src/util/genskyvec.pl

#!/usr/bin/perl -w
# RCSid $Id: genskyvec.pl,v 2.3 2009/12/09 21:30:48 greg Exp $
#
# Generate Reinhart vector for a given sky description
#
#       G. Ward
#
use strict;
my @skycolor = (0.960, 1.004, 1.118);
my $mf = 4;
while ($#ARGV >= 0) {
        if ("$ARGV[0]" eq "-c") {
                @skycolor = @ARGV[1..3];
                shift @ARGV; shift @ARGV; shift @ARGV;
        } elsif ("$ARGV[0]" eq "-m") {
                $mf = $ARGV[1];
                shift @ARGV;
        }
        shift @ARGV;
}
# Load sky description into line array, separating sun if one
my @skydesc;
my $lightline;
my @sunval;
my $sunline;
my $skyOK = 0;
my $srcmod;     # putting this inside loop breaks code(?!)
while (<>) {
        push @skydesc, $_;
        if (/^\w+\s+light\s+/) {
                s/\s*$//; s/^.*\s//;
                $srcmod = $_;
                $lightline = $#skydesc;
        } elsif (defined($srcmod) && /^($srcmod)\s+source\s/) {
                @sunval = split(/\s+/, $skydesc[$lightline + 3]);
                shift @sunval;
                $sunline = $#skydesc;
        } elsif (/\sskyfunc\s*$/) {
                $skyOK = 1;
        }
}
die "Bad sky description!\n" if (! $skyOK);
# Strip out the solar source if present
my @sundir;
if (defined $sunline) {
        @sundir = split(/\s+/, $skydesc[$sunline + 3]);
        shift @sundir;
        undef @sundir if ($sundir[2] <= 0);
        splice(@skydesc, $sunline, 5);
}
# Reinhart sky sample generator
my $rhcal = '
DEGREE : PI/180;
x1 = .5; x2 = .5;
alpha : 90/(MF*7 + .5);
tnaz(r) : select(r, 30, 30, 24, 24, 18, 12, 6);
rnaz(r) : if(r-(7*MF-.5), 1, MF*tnaz(floor((r+.5)/MF) + 1));
raccum(r) : if(r-.5, rnaz(r-1) + raccum(r-1), 0);
RowMax : 7*MF + 1;
Rmax : raccum(RowMax);
Rfindrow(r, rem) : if(rem-rnaz(r)-.5, Rfindrow(r+1, rem-rnaz(r)), r);
Rrow = if(Rbin-(Rmax-.5), RowMax-1, Rfindrow(0, Rbin));
Rcol = Rbin - raccum(Rrow) - 1;
Razi_width = 2*PI / rnaz(Rrow);
RAH : alpha*DEGREE;
Razi = if(Rbin-.5, (Rcol + x2 - .5)*Razi_width, 2*PI*x2);
Ralt = if(Rbin-.5, (Rrow + x1)*RAH, asin(-x1));
Romega = if(.5-Rbin, 2*PI, if(Rmax-.5-Rbin, 
        Razi_width*(sin(RAH*(Rrow+1)) - sin(RAH*Rrow)),
        2*PI*(1 - cos(RAH/2)) ) );
cos_ralt = cos(Ralt);
Dx = sin(Razi)*cos_ralt;
Dy = cos(Razi)*cos_ralt;
Dz = sin(Ralt);
';
my $nbins = `rcalc -n -e MF:$mf -e \'$rhcal\' -e \'\$1=Rmax+1\'`;
chomp $nbins;
# Create octree for rtrace
my $octree = "/tmp/gtv$$.oct";
open OCONV, "| oconv - > $octree";
print OCONV @skydesc;
print OCONV "skyfunc glow skyglow 0 0 4 @skycolor 0\n";
print OCONV "skyglow source sky 0 0 4 0 0 1 360\n";
close OCONV;
# Run rtrace and average output for every 16 samples
my $tregcommand = "cnt $nbins 16 | rcalc -of -e MF:$mf -e '$rhcal' " .
        q{-e 'Rbin=$1;x1=rand(recno*.37-5.3);x2=rand(recno*-1.47+.86)' } .
        q{-e '$1=0;$2=0;$3=0;$4=Dx;$5=Dy;$6=Dz' } .
        "| rtrace -h -ff -ab 0 -w $octree | total -if3 -16 -m";
my @tregval = `$tregcommand`;
unlink $octree;
# Find closest 3 patches to sun and divvy up direct solar contribution
my @bestdir;
if (@sundir) {
        my $somega = ($sundir[3]/360)**2 * 3.141592654**3;
        my $cmd = "cnt " . ($nbins-1) .
                " | rcalc -e MF:$mf -e '$rhcal' -e Rbin=recno " .
                "-e 'dot=Dx*$sundir[0] + Dy*$sundir[1] + Dz*$sundir[2]' " .
                "-e 'cond=dot-.866' " .
                q{-e '$1=if(1-dot,acos(dot),0);$2=Romega;$3=recno' };
        @bestdir = `$cmd | sort -n | head -3`;
        my (@ang, @dom, @ndx);
        my $wtot = 0;
        for my $i (0..2) {
                ($ang[$i], $dom[$i], $ndx[$i]) = split(/\s+/, $bestdir[$i]);
                $wtot += 1./($ang[$i]+.02);
        }
        for my $i (0..2) {
                my $wt = 1./($ang[$i]+.02)/$wtot * $somega / $dom[$i];
                my @scolor = split(/\s+/, $tregval[$ndx[$i]]);
                for my $j (0..2) { $scolor[$j] += $wt * $sunval[$j]; }
                $tregval[$ndx[$i]] = "$scolor[0]\t$scolor[1]\t$scolor[2]\n";
        }
}
# Output our final vector
print @tregval;
Revision:	2.4
Committed:	Sat Jan 23 22:30:29 2010 UTC (14 years, 9 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad4R0
Changes since 2.3:	+2 -2 lines
Log Message:	Made it so solar lines use same separator (tabs)
#	User	Rev	Content
1	greg	2.1	#!/usr/bin/perl -w
2	greg	2.4	# RCSid $Id: genskyvec.pl,v 2.3 2009/12/09 21:30:48 greg Exp $
3	greg	2.1	#
4			# Generate Reinhart vector for a given sky description
5			#
6			# G. Ward
7			#
8			use strict;
9			my @skycolor = (0.960, 1.004, 1.118);
10	greg	2.3	my $mf = 4;
11	greg	2.1	while ($#ARGV >= 0) {
12			if ("$ARGV[0]" eq "-c") {
13			@skycolor = @ARGV[1..3];
14			shift @ARGV; shift @ARGV; shift @ARGV;
15	greg	2.3	} elsif ("$ARGV[0]" eq "-m") {
16			$mf = $ARGV[1];
17			shift @ARGV;
18	greg	2.1	}
19			shift @ARGV;
20			}
21			# Load sky description into line array, separating sun if one
22			my @skydesc;
23			my $lightline;
24			my @sunval;
25			my $sunline;
26			my $skyOK = 0;
27			my $srcmod; # putting this inside loop breaks code(?!)
28			while (<>) {
29			push @skydesc, $_;
30			if (/^\w+\s+light\s+/) {
31			s/\s$//; s/^.\s//;
32			$srcmod = $_;
33			$lightline = $#skydesc;
34			} elsif (defined($srcmod) && /^($srcmod)\s+source\s/) {
35			@sunval = split(/\s+/, $skydesc[$lightline + 3]);
36			shift @sunval;
37			$sunline = $#skydesc;
38			} elsif (/\sskyfunc\s*$/) {
39			$skyOK = 1;
40			}
41			}
42			die "Bad sky description!\n" if (! $skyOK);
43			# Strip out the solar source if present
44			my @sundir;
45			if (defined $sunline) {
46			@sundir = split(/\s+/, $skydesc[$sunline + 3]);
47			shift @sundir;
48			undef @sundir if ($sundir[2] <= 0);
49			splice(@skydesc, $sunline, 5);
50			}
51			# Reinhart sky sample generator
52			my $rhcal = '
53			DEGREE : PI/180;
54			x1 = .5; x2 = .5;
55			alpha : 90/(MF*7 + .5);
56			tnaz(r) : select(r, 30, 30, 24, 24, 18, 12, 6);
57			rnaz(r) : if(r-(7MF-.5), 1, MFtnaz(floor((r+.5)/MF) + 1));
58			raccum(r) : if(r-.5, rnaz(r-1) + raccum(r-1), 0);
59			RowMax : 7*MF + 1;
60			Rmax : raccum(RowMax);
61			Rfindrow(r, rem) : if(rem-rnaz(r)-.5, Rfindrow(r+1, rem-rnaz(r)), r);
62	greg	2.2	Rrow = if(Rbin-(Rmax-.5), RowMax-1, Rfindrow(0, Rbin));
63	greg	2.1	Rcol = Rbin - raccum(Rrow) - 1;
64			Razi_width = 2*PI / rnaz(Rrow);
65			RAH : alpha*DEGREE;
66			Razi = if(Rbin-.5, (Rcol + x2 - .5)Razi_width, 2PI*x2);
67	greg	2.2	Ralt = if(Rbin-.5, (Rrow + x1)*RAH, asin(-x1));
68	greg	2.1	Romega = if(.5-Rbin, 2*PI, if(Rmax-.5-Rbin,
69			Razi_width(sin(RAH(Rrow+1)) - sin(RAH*Rrow)),
70			2PI(1 - cos(RAH/2)) ) );
71			cos_ralt = cos(Ralt);
72			Dx = sin(Razi)*cos_ralt;
73			Dy = cos(Razi)*cos_ralt;
74			Dz = sin(Ralt);
75			';
76	greg	2.3	my $nbins = `rcalc -n -e MF:$mf -e \'$rhcal\' -e \'\$1=Rmax+1\'`;
77			chomp $nbins;
78	greg	2.1	# Create octree for rtrace
79			my $octree = "/tmp/gtv$$.oct";
80			open OCONV, "\| oconv - > $octree";
81			print OCONV @skydesc;
82			print OCONV "skyfunc glow skyglow 0 0 4 @skycolor 0\n";
83			print OCONV "skyglow source sky 0 0 4 0 0 1 360\n";
84			close OCONV;
85			# Run rtrace and average output for every 16 samples
86	greg	2.3	my $tregcommand = "cnt $nbins 16 \| rcalc -of -e MF:$mf -e '$rhcal' " .
87	greg	2.1	q{-e 'Rbin=$1;x1=rand(recno.37-5.3);x2=rand(recno-1.47+.86)' } .
88			q{-e '$1=0;$2=0;$3=0;$4=Dx;$5=Dy;$6=Dz' } .
89			"\| rtrace -h -ff -ab 0 -w $octree \| total -if3 -16 -m";
90			my @tregval = `$tregcommand`;
91			unlink $octree;
92			# Find closest 3 patches to sun and divvy up direct solar contribution
93			my @bestdir;
94			if (@sundir) {
95			my $somega = ($sundir[3]/360)*2 3.141592654**3;
96	greg	2.2	my $cmd = "cnt " . ($nbins-1) .
97	greg	2.3	" \| rcalc -e MF:$mf -e '$rhcal' -e Rbin=recno " .
98	greg	2.1	"-e 'dot=Dx$sundir[0] + Dy$sundir[1] + Dz*$sundir[2]' " .
99			"-e 'cond=dot-.866' " .
100			q{-e '$1=if(1-dot,acos(dot),0);$2=Romega;$3=recno' };
101			@bestdir = `$cmd \| sort -n \| head -3`;
102			my (@ang, @dom, @ndx);
103			my $wtot = 0;
104			for my $i (0..2) {
105			($ang[$i], $dom[$i], $ndx[$i]) = split(/\s+/, $bestdir[$i]);
106			$wtot += 1./($ang[$i]+.02);
107			}
108			for my $i (0..2) {
109			my $wt = 1./($ang[$i]+.02)/$wtot * $somega / $dom[$i];
110			my @scolor = split(/\s+/, $tregval[$ndx[$i]]);
111			for my $j (0..2) { $scolor[$j] += $wt * $sunval[$j]; }
112	greg	2.4	$tregval[$ndx[$i]] = "$scolor[0]\t$scolor[1]\t$scolor[2]\n";
113	greg	2.1	}
114			}
115			# Output our final vector
116			print @tregval;