C++ ObjRef::constantIndexCount方法代码示例

double SingleCellViewSimulation::requiredMemory()
{
    // Determine and return the amount of required memory to run our simulation
    // Note #1: we return the amount as a double rather than a qulonglong (as we
    //          do when retrieving the total/free amount of memory available;
    //          see [OpenCOR]/src/plugins/misc/Core/src/coreutils.cpp) in case a
    //          simulation requires an insane amount of memory...
    // Note #2: the 1 is for mPoints in SingleCellViewSimulationResults...

    iface::cellml_services::CellMLCompiledModel*
        compModel(mData->isDAETypeSolver() ?
                  static_cast<iface::cellml_services::CellMLCompiledModel*>
                  (mRuntime->daeCompiledModel()) :
                  static_cast<iface::cellml_services::CellMLCompiledModel*>
                  (mRuntime->odeCompiledModel()));
    ObjRef<iface::cellml_services::CodeInformation> codeInfo
        (compModel->codeInformation());

    // This is not very accurate at all, because the solver caches a lot more
    // information about the problem being solved, some of it bigger than any
    // of the below (e.g. Jacobian matricies. Given the solver dependence of
    // this size, I'm not sure this function is that useful.
    return 
        size() *
        (1 + codeInfo->constantIndexCount() + codeInfo->rateIndexCount() * 3 +
         codeInfo->algebraicIndexCount())
        * sizeof(double);
}

void SingleCellViewSimulationData::setupOverrides()
{
    iface::cellml_services::CellMLCompiledModel*
        compModel(isDAETypeSolver() ?
                  static_cast<iface::cellml_services::CellMLCompiledModel*>
                  (mRuntime->daeCompiledModel()) :
                  static_cast<iface::cellml_services::CellMLCompiledModel*>
                  (mRuntime->odeCompiledModel()));
    ObjRef<iface::cellml_services::CodeInformation> codeInfo
        (compModel->codeInformation());
    
    for (unsigned int i = 0; i < codeInfo->constantIndexCount(); i++)
        if (mInitialConstants[i] != mConstants[i])
            mIntegrationRun->setOverride(iface::cellml_services::CONSTANT,
                                         i, mConstants[i]);
    for (unsigned int i = 0; i < codeInfo->rateIndexCount(); i++)
        if (mInitialStates[i] != mStates[i])
            mIntegrationRun->setOverride(iface::cellml_services::STATE_VARIABLE,
                                         i, mStates[i]);
}

//.........这里部分代码省略.........
             << "double acos(double x);\n"
             << "double acosh(double x);\n"
             << "double asin(double x);\n"
             << "double asinh(double x);\n"
             << "double atan(double x);\n"
             << "double atanh(double x);\n"
             << "double ceil(double x);\n"
             << "double cos(double x);\n"
             << "double cosh(double x);\n"
             << "double tan(double x);\n"
             << "double tanh(double x);\n"
             << "double sin(double x);\n"
             << "double sinh(double x);\n"
             << "double exp(double x);\n"
             << "double floor(double x);\n"
             << "double pow(double x, double y);\n"
             << "double factorial(double x);\n"
             << "double log(double x);\n"
             << "double arbitrary_log(double x, double base);\n"
             << "double gcd_pair(double a, double b);\n"
             << "double lcm_pair(double a, double b);\n"
             << "double gcd_multi(unsigned int size, ...);\n"
             << "double lcm_multi(unsigned int size, ...);\n"
             << "double multi_min(unsigned int size, ...);\n"
             << "double multi_max(unsigned int size, ...);\n"
             << "void NR_MINIMISE(double(*func)"
                "(double VOI, double *C, double *R, double *S, double *A),"
                "double VOI, double *C, double *R, double *S, double *A, "
                "double *V);\n";
        std::wstring frag = cci->functionsString();
        code << ws2s(frag);

        int nAlgebraic = cci->algebraicIndexCount();
        int nConstants = cci->constantIndexCount();

        code << "\n\nvoid csim_rhs_routine(double VOI, double* CSIM_STATE, double* CSIM_RATE, double* CSIM_OUTPUT, "
             << "double* CSIM_INPUT)\n{\n\n"
             << "double DUMMY_ASSIGNMENT;\n"
             << "double CONSTANTS["
             << nConstants
             << "], ALGEBRAIC["
             << nAlgebraic
             << "];\n\n";

        /* initConsts - all variables which aren't state variables but have
         *              an initial_value attribute, and any variables & rates
         *              which follow.
         */
        code << ws2s(cci->initConstsString());

        /* rates      - All rates which are not static.
         */
        code << ws2s(cci->ratesString());

        /* variables  - All variables not computed by initConsts or rates
         *  (i.e., these are not required for the integration of the model and
         *   thus only need to be called for output or presentation or similar
         *   purposes)
         */
        code << ws2s(cci->variablesString());

        // add in the setting of any outputs that are not already defined
        for (unsigned int i=0; i < capi->cevas->length(); i++)
        {
            ObjRef<iface::cellml_services::ConnectedVariableSet> cvs = capi->cevas->getVariableSet(i);
            ObjRef<iface::cellml_api::CellMLVariable> sv = cvs->sourceVariable();

void SingleCellViewSimulationData::initialValuesIn()
{
    iface::cellml_services::CellMLCompiledModel*
        compModel(isDAETypeSolver() ?
                  static_cast<iface::cellml_services::CellMLCompiledModel*>
                  (mRuntime->daeCompiledModel()) :
                  static_cast<iface::cellml_services::CellMLCompiledModel*>
                  (mRuntime->odeCompiledModel()));
    ObjRef<iface::cellml_services::CodeInformation> codeInfo
        (compModel->codeInformation());

    mState = SingleCellViewSimulationData::SIMSTATE_GOT_IV;

    if (mDidReset)
    {
      mInitialConstants.clear();
      mInitialConstants.reserve(codeInfo->constantIndexCount());
      mInitialStates.clear();
      mInitialStates.reserve(codeInfo->rateIndexCount());
    }

    mConstants.clear();
    mConstants.reserve(codeInfo->constantIndexCount());

    std::cout << "Computed " << mIVGrabber->consts().size() << " constants and "
              << mIVGrabber->states().size() << " initial values." << std::endl;
        

    for (std::vector<double>::iterator i = mIVGrabber->consts().begin();
         i != mIVGrabber->consts().end(); i++) {
        if (mDidReset)
            mInitialConstants << *i;
        mConstants << *i;
    }

    std::vector<double>& computedData = mIVGrabber->states();
    mStates.clear();
    mStates.reserve(codeInfo->rateIndexCount());
    for (unsigned int i = 0; i < codeInfo->rateIndexCount(); i++) {
        double v = computedData[1 + i];
        if (mDidReset)
            mInitialStates << v;
        mStates << v;
    }

    mRates.clear();
    mRates.reserve(codeInfo->rateIndexCount());
    const unsigned int rateOffset = codeInfo->rateIndexCount() + 1;
    for (unsigned int i = 0; i < codeInfo->rateIndexCount(); i++) {
      mRates << computedData[rateOffset + i];
    }
    
    mAlgebraic.clear();
    mAlgebraic.reserve(codeInfo->algebraicIndexCount());
    const unsigned int algebraicOffset = codeInfo->rateIndexCount() * 2 + 1;
    for (unsigned int i = 0; i < codeInfo->algebraicIndexCount(); i++) {
      mAlgebraic << computedData[algebraicOffset + i];
    }

    emit updated();
    emit modified(this, !mDidReset);
}