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This commit is contained in:
jpekkila
2019-10-07 17:17:58 +03:00
parent c8e0586b60
commit 16c8b1e748
2 changed files with 133 additions and 119 deletions
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4
acc/mhd_solver/stencil_definition.h
View File

@@ -9,8 +9,8 @@
#define LSINK (0)
#define AC_THERMAL_CONDUCTIVITY (AcReal(0.001)) // TODO: make an actual config parameter
#define H_CONST (0) // TODO: make an actual config parameter
#define C_CONST (0) // TODO: make an actual config parameter
#define H_CONST (0) // TODO: make an actual config parameter
#define C_CONST (0) // TODO: make an actual config parameter
// Int params
uniform int AC_max_steps;

248
acc/mhd_solver/stencil_process.ac
View File

@@ -1,7 +1,7 @@
#include <stdderiv.h>
#include "stencil_definition.h"
#include "stencil_assembly.h"
#include "stencil_definition.h"
#if LUPWD
Device Scalar
@@ -22,42 +22,44 @@ gradients(in VectorField uu)
#if LSINK
Device Vector
sink_gravity(int3 globalVertexIdx){
sink_gravity(int3 globalVertexIdx)
{
int accretion_switch = int(AC_switch_accretion);
if (accretion_switch == 1){
if (accretion_switch == 1) {
Vector force_gravity;
const Vector grid_pos = (Vector){(globalVertexIdx.x - DCONST(AC_nx_min)) * AC_dsx,
const Vector grid_pos = (Vector){(globalVertexIdx.x - DCONST(AC_nx_min)) * AC_dsx,
(globalVertexIdx.y - DCONST(AC_ny_min)) * AC_dsy,
(globalVertexIdx.z - DCONST(AC_nz_min)) * AC_dsz};
const Scalar sink_mass = AC_M_sink;
const Vector sink_pos = (Vector){AC_sink_pos_x,
AC_sink_pos_y,
AC_sink_pos_z};
const Scalar distance = length(grid_pos - sink_pos);
const Scalar soft = AC_soft;
//MV: The commit 083ff59 had AC_G_const defined wrong here in DSL making it exxessively strong.
//MV: Scalar gravity_magnitude = ... below is correct!
const Scalar gravity_magnitude = (AC_G_const * sink_mass) / pow(((distance * distance) + soft*soft), 1.5);
const Vector sink_pos = (Vector){AC_sink_pos_x, AC_sink_pos_y, AC_sink_pos_z};
const Scalar distance = length(grid_pos - sink_pos);
const Scalar soft = AC_soft;
// MV: The commit 083ff59 had AC_G_const defined wrong here in DSL making it exxessively
// strong. MV: Scalar gravity_magnitude = ... below is correct!
const Scalar gravity_magnitude = (AC_G_const * sink_mass) /
pow(((distance * distance) + soft * soft), 1.5);
const Vector direction = (Vector){(sink_pos.x - grid_pos.x) / distance,
(sink_pos.y - grid_pos.y) / distance,
(sink_pos.z - grid_pos.z) / distance};
force_gravity = gravity_magnitude * direction;
force_gravity = gravity_magnitude * direction;
return force_gravity;
} else {
}
else {
return (Vector){0.0, 0.0, 0.0};
}
}
#endif
#if LSINK
// Give Truelove density
Device Scalar
truelove_density(in ScalarField lnrho){
const Scalar rho = exp(value(lnrho));
truelove_density(in ScalarField lnrho)
{
const Scalar rho = exp(value(lnrho));
const Scalar Jeans_length_squared = (M_PI * AC_cs2_sound) / (AC_G_const * rho);
const Scalar TJ_rho = ((M_PI) * ((AC_dsx * AC_dsx) / Jeans_length_squared) * AC_cs2_sound) / (AC_G_const * AC_dsx * AC_dsx);
//TODO: AC_dsx will cancel out, deal with it later for optimization.
const Scalar TJ_rho = ((M_PI) * ((AC_dsx * AC_dsx) / Jeans_length_squared) * AC_cs2_sound) /
(AC_G_const * AC_dsx * AC_dsx);
// TODO: AC_dsx will cancel out, deal with it later for optimization.
Scalar accretion_rho = TJ_rho;
@@ -66,39 +68,41 @@ truelove_density(in ScalarField lnrho){
// This controls accretion of density/mass to the sink particle.
Device Scalar
sink_accretion(int3 globalVertexIdx, in ScalarField lnrho, Scalar dt){
const Vector grid_pos = (Vector){(globalVertexIdx.x - DCONST(AC_nx_min)) * AC_dsx,
sink_accretion(int3 globalVertexIdx, in ScalarField lnrho, Scalar dt)
{
const Vector grid_pos = (Vector){(globalVertexIdx.x - DCONST(AC_nx_min)) * AC_dsx,
(globalVertexIdx.y - DCONST(AC_ny_min)) * AC_dsy,
(globalVertexIdx.z - DCONST(AC_nz_min)) * AC_dsz};
const Vector sink_pos = (Vector){AC_sink_pos_x,
AC_sink_pos_y,
AC_sink_pos_z};
const Scalar profile_range = AC_accretion_range;
const Vector sink_pos = (Vector){AC_sink_pos_x, AC_sink_pos_y, AC_sink_pos_z};
const Scalar profile_range = AC_accretion_range;
const Scalar accretion_distance = length(grid_pos - sink_pos);
int accretion_switch = AC_switch_accretion;
int accretion_switch = AC_switch_accretion;
Scalar accretion_density;
Scalar weight;
if (accretion_switch == 1){
if ((accretion_distance) <= profile_range){
//weight = Scalar(1.0);
//Hann window function
Scalar window_ratio = accretion_distance/profile_range;
weight = Scalar(0.5)*(Scalar(1.0) - cos(Scalar(2.0)*M_PI*window_ratio));
} else {
if (accretion_switch == 1) {
if ((accretion_distance) <= profile_range) {
// weight = Scalar(1.0);
// Hann window function
Scalar window_ratio = accretion_distance / profile_range;
weight = Scalar(0.5) * (Scalar(1.0) - cos(Scalar(2.0) * M_PI * window_ratio));
}
else {
weight = Scalar(0.0);
}
//Truelove criterion is used as a kind of arbitrary density floor.
// Truelove criterion is used as a kind of arbitrary density floor.
const Scalar lnrho_min = log(truelove_density(lnrho));
Scalar rate;
if (value(lnrho) > lnrho_min) {
rate = (exp(value(lnrho)) - exp(lnrho_min)) / dt;
} else {
}
else {
rate = Scalar(0.0);
}
accretion_density = weight * rate ;
} else {
accretion_density = weight * rate;
}
else {
accretion_density = Scalar(0.0);
}
return accretion_density;
@@ -106,50 +110,50 @@ sink_accretion(int3 globalVertexIdx, in ScalarField lnrho, Scalar dt){
// This controls accretion of velocity to the sink particle.
Device Vector
sink_accretion_velocity(int3 globalVertexIdx, in VectorField uu, Scalar dt) {
const Vector grid_pos = (Vector){(globalVertexIdx.x - DCONST(AC_nx_min)) * AC_dsx,
sink_accretion_velocity(int3 globalVertexIdx, in VectorField uu, Scalar dt)
{
const Vector grid_pos = (Vector){(globalVertexIdx.x - DCONST(AC_nx_min)) * AC_dsx,
(globalVertexIdx.y - DCONST(AC_ny_min)) * AC_dsy,
(globalVertexIdx.z - DCONST(AC_nz_min)) * AC_dsz};
const Vector sink_pos = (Vector){AC_sink_pos_x,
AC_sink_pos_y,
AC_sink_pos_z};
const Scalar profile_range = AC_accretion_range;
const Vector sink_pos = (Vector){AC_sink_pos_x, AC_sink_pos_y, AC_sink_pos_z};
const Scalar profile_range = AC_accretion_range;
const Scalar accretion_distance = length(grid_pos - sink_pos);
int accretion_switch = AC_switch_accretion;
int accretion_switch = AC_switch_accretion;
Vector accretion_velocity;
if (accretion_switch == 1){
if (accretion_switch == 1) {
Scalar weight;
// Step function weighting
// Arch of a cosine function?
// Cubic spline x^3 - x in range [-0.5 , 0.5]
if ((accretion_distance) <= profile_range){
//weight = Scalar(1.0);
//Hann window function
Scalar window_ratio = accretion_distance/profile_range;
weight = Scalar(0.5)*(Scalar(1.0) - cos(Scalar(2.0)*M_PI*window_ratio));
} else {
if ((accretion_distance) <= profile_range) {
// weight = Scalar(1.0);
// Hann window function
Scalar window_ratio = accretion_distance / profile_range;
weight = Scalar(0.5) * (Scalar(1.0) - cos(Scalar(2.0) * M_PI * window_ratio));
}
else {
weight = Scalar(0.0);
}
Vector rate;
// MV: Could we use divergence here ephasize velocitie which are compressive and
// MV: not absorbins stuff that would not be accreted anyway?
if (length(value(uu)) > Scalar(0.0)) {
rate = (Scalar(1.0)/dt) * value(uu);
} else {
rate = (Scalar(1.0) / dt) * value(uu);
}
else {
rate = (Vector){0.0, 0.0, 0.0};
}
accretion_velocity = weight * rate ;
} else {
accretion_velocity = weight * rate;
}
else {
accretion_velocity = (Vector){0.0, 0.0, 0.0};
}
return accretion_velocity;
}
#endif
Device Scalar
continuity(int3 globalVertexIdx, in VectorField uu, in ScalarField lnrho, Scalar dt)
{
@@ -159,16 +163,15 @@ continuity(int3 globalVertexIdx, in VectorField uu, in ScalarField lnrho, Scalar
+ upwd_der6(uu, lnrho)
#endif
#if LSINK
- sink_accretion(globalVertexIdx, lnrho, dt) / exp(value(lnrho))
- sink_accretion(globalVertexIdx, lnrho, dt) / exp(value(lnrho))
#endif
- divergence(uu);
}
#if LENTROPY
Device Vector
momentum(int3 globalVertexIdx, in VectorField uu, in ScalarField lnrho, in ScalarField ss, in VectorField aa, Scalar dt)
momentum(int3 globalVertexIdx, in VectorField uu, in ScalarField lnrho, in ScalarField ss,
in VectorField aa, Scalar dt)
{
const Matrix S = stress_tensor(uu);
const Scalar cs2 = AC_cs2_sound * exp(AC_gamma * value(ss) / AC_cp_sound +
@@ -188,16 +191,17 @@ momentum(int3 globalVertexIdx, in VectorField uu, in ScalarField lnrho, in Scala
(laplace_vec(uu) + Scalar(1.0 / 3.0) * gradient_of_divergence(uu) +
Scalar(2.0) * mul(S, gradient(lnrho))) +
AC_zeta * gradient_of_divergence(uu)
#if LSINK
//Gravity term
#if LSINK
// Gravity term
+ sink_gravity(globalVertexIdx)
//Corresponding loss of momentum
- //(Scalar(1.0) / Scalar( (AC_dsx*AC_dsy*AC_dsz) * exp(value(lnrho)))) * // Correction factor by unit mass
sink_accretion_velocity(globalVertexIdx, uu, dt) // As in Lee et al.(2014)
;
#else
;
#endif
// Corresponding loss of momentum
- //(Scalar(1.0) / Scalar( (AC_dsx*AC_dsy*AC_dsz) * exp(value(lnrho)))) * //
//Correction factor by unit mass
sink_accretion_velocity(globalVertexIdx, uu, dt) // As in Lee et al.(2014)
;
#else
;
#endif
return mom;
}
#elif LTEMPERATURE
@@ -215,11 +219,11 @@ momentum(int3 globalVertexIdx, in VectorField uu, in ScalarField lnrho, in Scala
AC_nu_visc * (laplace_vec(uu) + Scalar(1.0 / 3.0) * gradient_of_divergence(uu) +
Scalar(2.0) * mul(S, gradient(lnrho))) +
AC_zeta * gradient_of_divergence(uu)
#if LSINK
#if LSINK
+ sink_gravity(globalVertexIdx);
#else
;
#endif
#else
;
#endif
#if LGRAVITY
mom = mom - (Vector){0, 0, -10.0};
@@ -240,15 +244,16 @@ momentum(int3 globalVertexIdx, in VectorField uu, in ScalarField lnrho, Scalar d
AC_nu_visc * (laplace_vec(uu) + Scalar(1.0 / 3.0) * gradient_of_divergence(uu) +
Scalar(2.0) * mul(S, gradient(lnrho))) +
AC_zeta * gradient_of_divergence(uu)
#if LSINK
#if LSINK
+ sink_gravity(globalVertexIdx)
//Corresponding loss of momentum
- //(Scalar(1.0) / Scalar( (AC_dsx*AC_dsy*AC_dsz) * exp(value(lnrho)))) * // Correction factor by unit mass
sink_accretion_velocity(globalVertexIdx, uu, dt) // As in Lee et al.(2014)
;
#else
;
#endif
// Corresponding loss of momentum
- //(Scalar(1.0) / Scalar( (AC_dsx*AC_dsy*AC_dsz) * exp(value(lnrho)))) * // Correction
//factor by unit mass
sink_accretion_velocity(globalVertexIdx, uu, dt) // As in Lee et al.(2014)
;
#else
;
#endif
#if LGRAVITY
mom = mom - (Vector){0, 0, -10.0};
@@ -339,22 +344,26 @@ heat_transfer(in VectorField uu, in ScalarField lnrho, in ScalarField tt)
#if LFORCING
Device Vector
simple_vortex_forcing(Vector a, Vector b, Scalar magnitude){
simple_vortex_forcing(Vector a, Vector b, Scalar magnitude)
{
int accretion_switch = AC_switch_accretion;
if (accretion_switch == 0){
return magnitude * cross(normalized(b - a), (Vector){ 0, 0, 1}); // Vortex
} else {
return (Vector){0,0,0};
if (accretion_switch == 0) {
return magnitude * cross(normalized(b - a), (Vector){0, 0, 1}); // Vortex
}
else {
return (Vector){0, 0, 0};
}
}
Device Vector
simple_outward_flow_forcing(Vector a, Vector b, Scalar magnitude){
simple_outward_flow_forcing(Vector a, Vector b, Scalar magnitude)
{
int accretion_switch = AC_switch_accretion;
if (accretion_switch == 0){
if (accretion_switch == 0) {
return magnitude * (1 / length(b - a)) * normalized(b - a); // Outward flow
} else {
return (Vector){0,0,0};
}
else {
return (Vector){0, 0, 0};
}
}
@@ -398,41 +407,45 @@ Vector
forcing(int3 globalVertexIdx, Scalar dt)
{
int accretion_switch = AC_switch_accretion;
if (accretion_switch == 0){
if (accretion_switch == 0) {
Vector a = Scalar(0.5) * (Vector){globalGridN.x * AC_dsx,
globalGridN.y * AC_dsy,
globalGridN.z * AC_dsz}; // source (origin)
Vector xx = (Vector){(globalVertexIdx.x - DCONST(AC_nx_min)) * AC_dsx,
Vector a = Scalar(0.5) * (Vector){globalGridN.x * AC_dsx, globalGridN.y * AC_dsy,
globalGridN.z * AC_dsz}; // source (origin)
Vector xx = (Vector){(globalVertexIdx.x - DCONST(AC_nx_min)) * AC_dsx,
(globalVertexIdx.y - DCONST(AC_ny_min)) * AC_dsy,
(globalVertexIdx.z - DCONST(AC_nz_min)) * AC_dsz}; // sink (current index)
(globalVertexIdx.z - DCONST(AC_nz_min)) *
AC_dsz}; // sink (current index)
const Scalar cs2 = AC_cs2_sound;
const Scalar cs = sqrt(cs2);
const Scalar cs = sqrt(cs2);
//Placeholders until determined properly
// Placeholders until determined properly
Scalar magnitude = AC_forcing_magnitude;
Scalar phase = AC_forcing_phase;
Vector k_force = (Vector){AC_k_forcex, AC_k_forcey, AC_k_forcez};
Vector k_force = (Vector){AC_k_forcex, AC_k_forcey, AC_k_forcez};
Vector ff_re = (Vector){AC_ff_hel_rex, AC_ff_hel_rey, AC_ff_hel_rez};
Vector ff_im = (Vector){AC_ff_hel_imx, AC_ff_hel_imy, AC_ff_hel_imz};
// Determine that forcing funtion type at this point.
// Vector force = simple_vortex_forcing(a, xx, magnitude);
// Vector force = simple_outward_flow_forcing(a, xx, magnitude);
Vector force = helical_forcing(magnitude, k_force, xx, ff_re, ff_im, phase);
//Determine that forcing funtion type at this point.
//Vector force = simple_vortex_forcing(a, xx, magnitude);
//Vector force = simple_outward_flow_forcing(a, xx, magnitude);
Vector force = helical_forcing(magnitude, k_force, xx, ff_re,ff_im, phase);
// Scaling N = magnitude*cs*sqrt(k*cs/dt) * dt
const Scalar NN = cs * sqrt(AC_kaver * cs);
// MV: Like in the Pencil Code. I don't understandf the logic here.
force.x = sqrt(dt) * NN * force.x;
force.y = sqrt(dt) * NN * force.y;
force.z = sqrt(dt) * NN * force.z;
//Scaling N = magnitude*cs*sqrt(k*cs/dt) * dt
const Scalar NN = cs*sqrt(AC_kaver*cs);
//MV: Like in the Pencil Code. I don't understandf the logic here.
force.x = sqrt(dt)*NN*force.x;
force.y = sqrt(dt)*NN*force.y;
force.z = sqrt(dt)*NN*force.z;
if (is_valid(force)) { return force; }
else { return (Vector){0, 0, 0}; }
} else {
return (Vector){0,0,0};
if (is_valid(force)) {
return force;
}
else {
return (Vector){0, 0, 0};
}
}
else {
return (Vector){0, 0, 0};
}
}
#endif // LFORCING
@@ -492,10 +505,11 @@ solve()
#endif
#if LSINK
out_accretion = rk3(out_accretion, accretion, sink_accretion(globalVertexIdx, lnrho, dt), dt);// unit now is rho!
out_accretion = rk3(out_accretion, accretion, sink_accretion(globalVertexIdx, lnrho, dt),
dt); // unit now is rho!
if (step_number == 2) {
out_accretion = out_accretion * AC_dsx * AC_dsy * AC_dsz;// unit is now mass!
out_accretion = out_accretion * AC_dsx * AC_dsy * AC_dsz; // unit is now mass!
}
#endif
}