[PATCH 5/6] Fixed formatting for consistent nesting level indentation

2019-05-01 11:28:27 +02:00 · 2019-05-01 11:28:27 +02:00 · 92f512894f
parent fdc1e32164
commit 92f512894f
1 changed files with 325 additions and 324 deletions
--- a/src/spicelib/devices/mos1/mos1load.c
+++ b/src/spicelib/devices/mos1/mos1load.c
@ -15,8 +15,8 @@ Modified: 2000 AlansFixes

 int
 MOS1load(GENmodel *inModel, CKTcircuit *ckt)
-        /* actually load the current value into the 
-         * sparse matrix previously provided 
+        /* actually load the current value into the
+         * sparse matrix previously provided
         */
 {
    MOS1model *model = (MOS1model *) inModel;
@ -75,13 +75,13 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)
    double capgd = 0.0;   /* total gate-drain capacitance */
    double capgb = 0.0;   /* total gate-bulk capacitance */
    int Check;
-#ifndef NOBYPASS    
+#ifndef NOBYPASS
    double tempv;
-#endif /*NOBYPASS*/    
+#endif /*NOBYPASS*/
    int error;
 #ifdef CAPBYPASS
    int senflag;
-#endif /*CAPBYPASS*/           
+#endif /*CAPBYPASS*/
    int SenCond;


@ -92,14 +92,14 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)
        (ckt->CKTsenInfo->SENmode & (ACSEN | TRANSEN))) {
        senflag = 1;
    }
-#endif /* CAPBYPASS */ 
+#endif /* CAPBYPASS */

    /*  loop through all the MOS1 device models */
    for( ; model != NULL; model = MOS1nextModel(model)) {

        /* loop through all the instances of the model */
        for (here = MOS1instances(model); here != NULL ;
-	     here=MOS1nextInstance(here)) {
+         here=MOS1nextInstance(here)) {

            vt = CONSTKoverQ * here->MOS1temp;
            Check=1;
@ -109,13 +109,13 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)
 #endif /* SENSDEBUG */

                if((ckt->CKTsenInfo->SENstatus == PERTURBATION)&&
-		   (here->MOS1senPertFlag == OFF))continue;
+                        (here->MOS1senPertFlag == OFF))continue;

            }
            SenCond = ckt->CKTsenInfo && here->MOS1senPertFlag;

 /*
-  
+
 */

            /* first, we compute a few useful values - these could be
@ -124,30 +124,30 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)
             */

            EffectiveLength=here->MOS1l - 2*model->MOS1latDiff;
-            
-            if( (here->MOS1tSatCurDens == 0) || 
+
+            if( (here->MOS1tSatCurDens == 0) ||
                    (here->MOS1drainArea == 0) ||
                    (here->MOS1sourceArea == 0)) {
                DrainSatCur = here->MOS1m * here->MOS1tSatCur;
                SourceSatCur = here->MOS1m * here->MOS1tSatCur;
            } else {
-                DrainSatCur = here->MOS1tSatCurDens * 
+                DrainSatCur = here->MOS1tSatCurDens *
                        here->MOS1m * here->MOS1drainArea;
-                SourceSatCur = here->MOS1tSatCurDens * 
+                SourceSatCur = here->MOS1tSatCurDens *
                        here->MOS1m * here->MOS1sourceArea;
            }
-            GateSourceOverlapCap = model->MOS1gateSourceOverlapCapFactor * 
+            GateSourceOverlapCap = model->MOS1gateSourceOverlapCapFactor *
                    here->MOS1m * here->MOS1w;
-            GateDrainOverlapCap = model->MOS1gateDrainOverlapCapFactor * 
+            GateDrainOverlapCap = model->MOS1gateDrainOverlapCapFactor *
                    here->MOS1m * here->MOS1w;
-            GateBulkOverlapCap = model->MOS1gateBulkOverlapCapFactor * 
+            GateBulkOverlapCap = model->MOS1gateBulkOverlapCapFactor *
                    here->MOS1m * EffectiveLength;
            Beta = here->MOS1tTransconductance * here->MOS1m *
                    here->MOS1w/EffectiveLength;
-            OxideCap = model->MOS1oxideCapFactor * EffectiveLength * 
+            OxideCap = model->MOS1oxideCapFactor * EffectiveLength *
                    here->MOS1m * here->MOS1w;
-           
-            /* 
+
+            /*
             * ok - now to do the start-up operations
             *
             * we must get values for vbs, vds, and vgs from somewhere
@ -162,7 +162,7 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)
                printf("MOS1senPertFlag = ON \n");
 #endif /* SENSDEBUG */
                if((ckt->CKTsenInfo->SENmode == TRANSEN) &&
-		   (ckt->CKTmode & MODEINITTRAN)) {
+           (ckt->CKTmode & MODEINITTRAN)) {
                    vgs = *(ckt->CKTstate1 + here->MOS1vgs);
                    vds = *(ckt->CKTstate1 + here->MOS1vds);
                    vbs = *(ckt->CKTstate1 + here->MOS1vbs);
@ -171,7 +171,7 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)
                    vgd = vgs - vds;
                }
                else if (ckt->CKTsenInfo->SENmode == ACSEN){
-                    vgb = model->MOS1type * ( 
+                    vgb = model->MOS1type * (
                        *(ckt->CKTrhsOp+here->MOS1gNode) -
                        *(ckt->CKTrhsOp+here->MOS1bNode));
                    vbs = *(ckt->CKTstate0 + here->MOS1vbs);
@ -197,41 +197,41 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)


            if((ckt->CKTmode & (MODEINITFLOAT | MODEINITPRED | MODEINITSMSIG
-				| MODEINITTRAN)) ||
-	       ( (ckt->CKTmode & MODEINITFIX) && (!here->MOS1off) )  ) {
+                    | MODEINITTRAN)) ||
+                    ( (ckt->CKTmode & MODEINITFIX) && (!here->MOS1off) )  ) {
 #ifndef PREDICTOR
                if(ckt->CKTmode & (MODEINITPRED | MODEINITTRAN) ) {

                    /* predictor step */

                    xfact=ckt->CKTdelta/ckt->CKTdeltaOld[1];
-                    *(ckt->CKTstate0 + here->MOS1vbs) = 
-			*(ckt->CKTstate1 + here->MOS1vbs);
+                    *(ckt->CKTstate0 + here->MOS1vbs) =
+                    *(ckt->CKTstate1 + here->MOS1vbs);
                    vbs = (1+xfact)* (*(ckt->CKTstate1 + here->MOS1vbs))
-			-(xfact * (*(ckt->CKTstate2 + here->MOS1vbs)));
-                    *(ckt->CKTstate0 + here->MOS1vgs) = 
-			*(ckt->CKTstate1 + here->MOS1vgs);
+                            -(xfact * (*(ckt->CKTstate2 + here->MOS1vbs)));
+                    *(ckt->CKTstate0 + here->MOS1vgs) =
+                            *(ckt->CKTstate1 + here->MOS1vgs);
                    vgs = (1+xfact)* (*(ckt->CKTstate1 + here->MOS1vgs))
-			-(xfact * (*(ckt->CKTstate2 + here->MOS1vgs)));
-                    *(ckt->CKTstate0 + here->MOS1vds) = 
-			*(ckt->CKTstate1 + here->MOS1vds);
+                            -(xfact * (*(ckt->CKTstate2 + here->MOS1vgs)));
+                    *(ckt->CKTstate0 + here->MOS1vds) =
+                            *(ckt->CKTstate1 + here->MOS1vds);
                    vds = (1+xfact)* (*(ckt->CKTstate1 + here->MOS1vds))
-			-(xfact * (*(ckt->CKTstate2 + here->MOS1vds)));
-                    *(ckt->CKTstate0 + here->MOS1vbd) = 
-			*(ckt->CKTstate0 + here->MOS1vbs)-
-			*(ckt->CKTstate0 + here->MOS1vds);
+                            -(xfact * (*(ckt->CKTstate2 + here->MOS1vds)));
+                    *(ckt->CKTstate0 + here->MOS1vbd) =
+                            *(ckt->CKTstate0 + here->MOS1vbs)-
+                    *(ckt->CKTstate0 + here->MOS1vds);
                } else {
 #endif /* PREDICTOR */

                    /* general iteration */

-                    vbs = model->MOS1type * ( 
-                        *(ckt->CKTrhsOld+here->MOS1bNode) -
-                        *(ckt->CKTrhsOld+here->MOS1sNodePrime));
-                    vgs = model->MOS1type * ( 
+                    vbs = model->MOS1type * (
+                            *(ckt->CKTrhsOld+here->MOS1bNode) -
+                            *(ckt->CKTrhsOld+here->MOS1sNodePrime));
+                    vgs = model->MOS1type * (
                        *(ckt->CKTrhsOld+here->MOS1gNode) -
                        *(ckt->CKTrhsOld+here->MOS1sNodePrime));
-                    vds = model->MOS1type * ( 
+                    vds = model->MOS1type * (
                        *(ckt->CKTrhsOld+here->MOS1dNodePrime) -
                        *(ckt->CKTrhsOld+here->MOS1sNodePrime));
 #ifndef PREDICTOR
@ -242,8 +242,8 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)

                vbd=vbs-vds;
                vgd=vgs-vds;
-                vgdo = *(ckt->CKTstate0 + here->MOS1vgs) - 
-		    *(ckt->CKTstate0 + here->MOS1vds);
+                vgdo = *(ckt->CKTstate0 + here->MOS1vgs) -
+                        *(ckt->CKTstate0 + here->MOS1vds);
                delvbs = vbs - *(ckt->CKTstate0 + here->MOS1vbs);
                delvbd = vbd - *(ckt->CKTstate0 + here->MOS1vbd);
                delvgs = vgs - *(ckt->CKTstate0 + here->MOS1vgs);
@ -254,98 +254,98 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)

                if (here->MOS1mode >= 0) {
                    cdhat=
-                        here->MOS1cd-
-                        here->MOS1gbd * delvbd +
-                        here->MOS1gmbs * delvbs +
-                        here->MOS1gm * delvgs + 
-                        here->MOS1gds * delvds ;
+                            here->MOS1cd-
+                            here->MOS1gbd * delvbd +
+                            here->MOS1gmbs * delvbs +
+                            here->MOS1gm * delvgs +
+                            here->MOS1gds * delvds ;
                } else {
                    cdhat=
-                        here->MOS1cd -
-                        ( here->MOS1gbd -
-			  here->MOS1gmbs) * delvbd -
-                        here->MOS1gm * delvgd + 
+                            here->MOS1cd -
+                            ( here->MOS1gbd -
+                            here->MOS1gmbs) * delvbd -
+                            here->MOS1gm * delvgd +
                        here->MOS1gds * delvds ;
                }
                cbhat=
-                    here->MOS1cbs +
-                    here->MOS1cbd +
-                    here->MOS1gbd * delvbd +
-                    here->MOS1gbs * delvbs ;
+                        here->MOS1cbs +
+                        here->MOS1cbd +
+                        here->MOS1gbd * delvbd +
+                        here->MOS1gbs * delvbs ;
 /*
-  
+
 */

 #ifndef NOBYPASS
                /* now lets see if we can bypass (ugh) */
                tempv = (MAX(fabs(cbhat),
-			    fabs(here->MOS1cbs + here->MOS1cbd)) +
-			 ckt->CKTabstol);
+                fabs(here->MOS1cbs + here->MOS1cbd)) +
+                        ckt->CKTabstol);
                if ((!(ckt->CKTmode &
-		       (MODEINITPRED|MODEINITTRAN|MODEINITSMSIG))) &&
-		    (ckt->CKTbypass) &&
-		    (fabs(cbhat-(here->MOS1cbs + 
-				 here->MOS1cbd)) < ckt->CKTreltol * tempv) &&
-		    (fabs(delvbs) < (ckt->CKTreltol *
-				     MAX(fabs(vbs),
-					 fabs( *(ckt->CKTstate0 +
-						 here->MOS1vbs))) +
-				     ckt->CKTvoltTol)) &&
-		    (fabs(delvbd) < (ckt->CKTreltol *
-				     MAX(fabs(vbd),
-					 fabs(*(ckt->CKTstate0 +
-						here->MOS1vbd))) +
-				     ckt->CKTvoltTol)) &&
-		    (fabs(delvgs) < (ckt->CKTreltol *
-				     MAX(fabs(vgs),
-					 fabs(*(ckt->CKTstate0 +
-						here->MOS1vgs)))+
-				     ckt->CKTvoltTol)) &&
-		    (fabs(delvds) < (ckt->CKTreltol *
-				     MAX(fabs(vds),
-					 fabs(*(ckt->CKTstate0 +
-						here->MOS1vds))) +
-				     ckt->CKTvoltTol)) &&
-		    (fabs(cdhat- here->MOS1cd) < (ckt->CKTreltol *
-						  MAX(fabs(cdhat),
-						      fabs(here->MOS1cd)) +
-						  ckt->CKTabstol))) {
-		  /* bypass code */
-		  /* nothing interesting has changed since last
-		   * iteration on this device, so we just
-		   * copy all the values computed last iteration out
-		   * and keep going
-		   */
-		  vbs = *(ckt->CKTstate0 + here->MOS1vbs);
-		  vbd = *(ckt->CKTstate0 + here->MOS1vbd);
-		  vgs = *(ckt->CKTstate0 + here->MOS1vgs);
-		  vds = *(ckt->CKTstate0 + here->MOS1vds);
-		  vgd = vgs - vds;
-		  vgb = vgs - vbs;
-		  cdrain = here->MOS1mode * (here->MOS1cd + here->MOS1cbd);
-		  if(ckt->CKTmode & (MODETRAN | MODETRANOP)) {
-		    capgs = ( *(ckt->CKTstate0+here->MOS1capgs)+ 
-			      *(ckt->CKTstate1+here->MOS1capgs) +
-			      GateSourceOverlapCap );
-		    capgd = ( *(ckt->CKTstate0+here->MOS1capgd)+ 
-			      *(ckt->CKTstate1+here->MOS1capgd) +
-			      GateDrainOverlapCap );
-		    capgb = ( *(ckt->CKTstate0+here->MOS1capgb)+ 
-			      *(ckt->CKTstate1+here->MOS1capgb) +
-			      GateBulkOverlapCap );
-		    
-		    if(ckt->CKTsenInfo){
-		      here->MOS1cgs = capgs;
-		      here->MOS1cgd = capgd;
-		      here->MOS1cgb = capgb;
-		    }
-		  }
-		  goto bypass;
-		}
+                        (MODEINITPRED|MODEINITTRAN|MODEINITSMSIG))) &&
+                        (ckt->CKTbypass) &&
+                        (fabs(cbhat-(here->MOS1cbs +
+                            here->MOS1cbd)) < ckt->CKTreltol * tempv) &&
+                        (fabs(delvbs) < (ckt->CKTreltol *
+                            MAX(fabs(vbs),
+                            fabs( *(ckt->CKTstate0 +
+                            here->MOS1vbs))) +
+                            ckt->CKTvoltTol)) &&
+                        (fabs(delvbd) < (ckt->CKTreltol *
+                                 MAX(fabs(vbd),
+                                 fabs(*(ckt->CKTstate0 +
+                                    here->MOS1vbd))) +
+                                 ckt->CKTvoltTol)) &&
+                        (fabs(delvgs) < (ckt->CKTreltol *
+                                 MAX(fabs(vgs),
+                                 fabs(*(ckt->CKTstate0 +
+                                    here->MOS1vgs)))+
+                                 ckt->CKTvoltTol)) &&
+                        (fabs(delvds) < (ckt->CKTreltol *
+                                 MAX(fabs(vds),
+                                 fabs(*(ckt->CKTstate0 +
+                                    here->MOS1vds))) +
+                                 ckt->CKTvoltTol)) &&
+                        (fabs(cdhat- here->MOS1cd) < (ckt->CKTreltol *
+                                      MAX(fabs(cdhat),
+                                          fabs(here->MOS1cd)) +
+                                      ckt->CKTabstol))) {
+                    /* bypass code */
+                    /* nothing interesting has changed since last
+                    * iteration on this device, so we just
+                    * copy all the values computed last iteration out
+                    * and keep going
+                    */
+                    vbs = *(ckt->CKTstate0 + here->MOS1vbs);
+                    vbd = *(ckt->CKTstate0 + here->MOS1vbd);
+                    vgs = *(ckt->CKTstate0 + here->MOS1vgs);
+                    vds = *(ckt->CKTstate0 + here->MOS1vds);
+                    vgd = vgs - vds;
+                    vgb = vgs - vbs;
+                    cdrain = here->MOS1mode * (here->MOS1cd + here->MOS1cbd);
+                    if(ckt->CKTmode & (MODETRAN | MODETRANOP)) {
+                        capgs = ( *(ckt->CKTstate0+here->MOS1capgs)+
+                              *(ckt->CKTstate1+here->MOS1capgs) +
+                              GateSourceOverlapCap );
+                        capgd = ( *(ckt->CKTstate0+here->MOS1capgd)+
+                              *(ckt->CKTstate1+here->MOS1capgd) +
+                              GateDrainOverlapCap );
+                        capgb = ( *(ckt->CKTstate0+here->MOS1capgb)+
+                              *(ckt->CKTstate1+here->MOS1capgb) +
+                              GateBulkOverlapCap );
+
+                        if(ckt->CKTsenInfo){
+                          here->MOS1cgs = capgs;
+                          here->MOS1cgd = capgd;
+                          here->MOS1cgb = capgb;
+                        }
+                    }
+                    goto bypass;
+                }
 #endif /*NOBYPASS*/

 /*
-  
+
 */

                /* ok - bypass is out, do it the hard way */
@ -353,7 +353,7 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)
                von = model->MOS1type * here->MOS1von;

 #ifndef NODELIMITING
-                /* 
+                /*
                 * limiting
                 *  we want to keep device voltages from changing
                 * so fast that the exponentials churn out overflows
@ -362,7 +362,7 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)

                if(*(ckt->CKTstate0 + here->MOS1vds) >=0) {
                    vgs = DEVfetlim(vgs,*(ckt->CKTstate0 + here->MOS1vgs)
-				    ,von);
+                    ,von);
                    vds = vgs - vgd;
                    vds = DEVlimvds(vds,*(ckt->CKTstate0 + here->MOS1vds));
                    vgd = vgs - vds;
@ -370,23 +370,23 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)
                    vgd = DEVfetlim(vgd,vgdo,von);
                    vds = vgs - vgd;
                    if(!(ckt->CKTfixLimit)) {
-                        vds = -DEVlimvds(-vds,-(*(ckt->CKTstate0 + 
-						  here->MOS1vds)));
+                        vds = -DEVlimvds(-vds,-(*(ckt->CKTstate0 +
+                          here->MOS1vds)));
                    }
                    vgs = vgd + vds;
                }
                if(vds >= 0) {
                    vbs = DEVpnjlim(vbs,*(ckt->CKTstate0 + here->MOS1vbs),
-				    vt,here->MOS1sourceVcrit,&Check);
+                    vt,here->MOS1sourceVcrit,&Check);
                    vbd = vbs-vds;
                } else {
                    vbd = DEVpnjlim(vbd,*(ckt->CKTstate0 + here->MOS1vbd),
-				    vt,here->MOS1drainVcrit,&Check);
+                    vt,here->MOS1drainVcrit,&Check);
                    vbs = vbd + vds;
                }
 #endif /*NODELIMITING*/
 /*
-  
+
 */

            } else {
@ -400,20 +400,20 @@ MOS1load(GENmodel *inModel, CKTcircuit *ckt)
                    vds= model->MOS1type * here->MOS1icVDS;
                    vgs= model->MOS1type * here->MOS1icVGS;
                    vbs= model->MOS1type * here->MOS1icVBS;
-                    if((vds==0) && (vgs==0) && (vbs==0) && 
-		       ((ckt->CKTmode & 
-			 (MODETRAN|MODEDCOP|MODEDCTRANCURVE)) ||
-			(!(ckt->CKTmode & MODEUIC)))) {
+                    if((vds==0) && (vgs==0) && (vbs==0) &&
+                            ((ckt->CKTmode &
+                            (MODETRAN|MODEDCOP|MODEDCTRANCURVE)) ||
+                            (!(ckt->CKTmode & MODEUIC)))) {
                        vbs = -1;
                        vgs = model->MOS1type * here->MOS1tVto;
                        vds = 0;
                    }
                } else {
                    vbs=vgs=vds=0;
-                } 
+                }
            }
 /*
-  
+
 */

            /*
@ -457,25 +457,25 @@ next1:      if(vbs <= -3*vt) {
                here->MOS1mode = -1;
            }
 /*
-  
+
 */

            {
-		/*
-		 *     this block of code evaluates the drain current and its 
-		 *     derivatives using the shichman-hodges model and the 
-		 *     charges associated with the gate, channel and bulk for 
-		 *     mosfets
-		 *
-		 */
+                /*
+                 *     this block of code evaluates the drain current and its
+                 *     derivatives using the shichman-hodges model and the
+                 *     charges associated with the gate, channel and bulk for
+                 *     mosfets
+                 *
+                 */

-		/* the following 4 variables are local to this code block until 
-		 * it is obvious that they can be made global 
-		 */
-		double arg;
-		double betap;
-		double sarg;
-		double vgst;
+                /* the following 4 variables are local to this code block until
+                 * it is obvious that they can be made global
+                 */
+                double arg;
+                double betap;
+                double sarg;
+                double vgst;

                if ((here->MOS1mode==1?vbs:vbd) <= 0 ) {
                    sarg=sqrt(here->MOS1tPhi-(here->MOS1mode==1?vbs:vbd));
@ -511,17 +511,17 @@ next1:      if(vbs <= -3*vt) {
                        here->MOS1gds=model->MOS1lambda*Beta*vgst*vgst*.5;
                        here->MOS1gmbs=here->MOS1gm*arg;
                    } else {
-			/*
-			 *     linear region
-			 */
+                        /*
+                         *     linear region
+                         */
                        cdrain=betap*(vds*here->MOS1mode)*
                            (vgst-.5*(vds*here->MOS1mode));
                        here->MOS1gm=betap*(vds*here->MOS1mode);
                        here->MOS1gds=betap*(vgst-(vds*here->MOS1mode))+
-			    model->MOS1lambda*Beta*
-			    (vds*here->MOS1mode)*
-			    (vgst-.5*(vds*here->MOS1mode));
-                        here->MOS1gmbs=here->MOS1gm*arg;
+                                model->MOS1lambda*Beta*
+                                (vds*here->MOS1mode)*
+                                (vgst-.5*(vds*here->MOS1mode));
+                                        here->MOS1gmbs=here->MOS1gm*arg;
                    }
                }
                /*
@ -529,7 +529,7 @@ next1:      if(vbs <= -3*vt) {
                 */
            }
 /*
-  
+
 */

            /* now deal with n vs p polarity */
@ -543,7 +543,7 @@ next1:      if(vbs <= -3*vt) {
            here->MOS1cd=here->MOS1mode * cdrain - here->MOS1cbd;

            if (ckt->CKTmode & (MODETRAN | MODETRANOP | MODEINITSMSIG)) {
-                /* 
+                /*
                 * now we do the hard part of the bulk-drain and bulk-source
                 * diode - we evaluate the non-linear capacitance and
                 * charge
@ -563,123 +563,123 @@ next1:      if(vbs <= -3*vt) {
                        fabs(*(ckt->CKTstate0+here->MOS1vbs)))+
                        ckt->CKTvoltTol)|| senflag)
 #endif /*CAPBYPASS*/
-		 
+
                {
                    /* can't bypass the diode capacitance calculations */
                    if(here->MOS1Cbs != 0 || here->MOS1Cbssw != 0 ) {
-			if (vbs < here->MOS1tDepCap){
-			    arg=1-vbs/here->MOS1tBulkPot;
-			    /*
-			     * the following block looks somewhat long and messy,
-			     * but since most users use the default grading
-			     * coefficients of .5, and sqrt is MUCH faster than an
-			     * exp(log()) we use this special case code to buy time.
-			     * (as much as 10% of total job time!)
-			     */
-			    if(model->MOS1bulkJctBotGradingCoeff ==
-			       model->MOS1bulkJctSideGradingCoeff) {
-				if(model->MOS1bulkJctBotGradingCoeff == .5) {
-				    sarg = sargsw = 1/sqrt(arg);
-				} else {
-				    sarg = sargsw =
-                                        exp(-model->MOS1bulkJctBotGradingCoeff*
-					    log(arg));
-				}
-			    } else {
-				if(model->MOS1bulkJctBotGradingCoeff == .5) {
-				    sarg = 1/sqrt(arg);
-				} else {
-				    sarg = exp(-model->MOS1bulkJctBotGradingCoeff*
-					       log(arg));
-				}
-				if(model->MOS1bulkJctSideGradingCoeff == .5) {
-				    sargsw = 1/sqrt(arg);
-				} else {
-				    sargsw =exp(-model->MOS1bulkJctSideGradingCoeff*
-						log(arg));
-				}
-			    }
-			    *(ckt->CKTstate0 + here->MOS1qbs) =
-				here->MOS1tBulkPot*(here->MOS1Cbs*
-						    (1-arg*sarg)/(1-model->MOS1bulkJctBotGradingCoeff)
-						    +here->MOS1Cbssw*
-						    (1-arg*sargsw)/
-						    (1-model->MOS1bulkJctSideGradingCoeff));
-			    here->MOS1capbs=here->MOS1Cbs*sarg+
-                                here->MOS1Cbssw*sargsw;
-			} else {
-			    *(ckt->CKTstate0 + here->MOS1qbs) = here->MOS1f4s +
-                                vbs*(here->MOS1f2s+vbs*(here->MOS1f3s/2));
-			    here->MOS1capbs=here->MOS1f2s+here->MOS1f3s*vbs;
-			}
+                        if (vbs < here->MOS1tDepCap){
+                            arg=1-vbs/here->MOS1tBulkPot;
+                            /*
+                             * the following block looks somewhat long and messy,
+                             * but since most users use the default grading
+                             * coefficients of .5, and sqrt is MUCH faster than an
+                             * exp(log()) we use this special case code to buy time.
+                             * (as much as 10% of total job time!)
+                             */
+                            if(model->MOS1bulkJctBotGradingCoeff ==
+                                    model->MOS1bulkJctSideGradingCoeff) {
+                                if(model->MOS1bulkJctBotGradingCoeff == .5) {
+                                    sarg = sargsw = 1/sqrt(arg);
+                                } else {
+                                    sarg = sargsw =
+                                            exp(-model->MOS1bulkJctBotGradingCoeff*
+                                            log(arg));
+                                }
+                            } else {
+                                if(model->MOS1bulkJctBotGradingCoeff == .5) {
+                                    sarg = 1/sqrt(arg);
+                                } else {
+                                    sarg = exp(-model->MOS1bulkJctBotGradingCoeff*
+                                           log(arg));
+                                }
+                                if(model->MOS1bulkJctSideGradingCoeff == .5) {
+                                    sargsw = 1/sqrt(arg);
+                                } else {
+                                    sargsw =exp(-model->MOS1bulkJctSideGradingCoeff*
+                                            log(arg));
+                                }
+                            }
+                            *(ckt->CKTstate0 + here->MOS1qbs) =
+                            here->MOS1tBulkPot*(here->MOS1Cbs*
+                                    (1-arg*sarg)/(1-model->MOS1bulkJctBotGradingCoeff)
+                                    +here->MOS1Cbssw*
+                                    (1-arg*sargsw)/
+                                    (1-model->MOS1bulkJctSideGradingCoeff));
+                            here->MOS1capbs=here->MOS1Cbs*sarg+
+                                    here->MOS1Cbssw*sargsw;
+                        } else {
+                            *(ckt->CKTstate0 + here->MOS1qbs) = here->MOS1f4s +
+                                            vbs*(here->MOS1f2s+vbs*(here->MOS1f3s/2));
+                            here->MOS1capbs=here->MOS1f2s+here->MOS1f3s*vbs;
+                        }
                    } else {
-			*(ckt->CKTstate0 + here->MOS1qbs) = 0;
+                        *(ckt->CKTstate0 + here->MOS1qbs) = 0;
                        here->MOS1capbs=0;
                    }
                }
 #ifdef CAPBYPASS
                    if(((ckt->CKTmode & (MODEINITPRED | MODEINITTRAN) ) ||
-                        fabs(delvbd) >= ckt->CKTreltol * MAX(fabs(vbd),
-                        fabs(*(ckt->CKTstate0+here->MOS1vbd)))+
-                        ckt->CKTvoltTol)|| senflag)
-#endif /*CAPBYPASS*/		    	
-	
+                            fabs(delvbd) >= ckt->CKTreltol * MAX(fabs(vbd),
+                            fabs(*(ckt->CKTstate0+here->MOS1vbd)))+
+                            ckt->CKTvoltTol)|| senflag)
+#endif /*CAPBYPASS*/
+
                    /* can't bypass the diode capacitance calculations */
                {
                    if(here->MOS1Cbd != 0 || here->MOS1Cbdsw != 0 ) {
-			if (vbd < here->MOS1tDepCap) {
-			    arg=1-vbd/here->MOS1tBulkPot;
-			    /*
-			     * the following block looks somewhat long and messy,
-			     * but since most users use the default grading
-			     * coefficients of .5, and sqrt is MUCH faster than an
-			     * exp(log()) we use this special case code to buy time.
-			     * (as much as 10% of total job time!)
-			     */
-			    if(model->MOS1bulkJctBotGradingCoeff == .5 &&
-			       model->MOS1bulkJctSideGradingCoeff == .5) {
-				sarg = sargsw = 1/sqrt(arg);
-			    } else {
-				if(model->MOS1bulkJctBotGradingCoeff == .5) {
-				    sarg = 1/sqrt(arg);
-				} else {
-				    sarg = exp(-model->MOS1bulkJctBotGradingCoeff*
-					       log(arg));
-				}
-				if(model->MOS1bulkJctSideGradingCoeff == .5) {
-				    sargsw = 1/sqrt(arg);
-				} else {
-				    sargsw =exp(-model->MOS1bulkJctSideGradingCoeff*
-						log(arg));
-				}
-			    }
-			    *(ckt->CKTstate0 + here->MOS1qbd) =
-				here->MOS1tBulkPot*(here->MOS1Cbd*
-						    (1-arg*sarg)
-						    /(1-model->MOS1bulkJctBotGradingCoeff)
-						    +here->MOS1Cbdsw*
-						    (1-arg*sargsw)
-						    /(1-model->MOS1bulkJctSideGradingCoeff));
-			    here->MOS1capbd=here->MOS1Cbd*sarg+
-                                here->MOS1Cbdsw*sargsw;
-			} else {
-			    *(ckt->CKTstate0 + here->MOS1qbd) = here->MOS1f4d +
-                                vbd * (here->MOS1f2d + vbd * here->MOS1f3d/2);
-			    here->MOS1capbd=here->MOS1f2d + vbd * here->MOS1f3d;
-			}
-		    } else {
-			*(ckt->CKTstate0 + here->MOS1qbd) = 0;
-			here->MOS1capbd = 0;
-		    }
+                        if (vbd < here->MOS1tDepCap) {
+                            arg=1-vbd/here->MOS1tBulkPot;
+                            /*
+                             * the following block looks somewhat long and messy,
+                             * but since most users use the default grading
+                             * coefficients of .5, and sqrt is MUCH faster than an
+                             * exp(log()) we use this special case code to buy time.
+                             * (as much as 10% of total job time!)
+                             */
+                            if(model->MOS1bulkJctBotGradingCoeff == .5 &&
+                                    model->MOS1bulkJctSideGradingCoeff == .5) {
+                                sarg = sargsw = 1/sqrt(arg);
+                            } else {
+                                if(model->MOS1bulkJctBotGradingCoeff == .5) {
+                                    sarg = 1/sqrt(arg);
+                                } else {
+                                    sarg = exp(-model->MOS1bulkJctBotGradingCoeff*
+                                           log(arg));
+                                }
+                                if(model->MOS1bulkJctSideGradingCoeff == .5) {
+                                    sargsw = 1/sqrt(arg);
+                                } else {
+                                    sargsw =exp(-model->MOS1bulkJctSideGradingCoeff*
+                                            log(arg));
+                                }
+                            }
+                            *(ckt->CKTstate0 + here->MOS1qbd) =
+                                    here->MOS1tBulkPot*(here->MOS1Cbd*
+                                    (1-arg*sarg)
+                                    /(1-model->MOS1bulkJctBotGradingCoeff)
+                                    +here->MOS1Cbdsw*
+                                    (1-arg*sargsw)
+                                    /(1-model->MOS1bulkJctSideGradingCoeff));
+                            here->MOS1capbd=here->MOS1Cbd*sarg+
+                                    here->MOS1Cbdsw*sargsw;
+                        } else {
+                            *(ckt->CKTstate0 + here->MOS1qbd) = here->MOS1f4d +
+                                    vbd * (here->MOS1f2d + vbd * here->MOS1f3d/2);
+                            here->MOS1capbd=here->MOS1f2d + vbd * here->MOS1f3d;
+                        }
+                    } else {
+                        *(ckt->CKTstate0 + here->MOS1qbd) = 0;
+                        here->MOS1capbd = 0;
+                    }
                }
 /*
-  
+
 */

                if(SenCond && (ckt->CKTsenInfo->SENmode==TRANSEN)) goto next2;

                if ( (ckt->CKTmode & MODETRAN) || ( (ckt->CKTmode&MODEINITTRAN)
-						    && !(ckt->CKTmode&MODEUIC)) ) {
+                            && !(ckt->CKTmode&MODEUIC)) ) {
                    /* (above only excludes tranop, since we're only at this
                     * point if tran or tranop )
                     */
@ -692,20 +692,20 @@ next1:      if(vbs <= -3*vt) {
                    /* integrate the capacitors and save results */

                    error = NIintegrate(ckt,&geq,&ceq,here->MOS1capbd,
-					here->MOS1qbd);
+                    here->MOS1qbd);
                    if(error) return(error);
                    here->MOS1gbd += geq;
                    here->MOS1cbd += *(ckt->CKTstate0 + here->MOS1cqbd);
                    here->MOS1cd -= *(ckt->CKTstate0 + here->MOS1cqbd);
                    error = NIintegrate(ckt,&geq,&ceq,here->MOS1capbs,
-					here->MOS1qbs);
+                    here->MOS1qbs);
                    if(error) return(error);
                    here->MOS1gbs += geq;
                    here->MOS1cbs += *(ckt->CKTstate0 + here->MOS1cqbs);
                }
            }
 /*
-  
+
 */

            if(SenCond) goto next2;
@ -714,26 +714,27 @@ next1:      if(vbs <= -3*vt) {
            /*
             *  check convergence
             */
-            if ( (here->MOS1off == 0)  || 
-		 (!(ckt->CKTmode & (MODEINITFIX|MODEINITSMSIG))) ){
+            if ( (here->MOS1off == 0)  ||
+                    (!(ckt->CKTmode & (MODEINITFIX|MODEINITSMSIG))) ){
                if (Check == 1) {
                    ckt->CKTnoncon++;
-		    ckt->CKTtroubleElt = (GENinstance *) here;
+                    ckt->CKTtroubleElt = (GENinstance *) here;
                }
            }
 /*
-  
+
 */

            /* save things away for next time */

-	next2:      *(ckt->CKTstate0 + here->MOS1vbs) = vbs;
+next2:
+            *(ckt->CKTstate0 + here->MOS1vbs) = vbs;
            *(ckt->CKTstate0 + here->MOS1vbd) = vbd;
            *(ckt->CKTstate0 + here->MOS1vgs) = vgs;
            *(ckt->CKTstate0 + here->MOS1vds) = vds;

 /*
-  
+
 */

            /*
@ -743,7 +744,7 @@ next1:      if(vbs <= -3*vt) {
                /*
                 *     calculate meyer's capacitors
                 */
-                /* 
+                /*
                 * new cmeyer - this just evaluates at the current time,
                 * expects you to remember values from previous time
                 * returns 1/2 of non-constant portion of capacitance
@ -752,37 +753,37 @@ next1:      if(vbs <= -3*vt) {
                 */
                if (here->MOS1mode > 0){
                    DEVqmeyer (vgs,vgd,vgb,von,vdsat,
-			       (ckt->CKTstate0 + here->MOS1capgs),
-			       (ckt->CKTstate0 + here->MOS1capgd),
-			       (ckt->CKTstate0 + here->MOS1capgb),
-			       here->MOS1tPhi,OxideCap);
+                   (ckt->CKTstate0 + here->MOS1capgs),
+                   (ckt->CKTstate0 + here->MOS1capgd),
+                   (ckt->CKTstate0 + here->MOS1capgb),
+                   here->MOS1tPhi,OxideCap);
                } else {
                    DEVqmeyer (vgd,vgs,vgb,von,vdsat,
-			       (ckt->CKTstate0 + here->MOS1capgd),
-			       (ckt->CKTstate0 + here->MOS1capgs),
-			       (ckt->CKTstate0 + here->MOS1capgb),
-			       here->MOS1tPhi,OxideCap);
+                   (ckt->CKTstate0 + here->MOS1capgd),
+                   (ckt->CKTstate0 + here->MOS1capgs),
+                   (ckt->CKTstate0 + here->MOS1capgb),
+                   here->MOS1tPhi,OxideCap);
                }
                vgs1 = *(ckt->CKTstate1 + here->MOS1vgs);
                vgd1 = vgs1 - *(ckt->CKTstate1 + here->MOS1vds);
                vgb1 = vgs1 - *(ckt->CKTstate1 + here->MOS1vbs);
                if(ckt->CKTmode & (MODETRANOP|MODEINITSMSIG)) {
-                    capgs =  2 * *(ckt->CKTstate0+here->MOS1capgs)+ 
-			GateSourceOverlapCap ;
-                    capgd =  2 * *(ckt->CKTstate0+here->MOS1capgd)+ 
-			GateDrainOverlapCap ;
-                    capgb =  2 * *(ckt->CKTstate0+here->MOS1capgb)+ 
-			GateBulkOverlapCap ;
+                    capgs =  2 * *(ckt->CKTstate0+here->MOS1capgs)+
+                            GateSourceOverlapCap ;
+                    capgd =  2 * *(ckt->CKTstate0+here->MOS1capgd)+
+                            GateDrainOverlapCap ;
+                    capgb =  2 * *(ckt->CKTstate0+here->MOS1capgb)+
+                            GateBulkOverlapCap ;
                } else {
-                    capgs = ( *(ckt->CKTstate0+here->MOS1capgs)+ 
-                              *(ckt->CKTstate1+here->MOS1capgs) +
-                              GateSourceOverlapCap );
-                    capgd = ( *(ckt->CKTstate0+here->MOS1capgd)+ 
-                              *(ckt->CKTstate1+here->MOS1capgd) +
-                              GateDrainOverlapCap );
-                    capgb = ( *(ckt->CKTstate0+here->MOS1capgb)+ 
-                              *(ckt->CKTstate1+here->MOS1capgb) +
-                              GateBulkOverlapCap );
+                    capgs = ( *(ckt->CKTstate0+here->MOS1capgs)+
+                            *(ckt->CKTstate1+here->MOS1capgs) +
+                            GateSourceOverlapCap );
+                    capgd = ( *(ckt->CKTstate0+here->MOS1capgd)+
+                            *(ckt->CKTstate1+here->MOS1capgd) +
+                            GateDrainOverlapCap );
+                    capgb = ( *(ckt->CKTstate0+here->MOS1capgb)+
+                            *(ckt->CKTstate1+here->MOS1capgb) +
+                            GateBulkOverlapCap );
                }
                if(ckt->CKTsenInfo){
                    here->MOS1cgs = capgs;
@ -790,7 +791,7 @@ next1:      if(vbs <= -3*vt) {
                    here->MOS1cgb = capgb;
                }
 /*
-  
+
 */

                /*
@ -799,7 +800,7 @@ next1:      if(vbs <= -3*vt) {
                 */
                if(SenCond){
                    if((ckt->CKTsenInfo->SENmode == DCSEN)||
-		       (ckt->CKTsenInfo->SENmode == ACSEN)){
+                            (ckt->CKTsenInfo->SENmode == ACSEN)){
                        continue;
                    }
                }
@ -807,14 +808,14 @@ next1:      if(vbs <= -3*vt) {
 #ifndef PREDICTOR
                if (ckt->CKTmode & (MODEINITPRED | MODEINITTRAN) ) {
                    *(ckt->CKTstate0 + here->MOS1qgs) =
-                        (1+xfact) * *(ckt->CKTstate1 + here->MOS1qgs)
-                        - xfact * *(ckt->CKTstate2 + here->MOS1qgs);
+                            (1+xfact) * *(ckt->CKTstate1 + here->MOS1qgs)
+                            - xfact * *(ckt->CKTstate2 + here->MOS1qgs);
                    *(ckt->CKTstate0 + here->MOS1qgd) =
-                        (1+xfact) * *(ckt->CKTstate1 + here->MOS1qgd)
-                        - xfact * *(ckt->CKTstate2 + here->MOS1qgd);
+                            (1+xfact) * *(ckt->CKTstate1 + here->MOS1qgd)
+                            - xfact * *(ckt->CKTstate2 + here->MOS1qgd);
                    *(ckt->CKTstate0 + here->MOS1qgb) =
-                        (1+xfact) * *(ckt->CKTstate1 + here->MOS1qgb)
-                        - xfact * *(ckt->CKTstate2 + here->MOS1qgb);
+                            (1+xfact) * *(ckt->CKTstate1 + here->MOS1qgb)
+                            - xfact * *(ckt->CKTstate2 + here->MOS1qgb);
                } else {
 #endif /*PREDICTOR*/
                    if(ckt->CKTmode & MODETRAN) {
@ -835,14 +836,14 @@ next1:      if(vbs <= -3*vt) {
 #endif /*PREDICTOR*/
            }
 #ifndef NOBYPASS
-	bypass:
+    bypass:
 #endif
            if(SenCond) continue;

-            if ( (ckt->CKTmode & (MODEINITTRAN)) || 
-		 (! (ckt->CKTmode & (MODETRAN)) )  ) {
+            if ( (ckt->CKTmode & (MODEINITTRAN)) ||
+                    (! (ckt->CKTmode & (MODETRAN)) )  ) {
                /*
-                 *  initialize to zero charge conductances 
+                 *  initialize to zero charge conductances
                 *  and current
                 */
                gcgs=0;
@ -865,12 +866,12 @@ next1:      if(vbs <= -3*vt) {
                if(error) return(error);
                error = NIintegrate(ckt,&gcgb,&ceqgb,capgb,here->MOS1qgb);
                if(error) return(error);
-                ceqgs=ceqgs-gcgs*vgs+ckt->CKTag[0]* 
-		    *(ckt->CKTstate0 + here->MOS1qgs);
+                ceqgs=ceqgs-gcgs*vgs+ckt->CKTag[0]*
+                        *(ckt->CKTstate0 + here->MOS1qgs);
                ceqgd=ceqgd-gcgd*vgd+ckt->CKTag[0]*
-		    *(ckt->CKTstate0 + here->MOS1qgd);
+                        *(ckt->CKTstate0 + here->MOS1qgd);
                ceqgb=ceqgb-gcgb*vgb+ckt->CKTag[0]*
-		    *(ckt->CKTstate0 + here->MOS1qgb);
+                        *(ckt->CKTstate0 + here->MOS1qgb);
            }
            /*
             *     store charge storage info for meyer's cap in lx table
@ -879,29 +880,29 @@ next1:      if(vbs <= -3*vt) {
            /*
             *  load current vector
             */
-            ceqbs = model->MOS1type * 
-		(here->MOS1cbs-(here->MOS1gbs)*vbs);
-            ceqbd = model->MOS1type * 
-		(here->MOS1cbd-(here->MOS1gbd)*vbd);
+            ceqbs = model->MOS1type *
+                    (here->MOS1cbs-(here->MOS1gbs)*vbs);
+            ceqbd = model->MOS1type *
+                (here->MOS1cbd-(here->MOS1gbd)*vbd);
            if (here->MOS1mode >= 0) {
                xnrm=1;
                xrev=0;
                cdreq=model->MOS1type*(cdrain-here->MOS1gds*vds-
-				       here->MOS1gm*vgs-here->MOS1gmbs*vbs);
+                       here->MOS1gm*vgs-here->MOS1gmbs*vbs);
            } else {
                xnrm=0;
                xrev=1;
                cdreq = -(model->MOS1type)*(cdrain-here->MOS1gds*(-vds)-
-					    here->MOS1gm*vgd-here->MOS1gmbs*vbd);
+                        here->MOS1gm*vgd-here->MOS1gmbs*vbd);
            }
-            *(ckt->CKTrhs + here->MOS1gNode) -= 
-                (model->MOS1type * (ceqgs + ceqgb + ceqgd));
+            *(ckt->CKTrhs + here->MOS1gNode) -=
+                    (model->MOS1type * (ceqgs + ceqgb + ceqgd));
            *(ckt->CKTrhs + here->MOS1bNode) -=
-                (ceqbs + ceqbd - model->MOS1type * ceqgb);
+                    (ceqbs + ceqbd - model->MOS1type * ceqgb);
            *(ckt->CKTrhs + here->MOS1dNodePrime) +=
-		(ceqbd - cdreq + model->MOS1type * ceqgd);
-            *(ckt->CKTrhs + here->MOS1sNodePrime) += 
-		cdreq + ceqbs + model->MOS1type * ceqgs;
+                    (ceqbd - cdreq + model->MOS1type * ceqgd);
+            *(ckt->CKTrhs + here->MOS1sNodePrime) +=
+                    cdreq + ceqbs + model->MOS1type * ceqgs;
            /*
             *  load y matrix
             */
@ -910,12 +911,12 @@ next1:      if(vbs <= -3*vt) {
            *(here->MOS1GgPtr) += ((gcgd+gcgs+gcgb));
            *(here->MOS1SsPtr) += (here->MOS1sourceConductance);
            *(here->MOS1BbPtr) += (here->MOS1gbd+here->MOS1gbs+gcgb);
-            *(here->MOS1DPdpPtr) += 
-		(here->MOS1drainConductance+here->MOS1gds+
-		 here->MOS1gbd+xrev*(here->MOS1gm+here->MOS1gmbs)+gcgd);
-            *(here->MOS1SPspPtr) += 
-		(here->MOS1sourceConductance+here->MOS1gds+
-		 here->MOS1gbs+xnrm*(here->MOS1gm+here->MOS1gmbs)+gcgs);
+            *(here->MOS1DPdpPtr) +=
+                    (here->MOS1drainConductance+here->MOS1gds+
+                    here->MOS1gbd+xrev*(here->MOS1gm+here->MOS1gmbs)+gcgd);
+            *(here->MOS1SPspPtr) +=
+                    (here->MOS1sourceConductance+here->MOS1gds+
+                    here->MOS1gbs+xnrm*(here->MOS1gm+here->MOS1gmbs)+gcgs);
            *(here->MOS1DdpPtr) += (-here->MOS1drainConductance);
            *(here->MOS1GbPtr) -= gcgb;
            *(here->MOS1GdpPtr) -= gcgd;
@ -928,13 +929,13 @@ next1:      if(vbs <= -3*vt) {
            *(here->MOS1DPgPtr) += ((xnrm-xrev)*here->MOS1gm-gcgd);
            *(here->MOS1DPbPtr) += (-here->MOS1gbd+(xnrm-xrev)*here->MOS1gmbs);
            *(here->MOS1DPspPtr) += (-here->MOS1gds-xnrm*
-				     (here->MOS1gm+here->MOS1gmbs));
+                     (here->MOS1gm+here->MOS1gmbs));
            *(here->MOS1SPgPtr) += (-(xnrm-xrev)*here->MOS1gm-gcgs);
            *(here->MOS1SPsPtr) += (-here->MOS1sourceConductance);
            *(here->MOS1SPbPtr) += (-here->MOS1gbs-(xnrm-xrev)*here->MOS1gmbs);
            *(here->MOS1SPdpPtr) += (-here->MOS1gds-xrev*
-				     (here->MOS1gm+here->MOS1gmbs));
+                     (here->MOS1gm+here->MOS1gmbs));
        }
    }
    return(OK);
-}
+} /* end of function MOS1load */