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# G. Ward |
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# |
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use strict; |
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use File::Temp qw/ :mktemp /; |
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sub userror { |
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< |
print STDERR "Usage: genBSDF [-n Nproc][-c Nsamp][-dim xmin xmax ymin ymax zmin zmax][{+|-}f][{+|-}b][{+|-}mgf][{+|-}geom] [input ..]\n"; |
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print STDERR "Usage: genBSDF [-n Nproc][-c Nsamp][-t{3|4} Nlog2][-r \"ropts\"][-dim xmin xmax ymin ymax zmin zmax][{+|-}f][{+|-}b][{+|-}mgf][{+|-}geom] [input ..]\n"; |
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exit 1; |
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} |
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< |
my $td = `mktemp -d /tmp/genBSDF.XXXXXX`; |
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my $td = mkdtemp("/tmp/genBSDF.XXXXXX"); |
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chomp $td; |
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my $tensortree = 0; |
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my $ttlog2 = 4; |
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my $nsamp = 1000; |
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my $rtargs = "-w -ab 5 -ad 700 -lw 3e-6"; |
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my $mgfin = 0; |
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my $geout = 1; |
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my $nproc = 1; |
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while ($#ARGV >= 0) { |
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if ("$ARGV[0]" =~ /^[-+]m/) { |
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$mgfin = ("$ARGV[0]" =~ /^\+/); |
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} elsif ("$ARGV[0]" eq "-r") { |
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$rtargs = "$rtargs $ARGV[1]"; |
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shift @ARGV; |
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} elsif ("$ARGV[0]" =~ /^[-+]g/) { |
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$geout = ("$ARGV[0]" =~ /^\+/); |
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} elsif ("$ARGV[0]" =~ /^[-+]f/) { |
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$doforw = ("$ARGV[0]" =~ /^\+/); |
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} elsif ("$ARGV[0]" =~ /^[-+]b/) { |
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$doback = ("$ARGV[0]" =~ /^\+/); |
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} elsif ("$ARGV[0]" =~ /^-t[34]$/) { |
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$tensortree = substr($ARGV[0], 2, 1); |
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$ttlog2 = $ARGV[1]; |
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shift @ARGV; |
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} elsif ("$ARGV[0]" eq "-c") { |
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$nsamp = $ARGV[1]; |
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shift @ARGV; |
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shift @ARGV; |
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} |
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# Check that we're actually being asked to do something |
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die "Must have at least one of +forward or +backward" if (!$doforw && !$doback); |
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die "Must have at least one of +forward or +backward\n" if (!$doforw && !$doback); |
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# Name our own persist file? |
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my $persistfile; |
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if ( $tensortree && $nproc > 1 && "$rtargs" !~ /-PP /) { |
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$persistfile = "$td/pfile.txt"; |
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$rtargs = "-PP $persistfile $rtargs"; |
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} |
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# Get scene description and dimensions |
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my $radscn = "$td/device.rad"; |
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my $mgfscn = "$td/device.mgf"; |
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die "Could not load MGF input\n" if ( $? ); |
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system "mgf2rad $mgfscn > $radscn"; |
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} else { |
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system "cat @ARGV | xform -e > $radscn"; |
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system "xform -e @ARGV > $radscn"; |
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die "Could not load Radiance input\n" if ( $? ); |
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system "rad2mgf $radscn > $mgfscn" if ( $geout ); |
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} |
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} |
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print STDERR "Warning: Device extends into room\n" if ($dim[5] > 1e-5); |
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# Add receiver surfaces (rectangular) |
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my $bmodnm="receiver_behind"; |
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my $fmodnm="receiver_face"; |
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my $bmodnm="receiver_behind"; |
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open(RADSCN, ">> $radscn"); |
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print RADSCN "void glow $fmodnm\n0\n0\n4 0 0 0 0\n\n"; |
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print RADSCN "$fmodnm polygon f_receiver\n0\n0\n12\n"; |
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print RADSCN "\t",$dim[0],"\t",$dim[2],"\t",$dim[5]+2e-5,"\n"; |
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print RADSCN "\t",$dim[0],"\t",$dim[3],"\t",$dim[5]+2e-5,"\n"; |
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print RADSCN "\t",$dim[1],"\t",$dim[3],"\t",$dim[5]+2e-5,"\n"; |
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print RADSCN "\t",$dim[1],"\t",$dim[2],"\t",$dim[5]+2e-5,"\n"; |
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print RADSCN "void glow $bmodnm\n0\n0\n4 0 0 0 0\n\n"; |
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print RADSCN "$bmodnm polygon b_receiver\n0\n0\n12\n"; |
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print RADSCN "\t",$dim[1],"\t",$dim[2],"\t",$dim[4]-2e-5,"\n"; |
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print RADSCN "\t",$dim[1],"\t",$dim[3],"\t",$dim[4]-2e-5,"\n"; |
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print RADSCN "\t",$dim[0],"\t",$dim[3],"\t",$dim[4]-2e-5,"\n"; |
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print RADSCN "\t",$dim[0],"\t",$dim[2],"\t",$dim[4]-2e-5,"\n"; |
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print RADSCN "void glow $fmodnm\n0\n0\n4 1 1 1 0\n\n"; |
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print RADSCN "$fmodnm source f_receiver\n0\n0\n4 0 0 1 180\n"; |
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print RADSCN "void glow $bmodnm\n0\n0\n4 1 1 1 0\n\n"; |
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print RADSCN "$bmodnm source b_receiver\n0\n0\n4 0 0 -1 180\n"; |
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close RADSCN; |
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# Generate octree |
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system "oconv -w $radscn > $octree"; |
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die "Could not compile scene\n" if ( $? ); |
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# Set up sampling of interior portal |
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# Output XML prologue |
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print |
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'<?xml version="1.0" encoding="UTF-8"?> |
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<WindowElement xmlns="http://windows.lbl.gov" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://windows.lbl.gov/BSDF-v1.4.xsd"> |
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<WindowElementType>System</WindowElementType> |
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<Optical> |
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<Layer> |
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<Material> |
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<Name>Name</Name> |
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<Manufacturer>Manufacturer</Manufacturer> |
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'; |
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printf "\t\t<Thickness unit=\"Meter\">%.3f</Thickness>\n", $dim[5] - $dim[4]; |
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printf "\t\t<Width unit=\"Meter\">%.3f</Width>\n", $dim[1] - $dim[0]; |
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printf "\t\t<Height unit=\"Meter\">%.3f</Height>\n", $dim[3] - $dim[2]; |
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print "\t\t<DeviceType>Integral</DeviceType>\n"; |
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# Output MGF description if requested |
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if ( $geout ) { |
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print "\t\t<Geometry format=\"MGF\" unit=\"Meter\">\n"; |
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printf "xf -t %.6f %.6f 0\n", -($dim[0]+$dim[1])/2, -($dim[2]+$dim[3])/2; |
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open(MGFSCN, "< $mgfscn"); |
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while (<MGFSCN>) { print $_; } |
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close MGFSCN; |
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print "xf\n"; |
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print "\t\t</Geometry>\n"; |
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} |
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print " </Material>\n"; |
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# Set up surface sampling |
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my $nx = int(sqrt($nsamp*($dim[1]-$dim[0])/($dim[3]-$dim[2])) + .5); |
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> |
my $ny = int($nsamp/$nx + .5); |
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> |
$nsamp = $nx * $ny; |
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> |
my $ns = 2**$ttlog2; |
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my (@pdiv, $disk2sq, $sq2disk, $tcal, $kcal); |
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# Create data segments (all the work happens here) |
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if ( $tensortree ) { |
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do_tree_bsdf(); |
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} else { |
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do_matrix_bsdf(); |
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} |
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# Output XML epilogue |
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print |
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'</Layer> |
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</Optical> |
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</WindowElement> |
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'; |
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# Clean up temporary files and exit |
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if ( $persistfile && open(PFI, "< $persistfile") ) { |
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while (<PFI>) { |
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s/^[^ ]* //; |
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kill('ALRM', $_); |
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last; |
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} |
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close PFI; |
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} |
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exec("rm -rf $td"); |
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|
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#-------------- End of main program segment --------------# |
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|
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#++++++++++++++ Tensor tree BSDF generation ++++++++++++++# |
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sub do_tree_bsdf { |
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# Get sampling rate and subdivide task |
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my $ns2 = $ns; |
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$ns2 /= 2 if ( $tensortree == 3 ); |
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@pdiv = (0, int($ns2/$nproc)); |
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my $nrem = $ns2 % $nproc; |
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for (my $i = 1; $i < $nproc; $i++) { |
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my $nv = $pdiv[$i] + $pdiv[1]; |
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++$nv if ( $nrem-- > 0 ); |
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push @pdiv, $nv; |
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} |
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die "Script error 1" if ($pdiv[-1] != $ns2); |
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# Shirley-Chiu mapping from unit square to disk |
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$sq2disk = ' |
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in_square_a = 2*in_square_x - 1; |
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in_square_b = 2*in_square_y - 1; |
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in_square_rgn = if(in_square_a + in_square_b, |
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if(in_square_a - in_square_b, 1, 2), |
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if(in_square_b - in_square_a, 3, 4)); |
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out_disk_r = .999995*select(in_square_rgn, in_square_a, in_square_b, |
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-in_square_a, -in_square_b); |
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out_disk_phi = PI/4 * select(in_square_rgn, |
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in_square_b/in_square_a, |
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2 - in_square_a/in_square_b, |
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4 + in_square_b/in_square_a, |
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if(in_square_b*in_square_b, |
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6 - in_square_a/in_square_b, 0)); |
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Dx = out_disk_r*cos(out_disk_phi); |
183 |
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Dy = out_disk_r*sin(out_disk_phi); |
184 |
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Dz = sqrt(1 - out_disk_r*out_disk_r); |
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'; |
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# Shirley-Chiu mapping from unit disk to square |
187 |
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$disk2sq = ' |
188 |
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norm_radians(p) : if(-p - PI/4, p + 2*PI, p); |
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in_disk_r = .999995*sqrt(Dx*Dx + Dy*Dy); |
190 |
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in_disk_phi = norm_radians(atan2(Dy, Dx)); |
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in_disk_rgn = floor((in_disk_phi + PI/4)/(PI/2)) + 1; |
192 |
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out_square_a = select(in_disk_rgn, |
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in_disk_r, |
194 |
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(PI/2 - in_disk_phi)*in_disk_r/(PI/4), |
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-in_disk_r, |
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(in_disk_phi - 3*PI/2)*in_disk_r/(PI/4)); |
197 |
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out_square_b = select(in_disk_rgn, |
198 |
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in_disk_phi*in_disk_r/(PI/4), |
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in_disk_r, |
200 |
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(PI - in_disk_phi)*in_disk_r/(PI/4), |
201 |
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-in_disk_r); |
202 |
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out_square_x = (out_square_a + 1)/2; |
203 |
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out_square_y = (out_square_b + 1)/2; |
204 |
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'; |
205 |
> |
# Announce ourselves in XML output |
206 |
> |
print "\t<DataDefinition>\n"; |
207 |
> |
print "\t\t<IncidentDataStructure>TensorTree$tensortree</IncidentDataStructure>\n"; |
208 |
> |
print "\t</DataDefinition>\n"; |
209 |
> |
# Fork parallel rtcontrib processes to compute each side |
210 |
> |
if ( $doback ) { |
211 |
> |
for (my $proc = 0; $proc < $nproc; $proc++) { |
212 |
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bg_tree_rtcontrib(0, $proc); |
213 |
> |
} |
214 |
> |
while (wait() >= 0) { |
215 |
> |
die "rtcontrib process reported error" if ( $? ); |
216 |
> |
} |
217 |
> |
ttree_out(0); |
218 |
> |
} |
219 |
> |
if ( $doforw ) { |
220 |
> |
for (my $proc = 0; $proc < $nproc; $proc++) { |
221 |
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bg_tree_rtcontrib(1, $proc); |
222 |
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} |
223 |
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while (wait() >= 0) { |
224 |
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die "rtcontrib process reported error" if ( $? ); |
225 |
> |
} |
226 |
> |
ttree_out(1); |
227 |
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} |
228 |
> |
} # end of sub do_tree_bsdf() |
229 |
> |
|
230 |
> |
# Run i'th rtcontrib process for generating tensor tree samples |
231 |
> |
sub bg_tree_rtcontrib { |
232 |
> |
my $pid = fork(); |
233 |
> |
die "Cannot fork new process" unless defined $pid; |
234 |
> |
if ($pid > 0) { return $pid; } |
235 |
> |
my $forw = shift; |
236 |
> |
my $pn = shift; |
237 |
> |
my $pbeg = $pdiv[$pn]; |
238 |
> |
my $plen = $pdiv[$pn+1] - $pbeg; |
239 |
> |
my $matargs = "-m $bmodnm"; |
240 |
> |
if ( !$forw || !$doback ) { $matargs .= " -m $fmodnm"; } |
241 |
> |
my $cmd = "rtcontrib $rtargs -h -ff -fo -c $nsamp " . |
242 |
> |
"-e '$disk2sq' -bn '$ns*$ns' " . |
243 |
> |
"-b '$ns*floor(out_square_x*$ns)+floor(out_square_y*$ns)' " . |
244 |
> |
"-o $td/%s_" . sprintf("%03d", $pn) . ".flt $matargs $octree"; |
245 |
> |
if ( $tensortree == 3 ) { |
246 |
> |
# Isotropic BSDF |
247 |
> |
$cmd = "cnt $plen $ny $nx " . |
248 |
> |
"| rcalc -e 'r1=rand(($pn+.8681)*recno-.673892)' " . |
249 |
> |
"-e 'r2=rand(($pn-5.37138)*recno+67.1737811)' " . |
250 |
> |
"-e 'r3=rand(($pn+3.17603772)*recno+83.766771)' " . |
251 |
> |
"-e 'Dx=1-2*($pbeg+\$1+r1)/$ns;Dy:0;Dz=sqrt(1-Dx*Dx)' " . |
252 |
> |
"-e 'xp=(\$3+r2)*(($dim[1]-$dim[0])/$nx)+$dim[0]' " . |
253 |
> |
"-e 'yp=(\$2+r3)*(($dim[3]-$dim[2])/$ny)+$dim[2]' " . |
254 |
> |
"-e 'zp=$dim[5-$forw]' -e 'myDz=Dz*($forw*2-1)' " . |
255 |
> |
"-e '\$1=xp-Dx;\$2=yp-Dy;\$3=zp-myDz' " . |
256 |
> |
"-e '\$4=Dx;\$5=Dy;\$6=myDz' -of " . |
257 |
> |
"| $cmd"; |
258 |
> |
} else { |
259 |
> |
# Anisotropic BSDF |
260 |
> |
# Sample area vertically to improve load balance, since |
261 |
> |
# shading systems usually have bilateral symmetry (L-R) |
262 |
> |
$cmd = "cnt $plen $ns $ny $nx " . |
263 |
> |
"| rcalc -e 'r1=rand(($pn+.8681)*recno-.673892)' " . |
264 |
> |
"-e 'r2=rand(($pn-5.37138)*recno+67.1737811)' " . |
265 |
> |
"-e 'r3=rand(($pn+3.17603772)*recno+83.766771)' " . |
266 |
> |
"-e 'r4=rand(($pn-2.3857833)*recno-964.72738)' " . |
267 |
> |
"-e 'in_square_x=($pbeg+\$1+r1)/$ns' " . |
268 |
> |
"-e 'in_square_y=(\$2+r2)/$ns' -e '$sq2disk' " . |
269 |
> |
"-e 'xp=(\$4+r3)*(($dim[1]-$dim[0])/$nx)+$dim[0]' " . |
270 |
> |
"-e 'yp=(\$3+r4)*(($dim[3]-$dim[2])/$ny)+$dim[2]' " . |
271 |
> |
"-e 'zp=$dim[5-$forw]' -e 'myDz=Dz*($forw*2-1)' " . |
272 |
> |
"-e '\$1=xp-Dx;\$2=yp-Dy;\$3=zp-myDz' " . |
273 |
> |
"-e '\$4=Dx;\$5=Dy;\$6=myDz' -of " . |
274 |
> |
"| $cmd"; |
275 |
> |
} |
276 |
> |
# print STDERR "Starting: $cmd\n"; |
277 |
> |
exec($cmd); # no return; status report to parent via wait |
278 |
> |
die "Cannot exec: $cmd\n"; |
279 |
> |
} # end of bg_tree_rtcontrib() |
280 |
> |
|
281 |
> |
# Simplify and output tensor tree results |
282 |
> |
sub ttree_out { |
283 |
> |
my $forw = shift; |
284 |
> |
my $side = ("Back","Front")[$forw]; |
285 |
> |
# Only output one transmitted distribution, preferring backwards |
286 |
> |
if ( !$forw || !$doback ) { |
287 |
> |
print |
288 |
> |
' <WavelengthData> |
289 |
> |
<LayerNumber>System</LayerNumber> |
290 |
> |
<Wavelength unit="Integral">Visible</Wavelength> |
291 |
> |
<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum> |
292 |
> |
<DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum> |
293 |
> |
<WavelengthDataBlock> |
294 |
> |
<WavelengthDataDirection>Transmission</WavelengthDataDirection> |
295 |
> |
<AngleBasis>LBNL/Shirley-Chiu</AngleBasis> |
296 |
> |
<ScatteringDataType>BTDF</ScatteringDataType> |
297 |
> |
<ScatteringData> |
298 |
> |
'; |
299 |
> |
system "rcalc -if3 -e 'Omega:PI/($ns*$ns)' " . |
300 |
> |
q{-e '$1=(0.265*$1+0.670*$2+0.065*$3)/Omega' -of } . |
301 |
> |
"$td/" . ($bmodnm,$fmodnm)[$forw] . "_???.flt " . |
302 |
> |
"| rttree_reduce -h -ff -r $tensortree -g $ttlog2"; |
303 |
> |
die "Failure running rttree_reduce" if ( $? ); |
304 |
> |
print |
305 |
> |
' </ScatteringData> |
306 |
> |
</WavelengthDataBlock> |
307 |
> |
</WavelengthData> |
308 |
> |
'; |
309 |
> |
} |
310 |
> |
# Output reflection |
311 |
> |
print |
312 |
> |
' <WavelengthData> |
313 |
> |
<LayerNumber>System</LayerNumber> |
314 |
> |
<Wavelength unit="Integral">Visible</Wavelength> |
315 |
> |
<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum> |
316 |
> |
<DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum> |
317 |
> |
<WavelengthDataBlock> |
318 |
> |
'; |
319 |
> |
print "\t\t\t<WavelengthDataDirection>Reflection $side</WavelengthDataDirection>\n"; |
320 |
> |
print ' <AngleBasis>LBNL/Shirley-Chiu</AngleBasis> |
321 |
> |
<ScatteringDataType>BRDF</ScatteringDataType> |
322 |
> |
<ScatteringData> |
323 |
> |
'; |
324 |
> |
system "rcalc -if3 -e 'Omega:PI/($ns*$ns)' " . |
325 |
> |
q{-e '$1=(0.265*$1+0.670*$2+0.065*$3)/Omega' -of } . |
326 |
> |
"$td/" . ($fmodnm,$bmodnm)[$forw] . "_???.flt " . |
327 |
> |
"| rttree_reduce -h -ff -r $tensortree -g $ttlog2"; |
328 |
> |
die "Failure running rttree_reduce" if ( $? ); |
329 |
> |
print |
330 |
> |
' </ScatteringData> |
331 |
> |
</WavelengthDataBlock> |
332 |
> |
</WavelengthData> |
333 |
> |
'; |
334 |
> |
} # end of ttree_out() |
335 |
> |
|
336 |
> |
#------------- End of do_tree_bsdf() & subroutines -------------# |
337 |
> |
|
338 |
> |
#+++++++++++++++ Klems matrix BSDF generation +++++++++++++++# |
339 |
> |
sub do_matrix_bsdf { |
340 |
> |
# Set up sampling of portal |
341 |
|
# Kbin to produce incident direction in full Klems basis with (x1,x2) randoms |
342 |
< |
my $tcal = ' |
342 |
> |
$tcal = ' |
343 |
|
DEGREE : PI/180; |
344 |
|
sq(x) : x*x; |
345 |
|
Kpola(r) : select(r+1, -5, 5, 15, 25, 35, 45, 55, 65, 75, 90); |
360 |
|
1 - sq(cos(Kpola(1)*DEGREE))); |
361 |
|
'; |
362 |
|
# Compute Klems bin from exiting ray direction (forward or backward) |
363 |
< |
my $kcal = ' |
363 |
> |
$kcal = ' |
364 |
|
DEGREE : PI/180; |
365 |
+ |
abs(x) : if(x, x, -x); |
366 |
|
Acos(x) : 1/DEGREE * if(x-1, 0, if(-1-x, 0, acos(x))); |
367 |
|
posangle(a) : if(-a, a + 2*PI, a); |
368 |
|
Atan2(y,x) : 1/DEGREE * posangle(atan2(y,x)); |
383 |
|
kaccum(7) + kazn(azi,360/knaz(8)), |
384 |
|
kaccum(8) + kazn(azi,360/knaz(9)) |
385 |
|
); |
386 |
< |
kbin = if(Dz, kbin2(Acos(Dz),Atan2(Dy,Dx)), kbin2(Acos(-Dz),Atan2(-Dy,-Dx))); |
386 |
> |
kbin = kbin2(Acos(abs(Dz)),Atan2(Dy,Dx)); |
387 |
|
'; |
388 |
|
my $ndiv = 145; |
136 |
– |
my $nx = int(sqrt($nsamp*($dim[1]-$dim[0])/($dim[3]-$dim[2])) + .5); |
137 |
– |
my $ny = int($nsamp/$nx + .5); |
138 |
– |
$nsamp = $nx * $ny; |
389 |
|
# Compute scattering data using rtcontrib |
390 |
|
my @tfarr; |
391 |
|
my @rfarr; |
392 |
|
my @tbarr; |
393 |
|
my @rbarr; |
394 |
|
my $cmd; |
395 |
< |
my $rtargs = "-w -ab 5 -ad 700 -lw 3e-6"; |
146 |
< |
my $rtcmd = "rtcontrib -h -ff -fo -n $nproc -c $nsamp " . |
395 |
> |
my $rtcmd = "rtcontrib $rtargs -h -ff -fo -n $nproc -c $nsamp " . |
396 |
|
"-e '$kcal' -b kbin -bn $ndiv " . |
397 |
< |
"-o '$td/%s.flt' -m $fmodnm -m $bmodnm $rtargs $octree"; |
397 |
> |
"-o '$td/%s.flt' -m $fmodnm -m $bmodnm $octree"; |
398 |
|
my $rccmd = "rcalc -e '$tcal' " . |
399 |
|
"-e 'mod(n,d):n-floor(n/d)*d' -e 'Kbin=mod(recno-.999,$ndiv)' " . |
400 |
|
q{-if3 -e '$1=(0.265*$1+0.670*$2+0.065*$3)/KprojOmega'}; |
401 |
|
if ( $doforw ) { |
402 |
|
$cmd = "cnt $ndiv $ny $nx | rcalc -of -e '$tcal' " . |
403 |
< |
"-e 'xp=(\$3+rand(.35*recno-15))*(($dim[1]-$dim[0])/$nx)+$dim[0]' " . |
404 |
< |
"-e 'yp=(\$2+rand(.86*recno+11))*(($dim[3]-$dim[2])/$ny)+$dim[2]' " . |
405 |
< |
"-e 'zp:$dim[4]-1e-5' " . |
406 |
< |
q{-e 'Kbin=$1;x1=rand(1.21*recno+2.75);x2=rand(-3.55*recno-7.57)' } . |
407 |
< |
q{-e '$1=xp;$2=yp;$3=zp;$4=Dx;$5=Dy;$6=Dz' } . |
403 |
> |
"-e 'xp=(\$3+rand(.12*recno+288))*(($dim[1]-$dim[0])/$nx)+$dim[0]' " . |
404 |
> |
"-e 'yp=(\$2+rand(.37*recno-44))*(($dim[3]-$dim[2])/$ny)+$dim[2]' " . |
405 |
> |
"-e 'zp:$dim[4]' " . |
406 |
> |
q{-e 'Kbin=$1;x1=rand(2.75*recno+3.1);x2=rand(-2.01*recno-3.37)' } . |
407 |
> |
q{-e '$1=xp-Dx;$2=yp-Dy;$3=zp-Dz;$4=Dx;$5=Dy;$6=Dz' } . |
408 |
|
"| $rtcmd"; |
409 |
|
system "$cmd" || die "Failure running: $cmd\n"; |
410 |
|
@tfarr = `$rccmd $td/$fmodnm.flt`; |
416 |
|
$cmd = "cnt $ndiv $ny $nx | rcalc -of -e '$tcal' " . |
417 |
|
"-e 'xp=(\$3+rand(.35*recno-15))*(($dim[1]-$dim[0])/$nx)+$dim[0]' " . |
418 |
|
"-e 'yp=(\$2+rand(.86*recno+11))*(($dim[3]-$dim[2])/$ny)+$dim[2]' " . |
419 |
< |
"-e 'zp:$dim[5]+1e-5' " . |
419 |
> |
"-e 'zp:$dim[5]' " . |
420 |
|
q{-e 'Kbin=$1;x1=rand(1.21*recno+2.75);x2=rand(-3.55*recno-7.57)' } . |
421 |
< |
q{-e '$1=xp;$2=yp;$3=zp;$4=-Dx;$5=-Dy;$6=-Dz' } . |
421 |
> |
q{-e '$1=xp-Dx;$2=yp-Dy;$3=zp+Dz;$4=Dx;$5=Dy;$6=-Dz' } . |
422 |
|
"| $rtcmd"; |
423 |
|
system "$cmd" || die "Failure running: $cmd\n"; |
424 |
|
@tbarr = `$rccmd $td/$bmodnm.flt`; |
426 |
|
@rbarr = `$rccmd $td/$fmodnm.flt`; |
427 |
|
die "Failure running: $rccmd $td/$fmodnm.flt\n" if ( $? ); |
428 |
|
} |
429 |
< |
# Output XML prologue |
429 |
> |
# Output angle basis |
430 |
|
print |
431 |
< |
'<?xml version="1.0" encoding="UTF-8"?> |
432 |
< |
<WindowElement xmlns="http://windows.lbl.gov" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://windows.lbl.gov/BSDF-v1.4.xsd"> |
433 |
< |
<WindowElementType>System</WindowElementType> |
185 |
< |
<Optical> |
186 |
< |
<Layer> |
187 |
< |
<Material> |
188 |
< |
<Name>Name</Name> |
189 |
< |
<Manufacturer>Manufacturer</Manufacturer> |
190 |
< |
'; |
191 |
< |
printf "\t\t\t<Thickness unit=\"Meter\">%.3f</Thickness>\n", $dim[5] - $dim[4]; |
192 |
< |
printf "\t\t\t<Width unit=\"Meter\">%.3f</Width>\n", $dim[1] - $dim[0]; |
193 |
< |
printf "\t\t\t<Height unit=\"Meter\">%.3f</Height>\n", $dim[3] - $dim[2]; |
194 |
< |
print "\t\t\t<DeviceType>Integral</DeviceType>\n"; |
195 |
< |
# Output MGF description if requested |
196 |
< |
if ( $geout ) { |
197 |
< |
print "\t\t\t<Geometry format=\"MGF\" unit=\"Meter\">\n"; |
198 |
< |
printf "xf -t %.6f %.6f 0\n", -($dim[0]+$dim[1])/2, -($dim[2]+$dim[3])/2; |
199 |
< |
system "cat $mgfscn"; |
200 |
< |
print "xf\n"; |
201 |
< |
print "\t\t\t</Geometry>\n"; |
202 |
< |
} |
203 |
< |
print ' </Material> |
204 |
< |
<DataDefinition> |
205 |
< |
<IncidentDataStructure>Columns</IncidentDataStructure> |
206 |
< |
<AngleBasis> |
431 |
> |
' <DataDefinition> |
432 |
> |
<IncidentDataStructure>Columns</IncidentDataStructure> |
433 |
> |
<AngleBasis> |
434 |
|
<AngleBasisName>LBNL/Klems Full</AngleBasisName> |
435 |
< |
<AngleBasisBlock> |
435 |
> |
<AngleBasisBlock> |
436 |
|
<Theta>0</Theta> |
437 |
|
<nPhis>1</nPhis> |
438 |
|
<ThetaBounds> |
439 |
< |
<LowerTheta>0</LowerTheta> |
440 |
< |
<UpperTheta>5</UpperTheta> |
439 |
> |
<LowerTheta>0</LowerTheta> |
440 |
> |
<UpperTheta>5</UpperTheta> |
441 |
|
</ThetaBounds> |
442 |
|
</AngleBasisBlock> |
443 |
|
<AngleBasisBlock> |
508 |
|
</DataDefinition> |
509 |
|
'; |
510 |
|
if ( $doforw ) { |
511 |
< |
print ' <WavelengthData> |
511 |
> |
print |
512 |
> |
' <WavelengthData> |
513 |
|
<LayerNumber>System</LayerNumber> |
514 |
|
<Wavelength unit="Integral">Visible</Wavelength> |
515 |
|
<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum> |
529 |
|
print "\n"; |
530 |
|
} |
531 |
|
print |
532 |
< |
' </ScatteringData> |
533 |
< |
</WavelengthDataBlock> |
532 |
> |
' </ScatteringData> |
533 |
> |
</WavelengthDataBlock> |
534 |
|
</WavelengthData> |
535 |
|
<WavelengthData> |
536 |
|
<LayerNumber>System</LayerNumber> |
552 |
|
print "\n"; |
553 |
|
} |
554 |
|
print |
555 |
< |
' </ScatteringData> |
556 |
< |
</WavelengthDataBlock> |
555 |
> |
' </ScatteringData> |
556 |
> |
</WavelengthDataBlock> |
557 |
|
</WavelengthData> |
558 |
|
'; |
559 |
|
} |
560 |
|
if ( $doback ) { |
561 |
< |
print ' <WavelengthData> |
561 |
> |
print |
562 |
> |
' <WavelengthData> |
563 |
|
<LayerNumber>System</LayerNumber> |
564 |
|
<Wavelength unit="Integral">Visible</Wavelength> |
565 |
|
<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum> |
579 |
|
print "\n"; |
580 |
|
} |
581 |
|
print |
582 |
< |
' </ScatteringData> |
583 |
< |
</WavelengthDataBlock> |
582 |
> |
' </ScatteringData> |
583 |
> |
</WavelengthDataBlock> |
584 |
|
</WavelengthData> |
585 |
|
<WavelengthData> |
586 |
|
<LayerNumber>System</LayerNumber> |
602 |
|
print "\n"; |
603 |
|
} |
604 |
|
print |
605 |
< |
' </ScatteringData> |
606 |
< |
</WavelengthDataBlock> |
605 |
> |
' </ScatteringData> |
606 |
> |
</WavelengthDataBlock> |
607 |
|
</WavelengthData> |
608 |
|
'; |
609 |
|
} |
610 |
< |
# Output XML epilogue |
611 |
< |
print '</Layer> |
383 |
< |
</Optical> |
384 |
< |
</WindowElement> |
385 |
< |
'; |
386 |
< |
# Clean up temporary files |
387 |
< |
system "rm -rf $td"; |
610 |
> |
} |
611 |
> |
#------------- End of do_matrix_bsdf() --------------# |