// Copyright (c) 2017-2026, 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 /// @file /// Structs and helper functions regarding the state of a newtonian simulation #pragma once #include #ifndef CEED_RUNNING_JIT_PASS #include #endif #include "newtonian_types.h" #include "utils.h" typedef struct { CeedScalar density; CeedScalar momentum[3]; CeedScalar E_total; } StateConservative; typedef struct { StateConservative U; StatePrimitive Y; } State; CEED_QFUNCTION_HELPER void UnpackState_U(StateConservative s, CeedScalar U[5]) { U[0] = s.density; for (int i = 0; i < 3; i++) U[i + 1] = s.momentum[i]; U[4] = s.E_total; } CEED_QFUNCTION_HELPER void UnpackState_Y(StatePrimitive s, CeedScalar Y[5]) { Y[0] = s.pressure; for (int i = 0; i < 3; i++) Y[i + 1] = s.velocity[i]; Y[4] = s.temperature; } CEED_QFUNCTION_HELPER void UnpackState_V(StateEntropy s, CeedScalar V[5]) { V[0] = s.S_density; for (int i = 0; i < 3; i++) V[i + 1] = s.S_momentum[i]; V[4] = s.S_energy; } CEED_QFUNCTION_HELPER CeedScalar HeatCapacityRatio(NewtonianIdealGasContext gas) { return gas->cp / gas->cv; } CEED_QFUNCTION_HELPER CeedScalar GasConstant(NewtonianIdealGasContext gas) { return gas->cp - gas->cv; } CEED_QFUNCTION_HELPER CeedScalar Prandtl(NewtonianIdealGasContext gas) { return gas->cp * gas->mu / gas->k; } CEED_QFUNCTION_HELPER CeedScalar SoundSpeed(NewtonianIdealGasContext gas, CeedScalar T) { return sqrt(gas->cp * (HeatCapacityRatio(gas) - 1.) * T); } CEED_QFUNCTION_HELPER CeedScalar Mach(NewtonianIdealGasContext gas, CeedScalar T, CeedScalar u) { return u / SoundSpeed(gas, T); } CEED_QFUNCTION_HELPER CeedScalar TotalSpecificEnthalpy(NewtonianIdealGasContext gas, const State s) { CeedScalar e_kinetic = 0.5 * Dot3(s.Y.velocity, s.Y.velocity); CeedScalar e_internal = gas->cv * s.Y.temperature; return e_internal + e_kinetic + s.Y.pressure / s.U.density; } CEED_QFUNCTION_HELPER CeedScalar TotalSpecificEnthalpy_fwd(NewtonianIdealGasContext gas, const State s, const State ds) { CeedScalar de_kinetic = Dot3(ds.Y.velocity, s.Y.velocity); CeedScalar de_internal = gas->cv * ds.Y.temperature; return de_internal + de_kinetic + ds.Y.pressure / s.U.density - s.Y.pressure / Square(s.U.density) * ds.U.density; } CEED_QFUNCTION_HELPER StatePrimitive StatePrimitiveFromConservative(NewtonianIdealGasContext gas, StateConservative U) { StatePrimitive Y; for (CeedInt i = 0; i < 3; i++) Y.velocity[i] = U.momentum[i] / U.density; CeedScalar e_kinetic = .5 * Dot3(Y.velocity, Y.velocity); CeedScalar e_total = U.E_total / U.density; CeedScalar e_internal = e_total - e_kinetic; Y.temperature = e_internal / gas->cv; Y.pressure = (HeatCapacityRatio(gas) - 1) * U.density * e_internal; return Y; } CEED_QFUNCTION_HELPER StatePrimitive StatePrimitiveFromConservative_fwd(NewtonianIdealGasContext gas, State s, StateConservative dU) { StatePrimitive dY; for (CeedInt i = 0; i < 3; i++) { dY.velocity[i] = (dU.momentum[i] - s.Y.velocity[i] * dU.density) / s.U.density; } CeedScalar e_kinetic = .5 * Dot3(s.Y.velocity, s.Y.velocity); CeedScalar de_kinetic = Dot3(dY.velocity, s.Y.velocity); CeedScalar e_total = s.U.E_total / s.U.density; CeedScalar de_total = (dU.E_total - e_total * dU.density) / s.U.density; CeedScalar e_internal = e_total - e_kinetic; CeedScalar de_internal = de_total - de_kinetic; dY.temperature = de_internal / gas->cv; dY.pressure = (HeatCapacityRatio(gas) - 1) * (dU.density * e_internal + s.U.density * de_internal); return dY; } CEED_QFUNCTION_HELPER StateEntropy StateEntropyFromPrimitive(NewtonianIdealGasContext gas, StatePrimitive Y) { StateEntropy V; const CeedScalar gamma = HeatCapacityRatio(gas); const CeedScalar rho = Y.pressure / (GasConstant(gas) * Y.temperature); const CeedScalar entropy = log(Y.pressure) - gamma * log(rho); const CeedScalar rho_div_p = rho / Y.pressure; const CeedScalar e_kinetic = 0.5 * Dot3(Y.velocity, Y.velocity); V.S_density = (gamma - entropy) / (gamma - 1) - rho_div_p * e_kinetic; for (int i = 0; i < 3; i++) V.S_momentum[i] = rho_div_p * Y.velocity[i]; V.S_energy = -rho_div_p; return V; } CEED_QFUNCTION_HELPER StateEntropy StateEntropyFromPrimitive_fwd(NewtonianIdealGasContext gas, State s, StatePrimitive dY) { StateEntropy dV; const CeedScalar gamma = HeatCapacityRatio(gas); CeedScalar drho = (dY.pressure * s.Y.temperature - s.Y.pressure * dY.temperature) / (GasConstant(gas) * s.Y.temperature * s.Y.temperature); const CeedScalar e_kinetic = .5 * Dot3(s.Y.velocity, s.Y.velocity); const CeedScalar de_kinetic = Dot3(dY.velocity, s.Y.velocity); const CeedScalar rho_div_p = s.U.density / s.Y.pressure; const CeedScalar drho_div_p = (drho * s.Y.pressure - s.U.density * dY.pressure) / Square(s.Y.pressure); CeedScalar dentropy = dY.pressure / s.Y.pressure - gamma * drho / s.U.density; dV.S_density = -dentropy / (gamma - 1) - de_kinetic * rho_div_p - e_kinetic * drho_div_p; for (CeedInt i = 0; i < 3; i++) dV.S_momentum[i] = rho_div_p * dY.velocity[i] + drho_div_p * s.Y.velocity[i]; dV.S_energy = -drho_div_p; return dV; } CEED_QFUNCTION_HELPER StatePrimitive StatePrimitiveFromEntropy(NewtonianIdealGasContext gas, StateEntropy V) { StatePrimitive Y; for (int i = 0; i < 3; i++) Y.velocity[i] = -V.S_momentum[i] / V.S_energy; Y.temperature = -1 / (GasConstant(gas) * V.S_energy); const CeedScalar gamma = HeatCapacityRatio(gas); const CeedScalar e_kinetic = 0.5 * Dot3(Y.velocity, Y.velocity); const CeedScalar entropy = gamma - (gamma - 1) * (V.S_density - e_kinetic * V.S_energy); const CeedScalar log_P = -(entropy + gamma * log(-V.S_energy)) / (gamma - 1); Y.pressure = exp(log_P); return Y; } CEED_QFUNCTION_HELPER StatePrimitive StatePrimitiveFromEntropy_fwd(NewtonianIdealGasContext gas, State s, StateEntropy dV) { StatePrimitive dY; StateEntropy V = StateEntropyFromPrimitive(gas, s.Y); for (int i = 0; i < 3; i++) dY.velocity[i] = -(dV.S_momentum[i] - V.S_momentum[i] * dV.S_energy / V.S_energy) / V.S_energy; dY.temperature = dV.S_energy / (GasConstant(gas) * V.S_energy * V.S_energy); const CeedScalar gamma = HeatCapacityRatio(gas); const CeedScalar e_kinetic = 0.5 * Dot3(s.Y.velocity, s.Y.velocity); const CeedScalar de_kinetic = Dot3(dY.velocity, s.Y.velocity); const CeedScalar dentropy = (1 - gamma) * (dV.S_density - e_kinetic * dV.S_energy - de_kinetic * V.S_energy); dY.pressure = s.Y.pressure * (-dentropy - gamma * dV.S_energy / V.S_energy) / (gamma - 1); return dY; } CEED_QFUNCTION_HELPER StateConservative StateConservativeFromPrimitive(NewtonianIdealGasContext gas, StatePrimitive Y) { StateConservative U; U.density = Y.pressure / (GasConstant(gas) * Y.temperature); for (int i = 0; i < 3; i++) U.momentum[i] = U.density * Y.velocity[i]; CeedScalar e_internal = gas->cv * Y.temperature; CeedScalar e_kinetic = .5 * Dot3(Y.velocity, Y.velocity); CeedScalar e_total = e_internal + e_kinetic; U.E_total = U.density * e_total; return U; } CEED_QFUNCTION_HELPER StateConservative StateConservativeFromPrimitive_fwd(NewtonianIdealGasContext gas, State s, StatePrimitive dY) { StateConservative dU; dU.density = (dY.pressure * s.Y.temperature - s.Y.pressure * dY.temperature) / (GasConstant(gas) * s.Y.temperature * s.Y.temperature); for (int i = 0; i < 3; i++) { dU.momentum[i] = dU.density * s.Y.velocity[i] + s.U.density * dY.velocity[i]; } CeedScalar e_kinetic = .5 * Dot3(s.Y.velocity, s.Y.velocity); CeedScalar de_kinetic = Dot3(dY.velocity, s.Y.velocity); CeedScalar e_internal = gas->cv * s.Y.temperature; CeedScalar de_internal = gas->cv * dY.temperature; CeedScalar e_total = e_internal + e_kinetic; CeedScalar de_total = de_internal + de_kinetic; dU.E_total = dU.density * e_total + s.U.density * de_total; return dU; } CEED_QFUNCTION_HELPER StateEntropy StateEntropyFromConservative(NewtonianIdealGasContext gas, StateConservative U) { StateEntropy V; const CeedScalar gamma = HeatCapacityRatio(gas); const CeedScalar e_kinetic = .5 * Dot3(U.momentum, U.momentum) / U.density; const CeedScalar e_internal = U.E_total - e_kinetic; const CeedScalar p = (gamma - 1) * e_internal; const CeedScalar entropy = log(p) - gamma * log(U.density); V.S_density = (gamma - entropy) / (gamma - 1) - e_kinetic / p; for (int i = 0; i < 3; i++) V.S_momentum[i] = U.momentum[i] / p; V.S_energy = -U.density / p; return V; } CEED_QFUNCTION_HELPER StateEntropy StateEntropyFromConservative_fwd(NewtonianIdealGasContext gas, State s, StateConservative dU) { StateEntropy dV; const CeedScalar gamma = HeatCapacityRatio(gas); const CeedScalar e_kinetic = .5 * Dot3(s.U.momentum, s.U.momentum) / s.U.density; const CeedScalar de_kinetic = (Dot3(s.U.momentum, dU.momentum) - e_kinetic * dU.density) / s.U.density; const CeedScalar de_internal = dU.E_total - de_kinetic; const CeedScalar p = s.Y.pressure; const CeedScalar dp = (gamma - 1) * de_internal; CeedScalar dentropy = dp / p - gamma * dU.density / s.U.density; dV.S_density = -dentropy / (gamma - 1) - de_kinetic / p + dp * e_kinetic / Square(p); for (CeedInt i = 0; i < 3; i++) { dV.S_momentum[i] = (dU.momentum[i] - s.U.momentum[i] * dp / p) / p; } dV.S_energy = -(dU.density - s.U.density * dp / p) / p; return dV; } CEED_QFUNCTION_HELPER StateConservative StateConservativeFromEntropy(NewtonianIdealGasContext gas, StateEntropy V) { StateConservative U; CeedScalar velocity[3]; for (int i = 0; i < 3; i++) velocity[i] = -V.S_momentum[i] / V.S_energy; const CeedScalar gamma = HeatCapacityRatio(gas); const CeedScalar e_kinetic = 0.5 * Dot3(velocity, velocity); const CeedScalar entropy = gamma - (gamma - 1) * (V.S_density - e_kinetic * V.S_energy); const CeedScalar log_rho = -(entropy + log(-V.S_energy)) / (gamma - 1); U.density = exp(log_rho); for (int i = 0; i < 3; i++) U.momentum[i] = U.density * velocity[i]; const CeedScalar e_internal = -gas->cv / (GasConstant(gas) * V.S_energy); U.E_total = U.density * (e_internal + e_kinetic); return U; } CEED_QFUNCTION_HELPER StateConservative StateConservativeFromEntropy_fwd(NewtonianIdealGasContext gas, State s, StateEntropy dV) { StateConservative dU; CeedScalar dvelocity[3]; StateEntropy V = StateEntropyFromPrimitive(gas, s.Y); for (int i = 0; i < 3; i++) dvelocity[i] = (-dV.S_momentum[i] - s.Y.velocity[i] * dV.S_energy) / V.S_energy; const CeedScalar gamma = HeatCapacityRatio(gas); const CeedScalar e_kinetic = 0.5 * Dot3(s.Y.velocity, s.Y.velocity); const CeedScalar de_kinetic = Dot3(dvelocity, s.Y.velocity); const CeedScalar entropy = gamma - (gamma - 1) * (V.S_density - e_kinetic * V.S_energy); const CeedScalar dentropy = -(gamma - 1) * (dV.S_density - (de_kinetic * V.S_energy + e_kinetic * dV.S_energy)); const CeedScalar log_rho = -(entropy + log(-V.S_energy)) / (gamma - 1); const CeedScalar rho = exp(log_rho); dU.density = -rho / (gamma - 1) * (dentropy + dV.S_energy / V.S_energy); for (int i = 0; i < 3; i++) dU.momentum[i] = dU.density * s.Y.velocity[i] + s.U.density * dvelocity[i]; const CeedScalar e_internal = -gas->cv / (GasConstant(gas) * V.S_energy); const CeedScalar de_internal = gas->cv * dV.S_energy / (GasConstant(gas) * V.S_energy * V.S_energy); const CeedScalar e_total = e_internal + e_kinetic; dU.E_total = dU.density * e_total + s.U.density * (de_internal + de_kinetic); return dU; } CEED_QFUNCTION_HELPER State StateFromPrimitive(NewtonianIdealGasContext gas, StatePrimitive Y) { StateConservative U = StateConservativeFromPrimitive(gas, Y); State s; s.U = U; s.Y = Y; return s; } CEED_QFUNCTION_HELPER State StateFromPrimitive_fwd(NewtonianIdealGasContext gas, State s, StatePrimitive dY) { StateConservative dU = StateConservativeFromPrimitive_fwd(gas, s, dY); State ds; ds.U = dU; ds.Y = dY; return ds; } // linear combination of n states CEED_QFUNCTION_HELPER StateConservative StateConservativeMult(CeedInt n, const CeedScalar a[], const StateConservative X[]) { StateConservative R = {0}; for (CeedInt i = 0; i < n; i++) { R.density += a[i] * X[i].density; for (int j = 0; j < 3; j++) R.momentum[j] += a[i] * X[i].momentum[j]; R.E_total += a[i] * X[i].E_total; } return R; } CEED_QFUNCTION_HELPER StateConservative StateConservativeAXPBYPCZ(CeedScalar a, StateConservative X, CeedScalar b, StateConservative Y, CeedScalar c, StateConservative Z) { StateConservative R; R.density = a * X.density + b * Y.density + c * Z.density; for (int i = 0; i < 3; i++) R.momentum[i] = a * X.momentum[i] + b * Y.momentum[i] + c * Z.momentum[i]; R.E_total = a * X.E_total + b * Y.E_total + c * Z.E_total; return R; } CEED_QFUNCTION_HELPER void StateToU(NewtonianIdealGasContext gas, const State input, CeedScalar U[5]) { UnpackState_U(input.U, U); } CEED_QFUNCTION_HELPER void StateToY(NewtonianIdealGasContext gas, const State input, CeedScalar Y[5]) { UnpackState_Y(input.Y, Y); } CEED_QFUNCTION_HELPER void StateToV(NewtonianIdealGasContext gas, const State input, CeedScalar V[5]) { StateEntropy state_V = StateEntropyFromPrimitive(gas, input.Y); UnpackState_V(state_V, V); } CEED_QFUNCTION_HELPER void StateToQ(NewtonianIdealGasContext gas, const State input, CeedScalar Q[5], StateVariable state_var) { switch (state_var) { case STATEVAR_CONSERVATIVE: StateToU(gas, input, Q); break; case STATEVAR_PRIMITIVE: StateToY(gas, input, Q); break; case STATEVAR_ENTROPY: StateToV(gas, input, Q); break; } } CEED_QFUNCTION_HELPER void StateToQ_fwd(NewtonianIdealGasContext gas, const State input, const State dinput, CeedScalar dQ[5], StateVariable state_var) { switch (state_var) { case STATEVAR_CONSERVATIVE: case STATEVAR_PRIMITIVE: StateToQ(gas, dinput, dQ, state_var); break; case STATEVAR_ENTROPY: { StateEntropy dstate_v; dstate_v = StateEntropyFromPrimitive_fwd(gas, input, dinput.Y); UnpackState_V(dstate_v, dQ); } break; } } CEED_QFUNCTION_HELPER State StateFromU(NewtonianIdealGasContext gas, const CeedScalar U[5]) { State s; s.U.density = U[0]; s.U.momentum[0] = U[1]; s.U.momentum[1] = U[2]; s.U.momentum[2] = U[3]; s.U.E_total = U[4]; s.Y = StatePrimitiveFromConservative(gas, s.U); return s; } CEED_QFUNCTION_HELPER State StateFromU_fwd(NewtonianIdealGasContext gas, State s, const CeedScalar dU[5]) { State ds; ds.U.density = dU[0]; ds.U.momentum[0] = dU[1]; ds.U.momentum[1] = dU[2]; ds.U.momentum[2] = dU[3]; ds.U.E_total = dU[4]; ds.Y = StatePrimitiveFromConservative_fwd(gas, s, ds.U); return ds; } CEED_QFUNCTION_HELPER State StateFromY(NewtonianIdealGasContext gas, const CeedScalar Y[5]) { State s; s.Y.pressure = Y[0]; s.Y.velocity[0] = Y[1]; s.Y.velocity[1] = Y[2]; s.Y.velocity[2] = Y[3]; s.Y.temperature = Y[4]; s.U = StateConservativeFromPrimitive(gas, s.Y); return s; } CEED_QFUNCTION_HELPER State StateFromY_fwd(NewtonianIdealGasContext gas, State s, const CeedScalar dY[5]) { State ds; ds.Y.pressure = dY[0]; ds.Y.velocity[0] = dY[1]; ds.Y.velocity[1] = dY[2]; ds.Y.velocity[2] = dY[3]; ds.Y.temperature = dY[4]; ds.U = StateConservativeFromPrimitive_fwd(gas, s, ds.Y); return ds; } CEED_QFUNCTION_HELPER State StateFromV(NewtonianIdealGasContext gas, const CeedScalar V[5]) { State s; StateEntropy state_V; state_V.S_density = V[0]; state_V.S_momentum[0] = V[1]; state_V.S_momentum[1] = V[2]; state_V.S_momentum[2] = V[3]; state_V.S_energy = V[4]; s.U = StateConservativeFromEntropy(gas, state_V); s.Y = StatePrimitiveFromEntropy(gas, state_V); return s; } CEED_QFUNCTION_HELPER State StateFromV_fwd(NewtonianIdealGasContext gas, State s, const CeedScalar dV[5]) { State ds; StateEntropy state_dV; state_dV.S_density = dV[0]; state_dV.S_momentum[0] = dV[1]; state_dV.S_momentum[1] = dV[2]; state_dV.S_momentum[2] = dV[3]; state_dV.S_energy = dV[4]; ds.U = StateConservativeFromEntropy_fwd(gas, s, state_dV); ds.Y = StatePrimitiveFromEntropy_fwd(gas, s, state_dV); return ds; } CEED_QFUNCTION_HELPER State StateFromQ(NewtonianIdealGasContext gas, const CeedScalar Q[5], StateVariable state_var) { State s; switch (state_var) { case STATEVAR_CONSERVATIVE: s = StateFromU(gas, Q); break; case STATEVAR_PRIMITIVE: s = StateFromY(gas, Q); break; case STATEVAR_ENTROPY: s = StateFromV(gas, Q); break; } return s; } CEED_QFUNCTION_HELPER State StateFromQ_fwd(NewtonianIdealGasContext gas, State s, const CeedScalar dQ[5], StateVariable state_var) { State ds; switch (state_var) { case STATEVAR_CONSERVATIVE: ds = StateFromU_fwd(gas, s, dQ); break; case STATEVAR_PRIMITIVE: ds = StateFromY_fwd(gas, s, dQ); break; case STATEVAR_ENTROPY: ds = StateFromV_fwd(gas, s, dQ); break; } return ds; } CEED_QFUNCTION_HELPER void FluxInviscid(NewtonianIdealGasContext gas, State s, StateConservative Flux[3]) { for (CeedInt i = 0; i < 3; i++) { Flux[i].density = s.U.momentum[i]; for (CeedInt j = 0; j < 3; j++) Flux[i].momentum[j] = s.U.momentum[i] * s.Y.velocity[j] + s.Y.pressure * (i == j); Flux[i].E_total = (s.U.E_total + s.Y.pressure) * s.Y.velocity[i]; } } CEED_QFUNCTION_HELPER void FluxInviscid_fwd(NewtonianIdealGasContext gas, State s, State ds, StateConservative dFlux[3]) { for (CeedInt i = 0; i < 3; i++) { dFlux[i].density = ds.U.momentum[i]; for (CeedInt j = 0; j < 3; j++) { dFlux[i].momentum[j] = ds.U.momentum[i] * s.Y.velocity[j] + s.U.momentum[i] * ds.Y.velocity[j] + ds.Y.pressure * (i == j); } dFlux[i].E_total = (ds.U.E_total + ds.Y.pressure) * s.Y.velocity[i] + (s.U.E_total + s.Y.pressure) * ds.Y.velocity[i]; } } CEED_QFUNCTION_HELPER StateConservative FluxInviscidDotNormal(NewtonianIdealGasContext gas, State s, const CeedScalar normal[3]) { StateConservative Flux[3], Flux_dot_n = {0}; FluxInviscid(gas, s, Flux); for (CeedInt i = 0; i < 3; i++) { Flux_dot_n.density += Flux[i].density * normal[i]; for (CeedInt j = 0; j < 3; j++) Flux_dot_n.momentum[j] += Flux[i].momentum[j] * normal[i]; Flux_dot_n.E_total += Flux[i].E_total * normal[i]; } return Flux_dot_n; } CEED_QFUNCTION_HELPER StateConservative FluxInviscidDotNormal_fwd(NewtonianIdealGasContext gas, State s, State ds, const CeedScalar normal[3]) { StateConservative dFlux[3], Flux_dot_n = {0}; FluxInviscid_fwd(gas, s, ds, dFlux); for (CeedInt i = 0; i < 3; i++) { Flux_dot_n.density += dFlux[i].density * normal[i]; for (CeedInt j = 0; j < 3; j++) Flux_dot_n.momentum[j] += dFlux[i].momentum[j] * normal[i]; Flux_dot_n.E_total += dFlux[i].E_total * normal[i]; } return Flux_dot_n; } CEED_QFUNCTION_HELPER void FluxInviscidStrong(NewtonianIdealGasContext gas, State s, State ds[3], CeedScalar strong_conv[5]) { for (CeedInt i = 0; i < 5; i++) strong_conv[i] = 0; for (CeedInt i = 0; i < 3; i++) { StateConservative dF[3]; FluxInviscid_fwd(gas, s, ds[i], dF); CeedScalar dF_i[5]; UnpackState_U(dF[i], dF_i); for (CeedInt j = 0; j < 5; j++) strong_conv[j] += dF_i[j]; } } CEED_QFUNCTION_HELPER void FluxTotal(const StateConservative F_inviscid[3], CeedScalar stress[3][3], CeedScalar Fe[3], CeedScalar Flux[5][3]) { for (CeedInt j = 0; j < 3; j++) { Flux[0][j] = F_inviscid[j].density; for (CeedInt k = 0; k < 3; k++) Flux[k + 1][j] = F_inviscid[j].momentum[k] - stress[k][j]; Flux[4][j] = F_inviscid[j].E_total + Fe[j]; } } CEED_QFUNCTION_HELPER void FluxTotal_Boundary(const StateConservative F_inviscid[3], const CeedScalar stress[3][3], const CeedScalar Fe[3], const CeedScalar normal[3], CeedScalar Flux[5]) { for (CeedInt j = 0; j < 5; j++) Flux[j] = 0.; for (CeedInt j = 0; j < 3; j++) { Flux[0] += F_inviscid[j].density * normal[j]; for (CeedInt k = 0; k < 3; k++) { Flux[k + 1] += (F_inviscid[j].momentum[k] - stress[k][j]) * normal[j]; } Flux[4] += (F_inviscid[j].E_total + Fe[j]) * normal[j]; } } CEED_QFUNCTION_HELPER void FluxTotal_RiemannBoundary(const StateConservative F_inviscid_normal, const CeedScalar stress[3][3], const CeedScalar Fe[3], const CeedScalar normal[3], CeedScalar Flux[5]) { Flux[0] = F_inviscid_normal.density; for (CeedInt k = 0; k < 3; k++) Flux[k + 1] = F_inviscid_normal.momentum[k]; Flux[4] = F_inviscid_normal.E_total; for (CeedInt j = 0; j < 3; j++) { for (CeedInt k = 0; k < 3; k++) { Flux[k + 1] -= stress[k][j] * normal[j]; } Flux[4] += Fe[j] * normal[j]; } } CEED_QFUNCTION_HELPER void VelocityGradient(const State grad_s[3], CeedScalar grad_velocity[3][3]) { grad_velocity[0][0] = grad_s[0].Y.velocity[0]; grad_velocity[0][1] = grad_s[1].Y.velocity[0]; grad_velocity[0][2] = grad_s[2].Y.velocity[0]; grad_velocity[1][0] = grad_s[0].Y.velocity[1]; grad_velocity[1][1] = grad_s[1].Y.velocity[1]; grad_velocity[1][2] = grad_s[2].Y.velocity[1]; grad_velocity[2][0] = grad_s[0].Y.velocity[2]; grad_velocity[2][1] = grad_s[1].Y.velocity[2]; grad_velocity[2][2] = grad_s[2].Y.velocity[2]; } CEED_QFUNCTION_HELPER void KMStrainRate(const CeedScalar grad_velocity[3][3], CeedScalar strain_rate[6]) { const CeedScalar weight = 1 / sqrt(2.); // Really sqrt(2.) / 2 strain_rate[0] = grad_velocity[0][0]; strain_rate[1] = grad_velocity[1][1]; strain_rate[2] = grad_velocity[2][2]; strain_rate[3] = weight * (grad_velocity[1][2] + grad_velocity[2][1]); strain_rate[4] = weight * (grad_velocity[0][2] + grad_velocity[2][0]); strain_rate[5] = weight * (grad_velocity[0][1] + grad_velocity[1][0]); } // Kelvin-Mandel notation CEED_QFUNCTION_HELPER void KMStrainRate_State(const State grad_s[3], CeedScalar strain_rate[6]) { CeedScalar grad_velocity[3][3]; VelocityGradient(grad_s, grad_velocity); KMStrainRate(grad_velocity, strain_rate); } //@brief Given velocity gradient du_i/dx_j, return 0.5*(du_i/dx_j - du_j/dx_i) CEED_QFUNCTION_HELPER void RotationRate(const CeedScalar grad_velocity[3][3], CeedScalar rotation_rate[3][3]) { rotation_rate[0][0] = 0; rotation_rate[1][1] = 0; rotation_rate[2][2] = 0; rotation_rate[1][2] = 0.5 * (grad_velocity[1][2] - grad_velocity[2][1]); rotation_rate[0][2] = 0.5 * (grad_velocity[0][2] - grad_velocity[2][0]); rotation_rate[0][1] = 0.5 * (grad_velocity[0][1] - grad_velocity[1][0]); rotation_rate[2][1] = -rotation_rate[1][2]; rotation_rate[2][0] = -rotation_rate[0][2]; rotation_rate[1][0] = -rotation_rate[0][1]; } CEED_QFUNCTION_HELPER void NewtonianStress(NewtonianIdealGasContext gas, const CeedScalar strain_rate[6], CeedScalar stress[6]) { CeedScalar div_u = strain_rate[0] + strain_rate[1] + strain_rate[2]; for (CeedInt i = 0; i < 6; i++) { stress[i] = gas->mu * (2 * strain_rate[i] + gas->lambda * div_u * (i < 3)); } } CEED_QFUNCTION_HELPER void ViscousEnergyFlux(NewtonianIdealGasContext gas, StatePrimitive Y, const State grad_s[3], const CeedScalar stress[3][3], CeedScalar Fe[3]) { for (CeedInt i = 0; i < 3; i++) { Fe[i] = -Y.velocity[0] * stress[0][i] - Y.velocity[1] * stress[1][i] - Y.velocity[2] * stress[2][i] - gas->k * grad_s[i].Y.temperature; } } CEED_QFUNCTION_HELPER void ViscousEnergyFlux_fwd(NewtonianIdealGasContext gas, StatePrimitive Y, StatePrimitive dY, const State grad_ds[3], const CeedScalar stress[3][3], const CeedScalar dstress[3][3], CeedScalar dFe[3]) { for (CeedInt i = 0; i < 3; i++) { dFe[i] = -Y.velocity[0] * dstress[0][i] - dY.velocity[0] * stress[0][i] - Y.velocity[1] * dstress[1][i] - dY.velocity[1] * stress[1][i] - Y.velocity[2] * dstress[2][i] - dY.velocity[2] * stress[2][i] - gas->k * grad_ds[i].Y.temperature; } } CEED_QFUNCTION_HELPER void Vorticity(const State grad_s[3], CeedScalar vorticity[3]) { CeedScalar grad_velocity[3][3]; VelocityGradient(grad_s, grad_velocity); Curl3(grad_velocity, vorticity); } CEED_QFUNCTION_HELPER void StatePhysicalGradientFromReference(CeedInt Q, CeedInt i, NewtonianIdealGasContext gas, State s, StateVariable state_var, const CeedScalar *grad_q, const CeedScalar dXdx[3][3], State grad_s[3]) { for (CeedInt k = 0; k < 3; k++) { CeedScalar dqi[5]; for (CeedInt j = 0; j < 5; j++) { dqi[j] = grad_q[(Q * 5) * 0 + Q * j + i] * dXdx[0][k] + grad_q[(Q * 5) * 1 + Q * j + i] * dXdx[1][k] + grad_q[(Q * 5) * 2 + Q * j + i] * dXdx[2][k]; } grad_s[k] = StateFromQ_fwd(gas, s, dqi, state_var); } } CEED_QFUNCTION_HELPER void StatePhysicalGradientFromReference_Boundary(CeedInt Q, CeedInt i, NewtonianIdealGasContext gas, State s, StateVariable state_var, const CeedScalar *grad_q, const CeedScalar dXdx[2][3], State grad_s[3]) { for (CeedInt k = 0; k < 3; k++) { CeedScalar dqi[5]; for (CeedInt j = 0; j < 5; j++) { dqi[j] = grad_q[(Q * 5) * 0 + Q * j + i] * dXdx[0][k] + grad_q[(Q * 5) * 1 + Q * j + i] * dXdx[1][k]; } grad_s[k] = StateFromQ_fwd(gas, s, dqi, state_var); } }