/* Model initialize function */
void model1_initialize(void)
{
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)model1_M, 0,
sizeof(RT_MODEL_model1_T));
rtmSetTFinal(model1_M, 2.0);
model1_M->Timing.stepSize0 = 5.0E-5;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
model1_M->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
rtliSetLogXSignalInfo(model1_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(model1_M->rtwLogInfo, (NULL));
rtliSetLogT(model1_M->rtwLogInfo, "tout");
rtliSetLogX(model1_M->rtwLogInfo, "");
rtliSetLogXFinal(model1_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(model1_M->rtwLogInfo, "rt_");
rtliSetLogFormat(model1_M->rtwLogInfo, 0);
rtliSetLogMaxRows(model1_M->rtwLogInfo, 1000);
rtliSetLogDecimation(model1_M->rtwLogInfo, 1);
rtliSetLogY(model1_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(model1_M->rtwLogInfo, (NULL));
rtliSetLogYSignalPtrs(model1_M->rtwLogInfo, (NULL));
}
/* states (dwork) */
(void) memset((void *)&model1_DW, 0,
sizeof(DW_model1_T));
/* Matfile logging */
rt_StartDataLoggingWithStartTime(model1_M->rtwLogInfo, 0.0, rtmGetTFinal
(model1_M), model1_M->Timing.stepSize0, (&rtmGetErrorStatus(model1_M)));
/* Enable for Sin: '<S11>/Sine Wave A' */
model1_DW.systemEnable = 1;
/* Enable for Sin: '<S11>/Sine Wave B' */
model1_DW.systemEnable_i = 1;
/* Enable for Sin: '<S11>/Sine Wave C' */
model1_DW.systemEnable_g = 1;
}
void rt_CleanUpForStateLogWithMMI(RTWLogInfo *li)
{
int_T i;
RTWLogSignalInfo *sigInfo = _rtliGetLogXSignalInfo(li); /* get the non-const ptr */
int_T nSignals = sigInfo->numSignals;
if ( nSignals > 0 ) {
for (i = 0; i < nSignals; ++i) utFree(sigInfo->blockNames.ptr[i]);
FREE(sigInfo->blockNames.ptr);
FREE(sigInfo->labels.ptr);
FREE(sigInfo->crossMdlRef);
FREE(sigInfo->dims);
FREE(sigInfo->dataTypes);
FREE(sigInfo->complexSignals);
FREE(sigInfo->isVarDims);
FREE(sigInfo);
rtliSetLogXSignalInfo(li, NULL);
FREE(_rtliGetLogXSignalPtrs(li)); /* get the non-const ptr */
rtliSetLogXSignalPtrs(li,NULL);
}
}
/* Model initialize function */
void Koordinatentransfer3_initialize(void)
{
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)Koordinatentransfer3_M, 0,
sizeof(RT_MODEL_Koordinatentransfer3_T));
rtmSetTFinal(Koordinatentransfer3_M, 0.1);
Koordinatentransfer3_M->Timing.stepSize0 = 0.02;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
Koordinatentransfer3_M->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
rtliSetLogXSignalInfo(Koordinatentransfer3_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(Koordinatentransfer3_M->rtwLogInfo, (NULL));
rtliSetLogT(Koordinatentransfer3_M->rtwLogInfo, "tout");
rtliSetLogX(Koordinatentransfer3_M->rtwLogInfo, "");
rtliSetLogXFinal(Koordinatentransfer3_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(Koordinatentransfer3_M->rtwLogInfo, "rt_");
rtliSetLogFormat(Koordinatentransfer3_M->rtwLogInfo, 0);
rtliSetLogMaxRows(Koordinatentransfer3_M->rtwLogInfo, 1000);
rtliSetLogDecimation(Koordinatentransfer3_M->rtwLogInfo, 1);
/*
* Set pointers to the data and signal info for each output
*/
{
static void * rt_LoggedOutputSignalPtrs[] = {
&Koordinatentransfer3_Y.a,
&Koordinatentransfer3_Y.b,
&Koordinatentransfer3_Y.c
};
rtliSetLogYSignalPtrs(Koordinatentransfer3_M->rtwLogInfo,
((LogSignalPtrsType)rt_LoggedOutputSignalPtrs));
}
{
static int_T rt_LoggedOutputWidths[] = {
1,
1,
1
};
static int_T rt_LoggedOutputNumDimensions[] = {
1,
1,
1
};
static int_T rt_LoggedOutputDimensions[] = {
1,
1,
1
};
static boolean_T rt_LoggedOutputIsVarDims[] = {
0,
0,
0
};
static void* rt_LoggedCurrentSignalDimensions[] = {
(NULL),
(NULL),
(NULL)
};
static int_T rt_LoggedCurrentSignalDimensionsSize[] = {
2,
2,
2
};
static BuiltInDTypeId rt_LoggedOutputDataTypeIds[] = {
SS_DOUBLE,
SS_DOUBLE,
SS_DOUBLE
};
static int_T rt_LoggedOutputComplexSignals[] = {
0,
0,
0
};
static const char_T *rt_LoggedOutputLabels[] = {
"",
"",
"" };
static const char_T *rt_LoggedOutputBlockNames[] = {
"Koordinatentransfer3/a",
"Koordinatentransfer3/b",
"Koordinatentransfer3/c" };
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 },
{ 0, SS_DOUBLE, SS_DOUBLE, 0, 0, 0, 1.0, 0, 0.0 }
};
static RTWLogSignalInfo rt_LoggedOutputSignalInfo[] = {
{
3,
rt_LoggedOutputWidths,
rt_LoggedOutputNumDimensions,
rt_LoggedOutputDimensions,
rt_LoggedOutputIsVarDims,
rt_LoggedCurrentSignalDimensions,
rt_LoggedCurrentSignalDimensionsSize,
rt_LoggedOutputDataTypeIds,
rt_LoggedOutputComplexSignals,
(NULL),
{ rt_LoggedOutputLabels },
(NULL),
(NULL),
(NULL),
{ rt_LoggedOutputBlockNames },
{ (NULL) },
(NULL),
rt_RTWLogDataTypeConvert
}
};
rtliSetLogYSignalInfo(Koordinatentransfer3_M->rtwLogInfo,
rt_LoggedOutputSignalInfo);
/* set currSigDims field */
rt_LoggedCurrentSignalDimensions[0] = &rt_LoggedOutputWidths[0];
rt_LoggedCurrentSignalDimensions[1] = &rt_LoggedOutputWidths[1];
rt_LoggedCurrentSignalDimensions[2] = &rt_LoggedOutputWidths[2];
}
rtliSetLogY(Koordinatentransfer3_M->rtwLogInfo, "yout");
}
/* external inputs */
(void) memset((void *)&Koordinatentransfer3_U, 0,
sizeof(ExtU_Koordinatentransfer3_T));
/* external outputs */
(void) memset((void *)&Koordinatentransfer3_Y, 0,
sizeof(ExtY_Koordinatentransfer3_T));
/* Matfile logging */
rt_StartDataLoggingWithStartTime(Koordinatentransfer3_M->rtwLogInfo, 0.0,
rtmGetTFinal(Koordinatentransfer3_M),
Koordinatentransfer3_M->Timing.stepSize0, (&rtmGetErrorStatus
(Koordinatentransfer3_M)));
}
/* Model initialize function */
void BP_MC1_initialize(boolean_T firstTime)
{
(void)firstTime;
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)BP_MC1_M,0,
sizeof(RT_MODEL_BP_MC1));
/* Initialize timing info */
{
int_T *mdlTsMap = BP_MC1_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
BP_MC1_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
BP_MC1_M->Timing.sampleTimes = (&BP_MC1_M->Timing.sampleTimesArray[0]);
BP_MC1_M->Timing.offsetTimes = (&BP_MC1_M->Timing.offsetTimesArray[0]);
/* task periods */
BP_MC1_M->Timing.sampleTimes[0] = (0.05);
/* task offsets */
BP_MC1_M->Timing.offsetTimes[0] = (0.0);
}
rtmSetTPtr(BP_MC1_M, &BP_MC1_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = BP_MC1_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
BP_MC1_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(BP_MC1_M, -1);
BP_MC1_M->Timing.stepSize0 = 0.05;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
BP_MC1_M->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
rtliSetLogXSignalInfo(BP_MC1_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(BP_MC1_M->rtwLogInfo, (NULL));
rtliSetLogT(BP_MC1_M->rtwLogInfo, "");
rtliSetLogX(BP_MC1_M->rtwLogInfo, "");
rtliSetLogXFinal(BP_MC1_M->rtwLogInfo, "");
rtliSetSigLog(BP_MC1_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(BP_MC1_M->rtwLogInfo, "rt_");
rtliSetLogFormat(BP_MC1_M->rtwLogInfo, 0);
rtliSetLogMaxRows(BP_MC1_M->rtwLogInfo, 1000);
rtliSetLogDecimation(BP_MC1_M->rtwLogInfo, 1);
rtliSetLogY(BP_MC1_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(BP_MC1_M->rtwLogInfo, (NULL));
rtliSetLogYSignalPtrs(BP_MC1_M->rtwLogInfo, (NULL));
}
BP_MC1_M->solverInfoPtr = (&BP_MC1_M->solverInfo);
BP_MC1_M->Timing.stepSize = (0.05);
rtsiSetFixedStepSize(&BP_MC1_M->solverInfo, 0.05);
rtsiSetSolverMode(&BP_MC1_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
BP_MC1_M->ModelData.blockIO = ((void *) &BP_MC1_B);
(void) memset(((void *) &BP_MC1_B),0,
sizeof(BlockIO_BP_MC1));
{
BP_MC1_B.u1 = 0.0;
BP_MC1_B.Sign = 0.0;
BP_MC1_B.PortVPS_X = 0.0;
BP_MC1_B.PortVPS_X_g = 0.0;
BP_MC1_B.u1_p = 0.0;
BP_MC1_B.PortVSP_Y = 0.0;
BP_MC1_B.PortVSP_Y_i = 0.0;
BP_MC1_B.u1_g = 0.0;
BP_MC1_B.StarboardVSP_X = 0.0;
BP_MC1_B.u1_pj = 0.0;
BP_MC1_B.StarboardVSP_Y = 0.0;
BP_MC1_B.Servo1 = 0.0;
BP_MC1_B.Servo2 = 0.0;
BP_MC1_B.Servo3 = 0.0;
BP_MC1_B.Servo4 = 0.0;
BP_MC1_B.VPS_Speed_Gain = 0.0;
BP_MC1_B.Sum = 0.0;
BP_MC1_B.BowThrusterdirection = 0.0;
BP_MC1_B.BT_D_Gain1 = 0.0;
BP_MC1_B.BT_D_Gain2 = 0.0;
BP_MC1_B.Add = 0.0;
BP_MC1_B.BT_L_Gain1 = 0.0;
BP_MC1_B.BT_L_Gain2 = 0.0;
BP_MC1_B.Sum1 = 0.0;
BP_MC1_B.Sum2 = 0.0;
BP_MC1_B.Switch = 0.0;
BP_MC1_B.Switch2 = 0.0;
}
/* parameters */
BP_MC1_M->ModelData.defaultParam = ((real_T *) &BP_MC1_P);
/* states (dwork) */
BP_MC1_M->Work.dwork = ((void *) &BP_MC1_DWork);
(void) memset((void *)&BP_MC1_DWork, 0,
sizeof(D_Work_BP_MC1));
}
/* Model initialize function */
void CelpSimulink_initialize(boolean_T firstTime)
{
(void)firstTime;
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((char_T *)CelpSimulink_M,0,
sizeof(RT_MODEL_CelpSimulink));
/* Initialize timing info */
{
int_T *mdlTsMap = CelpSimulink_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
CelpSimulink_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
CelpSimulink_M->Timing.sampleTimes =
(&CelpSimulink_M->Timing.sampleTimesArray[0]);
CelpSimulink_M->Timing.offsetTimes =
(&CelpSimulink_M->Timing.offsetTimesArray[0]);
/* task periods */
CelpSimulink_M->Timing.sampleTimes[0] = (0.01);
/* task offsets */
CelpSimulink_M->Timing.offsetTimes[0] = (0.0);
}
rtmSetTPtr(CelpSimulink_M, &CelpSimulink_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = CelpSimulink_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
CelpSimulink_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(CelpSimulink_M, -1);
CelpSimulink_M->Timing.stepSize0 = 0.01;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
CelpSimulink_M->rtwLogInfo = &rt_DataLoggingInfo;
rtliSetLogXSignalInfo(CelpSimulink_M->rtwLogInfo, NULL);
rtliSetLogXSignalPtrs(CelpSimulink_M->rtwLogInfo, NULL);
rtliSetLogT(CelpSimulink_M->rtwLogInfo, "tout");
rtliSetLogX(CelpSimulink_M->rtwLogInfo, "");
rtliSetLogXFinal(CelpSimulink_M->rtwLogInfo, "");
rtliSetSigLog(CelpSimulink_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(CelpSimulink_M->rtwLogInfo, "rt_");
rtliSetLogFormat(CelpSimulink_M->rtwLogInfo, 0);
rtliSetLogMaxRows(CelpSimulink_M->rtwLogInfo, 1000);
rtliSetLogDecimation(CelpSimulink_M->rtwLogInfo, 1);
rtliSetLogY(CelpSimulink_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(CelpSimulink_M->rtwLogInfo, NULL);
rtliSetLogYSignalPtrs(CelpSimulink_M->rtwLogInfo, NULL);
}
CelpSimulink_M->solverInfoPtr = (&CelpSimulink_M->solverInfo);
CelpSimulink_M->Timing.stepSize = (0.01);
rtsiSetFixedStepSize(&CelpSimulink_M->solverInfo, 0.01);
rtsiSetSolverMode(&CelpSimulink_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
CelpSimulink_M->ModelData.blockIO = ((void *) &CelpSimulink_B);
(void) memset(((void *) &CelpSimulink_B),0,
sizeof(BlockIO_CelpSimulink));
{
int_T i;
void *pVoidBlockIORegion;
pVoidBlockIORegion = (void *)(&CelpSimulink_B.FromWaveFile[0]);
for (i = 0; i < 411; i++) {
((real32_T*)pVoidBlockIORegion)[i] = 0.0F;
}
}
/* parameters */
CelpSimulink_M->ModelData.defaultParam = ((real_T *) &CelpSimulink_P);
/* states (dwork) */
CelpSimulink_M->Work.dwork = ((void *) &CelpSimulink_DWork);
(void) memset((char_T *) &CelpSimulink_DWork,0,
sizeof(D_Work_CelpSimulink));
CelpSimulink_DWork.Maximum1_Valdata = 0.0;
{
int_T i;
real32_T *dwork_ptr = (real32_T *)
&CelpSimulink_DWork.PreEmphasis_FILT_STATES[0];
for (i = 0; i < 1122; i++) {
dwork_ptr[i] = 0.0F;
}
}
}
/* Registration function */
RT_MODEL_sfcndemo_sfunmem_T *sfcndemo_sfunmem(void)
{
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)sfcndemo_sfunmem_M, 0,
sizeof(RT_MODEL_sfcndemo_sfunmem_T));
/* Initialize timing info */
{
int_T *mdlTsMap = sfcndemo_sfunmem_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
sfcndemo_sfunmem_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
sfcndemo_sfunmem_M->Timing.sampleTimes =
(&sfcndemo_sfunmem_M->Timing.sampleTimesArray[0]);
sfcndemo_sfunmem_M->Timing.offsetTimes =
(&sfcndemo_sfunmem_M->Timing.offsetTimesArray[0]);
/* task periods */
sfcndemo_sfunmem_M->Timing.sampleTimes[0] = (0.01);
/* task offsets */
sfcndemo_sfunmem_M->Timing.offsetTimes[0] = (0.0);
}
rtmSetTPtr(sfcndemo_sfunmem_M, &sfcndemo_sfunmem_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = sfcndemo_sfunmem_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
sfcndemo_sfunmem_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(sfcndemo_sfunmem_M, 0.5);
sfcndemo_sfunmem_M->Timing.stepSize0 = 0.01;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
sfcndemo_sfunmem_M->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
rtliSetLogXSignalInfo(sfcndemo_sfunmem_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(sfcndemo_sfunmem_M->rtwLogInfo, (NULL));
rtliSetLogT(sfcndemo_sfunmem_M->rtwLogInfo, "tout");
rtliSetLogX(sfcndemo_sfunmem_M->rtwLogInfo, "");
rtliSetLogXFinal(sfcndemo_sfunmem_M->rtwLogInfo, "");
rtliSetSigLog(sfcndemo_sfunmem_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(sfcndemo_sfunmem_M->rtwLogInfo, "rt_");
rtliSetLogFormat(sfcndemo_sfunmem_M->rtwLogInfo, 0);
rtliSetLogMaxRows(sfcndemo_sfunmem_M->rtwLogInfo, 0);
rtliSetLogDecimation(sfcndemo_sfunmem_M->rtwLogInfo, 1);
/*
* Set pointers to the data and signal info for each output
*/
{
static void * rt_LoggedOutputSignalPtrs[] = {
&sfcndemo_sfunmem_Y.Out1,
&sfcndemo_sfunmem_Y.Out2[0]
};
rtliSetLogYSignalPtrs(sfcndemo_sfunmem_M->rtwLogInfo, ((LogSignalPtrsType)
rt_LoggedOutputSignalPtrs));
}
{
static int_T rt_LoggedOutputWidths[] = {
1,
2
};
static int_T rt_LoggedOutputNumDimensions[] = {
1,
1
};
static int_T rt_LoggedOutputDimensions[] = {
1,
2
};
static boolean_T rt_LoggedOutputIsVarDims[] = {
0,
0
};
static void* rt_LoggedCurrentSignalDimensions[] = {
(NULL),
(NULL)
};
static int_T rt_LoggedCurrentSignalDimensionsSize[] = {
4,
4
};
static BuiltInDTypeId rt_LoggedOutputDataTypeIds[] = {
SS_DOUBLE,
SS_DOUBLE
};
static int_T rt_LoggedOutputComplexSignals[] = {
0,
0
};
static const char_T *rt_LoggedOutputLabels[] = {
"",
"" };
static const char_T *rt_LoggedOutputBlockNames[] = {
"sfcndemo_sfunmem/Out1",
"sfcndemo_sfunmem/Out2" };
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_LoggedOutputSignalInfo[] = {
{
2,
rt_LoggedOutputWidths,
rt_LoggedOutputNumDimensions,
rt_LoggedOutputDimensions,
rt_LoggedOutputIsVarDims,
rt_LoggedCurrentSignalDimensions,
rt_LoggedCurrentSignalDimensionsSize,
rt_LoggedOutputDataTypeIds,
rt_LoggedOutputComplexSignals,
(NULL),
{ rt_LoggedOutputLabels },
(NULL),
(NULL),
(NULL),
{ rt_LoggedOutputBlockNames },
{ (NULL) },
(NULL),
rt_RTWLogDataTypeConvert
}
};
rtliSetLogYSignalInfo(sfcndemo_sfunmem_M->rtwLogInfo,
rt_LoggedOutputSignalInfo);
/* set currSigDims field */
rt_LoggedCurrentSignalDimensions[0] = &rt_LoggedOutputWidths[0];
rt_LoggedCurrentSignalDimensions[1] = &rt_LoggedOutputWidths[1];
}
rtliSetLogY(sfcndemo_sfunmem_M->rtwLogInfo, "yout");
}
sfcndemo_sfunmem_M->solverInfoPtr = (&sfcndemo_sfunmem_M->solverInfo);
sfcndemo_sfunmem_M->Timing.stepSize = (0.01);
rtsiSetFixedStepSize(&sfcndemo_sfunmem_M->solverInfo, 0.01);
rtsiSetSolverMode(&sfcndemo_sfunmem_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
sfcndemo_sfunmem_M->ModelData.blockIO = ((void *) &sfcndemo_sfunmem_B);
{
sfcndemo_sfunmem_B.DiscretePulseGenerator = 0.0;
sfcndemo_sfunmem_B.Sum = 0.0;
}
/* parameters */
sfcndemo_sfunmem_M->ModelData.defaultParam = ((real_T *)&sfcndemo_sfunmem_P);
/* states (dwork) */
sfcndemo_sfunmem_M->ModelData.dwork = ((void *) &sfcndemo_sfunmem_DW);
(void) memset((void *)&sfcndemo_sfunmem_DW, 0,
sizeof(DW_sfcndemo_sfunmem_T));
sfcndemo_sfunmem_DW.SFunction1_RWORK.InputAtLastUpdate = 0.0;
sfcndemo_sfunmem_DW.SFunction2_RWORK.InputAtLastUpdate[0] = 0.0;
sfcndemo_sfunmem_DW.SFunction2_RWORK.InputAtLastUpdate[1] = 0.0;
/* external outputs */
sfcndemo_sfunmem_M->ModelData.outputs = (&sfcndemo_sfunmem_Y);
sfcndemo_sfunmem_Y.Out1 = 0.0;
sfcndemo_sfunmem_Y.Out2[0] = 0.0;
sfcndemo_sfunmem_Y.Out2[1] = 0.0;
/* Initialize Sizes */
sfcndemo_sfunmem_M->Sizes.numContStates = (0);/* Number of continuous states */
sfcndemo_sfunmem_M->Sizes.numY = (3);/* Number of model outputs */
sfcndemo_sfunmem_M->Sizes.numU = (0);/* Number of model inputs */
sfcndemo_sfunmem_M->Sizes.sysDirFeedThru = (0);/* The model is not direct feedthrough */
sfcndemo_sfunmem_M->Sizes.numSampTimes = (1);/* Number of sample times */
sfcndemo_sfunmem_M->Sizes.numBlocks = (7);/* Number of blocks */
sfcndemo_sfunmem_M->Sizes.numBlockIO = (4);/* Number of block outputs */
sfcndemo_sfunmem_M->Sizes.numBlockPrms = (4);/* Sum of parameter "widths" */
return sfcndemo_sfunmem_M;
}
/* 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 fi_mdl_radix2fft_withscaling_initialize(boolean_T firstTime)
{
if (firstTime) {
/* registration code */
/* initialize real-time model */
(void)memset((char_T *)fi_mdl_radix2fft_withscaling_M, 0,
sizeof(rtModel_fi_mdl_radix2fft_withscaling));
/* Initialize timing info */
{
int_T *mdlTsMap =
fi_mdl_radix2fft_withscaling_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
fi_mdl_radix2fft_withscaling_M->Timing.sampleTimeTaskIDPtr =
(&mdlTsMap[0]);
fi_mdl_radix2fft_withscaling_M->Timing.sampleTimes =
(&fi_mdl_radix2fft_withscaling_M->Timing.sampleTimesArray[0]);
fi_mdl_radix2fft_withscaling_M->Timing.offsetTimes =
(&fi_mdl_radix2fft_withscaling_M->Timing.offsetTimesArray[0]);
/* task periods */
fi_mdl_radix2fft_withscaling_M->Timing.sampleTimes[0] = (0.25);
/* task offsets */
fi_mdl_radix2fft_withscaling_M->Timing.offsetTimes[0] = (0.0);
}
rtmSetTPtr(fi_mdl_radix2fft_withscaling_M,
&fi_mdl_radix2fft_withscaling_M->Timing.tArray[0]);
{
int_T *mdlSampleHits =
fi_mdl_radix2fft_withscaling_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
fi_mdl_radix2fft_withscaling_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(fi_mdl_radix2fft_withscaling_M, 0.0);
fi_mdl_radix2fft_withscaling_M->Timing.stepSize0 = 0.25;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
fi_mdl_radix2fft_withscaling_M->rtwLogInfo = &rt_DataLoggingInfo;
rtliSetLogFormat(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, 0);
rtliSetLogMaxRows(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, 1000);
rtliSetLogDecimation(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, 1);
rtliSetLogVarNameModifier(fi_mdl_radix2fft_withscaling_M->rtwLogInfo,
"rt_");
rtliSetLogT(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, "tout");
rtliSetLogX(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, "");
rtliSetLogXFinal(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, "");
rtliSetSigLog(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, "");
rtliSetLogXSignalInfo(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, NULL);
rtliSetLogXSignalPtrs(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, NULL);
rtliSetLogY(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, NULL);
rtliSetLogYSignalPtrs(fi_mdl_radix2fft_withscaling_M->rtwLogInfo, NULL);
}
fi_mdl_radix2fft_withscaling_M->solverInfoPtr =
(&fi_mdl_radix2fft_withscaling_M->solverInfo);
fi_mdl_radix2fft_withscaling_M->Timing.stepSize = (0.25);
rtsiSetFixedStepSize(&fi_mdl_radix2fft_withscaling_M->solverInfo, 0.25);
rtsiSetSolverMode(&fi_mdl_radix2fft_withscaling_M->solverInfo,
SOLVER_MODE_SINGLETASKING);
/* parameters */
fi_mdl_radix2fft_withscaling_M->ModelData.defaultParam = ((real_T *)
&fi_mdl_radix2fft_withscaling_P);
/* data type work */
fi_mdl_radix2fft_withscaling_M->Work.dwork = ((void *)
&fi_mdl_radix2fft_withscaling_DWork);
(void)memset((char_T *) &fi_mdl_radix2fft_withscaling_DWork, 0,
sizeof(D_Work_fi_mdl_radix2fft_withscaling));
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
}
}
void trajectory_test_initialize(boolean_T firstTime)
{
if (firstTime) {
/* Registration code */
/* initialize real-time model */
(void) memset((char_T *)trajectory_test_M,0,
sizeof(RT_MODEL_trajectory_test));
/* Initialize timing info */
{
int_T *mdlTsMap = trajectory_test_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
trajectory_test_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
trajectory_test_M->Timing.sampleTimes =
(&trajectory_test_M->Timing.sampleTimesArray[0]);
trajectory_test_M->Timing.offsetTimes =
(&trajectory_test_M->Timing.offsetTimesArray[0]);
/* task periods */
trajectory_test_M->Timing.sampleTimes[0] = (0.01);
/* task offsets */
trajectory_test_M->Timing.offsetTimes[0] = (0.0);
}
rtmSetTPtr(trajectory_test_M, &trajectory_test_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = trajectory_test_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
trajectory_test_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(trajectory_test_M, 20.0);
trajectory_test_M->Timing.stepSize0 = 0.01;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
trajectory_test_M->rtwLogInfo = &rt_DataLoggingInfo;
rtliSetLogFormat(trajectory_test_M->rtwLogInfo, 0);
rtliSetLogMaxRows(trajectory_test_M->rtwLogInfo, 1000);
rtliSetLogDecimation(trajectory_test_M->rtwLogInfo, 1);
rtliSetLogVarNameModifier(trajectory_test_M->rtwLogInfo, "rt_");
rtliSetLogT(trajectory_test_M->rtwLogInfo, "tout");
rtliSetLogX(trajectory_test_M->rtwLogInfo, "");
rtliSetLogXFinal(trajectory_test_M->rtwLogInfo, "");
rtliSetSigLog(trajectory_test_M->rtwLogInfo, "");
rtliSetLogXSignalInfo(trajectory_test_M->rtwLogInfo, NULL);
rtliSetLogXSignalPtrs(trajectory_test_M->rtwLogInfo, NULL);
rtliSetLogY(trajectory_test_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(trajectory_test_M->rtwLogInfo, NULL);
rtliSetLogYSignalPtrs(trajectory_test_M->rtwLogInfo, NULL);
}
trajectory_test_M->solverInfoPtr = (&trajectory_test_M->solverInfo);
trajectory_test_M->Timing.stepSize = (0.01);
rtsiSetFixedStepSize(&trajectory_test_M->solverInfo, 0.01);
rtsiSetSolverMode(&trajectory_test_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
trajectory_test_M->ModelData.blockIO = ((void *) &trajectory_test_B);
{
int_T i;
void *pVoidBlockIORegion;
pVoidBlockIORegion = (void *)(&trajectory_test_B.sf_Trajectorydesign2.a0);
for (i = 0; i < 6; i++) {
((real_T*)pVoidBlockIORegion)[i] = 0.0;
}
pVoidBlockIORegion = (void *)(&trajectory_test_B.sf_Trajectorydesign1.a0);
for (i = 0; i < 6; i++) {
((real_T*)pVoidBlockIORegion)[i] = 0.0;
}
((real_T*)&trajectory_test_B.sf_Jointreferencesi_m.qa)[0] = 0.0;
((real_T*)&trajectory_test_B.sf_Jointreferencesing.qa)[0] = 0.0;
}
/* parameters */
trajectory_test_M->ModelData.defaultParam = ((real_T *) &trajectory_test_P);
/* states (dwork) */
trajectory_test_M->Work.dwork = ((void *) &trajectory_test_DWork);
(void) memset((char_T *) &trajectory_test_DWork,0,
sizeof(D_Work_trajectory_test));
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
}
}
/* Model initialize function */
void testSHM_initialize(boolean_T firstTime)
{
(void)firstTime;
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)testSHM_M,0,
sizeof(RT_MODEL_testSHM));
rtsiSetSolverName(&testSHM_M->solverInfo,"FixedStepDiscrete");
testSHM_M->solverInfoPtr = (&testSHM_M->solverInfo);
/* Initialize timing info */
{
int_T *mdlTsMap = testSHM_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
testSHM_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
testSHM_M->Timing.sampleTimes = (&testSHM_M->Timing.sampleTimesArray[0]);
testSHM_M->Timing.offsetTimes = (&testSHM_M->Timing.offsetTimesArray[0]);
/* task periods */
testSHM_M->Timing.sampleTimes[0] = (0.001);
/* task offsets */
testSHM_M->Timing.offsetTimes[0] = (0.0);
}
rtmSetTPtr(testSHM_M, &testSHM_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = testSHM_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
testSHM_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(testSHM_M, 10.0);
testSHM_M->Timing.stepSize0 = 0.001;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
testSHM_M->rtwLogInfo = &rt_DataLoggingInfo;
rtliSetLogXSignalInfo(testSHM_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(testSHM_M->rtwLogInfo, (NULL));
rtliSetLogT(testSHM_M->rtwLogInfo, "tout");
rtliSetLogX(testSHM_M->rtwLogInfo, "");
rtliSetLogXFinal(testSHM_M->rtwLogInfo, "");
rtliSetSigLog(testSHM_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(testSHM_M->rtwLogInfo, "rt_");
rtliSetLogFormat(testSHM_M->rtwLogInfo, 0);
rtliSetLogMaxRows(testSHM_M->rtwLogInfo, 1000);
rtliSetLogDecimation(testSHM_M->rtwLogInfo, 1);
rtliSetLogY(testSHM_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(testSHM_M->rtwLogInfo, (NULL));
rtliSetLogYSignalPtrs(testSHM_M->rtwLogInfo, (NULL));
}
testSHM_M->solverInfoPtr = (&testSHM_M->solverInfo);
testSHM_M->Timing.stepSize = (0.001);
rtsiSetFixedStepSize(&testSHM_M->solverInfo, 0.001);
rtsiSetSolverMode(&testSHM_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
testSHM_M->ModelData.blockIO = ((void *) &testSHM_B);
(void) memset(((void *) &testSHM_B),0,
sizeof(BlockIO_testSHM));
/* parameters */
testSHM_M->ModelData.defaultParam = ((real_T *) &testSHM_P);
/* states (dwork) */
testSHM_M->Work.dwork = ((void *) &testSHM_DWork);
(void) memset((void *)&testSHM_DWork, 0,
sizeof(D_Work_testSHM));
/* C API for Parameter Tuning and/or Signal Monitoring */
{
static ModelMappingInfo mapInfo;
(void) memset((char_T *) &mapInfo,0,
sizeof(mapInfo));
/* block signal monitoring map */
mapInfo.Signals.blockIOSignals = &rtBIOSignals[0];
mapInfo.Signals.numBlockIOSignals = 2;
/* parameter tuning maps */
mapInfo.Parameters.blockTuning = &rtBlockTuning[0];
mapInfo.Parameters.variableTuning = &rtVariableTuning[0];
mapInfo.Parameters.parametersMap = rtParametersMap;
mapInfo.Parameters.dimensionsMap = rtDimensionsMap;
mapInfo.Parameters.numBlockTuning = 4;
mapInfo.Parameters.numVariableTuning = 0;
testSHM_M->SpecialInfo.mappingInfo = (&mapInfo);
}
/* child S-Function registration */
{
RTWSfcnInfo *sfcnInfo = &testSHM_M->NonInlinedSFcns.sfcnInfo;
testSHM_M->sfcnInfo = (sfcnInfo);
rtssSetErrorStatusPtr(sfcnInfo, (&rtmGetErrorStatus(testSHM_M)));
rtssSetNumRootSampTimesPtr(sfcnInfo, &testSHM_M->Sizes.numSampTimes);
rtssSetTPtrPtr(sfcnInfo, &rtmGetTPtr(testSHM_M));
rtssSetTStartPtr(sfcnInfo, &rtmGetTStart(testSHM_M));
rtssSetTFinalPtr(sfcnInfo, &rtmGetTFinal(testSHM_M));
rtssSetTimeOfLastOutputPtr(sfcnInfo, &rtmGetTimeOfLastOutput(testSHM_M));
rtssSetStepSizePtr(sfcnInfo, &testSHM_M->Timing.stepSize);
rtssSetStopRequestedPtr(sfcnInfo, &rtmGetStopRequested(testSHM_M));
rtssSetDerivCacheNeedsResetPtr(sfcnInfo,
&testSHM_M->ModelData.derivCacheNeedsReset);
rtssSetZCCacheNeedsResetPtr(sfcnInfo,
&testSHM_M->ModelData.zCCacheNeedsReset);
rtssSetBlkStateChangePtr(sfcnInfo, &testSHM_M->ModelData.blkStateChange);
rtssSetSampleHitsPtr(sfcnInfo, &testSHM_M->Timing.sampleHits);
rtssSetPerTaskSampleHitsPtr(sfcnInfo, &testSHM_M->Timing.perTaskSampleHits);
rtssSetSimModePtr(sfcnInfo, &testSHM_M->simMode);
rtssSetSolverInfoPtr(sfcnInfo, &testSHM_M->solverInfoPtr);
}
testSHM_M->Sizes.numSFcns = (2);
/* register each child */
{
(void) memset((void *)&testSHM_M->NonInlinedSFcns.childSFunctions[0],0,
2*sizeof(SimStruct));
testSHM_M->childSfunctions = (&testSHM_M->
NonInlinedSFcns.childSFunctionPtrs[0]);
testSHM_M->childSfunctions[0] = (&testSHM_M->
NonInlinedSFcns.childSFunctions[0]);
testSHM_M->childSfunctions[1] = (&testSHM_M->
NonInlinedSFcns.childSFunctions[1]);
/* Level2 S-Function Block: testSHM/<Root>/S-Function (sSHM) */
{
SimStruct *rts = testSHM_M->childSfunctions[0];
/* timing info */
time_T *sfcnPeriod = testSHM_M->NonInlinedSFcns.Sfcn0.sfcnPeriod;
time_T *sfcnOffset = testSHM_M->NonInlinedSFcns.Sfcn0.sfcnOffset;
int_T *sfcnTsMap = testSHM_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, &testSHM_M->NonInlinedSFcns.blkInfo2[0]);
ssSetRTWSfcnInfo(rts, testSHM_M->sfcnInfo);
}
/* Allocate memory of model methods 2 */
{
ssSetModelMethods2(rts, &testSHM_M->NonInlinedSFcns.methods2[0]);
}
/* Allocate memory of model methods 3 */
{
ssSetModelMethods3(rts, &testSHM_M->NonInlinedSFcns.methods3[0]);
}
/* inputs */
{
_ssSetNumInputPorts(rts, 1);
ssSetPortInfoForInputs(rts,
&testSHM_M->NonInlinedSFcns.Sfcn0.inputPortInfo[0]);
/* port 0 */
{
ssSetInputPortRequiredContiguous(rts, 0, 1);
ssSetInputPortSignal(rts, 0, testSHM_B.TmpHiddenBufferAtSFunctionInpor);
_ssSetInputPortNumDimensions(rts, 0, 1);
ssSetInputPortWidth(rts, 0, 3);
}
}
/* outputs */
{
ssSetPortInfoForOutputs(rts,
&testSHM_M->NonInlinedSFcns.Sfcn0.outputPortInfo[0]);
_ssSetNumOutputPorts(rts, 1);
/* port 0 */
{
_ssSetOutputPortNumDimensions(rts, 0, 1);
ssSetOutputPortWidth(rts, 0, 3);
ssSetOutputPortSignal(rts, 0, ((real_T *) testSHM_B.SFunction));
}
}
/* path info */
ssSetModelName(rts, "S-Function");
ssSetPath(rts, "testSHM/S-Function");
ssSetRTModel(rts,testSHM_M);
ssSetParentSS(rts, (NULL));
ssSetRootSS(rts, rts);
ssSetVersion(rts, SIMSTRUCT_VERSION_LEVEL2);
/* work vectors */
{
struct _ssDWorkRecord *dWorkRecord = (struct _ssDWorkRecord *)
&testSHM_M->NonInlinedSFcns.Sfcn0.dWork;
struct _ssDWorkAuxRecord *dWorkAuxRecord = (struct _ssDWorkAuxRecord *)
&testSHM_M->NonInlinedSFcns.Sfcn0.dWorkAux;
ssSetSFcnDWork(rts, dWorkRecord);
ssSetSFcnDWorkAux(rts, dWorkAuxRecord);
_ssSetNumDWork(rts, 2);
/* DWORK1 */
ssSetDWorkWidth(rts, 0, 1);
ssSetDWorkDataType(rts, 0,SS_POINTER);
ssSetDWorkComplexSignal(rts, 0, 0);
ssSetDWork(rts, 0, &testSHM_DWork.SFunction_DWORK1);
/* DWORK2 */
ssSetDWorkWidth(rts, 1, 1);
ssSetDWorkDataType(rts, 1,SS_POINTER);
ssSetDWorkComplexSignal(rts, 1, 0);
ssSetDWork(rts, 1, &testSHM_DWork.SFunction_DWORK2);
}
/* registration */
sSHM(rts);
sfcnInitializeSizes(rts);
sfcnInitializeSampleTimes(rts);
/* adjust sample time */
ssSetSampleTime(rts, 0, 0.001);
ssSetOffsetTime(rts, 0, 0.0);
sfcnTsMap[0] = 0;
/* set compiled values of dynamic vector attributes */
ssSetNumNonsampledZCs(rts, 0);
/* Update connectivity flags for each port */
_ssSetInputPortConnected(rts, 0, 1);
_ssSetOutputPortConnected(rts, 0, 1);
_ssSetOutputPortBeingMerged(rts, 0, 0);
/* Update the BufferDstPort flags for each input port */
ssSetInputPortBufferDstPort(rts, 0, -1);
}
/* Level2 S-Function Block: testSHM/<Root>/RTAI_SCOPE (sfun_rtai_scope) */
{
SimStruct *rts = testSHM_M->childSfunctions[1];
/* timing info */
time_T *sfcnPeriod = testSHM_M->NonInlinedSFcns.Sfcn1.sfcnPeriod;
time_T *sfcnOffset = testSHM_M->NonInlinedSFcns.Sfcn1.sfcnOffset;
int_T *sfcnTsMap = testSHM_M->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, &testSHM_M->NonInlinedSFcns.blkInfo2[1]);
ssSetRTWSfcnInfo(rts, testSHM_M->sfcnInfo);
}
/* Allocate memory of model methods 2 */
{
ssSetModelMethods2(rts, &testSHM_M->NonInlinedSFcns.methods2[1]);
}
/* Allocate memory of model methods 3 */
{
ssSetModelMethods3(rts, &testSHM_M->NonInlinedSFcns.methods3[1]);
}
/* inputs */
{
_ssSetNumInputPorts(rts, 3);
ssSetPortInfoForInputs(rts,
&testSHM_M->NonInlinedSFcns.Sfcn1.inputPortInfo[0]);
/* port 0 */
{
real_T const **sfcnUPtrs = (real_T const **)
&testSHM_M->NonInlinedSFcns.Sfcn1.UPtrs0;
sfcnUPtrs[0] = &testSHM_B.SFunction[0];
ssSetInputPortSignalPtrs(rts, 0, (InputPtrsType)&sfcnUPtrs[0]);
_ssSetInputPortNumDimensions(rts, 0, 1);
ssSetInputPortWidth(rts, 0, 1);
}
/* port 1 */
{
real_T const **sfcnUPtrs = (real_T const **)
&testSHM_M->NonInlinedSFcns.Sfcn1.UPtrs1;
sfcnUPtrs[0] = &testSHM_B.SFunction[1];
ssSetInputPortSignalPtrs(rts, 1, (InputPtrsType)&sfcnUPtrs[0]);
_ssSetInputPortNumDimensions(rts, 1, 1);
ssSetInputPortWidth(rts, 1, 1);
}
/* port 2 */
{
real_T const **sfcnUPtrs = (real_T const **)
&testSHM_M->NonInlinedSFcns.Sfcn1.UPtrs2;
sfcnUPtrs[0] = &testSHM_B.SFunction[2];
ssSetInputPortSignalPtrs(rts, 2, (InputPtrsType)&sfcnUPtrs[0]);
_ssSetInputPortNumDimensions(rts, 2, 1);
ssSetInputPortWidth(rts, 2, 1);
}
}
/* path info */
ssSetModelName(rts, "RTAI_SCOPE");
ssSetPath(rts, "testSHM/RTAI_SCOPE");
ssSetRTModel(rts,testSHM_M);
ssSetParentSS(rts, (NULL));
ssSetRootSS(rts, rts);
ssSetVersion(rts, SIMSTRUCT_VERSION_LEVEL2);
/* parameters */
{
mxArray **sfcnParams = (mxArray **)
&testSHM_M->NonInlinedSFcns.Sfcn1.params;
ssSetSFcnParamsCount(rts, 2);
ssSetSFcnParamsPtr(rts, &sfcnParams[0]);
ssSetSFcnParam(rts, 0, (mxArray*)&testSHM_P.RTAI_SCOPE_P1_Size[0]);
ssSetSFcnParam(rts, 1, (mxArray*)&testSHM_P.RTAI_SCOPE_P2_Size[0]);
}
/* work vectors */
ssSetPWork(rts, (void **) &testSHM_DWork.RTAI_SCOPE_PWORK);
{
struct _ssDWorkRecord *dWorkRecord = (struct _ssDWorkRecord *)
&testSHM_M->NonInlinedSFcns.Sfcn1.dWork;
struct _ssDWorkAuxRecord *dWorkAuxRecord = (struct _ssDWorkAuxRecord *)
&testSHM_M->NonInlinedSFcns.Sfcn1.dWorkAux;
ssSetSFcnDWork(rts, dWorkRecord);
ssSetSFcnDWorkAux(rts, dWorkAuxRecord);
_ssSetNumDWork(rts, 1);
/* PWORK */
ssSetDWorkWidth(rts, 0, 1);
ssSetDWorkDataType(rts, 0,SS_POINTER);
ssSetDWorkComplexSignal(rts, 0, 0);
ssSetDWork(rts, 0, &testSHM_DWork.RTAI_SCOPE_PWORK);
}
/* registration */
sfun_rtai_scope(rts);
sfcnInitializeSizes(rts);
sfcnInitializeSampleTimes(rts);
/* adjust sample time */
ssSetSampleTime(rts, 0, 0.001);
ssSetOffsetTime(rts, 0, 0.0);
sfcnTsMap[0] = 0;
/* set compiled values of dynamic vector attributes */
ssSetNumNonsampledZCs(rts, 0);
/* Update connectivity flags for each port */
_ssSetInputPortConnected(rts, 0, 1);
_ssSetInputPortConnected(rts, 1, 1);
_ssSetInputPortConnected(rts, 2, 1);
/* Update the BufferDstPort flags for each input port */
ssSetInputPortBufferDstPort(rts, 0, -1);
ssSetInputPortBufferDstPort(rts, 1, -1);
ssSetInputPortBufferDstPort(rts, 2, -1);
}
}
}
/* 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 */
}
}
}
/* Registration function */
RT_MODEL_Force_ctrl_sixaxis_T *Force_ctrl_sixaxis(void)
{
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)Force_ctrl_sixaxis_M, 0,
sizeof(RT_MODEL_Force_ctrl_sixaxis_T));
/* Initialize timing info */
{
int_T *mdlTsMap = Force_ctrl_sixaxis_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
Force_ctrl_sixaxis_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
Force_ctrl_sixaxis_M->Timing.sampleTimes =
(&Force_ctrl_sixaxis_M->Timing.sampleTimesArray[0]);
Force_ctrl_sixaxis_M->Timing.offsetTimes =
(&Force_ctrl_sixaxis_M->Timing.offsetTimesArray[0]);
/* task periods */
Force_ctrl_sixaxis_M->Timing.sampleTimes[0] = (0.01);
/* task offsets */
Force_ctrl_sixaxis_M->Timing.offsetTimes[0] = (0.0);
}
rtmSetTPtr(Force_ctrl_sixaxis_M, &Force_ctrl_sixaxis_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = Force_ctrl_sixaxis_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
Force_ctrl_sixaxis_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(Force_ctrl_sixaxis_M, -1);
Force_ctrl_sixaxis_M->Timing.stepSize0 = 0.01;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
Force_ctrl_sixaxis_M->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
rtliSetLogXSignalInfo(Force_ctrl_sixaxis_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(Force_ctrl_sixaxis_M->rtwLogInfo, (NULL));
rtliSetLogT(Force_ctrl_sixaxis_M->rtwLogInfo, "tout");
rtliSetLogX(Force_ctrl_sixaxis_M->rtwLogInfo, "");
rtliSetLogXFinal(Force_ctrl_sixaxis_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(Force_ctrl_sixaxis_M->rtwLogInfo, "rt_");
rtliSetLogFormat(Force_ctrl_sixaxis_M->rtwLogInfo, 0);
rtliSetLogMaxRows(Force_ctrl_sixaxis_M->rtwLogInfo, 1000);
rtliSetLogDecimation(Force_ctrl_sixaxis_M->rtwLogInfo, 1);
rtliSetLogY(Force_ctrl_sixaxis_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(Force_ctrl_sixaxis_M->rtwLogInfo, (NULL));
rtliSetLogYSignalPtrs(Force_ctrl_sixaxis_M->rtwLogInfo, (NULL));
}
Force_ctrl_sixaxis_M->solverInfoPtr = (&Force_ctrl_sixaxis_M->solverInfo);
Force_ctrl_sixaxis_M->Timing.stepSize = (0.01);
rtsiSetFixedStepSize(&Force_ctrl_sixaxis_M->solverInfo, 0.01);
rtsiSetSolverMode(&Force_ctrl_sixaxis_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
Force_ctrl_sixaxis_M->ModelData.blockIO = ((void *) &Force_ctrl_sixaxis_B);
(void) memset(((void *) &Force_ctrl_sixaxis_B), 0,
sizeof(B_Force_ctrl_sixaxis_T));
/* parameters */
Force_ctrl_sixaxis_M->ModelData.defaultParam = ((real_T *)
&Force_ctrl_sixaxis_P);
/* states (dwork) */
Force_ctrl_sixaxis_M->ModelData.dwork = ((void *) &Force_ctrl_sixaxis_DW);
(void) memset((void *)&Force_ctrl_sixaxis_DW, 0,
sizeof(DW_Force_ctrl_sixaxis_T));
/* Initialize Sizes */
Force_ctrl_sixaxis_M->Sizes.numContStates = (0);/* Number of continuous states */
Force_ctrl_sixaxis_M->Sizes.numY = (0);/* Number of model outputs */
Force_ctrl_sixaxis_M->Sizes.numU = (0);/* Number of model inputs */
Force_ctrl_sixaxis_M->Sizes.sysDirFeedThru = (0);/* The model is not direct feedthrough */
Force_ctrl_sixaxis_M->Sizes.numSampTimes = (1);/* Number of sample times */
Force_ctrl_sixaxis_M->Sizes.numBlocks = (22);/* Number of blocks */
Force_ctrl_sixaxis_M->Sizes.numBlockIO = (12);/* Number of block outputs */
Force_ctrl_sixaxis_M->Sizes.numBlockPrms = (96);/* Sum of parameter "widths" */
return Force_ctrl_sixaxis_M;
}
/* Function: rt_FillStateSigInfoFromMMI =======================================
* Abstract:
*
* Returns:
* == NULL => success.
* ~= NULL => failure, the return value is a pointer to the error
* message, which is also set in the simstruct.
*/
const char_T * rt_FillStateSigInfoFromMMI(RTWLogInfo *li,
const char_T **errStatus)
{
int_T i;
int_T nSignals = 0;
int_T *dims = NULL;
BuiltInDTypeId *dTypes = NULL;
int_T *cSgnls = NULL;
char_T **labels = NULL;
char_T **blockNames = NULL;
char_T **stateNames = NULL;
boolean_T *crossMdlRef = NULL;
void **sigDataAddr = NULL;
int_T *logDataType = NULL;
boolean_T *isVarDims = NULL;
const rtwCAPI_ModelMappingInfo *mmi = (const rtwCAPI_ModelMappingInfo *)rtliGetMMI(li);
int_T sigIdx = 0;
RTWLogSignalInfo * sigInfo;
/* reset error status */
*errStatus = NULL;
sigInfo = (RTWLogSignalInfo *)calloc(1,sizeof(RTWLogSignalInfo));
if (sigInfo == NULL) goto ERROR_EXIT;
nSignals = rtwCAPI_GetNumStateRecordsForRTWLogging(mmi);
if (nSignals >0) {
/* These are all freed before exiting this function */
dims = (int_T *)calloc(nSignals,sizeof(int_T));
if (dims == NULL) goto ERROR_EXIT;
dTypes = (BuiltInDTypeId *)calloc(nSignals,sizeof(BuiltInDTypeId));
if (dTypes == NULL) goto ERROR_EXIT;
cSgnls = (int_T *)calloc(nSignals,sizeof(int_T));
if (cSgnls == NULL) goto ERROR_EXIT;
labels = (char_T **)calloc(nSignals, sizeof(char_T*));
if (labels == NULL) goto ERROR_EXIT;
blockNames = (char_T**)calloc(nSignals, sizeof(char_T*));
if (blockNames == NULL) goto ERROR_EXIT;
stateNames = (char_T**)calloc(nSignals, sizeof(char_T*));
if (stateNames == NULL) goto ERROR_EXIT;
crossMdlRef = (boolean_T*)calloc(nSignals, sizeof(boolean_T));
if (crossMdlRef == NULL) goto ERROR_EXIT;
logDataType = (int_T *)calloc(nSignals,sizeof(int_T));
if (logDataType == NULL) goto ERROR_EXIT;
/* Allocate memeory for isVarDims pointer and set all elements to 0's */
isVarDims = (boolean_T *)calloc(nSignals,sizeof(boolean_T));
if (isVarDims == NULL) goto ERROR_EXIT;
/* This is freed in stopDataLogging (it's needed in the meantime) */
sigDataAddr = (void **)calloc(nSignals,sizeof(void *));
if (sigDataAddr == NULL) goto ERROR_EXIT;
*errStatus = rtwCAPI_GetStateRecordInfo(mmi,
(const char_T**) blockNames,
(const char_T**) labels,
(const char_T**) stateNames,
dims,
(int_T*)dTypes,
logDataType,
cSgnls,
sigDataAddr,
crossMdlRef,
NULL,
NULL, /* sigSampleTime */
&sigIdx,
false, /* crossingModel */
NULL, /* stateDerivVector */
ACCESS_C_API_FOR_RTW_LOGGING);
if (*errStatus != NULL) goto ERROR_EXIT;
rtliSetLogXSignalPtrs(li,(LogSignalPtrsType)sigDataAddr);
}
sigInfo->numSignals = nSignals;
sigInfo->numCols = dims;
sigInfo->numDims = NULL;
sigInfo->dims = dims;
sigInfo->dataTypes = dTypes;
sigInfo->complexSignals = cSgnls;
sigInfo->frameData = NULL;
sigInfo->labels.ptr = labels;
sigInfo->titles = NULL;
sigInfo->titleLengths = NULL;
sigInfo->plotStyles = NULL;
sigInfo->blockNames.ptr = blockNames;
sigInfo->stateNames.ptr = stateNames;
sigInfo->crossMdlRef = crossMdlRef;
sigInfo->dataTypeConvert = NULL;
sigInfo->isVarDims = isVarDims;
sigInfo->currSigDims = NULL;
rtliSetLogXSignalInfo(li,sigInfo);
/* Free logDataType it's not needed any more,
* the rest of them will be freed later */
FREE(logDataType);
return(NULL); /* NORMAL_EXIT */
ERROR_EXIT:
if (*errStatus == NULL) {
*errStatus = rtMemAllocError;
}
/* Free local stuff that was allocated. It is no longer needed */
for (i = 0; i < nSignals; ++i) utFree(blockNames[i]);
FREE(blockNames);
for (i = 0; i < nSignals; ++i) utFree(stateNames[i]);
FREE(stateNames);
FREE(labels);
FREE(dims);
FREE(dTypes);
FREE(logDataType);
FREE(cSgnls);
FREE(isVarDims);
return(*errStatus);
} /* end rt_InitSignalsStruct */
/* 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 HConstfolding_initialize(void)
{
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)HConstfolding_M, 0,
sizeof(RT_MODEL_HConstfolding));
/* Initialize timing info */
{
int_T *mdlTsMap = HConstfolding_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
HConstfolding_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
HConstfolding_M->Timing.sampleTimes =
(&HConstfolding_M->Timing.sampleTimesArray[0]);
HConstfolding_M->Timing.offsetTimes =
(&HConstfolding_M->Timing.offsetTimesArray[0]);
/* task periods */
HConstfolding_M->Timing.sampleTimes[0] = (1.0);
/* task offsets */
HConstfolding_M->Timing.offsetTimes[0] = (0.0);
}
rtmSetTPtr(HConstfolding_M, &HConstfolding_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = HConstfolding_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
HConstfolding_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(HConstfolding_M, 1.0E+8);
HConstfolding_M->Timing.stepSize0 = 1.0;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
HConstfolding_M->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
rtliSetLogXSignalInfo(HConstfolding_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(HConstfolding_M->rtwLogInfo, (NULL));
rtliSetLogT(HConstfolding_M->rtwLogInfo, "tout");
rtliSetLogX(HConstfolding_M->rtwLogInfo, "");
rtliSetLogXFinal(HConstfolding_M->rtwLogInfo, "");
rtliSetSigLog(HConstfolding_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(HConstfolding_M->rtwLogInfo, "rt_");
rtliSetLogFormat(HConstfolding_M->rtwLogInfo, 0);
rtliSetLogMaxRows(HConstfolding_M->rtwLogInfo, 1000);
rtliSetLogDecimation(HConstfolding_M->rtwLogInfo, 1);
/*
* Set pointers to the data and signal info for each output
*/
{
static void * rt_LoggedOutputSignalPtrs[] = {
&HConstfolding_Y.Out1
};
rtliSetLogYSignalPtrs(HConstfolding_M->rtwLogInfo, ((LogSignalPtrsType)
rt_LoggedOutputSignalPtrs));
}
{
static int_T rt_LoggedOutputWidths[] = {
1
};
static int_T rt_LoggedOutputNumDimensions[] = {
1
};
static int_T rt_LoggedOutputDimensions[] = {
1
};
static boolean_T rt_LoggedOutputIsVarDims[] = {
0
};
static void* rt_LoggedCurrentSignalDimensions[] = {
(NULL)
};
static int_T rt_LoggedCurrentSignalDimensionsSize[] = {
4
};
static BuiltInDTypeId rt_LoggedOutputDataTypeIds[] = {
SS_DOUBLE
};
static int_T rt_LoggedOutputComplexSignals[] = {
0
};
static const char_T *rt_LoggedOutputLabels[] = {
"" };
static const char_T *rt_LoggedOutputBlockNames[] = {
"HConstfolding/Out1" };
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_LoggedCurrentSignalDimensionsSize,
rt_LoggedOutputDataTypeIds,
rt_LoggedOutputComplexSignals,
(NULL),
{ rt_LoggedOutputLabels },
(NULL),
(NULL),
(NULL),
{ rt_LoggedOutputBlockNames },
{ (NULL) },
(NULL),
rt_RTWLogDataTypeConvert
}
};
rtliSetLogYSignalInfo(HConstfolding_M->rtwLogInfo,
rt_LoggedOutputSignalInfo);
/* set currSigDims field */
rt_LoggedCurrentSignalDimensions[0] = &rt_LoggedOutputWidths[0];
}
rtliSetLogY(HConstfolding_M->rtwLogInfo, "yout");
}
HConstfolding_M->solverInfoPtr = (&HConstfolding_M->solverInfo);
HConstfolding_M->Timing.stepSize = (1.0);
rtsiSetFixedStepSize(&HConstfolding_M->solverInfo, 1.0);
rtsiSetSolverMode(&HConstfolding_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* states (dwork) */
(void) memset((void *)&HConstfolding_DWork, 0,
sizeof(D_Work_HConstfolding));
/* external outputs */
HConstfolding_Y.Out1 = 0.0;
/* Matfile logging */
rt_StartDataLoggingWithStartTime(HConstfolding_M->rtwLogInfo, 0.0,
rtmGetTFinal(HConstfolding_M), HConstfolding_M->Timing.stepSize0,
(&rtmGetErrorStatus(HConstfolding_M)));
/* Initialize Sizes */
HConstfolding_M->Sizes.numContStates = (0);/* Number of continuous states */
HConstfolding_M->Sizes.numY = (1); /* Number of model outputs */
HConstfolding_M->Sizes.numU = (0); /* Number of model inputs */
HConstfolding_M->Sizes.sysDirFeedThru = (0);/* The model is not direct feedthrough */
HConstfolding_M->Sizes.numSampTimes = (1);/* Number of sample times */
HConstfolding_M->Sizes.numBlocks = (14);/* Number of blocks */
HConstfolding_M->Sizes.numBlockIO = (0);/* Number of block outputs */
HConstfolding_M->Sizes.numBlockPrms = (10);/* Sum of parameter "widths" */
/* InitializeConditions for UnitDelay: '<Root>/Unit Delay' */
HConstfolding_DWork.UnitDelay_DSTATE = HConstfolding_P.UnitDelay_X0;
/* InitializeConditions for UnitDelay: '<Root>/Unit Delay1' */
HConstfolding_DWork.UnitDelay1_DSTATE = HConstfolding_P.UnitDelay1_X0;
}
/* Registration function */
RT_MODEL_RA4_student_T *RA4_student(void)
{
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)RA4_student_M, 0,
sizeof(RT_MODEL_RA4_student_T));
{
/* Setup solver object */
rtsiSetSimTimeStepPtr(&RA4_student_M->solverInfo,
&RA4_student_M->Timing.simTimeStep);
rtsiSetTPtr(&RA4_student_M->solverInfo, &rtmGetTPtr(RA4_student_M));
rtsiSetStepSizePtr(&RA4_student_M->solverInfo,
&RA4_student_M->Timing.stepSize0);
rtsiSetErrorStatusPtr(&RA4_student_M->solverInfo, (&rtmGetErrorStatus
(RA4_student_M)));
rtsiSetRTModelPtr(&RA4_student_M->solverInfo, RA4_student_M);
}
rtsiSetSimTimeStep(&RA4_student_M->solverInfo, MAJOR_TIME_STEP);
rtsiSetSolverName(&RA4_student_M->solverInfo,"FixedStepDiscrete");
RA4_student_M->solverInfoPtr = (&RA4_student_M->solverInfo);
/* Initialize timing info */
{
int_T *mdlTsMap = RA4_student_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
mdlTsMap[1] = 1;
RA4_student_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
RA4_student_M->Timing.sampleTimes = (&RA4_student_M->
Timing.sampleTimesArray[0]);
RA4_student_M->Timing.offsetTimes = (&RA4_student_M->
Timing.offsetTimesArray[0]);
/* task periods */
RA4_student_M->Timing.sampleTimes[0] = (0.0);
RA4_student_M->Timing.sampleTimes[1] = (0.000244140625);
/* task offsets */
RA4_student_M->Timing.offsetTimes[0] = (0.0);
RA4_student_M->Timing.offsetTimes[1] = (0.0);
}
rtmSetTPtr(RA4_student_M, &RA4_student_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = RA4_student_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
mdlSampleHits[1] = 1;
RA4_student_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(RA4_student_M, 1000.0);
RA4_student_M->Timing.stepSize0 = 0.000244140625;
RA4_student_M->Timing.stepSize1 = 0.000244140625;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
rt_DataLoggingInfo.loggingInterval = NULL;
RA4_student_M->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
rtliSetLogXSignalInfo(RA4_student_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(RA4_student_M->rtwLogInfo, (NULL));
rtliSetLogT(RA4_student_M->rtwLogInfo, "tout");
rtliSetLogX(RA4_student_M->rtwLogInfo, "");
rtliSetLogXFinal(RA4_student_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(RA4_student_M->rtwLogInfo, "rt_");
rtliSetLogFormat(RA4_student_M->rtwLogInfo, 0);
rtliSetLogMaxRows(RA4_student_M->rtwLogInfo, 0);
rtliSetLogDecimation(RA4_student_M->rtwLogInfo, 1);
rtliSetLogY(RA4_student_M->rtwLogInfo, "");
rtliSetLogYSignalInfo(RA4_student_M->rtwLogInfo, (NULL));
rtliSetLogYSignalPtrs(RA4_student_M->rtwLogInfo, (NULL));
}
/* External mode info */
RA4_student_M->Sizes.checksums[0] = (2785597085U);
RA4_student_M->Sizes.checksums[1] = (79388889U);
RA4_student_M->Sizes.checksums[2] = (3150282079U);
RA4_student_M->Sizes.checksums[3] = (1201550713U);
{
static const sysRanDType rtAlwaysEnabled = SUBSYS_RAN_BC_ENABLE;
static RTWExtModeInfo rt_ExtModeInfo;
static const sysRanDType *systemRan[2];
RA4_student_M->extModeInfo = (&rt_ExtModeInfo);
rteiSetSubSystemActiveVectorAddresses(&rt_ExtModeInfo, systemRan);
systemRan[0] = &rtAlwaysEnabled;
systemRan[1] = (sysRanDType *)&RA4_student_DW.Controller_SubsysRanBC;
rteiSetModelMappingInfoPtr(RA4_student_M->extModeInfo,
&RA4_student_M->SpecialInfo.mappingInfo);
rteiSetChecksumsPtr(RA4_student_M->extModeInfo,
RA4_student_M->Sizes.checksums);
rteiSetTPtr(RA4_student_M->extModeInfo, rtmGetTPtr(RA4_student_M));
}
RA4_student_M->solverInfoPtr = (&RA4_student_M->solverInfo);
RA4_student_M->Timing.stepSize = (0.000244140625);
rtsiSetFixedStepSize(&RA4_student_M->solverInfo, 0.000244140625);
rtsiSetSolverMode(&RA4_student_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
RA4_student_M->ModelData.blockIO = ((void *) &RA4_student_B);
(void) memset(((void *) &RA4_student_B), 0,
sizeof(B_RA4_student_T));
{
RA4_student_B.UnitDelay2[0] = 0.0;
RA4_student_B.UnitDelay2[1] = 0.0;
RA4_student_B.UnitDelay2[2] = 0.0;
RA4_student_B.UnitDelay1 = 0.0;
RA4_student_B.RobotArm_sfcn_o1 = 0.0;
RA4_student_B.RobotArm_sfcn_o2[0] = 0.0;
RA4_student_B.RobotArm_sfcn_o2[1] = 0.0;
RA4_student_B.RobotArm_sfcn_o2[2] = 0.0;
RA4_student_B.RobotArm_sfcn_o4 = 0.0;
RA4_student_B.Sum4 = 0.0;
RA4_student_B.Sum5 = 0.0;
RA4_student_B.Sum6 = 0.0;
RA4_student_B.ReferenceSolenoid = 0.0;
RA4_student_B.SFunction[0] = 0.0;
RA4_student_B.SFunction[1] = 0.0;
RA4_student_B.SFunction[2] = 0.0;
RA4_student_B.SFunction[3] = 0.0;
}
/* parameters */
RA4_student_M->ModelData.defaultParam = ((real_T *)&RA4_student_P);
/* states (dwork) */
RA4_student_M->ModelData.dwork = ((void *) &RA4_student_DW);
(void) memset((void *)&RA4_student_DW, 0,
sizeof(DW_RA4_student_T));
RA4_student_DW.UnitDelay2_DSTATE[0] = 0.0;
RA4_student_DW.UnitDelay2_DSTATE[1] = 0.0;
RA4_student_DW.UnitDelay2_DSTATE[2] = 0.0;
RA4_student_DW.UnitDelay1_DSTATE = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK0 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK1 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK2 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK3 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK4 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK5 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK6 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK7 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK8 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK9 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK10 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK11 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK12 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK13 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK14 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK15 = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK16[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK16[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK17[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK17[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK18[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK18[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK18[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK18[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK19[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK19[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK19[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK19[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK20[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK20[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK21[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK21[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK21[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK21[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK22[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK22[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK22[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK22[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK23[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK23[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK24[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK24[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK25[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK25[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK25[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK25[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK26[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK26[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK26[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK26[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK27[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK27[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK28[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK28[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK28[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK28[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK29[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK29[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK29[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK29[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK30[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK30[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK31[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK31[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK32[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK32[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK32[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK32[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK33[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK33[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK33[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK33[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK34[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK34[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK35[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK35[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK35[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK35[3] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK36[0] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK36[1] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK36[2] = 0.0;
RA4_student_DW.RobotArm_sfcn_DWORK36[3] = 0.0;
/* data type transition information */
{
static DataTypeTransInfo dtInfo;
(void) memset((char_T *) &dtInfo, 0,
sizeof(dtInfo));
RA4_student_M->SpecialInfo.mappingInfo = (&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;
}
/* child S-Function registration */
{
RTWSfcnInfo *sfcnInfo = &RA4_student_M->NonInlinedSFcns.sfcnInfo;
RA4_student_M->sfcnInfo = (sfcnInfo);
rtssSetErrorStatusPtr(sfcnInfo, (&rtmGetErrorStatus(RA4_student_M)));
rtssSetNumRootSampTimesPtr(sfcnInfo, &RA4_student_M->Sizes.numSampTimes);
RA4_student_M->NonInlinedSFcns.taskTimePtrs[0] = &(rtmGetTPtr(RA4_student_M)
[0]);
RA4_student_M->NonInlinedSFcns.taskTimePtrs[1] = &(rtmGetTPtr(RA4_student_M)
[1]);
rtssSetTPtrPtr(sfcnInfo,RA4_student_M->NonInlinedSFcns.taskTimePtrs);
rtssSetTStartPtr(sfcnInfo, &rtmGetTStart(RA4_student_M));
rtssSetTFinalPtr(sfcnInfo, &rtmGetTFinal(RA4_student_M));
rtssSetTimeOfLastOutputPtr(sfcnInfo, &rtmGetTimeOfLastOutput(RA4_student_M));
rtssSetStepSizePtr(sfcnInfo, &RA4_student_M->Timing.stepSize);
rtssSetStopRequestedPtr(sfcnInfo, &rtmGetStopRequested(RA4_student_M));
rtssSetDerivCacheNeedsResetPtr(sfcnInfo,
&RA4_student_M->ModelData.derivCacheNeedsReset);
rtssSetZCCacheNeedsResetPtr(sfcnInfo,
&RA4_student_M->ModelData.zCCacheNeedsReset);
rtssSetBlkStateChangePtr(sfcnInfo, &RA4_student_M->ModelData.blkStateChange);
rtssSetSampleHitsPtr(sfcnInfo, &RA4_student_M->Timing.sampleHits);
rtssSetPerTaskSampleHitsPtr(sfcnInfo,
&RA4_student_M->Timing.perTaskSampleHits);
rtssSetSimModePtr(sfcnInfo, &RA4_student_M->simMode);
rtssSetSolverInfoPtr(sfcnInfo, &RA4_student_M->solverInfoPtr);
}
RA4_student_M->Sizes.numSFcns = (2);
/* register each child */
{
(void) memset((void *)&RA4_student_M->NonInlinedSFcns.childSFunctions[0], 0,
2*sizeof(SimStruct));
RA4_student_M->childSfunctions =
(&RA4_student_M->NonInlinedSFcns.childSFunctionPtrs[0]);
RA4_student_M->childSfunctions[0] =
(&RA4_student_M->NonInlinedSFcns.childSFunctions[0]);
RA4_student_M->childSfunctions[1] =
(&RA4_student_M->NonInlinedSFcns.childSFunctions[1]);
/* Level2 S-Function Block: RA4_student/<S6>/S-Function (sf_rt_scope) */
{
SimStruct *rts = RA4_student_M->childSfunctions[0];
/* timing info */
time_T *sfcnPeriod = RA4_student_M->NonInlinedSFcns.Sfcn0.sfcnPeriod;
time_T *sfcnOffset = RA4_student_M->NonInlinedSFcns.Sfcn0.sfcnOffset;
int_T *sfcnTsMap = RA4_student_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, &RA4_student_M->NonInlinedSFcns.blkInfo2[0]);
}
ssSetRTWSfcnInfo(rts, RA4_student_M->sfcnInfo);
/* Allocate memory of model methods 2 */
{
ssSetModelMethods2(rts, &RA4_student_M->NonInlinedSFcns.methods2[0]);
}
/* Allocate memory of model methods 3 */
{
ssSetModelMethods3(rts, &RA4_student_M->NonInlinedSFcns.methods3[0]);
}
/* Allocate memory for states auxilliary information */
{
ssSetStatesInfo2(rts, &RA4_student_M->NonInlinedSFcns.statesInfo2[0]);
ssSetPeriodicStatesInfo(rts,
&RA4_student_M->NonInlinedSFcns.periodicStatesInfo[0]);
}
/* inputs */
{
_ssSetNumInputPorts(rts, 1);
ssSetPortInfoForInputs(rts,
&RA4_student_M->NonInlinedSFcns.Sfcn0.inputPortInfo[0]);
/* port 0 */
{
real_T const **sfcnUPtrs = (real_T const **)
&RA4_student_M->NonInlinedSFcns.Sfcn0.UPtrs0;
sfcnUPtrs[0] = (real_T*)&RA4_student_RGND;
sfcnUPtrs[1] = (real_T*)&RA4_student_RGND;
sfcnUPtrs[2] = (real_T*)&RA4_student_RGND;
sfcnUPtrs[3] = (real_T*)&RA4_student_RGND;
sfcnUPtrs[4] = (real_T*)&RA4_student_RGND;
sfcnUPtrs[5] = (real_T*)&RA4_student_RGND;
sfcnUPtrs[6] = (real_T*)&RA4_student_RGND;
sfcnUPtrs[7] = (real_T*)&RA4_student_RGND;
ssSetInputPortSignalPtrs(rts, 0, (InputPtrsType)&sfcnUPtrs[0]);
_ssSetInputPortNumDimensions(rts, 0, 1);
ssSetInputPortWidth(rts, 0, 8);
}
}
/* outputs */
{
ssSetPortInfoForOutputs(rts,
&RA4_student_M->NonInlinedSFcns.Sfcn0.outputPortInfo[0]);
_ssSetNumOutputPorts(rts, 1);
/* port 0 */
{
_ssSetOutputPortNumDimensions(rts, 0, 1);
ssSetOutputPortWidth(rts, 0, 4);
ssSetOutputPortSignal(rts, 0, ((real_T *) RA4_student_B.SFunction));
}
}
/* path info */
ssSetModelName(rts, "S-Function");
ssSetPath(rts, "RA4_student/Controller/RTScope/S-Function");
ssSetRTModel(rts,RA4_student_M);
ssSetParentSS(rts, (NULL));
ssSetRootSS(rts, rts);
ssSetVersion(rts, SIMSTRUCT_VERSION_LEVEL2);
/* parameters */
{
mxArray **sfcnParams = (mxArray **)
&RA4_student_M->NonInlinedSFcns.Sfcn0.params;
ssSetSFcnParamsCount(rts, 1);
ssSetSFcnParamsPtr(rts, &sfcnParams[0]);
ssSetSFcnParam(rts, 0, (mxArray*)RA4_student_P.SFunction_P1_Size);
}
/* registration */
sf_rt_scope(rts);
sfcnInitializeSizes(rts);
sfcnInitializeSampleTimes(rts);
/* adjust sample time */
ssSetSampleTime(rts, 0, 0.0);
ssSetOffsetTime(rts, 0, 0.0);
sfcnTsMap[0] = 0;
/* set compiled values of dynamic vector attributes */
ssSetNumNonsampledZCs(rts, 0);
/* Update connectivity flags for each port */
_ssSetInputPortConnected(rts, 0, 1);
_ssSetOutputPortConnected(rts, 0, 1);
_ssSetOutputPortBeingMerged(rts, 0, 0);
/* Update the BufferDstPort flags for each input port */
ssSetInputPortBufferDstPort(rts, 0, -1);
}
/* RTW Generated Level2 S-Function Block: RA4_student/<S2>/Robot Arm_sfcn (Robot_sf) */
{
SimStruct *rts = RA4_student_M->childSfunctions[1];
/* timing info */
time_T *sfcnPeriod = RA4_student_M->NonInlinedSFcns.Sfcn1.sfcnPeriod;
time_T *sfcnOffset = RA4_student_M->NonInlinedSFcns.Sfcn1.sfcnOffset;
int_T *sfcnTsMap = RA4_student_M->NonInlinedSFcns.Sfcn1.sfcnTsMap;
(void) memset((void*)sfcnPeriod, 0,
sizeof(time_T)*2);
(void) memset((void*)sfcnOffset, 0,
sizeof(time_T)*2);
ssSetSampleTimePtr(rts, &sfcnPeriod[0]);
ssSetOffsetTimePtr(rts, &sfcnOffset[0]);
ssSetSampleTimeTaskIDPtr(rts, sfcnTsMap);
/* Set up the mdlInfo pointer */
{
ssSetBlkInfo2Ptr(rts, &RA4_student_M->NonInlinedSFcns.blkInfo2[1]);
}
ssSetRTWSfcnInfo(rts, RA4_student_M->sfcnInfo);
/* Allocate memory of model methods 2 */
{
ssSetModelMethods2(rts, &RA4_student_M->NonInlinedSFcns.methods2[1]);
}
/* Allocate memory of model methods 3 */
{
ssSetModelMethods3(rts, &RA4_student_M->NonInlinedSFcns.methods3[1]);
}
/* Allocate memory for states auxilliary information */
{
ssSetStatesInfo2(rts, &RA4_student_M->NonInlinedSFcns.statesInfo2[1]);
ssSetPeriodicStatesInfo(rts,
&RA4_student_M->NonInlinedSFcns.periodicStatesInfo[1]);
}
/* inputs */
{
_ssSetNumInputPorts(rts, 2);
ssSetPortInfoForInputs(rts,
&RA4_student_M->NonInlinedSFcns.Sfcn1.inputPortInfo[0]);
/* port 0 */
{
real_T const **sfcnUPtrs = (real_T const **)
&RA4_student_M->NonInlinedSFcns.Sfcn1.UPtrs0;
sfcnUPtrs[0] = RA4_student_B.UnitDelay2;
sfcnUPtrs[1] = &RA4_student_B.UnitDelay2[1];
sfcnUPtrs[2] = &RA4_student_B.UnitDelay2[2];
ssSetInputPortSignalPtrs(rts, 0, (InputPtrsType)&sfcnUPtrs[0]);
_ssSetInputPortNumDimensions(rts, 0, 1);
ssSetInputPortWidth(rts, 0, 3);
}
/* port 1 */
{
real_T const **sfcnUPtrs = (real_T const **)
&RA4_student_M->NonInlinedSFcns.Sfcn1.UPtrs1;
sfcnUPtrs[0] = &RA4_student_B.UnitDelay1;
ssSetInputPortSignalPtrs(rts, 1, (InputPtrsType)&sfcnUPtrs[0]);
_ssSetInputPortNumDimensions(rts, 1, 1);
ssSetInputPortWidth(rts, 1, 1);
}
}
/* outputs */
{
ssSetPortInfoForOutputs(rts,
&RA4_student_M->NonInlinedSFcns.Sfcn1.outputPortInfo[0]);
_ssSetNumOutputPorts(rts, 4);
/* port 0 */
{
_ssSetOutputPortNumDimensions(rts, 0, 1);
ssSetOutputPortWidth(rts, 0, 1);
ssSetOutputPortSignal(rts, 0, ((real_T *)
&RA4_student_B.RobotArm_sfcn_o1));
}
/* port 1 */
{
_ssSetOutputPortNumDimensions(rts, 1, 1);
ssSetOutputPortWidth(rts, 1, 3);
ssSetOutputPortSignal(rts, 1, ((real_T *)
RA4_student_B.RobotArm_sfcn_o2));
}
/* port 2 */
{
_ssSetOutputPortNumDimensions(rts, 2, 1);
ssSetOutputPortWidth(rts, 2, 3);
ssSetOutputPortSignal(rts, 2, ((boolean_T *)
RA4_student_B.RobotArm_sfcn_o3));
}
/* port 3 */
{
_ssSetOutputPortNumDimensions(rts, 3, 1);
ssSetOutputPortWidth(rts, 3, 1);
ssSetOutputPortSignal(rts, 3, ((real_T *)
&RA4_student_B.RobotArm_sfcn_o4));
}
}
/* path info */
ssSetModelName(rts, "Robot Arm_sfcn");
ssSetPath(rts, "RA4_student/Robot Arm1/Robot Arm_sfcn");
ssSetRTModel(rts,RA4_student_M);
ssSetParentSS(rts, (NULL));
ssSetRootSS(rts, rts);
ssSetVersion(rts, SIMSTRUCT_VERSION_LEVEL2);
/* work vectors */
{
struct _ssDWorkRecord *dWorkRecord = (struct _ssDWorkRecord *)
&RA4_student_M->NonInlinedSFcns.Sfcn1.dWork;
struct _ssDWorkAuxRecord *dWorkAuxRecord = (struct _ssDWorkAuxRecord *)
&RA4_student_M->NonInlinedSFcns.Sfcn1.dWorkAux;
ssSetSFcnDWork(rts, dWorkRecord);
ssSetSFcnDWorkAux(rts, dWorkAuxRecord);
_ssSetNumDWork(rts, 47);
/* DWORK0 */
ssSetDWorkWidth(rts, 0, 1);
ssSetDWorkDataType(rts, 0,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 0, 0);
ssSetDWorkUsedAsDState(rts, 0, 1);
ssSetDWork(rts, 0, &RA4_student_DW.RobotArm_sfcn_DWORK0);
/* DWORK1 */
ssSetDWorkWidth(rts, 1, 1);
ssSetDWorkDataType(rts, 1,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 1, 0);
ssSetDWorkUsedAsDState(rts, 1, 1);
ssSetDWork(rts, 1, &RA4_student_DW.RobotArm_sfcn_DWORK1);
/* DWORK2 */
ssSetDWorkWidth(rts, 2, 1);
ssSetDWorkDataType(rts, 2,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 2, 0);
ssSetDWorkUsedAsDState(rts, 2, 1);
ssSetDWork(rts, 2, &RA4_student_DW.RobotArm_sfcn_DWORK2);
/* DWORK3 */
ssSetDWorkWidth(rts, 3, 1);
ssSetDWorkDataType(rts, 3,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 3, 0);
ssSetDWorkUsedAsDState(rts, 3, 1);
ssSetDWork(rts, 3, &RA4_student_DW.RobotArm_sfcn_DWORK3);
/* DWORK4 */
ssSetDWorkWidth(rts, 4, 1);
ssSetDWorkDataType(rts, 4,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 4, 0);
ssSetDWorkUsedAsDState(rts, 4, 1);
ssSetDWork(rts, 4, &RA4_student_DW.RobotArm_sfcn_DWORK4);
/* DWORK5 */
ssSetDWorkWidth(rts, 5, 1);
ssSetDWorkDataType(rts, 5,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 5, 0);
ssSetDWorkUsedAsDState(rts, 5, 1);
ssSetDWork(rts, 5, &RA4_student_DW.RobotArm_sfcn_DWORK5);
/* DWORK6 */
ssSetDWorkWidth(rts, 6, 1);
ssSetDWorkDataType(rts, 6,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 6, 0);
ssSetDWorkUsedAsDState(rts, 6, 1);
ssSetDWork(rts, 6, &RA4_student_DW.RobotArm_sfcn_DWORK6);
/* DWORK7 */
ssSetDWorkWidth(rts, 7, 1);
ssSetDWorkDataType(rts, 7,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 7, 0);
ssSetDWorkUsedAsDState(rts, 7, 1);
ssSetDWork(rts, 7, &RA4_student_DW.RobotArm_sfcn_DWORK7);
/* DWORK8 */
ssSetDWorkWidth(rts, 8, 1);
ssSetDWorkDataType(rts, 8,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 8, 0);
ssSetDWorkUsedAsDState(rts, 8, 1);
ssSetDWork(rts, 8, &RA4_student_DW.RobotArm_sfcn_DWORK8);
/* DWORK9 */
ssSetDWorkWidth(rts, 9, 1);
ssSetDWorkDataType(rts, 9,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 9, 0);
ssSetDWorkUsedAsDState(rts, 9, 1);
ssSetDWork(rts, 9, &RA4_student_DW.RobotArm_sfcn_DWORK9);
/* DWORK10 */
ssSetDWorkWidth(rts, 10, 1);
ssSetDWorkDataType(rts, 10,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 10, 0);
ssSetDWork(rts, 10, &RA4_student_DW.RobotArm_sfcn_DWORK10);
/* DWORK11 */
ssSetDWorkWidth(rts, 11, 1);
ssSetDWorkDataType(rts, 11,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 11, 0);
ssSetDWork(rts, 11, &RA4_student_DW.RobotArm_sfcn_DWORK11);
/* DWORK12 */
ssSetDWorkWidth(rts, 12, 1);
ssSetDWorkDataType(rts, 12,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 12, 0);
ssSetDWork(rts, 12, &RA4_student_DW.RobotArm_sfcn_DWORK12);
/* DWORK13 */
ssSetDWorkWidth(rts, 13, 1);
ssSetDWorkDataType(rts, 13,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 13, 0);
ssSetDWork(rts, 13, &RA4_student_DW.RobotArm_sfcn_DWORK13);
/* DWORK14 */
ssSetDWorkWidth(rts, 14, 1);
ssSetDWorkDataType(rts, 14,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 14, 0);
ssSetDWork(rts, 14, &RA4_student_DW.RobotArm_sfcn_DWORK14);
/* DWORK15 */
ssSetDWorkWidth(rts, 15, 1);
ssSetDWorkDataType(rts, 15,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 15, 0);
ssSetDWork(rts, 15, &RA4_student_DW.RobotArm_sfcn_DWORK15);
/* DWORK16 */
ssSetDWorkWidth(rts, 16, 2);
ssSetDWorkDataType(rts, 16,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 16, 0);
ssSetDWork(rts, 16, &RA4_student_DW.RobotArm_sfcn_DWORK16[0]);
/* DWORK17 */
ssSetDWorkWidth(rts, 17, 2);
ssSetDWorkDataType(rts, 17,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 17, 0);
ssSetDWork(rts, 17, &RA4_student_DW.RobotArm_sfcn_DWORK17[0]);
/* DWORK18 */
ssSetDWorkWidth(rts, 18, 4);
ssSetDWorkDataType(rts, 18,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 18, 0);
ssSetDWork(rts, 18, &RA4_student_DW.RobotArm_sfcn_DWORK18[0]);
/* DWORK19 */
ssSetDWorkWidth(rts, 19, 4);
ssSetDWorkDataType(rts, 19,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 19, 0);
ssSetDWork(rts, 19, &RA4_student_DW.RobotArm_sfcn_DWORK19[0]);
/* DWORK20 */
ssSetDWorkWidth(rts, 20, 2);
ssSetDWorkDataType(rts, 20,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 20, 0);
ssSetDWork(rts, 20, &RA4_student_DW.RobotArm_sfcn_DWORK20[0]);
/* DWORK21 */
ssSetDWorkWidth(rts, 21, 4);
ssSetDWorkDataType(rts, 21,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 21, 0);
ssSetDWork(rts, 21, &RA4_student_DW.RobotArm_sfcn_DWORK21[0]);
/* DWORK22 */
ssSetDWorkWidth(rts, 22, 4);
ssSetDWorkDataType(rts, 22,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 22, 0);
ssSetDWork(rts, 22, &RA4_student_DW.RobotArm_sfcn_DWORK22[0]);
/* DWORK23 */
ssSetDWorkWidth(rts, 23, 2);
ssSetDWorkDataType(rts, 23,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 23, 0);
ssSetDWork(rts, 23, &RA4_student_DW.RobotArm_sfcn_DWORK23[0]);
/* DWORK24 */
ssSetDWorkWidth(rts, 24, 2);
ssSetDWorkDataType(rts, 24,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 24, 0);
ssSetDWork(rts, 24, &RA4_student_DW.RobotArm_sfcn_DWORK24[0]);
/* DWORK25 */
ssSetDWorkWidth(rts, 25, 4);
ssSetDWorkDataType(rts, 25,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 25, 0);
ssSetDWork(rts, 25, &RA4_student_DW.RobotArm_sfcn_DWORK25[0]);
/* DWORK26 */
ssSetDWorkWidth(rts, 26, 4);
ssSetDWorkDataType(rts, 26,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 26, 0);
ssSetDWork(rts, 26, &RA4_student_DW.RobotArm_sfcn_DWORK26[0]);
/* DWORK27 */
ssSetDWorkWidth(rts, 27, 2);
ssSetDWorkDataType(rts, 27,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 27, 0);
ssSetDWork(rts, 27, &RA4_student_DW.RobotArm_sfcn_DWORK27[0]);
/* DWORK28 */
ssSetDWorkWidth(rts, 28, 4);
ssSetDWorkDataType(rts, 28,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 28, 0);
ssSetDWork(rts, 28, &RA4_student_DW.RobotArm_sfcn_DWORK28[0]);
/* DWORK29 */
ssSetDWorkWidth(rts, 29, 4);
ssSetDWorkDataType(rts, 29,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 29, 0);
ssSetDWork(rts, 29, &RA4_student_DW.RobotArm_sfcn_DWORK29[0]);
/* DWORK30 */
ssSetDWorkWidth(rts, 30, 2);
ssSetDWorkDataType(rts, 30,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 30, 0);
ssSetDWork(rts, 30, &RA4_student_DW.RobotArm_sfcn_DWORK30[0]);
/* DWORK31 */
ssSetDWorkWidth(rts, 31, 2);
ssSetDWorkDataType(rts, 31,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 31, 0);
ssSetDWork(rts, 31, &RA4_student_DW.RobotArm_sfcn_DWORK31[0]);
/* DWORK32 */
ssSetDWorkWidth(rts, 32, 4);
ssSetDWorkDataType(rts, 32,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 32, 0);
ssSetDWork(rts, 32, &RA4_student_DW.RobotArm_sfcn_DWORK32[0]);
/* DWORK33 */
ssSetDWorkWidth(rts, 33, 4);
ssSetDWorkDataType(rts, 33,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 33, 0);
ssSetDWork(rts, 33, &RA4_student_DW.RobotArm_sfcn_DWORK33[0]);
/* DWORK34 */
ssSetDWorkWidth(rts, 34, 2);
ssSetDWorkDataType(rts, 34,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 34, 0);
ssSetDWork(rts, 34, &RA4_student_DW.RobotArm_sfcn_DWORK34[0]);
/* DWORK35 */
ssSetDWorkWidth(rts, 35, 4);
ssSetDWorkDataType(rts, 35,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 35, 0);
ssSetDWork(rts, 35, &RA4_student_DW.RobotArm_sfcn_DWORK35[0]);
/* DWORK36 */
ssSetDWorkWidth(rts, 36, 4);
ssSetDWorkDataType(rts, 36,SS_DOUBLE);
ssSetDWorkComplexSignal(rts, 36, 0);
ssSetDWork(rts, 36, &RA4_student_DW.RobotArm_sfcn_DWORK36[0]);
/* DWORK37 */
ssSetDWorkWidth(rts, 37, 1);
ssSetDWorkDataType(rts, 37,SS_INT32);
ssSetDWorkComplexSignal(rts, 37, 0);
ssSetDWork(rts, 37, &RA4_student_DW.RobotArm_sfcn_DWORK37);
/* DWORK38 */
ssSetDWorkWidth(rts, 38, 1);
ssSetDWorkDataType(rts, 38,SS_UINT16);
ssSetDWorkComplexSignal(rts, 38, 0);
ssSetDWork(rts, 38, &RA4_student_DW.RobotArm_sfcn_DWORK38);
/* DWORK39 */
ssSetDWorkWidth(rts, 39, 1);
ssSetDWorkDataType(rts, 39,SS_UINT16);
ssSetDWorkComplexSignal(rts, 39, 0);
ssSetDWork(rts, 39, &RA4_student_DW.RobotArm_sfcn_DWORK39);
/* DWORK40 */
ssSetDWorkWidth(rts, 40, 1);
ssSetDWorkDataType(rts, 40,SS_UINT16);
ssSetDWorkComplexSignal(rts, 40, 0);
ssSetDWork(rts, 40, &RA4_student_DW.RobotArm_sfcn_DWORK40);
/* DWORK41 */
ssSetDWorkWidth(rts, 41, 1);
ssSetDWorkDataType(rts, 41,SS_UINT8);
ssSetDWorkComplexSignal(rts, 41, 0);
ssSetDWork(rts, 41, &RA4_student_DW.RobotArm_sfcn_DWORK41);
/* DWORK42 */
ssSetDWorkWidth(rts, 42, 1);
ssSetDWorkDataType(rts, 42,SS_UINT8);
ssSetDWorkComplexSignal(rts, 42, 0);
ssSetDWork(rts, 42, &RA4_student_DW.RobotArm_sfcn_DWORK42);
/* DWORK43 */
ssSetDWorkWidth(rts, 43, 1);
ssSetDWorkDataType(rts, 43,SS_UINT8);
ssSetDWorkComplexSignal(rts, 43, 0);
ssSetDWork(rts, 43, &RA4_student_DW.RobotArm_sfcn_DWORK43);
/* DWORK44 */
ssSetDWorkWidth(rts, 44, 1);
ssSetDWorkDataType(rts, 44,SS_UINT8);
ssSetDWorkComplexSignal(rts, 44, 0);
ssSetDWork(rts, 44, &RA4_student_DW.RobotArm_sfcn_DWORK44);
/* DWORK45 */
ssSetDWorkWidth(rts, 45, 1);
ssSetDWorkDataType(rts, 45,SS_UINT8);
ssSetDWorkComplexSignal(rts, 45, 0);
ssSetDWork(rts, 45, &RA4_student_DW.RobotArm_sfcn_DWORK45);
/* DWORK46 */
ssSetDWorkWidth(rts, 46, 1);
ssSetDWorkDataType(rts, 46,SS_UINT8);
ssSetDWorkComplexSignal(rts, 46, 0);
ssSetDWork(rts, 46, &RA4_student_DW.RobotArm_sfcn_DWORK46);
}
/* registration */
Robot_sf(rts);
sfcnInitializeSizes(rts);
sfcnInitializeSampleTimes(rts);
/* adjust sample time */
ssSetSampleTime(rts, 0, 0.0);
ssSetOffsetTime(rts, 0, 0.0);
ssSetSampleTime(rts, 1, 0.000244140625);
ssSetOffsetTime(rts, 1, 0.0);
sfcnTsMap[0] = 0;
sfcnTsMap[1] = 1;
/* set compiled values of dynamic vector attributes */
ssSetNumNonsampledZCs(rts, 0);
/* Update connectivity flags for each port */
_ssSetInputPortConnected(rts, 0, 1);
_ssSetInputPortConnected(rts, 1, 1);
_ssSetOutputPortConnected(rts, 0, 1);
_ssSetOutputPortConnected(rts, 1, 1);
_ssSetOutputPortConnected(rts, 2, 1);
_ssSetOutputPortConnected(rts, 3, 1);
_ssSetOutputPortBeingMerged(rts, 0, 0);
_ssSetOutputPortBeingMerged(rts, 1, 0);
_ssSetOutputPortBeingMerged(rts, 2, 0);
_ssSetOutputPortBeingMerged(rts, 3, 0);
/* Update the BufferDstPort flags for each input port */
ssSetInputPortBufferDstPort(rts, 0, -1);
ssSetInputPortBufferDstPort(rts, 1, -1);
/* Instance data for generated S-Function: Robot */
#include "Robot_sfcn_rtw/Robot_sid.h"
}
}
/* Initialize Sizes */
RA4_student_M->Sizes.numContStates = (0);/* Number of continuous states */
RA4_student_M->Sizes.numY = (0); /* Number of model outputs */
RA4_student_M->Sizes.numU = (0); /* Number of model inputs */
RA4_student_M->Sizes.sysDirFeedThru = (0);/* The model is not direct feedthrough */
RA4_student_M->Sizes.numSampTimes = (2);/* Number of sample times */
RA4_student_M->Sizes.numBlocks = (24);/* Number of blocks */
RA4_student_M->Sizes.numBlockIO = (11);/* Number of block outputs */
RA4_student_M->Sizes.numBlockPrms = (16);/* Sum of parameter "widths" */
return RA4_student_M;
}
/* 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);
}
}
}
/* Model initialize function */
void Hammerstein_initialize(void)
{
/* Registration code */
/* initialize non-finites */
rt_InitInfAndNaN(sizeof(real_T));
/* initialize real-time model */
(void) memset((void *)Hammerstein_M, 0,
sizeof(RT_MODEL_Hammerstein));
rtsiSetSolverName(&Hammerstein_M->solverInfo,"FixedStepDiscrete");
Hammerstein_M->solverInfoPtr = (&Hammerstein_M->solverInfo);
/* Initialize timing info */
{
int_T *mdlTsMap = Hammerstein_M->Timing.sampleTimeTaskIDArray;
mdlTsMap[0] = 0;
Hammerstein_M->Timing.sampleTimeTaskIDPtr = (&mdlTsMap[0]);
Hammerstein_M->Timing.sampleTimes = (&Hammerstein_M->
Timing.sampleTimesArray[0]);
Hammerstein_M->Timing.offsetTimes = (&Hammerstein_M->
Timing.offsetTimesArray[0]);
/* task periods */
Hammerstein_M->Timing.sampleTimes[0] = (0.06);
/* task offsets */
Hammerstein_M->Timing.offsetTimes[0] = (0.0);
}
rtmSetTPtr(Hammerstein_M, &Hammerstein_M->Timing.tArray[0]);
{
int_T *mdlSampleHits = Hammerstein_M->Timing.sampleHitArray;
mdlSampleHits[0] = 1;
Hammerstein_M->Timing.sampleHits = (&mdlSampleHits[0]);
}
rtmSetTFinal(Hammerstein_M, 9.9599999999999991);
Hammerstein_M->Timing.stepSize0 = 0.06;
/* Setup for data logging */
{
static RTWLogInfo rt_DataLoggingInfo;
Hammerstein_M->rtwLogInfo = &rt_DataLoggingInfo;
}
/* Setup for data logging */
{
rtliSetLogXSignalInfo(Hammerstein_M->rtwLogInfo, (NULL));
rtliSetLogXSignalPtrs(Hammerstein_M->rtwLogInfo, (NULL));
rtliSetLogT(Hammerstein_M->rtwLogInfo, "tout");
rtliSetLogX(Hammerstein_M->rtwLogInfo, "");
rtliSetLogXFinal(Hammerstein_M->rtwLogInfo, "");
rtliSetSigLog(Hammerstein_M->rtwLogInfo, "");
rtliSetLogVarNameModifier(Hammerstein_M->rtwLogInfo, "rt_");
rtliSetLogFormat(Hammerstein_M->rtwLogInfo, 0);
rtliSetLogMaxRows(Hammerstein_M->rtwLogInfo, 1000);
rtliSetLogDecimation(Hammerstein_M->rtwLogInfo, 1);
/*
* Set pointers to the data and signal info for each output
*/
{
static void * rt_LoggedOutputSignalPtrs[] = {
&Hammerstein_Y.Out1
};
rtliSetLogYSignalPtrs(Hammerstein_M->rtwLogInfo, ((LogSignalPtrsType)
rt_LoggedOutputSignalPtrs));
}
{
static int_T rt_LoggedOutputWidths[] = {
1
};
static int_T rt_LoggedOutputNumDimensions[] = {
1
};
static int_T rt_LoggedOutputDimensions[] = {
1
};
static boolean_T rt_LoggedOutputIsVarDims[] = {
0
};
static void* rt_LoggedCurrentSignalDimensions[] = {
(NULL)
};
static int_T rt_LoggedCurrentSignalDimensionsSize[] = {
4
};
static BuiltInDTypeId rt_LoggedOutputDataTypeIds[] = {
SS_DOUBLE
};
static int_T rt_LoggedOutputComplexSignals[] = {
0
};
static const char_T *rt_LoggedOutputLabels[] = {
"" };
static const char_T *rt_LoggedOutputBlockNames[] = {
"Hammerstein/Out1" };
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_LoggedCurrentSignalDimensionsSize,
rt_LoggedOutputDataTypeIds,
rt_LoggedOutputComplexSignals,
(NULL),
{ rt_LoggedOutputLabels },
(NULL),
(NULL),
(NULL),
{ rt_LoggedOutputBlockNames },
{ (NULL) },
(NULL),
rt_RTWLogDataTypeConvert
}
};
rtliSetLogYSignalInfo(Hammerstein_M->rtwLogInfo, rt_LoggedOutputSignalInfo);
/* set currSigDims field */
rt_LoggedCurrentSignalDimensions[0] = &rt_LoggedOutputWidths[0];
}
rtliSetLogY(Hammerstein_M->rtwLogInfo, "yout");
}
Hammerstein_M->solverInfoPtr = (&Hammerstein_M->solverInfo);
Hammerstein_M->Timing.stepSize = (0.06);
rtsiSetFixedStepSize(&Hammerstein_M->solverInfo, 0.06);
rtsiSetSolverMode(&Hammerstein_M->solverInfo, SOLVER_MODE_SINGLETASKING);
/* block I/O */
(void) memset(((void *) &Hammerstein_B), 0,
sizeof(BlockIO_Hammerstein));
/* states (dwork) */
(void) memset((void *)&Hammerstein_DWork, 0,
sizeof(D_Work_Hammerstein));
/* external inputs */
Hammerstein_U.In1 = 0.0;
/* external outputs */
Hammerstein_Y.Out1 = 0.0;
/* child S-Function registration */
{
RTWSfcnInfo *sfcnInfo = &Hammerstein_M->NonInlinedSFcns.sfcnInfo;
Hammerstein_M->sfcnInfo = (sfcnInfo);
rtssSetErrorStatusPtr(sfcnInfo, (&rtmGetErrorStatus(Hammerstein_M)));
rtssSetNumRootSampTimesPtr(sfcnInfo, &Hammerstein_M->Sizes.numSampTimes);
Hammerstein_M->NonInlinedSFcns.taskTimePtrs[0] = &(rtmGetTPtr(Hammerstein_M)
[0]);
rtssSetTPtrPtr(sfcnInfo,Hammerstein_M->NonInlinedSFcns.taskTimePtrs);
rtssSetTStartPtr(sfcnInfo, &rtmGetTStart(Hammerstein_M));
rtssSetTFinalPtr(sfcnInfo, &rtmGetTFinal(Hammerstein_M));
rtssSetTimeOfLastOutputPtr(sfcnInfo, &rtmGetTimeOfLastOutput(Hammerstein_M));
rtssSetStepSizePtr(sfcnInfo, &Hammerstein_M->Timing.stepSize);
rtssSetStopRequestedPtr(sfcnInfo, &rtmGetStopRequested(Hammerstein_M));
rtssSetDerivCacheNeedsResetPtr(sfcnInfo,
&Hammerstein_M->ModelData.derivCacheNeedsReset);
rtssSetZCCacheNeedsResetPtr(sfcnInfo,
&Hammerstein_M->ModelData.zCCacheNeedsReset);
rtssSetBlkStateChangePtr(sfcnInfo, &Hammerstein_M->ModelData.blkStateChange);
rtssSetSampleHitsPtr(sfcnInfo, &Hammerstein_M->Timing.sampleHits);
rtssSetPerTaskSampleHitsPtr(sfcnInfo,
&Hammerstein_M->Timing.perTaskSampleHits);
rtssSetSimModePtr(sfcnInfo, &Hammerstein_M->simMode);
rtssSetSolverInfoPtr(sfcnInfo, &Hammerstein_M->solverInfoPtr);
}
Hammerstein_M->Sizes.numSFcns = (2);
/* register each child */
{
(void) memset((void *)&Hammerstein_M->NonInlinedSFcns.childSFunctions[0], 0,
2*sizeof(SimStruct));
Hammerstein_M->childSfunctions =
(&Hammerstein_M->NonInlinedSFcns.childSFunctionPtrs[0]);
Hammerstein_M->childSfunctions[0] =
(&Hammerstein_M->NonInlinedSFcns.childSFunctions[0]);
Hammerstein_M->childSfunctions[1] =
(&Hammerstein_M->NonInlinedSFcns.childSFunctions[1]);
/* Level2 S-Function Block: Hammerstein/<S1>/Pwlinear1 (sfunpwlinear) */
{
SimStruct *rts = Hammerstein_M->childSfunctions[0];
/* timing info */
time_T *sfcnPeriod = Hammerstein_M->NonInlinedSFcns.Sfcn0.sfcnPeriod;
time_T *sfcnOffset = Hammerstein_M->NonInlinedSFcns.Sfcn0.sfcnOffset;
int_T *sfcnTsMap = Hammerstein_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, &Hammerstein_M->NonInlinedSFcns.blkInfo2[0]);
}
ssSetRTWSfcnInfo(rts, Hammerstein_M->sfcnInfo);
/* Allocate memory of model methods 2 */
{
ssSetModelMethods2(rts, &Hammerstein_M->NonInlinedSFcns.methods2[0]);
}
/* Allocate memory of model methods 3 */
{
ssSetModelMethods3(rts, &Hammerstein_M->NonInlinedSFcns.methods3[0]);
}
/* Allocate memory for states auxilliary information */
{
ssSetStatesInfo2(rts, &Hammerstein_M->NonInlinedSFcns.statesInfo2[0]);
}
/* inputs */
{
_ssSetNumInputPorts(rts, 1);
ssSetPortInfoForInputs(rts,
&Hammerstein_M->NonInlinedSFcns.Sfcn0.inputPortInfo[0]);
/* port 0 */
{
ssSetInputPortRequiredContiguous(rts, 0, 1);
ssSetInputPortSignal(rts, 0, &Hammerstein_B.LinearModel);
_ssSetInputPortNumDimensions(rts, 0, 1);
ssSetInputPortWidth(rts, 0, 1);
}
}
/* outputs */
{
ssSetPortInfoForOutputs(rts,
&Hammerstein_M->NonInlinedSFcns.Sfcn0.outputPortInfo[0]);
_ssSetNumOutputPorts(rts, 1);
/* port 0 */
{
_ssSetOutputPortNumDimensions(rts, 0, 1);
ssSetOutputPortWidth(rts, 0, 1);
ssSetOutputPortSignal(rts, 0, ((real_T *) &Hammerstein_Y.Out1));
}
}
/* path info */
ssSetModelName(rts, "Pwlinear1");
ssSetPath(rts, "Hammerstein/Hammerstein-Wiener Model1/Pwlinear1");
ssSetRTModel(rts,Hammerstein_M);
ssSetParentSS(rts, (NULL));
ssSetRootSS(rts, rts);
ssSetVersion(rts, SIMSTRUCT_VERSION_LEVEL2);
/* parameters */
{
mxArray **sfcnParams = (mxArray **)
&Hammerstein_M->NonInlinedSFcns.Sfcn0.params;
ssSetSFcnParamsCount(rts, 7);
ssSetSFcnParamsPtr(rts, &sfcnParams[0]);
ssSetSFcnParam(rts, 0, (mxArray*)Hammerstein_P.Pwlinear1_P1_Size);
ssSetSFcnParam(rts, 1, (mxArray*)Hammerstein_P.Pwlinear1_P2_Size);
ssSetSFcnParam(rts, 2, (mxArray*)Hammerstein_P.Pwlinear1_P3_Size);
ssSetSFcnParam(rts, 3, (mxArray*)Hammerstein_P.Pwlinear1_P4_Size);
ssSetSFcnParam(rts, 4, (mxArray*)Hammerstein_P.Pwlinear1_P5_Size);
ssSetSFcnParam(rts, 5, (mxArray*)Hammerstein_P.Pwlinear1_P6_Size);
ssSetSFcnParam(rts, 6, (mxArray*)Hammerstein_P.Pwlinear1_P7_Size);
}
/* registration */
sfunpwlinear(rts);
sfcnInitializeSizes(rts);
sfcnInitializeSampleTimes(rts);
/* adjust sample time */
ssSetSampleTime(rts, 0, 0.06);
ssSetOffsetTime(rts, 0, 0.0);
sfcnTsMap[0] = 0;
/* set compiled values of dynamic vector attributes */
ssSetNumNonsampledZCs(rts, 0);
/* Update connectivity flags for each port */
_ssSetInputPortConnected(rts, 0, 1);
_ssSetOutputPortConnected(rts, 0, 1);
_ssSetOutputPortBeingMerged(rts, 0, 0);
/* Update the BufferDstPort flags for each input port */
ssSetInputPortBufferDstPort(rts, 0, -1);
}
/* Level2 S-Function Block: Hammerstein/<S1>/Pwlinear (sfunpwlinear) */
{
SimStruct *rts = Hammerstein_M->childSfunctions[1];
/* timing info */
time_T *sfcnPeriod = Hammerstein_M->NonInlinedSFcns.Sfcn1.sfcnPeriod;
time_T *sfcnOffset = Hammerstein_M->NonInlinedSFcns.Sfcn1.sfcnOffset;
int_T *sfcnTsMap = Hammerstein_M->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, &Hammerstein_M->NonInlinedSFcns.blkInfo2[1]);
}
ssSetRTWSfcnInfo(rts, Hammerstein_M->sfcnInfo);
/* Allocate memory of model methods 2 */
{
ssSetModelMethods2(rts, &Hammerstein_M->NonInlinedSFcns.methods2[1]);
}
/* Allocate memory of model methods 3 */
{
ssSetModelMethods3(rts, &Hammerstein_M->NonInlinedSFcns.methods3[1]);
}
/* Allocate memory for states auxilliary information */
{
ssSetStatesInfo2(rts, &Hammerstein_M->NonInlinedSFcns.statesInfo2[1]);
}
/* inputs */
{
_ssSetNumInputPorts(rts, 1);
ssSetPortInfoForInputs(rts,
&Hammerstein_M->NonInlinedSFcns.Sfcn1.inputPortInfo[0]);
/* port 0 */
{
ssSetInputPortRequiredContiguous(rts, 0, 1);
ssSetInputPortSignal(rts, 0, &Hammerstein_U.In1);
_ssSetInputPortNumDimensions(rts, 0, 1);
ssSetInputPortWidth(rts, 0, 1);
}
}
/* outputs */
{
ssSetPortInfoForOutputs(rts,
&Hammerstein_M->NonInlinedSFcns.Sfcn1.outputPortInfo[0]);
_ssSetNumOutputPorts(rts, 1);
/* port 0 */
{
_ssSetOutputPortNumDimensions(rts, 0, 1);
ssSetOutputPortWidth(rts, 0, 1);
ssSetOutputPortSignal(rts, 0, ((real_T *) &Hammerstein_B.Pwlinear));
}
}
/* path info */
ssSetModelName(rts, "Pwlinear");
ssSetPath(rts, "Hammerstein/Hammerstein-Wiener Model1/Pwlinear");
ssSetRTModel(rts,Hammerstein_M);
ssSetParentSS(rts, (NULL));
ssSetRootSS(rts, rts);
ssSetVersion(rts, SIMSTRUCT_VERSION_LEVEL2);
/* parameters */
{
mxArray **sfcnParams = (mxArray **)
&Hammerstein_M->NonInlinedSFcns.Sfcn1.params;
ssSetSFcnParamsCount(rts, 7);
ssSetSFcnParamsPtr(rts, &sfcnParams[0]);
ssSetSFcnParam(rts, 0, (mxArray*)Hammerstein_P.Pwlinear_P1_Size);
ssSetSFcnParam(rts, 1, (mxArray*)Hammerstein_P.Pwlinear_P2_Size);
ssSetSFcnParam(rts, 2, (mxArray*)Hammerstein_P.Pwlinear_P3_Size);
ssSetSFcnParam(rts, 3, (mxArray*)Hammerstein_P.Pwlinear_P4_Size);
ssSetSFcnParam(rts, 4, (mxArray*)Hammerstein_P.Pwlinear_P5_Size);
ssSetSFcnParam(rts, 5, (mxArray*)Hammerstein_P.Pwlinear_P6_Size);
ssSetSFcnParam(rts, 6, (mxArray*)Hammerstein_P.Pwlinear_P7_Size);
}
/* registration */
sfunpwlinear(rts);
sfcnInitializeSizes(rts);
sfcnInitializeSampleTimes(rts);
/* adjust sample time */
ssSetSampleTime(rts, 0, 0.06);
ssSetOffsetTime(rts, 0, 0.0);
sfcnTsMap[0] = 0;
/* set compiled values of dynamic vector attributes */
ssSetNumNonsampledZCs(rts, 0);
/* Update connectivity flags for each port */
_ssSetInputPortConnected(rts, 0, 1);
_ssSetOutputPortConnected(rts, 0, 1);
_ssSetOutputPortBeingMerged(rts, 0, 0);
/* Update the BufferDstPort flags for each input port */
ssSetInputPortBufferDstPort(rts, 0, -1);
}
}
/* Matfile logging */
rt_StartDataLoggingWithStartTime(Hammerstein_M->rtwLogInfo, 0.0, rtmGetTFinal
(Hammerstein_M), Hammerstein_M->Timing.stepSize0, (&rtmGetErrorStatus
(Hammerstein_M)));
/* Level2 S-Function Block: '<S1>/Pwlinear1' (sfunpwlinear) */
{
SimStruct *rts = Hammerstein_M->childSfunctions[0];
sfcnStart(rts);
if (ssGetErrorStatus(rts) != (NULL))
return;
}
/* Level2 S-Function Block: '<S1>/Pwlinear' (sfunpwlinear) */
{
SimStruct *rts = Hammerstein_M->childSfunctions[1];
sfcnStart(rts);
if (ssGetErrorStatus(rts) != (NULL))
return;
}
/* InitializeConditions for DiscreteStateSpace: '<S1>/LinearModel' */
Hammerstein_DWork.LinearModel_DSTATE = Hammerstein_P.LinearModel_X0;
/* Level2 S-Function Block: '<S1>/Pwlinear1' (sfunpwlinear) */
{
SimStruct *rts = Hammerstein_M->childSfunctions[0];
sfcnInitializeConditions(rts);
if (ssGetErrorStatus(rts) != (NULL))
return;
}
/* Level2 S-Function Block: '<S1>/Pwlinear' (sfunpwlinear) */
{
SimStruct *rts = Hammerstein_M->childSfunctions[1];
sfcnInitializeConditions(rts);
if (ssGetErrorStatus(rts) != (NULL))
return;
}
}