PrusaSlicer-NonPlainar/xs/src/libslic3r/GCode/ToolOrdering.cpp

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#include "Print.hpp"
#include "ToolOrdering.hpp"
// #define SLIC3R_DEBUG
// Make assert active if SLIC3R_DEBUG
#ifdef SLIC3R_DEBUG
#define DEBUG
#define _DEBUG
#undef NDEBUG
#endif
#include <cassert>
#include <limits>
namespace Slic3r {
// For the use case when each object is printed separately
// (print.config.complete_objects is true).
ToolOrdering::ToolOrdering(const PrintObject &object, unsigned int first_extruder, bool prime_multi_material)
{
if (object.layers.empty())
return;
// Initialize the print layers for just a single object.
{
std::vector<coordf_t> zs;
zs.reserve(zs.size() + object.layers.size() + object.support_layers.size());
for (auto layer : object.layers)
zs.emplace_back(layer->print_z);
for (auto layer : object.support_layers)
zs.emplace_back(layer->print_z);
this->initialize_layers(zs);
}
// Collect extruders reuqired to print the layers.
this->collect_extruders(object);
// Reorder the extruders to minimize tool switches.
this->reorder_extruders(first_extruder);
this->fill_wipe_tower_partitions(object.print()->config, object.layers.front()->print_z - object.layers.front()->height);
this->collect_extruder_statistics(prime_multi_material);
}
// For the use case when all objects are printed at once.
// (print.config.complete_objects is false).
ToolOrdering::ToolOrdering(const Print &print, unsigned int first_extruder, bool prime_multi_material)
{
m_print_config_ptr = &print.config;
// Initialize the print layers for all objects and all layers.
coordf_t object_bottom_z = 0.;
{
std::vector<coordf_t> zs;
for (auto object : print.objects) {
zs.reserve(zs.size() + object->layers.size() + object->support_layers.size());
for (auto layer : object->layers)
zs.emplace_back(layer->print_z);
for (auto layer : object->support_layers)
zs.emplace_back(layer->print_z);
if (! object->layers.empty())
object_bottom_z = object->layers.front()->print_z - object->layers.front()->height;
}
this->initialize_layers(zs);
}
// Collect extruders reuqired to print the layers.
for (auto object : print.objects)
this->collect_extruders(*object);
// Reorder the extruders to minimize tool switches.
this->reorder_extruders(first_extruder);
this->fill_wipe_tower_partitions(print.config, object_bottom_z);
this->collect_extruder_statistics(prime_multi_material);
}
LayerTools& ToolOrdering::tools_for_layer(coordf_t print_z)
{
auto it_layer_tools = std::lower_bound(m_layer_tools.begin(), m_layer_tools.end(), LayerTools(print_z - EPSILON));
assert(it_layer_tools != m_layer_tools.end());
coordf_t dist_min = std::abs(it_layer_tools->print_z - print_z);
for (++ it_layer_tools; it_layer_tools != m_layer_tools.end(); ++it_layer_tools) {
coordf_t d = std::abs(it_layer_tools->print_z - print_z);
if (d >= dist_min)
break;
dist_min = d;
}
-- it_layer_tools;
assert(dist_min < EPSILON);
return *it_layer_tools;
}
void ToolOrdering::initialize_layers(std::vector<coordf_t> &zs)
{
sort_remove_duplicates(zs);
// Merge numerically very close Z values.
for (size_t i = 0; i < zs.size();) {
// Find the last layer with roughly the same print_z.
size_t j = i + 1;
coordf_t zmax = zs[i] + EPSILON;
for (; j < zs.size() && zs[j] <= zmax; ++ j) ;
// Assign an average print_z to the set of layers with nearly equal print_z.
m_layer_tools.emplace_back(LayerTools(0.5 * (zs[i] + zs[j-1]), m_print_config_ptr));
i = j;
}
}
// Collect extruders reuqired to print layers.
void ToolOrdering::collect_extruders(const PrintObject &object)
{
// Collect the support extruders.
for (auto support_layer : object.support_layers) {
LayerTools &layer_tools = this->tools_for_layer(support_layer->print_z);
ExtrusionRole role = support_layer->support_fills.role();
bool has_support = role == erMixed || role == erSupportMaterial;
bool has_interface = role == erMixed || role == erSupportMaterialInterface;
unsigned int extruder_support = object.config.support_material_extruder.value;
unsigned int extruder_interface = object.config.support_material_interface_extruder.value;
if (has_support)
layer_tools.extruders.push_back(extruder_support);
if (has_interface)
layer_tools.extruders.push_back(extruder_interface);
if (has_support || has_interface)
layer_tools.has_support = true;
}
// Collect the object extruders.
for (auto layer : object.layers) {
LayerTools &layer_tools = this->tools_for_layer(layer->print_z);
// What extruders are required to print this object layer?
for (size_t region_id = 0; region_id < object.print()->regions.size(); ++ region_id) {
const LayerRegion *layerm = (region_id < layer->regions.size()) ? layer->regions[region_id] : nullptr;
if (layerm == nullptr)
continue;
const PrintRegion &region = *object.print()->regions[region_id];
if (! layerm->perimeters.entities.empty()) {
bool something_nonoverriddable = false;
for (const auto& eec : layerm->perimeters.entities) // let's check if there are nonoverriddable entities
if (!layer_tools.wiping_extrusions.is_overriddable(dynamic_cast<const ExtrusionEntityCollection&>(*eec), *m_print_config_ptr, object, region)) {
something_nonoverriddable = true;
break;
}
if (something_nonoverriddable)
layer_tools.extruders.push_back(region.config.perimeter_extruder.value);
layer_tools.has_object = true;
}
bool has_infill = false;
bool has_solid_infill = false;
bool something_nonoverriddable = false;
for (const ExtrusionEntity *ee : layerm->fills.entities) {
// fill represents infill extrusions of a single island.
const auto *fill = dynamic_cast<const ExtrusionEntityCollection*>(ee);
ExtrusionRole role = fill->entities.empty() ? erNone : fill->entities.front()->role();
if (is_solid_infill(role))
has_solid_infill = true;
else if (role != erNone)
has_infill = true;
if (!something_nonoverriddable && !layer_tools.wiping_extrusions.is_overriddable(*fill, *m_print_config_ptr, object, region))
something_nonoverriddable = true;
}
if (something_nonoverriddable)
{
if (has_solid_infill)
layer_tools.extruders.push_back(region.config.solid_infill_extruder);
if (has_infill)
layer_tools.extruders.push_back(region.config.infill_extruder);
}
if (has_solid_infill || has_infill)
layer_tools.has_object = true;
}
}
for (auto& layer : m_layer_tools) {
// Sort and remove duplicates
sort_remove_duplicates(layer.extruders);
// make sure that there are some tools for each object layer (e.g. tall wiping object will result in empty extruders vector)
if (layer.extruders.empty() && layer.has_object)
layer.extruders.push_back(0); // 0="dontcare" extruder - it will be taken care of in reorder_extruders
}
}
// Reorder extruders to minimize layer changes.
void ToolOrdering::reorder_extruders(unsigned int last_extruder_id)
{
if (m_layer_tools.empty())
return;
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if (last_extruder_id == (unsigned int)-1) {
// The initial print extruder has not been decided yet.
// Initialize the last_extruder_id with the first non-zero extruder id used for the print.
last_extruder_id = 0;
for (size_t i = 0; i < m_layer_tools.size() && last_extruder_id == 0; ++ i) {
const LayerTools &lt = m_layer_tools[i];
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for (unsigned int extruder_id : lt.extruders)
if (extruder_id > 0) {
last_extruder_id = extruder_id;
break;
}
}
if (last_extruder_id == 0)
// Nothing to extrude.
return;
} else
// 1 based index
++ last_extruder_id;
for (LayerTools &lt : m_layer_tools) {
if (lt.extruders.empty())
continue;
if (lt.extruders.size() == 1 && lt.extruders.front() == 0)
lt.extruders.front() = last_extruder_id;
else {
if (lt.extruders.front() == 0)
// Pop the "don't care" extruder, the "don't care" region will be merged with the next one.
lt.extruders.erase(lt.extruders.begin());
// Reorder the extruders to start with the last one.
for (size_t i = 1; i < lt.extruders.size(); ++ i)
if (lt.extruders[i] == last_extruder_id) {
// Move the last extruder to the front.
memmove(lt.extruders.data() + 1, lt.extruders.data(), i * sizeof(unsigned int));
lt.extruders.front() = last_extruder_id;
break;
}
}
last_extruder_id = lt.extruders.back();
}
// Reindex the extruders, so they are zero based, not 1 based.
for (LayerTools &lt : m_layer_tools)
for (unsigned int &extruder_id : lt.extruders) {
assert(extruder_id > 0);
-- extruder_id;
}
}
void ToolOrdering::fill_wipe_tower_partitions(const PrintConfig &config, coordf_t object_bottom_z)
{
if (m_layer_tools.empty())
return;
// Count the minimum number of tool changes per layer.
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size_t last_extruder = size_t(-1);
for (LayerTools &lt : m_layer_tools) {
lt.wipe_tower_partitions = lt.extruders.size();
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if (! lt.extruders.empty()) {
if (last_extruder == size_t(-1) || last_extruder == lt.extruders.front())
// The first extruder on this layer is equal to the current one, no need to do an initial tool change.
-- lt.wipe_tower_partitions;
last_extruder = lt.extruders.back();
}
}
// Propagate the wipe tower partitions down to support the upper partitions by the lower partitions.
for (int i = int(m_layer_tools.size()) - 2; i >= 0; -- i)
m_layer_tools[i].wipe_tower_partitions = std::max(m_layer_tools[i + 1].wipe_tower_partitions, m_layer_tools[i].wipe_tower_partitions);
//FIXME this is a hack to get the ball rolling.
for (LayerTools &lt : m_layer_tools)
lt.has_wipe_tower = (lt.has_object && lt.wipe_tower_partitions > 0) || lt.print_z < object_bottom_z + EPSILON;
// Test for a raft, insert additional wipe tower layer to fill in the raft separation gap.
double max_layer_height = std::numeric_limits<double>::max();
for (size_t i = 0; i < config.nozzle_diameter.values.size(); ++ i) {
double mlh = config.max_layer_height.values[i];
if (mlh == 0.)
mlh = 0.75 * config.nozzle_diameter.values[i];
max_layer_height = std::min(max_layer_height, mlh);
}
for (size_t i = 0; i + 1 < m_layer_tools.size(); ++ i) {
const LayerTools &lt = m_layer_tools[i];
const LayerTools &lt_next = m_layer_tools[i + 1];
if (lt.print_z < object_bottom_z + EPSILON && lt_next.print_z >= object_bottom_z + EPSILON) {
// lt is the last raft layer. Find the 1st object layer.
size_t j = i + 1;
for (; j < m_layer_tools.size() && ! m_layer_tools[j].has_wipe_tower; ++ j);
if (j < m_layer_tools.size()) {
const LayerTools &lt_object = m_layer_tools[j];
coordf_t gap = lt_object.print_z - lt.print_z;
assert(gap > 0.f);
if (gap > max_layer_height + EPSILON) {
// Insert one additional wipe tower layer between lh.print_z and lt_object.print_z.
LayerTools lt_new(0.5f * (lt.print_z + lt_object.print_z));
// Find the 1st layer above lt_new.
for (j = i + 1; j < m_layer_tools.size() && m_layer_tools[j].print_z < lt_new.print_z - EPSILON; ++ j);
if (std::abs(m_layer_tools[j].print_z - lt_new.print_z) < EPSILON) {
m_layer_tools[j].has_wipe_tower = true;
} else {
LayerTools &lt_extra = *m_layer_tools.insert(m_layer_tools.begin() + j, lt_new);
LayerTools &lt_prev = m_layer_tools[j - 1];
LayerTools &lt_next = m_layer_tools[j + 1];
assert(! lt_prev.extruders.empty() && ! lt_next.extruders.empty());
assert(lt_prev.extruders.back() == lt_next.extruders.front());
lt_extra.has_wipe_tower = true;
lt_extra.extruders.push_back(lt_next.extruders.front());
lt_extra.wipe_tower_partitions = lt_next.wipe_tower_partitions;
}
}
}
break;
}
}
// Calculate the wipe_tower_layer_height values.
coordf_t wipe_tower_print_z_last = 0.;
for (LayerTools &lt : m_layer_tools)
if (lt.has_wipe_tower) {
lt.wipe_tower_layer_height = lt.print_z - wipe_tower_print_z_last;
wipe_tower_print_z_last = lt.print_z;
}
}
void ToolOrdering::collect_extruder_statistics(bool prime_multi_material)
{
m_first_printing_extruder = (unsigned int)-1;
for (const auto &lt : m_layer_tools)
if (! lt.extruders.empty()) {
m_first_printing_extruder = lt.extruders.front();
break;
}
m_last_printing_extruder = (unsigned int)-1;
for (auto lt_it = m_layer_tools.rbegin(); lt_it != m_layer_tools.rend(); ++ lt_it)
if (! lt_it->extruders.empty()) {
m_last_printing_extruder = lt_it->extruders.back();
break;
}
m_all_printing_extruders.clear();
for (const auto &lt : m_layer_tools) {
append(m_all_printing_extruders, lt.extruders);
sort_remove_duplicates(m_all_printing_extruders);
}
if (prime_multi_material && ! m_all_printing_extruders.empty()) {
// Reorder m_all_printing_extruders in the sequence they will be primed, the last one will be m_first_printing_extruder.
// Then set m_first_printing_extruder to the 1st extruder primed.
m_all_printing_extruders.erase(
std::remove_if(m_all_printing_extruders.begin(), m_all_printing_extruders.end(),
[ this ](const unsigned int eid) { return eid == m_first_printing_extruder; }),
m_all_printing_extruders.end());
m_all_printing_extruders.emplace_back(m_first_printing_extruder);
m_first_printing_extruder = m_all_printing_extruders.front();
}
}
// This function is called from Print::mark_wiping_extrusions and sets extruder this entity should be printed with (-1 .. as usual)
void WipingExtrusions::set_extruder_override(const ExtrusionEntity* entity, unsigned int copy_id, int extruder, unsigned int num_of_copies)
{
something_overridden = true;
auto entity_map_it = (entity_map.insert(std::make_pair(entity, std::vector<int>()))).first; // (add and) return iterator
auto& copies_vector = entity_map_it->second;
if (copies_vector.size() < num_of_copies)
copies_vector.resize(num_of_copies, -1);
if (copies_vector[copy_id] != -1)
std::cout << "ERROR: Entity extruder overriden multiple times!!!\n"; // A debugging message - this must never happen.
copies_vector[copy_id] = extruder;
}
// Finds last non-soluble extruder on the layer
bool WipingExtrusions::is_last_nonsoluble_on_layer(const PrintConfig& print_config, const LayerTools& lt, unsigned int extruder) const
{
for (auto extruders_it = lt.extruders.rbegin(); extruders_it != lt.extruders.rend(); ++extruders_it)
if (!print_config.filament_soluble.get_at(*extruders_it))
return (*extruders_it == extruder);
return false;
}
// Decides whether this entity could be overridden
bool WipingExtrusions::is_overriddable(const ExtrusionEntityCollection& eec, const PrintConfig& print_config, const PrintObject& object, const PrintRegion& region) const
{
if (print_config.filament_soluble.get_at(get_extruder(eec, region)))
return false;
if (object.config.wipe_into_objects)
return true;
if (!region.config.wipe_into_infill || eec.role() != erInternalInfill)
return false;
return true;
}
// Following function iterates through all extrusions on the layer, remembers those that could be used for wiping after toolchange
// and returns volume that is left to be wiped on the wipe tower.
float WipingExtrusions::mark_wiping_extrusions(const Print& print, const LayerTools& layer_tools, unsigned int new_extruder, float volume_to_wipe)
{
const float min_infill_volume = 0.f; // ignore infill with smaller volume than this
if (print.config.filament_soluble.get_at(new_extruder))
return volume_to_wipe; // Soluble filament cannot be wiped in a random infill
bool last_nonsoluble = is_last_nonsoluble_on_layer(print.config, layer_tools, new_extruder);
// we will sort objects so that dedicated for wiping are at the beginning:
PrintObjectPtrs object_list = print.objects;
std::sort(object_list.begin(), object_list.end(), [](const PrintObject* a, const PrintObject* b) { return a->config.wipe_into_objects; });
// We will now iterate through
// - first the dedicated objects to mark perimeters or infills (depending on infill_first)
// - second through the dedicated ones again to mark infills or perimeters (depending on infill_first)
// - then all the others to mark infills (in case that !infill_first, we must also check that the perimeter is finished already
// this is controlled by the following variable:
bool perimeters_done = false;
for (int i=0 ; i<(int)object_list.size() ; ++i) {
const auto& object = object_list[i];
if (!perimeters_done && (i+1==(int)object_list.size() || !object_list[i]->config.wipe_into_objects)) { // we passed the last dedicated object in list
perimeters_done = true;
i=-1; // let's go from the start again
continue;
}
// Finds this layer:
auto this_layer_it = std::find_if(object->layers.begin(), object->layers.end(), [&layer_tools](const Layer* lay) { return std::abs(layer_tools.print_z - lay->print_z)<EPSILON; });
if (this_layer_it == object->layers.end())
continue;
const Layer* this_layer = *this_layer_it;
unsigned int num_of_copies = object->_shifted_copies.size();
for (unsigned int copy = 0; copy < num_of_copies; ++copy) { // iterate through copies first, so that we mark neighbouring infills to minimize travel moves
for (size_t region_id = 0; region_id < object->print()->regions.size(); ++ region_id) {
const auto& region = *object->print()->regions[region_id];
if (!region.config.wipe_into_infill && !object->config.wipe_into_objects)
continue;
if (((!print.config.infill_first ? perimeters_done : !perimeters_done) || !object->config.wipe_into_objects) && region.config.wipe_into_infill) {
const ExtrusionEntityCollection& eec = this_layer->regions[region_id]->fills;
for (const ExtrusionEntity* ee : eec.entities) { // iterate through all infill Collections
auto* fill = dynamic_cast<const ExtrusionEntityCollection*>(ee);
if (fill->role() == erTopSolidInfill || fill->role() == erGapFill) // these cannot be changed - such infill is / may be visible
continue;
// What extruder would this normally be printed with?
unsigned int correct_extruder = get_extruder(*fill, region);
bool force_override = false;
// If the extruder is not in layer tools - we MUST override it. This happens whenever all extrusions, that would normally
// be printed with this extruder on this layer are "dont care" (part of infill/perimeter wiping):
if (last_nonsoluble && std::find(layer_tools.extruders.begin(), layer_tools.extruders.end(), correct_extruder) == layer_tools.extruders.end())
force_override = true;
if (!force_override && volume_to_wipe<=0)
continue;
if (!is_overriddable(*fill, print.config, *object, region))
continue;
if (!object->config.wipe_into_objects && !print.config.infill_first && !force_override) {
// In this case we must check that the original extruder is used on this layer before the one we are overridding
// (and the perimeters will be finished before the infill is printed):
if ((!print.config.infill_first && region.config.wipe_into_infill)) {
bool unused_yet = false;
for (unsigned i = 0; i < layer_tools.extruders.size(); ++i) {
if (layer_tools.extruders[i] == new_extruder)
unused_yet = true;
if (layer_tools.extruders[i] == correct_extruder)
break;
}
if (unused_yet)
continue;
}
}
if (force_override || (!is_entity_overridden(fill, copy) && fill->total_volume() > min_infill_volume)) { // this infill will be used to wipe this extruder
set_extruder_override(fill, copy, new_extruder, num_of_copies);
volume_to_wipe -= fill->total_volume();
}
}
}
if (object->config.wipe_into_objects && (print.config.infill_first ? perimeters_done : !perimeters_done))
{
const ExtrusionEntityCollection& eec = this_layer->regions[region_id]->perimeters;
for (const ExtrusionEntity* ee : eec.entities) { // iterate through all perimeter Collections
auto* fill = dynamic_cast<const ExtrusionEntityCollection*>(ee);
// What extruder would this normally be printed with?
unsigned int correct_extruder = get_extruder(*fill, region);
bool force_override = false;
if (last_nonsoluble && std::find(layer_tools.extruders.begin(), layer_tools.extruders.end(), correct_extruder) == layer_tools.extruders.end())
force_override = true;
if (!force_override && volume_to_wipe<=0)
continue;
if (!is_overriddable(*fill, print.config, *object, region))
continue;
if (force_override || (!is_entity_overridden(fill, copy) && fill->total_volume() > min_infill_volume)) {
set_extruder_override(fill, copy, new_extruder, num_of_copies);
volume_to_wipe -= fill->total_volume();
}
}
}
}
}
}
return std::max(0.f, volume_to_wipe);
}
// Following function is called from process_layer and returns pointer to vector with information about which extruders should be used for given copy of this entity.
// It first makes sure the pointer is valid (creates the vector if it does not exist) and contains a record for each copy
// It also modifies the vector in place and changes all -1 to correct_extruder_id (at the time the overrides were created, correct extruders were not known,
// so -1 was used as "print as usual".
// The resulting vector has to keep track of which extrusions are the ones that were overridden and which were not. In the extruder is used as overridden,
// its number is saved as it is (zero-based index). Usual extrusions are saved as -number-1 (unfortunately there is no negative zero).
const std::vector<int>* WipingExtrusions::get_extruder_overrides(const ExtrusionEntity* entity, int correct_extruder_id, int num_of_copies)
{
auto entity_map_it = entity_map.find(entity);
if (entity_map_it == entity_map.end())
entity_map_it = (entity_map.insert(std::make_pair(entity, std::vector<int>()))).first;
// Now the entity_map_it should be valid, let's make sure the vector is long enough:
entity_map_it->second.resize(num_of_copies, -1);
// Each -1 now means "print as usual" - we will replace it with actual extruder id (shifted it so we don't lose that information):
std::replace(entity_map_it->second.begin(), entity_map_it->second.end(), -1, -correct_extruder_id-1);
return &(entity_map_it->second);
}
} // namespace Slic3r