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//
// Date init       14.12.2004
//
// Revision date   $Date:: 14-11-07 12:40                                    $
//
// Filename        $Workfile:: c_output.c                                    $
//
// Version         $Revision:: 1                                             $
//
// Archive         $Archive:: /LMS2006/Sys01/Main_V02/Firmware/Source/c_outp $
//
// Platform        C
//

#include  <stdio.h>
#include  "stdbool.h"
#include  "stdconst.h"
#include  "modules.h"
#include  "c_output.iom"
#include  "c_output.h"
#include  "d_output.h"
#include  "c_display.iom"

static    IOMAPOUTPUT   IOMapOutput;
static    VARSOUTPUT    VarsOutput;

const     HEADER       cOutput =
{
  0x00020001L,
  "Output",
  cOutputInit,
  cOutputCtrl,
  cOutputExit,
  (void *)&IOMapOutput,
  (void *)&VarsOutput,
  (UWORD)sizeof(IOMapOutput),
  (UWORD)sizeof(VarsOutput),
  0x0000                      //Code size - not used so far
};


void      cOutputInit(void* pHeader)
{
  UBYTE   Tmp;

  for(Tmp = 0; Tmp < NO_OF_OUTPUTS; Tmp++)
  {
    OUTPUT * pOut = &(IOMapOutput.Outputs[Tmp]);
    pOut->Mode  = 0x00;
    pOut->Speed = 0x00;
    pOut->ActualSpeed = 0x00;
    pOut->TachoCnt = 0x00;
    pOut->RunState = 0x00;
    pOut->TachoLimit = 0x00;
    pOut->RegPParameter = DEFAULT_P_GAIN_FACTOR;
    pOut->RegIParameter = DEFAULT_I_GAIN_FACTOR;
    pOut->RegDParameter = DEFAULT_D_GAIN_FACTOR;
    pOut->Options = 0x00;
  }
  VarsOutput.TimeCnt = 0;
  dOutputInit();
}

void cOutputCtrl(void)
{
  UBYTE Tmp;

  for(Tmp = 0; Tmp < NO_OF_OUTPUTS; Tmp++)
  {
    OUTPUT * pOut = &(IOMapOutput.Outputs[Tmp]);
    if (pOut->Flags != 0)
    {
      if (pOut->Flags & UPDATE_RESET_ROTATION_COUNT)
      {
        pOut->Flags &= ~UPDATE_RESET_ROTATION_COUNT;
        dOutputResetRotationCaptureCount(Tmp);
      }      
      if (pOut->Flags & UPDATE_RESET_COUNT)
      {
        pOut->Flags &= ~UPDATE_RESET_COUNT;
        dOutputResetTachoLimit(Tmp);
      }
      if (pOut->Flags & UPDATE_RESET_BLOCK_COUNT)
      {
        pOut->Flags &= ~UPDATE_RESET_BLOCK_COUNT;
        dOutputResetBlockTachoLimit(Tmp);
      }
      if (pOut->Flags & UPDATE_SPEED)
      {
        pOut->Flags &= ~UPDATE_SPEED;
        if (pOut->Mode & MOTORON)
        {
          dOutputSetSpeed(Tmp, pOut->RunState, pOut->Speed, pOut->SyncTurnParameter);
        }
      }
      if (pOut->Flags & UPDATE_TACHO_LIMIT)
      {
        pOut->Flags &= ~UPDATE_TACHO_LIMIT;
        dOutputSetTachoLimit(Tmp, pOut->TachoLimit);
      }
      if (pOut->Flags & UPDATE_MODE)
      {
        pOut->Flags &= ~UPDATE_MODE;
        if (pOut->Mode & BRAKE)
        {
          // Motor is Braked
          dOutputSetMode(Tmp, BRAKE);
        }
        else
        {
          // Motor is floated
          dOutputSetMode(Tmp, 0x00);
        }
        if (pOut->Mode & MOTORON)
        {
          if (pOut->Mode & REGULATED)
          {
            dOutputEnableRegulation(Tmp, pOut->RegMode);
          }
          else
          {
            dOutputDisableRegulation(Tmp);
          }
        }
        else
        {
          dOutputSetSpeed(Tmp, 0x00, 0x00, 0x00);
          dOutputDisableRegulation(Tmp);
        }
      }
      if (pOut->Flags & UPDATE_PID_VALUES)
      {
        pOut->Flags &= ~UPDATE_PID_VALUES;
        dOutputSetPIDParameters(Tmp, pOut->RegPParameter, pOut->RegIParameter, pOut->RegDParameter);
      }
    }
  }
  dOutputCtrl();
  cOutputUpdateIomap();
}

void cOutputUpdateIomap(void)
{
	UBYTE TempCurrentMotorSpeed[NO_OF_OUTPUTS];
	UBYTE TempRunState[NO_OF_OUTPUTS];	
  UBYTE TempMotorOverloaded[NO_OF_OUTPUTS];
	SLONG TempTachoCount[NO_OF_OUTPUTS];
  SLONG TempBlockTachoCount[NO_OF_OUTPUTS];
  SLONG TempRotationCount[NO_OF_OUTPUTS];

  UBYTE Tmp;
  
	dOutputGetMotorParameters(TempCurrentMotorSpeed, TempTachoCount, TempBlockTachoCount, TempRunState, TempMotorOverloaded,TempRotationCount);

	for(Tmp = 0; Tmp < NO_OF_OUTPUTS; Tmp++)
  {
    OUTPUT * pOut = &(IOMapOutput.Outputs[Tmp]);
    pOut->ActualSpeed = TempCurrentMotorSpeed[Tmp];
    pOut->TachoCnt = TempTachoCount[Tmp];	
    pOut->BlockTachoCount = TempBlockTachoCount[Tmp];
    pOut->RotationCount = TempRotationCount[Tmp];
    pOut->Overloaded = TempMotorOverloaded[Tmp];
    if (!(pOut->Flags & PENDING_UPDATES))
    {
      pOut->RunState = TempRunState[Tmp];
    }
	}
}

void      cOutputExit(void)
{
  dOutputExit();
}