371 lines
9.4 KiB
Perl
Executable file
371 lines
9.4 KiB
Perl
Executable file
#!/usr/bin/perl
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#---------------------------------------------------------------------------
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# Toplevel script to automate DEM file processing and conversion
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#
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# Written by Curtis Olson, started January 1998.
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#
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# Copyright (C) 1997 Curtis L. Olson - curt@infoplane.com
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#
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# This program is free software; you can redistribute it and/or modify
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# it under the terms of the GNU General Public License as published by
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# the Free Software Foundation; either version 2 of the License, or
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# (at your option) any later version.
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#
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# This program is distributed in the hope that it will be useful,
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# but WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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# GNU General Public License for more details.
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#
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# You should have received a copy of the GNU General Public License
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# along with this program; if not, write to the Free Software
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# Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
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#
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# $Id$
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# (Log is kept at end of this file)
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#---------------------------------------------------------------------------
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$| = 1; # flush buffers after every write
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$do_demfit = 1;
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$do_triangle_1 = 1;
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$do_fixnode = 1;
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$do_splittris = 1;
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$do_assemtris = 1;
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$do_triangle_2 = 1;
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$do_tri2obj = 1;
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$do_strips = 1;
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$do_fixobj = 1;
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# return the file name root (ending at last ".")
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sub file_root {
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my($file) = @_;
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my($pos);
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$pos = rindex($file, ".");
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return substr($file, 0, $pos);
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}
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# set the FG_ROOT environment variable if it hasn't already been set.
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if ( $ENV{FG_ROOT} eq "" ) {
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# look for a file called fgtop as a place marker
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if ( -e "fgtop" ) {
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$ENV{FG_ROOT} = ".";
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} elsif ( -e "../fgtop" ) {
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$ENV{FG_ROOT} = "..";
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}
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}
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# 1. Start with file.dem
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$dem_file = shift(@ARGV);
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$error = shift(@ARGV);
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$error += 0.0;
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print "Source file = $dem_file Error tolerance = $error\n";
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if ( $error < 0.5 ) {
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die "I doubt you'll be happy with an error tolerance as low as $error.\n";
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}
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# 2. dem2node $FG_ROOT dem_file tolerance^2 (meters)
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#
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# - dem2node .. dem_file 160000
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#
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# splits dem file into 64 file.node's which contain the
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# irregularly fitted vertices
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if ( $do_demfit ) {
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if ( $dem_file =~ m/.gz$/ ) {
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$command = "gzip -dc $dem_file | ./Dem2node/demfit $ENV{FG_ROOT} - $error";
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} else {
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$command = "./Dem2node/demfit $ENV{FG_ROOT} $dem_file $error";
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}
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print "Running '$command'\n";
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open(OUT, "$command |");
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while ( <OUT> ) {
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print $_;
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if ( m/^Dir = / ) {
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$subdir = $_;
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$subdir =~ s/^Dir = //;
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chop($subdir);
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}
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}
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close(OUT);
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} else {
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$subdir = "../Scenery/w100n040/w093n045";
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print "WARNING: Hardcoding subdir = $subdir\n";
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}
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# 3. triangle -q file (Takes file.node and produces file.1.node and
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# file.1.ele)
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print "Subdirectory for this dem file is $subdir\n";
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if ( $do_triangle_1 ) {
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@FILES = `ls $subdir`;
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foreach $file ( @FILES ) {
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print $file;
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chop($file);
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if ( ($file =~ m/\.node$/) && ($file !~ m/\.\d\.node$/) ) {
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$command = "./Triangle/triangle -q $subdir/$file";
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print "Running '$command'\n";
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open(OUT, "$command |");
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while ( <OUT> ) {
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print $_;
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}
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close(OUT);
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# remove input file.node
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unlink("$subdir/$file");
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}
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}
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}
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# 4. fixnode file.dem subdir
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#
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# Take the original .dem file (for interpolating Z values) and the
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# subdirecotry containing all the file.1.node's and replace with
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# fixed file.1.node
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if ( $do_fixnode ) {
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if ( $dem_file =~ m/.gz$/ ) {
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$command = "gzip -dc $dem_file | ./FixNode/fixnode - $subdir";
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} else {
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$command = "./FixNode/fixnode $dem_file $subdir";
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}
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print "Running '$command'\n";
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open(OUT, "$command |");
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while ( <OUT> ) {
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print $_;
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}
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close(OUT);
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}
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# 4.1 splittris file (.1.node) (.1.ele)
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# Extract the corner, edge, and body vertices (in original
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# geodetic coordinates) and normals (in cartesian coordinates) and
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# save them in something very close to the .obj format as file.se,
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# file.sw, file.nw, file.ne, file.north, file.south, file.east,
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# file.west, and file.body. This way we can reconstruct the
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# region using consistant edges and corners.
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# Arbitration rules: If an opposite edge file already exists,
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# don't create our matching edge. If a corner already exists,
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# don't create ours. Basically, the early bird gets the worm and
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# gets to define the edge verticies and normals. All the other
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# adjacent tiles must use these.
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if ( $do_splittris ) {
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@FILES = `ls $subdir`;
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foreach $file ( @FILES ) {
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chop($file);
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if ( $file =~ m/\.1\.node$/ ) {
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$file =~ s/\.node$//; # strip off the ".node"
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$command = "./SplitTris/splittris $subdir/$file";
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print "Running '$command'\n";
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open(OUT, "$command |");
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while ( <OUT> ) {
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print $_;
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}
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close(OUT);
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unlink("$subdir/$file.node");
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unlink("$subdir/$file.node.orig");
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unlink("$subdir/$file.ele");
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}
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}
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}
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# 4.2 read in the split of version of the tiles, reconstruct the tile
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# using the proper shared corners and edges. Save as a node file
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# so we can retriangulate.
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if ( $do_assemtris ) {
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@FILES = `ls $subdir`;
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foreach $file ( @FILES ) {
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chop($file);
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if ( $file =~ m/\.1\.body$/ ) {
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$file =~ s/\.body$//; # strip off the ".body"
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$command = "./AssemTris/assemtris $subdir/$file";
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print "Running '$command'\n";
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open(OUT, "$command |");
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while ( <OUT> ) {
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print $_;
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}
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close(OUT);
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}
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unlink("$subdir/$file.body");
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}
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}
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# 4.3 Retriangulate reassembled files (without -q option) so no new
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# nodes are generated.
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if ( $do_triangle_2 ) {
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@FILES = `ls $subdir`;
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foreach $file ( @FILES ) {
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print $file;
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chop($file);
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if ( ($file =~ m/\.node$/) && ($file !~ m/\.\d\.node$/) ) {
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$command = "./Triangle/triangle $subdir/$file";
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print "Running '$command'\n";
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open(OUT, "$command |");
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while ( <OUT> ) {
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print $_;
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}
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close(OUT);
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# remove input file.node
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unlink("$subdir/$file");
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}
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}
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}
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# 5. tri2obj file (.1.node) (.1.ele)
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#
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# Take the file.1.node and file.1.ele and produce file.1.obj
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#
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# Extracts normals out of the shared edge/vertex files, and uses
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# the precalcuated normals for these nodes instead of calculating
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# new ones. By sharing normals as well as vertices, not only are
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# the gaps between tiles eliminated, but the colors and lighting
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# transition smoothly across tile boundaries.
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if ( $do_tri2obj ) {
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@FILES = `ls $subdir`;
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foreach $file ( @FILES ) {
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chop($file);
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if ( $file =~ m/\.1\.node$/ ) {
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$file =~ s/\.node$//; # strip off the ".node"
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$command = "./Tri2obj/tri2obj $subdir/$file";
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print "Running '$command'\n";
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open(OUT, "$command |");
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while ( <OUT> ) {
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print $_;
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}
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close(OUT);
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unlink("$subdir/$file.node");
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unlink("$subdir/$file.node.orig");
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unlink("$subdir/$file.ele");
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}
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}
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}
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# 6. strip file.1.obj
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#
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# Strip the file.1.obj's. Note, strips doesn't handle the minimal
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# case of striping a square correctly.
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#
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# 7. cp bands.d file.2.obj
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#
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# strips produces a file called "bands.d" ... copy this to file.2.obj
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if ( $do_strips ) {
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@FILES = `ls $subdir`;
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foreach $file ( @FILES ) {
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chop($file);
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if ( $file =~ m/\.1\.obj$/ ) {
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$command = "./Stripe_u/strips $subdir/$file";
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print "Running '$command'\n";
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open(OUT, "$command |");
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while ( <OUT> ) {
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print $_;
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}
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close(OUT);
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# copy to destination file
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$newfile = $file;
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$newfile =~ s/\.1\.obj$//;
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print "Copying to $subdir/$newfile.2.obj\n";
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open(IN, "<bands.d");
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open(OUT, ">$subdir/$newfile.2.obj");
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while ( <IN> ) {
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print OUT $_;
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}
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close(IN);
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close(OUT);
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unlink("$subdir/$file");
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}
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}
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}
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# 8. fixobj file-new
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#
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# Sort file.2.obj by strip winding
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if ( $do_fixobj ) {
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@FILES = `ls $subdir`;
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foreach $file ( @FILES ) {
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chop($file);
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if ( $file =~ m/\.2\.obj$/ ) {
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$newfile = $file;
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$newfile =~ s/\.2\.obj$/.obj/;
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$command = "./FixObj/fixobj $subdir/$file $subdir/$newfile";
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print "Running '$command'\n";
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open(OUT, "$command |");
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while ( <OUT> ) {
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print $_;
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}
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close(OUT);
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unlink("$subdir/$file");
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}
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}
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}
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#---------------------------------------------------------------------------
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# $Log$
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# Revision 1.10 1998/02/01 03:42:26 curt
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# Modifications to handle compressed dem files.
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#
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# Revision 1.9 1998/01/27 18:36:54 curt
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# Lots of updates to get back in sync with changes made over in .../Src/
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#
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# Revision 1.8 1998/01/21 17:59:05 curt
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# Uncomment lines to remove several intermediate files.
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#
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# Revision 1.7 1998/01/19 19:51:06 curt
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# A couple final pre-release tweaks.
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#
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# Revision 1.6 1998/01/15 21:33:33 curt
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# Assembling triangles and building a new .node file with the proper shared
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# vertices now works. Now we just have to use the shared normals and we'll
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# be all set.
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#
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# Revision 1.5 1998/01/15 02:50:08 curt
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# Tweaked to add next stage.
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#
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# Revision 1.4 1998/01/14 15:55:34 curt
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# Finished splittris, started assemtris.
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#
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# Revision 1.3 1998/01/14 02:15:52 curt
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# Updated front end script to keep plugging away on tile fitting.
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#
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# Revision 1.2 1998/01/12 20:42:08 curt
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# Working on fitting tiles together in a seamless manner.
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#
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# Revision 1.1 1998/01/09 23:06:46 curt
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# Initial revision.
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#
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