/* autogenerated from "macros/Linear/INTEGRAL_m.sci" */
function INTEGRAL_m() {
INTEGRAL_m.prototype.get = function INTEGRAL_m() {
}
INTEGRAL_m.prototype.set = function INTEGRAL_m() {
x=arg1;
graphics=arg1.graphics;
exprs=graphics.exprs;
model=arg1.model;
while (true) {
[ok,x0,reinit,satur,maxp,lowp,exprs]=scicos_getvalue("Set Integral block parameters",["Initial Condition","With re-intialization (1:yes, 0:no)","With saturation (1:yes, 0:no)","Upper limit","Lower limit"],list("mat",[-1,-1],"vec",1,"vec",1,"mat",[-1,-1],"mat",[-1,-1]),exprs);
if (!ok) {
break
}
if (isreal(x0)) {
Datatype=1;
} else {
Datatype=2;
}
if (reinit!=0) {
reinit=1;
}
if (satur!=0) {
satur=1;
if (Datatype==1) {
if (size(maxp,"*")==1) {
maxp=maxp*ones(x0);
}
if (size(lowp,"*")==1) {
lowp=lowp*ones(x0);
}
if ((size(x0)!=size(maxp)||size(x0)!=size(lowp))) {
message("x0 and Upper limit and Lower limit must have same size");
ok=false;
} else if (or(maxp<=lowp)) {
message("Upper limits must be > Lower limits");
ok=false;
} else if (or(x0>maxp)||or(x0<lowp)) {
message("Initial condition x0 should be inside the limits");
ok=false;
} else {
rpar=[real(maxp.slice()),real(lowp.slice())];
model.nzcross=size(x0,"*");
model.nmode=size(x0,"*");
}
} else if ((Datatype==2)) {
if (size(maxp,"*")==1) {
maxp=math.complex(maxp*ones(x0),(maxp*ones(x0)));
}
if (size(lowp,"*")==1) {
lowp=math.complex(lowp*ones(x0),(lowp*ones(x0)));
}
if ((size(x0)!=size(maxp)||size(x0)!=size(lowp))) {
message("x0 and Upper limit and Lower limit must have same size");
ok=false;
} else if (or(real(maxp)<=real(lowp))||or(imag(maxp)<=imag(lowp))) {
message("Upper limits must be > Lower limits");
ok=false;
} else if (or(real(x0)>real(maxp))||or(real(x0)<real(lowp))||or(imag(x0)>imag(maxp))||or(imag(x0)<imag(lowp))) {
message("Initial condition x0 should be inside the limits");
ok=false;
} else {
rpar=[real(maxp.slice()),real(lowp.slice()),imag(maxp.slice()),imag(lowp.slice())];
model.nzcross=2*size(x0,"*");
model.nmode=2*size(x0,"*");
}
}
} else {
rpar=[];
model.nzcross=0;
model.nmode=0;
}
if (ok) {
model.rpar=rpar;
if ((Datatype==1)) {
model.state=real(x0.slice());
model.sim=list("integral_func",4);
it=[1,ones(reinit,1)];
ot=1;
} else if ((Datatype==2)) {
model.state=[real(x0.slice()),imag(x0.slice())];
model.sim=list("integralz_func",4);
it=[2,2*ones(reinit,1)];
ot=2;
} else {
message("Datatype is not supported");
ok=false;
}
if (ok) {
in1=[size(x0,1)*[1,ones(reinit,1)],size(x0,2)*[1,ones(reinit,1)]];
out=size(x0);
[model,graphics,ok]=set_io(model,graphics,list(in1,it),list(out,ot),ones(reinit,1),[]);
}
}
if (ok) {
graphics.exprs=exprs;
x.graphics=graphics;
x.model=model;
break
}
}
}
INTEGRAL_m.prototype.define = function INTEGRAL_m() {
maxp=1;
minp=-1;
rpar=[];
model=scicos_model();
model.state=0;
model.sim=list("integral_func",4);
model.in1=1;
model.out=1;
model.in2=1;
model.out2=1;
model.rpar=rpar;
model.blocktype="c";
model.dep_ut=[false,true];
exprs=string([0,0,0,maxp,minp]);
gr_i=[];
x=standard_define([2,2],model,exprs,gr_i);
}
INTEGRAL_m.prototype.details = function INTEGRAL_m() {
}
}