--- Kst-2.0.8/src/plugins/fits/non_linear.h 2014-02-13 18:41:44.000000000 +0900 +++ Kst-2.0.8/src/plugins/fits/non_linear.h 2016-03-04 00:34:31.000000000 +0900 @@ -177,37 +177,45 @@ } iIterations++; } while( iStatus == GSL_CONTINUE && iIterations < MAX_NUM_ITERATIONS ); - gsl_multifit_covar( pSolver->J, 0.0, pMatrixCovariance ); - - // - // determine the fitted values... - // - for( i=0; ix, i ); - } - - for( i=0; ivalue()[i] = function_calculate( pInputX[i], dXInitial ); - vectorOutYResiduals->value()[i] = pInputY[i] - vectorOutYFitted->value()[i]; + + + gsl_matrix *J = gsl_matrix_alloc(pSolver->fdf->n, pSolver->fdf->p); + if (J != NULL) { + gsl_multifit_fdfsolver_jac(pSolver, J); + + gsl_multifit_covar( J, 0.0, pMatrixCovariance ); + + // + // determine the fitted values... + // + for( i=0; ix, i ); + } + + for( i=0; ivalue()[i] = function_calculate( pInputX[i], dXInitial ); + vectorOutYResiduals->value()[i] = pInputY[i] - vectorOutYFitted->value()[i]; + } + + // + // fill in the parameter values and covariance matrix... + // + for( i=0; ivalue()[i] = gsl_vector_get( pSolver->x, i ); + for( j=0; jvalue()[(i*NUM_PARAMS)+j] = gsl_matrix_get( pMatrixCovariance, i, j ); + } + } + + // + // determine the value of chi^2/nu + // + scalarOutChi->setValue(gsl_blas_dnrm2( pSolver->f )); + + bReturn = true; + + gsl_matrix_free( J ); } - - // - // fill in the parameter values and covariance matrix... - // - for( i=0; ivalue()[i] = gsl_vector_get( pSolver->x, i ); - for( j=0; jvalue()[(i*NUM_PARAMS)+j] = gsl_matrix_get( pMatrixCovariance, i, j ); - } - } - - // - // determine the value of chi^2/nu - // - scalarOutChi->setValue(gsl_blas_dnrm2( pSolver->f )); - - bReturn = true; - gsl_matrix_free( pMatrixCovariance ); } gsl_multifit_fdfsolver_free( pSolver ); --- Kst-2.0.8/src/plugins/fits/non_linear_weighted.h 2014-02-13 18:41:44.000000000 +0900 +++ Kst-2.0.8/src/plugins/fits/non_linear_weighted.h 2016-03-04 00:37:41.000000000 +0900 @@ -193,37 +193,43 @@ } while( iStatus == GSL_CONTINUE && iIterations < MAX_NUM_ITERATIONS ); - gsl_multifit_covar( pSolver->J, 0.0, pMatrixCovariance ); - - // - // determine the fitted values... - // - for( i=0; ix, i ); - } - - for( i=0; ivalue()[i] = function_calculate( pInputs[XVALUES][i], dXInitial ); - vectorOutYResiduals->value()[i] = pInputs[YVALUES][i] - vectorOutYFitted->value()[i]; - } - - // - // fill in the parameter values and covariance matrix... - // - for( i=0; ivalue()[i] = gsl_vector_get( pSolver->x, i ); - for( j=0; jvalue()[(i*NUM_PARAMS)+j] = gsl_matrix_get( pMatrixCovariance, i, j ); - } + gsl_matrix *J = gsl_matrix_alloc(pSolver->fdf->n, pSolver->fdf->p); + if (J != NULL) { + gsl_multifit_fdfsolver_jac(pSolver, J); + + gsl_multifit_covar( J, 0.0, pMatrixCovariance ); + + // + // determine the fitted values... + // + for( i=0; ix, i ); + } + + for( i=0; ivalue()[i] = function_calculate( pInputs[XVALUES][i], dXInitial ); + vectorOutYResiduals->value()[i] = pInputs[YVALUES][i] - vectorOutYFitted->value()[i]; + } + + // + // fill in the parameter values and covariance matrix... + // + for( i=0; ivalue()[i] = gsl_vector_get( pSolver->x, i ); + for( j=0; jvalue()[(i*NUM_PARAMS)+j] = gsl_matrix_get( pMatrixCovariance, i, j ); + } + } + + // + // determine the value of chi^2/nu + // + scalarOutChi->setValue(gsl_blas_dnrm2( pSolver->f )); + + bReturn = true; + + gsl_matrix_free( J ); } - - // - // determine the value of chi^2/nu - // - scalarOutChi->setValue(gsl_blas_dnrm2( pSolver->f )); - - bReturn = true; - gsl_matrix_free( pMatrixCovariance ); } gsl_multifit_fdfsolver_free( pSolver );