Scilab 5.5.2
- Ajuda do Scilab
- API Scilab
- Low level functions
- AssignOutputVariable
- CallOverloadFunction
- CheckInputArgument
- CheckOutputArgument
- ReturnArguments
- Boolean reading (Scilab gateway)
- Boolean writing (Scilab gateway)
- Boolean sparse reading (Scilab gateway)
- Boolean sparse writing (Scilab gateway)
- Check variable dimensions (Scilab gateway)
- Variable Reference (Scilab gateway)
- Variable dimension (Scilab gateway)
- Variable Type (Scilab gateway)
- Variable Complexity (Scilab gateway)
- Matrix Type (Scilab gateway)
- deleteNamedVariable
- Double reading (Scilab gateway)
- Double writing (Scilab gateway)
- getNbInputArgument (Scilab gateway)
- getNbOutputArgument (Scilab gateway)
- Handle reading (Scilab gateway)
- Handle writing (Scilab gateway)
- Integer Precision (Scilab gateway)
- Integer reading (Scilab gateway)
- Integer writing (Scilab gateway)
- nbInputArgument (Scilab gateway)
- Pointer reading (Scilab gateway)
- Pointer writing (Scilab gateway)
- Polynomial Symbolic Variable (Scilab gateway)
- Polynomial reading (Scilab gateway)
- Polynomial writing (Scilab gateway)
- Sparse matrix reading (Scilab gateway)
- Sparse writing (Scilab gateway)
- String reading (Scilab gateway)
- String writing (Scilab gateway)
Please note that the recommended version of Scilab is 2025.0.0. This page might be outdated.
However, this page did not exist in the previous stable version.
Polynomial Symbolic Variable (Scilab gateway)
How to get the symbolic variable name.
Calling Sequence
Input argument profile:
SciErr getPolyVariableName(void* _pvCtx, int* _piAddress, char* _pstVarName, int* _piVarNameLen)
Arguments
- _pvCtx
Scilab environment pointer, pass in "pvApiCtx" provided by api_scilab.h.
- _piAddress
Address of the variable.
- _pstVarName
Return the symbolic varaible name
- _piVarNameLen
Return the length of _pstVarName
- SciErr
Error structure where is stored errors messages history and first error number.
Description
This help describes how to get the symbolic variable name.
Gateway Source
#include "api_scilab.h" int read_poly(char *fname,unsigned long fname_len) { SciErr sciErr; int i,j; //variable info int iRows = 0; int iCols = 0; int iVarLen = 0; int* piAddr = NULL; int* piNbCoef = NULL; double** pdblReal = NULL; double** pdblImg = NULL; char* pstVarname = NULL; //check input and output arguments CheckInputArgument(pvApiCtx, 1, 1); CheckOutputArgument(pvApiCtx, 1, 1); sciErr = getVarAddressFromPosition(pvApiCtx, 1, &piAddr); if(sciErr.iErr) { printError(&sciErr, 0); return 0; } if(isVarComplex(pvApiCtx, piAddr) == FALSE) { //Error return 0; } //get variable name length sciErr = getPolyVariableName(pvApiCtx, piAddr, NULL, &iVarLen); if(sciErr.iErr) { printError(&sciErr, 0); return 0; } //alloc buff to receive variable name pstVarname = (char*)malloc(sizeof(char) * (iVarLen + 1));//1 for null termination //get variable name sciErr = getPolyVariableName(pvApiCtx, piAddr, pstVarname, &iVarLen); if(sciErr.iErr) { printError(&sciErr, 0); return 0; } //First call: retrieve dimmension sciErr = getComplexMatrixOfPoly(pvApiCtx, piAddr, &iRows, &iCols, NULL, NULL, NULL); if(sciErr.iErr) { printError(&sciErr, 0); return 0; } //alloc array of coefficient piNbCoef = (int*)malloc(sizeof(int) * iRows * iCols); //Second call: retrieve coefficient sciErr = getComplexMatrixOfPoly(pvApiCtx, piAddr, &iRows, &iCols, piNbCoef, NULL, NULL); if(sciErr.iErr) { printError(&sciErr, 0); return 0; } //alloc arrays of data pdblReal = (double**)malloc(sizeof(double*) * iRows * iCols); pdblImg = (double**)malloc(sizeof(double*) * iRows * iCols); for(i = 0 ; i < iRows * iCols ; i++) { pdblReal[i] = (double*)malloc(sizeof(double) * piNbCoef[i]); pdblImg[i] = (double*)malloc(sizeof(double) * piNbCoef[i]); } //Third call: retrieve data sciErr = getComplexMatrixOfPoly(pvApiCtx, piAddr, &iRows, &iCols, piNbCoef, pdblReal, pdblImg); if(sciErr.iErr) { printError(&sciErr, 0); return 0; } //Do something with Data //Invert polynomials in the matrix and invert coefficients for(i = 0 ; i < (iRows * iCols) / 2 ; i++) { int iPos1 = iRows * iCols - 1 - i; double* pdblSave = NULL; int iNbCoefSave = 0; //switch array of coefficient pdblSave = pdblReal[i]; pdblReal[i] = pdblReal[iPos1]; pdblReal[iPos1] = pdblSave; pdblSave = pdblImg[i]; pdblImg[i] = pdblImg[iPos1]; pdblImg[iPos1] = pdblSave; //switch number of coefficient iNbCoefSave = piNbCoef[i]; piNbCoef[i] = piNbCoef[iPos1]; piNbCoef[iPos1] = iNbCoefSave; } //switch coefficient for(i = 0 ; i < iRows * iCols ; i++) { for(j = 0 ; j < piNbCoef[i] /2 ; j++) { int iPos2 = piNbCoef[i] - 1 - j; double dblVal = pdblReal[i][j]; pdblReal[i][j] = pdblReal[i][iPos2]; pdblReal[i][iPos2] = dblVal; dblVal = pdblImg[i][j]; pdblImg[i][j] = pdblImg[i][iPos2]; pdblImg[i][iPos2] = dblVal; } } sciErr = createComplexMatrixOfPoly(pvApiCtx, nbInputArgument(pvApiCtx) + 1, pstVarname, iRows, iCols, piNbCoef, pdblReal, pdblImg); if(sciErr.iErr) { printError(&sciErr, 0); return 0; } //free OS memory free(pstVarname); free(piNbCoef); for(i = 0 ; i < iRows * iCols ; i++) { free(pdblReal[i]); free(pdblImg[i]); } free(pdblReal); free(pdblImg); //assign allocated variables to Lhs position AssignOutputVariable(pvApiCtx, 1) = nbInputArgument(pvApiCtx) + 1; return 0; }
Scilab test script
coeff1 = [ .. 29*%i,22*%i,16*%i,11*%i,7*%i,30,23,17,12,8,-31*%i,-24*%i,-18*%i,-13*%i,-9*%i,32,25,19,14,10,-33*%i,-26*%i,-20*%i,-15*%i,0,34,27,21,0,0,0,-28*%i,0,0,0,36-35*%i,0,0,0,0; .. 4*%i,2*%i,%i,22,16,5,-3,0,-23*%i,-17*%i,-6*%i,0,0,24,18,0,0,0,-25*%i,-19*%i,0,0,0,26,20,0,0,0,-27*%i,-21*%i,0,0,0,28,0,0,0,0,0,0; .. 11,7,4,2,1,-12*%i,-8*%i,-5*%i,3*%i,0,13,9,6,0,0,-14*%i,-10*%i,0,0,0,15,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0]; x = poly(0, "x"); p1 = 1; p2 = 2 * x + 3 * %i; p3 = 4 * x**2 - 5 * %i * x + 6; p4 = 7 * x**3 - 8 * %i * x**2 + 9 * x - 10 * %i; p5 = 11 * x**4 - 12 * %i * x**3 + 13 * x**2 - 14 * %i * x + 15; p6 = 16 * x**5 - 17 * %i * x**4 + 18 * x**3 - 19 * %i * x**2 + 20 * x - 21 * %i; p7 = 22 * x**6 - 23 * %i * x**5 + 24 * x**4 - 25 * %i * x**3 + 26 * x**2 - 27 * %i * x + 28; p8 = %i; p9 = 2 * %i * x - 3; p10 = 4 * %i * x**2 + 5 * x - 6 * %i; p11 = 7 * %i * x**3 + 8 * x**2 - 9 * %i * x + 10; p12 = 11 * %i * x**4 + 12 * x**3 - 13 * %i * x**2 + 14 * x - 15 * %i; p13 = 16 * %i * x**5 + 17 * x**4 - 18 * %i * x**3 + 19 * x**2 - 20 * %i * x + 21; p14 = 22 * %i * x**6 + 23 * x**5 - 24 * %i * x**4 + 25 * x**3 - 26 * %i * x**2 + 27 * x - 28 * %i; p15 = 29 * %i * x**7 + 30 * x**6 - 31 * %i * x**5 + 32 * x**4 - 33 * %i * x**3 + 34 * x**2 - 35 * %i + 36; p = [p1, p2, p3, p4, p5 ; p6, p7, p8, p9 ,p10 ; p11, p12, p13, p14, p15]; p1 = read_poly(p); coeff2 = coeff(p1); if or(coeff2 <> coeff1) then error("failed"), end
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