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# include <set>
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# include <regex>
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# include <mystdlib.h>
# include "global.hpp"
# include "debugging.hpp"
# include "boundarylayer.hpp"
# include "meshfunc.hpp"
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namespace netgen
{
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// checks if a segment is intersecting a plane, spanned by three points, lam will be set s.t. p_intersect = seg[0] + lam * (seg[1]-seg[0])
bool isIntersectingPlane ( const array < Point < 3 > , 2 > & seg , const array < Point < 3 > , 3 > & trig , double & lam )
{
auto n = Cross ( trig [ 1 ] - trig [ 0 ] , trig [ 2 ] - trig [ 0 ] ) ;
auto v0n = ( seg [ 0 ] - trig [ 0 ] ) * n ;
auto v1n = ( seg [ 1 ] - trig [ 0 ] ) * n ;
if ( v0n * v1n > = 0 )
return false ;
lam = - v0n / ( v1n - v0n ) ;
lam * = 0.9 ;
if ( lam < - 1e-8 | | lam > 1 + 1e-8 )
return false ;
return true ;
}
bool isIntersectingPlane ( const array < Point < 3 > , 2 > & seg , const ArrayMem < Point < 3 > , 4 > & face , double & lam )
{
lam = 1.0 ;
bool intersect0 = isIntersectingPlane ( seg , array < Point < 3 > , 3 > { face [ 0 ] , face [ 1 ] , face [ 2 ] } , lam ) ;
if ( face . Size ( ) = = 3 )
return intersect0 ;
double lam1 = 1.0 ;
bool intersect1 = isIntersectingPlane ( seg , array < Point < 3 > , 3 > { face [ 2 ] , face [ 3 ] , face [ 0 ] } , lam1 ) ;
lam = min ( lam , lam1 ) ;
return intersect0 | | intersect1 ;
}
bool isIntersectingTrig ( const array < Point < 3 > , 2 > & seg , const array < Point < 3 > , 3 > & trig , double & lam )
{
if ( ! isIntersectingPlane ( seg , trig , lam ) )
return false ;
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//buffer enlargement of triangle
auto pt0 = trig [ 0 ] ;
auto pt1 = trig [ 1 ] ;
auto pt2 = trig [ 2 ] ;
Point < 3 > center = { ( pt0 [ 0 ] + pt1 [ 0 ] + pt2 [ 0 ] ) / 3.0 , ( pt0 [ 1 ] + pt1 [ 1 ] + pt2 [ 1 ] ) / 3.0 , ( pt0 [ 2 ] + pt1 [ 2 ] + pt2 [ 2 ] ) / 3.0 } ;
array < Point < 3 > , 3 > larger_trig = {
center + ( pt0 - center ) * 1.1 ,
center + ( pt1 - center ) * 1.1 ,
center + ( pt2 - center ) * 1.1 , } ;
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auto p = seg [ 0 ] + lam / 0.9 * ( seg [ 1 ] - seg [ 0 ] ) ;
auto n_trig = Cross ( trig [ 1 ] - trig [ 0 ] , trig [ 2 ] - trig [ 0 ] ) . Normalize ( ) ;
for ( auto i : Range ( 3 ) )
{
// check if p0 and p are on same side of segment p1-p2
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auto p0 = larger_trig [ i ] ;
auto p1 = larger_trig [ ( i + 1 ) % 3 ] ;
auto p2 = larger_trig [ ( i + 2 ) % 3 ] ;
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// auto n = Cross(p2-p1, n_trig);
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auto v0 = ( p2 - p1 ) . Normalize ( ) ;
auto v1 = ( p0 - p1 ) . Normalize ( ) ;
auto inside_dir = ( v1 - ( v1 * v0 ) * v0 ) . Normalize ( ) ;
auto v2 = ( p - p1 ) . Normalize ( ) ;
if ( inside_dir * v1 < 0 )
inside_dir = - inside_dir ;
if ( ( inside_dir * v2 ) < 0 )
return false ;
}
return true ;
} ;
bool isIntersectingFace ( const array < Point < 3 > , 2 > & seg , const ArrayMem < Point < 3 > , 4 > & face , double & lam )
{
lam = 1.0 ;
double lam0 = 1.0 ;
bool intersect0 = isIntersectingTrig ( seg , { face [ 0 ] , face [ 1 ] , face [ 2 ] } , lam0 ) ;
if ( intersect0 )
lam = min ( lam , lam0 ) ;
if ( face . Size ( ) = = 3 )
return intersect0 ;
double lam1 = 1.0 ;
bool intersect1 = isIntersectingTrig ( seg , { face [ 2 ] , face [ 3 ] , face [ 0 ] } , lam1 ) ;
if ( intersect1 )
lam = min ( lam , lam1 ) ;
return intersect0 | | intersect1 ;
}
array < Point < 3 > , 2 > BoundaryLayerTool : : GetMappedSeg ( PointIndex pi )
{
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return { mesh [ pi ] , mesh [ pi ] + height * limits [ pi ] * growthvectors [ pi ] * 1.5 } ;
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}
ArrayMem < Point < 3 > , 4 > BoundaryLayerTool : : GetFace ( SurfaceElementIndex sei )
{
const auto & sel = mesh [ sei ] ;
ArrayMem < Point < 3 > , 4 > points ( sel . GetNP ( ) ) ;
for ( auto i : Range ( sel . GetNP ( ) ) )
points [ i ] = mesh [ sel [ i ] ] ;
return points ;
}
ArrayMem < Point < 3 > , 4 > BoundaryLayerTool : : GetMappedFace ( SurfaceElementIndex sei )
{
const auto & sel = mesh [ sei ] ;
ArrayMem < Point < 3 > , 4 > points ( sel . GetNP ( ) ) ;
for ( auto i : Range ( sel . GetNP ( ) ) )
points [ i ] = mesh [ sel [ i ] ] + height * limits [ sel [ i ] ] * growthvectors [ sel [ i ] ] ;
return points ;
}
ArrayMem < Point < 3 > , 4 > BoundaryLayerTool : : GetMappedFace ( SurfaceElementIndex sei , int face )
{
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if ( face = = - 1 ) return GetFace ( sei ) ;
if ( face = = - 2 ) return GetMappedFace ( sei ) ;
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const auto & sel = mesh [ sei ] ;
auto np = sel . GetNP ( ) ;
auto pi0 = sel [ face % np ] ;
auto pi1 = sel [ ( face + 1 ) % np ] ;
ArrayMem < Point < 3 > , 4 > points ( 4 ) ;
points [ 0 ] = points [ 3 ] = mesh [ pi0 ] ;
points [ 1 ] = points [ 2 ] = mesh [ pi1 ] ;
points [ 3 ] + = height * limits [ pi0 ] * growthvectors [ pi0 ] ;
points [ 2 ] + = height * limits [ pi1 ] * growthvectors [ pi1 ] ;
return points ;
}
Vec < 3 > BoundaryLayerTool : : getEdgeTangent ( PointIndex pi , int edgenr )
{
Vec < 3 > tangent = 0.0 ;
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ArrayMem < PointIndex , 2 > pts ;
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for ( auto segi : topo . GetVertexSegments ( pi ) )
{
auto & seg = mesh [ segi ] ;
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if ( seg . edgenr ! = edgenr + 1 )
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continue ;
PointIndex other = seg [ 0 ] + seg [ 1 ] - pi ;
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if ( ! pts . Contains ( other ) )
pts . Append ( other ) ;
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}
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if ( pts . Size ( ) ! = 2 )
throw Exception ( " Something went wrong in getEdgeTangent! " ) ;
tangent = mesh [ pts [ 1 ] ] - mesh [ pts [ 0 ] ] ;
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return tangent . Normalize ( ) ;
}
void BoundaryLayerTool : : LimitGrowthVectorLengths ( )
{
static Timer tall ( " BoundaryLayerTool::LimitGrowthVectorLengths " ) ; RegionTimer rtall ( tall ) ;
limits . SetSize ( np ) ;
limits = 1.0 ;
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// Function to calculate the dot product of two 3D vectors
// Is there netgen native function for this?
const auto Dot = [ ] ( Vec < 3 > a , Vec < 3 > b ) {
return a [ 0 ] * b [ 0 ] + a [ 1 ] * b [ 1 ] + a [ 2 ] * b [ 2 ] ;
} ;
auto parallel_limiter = [ & ] ( PointIndex pi1 , PointIndex pi2 , SurfaceElementIndex si ) {
MeshPoint & a_base = mesh [ pi1 ] ;
MeshPoint & b_base = mesh [ pi2 ] ;
MeshPoint a_end = mesh [ pi1 ] + height * limits [ pi1 ] * growthvectors [ pi1 ] ;
MeshPoint b_end = mesh [ pi2 ] + height * limits [ pi2 ] * growthvectors [ pi2 ] ;
double ab_base = ( b_base - a_base ) . Length ( ) ;
Vec < 3 > a_vec = ( a_end - a_base ) ;
Vec < 3 > b_vec = ( b_end - b_base ) ;
// Calculate parallel projections
Vec < 3 > ab_base_norm = ( b_base - a_base ) . Normalize ( ) ;
double a_vec_x = Dot ( a_vec , ab_base_norm ) ;
double b_vec_x = Dot ( b_vec , - ab_base_norm ) ;
double ratio_parallel = ( a_vec_x + b_vec_x ) / ab_base ;
double PARALLEL_RATIO_LIMIT = 0.85 ;
if ( ratio_parallel > PARALLEL_RATIO_LIMIT ) {
// Adjust limits, vectors, and projections if parallel ratio exceeds the limit
double corrector = PARALLEL_RATIO_LIMIT / ratio_parallel ;
limits [ pi1 ] * = corrector ;
limits [ pi2 ] * = corrector ;
}
} ;
auto perpendicular_limiter = [ & ] ( PointIndex pi1 , PointIndex pi2 , SurfaceElementIndex si ) {
// this part is same as in parallel limiter, but note that limits contents are already changed
MeshPoint & a_base = mesh [ pi1 ] ;
MeshPoint & b_base = mesh [ pi2 ] ;
MeshPoint a_end = mesh [ pi1 ] + height * limits [ pi1 ] * growthvectors [ pi1 ] ;
MeshPoint b_end = mesh [ pi2 ] + height * limits [ pi2 ] * growthvectors [ pi2 ] ;
double ab_base = ( b_base - a_base ) . Length ( ) ;
Vec < 3 > a_vec = ( a_end - a_base ) ;
Vec < 3 > b_vec = ( b_end - b_base ) ;
// Calculate parallel projections
Vec < 3 > ab_base_norm = ( b_base - a_base ) . Normalize ( ) ;
double a_vec_x = Dot ( a_vec , ab_base_norm ) ;
double b_vec_x = Dot ( b_vec , - ab_base_norm ) ;
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// double ratio_parallel = (a_vec_x + b_vec_x) / ab_base;
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// Calculate surface normal at point si
Vec < 3 > surface_normal = getNormal ( mesh [ si ] ) ;
double a_vec_y = abs ( Dot ( a_vec , surface_normal ) ) ;
double b_vec_y = abs ( Dot ( b_vec , surface_normal ) ) ;
double diff_perpendicular = abs ( a_vec_y - b_vec_y ) ;
double tan_alpha = diff_perpendicular / ( ab_base - a_vec_x - b_vec_x ) ;
double TAN_ALPHA_LIMIT = 0.36397 ; // Approximately 20 degrees in radians
if ( tan_alpha > TAN_ALPHA_LIMIT ) {
if ( a_vec_y > b_vec_y ) {
double correction = ( TAN_ALPHA_LIMIT / tan_alpha * diff_perpendicular + b_vec_y ) / a_vec_y ;
limits [ pi1 ] * = correction ;
}
else {
double correction = ( TAN_ALPHA_LIMIT / tan_alpha * diff_perpendicular + a_vec_y ) / b_vec_y ;
limits [ pi2 ] * = correction ;
}
}
} ;
auto neighbour_limiter = [ & ] ( PointIndex pi1 , PointIndex pi2 , SurfaceElementIndex si ) {
parallel_limiter ( pi1 , pi2 , si ) ;
perpendicular_limiter ( pi1 , pi2 , si ) ;
} ;
auto modifiedsmooth = [ & ] ( size_t nsteps ) {
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for ( [[maybe_unused]] auto i : Range ( nsteps ) )
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for ( SurfaceElementIndex sei : mesh . SurfaceElements ( ) . Range ( ) )
{
// assuming triangle
neighbour_limiter ( mesh [ sei ] . PNum ( 1 ) , mesh [ sei ] . PNum ( 2 ) , sei ) ;
neighbour_limiter ( mesh [ sei ] . PNum ( 2 ) , mesh [ sei ] . PNum ( 3 ) , sei ) ;
neighbour_limiter ( mesh [ sei ] . PNum ( 3 ) , mesh [ sei ] . PNum ( 1 ) , sei ) ;
}
} ;
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/*
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auto smooth = [ & ] ( size_t nsteps ) {
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for ( [[maybe_unused]] auto i : Range ( nsteps ) )
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for ( const auto & sel : mesh . SurfaceElements ( ) )
{
double min_limit = 999 ;
for ( auto pi : sel . PNums ( ) )
min_limit = min ( min_limit , limits [ pi ] ) ;
for ( auto pi : sel . PNums ( ) )
limits [ pi ] = min ( limits [ pi ] , 1.4 * min_limit ) ;
}
} ;
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*/
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// check for self-intersection within new elements (prisms/hexes)
auto self_intersection = [ & ] ( ) {
for ( SurfaceElementIndex sei : mesh . SurfaceElements ( ) . Range ( ) )
{
auto facei = mesh [ sei ] . GetIndex ( ) ;
if ( facei < nfd_old & & ! params . surfid . Contains ( facei ) )
continue ;
auto sel = mesh [ sei ] ;
auto np = sel . GetNP ( ) ;
// check if a new edge intesects the plane of any opposing face
double lam ;
for ( auto i : Range ( np ) )
for ( auto fi : Range ( np - 2 ) )
if ( isIntersectingPlane ( GetMappedSeg ( sel [ i ] ) , GetMappedFace ( sei , i + fi + 1 ) , lam ) )
if ( lam < 1.0 )
limits [ sel [ i ] ] * = lam ;
}
} ;
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// first step: intersect with other surface elements that are boundary of domain the layer is grown into
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// second (and subsequent) steps: intersect with other boundary layers, allow restriction by 20% in each step
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auto changed_domains = domains ;
if ( ! params . outside )
changed_domains . Invert ( ) ;
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bool limit_reached = true ;
double lam_lower_limit = 1.0 ;
int step = 0 ;
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while ( limit_reached | | step < 3 )
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{
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Array < double , PointIndex > new_limits ;
new_limits . SetSize ( np ) ;
new_limits = 1.0 ;
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if ( step > 1 )
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lam_lower_limit * = 0.8 ;
limit_reached = false ;
// build search tree with all surface elements (bounding box of a surface element also covers the generated boundary layer)
Box < 3 > bbox ( Box < 3 > : : EMPTY_BOX ) ;
for ( auto pi : mesh . Points ( ) . Range ( ) )
{
bbox . Add ( mesh [ pi ] ) ;
bbox . Add ( mesh [ pi ] + limits [ pi ] * height * growthvectors [ pi ] ) ;
}
BoxTree < 3 > tree ( bbox ) ;
for ( auto sei : mesh . SurfaceElements ( ) . Range ( ) )
{
const auto & sel = mesh [ sei ] ;
Box < 3 > box ( Box < 3 > : : EMPTY_BOX ) ;
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const auto & fd = mesh . GetFaceDescriptor ( sel . GetIndex ( ) ) ;
if ( ! changed_domains . Test ( fd . DomainIn ( ) ) & &
! changed_domains . Test ( fd . DomainOut ( ) ) )
continue ;
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for ( auto pi : sel . PNums ( ) )
box . Add ( mesh [ pi ] ) ;
// also add moved points to bounding box
if ( params . surfid . Contains ( sel . GetIndex ( ) ) )
for ( auto pi : sel . PNums ( ) )
box . Add ( mesh [ pi ] + limits [ pi ] * height * growthvectors [ pi ] ) ;
tree . Insert ( box , sei ) ;
}
for ( auto pi : mesh . Points ( ) . Range ( ) )
{
if ( mesh [ pi ] . Type ( ) = = INNERPOINT )
continue ;
if ( growthvectors [ pi ] . Length2 ( ) = = 0.0 )
continue ;
Box < 3 > box ( Box < 3 > : : EMPTY_BOX ) ;
auto seg = GetMappedSeg ( pi ) ;
box . Add ( seg [ 0 ] ) ;
box . Add ( seg [ 1 ] ) ;
double lam = 1.0 ;
tree . GetFirstIntersecting ( box . PMin ( ) , box . PMax ( ) , [ & ] ( SurfaceElementIndex sei )
{
const auto & sel = mesh [ sei ] ;
if ( sel . PNums ( ) . Contains ( pi ) )
return false ;
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auto face = GetMappedFace ( sei , - 2 ) ;
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double lam_ = 999 ;
bool is_bl_sel = params . surfid . Contains ( sel . GetIndex ( ) ) ;
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if ( step = = 0 )
{
face = GetMappedFace ( sei , - 1 ) ;
if ( isIntersectingFace ( seg , face , lam_ ) )
{
if ( is_bl_sel )
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lam_ * = params . limit_safety ;
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lam = min ( lam , lam_ ) ;
}
}
if ( step = = 1 )
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{
if ( isIntersectingFace ( seg , face , lam_ ) )
{
if ( is_bl_sel ) // allow only half the distance if the opposing surface element has a boundary layer too
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lam_ * = params . limit_safety ;
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lam = min ( lam , lam_ ) ;
}
}
// if the opposing surface element has a boundary layer, we need to additionally intersect with the new faces
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if ( step > 1 & & is_bl_sel )
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{
for ( auto facei : Range ( - 1 , sel . GetNP ( ) ) )
{
auto face = GetMappedFace ( sei , facei ) ;
if ( isIntersectingFace ( seg , face , lam_ ) ) // && lam_ > other_limit)
{
lam = min ( lam , lam_ ) ;
}
}
}
return false ;
} ) ;
if ( lam < 1 )
{
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if ( lam < lam_lower_limit & & step > 1 )
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{
limit_reached = true ;
lam = lam_lower_limit ;
}
}
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new_limits [ pi ] = min ( limits [ pi ] , lam * limits [ pi ] ) ;
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}
step + + ;
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limits = new_limits ;
if ( step > 0 )
modifiedsmooth ( 1 ) ;
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}
self_intersection ( ) ;
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modifiedsmooth ( 1 ) ;
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for ( auto pi : Range ( growthvectors ) )
growthvectors [ pi ] * = limits [ pi ] ;
}
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// depending on the geometry type, the mesh contains segments multiple times (once for each face)
bool HaveSingleSegments ( const Mesh & mesh )
{
auto & topo = mesh . GetTopology ( ) ;
NgArray < SurfaceElementIndex > surf_els ;
for ( auto segi : Range ( mesh . LineSegments ( ) ) )
{
mesh . GetTopology ( ) . GetSegmentSurfaceElements ( segi + 1 , surf_els ) ;
if ( surf_els . Size ( ) < 2 )
continue ;
auto seg = mesh [ segi ] ;
auto pi0 = min ( seg [ 0 ] , seg [ 1 ] ) ;
auto pi1 = max ( seg [ 0 ] , seg [ 1 ] ) ;
auto p0_segs = topo . GetVertexSegments ( seg [ 0 ] ) ;
for ( auto segi_other : p0_segs )
{
if ( segi_other = = segi )
continue ;
auto seg_other = mesh [ segi_other ] ;
auto pi0_other = min ( seg_other [ 0 ] , seg_other [ 1 ] ) ;
auto pi1_other = max ( seg_other [ 0 ] , seg_other [ 1 ] ) ;
if ( pi0_other = = pi0 & & pi1_other = = pi1 )
return false ;
}
// found segment with multiple adjacent surface elements but no other segments with same points -> have single segments
return true ;
}
return true ;
}
// duplicates segments (and sets seg.si accordingly) to have a unified data structure for all geometry types
Array < Segment > BuildSegments ( Mesh & mesh )
{
Array < Segment > segments ;
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// auto& topo = mesh.GetTopology();
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NgArray < SurfaceElementIndex > surf_els ;
for ( auto segi : Range ( mesh . LineSegments ( ) ) )
{
auto seg = mesh [ segi ] ;
mesh . GetTopology ( ) . GetSegmentSurfaceElements ( segi + 1 , surf_els ) ;
for ( auto seli : surf_els )
{
const auto & sel = mesh [ seli ] ;
seg . si = sel . GetIndex ( ) ;
auto np = sel . GetNP ( ) ;
for ( auto i : Range ( np ) )
{
if ( sel [ i ] = = seg [ 0 ] )
{
if ( sel [ ( i + 1 ) % np ] ! = seg [ 1 ] )
swap ( seg [ 0 ] , seg [ 1 ] ) ;
break ;
}
}
segments . Append ( seg ) ;
}
}
return segments ;
}
void MergeAndAddSegments ( Mesh & mesh , FlatArray < Segment > new_segments )
{
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INDEX_2_HASHTABLE < bool > already_added ( mesh . LineSegments ( ) . Size ( ) + 2 * new_segments . Size ( ) ) ;
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for ( auto & seg : mesh . LineSegments ( ) )
{
INDEX_2 i2 ( seg [ 0 ] , seg [ 1 ] ) ;
i2 . Sort ( ) ;
if ( ! already_added . Used ( i2 ) )
already_added . Set ( i2 , true ) ;
}
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for ( auto & seg : new_segments )
{
INDEX_2 i2 ( seg [ 0 ] , seg [ 1 ] ) ;
i2 . Sort ( ) ;
if ( ! already_added . Used ( i2 ) )
{
mesh . AddSegment ( seg ) ;
already_added . Set ( i2 , true ) ;
}
}
}
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void BoundaryLayerTool : : InterpolateSurfaceGrowthVectors ( )
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{
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static Timer tall ( " InterpolateSurfaceGrowthVectors " ) ; RegionTimer rtall ( tall ) ;
static Timer tsmooth ( " InterpolateSurfaceGrowthVectors-Smoothing " ) ;
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auto np = mesh . GetNP ( ) ;
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BitArray is_point_on_bl_surface ( np + 1 ) ;
is_point_on_bl_surface . Clear ( ) ;
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BitArray is_point_on_other_surface ( np + 1 ) ;
is_point_on_other_surface . Clear ( ) ;
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Array < Vec < 3 > , PointIndex > normals ( np ) ;
for ( auto pi : Range ( growthvectors ) )
normals [ pi ] = growthvectors [ pi ] ;
ParallelForRange ( mesh . SurfaceElements ( ) . Range ( ) , [ & ] ( auto myrange )
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{
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for ( SurfaceElementIndex sei : myrange )
{
auto facei = mesh [ sei ] . GetIndex ( ) ;
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if ( facei < nfd_old & & ! params . surfid . Contains ( facei ) )
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{
for ( auto pi : mesh [ sei ] . PNums ( ) )
if ( mesh [ pi ] . Type ( ) = = SURFACEPOINT )
is_point_on_other_surface . SetBitAtomic ( pi ) ;
}
else
{
for ( auto pi : mesh [ sei ] . PNums ( ) )
if ( mesh [ pi ] . Type ( ) = = SURFACEPOINT )
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is_point_on_bl_surface . SetBitAtomic ( pi ) ;
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}
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}
} ) ;
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Array < PointIndex > points ;
for ( PointIndex pi : mesh . Points ( ) . Range ( ) )
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{
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if ( is_point_on_bl_surface [ pi ] )
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{
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points . Append ( pi ) ;
growthvectors [ pi ] = 0.0 ;
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}
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if ( is_point_on_other_surface [ pi ] )
{
points . Append ( pi ) ;
}
}
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// smooth tangential part of growth vectors from edges to surface elements
RegionTimer rtsmooth ( tsmooth ) ;
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for ( [[maybe_unused]] auto i : Range ( 10 ) )
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{
for ( auto pi : points )
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{
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auto sels = p2sel [ pi ] ;
Vec < 3 > new_gw = growthvectors [ pi ] ;
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// int cnt = 1;
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std : : set < PointIndex > suround ;
suround . insert ( pi ) ;
auto normal = normals [ pi ] ;
for ( auto sei : sels )
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{
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const auto & sel = mesh [ sei ] ;
for ( auto pi1 : sel . PNums ( ) )
if ( suround . count ( pi1 ) = = 0 )
{
suround . insert ( pi1 ) ;
auto gw_other = growthvectors [ pi1 ] ;
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auto normal_other = getNormal ( mesh [ sei ] ) ;
auto tangent_part = gw_other - ( gw_other * normal_other ) * normal_other ;
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if ( is_point_on_bl_surface [ pi ] )
new_gw + = tangent_part ;
else
new_gw + = gw_other ;
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}
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}
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growthvectors [ pi ] = 1.0 / suround . size ( ) * new_gw ;
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}
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}
for ( auto pi : points )
growthvectors [ pi ] + = normals [ pi ] ;
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}
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BoundaryLayerTool : : BoundaryLayerTool ( Mesh & mesh_ , const BoundaryLayerParameters & params_ )
: mesh ( mesh_ ) , topo ( mesh_ . GetTopology ( ) ) , params ( params_ )
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{
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static Timer timer ( " BoundaryLayerTool::ctor " ) ;
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RegionTimer regt ( timer ) ;
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//for(auto & seg : mesh.LineSegments())
//seg.edgenr = seg.epgeominfo[1].edgenr;
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height = 0.0 ;
for ( auto h : params . heights )
height + = h ;
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max_edge_nr = - 1 ;
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for ( const auto & seg : mesh . LineSegments ( ) )
if ( seg . edgenr > max_edge_nr )
max_edge_nr = seg . edgenr ;
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int ndom = mesh . GetNDomains ( ) ;
ndom_old = ndom ;
new_mat_nrs . SetSize ( mesh . FaceDescriptors ( ) . Size ( ) + 1 ) ;
new_mat_nrs = - 1 ;
for ( auto [ bcname , matname ] : params . new_mat )
{
mesh . SetMaterial ( + + ndom , matname ) ;
regex pattern ( bcname ) ;
for ( auto i : Range ( 1 , mesh . GetNFD ( ) + 1 ) )
{
auto & fd = mesh . GetFaceDescriptor ( i ) ;
if ( regex_match ( fd . GetBCName ( ) , pattern ) )
new_mat_nrs [ i ] = ndom ;
}
}
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domains = params . domains ;
if ( ! params . outside )
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domains . Invert ( ) ;
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topo . SetBuildVertex2Element ( true ) ;
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mesh . UpdateTopology ( ) ;
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have_single_segments = HaveSingleSegments ( mesh ) ;
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if ( have_single_segments )
segments = BuildSegments ( mesh ) ;
else
segments = mesh . LineSegments ( ) ;
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np = mesh . GetNP ( ) ;
ne = mesh . GetNE ( ) ;
nse = mesh . GetNSE ( ) ;
nseg = segments . Size ( ) ;
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p2sel = mesh . CreatePoint2SurfaceElementTable ( ) ;
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nfd_old = mesh . GetNFD ( ) ;
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moved_surfaces . SetSize ( nfd_old + 1 ) ;
moved_surfaces . Clear ( ) ;
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si_map . SetSize ( nfd_old + 1 ) ;
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for ( auto i : Range ( nfd_old + 1 ) )
si_map [ i ] = i ;
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}
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void BoundaryLayerTool : : CreateNewFaceDescriptors ( )
{
surfacefacs . SetSize ( nfd_old + 1 ) ;
surfacefacs = 0.0 ;
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// create new FaceDescriptors
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for ( auto i : Range ( 1 , nfd_old + 1 ) )
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{
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const auto & fd = mesh . GetFaceDescriptor ( i ) ;
string name = fd . GetBCName ( ) ;
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if ( params . surfid . Contains ( i ) )
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{
if ( auto isIn = domains . Test ( fd . DomainIn ( ) ) ; isIn ! = domains . Test ( fd . DomainOut ( ) ) )
{
int new_si = mesh . GetNFD ( ) + 1 ;
surfacefacs [ i ] = isIn ? 1. : - 1. ;
// -1 surf nr is so that curving does not do anything
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FaceDescriptor new_fd ( - 1 , isIn ? new_mat_nrs [ i ] : fd . DomainIn ( ) ,
isIn ? fd . DomainOut ( ) : new_mat_nrs [ i ] , - 1 ) ;
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new_fd . SetBCProperty ( new_si ) ;
mesh . AddFaceDescriptor ( new_fd ) ;
si_map [ i ] = new_si ;
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moved_surfaces . SetBit ( i ) ;
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mesh . SetBCName ( new_si - 1 , " mapped_ " + name ) ;
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}
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// curving of surfaces with boundary layers will often
// result in pushed through elements, since we do not (yet)
// curvature through layers.
// Therefore we disable curving for these surfaces.
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if ( ! params . keep_surfaceindex )
mesh . GetFaceDescriptor ( i ) . SetSurfNr ( - 1 ) ;
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}
}
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for ( auto si : params . surfid )
if ( surfacefacs [ si ] = = 0.0 )
throw Exception ( " Surface " + to_string ( si ) + " is not a boundary of the domain to be grown into! " ) ;
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}
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void BoundaryLayerTool : : CreateFaceDescriptorsSides ( )
{
BitArray face_done ( mesh . GetNFD ( ) + 1 ) ;
face_done . Clear ( ) ;
for ( const auto & sel : mesh . SurfaceElements ( ) )
{
auto facei = sel . GetIndex ( ) ;
if ( face_done . Test ( facei ) )
continue ;
bool point_moved = false ;
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// bool point_fixed = false;
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for ( auto pi : sel . PNums ( ) )
{
if ( growthvectors [ pi ] . Length ( ) > 0 )
point_moved = true ;
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/*
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else
point_fixed = true ;
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*/
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}
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if ( point_moved & & ! moved_surfaces . Test ( facei ) )
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{
int new_si = mesh . GetNFD ( ) + 1 ;
const auto & fd = mesh . GetFaceDescriptor ( facei ) ;
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// auto isIn = domains.Test(fd.DomainIn());
// auto isOut = domains.Test(fd.DomainOut());
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int si = params . sides_keep_surfaceindex ? facei : - 1 ;
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// domin and domout can only be set later
FaceDescriptor new_fd ( si , - 1 ,
- 1 , si ) ;
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new_fd . SetBCProperty ( new_si ) ;
mesh . AddFaceDescriptor ( new_fd ) ;
si_map [ facei ] = new_si ;
mesh . SetBCName ( new_si - 1 , fd . GetBCName ( ) ) ;
face_done . SetBit ( facei ) ;
}
}
}
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void BoundaryLayerTool : : CalculateGrowthVectors ( )
{
growthvectors . SetSize ( np ) ;
growthvectors = 0. ;
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for ( auto pi : mesh . Points ( ) . Range ( ) )
{
const auto & p = mesh [ pi ] ;
if ( p . Type ( ) = = INNERPOINT )
continue ;
std : : map < int , Vec < 3 > > normals ;
// calculate one normal vector per face (average with angles as weights for multiple surface elements within a face)
for ( auto sei : p2sel [ pi ] )
{
const auto & sel = mesh [ sei ] ;
auto facei = sel . GetIndex ( ) ;
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if ( ! params . surfid . Contains ( facei ) )
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continue ;
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auto n = surfacefacs [ sel . GetIndex ( ) ] * getNormal ( sel ) ;
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int itrig = sel . PNums ( ) . Pos ( pi ) ;
itrig + = sel . GetNP ( ) ;
auto v0 = ( mesh [ sel . PNumMod ( itrig + 1 ) ] - mesh [ pi ] ) . Normalize ( ) ;
auto v1 = ( mesh [ sel . PNumMod ( itrig - 1 ) ] - mesh [ pi ] ) . Normalize ( ) ;
if ( normals . count ( facei ) = = 0 )
normals [ facei ] = { 0. , 0. , 0. } ;
normals [ facei ] + = acos ( v0 * v1 ) * n ;
}
for ( auto & [ facei , n ] : normals )
n * = 1.0 / n . Length ( ) ;
// combine normal vectors for each face to keep uniform distances
auto & np = growthvectors [ pi ] ;
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ArrayMem < Vec < 3 > , 3 > ns ;
for ( auto & [ facei , n ] : normals ) {
ns . Append ( n ) ;
}
ArrayMem < Vec < 3 > , 3 > removed ;
// reduce to full rank of max 3
while ( true )
{
if ( ns . Size ( ) < = 1 )
break ;
if ( ns . Size ( ) = = 2 & & ns [ 0 ] * ns [ 1 ] < 1 - 1e-6 )
break ;
if ( ns . Size ( ) = = 3 )
{
DenseMatrix mat ( 3 , 3 ) ;
for ( auto i : Range ( 3 ) )
for ( auto j : Range ( 3 ) )
mat ( i , j ) = ns [ i ] [ j ] ;
if ( fabs ( mat . Det ( ) ) > 1e-6 )
break ;
}
int maxpos1 ;
int maxpos2 ;
double val = 0 ;
for ( auto i : Range ( ns ) )
{
for ( auto j : Range ( i + 1 , ns . Size ( ) ) )
{
double ip = ns [ i ] * ns [ j ] ;
if ( ip > val )
{
val = ip ;
maxpos1 = i ;
maxpos2 = j ;
}
}
}
removed . Append ( ns [ maxpos1 ] ) ;
removed . Append ( ns [ maxpos2 ] ) ;
ns [ maxpos1 ] = 0.5 * ( ns [ maxpos1 ] + ns [ maxpos2 ] ) ;
ns . DeleteElement ( maxpos2 ) ;
}
if ( ns . Size ( ) = = 0 )
continue ;
if ( ns . Size ( ) = = 1 )
np = ns [ 0 ] ;
else if ( ns . Size ( ) = = 2 )
{
np = ns [ 0 ] ;
auto n = ns [ 1 ] ;
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auto npn = np * n ;
auto npnp = np * np ;
auto nn = n * n ;
if ( nn - npn * npn / npnp = = 0 ) { np = n ; continue ; }
np + = ( nn - npn ) / ( nn - npn * npn / npnp ) * ( n - npn / npnp * np ) ;
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}
else // ns.Size() == 3
{
DenseMatrix mat ( 3 , 3 ) ;
for ( auto i : Range ( 3 ) )
for ( auto j : Range ( 3 ) )
mat ( i , j ) = ns [ i ] * ns [ j ] ;
Vector rhs ( 3 ) ;
rhs = 1. ;
Vector res ( 3 ) ;
DenseMatrix inv ( 3 , ns . Size ( ) ) ;
CalcInverse ( mat , inv ) ;
inv . Mult ( rhs , res ) ;
for ( auto i : Range ( ns ) )
np + = res [ i ] * ns [ i ] ;
}
for ( auto & n : removed )
if ( n * np < 0 )
cout < < " WARNING: Growth vector at point " < < pi < < " in opposite direction to face normal! " < < endl < < " Growthvector = " < < np < < " , face normal = " < < n < < endl ;
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}
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}
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Array < Array < pair < SegmentIndex , int > > , SegmentIndex > BoundaryLayerTool : : BuildSegMap ( )
{
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// Bit array to keep track of segments already processed
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BitArray segs_done ( nseg + 1 ) ;
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segs_done . Clear ( ) ;
// map for all segments with same points
// points to pair of SegmentIndex, int
// int is type of other segment, either:
// 0 == adjacent surface grows layer
// 1 == adjacent surface doesn't grow layer, but layer ends on it
// 2 == adjacent surface is interior surface that ends on layer
// 3 == adjacent surface is exterior surface that ends on layer (not allowed yet)
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Array < Array < pair < SegmentIndex , int > > , SegmentIndex > segmap ( segments . Size ( ) ) ;
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// moved segments
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is_edge_moved . SetSize ( max_edge_nr + 1 ) ;
is_edge_moved = false ;
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// boundaries to project endings to
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is_boundary_projected . SetSize ( nfd_old + 1 ) ;
is_boundary_projected . Clear ( ) ;
is_boundary_moved . SetSize ( nfd_old + 1 ) ;
is_boundary_moved . Clear ( ) ;
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for ( auto si : Range ( segments ) )
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{
if ( segs_done [ si ] ) continue ;
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const auto & segi = segments [ si ] ;
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if ( ! moved_surfaces . Test ( segi . si ) ) continue ;
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segs_done . SetBit ( si ) ;
segmap [ si ] . Append ( make_pair ( si , 0 ) ) ;
moved_segs . Append ( si ) ;
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is_edge_moved . SetBit ( segi . edgenr ) ;
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for ( auto sj : Range ( segments ) )
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{
if ( segs_done . Test ( sj ) ) continue ;
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const auto & segj = segments [ sj ] ;
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if ( ( segi [ 0 ] = = segj [ 0 ] & & segi [ 1 ] = = segj [ 1 ] ) | |
( segi [ 0 ] = = segj [ 1 ] & & segi [ 1 ] = = segj [ 0 ] ) )
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{
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segs_done . SetBit ( sj ) ;
int type ;
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if ( moved_surfaces . Test ( segj . si ) )
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type = 0 ;
else if ( const auto & fd = mesh . GetFaceDescriptor ( segj . si ) ; domains . Test ( fd . DomainIn ( ) ) & & domains . Test ( fd . DomainOut ( ) ) )
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{
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type = 2 ;
if ( fd . DomainIn ( ) = = 0 | | fd . DomainOut ( ) = = 0 )
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is_boundary_projected . SetBit ( segj . si ) ;
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}
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else if ( const auto & fd = mesh . GetFaceDescriptor ( segj . si ) ; ! domains . Test ( fd . DomainIn ( ) ) & & ! domains . Test ( fd . DomainOut ( ) ) )
{
type = 3 ;
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is_boundary_moved . SetBit ( segj . si ) ;
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}
else
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{
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type = 1 ;
// in case 1 we project the growthvector onto the surface
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is_boundary_projected . SetBit ( segj . si ) ;
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}
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segmap [ si ] . Append ( make_pair ( sj , type ) ) ;
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}
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}
}
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return segmap ;
}
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BitArray BoundaryLayerTool : : ProjectGrowthVectorsOnSurface ( )
{
BitArray in_surface_direction ( nfd_old + 1 ) ;
in_surface_direction . Clear ( ) ;
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// project growthvector on surface for inner angles
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if ( params . grow_edges )
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{
for ( const auto & sel : mesh . SurfaceElements ( ) )
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if ( is_boundary_projected . Test ( sel . GetIndex ( ) ) )
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{
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auto n = getNormal ( sel ) ;
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for ( auto i : Range ( sel . PNums ( ) ) )
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{
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auto pi = sel . PNums ( ) [ i ] ;
if ( growthvectors [ pi ] . Length2 ( ) = = 0. )
continue ;
auto next = sel . PNums ( ) [ ( i + 1 ) % sel . GetNV ( ) ] ;
auto prev = sel . PNums ( ) [ i = = 0 ? sel . GetNV ( ) - 1 : i - 1 ] ;
auto v1 = ( mesh [ next ] - mesh [ pi ] ) . Normalize ( ) ;
auto v2 = ( mesh [ prev ] - mesh [ pi ] ) . Normalize ( ) ;
auto v3 = growthvectors [ pi ] ;
v3 . Normalize ( ) ;
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auto tol = v1 . Length ( ) * 1e-12 ;
if ( ( v1 * v3 > - tol ) & & ( v2 * v3 > - tol ) )
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in_surface_direction . SetBit ( sel . GetIndex ( ) ) ;
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else
continue ;
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if ( ! params . project_boundaries . Contains ( sel . GetIndex ( ) ) )
continue ;
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auto & g = growthvectors [ pi ] ;
auto ng = n * g ;
auto gg = g * g ;
auto nn = n * n ;
// if(fabs(ng*ng-nn*gg) < 1e-12 || fabs(ng) < 1e-12) continue;
auto a = - ng * ng / ( ng * ng - nn * gg ) ;
auto b = ng * gg / ( ng * ng - nn * gg ) ;
g + = a * g + b * n ;
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}
}
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}
else
{
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for ( const auto & seg : segments )
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{
int count = 0 ;
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for ( const auto & seg2 : segments )
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if ( ( ( seg [ 0 ] = = seg2 [ 0 ] & & seg [ 1 ] = = seg2 [ 1 ] ) | | ( seg [ 0 ] = = seg2 [ 1 ] & & seg [ 1 ] = = seg2 [ 0 ] ) ) & & params . surfid . Contains ( seg2 . si ) )
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count + + ;
if ( count = = 1 )
{
growthvectors [ seg [ 0 ] ] = { 0. , 0. , 0. } ;
growthvectors [ seg [ 1 ] ] = { 0. , 0. , 0. } ;
}
}
}
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return in_surface_direction ;
}
void BoundaryLayerTool : : InterpolateGrowthVectors ( )
{
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// interpolate tangential component of growth vector along edge
for ( auto edgenr : Range ( max_edge_nr ) )
{
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// if(!is_edge_moved[edgenr+1]) continue;
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// build sorted list of edge
Array < PointIndex > points ;
// find first vertex on edge
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double edge_len = 0. ;
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auto is_end_point = [ & ] ( PointIndex pi )
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{
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// if(mesh[pi].Type() == FIXEDPOINT)
// return true;
// return false;
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auto segs = topo . GetVertexSegments ( pi ) ;
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if ( segs . Size ( ) = = 1 )
return true ;
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auto first_edgenr = mesh [ segs [ 0 ] ] . edgenr ;
for ( auto segi : segs )
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if ( mesh [ segi ] . edgenr ! = first_edgenr )
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return true ;
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return false ;
} ;
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bool any_grows = false ;
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for ( const auto & seg : segments )
{
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if ( seg . edgenr - 1 = = edgenr )
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{
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if ( growthvectors [ seg [ 0 ] ] . Length2 ( ) ! = 0 | |
growthvectors [ seg [ 1 ] ] . Length2 ( ) ! = 0 )
any_grows = true ;
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if ( points . Size ( ) = = 0 & & is_end_point ( seg [ 0 ] ) )
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{
points . Append ( seg [ 0 ] ) ;
points . Append ( seg [ 1 ] ) ;
edge_len + = ( mesh [ seg [ 1 ] ] - mesh [ seg [ 0 ] ] ) . Length ( ) ;
}
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}
}
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if ( ! any_grows )
continue ;
if ( ! points . Size ( ) )
throw Exception ( " Could not find startpoint for edge " + ToString ( edgenr ) ) ;
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while ( true )
{
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bool point_found = false ;
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for ( auto si : topo . GetVertexSegments ( points . Last ( ) ) )
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{
const auto & seg = mesh [ si ] ;
if ( seg . edgenr - 1 ! = edgenr )
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continue ;
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if ( seg [ 0 ] = = points . Last ( ) & & points [ points . Size ( ) - 2 ] ! = seg [ 1 ] )
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{
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edge_len + = ( mesh [ points . Last ( ) ] - mesh [ seg [ 1 ] ] ) . Length ( ) ;
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points . Append ( seg [ 1 ] ) ;
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point_found = true ;
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break ;
}
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else if ( seg [ 1 ] = = points . Last ( ) & &
points [ points . Size ( ) - 2 ] ! = seg [ 0 ] )
{
edge_len + = ( mesh [ points . Last ( ) ] - mesh [ seg [ 0 ] ] ) . Length ( ) ;
points . Append ( seg [ 0 ] ) ;
point_found = true ;
break ;
}
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}
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if ( is_end_point ( points . Last ( ) ) )
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break ;
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if ( ! point_found )
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{
throw Exception ( string ( " Could not find connected list of line segments for edge " ) + edgenr ) ;
}
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}
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if ( growthvectors [ points [ 0 ] ] . Length2 ( ) = = 0 & &
growthvectors [ points . Last ( ) ] . Length2 ( ) = = 0 )
continue ;
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// tangential part of growth vectors
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auto t1 = ( mesh [ points [ 1 ] ] - mesh [ points [ 0 ] ] ) . Normalize ( ) ;
auto gt1 = growthvectors [ points [ 0 ] ] * t1 * t1 ;
auto t2 = ( mesh [ points . Last ( ) ] - mesh [ points [ points . Size ( ) - 2 ] ] ) . Normalize ( ) ;
auto gt2 = growthvectors [ points . Last ( ) ] * t2 * t2 ;
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if ( ! is_edge_moved [ edgenr + 1 ] )
{
if ( growthvectors [ points [ 0 ] ] * ( mesh [ points [ 1 ] ] - mesh [ points [ 0 ] ] ) < 0 )
gt1 = 0. ;
if ( growthvectors [ points . Last ( ) ] * ( mesh [ points [ points . Size ( ) - 2 ] ] - mesh [ points . Last ( ) ] ) < 0 )
gt2 = 0. ;
}
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double len = 0. ;
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for ( size_t i = 1 ; i < points . Size ( ) - 1 ; i + + )
{
auto pi = points [ i ] ;
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len + = ( mesh [ pi ] - mesh [ points [ i - 1 ] ] ) . Length ( ) ;
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auto t = getEdgeTangent ( pi , edgenr ) ;
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auto lam = len / edge_len ;
auto interpol = ( 1 - lam ) * ( gt1 * t ) * t + lam * ( gt2 * t ) * t ;
growthvectors [ pi ] + = interpol ;
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}
}
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InterpolateSurfaceGrowthVectors ( ) ;
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}
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void BoundaryLayerTool : : InsertNewElements ( FlatArray < Array < pair < SegmentIndex , int > > , SegmentIndex > segmap , const BitArray & in_surface_direction )
{
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static Timer timer ( " BoundaryLayerTool::InsertNewElements " ) ; RegionTimer rt ( timer ) ;
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Array < Array < PointIndex > , PointIndex > mapto ( np ) ;
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// insert new points
for ( PointIndex pi = 1 ; pi < = np ; pi + + )
if ( growthvectors [ pi ] . Length2 ( ) ! = 0 )
{
Point < 3 > p = mesh [ pi ] ;
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for ( auto i : Range ( params . heights ) )
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{
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p + = params . heights [ i ] * growthvectors [ pi ] ;
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mapto [ pi ] . Append ( mesh . AddPoint ( p ) ) ;
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}
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}
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// add 2d quads on required surfaces
map < pair < PointIndex , PointIndex > , int > seg2edge ;
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if ( params . grow_edges )
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{
for ( auto sei : moved_segs )
{
// copy here since we will add segments and this would
// invalidate a reference!
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// auto segi = segments[sei];
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for ( auto [ sej , type ] : segmap [ sei ] )
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{
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auto segj = segments [ sej ] ;
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if ( type = = 0 )
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{
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Segment s ;
s [ 0 ] = mapto [ segj [ 0 ] ] . Last ( ) ;
s [ 1 ] = mapto [ segj [ 1 ] ] . Last ( ) ;
s [ 2 ] = PointIndex : : INVALID ;
auto pair = s [ 0 ] < s [ 1 ] ? make_pair ( s [ 0 ] , s [ 1 ] ) : make_pair ( s [ 1 ] , s [ 0 ] ) ;
if ( seg2edge . find ( pair ) = = seg2edge . end ( ) )
seg2edge [ pair ] = + + max_edge_nr ;
s . edgenr = seg2edge [ pair ] ;
s . si = si_map [ segj . si ] ;
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new_segments . Append ( s ) ;
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}
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// here we need to grow the quad elements
else if ( type = = 1 )
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{
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PointIndex pp1 = segj [ 1 ] ;
PointIndex pp2 = segj [ 0 ] ;
if ( in_surface_direction . Test ( segj . si ) )
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{
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Swap ( pp1 , pp2 ) ;
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is_boundary_moved . SetBit ( segj . si ) ;
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}
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PointIndex p1 = pp1 ;
PointIndex p2 = pp2 ;
PointIndex p3 , p4 ;
Segment s0 ;
s0 [ 0 ] = p1 ;
s0 [ 1 ] = p2 ;
s0 [ 2 ] = PointIndex : : INVALID ;
s0 . edgenr = segj . edgenr ;
s0 . si = segj . si ;
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new_segments . Append ( s0 ) ;
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for ( auto i : Range ( params . heights ) )
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{
Element2d sel ( QUAD ) ;
p3 = mapto [ pp2 ] [ i ] ;
p4 = mapto [ pp1 ] [ i ] ;
sel [ 0 ] = p1 ;
sel [ 1 ] = p2 ;
sel [ 2 ] = p3 ;
sel [ 3 ] = p4 ;
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for ( auto i : Range ( 4 ) )
{
sel . GeomInfo ( ) [ i ] . u = 0.0 ;
sel . GeomInfo ( ) [ i ] . v = 0.0 ;
}
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sel . SetIndex ( si_map [ segj . si ] ) ;
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mesh . AddSurfaceElement ( sel ) ;
// TODO: Too many, would be enough to only add outermost ones
Segment s1 ;
s1 [ 0 ] = p2 ;
s1 [ 1 ] = p3 ;
s1 [ 2 ] = PointIndex : : INVALID ;
auto pair = make_pair ( p2 , p3 ) ;
if ( seg2edge . find ( pair ) = = seg2edge . end ( ) )
seg2edge [ pair ] = + + max_edge_nr ;
s1 . edgenr = seg2edge [ pair ] ;
s1 . si = segj . si ;
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new_segments . Append ( s1 ) ;
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Segment s2 ;
s2 [ 0 ] = p4 ;
s2 [ 1 ] = p1 ;
s2 [ 2 ] = PointIndex : : INVALID ;
pair = make_pair ( p1 , p4 ) ;
if ( seg2edge . find ( pair ) = = seg2edge . end ( ) )
seg2edge [ pair ] = + + max_edge_nr ;
s2 . edgenr = seg2edge [ pair ] ;
s2 . si = segj . si ;
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new_segments . Append ( s2 ) ;
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p1 = p4 ;
p2 = p3 ;
}
Segment s3 ;
s3 [ 0 ] = p3 ;
s3 [ 1 ] = p4 ;
s3 [ 2 ] = PointIndex : : INVALID ;
auto pair = p3 < p4 ? make_pair ( p3 , p4 ) : make_pair ( p4 , p3 ) ;
if ( seg2edge . find ( pair ) = = seg2edge . end ( ) )
seg2edge [ pair ] = + + max_edge_nr ;
s3 . edgenr = seg2edge [ pair ] ;
s3 . si = segj . si ;
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new_segments . Append ( s3 ) ;
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}
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}
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}
}
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BitArray fixed_points ( np + 1 ) ;
fixed_points . Clear ( ) ;
BitArray moveboundarypoint ( np + 1 ) ;
moveboundarypoint . Clear ( ) ;
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for ( SurfaceElementIndex si = 0 ; si < nse ; si + + )
{
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// copy because surfaceels array will be resized!
auto sel = mesh [ si ] ;
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if ( moved_surfaces . Test ( sel . GetIndex ( ) ) )
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{
Array < PointIndex > points ( sel . PNums ( ) ) ;
if ( surfacefacs [ sel . GetIndex ( ) ] > 0 ) Swap ( points [ 0 ] , points [ 2 ] ) ;
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for ( auto j : Range ( params . heights ) )
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{
auto eltype = points . Size ( ) = = 3 ? PRISM : HEX ;
Element el ( eltype ) ;
for ( auto i : Range ( points ) )
el [ i ] = points [ i ] ;
for ( auto i : Range ( points ) )
points [ i ] = mapto [ sel . PNums ( ) [ i ] ] [ j ] ;
if ( surfacefacs [ sel . GetIndex ( ) ] > 0 ) Swap ( points [ 0 ] , points [ 2 ] ) ;
for ( auto i : Range ( points ) )
el [ sel . PNums ( ) . Size ( ) + i ] = points [ i ] ;
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auto new_index = new_mat_nrs [ sel . GetIndex ( ) ] ;
if ( new_index = = - 1 )
throw Exception ( " Boundary " + ToString ( sel . GetIndex ( ) ) + " with name " + mesh . GetBCName ( sel . GetIndex ( ) - 1 ) + " extruded, but no new material specified for it! " ) ;
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el . SetIndex ( new_mat_nrs [ sel . GetIndex ( ) ] ) ;
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mesh . AddVolumeElement ( el ) ;
}
Element2d newel = sel ;
for ( auto & p : newel . PNums ( ) )
p = mapto [ p ] . Last ( ) ;
newel . SetIndex ( si_map [ sel . GetIndex ( ) ] ) ;
mesh . AddSurfaceElement ( newel ) ;
}
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else
{
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bool has_moved = false ;
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for ( auto p : sel . PNums ( ) )
if ( mapto [ p ] . Size ( ) )
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has_moved = true ;
if ( has_moved )
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for ( auto p : sel . PNums ( ) )
{
if ( ! mapto [ p ] . Size ( ) )
{
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fixed_points . SetBit ( p ) ;
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if ( is_boundary_moved . Test ( sel . GetIndex ( ) ) )
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moveboundarypoint . SetBit ( p ) ;
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}
}
}
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if ( is_boundary_moved . Test ( sel . GetIndex ( ) ) )
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{
for ( auto & p : mesh [ si ] . PNums ( ) )
if ( mapto [ p ] . Size ( ) )
p = mapto [ p ] . Last ( ) ;
}
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}
2015-01-09 02:18:22 +05:00
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for ( SegmentIndex sei = 0 ; sei < nseg ; sei + + )
{
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auto & seg = segments [ sei ] ;
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if ( is_boundary_moved . Test ( seg . si ) )
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for ( auto & p : seg . PNums ( ) )
if ( mapto [ p ] . Size ( ) )
p = mapto [ p ] . Last ( ) ;
}
2015-01-09 02:18:22 +05:00
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for ( ElementIndex ei = 0 ; ei < ne ; ei + + )
{
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auto el = mesh [ ei ] ;
ArrayMem < PointIndex , 4 > fixed ;
ArrayMem < PointIndex , 4 > moved ;
bool moved_bnd = false ;
for ( const auto & p : el . PNums ( ) )
{
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if ( fixed_points . Test ( p ) )
fixed . Append ( p ) ;
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if ( mapto [ p ] . Size ( ) )
moved . Append ( p ) ;
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if ( moveboundarypoint . Test ( p ) )
moved_bnd = true ;
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}
bool do_move , do_insert ;
if ( domains . Test ( el . GetIndex ( ) ) )
{
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do_move = fixed . Size ( ) & & moved_bnd ;
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do_insert = do_move ;
}
else
{
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do_move = ! fixed . Size ( ) | | moved_bnd ;
do_insert = ! do_move ;
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}
if ( do_move )
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{
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for ( auto & p : mesh [ ei ] . PNums ( ) )
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if ( mapto [ p ] . Size ( ) )
p = mapto [ p ] . Last ( ) ;
}
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if ( do_insert )
{
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if ( el . GetType ( ) = = TET )
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{
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if ( moved . Size ( ) = = 3 ) // inner corner
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{
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PointIndex p1 = moved [ 0 ] ;
PointIndex p2 = moved [ 1 ] ;
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PointIndex p3 = moved [ 2 ] ;
auto v1 = mesh [ p1 ] ;
auto n = Cross ( mesh [ p2 ] - v1 , mesh [ p3 ] - v1 ) ;
auto d = mesh [ mapto [ p1 ] [ 0 ] ] - v1 ;
if ( n * d > 0 )
Swap ( p2 , p3 ) ;
PointIndex p4 = p1 ;
PointIndex p5 = p2 ;
PointIndex p6 = p3 ;
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for ( auto i : Range ( params . heights ) )
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{
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Element nel ( PRISM ) ;
nel [ 0 ] = p4 ; nel [ 1 ] = p5 ; nel [ 2 ] = p6 ;
p4 = mapto [ p1 ] [ i ] ; p5 = mapto [ p2 ] [ i ] ; p6 = mapto [ p3 ] [ i ] ;
nel [ 3 ] = p4 ; nel [ 4 ] = p5 ; nel [ 5 ] = p6 ;
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nel . SetIndex ( el . GetIndex ( ) ) ;
mesh . AddVolumeElement ( nel ) ;
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}
}
if ( moved . Size ( ) = = 2 )
{
if ( fixed . Size ( ) = = 1 )
{
PointIndex p1 = moved [ 0 ] ;
PointIndex p2 = moved [ 1 ] ;
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for ( auto i : Range ( params . heights ) )
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{
PointIndex p3 = mapto [ moved [ 1 ] ] [ i ] ;
PointIndex p4 = mapto [ moved [ 0 ] ] [ i ] ;
Element nel ( PYRAMID ) ;
nel [ 0 ] = p1 ;
nel [ 1 ] = p2 ;
nel [ 2 ] = p3 ;
nel [ 3 ] = p4 ;
nel [ 4 ] = el [ 0 ] + el [ 1 ] + el [ 2 ] + el [ 3 ] - fixed [ 0 ] - moved [ 0 ] - moved [ 1 ] ;
if ( Cross ( mesh [ p2 ] - mesh [ p1 ] , mesh [ p4 ] - mesh [ p1 ] ) * ( mesh [ nel [ 4 ] ] - mesh [ nel [ 1 ] ] ) > 0 )
Swap ( nel [ 1 ] , nel [ 3 ] ) ;
nel . SetIndex ( el . GetIndex ( ) ) ;
mesh . AddVolumeElement ( nel ) ;
p1 = p4 ;
p2 = p3 ;
}
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}
}
if ( moved . Size ( ) = = 1 & & fixed . Size ( ) = = 1 )
{
PointIndex p1 = moved [ 0 ] ;
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for ( auto i : Range ( params . heights ) )
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{
Element nel = el ;
PointIndex p2 = mapto [ moved [ 0 ] ] [ i ] ;
for ( auto & p : nel . PNums ( ) )
{
if ( p = = moved [ 0 ] )
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p = p1 ;
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else if ( p = = fixed [ 0 ] )
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p = p2 ;
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}
p1 = p2 ;
mesh . AddVolumeElement ( nel ) ;
}
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}
}
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else if ( el . GetType ( ) = = PYRAMID )
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{
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if ( moved . Size ( ) = = 2 )
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{
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if ( fixed . Size ( ) ! = 2 )
throw Exception ( " This case is not implemented yet! Fixed size = " + ToString ( fixed . Size ( ) ) ) ;
PointIndex p1 = moved [ 0 ] ;
PointIndex p2 = moved [ 1 ] ;
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for ( auto i : Range ( params . heights ) )
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{
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PointIndex p3 = mapto [ moved [ 1 ] ] [ i ] ;
PointIndex p4 = mapto [ moved [ 0 ] ] [ i ] ;
Element nel ( PYRAMID ) ;
nel [ 0 ] = p1 ;
nel [ 1 ] = p2 ;
nel [ 2 ] = p3 ;
nel [ 3 ] = p4 ;
nel [ 4 ] = el [ 0 ] + el [ 1 ] + el [ 2 ] + el [ 3 ] + el [ 4 ] - fixed [ 0 ] - fixed [ 1 ] - moved [ 0 ] - moved [ 1 ] ;
if ( Cross ( mesh [ p2 ] - mesh [ p1 ] , mesh [ p4 ] - mesh [ p1 ] ) * ( mesh [ nel [ 4 ] ] - mesh [ nel [ 1 ] ] ) > 0 )
Swap ( nel [ 1 ] , nel [ 3 ] ) ;
nel . SetIndex ( el . GetIndex ( ) ) ;
mesh . AddVolumeElement ( nel ) ;
p1 = p4 ;
p2 = p3 ;
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}
}
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else if ( moved . Size ( ) = = 1 )
throw Exception ( " This case is not implemented yet! " ) ;
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}
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else
throw Exception ( " Boundarylayer only implemented for tets and pyramids outside yet! " ) ;
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}
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}
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}
2009-06-19 11:43:23 +06:00
2022-03-07 19:58:09 +05:00
void BoundaryLayerTool : : SetDomInOut ( )
{
for ( auto i : Range ( 1 , nfd_old + 1 ) )
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if ( moved_surfaces . Test ( i ) )
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{
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if ( auto dom = mesh . GetFaceDescriptor ( si_map [ i ] ) . DomainIn ( ) ; dom > ndom_old )
mesh . GetFaceDescriptor ( i ) . SetDomainOut ( dom ) ;
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else
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mesh . GetFaceDescriptor ( i ) . SetDomainIn ( mesh . GetFaceDescriptor ( si_map [ i ] ) . DomainOut ( ) ) ;
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}
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}
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void BoundaryLayerTool : : SetDomInOutSides ( )
{
BitArray done ( mesh . GetNFD ( ) + 1 ) ;
done . Clear ( ) ;
for ( auto sei : Range ( mesh . SurfaceElements ( ) ) )
{
auto & sel = mesh [ sei ] ;
auto index = sel . GetIndex ( ) ;
if ( done . Test ( index ) )
continue ;
done . SetBit ( index ) ;
auto & fd = mesh . GetFaceDescriptor ( index ) ;
if ( fd . DomainIn ( ) ! = - 1 )
continue ;
int e1 , e2 ;
mesh . GetTopology ( ) . GetSurface2VolumeElement ( sei + 1 , e1 , e2 ) ;
if ( e1 = = 0 )
fd . SetDomainIn ( 0 ) ;
else
fd . SetDomainIn ( mesh . VolumeElement ( e1 ) . GetIndex ( ) ) ;
if ( e2 = = 0 )
fd . SetDomainOut ( 0 ) ;
else
fd . SetDomainOut ( mesh . VolumeElement ( e2 ) . GetIndex ( ) ) ;
}
}
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void BoundaryLayerTool : : AddSegments ( )
{
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if ( have_single_segments )
MergeAndAddSegments ( mesh , new_segments ) ;
else
{
for ( auto & seg : new_segments )
mesh . AddSegment ( seg ) ;
}
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}
2022-03-07 20:04:21 +05:00
2022-03-07 19:58:09 +05:00
void BoundaryLayerTool : : FixVolumeElements ( )
{
static Timer timer ( " BoundaryLayerTool::FixVolumeElements " ) ; RegionTimer rt ( timer ) ;
BitArray is_inner_point ( mesh . GetNP ( ) + 1 ) ;
is_inner_point . Clear ( ) ;
auto changed_domains = domains ;
if ( ! params . outside )
changed_domains . Invert ( ) ;
for ( ElementIndex ei : Range ( ne ) )
if ( changed_domains . Test ( mesh [ ei ] . GetIndex ( ) ) )
for ( auto pi : mesh [ ei ] . PNums ( ) )
if ( mesh [ pi ] . Type ( ) = = INNERPOINT )
is_inner_point . SetBit ( pi ) ;
Array < PointIndex > points ;
for ( auto pi : mesh . Points ( ) . Range ( ) )
if ( is_inner_point . Test ( pi ) )
points . Append ( pi ) ;
auto p2el = mesh . CreatePoint2ElementTable ( is_inner_point ) ;
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// smooth growth vectors to shift additional element layers to the inside and fix flipped tets
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for ( [[maybe_unused]] auto step : Range ( 10 ) )
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{
for ( auto pi : points )
{
Vec < 3 > average_gw = 0.0 ;
auto & els = p2el [ pi ] ;
size_t cnt = 0 ;
for ( auto ei : els )
if ( ei < ne )
for ( auto pi1 : mesh [ ei ] . PNums ( ) )
if ( pi1 < = np )
{
average_gw + = growthvectors [ pi1 ] ;
cnt + + ;
}
growthvectors [ pi ] = 1.0 / cnt * average_gw ;
}
}
for ( auto pi : points )
{
mesh [ pi ] + = height * growthvectors [ pi ] ;
growthvectors [ pi ] = 0.0 ;
}
}
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void BoundaryLayerTool : : Perform ( )
{
CreateNewFaceDescriptors ( ) ;
CalculateGrowthVectors ( ) ;
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CreateFaceDescriptorsSides ( ) ;
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auto segmap = BuildSegMap ( ) ;
auto in_surface_direction = ProjectGrowthVectorsOnSurface ( ) ;
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if ( params . limit_growth_vectors )
LimitGrowthVectorLengths ( ) ;
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InterpolateGrowthVectors ( ) ;
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FixVolumeElements ( ) ;
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InsertNewElements ( segmap , in_surface_direction ) ;
SetDomInOut ( ) ;
AddSegments ( ) ;
mesh . GetTopology ( ) . ClearEdges ( ) ;
mesh . SetNextMajorTimeStamp ( ) ;
mesh . UpdateTopology ( ) ;
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SetDomInOutSides ( ) ;
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MeshingParameters mp ;
mp . optimize3d = " m " ;
mp . optsteps3d = 4 ;
OptimizeVolume ( mp , mesh ) ;
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}
void GenerateBoundaryLayer ( Mesh & mesh , const BoundaryLayerParameters & blp )
{
static Timer timer ( " Create Boundarylayers " ) ;
RegionTimer regt ( timer ) ;
BoundaryLayerTool tool ( mesh , blp ) ;
tool . Perform ( ) ;
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}
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} // namespace netgen