See Also edit
Description edit
Richard Suchenwirth 2002-06-15: Cameron Laird pointed me to Functional Image Synthesis
(Pan), by Conal Elliott, where images (of arbitrary size and resolution) are produced and manipulated in an elegant functional way.foo 1 o bar 2 o grill(where "o" is the composition operator) would in Tcl look like
o {foo 1} {bar 2} grillAs the example shows, additional arguments can be specified; only the last argument is passed through the generated "function nest":proc f x {foo 1 [bar 2 [grill $x]]}But the name of the generated function is much nicer than "f": namely, the complete call to "o" is used, so the example proc has the name{o {foo 1} {bar 2} grill}which is pretty self-documenting ;-) I implemented "o" like this (PYK 2014-04-14: Basic idea of RS is still here, but object system has been added, and changes to the interface made):Code edit
#! /bin/env tclsh
proc method {name params args} {
switch [llength $args] {
1 {
lassign $args body
set attributes {}
}
2 {
lassign $args attributes body
}
default {
error {wrong number args: should be \
"method name params ?attributes? body"}
}
}
proc $name $params [string map [
list {{{attributes}}} [list $attributes] {{{body}}} $body] {
set id $::errorInfo
foreach varname {{attributes}} {
upvar 0 ${id}::$varname $varname
}
{{body}}
}]
}
method o args {
# combine the functions in args, return the created name
set body [concat [join $args { [}] \$x]
append body [string repeat \] [expr {[llength $args]-1}]]
set name [string map {: _} $args]
regsub -all {[[:space:]]+} $name { } name
set name o\ $name
proc ${id}::$name x $body
return $name
}
# Now for the rendering framework:
method fim {f onfinish {zoom 100} {width 200} {height -}} busy {
set busy 1
# produce a photo image by applying function f to pixels
if {$height eq "-"} {set height $width}
set im [image create photo -height $height -width $width]
set data {}
set xs {}
for {set j 0} {$j < $width} {incr j} {
lappend xs [expr {($j-$width/2.)/$zoom}]
}
$id fim_doing $f $onfinish $zoom $height $xs 0 $im $data[set data {}]
}
method fim_doing {f onfinish zoom height xs i im data} {
if {$i >= $height} {
after idle [list {*}$onfinish $im $data]
return
}
set row {}
set y [expr {($i-$height/2.)/$zoom}]
foreach x $xs {
lappend row [{*}$f [list $x $y]]
}
lappend data $row
incr i
after idle [list $id fim_doing $f $onfinish $zoom $height $xs $i $im $data[
set data {}]]
}
proc vstrip p {
# a simple vertical bar
b2c [expr {abs([lindex $p 0]) < 0.5}]
}
proc udisk p {
# unit circle with radius 1
foreach {x y} $p break
b2c [expr {hypot($x,$y) < 1}]
}
proc xor {f1 f2 p} {
lappend f1 $p; lappend f2 $p
b2c [expr {[eval $f1] != [eval $f2]}]
}
proc and {f1 f2 p} {
lappend f1 $p; lappend f2 $p
b2c [expr {[eval $f1] eq "#000" && [eval $f2] eq "#000"}]
}
proc checker p {
# black and white checkerboard
foreach {x y} $p break
b2c [expr {int(floor($x)+floor($y)) % 2 == 0}]
}
proc gChecker p {
# greylevels correspond to fractional part of x,y
foreach {x y} $p break
g2c [expr {(fmod(abs($x),1.)*fmod(abs($y),1.))}]
}
proc bRings p {
# binary concentric rings
foreach {x y} $p break
b2c [expr {round(hypot($x,$y)) % 2 == 0}]
}
proc gRings p {
# grayscale concentric rings
foreach {x y} $p break
g2c [expr {(1 + cos(3.14159265359 * hypot($x,$y))) / 2.}]
}
proc radReg {n p} {
# n wedge slices starting at (0,0)
foreach {r a} [toPolars $p] break
b2c [expr {int(floor($a*$n/3.14159265359))%2 == 0}]
}
proc xPos p {b2c [expr {[lindex $p 0]>0}]}
proc cGrad p {
# color gradients - best watched at zoom=100
foreach {x y} $p break
if {abs($x)>1.} {set x 1.}
if {abs($y)>1.} {set y 1.}
set r [expr {int((1.-abs($x))*255.)}]
set g [expr {int((sqrt(2.)-hypot($x,$y))*180.)}]
set b [expr {int((1.-abs($y))*255.)}]
c2c $r $g $b
}
proc fplot {expr p} {
foreach {x y} $p break
b2c [expr abs($expr)<=0.04] ;# double eval required here!
}
proc bin2 {f1 f2 p} {
set a [eval $f1 [list $p]]
set b [eval $f2 [list $p]]
expr {
$a eq "#000" ?
$b eq "#000" ? "green"
: "yellow"
: $b eq "#000" ? "blue"
: "black"
}
}
#--------------------------------------- Pixel converters:
proc g2c {greylevel} {
# convert 0..1 to #000000..#FFFFFF
set hex [format %02X [expr {round($greylevel*255)}]]
return #$hex$hex$hex
}
proc b2c {binpixel} {
# 0 -> white, 1 -> black
expr {$binpixel ? "#000" : "#FFF"}
}
proc c2c {r g b} {
# make Tk color name: {0 128 255} -> #0080FF
format #%02X%02X%02X $r $g $b
}
proc bPaint {color0 color1 pixel} {
# convert a binary pixel to one of two specified colors
expr {$pixel eq "#000" ? $color0 : $color1}
}
proc gPaint {color pixel} {
set abspixel [lindex [rgb $pixel] 0]
set rgb [rgb $color]
set rgbw [rgb white]
foreach var {r g b} in $rgb ref $rgbw {
set $var [expr {round(double($abspixel)*$in/$ref/$ref*255.)}]
}
c2c $r $g $b
}
proc rgb {color} {
upvar "#0" rgb($color) rgb
if {![info exists rgb]} {set rgb [winfo rgb . $color]}
set rgb
}
#------------------------------ point -> point transformers
proc fromPolars p {
foreach {r a} $p break
list [expr {$r*cos($a)}] [expr {$r*sin($a)}]
}
proc toPolars p {
foreach {x y} $p break
# for Sun, we have to make sure atan2 gets no two 0's
list [expr {hypot($x,$y)}] [expr {$x||$y ? atan2($y,$x): 0}]
}
proc radInvert p {
foreach {r a} [toPolars $p] break
fromPolars [list [expr {$r ? 1/$r: 9999999}] $a]
}
proc rippleRad {n s p} {
foreach {r a} [toPolars $p] break
fromPolars [list [expr {$r*(1.+$s*sin($n*$a))}] $a]
}
proc slice {n p} {
foreach {r a} $p break
list $r [expr {$a*$n/3.14159265359}]
}
proc rotate {angle p} {
foreach {x y} $p break
set x1 [expr {$x*cos(-$angle) - $y*sin(-$angle)}]
set y1 [expr {$y*cos(-$angle) + $x*sin(-$angle)}]
list $x1 $y1
}
proc swirl {radius p} {
foreach {x y} $p break
set angle [expr {hypot($x,$y)*6.283185306/$radius}]
rotate $angle $p
}
#------------------------------ Contour
#contributed by Arjen Markus
proc contour {expr p} {
foreach {x y} $p break
colourClass {-10 -5 0 5 10} [expr $expr] ;# double eval required here!
}
proc colourClass {classbreaks value} {
set nobreaks [llength $classbreaks]
set colour [lindex {darkblue blue green yellow orange red magenta} end ]
for {set i 0} {$i < $nobreaks} {incr i} {
set break [lindex $classbreaks $i]
if { $value <= $break } {
set colour \
[lindex {darkblue blue green yellow orange red magenta} $i ]
break
}
}
return $colour
}
#------------------------------ Some fancier gradient operators
#contribued by DKF
method g2 {f1 f2 p} {
foreach {r1 g1 b1} [rgb [$id $f1 $p]] {break}
foreach {r2 g2 b2} [rgb [$id $f2 $p]] {break}
set r3 [expr {($r1+$r2)/2/256}]
set g3 [expr {($g1+$g2)/2/256}]
set b3 [expr {($b1+$b2)/2/256}]
c2c $r3 $g3 $b3
}
method g+ {f1 f2 p} {
foreach {r1 g1 b1} [rgb [$id $f1 $p]] {break}
foreach {r2 g2 b2} [rgb [$id $f2 $p]] {break}
set r3 [expr {($r1>$r2?$r1:$r2)/256}]
set g3 [expr {($g1>$g2?$g1:$g2)/256}]
set b3 [expr {($b1>$b2?$b1:$b2)/256}]
c2c $r3 $g3 $b3
}
method g- {f1 f2 p} {
foreach {r1 g1 b1} [rgb [$id $f1 $p] {break}
foreach {r2 g2 b2} [rgb [$id $f1 $p] {break}
set r3 [expr {($r1<$r2?$r1:$r2)/256}]
set g3 [expr {($g1<$g2?$g1:$g2)/256}]
set b3 [expr {($b1<$b2?$b1:$b2)/256}]
c2c $r3 $g3 $b3
}
proc invert {c} {
foreach {r1 g1 b1} [rgb $c] {break}
set r3 [expr {0xff-$r1/256}]
set g3 [expr {0xff-$g1/256}]
set b3 [expr {0xff-$b1/256}]
c2c $r3 $g3 $b3
}
#------------------------------ User Interface
method fim'show f {busy oldzoom onfinish t0 w zoom} {
set t0 [clock clicks]
set oldzoom $zoom
$id fim [list $id $f] [list $id fim'finished $f] $zoom [
winfo width $w.f2.c] [winfo height $w.f2.c]
}
method fim'finished {f im data} {busy cimg w t0} {
if {$cimg ne {}} {
$w.f2.c delete $cimg
}
set cimg [$w.f2.c create image 0 0 -image $im -anchor nw]
$im put $data
pack $w.f2.c
set busy {}
wm title . "[expr [clock clicks]-$t0] clicks for $f"
}
method fim'try {} {w try} {
set ${id}::command [list $id fim'show [$id o {*}$try]]
after idle [namespace eval $id [list namespace code {
if {[catch $command]} {
$w.f2.c delete all
$w.f2.c create text 10 10 -anchor nw -text $::errorInfo
}
}]]
}
package require Tk
#----------------------------------------------- testing
method behave {behaviour args} {busy} {
if {$busy ne {}} {
return
}
set busy [after idle [list $id $behaviour {*}$args]]
}
method randtoggle {} {w randomplay} {
if {$randomplay} {
set randomplay 0
$w.f2.rplay configure -fg black
} {
set randomplay 1
$w.f2.rplay configure -fg green
$id randomplay
}
}
method randomplay {} {try randomplay} {
if {!$randomplay} return
set funcs [lmap x [info procs ${id}::o\ *] {
string trimleft [string trimleft [namespace tail $x] o]
}]
set idx [expr {entier(rand()*[llength $funcs])}]
set try [lindex $funcs $idx]
$id behave fim'try
after 5000 [list after idle [list $id randomplay]]
}
method rezoom args {afterzoom scale_delay} {
after cancel $afterzoom
set afterzoom [after $scale_delay [list after idle [
namespace eval $id [list namespace code {
if {$zoom != $oldzoom} {
if {$try ne {}} {
$id behave fim'try
}
}
}]]]]
}
method gui {} {
namespace eval $id {
frame $w.f2
canvas $w.f2.c
variable cimg {}
variable try
entry $w.f2.e -bg white -textvar ${id}::try
bind $w.f2.e <Return> [namespace code {
$id behave fim'try}]
button $w.f2.rplay -text randplay -command [namespace code {
$id randtoggle
}]
scale $w.f2.s -from 1 -to 100 -variable \
${id}::zoom -ori hori -width 6
bind $w.f2.s <Button1-ButtonRelease> [list $id rezoom]
#--------------------------------- button bar:
frame $w.f
listbox $w.f.listbox -yscrollcommand [
list $w.f.scrbary set] -xscrollcommand [
list $w.f.scrbarx set]
foreach imf [lsort [info procs ${id}::o\ *]] {
$w.f.listbox insert end [string trimleft [
string trimleft [namespace tail $imf] o]]
}
bind $w.f.listbox <<ListboxSelect>> [namespace code {
set try [$w.f.listbox get [$w.f.listbox curselection]]
}]
bind $w.f.listbox <Return> [namespace code {
$id behave fim'try}]
bind $w.f.listbox <Double-Button-1> [namespace code {
$id behave fim'try}]
scrollbar $w.f.scrbarx -orient horizontal -command [
list $w.f.listbox xview]
scrollbar $w.f.scrbary -orient vertical -command [
list $w.f.listbox yview]
#pack {*}[winfo children $w.f] -side top -fill x -ipady 0
pack $w.f.scrbary -side right -fill y
pack $w.f.scrbarx -side bottom -fill x
pack $w.f.listbox -fill both -expand 1
pack $w.f2.c -side top -fill both -expand 1
pack $w.f2.e -side bottom -fill x
pack $w.f2.s -side left -fill x -expand 1
pack $w.f2.rplay -side right -fill x
pack $w.f $w.f2 -side left -anchor n -fill both -expand 1
}
}
proc new {id w} {
set id [namespace eval $id {
namespace export {[a-z]*}
namespace ensemble create -prefixes no
namespace path [namespace parent]
#dirtiest object system in The West!
namespace ensemble configure [namespace current] -unknown [
list apply [list {ns args} {
set args [lassign $args[set args {}] ns cmd]
set ::errorInfo $ns
list [namespace current] $cmd
} [namespace parent]] [namespace current]]
variable id [namespace current]
proc my {} {namespace current}
variable busy {}
variable scale_delay 0
variable zoom 25
variable oldzoom $zoom
variable afterzoom {}
variable randomplay 0
namespace import [namespace parent]::o\ *
set id
}]
$id o bRings
$id o cGrad
$id o checker
$id o gRings
$id o vstrip
$id o xPos
$id o {bPaint brown beige} checker
$id o checker {slice 10} toPolars
$id o checker {rotate 0.1}
$id o vstrip {swirl 1.5}
$id o checker {swirl 16}
$id o {fplot {$y + exp($x)}}
$id o checker radInvert
$id o gRings {rippleRad 8 0.3}
$id o xPos {swirl .75}
$id o gChecker
$id o {gPaint red} gRings
$id o {bin2 {radReg 7} udisk}
#contour plot (isoline-like) of the map ''f(x,y) = xy''.
$id o {contour {$x*$y}}
#Other cute variations by RS
$id o {contour {($x+$y)*$y}}
$id o {contour {sin($x)/cos($y)}}
$id o {contour {exp($y)-exp($x)}}
$id o {contour {exp($y)-cos($x)}}
$id o {contour {exp($x)*tan($x*$y)}}
$id o cGrad radInvert
$id o cGrad {swirl 8}
$id o {contour {sin($y)-tan($x)}}
$id o {contour {exp($x)-tan($x*$y)}} toPolars ;# at zoom 20, a weird tropical fish...
#contributed by DKF
$id o gRings {rippleRad 8 0.3} {swirl 16}
$id o gChecker {rippleRad 8 0.3} {swirl 16}
$id o gChecker {rippleRad 6 0.2} {swirl 26}
$id o {gPaint yellow} gChecker {rippleRad 6 0.2} {swirl 26} toPolars ;# Yellow Rose
$id o cGrad {swirl 8} {slice 110} radInvert
$id o cGrad {rippleRad 8 0.3} {swirl 8} radInvert {swirl 8} ;# Toothpaste!
#and here are some stranger ones contributed by DKF
$id o {gPaint yellow} gChecker fromPolars {rippleRad 6 0.2} {swirl 26} toPolars
$id o {gPaint yellow} gChecker toPolars {rippleRad 6 0.2} {swirl 26} fromPolars
#a few more
$id o {bin2 checker bRings} {swirl 5} radInvert
$id o cGrad {rippleRad 8 .3} {swirl 8}
$id o vstrip {swirl 1.5} {rippleRad 8 .3}
$id o {fplot {($x*$x-$y*$y)/10}} {swirl 15} {rippleRad 8 .3}
$id o gChecker {rotate .1} {slice 10} radInvert ;# two kissing fish
$id o cGrad fromPolars {swirl 16} ;# neon galaxy
#And some pretty demos from DKF, word-smithed by PYK
$id o invert {gPaint red} gRings
$id o [list g2 [$id o gRings] [$id o gRings {rippleRad 8 0.3}]]
$id o [list g+ [$id o {gPaint red} gRings] [$id o gRings {rippleRad 8 0.3}]]
$id o [list g+ [
$id o {gPaint red} gChecker {swirl 16}] [
$id o gRings {rippleRad 8 0.3}]]
$id o [list g+ [
$id o {gPaint red} gRings {rippleRad 8 0.3} {swirl 19}] [
$id o {gPaint green} gRings {rippleRad 8 0.3} {swirl 20}]]
$id o [list g+ [
$id o {gPaint yellow} gRings {rippleRad 8 0.9} {swirl 28}] [
$id o {gPaint blue} gRings {rippleRad 6 1.5} {swirl 14}]]
set ${id}::w $w
$id gui
set id
}
namespace export {[a-z]*}
namespace ensemble create
bind . <Escape> {exec wish $argv0 &; exit} ;# dev helper
bind . ? {console show} ;# dev helper, Win/Mac only
for {set i 0} {$i < 2} {incr i} {
frame .myframe$i
pack .myframe$i -expand 1 -fill both
for {set j 0} {$j < 2} {incr j} {
pack [frame .myframe$i.$j] -expand 1 -fill both -side left
new [info cmdcount] .myframe$i.$j
}
}
JCW - If you have Critcl (and gcc), then you can use the following code to halve the execution time of cGrad (others could be "critified" too, of course):
if {[catch { package require critcl }]} {
proc cGrad p {
# color gradients - best watched at zoom=100
foreach {x y} $p break
if {abs($x)>1.} {set x 1.}
if {abs($y)>1.} {set y 1.}
set r [expr {int((1.-abs($x))*255.)}]
set g [expr {int((sqrt(2.)-hypot($x,$y))*180.)}]
set b [expr {int((1.-abs($y))*255.)}]
c2c $r $g $b
}
} else {
proc cGrad p {
return [eval [linsert $p 0 _cGrad]]
}
critcl::ccode {
#include <math.h>
}
critcl::cproc _cGrad {double x double y} char* {
int r, g, b;
static char buf [10];
if (fabs(x) > 1) x = 1;
if (fabs(y) > 1) y = 1;
r = (1 - fabs(x)) * 255;
g = (sqrt(2) - hypot(x, y)) * 180;
b = (1 - fabs(y)) * 255;
sprintf(buf, "#%02X%02x%02x", r, g, b);
return buf;
}
}Discussion edit
Arjen Markus: Added contour and colourClass to the repertoire:RS: Beautiful - and fast: 1..2 sec on 833MHz W2K box. Best viewed at zoom ~10. There are many more left for to discover...DKF: This is really cool indeed. Pretty. I've added some of my favourites. Note that many images with radInvert don't look very good.
DKF: Here's some fancier operators for working with gradients...
(with a larger than usual image, I'll admit)Changes edit
PYK 2012-12-09: removed update, scale change now triggers redrawPYK 2014-04-12: revision 80. Various changes to the user interface. Added object system to turn it into a widget that can be instantiated multiple times. Consolidated contributed code examples into one script.
