PrusaSlicer-NonPlainar/xs/src/libslic3r/Extruder.cpp

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#include "Extruder.hpp"
namespace Slic3r {
Extruder::Extruder(unsigned int id, GCodeConfig *config)
: m_id(id),
m_config(config)
{
reset();
// cache values that are going to be called often
if (m_config->use_volumetric_e) {
m_e_per_mm3 = this->extrusion_multiplier();
} else {
m_e_per_mm3 = this->extrusion_multiplier()
* (4 / ((this->filament_diameter() * this->filament_diameter()) * PI));
}
}
double Extruder::extrude(double dE)
{
// in case of relative E distances we always reset to 0 before any output
if (m_config->use_relative_e_distances)
this->E = 0;
this->E += dE;
this->absolute_E += dE;
return dE;
}
/* This method makes sure the extruder is retracted by the specified amount
of filament and returns the amount of filament retracted.
If the extruder is already retracted by the same or a greater amount,
this method is a no-op.
The restart_extra argument sets the extra length to be used for
unretraction. If we're actually performing a retraction, any restart_extra
value supplied will overwrite the previous one if any. */
double Extruder::retract(double length, double restart_extra)
{
// in case of relative E distances we always reset to 0 before any output
if (m_config->use_relative_e_distances)
this->E = 0;
double to_retract = length - this->retracted;
if (to_retract > 0) {
this->E -= to_retract;
this->absolute_E -= to_retract;
this->retracted += to_retract;
this->restart_extra = restart_extra;
return to_retract;
} else {
return 0;
}
}
double Extruder::unretract()
{
double dE = this->retracted + this->restart_extra;
this->extrude(dE);
this->retracted = 0;
this->restart_extra = 0;
return dE;
}
double Extruder::e_per_mm(double mm3_per_mm) const
{
return mm3_per_mm * m_e_per_mm3;
}
double Extruder::extruded_volume() const
{
if (m_config->use_volumetric_e) {
// Any current amount of retraction should not affect used filament, since
// it represents empty volume in the nozzle. We add it back to E.
return this->absolute_E + this->retracted;
}
return this->used_filament() * (this->filament_diameter() * this->filament_diameter()) * PI/4;
}
double Extruder::used_filament() const
{
if (m_config->use_volumetric_e) {
return this->extruded_volume() / (this->filament_diameter() * this->filament_diameter() * PI/4);
}
// Any current amount of retraction should not affect used filament, since
// it represents empty volume in the nozzle. We add it back to E.
return this->absolute_E + this->retracted;
}
double Extruder::filament_diameter() const
{
return m_config->filament_diameter.get_at(m_id);
}
double Extruder::filament_density() const
{
return m_config->filament_density.get_at(m_id);
}
double Extruder::filament_cost() const
{
return m_config->filament_cost.get_at(m_id);
}
double Extruder::extrusion_multiplier() const
{
return m_config->extrusion_multiplier.get_at(m_id);
}
// Return a "retract_before_wipe" percentage as a factor clamped to <0, 1>
double Extruder::retract_before_wipe() const
{
return std::min(1., std::max(0., m_config->retract_before_wipe.get_at(m_id) * 0.01));
}
double Extruder::retract_length() const
{
return m_config->retract_length.get_at(m_id);
}
double Extruder::retract_lift() const
{
return m_config->retract_lift.get_at(m_id);
}
int Extruder::retract_speed() const
{
return m_config->retract_speed.get_at(m_id);
}
int Extruder::deretract_speed() const
{
int speed = m_config->deretract_speed.get_at(m_id);
return (speed > 0) ? speed : this->retract_speed();
}
double Extruder::retract_restart_extra() const
{
return m_config->retract_restart_extra.get_at(m_id);
}
double Extruder::retract_length_toolchange() const
{
return m_config->retract_length_toolchange.get_at(m_id);
}
double Extruder::retract_restart_extra_toolchange() const
{
return m_config->retract_restart_extra_toolchange.get_at(m_id);
}
}