/* Copyright 2014 SINTEF ICT, Applied Mathematics. Copyright 2017 IRIS AS This file is part of the Open Porous Media project (OPM). OPM is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. OPM 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. You should have received a copy of the GNU General Public License along with OPM. If not, see . */ #ifndef OPM_WELLSTATEFULLYIMPLICITBLACKOIL_HEADER_INCLUDED #define OPM_WELLSTATEFULLYIMPLICITBLACKOIL_HEADER_INCLUDED #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace Opm { class ParallelWellInfo; class Schedule; /// The state of a set of wells, tailored for use by the fully /// implicit blackoil simulator. class WellState { public: static const uint64_t event_mask = ScheduleEvents::WELL_STATUS_CHANGE + ScheduleEvents::PRODUCTION_UPDATE + ScheduleEvents::INJECTION_UPDATE; virtual ~WellState() = default; // TODO: same definition with WellInterface, eventually they should go to a common header file. static const int Water = BlackoilPhases::Aqua; static const int Oil = BlackoilPhases::Liquid; static const int Gas = BlackoilPhases::Vapour; explicit WellState(const PhaseUsage& pu) { this->phase_usage_ = pu; } std::size_t size() const { return this->wells_.size(); } std::vector wells() const { return this->wells_.wells(); } int numWells() const { return this->size(); } const ParallelWellInfo& parallelWellInfo(std::size_t well_index) const; /// Allocate and initialize if wells is non-null. Also tries /// to give useful initial values to the bhp(), wellRates() /// and perfPhaseRatesORG() fields, depending on controls void init(const std::vector& cellPressures, const Schedule& schedule, const std::vector& wells_ecl, const std::vector>& parallel_well_info, const int report_step, const WellState* prevState, const std::vector>& well_perf_data, const SummaryState& summary_state); void resize(const std::vector& wells_ecl, const std::vector>& parallel_well_info, const Schedule& schedule, const bool handle_ms_well, const size_t numCells, const std::vector>& well_perf_data, const SummaryState& summary_state); void setCurrentWellRates(const std::string& wellName, const std::vector& new_rates ) { auto& [owner, rates] = this->well_rates.at(wellName); if (owner) rates = new_rates; } const std::vector& currentWellRates(const std::string& wellName) const; bool hasWellRates(const std::string& wellName) const { return this->well_rates.find(wellName) != this->well_rates.end(); } template void gatherVectorsOnRoot(const std::vector< data::Connection >& from_connections, std::vector< data::Connection >& to_connections, const Communication& comm) const; data::Wells report(const int* globalCellIdxMap, const std::function& wasDynamicallyClosed) const; void reportConnections(std::vector& connections, const PhaseUsage &pu, std::size_t well_index, const int* globalCellIdxMap) const; /// init the MS well related. void initWellStateMSWell(const std::vector& wells_ecl, const WellState* prev_well_state); static void calculateSegmentRates(const std::vector>& segment_inlets, const std::vector>&segment_perforations, const std::vector& perforation_rates, const int np, const int segment, std::vector& segment_rates); template void communicateGroupRates(const Comm& comm); template void updateGlobalIsGrup(const Comm& comm); bool isInjectionGrup(const std::string& name) const { return this->global_well_info.value().in_injecting_group(name); } bool isProductionGrup(const std::string& name) const { return this->global_well_info.value().in_producing_group(name); } double getALQ( const std::string& name) const { return this->alq_state.get(name); } void setALQ( const std::string& name, double value) { this->alq_state.set(name, value); } int gliftGetDebugCounter() { return this->alq_state.get_debug_counter(); } void gliftSetDebugCounter(int value) { return this->alq_state.set_debug_counter(value); } int gliftUpdateDebugCounter() { return this->alq_state.update_debug_counter(); } bool gliftCheckAlqOscillation(const std::string &name) const { return this->alq_state.oscillation(name); } int gliftGetAlqDecreaseCount(const std::string &name) { return this->alq_state.get_decrement_count(name); } int gliftGetAlqIncreaseCount(const std::string &name) { return this->alq_state.get_increment_count(name); } void gliftUpdateAlqIncreaseCount(const std::string &name, bool increase) { this->alq_state.update_count(name, increase); } void gliftTimeStepInit() { this->alq_state.reset_count(); } int wellNameToGlobalIdx(const std::string &name) { return this->global_well_info.value().well_index(name); } std::string globalIdxToWellName(const int index) { return this->global_well_info.value().well_name(index); } bool wellIsOwned(std::size_t well_index, const std::string& wellName) const; bool wellIsOwned(const std::string& wellName) const; void updateStatus(int well_index, Well::Status status); void openWell(int well_index); void shutWell(int well_index); void stopWell(int well_index); /// The number of phases present. int numPhases() const { return this->phase_usage_.num_phases; } const PhaseUsage& phaseUsage() const { return this->phase_usage_; } /// One rate per well and phase. std::vector& wellRates(std::size_t well_index) { return this->wells_[well_index].surface_rates; } const std::vector& wellRates(std::size_t well_index) const { return this->wells_[well_index].surface_rates; } const std::string& name(std::size_t well_index) const { return this->wells_.well_name(well_index); } std::optional index(const std::string& well_name) const { return this->wells_.well_index(well_name); } const SingleWellState& operator[](std::size_t well_index) const { return this->wells_[well_index]; } const SingleWellState& operator[](const std::string& well_name) const { return this->wells_[well_name]; } SingleWellState& operator[](std::size_t well_index) { return this->wells_[well_index]; } SingleWellState& operator[](const std::string& well_name) { return this->wells_[well_name]; } const SingleWellState& well(std::size_t well_index) const { return this->operator[](well_index); } const SingleWellState& well(const std::string& well_name) const { return this->operator[](well_name); } SingleWellState& well(std::size_t well_index) { return this->operator[](well_index); } SingleWellState& well(const std::string& well_name) { return this->operator[](well_name); } bool has(const std::string& well_name) const { return this->wells_.has(well_name); } private: PhaseUsage phase_usage_; // The wells_ variable is essentially a map of all the wells on the current // process. Observe that since a well can be split over several processes a // well might appear in the WellContainer on different processes. WellContainer wells_; // The members alq_state, global_well_info and well_rates are map like // structures which will have entries for *all* the wells in the system. // Use of std::optional<> here is a technical crutch, the // WellStateFullyImplicitBlackoil class should be default constructible, // whereas the GlobalWellInfo is not. std::optional global_well_info; ALQState alq_state; // The well_rates variable is defined for all wells on all processors. The // bool in the value pair is whether the current process owns the well or // not. std::map>> well_rates; data::Segment reportSegmentResults(const int well_id, const int seg_ix, const int seg_no) const; // If the ALQ has changed since the previous report step, // reset current_alq and update default_alq. ALQ is used for // constant lift gas injection and for gas lift optimization // (THP controlled wells). void updateWellsDefaultALQ(const std::vector& wells_ecl); /// Allocate and initialize if wells is non-null. /// Also tries to give useful initial values to the bhp() and /// wellRates() fields, depending on controls. The /// perfRates() field is filled with zero, and perfPress() /// with -1e100. void base_init(const std::vector& cellPressures, const std::vector& wells_ecl, const std::vector>& parallel_well_info, const std::vector>& well_perf_data, const SummaryState& summary_state); void initSingleWell(const std::vector& cellPressures, const Well& well, const std::vector& well_perf_data, const ParallelWellInfo& well_info, const SummaryState& summary_state); void initSingleProducer(const Well& well, const ParallelWellInfo& well_info, double pressure_first_connection, const std::vector& well_perf_data, const SummaryState& summary_state); void initSingleInjector(const Well& well, const ParallelWellInfo& well_info, double pressure_first_connection, const std::vector& well_perf_data, const SummaryState& summary_state); }; } // namespace Opm #endif // OPM_WELLSTATEFULLYIMPLICITBLACKOIL_HEADER_INCLUDED