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/* autogenerated from "macros/NonLinear/QUANT_f.sci" */
function QUANT_f() {
QUANT_f.prototype.define = function QUANT_f() {
pas = 0.1;
meth = 1;
model = scicos_model();
model.sim = "qzrnd";
model.in1 = -1;
model.out = -1;
model.rpar = pas;
model.ipar = meth;
model.blocktype = "c";
model.dep_ut = [true,false];
exprs = [[string(pas)],[string(meth)]];
gr_i = [];
this.x = standard_define([2,2],model,exprs,gr_i);
}
QUANT_f.prototype.details = function QUANT_f() {
return this.x;
}
QUANT_f.prototype.get = function QUANT_f() {
}
QUANT_f.prototype.set = function QUANT_f() {
this.x = arg1;
graphics = arg1.graphics;
exprs = graphics.exprs;
model = arg1.model;
while (true) {
[ok,pas,meth,exprs] = scicos_getvalue("Set parameters",[["Step"],["Quantization Type (1-4)"]],list("vec",1,"vec",1),exprs);
if (!ok) {
break;
}
if (meth<1||meth>4) {
message("Quantization Type must be from 1 to 4");
} else {
rpar = pas;
model.rpar = rpar;
model.ipar = meth;
switch (meth) {
case 1:
model.sim = "qzrnd";
case 2:
model.sim = "qztrn";
case 3:
model.sim = "qzflr";
case 4:
model.sim = "qzcel";
}
graphics.exprs = exprs;
this.x.graphics = graphics;
this.x.model = model;
break;
}
}
}
}
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