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/* autogenerated from "macros/Sources/RAND_m.sci" */
function RAND_m() {
RAND_m.prototype.define = function RAND_m() {
this.a = 0;
this.b = 1;
dt = 0;
this.flag = 0;
function_name = "rndblk_m";
funtyp = 4;
this.model = scicos_model();
this.model.sim = list(new ScilabString(function_name),new ScilabDouble(funtyp));
this.model.in1 = [];
this.model.in2 = [];
this.model.intyp = [];
this.model.out = new ScilabDouble(1);
this.model.out2 = new ScilabDouble(1);
this.model.outtyp = new ScilabDouble(1);
this.model.evtin = new ScilabDouble(1);
this.model.evtout = [];
this.model.state = [];
this.model.dstate = [[int(rand()*(10^7-1))],[0*this.a.slice()]];
this.model.rpar = [this.a.slice(),this.b.slice()];
this.model.ipar = new ScilabDouble(this.flag);
this.model.blocktype = new ScilabString("d");
this.model.firing = [];
this.model.dep_ut = [false,false];
exprs = [[sci2exp(1)],[string(this.flag)],[sci2exp([this.a])],[sci2exp([this.b])],[sci2exp([this.model.dstate[1-1],int(rand()*(10^7-1))])]];
gr_i = [];
this.x = standard_define([3,2],this.model,exprs,gr_i);
return new BasicBlock(this.x);
}
RAND_m.prototype.details = function RAND_m() {
return this.x;
}
RAND_m.prototype.get = function RAND_m() {
var options = {
typ:["Datatype(1=real double 2=complex)",this.typ],
flag:["flag",this.flag],
a:["A",this.a],
b:["B",this.b],
seed_c:["SEED",this.seed_c],
}
return options;
}
RAND_m.prototype.set = function RAND_m() {
this.typ = inverse(arguments[0]["typ"])
this.flag = parseFloat(arguments[0]["flag"])
this.a = parseFloat(arguments[0]["a"])
this.b = parseFloat(arguments[0]["b"])
this.seed_c = arguments[0]["seed_c"]
this.x = arg1;
graphics = arg1.graphics;
exprs = graphics.exprs;
this.model = arg1.model;
if (size(exprs,"*")==14) {
exprs[9-1] = [];
}
while (true) {
[ok,this.typ,this.flag,this.a,this.b,this.seed_c,exprs] = scicos_getvalue([["Set Random generator block parameters"],["flag = 0 : Uniform distribution A is min and A+B max"],["flag = 1 : Normal distribution A is mean and B deviation"],[" "],["A and B must be matrix with equal sizes"]],["Datatype(1=real double 2=complex)","flag","A","B","SEED"],list("vec",1,"vec",1,"mat",[-1,-2],"mat","[-1 -2]","mat",[1,2]),exprs);
if (!ok) {
break;
}
if (this.flag!=0&&this.flag!=1) {
message("flag must be equal to 1 or 0");
} else {
out = size(this.a);
if (this.typ==1) {
function_name = "rndblk_m";
this.model.rpar = [[real(this.a.slice())],[real(this.b.slice())]];
this.model.dstate = [[this.seed_c[1-1]],[0*real(this.a.slice())]];
ot = 1;
} else if (this.typ==2) {
function_name = "rndblkz_m";
ot = 2;
this.model.rpar = [[real(this.a.slice())],[imag(this.a.slice())],[real(this.b.slice())],[imag(this.b.slice())]];
this.model.dstate = [[this.seed_c.slice()],[0*[[real(this.a.slice())],[imag(this.a.slice())]]]];
} else {
message("Datatype is not supported");
ok = false;
}
if (ok) {
[model,graphics,ok] = set_io(this.model,graphics,list([],[]),list(out,ot),1,[]);
if (ok) {
this.model.sim = list(new ScilabString(function_name),new ScilabDouble(4));
graphics.exprs = exprs;
this.model.ipar = new ScilabDouble(this.flag);
this.x.graphics = graphics;
this.x.model = this.model;
break;
}
}
}
}
return new BasicBlock(this.x);
}
}
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