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Add subcell limiting support for P4estMesh (#1954)
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* First part of P4estMesh support

* Adapt `get_boundary_outer_state` to allow supersoniv cylinder eilixir

* Add test

* Rename routine

* Rename other routine

* Adapt elixir and complete testing

* Adapt tests

* Adapt cfl in elixir

* Fix test

* Add sedov elixir to test periodic boundaries

* fmt

* Activate test for coverage run

* Remove extra lines of code

* Implement suggestions

* Adapt parameters to reduce bounds checking errors

* Implement first suggestions

* Remove `mesh` from `get_boundary_outer_state`

* Use `foreach_enumerate` to remove allocations

* Move `get_boundary_outer_state` to elixir

---------

Co-authored-by: Michael Schlottke-Lakemper <[email protected]>
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@bennibolm @sloede
bennibolm and sloede authored Aug 30, 2024
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102 changes: 102 additions & 0 deletions examples/p4est_2d_dgsem/elixir_euler_sedov_blast_wave_sc_subcell.jl
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using OrdinaryDiffEq
using Trixi

###############################################################################
# semidiscretization of the compressible Euler equations

equations = CompressibleEulerEquations2D(1.4)

"""
initial_condition_sedov_blast_wave(x, t, equations::CompressibleEulerEquations2D)
The Sedov blast wave setup based on Flash
- https://flash.rochester.edu/site/flashcode/user_support/flash_ug_devel/node187.html#SECTION010114000000000000000
"""
function initial_condition_sedov_blast_wave(x, t, equations::CompressibleEulerEquations2D)
# Set up polar coordinates
inicenter = SVector(0.0, 0.0)
x_norm = x[1] - inicenter[1]
y_norm = x[2] - inicenter[2]
r = sqrt(x_norm^2 + y_norm^2)

# Setup based on https://flash.rochester.edu/site/flashcode/user_support/flash_ug_devel/node187.html#SECTION010114000000000000000
r0 = 0.21875 # = 3.5 * smallest dx (for domain length=4 and max-ref=6)
E = 1.0
p0_inner = 3 * (equations.gamma - 1) * E / (3 * pi * r0^2)
p0_outer = 1.0e-5 # = true Sedov setup

# Calculate primitive variables
rho = 1.0
v1 = 0.0
v2 = 0.0
p = r > r0 ? p0_outer : p0_inner

return prim2cons(SVector(rho, v1, v2, p), equations)
end

initial_condition = initial_condition_sedov_blast_wave

# Get the DG approximation space
surface_flux = flux_lax_friedrichs
volume_flux = flux_ranocha
polydeg = 3
basis = LobattoLegendreBasis(polydeg)
limiter_idp = SubcellLimiterIDP(equations, basis;
local_twosided_variables_cons = ["rho"],
local_onesided_variables_nonlinear = [(Trixi.entropy_guermond_etal,
min)],
max_iterations_newton = 40, # Default parameters are not sufficient to fulfill bounds properly.
newton_tolerances = (1.0e-14, 1.0e-15))

volume_integral = VolumeIntegralSubcellLimiting(limiter_idp;
volume_flux_dg = volume_flux,
volume_flux_fv = surface_flux)
solver = DGSEM(basis, surface_flux, volume_integral)

###############################################################################

coordinates_min = (-1.0, -1.0)
coordinates_max = (1.0, 1.0)

trees_per_dimension = (4, 4)
mesh = P4estMesh(trees_per_dimension,
polydeg = polydeg, initial_refinement_level = 2,
coordinates_min = coordinates_min, coordinates_max = coordinates_max,
periodicity = true)

semi = SemidiscretizationHyperbolic(mesh, equations, initial_condition, solver)

###############################################################################
# ODE solvers, callbacks etc.

tspan = (0.0, 3.0)
ode = semidiscretize(semi, tspan)

summary_callback = SummaryCallback()

analysis_interval = 300
analysis_callback = AnalysisCallback(semi, interval = analysis_interval)

alive_callback = AliveCallback(analysis_interval = analysis_interval)

save_solution = SaveSolutionCallback(interval = 300,
save_initial_solution = true,
save_final_solution = true)

stepsize_callback = StepsizeCallback(cfl = 0.5)

callbacks = CallbackSet(summary_callback,
analysis_callback,
alive_callback,
save_solution,
stepsize_callback)

###############################################################################
# run the simulation

stage_callbacks = (SubcellLimiterIDPCorrection(), BoundsCheckCallback())

sol = Trixi.solve(ode, Trixi.SimpleSSPRK33(stage_callbacks = stage_callbacks);
dt = 1.0, # solve needs some value here but it will be overwritten by the stepsize_callback
callback = callbacks);
summary_callback() # print the timer summary
162 changes: 162 additions & 0 deletions examples/p4est_2d_dgsem/elixir_euler_supersonic_cylinder_sc_subcell.jl
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# Channel flow around a cylinder at Mach 3
#
# Boundary conditions are supersonic Mach 3 inflow at the left portion of the domain
# and supersonic outflow at the right portion of the domain. The top and bottom of the
# channel as well as the cylinder are treated as Euler slip wall boundaries.
# This flow results in strong shock reflections / interactions as well as Kelvin-Helmholtz
# instabilities at later times as two Mach stems form above and below the cylinder.
#
# For complete details on the problem setup see Section 5.7 of the paper:
# - Jean-Luc Guermond, Murtazo Nazarov, Bojan Popov, and Ignacio Tomas (2018)
# Second-Order Invariant Domain Preserving Approximation of the Euler Equations using Convex Limiting.
# [DOI: 10.1137/17M1149961](https://doi.org/10.1137/17M1149961)
#
# Keywords: supersonic flow, shock capturing, AMR, unstructured curved mesh, positivity preservation, compressible Euler, 2D

using OrdinaryDiffEq
using Trixi

###############################################################################
# semidiscretization of the compressible Euler equations

equations = CompressibleEulerEquations2D(1.4)

@inline function initial_condition_mach3_flow(x, t, equations::CompressibleEulerEquations2D)
# set the freestream flow parameters
rho_freestream = 1.4
v1 = 3.0
v2 = 0.0
p_freestream = 1.0

prim = SVector(rho_freestream, v1, v2, p_freestream)
return prim2cons(prim, equations)
end

initial_condition = initial_condition_mach3_flow

# Supersonic inflow boundary condition.
# Calculate the boundary flux entirely from the external solution state, i.e., set
# external solution state values for everything entering the domain.
@inline function boundary_condition_supersonic_inflow(u_inner,
normal_direction::AbstractVector,
x, t, surface_flux_function,
equations::CompressibleEulerEquations2D)
u_boundary = initial_condition_mach3_flow(x, t, equations)
flux = Trixi.flux(u_boundary, normal_direction, equations)

return flux
end

# For subcell limiting, the calculation of local bounds for non-periodic domains requires the
# boundary outer state. Those functions return the boundary value for a specific boundary condition
# at time `t`, for the node with spatial indices `indices` and the given `normal_direction`.
# only for P4estMesh{2}
@inline function Trixi.get_boundary_outer_state(u_inner, t,
boundary_condition::typeof(boundary_condition_supersonic_inflow),
normal_direction::AbstractVector,
equations, dg, cache,
indices...)
x = Trixi.get_node_coords(cache.elements.node_coordinates, equations, dg, indices...)

return initial_condition_mach3_flow(x, t, equations)
end

# Supersonic outflow boundary condition.
# Calculate the boundary flux entirely from the internal solution state. Analogous to supersonic inflow
# except all the solution state values are set from the internal solution as everything leaves the domain
@inline function boundary_condition_outflow(u_inner, normal_direction::AbstractVector, x, t,
surface_flux_function,
equations::CompressibleEulerEquations2D)
flux = Trixi.flux(u_inner, normal_direction, equations)

return flux
end

# only for P4estMesh{2}
@inline function Trixi.get_boundary_outer_state(u_inner, t,
boundary_condition::typeof(boundary_condition_outflow),
normal_direction::AbstractVector,
equations, dg, cache,
indices...)
return u_inner
end

# only for P4estMesh{2}
@inline function Trixi.get_boundary_outer_state(u_inner, t,
boundary_condition::typeof(boundary_condition_slip_wall),
normal_direction::AbstractVector,
equations::CompressibleEulerEquations2D,
dg, cache, indices...)
factor = (normal_direction[1] * u_inner[2] + normal_direction[2] * u_inner[3])
u_normal = (factor / sum(normal_direction .^ 2)) * normal_direction

return SVector(u_inner[1],
u_inner[2] - 2 * u_normal[1],
u_inner[3] - 2 * u_normal[2],
u_inner[4])
end

boundary_conditions = Dict(:Bottom => boundary_condition_slip_wall,
:Circle => boundary_condition_slip_wall,
:Top => boundary_condition_slip_wall,
:Right => boundary_condition_outflow,
:Left => boundary_condition_supersonic_inflow)

volume_flux = flux_ranocha_turbo
surface_flux = flux_lax_friedrichs
polydeg = 3
basis = LobattoLegendreBasis(polydeg)
limiter_idp = SubcellLimiterIDP(equations, basis;
local_twosided_variables_cons = ["rho"],
positivity_variables_nonlinear = [pressure],
local_onesided_variables_nonlinear = [(Trixi.entropy_guermond_etal,
min)],
max_iterations_newton = 50) # Default value of 10 iterations is too low to fulfill bounds.

volume_integral = VolumeIntegralSubcellLimiting(limiter_idp;
volume_flux_dg = volume_flux,
volume_flux_fv = surface_flux)
solver = DGSEM(basis, surface_flux, volume_integral)

# Get the unstructured quad mesh from a file (downloads the file if not available locally)
mesh_file = Trixi.download("https://gist.githubusercontent.com/andrewwinters5000/a08f78f6b185b63c3baeff911a63f628/raw/addac716ea0541f588b9d2bd3f92f643eb27b88f/abaqus_cylinder_in_channel.inp",
joinpath(@__DIR__, "abaqus_cylinder_in_channel.inp"))

mesh = P4estMesh{2}(mesh_file, initial_refinement_level = 0)

semi = SemidiscretizationHyperbolic(mesh, equations, initial_condition, solver,
boundary_conditions = boundary_conditions)

###############################################################################
# ODE solvers

tspan = (0.0, 2.0)
ode = semidiscretize(semi, tspan)

# Callbacks

summary_callback = SummaryCallback()

analysis_interval = 1000
analysis_callback = AnalysisCallback(semi, interval = analysis_interval)

alive_callback = AliveCallback(analysis_interval = analysis_interval)

save_solution = SaveSolutionCallback(interval = 1000,
save_initial_solution = true,
save_final_solution = true,
solution_variables = cons2prim)

stepsize_callback = StepsizeCallback(cfl = 0.8)

callbacks = CallbackSet(summary_callback,
analysis_callback, alive_callback,
save_solution,
stepsize_callback)

stage_callbacks = (SubcellLimiterIDPCorrection(), BoundsCheckCallback())

sol = Trixi.solve(ode, Trixi.SimpleSSPRK33(stage_callbacks = stage_callbacks);
dt = 1.0, # solve needs some value here but it will be overwritten by the stepsize_callback
callback = callbacks);
summary_callback() # print the timer summary
42 changes: 42 additions & 0 deletions src/callbacks_stage/subcell_bounds_check.jl
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Expand Up @@ -171,5 +171,47 @@ end
return nothing
end

@inline function save_bounds_check_errors(output_directory, time, iter, equations,
limiter::SubcellLimiterIDP)
(; local_twosided, positivity, local_onesided) = limiter
(; idp_bounds_delta_local) = limiter.cache

# Print to output file
open(joinpath(output_directory, "deviations.txt"), "a") do f
print(f, iter, ", ", time)
if local_twosided
for v in limiter.local_twosided_variables_cons
v_string = string(v)
print(f, ", ", idp_bounds_delta_local[Symbol(v_string, "_min")],
", ", idp_bounds_delta_local[Symbol(v_string, "_max")])
end
end
if local_onesided
for (variable, min_or_max) in limiter.local_onesided_variables_nonlinear
key = Symbol(string(variable), "_", string(min_or_max))
print(f, ", ", idp_bounds_delta_local[key])
end
end
if positivity
for v in limiter.positivity_variables_cons
if v in limiter.local_twosided_variables_cons
continue
end
print(f, ", ", idp_bounds_delta_local[Symbol(string(v), "_min")])
end
for variable in limiter.positivity_variables_nonlinear
print(f, ", ", idp_bounds_delta_local[Symbol(string(variable), "_min")])
end
end
println(f)
end
# Reset local maximum deviations
for (key, _) in idp_bounds_delta_local
idp_bounds_delta_local[key] = zero(eltype(idp_bounds_delta_local[key]))
end

return nothing
end

include("subcell_bounds_check_2d.jl")
end # @muladd
47 changes: 2 additions & 45 deletions src/callbacks_stage/subcell_bounds_check_2d.jl
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Expand Up @@ -5,8 +5,8 @@
@muladd begin
#! format: noindent

@inline function check_bounds(u, equations, solver, cache,
limiter::SubcellLimiterIDP)
@inline function check_bounds(u, equations::AbstractEquations{2}, # only works for 2D
solver, cache, limiter::SubcellLimiterIDP)
(; local_twosided, positivity, local_onesided) = solver.volume_integral.limiter
(; variable_bounds) = limiter.cache.subcell_limiter_coefficients
(; idp_bounds_delta_local, idp_bounds_delta_global) = limiter.cache
Expand Down Expand Up @@ -102,47 +102,4 @@

return nothing
end

@inline function save_bounds_check_errors(output_directory, time, iter, equations,
limiter::SubcellLimiterIDP)
(; local_twosided, positivity, local_onesided) = limiter
(; idp_bounds_delta_local) = limiter.cache

# Print to output file
open(joinpath(output_directory, "deviations.txt"), "a") do f
print(f, iter, ", ", time)
if local_twosided
for v in limiter.local_twosided_variables_cons
v_string = string(v)
print(f, ", ", idp_bounds_delta_local[Symbol(v_string, "_min")],
", ", idp_bounds_delta_local[Symbol(v_string, "_max")])
end
end
if local_onesided
for (variable, min_or_max) in limiter.local_onesided_variables_nonlinear
key = Symbol(string(variable), "_", string(min_or_max))
print(f, ", ", idp_bounds_delta_local[key])
end
end
if positivity
for v in limiter.positivity_variables_cons
if v in limiter.local_twosided_variables_cons
continue
end
print(f, ", ", idp_bounds_delta_local[Symbol(string(v), "_min")])
end
for variable in limiter.positivity_variables_nonlinear
print(f, ", ", idp_bounds_delta_local[Symbol(string(variable), "_min")])
end
end
println(f)
end

# Reset local maximum deviations
for (key, _) in idp_bounds_delta_local
idp_bounds_delta_local[key] = zero(eltype(idp_bounds_delta_local[key]))
end

return nothing
end
end # @muladd
3 changes: 2 additions & 1 deletion src/callbacks_stage/subcell_limiter_idp_correction_2d.jl
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Expand Up @@ -6,7 +6,8 @@
#! format: noindent

function perform_idp_correction!(u, dt,
mesh::Union{TreeMesh{2}, StructuredMesh{2}},
mesh::Union{TreeMesh{2}, StructuredMesh{2},
P4estMesh{2}},
equations, dg, cache)
@unpack inverse_weights = dg.basis
@unpack antidiffusive_flux1_L, antidiffusive_flux2_L, antidiffusive_flux1_R, antidiffusive_flux2_R = cache.antidiffusive_fluxes
Expand Down
2 changes: 2 additions & 0 deletions src/solvers/dgsem_p4est/dg.jl
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Expand Up @@ -53,4 +53,6 @@ include("dg_2d_parabolic.jl")
include("dg_3d.jl")
include("dg_3d_parabolic.jl")
include("dg_parallel.jl")

include("subcell_limiters_2d.jl")
end # @muladd
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