// =============================================================================
int csv_isDoubleScalar(void* _pvCtx, int _iVar)
{
SciErr sciErr;
int *piAddressVar = NULL;
sciErr = getVarAddressFromPosition(pvApiCtx, _iVar, &piAddressVar);
if (sciErr.iErr)
{
return 0;
}
if (csv_isScalar(_pvCtx, _iVar))
{
int iType = 0;
sciErr = getVarType(pvApiCtx, piAddressVar, &iType);
if (sciErr.iErr)
{
return 0;
}
if (isVarComplex(pvApiCtx, piAddressVar) == 0)
{
return (iType == sci_matrix);
}
}
return 0;
}
// =============================================================================
int sci_csvTextScan(char *fname, unsigned long fname_len)
{
SciErr sciErr;
int iErr = 0;
int i = 0;
int *piAddressVarOne = NULL;
int m1 = 0, n1 = 0;
int iType1 = 0;
char **text = NULL;
int *lengthText = NULL;
int nbLines = 0;
char *separator = NULL;
char *decimal = NULL;
char *conversion = NULL;
double * dRealValues = NULL;
int *iRange = NULL;
int haveRange = 0;
csvResult *result = NULL;
CheckRhs(1, 5);
CheckLhs(1, 1);
if (Rhs == 5)
{
int m5 = 0, n5 = 0;
iRange = csv_getArgumentAsMatrixofIntFromDouble(pvApiCtx, 5, fname, &m5, &n5, &iErr);
if (iErr)
{
return 0;
}
if ((m5 * n5 != SIZE_RANGE_SUPPORTED) )
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
Scierror(999, _("%s: Wrong size for input argument #%d: Four entries expected.\n"), fname, 5);
return 0;
}
if ((m5 != 1) && (n5 != 1))
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
Scierror(999, _("%s: Wrong size for input argument #%d: A column or row vector expected.\n"), fname, 5);
return 0;
}
if (isValidRange(iRange, m5 * n5))
{
haveRange = 1;
}
else
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
Scierror(999, _("%s: Wrong value for input argument #%d: Inconsistent range.\n"), fname, 5);
return 0;
}
}
if (Rhs >= 4)
{
conversion = csv_getArgumentAsStringWithEmptyManagement(pvApiCtx, 4, fname, getCsvDefaultConversion(), &iErr);
if (iErr)
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
return 0;
}
if (!((strcmp(conversion, CONVTOSTR) == 0) || (strcmp(conversion, CONVTODOUBLE) == 0)))
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
if (conversion)
{
FREE(conversion);
conversion = NULL;
}
Scierror(999, _("%s: Wrong value for input argument #%d: '%s' or '%s' string expected.\n"), fname, 4, "double", "string");
return 0;
}
}
else
{
conversion = strdup(getCsvDefaultConversion());
}
if (Rhs >= 3)
{
decimal = csv_getArgumentAsStringWithEmptyManagement(pvApiCtx, 3, fname, getCsvDefaultDecimal(), &iErr);
if (iErr)
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
if (conversion)
{
FREE(conversion);
conversion = NULL;
}
return 0;
}
if (decimal[0] != '.' && decimal[0] != ',')
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
if (conversion)
{
FREE(conversion);
conversion = NULL;
}
Scierror(999, _("%s: Wrong value for input argument #%d: '%s' or '%s' string expected.\n"), fname, 3, ",", ".");
return 0;
}
}
else
{
decimal = strdup(getCsvDefaultDecimal());
}
if (Rhs >= 2)
{
separator = csv_getArgumentAsStringWithEmptyManagement(pvApiCtx, 2, fname, getCsvDefaultSeparator(), &iErr);
if (iErr)
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
if (decimal)
{
FREE(decimal);
decimal = NULL;
}
if (conversion)
{
FREE(conversion);
conversion = NULL;
}
return 0;
}
}
else
{
separator = strdup(getCsvDefaultSeparator());
}
if (!csv_isRowVector(pvApiCtx, 1) &&
!csv_isColumnVector(pvApiCtx, 1) &&
!csv_isScalar(pvApiCtx, 1))
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
if (separator)
{
FREE(separator);
separator = NULL;
}
if (decimal)
{
FREE(decimal);
decimal = NULL;
}
if (conversion)
{
FREE(conversion);
conversion = NULL;
}
Scierror(999, _("%s: Wrong size for input argument #%d: Vector string expected.\n"), fname, 1);
return 0;
}
text = csv_getArgumentAsMatrixOfString(pvApiCtx, 1, fname, &m1, &n1, &iErr);
if (iErr)
{
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
if (separator)
{
FREE(separator);
separator = NULL;
}
if (decimal)
{
FREE(decimal);
decimal = NULL;
}
if (conversion)
{
FREE(conversion);
conversion = NULL;
}
return 0;
}
nbLines = m1 * n1;
result = csvTextScan((const char**)text, nbLines, separator, decimal);
if (text)
{
if (separator)
{
FREE(separator);
separator = NULL;
}
freeArrayOfString(text, nbLines);
text = NULL;
}
if (separator)
{
FREE(separator);
separator = NULL;
}
if (result)
{
switch (result->err)
{
case CSV_READ_SEPARATOR_DECIMAL_EQUAL:
{
Scierror(999, _("%s: separator and decimal must have different values.\n"), fname);
}
break;
case CSV_READ_NO_ERROR:
{
if (strcmp(conversion, CONVTOSTR) == 0)
{
if (haveRange)
{
int newM = 0;
int newN = 0;
char **pStrRange = getRangeAsString((const char**)result->pstrValues, result->m, result->n, iRange, &newM, &newN);
if (pStrRange)
{
sciErr = createMatrixOfString(pvApiCtx, Rhs + 1, newM, newN, pStrRange);
freeArrayOfString(pStrRange, newM * newN);
}
else
{
Scierror(999, _("%s: Memory allocation error.\n"), fname);
}
}
else
{
sciErr = createMatrixOfString(pvApiCtx, Rhs + 1, result->m, result->n, result->pstrValues);
}
}
else /* to double */
{
stringToComplexError ierr = STRINGTOCOMPLEX_ERROR;
csv_complexArray *ptrCsvComplexArray = stringsToCsvComplexArray((const char**)result->pstrValues, result->m * result->n, decimal, TRUE, &ierr);
if (ptrCsvComplexArray == NULL)
{
freeCsvResult(result);
if (decimal)
{
FREE(decimal);
decimal = NULL;
}
if (conversion)
{
FREE(conversion);
conversion = NULL;
}
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
if (ierr == STRINGTOCOMPLEX_ERROR)
{
Scierror(999, _("%s: can not convert data.\n"), fname);
}
else
{
Scierror(999, _("%s: Memory allocation error.\n"), fname);
}
return 0;
}
switch (ierr)
{
case STRINGTOCOMPLEX_NOT_A_NUMBER:
case STRINGTOCOMPLEX_NO_ERROR:
{
if (haveRange)
{
int newM = 0;
int newN = 0;
csv_complexArray *csvComplexRange = getRangeAsCsvComplexArray(ptrCsvComplexArray, result->m, result->n, iRange, &newM, &newN);
if (csvComplexRange)
{
if (csvComplexRange->isComplex)
{
sciErr = createComplexMatrixOfDouble(pvApiCtx, Rhs + 1, newM, newN, ptrCsvComplexArray->realPart, ptrCsvComplexArray->imagPart);
}
else
{
sciErr = createMatrixOfDouble(pvApiCtx, Rhs + 1, newM, newN, csvComplexRange->realPart);
}
freeCsvComplexArray(csvComplexRange);
csvComplexRange = NULL;
}
else
{
Scierror(999, _("%s: Memory allocation error.\n"), fname);
}
}
else
{
if (ptrCsvComplexArray->isComplex)
{
sciErr = createComplexMatrixOfDouble(pvApiCtx, Rhs + 1, result->m, result->n, ptrCsvComplexArray->realPart, ptrCsvComplexArray->imagPart);
}
else
{
sciErr = createMatrixOfDouble(pvApiCtx, Rhs + 1, result->m, result->n, ptrCsvComplexArray->realPart);
}
}
freeCsvComplexArray(ptrCsvComplexArray);
ptrCsvComplexArray = NULL;
}
break;
case STRINGTOCOMPLEX_MEMORY_ALLOCATION:
{
Scierror(999, _("%s: Memory allocation error.\n"), fname);
}
default:
case STRINGTOCOMPLEX_ERROR:
{
Scierror(999, _("%s: can not convert data.\n"), fname);
}
}
}
if (sciErr.iErr)
{
freeCsvResult(result);
if (decimal)
{
FREE(decimal);
decimal = NULL;
}
if (conversion)
{
FREE(conversion);
conversion = NULL;
}
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
printError(&sciErr, 0);
Scierror(17, _("%s: Memory allocation error.\n"), fname);
return 0;
}
else
{
LhsVar(1) = Rhs + 1;
PutLhsVar();
}
}
break;
case CSV_READ_MEMORY_ALLOCATION:
{
Scierror(999, _("%s: Memory allocation error.\n"), fname);
}
break;
case CSV_READ_COLUMNS_ERROR:
{
Scierror(999, _("%s: can not read text: Error in the column structure\n"), fname);
}
break;
case CSV_READ_READLINES_ERROR:
case CSV_READ_ERROR:
{
Scierror(999, _("%s: can not read text.\n"), fname);
}
break;
}
}
else
{
Scierror(999, _("%s: Memory allocation error.\n"), fname);
}
freeCsvResult(result);
if (decimal)
{
FREE(decimal);
decimal = NULL;
}
if (conversion)
{
FREE(conversion);
conversion = NULL;
}
if (iRange)
{
FREE(iRange);
iRange = NULL;
}
return 0;
}