Error occurred while executing External Mode MEX-file 'rtwinext': Error loading real-time image: undefined symbol "FAST_Sizes"

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David Kenko
David Kenko 2016 年 9 月 15 日
コメント済み: yue 2021 年 6 月 3 日
Dear all,
I want to simulate a S-Function Modell in Simulink External Mode. The s-function is working well in Normal mode but when i switch to external mode using SImulink Deslktop Real-Time it show the following error:
Error occurred while executing External Mode MEX-file 'rtwinext':
Error loading real-time image: undefined symbol "FAST_Sizes"
This is my C-Function
/*
* TEMPLATE File: sfuntmpl_gate_fortran.c
* TEMPLATE Copyright 1990-2013 The MathWorks, Inc.
*
* Modified by B. Jonkman, National Renewable Energy Laboratory
* for use with FAST v8
* 20-Jan-2015
*/
/*
* You must specify the S_FUNCTION_NAME as the name of your S-function
* (i.e. replace sfungate with the name of your S-function, which has
* to match the name of the final mex file, e.g., if the S_FUNCTION_NAME
* is my_sfuntmpl_gate_fortran, the mex filename will have to be
* my_sfuntmpl_gate_fortran.mexXXX where XXX is the 3 letter
* mex extension code for your platform).
*/
#define S_FUNCTION_LEVEL 2
#define S_FUNCTION_NAME FAST_SFunc
/*
* Need to include simstruc.h for the definition of the SimStruct and
* its associated macro definitions.
*/
#include "simstruc.h"
// #include "mex.h" // for mexPutVariable
// #include "matrix.h" // for mxCreateDoubleScalar
#include "FAST_Library.h"
#define PARAM_FILENAME 0
#define PARAM_TMAX 1
#define PARAM_ADDINPUTS 2
#define NUM_PARAM 3
// two DWork arrays:
#define WORKARY_OUTPUT 0
#define WORKARY_INPUT 1
static double dt = 0;
static double TMax = 0;
static int NumInputs = NumFixedInputs;
static int NumAddInputs = 0; // number of additional inputs
static int NumOutputs = 1;
static int ErrStat = 0;
static char ErrMsg[INTERFACE_STRING_LENGTH]; // make sure this is the same size as IntfStrLen in FAST_Library.f90
static char InputFileName[INTERFACE_STRING_LENGTH]; // make sure this is the same size as IntfStrLen in FAST_Library.f90
static int n_t_global = -2; // counter to determine which fixed-step simulation time we are at currently (start at -2 for initialization)
// function definitions
static int checkError(SimStruct *S);
static void mdlTerminate(SimStruct *S); // defined here so I can call it from checkError
static void getInputs(SimStruct *S, double *InputAry);
static void setOutputs(SimStruct *S, double *OutputAry);
/* Error handling
* --------------
*
* You should use the following technique to report errors encountered within
* an S-function:
*
* ssSetErrorStatus(S,"Error encountered due to ...");
* return;
*
* Note that the 2nd argument to ssSetErrorStatus must be persistent memory.
* It cannot be a local variable.
*/
static int
checkError(SimStruct *S){
if (ErrStat >= AbortErrLev){
ssPrintf("\n");
ssSetErrorStatus(S, ErrMsg);
mdlTerminate(S); // terminate on error (in case Simulink doesn't do so itself)
return 1;
}
else if (ErrStat >= ErrID_Warn){
ssPrintf("\n");
ssWarning(S, ErrMsg);
}
else if (ErrStat != ErrID_None){
ssPrintf("\n%s\n", ErrMsg);
}
return 0;
}
static void
getInputs(SimStruct *S, double *InputAry){
int k;
InputRealPtrsType uPtrs = ssGetInputPortRealSignalPtrs(S, 0);
for (k = 0; k < ssGetDWorkWidth(S, WORKARY_INPUT); k++) {
InputAry[k] = (double)(*uPtrs[k]);
}
}
static void
setOutputs(SimStruct *S, double *OutputAry){
int k;
double *y = ssGetOutputPortRealSignal(S, 0);
for (k = 0; k < ssGetOutputPortWidth(S, WORKARY_OUTPUT); k++) {
y[k] = OutputAry[k];
}
}
/*====================*
* S-function methods *
*====================*/
/* Function: mdlInitializeSizes ===============================================
* Abstract:
* The sizes information is used by Simulink to determine the S-function
* block's characteristics (number of inputs, outputs, states, etc.).
*/
static void mdlInitializeSizes(SimStruct *S)
{
int i = 0;
int j = 0;
int k = 0;
static char ChannelNames[CHANNEL_LENGTH * MAXIMUM_OUTPUTS + 1];
static double InitInputAry[MAXInitINPUTS];
//static char OutList[MAXIMUM_OUTPUTS][CHANNEL_LENGTH + 1];
static char OutList[CHANNEL_LENGTH + 1];
double *AdditionalInitInputs;
mxArray *pm, *chrAry;
mwSize m, n;
mwIndex indx;
if (n_t_global == -2) {
/* Expected S-Function Input Parameter(s) */
ssSetNumSFcnParams(S, NUM_PARAM); /* Number of expected parameters */
if (ssGetNumSFcnParams(S) != ssGetSFcnParamsCount(S)) {
/* Return if number of expected != number of actual parameters */
return;
}
// The parameters should not be changed during the course of a simulation
ssSetSFcnParamTunable(S, PARAM_FILENAME, SS_PRM_NOT_TUNABLE);
mxGetString(ssGetSFcnParam(S, PARAM_FILENAME), InputFileName, INTERFACE_STRING_LENGTH);
ssSetSFcnParamTunable(S, PARAM_TMAX, SS_PRM_NOT_TUNABLE);
TMax = mxGetScalar(ssGetSFcnParam(S, PARAM_TMAX));
ssSetSFcnParamTunable(S, PARAM_ADDINPUTS, SS_PRM_NOT_TUNABLE);
NumAddInputs = (int)(mxGetScalar(ssGetSFcnParam(S, PARAM_ADDINPUTS)) + 0.5); // add 0.5 for rounding from double
if (NumAddInputs < 0){
ErrStat = ErrID_Fatal;
strcpy(ErrMsg, "Parameter specifying number of additional inputs to the FAST SFunc must not be negative.\n");
checkError(S);
return;
}
NumInputs = NumFixedInputs + NumAddInputs;
// now see if there are other inputs that need to be processed...
if (NumAddInputs > 0){
k = (int)mxGetNumberOfElements(ssGetSFcnParam(S, PARAM_ADDINPUTS));
// k = min( k , MAXInitINPUTS );
AdditionalInitInputs = (double *)mxGetData(ssGetSFcnParam(S, PARAM_ADDINPUTS));
for (i = 0; i < k; i++){
InitInputAry[i] = AdditionalInitInputs[i + 1];
}
}
else{
InitInputAry[0] = SensorType_None; // tell it not to use lidar (shouldn't be necessary, but we'll cover our bases)
}
// set this before possibility of error in Fortran library:
ssSetOptions(S,
SS_OPTION_CALL_TERMINATE_ON_EXIT);
/* --------------------------------------------- */
// strcpy(InputFileName, "../../CertTest/Test01.fst");
FAST_Sizes(&TMax, InitInputAry, InputFileName, &AbortErrLev, &NumOutputs, &dt, &ErrStat, ErrMsg, ChannelNames);
n_t_global = -1;
if (checkError(S)) return;
// set DT in the Matlab workspace (necessary for Simulink block solver options)
pm = mxCreateDoubleScalar(dt);
ErrStat = mexPutVariable("base", "DT", pm);
mxDestroyArray(pm);
if (ErrStat != 0){
ErrStat = ErrID_Fatal;
strcpy(ErrMsg, "Error copying string array to 'DT' variable in the base Matlab workspace.");
checkError(S);
return;
}
// put the names of the output channels in a cell-array variable called "OutList" in the base matlab workspace
/* m = NumOutputs;
n = 1;
//pm = mxCreateCellMatrix(m, n);
pm = mxCreateDoubleMatrix(m, n, mxREAL);
for (i = 0; i < NumOutputs; i++){
j = CHANNEL_LENGTH - 1;
while (ChannelNames[i*CHANNEL_LENGTH + j] == ' '){
j--;
}
strncpy(&OutList[0], &ChannelNames[i*CHANNEL_LENGTH], j+1);
OutList[j + 1] = '\0';
chrAry = mxCreateString(OutList);
indx = i;
mxGetPr(pm, indx, chrAry);
//mxSetCell(pm, indx, chrAry);
//mxDestroyArray(chrAry);
}
ErrStat = mexPutVariable("base", "OutList", pm);
mxDestroyArray(pm);
*/
if (ErrStat != 0){
ErrStat = ErrID_Fatal;
strcpy(ErrMsg, "Error copying string array to 'OutList' variable in the base Matlab workspace.");
checkError(S);
return;
}
// ---------------------------------------------
ssSetNumContStates(S, 0); /* how many continuous states? */
ssSetNumDiscStates(S, 0); /* how many discrete states?*/
/* sets input port characteristics */
if (!ssSetNumInputPorts(S, 1)) return;
ssSetInputPortWidth(S, 0, NumInputs); // width of first input port
/*
* Set direct feedthrough flag (1=yes, 0=no).
* A port has direct feedthrough if the input is used in either
* the mdlOutputs or mdlGetTimeOfNextVarHit functions.
*/
ssSetInputPortDirectFeedThrough(S, 0, 0); // no direct feedthrough because we're just putting everything in one update routine (acting like a discrete system)
if (!ssSetNumOutputPorts(S, 1)) return;
ssSetOutputPortWidth(S, 0, NumOutputs);
ssSetNumSampleTimes(S, 1); // -> setting this > 0 calls mdlInitializeSampleTimes()
/*
* If your Fortran code uses REAL for the state, input, and/or output
* datatypes, use these DWorks as work areas to downcast continuous
* states from double to REAL before calling your code. You could
* also put the work vectors in hard-coded local (stack) variables.
*
* For fixed step code, keep a copy of the variables to be output
* in a DWork vector so the mdlOutputs() function can provide output
* data when needed. You can use as many DWork vectors as you like
* for both input and output (or hard-code local variables).
*/
if(!ssSetNumDWork( S, 2)) return;
ssSetDWorkWidth( S, WORKARY_OUTPUT, ssGetOutputPortWidth(S, 0));
ssSetDWorkDataType(S, WORKARY_OUTPUT, SS_DOUBLE); /* use SS_DOUBLE if needed */
ssSetDWorkWidth( S, WORKARY_INPUT, ssGetInputPortWidth(S, 0));
ssSetDWorkDataType(S, WORKARY_INPUT, SS_DOUBLE);
ssSetNumNonsampledZCs(S, 0);
/* Specify the sim state compliance to be same as a built-in block */
/* see sfun_simstate.c for example of other possible settings */
ssSetSimStateCompliance(S, USE_DEFAULT_SIM_STATE);
// ssSetOptions(S, 0); // bjj: what does this do? (not sure what 0 means: no options?) set option to call Terminate earlier...
}
}
/* Function: mdlInitializeSampleTimes =========================================
* Abstract:
* This function is used to specify the sample time(s) for your
* S-function. You must register the same number of sample times as
* specified in ssSetNumSampleTimes.
*/
static void mdlInitializeSampleTimes(SimStruct *S)
{
/*
* If the Fortran code implicitly steps time
* at a fixed rate and you don't want to change
* the code, you need to use a discrete (fixed
* step) sample time, 1 second is chosen below.
*/
ssSetSampleTime(S, 0, dt); /* Choose the sample time here if discrete */
ssSetOffsetTime(S, 0, 0.0);
ssSetModelReferenceSampleTimeDefaultInheritance(S);
}
#undef MDL_INITIALIZE_CONDITIONS /* Change to #undef to remove function */
#define MDL_START /* Change to #undef to remove function */
#if defined(MDL_START)
/* Function: mdlStart =======================================================
* Abstract:
* This function is called once at start of model execution. If you
* have states that should be initialized once, this is the place
* to do it.
*/
static void mdlStart(SimStruct *S)
{
/* bjj: this is really the initial output; I'd really like to have the inputs from Simulink here.... maybe if we put it in mdlOutputs?
but then do we need to say we have direct feed-through?
*/
double *InputAry = (double *)ssGetDWork(S, WORKARY_INPUT); //malloc(NumInputs*sizeof(double));
double *OutputAry = (double *)ssGetDWork(S, WORKARY_OUTPUT);
//n_t_global is -1 here; maybe use this fact in mdlOutputs
if (n_t_global == -1){ // first time to compute outputs:
// getInputs(S, InputAry);
FAST_Start(&NumInputs, &NumOutputs, InputAry, OutputAry, &ErrStat, ErrMsg);
n_t_global = 0;
if (checkError(S)) return;
}
}
#endif /* MDL_START */
/* Function: mdlOutputs =======================================================
* Abstract:
* In this function, you compute the outputs of your S-function
* block. The default datatype for signals in Simulink is double,
* but you can use other intrinsic C datatypes or even custom
* datatypes if you wish. See Simulink document "Writing S-functions"
* for details on datatype topics.
*/
static void mdlOutputs(SimStruct *S, int_T tid)
{
/*
* For Fixed Step Code
* -------------------
* If the Fortran code implements discrete states (implicitly or
* registered with Simulink, it doesn't matter), call the code
* from mdlUpdates() and save the output values in a DWork vector.
* The variable step solver may call mdlOutputs() several
* times in between calls to mdlUpdate, and you must extract the
* values from the DWork vector and copy them to the block output
* variables.
*
* Be sure that the ssSetDWorkDataType(S,0) declaration in
* mdlInitializeSizes() uses SS_DOUBLE for the datatype when
* this code is active.
*/
double *InputAry = (double *)ssGetDWork(S, WORKARY_INPUT);
double *OutputAry = (double *)ssGetDWork(S, WORKARY_OUTPUT);
if (n_t_global == -1){ // first time to compute outputs:
getInputs(S, InputAry);
FAST_Start(&NumInputs, &NumOutputs, InputAry, OutputAry, &ErrStat, ErrMsg);
n_t_global = 0;
if (checkError(S)) return;
}
setOutputs(S, OutputAry);
}
#define MDL_UPDATE /* Change to #undef to remove function */
#if defined(MDL_UPDATE)
/* Function: mdlUpdate ======================================================
* Abstract:
* This function is called once for every major integration time step.
* Discrete states are typically updated here, but this function is useful
* for performing any tasks that should only take place once per
* integration step.
*/
static void mdlUpdate(SimStruct *S, int_T tid)
{
/*
* For Fixed Step Code Only
* ------------------------
* If your Fortran code runs at a fixed time step that advances
* each time you call it, it is best to call it here instead of
* in mdlOutputs(). The states in the Fortran code need not be
* continuous if you call your code from here.
*/
double *InputAry = (double *)ssGetDWork(S, WORKARY_INPUT);
double *OutputAry = (double *)ssGetDWork(S, WORKARY_OUTPUT);
//time_T t = ssGetSampleTime(S, 0);
getInputs(S, InputAry);
/* ==== Call the Fortran routine (args are pass-by-reference) */
FAST_Update(&NumInputs, &NumOutputs, InputAry, OutputAry, &ErrStat, ErrMsg);
n_t_global = n_t_global + 1;
if (checkError(S)) return;
setOutputs(S, OutputAry);
}
#endif /* MDL_UPDATE */
#undef MDL_DERIVATIVES /* Change to #undef to remove function */
/* Function: mdlTerminate =====================================================
* Abstract:
* In this function, you should perform any actions that are necessary
* at the termination of a simulation. For example, if memory was
* allocated in mdlStart, this is the place to free it.
*/
static void mdlTerminate(SimStruct *S)
{
if (n_t_global > -2){ // just in case we've never initialized, check this time step
FAST_End();
n_t_global = -2;
}
}
/*=============================*
* Required S-function trailer *
*=============================*/
#ifdef MATLAB_MEX_FILE /* Is this file being compiled as a MEX-file? */
#include "simulink.c" /* MEX-file interface mechanism */
#else
#include "cg_sfun.h" /* Code generation registration function */
#endif
Thank you in advance and best regards
David

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