src/util/genBSDF.pl

#!/usr/bin/perl -w
# RCSid $Id: genBSDF.pl,v 2.15 2011/05/25 19:24:11 greg Exp $
#
# Compute BSDF based on geometry and material description
#
#       G. Ward
#
use strict;
use File::Temp qw/ :mktemp  /;
sub userror {
        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";
        exit 1;
}
my $td = mkdtemp("/tmp/genBSDF.XXXXXX");
chomp $td;
my $tensortree = 0;
my $ttlog2 = 4;
my $nsamp = 1000;
my $rtargs = "-w -ab 5 -ad 700 -lw 3e-6";
my $mgfin = 0;
my $geout = 1;
my $nproc = 1;
my $doforw = 0;
my $doback = 1;
my @dim;
# Get options
while ($#ARGV >= 0) {
        if ("$ARGV[0]" =~ /^[-+]m/) {
                $mgfin = ("$ARGV[0]" =~ /^\+/);
        } elsif ("$ARGV[0]" eq "-r") {
                $rtargs = "$rtargs $ARGV[1]";
                shift @ARGV;
        } elsif ("$ARGV[0]" =~ /^[-+]g/) {
                $geout = ("$ARGV[0]" =~ /^\+/);
        } elsif ("$ARGV[0]" =~ /^[-+]f/) {
                $doforw = ("$ARGV[0]" =~ /^\+/);
        } elsif ("$ARGV[0]" =~ /^[-+]b/) {
                $doback = ("$ARGV[0]" =~ /^\+/);
        } elsif ("$ARGV[0]" =~ /^-t[34]$/) {
                $tensortree = substr($ARGV[0], 2, 1);
                $ttlog2 = $ARGV[1];
                shift @ARGV;
        } elsif ("$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);
# Name our own persist file?
my $persistfile;
if ( $tensortree && $nproc > 1 && "$rtargs" !~ /-PP /) {
        $persistfile = "$td/pfile.txt";
        $rtargs = "-PP $persistfile $rtargs";
}
# Get scene description and dimensions
my $radscn = "$td/device.rad";
my $mgfscn = "$td/device.mgf";
my $octree = "$td/device.oct";
if ( $mgfin ) {
        system "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";
        die "Could not load MGF input\n" if ( $? );
        system "mgf2rad $mgfscn > $radscn";
} else {
        system "xform -e @ARGV > $radscn";
        die "Could not load Radiance input\n" if ( $? );
        system "rad2mgf $radscn > $mgfscn" if ( $geout );
}
if ($#dim != 5) {
        @dim = split ' ', `getbbox -h $radscn`;
}
print STDERR "Warning: Device extends into room\n" if ($dim[5] > 1e-5);
# Add receiver surfaces (rectangular)
my $fmodnm="receiver_face";
my $bmodnm="receiver_behind";
open(RADSCN, ">> $radscn");
print RADSCN "void glow $fmodnm\n0\n0\n4 1 1 1 0\n\n";
print RADSCN "$fmodnm source f_receiver\n0\n0\n4 0 0 1 180\n";
print RADSCN "void glow $bmodnm\n0\n0\n4 1 1 1 0\n\n";
print RADSCN "$bmodnm source b_receiver\n0\n0\n4 0 0 -1 180\n";
close RADSCN;
# Generate octree
system "oconv -w $radscn > $octree";
die "Could not compile scene\n" if ( $? );
# Output XML prologue
print
'<?xml version="1.0" encoding="UTF-8"?>
<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">
<WindowElementType>System</WindowElementType>
<Optical>
<Layer>
        <Material>
                <Name>Name</Name>
                <Manufacturer>Manufacturer</Manufacturer>
';
printf "\t\t<Thickness unit=\"Meter\">%.3f</Thickness>\n", $dim[5] - $dim[4];
printf "\t\t<Width unit=\"Meter\">%.3f</Width>\n", $dim[1] - $dim[0];
printf "\t\t<Height unit=\"Meter\">%.3f</Height>\n", $dim[3] - $dim[2];
print "\t\t<DeviceType>Integral</DeviceType>\n";
# Output MGF description if requested
if ( $geout ) {
        print "\t\t<Geometry format=\"MGF\" unit=\"Meter\">\n";
        printf "xf -t %.6f %.6f 0\n", -($dim[0]+$dim[1])/2, -($dim[2]+$dim[3])/2;
        open(MGFSCN, "< $mgfscn");
        while (<MGFSCN>) { print $_; }
        close MGFSCN;
        print "xf\n";
        print "\t\t</Geometry>\n";
}
print " </Material>\n";
# Set up surface sampling
my $nx = int(sqrt($nsamp*($dim[1]-$dim[0])/($dim[3]-$dim[2])) + .5);
my $ny = int($nsamp/$nx + .5);
$nsamp = $nx * $ny;
my $ns = 2**$ttlog2;
my (@pdiv, $disk2sq, $sq2disk, $tcal, $kcal);
# Create data segments (all the work happens here)
if ( $tensortree ) {
        do_tree_bsdf();
} else {
        do_matrix_bsdf();
}
# Output XML epilogue
print
'</Layer>
</Optical>
</WindowElement>
';
# Clean up temporary files and exit
if ( $persistfile && open(PFI, "< $persistfile") ) {
        while (<PFI>) {
                s/^[^ ]* //;
                kill('ALRM', $_);
                last;
        }
        close PFI;
}
exec("rm -rf $td");

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

#++++++++++++++ Tensor tree BSDF generation ++++++++++++++#
sub do_tree_bsdf {
# Get sampling rate and subdivide task
my $ns2 = $ns;
$ns2 /= 2 if ( $tensortree == 3 );
@pdiv = (0, int($ns2/$nproc));
my $nrem = $ns2 % $nproc;
for (my $i = 1; $i < $nproc; $i++) {
        my $nv = $pdiv[$i] + $pdiv[1];
        ++$nv if ( $nrem-- > 0 );
        push @pdiv, $nv;
}
die "Script error 1" if ($pdiv[-1] != $ns2);
# Shirley-Chiu mapping from unit square to disk
$sq2disk = '
in_square_a = 2*in_square_x - 1;
in_square_b = 2*in_square_y - 1;
in_square_rgn = if(in_square_a + in_square_b,
                        if(in_square_a - in_square_b, 1, 2),
                        if(in_square_b - in_square_a, 3, 4));
out_disk_r = .999995*select(in_square_rgn, in_square_a, in_square_b,
                        -in_square_a, -in_square_b);
out_disk_phi = PI/4 * select(in_square_rgn,
                                in_square_b/in_square_a,
                                2 - in_square_a/in_square_b,
                                4 + in_square_b/in_square_a,
                                if(in_square_b*in_square_b,
                                        6 - in_square_a/in_square_b, 0));
Dx = out_disk_r*cos(out_disk_phi);
Dy = out_disk_r*sin(out_disk_phi);
Dz = sqrt(1 - out_disk_r*out_disk_r);
';
# Shirley-Chiu mapping from unit disk to square
$disk2sq = '
norm_radians(p) : if(-p - PI/4, p + 2*PI, p);
in_disk_r = .999995*sqrt(Dx*Dx + Dy*Dy);
in_disk_phi = norm_radians(atan2(Dy, Dx));
in_disk_rgn = floor((in_disk_phi + PI/4)/(PI/2)) + 1;
out_square_a = select(in_disk_rgn,
                        in_disk_r,
                        (PI/2 - in_disk_phi)*in_disk_r/(PI/4),
                        -in_disk_r,
                        (in_disk_phi - 3*PI/2)*in_disk_r/(PI/4));
out_square_b = select(in_disk_rgn,
                        in_disk_phi*in_disk_r/(PI/4),
                        in_disk_r,
                        (PI - in_disk_phi)*in_disk_r/(PI/4),
                        -in_disk_r);
out_square_x = (out_square_a + 1)/2;
out_square_y = (out_square_b + 1)/2;
';
# Announce ourselves in XML output
print "\t<DataDefinition>\n";
print "\t\t<IncidentDataStructure>TensorTree$tensortree</IncidentDataStructure>\n";
print "\t</DataDefinition>\n";
# Fork parallel rtcontrib processes to compute each side
if ( $doback ) {
        for (my $proc = 0; $proc < $nproc; $proc++) {
                bg_tree_rtcontrib(0, $proc);
        }
        while (wait() >= 0) {
                die "rtcontrib process reported error" if ( $? );
        }
        ttree_out(0);
}
if ( $doforw ) {
        for (my $proc = 0; $proc < $nproc; $proc++) {
                bg_tree_rtcontrib(1, $proc);
        }
        while (wait() >= 0) {
                die "rtcontrib process reported error" if ( $? );
        }
        ttree_out(1);
}
}       # end of sub do_tree_bsdf()

# Run i'th rtcontrib process for generating tensor tree samples
sub bg_tree_rtcontrib {
        my $pid = fork();
        die "Cannot fork new process" unless defined $pid;
        if ($pid > 0) { return $pid; }
        my $forw = shift;
        my $pn = shift;
        my $pbeg = $pdiv[$pn];
        my $plen = $pdiv[$pn+1] - $pbeg;
        my $matargs = "-m $bmodnm";
        if ( !$forw || !$doback ) { $matargs .= " -m $fmodnm"; }
        my $cmd = "rtcontrib $rtargs -h -ff -fo -c $nsamp " .
                "-e '$disk2sq' -bn '$ns*$ns' " .
                "-b '$ns*floor(out_square_x*$ns)+floor(out_square_y*$ns)' " .
                "-o $td/%s_" . sprintf("%03d", $pn) . ".flt $matargs $octree";
        if ( $tensortree == 3 ) {
                # Isotropic BSDF
                $cmd = "cnt $plen $ny $nx " .
                        "| rcalc -e 'r1=rand(($pn+.8681)*recno-.673892)' " .
                        "-e 'r2=rand(($pn-5.37138)*recno+67.1737811)' " .
                        "-e 'r3=rand(($pn+3.17603772)*recno+83.766771)' " .
                        "-e 'Dx=1-($pbeg+\$1+r1)/$ns;Dy:0;Dz=sqrt(1-Dx*Dx)' " .
                        "-e 'xp=(\$3+r2)*(($dim[1]-$dim[0])/$nx)+$dim[0]' " .
                        "-e 'yp=(\$2+r3)*(($dim[3]-$dim[2])/$ny)+$dim[2]' " .
                        "-e 'zp=$dim[5-$forw]' -e 'myDz=Dz*($forw*2-1)' " .
                        "-e '\$1=xp-Dx;\$2=yp-Dy;\$3=zp-myDz' " .
                        "-e '\$4=Dx;\$5=Dy;\$6=myDz' -of " .
                        "| $cmd";
        } else {
                # Anisotropic BSDF
                # Sample area vertically to improve load balance, since
                # shading systems usually have bilateral symmetry (L-R)
                $cmd = "cnt $plen $ns $ny $nx " .
                        "| rcalc -e 'r1=rand(($pn+.8681)*recno-.673892)' " .
                        "-e 'r2=rand(($pn-5.37138)*recno+67.1737811)' " .
                        "-e 'r3=rand(($pn+3.17603772)*recno+83.766771)' " .
                        "-e 'r4=rand(($pn-2.3857833)*recno-964.72738)' " .
                        "-e 'in_square_x=($pbeg+\$1+r1)/$ns' " .
                        "-e 'in_square_y=(\$2+r2)/$ns' -e '$sq2disk' " .
                        "-e 'xp=(\$4+r3)*(($dim[1]-$dim[0])/$nx)+$dim[0]' " .
                        "-e 'yp=(\$3+r4)*(($dim[3]-$dim[2])/$ny)+$dim[2]' " .
                        "-e 'zp=$dim[5-$forw]' -e 'myDz=Dz*($forw*2-1)' " .
                        "-e '\$1=xp-Dx;\$2=yp-Dy;\$3=zp-myDz' " .
                        "-e '\$4=Dx;\$5=Dy;\$6=myDz' -of " .
                        "| $cmd";
        }
# print STDERR "Starting: $cmd\n";
        exec($cmd);             # no return; status report to parent via wait
        die "Cannot exec: $cmd\n";
}       # end of bg_tree_rtcontrib()

# Simplify and output tensor tree results
sub ttree_out {
        my $forw = shift;
        my $side = ("Back","Front")[$forw];
# Only output one transmitted distribution, preferring backwards
if ( !$forw || !$doback ) {
print
'       <WavelengthData>
                <LayerNumber>System</LayerNumber>
                <Wavelength unit="Integral">Visible</Wavelength>
                <SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
                <DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
                <WavelengthDataBlock>
                        <WavelengthDataDirection>Transmission</WavelengthDataDirection>
                        <AngleBasis>LBNL/Shirley-Chiu</AngleBasis>
                        <ScatteringDataType>BTDF</ScatteringDataType>
                        <ScatteringData>
';
system "rcalc -if3 -e 'Omega:PI/($ns*$ns)' " .
        q{-e '$1=(0.265*$1+0.670*$2+0.065*$3)/Omega' -of } .
        "$td/" . ($bmodnm,$fmodnm)[$forw] . "_???.flt " .
        "| rttree_reduce -h -ff -r $tensortree -g $ttlog2";
die "Failure running rttree_reduce" if ( $? );
print
'                       </ScatteringData>
                </WavelengthDataBlock>
        </WavelengthData>
';
}
# Output reflection
print
'       <WavelengthData>
                <LayerNumber>System</LayerNumber>
                <Wavelength unit="Integral">Visible</Wavelength>
                <SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
                <DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
                <WavelengthDataBlock>
                        <WavelengthDataDirection>Reflection $side</WavelengthDataDirection>
                        <AngleBasis>LBNL/Shirley-Chiu</AngleBasis>
                        <ScatteringDataType>BRDF</ScatteringDataType>
                        <ScatteringData>
';
system "rcalc -if3 -e 'Omega:PI/($ns*$ns)' " .
        q{-e '$1=(0.265*$1+0.670*$2+0.065*$3)/Omega' -of } .
        "$td/" . ($fmodnm,$bmodnm)[$forw] . "_???.flt " .
        "| rttree_reduce -h -ff -r $tensortree -g $ttlog2";
die "Failure running rttree_reduce" if ( $? );
print
'                       </ScatteringData>
                </WavelengthDataBlock>
        </WavelengthData>
';
}       # end of ttree_out()

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

#+++++++++++++++ Klems matrix BSDF generation +++++++++++++++#
sub do_matrix_bsdf {
# Set up sampling of portal
# Kbin to produce incident direction in full Klems basis with (x1,x2) randoms
$tcal = '
DEGREE : PI/180;
sq(x) : x*x;
Kpola(r) : select(r+1, -5, 5, 15, 25, 35, 45, 55, 65, 75, 90);
Knaz(r) : select(r, 1, 8, 16, 20, 24, 24, 24, 16, 12);
Kaccum(r) : if(r-.5, Knaz(r) + Kaccum(r-1), 0);
Kmax : Kaccum(Knaz(0));
Kfindrow(r, rem) : if(rem-Knaz(r)+.5, Kfindrow(r+1, rem-Knaz(r)), r);
Krow = if(Kbin-(Kmax-.5), 0, Kfindrow(1, Kbin));
Kcol = Kbin - Kaccum(Krow-1);
Kazi = 360*DEGREE * (Kcol + (.5 - x2)) / Knaz(Krow);
Kpol = DEGREE * (x1*Kpola(Krow) + (1-x1)*Kpola(Krow-1));
sin_kpol = sin(Kpol);
Dx = cos(Kazi)*sin_kpol;
Dy = sin(Kazi)*sin_kpol;
Dz = sqrt(1 - sin_kpol*sin_kpol);
KprojOmega = PI * if(Kbin-.5,
        (sq(cos(Kpola(Krow-1)*DEGREE)) - sq(cos(Kpola(Krow)*DEGREE)))/Knaz(Krow),
        1 - sq(cos(Kpola(1)*DEGREE)));
';
# Compute Klems bin from exiting ray direction (forward or backward)
$kcal = '
DEGREE : PI/180;
abs(x) : if(x, x, -x);
Acos(x) : 1/DEGREE * if(x-1, 0, if(-1-x, 0, acos(x)));
posangle(a) : if(-a, a + 2*PI, a);
Atan2(y,x) : 1/DEGREE * posangle(atan2(y,x));
kpola(r) : select(r, 5, 15, 25, 35, 45, 55, 65, 75, 90);
knaz(r) : select(r, 1, 8, 16, 20, 24, 24, 24, 16, 12);
kaccum(r) : if(r-.5, knaz(r) + kaccum(r-1), 0);
kfindrow(r, pol) : if(r-kpola(0)+.5, r,
                if(pol-kpola(r), kfindrow(r+1, pol), r) );
kazn(azi,inc) : if((360-.5*inc)-azi, floor((azi+.5*inc)/inc), 0);
kbin2(pol,azi) = select(kfindrow(1, pol),
                kazn(azi,360/knaz(1)),
                kaccum(1) + kazn(azi,360/knaz(2)),
                kaccum(2) + kazn(azi,360/knaz(3)),
                kaccum(3) + kazn(azi,360/knaz(4)),
                kaccum(4) + kazn(azi,360/knaz(5)),
                kaccum(5) + kazn(azi,360/knaz(6)),
                kaccum(6) + kazn(azi,360/knaz(7)),
                kaccum(7) + kazn(azi,360/knaz(8)),
                kaccum(8) + kazn(azi,360/knaz(9))
        );
kbin = kbin2(Acos(abs(Dz)),Atan2(Dy,Dx));
';
my $ndiv = 145;
# Compute scattering data using rtcontrib
my @tfarr;
my @rfarr;
my @tbarr;
my @rbarr;
my $cmd;
my $rtcmd = "rtcontrib $rtargs -h -ff -fo -n $nproc -c $nsamp " .
        "-e '$kcal' -b kbin -bn $ndiv " .
        "-o '$td/%s.flt' -m $fmodnm -m $bmodnm $octree";
my $rccmd = "rcalc -e '$tcal' " .
        "-e 'mod(n,d):n-floor(n/d)*d' -e 'Kbin=mod(recno-.999,$ndiv)' " .
        q{-if3 -e '$1=(0.265*$1+0.670*$2+0.065*$3)/KprojOmega'};
if ( $doforw ) {
$cmd = "cnt $ndiv $ny $nx | rcalc -of -e '$tcal' " .
        "-e 'xp=(\$3+rand(.12*recno+288))*(($dim[1]-$dim[0])/$nx)+$dim[0]' " .
        "-e 'yp=(\$2+rand(.37*recno-44))*(($dim[3]-$dim[2])/$ny)+$dim[2]' " .
        "-e 'zp:$dim[4]' " .
        q{-e 'Kbin=$1;x1=rand(2.75*recno+3.1);x2=rand(-2.01*recno-3.37)' } .
        q{-e '$1=xp-Dx;$2=yp-Dy;$3=zp-Dz;$4=Dx;$5=Dy;$6=Dz' } .
        "| $rtcmd";
system "$cmd" || die "Failure running: $cmd\n";
@tfarr = `$rccmd $td/$fmodnm.flt`;
die "Failure running: $rccmd $td/$fmodnm.flt\n" if ( $? );
@rfarr = `$rccmd $td/$bmodnm.flt`;
die "Failure running: $rccmd $td/$bmodnm.flt\n" if ( $? );
}
if ( $doback ) {
$cmd = "cnt $ndiv $ny $nx | rcalc -of -e '$tcal' " .
        "-e 'xp=(\$3+rand(.35*recno-15))*(($dim[1]-$dim[0])/$nx)+$dim[0]' " .
        "-e 'yp=(\$2+rand(.86*recno+11))*(($dim[3]-$dim[2])/$ny)+$dim[2]' " .
        "-e 'zp:$dim[5]' " .
        q{-e 'Kbin=$1;x1=rand(1.21*recno+2.75);x2=rand(-3.55*recno-7.57)' } .
        q{-e '$1=xp-Dx;$2=yp-Dy;$3=zp+Dz;$4=Dx;$5=Dy;$6=-Dz' } .
        "| $rtcmd";
system "$cmd" || die "Failure running: $cmd\n";
@tbarr = `$rccmd $td/$bmodnm.flt`;
die "Failure running: $rccmd $td/$bmodnm.flt\n" if ( $? );
@rbarr = `$rccmd $td/$fmodnm.flt`;
die "Failure running: $rccmd $td/$fmodnm.flt\n" if ( $? );
}
# Output angle basis
print
'       <DataDefinition>
                <IncidentDataStructure>Columns</IncidentDataStructure>
                <AngleBasis>
                        <AngleBasisName>LBNL/Klems Full</AngleBasisName>
                        <AngleBasisBlock>
                                <Theta>0</Theta>
                                <nPhis>1</nPhis>
                                <ThetaBounds>
                                        <LowerTheta>0</LowerTheta>
                                        <UpperTheta>5</UpperTheta>
                                </ThetaBounds>
                                </AngleBasisBlock>
                                <AngleBasisBlock>
                                <Theta>10</Theta>
                                <nPhis>8</nPhis>
                                <ThetaBounds>
                                        <LowerTheta>5</LowerTheta>
                                        <UpperTheta>15</UpperTheta>
                                </ThetaBounds>
                                </AngleBasisBlock>
                                <AngleBasisBlock>
                                <Theta>20</Theta>
                                <nPhis>16</nPhis>
                                <ThetaBounds>
                                        <LowerTheta>15</LowerTheta>
                                        <UpperTheta>25</UpperTheta>
                                </ThetaBounds>
                                </AngleBasisBlock>
                                <AngleBasisBlock>
                                <Theta>30</Theta>
                                <nPhis>20</nPhis>
                                <ThetaBounds>
                                        <LowerTheta>25</LowerTheta>
                                        <UpperTheta>35</UpperTheta>
                                </ThetaBounds>
                                </AngleBasisBlock>
                                <AngleBasisBlock>
                                <Theta>40</Theta>
                                <nPhis>24</nPhis>
                                <ThetaBounds>
                                        <LowerTheta>35</LowerTheta>
                                        <UpperTheta>45</UpperTheta>
                                </ThetaBounds>
                                </AngleBasisBlock>
                                <AngleBasisBlock>
                                <Theta>50</Theta>
                                <nPhis>24</nPhis>
                                <ThetaBounds>
                                        <LowerTheta>45</LowerTheta>
                                        <UpperTheta>55</UpperTheta>
                                </ThetaBounds>
                                </AngleBasisBlock>
                                <AngleBasisBlock>
                                <Theta>60</Theta>
                                <nPhis>24</nPhis>
                                <ThetaBounds>
                                        <LowerTheta>55</LowerTheta>
                                        <UpperTheta>65</UpperTheta>
                                </ThetaBounds>
                                </AngleBasisBlock>
                                <AngleBasisBlock>
                                <Theta>70</Theta>
                                <nPhis>16</nPhis>
                                <ThetaBounds>
                                        <LowerTheta>65</LowerTheta>
                                        <UpperTheta>75</UpperTheta>
                                </ThetaBounds>
                                </AngleBasisBlock>
                                <AngleBasisBlock>
                                <Theta>82.5</Theta>
                                <nPhis>12</nPhis>
                                <ThetaBounds>
                                        <LowerTheta>75</LowerTheta>
                                        <UpperTheta>90</UpperTheta>
                                </ThetaBounds>
                        </AngleBasisBlock>
                </AngleBasis>
        </DataDefinition>
';
if ( $doforw ) {
print
'       <WavelengthData>
                <LayerNumber>System</LayerNumber>
                <Wavelength unit="Integral">Visible</Wavelength>
                <SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
                <DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
                <WavelengthDataBlock>
                        <WavelengthDataDirection>Transmission Front</WavelengthDataDirection>
                        <ColumnAngleBasis>LBNL/Klems Full</ColumnAngleBasis>
                        <RowAngleBasis>LBNL/Klems Full</RowAngleBasis>
                        <ScatteringDataType>BTDF</ScatteringDataType>
                        <ScatteringData>
';
# Output front transmission (transposed order)
for (my $od = 0; $od < $ndiv; $od++) {
        for (my $id = 0; $id < $ndiv; $id++) {
                print $tfarr[$ndiv*$id + $od];
        }
        print "\n";
}
print
'                       </ScatteringData>
                </WavelengthDataBlock>
        </WavelengthData>
        <WavelengthData>
                <LayerNumber>System</LayerNumber>
                <Wavelength unit="Integral">Visible</Wavelength>
                <SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
                <DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
                <WavelengthDataBlock>
                        <WavelengthDataDirection>Reflection Front</WavelengthDataDirection>
                        <ColumnAngleBasis>LBNL/Klems Full</ColumnAngleBasis>
                        <RowAngleBasis>LBNL/Klems Full</RowAngleBasis>
                        <ScatteringDataType>BRDF</ScatteringDataType>
                        <ScatteringData>
';
# Output front reflection (transposed order)
for (my $od = 0; $od < $ndiv; $od++) {
        for (my $id = 0; $id < $ndiv; $id++) {
                print $rfarr[$ndiv*$id + $od];
        }
        print "\n";
}
print
'                       </ScatteringData>
                </WavelengthDataBlock>
        </WavelengthData>
';
}
if ( $doback ) {
print
'       <WavelengthData>
                <LayerNumber>System</LayerNumber>
                <Wavelength unit="Integral">Visible</Wavelength>
                <SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
                <DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
                <WavelengthDataBlock>
                        <WavelengthDataDirection>Transmission Back</WavelengthDataDirection>
                        <ColumnAngleBasis>LBNL/Klems Full</ColumnAngleBasis>
                        <RowAngleBasis>LBNL/Klems Full</RowAngleBasis>
                        <ScatteringDataType>BTDF</ScatteringDataType>
                        <ScatteringData>
';
# Output back transmission (transposed order)
for (my $od = 0; $od < $ndiv; $od++) {
        for (my $id = 0; $id < $ndiv; $id++) {
                print $tbarr[$ndiv*$id + $od];
        }
        print "\n";
}
print
'                       </ScatteringData>
                </WavelengthDataBlock>
        </WavelengthData>
        <WavelengthData>
                <LayerNumber>System</LayerNumber>
                <Wavelength unit="Integral">Visible</Wavelength>
                <SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
                <DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
                <WavelengthDataBlock>
                        <WavelengthDataDirection>Reflection Back</WavelengthDataDirection>
                        <ColumnAngleBasis>LBNL/Klems Full</ColumnAngleBasis>
                        <RowAngleBasis>LBNL/Klems Full</RowAngleBasis>
                        <ScatteringDataType>BRDF</ScatteringDataType>
                        <ScatteringData>
';
# Output back reflection (transposed order)
for (my $od = 0; $od < $ndiv; $od++) {
        for (my $id = 0; $id < $ndiv; $id++) {
                print $rbarr[$ndiv*$id + $od];
        }
        print "\n";
}
print
'                       </ScatteringData>
                </WavelengthDataBlock>
        </WavelengthData>
';
}
}
#------------- End of do_matrix_bsdf() --------------#
Revision:	2.16
Committed:	Tue May 31 20:50:26 2011 UTC (12 years, 11 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.15:	+7 -8 lines
Log Message:	Fixed bug in missing persist file and changed to percentile-based threshold
#	Content
1	#!/usr/bin/perl -w
2	# RCSid $Id: genBSDF.pl,v 2.15 2011/05/25 19:24:11 greg Exp $
3	#
4	# Compute BSDF based on geometry and material description
5	#
6	# G. Ward
7	#
8	use strict;
9	use File::Temp qw/ :mktemp /;
10	sub userror {
11	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";
12	exit 1;
13	}
14	my $td = mkdtemp("/tmp/genBSDF.XXXXXX");
15	chomp $td;
16	my $tensortree = 0;
17	my $ttlog2 = 4;
18	my $nsamp = 1000;
19	my $rtargs = "-w -ab 5 -ad 700 -lw 3e-6";
20	my $mgfin = 0;
21	my $geout = 1;
22	my $nproc = 1;
23	my $doforw = 0;
24	my $doback = 1;
25	my @dim;
26	# Get options
27	while ($#ARGV >= 0) {
28	if ("$ARGV[0]" =~ /^[-+]m/) {
29	$mgfin = ("$ARGV[0]" =~ /^\+/);
30	} elsif ("$ARGV[0]" eq "-r") {
31	$rtargs = "$rtargs $ARGV[1]";
32	shift @ARGV;
33	} elsif ("$ARGV[0]" =~ /^[-+]g/) {
34	$geout = ("$ARGV[0]" =~ /^\+/);
35	} elsif ("$ARGV[0]" =~ /^[-+]f/) {
36	$doforw = ("$ARGV[0]" =~ /^\+/);
37	} elsif ("$ARGV[0]" =~ /^[-+]b/) {
38	$doback = ("$ARGV[0]" =~ /^\+/);
39	} elsif ("$ARGV[0]" =~ /^-t[34]$/) {
40	$tensortree = substr($ARGV[0], 2, 1);
41	$ttlog2 = $ARGV[1];
42	shift @ARGV;
43	} elsif ("$ARGV[0]" eq "-c") {
44	$nsamp = $ARGV[1];
45	shift @ARGV;
46	} elsif ("$ARGV[0]" eq "-n") {
47	$nproc = $ARGV[1];
48	shift @ARGV;
49	} elsif ("$ARGV[0]" =~ /^-d/) {
50	userror() if ($#ARGV < 6);
51	@dim = @ARGV[1..6];
52	shift @ARGV for (1..6);
53	} elsif ("$ARGV[0]" =~ /^[-+]./) {
54	userror();
55	} else {
56	last;
57	}
58	shift @ARGV;
59	}
60	# Check that we're actually being asked to do something
61	die "Must have at least one of +forward or +backward\n" if (!$doforw && !$doback);
62	# Name our own persist file?
63	my $persistfile;
64	if ( $tensortree && $nproc > 1 && "$rtargs" !~ /-PP /) {
65	$persistfile = "$td/pfile.txt";
66	$rtargs = "-PP $persistfile $rtargs";
67	}
68	# Get scene description and dimensions
69	my $radscn = "$td/device.rad";
70	my $mgfscn = "$td/device.mgf";
71	my $octree = "$td/device.oct";
72	if ( $mgfin ) {
73	system "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";
74	die "Could not load MGF input\n" if ( $? );
75	system "mgf2rad $mgfscn > $radscn";
76	} else {
77	system "xform -e @ARGV > $radscn";
78	die "Could not load Radiance input\n" if ( $? );
79	system "rad2mgf $radscn > $mgfscn" if ( $geout );
80	}
81	if ($#dim != 5) {
82	@dim = split ' ', `getbbox -h $radscn`;
83	}
84	print STDERR "Warning: Device extends into room\n" if ($dim[5] > 1e-5);
85	# Add receiver surfaces (rectangular)
86	my $fmodnm="receiver_face";
87	my $bmodnm="receiver_behind";
88	open(RADSCN, ">> $radscn");
89	print RADSCN "void glow $fmodnm\n0\n0\n4 1 1 1 0\n\n";
90	print RADSCN "$fmodnm source f_receiver\n0\n0\n4 0 0 1 180\n";
91	print RADSCN "void glow $bmodnm\n0\n0\n4 1 1 1 0\n\n";
92	print RADSCN "$bmodnm source b_receiver\n0\n0\n4 0 0 -1 180\n";
93	close RADSCN;
94	# Generate octree
95	system "oconv -w $radscn > $octree";
96	die "Could not compile scene\n" if ( $? );
97	# Output XML prologue
98	print
99	'<?xml version="1.0" encoding="UTF-8"?>
100	<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">
101	<WindowElementType>System</WindowElementType>
102	<Optical>
103	<Layer>
104	<Material>
105	<Name>Name</Name>
106	<Manufacturer>Manufacturer</Manufacturer>
107	';
108	printf "\t\t<Thickness unit=\"Meter\">%.3f</Thickness>\n", $dim[5] - $dim[4];
109	printf "\t\t<Width unit=\"Meter\">%.3f</Width>\n", $dim[1] - $dim[0];
110	printf "\t\t<Height unit=\"Meter\">%.3f</Height>\n", $dim[3] - $dim[2];
111	print "\t\t<DeviceType>Integral</DeviceType>\n";
112	# Output MGF description if requested
113	if ( $geout ) {
114	print "\t\t<Geometry format=\"MGF\" unit=\"Meter\">\n";
115	printf "xf -t %.6f %.6f 0\n", -($dim[0]+$dim[1])/2, -($dim[2]+$dim[3])/2;
116	open(MGFSCN, "< $mgfscn");
117	while (<MGFSCN>) { print $_; }
118	close MGFSCN;
119	print "xf\n";
120	print "\t\t</Geometry>\n";
121	}
122	print " </Material>\n";
123	# Set up surface sampling
124	my $nx = int(sqrt($nsamp*($dim[1]-$dim[0])/($dim[3]-$dim[2])) + .5);
125	my $ny = int($nsamp/$nx + .5);
126	$nsamp = $nx * $ny;
127	my $ns = 2**$ttlog2;
128	my (@pdiv, $disk2sq, $sq2disk, $tcal, $kcal);
129	# Create data segments (all the work happens here)
130	if ( $tensortree ) {
131	do_tree_bsdf();
132	} else {
133	do_matrix_bsdf();
134	}
135	# Output XML epilogue
136	print
137	'</Layer>
138	</Optical>
139	</WindowElement>
140	';
141	# Clean up temporary files and exit
142	if ( $persistfile && open(PFI, "< $persistfile") ) {
143	while (<PFI>) {
144	s/^[^ ]* //;
145	kill('ALRM', $_);
146	last;
147	}
148	close PFI;
149	}
150	exec("rm -rf $td");
151
152	#-------------- End of main program segment --------------#
153
154	#++++++++++++++ Tensor tree BSDF generation ++++++++++++++#
155	sub do_tree_bsdf {
156	# Get sampling rate and subdivide task
157	my $ns2 = $ns;
158	$ns2 /= 2 if ( $tensortree == 3 );
159	@pdiv = (0, int($ns2/$nproc));
160	my $nrem = $ns2 % $nproc;
161	for (my $i = 1; $i < $nproc; $i++) {
162	my $nv = $pdiv[$i] + $pdiv[1];
163	++$nv if ( $nrem-- > 0 );
164	push @pdiv, $nv;
165	}
166	die "Script error 1" if ($pdiv[-1] != $ns2);
167	# Shirley-Chiu mapping from unit square to disk
168	$sq2disk = '
169	in_square_a = 2*in_square_x - 1;
170	in_square_b = 2*in_square_y - 1;
171	in_square_rgn = if(in_square_a + in_square_b,
172	if(in_square_a - in_square_b, 1, 2),
173	if(in_square_b - in_square_a, 3, 4));
174	out_disk_r = .999995*select(in_square_rgn, in_square_a, in_square_b,
175	-in_square_a, -in_square_b);
176	out_disk_phi = PI/4 * select(in_square_rgn,
177	in_square_b/in_square_a,
178	2 - in_square_a/in_square_b,
179	4 + in_square_b/in_square_a,
180	if(in_square_b*in_square_b,
181	6 - in_square_a/in_square_b, 0));
182	Dx = out_disk_r*cos(out_disk_phi);
183	Dy = out_disk_r*sin(out_disk_phi);
184	Dz = sqrt(1 - out_disk_r*out_disk_r);
185	';
186	# Shirley-Chiu mapping from unit disk to square
187	$disk2sq = '
188	norm_radians(p) : if(-p - PI/4, p + 2*PI, p);
189	in_disk_r = .999995sqrt(DxDx + Dy*Dy);
190	in_disk_phi = norm_radians(atan2(Dy, Dx));
191	in_disk_rgn = floor((in_disk_phi + PI/4)/(PI/2)) + 1;
192	out_square_a = select(in_disk_rgn,
193	in_disk_r,
194	(PI/2 - in_disk_phi)*in_disk_r/(PI/4),
195	-in_disk_r,
196	(in_disk_phi - 3PI/2)in_disk_r/(PI/4));
197	out_square_b = select(in_disk_rgn,
198	in_disk_phi*in_disk_r/(PI/4),
199	in_disk_r,
200	(PI - in_disk_phi)*in_disk_r/(PI/4),
201	-in_disk_r);
202	out_square_x = (out_square_a + 1)/2;
203	out_square_y = (out_square_b + 1)/2;
204	';
205	# Announce ourselves in XML output
206	print "\t<DataDefinition>\n";
207	print "\t\t<IncidentDataStructure>TensorTree$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	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	bg_tree_rtcontrib(1, $proc);
222	}
223	while (wait() >= 0) {
224	die "rtcontrib process reported error" if ( $? );
225	}
226	ttree_out(1);
227	}
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 '$nsfloor(out_square_x$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-($pbeg+\$1+r1)/$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($forw2-1)' " .
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-$forw]' -e 'myDz=Dz($forw2-1)' " .
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	<WavelengthDataDirection>Reflection $side</WavelengthDataDirection>
319	<AngleBasis>LBNL/Shirley-Chiu</AngleBasis>
320	<ScatteringDataType>BRDF</ScatteringDataType>
321	<ScatteringData>
322	';
323	system "rcalc -if3 -e 'Omega:PI/($ns*$ns)' " .
324	q{-e '$1=(0.265$1+0.670$2+0.065*$3)/Omega' -of } .
325	"$td/" . ($fmodnm,$bmodnm)[$forw] . "_???.flt " .
326	"\| rttree_reduce -h -ff -r $tensortree -g $ttlog2";
327	die "Failure running rttree_reduce" if ( $? );
328	print
329	' </ScatteringData>
330	</WavelengthDataBlock>
331	</WavelengthData>
332	';
333	} # end of ttree_out()
334
335	#------------- End of do_tree_bsdf() & subroutines -------------#
336
337	#+++++++++++++++ Klems matrix BSDF generation +++++++++++++++#
338	sub do_matrix_bsdf {
339	# Set up sampling of portal
340	# Kbin to produce incident direction in full Klems basis with (x1,x2) randoms
341	$tcal = '
342	DEGREE : PI/180;
343	sq(x) : x*x;
344	Kpola(r) : select(r+1, -5, 5, 15, 25, 35, 45, 55, 65, 75, 90);
345	Knaz(r) : select(r, 1, 8, 16, 20, 24, 24, 24, 16, 12);
346	Kaccum(r) : if(r-.5, Knaz(r) + Kaccum(r-1), 0);
347	Kmax : Kaccum(Knaz(0));
348	Kfindrow(r, rem) : if(rem-Knaz(r)+.5, Kfindrow(r+1, rem-Knaz(r)), r);
349	Krow = if(Kbin-(Kmax-.5), 0, Kfindrow(1, Kbin));
350	Kcol = Kbin - Kaccum(Krow-1);
351	Kazi = 360DEGREE (Kcol + (.5 - x2)) / Knaz(Krow);
352	Kpol = DEGREE * (x1Kpola(Krow) + (1-x1)Kpola(Krow-1));
353	sin_kpol = sin(Kpol);
354	Dx = cos(Kazi)*sin_kpol;
355	Dy = sin(Kazi)*sin_kpol;
356	Dz = sqrt(1 - sin_kpol*sin_kpol);
357	KprojOmega = PI * if(Kbin-.5,
358	(sq(cos(Kpola(Krow-1)DEGREE)) - sq(cos(Kpola(Krow)DEGREE)))/Knaz(Krow),
359	1 - sq(cos(Kpola(1)*DEGREE)));
360	';
361	# Compute Klems bin from exiting ray direction (forward or backward)
362	$kcal = '
363	DEGREE : PI/180;
364	abs(x) : if(x, x, -x);
365	Acos(x) : 1/DEGREE * if(x-1, 0, if(-1-x, 0, acos(x)));
366	posangle(a) : if(-a, a + 2*PI, a);
367	Atan2(y,x) : 1/DEGREE * posangle(atan2(y,x));
368	kpola(r) : select(r, 5, 15, 25, 35, 45, 55, 65, 75, 90);
369	knaz(r) : select(r, 1, 8, 16, 20, 24, 24, 24, 16, 12);
370	kaccum(r) : if(r-.5, knaz(r) + kaccum(r-1), 0);
371	kfindrow(r, pol) : if(r-kpola(0)+.5, r,
372	if(pol-kpola(r), kfindrow(r+1, pol), r) );
373	kazn(azi,inc) : if((360-.5inc)-azi, floor((azi+.5inc)/inc), 0);
374	kbin2(pol,azi) = select(kfindrow(1, pol),
375	kazn(azi,360/knaz(1)),
376	kaccum(1) + kazn(azi,360/knaz(2)),
377	kaccum(2) + kazn(azi,360/knaz(3)),
378	kaccum(3) + kazn(azi,360/knaz(4)),
379	kaccum(4) + kazn(azi,360/knaz(5)),
380	kaccum(5) + kazn(azi,360/knaz(6)),
381	kaccum(6) + kazn(azi,360/knaz(7)),
382	kaccum(7) + kazn(azi,360/knaz(8)),
383	kaccum(8) + kazn(azi,360/knaz(9))
384	);
385	kbin = kbin2(Acos(abs(Dz)),Atan2(Dy,Dx));
386	';
387	my $ndiv = 145;
388	# Compute scattering data using rtcontrib
389	my @tfarr;
390	my @rfarr;
391	my @tbarr;
392	my @rbarr;
393	my $cmd;
394	my $rtcmd = "rtcontrib $rtargs -h -ff -fo -n $nproc -c $nsamp " .
395	"-e '$kcal' -b kbin -bn $ndiv " .
396	"-o '$td/%s.flt' -m $fmodnm -m $bmodnm $octree";
397	my $rccmd = "rcalc -e '$tcal' " .
398	"-e 'mod(n,d):n-floor(n/d)*d' -e 'Kbin=mod(recno-.999,$ndiv)' " .
399	q{-if3 -e '$1=(0.265$1+0.670$2+0.065*$3)/KprojOmega'};
400	if ( $doforw ) {
401	$cmd = "cnt $ndiv $ny $nx \| rcalc -of -e '$tcal' " .
402	"-e 'xp=(\$3+rand(.12recno+288))(($dim[1]-$dim[0])/$nx)+$dim[0]' " .
403	"-e 'yp=(\$2+rand(.37recno-44))(($dim[3]-$dim[2])/$ny)+$dim[2]' " .
404	"-e 'zp:$dim[4]' " .
405	q{-e 'Kbin=$1;x1=rand(2.75recno+3.1);x2=rand(-2.01recno-3.37)' } .
406	q{-e '$1=xp-Dx;$2=yp-Dy;$3=zp-Dz;$4=Dx;$5=Dy;$6=Dz' } .
407	"\| $rtcmd";
408	system "$cmd" \|\| die "Failure running: $cmd\n";
409	@tfarr = `$rccmd $td/$fmodnm.flt`;
410	die "Failure running: $rccmd $td/$fmodnm.flt\n" if ( $? );
411	@rfarr = `$rccmd $td/$bmodnm.flt`;
412	die "Failure running: $rccmd $td/$bmodnm.flt\n" if ( $? );
413	}
414	if ( $doback ) {
415	$cmd = "cnt $ndiv $ny $nx \| rcalc -of -e '$tcal' " .
416	"-e 'xp=(\$3+rand(.35recno-15))(($dim[1]-$dim[0])/$nx)+$dim[0]' " .
417	"-e 'yp=(\$2+rand(.86recno+11))(($dim[3]-$dim[2])/$ny)+$dim[2]' " .
418	"-e 'zp:$dim[5]' " .
419	q{-e 'Kbin=$1;x1=rand(1.21recno+2.75);x2=rand(-3.55recno-7.57)' } .
420	q{-e '$1=xp-Dx;$2=yp-Dy;$3=zp+Dz;$4=Dx;$5=Dy;$6=-Dz' } .
421	"\| $rtcmd";
422	system "$cmd" \|\| die "Failure running: $cmd\n";
423	@tbarr = `$rccmd $td/$bmodnm.flt`;
424	die "Failure running: $rccmd $td/$bmodnm.flt\n" if ( $? );
425	@rbarr = `$rccmd $td/$fmodnm.flt`;
426	die "Failure running: $rccmd $td/$fmodnm.flt\n" if ( $? );
427	}
428	# Output angle basis
429	print
430	' <DataDefinition>
431	<IncidentDataStructure>Columns</IncidentDataStructure>
432	<AngleBasis>
433	<AngleBasisName>LBNL/Klems Full</AngleBasisName>
434	<AngleBasisBlock>
435	<Theta>0</Theta>
436	<nPhis>1</nPhis>
437	<ThetaBounds>
438	<LowerTheta>0</LowerTheta>
439	<UpperTheta>5</UpperTheta>
440	</ThetaBounds>
441	</AngleBasisBlock>
442	<AngleBasisBlock>
443	<Theta>10</Theta>
444	<nPhis>8</nPhis>
445	<ThetaBounds>
446	<LowerTheta>5</LowerTheta>
447	<UpperTheta>15</UpperTheta>
448	</ThetaBounds>
449	</AngleBasisBlock>
450	<AngleBasisBlock>
451	<Theta>20</Theta>
452	<nPhis>16</nPhis>
453	<ThetaBounds>
454	<LowerTheta>15</LowerTheta>
455	<UpperTheta>25</UpperTheta>
456	</ThetaBounds>
457	</AngleBasisBlock>
458	<AngleBasisBlock>
459	<Theta>30</Theta>
460	<nPhis>20</nPhis>
461	<ThetaBounds>
462	<LowerTheta>25</LowerTheta>
463	<UpperTheta>35</UpperTheta>
464	</ThetaBounds>
465	</AngleBasisBlock>
466	<AngleBasisBlock>
467	<Theta>40</Theta>
468	<nPhis>24</nPhis>
469	<ThetaBounds>
470	<LowerTheta>35</LowerTheta>
471	<UpperTheta>45</UpperTheta>
472	</ThetaBounds>
473	</AngleBasisBlock>
474	<AngleBasisBlock>
475	<Theta>50</Theta>
476	<nPhis>24</nPhis>
477	<ThetaBounds>
478	<LowerTheta>45</LowerTheta>
479	<UpperTheta>55</UpperTheta>
480	</ThetaBounds>
481	</AngleBasisBlock>
482	<AngleBasisBlock>
483	<Theta>60</Theta>
484	<nPhis>24</nPhis>
485	<ThetaBounds>
486	<LowerTheta>55</LowerTheta>
487	<UpperTheta>65</UpperTheta>
488	</ThetaBounds>
489	</AngleBasisBlock>
490	<AngleBasisBlock>
491	<Theta>70</Theta>
492	<nPhis>16</nPhis>
493	<ThetaBounds>
494	<LowerTheta>65</LowerTheta>
495	<UpperTheta>75</UpperTheta>
496	</ThetaBounds>
497	</AngleBasisBlock>
498	<AngleBasisBlock>
499	<Theta>82.5</Theta>
500	<nPhis>12</nPhis>
501	<ThetaBounds>
502	<LowerTheta>75</LowerTheta>
503	<UpperTheta>90</UpperTheta>
504	</ThetaBounds>
505	</AngleBasisBlock>
506	</AngleBasis>
507	</DataDefinition>
508	';
509	if ( $doforw ) {
510	print
511	' <WavelengthData>
512	<LayerNumber>System</LayerNumber>
513	<Wavelength unit="Integral">Visible</Wavelength>
514	<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
515	<DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
516	<WavelengthDataBlock>
517	<WavelengthDataDirection>Transmission Front</WavelengthDataDirection>
518	<ColumnAngleBasis>LBNL/Klems Full</ColumnAngleBasis>
519	<RowAngleBasis>LBNL/Klems Full</RowAngleBasis>
520	<ScatteringDataType>BTDF</ScatteringDataType>
521	<ScatteringData>
522	';
523	# Output front transmission (transposed order)
524	for (my $od = 0; $od < $ndiv; $od++) {
525	for (my $id = 0; $id < $ndiv; $id++) {
526	print $tfarr[$ndiv*$id + $od];
527	}
528	print "\n";
529	}
530	print
531	' </ScatteringData>
532	</WavelengthDataBlock>
533	</WavelengthData>
534	<WavelengthData>
535	<LayerNumber>System</LayerNumber>
536	<Wavelength unit="Integral">Visible</Wavelength>
537	<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
538	<DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
539	<WavelengthDataBlock>
540	<WavelengthDataDirection>Reflection Front</WavelengthDataDirection>
541	<ColumnAngleBasis>LBNL/Klems Full</ColumnAngleBasis>
542	<RowAngleBasis>LBNL/Klems Full</RowAngleBasis>
543	<ScatteringDataType>BRDF</ScatteringDataType>
544	<ScatteringData>
545	';
546	# Output front reflection (transposed order)
547	for (my $od = 0; $od < $ndiv; $od++) {
548	for (my $id = 0; $id < $ndiv; $id++) {
549	print $rfarr[$ndiv*$id + $od];
550	}
551	print "\n";
552	}
553	print
554	' </ScatteringData>
555	</WavelengthDataBlock>
556	</WavelengthData>
557	';
558	}
559	if ( $doback ) {
560	print
561	' <WavelengthData>
562	<LayerNumber>System</LayerNumber>
563	<Wavelength unit="Integral">Visible</Wavelength>
564	<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
565	<DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
566	<WavelengthDataBlock>
567	<WavelengthDataDirection>Transmission Back</WavelengthDataDirection>
568	<ColumnAngleBasis>LBNL/Klems Full</ColumnAngleBasis>
569	<RowAngleBasis>LBNL/Klems Full</RowAngleBasis>
570	<ScatteringDataType>BTDF</ScatteringDataType>
571	<ScatteringData>
572	';
573	# Output back transmission (transposed order)
574	for (my $od = 0; $od < $ndiv; $od++) {
575	for (my $id = 0; $id < $ndiv; $id++) {
576	print $tbarr[$ndiv*$id + $od];
577	}
578	print "\n";
579	}
580	print
581	' </ScatteringData>
582	</WavelengthDataBlock>
583	</WavelengthData>
584	<WavelengthData>
585	<LayerNumber>System</LayerNumber>
586	<Wavelength unit="Integral">Visible</Wavelength>
587	<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>
588	<DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>
589	<WavelengthDataBlock>
590	<WavelengthDataDirection>Reflection Back</WavelengthDataDirection>
591	<ColumnAngleBasis>LBNL/Klems Full</ColumnAngleBasis>
592	<RowAngleBasis>LBNL/Klems Full</RowAngleBasis>
593	<ScatteringDataType>BRDF</ScatteringDataType>
594	<ScatteringData>
595	';
596	# Output back reflection (transposed order)
597	for (my $od = 0; $od < $ndiv; $od++) {
598	for (my $id = 0; $id < $ndiv; $id++) {
599	print $rbarr[$ndiv*$id + $od];
600	}
601	print "\n";
602	}
603	print
604	' </ScatteringData>
605	</WavelengthDataBlock>
606	</WavelengthData>
607	';
608	}
609	}
610	#------------- End of do_matrix_bsdf() --------------#