package Slic3r::Print; use Moo; use File::Basename qw(basename fileparse); use File::Spec; use List::Util qw(max first); use Math::ConvexHull::MonotoneChain qw(convex_hull); use Slic3r::ExtrusionPath ':roles'; use Slic3r::Geometry qw(X Y Z X1 Y1 X2 Y2 MIN PI scale unscale move_points nearest_point); use Slic3r::Geometry::Clipper qw(diff_ex union_ex intersection_ex offset JT_ROUND JT_SQUARE); use Time::HiRes qw(gettimeofday tv_interval); has 'config' => (is => 'rw', default => sub { Slic3r::Config->new_from_defaults }, trigger => 1); has 'extra_variables' => (is => 'rw', default => sub {{}}); has 'objects' => (is => 'rw', default => sub {[]}); has 'total_extrusion_length' => (is => 'rw'); has 'processing_time' => (is => 'rw'); has 'extruders' => (is => 'rw', default => sub {[]}); has 'regions' => (is => 'rw', default => sub {[]}); has 'support_material_flow' => (is => 'rw'); has 'first_layer_support_material_flow' => (is => 'rw'); # ordered collection of extrusion paths to build skirt loops has 'skirt' => ( is => 'rw', #isa => 'ArrayRef[Slic3r::ExtrusionLoop]', default => sub { [] }, ); # ordered collection of extrusion paths to build a brim has 'brim' => ( is => 'rw', #isa => 'ArrayRef[Slic3r::ExtrusionLoop]', default => sub { [] }, ); sub BUILD { my $self = shift; # call this manually because the 'default' coderef doesn't trigger the trigger $self->_trigger_config; } sub _trigger_config { my $self = shift; # store config in a handy place $Slic3r::Config = $self->config; # legacy with existing config files $self->config->set('first_layer_height', $self->config->layer_height) if !$self->config->first_layer_height; $self->config->set_ifndef('small_perimeter_speed', $self->config->perimeter_speed); $self->config->set_ifndef('bridge_speed', $self->config->infill_speed); $self->config->set_ifndef('solid_infill_speed', $self->config->infill_speed); $self->config->set_ifndef('top_solid_infill_speed', $self->config->solid_infill_speed); $self->config->set_ifndef('top_solid_layers', $self->config->solid_layers); $self->config->set_ifndef('bottom_solid_layers', $self->config->solid_layers); # G-code flavors $self->config->set('extrusion_axis', 'A') if $self->config->gcode_flavor eq 'mach3'; $self->config->set('extrusion_axis', '') if $self->config->gcode_flavor eq 'no-extrusion'; } sub add_model { my $self = shift; my ($model) = @_; # append/merge materials and preserve a mapping between the original material ID # and our numeric material index my %materials = (); { my @material_ids = sort keys %{$model->materials}; @material_ids = (0) if !@material_ids; for (my $i = $self->regions_count; $i < @material_ids; $i++) { push @{$self->regions}, Slic3r::Print::Region->new; $materials{$material_ids[$i]} = $#{$self->regions}; } } foreach my $object (@{ $model->objects }) { my @meshes = (); # by region_id foreach my $volume (@{$object->volumes}) { # should the object contain multiple volumes of the same material, merge them my $region_id = defined $volume->material_id ? $materials{$volume->material_id} : 0; my $mesh = $volume->mesh->clone; $meshes[$region_id] = $meshes[$region_id] ? Slic3r::TriangleMesh->merge($meshes[$region_id], $mesh) : $mesh; } foreach my $mesh (@meshes) { next unless $mesh; $mesh->check_manifoldness; if ($object->instances) { # we ignore the per-instance rotation currently and only # consider the first one $mesh->rotate($object->instances->[0]->rotation); } $mesh->rotate($Slic3r::Config->rotate); $mesh->scale($Slic3r::Config->scale / &Slic3r::SCALING_FACTOR); } my $complete_mesh = Slic3r::TriangleMesh->merge(grep defined $_, @meshes); # initialize print object my $print_object = Slic3r::Print::Object->new( print => $self, meshes => [ @meshes ], size => [ $complete_mesh->size ], input_file => $object->input_file ); push @{$self->objects}, $print_object; # align object to origin { my @extents = $complete_mesh->extents; foreach my $mesh (grep defined $_, @meshes) { $mesh->move(map -$extents[$_][MIN], X,Y,Z); } } if ($object->instances) { # replace the default [0,0] instance with the custom ones @{$print_object->copies} = map [ scale $_->offset->[X], scale $_->offset->[Y] ], @{$object->instances}; } } } sub validate { my $self = shift; if ($Slic3r::Config->complete_objects) { # check horizontal clearance { my @a = (); for my $obj_idx (0 .. $#{$self->objects}) { my $clearance; { my @points = map [ @$_[X,Y] ], map @{$_->vertices}, @{$self->objects->[$obj_idx]->meshes}; my $convex_hull = Slic3r::Polygon->new(convex_hull(\@points)); $clearance = +($convex_hull->offset(scale $Slic3r::Config->extruder_clearance_radius / 2, 1, JT_ROUND))[0]; } for my $copy (@{$self->objects->[$obj_idx]->copies}) { my $copy_clearance = $clearance->clone; $copy_clearance->translate(@$copy); if (@{ intersection_ex(\@a, [$copy_clearance]) }) { die "Some objects are too close; your extruder will collide with them.\n"; } @a = map @$_, @{union_ex([ @a, $copy_clearance ])}; } } } # check vertical clearance { my @obj_copies = $self->object_copies; pop @obj_copies; # ignore the last copy: its height doesn't matter my $scaled_clearance = scale $Slic3r::Config->extruder_clearance_height; if (grep { +($_->size)[Z] > $scaled_clearance } map @{$self->objects->[$_->[0]]->meshes}, @obj_copies) { die "Some objects are too tall and cannot be printed without extruder collisions.\n"; } } } } sub init_extruders { my $self = shift; # map regions to extruders (ghetto mapping for now) my %extruder_mapping = map { $_ => $_ } 0..$#{$self->regions}; # initialize all extruder(s) we need my @used_extruders = ( 0, (map $self->config->get("${_}_extruder")-1, qw(perimeter infill support_material)), (values %extruder_mapping), ); for my $extruder_id (keys %{{ map {$_ => 1} @used_extruders }}) { $self->extruders->[$extruder_id] = Slic3r::Extruder->new( id => $extruder_id, map { $_ => $self->config->get($_)->[$extruder_id] // $self->config->get($_)->[0] } #/ @{&Slic3r::Extruder::OPTIONS} ); } # calculate default flows $Slic3r::flow = $self->extruders->[0]->make_flow( width => $self->config->extrusion_width, ); $Slic3r::first_layer_flow = $self->extruders->[0]->make_flow( layer_height => $self->config->get_value('first_layer_height'), width => $self->config->first_layer_extrusion_width, ); # calculate regions' flows for my $region_id (0 .. $#{$self->regions}) { my $region = $self->regions->[$region_id]; # per-role extruders and flows for (qw(perimeter infill)) { $region->extruders->{$_} = ($self->regions_count > 1) ? $self->extruders->[$extruder_mapping{$region_id}] : $self->extruders->[$self->config->get("${_}_extruder")-1]; $region->flows->{$_} = $region->extruders->{$_}->make_flow( width => $self->config->get("${_}_extrusion_width") || $self->config->extrusion_width, ); $region->first_layer_flows->{$_} = $region->extruders->{$_}->make_flow( layer_height => $self->config->get_value('first_layer_height'), width => $self->config->first_layer_extrusion_width, ); } } # calculate support material flow if ($self->config->support_material) { my $extruder = $self->extruders->[$self->config->support_material_extruder-1]; $self->support_material_flow($extruder->make_flow( width => $self->config->support_material_extrusion_width || $self->config->extrusion_width, )); $self->first_layer_support_material_flow($extruder->make_flow( layer_height => $self->config->get_value('first_layer_height'), width => $self->config->first_layer_extrusion_width, )); } Slic3r::debugf "Default flow width = %s (spacing = %s)\n", $Slic3r::flow->width, $Slic3r::flow->spacing; } sub object_copies { my $self = shift; my @oc = (); for my $obj_idx (0 .. $#{$self->objects}) { push @oc, map [ $obj_idx, $_ ], @{$self->objects->[$obj_idx]->copies}; } return @oc; } sub layer_count { my $self = shift; my $count = 0; foreach my $object (@{$self->objects}) { $count = @{$object->layers} if @{$object->layers} > $count; } return $count; } sub regions_count { my $self = shift; return scalar @{$self->regions}; } sub duplicate { my $self = shift; if ($Slic3r::Config->duplicate_grid->[X] > 1 || $Slic3r::Config->duplicate_grid->[Y] > 1) { if (@{$self->objects} > 1) { die "Grid duplication is not supported with multiple objects\n"; } my $object = $self->objects->[0]; # generate offsets for copies my $dist = scale $Slic3r::Config->duplicate_distance; @{$self->objects->[0]->copies} = (); for my $x_copy (1..$Slic3r::Config->duplicate_grid->[X]) { for my $y_copy (1..$Slic3r::Config->duplicate_grid->[Y]) { push @{$self->objects->[0]->copies}, [ ($object->size->[X] + $dist) * ($x_copy-1), ($object->size->[Y] + $dist) * ($y_copy-1), ]; } } } elsif ($Slic3r::Config->duplicate > 1) { foreach my $object (@{$self->objects}) { @{$object->copies} = map [0,0], 1..$Slic3r::Config->duplicate; } $self->arrange_objects; } } sub arrange_objects { my $self = shift; my $total_parts = scalar map @{$_->copies}, @{$self->objects}; my $partx = max(map $_->size->[X], @{$self->objects}); my $party = max(map $_->size->[Y], @{$self->objects}); my @positions = Slic3r::Geometry::arrange ($total_parts, $partx, $party, (map scale $_, @{$Slic3r::Config->bed_size}), scale $Slic3r::Config->min_object_distance, $self->config); @{$_->copies} = splice @positions, 0, scalar @{$_->copies} for @{$self->objects}; } sub bounding_box { my $self = shift; my @points = (); foreach my $obj_idx (0 .. $#{$self->objects}) { my $object = $self->objects->[$obj_idx]; foreach my $copy (@{$self->objects->[$obj_idx]->copies}) { push @points, [ $copy->[X], $copy->[Y] ], [ $copy->[X] + $object->size->[X], $copy->[Y] ], [ $copy->[X] + $object->size->[X], $copy->[Y] + $object->size->[Y] ], [ $copy->[X], $copy->[Y] + $object->size->[Y] ]; } } return Slic3r::Geometry::bounding_box(\@points); } sub size { my $self = shift; my @bb = $self->bounding_box; return [ $bb[X2] - $bb[X1], $bb[Y2] - $bb[Y1] ]; } sub export_gcode { my $self = shift; my %params = @_; $self->init_extruders; my $status_cb = $params{status_cb} || sub {}; my $t0 = [gettimeofday]; # skein the STL into layers # each layer has surfaces with holes $status_cb->(10, "Processing triangulated mesh"); $_->slice(keep_meshes => $params{keep_meshes}) for @{$self->objects}; # make perimeters # this will add a set of extrusion loops to each layer # as well as generate infill boundaries $status_cb->(20, "Generating perimeters"); $_->make_perimeters for @{$self->objects}; # simplify slices (both layer and region slices), # we only need the max resolution for perimeters foreach my $layer (map @{$_->layers}, @{$self->objects}) { $_->simplify(scale &Slic3r::RESOLUTION) for @{$layer->slices}, (map $_->expolygon, map @{$_->slices}, @{$layer->regions}); } # this will clip $layer->surfaces to the infill boundaries # and split them in top/bottom/internal surfaces; $status_cb->(30, "Detecting solid surfaces"); $_->detect_surfaces_type for @{$self->objects}; # decide what surfaces are to be filled $status_cb->(35, "Preparing infill surfaces"); $_->prepare_fill_surfaces for map @{$_->regions}, map @{$_->layers}, @{$self->objects}; # this will detect bridges and reverse bridges # and rearrange top/bottom/internal surfaces $status_cb->(45, "Detect bridges"); $_->process_bridges for map @{$_->regions}, map @{$_->layers}, @{$self->objects}; # detect which fill surfaces are near external layers # they will be split in internal and internal-solid surfaces $status_cb->(60, "Generating horizontal shells"); $_->discover_horizontal_shells for @{$self->objects}; # free memory $_->surfaces(undef) for map @{$_->regions}, map @{$_->layers}, @{$self->objects}; # combine fill surfaces to honor the "infill every N layers" option $status_cb->(70, "Combining infill"); $_->combine_infill for @{$self->objects}; # this will generate extrusion paths for each layer $status_cb->(80, "Infilling layers"); { my $fill_maker = Slic3r::Fill->new('print' => $self); Slic3r::parallelize( items => sub { my @items = (); # [obj_idx, layer_id] for my $obj_idx (0 .. $#{$self->objects}) { for my $region_id (0 .. ($self->regions_count-1)) { push @items, map [$obj_idx, $_, $region_id], 0..($self->objects->[$obj_idx]->layer_count-1); } } @items; }, thread_cb => sub { my $q = shift; $Slic3r::Geometry::Clipper::clipper = Math::Clipper->new; my $fills = {}; while (defined (my $obj_layer = $q->dequeue)) { my ($obj_idx, $layer_id, $region_id) = @$obj_layer; $fills->{$obj_idx} ||= {}; $fills->{$obj_idx}{$layer_id} ||= {}; $fills->{$obj_idx}{$layer_id}{$region_id} = [ $fill_maker->make_fill($self->objects->[$obj_idx]->layers->[$layer_id]->regions->[$region_id]), ]; } return $fills; }, collect_cb => sub { my $fills = shift; foreach my $obj_idx (keys %$fills) { my $object = $self->objects->[$obj_idx]; foreach my $layer_id (keys %{$fills->{$obj_idx}}) { my $layer = $object->layers->[$layer_id]; foreach my $region_id (keys %{$fills->{$obj_idx}{$layer_id}}) { $layer->regions->[$region_id]->fills($fills->{$obj_idx}{$layer_id}{$region_id}); } } } }, no_threads_cb => sub { foreach my $layerm (map @{$_->regions}, map @{$_->layers}, @{$self->objects}) { $layerm->fills([ $fill_maker->make_fill($layerm) ]); } }, ); } # generate support material if ($Slic3r::Config->support_material) { $status_cb->(85, "Generating support material"); $_->generate_support_material for @{$self->objects}; } # free memory (note that support material needs fill_surfaces) $_->fill_surfaces(undef) for map @{$_->regions}, map @{$_->layers}, @{$self->objects}; # make skirt $status_cb->(88, "Generating skirt"); $self->make_skirt; $self->make_brim; # must come after make_skirt # output everything to a G-code file my $output_file = $self->expanded_output_filepath($params{output_file}); $status_cb->(90, "Exporting G-code to $output_file"); $self->write_gcode($output_file); # run post-processing scripts if (@{$Slic3r::Config->post_process}) { $status_cb->(95, "Running post-processing scripts"); $Slic3r::Config->setenv; for (@{$Slic3r::Config->post_process}) { Slic3r::debugf " '%s' '%s'\n", $_, $output_file; system($_, $output_file); } } # output some statistics $self->processing_time(tv_interval($t0)); printf "Done. Process took %d minutes and %.3f seconds\n", int($self->processing_time/60), $self->processing_time - int($self->processing_time/60)*60; # TODO: more statistics! printf "Filament required: %.1fmm (%.1fcm3)\n", $self->total_extrusion_length, $self->total_extrusion_volume; } sub export_svg { my $self = shift; my %params = @_; # this shouldn't be needed, but we're currently relying on ->make_surfaces() which # calls ->perimeter_flow $self->init_extruders; $_->slice(keep_meshes => $params{keep_meshes}) for @{$self->objects}; $self->arrange_objects; my $output_file = $self->expanded_output_filepath($params{output_file}); $output_file =~ s/\.gcode$/.svg/i; open my $fh, ">", $output_file or die "Failed to open $output_file for writing\n"; print "Exporting to $output_file..."; my $print_size = $self->size; print $fh sprintf <<"EOF", unscale($print_size->[X]), unscale($print_size->[Y]); EOF my $print_polygon = sub { my ($polygon, $type) = @_; printf $fh qq{ \n}, $type, (join ' ', map { join ',', map unscale $_, @$_ } @$polygon), ($type eq 'contour' ? 'white' : 'black'); }; my @previous_layer_slices = (); for my $layer_id (0..$self->layer_count-1) { my @layers = map $_->layers->[$layer_id], @{$self->objects}; printf $fh qq{ \n}, $layer_id, unscale +(grep defined $_, @layers)[0]->slice_z; my @current_layer_slices = (); for my $obj_idx (0 .. $#{$self->objects}) { my $layer = $self->objects->[$obj_idx]->layers->[$layer_id] or next; # sort slices so that the outermost ones come first my @slices = sort { $a->contour->encloses_point($b->contour->[0]) ? 0 : 1 } @{$layer->slices}; foreach my $copy (@{$self->objects->[$obj_idx]->copies}) { foreach my $slice (@slices) { my $expolygon = $slice->clone; $expolygon->translate(@$copy); $print_polygon->($expolygon->contour, 'contour'); $print_polygon->($_, 'hole') for $expolygon->holes; push @current_layer_slices, $expolygon; } } } # generate support material if ($Slic3r::Config->support_material && $layer_id > 0) { my (@supported_slices, @unsupported_slices) = (); foreach my $expolygon (@current_layer_slices) { my $intersection = intersection_ex( [ map @$_, @previous_layer_slices ], $expolygon, ); @$intersection ? push @supported_slices, $expolygon : push @unsupported_slices, $expolygon; } my @supported_points = map @$_, @$_, @supported_slices; foreach my $expolygon (@unsupported_slices) { # look for the nearest point to this island among all # supported points my $support_point = nearest_point($expolygon->contour->[0], \@supported_points) or next; my $anchor_point = nearest_point($support_point, $expolygon->contour); printf $fh qq{ \n}, map @$_, $support_point, $anchor_point; } } print $fh qq{ \n}; @previous_layer_slices = @current_layer_slices; } print $fh "\n"; close $fh; print "Done.\n"; } sub make_skirt { my $self = shift; return unless $Slic3r::Config->skirts > 0; # collect points from all layers contained in skirt height my $skirt_height = $Slic3r::Config->skirt_height; $skirt_height = $self->layer_count if $skirt_height > $self->layer_count; my @points = (); foreach my $obj_idx (0 .. $#{$self->objects}) { my @layers = map $self->objects->[$obj_idx]->layer($_), 0..($skirt_height-1); my @layer_points = ( (map @$_, map @$_, map @{$_->slices}, @layers), (map @$_, map @{$_->thin_walls}, map @{$_->regions}, @layers), (map @{$_->unpack->polyline}, map @{$_->support_fills->paths}, grep $_->support_fills, @layers), ); push @points, map move_points($_, @layer_points), @{$self->objects->[$obj_idx]->copies}; } return if @points < 3; # at least three points required for a convex hull # find out convex hull my $convex_hull = convex_hull(\@points); my @extruded_length = (); # for each extruder my $spacing = $Slic3r::first_layer_flow->spacing; my $first_layer_height = $Slic3r::Config->get_value('first_layer_height'); my @extruders_e_per_mm = (); my $extruder_idx = 0; # draw outlines from outside to inside # loop while we have less skirts than required or any extruder hasn't reached the min length if any my $distance = scale $Slic3r::Config->skirt_distance; for (my $i = $Slic3r::Config->skirts; $i > 0; $i--) { $distance += scale $spacing; my $loop = Math::Clipper::offset([$convex_hull], $distance, &Slic3r::SCALING_FACTOR * 100, JT_ROUND)->[0]; push @{$self->skirt}, Slic3r::ExtrusionLoop->pack( polygon => Slic3r::Polygon->new(@$loop), role => EXTR_ROLE_SKIRT, flow_spacing => $spacing, ); if ($Slic3r::Config->min_skirt_length > 0) { bless $loop, 'Slic3r::Polygon'; $extruded_length[$extruder_idx] ||= 0; $extruders_e_per_mm[$extruder_idx] ||= $self->extruders->[$extruder_idx]->e_per_mm($spacing, $first_layer_height); $extruded_length[$extruder_idx] += unscale $loop->length * $extruders_e_per_mm[$extruder_idx]; $i++ if defined first { ($extruded_length[$_] // 0) < $Slic3r::Config->min_skirt_length } 0 .. $#{$self->extruders}; if ($extruded_length[$extruder_idx] >= $Slic3r::Config->min_skirt_length) { if ($extruder_idx < $#{$self->extruders}) { $extruder_idx++; next; } } } } @{$self->skirt} = reverse @{$self->skirt}; } sub make_brim { my $self = shift; return unless $Slic3r::Config->brim_width > 0; my $grow_distance = $Slic3r::first_layer_flow->scaled_width / 2; my @islands = (); # array of polygons foreach my $obj_idx (0 .. $#{$self->objects}) { my $layer0 = $self->objects->[$obj_idx]->layers->[0]; my @object_islands = ( (map $_->contour, @{$layer0->slices}), (map { $_->isa('Slic3r::Polygon') ? $_ : $_->grow($grow_distance) } map @{$_->thin_walls}, @{$layer0->regions}), (map $_->unpack->polyline->grow($grow_distance), map @{$_->support_fills->paths}, grep $_->support_fills, $layer0), ); foreach my $copy (@{$self->objects->[$obj_idx]->copies}) { push @islands, map $_->clone->translate(@$copy), @object_islands; } } # if brim touches skirt, make it around skirt too if ($Slic3r::Config->skirt_distance + (($Slic3r::Config->skirts - 1) * $Slic3r::first_layer_flow->spacing) <= $Slic3r::Config->brim_width) { push @islands, map $_->unpack->split_at_first_point->polyline->grow($grow_distance), @{$self->skirt}; } my $num_loops = sprintf "%.0f", $Slic3r::Config->brim_width / $Slic3r::first_layer_flow->width; for my $i (reverse 1 .. $num_loops) { # JT_SQUARE ensures no vertex is outside the given offset distance push @{$self->brim}, Slic3r::ExtrusionLoop->pack( polygon => Slic3r::Polygon->new($_), role => EXTR_ROLE_SKIRT, flow_spacing => $Slic3r::first_layer_flow->spacing, ) for @{Math::Clipper::offset(\@islands, $i * $Slic3r::first_layer_flow->scaled_spacing, 100, JT_SQUARE)}; # TODO: we need the offset inwards/offset outwards logic to avoid overlapping extrusions } } sub write_gcode { my $self = shift; my ($file) = @_; # open output gcode file open my $fh, ">", $file or die "Failed to open $file for writing\n"; # write some information my @lt = localtime; printf $fh "; generated by Slic3r $Slic3r::VERSION on %04d-%02d-%02d at %02d:%02d:%02d\n\n", $lt[5] + 1900, $lt[4]+1, $lt[3], $lt[2], $lt[1], $lt[0]; print $fh "; $_\n" foreach split /\R/, $Slic3r::Config->notes; print $fh "\n" if $Slic3r::Config->notes; for (qw(layer_height perimeters top_solid_layers bottom_solid_layers fill_density perimeter_speed infill_speed travel_speed scale)) { printf $fh "; %s = %s\n", $_, $Slic3r::Config->$_; } for (qw(nozzle_diameter filament_diameter extrusion_multiplier)) { printf $fh "; %s = %s\n", $_, $Slic3r::Config->$_->[0]; } printf $fh "; perimeters extrusion width = %.2fmm\n", $self->regions->[0]->flows->{perimeter}->width; printf $fh "; infill extrusion width = %.2fmm\n", $self->regions->[0]->flows->{infill}->width; printf $fh "; support material extrusion width = %.2fmm\n", $self->support_material_flow->width if $self->support_material_flow; printf $fh "; first layer extrusion width = %.2fmm\n", $Slic3r::first_layer_flow->width if $Slic3r::first_layer_flow; print $fh "\n"; # set up our extruder object my $gcodegen = Slic3r::GCode->new( multiple_extruders => (@{$self->extruders} > 1), ); my $min_print_speed = 60 * $Slic3r::Config->min_print_speed; my $dec = $gcodegen->dec; print $fh $gcodegen->set_fan(0, 1) if $Slic3r::Config->cooling && $Slic3r::Config->disable_fan_first_layers; # write start commands to file printf $fh $gcodegen->set_bed_temperature($Slic3r::Config->first_layer_bed_temperature, 1), if $Slic3r::Config->first_layer_bed_temperature && $Slic3r::Config->start_gcode !~ /M190/i; my $print_first_layer_temperature = sub { for my $t (grep $self->extruders->[$_], 0 .. $#{$Slic3r::Config->first_layer_temperature}) { printf $fh $gcodegen->set_temperature($self->extruders->[$t]->first_layer_temperature, 0, $t) if $self->extruders->[$t]->first_layer_temperature; } }; $print_first_layer_temperature->(); printf $fh "%s\n", $Slic3r::Config->replace_options($Slic3r::Config->start_gcode); for my $t (grep $self->extruders->[$_], 0 .. $#{$Slic3r::Config->first_layer_temperature}) { printf $fh $gcodegen->set_temperature($self->extruders->[$t]->first_layer_temperature, 1, $t) if $self->extruders->[$t]->first_layer_temperature && $Slic3r::Config->start_gcode !~ /M109/i; } print $fh "G90 ; use absolute coordinates\n"; print $fh "G21 ; set units to millimeters\n"; if ($Slic3r::Config->gcode_flavor =~ /^(?:reprap|teacup)$/) { printf $fh $gcodegen->reset_e; if ($Slic3r::Config->gcode_flavor =~ /^(?:reprap|makerbot)$/) { if ($Slic3r::Config->use_relative_e_distances) { print $fh "M83 ; use relative distances for extrusion\n"; } else { print $fh "M82 ; use absolute distances for extrusion\n"; } } } # apply Z offset if ($Slic3r::Config->z_offset > 0) { printf $fh "G1 Z%s ; set Z offset\n", $Slic3r::Config->z_offset; print $fh "G92 Z0 ; set Z offset\n"; } elsif ($Slic3r::Config->z_offset < 0) { printf $fh "G92 Z%s ; set Z offset\n", 1*(-$Slic3r::Config->z_offset); } # calculate X,Y shift to center print around specified origin my @print_bb = $self->bounding_box; my @shift = ( $Slic3r::Config->print_center->[X] - (unscale ($print_bb[X2] - $print_bb[X1]) / 2) - unscale $print_bb[X1], $Slic3r::Config->print_center->[Y] - (unscale ($print_bb[Y2] - $print_bb[Y1]) / 2) - unscale $print_bb[Y1], ); # prepare the logic to print one layer my $skirt_done = 0; # count of skirt layers done my $brim_done = 0; my $extrude_layer = sub { my ($layer_id, $object_copies) = @_; my $gcode = ""; if ($layer_id == 1) { for my $t (grep $self->extruders->[$_], 0 .. $#{$Slic3r::Config->temperature}) { $gcode .= $gcodegen->set_temperature($self->extruders->[$t]->temperature, 0, $t) if $self->extruders->[$t]->temperature && $self->extruders->[$t]->temperature != $self->extruders->[$t]->first_layer_temperature; } $gcode .= $gcodegen->set_bed_temperature($Slic3r::Config->bed_temperature) if $Slic3r::Config->bed_temperature && $Slic3r::Config->bed_temperature != $Slic3r::Config->first_layer_bed_temperature; } # set new layer, but don't move Z as support material interfaces may need an intermediate one $gcode .= $gcodegen->change_layer($self->objects->[$object_copies->[0][0]]->layers->[$layer_id]); $gcodegen->elapsed_time(0); # extrude skirt if ($skirt_done < $Slic3r::Config->skirt_height) { $gcodegen->shift_x($shift[X]); $gcodegen->shift_y($shift[Y]); $gcode .= $gcodegen->set_extruder($self->extruders->[0]); # move_z requires extruder $gcode .= $gcodegen->move_z($gcodegen->layer->print_z); $gcode .= $gcodegen->set_acceleration($Slic3r::Config->perimeter_acceleration); # skip skirt if we have a large brim if ($layer_id < $Slic3r::Config->skirt_height) { # distribute skirt loops across all extruders for my $i (0 .. $#{$self->skirt}) { $gcode .= $gcodegen->set_extruder($self->extruders->[ ($i/@{$self->extruders}) % @{$self->extruders} ]); $gcode .= $gcodegen->extrude_loop($self->skirt->[$i], 'skirt'); } } $skirt_done++; } # extrude brim if ($layer_id == 0 && !$brim_done) { $gcode .= $gcodegen->move_z($gcodegen->layer->print_z); $gcode .= $gcodegen->set_extruder($self->extruders->[$Slic3r::Config->support_material_extruder-1]); $gcodegen->shift_x($shift[X]); $gcodegen->shift_y($shift[Y]); $gcode .= $gcodegen->extrude_loop($_, 'brim') for @{$self->brim}; $brim_done = 1; } for my $obj_copy (@$object_copies) { my ($obj_idx, $copy) = @$obj_copy; my $layer = $self->objects->[$obj_idx]->layers->[$layer_id]; $gcodegen->shift_x($shift[X] + unscale $copy->[X]); $gcodegen->shift_y($shift[Y] + unscale $copy->[Y]); # extrude support material before other things because it might use a lower Z # and also because we avoid travelling on other things when printing it if ($Slic3r::Config->support_material) { $gcode .= $gcodegen->move_z($layer->support_material_interface_z) if @{ $layer->support_interface_fills->paths }; $gcode .= $gcodegen->set_extruder($self->extruders->[$Slic3r::Config->support_material_extruder-1]); $gcode .= $gcodegen->extrude_path($_, 'support material interface') for $layer->support_interface_fills->shortest_path($gcodegen->last_pos); $gcode .= $gcodegen->move_z($layer->print_z); $gcode .= $gcodegen->extrude_path($_, 'support material') for $layer->support_fills->shortest_path($gcodegen->last_pos); } # set actual Z - this will force a retraction $gcode .= $gcodegen->move_z($layer->print_z); foreach my $region_id (0 .. ($self->regions_count-1)) { my $layerm = $layer->regions->[$region_id]; my $region = $self->regions->[$region_id]; # extrude perimeters if (@{ $layerm->perimeters }) { $gcode .= $gcodegen->set_extruder($region->extruders->{perimeter}); $gcode .= $gcodegen->extrude($_, 'perimeter') for @{ $layerm->perimeters }; } # extrude fills if (@{ $layerm->fills }) { $gcode .= $gcodegen->set_extruder($region->extruders->{infill}); $gcode .= $gcodegen->set_acceleration($Slic3r::Config->infill_acceleration); for my $fill (@{ $layerm->fills }) { if ($fill->isa('Slic3r::ExtrusionPath::Collection')) { $gcode .= $gcodegen->extrude($_, 'fill') for $fill->shortest_path($gcodegen->last_pos); } else { $gcode .= $gcodegen->extrude($fill, 'fill') ; } } } } } return if !$gcode; my $fan_speed = $Slic3r::Config->fan_always_on ? $Slic3r::Config->min_fan_speed : 0; my $speed_factor = 1; if ($Slic3r::Config->cooling) { my $layer_time = $gcodegen->elapsed_time; Slic3r::debugf "Layer %d estimated printing time: %d seconds\n", $layer_id, $layer_time; if ($layer_time < $Slic3r::Config->slowdown_below_layer_time) { $fan_speed = $Slic3r::Config->max_fan_speed; $speed_factor = $layer_time / $Slic3r::Config->slowdown_below_layer_time; } elsif ($layer_time < $Slic3r::Config->fan_below_layer_time) { $fan_speed = $Slic3r::Config->max_fan_speed - ($Slic3r::Config->max_fan_speed - $Slic3r::Config->min_fan_speed) * ($layer_time - $Slic3r::Config->slowdown_below_layer_time) / ($Slic3r::Config->fan_below_layer_time - $Slic3r::Config->slowdown_below_layer_time); #/ } Slic3r::debugf " fan = %d%%, speed = %d%%\n", $fan_speed, $speed_factor * 100; if ($speed_factor < 1) { $gcode =~ s/^(?=.*? [XY])(?=.*? E)(?disable_fan_first_layers; } $gcode = $gcodegen->set_fan($fan_speed) . $gcode; # bridge fan speed if (!$Slic3r::Config->cooling || $Slic3r::Config->bridge_fan_speed == 0 || $layer_id < $Slic3r::Config->disable_fan_first_layers) { $gcode =~ s/^;_BRIDGE_FAN_(?:START|END)\n//gm; } else { $gcode =~ s/^;_BRIDGE_FAN_START\n/ $gcodegen->set_fan($Slic3r::Config->bridge_fan_speed, 1) /gmex; $gcode =~ s/^;_BRIDGE_FAN_END\n/ $gcodegen->set_fan($fan_speed, 1) /gmex; } return $gcode; }; # do all objects for each layer if ($Slic3r::Config->complete_objects) { # print objects from the smallest to the tallest to avoid collisions # when moving onto next object starting point my @obj_idx = sort { $self->objects->[$a]->layer_count <=> $self->objects->[$b]->layer_count } 0..$#{$self->objects}; my $finished_objects = 0; for my $obj_idx (@obj_idx) { for my $copy (@{ $self->objects->[$obj_idx]->copies }) { # move to the origin position for the copy we're going to print. # this happens before Z goes down to layer 0 again, so that # no collision happens hopefully. if ($finished_objects > 0) { $gcodegen->shift_x($shift[X] + unscale $copy->[X]); $gcodegen->shift_y($shift[Y] + unscale $copy->[Y]); print $fh $gcodegen->retract; print $fh $gcodegen->G0(Slic3r::Point->new(0,0), undef, 0, 'move to origin position for next object'); } for my $layer_id (0..$#{$self->objects->[$obj_idx]->layers}) { # if we are printing the bottom layer of an object, and we have already finished # another one, set first layer temperatures. this happens before the Z move # is triggered, so machine has more time to reach such temperatures if ($layer_id == 0 && $finished_objects > 0) { printf $fh $gcodegen->set_bed_temperature($Slic3r::Config->first_layer_bed_temperature), if $Slic3r::Config->first_layer_bed_temperature; $print_first_layer_temperature->(); } print $fh $extrude_layer->($layer_id, [[ $obj_idx, $copy ]]); } $finished_objects++; } } } else { for my $layer_id (0..$self->layer_count-1) { my @object_copies = (); for my $obj_idx (grep $self->objects->[$_]->layers->[$layer_id], 0..$#{$self->objects}) { push @object_copies, map [ $obj_idx, $_ ], @{ $self->objects->[$obj_idx]->copies }; } print $fh $extrude_layer->($layer_id, \@object_copies); } } # save statistic data $self->total_extrusion_length($gcodegen->total_extrusion_length); # write end commands to file print $fh $gcodegen->retract; print $fh $gcodegen->set_fan(0); print $fh "M501 ; reset acceleration\n" if $Slic3r::Config->acceleration; printf $fh "%s\n", $Slic3r::Config->replace_options($Slic3r::Config->end_gcode); printf $fh "; filament used = %.1fmm (%.1fcm3)\n", $self->total_extrusion_length, $self->total_extrusion_volume; # close our gcode file close $fh; } sub total_extrusion_volume { my $self = shift; return $self->total_extrusion_length * ($self->extruders->[0]->filament_diameter**2) * PI/4 / 1000; } # this method will return the supplied input file path after expanding its # format variables with their values sub expanded_output_filepath { my $self = shift; my ($path, $input_file) = @_; # if no input file was supplied, take the first one from our objects $input_file ||= $self->objects->[0]->input_file; # if output path is an existing directory, we take that and append # the specified filename format $path = File::Spec->join($path, $Slic3r::Config->output_filename_format) if ($path && -d $path); # if no explicit output file was defined, we take the input # file directory and append the specified filename format $path ||= (fileparse($input_file))[1] . $Slic3r::Config->output_filename_format; my $input_filename = my $input_filename_base = basename($input_file); $input_filename_base =~ s/\.(?:stl|amf(?:\.xml)?)$//i; return $Slic3r::Config->replace_options($path, { input_filename => $input_filename, input_filename_base => $input_filename_base, %{ $self->extra_variables }, }); } 1;