#include "libslic3r/libslic3r.h" #include "GCodeViewer.hpp" #include "libslic3r/Print.hpp" #include "libslic3r/Geometry.hpp" #include "libslic3r/Model.hpp" #include "libslic3r/Utils.hpp" #include "libslic3r/LocalesUtils.hpp" #include "GUI_App.hpp" #include "MainFrame.hpp" #include "Plater.hpp" #include "libslic3r/PresetBundle.hpp" #include "Camera.hpp" #include "I18N.hpp" #include "GUI_Utils.hpp" #include "GUI.hpp" #include "DoubleSlider.hpp" #include "GLCanvas3D.hpp" #include "GLToolbar.hpp" #include "GUI_Preview.hpp" #include "GUI_ObjectManipulation.hpp" #include #include #include #include #include #include #include #include #include #include #include namespace Slic3r { namespace GUI { static unsigned char buffer_id(EMoveType type) { return static_cast(type) - static_cast(EMoveType::Retract); } static EMoveType buffer_type(unsigned char id) { return static_cast(static_cast(EMoveType::Retract) + id); } static std::array decode_color(const std::string& color) { static const float INV_255 = 1.0f / 255.0f; std::array ret = { 0.0f, 0.0f, 0.0f }; const char* c = color.data() + 1; if (color.size() == 7 && color.front() == '#') { for (size_t j = 0; j < 3; ++j) { int digit1 = hex_digit_to_int(*c++); int digit2 = hex_digit_to_int(*c++); if (digit1 == -1 || digit2 == -1) break; ret[j] = float(digit1 * 16 + digit2) * INV_255; } } return ret; } static std::vector> decode_colors(const std::vector& colors) { std::vector> output(colors.size(), { 0.0f, 0.0f, 0.0f }); for (size_t i = 0; i < colors.size(); ++i) { output[i] = decode_color(colors[i]); } return output; } static float round_to_nearest(float value, unsigned int decimals) { float res = 0.0f; if (decimals == 0) res = std::round(value); else { char buf[64]; // locales should not matter, both sprintf and stof are sensitive, so... sprintf(buf, "%.*g", decimals, value); res = std::stof(buf); } return res; } void GCodeViewer::VBuffer::reset() { // release gpu memory if (!vbos.empty()) { glsafe(::glDeleteBuffers(static_cast(vbos.size()), static_cast(vbos.data()))); vbos.clear(); } sizes.clear(); count = 0; } void GCodeViewer::IBuffer::reset() { // release gpu memory if (ibo > 0) { glsafe(::glDeleteBuffers(1, &ibo)); ibo = 0; } vbo = 0; count = 0; } bool GCodeViewer::Path::matches(const GCodeProcessor::MoveVertex& move) const { auto matches_percent = [](float value1, float value2, float max_percent) { return std::abs(value2 - value1) / value1 <= max_percent; }; switch (move.type) { case EMoveType::Tool_change: case EMoveType::Color_change: case EMoveType::Pause_Print: case EMoveType::Custom_GCode: case EMoveType::Retract: case EMoveType::Unretract: case EMoveType::Seam: case EMoveType::Extrude: { // use rounding to reduce the number of generated paths return type == move.type && extruder_id == move.extruder_id && cp_color_id == move.cp_color_id && role == move.extrusion_role && move.position[2] <= sub_paths.front().first.position[2] && feedrate == move.feedrate && fan_speed == move.fan_speed && height == round_to_nearest(move.height, 2) && width == round_to_nearest(move.width, 2) && matches_percent(volumetric_rate, move.volumetric_rate(), 0.05f); } case EMoveType::Travel: { return type == move.type && feedrate == move.feedrate && extruder_id == move.extruder_id && cp_color_id == move.cp_color_id; } default: { return false; } } } void GCodeViewer::TBuffer::reset() { // release gpu memory vertices.reset(); for (IBuffer& buffer : indices) { buffer.reset(); } // release cpu memory indices.clear(); paths.clear(); render_paths.clear(); } void GCodeViewer::TBuffer::add_path(const GCodeProcessor::MoveVertex& move, unsigned int b_id, size_t i_id, size_t s_id) { Path::Endpoint endpoint = { b_id, i_id, s_id, move.position }; // use rounding to reduce the number of generated paths paths.push_back({ move.type, move.extrusion_role, move.delta_extruder, round_to_nearest(move.height, 2), round_to_nearest(move.width, 2), move.feedrate, move.fan_speed, move.temperature, move.volumetric_rate(), move.extruder_id, move.cp_color_id, { { endpoint, endpoint } } }); } GCodeViewer::Color GCodeViewer::Extrusions::Range::get_color_at(float value) const { // Input value scaled to the colors range const float step = step_size(); const float global_t = (step != 0.0f) ? std::max(0.0f, value - min) / step : 0.0f; // lower limit of 0.0f const size_t color_max_idx = Range_Colors.size() - 1; // Compute the two colors just below (low) and above (high) the input value const size_t color_low_idx = std::clamp(static_cast(global_t), 0, color_max_idx); const size_t color_high_idx = std::clamp(color_low_idx + 1, 0, color_max_idx); // Compute how far the value is between the low and high colors so that they can be interpolated const float local_t = std::clamp(global_t - static_cast(color_low_idx), 0.0f, 1.0f); // Interpolate between the low and high colors to find exactly which color the input value should get Color ret; for (unsigned int i = 0; i < 3; ++i) { ret[i] = lerp(Range_Colors[color_low_idx][i], Range_Colors[color_high_idx][i], local_t); } return ret; } GCodeViewer::SequentialRangeCap::~SequentialRangeCap() { if (ibo > 0) glsafe(::glDeleteBuffers(1, &ibo)); } void GCodeViewer::SequentialRangeCap::reset() { if (ibo > 0) glsafe(::glDeleteBuffers(1, &ibo)); buffer = nullptr; ibo = 0; vbo = 0; color = { 0.0f, 0.0f, 0.0f }; } void GCodeViewer::SequentialView::Marker::init() { m_model.init_from(stilized_arrow(16, 2.0f, 4.0f, 1.0f, 8.0f)); m_model.set_color(-1, { 1.0f, 1.0f, 1.0f, 0.5f }); } void GCodeViewer::SequentialView::Marker::set_world_position(const Vec3f& position) { m_world_position = position; m_world_transform = (Geometry::assemble_transform((position + m_z_offset * Vec3f::UnitZ()).cast()) * Geometry::assemble_transform(m_model.get_bounding_box().size()[2] * Vec3d::UnitZ(), { M_PI, 0.0, 0.0 })).cast(); } void GCodeViewer::SequentialView::Marker::render() const { if (!m_visible) return; GLShaderProgram* shader = wxGetApp().get_shader("gouraud_light"); if (shader == nullptr) return; glsafe(::glEnable(GL_BLEND)); glsafe(::glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA)); shader->start_using(); shader->set_uniform("emission_factor", 0.0); glsafe(::glPushMatrix()); glsafe(::glMultMatrixf(m_world_transform.data())); m_model.render(); glsafe(::glPopMatrix()); shader->stop_using(); glsafe(::glDisable(GL_BLEND)); static float last_window_width = 0.0f; static size_t last_text_length = 0; ImGuiWrapper& imgui = *wxGetApp().imgui(); Size cnv_size = wxGetApp().plater()->get_current_canvas3D()->get_canvas_size(); imgui.set_next_window_pos(0.5f * static_cast(cnv_size.get_width()), static_cast(cnv_size.get_height()), ImGuiCond_Always, 0.5f, 1.0f); ImGui::PushStyleVar(ImGuiStyleVar_WindowRounding, 0.0f); ImGui::SetNextWindowBgAlpha(0.25f); imgui.begin(std::string("ToolPosition"), ImGuiWindowFlags_AlwaysAutoResize | ImGuiWindowFlags_NoDecoration | ImGuiWindowFlags_NoMove); imgui.text_colored(ImGuiWrapper::COL_ORANGE_LIGHT, _u8L("Tool position") + ":"); ImGui::SameLine(); char buf[1024]; sprintf(buf, "X: %.3f, Y: %.3f, Z: %.3f", m_world_position(0), m_world_position(1), m_world_position(2)); imgui.text(std::string(buf)); // force extra frame to automatically update window size float width = ImGui::GetWindowWidth(); size_t length = strlen(buf); if (width != last_window_width || length != last_text_length) { last_window_width = width; last_text_length = length; wxGetApp().plater()->get_current_canvas3D()->set_as_dirty(); wxGetApp().plater()->get_current_canvas3D()->request_extra_frame(); } imgui.end(); ImGui::PopStyleVar(); } void GCodeViewer::SequentialView::GCodeWindow::load_gcode() { if (m_filename.empty()) return; if (m_file.is_open()) return; try { // generate mapping for accessing data in file by line number boost::nowide::ifstream f(m_filename); f.seekg(0, f.end); uint64_t file_length = static_cast(f.tellg()); f.seekg(0, f.beg); std::string line; uint64_t offset = 0; while (std::getline(f, line)) { uint64_t line_length = static_cast(line.length()); m_lines_map.push_back({ offset, line_length }); offset += static_cast(line_length) + 1; } if (offset != file_length) { // if the final offset does not match with file length, lines are terminated with CR+LF // so update all offsets accordingly for (size_t i = 0; i < m_lines_map.size(); ++i) { m_lines_map[i].first += static_cast(i); } } } catch (...) { BOOST_LOG_TRIVIAL(error) << "Unable to load data from " << m_filename << ". Cannot show G-code window."; reset(); return; } m_selected_line_id = 0; m_last_lines_size = 0; try { m_file.open(boost::filesystem::path(m_filename)); } catch (...) { BOOST_LOG_TRIVIAL(error) << "Unable to map file " << m_filename << ". Cannot show G-code window."; reset(); } } void GCodeViewer::SequentialView::GCodeWindow::render(float top, float bottom, uint64_t curr_line_id) const { auto update_lines = [this](uint64_t start_id, uint64_t end_id) { std::vector ret; ret.reserve(end_id - start_id + 1); for (uint64_t id = start_id; id <= end_id; ++id) { // read line from file std::string gline(m_file.data() + m_lines_map[id - 1].first, m_lines_map[id - 1].second); std::string command; std::string parameters; std::string comment; // extract comment std::vector tokens; boost::split(tokens, gline, boost::is_any_of(";"), boost::token_compress_on); command = tokens.front(); if (tokens.size() > 1) comment = ";" + tokens.back(); // extract gcode command and parameters if (!command.empty()) { boost::split(tokens, command, boost::is_any_of(" "), boost::token_compress_on); command = tokens.front(); if (tokens.size() > 1) { for (size_t i = 1; i < tokens.size(); ++i) { parameters += " " + tokens[i]; } } } ret.push_back({ command, parameters, comment }); } return ret; }; static const ImVec4 LINE_NUMBER_COLOR = ImGuiWrapper::COL_ORANGE_LIGHT; static const ImVec4 SELECTION_RECT_COLOR = ImGuiWrapper::COL_ORANGE_DARK; static const ImVec4 COMMAND_COLOR = { 0.8f, 0.8f, 0.0f, 1.0f }; static const ImVec4 PARAMETERS_COLOR = { 1.0f, 1.0f, 1.0f, 1.0f }; static const ImVec4 COMMENT_COLOR = { 0.7f, 0.7f, 0.7f, 1.0f }; if (!m_visible || m_filename.empty() || m_lines_map.empty() || curr_line_id == 0) return; // window height const float wnd_height = bottom - top; // number of visible lines const float text_height = ImGui::CalcTextSize("0").y; const ImGuiStyle& style = ImGui::GetStyle(); const uint64_t lines_count = static_cast((wnd_height - 2.0f * style.WindowPadding.y + style.ItemSpacing.y) / (text_height + style.ItemSpacing.y)); if (lines_count == 0) return; // visible range const uint64_t half_lines_count = lines_count / 2; uint64_t start_id = (curr_line_id >= half_lines_count) ? curr_line_id - half_lines_count : 0; uint64_t end_id = start_id + lines_count - 1; if (end_id >= static_cast(m_lines_map.size())) { end_id = static_cast(m_lines_map.size()) - 1; start_id = end_id - lines_count + 1; } // updates list of lines to show, if needed if (m_selected_line_id != curr_line_id || m_last_lines_size != end_id - start_id + 1) { try { *const_cast*>(&m_lines) = update_lines(start_id, end_id); } catch (...) { BOOST_LOG_TRIVIAL(error) << "Error while loading from file " << m_filename << ". Cannot show G-code window."; return; } *const_cast(&m_selected_line_id) = curr_line_id; *const_cast(&m_last_lines_size) = m_lines.size(); } // line number's column width const float id_width = ImGui::CalcTextSize(std::to_string(end_id).c_str()).x; ImGuiWrapper& imgui = *wxGetApp().imgui(); imgui.set_next_window_pos(0.0f, top, ImGuiCond_Always, 0.0f, 0.0f); imgui.set_next_window_size(0.0f, wnd_height, ImGuiCond_Always); ImGui::PushStyleVar(ImGuiStyleVar_WindowRounding, 0.0f); ImGui::SetNextWindowBgAlpha(0.6f); imgui.begin(std::string("G-code"), ImGuiWindowFlags_AlwaysAutoResize | ImGuiWindowFlags_NoDecoration | ImGuiWindowFlags_NoMove); // center the text in the window by pushing down the first line const float f_lines_count = static_cast(lines_count); ImGui::SetCursorPosY(0.5f * (wnd_height - f_lines_count * text_height - (f_lines_count - 1.0f) * style.ItemSpacing.y)); // render text lines for (uint64_t id = start_id; id <= end_id; ++id) { const Line& line = m_lines[id - start_id]; // rect around the current selected line if (id == curr_line_id) { const float pos_y = ImGui::GetCursorScreenPos().y; const float half_ItemSpacing_y = 0.5f * style.ItemSpacing.y; const float half_padding_x = 0.5f * style.WindowPadding.x; ImGui::GetWindowDrawList()->AddRect({ half_padding_x, pos_y - half_ItemSpacing_y }, { ImGui::GetCurrentWindow()->Size.x - half_padding_x, pos_y + text_height + half_ItemSpacing_y }, ImGui::GetColorU32(SELECTION_RECT_COLOR)); } // render line number const std::string id_str = std::to_string(id); // spacer to right align text ImGui::Dummy({ id_width - ImGui::CalcTextSize(id_str.c_str()).x, text_height }); ImGui::SameLine(0.0f, 0.0f); ImGui::PushStyleColor(ImGuiCol_Text, LINE_NUMBER_COLOR); imgui.text(id_str); ImGui::PopStyleColor(); if (!line.command.empty() || !line.comment.empty()) ImGui::SameLine(); // render command if (!line.command.empty()) { ImGui::PushStyleColor(ImGuiCol_Text, COMMAND_COLOR); imgui.text(line.command); ImGui::PopStyleColor(); } // render parameters if (!line.parameters.empty()) { ImGui::SameLine(0.0f, 0.0f); ImGui::PushStyleColor(ImGuiCol_Text, PARAMETERS_COLOR); imgui.text(line.parameters); ImGui::PopStyleColor(); } // render comment if (!line.comment.empty()) { if (!line.command.empty()) ImGui::SameLine(0.0f, 0.0f); ImGui::PushStyleColor(ImGuiCol_Text, COMMENT_COLOR); imgui.text(line.comment); ImGui::PopStyleColor(); } } imgui.end(); ImGui::PopStyleVar(); } void GCodeViewer::SequentialView::GCodeWindow::stop_mapping_file() { if (m_file.is_open()) m_file.close(); } void GCodeViewer::SequentialView::render(float legend_height) const { marker.render(); float bottom = wxGetApp().plater()->get_current_canvas3D()->get_canvas_size().get_height(); if (wxGetApp().is_editor()) bottom -= wxGetApp().plater()->get_view_toolbar().get_height(); gcode_window.render(legend_height, bottom, static_cast(gcode_ids[current.last])); } const std::vector GCodeViewer::Extrusion_Role_Colors {{ { 0.75f, 0.75f, 0.75f }, // erNone { 1.00f, 0.90f, 0.30f }, // erPerimeter { 1.00f, 0.49f, 0.22f }, // erExternalPerimeter { 0.12f, 0.12f, 1.00f }, // erOverhangPerimeter { 0.69f, 0.19f, 0.16f }, // erInternalInfill { 0.59f, 0.33f, 0.80f }, // erSolidInfill { 0.94f, 0.25f, 0.25f }, // erTopSolidInfill { 1.00f, 0.55f, 0.41f }, // erIroning { 0.30f, 0.50f, 0.73f }, // erBridgeInfill { 1.00f, 1.00f, 1.00f }, // erGapFill { 0.00f, 0.53f, 0.43f }, // erSkirt { 0.00f, 1.00f, 0.00f }, // erSupportMaterial { 0.00f, 0.50f, 0.00f }, // erSupportMaterialInterface { 0.70f, 0.89f, 0.67f }, // erWipeTower { 0.37f, 0.82f, 0.58f }, // erCustom { 0.00f, 0.00f, 0.00f } // erMixed }}; const std::vector GCodeViewer::Options_Colors {{ { 0.803f, 0.135f, 0.839f }, // Retractions { 0.287f, 0.679f, 0.810f }, // Unretractions { 0.900f, 0.900f, 0.900f }, // Seams { 0.758f, 0.744f, 0.389f }, // ToolChanges { 0.856f, 0.582f, 0.546f }, // ColorChanges { 0.322f, 0.942f, 0.512f }, // PausePrints { 0.886f, 0.825f, 0.262f } // CustomGCodes }}; const std::vector GCodeViewer::Travel_Colors {{ { 0.219f, 0.282f, 0.609f }, // Move { 0.112f, 0.422f, 0.103f }, // Extrude { 0.505f, 0.064f, 0.028f } // Retract }}; const GCodeViewer::Color GCodeViewer::Wipe_Color = { 1.0f, 1.0f, 0.0f }; const std::vector GCodeViewer::Range_Colors {{ { 0.043f, 0.173f, 0.478f }, // bluish { 0.075f, 0.349f, 0.522f }, { 0.110f, 0.533f, 0.569f }, { 0.016f, 0.839f, 0.059f }, { 0.667f, 0.949f, 0.000f }, { 0.988f, 0.975f, 0.012f }, { 0.961f, 0.808f, 0.039f }, { 0.890f, 0.533f, 0.125f }, { 0.820f, 0.408f, 0.188f }, { 0.761f, 0.322f, 0.235f }, { 0.581f, 0.149f, 0.087f } // reddish }}; GCodeViewer::GCodeViewer() { // initializes non OpenGL data of TBuffers // OpenGL data are initialized into render().init_gl_data() for (size_t i = 0; i < m_buffers.size(); ++i) { TBuffer& buffer = m_buffers[i]; switch (buffer_type(i)) { default: { break; } case EMoveType::Tool_change: case EMoveType::Color_change: case EMoveType::Pause_Print: case EMoveType::Custom_GCode: case EMoveType::Retract: case EMoveType::Unretract: case EMoveType::Seam: { buffer.render_primitive_type = TBuffer::ERenderPrimitiveType::Point; buffer.vertices.format = VBuffer::EFormat::Position; break; } case EMoveType::Wipe: case EMoveType::Extrude: { buffer.render_primitive_type = TBuffer::ERenderPrimitiveType::Triangle; buffer.vertices.format = VBuffer::EFormat::PositionNormal3; break; } case EMoveType::Travel: { buffer.render_primitive_type = TBuffer::ERenderPrimitiveType::Line; buffer.vertices.format = VBuffer::EFormat::PositionNormal1; break; } } } set_toolpath_move_type_visible(EMoveType::Extrude, true); // m_sequential_view.skip_invisible_moves = true; } void GCodeViewer::load(const GCodeProcessor::Result& gcode_result, const Print& print, bool initialized) { // avoid processing if called with the same gcode_result if (m_last_result_id == gcode_result.id) return; m_last_result_id = gcode_result.id; // release gpu memory, if used reset(); m_sequential_view.gcode_window.set_filename(gcode_result.filename); m_sequential_view.gcode_window.load_gcode(); #if ENABLE_FIX_IMPORTING_COLOR_PRINT_VIEW_INTO_GCODEVIEWER if (wxGetApp().is_gcode_viewer()) m_custom_gcode_per_print_z = gcode_result.custom_gcode_per_print_z; #endif // ENABLE_FIX_IMPORTING_COLOR_PRINT_VIEW_INTO_GCODEVIEWER load_toolpaths(gcode_result); if (m_layers.empty()) return; m_settings_ids = gcode_result.settings_ids; m_filament_diameters = gcode_result.filament_diameters; m_filament_densities = gcode_result.filament_densities; if (wxGetApp().is_editor()) load_shells(print, initialized); else { Pointfs bed_shape; std::string texture; std::string model; if (!gcode_result.bed_shape.empty()) { // bed shape detected in the gcode bed_shape = gcode_result.bed_shape; auto bundle = wxGetApp().preset_bundle; if (bundle != nullptr && !m_settings_ids.printer.empty()) { const Preset* preset = bundle->printers.find_preset(m_settings_ids.printer); if (preset != nullptr) { model = PresetUtils::system_printer_bed_model(*preset); texture = PresetUtils::system_printer_bed_texture(*preset); } } } else { // adjust printbed size in dependence of toolpaths bbox const double margin = 10.0; Vec2d min(m_paths_bounding_box.min(0) - margin, m_paths_bounding_box.min(1) - margin); Vec2d max(m_paths_bounding_box.max(0) + margin, m_paths_bounding_box.max(1) + margin); Vec2d size = max - min; bed_shape = { { min(0), min(1) }, { max(0), min(1) }, { max(0), min(1) + 0.442265 * size[1]}, { max(0) - 10.0, min(1) + 0.4711325 * size[1]}, { max(0) + 10.0, min(1) + 0.5288675 * size[1]}, { max(0), min(1) + 0.557735 * size[1]}, { max(0), max(1) }, { min(0) + 0.557735 * size[0], max(1)}, { min(0) + 0.5288675 * size[0], max(1) - 10.0}, { min(0) + 0.4711325 * size[0], max(1) + 10.0}, { min(0) + 0.442265 * size[0], max(1)}, { min(0), max(1) } }; } wxGetApp().plater()->set_bed_shape(bed_shape, texture, model, gcode_result.bed_shape.empty()); } m_print_statistics = gcode_result.print_statistics; if (m_time_estimate_mode != PrintEstimatedStatistics::ETimeMode::Normal) { float time = m_print_statistics.modes[static_cast(m_time_estimate_mode)].time; if (time == 0.0f || short_time(get_time_dhms(time)) == short_time(get_time_dhms(m_print_statistics.modes[static_cast(PrintEstimatedStatistics::ETimeMode::Normal)].time))) m_time_estimate_mode = PrintEstimatedStatistics::ETimeMode::Normal; } } void GCodeViewer::refresh(const GCodeProcessor::Result& gcode_result, const std::vector& str_tool_colors) { #if ENABLE_GCODE_VIEWER_STATISTICS auto start_time = std::chrono::high_resolution_clock::now(); #endif // ENABLE_GCODE_VIEWER_STATISTICS if (m_moves_count == 0) return; wxBusyCursor busy; if (m_view_type == EViewType::Tool && !gcode_result.extruder_colors.empty()) // update tool colors from config stored in the gcode m_tool_colors = decode_colors(gcode_result.extruder_colors); else // update tool colors m_tool_colors = decode_colors(str_tool_colors); // ensure at least one (default) color is defined if (m_tool_colors.empty()) m_tool_colors.push_back(decode_color("#FF8000")); // update ranges for coloring / legend m_extrusions.reset_ranges(); for (size_t i = 0; i < m_moves_count; ++i) { // skip first vertex if (i == 0) continue; const GCodeProcessor::MoveVertex& curr = gcode_result.moves[i]; switch (curr.type) { case EMoveType::Extrude: { m_extrusions.ranges.height.update_from(round_to_nearest(curr.height, 2)); m_extrusions.ranges.width.update_from(round_to_nearest(curr.width, 2)); m_extrusions.ranges.fan_speed.update_from(curr.fan_speed); m_extrusions.ranges.temperature.update_from(curr.temperature); m_extrusions.ranges.volumetric_rate.update_from(round_to_nearest(curr.volumetric_rate(), 2)); [[fallthrough]]; } case EMoveType::Travel: { if (m_buffers[buffer_id(curr.type)].visible) m_extrusions.ranges.feedrate.update_from(curr.feedrate); break; } default: { break; } } } #if ENABLE_GCODE_VIEWER_STATISTICS m_statistics.refresh_time = std::chrono::duration_cast(std::chrono::high_resolution_clock::now() - start_time).count(); #endif // ENABLE_GCODE_VIEWER_STATISTICS // update buffers' render paths refresh_render_paths(); log_memory_used("Refreshed G-code extrusion paths, "); } void GCodeViewer::refresh_render_paths() { refresh_render_paths(false, false); } void GCodeViewer::update_shells_color_by_extruder(const DynamicPrintConfig* config) { if (config != nullptr) m_shells.volumes.update_colors_by_extruder(config); } void GCodeViewer::reset() { m_moves_count = 0; for (TBuffer& buffer : m_buffers) { buffer.reset(); } m_paths_bounding_box = BoundingBoxf3(); m_max_bounding_box = BoundingBoxf3(); m_tool_colors = std::vector(); m_extruders_count = 0; m_extruder_ids = std::vector(); m_filament_diameters = std::vector(); m_filament_densities = std::vector(); m_extrusions.reset_role_visibility_flags(); m_extrusions.reset_ranges(); m_shells.volumes.clear(); m_layers.reset(); m_layers_z_range = { 0, 0 }; m_roles = std::vector(); m_print_statistics.reset(); #if ENABLE_FIX_IMPORTING_COLOR_PRINT_VIEW_INTO_GCODEVIEWER m_custom_gcode_per_print_z = std::vector(); #endif // ENABLE_FIX_IMPORTING_COLOR_PRINT_VIEW_INTO_GCODEVIEWER m_sequential_view.gcode_window.reset(); #if ENABLE_GCODE_VIEWER_STATISTICS m_statistics.reset_all(); #endif // ENABLE_GCODE_VIEWER_STATISTICS } void GCodeViewer::render() const { auto init_gl_data = [this]() { // initializes opengl data of TBuffers for (size_t i = 0; i < m_buffers.size(); ++i) { TBuffer& buffer = const_cast(m_buffers[i]); switch (buffer_type(i)) { default: { break; } case EMoveType::Tool_change: case EMoveType::Color_change: case EMoveType::Pause_Print: case EMoveType::Custom_GCode: case EMoveType::Retract: case EMoveType::Unretract: case EMoveType::Seam: { buffer.shader = wxGetApp().is_glsl_version_greater_or_equal_to(1, 20) ? "options_120" : "options_110"; break; } case EMoveType::Wipe: case EMoveType::Extrude: { buffer.shader = "gouraud_light"; break; } case EMoveType::Travel: { buffer.shader = "toolpaths_lines"; break; } } } // initializes tool marker const_cast(&m_sequential_view)->marker.init(); // initializes point sizes std::array point_sizes; ::glGetIntegerv(GL_ALIASED_POINT_SIZE_RANGE, point_sizes.data()); *const_cast*>(&m_detected_point_sizes) = { static_cast(point_sizes[0]), static_cast(point_sizes[1]) }; *const_cast(&m_gl_data_initialized) = true; }; #if ENABLE_GCODE_VIEWER_STATISTICS const_cast(&m_statistics)->reset_opengl(); #endif // ENABLE_GCODE_VIEWER_STATISTICS // OpenGL data must be initialized after the glContext has been created. // This is ensured when this method is called by GLCanvas3D::_render_gcode(). if (!m_gl_data_initialized) init_gl_data(); if (m_roles.empty()) return; glsafe(::glEnable(GL_DEPTH_TEST)); render_toolpaths(); render_shells(); float legend_height = 0.0f; render_legend(legend_height); SequentialView* sequential_view = const_cast(&m_sequential_view); if (sequential_view->current.last != sequential_view->endpoints.last) { sequential_view->marker.set_world_position(sequential_view->current_position); sequential_view->render(legend_height); } #if ENABLE_GCODE_VIEWER_STATISTICS render_statistics(); #endif // ENABLE_GCODE_VIEWER_STATISTICS } bool GCodeViewer::can_export_toolpaths() const { return has_data() && m_buffers[buffer_id(EMoveType::Extrude)].render_primitive_type == TBuffer::ERenderPrimitiveType::Triangle; } void GCodeViewer::update_sequential_view_current(unsigned int first, unsigned int last) { auto is_visible = [this](unsigned int id) { for (const TBuffer& buffer : m_buffers) { if (buffer.visible) { for (const Path& path : buffer.paths) { if (path.sub_paths.front().first.s_id <= id && id <= path.sub_paths.back().last.s_id) return true; } } } return false; }; int first_diff = static_cast(first) - static_cast(m_sequential_view.last_current.first); int last_diff = static_cast(last) - static_cast(m_sequential_view.last_current.last); unsigned int new_first = first; unsigned int new_last = last; if (m_sequential_view.skip_invisible_moves) { while (!is_visible(new_first)) { if (first_diff > 0) ++new_first; else --new_first; } while (!is_visible(new_last)) { if (last_diff > 0) ++new_last; else --new_last; } } m_sequential_view.current.first = new_first; m_sequential_view.current.last = new_last; m_sequential_view.last_current = m_sequential_view.current; refresh_render_paths(true, true); if (new_first != first || new_last != last) wxGetApp().plater()->update_preview_moves_slider(); } bool GCodeViewer::is_toolpath_move_type_visible(EMoveType type) const { size_t id = static_cast(buffer_id(type)); return (id < m_buffers.size()) ? m_buffers[id].visible : false; } void GCodeViewer::set_toolpath_move_type_visible(EMoveType type, bool visible) { size_t id = static_cast(buffer_id(type)); if (id < m_buffers.size()) m_buffers[id].visible = visible; } unsigned int GCodeViewer::get_options_visibility_flags() const { auto set_flag = [](unsigned int flags, unsigned int flag, bool active) { return active ? (flags | (1 << flag)) : flags; }; unsigned int flags = 0; flags = set_flag(flags, static_cast(Preview::OptionType::Travel), is_toolpath_move_type_visible(EMoveType::Travel)); flags = set_flag(flags, static_cast(Preview::OptionType::Wipe), is_toolpath_move_type_visible(EMoveType::Wipe)); flags = set_flag(flags, static_cast(Preview::OptionType::Retractions), is_toolpath_move_type_visible(EMoveType::Retract)); flags = set_flag(flags, static_cast(Preview::OptionType::Unretractions), is_toolpath_move_type_visible(EMoveType::Unretract)); flags = set_flag(flags, static_cast(Preview::OptionType::Seams), is_toolpath_move_type_visible(EMoveType::Seam)); flags = set_flag(flags, static_cast(Preview::OptionType::ToolChanges), is_toolpath_move_type_visible(EMoveType::Tool_change)); flags = set_flag(flags, static_cast(Preview::OptionType::ColorChanges), is_toolpath_move_type_visible(EMoveType::Color_change)); flags = set_flag(flags, static_cast(Preview::OptionType::PausePrints), is_toolpath_move_type_visible(EMoveType::Pause_Print)); flags = set_flag(flags, static_cast(Preview::OptionType::CustomGCodes), is_toolpath_move_type_visible(EMoveType::Custom_GCode)); flags = set_flag(flags, static_cast(Preview::OptionType::Shells), m_shells.visible); flags = set_flag(flags, static_cast(Preview::OptionType::ToolMarker), m_sequential_view.marker.is_visible()); flags = set_flag(flags, static_cast(Preview::OptionType::Legend), is_legend_enabled()); return flags; } void GCodeViewer::set_options_visibility_from_flags(unsigned int flags) { auto is_flag_set = [flags](unsigned int flag) { return (flags & (1 << flag)) != 0; }; set_toolpath_move_type_visible(EMoveType::Travel, is_flag_set(static_cast(Preview::OptionType::Travel))); set_toolpath_move_type_visible(EMoveType::Wipe, is_flag_set(static_cast(Preview::OptionType::Wipe))); set_toolpath_move_type_visible(EMoveType::Retract, is_flag_set(static_cast(Preview::OptionType::Retractions))); set_toolpath_move_type_visible(EMoveType::Unretract, is_flag_set(static_cast(Preview::OptionType::Unretractions))); set_toolpath_move_type_visible(EMoveType::Seam, is_flag_set(static_cast(Preview::OptionType::Seams))); set_toolpath_move_type_visible(EMoveType::Tool_change, is_flag_set(static_cast(Preview::OptionType::ToolChanges))); set_toolpath_move_type_visible(EMoveType::Color_change, is_flag_set(static_cast(Preview::OptionType::ColorChanges))); set_toolpath_move_type_visible(EMoveType::Pause_Print, is_flag_set(static_cast(Preview::OptionType::PausePrints))); set_toolpath_move_type_visible(EMoveType::Custom_GCode, is_flag_set(static_cast(Preview::OptionType::CustomGCodes))); m_shells.visible = is_flag_set(static_cast(Preview::OptionType::Shells)); m_sequential_view.marker.set_visible(is_flag_set(static_cast(Preview::OptionType::ToolMarker))); enable_legend(is_flag_set(static_cast(Preview::OptionType::Legend))); } void GCodeViewer::set_layers_z_range(const std::array& layers_z_range) { bool keep_sequential_current_first = layers_z_range[0] >= m_layers_z_range[0]; bool keep_sequential_current_last = layers_z_range[1] <= m_layers_z_range[1]; m_layers_z_range = layers_z_range; refresh_render_paths(keep_sequential_current_first, keep_sequential_current_last); wxGetApp().plater()->update_preview_moves_slider(); } void GCodeViewer::export_toolpaths_to_obj(const char* filename) const { if (filename == nullptr) return; if (!has_data()) return; wxBusyCursor busy; // the data needed is contained into the Extrude TBuffer const TBuffer& t_buffer = m_buffers[buffer_id(EMoveType::Extrude)]; if (!t_buffer.has_data()) return; if (t_buffer.render_primitive_type != TBuffer::ERenderPrimitiveType::Triangle) return; // collect color information to generate materials std::vector colors; for (const RenderPath& path : t_buffer.render_paths) { colors.push_back(path.color); } std::sort(colors.begin(), colors.end()); colors.erase(std::unique(colors.begin(), colors.end()), colors.end()); // save materials file boost::filesystem::path mat_filename(filename); mat_filename.replace_extension("mtl"); CNumericLocalesSetter locales_setter; FILE* fp = boost::nowide::fopen(mat_filename.string().c_str(), "w"); if (fp == nullptr) { BOOST_LOG_TRIVIAL(error) << "GCodeViewer::export_toolpaths_to_obj: Couldn't open " << mat_filename.string().c_str() << " for writing"; return; } fprintf(fp, "# G-Code Toolpaths Materials\n"); fprintf(fp, "# Generated by %s-%s based on Slic3r\n", SLIC3R_APP_NAME, SLIC3R_VERSION); unsigned int colors_count = 1; for (const Color& color : colors) { fprintf(fp, "\nnewmtl material_%d\n", colors_count++); fprintf(fp, "Ka 1 1 1\n"); fprintf(fp, "Kd %g %g %g\n", color[0], color[1], color[2]); fprintf(fp, "Ks 0 0 0\n"); } fclose(fp); // save geometry file fp = boost::nowide::fopen(filename, "w"); if (fp == nullptr) { BOOST_LOG_TRIVIAL(error) << "GCodeViewer::export_toolpaths_to_obj: Couldn't open " << filename << " for writing"; return; } fprintf(fp, "# G-Code Toolpaths\n"); fprintf(fp, "# Generated by %s-%s based on Slic3r\n", SLIC3R_APP_NAME, SLIC3R_VERSION); fprintf(fp, "\nmtllib ./%s\n", mat_filename.filename().string().c_str()); const size_t floats_per_vertex = t_buffer.vertices.vertex_size_floats(); std::vector out_vertices; std::vector out_normals; struct VerticesOffset { unsigned int vbo; size_t offset; }; std::vector vertices_offsets; vertices_offsets.push_back({ t_buffer.vertices.vbos.front(), 0 }); // get vertices/normals data from vertex buffers on gpu for (size_t i = 0; i < t_buffer.vertices.vbos.size(); ++i) { const size_t floats_count = t_buffer.vertices.sizes[i] / sizeof(float); VertexBuffer vertices(floats_count); glsafe(::glBindBuffer(GL_ARRAY_BUFFER, t_buffer.vertices.vbos[i])); glsafe(::glGetBufferSubData(GL_ARRAY_BUFFER, 0, static_cast(t_buffer.vertices.sizes[i]), static_cast(vertices.data()))); glsafe(::glBindBuffer(GL_ARRAY_BUFFER, 0)); const size_t vertices_count = floats_count / floats_per_vertex; for (size_t j = 0; j < vertices_count; ++j) { const size_t base = j * floats_per_vertex; out_vertices.push_back({ vertices[base + 0], vertices[base + 1], vertices[base + 2] }); out_normals.push_back({ vertices[base + 3], vertices[base + 4], vertices[base + 5] }); } if (i < t_buffer.vertices.vbos.size() - 1) vertices_offsets.push_back({ t_buffer.vertices.vbos[i + 1], vertices_offsets.back().offset + vertices_count }); } // save vertices to file fprintf(fp, "\n# vertices\n"); for (const Vec3f& v : out_vertices) { fprintf(fp, "v %g %g %g\n", v[0], v[1], v[2]); } // save normals to file fprintf(fp, "\n# normals\n"); for (const Vec3f& n : out_normals) { fprintf(fp, "vn %g %g %g\n", n[0], n[1], n[2]); } size_t i = 0; for (const Color& color : colors) { // save material triangles to file fprintf(fp, "\nusemtl material_%zu\n", i + 1); fprintf(fp, "# triangles material %zu\n", i + 1); for (const RenderPath& render_path : t_buffer.render_paths) { if (render_path.color != color) continue; const IBuffer& ibuffer = t_buffer.indices[render_path.ibuffer_id]; size_t vertices_offset = 0; for (size_t j = 0; j < vertices_offsets.size(); ++j) { const VerticesOffset& offset = vertices_offsets[j]; if (offset.vbo == ibuffer.vbo) { vertices_offset = offset.offset; break; } } // get indices data from index buffer on gpu glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, ibuffer.ibo)); for (size_t j = 0; j < render_path.sizes.size(); ++j) { IndexBuffer indices(render_path.sizes[j]); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast(render_path.offsets[j]), static_cast(render_path.sizes[j] * sizeof(IBufferType)), static_cast(indices.data()))); const size_t triangles_count = render_path.sizes[j] / 3; for (size_t k = 0; k < triangles_count; ++k) { const size_t base = k * 3; const size_t v1 = 1 + static_cast(indices[base + 0]) + vertices_offset; const size_t v2 = 1 + static_cast(indices[base + 1]) + vertices_offset; const size_t v3 = 1 + static_cast(indices[base + 2]) + vertices_offset; if (v1 != v2) // do not export dummy triangles fprintf(fp, "f %zu//%zu %zu//%zu %zu//%zu\n", v1, v1, v2, v2, v3, v3); } } glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); } ++i; } fclose(fp); } void GCodeViewer::start_mapping_gcode_window() { m_sequential_view.gcode_window.load_gcode(); } void GCodeViewer::stop_mapping_gcode_window() { m_sequential_view.gcode_window.stop_mapping_file(); } void GCodeViewer::load_toolpaths(const GCodeProcessor::Result& gcode_result) { // max index buffer size, in bytes static const size_t IBUFFER_THRESHOLD_BYTES = 64 * 1024 * 1024; auto log_memory_usage = [this](const std::string& label, const std::vector& vertices, const std::vector& indices) { int64_t vertices_size = 0; for (const MultiVertexBuffer& buffers : vertices) { for (const VertexBuffer& buffer : buffers) { vertices_size += SLIC3R_STDVEC_MEMSIZE(buffer, float); } } int64_t indices_size = 0; for (const MultiIndexBuffer& buffers : indices) { for (const IndexBuffer& buffer : buffers) { indices_size += SLIC3R_STDVEC_MEMSIZE(buffer, IBufferType); } } log_memory_used(label, vertices_size + indices_size); }; // format data into the buffers to be rendered as points auto add_vertices_as_point = [](const GCodeProcessor::MoveVertex& curr, VertexBuffer& vertices) { vertices.push_back(curr.position[0]); vertices.push_back(curr.position[1]); vertices.push_back(curr.position[2]); }; auto add_indices_as_point = [](const GCodeProcessor::MoveVertex& curr, TBuffer& buffer, unsigned int ibuffer_id, IndexBuffer& indices, size_t move_id) { buffer.add_path(curr, ibuffer_id, indices.size(), move_id); indices.push_back(static_cast(indices.size())); }; // format data into the buffers to be rendered as lines auto add_vertices_as_line = [](const GCodeProcessor::MoveVertex& prev, const GCodeProcessor::MoveVertex& curr, VertexBuffer& vertices) { // x component of the normal to the current segment (the normal is parallel to the XY plane) float normal_x = (curr.position - prev.position).normalized()[1]; auto add_vertex = [&vertices, normal_x](const GCodeProcessor::MoveVertex& vertex) { // add position vertices.push_back(vertex.position[0]); vertices.push_back(vertex.position[1]); vertices.push_back(vertex.position[2]); // add normal x component vertices.push_back(normal_x); }; // add previous vertex add_vertex(prev); // add current vertex add_vertex(curr); }; auto add_indices_as_line = [](const GCodeProcessor::MoveVertex& prev, const GCodeProcessor::MoveVertex& curr, TBuffer& buffer, unsigned int ibuffer_id, IndexBuffer& indices, size_t move_id) { if (prev.type != curr.type || !buffer.paths.back().matches(curr)) { // add starting index indices.push_back(static_cast(indices.size())); buffer.add_path(curr, ibuffer_id, indices.size() - 1, move_id - 1); buffer.paths.back().sub_paths.front().first.position = prev.position; } Path& last_path = buffer.paths.back(); if (last_path.sub_paths.front().first.i_id != last_path.sub_paths.back().last.i_id) { // add previous index indices.push_back(static_cast(indices.size())); } // add current index indices.push_back(static_cast(indices.size())); last_path.sub_paths.back().last = { ibuffer_id, indices.size() - 1, move_id, curr.position }; }; // format data into the buffers to be rendered as solid auto add_vertices_as_solid = [](const GCodeProcessor::MoveVertex& prev, const GCodeProcessor::MoveVertex& curr, TBuffer& buffer, unsigned int vbuffer_id, VertexBuffer& vertices, size_t move_id) { auto store_vertex = [](VertexBuffer& vertices, const Vec3f& position, const Vec3f& normal) { // append position vertices.push_back(position[0]); vertices.push_back(position[1]); vertices.push_back(position[2]); // append normal vertices.push_back(normal[0]); vertices.push_back(normal[1]); vertices.push_back(normal[2]); }; if (prev.type != curr.type || !buffer.paths.back().matches(curr)) { buffer.add_path(curr, vbuffer_id, vertices.size(), move_id - 1); buffer.paths.back().sub_paths.back().first.position = prev.position; } Path& last_path = buffer.paths.back(); Vec3f dir = (curr.position - prev.position).normalized(); Vec3f right = Vec3f(dir[1], -dir[0], 0.0f).normalized(); Vec3f left = -right; Vec3f up = right.cross(dir); Vec3f down = -up; float half_width = 0.5f * last_path.width; float half_height = 0.5f * last_path.height; Vec3f prev_pos = prev.position - half_height * up; Vec3f curr_pos = curr.position - half_height * up; Vec3f d_up = half_height * up; Vec3f d_down = -half_height * up; Vec3f d_right = half_width * right; Vec3f d_left = -half_width * right; // vertices 1st endpoint if (last_path.vertices_count() == 1 || vertices.empty()) { // 1st segment or restart into a new vertex buffer // =============================================== store_vertex(vertices, prev_pos + d_up, up); store_vertex(vertices, prev_pos + d_right, right); store_vertex(vertices, prev_pos + d_down, down); store_vertex(vertices, prev_pos + d_left, left); } else { // any other segment // ================= store_vertex(vertices, prev_pos + d_right, right); store_vertex(vertices, prev_pos + d_left, left); } // vertices 2nd endpoint store_vertex(vertices, curr_pos + d_up, up); store_vertex(vertices, curr_pos + d_right, right); store_vertex(vertices, curr_pos + d_down, down); store_vertex(vertices, curr_pos + d_left, left); last_path.sub_paths.back().last = { vbuffer_id, vertices.size(), move_id, curr.position }; }; auto add_indices_as_solid = [&](const GCodeProcessor::MoveVertex& prev, const GCodeProcessor::MoveVertex& curr, const GCodeProcessor::MoveVertex* next, TBuffer& buffer, size_t& vbuffer_size, unsigned int ibuffer_id, IndexBuffer& indices, size_t move_id) { static Vec3f prev_dir; static Vec3f prev_up; static float sq_prev_length; auto store_triangle = [](IndexBuffer& indices, IBufferType i1, IBufferType i2, IBufferType i3) { indices.push_back(i1); indices.push_back(i2); indices.push_back(i3); }; auto append_dummy_cap = [store_triangle](IndexBuffer& indices, IBufferType id) { store_triangle(indices, id, id, id); store_triangle(indices, id, id, id); }; auto convert_vertices_offset = [](size_t vbuffer_size, const std::array& v_offsets) { std::array ret = { static_cast(static_cast(vbuffer_size) + v_offsets[0]), static_cast(static_cast(vbuffer_size) + v_offsets[1]), static_cast(static_cast(vbuffer_size) + v_offsets[2]), static_cast(static_cast(vbuffer_size) + v_offsets[3]), static_cast(static_cast(vbuffer_size) + v_offsets[4]), static_cast(static_cast(vbuffer_size) + v_offsets[5]), static_cast(static_cast(vbuffer_size) + v_offsets[6]), static_cast(static_cast(vbuffer_size) + v_offsets[7]) }; return ret; }; auto append_starting_cap_triangles = [&](IndexBuffer& indices, const std::array& v_offsets) { store_triangle(indices, v_offsets[0], v_offsets[2], v_offsets[1]); store_triangle(indices, v_offsets[0], v_offsets[3], v_offsets[2]); }; auto append_stem_triangles = [&](IndexBuffer& indices, const std::array& v_offsets) { store_triangle(indices, v_offsets[0], v_offsets[1], v_offsets[4]); store_triangle(indices, v_offsets[1], v_offsets[5], v_offsets[4]); store_triangle(indices, v_offsets[1], v_offsets[2], v_offsets[5]); store_triangle(indices, v_offsets[2], v_offsets[6], v_offsets[5]); store_triangle(indices, v_offsets[2], v_offsets[3], v_offsets[6]); store_triangle(indices, v_offsets[3], v_offsets[7], v_offsets[6]); store_triangle(indices, v_offsets[3], v_offsets[0], v_offsets[7]); store_triangle(indices, v_offsets[0], v_offsets[4], v_offsets[7]); }; auto append_ending_cap_triangles = [&](IndexBuffer& indices, const std::array& v_offsets) { store_triangle(indices, v_offsets[4], v_offsets[6], v_offsets[7]); store_triangle(indices, v_offsets[4], v_offsets[5], v_offsets[6]); }; if (prev.type != curr.type || !buffer.paths.back().matches(curr)) { buffer.add_path(curr, ibuffer_id, indices.size(), move_id - 1); buffer.paths.back().sub_paths.back().first.position = prev.position; } Path& last_path = buffer.paths.back(); Vec3f dir = (curr.position - prev.position).normalized(); Vec3f right = Vec3f(dir[1], -dir[0], 0.0f).normalized(); Vec3f up = right.cross(dir); float sq_length = (curr.position - prev.position).squaredNorm(); const std::array first_seg_v_offsets = convert_vertices_offset(vbuffer_size, { 0, 1, 2, 3, 4, 5, 6, 7 }); const std::array non_first_seg_v_offsets = convert_vertices_offset(vbuffer_size, { -4, 0, -2, 1, 2, 3, 4, 5 }); bool is_first_segment = (last_path.vertices_count() == 1); if (is_first_segment || vbuffer_size == 0) { // 1st segment or restart into a new vertex buffer // =============================================== if (is_first_segment) // starting cap triangles append_starting_cap_triangles(indices, first_seg_v_offsets); // dummy triangles outer corner cap append_dummy_cap(indices, vbuffer_size); // stem triangles append_stem_triangles(indices, first_seg_v_offsets); vbuffer_size += 8; } else { // any other segment // ================= float displacement = 0.0f; float cos_dir = prev_dir.dot(dir); if (cos_dir > -0.9998477f) { // if the angle between adjacent segments is smaller than 179 degrees Vec3f med_dir = (prev_dir + dir).normalized(); float half_width = 0.5f * last_path.width; displacement = half_width * ::tan(::acos(std::clamp(dir.dot(med_dir), -1.0f, 1.0f))); } float sq_displacement = sqr(displacement); bool can_displace = displacement > 0.0f && sq_displacement < sq_prev_length && sq_displacement < sq_length; bool is_right_turn = prev_up.dot(prev_dir.cross(dir)) <= 0.0f; // whether the angle between adjacent segments is greater than 45 degrees bool is_sharp = cos_dir < 0.7071068f; bool right_displaced = false; bool left_displaced = false; if (!is_sharp && can_displace) { if (is_right_turn) left_displaced = true; else right_displaced = true; } // triangles outer corner cap if (is_right_turn) { if (left_displaced) // dummy triangles append_dummy_cap(indices, vbuffer_size); else { store_triangle(indices, vbuffer_size - 4, vbuffer_size + 1, vbuffer_size - 1); store_triangle(indices, vbuffer_size + 1, vbuffer_size - 2, vbuffer_size - 1); } } else { if (right_displaced) // dummy triangles append_dummy_cap(indices, vbuffer_size); else { store_triangle(indices, vbuffer_size - 4, vbuffer_size - 3, vbuffer_size + 0); store_triangle(indices, vbuffer_size - 3, vbuffer_size - 2, vbuffer_size + 0); } } // stem triangles append_stem_triangles(indices, non_first_seg_v_offsets); vbuffer_size += 6; } if (next != nullptr && (curr.type != next->type || !last_path.matches(*next))) // ending cap triangles append_ending_cap_triangles(indices, is_first_segment ? first_seg_v_offsets : non_first_seg_v_offsets); last_path.sub_paths.back().last = { ibuffer_id, indices.size() - 1, move_id, curr.position }; prev_dir = dir; prev_up = up; sq_prev_length = sq_length; }; #if ENABLE_GCODE_VIEWER_STATISTICS auto start_time = std::chrono::high_resolution_clock::now(); m_statistics.results_size = SLIC3R_STDVEC_MEMSIZE(gcode_result.moves, GCodeProcessor::MoveVertex); m_statistics.results_time = gcode_result.time; #endif // ENABLE_GCODE_VIEWER_STATISTICS m_moves_count = gcode_result.moves.size(); if (m_moves_count == 0) return; m_extruders_count = gcode_result.extruders_count; unsigned int progress_count = 0; static const unsigned int progress_threshold = 1000; wxProgressDialog* progress_dialog = wxGetApp().is_gcode_viewer() ? new wxProgressDialog(_L("Generating toolpaths"), "...", 100, wxGetApp().plater(), wxPD_AUTO_HIDE | wxPD_APP_MODAL) : nullptr; wxBusyCursor busy; // extract approximate paths bounding box from result for (const GCodeProcessor::MoveVertex& move : gcode_result.moves) { if (wxGetApp().is_gcode_viewer()) // for the gcode viewer we need to take in account all moves to correctly size the printbed m_paths_bounding_box.merge(move.position.cast()); else { if (move.type == EMoveType::Extrude && move.extrusion_role != erCustom && move.width != 0.0f && move.height != 0.0f) m_paths_bounding_box.merge(move.position.cast()); } } // set approximate max bounding box (take in account also the tool marker) m_max_bounding_box = m_paths_bounding_box; m_max_bounding_box.merge(m_paths_bounding_box.max + m_sequential_view.marker.get_bounding_box().size()[2] * Vec3d::UnitZ()); m_sequential_view.gcode_ids.clear(); for (const GCodeProcessor::MoveVertex& move : gcode_result.moves) { m_sequential_view.gcode_ids.push_back(move.gcode_id); } std::vector vertices(m_buffers.size()); std::vector indices(m_buffers.size()); std::vector options_zs; // toolpaths data -> extract vertices from result for (size_t i = 0; i < m_moves_count; ++i) { const GCodeProcessor::MoveVertex& curr = gcode_result.moves[i]; // skip first vertex if (i == 0) continue; const GCodeProcessor::MoveVertex& prev = gcode_result.moves[i - 1]; // update progress dialog ++progress_count; if (progress_dialog != nullptr && progress_count % progress_threshold == 0) { progress_dialog->Update(int(100.0f * float(i) / (2.0f * float(m_moves_count))), _L("Generating vertex buffer") + ": " + wxNumberFormatter::ToString(100.0 * double(i) / double(m_moves_count), 0, wxNumberFormatter::Style_None) + "%"); progress_dialog->Fit(); progress_count = 0; } unsigned char id = buffer_id(curr.type); TBuffer& t_buffer = m_buffers[id]; MultiVertexBuffer& v_multibuffer = vertices[id]; // ensure there is at least one vertex buffer if (v_multibuffer.empty()) v_multibuffer.push_back(VertexBuffer()); // if adding the vertices for the current segment exceeds the threshold size of the current vertex buffer // add another vertex buffer if (v_multibuffer.back().size() * sizeof(float) > t_buffer.vertices.max_size_bytes() - t_buffer.max_vertices_per_segment_size_bytes()) { v_multibuffer.push_back(VertexBuffer()); if (t_buffer.render_primitive_type == TBuffer::ERenderPrimitiveType::Triangle) { Path& last_path = t_buffer.paths.back(); if (prev.type == curr.type && last_path.matches(curr)) last_path.add_sub_path(prev, static_cast(v_multibuffer.size()) - 1, 0, i - 1); } } VertexBuffer& v_buffer = v_multibuffer.back(); switch (t_buffer.render_primitive_type) { case TBuffer::ERenderPrimitiveType::Point: { add_vertices_as_point(curr, v_buffer); break; } case TBuffer::ERenderPrimitiveType::Line: { add_vertices_as_line(prev, curr, v_buffer); break; } case TBuffer::ERenderPrimitiveType::Triangle: { add_vertices_as_solid(prev, curr, t_buffer, static_cast(v_multibuffer.size()) - 1, v_buffer, i); break; } } // collect options zs for later use if (curr.type == EMoveType::Pause_Print || curr.type == EMoveType::Custom_GCode) { const float* const last_z = options_zs.empty() ? nullptr : &options_zs.back(); if (last_z == nullptr || curr.position[2] < *last_z - EPSILON || *last_z + EPSILON < curr.position[2]) options_zs.emplace_back(curr.position[2]); } } // smooth toolpaths corners for the given TBuffer using triangles auto smooth_triangle_toolpaths_corners = [&gcode_result](const TBuffer& t_buffer, MultiVertexBuffer& v_multibuffer) { auto extract_position_at = [](const VertexBuffer& vertices, size_t offset) { return Vec3f(vertices[offset + 0], vertices[offset + 1], vertices[offset + 2]); }; auto update_position_at = [](VertexBuffer& vertices, size_t offset, const Vec3f& position) { vertices[offset + 0] = position[0]; vertices[offset + 1] = position[1]; vertices[offset + 2] = position[2]; }; auto match_right_vertices = [&](const Path::Sub_Path& prev_sub_path, const Path::Sub_Path& next_sub_path, size_t curr_s_id, size_t vertex_size_floats, const Vec3f& displacement_vec) { if (&prev_sub_path == &next_sub_path) { // previous and next segment are both contained into to the same vertex buffer VertexBuffer& vbuffer = v_multibuffer[prev_sub_path.first.b_id]; // offset into the vertex buffer of the next segment 1st vertex size_t next_1st_offset = (prev_sub_path.last.s_id - curr_s_id) * 6 * vertex_size_floats; // offset into the vertex buffer of the right vertex of the previous segment size_t prev_right_offset = prev_sub_path.last.i_id - next_1st_offset - 3 * vertex_size_floats; // new position of the right vertices Vec3f shared_vertex = extract_position_at(vbuffer, prev_right_offset) + displacement_vec; // update previous segment update_position_at(vbuffer, prev_right_offset, shared_vertex); // offset into the vertex buffer of the right vertex of the next segment size_t next_right_offset = next_sub_path.last.i_id - next_1st_offset; // update next segment update_position_at(vbuffer, next_right_offset, shared_vertex); } else { // previous and next segment are contained into different vertex buffers VertexBuffer& prev_vbuffer = v_multibuffer[prev_sub_path.first.b_id]; VertexBuffer& next_vbuffer = v_multibuffer[next_sub_path.first.b_id]; // offset into the previous vertex buffer of the right vertex of the previous segment size_t prev_right_offset = prev_sub_path.last.i_id - 3 * vertex_size_floats; // new position of the right vertices Vec3f shared_vertex = extract_position_at(prev_vbuffer, prev_right_offset) + displacement_vec; // update previous segment update_position_at(prev_vbuffer, prev_right_offset, shared_vertex); // offset into the next vertex buffer of the right vertex of the next segment size_t next_right_offset = next_sub_path.first.i_id + 1 * vertex_size_floats; // update next segment update_position_at(next_vbuffer, next_right_offset, shared_vertex); } }; auto match_left_vertices = [&](const Path::Sub_Path& prev_sub_path, const Path::Sub_Path& next_sub_path, size_t curr_s_id, size_t vertex_size_floats, const Vec3f& displacement_vec) { if (&prev_sub_path == &next_sub_path) { // previous and next segment are both contained into to the same vertex buffer VertexBuffer& vbuffer = v_multibuffer[prev_sub_path.first.b_id]; // offset into the vertex buffer of the next segment 1st vertex size_t next_1st_offset = (prev_sub_path.last.s_id - curr_s_id) * 6 * vertex_size_floats; // offset into the vertex buffer of the left vertex of the previous segment size_t prev_left_offset = prev_sub_path.last.i_id - next_1st_offset - 1 * vertex_size_floats; // new position of the left vertices Vec3f shared_vertex = extract_position_at(vbuffer, prev_left_offset) + displacement_vec; // update previous segment update_position_at(vbuffer, prev_left_offset, shared_vertex); // offset into the vertex buffer of the left vertex of the next segment size_t next_left_offset = next_sub_path.last.i_id - next_1st_offset + 1 * vertex_size_floats; // update next segment update_position_at(vbuffer, next_left_offset, shared_vertex); } else { // previous and next segment are contained into different vertex buffers VertexBuffer& prev_vbuffer = v_multibuffer[prev_sub_path.first.b_id]; VertexBuffer& next_vbuffer = v_multibuffer[next_sub_path.first.b_id]; // offset into the previous vertex buffer of the left vertex of the previous segment size_t prev_left_offset = prev_sub_path.last.i_id - 1 * vertex_size_floats; // new position of the left vertices Vec3f shared_vertex = extract_position_at(prev_vbuffer, prev_left_offset) + displacement_vec; // update previous segment update_position_at(prev_vbuffer, prev_left_offset, shared_vertex); // offset into the next vertex buffer of the left vertex of the next segment size_t next_left_offset = next_sub_path.first.i_id + 3 * vertex_size_floats; // update next segment update_position_at(next_vbuffer, next_left_offset, shared_vertex); } }; size_t vertex_size_floats = t_buffer.vertices.vertex_size_floats(); for (const Path& path : t_buffer.paths) { // the two segments of the path sharing the current vertex may belong // to two different vertex buffers size_t prev_sub_path_id = 0; size_t next_sub_path_id = 0; size_t path_vertices_count = path.vertices_count(); float half_width = 0.5f * path.width; for (size_t j = 1; j < path_vertices_count - 1; ++j) { size_t curr_s_id = path.sub_paths.front().first.s_id + j; const Vec3f& prev = gcode_result.moves[curr_s_id - 1].position; const Vec3f& curr = gcode_result.moves[curr_s_id].position; const Vec3f& next = gcode_result.moves[curr_s_id + 1].position; // select the subpaths which contains the previous/next segments if (!path.sub_paths[prev_sub_path_id].contains(curr_s_id)) ++prev_sub_path_id; if (!path.sub_paths[next_sub_path_id].contains(curr_s_id + 1)) ++next_sub_path_id; const Path::Sub_Path& prev_sub_path = path.sub_paths[prev_sub_path_id]; const Path::Sub_Path& next_sub_path = path.sub_paths[next_sub_path_id]; Vec3f prev_dir = (curr - prev).normalized(); Vec3f prev_right = Vec3f(prev_dir[1], -prev_dir[0], 0.0f).normalized(); Vec3f prev_up = prev_right.cross(prev_dir); Vec3f next_dir = (next - curr).normalized(); bool is_right_turn = prev_up.dot(prev_dir.cross(next_dir)) <= 0.0f; float cos_dir = prev_dir.dot(next_dir); // whether the angle between adjacent segments is greater than 45 degrees bool is_sharp = cos_dir < 0.7071068f; float displacement = 0.0f; if (cos_dir > -0.9998477f) { // if the angle between adjacent segments is smaller than 179 degrees Vec3f med_dir = (prev_dir + next_dir).normalized(); displacement = half_width * ::tan(::acos(std::clamp(next_dir.dot(med_dir), -1.0f, 1.0f))); } float sq_prev_length = (curr - prev).squaredNorm(); float sq_next_length = (next - curr).squaredNorm(); float sq_displacement = sqr(displacement); bool can_displace = displacement > 0.0f && sq_displacement < sq_prev_length && sq_displacement < sq_next_length; if (can_displace) { // displacement to apply to the vertices to match Vec3f displacement_vec = displacement * prev_dir; // matches inner corner vertices if (is_right_turn) match_right_vertices(prev_sub_path, next_sub_path, curr_s_id, vertex_size_floats, -displacement_vec); else match_left_vertices(prev_sub_path, next_sub_path, curr_s_id, vertex_size_floats, -displacement_vec); if (!is_sharp) { // matches outer corner vertices if (is_right_turn) match_left_vertices(prev_sub_path, next_sub_path, curr_s_id, vertex_size_floats, displacement_vec); else match_right_vertices(prev_sub_path, next_sub_path, curr_s_id, vertex_size_floats, displacement_vec); } } } } }; #if ENABLE_GCODE_VIEWER_STATISTICS auto load_vertices_time = std::chrono::high_resolution_clock::now(); m_statistics.load_vertices = std::chrono::duration_cast(std::chrono::high_resolution_clock::now() - start_time).count(); #endif // ENABLE_GCODE_VIEWER_STATISTICS // smooth toolpaths corners for TBuffers using triangles for (size_t i = 0; i < m_buffers.size(); ++i) { const TBuffer& t_buffer = m_buffers[i]; if (t_buffer.render_primitive_type == TBuffer::ERenderPrimitiveType::Triangle) { smooth_triangle_toolpaths_corners(t_buffer, vertices[i]); } } for (MultiVertexBuffer& v_multibuffer : vertices) { for (VertexBuffer& v_buffer : v_multibuffer) { v_buffer.shrink_to_fit(); } } // move the wipe toolpaths half height up to render them on proper position MultiVertexBuffer& wipe_vertices = vertices[buffer_id(EMoveType::Wipe)]; for (VertexBuffer& v_buffer : wipe_vertices) { for (size_t i = 2; i < v_buffer.size(); i += 3) { v_buffer[i] += 0.5f * GCodeProcessor::Wipe_Height; } } // send vertices data to gpu for (size_t i = 0; i < m_buffers.size(); ++i) { TBuffer& t_buffer = m_buffers[i]; const MultiVertexBuffer& v_multibuffer = vertices[i]; for (const VertexBuffer& v_buffer : v_multibuffer) { size_t size_elements = v_buffer.size(); size_t size_bytes = size_elements * sizeof(float); size_t vertices_count = size_elements / t_buffer.vertices.vertex_size_floats(); t_buffer.vertices.count += vertices_count; #if ENABLE_GCODE_VIEWER_STATISTICS m_statistics.total_vertices_gpu_size += static_cast(size_bytes); m_statistics.max_vbuffer_gpu_size = std::max(m_statistics.max_vbuffer_gpu_size, static_cast(size_bytes)); ++m_statistics.vbuffers_count; #endif // ENABLE_GCODE_VIEWER_STATISTICS GLuint id = 0; glsafe(::glGenBuffers(1, &id)); t_buffer.vertices.vbos.push_back(static_cast(id)); t_buffer.vertices.sizes.push_back(size_bytes); glsafe(::glBindBuffer(GL_ARRAY_BUFFER, id)); glsafe(::glBufferData(GL_ARRAY_BUFFER, size_bytes, v_buffer.data(), GL_STATIC_DRAW)); glsafe(::glBindBuffer(GL_ARRAY_BUFFER, 0)); } } #if ENABLE_GCODE_VIEWER_STATISTICS auto smooth_vertices_time = std::chrono::high_resolution_clock::now(); m_statistics.smooth_vertices = std::chrono::duration_cast(std::chrono::high_resolution_clock::now() - load_vertices_time).count(); #endif // ENABLE_GCODE_VIEWER_STATISTICS log_memory_usage("Loaded G-code generated vertex buffers ", vertices, indices); // dismiss vertices data, no more needed std::vector().swap(vertices); // toolpaths data -> extract indices from result // paths may have been filled while extracting vertices, // so reset them, they will be filled again while extracting indices for (TBuffer& buffer : m_buffers) { buffer.paths.clear(); } // variable used to keep track of the current vertex buffers index and size using CurrVertexBuffer = std::pair; std::vector curr_vertex_buffers(m_buffers.size(), { 0, 0 }); // variable used to keep track of the vertex buffers ids using VboIndexList = std::vector; std::vector vbo_indices(m_buffers.size()); for (size_t i = 0; i < m_moves_count; ++i) { const GCodeProcessor::MoveVertex& curr = gcode_result.moves[i]; // skip first vertex if (i == 0) continue; const GCodeProcessor::MoveVertex& prev = gcode_result.moves[i - 1]; const GCodeProcessor::MoveVertex* next = nullptr; if (i < m_moves_count - 1) next = &gcode_result.moves[i + 1]; ++progress_count; if (progress_dialog != nullptr && progress_count % progress_threshold == 0) { progress_dialog->Update(int(100.0f * float(m_moves_count + i) / (2.0f * float(m_moves_count))), _L("Generating index buffers") + ": " + wxNumberFormatter::ToString(100.0 * double(i) / double(m_moves_count), 0, wxNumberFormatter::Style_None) + "%"); progress_dialog->Fit(); progress_count = 0; } unsigned char id = buffer_id(curr.type); TBuffer& t_buffer = m_buffers[id]; MultiIndexBuffer& i_multibuffer = indices[id]; CurrVertexBuffer& curr_vertex_buffer = curr_vertex_buffers[id]; VboIndexList& vbo_index_list = vbo_indices[id]; // ensure there is at least one index buffer if (i_multibuffer.empty()) { i_multibuffer.push_back(IndexBuffer()); vbo_index_list.push_back(t_buffer.vertices.vbos[curr_vertex_buffer.first]); } // if adding the indices for the current segment exceeds the threshold size of the current index buffer // create another index buffer if (i_multibuffer.back().size() * sizeof(IBufferType) >= IBUFFER_THRESHOLD_BYTES - t_buffer.max_indices_per_segment_size_bytes()) { i_multibuffer.push_back(IndexBuffer()); vbo_index_list.push_back(t_buffer.vertices.vbos[curr_vertex_buffer.first]); if (t_buffer.render_primitive_type != TBuffer::ERenderPrimitiveType::Point) { Path& last_path = t_buffer.paths.back(); last_path.add_sub_path(prev, static_cast(i_multibuffer.size()) - 1, 0, i - 1); } } // if adding the vertices for the current segment exceeds the threshold size of the current vertex buffer // create another index buffer if (curr_vertex_buffer.second * t_buffer.vertices.vertex_size_bytes() > t_buffer.vertices.max_size_bytes() - t_buffer.max_vertices_per_segment_size_bytes()) { i_multibuffer.push_back(IndexBuffer()); ++curr_vertex_buffer.first; curr_vertex_buffer.second = 0; vbo_index_list.push_back(t_buffer.vertices.vbos[curr_vertex_buffer.first]); if (t_buffer.render_primitive_type != TBuffer::ERenderPrimitiveType::Point) { Path& last_path = t_buffer.paths.back(); last_path.add_sub_path(prev, static_cast(i_multibuffer.size()) - 1, 0, i - 1); } } IndexBuffer& i_buffer = i_multibuffer.back(); switch (t_buffer.render_primitive_type) { case TBuffer::ERenderPrimitiveType::Point: { add_indices_as_point(curr, t_buffer, static_cast(i_multibuffer.size()) - 1, i_buffer, i); curr_vertex_buffer.second += t_buffer.max_vertices_per_segment(); break; } case TBuffer::ERenderPrimitiveType::Line: { add_indices_as_line(prev, curr, t_buffer, static_cast(i_multibuffer.size()) - 1, i_buffer, i); curr_vertex_buffer.second += t_buffer.max_vertices_per_segment(); break; } case TBuffer::ERenderPrimitiveType::Triangle: { add_indices_as_solid(prev, curr, next, t_buffer, curr_vertex_buffer.second, static_cast(i_multibuffer.size()) - 1, i_buffer, i); break; } } } for (MultiIndexBuffer& i_multibuffer : indices) { for (IndexBuffer& i_buffer : i_multibuffer) { i_buffer.shrink_to_fit(); } } // toolpaths data -> send indices data to gpu for (size_t i = 0; i < m_buffers.size(); ++i) { TBuffer& t_buffer = m_buffers[i]; const MultiIndexBuffer& i_multibuffer = indices[i]; for (const IndexBuffer& i_buffer : i_multibuffer) { size_t size_elements = i_buffer.size(); size_t size_bytes = size_elements * sizeof(IBufferType); // stores index buffer informations into TBuffer t_buffer.indices.push_back(IBuffer()); IBuffer& ibuf = t_buffer.indices.back(); ibuf.count = size_elements; ibuf.vbo = vbo_indices[i][t_buffer.indices.size() - 1]; #if ENABLE_GCODE_VIEWER_STATISTICS m_statistics.total_indices_gpu_size += static_cast(size_bytes); m_statistics.max_ibuffer_gpu_size = std::max(m_statistics.max_ibuffer_gpu_size, static_cast(size_bytes)); ++m_statistics.ibuffers_count; #endif // ENABLE_GCODE_VIEWER_STATISTICS glsafe(::glGenBuffers(1, &ibuf.ibo)); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, ibuf.ibo)); glsafe(::glBufferData(GL_ELEMENT_ARRAY_BUFFER, size_bytes, i_buffer.data(), GL_STATIC_DRAW)); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); } } if (progress_dialog != nullptr) { progress_dialog->Update(100, ""); progress_dialog->Fit(); } #if ENABLE_GCODE_VIEWER_STATISTICS for (const TBuffer& buffer : m_buffers) { m_statistics.paths_size += SLIC3R_STDVEC_MEMSIZE(buffer.paths, Path); } auto update_segments_count = [&](EMoveType type, int64_t& count) { unsigned int id = buffer_id(type); const MultiIndexBuffer& buffers = indices[id]; int64_t indices_count = 0; for (const IndexBuffer& buffer : buffers) { indices_count += buffer.size(); } const TBuffer& t_buffer = m_buffers[id]; if (t_buffer.render_primitive_type == TBuffer::ERenderPrimitiveType::Triangle) indices_count -= static_cast(12 * t_buffer.paths.size()); // remove the starting + ending caps = 4 triangles count += indices_count / t_buffer.indices_per_segment(); }; update_segments_count(EMoveType::Travel, m_statistics.travel_segments_count); update_segments_count(EMoveType::Wipe, m_statistics.wipe_segments_count); update_segments_count(EMoveType::Extrude, m_statistics.extrude_segments_count); m_statistics.load_indices = std::chrono::duration_cast(std::chrono::high_resolution_clock::now() - smooth_vertices_time).count(); #endif // ENABLE_GCODE_VIEWER_STATISTICS log_memory_usage("Loaded G-code generated indices buffers ", vertices, indices); // dismiss indices data, no more needed std::vector().swap(indices); // layers zs / roles / extruder ids -> extract from result size_t last_travel_s_id = 0; for (size_t i = 0; i < m_moves_count; ++i) { const GCodeProcessor::MoveVertex& move = gcode_result.moves[i]; if (move.type == EMoveType::Extrude) { // layers zs const double* const last_z = m_layers.empty() ? nullptr : &m_layers.get_zs().back(); double z = static_cast(move.position[2]); if (last_z == nullptr || z < *last_z - EPSILON || *last_z + EPSILON < z) m_layers.append(z, { last_travel_s_id, i }); else m_layers.get_endpoints().back().last = i; // extruder ids m_extruder_ids.emplace_back(move.extruder_id); // roles if (i > 0) m_roles.emplace_back(move.extrusion_role); } else if (move.type == EMoveType::Travel) { if (i - last_travel_s_id > 1 && !m_layers.empty()) m_layers.get_endpoints().back().last = i; last_travel_s_id = i; } } // roles -> remove duplicates std::sort(m_roles.begin(), m_roles.end()); m_roles.erase(std::unique(m_roles.begin(), m_roles.end()), m_roles.end()); m_roles.shrink_to_fit(); // extruder ids -> remove duplicates std::sort(m_extruder_ids.begin(), m_extruder_ids.end()); m_extruder_ids.erase(std::unique(m_extruder_ids.begin(), m_extruder_ids.end()), m_extruder_ids.end()); m_extruder_ids.shrink_to_fit(); // set layers z range if (!m_layers.empty()) m_layers_z_range = { 0, static_cast(m_layers.size() - 1) }; // change color of paths whose layer contains option points if (!options_zs.empty()) { TBuffer& extrude_buffer = m_buffers[buffer_id(EMoveType::Extrude)]; for (Path& path : extrude_buffer.paths) { float z = path.sub_paths.front().first.position[2]; if (std::find_if(options_zs.begin(), options_zs.end(), [z](float f) { return f - EPSILON <= z && z <= f + EPSILON; }) != options_zs.end()) path.cp_color_id = 255 - path.cp_color_id; } } #if ENABLE_GCODE_VIEWER_STATISTICS m_statistics.load_time = std::chrono::duration_cast(std::chrono::high_resolution_clock::now() - start_time).count(); #endif // ENABLE_GCODE_VIEWER_STATISTICS if (progress_dialog != nullptr) progress_dialog->Destroy(); } void GCodeViewer::load_shells(const Print& print, bool initialized) { if (print.objects().empty()) // no shells, return return; // adds objects' volumes int object_id = 0; for (const PrintObject* obj : print.objects()) { const ModelObject* model_obj = obj->model_object(); std::vector instance_ids(model_obj->instances.size()); for (int i = 0; i < (int)model_obj->instances.size(); ++i) { instance_ids[i] = i; } m_shells.volumes.load_object(model_obj, object_id, instance_ids, "object", initialized); ++object_id; } if (wxGetApp().preset_bundle->printers.get_edited_preset().printer_technology() == ptFFF) { // adds wipe tower's volume double max_z = print.objects()[0]->model_object()->get_model()->bounding_box().max(2); const PrintConfig& config = print.config(); size_t extruders_count = config.nozzle_diameter.size(); if ((extruders_count > 1) && config.wipe_tower && !config.complete_objects) { float depth = print.wipe_tower_data(extruders_count).depth; float brim_width = print.wipe_tower_data(extruders_count).brim_width; m_shells.volumes.load_wipe_tower_preview(1000, config.wipe_tower_x, config.wipe_tower_y, config.wipe_tower_width, depth, max_z, config.wipe_tower_rotation_angle, !print.is_step_done(psWipeTower), brim_width, initialized); } } // remove modifiers while (true) { GLVolumePtrs::iterator it = std::find_if(m_shells.volumes.volumes.begin(), m_shells.volumes.volumes.end(), [](GLVolume* volume) { return volume->is_modifier; }); if (it != m_shells.volumes.volumes.end()) { delete (*it); m_shells.volumes.volumes.erase(it); } else break; } for (GLVolume* volume : m_shells.volumes.volumes) { volume->zoom_to_volumes = false; volume->color[3] = 0.25f; volume->force_native_color = true; volume->set_render_color(); } } void GCodeViewer::refresh_render_paths(bool keep_sequential_current_first, bool keep_sequential_current_last) const { #if ENABLE_GCODE_VIEWER_STATISTICS auto start_time = std::chrono::high_resolution_clock::now(); #endif // ENABLE_GCODE_VIEWER_STATISTICS auto extrusion_color = [this](const Path& path) { Color color; switch (m_view_type) { case EViewType::FeatureType: { color = Extrusion_Role_Colors[static_cast(path.role)]; break; } case EViewType::Height: { color = m_extrusions.ranges.height.get_color_at(path.height); break; } case EViewType::Width: { color = m_extrusions.ranges.width.get_color_at(path.width); break; } case EViewType::Feedrate: { color = m_extrusions.ranges.feedrate.get_color_at(path.feedrate); break; } case EViewType::FanSpeed: { color = m_extrusions.ranges.fan_speed.get_color_at(path.fan_speed); break; } case EViewType::Temperature: { color = m_extrusions.ranges.temperature.get_color_at(path.temperature); break; } case EViewType::VolumetricRate: { color = m_extrusions.ranges.volumetric_rate.get_color_at(path.volumetric_rate); break; } case EViewType::Tool: { color = m_tool_colors[path.extruder_id]; break; } case EViewType::ColorPrint: { if (path.cp_color_id >= static_cast(m_tool_colors.size())) { color = { 0.5f, 0.5f, 0.5f }; // // complementary color // color = m_tool_colors[255 - path.cp_color_id]; // color = { 1.0f - color[0], 1.0f - color[1], 1.0f - color[2] }; } else color = m_tool_colors[path.cp_color_id]; break; } default: { color = { 1.0f, 1.0f, 1.0f }; break; } } return color; }; auto travel_color = [](const Path& path) { return (path.delta_extruder < 0.0f) ? Travel_Colors[2] /* Retract */ : ((path.delta_extruder > 0.0f) ? Travel_Colors[1] /* Extrude */ : Travel_Colors[0] /* Move */); }; auto is_in_layers_range = [this](const Path& path, size_t min_id, size_t max_id) { auto in_layers_range = [this, min_id, max_id](size_t id) { return m_layers.get_endpoints_at(min_id).first <= id && id <= m_layers.get_endpoints_at(max_id).last; }; return in_layers_range(path.sub_paths.front().first.s_id) || in_layers_range(path.sub_paths.back().last.s_id); }; auto is_travel_in_layers_range = [this](size_t path_id, size_t min_id, size_t max_id) { const TBuffer& buffer = m_buffers[buffer_id(EMoveType::Travel)]; if (path_id >= buffer.paths.size()) return false; Path path = buffer.paths[path_id]; size_t first = path_id; size_t last = path_id; // check adjacent paths while (first > 0 && path.sub_paths.front().first.position.isApprox(buffer.paths[first - 1].sub_paths.back().last.position)) { --first; path.sub_paths.front().first = buffer.paths[first].sub_paths.front().first; } while (last < buffer.paths.size() - 1 && path.sub_paths.back().last.position.isApprox(buffer.paths[last + 1].sub_paths.front().first.position)) { ++last; path.sub_paths.back().last = buffer.paths[last].sub_paths.back().last; } size_t min_s_id = m_layers.get_endpoints_at(min_id).first; size_t max_s_id = m_layers.get_endpoints_at(max_id).last; return (min_s_id <= path.sub_paths.front().first.s_id && path.sub_paths.front().first.s_id <= max_s_id) || (min_s_id <= path.sub_paths.back().last.s_id && path.sub_paths.back().last.s_id <= max_s_id); }; #if ENABLE_GCODE_VIEWER_STATISTICS Statistics* statistics = const_cast(&m_statistics); statistics->render_paths_size = 0; #endif // ENABLE_GCODE_VIEWER_STATISTICS bool top_layer_only = get_app_config()->get("seq_top_layer_only") == "1"; SequentialView::Endpoints global_endpoints = { m_moves_count , 0 }; SequentialView::Endpoints top_layer_endpoints = global_endpoints; SequentialView* sequential_view = const_cast(&m_sequential_view); if (top_layer_only || !keep_sequential_current_first) sequential_view->current.first = 0; if (!keep_sequential_current_last) sequential_view->current.last = m_moves_count; // first pass: collect visible paths and update sequential view data std::vector> paths; for (size_t b = 0; b < m_buffers.size(); ++b) { TBuffer& buffer = const_cast(m_buffers[b]); // reset render paths buffer.render_paths.clear(); if (!buffer.visible) continue; for (size_t i = 0; i < buffer.paths.size(); ++i) { const Path& path = buffer.paths[i]; if (path.type == EMoveType::Travel) { if (!is_travel_in_layers_range(i, m_layers_z_range[0], m_layers_z_range[1])) continue; } else if (!is_in_layers_range(path, m_layers_z_range[0], m_layers_z_range[1])) continue; if (path.type == EMoveType::Extrude && !is_visible(path)) continue; // store valid path for (size_t j = 0; j < path.sub_paths.size(); ++j) { paths.push_back({ static_cast(b), path.sub_paths[j].first.b_id, static_cast(i), static_cast(j) }); } global_endpoints.first = std::min(global_endpoints.first, path.sub_paths.front().first.s_id); global_endpoints.last = std::max(global_endpoints.last, path.sub_paths.back().last.s_id); if (top_layer_only) { if (path.type == EMoveType::Travel) { if (is_travel_in_layers_range(i, m_layers_z_range[1], m_layers_z_range[1])) { top_layer_endpoints.first = std::min(top_layer_endpoints.first, path.sub_paths.front().first.s_id); top_layer_endpoints.last = std::max(top_layer_endpoints.last, path.sub_paths.back().last.s_id); } } else if (is_in_layers_range(path, m_layers_z_range[1], m_layers_z_range[1])) { top_layer_endpoints.first = std::min(top_layer_endpoints.first, path.sub_paths.front().first.s_id); top_layer_endpoints.last = std::max(top_layer_endpoints.last, path.sub_paths.back().last.s_id); } } } } // update current sequential position sequential_view->current.first = !top_layer_only && keep_sequential_current_first ? std::clamp(sequential_view->current.first, global_endpoints.first, global_endpoints.last) : global_endpoints.first; sequential_view->current.last = keep_sequential_current_last ? std::clamp(sequential_view->current.last, global_endpoints.first, global_endpoints.last) : global_endpoints.last; // get the world position from gpu bool found = false; for (const TBuffer& buffer : m_buffers) { // searches the path containing the current position for (const Path& path : buffer.paths) { if (path.contains(m_sequential_view.current.last)) { int sub_path_id = path.get_id_of_sub_path_containing(m_sequential_view.current.last); if (sub_path_id != -1) { const Path::Sub_Path& sub_path = path.sub_paths[sub_path_id]; unsigned int offset = static_cast(m_sequential_view.current.last - sub_path.first.s_id); if (offset > 0) { if (buffer.render_primitive_type == TBuffer::ERenderPrimitiveType::Line) offset = 2 * offset - 1; else if (buffer.render_primitive_type == TBuffer::ERenderPrimitiveType::Triangle) { unsigned int indices_count = buffer.indices_per_segment(); offset = indices_count * (offset - 1) + (indices_count - 2); if (sub_path_id == 0) offset += 6; // add 2 triangles for starting cap } } offset += static_cast(sub_path.first.i_id); // gets the vertex index from the index buffer on gpu const IBuffer& i_buffer = buffer.indices[sub_path.first.b_id]; unsigned int index = 0; glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, i_buffer.ibo)); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast(offset * sizeof(IBufferType)), static_cast(sizeof(IBufferType)), static_cast(&index))); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); // gets the position from the vertices buffer on gpu glsafe(::glBindBuffer(GL_ARRAY_BUFFER, i_buffer.vbo)); glsafe(::glGetBufferSubData(GL_ARRAY_BUFFER, static_cast(index * buffer.vertices.vertex_size_bytes()), static_cast(3 * sizeof(float)), static_cast(sequential_view->current_position.data()))); glsafe(::glBindBuffer(GL_ARRAY_BUFFER, 0)); found = true; break; } } } if (found) break; } // second pass: filter paths by sequential data and collect them by color RenderPath* render_path = nullptr; for (const auto& [tbuffer_id, ibuffer_id, path_id, sub_path_id] : paths) { TBuffer& buffer = const_cast(m_buffers[tbuffer_id]); const Path& path = buffer.paths[path_id]; const Path::Sub_Path& sub_path = path.sub_paths[sub_path_id]; if (m_sequential_view.current.last < sub_path.first.s_id || sub_path.last.s_id < m_sequential_view.current.first) continue; Color color; switch (path.type) { case EMoveType::Tool_change: { color = Options_Colors[static_cast(EOptionsColors::ToolChanges)]; break; } case EMoveType::Color_change: { color = Options_Colors[static_cast(EOptionsColors::ColorChanges)]; break; } case EMoveType::Pause_Print: { color = Options_Colors[static_cast(EOptionsColors::PausePrints)]; break; } case EMoveType::Custom_GCode: { color = Options_Colors[static_cast(EOptionsColors::CustomGCodes)]; break; } case EMoveType::Retract: { color = Options_Colors[static_cast(EOptionsColors::Retractions)]; break; } case EMoveType::Unretract: { color = Options_Colors[static_cast(EOptionsColors::Unretractions)]; break; } case EMoveType::Seam: { color = Options_Colors[static_cast(EOptionsColors::Seams)]; break; } case EMoveType::Extrude: { if (!top_layer_only || m_sequential_view.current.last == global_endpoints.last || is_in_layers_range(path, m_layers_z_range[1], m_layers_z_range[1])) color = extrusion_color(path); else color = { 0.25f, 0.25f, 0.25f }; break; } case EMoveType::Travel: { if (!top_layer_only || m_sequential_view.current.last == global_endpoints.last || is_travel_in_layers_range(path_id, m_layers_z_range[1], m_layers_z_range[1])) color = (m_view_type == EViewType::Feedrate || m_view_type == EViewType::Tool || m_view_type == EViewType::ColorPrint) ? extrusion_color(path) : travel_color(path); else color = { 0.25f, 0.25f, 0.25f }; break; } case EMoveType::Wipe: { color = Wipe_Color; break; } default: { color = { 0.0f, 0.0f, 0.0f }; break; } } RenderPath key{ tbuffer_id, color, static_cast(ibuffer_id), path_id }; if (render_path == nullptr || !RenderPathPropertyEqual()(*render_path, key)) render_path = const_cast(&(*buffer.render_paths.emplace(key).first)); unsigned int delta_1st = 0; if (sub_path.first.s_id < m_sequential_view.current.first && m_sequential_view.current.first <= sub_path.last.s_id) delta_1st = static_cast(m_sequential_view.current.first - sub_path.first.s_id); unsigned int size_in_indices = 0; switch (buffer.render_primitive_type) { case TBuffer::ERenderPrimitiveType::Point: { size_in_indices = buffer.indices_per_segment(); break; } case TBuffer::ERenderPrimitiveType::Line: case TBuffer::ERenderPrimitiveType::Triangle: { unsigned int segments_count = std::min(m_sequential_view.current.last, sub_path.last.s_id) - std::max(m_sequential_view.current.first, sub_path.first.s_id); size_in_indices = buffer.indices_per_segment() * segments_count; break; } } if (size_in_indices == 0) continue; if (buffer.render_primitive_type == TBuffer::ERenderPrimitiveType::Triangle) { if (sub_path_id == 0 && delta_1st == 0) size_in_indices += 6; // add 2 triangles for starting cap if (sub_path_id == path.sub_paths.size() - 1 && path.sub_paths.back().last.s_id <= m_sequential_view.current.last) size_in_indices += 6; // add 2 triangles for ending cap if (delta_1st > 0) size_in_indices -= 6; // remove 2 triangles for corner cap } render_path->sizes.push_back(size_in_indices); if (buffer.render_primitive_type == TBuffer::ERenderPrimitiveType::Triangle) { delta_1st *= buffer.indices_per_segment(); if (delta_1st > 0) { delta_1st += 6; // skip 2 triangles for corner cap if (sub_path_id == 0) delta_1st += 6; // skip 2 triangles for starting cap } } render_path->offsets.push_back(static_cast((sub_path.first.i_id + delta_1st) * sizeof(IBufferType))); #if 0 // check sizes and offsets against index buffer size on gpu GLint buffer_size; glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, buffer->indices[render_path->ibuffer_id].ibo)); glsafe(::glGetBufferParameteriv(GL_ELEMENT_ARRAY_BUFFER, GL_BUFFER_SIZE, &buffer_size)); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); if (render_path->offsets.back() + render_path->sizes.back() * sizeof(IBufferType) > buffer_size) BOOST_LOG_TRIVIAL(error) << "GCodeViewer::refresh_render_paths: Invalid render path data"; #endif } // set sequential data to their final value sequential_view->endpoints = top_layer_only ? top_layer_endpoints : global_endpoints; sequential_view->current.first = !top_layer_only && keep_sequential_current_first ? std::clamp(sequential_view->current.first, sequential_view->endpoints.first, sequential_view->endpoints.last) : sequential_view->endpoints.first; // updates sequential range caps std::array* sequential_range_caps = const_cast*>(&m_sequential_range_caps); (*sequential_range_caps)[0].reset(); (*sequential_range_caps)[1].reset(); if (m_sequential_view.current.first != m_sequential_view.current.last) { for (const auto& [tbuffer_id, ibuffer_id, path_id, sub_path_id] : paths) { TBuffer& buffer = const_cast(m_buffers[tbuffer_id]); if (buffer.render_primitive_type != TBuffer::ERenderPrimitiveType::Triangle) continue; const Path& path = buffer.paths[path_id]; const Path::Sub_Path& sub_path = path.sub_paths[sub_path_id]; if (m_sequential_view.current.last <= sub_path.first.s_id || sub_path.last.s_id <= m_sequential_view.current.first) continue; // update cap for first endpoint of current range if (m_sequential_view.current.first > sub_path.first.s_id) { SequentialRangeCap& cap = (*sequential_range_caps)[0]; const IBuffer& i_buffer = buffer.indices[ibuffer_id]; cap.buffer = &buffer; cap.vbo = i_buffer.vbo; // calculate offset into the index buffer unsigned int offset = sub_path.first.i_id; offset += 6; // add 2 triangles for corner cap offset += static_cast(m_sequential_view.current.first - sub_path.first.s_id) * buffer.indices_per_segment(); if (sub_path_id == 0) offset += 6; // add 2 triangles for starting cap // extract indices from index buffer std::array indices{ 0, 0, 0, 0, 0, 0 }; glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, i_buffer.ibo)); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast((offset + 0) * sizeof(IBufferType)), static_cast(sizeof(IBufferType)), static_cast(&indices[0]))); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast((offset + 7) * sizeof(IBufferType)), static_cast(sizeof(IBufferType)), static_cast(&indices[1]))); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast((offset + 1) * sizeof(IBufferType)), static_cast(sizeof(IBufferType)), static_cast(&indices[2]))); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast((offset + 13) * sizeof(IBufferType)), static_cast(sizeof(IBufferType)), static_cast(&indices[4]))); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); indices[3] = indices[0]; indices[5] = indices[1]; // send indices to gpu glsafe(::glGenBuffers(1, &cap.ibo)); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, cap.ibo)); glsafe(::glBufferData(GL_ELEMENT_ARRAY_BUFFER, indices.size() * sizeof(IBufferType), indices.data(), GL_STATIC_DRAW)); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); // extract color from render path size_t offset_bytes = offset * sizeof(IBufferType); for (const RenderPath& render_path : buffer.render_paths) { if (render_path.ibuffer_id == ibuffer_id) { for (size_t j = 0; j < render_path.offsets.size(); ++j) { if (render_path.contains(offset_bytes)) { cap.color = render_path.color; break; } } } } } // update cap for last endpoint of current range if (m_sequential_view.current.last < sub_path.last.s_id) { SequentialRangeCap& cap = (*sequential_range_caps)[1]; const IBuffer& i_buffer = buffer.indices[ibuffer_id]; cap.buffer = &buffer; cap.vbo = i_buffer.vbo; // calculate offset into the index buffer unsigned int offset = sub_path.first.i_id; offset += 6; // add 2 triangles for corner cap offset += static_cast(m_sequential_view.current.last - 1 - sub_path.first.s_id) * buffer.indices_per_segment(); if (sub_path_id == 0) offset += 6; // add 2 triangles for starting cap // extract indices from index buffer std::array indices{ 0, 0, 0, 0, 0, 0 }; glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, i_buffer.ibo)); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast((offset + 2) * sizeof(IBufferType)), static_cast(sizeof(IBufferType)), static_cast(&indices[0]))); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast((offset + 4) * sizeof(IBufferType)), static_cast(sizeof(IBufferType)), static_cast(&indices[1]))); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast((offset + 10) * sizeof(IBufferType)), static_cast(sizeof(IBufferType)), static_cast(&indices[2]))); glsafe(::glGetBufferSubData(GL_ELEMENT_ARRAY_BUFFER, static_cast((offset + 16) * sizeof(IBufferType)), static_cast(sizeof(IBufferType)), static_cast(&indices[5]))); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); indices[3] = indices[0]; indices[4] = indices[2]; // send indices to gpu glsafe(::glGenBuffers(1, &cap.ibo)); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, cap.ibo)); glsafe(::glBufferData(GL_ELEMENT_ARRAY_BUFFER, 6 * sizeof(IBufferType), indices.data(), GL_STATIC_DRAW)); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); // extract color from render path size_t offset_bytes = offset * sizeof(IBufferType); for (const RenderPath& render_path : buffer.render_paths) { if (render_path.ibuffer_id == ibuffer_id) { for (size_t j = 0; j < render_path.offsets.size(); ++j) { if (render_path.contains(offset_bytes)) { cap.color = render_path.color; break; } } } } } if ((*sequential_range_caps)[0].is_renderable() && (*sequential_range_caps)[1].is_renderable()) break; } } wxGetApp().plater()->enable_preview_moves_slider(!paths.empty()); #if ENABLE_GCODE_VIEWER_STATISTICS for (const TBuffer& buffer : m_buffers) { statistics->render_paths_size += SLIC3R_STDUNORDEREDSET_MEMSIZE(buffer.render_paths, RenderPath); for (const RenderPath& path : buffer.render_paths) { statistics->render_paths_size += SLIC3R_STDVEC_MEMSIZE(path.sizes, unsigned int); statistics->render_paths_size += SLIC3R_STDVEC_MEMSIZE(path.offsets, size_t); } } statistics->refresh_paths_time = std::chrono::duration_cast(std::chrono::high_resolution_clock::now() - start_time).count(); #endif // ENABLE_GCODE_VIEWER_STATISTICS } void GCodeViewer::render_toolpaths() const { #if ENABLE_FIXED_SCREEN_SIZE_POINT_MARKERS float point_size = 20.0f; #else float point_size = 0.8f; #endif // ENABLE_FIXED_SCREEN_SIZE_POINT_MARKERS std::array light_intensity = { 0.25f, 0.70f, 0.75f, 0.75f }; const Camera& camera = wxGetApp().plater()->get_camera(); double zoom = camera.get_zoom(); const std::array& viewport = camera.get_viewport(); float near_plane_height = camera.get_type() == Camera::EType::Perspective ? static_cast(viewport[3]) / (2.0f * static_cast(2.0 * std::tan(0.5 * Geometry::deg2rad(camera.get_fov())))) : static_cast(viewport[3]) * 0.0005; auto set_uniform_color = [](const std::array& color, GLShaderProgram& shader) { std::array color4 = { color[0], color[1], color[2], 1.0f }; shader.set_uniform("uniform_color", color4); }; #if ENABLE_GCODE_VIEWER_STATISTICS auto render_as_points = [this, zoom, point_size, near_plane_height, set_uniform_color] #else auto render_as_points = [zoom, point_size, near_plane_height, set_uniform_color] #endif // ENABLE_GCODE_VIEWER_STATISTICS (const TBuffer& buffer, unsigned int ibuffer_id, GLShaderProgram& shader) { #if ENABLE_FIXED_SCREEN_SIZE_POINT_MARKERS shader.set_uniform("use_fixed_screen_size", 1); #else shader.set_uniform("use_fixed_screen_size", 0); #endif // ENABLE_FIXED_SCREEN_SIZE_POINT_MARKERS shader.set_uniform("zoom", zoom); shader.set_uniform("percent_outline_radius", 0.0f); shader.set_uniform("percent_center_radius", 0.33f); shader.set_uniform("point_size", point_size); shader.set_uniform("near_plane_height", near_plane_height); glsafe(::glEnable(GL_VERTEX_PROGRAM_POINT_SIZE)); glsafe(::glEnable(GL_POINT_SPRITE)); for (const RenderPath& path : buffer.render_paths) { if (path.ibuffer_id == ibuffer_id) { set_uniform_color(path.color, shader); glsafe(::glMultiDrawElements(GL_POINTS, (const GLsizei*)path.sizes.data(), GL_UNSIGNED_SHORT, (const void* const*)path.offsets.data(), (GLsizei)path.sizes.size())); #if ENABLE_GCODE_VIEWER_STATISTICS ++const_cast(&m_statistics)->gl_multi_points_calls_count; #endif // ENABLE_GCODE_VIEWER_STATISTICS } } glsafe(::glDisable(GL_POINT_SPRITE)); glsafe(::glDisable(GL_VERTEX_PROGRAM_POINT_SIZE)); }; #if ENABLE_GCODE_VIEWER_STATISTICS auto render_as_lines = [this, light_intensity, set_uniform_color] #else auto render_as_lines = [light_intensity, set_uniform_color] #endif // ENABLE_GCODE_VIEWER_STATISTICS (const TBuffer& buffer, unsigned int ibuffer_id, GLShaderProgram& shader) { shader.set_uniform("light_intensity", light_intensity); for (const RenderPath& path : buffer.render_paths) { if (path.ibuffer_id == ibuffer_id) { set_uniform_color(path.color, shader); glsafe(::glMultiDrawElements(GL_LINES, (const GLsizei*)path.sizes.data(), GL_UNSIGNED_SHORT, (const void* const*)path.offsets.data(), (GLsizei)path.sizes.size())); #if ENABLE_GCODE_VIEWER_STATISTICS ++const_cast(&m_statistics)->gl_multi_lines_calls_count; #endif // ENABLE_GCODE_VIEWER_STATISTICS } } }; #if ENABLE_GCODE_VIEWER_STATISTICS auto render_as_triangles = [this, set_uniform_color] #else auto render_as_triangles = [set_uniform_color] #endif // ENABLE_GCODE_VIEWER_STATISTICS (const TBuffer& buffer, unsigned int ibuffer_id, GLShaderProgram& shader) { for (const RenderPath& path : buffer.render_paths) { if (path.ibuffer_id == ibuffer_id) { set_uniform_color(path.color, shader); glsafe(::glMultiDrawElements(GL_TRIANGLES, (const GLsizei*)path.sizes.data(), GL_UNSIGNED_SHORT, (const void* const*)path.offsets.data(), (GLsizei)path.sizes.size())); #if ENABLE_GCODE_VIEWER_STATISTICS ++const_cast(&m_statistics)->gl_multi_triangles_calls_count; #endif // ENABLE_GCODE_VIEWER_STATISTICS } } }; auto line_width = [](double zoom) { return (zoom < 5.0) ? 1.0 : (1.0 + 5.0 * (zoom - 5.0) / (100.0 - 5.0)); }; glsafe(::glLineWidth(static_cast(line_width(zoom)))); unsigned char begin_id = buffer_id(EMoveType::Retract); unsigned char end_id = buffer_id(EMoveType::Count); for (unsigned char i = begin_id; i < end_id; ++i) { const TBuffer& buffer = m_buffers[i]; if (!buffer.visible || !buffer.has_data()) continue; GLShaderProgram* shader = wxGetApp().get_shader(buffer.shader.c_str()); if (shader != nullptr) { shader->start_using(); for (size_t j = 0; j < buffer.indices.size(); ++j) { const IBuffer& i_buffer = buffer.indices[j]; glsafe(::glBindBuffer(GL_ARRAY_BUFFER, i_buffer.vbo)); glsafe(::glVertexPointer(buffer.vertices.position_size_floats(), GL_FLOAT, buffer.vertices.vertex_size_bytes(), (const void*)buffer.vertices.position_offset_bytes())); glsafe(::glEnableClientState(GL_VERTEX_ARRAY)); bool has_normals = buffer.vertices.normal_size_floats() > 0; if (has_normals) { glsafe(::glNormalPointer(GL_FLOAT, buffer.vertices.vertex_size_bytes(), (const void*)buffer.vertices.normal_offset_bytes())); glsafe(::glEnableClientState(GL_NORMAL_ARRAY)); } glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, i_buffer.ibo)); switch (buffer.render_primitive_type) { case TBuffer::ERenderPrimitiveType::Point: { render_as_points(buffer, static_cast(j), *shader); break; } case TBuffer::ERenderPrimitiveType::Line: { render_as_lines(buffer, static_cast(j), *shader); break; } case TBuffer::ERenderPrimitiveType::Triangle: { render_as_triangles(buffer, static_cast(j), *shader); break; } } glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); if (has_normals) glsafe(::glDisableClientState(GL_NORMAL_ARRAY)); glsafe(::glDisableClientState(GL_VERTEX_ARRAY)); glsafe(::glBindBuffer(GL_ARRAY_BUFFER, 0)); } shader->stop_using(); } } #if ENABLE_GCODE_VIEWER_STATISTICS auto render_sequential_range_cap = [this, set_uniform_color] #else auto render_sequential_range_cap = [set_uniform_color] #endif // ENABLE_GCODE_VIEWER_STATISTICS (const SequentialRangeCap& cap) { GLShaderProgram* shader = wxGetApp().get_shader(cap.buffer->shader.c_str()); if (shader != nullptr) { shader->start_using(); glsafe(::glBindBuffer(GL_ARRAY_BUFFER, cap.vbo)); glsafe(::glVertexPointer(cap.buffer->vertices.position_size_floats(), GL_FLOAT, cap.buffer->vertices.vertex_size_bytes(), (const void*)cap.buffer->vertices.position_offset_bytes())); glsafe(::glEnableClientState(GL_VERTEX_ARRAY)); bool has_normals = cap.buffer->vertices.normal_size_floats() > 0; if (has_normals) { glsafe(::glNormalPointer(GL_FLOAT, cap.buffer->vertices.vertex_size_bytes(), (const void*)cap.buffer->vertices.normal_offset_bytes())); glsafe(::glEnableClientState(GL_NORMAL_ARRAY)); } set_uniform_color(cap.color, *shader); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, cap.ibo)); glsafe(::glDrawElements(GL_TRIANGLES, (GLsizei)cap.indices_count(), GL_UNSIGNED_SHORT, nullptr)); glsafe(::glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0)); #if ENABLE_GCODE_VIEWER_STATISTICS ++const_cast(&m_statistics)->gl_triangles_calls_count; #endif // ENABLE_GCODE_VIEWER_STATISTICS if (has_normals) glsafe(::glDisableClientState(GL_NORMAL_ARRAY)); glsafe(::glDisableClientState(GL_VERTEX_ARRAY)); glsafe(::glBindBuffer(GL_ARRAY_BUFFER, 0)); shader->stop_using(); } }; for (unsigned int i = 0; i < 2; ++i) { if (m_sequential_range_caps[i].is_renderable()) render_sequential_range_cap(m_sequential_range_caps[i]); } } void GCodeViewer::render_shells() const { if (!m_shells.visible || m_shells.volumes.empty()) return; GLShaderProgram* shader = wxGetApp().get_shader("gouraud_light"); if (shader == nullptr) return; // glsafe(::glDepthMask(GL_FALSE)); shader->start_using(); m_shells.volumes.render(GLVolumeCollection::ERenderType::Transparent, true, wxGetApp().plater()->get_camera().get_view_matrix()); shader->stop_using(); // glsafe(::glDepthMask(GL_TRUE)); } void GCodeViewer::render_legend(float& legend_height) const { if (!m_legend_enabled) return; const Size cnv_size = wxGetApp().plater()->get_current_canvas3D()->get_canvas_size(); ImGuiWrapper& imgui = *wxGetApp().imgui(); imgui.set_next_window_pos(0.0f, 0.0f, ImGuiCond_Always); ImGui::PushStyleVar(ImGuiStyleVar_WindowRounding, 0.0f); ImGui::SetNextWindowBgAlpha(0.6f); const float max_height = 0.75f * static_cast(cnv_size.get_height()); const float child_height = 0.3333f * max_height; ImGui::SetNextWindowSizeConstraints({ 0.0f, 0.0f }, { -1.0f, max_height }); imgui.begin(std::string("Legend"), ImGuiWindowFlags_AlwaysAutoResize | ImGuiWindowFlags_NoTitleBar | ImGuiWindowFlags_NoResize | ImGuiWindowFlags_NoCollapse | ImGuiWindowFlags_NoMove); enum class EItemType : unsigned char { Rect, Circle, Hexagon, Line }; const PrintEstimatedStatistics::Mode& time_mode = m_print_statistics.modes[static_cast(m_time_estimate_mode)]; bool show_estimated_time = time_mode.time > 0.0f && (m_view_type == EViewType::FeatureType || (m_view_type == EViewType::ColorPrint && !time_mode.custom_gcode_times.empty())); const float icon_size = ImGui::GetTextLineHeight(); const float percent_bar_size = 2.0f * ImGui::GetTextLineHeight(); bool imperial_units = wxGetApp().app_config->get("use_inches") == "1"; auto append_item = [this, icon_size, percent_bar_size, &imgui, imperial_units](EItemType type, const Color& color, const std::string& label, bool visible = true, const std::string& time = "", float percent = 0.0f, float max_percent = 0.0f, const std::array& offsets = { 0.0f, 0.0f, 0.0f, 0.0f }, double used_filament_m = 0.0, double used_filament_g = 0.0, std::function callback = nullptr) { if (!visible) ImGui::PushStyleVar(ImGuiStyleVar_Alpha, 0.3333f); ImDrawList* draw_list = ImGui::GetWindowDrawList(); ImVec2 pos = ImGui::GetCursorScreenPos(); switch (type) { default: case EItemType::Rect: { draw_list->AddRectFilled({ pos.x + 1.0f, pos.y + 1.0f }, { pos.x + icon_size - 1.0f, pos.y + icon_size - 1.0f }, ImGui::GetColorU32({ color[0], color[1], color[2], 1.0f })); break; } case EItemType::Circle: { ImVec2 center(0.5f * (pos.x + pos.x + icon_size), 0.5f * (pos.y + pos.y + icon_size)); if (m_buffers[buffer_id(EMoveType::Retract)].shader == "options_120") { draw_list->AddCircleFilled(center, 0.5f * icon_size, ImGui::GetColorU32({ 0.5f * color[0], 0.5f * color[1], 0.5f * color[2], 1.0f }), 16); float radius = 0.5f * icon_size; draw_list->AddCircleFilled(center, radius, ImGui::GetColorU32({ color[0], color[1], color[2], 1.0f }), 16); radius = 0.5f * icon_size * 0.01f * 33.0f; draw_list->AddCircleFilled(center, radius, ImGui::GetColorU32({ 0.5f * color[0], 0.5f * color[1], 0.5f * color[2], 1.0f }), 16); } else draw_list->AddCircleFilled(center, 0.5f * icon_size, ImGui::GetColorU32({ color[0], color[1], color[2], 1.0f }), 16); break; } case EItemType::Hexagon: { ImVec2 center(0.5f * (pos.x + pos.x + icon_size), 0.5f * (pos.y + pos.y + icon_size)); draw_list->AddNgonFilled(center, 0.5f * icon_size, ImGui::GetColorU32({ color[0], color[1], color[2], 1.0f }), 6); break; } case EItemType::Line: { draw_list->AddLine({ pos.x + 1, pos.y + icon_size - 1 }, { pos.x + icon_size - 1, pos.y + 1 }, ImGui::GetColorU32({ color[0], color[1], color[2], 1.0f }), 3.0f); break; } } // draw text ImGui::Dummy({ icon_size, icon_size }); ImGui::SameLine(); if (callback != nullptr) { if (ImGui::MenuItem(label.c_str())) callback(); else { // show tooltip if (ImGui::IsItemHovered()) { if (!visible) ImGui::PopStyleVar(); ImGui::PushStyleColor(ImGuiCol_PopupBg, ImGuiWrapper::COL_WINDOW_BACKGROUND); ImGui::BeginTooltip(); imgui.text(visible ? _u8L("Click to hide") : _u8L("Click to show")); ImGui::EndTooltip(); ImGui::PopStyleColor(); if (!visible) ImGui::PushStyleVar(ImGuiStyleVar_Alpha, 0.3333f); // to avoid the tooltip to change size when moving the mouse wxGetApp().plater()->get_current_canvas3D()->set_as_dirty(); wxGetApp().plater()->get_current_canvas3D()->request_extra_frame(); } } if (!time.empty()) { ImGui::SameLine(offsets[0]); imgui.text(time); ImGui::SameLine(offsets[1]); pos = ImGui::GetCursorScreenPos(); const float width = std::max(1.0f, percent_bar_size * percent / max_percent); draw_list->AddRectFilled({ pos.x, pos.y + 2.0f }, { pos.x + width, pos.y + icon_size - 2.0f }, ImGui::GetColorU32(ImGuiWrapper::COL_ORANGE_LIGHT)); ImGui::Dummy({ percent_bar_size, icon_size }); ImGui::SameLine(); char buf[64]; ::sprintf(buf, "%.1f%%", 100.0f * percent); ImGui::TextUnformatted((percent > 0.0f) ? buf : ""); ImGui::SameLine(offsets[2]); ::sprintf(buf, imperial_units ? "%.2f in" : "%.2f m", used_filament_m); imgui.text(buf); ImGui::SameLine(offsets[3]); ::sprintf(buf, "%.2f g", used_filament_g); imgui.text(buf); } } else { imgui.text(label); if (used_filament_m > 0.0) { char buf[64]; ImGui::SameLine(offsets[0]); ::sprintf(buf, imperial_units ? "%.2f in" : "%.2f m", used_filament_m); imgui.text(buf); ImGui::SameLine(offsets[1]); ::sprintf(buf, "%.2f g", used_filament_g); imgui.text(buf); } } if (!visible) ImGui::PopStyleVar(); }; auto append_range = [append_item](const Extrusions::Range& range, unsigned int decimals) { auto append_range_item = [append_item](int i, float value, unsigned int decimals) { char buf[1024]; ::sprintf(buf, "%.*f", decimals, value); append_item(EItemType::Rect, Range_Colors[i], buf); }; if (range.count == 1) // single item use case append_range_item(0, range.min, decimals); else if (range.count == 2) { append_range_item(static_cast(Range_Colors.size()) - 1, range.max, decimals); append_range_item(0, range.min, decimals); } else { const float step_size = range.step_size(); for (int i = static_cast(Range_Colors.size()) - 1; i >= 0; --i) { append_range_item(i, range.min + static_cast(i) * step_size, decimals); } } }; auto append_headers = [&imgui](const std::array& texts, const std::array& offsets) { size_t i = 0; for (; i < offsets.size(); i++) { imgui.text(texts[i]); ImGui::SameLine(offsets[i]); } imgui.text(texts[i]); ImGui::Separator(); }; auto max_width = [](const std::vector& items, const std::string& title, float extra_size = 0.0f) { float ret = ImGui::CalcTextSize(title.c_str()).x; for (const std::string& item : items) { ret = std::max(ret, extra_size + ImGui::CalcTextSize(item.c_str()).x); } return ret; }; auto calculate_offsets = [max_width](const std::vector& labels, const std::vector& times, const std::array& titles, float extra_size = 0.0f) { const ImGuiStyle& style = ImGui::GetStyle(); std::array ret = { 0.0f, 0.0f, 0.0f, 0.0f }; ret[0] = max_width(labels, titles[0], extra_size) + 3.0f * style.ItemSpacing.x; for (size_t i = 1; i < titles.size(); i++) ret[i] = ret[i-1] + max_width(times, titles[i]) + style.ItemSpacing.x; return ret; }; auto color_print_ranges = [this](unsigned char extruder_id, const std::vector& custom_gcode_per_print_z) { std::vector>> ret; ret.reserve(custom_gcode_per_print_z.size()); for (const auto& item : custom_gcode_per_print_z) { if (extruder_id + 1 != static_cast(item.extruder)) continue; if (item.type != ColorChange) continue; const std::vector zs = m_layers.get_zs(); auto lower_b = std::lower_bound(zs.begin(), zs.end(), item.print_z - Slic3r::DoubleSlider::epsilon()); if (lower_b == zs.end()) continue; const double current_z = *lower_b; const double previous_z = (lower_b == zs.begin()) ? 0.0 : *(--lower_b); // to avoid duplicate values, check adding values if (ret.empty() || !(ret.back().second.first == previous_z && ret.back().second.second == current_z)) ret.push_back({ decode_color(item.color), { previous_z, current_z } }); } return ret; }; auto upto_label = [](double z) { char buf[64]; ::sprintf(buf, "%.2f", z); return _u8L("up to") + " " + std::string(buf) + " " + _u8L("mm"); }; auto above_label = [](double z) { char buf[64]; ::sprintf(buf, "%.2f", z); return _u8L("above") + " " + std::string(buf) + " " + _u8L("mm"); }; auto fromto_label = [](double z1, double z2) { char buf1[64]; ::sprintf(buf1, "%.2f", z1); char buf2[64]; ::sprintf(buf2, "%.2f", z2); return _u8L("from") + " " + std::string(buf1) + " " + _u8L("to") + " " + std::string(buf2) + " " + _u8L("mm"); }; auto role_time_and_percent = [time_mode](ExtrusionRole role) { auto it = std::find_if(time_mode.roles_times.begin(), time_mode.roles_times.end(), [role](const std::pair& item) { return role == item.first; }); return (it != time_mode.roles_times.end()) ? std::make_pair(it->second, it->second / time_mode.time) : std::make_pair(0.0f, 0.0f); }; auto used_filament_per_role = [this, imperial_units](ExtrusionRole role) { auto it = m_print_statistics.used_filaments_per_role.find(role); if (it == m_print_statistics.used_filaments_per_role.end()) return std::make_pair(0.0, 0.0); double koef = imperial_units ? 1000.0 / ObjectManipulation::in_to_mm : 1.0; return std::make_pair(it->second.first * koef, it->second.second); }; // data used to properly align items in columns when showing time std::array offsets = { 0.0f, 0.0f, 0.0f, 0.0f }; std::vector labels; std::vector times; std::vector percents; std::vector used_filaments_m; std::vector used_filaments_g; float max_percent = 0.0f; if (m_view_type == EViewType::FeatureType) { // calculate offsets to align time/percentage data for (size_t i = 0; i < m_roles.size(); ++i) { ExtrusionRole role = m_roles[i]; if (role < erCount) { labels.push_back(_u8L(ExtrusionEntity::role_to_string(role))); auto [time, percent] = role_time_and_percent(role); times.push_back((time > 0.0f) ? short_time(get_time_dhms(time)) : ""); percents.push_back(percent); max_percent = std::max(max_percent, percent); auto [used_filament_m, used_filament_g] = used_filament_per_role(role); used_filaments_m.push_back(used_filament_m); used_filaments_g.push_back(used_filament_g); } } std::string longest_percentage_string; for (double item : percents) { char buffer[64]; ::sprintf(buffer, "%.2f %%", item); if (::strlen(buffer) > longest_percentage_string.length()) longest_percentage_string = buffer; } longest_percentage_string += " "; if (_u8L("Percentage").length() > longest_percentage_string.length()) longest_percentage_string = _u8L("Percentage"); std::string longest_used_filament_string; for (double item : used_filaments_m) { char buffer[64]; ::sprintf(buffer, imperial_units ? "%.2f in" : "%.2f m", item); if (::strlen(buffer) > longest_used_filament_string.length()) longest_used_filament_string = buffer; } offsets = calculate_offsets(labels, times, { _u8L("Feature type"), _u8L("Time"), longest_percentage_string, longest_used_filament_string }, icon_size); } // get used filament (meters and grams) from used volume in respect to the active extruder auto get_used_filament_from_volume = [this, imperial_units](double volume, int extruder_id) { double koef = imperial_units ? 1.0 / ObjectManipulation::in_to_mm : 0.001; std::pair ret = { koef * volume / (PI * sqr(0.5 * m_filament_diameters[extruder_id])), volume * m_filament_densities[extruder_id] * 0.001 }; return ret; }; if (m_view_type == EViewType::Tool) { // calculate used filaments data for (size_t extruder_id : m_extruder_ids) { if (m_print_statistics.volumes_per_extruder.find(extruder_id) == m_print_statistics.volumes_per_extruder.end()) continue; double volume = m_print_statistics.volumes_per_extruder.at(extruder_id); auto [used_filament_m, used_filament_g] = get_used_filament_from_volume(volume, extruder_id); used_filaments_m.push_back(used_filament_m); used_filaments_g.push_back(used_filament_g); } std::string longest_used_filament_string; for (double item : used_filaments_m) { char buffer[64]; ::sprintf(buffer, imperial_units ? "%.2f in" : "%.2f m", item); if (::strlen(buffer) > longest_used_filament_string.length()) longest_used_filament_string = buffer; } offsets = calculate_offsets(labels, times, { "Extruder NNN", longest_used_filament_string }, icon_size); } // extrusion paths section -> title switch (m_view_type) { case EViewType::FeatureType: { append_headers({ _u8L("Feature type"), _u8L("Time"), _u8L("Percentage"), _u8L("Used filament") }, offsets); break; } case EViewType::Height: { imgui.title(_u8L("Height (mm)")); break; } case EViewType::Width: { imgui.title(_u8L("Width (mm)")); break; } case EViewType::Feedrate: { imgui.title(_u8L("Speed (mm/s)")); break; } case EViewType::FanSpeed: { imgui.title(_u8L("Fan Speed (%)")); break; } case EViewType::Temperature: { imgui.title(_u8L("Temperature (°C)")); break; } case EViewType::VolumetricRate: { imgui.title(_u8L("Volumetric flow rate (mm³/s)")); break; } case EViewType::Tool: { append_headers({ _u8L("Tool"), _u8L("Used filament") }, offsets); break; } case EViewType::ColorPrint: { imgui.title(_u8L("Color Print")); break; } default: { break; } } // extrusion paths section -> items switch (m_view_type) { case EViewType::FeatureType: { for (size_t i = 0; i < m_roles.size(); ++i) { ExtrusionRole role = m_roles[i]; if (role >= erCount) continue; const bool visible = is_visible(role); append_item(EItemType::Rect, Extrusion_Role_Colors[static_cast(role)], labels[i], visible, times[i], percents[i], max_percent, offsets, used_filaments_m[i], used_filaments_g[i], [this, role, visible]() { Extrusions* extrusions = const_cast(&m_extrusions); extrusions->role_visibility_flags = visible ? extrusions->role_visibility_flags & ~(1 << role) : extrusions->role_visibility_flags | (1 << role); // update buffers' render paths refresh_render_paths(false, false); wxGetApp().plater()->update_preview_moves_slider(); wxGetApp().plater()->get_current_canvas3D()->set_as_dirty(); wxGetApp().plater()->update_preview_bottom_toolbar(); } ); } break; } case EViewType::Height: { append_range(m_extrusions.ranges.height, 3); break; } case EViewType::Width: { append_range(m_extrusions.ranges.width, 3); break; } case EViewType::Feedrate: { append_range(m_extrusions.ranges.feedrate, 1); break; } case EViewType::FanSpeed: { append_range(m_extrusions.ranges.fan_speed, 0); break; } case EViewType::Temperature: { append_range(m_extrusions.ranges.temperature, 0); break; } case EViewType::VolumetricRate: { append_range(m_extrusions.ranges.volumetric_rate, 3); break; } case EViewType::Tool: { // shows only extruders actually used size_t i = 0; for (unsigned char extruder_id : m_extruder_ids) { append_item(EItemType::Rect, m_tool_colors[extruder_id], _u8L("Extruder") + " " + std::to_string(extruder_id + 1), true, "", 0.0f, 0.0f, offsets, used_filaments_m[i], used_filaments_g[i]); i++; } break; } case EViewType::ColorPrint: { #if ENABLE_FIX_IMPORTING_COLOR_PRINT_VIEW_INTO_GCODEVIEWER const std::vector& custom_gcode_per_print_z = wxGetApp().is_editor() ? wxGetApp().plater()->model().custom_gcode_per_print_z.gcodes : m_custom_gcode_per_print_z; #else const std::vector& custom_gcode_per_print_z = wxGetApp().plater()->model().custom_gcode_per_print_z.gcodes; #endif // ENABLE_FIX_IMPORTING_COLOR_PRINT_VIEW_INTO_GCODEVIEWER size_t total_items = 1; for (unsigned char i : m_extruder_ids) { total_items += color_print_ranges(i, custom_gcode_per_print_z).size(); } const bool need_scrollable = static_cast(total_items) * (icon_size + ImGui::GetStyle().ItemSpacing.y) > child_height; // add scrollable region, if needed if (need_scrollable) ImGui::BeginChild("color_prints", { -1.0f, child_height }, false); if (m_extruders_count == 1) { // single extruder use case const std::vector>> cp_values = color_print_ranges(0, custom_gcode_per_print_z); const int items_cnt = static_cast(cp_values.size()); if (items_cnt == 0) { // There are no color changes, but there are some pause print or custom Gcode append_item(EItemType::Rect, m_tool_colors.front(), _u8L("Default color")); } else { for (int i = items_cnt; i >= 0; --i) { // create label for color change item if (i == 0) { append_item(EItemType::Rect, m_tool_colors[0], upto_label(cp_values.front().second.first)); break; } else if (i == items_cnt) { append_item(EItemType::Rect, cp_values[i - 1].first, above_label(cp_values[i - 1].second.second)); continue; } append_item(EItemType::Rect, cp_values[i - 1].first, fromto_label(cp_values[i - 1].second.second, cp_values[i].second.first)); } } } else { // multi extruder use case // shows only extruders actually used for (unsigned char i : m_extruder_ids) { const std::vector>> cp_values = color_print_ranges(i, custom_gcode_per_print_z); const int items_cnt = static_cast(cp_values.size()); if (items_cnt == 0) { // There are no color changes, but there are some pause print or custom Gcode append_item(EItemType::Rect, m_tool_colors[i], _u8L("Extruder") + " " + std::to_string(i + 1) + " " + _u8L("default color")); } else { for (int j = items_cnt; j >= 0; --j) { // create label for color change item std::string label = _u8L("Extruder") + " " + std::to_string(i + 1); if (j == 0) { label += " " + upto_label(cp_values.front().second.first); append_item(EItemType::Rect, m_tool_colors[i], label); break; } else if (j == items_cnt) { label += " " + above_label(cp_values[j - 1].second.second); append_item(EItemType::Rect, cp_values[j - 1].first, label); continue; } label += " " + fromto_label(cp_values[j - 1].second.second, cp_values[j].second.first); append_item(EItemType::Rect, cp_values[j - 1].first, label); } } } } if (need_scrollable) ImGui::EndChild(); break; } default: { break; } } // partial estimated printing time section if (m_view_type == EViewType::ColorPrint) { using Times = std::pair; using TimesList = std::vector>; // helper structure containig the data needed to render the time items struct PartialTime { enum class EType : unsigned char { Print, ColorChange, Pause }; EType type; int extruder_id; Color color1; Color color2; Times times; std::pair used_filament {0.0f, 0.0f}; }; using PartialTimes = std::vector; auto generate_partial_times = [this, get_used_filament_from_volume](const TimesList& times, const std::vector& used_filaments) { PartialTimes items; #if ENABLE_FIX_IMPORTING_COLOR_PRINT_VIEW_INTO_GCODEVIEWER std::vector custom_gcode_per_print_z = wxGetApp().is_editor() ? wxGetApp().plater()->model().custom_gcode_per_print_z.gcodes : m_custom_gcode_per_print_z; #else std::vector custom_gcode_per_print_z = wxGetApp().plater()->model().custom_gcode_per_print_z.gcodes; #endif // ENABLE_FIX_IMPORTING_COLOR_PRINT_VIEW_INTO_GCODEVIEWER int extruders_count = wxGetApp().extruders_edited_cnt(); std::vector last_color(extruders_count); for (int i = 0; i < extruders_count; ++i) { last_color[i] = m_tool_colors[i]; } int last_extruder_id = 1; int color_change_idx = 0; for (const auto& time_rec : times) { switch (time_rec.first) { case CustomGCode::PausePrint: { auto it = std::find_if(custom_gcode_per_print_z.begin(), custom_gcode_per_print_z.end(), [time_rec](const CustomGCode::Item& item) { return item.type == time_rec.first; }); if (it != custom_gcode_per_print_z.end()) { items.push_back({ PartialTime::EType::Print, it->extruder, last_color[it->extruder - 1], Color(), time_rec.second }); items.push_back({ PartialTime::EType::Pause, it->extruder, Color(), Color(), time_rec.second }); custom_gcode_per_print_z.erase(it); } break; } case CustomGCode::ColorChange: { auto it = std::find_if(custom_gcode_per_print_z.begin(), custom_gcode_per_print_z.end(), [time_rec](const CustomGCode::Item& item) { return item.type == time_rec.first; }); if (it != custom_gcode_per_print_z.end()) { items.push_back({ PartialTime::EType::Print, it->extruder, last_color[it->extruder - 1], Color(), time_rec.second, get_used_filament_from_volume(used_filaments[color_change_idx++], it->extruder-1) }); items.push_back({ PartialTime::EType::ColorChange, it->extruder, last_color[it->extruder - 1], decode_color(it->color), time_rec.second }); last_color[it->extruder - 1] = decode_color(it->color); last_extruder_id = it->extruder; custom_gcode_per_print_z.erase(it); } else items.push_back({ PartialTime::EType::Print, last_extruder_id, last_color[last_extruder_id - 1], Color(), time_rec.second, get_used_filament_from_volume(used_filaments[color_change_idx++], last_extruder_id -1) }); break; } default: { break; } } } return items; }; auto append_color_change = [&imgui](const Color& color1, const Color& color2, const std::array& offsets, const Times& times) { imgui.text(_u8L("Color change")); ImGui::SameLine(); float icon_size = ImGui::GetTextLineHeight(); ImDrawList* draw_list = ImGui::GetWindowDrawList(); ImVec2 pos = ImGui::GetCursorScreenPos(); pos.x -= 0.5f * ImGui::GetStyle().ItemSpacing.x; draw_list->AddRectFilled({ pos.x + 1.0f, pos.y + 1.0f }, { pos.x + icon_size - 1.0f, pos.y + icon_size - 1.0f }, ImGui::GetColorU32({ color1[0], color1[1], color1[2], 1.0f })); pos.x += icon_size; draw_list->AddRectFilled({ pos.x + 1.0f, pos.y + 1.0f }, { pos.x + icon_size - 1.0f, pos.y + icon_size - 1.0f }, ImGui::GetColorU32({ color2[0], color2[1], color2[2], 1.0f })); ImGui::SameLine(offsets[0]); imgui.text(short_time(get_time_dhms(times.second - times.first))); }; auto append_print = [&imgui, imperial_units](const Color& color, const std::array& offsets, const Times& times, std::pair used_filament) { imgui.text(_u8L("Print")); ImGui::SameLine(); float icon_size = ImGui::GetTextLineHeight(); ImDrawList* draw_list = ImGui::GetWindowDrawList(); ImVec2 pos = ImGui::GetCursorScreenPos(); pos.x -= 0.5f * ImGui::GetStyle().ItemSpacing.x; draw_list->AddRectFilled({ pos.x + 1.0f, pos.y + 1.0f }, { pos.x + icon_size - 1.0f, pos.y + icon_size - 1.0f }, ImGui::GetColorU32({ color[0], color[1], color[2], 1.0f })); ImGui::SameLine(offsets[0]); imgui.text(short_time(get_time_dhms(times.second))); ImGui::SameLine(offsets[1]); imgui.text(short_time(get_time_dhms(times.first))); if (used_filament.first > 0.0f) { char buffer[64]; ImGui::SameLine(offsets[2]); ::sprintf(buffer, imperial_units ? "%.2f in" : "%.2f m", used_filament.first); imgui.text(buffer); ImGui::SameLine(offsets[3]); ::sprintf(buffer, "%.2f g", used_filament.second); imgui.text(buffer); } }; PartialTimes partial_times = generate_partial_times(time_mode.custom_gcode_times, m_print_statistics.volumes_per_color_change); if (!partial_times.empty()) { labels.clear(); times.clear(); for (const PartialTime& item : partial_times) { switch (item.type) { case PartialTime::EType::Print: { labels.push_back(_u8L("Print")); break; } case PartialTime::EType::Pause: { labels.push_back(_u8L("Pause")); break; } case PartialTime::EType::ColorChange: { labels.push_back(_u8L("Color change")); break; } } times.push_back(short_time(get_time_dhms(item.times.second))); } std::string longest_used_filament_string; for (const PartialTime& item : partial_times) { if (item.used_filament.first > 0.0f) { char buffer[64]; ::sprintf(buffer, imperial_units ? "%.2f in" : "%.2f m", item.used_filament.first); if (::strlen(buffer) > longest_used_filament_string.length()) longest_used_filament_string = buffer; } } offsets = calculate_offsets(labels, times, { _u8L("Event"), _u8L("Remaining time"), _u8L("Duration"), longest_used_filament_string }, 2.0f * icon_size); ImGui::Spacing(); append_headers({ _u8L("Event"), _u8L("Remaining time"), _u8L("Duration"), _u8L("Used filament") }, offsets); const bool need_scrollable = static_cast(partial_times.size()) * (icon_size + ImGui::GetStyle().ItemSpacing.y) > child_height; if (need_scrollable) // add scrollable region ImGui::BeginChild("events", { -1.0f, child_height }, false); for (const PartialTime& item : partial_times) { switch (item.type) { case PartialTime::EType::Print: { append_print(item.color1, offsets, item.times, item.used_filament); break; } case PartialTime::EType::Pause: { imgui.text(_u8L("Pause")); ImGui::SameLine(offsets[0]); imgui.text(short_time(get_time_dhms(item.times.second - item.times.first))); break; } case PartialTime::EType::ColorChange: { append_color_change(item.color1, item.color2, offsets, item.times); break; } } } if (need_scrollable) ImGui::EndChild(); } } // travel paths section if (m_buffers[buffer_id(EMoveType::Travel)].visible) { switch (m_view_type) { case EViewType::Feedrate: case EViewType::Tool: case EViewType::ColorPrint: { break; } default: { // title ImGui::Spacing(); imgui.title(_u8L("Travel")); // items append_item(EItemType::Line, Travel_Colors[0], _u8L("Movement")); append_item(EItemType::Line, Travel_Colors[1], _u8L("Extrusion")); append_item(EItemType::Line, Travel_Colors[2], _u8L("Retraction")); break; } } } // wipe paths section if (m_buffers[buffer_id(EMoveType::Wipe)].visible) { switch (m_view_type) { case EViewType::Feedrate: case EViewType::Tool: case EViewType::ColorPrint: { break; } default: { // title ImGui::Spacing(); imgui.title(_u8L("Wipe")); // items append_item(EItemType::Line, Wipe_Color, _u8L("Wipe")); break; } } } auto any_option_available = [this]() { auto available = [this](EMoveType type) { const TBuffer& buffer = m_buffers[buffer_id(type)]; return buffer.visible && buffer.has_data(); }; return available(EMoveType::Color_change) || available(EMoveType::Custom_GCode) || available(EMoveType::Pause_Print) || available(EMoveType::Retract) || available(EMoveType::Tool_change) || available(EMoveType::Unretract) || available(EMoveType::Seam); }; auto add_option = [this, append_item](EMoveType move_type, EOptionsColors color, const std::string& text) { const TBuffer& buffer = m_buffers[buffer_id(move_type)]; if (buffer.visible && buffer.has_data()) append_item((buffer.shader == "options_110") ? EItemType::Rect : EItemType::Circle, Options_Colors[static_cast(color)], text); }; // options section if (any_option_available()) { // title ImGui::Spacing(); imgui.title(_u8L("Options")); // items add_option(EMoveType::Retract, EOptionsColors::Retractions, _u8L("Retractions")); add_option(EMoveType::Unretract, EOptionsColors::Unretractions, _u8L("Deretractions")); add_option(EMoveType::Seam, EOptionsColors::Seams, _u8L("Seams")); add_option(EMoveType::Tool_change, EOptionsColors::ToolChanges, _u8L("Tool changes")); add_option(EMoveType::Color_change, EOptionsColors::ColorChanges, _u8L("Color changes")); add_option(EMoveType::Pause_Print, EOptionsColors::PausePrints, _u8L("Print pauses")); add_option(EMoveType::Custom_GCode, EOptionsColors::CustomGCodes, _u8L("Custom G-codes")); } // settings section bool has_settings = false; has_settings |= !m_settings_ids.print.empty(); has_settings |= !m_settings_ids.printer.empty(); bool has_filament_settings = true; has_filament_settings &= !m_settings_ids.filament.empty(); for (const std::string& fs : m_settings_ids.filament) { has_filament_settings &= !fs.empty(); } has_settings |= has_filament_settings; bool show_settings = wxGetApp().is_gcode_viewer(); show_settings &= (m_view_type == EViewType::FeatureType || m_view_type == EViewType::Tool); show_settings &= has_settings; if (show_settings) { auto calc_offset = [this]() { float ret = 0.0f; if (!m_settings_ids.printer.empty()) ret = std::max(ret, ImGui::CalcTextSize((_u8L("Printer") + std::string(":")).c_str()).x); if (!m_settings_ids.print.empty()) ret = std::max(ret, ImGui::CalcTextSize((_u8L("Print settings") + std::string(":")).c_str()).x); if (!m_settings_ids.filament.empty()) { for (unsigned char i : m_extruder_ids) { ret = std::max(ret, ImGui::CalcTextSize((_u8L("Filament") + " " + std::to_string(i + 1) + ":").c_str()).x); } } if (ret > 0.0f) ret += 2.0f * ImGui::GetStyle().ItemSpacing.x; return ret; }; ImGui::Spacing(); imgui.title(_u8L("Settings")); float offset = calc_offset(); if (!m_settings_ids.printer.empty()) { imgui.text(_u8L("Printer") + ":"); ImGui::SameLine(offset); imgui.text(m_settings_ids.printer); } if (!m_settings_ids.print.empty()) { imgui.text(_u8L("Print settings") + ":"); ImGui::SameLine(offset); imgui.text(m_settings_ids.print); } if (!m_settings_ids.filament.empty()) { for (unsigned char i : m_extruder_ids) { if (i < static_cast(m_settings_ids.filament.size()) && !m_settings_ids.filament[i].empty()) { std::string txt = _u8L("Filament"); txt += (m_extruder_ids.size() == 1) ? ":" : " " + std::to_string(i + 1); imgui.text(txt); ImGui::SameLine(offset); imgui.text(m_settings_ids.filament[i]); } } } } // total estimated printing time section if (show_estimated_time) { ImGui::Spacing(); std::string time_title = _u8L("Estimated printing times"); auto can_show_mode_button = [this](PrintEstimatedStatistics::ETimeMode mode) { bool show = false; if (m_print_statistics.modes.size() > 1 && m_print_statistics.modes[static_cast(mode)].roles_times.size() > 0) { for (size_t i = 0; i < m_print_statistics.modes.size(); ++i) { if (i != static_cast(mode) && m_print_statistics.modes[i].time > 0.0f && short_time(get_time_dhms(m_print_statistics.modes[static_cast(mode)].time)) != short_time(get_time_dhms(m_print_statistics.modes[i].time))) { show = true; break; } } } return show; }; if (can_show_mode_button(m_time_estimate_mode)) { switch (m_time_estimate_mode) { case PrintEstimatedStatistics::ETimeMode::Normal: { time_title += " [" + _u8L("Normal mode") + "]"; break; } case PrintEstimatedStatistics::ETimeMode::Stealth: { time_title += " [" + _u8L("Stealth mode") + "]"; break; } default: { assert(false); break; } } } imgui.title(time_title + ":"); std::string first_str = _u8L("First layer"); std::string total_str = _u8L("Total"); float max_len = 10.0f + ImGui::GetStyle().ItemSpacing.x; if (time_mode.layers_times.empty()) max_len += ImGui::CalcTextSize(total_str.c_str()).x; else max_len += std::max(ImGui::CalcTextSize(first_str.c_str()).x, ImGui::CalcTextSize(total_str.c_str()).x); if (!time_mode.layers_times.empty()) { imgui.text(first_str + ":"); ImGui::SameLine(max_len); imgui.text(short_time(get_time_dhms(time_mode.layers_times.front()))); } imgui.text(total_str + ":"); ImGui::SameLine(max_len); imgui.text(short_time(get_time_dhms(time_mode.time))); auto show_mode_button = [this, &imgui, can_show_mode_button](const wxString& label, PrintEstimatedStatistics::ETimeMode mode) { if (can_show_mode_button(mode)) { if (imgui.button(label)) { *const_cast(&m_time_estimate_mode) = mode; wxGetApp().plater()->get_current_canvas3D()->set_as_dirty(); wxGetApp().plater()->get_current_canvas3D()->request_extra_frame(); } } }; switch (m_time_estimate_mode) { case PrintEstimatedStatistics::ETimeMode::Normal: { show_mode_button(_L("Show stealth mode"), PrintEstimatedStatistics::ETimeMode::Stealth); break; } case PrintEstimatedStatistics::ETimeMode::Stealth: { show_mode_button(_L("Show normal mode"), PrintEstimatedStatistics::ETimeMode::Normal); break; } default : { assert(false); break; } } } legend_height = ImGui::GetCurrentWindow()->Size.y; imgui.end(); ImGui::PopStyleVar(); } #if ENABLE_GCODE_VIEWER_STATISTICS void GCodeViewer::render_statistics() const { static const float offset = 275.0f; ImGuiWrapper& imgui = *wxGetApp().imgui(); auto add_time = [this, &imgui](const std::string& label, int64_t time) { imgui.text_colored(ImGuiWrapper::COL_ORANGE_LIGHT, label); ImGui::SameLine(offset); imgui.text(std::to_string(time) + " ms (" + get_time_dhms(static_cast(time) * 0.001f) + ")"); }; auto add_memory = [this, &imgui](const std::string& label, int64_t memory) { auto format_string = [memory](const std::string& units, float value) { return std::to_string(memory) + " bytes (" + Slic3r::float_to_string_decimal_point(float(memory) * value, 3) + " " + units + ")"; }; static const float kb = 1024.0f; static const float inv_kb = 1.0f / kb; static const float mb = 1024.0f * kb; static const float inv_mb = 1.0f / mb; static const float gb = 1024.0f * mb; static const float inv_gb = 1.0f / gb; imgui.text_colored(ImGuiWrapper::COL_ORANGE_LIGHT, label); ImGui::SameLine(offset); if (static_cast(memory) < mb) imgui.text(format_string("KB", inv_kb)); else if (static_cast(memory) < gb) imgui.text(format_string("MB", inv_mb)); else imgui.text(format_string("GB", inv_gb)); }; auto add_counter = [this, &imgui](const std::string& label, int64_t counter) { imgui.text_colored(ImGuiWrapper::COL_ORANGE_LIGHT, label); ImGui::SameLine(offset); imgui.text(std::to_string(counter)); }; imgui.set_next_window_pos(0.5f * wxGetApp().plater()->get_current_canvas3D()->get_canvas_size().get_width(), 0.0f, ImGuiCond_Once, 0.5f, 0.0f); ImGui::SetNextWindowSizeConstraints({ 300.0f, 100.0f }, { 600.0f, 900.0f }); imgui.begin(std::string("GCodeViewer Statistics"), ImGuiWindowFlags_AlwaysAutoResize | ImGuiWindowFlags_NoResize); ImGui::BringWindowToDisplayFront(ImGui::GetCurrentWindow()); if (ImGui::CollapsingHeader("Time")) { add_time(std::string("GCodeProcessor:"), m_statistics.results_time); ImGui::Separator(); add_time(std::string("Load:"), m_statistics.load_time); add_time(std::string(" Load vertices:"), m_statistics.load_vertices); add_time(std::string(" Smooth vertices:"), m_statistics.smooth_vertices); add_time(std::string(" Load indices:"), m_statistics.load_indices); add_time(std::string("Refresh:"), m_statistics.refresh_time); add_time(std::string("Refresh paths:"), m_statistics.refresh_paths_time); } if (ImGui::CollapsingHeader("OpenGL calls")) { add_counter(std::string("Multi GL_POINTS:"), m_statistics.gl_multi_points_calls_count); add_counter(std::string("Multi GL_LINES:"), m_statistics.gl_multi_lines_calls_count); add_counter(std::string("Multi GL_TRIANGLES:"), m_statistics.gl_multi_triangles_calls_count); add_counter(std::string("GL_TRIANGLES:"), m_statistics.gl_triangles_calls_count); } if (ImGui::CollapsingHeader("CPU memory")) { add_memory(std::string("GCodeProcessor results:"), m_statistics.results_size); ImGui::Separator(); add_memory(std::string("Paths:"), m_statistics.paths_size); add_memory(std::string("Render paths:"), m_statistics.render_paths_size); } if (ImGui::CollapsingHeader("GPU memory")) { add_memory(std::string("Vertices:"), m_statistics.total_vertices_gpu_size); add_memory(std::string("Indices:"), m_statistics.total_indices_gpu_size); ImGui::Separator(); add_memory(std::string("Max VBuffer:"), m_statistics.max_vbuffer_gpu_size); add_memory(std::string("Max IBuffer:"), m_statistics.max_ibuffer_gpu_size); } if (ImGui::CollapsingHeader("Other")) { add_counter(std::string("Travel segments count:"), m_statistics.travel_segments_count); add_counter(std::string("Wipe segments count:"), m_statistics.wipe_segments_count); add_counter(std::string("Extrude segments count:"), m_statistics.extrude_segments_count); ImGui::Separator(); add_counter(std::string("VBuffers count:"), m_statistics.vbuffers_count); add_counter(std::string("IBuffers count:"), m_statistics.ibuffers_count); } imgui.end(); } #endif // ENABLE_GCODE_VIEWER_STATISTICS void GCodeViewer::log_memory_used(const std::string& label, int64_t additional) const { if (Slic3r::get_logging_level() >= 5) { int64_t paths_size = 0; int64_t render_paths_size = 0; for (const TBuffer& buffer : m_buffers) { paths_size += SLIC3R_STDVEC_MEMSIZE(buffer.paths, Path); render_paths_size += SLIC3R_STDUNORDEREDSET_MEMSIZE(buffer.render_paths, RenderPath); for (const RenderPath& path : buffer.render_paths) { render_paths_size += SLIC3R_STDVEC_MEMSIZE(path.sizes, unsigned int); render_paths_size += SLIC3R_STDVEC_MEMSIZE(path.offsets, size_t); } } int64_t layers_size = SLIC3R_STDVEC_MEMSIZE(m_layers.get_zs(), double); layers_size += SLIC3R_STDVEC_MEMSIZE(m_layers.get_endpoints(), Layers::Endpoints); BOOST_LOG_TRIVIAL(trace) << label << "(" << format_memsize_MB(additional + paths_size + render_paths_size + layers_size) << ");" << log_memory_info(); } } } // namespace GUI } // namespace Slic3r