void ToolManager::on_get_public_data(void* argument)
{
PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
if(!pdr->starts_with(tool_manager_checksum)) return;
if(pdr->second_element_is(is_active_tool_checksum)) {
// check that we control the given tool
bool managed = false;
for(auto t : tools) {
uint16_t n = t->get_name();
if(pdr->third_element_is(n)) {
managed = true;
break;
}
}
// we are not managing this tool so do not answer
if(!managed) return;
pdr->set_data_ptr(&this->current_tool_name);
pdr->set_taken();
}else if(pdr->second_element_is(get_active_tool_checksum)) {
pdr->set_data_ptr(&this->active_tool);
pdr->set_taken();
}
}
void Extruder::on_set_public_data(void *argument)
{
PublicDataRequest *pdr = static_cast<PublicDataRequest *>(argument);
if(!pdr->starts_with(extruder_checksum)) return;
// handle extrude rates request from robot
if(pdr->second_element_is(target_checksum)) {
// disabled extruders do not reply NOTE only one enabled extruder supported
if(!this->enabled) return;
float *d = static_cast<float *>(pdr->get_data_ptr());
float target = d[0]; // the E passed in on Gcode is in mm³ (maybe absolute or relative)
float isecs = d[1]; // inverted secs
// check against maximum speeds and return rate modifier
d[1] = check_max_speeds(target, isecs);
pdr->set_taken();
return;
}
// save or restore state
if(pdr->second_element_is(save_state_checksum)) {
this->saved_current_position = this->current_position;
this->saved_absolute_mode = this->absolute_mode;
pdr->set_taken();
} else if(pdr->second_element_is(restore_state_checksum)) {
// NOTE this only gets called when the queue is empty so the milestones will be the same
this->milestone_last_position= this->current_position = this->saved_current_position;
this->milestone_absolute_mode= this->absolute_mode = this->saved_absolute_mode;
pdr->set_taken();
}
}
void Robot::on_set_public_data(void *argument)
{
PublicDataRequest *pdr = static_cast<PublicDataRequest *>(argument);
if(!pdr->starts_with(robot_checksum)) return;
if(pdr->second_element_is(speed_override_percent_checksum)) {
// NOTE do not use this while printing!
float t = *static_cast<float *>(pdr->get_data_ptr());
// enforce minimum 10% speed
if (t < 10.0F) t = 10.0F;
this->seconds_per_minute = t / 0.6F; // t * 60 / 100
pdr->set_taken();
} else if(pdr->second_element_is(current_position_checksum)) {
float *t = static_cast<float *>(pdr->get_data_ptr());
for (int i = 0; i < 3; i++) {
this->last_milestone[i] = this->to_millimeters(t[i]);
}
float actuator_pos[3];
arm_solution->cartesian_to_actuator(last_milestone, actuator_pos);
for (int i = 0; i < 3; i++)
actuators[i]->change_last_milestone(actuator_pos[i]);
pdr->set_taken();
}
}
void TemperatureControl::on_get_public_data(void *argument)
{
PublicDataRequest *pdr = static_cast<PublicDataRequest *>(argument);
if(!pdr->starts_with(temperature_control_checksum)) return;
if(pdr->second_element_is(pool_index_checksum)) {
// asking for our instance pointer if we have this pool_index
if(pdr->third_element_is(this->pool_index)) {
static void *return_data;
return_data = this;
pdr->set_data_ptr(&return_data);
pdr->set_taken();
}
return;
} else if(!pdr->second_element_is(this->name_checksum)) return;
// ok this is targeted at us, so send back the requested data
if(pdr->third_element_is(current_temperature_checksum)) {
this->public_data_return.current_temperature = this->get_temperature();
this->public_data_return.target_temperature = (target_temperature == UNDEFINED) ? 0 : this->target_temperature;
this->public_data_return.pwm = this->o;
this->public_data_return.designator= this->designator;
pdr->set_data_ptr(&this->public_data_return);
pdr->set_taken();
}
}
void TemperatureControl::on_get_public_data(void *argument)
{
PublicDataRequest *pdr = static_cast<PublicDataRequest *>(argument);
if(!pdr->starts_with(temperature_control_checksum)) return;
if(pdr->second_element_is(pool_index_checksum)) {
// asking for our instance pointer if we have this pool_index
if(pdr->third_element_is(this->pool_index)) {
static void *return_data;
return_data = this;
pdr->set_data_ptr(&return_data);
pdr->set_taken();
}
}else if(pdr->second_element_is(poll_controls_checksum)) {
// polling for all temperature controls
// add our data to the list which is passed in via the data_ptr
std::vector<struct pad_temperature> *v= static_cast<std::vector<pad_temperature>*>(pdr->get_data_ptr());
struct pad_temperature t;
// setup data
t.current_temperature = this->get_temperature();
t.target_temperature = (target_temperature <= 0) ? 0 : this->target_temperature;
t.pwm = this->o;
t.designator= this->designator;
t.id= this->name_checksum;
v->push_back(t);
pdr->set_taken();
}else if(pdr->second_element_is(current_temperature_checksum)) {
// if targeted at us
if(pdr->third_element_is(this->name_checksum)) {
// ok this is targeted at us, so set the requ3sted data in the pointer passed into us
struct pad_temperature *t= static_cast<pad_temperature*>(pdr->get_data_ptr());
t->current_temperature = this->get_temperature();
t->target_temperature = (target_temperature <= 0) ? 0 : this->target_temperature;
t->pwm = this->o;
t->designator= this->designator;
t->id= this->name_checksum;
pdr->set_taken();
}
}
}
void Player::on_set_public_data(void* argument) {
PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
if(!pdr->starts_with(player_checksum)) return;
if(pdr->second_element_is(abort_play_checksum)) {
abort_command("", &(StreamOutput::NullStream));
pdr->set_taken();
}
}
void Extruder::on_get_public_data(void* argument) {
PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
if(!pdr->starts_with(extruder_checksum)) return;
if(this->enabled) {
// Note this is allowing both step/mm and filament diameter to be exposed via public data
pdr->set_data_ptr(&this->steps_per_millimeter);
pdr->set_taken();
}
}
void TemperatureControl::on_set_public_data(void* argument){
PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
if(!pdr->starts_with(temperature_control_checksum)) return;
if(!pdr->second_element_is(this->name_checksum)) return; // will be bed or hotend
// ok this is targeted at us, so set the temp
float t= *static_cast<float*>(pdr->get_data_ptr());
this->set_desired_temperature(t);
pdr->set_taken();
}
void Switch::on_set_public_data(void *argument)
{
PublicDataRequest *pdr = static_cast<PublicDataRequest *>(argument);
if(!pdr->starts_with(switch_checksum)) return;
if(!pdr->second_element_is(this->name_checksum)) return; // likely fan, but could be anything
// ok this is targeted at us, so set the value
if(pdr->third_element_is(state_checksum)) {
bool t = *static_cast<bool *>(pdr->get_data_ptr());
this->switch_state = t;
pdr->set_taken();
this->switch_changed= true;
} else if(pdr->third_element_is(value_checksum)) {
float t = *static_cast<float *>(pdr->get_data_ptr());
this->switch_value = t;
pdr->set_taken();
}
}
void Robot::on_get_public_data(void* argument){
PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
if(!pdr->starts_with(robot_checksum)) return;
if(pdr->second_element_is(speed_override_percent_checksum)) {
static double return_data;
return_data= 100*this->seconds_per_minute/60;
pdr->set_data_ptr(&return_data);
pdr->set_taken();
}else if(pdr->second_element_is(current_position_checksum)) {
static double return_data[3];
return_data[0]= from_millimeters(this->current_position[0]);
return_data[1]= from_millimeters(this->current_position[1]);
return_data[2]= from_millimeters(this->current_position[2]);
pdr->set_data_ptr(&return_data);
pdr->set_taken();
}
}
void Player::on_get_public_data(void* argument) {
PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
if(!pdr->starts_with(player_checksum)) return;
if(pdr->second_element_is(is_playing_checksum)) {
static bool bool_data;
bool_data= this->playing_file;
pdr->set_data_ptr(&bool_data);
pdr->set_taken();
}else if(pdr->second_element_is(get_progress_checksum)) {
static struct pad_progress p;
if(file_size > 0 && playing_file) {
p.elapsed_secs= this->elapsed_secs;
p.percent_complete= (this->file_size - (this->file_size - this->played_cnt)) * 100 / this->file_size;
p.filename= this->filename;
pdr->set_data_ptr(&p);
pdr->set_taken();
}
}
}
void TemperatureControl::on_set_public_data(void *argument)
{
PublicDataRequest *pdr = static_cast<PublicDataRequest *>(argument);
if(!pdr->starts_with(temperature_control_checksum)) return;
if(!pdr->second_element_is(this->name_checksum)) return;
// ok this is targeted at us, so set the temp
// NOTE unlike the M code this will set the temp now not when the queue is empty
float t = *static_cast<float *>(pdr->get_data_ptr());
this->set_desired_temperature(t);
pdr->set_taken();
}
void Network::on_get_public_data(void* argument) {
PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
if(!pdr->starts_with(network_checksum)) return;
if(pdr->second_element_is(get_ip_checksum)) {
pdr->set_data_ptr(this->ipaddr);
pdr->set_taken();
}else if(pdr->second_element_is(get_ipconfig_checksum)) {
// NOTE caller must free the returned string when done
char buf[200];
int n1= snprintf(buf, sizeof(buf), "IP Addr: %d.%d.%d.%d\n", ipaddr[0], ipaddr[1], ipaddr[2], ipaddr[3]);
int n2= snprintf(&buf[n1], sizeof(buf)-n1, "IP GW: %d.%d.%d.%d\n", ipgw[0], ipgw[1], ipgw[2], ipgw[3]);
int n3= snprintf(&buf[n1+n2], sizeof(buf)-n1-n2, "IP mask: %d.%d.%d.%d\n", ipmask[0], ipmask[1], ipmask[2], ipmask[3]);
int n4= snprintf(&buf[n1+n2+n3], sizeof(buf)-n1-n2-n3, "MAC Address: %02X:%02X:%02X:%02X:%02X:%02X\n",
mac_address[0], mac_address[1], mac_address[2], mac_address[3], mac_address[4], mac_address[5]);
char *str = (char *)malloc(n1+n2+n3+n4+1);
memcpy(str, buf, n1+n2+n3+n4);
str[n1+n2+n3+n4]= '\0';
pdr->set_data_ptr(str);
pdr->set_taken();
}
}
void Robot::on_set_public_data(void* argument){
PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
if(!pdr->starts_with(robot_checksum)) return;
if(pdr->second_element_is(speed_override_percent_checksum)) {
// NOTE do not use this while printing!
double t= *static_cast<double*>(pdr->get_data_ptr());
// enforce minimum 10% speed
if (t < 10.0) t= 10.0;
this->seconds_per_minute= t * 0.6;
pdr->set_taken();
}
}
void Switch::on_get_public_data(void *argument)
{
PublicDataRequest *pdr = static_cast<PublicDataRequest *>(argument);
if(!pdr->starts_with(switch_checksum)) return;
if(!pdr->second_element_is(this->name_checksum)) return; // likely fan, but could be anything
// ok this is targeted at us, so send back the requested data
// this must be static as it will be accessed long after we have returned
static struct pad_switch pad;
pad.name = this->name_checksum;
pad.state = this->switch_state;
pad.value = this->switch_value;
pdr->set_data_ptr(&pad);
pdr->set_taken();
}
void TemperatureControl::on_get_public_data(void* argument){
PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
if(!pdr->starts_with(temperature_control_checksum)) return;
if(!pdr->second_element_is(this->name_checksum)) return; // will be bed or hotend
// ok this is targeted at us, so send back the requested data
if(pdr->third_element_is(current_temperature_checksum)) {
// this must be static as it will be accessed long after we have returned
static struct pad_temperature temp_return;
temp_return.current_temperature= this->get_temperature();
temp_return.target_temperature= (target_temperature == UNDEFINED) ? 0 : this->target_temperature;
temp_return.pwm= this->o;
pdr->set_data_ptr(&temp_return);
pdr->set_taken();
}
}