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8f08b587c63b2d4eb9b0c2e526654c140aa880d7
OrcaSlicer/src/slic3r/GUI/DeviceManager.cpp
maosheng.wei 8f08b587c6 ENH: Optimize the number of function calls during information parsing 
During the printer connection cycle, each Filament and slot is only judged once
When deleting custom filaments or modifying the temperature of custom filaments, re evaluate

Jira: XXXX

Change-Id: If495a343efdb1be6f46d11dd20f6ec7934266e87
(cherry picked from commit e5dab1487188d744c732568232b32666e5f2cc5c)
2025-01-23 11:38:11 +08:00

6074 lines
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#include "libslic3r/libslic3r.h"
#include "DeviceManager.hpp"
#include "libslic3r/Time.hpp"
#include "libslic3r/Thread.hpp"
#include "slic3r/Utils/ColorSpaceConvert.hpp"
#include "GUI_App.hpp"
#include "MsgDialog.hpp"
#include "Plater.hpp"
#include "GUI_App.hpp"
#include "ReleaseNote.hpp"
#include <thread>
#include <mutex>
#include <codecvt>
#include <boost/foreach.hpp>
#include <boost/typeof/typeof.hpp>
#include <boost/uuid/uuid.hpp>
#include <boost/uuid/uuid_generators.hpp>
#include <boost/uuid/uuid_io.hpp>
#include "fast_float/fast_float.h"
#define CALI_DEBUG
#define MINUTE_30 1800000 //ms
#define TIME_OUT 5000 //ms
namespace pt = boost::property_tree;
float string_to_float(const std::string& str_value) {
float value = 0.0;
fast_float::from_chars(str_value.c_str(), str_value.c_str() + str_value.size(), value);
return value;
}
const int PRINTING_STAGE_COUNT = 36;
std::string PRINTING_STAGE_STR[PRINTING_STAGE_COUNT] = {
"printing",
"bed_leveling",
"heatbed_preheating",
"xy_mech_mode_sweep",
"change_material",
"m400_pause",
"filament_runout_pause",
"hotend_heating",
"extrude_compensation_scan",
"bed_scan",
"first_layer_scan",
"be_surface_typt_idetification",
"scanner_extrinsic_para_cali",
"toohead_homing",
"nozzle_tip_cleaning",
"extruder_temp_protect_cali",
"user_pause",
"toolhead_shell_off_pause",
"scanner_laser_para_cali",
"extruder_absolute_flow_cali",
"hotend_temperature_error_pause", // 20
"heated_bed_temperature_error_pause",
"filament_unloading",
"skip_step_pause",
"filament_loading",
"motor_noise_calibration",
"ams_lost_pause",
"heat_break_fan_pause",
"chamber_temperature_control_error_pause",
"chamber_cooling",
"user_insert_gcode_pause",
"motor_noise_showoff",
"nozzle_filament_covered_detected_pause",
"cutter_error_pause",
"first_layer_error_pause",
"nozzle_clog_pause"
};
wxString get_stage_string(int stage)
{
switch(stage) {
case 0:
//return _L("Printing");
return "";
case 1:
return _L("Auto bed leveling");
case 2:
return _L("Heatbed preheating");
case 3:
return _L("Sweeping XY mech mode");
case 4:
return _L("Changing filament");
case 5:
return _L("M400 pause");
case 6:
return _L("Paused due to filament runout");
case 7:
return _L("Heating hotend");
case 8:
return _L("Calibrating extrusion");
case 9:
return _L("Scanning bed surface");
case 10:
return _L("Inspecting first layer");
case 11:
return _L("Identifying build plate type");
case 12:
return _L("Calibrating Micro Lidar");
case 13:
return _L("Homing toolhead");
case 14:
return _L("Cleaning nozzle tip");
case 15:
return _L("Checking extruder temperature");
case 16:
return _L("Printing was paused by the user");
case 17:
return _L("Pause of front cover falling");
case 18:
return _L("Calibrating the micro lida");
case 19:
return _L("Calibrating extrusion flow");
case 20:
return _L("Paused due to nozzle temperature malfunction");
case 21:
return _L("Paused due to heat bed temperature malfunction");
case 22:
return _L("Filament unloading");
case 23:
return _L("Skip step pause");
case 24:
return _L("Filament loading");
case 25:
return _L("Motor noise calibration");
case 26:
return _L("Paused due to AMS lost");
case 27:
return _L("Paused due to low speed of the heat break fan");
case 28:
return _L("Paused due to chamber temperature control error");
case 29:
return _L("Cooling chamber");
case 30:
return _L("Paused by the Gcode inserted by user");
case 31:
return _L("Motor noise showoff");
case 32:
return _L("Nozzle filament covered detected pause");
case 33:
return _L("Cutter error pause");
case 34:
return _L("First layer error pause");
case 35:
return _L("Nozzle clog pause");
default:
;
}
return "";
}
std::string to_string_nozzle_diameter(float nozzle_diameter)
{
float eps = 1e-3;
if (abs(nozzle_diameter - 0.2) < eps) {
return "0.2";
}
else if (abs(nozzle_diameter - 0.4) < eps) {
return "0.4";
}
else if (abs(nozzle_diameter - 0.6) < eps) {
return "0.6";
}
else if (abs(nozzle_diameter - 0.8) < eps) {
return "0.8";
}
return "0";
}
namespace Slic3r {
/* Common Functions */
void split_string(std::string s, std::vector<std::string>& v) {
std::string t = "";
for (int i = 0; i < s.length(); ++i) {
if (s[i] == ',') {
v.push_back(t);
t = "";
}
else {
t.push_back(s[i]);
}
}
v.push_back(t);
}
PrinterArch get_printer_arch_by_str(std::string arch_str)
{
if (arch_str == "i3") {
return PrinterArch::ARCH_I3;
}
else if (arch_str == "core_xy") {
return PrinterArch::ARCH_CORE_XY;
}
return PrinterArch::ARCH_CORE_XY;
}
void AmsTray::update_color_from_str(std::string color)
{
if (color.empty()) return;
if (this->color.compare(color) == 0)
return;
wx_color = "#" + wxString::FromUTF8(color);
this->color = color;
}
wxColour AmsTray::get_color()
{
return AmsTray::decode_color(color);
}
void AmsTray::reset()
{
tag_uid = "";
setting_id = "";
filament_setting_id = "";
type = "";
sub_brands = "";
color = "";
weight = "";
diameter = "";
temp = "";
time = "";
bed_temp_type = "";
bed_temp = "";
nozzle_temp_max = "";
nozzle_temp_min = "";
xcam_info = "";
uuid = "";
k = 0.0f;
n = 0.0f;
is_bbl = false;
hold_count = 0;
remain = 0;
}
bool AmsTray::is_tray_info_ready()
{
if (color.empty())
return false;
if (type.empty())
return false;
//if (setting_id.empty())
//return false;
return true;
}
bool AmsTray::is_unset_third_filament()
{
if (this->is_bbl)
return false;
if (color.empty() || type.empty())
return true;
return false;
}
std::string AmsTray::get_display_filament_type()
{
if (type == "PLA-S")
return "Sup.PLA";
else if (type == "PA-S")
return "Sup.PA";
else
return type;
return type;
}
std::string AmsTray::get_filament_type()
{
if (type == "Sup.PLA") {
return "PLA-S";
} else if (type == "Sup.PA") {
return "PA-S";
} else if (type == "Support W") {
return "PLA-S";
} else if (type == "Support G") {
return "PA-S";
} else if (type == "Support") {
if (setting_id == "GFS00") {
type = "PLA-S";
} else if (setting_id == "GFS01") {
type = "PA-S";
} else {
return "PLA-S";
}
} else {
return type;
}
return type;
}
bool HMSItem::parse_hms_info(unsigned attr, unsigned code)
{
bool result = true;
unsigned int model_id_int = (attr >> 24) & 0xFF;
this->module_id = (ModuleID)model_id_int;
this->module_num = (attr >> 16) & 0xFF;
this->part_id = (attr >> 8) & 0xFF;
this->reserved = (attr >> 0) & 0xFF;
unsigned msg_level_int = code >> 16;
if (msg_level_int < (unsigned)HMS_MSG_LEVEL_MAX)
this->msg_level = (HMSMessageLevel)msg_level_int;
else
this->msg_level = HMS_UNKNOWN;
this->msg_code = code & 0xFFFF;
return result;
}
std::string HMSItem::get_long_error_code()
{
char buf[64];
::sprintf(buf, "%02X%02X%02X00000%1X%04X",
this->module_id,
this->module_num,
this->part_id,
(int)this->msg_level,
this->msg_code);
return std::string(buf);
}
wxString HMSItem::get_module_name(ModuleID module_id)
{
switch (module_id)
{
case MODULE_MC:
return "MC";
case MODULE_MAINBOARD:
return "MainBoard";
case MODULE_AMS:
return "AMS";
case MODULE_TH:
return "TH";
case MODULE_XCAM:
return "XCam";
default:
wxString text = _L("Unknown") + wxString::Format("0x%x", (unsigned)module_id);
return text;
}
return "";
}
wxString HMSItem::get_hms_msg_level_str(HMSMessageLevel level)
{
switch(level) {
case HMS_FATAL:
return _L("Fatal");
case HMS_SERIOUS:
return _L("Serious");
case HMS_COMMON:
return _L("Common");
case HMS_INFO:
return _L("Info");
default:
return _L("Unknown");
}
return "";
}
std::string MachineObject::parse_printer_type(std::string type_str)
{
if (type_str.compare("3DPrinter-X1") == 0) {
return "BL-P002";
} else if (type_str.compare("3DPrinter-X1-Carbon") == 0) {
return "BL-P001";
} else if (type_str.compare("BL-P001") == 0) {
return type_str;
} else if (type_str.compare("BL-P002") == 0) {
return type_str;
} else {
return DeviceManager::parse_printer_type(type_str);
}
return "";
}
std::string MachineObject::get_preset_printer_model_name(std::string printer_type)
{
return DeviceManager::get_printer_display_name(printer_type);
}
std::string MachineObject::get_preset_printer_thumbnail_img(std::string printer_type)
{
return DeviceManager::get_printer_thumbnail_img(printer_type);
}
wxString MachineObject::get_printer_type_display_str()
{
std::string display_name = get_preset_printer_model_name(printer_type);
if (!display_name.empty())
return display_name;
else
return _L("Unknown");
}
std::string MachineObject::get_printer_thumbnail_img_str()
{
std::string img_str = get_preset_printer_thumbnail_img(printer_type);
std::string img_url;
if (!img_str.empty()) {
img_url = Slic3r::resources_dir() + "\\printers\\image\\" + img_str;
if (fs::exists(img_url + ".svg")) {
return img_url;
}
else {
img_url = img_str;
}
}
else {
img_url = "printer_thumbnail";
}
return img_url;
}
std::string MachineObject::get_ftp_folder()
{
return DeviceManager::get_ftp_folder(printer_type);
}
std::string MachineObject::get_access_code()
{
if (get_user_access_code().empty())
return access_code;
return get_user_access_code();
}
void MachineObject::set_access_code(std::string code, bool only_refresh)
{
this->access_code = code;
if (only_refresh) {
AppConfig* config = GUI::wxGetApp().app_config;
if (config && !code.empty()) {
GUI::wxGetApp().app_config->set_str("access_code", dev_id, code);
}
}
}
void MachineObject::erase_user_access_code()
{
this->user_access_code = "";
AppConfig* config = GUI::wxGetApp().app_config;
if (config) {
GUI::wxGetApp().app_config->erase("user_access_code", dev_id);
//GUI::wxGetApp().app_config->save();
}
}
void MachineObject::set_user_access_code(std::string code, bool only_refresh)
{
this->user_access_code = code;
if (only_refresh && !code.empty()) {
AppConfig* config = GUI::wxGetApp().app_config;
if (config && !code.empty()) {
GUI::wxGetApp().app_config->set_str("user_access_code", dev_id, code);
}
}
}
std::string MachineObject::get_user_access_code()
{
AppConfig* config = GUI::wxGetApp().app_config;
if (config) {
return GUI::wxGetApp().app_config->get("user_access_code", dev_id);
}
return "";
}
bool MachineObject::is_lan_mode_printer()
{
bool result = false;
if (!dev_connection_type.empty() && dev_connection_type == "lan")
return true;
return result;
}
PrinterSeries MachineObject::get_printer_series() const
{
std::string series = DeviceManager::get_printer_series(printer_type);
if (series == "series_x1")
return PrinterSeries::SERIES_X1;
else if (series == "series_p1p")
return PrinterSeries::SERIES_P1P;
else
return PrinterSeries::SERIES_P1P;
}
PrinterArch MachineObject::get_printer_arch() const
{
return DeviceManager::get_printer_arch(printer_type);
}
std::string MachineObject::get_printer_ams_type() const
{
return DeviceManager::get_printer_ams_type(printer_type);
}
bool MachineObject::get_printer_is_enclosed() const
{
return DeviceManager::get_printer_is_enclosed(printer_type);
}
void MachineObject::reload_printer_settings()
{
print_json.load_compatible_settings("", "");
parse_json("{}");
}
MachineObject::MachineObject(NetworkAgent* agent, std::string name, std::string id, std::string ip)
:dev_name(name),
dev_id(id),
dev_ip(ip),
subtask_(nullptr),
model_task(nullptr),
slice_info(nullptr),
m_is_online(false),
vt_tray(std::to_string(VIRTUAL_TRAY_ID))
{
m_agent = agent;
reset();
/* temprature fields */
nozzle_temp = 0.0f;
nozzle_temp_target = 0.0f;
bed_temp = 0.0f;
bed_temp_target = 0.0f;
chamber_temp = 0.0f;
chamber_temp_target = 0.0f;
frame_temp = 0.0f;
/* ams fileds */
ams_exist_bits = 0;
tray_exist_bits = 0;
tray_is_bbl_bits = 0;
ams_rfid_status = 0;
is_ams_need_update = false;
ams_insert_flag = false;
ams_power_on_flag = false;
ams_support_use_ams = false;
ams_calibrate_remain_flag = false;
ams_humidity = 5;
/* signals */
wifi_signal = "";
/* upgrade */
upgrade_force_upgrade = false;
upgrade_new_version = false;
upgrade_consistency_request = false;
/* cooling */
heatbreak_fan_speed = 0;
cooling_fan_speed = 0;
big_fan1_speed = 0;
big_fan2_speed = 0;
fan_gear = 0;
/* printing */
mc_print_stage = 0;
mc_print_error_code = 0;
print_error = 0;
mc_print_line_number = 0;
mc_print_percent = 0;
mc_print_sub_stage = 0;
mc_left_time = 0;
home_flag = -1;
hw_switch_state = 0;
printing_speed_lvl = PrintingSpeedLevel::SPEED_LEVEL_INVALID;
has_ipcam = true; // default true
}
MachineObject::~MachineObject()
{
if (subtask_) {
delete subtask_;
subtask_ = nullptr;
}
if (model_task) {
delete model_task;
model_task = nullptr;
}
if (get_slice_info_thread) {
if (get_slice_info_thread->joinable()) {
get_slice_info_thread->join();
get_slice_info_thread = nullptr;
}
}
if (slice_info) {
delete slice_info;
slice_info = nullptr;
}
for (auto it = amsList.begin(); it != amsList.end(); it++) {
for (auto tray_it = it->second->trayList.begin(); tray_it != it->second->trayList.end(); tray_it++) {
if (tray_it->second) {
delete tray_it->second;
tray_it->second = nullptr;
}
}
it->second->trayList.clear();
}
amsList.clear();
}
bool MachineObject::check_valid_ip()
{
if (dev_ip.empty()) {
return false;
}
return true;
}
void MachineObject::_parse_print_option_ack(int option)
{
xcam_auto_recovery_step_loss = ((option >> (int)PRINT_OP_AUTO_RECOVERY) & 0x01) != 0;
}
bool MachineObject::is_in_extrusion_cali()
{
auto curr_time = std::chrono::system_clock::now();
auto diff = std::chrono::duration_cast<std::chrono::milliseconds>(curr_time - last_extrusion_cali_start_time);
if (diff.count() < EXTRUSION_OMIT_TIME) {
mc_print_percent = 0;
return true;
}
if (is_in_printing_status(print_status)
&& print_type == "system"
&& boost::contains(m_gcode_file, "extrusion_cali")
)
{
return true;
}
return false;
}
bool MachineObject::is_extrusion_cali_finished()
{
auto curr_time = std::chrono::system_clock::now();
auto diff = std::chrono::duration_cast<std::chrono::milliseconds>(curr_time - last_extrusion_cali_start_time);
if (diff.count() < EXTRUSION_OMIT_TIME) {
return false;
}
if (boost::contains(m_gcode_file, "extrusion_cali")
&& this->mc_print_percent == 100)
return true;
else
return false;
}
void MachineObject::_parse_tray_now(std::string tray_now)
{
m_tray_now = tray_now;
if (tray_now.empty()) {
return;
} else {
try {
int tray_now_int = atoi(tray_now.c_str());
if (tray_now_int >= 0 && tray_now_int < 16) {
m_ams_id = std::to_string(tray_now_int >> 2);
m_tray_id = std::to_string(tray_now_int & 0x3);
}
else if (tray_now_int == 255) {
m_ams_id = "0";
m_tray_id = "0";
}
}
catch(...) {
}
}
}
Ams *MachineObject::get_curr_Ams()
{
auto it = amsList.find(m_ams_id);
if (it != amsList.end())
return it->second;
return nullptr;
}
AmsTray *MachineObject::get_curr_tray()
{
if (m_tray_now.compare(std::to_string(VIRTUAL_TRAY_ID)) == 0) {
return &vt_tray;
}
Ams* curr_ams = get_curr_Ams();
if (!curr_ams) return nullptr;
try {
int tray_index = atoi(m_tray_now.c_str());
int ams_index = atoi(curr_ams->id.c_str());
std::string tray_now_index = std::to_string(tray_index - ams_index * 4);
auto it = curr_ams->trayList.find(tray_now_index);
if (it != curr_ams->trayList.end())
return it->second;
}
catch (...) {
;
}
return nullptr;
}
AmsTray *MachineObject::get_ams_tray(std::string ams_id, std::string tray_id)
{
auto it = amsList.find(ams_id);
if (it == amsList.end()) return nullptr;
if (!it->second) return nullptr;
auto iter = it->second->trayList.find(tray_id);
if (iter != it->second->trayList.end())
return iter->second;
else
return nullptr;
}
void MachineObject::_parse_ams_status(int ams_status)
{
ams_status_sub = ams_status & 0xFF;
int ams_status_main_int = (ams_status & 0xFF00) >> 8;
if (ams_status_main_int == (int)AmsStatusMain::AMS_STATUS_MAIN_IDLE) {
ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_IDLE;
} else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_FILAMENT_CHANGE) {
ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_FILAMENT_CHANGE;
} else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_RFID_IDENTIFYING) {
ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_RFID_IDENTIFYING;
} else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_ASSIST) {
ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_ASSIST;
} else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_CALIBRATION) {
ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_CALIBRATION;
} else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_SELF_CHECK) {
ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_SELF_CHECK;
} else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_DEBUG) {
ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_DEBUG;
} else {
ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_UNKNOWN;
}
BOOST_LOG_TRIVIAL(trace) << "ams_debug: main = " << ams_status_main_int << ", sub = " << ams_status_sub;
}
bool MachineObject::can_unload_filament()
{
bool result = false;
if (!has_ams())
return true;
if (ams_status_main == AMS_STATUS_MAIN_IDLE && hw_switch_state == 1 && m_tray_now == "255") {
return true;
}
return result;
}
bool MachineObject::is_support_ams_mapping()
{
return true;
}
static float calc_color_distance(wxColour c1, wxColour c2)
{
float lab[2][3];
RGB2Lab(c1.Red(), c1.Green(), c1.Blue(), &lab[0][0], &lab[0][1], &lab[0][2]);
RGB2Lab(c2.Red(), c2.Green(), c2.Blue(), &lab[1][0], &lab[1][1], &lab[1][2]);
return DeltaE76(lab[0][0], lab[0][1], lab[0][2], lab[1][0], lab[1][1], lab[1][2]);
}
void MachineObject::get_ams_colors(std::vector<wxColour> &ams_colors) {
ams_colors.clear();
ams_colors.reserve(amsList.size());
for (auto ams = amsList.begin(); ams != amsList.end(); ams++) {
for (auto tray = ams->second->trayList.begin(); tray != ams->second->trayList.end(); tray++) {
if (tray->second->is_tray_info_ready()) {
auto ams_color = AmsTray::decode_color(tray->second->color);
ams_colors.emplace_back(ams_color);
}
}
}
}
int MachineObject::ams_filament_mapping(std::vector<FilamentInfo> filaments, std::vector<FilamentInfo> &result, std::vector<int> exclude_id)
{
if (filaments.empty())
return -1;
// tray_index : tray_color
std::map<int, FilamentInfo> tray_filaments;
for (auto ams = amsList.begin(); ams != amsList.end(); ams++) {
for (auto tray = ams->second->trayList.begin(); tray != ams->second->trayList.end(); tray++) {
int ams_id = atoi(ams->first.c_str());
int tray_id = atoi(tray->first.c_str());
int tray_index = ams_id * 4 + tray_id;
// skip exclude id
for (int i = 0; i < exclude_id.size(); i++) {
if (tray_index == exclude_id[i])
continue;
}
// push
if (tray->second->is_tray_info_ready()) {
FilamentInfo info;
info.color = tray->second->color;
info.type = tray->second->get_filament_type();
info.id = tray_index;
info.filament_id = tray->second->setting_id;
info.ctype = tray->second->ctype;
info.colors = tray->second->cols;
tray_filaments.emplace(std::make_pair(tray_index, info));
}
}
}
// tray info list
std::vector<FilamentInfo> tray_info_list;
for (auto it = amsList.begin(); it != amsList.end(); it++) {
for (int i = 0; i < 4; i++) {
FilamentInfo info;
auto tray_it = it->second->trayList.find(std::to_string(i));
if (tray_it != it->second->trayList.end()) {
info.id = atoi(tray_it->first.c_str()) + atoi(it->first.c_str()) * 4;
info.tray_id = atoi(tray_it->first.c_str()) + atoi(it->first.c_str()) * 4;
info.color = tray_it->second->color;
info.type = tray_it->second->get_filament_type();
info.ctype = tray_it->second->ctype;
info.colors = tray_it->second->cols;
}
else {
info.id = -1;
info.tray_id = -1;
}
tray_info_list.push_back(info);
}
}
// is_support_ams_mapping
if (!is_support_ams_mapping()) {
BOOST_LOG_TRIVIAL(info) << "ams_mapping: do not support, use order mapping";
result.clear();
for (int i = 0; i < filaments.size(); i++) {
FilamentInfo info;
info.id = filaments[i].id;
int ams_id = filaments[i].id / 4;
auto ams_it = amsList.find(std::to_string(ams_id));
if (ams_it == amsList.end()) {
info.tray_id = -1;
info.mapping_result = (int)MappingResult::MAPPING_RESULT_EXCEED;
} else {
info.tray_id = filaments[i].id;
int tray_id = filaments[i].id % 4;
auto tray_it = ams_it->second->trayList.find(std::to_string(tray_id));
if (tray_it != ams_it->second->trayList.end()) {
if (!tray_it->second->is_exists || tray_it->second->is_unset_third_filament()) {
;
} else {
if (filaments[i].type == tray_it->second->get_filament_type()) {
info.color = tray_it->second->color;
info.type = tray_it->second->get_filament_type();
info.ctype = tray_it->second->ctype;
std::vector<wxColour> cols;
info.colors = tray_it->second->cols;
} else {
info.tray_id = -1;
info.mapping_result = (int)MappingResult::MAPPING_RESULT_TYPE_MISMATCH;
}
}
}
}
result.push_back(info);
}
return 1;
}
char buffer[256];
std::vector<std::vector<DisValue>> distance_map;
// print title
::sprintf(buffer, "F(id)");
std::string line = std::string(buffer);
for (auto tray = tray_filaments.begin(); tray != tray_filaments.end(); tray++) {
::sprintf(buffer, " AMS%02d", tray->second.id+1);
line += std::string(buffer);
}
BOOST_LOG_TRIVIAL(info) << "ams_mapping_distance:" << line;
for (int i = 0; i < filaments.size(); i++) {
std::vector<DisValue> rol;
::sprintf(buffer, "F(%02d)", filaments[i].id+1);
line = std::string(buffer);
for (auto tray = tray_filaments.begin(); tray != tray_filaments.end(); tray++) {
DisValue val;
val.tray_id = tray->second.id;
wxColour c = wxColour(filaments[i].color);
wxColour tray_c = AmsTray::decode_color(tray->second.color);
val.distance = calc_color_distance(c, tray_c);
if (filaments[i].type != tray->second.type) {
val.distance = 999999;
val.is_type_match = false;
} else {
if (c.Alpha() != tray_c.Alpha())
val.distance = 999999;
val.is_type_match = true;
}
::sprintf(buffer, " %6.0f", val.distance);
line += std::string(buffer);
rol.push_back(val);
}
BOOST_LOG_TRIVIAL(info) << "ams_mapping_distance:" << line;
distance_map.push_back(rol);
}
// mapping algorithm
for (int i = 0; i < filaments.size(); i++) {
FilamentInfo info;
info.id = filaments[i].id;
info.tray_id = -1;
result.push_back(info);
}
std::set<int> picked_src;
std::set<int> picked_tar;
for (int k = 0; k < distance_map.size(); k++) {
float min_val = INT_MAX;
int picked_src_idx = -1;
int picked_tar_idx = -1;
for (int i = 0; i < distance_map.size(); i++) {
if (picked_src.find(i) != picked_src.end())
continue;
for (int j = 0; j < distance_map[i].size(); j++) {
if (picked_tar.find(j) != picked_tar.end()){
if (distance_map[i][j].is_same_color
&& distance_map[i][j].is_type_match
&& distance_map[i][j].distance < (float)0.0001) {
min_val = distance_map[i][j].distance;
picked_src_idx = i;
picked_tar_idx = j;
}
continue;
}
if (distance_map[i][j].is_same_color
&& distance_map[i][j].is_type_match) {
if (min_val > distance_map[i][j].distance) {
min_val = distance_map[i][j].distance;
picked_src_idx = i;
picked_tar_idx = j;
}
else if (min_val == distance_map[i][j].distance&& filaments[picked_src_idx].filament_id!= tray_filaments[picked_tar_idx].filament_id && filaments[i].filament_id == tray_filaments[j].filament_id) {
picked_src_idx = i;
picked_tar_idx = j;
}
}
}
}
if (picked_src_idx >= 0 && picked_tar_idx >= 0) {
auto tray = tray_filaments.find(distance_map[k][picked_tar_idx].tray_id);
if (tray != tray_filaments.end()) {
result[picked_src_idx].tray_id = tray->first;
result[picked_src_idx].color = tray->second.color;
result[picked_src_idx].type = tray->second.type;
result[picked_src_idx].distance = tray->second.distance;
result[picked_src_idx].filament_id = tray->second.filament_id;
result[picked_src_idx].ctype = tray->second.ctype;
result[picked_src_idx].colors = tray->second.colors;
}
else {
FilamentInfo info;
info.tray_id = -1;
}
::sprintf(buffer, "ams_mapping, picked F(%02d) AMS(%02d), distance=%6.0f", picked_src_idx+1, picked_tar_idx+1,
distance_map[picked_src_idx][picked_tar_idx].distance);
BOOST_LOG_TRIVIAL(info) << std::string(buffer);
picked_src.insert(picked_src_idx);
picked_tar.insert(picked_tar_idx);
}
}
std::vector<FilamentInfo> cache_map_result = result;
//check ams mapping result
if (is_valid_mapping_result(result, true)) {
return 0;
}
reset_mapping_result(result);
try {
// try to use ordering ams mapping
bool order_mapping_result = true;
for (int i = 0; i < filaments.size(); i++) {
if (i >= tray_info_list.size()) {
order_mapping_result = false;
break;
}
if (tray_info_list[i].tray_id == -1) {
result[i].tray_id = tray_info_list[i].tray_id;
} else {
if (!tray_info_list[i].type.empty() && tray_info_list[i].type != filaments[i].type) {
order_mapping_result = false;
break;
} else {
result[i].tray_id = tray_info_list[i].tray_id;
result[i].color = tray_info_list[i].color;
result[i].type = tray_info_list[i].type;
result[i].ctype = tray_info_list[i].ctype;
result[i].colors = tray_info_list[i].colors;
}
}
}
//check order mapping result
if (is_valid_mapping_result(result, true)) {
return 0;
}
} catch(...) {
reset_mapping_result(result);
return -1;
}
// try to match some color
reset_mapping_result(result);
result = cache_map_result;
for (auto it = result.begin(); it != result.end(); it++) {
if (it->distance >= 6000) {
it->tray_id = -1;
}
}
return 0;
}
bool MachineObject::is_valid_mapping_result(std::vector<FilamentInfo>& result, bool check_empty_slot)
{
bool valid_ams_mapping_result = true;
if (result.empty()) return false;
for (int i = 0; i < result.size(); i++) {
// invalid mapping result
if (result[i].tray_id < 0)
valid_ams_mapping_result = false;
else {
int ams_id = result[i].tray_id / 4;
auto ams_item = amsList.find(std::to_string(ams_id));
if (ams_item == amsList.end()) {
result[i].tray_id = -1;
valid_ams_mapping_result = false;
} else {
if (check_empty_slot) {
int tray_id = result[i].tray_id % 4;
auto tray_item = ams_item->second->trayList.find(std::to_string(tray_id));
if (tray_item == ams_item->second->trayList.end()) {
result[i].tray_id = -1;
valid_ams_mapping_result = false;
} else {
if (!tray_item->second->is_exists) {
result[i].tray_id = -1;
valid_ams_mapping_result = false;
}
}
}
}
}
}
return valid_ams_mapping_result;
}
bool MachineObject::is_mapping_exceed_filament(std::vector<FilamentInfo> & result, int &exceed_index)
{
bool is_exceed = false;
for (int i = 0; i < result.size(); i++) {
int ams_id = result[i].tray_id / 4;
if (amsList.find(std::to_string(ams_id)) == amsList.end()) {
exceed_index = result[i].tray_id;
result[i].tray_id = -1;
is_exceed = true;
break;
}
if (result[i].mapping_result == MappingResult::MAPPING_RESULT_EXCEED) {
exceed_index = result[i].id;
is_exceed = true;
break;
}
}
return is_exceed;
}
void MachineObject::reset_mapping_result(std::vector<FilamentInfo>& result)
{
for (int i = 0; i < result.size(); i++) {
result[i].tray_id = -1;
result[i].distance = 99999;
result[i].mapping_result = 0;
}
}
bool MachineObject::is_bbl_filament(std::string tag_uid)
{
if (tag_uid.empty())
return false;
for (int i = 0; i < tag_uid.length(); i++) {
if (tag_uid[i] != '0')
return true;
}
return false;
}
std::string MachineObject::light_effect_str(LIGHT_EFFECT effect)
{
switch (effect)
{
case LIGHT_EFFECT::LIGHT_EFFECT_ON:
return "on";
case LIGHT_EFFECT::LIGHT_EFFECT_OFF:
return "off";
case LIGHT_EFFECT::LIGHT_EFFECT_FLASHING:
return "flashing";
default:
return "unknown";
}
return "unknown";
}
MachineObject::LIGHT_EFFECT MachineObject::light_effect_parse(std::string effect_str)
{
if (effect_str.compare("on") == 0)
return LIGHT_EFFECT::LIGHT_EFFECT_ON;
else if (effect_str.compare("off") == 0)
return LIGHT_EFFECT::LIGHT_EFFECT_OFF;
else if (effect_str.compare("flashing") == 0)
return LIGHT_EFFECT::LIGHT_EFFECT_FLASHING;
else
return LIGHT_EFFECT::LIGHT_EFFECT_UNKOWN;
return LIGHT_EFFECT::LIGHT_EFFECT_UNKOWN;
}
std::string MachineObject::get_firmware_type_str()
{
/*if (firmware_type == PrinterFirmwareType::FIRMWARE_TYPE_ENGINEER)
return "engineer";
else if (firmware_type == PrinterFirmwareType::FIRMWARE_TYPE_PRODUCTION)
return "product";*/
// return product by default;
// always return product, printer do not push this field
return "product";
}
std::string MachineObject::get_lifecycle_type_str()
{
/*if (lifecycle == PrinterFirmwareType::FIRMWARE_TYPE_ENGINEER)
return "engineer";
else if (lifecycle == PrinterFirmwareType::FIRMWARE_TYPE_PRODUCTION)
return "product";*/
// return product by default;
// always return product, printer do not push this field
return "product";
}
bool MachineObject::is_in_upgrading()
{
return upgrade_display_state == (int)UpgradingInProgress;
}
bool MachineObject::is_upgrading_avalable()
{
return upgrade_display_state == (int)UpgradingAvaliable;
}
int MachineObject::get_upgrade_percent()
{
if (upgrade_progress.empty())
return 0;
try {
int result = atoi(upgrade_progress.c_str());
return result;
} catch(...) {
;
}
return 0;
}
std::string MachineObject::get_ota_version()
{
auto it = module_vers.find("ota");
if (it != module_vers.end()) {
//double check name
if (it->second.name == "ota") {
return it->second.sw_ver;
}
}
return "";
}
bool MachineObject::check_version_valid()
{
bool valid = true;
for (auto module : module_vers) {
if (module.second.sn.empty()
&& module.first != "ota"
&& module.first != "xm")
return false;
if (module.second.sw_ver.empty())
return false;
}
get_version_retry = 0;
return valid;
}
wxString MachineObject::get_upgrade_result_str(int err_code)
{
switch(err_code) {
case UpgradeNoError:
return _L("Update successful.");
case UpgradeDownloadFailed:
return _L("Downloading failed.");
case UpgradeVerfifyFailed:
return _L("Verification failed.");
case UpgradeFlashFailed:
return _L("Update failed.");
case UpgradePrinting:
return _L("Update failed.");
default:
return _L("Update failed.");
}
return "";
}
std::map<int, MachineObject::ModuleVersionInfo> MachineObject::get_ams_version()
{
std::map<int, ModuleVersionInfo> result;
for (int i = 0; i < 4; i++) {
std::string ams_id = "ams/" + std::to_string(i);
auto it = module_vers.find(ams_id);
if (it != module_vers.end()) {
result.emplace(std::pair(i, it->second));
}
}
return result;
}
bool MachineObject::is_system_printing()
{
if (is_in_calibration() && is_in_printing_status(print_status))
return true;
//FIXME
//if (print_type == "system" && is_in_printing_status(print_status))
//return true;
return false;
}
bool MachineObject::check_pa_result_validation(PACalibResult& result)
{
if (result.k_value < 0 || result.k_value > 10)
return false;
return true;
}
bool MachineObject::is_axis_at_home(std::string axis)
{
if (home_flag < 0)
return true;
if (axis == "X") {
return (home_flag & 1) == 1;
} else if (axis == "Y") {
return (home_flag >> 1 & 1) == 1;
} else if (axis == "Z") {
return (home_flag >> 2 & 1) == 1;
} else {
return true;
}
}
bool MachineObject::is_filament_at_extruder()
{
if (hw_switch_state == 1)
return true;
else if (hw_switch_state == 0)
return false;
else {
//default
return true;
}
}
wxString MachineObject::get_curr_stage()
{
if (stage_list_info.empty()) {
return "";
}
return get_stage_string(stage_curr);
}
int MachineObject::get_curr_stage_idx()
{
int result = -1;
for (int i = 0; i < stage_list_info.size(); i++) {
if (stage_list_info[i] == stage_curr) {
return i;
}
}
return -1;
}
bool MachineObject::is_in_calibration()
{
// gcode file: auto_cali_for_user.gcode or auto_cali_for_user_param
if (boost::contains(m_gcode_file, "auto_cali_for_user")
&& stage_curr != 0) {
return true;
} else {
// reset
if (stage_curr != 0) {
calibration_done = false;
}
}
return false;
}
bool MachineObject::is_calibration_done()
{
return calibration_done;
}
bool MachineObject::is_calibration_running()
{
if (is_in_calibration() && is_in_printing_status(print_status))
return true;
return false;
}
void MachineObject::parse_state_changed_event()
{
// parse calibration done
if (last_mc_print_stage != mc_print_stage) {
if (mc_print_stage == 1 && boost::contains(m_gcode_file, "auto_cali_for_user")) {
calibration_done = true;
} else {
calibration_done = false;
}
}
last_mc_print_stage = mc_print_stage;
}
void MachineObject::parse_status(int flag)
{
is_220V_voltage = ((flag >> 3) & 0x1) != 0;
if (xcam_auto_recovery_hold_count > 0)
xcam_auto_recovery_hold_count--;
else {
xcam_auto_recovery_step_loss = ((flag >> 4) & 0x1) != 0;
}
camera_recording = ((flag >> 5) & 0x1) != 0;
ams_calibrate_remain_flag = ((flag >> 7) & 0x1) != 0;
if (ams_print_option_count > 0)
ams_print_option_count--;
else {
ams_auto_switch_filament_flag = ((flag >> 10) & 0x1) != 0;
}
if (xcam_prompt_sound_hold_count > 0)
xcam_prompt_sound_hold_count--;
else {
xcam_allow_prompt_sound = ((flag >> 17) & 0x1) != 0;
}
if (((flag >> 18) & 0x1) != 0) {
is_support_prompt_sound = true;
}
is_support_filament_tangle_detect = ((flag >> 19) & 0x1) != 0;
is_support_user_preset = ((flag >> 22) & 0x1) != 0;
if (xcam_filament_tangle_detect_count > 0)
xcam_filament_tangle_detect_count--;
else {
xcam_filament_tangle_detect = ((flag >> 20) & 0x1) != 0;
}
if(!is_support_motor_noise_cali){
is_support_motor_noise_cali = ((flag >> 21) & 0x1) != 0;
}
is_support_nozzle_blob_detection = ((flag >> 25) & 0x1) != 0;
nozzle_blob_detection_enabled = ((flag >> 24) & 0x1) != 0;
is_support_air_print_detection = ((flag >> 29) & 0x1) != 0;
ams_air_print_status = ((flag >> 28) & 0x1) != 0;
if (!is_support_p1s_plus) {
auto supported_plus = ((flag >> 27) & 0x1) != 0;
auto installed_plus = ((flag >> 26) & 0x1) != 0;
if (installed_plus && supported_plus) {
is_support_p1s_plus = true;
}
else {
is_support_p1s_plus = false;
}
}
sdcard_state = MachineObject::SdcardState((flag >> 8) & 0x11);
is_support_agora = ((flag >> 30) & 0x1) != 0;
if (is_support_agora)
is_support_tunnel_mqtt = false;
}
PrintingSpeedLevel MachineObject::_parse_printing_speed_lvl(int lvl)
{
if (lvl < (int)SPEED_LEVEL_COUNT)
return PrintingSpeedLevel(lvl);
return PrintingSpeedLevel::SPEED_LEVEL_INVALID;
}
int MachineObject::get_bed_temperature_limit()
{
if (get_printer_series() == PrinterSeries::SERIES_X1) {
if (is_220V_voltage)
return 110;
else {
return 120;
}
} else {
int limit = bed_temperature_limit < 0?BED_TEMP_LIMIT:bed_temperature_limit;
return limit;
}
return BED_TEMP_LIMIT;
}
bool MachineObject::is_makeworld_subtask()
{
if (model_task && model_task->design_id > 0) {
BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " model task id: " << model_task->task_id << " is makeworld model";
return true;
}
return false;
}
bool MachineObject::is_sdcard_printing()
{
if (can_abort()
&& (obj_subtask_id.compare("0") == 0 || obj_subtask_id.empty())
&& (profile_id_ == "0" || profile_id_.empty())
&& (project_id_ == "0" || project_id_.empty()))
return true;
else
return false;
}
bool MachineObject::has_sdcard()
{
return (sdcard_state == MachineObject::SdcardState::HAS_SDCARD_NORMAL);
}
MachineObject::SdcardState MachineObject::get_sdcard_state()
{
return sdcard_state;
}
bool MachineObject::is_timelapse()
{
return camera_timelapse;
}
bool MachineObject::is_recording_enable()
{
return camera_recording_when_printing;
}
bool MachineObject::is_recording()
{
return camera_recording;
}
std::string MachineObject::parse_version()
{
auto ota_version = module_vers.find("ota");
if (ota_version != module_vers.end()) return ota_version->second.sw_ver;
auto series = get_printer_series();
if (series == PrinterSeries::SERIES_X1) {
auto rv1126_version = module_vers.find("rv1126");
if (rv1126_version != module_vers.end()) return rv1126_version->second.sw_ver;
} else if (series == PrinterSeries::SERIES_P1P) {
auto esp32_version = module_vers.find("esp32");
if (esp32_version != module_vers.end()) return esp32_version->second.sw_ver;
}
return "";
}
void MachineObject::parse_version_func()
{
}
bool MachineObject::is_studio_cmd(int sequence_id)
{
if (sequence_id >= START_SEQ_ID && sequence_id < END_SEQ_ID) {
return true;
}
return false;
}
int MachineObject::command_get_version(bool with_retry)
{
BOOST_LOG_TRIVIAL(info) << "command_get_version";
json j;
j["info"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["info"]["command"] = "get_version";
if (with_retry)
get_version_retry = GET_VERSION_RETRYS;
return this->publish_json(j.dump(), 1);
}
int MachineObject::command_get_access_code() {
BOOST_LOG_TRIVIAL(info) << "command_get_access_code";
json j;
j["system"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["system"]["command"] = "get_access_code";
return this->publish_json(j.dump());
}
int MachineObject::command_request_push_all(bool request_now)
{
auto curr_time = std::chrono::system_clock::now();
auto diff = std::chrono::duration_cast<std::chrono::milliseconds>(curr_time - last_request_push);
if (diff.count() < REQUEST_PUSH_MIN_TIME) {
if (request_now) {
BOOST_LOG_TRIVIAL(trace) << "static: command_request_push_all, dev_id=" << dev_id;
last_request_push = std::chrono::system_clock::now();
}
else {
BOOST_LOG_TRIVIAL(trace) << "static: command_request_push_all: send request too fast, dev_id=" << dev_id;
return -1;
}
} else {
BOOST_LOG_TRIVIAL(trace) << "static: command_request_push_all, dev_id=" << dev_id;
last_request_push = std::chrono::system_clock::now();
}
json j;
j["pushing"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["pushing"]["command"] = "pushall";
j["pushing"]["version"] = 1;
j["pushing"]["push_target"] = 1;
return this->publish_json(j.dump());
}
int MachineObject::command_pushing(std::string cmd)
{
auto curr_time = std::chrono::system_clock::now();
auto diff = std::chrono::duration_cast<std::chrono::milliseconds>(curr_time - last_request_start);
if (diff.count() < REQUEST_START_MIN_TIME) {
BOOST_LOG_TRIVIAL(trace) << "static: command_request_start: send request too fast, dev_id=" << dev_id;
return -1;
}
else {
BOOST_LOG_TRIVIAL(trace) << "static: command_request_start, dev_id=" << dev_id;
last_request_start = std::chrono::system_clock::now();
}
if (cmd == "start" || cmd == "stop") {
json j;
j["pushing"]["command"] = cmd;
j["pushing"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
return this->publish_json(j.dump());
}
return -1;
}
int MachineObject::command_clean_print_error(std::string subtask_id, int print_error)
{
BOOST_LOG_TRIVIAL(info) << "command_clean_print_error, id = " << subtask_id;
json j;
j["print"]["command"] = "clean_print_error";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["subtask_id"] = subtask_id;
j["print"]["print_error"] = print_error;
return this->publish_json(j.dump());
}
int MachineObject::command_upgrade_confirm()
{
BOOST_LOG_TRIVIAL(info) << "command_upgrade_confirm";
json j;
j["upgrade"]["command"] = "upgrade_confirm";
j["upgrade"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["upgrade"]["src_id"] = 1; // 1 for slicer
return this->publish_json(j.dump());
}
int MachineObject::command_consistency_upgrade_confirm()
{
BOOST_LOG_TRIVIAL(info) << "command_consistency_upgrade_confirm";
json j;
j["upgrade"]["command"] = "consistency_confirm";
j["upgrade"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["upgrade"]["src_id"] = 1; // 1 for slicer
return this->publish_json(j.dump());
}
int MachineObject::command_upgrade_firmware(FirmwareInfo info)
{
std::string version = info.version;
std::string dst_url = info.url;
std::string module_name = info.module_type;
json j;
j["upgrade"]["command"] = "start";
j["upgrade"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["upgrade"]["url"] = info.url;
j["upgrade"]["module"] = info.module_type;
j["upgrade"]["version"] = info.version;
j["upgrade"]["src_id"] = 1;
return this->publish_json(j.dump());
}
int MachineObject::command_upgrade_module(std::string url, std::string module_type, std::string version)
{
json j;
j["upgrade"]["command"] = "start";
j["upgrade"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["upgrade"]["url"] = url;
j["upgrade"]["module"] = module_type;
j["upgrade"]["version"] = version;
j["upgrade"]["src_id"] = 1;
return this->publish_json(j.dump());
}
int MachineObject::command_xyz_abs()
{
return this->publish_gcode("G90 \n");
}
int MachineObject::command_auto_leveling()
{
return this->publish_gcode("G29 \n");
}
int MachineObject::command_go_home()
{
return this->publish_gcode("G28 \n");
}
int MachineObject::command_control_fan(FanType fan_type, bool on_off)
{
std::string gcode = (boost::format("M106 P%1% S%2% \n") % (int)fan_type % (on_off ? 255 : 0)).str();
return this->publish_gcode(gcode);
}
int MachineObject::command_control_fan_val(FanType fan_type, int val)
{
std::string gcode = (boost::format("M106 P%1% S%2% \n") % (int)fan_type % (val)).str();
return this->publish_gcode(gcode);
}
int MachineObject::command_task_abort()
{
BOOST_LOG_TRIVIAL(trace) << "command_task_abort: ";
json j;
j["print"]["command"] = "stop";
j["print"]["param"] = "";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
return this->publish_json(j.dump(), 1);
}
int MachineObject::command_task_cancel(std::string job_id)
{
BOOST_LOG_TRIVIAL(trace) << "command_task_cancel: " << job_id;
json j;
j["print"]["command"] = "stop";
j["print"]["param"] = "";
j["print"]["job_id"] = job_id;
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
return this->publish_json(j.dump(), 1);
}
int MachineObject::command_task_pause()
{
json j;
j["print"]["command"] = "pause";
j["print"]["param"] = "";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
return this->publish_json(j.dump(), 1);
}
int MachineObject::command_task_resume()
{
json j;
j["print"]["command"] = "resume";
j["print"]["param"] = "";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
return this->publish_json(j.dump(), 1);
}
int MachineObject::command_set_bed(int temp)
{
std::string gcode_str = (boost::format("M140 S%1%\n") % temp).str();
return this->publish_gcode(gcode_str);
}
int MachineObject::command_set_nozzle(int temp)
{
std::string gcode_str = (boost::format("M104 S%1%\n") % temp).str();
return this->publish_gcode(gcode_str);
}
int MachineObject::command_set_chamber(int temp)
{
json j;
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["command"] = "set_ctt";
j["print"]["ctt_val"] = temp;
return this->publish_json(j.dump(), 1);
}
int MachineObject::command_ams_switch(int tray_index, int old_temp, int new_temp)
{
BOOST_LOG_TRIVIAL(trace) << "ams_switch to " << tray_index << " with temp: " << old_temp << ", " << new_temp;
if (old_temp < 0) old_temp = FILAMENT_DEF_TEMP;
if (new_temp < 0) new_temp = FILAMENT_DEF_TEMP;
std::string gcode = "";
int result = 0;
//command
if (is_support_command_ams_switch) {
command_ams_change_filament(tray_index, old_temp, new_temp);
}
else {
std::string gcode = "";
if (tray_index == 255) {
gcode = DeviceManager::load_gcode(printer_type, "ams_unload.gcode");
}
else {
// include VIRTUAL_TRAY_ID
gcode = DeviceManager::load_gcode(printer_type, "ams_load.gcode");
boost::replace_all(gcode, "[next_extruder]", std::to_string(tray_index));
boost::replace_all(gcode, "[new_filament_temp]", std::to_string(new_temp));
}
result = this->publish_gcode(gcode);
}
return result;
}
int MachineObject::command_ams_change_filament(int tray_id, int old_temp, int new_temp)
{
json j;
j["print"]["command"] = "ams_change_filament";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["target"] = tray_id;
j["print"]["curr_temp"] = old_temp;
j["print"]["tar_temp"] = new_temp;
return this->publish_json(j.dump());
}
int MachineObject::command_ams_user_settings(int ams_id, bool start_read_opt, bool tray_read_opt, bool remain_flag)
{
json j;
j["print"]["command"] = "ams_user_setting";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["ams_id"] = ams_id;
j["print"]["startup_read_option"] = start_read_opt;
j["print"]["tray_read_option"] = tray_read_opt;
j["print"]["calibrate_remain_flag"] = remain_flag;
ams_insert_flag = tray_read_opt;
ams_power_on_flag = start_read_opt;
ams_calibrate_remain_flag = remain_flag;
ams_user_setting_hold_count = HOLD_COUNT_MAX;
return this->publish_json(j.dump());
}
int MachineObject::command_ams_user_settings(int ams_id, AmsOptionType op, bool value)
{
json j;
j["print"]["command"] = "ams_user_setting";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["ams_id"] = ams_id;
if (op == AmsOptionType::AMS_OP_STARTUP_READ) {
j["print"]["startup_read_option"] = value;
ams_power_on_flag = value;
} else if (op == AmsOptionType::AMS_OP_TRAY_READ) {
j["print"]["tray_read_option"] = value;
ams_insert_flag = value;
} else if (op == AmsOptionType::AMS_OP_CALIBRATE_REMAIN) {
j["print"]["calibrate_remain_flag"] = value;
ams_calibrate_remain_flag = value;
} else {
return -1;
}
ams_user_setting_hold_count = HOLD_COUNT_MAX;
return this->publish_json(j.dump());
}
int MachineObject::command_ams_calibrate(int ams_id)
{
std::string gcode_cmd = (boost::format("M620 C%1% \n") % ams_id).str();
BOOST_LOG_TRIVIAL(trace) << "ams_debug: gcode_cmd" << gcode_cmd;
return this->publish_gcode(gcode_cmd);
}
int MachineObject::command_ams_filament_settings(int ams_id, int tray_id, std::string filament_id, std::string setting_id, std::string tray_color, std::string tray_type, int nozzle_temp_min, int nozzle_temp_max)
{
BOOST_LOG_TRIVIAL(info) << "command_ams_filament_settings, ams_id = " << ams_id << ", tray_id = " << tray_id << ", tray_color = " << tray_color
<< ", tray_type = " << tray_type << ", filament_id = " << filament_id
<< ", setting_id = " << setting_id << ", temp_min: = " << nozzle_temp_min << ", temp_max: = " << nozzle_temp_max;
json j;
j["print"]["command"] = "ams_filament_setting";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["ams_id"] = ams_id;
j["print"]["tray_id"] = tray_id;
j["print"]["tray_info_idx"] = filament_id;
j["print"]["setting_id"] = setting_id;
// format "FFFFFFFF" RGBA
j["print"]["tray_color"] = tray_color;
j["print"]["nozzle_temp_min"] = nozzle_temp_min;
j["print"]["nozzle_temp_max"] = nozzle_temp_max;
j["print"]["tray_type"] = tray_type;
return this->publish_json(j.dump());
}
int MachineObject::command_ams_refresh_rfid(std::string tray_id)
{
std::string gcode_cmd = (boost::format("M620 R%1% \n") % tray_id).str();
BOOST_LOG_TRIVIAL(trace) << "ams_debug: gcode_cmd" << gcode_cmd;
return this->publish_gcode(gcode_cmd);
}
int MachineObject::command_ams_select_tray(std::string tray_id)
{
std::string gcode_cmd = (boost::format("M620 P%1% \n") % tray_id).str();
BOOST_LOG_TRIVIAL(trace) << "ams_debug: gcode_cmd" << gcode_cmd;
return this->publish_gcode(gcode_cmd);
}
int MachineObject::command_ams_control(std::string action)
{
//valid actions
if (action == "resume" || action == "reset" || action == "pause" || action == "done") {
json j;
j["print"]["command"] = "ams_control";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["param"] = action;
return this->publish_json(j.dump());
}
return -1;
}
int MachineObject::command_set_chamber_light(LIGHT_EFFECT effect, int on_time, int off_time, int loops, int interval)
{
json j;
j["system"]["command"] = "ledctrl";
j["system"]["led_node"] = "chamber_light";
j["system"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["system"]["led_mode"] = light_effect_str(effect);
j["system"]["led_on_time"] = on_time;
j["system"]["led_off_time"] = off_time;
j["system"]["loop_times"] = loops;
j["system"]["interval_time"] = interval;
return this->publish_json(j.dump());
}
int MachineObject::command_set_printer_nozzle(std::string nozzle_type, float diameter)
{
nozzle_setting_hold_count = HOLD_COUNT_MAX * 2;
BOOST_LOG_TRIVIAL(info) << "command_set_printer_nozzle, nozzle_type = " << nozzle_type << " diameter = " << diameter;
json j;
j["system"]["command"] = "set_accessories";
j["system"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["system"]["accessory_type"] = "nozzle";
j["system"]["nozzle_type"] = nozzle_type;
j["system"]["nozzle_diameter"] = diameter;
return this->publish_json(j.dump());
}
int MachineObject::command_set_work_light(LIGHT_EFFECT effect, int on_time, int off_time, int loops, int interval)
{
json j;
j["system"]["command"] = "ledctrl";
j["system"]["led_node"] = "work_light";
j["system"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["system"]["led_mode"] = light_effect_str(effect);
j["system"]["led_on_time"] = on_time;
j["system"]["led_off_time"] = off_time;
j["system"]["loop_times"] = loops;
j["system"]["interval_time"] = interval;
return this->publish_json(j.dump());
}
int MachineObject::command_start_extrusion_cali(int tray_index, int nozzle_temp, int bed_temp, float max_volumetric_speed, std::string setting_id)
{
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali: tray_id = " << tray_index << ", nozzle_temp = " << nozzle_temp << ", bed_temp = " << bed_temp
<< ", max_volumetric_speed = " << max_volumetric_speed;
json j;
j["print"]["command"] = "extrusion_cali";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["tray_id"] = tray_index;
//j["print"]["setting_id"] = setting_id;
//j["print"]["name"] = "";
j["print"]["nozzle_temp"] = nozzle_temp;
j["print"]["bed_temp"] = bed_temp;
j["print"]["max_volumetric_speed"] = max_volumetric_speed;
// enter extusion cali
last_extrusion_cali_start_time = std::chrono::system_clock::now();
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali: " << j.dump();
return this->publish_json(j.dump());
}
int MachineObject::command_stop_extrusion_cali()
{
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali: stop";
if (is_in_extrusion_cali()) {
return command_task_abort();
}
return 0;
}
int MachineObject::command_extrusion_cali_set(int tray_index, std::string setting_id, std::string name, float k, float n, int bed_temp, int nozzle_temp, float max_volumetric_speed)
{
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali: tray_id = " << tray_index << ", setting_id = " << setting_id << ", k = " << k
<< ", n = " << n;
json j;
j["print"]["command"] = "extrusion_cali_set";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["tray_id"] = tray_index;
//j["print"]["setting_id"] = setting_id;
//j["print"]["name"] = name;
j["print"]["k_value"] = k;
j["print"]["n_coef"] = 1.4f; // fixed n
//j["print"]["n_coef"] = n;
if (bed_temp >= 0 && nozzle_temp >= 0 && max_volumetric_speed >= 0) {
j["print"]["bed_temp"] = bed_temp;
j["print"]["nozzle_temp"] = nozzle_temp;
j["print"]["max_volumetric_speed"] = max_volumetric_speed;
}
return this->publish_json(j.dump());
}
int MachineObject::command_set_printing_speed(PrintingSpeedLevel lvl)
{
json j;
j["print"]["command"] = "print_speed";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["param"] = std::to_string((int)lvl);
return this->publish_json(j.dump());
}
int MachineObject::command_set_printing_option(bool auto_recovery)
{
int print_option = (int)auto_recovery << (int)PRINT_OP_AUTO_RECOVERY;
json j;
j["print"]["command"] = "print_option";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["option"] = print_option;
j["print"]["auto_recovery"] = auto_recovery;
return this->publish_json(j.dump());
}
int MachineObject::command_nozzle_blob_detect(bool nozzle_blob_detect)
{
json j;
j["print"]["command"] = "print_option";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["nozzle_blob_detect"] = nozzle_blob_detect;
nozzle_blob_detection_enabled = nozzle_blob_detect;
return this->publish_json(j.dump());
}
int MachineObject::command_set_prompt_sound(bool prompt_sound){
json j;
j["print"]["command"] = "print_option";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["sound_enable"] = prompt_sound;
return this->publish_json(j.dump());
}
int MachineObject::command_set_filament_tangle_detect(bool filament_tangle_detect) {
json j;
j["print"]["command"] = "print_option";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["filament_tangle_detect"] = filament_tangle_detect;
return this->publish_json(j.dump());
}
int MachineObject::command_ams_switch_filament(bool switch_filament)
{
json j;
j["print"]["command"] = "print_option";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["auto_switch_filament"] = switch_filament;
ams_auto_switch_filament_flag = switch_filament;
BOOST_LOG_TRIVIAL(trace) << "command_ams_filament_settings:" << switch_filament;
ams_print_option_count = HOLD_COUNT_MAX;
return this->publish_json(j.dump());
}
int MachineObject::command_ams_air_print_detect(bool air_print_detect)
{
json j;
j["print"]["command"] = "print_option";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["air_print_detect"] = air_print_detect;
ams_air_print_status = air_print_detect;
BOOST_LOG_TRIVIAL(trace) << "command_ams_air_print_detect:" << air_print_detect;
return this->publish_json(j.dump());
}
int MachineObject::command_axis_control(std::string axis, double unit, double input_val, int speed)
{
double value = input_val;
if (!is_core_xy()) {
if ( axis.compare("Y") == 0
|| axis.compare("Z") == 0) {
value = -1.0 * input_val;
}
}
char cmd[256];
if (axis.compare("X") == 0
|| axis.compare("Y") == 0
|| axis.compare("Z") == 0) {
sprintf(cmd, "M211 S \nM211 X1 Y1 Z1\nM1002 push_ref_mode\nG91 \nG1 %s%0.1f F%d\nM1002 pop_ref_mode\nM211 R\n", axis.c_str(), value * unit, speed);
}
else if (axis.compare("E") == 0) {
sprintf(cmd, "M83 \nG0 %s%0.1f F%d\n", axis.c_str(), value * unit, speed);
extruder_axis_status = (value >= 0.0f)? LOAD : UNLOAD;
}
else {
return -1;
}
return this->publish_gcode(cmd);
}
bool MachineObject::is_support_command_calibration()
{
if (get_printer_series() == PrinterSeries::SERIES_X1) {
auto ap_ver_it = module_vers.find("rv1126");
if (ap_ver_it != module_vers.end()) {
if (ap_ver_it->second.sw_ver.compare("00.00.15.79") < 0)
return false;
}
}
return true;
}
int MachineObject::command_start_calibration(bool vibration, bool bed_leveling, bool xcam_cali, bool motor_noise)
{
if (!is_support_command_calibration()) {
// fixed gcode file
json j;
j["print"]["command"] = "gcode_file";
j["print"]["param"] = "/usr/etc/print/auto_cali_for_user.gcode";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
return this->publish_json(j.dump());
} else {
json j;
j["print"]["command"] = "calibration";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["option"]= (motor_noise ? 1 << 3 : 0)
+ (vibration ? 1 << 2 : 0)
+ (bed_leveling ? 1 << 1 : 0)
+ (xcam_cali ? 1 << 0 : 0);
return this->publish_json(j.dump());
}
}
int MachineObject::command_start_pa_calibration(const X1CCalibInfos &pa_data, int mode)
{
CNumericLocalesSetter locales_setter;
pa_calib_results.clear();
json j;
j["print"]["command"] = "extrusion_cali";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(pa_data.calib_datas[0].nozzle_diameter);
j["print"]["mode"] = mode;
std::string filament_ids;
for (int i = 0; i < pa_data.calib_datas.size(); ++i) {
j["print"]["filaments"][i]["tray_id"] = pa_data.calib_datas[i].tray_id;
j["print"]["filaments"][i]["bed_temp"] = pa_data.calib_datas[i].bed_temp;
j["print"]["filaments"][i]["filament_id"] = pa_data.calib_datas[i].filament_id;
j["print"]["filaments"][i]["setting_id"] = pa_data.calib_datas[i].setting_id;
j["print"]["filaments"][i]["nozzle_temp"] = pa_data.calib_datas[i].nozzle_temp;
j["print"]["filaments"][i]["max_volumetric_speed"] = std::to_string(pa_data.calib_datas[i].max_volumetric_speed);
if (i > 0) filament_ids += ",";
filament_ids += pa_data.calib_datas[i].filament_id;
}
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali: " << j.dump();
try {
json js;
js["cali_type"] = "cali_pa_auto";
js["nozzle_diameter"] = pa_data.calib_datas[0].nozzle_diameter;
js["filament_id"] = filament_ids;
js["printer_type"] = this->printer_type;
NetworkAgent *agent = GUI::wxGetApp().getAgent();
if (agent) agent->track_event("cali", js.dump());
} catch (...) {}
return this->publish_json(j.dump());
}
int MachineObject::command_set_pa_calibration(const std::vector<PACalibResult> &pa_calib_values, bool is_auto_cali)
{
CNumericLocalesSetter locales_setter;
if (pa_calib_values.size() > 0) {
json j;
j["print"]["command"] = "extrusion_cali_set";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(pa_calib_values[0].nozzle_diameter);
for (int i = 0; i < pa_calib_values.size(); ++i) {
if (pa_calib_values[i].tray_id >= 0)
j["print"]["filaments"][i]["tray_id"] = pa_calib_values[i].tray_id;
if (pa_calib_values[i].cali_idx >= 0)
j["print"]["filaments"][i]["cali_idx"] = pa_calib_values[i].cali_idx;
j["print"]["filaments"][i]["tray_id"] = pa_calib_values[i].tray_id;
j["print"]["filaments"][i]["filament_id"] = pa_calib_values[i].filament_id;
j["print"]["filaments"][i]["setting_id"] = pa_calib_values[i].setting_id;
j["print"]["filaments"][i]["name"] = pa_calib_values[i].name;
j["print"]["filaments"][i]["k_value"] = std::to_string(pa_calib_values[i].k_value);
if (is_auto_cali)
j["print"]["filaments"][i]["n_coef"] = std::to_string(pa_calib_values[i].n_coef);
else
j["print"]["filaments"][i]["n_coef"] = "0.0";
}
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali_set: " << j.dump();
return this->publish_json(j.dump());
}
return -1;
}
int MachineObject::command_delete_pa_calibration(const PACalibIndexInfo& pa_calib)
{
json j;
j["print"]["command"] = "extrusion_cali_del";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["filament_id"] = pa_calib.filament_id;
j["print"]["cali_idx"] = pa_calib.cali_idx;
j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(pa_calib.nozzle_diameter);
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali_del: " << j.dump();
return this->publish_json(j.dump());
}
int MachineObject::command_get_pa_calibration_tab(float nozzle_diameter, const std::string &filament_id)
{
reset_pa_cali_history_result();
json j;
j["print"]["command"] = "extrusion_cali_get";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["filament_id"] = filament_id;
j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(nozzle_diameter);
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali_get: " << j.dump();
return this->publish_json(j.dump());
}
int MachineObject::command_get_pa_calibration_result(float nozzle_diameter)
{
json j;
j["print"]["command"] = "extrusion_cali_get_result";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(nozzle_diameter);
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali_get_result: " << j.dump();
return this->publish_json(j.dump());
}
int MachineObject::commnad_select_pa_calibration(const PACalibIndexInfo& pa_calib_info)
{
json j;
j["print"]["command"] = "extrusion_cali_sel";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["tray_id"] = pa_calib_info.tray_id;
j["print"]["cali_idx"] = pa_calib_info.cali_idx;
j["print"]["filament_id"] = pa_calib_info.filament_id;
j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(pa_calib_info.nozzle_diameter);
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali_sel: " << j.dump();
return this->publish_json(j.dump());
}
int MachineObject::command_start_flow_ratio_calibration(const X1CCalibInfos& calib_data)
{
CNumericLocalesSetter locales_setter;
if (calib_data.calib_datas.size() > 0) {
json j;
j["print"]["command"] = "flowrate_cali";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["tray_id"] = calib_data.calib_datas[0].tray_id;
j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(calib_data.calib_datas[0].nozzle_diameter);
std::string filament_ids;
for (int i = 0; i < calib_data.calib_datas.size(); ++i) {
j["print"]["filaments"][i]["tray_id"] = calib_data.calib_datas[i].tray_id;
j["print"]["filaments"][i]["bed_temp"] = calib_data.calib_datas[i].bed_temp;
j["print"]["filaments"][i]["filament_id"] = calib_data.calib_datas[i].filament_id;
j["print"]["filaments"][i]["setting_id"] = calib_data.calib_datas[i].setting_id;
j["print"]["filaments"][i]["nozzle_temp"] = calib_data.calib_datas[i].nozzle_temp;
j["print"]["filaments"][i]["def_flow_ratio"] = std::to_string(calib_data.calib_datas[i].flow_rate);
j["print"]["filaments"][i]["max_volumetric_speed"] = std::to_string(calib_data.calib_datas[i].max_volumetric_speed);
if (i > 0)
filament_ids += ",";
filament_ids += calib_data.calib_datas[i].filament_id;
}
BOOST_LOG_TRIVIAL(trace) << "flowrate_cali: " << j.dump();
return this->publish_json(j.dump());
}
return -1;
}
int MachineObject::command_get_flow_ratio_calibration_result(float nozzle_diameter)
{
json j;
j["print"]["command"] = "flowrate_get_result";
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(nozzle_diameter);
BOOST_LOG_TRIVIAL(trace) << "flowrate_get_result: " << j.dump();
return this->publish_json(j.dump());
}
int MachineObject::command_ipcam_record(bool on_off)
{
BOOST_LOG_TRIVIAL(info) << "command_ipcam_record = " << on_off;
json j;
j["camera"]["command"] = "ipcam_record_set";
j["camera"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["camera"]["control"] = on_off ? "enable" : "disable";
camera_recording_hold_count = HOLD_COUNT_CAMERA;
this->camera_recording_when_printing = on_off;
return this->publish_json(j.dump());
}
int MachineObject::command_ipcam_timelapse(bool on_off)
{
BOOST_LOG_TRIVIAL(info) << "command_ipcam_timelapse " << on_off;
json j;
j["camera"]["command"] = "ipcam_timelapse";
j["camera"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["camera"]["control"] = on_off ? "enable" : "disable";
camera_timelapse_hold_count = HOLD_COUNT_CAMERA;
this->camera_timelapse = on_off;
return this->publish_json(j.dump());
}
int MachineObject::command_ipcam_resolution_set(std::string resolution)
{
BOOST_LOG_TRIVIAL(info) << "command:ipcam_resolution_set" << ", resolution:" << resolution;
json j;
j["camera"]["command"] = "ipcam_resolution_set";
j["camera"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["camera"]["resolution"] = resolution;
camera_resolution_hold_count = HOLD_COUNT_CAMERA;
camera_recording_hold_count = HOLD_COUNT_CAMERA;
this->camera_resolution = resolution;
return this->publish_json(j.dump());
}
int MachineObject::command_xcam_control(std::string module_name, bool on_off, std::string lvl)
{
json j;
j["xcam"]["command"] = "xcam_control_set";
j["xcam"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
j["xcam"]["module_name"] = module_name;
j["xcam"]["control"] = on_off;
j["xcam"]["enable"] = on_off; //old protocol
j["xcam"]["print_halt"] = true; //old protocol
if (!lvl.empty()) {
j["xcam"]["halt_print_sensitivity"] = lvl;
}
BOOST_LOG_TRIVIAL(info) << "command:xcam_control_set" << ", module_name:" << module_name << ", control:" << on_off << ", halt_print_sensitivity:" << lvl;
return this->publish_json(j.dump());
}
int MachineObject::command_xcam_control_ai_monitoring(bool on_off, std::string lvl)
{
bool print_halt = (lvl == "never_halt") ? false:true;
xcam_ai_monitoring = on_off;
xcam_ai_monitoring_hold_count = HOLD_COUNT_MAX;
xcam_ai_monitoring_sensitivity = lvl;
return command_xcam_control("printing_monitor", on_off, lvl);
}
int MachineObject::command_xcam_control_buildplate_marker_detector(bool on_off)
{
xcam_buildplate_marker_detector = on_off;
xcam_buildplate_marker_hold_count = HOLD_COUNT_MAX;
return command_xcam_control("buildplate_marker_detector", on_off);
}
int MachineObject::command_xcam_control_first_layer_inspector(bool on_off, bool print_halt)
{
xcam_first_layer_inspector = on_off;
xcam_first_layer_hold_count = HOLD_COUNT_MAX;
return command_xcam_control("first_layer_inspector", on_off);
}
int MachineObject::command_xcam_control_auto_recovery_step_loss(bool on_off)
{
xcam_auto_recovery_step_loss = on_off;
xcam_auto_recovery_hold_count = HOLD_COUNT_MAX;
return command_set_printing_option(on_off);
}
int MachineObject::command_xcam_control_allow_prompt_sound(bool on_off)
{
xcam_allow_prompt_sound = on_off;
xcam_prompt_sound_hold_count = HOLD_COUNT_MAX;
return command_set_prompt_sound(on_off);
}
int MachineObject::command_xcam_control_filament_tangle_detect(bool on_off)
{
xcam_filament_tangle_detect = on_off;
xcam_filament_tangle_detect_count = HOLD_COUNT_MAX;
return command_set_filament_tangle_detect(on_off);
}
void MachineObject::set_bind_status(std::string status)
{
bind_user_name = status;
}
std::string MachineObject::get_bind_str()
{
std::string default_result = "N/A";
if (bind_user_name.compare("null") == 0) {
return "Free";
}
else if (!bind_user_name.empty()) {
return bind_user_name;
}
return default_result;
}
bool MachineObject::can_print()
{
if (print_status.compare("RUNNING") == 0) {
return false;
}
if (print_status.compare("IDLE") == 0 || print_status.compare("FINISH") == 0) {
return true;
}
return true;
}
bool MachineObject::can_resume()
{
if (print_status.compare("PAUSE") == 0)
return true;
return false;
}
bool MachineObject::can_pause()
{
if (print_status.compare("RUNNING") == 0)
return true;
return false;
}
bool MachineObject::can_abort()
{
return MachineObject::is_in_printing_status(print_status);
}
bool MachineObject::is_in_printing_status(std::string status)
{
if (status.compare("PAUSE") == 0
|| status.compare("RUNNING") == 0
|| status.compare("SLICING") == 0
|| status.compare("PREPARE") == 0) {
return true;
}
return false;
}
bool MachineObject::is_in_printing()
{
/* use print_status if print_status is valid */
if (!print_status.empty())
return MachineObject::is_in_printing_status(print_status);
else {
return MachineObject::is_in_printing_status(iot_print_status);
}
return false;
}
bool MachineObject::is_in_prepare()
{
return print_status == "PREPARE";
}
bool MachineObject::is_printing_finished()
{
if (print_status.compare("FINISH") == 0
|| print_status.compare("FAILED") == 0) {
return true;
}
return false;
}
bool MachineObject::is_core_xy()
{
if (get_printer_arch() == PrinterArch::ARCH_CORE_XY)
return true;
return false;
}
void MachineObject::reset_update_time()
{
BOOST_LOG_TRIVIAL(trace) << "reset reset_update_time, dev_id =" << dev_id;
last_update_time = std::chrono::system_clock::now();
subscribe_counter = 3;
}
void MachineObject::reset()
{
BOOST_LOG_TRIVIAL(trace) << "reset dev_id=" << dev_id;
last_update_time = std::chrono::system_clock::now();
m_push_count = 0;
is_220V_voltage = false;
get_version_retry = 0;
camera_recording = false;
camera_recording_when_printing = false;
camera_timelapse = false;
//camera_resolution = "";
printing_speed_mag = 100;
gcode_file_prepare_percent = 0;
iot_print_status = "";
print_status = "";
last_mc_print_stage = -1;
m_new_ver_list_exist = false;
extruder_axis_status = LOAD;
nozzle_diameter = 0.0f;
network_wired = false;
dev_connection_name = "";
subscribe_counter = 3;
job_id_ = "";
m_plate_index = -1;
// reset print_json
json empty_j;
print_json.diff2all_base_reset(empty_j);
vt_tray.reset();
subtask_ = nullptr;
}
void MachineObject::set_print_state(std::string status)
{
print_status = status;
}
int MachineObject::connect(bool is_anonymous, bool use_openssl)
{
if (dev_ip.empty()) return -1;
std::string username;
std::string password;
if (!is_anonymous) {
username = "bblp";
password = get_access_code();
}
if (m_agent) {
try {
return m_agent->connect_printer(dev_id, dev_ip, username, password, use_openssl);
} catch (...) {
;
}
}
return -1;
}
int MachineObject::disconnect()
{
if (m_agent) {
return m_agent->disconnect_printer();
}
return -1;
}
bool MachineObject::is_connected()
{
std::chrono::system_clock::time_point curr_time = std::chrono::system_clock::now();
auto diff = std::chrono::duration_cast<std::chrono::milliseconds>(curr_time - last_update_time);
if (diff.count() > DISCONNECT_TIMEOUT) {
BOOST_LOG_TRIVIAL(trace) << "machine_object: dev_id=" << dev_id <<", diff count = " << diff.count();
return false;
}
if (!is_lan_mode_printer()) {
NetworkAgent* m_agent = Slic3r::GUI::wxGetApp().getAgent();
if (m_agent) {
return m_agent->is_server_connected();
}
}
return true;
}
bool MachineObject::is_connecting()
{
return is_connected() && m_push_count == 0;
}
void MachineObject::set_online_state(bool on_off)
{
m_is_online = on_off;
if (!on_off) m_active_state = NotActive;
}
bool MachineObject::is_info_ready()
{
if (module_vers.empty())
return false;
std::chrono::system_clock::time_point curr_time = std::chrono::system_clock::now();
auto diff = std::chrono::duration_cast<std::chrono::microseconds>(last_push_time - curr_time);
if (m_push_count > 0 && diff.count() < PUSHINFO_TIMEOUT) {
return true;
}
return false;
}
std::vector<std::string> MachineObject::get_resolution_supported()
{
return camera_resolution_supported;
}
std::vector<std::string> MachineObject::get_compatible_machine()
{
return DeviceManager::get_compatible_machine(printer_type);
}
bool MachineObject::is_camera_busy_off()
{
if (get_printer_series() == PrinterSeries::SERIES_P1P)
return is_in_prepare() || is_in_upgrading();
return false;
}
int MachineObject::publish_json(std::string json_str, int qos)
{
if (is_lan_mode_printer()) {
return local_publish_json(json_str, qos);
} else {
return cloud_publish_json(json_str, qos);
}
}
int MachineObject::cloud_publish_json(std::string json_str, int qos)
{
int result = -1;
if (m_agent)
result = m_agent->send_message(dev_id, json_str, qos);
return result;
}
int MachineObject::local_publish_json(std::string json_str, int qos)
{
int result = -1;
if (m_agent) {
result = m_agent->send_message_to_printer(dev_id, json_str, qos);
}
return result;
}
std::string MachineObject::setting_id_to_type(std::string setting_id, std::string tray_type)
{
std::string type;
PresetBundle* preset_bundle = GUI::wxGetApp().preset_bundle;
if (preset_bundle) {
for (auto it = preset_bundle->filaments.begin(); it != preset_bundle->filaments.end(); it++) {
if (it->filament_id.compare(setting_id) == 0 && it->is_system) {
std::string display_filament_type;
it->config.get_filament_type(display_filament_type);
type = display_filament_type;
break;
}
}
}
if (tray_type != type || type.empty()) {
if (type.empty()) { type = tray_type; }
BOOST_LOG_TRIVIAL(info) << "The values of tray_info_idx and tray_type do not match tray_info_idx " << setting_id << " tray_type " << tray_type << " system_type" << type;
}
return type;
}
template <class ENUM>
static ENUM enum_index_of(char const *key, char const **enum_names, int enum_count, ENUM defl = static_cast<ENUM>(0))
{
for (int i = 0; i < enum_count; ++i)
if (strcmp(enum_names[i], key) == 0) return static_cast<ENUM>(i);
return defl;
}
int MachineObject::parse_json(std::string payload, bool key_field_only)
{
parse_msg_count++;
std::chrono::system_clock::time_point clock_start = std::chrono::system_clock::now();
this->set_online_state(true);
std::chrono::system_clock::time_point curr_time = std::chrono::system_clock::now();
auto diff1 = std::chrono::duration_cast<std::chrono::microseconds>(curr_time - last_update_time);
/* update last received time */
last_update_time = std::chrono::system_clock::now();
try {
bool restored_json = false;
json j;
json j_pre = json::parse(payload);
CNumericLocalesSetter locales_setter;
if (j_pre.empty()) {
return 0;
}
if (j_pre.contains("print")) {
if (m_active_state == NotActive) m_active_state = Active;
if (j_pre["print"].contains("command")) {
if (j_pre["print"]["command"].get<std::string>() == "push_status") {
if (j_pre["print"].contains("msg")) {
if (j_pre["print"]["msg"].get<int>() == 0) { //all message
BOOST_LOG_TRIVIAL(trace) << "static: get push_all msg, dev_id=" << dev_id;
m_push_count++;
if (!printer_type.empty())
print_json.load_compatible_settings(printer_type, "");
print_json.diff2all_base_reset(j_pre);
} else if (j_pre["print"]["msg"].get<int>() == 1) { //diff message
if (print_json.diff2all(j_pre, j) == 0) {
restored_json = true;
} else {
BOOST_LOG_TRIVIAL(trace) << "parse_json: restore failed! count = " << parse_msg_count;
if (print_json.is_need_request()) {
BOOST_LOG_TRIVIAL(trace) << "parse_json: need request pushall, count = " << parse_msg_count;
// request new push
GUI::wxGetApp().CallAfter([this]{
this->command_request_push_all();
});
return -1;
}
return -1;
}
} else {
BOOST_LOG_TRIVIAL(warning) << "unsupported msg_type=" << j_pre["print"]["msg"].get<std::string>();
}
}
else {
if (!printer_type.empty() && connection_type() == "lan")
print_json.load_compatible_settings(printer_type, "");
print_json.diff2all_base_reset(j_pre);
}
}
}
}
if (j_pre.contains("system")) {
if (j_pre["system"].contains("command")) {
if (j_pre["system"]["command"].get<std::string>() == "get_access_code") {
if (j_pre["system"].contains("access_code")) {
std::string access_code = j_pre["system"]["access_code"].get<std::string>();
if (!access_code.empty()) {
set_access_code(access_code);
set_user_access_code(access_code);
}
}
}
}
}
if (!restored_json) {
j = j_pre;
}
uint64_t t_utc = j.value("t_utc", 0ULL);
if (t_utc > 0) {
last_utc_time = std::chrono::system_clock::time_point(t_utc * 1ms);
std::chrono::system_clock::time_point now = std::chrono::system_clock::now();
auto millisec_since_epoch = std::chrono::duration_cast<std::chrono::milliseconds>(now.time_since_epoch()).count();
auto delay = millisec_since_epoch - t_utc; //ms
std::string message_type = is_lan_mode_printer() ? "Local Mqtt" : is_tunnel_mqtt ? "Tunnel Mqtt" : "Cloud Mqtt";
if (!message_delay.empty()) {
const auto& [first_type, first_time_stamp, first_delay] = message_delay.front();
const auto& [last_type, last_time_stap, last_delay] = message_delay.back();
BOOST_LOG_TRIVIAL(debug) << __FUNCTION__ << ", message delay, last time stamp: " << last_time_stap;
if (last_time_stap - first_time_stamp >= MINUTE_30) {
// record, excluding current data
int total = message_delay.size();
int local_mqtt = 0;
int tunnel_mqtt = 0;
int cloud_mqtt = 0;
int local_mqtt_timeout = 0;
int tunnel_mqtt_timeout = 0;
int cloud_mqtt_timeout = 0;
for (const auto& [type, time_stamp, delay] : message_delay) {
if (type == "Local Mqtt") {
local_mqtt++;
if (delay >= TIME_OUT) {
local_mqtt_timeout++;
}
}
else if (type == "Tunnel Mqtt") {
tunnel_mqtt++;
if (delay >= TIME_OUT) {
tunnel_mqtt_timeout++;
}
}
else if (type == "Cloud Mqtt"){
cloud_mqtt++;
if (delay >= TIME_OUT) {
cloud_mqtt_timeout++;
}
}
}
BOOST_LOG_TRIVIAL(debug) << __FUNCTION__ << ", message delay, message total: " << total;
try {
if (m_agent) {
json j_message;
// Convert timestamp to time
std::time_t t = time_t(last_time_stap / 1000); //s
std::tm* now_tm = std::localtime(&t);
char buffer[80];
std::strftime(buffer, sizeof(buffer), "%Y-%m-%d %H:%M:%S", now_tm);
std::string time_str = std::string(buffer);
j_message["time"] = time_str;
j_message["total"] = total;
j_message["local_mqtt"] = std::to_string(local_mqtt_timeout) + "/" + std::to_string(local_mqtt);
j_message["tunnel_mqtt"] = std::to_string(tunnel_mqtt_timeout) + "/" + std::to_string(tunnel_mqtt);
j_message["cloud_mqtt"] = std::to_string(cloud_mqtt_timeout) + "/" + std::to_string(cloud_mqtt);
m_agent->track_event("message_delay", j_message.dump());
}
}
catch (...) {}
message_delay.clear();
message_delay.shrink_to_fit();
}
}
message_delay.push_back(std::make_tuple(message_type, t_utc, delay));
}
else
last_utc_time = last_update_time;
BOOST_LOG_TRIVIAL(trace) << "parse_json: dev_id=" << dev_id << ", playload=" << j.dump(4);
// Parse version info first, as if version arrive or change, 'print' need parse again with new compatible settings
try {
if (j.contains("info")) {
if (j["info"].contains("command") && j["info"]["command"].get<std::string>() == "get_version") {
json j_module = j["info"]["module"];
module_vers.clear();
for (auto it = j_module.begin(); it != j_module.end(); it++) {
ModuleVersionInfo ver_info;
ver_info.name = (*it)["name"].get<std::string>();
if ((*it).contains("sw_ver"))
ver_info.sw_ver = (*it)["sw_ver"].get<std::string>();
if ((*it).contains("sn"))
ver_info.sn = (*it)["sn"].get<std::string>();
if ((*it).contains("hw_ver"))
ver_info.hw_ver = (*it)["hw_ver"].get<std::string>();
if((*it).contains("flag"))
ver_info.firmware_status= (*it)["flag"].get<int>();
module_vers.emplace(ver_info.name, ver_info);
if (ver_info.name == "ota") {
NetworkAgent* agent = GUI::wxGetApp().getAgent();
if (agent) {
std::string dev_ota_str = "dev_ota_ver:" + this->dev_id;
agent->track_update_property(dev_ota_str, ver_info.sw_ver);
}
}
}
parse_version_func();
bool get_version_result = true;
if (j["info"].contains("result"))
if (j["info"]["result"].get<std::string>() == "fail")
get_version_result = false;
if ((!check_version_valid() && get_version_retry-- >= 0)
&& get_version_result) {
BOOST_LOG_TRIVIAL(info) << "get_version_retry = " << get_version_retry;
boost::thread retry = boost::thread([this] {
boost::this_thread::sleep_for(boost::chrono::milliseconds(RETRY_INTERNAL));
GUI::wxGetApp().CallAfter([this] {
this->command_get_version(false);
});
});
}
}
std::string version = parse_version();
if (!version.empty() && print_json.load_compatible_settings(printer_type, version)) {
// reload because compatible settings changed
j.clear();
print_json.diff2all(json{}, j);
}
}
} catch (...) {}
if (j.contains("print")) {
json jj = j["print"];
int sequence_id = 0;
if (jj.contains("sequence_id")) {
if (jj["sequence_id"].is_string()) {
std::string str_seq = jj["sequence_id"].get<std::string>();
try {
sequence_id = stoi(str_seq);
}
catch(...) {
;
}
}
}
if (!key_field_only) {
if (!DeviceManager::EnableMultiMachine && !is_support_agora) {
if (jj.contains("support_tunnel_mqtt")) {
if (jj["support_tunnel_mqtt"].is_boolean()) {
is_support_tunnel_mqtt = jj["support_tunnel_mqtt"].get<bool>();
}
}
}
//supported function
if (jj.contains("support_chamber_temp_edit")) {
if (jj["support_chamber_temp_edit"].is_boolean()) {
is_support_chamber_edit = jj["support_chamber_temp_edit"].get<bool>();
}
}
if (jj.contains("support_extrusion_cali")) {
if (jj["support_extrusion_cali"].is_boolean()) {
is_support_extrusion_cali = jj["support_extrusion_cali"].get<bool>();
}
}
if (jj.contains("support_first_layer_inspect")) {
if (jj["support_first_layer_inspect"].is_boolean()) {
is_support_first_layer_inspect = jj["support_first_layer_inspect"].get<bool>();
}
}
if (jj.contains("support_ai_monitoring")) {
if (jj["support_ai_monitoring"].is_boolean()) {
is_support_ai_monitoring = jj["support_ai_monitoring"].get<bool>();
}
}
if (jj.contains("support_lidar_calibration")) {
if (jj["support_lidar_calibration"].is_boolean()) {
is_support_lidar_calibration = jj["support_lidar_calibration"].get<bool>();
}
}
if (jj.contains("support_build_plate_marker_detect")) {
if (jj["support_build_plate_marker_detect"].is_boolean()) {
is_support_build_plate_marker_detect = jj["support_build_plate_marker_detect"].get<bool>();
}
}
if (jj.contains("support_flow_calibration")) {
if (jj["support_flow_calibration"].is_boolean()) {
is_support_flow_calibration = jj["support_flow_calibration"].get<bool>();
}
}
if (jj.contains("support_print_without_sd")) {
if (jj["support_print_without_sd"].is_boolean()) {
is_support_print_without_sd = jj["support_print_without_sd"].get<bool>();
}
}
if (jj.contains("support_print_all")) {
if (jj["support_print_all"].is_boolean()) {
is_support_print_all = jj["support_print_all"].get<bool>();
}
}
if (jj.contains("support_send_to_sd")) {
if (jj["support_send_to_sd"].is_boolean()) {
is_support_send_to_sdcard = jj["support_send_to_sd"].get<bool>();
}
}
if (jj.contains("support_aux_fan")) {
if (jj["support_aux_fan"].is_boolean()) {
is_support_aux_fan = jj["support_aux_fan"].get<bool>();
}
}
if (jj.contains("support_chamber_fan")) {
if (jj["support_chamber_fan"].is_boolean()) {
is_support_chamber_fan = jj["support_chamber_fan"].get<bool>();
}
}
if (jj.contains("support_filament_backup")) {
if (jj["support_filament_backup"].is_boolean()) {
is_support_filament_backup = jj["support_filament_backup"].get<bool>();
}
}
if (jj.contains("support_update_remain")) {
if (jj["support_update_remain"].is_boolean()) {
is_support_update_remain = jj["support_update_remain"].get<bool>();
}
}
if (jj.contains("support_auto_leveling")) {
if (jj["support_auto_leveling"].is_boolean()) {
is_support_auto_leveling = jj["support_auto_leveling"].get<bool>();
}
}
if (jj.contains("support_auto_recovery_step_loss")) {
if (jj["support_auto_recovery_step_loss"].is_boolean()) {
is_support_auto_recovery_step_loss = jj["support_auto_recovery_step_loss"].get<bool>();
}
}
if (jj.contains("support_ams_humidity")) {
if (jj["support_ams_humidity"].is_boolean()) {
is_support_ams_humidity = jj["support_ams_humidity"].get<bool>();
}
}
if (jj.contains("support_prompt_sound")) {
if (jj["support_prompt_sound"].is_boolean()) {
is_support_prompt_sound = jj["support_prompt_sound"].get<bool>();
}
}
//if (jj.contains("support_filament_tangle_detect")) {
// if (jj["support_filament_tangle_detect"].is_boolean()) {
// is_support_filament_tangle_detect = jj["support_filament_tangle_detect"].get<bool>();
// }
//}
if (jj.contains("support_1080dpi")) {
if (jj["support_1080dpi"].is_boolean()) {
is_support_1080dpi = jj["support_1080dpi"].get<bool>();
}
}
if (jj.contains("support_cloud_print_only")) {
if (jj["support_cloud_print_only"].is_boolean()) {
is_support_cloud_print_only = jj["support_cloud_print_only"].get<bool>();
}
}
if (jj.contains("support_command_ams_switch")) {
if (jj["support_command_ams_switch"].is_boolean()) {
is_support_command_ams_switch = jj["support_command_ams_switch"].get<bool>();
}
}
if (jj.contains("support_mqtt_alive")) {
if (jj["support_mqtt_alive"].is_boolean()) {
is_support_mqtt_alive = jj["support_mqtt_alive"].get<bool>();
}
}
if (jj.contains("support_motor_noise_cali")) {
if (jj["support_motor_noise_cali"].is_boolean()) {
is_support_motor_noise_cali = jj["support_motor_noise_cali"].get<bool>();
}
}
if (jj.contains("support_timelapse")) {
if (jj["support_timelapse"].is_boolean()) {
is_support_timelapse = jj["support_timelapse"].get<bool>();
}
}
if (jj.contains("support_user_preset")) {
if (jj["support_user_preset"].is_boolean()) {
is_support_user_preset = jj["support_user_preset"].get<bool>();
}
}
if (jj.contains("nozzle_max_temperature")) {
if (jj["nozzle_max_temperature"].is_number_integer()) {
nozzle_max_temperature = jj["nozzle_max_temperature"].get<int>();
}
}
if (jj.contains("bed_temperature_limit")) {
if (jj["bed_temperature_limit"].is_number_integer()) {
bed_temperature_limit = jj["bed_temperature_limit"].get<int>();
}
}
}
if (jj.contains("command")) {
if (jj["command"].get<std::string>() == "ams_change_filament") {
if (jj.contains("errno")) {
if (jj["errno"].is_number()) {
if (jj["errno"].get<int>() == -2) {
wxString text = _L("The current chamber temperature or the target chamber temperature exceeds 45\u2103.In order to avoid extruder clogging,low temperature filament(PLA/PETG/TPU) is not allowed to be loaded.");
GUI::wxGetApp().push_notification(text);
}
}
}
}
if (jj["command"].get<std::string>() == "set_ctt") {
if (m_agent && is_studio_cmd(sequence_id)) {
if (jj["errno"].is_number()) {
wxString text;
if (jj["errno"].get<int>() == -2) {
text = _L("Low temperature filament(PLA/PETG/TPU) is loaded in the extruder.In order to avoid extruder clogging,it is not allowed to set the chamber temperature above 45\u2103.");
}
else if (jj["errno"].get<int>() == -4) {
text = _L("When you set the chamber temperature below 40\u2103, the chamber temperature control will not be activated. And the target chamber temperature will automatically be set to 0\u2103.");
}
if(!text.empty()){
#if __WXOSX__
set_ctt_dlg(text);
#else
GUI::wxGetApp().push_notification(text);
#endif
}
}
}
}
if (jj["command"].get<std::string>() == "push_status") {
m_push_count++;
last_push_time = last_update_time;
#pragma region printing
// U0 firmware
if (jj.contains("print_type")) {
print_type = jj["print_type"].get<std::string>();
}
if (jj.contains("mc_percent")) {
if (jj["mc_percent"].is_string())
mc_print_percent = stoi(j["print"]["mc_percent"].get<std::string>());
else if (jj["mc_percent"].is_number_integer())
mc_print_percent = j["print"]["mc_percent"].get<int>();
}
if (jj.contains("mc_print_sub_stage")) {
if (jj["mc_print_sub_stage"].is_number_integer())
mc_print_sub_stage = j["print"]["mc_print_sub_stage"].get<int>();
}
/* printing */
if (jj.contains("mc_print_stage")) {
if (jj["mc_print_stage"].is_string())
mc_print_stage = atoi(jj["mc_print_stage"].get<std::string>().c_str());
if (jj["mc_print_stage"].is_number())
mc_print_stage = jj["mc_print_stage"].get<int>();
}
if (jj.contains("mc_print_error_code")) {
if (jj["mc_print_error_code"].is_number())
mc_print_error_code = jj["mc_print_error_code"].get<int>();
}
if (jj.contains("mc_remaining_time")) {
if (jj["mc_remaining_time"].is_string())
mc_left_time = stoi(j["print"]["mc_remaining_time"].get<std::string>()) * 60;
else if (jj["mc_remaining_time"].is_number_integer())
mc_left_time = j["print"]["mc_remaining_time"].get<int>() * 60;
}
if (jj.contains("print_error")) {
if (jj["print_error"].is_number())
print_error = jj["print_error"].get<int>();
}
if (!key_field_only) {
if (jj.contains("home_flag")) {
home_flag = jj["home_flag"].get<int>();
parse_status(home_flag);
}
if (jj.contains("hw_switch_state")) {
hw_switch_state = jj["hw_switch_state"].get<int>();
}
if (jj.contains("mc_print_line_number")) {
if (jj["mc_print_line_number"].is_string() && !jj["mc_print_line_number"].is_null())
mc_print_line_number = atoi(jj["mc_print_line_number"].get<std::string>().c_str());
}
}
if (!key_field_only) {
if (jj.contains("flag3")) {
int flag3 = jj["flag3"].get<int>();
//is_support_filament_setting_inprinting = get_flag_bits(flag3, 3);
}
}
if (!key_field_only) {
if (jj.contains("net")) {
if (jj["net"].contains("conf")) {
network_wired = (jj["net"]["conf"].get<int>() & (0x1)) != 0;
}
}
}
#pragma endregion
#pragma region online
if (!key_field_only) {
// parse online info
try {
if (jj.contains("online")) {
if (jj["online"].contains("ahb")) {
if (jj["online"]["ahb"].get<bool>()) {
online_ahb = true;
} else {
online_ahb = false;
}
}
if (jj["online"].contains("rfid")) {
if (jj["online"]["rfid"].get<bool>()) {
online_rfid = true;
} else {
online_rfid = false;
}
}
std::string str = jj.dump();
if (jj["online"].contains("version")) {
online_version = jj["online"]["version"].get<int>();
}
if (last_online_version != online_version) {
last_online_version = online_version;
GUI::wxGetApp().CallAfter([this] {
this->command_get_version();
});
}
}
} catch (...) {
;
}
}
#pragma endregion
#pragma region print_task
if (jj.contains("gcode_state")) {
this->set_print_state(jj["gcode_state"].get<std::string>());
}
if (jj.contains("job_id")) {
is_support_wait_sending_finish = true;
this->job_id_ = jj["job_id"].get<std::string>();
}
else {
is_support_wait_sending_finish = false;
}
if (jj.contains("subtask_name")) {
subtask_name = jj["subtask_name"].get<std::string>();
}
if (!key_field_only) {
if (jj.contains("printer_type")) {
printer_type = parse_printer_type(jj["printer_type"].get<std::string>());
}
if (jj.contains("layer_num")) {
curr_layer = jj["layer_num"].get<int>();
}
if (jj.contains("total_layer_num")) {
total_layers = jj["total_layer_num"].get<int>();
if (total_layers == 0)
is_support_layer_num = false;
else
is_support_layer_num = true;
}
else {
is_support_layer_num = false;
}
if (jj.contains("queue_number")) {
this->queue_number = jj["queue_number"].get<int>();
}
else {
this->queue_number = 0;
}
if (jj.contains("task_id")) {
this->task_id_ = jj["task_id"].get<std::string>();
}
if (jj.contains("gcode_file"))
this->m_gcode_file = jj["gcode_file"].get<std::string>();
if (jj.contains("gcode_file_prepare_percent")) {
std::string percent_str = jj["gcode_file_prepare_percent"].get<std::string>();
if (!percent_str.empty()) {
try {
this->gcode_file_prepare_percent = atoi(percent_str.c_str());
}
catch (...) {}
}
}
}
if (jj.contains("project_id")
&& jj.contains("profile_id")
&& jj.contains("subtask_id")
){
obj_subtask_id = jj["subtask_id"].get<std::string>();
int plate_index = -1;
/* parse local plate_index from task */
if (obj_subtask_id.compare("0") == 0 && jj["profile_id"].get<std::string>() != "0") {
if (jj.contains("gcode_file")) {
m_gcode_file = jj["gcode_file"].get<std::string>();
int idx_start = m_gcode_file.find_last_of("_") + 1;
int idx_end = m_gcode_file.find_last_of(".");
if (idx_start > 0 && idx_end > idx_start) {
try {
plate_index = atoi(m_gcode_file.substr(idx_start, idx_end - idx_start).c_str());
this->m_plate_index = plate_index;
}
catch (...) {
;
}
}
}
}
update_slice_info(jj["project_id"].get<std::string>(), jj["profile_id"].get<std::string>(), jj["subtask_id"].get<std::string>(), plate_index);
BBLSubTask* curr_task = get_subtask();
if (curr_task) {
curr_task->task_progress = mc_print_percent;
curr_task->printing_status = print_status;
curr_task->task_id = jj["subtask_id"].get<std::string>();
}
}
#pragma endregion
#pragma region status
if (!key_field_only) {
/* temperature */
if (jj.contains("bed_temper")) {
if (jj["bed_temper"].is_number()) {
bed_temp = jj["bed_temper"].get<float>();
}
}
if (jj.contains("bed_target_temper")) {
if (jj["bed_target_temper"].is_number()) {
bed_temp_target = jj["bed_target_temper"].get<float>();
}
}
if (jj.contains("frame_temper")) {
if (jj["frame_temper"].is_number()) {
frame_temp = jj["frame_temper"].get<float>();
}
}
if (jj.contains("nozzle_temper")) {
if (jj["nozzle_temper"].is_number()) {
nozzle_temp = jj["nozzle_temper"].get<float>();
}
}
if (jj.contains("nozzle_target_temper")) {
if (jj["nozzle_target_temper"].is_number()) {
nozzle_temp_target = jj["nozzle_target_temper"].get<float>();
}
}
if (jj.contains("chamber_temper")) {
if (jj["chamber_temper"].is_number()) {
chamber_temp = jj["chamber_temper"].get<float>();
}
}
if (jj.contains("ctt")) {
if (jj["ctt"].is_number()) {
chamber_temp_target = jj["ctt"].get<float>();
}
}
/* signals */
if (jj.contains("link_th_state"))
link_th = jj["link_th_state"].get<std::string>();
if (jj.contains("link_ams_state"))
link_ams = jj["link_ams_state"].get<std::string>();
if (jj.contains("wifi_signal"))
wifi_signal = jj["wifi_signal"].get<std::string>();
/* cooling */
if (jj.contains("fan_gear")) {
fan_gear = jj["fan_gear"].get<std::uint32_t>();
big_fan2_speed = (int)((fan_gear & 0x00FF0000) >> 16);
big_fan1_speed = (int)((fan_gear & 0x0000FF00) >> 8);
cooling_fan_speed = (int)((fan_gear & 0x000000FF) >> 0);
}
else {
if (jj.contains("cooling_fan_speed")) {
cooling_fan_speed = stoi(jj["cooling_fan_speed"].get<std::string>());
cooling_fan_speed = round(floor(cooling_fan_speed / float(1.5)) * float(25.5));
}
else {
cooling_fan_speed = 0;
}
if (jj.contains("big_fan1_speed")) {
big_fan1_speed = stoi(jj["big_fan1_speed"].get<std::string>());
big_fan1_speed = round( floor(big_fan1_speed / float(1.5)) * float(25.5) );
}
else {
big_fan1_speed = 0;
}
if (jj.contains("big_fan2_speed")) {
big_fan2_speed = stoi(jj["big_fan2_speed"].get<std::string>());
big_fan2_speed = round( floor(big_fan2_speed / float(1.5)) * float(25.5) );
}
else {
big_fan2_speed = 0;
}
}
if (jj.contains("heatbreak_fan_speed")) {
heatbreak_fan_speed = stoi(jj["heatbreak_fan_speed"].get<std::string>());
}
/* parse speed */
try {
if (jj.contains("spd_lvl")) {
printing_speed_lvl = (PrintingSpeedLevel)jj["spd_lvl"].get<int>();
}
if (jj.contains("spd_mag")) {
printing_speed_mag = jj["spd_mag"].get<int>();
}
if (jj.contains("heatbreak_fan_speed")) {
heatbreak_fan_speed = stoi(jj["heatbreak_fan_speed"].get<std::string>());
}
}
catch (...) {
;
}
}
try {
if (jj.contains("stg")) {
stage_list_info.clear();
if (jj["stg"].is_array()) {
for (auto it = jj["stg"].begin(); it != jj["stg"].end(); it++) {
for (auto kv = (*it).begin(); kv != (*it).end(); kv++) {
stage_list_info.push_back(kv.value().get<int>());
}
}
}
}
if (jj.contains("stg_cur")) {
stage_curr = jj["stg_cur"].get<int>();
}
}
catch (...) {
;
}
if (!key_field_only) {
/*get filam_bak*/
try {
if (jj.contains("filam_bak")) {
is_support_show_filament_backup = true;
filam_bak.clear();
if (jj["filam_bak"].is_array()) {
for (auto it = jj["filam_bak"].begin(); it != jj["filam_bak"].end(); it++) {
filam_bak.push_back(it.value().get<int>());
}
}
}
else {
is_support_show_filament_backup = false;
}
}
catch (...) {
;
}
/* get fimware type */
try {
if (jj.contains("mess_production_state")) {
if (jj["mess_production_state"].get<std::string>() == "engineer")
firmware_type = PrinterFirmwareType::FIRMWARE_TYPE_ENGINEER;
else if (jj["mess_production_state"].get<std::string>() == "product")
firmware_type = PrinterFirmwareType::FIRMWARE_TYPE_PRODUCTION;
}
}
catch (...) {
;
}
}
if (!key_field_only) {
try {
if (jj.contains("lifecycle")) {
if (jj["lifecycle"].get<std::string>() == "engineer")
lifecycle = PrinterFirmwareType::FIRMWARE_TYPE_ENGINEER;
else if (jj["lifecycle"].get<std::string>() == "product")
lifecycle = PrinterFirmwareType::FIRMWARE_TYPE_PRODUCTION;
}
}
catch (...) {
;
}
try {
if (jj.contains("lights_report") && jj["lights_report"].is_array()) {
for (auto it = jj["lights_report"].begin(); it != jj["lights_report"].end(); it++) {
if ((*it)["node"].get<std::string>().compare("chamber_light") == 0)
chamber_light = light_effect_parse((*it)["mode"].get<std::string>());
if ((*it)["node"].get<std::string>().compare("work_light") == 0)
work_light = light_effect_parse((*it)["mode"].get<std::string>());
}
}
}
catch (...) {
;
}
// media
try {
if (jj.contains("sdcard")) {
if (jj["sdcard"].get<bool>())
sdcard_state = MachineObject::SdcardState::HAS_SDCARD_NORMAL;
else
sdcard_state = MachineObject::SdcardState::NO_SDCARD;
} else {
//do not check sdcard if no sdcard field
sdcard_state = MachineObject::SdcardState::NO_SDCARD;
}
}
catch (...) {
;
}
}
#pragma endregion
if (!key_field_only) {
try {
if (jj.contains("nozzle_diameter")) {
if (nozzle_setting_hold_count > 0) {
nozzle_setting_hold_count--;
} else {
if (jj["nozzle_diameter"].is_number_float()) {
nozzle_diameter = jj["nozzle_diameter"].get<float>();
}
else if (jj["nozzle_diameter"].is_string()) {
nozzle_diameter = string_to_float(jj["nozzle_diameter"].get<std::string>());
}
}
}
}
catch(...) {
;
}
try {
if (jj.contains("nozzle_type")) {
if (nozzle_setting_hold_count > 0) {
nozzle_setting_hold_count--;
}
else {
if (jj["nozzle_type"].is_string()) {
nozzle_type = jj["nozzle_type"].get<std::string>();
}
}
}
else {
nozzle_type = "";
}
}
catch (...) {
;
}
}
#pragma region upgrade
try {
if (jj.contains("upgrade_state")) {
if (jj["upgrade_state"].contains("status"))
upgrade_status = jj["upgrade_state"]["status"].get<std::string>();
if (jj["upgrade_state"].contains("progress")) {
upgrade_progress = jj["upgrade_state"]["progress"].get<std::string>();
} if (jj["upgrade_state"].contains("new_version_state"))
upgrade_new_version = jj["upgrade_state"]["new_version_state"].get<int>() == 1 ? true : false;
if (jj["upgrade_state"].contains("ams_new_version_number"))
ams_new_version_number = jj["upgrade_state"]["ams_new_version_number"].get<std::string>();
if (jj["upgrade_state"].contains("ota_new_version_number"))
ota_new_version_number = jj["upgrade_state"]["ota_new_version_number"].get<std::string>();
if (jj["upgrade_state"].contains("ahb_new_version_number"))
ahb_new_version_number = jj["upgrade_state"]["ahb_new_version_number"].get<std::string>();
if (jj["upgrade_state"].contains("module"))
upgrade_module = jj["upgrade_state"]["module"].get<std::string>();
if (jj["upgrade_state"].contains("message"))
upgrade_message = jj["upgrade_state"]["message"].get<std::string>();
if (jj["upgrade_state"].contains("consistency_request"))
upgrade_consistency_request = jj["upgrade_state"]["consistency_request"].get<bool>();
if (jj["upgrade_state"].contains("force_upgrade"))
upgrade_force_upgrade = jj["upgrade_state"]["force_upgrade"].get<bool>();
if (jj["upgrade_state"].contains("err_code"))
upgrade_err_code = jj["upgrade_state"]["err_code"].get<int>();
if (jj["upgrade_state"].contains("dis_state")) {
if (upgrade_display_state != jj["upgrade_state"]["dis_state"].get<int>()
&& jj["upgrade_state"]["dis_state"].get<int>() == 3) {
GUI::wxGetApp().CallAfter([this] {
this->command_get_version();
});
}
if (upgrade_display_hold_count > 0)
upgrade_display_hold_count--;
else
upgrade_display_state = jj["upgrade_state"]["dis_state"].get<int>();
} else {
if (upgrade_display_hold_count > 0)
upgrade_display_hold_count--;
else {
//BBS compatibility with old version
if (upgrade_status == "DOWNLOADING"
|| upgrade_status == "FLASHING"
|| upgrade_status == "UPGRADE_REQUEST"
|| upgrade_status == "PRE_FLASH_START"
|| upgrade_status == "PRE_FLASH_SUCCESS") {
upgrade_display_state = (int)UpgradingDisplayState::UpgradingInProgress;
}
else if (upgrade_status == "UPGRADE_SUCCESS"
|| upgrade_status == "DOWNLOAD_FAIL"
|| upgrade_status == "FLASH_FAIL"
|| upgrade_status == "PRE_FLASH_FAIL"
|| upgrade_status == "UPGRADE_FAIL") {
upgrade_display_state = (int)UpgradingDisplayState::UpgradingFinished;
}
else {
if (upgrade_new_version) {
upgrade_display_state = (int)UpgradingDisplayState::UpgradingAvaliable;
}
else {
upgrade_display_state = (int)UpgradingDisplayState::UpgradingUnavaliable;
}
}
}
}
// new ver list
if (jj["upgrade_state"].contains("new_ver_list")) {
m_new_ver_list_exist = true;
new_ver_list.clear();
for (auto ver_item = jj["upgrade_state"]["new_ver_list"].begin(); ver_item != jj["upgrade_state"]["new_ver_list"].end(); ver_item++) {
ModuleVersionInfo ver_info;
if (ver_item->contains("name"))
ver_info.name = (*ver_item)["name"].get<std::string>();
else
continue;
if (ver_item->contains("cur_ver"))
ver_info.sw_ver = (*ver_item)["cur_ver"].get<std::string>();
if (ver_item->contains("new_ver"))
ver_info.sw_new_ver = (*ver_item)["new_ver"].get<std::string>();
if (ver_info.name == "ota") {
ota_new_version_number = ver_info.sw_new_ver;
}
new_ver_list.insert(std::make_pair(ver_info.name, ver_info));
}
} else {
new_ver_list.clear();
}
}
}
catch (...) {
;
}
#pragma endregion
#pragma region camera
if (!key_field_only) {
// parse camera info
try {
if (jj.contains("ipcam")) {
json const & ipcam = jj["ipcam"];
if (ipcam.contains("ipcam_record")) {
if (camera_recording_hold_count > 0)
camera_recording_hold_count--;
else {
if (ipcam["ipcam_record"].get<std::string>() == "enable") {
camera_recording_when_printing = true;
}
else {
camera_recording_when_printing = false;
}
}
}
if (ipcam.contains("timelapse")) {
if (camera_timelapse_hold_count > 0)
camera_timelapse_hold_count--;
else {
if (ipcam["timelapse"].get<std::string>() == "enable") {
camera_timelapse = true;
}
else {
camera_timelapse = false;
}
}
}
if (ipcam.contains("ipcam_dev")) {
if (ipcam["ipcam_dev"].get<std::string>() == "1") {
has_ipcam = true;
} else {
has_ipcam = false;
}
}
if (ipcam.contains("resolution")) {
if (camera_resolution_hold_count > 0)
camera_resolution_hold_count--;
else {
camera_resolution = ipcam["resolution"].get<std::string>();
}
}
if (ipcam.contains("resolution_supported")) {
std::vector<std::string> resolution_supported;
for (auto res : ipcam["resolution_supported"])
resolution_supported.emplace_back(res.get<std::string>());
camera_resolution_supported.swap(resolution_supported);
}
if (ipcam.contains("liveview")) {
char const *local_protos[] = {"none", "disabled", "local", "rtsps", "rtsp"};
liveview_local = enum_index_of(ipcam["liveview"].value<std::string>("local", "none").c_str(), local_protos, 5, LiveviewLocal::LVL_None);
char const *remote_protos[] = {"none", "tutk", "agora", "tutk_agaro"};
liveview_remote = enum_index_of(ipcam["liveview"].value<std::string>("remote", "none").c_str(), remote_protos, 4, LiveviewRemote::LVR_None);
if (is_support_agora)
liveview_remote = liveview_remote == LVR_None ? LVR_Agora : liveview_remote == LVR_Tutk ? LVR_TutkAgora : liveview_remote;
}
if (ipcam.contains("file")) {
char const *local_protos[] = {"none", "local"};
file_local = enum_index_of(ipcam["file"].value<std::string>("local", "none").c_str(), local_protos, 2, FileLocal::FL_None);
char const *remote_protos[] = {"none", "tutk", "agora", "tutk_agaro"};
file_remote = enum_index_of(ipcam["file"].value<std::string>("remote", "none").c_str(), remote_protos, 4, FileRemote::FR_None);
if (is_support_agora)
file_remote = file_remote == FR_None ? FR_Agora : file_remote == FR_Tutk ? FR_TutkAgora : file_remote;
file_model_download = ipcam["file"].value<std::string>("model_download", "disabled") == "enabled";
}
virtual_camera = ipcam.value<std::string>("virtual_camera", "disabled") == "enabled";
if (ipcam.contains("rtsp_url")) {
local_rtsp_url = ipcam["rtsp_url"].get<std::string>();
liveview_local = local_rtsp_url.empty() ? LVL_None : local_rtsp_url == "disable"
? LVL_Disable : boost::algorithm::starts_with(local_rtsp_url, "rtsps") ? LVL_Rtsps : LVL_Rtsp;
}
if (ipcam.contains("tutk_server")) {
tutk_state = ipcam["tutk_server"].get<std::string>();
}
}
}
catch (...) {
;
}
try {
if (jj.contains("xcam")) {
if (xcam_ai_monitoring_hold_count > 0)
xcam_ai_monitoring_hold_count--;
else {
if (jj["xcam"].contains("printing_monitor")) {
// new protocol
xcam_ai_monitoring = jj["xcam"]["printing_monitor"].get<bool>();
} else {
// old version protocol
if (jj["xcam"].contains("spaghetti_detector")) {
xcam_ai_monitoring = jj["xcam"]["spaghetti_detector"].get<bool>();
if (jj["xcam"].contains("print_halt")) {
bool print_halt = jj["xcam"]["print_halt"].get<bool>();
if (print_halt) { xcam_ai_monitoring_sensitivity = "medium"; }
}
}
}
if (jj["xcam"].contains("halt_print_sensitivity")) {
xcam_ai_monitoring_sensitivity = jj["xcam"]["halt_print_sensitivity"].get<std::string>();
}
}
if (xcam_first_layer_hold_count > 0)
xcam_first_layer_hold_count--;
else {
if (jj["xcam"].contains("first_layer_inspector")) {
xcam_first_layer_inspector = jj["xcam"]["first_layer_inspector"].get<bool>();
}
}
if (xcam_buildplate_marker_hold_count > 0)
xcam_buildplate_marker_hold_count--;
else {
if (jj["xcam"].contains("buildplate_marker_detector")) {
xcam_buildplate_marker_detector = jj["xcam"]["buildplate_marker_detector"].get<bool>();
is_support_build_plate_marker_detect = true;
} else {
is_support_build_plate_marker_detect = false;
}
}
}
}
catch (...) {
;
}
}
#pragma endregion
#pragma region hms
if (!key_field_only) {
// parse hms msg
try {
hms_list.clear();
if (jj.contains("hms")) {
if (jj["hms"].is_array()) {
for (auto it = jj["hms"].begin(); it != jj["hms"].end(); it++) {
HMSItem item;
if ((*it).contains("attr") && (*it).contains("code")) {
unsigned attr = (*it)["attr"].get<unsigned>();
unsigned code = (*it)["code"].get<unsigned>();
item.parse_hms_info(attr, code);
}
hms_list.push_back(item);
}
}
}
}
catch (...) {
;
}
}
#pragma endregion
#pragma region push_ams
/* ams status */
try {
if (jj.contains("ams_status")) {
int ams_status = jj["ams_status"].get<int>();
this->_parse_ams_status(ams_status);
}
std::string str_j = jj.dump();
if (jj.contains("cali_version")) {
cali_version = jj["cali_version"].get<int>();
}
else {
cali_version = -1;
}
std::string str = jj.dump();
}
catch (...) {
;
}
PresetBundle *preset_bundle = Slic3r::GUI::wxGetApp().preset_bundle;
std::ostringstream stream;
stream << std::fixed << std::setprecision(1) << nozzle_diameter;
std::string nozzle_diameter_str = stream.str();
if (m_printer_preset_name.find(nozzle_diameter_str + " nozzle") == std::string::npos)
update_printer_preset_name(nozzle_diameter_str);
update_filament_list();
std::set<std::string> need_checked_filament_id;
if (jj.contains("ams")) {
if (jj["ams"].contains("ams")) {
long int last_ams_exist_bits = ams_exist_bits;
long int last_tray_exist_bits = tray_exist_bits;
long int last_is_bbl_bits = tray_is_bbl_bits;
long int last_read_done_bits = tray_read_done_bits;
long int last_ams_version = ams_version;
if (jj["ams"].contains("ams_exist_bits")) {
ams_exist_bits = stol(jj["ams"]["ams_exist_bits"].get<std::string>(), nullptr, 16);
}
if (jj["ams"].contains("tray_exist_bits")) {
tray_exist_bits = stol(jj["ams"]["tray_exist_bits"].get<std::string>(), nullptr, 16);
}
if (!key_field_only) {
if (jj["ams"].contains("tray_read_done_bits")) {
tray_read_done_bits = stol(jj["ams"]["tray_read_done_bits"].get<std::string>(), nullptr, 16);
}
if (jj["ams"].contains("tray_reading_bits")) {
tray_reading_bits = stol(jj["ams"]["tray_reading_bits"].get<std::string>(), nullptr, 16);
ams_support_use_ams = true;
}
if (jj["ams"].contains("tray_is_bbl_bits")) {
tray_is_bbl_bits = stol(jj["ams"]["tray_is_bbl_bits"].get<std::string>(), nullptr, 16);
}
if (jj["ams"].contains("version")) {
if (jj["ams"]["version"].is_number())
ams_version = jj["ams"]["version"].get<int>();
}
if (jj["ams"].contains("tray_now")) {
this->_parse_tray_now(jj["ams"]["tray_now"].get<std::string>());
}
if (jj["ams"].contains("tray_tar")) {
m_tray_tar = jj["ams"]["tray_tar"].get<std::string>();
}
if (jj["ams"].contains("ams_rfid_status"))
ams_rfid_status = jj["ams"]["ams_rfid_status"].get<int>();
if (jj["ams"].contains("humidity")) {
if (jj["ams"]["humidity"].is_string()) {
std::string humidity_str = jj["ams"]["humidity"].get<std::string>();
try {
ams_humidity = atoi(humidity_str.c_str());
} catch (...) {
;
}
}
}
if (jj["ams"].contains("insert_flag") || jj["ams"].contains("power_on_flag")
|| jj["ams"].contains("calibrate_remain_flag")) {
if (ams_user_setting_hold_count > 0) {
ams_user_setting_hold_count--;
} else {
if (jj["ams"].contains("insert_flag")) {
ams_insert_flag = jj["ams"]["insert_flag"].get<bool>();
}
if (jj["ams"].contains("power_on_flag")) {
ams_power_on_flag = jj["ams"]["power_on_flag"].get<bool>();
}
if (jj["ams"].contains("calibrate_remain_flag")) {
ams_calibrate_remain_flag = jj["ams"]["calibrate_remain_flag"].get<bool>();
}
}
}
if (ams_exist_bits != last_ams_exist_bits
|| tray_exist_bits != last_tray_exist_bits
|| tray_is_bbl_bits != last_is_bbl_bits
|| tray_read_done_bits != last_read_done_bits
|| ams_version != last_ams_version) {
is_ams_need_update = true;
}
else {
is_ams_need_update = false;
}
json j_ams = jj["ams"]["ams"];
std::set<std::string> ams_id_set;
for (auto it = amsList.begin(); it != amsList.end(); it++) {
ams_id_set.insert(it->first);
}
for (auto it = j_ams.begin(); it != j_ams.end(); it++) {
if (!it->contains("id")) continue;
std::string ams_id = (*it)["id"].get<std::string>();
ams_id_set.erase(ams_id);
Ams* curr_ams = nullptr;
auto ams_it = amsList.find(ams_id);
if (ams_it == amsList.end()) {
Ams* new_ams = new Ams(ams_id);
try {
if (!ams_id.empty()) {
int ams_id_int = atoi(ams_id.c_str());
new_ams->is_exists = (ams_exist_bits & (1 << ams_id_int)) != 0 ? true : false;
}
}
catch (...) {
;
}
amsList.insert(std::make_pair(ams_id, new_ams));
// new ams added event
curr_ams = new_ams;
} else {
curr_ams = ams_it->second;
}
if (!curr_ams) continue;
if (it->contains("humidity")) {
std::string humidity = (*it)["humidity"].get<std::string>();
try {
curr_ams->humidity = atoi(humidity.c_str());
}
catch (...) {
;
}
}
if (it->contains("tray")) {
std::set<std::string> tray_id_set;
for (auto it = curr_ams->trayList.begin(); it != curr_ams->trayList.end(); it++) {
tray_id_set.insert(it->first);
}
for (auto tray_it = (*it)["tray"].begin(); tray_it != (*it)["tray"].end(); tray_it++) {
if (!tray_it->contains("id")) continue;
std::string tray_id = (*tray_it)["id"].get<std::string>();
tray_id_set.erase(tray_id);
// compare tray_list
AmsTray* curr_tray = nullptr;
auto tray_iter = curr_ams->trayList.find(tray_id);
if (tray_iter == curr_ams->trayList.end()) {
AmsTray* new_tray = new AmsTray(tray_id);
curr_ams->trayList.insert(std::make_pair(tray_id, new_tray));
curr_tray = new_tray;
}
else {
curr_tray = tray_iter->second;
}
if (!curr_tray) continue;
if (curr_tray->hold_count > 0) {
curr_tray->hold_count--;
continue;
}
curr_tray->id = (*tray_it)["id"].get<std::string>();
if (tray_it->contains("tag_uid"))
curr_tray->tag_uid = (*tray_it)["tag_uid"].get<std::string>();
else
curr_tray->tag_uid = "0";
if (tray_it->contains("tray_info_idx") && tray_it->contains("tray_type")) {
curr_tray->setting_id = (*tray_it)["tray_info_idx"].get<std::string>();
//std::string type = (*tray_it)["tray_type"].get<std::string>();
std::string type = setting_id_to_type(curr_tray->setting_id, (*tray_it)["tray_type"].get<std::string>());
if (curr_tray->setting_id == "GFS00") {
curr_tray->type = "PLA-S";
}
else if (curr_tray->setting_id == "GFS01") {
curr_tray->type = "PA-S";
} else {
curr_tray->type = type;
}
// settings_id is not exist in filament_list
if (curr_tray->setting_id.size() == 8 && curr_tray->setting_id[0] == 'P' &&
m_filament_list.find(curr_tray->setting_id) == m_filament_list.end()) {
if (m_checked_filament.find(curr_tray->setting_id) == m_checked_filament.end()) {
need_checked_filament_id.insert(curr_tray->setting_id);
wxColour color = *wxWHITE;
char col_buf[10];
sprintf(col_buf, "%02X%02X%02XFF", (int) color.Red(), (int) color.Green(), (int) color.Blue());
try {
BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__
<< " ams settings_id is not exist in filament_list and reset, ams_id: " << ams_id
<< " tray_id" << tray_id << "filament_id: " << curr_tray->setting_id;
this->command_ams_filament_settings(std::stoi(ams_id), std::stoi(tray_id), "", "", std::string(col_buf), "", 0, 0);
continue;
} catch (...) {
BOOST_LOG_TRIVIAL(info)
<< __FUNCTION__ << " " << __LINE__ << " stoi error and ams_id: " << ams_id << " tray_id" << tray_id;
}
}
}
} else {
curr_tray->setting_id = "";
curr_tray->type = "";
}
if (tray_it->contains("tray_sub_brands"))
curr_tray->sub_brands = (*tray_it)["tray_sub_brands"].get<std::string>();
else
curr_tray->sub_brands = "";
if (tray_it->contains("tray_weight"))
curr_tray->weight = (*tray_it)["tray_weight"].get<std::string>();
else
curr_tray->weight = "";
if (tray_it->contains("tray_diameter"))
curr_tray->diameter = (*tray_it)["tray_diameter"].get<std::string>();
else
curr_tray->diameter = "";
if (tray_it->contains("tray_temp"))
curr_tray->temp = (*tray_it)["tray_temp"].get<std::string>();
else
curr_tray->temp = "";
if (tray_it->contains("tray_time"))
curr_tray->time = (*tray_it)["tray_time"].get<std::string>();
else
curr_tray->time = "";
if (tray_it->contains("bed_temp_type"))
curr_tray->bed_temp_type = (*tray_it)["bed_temp_type"].get<std::string>();
else
curr_tray->bed_temp_type = "";
if (tray_it->contains("bed_temp"))
curr_tray->bed_temp = (*tray_it)["bed_temp"].get<std::string>();
else
curr_tray->bed_temp = "";
if (tray_it->contains("tray_color")) {
auto color = (*tray_it)["tray_color"].get<std::string>();
curr_tray->update_color_from_str(color);
} else {
curr_tray->color = "";
}
if (tray_it->contains("nozzle_temp_max")) {
curr_tray->nozzle_temp_max = (*tray_it)["nozzle_temp_max"].get<std::string>();
}
else
curr_tray->nozzle_temp_max = "";
if (tray_it->contains("nozzle_temp_min"))
curr_tray->nozzle_temp_min = (*tray_it)["nozzle_temp_min"].get<std::string>();
else
curr_tray->nozzle_temp_min = "";
if (curr_tray->setting_id.size() == 8 && curr_tray->setting_id[0] == 'P' && curr_tray->nozzle_temp_min != "" && curr_tray->nozzle_temp_max != "") {
if (m_checked_filament.find(vt_tray.setting_id) == m_checked_filament.end()) {
need_checked_filament_id.insert(vt_tray.setting_id);
try {
std::string preset_setting_id;
bool is_equation = preset_bundle->check_filament_temp_equation_by_printer_type_and_nozzle_for_mas_tray(
MachineObject::get_preset_printer_model_name(this->printer_type), nozzle_diameter_str, curr_tray->setting_id,
curr_tray->tag_uid, curr_tray->nozzle_temp_min, curr_tray->nozzle_temp_max, preset_setting_id);
if (!is_equation) {
BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__
<< " ams filament is not match min max temp and reset, ams_id: " << ams_id
<< " tray_id" << tray_id << "filament_id: " << curr_tray->setting_id;
command_ams_filament_settings(std::stoi(ams_id), std::stoi(tray_id), curr_tray->setting_id, preset_setting_id,
curr_tray->color, curr_tray->type,
std::stoi(curr_tray->nozzle_temp_min),
std::stoi(curr_tray->nozzle_temp_max));
}
continue;
} catch (...) {
BOOST_LOG_TRIVIAL(info) << "check fail and curr_tray ams_id" << ams_id << " curr_tray tray_id"<<tray_id;
}
}
}
if (tray_it->contains("xcam_info"))
curr_tray->xcam_info = (*tray_it)["xcam_info"].get<std::string>();
else
curr_tray->xcam_info = "";
if (tray_it->contains("tray_uuid"))
curr_tray->uuid = (*tray_it)["tray_uuid"].get<std::string>();
else
curr_tray->uuid = "0";
if (tray_it->contains("ctype"))
curr_tray->ctype = (*tray_it)["ctype"].get<int>();
else
curr_tray->ctype = 0;
curr_tray->cols.clear();
if (tray_it->contains("cols")) {
if ((*tray_it)["cols"].is_array()) {
for (auto it = (*tray_it)["cols"].begin(); it != (*tray_it)["cols"].end(); it++) {
curr_tray->cols.push_back(it.value().get<std::string>());
}
}
}
if (tray_it->contains("remain")) {
curr_tray->remain = (*tray_it)["remain"].get<int>();
} else {
curr_tray->remain = -1;
}
int ams_id_int = 0;
int tray_id_int = 0;
try {
if (!ams_id.empty() && !curr_tray->id.empty()) {
ams_id_int = atoi(ams_id.c_str());
tray_id_int = atoi(curr_tray->id.c_str());
curr_tray->is_exists = (tray_exist_bits & (1 << (ams_id_int * 4 + tray_id_int))) != 0 ? true : false;
}
}
catch (...) {
}
if (tray_it->contains("setting_id")) {
curr_tray->filament_setting_id = (*tray_it)["setting_id"].get<std::string>();
}
auto curr_time = std::chrono::system_clock::now();
auto diff = std::chrono::duration_cast<std::chrono::milliseconds>(curr_time - extrusion_cali_set_hold_start);
if (diff.count() > HOLD_TIMEOUT || diff.count() < 0
|| ams_id_int != (extrusion_cali_set_tray_id / 4)
|| tray_id_int != (extrusion_cali_set_tray_id % 4)) {
if (tray_it->contains("k")) {
curr_tray->k = (*tray_it)["k"].get<float>();
}
if (tray_it->contains("n")) {
curr_tray->n = (*tray_it)["n"].get<float>();
}
}
std::string temp = tray_it->dump();
if (tray_it->contains("cali_idx")) {
curr_tray->cali_idx = (*tray_it)["cali_idx"].get<int>();
}
}
// remove not in trayList
for (auto tray_it = tray_id_set.begin(); tray_it != tray_id_set.end(); tray_it++) {
std::string tray_id = *tray_it;
auto tray = curr_ams->trayList.find(tray_id);
if (tray != curr_ams->trayList.end()) {
curr_ams->trayList.erase(tray_id);
BOOST_LOG_TRIVIAL(trace) << "parse_json: remove ams_id=" << ams_id << ", tray_id=" << tray_id;
}
}
}
}
// remove not in amsList
for (auto it = ams_id_set.begin(); it != ams_id_set.end(); it++) {
std::string ams_id = *it;
auto ams = amsList.find(ams_id);
if (ams != amsList.end()) {
BOOST_LOG_TRIVIAL(trace) << "parse_json: remove ams_id=" << ams_id;
amsList.erase(ams_id);
}
}
}
}
}
/* vitrual tray*/
if (!key_field_only) {
try {
if (jj.contains("vt_tray")) {
if (jj["vt_tray"].contains("id"))
vt_tray.id = jj["vt_tray"]["id"].get<std::string>();
auto curr_time = std::chrono::system_clock::now();
auto diff = std::chrono::duration_cast<std::chrono::milliseconds>(curr_time - extrusion_cali_set_hold_start);
if (diff.count() > HOLD_TIMEOUT || diff.count() < 0
|| extrusion_cali_set_tray_id != VIRTUAL_TRAY_ID) {
if (jj["vt_tray"].contains("k"))
vt_tray.k = jj["vt_tray"]["k"].get<float>();
if (jj["vt_tray"].contains("n"))
vt_tray.n = jj["vt_tray"]["n"].get<float>();
}
ams_support_virtual_tray = true;
if (vt_tray.hold_count > 0) {
vt_tray.hold_count--;
} else {
if (jj["vt_tray"].contains("tag_uid"))
vt_tray.tag_uid = jj["vt_tray"]["tag_uid"].get<std::string>();
else
vt_tray.tag_uid = "0";
if (jj["vt_tray"].contains("tray_info_idx") && jj["vt_tray"].contains("tray_type")) {
vt_tray.setting_id = jj["vt_tray"]["tray_info_idx"].get<std::string>();
//std::string type = jj["vt_tray"]["tray_type"].get<std::string>();
std::string type = setting_id_to_type(vt_tray.setting_id, jj["vt_tray"]["tray_type"].get<std::string>());
if (vt_tray.setting_id == "GFS00") {
vt_tray.type = "PLA-S";
}
else if (vt_tray.setting_id == "GFS01") {
vt_tray.type = "PA-S";
}
else {
vt_tray.type = type;
}
if (vt_tray.setting_id.size() == 8 && vt_tray.setting_id[0] == 'P' &&
m_filament_list.find(vt_tray.setting_id) == m_filament_list.end()) {
if (m_checked_filament.find(vt_tray.setting_id) == m_checked_filament.end()) {
need_checked_filament_id.insert(vt_tray.setting_id);
wxColour color = *wxWHITE;
char col_buf[10];
sprintf(col_buf, "%02X%02X%02XFF", (int) color.Red(), (int) color.Green(), (int) color.Blue());
try {
BOOST_LOG_TRIVIAL(info) << "vt_tray.setting_id is not exist in filament_list and reset vt_tray and the filament_id is: " << vt_tray.setting_id;
this->command_ams_filament_settings(255, std::stoi(vt_tray.id), "", "", std::string(col_buf), "", 0, 0);
} catch (...) {
BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << " stoi error and tray_id" << vt_tray.id;
}
}
}
}
else {
vt_tray.setting_id = "";
vt_tray.type = "";
}
if (jj["vt_tray"].contains("tray_sub_brands"))
vt_tray.sub_brands = jj["vt_tray"]["tray_sub_brands"].get<std::string>();
else
vt_tray.sub_brands = "";
if (jj["vt_tray"].contains("tray_weight"))
vt_tray.weight = jj["vt_tray"]["tray_weight"].get<std::string>();
else
vt_tray.weight = "";
if (jj["vt_tray"].contains("tray_diameter"))
vt_tray.diameter = jj["vt_tray"]["tray_diameter"].get<std::string>();
else
vt_tray.diameter = "";
if (jj["vt_tray"].contains("tray_temp"))
vt_tray.temp = jj["vt_tray"]["tray_temp"].get<std::string>();
else
vt_tray.temp = "";
if (jj["vt_tray"].contains("tray_time"))
vt_tray.time = jj["vt_tray"]["tray_time"].get<std::string>();
else
vt_tray.time = "";
if (jj["vt_tray"].contains("bed_temp_type"))
vt_tray.bed_temp_type = jj["vt_tray"]["bed_temp_type"].get<std::string>();
else
vt_tray.bed_temp_type = "";
if (jj["vt_tray"].contains("bed_temp"))
vt_tray.bed_temp = jj["vt_tray"]["bed_temp"].get<std::string>();
else
vt_tray.bed_temp = "";
if (jj["vt_tray"].contains("tray_color")) {
auto color = jj["vt_tray"]["tray_color"].get<std::string>();
vt_tray.update_color_from_str(color);
} else {
vt_tray.color = "";
}
if (jj["vt_tray"].contains("nozzle_temp_max"))
vt_tray.nozzle_temp_max = jj["vt_tray"]["nozzle_temp_max"].get<std::string>();
else
vt_tray.nozzle_temp_max = "";
if (jj["vt_tray"].contains("nozzle_temp_min"))
vt_tray.nozzle_temp_min = jj["vt_tray"]["nozzle_temp_min"].get<std::string>();
else
vt_tray.nozzle_temp_min = "";
if (vt_tray.setting_id.size() == 8 && vt_tray.setting_id[0] == 'P' && vt_tray.nozzle_temp_min != "" && vt_tray.nozzle_temp_max != "") {
if (m_checked_filament.find(vt_tray.setting_id) == m_checked_filament.end()) {
need_checked_filament_id.insert(vt_tray.setting_id);
try {
std::string preset_setting_id;
bool is_equation = preset_bundle->check_filament_temp_equation_by_printer_type_and_nozzle_for_mas_tray(
MachineObject::get_preset_printer_model_name(this->printer_type), nozzle_diameter_str, vt_tray.setting_id, vt_tray.tag_uid,
vt_tray.nozzle_temp_min, vt_tray.nozzle_temp_max, preset_setting_id);
if (!is_equation) {
BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << " vt_tray filament is not match min max temp and reset, filament_id: " << vt_tray.setting_id;
command_ams_filament_settings(255, std::stoi(vt_tray.id), vt_tray.setting_id, preset_setting_id, vt_tray.color, vt_tray.type,
std::stoi(vt_tray.nozzle_temp_min), std::stoi(vt_tray.nozzle_temp_max));
}
} catch (...) {
BOOST_LOG_TRIVIAL(info) << "check fail and vt_tray.id" << vt_tray.id;
}
}
}
if (jj["vt_tray"].contains("xcam_info"))
vt_tray.xcam_info = jj["vt_tray"]["xcam_info"].get<std::string>();
else
vt_tray.xcam_info = "";
if (jj["vt_tray"].contains("tray_uuid"))
vt_tray.uuid = jj["vt_tray"]["tray_uuid"].get<std::string>();
else
vt_tray.uuid = "0";
if (jj["vt_tray"].contains("cali_idx"))
vt_tray.cali_idx = jj["vt_tray"]["cali_idx"].get<int>();
else
vt_tray.cali_idx = -1;
vt_tray.cols.clear();
if (jj["vt_tray"].contains("cols")) {
if (jj["vt_tray"].is_array()) {
for (auto it = jj["vt_tray"].begin(); it != jj["vt_tray"].end(); it++) {
vt_tray.cols.push_back(it.value().get<std::string>());
}
}
}
if (jj["vt_tray"].contains("remain")) {
vt_tray.remain = jj["vt_tray"]["remain"].get<int>();
}
else {
vt_tray.remain = -1;
}
}
} else {
ams_support_virtual_tray = false;
is_support_extrusion_cali = false;
}
}
catch (...) {
;
}
}
for (auto &filament_id : need_checked_filament_id)
m_checked_filament.insert(filament_id);
#pragma endregion
} else if (jj["command"].get<std::string>() == "gcode_line") {
//ack of gcode_line
BOOST_LOG_TRIVIAL(debug) << "parse_json, ack of gcode_line = " << j.dump(4);
} else if (jj["command"].get<std::string>() == "project_prepare") {
//ack of project file
BOOST_LOG_TRIVIAL(info) << "parse_json, ack of project_prepare = " << j.dump(4);
if (m_agent) {
if (jj.contains("job_id")) {
this->job_id_ = jj["job_id"].get<std::string>();
}
}
} else if (jj["command"].get<std::string>() == "project_file") {
//ack of project file
BOOST_LOG_TRIVIAL(debug) << "parse_json, ack of project_file = " << j.dump(4);
std::string result;
if (jj.contains("result")) {
result = jj["result"].get<std::string>();
if (result == "FAIL") {
wxString text = _L("Failed to start printing job");
GUI::wxGetApp().push_notification(text);
}
}
} else if (jj["command"].get<std::string>() == "ams_filament_setting" && !key_field_only) {
if (jj.contains("result") && jj.contains("reason")) {
if (jj["result"].get<std::string>() == "fail") {
auto err_code = jj["err_code"].get<int>();
print_error = err_code;
}
}
// BBS trigger ams UI update
ams_version = -1;
if (jj["ams_id"].is_number()) {
int ams_id = jj["ams_id"].get<int>();
int tray_id = 0;
if (jj.contains("tray_id")) {
tray_id = jj["tray_id"].get<int>();
}
if (ams_id == 255 && tray_id == VIRTUAL_TRAY_ID) {
BOOST_LOG_TRIVIAL(info) << "ams_filament_setting, parse tray info";
vt_tray.nozzle_temp_max = std::to_string(jj["nozzle_temp_max"].get<int>());
vt_tray.nozzle_temp_min = std::to_string(jj["nozzle_temp_min"].get<int>());
vt_tray.color = jj["tray_color"].get<std::string>();
vt_tray.setting_id = jj["tray_info_idx"].get<std::string>();
//vt_tray.type = jj["tray_type"].get<std::string>();
vt_tray.type = setting_id_to_type(vt_tray.setting_id, jj["tray_type"].get<std::string>());
// delay update
vt_tray.set_hold_count();
} else {
auto ams_it = amsList.find(std::to_string(ams_id));
if (ams_it != amsList.end()) {
tray_id = jj["tray_id"].get<int>();
auto tray_it = ams_it->second->trayList.find(std::to_string(tray_id));
if (tray_it != ams_it->second->trayList.end()) {
BOOST_LOG_TRIVIAL(trace) << "ams_filament_setting, parse tray info";
tray_it->second->nozzle_temp_max = std::to_string(jj["nozzle_temp_max"].get<int>());
tray_it->second->nozzle_temp_min = std::to_string(jj["nozzle_temp_min"].get<int>());
//tray_it->second->type = jj["tray_type"].get<std::string>();
tray_it->second->color = jj["tray_color"].get<std::string>();
/*tray_it->second->cols.clear();
if (jj.contains("cols")) {
if (jj["cols"].is_array()) {
for (auto it = jj["cols"].begin(); it != jj["cols"].end(); it++) {
tray_it->second->cols.push_back(it.value().get<std::string>());
}
}
}*/
tray_it->second->setting_id = jj["tray_info_idx"].get<std::string>();
tray_it->second->type = setting_id_to_type(tray_it->second->setting_id, jj["tray_type"].get<std::string>());
// delay update
tray_it->second->set_hold_count();
} else {
BOOST_LOG_TRIVIAL(warning) << "ams_filament_setting, can not find in trayList, tray_id=" << tray_id;
}
} else {
BOOST_LOG_TRIVIAL(warning) << "ams_filament_setting, can not find in amsList, ams_id=" << ams_id;
}
}
}
} else if (jj["command"].get<std::string>() == "xcam_control_set" && !key_field_only) {
if (jj.contains("module_name")) {
if (jj.contains("enable") || jj.contains("control")) {
bool enable = false;
if (jj.contains("enable"))
enable = jj["enable"].get<bool>();
else if (jj.contains("control"))
enable = jj["control"].get<bool>();
else {
;
}
if (jj["module_name"].get<std::string>() == "first_layer_inspector") {
xcam_first_layer_inspector = enable;
xcam_first_layer_hold_count = HOLD_COUNT_MAX;
}
else if (jj["module_name"].get<std::string>() == "buildplate_marker_detector") {
xcam_buildplate_marker_detector = enable;
xcam_buildplate_marker_hold_count = HOLD_COUNT_MAX;
}
else if (jj["module_name"].get<std::string>() == "printing_monitor") {
xcam_ai_monitoring = enable;
xcam_ai_monitoring_hold_count = HOLD_COUNT_MAX;
if (jj.contains("halt_print_sensitivity")) {
xcam_ai_monitoring_sensitivity = jj["halt_print_sensitivity"].get<std::string>();
}
}
else if (jj["module_name"].get<std::string>() == "spaghetti_detector") {
// old protocol
xcam_ai_monitoring = enable;
xcam_ai_monitoring_hold_count = HOLD_COUNT_MAX;
if (jj.contains("print_halt")) {
if (jj["print_halt"].get<bool>())
xcam_ai_monitoring_sensitivity = "medium";
}
}
}
}
} else if(jj["command"].get<std::string>() == "print_option") {
try {
if (jj.contains("option")) {
if (jj["option"].is_number()) {
int option = jj["option"].get<int>();
_parse_print_option_ack(option);
}
}
if (jj.contains("auto_recovery")) {
xcam_auto_recovery_step_loss = jj["auto_recovery"].get<bool>();
}
}
catch(...) {
}
} else if (jj["command"].get<std::string>() == "extrusion_cali" || jj["command"].get<std::string>() == "flowrate_cali") {
if (jj.contains("result")) {
if (jj["result"].get<std::string>() == "success") {
;
}
else if (jj["result"].get<std::string>() == "fail") {
std::string cali_mode = jj["command"].get<std::string>();
std::string reason = jj["reason"].get<std::string>();
wxString info = "";
if (reason == "invalid nozzle_diameter" || reason == "nozzle_diameter is not supported") {
info = _L("This calibration does not support the currently selected nozzle diameter");
}
else if (reason == "invalid handle_flowrate_cali param") {
info = _L("Current flowrate cali param is invalid");
}
else if (reason == "nozzle_diameter is not matched") {
info = _L("Selected diameter and machine diameter do not match");
}
else if (reason == "generate auto filament cali gcode failure") {
info = _L("Failed to generate cali gcode");
}
else {
info = reason;
}
GUI::wxGetApp().push_notification(info, _L("Calibration error"), UserNotificationStyle::UNS_WARNING_CONFIRM);
BOOST_LOG_TRIVIAL(trace) << cali_mode << " result fail, reason = " << reason;
}
}
} else if (jj["command"].get<std::string>() == "extrusion_cali_set") {
#ifdef CALI_DEBUG
std::string str = jj.dump();
BOOST_LOG_TRIVIAL(info) << "extrusion_cali_set: " << str;
#endif
int ams_id = -1;
int tray_id = -1;
int curr_tray_id = -1;
if (jj.contains("tray_id")) {
try {
curr_tray_id = jj["tray_id"].get<int>();
if (curr_tray_id == VIRTUAL_TRAY_ID)
tray_id = curr_tray_id;
else if (curr_tray_id >= 0 && curr_tray_id < 16){
ams_id = curr_tray_id / 4;
tray_id = curr_tray_id % 4;
} else {
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali_set: unsupported tray_id = " << curr_tray_id;
}
}
catch(...) {
;
}
}
if (tray_id == VIRTUAL_TRAY_ID) {
if (jj.contains("k_value"))
vt_tray.k = jj["k_value"].get<float>();
if (jj.contains("n_coef"))
vt_tray.n = jj["n_coef"].get<float>();
} else {
auto ams_item = this->amsList.find(std::to_string(ams_id));
if (ams_item != this->amsList.end()) {
auto tray_item = ams_item->second->trayList.find(std::to_string(tray_id));
if (tray_item != ams_item->second->trayList.end()) {
if (jj.contains("k_value"))
tray_item->second->k = jj["k_value"].get<float>();
if (jj.contains("n_coef"))
tray_item->second->n = jj["n_coef"].get<float>();
}
}
}
extrusion_cali_set_tray_id = curr_tray_id;
extrusion_cali_set_hold_start = std::chrono::system_clock::now();
}
else if (jj["command"].get<std::string>() == "extrusion_cali_sel") {
#ifdef CALI_DEBUG
std::string str = jj.dump();
BOOST_LOG_TRIVIAL(info) << "extrusion_cali_sel: " << str;
#endif
int ams_id = -1;
int tray_id = -1;
int curr_tray_id = -1;
if (jj.contains("tray_id")) {
try {
curr_tray_id = jj["tray_id"].get<int>();
if (curr_tray_id == VIRTUAL_TRAY_ID)
tray_id = curr_tray_id;
else if (curr_tray_id >= 0 && curr_tray_id < 16) {
ams_id = curr_tray_id / 4;
tray_id = curr_tray_id % 4;
} else {
BOOST_LOG_TRIVIAL(trace) << "extrusion_cali_sel: unsupported tray_id = " << curr_tray_id;
}
} catch (...) {
;
}
}
if (tray_id == VIRTUAL_TRAY_ID) {
if (jj.contains("cali_idx")) {
vt_tray.cali_idx = jj["cali_idx"].get<int>();
vt_tray.set_hold_count();
}
} else {
auto ams_item = this->amsList.find(std::to_string(ams_id));
if (ams_item != this->amsList.end()) {
auto tray_item = ams_item->second->trayList.find(std::to_string(tray_id));
if (tray_item != ams_item->second->trayList.end()) {
if (jj.contains("cali_idx")) {
tray_item->second->cali_idx = jj["cali_idx"].get<int>();
tray_item->second->set_hold_count();
}
}
}
}
}
else if (jj["command"].get<std::string>() == "extrusion_cali_get") {
reset_pa_cali_history_result();
has_get_pa_calib_tab = true;
if (jj.contains("nozzle_diameter")) {
if (jj["nozzle_diameter"].is_number_float()) {
pa_calib_tab_nozzle_dia = jj["nozzle_diameter"].get<float>();
}
else if (jj["nozzle_diameter"].is_string()) {
pa_calib_tab_nozzle_dia = string_to_float(jj["nozzle_diameter"].get<std::string>());
}
else {
assert(false);
}
}
else {
assert(false);
}
if (jj.contains("filaments") && jj["filaments"].is_array()) {
try {
#ifdef CALI_DEBUG
std::string str = jj.dump();
BOOST_LOG_TRIVIAL(info) << "extrusion_cali_get: " << str;
#endif
for (auto it = jj["filaments"].begin(); it != jj["filaments"].end(); it++) {
PACalibResult pa_calib_result;
pa_calib_result.filament_id = (*it)["filament_id"].get<std::string>();
pa_calib_result.setting_id = (*it)["setting_id"].get<std::string>();
pa_calib_result.name = (*it)["name"].get<std::string>();
pa_calib_result.cali_idx = (*it)["cali_idx"].get<int>();
if (jj["nozzle_diameter"].is_number_float()) {
pa_calib_result.nozzle_diameter = jj["nozzle_diameter"].get<float>();
} else if (jj["nozzle_diameter"].is_string()) {
pa_calib_result.nozzle_diameter = string_to_float(jj["nozzle_diameter"].get<std::string>());
}
if ((*it)["k_value"].is_number_float())
pa_calib_result.k_value = (*it)["k_value"].get<float>();
else if ((*it)["k_value"].is_string())
pa_calib_result.k_value = string_to_float((*it)["k_value"].get<std::string>());
if ((*it)["n_coef"].is_number_float())
pa_calib_result.n_coef = (*it)["n_coef"].get<float>();
else if ((*it)["n_coef"].is_string())
pa_calib_result.n_coef = string_to_float((*it)["n_coef"].get<std::string>());
if (check_pa_result_validation(pa_calib_result))
pa_calib_tab.push_back(pa_calib_result);
else {
BOOST_LOG_TRIVIAL(info) << "pa result is invalid";
}
}
}
catch (...) {
}
}
// notify cali history to update
}
else if (jj["command"].get<std::string>() == "extrusion_cali_get_result") {
reset_pa_cali_result();
get_pa_calib_result = true;
if (jj.contains("filaments") && jj["filaments"].is_array()) {
try {
#ifdef CALI_DEBUG
std::string str = jj.dump();
BOOST_LOG_TRIVIAL(info) << "extrusion_cali_get_result: " << str;
#endif
for (auto it = jj["filaments"].begin(); it != jj["filaments"].end(); it++) {
PACalibResult pa_calib_result;
pa_calib_result.tray_id = (*it)["tray_id"].get<int>();
pa_calib_result.filament_id = (*it)["filament_id"].get<std::string>();
pa_calib_result.setting_id = (*it)["setting_id"].get<std::string>();
if (jj["nozzle_diameter"].is_number_float()) {
pa_calib_result.nozzle_diameter = jj["nozzle_diameter"].get<float>();
} else if (jj["nozzle_diameter"].is_string()) {
pa_calib_result.nozzle_diameter = string_to_float(jj["nozzle_diameter"].get<std::string>());
}
if ((*it)["k_value"].is_number_float())
pa_calib_result.k_value = (*it)["k_value"].get<float>();
else if ((*it)["k_value"].is_string())
pa_calib_result.k_value = string_to_float((*it)["k_value"].get<std::string>());
if ((*it)["n_coef"].is_number_float())
pa_calib_result.n_coef = (*it)["n_coef"].get<float>();
else if ((*it)["n_coef"].is_string())
pa_calib_result.n_coef = string_to_float((*it)["n_coef"].get<std::string>());
if (it->contains("confidence")) {
pa_calib_result.confidence = (*it)["confidence"].get<int>();
} else {
pa_calib_result.confidence = 0;
}
if (check_pa_result_validation(pa_calib_result))
pa_calib_results.push_back(pa_calib_result);
else {
BOOST_LOG_TRIVIAL(info) << "pa result is invalid";
}
}
} catch (...) {}
}
if (pa_calib_results.empty()) {
BOOST_LOG_TRIVIAL(info) << "no pa calib result";
}
}
else if (jj["command"].get<std::string>() == "flowrate_get_result" && !key_field_only) {
this->reset_flow_rate_cali_result();
get_flow_calib_result = true;
if (jj.contains("filaments") && jj["filaments"].is_array()) {
try {
#ifdef CALI_DEBUG
std::string str = jj.dump();
BOOST_LOG_TRIVIAL(info) << "flowrate_get_result: " << str;
#endif
for (auto it = jj["filaments"].begin(); it != jj["filaments"].end(); it++) {
FlowRatioCalibResult flow_ratio_calib_result;
flow_ratio_calib_result.tray_id = (*it)["tray_id"].get<int>();
flow_ratio_calib_result.filament_id = (*it)["filament_id"].get<std::string>();
flow_ratio_calib_result.setting_id = (*it)["setting_id"].get<std::string>();
flow_ratio_calib_result.nozzle_diameter = string_to_float(jj["nozzle_diameter"].get<std::string>());
flow_ratio_calib_result.flow_ratio = string_to_float((*it)["flow_ratio"].get<std::string>());
if (it->contains("confidence")) {
flow_ratio_calib_result.confidence = (*it)["confidence"].get<int>();
} else {
flow_ratio_calib_result.confidence = 0;
}
flow_ratio_results.push_back(flow_ratio_calib_result);
}
} catch (...) {}
}
}
}
}
if (!key_field_only) {
try {
if (j.contains("camera")) {
if (j["camera"].contains("command")) {
if (j["camera"]["command"].get<std::string>() == "ipcam_timelapse") {
if (j["camera"]["control"].get<std::string>() == "enable")
this->camera_timelapse = true;
if (j["camera"]["control"].get<std::string>() == "disable")
this->camera_timelapse = false;
BOOST_LOG_TRIVIAL(info) << "ack of timelapse = " << camera_timelapse;
} else if (j["camera"]["command"].get<std::string>() == "ipcam_record_set") {
if (j["camera"]["control"].get<std::string>() == "enable")
this->camera_recording_when_printing = true;
if (j["camera"]["control"].get<std::string>() == "disable")
this->camera_recording_when_printing = false;
BOOST_LOG_TRIVIAL(info) << "ack of ipcam_record_set " << camera_recording_when_printing;
} else if (j["camera"]["command"].get<std::string>() == "ipcam_resolution_set") {
this->camera_resolution = j["camera"]["resolution"].get<std::string>();
BOOST_LOG_TRIVIAL(info) << "ack of resolution = " << camera_resolution;
}
}
}
} catch (...) {}
}
if (!key_field_only) {
// upgrade
try {
if (j.contains("upgrade")) {
if (j["upgrade"].contains("command")) {
if (j["upgrade"]["command"].get<std::string>() == "upgrade_confirm") {
this->upgrade_display_state = UpgradingInProgress;
upgrade_display_hold_count = HOLD_COUNT_MAX;
BOOST_LOG_TRIVIAL(info) << "ack of upgrade_confirm";
}
}
}
}
catch (...) {
;
}
}
// event info
try {
if (j.contains("event")) {
if (j["event"].contains("event")) {
if (j["event"]["event"].get<std::string>() == "client.disconnected")
set_online_state(false);
else if (j["event"]["event"].get<std::string>() == "client.connected")
set_online_state(true);
}
}
}
catch (...) {}
if (!key_field_only) {
if (m_active_state == Active && !module_vers.empty() && check_version_valid()
&& !is_camera_busy_off()) {
m_active_state = UpdateToDate;
parse_version_func();
if (is_support_tunnel_mqtt && connection_type() != "lan") {
m_agent->start_subscribe("tunnel");
}
parse_state_changed_event();
}
}
}
catch (...) {
BOOST_LOG_TRIVIAL(trace) << "parse_json failed! dev_id=" << this->dev_id <<", payload = " << payload;
}
std::chrono::system_clock::time_point clock_stop = std::chrono::system_clock::now();
auto diff = std::chrono::duration_cast<std::chrono::milliseconds>(clock_stop - clock_start);
if (diff.count() > 10.0f) {
BOOST_LOG_TRIVIAL(trace) << "parse_json timeout = " << diff.count();
}
return 0;
}
void MachineObject::set_ctt_dlg( wxString text){
if (!m_set_ctt_dlg) {
m_set_ctt_dlg = true;
auto print_error_dlg = new GUI::SecondaryCheckDialog(nullptr, wxID_ANY, _L("Warning"), GUI::SecondaryCheckDialog::ButtonStyle::ONLY_CONFIRM);
print_error_dlg->update_text(text);
print_error_dlg->Bind(wxEVT_SHOW, [this](auto& e) {
if (!e.IsShown()) {
m_set_ctt_dlg = false;
}
});
print_error_dlg->Bind(wxEVT_CLOSE_WINDOW, [this](auto& e) {
e.Skip();
m_set_ctt_dlg = false;
});
print_error_dlg->on_show();
}
}
int MachineObject::publish_gcode(std::string gcode_str)
{
json j;
j["print"]["command"] = "gcode_line";
j["print"]["param"] = gcode_str;
j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++);
return publish_json(j.dump());
}
BBLSubTask* MachineObject::get_subtask()
{
if (!subtask_)
subtask_ = new BBLSubTask(nullptr);
return subtask_;
}
BBLModelTask* MachineObject::get_modeltask()
{
return model_task;
}
void MachineObject::set_modeltask(BBLModelTask* task)
{
model_task = task;
}
void MachineObject::update_model_task()
{
if (request_model_result > 10) return;
if (!m_agent) return;
if (!model_task) return;
if (!subtask_) return;
if (model_task->task_id != subtask_->task_id) {
BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " times: " << request_model_result << " model_task_id !=subtask_id";
return;
}
if (model_task->instance_id <= 0) {
BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " times: " << request_model_result << " instance_id <= 0";
return;
}
if ((!subtask_id_.empty() && last_subtask_id_ != subtask_id_) || get_model_mall_result_need_retry) {
if (!subtask_id_.empty() && last_subtask_id_ != subtask_id_) {
BOOST_LOG_TRIVIAL(info) << "update_model_task: last=" << last_subtask_id_ << ", curr=" << subtask_id_;
last_subtask_id_ = subtask_id_;
request_model_result = 0;
}
if (get_model_mall_result_need_retry) {
BOOST_LOG_TRIVIAL(info) << "need retry";
get_model_mall_result_need_retry = false;
}
} else {
BOOST_LOG_TRIVIAL(info) << "subtask_id_ no change and do not need retry";
return;
}
int curr_instance_id = model_task->instance_id;
if (rating_info) {
delete rating_info;
rating_info = nullptr;
}
get_model_task_thread = new boost::thread([this, curr_instance_id, token = std::weak_ptr<int>(m_token)]{
if (token.expired()) { return; }
try {
std::string rating_result;
unsigned int http_code = 404;
std::string http_error;
int res = -1;
res = m_agent->get_model_mall_rating_result(curr_instance_id, rating_result, http_code, http_error);
request_model_result++;
BOOST_LOG_TRIVIAL(info) << "request times: " << request_model_result << " http code: " << http_code;
auto rating_info = new RatingInfo();
rating_info->http_code = http_code;
if (0 == res && 200 == http_code) {
try {
json rating_json = json::parse(rating_result);
if (rating_json.contains("id")) {
rating_info->rating_id = rating_json["id"].get<unsigned int>();
//rating id is necessary info, so rating id must have
request_model_result = 0;
rating_info->request_successful = true;
BOOST_LOG_TRIVIAL(info) << "get rating id";
} else {
rating_info->request_successful = false;
BOOST_LOG_TRIVIAL(info) << "can not get rating id";
Slic3r::GUI::wxGetApp().CallAfter([this, token, rating_info]() {
if (!token.expired()) this->rating_info = rating_info;
});
return;
}
if (rating_json.contains("score")) {
rating_info->start_count = rating_json["score"].get<int>();
}
if (rating_json.contains("content"))
rating_info->content = rating_json["content"].get<std::string>();
if (rating_json.contains("successPrinted"))
rating_info->success_printed = rating_json["successPrinted"].get<bool>();
if (rating_json.contains("images")) {
rating_info->image_url_paths = rating_json["images"].get<std::vector<std::string>>();
}
Slic3r::GUI::wxGetApp().CallAfter([this, token, rating_info]() {
if (!token.expired()) this->rating_info = rating_info;
});
} catch (...) {
BOOST_LOG_TRIVIAL(info) << "parse model mall result json failed";
}
}
else {
rating_info->request_successful = false;
Slic3r::GUI::wxGetApp().CallAfter([this, token, rating_info]() {
if (!token.expired()) this->rating_info = rating_info;
});
BOOST_LOG_TRIVIAL(info) << "model mall result request failed, request time: " << request_model_result << " http_code: " << http_code
<< " error msg: " << http_error;
return;
}
}
catch (...) {
BOOST_LOG_TRIVIAL(info) << "get mall model rating id failed and hide scoring page";
}
});
}
void MachineObject::update_slice_info(std::string project_id, std::string profile_id, std::string subtask_id, int plate_idx)
{
if (!m_agent) return;
if (project_id_ != project_id || profile_id_ != profile_id || slice_info == nullptr || subtask_id_ != subtask_id) {
project_id_ = project_id;
profile_id_ = profile_id;
subtask_id_ = subtask_id;
if (project_id.empty()
|| profile_id.empty()
|| subtask_id.empty()) {
return;
}
if (project_id.compare("0") == 0
|| profile_id.compare("0") == 0
|| subtask_id.compare("0") == 0) return;
BOOST_LOG_TRIVIAL(trace) << "slice_info: start";
slice_info = new BBLSliceInfo();
get_slice_info_thread = new boost::thread([this, project_id, profile_id, subtask_id, plate_idx] {
int plate_index = -1;
if (!m_agent) return;
if (plate_idx >= 0) {
plate_index = plate_idx;
}
else {
std::string subtask_json;
unsigned http_code = 0;
std::string http_body;
if (m_agent->get_subtask_info(subtask_id, &subtask_json, &http_code, &http_body) == 0) {
try {
if (!subtask_json.empty()) {
json task_j = json::parse(subtask_json);
if (task_j.contains("content")) {
std::string content_str = task_j["content"].get<std::string>();
json content_j = json::parse(content_str);
plate_index = content_j["info"]["plate_idx"].get<int>();
}
if (task_j.contains("context") && task_j["context"].contains("plates")) {
for (int i = 0; i < task_j["context"]["plates"].size(); i++) {
if (task_j["context"]["plates"][i].contains("index") && task_j["context"]["plates"][i]["index"].get<int>() == plate_index) {
if (task_j["context"]["plates"][i].contains("thumbnail") && task_j["context"]["plates"][i]["thumbnail"].contains("url")) {
slice_info->thumbnail_url = task_j["context"]["plates"][i]["thumbnail"]["url"].get<std::string>();
}
if (task_j["context"]["plates"][i].contains("prediction")) {
slice_info->prediction = task_j["context"]["plates"][i]["prediction"].get<int>();
}
if (task_j["context"]["plates"][i].contains("weight")) {
slice_info->weight = task_j["context"]["plates"][i]["weight"].get<float>();
}
if (!task_j["context"]["plates"][i]["filaments"].is_null()) {
for (auto filament : task_j["context"]["plates"][i]["filaments"]) {
FilamentInfo f;
if(filament.contains("color")){
f.color = filament["color"].get<std::string>();
}
if (filament.contains("type")) {
f.type = filament["type"].get<std::string>();
}
if (filament.contains("used_g")) {
f.used_g = stof(filament["used_g"].get<std::string>());
}
if (filament.contains("used_m")) {
f.used_m = stof(filament["used_m"].get<std::string>());
}
slice_info->filaments_info.push_back(f);
}
}
BOOST_LOG_TRIVIAL(trace) << "task_info: thumbnail url=" << slice_info->thumbnail_url;
}
}
}
else {
BOOST_LOG_TRIVIAL(error) << "task_info: no context or plates";
}
}
}
catch (...) {
}
}
else {
BOOST_LOG_TRIVIAL(error) << "task_info: get subtask id failed!";
}
}
this->m_plate_index = plate_index;
});
}
}
void MachineObject::get_firmware_info()
{
m_firmware_valid = false;
if (m_firmware_thread_started)
return;
boost::thread update_info_thread = Slic3r::create_thread(
[&] {
m_firmware_thread_started = true;
int result = 0;
unsigned int http_code;
std::string http_body;
if (!m_agent) return;
result = m_agent->get_printer_firmware(dev_id, &http_code, &http_body);
if (result < 0) {
// get upgrade list failed
return;
}
try {
json j = json::parse(http_body);
if (j.contains("devices") && !j["devices"].is_null()) {
firmware_list.clear();
for (json::iterator it = j["devices"].begin(); it != j["devices"].end(); it++) {
if ((*it)["dev_id"].get<std::string>() == this->dev_id) {
try {
json firmware = (*it)["firmware"];
for (json::iterator firmware_it = firmware.begin(); firmware_it != firmware.end(); firmware_it++) {
FirmwareInfo item;
item.version = (*firmware_it)["version"].get<std::string>();
item.url = (*firmware_it)["url"].get<std::string>();
if ((*firmware_it).contains("description"))
item.description = (*firmware_it)["description"].get<std::string>();
item.module_type = "ota";
int name_start = item.url.find_last_of('/') + 1;
if (name_start > 0) {
item.name = item.url.substr(name_start, item.url.length() - name_start);
firmware_list.push_back(item);
}
else {
BOOST_LOG_TRIVIAL(trace) << "skip";
}
}
}
catch (...) {}
try {
if ((*it).contains("ams")) {
json ams_list = (*it)["ams"];
if (ams_list.size() > 0) {
auto ams_front = ams_list.front();
json firmware_ams = (ams_front)["firmware"];
for (json::iterator ams_it = firmware_ams.begin(); ams_it != firmware_ams.end(); ams_it++) {
FirmwareInfo item;
item.version = (*ams_it)["version"].get<std::string>();
item.url = (*ams_it)["url"].get<std::string>();
if ((*ams_it).contains("description"))
item.description = (*ams_it)["description"].get<std::string>();
item.module_type = "ams";
int name_start = item.url.find_last_of('/') + 1;
if (name_start > 0) {
item.name = item.url.substr(name_start, item.url.length() - name_start);
firmware_list.push_back(item);
}
else {
BOOST_LOG_TRIVIAL(trace) << "skip";
}
}
}
}
}
catch (...) {
;
}
}
}
}
}
catch (...) {
return;
}
m_firmware_thread_started = false;
m_firmware_valid = true;
}
);
return;
}
bool MachineObject::is_firmware_info_valid()
{
return m_firmware_valid;
}
std::string MachineObject::get_string_from_fantype(FanType type)
{
switch (type) {
case FanType::COOLING_FAN:
return "cooling_fan";
case FanType::BIG_COOLING_FAN:
return "big_cooling_fan";
case FanType::CHAMBER_FAN:
return "chamber_fan";
default:
return "";
}
return "";
}
void MachineObject::update_filament_list()
{
PresetBundle *preset_bundle = Slic3r::GUI::wxGetApp().preset_bundle;
// custom filament
std::map<std::string, std::pair<int, int>> filament_list;
for (auto &preset : preset_bundle->filaments()) {
if (preset.is_user() && preset.inherits() == "") {
ConfigOption * printer_opt = const_cast<Preset&>(preset).config.option("compatible_printers");
ConfigOptionStrings *printer_strs = dynamic_cast<ConfigOptionStrings *>(printer_opt);
for (const std::string &printer_str : printer_strs->values) {
if (printer_str == m_printer_preset_name) {
ConfigOption *opt_min = const_cast<Preset &>(preset).config.option("nozzle_temperature_range_low");
int min_temp = -1;
if (opt_min) {
ConfigOptionInts *opt_min_ints = dynamic_cast<ConfigOptionInts *>(opt_min);
min_temp = opt_min_ints->get_at(0);
}
ConfigOption *opt_max = const_cast<Preset &>(preset).config.option("nozzle_temperature_range_high");
int max_temp = -1;
if (opt_max) {
ConfigOptionInts *opt_max_ints = dynamic_cast<ConfigOptionInts *>(opt_max);
max_temp = opt_max_ints->get_at(0);
}
filament_list[preset.filament_id] = std::make_pair(min_temp, max_temp);
break;
}
}
}
}
for (auto it = filament_list.begin(); it != filament_list.end(); it++) {
if (m_filament_list.find(it->first) != m_filament_list.end()) {
assert(it->first.size() == 8 && it->first[0] == 'P');
if (it->second.first != m_filament_list[it->first].first) {
BOOST_LOG_TRIVIAL(info) << "old min temp is not equal to new min temp and filament id: " << it->first;
continue;
}
if (it->second.second != m_filament_list[it->first].second) {
BOOST_LOG_TRIVIAL(info) << "old max temp is not equal to new max temp and filament id: " << it->first;
continue;
}
m_filament_list.erase(it->first);
}
}
for (auto it = m_filament_list.begin(); it != m_filament_list.end(); it++) {
m_checked_filament.erase(it->first);
}
m_filament_list = filament_list;
}
void MachineObject::update_printer_preset_name(const std::string &nozzle_diameter_str)
{
BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << "start update preset_name";
auto preset_boundle = Slic3r::GUI::wxGetApp().preset_bundle;
auto printer_set = preset_boundle->get_printer_names_by_printer_type_and_nozzle(MachineObject::get_preset_printer_model_name(this->printer_type), nozzle_diameter_str);
if (printer_set.size() > 0)
m_printer_preset_name = *printer_set.begin();
else
BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << " update printer preset name failed ";
}
bool DeviceManager::EnableMultiMachine = false;
bool DeviceManager::key_field_only = false;
DeviceManager::DeviceManager(NetworkAgent* agent)
{
m_agent = agent;
}
DeviceManager::~DeviceManager()
{
for (auto it = localMachineList.begin(); it != localMachineList.end(); it++) {
if (it->second) {
delete it->second;
it->second = nullptr;
}
}
localMachineList.clear();
for (auto it = userMachineList.begin(); it != userMachineList.end(); it++) {
if (it->second) {
delete it->second;
it->second = nullptr;
}
}
userMachineList.clear();
}
void DeviceManager::set_agent(NetworkAgent* agent)
{
m_agent = agent;
}
void DeviceManager::keep_alive()
{
MachineObject* obj = this->get_selected_machine();
if (obj) {
if (obj->keep_alive_count == 0) {
obj->last_keep_alive = std::chrono::system_clock::now();
}
obj->keep_alive_count++;
std::chrono::system_clock::time_point start = std::chrono::system_clock::now();
auto internal = std::chrono::duration_cast<std::chrono::milliseconds>(start - obj->last_keep_alive);
if (internal.count() > TIMEOUT_FOR_KEEPALIVE && (internal.count() < 1000 * 60 * 60 * 300) ) {
BOOST_LOG_TRIVIAL(info) << "keep alive = " << internal.count() << ", count = " << obj->keep_alive_count;
obj->command_request_push_all();
obj->last_keep_alive = start;
}
else if(obj->m_push_count == 0){
BOOST_LOG_TRIVIAL(info) << "keep alive = " << internal.count() << ", push_count = 0, count = " << obj->keep_alive_count;
obj->command_request_push_all();
obj->last_keep_alive = start;
}
}
}
void DeviceManager::check_pushing()
{
keep_alive();
MachineObject* obj = this->get_selected_machine();
if (obj && !obj->is_support_mqtt_alive) {
std::chrono::system_clock::time_point start = std::chrono::system_clock::now();
auto internal = std::chrono::duration_cast<std::chrono::milliseconds>(start - obj->last_update_time);
if (internal.count() > TIMEOUT_FOR_STRAT && internal.count() < 1000 * 60 * 60 * 300) {
BOOST_LOG_TRIVIAL(info) << "command_pushing: diff = " << internal.count();
obj->command_pushing("start");
}
}
}
void DeviceManager::on_machine_alive(std::string json_str)
{
try {
BOOST_LOG_TRIVIAL(trace) << "DeviceManager::SsdpDiscovery, json" << json_str;
json j = json::parse(json_str);
std::string dev_name = j["dev_name"].get<std::string>();
std::string dev_id = j["dev_id"].get<std::string>();
std::string dev_ip = j["dev_ip"].get<std::string>();
std::string printer_type_str= j["dev_type"].get<std::string>();
std::string printer_signal = j["dev_signal"].get<std::string>();
std::string connect_type = j["connect_type"].get<std::string>();
std::string bind_state = j["bind_state"].get<std::string>();
if (connect_type == "farm") {
connect_type ="lan";
bind_state = "free";
}
std::string sec_link = "";
std::string ssdp_version = "";
if (j.contains("sec_link")) {
sec_link = j["sec_link"].get<std::string>();
}
if (j.contains("ssdp_version")) {
ssdp_version = j["ssdp_version"].get<std::string>();
}
std::string connection_name = "";
if (j.contains("connection_name")) {
connection_name = j["connection_name"].get<std::string>();
}
MachineObject* obj;
/* update userMachineList info */
auto it = userMachineList.find(dev_id);
if (it != userMachineList.end()) {
it->second->dev_ip = dev_ip;
it->second->bind_state = bind_state;
it->second->bind_sec_link = sec_link;
it->second->dev_connection_type = connect_type;
it->second->bind_ssdp_version = ssdp_version;
}
/* update localMachineList */
it = localMachineList.find(dev_id);
if (it != localMachineList.end()) {
// update properties
/* ip changed */
obj = it->second;
if (obj->dev_ip.compare(dev_ip) != 0) {
if ( connection_name.empty() ) {
BOOST_LOG_TRIVIAL(info) << "MachineObject IP changed from " << Slic3r::GUI::wxGetApp().format_IP(obj->dev_ip) << " to " << Slic3r::GUI::wxGetApp().format_IP(dev_ip);
obj->dev_ip = dev_ip;
}
else {
if ( obj->dev_connection_name.empty() || obj->dev_connection_name.compare(connection_name) == 0) {
BOOST_LOG_TRIVIAL(info) << "MachineObject IP changed from " << Slic3r::GUI::wxGetApp().format_IP(obj->dev_ip) << " to " << Slic3r::GUI::wxGetApp().format_IP(dev_ip) << " connection_name is " << connection_name;
if(obj->dev_connection_name.empty()){obj->dev_connection_name = connection_name;}
obj->dev_ip = dev_ip;
}
}
/* ip changed reconnect mqtt */
}
obj->wifi_signal = printer_signal;
obj->dev_connection_type= connect_type;
obj->bind_state = bind_state;
obj->bind_sec_link = sec_link;
obj->bind_ssdp_version = ssdp_version;
obj->printer_type = MachineObject::parse_printer_type(printer_type_str);
// U0 firmware
if (obj->dev_connection_type.empty() && obj->bind_state.empty())
obj->bind_state = "free";
BOOST_LOG_TRIVIAL(debug) << "SsdpDiscovery:: Update Machine Info, printer_sn = " << dev_id << ", signal = " << printer_signal;
obj->last_alive = Slic3r::Utils::get_current_time_utc();
obj->m_is_online = true;
/* if (!obj->dev_ip.empty()) {
Slic3r::GUI::wxGetApp().app_config->set_str("ip_address", obj->dev_id, obj->dev_ip);
Slic3r::GUI::wxGetApp().app_config->save();
}*/
}
else {
/* insert a new machine */
obj = new MachineObject(m_agent, dev_name, dev_id, dev_ip);
obj->printer_type = MachineObject::parse_printer_type(printer_type_str);
obj->wifi_signal = printer_signal;
obj->dev_connection_type = connect_type;
obj->bind_state = bind_state;
obj->bind_sec_link = sec_link;
obj->dev_connection_name = connection_name;
obj->bind_ssdp_version = ssdp_version;
obj->m_is_online = true;
//load access code
AppConfig* config = Slic3r::GUI::wxGetApp().app_config;
if (config) {
obj->set_access_code(Slic3r::GUI::wxGetApp().app_config->get("access_code", dev_id));
obj->set_user_access_code(Slic3r::GUI::wxGetApp().app_config->get("user_access_code", dev_id));
}
localMachineList.insert(std::make_pair(dev_id, obj));
/* if (!obj->dev_ip.empty()) {
Slic3r::GUI::wxGetApp().app_config->set_str("ip_address", obj->dev_id, obj->dev_ip);
Slic3r::GUI::wxGetApp().app_config->save();
}*/
BOOST_LOG_TRIVIAL(info) << "SsdpDiscovery::New Machine, ip = " << Slic3r::GUI::wxGetApp().format_IP(dev_ip) << ", printer_name= " << dev_name << ", printer_type = " << printer_type_str << ", signal = " << printer_signal;
}
}
catch (...) {
;
}
}
MachineObject* DeviceManager::insert_local_device(std::string dev_name, std::string dev_id, std::string dev_ip, std::string connection_type, std::string bind_state, std::string version, std::string access_code)
{
MachineObject* obj;
obj = new MachineObject(m_agent, dev_name, dev_id, dev_ip);
obj->printer_type = MachineObject::parse_printer_type("C11");
obj->dev_connection_type = connection_type;
obj->bind_state = bind_state;
obj->bind_sec_link = "secure";
obj->bind_ssdp_version = version;
obj->m_is_online = true;
obj->set_access_code(access_code, false);
obj->set_user_access_code(access_code, false);
return obj;
}
void DeviceManager::disconnect_all()
{
}
int DeviceManager::query_bind_status(std::string &msg)
{
if (!m_agent) {
msg = "";
return -1;
}
BOOST_LOG_TRIVIAL(trace) << "DeviceManager::query_bind_status";
std::map<std::string, MachineObject*>::iterator it;
std::vector<std::string> query_list;
for (it = localMachineList.begin(); it != localMachineList.end(); it++) {
query_list.push_back(it->first);
}
unsigned int http_code;
std::string http_body;
int result = m_agent->query_bind_status(query_list, &http_code, &http_body);
if (result < 0) {
msg = (boost::format("code=%1%,body=%2") % http_code % http_body).str();
} else {
msg = "";
try {
json j = json::parse(http_body);
if (j.contains("bind_list")) {
for (auto& item : j["bind_list"]) {
auto it = localMachineList.find(item["dev_id"].get<std::string>());
if (it != localMachineList.end()) {
if (!item["user_id"].is_null())
it->second->bind_user_id = item["user_id"].get<std::string>();
if (!item["user_name"].is_null())
it->second->bind_user_name = item["user_name"].get<std::string>();
else
it->second->bind_user_name = "Free";
}
}
}
} catch(...) {
;
}
}
return result;
}
MachineObject* DeviceManager::get_local_selected_machine()
{
return get_local_machine(local_selected_machine);
}
void DeviceManager::reload_printer_settings()
{
for (auto obj : this->userMachineList)
obj.second->reload_printer_settings();
}
MachineObject* DeviceManager::get_default_machine() {
std::string dev_id;
if (m_agent) {
m_agent->get_user_selected_machine();
}
if (dev_id.empty()) return nullptr;
auto it = userMachineList.find(dev_id);
if (it == userMachineList.end()) return nullptr;
return it->second;
}
MachineObject* DeviceManager::get_local_machine(std::string dev_id)
{
if (dev_id.empty()) return nullptr;
auto it = localMachineList.find(dev_id);
if (it == localMachineList.end()) return nullptr;
return it->second;
}
void DeviceManager::erase_user_machine(std::string dev_id)
{
userMachineList.erase(dev_id);
}
MachineObject* DeviceManager::get_user_machine(std::string dev_id)
{
if (!Slic3r::GUI::wxGetApp().is_user_login())
return nullptr;
std::map<std::string, MachineObject*>::iterator it = userMachineList.find(dev_id);
if (it == userMachineList.end()) return nullptr;
return it->second;
}
MachineObject* DeviceManager::get_my_machine(std::string dev_id)
{
auto list = get_my_machine_list();
auto it = list.find(dev_id);
if (it != list.end()) {
return it->second;
}
return nullptr;
}
void DeviceManager::clean_user_info()
{
BOOST_LOG_TRIVIAL(trace) << "DeviceManager::clean_user_info";
// reset selected_machine
selected_machine = "";
local_selected_machine = "";
// clean access code
for (auto it = userMachineList.begin(); it != userMachineList.end(); it++) {
it->second->set_access_code("");
}
// clean user list
for (auto it = userMachineList.begin(); it != userMachineList.end(); it++) {
if (it->second) {
delete it->second;
it->second = nullptr;
}
}
userMachineList.clear();
}
bool DeviceManager::set_selected_machine(std::string dev_id, bool need_disconnect)
{
BOOST_LOG_TRIVIAL(info) << "set_selected_machine=" << dev_id;
auto my_machine_list = get_my_machine_list();
auto it = my_machine_list.find(dev_id);
// disconnect last
auto last_selected = my_machine_list.find(selected_machine);
if (last_selected != my_machine_list.end()) {
last_selected->second->m_active_state = MachineObject::NotActive;
if (last_selected->second->connection_type() == "lan") {
if (last_selected->second->is_connecting() && !need_disconnect)
return false;
if (!need_disconnect) {m_agent->disconnect_printer(); }
}
}
// connect curr
if (it != my_machine_list.end()) {
if (selected_machine == dev_id) {
if (it->second->connection_type() != "lan") {
// only reset update time
it->second->reset_update_time();
// check subscribe state
Slic3r::GUI::wxGetApp().on_start_subscribe_again(dev_id);
return true;
} else {
// lan mode printer reconnect printer
if (m_agent) {
if (!need_disconnect) {m_agent->disconnect_printer();}
it->second->reset();
#if !BBL_RELEASE_TO_PUBLIC
it->second->connect(false, Slic3r::GUI::wxGetApp().app_config->get("enable_ssl_for_mqtt") == "true" ? true : false);
#else
it->second->connect(false, it->second->local_use_ssl_for_mqtt);
#endif
it->second->set_lan_mode_connection_state(true);
}
}
} else {
if (m_agent) {
if (it->second->connection_type() != "lan" || it->second->connection_type().empty()) {
if (m_agent->get_user_selected_machine() == dev_id) {
it->second->reset_update_time();
}
else {
BOOST_LOG_TRIVIAL(info) << "static: set_selected_machine: same dev_id = " << dev_id;
m_agent->set_user_selected_machine(dev_id);
it->second->reset();
}
} else {
BOOST_LOG_TRIVIAL(info) << "static: set_selected_machine: same dev_id = empty";
m_agent->set_user_selected_machine("");
it->second->reset();
#if !BBL_RELEASE_TO_PUBLIC
it->second->connect(false, Slic3r::GUI::wxGetApp().app_config->get("enable_ssl_for_mqtt") == "true" ? true : false);
#else
it->second->connect(false, it->second->local_use_ssl_for_mqtt);
#endif
it->second->set_lan_mode_connection_state(true);
}
}
}
it->second->m_checked_filament.clear();
}
selected_machine = dev_id;
return true;
}
MachineObject* DeviceManager::get_selected_machine()
{
if (selected_machine.empty()) return nullptr;
MachineObject* obj = get_user_machine(selected_machine);
if (obj)
return obj;
// return local machine has access code
auto it = localMachineList.find(selected_machine);
if (it != localMachineList.end()) {
if (it->second->has_access_right())
return it->second;
}
return nullptr;
}
void DeviceManager::add_user_subscribe()
{
/* user machine */
std::vector<std::string> dev_list;
for (auto it = userMachineList.begin(); it != userMachineList.end(); it++) {
dev_list.push_back(it->first);
BOOST_LOG_TRIVIAL(trace) << "add_user_subscribe: " << it->first;
}
m_agent->add_subscribe(dev_list);
}
void DeviceManager::del_user_subscribe()
{
/* user machine */
std::vector<std::string> dev_list;
for (auto it = userMachineList.begin(); it != userMachineList.end(); it++) {
dev_list.push_back(it->first);
BOOST_LOG_TRIVIAL(trace) << "del_user_subscribe: " << it->first;
}
m_agent->del_subscribe(dev_list);
}
void DeviceManager::subscribe_device_list(std::vector<std::string> dev_list)
{
std::vector<std::string> unsub_list;
subscribe_list_cache.clear();
for (auto& it : subscribe_list_cache) {
if (it != selected_machine) {
unsub_list.push_back(it);
BOOST_LOG_TRIVIAL(trace) << "subscribe_device_list: unsub dev id = " << it;
}
}
BOOST_LOG_TRIVIAL(trace) << "subscribe_device_list: unsub_list size = " << unsub_list.size();
if (!selected_machine.empty()) {
subscribe_list_cache.push_back(selected_machine);
}
for (auto& it : dev_list) {
subscribe_list_cache.push_back(it);
BOOST_LOG_TRIVIAL(trace) << "subscribe_device_list: sub dev id = " << it;
}
BOOST_LOG_TRIVIAL(trace) << "subscribe_device_list: sub_list size = " << subscribe_list_cache.size();
if (!unsub_list.empty())
m_agent->del_subscribe(unsub_list);
if (!dev_list.empty())
m_agent->add_subscribe(subscribe_list_cache);
}
std::map<std::string, MachineObject*> DeviceManager::get_my_machine_list()
{
std::map<std::string, MachineObject*> result;
for (auto it = userMachineList.begin(); it != userMachineList.end(); it++) {
if (!it->second)
continue;
if (!it->second->is_lan_mode_printer())
result.insert(std::make_pair(it->first, it->second));
}
for (auto it = localMachineList.begin(); it != localMachineList.end(); it++) {
if (!it->second)
continue;
if (it->second->has_access_right() && it->second->is_avaliable() && it->second->is_lan_mode_printer()) {
// remove redundant in userMachineList
if (result.find(it->first) == result.end()) {
result.emplace(std::make_pair(it->first, it->second));
}
}
}
return result;
}
std::map<std::string, MachineObject*> DeviceManager::get_my_cloud_machine_list()
{
std::map<std::string, MachineObject*> result;
for (auto it = userMachineList.begin(); it != userMachineList.end(); it++) {
if (!it->second)
continue;
if (!it->second->is_lan_mode_printer())
result.emplace(*it);
}
return result;
}
std::string DeviceManager::get_first_online_user_machine() {
for (auto it = userMachineList.begin(); it != userMachineList.end(); it++) {
if (it->second && it->second->is_online()) {
return it->second->dev_id;
}
}
return "";
}
void DeviceManager::modify_device_name(std::string dev_id, std::string dev_name)
{
BOOST_LOG_TRIVIAL(trace) << "modify_device_name";
if (m_agent) {
int result = m_agent->modify_printer_name(dev_id, dev_name);
if (result == 0) {
update_user_machine_list_info();
}
}
}
void DeviceManager::parse_user_print_info(std::string body)
{
BOOST_LOG_TRIVIAL(trace) << "DeviceManager::parse_user_print_info";
std::lock_guard<std::mutex> lock(listMutex);
std::set<std::string> new_list;
try {
json j = json::parse(body);
if (j.contains("devices") && !j["devices"].is_null()) {
for (auto& elem : j["devices"]) {
MachineObject* obj = nullptr;
std::string dev_id;
if (!elem["dev_id"].is_null()) {
dev_id = elem["dev_id"].get<std::string>();
new_list.insert(dev_id);
}
std::map<std::string, MachineObject*>::iterator iter = userMachineList.find(dev_id);
if (iter != userMachineList.end()) {
/* update field */
obj = iter->second;
obj->dev_id = dev_id;
}
else {
obj = new MachineObject(m_agent, "", "", "");
if (m_agent) {
obj->set_bind_status(m_agent->get_user_name());
}
if (obj->dev_ip.empty()) {
obj->dev_ip = Slic3r::GUI::wxGetApp().app_config->get("ip_address", dev_id);
}
userMachineList.insert(std::make_pair(dev_id, obj));
}
if (!obj) continue;
if (!elem["dev_id"].is_null())
obj->dev_id = elem["dev_id"].get<std::string>();
if (!elem["dev_name"].is_null())
obj->dev_name = elem["dev_name"].get<std::string>();
if (!elem["dev_online"].is_null())
obj->m_is_online = elem["dev_online"].get<bool>();
if (elem.contains("dev_model_name") && !elem["dev_model_name"].is_null())
obj->printer_type = elem["dev_model_name"].get<std::string>();
if (!elem["task_status"].is_null())
obj->iot_print_status = elem["task_status"].get<std::string>();
if (elem.contains("dev_product_name") && !elem["dev_product_name"].is_null())
obj->product_name = elem["dev_product_name"].get<std::string>();
if (elem.contains("dev_access_code") && !elem["dev_access_code"].is_null()) {
std::string acc_code = elem["dev_access_code"].get<std::string>();
acc_code.erase(std::remove(acc_code.begin(), acc_code.end(), '\n'), acc_code.end());
obj->set_access_code(acc_code);
}
}
//remove MachineObject from userMachineList
std::map<std::string, MachineObject*>::iterator iterat;
for (iterat = userMachineList.begin(); iterat != userMachineList.end(); ) {
if (new_list.find(iterat->first) == new_list.end()) {
iterat = userMachineList.erase(iterat);
}
else {
iterat++;
}
}
}
}
catch (std::exception&) {
;
}
}
void DeviceManager::update_user_machine_list_info()
{
if (!m_agent) return;
BOOST_LOG_TRIVIAL(debug) << "update_user_machine_list_info";
unsigned int http_code;
std::string body;
int result = m_agent->get_user_print_info(&http_code, &body);
if (result == 0) {
parse_user_print_info(body);
}
}
std::map<std::string ,MachineObject*> DeviceManager::get_local_machine_list()
{
std::map<std::string, MachineObject*> result;
std::map<std::string, MachineObject*>::iterator it;
for (it = localMachineList.begin(); it != localMachineList.end(); it++) {
if (it->second->m_is_online) {
result.insert(std::make_pair(it->first, it->second));
}
}
return result;
}
void DeviceManager::load_last_machine()
{
if (userMachineList.empty()) return;
else if (userMachineList.size() == 1) {
this->set_selected_machine(userMachineList.begin()->second->dev_id);
} else {
if (m_agent) {
std::string last_monitor_machine = m_agent->get_user_selected_machine();
bool found = false;
for (auto it = userMachineList.begin(); it != userMachineList.end(); it++) {
if (last_monitor_machine == it->first) {
this->set_selected_machine(last_monitor_machine);
found = true;
}
}
if (!found)
this->set_selected_machine(userMachineList.begin()->second->dev_id);
}
}
}
json DeviceManager::filaments_blacklist = json::object();
std::string DeviceManager::parse_printer_type(std::string type_str)
{
return get_value_from_config<std::string>(type_str, "printer_type");
}
std::string DeviceManager::get_printer_display_name(std::string type_str)
{
return get_value_from_config<std::string>(type_str, "display_name");
}
std::string DeviceManager::get_ftp_folder(std::string type_str)
{
return get_value_from_config<std::string>(type_str, "ftp_folder");
}
PrinterArch DeviceManager::get_printer_arch(std::string type_str)
{
return get_printer_arch_by_str(get_value_from_config<std::string>(type_str, "printer_arch"));
}
std::string DeviceManager::get_printer_thumbnail_img(std::string type_str)
{
return get_value_from_config<std::string>(type_str, "printer_thumbnail_image");
}
std::string DeviceManager::get_printer_ams_type(std::string type_str)
{
return get_value_from_config<std::string>(type_str, "use_ams_type");
}
std::string DeviceManager::get_printer_series(std::string type_str)
{
return get_value_from_config<std::string>(type_str, "printer_series");
}
std::string DeviceManager::get_printer_diagram_img(std::string type_str)
{
return get_value_from_config<std::string>(type_str, "printer_connect_help_image");
}
std::string DeviceManager::get_printer_ams_img(std::string type_str)
{
return get_value_from_config<std::string>(type_str, "printer_use_ams_image");
}
bool DeviceManager::get_printer_is_enclosed(std::string type_str) {
return get_value_from_config<bool>(type_str, "printer_is_enclosed");
}
std::vector<std::string> DeviceManager::get_resolution_supported(std::string type_str)
{
std::vector<std::string> resolution_supported;
std::string config_file = Slic3r::resources_dir() + "/printers/" + type_str + ".json";
boost::nowide::ifstream json_file(config_file.c_str());
try {
json jj;
if (json_file.is_open()) {
json_file >> jj;
if (jj.contains("00.00.00.00")) {
json const& printer = jj["00.00.00.00"];
if (printer.contains("camera_resolution")) {
for (auto res : printer["camera_resolution"])
resolution_supported.emplace_back(res.get<std::string>());
}
}
}
}
catch (...) {}
return resolution_supported;
}
std::vector<std::string> DeviceManager::get_compatible_machine(std::string type_str)
{
std::vector<std::string> compatible_machine;
std::string config_file = Slic3r::resources_dir() + "/printers/" + type_str + ".json";
boost::nowide::ifstream json_file(config_file.c_str());
try {
json jj;
if (json_file.is_open()) {
json_file >> jj;
if (jj.contains("00.00.00.00")) {
json const& printer = jj["00.00.00.00"];
if (printer.contains("compatible_machine")) {
for (auto res : printer["compatible_machine"])
compatible_machine.emplace_back(res.get<std::string>());
}
}
}
}
catch (...) {}
return compatible_machine;
}
bool DeviceManager::load_filaments_blacklist_config()
{
filaments_blacklist = json::object();
std::string config_file = Slic3r::resources_dir() + "/printers/filaments_blacklist.json";
boost::nowide::ifstream json_file(config_file.c_str());
try {
if (json_file.is_open()) {
json_file >> filaments_blacklist;
return true;
}
else {
BOOST_LOG_TRIVIAL(error) << "load filaments blacklist config failed, file = " << config_file;
}
}
catch (...) {
BOOST_LOG_TRIVIAL(error) << "load filaments blacklist config failed, file = " << config_file;
return false;
}
return true;
}
void DeviceManager::check_filaments_in_blacklist(std::string tag_vendor, std::string tag_type, bool& in_blacklist, std::string& ac, std::string& info)
{
std::unordered_map<std::string, wxString> blacklist_prompt =
{
{"TPU: not supported", _L("TPU is not supported by AMS.")},
{"Bambu PET-CF/PA6-CF: not supported", _L("Bambu PET-CF/PA6-CF is not supported by AMS.")},
{"PVA: flexible", _L("Damp PVA will become flexible and get stuck inside AMS,please take care to dry it before use.")},
{"CF/GF: hard and brittle", _L("CF/GF filaments are hard and brittle, It's easy to break or get stuck in AMS, please use with caution.")}
};
in_blacklist = false;
if (filaments_blacklist.contains("blacklist")) {
for (auto prohibited_filament : filaments_blacklist["blacklist"]) {
std::string vendor;
std::string type;
std::string action;
std::string description;
if (prohibited_filament.contains("vendor") &&
prohibited_filament.contains("type") &&
prohibited_filament.contains("action") &&
prohibited_filament.contains("description"))
{
vendor = prohibited_filament["vendor"].get<std::string>();
type = prohibited_filament["type"].get<std::string>();
if (GUI::wxGetApp().app_config->get("skip_ams_blacklist_check") == "true") {
action = "warning";
}
else {
action = prohibited_filament["action"].get<std::string>();
}
description = prohibited_filament["description"].get<std::string>();
description = blacklist_prompt[description].ToUTF8().data();
}
else {
return;
}
std::transform(vendor.begin(), vendor.end(), vendor.begin(), ::tolower);
std::transform(tag_vendor.begin(), tag_vendor.end(), tag_vendor.begin(), ::tolower);
std::transform(tag_type.begin(), tag_type.end(), tag_type.begin(), ::tolower);
std::transform(type.begin(), type.end(), type.begin(), ::tolower);
//third party
if (vendor == "third party") {
if ("bambulab" != vendor && tag_type == type) {
in_blacklist = true;
ac = action;
info = description;
return;
}
}
else {
if (vendor == tag_vendor && tag_type == type) {
in_blacklist = true;
ac = action;
info = description;
return;
}
}
}
}
}
std::string DeviceManager::load_gcode(std::string type_str, std::string gcode_file)
{
std::string gcode_full_path = Slic3r::resources_dir() + "/printers/" + gcode_file;
std::ifstream gcode(encode_path(gcode_full_path.c_str()).c_str());
try {
std::stringstream gcode_str;
if (gcode.is_open()) {
gcode_str << gcode.rdbuf();
gcode.close();
return gcode_str.str();
}
} catch(...) {
BOOST_LOG_TRIVIAL(error) << "load gcode file failed, file = " << gcode_file << ", path = " << gcode_full_path;
}
return "";
}
void change_the_opacity(wxColour& colour)
{
if (colour.Alpha() == 255) {
colour = wxColour(colour.Red(), colour.Green(), colour.Blue(), 254);
}
}
} // namespace Slic3r
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