameters to XSUBs.

=head2 Perl Objects And C Structures

When dealing with C structures one should select either
B<T_PTROBJ> or B<T_PTRREF> for the XS type.  Both types are
designed to handle pointers to complex objects.  The
T_PTRREF type will allow the Perl object to be unblessed
while the T_PTROBJ type requires that the object be blessed.
By using T_PTROBJ one can achieve a form of type-checking
because the XSUB will attempt to verify that the Perl object
is of the expected type.

The following XS code shows the getnetconfigent() function which is used
with ONC+ TIRPC.  The getnetconfigent() function will return a pointer to a
C structure and has the C prototype shown below.  The example will
demonstrate how the C pointer will become a Perl reference.  Perl will
consider this reference to be a pointer to a blessed object and will
attempt to call a destructor for the object.  A destructor will be
provided in the XS source to free the memory used by getnetconfigent().
Destructors in XS can be created by specifying an XSUB function whose name
ends with the word B<DESTROY>.  XS destructors can be used to free memory
which may have been malloc'd by another XSUB.

     struct netconfig *getnetconfigent(const char *netid);

A C<typedef> will be created for C<struct netconfig>.  The Perl
object will be blessed in a class matching the name of the C
type, with the tag C<Ptr> appended, and the name should not
have embedded spaces if it will be a Perl package name.  The
destructor will be placed in a class corresponding to the
class of the object and the PREFIX keyword will be used to
trim the name to the word DESTROY as Perl will expect.

     typedef struct netconfig Netconfig;

     MODULE = RPC  PACKAGE = RPC

     Netconfig *
     getnetconfigent(netid)
          char *netid

     MODULE = RPC  PACKAGE = NetconfigPtr  PREFIX = rpcb_

     void
     rpcb_DESTROY(netconf)
          Netconfig *netconf
        CODE:
          printf("Now in NetconfigPtr::DESTROY\n");
          free( netconf );

This example requires the following typemap entry.  Consult the typemap
section for more information about adding new typemaps for an extension.

     TYPEMAP
     Netconfig *  T_PTROBJ

This example will be used with the following Perl statements.

     use RPC;
     $netconf = getnetconfigent("udp");

When Perl destroys the object referenced by $netconf it will send the
object to the supplied XSUB DESTROY function.  Perl cannot determine, and
does not care, that this object is a C struct and not a Perl object.  In
this sense, there is no difference between the object created by the
getnetconfigent() XSUB and an object created by a normal Perl subroutine.

=head2 The Typemap

The typemap is a collection of code fragments which are used by the B<xsubpp>
compiler to map C function parameters and values to Perl values.  The
typemap file may consist of three sections labelled C<TYPEMAP>, C<INPUT>, and
C<OUTPUT>.  An unlabelled initial section is assumed to be a C<TYPEMAP>
section.  The INPUT section tells
the compiler how to translate Perl values
into variables of certain C types.  The OUTPUT section tells the compiler
how to translate the values from certain C types into values Perl can
understand.  The TYPEMAP section tells the compiler which of the INPUT and
OUTPUT code fragments should be used to map a given C type to a Perl value.
The section labels C<TYPEMAP>, C<INPUT>, or C<OUTPUT> must begin
in the first column on a line by themselves, and must be in uppercase.

The default typemap in the C<lib/ExtUtils> directory of the Perl source
contains many useful types which can be used by Perl extensions.  Some
extensions define additional typemaps which they keep in their own directory.
These additional typemaps may reference INPUT and OUTPUT maps in the main
typemap.  The B<xsubpp> compiler will allow the extension's own typemap to
override any mappings which are in the default typemap.

Most extensions which require a custom typemap will need only the TYPEMAP
section of the typemap file.  The custom typemap used in the
getnetconfigent() example shown earlier demonstrates what may be the typical
use of extension typemaps.  That typemap is used to equate a C structure
with the T_PTROBJ typemap.  The typemap used by getnetconfigent() is shown
here.  Note that the C type is separated from the XS type with a tab and
that the C unary operator C<*> is considered to be a part of the C type name.

        TYPEMAP
        Netconfig *<tab>T_PTROBJ

Here's a more complicated example: suppose that you wanted C<struct
netconfig> to be blessed into the class C<Net::Config>.  One way to do
this is to use underscores (_) to separate package names, as follows:

        typedef struct netconfig * Net_Config;

And then provide a typemap entry C<T_PTROBJ_SPECIAL> that maps underscores to
double-colons (::), and declare C<Net_Config> to be of that type:


        TYPEMAP
        Net_Config      T_PTROBJ_SPECIAL

        INPUT
        T_PTROBJ_SPECIAL
                if (sv_derived_from($arg, \"${(my $ntt=$ntype)=~s/_/::/g;\$ntt}\")) {
                        IV tmp = SvIV((SV*)SvRV($arg));
                $var = ($type) tmp;
                }
                else
                        croak(\"$var is not of type ${(my $ntt=$ntype)=~s/_/::/g;\$ntt}\")

        OUTPUT
        T_PTROBJ_SPECIAL
                sv_setref_pv($arg, \"${(my $ntt=$ntype)=~s/_/::/g;\$ntt}\",
                (void*)$var);

The INPUT and OUTPUT sections substitute underscores for double-colons
on the fly, giving the desired effect.  This example demonstrates some
of the power and versatility of the typemap facility.

=head2 Safely Storing Static Data in XS

Starting with Perl 5.8, a macro framework has been defined to allow
static data to be safely stored in XS modules that will be accessed from
a multi-threaded Perl.

Although primarily designed for use with multi-threaded Perl, the macros
have been designed so that they will work with non-threaded Perl as well.

It is therefore strongly recommended that these macros be used by all
XS modules that make use of static data.

The easiest way to get a template set of macros to use is by specifying
the C<-g> (C<--global>) option with h2xs (see L<h2xs>).

Below is an example module that makes use of the macros.

    #include "EXTERN.h"
    #include "perl.h"
    #include "XSUB.h"

    /* Global Data */

    #define MY_CXT_KEY "BlindMice::_guts" XS_VERSION

    typedef struct {
        int count;
        char name[3][100];
    } my_cxt_t;

    START_MY_CXT

    MODULE = BlindMice           PACKAGE = BlindMice

    BOOT:
    {
        MY_CXT_INIT;
        MY_CXT.count = 0;
        strcpy(MY_CXT.name[0], "None");
        strcpy(MY_CXT.name[1], "None");
        strcpy(MY_CXT.name[2], "None");
    }                              

    int
    newMouse(char * name)
        char * name;
        PREINIT:
          dMY_CXT;
        CODE:
          if (MY_CXT.count >= 3) {
              warn("Already have 3 blind mice") ;
              RETVAL = 0;
          }
          else {
              RETVAL = ++ MY_CXT.count;
              strcpy(MY_CXT.name[MY_CXT.count - 1], name);
          }

    char *
    get_mouse_name(index)
      int index
      CODE:
        dMY_CXT;
        RETVAL = MY_CXT.lives ++;
        if (index > MY_CXT.count)
          croak("There are only 3 blind mice.");
        else
          RETVAL = newSVpv(MY_CXT.name[index - 1]);


B<REFERENCE>

=over 5

=item MY_CXT_KEY

This macro is used to define a unique key to refer to the static data
for an XS module. The suggested naming scheme, as used by h2xs, is to
use a string that consists of the module name, the string "::_guts"
and the module version number.

    #define MY_CXT_KEY "MyModule::_guts" XS_VERSION

=item typedef my_cxt_t

This struct typedef I<must> always be called C<my_cxt_t> -- the other
C<CXT*> macros assume the existence of the C<my_cxt_t> typedef name.

Declare a typedef named C<my_cxt_t> that is a structure that contains
all the data that needs to be interpreter-local.

    typedef struct {
        int some_value;
    } my_cxt_t;

=item START_MY_CXT

Always place the START_MY_CXT macro directly after the declaration
of C<my_cxt_t>.

=item MY_CXT_INIT

The MY_CXT_INIT macro initialises storage for the C<my_cxt_t> struct.

It I<must> be called exactly once -- typically in a BOOT: section.

=item dMY_CXT

Use the dMY_CXT macro (a declaration) in all the functions that access
MY_CXT.

=item MY_CXT

Use the MY_CXT macro to access members of the C<my_cxt_t> struct. For
example, if C<my_cxt_t> is 

    typedef struct {
        int index;
    } my_cxt_t;

then use this to access the C<index> member

    dMY_CXT;
    MY_CXT.index = 2;

=back

=head1 EXAMPLES

File C<RPC.xs>: Interface to some ONC+ RPC bind library functions.

     #include "EXTERN.h"
     #include "perl.h"
     #include "XSUB.h"

     #include <rpc/rpc.h>

     typedef struct netconfig Netconfig;

     MODULE = RPC  PACKAGE = RPC

     SV *
     rpcb_gettime(host="localhost")
          char *host
        PREINIT:
          time_t  timep;
        CODE:
          ST(0) = sv_newmortal();
          if( rpcb_gettime( host, &timep ) )
               sv_setnv( ST(0), (double)timep );

     Netconfig *
     getnetconfigent(netid="udp")
          char *netid

     MODULE = RPC  PACKAGE = NetconfigPtr  PREFIX = rpcb_

     void
     rpcb_DESTROY(netconf)
          Netconfig *netconf
        CODE:
          printf("NetconfigPtr::DESTROY\n");
          free( netconf );

File C<typemap>: Custom typemap for RPC.xs.

     TYPEMAP
     Netconfig *  T_PTROBJ

File C<RPC.pm>: Perl module for the RPC extension.

     package RPC;

     require Exporter;
     require DynaLoader;
     @ISA = qw(Exporter DynaLoader);
     @EXPORT = qw(rpcb_gettime getnetconfigent);

     bootstrap RPC;
     1;

File C<rpctest.pl>: Perl test program for the RPC extension.

     use RPC;

     $netconf = getnetconfigent();
     $a = rpcb_gettime();
     print "time = $a\n";
     print "netconf = $netconf\n";

     $netconf = getnetconfigent("tcp");
     $a = rpcb_gettime("poplar");
     print "time = $a\n";
     print "netconf = $netconf\n";


=head1 XS VERSION

This document covers features supported by C<xsubpp> 1.935.

=head1 AUTHOR

Originally written by Dean Roehrich <F<roehrich@cray.com>>.

Maintained since 1996 by The Perl Porters <F<perlbug@perl.org>>.