/* autogenerated from "macros/Linear/INTEGRAL_m.sci" */
function INTEGRAL_m() {
    INTEGRAL_m.prototype.define = function INTEGRAL_m() {
        this.maxp = 1;
        var minp = -1;
        var rpar = [];
        this.model = scicos_model();
        this.model.state = new ScilabDouble([0]);
        this.model.sim = list(new ScilabString(["integral_func"]), new ScilabDouble([4]));
        this.model.in = new ScilabDouble([1]);
        this.model.out = new ScilabDouble([1]);
        this.model.in2 = new ScilabDouble([1]);
        this.model.out2 = new ScilabDouble([1]);
        this.model.rpar = new ScilabDouble(rpar);
        this.model.blocktype = new ScilabString(["c"]);
        this.model.dep_ut = new ScilabBoolean([false,true]);
        var exprs = string([[0],[0],[0],[this.maxp],[minp]]);
        var gr_i = new ScilabString(["xstringb(orig(1),orig(2),\"INTEGRAL_m\",sz(1),sz(2));"]);
        this.x = new standard_define(new ScilabDouble([2,2]),this.model,new ScilabString([exprs]),gr_i);
        return new BasicBlock(this.x);
    }
    INTEGRAL_m.prototype.details = function INTEGRAL_m() {
        return this.x;
    }
    INTEGRAL_m.prototype.get = function INTEGRAL_m() {
        var exprs = this.graphics.exprs;
        this.set_param_popup_title = "Set Integral block parameters";
        var options = {
            x0:["Initial Condition",this.x0],
            reinit:["With re-intialization (1:yes, 0:no)",this.reinit],
            satur:["With saturation (1:yes, 0:no)",this.satur],
            maxp:["Upper limit",this.maxp],
            lowp:["Lower limit",this.lowp],
        }
        return options;
    }
    INTEGRAL_m.prototype.set = function INTEGRAL_m() {
        var exprs = this.graphics.exprs;
        while (true) {
            var ok = true;
            this.x0 = arguments[0]["x0"];
            this.reinit = parseFloat(arguments[0]["reinit"]);
            this.satur = parseFloat(arguments[0]["satur"]);
            this.maxp = parseFloat(arguments[0]["maxp"]);
            this.lowp = parseFloat(arguments[0]["lowp"]);
            var exprs = [arguments[0]["x0"], arguments[0]["reinit"], arguments[0]["satur"], arguments[0]["maxp"], arguments[0]["lowp"]];
            if (!ok) {
                break;
            }
            if (isreal(this.x0)) {
                var Datatype = 1;
            } else {
                var Datatype = 2;
            }
            if (this.reinit!=0) {
                this.reinit = 1;
            }
            if (this.satur!=0) {
                this.satur = 1;
                if (Datatype==1) {
                    if (size(this.maxp,"*")==1) {
                        this.maxp = this.maxp*ones(this.x0);
                    }
                    if (size(this.lowp,"*")==1) {
                        this.lowp = this.lowp*ones(this.x0);
                    }
                    if ((size(this.x0)!=size(this.maxp)||size(this.x0)!=size(this.lowp))) {
                        message("x0 and Upper limit and Lower limit must have same size");
                        throw "user error";
                        var ok = false;
                    } else if (or(this.maxp<=this.lowp)) {
                        message("Upper limits must be > Lower limits");
                        throw "user error";
                        var ok = false;
                    } else if (or(this.x0>this.maxp)||or(this.x0<this.lowp)) {
                        message("Initial condition x0 should be inside the limits");
                        throw "user error";
                        var ok = false;
                    } else {
                        var rpar = [[real(this.maxp.slice())],[real(this.lowp.slice())]];
                        this.model.nzcross = new ScilabDouble([size(this.x0,"*")]);
                        this.model.nmode = new ScilabDouble([size(this.x0,"*")]);
                    }
                } else if ((Datatype==2)) {
                    if (size(this.maxp,"*")==1) {
                        this.maxp = math.complex(this.maxp*ones(this.x0),(this.maxp*ones(this.x0)));
                    }
                    if (size(this.lowp,"*")==1) {
                        this.lowp = math.complex(this.lowp*ones(this.x0),(this.lowp*ones(this.x0)));
                    }
                    if ((size(this.x0)!=size(this.maxp)||size(this.x0)!=size(this.lowp))) {
                        message("x0 and Upper limit and Lower limit must have same size");
                        throw "user error";
                        var ok = false;
                    } else if (or(real(this.maxp)<=real(this.lowp))||or(imag(this.maxp)<=imag(this.lowp))) {
                        message("Upper limits must be > Lower limits");
                        throw "user error";
                        var ok = false;
                    } else if (or(real(this.x0)>real(this.maxp))||or(real(this.x0)<real(this.lowp))||or(imag(this.x0)>imag(this.maxp))||or(imag(this.x0)<imag(this.lowp))) {
                        message("Initial condition x0 should be inside the limits");
                        throw "user error";
                        var ok = false;
                    } else {
                        var rpar = [[real(this.maxp.slice())],[real(this.lowp.slice())],[imag(this.maxp.slice())],[imag(this.lowp.slice())]];
                        this.model.nzcross = new ScilabDouble([2*size(this.x0,"*")]);
                        this.model.nmode = new ScilabDouble([2*size(this.x0,"*")]);
                    }
                }
            } else {
                var rpar = [];
                this.model.nzcross = new ScilabDouble([0]);
                this.model.nmode = new ScilabDouble([0]);
            }
            if (ok) {
                this.model.rpar = new ScilabDouble(rpar);
                if ((Datatype==1)) {
                    this.model.state = new ScilabDouble([real(this.x0.slice())]);
                    this.model.sim = list(new ScilabString(["integral_func"]), new ScilabDouble([4]));
                    var it = [[1],[ones(this.reinit,1)]];
                    var ot = 1;
                } else if ((Datatype==2)) {
                    this.model.state = new ScilabDouble([real(this.x0.slice())],[imag(this.x0.slice())]);
                    this.model.sim = list(new ScilabString(["integralz_func"]), new ScilabDouble([4]));
                    var it = [[2],[2*ones(this.reinit,1)]];
                    var ot = 2;
                } else {
                    message("Datatype is not supported");
                    throw "user error";
                    var ok = false;
                }
                if (ok) {
                    var in1 = [size(this.x0,1)*[[1],[ones(this.reinit,1)]],size(this.x0,2)*[[1],[ones(this.reinit,1)]]];
                    var out = size(this.x0);
                    var tmpvar0 = set_io(this.model,this.graphics,list(in1,it),list(out,ot),ones(this.reinit,1),[]);
                    this.model = tmpvar0[0];
                    this.graphics = tmpvar0[1];
                    var ok = tmpvar0[2];
                }
            }
            if (ok) {
                this.graphics.exprs = new ScilabDouble([exprs]);
                this.x.graphics = this.graphics;
                this.x.model = this.model;
                break;
            }
        }
        return new BasicBlock(this.x);
    }
    INTEGRAL_m.prototype.get_popup_title = function INTEGRAL_m() {
        return this.set_param_popup_title;
    }
    INTEGRAL_m.prototype.importset = function INTEGRAL_m() {
        var graphics = this.x.graphics;
        var ary = getData(graphics.exprs);
        this.x0 = ary[0];
        this.reinit = ary[1];
        this.satur = ary[2];
        this.maxp = ary[3];
        this.lowp = ary[4];
    }
    INTEGRAL_m.prototype.getContainer = function INTEGRAL_m() { return new BasicBlock(this.x); }
}