[clinton/Smoothieware.git] / src / modules / tools / temperaturecontrol / TemperatureControl.cpp

/*
      This file is part of Smoothie (http://smoothieware.org/). The motion control part is heavily based on Grbl (https://github.com/simen/grbl).
      Smoothie is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version.
      Smoothie is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.
      You should have received a copy of the GNU General Public License along with Smoothie. If not, see <http://www.gnu.org/licenses/>.
*/

// TODO : THIS FILE IS LAME, MUST BE MADE MUCH BETTER

#include "libs/Module.h"
#include "libs/Kernel.h"
#include <math.h>
#include "TemperatureControl.h"
#include "TemperatureControlPool.h"
#include "libs/Pin.h"
#include "libs/Median.h"
#include "modules/robot/Conveyor.h"
#include "PublicDataRequest.h"

#include "MRI_Hooks.h"

TemperatureControl::TemperatureControl(uint16_t name) :
  name_checksum(name), waiting(false), min_temp_violated(false) {}

void TemperatureControl::on_module_loaded(){

    // We start not desiring any temp
    this->target_temperature = UNDEFINED;

    // Settings
    this->on_config_reload(this);

    this->acceleration_factor = 10;

    // Register for events
    register_for_event(ON_CONFIG_RELOAD);
    this->register_for_event(ON_GCODE_EXECUTE);
    this->register_for_event(ON_GCODE_RECEIVED);
    this->register_for_event(ON_MAIN_LOOP);
    this->register_for_event(ON_SECOND_TICK);
    this->register_for_event(ON_GET_PUBLIC_DATA);
    this->register_for_event(ON_SET_PUBLIC_DATA);
}

void TemperatureControl::on_main_loop(void* argument){
    if (this->min_temp_violated) {
        kernel->streams->printf("Error: MINTEMP triggered on P%d.%d! check your thermistors!\n", this->thermistor_pin.port_number, this->thermistor_pin.pin);
        this->min_temp_violated = false;
    }
}

// Get configuration from the config file
void TemperatureControl::on_config_reload(void* argument){

    // General config
    this->set_m_code          = this->kernel->config->value(temperature_control_checksum, this->name_checksum, set_m_code_checksum)->by_default(104)->as_number();
    this->set_and_wait_m_code = this->kernel->config->value(temperature_control_checksum, this->name_checksum, set_and_wait_m_code_checksum)->by_default(109)->as_number();
    this->get_m_code          = this->kernel->config->value(temperature_control_checksum, this->name_checksum, get_m_code_checksum)->by_default(105)->as_number();
    this->readings_per_second = this->kernel->config->value(temperature_control_checksum, this->name_checksum, readings_per_second_checksum)->by_default(20)->as_number();

    this->designator          = this->kernel->config->value(temperature_control_checksum, this->name_checksum, designator_checksum)->by_default(string("T"))->as_string();

    // Values are here : http://reprap.org/wiki/Thermistor
    this->r0   = 100000;
    this->t0   = 25;
    this->beta = 4066;
    this->r1   = 0;
    this->r2   = 4700;

    // Preset values for various common types of thermistors
    ConfigValue* thermistor = this->kernel->config->value(temperature_control_checksum, this->name_checksum, thermistor_checksum);
    if(       thermistor->value.compare("EPCOS100K"    ) == 0 ){ // Default
    }else if( thermistor->value.compare("RRRF100K"     ) == 0 ){ this->beta = 3960;
    }else if( thermistor->value.compare("RRRF10K"      ) == 0 ){ this->beta = 3964; this->r0 = 10000; this->r1 = 680; this->r2 = 1600;
    }else if( thermistor->value.compare("Honeywell100K") == 0 ){ this->beta = 3974;
    }else if( thermistor->value.compare("Semitec"      ) == 0 ){ this->beta = 4267; 
    }else if( thermistor->value.compare("HT100K"       ) == 0 ){ this->beta = 3990; }

    // Preset values are overriden by specified values
    this->r0 =                  this->kernel->config->value(temperature_control_checksum, this->name_checksum, r0_checksum  )->by_default(this->r0  )->as_number();               // Stated resistance eg. 100K
    this->t0 =                  this->kernel->config->value(temperature_control_checksum, this->name_checksum, t0_checksum  )->by_default(this->t0  )->as_number();               // Temperature at stated resistance, eg. 25C
    this->beta =                this->kernel->config->value(temperature_control_checksum, this->name_checksum, beta_checksum)->by_default(this->beta)->as_number();               // Thermistor beta rating. See http://reprap.org/bin/view/Main/MeasuringThermistorBeta
    this->r1 =                  this->kernel->config->value(temperature_control_checksum, this->name_checksum, r1_checksum  )->by_default(this->r1  )->as_number();
    this->r2 =                  this->kernel->config->value(temperature_control_checksum, this->name_checksum, r2_checksum  )->by_default(this->r2  )->as_number();

    this->preset1 =             this->kernel->config->value(temperature_control_checksum, this->name_checksum, preset1_checksum)->by_default(0)->as_number();
    this->preset2 =             this->kernel->config->value(temperature_control_checksum, this->name_checksum, preset2_checksum)->by_default(0)->as_number();


    // Thermistor math
    j = (1.0 / beta);
    k = (1.0 / (t0 + 273.15));

    // sigma-delta output modulation
    o = 0;

    // Thermistor pin for ADC readings
    this->thermistor_pin.from_string(this->kernel->config->value(temperature_control_checksum, this->name_checksum, thermistor_pin_checksum )->required()->as_string());
    this->kernel->adc->enable_pin(&thermistor_pin);

    // Heater pin
    this->heater_pin.from_string(    this->kernel->config->value(temperature_control_checksum, this->name_checksum, heater_pin_checksum)->required()->as_string())->as_output();
    this->heater_pin.max_pwm(        this->kernel->config->value(temperature_control_checksum, this->name_checksum, max_pwm_checksum)->by_default(255)->as_number() );
    this->heater_pin.set(0);

    set_low_on_debug(heater_pin.port_number, heater_pin.pin);

    // activate SD-DAC timer
    this->kernel->slow_ticker->attach(1000, &heater_pin, &Pwm::on_tick);

    // reading tick
    this->kernel->slow_ticker->attach( this->readings_per_second, this, &TemperatureControl::thermistor_read_tick );

    // PID
    this->p_factor = this->kernel->config->value(temperature_control_checksum, this->name_checksum, p_factor_checksum)->by_default(10 )->as_number();
    this->i_factor = this->kernel->config->value(temperature_control_checksum, this->name_checksum, i_factor_checksum)->by_default(0.3)->as_number();
    this->d_factor = this->kernel->config->value(temperature_control_checksum, this->name_checksum, d_factor_checksum)->by_default(200)->as_number();
    this->i_max    = this->kernel->config->value(temperature_control_checksum, this->name_checksum, i_max_checksum   )->by_default(255)->as_number();
    this->i = 0.0;
    this->last_reading = 0.0;
}

void TemperatureControl::on_gcode_received(void* argument){
    Gcode* gcode = static_cast<Gcode*>(argument);
    if (gcode->has_m)
    {
        // Get temperature
        if( gcode->m == this->get_m_code ){
            char buf[32]; // should be big enough for any status
            int n= snprintf(buf, sizeof(buf), "%s:%3.1f /%3.1f @%d ", this->designator.c_str(), this->get_temperature(), ((target_temperature == UNDEFINED)?0.0:target_temperature), this->o);
            gcode->txt_after_ok.append(buf, n);
        }
        if (gcode->m == 301)
        {
            gcode->mark_as_taken();
            if (gcode->has_letter('S') && (gcode->get_value('S') == this->pool_index))
            {
                if (gcode->has_letter('P'))
                    this->p_factor = gcode->get_value('P');
                if (gcode->has_letter('I'))
                    this->i_factor = gcode->get_value('I');
                if (gcode->has_letter('D'))
                    this->d_factor = gcode->get_value('D');
                if (gcode->has_letter('X'))
                    this->i_max    = gcode->get_value('X');
            }
            gcode->stream->printf("%s(S%d): Pf:%g If:%g Df:%g X(I_max):%g Pv:%g Iv:%g Dv:%g O:%d\n", this->designator.c_str(), this->pool_index, this->p_factor, this->i_factor, this->d_factor, this->i_max, this->p, this->i, this->d, o);
        }
        if (gcode->m == 303)
        {
            gcode->mark_as_taken();
            if (gcode->has_letter('S') && (gcode->get_value('S') == this->pool_index))
            {
                double target = 150.0;
                if (gcode->has_letter('P'))
                {
                    target = gcode->get_value('P');
                    gcode->stream->printf("Target: %5.1f\n", target);
                }
                gcode->stream->printf("Start PID tune, command is %s\n", gcode->command.c_str());
                this->pool->PIDtuner->begin(this, target, gcode->stream);
            }
        }

        // Attach gcodes to the last block for on_gcode_execute
        if( ( gcode->m == this->set_m_code || gcode->m == this->set_and_wait_m_code ) && gcode->has_letter('S') ){
            if( this->kernel->conveyor->queue.size() == 0 ){
                this->kernel->call_event(ON_GCODE_EXECUTE, gcode );
            }else{
                Block* block = this->kernel->conveyor->queue.get_ref( this->kernel->conveyor->queue.size() - 1 );
                block->append_gcode(gcode);
            }

        }
    }
}

void TemperatureControl::on_gcode_execute(void* argument){
    Gcode* gcode = static_cast<Gcode*>(argument);
    if( gcode->has_m){
        if (((gcode->m == this->set_m_code) || (gcode->m == this->set_and_wait_m_code))
            && gcode->has_letter('S'))
        {
            double v = gcode->get_value('S');

            if (v == 0.0)
            {
                this->target_temperature = UNDEFINED;
                this->heater_pin.set(0);
            }
            else
            {
                this->set_desired_temperature(v);

                if( gcode->m == this->set_and_wait_m_code)
                {
                    gcode->mark_as_taken();
                    this->kernel->pauser->take();
                    this->waiting = true;
                }
            }
        }
    }
}

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();
    }
}

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
    double t= *static_cast<double*>(pdr->get_data_ptr());
    this->set_desired_temperature(t);
    pdr->set_taken();
}

void TemperatureControl::set_desired_temperature(double desired_temperature)
{
    if (desired_temperature == 1.0)
        desired_temperature = preset1;
    else if (desired_temperature == 2.0)
        desired_temperature = preset2;

    target_temperature = desired_temperature;
    if (desired_temperature == 0.0)
        heater_pin.set((o = 0));
}

double TemperatureControl::get_temperature(){
    return last_reading;
}

double TemperatureControl::adc_value_to_temperature(int adc_value)
{
    if ((adc_value == 4095) || (adc_value == 0))
        return INFINITY;
    double r = r2 / ((4095.0 / adc_value) - 1.0);
    if (r1 > 0)
        r = (r1 * r) / (r1 - r);
    return (1.0 / (k + (j * log(r / r0)))) - 273.15;
}

uint32_t TemperatureControl::thermistor_read_tick(uint32_t dummy){
    int r = new_thermistor_reading();

    double temperature = adc_value_to_temperature(r);

    if (target_temperature > 0)
    {
        if ((r <= 1) || (r >= 4094))
        {
            this->min_temp_violated = true;
            target_temperature = UNDEFINED;
            heater_pin.set(0);
        }
        else
        {
            pid_process(temperature);
            if ((temperature > target_temperature) && waiting)
            {
                kernel->pauser->release();
                waiting = false;
            }
        }
    }
    else
    {
        heater_pin.set((o = 0));
    }
    last_reading = temperature;
    return 0;
}

void TemperatureControl::pid_process(double temperature)
{
    double error = target_temperature - temperature;

    p  = error * p_factor;
    i += (error * this->i_factor);
    // d was imbued with oldest_raw earlier in new_thermistor_reading
    d = adc_value_to_temperature(d);
    d = (d - temperature) * this->d_factor;

    if (i > this->i_max)
        i = this->i_max;
    if (i < -this->i_max)
        i = -this->i_max;

    this->o = (p + i + d) * heater_pin.max_pwm() / 256;

    if (this->o >= heater_pin.max_pwm())
        this->o = heater_pin.max_pwm();
    else if (this->o < 0)
        this->o = 0;

    this->heater_pin.pwm(this->o);
}

int TemperatureControl::new_thermistor_reading()
{
    int last_raw = this->kernel->adc->read(&thermistor_pin);
    if (queue.size() >= queue.capacity())
    {
        uint16_t l;
        queue.pop_front(l);
        d = l;
    }
    uint16_t r = last_raw;
    queue.push_back(r);
    for (int i=0; i<queue.size(); i++)
      median_buffer[i] = *queue.get_ref(i);
    uint16_t m = median_buffer[quick_median(median_buffer, queue.size())];
    return m;
}

void TemperatureControl::on_second_tick(void* argument)
{
    if (waiting)
        kernel->streams->printf("%s:%3.1f /%3.1f @%d\n", designator.c_str(), get_temperature(), ((target_temperature == UNDEFINED)?0.0:target_temperature), o);
}
Commit	Line	Data
df27a6a3	1	/*
cd011f58 AW	2	This file is part of Smoothie (http://smoothieware.org/). The motion control part is heavily based on Grbl (https://github.com/simen/grbl).
	3	Smoothie is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version.
	4	Smoothie is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.
df27a6a3	5	You should have received a copy of the GNU General Public License along with Smoothie. If not, see <http://www.gnu.org/licenses/>.
cd011f58 AW	6	*/
cd011f58 AW	7
7b49793d	8	// TODO : THIS FILE IS LAME, MUST BE MADE MUCH BETTER
cd011f58	9
ded56b35 AW	10	#include "libs/Module.h"
	11	#include "libs/Kernel.h"
	12	#include <math.h>
	13	#include "TemperatureControl.h"
3c308aeb	14	#include "TemperatureControlPool.h"
3c132bd0	15	#include "libs/Pin.h"
e84c3be3	16	#include "libs/Median.h"
3c4f2dd8	17	#include "modules/robot/Conveyor.h"
8293d443	18	#include "PublicDataRequest.h"
ded56b35	19
8f91e4e6 MM	20	#include "MRI_Hooks.h"
8f91e4e6 MM	21
7e57bc2c BG	22	TemperatureControl::TemperatureControl(uint16_t name) :
7e57bc2c BG	23	name_checksum(name), waiting(false), min_temp_violated(false) {}
ded56b35 AW	24
ded56b35 AW	25	void TemperatureControl::on_module_loaded(){
907d5e8a	26
81b547a1	27	// We start not desiring any temp
907d5e8a	28	this->target_temperature = UNDEFINED;
ded56b35 AW	29
ded56b35 AW	30	// Settings
7dd8133c	31	this->on_config_reload(this);
ded56b35 AW	32
	33	this->acceleration_factor = 10;
	34
ded56b35	35	// Register for events
476dcb96	36	register_for_event(ON_CONFIG_RELOAD);
df27a6a3	37	this->register_for_event(ON_GCODE_EXECUTE);
b0be67b5	38	this->register_for_event(ON_GCODE_RECEIVED);
df27a6a3	39	this->register_for_event(ON_MAIN_LOOP);
8ccab7cf	40	this->register_for_event(ON_SECOND_TICK);
8293d443	41	this->register_for_event(ON_GET_PUBLIC_DATA);
991d98cc	42	this->register_for_event(ON_SET_PUBLIC_DATA);
ded56b35 AW	43	}
ded56b35 AW	44
7e57bc2c BG	45	void TemperatureControl::on_main_loop(void* argument){
7e57bc2c BG	46	if (this->min_temp_violated) {
482d02f0	47	kernel->streams->printf("Error: MINTEMP triggered on P%d.%d! check your thermistors!\n", this->thermistor_pin.port_number, this->thermistor_pin.pin);
7e57bc2c	48	this->min_temp_violated = false;
a7f12bed	49	}
7e57bc2c	50	}
7dd8133c AW	51
	52	// Get configuration from the config file
	53	void TemperatureControl::on_config_reload(void* argument){
	54
1306ba99 AW	55	// General config
	56	this->set_m_code = this->kernel->config->value(temperature_control_checksum, this->name_checksum, set_m_code_checksum)->by_default(104)->as_number();
	57	this->set_and_wait_m_code = this->kernel->config->value(temperature_control_checksum, this->name_checksum, set_and_wait_m_code_checksum)->by_default(109)->as_number();
	58	this->get_m_code = this->kernel->config->value(temperature_control_checksum, this->name_checksum, get_m_code_checksum)->by_default(105)->as_number();
f39da6fe	59	this->readings_per_second = this->kernel->config->value(temperature_control_checksum, this->name_checksum, readings_per_second_checksum)->by_default(20)->as_number();
7dee00e4	60
b0be67b5 MM	61	this->designator = this->kernel->config->value(temperature_control_checksum, this->name_checksum, designator_checksum)->by_default(string("T"))->as_string();
b0be67b5 MM	62
7dd8133c	63	// Values are here : http://reprap.org/wiki/Thermistor
423df6df AW	64	this->r0 = 100000;
423df6df AW	65	this->t0 = 25;
a98f72da	66	this->beta = 4066;
423df6df AW	67	this->r1 = 0;
423df6df AW	68	this->r2 = 4700;
a98f72da	69
3c132bd0	70	// Preset values for various common types of thermistors
df27a6a3	71	ConfigValue* thermistor = this->kernel->config->value(temperature_control_checksum, this->name_checksum, thermistor_checksum);
423df6df AW	72	if( thermistor->value.compare("EPCOS100K" ) == 0 ){ // Default
	73	}else if( thermistor->value.compare("RRRF100K" ) == 0 ){ this->beta = 3960;
	74	}else if( thermistor->value.compare("RRRF10K" ) == 0 ){ this->beta = 3964; this->r0 = 10000; this->r1 = 680; this->r2 = 1600;
	75	}else if( thermistor->value.compare("Honeywell100K") == 0 ){ this->beta = 3974;
93356612 AW	76	}else if( thermistor->value.compare("Semitec" ) == 0 ){ this->beta = 4267;
93356612 AW	77	}else if( thermistor->value.compare("HT100K" ) == 0 ){ this->beta = 3990; }
a98f72da	78
3c132bd0	79	// Preset values are overriden by specified values
907d5e8a MM	80	this->r0 = this->kernel->config->value(temperature_control_checksum, this->name_checksum, r0_checksum )->by_default(this->r0 )->as_number(); // Stated resistance eg. 100K
	81	this->t0 = this->kernel->config->value(temperature_control_checksum, this->name_checksum, t0_checksum )->by_default(this->t0 )->as_number(); // Temperature at stated resistance, eg. 25C
	82	this->beta = this->kernel->config->value(temperature_control_checksum, this->name_checksum, beta_checksum)->by_default(this->beta)->as_number(); // Thermistor beta rating. See http://reprap.org/bin/view/Main/MeasuringThermistorBeta
	83	this->r1 = this->kernel->config->value(temperature_control_checksum, this->name_checksum, r1_checksum )->by_default(this->r1 )->as_number();
	84	this->r2 = this->kernel->config->value(temperature_control_checksum, this->name_checksum, r2_checksum )->by_default(this->r2 )->as_number();
	85
f4bd4fc3 MM	86	this->preset1 = this->kernel->config->value(temperature_control_checksum, this->name_checksum, preset1_checksum)->by_default(0)->as_number();
	87	this->preset2 = this->kernel->config->value(temperature_control_checksum, this->name_checksum, preset2_checksum)->by_default(0)->as_number();
	88
907d5e8a	89
df27a6a3	90	// Thermistor math
907d5e8a MM	91	j = (1.0 / beta);
	92	k = (1.0 / (t0 + 273.15));
	93
c4f4cf73 MM	94	// sigma-delta output modulation
c4f4cf73 MM	95	o = 0;
3c132bd0 AW	96
3c132bd0 AW	97	// Thermistor pin for ADC readings
7dee00e4 MM	98	this->thermistor_pin.from_string(this->kernel->config->value(temperature_control_checksum, this->name_checksum, thermistor_pin_checksum )->required()->as_string());
7dee00e4 MM	99	this->kernel->adc->enable_pin(&thermistor_pin);
3c132bd0 AW	100
3c132bd0 AW	101	// Heater pin
7dee00e4	102	this->heater_pin.from_string( this->kernel->config->value(temperature_control_checksum, this->name_checksum, heater_pin_checksum)->required()->as_string())->as_output();
a7f12bed	103	this->heater_pin.max_pwm( this->kernel->config->value(temperature_control_checksum, this->name_checksum, max_pwm_checksum)->by_default(255)->as_number() );
7dee00e4	104	this->heater_pin.set(0);
7dd8133c	105
cb3460e9	106	set_low_on_debug(heater_pin.port_number, heater_pin.pin);
8f91e4e6	107
907d5e8a	108	// activate SD-DAC timer
7dee00e4	109	this->kernel->slow_ticker->attach(1000, &heater_pin, &Pwm::on_tick);
907d5e8a	110
f39da6fe MM	111	// reading tick
	112	this->kernel->slow_ticker->attach( this->readings_per_second, this, &TemperatureControl::thermistor_read_tick );
	113
907d5e8a MM	114	// PID
907d5e8a MM	115	this->p_factor = this->kernel->config->value(temperature_control_checksum, this->name_checksum, p_factor_checksum)->by_default(10 )->as_number();
b6a72b99 MM	116	this->i_factor = this->kernel->config->value(temperature_control_checksum, this->name_checksum, i_factor_checksum)->by_default(0.3)->as_number();
b6a72b99 MM	117	this->d_factor = this->kernel->config->value(temperature_control_checksum, this->name_checksum, d_factor_checksum)->by_default(200)->as_number();
4b9388c2	118	this->i_max = this->kernel->config->value(temperature_control_checksum, this->name_checksum, i_max_checksum )->by_default(255)->as_number();
b6a72b99	119	this->i = 0.0;
907d5e8a	120	this->last_reading = 0.0;
7dd8133c AW	121	}
7dd8133c AW	122
3c4f2dd8	123	void TemperatureControl::on_gcode_received(void* argument){
b0be67b5 MM	124	Gcode* gcode = static_cast<Gcode*>(argument);
	125	if (gcode->has_m)
	126	{
	127	// Get temperature
	128	if( gcode->m == this->get_m_code ){
93284f6f JM	129	char buf[32]; // should be big enough for any status
	130	int n= snprintf(buf, sizeof(buf), "%s:%3.1f /%3.1f @%d ", this->designator.c_str(), this->get_temperature(), ((target_temperature == UNDEFINED)?0.0:target_temperature), this->o);
	131	gcode->txt_after_ok.append(buf, n);
b0be67b5	132	}
827a49ca MM	133	if (gcode->m == 301)
827a49ca MM	134	{
74b6303c	135	gcode->mark_as_taken();
827a49ca MM	136	if (gcode->has_letter('S') && (gcode->get_value('S') == this->pool_index))
	137	{
	138	if (gcode->has_letter('P'))
	139	this->p_factor = gcode->get_value('P');
	140	if (gcode->has_letter('I'))
	141	this->i_factor = gcode->get_value('I');
	142	if (gcode->has_letter('D'))
	143	this->d_factor = gcode->get_value('D');
	144	if (gcode->has_letter('X'))
	145	this->i_max = gcode->get_value('X');
	146	}
	147	gcode->stream->printf("%s(S%d): Pf:%g If:%g Df:%g X(I_max):%g Pv:%g Iv:%g Dv:%g O:%d\n", this->designator.c_str(), this->pool_index, this->p_factor, this->i_factor, this->d_factor, this->i_max, this->p, this->i, this->d, o);
	148	}
	149	if (gcode->m == 303)
	150	{
74b6303c	151	gcode->mark_as_taken();
827a49ca MM	152	if (gcode->has_letter('S') && (gcode->get_value('S') == this->pool_index))
	153	{
	154	double target = 150.0;
	155	if (gcode->has_letter('P'))
	156	{
	157	target = gcode->get_value('P');
	158	gcode->stream->printf("Target: %5.1f\n", target);
	159	}
	160	gcode->stream->printf("Start PID tune, command is %s\n", gcode->command.c_str());
	161	this->pool->PIDtuner->begin(this, target, gcode->stream);
	162	}
	163	}
cf1a7632	164
3c4f2dd8 AW	165	// Attach gcodes to the last block for on_gcode_execute
	166	if( ( gcode->m == this->set_m_code \|\| gcode->m == this->set_and_wait_m_code ) && gcode->has_letter('S') ){
	167	if( this->kernel->conveyor->queue.size() == 0 ){
	168	this->kernel->call_event(ON_GCODE_EXECUTE, gcode );
	169	}else{
	170	Block* block = this->kernel->conveyor->queue.get_ref( this->kernel->conveyor->queue.size() - 1 );
	171	block->append_gcode(gcode);
3c4f2dd8	172	}
cf1a7632	173
3c4f2dd8	174	}
b0be67b5 MM	175	}
b0be67b5 MM	176	}
db453125	177
ded56b35 AW	178	void TemperatureControl::on_gcode_execute(void* argument){
ded56b35 AW	179	Gcode* gcode = static_cast<Gcode*>(argument);
e6b5ae25	180	if( gcode->has_m){
cf1a7632 MM	181	if (((gcode->m == this->set_m_code) \|\| (gcode->m == this->set_and_wait_m_code))
cf1a7632 MM	182	&& gcode->has_letter('S'))
907d5e8a	183	{
f4bd4fc3 MM	184	double v = gcode->get_value('S');
f4bd4fc3 MM	185
cf1a7632	186	if (v == 0.0)
eabf7a9b	187	{
907d5e8a	188	this->target_temperature = UNDEFINED;
7dee00e4	189	this->heater_pin.set(0);
eabf7a9b MM	190	}
	191	else
	192	{
f4bd4fc3	193	this->set_desired_temperature(v);
cf1a7632 MM	194
	195	if( gcode->m == this->set_and_wait_m_code)
	196	{
74b6303c	197	gcode->mark_as_taken();
cf1a7632 MM	198	this->kernel->pauser->take();
	199	this->waiting = true;
	200	}
907d5e8a	201	}
df27a6a3	202	}
df27a6a3	203	}
ded56b35 AW	204	}
ded56b35 AW	205
8293d443	206	void TemperatureControl::on_get_public_data(void* argument){
b19aa09d JM	207	PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
	208
	209	if(!pdr->starts_with(temperature_control_checksum)) return;
	210
	211	if(!pdr->second_element_is(this->name_checksum)) return; // will be bed or hotend
	212
	213	// ok this is targeted at us, so send back the requested data
	214	if(pdr->third_element_is(current_temperature_checksum)) {
	215	// this must be static as it will be accessed long after we have returned
	216	static struct pad_temperature temp_return;
	217	temp_return.current_temperature= this->get_temperature();
	218	temp_return.target_temperature= (target_temperature == UNDEFINED) ? 0 : this->target_temperature;
	219	temp_return.pwm= this->o;
	220
	221	pdr->set_data_ptr(&temp_return);
	222	pdr->set_taken();
	223	}
8293d443	224	}
db453125	225
77047e76	226	void TemperatureControl::on_set_public_data(void* argument){
991d98cc	227	PublicDataRequest* pdr = static_cast<PublicDataRequest*>(argument);
77047e76	228
991d98cc	229	if(!pdr->starts_with(temperature_control_checksum)) return;
77047e76	230
991d98cc	231	if(!pdr->second_element_is(this->name_checksum)) return; // will be bed or hotend
77047e76	232
991d98cc JM	233	// ok this is targeted at us, so set the temp
	234	double t= static_cast<double>(pdr->get_data_ptr());
	235	this->set_desired_temperature(t);
	236	pdr->set_taken();
77047e76 JM	237	}
77047e76 JM	238
cf1a7632 MM	239	void TemperatureControl::set_desired_temperature(double desired_temperature)
	240	{
	241	if (desired_temperature == 1.0)
	242	desired_temperature = preset1;
	243	else if (desired_temperature == 2.0)
	244	desired_temperature = preset2;
	245
907d5e8a	246	target_temperature = desired_temperature;
959dc7db	247	if (desired_temperature == 0.0)
7dee00e4	248	heater_pin.set((o = 0));
ded56b35 AW	249	}
	250
	251	double TemperatureControl::get_temperature(){
907d5e8a	252	return last_reading;
ded56b35 AW	253	}
ded56b35 AW	254
907d5e8a MM	255	double TemperatureControl::adc_value_to_temperature(int adc_value)
	256	{
	257	if ((adc_value == 4095) \|\| (adc_value == 0))
	258	return INFINITY;
	259	double r = r2 / ((4095.0 / adc_value) - 1.0);
	260	if (r1 > 0)
	261	r = (r1 * r) / (r1 - r);
	262	return (1.0 / (k + (j * log(r / r0)))) - 273.15;
ded56b35 AW	263	}
ded56b35 AW	264
8b8b3339	265	uint32_t TemperatureControl::thermistor_read_tick(uint32_t dummy){
907d5e8a MM	266	int r = new_thermistor_reading();
	267
	268	double temperature = adc_value_to_temperature(r);
	269
	270	if (target_temperature > 0)
	271	{
	272	if ((r <= 1) \|\| (r >= 4094))
36a3f3f0	273	{
7e57bc2c	274	this->min_temp_violated = true;
907d5e8a	275	target_temperature = UNDEFINED;
7dee00e4	276	heater_pin.set(0);
36a3f3f0 MM	277	}
	278	else
	279	{
907d5e8a MM	280	pid_process(temperature);
907d5e8a MM	281	if ((temperature > target_temperature) && waiting)
36a3f3f0	282	{
907d5e8a MM	283	kernel->pauser->release();
907d5e8a MM	284	waiting = false;
81b547a1	285	}
ded56b35 AW	286	}
ded56b35 AW	287	}
959dc7db MM	288	else
959dc7db MM	289	{
7dee00e4	290	heater_pin.set((o = 0));
959dc7db	291	}
907d5e8a	292	last_reading = temperature;
281967e4	293	return 0;
ded56b35 AW	294	}
ded56b35 AW	295
907d5e8a MM	296	void TemperatureControl::pid_process(double temperature)
	297	{
	298	double error = target_temperature - temperature;
ded56b35	299
8cdae54c	300	p = error * p_factor;
b6a72b99	301	i += (error * this->i_factor);
827a49ca MM	302	// d was imbued with oldest_raw earlier in new_thermistor_reading
	303	d = adc_value_to_temperature(d);
	304	d = (d - temperature) * this->d_factor;
ded56b35	305
907d5e8a MM	306	if (i > this->i_max)
	307	i = this->i_max;
	308	if (i < -this->i_max)
	309	i = -this->i_max;
ded56b35	310
7dee00e4	311	this->o = (p + i + d) * heater_pin.max_pwm() / 256;
8cdae54c	312
7dee00e4	313	if (this->o >= heater_pin.max_pwm())
7dee00e4	314	this->o = heater_pin.max_pwm();
27aecda6	315	else if (this->o < 0)
907d5e8a MM	316	this->o = 0;
907d5e8a MM	317
27aecda6	318	this->heater_pin.pwm(this->o);
907d5e8a	319	}
ded56b35	320
907d5e8a MM	321	int TemperatureControl::new_thermistor_reading()
907d5e8a MM	322	{
7dee00e4	323	int last_raw = this->kernel->adc->read(&thermistor_pin);
907d5e8a MM	324	if (queue.size() >= queue.capacity())
	325	{
	326	uint16_t l;
	327	queue.pop_front(l);
827a49ca	328	d = l;
907d5e8a	329	}
c4f4cf73 MM	330	uint16_t r = last_raw;
c4f4cf73 MM	331	queue.push_back(r);
e84c3be3 BG	332	for (int i=0; i<queue.size(); i++)
	333	median_buffer[i] = *queue.get_ref(i);
	334	uint16_t m = median_buffer[quick_median(median_buffer, queue.size())];
	335	return m;
907d5e8a	336	}
8ccab7cf MM	337
	338	void TemperatureControl::on_second_tick(void* argument)
	339	{
	340	if (waiting)
8f91e4e6	341	kernel->streams->printf("%s:%3.1f /%3.1f @%d\n", designator.c_str(), get_temperature(), ((target_temperature == UNDEFINED)?0.0:target_temperature), o);
8ccab7cf	342	}