1dc936754SJeremy L Thompson // Copyright (c) 2017-2024, Lawrence Livermore National Security, LLC and other CEED contributors. 29ed3d70dSJames Wright // All Rights Reserved. See the top-level LICENSE and NOTICE files for details. 39ed3d70dSJames Wright // 49ed3d70dSJames Wright // SPDX-License-Identifier: BSD-2-Clause 59ed3d70dSJames Wright // 69ed3d70dSJames Wright // This file is part of CEED: http://github.com/ceed 79ed3d70dSJames Wright 89ed3d70dSJames Wright /// @file 99ed3d70dSJames Wright /// Helper functions for solving the Riemann problem. 109ed3d70dSJames Wright // The left and right states are specified from the perspective of an outward-facing normal vector pointing left to right: 119ed3d70dSJames Wright // 129ed3d70dSJames Wright // (domain) 139ed3d70dSJames Wright // / (outward facing normal) 149ed3d70dSJames Wright // |------------| / 159ed3d70dSJames Wright // | | / 169ed3d70dSJames Wright // | Left |----> Right 179ed3d70dSJames Wright // | (Interior) | (Exterior) 189ed3d70dSJames Wright // |------------| 199ed3d70dSJames Wright // 209ed3d70dSJames Wright // The right state is exterior to the domain and the left state is the interior to the domain. 219ed3d70dSJames Wright // Much of the work references Eleuterio F. Toro's "Riemann Solvers and Numerical Methods for Fluid Dynamics", 2009 229ed3d70dSJames Wright #include "newtonian_state.h" 239ed3d70dSJames Wright #include "newtonian_types.h" 249ed3d70dSJames Wright 259ed3d70dSJames Wright enum RiemannFluxType_ { RIEMANN_HLL, RIEMANN_HLLC }; 269ed3d70dSJames Wright typedef enum RiemannFluxType_ RiemannFluxType; 279ed3d70dSJames Wright 289ed3d70dSJames Wright typedef struct { 299ed3d70dSJames Wright CeedScalar left, right; 309ed3d70dSJames Wright } RoeWeights; 319ed3d70dSJames Wright 329ed3d70dSJames Wright CEED_QFUNCTION_HELPER RoeWeights RoeSetup(CeedScalar rho_left, CeedScalar rho_right) { 339ed3d70dSJames Wright CeedScalar sqrt_left = sqrt(rho_left), sqrt_right = sqrt(rho_right); 349ed3d70dSJames Wright RoeWeights w = {sqrt_left / (sqrt_left + sqrt_right), sqrt_right / (sqrt_left + sqrt_right)}; 359ed3d70dSJames Wright return w; 369ed3d70dSJames Wright } 379ed3d70dSJames Wright 389ed3d70dSJames Wright CEED_QFUNCTION_HELPER RoeWeights RoeSetup_fwd(CeedScalar rho_left, CeedScalar rho_right, CeedScalar drho_left, CeedScalar drho_right) { 399ed3d70dSJames Wright CeedScalar sqrt_left = sqrt(rho_left), sqrt_right = sqrt(rho_right); 409ed3d70dSJames Wright CeedScalar square_sum_root = Square(sqrt_left + sqrt_right); 419ed3d70dSJames Wright CeedScalar r_right = (sqrt_left / (2 * sqrt_right * square_sum_root)) * drho_right - (sqrt_right / (2 * sqrt_left * square_sum_root)) * drho_left; 429ed3d70dSJames Wright CeedScalar r_left = (sqrt_right / (2 * sqrt_left * square_sum_root)) * drho_left - (sqrt_left / (2 * sqrt_right * square_sum_root)) * drho_right; 439ed3d70dSJames Wright RoeWeights dw = {r_left, r_right}; 449ed3d70dSJames Wright return dw; 459ed3d70dSJames Wright } 469ed3d70dSJames Wright 479ed3d70dSJames Wright CEED_QFUNCTION_HELPER CeedScalar RoeAverage(RoeWeights r, CeedScalar q_left, CeedScalar q_right) { return r.left * q_left + r.right * q_right; } 489ed3d70dSJames Wright 499ed3d70dSJames Wright CEED_QFUNCTION_HELPER CeedScalar RoeAverage_fwd(RoeWeights r, RoeWeights dr, CeedScalar q_left, CeedScalar q_right, CeedScalar dq_left, 509ed3d70dSJames Wright CeedScalar dq_right) { 519ed3d70dSJames Wright return q_right * dr.right + q_left * dr.left + r.right * dq_right + r.left * dq_left; 529ed3d70dSJames Wright } 539ed3d70dSJames Wright 549ed3d70dSJames Wright CEED_QFUNCTION_HELPER StateConservative Flux_HLL(State left, State right, StateConservative flux_left, StateConservative flux_right, 559ed3d70dSJames Wright CeedScalar s_left, CeedScalar s_right) { 569ed3d70dSJames Wright CeedScalar U_left[5], U_right[5], F_right[5], F_left[5], F_hll[5]; 579ed3d70dSJames Wright UnpackState_U(left.U, U_left); 589ed3d70dSJames Wright UnpackState_U(right.U, U_right); 599ed3d70dSJames Wright UnpackState_U(flux_left, F_left); 609ed3d70dSJames Wright UnpackState_U(flux_right, F_right); 619ed3d70dSJames Wright for (int i = 0; i < 5; i++) { 629ed3d70dSJames Wright F_hll[i] = (s_right * F_left[i] - s_left * F_right[i] + s_left * s_right * (U_right[i] - U_left[i])) / (s_right - s_left); 639ed3d70dSJames Wright } 649ed3d70dSJames Wright StateConservative F = { 659ed3d70dSJames Wright F_hll[0], 669ed3d70dSJames Wright {F_hll[1], F_hll[2], F_hll[3]}, 679ed3d70dSJames Wright F_hll[4], 689ed3d70dSJames Wright }; 699ed3d70dSJames Wright return F; 709ed3d70dSJames Wright } 719ed3d70dSJames Wright 729ed3d70dSJames Wright CEED_QFUNCTION_HELPER StateConservative Flux_HLL_fwd(State left, State right, State dleft, State dright, StateConservative flux_left, 739ed3d70dSJames Wright StateConservative flux_right, StateConservative dflux_left, StateConservative dflux_right, 749ed3d70dSJames Wright CeedScalar S_l, CeedScalar S_r, CeedScalar dS_l, CeedScalar dS_r) { 759ed3d70dSJames Wright CeedScalar U_l[5], U_r[5], F_r[5], F_l[5]; 769ed3d70dSJames Wright UnpackState_U(left.U, U_l); 779ed3d70dSJames Wright UnpackState_U(right.U, U_r); 789ed3d70dSJames Wright UnpackState_U(flux_left, F_l); 799ed3d70dSJames Wright UnpackState_U(flux_right, F_r); 809ed3d70dSJames Wright 819ed3d70dSJames Wright CeedScalar dU_l[5], dU_r[5], dF_r[5], dF_l[5], dF_hll[5] = {0.}; 829ed3d70dSJames Wright UnpackState_U(dleft.U, dU_l); 839ed3d70dSJames Wright UnpackState_U(dright.U, dU_r); 849ed3d70dSJames Wright UnpackState_U(dflux_left, dF_l); 859ed3d70dSJames Wright UnpackState_U(dflux_right, dF_r); 869ed3d70dSJames Wright for (int i = 0; i < 5; i++) { 879ed3d70dSJames Wright const CeedScalar S_diff = S_r - S_l; 889ed3d70dSJames Wright 89*9bafb137SJames Wright dF_hll[i] += (S_l * (-F_l[i] + F_r[i] + S_l * U_l[i] - S_l * U_r[i]) / Square(S_diff)) * dS_r; 90*9bafb137SJames Wright dF_hll[i] += (S_r * (F_l[i] - F_r[i] - S_r * U_l[i] + S_r * U_r[i]) / Square(S_diff)) * dS_l; 91*9bafb137SJames Wright dF_hll[i] += (S_r * dF_l[i] - S_l * dF_r[i] + S_r * S_l * (dU_r[i] - dU_l[i])) / S_diff; 929ed3d70dSJames Wright } 939ed3d70dSJames Wright StateConservative dF = { 949ed3d70dSJames Wright dF_hll[0], 959ed3d70dSJames Wright {dF_hll[1], dF_hll[2], dF_hll[3]}, 969ed3d70dSJames Wright dF_hll[4], 979ed3d70dSJames Wright }; 989ed3d70dSJames Wright return dF; 999ed3d70dSJames Wright } 1009ed3d70dSJames Wright 1019ed3d70dSJames Wright CEED_QFUNCTION_HELPER void ComputeHLLSpeeds_Roe(NewtonianIdealGasContext gas, State left, CeedScalar u_left, State right, CeedScalar u_right, 1029ed3d70dSJames Wright CeedScalar *s_left, CeedScalar *s_right) { 1039ed3d70dSJames Wright const CeedScalar gamma = HeatCapacityRatio(gas); 1049ed3d70dSJames Wright 1059ed3d70dSJames Wright RoeWeights r = RoeSetup(left.U.density, right.U.density); 1069ed3d70dSJames Wright // Speed estimate 1079ed3d70dSJames Wright // Roe average eigenvalues for left and right non-linear waves. 1089ed3d70dSJames Wright // Stability requires that these speed estimates are *at least* as fast as the physical wave speeds. 1099ed3d70dSJames Wright CeedScalar u_roe = RoeAverage(r, u_left, u_right); 1109ed3d70dSJames Wright 1119ed3d70dSJames Wright // TODO: revisit this for gravity 1129ed3d70dSJames Wright CeedScalar H_left = TotalSpecificEnthalpy(gas, left); 1139ed3d70dSJames Wright CeedScalar H_right = TotalSpecificEnthalpy(gas, right); 1149ed3d70dSJames Wright CeedScalar H_roe = RoeAverage(r, H_left, H_right); 1159ed3d70dSJames Wright CeedScalar a_roe = sqrt((gamma - 1) * (H_roe - 0.5 * Square(u_roe))); 1169ed3d70dSJames Wright 1179ed3d70dSJames Wright // Einfeldt (1988) justifies (and Toro's book repeats) that Roe speeds can be used here. 1189ed3d70dSJames Wright *s_left = u_roe - a_roe; 1199ed3d70dSJames Wright *s_right = u_roe + a_roe; 1209ed3d70dSJames Wright } 1219ed3d70dSJames Wright 1229ed3d70dSJames Wright CEED_QFUNCTION_HELPER void ComputeHLLSpeeds_Roe_fwd(NewtonianIdealGasContext gas, State left, State dleft, CeedScalar u_left, CeedScalar du_left, 1239ed3d70dSJames Wright State right, State dright, CeedScalar u_right, CeedScalar du_right, CeedScalar *s_left, 1249ed3d70dSJames Wright CeedScalar *ds_left, CeedScalar *s_right, CeedScalar *ds_right) { 1259ed3d70dSJames Wright const CeedScalar gamma = HeatCapacityRatio(gas); 1269ed3d70dSJames Wright 1279ed3d70dSJames Wright RoeWeights r = RoeSetup(left.U.density, right.U.density); 1289ed3d70dSJames Wright RoeWeights dr = RoeSetup_fwd(left.U.density, right.U.density, dleft.U.density, dright.U.density); 1299ed3d70dSJames Wright // Speed estimate 1309ed3d70dSJames Wright // Roe average eigenvalues for left and right non-linear waves. 1319ed3d70dSJames Wright // Stability requires that these speed estimates are *at least* as fast as the physical wave speeds. 1329ed3d70dSJames Wright CeedScalar u_roe = RoeAverage(r, u_left, u_right); 1339ed3d70dSJames Wright CeedScalar du_roe = RoeAverage_fwd(r, dr, u_left, u_right, du_left, du_right); 1349ed3d70dSJames Wright 1359ed3d70dSJames Wright CeedScalar H_left = TotalSpecificEnthalpy(gas, left); 1369ed3d70dSJames Wright CeedScalar H_right = TotalSpecificEnthalpy(gas, right); 1379ed3d70dSJames Wright CeedScalar dH_left = TotalSpecificEnthalpy_fwd(gas, left, dleft); 1389ed3d70dSJames Wright CeedScalar dH_right = TotalSpecificEnthalpy_fwd(gas, right, dright); 1399ed3d70dSJames Wright 1409ed3d70dSJames Wright CeedScalar H_roe = RoeAverage(r, H_left, H_right); 1419ed3d70dSJames Wright CeedScalar dH_roe = RoeAverage_fwd(r, dr, H_left, H_right, dH_left, dH_right); 1429ed3d70dSJames Wright CeedScalar a_roe = sqrt((gamma - 1) * (H_roe - 0.5 * Square(u_roe))); 143*9bafb137SJames Wright CeedScalar da_roe = 0.5 * sqrt((gamma - 1) / (H_roe - 0.5 * Square(u_roe))) * dH_roe; // (da/dH) dH 144*9bafb137SJames Wright da_roe -= 0.5 * sqrt(gamma - 1) * u_roe / sqrt(H_roe - 0.5 * Square(u_roe)) * du_roe; // (da/du) du 1459ed3d70dSJames Wright 1469ed3d70dSJames Wright *s_left = u_roe - a_roe; 1479ed3d70dSJames Wright *ds_left = du_roe - da_roe; 1489ed3d70dSJames Wright *s_right = u_roe + a_roe; 1499ed3d70dSJames Wright *ds_right = du_roe + da_roe; 1509ed3d70dSJames Wright } 1519ed3d70dSJames Wright 1529ed3d70dSJames Wright // ***************************************************************************** 1539ed3d70dSJames Wright // @brief Harten Lax VanLeer (HLL) approximate Riemann solver. 1549ed3d70dSJames Wright // Taking in two states (left, right) and returns RiemannFlux_HLL. 1559ed3d70dSJames Wright // The left and right states are specified from the perspective of an outward-facing normal vector pointing left to right. 1569ed3d70dSJames Wright // 1579ed3d70dSJames Wright // @param[in] gas NewtonianIdealGasContext for the fluid 1589ed3d70dSJames Wright // @param[in] left Fluid state of the domain interior (the current solution) 1599ed3d70dSJames Wright // @param[in] right Fluid state of the domain exterior (free stream conditions) 1609ed3d70dSJames Wright // @param[in] normal Normalized, outward facing boundary normal vector 1619ed3d70dSJames Wright // 1629ed3d70dSJames Wright // @return StateConservative with HLL Riemann Flux 1639ed3d70dSJames Wright // ***************************************************************************** 1649ed3d70dSJames Wright CEED_QFUNCTION_HELPER StateConservative RiemannFlux_HLL(NewtonianIdealGasContext gas, State left, State right, const CeedScalar normal[3]) { 1659ed3d70dSJames Wright StateConservative flux_left = FluxInviscidDotNormal(gas, left, normal); 1669ed3d70dSJames Wright StateConservative flux_right = FluxInviscidDotNormal(gas, right, normal); 1679ed3d70dSJames Wright 1689ed3d70dSJames Wright CeedScalar u_left = Dot3(left.Y.velocity, normal); 1699ed3d70dSJames Wright CeedScalar u_right = Dot3(right.Y.velocity, normal); 1709ed3d70dSJames Wright 1719ed3d70dSJames Wright CeedScalar s_left, s_right; 1729ed3d70dSJames Wright ComputeHLLSpeeds_Roe(gas, left, u_left, right, u_right, &s_left, &s_right); 1739ed3d70dSJames Wright 1749ed3d70dSJames Wright // Compute HLL flux 1759ed3d70dSJames Wright if (0 <= s_left) { 1769ed3d70dSJames Wright return flux_left; 1779ed3d70dSJames Wright } else if (s_right <= 0) { 1789ed3d70dSJames Wright return flux_right; 1799ed3d70dSJames Wright } else { 1809ed3d70dSJames Wright return Flux_HLL(left, right, flux_left, flux_right, s_left, s_right); 1819ed3d70dSJames Wright } 1829ed3d70dSJames Wright } 1839ed3d70dSJames Wright 1849ed3d70dSJames Wright // ***************************************************************************** 1859ed3d70dSJames Wright // @brief Forward-mode Derivative of Harten Lax VanLeer (HLL) approximate Riemann solver. 1869ed3d70dSJames Wright // 1879ed3d70dSJames Wright // @param gas NewtonianIdealGasContext for the fluid 1889ed3d70dSJames Wright // @param left Fluid state of the domain interior (the current solution) 1899ed3d70dSJames Wright // @param right Fluid state of the domain exterior (free stream conditions) 1909ed3d70dSJames Wright // @param dleft Derivative of fluid state of the domain interior (the current solution) 1919ed3d70dSJames Wright // @param dright Derivative of fluid state of the domain exterior (free stream conditions) 1929ed3d70dSJames Wright // @param normal Normalized, outward facing boundary normal vector 1939ed3d70dSJames Wright // 1949ed3d70dSJames Wright // @return StateConservative with derivative of HLL Riemann Flux 1959ed3d70dSJames Wright // ***************************************************************************** 1969ed3d70dSJames Wright CEED_QFUNCTION_HELPER StateConservative RiemannFlux_HLL_fwd(NewtonianIdealGasContext gas, State left, State dleft, State right, State dright, 1979ed3d70dSJames Wright const CeedScalar normal[3]) { 1989ed3d70dSJames Wright StateConservative flux_left = FluxInviscidDotNormal(gas, left, normal); 1999ed3d70dSJames Wright StateConservative flux_right = FluxInviscidDotNormal(gas, right, normal); 2009ed3d70dSJames Wright StateConservative dflux_left = FluxInviscidDotNormal_fwd(gas, left, dleft, normal); 2019ed3d70dSJames Wright StateConservative dflux_right = FluxInviscidDotNormal_fwd(gas, right, dright, normal); 2029ed3d70dSJames Wright 2039ed3d70dSJames Wright CeedScalar u_left = Dot3(left.Y.velocity, normal); 2049ed3d70dSJames Wright CeedScalar u_right = Dot3(right.Y.velocity, normal); 2059ed3d70dSJames Wright CeedScalar du_left = Dot3(dleft.Y.velocity, normal); 2069ed3d70dSJames Wright CeedScalar du_right = Dot3(dright.Y.velocity, normal); 2079ed3d70dSJames Wright 2089ed3d70dSJames Wright CeedScalar s_left, ds_left, s_right, ds_right; 2099ed3d70dSJames Wright ComputeHLLSpeeds_Roe_fwd(gas, left, dleft, u_left, du_left, right, dright, u_right, du_right, &s_left, &ds_left, &s_right, &ds_right); 2109ed3d70dSJames Wright 2119ed3d70dSJames Wright if (0 <= s_left) { 2129ed3d70dSJames Wright return dflux_left; 2139ed3d70dSJames Wright } else if (s_right <= 0) { 2149ed3d70dSJames Wright return dflux_right; 2159ed3d70dSJames Wright } else { 2169ed3d70dSJames Wright return Flux_HLL_fwd(left, right, dleft, dright, flux_left, flux_right, dflux_left, dflux_right, s_left, s_right, ds_left, ds_right); 2179ed3d70dSJames Wright } 2189ed3d70dSJames Wright } 2199ed3d70dSJames Wright 2209ed3d70dSJames Wright CEED_QFUNCTION_HELPER StateConservative RiemannFlux_HLLC_Star(NewtonianIdealGasContext gas, State side, StateConservative F_side, 2219ed3d70dSJames Wright const CeedScalar normal[3], CeedScalar u_side, CeedScalar s_side, CeedScalar s_star) { 2229ed3d70dSJames Wright CeedScalar fact = side.U.density * (s_side - u_side) / (s_side - s_star); 2239ed3d70dSJames Wright CeedScalar denom = side.U.density * (s_side - u_side); 2249ed3d70dSJames Wright // U_* = fact * star 2259ed3d70dSJames Wright StateConservative star = { 2269ed3d70dSJames Wright 1.0, 2279ed3d70dSJames Wright { 2289ed3d70dSJames Wright side.Y.velocity[0] + (s_star - u_side) * normal[0], 2299ed3d70dSJames Wright side.Y.velocity[1] + (s_star - u_side) * normal[1], 2309ed3d70dSJames Wright side.Y.velocity[2] + (s_star - u_side) * normal[2], 2319ed3d70dSJames Wright }, 2329ed3d70dSJames Wright side.U.E_total / side.U.density // 2339ed3d70dSJames Wright + (s_star - u_side) * (s_star + side.Y.pressure / denom) 2349ed3d70dSJames Wright }; 2359ed3d70dSJames Wright return StateConservativeAXPBYPCZ(1, F_side, s_side * fact, star, -s_side, side.U); 2369ed3d70dSJames Wright } 2379ed3d70dSJames Wright 2389ed3d70dSJames Wright CEED_QFUNCTION_HELPER StateConservative RiemannFlux_HLLC_Star_fwd(NewtonianIdealGasContext gas, State side, State dside, StateConservative F_side, 2399ed3d70dSJames Wright StateConservative dF_side, const CeedScalar normal[3], CeedScalar u_side, 2409ed3d70dSJames Wright CeedScalar du_side, CeedScalar s_side, CeedScalar ds_side, CeedScalar s_star, 2419ed3d70dSJames Wright CeedScalar ds_star) { 2429ed3d70dSJames Wright CeedScalar fact = side.U.density * (s_side - u_side) / (s_side - s_star); 2439ed3d70dSJames Wright CeedScalar dfact = (side.U.density * (ds_side - du_side) + dside.U.density * (s_side - u_side)) / (s_side - s_star) // 2449ed3d70dSJames Wright - fact / (s_side - s_star) * (ds_side - ds_star); 2459ed3d70dSJames Wright CeedScalar denom = side.U.density * (s_side - u_side); 2469ed3d70dSJames Wright CeedScalar ddenom = side.U.density * (ds_side - du_side) + dside.U.density * (s_side - u_side); 2479ed3d70dSJames Wright 2489ed3d70dSJames Wright StateConservative star = { 2499ed3d70dSJames Wright 1.0, 2509ed3d70dSJames Wright { 2519ed3d70dSJames Wright side.Y.velocity[0] + (s_star - u_side) * normal[0], 2529ed3d70dSJames Wright side.Y.velocity[1] + (s_star - u_side) * normal[1], 2539ed3d70dSJames Wright side.Y.velocity[2] + (s_star - u_side) * normal[2], 2549ed3d70dSJames Wright }, 2559ed3d70dSJames Wright side.U.E_total / side.U.density // 2569ed3d70dSJames Wright + (s_star - u_side) * (s_star + side.Y.pressure / denom) 2579ed3d70dSJames Wright }; 2589ed3d70dSJames Wright StateConservative dstar = { 2599ed3d70dSJames Wright 0., 2609ed3d70dSJames Wright { 2619ed3d70dSJames Wright dside.Y.velocity[0] + (ds_star - du_side) * normal[0], 2629ed3d70dSJames Wright dside.Y.velocity[1] + (ds_star - du_side) * normal[1], 2639ed3d70dSJames Wright dside.Y.velocity[2] + (ds_star - du_side) * normal[2], 2649ed3d70dSJames Wright }, 2659ed3d70dSJames Wright dside.U.E_total / side.U.density - side.U.E_total / Square(side.U.density) * dside.U.density // 2669ed3d70dSJames Wright + (ds_star - du_side) * (s_star + side.Y.pressure / denom) // 2679ed3d70dSJames Wright + (s_star - u_side) * (ds_star + dside.Y.pressure / denom - side.Y.pressure / Square(denom) * ddenom) // 2689ed3d70dSJames Wright }; 2699ed3d70dSJames Wright 2709ed3d70dSJames Wright const CeedScalar a[] = {1, ds_side * fact + s_side * dfact, s_side * fact, -ds_side, -s_side}; 2719ed3d70dSJames Wright const StateConservative U[] = {dF_side, star, dstar, side.U, dside.U}; 2729ed3d70dSJames Wright return StateConservativeMult(5, a, U); 2739ed3d70dSJames Wright } 2749ed3d70dSJames Wright 2759ed3d70dSJames Wright // HLLC Riemann solver (from Toro's book) 2769ed3d70dSJames Wright CEED_QFUNCTION_HELPER StateConservative RiemannFlux_HLLC(NewtonianIdealGasContext gas, State left, State right, const CeedScalar normal[3]) { 2779ed3d70dSJames Wright StateConservative flux_left = FluxInviscidDotNormal(gas, left, normal); 2789ed3d70dSJames Wright StateConservative flux_right = FluxInviscidDotNormal(gas, right, normal); 2799ed3d70dSJames Wright 2809ed3d70dSJames Wright CeedScalar u_left = Dot3(left.Y.velocity, normal); 2819ed3d70dSJames Wright CeedScalar u_right = Dot3(right.Y.velocity, normal); 2829ed3d70dSJames Wright CeedScalar s_left, s_right; 2839ed3d70dSJames Wright ComputeHLLSpeeds_Roe(gas, left, u_left, right, u_right, &s_left, &s_right); 2849ed3d70dSJames Wright 2859ed3d70dSJames Wright // Contact wave speed; Toro (10.37) 2869ed3d70dSJames Wright CeedScalar rhou_left = left.U.density * u_left, rhou_right = right.U.density * u_right; 2879ed3d70dSJames Wright CeedScalar numer = right.Y.pressure - left.Y.pressure + rhou_left * (s_left - u_left) - rhou_right * (s_right - u_right); 2889ed3d70dSJames Wright CeedScalar denom = left.U.density * (s_left - u_left) - right.U.density * (s_right - u_right); 2899ed3d70dSJames Wright CeedScalar s_star = numer / denom; 2909ed3d70dSJames Wright 2919ed3d70dSJames Wright // Compute HLLC flux 2929ed3d70dSJames Wright if (0 <= s_left) { 2939ed3d70dSJames Wright return flux_left; 2949ed3d70dSJames Wright } else if (0 <= s_star) { 2959ed3d70dSJames Wright return RiemannFlux_HLLC_Star(gas, left, flux_left, normal, u_left, s_left, s_star); 2969ed3d70dSJames Wright } else if (0 <= s_right) { 2979ed3d70dSJames Wright return RiemannFlux_HLLC_Star(gas, right, flux_right, normal, u_right, s_right, s_star); 2989ed3d70dSJames Wright } else { 2999ed3d70dSJames Wright return flux_right; 3009ed3d70dSJames Wright } 3019ed3d70dSJames Wright } 3029ed3d70dSJames Wright 3039ed3d70dSJames Wright CEED_QFUNCTION_HELPER StateConservative RiemannFlux_HLLC_fwd(NewtonianIdealGasContext gas, State left, State dleft, State right, State dright, 3049ed3d70dSJames Wright const CeedScalar normal[3]) { 3059ed3d70dSJames Wright StateConservative flux_left = FluxInviscidDotNormal(gas, left, normal); 3069ed3d70dSJames Wright StateConservative flux_right = FluxInviscidDotNormal(gas, right, normal); 3079ed3d70dSJames Wright StateConservative dflux_left = FluxInviscidDotNormal_fwd(gas, left, dleft, normal); 3089ed3d70dSJames Wright StateConservative dflux_right = FluxInviscidDotNormal_fwd(gas, right, dright, normal); 3099ed3d70dSJames Wright 3109ed3d70dSJames Wright CeedScalar u_left = Dot3(left.Y.velocity, normal); 3119ed3d70dSJames Wright CeedScalar u_right = Dot3(right.Y.velocity, normal); 3129ed3d70dSJames Wright CeedScalar du_left = Dot3(dleft.Y.velocity, normal); 3139ed3d70dSJames Wright CeedScalar du_right = Dot3(dright.Y.velocity, normal); 3149ed3d70dSJames Wright 3159ed3d70dSJames Wright CeedScalar s_left, ds_left, s_right, ds_right; 3169ed3d70dSJames Wright ComputeHLLSpeeds_Roe_fwd(gas, left, dleft, u_left, du_left, right, dright, u_right, du_right, &s_left, &ds_left, &s_right, &ds_right); 3179ed3d70dSJames Wright 3189ed3d70dSJames Wright // Contact wave speed; Toro (10.37) 3199ed3d70dSJames Wright CeedScalar rhou_left = left.U.density * u_left, drhou_left = left.U.density * du_left + dleft.U.density * u_left; 3209ed3d70dSJames Wright CeedScalar rhou_right = right.U.density * u_right, drhou_right = right.U.density * du_right + dright.U.density * u_right; 3219ed3d70dSJames Wright CeedScalar numer = right.Y.pressure - left.Y.pressure // 3229ed3d70dSJames Wright + rhou_left * (s_left - u_left) // 3239ed3d70dSJames Wright - rhou_right * (s_right - u_right); 3249ed3d70dSJames Wright CeedScalar dnumer = dright.Y.pressure - dleft.Y.pressure // 3259ed3d70dSJames Wright + rhou_left * (ds_left - du_left) + drhou_left * (s_left - u_left) // 3269ed3d70dSJames Wright - rhou_right * (ds_right - du_right) - drhou_right * (s_right - u_right); 3279ed3d70dSJames Wright CeedScalar denom = left.U.density * (s_left - u_left) - right.U.density * (s_right - u_right); 3289ed3d70dSJames Wright CeedScalar ddenom = left.U.density * (ds_left - du_left) + dleft.U.density * (s_left - u_left) // 3299ed3d70dSJames Wright - right.U.density * (ds_right - du_right) - dright.U.density * (s_right - u_right); 3309ed3d70dSJames Wright CeedScalar s_star = numer / denom; 3319ed3d70dSJames Wright CeedScalar ds_star = dnumer / denom - numer / Square(denom) * ddenom; 3329ed3d70dSJames Wright 3339ed3d70dSJames Wright // Compute HLLC flux 3349ed3d70dSJames Wright if (0 <= s_left) { 3359ed3d70dSJames Wright return dflux_left; 3369ed3d70dSJames Wright } else if (0 <= s_star) { 3379ed3d70dSJames Wright return RiemannFlux_HLLC_Star_fwd(gas, left, dleft, flux_left, dflux_left, normal, u_left, du_left, s_left, ds_left, s_star, ds_star); 3389ed3d70dSJames Wright } else if (0 <= s_right) { 3399ed3d70dSJames Wright return RiemannFlux_HLLC_Star_fwd(gas, right, dright, flux_right, dflux_right, normal, u_right, du_right, s_right, ds_right, s_star, ds_star); 3409ed3d70dSJames Wright } else { 3419ed3d70dSJames Wright return dflux_right; 3429ed3d70dSJames Wright } 3439ed3d70dSJames Wright } 344