#ifdef _WINDOWS#include <windows.h>#endif #include <stdio.h>#ifndef LINUX#include <conio.h>#endif#include <assert.h>#include <string.h>#include <math.h>#include <stdlib.h>#include <ctype.h>#include <stdarg.h>#include "wlantype.h"   /* typedefs for A_UINT16 etc.. */#include "wlanproto.h"#include "athreg.h"#include "manlib.h"     /* The Manufacturing Library */#include "MLIBif.h"     /* Manufacturing Library low level driver support functions */#ifdef JUNGO#include "mld.h"        /* Low level driver information */#endif#include "common_hw.h"#include "manlibInst.h" /* The Manufacturing Library Instrument Library extension */#include "mEeprom.h"    /* Definitions for the data structure */#include "dynamic_optimizations.h"#include "maui_cal.h"   /* Definitions for the Calibration Library */#include "rssi_power.h"#include "test.h"#include "parse.h"#include "dk_cmds.h"#include "dk_ver.h"//#include "mConfig.h"
#ifdef LINUX#include "linux_ansi.h"#include "unistd.h"#endif    #include "art_if.h"#include "ar2413/mEEPROM_g.h"#include "ar5212/mEEPROM_d.h"#include "cal_gen5.h"#include "ar6000/mEepStruct6000.h"extern  RAW_DATA_STRUCT_GEN5 *pRawDataset_gen5[] ; extern TARGETS_SET      *pTargetsSet;extern TARGETS_SET      *pTargetsSet_2p4[];extern YIELD_LOG_STRUCT yldStruct;static void ar6000EepromDump(A_UINT32 devNum, AR6K_EEPROM *);static void fillHeader(AR6K_EEPROM *pEepStruct);static void fillCalData (AR6K_EEPROM *pEepStruct);static void fillPwrVpdData (CAL_DATA_PER_FREQ *pCalData, RAW_DATA_PER_CHANNEL_GEN5 *pCalCh, A_UINT32 pierIndex);static void fillTargetPowerData (AR6K_EEPROM *pEepStruct);static void fillCtlData (AR6K_EEPROM *pEepStruct);static void computeChecksum (AR6K_EEPROM *pEepStruct);static void writeEepromStruct (A_UINT32 devNum, AR6K_EEPROM *pEepStruct);static void fillAR6000EepromLabel (A_UINT32 devNum,  AR6K_EEPROM *pEepStruct) ;//static A_BOOL eepStructValid = FALSE;

#define A_MIN(x, y) (((x) < (y)) ? (x) : (y))void programCompactEeprom( A_UINT32 devNum){
    AR6K_EEPROM eepStruct;	//printf("IN programCompactEeprom \n");	    //zero out the structure    memset((void *)&eepStruct, 0, sizeof(AR6K_EEPROM));    //base structure (some of it)    eepStruct.baseEepHeader.version = 0xf000;    // zero checksum    eepStruct.baseEepHeader.checksum = 0x0000;    eepStruct.baseEepHeader.regDmn = (A_UINT16)(((CalSetup.countryOrDomain & 0x1) << 15) | ((CalSetup.worldWideRoaming & 0x1) << 14) |                                (CalSetup.countryOrDomainCode & 0xfff)) ;	if(CalSetup.countryOrDomain && CalSetup.worldWideRoaming && (CalSetup.countryOrDomainCode & 0xfff))	{		//set the other 2 bits of regDmn to 1		eepStruct.baseEepHeader.regDmn = eepStruct.baseEepHeader.regDmn | (0x3 << 12);	}	else	{		//clear the two bits		eepStruct.baseEepHeader.regDmn = (eepStruct.baseEepHeader.regDmn & 0xCFFF);	}    //mac address - assuming label scheme for now - need to make some more changes for customer release        if(configSetup.enableLabelScheme) {		eepStruct.baseEepHeader.macAddr[0] = (A_UCHAR)((yldStruct.macID1[0] >> 8) & 0xFF);		    eepStruct.baseEepHeader.macAddr[1] = (A_UCHAR)((yldStruct.macID1[0]) & 0xFF);		    eepStruct.baseEepHeader.macAddr[2] = (A_UCHAR)((yldStruct.macID1[1] >> 8) & 0xFF);	    eepStruct.baseEepHeader.macAddr[3] = (A_UCHAR)((yldStruct.macID1[1]) & 0xFF);	    eepStruct.baseEepHeader.macAddr[4] = (A_UCHAR)((yldStruct.macID1[2] >> 8) & 0xFF);	    eepStruct.baseEepHeader.macAddr[5] = (A_UCHAR)((yldStruct.macID1[2]) & 0xFF);	}    else //write 1's, so WLAN driver will load even before real address is written.    {    	eepStruct.baseEepHeader.macAddr[0] = (A_UCHAR)(0xFF);		    eepStruct.baseEepHeader.macAddr[1] = (A_UCHAR)(0xFF);		    eepStruct.baseEepHeader.macAddr[2] = (A_UCHAR)(0xFF);	    eepStruct.baseEepHeader.macAddr[3] = (A_UCHAR)(0xFF);	    eepStruct.baseEepHeader.macAddr[4] = (A_UCHAR)(0xFF);	    eepStruct.baseEepHeader.macAddr[5] = (A_UCHAR)(0xFF);      }        eepStruct.baseEepHeader.opFlags = ((CalSetup.Amode) ? AR6000_OPFLAGS_11A : 0) |         ((CalSetup.Gmode) ? AR6000_OPFLAGS_11G : 0);        {	   A_UINT16  *pSubSystemID = (A_UINT16 *)(&(eepStruct.baseEepHeader.custData[0]));	   A_UINT16 i;       *pSubSystemID = CalSetup.subsystemID;	   	   	   for(i = 2; i < 30; i++) {	       eepStruct.baseEepHeader.custData[i] = 0xff;	   }       }     //fill in the header information    fillHeader(&eepStruct);    //Would fill in the spur information here, leave these for now - default to no spurs    eepStruct.spurChans[0][0] = 0x8000;    eepStruct.spurChans[1][0] = 0x8000;    //fill in the calibration information    fillCalData(&eepStruct);    //fill the target power information    fillTargetPowerData(&eepStruct);    //fill the CTL information    fillCtlData(&eepStruct);
	    if(configSetup.enableLabelScheme) {	    //fill the label - again assuming label scheme for now, change for customer release	    fillAR6000EepromLabel(devNum, &eepStruct);	}
		//Compute checksum once all other areas are filled.    computeChecksum(&eepStruct);
	    //write struct to eeprom     writeEepromStruct(devNum, &eepStruct);//    ar6000EepromDump(devNum, &eepStruct);    
		}void fillHeader( AR6K_EEPROM *pEepStruct){    MODAL_EEP_HEADER *pModal;    //11a header    pModal = &(pEepStruct->modalHeader[0]);        //antennaControl    pModal->antCtrl0 = (A_UINT8)(CalSetup.antennaControl[0] & 0xff);    pModal->antCtrl[0] = CalSetup.antennaControl[1] & 0x3F;    pModal->antCtrl[0] |= ((CalSetup.antennaControl[2] & 0x3F) << 6);    pModal->antCtrl[0] |= ((CalSetup.antennaControl[3] & 0x3F) << 12);    pModal->antCtrl[0] |= ((CalSetup.antennaControl[4] & 0x3F) << 18);    pModal->antCtrl[0] |= ((CalSetup.antennaControl[5] & 0x3F) << 24);    pModal->antCtrl[1] = CalSetup.antennaControl[6] & 0x3F;    pModal->antCtrl[1] |= ((CalSetup.antennaControl[7] & 0x3F) << 6);    pModal->antCtrl[1] |= ((CalSetup.antennaControl[8] & 0x3F) << 12);    pModal->antCtrl[1] |= ((CalSetup.antennaControl[9] & 0x3F) << 18);    pModal->antCtrl[1] |= ((CalSetup.antennaControl[10] & 0x3F) << 24);    pModal->antennaGain = CalSetup.antennaGain5G & 0xff;    pModal->switchSettling = (A_UINT8)(CalSetup.switchSettling & 0x7f);    pModal->txRxAtten = (A_UINT8)(CalSetup.txrxAtten & 0x3f);    pModal->rxTxMargin = (A_UINT8)(CalSetup.rxtx_margin[MODE_11a] & 0x3F);    pModal->adcDesiredSize = CalSetup.adcDesiredSize & 0xff;    pModal->pgaDesiredSize = CalSetup.pgaDesiredSize & 0xff;    pModal->txEndToXlnaOn = (A_UINT8)(CalSetup.txEndToXLNAOn & 0xff);    pModal->xlnaGain = (A_UINT8)(CalSetup.xlnaGain & 0xff);    pModal->txEndToXpaOff = (A_UINT8)(CalSetup.txEndToXPAOff & 0xff);    pModal->txFrameToXpaOn = (A_UINT8)(CalSetup.txFrameToXPAOn & 0xff);    pModal->thresh62 = (A_UINT8)(CalSetup.thresh62 & 0xff);    pModal->noiseFloorThresh = CalSetup.noisefloor_thresh & 0xff;    pModal->xpdGain = (A_UINT8)(CalSetup.xgain & 0xf);    pModal->xpd = (A_UINT8)(CalSetup.xpd & 0x1);        //Set IQ coeffs to 0 right now, at some point we may decide we need it    //at that point verify that the data is being correctly held for     //signed use.    pModal->iqCalI = CalSetup.iqcal_i_corr[MODE_11a] & 0x3f;    pModal->iqCalQ = CalSetup.iqcal_q_corr[MODE_11a] & 0x1f;    //11g header info    pModal = &(pEepStruct->modalHeader[1]);    //antennaControl       pModal->antCtrl0 = (A_UINT8)(CalSetup.antennaControl_2p4[MODE_11g][0]);    pModal->antCtrl[0] = CalSetup.antennaControl_2p4[MODE_11g][1] & 0x3F;    pModal->antCtrl[0] |= ((CalSetup.antennaControl_2p4[MODE_11g][2] & 0x3F) << 6);    pModal->antCtrl[0] |= ((CalSetup.antennaControl_2p4[MODE_11g][3] & 0x3F) << 12);    pModal->antCtrl[0] |= ((CalSetup.antennaControl_2p4[MODE_11g][4] & 0x3F) << 18);    pModal->antCtrl[0] |= ((CalSetup.antennaControl_2p4[MODE_11g][5] & 0x3F) << 24);    pModal->antCtrl[1] = CalSetup.antennaControl_2p4[MODE_11g][6] & 0x3F;    pModal->antCtrl[1] |= ((CalSetup.antennaControl_2p4[MODE_11g][7] & 0x3F) << 6);    pModal->antCtrl[1] |= ((CalSetup.antennaControl_2p4[MODE_11g][8] & 0x3F) << 12);    pModal->antCtrl[1] |= ((CalSetup.antennaControl_2p4[MODE_11g][9] & 0x3F) << 18);    pModal->antCtrl[1] |= ((CalSetup.antennaControl_2p4[MODE_11g][10] & 0x3F) << 24);    pModal->antennaGain = CalSetup.antennaGain2p5G & 0xff;    pModal->switchSettling = (A_UINT8)(CalSetup.switchSettling_2p4[MODE_11g] & 0x7f);    pModal->txRxAtten = (A_UINT8)(CalSetup.txrxAtten_2p4[MODE_11g] & 0x3f);    pModal->rxTxMargin = (A_UINT8)(CalSetup.rxtx_margin[MODE_11g] & 0x3F);    pModal->adcDesiredSize = CalSetup.adcDesiredSize_2p4[MODE_11g] & 0xff;    pModal->pgaDesiredSize = CalSetup.pgaDesiredSize_2p4[MODE_11g] & 0xff;    pModal->txEndToXlnaOn = (A_UINT8)(CalSetup.txEndToXLNAOn_2p4[MODE_11g] & 0xff);    pModal->xlnaGain = (A_UINT8)(CalSetup.xlnaGain_2p4[MODE_11g] & 0xff);    pModal->txEndToXpaOff = (A_UINT8)(CalSetup.txEndToXPAOff_2p4[MODE_11g] & 0xff);    pModal->txFrameToXpaOn = (A_UINT8)(CalSetup.txFrameToXPAOn_2p4[MODE_11g] & 0xff);    pModal->thresh62 = (A_UINT8)(CalSetup.thresh62_2p4[MODE_11g] & 0xff);    pModal->noiseFloorThresh = CalSetup.noisefloor_thresh_2p4[MODE_11g] & 0xff;    pModal->xpdGain = (A_UINT8)(CalSetup.xgain_2p4[MODE_11g] & 0xf);    pModal->xpd = (A_UINT8)(CalSetup.xpd_2p4[MODE_11g] & 0x1);    //Set IQ coeffs to 0 right now, at some point we may decide we need it    //at that point verify that the data is being correctly held for     //signed use.    pModal->iqCalI = CalSetup.iqcal_i_corr[MODE_11g] & 0x3f;    pModal->iqCalQ = CalSetup.iqcal_q_corr[MODE_11g] & 0x1f;}void fillCalData ( AR6K_EEPROM *pEepStruct){    A_UINT32 ii, jj;    A_UINT32 numPiers;    A_UINT16 freqmask = 0xff;    RAW_DATA_PER_CHANNEL_GEN5 *pCalCh;    //fill 11a frequency piers and cal data    numPiers = pRawDataset_gen5[MODE_11a]->numChannels;    if (numPiers > AR6000_NUM_11A_CAL_PIERS) {        numPiers = AR6000_NUM_11A_CAL_PIERS;    }    for (ii=0; ii<numPiers; ii++)    {        //frequency pier        pEepStruct->calFreqPier11A[ii] = (A_UINT8)(freq2fbin(pRawDataset_gen5[MODE_11a]->pChannels[ii]));        pCalCh = &(pRawDataset_gen5[MODE_11a]->pDataPerChannel[ii]);        if((pCalCh->numPdGains > AR6000_NUM_PD_GAINS) || (pCalCh->numPdGains == 0)) {            uiPrintf("Number of pdgains must be 1 or 2 for ar6000 chipset.  Exiting...\n");            exit(0);        }                //fill the 11a calibration values        fillPwrVpdData(pEepStruct->calPierData11A, pCalCh, ii);    }        if(numPiers < AR6000_NUM_11A_CAL_PIERS) {        for(jj = ii ; jj < AR6000_NUM_11A_CAL_PIERS; jj++) {            pEepStruct->calFreqPier11A[jj] = 0xff;        }    }    //11g frequency piers    numPiers = CalSetup.numForcedPiers_2p4[MODE_11g];    if (numPiers > AR6000_NUM_11G_CAL_PIERS) {        numPiers = AR6000_NUM_11G_CAL_PIERS;    }    for(ii = 0; ii < numPiers; ii++) {        pEepStruct->calFreqPier11G[ii] = (A_UINT8)(freq2fbin(CalSetup.piersList_2p4[MODE_11g][ii]));        pCalCh = &(pRawDataset_gen5[MODE_11g]->pDataPerChannel[ii]);        if((pCalCh->numPdGains > AR6000_NUM_PD_GAINS) || (pCalCh->numPdGains == 0)) {            uiPrintf("Number of pdgains must be 1 or 2 for ar6000 chipset.  Exiting...\n");            exit(0);        }                //fill the 11g calibration values        fillPwrVpdData(pEepStruct->calPierData11G, pCalCh, ii);    }