% $Id: pstricks.pro 615 2022-09-22 08:39:26Z herbert $ % %% PostScript prologue for pstricks.tex. %% Version 1.41, 2021/11/16 %% %% This program can be redistributed and/or modified under the terms %% of the LaTeX Project Public License Distributed from CTAN archives %% in directory macros/latex/base/lppl.txt. % % % Define the follwing gs-functions if not known, eg when using distiller % revision 952 gt { systemdict /.setopacityalpha known not { (\n\n%%%% WARNING: Transparency operations ignored - need to use -dALLOWPSTRANSPARENCY\n\n) print flush /.setopacityalpha { pop } bind def /.setshapealpha { pop } bind def /.setfillconstantalpha { pop } bind def /.setstrokeconstantalpha { pop } bind def } { /.setopacityalpha /.setfillconstantalpha load def % /.setblendmode { pop } def %% works again hv 20210825 /.setshapealpha {dup .setfillconstantalpha .setstrokeconstantalpha true .setalphaisshape } def } ifelse } { systemdict /.setopacityalpha known not { (\n\n%%%% WARNING: Transparency operations ignored - need to use -dNOSAFER\n\n) print flush /.setopacityalpha { pop } bind def /.setshapealpha { pop } bind def } if } ifelse % %% .setalphaisshape - %% If true, the values set by setstrokeconstantalpha and setfillconstantalpha are interpreted as shape values. The initial value of the AIS flag is false. % % /tx@Dict 200 dict def % the main PSTricks dictionary tx@Dict begin /ADict 25 dict def % The arrow dictionary /fill@Dict 30 dict def % the fill dictionary /CM { matrix currentmatrix } bind def /SLW /setlinewidth load def /CLW /currentlinewidth load def /CP /currentpoint load def /ED { exch def } bind def /L /lineto load def /T /translate load def /TMatrix { } def /RAngle { 0 } def /Sqrt { dup 0 lt { pop 0 } { sqrt } ifelse } def % return 0 for negative arguments /Atan { /atan load stopped { pop pop 0 } if } def % return 0 if atan not known /ATAN1 {neg -1 atan 180 sub } def % atan(x) (only one parameter) /Div { dup 0 eq { pop } { div } ifelse } def % control the division /Log { dup 1e-20 lt { pop -1e30 }{ log } ifelse } def % control the log /tan { dup cos abs 1.e-10 lt { pop 1.e10 } % return 1.e10 as infinit { dup sin exch cos div } ifelse % default sin/cos } def /Tan { dup sin exch cos Div } def % sin(x)/cos(x) x in degrees /Acos {dup dup mul neg 1 add dup 0 lt { % arc cos, returns 0 when negative root pop pop 0 }{ sqrt exch atan} ifelse } def /Acos2 { 2 dict begin /x ED /y ED y abs 1.0e-20 lt { 1.0e30 } if x y div dup dup mul neg 1 add dup 0 lt { % arc cos needs two values x,y pop pop 0 }{ sqrt exch atan} ifelse y 0 lt { 180 add } if } def /Power { % a^b latest ghostscript don't allow -4^-3.1 2 dict begin % hold all local /b ED /a ED a 0 lt % prevent something like (-4)^(-3.1)=> 1/(-4)^3 { b 0 lt { a b cvi exp } { a b exp } ifelse } { a 0 eq { 0 }{ a b exp } ifelse } ifelse end } def % /NET { neg exch neg exch T } def % change coordinate system to the negative one /Pyth { dup mul exch dup mul add sqrt } def % Pythagoras, expects 2 parameter /addCoors { 3 -1 roll % xA xB yB yA add % xA xB yB+yA 3 1 roll % yB+yA xA xB add % yB+yA xA+xB exch % xA+xB yA+yB } def /Pyth2 { % Pythagoras, xA yA xB yB 3 -1 roll % xA xB yB yA sub % xA xB yB-yA 3 1 roll % yB-yA xA xB sub % yB-yA xA-xB Pyth } def /PtoC { 2 copy cos mul 3 1 roll sin mul } def % Polar to Cartesian (original) /PtoCrel { pst@angleunit PtoC } def % Polar to Cartesian with \degrees[??] /PtoCab { dup cos 4 -1 roll mul 3 1 roll sin mul } def % Polar to Cartesian (Ellipse) a b phi-> x y /AnytoDeg { pst@angleunit } def /DegtoAny { 1 pst@angleunit div} def /AnytoRad { AnytoDeg DegtoRad } def /RadtoAny { RadtoDeg DegtoAny } def % %/Rand { rand 4294967295 div } def % a real random number /Rand { rand 2147483447 div } def % a real random number between 0 and 1 %----------------- hv added 20050516 --------------- /PiDiv2 1.57079632680 def /Pi 3.14159265359 def /TwoPi 6.28318530718 def /Euler 2.71828182846 def %/e Euler bind def % /RadtoDeg { 180 mul Pi div } bind def % convert from radian to degrees /DegtoRad { Pi mul 180 div } bind def % viceversa % /startGlobal { true setglobal globaldict begin } bind def /endGlobal { end false setglobal } bind def % /pssetRGBcolor /setrgbcolor load def /pssetCMYKcolor /setcmykcolor load def /pssetGraycolor /setgray load def % %----------------- hv end--------------------------- /PathLength@ { /z z y y1 sub x x1 sub Pyth add def /y1 y def /x1 x def } def % /PathLength { 10 dict begin flattenpath /z 0 def { /y1 ED /x1 ED /y2 y1 def /x2 x1 def } { /y ED /x ED PathLength@ } {} { /y y2 def /x x2 def PathLength@ } /pathforall load stopped { pop pop pop pop } if z end } def % /STP { .996264 dup scale } def % BP/PT scaling /STV { SDict begin normalscale end STP } def % % /DashLine { dup 0 gt { /a .5 def PathLength exch div } { pop /a 1 def PathLength } ifelse /b ED % pattern should fit evenly in b dup /X ED % pattern array 0 get /y ED % length of first black segment /z 0 X {add} forall def % length of the full pattern %% Computation of the scaling factor as described by van Zandt: b a .5 sub 2 mul y mul sub z Div round z mul a .5 sub 2 mul y mul add b exch Div %%%% scaling factor on stack. /z ED %% now, z is the scaling factor false % for the length test below X { z mul } forall X astore %% modification TN 04-08-07 %%% Checking whether at least one dash in X has positive length: {0 gt or} forall { X 1 a sub y mul } { [ 1 0 ] 0 } ifelse setdash stroke } def % /DotLine { /b PathLength def /a ED /z ED /y CLW def /z y z add def a 0 gt { /b b a div def }{ a 0 eq { /b b y sub def }{ a -3 eq { /b b y add def } if } ifelse } ifelse [ 0 b b z Div round Div dup 0 le { pop 1 } if ] a 0 gt { 0 }{ y 2 div a -2 gt { neg }if } ifelse setdash 1 setlinecap stroke } def % /SymbolLine { % on stack [ x y x y ... counttomark % number of elements 2 div cvi /n ED % n pairs /YA ED /XA ED % the start point n 1 sub { /YB ED /XB ED /XLength XB XA sub def /YLength YB YA sub def /PAngle YLength XLength Atan def /XYLength XLength YLength Pyth def %% for negative SymStep we calculate the distance SymStep 0 lt { %XYLength SymStep div abs cvi /nSym SymStep abs cvi def } { /nSym XYLength SymStep div cvi def } ifelse 0.5 setflat /Shift Symbol stringwidth pop 2 div def /deltaX XLength nSym div def /deltaY YLength nSym div def curveticks { XA YA moveto } { XA Shift sub YA Shift sub moveto } ifelse nSym { gsave curveticks { PAngle 180 sub CorrAngle sub tickAngle add /rotAngle ED currentpoint translate rotAngle rotate 0 SymbolWidth 2 div moveto 0 SymbolWidth 2 div neg lineto SymbolLinewidth setlinewidth stroke } { rotateSymbol { PAngle 180 sub CorrAngle sub rotate } if Symbol show } ifelse grestore deltaX deltaY rmoveto } repeat /YA YB def /XA XB def } repeat curveticks { XA YA moveto } { XA Shift sub YA Shift sub moveto } ifelse gsave curveticks { PAngle 180 sub CorrAngle sub tickAngle add /rotAngle ED XA YA translate rotAngle rotate 0 SymbolWidth 2 div moveto 0 SymbolWidth 2 div neg lineto SymbolLinewidth setlinewidth stroke } { rotateSymbol { PAngle 180 sub CorrAngle sub rotate } if Symbol show } ifelse grestore pop % delete the mark symbol } def % /LineFill { % hv ------------ patch 7 ------------- gsave abs /hatchWidthInc ED abs /hatchSepInc ED abs CLW add /a ED a 0 dtransform round exch round exch 2 copy idtransform exch Atan rotate idtransform pop /a ED .25 .25 itransform pathbbox /y2 ED a Div ceiling cvi /x2 ED /y1 ED a Div cvi /x1 ED /y2 y2 y1 sub def clipType % must be defined in pstricks.tex: clip -- eoclip newpath 2 setlinecap systemdict /setstrokeadjust known { true setstrokeadjust } if x2 x1 sub 1 add { x1 a mul y1 moveto 0 y2 rlineto stroke /x1 x1 1 add hatchWidthInc 0 gt { CLW add } if def hatchSepInc 0 gt hatchWidthInc 0 gt or { /a a hatchSepInc add def CLW hatchWidthInc add SLW } if } repeat grestore pop pop } def % /DotFill {% on stack: dot radius /dotRadius ED abs CLW add /a ED a 0 dtransform round exch round exch 2 copy idtransform exch Atan rotate idtransform pop /a ED .25 .25 itransform pathbbox % llx lly urx ury of smallest bounding box /y2 ED /x2 ED /y1 ED /x1 ED y2 y1 sub a div 2 add cvi /Ny ED x2 x1 sub a div 2 add cvi /Nx ED clipType % must be defined in pstricks.tex: clip -- eoclip newpath /yA y1 dotRadius add CLW add def /xA0 x1 dotRadius add CLW add def Ny { /xA xA0 def Nx { newpath xA yA dotRadius 0 360 arc SolidDot { gsave fill grestore } if stroke xA a add /xA ED } repeat yA a add /yA ED } repeat grestore } def % /PenroseFill {% on stack: scaling factor 40 dict begin /Scale ED % 1 exch div round /penroseFactor ED % a 0 dtransform round exch round exch % 2 copy idtransform % exch Atan rotate % idtransform pop /a ED % .25 .25 itransform pathbbox % /y2 ED % a Div ceiling cvi /x2 ED /y1 ED % a Div cvi /x1 ED /y2 y2 y1 sub def clip newpath gsave 220 150 translate Scale dup scale systemdict /setstrokeadjust known { true setstrokeadjust } if /I/S/L/W/G/+/Z/F/E/D[/def/exch/for{E D}/add{s E get mul} { Z -36.2001 1 33 }{25 E S rlineto}{/q Z dup q G E q 1 + G}{Z 2 2}]{cvx def}forall [0 72 1008 {dup sin E cos }F ]1 setlinejoin/s W{/a W{/b I 10{/i I 4{/m I moveto i m +/j I 10{/l Z b m l + G a l G sub s m get div .2 + floor .3 + 25 mul j l + S rmoveto}F i L j L stroke }F}F}F}F grestore % pop pop end % userdict } def % /PenroseFillA {% on stack: scaling factor, border color, kite color, dart color 50 dict begin /Scale ED Scale dup scale /border_colour ED /kite_colour ED /dart_colour ED clip newpath gsave 100 100 translate 6 Scale 1 lt { 1 Scale dup add div mul cvi } if %%%% Number of iterations 10 %%%% Long side length in millimeters /border_width { L 0.06 mul }def %%%% Choose the scalefactor for the borders /L exch 25.4 div 72 mul def %%%% Conversion: mm -> inches -> points /f{-1 5 sqrt add 2 div}bind def %%%% The reciprocal of the golden ratio /l{L f mul}bind def %%%% Short side length l = L*f /Ll{L l add}bind def %%%% Ll = L + l /c{36 cos L mul}bind def %%%% c = L*cos(36) /s{36 sin L mul}bind def %%%% s = L*sin(36) /draw_tile { 0 0 moveto c s lineto 0 lineto gsave closepath gsave fill grestore 0 setlinewidth stroke grestore border_colour stroke } bind def /half_kite { dup dup 0 gt{ 1 sub gsave f f neg scale -36 rotate half_dart Ll 0 translate 144 rotate kite grestore } { kite_colour L draw_tile }ifelse pop } bind def /half_dart { dup dup 0 gt{ 1 sub gsave f f scale half_kite -144 rotate Ll neg 0 translate half_dart grestore } { dart_colour l draw_tile }ifelse pop } bind def /kite{ gsave half_kite 1 -1 scale half_kite grestore }bind def border_width setlinewidth 1 setlinejoin 1 setlinecap % 450 0 translate dup f exch neg exp dup scale 5 {kite 72 rotate } repeat stroke grestore end % userdict } def % % /TruchetFill { % on stack: scaling factor 20 dict begin dup dup scale 1 exch div round /penroseFactor ED a 0 dtransform round exch round exch 2 copy idtransform exch Atan rotate idtransform pop /a ED .25 .25 itransform pathbbox /y2 ED a Div ceiling cvi /x2 ED /y1 ED a Div cvi /x1 ED /y2 y2 y1 sub def clip newpath systemdict /setstrokeadjust known { true setstrokeadjust } if /ma a neg def /ha a 2 div def /mha ha neg def /tile { rand dup 2 idiv 2 mul eq { 90 rotate } if mha mha moveto ha mha lineto ha ha lineto mha ha lineto % closepath .1 setlinewidth stroke contents } def /contents{ 0 ha moveto ha 0 lineto 0 mha moveto mha 0 lineto % 1 setlinewidth stroke } def /dotiling { f ma mul a f a mul { /i exch def f ma mul a f a mul { /j exch def gsave i j translate tile stroke grestore } for } for } def % /f 3 def 5 srand dotiling end % local user dict } def % /BeginArrow { ADict begin % hold it local, for end see EndArrow /@mtrx CM def gsave 2 copy T 2 index sub neg exch 3 index sub exch Atan rotate newpath } def % /EndArrow { @mtrx setmatrix CP grestore end } def % end the ADict % /Arrow { CLW mul add dup 2 div /w ED mul dup /h ED mul /a ED { 0 h T 1 -1 scale } if w neg h moveto 0 0 L w h L w neg a neg rlineto gsave % gsave w neg h lineto CLW 0.5 add setlinewidth % test für border beim Pfeil % 1 setgray 0 setlinejoin closepath stroke % grestore fill grestore } def % /ArrowD { % the sides are drawn as curves (hv 20071211) CLW mul add dup 2 div /w ED mul dup /h ED mul /Inset ED { 0 h T 1 -1 scale } if % changes the direction % we use y=w/h^2 * x^2 as equation for the control points % for the coordinates the arrow is seen from top to bottom % the bottom (tip) is (0;0) w neg h moveto % lower left of > w 9 div 4 mul neg h 3 div 2 mul w 9 div neg h 3 div 0 0 curveto % tip of > w 9 div h 3 div w 9 div 4 mul h 3 div 2 mul w h curveto % upper left of > w neg Inset neg rlineto % move to x=0 and inset gsave fill grestore } def % /ArrowT { % like tikz CLW mul add dup 2 div /w ED mul dup /h ED mul /Inset ED { 0 h T 1 -1 scale } if % changes the direction w 2 mul /w exch def w neg h moveto % lower left of > w 9 div 4 mul neg h 3 div 2 mul w 9 div neg h 3 div 0 0 curveto % tip of > w 9 div h 3 div w 9 div 4 mul h 3 div 2 mul w h curveto % upper left of > % w neg Inset neg rlineto % move to x=0 and inset % CLW SLW % 1 0 0 setrgbcolor 2 setlinejoin stroke 0 0 moveto } def % /Tbar { CLW mul add /z ED z -2 div CLW 2 div moveto z 0 rlineto stroke 0 CLW moveto } def % /Bracket { CLW mul add dup CLW sub 2 div /x ED mul CLW add /y ED /z CLW 2 div def x neg y moveto x neg CLW 2 div L x CLW 2 div L x y L stroke 0 CLW moveto } def % /RoundBracket { CLW mul add dup 2 div /x ED mul /y ED /mtrx CM def 0 CLW 2 div T x y mul 0 ne { x y scale } if 1 1 moveto .85 .5 .35 0 0 0 curveto -.35 0 -.85 .5 -1 1 curveto mtrx setmatrix stroke 0 CLW moveto } def % /SD { 0 360 arc fill } def % /EndDot { % DS is the dot size { /z DS def } { /z 0 def } ifelse % outer or inner dimen /b ED % the color definition 0 z DS SD b { 0 z DS CLW sub SD } if 0 DS z add CLW 4 div sub moveto } def % /Shadow { [ { /moveto load } { /lineto load } { /curveto load } { /closepath load } /pathforall load stopped { pop pop pop pop CP /moveto load } if ] cvx newpath 3 1 roll T exec } def % /NArray { % holds the coordinates and on top of stack the showpoints boolean /showpoints ED counttomark 2 div dup cvi /n ED % n 2 div on stack n eq not { exch pop } if % even numbers of points? delete one ] aload /Points ED showpoints not { Points aload pop } if % { ] aload /Points ED } % { n 2 mul 1 add -1 roll pop } ifelse % delete the mark symbol } def % /Line { NArray n 0 eq not { n 1 eq { 0 0 /n 2 def } if ArrowA /n n 2 sub def n { Lineto } repeat CP 4 2 roll ArrowB L pop pop } if } def % /LineToYAxis { /Ox ED % Save the x origin value NArray % all x-y pairs on stack n { 2 copy moveto % go to current point Ox exch Lineto % line to y-axis pop % delete old x-value } repeat } def % /LineToXAxis{ /Oy ED % Save the y origin value NArray % all x-y pairs on stack n 0 eq not { n 1 eq { 0 0 /n 2 def } if ArrowA /n n 2 sub def CP 2 copy moveto pop Oy Lineto n { 2 copy moveto pop Oy Lineto } repeat CP 4 2 roll ArrowB 2 copy moveto pop Oy L pop pop } if } def % /Arcto { /a [ 6 -2 roll ] cvx def a r /arcto load stopped { 5 } { 4 } ifelse { pop } repeat a } def % /CheckClosed { dup n 2 mul 1 sub index eq 2 index n 2 mul 1 add index eq and { pop pop /n n 1 sub def } if } def % /Polygon { NArray n 2 eq { 0 0 /n 3 def } if n 3 lt { n { pop pop } repeat } { n 3 gt { CheckClosed } if n 2 mul -2 roll /y0 ED /x0 ED /y1 ED /x1 ED x1 y1 /x1 x0 x1 add 2 div def /y1 y0 y1 add 2 div def x1 y1 moveto /n n 2 sub def n { Lineto } repeat x1 y1 x0 y0 6 4 roll Lineto Lineto pop pop closepath } ifelse } def % /SymbolPolygon { % on stack [ x y x y ... counttomark % number of elements 2 add /m ED 2 copy m 2 roll % copy last two m 2 div cvi /n ED % n pairs /YA ED /XA ED % the start point n 1 sub { /YB ED /XB ED /XLength XB XA sub def /YLength YB YA sub def /PAngle YLength XLength Atan def /XYLength XLength YLength Pyth def /nSym XYLength SymStep Div cvi def /Shift Symbol stringwidth pop 2 Div def /deltaX XLength nSym Div def /deltaY YLength nSym Div def XA Shift sub YA Shift sub moveto nSym { gsave rotateSymbol { PAngle 180 sub CorrAngle sub rotate } if Symbol show grestore deltaX deltaY rmoveto } repeat % XB Shift sub YB Shift sub moveto Symbol show /YA YB def /XA XB def } repeat pop % delete the mark symbol } def % /Diamond { /mtrx CM def T rotate /h ED /w ED dup 0 eq { pop } { CLW mul neg /d ED /a w h Atan def /h d a sin Div h add def /w d a cos Div w add def } ifelse mark w 2 div h 2 div w 0 0 h neg w neg 0 0 h w 2 div h 2 div /ArrowA { moveto } def /ArrowB { } def false Line closepath mtrx setmatrix } def % /Triangle { /mtrx CM def translate rotate /h ED 2 div /w ED dup CLW mul /d ED /h h d w h Atan sin Div sub def /w w d h w Atan 2 div dup cos exch sin Div mul sub def mark 0 d w neg d 0 h w d 0 d /ArrowA { moveto } def /ArrowB { } def false Line closepath mtrx % DG/SR modification begin - Jun. 1, 1998 - Patch 3 (from Michael Vulis) % setmatrix } def setmatrix pop } def % DG/SR modification end % /CCA { /y ED /x ED 2 copy y sub /dy1 ED x sub /dx1 ED /l1 dx1 dy1 Pyth def } def % /CC { /l0 l1 def /x1 x dx sub def /y1 y dy sub def /dx0 dx1 def /dy0 dy1 def CCA /dx dx0 l1 c exp mul dx1 l0 c exp mul add def /dy dy0 l1 c exp mul dy1 l0 c exp mul add def /m dx0 dy0 Atan dx1 dy1 Atan sub 2 div cos abs b exp a mul dx dy Pyth Div 2 div def /x2 x l0 dx mul m mul sub def /y2 y l0 dy mul m mul sub def /dx l1 dx mul m mul neg def /dy l1 dy mul m mul neg def } def % /IC { /c c 1 add def c 0 lt { /c 0 def } { c 3 gt { /c 3 def } if } ifelse /a a 2 mul 3 div 45 cos b exp div def CCA /dx 0 def /dy 0 def } def % /BOC { IC CC x2 y2 x1 y1 ArrowA CP 4 2 roll x y curveto } def /NC { CC x1 y1 x2 y2 x y curveto } def /EOC { x dx sub y dy sub 4 2 roll ArrowB 2 copy curveto } def /BAC { IC CC x y moveto CC x1 y1 CP ArrowA } def /NAC { x2 y2 x y curveto CC x1 y1 } def /EAC { x2 y2 x y ArrowB curveto pop pop } def % /OpenCurve { % 5 dict begin NArray n 3 lt { n { pop pop } repeat } { BOC /n n 3 sub def n { NC } repeat EOC } ifelse % end } def % /CurvePath { %% for negative SymStep we calculate the distance SymStep 0 lt { gsave PathLength SymStep div abs /SymStep ED grestore } if 0.5 setflat flattenpath /z 0 def /z0 0 def { /y1 ED /x1 ED /y2 y1 def /x2 x1 def x1 Shift sub y1 Shift sub moveto gsave curveticks { x1 y1 translate startAngle rotate 0 SymbolWidth 2 div moveto 0 SymbolWidth 2 div neg lineto SymbolLinewidth setlinewidth stroke } { startAngle rotate Symbol show } ifelse grestore /z0 z def } { /y ED /x ED PathLength@ z z0 sub SymStep ge { x Shift sub y Shift sub moveto gsave curveticks { y yOld sub x xOld sub Atan 180 sub CorrAngle sub /rotAngle ED x y translate rotAngle rotate 0 SymbolWidth 2 div moveto 0 SymbolWidth 2 div neg lineto SymbolLinewidth setlinewidth stroke } { rotateSymbol { y yOld sub x xOld sub Atan 180 sub CorrAngle sub rotate } if Symbol show } ifelse grestore /z0 z def } if /yOld y def /xOld x def } {} %% the lineto part { /y y2 def /x x2 def PathLength@ x Shift sub y Shift sub moveto gsave curveticks { y yOld sub x xOld sub Atan 180 sub /rotAngle ED x y translate rotAngle rotate 0 SymbolWidth 2 div moveto 0 SymbolWidth 2 div neg lineto SymbolLinewidth setlinewidth stroke } { x Shift sub y Shift sub moveto rotateSymbol { y yOld sub x xOld sub Atan 180 sub CorrAngle sub rotate } if Symbol show } ifelse grestore } pathforall % curveticks % { gsave % x y translate rotAngle rotate % 0 SymbolWidth 2 div moveto 0 SymbolWidth 2 div neg lineto % SymbolLinewidth setlinewidth stroke grestore % } if z } def % /OpenSymbolCurve { OpenCurve 0.1 setflat /Shift Symbol stringwidth pop 2 div def CurvePath } def % /AltCurve { { false NArray n 2 mul 2 roll [ n 2 mul 3 sub 1 roll ] aload /Points ED n 2 mul -2 roll } { false NArray } ifelse n 4 lt { n { pop pop } repeat } { BAC /n n 4 sub def n { NAC } repeat EAC } ifelse } def % /AltOpenSymbolCurve { AltCurve 0.1 setflat /Shift Symbol stringwidth pop 2 div def CurvePath } def % /ClosedCurve { NArray n 3 lt { n { pop pop } repeat } { n 3 gt { CheckClosed } if 6 copy n 2 mul 6 add 6 roll IC CC x y moveto n { NC } repeat closepath pop pop } ifelse } def % /ClosedSymbolCurve { ClosedCurve 0.1 setflat /Shift Symbol stringwidth pop 2 div def CurvePath } def % /CalcBezierSpline {% Christoph Bersch 10 dict begin /getX { Points exch 2 mul get } def /getY { Points exch 2 mul 1 add get } def /n Points length 1 sub 2 idiv def /GetFirstControlPoints { /x n array def /tmp n array def /b 2 def x 0 rhs 0 get b div put 1 1 n 1 sub { /i exch def tmp i 1 b div dup 4 1 roll put i n 1 sub lt { 4 }{ 3.5 } ifelse exch sub /b exch def x i rhs i get x i 1 sub get sub b div put } for 1 1 n 1 sub { n exch sub dup dup x exch 1 sub 2 copy 6 2 roll get 3 1 roll tmp exch get exch x exch get mul sub put } for x } def % n 1 eq { 0 getX 2 mul 1 getX add 3 div 0 getY 2 mul 1 getY add 3 div exch dup 3 1 roll 2 mul 0 getX sub exch dup 3 1 roll 2 mul 0 getY sub [ 0 getX 0 getY 7 3 roll 1 getX 1 getY ] /outPoints exch def } { /outPoints 6 n mul 2 add array def 0 1 n { dup dup 6 mul dup 1 add outPoints exch 5 -1 roll getY put outPoints exch 3 -1 roll getX put } for /rhs n array def 1 1 n 2 sub { rhs exch dup dup getX 4 mul exch 1 add getX 2 mul add put } for rhs 0 0 getX 1 getX 2 mul add put rhs n 1 sub dup getX 8 mul n getX add 2 div put GetFirstControlPoints 1 1 n 2 sub { rhs exch dup dup getY 4 mul exch 1 add getY 2 mul add put } for rhs 0 0 getY 1 getY 2 mul add put rhs n 1 sub dup getY 8 mul n getY add 2 div put GetFirstControlPoints 0 1 n 1 sub { /i exch def 2 copy i get outPoints 6 i mul 3 add 3 -1 roll put i get outPoints 6 i mul 2 add 3 -1 roll put 2 copy i n 1 sub lt { i 1 add get i 1 add getY 2 mul exch sub outPoints 6 i mul 5 add 3 -1 roll put i 1 add get i 1 add getX 2 mul exch sub outPoints 6 i mul 4 add 3 -1 roll put }{ n 1 sub get n getY add 2 div outPoints 6 n 1 sub mul 5 add 3 -1 roll put n 1 sub get n getX add 2 div outPoints 6 n 1 sub mul 4 add 3 -1 roll put } ifelse } for pop pop } ifelse outPoints end } def /Spline { /showpoints ED counttomark 2 div dup cvi /n ED n eq not { exch pop } if ] /Points ED n 1 gt { CalcBezierSpline mark exch aload pop ArrowA n 2 sub { 6 2 roll 4 2 roll curveto } repeat 6 2 roll 4 2 roll ArrowB curveto } if } def /OpenSymbolSpline { Spline 0.1 setflat /Shift Symbol stringwidth pop 2 div def CurvePath } def % /SQ { /r ED r r moveto r r neg L r neg r neg L r neg r L fill } def /ST { /y ED /x ED x y moveto x neg y L 0 x L fill } def /SP { /r ED gsave 0 r moveto 4 { 72 rotate 0 r L } repeat fill grestore } def % /FontDot { DS 2 mul dup matrix scale matrix concatmatrix exch matrix rotate matrix concatmatrix exch findfont exch makefont setfont } def % /Rect { x1 y1 y2 add 2 div moveto % x1 y2 lineto % x2 y2 lineto % x2 y1 lineto % x1 y1 lineto x1 y1 lineto % counter clockwise path x2 y1 lineto x2 y2 lineto x1 y2 lineto closepath } def % /OvalFrame { x1 x2 eq y1 y2 eq or { pop pop x1 y1 moveto x2 y2 L } { y1 y2 sub abs x1 x2 sub abs 2 copy gt { exch pop } { pop } ifelse 2 div exch { dup 3 1 roll mul exch } if 2 copy lt { pop } { exch pop } ifelse /b ED x1 y1 y2 add 2 div moveto x1 y2 x2 y2 b arcto x2 y2 x2 y1 b arcto x2 y1 x1 y1 b arcto x1 y1 x1 y2 b arcto 16 { pop } repeat closepath } ifelse } def % /Frame { % on stack \psk@dimen CLW mul /a ED % save radius 3 -1 roll 2 copy gt { exch } if a sub /y2 ED a add /y1 ED 2 copy gt { exch } if a sub /x2 ED a add /x1 ED 1 index 0 eq { pop pop Rect } { OvalFrame } ifelse } def % /BezierNArray { /f ED counttomark 2 div dup cvi /n ED n eq not { exch pop } if n 1 sub neg 3 mod 3 add 3 mod { 0 0 /n n 1 add def } repeat f { ] aload /Points ED } { n 2 mul 1 add -1 roll pop } ifelse } def % /OpenBezier { BezierNArray n 1 eq { pop pop } { ArrowA n 4 sub 3 idiv { 6 2 roll 4 2 roll curveto } repeat 6 2 roll 4 2 roll ArrowB curveto } ifelse } def % /OpenSymbolBezier { OpenBezier 0.1 setflat /Shift Symbol stringwidth pop 2 div def CurvePath } def % /ClosedBezier { BezierNArray n 1 eq { pop pop } { moveto n 1 sub 3 idiv { 6 2 roll 4 2 roll curveto } repeat closepath } ifelse } def % /ClosedSymbolBezier { /f ED % save showpoints value 2 copy /yEnd ED /xEnd ED counttomark -2 roll 2 copy /yStart ED /xStart ED counttomark 2 roll f ClosedBezier 0.1 setflat /Shift Symbol stringwidth pop 2 div def CurvePath [ xEnd yEnd xStart yStart SymbolLine } def % /BezierShowPoints { gsave Points aload length 2 div cvi /n ED moveto n 1 sub { lineto } repeat CLW 2 div SLW [ 4 4 ] 0 setdash stroke grestore } def % /Parab { /y0 ED /x0 ED /y1 ED /x1 ED /dx x0 x1 sub 3 div def /dy y0 y1 sub 3 div def x0 dx sub y0 dy add x1 y1 ArrowA x0 dx add y0 dy add x0 2 mul x1 sub y1 ArrowB curveto /Points [ x1 y1 x0 y0 x0 2 mul x1 sub y1 ] def } def % /Parab1 { % 1 end | 0 SP /ySP ED /xSP ED /y1 ED /x1 ED /dx xSP x1 sub 3 div def /dy ySP y1 sub 3 div def newpath x1 y1 moveto xSP y1 lineto xSP ySP lineto x1 ySP lineto closepath clip currentpoint newpath moveto xSP dx sub ySP dy add x1 y1 ArrowA xSP dx add ySP dy add xSP 2 mul x1 sub y1 ArrowB curveto /Points [ x1 y1 xSP ySP xSP 2 mul x1 sub y1 ] def } def % /Grid { 40 dict begin newpath /a 4 string def /b ED % psk@gridlabels in pt /c ED % { \pst@usecolor\psgridlabelcolor } /n ED % psk@griddots cvi dup 1 lt { pop 1 } if /s ED % \psk@subgriddiv s div dup 0 eq { pop 1 } if /dy ED s div dup 0 eq { pop 1 } if % \pst@number\psyunit abs /dx ED dy div round dy mul % \pst@number\psxunit abs /y0 ED dx div round dx mul /x0 ED dy div round cvi /y2 ED dx div round cvi /x2 ED dy div round cvi /y1 ED dx div round cvi /x1 ED /h y2 y1 sub 0 gt { 1 } { -1 } ifelse def /w x2 x1 sub 0 gt { 1 } { -1 } ifelse def b 0 gt { /z1 b 4 div CLW 2 div add def %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Helvetica findfont b scalefont setfont % is set in pstricks.tex %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % /NimbusSanL-Regu findfont b scalefont setfont /b b .95 mul CLW 2 div add def } if systemdict /setstrokeadjust known { true setstrokeadjust /t { } def } { /t { transform 0.25 sub round 0.25 add exch 0.25 sub round 0.25 add exch itransform } bind def } ifelse gsave n 0 gt { 1 setlinecap [ 0 dy n div ] dy n div 2 div setdash } { 2 setlinecap } ifelse /i x1 def /f y1 dy mul n 0 gt { dy n div 2 div h mul sub } if def /g y2 dy mul n 0 gt { dy n div 2 div h mul add } if def x2 x1 sub w mul 1 add dup 1000 gt { pop 1000 } if dup % run loop two times: lines and labels { i dx mul dup xGridOffset add y0 moveto % draw the lines dup t f moveto g t L stroke /i i w add def } repeat /i x1 def GridDX div ceiling cvi { i dx mul GridDX mul dup xGridOffset add y0 moveto % plot the labels b 0 gt { gsave c i GridDX mul a cvs dup stringwidth pop /z2 ED w 0 gt {z1} {z1 z2 add neg} ifelse h 0 gt {b neg}{z1} ifelse exch GridDX div z2 2 div sub exch rmoveto show grestore } if /i i w add def } repeat grestore gsave n 0 gt { 1 setlinecap [ 0 dx n div ] dx n div 2 div setdash } { 2 setlinecap } ifelse /i y1 def /f x1 dx mul n 0 gt { dx n div 2 div w mul sub } if def /g x2 dx mul n 0 gt { dx n div 2 div w mul add } if def y2 y1 sub h mul 1 add dup 1000 gt { pop 1000 } if dup % run loop two times: lines and labels { newpath i dy mul dup yGridOffset add x0 exch moveto dup f exch t moveto g exch t L stroke /i i h add def } repeat /i y1 def GridDY div ceiling cvi { newpath i dy mul GridDY mul dup yGridOffset add x0 exch moveto b 0 gt { gsave c i GridDY mul a cvs dup stringwidth pop /z2 ED w 0 gt {z1 z2 add neg} {z1} ifelse h 0 gt {z1} {b neg} ifelse GridDY div b 2 div sub rmoveto show grestore } if /i i h add def } repeat grestore end } def % /ArcArrow { /d ED /b ED /a ED gsave newpath 0 -1000 moveto clip newpath 0 1 0 0 b grestore c mul /e ED pop pop pop r a e d PtoC y add exch x add exch r a PtoC y add exch x add exch b pop pop pop pop a e d CLW 8 div c mul neg d } def % % /isbool { type (booleantype) cvn eq } def % /Ellipse { dup isbool { /MoveToStart ED }{ /MoveToStart false def }ifelse % false or true /rotAngle ED /mtrx CM def T rotAngle rotate scale MoveToStart { 0 0 moveto 1 0 rmoveto } if % move to the start position 0 0 1 5 3 roll arc mtrx setmatrix } def % /ArcAdjust { %%%% Vincent Guirardel % given a target length (targetLength) and an initial angle (angle0) [in the stack], % let M(angle0)=(rx*cos(angle0),ry*sin(angle0))=(x0,y0). % This computes an angle t such that (x0,y0) is at distance % targetLength from the point M(t)=(rx*cos(t),ry*sin(t)). % NOTE: this an absolute angle, it does not have to be added or substracted to angle0 % contrary to TvZ's code. % To achieve, this, one iterates the following process: start with some angle t, % compute the point M' at distance targetLength of (x0,y0) on the semi-line [(x0,y0) M(t)]. % Now take t' (= new angle) so that (0,0) M(t') and M' are aligned. % % Another difference with TvZ's code is that we need d (=add/sub) to be defined. % the value of d = add/sub is used to know on which side we have to move. % It is only used in the initialisation of the angle before the iteration. % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Input stack: 1: target length 2: initial angle % variables used : rx, ry, d (=add/sub) % /targetLength ED /angle0 ED /x0 rx angle0 cos mul def /y0 ry angle0 sin mul def % we are looking for an angle t such that (x0,y0) is at distance targetLength % from the point M(t)=(rx*cos(t),ry*sin(t))) %initialisation of angle (using 1st order approx = TvZ's code) targetLength 57.2958 mul angle0 sin rx mul dup mul angle0 cos ry mul dup mul add sqrt div % if initialisation angle is two large (more than 90 degrees) set it to 90 degrees % (if the ellipse is very curved at the point where we draw the arrow, % % the value can be much more than 360 degrees !) % this should avoid going on the wrong side (more than 180 degrees) or go near % a bad attractive point (at 180 degrees) dup 90 ge { pop 90 } if angle0 exch d % add or sub % maximum number of times to iterate the iterative procedure: % iterative procedure: takes an angle t on top of stack, computes a % better angle (and put it on top of stack) 30 { dup % compute distance D between (x0,y0) and M(t) dup cos rx mul x0 sub dup mul exch sin ry mul y0 sub dup mul add sqrt % if D almost equals targetLength, we stop dup targetLength sub abs 1e-5 le { pop exit } if % stack now contains D t % compute the point M(t') at distance targetLength of (x0,y0) on the semi-line [(x0,y0) M(t)]: % M(t')= ( (x(t)-x0)*targetLength/d+x0 , (y(t)-y0)*targetLength/d+y0 ) exch dup cos rx mul x0 sub exch sin ry mul y0 sub % stack contains: y(t)-y0, x(t)-x0, d 2 index Div targetLength mul y0 add ry Div exch 2 index Div targetLength mul x0 add rx Div % stack contains x(t')/rx , y(t')/ry , d % now compute t', and remove D from stack atan exch pop } repeat % we don't look at what happened... in particular, if targetLength is greater % than the diameter of the ellipse... % the final angle will be around /angle0 + 180. maybe we should treat this pathological case... % after iteration, stack contains an angle t such that M(t) is the tail of the arrow % to give back the result as a an angle relative to angle0 we could add the following line: % angle0 sub 0 exch d % % begin bug fix 2006-01-11 % we want to adjust the new angle t' by a multiple of 360 so that | t'-angle0 | <= 180 %(we don't want to make the ellipse turn more or less than it should)... dup angle0 sub dup abs 180 gt { 180 add 360 div floor 360 mul sub } { pop } ifelse % end bug fix } def % /EllipticArcArrow { /d ED % is add or sub /b ED % arrow procedure /a1 ED % angle gsave newpath 0 -1000 moveto clip % Set clippath far from arrow. newpath 0 1 0 0 b % Draw arrow to determine length. grestore % Length of arrow is on top of stack. Next 3 numbers are junk. % a1 exch ArcAdjust % Angular position of base of arrow. /a2 ED pop pop pop a2 cos rx mul xOrig add % hv 2007-08-29 x->xOrig a2 sin ry mul yOrig add % hv 2007-08-29 y->yOrig a1 cos rx mul xOrig add % a1 sin ry mul yOrig add % % Now arrow tip coor and base coor are on stack. b pop pop pop pop % Draw arrow, and discard coordinates. a2 CLW 8 div % change value of d (test it by looking if `` 1 1 d '' gives 2 or not ) 1 1 d 2 eq { /d { sub } def } { /d { add } def } ifelse ArcAdjust % resets original value of d 1 1 d 2 eq { /d { sub } def } { /d { add } def } ifelse % Adjust angle to give overlap. } def %%------------------ tvz/DG/hv (2004-05-10) end -------------------%% % /Rot { CP CP translate 3 -1 roll neg rotate NET } def % /RotBegin { tx@Dict /TMatrix known not { /TMatrix { } def /RAngle { 0 } def } if /TMatrix [ TMatrix CM ] cvx def /RotAngle ED RotAngle Rot /RAngle [ RAngle dup RotAngle add ] cvx def } def % /RotEnd { /TMatrix [ TMatrix setmatrix ] cvx def /RAngle [ RAngle pop ] cvx def } def % /PutCoor { gsave CP T CM STV exch exec moveto setmatrix CP grestore } def /PutBegin { /TMatrix [ TMatrix CM ] cvx def CP 4 2 roll T moveto } def /PutEnd { CP /TMatrix [ TMatrix setmatrix ] cvx def moveto } def % /Uput { /a ED add 2 div /h ED 2 div /w ED /s a sin def /c a cos def /b s abs c abs 2 copy gt dup /q ED { pop } { exch pop } ifelse def /w1 c b div w mul def /h1 s b div h mul def q { w1 abs w sub dup c mul abs }{ h1 abs h sub dup s mul abs } ifelse } def % /UUput { 5 dict begin /z ED abs /y ED /x ED q { x s div c mul abs y gt }{ x c div s mul abs y gt } ifelse { x x mul y y mul sub z z mul add sqrt z add } { q { x s div } { x c div } ifelse abs } ifelse a PtoC h1 add exch w1 add exch end } def % end %-----------------------------------------------------------------------------% % % END pstricks.pro