/* autogenerated from "macros/Misc/RATELIMITER.sci" */
function RATELIMITER() {
    RATELIMITER.prototype.define = function RATELIMITER() {
        this.minp = -1;
        this.maxp = 1;
        rpar = [[this.maxp],[this.minp]];
        model = scicos_model();
        model.sim = list("ratelimiter",4);
        model.in1 = 1;
        model.out = 1;
        model.rpar = rpar;
        model.blocktype = "c";
        model.dep_ut = [true,false];
        exprs = [[string(this.maxp)],[string(this.minp)]];
        gr_i = [];
        this.x = standard_define([3.5,2],model,exprs,gr_i);
        return new BasicBlock(this.x);
    }
    RATELIMITER.prototype.details = function RATELIMITER() {
        return this.x;
    }
    RATELIMITER.prototype.get = function RATELIMITER() {
        var options = {
            maxp:["max slope",this.maxp],
            minp:["min slope",this.minp],
        }
        return options;
    }
    RATELIMITER.prototype.set = function RATELIMITER() {
        this.maxp = parseFloat(arguments[0]["maxp"])
        this.minp = parseFloat(arguments[0]["minp"])
        this.x = arg1;
        graphics = arg1.graphics;
        exprs = graphics.exprs;
        model = arg1.model;
        while (true) {
            [ok,this.maxp,this.minp,exprs] = scicos_getvalue("Set rate limiter parameters",["max slope","min slope"],list("vec",1,"vec",1),exprs);
            if (!ok) {
                break;
            }
            if (this.maxp<=this.minp||this.maxp<=0||this.minp>=0) {
                message("We must have max_slope> 0 > min_slope.");
            } else {
                rpar = [[this.maxp],[this.minp]];
                model.rpar = rpar;
                graphics.exprs = exprs;
                this.x.graphics = graphics;
                this.x.model = model;
                break;
            }
        }
        return new BasicBlock(this.x);
    }
}