src/px/normpat.csh

#!/bin/csh -f
# SCCSid "$SunId$ LBL"
#
# Normalize a pattern for tiling (-b option blends edges) by removing
# lowest frequencies from image and reducing to standard size (-r option)
#
set pf="pfilt -e 2"
while ($#argv > 0)
        switch ($argv[1])
        case -r:
                shift argv
                set pf="$pf -x $argv[1] -y $argv[1] -p 1"
                breaksw
        case -b:
                set blend
                breaksw
        case -v:
                set verb
                breaksw
        case -*:
                echo bad option $argv[1]
                exit 1
        default:
                goto dofiles
        endsw
        shift argv
end
dofiles:
onintr quit
set td=/usr/tmp/np$$
mkdir $td
set ha=$0
set ha=$ha:t
if ( $?blend ) then
        set ha="$ha -b"
else
        mknod $td/hf p
endif
cat > $td/coef.fmt << '_EOF_'
  rcx=${   $1   };   rcy=${   $2   };   rsx=${   $3   };   rsy=${   $4   };
rcxcy=${   $5   }; rcxsy=${   $6   }; rsxcy=${   $7   }; rsxsy=${   $8   };
  gcx=${   $9   };   gcy=${  $10   };   gsx=${  $11   };   gsy=${  $12   };
gcxcy=${  $13   }; gcxsy=${  $14   }; gsxcy=${  $15   }; gsxsy=${  $16   };
  bcx=${  $17   };   bcy=${  $18   };   bsx=${  $19   };   bsy=${  $20   };
bcxcy=${  $21   }; bcxsy=${  $22   }; bsxcy=${  $23   }; bsxsy=${  $24   };
'_EOF_'
cat > $td/coef.cal << '_EOF_'
$1=$3*2*cx; $2=$3*2*cy; $3=$3*2*sx; $4=$3*2*sy;
$5=$3*4*cx*cy; $6=$3*4*cx*sy; $7=$3*4*sx*cy; $8=$3*4*sx*sy;
$9=$4*2*cx; $10=$4*2*cy; $11=$4*2*sx; $12=$4*2*sy;
$13=$4*4*cx*cy; $14=$4*4*cx*sy; $15=$4*4*sx*cy; $16=$4*4*sx*sy;
$17=$5*2*cx; $18=$5*2*cy; $19=$5*2*sx; $20=$5*2*sy;
$21=$5*4*cx*cy; $22=$5*4*cx*sy; $23=$5*4*sx*cy; $24=$5*4*sx*sy;
cx=cos(wx); cy=cos(wy);
sx=sin(wx); sy=sin(wy);
wx=2*PI*($1+.5)/xres; wy=2*PI*($2+.5)/yres;
'_EOF_'
cat > $td/fsub.cal << '_EOF_'
ro=ri(1)-rcx*cx-rcy*cy-rsx*sx-rsy*sy
        -rcxcy*cx*cy-rcxsy*cx*sy-rsxcy*sx*cy-rsxsy*sx*sy;
go=gi(1)-gcx*cx-gcy*cy-gsx*sx-gsy*sy
        -gcxcy*cx*cy-gcxsy*cx*sy-gsxcy*sx*cy-gsxsy*sx*sy;
bo=bi(1)-bcx*cx-bcy*cy-bsx*sx-bsy*sy
        -bcxcy*cx*cy-bcxsy*cx*sy-bsxcy*sx*cy-bsxsy*sx*sy;
cx=cos(wx); cy=cos(wy);
sx=sin(wx); sy=sin(wy);
wx=2*PI*(x+.5)/xres; wy=2*PI*(y+.5)/yres;
PI=3.14159265358979323846;
'_EOF_'
foreach f ($*)
        if ( $?verb ) then
                echo $f\:
                echo adjusting exposure/size...
        endif
        $pf $f > $td/pf
        getinfo < $td/pf > $f
        ed - $f << _EOF_
i
$ha
.
w
q
_EOF_
        set resolu=`getinfo -d < $td/pf | sed 's/-Y \([0-9]*\) +X \([0-9]*\)/\2 \1/'`
        if ( $?verb ) then
                echo computing Fourier coefficients...
        endif
        pfilt -1 -x 32 -y 32 $td/pf | pvalue -h \
                | rcalc -f $td/coef.cal -e 'xres=32;yres=32' \
                | total -m | rcalc -o $td/coef.fmt \
                > $td/coef
        if ( $?verb ) then
                cat $td/coef
                echo removing low frequencies...
        endif
        if ( ! $?blend ) then
                ( getinfo - < $td/hf >> $f & ) > /dev/null
        endif
        pcomb -f $td/fsub.cal -f $td/coef \
                -e "xres=$resolu[1];yres=$resolu[2]" \
                $td/pf > $td/hf
        if ( $?blend ) then
                if ( $?verb ) then
                        echo blending edges...
                endif
                @ mar= $resolu[1] - 3
                pcompos -x 3 $td/hf 0 0 > $td/left
                pcompos $td/hf -$mar 0 > $td/right
                pcomb -e 'ro=f(ri);go=f(gi);bo=f(bi)' \
                        -e 'f(p)=(3-x)/7*p(1)+(4+x)/7*p(2)' \
                        $td/right $td/left > $td/left.patch
                pcomb -e 'ro=f(ri);go=f(gi);bo=f(bi)' \
                        -e 'f(p)=(1+x)/7*p(1)+(6-x)/7*p(2)' \
                        $td/left $td/right > $td/right.patch
                pcompos $td/hf 0 0 $td/left.patch 0 0 $td/right.patch $mar 0 \
                        > $td/hflr
                @ mar= $resolu[2] - 3
                pcompos -y 3 $td/hflr 0 0 > $td/bottom
                pcompos $td/hflr 0 -$mar > $td/top
                pcomb -e 'ro=f(ri);go=f(gi);bo=f(bi)' \
                        -e 'f(p)=(3-y)/7*p(1)+(4+y)/7*p(2)' \
                        $td/top $td/bottom > $td/bottom.patch
                pcomb -e 'ro=f(ri);go=f(gi);bo=f(bi)' \
                        -e 'f(p)=(1+y)/7*p(1)+(6-y)/7*p(2)' \
                        $td/bottom $td/top > $td/top.patch
                pcompos $td/hflr 0 0 $td/bottom.patch 0 0 $td/top.patch 0 $mar \
                        | getinfo - >> $f
        endif
        if ( $?verb ) then
                echo $f done.
        endif
end
quit:
rm -rf $td
Revision:	1.4
Committed:	Fri Jan 4 23:01:51 1991 UTC (33 years, 4 months ago) by greg
Content type:	application/x-csh
Branch:	MAIN
Changes since 1.3:	+38 -12 lines
Log Message:	changed to Fourier analysis on each primary color
#	User	Rev	Content
1	greg	1.1	#!/bin/csh -f
2			# SCCSid "$SunId$ LBL"
3			#
4	greg	1.2	# Normalize a pattern for tiling (-b option blends edges) by removing
5			# lowest frequencies from image and reducing to standard size (-r option)
6	greg	1.1	#
7	greg	1.2	set pf="pfilt -e 2"
8			while ($#argv > 0)
9			switch ($argv[1])
10			case -r:
11			shift argv
12			set pf="$pf -x $argv[1] -y $argv[1] -p 1"
13			breaksw
14			case -b:
15			set blend
16			breaksw
17	greg	1.3	case -v:
18			set verb
19			breaksw
20	greg	1.2	case -*:
21			echo bad option $argv[1]
22			exit 1
23			default:
24			goto dofiles
25			endsw
26			shift argv
27			end
28			dofiles:
29			onintr quit
30			set td=/usr/tmp/np$$
31			mkdir $td
32			set ha=$0
33			set ha=$ha:t
34			if ( $?blend ) then
35			set ha="$ha -b"
36			else
37			mknod $td/hf p
38			endif
39	greg	1.4	cat > $td/coef.fmt << '_EOF_'
40			rcx=${ $1 }; rcy=${ $2 }; rsx=${ $3 }; rsy=${ $4 };
41			rcxcy=${ $5 }; rcxsy=${ $6 }; rsxcy=${ $7 }; rsxsy=${ $8 };
42			gcx=${ $9 }; gcy=${ $10 }; gsx=${ $11 }; gsy=${ $12 };
43			gcxcy=${ $13 }; gcxsy=${ $14 }; gsxcy=${ $15 }; gsxsy=${ $16 };
44			bcx=${ $17 }; bcy=${ $18 }; bsx=${ $19 }; bsy=${ $20 };
45			bcxcy=${ $21 }; bcxsy=${ $22 }; bsxcy=${ $23 }; bsxsy=${ $24 };
46			'_EOF_'
47			cat > $td/coef.cal << '_EOF_'
48			$1=$32cx; $2=$32cy; $3=$32sx; $4=$32sy;
49			$5=$34cxcy; $6=$34cxsy; $7=$34sxcy; $8=$34sxsy;
50			$9=$42cx; $10=$42cy; $11=$42sx; $12=$42sy;
51			$13=$44cxcy; $14=$44cxsy; $15=$44sxcy; $16=$44sxsy;
52			$17=$52cx; $18=$52cy; $19=$52sx; $20=$52sy;
53			$21=$54cxcy; $22=$54cxsy; $23=$54sxcy; $24=$54sxsy;
54			cx=cos(wx); cy=cos(wy);
55			sx=sin(wx); sy=sin(wy);
56			wx=2PI($1+.5)/xres; wy=2PI($2+.5)/yres;
57			'_EOF_'
58			cat > $td/fsub.cal << '_EOF_'
59			ro=ri(1)-rcxcx-rcycy-rsxsx-rsysy
60			-rcxcycxcy-rcxsycxsy-rsxcysxcy-rsxsysxsy;
61			go=gi(1)-gcxcx-gcycy-gsxsx-gsysy
62			-gcxcycxcy-gcxsycxsy-gsxcysxcy-gsxsysxsy;
63			bo=bi(1)-bcxcx-bcycy-bsxsx-bsysy
64			-bcxcycxcy-bcxsycxsy-bsxcysxcy-bsxsysxsy;
65			cx=cos(wx); cy=cos(wy);
66			sx=sin(wx); sy=sin(wy);
67			wx=2PI(x+.5)/xres; wy=2PI(y+.5)/yres;
68			PI=3.14159265358979323846;
69			'_EOF_'
70	greg	1.1	foreach f ($*)
71	greg	1.3	if ( $?verb ) then
72			echo $f\:
73			echo adjusting exposure/size...
74			endif
75	greg	1.2	$pf $f > $td/pf
76			getinfo < $td/pf > $f
77			ed - $f << _EOF_
78			i
79			$ha
80			.
81			w
82			q
83			_EOF_
84	greg	1.3	set resolu=`getinfo -d < $td/pf \| sed 's/-Y \([0-9]\) +X \([0-9]\)/\2 \1/'`
85			if ( $?verb ) then
86			echo computing Fourier coefficients...
87			endif
88	greg	1.4	pfilt -1 -x 32 -y 32 $td/pf \| pvalue -h \
89			\| rcalc -f $td/coef.cal -e 'xres=32;yres=32' \
90			\| total -m \| rcalc -o $td/coef.fmt \
91			> $td/coef
92	greg	1.3	if ( $?verb ) then
93	greg	1.4	cat $td/coef
94	greg	1.3	echo removing low frequencies...
95			endif
96	greg	1.2	if ( ! $?blend ) then
97	greg	1.3	( getinfo - < $td/hf >> $f & ) > /dev/null
98	greg	1.2	endif
99	greg	1.4	pcomb -f $td/fsub.cal -f $td/coef \
100			-e "xres=$resolu[1];yres=$resolu[2]" \
101	greg	1.2	$td/pf > $td/hf
102			if ( $?blend ) then
103	greg	1.3	if ( $?verb ) then
104			echo blending edges...
105			endif
106	greg	1.2	@ mar= $resolu[1] - 3
107			pcompos -x 3 $td/hf 0 0 > $td/left
108			pcompos $td/hf -$mar 0 > $td/right
109			pcomb -e 'ro=f(ri);go=f(gi);bo=f(bi)' \
110			-e 'f(p)=(3-x)/7p(1)+(4+x)/7p(2)' \
111			$td/right $td/left > $td/left.patch
112			pcomb -e 'ro=f(ri);go=f(gi);bo=f(bi)' \
113			-e 'f(p)=(1+x)/7p(1)+(6-x)/7p(2)' \
114			$td/left $td/right > $td/right.patch
115			pcompos $td/hf 0 0 $td/left.patch 0 0 $td/right.patch $mar 0 \
116			> $td/hflr
117			@ mar= $resolu[2] - 3
118			pcompos -y 3 $td/hflr 0 0 > $td/bottom
119			pcompos $td/hflr 0 -$mar > $td/top
120			pcomb -e 'ro=f(ri);go=f(gi);bo=f(bi)' \
121			-e 'f(p)=(3-y)/7p(1)+(4+y)/7p(2)' \
122			$td/top $td/bottom > $td/bottom.patch
123			pcomb -e 'ro=f(ri);go=f(gi);bo=f(bi)' \
124			-e 'f(p)=(1+y)/7p(1)+(6-y)/7p(2)' \
125			$td/bottom $td/top > $td/top.patch
126			pcompos $td/hflr 0 0 $td/bottom.patch 0 0 $td/top.patch 0 $mar \
127			\| getinfo - >> $f
128			endif
129	greg	1.3	if ( $?verb ) then
130			echo $f done.
131			endif
132	greg	1.1	end
133	greg	1.2	quit:
134			rm -rf $td