xref: /libCEED/examples/fluids/navierstokes.h (revision 431cd09ad1a10ccea7826f0ddce8343dc129bbd9)

// Copyright (c) 2017-2022, Lawrence Livermore National Security, LLC and other CEED contributors.
// All Rights Reserved. See the top-level LICENSE and NOTICE files for details.
//
// SPDX-License-Identifier: BSD-2-Clause
//
// This file is part of CEED:  http://github.com/ceed

#ifndef libceed_fluids_examples_navier_stokes_h
#define libceed_fluids_examples_navier_stokes_h

#include <ceed.h>
#include <petscts.h>
#include <stdbool.h>

#include "./include/petsc_ops.h"
#include "qfunctions/newtonian_types.h"
#include "qfunctions/stabilization_types.h"

// -----------------------------------------------------------------------------
// PETSc Version
// -----------------------------------------------------------------------------
#if PETSC_VERSION_LT(3, 19, 0)
#error "PETSc v3.19 or later is required"
#endif

// -----------------------------------------------------------------------------
// Enums
// -----------------------------------------------------------------------------
// Translate PetscMemType to CeedMemType
static inline CeedMemType MemTypeP2C(PetscMemType mem_type) { return PetscMemTypeDevice(mem_type) ? CEED_MEM_DEVICE : CEED_MEM_HOST; }

// Advection - Wind Options
typedef enum {
  WIND_ROTATION    = 0,
  WIND_TRANSLATION = 1,
} WindType;
static const char *const WindTypes[] = {"rotation", "translation", "WindType", "WIND_", NULL};

// Advection - Bubble Types
typedef enum {
  BUBBLE_SPHERE   = 0,  // dim=3
  BUBBLE_CYLINDER = 1,  // dim=2
} BubbleType;
static const char *const BubbleTypes[] = {"sphere", "cylinder", "BubbleType", "BUBBLE_", NULL};

// Advection - Bubble Continuity Types
typedef enum {
  BUBBLE_CONTINUITY_SMOOTH     = 0,  // Original continuous, smooth shape
  BUBBLE_CONTINUITY_BACK_SHARP = 1,  // Discontinuous, sharp back half shape
  BUBBLE_CONTINUITY_THICK      = 2,  // Define a finite thickness
} BubbleContinuityType;
static const char *const BubbleContinuityTypes[] = {"smooth", "back_sharp", "thick", "BubbleContinuityType", "BUBBLE_CONTINUITY_", NULL};

// Euler - test cases
typedef enum {
  EULER_TEST_ISENTROPIC_VORTEX = 0,
  EULER_TEST_1                 = 1,
  EULER_TEST_2                 = 2,
  EULER_TEST_3                 = 3,
  EULER_TEST_4                 = 4,
  EULER_TEST_5                 = 5,
} EulerTestType;
static const char *const EulerTestTypes[] = {"isentropic_vortex", "test_1",      "test_2", "test_3", "test_4", "test_5",
                                             "EulerTestType",     "EULER_TEST_", NULL};

// Stabilization methods
static const char *const StabilizationTypes[] = {"none", "SU", "SUPG", "StabilizationType", "STAB_", NULL};

// Test mode type
typedef enum {
  TESTTYPE_NONE           = 0,
  TESTTYPE_SOLVER         = 1,
  TESTTYPE_TURB_SPANSTATS = 2,
  TESTTYPE_DIFF_FILTER    = 3,
} TestType;
static const char *const TestTypes[] = {"none", "solver", "turb_spanstats", "diff_filter", "TestType", "TESTTYPE_", NULL};

// Test mode type
typedef enum {
  SGS_MODEL_NONE        = 0,
  SGS_MODEL_DATA_DRIVEN = 1,
} SGSModelType;
static const char *const SGSModelTypes[] = {"none", "data_driven", "SGSModelType", "SGS_MODEL_", NULL};

// -----------------------------------------------------------------------------
// Structs
// -----------------------------------------------------------------------------
// Structs declarations
typedef struct AppCtx_private   *AppCtx;
typedef struct CeedData_private *CeedData;
typedef struct User_private     *User;
typedef struct Units_private    *Units;
typedef struct SimpleBC_private *SimpleBC;
typedef struct Physics_private  *Physics;

// Application context from user command line options
struct AppCtx_private {
  // libCEED arguments
  char     ceed_resource[PETSC_MAX_PATH_LEN];  // libCEED backend
  PetscInt degree;
  PetscInt q_extra;
  // Solver arguments
  MatType   amat_type;
  PetscBool pmat_pbdiagonal;
  // Post-processing arguments
  PetscInt  checkpoint_interval;
  PetscInt  viz_refine;
  PetscInt  cont_steps;
  PetscReal cont_time;
  char      cont_file[PETSC_MAX_PATH_LEN];
  char      cont_time_file[PETSC_MAX_PATH_LEN];
  char      output_dir[PETSC_MAX_PATH_LEN];
  PetscBool add_stepnum2bin;
  PetscBool checkpoint_vtk;
  // Problem type arguments
  PetscFunctionList problems;
  char              problem_name[PETSC_MAX_PATH_LEN];
  // Test mode arguments
  TestType    test_type;
  PetscScalar test_tol;
  char        test_file_path[PETSC_MAX_PATH_LEN];
  // Turbulent spanwise statistics
  PetscBool         turb_spanstats_enable;
  PetscInt          turb_spanstats_collect_interval;
  PetscInt          turb_spanstats_viewer_interval;
  PetscViewer       turb_spanstats_viewer;
  PetscViewerFormat turb_spanstats_viewer_format;
  // Wall forces
  struct {
    PetscInt          num_wall;
    PetscInt         *walls;
    PetscViewer       viewer;
    PetscViewerFormat viewer_format;
    PetscBool         header_written;
  } wall_forces;
  // Subgrid Stress Model
  SGSModelType sgs_model_type;
  // Differential Filtering
  PetscBool diff_filter_monitor;
};

// libCEED data struct
struct CeedData_private {
  CeedVector           x_coord, q_data;
  CeedBasis            basis_x, basis_xc, basis_q, basis_x_sur, basis_q_sur, basis_xc_sur;
  CeedElemRestriction  elem_restr_x, elem_restr_q, elem_restr_qd_i;
  CeedOperator         op_setup_vol;
  OperatorApplyContext op_ics_ctx;
  CeedQFunction        qf_setup_vol, qf_ics, qf_rhs_vol, qf_ifunction_vol, qf_setup_sur, qf_apply_inflow, qf_apply_inflow_jacobian, qf_apply_outflow,
      qf_apply_outflow_jacobian, qf_apply_freestream, qf_apply_freestream_jacobian;
};

typedef struct {
  DM                    dm;
  PetscSF               sf;  // For communicating child data to parents
  OperatorApplyContext  op_stats_collect_ctx, op_proj_rhs_ctx;
  PetscInt              num_comp_stats;
  Vec                   Child_Stats_loc, Parent_Stats_loc;
  KSP                   ksp;         // For the L^2 projection solve
  CeedScalar            span_width;  // spanwise width of the child domain
  PetscBool             do_mms_test;
  OperatorApplyContext  mms_error_ctx;
  CeedContextFieldLabel solution_time_label, previous_time_label;
} Span_Stats;

typedef struct {
  DM                   dm;
  PetscInt             num_comp;
  OperatorApplyContext l2_rhs_ctx;
  KSP                  ksp;
} *NodalProjectionData;

typedef struct {
  DM                   dm_sgs;
  PetscInt             num_comp_sgs;
  OperatorApplyContext op_nodal_evaluation_ctx, op_sgs_apply_ctx;
  CeedVector           sgs_nodal_ceed;
} *SGS_DD_Data;

typedef struct {
  DM                   dm_filter;
  CeedInt              num_comp_filter;
  OperatorApplyContext op_rhs_ctx;
  KSP                  ksp;
  PetscBool            do_mms_test;
} *DiffFilterData;

// PETSc user data
struct User_private {
  MPI_Comm             comm;
  DM                   dm;
  DM                   dm_viz;
  Mat                  interp_viz;
  Ceed                 ceed;
  Units                units;
  Vec                  M_inv, Q_loc, Q_dot_loc;
  Physics              phys;
  AppCtx               app_ctx;
  CeedVector           q_ceed, q_dot_ceed, g_ceed, coo_values_amat, coo_values_pmat, x_ceed;
  CeedOperator         op_rhs_vol, op_ifunction_vol, op_ifunction, op_ijacobian;
  OperatorApplyContext op_rhs_ctx, op_strong_bc_ctx;
  bool                 matrices_set_up;
  CeedScalar           time_bc_set;
  Span_Stats           spanstats;
  NodalProjectionData  grad_velo_proj;
  SGS_DD_Data          sgs_dd_data;
  DiffFilterData       diff_filter;
};

// Units
struct Units_private {
  // fundamental units
  PetscScalar meter;
  PetscScalar kilogram;
  PetscScalar second;
  PetscScalar Kelvin;
  // derived units
  PetscScalar Pascal;
  PetscScalar J_per_kg_K;
  PetscScalar m_per_squared_s;
  PetscScalar W_per_m_K;
  PetscScalar Joule;
};

// Boundary conditions
struct SimpleBC_private {
  PetscInt num_wall,  // Number of faces with wall BCs
      wall_comps[5],  // An array of constrained component numbers
      num_comps,
      num_slip[3],  // Number of faces with slip BCs
      num_inflow, num_outflow, num_freestream;
  PetscInt  walls[16], slips[3][16], inflows[16], outflows[16], freestreams[16];
  PetscBool user_bc;
};

// Struct that contains all enums and structs used for the physics of all problems
struct Physics_private {
  WindType              wind_type;
  BubbleType            bubble_type;
  BubbleContinuityType  bubble_continuity_type;
  EulerTestType         euler_test;
  StabilizationType     stab;
  PetscBool             implicit;
  StateVariable         state_var;
  PetscBool             has_curr_time;
  PetscBool             has_neumann;
  CeedContextFieldLabel solution_time_label;
  CeedContextFieldLabel stg_solution_time_label;
  CeedContextFieldLabel timestep_size_label;
  CeedContextFieldLabel ics_time_label;
  CeedContextFieldLabel ijacobian_time_shift_label;
};

typedef struct {
  CeedQFunctionUser    qfunction;
  const char          *qfunction_loc;
  CeedQFunctionContext qfunction_context;
} ProblemQFunctionSpec;

// Problem specific data
typedef struct ProblemData_private ProblemData;
struct ProblemData_private {
  CeedInt              dim, q_data_size_vol, q_data_size_sur, jac_data_size_sur;
  CeedScalar           dm_scale;
  ProblemQFunctionSpec setup_vol, setup_sur, ics, apply_vol_rhs, apply_vol_ifunction, apply_vol_ijacobian, apply_inflow, apply_outflow,
      apply_freestream, apply_inflow_jacobian, apply_outflow_jacobian, apply_freestream_jacobian;
  bool non_zero_time;
  PetscErrorCode (*bc)(PetscInt, PetscReal, const PetscReal[], PetscInt, PetscScalar[], void *);
  void     *bc_ctx;
  PetscBool bc_from_ics, use_strong_bc_ceed;
  PetscErrorCode (*print_info)(ProblemData *, AppCtx);
};

extern int FreeContextPetsc(void *);

// -----------------------------------------------------------------------------
// Set up problems
// -----------------------------------------------------------------------------
// Set up function for each problem
extern PetscErrorCode NS_GAUSSIAN_WAVE(ProblemData *problem, DM dm, void *ctx, SimpleBC bc);
extern PetscErrorCode NS_CHANNEL(ProblemData *problem, DM dm, void *ctx, SimpleBC bc);
extern PetscErrorCode NS_BLASIUS(ProblemData *problem, DM dm, void *ctx, SimpleBC bc);
extern PetscErrorCode NS_NEWTONIAN_IG(ProblemData *problem, DM dm, void *ctx, SimpleBC bc);
extern PetscErrorCode NS_DENSITY_CURRENT(ProblemData *problem, DM dm, void *ctx, SimpleBC bc);
extern PetscErrorCode NS_EULER_VORTEX(ProblemData *problem, DM dm, void *ctx, SimpleBC bc);
extern PetscErrorCode NS_SHOCKTUBE(ProblemData *problem, DM dm, void *ctx, SimpleBC bc);
extern PetscErrorCode NS_ADVECTION(ProblemData *problem, DM dm, void *ctx, SimpleBC bc);
extern PetscErrorCode NS_ADVECTION2D(ProblemData *problem, DM dm, void *ctx, SimpleBC bc);

// Print function for each problem
extern PetscErrorCode PRINT_NEWTONIAN(ProblemData *problem, AppCtx app_ctx);

extern PetscErrorCode PRINT_EULER_VORTEX(ProblemData *problem, AppCtx app_ctx);

extern PetscErrorCode PRINT_SHOCKTUBE(ProblemData *problem, AppCtx app_ctx);

extern PetscErrorCode PRINT_ADVECTION(ProblemData *problem, AppCtx app_ctx);

extern PetscErrorCode PRINT_ADVECTION2D(ProblemData *problem, AppCtx app_ctx);

// -----------------------------------------------------------------------------
// libCEED functions
// -----------------------------------------------------------------------------
// Utility function - essential BC dofs are encoded in closure indices as -(i+1).
PetscInt Involute(PetscInt i);

// Utility function to create local CEED restriction
PetscErrorCode CreateRestrictionFromPlex(Ceed ceed, DM dm, CeedInt height, DMLabel domain_label, CeedInt label_value, PetscInt dm_field,
                                         CeedElemRestriction *elem_restr);

// Utility function to get Ceed Restriction for each domain
PetscErrorCode GetRestrictionForDomain(Ceed ceed, DM dm, CeedInt height, DMLabel domain_label, PetscInt label_value, PetscInt dm_field, CeedInt Q,
                                       CeedInt q_data_size, CeedElemRestriction *elem_restr_q, CeedElemRestriction *elem_restr_x,
                                       CeedElemRestriction *elem_restr_qd_i);

// Utility function to create CEED Composite Operator for the entire domain
PetscErrorCode CreateOperatorForDomain(Ceed ceed, DM dm, SimpleBC bc, CeedData ceed_data, Physics phys, CeedOperator op_apply_vol,
                                       CeedOperator op_apply_ijacobian_vol, CeedInt height, CeedInt P_sur, CeedInt Q_sur, CeedInt q_data_size_sur,
                                       CeedInt jac_data_size_sur, CeedOperator *op_apply, CeedOperator *op_apply_ijacobian);

PetscErrorCode SetupLibceed(Ceed ceed, CeedData ceed_data, DM dm, User user, AppCtx app_ctx, ProblemData *problem, SimpleBC bc);

// -----------------------------------------------------------------------------
// Time-stepping functions
// -----------------------------------------------------------------------------
// Compute mass matrix for explicit scheme
PetscErrorCode ComputeLumpedMassMatrix(Ceed ceed, DM dm, CeedData ceed_data, Vec M);

// RHS (Explicit time-stepper) function setup
PetscErrorCode RHS_NS(TS ts, PetscReal t, Vec Q, Vec G, void *user_data);

// Implicit time-stepper function setup
PetscErrorCode IFunction_NS(TS ts, PetscReal t, Vec Q, Vec Q_dot, Vec G, void *user_data);

// User provided TS Monitor
PetscErrorCode TSMonitor_NS(TS ts, PetscInt step_no, PetscReal time, Vec Q, void *ctx);

// TS: Create, setup, and solve
PetscErrorCode TSSolve_NS(DM dm, User user, AppCtx app_ctx, Physics phys, Vec *Q, PetscScalar *f_time, TS *ts);

// Update Boundary Values when time has changed
PetscErrorCode UpdateBoundaryValues(User user, Vec Q_loc, PetscReal t);

// -----------------------------------------------------------------------------
// Setup DM
// -----------------------------------------------------------------------------
// Create mesh
PetscErrorCode CreateDM(MPI_Comm comm, ProblemData *problem, MatType, VecType, DM *dm);

// Set up DM
PetscErrorCode SetUpDM(DM dm, ProblemData *problem, PetscInt degree, SimpleBC bc, Physics phys);

// Refine DM for high-order viz
PetscErrorCode VizRefineDM(DM dm, User user, ProblemData *problem, SimpleBC bc, Physics phys);

// -----------------------------------------------------------------------------
// Process command line options
// -----------------------------------------------------------------------------
// Register problems to be available on the command line
PetscErrorCode RegisterProblems_NS(AppCtx app_ctx);

// Process general command line options
PetscErrorCode ProcessCommandLineOptions(MPI_Comm comm, AppCtx app_ctx, SimpleBC bc);

// -----------------------------------------------------------------------------
// Miscellaneous utility functions
// -----------------------------------------------------------------------------
PetscErrorCode ICs_FixMultiplicity(DM dm, CeedData ceed_data, User user, Vec Q_loc, Vec Q, CeedScalar time);

PetscErrorCode DMPlexInsertBoundaryValues_NS(DM dm, PetscBool insert_essential, Vec Q_loc, PetscReal time, Vec face_geom_FVM, Vec cell_geom_FVM,
                                             Vec grad_FVM);

// Compare reference solution values with current test run for CI
PetscErrorCode RegressionTests_NS(AppCtx app_ctx, Vec Q);

// Get error for problems with exact solutions
PetscErrorCode GetError_NS(CeedData ceed_data, DM dm, User user, Vec Q, PetscScalar final_time);

// Post-processing
PetscErrorCode PostProcess_NS(TS ts, CeedData ceed_data, DM dm, ProblemData *problem, User user, Vec Q, PetscScalar final_time);

// -- Gather initial Q values in case of continuation of simulation
PetscErrorCode SetupICsFromBinary(MPI_Comm comm, AppCtx app_ctx, Vec Q);

// Record boundary values from initial condition
PetscErrorCode SetBCsFromICs_NS(DM dm, Vec Q, Vec Q_loc);

// Versioning token for binary checkpoints
extern const PetscInt FLUIDS_FILE_TOKEN;

// Create appropriate mass qfunction based on number of components N
PetscErrorCode CreateMassQFunction(Ceed ceed, CeedInt N, CeedInt q_data_size, CeedQFunction *qf);

PetscErrorCode ComputeL2Projection(Vec source_vec, Vec target_vec, OperatorApplyContext rhs_matop_ctx, KSP ksp);

PetscErrorCode NodalProjectionDataDestroy(NodalProjectionData context);

PetscErrorCode PHASTADatFileOpen(const MPI_Comm comm, const char path[PETSC_MAX_PATH_LEN], const PetscInt char_array_len, PetscInt dims[2],
                                 FILE **fp);

PetscErrorCode PHASTADatFileGetNRows(const MPI_Comm comm, const char path[PETSC_MAX_PATH_LEN], PetscInt *nrows);

PetscErrorCode PHASTADatFileReadToArrayReal(const MPI_Comm comm, const char path[PETSC_MAX_PATH_LEN], PetscReal array[]);

// -----------------------------------------------------------------------------
// Turbulence Statistics Collection Functions
// -----------------------------------------------------------------------------

PetscErrorCode TurbulenceStatisticsSetup(Ceed ceed, User user, CeedData ceed_data, ProblemData *problem);
PetscErrorCode TSMonitor_TurbulenceStatistics(TS ts, PetscInt steps, PetscReal solution_time, Vec Q, void *ctx);
PetscErrorCode TurbulenceStatisticsDestroy(User user, CeedData ceed_data);

// -----------------------------------------------------------------------------
// Data-Driven Subgrid Stress (DD-SGS) Modeling Functions
// -----------------------------------------------------------------------------

PetscErrorCode SGS_DD_ModelSetup(Ceed ceed, User user, CeedData ceed_data, ProblemData *problem);
PetscErrorCode SGS_DD_DataDestroy(SGS_DD_Data sgs_dd_data);
PetscErrorCode SGS_DD_ModelApplyIFunction(User user, const Vec Q_loc, Vec G_loc);
PetscErrorCode VelocityGradientProjectionSetup(Ceed ceed, User user, CeedData ceed_data, ProblemData *problem);
PetscErrorCode VelocityGradientProjectionApply(User user, Vec Q_loc, Vec VelocityGradient);
PetscErrorCode GridAnisotropyTensorProjectionSetupApply(Ceed ceed, User user, CeedData ceed_data, CeedElemRestriction *elem_restr_grid_aniso,
                                                        CeedVector *grid_aniso_vector);
PetscErrorCode GridAnisotropyTensorCalculateCollocatedVector(Ceed ceed, User user, CeedData ceed_data, CeedElemRestriction *elem_restr_grid_aniso,
                                                             CeedVector *aniso_colloc_ceed, PetscInt *num_comp_aniso);

// -----------------------------------------------------------------------------
// Boundary Condition Related Functions
// -----------------------------------------------------------------------------

// Setup StrongBCs that use QFunctions
PetscErrorCode SetupStrongBC_Ceed(Ceed ceed, CeedData ceed_data, DM dm, User user, ProblemData *problem, SimpleBC bc, CeedInt Q_sur,
                                  CeedInt q_data_size_sur);

PetscErrorCode FreestreamBCSetup(ProblemData *problem, DM dm, void *ctx, NewtonianIdealGasContext newtonian_ig_ctx, const StatePrimitive *reference);
PetscErrorCode OutflowBCSetup(ProblemData *problem, DM dm, void *ctx, NewtonianIdealGasContext newtonian_ig_ctx, const StatePrimitive *reference);

// -----------------------------------------------------------------------------
// Differential Filtering Functions
// -----------------------------------------------------------------------------

PetscErrorCode DifferentialFilterSetup(Ceed ceed, User user, CeedData ceed_data, ProblemData *problem);
PetscErrorCode DifferentialFilterDataDestroy(DiffFilterData diff_filter);
PetscErrorCode TSMonitor_DifferentialFilter(TS ts, PetscInt steps, PetscReal solution_time, Vec Q, void *ctx);
PetscErrorCode DifferentialFilterApply(User user, const PetscReal solution_time, const Vec Q, Vec Filtered_Solution);
PetscErrorCode DifferentialFilter_MMS_ICSetup(ProblemData *problem);

#endif  // libceed_fluids_examples_navier_stokes_h