Commit 026cf82d authored by Martin Bauer's avatar Martin Bauer
Browse files

Functions to compile boundary handling at border into kernel

parent b6a765a0
...@@ -3,7 +3,6 @@ import sympy as sp ...@@ -3,7 +3,6 @@ import sympy as sp
from lbmpy.boundaries.boundaryhandling import BoundaryOffsetInfo, LbmWeightInfo from lbmpy.boundaries.boundaryhandling import BoundaryOffsetInfo, LbmWeightInfo
from lbmpy.simplificationfactory import create_simplification_strategy from lbmpy.simplificationfactory import create_simplification_strategy
from pystencils import Assignment, Field from pystencils import Assignment, Field
from pystencils.astnodes import SympyAssignment
from pystencils.data_types import create_type from pystencils.data_types import create_type
from pystencils.sympyextensions import get_symmetric_part from pystencils.sympyextensions import get_symmetric_part
...@@ -203,8 +202,8 @@ class FixedDensity(Boundary): ...@@ -203,8 +202,8 @@ class FixedDensity(Boundary):
subexpressions = [Assignment(eq.lhs, transformed_density if eq.lhs == density_symbol else eq.rhs) subexpressions = [Assignment(eq.lhs, transformed_density if eq.lhs == density_symbol else eq.rhs)
for eq in symmetric_eq.subexpressions] for eq in symmetric_eq.subexpressions]
return subexpressions + [SympyAssignment(pdf_field[neighbor](inverse_dir), return subexpressions + [Assignment(pdf_field[neighbor](inverse_dir),
2 * eq_component - pdf_field(direction_symbol))] 2 * eq_component - pdf_field(direction_symbol))]
class NeumannByCopy(Boundary): class NeumannByCopy(Boundary):
......
import sympy as sp
from lbmpy.boundaries.boundaryhandling import BoundaryOffsetInfo, LbmWeightInfo
from pystencils.assignment import Assignment
from pystencils.astnodes import LoopOverCoordinate
from pystencils.data_types import cast_func
from pystencils.field import Field
from pystencils.simp.assignment_collection import AssignmentCollection
from pystencils.stencil import inverse_direction
from pystencils.sympyextensions import fast_subs
def direction_indices_in_direction(direction, stencil):
for i, offset in enumerate(stencil):
for d_i, o_i in zip(direction, offset):
if (d_i == 1 and o_i == 1) or (d_i == -1 and o_i == -1):
yield i
break
def boundary_substitutions(lb_method):
stencil = lb_method.stencil
w = lb_method.weights
replacements = {}
for idx, offset in enumerate(stencil):
symbolic_offset = BoundaryOffsetInfo.offset_from_dir(idx, dim=lb_method.dim)
for sym, value in zip(symbolic_offset, offset):
replacements[sym] = value
replacements[BoundaryOffsetInfo.inv_dir(idx)] = stencil.index(inverse_direction(offset))
replacements[LbmWeightInfo.weight_of_direction(idx)] = w[idx]
return replacements
def transformed_boundary_rule(boundary, accessor, field, direction_symbol, lb_method, **kwargs):
tmp_field = field.new_field_with_different_name("_tmp")
rule = boundary(tmp_field, direction_symbol, lb_method, **kwargs)
bsubs = boundary_substitutions(lb_method)
rule = [a.subs(bsubs) for a in rule]
accessor_writes = accessor.write(tmp_field, lb_method.stencil)
to_replace = set()
for assignment in rule:
to_replace.update({fa for fa in assignment.atoms(Field.Access) if fa.field == tmp_field})
def compute_replacement(fa):
f = fa.index[0]
shift = accessor_writes[f].offsets
new_index = tuple(a + b for a, b in zip(fa.offsets, shift))
return field[new_index](accessor_writes[f].index[0])
substitutions = {fa: compute_replacement(fa) for fa in to_replace}
all_assignments = [assignment.subs(substitutions) for assignment in rule]
main_assignments = [a for a in all_assignments if isinstance(a.lhs, Field.Access)]
sub_expressions = [a for a in all_assignments if not isinstance(a.lhs, Field.Access)]
return AssignmentCollection(main_assignments, sub_expressions)
def type_all_numbers(expr, dtype):
substitutions = {a: cast_func(a, dtype) for a in expr.atoms(sp.Number)}
return expr.subs(substitutions)
def border_conditions(direction, field, ghost_layers=1):
abs_direction = tuple(-e if e < 0 else e for e in direction)
assert sum(abs_direction) == 1
idx = abs_direction.index(1)
val = direction[idx]
loop_ctrs = [LoopOverCoordinate.get_loop_counter_symbol(i) for i in range(len(direction))]
loop_ctr = loop_ctrs[idx]
gl = ghost_layers
border_condition = sp.Eq(loop_ctr, gl if val < 0 else field.shape[idx] - gl - 1)
if ghost_layers == 0:
return type_all_numbers(border_condition, loop_ctr.dtype)
else:
other_min = [sp.Ge(c, gl)
for c in loop_ctrs if c != loop_ctr]
other_max = [sp.Lt(c, field.shape[i] - gl)
for i, c in enumerate(loop_ctrs) if c != loop_ctr]
result = sp.And(border_condition, *other_min, *other_max)
return type_all_numbers(result, loop_ctr.dtype)
def read_assignments_with_boundaries(collision_rule, pdf_field,
boundary_spec,
prev_timestep_accessor,
current_timestep_accessor):
method = collision_rule.method
result = {a: [b, a] for a, b in zip(current_timestep_accessor.read(pdf_field, method.stencil),
method.pre_collision_pdf_symbols)}
for direction, boundary in boundary_spec.items():
dir_indices = direction_indices_in_direction(direction, method.stencil)
border_cond = border_conditions(direction, pdf_field, ghost_layers=1)
for dir_index in dir_indices:
ac = transformed_boundary_rule(boundary, prev_timestep_accessor, pdf_field, dir_index,
method, index_field=None)
assignments = ac.new_without_subexpressions().main_assignments
assert len(assignments) == 1
assignment = assignments[0]
assert assignment.lhs in result
value_without_boundary = result[assignment.lhs][1]
result[assignment.lhs][1] = sp.Piecewise((assignment.rhs, border_cond),
(value_without_boundary, True))
return AssignmentCollection([Assignment(*e) for e in result.values()])
def update_rule_with_boundaries(collision_rule, input_field, output_field,
boundaries,
accessor, prev_accessor=None):
if prev_accessor is None:
prev_accessor = accessor
reads = read_assignments_with_boundaries(collision_rule, input_field, boundaries,
prev_timestep_accessor=prev_accessor,
current_timestep_accessor=accessor)
write_substitutions = {}
method = collision_rule.method
post_collision_symbols = method.post_collision_pdf_symbols
pre_collision_symbols = method.pre_collision_pdf_symbols
output_accesses = accessor.write(output_field, method.stencil)
input_accesses = accessor.read(input_field, method.stencil)
for (idx, offset), output_access in zip(enumerate(method.stencil), output_accesses):
write_substitutions[post_collision_symbols[idx]] = output_access
result = collision_rule.new_with_substitutions(write_substitutions)
result.subexpressions = reads.all_assignments + result.subexpressions
if 'split_groups' in result.simplification_hints:
all_substitutions = write_substitutions.copy()
for (idx, offset), input_access in zip(enumerate(method.stencil), input_accesses):
all_substitutions[pre_collision_symbols[idx]] = input_access
new_split_groups = []
for split_group in result.simplification_hints['split_groups']:
new_split_groups.append([fast_subs(e, all_substitutions) for e in split_group])
result.simplification_hints['split_groups'] = new_split_groups
return result
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