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/* autogenerated from "macros/Sinks/CSCOPXY3D.sci" */
function CSCOPXY3D() {
CSCOPXY3D.prototype.define = function CSCOPXY3D() {
this.win = -1;
this.clrs = [[1],[2],[3],[4],[5],[6],[7],[13]];
this.siz = [[1],[1],[1],[1],[1],[1],[1],[1]];
this.wdim = [[600],[400]];
this.wpos = [[-1],[-1]];
this.N = 2;
this.param3ds = [[50],[280]];
this.vec_x = [[-15],[15]];
this.vec_y = [[-15],[15]];
this.vec_z = [[-15],[15]];
this.nbr_curves = 1;
this.model = scicos_model();
this.model.sim = list(new ScilabString(["cscopxy3d"]), new ScilabDouble([4]));
this.model.in1 = [[1],[1],[1]];
this.model.in2 = [[1],[1],[1]];
this.model.intyp = [[1],[1],[1]];
this.model.evtin = new ScilabDouble([1]);
this.model.rpar = [[this.vec_x.slice()],[this.vec_y.slice()],[this.vec_z.slice()],[this.param3ds.slice()]];
this.model.ipar = [[this.win],[8],[this.N],[this.clrs.slice()],[this.siz.slice()],[8],[this.wpos.slice()],[this.wdim.slice()],[this.nbr_curves]];
this.model.blocktype = new ScilabString(["d"]);
this.model.dep_ut = [false,false];
exprs = [[string(this.nbr_curves)],[strcat(string(this.clrs)," ")],[strcat(string(this.siz)," ")],[string(this.win)],[sci2exp([])],[sci2exp(this.wdim)],[strcat(string(this.vec_x)," ")],[strcat(string(this.vec_y)," ")],[strcat(string(this.vec_z)," ")],[strcat(string(this.param3ds)," ")],[string(this.N)]];
gr_i = [];
this.x = standard_define([2,2],this.model,exprs,gr_i);
return new BasicBlock(this.x);
}
CSCOPXY3D.prototype.details = function CSCOPXY3D() {
return this.x;
}
CSCOPXY3D.prototype.get = function CSCOPXY3D() {
var options = {
nbr_curves:["Number of curves",this.nbr_curves],
clrs:["color (>0) or mark (<0)",this.clrs.toString().replace(/,/g," ")],
siz:["Line or Mark Size",this.siz.toString().replace(/,/g," ")],
win:["Output window number (-1 for automatic)",this.win],
wpos:["Output window position",this.wpos.toString().replace(/,/g," ")],
wdim:["Output window sizes",this.wdim.toString().replace(/,/g," ")],
vec_x:["Xmin and Xmax",this.vec_x.toString().replace(/,/g," ")],
vec_y:["Ymin and Ymax",this.vec_y.toString().replace(/,/g," ")],
vec_z:["Zmin and Zmax",this.vec_z.toString().replace(/,/g," ")],
param3ds:["Alpha and Theta",this.param3ds.toString().replace(/,/g," ")],
N:["Buffer size",this.N],
}
return options;
}
CSCOPXY3D.prototype.set = function CSCOPXY3D() {
this.nbr_curves = parseFloat(arguments[0]["nbr_curves"])
this.clrs = inverse(arguments[0]["clrs"])
this.siz = inverse(arguments[0]["siz"])
this.win = parseFloat(arguments[0]["win"])
this.wpos = inverse(arguments[0]["wpos"])
this.wdim = inverse(arguments[0]["wdim"])
this.vec_x = inverse(arguments[0]["vec_x"])
this.vec_y = inverse(arguments[0]["vec_y"])
this.vec_z = inverse(arguments[0]["vec_z"])
this.param3ds = inverse(arguments[0]["param3ds"])
this.N = parseFloat(arguments[0]["N"])
this.x = arg1;
graphics = arg1.graphics;
exprs = graphics.exprs;
this.model = arg1.model;
while (true) {
[ok,this.nbr_curves,this.clrs,this.siz,this.win,this.wpos,this.wdim,this.vec_x,this.vec_y,this.vec_z,this.param3ds,this.N,exprs] = scicos_getvalue("Set Scope parameters",["Number of curves","color (>0) or mark (<0)","Line or Mark Size","Output window number (-1 for automatic)","Output window position","Output window sizes","Xmin and Xmax","Ymin and Ymax","Zmin and Zmax","Alpha and Theta","Buffer size"],list("vec",1,"vec",-1,"vec",-1,"vec",1,"vec",-1,"vec",-1,"vec",2,"vec",2,"vec",2,"vec",2,"vec",1),exprs);
if (!ok) {
break;
}
mess = [];
if (size(this.wpos,"*")!=0&&size(this.wpos,"*")!=2) {
mess = [[mess],["Window position must be [] or a 2 vector"],[" "]];
ok = false;
}
if (size(this.wdim,"*")!=0&&size(this.wdim,"*")!=2) {
mess = [[mess],["Window dim must be [] or a 2 vector"],[" "]];
ok = false;
}
if (size(this.clrs,"*")!=size(this.siz,"*")) {
mess = [[mess],["Colors and Size must have same size"],[" "]];
ok = false;
}
if (this.nbr_curves<=0) {
mess = [[mess],["Number of curves cannot be negative or null"],[" "]];
ok = false;
}
if (this.win<-1) {
mess = [[mess],["Window number cannot be inferior than -1"],[" "]];
ok = false;
}
if (this.N<1) {
mess = [[mess],["Buffer size must be at least 1"],[" "]];
ok = false;
}
if (this.N<2) {
for (i=1;i<=size(this.clrs,"*");i+=1) {
if (this.clrs[i-1]>0) {
mess = [[mess],["Buffer size must be at least 2 or Change a color (must be >0)"],[" "]];
ok = false;
}
}
}
if (this.vec_y[1-1]>=this.vec_y[2-1]) {
mess = [[mess],["Ymax must be higher than Ymin"],[" "]];
ok = false;
}
if (this.vec_x[1-1]>=this.vec_x[2-1]) {
mess = [[mess],["Xmax must be higher than Xmin"],[" "]];
ok = false;
}
if (this.vec_z[1-1]>=this.vec_z[2-1]) {
mess = [[mess],["Zmax must be higher than Zmin"],[" "]];
ok = false;
}
if (ok) {
in1 = this.nbr_curves*ones(3,1);
in2 = ones(3,1);
[this.model,graphics,ok] = set_io(this.model,graphics,list([in1,in2],ones(3,1)),list(),ones(1,1),[]);
if (this.wpos==[]) {
this.wpos = [[-1],[-1]];
}
if (this.wdim==[]) {
this.wdim = [[-1],[-1]];
}
rpar = [[this.vec_x.slice()],[this.vec_y.slice()],[this.vec_z.slice()],[this.param3ds.slice()]];
size_siz = size(this.siz,"*");
ipar = [[this.win],[size_siz],[this.N],[this.clrs.slice()],[this.siz.slice()],[1],[this.wpos.slice()],[this.wdim.slice()],[this.nbr_curves]];
this.model.rpar = rpar;
this.model.ipar = ipar;
graphics.exprs = exprs;
this.x.graphics = graphics;
this.x.model = this.model;
break;
} else {
message(mess);
}
}
return new BasicBlock(this.x);
}
}
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