field.impl.hh

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/*!
 *
 * Copyright (C) 2015 Technical University of Liberec.  All rights reserved.
 * 
 * This program is free software; you can redistribute it and/or modify it under
 * the terms of the GNU General Public License version 3 as published by the
 * Free Software Foundation. (http://www.gnu.org/licenses/gpl-3.0.en.html)
 * 
 * This program is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
 * FOR A PARTICULAR PURPOSE.  See the GNU General Public License for more details.
 *
 * 
 * @file    field.impl.hh
 * @brief   
 */
 
#ifndef FIELD_IMPL_HH_
#define FIELD_IMPL_HH_
 
#include "field.hh"
#include "field_algo_base.impl.hh"
#include "field_fe.hh"
#include "fields/eval_subset.hh"
#include "fields/eval_points.hh"
#include "fields/field_value_cache.hh"
#include "fields/field_set.hh"
#include "mesh/region.hh"
#include "input/reader_to_storage.hh"
#include "input/accessors.hh"
#include "io/observe.hh"
#include "io/output_mesh.hh"
#include "io/output_element.hh"
 
 
/******************************************************************************************
 * Implementation of Field<...>
 */
 
template<int spacedim, class Value>
Field<spacedim,Value>::Field()
: data_(std::make_shared<SharedData>()),
  value_cache_( FieldValueCache<typename Value::element_type>(Value::NRows_, Value::NCols_) )
{
    // n_comp is nonzero only for variable size vectors Vector, VectorEnum, ..
    // this invariant is kept also by n_comp setter
    shared_->n_comp_ = (Value::NRows_ ? 0 : 1);
    this->add_factory( std::make_shared<FactoryBase>() );
 
    unsigned int cache_size = 1.1 * CacheMapElementNumber::get();
    value_cache_.reinit(cache_size);
    value_cache_.resize(cache_size);
 
    this->multifield_ = false;
    this->set_shape( Value::NRows_, Value::NCols_ );
}
 
 
template<int spacedim, class Value>
Field<spacedim,Value>::Field(const string &name, bool bc)
: data_(std::make_shared<SharedData>()),
  value_cache_( FieldValueCache<typename Value::element_type>(Value::NRows_, Value::NCols_) )
{
        // n_comp is nonzero only for variable size vectors Vector, VectorEnum, ..
        // this invariant is kept also by n_comp setter
        shared_->n_comp_ = (Value::NRows_ ? 0 : 1);
        shared_->bc_=bc;
        this->name( name );
        this->add_factory( std::make_shared<FactoryBase>() );
        unsigned int cache_size = 1.1 * CacheMapElementNumber::get();
        value_cache_.reinit(cache_size);
        value_cache_.resize(cache_size);
 
        this->multifield_ = false;
        this->set_shape( Value::NRows_, Value::NCols_ );
}
 
 
 
template<int spacedim, class Value>
Field<spacedim,Value>::Field(unsigned int component_index, string input_name, string name, bool bc)
: data_(std::make_shared<SharedData>()),
  value_cache_( FieldValueCache<typename Value::element_type>(Value::NRows_, Value::NCols_) )
{
    // n_comp is nonzero only for variable size vectors Vector, VectorEnum, ..
    // this invariant is kept also by n_comp setter
    shared_->n_comp_ = (Value::NRows_ ? 0 : 1);
    this->set_component_index(component_index);
    this->name_ = (name=="") ? input_name : name;
    this->shared_->input_name_ = input_name;
    shared_->bc_ = bc;
 
    unsigned int cache_size = 1.1 * CacheMapElementNumber::get();
    value_cache_.reinit(cache_size);
    value_cache_.resize(cache_size);
 
    this->multifield_ = false;
    this->set_shape( Value::NRows_, Value::NCols_ );
}
 
 
template<int spacedim, class Value>
Field<spacedim,Value>::Field(const Field &other)
: FieldCommon(other),
  data_(other.data_),
  region_fields_(other.region_fields_),
  factories_(other.factories_),
  value_cache_(other.value_cache_)
{
    if (other.no_check_control_field_)
        no_check_control_field_ =  make_shared<ControlField>(*other.no_check_control_field_);
 
    this->multifield_ = false;
    this->set_shape( Value::NRows_, Value::NCols_ );
}
 
 
template<int spacedim, class Value>
Field<spacedim,Value> &Field<spacedim,Value>::operator=(const Field<spacedim,Value> &other)
{
    //ASSERT( flags().match(FieldFlag::input_copy) )(this->name())(other.name()).error("Try to assign to non-copy field from the field.");
    ASSERT(other.shared_->mesh_).error("Must call set_mesh before assign to other field.\n");
    ASSERT( !shared_->mesh_ || (shared_->mesh_==other.shared_->mesh_) ).error("Assignment between fields with different meshes.\n");
 
    // check for self assignement
    if (&other == this) return *this;
 
    // class members derived from FieldCommon
    shared_ = other.shared_;
    shared_->is_fully_initialized_ = false;
    set_time_result_ = other.set_time_result_;
    last_time_ = other.last_time_;
    last_limit_side_ = other.last_limit_side_;
    is_jump_time_ = other.is_jump_time_;
    component_index_ = other.component_index_;
    this->multifield_ = false;
 
    // class members of Field class
    data_ = other.data_;
    factories_ = other.factories_;
    region_fields_ = other.region_fields_;
    value_cache_ = other.value_cache_;
    this->shape_ = other.shape_;
 
    if (other.no_check_control_field_) {
        no_check_control_field_ =  make_shared<ControlField>(*other.no_check_control_field_);
    }
 
    return *this;
}
 
 
 
template<int spacedim, class Value>
typename Value::return_type Field<spacedim,Value>::operator() (BulkPoint &p) {
    return p.elm_cache_map()->get_value<Value>(value_cache_, p.elem_patch_idx(), p.eval_point_idx());
}
 
 
 
template<int spacedim, class Value>
typename Value::return_type Field<spacedim,Value>::operator() (EdgePoint &p) {
    return p.elm_cache_map()->get_value<Value>(value_cache_, p.elem_patch_idx(), p.eval_point_idx());
}
 
 
 
template<int spacedim, class Value>
typename Value::return_type Field<spacedim,Value>::operator() (CouplingPoint &p) {
    return p.elm_cache_map()->get_value<Value>(value_cache_, p.elem_patch_idx(), p.eval_point_idx());
}
 
 
 
template<int spacedim, class Value>
typename Value::return_type Field<spacedim,Value>::operator() (BoundaryPoint &p) {
    return p.elm_cache_map()->get_value<Value>(value_cache_, p.elem_patch_idx(), p.eval_point_idx());
}
 
 
 
template<int spacedim, class Value>
typename Value::return_type
Field<spacedim,Value>::operator[] (unsigned int i_cache_point) const
{
    return Value::get_from_array( this->value_cache_, i_cache_point );
}
 
 
 
template<int spacedim, class Value>
it::Instance Field<spacedim,Value>::get_input_type() {
    return FieldBaseType::get_input_type_instance(shared_->input_element_selection_);
}
 
 
 
template<int spacedim, class Value>
it::Array Field<spacedim,Value>::get_multifield_input_type() {
    ASSERT(false).error("This method can't be used for Field");
 
    it::Array arr = it::Array( it::Integer() );
    return arr;
}
 
 
 
template<int spacedim, class Value>
auto Field<spacedim, Value>::disable_where(
        const Field<spacedim, typename FieldValue<spacedim>::Enum > &control_field,
        const vector<FieldEnum> &value_list) -> Field &
{
    no_check_control_field_=std::make_shared<ControlField>(control_field);
    shared_->no_check_values_=value_list;
    return *this;
}
 
template<int spacedim, class Value>
void Field<spacedim,Value>::set_mesh(const Mesh &in_mesh) {
    // since we allow copy of fields before set_mesh is called
    // we have to check that all copies set the same mesh
    if (shared_->mesh_ && shared_->mesh_ != &in_mesh) {
        THROW(ExcFieldMeshDifference() << EI_Field(name()) );
    }
 
    shared_->mesh_ = &in_mesh;
 
    // initialize table if it is empty, we assume that the RegionDB is closed at this moment
    region_fields_.resize( mesh()->region_db().size() );
    RegionHistory init_history(history_length_limit_);  // capacity
    data_->region_history_.resize( mesh()->region_db().size(), init_history );
 
    if (no_check_control_field_) no_check_control_field_->set_mesh(in_mesh);
}
 
 
/*
template<int spacedim, class Value>
std::shared_ptr< typename Field<spacedim,Value>::FieldBaseType >
Field<spacedim,Value>::operator[] (Region reg)
{
    ASSERT_LT(reg.idx(), this->region_fields_.size());
    return this->region_fields_[reg.idx()];
}
*/
 
 
template <int spacedim, class Value>
bool Field<spacedim, Value>::is_constant(Region reg) {
    ASSERT(this->set_time_result_ != TimeStatus::unknown).error("Unknown time status.\n");
    ASSERT_LT(reg.idx(), this->region_fields_.size());
    FieldBasePtr region_field = this->region_fields_[reg.idx()];
    return ( region_field && region_field->is_constant_in_space() );
}
 
 
template<int spacedim, class Value>
void Field<spacedim, Value>::set(
        FieldBasePtr field,
        double time,
        std::vector<std::string> region_set_names)
{
    ASSERT_PTR(field).error("Null field pointer.\n");
 
    ASSERT_PTR( mesh() ).error("Null mesh pointer, set_mesh() has to be called before set().\n");
    ASSERT_EQ( field->n_comp() , shared_->n_comp_);
    field->set_mesh( mesh() , is_bc() );
 
    for (auto set_name : region_set_names) {
        RegionSet domain = mesh()->region_db().get_region_set(set_name);
        if (domain.size() == 0) continue;
 
        HistoryPoint hp = HistoryPoint(time, field);
        for(const Region &reg: domain) {
            RegionHistory &region_history = data_->region_history_[reg.idx()];
            // insert hp into descending time sequence
            ASSERT( region_history.size() == 0 || region_history[0].first < hp.first)(hp.first)(region_history[0].first)
                    .error("Can not insert smaller time then last time in field's history.\n");
            region_history.push_front(hp);
        }
    }
    set_history_changed();
}
 
 
 
template<int spacedim, class Value>
void Field<spacedim, Value>::set(
        const Input::AbstractRecord &a_rec,
        double time,
        std::vector<std::string> region_set_names)
{
    FieldAlgoBaseInitData init_data(input_name(), n_comp(), units(), limits(), flags());
    set(FieldBaseType::function_factory(a_rec, init_data), time, region_set_names);
}
 
 
 
template<int spacedim, class Value>
bool Field<spacedim, Value>::set_time(const TimeStep &time_step, LimitSide limit_side)
{
    ASSERT_PTR( mesh() )( name() ).error("NULL mesh pointer of field with given name. set_mesh must be called before.\n");
 
    // Skip setting time if the new time is equal to current time of the field
    // and if either the field is continuous in that time or the current limit side is same as the new one.
    if (time_step.end() == last_time_) {
        if ( ! is_jump_time() ||
             limit_side == last_limit_side_) {
            last_limit_side_ = limit_side;
            return changed();
        }
    }
 
    last_time_=time_step.end();
    last_limit_side_ = limit_side;
 
    // possibly update our control field
    if (no_check_control_field_) {
            no_check_control_field_->set_time(time_step, limit_side);
    }
        
    set_time_result_ = TimeStatus::constant;
    
    // read all descriptors satisfying time.ge(input_time)
    update_history(time_step);
    check_initialized_region_fields_();
 
    //
    is_jump_time_=false;
    // set time_step on all regions
    // for regions that match type of the field domain
    for(const Region &reg: mesh()->region_db().get_region_set("ALL") ) {
        auto rh = data_->region_history_[reg.idx()];
 
        // skip regions with no matching BC flag
        if (reg.is_boundary() != is_bc()) continue;
 
        // Check regions with empty history, possibly set default.
        if ( rh.empty()) continue;
 
        double last_time_in_history = rh.front().first;
        unsigned int history_size=rh.size();
        unsigned int i_history;
        ASSERT( time_step.ge(last_time_in_history) ).error("Setting field time back in history not fully supported yet!");
 
        // set history index
        if ( time_step.gt(last_time_in_history) ) {
            // in smooth time_step
            i_history=0;
        } else {
            // time_step .eq. input_time; i.e. jump time
            is_jump_time_=true;
            if (limit_side == LimitSide::right) {
                i_history=0;
            } else {
                i_history=1;
            }
        }
        i_history=min(i_history, history_size - 1);
        ASSERT(i_history >= 0).error("Empty field history.");
        // possibly update field pointer
 
        auto new_ptr = rh.at(i_history).second;
        if (new_ptr != region_fields_[reg.idx()]) {
            region_fields_[reg.idx()]=new_ptr;
            set_time_result_ = TimeStatus::changed;
        }
        // let FieldBase implementation set the time
        if ( new_ptr->set_time(time_step) )  set_time_result_ = TimeStatus::changed;
 
    }
 
    return changed();
}
 
 
template<int spacedim, class Value>
void Field<spacedim, Value>::copy_from(const FieldCommon & other) {
    ASSERT( flags().match(FieldFlag::equation_input))(other.name().c_str())(this->name().c_str())
            .error("Can not copy to the non-input field.");
 
    // do not use copy if the field have its own input
    if ( flags().match(FieldFlag::declare_input)
         && this->shared_->input_list_.size() != 0 ) return;
 
    if (typeid(other) == typeid(*this)) {
        auto  const &other_field = dynamic_cast<  Field<spacedim, Value> const &>(other);
        this->operator=(other_field);
    }
}
 
 
 
template<int spacedim, class Value>
void Field<spacedim, Value>::field_output(std::shared_ptr<OutputTime> stream, OutputTime::DiscreteSpaceFlags type)
{
    // currently we cannot output boundary fields
    if (!is_bc()) {
        ASSERT( OutputTime::discrete_flags_defined(type) ).error();
        this->compute_field_data( type, stream);
    }
}
 
 
template<int spacedim, class Value>
void Field<spacedim, Value>::observe_output(std::shared_ptr<Observe> observe)
{
    typedef typename Value::element_type ElemType;
 
    if (observe->point_ds()->size() == 0) return;
 
    ElementDataCache<ElemType> &output_data = observe->prepare_compute_data<ElemType>(this->name(), this->time(),
                            (unsigned int)Value::NRows_, (unsigned int)Value::NCols_);
 
    unsigned int loc_point_time_index, ele_index;
    for(ObservePointAccessor op_acc : observe->local_range()) {
        loc_point_time_index = op_acc.loc_point_time_index();
        ele_index = op_acc.observe_point().element_idx();
        const Value &obs_value =
                        Value( const_cast<typename Value::return_type &>(
                                this->value(op_acc.observe_point().global_coords(),
                                        ElementAccessor<spacedim>(this->mesh(), ele_index)) ));
        ASSERT_EQ(output_data.n_comp(), obs_value.n_rows()*obs_value.n_cols()).error();
        output_data.store_value(loc_point_time_index, obs_value.mem_ptr());
    }
}
 
 
 
template<int spacedim, class Value>
FieldResult Field<spacedim,Value>::field_result( RegionSet region_set) const {
 
    FieldResult result_all = result_none;
    for(Region &reg : region_set) {
        auto f = region_fields_[reg.idx()];
        if (f) {
            FieldResult fr = f->field_result();
            if (result_all == result_none) // first region
                result_all = fr;
            else if (fr != result_all)
                result_all = result_other; // if results from individual regions are different
        } else return result_none; // if field is undefined on any region of the region set
    }
 
    if (result_all == result_constant && region_set.size() > 1)
        return result_other; // constant result for individual regions could be non-constant on the whole region set
 
    return result_all;
 
}
 
 
template<int spacedim, class Value>
std::string Field<spacedim,Value>::get_value_attribute() const
{
    int nrows = Value::NRows_;
    int ncols = Value::NCols_;
    string type = "Integer";
    if (std::is_floating_point<typename Value::element_type>::value)
        type = "Double";
 
    return fmt::format("{{ \"shape\": [ {}, {} ], \"type\": \"{}\", \"limit\": [ {}, {} ] }}",
                        nrows, ncols, type, this->limits().first, this->limits().second);
}
 
 
template<int spacedim, class Value>
void Field<spacedim,Value>::update_history(const TimeStep &time) {
    ASSERT_PTR( mesh() ).error("Null mesh pointer, set_mesh() has to be called before.\n");
 
    // read input up to given time
    double input_time;
    if (shared_->input_list_.size() != 0) {
        while( shared_->list_idx_ < shared_->input_list_.size()
               && time.ge( input_time = time.read_time( shared_->input_list_[shared_->list_idx_].find<Input::Tuple>("time") ) ) ) {
 
            const Input::Record & actual_list_item = shared_->input_list_[shared_->list_idx_];
            // get domain specification
            RegionSet domain;
            Input::Array domain_name_array;
            unsigned int id;
            if (actual_list_item.opt_val("region", domain_name_array)) {
                std::vector<string> domain_names = mesh()->region_db().get_and_check_operands(domain_name_array);
                domain = mesh()->region_db().union_set(domain_names);
 
            } else if (actual_list_item.opt_val("rid", id)) {
                Region region;
                try {
                    region = mesh()->region_db().find_id(id);
                } catch (RegionDB::ExcUniqueRegionId &e) {
                    e << actual_list_item.ei_address();
                    throw;
                }
                if (region.is_valid())
                    domain.push_back(region);
                else
                    THROW(RegionDB::ExcUnknownRegion() << RegionDB::EI_ID(id) );
            } else {
                THROW(ExcMissingDomain()
                        << actual_list_item.ei_address() );
            }
 
            // get field instance   
            for(auto rit = factories_.rbegin() ; rit != factories_.rend(); ++rit) {
                FieldBasePtr field_instance = (*rit)->create_field(actual_list_item, *this);
                if (field_instance)  // skip descriptors without related keys
                {
                    // add to history
                    ASSERT_EQ( field_instance->n_comp() , shared_->n_comp_);
                    field_instance->set_mesh( mesh() , is_bc() );
                    for(const Region &reg: domain) {
                        // if region history is empty, add new field
                        // or if region history is not empty and the input_time is higher, add new field
                        // otherwise (region history is not empty and the input_time is the same),
                        //      rewrite the region field
                        if( data_->region_history_[reg.idx()].size() == 0
                            || data_->region_history_[reg.idx()].back().first < input_time)
                        {
                            data_->region_history_[reg.idx()].push_front(
                                    HistoryPoint(input_time, field_instance));
                            //DebugOut() << "Update history" << print_var(this->name()) << print_var(reg.label()) << print_var(input_time);
                        }
                        else
                        {
                            data_->region_history_[reg.idx()].back() = 
                                    HistoryPoint(input_time, field_instance);
                        }
                    }
                    break;
                }
            }
 
            ++shared_->list_idx_;
        }
    }
}
 
template<int spacedim, class Value>
void Field<spacedim,Value>::check_initialized_region_fields_() {
    ASSERT_PTR(mesh()).error("Null mesh pointer.");
    //if (shared_->is_fully_initialized_) return;
 
    // check there are no empty field pointers, collect regions to be initialized from default value
    RegionSet regions_to_init; // empty vector
 
    for(const Region &reg : mesh()->region_db().get_region_set("ALL") )
        if (reg.is_boundary() == is_bc()) {             // for regions that match type of the field domain
            RegionHistory &rh = data_->region_history_[reg.idx()];
            if ( rh.empty() ||  ! rh[0].second)   // empty region history
            {
                // test if check is turned on and control field is FieldConst
                if (no_check_control_field_ && no_check_control_field_->is_constant(reg) ) {
                    // get constant enum value
                    auto elm = ElementAccessor<spacedim>(mesh(), reg);
                    FieldEnum value = no_check_control_field_->value(elm.centre(),elm);
                    // check that the value is in the disable list
                    if ( std::find(shared_->no_check_values_.begin(), shared_->no_check_values_.end(), value)
                             != shared_->no_check_values_.end() )
                        continue;                  // the field is not needed on this region
                }
                if (shared_->input_default_ != "") {    // try to use default
                    regions_to_init.push_back( reg );
                } else {
                    THROW( ExcMissingFieldValue() << EI_FieldInputName(input_name()) << EI_FieldName(name())
                            << EI_RegId(reg.id()) << EI_RegLabel(reg.label()) );
                }
            }
        }
 
    // possibly set from default value
    if ( regions_to_init.size() ) {
        std::string region_list;
        // has to deal with fact that reader can not deal with input consisting of simple values
        string default_input=input_default();
        auto input_type = get_input_type().make_instance().first;
        Input::ReaderToStorage reader( default_input, *input_type, Input::FileFormat::format_JSON );
 
        auto a_rec = reader.get_root_interface<Input::AbstractRecord>();
        FieldAlgoBaseInitData init_data(input_name(), n_comp(), units(), limits(), flags());
        auto field_ptr = FieldBaseType::function_factory( a_rec , init_data );
        field_ptr->set_mesh( mesh(), is_bc() );
        for(const Region &reg: regions_to_init) {
            data_->region_history_[reg.idx()]
                            .push_front(HistoryPoint( 0.0, field_ptr) );
            region_list+=" "+reg.label();
        }
        FieldCommon::messages_data_.push_back( MessageData(input_default(), name(), region_list) );
 
    }
    //shared_->is_fully_initialized_ = true;
}
 
 
template<int spacedim, class Value>
void Field<spacedim,Value>::add_factory(const std::shared_ptr<FactoryBase> factory) {
    factories_.push_back( factory );
}
 
 
template<int spacedim, class Value>
typename Field<spacedim,Value>::FieldBasePtr Field<spacedim,Value>::FactoryBase::create_field(Input::Record rec, const FieldCommon &field) {
    Input::AbstractRecord field_record;
    if (rec.opt_val(field.input_name(), field_record)) {
        FieldAlgoBaseInitData init_data(field.input_name(), field.n_comp(), field.units(), field.limits(), field.get_flags());
        return FieldBaseType::function_factory(field_record, init_data );
    }
    else
        return FieldBasePtr();
}
 
 
template<int spacedim, class Value>
bool Field<spacedim,Value>::FactoryBase::is_active_field_descriptor(const Input::Record &in_rec, const std::string &input_name) {
    return in_rec.find<Input::AbstractRecord>(input_name);
}
 
 
 
 
template<int spacedim, class Value>
void Field<spacedim,Value>::set_input_list(const Input::Array &list, const TimeGovernor &tg) {
    if (! flags().match(FieldFlag::declare_input)) return;
 
    // check that times forms ascending sequence
    double time,last_time=0.0;
 
    for (Input::Iterator<Input::Record> it = list.begin<Input::Record>();
                    it != list.end();
                    ++it) {
        for(auto rit = factories_.rbegin() ; rit != factories_.rend(); ++rit) {
            if ( (*rit)->is_active_field_descriptor( (*it), this->input_name() ) ) {
                shared_->input_list_.push_back( Input::Record( *it ) );
                time = tg.read_time( it->find<Input::Tuple>("time") );
                if (time < last_time) {
                    THROW( ExcNonascendingTime()
                            << EI_Time(time)
                            << EI_Field(input_name())
                            << it->ei_address());
                }
                last_time = time;
 
                break;
            }
        }
    }
 
}
 
 
 
template<int spacedim, class Value>
void Field<spacedim,Value>::compute_field_data(OutputTime::DiscreteSpaceFlags space_type, std::shared_ptr<OutputTime> stream) {
    typedef typename Value::element_type ElemType;
    for (uint i=0; i<OutputTime::N_DISCRETE_SPACES; ++i)
        if (space_type[i]) {
            OutputTime::DiscreteSpace type = OutputTime::DiscreteSpace(i);
 
            OutputTime::OutputDataPtr output_data_base = stream->prepare_compute_data<ElemType>(this->name(), type,
                    (unsigned int)Value::NRows_, (unsigned int)Value::NCols_);
 
            try{
                // try casting actual ElementDataCache
                if( ! output_data_base->is_dummy()){
                    auto output_data = std::dynamic_pointer_cast<ElementDataCache<ElemType>>(output_data_base);
                    fill_data_cache(type, stream, output_data);
                }
 
            } catch(const std::bad_cast& e){
                // skip
            }
        }
 
    /* Set the last time */
    stream->update_time(this->time());
 
}
 
template<int spacedim, class Value>
void Field<spacedim,Value>::fill_data_cache(OutputTime::DiscreteSpace space_type,
                                            std::shared_ptr<OutputTime> stream,
                                            std::shared_ptr<ElementDataCache<typename Value::element_type>> data_cache)
{
    std::shared_ptr<OutputMeshBase> output_mesh = stream->get_output_mesh_ptr();
    ASSERT(output_mesh);
 
    /* Copy data to array */
    switch(space_type) {
        case OutputTime::NODE_DATA:
        case OutputTime::CORNER_DATA: {
            unsigned int node_index = 0;
            for(const auto & ele : *output_mesh )
            {
                std::vector<Space<3>::Point> vertices = ele.vertex_list();
                for(unsigned int i=0; i < ele.n_nodes(); i++)
                {
                    const Value &node_value =
                            Value( const_cast<typename Value::return_type &>(
                                    this->value(vertices[i],
                                                ElementAccessor<spacedim>(ele.orig_mesh(), ele.orig_element_idx()) ))
                                );
                    ASSERT_EQ(data_cache->n_comp(), node_value.n_rows()*node_value.n_cols()).error();
                    data_cache->store_value(node_index, node_value.mem_ptr() );
                    ++node_index;
                }
            }
        }
        break;
        case OutputTime::ELEM_DATA: {
            for(const auto & ele : *output_mesh )
            {
                unsigned int ele_index = ele.idx();
                const Value &ele_value =
                            Value( const_cast<typename Value::return_type &>(
                                    this->value(ele.centre(),
                                                ElementAccessor<spacedim>(ele.orig_mesh(), ele.orig_element_idx()))
                                                                            )
                                );
                ASSERT_EQ(data_cache->n_comp(), ele_value.n_rows()*ele_value.n_cols()).error();
                data_cache->store_value(ele_index, ele_value.mem_ptr() );
            }
        }
        break;
        case OutputTime::NATIVE_DATA: {
            std::shared_ptr< FieldFE<spacedim, Value> > field_fe_ptr = this->get_field_fe();
 
            if (field_fe_ptr) {
                auto native_output_data_base = stream->prepare_compute_data<double>(this->name(), space_type,
                        (unsigned int)Value::NRows_, (unsigned int)Value::NCols_,
                        typeid(field_fe_ptr->get_dofhandler()->ds()->fe()[0_d].get()).name(),  // should be used better solution of fe_type setting
                                                                                               // e.g. method 'name()' of FiniteElement and descendants
                        field_fe_ptr->get_dofhandler()->max_elem_dofs());
                // try casting actual ElementDataCache
                auto native_output_data = std::dynamic_pointer_cast<ElementDataCache<double>>(native_output_data_base);
                field_fe_ptr->native_data_to_cache(*native_output_data);
            } else {
                WarningOut().fmt("Field '{}' of native data space type is not of type FieldFE. Output will be skipped.\n", this->name());
            }
        }
        break;
        case OutputTime::MESH_DEFINITION:
        case OutputTime::UNDEFINED:
            //should not happen
        break;
    }
}
 
template<int spacedim, class Value>
std::shared_ptr< FieldFE<spacedim, Value> > Field<spacedim,Value>::get_field_fe() {
    ASSERT_EQ_DBG(this->mesh()->region_db().size(), region_fields_.size()).error();
    ASSERT(!this->shared_->bc_).error("FieldFE output of native data is supported only for bulk fields!");
 
    std::shared_ptr< FieldFE<spacedim, Value> > field_fe_ptr;
 
    bool is_fe = (region_fields_.size()>0); // indicate if FieldFE is defined on all bulk regions
    is_fe = is_fe && region_fields_[1] && (typeid(*region_fields_[1]) == typeid(FieldFE<spacedim, Value>));
    for (unsigned int i=3; i<2*this->mesh()->region_db().bulk_size(); i+=2)
        if (!region_fields_[i] || (region_fields_[i] != region_fields_[1])) {
            is_fe = false;
            break;
        }
    if (is_fe) {
        field_fe_ptr = std::dynamic_pointer_cast<  FieldFE<spacedim, Value> >( region_fields_[1] );
    }
 
    return field_fe_ptr;
}
 
 
template<int spacedim, class Value>
void Field<spacedim, Value>::cache_reallocate(const ElementCacheMap &cache_map, unsigned int region_idx) const {
    // Call cache_reinit of FieldAlgoBase descendant on appropriate region
    if (region_fields_[region_idx] != nullptr)
        region_fields_[region_idx]->cache_reinit(cache_map);
}
 
 
template<int spacedim, class Value>
void Field<spacedim, Value>::cache_update(ElementCacheMap &cache_map, unsigned int region_patch_idx) const {
    unsigned int region_idx = cache_map.region_idx_from_chunk_position(region_patch_idx);
    if (region_fields_[region_idx] != nullptr) // skips bounadry regions for bulk fields and vice versa
        region_fields_[region_idx]->cache_update(value_cache_, cache_map, region_patch_idx);
}
 
 
template<int spacedim, class Value>
std::vector<const FieldCommon *> Field<spacedim, Value>::set_dependency(FieldSet &field_set, unsigned int i_reg) const {
    if (region_fields_[i_reg] != nullptr) return region_fields_[i_reg]->set_dependency(field_set);
    else return std::vector<const FieldCommon *>();
}
 
 
template<int spacedim, class Value>
FieldValueCache<double> * Field<spacedim, Value>::value_cache() {
    return &value_cache_;
}
 
 
template<>
FieldValueCache<double> * Field<3, FieldValue<0>::Enum>::value_cache() {
    return nullptr;
}
 
template<>
FieldValueCache<double> * Field<3, FieldValue<0>::Integer>::value_cache() {
    return nullptr;
}
 
 
template<int spacedim, class Value>
const FieldValueCache<double> * Field<spacedim, Value>::value_cache() const {
    return &value_cache_;
}
 
 
template<>
const FieldValueCache<double> * Field<3, FieldValue<0>::Enum>::value_cache() const {
    return nullptr;
}
 
template<>
const FieldValueCache<double> * Field<3, FieldValue<0>::Integer>::value_cache() const {
    return nullptr;
}
 
 
 
 
#endif /* FIELD_IMPL_HH_ */