dox/html/SVTV1P0__ADCR__SR_8cxx_source.html

 /***************************************************************************

  *

  * $Id: SVTV1P0_ADCR_SR.cxx,v 1.5 2007/12/24 06:04:27 fine Exp $

  *

  * Author: Jeff Landgraf, M.J. LeVine, Marcelo Munhoz, J. Schambach

  *

  ***************************************************************************

  *

  * Description: // SVT ADC Raw Reader

  *

  ***************************************************************************

  *

  * $Log: SVTV1P0_ADCR_SR.cxx,v $

  * Revision 1.5  2007/12/24 06:04:27  fine

  * introduce OLDEVP namespace to allow ole and new EVP library concurrently

  *

  * Revision 1.4  2003/09/02 17:55:33  perev

  * gcc 3.2 updates + WarnOff

  *

  * Revision 1.3  2001/05/10 15:19:08  jschamba

  * unscrambling of Format = 2 data was done each time initialize was called. Rewrite header

  * to indicate Format = 0 after unscrambling prevents this.

  *

  * Revision 1.2  2001/04/18 19:47:25  ward

  * StDaqLib/SVT stuff from Jo Schambach.

  *

  * Revision 1.1  2000/06/06 18:08:31  jml

  * Initial version of SVT Readers (author: marcello munholz, helen caines)

  *

  *

  **************************************************************************/

 #include <Stiostream.h>


 #include "StDaqLib/GENERIC/EventReader.hh"

 #include "SVTV1P0.hh"


 //==================== ADC Raw  Reader =============================


 using namespace OLDEVP;


 SVTV1P0_ADCR_SR::SVTV1P0_ADCR_SR(int w, SVTV1P0_Reader *det)

 {

   //  cout << "Constructing SVTV1P0_ADCR_SR" << endl;

   barrel = 0;

   ladder = 0;

   wafer = w;

   detector = det;


   // NULLS in banks array

   banks = (classname(Bank_SVTADCR) *)NULL;

 }


 SVTV1P0_ADCR_SR::SVTV1P0_ADCR_SR(int b, int l, int w, SVTV1P0_Reader *det)

 {

   //  cout << "Constructing SVTV1P0_ADCR_SR" << endl;

   barrel = b;

   ladder = l;

   wafer = w;

   detector = det;


   // NULLS in banks array

   banks = (classname(Bank_SVTADCR) *)NULL;

 }


 int SVTV1P0_ADCR_SR::initialize()

 {

   // get a sector reader for ANODK

   anodkr = detector->getANODKReader();

   if (!anodkr) return FALSE;


   int hypersector, rcb, mz;


   ANODK_entry ent;

   // store pointers to the ADCR banks

   int hybrid = 1; // both hybrids are in same bank

   if (barrel)

     anodkr->get(barrel, ladder, wafer, hybrid, &ent);

   else

     anodkr->get(wafer, hybrid, &ent);


   hypersector = ent.hypersector;

   rcb = ent.rb;

   mz = ent.mz;


   /*

     printf("SVTV1P0_ADCR_SR::wafer = %d, hybrid = %d, hypersector = %d, rcb = %d, mz = %d\n",

     wafer,hybrid,hypersector,rcb,mz);

   */


   if ((hypersector) && (rcb) && (mz)) {

     banks = detector->getBankSVTADCR(hypersector,rcb,mz);


     if (banks) {

       // check the format number for different raw data formats:

       if (banks->header.FormatNumber == 2) {

         // new format of raw data, need to convert it:

         u_char *adc_old = (u_char *)banks->ADC;

         u_char adc_new[6][256][128];

         for (hybrid=0; hybrid<6; hybrid++) {

           u_char *ptr0   = adc_old + hybrid*128*256;

           u_char *ptr64  = adc_old + hybrid*128*256 + 1;

           u_char *ptr128 = adc_old + hybrid*128*256 + 2;

           u_char *ptr192 = adc_old + hybrid*128*256 + 3;

           for (int anode=0; anode<64; anode++)

             for (int tb=0; tb<128; tb++) {

               adc_new[hybrid][anode][tb]     = *ptr0;

               adc_new[hybrid][anode+64][tb]  = *ptr64;

               adc_new[hybrid][anode+128][tb] = *ptr128;

               adc_new[hybrid][anode+192][tb] = *ptr192;

               ptr0+=4; ptr64+=4; ptr128+=4; ptr192+=4;

             }

         }

         memcpy((void *)adc_old, (const void *)adc_new, 6*256*128);

         // since this now looks like unscrambled (format 0) data

         // change the format number in the header to 0

         banks->header.FormatNumber = 0;

       } // ...if (banks->header.FormatNumber == 2

     }   // ...if (banks

   }

   else

     return FALSE;


   return TRUE;

 }


 SVTV1P0_ADCR_SR::~SVTV1P0_ADCR_SR()

 {

   //  cout << "Deleting SVTV1P0_ADCR_SR" << endl;

 }


 int SVTV1P0_ADCR_SR::getPadList(int hybrid, u_char **anodeList)

 {

   // Construct the anodelist array for this PadRow

   int i;

   ANODK_entry ent;


   // Fill in padrows

   int j=0;

   for(i=1; i<=SVT_ANODES; i++)

   {

     if (barrel)

       anodkr->get(barrel, ladder, wafer, hybrid, &ent);

     else

       anodkr->get(wafer, hybrid, &ent);


     if((ent.mz == 0) || (ent.rb == 0) || (ent.hypersector == 0)) continue;

     anodelist[hybrid-1][j++] = i;

   }

           // confusing syntax but correct

   *anodeList = &anodelist[hybrid-1][0];

   return j;

 }


 int SVTV1P0_ADCR_SR::getSequences(int hybrid, int Anode, int *nArray,

                                   u_char **Array)

 {

   ANODK_entry ent;

   if (barrel)

     anodkr->get(barrel, ladder, wafer, hybrid, &ent);

   else

     anodkr->get(wafer, hybrid, &ent);


   if((ent.mz == 0) || (ent.rb == 0) || (ent.hypersector == 0))

   {

     *nArray = 0;

     *Array = NULL;

     spERROR(ERR_BANK);

     return -1;

   }


   int offset = (ent.offset * anodkr->getADCBytes() * SVT_MZANODES) +

     (anodkr->getADCBytes() * (Anode-1));

   *nArray = anodkr->getADCBytes();


   //  printf("Offset = %d\n",offset);

   // printf("array coord:  rb=%d,  mz=%d\n",ent.rb,ent.mz);


   if (banks != NULL)

     {

       *Array = (((u_char *)banks->ADC) + offset);

       //      cout << "SVTV1P0_ADCR_SR::Array = " << *Array << endl;

       return 1;

     }


   return 0;

 }


 int SVTV1P0_ADCR_SR::MemUsed()

 {

   return 0;

 }


 //==================== Pedestal Reader ===========================


 SVTV1P0_PEDR_SR::SVTV1P0_PEDR_SR(int w, SVTV1P0_Reader *det)

 {

   //  cout << "Constructing SVTV1P0_PEDR_SR" << endl;

   barrel = 0;

   ladder = 0;

   wafer = w;

   detector = det;


   // NULLS in banks array

   banks = (classname(Bank_SVTPEDR) *)NULL;

   numEvents = 0;

 }


 SVTV1P0_PEDR_SR::SVTV1P0_PEDR_SR(int b, int l, int w, SVTV1P0_Reader *det)

 {

   //  cout << "Constructing SVTV1P0_PEDR_SR" << endl;

   barrel = b;

   ladder = l;

   wafer = w;

   detector = det;


   // NULLS in banks array

   banks = (classname(Bank_SVTPEDR) *)NULL;

   numEvents = 0;

 }


 int SVTV1P0_PEDR_SR::initialize()

 {

   // get a sector reader for ANODK

   anodkr = detector->getANODKReader();

   if (!anodkr) return FALSE;


   int hypersector, rcb, mz;


   ANODK_entry ent;

   // store pointers to the PEDR banks

   int hybrid = 1; // both hybrids are in same bank

   if (barrel)

     anodkr->get(barrel, ladder, wafer, hybrid, &ent);

   else

     anodkr->get(wafer, hybrid, &ent);


   hypersector = ent.hypersector;

   rcb = ent.rb;

   mz = ent.mz;


   banks = detector->getBankSVTPEDR(hypersector,rcb,mz);


   if (banks != NULL) {

     numEvents = banks->NumEvents;

     // check the format number for different raw data formats:

     if (banks->header.FormatNumber == 2) {

       // new format of raw data, need to convert it:

       u_char *adc_old = (u_char *)banks->pedestal;

       u_char adc_new[6][256][128];

       for (hybrid=0; hybrid<6; hybrid++) {

         u_char *ptr0   = adc_old + hybrid*128*256;

         u_char *ptr64  = adc_old + hybrid*128*256 + 1;

         u_char *ptr128 = adc_old + hybrid*128*256 + 2;

         u_char *ptr192 = adc_old + hybrid*128*256 + 3;

         for (int anode=0; anode<64; anode++)

           for (int tb=0; tb<128; tb++) {

             adc_new[hybrid][anode][tb]     = *ptr0;

             adc_new[hybrid][anode+64][tb]  = *ptr64;

             adc_new[hybrid][anode+128][tb] = *ptr128;

             adc_new[hybrid][anode+192][tb] = *ptr192;

             ptr0+=4; ptr64+=4; ptr128+=4; ptr192+=4;

           }

       }

       memcpy((void *)adc_old, (const void *)adc_new, 6*256*128);

       // since this now looks like unscrambled (format 0) data

       // change the format number in the header to 0

       banks->header.FormatNumber = 0;

     } // ...if (banks->header.FormatNumber == 2

   }   // ...if (banks != NULL


   return TRUE;

 }


 SVTV1P0_PEDR_SR::~SVTV1P0_PEDR_SR()

 {

   //  cout << "Deleting SVTV1P0_PEDR_SR" << endl;

 }


 int SVTV1P0_PEDR_SR::getPadList(int hybrid, u_char **anodeList)

 {

   // Construct the anodelist array for this PadRow

   int i;

   ANODK_entry ent;


   // Fill in padrows

   int j=0;

   for(i=1; i<=SVT_ANODES; i++)

   {

     if (barrel)

       anodkr->get(barrel, ladder, wafer, hybrid, &ent);

     else

       anodkr->get(wafer, hybrid, &ent);


     if((ent.mz == 0) || (ent.rb == 0) || (ent.hypersector == 0)) continue;

     anodelist[hybrid-1][j++] = i;

   }

           // confusing syntax but correct

   *anodeList = &anodelist[hybrid-1][0];

   return j;

 }


 int SVTV1P0_PEDR_SR::getSequences(int hybrid, int Anode, int *nArray,

                                   u_char **Array)

 {

   ANODK_entry ent;

   if (barrel)

     anodkr->get(barrel, ladder, wafer, hybrid, &ent);

   else

     anodkr->get(wafer, hybrid, &ent);


   if((ent.mz == 0) || (ent.rb == 0) || (ent.hypersector == 0))

   {

     *nArray = 0;

     *Array = NULL;

     spERROR(ERR_BANK);

     return -1;

   }


   int offset = (ent.offset * anodkr->getPEDBytes() * SVT_MZANODES) +

     (anodkr->getPEDBytes() * (Anode-1));

   *nArray = anodkr->getPEDBytes();


   if (banks != NULL) {

     //      printf("Offset = %d\n",offset);

     //      printf("array coord:  rb=%d,  mz=%d\n",ent.rb,ent.mz);

     *Array = (((u_char *)banks->pedestal) + offset);

     return 1;

   }

   return 0;

 }


 int SVTV1P0_PEDR_SR::getNumberOfEvents()

 {

   return numEvents;

 }


 int SVTV1P0_PEDR_SR::MemUsed()

 {

   return 0;

 }


 //==================== RMS  Reader =============================


 SVTV1P0_PRMS_SR::SVTV1P0_PRMS_SR(int w, SVTV1P0_Reader *det)

 {

   //  cout << "Constructing SVTV1P0_PRMS_SR" << endl;

   barrel = 0;

   ladder = 0;

   wafer = w;

   detector = det;


   // NULLS in banks array

   banks = (classname(Bank_SVTRMSR) *)NULL;

   numEvents = 0;


 }


 SVTV1P0_PRMS_SR::SVTV1P0_PRMS_SR(int b, int l, int w, SVTV1P0_Reader *det)

 {

   //  cout << "Constructing SVTV1P0_PRMS_SR" << endl;

   barrel = b;

   ladder = l;

   wafer = w;

   detector = det;


   // NULLS in banks array

   banks = (classname(Bank_SVTRMSR) *)NULL;

   numEvents = 0;

 }


 int SVTV1P0_PRMS_SR::initialize()

 {

   // get a sector reader for ANODK

   anodkr = detector->getANODKReader();

   if (!anodkr) return FALSE;


   int hypersector, rcb, mz;


   ANODK_entry ent;

   // store pointers to the ADCR banks

   int hybrid = 1;

   if (barrel)

     anodkr->get(barrel, ladder, wafer, hybrid, &ent);

   else

     anodkr->get(wafer, hybrid, &ent);


   hypersector = ent.hypersector;

   rcb = ent.rb;

   mz = ent.mz;


   banks = detector->getBankSVTRMSR(hypersector,rcb,mz);


   if (banks != NULL) {

     numEvents = banks->NumEvents;


     // check the format number for different raw data formats:

     if (banks->header.FormatNumber == 2) {

       // new format of raw data, need to convert it:

       u_char *adc_old = (u_char *)banks->pedRMSt16;

       u_char adc_new[6][256][128];

       for (hybrid=0; hybrid<6; hybrid++) {

         u_char *ptr0   = adc_old + hybrid*128*256;

         u_char *ptr64  = adc_old + hybrid*128*256 + 1;

         u_char *ptr128 = adc_old + hybrid*128*256 + 2;

         u_char *ptr192 = adc_old + hybrid*128*256 + 3;

         for (int anode=0; anode<64; anode++)

           for (int tb=0; tb<128; tb++) {

             adc_new[hybrid][anode][tb]     = *ptr0;

             adc_new[hybrid][anode+64][tb]  = *ptr64;

             adc_new[hybrid][anode+128][tb] = *ptr128;

             adc_new[hybrid][anode+192][tb] = *ptr192;

             ptr0+=4; ptr64+=4; ptr128+=4; ptr192+=4;

           }

       }

       memcpy((void *)adc_old, (const void *)adc_new, 6*256*128);

       // since this now looks like unscrambled (format 0) data

       // change the format number in the header to 0

       banks->header.FormatNumber = 0;

     } // ...if (banks->header.FormatNumber == 2

   }   // ...if (banks !=NULL


   return TRUE;

 }


 SVTV1P0_PRMS_SR::~SVTV1P0_PRMS_SR()

 {

   //  cout << "Deleting SVTV1P0_PRMS_SR" << endl;

 }


 int SVTV1P0_PRMS_SR::getPadList(int hybrid, u_char **anodeList)

 {

   // Construct the anodelist array for this PadRow

   int i;

   ANODK_entry ent;


   // Fill in padrows

   int j=0;

   for(i=1; i<=SVT_ANODES; i++)

   {

     if (barrel)

       anodkr->get(barrel, ladder, wafer, hybrid, &ent);

     else

       anodkr->get(wafer, hybrid, &ent);


     if((ent.mz == 0) || (ent.rb == 0) || (ent.hypersector == 0)) continue;

     anodelist[hybrid-1][j++] = i;

   }

           // confusing syntax but correct

   *anodeList = &anodelist[hybrid-1][0];

   return j;

 }


 int SVTV1P0_PRMS_SR::getSequences(int hybrid, int Anode, int *nArray,

                                   u_char **Array)

 {

   ANODK_entry ent;

   if (barrel)

     anodkr->get(barrel, ladder, wafer, hybrid, &ent);

   else

     anodkr->get(wafer, hybrid, &ent);


   if((ent.mz == 0) || (ent.rb == 0) || (ent.hypersector == 0))

   {

     *nArray = 0;

     *Array = NULL;

     spERROR(ERR_BANK);

     return -1;

   }


   int offset = (ent.offset * anodkr->getRMSBytes() * SVT_MZANODES) +

     (anodkr->getRMSBytes() * (Anode-1));

   *nArray = anodkr->getRMSBytes();


   if (banks != NULL)

     {

       // printf("Offset = %d\n",offset);

       // printf("array coord:  rb=%d,  mz=%d\n",ent.rb,ent.mz);

       *Array = (((u_char *)banks->pedRMSt16) + offset);

       return 1;

     }

   return 0;

 }


 int SVTV1P0_PRMS_SR::getNumberOfEvents()

 {

   return numEvents;

 }


 int SVTV1P0_PRMS_SR::MemUsed()

 {

   return 0;

 }


Stiostream.h

SVTV1P0_Reader
Definition: SVTV1P0_Reader.hh:54

ANODK_entry
Definition: SVTV1P0.hh:222