OpenXM_contrib2/asir2000/lib/glib - diff

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Diff for /OpenXM_contrib2/asir2000/lib/glib between version 1.6 and 1.16

version 1.6, 2002/07/14 07:10:01

version 1.16, 2004/03/14 12:56:47

Line 1

/* $OpenXM: OpenXM_contrib2/asir2000/lib/glib,v 1.5 2002/07/14 03:57:24 takayama Exp $ */

/* $OpenXM: OpenXM_contrib2/asir2000/lib/glib,v 1.15 2004/03/11 21:59:36 takayama Exp $ */

/* $Id$ */

/* BUG: this library has not yet been adapted to the new automatic launcher

of ox_plot. 2002, Aug, 4. Do not load glib more than twice.

#define DO_NOT_START_SERVER_EXPLICITLY

/* #define CLIP 1 */

/* #define DEBUG 1 */

#define LIST 4

Line 24 def roots(F) {

Line 29 def roots(F) {

/* ---------------------------------------------- */

def ox_get_errors(P) {

def glib_ox_get_errors(P) {

ox_push_cmd(P,276);

return(ox_pop_cmo(P));

}

Line 41 Glib_canvas_x = 400$

Line 46 Glib_canvas_x = 400$

Glib_canvas_y = 400$

Glib_xmin=0$ Glib_xmax=Glib_canvas_x$

Glib_ymin=0$ Glib_ymax=Glib_canvas_y$

#define START_SERVER \

Glib_math_coordinate=0$

extern Glib_server_started, Glib_process$ \

if (type(Glib_server_started) == 0) { \

Glib_process = ox_launch_nox(0,"ox_plot")$ \

register_handler(reset_plot); \

Glib_server_started = 1$ \

Glib_canvas = -1$

Glib_xmag = 1$ Glib_ymag=1$ Glib_xoffset=0$ Glib_yoffset=0$

Glib_safe_mode = 2 $

Glib_counter = 100$

extern Glib_ps_sx$

extern Glib_ps_sy$

Glib_ps_sx=2$ /* mag=1/2 for PS picture. cf. glib_ps_form, glib_tops */

Glib_ps_sy=2$ /* mag=1/2 for PS picture */

def open_Canvas(P,S) {

open_canvas(P,S);

extern Glib_process;

if (P < 0) P=open_canvas(S); /* BUG, get process No. */

else open_canvas(P,S);

Glib_process = P;

R = ox_pop_cmo(P);

if (ox_get_errors(P) == []) {

if (glib_ox_get_errors(P) == []) {

R = ox_pop_cmo(P);

}else{

debug;

Line 67 def open_Canvas(P,S) {

Line 75 def open_Canvas(P,S) {

return(R);

}

/*&usage begin: glib_open()

It starts the ox_plot server and opens a canvas.

The canvas size is set to {Glib_canvas_x} X {Glib_canvas_y}

(the default value is 400).

This function is automatically called when the user calls glib

functions.

end: */

def glib_open() {

extern Glib_canvas_x, Glib_canvas_y,

Glib_process, Glib_canvas;

Glib_process, Glib_canvas,

START_SERVER

Glib_server_started, Glib_process$

#ifndef DO_NOT_START_SERVER_EXPLICITLY

if (type(Glib_server_started) == 0) {

Glib_process = ox_launch_nox(0,"ox_plot")$

register_handler(reset_plot);

Glib_server_started = 1$

Glib_canvas = open_Canvas(Glib_process,[Glib_canvas_x,Glib_canvas_y])$

#else

Glib_canvas = open_Canvas(-1,[Glib_canvas_x,Glib_canvas_y])$

register_handler(reset_plot);

Glib_server_started = 1$

#endif

glib_check_strict();

return(Glib_canvas);

}

Line 98 def glib_check_strict() {

Line 125 def glib_check_strict() {

if (Glib_canvas < 0) {

glib_open();

}

E = ox_get_errors(Glib_process);

E = glib_ox_get_errors(Glib_process);

if (E != []) {

ox_pops(Glib_process,200);

print(E);

Line 119 def glib_clear() {

Line 146 def glib_clear() {

/*&usage begin: glib_window(Xmin,Ymin,Xmax,Ymax)

It generates a window with the left top corner [{Xmin},{Ymin}] and

the right bottom corner [{Xmax},{Ymax}].

If the global variable {Glib_math_coordinate} is set to 1, mathematical

coordinate system will be employed, i.e., the left top

corner will have the coordinate [{Xmin},{Ymax}].

example: glib_window(-1,-1,10,10);

end: */

def glib_window(Xmin,Ymin,Xmax,Ymax) {

Line 153 def glib_check_arg(X,Y) {

Line 183 def glib_check_arg(X,Y) {

end: */

def glib_putpixel(X,Y) {

extern Glib_process, Glib_canvas,

Glib_xoffset, Glib_yoffset, Glib_xmag, Glib_ymag, Glib_ps;

Glib_xoffset, Glib_yoffset, Glib_xmag, Glib_ymag, Glib_ps,

Glib_math_coordinate, Glib_canvas_y;

if (Glib_canvas < 0) glib_open();

glib_check();

glib_check_arg(X,Y);

C = getopt(color);

Pos = [glib_floor(Glib_xmag*(X+Glib_xoffset)),

if (Glib_math_coordinate) {

glib_floor(Glib_ymag*(Y+Glib_yoffset))];

Pos = [glib_floor(Glib_xmag*(X+Glib_xoffset)),

Glib_canvas_y-glib_floor(Glib_ymag*(Y+Glib_yoffset))];

Pos2= [glib_floor(Glib_xmag*(X+Glib_xoffset)),

glib_floor(Glib_ymag*(Y+Glib_yoffset))];

}else{

Pos = [glib_floor(Glib_xmag*(X+Glib_xoffset)),

glib_floor(Glib_ymag*(Y+Glib_yoffset))];

Pos2= [glib_floor(Glib_xmag*(X+Glib_xoffset)),

Glib_canvas_y-glib_floor(Glib_ymag*(Y+Glib_yoffset))];

}

if ( type(C) != -1 ) {

draw_obj(Glib_process,Glib_canvas,Pos,C);

if (Glib_ps) glib_history(["putpixel",Pos,C]);

if (Glib_ps) glib_history(["putpixel",Pos2,C]);

}else{

draw_obj(Glib_process,Glib_canvas,Pos);

if (Glib_ps) glib_history(["putpixel",Pos,0]);

if (Glib_ps) glib_history(["putpixel",Pos2,0]);

}

/*&usage begin: glib_line(X0,Y0,X1,Y1|color)

It draw the line [{X0},{Y0}]-- [{X1},{Y1}]with {color}

It draws the line [{X0},{Y0}]-- [{X1},{Y1}] with {color}

example: glib_line(0,0,5,3/2 | color=0xff00ff);

end: */

def glib_line(X0,Y0,X1,Y1) {

Line 188 def glib_clip_line(X0,Y0,X1,Y1,Color) {

Line 228 def glib_clip_line(X0,Y0,X1,Y1,Color) {

/* X0, Y0, X1, Y1 should be integers.

Coordinates are already translated. */

extern Glib_process, Glib_canvas, Glib_canvas_x, Glib_canvas_y,

Glib_ps;

Glib_ps, Glib_math_coordinate;

if (Glib_canvas < 0) glib_open();

if (Glib_ps) {

Line 230 if (Glib_ps) {

Line 270 if (Glib_ps) {

}

glib_check();

Pos = [glib_floor(X0),glib_floor(Y0),glib_floor(X1),glib_floor(Y1)];

if (Glib_math_coordinate) {

Pos = [glib_floor(X0),Glib_canvas_y-glib_floor(Y0),

glib_floor(X1),Glib_canvas_y-glib_floor(Y1)];

Pos2= [glib_floor(X0),glib_floor(Y0),glib_floor(X1),glib_floor(Y1)];

}else{

Pos = [glib_floor(X0),glib_floor(Y0),glib_floor(X1),glib_floor(Y1)];

Pos2 = [glib_floor(X0),Glib_canvas_y-glib_floor(Y0),

glib_floor(X1),Glib_canvas_y-glib_floor(Y1)];

}

if ( type(Color) != -1 ) {

draw_obj(Glib_process,Glib_canvas,Pos,Color);

if (Glib_ps) glib_history(["line",Pos,Color]);

if (Glib_ps) glib_history(["line",Pos2,Color]);

}else{

draw_obj(Glib_process,Glib_canvas,Pos);

if (Glib_ps) glib_history(["line",Pos,0]);

if (Glib_ps) glib_history(["line",Pos2,0]);

}

Line 287 def glib_clip1_y(X0,Y0,X1,Y1,Clip) {

Line 335 def glib_clip1_y(X0,Y0,X1,Y1,Clip) {

end: */

def glib_print(X,Y,Text) {

extern Glib_process, Glib_canvas,

Glib_xoffset, Glib_yoffset, Glib_xmag, Glib_ymag, Glib_ps;

Glib_xoffset, Glib_yoffset, Glib_xmag, Glib_ymag, Glib_ps,

Glib_math_coordinate, Glib_canvas_y;

if (Glib_canvas < 0) glib_open();

glib_check();

glib_check_arg(X,Y);

if (type(Text) != 7) error("glib_print(X,Y,Text): Text must be a string.");

C = getopt(color);

Pos = [glib_floor(Glib_xmag*(X+Glib_xoffset)),

if (Glib_math_coordinate) {

glib_floor(Glib_ymag*(Y+Glib_yoffset))];

Pos = [glib_floor(Glib_xmag*(X+Glib_xoffset)),

Glib_canvas_y-glib_floor(Glib_ymag*(Y+Glib_yoffset))];

Pos2= [glib_floor(Glib_xmag*(X+Glib_xoffset)),

glib_floor(Glib_ymag*(Y+Glib_yoffset))];

}else{

Pos = [glib_floor(Glib_xmag*(X+Glib_xoffset)),

glib_floor(Glib_ymag*(Y+Glib_yoffset))];

Pos2= [glib_floor(Glib_xmag*(X+Glib_xoffset)),

Glib_canvas_y-glib_floor(Glib_ymag*(Y+Glib_yoffset))];

}

if ( type(C) != -1 ) {

draw_string(Glib_process,Glib_canvas,Pos,Text,C);

if (Glib_ps) glib_history(["print",Pos,Text,C]);

if (Glib_ps) glib_history(["print",Pos2,Text,C]);

}else{

draw_string(Glib_process,Glib_canvas,Pos,Text);

if (Glib_ps) glib_history(["print",Pos,Text,0]);

if (Glib_ps) glib_history(["print",Pos2,Text,0]);

}

def glib_history(L) {

extern Glib_h, Glib_canvas_x, Glib_canvas_y;

extern Glib_h, Glib_canvas_x, Glib_canvas_y,

Glib_math_coodinate;

if (L[0] == "putpixel" || L[0] == "print") {

if (L[1][0] <= Glib_canvas_x && L[1][0] >= 0) {

if (L[1][1] <= Glib_canvas_x && L[1][1] >= 0)

Line 317 def glib_history(L) {

Line 376 def glib_history(L) {

return 0;

}

#define xxx(x) idiv(x,Glib_ps_sx)

#define yyy(y) idiv(y,Glib_ps_sy)

/*&usage begin: glib_tops()

If Glib_ps is set to 1,

it returns a postscript program to draw the picture on the canvas.

ref: print_output

end: */

def glib_tops() {

extern Glib_h;

return glib_ps(Glib_h);

}

def glib_ps(L) {

PS = "";

extern Glib_ps_sx;

extern Glib_ps_sy;

PS = string_to_tb("");

Prev_color = 0;

/* Prolog */

PS += "%%!PS-Adobe-1.0\n";

write_to_tb("%%!PS-Adobe-1.0\n",PS);

PS += "%%BoundingBox: 0 0 " +

write_to_tb("%%BoundingBox: 0 0 " +

rtostr(Glib_canvas_x) + " " + rtostr(Glib_canvas_y) + "\n";

rtostr(xxx(Glib_canvas_x)) + " " + rtostr(yyy(Glib_canvas_y)) + "\n",PS);

PS += "%%Creator: This is generated by ifplot\n";

write_to_tb("%%Creator: This is generated by ifplot\n",PS);

PS += "%%Title: ifplot\n";

write_to_tb("%%Title: ifplot\n",PS);

PS += "%%EndComments: \n";

write_to_tb("%%EndComments: \n",PS);

PS += "0.1 setlinewidth \n";

write_to_tb("0.1 setlinewidth \n",PS);

PS += "2 setlinecap \n";

write_to_tb("2 setlinecap \n",PS);

PS += "2 setlinejoin \n";

write_to_tb("2 setlinejoin \n",PS);

PS += "/ifplot_putpixel { \n";

write_to_tb("/ifplot_putpixel { \n",PS);

PS += " /yyy 2 1 roll def /xxx 2 1 roll def \n";

write_to_tb(" /yyy 2 1 roll def /xxx 2 1 roll def \n",PS);

PS += " gsave newpath xxx yyy .5 0 360 arc \n";

write_to_tb(" gsave newpath xxx yyy .5 0 360 arc \n",PS);

PS += " fill grestore \n";

write_to_tb(" fill grestore \n",PS);

PS += "} def \n";

write_to_tb("} def \n",PS);

L = reverse(L);

N = length(L);

Line 350 def glib_ps(L) {

Line 415 def glib_ps(L) {

C = L[I];

if (C[length(C)-1] != Prev_color) {

Prev_color = C[length(C)-1];

PS += rtostr(deval(ishift(Prev_color,16)/256)) + " " +

write_to_tb(rtostr(deval(ishift(Prev_color,16)/256)) + " " +

rtostr(deval(iand(ishift(Prev_color,8),0xff)/256)) + " " +

rtostr(deval(iand(Prev_color,0xff)/256)) + " setrgbcolor \n";

rtostr(deval(iand(Prev_color,0xff)/256)) + " setrgbcolor \n",PS);

}

if (C[0] == "putpixel") {

PS += rtostr(C[1][0]) + " " + rtostr(C[1][1]) + " ifplot_putpixel \n";

write_to_tb(rtostr(xxx(C[1][0])) + " " + rtostr(yyy(C[1][1])) + " ifplot_putpixel \n",PS);

}

if (C[0] == "line") {

PS += " newpath ";

write_to_tb(" newpath ",PS);

PS += rtostr(C[1][0]) + " " + rtostr(C[1][1]) + " moveto " +

write_to_tb(rtostr(xxx(C[1][0])) + " " + rtostr(yyy(C[1][1])) + " moveto " +

rtostr(C[1][2]) + " " + rtostr(C[1][3]) + " lineto stroke \n";

rtostr(xxx(C[1][2])) + " " + rtostr(yyy(C[1][3])) + " lineto stroke \n",PS);

}

if (C[0] == "print") {

PS += "/Times-Roman findfont 10 scalefont setfont \n";

write_to_tb("/Times-Roman findfont 10 scalefont setfont \n",PS);

PS += rtostr(C[1][0]) + " " + rtostr(C[1][1]) + " moveto ";

write_to_tb(rtostr(xxx(C[1][0])) + " " + rtostr(yyy(C[1][1])) + " moveto ",PS);

PS += "(" + C[2] + ") show \n";

write_to_tb("(" + C[2] + ") show \n",PS);

}

/* Epilog */

PS += "0 0 0 setrgbcolor \n";

write_to_tb("0 0 0 setrgbcolor \n",PS);

PS += "showpage \n";

write_to_tb("showpage \n",PS);

return PS;

return tb_to_string(PS);

}

/*&usage begin: glib_ps_form(S)

It returns the PS code generated by executing {S}

(experimental).

example: glib_ps_form(quote( glib_line(0,0,100,100) ));

example: glib_ps_form(quote([glib_line(0,0,100,100),glib_line(100,0,0,100)]));

ref: glib_tops

end: */

/* Todo. Change the canvas size. */

def glib_ps_form(F) {

extern Glib_h;

extern Glib_ps;

H = Glib_h; /* push Glib_h */

P = Glib_ps; /* push Glib_ps */

Glib_ps=1; Glib_h = [];

if (type(F) != 17) {

return "Error: argument should be quote(...).";

}

eval_quote(F);

/* bug. eval_str causes seg fault for ccurve.rr main(8) */

R = glib_tops();

Glib_h = H; /* pop Glib_h */

Glib_ps = P; /* pop Glib_ps */

return R;

}

/*&usage begin: glib_plot(F)

It plots an object {F} on the glib canvas.

example: glib_plot([[0,1],[0.1,0.9],[0.2,0.7],[0.3,0.5],[0.4,0.8]]);

example: glib_plot(tan(x));

end: */

/* bug, xmin, xmax, color should be optional variables. */

def glib_plot(F) {

Opt = getopt();

taka_glib_plot(F,Opt);

}

end$

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