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# include "ClipperUtils.hpp"
# include "ExtrusionEntityCollection.hpp"
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# include "PerimeterGenerator.hpp"
# include "Layer.hpp"
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# include "Print.hpp"
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# include "SupportMaterial.hpp"
# include "Fill/FillBase.hpp"
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# include "EdgeGrid.hpp"
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# include "Geometry.hpp"
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# include <cmath>
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# include <memory>
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# include <boost/log/trivial.hpp>
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# include <tbb/parallel_for.h>
# include <tbb/atomic.h>
# include <tbb/spin_mutex.h>
# include <tbb/task_group.h>
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// #define SLIC3R_DEBUG
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// Make assert active if SLIC3R_DEBUG
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# ifdef SLIC3R_DEBUG
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# define DEBUG
# define _DEBUG
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# undef NDEBUG
# include "SVG.hpp"
# endif
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// #undef NDEBUG
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# include <cassert>
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namespace Slic3r {
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// Increment used to reach MARGIN in steps to avoid trespassing thin objects
# define NUM_MARGIN_STEPS 3
// Dimensions of a tree-like structure to save material
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# define PILLAR_SIZE (2.5)
# define PILLAR_SPACING 10
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//#define SUPPORT_SURFACES_OFFSET_PARAMETERS ClipperLib::jtMiter, 3.
//#define SUPPORT_SURFACES_OFFSET_PARAMETERS ClipperLib::jtMiter, 1.5
# define SUPPORT_SURFACES_OFFSET_PARAMETERS ClipperLib::jtSquare, 0.
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# ifdef SLIC3R_DEBUG
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const char * support_surface_type_to_color_name ( const PrintObjectSupportMaterial : : SupporLayerType surface_type )
{
switch ( surface_type ) {
case PrintObjectSupportMaterial : : sltTopContact : return " rgb(255,0,0) " ; // "red";
case PrintObjectSupportMaterial : : sltTopInterface : return " rgb(0,255,0) " ; // "green";
case PrintObjectSupportMaterial : : sltBase : return " rgb(0,0,255) " ; // "blue";
case PrintObjectSupportMaterial : : sltBottomInterface : return " rgb(255,255,128) " ; // yellow
case PrintObjectSupportMaterial : : sltBottomContact : return " rgb(255,0,255) " ; // magenta
case PrintObjectSupportMaterial : : sltRaftInterface : return " rgb(0,255,255) " ;
case PrintObjectSupportMaterial : : sltRaftBase : return " rgb(128,128,128) " ;
case PrintObjectSupportMaterial : : sltUnknown : return " rgb(128,0,0) " ; // maroon
default : return " rgb(64,64,64) " ;
} ;
}
Point export_support_surface_type_legend_to_svg_box_size ( )
{
return Point ( scale_ ( 1. + 10. * 8. ) , scale_ ( 3. ) ) ;
}
void export_support_surface_type_legend_to_svg ( SVG & svg , const Point & pos )
{
// 1st row
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coord_t pos_x0 = pos ( 0 ) + scale_ ( 1. ) ;
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coord_t pos_x = pos_x0 ;
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coord_t pos_y = pos ( 1 ) + scale_ ( 1.5 ) ;
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coord_t step_x = scale_ ( 10. ) ;
svg . draw_legend ( Point ( pos_x , pos_y ) , " top contact " , support_surface_type_to_color_name ( PrintObjectSupportMaterial : : sltTopContact ) ) ;
pos_x + = step_x ;
svg . draw_legend ( Point ( pos_x , pos_y ) , " top iface " , support_surface_type_to_color_name ( PrintObjectSupportMaterial : : sltTopInterface ) ) ;
pos_x + = step_x ;
svg . draw_legend ( Point ( pos_x , pos_y ) , " base " , support_surface_type_to_color_name ( PrintObjectSupportMaterial : : sltBase ) ) ;
pos_x + = step_x ;
svg . draw_legend ( Point ( pos_x , pos_y ) , " bottom iface " , support_surface_type_to_color_name ( PrintObjectSupportMaterial : : sltBottomInterface ) ) ;
pos_x + = step_x ;
svg . draw_legend ( Point ( pos_x , pos_y ) , " bottom contact " , support_surface_type_to_color_name ( PrintObjectSupportMaterial : : sltBottomContact ) ) ;
// 2nd row
pos_x = pos_x0 ;
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pos_y = pos ( 1 ) + scale_ ( 2.8 ) ;
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svg . draw_legend ( Point ( pos_x , pos_y ) , " raft interface " , support_surface_type_to_color_name ( PrintObjectSupportMaterial : : sltRaftInterface ) ) ;
pos_x + = step_x ;
svg . draw_legend ( Point ( pos_x , pos_y ) , " raft base " , support_surface_type_to_color_name ( PrintObjectSupportMaterial : : sltRaftBase ) ) ;
pos_x + = step_x ;
svg . draw_legend ( Point ( pos_x , pos_y ) , " unknown " , support_surface_type_to_color_name ( PrintObjectSupportMaterial : : sltUnknown ) ) ;
pos_x + = step_x ;
svg . draw_legend ( Point ( pos_x , pos_y ) , " intermediate " , support_surface_type_to_color_name ( PrintObjectSupportMaterial : : sltIntermediate ) ) ;
}
void export_print_z_polygons_to_svg ( const char * path , PrintObjectSupportMaterial : : MyLayer * * const layers , size_t n_layers )
{
BoundingBox bbox ;
for ( int i = 0 ; i < n_layers ; + + i )
bbox . merge ( get_extents ( layers [ i ] - > polygons ) ) ;
Point legend_size = export_support_surface_type_legend_to_svg_box_size ( ) ;
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Point legend_pos ( bbox . min ( 0 ) , bbox . max ( 1 ) ) ;
bbox . merge ( Point ( std : : max ( bbox . min ( 0 ) + legend_size ( 0 ) , bbox . max ( 0 ) ) , bbox . max ( 1 ) + legend_size ( 1 ) ) ) ;
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SVG svg ( path , bbox ) ;
const float transparency = 0.5f ;
for ( int i = 0 ; i < n_layers ; + + i )
svg . draw ( union_ex ( layers [ i ] - > polygons ) , support_surface_type_to_color_name ( layers [ i ] - > layer_type ) , transparency ) ;
for ( int i = 0 ; i < n_layers ; + + i )
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svg . draw ( to_polylines ( layers [ i ] - > polygons ) , support_surface_type_to_color_name ( layers [ i ] - > layer_type ) ) ;
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export_support_surface_type_legend_to_svg ( svg , legend_pos ) ;
svg . Close ( ) ;
}
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void export_print_z_polygons_and_extrusions_to_svg (
const char * path ,
PrintObjectSupportMaterial : : MyLayer * * const layers ,
size_t n_layers ,
SupportLayer & support_layer )
{
BoundingBox bbox ;
for ( int i = 0 ; i < n_layers ; + + i )
bbox . merge ( get_extents ( layers [ i ] - > polygons ) ) ;
Point legend_size = export_support_surface_type_legend_to_svg_box_size ( ) ;
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Point legend_pos ( bbox . min ( 0 ) , bbox . max ( 1 ) ) ;
bbox . merge ( Point ( std : : max ( bbox . min ( 0 ) + legend_size ( 0 ) , bbox . max ( 0 ) ) , bbox . max ( 1 ) + legend_size ( 1 ) ) ) ;
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SVG svg ( path , bbox ) ;
const float transparency = 0.5f ;
for ( int i = 0 ; i < n_layers ; + + i )
svg . draw ( union_ex ( layers [ i ] - > polygons ) , support_surface_type_to_color_name ( layers [ i ] - > layer_type ) , transparency ) ;
for ( int i = 0 ; i < n_layers ; + + i )
svg . draw ( to_polylines ( layers [ i ] - > polygons ) , support_surface_type_to_color_name ( layers [ i ] - > layer_type ) ) ;
Polygons polygons_support , polygons_interface ;
support_layer . support_fills . polygons_covered_by_width ( polygons_support , SCALED_EPSILON ) ;
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// support_layer.support_interface_fills.polygons_covered_by_width(polygons_interface, SCALED_EPSILON);
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svg . draw ( union_ex ( polygons_support ) , " brown " ) ;
svg . draw ( union_ex ( polygons_interface ) , " black " ) ;
export_support_surface_type_legend_to_svg ( svg , legend_pos ) ;
svg . Close ( ) ;
}
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# endif /* SLIC3R_DEBUG */
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PrintObjectSupportMaterial : : PrintObjectSupportMaterial ( const PrintObject * object , const SlicingParameters & slicing_params ) :
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m_object ( object ) ,
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m_print_config ( & object - > print ( ) - > config ( ) ) ,
m_object_config ( & object - > config ( ) ) ,
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m_slicing_params ( slicing_params ) ,
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m_first_layer_flow ( support_material_1st_layer_flow ( object , float ( slicing_params . first_print_layer_height ) ) ) ,
m_support_material_flow ( support_material_flow ( object , float ( slicing_params . layer_height ) ) ) ,
m_support_material_interface_flow ( support_material_interface_flow ( object , float ( slicing_params . layer_height ) ) ) ,
m_support_layer_height_min ( 0.01 )
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{
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// Calculate a minimum support layer height as a minimum over all extruders, but not smaller than 10um.
m_support_layer_height_min = 1000000. ;
for ( auto lh : m_print_config - > min_layer_height . values )
m_support_layer_height_min = std : : min ( m_support_layer_height_min , std : : max ( 0.01 , lh ) ) ;
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if ( m_object_config - > support_material_interface_layers . value = = 0 ) {
// No interface layers allowed, print everything with the base support pattern.
m_support_material_interface_flow = m_support_material_flow ;
}
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// Evaluate the XY gap between the object outer perimeters and the support structures.
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// Evaluate the XY gap between the object outer perimeters and the support structures.
coordf_t external_perimeter_width = 0. ;
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for ( size_t region_id = 0 ; region_id < object - > region_volumes . size ( ) ; + + region_id )
if ( ! object - > region_volumes [ region_id ] . empty ( ) )
external_perimeter_width = std : : max ( external_perimeter_width ,
( coordf_t ) object - > print ( ) - > get_region ( region_id ) - > flow ( frExternalPerimeter , slicing_params . layer_height , false , false , - 1 , * object ) . width ) ;
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m_gap_xy = m_object_config - > support_material_xy_spacing . get_abs_value ( external_perimeter_width ) ;
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m_can_merge_support_regions = m_object_config - > support_material_extruder . value = = m_object_config - > support_material_interface_extruder . value ;
if ( ! m_can_merge_support_regions & & ( m_object_config - > support_material_extruder . value = = 0 | | m_object_config - > support_material_interface_extruder . value = = 0 ) ) {
// One of the support extruders is of "don't care" type.
auto object_extruders = m_object - > print ( ) - > object_extruders ( ) ;
if ( object_extruders . size ( ) = = 1 & &
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* object_extruders . begin ( ) = = std : : max < unsigned int > ( m_object_config - > support_material_extruder . value , m_object_config - > support_material_interface_extruder . value ) )
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// Object is printed with the same extruder as the support.
m_can_merge_support_regions = true ;
}
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}
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// Using the std::deque as an allocator.
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inline PrintObjectSupportMaterial : : MyLayer & layer_allocate (
std : : deque < PrintObjectSupportMaterial : : MyLayer > & layer_storage ,
PrintObjectSupportMaterial : : SupporLayerType layer_type )
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{
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layer_storage . push_back ( PrintObjectSupportMaterial : : MyLayer ( ) ) ;
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layer_storage . back ( ) . layer_type = layer_type ;
return layer_storage . back ( ) ;
}
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inline PrintObjectSupportMaterial : : MyLayer & layer_allocate (
std : : deque < PrintObjectSupportMaterial : : MyLayer > & layer_storage ,
tbb : : spin_mutex & layer_storage_mutex ,
PrintObjectSupportMaterial : : SupporLayerType layer_type )
{
layer_storage_mutex . lock ( ) ;
layer_storage . push_back ( PrintObjectSupportMaterial : : MyLayer ( ) ) ;
PrintObjectSupportMaterial : : MyLayer * layer_new = & layer_storage . back ( ) ;
layer_storage_mutex . unlock ( ) ;
layer_new - > layer_type = layer_type ;
return * layer_new ;
}
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inline void layers_append ( PrintObjectSupportMaterial : : MyLayersPtr & dst , const PrintObjectSupportMaterial : : MyLayersPtr & src )
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{
dst . insert ( dst . end ( ) , src . begin ( ) , src . end ( ) ) ;
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}
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// Compare layers lexicographically.
struct MyLayersPtrCompare
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{
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bool operator ( ) ( const PrintObjectSupportMaterial : : MyLayer * layer1 , const PrintObjectSupportMaterial : : MyLayer * layer2 ) const {
return * layer1 < * layer2 ;
}
} ;
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void PrintObjectSupportMaterial : : generate ( PrintObject & object )
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{
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Start " ;
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coordf_t max_object_layer_height = 0. ;
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for ( size_t i = 0 ; i < object . layer_count ( ) ; + + i )
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max_object_layer_height = std : : max ( max_object_layer_height , object . layers ( ) [ i ] - > height ) ;
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// Layer instances will be allocated by std::deque and they will be kept until the end of this function call.
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// The layers will be referenced by various LayersPtr (of type std::vector<Layer*>)
MyLayerStorage layer_storage ;
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Creating top contacts " ;
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// Determine the top contact surfaces of the support, defined as:
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// contact = overhangs - clearance + margin
// This method is responsible for identifying what contact surfaces
// should the support material expose to the object in order to guarantee
// that it will be effective, regardless of how it's built below.
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// If raft is to be generated, the 1st top_contact layer will contain the 1st object layer silhouette without holes.
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MyLayersPtr top_contacts = this - > top_contact_layers ( object , layer_storage ) ;
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if ( top_contacts . empty ( ) )
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// Nothing is supported, no supports are generated.
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return ;
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# ifdef SLIC3R_DEBUG
static int iRun = 0 ;
iRun + + ;
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for ( const MyLayer * layer : top_contacts )
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Slic3r : : SVG : : export_expolygons (
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debug_out_path ( " support-top-contacts-%d-%lf.svg " , iRun , layer - > print_z ) ,
union_ex ( layer - > polygons , false ) ) ;
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# endif /* SLIC3R_DEBUG */
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Creating bottom contacts " ;
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// Determine the bottom contact surfaces of the supports over the top surfaces of the object.
// Depending on whether the support is soluble or not, the contact layer thickness is decided.
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// layer_support_areas contains the per object layer support areas. These per object layer support areas
// may get merged and trimmed by this->generate_base_layers() if the support layers are not synchronized with object layers.
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std : : vector < Polygons > layer_support_areas ;
MyLayersPtr bottom_contacts = this - > bottom_contact_layers_and_layer_support_areas (
object , top_contacts , layer_storage ,
layer_support_areas ) ;
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# ifdef SLIC3R_DEBUG
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for ( size_t layer_id = 0 ; layer_id < object . layers ( ) . size ( ) ; + + layer_id )
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Slic3r : : SVG : : export_expolygons (
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debug_out_path ( " support-areas-%d-%lf.svg " , iRun , object . layers ( ) [ layer_id ] - > print_z ) ,
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union_ex ( layer_support_areas [ layer_id ] , false ) ) ;
# endif /* SLIC3R_DEBUG */
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Creating intermediate layers - indices " ;
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// Allocate empty layers between the top / bottom support contact layers
// as placeholders for the base and intermediate support layers.
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// The layers may or may not be synchronized with the object layers, depending on the configuration.
// For example, a single nozzle multi material printing will need to generate a waste tower, which in turn
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// wastes less material, if there are as little tool changes as possible.
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MyLayersPtr intermediate_layers = this - > raft_and_intermediate_support_layers (
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object , bottom_contacts , top_contacts , layer_storage ) ;
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// this->trim_support_layers_by_object(object, top_contacts, m_slicing_params.soluble_interface ? 0. : m_support_layer_height_min, 0., m_gap_xy);
this - > trim_support_layers_by_object ( object , top_contacts ,
m_slicing_params . soluble_interface ? 0. : m_object_config - > support_material_contact_distance . value ,
m_slicing_params . soluble_interface ? 0. : m_object_config - > support_material_contact_distance . value , m_gap_xy ) ;
# ifdef SLIC3R_DEBUG
for ( const MyLayer * layer : top_contacts )
Slic3r : : SVG : : export_expolygons (
debug_out_path ( " support-top-contacts-trimmed-by-object-%d-%lf.svg " , iRun , layer - > print_z ) ,
union_ex ( layer - > polygons , false ) ) ;
# endif
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Creating base layers " ;
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// Fill in intermediate layers between the top / bottom support contact layers, trimm them by the object.
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this - > generate_base_layers ( object , bottom_contacts , top_contacts , intermediate_layers , layer_support_areas ) ;
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# ifdef SLIC3R_DEBUG
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for ( MyLayersPtr : : const_iterator it = intermediate_layers . begin ( ) ; it ! = intermediate_layers . end ( ) ; + + it )
Slic3r : : SVG : : export_expolygons (
debug_out_path ( " support-base-layers-%d-%lf.svg " , iRun , ( * it ) - > print_z ) ,
union_ex ( ( * it ) - > polygons , false ) ) ;
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# endif /* SLIC3R_DEBUG */
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Trimming top contacts by bottom contacts " ;
// Because the top and bottom contacts are thick slabs, they may overlap causing over extrusion
// and unwanted strong bonds to the object.
// Rather trim the top contacts by their overlapping bottom contacts to leave a gap instead of over extruding
// top contacts over the bottom contacts.
this - > trim_top_contacts_by_bottom_contacts ( object , bottom_contacts , top_contacts ) ;
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Creating interfaces " ;
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// Propagate top / bottom contact layers to generate interface layers.
MyLayersPtr interface_layers = this - > generate_interface_layers (
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bottom_contacts , top_contacts , intermediate_layers , layer_storage ) ;
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Creating raft " ;
// If raft is to be generated, the 1st top_contact layer will contain the 1st object layer silhouette with holes filled.
// There is also a 1st intermediate layer containing bases of support columns.
// Inflate the bases of the support columns and create the raft base under the object.
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MyLayersPtr raft_layers = this - > generate_raft_base ( top_contacts , interface_layers , intermediate_layers , layer_storage ) ;
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# ifdef SLIC3R_DEBUG
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for ( MyLayersPtr : : const_iterator it = interface_layers . begin ( ) ; it ! = interface_layers . end ( ) ; + + it )
Slic3r : : SVG : : export_expolygons (
debug_out_path ( " support-interface-layers-%d-%lf.svg " , iRun , ( * it ) - > print_z ) ,
union_ex ( ( * it ) - > polygons , false ) ) ;
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# endif /* SLIC3R_DEBUG */
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/*
// Clip with the pillars.
if ( ! shape . empty ( ) ) {
this - > clip_with_shape ( interface , shape ) ;
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this - > clip_with_shape ( base , shape ) ;
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}
*/
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Creating layers " ;
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// For debugging purposes, one may want to show only some of the support extrusions.
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// raft_layers.clear();
// bottom_contacts.clear();
// top_contacts.clear();
// intermediate_layers.clear();
// interface_layers.clear();
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// Install support layers into the object.
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// A support layer installed on a PrintObject has a unique print_z.
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MyLayersPtr layers_sorted ;
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layers_sorted . reserve ( raft_layers . size ( ) + bottom_contacts . size ( ) + top_contacts . size ( ) + intermediate_layers . size ( ) + interface_layers . size ( ) ) ;
layers_append ( layers_sorted , raft_layers ) ;
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layers_append ( layers_sorted , bottom_contacts ) ;
layers_append ( layers_sorted , top_contacts ) ;
layers_append ( layers_sorted , intermediate_layers ) ;
layers_append ( layers_sorted , interface_layers ) ;
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// Sort the layers lexicographically by a raising print_z and a decreasing height.
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std : : sort ( layers_sorted . begin ( ) , layers_sorted . end ( ) , MyLayersPtrCompare ( ) ) ;
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int layer_id = 0 ;
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assert ( object . support_layers ( ) . empty ( ) ) ;
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for ( size_t i = 0 ; i < layers_sorted . size ( ) ; ) {
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// Find the last layer with roughly the same print_z, find the minimum layer height of all.
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// Due to the floating point inaccuracies, the print_z may not be the same even if in theory they should.
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size_t j = i + 1 ;
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coordf_t zmax = layers_sorted [ i ] - > print_z + EPSILON ;
for ( ; j < layers_sorted . size ( ) & & layers_sorted [ j ] - > print_z < = zmax ; + + j ) ;
// Assign an average print_z to the set of layers with nearly equal print_z.
coordf_t zavg = 0.5 * ( layers_sorted [ i ] - > print_z + layers_sorted [ j - 1 ] - > print_z ) ;
coordf_t height_min = layers_sorted [ i ] - > height ;
bool empty = true ;
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for ( size_t u = i ; u < j ; + + u ) {
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MyLayer & layer = * layers_sorted [ u ] ;
if ( ! layer . polygons . empty ( ) )
empty = false ;
layer . print_z = zavg ;
height_min = std : : min ( height_min , layer . height ) ;
}
if ( ! empty ) {
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// Here the upper_layer and lower_layer pointers are left to null at the support layers,
// as they are never used. These pointers are candidates for removal.
object . add_support_layer ( layer_id + + , height_min , zavg ) ;
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}
i = j ;
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}
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - Generating tool paths " ;
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// Generate the actual toolpaths and save them into each layer.
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this - > generate_toolpaths ( object , raft_layers , bottom_contacts , top_contacts , intermediate_layers , interface_layers ) ;
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# ifdef SLIC3R_DEBUG
{
size_t layer_id = 0 ;
for ( int i = 0 ; i < int ( layers_sorted . size ( ) ) ; ) {
// Find the last layer with roughly the same print_z, find the minimum layer height of all.
// Due to the floating point inaccuracies, the print_z may not be the same even if in theory they should.
int j = i + 1 ;
coordf_t zmax = layers_sorted [ i ] - > print_z + EPSILON ;
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bool empty = true ;
for ( ; j < layers_sorted . size ( ) & & layers_sorted [ j ] - > print_z < = zmax ; + + j )
if ( ! layers_sorted [ j ] - > polygons . empty ( ) )
empty = false ;
if ( ! empty ) {
export_print_z_polygons_to_svg (
debug_out_path ( " support-%d-%lf.svg " , iRun , layers_sorted [ i ] - > print_z ) . c_str ( ) ,
layers_sorted . data ( ) + i , j - i ) ;
export_print_z_polygons_and_extrusions_to_svg (
debug_out_path ( " support-w-fills-%d-%lf.svg " , iRun , layers_sorted [ i ] - > print_z ) . c_str ( ) ,
layers_sorted . data ( ) + i , j - i ,
* object . support_layers [ layer_id ] ) ;
+ + layer_id ;
}
i = j ;
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}
}
# endif /* SLIC3R_DEBUG */
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BOOST_LOG_TRIVIAL ( info ) < < " Support generator - End " ;
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}
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// Collect all polygons of all regions in a layer with a given surface type.
Polygons collect_region_slices_by_type ( const Layer & layer , SurfaceType surface_type )
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{
// 1) Count the new polygons first.
size_t n_polygons_new = 0 ;
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for ( const LayerRegion * region : layer . regions ( ) )
for ( const Surface & surface : region - > slices . surfaces )
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if ( surface . surface_type = = surface_type )
n_polygons_new + = surface . expolygon . holes . size ( ) + 1 ;
// 2) Collect the new polygons.
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Polygons out ;
out . reserve ( n_polygons_new ) ;
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for ( const LayerRegion * region : layer . regions ( ) )
for ( const Surface & surface : region - > slices . surfaces )
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if ( surface . surface_type = = surface_type )
polygons_append ( out , surface . expolygon ) ;
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return out ;
}
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// Collect outer contours of all slices of this layer.
// This is useful for calculating the support base with holes filled.
Polygons collect_slices_outer ( const Layer & layer )
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{
Polygons out ;
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out . reserve ( out . size ( ) + layer . slices . expolygons . size ( ) ) ;
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for ( const ExPolygon & expoly : layer . slices . expolygons )
out . emplace_back ( expoly . contour ) ;
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return out ;
}
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class SupportGridPattern
{
public :
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// Achtung! The support_polygons need to be trimmed by trimming_polygons, otherwise
// the selection by island_samples (see the island_samples() method) will not work!
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SupportGridPattern (
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// Support islands, to be stretched into a grid. Already trimmed with min(lower_layer_offset, m_gap_xy)
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const Polygons & support_polygons ,
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// Trimming polygons, to trim the stretched support islands. support_polygons were already trimmed with trimming_polygons.
const Polygons & trimming_polygons ,
// Grid spacing, given by "support_material_spacing" + m_support_material_flow.spacing()
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coordf_t support_spacing ,
coordf_t support_angle ) :
m_support_polygons ( & support_polygons ) , m_trimming_polygons ( & trimming_polygons ) ,
m_support_spacing ( support_spacing ) , m_support_angle ( support_angle )
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{
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if ( m_support_angle ! = 0. ) {
// Create a copy of the rotated contours.
m_support_polygons_rotated = support_polygons ;
m_trimming_polygons_rotated = trimming_polygons ;
m_support_polygons = & m_support_polygons_rotated ;
m_trimming_polygons = & m_trimming_polygons_rotated ;
polygons_rotate ( m_support_polygons_rotated , - support_angle ) ;
polygons_rotate ( m_trimming_polygons_rotated , - support_angle ) ;
}
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// Create an EdgeGrid, initialize it with projection, initialize signed distance field.
coord_t grid_resolution = coord_t ( scale_ ( m_support_spacing ) ) ;
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BoundingBox bbox = get_extents ( * m_support_polygons ) ;
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bbox . offset ( 20 ) ;
bbox . align_to_grid ( grid_resolution ) ;
m_grid . set_bbox ( bbox ) ;
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m_grid . create ( * m_support_polygons , grid_resolution ) ;
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#if 0
if ( m_grid . has_intersecting_edges ( ) ) {
// EdgeGrid fails to produce valid signed distance function for self-intersecting polygons.
m_support_polygons_rotated = simplify_polygons ( * m_support_polygons ) ;
m_support_polygons = & m_support_polygons_rotated ;
m_grid . set_bbox ( bbox ) ;
m_grid . create ( * m_support_polygons , grid_resolution ) ;
// assert(! m_grid.has_intersecting_edges());
printf ( " SupportGridPattern: fixing polygons with intersection %s \n " ,
m_grid . has_intersecting_edges ( ) ? " FAILED " : " SUCCEEDED " ) ;
}
# endif
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m_grid . calculate_sdf ( ) ;
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// Sample a single point per input support polygon, keep it as a reference to maintain corresponding
// polygons if ever these polygons get split into parts by the trimming polygons.
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m_island_samples = island_samples ( * m_support_polygons ) ;
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}
// Extract polygons from the grid, offsetted by offset_in_grid,
// and trim the extracted polygons by trimming_polygons.
// Trimming by the trimming_polygons may split the extracted polygons into pieces.
// Remove all the pieces, which do not contain any of the island_samples.
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Polygons extract_support ( const coord_t offset_in_grid , bool fill_holes )
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{
// Generate islands, so each island may be tested for overlap with m_island_samples.
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assert ( std : : abs ( 2 * offset_in_grid ) < m_grid . resolution ( ) ) ;
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# ifdef SLIC3R_DEBUG
Polygons support_polygons_simplified = m_grid . contours_simplified ( offset_in_grid , fill_holes ) ;
ExPolygons islands = diff_ex ( support_polygons_simplified , * m_trimming_polygons , false ) ;
# else
ExPolygons islands = diff_ex ( m_grid . contours_simplified ( offset_in_grid , fill_holes ) , * m_trimming_polygons , false ) ;
# endif
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// Extract polygons, which contain some of the m_island_samples.
Polygons out ;
for ( ExPolygon & island : islands ) {
BoundingBox bbox = get_extents ( island . contour ) ;
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// Samples are sorted lexicographically.
Removed Point::scale(),translate(),coincides_with(),distance_to(),
distance_to_squared(),perp_distance_to(),negative(),vector_to(),
translate(), distance_to() etc,
replaced with the Eigen equivalents.
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auto it_lower = std : : lower_bound ( m_island_samples . begin ( ) , m_island_samples . end ( ) , Point ( bbox . min - Point ( 1 , 1 ) ) ) ;
auto it_upper = std : : upper_bound ( m_island_samples . begin ( ) , m_island_samples . end ( ) , Point ( bbox . max + Point ( 1 , 1 ) ) ) ;
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std : : vector < std : : pair < Point , bool > > samples_inside ;
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for ( auto it = it_lower ; it ! = it_upper ; + + it )
if ( bbox . contains ( * it ) )
samples_inside . push_back ( std : : make_pair ( * it , false ) ) ;
if ( ! samples_inside . empty ( ) ) {
// For all samples_inside count the boundary crossing.
for ( size_t i_contour = 0 ; i_contour < = island . holes . size ( ) ; + + i_contour ) {
Polygon & contour = ( i_contour = = 0 ) ? island . contour : island . holes [ i_contour - 1 ] ;
Points : : const_iterator i = contour . points . begin ( ) ;
Points : : const_iterator j = contour . points . end ( ) - 1 ;
for ( ; i ! = contour . points . end ( ) ; j = i + + ) {
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//FIXME this test is not numerically robust. Particularly, it does not handle horizontal segments at y == point(1) well.
// Does the ray with y == point(1) intersect this line segment?
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for ( auto & sample_inside : samples_inside ) {
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if ( ( ( * i ) ( 1 ) > sample_inside . first ( 1 ) ) ! = ( ( * j ) ( 1 ) > sample_inside . first ( 1 ) ) ) {
double x1 = ( double ) sample_inside . first ( 0 ) ;
double x2 = ( double ) ( * i ) ( 0 ) + ( double ) ( ( * j ) ( 0 ) - ( * i ) ( 0 ) ) * ( double ) ( sample_inside . first ( 1 ) - ( * i ) ( 1 ) ) / ( double ) ( ( * j ) ( 1 ) - ( * i ) ( 1 ) ) ;
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if ( x1 < x2 )
sample_inside . second = ! sample_inside . second ;
}
}
}
}
// If any of the sample is inside this island, add this island to the output.
for ( auto & sample_inside : samples_inside )
if ( sample_inside . second ) {
polygons_append ( out , std : : move ( island ) ) ;
island . clear ( ) ;
break ;
}
}
}
# ifdef SLIC3R_DEBUG
static int iRun = 0 ;
+ + iRun ;
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BoundingBox bbox = get_extents ( * m_trimming_polygons ) ;
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if ( ! islands . empty ( ) )
bbox . merge ( get_extents ( islands ) ) ;
if ( ! out . empty ( ) )
bbox . merge ( get_extents ( out ) ) ;
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if ( ! support_polygons_simplified . empty ( ) )
bbox . merge ( get_extents ( support_polygons_simplified ) ) ;
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SVG svg ( debug_out_path ( " extract_support_from_grid_trimmed-%d.svg " , iRun ) . c_str ( ) , bbox ) ;
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svg . draw ( union_ex ( support_polygons_simplified ) , " gray " , 0.25f ) ;
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svg . draw ( islands , " red " , 0.5f ) ;
svg . draw ( union_ex ( out ) , " green " , 0.5f ) ;
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svg . draw ( union_ex ( * m_support_polygons ) , " blue " , 0.5f ) ;
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svg . draw_outline ( islands , " red " , " red " , scale_ ( 0.05 ) ) ;
svg . draw_outline ( union_ex ( out ) , " green " , " green " , scale_ ( 0.05 ) ) ;
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svg . draw_outline ( union_ex ( * m_support_polygons ) , " blue " , " blue " , scale_ ( 0.05 ) ) ;
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for ( const Point & pt : m_island_samples )
svg . draw ( pt , " black " , coord_t ( scale_ ( 0.15 ) ) ) ;
svg . Close ( ) ;
# endif /* SLIC3R_DEBUG */
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if ( m_support_angle ! = 0. )
polygons_rotate ( out , m_support_angle ) ;
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return out ;
}
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# ifdef SLIC3R_DEBUG
void serialize ( const std : : string & path )
{
FILE * file = : : fopen ( path . c_str ( ) , " wb " ) ;
: : fwrite ( & m_support_spacing , 8 , 1 , file ) ;
: : fwrite ( & m_support_angle , 8 , 1 , file ) ;
uint32_t n_polygons = m_support_polygons - > size ( ) ;
: : fwrite ( & n_polygons , 4 , 1 , file ) ;
for ( uint32_t i = 0 ; i < n_polygons ; + + i ) {
const Polygon & poly = ( * m_support_polygons ) [ i ] ;
uint32_t n_points = poly . size ( ) ;
: : fwrite ( & n_points , 4 , 1 , file ) ;
for ( uint32_t j = 0 ; j < n_points ; + + j ) {
const Point & pt = poly . points [ j ] ;
: : fwrite ( & pt . x , sizeof ( coord_t ) , 1 , file ) ;
: : fwrite ( & pt . y , sizeof ( coord_t ) , 1 , file ) ;
}
}
n_polygons = m_trimming_polygons - > size ( ) ;
: : fwrite ( & n_polygons , 4 , 1 , file ) ;
for ( uint32_t i = 0 ; i < n_polygons ; + + i ) {
const Polygon & poly = ( * m_trimming_polygons ) [ i ] ;
uint32_t n_points = poly . size ( ) ;
: : fwrite ( & n_points , 4 , 1 , file ) ;
for ( uint32_t j = 0 ; j < n_points ; + + j ) {
const Point & pt = poly . points [ j ] ;
: : fwrite ( & pt . x , sizeof ( coord_t ) , 1 , file ) ;
: : fwrite ( & pt . y , sizeof ( coord_t ) , 1 , file ) ;
}
}
: : fclose ( file ) ;
}
static SupportGridPattern deserialize ( const std : : string & path , int which = - 1 )
{
SupportGridPattern out ;
out . deserialize_ ( path , which ) ;
return out ;
}
// Deserialization constructor
bool deserialize_ ( const std : : string & path , int which = - 1 )
{
FILE * file = : : fopen ( path . c_str ( ) , " rb " ) ;
if ( file = = nullptr )
return false ;
m_support_polygons = & m_support_polygons_deserialized ;
m_trimming_polygons = & m_trimming_polygons_deserialized ;
: : fread ( & m_support_spacing , 8 , 1 , file ) ;
: : fread ( & m_support_angle , 8 , 1 , file ) ;
//FIXME
//m_support_spacing *= 0.01 / 2;
uint32_t n_polygons ;
: : fread ( & n_polygons , 4 , 1 , file ) ;
m_support_polygons_deserialized . reserve ( n_polygons ) ;
int32_t scale = 1 ;
for ( uint32_t i = 0 ; i < n_polygons ; + + i ) {
Polygon poly ;
uint32_t n_points ;
: : fread ( & n_points , 4 , 1 , file ) ;
poly . points . reserve ( n_points ) ;
for ( uint32_t j = 0 ; j < n_points ; + + j ) {
coord_t x , y ;
: : fread ( & x , sizeof ( coord_t ) , 1 , file ) ;
: : fread ( & y , sizeof ( coord_t ) , 1 , file ) ;
poly . points . emplace_back ( Point ( x * scale , y * scale ) ) ;
}
if ( which = = - 1 | | which = = i )
m_support_polygons_deserialized . emplace_back ( std : : move ( poly ) ) ;
printf ( " Polygon %d, area: %lf \n " , i , area ( poly . points ) ) ;
}
: : fread ( & n_polygons , 4 , 1 , file ) ;
m_trimming_polygons_deserialized . reserve ( n_polygons ) ;
for ( uint32_t i = 0 ; i < n_polygons ; + + i ) {
Polygon poly ;
uint32_t n_points ;
: : fread ( & n_points , 4 , 1 , file ) ;
poly . points . reserve ( n_points ) ;
for ( uint32_t j = 0 ; j < n_points ; + + j ) {
coord_t x , y ;
: : fread ( & x , sizeof ( coord_t ) , 1 , file ) ;
: : fread ( & y , sizeof ( coord_t ) , 1 , file ) ;
poly . points . emplace_back ( Point ( x * scale , y * scale ) ) ;
}
m_trimming_polygons_deserialized . emplace_back ( std : : move ( poly ) ) ;
}
: : fclose ( file ) ;
m_support_polygons_deserialized = simplify_polygons ( m_support_polygons_deserialized , false ) ;
//m_support_polygons_deserialized = to_polygons(union_ex(m_support_polygons_deserialized, false));
// Create an EdgeGrid, initialize it with projection, initialize signed distance field.
coord_t grid_resolution = coord_t ( scale_ ( m_support_spacing ) ) ;
BoundingBox bbox = get_extents ( * m_support_polygons ) ;
bbox . offset ( 20 ) ;
bbox . align_to_grid ( grid_resolution ) ;
m_grid . set_bbox ( bbox ) ;
m_grid . create ( * m_support_polygons , grid_resolution ) ;
m_grid . calculate_sdf ( ) ;
// Sample a single point per input support polygon, keep it as a reference to maintain corresponding
// polygons if ever these polygons get split into parts by the trimming polygons.
m_island_samples = island_samples ( * m_support_polygons ) ;
return true ;
}
const Polygons & support_polygons ( ) const { return * m_support_polygons ; }
const Polygons & trimming_polygons ( ) const { return * m_trimming_polygons ; }
const EdgeGrid : : Grid & grid ( ) const { return m_grid ; }
# endif /* SLIC3R_DEBUG */
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private :
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SupportGridPattern ( ) { }
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SupportGridPattern & operator = ( const SupportGridPattern & rhs ) ;
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#if 0
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// Get some internal point of an expolygon, to be used as a representative
// sample to test, whether this island is inside another island.
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//FIXME this was quick, but not sufficiently robust.
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static Point island_sample ( const ExPolygon & expoly )
{
// Find the lowest point lexicographically.
const Point * pt_min = & expoly . contour . points . front ( ) ;
for ( size_t i = 1 ; i < expoly . contour . points . size ( ) ; + + i )
if ( expoly . contour . points [ i ] < * pt_min )
pt_min = & expoly . contour . points [ i ] ;
// Lowest corner will always be convex, in worst case denegenerate with zero angle.
const Point & p1 = ( pt_min = = & expoly . contour . points . front ( ) ) ? expoly . contour . points . back ( ) : * ( pt_min - 1 ) ;
const Point & p2 = * pt_min ;
const Point & p3 = ( pt_min = = & expoly . contour . points . back ( ) ) ? expoly . contour . points . front ( ) : * ( pt_min + 1 ) ;
Vector v = ( p3 - p2 ) + ( p1 - p2 ) ;
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double l2 = double ( v ( 0 ) ) * double ( v ( 0 ) ) + double ( v ( 1 ) ) * double ( v ( 1 ) ) ;
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if ( l2 = = 0. )
return p2 ;
double coef = 20. / sqrt ( l2 ) ;
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return Point ( p2 ( 0 ) + coef * v ( 0 ) , p2 ( 1 ) + coef * v ( 1 ) ) ;
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}
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# endif
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// Sample one internal point per expolygon.
// FIXME this is quite an overkill to calculate a complete offset just to get a single point, but at least it is robust.
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static Points island_samples ( const ExPolygons & expolygons )
{
Points pts ;
pts . reserve ( expolygons . size ( ) ) ;
for ( const ExPolygon & expoly : expolygons )
if ( expoly . contour . points . size ( ) > 2 ) {
#if 0
pts . push_back ( island_sample ( expoly ) ) ;
# else
Polygons polygons = offset ( expoly , - 20.f ) ;
for ( const Polygon & poly : polygons )
if ( ! poly . points . empty ( ) ) {
pts . push_back ( poly . points . front ( ) ) ;
break ;
}
# endif
}
// Sort the points lexicographically, so a binary search could be used to locate points inside a bounding box.
std : : sort ( pts . begin ( ) , pts . end ( ) ) ;
return pts ;
}
static Points island_samples ( const Polygons & polygons )
{
return island_samples ( union_ex ( polygons ) ) ;
}
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const Polygons * m_support_polygons ;
const Polygons * m_trimming_polygons ;
Polygons m_support_polygons_rotated ;
Polygons m_trimming_polygons_rotated ;
// Angle in radians, by which the whole support is rotated.
coordf_t m_support_angle ;
// X spacing of the support lines parallel with the Y axis.
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coordf_t m_support_spacing ;
Slic3r : : EdgeGrid : : Grid m_grid ;
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// Internal sample points of supporting expolygons. These internal points are used to pick regions corresponding
// to the initial supporting regions, after these regions werre grown and possibly split to many by the trimming polygons.
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Points m_island_samples ;
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# ifdef SLIC3R_DEBUG
// support for deserialization of m_support_polygons, m_trimming_polygons
Polygons m_support_polygons_deserialized ;
Polygons m_trimming_polygons_deserialized ;
# endif /* SLIC3R_DEBUG */
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} ;
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namespace SupportMaterialInternal {
static inline bool has_bridging_perimeters ( const ExtrusionLoop & loop )
{
for ( const ExtrusionPath & ep : loop . paths )
if ( ep . role ( ) = = erOverhangPerimeter & & ! ep . polyline . empty ( ) )
return ep . size ( ) > = ( ep . is_closed ( ) ? 3 : 2 ) ;
return false ;
}
static bool has_bridging_perimeters ( const ExtrusionEntityCollection & perimeters )
{
for ( const ExtrusionEntity * ee : perimeters . entities ) {
if ( ee - > is_collection ( ) ) {
for ( const ExtrusionEntity * ee2 : static_cast < const ExtrusionEntityCollection * > ( ee ) - > entities ) {
assert ( ! ee2 - > is_collection ( ) ) ;
if ( ee2 - > is_loop ( ) )
if ( has_bridging_perimeters ( * static_cast < const ExtrusionLoop * > ( ee2 ) ) )
return true ;
}
} else if ( ee - > is_loop ( ) & & has_bridging_perimeters ( * static_cast < const ExtrusionLoop * > ( ee ) ) )
return true ;
}
return false ;
}
static bool has_bridging_fills ( const ExtrusionEntityCollection & fills )
{
for ( const ExtrusionEntity * ee : fills . entities ) {
assert ( ee - > is_collection ( ) ) ;
for ( const ExtrusionEntity * ee2 : static_cast < const ExtrusionEntityCollection * > ( ee ) - > entities ) {
assert ( ! ee2 - > is_collection ( ) ) ;
assert ( ! ee2 - > is_loop ( ) ) ;
if ( ee2 - > role ( ) = = erBridgeInfill )
return true ;
}
}
return false ;
}
static bool has_bridging_extrusions ( const Layer & layer )
{
for ( const LayerRegion * region : layer . regions ( ) ) {
if ( SupportMaterialInternal : : has_bridging_perimeters ( region - > perimeters ) )
return true ;
if ( region - > fill_surfaces . has ( stBottomBridge ) & & has_bridging_fills ( region - > fills ) )
return true ;
}
return false ;
}
static inline void collect_bridging_perimeter_areas ( const ExtrusionLoop & loop , const float expansion_scaled , Polygons & out )
{
assert ( expansion_scaled > = 0.f ) ;
for ( const ExtrusionPath & ep : loop . paths )
if ( ep . role ( ) = = erOverhangPerimeter & & ! ep . polyline . empty ( ) ) {
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float exp = 0.5f * ( float ) scale_ ( ep . width ) + expansion_scaled ;
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if ( ep . is_closed ( ) ) {
if ( ep . size ( ) > = 3 ) {
// This is a complete loop.
// Add the outer contour first.
Polygon poly ;
poly . points = ep . polyline . points ;
poly . points . pop_back ( ) ;
if ( poly . area ( ) < 0 )
poly . reverse ( ) ;
polygons_append ( out , offset ( poly , exp , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
Polygons holes = offset ( poly , - exp , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ;
polygons_reverse ( holes ) ;
polygons_append ( out , holes ) ;
}
} else if ( ep . size ( ) > = 2 ) {
// Offset the polyline.
polygons_append ( out , offset ( ep . polyline , exp , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
}
}
}
static void collect_bridging_perimeter_areas ( const ExtrusionEntityCollection & perimeters , const float expansion_scaled , Polygons & out )
{
for ( const ExtrusionEntity * ee : perimeters . entities ) {
if ( ee - > is_collection ( ) ) {
for ( const ExtrusionEntity * ee2 : static_cast < const ExtrusionEntityCollection * > ( ee ) - > entities ) {
assert ( ! ee2 - > is_collection ( ) ) ;
if ( ee2 - > is_loop ( ) )
collect_bridging_perimeter_areas ( * static_cast < const ExtrusionLoop * > ( ee2 ) , expansion_scaled , out ) ;
}
} else if ( ee - > is_loop ( ) )
collect_bridging_perimeter_areas ( * static_cast < const ExtrusionLoop * > ( ee ) , expansion_scaled , out ) ;
}
}
static void remove_bridges_from_contacts (
const PrintConfig & print_config ,
const Layer & lower_layer ,
const Polygons & lower_layer_polygons ,
LayerRegion * layerm ,
float fw ,
Polygons & contact_polygons )
{
// compute the area of bridging perimeters
Polygons bridges ;
{
// Surface supporting this layer, expanded by 0.5 * nozzle_diameter, as we consider this kind of overhang to be sufficiently supported.
Polygons lower_grown_slices = offset ( lower_layer_polygons ,
//FIXME to mimic the decision in the perimeter generator, we should use half the external perimeter width.
0.5f * float ( scale_ ( print_config . nozzle_diameter . get_at ( layerm - > region ( ) - > config ( ) . perimeter_extruder - 1 ) ) ) ,
SUPPORT_SURFACES_OFFSET_PARAMETERS ) ;
// Collect perimeters of this layer.
//FIXME split_at_first_point() could split a bridge mid-way
#if 0
Polylines overhang_perimeters = layerm - > perimeters . as_polylines ( ) ;
// workaround for Clipper bug, see Slic3r::Polygon::clip_as_polyline()
for ( Polyline & polyline : overhang_perimeters )
polyline . points [ 0 ] . x + = 1 ;
// Trim the perimeters of this layer by the lower layer to get the unsupported pieces of perimeters.
overhang_perimeters = diff_pl ( overhang_perimeters , lower_grown_slices ) ;
# else
Polylines overhang_perimeters = diff_pl ( layerm - > perimeters . as_polylines ( ) , lower_grown_slices ) ;
# endif
// only consider straight overhangs
// only consider overhangs having endpoints inside layer's slices
// convert bridging polylines into polygons by inflating them with their thickness
// since we're dealing with bridges, we can't assume width is larger than spacing,
// so we take the largest value and also apply safety offset to be ensure no gaps
// are left in between
Flow bridge_flow = layerm - > flow ( frPerimeter , true ) ;
float w = float ( std : : max ( bridge_flow . scaled_width ( ) , bridge_flow . scaled_spacing ( ) ) ) ;
for ( Polyline & polyline : overhang_perimeters )
if ( polyline . is_straight ( ) ) {
// This is a bridge
polyline . extend_start ( fw ) ;
polyline . extend_end ( fw ) ;
// Is the straight perimeter segment supported at both sides?
if ( lower_layer . slices . contains ( polyline . first_point ( ) ) & & lower_layer . slices . contains ( polyline . last_point ( ) ) )
// Offset a polyline into a thick line.
polygons_append ( bridges , offset ( polyline , 0.5f * w + 10.f ) ) ;
}
bridges = union_ ( bridges ) ;
}
// remove the entire bridges and only support the unsupported edges
//FIXME the brided regions are already collected as layerm->bridged. Use it?
for ( const Surface & surface : layerm - > fill_surfaces . surfaces )
if ( surface . surface_type = = stBottomBridge & & surface . bridge_angle ! = - 1 )
polygons_append ( bridges , surface . expolygon ) ;
//FIXME add the gap filled areas. Extrude the gaps with a bridge flow?
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// Remove the unsupported ends of the bridges from the bridged areas.
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//FIXME add supports at regular intervals to support long bridges!
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bridges = diff ( bridges ,
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// Offset unsupported edges into polygons.
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offset ( layerm - > unsupported_bridge_edges . polylines , scale_ ( SUPPORT_MATERIAL_MARGIN ) , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
// Remove bridged areas from the supported areas.
contact_polygons = diff ( contact_polygons , bridges , true ) ;
}
}
#if 0
static int Test ( )
{
// for (int i = 0; i < 30; ++ i)
{
int i = - 1 ;
// SupportGridPattern grid("d:\\temp\\support-top-contacts-final-run1-layer460-z70.300000-prev.bin", i);
// SupportGridPattern grid("d:\\temp\\support-top-contacts-final-run1-layer460-z70.300000.bin", i);
auto grid = SupportGridPattern : : deserialize ( " d: \\ temp \\ support-top-contacts-final-run1-layer27-z5.650000.bin " , i ) ;
std : : vector < std : : pair < EdgeGrid : : Grid : : ContourEdge , EdgeGrid : : Grid : : ContourEdge > > intersections = grid . grid ( ) . intersecting_edges ( ) ;
if ( ! intersections . empty ( ) )
printf ( " Intersections between contours! \n " ) ;
Slic3r : : export_intersections_to_svg ( " d: \\ temp \\ support_polygon_intersections.svg " , grid . support_polygons ( ) ) ;
Slic3r : : SVG : : export_expolygons ( " d: \\ temp \\ support_polygons.svg " , union_ex ( grid . support_polygons ( ) , false ) ) ;
Slic3r : : SVG : : export_expolygons ( " d: \\ temp \\ trimming_polygons.svg " , union_ex ( grid . trimming_polygons ( ) , false ) ) ;
Polygons extracted = grid . extract_support ( scale_ ( 0.21 / 2 ) , true ) ;
Slic3r : : SVG : : export_expolygons ( " d: \\ temp \\ extracted.svg " , union_ex ( extracted , false ) ) ;
printf ( " hu! " ) ;
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}
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return 0 ;
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}
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static int run_support_test = Test ( ) ;
# endif /* SLIC3R_DEBUG */
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// Generate top contact layers supporting overhangs.
// For a soluble interface material synchronize the layer heights with the object, otherwise leave the layer height undefined.
// If supports over bed surface only are requested, don't generate contact layers over an object.
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PrintObjectSupportMaterial : : MyLayersPtr PrintObjectSupportMaterial : : top_contact_layers (
const PrintObject & object , MyLayerStorage & layer_storage ) const
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{
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# ifdef SLIC3R_DEBUG
static int iRun = 0 ;
+ + iRun ;
# endif /* SLIC3R_DEBUG */
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// Slice support enforcers / support blockers.
std : : vector < ExPolygons > enforcers = object . slice_support_enforcers ( ) ;
std : : vector < ExPolygons > blockers = object . slice_support_blockers ( ) ;
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// Output layers, sorted by top Z.
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MyLayersPtr contact_out ;
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const bool support_auto = m_object_config - > support_material_auto . value ;
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// If user specified a custom angle threshold, convert it to radians.
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// Zero means automatic overhang detection.
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const double threshold_rad = ( m_object_config - > support_material_threshold . value > 0 ) ?
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M_PI * double ( m_object_config - > support_material_threshold . value + 1 ) / 180. : // +1 makes the threshold inclusive
0. ;
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// Build support on a build plate only? If so, then collect and union all the surfaces below the current layer.
// Unfortunately this is an inherently serial process.
const bool buildplate_only = this - > build_plate_only ( ) ;
std : : vector < Polygons > buildplate_covered ;
if ( buildplate_only ) {
BOOST_LOG_TRIVIAL ( debug ) < < " PrintObjectSupportMaterial::top_contact_layers() - collecting regions covering the print bed. " ;
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buildplate_covered . assign ( object . layers ( ) . size ( ) , Polygons ( ) ) ;
for ( size_t layer_id = 1 ; layer_id < object . layers ( ) . size ( ) ; + + layer_id ) {
const Layer & lower_layer = * object . layers ( ) [ layer_id - 1 ] ;
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// Merge the new slices with the preceding slices.
// Apply the safety offset to the newly added polygons, so they will connect
// with the polygons collected before,
// but don't apply the safety offset during the union operation as it would
// inflate the polygons over and over.
Polygons & covered = buildplate_covered [ layer_id ] ;
covered = buildplate_covered [ layer_id - 1 ] ;
polygons_append ( covered , offset ( lower_layer . slices . expolygons , scale_ ( 0.01 ) ) ) ;
covered = union_ ( covered , false ) ; // don't apply the safety offset.
}
}
BOOST_LOG_TRIVIAL ( debug ) < < " PrintObjectSupportMaterial::top_contact_layers() in parallel - start " ;
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// Determine top contact areas.
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// If generating raft only (no support), only calculate top contact areas for the 0th layer.
// If having a raft, start with 0th layer, otherwise with 1st layer.
// Note that layer_id < layer->id when raft_layers > 0 as the layer->id incorporates the raft layers.
// So layer_id == 0 means first object layer and layer->id == 0 means first print layer if there are no explicit raft layers.
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size_t num_layers = this - > has_support ( ) ? object . layer_count ( ) : 1 ;
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// For each overhang layer, two supporting layers may be generated: One for the overhangs extruded with a bridging flow,
// and the other for the overhangs extruded with a normal flow.
contact_out . assign ( num_layers * 2 , nullptr ) ;
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tbb : : spin_mutex layer_storage_mutex ;
tbb : : parallel_for ( tbb : : blocked_range < size_t > ( this - > has_raft ( ) ? 0 : 1 , num_layers ) ,
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[ this , & object , & buildplate_covered , & enforcers , & blockers , support_auto , threshold_rad , & layer_storage , & layer_storage_mutex , & contact_out ]
( const tbb : : blocked_range < size_t > & range ) {
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for ( size_t layer_id = range . begin ( ) ; layer_id < range . end ( ) ; + + layer_id )
{
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const Layer & layer = * object . layers ( ) [ layer_id ] ;
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// Detect overhangs and contact areas needed to support them.
// Collect overhangs and contacts of all regions of this layer supported by the layer immediately below.
Polygons overhang_polygons ;
Polygons contact_polygons ;
Polygons slices_margin_cached ;
float slices_margin_cached_offset = - 1. ;
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Polygons lower_layer_polygons = ( layer_id = = 0 ) ? Polygons ( ) : to_polygons ( object . layers ( ) [ layer_id - 1 ] - > slices . expolygons ) ;
// Offset of the lower layer, to trim the support polygons with to calculate dense supports.
float no_interface_offset = 0.f ;
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if ( layer_id = = 0 ) {
// This is the first object layer, so the object is being printed on a raft and
// we're here just to get the object footprint for the raft.
// We only consider contours and discard holes to get a more continuous raft.
overhang_polygons = collect_slices_outer ( layer ) ;
// Extend by SUPPORT_MATERIAL_MARGIN, which is 1.5mm
contact_polygons = offset ( overhang_polygons , scale_ ( SUPPORT_MATERIAL_MARGIN ) ) ;
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} else {
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// Generate overhang / contact_polygons for non-raft layers.
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const Layer & lower_layer = * object . layers ( ) [ layer_id - 1 ] ;
for ( LayerRegion * layerm : layer . regions ( ) ) {
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// Extrusion width accounts for the roundings of the extrudates.
// It is the maximum widh of the extrudate.
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float fw = float ( layerm - > flow ( frExternalPerimeter ) . scaled_width ( ) ) ;
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no_interface_offset = ( no_interface_offset = = 0.f ) ? fw : std : : min ( no_interface_offset , fw ) ;
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float lower_layer_offset =
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( layer_id < ( size_t ) m_object_config - > support_material_enforce_layers . value ) ?
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// Enforce a full possible support, ignore the overhang angle.
0.f :
( threshold_rad > 0. ?
// Overhang defined by an angle.
float ( scale_ ( lower_layer . height / tan ( threshold_rad ) ) ) :
// Overhang defined by half the extrusion width.
0.5f * fw ) ;
// Overhang polygons for this layer and region.
Polygons diff_polygons ;
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Polygons layerm_polygons = to_polygons ( layerm - > slices ) ;
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if ( lower_layer_offset = = 0.f ) {
// Support everything.
diff_polygons = diff ( layerm_polygons , lower_layer_polygons ) ;
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if ( ! buildplate_covered . empty ( ) ) {
// Don't support overhangs above the top surfaces.
// This step is done before the contact surface is calculated by growing the overhang region.
diff_polygons = diff ( diff_polygons , buildplate_covered [ layer_id ] ) ;
}
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} else {
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if ( support_auto ) {
// Get the regions needing a suport, collapse very tiny spots.
//FIXME cache the lower layer offset if this layer has multiple regions.
# if 1
diff_polygons = offset2 (
diff ( layerm_polygons ,
offset2 ( lower_layer_polygons , - 0.5f * fw , lower_layer_offset + 0.5f * fw , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ,
//FIXME This offset2 is targeted to reduce very thin regions to support, but it may lead to
// no support at all for not so steep overhangs.
- 0.1f * fw , 0.1f * fw ) ;
# else
diff_polygons =
diff ( layerm_polygons ,
offset ( lower_layer_polygons , lower_layer_offset , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
# endif
if ( ! buildplate_covered . empty ( ) ) {
// Don't support overhangs above the top surfaces.
// This step is done before the contact surface is calculated by growing the overhang region.
diff_polygons = diff ( diff_polygons , buildplate_covered [ layer_id ] ) ;
}
if ( ! diff_polygons . empty ( ) ) {
// Offset the support regions back to a full overhang, restrict them to the full overhang.
// This is done to increase size of the supporting columns below, as they are calculated by
// propagating these contact surfaces downwards.
diff_polygons = diff (
intersection ( offset ( diff_polygons , lower_layer_offset , SUPPORT_SURFACES_OFFSET_PARAMETERS ) , layerm_polygons ) ,
lower_layer_polygons ) ;
}
}
if ( ! enforcers . empty ( ) ) {
// Apply the "support enforcers".
//FIXME add the "enforcers" to the sparse support regions only.
const ExPolygons & enforcer = enforcers [ layer_id - 1 ] ;
if ( ! enforcer . empty ( ) ) {
// Enforce supports (as if with 90 degrees of slope) for the regions covered by the enforcer meshes.
Polygons new_contacts = diff ( intersection ( layerm_polygons , to_polygons ( enforcer ) ) ,
offset ( lower_layer_polygons , 0.05f * fw , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
if ( ! new_contacts . empty ( ) ) {
if ( diff_polygons . empty ( ) )
diff_polygons = std : : move ( new_contacts ) ;
else
diff_polygons = union_ ( diff_polygons , new_contacts ) ;
}
}
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}
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}
// Apply the "support blockers".
if ( ! diff_polygons . empty ( ) & & ! blockers . empty ( ) & & ! blockers [ layer_id ] . empty ( ) ) {
// Enforce supports (as if with 90 degrees of slope) for the regions covered by the enforcer meshes.
diff_polygons = diff ( diff_polygons , to_polygons ( blockers [ layer_id ] ) ) ;
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}
if ( diff_polygons . empty ( ) )
continue ;
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# ifdef SLIC3R_DEBUG
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{
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: : Slic3r : : SVG svg ( debug_out_path ( " support-top-contacts-raw-run%d-layer%d-region%d.svg " ,
iRun , layer_id ,
std : : find_if ( layer . regions . begin ( ) , layer . regions . end ( ) , [ layerm ] ( const LayerRegion * other ) { return other = = layerm ; } ) - layer . regions . begin ( ) ) ,
get_extents ( diff_polygons ) ) ;
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Slic3r : : ExPolygons expolys = union_ex ( diff_polygons , false ) ;
svg . draw ( expolys ) ;
}
# endif /* SLIC3R_DEBUG */
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if ( this - > m_object_config - > dont_support_bridges )
SupportMaterialInternal : : remove_bridges_from_contacts (
* m_print_config , lower_layer , lower_layer_polygons , layerm , fw , diff_polygons ) ;
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if ( diff_polygons . empty ( ) )
continue ;
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# ifdef SLIC3R_DEBUG
Slic3r : : SVG : : export_expolygons (
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debug_out_path ( " support-top-contacts-filtered-run%d-layer%d-region%d-z%f.svg " ,
iRun , layer_id ,
std : : find_if ( layer . regions . begin ( ) , layer . regions . end ( ) , [ layerm ] ( const LayerRegion * other ) { return other = = layerm ; } ) - layer . regions . begin ( ) ,
layer . print_z ) ,
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union_ex ( diff_polygons , false ) ) ;
# endif /* SLIC3R_DEBUG */
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//FIXME the overhang_polygons are used to construct the support towers as well.
//if (this->has_contact_loops())
// Store the exact contour of the overhang for the contact loops.
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polygons_append ( overhang_polygons , diff_polygons ) ;
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// Let's define the required contact area by using a max gap of half the upper
// extrusion width and extending the area according to the configured margin.
// We increment the area in steps because we don't want our support to overflow
// on the other side of the object (if it's very thin).
{
//FIMXE 1) Make the offset configurable, 2) Make the Z span configurable.
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//FIXME one should trim with the layer span colliding with the support layer, this layer
// may be lower than lower_layer, so the support area needed may need to be actually bigger!
// For the same reason, the non-bridging support area may be smaller than the bridging support area!
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float slices_margin_offset = std : : min ( lower_layer_offset , float ( scale_ ( m_gap_xy ) ) ) ;
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if ( slices_margin_cached_offset ! = slices_margin_offset ) {
slices_margin_cached_offset = slices_margin_offset ;
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slices_margin_cached = ( slices_margin_offset = = 0.f ) ?
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lower_layer_polygons :
offset2 ( to_polygons ( lower_layer . slices . expolygons ) , - no_interface_offset * 0.5f , slices_margin_offset + no_interface_offset * 0.5f , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ;
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if ( ! buildplate_covered . empty ( ) ) {
// Trim the inflated contact surfaces by the top surfaces as well.
polygons_append ( slices_margin_cached , buildplate_covered [ layer_id ] ) ;
slices_margin_cached = union_ ( slices_margin_cached ) ;
}
}
// Offset the contact polygons outside.
for ( size_t i = 0 ; i < NUM_MARGIN_STEPS ; + + i ) {
diff_polygons = diff (
offset (
diff_polygons ,
SUPPORT_MATERIAL_MARGIN / NUM_MARGIN_STEPS ,
ClipperLib : : jtRound ,
// round mitter limit
scale_ ( 0.05 ) ) ,
slices_margin_cached ) ;
}
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}
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polygons_append ( contact_polygons , diff_polygons ) ;
} // for each layer.region
} // end of Generate overhang/contact_polygons for non-raft layers.
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// Now apply the contact areas to the layer where they need to be made.
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if ( ! contact_polygons . empty ( ) ) {
MyLayer & new_layer = layer_allocate ( layer_storage , layer_storage_mutex , sltTopContact ) ;
new_layer . idx_object_layer_above = layer_id ;
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MyLayer * bridging_layer = nullptr ;
if ( layer_id = = 0 ) {
// This is a raft contact layer sitting directly on the print bed.
assert ( this - > has_raft ( ) ) ;
new_layer . print_z = m_slicing_params . raft_contact_top_z ;
new_layer . bottom_z = m_slicing_params . raft_interface_top_z ;
new_layer . height = m_slicing_params . contact_raft_layer_height ;
} else if ( m_slicing_params . soluble_interface ) {
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// Align the contact surface height with a layer immediately below the supported layer.
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// Interface layer will be synchronized with the object.
new_layer . print_z = layer . print_z - layer . height ;
new_layer . height = object . layers ( ) [ layer_id - 1 ] - > height ;
new_layer . bottom_z = ( layer_id = = 1 ) ? m_slicing_params . object_print_z_min : object . layers ( ) [ layer_id - 2 ] - > print_z ;
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} else {
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new_layer . print_z = layer . print_z - layer . height - m_object_config - > support_material_contact_distance ;
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new_layer . bottom_z = new_layer . print_z ;
new_layer . height = 0. ;
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// Ignore this contact area if it's too low.
// Don't want to print a layer below the first layer height as it may not stick well.
//FIXME there may be a need for a single layer support, then one may decide to print it either as a bottom contact or a top contact
// and it may actually make sense to do it with a thinner layer than the first layer height.
if ( new_layer . print_z < m_slicing_params . first_print_layer_height - EPSILON ) {
// This contact layer is below the first layer height, therefore not printable. Don't support this surface.
continue ;
} else if ( new_layer . print_z < m_slicing_params . first_print_layer_height + EPSILON ) {
// Align the layer with the 1st layer height.
new_layer . print_z = m_slicing_params . first_print_layer_height ;
new_layer . bottom_z = 0 ;
new_layer . height = m_slicing_params . first_print_layer_height ;
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} else {
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// Don't know the height of the top contact layer yet. The top contact layer is printed with a normal flow and
// its height will be set adaptively later on.
}
// Contact layer will be printed with a normal flow, but
// it will support layers printed with a bridging flow.
if ( SupportMaterialInternal : : has_bridging_extrusions ( layer ) ) {
coordf_t bridging_height = 0. ;
for ( const LayerRegion * region : layer . regions ( ) )
bridging_height + = region - > region ( ) - > bridging_height_avg ( * m_print_config ) ;
bridging_height / = coordf_t ( layer . regions ( ) . size ( ) ) ;
coordf_t bridging_print_z = layer . print_z - bridging_height - m_object_config - > support_material_contact_distance ;
if ( bridging_print_z > = m_slicing_params . first_print_layer_height - EPSILON ) {
// Not below the first layer height means this layer is printable.
if ( new_layer . print_z < m_slicing_params . first_print_layer_height + EPSILON ) {
// Align the layer with the 1st layer height.
bridging_print_z = m_slicing_params . first_print_layer_height ;
}
if ( bridging_print_z < new_layer . print_z - EPSILON ) {
// Allocate the new layer.
bridging_layer = & layer_allocate ( layer_storage , layer_storage_mutex , sltTopContact ) ;
bridging_layer - > idx_object_layer_above = layer_id ;
bridging_layer - > print_z = bridging_print_z ;
if ( bridging_print_z = = m_slicing_params . first_print_layer_height ) {
bridging_layer - > bottom_z = 0 ;
bridging_layer - > height = m_slicing_params . first_print_layer_height ;
} else {
// Don't know the height yet.
bridging_layer - > bottom_z = bridging_print_z ;
bridging_layer - > height = 0 ;
}
}
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}
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}
}
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// Achtung! The contact_polygons need to be trimmed by slices_margin_cached, otherwise
// the selection by island_samples (see the SupportGridPattern::island_samples() method) will not work!
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SupportGridPattern support_grid_pattern (
// Support islands, to be stretched into a grid.
contact_polygons ,
// Trimming polygons, to trim the stretched support islands.
slices_margin_cached ,
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// Grid resolution.
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m_object_config - > support_material_spacing . value + m_support_material_flow . spacing ( ) ,
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Geometry : : deg2rad ( m_object_config - > support_material_angle . value ) ) ;
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// 1) Contact polygons will be projected down. To keep the interface and base layers from growing, return a contour a tiny bit smaller than the grid cells.
new_layer . contact_polygons = new Polygons ( support_grid_pattern . extract_support ( - 3 , true ) ) ;
// 2) infill polygons, expand them by half the extrusion width + a tiny bit of extra.
if ( layer_id = = 0 | | m_slicing_params . soluble_interface ) {
// if (no_interface_offset == 0.f) {
new_layer . polygons = support_grid_pattern . extract_support ( m_support_material_flow . scaled_spacing ( ) / 2 + 5 , true ) ;
} else {
// Reduce the amount of dense interfaces: Do not generate dense interfaces below overhangs with 60% overhang of the extrusions.
Polygons dense_interface_polygons = diff ( overhang_polygons ,
offset2 ( lower_layer_polygons , - no_interface_offset * 0.5f , no_interface_offset * ( 0.6f + 0.5f ) , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
if ( ! dense_interface_polygons . empty ( ) ) {
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dense_interface_polygons =
// Achtung! The dense_interface_polygons need to be trimmed by slices_margin_cached, otherwise
// the selection by island_samples (see the SupportGridPattern::island_samples() method) will not work!
diff (
// Regularize the contour.
offset ( dense_interface_polygons , no_interface_offset * 0.1f ) ,
slices_margin_cached ) ;
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SupportGridPattern support_grid_pattern (
// Support islands, to be stretched into a grid.
dense_interface_polygons ,
// Trimming polygons, to trim the stretched support islands.
slices_margin_cached ,
// Grid resolution.
m_object_config - > support_material_spacing . value + m_support_material_flow . spacing ( ) ,
Geometry : : deg2rad ( m_object_config - > support_material_angle . value ) ) ;
new_layer . polygons = support_grid_pattern . extract_support ( m_support_material_flow . scaled_spacing ( ) / 2 + 5 , false ) ;
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# ifdef SLIC3R_DEBUG
{
support_grid_pattern . serialize ( debug_out_path ( " support-top-contacts-final-run%d-layer%d-z%f.bin " , iRun , layer_id , layer . print_z ) ) ;
BoundingBox bbox = get_extents ( contact_polygons ) ;
bbox . merge ( get_extents ( new_layer . polygons ) ) ;
: : Slic3r : : SVG svg ( debug_out_path ( " support-top-contacts-final0-run%d-layer%d-z%f.svg " , iRun , layer_id , layer . print_z ) ) ;
svg . draw ( union_ex ( * new_layer . contact_polygons , false ) , " gray " , 0.5f ) ;
svg . draw ( union_ex ( contact_polygons , false ) , " blue " , 0.5f ) ;
svg . draw ( union_ex ( dense_interface_polygons , false ) , " green " , 0.5f ) ;
svg . draw ( union_ex ( new_layer . polygons , true ) , " red " , 0.5f ) ;
svg . draw_outline ( union_ex ( new_layer . polygons , true ) , " black " , " black " , scale_ ( 0.1f ) ) ;
}
# endif /* SLIC3R_DEBUG */
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}
}
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# ifdef SLIC3R_DEBUG
{
BoundingBox bbox = get_extents ( contact_polygons ) ;
bbox . merge ( get_extents ( new_layer . polygons ) ) ;
: : Slic3r : : SVG svg ( debug_out_path ( " support-top-contacts-final-run%d-layer%d-z%f.svg " , iRun , layer_id , layer . print_z ) ) ;
svg . draw ( union_ex ( * new_layer . contact_polygons , false ) , " gray " , 0.5f ) ;
svg . draw ( union_ex ( contact_polygons , false ) , " blue " , 0.5f ) ;
svg . draw ( union_ex ( overhang_polygons , false ) , " green " , 0.5f ) ;
svg . draw ( union_ex ( new_layer . polygons , true ) , " red " , 0.5f ) ;
svg . draw_outline ( union_ex ( new_layer . polygons , true ) , " black " , " black " , scale_ ( 0.1f ) ) ;
}
# endif /* SLIC3R_DEBUG */
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// Even after the contact layer was expanded into a grid, some of the contact islands may be too tiny to be extruded.
// Remove those tiny islands from new_layer.polygons and new_layer.contact_polygons.
// Store the overhang polygons.
// The overhang polygons are used in the path generator for planning of the contact loops.
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// if (this->has_contact_loops()). Compared to "polygons", "overhang_polygons" are snug.
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new_layer . overhang_polygons = new Polygons ( std : : move ( overhang_polygons ) ) ;
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contact_out [ layer_id * 2 ] = & new_layer ;
if ( bridging_layer ! = nullptr ) {
bridging_layer - > polygons = new_layer . polygons ;
bridging_layer - > contact_polygons = new Polygons ( * new_layer . contact_polygons ) ;
bridging_layer - > overhang_polygons = new Polygons ( * new_layer . overhang_polygons ) ;
contact_out [ layer_id * 2 + 1 ] = bridging_layer ;
}
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}
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}
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} ) ;
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// Compress contact_out, remove the nullptr items.
remove_nulls ( contact_out ) ;
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// Sort the layers, as one layer may produce bridging and non-bridging contact layers with different print_z.
std : : sort ( contact_out . begin ( ) , contact_out . end ( ) , [ ] ( const MyLayer * l1 , const MyLayer * l2 ) { return l1 - > print_z < l2 - > print_z ; } ) ;
// Merge close contact layers conservatively: If two layers are closer than the minimum allowed print layer height (the min_layer_height parameter),
// the top contact layer is merged into the bottom contact layer.
{
int i = 0 ;
int k = 0 ;
{
// Find the span of layers, which are to be printed at the first layer height.
int j = 0 ;
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for ( ; j < ( int ) contact_out . size ( ) & & contact_out [ j ] - > print_z < m_slicing_params . first_print_layer_height + this - > m_support_layer_height_min - EPSILON ; + + j ) ;
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if ( j > 0 ) {
// Merge the contact_out layers (0) to (j - 1) into the contact_out[0].
MyLayer & dst = * contact_out . front ( ) ;
for ( int u = 1 ; u < j ; + + u ) {
MyLayer & src = * contact_out [ u ] ;
// The union_() does not support move semantic yet, but maybe one day it will.
dst . polygons = union_ ( dst . polygons , std : : move ( src . polygons ) ) ;
* dst . contact_polygons = union_ ( * dst . contact_polygons , std : : move ( * src . contact_polygons ) ) ;
* dst . overhang_polygons = union_ ( * dst . overhang_polygons , std : : move ( * src . overhang_polygons ) ) ;
// Source polygon is no more needed, it will not be refrenced. Release its data.
src . reset ( ) ;
}
// Snap the first layer to the 1st layer height.
dst . print_z = m_slicing_params . first_print_layer_height ;
dst . height = m_slicing_params . first_print_layer_height ;
dst . bottom_z = 0 ;
+ + k ;
}
i = j ;
}
for ( ; i < int ( contact_out . size ( ) ) ; + + k ) {
// Find the span of layers closer than m_support_layer_height_min.
int j = i + 1 ;
coordf_t zmax = contact_out [ i ] - > print_z + m_support_layer_height_min + EPSILON ;
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for ( ; j < ( int ) contact_out . size ( ) & & contact_out [ j ] - > print_z < zmax ; + + j ) ;
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if ( i + 1 < j ) {
// Merge the contact_out layers (i + 1) to (j - 1) into the contact_out[i].
MyLayer & dst = * contact_out [ i ] ;
for ( int u = i + 1 ; u < j ; + + u ) {
MyLayer & src = * contact_out [ u ] ;
// The union_() does not support move semantic yet, but maybe one day it will.
dst . polygons = union_ ( dst . polygons , std : : move ( src . polygons ) ) ;
* dst . contact_polygons = union_ ( * dst . contact_polygons , std : : move ( * src . contact_polygons ) ) ;
* dst . overhang_polygons = union_ ( * dst . overhang_polygons , std : : move ( * src . overhang_polygons ) ) ;
// Source polygon is no more needed, it will not be refrenced. Release its data.
src . reset ( ) ;
}
}
if ( k < i )
contact_out [ k ] = contact_out [ i ] ;
i = j ;
}
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if ( k < ( int ) contact_out . size ( ) )
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contact_out . erase ( contact_out . begin ( ) + k , contact_out . end ( ) ) ;
}
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BOOST_LOG_TRIVIAL ( debug ) < < " PrintObjectSupportMaterial::top_contact_layers() in parallel - end " ;
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return contact_out ;
}
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// Generate bottom contact layers supporting the top contact layers.
// For a soluble interface material synchronize the layer heights with the object,
// otherwise set the layer height to a bridging flow of a support interface nozzle.
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PrintObjectSupportMaterial : : MyLayersPtr PrintObjectSupportMaterial : : bottom_contact_layers_and_layer_support_areas (
const PrintObject & object , const MyLayersPtr & top_contacts , MyLayerStorage & layer_storage ,
std : : vector < Polygons > & layer_support_areas ) const
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{
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# ifdef SLIC3R_DEBUG
static int iRun = 0 ;
+ + iRun ;
# endif /* SLIC3R_DEBUG */
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// Allocate empty surface areas, one per object layer.
layer_support_areas . assign ( object . total_layer_count ( ) , Polygons ( ) ) ;
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// find object top surfaces
// we'll use them to clip our support and detect where does it stick
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MyLayersPtr bottom_contacts ;
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if ( ! top_contacts . empty ( ) )
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{
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// There is some support to be built, if there are non-empty top surfaces detected.
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// Sum of unsupported contact areas above the current layer.print_z.
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Polygons projection ;
// Last top contact layer visited when collecting the projection of contact areas.
int contact_idx = int ( top_contacts . size ( ) ) - 1 ;
for ( int layer_id = int ( object . total_layer_count ( ) ) - 2 ; layer_id > = 0 ; - - layer_id ) {
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BOOST_LOG_TRIVIAL ( trace ) < < " Support generator - bottom_contact_layers - layer " < < layer_id ;
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const Layer & layer = * object . get_layer ( layer_id ) ;
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// Collect projections of all contact areas above or at the same level as this top surface.
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for ( ; contact_idx > = 0 & & top_contacts [ contact_idx ] - > print_z > layer . print_z - EPSILON ; - - contact_idx ) {
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Polygons polygons_new ;
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// Contact surfaces are expanded away from the object, trimmed by the object.
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// Use a slight positive offset to overlap the touching regions.
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#if 0
// Merge and collect the contact polygons. The contact polygons are inflated, but not extended into a grid form.
polygons_append ( polygons_new , offset ( * top_contacts [ contact_idx ] - > contact_polygons , SCALED_EPSILON ) ) ;
# else
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// Consume the contact_polygons. The contact polygons are already expanded into a grid form, and they are a tiny bit smaller
// than the grid cells.
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polygons_append ( polygons_new , std : : move ( * top_contacts [ contact_idx ] - > contact_polygons ) ) ;
# endif
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// These are the overhang surfaces. They are touching the object and they are not expanded away from the object.
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// Use a slight positive offset to overlap the touching regions.
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polygons_append ( polygons_new , offset ( * top_contacts [ contact_idx ] - > overhang_polygons , float ( SCALED_EPSILON ) ) ) ;
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polygons_append ( projection , union_ ( polygons_new ) ) ;
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}
if ( projection . empty ( ) )
continue ;
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Polygons projection_raw = union_ ( projection ) ;
tbb : : task_group task_group ;
if ( ! m_object_config - > support_material_buildplate_only )
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// Find the bottom contact layers above the top surfaces of this layer.
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task_group . run ( [ this , & object , & top_contacts , contact_idx , & layer , layer_id , & layer_storage , & layer_support_areas , & bottom_contacts , & projection_raw ] {
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Polygons top = collect_region_slices_by_type ( layer , stTop ) ;
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# ifdef SLIC3R_DEBUG
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{
BoundingBox bbox = get_extents ( projection_raw ) ;
bbox . merge ( get_extents ( top ) ) ;
: : Slic3r : : SVG svg ( debug_out_path ( " support-bottom-layers-raw-%d-%lf.svg " , iRun , layer . print_z ) , bbox ) ;
svg . draw ( union_ex ( top , false ) , " blue " , 0.5f ) ;
svg . draw ( union_ex ( projection_raw , true ) , " red " , 0.5f ) ;
svg . draw_outline ( union_ex ( projection_raw , true ) , " red " , " blue " , scale_ ( 0.1f ) ) ;
svg . draw ( layer . slices . expolygons , " green " , 0.5f ) ;
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}
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# endif /* SLIC3R_DEBUG */
// Now find whether any projection of the contact surfaces above layer.print_z not yet supported by any
// top surfaces above layer.print_z falls onto this top surface.
// Touching are the contact surfaces supported exclusively by this top surfaces.
// Don't use a safety offset as it has been applied during insertion of polygons.
if ( ! top . empty ( ) ) {
Polygons touching = intersection ( top , projection_raw , false ) ;
if ( ! touching . empty ( ) ) {
// Allocate a new bottom contact layer.
MyLayer & layer_new = layer_allocate ( layer_storage , sltBottomContact ) ;
bottom_contacts . push_back ( & layer_new ) ;
// Grow top surfaces so that interface and support generation are generated
// with some spacing from object - it looks we don't need the actual
// top shapes so this can be done here
2018-09-17 13:12:13 +00:00
//FIXME calculate layer height based on the actual thickness of the layer:
// If the layer is extruded with no bridging flow, support just the normal extrusions.
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layer_new . height = m_slicing_params . soluble_interface ?
// Align the interface layer with the object's layer height.
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object . layers ( ) [ layer_id + 1 ] - > height :
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// Place a bridge flow interface layer over the top surface.
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//FIXME Check whether the bottom bridging surfaces are extruded correctly (no bridging flow correction applied?)
// According to Jindrich the bottom surfaces work well.
//FIXME test the bridging flow instead?
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m_support_material_interface_flow . nozzle_diameter ;
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layer_new . print_z = m_slicing_params . soluble_interface ? object . layers ( ) [ layer_id + 1 ] - > print_z :
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layer . print_z + layer_new . height + m_object_config - > support_material_contact_distance . value ;
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layer_new . bottom_z = layer . print_z ;
layer_new . idx_object_layer_below = layer_id ;
layer_new . bridging = ! m_slicing_params . soluble_interface ;
2018-09-17 13:12:13 +00:00
//FIXME how much to inflate the bottom surface, as it is being extruded with a bridging flow? The following line uses a normal flow.
//FIXME why is the offset positive? It will be trimmed by the object later on anyway, but then it just wastes CPU clocks.
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layer_new . polygons = offset ( touching , float ( m_support_material_flow . scaled_width ( ) ) , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ;
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if ( ! m_slicing_params . soluble_interface ) {
// Walk the top surfaces, snap the top of the new bottom surface to the closest top of the top surface,
// so there will be no support surfaces generated with thickness lower than m_support_layer_height_min.
for ( size_t top_idx = size_t ( std : : max < int > ( 0 , contact_idx ) ) ;
2018-09-17 13:12:13 +00:00
top_idx < top_contacts . size ( ) & & top_contacts [ top_idx ] - > print_z < layer_new . print_z + this - > m_support_layer_height_min + EPSILON ;
2017-05-12 09:18:32 +00:00
+ + top_idx ) {
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if ( top_contacts [ top_idx ] - > print_z > layer_new . print_z - this - > m_support_layer_height_min - EPSILON ) {
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// A top layer has been found, which is close to the new bottom layer.
coordf_t diff = layer_new . print_z - top_contacts [ top_idx ] - > print_z ;
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assert ( std : : abs ( diff ) < = this - > m_support_layer_height_min + EPSILON ) ;
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if ( diff > 0. ) {
// The top contact layer is below this layer. Make the bridging layer thinner to align with the existing top layer.
assert ( diff < layer_new . height + EPSILON ) ;
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assert ( layer_new . height - diff > = m_support_layer_height_min - EPSILON ) ;
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layer_new . print_z = top_contacts [ top_idx ] - > print_z ;
layer_new . height - = diff ;
} else {
// The top contact layer is above this layer. One may either make this layer thicker or thinner.
// By making the layer thicker, one will decrease the number of discrete layers with the price of extruding a bit too thick bridges.
// By making the layer thinner, one adds one more discrete layer.
layer_new . print_z = top_contacts [ top_idx ] - > print_z ;
layer_new . height - = diff ;
}
break ;
}
}
}
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# ifdef SLIC3R_DEBUG
Slic3r : : SVG : : export_expolygons (
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debug_out_path ( " support-bottom-contacts-%d-%lf.svg " , iRun , layer_new . print_z ) ,
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union_ex ( layer_new . polygons , false ) ) ;
# endif /* SLIC3R_DEBUG */
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// Trim the already created base layers above the current layer intersecting with the new bottom contacts layer.
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//FIXME Maybe this is no more needed, as the overlapping base layers are trimmed by the bottom layers at the final stage?
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touching = offset ( touching , float ( SCALED_EPSILON ) ) ;
for ( int layer_id_above = layer_id + 1 ; layer_id_above < int ( object . total_layer_count ( ) ) ; + + layer_id_above ) {
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const Layer & layer_above = * object . layers ( ) [ layer_id_above ] ;
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if ( layer_above . print_z > layer_new . print_z - EPSILON )
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break ;
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if ( ! layer_support_areas [ layer_id_above ] . empty ( ) ) {
# ifdef SLIC3R_DEBUG
{
BoundingBox bbox = get_extents ( touching ) ;
bbox . merge ( get_extents ( layer_support_areas [ layer_id_above ] ) ) ;
: : Slic3r : : SVG svg ( debug_out_path ( " support-support-areas-raw-before-trimming-%d-with-%f-%lf.svg " , iRun , layer . print_z , layer_above . print_z ) , bbox ) ;
svg . draw ( union_ex ( touching , false ) , " blue " , 0.5f ) ;
svg . draw ( union_ex ( layer_support_areas [ layer_id_above ] , true ) , " red " , 0.5f ) ;
svg . draw_outline ( union_ex ( layer_support_areas [ layer_id_above ] , true ) , " red " , " blue " , scale_ ( 0.1f ) ) ;
}
# endif /* SLIC3R_DEBUG */
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layer_support_areas [ layer_id_above ] = diff ( layer_support_areas [ layer_id_above ] , touching ) ;
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# ifdef SLIC3R_DEBUG
Slic3r : : SVG : : export_expolygons (
debug_out_path ( " support-support-areas-raw-after-trimming-%d-with-%f-%lf.svg " , iRun , layer . print_z , layer_above . print_z ) ,
union_ex ( layer_support_areas [ layer_id_above ] , false ) ) ;
# endif /* SLIC3R_DEBUG */
}
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}
}
} // ! top.empty()
} ) ;
Polygons & layer_support_area = layer_support_areas [ layer_id ] ;
task_group . run ( [ this , & projection , & projection_raw , & layer , & layer_support_area , layer_id ] {
// Remove the areas that touched from the projection that will continue on next, lower, top surfaces.
// Polygons trimming = union_(to_polygons(layer.slices.expolygons), touching, true);
Polygons trimming = offset ( layer . slices . expolygons , float ( SCALED_EPSILON ) ) ;
projection = diff ( projection_raw , trimming , false ) ;
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# ifdef SLIC3R_DEBUG
{
BoundingBox bbox = get_extents ( projection_raw ) ;
bbox . merge ( get_extents ( trimming ) ) ;
: : Slic3r : : SVG svg ( debug_out_path ( " support-support-areas-raw-%d-%lf.svg " , iRun , layer . print_z ) , bbox ) ;
svg . draw ( union_ex ( trimming , false ) , " blue " , 0.5f ) ;
svg . draw ( union_ex ( projection , true ) , " red " , 0.5f ) ;
svg . draw_outline ( union_ex ( projection , true ) , " red " , " blue " , scale_ ( 0.1f ) ) ;
}
# endif /* SLIC3R_DEBUG */
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remove_sticks ( projection ) ;
remove_degenerate ( projection ) ;
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# ifdef SLIC3R_DEBUG
Slic3r : : SVG : : export_expolygons (
debug_out_path ( " support-support-areas-raw-cleaned-%d-%lf.svg " , iRun , layer . print_z ) ,
union_ex ( projection , false ) ) ;
# endif /* SLIC3R_DEBUG */
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SupportGridPattern support_grid_pattern (
// Support islands, to be stretched into a grid.
projection ,
// Trimming polygons, to trim the stretched support islands.
trimming ,
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// Grid spacing.
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m_object_config - > support_material_spacing . value + m_support_material_flow . spacing ( ) ,
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Geometry : : deg2rad ( m_object_config - > support_material_angle . value ) ) ;
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tbb : : task_group task_group_inner ;
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// 1) Cache the slice of a support volume. The support volume is expanded by 1/2 of support material flow spacing
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// to allow a placement of suppot zig-zag snake along the grid lines.
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task_group_inner . run ( [ this , & support_grid_pattern , & layer_support_area
# ifdef SLIC3R_DEBUG
, & layer
# endif /* SLIC3R_DEBUG */
] {
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layer_support_area = support_grid_pattern . extract_support ( m_support_material_flow . scaled_spacing ( ) / 2 + 25 , true ) ;
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# ifdef SLIC3R_DEBUG
Slic3r : : SVG : : export_expolygons (
debug_out_path ( " support-layer_support_area-gridded-%d-%lf.svg " , iRun , layer . print_z ) ,
union_ex ( layer_support_area , false ) ) ;
# endif /* SLIC3R_DEBUG */
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} ) ;
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// 2) Support polygons will be projected down. To keep the interface and base layers from growing, return a contour a tiny bit smaller than the grid cells.
Polygons projection_new ;
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task_group_inner . run ( [ & projection_new , & support_grid_pattern
# ifdef SLIC3R_DEBUG
, & layer
# endif /* SLIC3R_DEBUG */
] {
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projection_new = support_grid_pattern . extract_support ( - 5 , true ) ;
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# ifdef SLIC3R_DEBUG
Slic3r : : SVG : : export_expolygons (
debug_out_path ( " support-projection_new-gridded-%d-%lf.svg " , iRun , layer . print_z ) ,
union_ex ( projection_new , false ) ) ;
# endif /* SLIC3R_DEBUG */
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} ) ;
task_group_inner . wait ( ) ;
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projection = std : : move ( projection_new ) ;
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} ) ;
task_group . wait ( ) ;
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}
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std : : reverse ( bottom_contacts . begin ( ) , bottom_contacts . end ( ) ) ;
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// trim_support_layers_by_object(object, bottom_contacts, 0., 0., m_gap_xy);
trim_support_layers_by_object ( object , bottom_contacts ,
m_slicing_params . soluble_interface ? 0. : m_object_config - > support_material_contact_distance . value ,
m_slicing_params . soluble_interface ? 0. : m_object_config - > support_material_contact_distance . value , m_gap_xy ) ;
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} // ! top_contacts.empty()
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return bottom_contacts ;
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}
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// FN_HIGHER_EQUAL: the provided object pointer has a Z value >= of an internal threshold.
// Find the first item with Z value >= of an internal threshold of fn_higher_equal.
// If no vec item with Z value >= of an internal threshold of fn_higher_equal is found, return vec.size()
// If the initial idx is size_t(-1), then use binary search.
// Otherwise search linearly upwards.
template < typename T , typename FN_HIGHER_EQUAL >
size_t idx_higher_or_equal ( const std : : vector < T * > & vec , size_t idx , FN_HIGHER_EQUAL fn_higher_equal )
{
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if ( vec . empty ( ) ) {
idx = 0 ;
} else if ( idx = = size_t ( - 1 ) ) {
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// First of the batch of layers per thread pool invocation. Use binary search.
int idx_low = 0 ;
int idx_high = std : : max ( 0 , int ( vec . size ( ) ) - 1 ) ;
while ( idx_low + 1 < idx_high ) {
int idx_mid = ( idx_low + idx_high ) / 2 ;
if ( fn_higher_equal ( vec [ idx_mid ] ) )
idx_high = idx_mid ;
else
idx_low = idx_mid ;
}
idx = fn_higher_equal ( vec [ idx_low ] ) ? idx_low :
( fn_higher_equal ( vec [ idx_high ] ) ? idx_high : vec . size ( ) ) ;
} else {
// For the other layers of this batch of layers, search incrementally, which is cheaper than the binary search.
while ( idx < vec . size ( ) & & ! fn_higher_equal ( vec [ idx ] ) )
+ + idx ;
}
return idx ;
}
// FN_LOWER_EQUAL: the provided object pointer has a Z value <= of an internal threshold.
// Find the first item with Z value <= of an internal threshold of fn_lower_equal.
// If no vec item with Z value <= of an internal threshold of fn_lower_equal is found, return -1.
// If the initial idx is < -1, then use binary search.
// Otherwise search linearly downwards.
template < typename T , typename FN_LOWER_EQUAL >
int idx_lower_or_equal ( const std : : vector < T * > & vec , int idx , FN_LOWER_EQUAL fn_lower_equal )
{
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if ( vec . empty ( ) ) {
idx = - 1 ;
} else if ( idx < - 1 ) {
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// First of the batch of layers per thread pool invocation. Use binary search.
int idx_low = 0 ;
int idx_high = std : : max ( 0 , int ( vec . size ( ) ) - 1 ) ;
while ( idx_low + 1 < idx_high ) {
int idx_mid = ( idx_low + idx_high ) / 2 ;
if ( fn_lower_equal ( vec [ idx_mid ] ) )
idx_low = idx_mid ;
else
idx_high = idx_mid ;
}
idx = fn_lower_equal ( vec [ idx_high ] ) ? idx_high :
( fn_lower_equal ( vec [ idx_low ] ) ? idx_low : - 1 ) ;
} else {
// For the other layers of this batch of layers, search incrementally, which is cheaper than the binary search.
while ( idx > = 0 & & ! fn_lower_equal ( vec [ idx ] ) )
- - idx ;
}
return idx ;
}
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// Trim the top_contacts layers with the bottom_contacts layers if they overlap, so there would not be enough vertical space for both of them.
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void PrintObjectSupportMaterial : : trim_top_contacts_by_bottom_contacts (
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const PrintObject & object , const MyLayersPtr & bottom_contacts , MyLayersPtr & top_contacts ) const
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{
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tbb : : parallel_for ( tbb : : blocked_range < int > ( 0 , int ( top_contacts . size ( ) ) ) ,
[ this , & object , & bottom_contacts , & top_contacts ] ( const tbb : : blocked_range < int > & range ) {
int idx_bottom_overlapping_first = - 2 ;
// For all top contact layers, counting downwards due to the way idx_higher_or_equal caches the last index to avoid repeated binary search.
for ( int idx_top = range . end ( ) - 1 ; idx_top > = range . begin ( ) ; - - idx_top ) {
MyLayer & layer_top = * top_contacts [ idx_top ] ;
// Find the first bottom layer overlapping with layer_top.
idx_bottom_overlapping_first = idx_lower_or_equal ( bottom_contacts , idx_bottom_overlapping_first , [ & layer_top ] ( const MyLayer * layer_bottom ) { return layer_bottom - > bottom_print_z ( ) - EPSILON < = layer_top . bottom_z ; } ) ;
// For all top contact layers overlapping with the thick bottom contact layer:
for ( int idx_bottom_overlapping = idx_bottom_overlapping_first ; idx_bottom_overlapping > = 0 ; - - idx_bottom_overlapping ) {
const MyLayer & layer_bottom = * bottom_contacts [ idx_bottom_overlapping ] ;
assert ( layer_bottom . bottom_print_z ( ) - EPSILON < = layer_top . bottom_z ) ;
if ( layer_top . print_z < layer_bottom . print_z + EPSILON ) {
// Layers overlap. Trim layer_top with layer_bottom.
layer_top . polygons = diff ( layer_top . polygons , layer_bottom . polygons ) ;
} else
break ;
}
}
} ) ;
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}
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PrintObjectSupportMaterial : : MyLayersPtr PrintObjectSupportMaterial : : raft_and_intermediate_support_layers (
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const PrintObject & object ,
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const MyLayersPtr & bottom_contacts ,
const MyLayersPtr & top_contacts ,
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MyLayerStorage & layer_storage ) const
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{
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MyLayersPtr intermediate_layers ;
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// Collect and sort the extremes (bottoms of the top contacts and tops of the bottom contacts).
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MyLayersPtr extremes ;
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extremes . reserve ( top_contacts . size ( ) + bottom_contacts . size ( ) ) ;
for ( size_t i = 0 ; i < top_contacts . size ( ) ; + + i )
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// Bottoms of the top contact layers. In case of non-soluble supports,
// the top contact layer thickness is not known yet.
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extremes . push_back ( top_contacts [ i ] ) ;
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for ( size_t i = 0 ; i < bottom_contacts . size ( ) ; + + i )
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// Tops of the bottom contact layers.
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extremes . push_back ( bottom_contacts [ i ] ) ;
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if ( extremes . empty ( ) )
return intermediate_layers ;
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auto layer_extreme_lower = [ ] ( const MyLayer * l1 , const MyLayer * l2 ) {
coordf_t z1 = l1 - > extreme_z ( ) ;
coordf_t z2 = l2 - > extreme_z ( ) ;
// If the layers are aligned, return the top contact surface first.
return z1 < z2 | | ( z1 = = z2 & & l1 - > layer_type = = PrintObjectSupportMaterial : : sltTopContact & & l2 - > layer_type = = PrintObjectSupportMaterial : : sltBottomContact ) ;
} ;
std : : sort ( extremes . begin ( ) , extremes . end ( ) , layer_extreme_lower ) ;
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assert ( extremes . empty ( ) | |
( extremes . front ( ) - > extreme_z ( ) > m_slicing_params . raft_interface_top_z - EPSILON & &
( m_slicing_params . raft_layers ( ) = = 1 | | // only raft contact layer
extremes . front ( ) - > layer_type = = sltTopContact | | // first extreme is a top contact layer
extremes . front ( ) - > extreme_z ( ) > m_slicing_params . first_print_layer_height - EPSILON ) ) ) ;
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bool synchronize = this - > synchronize_layers ( ) ;
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# ifdef _DEBUG
// Verify that the extremes are separated by m_support_layer_height_min.
for ( size_t i = 1 ; i < extremes . size ( ) ; + + i ) {
assert ( extremes [ i ] - > extreme_z ( ) - extremes [ i - 1 ] - > extreme_z ( ) = = 0. | |
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extremes [ i ] - > extreme_z ( ) - extremes [ i - 1 ] - > extreme_z ( ) > m_support_layer_height_min - EPSILON ) ;
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assert ( extremes [ i ] - > extreme_z ( ) - extremes [ i - 1 ] - > extreme_z ( ) > 0. | |
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extremes [ i ] - > layer_type = = extremes [ i - 1 ] - > layer_type | |
( extremes [ i ] - > layer_type = = sltBottomContact & & extremes [ i - 1 ] - > layer_type = = sltTopContact ) ) ;
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}
# endif
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// Generate intermediate layers.
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// The first intermediate layer is the same as the 1st layer if there is no raft,
// or the bottom of the first intermediate layer is aligned with the bottom of the raft contact layer.
// Intermediate layers are always printed with a normal etrusion flow (non-bridging).
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size_t idx_layer_object = 0 ;
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for ( size_t idx_extreme = 0 ; idx_extreme < extremes . size ( ) ; + + idx_extreme ) {
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MyLayer * extr2 = extremes [ idx_extreme ] ;
coordf_t extr2z = extr2 - > extreme_z ( ) ;
if ( std : : abs ( extr2z - m_slicing_params . raft_interface_top_z ) < EPSILON ) {
// This is a raft contact layer, its height has been decided in this->top_contact_layers().
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assert ( extr2 - > layer_type = = sltTopContact ) ;
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continue ;
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}
if ( std : : abs ( extr2z - m_slicing_params . first_print_layer_height ) < EPSILON ) {
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// This is a bottom of a synchronized (or soluble) top contact layer, its height has been decided in this->top_contact_layers().
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assert ( extr2 - > layer_type = = sltTopContact ) ;
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assert ( extr2 - > bottom_z = = m_slicing_params . first_print_layer_height ) ;
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assert ( extr2 - > print_z > = m_slicing_params . first_print_layer_height + m_support_layer_height_min - EPSILON ) ;
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if ( intermediate_layers . empty ( ) | | intermediate_layers . back ( ) - > print_z < m_slicing_params . first_print_layer_height ) {
MyLayer & layer_new = layer_allocate ( layer_storage , sltIntermediate ) ;
layer_new . bottom_z = 0. ;
layer_new . print_z = m_slicing_params . first_print_layer_height ;
layer_new . height = m_slicing_params . first_print_layer_height ;
intermediate_layers . push_back ( & layer_new ) ;
}
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continue ;
}
assert ( extr2z > = m_slicing_params . raft_interface_top_z + EPSILON ) ;
assert ( extr2z > = m_slicing_params . first_print_layer_height + EPSILON ) ;
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MyLayer * extr1 = ( idx_extreme = = 0 ) ? nullptr : extremes [ idx_extreme - 1 ] ;
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// Fuse a support layer firmly to the raft top interface (not to the raft contacts).
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coordf_t extr1z = ( extr1 = = nullptr ) ? m_slicing_params . raft_interface_top_z : extr1 - > extreme_z ( ) ;
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assert ( extr2z > = extr1z ) ;
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assert ( extr2z > extr1z | | ( extr1 ! = nullptr & & extr2 - > layer_type = = sltBottomContact ) ) ;
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if ( std : : abs ( extr1z ) < EPSILON ) {
// This layer interval starts with the 1st layer. Print the 1st layer using the prescribed 1st layer thickness.
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assert ( ! m_slicing_params . has_raft ( ) ) ;
assert ( intermediate_layers . empty ( ) | | intermediate_layers . back ( ) - > print_z < = m_slicing_params . first_print_layer_height ) ;
// At this point only layers above first_print_layer_heigth + EPSILON are expected as the other cases were captured earlier.
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assert ( extr2z > = m_slicing_params . first_print_layer_height + EPSILON ) ;
// Generate a new intermediate layer.
MyLayer & layer_new = layer_allocate ( layer_storage , sltIntermediate ) ;
layer_new . bottom_z = 0. ;
layer_new . print_z = extr1z = m_slicing_params . first_print_layer_height ;
layer_new . height = extr1z ;
intermediate_layers . push_back ( & layer_new ) ;
// Continue printing the other layers up to extr2z.
}
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coordf_t dist = extr2z - extr1z ;
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assert ( dist > = 0. ) ;
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if ( dist = = 0. )
continue ;
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// The new layers shall be at least m_support_layer_height_min thick.
assert ( dist > = m_support_layer_height_min - EPSILON ) ;
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if ( synchronize ) {
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// Emit support layers synchronized with the object layers.
// Find the first object layer, which has its print_z in this support Z range.
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while ( idx_layer_object < object . layers ( ) . size ( ) & & object . layers ( ) [ idx_layer_object ] - > print_z < extr1z + EPSILON )
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+ + idx_layer_object ;
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if ( idx_layer_object = = 0 & & extr1z = = m_slicing_params . raft_interface_top_z ) {
// Insert one base support layer below the object.
MyLayer & layer_new = layer_allocate ( layer_storage , sltIntermediate ) ;
layer_new . print_z = m_slicing_params . object_print_z_min ;
layer_new . bottom_z = m_slicing_params . raft_interface_top_z ;
layer_new . height = layer_new . print_z - layer_new . bottom_z ;
intermediate_layers . push_back ( & layer_new ) ;
}
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// Emit all intermediate support layers synchronized with object layers up to extr2z.
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for ( ; idx_layer_object < object . layers ( ) . size ( ) & & object . layers ( ) [ idx_layer_object ] - > print_z < extr2z + EPSILON ; + + idx_layer_object ) {
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MyLayer & layer_new = layer_allocate ( layer_storage , sltIntermediate ) ;
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layer_new . print_z = object . layers ( ) [ idx_layer_object ] - > print_z ;
layer_new . height = object . layers ( ) [ idx_layer_object ] - > height ;
layer_new . bottom_z = ( idx_layer_object > 0 ) ? object . layers ( ) [ idx_layer_object - 1 ] - > print_z : ( layer_new . print_z - layer_new . height ) ;
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assert ( intermediate_layers . empty ( ) | | intermediate_layers . back ( ) - > print_z < layer_new . print_z + EPSILON ) ;
intermediate_layers . push_back ( & layer_new ) ;
}
} else {
// Insert intermediate layers.
size_t n_layers_extra = size_t ( ceil ( dist / m_slicing_params . max_suport_layer_height ) ) ;
assert ( n_layers_extra > 0 ) ;
coordf_t step = dist / coordf_t ( n_layers_extra ) ;
if ( extr1 ! = nullptr & & extr1 - > layer_type = = sltTopContact & &
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extr1 - > print_z + m_support_layer_height_min > extr1 - > bottom_z + step ) {
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// The bottom extreme is a bottom of a top surface. Ensure that the gap
// between the 1st intermediate layer print_z and extr1->print_z is not too small.
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assert ( extr1 - > bottom_z + m_support_layer_height_min < extr1 - > print_z + EPSILON ) ;
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// Generate the first intermediate layer.
MyLayer & layer_new = layer_allocate ( layer_storage , sltIntermediate ) ;
layer_new . bottom_z = extr1 - > bottom_z ;
layer_new . print_z = extr1z = extr1 - > print_z ;
layer_new . height = extr1 - > height ;
intermediate_layers . push_back ( & layer_new ) ;
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dist = extr2z - extr1z ;
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n_layers_extra = size_t ( ceil ( dist / m_slicing_params . max_suport_layer_height ) ) ;
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if ( n_layers_extra = = 0 )
continue ;
// Continue printing the other layers up to extr2z.
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step = dist / coordf_t ( n_layers_extra ) ;
}
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if ( ! m_slicing_params . soluble_interface & & extr2 - > layer_type = = sltTopContact ) {
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// This is a top interface layer, which does not have a height assigned yet. Do it now.
assert ( extr2 - > height = = 0. ) ;
assert ( extr1z > m_slicing_params . first_print_layer_height - EPSILON ) ;
extr2 - > height = step ;
extr2 - > bottom_z = extr2z = extr2 - > print_z - step ;
if ( - - n_layers_extra = = 0 )
continue ;
}
coordf_t extr2z_large_steps = extr2z ;
// Take the largest allowed step in the Z axis until extr2z_large_steps is reached.
for ( size_t i = 0 ; i < n_layers_extra ; + + i ) {
MyLayer & layer_new = layer_allocate ( layer_storage , sltIntermediate ) ;
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if ( i + 1 = = n_layers_extra ) {
// Last intermediate layer added. Align the last entered layer with extr2z_large_steps exactly.
layer_new . bottom_z = ( i = = 0 ) ? extr1z : intermediate_layers . back ( ) - > print_z ;
layer_new . print_z = extr2z_large_steps ;
layer_new . height = layer_new . print_z - layer_new . bottom_z ;
}
else {
// Intermediate layer, not the last added.
layer_new . height = step ;
layer_new . bottom_z = extr1z + i * step ;
layer_new . print_z = layer_new . bottom_z + step ;
}
assert ( intermediate_layers . empty ( ) | | intermediate_layers . back ( ) - > print_z < = layer_new . print_z ) ;
intermediate_layers . push_back ( & layer_new ) ;
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}
}
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}
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# ifdef _DEBUG
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for ( size_t i = 0 ; i < top_contacts . size ( ) ; + + i )
assert ( top_contacts [ i ] - > height > 0. ) ;
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# endif /* _DEBUG */
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return intermediate_layers ;
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}
// At this stage there shall be intermediate_layers allocated between bottom_contacts and top_contacts, but they have no polygons assigned.
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// Also the bottom/top_contacts shall have a layer thickness assigned already.
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void PrintObjectSupportMaterial : : generate_base_layers (
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const PrintObject & object ,
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const MyLayersPtr & bottom_contacts ,
const MyLayersPtr & top_contacts ,
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MyLayersPtr & intermediate_layers ,
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const std : : vector < Polygons > & layer_support_areas ) const
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{
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# ifdef SLIC3R_DEBUG
static int iRun = 0 ;
# endif /* SLIC3R_DEBUG */
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if ( top_contacts . empty ( ) )
// No top contacts -> no intermediate layers will be produced.
return ;
// coordf_t fillet_radius_scaled = scale_(m_object_config->support_material_spacing);
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BOOST_LOG_TRIVIAL ( debug ) < < " PrintObjectSupportMaterial::generate_base_layers() in parallel - start " ;
tbb : : parallel_for (
tbb : : blocked_range < size_t > ( 0 , intermediate_layers . size ( ) ) ,
[ this , & object , & bottom_contacts , & top_contacts , & intermediate_layers , & layer_support_areas ] ( const tbb : : blocked_range < size_t > & range ) {
// index -2 means not initialized yet, -1 means intialized and decremented to 0 and then -1.
int idx_top_contact_above = - 2 ;
int idx_bottom_contact_overlapping = - 2 ;
int idx_object_layer_above = - 2 ;
// Counting down due to the way idx_lower_or_equal caches indices to avoid repeated binary search over the complete sequence.
for ( int idx_intermediate = int ( range . end ( ) ) - 1 ; idx_intermediate > = int ( range . begin ( ) ) ; - - idx_intermediate )
{
BOOST_LOG_TRIVIAL ( trace ) < < " Support generator - generate_base_layers - creating layer " < <
idx_intermediate < < " of " < < intermediate_layers . size ( ) ;
MyLayer & layer_intermediate = * intermediate_layers [ idx_intermediate ] ;
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// Layers must be sorted by print_z.
assert ( idx_intermediate = = 0 | | layer_intermediate . print_z > = intermediate_layers [ idx_intermediate - 1 ] - > print_z ) ;
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// Find a top_contact layer touching the layer_intermediate from above, if any, and collect its polygons into polygons_new.
// New polygons for layer_intermediate.
Polygons polygons_new ;
// Use the precomputed layer_support_areas.
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idx_object_layer_above = std : : max ( 0 , idx_lower_or_equal ( object . layers ( ) , idx_object_layer_above ,
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[ & layer_intermediate ] ( const Layer * layer ) { return layer - > print_z < = layer_intermediate . print_z + EPSILON ; } ) ) ;
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polygons_new = layer_support_areas [ idx_object_layer_above ] ;
// Polygons to trim polygons_new.
Polygons polygons_trimming ;
// Trimming the base layer with any overlapping top layer.
// Following cases are recognized:
// 1) top.bottom_z >= base.top_z -> No overlap, no trimming needed.
// 2) base.bottom_z >= top.print_z -> No overlap, no trimming needed.
// 3) base.print_z > top.print_z && base.bottom_z >= top.bottom_z -> Overlap, which will be solved inside generate_toolpaths() by reducing the base layer height where it overlaps the top layer. No trimming needed here.
// 4) base.print_z > top.bottom_z && base.bottom_z < top.bottom_z -> Base overlaps with top.bottom_z. This must not happen.
// 5) base.print_z <= top.print_z && base.bottom_z >= top.bottom_z -> Base is fully inside top. Trim base by top.
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idx_top_contact_above = idx_lower_or_equal ( top_contacts , idx_top_contact_above ,
[ & layer_intermediate ] ( const MyLayer * layer ) { return layer - > bottom_z < = layer_intermediate . print_z - EPSILON ; } ) ;
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// Collect all the top_contact layer intersecting with this layer.
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for ( int idx_top_contact_overlapping = idx_top_contact_above ; idx_top_contact_overlapping > = 0 ; - - idx_top_contact_overlapping ) {
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MyLayer & layer_top_overlapping = * top_contacts [ idx_top_contact_overlapping ] ;
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if ( layer_top_overlapping . print_z < layer_intermediate . bottom_z + EPSILON )
break ;
// Base must not overlap with top.bottom_z.
assert ( ! ( layer_intermediate . print_z > layer_top_overlapping . bottom_z + EPSILON & & layer_intermediate . bottom_z < layer_top_overlapping . bottom_z - EPSILON ) ) ;
if ( layer_intermediate . print_z < = layer_top_overlapping . print_z + EPSILON & & layer_intermediate . bottom_z > = layer_top_overlapping . bottom_z - EPSILON )
// Base is fully inside top. Trim base by top.
polygons_append ( polygons_trimming , layer_top_overlapping . polygons ) ;
}
// Trimming the base layer with any overlapping bottom layer.
// Following cases are recognized:
// 1) bottom.bottom_z >= base.top_z -> No overlap, no trimming needed.
// 2) base.bottom_z >= bottom.print_z -> No overlap, no trimming needed.
// 3) base.print_z > bottom.bottom_z && base.bottom_z < bottom.bottom_z -> Overlap, which will be solved inside generate_toolpaths() by reducing the bottom layer height where it overlaps the base layer. No trimming needed here.
// 4) base.print_z > bottom.print_z && base.bottom_z >= bottom.print_z -> Base overlaps with bottom.print_z. This must not happen.
// 5) base.print_z <= bottom.print_z && base.bottom_z >= bottom.bottom_z -> Base is fully inside top. Trim base by top.
idx_bottom_contact_overlapping = idx_lower_or_equal ( bottom_contacts , idx_bottom_contact_overlapping ,
[ & layer_intermediate ] ( const MyLayer * layer ) { return layer - > bottom_print_z ( ) < = layer_intermediate . print_z - EPSILON ; } ) ;
// Collect all the bottom_contacts layer intersecting with this layer.
for ( int i = idx_bottom_contact_overlapping ; i > = 0 ; - - i ) {
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MyLayer & layer_bottom_overlapping = * bottom_contacts [ i ] ;
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if ( layer_bottom_overlapping . print_z < layer_intermediate . bottom_print_z ( ) + EPSILON )
break ;
// Base must not overlap with bottom.top_z.
assert ( ! ( layer_intermediate . print_z > layer_bottom_overlapping . print_z + EPSILON & & layer_intermediate . bottom_z < layer_bottom_overlapping . print_z - EPSILON ) ) ;
if ( layer_intermediate . print_z < = layer_bottom_overlapping . print_z + EPSILON & & layer_intermediate . bottom_z > = layer_bottom_overlapping . bottom_print_z ( ) - EPSILON )
// Base is fully inside bottom. Trim base by bottom.
polygons_append ( polygons_trimming , layer_bottom_overlapping . polygons ) ;
}
# ifdef SLIC3R_DEBUG
{
BoundingBox bbox = get_extents ( polygons_new ) ;
bbox . merge ( get_extents ( polygons_trimming ) ) ;
: : Slic3r : : SVG svg ( debug_out_path ( " support-intermediate-layers-raw-%d-%lf.svg " , iRun , layer_intermediate . print_z ) , bbox ) ;
svg . draw ( union_ex ( polygons_new , false ) , " blue " , 0.5f ) ;
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svg . draw ( to_polylines ( polygons_new ) , " blue " ) ;
svg . draw ( union_ex ( polygons_trimming , true ) , " red " , 0.5f ) ;
svg . draw ( to_polylines ( polygons_trimming ) , " red " ) ;
}
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# endif /* SLIC3R_DEBUG */
// Trim the polygons, store them.
if ( polygons_trimming . empty ( ) )
layer_intermediate . polygons = std : : move ( polygons_new ) ;
else
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layer_intermediate . polygons = diff (
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polygons_new ,
polygons_trimming ,
true ) ; // safety offset to merge the touching source polygons
layer_intermediate . layer_type = sltBase ;
#if 0
// Fillet the base polygons and trim them again with the top, interface and contact layers.
$ base - > { $ i } = diff (
offset2 (
$ base - > { $ i } ,
$ fillet_radius_scaled ,
- $ fillet_radius_scaled ,
# Use a geometric offsetting for filleting.
JT_ROUND ,
0.2 * $ fillet_radius_scaled ) ,
$ trim_polygons ,
false ) ; // don't apply the safety offset.
}
# endif
}
} ) ;
BOOST_LOG_TRIVIAL ( debug ) < < " PrintObjectSupportMaterial::generate_base_layers() in parallel - end " ;
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# ifdef SLIC3R_DEBUG
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for ( MyLayersPtr : : const_iterator it = intermediate_layers . begin ( ) ; it ! = intermediate_layers . end ( ) ; + + it )
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: : Slic3r : : SVG : : export_expolygons (
debug_out_path ( " support-intermediate-layers-untrimmed-%d-%lf.svg " , iRun , ( * it ) - > print_z ) ,
union_ex ( ( * it ) - > polygons , false ) ) ;
+ + iRun ;
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# endif /* SLIC3R_DEBUG */
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// trim_support_layers_by_object(object, intermediate_layers, 0., 0., m_gap_xy);
this - > trim_support_layers_by_object ( object , intermediate_layers ,
m_slicing_params . soluble_interface ? 0. : m_object_config - > support_material_contact_distance . value ,
m_slicing_params . soluble_interface ? 0. : m_object_config - > support_material_contact_distance . value , m_gap_xy ) ;
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}
void PrintObjectSupportMaterial : : trim_support_layers_by_object (
const PrintObject & object ,
MyLayersPtr & support_layers ,
const coordf_t gap_extra_above ,
const coordf_t gap_extra_below ,
const coordf_t gap_xy ) const
{
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const float gap_xy_scaled = float ( scale_ ( gap_xy ) ) ;
// Collect non-empty layers to be processed in parallel.
// This is a good idea as pulling a thread from a thread pool for an empty task is expensive.
MyLayersPtr nonempty_layers ;
nonempty_layers . reserve ( support_layers . size ( ) ) ;
for ( size_t idx_layer = 0 ; idx_layer < support_layers . size ( ) ; + + idx_layer ) {
MyLayer * support_layer = support_layers [ idx_layer ] ;
if ( ! support_layer - > polygons . empty ( ) & & support_layer - > print_z > = m_slicing_params . raft_contact_top_z + EPSILON )
// Non-empty support layer and not a raft layer.
nonempty_layers . push_back ( support_layer ) ;
}
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// For all intermediate support layers:
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BOOST_LOG_TRIVIAL ( debug ) < < " PrintObjectSupportMaterial::trim_support_layers_by_object() in parallel - start " ;
tbb : : parallel_for (
tbb : : blocked_range < size_t > ( 0 , nonempty_layers . size ( ) ) ,
[ this , & object , & nonempty_layers , gap_extra_above , gap_extra_below , gap_xy_scaled ] ( const tbb : : blocked_range < size_t > & range ) {
size_t idx_object_layer_overlapping = size_t ( - 1 ) ;
for ( size_t idx_layer = range . begin ( ) ; idx_layer < range . end ( ) ; + + idx_layer ) {
MyLayer & support_layer = * nonempty_layers [ idx_layer ] ;
// BOOST_LOG_TRIVIAL(trace) << "Support generator - trim_support_layers_by_object - trimmming non-empty layer " << idx_layer << " of " << nonempty_layers.size();
assert ( ! support_layer . polygons . empty ( ) & & support_layer . print_z > = m_slicing_params . raft_contact_top_z + EPSILON ) ;
// Find the overlapping object layers including the extra above / below gap.
coordf_t z_threshold = support_layer . print_z - support_layer . height - gap_extra_below + EPSILON ;
idx_object_layer_overlapping = idx_higher_or_equal (
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object . layers ( ) , idx_object_layer_overlapping ,
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[ z_threshold ] ( const Layer * layer ) { return layer - > print_z > = z_threshold ; } ) ;
// Collect all the object layers intersecting with this layer.
Polygons polygons_trimming ;
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size_t i = idx_object_layer_overlapping ;
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for ( ; i < object . layers ( ) . size ( ) ; + + i ) {
const Layer & object_layer = * object . layers ( ) [ i ] ;
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if ( object_layer . print_z - object_layer . height > support_layer . print_z + gap_extra_above - EPSILON )
break ;
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polygons_append ( polygons_trimming , offset ( object_layer . slices . expolygons , gap_xy_scaled , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
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}
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if ( ! m_slicing_params . soluble_interface ) {
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// Collect all bottom surfaces, which will be extruded with a bridging flow.
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for ( ; i < object . layers ( ) . size ( ) ; + + i ) {
const Layer & object_layer = * object . layers ( ) [ i ] ;
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bool some_region_overlaps = false ;
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for ( LayerRegion * region : object_layer . regions ( ) ) {
coordf_t bridging_height = region - > region ( ) - > bridging_height_avg ( * this - > m_print_config ) ;
if ( object_layer . print_z - bridging_height > support_layer . print_z + gap_extra_above - EPSILON )
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break ;
some_region_overlaps = true ;
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polygons_append ( polygons_trimming ,
offset ( to_expolygons ( region - > fill_surfaces . filter_by_type ( stBottomBridge ) ) ,
gap_xy_scaled , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
if ( region - > region ( ) - > config ( ) . overhangs . value )
SupportMaterialInternal : : collect_bridging_perimeter_areas ( region - > perimeters , gap_xy_scaled , polygons_trimming ) ;
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}
if ( ! some_region_overlaps )
break ;
}
}
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// $layer->slices contains the full shape of layer, thus including
// perimeter's width. $support contains the full shape of support
// material, thus including the width of its foremost extrusion.
// We leave a gap equal to a full extrusion width.
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support_layer . polygons = diff ( support_layer . polygons , polygons_trimming ) ;
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}
} ) ;
BOOST_LOG_TRIVIAL ( debug ) < < " PrintObjectSupportMaterial::trim_support_layers_by_object() in parallel - end " ;
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}
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PrintObjectSupportMaterial : : MyLayersPtr PrintObjectSupportMaterial : : generate_raft_base (
const MyLayersPtr & top_contacts ,
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const MyLayersPtr & interface_layers ,
const MyLayersPtr & base_layers ,
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MyLayerStorage & layer_storage ) const
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{
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// How much to inflate the support columns to be stable. This also applies to the 1st layer, if no raft layers are to be printed.
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const float inflate_factor_fine = float ( scale_ ( ( m_slicing_params . raft_layers ( ) > 1 ) ? 0.5 : EPSILON ) ) ;
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const float inflate_factor_1st_layer = float ( scale_ ( 3. ) ) - inflate_factor_fine ;
MyLayer * contacts = top_contacts . empty ( ) ? nullptr : top_contacts . front ( ) ;
MyLayer * interfaces = interface_layers . empty ( ) ? nullptr : interface_layers . front ( ) ;
MyLayer * columns_base = base_layers . empty ( ) ? nullptr : base_layers . front ( ) ;
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if ( contacts ! = nullptr & & contacts - > print_z > std : : max ( m_slicing_params . first_print_layer_height , m_slicing_params . raft_contact_top_z ) + EPSILON )
// This is not the raft contact layer.
contacts = nullptr ;
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if ( interfaces ! = nullptr & & interfaces - > bottom_print_z ( ) > m_slicing_params . raft_interface_top_z + EPSILON )
// This is not the raft column base layer.
interfaces = nullptr ;
if ( columns_base ! = nullptr & & columns_base - > bottom_print_z ( ) > m_slicing_params . raft_interface_top_z + EPSILON )
// This is not the raft interface layer.
columns_base = nullptr ;
Polygons interface_polygons ;
if ( contacts ! = nullptr & & ! contacts - > polygons . empty ( ) )
polygons_append ( interface_polygons , offset ( contacts - > polygons , inflate_factor_fine , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
if ( interfaces ! = nullptr & & ! interfaces - > polygons . empty ( ) )
polygons_append ( interface_polygons , offset ( interfaces - > polygons , inflate_factor_fine , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
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// Output vector.
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MyLayersPtr raft_layers ;
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if ( m_slicing_params . raft_layers ( ) > 1 ) {
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Polygons base ;
Polygons columns ;
if ( columns_base ! = nullptr ) {
base = columns_base - > polygons ;
columns = base ;
if ( ! interface_polygons . empty ( ) )
// Trim the 1st layer columns with the inflated interface polygons.
columns = diff ( columns , interface_polygons ) ;
}
if ( ! interface_polygons . empty ( ) ) {
// Merge the untrimmed columns base with the expanded raft interface, to be used for the support base and interface.
base = union_ ( base , interface_polygons ) ;
}
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// Do not add the raft contact layer, only add the raft layers below the contact layer.
// Insert the 1st layer.
{
MyLayer & new_layer = layer_allocate ( layer_storage , ( m_slicing_params . base_raft_layers > 0 ) ? sltRaftBase : sltRaftInterface ) ;
raft_layers . push_back ( & new_layer ) ;
new_layer . print_z = m_slicing_params . first_print_layer_height ;
new_layer . height = m_slicing_params . first_print_layer_height ;
new_layer . bottom_z = 0. ;
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new_layer . polygons = offset ( base , inflate_factor_1st_layer ) ;
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}
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// Insert the base layers.
for ( size_t i = 1 ; i < m_slicing_params . base_raft_layers ; + + i ) {
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coordf_t print_z = raft_layers . back ( ) - > print_z ;
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MyLayer & new_layer = layer_allocate ( layer_storage , sltRaftBase ) ;
raft_layers . push_back ( & new_layer ) ;
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new_layer . print_z = print_z + m_slicing_params . base_raft_layer_height ;
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new_layer . height = m_slicing_params . base_raft_layer_height ;
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new_layer . bottom_z = print_z ;
new_layer . polygons = base ;
}
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// Insert the interface layers.
for ( size_t i = 1 ; i < m_slicing_params . interface_raft_layers ; + + i ) {
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coordf_t print_z = raft_layers . back ( ) - > print_z ;
MyLayer & new_layer = layer_allocate ( layer_storage , sltRaftInterface ) ;
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raft_layers . push_back ( & new_layer ) ;
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new_layer . print_z = print_z + m_slicing_params . interface_raft_layer_height ;
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new_layer . height = m_slicing_params . interface_raft_layer_height ;
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new_layer . bottom_z = print_z ;
new_layer . polygons = interface_polygons ;
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//FIXME misusing contact_polygons for support columns.
new_layer . contact_polygons = new Polygons ( columns ) ;
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}
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} else if ( columns_base ! = nullptr ) {
// Expand the bases of the support columns in the 1st layer.
columns_base - > polygons = diff (
offset ( columns_base - > polygons , inflate_factor_1st_layer ) ,
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offset ( m_object - > layers ( ) . front ( ) - > slices . expolygons , ( float ) scale_ ( m_gap_xy ) , SUPPORT_SURFACES_OFFSET_PARAMETERS ) ) ;
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if ( contacts ! = nullptr )
columns_base - > polygons = diff ( columns_base - > polygons , interface_polygons ) ;
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}
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return raft_layers ;
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}
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// Convert some of the intermediate layers into top/bottom interface layers.
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PrintObjectSupportMaterial : : MyLayersPtr PrintObjectSupportMaterial : : generate_interface_layers (
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const MyLayersPtr & bottom_contacts ,
const MyLayersPtr & top_contacts ,
MyLayersPtr & intermediate_layers ,
MyLayerStorage & layer_storage ) const
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{
// my $area_threshold = $self->interface_flow->scaled_spacing ** 2;
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MyLayersPtr interface_layers ;
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// Contact layer is considered an interface layer, therefore run the following block only if support_material_interface_layers > 1.
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if ( ! intermediate_layers . empty ( ) & & m_object_config - > support_material_interface_layers . value > 1 ) {
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// For all intermediate layers, collect top contact surfaces, which are not further than support_material_interface_layers.
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BOOST_LOG_TRIVIAL ( debug ) < < " PrintObjectSupportMaterial::generate_interface_layers() in parallel - start " ;
interface_layers . assign ( intermediate_layers . size ( ) , nullptr ) ;
tbb : : spin_mutex layer_storage_mutex ;
tbb : : parallel_for ( tbb : : blocked_range < size_t > ( 0 , intermediate_layers . size ( ) ) ,
[ this , & bottom_contacts , & top_contacts , & intermediate_layers , & layer_storage , & layer_storage_mutex , & interface_layers ] ( const tbb : : blocked_range < size_t > & range ) {
// Index of the first top contact layer intersecting the current intermediate layer.
size_t idx_top_contact_first = size_t ( - 1 ) ;
// Index of the first bottom contact layer intersecting the current intermediate layer.
size_t idx_bottom_contact_first = size_t ( - 1 ) ;
for ( size_t idx_intermediate_layer = range . begin ( ) ; idx_intermediate_layer < range . end ( ) ; + + idx_intermediate_layer ) {
MyLayer & intermediate_layer = * intermediate_layers [ idx_intermediate_layer ] ;
// Top / bottom Z coordinate of a slab, over which we are collecting the top / bottom contact surfaces.
coordf_t top_z = intermediate_layers [ std : : min < int > ( intermediate_layers . size ( ) - 1 , idx_intermediate_layer + m_object_config - > support_material_interface_layers - 1 ) ] - > print_z ;
coordf_t bottom_z = intermediate_layers [ std : : max < int > ( 0 , int ( idx_intermediate_layer ) - int ( m_object_config - > support_material_interface_layers ) + 1 ) ] - > bottom_z ;
// Move idx_top_contact_first up until above the current print_z.
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idx_top_contact_first = idx_higher_or_equal ( top_contacts , idx_top_contact_first , [ & intermediate_layer ] ( const MyLayer * layer ) { return layer - > print_z > = intermediate_layer . print_z ; } ) ; // - EPSILON
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// Collect the top contact areas above this intermediate layer, below top_z.
Polygons polygons_top_contact_projected ;
for ( size_t idx_top_contact = idx_top_contact_first ; idx_top_contact < top_contacts . size ( ) ; + + idx_top_contact ) {
const MyLayer & top_contact_layer = * top_contacts [ idx_top_contact ] ;
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//FIXME maybe this adds one interface layer in excess?
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if ( top_contact_layer . bottom_z - EPSILON > top_z )
break ;
polygons_append ( polygons_top_contact_projected , top_contact_layer . polygons ) ;
}
// Move idx_bottom_contact_first up until touching bottom_z.
idx_bottom_contact_first = idx_higher_or_equal ( bottom_contacts , idx_bottom_contact_first , [ bottom_z ] ( const MyLayer * layer ) { return layer - > print_z > = bottom_z - EPSILON ; } ) ;
// Collect the top contact areas above this intermediate layer, below top_z.
Polygons polygons_bottom_contact_projected ;
for ( size_t idx_bottom_contact = idx_bottom_contact_first ; idx_bottom_contact < bottom_contacts . size ( ) ; + + idx_bottom_contact ) {
const MyLayer & bottom_contact_layer = * bottom_contacts [ idx_bottom_contact ] ;
if ( bottom_contact_layer . print_z - EPSILON > intermediate_layer . bottom_z )
break ;
polygons_append ( polygons_bottom_contact_projected , bottom_contact_layer . polygons ) ;
}
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if ( polygons_top_contact_projected . empty ( ) & & polygons_bottom_contact_projected . empty ( ) )
continue ;
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// Insert a new layer into top_interface_layers.
MyLayer & layer_new = layer_allocate ( layer_storage , layer_storage_mutex ,
polygons_top_contact_projected . empty ( ) ? sltBottomInterface : sltTopInterface ) ;
layer_new . print_z = intermediate_layer . print_z ;
layer_new . bottom_z = intermediate_layer . bottom_z ;
layer_new . height = intermediate_layer . height ;
layer_new . bridging = intermediate_layer . bridging ;
interface_layers [ idx_intermediate_layer ] = & layer_new ;
polygons_append ( polygons_top_contact_projected , polygons_bottom_contact_projected ) ;
polygons_top_contact_projected = union_ ( polygons_top_contact_projected , true ) ;
layer_new . polygons = intersection ( intermediate_layer . polygons , polygons_top_contact_projected ) ;
//FIXME filter layer_new.polygons islands by a minimum area?
// $interface_area = [ grep abs($_->area) >= $area_threshold, @$interface_area ];
intermediate_layer . polygons = diff ( intermediate_layer . polygons , polygons_top_contact_projected , false ) ;
}
} ) ;
// Compress contact_out, remove the nullptr items.
remove_nulls ( interface_layers ) ;
BOOST_LOG_TRIVIAL ( debug ) < < " PrintObjectSupportMaterial::generate_interface_layers() in parallel - start " ;
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}
return interface_layers ;
}
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static inline void fill_expolygons_generate_paths (
ExtrusionEntitiesPtr & dst ,
const ExPolygons & expolygons ,
Fill * filler ,
float density ,
ExtrusionRole role ,
const Flow & flow )
{
FillParams fill_params ;
fill_params . density = density ;
fill_params . complete = true ;
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fill_params . dont_adjust = true ;
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for ( const ExPolygon & expoly : expolygons ) {
Surface surface ( stInternal , expoly ) ;
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extrusion_entities_append_paths (
dst ,
filler - > fill_surface ( & surface , fill_params ) ,
role ,
flow . mm3_per_mm ( ) , flow . width , flow . height ) ;
}
}
static inline void fill_expolygons_generate_paths (
ExtrusionEntitiesPtr & dst ,
ExPolygons & & expolygons ,
Fill * filler ,
float density ,
ExtrusionRole role ,
const Flow & flow )
{
FillParams fill_params ;
fill_params . density = density ;
fill_params . complete = true ;
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fill_params . dont_adjust = true ;
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for ( ExPolygon & expoly : expolygons ) {
Surface surface ( stInternal , std : : move ( expoly ) ) ;
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extrusion_entities_append_paths (
dst ,
filler - > fill_surface ( & surface , fill_params ) ,
role ,
flow . mm3_per_mm ( ) , flow . width , flow . height ) ;
}
}
// Support layers, partially processed.
struct MyLayerExtruded
{
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MyLayerExtruded ( ) : layer ( nullptr ) , m_polygons_to_extrude ( nullptr ) { }
~ MyLayerExtruded ( ) { delete m_polygons_to_extrude ; m_polygons_to_extrude = nullptr ; }
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bool empty ( ) const {
return layer = = nullptr | | layer - > polygons . empty ( ) ;
}
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void set_polygons_to_extrude ( Polygons & & polygons ) {
if ( m_polygons_to_extrude = = nullptr )
m_polygons_to_extrude = new Polygons ( std : : move ( polygons ) ) ;
else
* m_polygons_to_extrude = std : : move ( polygons ) ;
}
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Polygons & polygons_to_extrude ( ) { return ( m_polygons_to_extrude = = nullptr ) ? layer - > polygons : * m_polygons_to_extrude ; }
const Polygons & polygons_to_extrude ( ) const { return ( m_polygons_to_extrude = = nullptr ) ? layer - > polygons : * m_polygons_to_extrude ; }
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bool could_merge ( const MyLayerExtruded & other ) const {
return ! this - > empty ( ) & & ! other . empty ( ) & &
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std : : abs ( this - > layer - > height - other . layer - > height ) < EPSILON & &
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this - > layer - > bridging = = other . layer - > bridging ;
}
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// Merge regions, perform boolean union over the merged polygons.
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void merge ( MyLayerExtruded & & other ) {
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assert ( this - > could_merge ( other ) ) ;
// 1) Merge the rest polygons to extrude, if there are any.
if ( other . m_polygons_to_extrude ! = nullptr ) {
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if ( m_polygons_to_extrude = = nullptr ) {
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// This layer has no extrusions generated yet, if it has no m_polygons_to_extrude (its area to extrude was not reduced yet).
assert ( this - > extrusions . empty ( ) ) ;
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m_polygons_to_extrude = new Polygons ( this - > layer - > polygons ) ;
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}
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Slic3r : : polygons_append ( * m_polygons_to_extrude , std : : move ( * other . m_polygons_to_extrude ) ) ;
* m_polygons_to_extrude = union_ ( * m_polygons_to_extrude , true ) ;
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delete other . m_polygons_to_extrude ;
other . m_polygons_to_extrude = nullptr ;
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} else if ( m_polygons_to_extrude ! = nullptr ) {
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assert ( other . m_polygons_to_extrude = = nullptr ) ;
// The other layer has no extrusions generated yet, if it has no m_polygons_to_extrude (its area to extrude was not reduced yet).
assert ( other . extrusions . empty ( ) ) ;
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Slic3r : : polygons_append ( * m_polygons_to_extrude , other . layer - > polygons ) ;
* m_polygons_to_extrude = union_ ( * m_polygons_to_extrude , true ) ;
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}
// 2) Merge the extrusions.
this - > extrusions . insert ( this - > extrusions . end ( ) , other . extrusions . begin ( ) , other . extrusions . end ( ) ) ;
other . extrusions . clear ( ) ;
// 3) Merge the infill polygons.
Slic3r : : polygons_append ( this - > layer - > polygons , std : : move ( other . layer - > polygons ) ) ;
this - > layer - > polygons = union_ ( this - > layer - > polygons , true ) ;
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other . layer - > polygons . clear ( ) ;
}
void polygons_append ( Polygons & dst ) const {
if ( layer ! = NULL & & ! layer - > polygons . empty ( ) )
Slic3r : : polygons_append ( dst , layer - > polygons ) ;
}
// The source layer. It carries the height and extrusion type (bridging / non bridging, extrusion height).
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PrintObjectSupportMaterial : : MyLayer * layer ;
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// Collect extrusions. They will be exported sorted by the bottom height.
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ExtrusionEntitiesPtr extrusions ;
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// In case the extrusions are non-empty, m_polygons_to_extrude may contain the rest areas yet to be filled by additional support.
// This is useful mainly for the loop interfaces, which are generated before the zig-zag infills.
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Polygons * m_polygons_to_extrude ;
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} ;
typedef std : : vector < MyLayerExtruded * > MyLayerExtrudedPtrs ;
struct LoopInterfaceProcessor
{
LoopInterfaceProcessor ( coordf_t circle_r ) :
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n_contact_loops ( 0 ) ,
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circle_radius ( circle_r ) ,
circle_distance ( circle_r * 3. )
{
// Shape of the top contact area.
circle . points . reserve ( 6 ) ;
for ( size_t i = 0 ; i < 6 ; + + i ) {
double angle = double ( i ) * M_PI / 3. ;
circle . points . push_back ( Point ( circle_radius * cos ( angle ) , circle_radius * sin ( angle ) ) ) ;
}
}
// Generate loop contacts at the top_contact_layer,
// trim the top_contact_layer->polygons with the areas covered by the loops.
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void generate ( MyLayerExtruded & top_contact_layer , const Flow & interface_flow_src ) const ;
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int n_contact_loops ;
coordf_t circle_radius ;
coordf_t circle_distance ;
Polygon circle ;
} ;
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void LoopInterfaceProcessor : : generate ( MyLayerExtruded & top_contact_layer , const Flow & interface_flow_src ) const
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{
if ( n_contact_loops = = 0 | | top_contact_layer . empty ( ) )
return ;
Flow flow = interface_flow_src ;
flow . height = float ( top_contact_layer . layer - > height ) ;
Polygons overhang_polygons ;
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if ( top_contact_layer . layer - > overhang_polygons ! = nullptr )
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overhang_polygons = std : : move ( * top_contact_layer . layer - > overhang_polygons ) ;
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// Generate the outermost loop.
// Find centerline of the external loop (or any other kind of extrusions should the loop be skipped)
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ExPolygons top_contact_expolygons = offset_ex ( union_ex ( top_contact_layer . layer - > polygons ) , - 0.5f * flow . scaled_width ( ) ) ;
// Grid size and bit shifts for quick and exact to/from grid coordinates manipulation.
coord_t circle_grid_resolution = 1 ;
coord_t circle_grid_powerof2 = 0 ;
{
// epsilon to account for rounding errors
coord_t circle_grid_resolution_non_powerof2 = coord_t ( 2. * circle_distance + 3. ) ;
while ( circle_grid_resolution < circle_grid_resolution_non_powerof2 ) {
circle_grid_resolution < < = 1 ;
+ + circle_grid_powerof2 ;
}
}
struct PointAccessor {
const Point * operator ( ) ( const Point & pt ) const { return & pt ; }
} ;
typedef ClosestPointInRadiusLookup < Point , PointAccessor > ClosestPointLookupType ;
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Polygons loops0 ;
{
// find centerline of the external loop of the contours
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// Only consider the loops facing the overhang.
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Polygons external_loops ;
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// Holes in the external loops.
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Polygons circles ;
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Polygons overhang_with_margin = offset ( union_ex ( overhang_polygons ) , 0.5f * flow . scaled_width ( ) ) ;
for ( ExPolygons : : iterator it_contact_expoly = top_contact_expolygons . begin ( ) ; it_contact_expoly ! = top_contact_expolygons . end ( ) ; + + it_contact_expoly ) {
// Store the circle centers placed for an expolygon into a regular grid, hashed by the circle centers.
ClosestPointLookupType circle_centers_lookup ( coord_t ( circle_distance - SCALED_EPSILON ) ) ;
Points circle_centers ;
Point center_last ;
// For each contour of the expolygon, start with the outer contour, continue with the holes.
for ( size_t i_contour = 0 ; i_contour < = it_contact_expoly - > holes . size ( ) ; + + i_contour ) {
Polygon & contour = ( i_contour = = 0 ) ? it_contact_expoly - > contour : it_contact_expoly - > holes [ i_contour - 1 ] ;
const Point * seg_current_pt = nullptr ;
coordf_t seg_current_t = 0. ;
if ( ! intersection_pl ( contour . split_at_first_point ( ) , overhang_with_margin ) . empty ( ) ) {
// The contour is below the overhang at least to some extent.
//FIXME ideally one would place the circles below the overhang only.
// Walk around the contour and place circles so their centers are not closer than circle_distance from each other.
if ( circle_centers . empty ( ) ) {
// Place the first circle.
seg_current_pt = & contour . points . front ( ) ;
seg_current_t = 0. ;
center_last = * seg_current_pt ;
circle_centers_lookup . insert ( center_last ) ;
circle_centers . push_back ( center_last ) ;
}
for ( Points : : const_iterator it = contour . points . begin ( ) + 1 ; it ! = contour . points . end ( ) ; + + it ) {
// Is it possible to place a circle on this segment? Is it not too close to any of the circles already placed on this contour?
const Point & p1 = * ( it - 1 ) ;
const Point & p2 = * it ;
// Intersection of a ray (p1, p2) with a circle placed at center_last, with radius of circle_distance.
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const Vec2d v_seg ( coordf_t ( p2 ( 0 ) ) - coordf_t ( p1 ( 0 ) ) , coordf_t ( p2 ( 1 ) ) - coordf_t ( p1 ( 1 ) ) ) ;
const Vec2d v_cntr ( coordf_t ( p1 ( 0 ) - center_last ( 0 ) ) , coordf_t ( p1 ( 1 ) - center_last ( 1 ) ) ) ;
Removed Point::scale(),translate(),coincides_with(),distance_to(),
distance_to_squared(),perp_distance_to(),negative(),vector_to(),
translate(), distance_to() etc,
replaced with the Eigen equivalents.
2018-08-17 12:14:24 +00:00
coordf_t a = v_seg . squaredNorm ( ) ;
coordf_t b = 2. * v_seg . dot ( v_cntr ) ;
coordf_t c = v_cntr . squaredNorm ( ) - circle_distance * circle_distance ;
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coordf_t disc = b * b - 4. * a * c ;
if ( disc > 0. ) {
// The circle intersects a ray. Avoid the parts of the segment inside the circle.
coordf_t t1 = ( - b - sqrt ( disc ) ) / ( 2. * a ) ;
coordf_t t2 = ( - b + sqrt ( disc ) ) / ( 2. * a ) ;
coordf_t t0 = ( seg_current_pt = = & p1 ) ? seg_current_t : 0. ;
// Take the lowest t in <t0, 1.>, excluding <t1, t2>.
coordf_t t ;
if ( t0 < = t1 )
t = t0 ;
else if ( t2 < = 1. )
t = t2 ;
else {
// Try the following segment.
seg_current_pt = nullptr ;
continue ;
}
seg_current_pt = & p1 ;
seg_current_t = t ;
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center_last = Point ( p1 ( 0 ) + coord_t ( v_seg ( 0 ) * t ) , p1 ( 1 ) + coord_t ( v_seg ( 1 ) * t ) ) ;
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// It has been verified that the new point is far enough from center_last.
// Ensure, that it is far enough from all the centers.
std : : pair < const Point * , coordf_t > circle_closest = circle_centers_lookup . find ( center_last ) ;
if ( circle_closest . first ! = nullptr ) {
- - it ;
continue ;
}
} else {
// All of the segment is outside the circle. Take the first point.
seg_current_pt = & p1 ;
seg_current_t = 0. ;
center_last = p1 ;
}
// Place the first circle.
circle_centers_lookup . insert ( center_last ) ;
circle_centers . push_back ( center_last ) ;
}
external_loops . push_back ( std : : move ( contour ) ) ;
Removed Point::scale(),translate(),coincides_with(),distance_to(),
distance_to_squared(),perp_distance_to(),negative(),vector_to(),
translate(), distance_to() etc,
replaced with the Eigen equivalents.
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for ( const Point & center : circle_centers ) {
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circles . push_back ( circle ) ;
Removed Point::scale(),translate(),coincides_with(),distance_to(),
distance_to_squared(),perp_distance_to(),negative(),vector_to(),
translate(), distance_to() etc,
replaced with the Eigen equivalents.
2018-08-17 12:14:24 +00:00
circles . back ( ) . translate ( center ) ;
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}
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}
}
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}
// Apply a pattern to the external loops.
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loops0 = diff ( external_loops , circles ) ;
}
Polylines loop_lines ;
{
// make more loops
Polygons loop_polygons = loops0 ;
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for ( int i = 1 ; i < n_contact_loops ; + + i )
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polygons_append ( loop_polygons ,
offset2 (
loops0 ,
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- i * flow . scaled_spacing ( ) - 0.5f * flow . scaled_spacing ( ) ,
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0.5f * flow . scaled_spacing ( ) ) ) ;
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// Clip such loops to the side oriented towards the object.
// Collect split points, so they will be recognized after the clipping.
// At the split points the clipped pieces will be stitched back together.
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loop_lines . reserve ( loop_polygons . size ( ) ) ;
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std : : unordered_map < Point , int , PointHash > map_split_points ;
for ( Polygons : : const_iterator it = loop_polygons . begin ( ) ; it ! = loop_polygons . end ( ) ; + + it ) {
assert ( map_split_points . find ( it - > first_point ( ) ) = = map_split_points . end ( ) ) ;
map_split_points [ it - > first_point ( ) ] = - 1 ;
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loop_lines . push_back ( it - > split_at_first_point ( ) ) ;
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}
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loop_lines = intersection_pl ( loop_lines , offset ( overhang_polygons , scale_ ( SUPPORT_MATERIAL_MARGIN ) ) ) ;
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// Because a closed loop has been split to a line, loop_lines may contain continuous segments split to 2 pieces.
// Try to connect them.
for ( int i_line = 0 ; i_line < int ( loop_lines . size ( ) ) ; + + i_line ) {
Polyline & polyline = loop_lines [ i_line ] ;
auto it = map_split_points . find ( polyline . first_point ( ) ) ;
if ( it ! = map_split_points . end ( ) ) {
// This is a stitching point.
// If this assert triggers, multiple source polygons likely intersected at this point.
assert ( it - > second ! = - 2 ) ;
if ( it - > second < 0 ) {
// First occurence.
it - > second = i_line ;
} else {
// Second occurence. Join the lines.
Polyline & polyline_1st = loop_lines [ it - > second ] ;
assert ( polyline_1st . first_point ( ) = = it - > first | | polyline_1st . last_point ( ) = = it - > first ) ;
if ( polyline_1st . first_point ( ) = = it - > first )
polyline_1st . reverse ( ) ;
polyline_1st . append ( std : : move ( polyline ) ) ;
it - > second = - 2 ;
}
continue ;
}
it = map_split_points . find ( polyline . last_point ( ) ) ;
if ( it ! = map_split_points . end ( ) ) {
// This is a stitching point.
// If this assert triggers, multiple source polygons likely intersected at this point.
assert ( it - > second ! = - 2 ) ;
if ( it - > second < 0 ) {
// First occurence.
it - > second = i_line ;
} else {
// Second occurence. Join the lines.
Polyline & polyline_1st = loop_lines [ it - > second ] ;
assert ( polyline_1st . first_point ( ) = = it - > first | | polyline_1st . last_point ( ) = = it - > first ) ;
if ( polyline_1st . first_point ( ) = = it - > first )
polyline_1st . reverse ( ) ;
polyline . reverse ( ) ;
polyline_1st . append ( std : : move ( polyline ) ) ;
it - > second = - 2 ;
}
}
}
// Remove empty lines.
remove_degenerate ( loop_lines ) ;
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}
// add the contact infill area to the interface area
// note that growing loops by $circle_radius ensures no tiny
// extrusions are left inside the circles; however it creates
// a very large gap between loops and contact_infill_polygons, so maybe another
// solution should be found to achieve both goals
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// Store the trimmed polygons into a separate polygon set, so the original infill area remains intact for
// "modulate by layer thickness".
top_contact_layer . set_polygons_to_extrude ( diff ( top_contact_layer . layer - > polygons , offset ( loop_lines , float ( circle_radius * 1.1 ) ) ) ) ;
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// Transform loops into ExtrusionPath objects.
extrusion_entities_append_paths (
top_contact_layer . extrusions ,
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std : : move ( loop_lines ) ,
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erSupportMaterialInterface , flow . mm3_per_mm ( ) , flow . width , flow . height ) ;
}
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# ifdef SLIC3R_DEBUG
static std : : string dbg_index_to_color ( int idx )
{
if ( idx < 0 )
return " yellow " ;
idx = idx % 3 ;
switch ( idx ) {
case 0 : return " red " ;
case 1 : return " green " ;
default : return " blue " ;
}
}
# endif /* SLIC3R_DEBUG */
// When extruding a bottom interface layer over an object, the bottom interface layer is extruded in a thin air, therefore
// it is being extruded with a bridging flow to not shrink excessively (the die swell effect).
// Tiny extrusions are better avoided and it is always better to anchor the thread to an existing support structure if possible.
// Therefore the bottom interface spots are expanded a bit. The expanded regions may overlap with another bottom interface layers,
// leading to over extrusion, where they overlap. The over extrusion is better avoided as it often makes the interface layers
// to stick too firmly to the object.
void modulate_extrusion_by_overlapping_layers (
// Extrusions generated for this_layer.
ExtrusionEntitiesPtr & extrusions_in_out ,
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const PrintObjectSupportMaterial : : MyLayer & this_layer ,
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// Multiple layers overlapping with this_layer, sorted bottom up.
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const PrintObjectSupportMaterial : : MyLayersPtr & overlapping_layers )
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{
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size_t n_overlapping_layers = overlapping_layers . size ( ) ;
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if ( n_overlapping_layers = = 0 | | extrusions_in_out . empty ( ) )
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// The extrusions do not overlap with any other extrusion.
return ;
// Get the initial extrusion parameters.
ExtrusionPath * extrusion_path_template = dynamic_cast < ExtrusionPath * > ( extrusions_in_out . front ( ) ) ;
assert ( extrusion_path_template ! = nullptr ) ;
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ExtrusionRole extrusion_role = extrusion_path_template - > role ( ) ;
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float extrusion_width = extrusion_path_template - > width ;
struct ExtrusionPathFragment
{
ExtrusionPathFragment ( ) : mm3_per_mm ( - 1 ) , width ( - 1 ) , height ( - 1 ) { } ;
ExtrusionPathFragment ( double mm3_per_mm , float width , float height ) : mm3_per_mm ( mm3_per_mm ) , width ( width ) , height ( height ) { } ;
Polylines polylines ;
double mm3_per_mm ;
float width ;
float height ;
} ;
// Split the extrusions by the overlapping layers, reduce their extrusion rate.
// The last path_fragment is from this_layer.
std : : vector < ExtrusionPathFragment > path_fragments (
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n_overlapping_layers + 1 ,
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ExtrusionPathFragment ( extrusion_path_template - > mm3_per_mm , extrusion_path_template - > width , extrusion_path_template - > height ) ) ;
// Don't use it, it will be released.
extrusion_path_template = nullptr ;
# ifdef SLIC3R_DEBUG
static int iRun = 0 ;
+ + iRun ;
BoundingBox bbox ;
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for ( size_t i_overlapping_layer = 0 ; i_overlapping_layer < n_overlapping_layers ; + + i_overlapping_layer ) {
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const PrintObjectSupportMaterial : : MyLayer & overlapping_layer = * overlapping_layers [ i_overlapping_layer ] ;
bbox . merge ( get_extents ( overlapping_layer . polygons ) ) ;
}
for ( ExtrusionEntitiesPtr : : const_iterator it = extrusions_in_out . begin ( ) ; it ! = extrusions_in_out . end ( ) ; + + it ) {
ExtrusionPath * path = dynamic_cast < ExtrusionPath * > ( * it ) ;
assert ( path ! = nullptr ) ;
bbox . merge ( get_extents ( path - > polyline ) ) ;
}
SVG svg ( debug_out_path ( " support-fragments-%d-%lf.svg " , iRun , this_layer . print_z ) . c_str ( ) , bbox ) ;
const float transparency = 0.5f ;
// Filled polygons for the overlapping regions.
svg . draw ( union_ex ( this_layer . polygons ) , dbg_index_to_color ( - 1 ) , transparency ) ;
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for ( size_t i_overlapping_layer = 0 ; i_overlapping_layer < n_overlapping_layers ; + + i_overlapping_layer ) {
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const PrintObjectSupportMaterial : : MyLayer & overlapping_layer = * overlapping_layers [ i_overlapping_layer ] ;
svg . draw ( union_ex ( overlapping_layer . polygons ) , dbg_index_to_color ( int ( i_overlapping_layer ) ) , transparency ) ;
}
// Contours of the overlapping regions.
svg . draw ( to_polylines ( this_layer . polygons ) , dbg_index_to_color ( - 1 ) , scale_ ( 0.2 ) ) ;
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for ( size_t i_overlapping_layer = 0 ; i_overlapping_layer < n_overlapping_layers ; + + i_overlapping_layer ) {
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const PrintObjectSupportMaterial : : MyLayer & overlapping_layer = * overlapping_layers [ i_overlapping_layer ] ;
svg . draw ( to_polylines ( overlapping_layer . polygons ) , dbg_index_to_color ( int ( i_overlapping_layer ) ) , scale_ ( 0.1 ) ) ;
}
// Fill extrusion, the source.
for ( ExtrusionEntitiesPtr : : const_iterator it = extrusions_in_out . begin ( ) ; it ! = extrusions_in_out . end ( ) ; + + it ) {
ExtrusionPath * path = dynamic_cast < ExtrusionPath * > ( * it ) ;
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std : : string color_name ;
switch ( ( it - extrusions_in_out . begin ( ) ) % 9 ) {
case 0 : color_name = " magenta " ; break ;
case 1 : color_name = " deepskyblue " ; break ;
case 2 : color_name = " coral " ; break ;
case 3 : color_name = " goldenrod " ; break ;
case 4 : color_name = " orange " ; break ;
case 5 : color_name = " olivedrab " ; break ;
case 6 : color_name = " blueviolet " ; break ;
case 7 : color_name = " brown " ; break ;
default : color_name = " orchid " ; break ;
}
svg . draw ( path - > polyline , color_name , scale_ ( 0.2 ) ) ;
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}
# endif /* SLIC3R_DEBUG */
// End points of the original paths.
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std : : vector < std : : pair < Point , Point > > path_ends ;
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// Collect the paths of this_layer.
{
Polylines & polylines = path_fragments . back ( ) . polylines ;
for ( ExtrusionEntitiesPtr : : const_iterator it = extrusions_in_out . begin ( ) ; it ! = extrusions_in_out . end ( ) ; + + it ) {
ExtrusionPath * path = dynamic_cast < ExtrusionPath * > ( * it ) ;
assert ( path ! = nullptr ) ;
polylines . emplace_back ( Polyline ( std : : move ( path - > polyline ) ) ) ;
path_ends . emplace_back ( std : : pair < Point , Point > ( polylines . back ( ) . points . front ( ) , polylines . back ( ) . points . back ( ) ) ) ;
}
}
// Destroy the original extrusion paths, their polylines were moved to path_fragments already.
// This will be the destination for the new paths.
extrusions_in_out . clear ( ) ;
// Fragment the path segments by overlapping layers. The overlapping layers are sorted by an increasing print_z.
// Trim by the highest overlapping layer first.
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for ( int i_overlapping_layer = int ( n_overlapping_layers ) - 1 ; i_overlapping_layer > = 0 ; - - i_overlapping_layer ) {
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const PrintObjectSupportMaterial : : MyLayer & overlapping_layer = * overlapping_layers [ i_overlapping_layer ] ;
ExtrusionPathFragment & frag = path_fragments [ i_overlapping_layer ] ;
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Polygons polygons_trimming = offset ( union_ex ( overlapping_layer . polygons ) , float ( scale_ ( 0.5 * extrusion_width ) ) ) ;
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frag . polylines = intersection_pl ( path_fragments . back ( ) . polylines , polygons_trimming , false ) ;
path_fragments . back ( ) . polylines = diff_pl ( path_fragments . back ( ) . polylines , polygons_trimming , false ) ;
// Adjust the extrusion parameters for a reduced layer height and a non-bridging flow (nozzle_dmr = -1, does not matter).
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assert ( this_layer . print_z > overlapping_layer . print_z ) ;
frag . height = float ( this_layer . print_z - overlapping_layer . print_z ) ;
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frag . mm3_per_mm = Flow ( frag . width , frag . height , - 1.f , false ) . mm3_per_mm ( ) ;
# ifdef SLIC3R_DEBUG
svg . draw ( frag . polylines , dbg_index_to_color ( i_overlapping_layer ) , scale_ ( 0.1 ) ) ;
# endif /* SLIC3R_DEBUG */
}
# ifdef SLIC3R_DEBUG
svg . draw ( path_fragments . back ( ) . polylines , dbg_index_to_color ( - 1 ) , scale_ ( 0.1 ) ) ;
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svg . Close ( ) ;
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# endif /* SLIC3R_DEBUG */
// Now chain the split segments using hashing and a nearly exact match, maintaining the order of segments.
// Create a single ExtrusionPath or ExtrusionEntityCollection per source ExtrusionPath.
// Map of fragment start/end points to a pair of <i_overlapping_layer, i_polyline_in_layer>
// Because a non-exact matching is used for the end points, a multi-map is used.
// As the clipper library may reverse the order of some clipped paths, store both ends into the map.
struct ExtrusionPathFragmentEnd
{
ExtrusionPathFragmentEnd ( size_t alayer_idx , size_t apolyline_idx , bool ais_start ) :
layer_idx ( alayer_idx ) , polyline_idx ( apolyline_idx ) , is_start ( ais_start ) { }
size_t layer_idx ;
size_t polyline_idx ;
bool is_start ;
} ;
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class ExtrusionPathFragmentEndPointAccessor {
public :
ExtrusionPathFragmentEndPointAccessor ( const std : : vector < ExtrusionPathFragment > & path_fragments ) : m_path_fragments ( path_fragments ) { }
// Return an end point of a fragment, or nullptr if the fragment has been consumed already.
const Point * operator ( ) ( const ExtrusionPathFragmentEnd & fragment_end ) const {
const Polyline & polyline = m_path_fragments [ fragment_end . layer_idx ] . polylines [ fragment_end . polyline_idx ] ;
return polyline . points . empty ( ) ? nullptr :
( fragment_end . is_start ? & polyline . points . front ( ) : & polyline . points . back ( ) ) ;
}
private :
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ExtrusionPathFragmentEndPointAccessor & operator = ( const ExtrusionPathFragmentEndPointAccessor & ) {
return * this ;
}
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const std : : vector < ExtrusionPathFragment > & m_path_fragments ;
} ;
const coord_t search_radius = 7 ;
ClosestPointInRadiusLookup < ExtrusionPathFragmentEnd , ExtrusionPathFragmentEndPointAccessor > map_fragment_starts (
search_radius , ExtrusionPathFragmentEndPointAccessor ( path_fragments ) ) ;
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for ( size_t i_overlapping_layer = 0 ; i_overlapping_layer < = n_overlapping_layers ; + + i_overlapping_layer ) {
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const Polylines & polylines = path_fragments [ i_overlapping_layer ] . polylines ;
for ( size_t i_polyline = 0 ; i_polyline < polylines . size ( ) ; + + i_polyline ) {
// Map a starting point of a polyline to a pair of <layer, polyline>
if ( polylines [ i_polyline ] . points . size ( ) > = 2 ) {
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map_fragment_starts . insert ( ExtrusionPathFragmentEnd ( i_overlapping_layer , i_polyline , true ) ) ;
map_fragment_starts . insert ( ExtrusionPathFragmentEnd ( i_overlapping_layer , i_polyline , false ) ) ;
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}
}
}
// For each source path:
for ( size_t i_path = 0 ; i_path < path_ends . size ( ) ; + + i_path ) {
const Point & pt_start = path_ends [ i_path ] . first ;
const Point & pt_end = path_ends [ i_path ] . second ;
Point pt_current = pt_start ;
// Find a chain of fragments with the original / reduced print height.
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ExtrusionMultiPath multipath ;
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for ( ; ; ) {
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// Find a closest end point to pt_current.
std : : pair < const ExtrusionPathFragmentEnd * , coordf_t > end_and_dist2 = map_fragment_starts . find ( pt_current ) ;
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// There may be a bug in Clipper flipping the order of two last points in a fragment?
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// assert(end_and_dist2.first != nullptr);
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assert ( end_and_dist2 . first = = nullptr | | end_and_dist2 . second < search_radius * search_radius ) ;
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if ( end_and_dist2 . first = = nullptr ) {
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// New fragment connecting to pt_current was not found.
// Verify that the last point found is close to the original end point of the unfragmented path.
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//const double d2 = (pt_end - pt_current).cast<double>.squaredNorm();
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//assert(d2 < coordf_t(search_radius * search_radius));
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// End of the path.
break ;
}
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const ExtrusionPathFragmentEnd & fragment_end_min = * end_and_dist2 . first ;
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// Fragment to consume.
ExtrusionPathFragment & frag = path_fragments [ fragment_end_min . layer_idx ] ;
Polyline & frag_polyline = frag . polylines [ fragment_end_min . polyline_idx ] ;
// Path to append the fragment to.
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ExtrusionPath * path = multipath . paths . empty ( ) ? nullptr : & multipath . paths . back ( ) ;
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if ( path ! = nullptr ) {
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// Verify whether the path is compatible with the current fragment.
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assert ( this_layer . layer_type = = PrintObjectSupportMaterial : : sltBottomContact | | path - > height ! = frag . height | | path - > mm3_per_mm ! = frag . mm3_per_mm ) ;
if ( path - > height ! = frag . height | | path - > mm3_per_mm ! = frag . mm3_per_mm ) {
path = nullptr ;
}
// Merging with the previous path. This can only happen if the current layer was reduced by a base layer, which was split into a base and interface layer.
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}
if ( path = = nullptr ) {
// Allocate a new path.
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multipath . paths . push_back ( ExtrusionPath ( extrusion_role , frag . mm3_per_mm , frag . width , frag . height ) ) ;
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path = & multipath . paths . back ( ) ;
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}
// The Clipper library may flip the order of the clipped polylines arbitrarily.
// Reverse the source polyline, if connecting to the end.
if ( ! fragment_end_min . is_start )
frag_polyline . reverse ( ) ;
// Enforce exact overlap of the end points of successive fragments.
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assert ( frag_polyline . points . front ( ) = = pt_current ) ;
frag_polyline . points . front ( ) = pt_current ;
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// Don't repeat the first point.
if ( ! path - > polyline . points . empty ( ) )
path - > polyline . points . pop_back ( ) ;
// Consume the fragment's polyline, remove it from the input fragments, so it will be ignored the next time.
path - > polyline . append ( std : : move ( frag_polyline ) ) ;
frag_polyline . points . clear ( ) ;
pt_current = path - > polyline . points . back ( ) ;
if ( pt_current = = pt_end ) {
// End of the path.
break ;
}
}
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if ( ! multipath . paths . empty ( ) ) {
if ( multipath . paths . size ( ) = = 1 ) {
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// This path was not fragmented.
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extrusions_in_out . push_back ( new ExtrusionPath ( std : : move ( multipath . paths . front ( ) ) ) ) ;
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} else {
// This path was fragmented. Copy the collection as a whole object, so the order inside the collection will not be changed
// during the chaining of extrusions_in_out.
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extrusions_in_out . push_back ( new ExtrusionMultiPath ( std : : move ( multipath ) ) ) ;
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}
}
}
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// If there are any non-consumed fragments, add them separately.
//FIXME this shall not happen, if the Clipper works as expected and all paths split to fragments could be re-connected.
for ( auto it_fragment = path_fragments . begin ( ) ; it_fragment ! = path_fragments . end ( ) ; + + it_fragment )
extrusion_entities_append_paths ( extrusions_in_out , std : : move ( it_fragment - > polylines ) , extrusion_role , it_fragment - > mm3_per_mm , it_fragment - > width , it_fragment - > height ) ;
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}
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void PrintObjectSupportMaterial : : generate_toolpaths (
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const PrintObject & object ,
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const MyLayersPtr & raft_layers ,
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const MyLayersPtr & bottom_contacts ,
const MyLayersPtr & top_contacts ,
const MyLayersPtr & intermediate_layers ,
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const MyLayersPtr & interface_layers ) const
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{
// Slic3r::debugf "Generating patterns\n";
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// loop_interface_processor with a given circle radius.
LoopInterfaceProcessor loop_interface_processor ( 1.5 * m_support_material_interface_flow . scaled_width ( ) ) ;
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loop_interface_processor . n_contact_loops = this - > has_contact_loops ( ) ? 1 : 0 ;
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float base_angle = Geometry : : deg2rad ( float ( m_object_config - > support_material_angle . value ) ) ;
float interface_angle = Geometry : : deg2rad ( float ( m_object_config - > support_material_angle . value + 90. ) ) ;
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coordf_t interface_spacing = m_object_config - > support_material_interface_spacing . value + m_support_material_interface_flow . spacing ( ) ;
coordf_t interface_density = std : : min ( 1. , m_support_material_interface_flow . spacing ( ) / interface_spacing ) ;
coordf_t support_spacing = m_object_config - > support_material_spacing . value + m_support_material_flow . spacing ( ) ;
coordf_t support_density = std : : min ( 1. , m_support_material_flow . spacing ( ) / support_spacing ) ;
if ( m_object_config - > support_material_interface_layers . value = = 0 ) {
// No interface layers allowed, print everything with the base support pattern.
interface_spacing = support_spacing ;
interface_density = support_density ;
}
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// Prepare fillers.
SupportMaterialPattern support_pattern = m_object_config - > support_material_pattern ;
bool with_sheath = m_object_config - > support_material_with_sheath ;
InfillPattern infill_pattern ;
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std : : vector < float > angles ;
angles . push_back ( base_angle ) ;
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switch ( support_pattern ) {
case smpRectilinearGrid :
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angles . push_back ( interface_angle ) ;
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// fall through
case smpRectilinear :
infill_pattern = ipRectilinear ;
break ;
case smpHoneycomb :
infill_pattern = ipHoneycomb ;
break ;
}
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BoundingBox bbox_object ( Point ( - scale_ ( 1. ) , - scale_ ( 1.0 ) ) , Point ( scale_ ( 1. ) , scale_ ( 1. ) ) ) ;
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// const coordf_t link_max_length_factor = 3.;
const coordf_t link_max_length_factor = 0. ;
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float raft_angle_1st_layer = 0.f ;
float raft_angle_base = 0.f ;
float raft_angle_interface = 0.f ;
if ( m_slicing_params . base_raft_layers > 1 ) {
// There are all raft layer types (1st layer, base, interface & contact layers) available.
raft_angle_1st_layer = interface_angle ;
raft_angle_base = base_angle ;
raft_angle_interface = interface_angle ;
} else if ( m_slicing_params . base_raft_layers = = 1 | | m_slicing_params . interface_raft_layers > 1 ) {
// 1st layer, interface & contact layers available.
raft_angle_1st_layer = base_angle ;
if ( this - > has_support ( ) )
// Print 1st layer at 45 degrees from both the interface and base angles as both can land on the 1st layer.
raft_angle_1st_layer + = 0.7854f ;
raft_angle_interface = interface_angle ;
} else if ( m_slicing_params . interface_raft_layers = = 1 ) {
// Only the contact raft layer is non-empty, which will be printed as the 1st layer.
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assert ( m_slicing_params . base_raft_layers = = 0 ) ;
assert ( m_slicing_params . interface_raft_layers = = 1 ) ;
assert ( m_slicing_params . raft_layers ( ) = = 1 & & raft_layers . size ( ) = = 0 ) ;
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} else {
// No raft.
assert ( m_slicing_params . base_raft_layers = = 0 ) ;
assert ( m_slicing_params . interface_raft_layers = = 0 ) ;
assert ( m_slicing_params . raft_layers ( ) = = 0 & & raft_layers . size ( ) = = 0 ) ;
}
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// Insert the raft base layers.
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size_t n_raft_layers = size_t ( std : : max ( 0 , int ( m_slicing_params . raft_layers ( ) ) - 1 ) ) ;
tbb : : parallel_for ( tbb : : blocked_range < size_t > ( 0 , n_raft_layers ) ,
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[ this , & object , & raft_layers ,
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infill_pattern , & bbox_object , support_density , interface_density , raft_angle_1st_layer , raft_angle_base , raft_angle_interface , link_max_length_factor , with_sheath ]
( const tbb : : blocked_range < size_t > & range ) {
for ( size_t support_layer_id = range . begin ( ) ; support_layer_id < range . end ( ) ; + + support_layer_id )
{
assert ( support_layer_id < raft_layers . size ( ) ) ;
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SupportLayer & support_layer = * object . support_layers ( ) [ support_layer_id ] ;
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assert ( support_layer . support_fills . entities . empty ( ) ) ;
MyLayer & raft_layer = * raft_layers [ support_layer_id ] ;
std : : unique_ptr < Fill > filler_interface = std : : unique_ptr < Fill > ( Fill : : new_from_type ( ipRectilinear ) ) ;
std : : unique_ptr < Fill > filler_support = std : : unique_ptr < Fill > ( Fill : : new_from_type ( infill_pattern ) ) ;
filler_interface - > set_bounding_box ( bbox_object ) ;
filler_support - > set_bounding_box ( bbox_object ) ;
// Print the support base below the support columns, or the support base for the support columns plus the contacts.
if ( support_layer_id > 0 ) {
Polygons to_infill_polygons = ( support_layer_id < m_slicing_params . base_raft_layers ) ?
raft_layer . polygons :
//FIXME misusing contact_polygons for support columns.
( ( raft_layer . contact_polygons = = nullptr ) ? Polygons ( ) : * raft_layer . contact_polygons ) ;
if ( ! to_infill_polygons . empty ( ) ) {
Flow flow ( float ( m_support_material_flow . width ) , float ( raft_layer . height ) , m_support_material_flow . nozzle_diameter , raft_layer . bridging ) ;
// find centerline of the external loop/extrusions
ExPolygons to_infill = ( support_layer_id = = 0 | | ! with_sheath ) ?
// union_ex(base_polygons, true) :
offset2_ex ( to_infill_polygons , float ( SCALED_EPSILON ) , float ( - SCALED_EPSILON ) ) :
offset2_ex ( to_infill_polygons , float ( SCALED_EPSILON ) , float ( - SCALED_EPSILON - 0.5 * flow . scaled_width ( ) ) ) ;
if ( ! to_infill . empty ( ) & & with_sheath ) {
// Draw a perimeter all around the support infill. This makes the support stable, but difficult to remove.
// TODO: use brim ordering algorithm
to_infill_polygons = to_polygons ( to_infill ) ;
// TODO: use offset2_ex()
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to_infill = offset_ex ( to_infill , float ( - 0.4 * flow . scaled_spacing ( ) ) ) ;
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extrusion_entities_append_paths (
support_layer . support_fills . entities ,
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to_polylines ( std : : move ( to_infill_polygons ) ) ,
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erSupportMaterial , flow . mm3_per_mm ( ) , flow . width , flow . height ) ;
}
if ( ! to_infill . empty ( ) ) {
// We don't use $base_flow->spacing because we need a constant spacing
// value that guarantees that all layers are correctly aligned.
Fill * filler = filler_support . get ( ) ;
filler - > angle = raft_angle_base ;
filler - > spacing = m_support_material_flow . spacing ( ) ;
filler - > link_max_length = coord_t ( scale_ ( filler - > spacing * link_max_length_factor / support_density ) ) ;
fill_expolygons_generate_paths (
// Destination
support_layer . support_fills . entities ,
// Regions to fill
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std : : move ( to_infill ) ,
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// Filler and its parameters
filler , float ( support_density ) ,
// Extrusion parameters
erSupportMaterial , flow ) ;
}
}
}
Fill * filler = filler_interface . get ( ) ;
Flow flow = m_first_layer_flow ;
float density = 0.f ;
if ( support_layer_id = = 0 ) {
// Base flange.
filler - > angle = raft_angle_1st_layer ;
filler - > spacing = m_first_layer_flow . spacing ( ) ;
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// 70% of density on the 1st layer.
density = 0.7f ;
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} else if ( support_layer_id > = m_slicing_params . base_raft_layers ) {
filler - > angle = raft_angle_interface ;
// We don't use $base_flow->spacing because we need a constant spacing
// value that guarantees that all layers are correctly aligned.
filler - > spacing = m_support_material_flow . spacing ( ) ;
flow = Flow ( float ( m_support_material_interface_flow . width ) , float ( raft_layer . height ) , m_support_material_flow . nozzle_diameter , raft_layer . bridging ) ;
density = float ( interface_density ) ;
} else
continue ;
filler - > link_max_length = coord_t ( scale_ ( filler - > spacing * link_max_length_factor / density ) ) ;
fill_expolygons_generate_paths (
// Destination
support_layer . support_fills . entities ,
// Regions to fill
offset2_ex ( raft_layer . polygons , float ( SCALED_EPSILON ) , float ( - SCALED_EPSILON ) ) ,
// Filler and its parameters
filler , density ,
// Extrusion parameters
( support_layer_id < m_slicing_params . base_raft_layers ) ? erSupportMaterial : erSupportMaterialInterface , flow ) ;
}
} ) ;
struct LayerCacheItem {
LayerCacheItem ( MyLayerExtruded * layer_extruded = nullptr ) : layer_extruded ( layer_extruded ) { }
MyLayerExtruded * layer_extruded ;
std : : vector < MyLayer * > overlapping ;
} ;
struct LayerCache {
MyLayerExtruded bottom_contact_layer ;
MyLayerExtruded top_contact_layer ;
MyLayerExtruded base_layer ;
MyLayerExtruded interface_layer ;
std : : vector < LayerCacheItem > overlaps ;
} ;
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std : : vector < LayerCache > layer_caches ( object . support_layers ( ) . size ( ) , LayerCache ( ) ) ;
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tbb : : parallel_for ( tbb : : blocked_range < size_t > ( n_raft_layers , object . support_layers ( ) . size ( ) ) ,
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[ this , & object , & bottom_contacts , & top_contacts , & intermediate_layers , & interface_layers , & layer_caches , & loop_interface_processor ,
infill_pattern , & bbox_object , support_density , interface_density , interface_angle , & angles , link_max_length_factor , with_sheath ]
( const tbb : : blocked_range < size_t > & range ) {
// Indices of the 1st layer in their respective container at the support layer height.
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size_t idx_layer_bottom_contact = size_t ( - 1 ) ;
size_t idx_layer_top_contact = size_t ( - 1 ) ;
size_t idx_layer_intermediate = size_t ( - 1 ) ;
size_t idx_layer_inteface = size_t ( - 1 ) ;
std : : unique_ptr < Fill > filler_interface = std : : unique_ptr < Fill > ( Fill : : new_from_type ( m_slicing_params . soluble_interface ? ipConcentric : ipRectilinear ) ) ;
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std : : unique_ptr < Fill > filler_support = std : : unique_ptr < Fill > ( Fill : : new_from_type ( infill_pattern ) ) ;
filler_interface - > set_bounding_box ( bbox_object ) ;
filler_support - > set_bounding_box ( bbox_object ) ;
for ( size_t support_layer_id = range . begin ( ) ; support_layer_id < range . end ( ) ; + + support_layer_id )
{
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SupportLayer & support_layer = * object . support_layers ( ) [ support_layer_id ] ;
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LayerCache & layer_cache = layer_caches [ support_layer_id ] ;
// Find polygons with the same print_z.
MyLayerExtruded & bottom_contact_layer = layer_cache . bottom_contact_layer ;
MyLayerExtruded & top_contact_layer = layer_cache . top_contact_layer ;
MyLayerExtruded & base_layer = layer_cache . base_layer ;
MyLayerExtruded & interface_layer = layer_cache . interface_layer ;
// Increment the layer indices to find a layer at support_layer.print_z.
{
auto fun = [ & support_layer ] ( const MyLayer * l ) { return l - > print_z > = support_layer . print_z - EPSILON ; } ;
idx_layer_bottom_contact = idx_higher_or_equal ( bottom_contacts , idx_layer_bottom_contact , fun ) ;
idx_layer_top_contact = idx_higher_or_equal ( top_contacts , idx_layer_top_contact , fun ) ;
idx_layer_intermediate = idx_higher_or_equal ( intermediate_layers , idx_layer_intermediate , fun ) ;
idx_layer_inteface = idx_higher_or_equal ( interface_layers , idx_layer_inteface , fun ) ;
}
// Copy polygons from the layers.
if ( idx_layer_bottom_contact < bottom_contacts . size ( ) & & bottom_contacts [ idx_layer_bottom_contact ] - > print_z < support_layer . print_z + EPSILON )
bottom_contact_layer . layer = bottom_contacts [ idx_layer_bottom_contact ] ;
if ( idx_layer_top_contact < top_contacts . size ( ) & & top_contacts [ idx_layer_top_contact ] - > print_z < support_layer . print_z + EPSILON )
top_contact_layer . layer = top_contacts [ idx_layer_top_contact ] ;
if ( idx_layer_inteface < interface_layers . size ( ) & & interface_layers [ idx_layer_inteface ] - > print_z < support_layer . print_z + EPSILON )
interface_layer . layer = interface_layers [ idx_layer_inteface ] ;
if ( idx_layer_intermediate < intermediate_layers . size ( ) & & intermediate_layers [ idx_layer_intermediate ] - > print_z < support_layer . print_z + EPSILON )
base_layer . layer = intermediate_layers [ idx_layer_intermediate ] ;
if ( m_object_config - > support_material_interface_layers = = 0 ) {
// If no interface layers were requested, we treat the contact layer exactly as a generic base layer.
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if ( m_can_merge_support_regions ) {
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if ( base_layer . could_merge ( top_contact_layer ) )
base_layer . merge ( std : : move ( top_contact_layer ) ) ;
else if ( base_layer . empty ( ) & & ! top_contact_layer . empty ( ) & & ! top_contact_layer . layer - > bridging )
std : : swap ( base_layer , top_contact_layer ) ;
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if ( base_layer . could_merge ( bottom_contact_layer ) )
base_layer . merge ( std : : move ( bottom_contact_layer ) ) ;
else if ( base_layer . empty ( ) & & ! bottom_contact_layer . empty ( ) & & ! bottom_contact_layer . layer - > bridging )
std : : swap ( base_layer , bottom_contact_layer ) ;
}
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} else {
loop_interface_processor . generate ( top_contact_layer , m_support_material_interface_flow ) ;
// If no loops are allowed, we treat the contact layer exactly as a generic interface layer.
// Merge interface_layer into top_contact_layer, as the top_contact_layer is not synchronized and therefore it will be used
// to trim other layers.
if ( top_contact_layer . could_merge ( interface_layer ) )
top_contact_layer . merge ( std : : move ( interface_layer ) ) ;
}
if ( ! interface_layer . empty ( ) & & ! base_layer . empty ( ) ) {
// turn base support into interface when it's contained in our holes
// (this way we get wider interface anchoring)
//FIXME one wants to fill in the inner most holes of the interfaces, not all the holes.
Polygons islands = top_level_islands ( interface_layer . layer - > polygons ) ;
polygons_append ( interface_layer . layer - > polygons , intersection ( base_layer . layer - > polygons , islands ) ) ;
base_layer . layer - > polygons = diff ( base_layer . layer - > polygons , islands ) ;
}
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// Top and bottom contacts, interface layers.
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for ( size_t i = 0 ; i < 3 ; + + i ) {
MyLayerExtruded & layer_ex = ( i = = 0 ) ? top_contact_layer : ( i = = 1 ? bottom_contact_layer : interface_layer ) ;
if ( layer_ex . empty ( ) | | layer_ex . polygons_to_extrude ( ) . empty ( ) )
continue ;
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//FIXME When paralellizing, each thread shall have its own copy of the fillers.
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bool interface_as_base = ( & layer_ex = = & interface_layer ) & & m_object_config - > support_material_interface_layers . value = = 0 ;
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//FIXME Bottom interfaces are extruded with the briding flow. Some bridging layers have its height slightly reduced, therefore
// the bridging flow does not quite apply. Reduce the flow to area of an ellipse? (A = pi * a * b)
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Flow interface_flow (
float ( layer_ex . layer - > bridging ? layer_ex . layer - > height : ( interface_as_base ? m_support_material_flow . width : m_support_material_interface_flow . width ) ) ,
float ( layer_ex . layer - > height ) ,
m_support_material_interface_flow . nozzle_diameter ,
layer_ex . layer - > bridging ) ;
filler_interface - > angle = interface_as_base ?
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// If zero interface layers are configured, use the same angle as for the base layers.
angles [ support_layer_id % angles . size ( ) ] :
// Use interface angle for the interface layers.
interface_angle ;
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filler_interface - > spacing = m_support_material_interface_flow . spacing ( ) ;
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filler_interface - > link_max_length = coord_t ( scale_ ( filler_interface - > spacing * link_max_length_factor / interface_density ) ) ;
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fill_expolygons_generate_paths (
// Destination
layer_ex . extrusions ,
// Regions to fill
union_ex ( layer_ex . polygons_to_extrude ( ) , true ) ,
// Filler and its parameters
filler_interface . get ( ) , float ( interface_density ) ,
// Extrusion parameters
erSupportMaterialInterface , interface_flow ) ;
}
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// Base support or flange.
if ( ! base_layer . empty ( ) & & ! base_layer . polygons_to_extrude ( ) . empty ( ) ) {
//FIXME When paralellizing, each thread shall have its own copy of the fillers.
Fill * filler = filler_support . get ( ) ;
filler - > angle = angles [ support_layer_id % angles . size ( ) ] ;
// We don't use $base_flow->spacing because we need a constant spacing
// value that guarantees that all layers are correctly aligned.
2017-03-28 11:46:31 +00:00
Flow flow (
float ( base_layer . layer - > bridging ? base_layer . layer - > height : m_support_material_flow . width ) ,
float ( base_layer . layer - > height ) ,
m_support_material_flow . nozzle_diameter ,
base_layer . layer - > bridging ) ;
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filler - > spacing = m_support_material_flow . spacing ( ) ;
filler - > link_max_length = coord_t ( scale_ ( filler - > spacing * link_max_length_factor / support_density ) ) ;
float density = float ( support_density ) ;
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// find centerline of the external loop/extrusions
ExPolygons to_infill = ( support_layer_id = = 0 | | ! with_sheath ) ?
// union_ex(base_polygons, true) :
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offset2_ex ( base_layer . polygons_to_extrude ( ) , float ( SCALED_EPSILON ) , float ( - SCALED_EPSILON ) ) :
offset2_ex ( base_layer . polygons_to_extrude ( ) , float ( SCALED_EPSILON ) , float ( - SCALED_EPSILON - 0.5 * flow . scaled_width ( ) ) ) ;
if ( base_layer . layer - > bottom_z < EPSILON ) {
// Base flange (the 1st layer).
filler = filler_interface . get ( ) ;
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filler - > angle = Geometry : : deg2rad ( float ( m_object_config - > support_material_angle . value + 90. ) ) ;
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density = 0.5f ;
flow = m_first_layer_flow ;
// use the proper spacing for first layer as we don't need to align
// its pattern to the other layers
//FIXME When paralellizing, each thread shall have its own copy of the fillers.
filler - > spacing = flow . spacing ( ) ;
filler - > link_max_length = coord_t ( scale_ ( filler - > spacing * link_max_length_factor / density ) ) ;
} else if ( with_sheath ) {
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// Draw a perimeter all around the support infill. This makes the support stable, but difficult to remove.
// TODO: use brim ordering algorithm
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Polygons to_infill_polygons = to_polygons ( to_infill ) ;
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// TODO: use offset2_ex()
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to_infill = offset_ex ( to_infill , - 0.4f * float ( flow . scaled_spacing ( ) ) ) ;
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extrusion_entities_append_paths (
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base_layer . extrusions ,
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to_polylines ( std : : move ( to_infill_polygons ) ) ,
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erSupportMaterial , flow . mm3_per_mm ( ) , flow . width , flow . height ) ;
}
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fill_expolygons_generate_paths (
// Destination
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base_layer . extrusions ,
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// Regions to fill
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std : : move ( to_infill ) ,
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// Filler and its parameters
filler , density ,
// Extrusion parameters
erSupportMaterial , flow ) ;
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}
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layer_cache . overlaps . reserve ( 4 ) ;
if ( ! bottom_contact_layer . empty ( ) )
layer_cache . overlaps . push_back ( & bottom_contact_layer ) ;
if ( ! top_contact_layer . empty ( ) )
layer_cache . overlaps . push_back ( & top_contact_layer ) ;
if ( ! interface_layer . empty ( ) )
layer_cache . overlaps . push_back ( & interface_layer ) ;
if ( ! base_layer . empty ( ) )
layer_cache . overlaps . push_back ( & base_layer ) ;
// Sort the layers with the same print_z coordinate by their heights, thickest first.
std : : sort ( layer_cache . overlaps . begin ( ) , layer_cache . overlaps . end ( ) , [ ] ( const LayerCacheItem & lc1 , const LayerCacheItem & lc2 ) { return lc1 . layer_extruded - > layer - > height > lc2 . layer_extruded - > layer - > height ; } ) ;
// Collect the support areas with this print_z into islands, as there is no need
// for retraction over these islands.
Polygons polys ;
// Collect the extrusions, sorted by the bottom extrusion height.
for ( LayerCacheItem & layer_cache_item : layer_cache . overlaps ) {
// Collect islands to polys.
layer_cache_item . layer_extruded - > polygons_append ( polys ) ;
// The print_z of the top contact surfaces and bottom_z of the bottom contact surfaces are "free"
// in a sense that they are not synchronized with other support layers. As the top and bottom contact surfaces
// are inflated to achieve a better anchoring, it may happen, that these surfaces will at least partially
// overlap in Z with another support layers, leading to over-extrusion.
// Mitigate the over-extrusion by modulating the extrusion rate over these regions.
// The print head will follow the same print_z, but the layer thickness will be reduced
// where it overlaps with another support layer.
//FIXME When printing a briging path, what is an equivalent height of the squished extrudate of the same width?
// Collect overlapping top/bottom surfaces.
layer_cache_item . overlapping . reserve ( 16 ) ;
coordf_t bottom_z = layer_cache_item . layer_extruded - > layer - > bottom_print_z ( ) + EPSILON ;
for ( int i = int ( idx_layer_bottom_contact ) - 1 ; i > = 0 & & bottom_contacts [ i ] - > print_z > bottom_z ; - - i )
layer_cache_item . overlapping . push_back ( bottom_contacts [ i ] ) ;
for ( int i = int ( idx_layer_top_contact ) - 1 ; i > = 0 & & top_contacts [ i ] - > print_z > bottom_z ; - - i )
layer_cache_item . overlapping . push_back ( top_contacts [ i ] ) ;
if ( layer_cache_item . layer_extruded - > layer - > layer_type = = sltBottomContact ) {
// Bottom contact layer may overlap with a base layer, which may be changed to interface layer.
for ( int i = int ( idx_layer_intermediate ) - 1 ; i > = 0 & & intermediate_layers [ i ] - > print_z > bottom_z ; - - i )
layer_cache_item . overlapping . push_back ( intermediate_layers [ i ] ) ;
for ( int i = int ( idx_layer_inteface ) - 1 ; i > = 0 & & interface_layers [ i ] - > print_z > bottom_z ; - - i )
layer_cache_item . overlapping . push_back ( interface_layers [ i ] ) ;
}
std : : sort ( layer_cache_item . overlapping . begin ( ) , layer_cache_item . overlapping . end ( ) , MyLayersPtrCompare ( ) ) ;
}
if ( ! polys . empty ( ) )
expolygons_append ( support_layer . support_islands . expolygons , union_ex ( polys ) ) ;
/* {
require " Slic3r/SVG.pm " ;
Slic3r : : SVG : : output ( " islands_ " . $ z . " .svg " ,
red_expolygons = > union_ex ( $ contact ) ,
green_expolygons = > union_ex ( $ interface ) ,
green_polylines = > [ map $ _ - > unpack - > polyline , @ { $ layer - > support_contact_fills } ] ,
polylines = > [ map $ _ - > unpack - > polyline , @ { $ layer - > support_fills } ] ,
) ;
} */
} // for each support_layer_id
} ) ;
// Now modulate the support layer height in parallel.
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tbb : : parallel_for ( tbb : : blocked_range < size_t > ( n_raft_layers , object . support_layers ( ) . size ( ) ) ,
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[ this , & object , & layer_caches ]
( const tbb : : blocked_range < size_t > & range ) {
for ( size_t support_layer_id = range . begin ( ) ; support_layer_id < range . end ( ) ; + + support_layer_id ) {
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SupportLayer & support_layer = * object . support_layers ( ) [ support_layer_id ] ;
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LayerCache & layer_cache = layer_caches [ support_layer_id ] ;
for ( LayerCacheItem & layer_cache_item : layer_cache . overlaps ) {
modulate_extrusion_by_overlapping_layers ( layer_cache_item . layer_extruded - > extrusions , * layer_cache_item . layer_extruded - > layer , layer_cache_item . overlapping ) ;
support_layer . support_fills . append ( std : : move ( layer_cache_item . layer_extruded - > extrusions ) ) ;
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}
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}
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} ) ;
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}
/*
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void PrintObjectSupportMaterial : : clip_by_pillars (
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const PrintObject & object ,
LayersPtr & bottom_contacts ,
LayersPtr & top_contacts ,
LayersPtr & intermediate_contacts ) ;
{
// this prevents supplying an empty point set to BoundingBox constructor
if ( top_contacts . empty ( ) )
return ;
coord_t pillar_size = scale_ ( PILLAR_SIZE ) ;
coord_t pillar_spacing = scale_ ( PILLAR_SPACING ) ;
// A regular grid of pillars, filling the 2D bounding box.
Polygons grid ;
{
// Rectangle with a side of 2.5x2.5mm.
Polygon pillar ;
pillar . points . push_back ( Point ( 0 , 0 ) ) ;
pillar . points . push_back ( Point ( pillar_size , 0 ) ) ;
pillar . points . push_back ( Point ( pillar_size , pillar_size ) ) ;
pillar . points . push_back ( Point ( 0 , pillar_size ) ) ;
// 2D bounding box of the projection of all contact polygons.
BoundingBox bbox ;
for ( LayersPtr : : const_iterator it = top_contacts . begin ( ) ; it ! = top_contacts . end ( ) ; + + it )
bbox . merge ( get_extents ( ( * it ) - > polygons ) ) ;
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grid . reserve ( size_t ( ceil ( bb . size ( ) ( 0 ) / pillar_spacing ) ) * size_t ( ceil ( bb . size ( ) ( 1 ) / pillar_spacing ) ) ) ;
for ( coord_t x = bb . min ( 0 ) ; x < = bb . max ( 0 ) - pillar_size ; x + = pillar_spacing ) {
for ( coord_t y = bb . min ( 1 ) ; y < = bb . max ( 1 ) - pillar_size ; y + = pillar_spacing ) {
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grid . push_back ( pillar ) ;
for ( size_t i = 0 ; i < pillar . points . size ( ) ; + + i )
grid . back ( ) . points [ i ] . translate ( Point ( x , y ) ) ;
}
}
}
// add pillars to every layer
for my $ i ( 0. . n_support_z ) {
$ shape - > [ $ i ] = [ @ $ grid ] ;
}
// build capitals
for my $ i ( 0. . n_support_z ) {
my $ z = $ support_z - > [ $ i ] ;
my $ capitals = intersection (
$ grid ,
$ contact - > { $ z } // [],
) ;
// work on one pillar at time (if any) to prevent the capitals from being merged
// but store the contact area supported by the capital because we need to make
// sure nothing is left
my $ contact_supported_by_capitals = [ ] ;
foreach my $ capital ( @ $ capitals ) {
// enlarge capital tops
$ capital = offset ( [ $ capital ] , + ( $ pillar_spacing - $ pillar_size ) / 2 ) ;
push @ $ contact_supported_by_capitals , @ $ capital ;
for ( my $ j = $ i - 1 ; $ j > = 0 ; $ j - - ) {
my $ jz = $ support_z - > [ $ j ] ;
$ capital = offset ( $ capital , - $ self - > interface_flow - > scaled_width / 2 ) ;
last if ! @ $ capitals ;
push @ { $ shape - > [ $ j ] } , @ $ capital ;
}
}
// Capitals will not generally cover the whole contact area because there will be
// remainders. For now we handle this situation by projecting such unsupported
// areas to the ground, just like we would do with a normal support.
my $ contact_not_supported_by_capitals = diff (
$ contact - > { $ z } // [],
$ contact_supported_by_capitals ,
) ;
if ( @ $ contact_not_supported_by_capitals ) {
for ( my $ j = $ i - 1 ; $ j > = 0 ; $ j - - ) {
push @ { $ shape - > [ $ j ] } , @ $ contact_not_supported_by_capitals ;
}
}
}
}
sub clip_with_shape {
my ( $ self , $ support , $ shape ) = @ _ ;
foreach my $ i ( keys % $ support ) {
// don't clip bottom layer with shape so that we
// can generate a continuous base flange
// also don't clip raft layers
next if $ i = = 0 ;
next if $ i < $ self - > object_config - > raft_layers ;
$ support - > { $ i } = intersection (
$ support - > { $ i } ,
$ shape - > [ $ i ] ,
) ;
}
}
*/
} // namespace Slic3r