/* Model initialize function */
void xpcosc_initialize(boolean_T firstTime)
{
(void)firstTime;
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)xpcosc_rtM, 0,
sizeof(rtModel_xpcosc));
{
/* Setup solver object */
rtsiSetSimTimeStepPtr(&xpcosc_rtM->solverInfo,
&xpcosc_rtM->Timing.simTimeStep);
rtsiSetTPtr(&xpcosc_rtM->solverInfo, &rtmGetTPtr(xpcosc_rtM));
rtsiSetStepSizePtr(&xpcosc_rtM->solverInfo, &xpcosc_rtM->Timing.stepSize0);
rtsiSetdXPtr(&xpcosc_rtM->solverInfo, &xpcosc_rtM->ModelData.derivs);
rtsiSetContStatesPtr(&xpcosc_rtM->solverInfo,
&xpcosc_rtM->ModelData.contStates);
rtsiSetNumContStatesPtr(&xpcosc_rtM->solverInfo,
&xpcosc_rtM->Sizes.numContStates);
rtsiSetErrorStatusPtr(&xpcosc_rtM->solverInfo, (&rtmGetErrorStatus
(xpcosc_rtM)));
rtsiSetRTModelPtr(&xpcosc_rtM->solverInfo, xpcosc_rtM);
}
rtsiSetSimTimeStep(&xpcosc_rtM->solverInfo, MAJOR_TIME_STEP);
xpcosc_rtM->ModelData.intgData.y = xpcosc_rtM->ModelData.odeY;
xpcosc_rtM->ModelData.intgData.f[0] = xpcosc_rtM->ModelData.odeF[0];
xpcosc_rtM->ModelData.intgData.f[1] = xpcosc_rtM->ModelData.odeF[1];
xpcosc_rtM->ModelData.intgData.f[2] = xpcosc_rtM->ModelData.odeF[2];
xpcosc_rtM->ModelData.intgData.f[3] = xpcosc_rtM->ModelData.odeF[3];
xpcosc_rtM->ModelData.contStates = ((real_T *) &xpcosc_X);
rtsiSetSolverData(&xpcosc_rtM->solverInfo, (void *)
&xpcosc_rtM->ModelData.intgData);
rtsiSetSolverName(&xpcosc_rtM->solverInfo,"ode4");
xpcosc_rtM->solverInfoPtr = (&xpcosc_rtM->solverInfo);
/* Initialize timing info */
{
int_T *mdlTsMap = xpcosc_rtM->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
mdlTsMap[1] = 1;
xpcosc_rtM->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
xpcosc_rtM->Timing.sampleTimes = (&xpcosc_rtM->Timing.sampleTimesArray[0]);
xpcosc_rtM->Timing.offsetTimes = (&xpcosc_rtM->Timing.offsetTimesArray[0]);
/* task periods */
xpcosc_rtM->Timing.sampleTimes[0] = (0.0);
xpcosc_rtM->Timing.sampleTimes[1] = (0.001);
/* task offsets */
xpcosc_rtM->Timing.offsetTimes[0] = (0.0);
xpcosc_rtM->Timing.offsetTimes[1] = (0.0);
}
rtmSetTPtr(xpcosc_rtM, &xpcosc_rtM->Timing.tArray[0]);
{
int_T *mdlSampleHits = xpcosc_rtM->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
mdlSampleHits[1] = 1;
xpcosc_rtM->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(xpcosc_rtM, 0.2);
xpcosc_rtM->Timing.stepSize0 = 0.001;
xpcosc_rtM->Timing.stepSize1 = 0.001;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
xpcosc_rtM->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
/*
* Set pointers to the data and signal info each state
*/
{
static int_T rt_LoggedStateWidths[] = {
1,
1
};
static int_T rt_LoggedStateNumDimensions[] = {
1,
1
};
static int_T rt_LoggedStateDimensions[] = {
1,
1
};
static boolean_T rt_LoggedStateIsVarDims[] = {
0,
0
};
static BuiltInDTypeId rt_LoggedStateDataTypeIds[] = {
SS_DOUBLE,
SS_DOUBLE
};
static int_T rt_LoggedStateComplexSignals[] = {
0,
0
};
static const char_T *rt_LoggedStateLabels[] = {
"CSTATE",
"CSTATE"
};
static const char_T *rt_LoggedStateBlockNames[] = {
"xpcosc/Integrator1",
"xpcosc/Integrator"
};
static const char_T *rt_LoggedStateNames[] = {
"",
""
};
static boolean_T rt_LoggedStateCrossMdlRef[] = {
0,
0
};
static RTWLogDataTypeConvert rt_RTWLogDataTypeConvert[] = {
{ 0, SS_DOUBLE, SS_DOUBLE, 0, 0, 0, 1.0, 0, 0.0 },
{ 0, SS_DOUBLE, SS_DOUBLE, 0, 0, 0, 1.0, 0, 0.0 }
};
static RTWLogSignalInfo rt_LoggedStateSignalInfo = {
2,
rt_LoggedStateWidths,
rt_LoggedStateNumDimensions,
rt_LoggedStateDimensions,
rt_LoggedStateIsVarDims,
(NULL),
rt_LoggedStateDataTypeIds,
rt_LoggedStateComplexSignals,
(NULL),
{ rt_LoggedStateLabels },
(NULL),
(NULL),
(NULL),
{ rt_LoggedStateBlockNames },
{ rt_LoggedStateNames },
rt_LoggedStateCrossMdlRef,
rt_RTWLogDataTypeConvert
};
static void * rt_LoggedStateSignalPtrs[2];
rtliSetLogXSignalPtrs(xpcosc_rtM->rtwLogInfo, (LogSignalPtrsType)
rt_LoggedStateSignalPtrs);
rtliSetLogXSignalInfo(xpcosc_rtM->rtwLogInfo, &rt_LoggedStateSignalInfo);
rt_LoggedStateSignalPtrs[0] = (void*)&xpcosc_X.Integrator1_CSTATE;
rt_LoggedStateSignalPtrs[1] = (void*)&xpcosc_X.Integrator_CSTATE;
}
rtliSetLogT(xpcosc_rtM->rtwLogInfo, "tout");
rtliSetLogX(xpcosc_rtM->rtwLogInfo, "xout");
rtliSetLogXFinal(xpcosc_rtM->rtwLogInfo, "");
rtliSetSigLog(xpcosc_rtM->rtwLogInfo, "");
rtliSetLogVarNameModifier(xpcosc_rtM->rtwLogInfo, "rt_");
rtliSetLogFormat(xpcosc_rtM->rtwLogInfo, 0);
rtliSetLogMaxRows(xpcosc_rtM->rtwLogInfo, 0);
rtliSetLogDecimation(xpcosc_rtM->rtwLogInfo, 1);
/*
* Set pointers to the data and signal info for each output
*/
{
static void * rt_LoggedOutputSignalPtrs[] = {
&xpcosc_Y.Outport[0]
};
rtliSetLogYSignalPtrs(xpcosc_rtM->rtwLogInfo, ((LogSignalPtrsType)
rt_LoggedOutputSignalPtrs));
}
{
static int_T rt_LoggedOutputWidths[] = {
2
};
static int_T rt_LoggedOutputNumDimensions[] = {
1
};
static int_T rt_LoggedOutputDimensions[] = {
2
};
static boolean_T rt_LoggedOutputIsVarDims[] = {
0
};
static int_T* rt_LoggedCurrentSignalDimensions[] = {
(NULL)
};
static BuiltInDTypeId rt_LoggedOutputDataTypeIds[] = {
SS_DOUBLE
};
static int_T rt_LoggedOutputComplexSignals[] = {
0
};
static const char_T *rt_LoggedOutputLabels[] = {
"" };
static const char_T *rt_LoggedOutputBlockNames[] = {
"xpcosc/Outport" };
static RTWLogDataTypeConvert rt_RTWLogDataTypeConvert[] = {
{ 0, SS_DOUBLE, SS_DOUBLE, 0, 0, 0, 1.0, 0, 0.0 }
};
static RTWLogSignalInfo rt_LoggedOutputSignalInfo[] = {
{
1,
rt_LoggedOutputWidths,
rt_LoggedOutputNumDimensions,
rt_LoggedOutputDimensions,
rt_LoggedOutputIsVarDims,
rt_LoggedCurrentSignalDimensions,
rt_LoggedOutputDataTypeIds,
rt_LoggedOutputComplexSignals,
(NULL),
{ rt_LoggedOutputLabels },
(NULL),
(NULL),
(NULL),
{ rt_LoggedOutputBlockNames },
{ (NULL) },
(NULL),
rt_RTWLogDataTypeConvert
}
};
rtliSetLogYSignalInfo(xpcosc_rtM->rtwLogInfo, rt_LoggedOutputSignalInfo);
/* set currSigDims field */
rt_LoggedCurrentSignalDimensions[0] = &rt_LoggedOutputWidths[0];
}
rtliSetLogY(xpcosc_rtM->rtwLogInfo, "yout");
}
/* external mode info */
xpcosc_rtM->Sizes.checksums[0] = (1235351435U);
xpcosc_rtM->Sizes.checksums[1] = (4143988505U);
xpcosc_rtM->Sizes.checksums[2] = (362576123U);
xpcosc_rtM->Sizes.checksums[3] = (1068881914U);
{
static const sysRanDType rtAlwaysEnabled = SUBSYS_RAN_BC_ENABLE;
static RTWExtModeInfo rt_ExtModeInfo;
static const sysRanDType *systemRan[1];
xpcosc_rtM->extModeInfo = (&rt_ExtModeInfo);
rteiSetSubSystemActiveVectorAddresses(&rt_ExtModeInfo, systemRan);
systemRan[0] = &rtAlwaysEnabled;
rteiSetModelMappingInfoPtr(xpcosc_rtM->extModeInfo,
&xpcosc_rtM->SpecialInfo.mappingInfo);
rteiSetChecksumsPtr(xpcosc_rtM->extModeInfo, xpcosc_rtM->Sizes.checksums);
rteiSetTPtr(xpcosc_rtM->extModeInfo, rtmGetTPtr(xpcosc_rtM));
}
xpcosc_rtM->solverInfoPtr = (&xpcosc_rtM->solverInfo);
xpcosc_rtM->Timing.stepSize = (0.001);
rtsiSetFixedStepSize(&xpcosc_rtM->solverInfo, 0.001);
rtsiSetSolverMode(&xpcosc_rtM->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
xpcosc_rtM->ModelData.blockIO = ((void *) &xpcosc_B);
{
xpcosc_B.Integrator1 = 0.0;
xpcosc_B.PCI6221AD = 0.0;
xpcosc_B.RateTransition1 = 0.0;
xpcosc_B.SignalGenerator = 0.0;
xpcosc_B.RateTransition = 0.0;
xpcosc_B.Gain = 0.0;
xpcosc_B.Integrator = 0.0;
xpcosc_B.Gain1 = 0.0;
xpcosc_B.Gain2 = 0.0;
xpcosc_B.Sum = 0.0;
}
/* parameters */
xpcosc_rtM->ModelData.defaultParam = ((real_T *)&xpcosc_P);
/* states (continuous) */
{
real_T *x = (real_T *) &xpcosc_X;
xpcosc_rtM->ModelData.contStates = (x);
(void) memset((void *)&xpcosc_X, 0,
sizeof(ContinuousStates_xpcosc));
}
/* states (dwork) */
xpcosc_rtM->Work.dwork = ((void *) &xpcosc_DWork);
(void) memset((void *)&xpcosc_DWork, 0,
sizeof(D_Work_xpcosc));
xpcosc_DWork.PCI6713DA_RWORK = 0.0;
/* external outputs */
xpcosc_rtM->ModelData.outputs = (&xpcosc_Y);
xpcosc_Y.Outport[0] = 0.0;
xpcosc_Y.Outport[1] = 0.0;
/* data type transition information */
{
static DataTypeTransInfo dtInfo;
(void) memset((char_T *) &dtInfo, 0,
sizeof(dtInfo));
xpcosc_rtM->SpecialInfo.mappingInfo = (&dtInfo);
xpcosc_rtM->SpecialInfo.xpcData = ((void*) &dtInfo);
dtInfo.numDataTypes = 14;
dtInfo.dataTypeSizes = &rtDataTypeSizes[0];
dtInfo.dataTypeNames = &rtDataTypeNames[0];
/* Block I/O transition table */
dtInfo.B = &rtBTransTable;
/* Parameters transition table */
dtInfo.P = &rtPTransTable;
}
/* Initialize DataMapInfo substructure containing ModelMap for C API */
xpcosc_InitializeDataMapInfo(xpcosc_rtM);
/* child S-Function registration */
{
RTWSfcnInfo *sfcnInfo = &xpcosc_rtM->NonInlinedSFcns.sfcnInfo;
xpcosc_rtM->sfcnInfo = (sfcnInfo);
rtssSetErrorStatusPtr(sfcnInfo, (&rtmGetErrorStatus(xpcosc_rtM)));
rtssSetNumRootSampTimesPtr(sfcnInfo, &xpcosc_rtM->Sizes.numSampTimes);
xpcosc_rtM->NonInlinedSFcns.taskTimePtrs[0] = &(rtmGetTPtr(xpcosc_rtM)[0]);
xpcosc_rtM->NonInlinedSFcns.taskTimePtrs[1] = &(rtmGetTPtr(xpcosc_rtM)[1]);
rtssSetTPtrPtr(sfcnInfo,xpcosc_rtM->NonInlinedSFcns.taskTimePtrs);
rtssSetTStartPtr(sfcnInfo, &rtmGetTStart(xpcosc_rtM));
rtssSetTFinalPtr(sfcnInfo, &rtmGetTFinal(xpcosc_rtM));
rtssSetTimeOfLastOutputPtr(sfcnInfo, &rtmGetTimeOfLastOutput(xpcosc_rtM));
rtssSetStepSizePtr(sfcnInfo, &xpcosc_rtM->Timing.stepSize);
rtssSetStopRequestedPtr(sfcnInfo, &rtmGetStopRequested(xpcosc_rtM));
rtssSetDerivCacheNeedsResetPtr(sfcnInfo,
&xpcosc_rtM->ModelData.derivCacheNeedsReset);
rtssSetZCCacheNeedsResetPtr(sfcnInfo,
&xpcosc_rtM->ModelData.zCCacheNeedsReset);
rtssSetBlkStateChangePtr(sfcnInfo, &xpcosc_rtM->ModelData.blkStateChange);
rtssSetSampleHitsPtr(sfcnInfo, &xpcosc_rtM->Timing.sampleHits);
rtssSetPerTaskSampleHitsPtr(sfcnInfo, &xpcosc_rtM->Timing.perTaskSampleHits);
rtssSetSimModePtr(sfcnInfo, &xpcosc_rtM->simMode);
rtssSetSolverInfoPtr(sfcnInfo, &xpcosc_rtM->solverInfoPtr);
}
xpcosc_rtM->Sizes.numSFcns = (2);
/* register each child */
{
(void) memset((void *)&xpcosc_rtM->NonInlinedSFcns.childSFunctions[0], 0,
2*sizeof(SimStruct));
xpcosc_rtM->childSfunctions =
(&xpcosc_rtM->NonInlinedSFcns.childSFunctionPtrs[0]);
xpcosc_rtM->childSfunctions[0] =
(&xpcosc_rtM->NonInlinedSFcns.childSFunctions[0]);
xpcosc_rtM->childSfunctions[1] =
(&xpcosc_rtM->NonInlinedSFcns.childSFunctions[1]);
/* Level2 S-Function Block: xpcosc/<Root>/PCI-6221 AD (adnipcim) */
{
SimStruct *rts = xpcosc_rtM->childSfunctions[0];
/* timing info */
time_T *sfcnPeriod = xpcosc_rtM->NonInlinedSFcns.Sfcn0.sfcnPeriod;
time_T *sfcnOffset = xpcosc_rtM->NonInlinedSFcns.Sfcn0.sfcnOffset;
int_T *sfcnTsMap = xpcosc_rtM->NonInlinedSFcns.Sfcn0.sfcnTsMap;
(void) memset((void*)sfcnPeriod, 0,
sizeof(time_T)*1);
(void) memset((void*)sfcnOffset, 0,
sizeof(time_T)*1);
ssSetSampleTimePtr(rts, &sfcnPeriod[0]);
ssSetOffsetTimePtr(rts, &sfcnOffset[0]);
ssSetSampleTimeTaskIDPtr(rts, sfcnTsMap);
/* Set up the mdlInfo pointer */
{
ssSetBlkInfo2Ptr(rts, &xpcosc_rtM->NonInlinedSFcns.blkInfo2[0]);
}
ssSetRTWSfcnInfo(rts, xpcosc_rtM->sfcnInfo);
/* Allocate memory of model methods 2 */
{
ssSetModelMethods2(rts, &xpcosc_rtM->NonInlinedSFcns.methods2[0]);
}
/* Allocate memory of model methods 3 */
{
ssSetModelMethods3(rts, &xpcosc_rtM->NonInlinedSFcns.methods3[0]);
}
/* Allocate memory for states auxilliary information */
{
ssSetStatesInfo2(rts, &xpcosc_rtM->NonInlinedSFcns.statesInfo2[0]);
}
/* outputs */
{
ssSetPortInfoForOutputs(rts,
&xpcosc_rtM->NonInlinedSFcns.Sfcn0.outputPortInfo[0]);
_ssSetNumOutputPorts(rts, 1);
/* port 0 */
{
_ssSetOutputPortNumDimensions(rts, 0, 1);
ssSetOutputPortWidth(rts, 0, 1);
ssSetOutputPortSignal(rts, 0, ((real_T *) &xpcosc_B.PCI6221AD));
}
}
/* path info */
ssSetModelName(rts, "PCI-6221 AD");
ssSetPath(rts, "xpcosc/PCI-6221 AD");
ssSetRTModel(rts,xpcosc_rtM);
ssSetParentSS(rts, (NULL));
ssSetRootSS(rts, rts);
ssSetVersion(rts, SIMSTRUCT_VERSION_LEVEL2);
/* parameters */
{
mxArray **sfcnParams = (mxArray **)
&xpcosc_rtM->NonInlinedSFcns.Sfcn0.params;
ssSetSFcnParamsCount(rts, 7);
ssSetSFcnParamsPtr(rts, &sfcnParams[0]);
ssSetSFcnParam(rts, 0, (mxArray*)xpcosc_P.PCI6221AD_P1_Size);
ssSetSFcnParam(rts, 1, (mxArray*)xpcosc_P.PCI6221AD_P2_Size);
ssSetSFcnParam(rts, 2, (mxArray*)xpcosc_P.PCI6221AD_P3_Size);
ssSetSFcnParam(rts, 3, (mxArray*)xpcosc_P.PCI6221AD_P4_Size);
ssSetSFcnParam(rts, 4, (mxArray*)xpcosc_P.PCI6221AD_P5_Size);
ssSetSFcnParam(rts, 5, (mxArray*)xpcosc_P.PCI6221AD_P6_Size);
ssSetSFcnParam(rts, 6, (mxArray*)xpcosc_P.PCI6221AD_P7_Size);
}
/* work vectors */
ssSetIWork(rts, (int_T *) &xpcosc_DWork.PCI6221AD_IWORK[0]);
ssSetPWork(rts, (void **) &xpcosc_DWork.PCI6221AD_PWORK);
{
struct _ssDWorkRecord *dWorkRecord = (struct _ssDWorkRecord *)
&xpcosc_rtM->NonInlinedSFcns.Sfcn0.dWork;
struct _ssDWorkAuxRecord *dWorkAuxRecord = (struct _ssDWorkAuxRecord *)
&xpcosc_rtM->NonInlinedSFcns.Sfcn0.dWorkAux;
ssSetSFcnDWork(rts, dWorkRecord);
ssSetSFcnDWorkAux(rts, dWorkAuxRecord);
_ssSetNumDWork(rts, 2);
/* IWORK */
ssSetDWorkWidth(rts, 0, 41);
ssSetDWorkDataType(rts, 0,SS_INTEGER);
ssSetDWorkComplexSignal(rts, 0, 0);
ssSetDWork(rts, 0, &xpcosc_DWork.PCI6221AD_IWORK[0]);
/* PWORK */
ssSetDWorkWidth(rts, 1, 1);
ssSetDWorkDataType(rts, 1,SS_POINTER);
ssSetDWorkComplexSignal(rts, 1, 0);
ssSetDWork(rts, 1, &xpcosc_DWork.PCI6221AD_PWORK);
}
/* registration */
adnipcim(rts);
sfcnInitializeSizes(rts);
sfcnInitializeSampleTimes(rts);
/* adjust sample time */
ssSetSampleTime(rts, 0, 0.001);
ssSetOffsetTime(rts, 0, 0.0);
sfcnTsMap[0] = 1;
/* set compiled values of dynamic vector attributes */
ssSetNumNonsampledZCs(rts, 0);
/* Update connectivity flags for each port */
_ssSetOutputPortConnected(rts, 0, 1);
_ssSetOutputPortBeingMerged(rts, 0, 0);
/* Update the BufferDstPort flags for each input port */
}
/* Level2 S-Function Block: xpcosc/<Root>/PCI-6713 DA (danipci671x) */
{
SimStruct *rts = xpcosc_rtM->childSfunctions[1];
/* timing info */
time_T *sfcnPeriod = xpcosc_rtM->NonInlinedSFcns.Sfcn1.sfcnPeriod;
time_T *sfcnOffset = xpcosc_rtM->NonInlinedSFcns.Sfcn1.sfcnOffset;
int_T *sfcnTsMap = xpcosc_rtM->NonInlinedSFcns.Sfcn1.sfcnTsMap;
(void) memset((void*)sfcnPeriod, 0,
sizeof(time_T)*1);
(void) memset((void*)sfcnOffset, 0,
sizeof(time_T)*1);
ssSetSampleTimePtr(rts, &sfcnPeriod[0]);
ssSetOffsetTimePtr(rts, &sfcnOffset[0]);
ssSetSampleTimeTaskIDPtr(rts, sfcnTsMap);
/* Set up the mdlInfo pointer */
{
ssSetBlkInfo2Ptr(rts, &xpcosc_rtM->NonInlinedSFcns.blkInfo2[1]);
}
ssSetRTWSfcnInfo(rts, xpcosc_rtM->sfcnInfo);
/* Allocate memory of model methods 2 */
{
ssSetModelMethods2(rts, &xpcosc_rtM->NonInlinedSFcns.methods2[1]);
}
/* Allocate memory of model methods 3 */
{
ssSetModelMethods3(rts, &xpcosc_rtM->NonInlinedSFcns.methods3[1]);
}
/* Allocate memory for states auxilliary information */
{
ssSetStatesInfo2(rts, &xpcosc_rtM->NonInlinedSFcns.statesInfo2[1]);
}
/* inputs */
{
_ssSetNumInputPorts(rts, 1);
ssSetPortInfoForInputs(rts,
&xpcosc_rtM->NonInlinedSFcns.Sfcn1.inputPortInfo[0]);
/* port 0 */
{
real_T const **sfcnUPtrs = (real_T const **)
&xpcosc_rtM->NonInlinedSFcns.Sfcn1.UPtrs0;
sfcnUPtrs[0] = &xpcosc_B.RateTransition;
ssSetInputPortSignalPtrs(rts, 0, (InputPtrsType)&sfcnUPtrs[0]);
_ssSetInputPortNumDimensions(rts, 0, 1);
ssSetInputPortWidth(rts, 0, 1);
}
}
/* path info */
ssSetModelName(rts, "PCI-6713 DA");
ssSetPath(rts, "xpcosc/PCI-6713 DA");
ssSetRTModel(rts,xpcosc_rtM);
ssSetParentSS(rts, (NULL));
ssSetRootSS(rts, rts);
ssSetVersion(rts, SIMSTRUCT_VERSION_LEVEL2);
/* parameters */
{
mxArray **sfcnParams = (mxArray **)
&xpcosc_rtM->NonInlinedSFcns.Sfcn1.params;
ssSetSFcnParamsCount(rts, 6);
ssSetSFcnParamsPtr(rts, &sfcnParams[0]);
ssSetSFcnParam(rts, 0, (mxArray*)xpcosc_P.PCI6713DA_P1_Size);
ssSetSFcnParam(rts, 1, (mxArray*)xpcosc_P.PCI6713DA_P2_Size);
ssSetSFcnParam(rts, 2, (mxArray*)xpcosc_P.PCI6713DA_P3_Size);
ssSetSFcnParam(rts, 3, (mxArray*)xpcosc_P.PCI6713DA_P4_Size);
ssSetSFcnParam(rts, 4, (mxArray*)xpcosc_P.PCI6713DA_P5_Size);
ssSetSFcnParam(rts, 5, (mxArray*)xpcosc_P.PCI6713DA_P6_Size);
}
/* work vectors */
ssSetRWork(rts, (real_T *) &xpcosc_DWork.PCI6713DA_RWORK);
ssSetIWork(rts, (int_T *) &xpcosc_DWork.PCI6713DA_IWORK[0]);
{
struct _ssDWorkRecord *dWorkRecord = (struct _ssDWorkRecord *)
&xpcosc_rtM->NonInlinedSFcns.Sfcn1.dWork;
struct _ssDWorkAuxRecord *dWorkAuxRecord = (struct _ssDWorkAuxRecord *)
&xpcosc_rtM->NonInlinedSFcns.Sfcn1.dWorkAux;
ssSetSFcnDWork(rts, dWorkRecord);
ssSetSFcnDWorkAux(rts, dWorkAuxRecord);
_ssSetNumDWork(rts, 2);
/* RWORK */
ssSetDWorkWidth(rts, 0, 1);
ssSetDWorkDataType(rts, 0,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 0, 0);
ssSetDWork(rts, 0, &xpcosc_DWork.PCI6713DA_RWORK);
/* IWORK */
ssSetDWorkWidth(rts, 1, 2);
ssSetDWorkDataType(rts, 1,SS_INTEGER);
ssSetDWorkComplexSignal(rts, 1, 0);
ssSetDWork(rts, 1, &xpcosc_DWork.PCI6713DA_IWORK[0]);
}
/* registration */
danipci671x(rts);
sfcnInitializeSizes(rts);
sfcnInitializeSampleTimes(rts);
/* adjust sample time */
ssSetSampleTime(rts, 0, 0.001);
ssSetOffsetTime(rts, 0, 0.0);
sfcnTsMap[0] = 1;
/* set compiled values of dynamic vector attributes */
ssSetNumNonsampledZCs(rts, 0);
/* Update connectivity flags for each port */
_ssSetInputPortConnected(rts, 0, 1);
/* Update the BufferDstPort flags for each input port */
ssSetInputPortBufferDstPort(rts, 0, -1);
}
}
}
/* Registration function */
RT_MODEL_motor_io_position_T *motor_io_position(void)
{
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)motor_io_position_M, 0,
sizeof(RT_MODEL_motor_io_position_T));
{
/* Setup solver object */
rtsiSetSimTimeStepPtr(&motor_io_position_M->solverInfo,
&motor_io_position_M->Timing.simTimeStep);
rtsiSetTPtr(&motor_io_position_M->solverInfo, &rtmGetTPtr
(motor_io_position_M));
rtsiSetStepSizePtr(&motor_io_position_M->solverInfo,
&motor_io_position_M->Timing.stepSize0);
rtsiSetdXPtr(&motor_io_position_M->solverInfo,
&motor_io_position_M->ModelData.derivs);
rtsiSetContStatesPtr(&motor_io_position_M->solverInfo, (real_T **)
&motor_io_position_M->ModelData.contStates);
rtsiSetNumContStatesPtr(&motor_io_position_M->solverInfo,
&motor_io_position_M->Sizes.numContStates);
rtsiSetErrorStatusPtr(&motor_io_position_M->solverInfo, (&rtmGetErrorStatus
(motor_io_position_M)));
rtsiSetRTModelPtr(&motor_io_position_M->solverInfo, motor_io_position_M);
}
rtsiSetSimTimeStep(&motor_io_position_M->solverInfo, MAJOR_TIME_STEP);
motor_io_position_M->ModelData.intgData.f[0] =
motor_io_position_M->ModelData.odeF[0];
motor_io_position_M->ModelData.contStates = ((real_T *) &motor_io_position_X);
rtsiSetSolverData(&motor_io_position_M->solverInfo, (void *)
&motor_io_position_M->ModelData.intgData);
rtsiSetSolverName(&motor_io_position_M->solverInfo,"ode1");
/* Initialize timing info */
{
int_T *mdlTsMap = motor_io_position_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
mdlTsMap[1] = 1;
motor_io_position_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
motor_io_position_M->Timing.sampleTimes =
(&motor_io_position_M->Timing.sampleTimesArray[0]);
motor_io_position_M->Timing.offsetTimes =
(&motor_io_position_M->Timing.offsetTimesArray[0]);
/* task periods */
motor_io_position_M->Timing.sampleTimes[0] = (0.0);
motor_io_position_M->Timing.sampleTimes[1] = (0.03642463102798723);
/* task offsets */
motor_io_position_M->Timing.offsetTimes[0] = (0.0);
motor_io_position_M->Timing.offsetTimes[1] = (0.0);
}
rtmSetTPtr(motor_io_position_M, &motor_io_position_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = motor_io_position_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
mdlSampleHits[1] = 1;
motor_io_position_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(motor_io_position_M, -1);
motor_io_position_M->Timing.stepSize0 = 0.03642463102798723;
motor_io_position_M->Timing.stepSize1 = 0.03642463102798723;
motor_io_position_M->solverInfoPtr = (&motor_io_position_M->solverInfo);
motor_io_position_M->Timing.stepSize = (0.03642463102798723);
rtsiSetFixedStepSize(&motor_io_position_M->solverInfo, 0.03642463102798723);
rtsiSetSolverMode(&motor_io_position_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
motor_io_position_M->ModelData.blockIO = ((void *) &motor_io_position_B);
(void) memset(((void *) &motor_io_position_B), 0,
sizeof(B_motor_io_position_T));
{
motor_io_position_B.SFunction1 = 0.0;
motor_io_position_B.fi1_scaling = 0.0;
motor_io_position_B.Gfbreal = 0.0;
motor_io_position_B.SinGenerator = 0.0;
motor_io_position_B.SquareGenerator = 0.0;
motor_io_position_B.ref = 0.0;
motor_io_position_B.Gffreal = 0.0;
motor_io_position_B.Sum = 0.0;
motor_io_position_B.Gain = 0.0;
motor_io_position_B.Volt = 0.0;
motor_io_position_B.pwm_skalning = 0.0;
motor_io_position_B.Sum_f = 0.0;
motor_io_position_B.Gff = 0.0;
motor_io_position_B.Integrator1 = 0.0;
motor_io_position_B.Quantizer = 0.0;
motor_io_position_B.ZeroOrderHold = 0.0;
motor_io_position_B.Gfb = 0.0;
motor_io_position_B.Sum1 = 0.0;
motor_io_position_B.Saturation = 0.0;
motor_io_position_B.Integrator = 0.0;
motor_io_position_B.Gain1 = 0.0;
motor_io_position_B.Add = 0.0;
motor_io_position_B.kR = 0.0;
motor_io_position_B.Stickslipregion = 0.0;
motor_io_position_B.Abs = 0.0;
motor_io_position_B.Vicousfriction = 0.0;
motor_io_position_B.Sign = 0.0;
motor_io_position_B.Product = 0.0;
motor_io_position_B.Viscousregion = 0.0;
motor_io_position_B.Friction = 0.0;
motor_io_position_B.Add1 = 0.0;
motor_io_position_B.Gain2 = 0.0;
motor_io_position_B.Add2 = 0.0;
motor_io_position_B.Inertias1J = 0.0;
motor_io_position_B.Switch1 = 0.0;
motor_io_position_B.SFunction2 = 0.0;
motor_io_position_B.w1_scaling = 0.0;
}
/* parameters */
motor_io_position_M->ModelData.defaultParam = ((real_T *)&motor_io_position_P);
/* states (continuous) */
{
real_T *x = (real_T *) &motor_io_position_X;
motor_io_position_M->ModelData.contStates = (x);
(void) memset((void *)&motor_io_position_X, 0,
sizeof(X_motor_io_position_T));
}
/* states (dwork) */
motor_io_position_M->ModelData.dwork = ((void *) &motor_io_position_DW);
(void) memset((void *)&motor_io_position_DW, 0,
sizeof(DW_motor_io_position_T));
motor_io_position_DW.Gfbreal_states[0] = 0.0;
motor_io_position_DW.Gfbreal_states[1] = 0.0;
motor_io_position_DW.Gffreal_states[0] = 0.0;
motor_io_position_DW.Gffreal_states[1] = 0.0;
motor_io_position_DW.Gff_states[0] = 0.0;
motor_io_position_DW.Gff_states[1] = 0.0;
motor_io_position_DW.Gfb_states[0] = 0.0;
motor_io_position_DW.Gfb_states[1] = 0.0;
motor_io_position_DW.Gfbreal_tmp = 0.0;
motor_io_position_DW.Gffreal_tmp = 0.0;
motor_io_position_DW.Gff_tmp = 0.0;
motor_io_position_DW.Gfb_tmp = 0.0;
{
/* user code (registration function declaration) */
/*Call the macro that initializes the global TRC pointers
inside the model initialization/registration function. */
RTI_INIT_TRC_POINTERS();
}
/* Initialize Sizes */
motor_io_position_M->Sizes.numContStates = (2);/* Number of continuous states */
motor_io_position_M->Sizes.numY = (0);/* Number of model outputs */
motor_io_position_M->Sizes.numU = (0);/* Number of model inputs */
motor_io_position_M->Sizes.sysDirFeedThru = (0);/* The model is not direct feedthrough */
motor_io_position_M->Sizes.numSampTimes = (2);/* Number of sample times */
motor_io_position_M->Sizes.numBlocks = (58);/* Number of blocks */
motor_io_position_M->Sizes.numBlockIO = (39);/* Number of block outputs */
motor_io_position_M->Sizes.numBlockPrms = (58);/* Sum of parameter "widths" */
return motor_io_position_M;
}
/* Model initialize function */
void Crane_initialize(boolean_T firstTime)
{
(void)firstTime;
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T)); /* initialize real-time model */
(void) memset((char_T *)Crane_M,0,
sizeof(RT_MODEL_Crane));
{
/* Setup solver object */
rtsiSetSimTimeStepPtr(&Crane_M->solverInfo, &Crane_M->Timing.simTimeStep);
rtsiSetTPtr(&Crane_M->solverInfo, &rtmGetTPtr(Crane_M));
rtsiSetStepSizePtr(&Crane_M->solverInfo, &Crane_M->Timing.stepSize0);
rtsiSetdXPtr(&Crane_M->solverInfo, &Crane_M->ModelData.derivs);
rtsiSetContStatesPtr(&Crane_M->solverInfo, &Crane_M->ModelData.contStates);
rtsiSetNumContStatesPtr(&Crane_M->solverInfo, &Crane_M->Sizes.numContStates);
rtsiSetErrorStatusPtr(&Crane_M->solverInfo, (&rtmGetErrorStatus(Crane_M)));
rtsiSetRTModelPtr(&Crane_M->solverInfo, Crane_M);
}
rtsiSetSimTimeStep(&Crane_M->solverInfo, MAJOR_TIME_STEP);
Crane_M->ModelData.intgData.f[0] = Crane_M->ModelData.odeF[0];
Crane_M->ModelData.contStates = ((real_T *) &Crane_X);
rtsiSetSolverData(&Crane_M->solverInfo, (void *)&Crane_M->ModelData.intgData);
rtsiSetSolverName(&Crane_M->solverInfo,"ode1");
/* Initialize timing info */
{
int_T *mdlTsMap = Crane_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
mdlTsMap[1] = 1;
Crane_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
Crane_M->Timing.sampleTimes = (&Crane_M->Timing.sampleTimesArray[0]);
Crane_M->Timing.offsetTimes = (&Crane_M->Timing.offsetTimesArray[0]);
/* task periods */
Crane_M->Timing.sampleTimes[0] = (0.0);
Crane_M->Timing.sampleTimes[1] = (0.001);
/* task offsets */
Crane_M->Timing.offsetTimes[0] = (0.0);
Crane_M->Timing.offsetTimes[1] = (0.0);
}
rtmSetTPtr(Crane_M, &Crane_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = Crane_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
mdlSampleHits[1] = 1;
Crane_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(Crane_M, -1);
Crane_M->Timing.stepSize0 = 0.001;
Crane_M->Timing.stepSize1 = 0.001;
/* external mode info */
Crane_M->Sizes.checksums[0] = (2478158774U);
Crane_M->Sizes.checksums[1] = (3803381746U);
Crane_M->Sizes.checksums[2] = (277883647U);
Crane_M->Sizes.checksums[3] = (670793414U);
{
static const sysRanDType rtAlwaysEnabled = SUBSYS_RAN_BC_ENABLE;
static RTWExtModeInfo rt_ExtModeInfo;
static const sysRanDType *systemRan[1];
Crane_M->extModeInfo = (&rt_ExtModeInfo);
rteiSetSubSystemActiveVectorAddresses(&rt_ExtModeInfo, systemRan);
systemRan[0] = &rtAlwaysEnabled;
rteiSetModelMappingInfoPtr(&rt_ExtModeInfo,
&Crane_M->SpecialInfo.mappingInfo);
rteiSetChecksumsPtr(&rt_ExtModeInfo, Crane_M->Sizes.checksums);
rteiSetTPtr(&rt_ExtModeInfo, rtmGetTPtr(Crane_M));
}
Crane_M->solverInfoPtr = (&Crane_M->solverInfo);
Crane_M->Timing.stepSize = (0.001);
rtsiSetFixedStepSize(&Crane_M->solverInfo, 0.001);
rtsiSetSolverMode(&Crane_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
Crane_M->ModelData.blockIO = ((void *) &Crane_B);
{
int_T i;
void *pVoidBlockIORegion;
pVoidBlockIORegion = (void *)(&Crane_B.Block1_o1[0]);
for (i = 0; i < 49; i++) {
((real_T*)pVoidBlockIORegion)[i] = 0.0;
}
}
/* parameters */
Crane_M->ModelData.defaultParam = ((real_T *) &Crane_P);
/* states (continuous) */
{
real_T *x = (real_T *) &Crane_X;
Crane_M->ModelData.contStates = (x);
(void) memset((char_T *)x,0,
sizeof(ContinuousStates_Crane));
}
/* states (dwork) */
Crane_M->Work.dwork = ((void *) &Crane_DWork);
(void) memset((char_T *) &Crane_DWork,0,
sizeof(D_Work_Crane));
{
int_T i;
real_T *dwork_ptr = (real_T *) &Crane_DWork.Memory_PreviousInput[0];
for (i = 0; i < 11; i++) {
dwork_ptr[i] = 0.0;
}
}
/* data type transition information */
{
static DataTypeTransInfo dtInfo;
(void) memset((char_T *) &dtInfo,0,
sizeof(dtInfo));
Crane_M->SpecialInfo.mappingInfo = (&dtInfo);
dtInfo.numDataTypes = 15;
dtInfo.dataTypeSizes = &rtDataTypeSizes[0];
dtInfo.dataTypeNames = &rtDataTypeNames[0];
/* Block I/O transition table */
dtInfo.B = &rtBTransTable;
/* Parameters transition table */
dtInfo.P = &rtPTransTable;
}
}
/* Model initialize function */
void trajectoryModel_initialize(void)
{
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* non-finite (run-time) assignments */
trajectoryModel_P.stopRadius = rtInf;
/* initialize real-time model */
(void) memset((void *)trajectoryModel_M, 0,
sizeof(RT_MODEL_trajectoryModel_T));
{
/* Setup solver object */
rtsiSetSimTimeStepPtr(&trajectoryModel_M->solverInfo,
&trajectoryModel_M->Timing.simTimeStep);
rtsiSetTPtr(&trajectoryModel_M->solverInfo, &rtmGetTPtr(trajectoryModel_M));
rtsiSetStepSizePtr(&trajectoryModel_M->solverInfo,
&trajectoryModel_M->Timing.stepSize0);
rtsiSetdXPtr(&trajectoryModel_M->solverInfo,
&trajectoryModel_M->ModelData.derivs);
rtsiSetContStatesPtr(&trajectoryModel_M->solverInfo, (real_T **)
&trajectoryModel_M->ModelData.contStates);
rtsiSetNumContStatesPtr(&trajectoryModel_M->solverInfo,
&trajectoryModel_M->Sizes.numContStates);
rtsiSetErrorStatusPtr(&trajectoryModel_M->solverInfo, (&rtmGetErrorStatus
(trajectoryModel_M)));
rtsiSetRTModelPtr(&trajectoryModel_M->solverInfo, trajectoryModel_M);
}
rtsiSetSimTimeStep(&trajectoryModel_M->solverInfo, MAJOR_TIME_STEP);
trajectoryModel_M->ModelData.intgData.y = trajectoryModel_M->ModelData.odeY;
trajectoryModel_M->ModelData.intgData.f[0] = trajectoryModel_M->
ModelData.odeF[0];
trajectoryModel_M->ModelData.intgData.f[1] = trajectoryModel_M->
ModelData.odeF[1];
trajectoryModel_M->ModelData.intgData.f[2] = trajectoryModel_M->
ModelData.odeF[2];
trajectoryModel_M->ModelData.contStates = ((X_trajectoryModel_T *)
&trajectoryModel_X);
rtsiSetSolverData(&trajectoryModel_M->solverInfo, (void *)
&trajectoryModel_M->ModelData.intgData);
rtsiSetSolverName(&trajectoryModel_M->solverInfo,"ode3");
rtmSetTPtr(trajectoryModel_M, &trajectoryModel_M->Timing.tArray[0]);
rtmSetTFinal(trajectoryModel_M, 12.0);
trajectoryModel_M->Timing.stepSize0 = 0.01;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
trajectoryModel_M->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
rtliSetLogXSignalInfo(trajectoryModel_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(trajectoryModel_M->rtwLogInfo, (NULL));
rtliSetLogT(trajectoryModel_M->rtwLogInfo, "tout");
rtliSetLogX(trajectoryModel_M->rtwLogInfo, "");
rtliSetLogXFinal(trajectoryModel_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(trajectoryModel_M->rtwLogInfo, "rt_");
rtliSetLogFormat(trajectoryModel_M->rtwLogInfo, 0);
rtliSetLogMaxRows(trajectoryModel_M->rtwLogInfo, 1000);
rtliSetLogDecimation(trajectoryModel_M->rtwLogInfo, 1);
rtliSetLogY(trajectoryModel_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(trajectoryModel_M->rtwLogInfo, (NULL));
rtliSetLogYSignalPtrs(trajectoryModel_M->rtwLogInfo, (NULL));
}
/* block I/O */
(void) memset(((void *) &trajectoryModel_B), 0,
sizeof(B_trajectoryModel_T));
/* states (continuous) */
{
(void) memset((void *)&trajectoryModel_X, 0,
sizeof(X_trajectoryModel_T));
}
/* states (dwork) */
(void) memset((void *)&trajectoryModel_DW, 0,
sizeof(DW_trajectoryModel_T));
/* Matfile logging */
rt_StartDataLoggingWithStartTime(trajectoryModel_M->rtwLogInfo, 0.0,
rtmGetTFinal(trajectoryModel_M), trajectoryModel_M->Timing.stepSize0,
(&rtmGetErrorStatus(trajectoryModel_M)));
/* Start for If: '<Root>/If' */
trajectoryModel_DW.If_ActiveSubsystem = -1;
/* Start for IfAction SubSystem: '<Root>/If Action Subsystem' */
traject_IfActionSubsystem_Start(&trajectoryModel_B.IfActionSubsystem,
(P_IfActionSubsystem_trajector_T *)&trajectoryModel_P.IfActionSubsystem);
/* End of Start for SubSystem: '<Root>/If Action Subsystem' */
/* Start for IfAction SubSystem: '<Root>/If Action Subsystem1' */
traject_IfActionSubsystem_Start(&trajectoryModel_B.IfActionSubsystem1,
(P_IfActionSubsystem_trajector_T *)&trajectoryModel_P.IfActionSubsystem1);
/* End of Start for SubSystem: '<Root>/If Action Subsystem1' */
/* InitializeConditions for Integrator: '<Root>/x' */
trajectoryModel_X.x_CSTATE = trajectoryModel_P.initialConditions[0];
/* InitializeConditions for Integrator: '<Root>/y ' */
trajectoryModel_X.y_CSTATE = trajectoryModel_P.initialConditions[2];
/* InitializeConditions for Integrator: '<Root>/dx' */
trajectoryModel_X.dx_CSTATE = trajectoryModel_P.initialConditions[1];
/* InitializeConditions for Integrator: '<Root>/dy' */
trajectoryModel_X.dy_CSTATE = trajectoryModel_P.initialConditions[3];
}
/* Model initialize function */
void Position_TiltModelClass::initialize()
{
/* Registration code */
/* initialize real-time model */
(void) memset((void *)(&Position_Tilt_M), 0,
sizeof(RT_MODEL_Position_Tilt_T));
{
/* Setup solver object */
rtsiSetSimTimeStepPtr(&(&Position_Tilt_M)->solverInfo, &(&Position_Tilt_M)
->Timing.simTimeStep);
rtsiSetTPtr(&(&Position_Tilt_M)->solverInfo, &rtmGetTPtr((&Position_Tilt_M)));
rtsiSetStepSizePtr(&(&Position_Tilt_M)->solverInfo, &(&Position_Tilt_M)
->Timing.stepSize0);
rtsiSetdXPtr(&(&Position_Tilt_M)->solverInfo, &(&Position_Tilt_M)
->ModelData.derivs);
rtsiSetContStatesPtr(&(&Position_Tilt_M)->solverInfo, (real_T **)
&(&Position_Tilt_M)->ModelData.contStates);
rtsiSetNumContStatesPtr(&(&Position_Tilt_M)->solverInfo, &(&Position_Tilt_M
)->Sizes.numContStates);
rtsiSetNumPeriodicContStatesPtr(&(&Position_Tilt_M)->solverInfo,
&(&Position_Tilt_M)->Sizes.numPeriodicContStates);
rtsiSetPeriodicContStateIndicesPtr(&(&Position_Tilt_M)->solverInfo,
&(&Position_Tilt_M)->ModelData.periodicContStateIndices);
rtsiSetPeriodicContStateRangesPtr(&(&Position_Tilt_M)->solverInfo,
&(&Position_Tilt_M)->ModelData.periodicContStateRanges);
rtsiSetErrorStatusPtr(&(&Position_Tilt_M)->solverInfo, (&rtmGetErrorStatus((
&Position_Tilt_M))));
rtsiSetRTModelPtr(&(&Position_Tilt_M)->solverInfo, (&Position_Tilt_M));
}
rtsiSetSimTimeStep(&(&Position_Tilt_M)->solverInfo, MAJOR_TIME_STEP);
(&Position_Tilt_M)->ModelData.intgData.y = (&Position_Tilt_M)->ModelData.odeY;
(&Position_Tilt_M)->ModelData.intgData.f[0] = (&Position_Tilt_M)
->ModelData.odeF[0];
(&Position_Tilt_M)->ModelData.intgData.f[1] = (&Position_Tilt_M)
->ModelData.odeF[1];
(&Position_Tilt_M)->ModelData.contStates = ((X_Position_Tilt_T *)
&Position_Tilt_X);
rtsiSetSolverData(&(&Position_Tilt_M)->solverInfo, (void *)&(&Position_Tilt_M
)->ModelData.intgData);
rtsiSetSolverName(&(&Position_Tilt_M)->solverInfo,"ode2");
rtmSetTPtr((&Position_Tilt_M), &(&Position_Tilt_M)->Timing.tArray[0]);
(&Position_Tilt_M)->Timing.stepSize0 = 0.01;
/* block I/O */
(void) memset(((void *) &Position_Tilt_B), 0,
sizeof(B_Position_Tilt_T));
/* states (continuous) */
{
(void) memset((void *)&Position_Tilt_X, 0,
sizeof(X_Position_Tilt_T));
}
/* external inputs */
(void) memset((void *)&Position_Tilt_U, 0,
sizeof(ExtU_Position_Tilt_T));
/* external outputs */
(void) memset((void *)&Position_Tilt_Y, 0,
sizeof(ExtY_Position_Tilt_T));
/* InitializeConditions for Integrator: '<S2>/Filter' */
Position_Tilt_X.Filter_CSTATE = Position_Tilt_P.Filter_IC;
/* InitializeConditions for Integrator: '<S3>/Filter' */
Position_Tilt_X.Filter_CSTATE_b = Position_Tilt_P.Filter_IC_d;
}
/* Model initialize function */
void Mechanics_initialize(boolean_T firstTime)
{
(void)firstTime;
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T)); /* initialize real-time model */
(void) memset((char_T *)Mechanics_M,0,
sizeof(RT_MODEL_Mechanics));
{
/* Setup solver object */
rtsiSetSimTimeStepPtr(&Mechanics_M->solverInfo,
&Mechanics_M->Timing.simTimeStep);
rtsiSetTPtr(&Mechanics_M->solverInfo, &rtmGetTPtr(Mechanics_M));
rtsiSetStepSizePtr(&Mechanics_M->solverInfo, &Mechanics_M->Timing.stepSize0);
rtsiSetdXPtr(&Mechanics_M->solverInfo, &Mechanics_M->ModelData.derivs);
rtsiSetContStatesPtr(&Mechanics_M->solverInfo,
&Mechanics_M->ModelData.contStates);
rtsiSetNumContStatesPtr(&Mechanics_M->solverInfo,
&Mechanics_M->Sizes.numContStates);
rtsiSetErrorStatusPtr(&Mechanics_M->solverInfo, (&rtmGetErrorStatus
(Mechanics_M)));
rtsiSetRTModelPtr(&Mechanics_M->solverInfo, Mechanics_M);
}
rtsiSetSimTimeStep(&Mechanics_M->solverInfo, MAJOR_TIME_STEP);
Mechanics_M->ModelData.intgData.y = Mechanics_M->ModelData.odeY;
Mechanics_M->ModelData.intgData.f[0] = Mechanics_M->ModelData.odeF[0];
Mechanics_M->ModelData.intgData.f[1] = Mechanics_M->ModelData.odeF[1];
Mechanics_M->ModelData.intgData.f[2] = Mechanics_M->ModelData.odeF[2];
Mechanics_M->ModelData.contStates = ((real_T *) &Mechanics_X);
rtsiSetSolverData(&Mechanics_M->solverInfo, (void *)
&Mechanics_M->ModelData.intgData);
rtsiSetSolverName(&Mechanics_M->solverInfo,"ode3");
Mechanics_M->solverInfoPtr = (&Mechanics_M->solverInfo);
/* Initialize timing info */
{
int_T *mdlTsMap = Mechanics_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
mdlTsMap[1] = 1;
Mechanics_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
Mechanics_M->Timing.sampleTimes = (&Mechanics_M->Timing.sampleTimesArray[0]);
Mechanics_M->Timing.offsetTimes = (&Mechanics_M->Timing.offsetTimesArray[0]);
/* task periods */
Mechanics_M->Timing.sampleTimes[0] = (0.0);
Mechanics_M->Timing.sampleTimes[1] = (35.0);
/* task offsets */
Mechanics_M->Timing.offsetTimes[0] = (0.0);
Mechanics_M->Timing.offsetTimes[1] = (0.0);
}
rtmSetTPtr(Mechanics_M, &Mechanics_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = Mechanics_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
mdlSampleHits[1] = 1;
Mechanics_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(Mechanics_M, -1);
Mechanics_M->Timing.stepSize0 = 35.0;
Mechanics_M->Timing.stepSize1 = 35.0;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
Mechanics_M->rtwLogInfo = &rt_DataLoggingInfo;
rtliSetLogFormat(Mechanics_M->rtwLogInfo, 0);
rtliSetLogMaxRows(Mechanics_M->rtwLogInfo, 1000);
rtliSetLogDecimation(Mechanics_M->rtwLogInfo, 1);
rtliSetLogVarNameModifier(Mechanics_M->rtwLogInfo, "rt_");
rtliSetLogT(Mechanics_M->rtwLogInfo, "tout");
rtliSetLogX(Mechanics_M->rtwLogInfo, "");
rtliSetLogXFinal(Mechanics_M->rtwLogInfo, "");
rtliSetSigLog(Mechanics_M->rtwLogInfo, "");
rtliSetLogXSignalInfo(Mechanics_M->rtwLogInfo, NULL);
rtliSetLogXSignalPtrs(Mechanics_M->rtwLogInfo, NULL);
rtliSetLogY(Mechanics_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(Mechanics_M->rtwLogInfo, NULL);
rtliSetLogYSignalPtrs(Mechanics_M->rtwLogInfo, NULL);
}
Mechanics_M->solverInfoPtr = (&Mechanics_M->solverInfo);
Mechanics_M->Timing.stepSize = (35.0);
rtsiSetFixedStepSize(&Mechanics_M->solverInfo, 35.0);
rtsiSetSolverMode(&Mechanics_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
Mechanics_M->ModelData.blockIO = ((void *) &Mechanics_B);
{
int_T i;
void *pVoidBlockIORegion;
pVoidBlockIORegion = (void *)(&Mechanics_B.Arduino);
for (i = 0; i < 18; i++) {
((real_T*)pVoidBlockIORegion)[i] = 0.0;
}
}
/* parameters */
Mechanics_M->ModelData.defaultParam = ((real_T *) &Mechanics_P);
/* states (continuous) */
{
real_T *x = (real_T *) &Mechanics_X;
Mechanics_M->ModelData.contStates = (x);
(void) memset((char_T *)x,0,
sizeof(ContinuousStates_Mechanics));
}
/* states (dwork) */
Mechanics_M->Work.dwork = ((void *) &Mechanics_DWork);
(void) memset((char_T *) &Mechanics_DWork,0,
sizeof(D_Work_Mechanics));
/* child S-Function registration */
{
RTWSfcnInfo *sfcnInfo = &Mechanics_M->NonInlinedSFcns.sfcnInfo;
Mechanics_M->sfcnInfo = (sfcnInfo);
rtssSetErrorStatusPtr(sfcnInfo, (&rtmGetErrorStatus(Mechanics_M)));
rtssSetNumRootSampTimesPtr(sfcnInfo, &Mechanics_M->Sizes.numSampTimes);
rtssSetTPtrPtr(sfcnInfo, &rtmGetTPtr(Mechanics_M));
rtssSetTStartPtr(sfcnInfo, &rtmGetTStart(Mechanics_M));
rtssSetTFinalPtr(sfcnInfo, &rtmGetTFinal(Mechanics_M));
rtssSetTimeOfLastOutputPtr(sfcnInfo, &rtmGetTimeOfLastOutput(Mechanics_M));
rtssSetStepSizePtr(sfcnInfo, &Mechanics_M->Timing.stepSize);
rtssSetStopRequestedPtr(sfcnInfo, &rtmGetStopRequested(Mechanics_M));
rtssSetDerivCacheNeedsResetPtr(sfcnInfo,
&Mechanics_M->ModelData.derivCacheNeedsReset);
rtssSetZCCacheNeedsResetPtr(sfcnInfo,
&Mechanics_M->ModelData.zCCacheNeedsReset);
rtssSetBlkStateChangePtr(sfcnInfo, &Mechanics_M->ModelData.blkStateChange);
rtssSetSampleHitsPtr(sfcnInfo, &Mechanics_M->Timing.sampleHits);
rtssSetPerTaskSampleHitsPtr(sfcnInfo, &Mechanics_M->Timing.perTaskSampleHits);
rtssSetSimModePtr(sfcnInfo, &Mechanics_M->simMode);
rtssSetSolverInfoPtr(sfcnInfo, &Mechanics_M->solverInfoPtr);
}
Mechanics_M->Sizes.numSFcns = (1);
/* register each child */
{
(void) memset((void *)&Mechanics_M->NonInlinedSFcns.childSFunctions[0],0,
1*sizeof(SimStruct));
Mechanics_M->childSfunctions =
(&Mechanics_M->NonInlinedSFcns.childSFunctionPtrs[0]);
Mechanics_M->childSfunctions[0] =
(&Mechanics_M->NonInlinedSFcns.childSFunctions[0]);
/* Level2 S-Function Block: Mechanics/<Root>/Arduino (QueryInstrument) */
{
SimStruct *rts = Mechanics_M->childSfunctions[0];
/* timing info */
time_T *sfcnPeriod = Mechanics_M->NonInlinedSFcns.Sfcn0.sfcnPeriod;
time_T *sfcnOffset = Mechanics_M->NonInlinedSFcns.Sfcn0.sfcnOffset;
int_T *sfcnTsMap = Mechanics_M->NonInlinedSFcns.Sfcn0.sfcnTsMap;
(void) memset((void*)sfcnPeriod,0,
sizeof(time_T)*1);
(void) memset((void*)sfcnOffset,0,
sizeof(time_T)*1);
ssSetSampleTimePtr(rts, &sfcnPeriod[0]);
ssSetOffsetTimePtr(rts, &sfcnOffset[0]);
ssSetSampleTimeTaskIDPtr(rts, sfcnTsMap);
/* Set up the mdlInfo pointer */
{
ssSetBlkInfo2Ptr(rts, &Mechanics_M->NonInlinedSFcns.blkInfo2[0]);
ssSetRTWSfcnInfo(rts, Mechanics_M->sfcnInfo);
}
/* Allocate memory of model methods 2 */
{
ssSetModelMethods2(rts, &Mechanics_M->NonInlinedSFcns.methods2[0]);
}
/* outputs */
{
ssSetPortInfoForOutputs(rts,
&Mechanics_M->NonInlinedSFcns.Sfcn0.outputPortInfo[0]);
_ssSetNumOutputPorts(rts, 1);
/* port 0 */
{
_ssSetOutputPortNumDimensions(rts, 0, 1);
ssSetOutputPortWidth(rts, 0, 1);
ssSetOutputPortSignal(rts, 0, ((real_T *) &Mechanics_B.Arduino));
}
}
/* path info */
ssSetModelName(rts, "Arduino");
ssSetPath(rts, "Mechanics/Arduino");
ssSetRTModel(rts,Mechanics_M);
ssSetParentSS(rts, NULL);
ssSetRootSS(rts, rts);
ssSetVersion(rts, SIMSTRUCT_VERSION_LEVEL2);
/* parameters */
{
mxArray **sfcnParams = (mxArray **)
&Mechanics_M->NonInlinedSFcns.Sfcn0.params;
ssSetSFcnParamsCount(rts, 39);
ssSetSFcnParamsPtr(rts, &sfcnParams[0]);
ssSetSFcnParam(rts, 0, (mxArray*)&Mechanics_P.Arduino_P1_Size[0]);
ssSetSFcnParam(rts, 1, (mxArray*)&Mechanics_P.Arduino_P2_Size[0]);
ssSetSFcnParam(rts, 2, (mxArray*)&Mechanics_P.Arduino_P3_Size[0]);
ssSetSFcnParam(rts, 3, (mxArray*)&Mechanics_P.Arduino_P4_Size[0]);
ssSetSFcnParam(rts, 4, (mxArray*)&Mechanics_P.Arduino_P5_Size[0]);
ssSetSFcnParam(rts, 5, (mxArray*)&Mechanics_P.Arduino_P6_Size[0]);
ssSetSFcnParam(rts, 6, (mxArray*)&Mechanics_P.Arduino_P7_Size[0]);
ssSetSFcnParam(rts, 7, (mxArray*)&Mechanics_P.Arduino_P8_Size[0]);
ssSetSFcnParam(rts, 8, (mxArray*)&Mechanics_P.Arduino_P9_Size[0]);
ssSetSFcnParam(rts, 9, (mxArray*)&Mechanics_P.Arduino_P10_Size[0]);
ssSetSFcnParam(rts, 10, (mxArray*)&Mechanics_P.Arduino_P11_Size[0]);
ssSetSFcnParam(rts, 11, (mxArray*)&Mechanics_P.Arduino_P12_Size[0]);
ssSetSFcnParam(rts, 12, (mxArray*)&Mechanics_P.Arduino_P13_Size[0]);
ssSetSFcnParam(rts, 13, (mxArray*)&Mechanics_P.Arduino_P14_Size[0]);
ssSetSFcnParam(rts, 14, (mxArray*)&Mechanics_P.Arduino_P15_Size[0]);
ssSetSFcnParam(rts, 15, (mxArray*)&Mechanics_P.Arduino_P16_Size[0]);
ssSetSFcnParam(rts, 16, (mxArray*)&Mechanics_P.Arduino_P17_Size[0]);
ssSetSFcnParam(rts, 17, (mxArray*)&Mechanics_P.Arduino_P18_Size[0]);
ssSetSFcnParam(rts, 18, (mxArray*)&Mechanics_P.Arduino_P19_Size[0]);
ssSetSFcnParam(rts, 19, (mxArray*)&Mechanics_P.Arduino_P20_Size[0]);
ssSetSFcnParam(rts, 20, (mxArray*)&Mechanics_P.Arduino_P21_Size[0]);
ssSetSFcnParam(rts, 21, (mxArray*)&Mechanics_P.Arduino_P22_Size[0]);
ssSetSFcnParam(rts, 22, (mxArray*)&Mechanics_P.Arduino_P23_Size[0]);
ssSetSFcnParam(rts, 23, (mxArray*)&Mechanics_P.Arduino_P24_Size[0]);
ssSetSFcnParam(rts, 24, (mxArray*)&Mechanics_P.Arduino_P25_Size[0]);
ssSetSFcnParam(rts, 25, (mxArray*)&Mechanics_P.Arduino_P26_Size[0]);
ssSetSFcnParam(rts, 26, (mxArray*)&Mechanics_P.Arduino_P27_Size[0]);
ssSetSFcnParam(rts, 27, (mxArray*)&Mechanics_P.Arduino_P28_Size[0]);
ssSetSFcnParam(rts, 28, (mxArray*)&Mechanics_P.Arduino_P29_Size[0]);
ssSetSFcnParam(rts, 29, (mxArray*)&Mechanics_P.Arduino_P30_Size[0]);
ssSetSFcnParam(rts, 30, (mxArray*)&Mechanics_P.Arduino_P31_Size[0]);
ssSetSFcnParam(rts, 31, (mxArray*)&Mechanics_P.Arduino_P32_Size[0]);
ssSetSFcnParam(rts, 32, (mxArray*)&Mechanics_P.Arduino_P33_Size[0]);
ssSetSFcnParam(rts, 33, (mxArray*)&Mechanics_P.Arduino_P34_Size[0]);
ssSetSFcnParam(rts, 34, (mxArray*)&Mechanics_P.Arduino_P35_Size[0]);
ssSetSFcnParam(rts, 35, (mxArray*)&Mechanics_P.Arduino_P36_Size[0]);
ssSetSFcnParam(rts, 36, (mxArray*)&Mechanics_P.Arduino_P37_Size[0]);
ssSetSFcnParam(rts, 37, (mxArray*)&Mechanics_P.Arduino_P38_Size[0]);
ssSetSFcnParam(rts, 38, (mxArray*)&Mechanics_P.Arduino_P39_Size[0]);
}
/* work vectors */
ssSetPWork(rts, (void **) &Mechanics_DWork.Arduino_PWORK);
{
struct _ssDWorkRecord *dWorkRecord = (struct _ssDWorkRecord *)
&Mechanics_M->NonInlinedSFcns.Sfcn0.dWork;
ssSetSFcnDWork(rts, dWorkRecord);
_ssSetNumDWork(rts, 1);
/* PWORK */
ssSetDWorkWidth(rts, 0, 1);
ssSetDWorkDataType(rts, 0,SS_POINTER);
ssSetDWorkComplexSignal(rts, 0, 0);
ssSetDWork(rts, 0, &Mechanics_DWork.Arduino_PWORK);
}
/* registration */
QueryInstrument(rts);
sfcnInitializeSizes(rts);
sfcnInitializeSampleTimes(rts);
/* adjust sample time */
ssSetSampleTime(rts, 0, 35.0);
ssSetOffsetTime(rts, 0, 0.0);
sfcnTsMap[0] = 1;
/* set compiled values of dynamic vector attributes */
ssSetNumNonsampledZCs(rts, 0);
/* Update connectivity flags for each port */
_ssSetOutputPortConnected(rts, 0, 1);
_ssSetOutputPortBeingMerged(rts, 0, 0);
/* Update the BufferDstPort flags for each input port */
}
}
}
/* Model initialize function */
void m1006_initialize(boolean_T firstTime)
{
if (firstTime) {
/* registration code */
/* initialize real-time model */
(void)memset((char_T *)m1006_M, 0, sizeof(rtModel_m1006));
{
/* Setup solver object */
rtsiSetSimTimeStepPtr(&m1006_M->solverInfo, &m1006_M->Timing.simTimeStep);
rtsiSetTPtr(&m1006_M->solverInfo, &rtmGetTPtr(m1006_M));
rtsiSetStepSizePtr(&m1006_M->solverInfo, &m1006_M->Timing.stepSize0);
rtsiSetdXPtr(&m1006_M->solverInfo, &m1006_M->ModelData.derivs);
rtsiSetContStatesPtr(&m1006_M->solverInfo, &m1006_M->ModelData.contStates);
rtsiSetNumContStatesPtr(&m1006_M->solverInfo,
&m1006_M->Sizes.numContStates);
rtsiSetErrorStatusPtr(&m1006_M->solverInfo, &rtmGetErrorStatus(m1006_M));
rtsiSetRTModelPtr(&m1006_M->solverInfo, m1006_M);
}
rtsiSetSimTimeStep(&m1006_M->solverInfo, MAJOR_TIME_STEP);
m1006_M->ModelData.intgData.y = m1006_M->ModelData.odeY;
m1006_M->ModelData.intgData.f[0] = m1006_M->ModelData.odeF[0];
m1006_M->ModelData.intgData.f[1] = m1006_M->ModelData.odeF[1];
m1006_M->ModelData.intgData.f[2] = m1006_M->ModelData.odeF[2];
m1006_M->ModelData.intgData.f[3] = m1006_M->ModelData.odeF[3];
m1006_M->ModelData.contStates = ((real_T *) &m1006_X);
rtsiSetSolverData(&m1006_M->solverInfo, (void
*)&m1006_M->ModelData.intgData);
rtsiSetSolverName(&m1006_M->solverInfo,"ode4");
/* Initialize timing info */
{
int_T *mdlTsMap = m1006_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
mdlTsMap[1] = 1;
m1006_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
m1006_M->Timing.sampleTimes = (&m1006_M->Timing.sampleTimesArray[0]);
m1006_M->Timing.offsetTimes = (&m1006_M->Timing.offsetTimesArray[0]);
/* task periods */
m1006_M->Timing.sampleTimes[0] = (0.0);
m1006_M->Timing.sampleTimes[1] = (0.1);
/* task offsets */
m1006_M->Timing.offsetTimes[0] = (0.0);
m1006_M->Timing.offsetTimes[1] = (0.0);
}
rtmSetTPtr(m1006_M, &m1006_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = m1006_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
mdlSampleHits[1] = 1;
m1006_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(m1006_M, 10.0);
m1006_M->Timing.stepSize0 = 0.1;
m1006_M->Timing.stepSize1 = 0.1;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
m1006_M->rtwLogInfo = &rt_DataLoggingInfo;
rtliSetLogFormat(m1006_M->rtwLogInfo, 0);
rtliSetLogMaxRows(m1006_M->rtwLogInfo, 1000);
rtliSetLogDecimation(m1006_M->rtwLogInfo, 1);
rtliSetLogVarNameModifier(m1006_M->rtwLogInfo, "rt_");
rtliSetLogT(m1006_M->rtwLogInfo, "tout");
rtliSetLogX(m1006_M->rtwLogInfo, "");
rtliSetLogXFinal(m1006_M->rtwLogInfo, "");
rtliSetSigLog(m1006_M->rtwLogInfo, "");
rtliSetLogXSignalInfo(m1006_M->rtwLogInfo, NULL);
rtliSetLogXSignalPtrs(m1006_M->rtwLogInfo, NULL);
rtliSetLogY(m1006_M->rtwLogInfo, "yout");
/*
* Set pointers to the data and signal info for each output
*/
{
static void * rt_LoggedOutputSignalPtrs[] = {
&m1006_Y.Out1
};
rtliSetLogYSignalPtrs(m1006_M->rtwLogInfo,
((LogSignalPtrsType)rt_LoggedOutputSignalPtrs));
}
{
static int_T rt_LoggedOutputWidths[] = {
1
};
static int_T rt_LoggedOutputNumDimensions[] = {
1
};
static int_T rt_LoggedOutputDimensions[] = {
1
};
static BuiltInDTypeId rt_LoggedOutputDataTypeIds[] = {
SS_DOUBLE
};
static int_T rt_LoggedOutputComplexSignals[] = {
0
};
static const char_T *rt_LoggedOutputLabels[] = {
""};
static const char_T *rt_LoggedOutputBlockNames[] = {
"m1006/Out1"};
static RTWLogDataTypeConvert rt_RTWLogDataTypeConvert[] = {
{ 0, SS_DOUBLE, SS_DOUBLE, 1.0, 0, 0.0}
};
static RTWLogSignalInfo rt_LoggedOutputSignalInfo[] = {
{
1,
rt_LoggedOutputWidths,
rt_LoggedOutputNumDimensions,
rt_LoggedOutputDimensions,
rt_LoggedOutputDataTypeIds,
rt_LoggedOutputComplexSignals,
NULL,
rt_LoggedOutputLabels,
NULL,
NULL,
NULL,
rt_LoggedOutputBlockNames,
NULL,
rt_RTWLogDataTypeConvert
}
};
rtliSetLogYSignalInfo(m1006_M->rtwLogInfo, rt_LoggedOutputSignalInfo);
}
}
m1006_M->solverInfoPtr = (&m1006_M->solverInfo);
m1006_M->Timing.stepSize = (0.1);
rtsiSetFixedStepSize(&m1006_M->solverInfo, 0.1);
rtsiSetSolverMode(&m1006_M->solverInfo, SOLVER_MODE_SINGLETASKING);
{
/* block I/O */
void *b = (void *) &m1006_B;
m1006_M->ModelData.blockIO = (b);
{
int_T i;
b =&m1006_B.SineWave;
for (i = 0; i < 2; i++) {
((real_T*)b)[i] = 0.0;
}
}
}
/* parameters */
m1006_M->ModelData.defaultParam = ((real_T *) &m1006_P);
/* states */
{
real_T *x = (real_T *) &m1006_X;
m1006_M->ModelData.contStates = (x);
(void)memset((char_T *)x, 0, sizeof(ContinuousStates_m1006));
}
/* external outputs */
m1006_M->ModelData.outputs = (&m1006_Y);
m1006_Y.Out1 = 0.0;
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
}
}
/* Model initialize function */
void AttitudeModelClass::initialize()
{
/* Registration code */
/* initialize real-time model */
(void) memset((void *)(&Attitude_M), 0,
sizeof(RT_MODEL_Attitude_T));
{
/* Setup solver object */
rtsiSetSimTimeStepPtr(&(&Attitude_M)->solverInfo, &(&Attitude_M)
->Timing.simTimeStep);
rtsiSetTPtr(&(&Attitude_M)->solverInfo, &rtmGetTPtr((&Attitude_M)));
rtsiSetStepSizePtr(&(&Attitude_M)->solverInfo, &(&Attitude_M)
->Timing.stepSize0);
rtsiSetdXPtr(&(&Attitude_M)->solverInfo, &(&Attitude_M)->ModelData.derivs);
rtsiSetContStatesPtr(&(&Attitude_M)->solverInfo, (real_T **) &(&Attitude_M
)->ModelData.contStates);
rtsiSetNumContStatesPtr(&(&Attitude_M)->solverInfo, &(&Attitude_M)
->Sizes.numContStates);
rtsiSetNumPeriodicContStatesPtr(&(&Attitude_M)->solverInfo, &(&Attitude_M)
->Sizes.numPeriodicContStates);
rtsiSetPeriodicContStateIndicesPtr(&(&Attitude_M)->solverInfo, &(&Attitude_M)
->ModelData.periodicContStateIndices);
rtsiSetPeriodicContStateRangesPtr(&(&Attitude_M)->solverInfo, &(&Attitude_M
)->ModelData.periodicContStateRanges);
rtsiSetErrorStatusPtr(&(&Attitude_M)->solverInfo, (&rtmGetErrorStatus
((&Attitude_M))));
rtsiSetRTModelPtr(&(&Attitude_M)->solverInfo, (&Attitude_M));
}
rtsiSetSimTimeStep(&(&Attitude_M)->solverInfo, MAJOR_TIME_STEP);
(&Attitude_M)->ModelData.intgData.y = (&Attitude_M)->ModelData.odeY;
(&Attitude_M)->ModelData.intgData.f[0] = (&Attitude_M)->ModelData.odeF[0];
(&Attitude_M)->ModelData.intgData.f[1] = (&Attitude_M)->ModelData.odeF[1];
(&Attitude_M)->ModelData.contStates = ((X_Attitude_T *) &Attitude_X);
rtsiSetSolverData(&(&Attitude_M)->solverInfo, (void *)&(&Attitude_M)
->ModelData.intgData);
rtsiSetSolverName(&(&Attitude_M)->solverInfo,"ode2");
rtmSetTPtr((&Attitude_M), &(&Attitude_M)->Timing.tArray[0]);
(&Attitude_M)->Timing.stepSize0 = 0.01;
/* block I/O */
(void) memset(((void *) &Attitude_B), 0,
sizeof(B_Attitude_T));
/* states (continuous) */
{
(void) memset((void *)&Attitude_X, 0,
sizeof(X_Attitude_T));
}
/* external inputs */
(void) memset((void *)&Attitude_U, 0,
sizeof(ExtU_Attitude_T));
/* external outputs */
(void) memset(&Attitude_Y.Moments[0], 0,
3U*sizeof(real_T));
/* InitializeConditions for Integrator: '<S3>/Filter' */
Attitude_X.Filter_CSTATE = Attitude_P.Filter_IC;
/* InitializeConditions for Integrator: '<S2>/Filter' */
Attitude_X.Filter_CSTATE_m = Attitude_P.Filter_IC_f;
/* InitializeConditions for Integrator: '<S4>/Filter' */
Attitude_X.Filter_CSTATE_mi = Attitude_P.Filter_IC_e;
/* InitializeConditions for Integrator: '<S5>/Integrator' */
Attitude_X.Integrator_CSTATE = Attitude_P.Integrator_IC;
/* InitializeConditions for Integrator: '<S5>/Filter' */
Attitude_X.Filter_CSTATE_k = Attitude_P.Filter_IC_c;
/* InitializeConditions for Integrator: '<S6>/Integrator' */
Attitude_X.Integrator_CSTATE_f = Attitude_P.Integrator_IC_l;
/* InitializeConditions for Integrator: '<S6>/Filter' */
Attitude_X.Filter_CSTATE_e = Attitude_P.Filter_IC_fv;
/* InitializeConditions for Integrator: '<S7>/Integrator' */
Attitude_X.Integrator_CSTATE_h = Attitude_P.Integrator_IC_k;
/* InitializeConditions for Integrator: '<S7>/Filter' */
Attitude_X.Filter_CSTATE_g = Attitude_P.Filter_IC_a;
}