166 lines
5.3 KiB
Perl
166 lines
5.3 KiB
Perl
package Slic3r::Flow;
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use Moo;
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require Exporter;
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our @ISA = qw(Exporter);
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our @EXPORT_OK = qw(FLOW_ROLE_PERIMETER FLOW_ROLE_INFILL FLOW_ROLE_SOLID_INFILL FLOW_ROLE_TOP_SOLID_INFILL
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FLOW_ROLE_SUPPORT_MATERIAL FLOW_ROLE_SUPPORT_MATERIAL_INTERFACE);
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our %EXPORT_TAGS = (roles => \@EXPORT_OK);
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use Slic3r::Geometry qw(PI);
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has 'width' => (is => 'ro', required => 1);
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has 'spacing' => (is => 'ro', required => 1);
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has 'nozzle_diameter' => (is => 'ro', required => 1);
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has 'bridge' => (is => 'ro', default => sub {0});
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has 'scaled_width' => (is => 'lazy');
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has 'scaled_spacing' => (is => 'lazy');
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use constant FLOW_ROLE_PERIMETER => 1;
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use constant FLOW_ROLE_INFILL => 2;
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use constant FLOW_ROLE_SOLID_INFILL => 3;
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use constant FLOW_ROLE_TOP_SOLID_INFILL => 4;
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use constant FLOW_ROLE_SUPPORT_MATERIAL => 5;
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use constant FLOW_ROLE_SUPPORT_MATERIAL_INTERFACE => 6;
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use constant BRIDGE_EXTRA_SPACING => 0.05;
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use constant OVERLAP_FACTOR => 1;
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sub new_from_width {
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my ($class, %args) = @_;
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if ($args{width} eq '0') {
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$args{width} = _width(@args{qw(role nozzle_diameter layer_height bridge_flow_ratio)});
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} elsif ($args{width} =~ /^(\d+(?:\.\d+)?)%$/) {
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$args{width} = $args{layer_height} * $1 / 100;
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}
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return $class->new(
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width => $args{width},
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spacing => _spacing(@args{qw(width nozzle_diameter layer_height bridge_flow_ratio)}),
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nozzle_diameter => $args{nozzle_diameter},
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bridge => ($args{bridge_flow_ratio} > 0) ? 1 : 0,
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);
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}
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sub new_from_spacing {
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my ($class, %args) = @_;
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return $class->new(
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width => _width_from_spacing(@args{qw(spacing nozzle_diameter layer_height bridge)}),
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spacing => $args{spacing},
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nozzle_diameter => $args{nozzle_diameter},
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bridge => $args{bridge},
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);
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}
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sub clone {
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my $self = shift;
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return (ref $self)->new(
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width => $self->width,
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spacing => $self->spacing,
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nozzle_diameter => $self->nozzle_diameter,
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bridge => $self->bridge,
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);
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}
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sub mm3_per_mm {
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my ($self, $h) = @_;
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my $w = $self->width;
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my $s = $self->spacing;
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if ($self->bridge) {
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return ($s**2) * PI/4;
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} elsif ($w >= ($self->nozzle_diameter + $h)) {
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# rectangle with semicircles at the ends
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return $w * $h + ($h**2) / 4 * (PI - 4);
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} else {
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# rectangle with shrunk semicircles at the ends
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return $self->nozzle_diameter * $h * (1 - PI/4) + $h * $w * PI/4;
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}
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}
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sub _width {
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my ($role, $nozzle_diameter, $layer_height, $bridge_flow_ratio) = @_;
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if ($bridge_flow_ratio > 0) {
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return sqrt($bridge_flow_ratio * ($nozzle_diameter**2));
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}
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# here we calculate a sane default by matching the flow speed (at the nozzle) and the feed rate
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my $volume = ($nozzle_diameter**2) * PI/4;
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my $shape_threshold = $nozzle_diameter * $layer_height + ($layer_height**2) * PI/4;
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my $width;
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if ($volume >= $shape_threshold) {
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# rectangle with semicircles at the ends
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$width = (($nozzle_diameter**2) * PI + ($layer_height**2) * (4 - PI)) / (4 * $layer_height);
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} else {
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# rectangle with squished semicircles at the ends
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$width = $nozzle_diameter * ($nozzle_diameter/$layer_height - 4/PI + 1);
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}
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my $min = $nozzle_diameter * 1.05;
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my $max;
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if ($role == FLOW_ROLE_PERIMETER || $role == FLOW_ROLE_SUPPORT_MATERIAL) {
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$min = $max = $nozzle_diameter;
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} elsif ($role != FLOW_ROLE_INFILL) {
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# do not limit width for sparse infill so that we use full native flow for it
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$max = $nozzle_diameter * 1.7;
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}
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$width = $max if defined($max) && $width > $max;
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$width = $min if $width < $min;
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return $width;
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}
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sub _width_from_spacing {
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my ($s, $nozzle_diameter, $h, $bridge) = @_;
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if ($bridge) {
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return $s - BRIDGE_EXTRA_SPACING;
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}
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my $w_threshold = $h + $nozzle_diameter;
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my $s_threshold = $w_threshold - OVERLAP_FACTOR * ($w_threshold - ($w_threshold - $h * (1 - PI/4)));
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if ($s >= $s_threshold) {
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# rectangle with semicircles at the ends
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return $s + OVERLAP_FACTOR * $h * (1 - PI/4);
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} else {
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# rectangle with shrunk semicircles at the ends
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return ($s + $nozzle_diameter * OVERLAP_FACTOR * (PI/4 - 1)) / (1 + OVERLAP_FACTOR * (PI/4 - 1));
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}
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}
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sub _spacing {
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my ($width, $nozzle_diameter, $layer_height, $bridge_flow_ratio) = @_;
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if ($bridge_flow_ratio > 0) {
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return $width + BRIDGE_EXTRA_SPACING;
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}
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my $min_flow_spacing;
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if ($width >= ($nozzle_diameter + $layer_height)) {
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# rectangle with semicircles at the ends
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$min_flow_spacing = $width - $layer_height * (1 - PI/4);
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} else {
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# rectangle with shrunk semicircles at the ends
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$min_flow_spacing = $nozzle_diameter * (1 - PI/4) + $width * PI/4;
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}
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return $width - OVERLAP_FACTOR * ($width - $min_flow_spacing);
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}
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sub _build_scaled_width {
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my $self = shift;
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return Slic3r::Geometry::scale($self->width);
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}
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sub _build_scaled_spacing {
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my $self = shift;
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return Slic3r::Geometry::scale($self->spacing);
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}
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1;
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