/* File produced by Kranc */ #define KRANC_C #include #include #include #include #include #include "cctk.h" #include "cctk_Arguments.h" #include "cctk_Parameters.h" #include "GenericFD.h" #include "Differencing.h" #include "cctk_Loop.h" #include "loopcontrol.h" /* Define macros used in calculations */ #define INITVALUE (42) #define INV(x) ((CCTK_REAL)1.0 / (x)) #define SQR(x) ((x) * (x)) #define CUB(x) ((x) * SQR(x)) #define QAD(x) (SQR(SQR(x))) extern "C" void eulerauto_cons_calc_flux_2_SelectBCs(CCTK_ARGUMENTS) { DECLARE_CCTK_ARGUMENTS; DECLARE_CCTK_PARAMETERS; CCTK_INT ierr CCTK_ATTRIBUTE_UNUSED = 0; ierr = Boundary_SelectGroupForBC(cctkGH, CCTK_ALL_FACES, GenericFD_GetBoundaryWidth(cctkGH), -1 /* no table */, "EulerAuto::Den_flux_group","flat"); if (ierr < 0) CCTK_WARN(1, "Failed to register flat BC for EulerAuto::Den_flux_group."); ierr = Boundary_SelectGroupForBC(cctkGH, CCTK_ALL_FACES, GenericFD_GetBoundaryWidth(cctkGH), -1 /* no table */, "EulerAuto::En_flux_group","flat"); if (ierr < 0) CCTK_WARN(1, "Failed to register flat BC for EulerAuto::En_flux_group."); ierr = Boundary_SelectGroupForBC(cctkGH, CCTK_ALL_FACES, GenericFD_GetBoundaryWidth(cctkGH), -1 /* no table */, "EulerAuto::S1_flux_group","flat"); if (ierr < 0) CCTK_WARN(1, "Failed to register flat BC for EulerAuto::S1_flux_group."); ierr = Boundary_SelectGroupForBC(cctkGH, CCTK_ALL_FACES, GenericFD_GetBoundaryWidth(cctkGH), -1 /* no table */, "EulerAuto::S2_flux_group","flat"); if (ierr < 0) CCTK_WARN(1, "Failed to register flat BC for EulerAuto::S2_flux_group."); ierr = Boundary_SelectGroupForBC(cctkGH, CCTK_ALL_FACES, GenericFD_GetBoundaryWidth(cctkGH), -1 /* no table */, "EulerAuto::S3_flux_group","flat"); if (ierr < 0) CCTK_WARN(1, "Failed to register flat BC for EulerAuto::S3_flux_group."); return; } static void eulerauto_cons_calc_flux_2_Body(cGH const * restrict const cctkGH, int const dir, int const face, CCTK_REAL const normal[3], CCTK_REAL const tangentA[3], CCTK_REAL const tangentB[3], int const imin[3], int const imax[3], int const n_subblock_gfs, CCTK_REAL * restrict const subblock_gfs[]) { DECLARE_CCTK_ARGUMENTS; DECLARE_CCTK_PARAMETERS; /* Include user-supplied include files */ /* Initialise finite differencing variables */ ptrdiff_t /*const*/ di CCTK_ATTRIBUTE_UNUSED = 1; ptrdiff_t /*const*/ dj CCTK_ATTRIBUTE_UNUSED = CCTK_GFINDEX3D(cctkGH,0,1,0) - CCTK_GFINDEX3D(cctkGH,0,0,0); ptrdiff_t /*const*/ dk CCTK_ATTRIBUTE_UNUSED = CCTK_GFINDEX3D(cctkGH,0,0,1) - CCTK_GFINDEX3D(cctkGH,0,0,0); ptrdiff_t /*const*/ cdi CCTK_ATTRIBUTE_UNUSED = sizeof(CCTK_REAL) * di; ptrdiff_t /*const*/ cdj CCTK_ATTRIBUTE_UNUSED = sizeof(CCTK_REAL) * dj; ptrdiff_t /*const*/ cdk CCTK_ATTRIBUTE_UNUSED = sizeof(CCTK_REAL) * dk; CCTK_REAL /*const*/ dx CCTK_ATTRIBUTE_UNUSED = ToReal(CCTK_DELTA_SPACE(0)); CCTK_REAL /*const*/ dy CCTK_ATTRIBUTE_UNUSED = ToReal(CCTK_DELTA_SPACE(1)); CCTK_REAL /*const*/ dz CCTK_ATTRIBUTE_UNUSED = ToReal(CCTK_DELTA_SPACE(2)); CCTK_REAL /*const*/ dt CCTK_ATTRIBUTE_UNUSED = ToReal(CCTK_DELTA_TIME); CCTK_REAL /*const*/ t CCTK_ATTRIBUTE_UNUSED = ToReal(cctk_time); CCTK_REAL /*const*/ dxi CCTK_ATTRIBUTE_UNUSED = INV(dx); CCTK_REAL /*const*/ dyi CCTK_ATTRIBUTE_UNUSED = INV(dy); CCTK_REAL /*const*/ dzi CCTK_ATTRIBUTE_UNUSED = INV(dz); CCTK_REAL /*const*/ khalf CCTK_ATTRIBUTE_UNUSED = 0.5; CCTK_REAL /*const*/ kthird CCTK_ATTRIBUTE_UNUSED = 1/3.0; CCTK_REAL /*const*/ ktwothird CCTK_ATTRIBUTE_UNUSED = 2.0/3.0; CCTK_REAL /*const*/ kfourthird CCTK_ATTRIBUTE_UNUSED = 4.0/3.0; CCTK_REAL /*const*/ keightthird CCTK_ATTRIBUTE_UNUSED = 8.0/3.0; CCTK_REAL /*const*/ hdxi CCTK_ATTRIBUTE_UNUSED = 0.5 * dxi; CCTK_REAL /*const*/ hdyi CCTK_ATTRIBUTE_UNUSED = 0.5 * dyi; CCTK_REAL /*const*/ hdzi CCTK_ATTRIBUTE_UNUSED = 0.5 * dzi; /* Initialize predefined quantities */ CCTK_REAL /*const*/ p1o1 CCTK_ATTRIBUTE_UNUSED = 1.; CCTK_REAL /*const*/ p1odx CCTK_ATTRIBUTE_UNUSED = INV(dx); CCTK_REAL /*const*/ p1ody CCTK_ATTRIBUTE_UNUSED = INV(dy); CCTK_REAL /*const*/ p1odz CCTK_ATTRIBUTE_UNUSED = INV(dz); /* Assign local copies of arrays functions */ /* Calculate temporaries and arrays functions */ /* Copy local copies back to grid functions */ /* Loop over the grid points */ #pragma omp parallel CCTK_LOOP3(eulerauto_cons_calc_flux_2, i,j,k, imin[0],imin[1],imin[2], imax[0],imax[1],imax[2], cctk_ash[0],cctk_ash[1],cctk_ash[2]) { ptrdiff_t /*const*/ index CCTK_ATTRIBUTE_UNUSED = di*i + dj*j + dk*k; /* Assign local copies of grid functions */ CCTK_REAL DenLeftL CCTK_ATTRIBUTE_UNUSED = DenLeft[index]; CCTK_REAL DenRightL CCTK_ATTRIBUTE_UNUSED = DenRight[index]; CCTK_REAL EnLeftL CCTK_ATTRIBUTE_UNUSED = EnLeft[index]; CCTK_REAL EnRightL CCTK_ATTRIBUTE_UNUSED = EnRight[index]; CCTK_REAL pLeftL CCTK_ATTRIBUTE_UNUSED = pLeft[index]; CCTK_REAL pRightL CCTK_ATTRIBUTE_UNUSED = pRight[index]; CCTK_REAL rhoLeftL CCTK_ATTRIBUTE_UNUSED = rhoLeft[index]; CCTK_REAL rhoRightL CCTK_ATTRIBUTE_UNUSED = rhoRight[index]; CCTK_REAL S1LeftL CCTK_ATTRIBUTE_UNUSED = S1Left[index]; CCTK_REAL S1RightL CCTK_ATTRIBUTE_UNUSED = S1Right[index]; CCTK_REAL S2LeftL CCTK_ATTRIBUTE_UNUSED = S2Left[index]; CCTK_REAL S2RightL CCTK_ATTRIBUTE_UNUSED = S2Right[index]; CCTK_REAL S3LeftL CCTK_ATTRIBUTE_UNUSED = S3Left[index]; CCTK_REAL S3RightL CCTK_ATTRIBUTE_UNUSED = S3Right[index]; CCTK_REAL v1LeftL CCTK_ATTRIBUTE_UNUSED = v1Left[index]; CCTK_REAL v1RightL CCTK_ATTRIBUTE_UNUSED = v1Right[index]; CCTK_REAL v2LeftL CCTK_ATTRIBUTE_UNUSED = v2Left[index]; CCTK_REAL v2RightL CCTK_ATTRIBUTE_UNUSED = v2Right[index]; CCTK_REAL v3LeftL CCTK_ATTRIBUTE_UNUSED = v3Left[index]; CCTK_REAL v3RightL CCTK_ATTRIBUTE_UNUSED = v3Right[index]; /* Include user supplied include files */ /* Precompute derivatives */ CCTK_REAL /*const*/ ShiftMinus2DenRight CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&DenRight[index]); CCTK_REAL /*const*/ ShiftMinus2EnRight CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&EnRight[index]); CCTK_REAL /*const*/ ShiftMinus2pRight CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&pRight[index]); CCTK_REAL /*const*/ ShiftMinus2rhoRight CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&rhoRight[index]); CCTK_REAL /*const*/ ShiftMinus2S1Right CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&S1Right[index]); CCTK_REAL /*const*/ ShiftMinus2S2Right CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&S2Right[index]); CCTK_REAL /*const*/ ShiftMinus2S3Right CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&S3Right[index]); CCTK_REAL /*const*/ ShiftMinus2v1Right CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&v1Right[index]); CCTK_REAL /*const*/ ShiftMinus2v2Right CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&v2Right[index]); CCTK_REAL /*const*/ ShiftMinus2v3Right CCTK_ATTRIBUTE_UNUSED = ShiftMinus2(&v3Right[index]); /* Calculate temporaries and grid functions */ CCTK_REAL CCTK_ATTRIBUTE_UNUSED DenFluxLeft = rhoLeftL*v2LeftL; CCTK_REAL CCTK_ATTRIBUTE_UNUSED DenFluxRight = ShiftMinus2rhoRight*ShiftMinus2v2Right; CCTK_REAL CCTK_ATTRIBUTE_UNUSED DenFluxL = 0.5*(DenFluxLeft + DenFluxRight + (-1.*DenLeftL + ShiftMinus2DenRight)*ToReal(hlleAlpha)); CCTK_REAL CCTK_ATTRIBUTE_UNUSED S1FluxLeft = rhoLeftL*v1LeftL*v2LeftL; CCTK_REAL CCTK_ATTRIBUTE_UNUSED S1FluxRight = ShiftMinus2rhoRight*ShiftMinus2v1Right*ShiftMinus2v2Right; CCTK_REAL CCTK_ATTRIBUTE_UNUSED S1FluxL = 0.5*(S1FluxLeft + S1FluxRight + (-1.*S1LeftL + ShiftMinus2S1Right)*ToReal(hlleAlpha)); CCTK_REAL CCTK_ATTRIBUTE_UNUSED S2FluxLeft = pLeftL + rhoLeftL*SQR(v2LeftL); CCTK_REAL CCTK_ATTRIBUTE_UNUSED S2FluxRight = ShiftMinus2pRight + ShiftMinus2rhoRight*SQR(ShiftMinus2v2Right); CCTK_REAL CCTK_ATTRIBUTE_UNUSED S2FluxL = 0.5*(S2FluxLeft + S2FluxRight + (-1.*S2LeftL + ShiftMinus2S2Right)*ToReal(hlleAlpha)); CCTK_REAL CCTK_ATTRIBUTE_UNUSED S3FluxLeft = rhoLeftL*v2LeftL*v3LeftL; CCTK_REAL CCTK_ATTRIBUTE_UNUSED S3FluxRight = ShiftMinus2rhoRight*ShiftMinus2v2Right*ShiftMinus2v3Right; CCTK_REAL CCTK_ATTRIBUTE_UNUSED S3FluxL = 0.5*(S3FluxLeft + S3FluxRight + (-1.*S3LeftL + ShiftMinus2S3Right)*ToReal(hlleAlpha)); CCTK_REAL CCTK_ATTRIBUTE_UNUSED EnFluxLeft = (EnLeftL + pLeftL)*v2LeftL; CCTK_REAL CCTK_ATTRIBUTE_UNUSED EnFluxRight = (ShiftMinus2EnRight + ShiftMinus2pRight)*ShiftMinus2v2Right; CCTK_REAL CCTK_ATTRIBUTE_UNUSED EnFluxL = 0.5*(EnFluxLeft + EnFluxRight + (-1.*EnLeftL + ShiftMinus2EnRight)*ToReal(hlleAlpha)); /* Copy local copies back to grid functions */ DenFlux[index] = DenFluxL; EnFlux[index] = EnFluxL; S1Flux[index] = S1FluxL; S2Flux[index] = S2FluxL; S3Flux[index] = S3FluxL; } CCTK_ENDLOOP3(eulerauto_cons_calc_flux_2); } extern "C" void eulerauto_cons_calc_flux_2(CCTK_ARGUMENTS) { DECLARE_CCTK_ARGUMENTS; DECLARE_CCTK_PARAMETERS; if (verbose > 1) { CCTK_VInfo(CCTK_THORNSTRING,"Entering eulerauto_cons_calc_flux_2_Body"); } if (cctk_iteration % eulerauto_cons_calc_flux_2_calc_every != eulerauto_cons_calc_flux_2_calc_offset) { return; } const char *const groups[] = { "EulerAuto::Den_flux_group", "EulerAuto::Den_lr_group", "EulerAuto::En_flux_group", "EulerAuto::En_lr_group", "EulerAuto::p_lr_group", "EulerAuto::rho_lr_group", "EulerAuto::S1_flux_group", "EulerAuto::S1_lr_group", "EulerAuto::S2_flux_group", "EulerAuto::S2_lr_group", "EulerAuto::S3_flux_group", "EulerAuto::S3_lr_group", "EulerAuto::v1_lr_group", "EulerAuto::v2_lr_group", "EulerAuto::v3_lr_group"}; GenericFD_AssertGroupStorage(cctkGH, "eulerauto_cons_calc_flux_2", 15, groups); GenericFD_EnsureStencilFits(cctkGH, "eulerauto_cons_calc_flux_2", 1, 1, 1); GenericFD_LoopOverInterior(cctkGH, eulerauto_cons_calc_flux_2_Body); if (verbose > 1) { CCTK_VInfo(CCTK_THORNSTRING,"Leaving eulerauto_cons_calc_flux_2_Body"); } }