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/*

  Copyright 2024 Equinor ASA


  This file is part of the Open Porous Media project (OPM).


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  it under the terms of the GNU General Public License as published by

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#ifndef OPM_RESERVOIR_COUPLING_SLAVE_HPP

#define OPM_RESERVOIR_COUPLING_SLAVE_HPP


#include <opm/simulators/flow/rescoup/ReservoirCoupling.hpp>

#include <opm/simulators/flow/rescoup/ReservoirCouplingSlaveReportStep.hpp>

#include <opm/input/eclipse/Schedule/Schedule.hpp>

#include <opm/simulators/utils/ParallelCommunication.hpp>

#include <opm/simulators/timestepping/SimulatorTimer.hpp>

#include <opm/common/OpmLog/OpmLog.hpp>


#include <mpi.h>


#include <vector>


namespace Opm {


template <class Scalar>

class ReservoirCouplingSlaveReportStep;


template <class Scalar>


class ReservoirCouplingSlave {

public:

    using MessageTag = ReservoirCoupling::MessageTag;

    using Potentials = ReservoirCoupling::Potentials<Scalar>;

    using SlaveGroupInjectionData = ReservoirCoupling::SlaveGroupInjectionData<Scalar>;

    using SlaveGroupProductionData = ReservoirCoupling::SlaveGroupProductionData<Scalar>;

    using InjectionGroupTarget = ReservoirCoupling::InjectionGroupTarget<Scalar>;

    using MasterProductionLimits = typename ReservoirCoupling::MasterProductionLimits<Scalar>;

    using ProductionGroupConstraints = ReservoirCoupling::ProductionGroupConstraints<Scalar>;


    ReservoirCouplingSlave(

        const Parallel::Communication &comm, const Schedule &schedule, const SimulatorTimer &timer

    );

    bool activated() const { return activated_; }

    void clearDeferredLogger() { logger_.clearDeferredLogger(); }

    const Parallel::Communication& getComm() const { return comm_; }

    MPI_Comm getMasterComm() const { return slave_master_comm_; }

    const std::string& getSlaveName() const { return slave_name_; }

    const std::map<std::string, std::string>& getSlaveToMasterGroupNameMap() const {

        return slave_to_master_group_map_; }

    bool hasMasterInjectionTarget(const std::string& gname, const Phase phase) const;


    bool hasMasterProductionLimits(const std::string& gname) const;


    bool hasMasterProductionTarget(const std::string& gname) const;

    void initTimeStepping();

    bool isFirstSubstepOfSyncTimestep() const;

    bool isSlaveGroup(const std::string& group_name) const;

    ReservoirCoupling::Logger& logger() { return this->logger_; }

    ReservoirCoupling::Logger& logger() const { return this->logger_; }

    std::pair<Scalar, Group::InjectionCMode> masterInjectionTarget(

        const std::string& gname, const Phase phase) const;


    const MasterProductionLimits& masterProductionLimits(const std::string& gname) const;


    std::pair<Scalar, Group::ProductionCMode> masterProductionTarget(const std::string& gname) const;

    void maybeActivate(int report_step);

    std::size_t numSlaveGroups() const { return this->slave_group_order_.size(); }

    double receiveNextTimeStepFromMaster();

    std::pair<std::size_t, std::size_t> receiveNumGroupConstraintsFromMaster() const;

    void receiveInjectionGroupTargetsFromMaster(std::size_t num_targets);


    void receiveProductionGroupConstraintsFromMaster(std::size_t num_targets);


    void sendAndReceiveInitialData();

    void sendInjectionDataToMaster(const std::vector<SlaveGroupInjectionData> &injection_data) const;

    void sendNextReportDateToMasterProcess() const;

    void sendProductionDataToMaster(const std::vector<SlaveGroupProductionData> &production_data) const;

    void setDeferredLogger(DeferredLogger *deferred_logger) {

        this->logger_.setDeferredLogger(deferred_logger);

    }

    void setFirstSubstepOfSyncTimestep(bool value);

    const std::string& slaveGroupIdxToGroupName(std::size_t group_idx) const {

        return this->slave_group_order_.at(group_idx);

    }

    bool terminated() const { return this->terminated_; }


    bool maybeReceiveTerminateSignalFromMaster();


    void receiveTerminateAndDisconnect();


private:

    void checkGrupSlavGroupNames_();

    std::pair<double, bool> getGrupSlavActivationDateAndCheckHistoryMatchingMode_() const;

    bool historyMatchingMode_() const { return this->history_matching_mode_; }

    std::size_t numMasterGroups_() const { return this->slave_to_master_group_map_.size(); }

    void receiveMasterGroupNamesFromMasterProcess_();

    void receiveSlaveNameFromMasterProcess_();

    void saveMasterGroupNamesAsMapAndEstablishOrder_(const std::vector<char>& group_names);

    void sendActivationDateToMasterProcess_();

    void sendActivationHandshakeToMasterProcess_() const;

    void sendSimulationStartDateToMasterProcess_() const;


    const Parallel::Communication &comm_;

    const Schedule& schedule_;

    const SimulatorTimer &timer_;

    // MPI parent communicator for a slave process

    MPI_Comm slave_master_comm_{MPI_COMM_NULL};

    std::map<std::string, std::string> slave_to_master_group_map_;

    bool activated_{false};

    // True if the slave was terminated by the master process

    bool terminated_{false};

    // True if no GRUPMAST keyword in the master schedule and no GRUPSLAV keyword in the slave schedule

    bool history_matching_mode_{false};

    std::string slave_name_;  // This is the slave name as defined in the master process

    mutable ReservoirCoupling::Logger logger_;

    // Order of the slave groups. A mapping from slave group index to slave group name.

    // The indices are determined by the order the master process sends us the group names, see

    // receiveMasterGroupNamesFromMasterProcess_()

    // Later, the master process will send us group name indices, and not the group names themselves,

    // so we use this mapping to recover the slave group names from the indices.

    std::map<std::size_t, std::string> slave_group_order_;

    // Stores data that changes for a single report step or for timesteps within a report step.

    std::unique_ptr<ReservoirCouplingSlaveReportStep<Scalar>> report_step_data_{nullptr};

};


} // namespace Opm


#endif // OPM_RESERVOIR_COUPLING_SLAVE_HPP

Opm::DeferredLogger
Definition DeferredLogger.hpp:57

Opm::ReservoirCouplingSlaveReportStep
Manages slave-side reservoir coupling operations for a single report step.
Definition ReservoirCouplingSlaveReportStep.hpp:55

Opm::ReservoirCouplingSlave::masterProductionTarget
std::pair< Scalar, Group::ProductionCMode > masterProductionTarget(const std::string &gname) const
Get the master-imposed production target and control mode for a group.
Definition ReservoirCouplingSlave.cpp:138

Opm::ReservoirCouplingSlave::masterProductionLimits
const MasterProductionLimits & masterProductionLimits(const std::string &gname) const
Get the master-imposed per-rate-type production limits for a group.
Definition ReservoirCouplingSlave.cpp:129

Opm::ReservoirCouplingSlave::receiveInjectionGroupTargetsFromMaster
void receiveInjectionGroupTargetsFromMaster(std::size_t num_targets)
Receive injection group targets from master and store them locally.
Definition ReservoirCouplingSlave.cpp:206

Opm::ReservoirCouplingSlave::receiveProductionGroupConstraintsFromMaster
void receiveProductionGroupConstraintsFromMaster(std::size_t num_targets)
Receive production group constraints from master and store them locally.
Definition ReservoirCouplingSlave.cpp:249

Opm::ReservoirCouplingSlave::hasMasterInjectionTarget
bool hasMasterInjectionTarget(const std::string &gname, const Phase phase) const
Check if a master-imposed injection target exists for a group and phase.
Definition ReservoirCouplingSlave.cpp:68

Opm::ReservoirCouplingSlave::masterInjectionTarget
std::pair< Scalar, Group::InjectionCMode > masterInjectionTarget(const std::string &gname, const Phase phase) const
Get the master-imposed injection target and control mode for a group and phase.
Definition ReservoirCouplingSlave.cpp:120

Opm::ReservoirCouplingSlave::maybeReceiveTerminateSignalFromMaster
bool maybeReceiveTerminateSignalFromMaster()
Blocking receive for terminate/continue signal from master.
Definition ReservoirCouplingSlave.cpp:172

Opm::ReservoirCouplingSlave::hasMasterProductionTarget
bool hasMasterProductionTarget(const std::string &gname) const
Check if a master-imposed production target exists for a group.
Definition ReservoirCouplingSlave.cpp:86

Opm::ReservoirCouplingSlave::hasMasterProductionLimits
bool hasMasterProductionLimits(const std::string &gname) const
Check if master-imposed per-rate-type production limits exist for a group.
Definition ReservoirCouplingSlave.cpp:77

Opm::ReservoirCouplingSlave::receiveTerminateAndDisconnect
void receiveTerminateAndDisconnect()
Receive terminate signal from master and disconnect the intercommunicator.
Definition ReservoirCouplingSlave.cpp:258

Opm::ReservoirCoupling::Logger
Definition ReservoirCoupling.hpp:42

Opm::SimulatorTimer
Definition SimulatorTimer.hpp:39

Opm
This file contains a set of helper functions used by VFPProd / VFPInj.
Definition blackoilbioeffectsmodules.hh:45

Opm::ReservoirCoupling::InjectionGroupTarget
Definition ReservoirCoupling.hpp:235

Opm::ReservoirCoupling::MasterProductionLimits
Per-rate-type production limits received from master hierarchy.
Definition ReservoirCoupling.hpp:263

Opm::ReservoirCoupling::Potentials
Definition ReservoirCoupling.hpp:187

Opm::ReservoirCoupling::ProductionGroupConstraints
Definition ReservoirCoupling.hpp:245

Opm::ReservoirCoupling::SlaveGroupInjectionData
Definition ReservoirCoupling.hpp:229

Opm::ReservoirCoupling::SlaveGroupProductionData
Definition ReservoirCoupling.hpp:211