opm-simulators/opm/core/pressure/FlowBCManager.cpp

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/*
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 <http://www.gnu.org/licenses/>.
*/
#include <opm/core/pressure/FlowBCManager.hpp>
#include <opm/core/utility/ErrorMacros.hpp>
#include <opm/core/grid.h>
#include <vector>
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namespace Opm
{
namespace
{
std::string sideString(FlowBCManager::Side s);
void findSideFaces(const UnstructuredGrid& grid,
const FlowBCManager::Side side,
std::vector<int>& faces);
} // anon namespace
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/// Default constructor sets up empty boundary conditions.
/// By convention, this is equivalent to all-noflow conditions.
FlowBCManager::FlowBCManager()
: bc_(0)
{
bc_ = flow_conditions_construct(0);
if (!bc_) {
THROW("Failed to construct FlowBoundaryConditions struct.");
}
}
/// Destructor.
FlowBCManager::~FlowBCManager()
{
flow_conditions_destroy(bc_);
}
/// Remove all appended BCs.
/// By convention, BCs are now equivalent to all-noflow conditions.
void FlowBCManager::clear()
{
flow_conditions_clear(bc_);
}
/// Append a single boundary condition.
/// If the type is BC_NOFLOW the value argument is not used.
/// If the type is BC_PRESSURE the value argument is a pressure value.
/// If the type is BC_FLUX_TOTVOL the value argument is a total flux value (m^3/s).
/// Note: unset boundary conditions are noflow by convention,
/// so it is normally not necessary to explicitly append
/// BC_NOFLOW conditions. However, it may make sense to do so
/// if the bc will change during a simulation run.
/// Note: if normal velocity bcs are desired, convert to
/// fluxes by multiplying with face area.
void FlowBCManager::append(const FlowBCType type,
const int face,
const double value)
{
int ok = flow_conditions_append(type, face, value, bc_);
if (!ok) {
THROW("Failed to append boundary condition for face " << face);
}
}
/// Add BC_PRESSURE boundary conditions to all faces on a given side.
/// The grid must have a logical cartesian structure, and grid
/// faces must be tagged (i.e. grid.cell_facetag must be
/// non-null). Only the set of faces adjacent to cells with
/// minimum/maximum I/J/K coordinate (depending on side) are
/// considered.
void FlowBCManager::pressureSide(const UnstructuredGrid& grid,
const Side side,
const double pressure)
{
std::vector<int> faces;
findSideFaces(grid, side, faces);
int ok = flow_conditions_append_multi(BC_PRESSURE, faces.size(), &faces[0], pressure, bc_);
if (!ok) {
THROW("Failed to append pressure boundary conditions for side " << sideString(side));
}
}
/// Add BC_FLUX_TOTVOL boundary conditions to all faces on a given side.
/// The grid must have a logical cartesian structure, and grid
/// faces must be tagged (i.e. grid.cell_facetag must be
/// non-null). Only the set of faces adjacent to cells with
/// minimum/maximum I/J/K coordinate (depending on side) are
/// considered.
/// The flux specified is taken to be the total flux through
/// the side, each individual face receiving a part of the
/// total flux in proportion to its area, so that all faces
/// will have identical normal velocities.
void FlowBCManager::fluxSide(const UnstructuredGrid& grid,
const Side side,
const double flux)
{
// Find side faces.
std::vector<int> faces;
findSideFaces(grid, side, faces);
// Compute total area of faces.
double tot_area = 0.0;
for (int fi = 0; fi < int(faces.size()); ++fi) {
tot_area += grid.face_areas[faces[fi]];
}
// Append flux conditions for all the faces individually.
for (int fi = 0; fi < int(faces.size()); ++fi) {
const double face_flux = flux * grid.face_areas[faces[fi]] / tot_area;
int ok = flow_conditions_append(BC_FLUX_TOTVOL, faces[fi], face_flux, bc_);
if (!ok) {
THROW("Failed to append flux boundary conditions for face " << faces[fi] << " on side " << sideString(side));
}
}
}
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/// Access the managed boundary conditions.
/// The method is named similarly to c_str() in std::string,
/// to make it clear that we are returning a C-compatible struct.
const FlowBoundaryConditions* FlowBCManager::c_bcs() const
{
return bc_;
}
// ------ Utility functions ------
namespace
{
std::string sideString(FlowBCManager::Side s)
{
switch (s) {
case FlowBCManager::Xmin: return "Xmin";
case FlowBCManager::Xmax: return "Xmax";
case FlowBCManager::Ymin: return "Ymin";
case FlowBCManager::Ymax: return "Ymax";
case FlowBCManager::Zmin: return "Zmin";
case FlowBCManager::Zmax: return "Zmax";
default: THROW("Unknown side tag " << s);
}
}
void cartCoord(const int ndims,
const int log_cart_coord,
const int* dims,
int* ijk)
{
int ix = log_cart_coord;
for (int dim = 0; dim < ndims; ++dim) {
ijk[dim] = ix % dims[dim];
ix /= dims[dim];
}
ASSERT2 (ix == 0,
"Lexicographic index is not consistent "
"with grid dimensions.");
}
/// The grid must have a logical cartesian structure, and grid
/// faces must be tagged (i.e. grid.cell_facetag must be
/// non-null). Only the set of faces adjacent to cells with
/// minimum/maximum I/J/K coordinate (depending on side) are
/// considered.
void findSideFaces(const UnstructuredGrid& grid,
const FlowBCManager::Side side,
std::vector<int>& faces)
{
if (grid.cell_facetag == 0) {
THROW("Faces not tagged - cannot extract " << sideString(side) << " faces.");
}
ASSERT2 (grid.dimensions <= 3,
"Grid must have three dimensions or less.");
ASSERT2 (side < 2 * grid.dimensions,
"Boundary condition side not consistent with "
"number of physical grid dimensions.");
// Get all boundary faces with the correct tag and with
// min/max i/j/k (depending on side).
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const int correct_ijk = (side % 2) ? grid.cartdims[side/2] - 1 : 0;
for (int c = 0; c < grid.number_of_cells; ++c) {
int ijk[3] = { -1, -1, -1 };
int gc = (grid.global_cell != 0) ? grid.global_cell[c] : c;
cartCoord(grid.dimensions, gc, grid.cartdims, ijk);
if (ijk[side/2] != correct_ijk) {
continue;
}
for (int hf = grid.cell_facepos[c]; hf < grid.cell_facepos[c + 1]; ++hf) {
if (grid.cell_facetag[hf] == side) {
// Tag is correct.
const int f = grid.cell_faces[hf];
if (grid.face_cells[2*f] == -1 || grid.face_cells[2*f + 1] == -1) {
// Face is on boundary.
faces.push_back(f);
} else {
THROW("Face not on boundary, even with correct tag and boundary cell. This should not occur.");
}
}
}
}
}
} // anon namespace
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} // namespace Opm