/* Copyright 2012 SINTEF ICT, Applied Mathematics. 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 . */ #if HAVE_CONFIG_H #include "config.h" #endif // HAVE_CONFIG_H #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace { void warnIfUnusedParams(const Opm::parameter::ParameterGroup& param) { if (param.anyUnused()) { std::cout << "-------------------- Unused parameters: --------------------\n"; param.displayUsage(); std::cout << "----------------------------------------------------------------" << std::endl; } } } // anon namespace // ----------------- Main program ----------------- int main(int argc, char** argv) { using namespace Opm; std::cout << "\n================ Test program for weakly compressible two-phase flow ===============\n\n"; parameter::ParameterGroup param(argc, argv, false); std::cout << "--------------- Reading parameters ---------------" << std::endl; // If we have a "deck_filename", grid and props will be read from that. bool use_deck = param.has("deck_filename"); boost::scoped_ptr deck; boost::scoped_ptr grid; boost::scoped_ptr props; boost::scoped_ptr rock_comp; BlackoilState state; // bool check_well_controls = false; // int max_well_control_iterations = 0; double gravity[3] = { 0.0 }; if (use_deck) { std::string deck_filename = param.get("deck_filename"); deck.reset(new EclipseGridParser(deck_filename)); // Grid init grid.reset(new GridManager(*deck)); // Rock and fluid init props.reset(new BlackoilPropertiesFromDeck(*deck, *grid->c_grid())); // check_well_controls = param.getDefault("check_well_controls", false); // max_well_control_iterations = param.getDefault("max_well_control_iterations", 10); // Rock compressibility. rock_comp.reset(new RockCompressibility(*deck)); // Gravity. gravity[2] = deck->hasField("NOGRAV") ? 0.0 : unit::gravity; // Init state variables (saturation and pressure). if (param.has("init_saturation")) { initStateBasic(*grid->c_grid(), *props, param, gravity[2], state); } else { initStateFromDeck(*grid->c_grid(), *props, *deck, gravity[2], state); } initBlackoilSurfvol(*grid->c_grid(), *props, state); } else { // Grid init. const int nx = param.getDefault("nx", 100); const int ny = param.getDefault("ny", 100); const int nz = param.getDefault("nz", 1); const double dx = param.getDefault("dx", 1.0); const double dy = param.getDefault("dy", 1.0); const double dz = param.getDefault("dz", 1.0); grid.reset(new GridManager(nx, ny, nz, dx, dy, dz)); // Rock and fluid init. props.reset(new BlackoilPropertiesBasic(param, grid->c_grid()->dimensions, grid->c_grid()->number_of_cells)); // Rock compressibility. rock_comp.reset(new RockCompressibility(param)); // Gravity. gravity[2] = param.getDefault("gravity", 0.0); // Init state variables (saturation and pressure). initStateBasic(*grid->c_grid(), *props, param, gravity[2], state); initBlackoilSurfvol(*grid->c_grid(), *props, state); } bool use_gravity = (gravity[0] != 0.0 || gravity[1] != 0.0 || gravity[2] != 0.0); const double *grav = use_gravity ? &gravity[0] : 0; // Initialising src int num_cells = grid->c_grid()->number_of_cells; std::vector src(num_cells, 0.0); if (use_deck) { // Do nothing, wells will be the driving force, not source terms. } else { // Compute pore volumes, in order to enable specifying injection rate // terms of total pore volume. std::vector porevol; if (rock_comp->isActive()) { computePorevolume(*grid->c_grid(), props->porosity(), *rock_comp, state.pressure(), porevol); } else { computePorevolume(*grid->c_grid(), props->porosity(), porevol); } const double tot_porevol_init = std::accumulate(porevol.begin(), porevol.end(), 0.0); const double default_injection = use_gravity ? 0.0 : 0.1; const double flow_per_sec = param.getDefault("injected_porevolumes_per_day", default_injection) *tot_porevol_init/unit::day; src[0] = flow_per_sec; src[num_cells - 1] = -flow_per_sec; } // Boundary conditions. FlowBCManager bcs; if (param.getDefault("use_pside", false)) { int pside = param.get("pside"); double pside_pressure = param.get("pside_pressure"); bcs.pressureSide(*grid->c_grid(), FlowBCManager::Side(pside), pside_pressure); } // Linear solver. LinearSolverFactory linsolver(param); // Write parameters used for later reference. bool output = param.getDefault("output", true); std::ofstream epoch_os; std::string output_dir; if (output) { output_dir = param.getDefault("output_dir", std::string("output")); boost::filesystem::path fpath(output_dir); try { create_directories(fpath); } catch (...) { THROW("Creating directories failed: " << fpath); } std::string filename = output_dir + "/epoch_timing.param"; epoch_os.open(filename.c_str(), std::fstream::trunc | std::fstream::out); // open file to clean it. The file is appended to in SimulatorTwophase filename = output_dir + "/step_timing.param"; std::fstream step_os(filename.c_str(), std::fstream::trunc | std::fstream::out); step_os.close(); param.writeParam(output_dir + "/simulation.param"); } std::cout << "\n\n================ Starting main simulation loop ===============\n" << " (number of epochs: " << (use_deck ? deck->numberOfEpochs() : 1) << ")\n\n" << std::flush; SimulatorReport rep; if (!use_deck) { // Simple simulation without a deck. WellsManager wells; // no wells. SimulatorCompressibleTwophase simulator(param, *grid->c_grid(), *props, rock_comp->isActive() ? rock_comp.get() : 0, wells, src, bcs.c_bcs(), linsolver, grav); SimulatorTimer simtimer; simtimer.init(param); warnIfUnusedParams(param); WellState well_state; well_state.init(0, state); rep = simulator.run(simtimer, state, well_state); } else { // With a deck, we may have more epochs etc. WellState well_state; int step = 0; SimulatorTimer simtimer; // Use timer for last epoch to obtain total time. deck->setCurrentEpoch(deck->numberOfEpochs() - 1); simtimer.init(*deck); const double total_time = simtimer.totalTime(); for (int epoch = 0; epoch < deck->numberOfEpochs(); ++epoch) { // Set epoch index. deck->setCurrentEpoch(epoch); // Update the timer. if (deck->hasField("TSTEP")) { simtimer.init(*deck); } else { if (epoch != 0) { THROW("No TSTEP in deck for epoch " << epoch); } simtimer.init(param); } simtimer.setCurrentStepNum(step); simtimer.setTotalTime(total_time); // Report on start of epoch. std::cout << "\n\n-------------- Starting epoch " << epoch << " --------------" << "\n (number of steps: " << simtimer.numSteps() - step << ")\n\n" << std::flush; // Create new wells, well_state WellsManager wells(*deck, *grid->c_grid(), props->permeability()); // @@@ HACK: we should really make a new well state and // properly transfer old well state to it every epoch, // since number of wells may change etc. if (epoch == 0) { well_state.init(wells.c_wells(), state); } // Create and run simulator. SimulatorCompressibleTwophase simulator(param, *grid->c_grid(), *props, rock_comp->isActive() ? rock_comp.get() : 0, wells, src, bcs.c_bcs(), linsolver, grav); if (epoch == 0) { warnIfUnusedParams(param); } SimulatorReport epoch_rep = simulator.run(simtimer, state, well_state); if (output) { epoch_rep.reportParam(epoch_os); } // Update total timing report and remember step number. rep += epoch_rep; step = simtimer.currentStepNum(); } } std::cout << "\n\n================ End of simulation ===============\n\n"; rep.report(std::cout); if (output) { std::string filename = output_dir + "/walltime.param"; std::fstream tot_os(filename.c_str(),std::fstream::trunc | std::fstream::out); rep.reportParam(tot_os); } }