DiffusiveFluxKernelThermalized_double_precision.h

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//======================================================================================================================
//
//  This file is part of waLBerla. waLBerla 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.
//
//  waLBerla 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 waLBerla (see COPYING.txt). If not, see <http://www.gnu.org/licenses/>.
//
//! \\file DiffusiveFluxKernelThermalized_double_precision.h
//! \\author pystencils
//======================================================================================================================
 
// kernel generated with pystencils v1.3.3, lbmpy v1.3.3,
// lbmpy_walberla/pystencils_walberla from waLBerla commit
// b0842e1a493ce19ef1bbb8d2cf382fc343970a7f
 
#pragma once
#include "core/DataTypes.h"
#include "core/logging/Logging.h"
 
#include "domain_decomposition/BlockDataID.h"
#include "domain_decomposition/IBlock.h"
#include "domain_decomposition/StructuredBlockStorage.h"
#include "field/GhostLayerField.h"
#include "field/SwapableCompare.h"
#include <set>
 
#ifdef __GNUC__
#define RESTRICT __restrict__
#elif _MSC_VER
#define RESTRICT __restrict
#else
#define RESTRICT
#endif
 
#if (defined WALBERLA_CXX_COMPILER_IS_GNU) ||                                  \
    (defined WALBERLA_CXX_COMPILER_IS_CLANG)
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-parameter"
#pragma GCC diagnostic ignored "-Wreorder"
#endif
 
namespace walberla {
namespace pystencils {
 
class DiffusiveFluxKernelThermalized_double_precision {
public:
  DiffusiveFluxKernelThermalized_double_precision(
      BlockDataID jID_, BlockDataID rhoID_, double D, uint32_t field_size_0,
      uint32_t field_size_1, uint32_t field_size_2, uint32_t seed,
      uint32_t time_step)
      : jID(jID_), rhoID(rhoID_), D_(D), field_size_0_(field_size_0),
        field_size_1_(field_size_1), field_size_2_(field_size_2), seed_(seed),
        time_step_(time_step), configured_(false){};
 
  void run(IBlock *block);
 
  void runOnCellInterval(const shared_ptr<StructuredBlockStorage> &blocks,
                         const CellInterval &globalCellInterval,
                         cell_idx_t ghostLayers, IBlock *block);
 
  void operator()(IBlock *block) { run(block); }
 
  static std::function<void(IBlock *)>
  getSweep(const shared_ptr<DiffusiveFluxKernelThermalized_double_precision>
               &kernel) {
    return [kernel](IBlock *b) { kernel->run(b); };
  }
 
  static std::function<void(IBlock *)> getSweepOnCellInterval(
      const shared_ptr<DiffusiveFluxKernelThermalized_double_precision> &kernel,
      const shared_ptr<StructuredBlockStorage> &blocks,
      const CellInterval &globalCellInterval, cell_idx_t ghostLayers = 1) {
    return [kernel, blocks, globalCellInterval, ghostLayers](IBlock *b) {
      kernel->runOnCellInterval(blocks, globalCellInterval, ghostLayers, b);
    };
  }
 
  std::function<void(IBlock *)> getSweep() {
    return [this](IBlock *b) { this->run(b); };
  }
 
  std::function<void(IBlock *)>
  getSweepOnCellInterval(const shared_ptr<StructuredBlockStorage> &blocks,
                         const CellInterval &globalCellInterval,
                         cell_idx_t ghostLayers = 1) {
    return [this, blocks, globalCellInterval, ghostLayers](IBlock *b) {
      this->runOnCellInterval(blocks, globalCellInterval, ghostLayers, b);
    };
  }
 
  void configure(const shared_ptr<StructuredBlockStorage> &blocks,
                 IBlock *block) {
    Cell BlockCellBB = blocks->getBlockCellBB(*block).min();
    block_offset_0_ = uint32_t(BlockCellBB[0]);
    block_offset_1_ = uint32_t(BlockCellBB[1]);
    block_offset_2_ = uint32_t(BlockCellBB[2]);
    configured_ = true;
  }
 
  BlockDataID jID;
  BlockDataID rhoID;
  double D_;
  uint32_t block_offset_0_;
  uint32_t block_offset_1_;
  uint32_t block_offset_2_;
  uint32_t field_size_0_;
  uint32_t field_size_1_;
  uint32_t field_size_2_;
  uint32_t seed_;
  uint32_t time_step_;
  bool configured_;
};
 
} // namespace pystencils
} // namespace walberla
 
#if (defined WALBERLA_CXX_COMPILER_IS_GNU) ||                                  \
    (defined WALBERLA_CXX_COMPILER_IS_CLANG)
#pragma GCC diagnostic pop
#endif