NAME

    FFI::C - C data types for FFI

VERSION

    version 0.02

SYNOPSIS

    In C:

     #include <stdint.h>
     
     typedef struct {
       uint8_t red;
       uint8_t green;
       uint8_t blue;
     } color_value_t;
     
     typedef struct {
       char name[22];
       color_value_t value;
     } named_color_t;
     
     typedef named_color_t array_named_color_t[4];
     
     typedef union {
       uint8_t  u8;
       uint16_t u16;
       uint32_t u32;
       uint64_t u64;
     } anyint_t;

    In Perl:

     use FFI::C;
     
     package ColorValue {
       FFI::C->struct([
         red   => 'uint8',
         green => 'uint8',
         blue  => 'uint8',
       ]);
     }
     
     package NamedColor {
       FFI::C->struct([
         name  => 'string(22)',
         value => 'color_value_t',
       ]);
     }
     
     package ArrayNamedColor {
       FFI::C->array(['named_color_t' => 4]);
     };
     
     my $array = ArrayNamedColor->new([
       { name => "red",    value => { red   => 255 } },
       { name => "green",  value => { green => 255 } },
       { name => "blue",   value => { blue  => 255 } },
       { name => "purple", value => { red   => 255,
                                      blue  => 255 } },
     ]);
     
     # dim each color by 1/2
     foreach my $color (@$array)
     {
       $color->value->red  ( $color->value->red   / 2 );
       $color->value->green( $color->value->green / 2 );
       $color->value->blue ( $color->value->blue  / 2 );
     }
     
     # print out the colors
     foreach my $color (@$array)
     {
       printf "%s [%02x %02x %02x]\n",
         $color->name,
         $color->value->red,
         $color->value->green,
         $color->value->blue;
     }
     
     package AnyInt {
       FFI::C->union([
         u8  => 'uint8',
         u16 => 'uint16',
         u32 => 'uint32',
         u64 => 'uint64',
       ]);
     }
     
     my $int = AnyInt->new({ u8 => 42 });
     print $int->u32;

DESCRIPTION

    This distribution provides tools for building classes to interface for
    common C data types. Arrays, struct, union and nested types based on
    those are supported.

METHODS

 ffi

 struct

     FFI::C->struct($name, \@members);
     FFI::C->struct(\@members);

    Generate a new FFI::C::Struct class with the given @members into the
    calling package. (@members should be a list of name/type pairs). You
    may optionally give a $name which will be used for the FFI::Platypus
    type name for the generated class. If you do not specify a $name, a C
    style name will be generated from the last segment in the calling
    package name by converting to snake case and appending a _t to the end.

    As an example, given:

     package MyLibrary::FooBar {
       FFI::C->struct([
         a => 'uint8',
         b => 'float',
       ]);
     };

    You can use MyLibrary::FooBar via the file scoped FFI::Platypus
    instance using the type foo_bar_t.

     my $foobar = MyLibrary::FooBar->new({ a => 1, b => 3.14 });
     $ffi->function( my_library_func => [ 'foo_bar_t' ] => 'void' )->call($foobar);

 union

     FFI::C->union($name, \@members);
     FFI::C->union(\@members);

    This works exactly like the struct method above, except a FFI::C::Union
    class is generated instead.

 array

     FFI::C->array($name, [$type, $count]);
     FFI::C->array($name, [$type]);
     FFI::C->array([$type, $count]);
     FFI::C->array([$type]);

    This is similar to struct and union above, except FFI::C::Array is
    generated. For an array you give it the member type and the element
    count. The element count is optional for variable length arrays, but
    keep in mind that when you create such an array you do need to provide
    a size.

EXAMPLES

 unix time struct

     use FFI::Platypus 1.00;
     use FFI::C;
     
     my $ffi = FFI::Platypus->new(
       api => 1,
       lib => [undef],
     );
     FFI::C->ffi($ffi);
     
     package Unix::TimeStruct {
     
       FFI::C->struct(tm => [
         tm_sec    => 'int',
         tm_min    => 'int',
         tm_hour   => 'int',
         tm_mday   => 'int',
         tm_mon    => 'int',
         tm_year   => 'int',
         tm_wday   => 'int',
         tm_yday   => 'int',
         tm_isdst  => 'int',
         tm_gmtoff => 'long',
         _tm_zone  => 'opaque',
       ]);
     
       # For now 'string' is unsupported by FFI::C, but we
       # can cast the time zone from an opaque pointer to
       # string.
       sub tm_zone {
         my $self = shift;
         $ffi->cast('opaque', 'string', $self->_tm_zone);
       }
     
       # attach the C localtime function
       $ffi->attach( localtime => ['time_t*'] => 'tm', sub {
         my($inner, $class, $time) = @_;
         $time = time unless defined $time;
         $inner->(\$time);
       });
     }
     
     # now we can actually use our My::UnixTime class
     my $time = Unix::TimeStruct->localtime;
     printf "time is %d:%d:%d %s\n",
       $time->tm_hour,
       $time->tm_min,
       $time->tm_sec,
       $time->tm_zone;

CAVEATS

    FFI::C objects must be passed into C via FFI::Platypus by pointers.
    So-called "pass-by-value" is not and will not be supported. For
    "pass-by-value" record types, you should instead use
    FFI::Platypus::Record.

SEE ALSO

    FFI::C

    FFI::C::Array

    FFI::C::ArrayDef

    FFI::C::Def

    FFI::C::Struct

    FFI::C::StructDef

    FFI::C::Union

    FFI::C::UnionDef

    FFI::C::Util

    FFI::Platypus::Record

AUTHOR

    Graham Ollis <plicease@cpan.org>

COPYRIGHT AND LICENSE

    This software is copyright (c) 2020 by Graham Ollis.

    This is free software; you can redistribute it and/or modify it under
    the same terms as the Perl 5 programming language system itself.

