aboutsummaryrefslogtreecommitdiffstats
path: root/Software/Embedded_SW/Embedded/Modules/Control/MillisecTask.c
blob: 471833dc5a8eb7fc888268d4c70ae6c7e46781f9 (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47pre { line-height: 125%; }
td.linenos .normal { color: inherit; background-color: transparent; padding-left: 5px; padding-right: 5px; }
span.linenos { color: inherit; background-color: transparent; padding-left: 5px; padding-right: 5px; }
td.linenos .special { color: #000000; background-color: #ffffc0; padding-left: 5px; padding-right: 5px; }
span.linenos.special { color: #000000; background-color: #ffffc0; padding-left: 5px; padding-right: 5px; }
.highlight .hll { background-color: #ffffcc }
.highlight .c { color: #888888 } /* Comment */
.highlight .err { color: #a61717; background-color: #e3d2d2 } /* Error */
.highlight .k { color: #008800; font-weight: bold } /* Keyword */
.highlight .ch { color: #888888 } /* Comment.Hashbang */
.highlight .cm { color: #888888 } /* Comment.Multiline */
.highlight .cp { color: #cc0000; font-weight: bold } /* Comment.Preproc */
.highlight .cpf { color: #888888 } /* Comment.PreprocFile */
.highlight .c1 { color: #888888 } /* Comment.Single */
.highlight .cs { color: #cc0000; font-weight: bold; background-color: #fff0f0 } /* Comment.Special */
.highlight .gd { color: #000000; background-color: #ffdddd } /* Generic.Deleted */
.highlight .ge { font-style: italic } /* Generic.Emph */
.highlight .ges { font-weight: bold; font-style: italic } /* Generic.EmphStrong */
.highlight .gr { color: #aa0000 } /* Generic.Error */
.highlight .gh { color: #333333 } /* Generic.Heading */
.highlight .gi { color: #000000; background-color: #ddffdd } /* Generic.Inserted */
.highlight .go { color: #888888 } /* Generic.Output */
.highlight .gp { color: #555555 } /* Generic.Prompt */
.highlight .gs { font-weight: bold } /* Generic.Strong */
.highlight .gu { color: #666666 } /* Generic.Subheading */
.highlight .gt { color: #aa0000 } /* Generic.Traceback */
.highlight .kc { color: #008800; font-weight: bold } /* Keyword.Constant */
.highlight .kd { color: #008800; font-weight: bold } /* Keyword.Declaration */
.highlight .kn { color: #008800; font-weight: bold } /* Keyword.Namespace */
.highlight .kp { color: #008800 } /* Keyword.Pseudo */
.highlight .kr { color: #008800; font-weight: bold } /* Keyword.Reserved */
.highlight .kt { color: #888888; font-weight: bold } /* Keyword.Type */
.highlight .m { color: #0000DD; font-weight: bold } /* Literal.Number */
.highlight .s { color: #dd2200; background-color: #fff0f0 } /* Literal.String */
.highlight .na { color: #336699 } /* Name.Attribute */
.highlight .nb { color: #003388 } /* Name.Builtin */
.highlight .nc { color: #bb0066; font-weight: bold } /* Name.Class */
.highlight .no { color: #003366; font-weight: bold } /* Name.Constant */
.highlight .nd { color: #555555 } /* Name.Decorator */
.highlight .ne { color: #bb0066; font-weight: bold } /* Name.Exception */
.highlight .nf { color: #0066bb; font-weight: bold } /* Name.Function */
.highlight .nl { color: #336699; font-style: italic } /* Name.Label */
.highlight .nn { color: #bb0066; font-weight: bold } /* Name.Namespace */
.highlight .py { color: #336699; font-weight: bold } /* Name.Property */
.highlight .nt { color: #bb0066; font-weight: bold } /* Name.Tag */
.highlight .nv { color: #336699 } /* Name.Variable */
.highlight .ow { color: #008800 } /* Operator.Word */
.highlight .w { color: #bbbbbb } /* Text.Whitespace */
.highlight .mb { color: #0000DD; font-weight: bold } /* Literal.Number.Bin */
.highlight .mf { color: #0000DD; font-weight: bold } /* Literal.Number.Float */
.highlight .mh { color: #0000DD; font-weight: bold } /* Literal.Number.Hex */
.highlight .mi { color: #0000DD; font-weight: bold } /* Literal.Number.Integer */
.highlight .mo { color: #0000DD; font-weight: bold } /* Literal.Number.Oct */
.highlight .sa { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Affix */
.highlight .sb { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Backtick */
.highlight .sc { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Char */
.highlight .dl { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Delimiter */
.highlight .sd { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Doc */
.highlight .s2 { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Double */
.highlight .se { color: #0044dd; background-color: #fff0f0 } /* Literal.String.Escape */
.highlight .sh { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Heredoc */
.highlight .si { color: #3333bb; background-color: #fff0f0 } /* Literal.String.Interpol */
.highlight .sx { color: #22bb22; background-color: #f0fff0 } /* Literal.String.Other */
.highlight .sr { color: #008800; background-color: #fff0ff } /* Literal.String.Regex */
.highlight .s1 { color: #dd2200; background-color: #fff0f0 } /* Literal.String.Single */
.highlight .ss { color: #aa6600; background-color: #fff0f0 } /* Literal.String.Symbol */
.highlight .bp { color: #003388 } /* Name.Builtin.Pseudo */
.highlight .fm { color: #0066bb; font-weight: bold } /* Name.Function.Magic */
.highlight .vc { color: #336699 } /* Name.Variable.Class */
.highlight .vg { color: #dd7700 } /* Name.Variable.Global */
.highlight .vi { color: #3333bb } /* Name.Variable.Instance */
.highlight .vm { color: #336699 } /* Name.Variable.Magic */
.highlight .il { color: #0000DD; font-weight: bold } /* Literal.Number.Integer.Long */
//------------------------------------------------------------------------------
// <auto-generated>
//     This code was generated by a tool.
//     Runtime Version:4.0.30319.42000
//
//     Changes to this file may cause incorrect behavior and will be lost if
//     the code is regenerated.
// </auto-generated>
//------------------------------------------------------------------------------

namespace Tango.MachineStudio.Common.Properties
{
    
    
    [global::System.Runtime.CompilerServices.CompilerGeneratedAttribute()]
    [global::System.CodeDom.Compiler.GeneratedCodeAttribute("Microsoft.VisualStudio.Editors.SettingsDesigner.SettingsSingleFileGenerator", "11.0.0.0")]
    internal sealed partial class Settings : global::System.Configuration.ApplicationSettingsBase
    {
        
        private static Settings defaultInstance = ((Settings)(global::System.Configuration.ApplicationSettingsBase.Synchronized(new Settings())));
        
        public static Settings Default
        {
            get
            {
                return defaultInstance;
            }
        }
    }
}
18' href='#n318'>318 319 320 321 322 323 324 325 326 327 328 329 330 331 332 333 334 335 336 337 338 339 340 341 342 343 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 359 360 361 362 363 364 365 366 367 368 369 370 371 372 373 374 375 376 377 378 379 380 381 382 383 384 385 386 387 388 389 390 391 392 393 394 395 396 397 398 399 400 401 402 403 404 405 406 407 408 409 410 411 412 413 414 415 416 417 418 419 420 421 422 423 424 425 426 427 428 429 430 431 432 433 434 435 436 437 438 439 440 441 442 443 444 445 446 447 448 449 450 451 452 453 454 455 456 457 458 459 460 461 462 463 464 465 466 467 468 469 470 471 472 473 474 475 476 477 478 479 480 481 482 483 484 485 486 487 488 489 490 491 492 493 494 495 496 497 498 499 500 501 502 503 504 505 506 507 508 509 510 511 512 513 514 515 516 517 518 519 520 521 522 523 524 525 526 527 528 529 530 531 532 533 534 535 536 537 538 539 540 541 542 543 544 545 546 547 548 549 550 551 552 553 554 555 556 557 558 559 560 561 562 563 564 565 566 567 568 569 570 571 572 573 574 575 576 577 578 579 580 581 582 583 584 585 586 587 588 589 590 591 592 593 594 595 596 597 598 599 600 601 602
/************************************************************************************************************************
 * Millisec.c
 * Millisec module
 *
 * The millisec task is called once every 1 millisecond to gather data from the FPGA crucial modules,
 * so it will be ready for the Millisec operations. it is called 300 (TBD, configurable)
 * microsecond before the Millisec task, so that the data will be ready for the Millisec handling.
 * the ,millisecond task holds the pointer to a double buffer of results, so that the Millisec will handle the
 * most updated data, without disturbing data gathering
 *
 **************************************************************************************************************************/

////////////////////////////////State machine operation////////////////////////////////////
//the state machine operation is used to operate in runtime correct profile flow execution
//by recieved design flow of the user from the UI
///////////////////////////////////////////////////////////////////////////////////////////
#include "include.h"
#include "Modules/General/GeneralHardware.h"
#include "Modules/AlarmHandling/AlarmHandling.h"

#include "MillisecTask.h"
#include <driverlib/timer.h>
#include <Drivers/SSI_Comm/SSI_Comm.h>
#include <Drivers/SSI_Comm/Speed_Sensor/Speed_Sensor.h>
#include <Drivers/SSI_Comm/Dancer/Dancer.h>
#include "drivers/I2C_Communication/ADC_MUX/ADC_MUX.h"
#include <inc/hw_ints.h>

#include "drivers/adc_sampling/adc.h"
#include "control.h"

#include "drivers/Motors/Motor.h"
#include "drivers/Heater/TemperatureSensor.h"
#include "drivers/FPGA/FPGA_SPI_Comm.h"
#include "drivers/FPGA/FPGA.h"
#include <drivers/FPGA/FPGA_Comm.h>
#include "drivers/Valves/Valve.h"
#include "drivers/FPGA/FPGA_GPIO/FPGA_GPIO.h"

#include "modules/thread/thread_ex.h"
#include "modules/ids/ids_ex.h"

#include "Communication/Connection.h"

Task_Handle Millisecond_Task_Handle;
/******************** Definitions  ********************************************/

/******************** STRUCTURES AND ENUMs  ********************************************/
typedef struct MillisecMotorData
{
    bool WaitForData;
    bool DataRequired;
    bool SyncRequired;
    MSecFptr Callback;
    unsigned long Data;
    int Length;
    bool Active;
}MillisecMotorDataStruc;
typedef enum
{
    OneMillisec,
}MillisecMessages;

typedef struct MillisecMessage{
    uint16_t messageId;
    uint16_t msglen;
    uint32_t tick;
    uint8_t messageData[20];
}MillisecMessageStruc;

//uint32_t  ADC_Data[MAX_ADC_DEVICES] = {0};
//uint32_t  TemperatureSensor_Data[MAX_TEMPERATURE_SENSOR_ID] = {0};
//uint32_t  MotorSpeed_Data[NUM_OF_MOTORS] = {0};
//uint32_t  MotorStatus_Data[NUM_OF_MOTORS] = {0};
//uint32_t  MotorPosition_Data[NUM_OF_MOTORS] = {0};
//bool      MotorBusy_Data[NUM_OF_MOTORS] = {true};
uint32_t  Dancer_Data[NUM_OF_DANCERS] = {0};
float  Speed_Data = 0;
uint32_t DrawerFansStatus = 0;

bool watchdogCriticalAlarm = false;

uint32_t msec_millisecondCounter = 0;

extern bool Machine_Idle_Mode;

MillisecMotorDataStruc ScrewSetMaxSpeedPending = {0};
MillisecMotorDataStruc ScrewMovePending = {0};
MillisecMotorDataStruc MotorData[NUM_OF_MOTORS] = {0};
MillisecMotorDataStruc SpeedSetPending[NUM_OF_MOTORS] = {0};
MillisecMotorDataStruc PT100Data[MAX_TEMPERATURE_SENSOR_ID] = {0};
/******************** GLOBAL PARAMETERS  ********************************************/
Mailbox_Handle          MillisecMsgQ = NULL;
Mailbox_Handle          TenMillisecMsgQ = NULL;
Mailbox_Handle          MotorsMsgQ[NUM_OF_MOTORS] = {NULL};
bool                    MillisecRestart;
static GateMutex_Handle gateMillisecDB;

uint32_t        Millisec_timerBase = TIMER1_BASE;        //Timer handle
/******************** Functions  ********************************************/
uint32_t Control_Delta_Position_Pass(uint32_t Current_Read,uint32_t Previous_Read);
//**********************************************************************
/******************** CODE  ********************************************/
//**********************************************************************
#define LOG_SIZE 200
uint32_t MSBacklog[LOG_SIZE+1]={0};
uint8_t Motor_Id[LOG_SIZE+1]={0};
uint32_t MSTick[LOG_SIZE+1]={0};
uint16_t MsecLogindex = 0;

void MillisecInit(void)
{
    Error_Block eb;
    int i;

    Error_init(&eb);

    MillisecMsgQ = Mailbox_create(sizeof(MillisecMessageStruc), 2, NULL,&eb);
    TenMillisecMsgQ = Mailbox_create(sizeof(MillisecMessageStruc), 2, NULL,&eb);
    for (i=0;i<NUM_OF_MOTORS;i++)
    {
        MotorsMsgQ[i] = Mailbox_create(sizeof(MillisecMotorDataStruc), 5, NULL,&eb);
    }

    MillisecRestart = false;


    gateMillisecDB = GateMutex_create(NULL, &eb);
    if (gateMillisecDB == NULL)
    {
        System_abort("Could not create USB Wait gate");
    }

    ROM_SysCtlPeripheralEnable(SYSCTL_PERIPH_TIMER0);
    ROM_TimerConfigure(Millisec_timerBase, TIMER_CFG_PERIODIC);   // 32 bits Timer
    //TimerIntRegister(Millisec_timerBase, TIMER_A, Timer0Isr);    // Registering  isr
    ROM_TimerEnable(Millisec_timerBase, TIMER_A);
    ROM_IntEnable(INT_TIMER1A);
    ROM_TimerIntEnable(Millisec_timerBase, TIMER_TIMA_TIMEOUT);

    ADCAcquireInit();

    return;
}
void MillisecStop(void)
{
    MillisecRestart = false;
    ADCAcquireStop();
}
#define HIGH_TASK_FREQUENCY 120000
void MillisecStart(void)
{
    MillisecRestart = true;

    ROM_TimerLoadSet(Millisec_timerBase, TIMER_A,HIGH_TASK_FREQUENCY);
    ROM_TimerEnable(Millisec_timerBase, TIMER_A);
    ROM_IntEnable(INT_TIMER1A);
    ROM_TimerIntEnable(Millisec_timerBase, TIMER_TIMA_TIMEOUT);
    ADCAcquireStart(0,1);

}

void OneMilliSecondMillisecInterrupt(UArg arg0)
{
    MillisecMessageStruc MillisecMessage;
    uint32_t Tenmsec_millisecondCounter = 0;
    ROM_IntMasterDisable();
    ROM_TimerIntClear(Millisec_timerBase, TIMER_TIMA_TIMEOUT);  // Clear the timer interrupt
    if (MillisecRestart == true)
    {
        ROM_TimerLoadSet(Millisec_timerBase, TIMER_A,HIGH_TASK_FREQUENCY);
    }
    else
	{
        ROM_TimerDisable(Millisec_timerBase,TIMER_A);
	    ROM_IntMasterEnable();
		return;
	}
    if (msec_millisecondCounter%10 == 0)
    {
        Tenmsec_millisecondCounter = msec_millisecondCounter;
    }
    //send message to the Millisec task
    MillisecMessage.messageId = OneMillisec;
    MillisecMessage.tick = msec_millisecondCounter++;
    MillisecMessage.msglen = sizeof(MillisecMessageStruc);
    if (MillisecMsgQ != NULL)
        Mailbox_post(MillisecMsgQ , &MillisecMessage, BIOS_NO_WAIT);

    if (Tenmsec_millisecondCounter)
    {
        MillisecMessage.messageId = OneMillisec;
        MillisecMessage.tick = Tenmsec_millisecondCounter;
        MillisecMessage.msglen = sizeof(MillisecMessageStruc);
        if (TenMillisecMsgQ != NULL)
            Mailbox_post(TenMillisecMsgQ , &MillisecMessage, BIOS_NO_WAIT);
    }

    //
    // Enable all interrupts.
    //
    ROM_IntMasterEnable();
    return ;
}
uint32_t PT100Activity = 0;
int32_t MillisecReadFromTempSensor(uint32_t TempSensorId,  MSecFptr Callback)
{
    if (TempSensorId >= MAX_TEMPERATURE_SENSOR_ID) return -1;
    PT100Activity++; //read request
    PT100Data[TempSensorId].Callback = Callback;
    PT100Data[TempSensorId].Active = true;

    return OK;
}
//typedef  uint32_t (* MSecFptr)(uint32_t deviceID, uint32_t ReadValue);
uint32_t MotorActivity = 0;

int32_t MillisecSetMotorSpeed(TimerMotors_t MotorId, unsigned long Data, int Length, MSecFptr Callback)
{
    if (MotorId >= NUM_OF_MOTORS) return -1;
    //==========================
    if ((MotorId == HARDWARE_MOTOR_TYPE__MOTO_WINDER)||
        (MotorId == HARDWARE_MOTOR_TYPE__MOTO_RDRIVING)||
        (MotorId == HARDWARE_MOTOR_TYPE__MOTO_LDRIVING)||
		(MotorId == HARDWARE_MOTOR_TYPE__MOTO_SCREW))
    {
    MSBacklog[MsecLogindex]=Data;
    MSTick[MsecLogindex]=msec_millisecondCounter;
    Motor_Id[MsecLogindex]=MotorId;
    MsecLogindex++;
    if (MsecLogindex>=LOG_SIZE)
        MsecLogindex = 0;
    }
    //==========================

    SpeedSetPending[MotorId].Callback = Callback;
    SpeedSetPending[MotorId].Data = Data;
    SpeedSetPending[MotorId].Length = Length;
    SpeedSetPending[MotorId].DataRequired = false;
    if (SpeedSetPending[MotorId].Active == false)
    {
        MotorActivity++;
        SpeedSetPending[MotorId].Active = true;
    }

    return OK;
}
int MillisecFlushMsgQ(TimerMotors_t MotorId)
{
    MillisecMotorDataStruc MotorData = {0};
    int pend = Mailbox_getNumPendingMsgs(MotorsMsgQ[MotorId]);
    int i;
    if (pend)
    {
        for (i=0;i<pend;i++)
            Mailbox_pend(MotorsMsgQ[MotorId] , &MotorData, BIOS_NO_WAIT);
    }
   return pend;
}
int32_t MillisecWriteToMotor(TimerMotors_t MotorId, unsigned long Data, int Length, MSecFptr Callback)
{
    MillisecMotorDataStruc MotorData = {0};
    //==========================
    if ((MotorId == HARDWARE_MOTOR_TYPE__MOTO_WINDER)||
        (MotorId == HARDWARE_MOTOR_TYPE__MOTO_RDRIVING)||
        (MotorId == HARDWARE_MOTOR_TYPE__MOTO_LDRIVING)||
		(MotorId == HARDWARE_MOTOR_TYPE__MOTO_SCREW))
    {
    MSBacklog[MsecLogindex]=Data;
    MSTick[MsecLogindex]=msec_millisecondCounter;
    Motor_Id[MsecLogindex]=MotorId;
    MsecLogindex++;
    if (MsecLogindex>=LOG_SIZE)
        MsecLogindex = 0;
    }
    //==========================
    if (MotorId >= NUM_OF_MOTORS) return -1;
    MotorActivity++;
    MotorData.Callback = Callback;
    MotorData.Data = Data;
    MotorData.Length = Length;
    MotorData.DataRequired = false;
    if (MotorsMsgQ[MotorId] != NULL)
        return Mailbox_post(MotorsMsgQ[MotorId] , &MotorData, BIOS_NO_WAIT);
    else return false;
}
int32_t MillisecReadFromMotor(TimerMotors_t MotorId, unsigned long Data, int Length, MSecFptr Callback)
{
    MillisecMotorDataStruc MotorData = {0};
    if (MotorId >= NUM_OF_MOTORS) return -1;
//==========================
    if ((MotorId == HARDWARE_MOTOR_TYPE__MOTO_WINDER)||
        (MotorId == HARDWARE_MOTOR_TYPE__MOTO_RDRIVING)||
        (MotorId == HARDWARE_MOTOR_TYPE__MOTO_LDRIVING)||
		(MotorId == HARDWARE_MOTOR_TYPE__MOTO_SCREW))
    {
    MSBacklog[MsecLogindex]=Data;
    Motor_Id[MsecLogindex]=MotorId;
    MSTick[MsecLogindex]=msec_millisecondCounter;
    MsecLogindex++;
    if (MsecLogindex>=LOG_SIZE)
        MsecLogindex = 0;
    }
    //==========================
    MotorActivity++;
    MotorActivity++;
    MotorData.Callback = Callback;
    MotorData.Data = Data;
    MotorData.Length = Length;
    MotorData.DataRequired = true;
    if (MotorsMsgQ[MotorId] != NULL)
        return Mailbox_post(MotorsMsgQ[MotorId] , &MotorData, BIOS_NO_WAIT);
    else return false;
}

uint32_t MillisecLoop(uint32_t tick)
{
    uint8_t Motor_i;
    TEMPERATURE_SENSOR_ID_ENUM Sensor_i;
    unsigned int MotorInfo = 0;
    static int temp=0;
    //call all modules Millisec functions
    //test dancers and speed encoders
    //check all callback units (state machine waiting for completion of a change)
/*    bool Ten_msTick, Hundred_msTick, Onesecond_Tick,O900Millisecond_Tick,Tick98,OneMinute_Tick;
    Ten_msTick      =   (tick%eTenMillisecond == 0)      ?true:false;
    Hundred_msTick  =   (tick%eHundredMillisecond == 0)  ?true:false;
    O900Millisecond_Tick  =   (tick%eOneSecond == 900)           ?true:false;
    Onesecond_Tick  =   (tick%eOneSecond == 0)           ?true:false;
    OneMinute_Tick  =   (tick%eOneMinute == 0)           ?true:false;
    Tick98          =   (tick%eHundredMillisecond == 99) ?true:false;
    //gather Motor data from FPGA
    //ROM_IntMasterDisable();
*/
#ifndef EVALUATION_BOARD
        FPGA_GetBusy();  //load the busy motor information to all motors
        FPGA_Read_LS_Safty_Ind_Reg();
        //Read_FPGA_GPI_Rgisters();//FPGA_Read_limit_Switches();
#endif

        temp += MotorActivity;
   if (MotorActivity)
   {
        for (Motor_i = 0;Motor_i < NUM_OF_MOTORS;Motor_i++)
        {
            if (MotorDriverResponse[Motor_i].Busy == true)
            {
                temp++;
                continue;
            }
            if (MotorData[Motor_i].WaitForData == true) //Read request sent, data is waiting
            {
                if (MotorGetFPGAResponse((HardwareMotorType)Motor_i,&MotorInfo) == OK) //got the data from the FPGA
                {
                    MotorData[Motor_i].WaitForData = false;
                    if (MotorData[Motor_i].Callback)
                        MotorData[Motor_i].Callback(Motor_i,MotorInfo);
                }
                MotorActivity--;
            }
            if (SpeedSetPending[Motor_i].Active == true)
            {
                MotorSendFPGARequest((HardwareMotorType)Motor_i,SpeedSetPending[Motor_i].Data,SpeedSetPending[Motor_i].Length);
                MotorActivity--;
                SpeedSetPending[Motor_i].Active = false;
                if (SpeedSetPending[Motor_i].Callback)
                    SpeedSetPending[Motor_i].Callback(Motor_i,0);
            }
            else if (Mailbox_pend(MotorsMsgQ[Motor_i] , &MotorData[Motor_i], BIOS_NO_WAIT)==true)
            {
                if (MotorSendFPGARequest((HardwareMotorType)Motor_i,MotorData[Motor_i].Data,MotorData[Motor_i].Length) == OK) //sent the data to the FPGA
                {
                    if (MotorData[Motor_i].DataRequired == true)
                    {
                        MotorData[Motor_i].WaitForData = true; // mark the motor for data request next round
                    }
                    else
                    {
                        if (MotorData[Motor_i].Callback)
                            MotorData[Motor_i].Callback(Motor_i,0); // call the callback to report execution
                    }
                }
                MotorActivity--;
            }
        }
   }
    //FPGA_GetTempSensorBusy();
   //int PT100Busy[MAX_TEMPERATURE_SENSOR_ID] = {0,0,0,0,0,0,0,0,0,0};
   if (PT100Activity)
   {
       for (Sensor_i = 0;Sensor_i < MAX_TEMPERATURE_SENSOR_ID;Sensor_i++)
       {
           /*if (TempSensorResponse[Sensor_i].Busy == true)
           {
               PT100Busy[Sensor_i]++;
               continue;
           }*/
           if (PT100Data[Sensor_i].Active == true)
           {
               TemperatureSendSensorDummyClk(Sensor_i);
               PT100Data[Sensor_i].Active = false;
               PT100Data[Sensor_i].WaitForData = true; // mark the motor for data request next round
               break; //  one PT100 activitiy per MS 
           }
           else if (PT100Data[Sensor_i].WaitForData == true) //Read request sent, data is waiting
           {
               TemperatureSensorReadFromFPGA_Res(Sensor_i); //got the data from the FPGA
               PT100Data[Sensor_i].WaitForData = false;
               PT100Data[Sensor_i].SyncRequired = true;
               if (PT100Data[Sensor_i].Callback)
                       PT100Data[Sensor_i].Callback(Sensor_i,MotorInfo);
               break; // one PT100 activitiy per MS 
           }
           else if (PT100Data[Sensor_i].SyncRequired == true)
           {
               TemperatureSensorSync(Sensor_i);
               PT100Data[Sensor_i].SyncRequired = false;
               PT100Activity--;
               break; // one PT100 activitiy per MS 
           }
       }
   }
    Dancer_Data[FEEDER_DANCER] = Read_Dancer_Position(FEEDER_DANCER);
    Dancer_Data[POOLER_DANCER] = Read_Dancer_Position(POOLER_DANCER);
    Dancer_Data[WINDER_DANCER] = Read_Dancer_Position(WINDER_DANCER);

    return OK;
}
uint32_t MillisecLowLoop(uint32_t tick)
{
    uint8_t Motor_i,Disp_i,Heater_i;
    TEMPERATURE_SENSOR_ID_ENUM Sensor_i;

    //static int temp=0;
    //call all modules Millisec functions
    //test dancers and speed encoders
    //check all callback units (state machine waiting for completion of a change)
    bool Ten_msTick, Hundred_msTick, Onesecond_Tick,O900Millisecond_Tick,OneMinute_Tick;
    Ten_msTick      =   (tick%eTenMillisecond == 0)      ?true:false;
    Hundred_msTick  =   (tick%eHundredMillisecond == 0)  ?true:false;
    O900Millisecond_Tick  =   (tick%eOneSecond == 900)           ?true:false;
    Onesecond_Tick  =   (tick%eOneSecond == 0)           ?true:false;
    OneMinute_Tick  =   (tick%eOneMinute == 0)           ?true:false;
    //gather Motor data from FPGA
    //ROM_IntMasterDisable();

    if (Ten_msTick)
    {
        //Speed_Data = Calculate_Speed_Sensor_Velocity();
        //MillisecReadFromTempSensor(Sensor_Read, NULL);
        //if (Sensor_Read++ >= MAX_TEMPERATURE_SENSOR_ID) Sensor_Read = 0;
        if(Machine_Idle_Mode == true)
            Machine_Idle_Breathing_Led();
    }
    if (Hundred_msTick)
    {
        Speed_Data = Calculate_Speed_Sensor_Velocity();
        for (Sensor_i = 0;Sensor_i < MAX_TEMPERATURE_SENSOR_ID;Sensor_i++)
        {
            MillisecReadFromTempSensor(Sensor_i, NULL);
        }
        if (GeneralHwReady == true)
        {
            if (watchdogCriticalAlarm == false)
            {
                Control_WD(ENABLE,5);  //activate heaters/dispenser watchdog, 0.5 seconds
            }
        }
    }

    if (O900Millisecond_Tick)
    {
        ADC_TriggerCollection();
    }
    if (Onesecond_Tick)
    {
        for (Disp_i = 0;Disp_i < MAX_SYSTEM_DISPENSERS;Disp_i++)
        {
            CalculateDispenserPressure(Disp_i);
            //Read_MidTank_Pressure_Sensor(Disp_i);
        }
        FPGA_GetAllDispensersValveBusyOCD();
        DrawerFansStatus = Read_Fans_Tacho();
        KeepAliveOneSecondCall();
        for (Motor_i = 0;Motor_i < NUM_OF_MOTORS;Motor_i++)
        {
            if (Motor_i == HARDWARE_MOTOR_TYPE__MOTO_SCREW)
                continue;  //
            if (isMotorConfigured(Motor_i))
                MotorGetStatusFromFPGA(Motor_i);
        }
        for (Heater_i = 0;Heater_i < NUM_OF_HEATERS;Heater_i++)
        {
            Read_Head_MixChip_Heaters_Current(Heater_i);
        }
    }
    if (OneMinute_Tick)
    {
        for (Disp_i = 0;Disp_i < MAX_SYSTEM_DISPENSERS;Disp_i++)
        {
            Read_MidTank_Pressure_Sensor(Disp_i);
        }
/*        for (Motor_i = 0;Motor_i < NUM_OF_MOTORS;Motor_i++)
        {
            if (Motor_i == HARDWARE_MOTOR_TYPE__MOTO_SCREW)
                continue;  //
            if (isMotorConfigured(Motor_i))
                MotorGetStatusFromFPGA(Motor_i);
        }*/
    }
    //ROM_IntMasterEnable();


    return OK;
}
/******************************************************************************
 *  ======== messageTsk ========
 *  Task for this function is created statically. See the project's .cfg file.
 *  this message task is created statically in system initialization,
 ******************************************************************************/
void MillisecTask(UArg arg0, UArg arg1)
{
    MillisecMessageStruc MillisecMessage;
    //char str[60];
    //uint16_t length;
    //Clock_setTimeout(HostKAClock, 1000);
    //Clock_start(HostKAClock);
    //MillisecInit();
    Millisecond_Task_Handle = Task_self();
    while(1)
    {
        Mailbox_pend(MillisecMsgQ , &MillisecMessage, BIOS_WAIT_FOREVER);
        switch (MillisecMessage.messageId)
        {
            case OneMillisec:
                MillisecLoop(MillisecMessage.tick);
                break;
            default:
                break;
        }
    }
}
/******************************************************************************
 *  ======== messageTsk ========
 *  Task for this function is created statically. See the project's .cfg file.
 *  this message task is created statically in system initialization,
 ******************************************************************************/
void MillisecLowTask(UArg arg0, UArg arg1)
{
    MillisecMessageStruc MillisecLowMessage;
    //char str[60];
    //uint16_t length;
    //Clock_setTimeout(HostKAClock, 1000);
    //Clock_start(HostKAClock);
    //MillisecInit();
    //Millisecond_Task_Handle = Task_self();
    while(1)
    {
        Mailbox_pend(TenMillisecMsgQ , &MillisecLowMessage, BIOS_WAIT_FOREVER);
        switch (MillisecLowMessage.messageId)
        {
            case OneMillisec:
                MillisecLowLoop(MillisecLowMessage.tick);
                break;
            default:
                break;
        }
    }
}


/*uint32_t getMotorStatusData(int MotorId)
{
    assert (MotorId < NUM_OF_MOTORS);
    return MotorStatus_Data[MotorId];
}*/
/*uint32_t getMotorSpeedData(int MotorId)
{
    assert (MotorId < NUM_OF_MOTORS);
    return MotorSpeed_Data[MotorId];
}
*/
/*uint32_t getTemperatureSensorData(int SensorId)
{
    assert (SensorId < MAX_TEMPERATURE_SENSOR_ID);
    return TemperatureSensor_Data[SensorId];
}*/

/*uint32_t getADCData(int DeviceId)
{
    assert (DeviceId < MAX_ADC_DEVICES);
    return ADC_Data[DeviceId];
}*/
float getSensorSpeedData(void)
{
    return Speed_Data;
}

uint32_t getDrawerFansStatus(void)
{
    return DrawerFansStatus;
}