1 // Copyright (c) 2017-2026, Lawrence Livermore National Security, LLC and other CEED contributors.
2 // All Rights Reserved. See the top-level LICENSE and NOTICE files for details.
3 //
4 // SPDX-License-Identifier: BSD-2-Clause
5 //
6 // This file is part of CEED: http://github.com/ceed
7
8 /// @file
9 /// Operator for Navier-Stokes example using PETSc
10 #include <ceed/types.h>
11 #ifndef CEED_RUNNING_JIT_PASS
12 #include <stdbool.h>
13 #endif
14
15 #include "newtonian_state.h"
16 #include "newtonian_types.h"
17 #include "utils.h"
18
19 #define BLASIUS_MAX_N_CHEBYSHEV 50
20
21 typedef struct BlasiusContext_ *BlasiusContext;
22 struct BlasiusContext_ {
23 bool implicit; // !< Using implicit timesteping or not
24 bool weakT; // !< flag to set Temperature weakly at inflow
25 CeedScalar delta0; // !< Boundary layer height at inflow
26 State S_infty;
27 CeedScalar T_wall; // !< Temperature at the wall
28 CeedScalar x_inflow; // !< Location of inflow in x
29 CeedScalar n_cheb; // !< Number of Chebyshev terms
30 CeedScalar *X; // !< Chebyshev polynomial coordinate vector (CPU only)
31 CeedScalar eta_max; // !< Maximum eta in the domain
32 CeedScalar Tf_cheb[BLASIUS_MAX_N_CHEBYSHEV]; // !< Chebyshev coefficient for f
33 CeedScalar Th_cheb[BLASIUS_MAX_N_CHEBYSHEV - 1]; // !< Chebyshev coefficient for h
34 struct NewtonianIdealGasContext_ newtonian_ctx;
35 };
36
37 // *****************************************************************************
38 // This helper function evaluates Chebyshev polynomials with a set of coefficients with all their derivatives represented as a recurrence table.
39 // *****************************************************************************
ChebyshevEval(int N,const double * Tf,double x,double eta_max,double * f)40 CEED_QFUNCTION_HELPER void ChebyshevEval(int N, const double *Tf, double x, double eta_max, double *f) {
41 double dX_deta = 2 / eta_max;
42 double table[4][3] = {
43 // Chebyshev polynomials T_0, T_1, T_2 of the first kind in (-1,1)
44 {1, x, 2 * x * x - 1},
45 {0, 1, 4 * x },
46 {0, 0, 4 },
47 {0, 0, 0 }
48 };
49 for (int i = 0; i < 4; i++) {
50 // i-th derivative of f
51 f[i] = table[i][0] * Tf[0] + table[i][1] * Tf[1] + table[i][2] * Tf[2];
52 }
53 for (int i = 3; i < N; i++) {
54 // T_n(x) = 2xT_{n-1}(x) - T_{n-2}(x)
55 table[0][i % 3] = 2 * x * table[0][(i - 1) % 3] - table[0][(i - 2) % 3];
56 // Differentiate Chebyshev polynomials with the recurrence relation
57 for (int j = 1; j < 4; j++) {
58 // T'_{n}(x)/n = 2T_{n-1}(x) + T'_{n-2}(x)/n-2
59 table[j][i % 3] = i * (2 * table[j - 1][(i - 1) % 3] + table[j][(i - 2) % 3] / (i - 2));
60 }
61 for (int j = 0; j < 4; j++) {
62 f[j] += table[j][i % 3] * Tf[i];
63 }
64 }
65 for (int i = 1; i < 4; i++) {
66 // Transform derivatives from Chebyshev [-1, 1] to [0, eta_max].
67 for (int j = 0; j < i; j++) f[i] *= dX_deta;
68 }
69 }
70
71 // *****************************************************************************
72 // This helper function computes the Blasius boundary layer solution.
73 // *****************************************************************************
BlasiusSolution(const BlasiusContext blasius,const CeedScalar x[3],const CeedScalar x0,const CeedScalar x_inflow,const CeedScalar rho_infty,CeedScalar * t12)74 State CEED_QFUNCTION_HELPER(BlasiusSolution)(const BlasiusContext blasius, const CeedScalar x[3], const CeedScalar x0, const CeedScalar x_inflow,
75 const CeedScalar rho_infty, CeedScalar *t12) {
76 CeedInt N = blasius->n_cheb;
77 CeedScalar mu = blasius->newtonian_ctx.mu;
78 State S_infty = blasius->S_infty;
79 CeedScalar nu = mu / rho_infty;
80 CeedScalar U_infty = sqrt(Dot3(S_infty.Y.velocity, S_infty.Y.velocity));
81 CeedScalar eta = x[1] * sqrt(U_infty / (nu * (x0 + x[0] - x_inflow)));
82 CeedScalar X = 2 * (eta / blasius->eta_max) - 1.;
83 CeedScalar Rd = GasConstant(&blasius->newtonian_ctx);
84
85 CeedScalar f[4], h[4];
86 ChebyshevEval(N, blasius->Tf_cheb, X, blasius->eta_max, f);
87 ChebyshevEval(N - 1, blasius->Th_cheb, X, blasius->eta_max, h);
88
89 *t12 = mu * U_infty * f[2] * sqrt(U_infty / (nu * (x0 + x[0] - x_inflow)));
90
91 CeedScalar Y[5];
92 Y[1] = U_infty * f[1];
93 Y[2] = 0.5 * sqrt(nu * U_infty / (x0 + x[0] - x_inflow)) * (eta * f[1] - f[0]);
94 Y[3] = 0.;
95 Y[4] = S_infty.Y.temperature * h[0];
96 Y[0] = rho_infty / h[0] * Rd * Y[4];
97 return StateFromY(&blasius->newtonian_ctx, Y);
98 }
99
100 // *****************************************************************************
101 // This QFunction sets a Blasius boundary layer for the initial condition
102 // *****************************************************************************
ICsBlasius(void * ctx,CeedInt Q,const CeedScalar * const * in,CeedScalar * const * out)103 CEED_QFUNCTION(ICsBlasius)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) {
104 const CeedScalar(*X)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[0];
105 CeedScalar(*q0)[CEED_Q_VLA] = (CeedScalar(*)[CEED_Q_VLA])out[0];
106
107 const BlasiusContext context = (BlasiusContext)ctx;
108 const NewtonianIdealGasContext gas = &context->newtonian_ctx;
109 const CeedScalar mu = context->newtonian_ctx.mu;
110 const CeedScalar delta0 = context->delta0;
111 const CeedScalar x_inflow = context->x_inflow;
112 CeedScalar t12;
113
114 const State S_infty = context->S_infty;
115 const CeedScalar U_infty = sqrt(Dot3(S_infty.Y.velocity, S_infty.Y.velocity));
116
117 const CeedScalar x0 = U_infty * S_infty.U.density / (mu * 25 / Square(delta0));
118
119 CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) {
120 const CeedScalar x[3] = {X[0][i], X[1][i], X[2][i]};
121 State s = BlasiusSolution(context, x, x0, x_inflow, S_infty.U.density, &t12);
122 CeedScalar q[5] = {0};
123
124 StateToQ(gas, s, q, gas->state_var);
125 for (CeedInt j = 0; j < 5; j++) q0[j][i] = q[j];
126 }
127 return 0;
128 }
129
130 // *****************************************************************************
Blasius_Inflow(void * ctx,CeedInt Q,const CeedScalar * const * in,CeedScalar * const * out)131 CEED_QFUNCTION(Blasius_Inflow)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) {
132 const BlasiusContext context = (BlasiusContext)ctx;
133 const CeedScalar(*q)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[0];
134 const CeedScalar(*q_data_sur) = in[2];
135 const CeedScalar(*X)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[3];
136 CeedScalar(*v)[CEED_Q_VLA] = (CeedScalar(*)[CEED_Q_VLA])out[0];
137 CeedScalar(*jac_data_sur) = context->newtonian_ctx.is_implicit ? out[1] : NULL;
138
139 const bool is_implicit = context->implicit;
140 const NewtonianIdealGasContext gas = &context->newtonian_ctx;
141 State S_infty = context->S_infty;
142 const CeedScalar rho_0 = S_infty.U.density;
143 const CeedScalar U_infty = sqrt(Dot3(S_infty.Y.velocity, S_infty.Y.velocity));
144 const CeedScalar x0 = U_infty * rho_0 / (gas->mu * 25 / Square(context->delta0));
145 const CeedScalar zeros[11] = {0.};
146
147 CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) {
148 CeedScalar wdetJb, norm[3];
149 QdataBoundaryUnpack_3D(Q, i, q_data_sur, &wdetJb, NULL, norm);
150 wdetJb *= is_implicit ? -1. : 1.;
151
152 // Calculate inflow values
153 const CeedScalar x[3] = {X[0][i], X[1][i], 0.};
154 CeedScalar t12;
155 State s = BlasiusSolution(context, x, x0, context->x_inflow, rho_0, &t12);
156 CeedScalar qi[5];
157 for (CeedInt j = 0; j < 5; j++) qi[j] = q[j][i];
158 State s_int = StateFromU(gas, qi);
159
160 // enabling user to choose between weak T and weak rho inflow
161 if (context->weakT) { // density from the current solution
162 s.U.density = s_int.U.density;
163 s.Y = StatePrimitiveFromConservative(gas, s.U);
164 } else { // Total energy from current solution
165 s.U.E_total = s_int.U.E_total;
166 s.Y = StatePrimitiveFromConservative(gas, s.U);
167 }
168
169 StateConservative Flux_inviscid[3];
170 FluxInviscid(&context->newtonian_ctx, s, Flux_inviscid);
171
172 const CeedScalar stress[3][3] = {
173 {0, t12, 0},
174 {t12, 0, 0},
175 {0, 0, 0}
176 };
177 const CeedScalar Fe[3] = {0}; // TODO: viscous energy flux needs grad temperature
178 CeedScalar Flux[5];
179 FluxTotal_Boundary(Flux_inviscid, stress, Fe, norm, Flux);
180 for (CeedInt j = 0; j < 5; j++) v[j][i] = -wdetJb * Flux[j];
181 if (is_implicit) StoredValuesPack(Q, i, 0, 11, zeros, jac_data_sur);
182 }
183 return 0;
184 }
185
186 // *****************************************************************************
Blasius_Inflow_Jacobian(void * ctx,CeedInt Q,const CeedScalar * const * in,CeedScalar * const * out)187 CEED_QFUNCTION(Blasius_Inflow_Jacobian)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) {
188 const CeedScalar(*dq)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[0];
189 const CeedScalar(*q_data_sur) = in[2];
190 const CeedScalar(*X)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[3];
191 CeedScalar(*v)[CEED_Q_VLA] = (CeedScalar(*)[CEED_Q_VLA])out[0];
192
193 const BlasiusContext context = (BlasiusContext)ctx;
194 const NewtonianIdealGasContext gas = &context->newtonian_ctx;
195 const bool is_implicit = context->implicit;
196 const CeedScalar Rd = GasConstant(gas);
197 const CeedScalar gamma = HeatCapacityRatio(gas);
198 const State S_infty = context->S_infty;
199 const CeedScalar rho_0 = S_infty.U.density;
200 const CeedScalar U_infty = sqrt(Dot3(S_infty.Y.velocity, S_infty.Y.velocity));
201 const CeedScalar x0 = U_infty * rho_0 / (gas->mu * 25 / Square(context->delta0));
202
203 CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) {
204 CeedScalar wdetJb, norm[3];
205 QdataBoundaryUnpack_3D(Q, i, q_data_sur, &wdetJb, NULL, norm);
206 wdetJb *= is_implicit ? -1. : 1.;
207
208 // Calculate inflow values
209 const CeedScalar x[3] = {X[0][i], X[1][i], X[2][i]};
210 CeedScalar t12;
211 State s = BlasiusSolution(context, x, x0, 0, rho_0, &t12);
212
213 // enabling user to choose between weak T and weak rho inflow
214 CeedScalar drho, dE, dP;
215 if (context->weakT) {
216 // rho should be from the current solution
217 drho = dq[0][i];
218 CeedScalar dE_internal = drho * gas->cv * S_infty.Y.temperature;
219 CeedScalar dE_kinetic = .5 * drho * Dot3(s.Y.velocity, s.Y.velocity);
220 dE = dE_internal + dE_kinetic;
221 dP = drho * Rd * S_infty.Y.temperature; // interior rho with exterior T
222 } else {
223 // rho specified, E_internal from solution
224 drho = 0;
225 dE = dq[4][i];
226 dP = dE * (gamma - 1.);
227 }
228
229 const CeedScalar u_normal = Dot3(norm, s.Y.velocity);
230
231 v[0][i] = -wdetJb * drho * u_normal;
232 for (int j = 0; j < 3; j++) {
233 v[j + 1][i] = -wdetJb * (drho * u_normal * s.Y.velocity[j] + norm[j] * dP);
234 }
235 v[4][i] = -wdetJb * u_normal * (dE + dP);
236 }
237 return 0;
238 }
239