Provided by: libinline-perl_0.53-1_all bug

NAME

       Inline::C-Cookbook - A Cornucopia of Inline C Recipes

DESCRIPTION

       It's a lot easier for most of us to cook a meal from a recipe, rather than just throwing
       things into a pot until something edible forms. So it is with programming as well.
       "Inline.pm" makes C programming for Perl as easy as possible. Having a set of easy to
       understand samples, makes it simpler yet.

       This Cookbook is intended to be an evergrowing repository of small yet complete coding
       examples; each showing how to accomplish a particular task with Inline. Each example is
       followed by a short discussion, explaining in detail the particular features that are
       being demonstrated.

       Many of these recipes are apdapted from email discussions I have had with Inline users
       around the world. It has been my experience so far, that Inline provides an elegant
       solution to almost all problems involving Perl and C.

       Bon Appetit!

Appetizers

   Hello, world
       Problem
           It seems that the first thing any programmer wants to do when he learns a new
           programming technique is to use it to greet the Earth. How can I do this using Inline?

       Solution
               use Inline C => <<'END_C';

               void greet() {
                   printf("Hello, world\n");
               }
               END_C

               greet;

       Discussion
           Nothing too fancy here. We define a single C function "greet()" which prints a message
           to STDOUT. One thing to note is that since the Inline code comes before the function
           call to "greet", we can call it as a bareword (no parentheses).

       See Also
           See Inline and Inline::C for basic info about "Inline.pm".

       Credits
           Brian Kernigan

           Dennis Ritchie

   One Liner
       Problem
           A concept is valid in Perl only if it can be shown to work in one line.  Can Inline
           reduce the complexities of Perl/C interaction to a one-liner?

       Solution
               perl -e 'use Inline C=>q{void greet(){printf("Hello, world\n");}};greet'

       Discussion
           Try doing that in XS :-)

       See Also
           My email signature of late is:

               perl -le 'use Inline C=>q{SV*JAxH(char*x){return newSVpvf("Just Another %s Hacker",x);}};print JAxH+Perl'

           A bit fancier but a few bytes too long to qualify as a true one liner :-(

       Credits
           "Eli the Bearded" <elijah@workspot.net> gave me the idea that I should have an Inline
           one-liner as a signature.

Meat & Potatoes

   Data Types
       Problem
           How do I pass different types of data to and from Inline C functions; like strings,
           numbers and integers?

       Solution
               # vowels.pl
               use Inline C;

               $filename = $ARGV[0];
               die "Usage: perl vowels.pl filename\n" unless -f $filename;

               $text = join '', <>;           # slurp input file
               $vp = vowel_scan($text);       # call our function
               $vp = sprintf("%03.1f", $vp * 100);  # format for printing
               print "The letters in $filename are $vp% vowels.\n";

               __END__
               __C__

               /* Find percentage of vowels to letters */
               double vowel_scan(char* str) {
                   int letters = 0;
                   int vowels = 0;
                   int i = 0;
                   char c;
                   char normalize = 'a' ^ 'A';
                   /* normalize forces lower case in ASCII; upper in EBCDIC */
                   char A = normalize | 'a';
                   char E = normalize | 'e';
                   char I = normalize | 'i';
                   char O = normalize | 'o';
                   char U = normalize | 'u';
                   char Z = normalize | 'z';

                   while(c = str[i++]) {
                       c |= normalize;
                       if (c >= A && c <= Z) {
                            letters++;
                            if (c == A || c == E || c == I || c == O || c == U)
                                vowels++;
                       }
                   }

                   return letters ? ((double) vowels / letters) : 0.0;
               }

       Discussion
           This script takes a file name from the command line and prints the ratio of vowels to
           letters in that file. "vowels.pl" uses an Inline C function called "vowel_scan", that
           takes a string argument, and returns the percentage of vowels as a floating point
           number between 0 and 1. It handles upper and lower case letters, and works with ASCII
           and EBCDIC.  It is also quite fast.

           Running this script produces:

               > perl vowels.pl /usr/share/dict/words
               The letters in /usr/share/dict/words are 37.5% vowels.

       See Also
           The Perl Journal vol #19 has an article about Inline which uses this example.

       Credits
           This example was reprinted by permission of The Perl Journal. It was edited to work
           with Inline v0.30 and higher.

   Variable Argument Lists
       Problem
           How do I pass a variable-sized list of arguments to an Inline C function?

       Solution
               greet(qw(Sarathy Jan Sparky Murray Mike));

               use Inline C => <<'END_OF_C_CODE';

               void greet(SV* name1, ...) {
                   Inline_Stack_Vars;
                   int i;

                   for (i = 0; i < Inline_Stack_Items; i++)
                       printf("Hello %s!\n", SvPV(Inline_Stack_Item(i), PL_na));

                   Inline_Stack_Void;
               }

               END_OF_C_CODE

       Discussion
           This little program greets a group of people, such as my coworkers. We use the "C"
           ellipsis syntax: ""..."", since the list can be of any size.

           Since there are no types or names associated with each argument, we can't expect XS to
           handle the conversions for us. We'll need to pop them off the Stack ourselves. Luckily
           there are two functions (macros) that make this a very easy task.

           First, we need to begin our function with a ""Inline_Stack_Vars"" statement. This
           defines a few internal variables that we need to access the Stack. Now we can use
           ""Inline_Stack_Items"", which returns an integer containing the number of arguments
           passed to us from Perl.

           NOTE: It is important to only use ""Inline_Stack_"" macros when there is an ellipsis
           ("...") in the argument list, or the function has a return type of void.

           Second, we use the Inline_Stack_Item(x) function to access each argument where "0 <= x
           < items".

           NOTE: When using a variable length argument list, you have to specify at least one
           argument before the ellipsis. (On my compiler, anyway.) When XS does it's argument
           checking, it will complain if you pass in less than the number of defined arguments.
           Therefore, there is currently no way to pass an empty list when a variable length list
           is expected.

       See Also
       Credits

   Multiple Return Values
       Problem
           How do I return a list of values from a C function?

       Solution
               print map {"$_\n"} get_localtime(time);

               use Inline C => <<'END_OF_C_CODE';

               #include <time.h>

               void get_localtime(int utc) {
                 struct tm *ltime = localtime(&utc);
                 Inline_Stack_Vars;

                 Inline_Stack_Reset;
                 Inline_Stack_Push(sv_2mortal(newSViv(ltime->tm_year)));
                 Inline_Stack_Push(sv_2mortal(newSViv(ltime->tm_mon)));
                 Inline_Stack_Push(sv_2mortal(newSViv(ltime->tm_mday)));
                 Inline_Stack_Push(sv_2mortal(newSViv(ltime->tm_hour)));
                 Inline_Stack_Push(sv_2mortal(newSViv(ltime->tm_min)));
                 Inline_Stack_Push(sv_2mortal(newSViv(ltime->tm_sec)));
                 Inline_Stack_Push(sv_2mortal(newSViv(ltime->tm_isdst)));
                 Inline_Stack_Done;
               }
               END_OF_C_CODE

       Discussion
           Perl is a language where it is common to return a list of values from a subroutine
           call instead of just a single value. C is not such a language. In order to accomplish
           this in C we need to manipulate the Perl call stack by hand. Luckily, Inline provides
           macros to make this easy.

           This example calls the system "localtime", and returns each of the parts of the time
           struct; much like the perl builtin "localtime()". On each stack push, we are creating
           a new Perl integer (SVIV) and mortalizing it. The sv_2mortal() call makes sure that
           the reference count is set properly. Without it, the program would leak memory.

           NOTE: The "#include" statement is not really needed, because Inline automatically
           includes the Perl headers which include almost all standard system calls.

       See Also
           For more information on the Inline stack macros, see Inline::C.

       Credits
           Richard Anderson <starfire@zipcon.net> contributed the original idea for this snippet.

   Multiple Return Values (Another Way)
       Problem
           How can I pass back more than one value without using the Perl Stack?

       Solution
               use Inline::Files;
               use Inline C;

               my ($foo, $bar);
               change($foo, $bar);

               print "\$foo = $foo\n";
               print "\$bar = $bar\n";

               __C__

               int change(SV* var1, SV* var2) {
                   sv_setpvn(var1, "Perl Rocks!", 11);
                   sv_setpvn(var2, "Inline Rules!", 13);
                   return 1;
               }

       Discussion
           Most perl function interfaces return values as a list of one or more scalars. Very few
           like "chomp", will modify an input scalar in place.  On the other hand, in C you do
           this quite often. Values are passed in by reference and modified in place by the
           called function.

           It turns out that we can do that with Inline as well. The secret is to use a type of
           '"SV*"' for each argument that is to be modified. This ensures passing by reference,
           because no typemapping is needed.

           The function can then use the Perl5 API to operate on that argument.  When control
           returns to Perl, the argument will retain the value set by the C function. In this
           example we passed in 2 empty scalars and assigned values directly to them.

       See Also
       Credits
           Ned Konz <ned@bike-nomad.com> brought this behavior to my attention. He also pointed
           out that he is not the world famous computer cyclist Steve Roberts
           (http://www.microship.com), but he is close (http://bike-nomad.com). Thanks Ned.

   Using Memory
       Problem
           How should I allocate buffers in my Inline C code?

       Solution
               print greeting('Ingy');

               use Inline C => <<'END_OF_C_CODE';

               SV* greeting(SV* sv_name) {
                   return (newSVpvf("Hello %s!\n", SvPV(sv_name, PL_na)));
               }

               END_OF_C_CODE

       Discussion
           In this example we will return the greeting to the caller, rather than printing it.
           This would seem mighty easy, except for the fact that we need to allocate a small
           buffer to create the greeting.

           I would urge you to stay away from "malloc"ing your own buffer. Just use Perl's built
           in memory management. In other words, just create a new Perl string scalar. The
           function "newSVpv" does just that. And "newSVpvf" includes "sprintf" functionality.

           The other problem is getting rid of this new scalar. How will the ref count get
           decremented after we pass the scalar back? Perl also provides a function called
           "sv_2mortal". Mortal variables die when the context goes out of scope. In other words,
           Perl will wait until the new scalar gets passed back and then decrement the ref count
           for you, thereby making it eligible for garbage collection. See "perldoc perlguts".

           In this example the "sv_2mortal" call gets done under the hood by XS, because we
           declared the return type to be "SV*".

           To view the generated XS code, run the command ""perl -MInline=INFO,FORCE,NOCLEAN
           example004.pl"". This will leave the build directory intact and tell you where to find
           it.

       See Also
       Credits

Fast Food

   Inline CGI
       Problem
           How do I use Inline securely in a CGI environment?

       Solution
               #!/usr/bin/perl

               use CGI qw(:standard);
               use Inline (Config =>
                           DIRECTORY => '/usr/local/apache/Inline',
                          );

               print (header,
                      start_html('Inline CGI Example'),
                      h1(JAxH('Inline')),
                      end_html
                     );

               use Inline C => <<END;
               SV* JAxH(char* x) {
                   return newSVpvf("Just Another %s Hacker", x);
               }
               END

       Discussion
           The problem with running Inline code from a CGI script is that Inline writes to a
           build area on your disk whenever it compiles code. Most CGI scripts don't (and
           shouldn't) be able to create a directory and write into it.

           The solution is to explicitly tell Inline which directory to use with the 'use Inline
           Config => DIRECTORY => ...' line. Then you need to give write access to that directory
           from the web server (CGI script).

           If you see this as a security hole, then there is another option.  Give write access
           to yourself, but read-only access to the CGI script. Then run the script once by hand
           (from the command line).  This will cause Inline to precompile the C code. That way
           the CGI will only need read access to the build directory (to load in the shared
           library from there).

           Just remember that whenever you change the C code, you need to precompile it again.

       See Also
           See CGI for more information on using the "CGI.pm" module.

       Credits

   mod_perl
       Problem
           How do I use Inline with mod_perl?

       Solution
               package Factorial;
               use strict;
               use Inline Config =>
                          DIRECTORY => '/usr/local/apache/Inline',
                          ENABLE => 'UNTAINT';
               use Inline 'C';
               Inline->init;

               sub handler {
                   my $r = shift;
                   $r->send_http_header('text/plain');
                   printf "%3d! = %10d\n", $_, factorial($_) for 1..100;
                   return Apache::Constants::OK;
               }

               1;
               __DATA__
               __C__
               double factorial(double x) {
                   if (x < 2)  return 1;
                   return x * factorial(x - 1)
               }

       Discussion
           This is a fully functional mod_perl handler that prints out the factorial values for
           the numbers 1 to 100. Since we are using Inline under mod_perl, there are a few
           considerations to , um, consider.

           First, mod_perl handlers are usually run with "-T" taint detection.  Therefore, we
           need to enable the UNTAINT option. The next thing to deal with is the fact that this
           handler will most likely be loaded after Perl's compile time. Since we are using the
           DATA section, we need to use the special "init()" call. And of course we need to
           specify a DIRECTORY that mod_perl can compile into. See the above CGI example for more
           info.

           Other than that, this is a pretty straightforward mod_perl handler, tuned for even
           more speed!

       See Also
           See Stas Bekman's upcoming O'Reilly book on mod_perl to which this example was
           contributed.

       Credits

   Object Oriented Inline
       Problem
           How do I implement Object Oriented programming in Perl using C objects?

       Solution
               my $obj1 = Soldier->new('Benjamin', 'Private', 11111);
               my $obj2 = Soldier->new('Sanders', 'Colonel', 22222);
               my $obj3 = Soldier->new('Matt', 'Sergeant', 33333);

               for my $obj ($obj1, $obj2, $obj3) {
                   print  $obj->get_serial, ") ",
                          $obj->get_name, " is a ",
                          $obj->get_rank, "\n";
               }

               #---------------------------------------------------------

               package Soldier;

               use Inline C => <<'END';

               typedef struct {
                 char* name;
                 char* rank;
                 long  serial;
                 } Soldier;

               SV* new(char* class, char* name, char* rank, long serial) {
                   Soldier* soldier;
                   SV*      obj_ref = newSViv(0);
                   SV*      obj = newSVrv(obj_ref, class);

                   New(42, soldier, 1, Soldier);

                   soldier->name = savepv(name);
                   soldier->rank = savepv(rank);
                   soldier->serial = serial;

                   sv_setiv(obj, (IV)soldier);
                   SvREADONLY_on(obj);
                   return obj_ref;
                }

                char* get_name(SV* obj) {
                      return ((Soldier*)SvIV(SvRV(obj)))->name;
                }

                char* get_rank(SV* obj) {
                      return ((Soldier*)SvIV(SvRV(obj)))->rank;
                }

                long get_serial(SV* obj) {
                     return ((Soldier*)SvIV(SvRV(obj)))->serial;
                }

                void DESTROY(SV* obj) {
                     Soldier* soldier = (Soldier*)SvIV(SvRV(obj));
                     Safefree(soldier->name);
                     Safefree(soldier->rank);
                     Safefree(soldier);
               }

               END

       Discussion
           Damian Conway has given us myriad ways of implementing OOP in Perl. This is one he
           might not have thought of.

           The interesting thing about this example is that it uses Perl for all the OO bindings
           while using C for the attributes and methods.

           If you examine the Perl code everything looks exactly like a regular OO example. There
           is a "new" method and several accessor methods. The familiar 'arrow syntax' is used to
           invoke them.

           In the class definition (second part) the Perl "package" statement is used to name the
           object class or namespace. But that's where the similarities end Inline takes over.

           The idea is that we call a C subroutine called "new()" which returns a blessed scalar.
           The scalar contains a readonly integer which is a C pointer to a Soldier struct. This
           is our object.

           The "new()" function needs to malloc the memory for the struct and then copy the
           initial values into it using "savepv()". This also allocates more memory (which we
           have to keep track of).

           Note that "newSVrv()" doesn't create a reference, but returns a new SV ('obj') and
           makes 'obj_ref' a reference to it. Ultimately, 'obj_ref' (which is the SV that "new()"
           returns) holds a reference to the blessed scalar in 'obj', which in turn contains an
           integer that corresponds to the memory address of the C object.

           The accessor methods are pretty straightforward. They return the current value of
           their attribute.

           The last method "DESTROY()" is called automatically by Perl whenever an object goes
           out of scope. This is where we can free all the memory used by the object.

           That's it. It's a very simplistic example. It doesn't show off any advanced OO
           features, but it is pretty cool to see how easy the implementation can be. The
           important Perl call is "newSVrv()" which creates a blessed scalar.

       See Also
           Read "Object Oriented Perl" by Damian Conway, for more useful ways of doing OOP in
           Perl.

           You can learn more Perl calls in perlapi. If you don't have Perl 5.6.0 or higher,
           visit http://www.perldoc.com/perl5.6/pod/perlapi.html

       Credits

The Main Course

   Exposing Shared Libraries
       Problem
           You have this great C library and you want to be able to access parts of it with Perl.

       Solution
               print get('http://www.axkit.org');

               use Inline C => Config =>
                          LIBS => '-lghttp';
               use Inline C => <<'END_OF_C_CODE';

               #include <ghttp.h>

               char *get(SV* uri) {
                  SV* buffer;
                  ghttp_request* request;

                  buffer = NEWSV(0,0);
                  request = ghttp_request_new();
                  ghttp_set_uri(request, SvPV(uri, PL_na));

                  ghttp_set_header(request, http_hdr_Connection, "close");

                  ghttp_prepare(request);
                  ghttp_process(request);

                  sv_catpv(buffer, ghttp_get_body(request));

                  ghttp_request_destroy(request);

                  return SvPV(buffer, PL_na);
               }

               END_OF_C_CODE

       Discussion
           This example fetches and prints the HTML from http://www.axkit.org It requires the
           GNOME http libraries. http://www.gnome.org

           One of the most common questions I get is "How can I use Inline to make use of some
           shared library?". Although it has always been possible to do so, the configuration was
           ugly, and there were no specific examples.

           With version 0.30 and higher, you can specify the use of shared libraries easily with
           something like this:

               use Inline C => Config => LIBS => '-lghttp';
               use Inline C => "code ...";

           or

               use Inline C => "code ...", LIBS => '-lghttp';

           To specify a specific library path, use:

               use Inline C => "code ...", LIBS => '-L/your/lib/path -lyourlib';

           To specify an include path use:

               use Inline C => "code ...",
                          LIBS => '-lghttp',
                          INC => '-I/your/inc/path';

       See Also
           The "LIBS" and "INC" configuration options are formatted and passed into MakeMaker.
           For more info see ExtUtils::MakeMaker. For more options see Inline::C.

       Credits
           This code was written by Matt Sergeant <matt@sergeant.org>, author of many CPAN
           modules. The configuration syntax has been modified for use with Inline v0.30.

   Automatic Function Wrappers
       Problem
           You have some functions in a C library that you want to access from Perl exactly as
           you would from C.

       Solution
           The error function "erf()" is probably defined in your standard math library.
           Annoyingly, Perl does not let you access it. To print out a small table of its values,
           just say:

               perl -le 'use Inline C => q{ double erf(double); }, ENABLE => "AUTOWRAP"; print "$_ @{[erf($_)]}" for (0..10)'

           The excellent "Term::ReadLine::Gnu" implements Term::ReadLine using the GNU ReadLine
           library. Here is an easy way to access just "readline()" from that library:

               package MyTerm;

               use Inline C => Config =>
                          ENABLE => AUTOWRAP =>
                          LIBS => "-lreadline -lncurses -lterminfo -ltermcap ";
               use Inline C => q{ char * readline(char *); };

               package main;
               my $x = MyTerm::readline("xyz: ");

           Note however that it fails to "free()" the memory returned by readline, and that
           "Term::ReadLine::Gnu" offers a much richer interface.

       Discussion
           We access existing functions by merely showing Inline their declarations, rather than
           a full definition. Of course the function declared must exist, either in a library
           already linked to Perl or in a library specified using the "LIBS" option.

           The first example wraps a function from the standard math library, so Inline requires
           no additional "LIBS" directive. The second uses the Config option to specify the
           libraries that contain the actual compiled C code.

           This behavior is always disabled by default. You must enable the "AUTOWRAP" option to
           make it work.

       See Also
           "readline", "Term::ReadLine::Gnu"

       Credits
           GNU ReadLine was written by Brian Fox <bfox@ai.mit.edu> and Chet Ramey
           <chet@ins.cwru.edu>. Term::ReadLine::Gnu was written by Hiroo Hayashi
           <hiroo.hayashi@computer.org>. Both are far richer than the slim interface given here!

           The idea of producing wrapper code given only a function declaration is taken from
           Swig by David M. Beazley <beazley@cs.uchicago.edu>.

           Ingy's inline editorial insight:

           This entire entry was contributed by Ariel Scolnicov <ariels@compugen.co.il>. Ariel
           also first suggested the idea for Inline to support function declaration processing.

   Complex Data
       Problem
           How do I deal with complex data types like hashes in Inline C?

       Solution
               use Inline C => <<'END_OF_C_CODE';

               void dump_hash(SV* hash_ref) {
                   HV* hash;
                   HE* hash_entry;
                   int num_keys, i;
                   SV* sv_key;
                   SV* sv_val;

                   if (! SvROK(hash_ref))
                       croak("hash_ref is not a reference");

                   hash = (HV*)SvRV(hash_ref);
                   num_keys = hv_iterinit(hash);
                   for (i = 0; i < num_keys; i++) {
                       hash_entry = hv_iternext(hash);
                       sv_key = hv_iterkeysv(hash_entry);
                       sv_val = hv_iterval(hash, hash_entry);
                       printf("%s => %s\n", SvPV(sv_key, PL_na), SvPV(sv_val, PL_na));
                   }
                   return;
               }

               END_OF_C_CODE

               my %hash = (
                           Author => "Brian Ingerson",
                           Nickname => "INGY",
                           Module => "Inline.pm",
                           Version => "0.30",
                           Language => "C",
                          );

               dump_hash(\%hash);

       Discussion
           The world is not made of scalars alone, although they are definitely the easiest
           creatures to deal with, when doing Inline stuff.  Sometimes we need to deal with
           arrays, hashes, and code references, among other things.

           Since Perl subroutine calls only pass scalars as arguments, we'll need to use the
           argument type "SV*" and pass references to more complex types.

           The above program dumps the key/value pairs of a hash. To figure it out, just curl up
           with perlapi for a couple hours. Actually, its fairly straight forward once you are
           familiar with the calls.

           Note the "croak" function call. This is the proper way to die from your C extensions.

       See Also
           See perlapi for information about the Perl5 internal API.

       Credits

   Hash of Lists
       Problem
           How do I create a Hash of Lists from C?

       Solution
               use Inline C;
               use Data::Dumper;

               $hash_ref = load_data("./cartoon.txt");
               print Dumper $hash_ref;

               __END__
               __C__

               static int next_word(char**, char*);

               SV* load_data(char* file_name) {
                   char buffer[100], word[100], * pos;
                   AV* array;
                   HV* hash = newHV();
                   FILE* fh = fopen(file_name, "r");

                   while (fgets(pos = buffer, sizeof(buffer), fh)) {
                       if (next_word(&pos, word)) {
                           hv_store(hash, word, strlen(word),
                                   newRV_noinc((SV*)array = newAV()), 0);
                           while (next_word(&pos, word))
                               av_push(array, newSVpvf("%s", word));
                       }
                   }
                   fclose(fh);
                   return newRV_noinc((SV*) hash);
               }

               static int next_word(char** text_ptr, char* word) {
                   char* text = *text_ptr;
                   while(*text != '\0' &&
                         *text <= ' ')
                       text++;
                   if (*text <= ' ')
                       return 0;
                   while(*text != '\0' &&
                         *text > ' ') {
                       *word++ = *text++;
                   }
                   *word = '\0';
                   *text_ptr = text;
                   return 1;
               }

       Discussion
           This is one of the larger recipes. But when you consider the number of calories it
           has, it's not so bad. The function "load_data" takes the name of a file as it's input.
           The file "cartoon.text" might look like:

               flintstones fred barney
               jetsons     george jane elroy
               simpsons    homer marge bart

           The function will read the file, parsing each line into words. Then it will create a
           new hash, whereby the first word in a line becomes a hash key and the remaining words
           are put into an array whose reference becomes the hash value. The output looks like
           this:

               $VAR1 = {
                         'flintstones' => [
                                            'fred',
                                            'barney'
                                          ],
                         'simpsons' => [
                                         'homer',
                                         'marge',
                                         'bart'
                                       ],
                         'jetsons' => [
                                        'george',
                                        'jane',
                                        'elroy'
                                      ]
                       };

       See Also
           See perlapi for information about the Perl5 internal API.

       Credits
           Al Danial <alnd@pacbell.net> requested a solution to this on comp.lang.perl.misc. He
           borrowed the idea from the "Hash of Lists" example in the Camel book.

Just Desserts

   Win32
       Problem
           How do I access Win32 DLL-s using Inline?

       Solution
               use Inline C => DATA =>
                          LIBS => '-luser32';

               $text = "@ARGV" || 'Inline.pm works with MSWin32. Scary...';

               WinBox('Inline Text Box', $text);

               __END__
               __C__

               #include <windows.h>

               int WinBox(char* Caption, char* Text) {
                 return MessageBoxA(0, Text, Caption, 0);
               }

       Discussion
           This example runs on MS Windows. It makes a text box appear on the screen which
           contains a message of your choice.

           The important thing is that its proof that you can use Inline to interact with Windows
           DLL-s. Very scary indeed. 8-o

           To use Inline on Windows with ActivePerl ( http://www.ActiveState.com ) you'll need MS
           Visual Studio. You can also use the Cygwin environment, available at
           http://www.cygwin.com .

       See Also
           See Inline-Support for more info on MSWin32 programming with Inline.

       Credits
           This example was adapted from some sample code written by Garrett Goebel
           <garrett@scriptpro.com>

   Embedding Perl in C
       Problem
           How do I use Perl from a regular C program?

       Solution
               #!/usr/bin/cpr

               int main(void) {

                   printf("Using Perl version %s from a C program!\n\n",
                          CPR_eval("use Config; $Config{version};"));

                   CPR_eval("use Data::Dumper;");
                   CPR_eval("print Dumper \\%INC;");

                   return 0;

               }

       Discussion
           By using CPR. (C Perl Run)

           This example uses another Inline module, "Inline::CPR", available separately on CPAN.
           When you install this module it also installs a binary interpreter called
           "/usr/bin/cpr". (The path may be different on your system)

           When you feed a C program to the CPR interpreter, it automatically compiles and runs
           your code using Inline. This gives you full access to the Perl internals. CPR also
           provides a set of easy to use C macros for calling Perl internals.

           This means that you can effectively "run" C source code by putting a CPR hashbang as
           the first line of your C program.

       See Also
           See Inline::CPR for more information on using CPR.

           "Inline::CPR" can be obtained from http://search.cpan.org/search?dist=Inline-CPR

       Credits
           Randal Schwartz <merlyn@stonehenge.com>, Randolph Bentson
           <bentson@grieg.holmsjoen.com>, Richard Anderson <starfire@zipcon.net>, and Tim Maher
           <tim@consultix-inc.com> helped me figure out how to write a program that would work as
           a hashbang.

Entertaining Guests

       As of version 0.30, Inline has the ability to work in cooperation with other modules that
       want to expose a C API of their own. The general syntax for doing this is:

           use Inline with => 'Module';
           use Inline C => ... ;

       This tells "Module" to pass configuration options to Inline. Options like typemaps,
       include paths, and external libraries, are all resolved automatically so you can just
       concentrate on writing the functions.

   Event handling with Event.pm
       Problem
           You need to write a C callback for the "Event.pm" module. Can this be done more easily
           with Inline?

       Solution
               use Inline with => 'Event';

               Event->timer(desc     => 'Timer #1',
                            interval => 2,
                            cb       => \&my_callback,
                           );

               Event->timer(desc     => 'Timer #2',
                            interval => 3,
                            cb       => \&my_callback,
                           );

               print "Starting...\n";
               Event::loop;

               use Inline C => <<'END';
               void my_callback(pe_event* event) {
                   pe_timer * watcher = event->up;

                   printf("%s\n\tEvent priority = %d\n\tWatcher priority = %d\n\n",
                          SvPVX(watcher->base.desc),
                          event->prio,
                          watcher->base.prio
                         );
               }
               END

       Discussion
           The first line tells Inline to load the "Event.pm" module. Inline then queries "Event"
           for configuration information. It gets the name and location of Event's header files,
           typemaps and shared objects. The parameters that "Event" returns look like:

               INC => "-I $path/Event",
               TYPEMAPS => "$path/Event/typemap",
               MYEXTLIB => "$path/auto/Event/Event.$so",
               AUTO_INCLUDE => '#include "EventAPI.h"',
               BOOT => 'I_EVENT_API("Inline");',

           Doing all of this automatically allows you, the programmer, to simply write a function
           that receives a pointer of type 'pe_event*'. This gives you access to the "Event"
           structure that was passed to you.

           In this example, I simply print values out of the structure. The Perl code defines 2
           timer events which each invoke the same callback. The first one, every two seconds,
           and the second one, every three seconds.

           As of this writing, "Event.pm" is the only CPAN module that works in cooperation with
           Inline.

       See Also
           Read the "Event.pm" documentation for more information. It contains a tutorial showing
           several examples of using Inline with "Event".

       Credits
           Jochen Stenzel <perl@jochen-stenzel.de> originally came up with the idea of mixing
           Inline and "Event". He also authored the "Event" tutorial.

           Joshua Pritikin <joshua.pritikin@db.com> is the author of "Event.pm".

Food for Thought

   Calling C from both Perl and C
       Problem
           I'd like to be able to call the same C function from both Perl and C.  Also I like to
           define a C function that doesn't get bound to Perl.  How do I do that?

       Solution
               print "9 + 5 = ", add(9, 5), "\n";
               print "SQRT(9^2 + 5^2) = ", pyth(9, 5), "\n";
               print "9 * 5 = ", mult(9, 5), "\n";

               use Inline C => <<'END_C';
               int add(int x, int y) {
                   return x + y;
               }
               static int mult(int x, int y) {
                   return x * y;
               }
               double pyth(int x, int y) {
                   return sqrt(add(mult(x, x), mult(y, y)));
               }
               END_C

       Discussion
           The program produces:

               9 + 5 = 14
               SQRT(9^2 + 5^2) = 10.295630140987
               Can't locate auto/main/mult.al in @INC ...

           Every Inline function that is bound to Perl is also callable by C. You don't have to
           do anything special. Inline arranges it so that all the typemap code gets done by XS
           and is out of sight. By the time the C function receives control, everything has been
           converted from Perl to C.

           Of course if your function manipulates the Perl Stack, you probably don't want to call
           it from C (unless you really know what you're doing).

           If you declare a function as "static", Inline won't bind it to Perl.  That's why we
           were able to call "mult()" from C but the call failed from Perl.

       See Also
       Credits

   Calling Perl from C
       Problem
           So now that I can call C from Perl, how do I call a Perl subroutine from an Inline C
           function.

       Solution
               use Inline C;

               for(1..5) {
                  c_func_1('This is the first line');
                  c_func_2('This is the second line');
                  print "\n";
               }

               sub perl_sub_1 {
                   print map "$_\n", @_;
               }

               __DATA__
               __C__

               void c_func_2(SV* text) {
                    dSP;

                    ENTER;
                    SAVETMPS;

                    XPUSHs(sv_2mortal(newSVpvf("Plus an extra line")));
                    PUTBACK;

                    call_pv("perl_sub_1", G_DISCARD);

                    FREETMPS;
                    LEAVE;
               }

               void c_func_1(SV* text) {
                    c_func_2(text);
               }

       Discussion
           This demo previously made use of Inline Stack macros only - but that's not the correct
           way to do it. Instead, base the callbacks on the perlcall documentation (as we're now
           doing).

           Actually, this program demonstrates calling a C function which calls another C
           function which in turn calls a Perl subroutine.

           The nice thing about Inline C functions is that you can call them from both Perl-space
           and C-space. That's because Inline creates a wrapper function around each C function.
           When you use Perl to call C you're actually calling that function's wrapper. The
           wrapper handles typemapping and Stack management, and then calls your C function.

           The first time we call "c_func_1" which calls "c_func_2". The second time we call
           "c_func_2" directly. "c_func_2" calls the Perl subroutine ("perl_sub_1") using the
           internal "perl_call_pv" function. It has to put arguments on the stack by hand. Since
           there is already one argument on the stack when we enter the function, the "XPUSHs" (
           which is equivalent to an "Inline_Stack_Push" ) adds a second argument.

           We iterate through a 'for' loop 5 times just to demonstrate that things still work
           correctly when we do that. (This was where the previous rendition, making use solely
           of Inline Stack macros, fell down.)

       See Also
           See Inline::C for more information about Stack macros.

           See perlapi for more information about the Perl5 internal API.

       Credits

   Evaling C
       Problem
           I've totally lost my marbles and I want to generate C code at run time, and "eval" it
           into Perl. How do I do this?

       Solution
               use Inline;
               use Code::Generator;

               my $c_code = generate('foo_function');

               Inline->bind(C => $c_code);

               foo_function(1, 2, 3);

       Discussion
           I can't think of a real life application where you would want to generate C code on
           the fly, but at least I know how I would do it.  :)

           The "bind()" function of Inline let's you bind (compile/load/execute) C functions at
           run time. It takes all of the same arguments as 'use Inline C => ...'.

           The nice thing is that once a particular snippet is compiled, it remains cached so
           that it doesn't need to be compiled again. I can imagine that someday a mad scientist
           will dream up a self generating modeling system that would run faster and faster over
           time.

           If you know such a person, have them drop me a line.

       See Also
       Credits

   Providing a pure perl alternative
       Problem
           I want to write a script that will use a C subroutine if Inline::C is installed, but
           will otherwise use an equivalent pure perl subroutine if Inline::C is not already
           installed.  How do I do this?

       Solution
             use strict;
              use warnings;

             eval {
              require Inline;
              Inline->import (C => Config =>
                              BUILD_NOISY => 1);
              Inline->import (C =><<'EOC');

              int foo() {
                warn("Using Inline\n");
                return 42;
              }

             EOC
             };

             if($@) {
               *foo =\&bar;
             }

             sub bar {
               warn("Using Pure Perl Implementation\n");
               return 42;
             }

             my $x = foo();
             print "$x\n";

       Discussion
           If Inline::C is installed and functioning properly, the C sub foo is called by the
           perl code. Otherwise, $@ gets set, and the equivalent pure perl function bar is
           instead called.

           Note, too, that the pure perl sub bar can still be explicitly called even if Inline::C
           is available.

   Accessing Fortran subs using Inline::C
       Problem
           I've been given a neat little sub written in fortran that takes, as its args, two
           integers and returns their product. And I would like to use that sub as is from
           Inline::C. By way of example, let's say that the fortran source file is named
           'prod.f', and that it looks like this:

                 integer function sqarea(r,s)
                 integer r, s
                 sqarea = r*s
                 return
                 end

       Solution
           We can't access that code directly, but we can compile it into a library which we
           *can* then access from Inline::C.  Using gcc we could run:

             gfortran -c prod.f -o prod.o
             ar cru libprod.a prod.o

           The function is then accessible as follows:

             use warnings;

             use Inline C => Config =>
               LIBS =>
                '-L/full/path/to/libprod_location -lprod -lgfortran';

             use Inline C => <<'  EOC';

             int wrap_sqarea(int a, int b) {
                 return sqarea_(&a, &b);
             }

             EOC

             $x = 15;
             $y = $x + 3;
             $ret = wrap_sqarea($x, $y);
             print "Product of $x and $y is $ret\n";

       Discussion
           Note firstly that, although the function is specified as 'sqarea' in the source file,
           gfortran appends an underscore to the name when the source is compiled. (I don't know
           if *all* fortran compilers do this.) Therefore Inline::C needs to call the function as
           'sqarea_'.

           Secondly, because fortran subs pass args by reference, we need to pass the *addresses*
           of the two integer args to sqarea() when we call it from our Inline::C sub.

           If using g77 instead of gfortran, the only necessary change is that we specify '-lg2c'
           instead of '-lgfortran' in our 'LIBS' setting.

SEE ALSO

       For generic information about Inline, see Inline.

       For information about using Inline with C see Inline::C.

       For information on supported languages and platforms see Inline-Support.

       For information on writing your own Inline language support module, see Inline-API.

       Inline's mailing list is inline@perl.org

       To subscribe, send email to inline-subscribe@perl.org

AUTHOR

       Brian Ingerson <INGY@cpan.org>

COPYRIGHT

       Copyright (c) 2001, 2002. Brian Ingerson.

       Copyright (c) 2008, 2010-2013. Sisyphus.

       All Rights Reserved. This module is free software. It may be used, redistributed and/or
       modified under the terms of the Perl Artistic License.

       See http://www.perl.com/perl/misc/Artistic.html