void CVodesIntegrator::sensInit(double t0, FuncEval& func)
{
    m_np = func.nparams();
    size_t nv = func.neq();
    m_sens_ok = false;

    doublereal* data;
    N_Vector y;
    y = N_VNew_Serial(static_cast<sd_size_t>(nv));
    m_yS = N_VCloneVectorArray_Serial(static_cast<sd_size_t>(m_np), y);
    for (size_t n = 0; n < m_np; n++) {
        data = NV_DATA_S(m_yS[n]);
        for (size_t j = 0; j < nv; j++) {
            data[j] =0.0;
        }
    }

    int flag = CVodeSensInit(m_cvode_mem, static_cast<sd_size_t>(m_np),
                             CV_STAGGERED, CVSensRhsFn(0), m_yS);

    if (flag != CV_SUCCESS) {
        throw CVodesErr("Error in CVodeSensMalloc");
    }
    vector_fp atol(m_np, m_abstolsens);
    double rtol = m_reltolsens;
    flag = CVodeSensSStolerances(m_cvode_mem, rtol, atol.data());

}
void CVodesIntegrator::sensInit(double t0, FuncEval& func)
{
    m_np = func.nparams();
    m_sens_ok = false;

    N_Vector y = N_VNew_Serial(static_cast<sd_size_t>(func.neq()));
    m_yS = N_VCloneVectorArray_Serial(static_cast<sd_size_t>(m_np), y);
    for (size_t n = 0; n < m_np; n++) {
        N_VConst(0.0, m_yS[n]);
    }
    N_VDestroy_Serial(y);

    int flag = CVodeSensInit(m_cvode_mem, static_cast<sd_size_t>(m_np),
                             CV_STAGGERED, CVSensRhsFn(0), m_yS);

    if (flag != CV_SUCCESS) {
        throw CanteraError("CVodesIntegrator::sensInit", "Error in CVodeSensInit");
    }
    vector_fp atol(m_np);
    for (size_t n = 0; n < m_np; n++) {
        // This scaling factor is tuned so that reaction and species enthalpy
        // sensitivities can be computed simultaneously with the same abstol.
        atol[n] = m_abstolsens / func.m_paramScales[n];
    }
    flag = CVodeSensSStolerances(m_cvode_mem, m_reltolsens, atol.data());
}
Beispiel #3
0
  void CVodesIntegrator::sensInit(double t0, FuncEval& func) {
    m_np = func.nparams();
    long int nv = func.neq();

    doublereal* data;
    int n, j;
    N_Vector y;
    y = N_VNew_Serial(nv);
    m_yS = N_VCloneVectorArray_Serial(m_np, y);
    for (n = 0; n < m_np; n++) {
      data = NV_DATA_S(m_yS[n]);
      for (j = 0; j < nv; j++) {
	data[j] =0.0;
      }
    }

    int flag;

#if defined(SUNDIALS_VERSION_22) || defined(SUNDIALS_VERSION_23)
    flag = CVodeSensMalloc(m_cvode_mem, m_np, CV_STAGGERED, m_yS);
    if (flag != CV_SUCCESS) {
      throw CVodesErr("Error in CVodeSensMalloc");
    }
    vector_fp atol(m_np, m_abstolsens);
    double rtol = m_reltolsens;
    flag = CVodeSetSensTolerances(m_cvode_mem, CV_SS, rtol, DATA_PTR(atol));
#elif defined(SUNDIALS_VERSION_24)
    flag = CVodeSensInit(m_cvode_mem, m_np, CV_STAGGERED,
			 CVSensRhsFn (0), m_yS);

    if (flag != CV_SUCCESS) {
      throw CVodesErr("Error in CVodeSensMalloc");
    }
    vector_fp atol(m_np, m_abstolsens);
    double rtol = m_reltolsens;
    flag = CVodeSensSStolerances(m_cvode_mem, rtol, DATA_PTR(atol));

#endif
 
  }
Beispiel #4
0
  void CVodesIntegrator::initialize(double t0, FuncEval& func) 
  {
    m_neq = func.neq();
    m_t0  = t0;

    if (m_y) {
      N_VDestroy_Serial(nv(m_y));    // free solution vector if already allocated
    }
    m_y = reinterpret_cast<void*>(N_VNew_Serial(m_neq));   // allocate solution vector
    for (int i=0; i<m_neq; i++) {
      NV_Ith_S(nv(m_y), i) = 0.0;
    }
    // check abs tolerance array size
    if (m_itol == CV_SV && m_nabs < m_neq) 
      throw CVodesErr("not enough absolute tolerance values specified.");

    func.getInitialConditions(m_t0, m_neq, NV_DATA_S(nv(m_y)));

    if (m_cvode_mem) CVodeFree(&m_cvode_mem);

    /*
     *  Specify the method and the iteration type:
     *      Cantera Defaults:
     *         CV_BDF  - Use BDF methods 
     *         CV_NEWTON - use newton's method 
     */
    m_cvode_mem = CVodeCreate(m_method, m_iter);
    if (!m_cvode_mem) throw CVodesErr("CVodeCreate failed.");

    int flag = 0;
#if defined(SUNDIALS_VERSION_22) || defined(SUNDIALS_VERSION_23)
    if (m_itol == CV_SV) {
      // vector atol
      flag = CVodeMalloc(m_cvode_mem, cvodes_rhs, m_t0, nv(m_y), m_itol,
			 m_reltol, nv(m_abstol));
    }
    else {
      // scalar atol
      flag = CVodeMalloc(m_cvode_mem, cvodes_rhs, m_t0, nv(m_y), m_itol,
			 m_reltol, &m_abstols);
    }
    if (flag != CV_SUCCESS) {
      if (flag == CV_MEM_FAIL) {
	throw CVodesErr("Memory allocation failed.");
      }
      else if (flag == CV_ILL_INPUT) {
	throw CVodesErr("Illegal value for CVodeMalloc input argument.");
      }
      else 
	throw CVodesErr("CVodeMalloc failed.");
    }
#elif defined(SUNDIALS_VERSION_24)

    flag = CVodeInit(m_cvode_mem, cvodes_rhs, m_t0, nv(m_y));
    if (flag != CV_SUCCESS) {
      if (flag == CV_MEM_FAIL) {
	throw CVodesErr("Memory allocation failed.");
      } else if (flag == CV_ILL_INPUT) {
	throw CVodesErr("Illegal value for CVodeInit input argument.");
      } else {
	throw CVodesErr("CVodeInit failed.");
      }
    }

    if (m_itol == CV_SV) {
      flag = CVodeSVtolerances(m_cvode_mem, m_reltol, nv(m_abstol));
    } else {
      flag = CVodeSStolerances(m_cvode_mem, m_reltol, m_abstols);
    }
    if (flag != CV_SUCCESS) {
      if (flag == CV_MEM_FAIL) {
	throw CVodesErr("Memory allocation failed.");
      } else if (flag == CV_ILL_INPUT) {
	throw CVodesErr("Illegal value for CVodeInit input argument.");
      } else {
	throw CVodesErr("CVodeInit failed.");
      }
    }
#else
    printf("unknown sundials verson\n");
    exit(-1);
#endif



    if (m_type == DENSE + NOJAC) {
      long int N = m_neq;
      CVDense(m_cvode_mem, N);
    }
    else if (m_type == DIAG) {
      CVDiag(m_cvode_mem);
    }
    else if (m_type == GMRES) {
      CVSpgmr(m_cvode_mem, PREC_NONE, 0);
    }
    else if (m_type == BAND + NOJAC) {
      long int N = m_neq;
      long int nu = m_mupper;
      long int nl = m_mlower;
      CVBand(m_cvode_mem, N, nu, nl);
    }
    else {
      throw CVodesErr("unsupported option");
    }

    // pass a pointer to func in m_data 
    m_fdata = new FuncData(&func, func.nparams());

    //m_data = (void*)&func;
#if defined(SUNDIALS_VERSION_22) || defined(SUNDIALS_VERSION_23)
    flag = CVodeSetFdata(m_cvode_mem, (void*)m_fdata);
    if (flag != CV_SUCCESS) {
      throw CVodesErr("CVodeSetFdata failed.");
    }
#elif defined(SUNDIALS_VERSION_24)
    flag = CVodeSetUserData(m_cvode_mem, (void*)m_fdata);
    if (flag != CV_SUCCESS) {
      throw CVodesErr("CVodeSetUserData failed.");
    }
#endif
    if (func.nparams() > 0) {
      sensInit(t0, func);
      flag = CVodeSetSensParams(m_cvode_mem, DATA_PTR(m_fdata->m_pars), 
				NULL, NULL);
    }

    // set options
    if (m_maxord > 0)
      flag = CVodeSetMaxOrd(m_cvode_mem, m_maxord);
    if (m_maxsteps > 0)
      flag = CVodeSetMaxNumSteps(m_cvode_mem, m_maxsteps);
    if (m_hmax > 0)
      flag = CVodeSetMaxStep(m_cvode_mem, m_hmax);
  }
void CVodesIntegrator::initialize(double t0, FuncEval& func)
{
    m_neq = func.neq();
    m_t0 = t0;
    m_time = t0;

    if (m_y) {
        N_VDestroy_Serial(m_y); // free solution vector if already allocated
    }
    m_y = N_VNew_Serial(static_cast<sd_size_t>(m_neq)); // allocate solution vector
    for (size_t i = 0; i < m_neq; i++) {
        NV_Ith_S(m_y, i) = 0.0;
    }
    // check abs tolerance array size
    if (m_itol == CV_SV && m_nabs < m_neq) {
        throw CVodesErr("not enough absolute tolerance values specified.");
    }

    func.getInitialConditions(m_t0, m_neq, NV_DATA_S(m_y));

    if (m_cvode_mem) {
        CVodeFree(&m_cvode_mem);
    }

    /*
     *  Specify the method and the iteration type:
     *      Cantera Defaults:
     *         CV_BDF  - Use BDF methods
     *         CV_NEWTON - use Newton's method
     */
    m_cvode_mem = CVodeCreate(m_method, m_iter);
    if (!m_cvode_mem) {
        throw CVodesErr("CVodeCreate failed.");
    }

    int flag = CVodeInit(m_cvode_mem, cvodes_rhs, m_t0, m_y);
    if (flag != CV_SUCCESS) {
        if (flag == CV_MEM_FAIL) {
            throw CVodesErr("Memory allocation failed.");
        } else if (flag == CV_ILL_INPUT) {
            throw CVodesErr("Illegal value for CVodeInit input argument.");
        } else {
            throw CVodesErr("CVodeInit failed.");
        }
    }
    CVodeSetErrHandlerFn(m_cvode_mem, &cvodes_err, this);

    if (m_itol == CV_SV) {
        flag = CVodeSVtolerances(m_cvode_mem, m_reltol, m_abstol);
    } else {
        flag = CVodeSStolerances(m_cvode_mem, m_reltol, m_abstols);
    }
    if (flag != CV_SUCCESS) {
        if (flag == CV_MEM_FAIL) {
            throw CVodesErr("Memory allocation failed.");
        } else if (flag == CV_ILL_INPUT) {
            throw CVodesErr("Illegal value for CVodeInit input argument.");
        } else {
            throw CVodesErr("CVodeInit failed.");
        }
    }

    // pass a pointer to func in m_data
    m_fdata.reset(new FuncData(&func, func.nparams()));

    flag = CVodeSetUserData(m_cvode_mem, m_fdata.get());
    if (flag != CV_SUCCESS) {
        throw CVodesErr("CVodeSetUserData failed.");
    }
    if (func.nparams() > 0) {
        sensInit(t0, func);
        flag = CVodeSetSensParams(m_cvode_mem, m_fdata->m_pars.data(),
                                  NULL, NULL);
    }
    applyOptions();
}
void CVodesIntegrator::initialize(double t0, FuncEval& func)
{
    m_neq = func.neq();
    m_t0 = t0;
    m_time = t0;

    if (m_y) {
        N_VDestroy_Serial(m_y); // free solution vector if already allocated
    }
    m_y = N_VNew_Serial(static_cast<sd_size_t>(m_neq)); // allocate solution vector
    N_VConst(0.0, m_y);
    // check abs tolerance array size
    if (m_itol == CV_SV && m_nabs < m_neq) {
        throw CanteraError("CVodesIntegrator::initialize",
                           "not enough absolute tolerance values specified.");
    }

    func.getState(NV_DATA_S(m_y));

    if (m_cvode_mem) {
        CVodeFree(&m_cvode_mem);
    }

    //! Specify the method and the iteration type. Cantera Defaults:
    //!        CV_BDF  - Use BDF methods
    //!        CV_NEWTON - use Newton's method
    m_cvode_mem = CVodeCreate(m_method, m_iter);
    if (!m_cvode_mem) {
        throw CanteraError("CVodesIntegrator::initialize",
                           "CVodeCreate failed.");
    }

    int flag = CVodeInit(m_cvode_mem, cvodes_rhs, m_t0, m_y);
    if (flag != CV_SUCCESS) {
        if (flag == CV_MEM_FAIL) {
            throw CanteraError("CVodesIntegrator::initialize",
                               "Memory allocation failed.");
        } else if (flag == CV_ILL_INPUT) {
            throw CanteraError("CVodesIntegrator::initialize",
                               "Illegal value for CVodeInit input argument.");
        } else {
            throw CanteraError("CVodesIntegrator::initialize",
                               "CVodeInit failed.");
        }
    }
    CVodeSetErrHandlerFn(m_cvode_mem, &cvodes_err, this);

    if (m_itol == CV_SV) {
        flag = CVodeSVtolerances(m_cvode_mem, m_reltol, m_abstol);
    } else {
        flag = CVodeSStolerances(m_cvode_mem, m_reltol, m_abstols);
    }
    if (flag != CV_SUCCESS) {
        if (flag == CV_MEM_FAIL) {
            throw CanteraError("CVodesIntegrator::initialize",
                               "Memory allocation failed.");
        } else if (flag == CV_ILL_INPUT) {
            throw CanteraError("CVodesIntegrator::initialize",
                               "Illegal value for CVodeInit input argument.");
        } else {
            throw CanteraError("CVodesIntegrator::initialize",
                               "CVodeInit failed.");
        }
    }

    flag = CVodeSetUserData(m_cvode_mem, &func);
    if (flag != CV_SUCCESS) {
        throw CanteraError("CVodesIntegrator::initialize",
                           "CVodeSetUserData failed.");
    }
    if (func.nparams() > 0) {
        sensInit(t0, func);
        flag = CVodeSetSensParams(m_cvode_mem, func.m_sens_params.data(),
                                  func.m_paramScales.data(), NULL);
        if (flag != CV_SUCCESS) {
            throw CanteraError("CVodesIntegrator::initialize",
                               "CVodeSetSensParams failed.");
        }
    }
    applyOptions();
}