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| author | Sunil Shetye | 2018-06-25 18:20:39 +0530 |
|---|---|---|
| committer | Sunil Shetye | 2018-06-26 11:06:22 +0530 |
| commit | 7465daea85285ba7f291b6bf6ddc45caa9e7ad65 (patch) | |
| tree | e8e3e4dd60d469c290d55de15644ddbc1e013bc6 /js/Linear/INTEGRAL_m.js | |
| parent | 7c70459c10aed0d74ee03896abaf47fefdbf7c8f (diff) | |
| download | sci2js-7465daea85285ba7f291b6bf6ddc45caa9e7ad65.tar.gz sci2js-7465daea85285ba7f291b6bf6ddc45caa9e7ad65.tar.bz2 sci2js-7465daea85285ba7f291b6bf6ddc45caa9e7ad65.zip | |
add spacing to end of block also
Diffstat (limited to 'js/Linear/INTEGRAL_m.js')
| -rw-r--r-- | js/Linear/INTEGRAL_m.js | 187 |
1 files changed, 94 insertions, 93 deletions
diff --git a/js/Linear/INTEGRAL_m.js b/js/Linear/INTEGRAL_m.js index 733d18f2..f5e0b140 100644 --- a/js/Linear/INTEGRAL_m.js +++ b/js/Linear/INTEGRAL_m.js @@ -16,108 +16,109 @@ function INTEGRAL_m() { model.dep_ut = [false,true]; exprs = string([[0],[0],[0],[maxp],[minp]]); gr_i = []; - x = standard_define([2,2],model,exprs,gr_i); + this.x = standard_define([2,2],model,exprs,gr_i); } INTEGRAL_m.prototype.details = function INTEGRAL_m() { + return this.x; } INTEGRAL_m.prototype.get = function INTEGRAL_m() { } INTEGRAL_m.prototype.set = function INTEGRAL_m() { - x = arg1; + this.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; -} -} + [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; + this.x.graphics = graphics; + this.x.model = model; + break; + } + } } } |