src/util/genBSDF.pl

#!/usr/bin/perl -w
# RCSid $Id: genBSDF.pl,v 2.65 2016/08/18 15:09:29 greg Exp $
#
# Compute BSDF based on geometry and material description
#
#       G. Ward
#
use strict;
my $windoz = ($^O eq "MSWin32" or $^O eq "MSWin64");
use File::Temp qw/ :mktemp  /;
sub userror {
        print STDERR "Usage: genBSDF [-n Nproc][-c Nsamp][-W][-t{3|4} Nlog2][-r \"ropts\"][-s \"x=string;y=string\"][-dim xmin xmax ymin ymax zmin zmax][{+|-}C][{+|-}f][{+|-}b][{+|-}mgf][{+|-}geom units] [input ..]\n";
        exit 1;
}
my ($td,$radscn,$mgfscn,$octree,$fsender,$bsender,$receivers,$facedat,$behinddat,$rmtmp);
my ($tf,$rf,$tb,$rb,$tfx,$rfx,$tbx,$rbx,$tfz,$rfz,$tbz,$rbz,$cph,$sav);
my ($curphase, $recovery);
if ($#ARGV == 1 && "$ARGV[0]" =~ /^-rec/) {
        $td = $ARGV[1];
        open(MYAVH, "< $td/savedARGV.txt") or die "$td: invalid path\n";
        @ARGV = <MYAVH>;
        close MYAVH;
        chomp @ARGV;
        if (open(MYPH, "< $td/phase.txt")) {
                while (<MYPH>) {
                        chomp($recovery = $_);
                }
                close MYPH;
        }
} elsif ($windoz) {
        my $tmploc = `echo \%TMP\%`;
        chomp $tmploc;
        $td = mkdtemp("$tmploc\\genBSDF.XXXXXX");
} else {
        $td = mkdtemp("/tmp/genBSDF.XXXXXX");
        chomp $td;
}
if ($windoz) {
        $radscn = "$td\\device.rad";
        $mgfscn = "$td\\device.mgf";
        $octree = "$td\\device.oct";
        $fsender = "$td\\fsender.rad";
        $bsender = "$td\\bsender.rad";
        $receivers = "$td\\receivers.rad";
        $facedat = "$td\\face.dat";
        $behinddat = "$td\\behind.dat";
        $tf = "$td\\tf.dat";
        $rf = "$td\\rf.dat";
        $tb = "$td\\tb.dat";
        $rb = "$td\\rb.dat";
        $tfx = "$td\\tfx.dat";
        $rfx = "$td\\rfx.dat";
        $tbx = "$td\\tbx.dat";
        $rbx = "$td\\rbx.dat";
        $tfz = "$td\\tfz.dat";
        $rfz = "$td\\rfz.dat";
        $tbz = "$td\\tbz.dat";
        $rbz = "$td\\rbz.dat";
        $cph = "$td\\phase.txt";
        $rmtmp = "rd /S /Q $td";
} else {
        $radscn = "$td/device.rad";
        $mgfscn = "$td/device.mgf";
        $octree = "$td/device.oct";
        $fsender = "$td/fsender.rad";
        $bsender = "$td/bsender.rad";
        $receivers = "$td/receivers.rad";
        $facedat = "$td/face.dat";
        $behinddat = "$td/behind.dat";
        $tf = "$td/tf.dat";
        $rf = "$td/rf.dat";
        $tb = "$td/tb.dat";
        $rb = "$td/rb.dat";
        $tfx = "$td/tfx.dat";
        $rfx = "$td/rfx.dat";
        $tbx = "$td/tbx.dat";
        $rbx = "$td/rbx.dat";
        $tfz = "$td/tfz.dat";
        $rfz = "$td/rfz.dat";
        $tbz = "$td/tbz.dat";
        $rbz = "$td/rbz.dat";
        $cph = "$td/phase.txt";
        $rmtmp = "rm -rf $td";
}
my @savedARGV = @ARGV;
my $rfluxmtx = "rfluxmtx -ab 5 -ad 700 -lw 3e-6";
my $wrapper = "wrapBSDF";
my $tensortree = 0;
my $ttlog2 = 4;
my $nsamp = 2000;
my $mgfin = 0;
my $geout = 1;
my $nproc = 1;
my $docolor = 0;
my $doforw = 0;
my $doback = 1;
my $pctcull = 90;
my $gunit = "meter";
my $curspec = "Visible";
my @dim;
# Get options
while ($#ARGV >= 0) {
        if ("$ARGV[0]" =~ /^[-+]m/) {
                $mgfin = ("$ARGV[0]" =~ /^\+/);
        } elsif ("$ARGV[0]" eq "-r") {
                $rfluxmtx .= " $ARGV[1]";
                shift @ARGV;
        } elsif ("$ARGV[0]" =~ /^[-+]g/) {
                $geout = ("$ARGV[0]" =~ /^\+/);
                $gunit = $ARGV[1];
                if ($gunit !~ /^(?i)(meter|foot|inch|centimeter|millimeter)$/) {
                        die "Illegal geometry unit '$gunit': must be meter, foot, inch, centimeter, or millimeter\n";
                }
                shift @ARGV;
        } elsif ("$ARGV[0]" =~ /^[-+]C/) {
                $docolor = ("$ARGV[0]" =~ /^\+/);
        } elsif ("$ARGV[0]" =~ /^[-+]f/) {
                $doforw = ("$ARGV[0]" =~ /^\+/);
        } elsif ("$ARGV[0]" =~ /^[-+]b/) {
                $doback = ("$ARGV[0]" =~ /^\+/);
        } elsif ("$ARGV[0]" eq "-t") {
                # Use value < 0 for rttree_reduce bypass
                $pctcull = $ARGV[1];
                if ($pctcull >= 100) {
                        die "Illegal -t culling percentage, must be < 100\n";
                }
                shift @ARGV;
        } elsif ("$ARGV[0]" =~ /^-t[34]$/) {
                $tensortree = substr($ARGV[0], 2, 1);
                $ttlog2 = $ARGV[1];
                shift @ARGV;
        } elsif ("$ARGV[0]" eq "-s") {
                $wrapper .= " -f \"$ARGV[1]\"";
                shift @ARGV;
        } elsif ("$ARGV[0]" eq "-W") {
                $wrapper .= " -W";
        } elsif ("$ARGV[0]" eq "-c") {
                $nsamp = $ARGV[1];
                shift @ARGV;
        } elsif ("$ARGV[0]" eq "-n") {
                $nproc = $ARGV[1];
                shift @ARGV;
        } elsif ("$ARGV[0]" =~ /^-d/) {
                userror() if ($#ARGV < 6);
                @dim = @ARGV[1..6];
                shift @ARGV for (1..6);
        } elsif ("$ARGV[0]" =~ /^[-+]./) {
                userror();
        } else {
                last;
        }
        shift @ARGV;
}
# Check that we're actually being asked to do something
die "Must have at least one of +forward or +backward\n" if (!$doforw && !$doback);
$wrapper .= $tensortree ? " -a t$tensortree" : " -a kf -c";
$wrapper .= " -u $gunit";
if (!defined $recovery) {
        # Issue warning for unhandled reciprocity case
        print STDERR "Warning: recommend both +forward and +backward with -t3\n" if
                        ($tensortree==3 && !($doforw && $doback));
        # Get scene description and dimensions
        if ( $mgfin ) {
                system "mgf2rad @ARGV > $radscn";
                die "Could not load MGF input\n" if ( $? );
        } else {
                system "xform -e @ARGV > $radscn";
                die "Could not load Radiance input\n" if ( $? );
        }
}
if ($#dim != 5) {
        @dim = split ' ', `getbbox -h $radscn`;
}
die "Device entirely inside room!\n" if ($dim[4] >= 0);
if ($dim[5] > 1e-5) {
        print STDERR "Warning: Device extends into room\n";
} elsif ($dim[5]*$dim[5] > .01*($dim[1]-$dim[0])*($dim[3]-$dim[2])) {
        print STDERR "Warning: Device far behind Z==0 plane\n";
}
# Assume Zmax==0 to derive thickness so pkgBSDF will work
$wrapper .= ' -f "t=' . (-$dim[4]) . ';w=' . ($dim[1] - $dim[0]) .
                ';h=' . ($dim[3] - $dim[2]) . '"';
# Calculate CIE (u',v') from Radiance RGB:
my $CIEuv =     'Xi=.5141*Ri+.3239*Gi+.1620*Bi;' .
                'Yi=.2651*Ri+.6701*Gi+.0648*Bi;' .
                'Zi=.0241*Ri+.1229*Gi+.8530*Bi;' .
                'den=Xi+15*Yi+3*Zi;' .
                'uprime=4*Xi/den;vprime=9*Yi/den;' ;
my $FEPS = 1e-5;
my $ns = 2**$ttlog2;
my $nx = int(sqrt($nsamp*($dim[1]-$dim[0])/($dim[3]-$dim[2])) + 1);
my $ny = int($nsamp/$nx + 1);
$nsamp = $nx * $ny;
$rfluxmtx .= " -n $nproc -c $nsamp";
if (!defined $recovery) {
        open(MYAVH, "> $td/savedARGV.txt");
        foreach (@savedARGV) {
                print MYAVH "$_\n";
        }
        close MYAVH;
        # Generate octree
        system "oconv -w $radscn > $octree";
        die "Could not compile scene\n" if ( $? );
        # Add MGF description if requested
        if ( $geout ) {
                open(MGFSCN, "> $mgfscn");
                printf MGFSCN "xf -t %.6f %.6f 0\n", -($dim[0]+$dim[1])/2, -($dim[2]+$dim[3])/2;
                close MGFSCN;
                if ( $mgfin ) {
                        system qq{mgfilt "#,o,xf,c,cxy,cspec,cmix,m,sides,rd,td,rs,ts,ir,v,p,n,f,fh,sph,cyl,cone,prism,ring,torus" @ARGV >> $mgfscn};
                } else {
                        system "rad2mgf $radscn >> $mgfscn";
                }
                open(MGFSCN, ">> $mgfscn");
                print MGFSCN "xf\n";
                close MGFSCN;
                $wrapper .= " -g $mgfscn";
        }
        # Create receiver & sender surfaces (rectangular)
        open(RADSCN, "> $receivers");
        print RADSCN '#@rfluxmtx ' . ($tensortree ? "h=-sc$ns\n" : "h=-kf\n");
        print RADSCN '#@rfluxmtx ' . "u=-Y o=$facedat\n\n";
        print RADSCN "void glow receiver_face\n0\n0\n4 1 1 1 0\n\n";
        print RADSCN "receiver_face source f_receiver\n0\n0\n4 0 0 1 180\n\n";
        print RADSCN '#@rfluxmtx ' . ($tensortree ? "h=+sc$ns\n" : "h=+kf\n");
        print RADSCN '#@rfluxmtx ' . "u=-Y o=$behinddat\n\n";
        print RADSCN "void glow receiver_behind\n0\n0\n4 1 1 1 0\n\n";
        print RADSCN "receiver_behind source b_receiver\n0\n0\n4 0 0 -1 180\n";
        close RADSCN;
        # Prepare sender surfaces
        if ( $tensortree != 3 ) {       # Isotropic tensor tree is exception
                open (RADSCN, "> $fsender");
                print RADSCN '#@rfluxmtx u=-Y ' . ($tensortree ? "h=-sc$ns\n\n" : "h=-kf\n\n");
                print RADSCN "void polygon fwd_sender\n0\n0\n12\n";
                printf RADSCN "\t%e\t%e\t%e\n", $dim[0], $dim[2], $dim[4]-$FEPS;
                printf RADSCN "\t%e\t%e\t%e\n", $dim[0], $dim[3], $dim[4]-$FEPS;
                printf RADSCN "\t%e\t%e\t%e\n", $dim[1], $dim[3], $dim[4]-$FEPS;
                printf RADSCN "\t%e\t%e\t%e\n", $dim[1], $dim[2], $dim[4]-$FEPS;
                close RADSCN;
                open (RADSCN, "> $bsender");
                print RADSCN '#@rfluxmtx u=-Y ' . ($tensortree ? "h=+sc$ns\n\n" : "h=+kf\n\n");
                print RADSCN "void polygon bwd_sender\n0\n0\n12\n";
                printf RADSCN "\t%e\t%e\t%e\n", $dim[0], $dim[2], $dim[5]+$FEPS;
                printf RADSCN "\t%e\t%e\t%e\n", $dim[1], $dim[2], $dim[5]+$FEPS;
                printf RADSCN "\t%e\t%e\t%e\n", $dim[1], $dim[3], $dim[5]+$FEPS;
                printf RADSCN "\t%e\t%e\t%e\n", $dim[0], $dim[3], $dim[5]+$FEPS;
                close RADSCN;
        }
        print STDERR "Recover using: $0 -recover $td\n";
}
open(MYPH, ">> $td/phase.txt");
{               # unbuffer output to MYPH
        my $ofh = select MYPH;
        $| = 1;
        select $ofh;
}
$curphase = 0;
# Function to determine if next phase should be skipped or recovered
sub do_phase {
        $curphase++;
        if (defined $recovery) {
                if ($recovery == $curphase) { return -1; }
                if ($recovery > $curphase) { return 0; }
        }
        print MYPH "$curphase\n";
        return 1;
}
# Create data segments (all the work happens here)
if ( $tensortree ) {
        do_tree_bsdf();
} else {
        do_matrix_bsdf();
}
# Output XML
print STDERR "Running: $wrapper\n";
system "$wrapper -C \"Created by: genBSDF @savedARGV\"";
die "Could not wrap BSDF data\n" if ( $? );
# Clean up temporary files and exit
exec $rmtmp;

#-------------- End of main program segment --------------#

#++++++++++++++ Tensor tree BSDF generation ++++++++++++++#
sub do_tree_bsdf {

        # Run rfluxmtx processes to compute each side
        do_ttree_dir(0) if ( $doback );
        do_ttree_dir(1) if ( $doforw );

}       # end of sub do_tree_bsdf()

# Call rfluxmtx and process tensor tree BSDF for the given direction
sub do_ttree_dir {
        my $forw = shift;
        my $r = do_phase();
        if (!$r) { return; }
        $r = ($r < 0) ? " -r" : "";
        my $cmd;
        if ( $tensortree == 3 ) {
                # Isotropic BSDF
                my $ns2 = $ns / 2;
                if ($windoz) {
                        $cmd = "cnt $ns2 $ny $nx " .
                                qq{| rcalc -e "r1=rand(.8681*recno-.673892)" } .
                                qq{-e "r2=rand(-5.37138*recno+67.1737811)" } .
                                qq{-e "r3=rand(+3.17603772*recno+83.766771)" } .
                                qq{-e "Dx=1-2*(\$1+r1)/$ns;Dy:0;Dz=sqrt(1-Dx*Dx)" } .
                                qq{-e "xp=(\$3+r2)*(($dim[1]-$dim[0])/$nx)+$dim[0]" } .
                                qq{-e "yp=(\$2+r3)*(($dim[3]-$dim[2])/$ny)+$dim[2]" } .
                                qq{-e "zp=$dim[5-$forw]" -e "myDz=Dz*($forw*2-1)" } .
                                qq{-e "\$1=xp-Dx;\$2=yp-Dy;\$3=zp-myDz" } .
                                qq{-e "\$4=Dx;\$5=Dy;\$6=myDz" } .
                                "| $rfluxmtx$r -fa -y $ns2 - $receivers -i $octree";
                } else {
                        $cmd = "cnt $ns2 $ny $nx " .
                                qq{| rcalc -e "r1=rand(.8681*recno-.673892)" } .
                                qq{-e "r2=rand(-5.37138*recno+67.1737811)" } .
                                qq{-e "r3=rand(+3.17603772*recno+83.766771)" } .
                                qq{-e "Dx=1-2*(\$1+r1)/$ns;Dy:0;Dz=sqrt(1-Dx*Dx)" } .
                                qq{-e "xp=(\$3+r2)*(($dim[1]-$dim[0])/$nx)+$dim[0]" } .
                                qq{-e "yp=(\$2+r3)*(($dim[3]-$dim[2])/$ny)+$dim[2]" } .
                                qq{-e "zp=$dim[5-$forw]" -e "myDz=Dz*($forw*2-1)" } .
                                qq{-e '\$1=xp-Dx;\$2=yp-Dy;\$3=zp-myDz' } .
                                qq{-e '\$4=Dx;\$5=Dy;\$6=myDz' -of } .
                                "| $rfluxmtx$r -h -ff -y $ns2 - $receivers -i $octree";
                }
        } else {
                # Anisotropic BSDF
                my $sender = ($bsender,$fsender)[$forw];
                if ($windoz) {
                        $cmd = "$rfluxmtx$r -fa $sender $receivers -i $octree";
                } else {
                        $cmd = "$rfluxmtx$r -h -ff $sender $receivers -i $octree";
                }
        }
        print STDERR "Starting: $cmd\n";
        system $cmd;
        die "Failure running rfluxmtx" if ( $? );
        ttree_out($forw);
}       # end of do_ttree_dir()

# Simplify and store tensor tree results
sub ttree_out {
        my $forw = shift;
        my ($refldat,$transdat);
        if ( $forw ) {
                $transdat = $facedat;
                $refldat = $behinddat;
        } else {
                $transdat = $behinddat;
                $refldat = $facedat;
        }
        # Only output one transmitted anisotropic distribution, preferring backwards
        if ( !$forw || !$doback || $tensortree==3 ) {
                my $ttyp = ("tb","tf")[$forw];
                ttree_comp($ttyp, "Visible", $transdat, ($tb,$tf)[$forw]);
                if ( $docolor ) {
                        ttree_comp($ttyp, "CIE-u", $transdat, ($tbx,$tfx)[$forw]);
                        ttree_comp($ttyp, "CIE-v", $transdat, ($tbz,$tfz)[$forw]);
                }
        }
        # Output reflection
        my $rtyp = ("rb","rf")[$forw];
        ttree_comp($rtyp, "Visible", $refldat, ($rb,$rf)[$forw]);
        if ( $docolor ) {
                ttree_comp($rtyp, "CIE-u", $refldat, ($rbx,$rfx)[$forw]);
                ttree_comp($rtyp, "CIE-v", $refldat, ($rbz,$rfz)[$forw]);
        }
}       # end of ttree_out()

# Call rttree_reduce on the given component
sub ttree_comp {
        my $typ = shift;
        my $spec = shift;
        my $src = shift;
        my $dest = shift;
        my $cmd;
        if ($windoz) {
                if ("$spec" eq "Visible") {
                        $cmd = qq{rcalc -e "Omega:PI/($ns*$ns)" } .
                                q{-e "Ri=$1;Gi=$2;Bi=$3" } .
                                qq{-e "$CIEuv" } .
                                q{-e "$1=Yi/Omega"};
                } elsif ("$spec" eq "CIE-u") {
                        $cmd = q{rcalc -e "Ri=$1;Gi=$2;Bi=$3" } .
                                qq{-e "$CIEuv" } .
                                q{-e "$1=uprime"};
                } elsif ("$spec" eq "CIE-v") {
                        $cmd = q{rcalc -e "Ri=$1;Gi=$2;Bi=$3" } .
                                qq{-e "$CIEuv" } .
                                q{-e "$1=vprime"};
                }
        } else {
                if ("$spec" eq "Visible") {
                        $cmd = "rcalc -if3 -e 'Omega:PI/($ns*$ns)' " .
                                q{-e 'Ri=$1;Gi=$2;Bi=$3' } .
                                "-e '$CIEuv' " .
                                q{-e '$1=Yi/Omega'};
                } elsif ("$spec" eq "CIE-u") {
                        $cmd = q{rcalc -if3 -e 'Ri=$1;Gi=$2;Bi=$3' } .
                                "-e '$CIEuv' " .
                                q{-e '$1=uprime'};
                } elsif ("$spec" eq "CIE-v") {
                        $cmd = q{rcalc -if3 -e 'Ri=$1;Gi=$2;Bi=$3' } .
                                "-e '$CIEuv' " .
                                q{-e '$1=vprime'};
                }
        }
        if ($pctcull >= 0) {
                my $avg = ( "$typ" =~ /^r[fb]/ ) ? " -a" : "";
                my $pcull = ("$spec" eq "Visible") ? $pctcull :
                                                     (100 - (100-$pctcull)*.25) ;
                if ($windoz) {
                        $cmd = "rcollate -ho -oc 1 $src | " .
                                        $cmd .
                                        " | rttree_reduce$avg -h -fa -t $pcull -r $tensortree -g $ttlog2";
                } else {
                        $cmd .= " -of $src " .
                                        "| rttree_reduce$avg -h -ff -t $pcull -r $tensortree -g $ttlog2";
                }
                print STDERR "Running: $cmd\n";
                system "$cmd > $dest";
                die "Failure running rttree_reduce" if ( $? );
        } else {
                if ($windoz) {
                        $cmd = "rcollate -ho -oc 1 $src | " . $cmd ;
                } else {
                        $cmd .= " $src";
                }
                open(DATOUT, "> $dest");
                print DATOUT "{\n";
                close DATOUT;
                print STDERR "Running: $cmd\n";
                system "$cmd >> $dest";
                die "Failure running rcalc" if ( $? );
                open(DATOUT, ">> $dest");
                for (my $i = ($tensortree==3)*$ns*$ns*$ns/2; $i-- > 0; ) {
                        print DATOUT "0\n";
                }
                print DATOUT "}\n";
                close DATOUT;
        }
        if ( "$spec" ne "$curspec" ) {
                $wrapper .= " -s $spec";
                $curspec = $spec;
        }
        $wrapper .= " -$typ $dest";
}       # end of ttree_comp()

#------------- End of do_tree_bsdf() & subroutines -------------#

#+++++++++++++++ Klems matrix BSDF generation +++++++++++++++#
sub do_matrix_bsdf {

        # Run rfluxmtx processes to compute each side
        do_matrix_dir(0) if ( $doback );
        do_matrix_dir(1) if ( $doforw );

}       # end of sub do_matrix_bsdf()

# Call rfluxmtx and process tensor tree BSDF for the given direction
sub do_matrix_dir {
        my $forw = shift;
        my $r = do_phase();
        if (!$r) { return; }
        $r = ($r < 0) ? " -r" : "";
        my $cmd;
        my $sender = ($bsender,$fsender)[$forw];
        $cmd = "$rfluxmtx$r -fd $sender $receivers -i $octree";
        print STDERR "Starting: $cmd\n";
        system $cmd;
        die "Failure running rfluxmtx" if ( $? );
        matrix_out($forw);
}       # end of do_matrix_dir()

sub matrix_out {
        my $forw = shift;
        my ($refldat,$transdat);
        if ( $forw ) {
                $transdat = $facedat;
                $refldat = $behinddat;
        } else {
                $transdat = $behinddat;
                $refldat = $facedat;
        }
        # Output transmission
        my $ttyp = ("tb","tf")[$forw];
        matrix_comp($ttyp, "Visible", $transdat, ($tb,$tf)[$forw]);
        if ( $docolor ) {
                matrix_comp($ttyp, "CIE-X", $transdat, ($tbx,$tfx)[$forw]);
                matrix_comp($ttyp, "CIE-Z", $transdat, ($tbz,$tfz)[$forw]);
        }
        # Output reflection
        my $rtyp = ("rb","rf")[$forw];
        matrix_comp($rtyp, "Visible", $refldat, ($rb,$rf)[$forw]);
        if ( $docolor ) {
                matrix_comp($rtyp, "CIE-X", $refldat, ($rbx,$rfx)[$forw]);
                matrix_comp($rtyp, "CIE-Z", $refldat, ($rbz,$rfz)[$forw]);
        }
}       # end of matrix_out()

# Transpose matrix component data and save to file
sub matrix_comp {
        my $typ = shift;
        my $spec = shift;
        my $src = shift;
        my $dest = shift;
        my $cmd = "rmtxop -fa -t";
        if ("$spec" eq "Visible") {
                $cmd .= " -c 0.2651 0.6701 0.0648";
        } elsif ("$spec" eq "CIE-X") {
                $cmd .= " -c 0.5141 0.3239 0.1620";
        } elsif ("$spec" eq "CIE-Z") {
                $cmd .= " -c 0.0241 0.1229 0.8530";
        }
        $cmd .= " $src | rcollate -ho -oc 145";
        print STDERR "Running: $cmd\n";
        system "$cmd > $dest";
        die "Failure running rmtxop" if ( $? );
        if ( "$spec" ne "$curspec" ) {
                $wrapper .= " -s $spec";
                $curspec = $spec;
        }
        $wrapper .= " -$typ $dest";
}       # end of matrix_comp()

#------------- End of do_matrix_bsdf() & subroutines --------------#
Revision:	2.66
Committed:	Fri Sep 16 17:54:56 2016 UTC (7 years, 7 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.65:	+131 -81 lines
Log Message:	Added -recover option to genBSDF at Lars Grobe's request
#	Content
1	#!/usr/bin/perl -w
2	# RCSid $Id: genBSDF.pl,v 2.65 2016/08/18 15:09:29 greg Exp $
3	#
4	# Compute BSDF based on geometry and material description
5	#
6	# G. Ward
7	#
8	use strict;
9	my $windoz = ($^O eq "MSWin32" or $^O eq "MSWin64");
10	use File::Temp qw/ :mktemp /;
11	sub userror {
12	print STDERR "Usage: genBSDF [-n Nproc][-c Nsamp][-W][-t{3\|4} Nlog2][-r \"ropts\"][-s \"x=string;y=string\"][-dim xmin xmax ymin ymax zmin zmax][{+\|-}C][{+\|-}f][{+\|-}b][{+\|-}mgf][{+\|-}geom units] [input ..]\n";
13	exit 1;
14	}
15	my ($td,$radscn,$mgfscn,$octree,$fsender,$bsender,$receivers,$facedat,$behinddat,$rmtmp);
16	my ($tf,$rf,$tb,$rb,$tfx,$rfx,$tbx,$rbx,$tfz,$rfz,$tbz,$rbz,$cph,$sav);
17	my ($curphase, $recovery);
18	if ($#ARGV == 1 && "$ARGV[0]" =~ /^-rec/) {
19	$td = $ARGV[1];
20	open(MYAVH, "< $td/savedARGV.txt") or die "$td: invalid path\n";
21	@ARGV = <MYAVH>;
22	close MYAVH;
23	chomp @ARGV;
24	if (open(MYPH, "< $td/phase.txt")) {
25	while (<MYPH>) {
26	chomp($recovery = $_);
27	}
28	close MYPH;
29	}
30	} elsif ($windoz) {
31	my $tmploc = `echo \%TMP\%`;
32	chomp $tmploc;
33	$td = mkdtemp("$tmploc\\genBSDF.XXXXXX");
34	} else {
35	$td = mkdtemp("/tmp/genBSDF.XXXXXX");
36	chomp $td;
37	}
38	if ($windoz) {
39	$radscn = "$td\\device.rad";
40	$mgfscn = "$td\\device.mgf";
41	$octree = "$td\\device.oct";
42	$fsender = "$td\\fsender.rad";
43	$bsender = "$td\\bsender.rad";
44	$receivers = "$td\\receivers.rad";
45	$facedat = "$td\\face.dat";
46	$behinddat = "$td\\behind.dat";
47	$tf = "$td\\tf.dat";
48	$rf = "$td\\rf.dat";
49	$tb = "$td\\tb.dat";
50	$rb = "$td\\rb.dat";
51	$tfx = "$td\\tfx.dat";
52	$rfx = "$td\\rfx.dat";
53	$tbx = "$td\\tbx.dat";
54	$rbx = "$td\\rbx.dat";
55	$tfz = "$td\\tfz.dat";
56	$rfz = "$td\\rfz.dat";
57	$tbz = "$td\\tbz.dat";
58	$rbz = "$td\\rbz.dat";
59	$cph = "$td\\phase.txt";
60	$rmtmp = "rd /S /Q $td";
61	} else {
62	$radscn = "$td/device.rad";
63	$mgfscn = "$td/device.mgf";
64	$octree = "$td/device.oct";
65	$fsender = "$td/fsender.rad";
66	$bsender = "$td/bsender.rad";
67	$receivers = "$td/receivers.rad";
68	$facedat = "$td/face.dat";
69	$behinddat = "$td/behind.dat";
70	$tf = "$td/tf.dat";
71	$rf = "$td/rf.dat";
72	$tb = "$td/tb.dat";
73	$rb = "$td/rb.dat";
74	$tfx = "$td/tfx.dat";
75	$rfx = "$td/rfx.dat";
76	$tbx = "$td/tbx.dat";
77	$rbx = "$td/rbx.dat";
78	$tfz = "$td/tfz.dat";
79	$rfz = "$td/rfz.dat";
80	$tbz = "$td/tbz.dat";
81	$rbz = "$td/rbz.dat";
82	$cph = "$td/phase.txt";
83	$rmtmp = "rm -rf $td";
84	}
85	my @savedARGV = @ARGV;
86	my $rfluxmtx = "rfluxmtx -ab 5 -ad 700 -lw 3e-6";
87	my $wrapper = "wrapBSDF";
88	my $tensortree = 0;
89	my $ttlog2 = 4;
90	my $nsamp = 2000;
91	my $mgfin = 0;
92	my $geout = 1;
93	my $nproc = 1;
94	my $docolor = 0;
95	my $doforw = 0;
96	my $doback = 1;
97	my $pctcull = 90;
98	my $gunit = "meter";
99	my $curspec = "Visible";
100	my @dim;
101	# Get options
102	while ($#ARGV >= 0) {
103	if ("$ARGV[0]" =~ /^[-+]m/) {
104	$mgfin = ("$ARGV[0]" =~ /^\+/);
105	} elsif ("$ARGV[0]" eq "-r") {
106	$rfluxmtx .= " $ARGV[1]";
107	shift @ARGV;
108	} elsif ("$ARGV[0]" =~ /^[-+]g/) {
109	$geout = ("$ARGV[0]" =~ /^\+/);
110	$gunit = $ARGV[1];
111	if ($gunit !~ /^(?i)(meter\|foot\|inch\|centimeter\|millimeter)$/) {
112	die "Illegal geometry unit '$gunit': must be meter, foot, inch, centimeter, or millimeter\n";
113	}
114	shift @ARGV;
115	} elsif ("$ARGV[0]" =~ /^[-+]C/) {
116	$docolor = ("$ARGV[0]" =~ /^\+/);
117	} elsif ("$ARGV[0]" =~ /^[-+]f/) {
118	$doforw = ("$ARGV[0]" =~ /^\+/);
119	} elsif ("$ARGV[0]" =~ /^[-+]b/) {
120	$doback = ("$ARGV[0]" =~ /^\+/);
121	} elsif ("$ARGV[0]" eq "-t") {
122	# Use value < 0 for rttree_reduce bypass
123	$pctcull = $ARGV[1];
124	if ($pctcull >= 100) {
125	die "Illegal -t culling percentage, must be < 100\n";
126	}
127	shift @ARGV;
128	} elsif ("$ARGV[0]" =~ /^-t[34]$/) {
129	$tensortree = substr($ARGV[0], 2, 1);
130	$ttlog2 = $ARGV[1];
131	shift @ARGV;
132	} elsif ("$ARGV[0]" eq "-s") {
133	$wrapper .= " -f \"$ARGV[1]\"";
134	shift @ARGV;
135	} elsif ("$ARGV[0]" eq "-W") {
136	$wrapper .= " -W";
137	} elsif ("$ARGV[0]" eq "-c") {
138	$nsamp = $ARGV[1];
139	shift @ARGV;
140	} elsif ("$ARGV[0]" eq "-n") {
141	$nproc = $ARGV[1];
142	shift @ARGV;
143	} elsif ("$ARGV[0]" =~ /^-d/) {
144	userror() if ($#ARGV < 6);
145	@dim = @ARGV[1..6];
146	shift @ARGV for (1..6);
147	} elsif ("$ARGV[0]" =~ /^[-+]./) {
148	userror();
149	} else {
150	last;
151	}
152	shift @ARGV;
153	}
154	# Check that we're actually being asked to do something
155	die "Must have at least one of +forward or +backward\n" if (!$doforw && !$doback);
156	$wrapper .= $tensortree ? " -a t$tensortree" : " -a kf -c";
157	$wrapper .= " -u $gunit";
158	if (!defined $recovery) {
159	# Issue warning for unhandled reciprocity case
160	print STDERR "Warning: recommend both +forward and +backward with -t3\n" if
161	($tensortree==3 && !($doforw && $doback));
162	# Get scene description and dimensions
163	if ( $mgfin ) {
164	system "mgf2rad @ARGV > $radscn";
165	die "Could not load MGF input\n" if ( $? );
166	} else {
167	system "xform -e @ARGV > $radscn";
168	die "Could not load Radiance input\n" if ( $? );
169	}
170	}
171	if ($#dim != 5) {
172	@dim = split ' ', `getbbox -h $radscn`;
173	}
174	die "Device entirely inside room!\n" if ($dim[4] >= 0);
175	if ($dim[5] > 1e-5) {
176	print STDERR "Warning: Device extends into room\n";
177	} elsif ($dim[5]$dim[5] > .01($dim[1]-$dim[0])*($dim[3]-$dim[2])) {
178	print STDERR "Warning: Device far behind Z==0 plane\n";
179	}
180	# Assume Zmax==0 to derive thickness so pkgBSDF will work
181	$wrapper .= ' -f "t=' . (-$dim[4]) . ';w=' . ($dim[1] - $dim[0]) .
182	';h=' . ($dim[3] - $dim[2]) . '"';
183	# Calculate CIE (u',v') from Radiance RGB:
184	my $CIEuv = 'Xi=.5141Ri+.3239Gi+.1620*Bi;' .
185	'Yi=.2651Ri+.6701Gi+.0648*Bi;' .
186	'Zi=.0241Ri+.1229Gi+.8530*Bi;' .
187	'den=Xi+15Yi+3Zi;' .
188	'uprime=4Xi/den;vprime=9Yi/den;' ;
189	my $FEPS = 1e-5;
190	my $ns = 2**$ttlog2;
191	my $nx = int(sqrt($nsamp*($dim[1]-$dim[0])/($dim[3]-$dim[2])) + 1);
192	my $ny = int($nsamp/$nx + 1);
193	$nsamp = $nx * $ny;
194	$rfluxmtx .= " -n $nproc -c $nsamp";
195	if (!defined $recovery) {
196	open(MYAVH, "> $td/savedARGV.txt");
197	foreach (@savedARGV) {
198	print MYAVH "$_\n";
199	}
200	close MYAVH;
201	# Generate octree
202	system "oconv -w $radscn > $octree";
203	die "Could not compile scene\n" if ( $? );
204	# Add MGF description if requested
205	if ( $geout ) {
206	open(MGFSCN, "> $mgfscn");
207	printf MGFSCN "xf -t %.6f %.6f 0\n", -($dim[0]+$dim[1])/2, -($dim[2]+$dim[3])/2;
208	close MGFSCN;
209	if ( $mgfin ) {
210	system qq{mgfilt "#,o,xf,c,cxy,cspec,cmix,m,sides,rd,td,rs,ts,ir,v,p,n,f,fh,sph,cyl,cone,prism,ring,torus" @ARGV >> $mgfscn};
211	} else {
212	system "rad2mgf $radscn >> $mgfscn";
213	}
214	open(MGFSCN, ">> $mgfscn");
215	print MGFSCN "xf\n";
216	close MGFSCN;
217	$wrapper .= " -g $mgfscn";
218	}
219	# Create receiver & sender surfaces (rectangular)
220	open(RADSCN, "> $receivers");
221	print RADSCN '#@rfluxmtx ' . ($tensortree ? "h=-sc$ns\n" : "h=-kf\n");
222	print RADSCN '#@rfluxmtx ' . "u=-Y o=$facedat\n\n";
223	print RADSCN "void glow receiver_face\n0\n0\n4 1 1 1 0\n\n";
224	print RADSCN "receiver_face source f_receiver\n0\n0\n4 0 0 1 180\n\n";
225	print RADSCN '#@rfluxmtx ' . ($tensortree ? "h=+sc$ns\n" : "h=+kf\n");
226	print RADSCN '#@rfluxmtx ' . "u=-Y o=$behinddat\n\n";
227	print RADSCN "void glow receiver_behind\n0\n0\n4 1 1 1 0\n\n";
228	print RADSCN "receiver_behind source b_receiver\n0\n0\n4 0 0 -1 180\n";
229	close RADSCN;
230	# Prepare sender surfaces
231	if ( $tensortree != 3 ) { # Isotropic tensor tree is exception
232	open (RADSCN, "> $fsender");
233	print RADSCN '#@rfluxmtx u=-Y ' . ($tensortree ? "h=-sc$ns\n\n" : "h=-kf\n\n");
234	print RADSCN "void polygon fwd_sender\n0\n0\n12\n";
235	printf RADSCN "\t%e\t%e\t%e\n", $dim[0], $dim[2], $dim[4]-$FEPS;
236	printf RADSCN "\t%e\t%e\t%e\n", $dim[0], $dim[3], $dim[4]-$FEPS;
237	printf RADSCN "\t%e\t%e\t%e\n", $dim[1], $dim[3], $dim[4]-$FEPS;
238	printf RADSCN "\t%e\t%e\t%e\n", $dim[1], $dim[2], $dim[4]-$FEPS;
239	close RADSCN;
240	open (RADSCN, "> $bsender");
241	print RADSCN '#@rfluxmtx u=-Y ' . ($tensortree ? "h=+sc$ns\n\n" : "h=+kf\n\n");
242	print RADSCN "void polygon bwd_sender\n0\n0\n12\n";
243	printf RADSCN "\t%e\t%e\t%e\n", $dim[0], $dim[2], $dim[5]+$FEPS;
244	printf RADSCN "\t%e\t%e\t%e\n", $dim[1], $dim[2], $dim[5]+$FEPS;
245	printf RADSCN "\t%e\t%e\t%e\n", $dim[1], $dim[3], $dim[5]+$FEPS;
246	printf RADSCN "\t%e\t%e\t%e\n", $dim[0], $dim[3], $dim[5]+$FEPS;
247	close RADSCN;
248	}
249	print STDERR "Recover using: $0 -recover $td\n";
250	}
251	open(MYPH, ">> $td/phase.txt");
252	{ # unbuffer output to MYPH
253	my $ofh = select MYPH;
254	$\| = 1;
255	select $ofh;
256	}
257	$curphase = 0;
258	# Function to determine if next phase should be skipped or recovered
259	sub do_phase {
260	$curphase++;
261	if (defined $recovery) {
262	if ($recovery == $curphase) { return -1; }
263	if ($recovery > $curphase) { return 0; }
264	}
265	print MYPH "$curphase\n";
266	return 1;
267	}
268	# Create data segments (all the work happens here)
269	if ( $tensortree ) {
270	do_tree_bsdf();
271	} else {
272	do_matrix_bsdf();
273	}
274	# Output XML
275	print STDERR "Running: $wrapper\n";
276	system "$wrapper -C \"Created by: genBSDF @savedARGV\"";
277	die "Could not wrap BSDF data\n" if ( $? );
278	# Clean up temporary files and exit
279	exec $rmtmp;
280
281	#-------------- End of main program segment --------------#
282
283	#++++++++++++++ Tensor tree BSDF generation ++++++++++++++#
284	sub do_tree_bsdf {
285
286	# Run rfluxmtx processes to compute each side
287	do_ttree_dir(0) if ( $doback );
288	do_ttree_dir(1) if ( $doforw );
289
290	} # end of sub do_tree_bsdf()
291
292	# Call rfluxmtx and process tensor tree BSDF for the given direction
293	sub do_ttree_dir {
294	my $forw = shift;
295	my $r = do_phase();
296	if (!$r) { return; }
297	$r = ($r < 0) ? " -r" : "";
298	my $cmd;
299	if ( $tensortree == 3 ) {
300	# Isotropic BSDF
301	my $ns2 = $ns / 2;
302	if ($windoz) {
303	$cmd = "cnt $ns2 $ny $nx " .
304	qq{\| rcalc -e "r1=rand(.8681*recno-.673892)" } .
305	qq{-e "r2=rand(-5.37138*recno+67.1737811)" } .
306	qq{-e "r3=rand(+3.17603772*recno+83.766771)" } .
307	qq{-e "Dx=1-2(\$1+r1)/$ns;Dy:0;Dz=sqrt(1-DxDx)" } .
308	qq{-e "xp=(\$3+r2)*(($dim[1]-$dim[0])/$nx)+$dim[0]" } .
309	qq{-e "yp=(\$2+r3)*(($dim[3]-$dim[2])/$ny)+$dim[2]" } .
310	qq{-e "zp=$dim[5-$forw]" -e "myDz=Dz($forw2-1)" } .
311	qq{-e "\$1=xp-Dx;\$2=yp-Dy;\$3=zp-myDz" } .
312	qq{-e "\$4=Dx;\$5=Dy;\$6=myDz" } .
313	"\| $rfluxmtx$r -fa -y $ns2 - $receivers -i $octree";
314	} else {
315	$cmd = "cnt $ns2 $ny $nx " .
316	qq{\| rcalc -e "r1=rand(.8681*recno-.673892)" } .
317	qq{-e "r2=rand(-5.37138*recno+67.1737811)" } .
318	qq{-e "r3=rand(+3.17603772*recno+83.766771)" } .
319	qq{-e "Dx=1-2(\$1+r1)/$ns;Dy:0;Dz=sqrt(1-DxDx)" } .
320	qq{-e "xp=(\$3+r2)*(($dim[1]-$dim[0])/$nx)+$dim[0]" } .
321	qq{-e "yp=(\$2+r3)*(($dim[3]-$dim[2])/$ny)+$dim[2]" } .
322	qq{-e "zp=$dim[5-$forw]" -e "myDz=Dz($forw2-1)" } .
323	qq{-e '\$1=xp-Dx;\$2=yp-Dy;\$3=zp-myDz' } .
324	qq{-e '\$4=Dx;\$5=Dy;\$6=myDz' -of } .
325	"\| $rfluxmtx$r -h -ff -y $ns2 - $receivers -i $octree";
326	}
327	} else {
328	# Anisotropic BSDF
329	my $sender = ($bsender,$fsender)[$forw];
330	if ($windoz) {
331	$cmd = "$rfluxmtx$r -fa $sender $receivers -i $octree";
332	} else {
333	$cmd = "$rfluxmtx$r -h -ff $sender $receivers -i $octree";
334	}
335	}
336	print STDERR "Starting: $cmd\n";
337	system $cmd;
338	die "Failure running rfluxmtx" if ( $? );
339	ttree_out($forw);
340	} # end of do_ttree_dir()
341
342	# Simplify and store tensor tree results
343	sub ttree_out {
344	my $forw = shift;
345	my ($refldat,$transdat);
346	if ( $forw ) {
347	$transdat = $facedat;
348	$refldat = $behinddat;
349	} else {
350	$transdat = $behinddat;
351	$refldat = $facedat;
352	}
353	# Only output one transmitted anisotropic distribution, preferring backwards
354	if ( !$forw \|\| !$doback \|\| $tensortree==3 ) {
355	my $ttyp = ("tb","tf")[$forw];
356	ttree_comp($ttyp, "Visible", $transdat, ($tb,$tf)[$forw]);
357	if ( $docolor ) {
358	ttree_comp($ttyp, "CIE-u", $transdat, ($tbx,$tfx)[$forw]);
359	ttree_comp($ttyp, "CIE-v", $transdat, ($tbz,$tfz)[$forw]);
360	}
361	}
362	# Output reflection
363	my $rtyp = ("rb","rf")[$forw];
364	ttree_comp($rtyp, "Visible", $refldat, ($rb,$rf)[$forw]);
365	if ( $docolor ) {
366	ttree_comp($rtyp, "CIE-u", $refldat, ($rbx,$rfx)[$forw]);
367	ttree_comp($rtyp, "CIE-v", $refldat, ($rbz,$rfz)[$forw]);
368	}
369	} # end of ttree_out()
370
371	# Call rttree_reduce on the given component
372	sub ttree_comp {
373	my $typ = shift;
374	my $spec = shift;
375	my $src = shift;
376	my $dest = shift;
377	my $cmd;
378	if ($windoz) {
379	if ("$spec" eq "Visible") {
380	$cmd = qq{rcalc -e "Omega:PI/($ns*$ns)" } .
381	q{-e "Ri=$1;Gi=$2;Bi=$3" } .
382	qq{-e "$CIEuv" } .
383	q{-e "$1=Yi/Omega"};
384	} elsif ("$spec" eq "CIE-u") {
385	$cmd = q{rcalc -e "Ri=$1;Gi=$2;Bi=$3" } .
386	qq{-e "$CIEuv" } .
387	q{-e "$1=uprime"};
388	} elsif ("$spec" eq "CIE-v") {
389	$cmd = q{rcalc -e "Ri=$1;Gi=$2;Bi=$3" } .
390	qq{-e "$CIEuv" } .
391	q{-e "$1=vprime"};
392	}
393	} else {
394	if ("$spec" eq "Visible") {
395	$cmd = "rcalc -if3 -e 'Omega:PI/($ns*$ns)' " .
396	q{-e 'Ri=$1;Gi=$2;Bi=$3' } .
397	"-e '$CIEuv' " .
398	q{-e '$1=Yi/Omega'};
399	} elsif ("$spec" eq "CIE-u") {
400	$cmd = q{rcalc -if3 -e 'Ri=$1;Gi=$2;Bi=$3' } .
401	"-e '$CIEuv' " .
402	q{-e '$1=uprime'};
403	} elsif ("$spec" eq "CIE-v") {
404	$cmd = q{rcalc -if3 -e 'Ri=$1;Gi=$2;Bi=$3' } .
405	"-e '$CIEuv' " .
406	q{-e '$1=vprime'};
407	}
408	}
409	if ($pctcull >= 0) {
410	my $avg = ( "$typ" =~ /^r[fb]/ ) ? " -a" : "";
411	my $pcull = ("$spec" eq "Visible") ? $pctcull :
412	(100 - (100-$pctcull)*.25) ;
413	if ($windoz) {
414	$cmd = "rcollate -ho -oc 1 $src \| " .
415	$cmd .
416	" \| rttree_reduce$avg -h -fa -t $pcull -r $tensortree -g $ttlog2";
417	} else {
418	$cmd .= " -of $src " .
419	"\| rttree_reduce$avg -h -ff -t $pcull -r $tensortree -g $ttlog2";
420	}
421	print STDERR "Running: $cmd\n";
422	system "$cmd > $dest";
423	die "Failure running rttree_reduce" if ( $? );
424	} else {
425	if ($windoz) {
426	$cmd = "rcollate -ho -oc 1 $src \| " . $cmd ;
427	} else {
428	$cmd .= " $src";
429	}
430	open(DATOUT, "> $dest");
431	print DATOUT "{\n";
432	close DATOUT;
433	print STDERR "Running: $cmd\n";
434	system "$cmd >> $dest";
435	die "Failure running rcalc" if ( $? );
436	open(DATOUT, ">> $dest");
437	for (my $i = ($tensortree==3)$ns$ns*$ns/2; $i-- > 0; ) {
438	print DATOUT "0\n";
439	}
440	print DATOUT "}\n";
441	close DATOUT;
442	}
443	if ( "$spec" ne "$curspec" ) {
444	$wrapper .= " -s $spec";
445	$curspec = $spec;
446	}
447	$wrapper .= " -$typ $dest";
448	} # end of ttree_comp()
449
450	#------------- End of do_tree_bsdf() & subroutines -------------#
451
452	#+++++++++++++++ Klems matrix BSDF generation +++++++++++++++#
453	sub do_matrix_bsdf {
454
455	# Run rfluxmtx processes to compute each side
456	do_matrix_dir(0) if ( $doback );
457	do_matrix_dir(1) if ( $doforw );
458
459	} # end of sub do_matrix_bsdf()
460
461	# Call rfluxmtx and process tensor tree BSDF for the given direction
462	sub do_matrix_dir {
463	my $forw = shift;
464	my $r = do_phase();
465	if (!$r) { return; }
466	$r = ($r < 0) ? " -r" : "";
467	my $cmd;
468	my $sender = ($bsender,$fsender)[$forw];
469	$cmd = "$rfluxmtx$r -fd $sender $receivers -i $octree";
470	print STDERR "Starting: $cmd\n";
471	system $cmd;
472	die "Failure running rfluxmtx" if ( $? );
473	matrix_out($forw);
474	} # end of do_matrix_dir()
475
476	sub matrix_out {
477	my $forw = shift;
478	my ($refldat,$transdat);
479	if ( $forw ) {
480	$transdat = $facedat;
481	$refldat = $behinddat;
482	} else {
483	$transdat = $behinddat;
484	$refldat = $facedat;
485	}
486	# Output transmission
487	my $ttyp = ("tb","tf")[$forw];
488	matrix_comp($ttyp, "Visible", $transdat, ($tb,$tf)[$forw]);
489	if ( $docolor ) {
490	matrix_comp($ttyp, "CIE-X", $transdat, ($tbx,$tfx)[$forw]);
491	matrix_comp($ttyp, "CIE-Z", $transdat, ($tbz,$tfz)[$forw]);
492	}
493	# Output reflection
494	my $rtyp = ("rb","rf")[$forw];
495	matrix_comp($rtyp, "Visible", $refldat, ($rb,$rf)[$forw]);
496	if ( $docolor ) {
497	matrix_comp($rtyp, "CIE-X", $refldat, ($rbx,$rfx)[$forw]);
498	matrix_comp($rtyp, "CIE-Z", $refldat, ($rbz,$rfz)[$forw]);
499	}
500	} # end of matrix_out()
501
502	# Transpose matrix component data and save to file
503	sub matrix_comp {
504	my $typ = shift;
505	my $spec = shift;
506	my $src = shift;
507	my $dest = shift;
508	my $cmd = "rmtxop -fa -t";
509	if ("$spec" eq "Visible") {
510	$cmd .= " -c 0.2651 0.6701 0.0648";
511	} elsif ("$spec" eq "CIE-X") {
512	$cmd .= " -c 0.5141 0.3239 0.1620";
513	} elsif ("$spec" eq "CIE-Z") {
514	$cmd .= " -c 0.0241 0.1229 0.8530";
515	}
516	$cmd .= " $src \| rcollate -ho -oc 145";
517	print STDERR "Running: $cmd\n";
518	system "$cmd > $dest";
519	die "Failure running rmtxop" if ( $? );
520	if ( "$spec" ne "$curspec" ) {
521	$wrapper .= " -s $spec";
522	$curspec = $spec;
523	}
524	$wrapper .= " -$typ $dest";
525	} # end of matrix_comp()
526
527	#------------- End of do_matrix_bsdf() & subroutines --------------#