use strict;
use warnings;
{ no warnings 'once'; # pass info back to Makefile.PL
$PDL::Core::Dev::EXTRAS{$::PDLMOD}{OBJECT} .= join '', map " $::PDLBASE/$_\$(OBJ_EXT)", qw(ppm_quant);
$PDL::Core::Dev::EXTRAS{$::PDLMOD}{INC} .= qq{ "-I$::PDLBASE"};
}
pp_add_exported('',"interlrgb rgbtogr bytescl cquant ");
pp_addhdr('
#include "pdlppm.h" /* Local decs */
');
pp_addpm({At=>'Top'},<<'EOD');
use strict;
use warnings;
=head1 NAME
PDL::ImageRGB -- some utility functions for RGB image data handling
=head1 DESCRIPTION
Collection of a few commonly used routines involved in handling of RGB, palette
and grayscale images. Not much more than a start. Should be a good place to
exercise some of the broadcast/map/clump PP stuff.
Other stuff that should/could go here:
=over 3
=item *
color space conversion
=item *
common image filters
=item *
image rebinning
=back
=head1 SYNOPSIS
use PDL::ImageRGB;
=cut
use vars qw( $typecheck $EPS );
use PDL::Core;
use PDL::Basic;
use PDL::Primitive;
use PDL::Types;
use Carp;
use strict 'vars';
$PDL::ImageRGB::EPS = 1e-7; # there is probably a more portable way
=head1 FUNCTIONS
=head2 cquant
=for ref
quantize and reduce colours in 8-bit images
=for usage
($out, $lut) = cquant($image [,$ncols]);
This function does color reduction for <=8bit displays and accepts 8bit RGB
and 8bit palette images. It does this through an interface to the ppm_quant
routine from the pbmplus package that implements the median cut routine which
intelligently selects the 'best' colors to represent your image on a <= 8bit
display (based on the median cut algorithm). Optional args: $ncols sets the
maximum nunmber of colours used for the output image (defaults to 256).
There are images where a different color
reduction scheme gives better results (it seems this is true for images
containing large areas with very smoothly changing colours).
Returns a list containing the new palette image (type PDL_Byte) and the RGB
colormap.
=cut
# full broadcasting support intended
*cquant = \&PDL::cquant;
sub PDL::cquant {
barf 'Usage: ($out,$olut) = cquant($image[,$ncols])'
if $#_<0 || $#_>1;
my $image = shift;
my $ncols;
if ($#_ >= 0 ) { $ncols=shift; } else { $ncols = 256; };
my @Dims = $image->dims;
my ($out, $olut) = (null,null);
barf "input must be byte (3,x,x)" if (@Dims < 2) || ($Dims[0] != 3)
|| ($image->get_datatype != $PDL_B);
cquant_c($image,$out,$olut,$ncols);
return ($out,$olut);
}
=head2 interlrgb
=for ref
Make an RGB image from a palette image and its lookup table.
=for usage
$rgb = $palette_im->interlrgb($lut)
Input should be of an integer type and the lookup table (3,x,...). Will perform
the lookup for any N-dimensional input pdl (i.e. 0D, 1D, 2D, ...). Uses the
index command but will dataflow only if
the $lut ndarray has the dataflow_forward flag set (see L<PDL::Core/fflows>).
=cut
# interlace a palette image, input as 8bit-image, RGB-lut (3,x,..) to
# (R,G,B) format for each pixel in the image
# should already support broadcasting
*interlrgb=\&PDL::interlrgb;
sub PDL::interlrgb {
my ($pdl,$lut) = @_;
my $lut_fflows = $lut->fflows;
# for our purposes $lut should be (3,z) where z is the number
# of colours in the lut
barf "expecting (3,x) input" if ($lut->dims)[0] != 3;
# do the conversion as an implicitly broadcasted index lookup
my $res = $lut->transpose->index($pdl->dummy(0));
$res->sever if !$lut_fflows;
return $res;
}
=head2 rgbtogr
=for ref
Converts an RGB image to a grey scale using standard transform
=for usage
$gr = $rgb->rgbtogr
Performs a conversion of an RGB input image (3,x,....) to a
greyscale image (x,.....) using standard formula:
Grey = 0.301 R + 0.586 G + 0.113 B
=cut
# convert interlaced rgb image to grayscale
# will convert any (3,...) dim pdl, i.e. also single lines,
# stacks of RGB images, etc since implicit broadcasting takes care of this
# should already support broadcasting
*rgbtogr = \&PDL::rgbtogr;
sub PDL::rgbtogr {
barf "Usage: \$im->rgbtogr" if $#_ < 0;
my $im = shift;
barf "rgbtogr: expecting RGB (3,...) input"
if (($im->dims)[0] != 3);
my $type = $im->get_datatype;
my $rgb = float([77,150,29])/256; # vector for rgb conversion
my $oim = null; # flag PP we want it to allocate
inner($im,$rgb,$oim); # do the conversion as a broadcasted inner prod
return $oim->convert($type); # convert back to original type
}
=head2 bytescl
=for ref
Scales a pdl into a specified data range (default 0-255)
=for usage
$scale = $im->bytescl([$top])
By default $top=255, otherwise you have to give the desired top value as an
argument to C<bytescl>. Normally C<bytescl> doesn't rescale data that fits
already in the bounds 0..$top (it only does the type conversion if required).
If you want to force it to rescale so that the max of the output is at $top and
the min at 0 you give a negative $top value to indicate this.
=cut
# scale any pdl linearly so that its data fits into the range
# 0<=x<=$ncols where $ncols<=255
# returns scaled data with type converted to byte
# doesn't rescale but just typecasts if data already fits into range, i.e.
# data ist not necessarily stretched to 0..$ncols
# needs some changes for full broadcasting support ?? (explicit broadcasting?)
*bytescl = \&PDL::bytescl;
sub PDL::bytescl {
barf 'Usage: bytescl $im[,$top]' if $#_ < 0;
my $pdl = shift;
my ($top,$force) = (255,0);
$top = shift if $#_ > -1;
if ($top < 0) { $force=1; $top *= -1; }
$top = 255 if $top > 255;
print "bytescl: scaling from 0..$top\n" if $PDL::debug;
my ($max, $min);
$max = max $pdl;
$min = min $pdl;
return byte $pdl if ($min >= 0 && $max <= $top && !$force);
# check for pathological cases
if (($max-$min) < $EPS) {
print "bytescl: pathological case\n" if $PDL::debug;
return byte $pdl
if (abs($max) < $EPS) || ($max >= 0 && $max <= $top);
return byte ($pdl/$max);
}
my $type = $pdl->get_datatype > $PDL_F ? $PDL_D : $PDL_F;
return byte ($top*($pdl->convert($type)-$min)/($max-$min)+0.5);
}
;# Exit with OK status
1;
=head1 BUGS
This package doesn't yet contain enough useful functions!
=head1 AUTHOR
Copyright 1997 Christian Soeller <c.soeller@auckland.ac.nz>
All rights reserved. There is no warranty. You are allowed
to redistribute this software / documentation under certain
conditions. For details, see the file COPYING in the PDL
distribution. If this file is separated from the PDL distribution,
the copyright notice should be included in the file.
=cut
EOD
################################ XS CODE #################################
# a is the input image
# b is the output image and c the output lut
pp_def(
'cquant_c',Doc=>undef,
Pars => 'a(m=3,n,o); [o]b(n,o); [o]c(m,p);',
GenericTypes => ['B'],
OtherPars => 'int psz => p',
Code => 'int status;
status = ppm_quant($P(a), NULL, NULL, $SIZE(n),
$SIZE(o),$P(b), NULL, $P(c), 0,
$SIZE(p), 1);
if (!status)
$CROAK("ppm_quant returned error status");'
);
pp_done();