Limiter
function [x,y,typ]=Limiter(job,arg1,arg2)
// Copyright INRIA
// the automatically generated interface block for Modelica Limiter.mo model
// - avec un dialogue de saisie de parametre
x=[];y=[];typ=[];
select job
case 'plot' then
standard_draw(arg1,%f,Limiter_draw_ports)
case 'getinputs' then
[x,y,typ]=Limiter_inputs(arg1)
case 'getoutputs' then
[x,y,typ]=Limiter_outputs(arg1)
case 'getorigin' then
[x,y]=standard_origin(arg1)
case 'set' then
x=arg1;
graphics=arg1.graphics;exprs=graphics.exprs
model=arg1.model;
x=arg1
exprs=x.graphics.exprs
while %t do
[ok,uMax,uMin,exprs]=getvalue(["Set Limiter block parameters:";"";"uMax: Upper limit";"uMin: Lower limit"],["uMax";"uMin"],list("vec",1,"vec",1),exprs)
if ~ok then break,end
x.model.equations.parameters(2)=list(uMax,uMin)
x.graphics.exprs=exprs
break
end
case 'define' then
ModelName="Limiter"
PrametersValue=[]
ParametersName=["uMax";"uMin"]
model=scicos_model()
Typein=[];Typeout=[];MI=[];MO=[]
P=[-5,50,2,0;105,50,-2,0]
PortName=["RealInputx";"RealOutputx"]
for i=1:size(P,'r')
if P(i,3)==1 then Typein= [Typein; 'E'];MI=[MI;PortName(i)];end
if P(i,3)==2 then Typein= [Typein; 'I'];MI=[MI;PortName(i)];end
if P(i,3)==-1 then Typeout=[Typeout;'E'];MO=[MO;PortName(i)];end
if P(i,3)==-2 then Typeout=[Typeout;'I'];MO=[MO;PortName(i)];end
end
model=scicos_model()
mo=modelica()
model.sim=ModelName;
mo.inputs=MI;
mo.outputs=MO;
model.rpar=PrametersValue;
mo.parameters=list(ParametersName,PrametersValue,zeros(ParametersName));
exprs=["1";"-1"]
gr_i=["";"if orient then";" xpolys(orig(1)+[0.5,0.05;0.5,0.84]*sz(1),orig(2)+[0.05,0.5;0.84,0.5]*sz(2),[3,3])";" xset(''thickness'',2);";" xpolys(orig(1)+[0.1;0.25;0.75;0.9]*sz(1),orig(2)+[0.15;0.15;0.85;0.85]*sz(2),5)";" xset(''color'',[2,2])";" xfpolys(orig(1)+[0.96,0.5;0.85,0.46;0.85,0.54;0.96,0.5]*sz(1),orig(2)+[0.5,0.97;0.54,0.86;0.46,0.86;0.5,0.97]*sz(2),[1,1])";" xset(''thickness'',1);";" xpolys(orig(1)+[0;0;1;1;0]*sz(1),orig(2)+[1;0;0;1;1]*sz(2),3)";"else";" xpolys(orig(1)+[0.5,0.95;0.5,0.16]*sz(1),orig(2)+[0.05,0.5;0.84,0.5]*sz(2),[3,3])";" xset(''thickness'',2);";" xpolys(orig(1)+[0.9;0.75;0.25;0.1]*sz(1),orig(2)+[0.15;0.15;0.85;0.85]*sz(2),5)";" xset(''color'',[2,2])";" xfpolys(orig(1)+[0.04,0.5;0.15,0.54;0.15,0.46;0.04,0.5]*sz(1),orig(2)+[0.5,0.97;0.54,0.86;0.46,0.86;0.5,0.97]*sz(2),[1,1])";" xset(''thickness'',1);";" xpolys(orig(1)+[1;1;0;0;1]*sz(1),orig(2)+[1;0;0;1;1]*sz(2),3)";"end"]
model.blocktype='c'
model.dep_ut=[%f %t]
mo.model=ModelName
model.equations=mo
model.in=ones(size(MI,'*'),1)
model.out=ones(size(MO,'*'),1)
x=standard_define([2,2],model,exprs,list(gr_i,0))
x.graphics.in_implicit=Typein;
x.graphics.out_implicit=Typeout;
end
endfunction
//=========================
function Limiter_draw_ports(o)
[orig,sz,orient]=(o.graphics.orig,o.graphics.sz,o.graphics.flip)
xset('pattern',default_color(0))
// draw input/output ports
//------------------------
// [x_in_Icon,y_in_Icon,type(2=imp_in/-2:imp_out/1=exp_input/-1_exp_output),orientation(degree)]
P=[-5,50,2,0;105,50,-2,0]
//============================
// setting the input/ outputs and direction
// implicit port: if it's located in the right it's output and while,
// else black
// explicit ports:
in= [-1 -1; 1 0;-1 1; -1 -1; -1 0]*diag([xf/28,yf/28]) ;// left_triangle
out= [-1 -1; 1 0;-1 1; -1 -1; 1 0]*diag([xf/28,yf/28]) ;// downward_triangle
in2= [-1 -1; 1 -1; 1 1; -1 1; -1 -1; 0 0]*diag([xf/28,yf/28])
out2=[ 1 1;-1 1;-1 -1; 1 -1; 1 1; 0 0]*diag([xf/28,yf/28])
xset('pattern',default_color(1))
xset('thickness',1)
if orient then
for i=1:size(P,'r')
theta=P(i,4)*%pi/180;
R=[cos(theta),sin(theta);sin(-theta),cos(theta)];
if P(i,3)==1 then // explicit
inR=in*R;
xfpoly(orig(1)+inR(:,1)+P(i,1)*sz(1)/100,orig(2)+inR(:,2)+P(i,2)*sz(2)/100,1)
end
if P(i,3)==-1 then
outR=out*R;
xfpoly(orig(1)+outR(:,1)+P(i,1)*sz(1)/100,orig(2)+outR(:,2)+P(i,2)*sz(2)/100,1)
end
if P(i,3)==2 then // deciding the port's color: black, if x<sz(1)/2 else white.
in2R=in2*R;
xfpoly(orig(1)+in2R(:,1)+P(i,1)*sz(1)/100,orig(2)+ in2R(:,2)+P(i,2)*sz(2)/100,1)
end
if P(i,3)==-2 then // deciding the port's color: black, if x<sz(1)/2 else white.
out2R=out2*R;
xpoly(orig(1)+out2R(:,1)+P(i,1)*sz(1)/100,orig(2)+ out2R(:,2)+P(i,2)*sz(2)/100, 'lines',1)
end
end
else
for i=1:size(P,'r')
theta=P(i,4)*%pi/180;
R=[cos(theta),sin(theta);sin(-theta),cos(theta)];
if P(i,3)==1 then // explicit
inR=in*R;
xfpoly(orig(1)+sz(1)-inR(:,1)-P(i,1)*sz(1)/100,orig(2)+inR(:,2)+P(i,2)*sz(2)/100,1)
end
if P(i,3)==-1 then // explicit
outR=out*R;
xfpoly(orig(1)+sz(1)-outR(:,1)-P(i,1)*sz(1)/100,orig(2)+outR(:,2)+P(i,2)*sz(2)/100,1)
end
if P(i,3)==2 then // deciding the port's color: black, if x<sz(1)/2 else white.
in2R=in2*R;
xfpoly(orig(1)+sz(1)-in2R(:,1)-P(i,1)*sz(1)/100,orig(2)+ in2R(:,2)+P(i,2)*sz(2)/100,1)
end
if P(i,3)==-2 then // deciding the port's color: black, if x<sz(1)/2 else white.
out2R=out2*R;
xpoly(orig(1)+sz(1)-out2R(:,1)-P(i,1)*sz(1)/100,orig(2)+ out2R(:,2)+P(i,2)*sz(2)/100, 'lines',1)
end
end
end
endfunction
//=========================
function [x,y,typ]=Limiter_inputs(o)
// Copyright INRIA
xf=60
yf=40
[orig,sz,orient]=(o.graphics.orig,o.graphics.sz,o.graphics.flip)
//[orig,sz,orient]=o(2)(1:3);
inp=size(o.model.in,1);clkinp=size(o.model.evtin,1);
// [x_in_Icon,y_in_Icon,type(2=imp/1=exp_input/-1_exp_output),orientation(degree)]
P=[-5,50,2,0;105,50,-2,0]
in= [-1 -1; 1 0;-1 1; -1 -1; -1 0]*diag([xf/28,yf/28]) ;// left_triangle
out= [-1 -1; 1 0;-1 1; -1 -1; 1 0]*diag([xf/28,yf/28]) ;// downward_triangle
in2= [-1 -1; 1 -1; 1 1; -1 1; -1 -1; 0 0]*diag([xf/28,yf/28])
out2=[ 1 1;-1 1;-1 -1; 1 -1; 1 1; 0 0]*diag([xf/28,yf/28])
x=[];y=[];typ=[]
if orient then
for i=1:size(P,'r')
theta=P(i,4)*%pi/180;
R=[cos(theta),sin(theta);sin(-theta),cos(theta)];
if (P(i,3))==1 then // explicit_input
inR=in($,:)*R;
x=[x,orig(1)+inR(:,1)+P(i,1)*sz(1)/100];
y=[y,orig(2)+inR(:,2)+P(i,2)*sz(2)/100];
typ=[typ,1];
end
if(P(i,3)==2) then // implicit
in2R=in2($,:)*R;
x=[x,orig(1)+in2R(:,1)+P(i,1)*sz(1)/100];// Black
y=[y,orig(2)+in2R(:,2)+P(i,2)*sz(2)/100];
typ=[typ,2];
end
end
else
for i=1:size(P,'r')
theta=P(i,4)*%pi/180;
R=[cos(theta),sin(theta);sin(-theta),cos(theta)];
if (P(i,3))==1 then // explicit_input
inR=in($,:)*R;
x=[x,orig(1)+sz(1)-inR(:,1)-P(i,1)*sz(1)/100];
y=[y,orig(2)+inR(:,2)+P(i,2)*sz(2)/100];
typ=[typ,1];
end
if(P(i,3)==2) then // implicit
in2R=in2($,:)*R;
x=[x,orig(1)+sz(1)-in2R(:,1)-P(i,1)*sz(1)/100];
y=[y,orig(2)+in2R(:,2)+P(i,2)*sz(2)/100];
typ=[typ,2];
end
end
end
endfunction
//=========================
function [x,y,typ]=Limiter_outputs(o)
// Copyright INRIA
xf=60
yf=40
[orig,sz,orient]=(o.graphics.orig,o.graphics.sz,o.graphics.flip)
out=size(o.model.out,1);clkout=size(o.model.evtout,1);
P=[-5,50,2,0;105,50,-2,0]
in= [-1 -1; 1 0;-1 1; -1 -1; -1 0]*diag([xf/28,yf/28]) ;// left_triangle
out= [-1 -1; 1 0;-1 1; -1 -1; 1 0]*diag([xf/28,yf/28]) ;// downward_triangle
in2= [-1 -1; 1 -1; 1 1; -1 1; -1 -1; 0 0]*diag([xf/28,yf/28])
out2=[ 1 1;-1 1;-1 -1; 1 -1; 1 1; 0 0]*diag([xf/28,yf/28])
x=[];y=[];typ=[];
if orient then
for i=1:size(P,'r')
theta=P(i,4)*%pi/180;
R=[cos(theta),sin(theta);sin(-theta),cos(theta)];
if (P(i,3))==-1 then // explicit_output
outR=out($,:)*R;
x=[x,orig(1)+outR(:,1)+P(i,1)*sz(1)/100];
y=[y,orig(2)+outR(:,2)+P(i,2)*sz(2)/100];
typ=[typ,1];
end
if(P(i,3)==-2) then // implicit
out2R=out2($,:)*R;
x=[x,orig(1)+out2R(:,1)+P(i,1)*sz(1)/100];
y=[y,orig(2)+out2R(:,2)+P(i,2)*sz(2)/100];
typ=[typ,2];
end
end
else
for i=1:size(P,'r')
theta=P(i,4)*%pi/180;
R=[cos(theta),sin(theta);sin(-theta),cos(theta)];
if (P(i,3))==-1 then // explicit_output
outR=out($,:)*R;
x=[x,orig(1)+sz(1)-outR(:,1)-P(i,1)*sz(1)/100];
y=[y,orig(2)+outR(:,2)+P(i,2)*sz(2)/100];
typ=[typ,1];
end
if(P(i,3)==-2) then // implicit
out2R=out2($,:)*R;
x=[x,orig(1)+sz(1)-out2R(:,1)-P(i,1)*sz(1)/100];
y=[y,orig(2)+out2R(:,2)+P(i,2)*sz(2)/100];
typ=[typ,2];
end
end
end
endfunction