/* * C-type: unsigned int * Scilab type: double or uint32 */ %fragment(SWIG_AsVal_frag(unsigned int), "header", fragment="SWIG_SciDoubleOrUint32_AsUnsignedInt", fragment="") { %#define SWIG_AsVal_unsigned_SS_int(scilabValue, valuePointer) SWIG_SciDoubleOrUint32_AsUnsignedInt(pvApiCtx, scilabValue, valuePointer, SWIG_Scilab_GetFuncName()) } %fragment("SWIG_SciDoubleOrUint32_AsUnsignedInt", "header") { SWIGINTERN int SWIG_SciDoubleOrUint32_AsUnsignedInt(void *pvApiCtx, int iVar, unsigned int *puiValue, char *fname) { SciErr sciErr; int iType = 0; int iRows = 0; int iCols = 0; int iPrec = 0; int *piAddrVar = NULL; unsigned int *puiData = NULL; sciErr = getVarAddressFromPosition(pvApiCtx, iVar, &piAddrVar); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } sciErr = getVarType(pvApiCtx, piAddrVar, &iType); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } if (iType == sci_ints) { if (puiValue) { sciErr = getMatrixOfIntegerPrecision(pvApiCtx, piAddrVar, &iPrec); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } if (iPrec != SCI_UINT32) { Scierror(SCILAB_API_ARGUMENT_ERROR, _("%s: Wrong type for input argument #%d: A 32-bit unsigned integer or a double expected.\n"), fname, iVar); return SWIG_ERROR; } sciErr = getMatrixOfUnsignedInteger32(pvApiCtx, piAddrVar, &iRows, &iCols, &puiData); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } if (iRows * iCols != 1) { Scierror(SCILAB_API_ARGUMENT_ERROR, _("%s: Wrong size for input argument #%d: A 32-bit unsigned integer or a double expected.\n"), fname, iVar); return SWIG_ERROR; } *puiValue = *puiData; } } else if (iType == sci_matrix) { if (puiValue) { double *pdData = NULL; double dValue = 0.0f; sciErr = getMatrixOfDouble(pvApiCtx, piAddrVar, &iRows, &iCols, &pdData); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } if (iRows * iCols != 1) { Scierror(SCILAB_API_ARGUMENT_ERROR, _("%s: Wrong size for input argument #%d: A 32-bit unsigned integer or a double expected.\n"), fname, iVar); return SWIG_TypeError; } dValue = *pdData; if (dValue != floor(dValue)) { Scierror(SCILAB_API_ARGUMENT_ERROR, _("%s: Incorrect value for input argument #%d: The double value cannot be converted to a 32-bit unsigned integer.\n"), fname, iVar); return SWIG_ValueError; } if ((dValue < 0) || (dValue > UINT_MAX)) { Scierror(SCILAB_API_ARGUMENT_ERROR, _("%s: Overflow error for input argument #%d: The double value cannot be converted to a 32-bit unsigned integer.\n"), fname, iVar); return SWIG_OverflowError; } *puiValue = (unsigned int) dValue; } } else { Scierror(SCILAB_API_ARGUMENT_ERROR, _("%s: Wrong type for input argument #%d: A 32-bit unsigned integer or a double expected.\n"), fname, iVar); return SWIG_ERROR; } return SWIG_OK; } } %fragment(SWIG_From_frag(unsigned int), "header", fragment="SWIG_SciDouble_FromUnsignedInt") { %#define SWIG_From_unsigned_SS_int(scilabValue) SWIG_SciDouble_FromUnsignedInt(pvApiCtx, SWIG_Scilab_GetOutputPosition(), scilabValue, SWIG_Scilab_GetFuncName()) } %fragment("SWIG_SciDouble_FromUnsignedInt", "header") { SWIGINTERN int SWIG_SciDouble_FromUnsignedInt(void *pvApiCtx, int iVarOut, unsigned int uiValue, char *fname) { if (createScalarDouble(pvApiCtx, SWIG_NbInputArgument(pvApiCtx) + iVarOut, (double) uiValue)) return SWIG_ERROR; return SWIG_OK; } } /* * C-type: unsigned int[] * Scilab type: uint32 vector */ %fragment("SWIG_SciDoubleOrUint32_AsUnsignedIntArrayAndSize", "header") { SWIGINTERN int SWIG_SciDoubleOrUint32_AsUnsignedIntArrayAndSize(void *pvApiCtx, int iVar, int *iRows, int *iCols, unsigned int **puiValue, char *fname) { SciErr sciErr; int iType = 0; int iPrec = 0; int *piAddrVar = NULL; sciErr = getVarAddressFromPosition(pvApiCtx, iVar, &piAddrVar); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } sciErr = getVarType(pvApiCtx, piAddrVar, &iType); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } if (iType == sci_matrix) { double *pdData = NULL; int size = 0; int i; sciErr = getMatrixOfDouble(pvApiCtx, piAddrVar, iRows, iCols, &pdData); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } size = (*iRows) * (*iCols); *puiValue = (unsigned int*) malloc(size * sizeof(int*)); for (i = 0; i < size; i++) (*puiValue)[i] = (unsigned int) pdData[i]; } else if (iType == sci_ints) { sciErr = getMatrixOfIntegerPrecision(pvApiCtx, piAddrVar, &iPrec); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } if (iPrec != SCI_UINT32) { Scierror(SCILAB_API_ARGUMENT_ERROR, _("%s: Wrong type for input argument #%d: A 32-bit unsigned integer or a double vector expected.\n"), fname, iVar); return SWIG_ERROR; } sciErr = getMatrixOfUnsignedInteger32(pvApiCtx, piAddrVar, iRows, iCols, puiValue); if (sciErr.iErr) { printError(&sciErr, 0); return SWIG_ERROR; } } else { Scierror(SCILAB_API_ARGUMENT_ERROR, _("%s: Wrong type for input argument #%d: A 32-bit unsigned integer or a double vector expected.\n"), fname, iVar); return SWIG_ERROR; } return SWIG_OK; } } %fragment("SWIG_SciDouble_FromUnsignedIntArrayAndSize", "header") { SWIGINTERN int SWIG_SciDouble_FromUnsignedIntArrayAndSize(void *pvApiCtx, int iVarOut, int iRows, int iCols, unsigned int *puiValues) { SciErr sciErr; double *pdValues = NULL; int i; pdValues = (double*) malloc(iRows * iCols * sizeof(double)); for (i=0; i