DCLibraries/src/storeINdata.cpp

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2023-11-08 13:02:26 +01:00
#include <stdint.h>
#include <QString>
#include <QDebug>
#include "storeINdata.h"
#include "tslib.h"
#include "shared_mem_buffer.h"
#include "datei.h"
// gpi: grafical access to PI: access from external devices over device controller FOR GUI
// epi: external access from GUI to PI: FOR external devices (DC)
// store power on/off condition of the devices to control the data request
//static bool indat_savePrnPwr;
void indat_storePrinterPower(bool isOn)
{
SharedMem::write()->indat_savePrnPwr=isOn;
}
bool indat_isPrinterOn()
{
return SharedMem::read()->indat_savePrnPwr;
}
//static bool indat_saveMifPwr;
void indat_storeMifarePower(bool isOn)
{
SharedMem::write()->indat_saveMifPwr=isOn;
}
bool indat_isMifareOn()
{
return SharedMem::read()->indat_saveMifPwr;
}
//static bool indat_MdbIsOn;
void indat_storeMDBisOn(bool isOn)
{
SharedMem::write()->indat_MdbIsOn=isOn;
}
bool indat_isMdbOn()
{
return SharedMem::read()->indat_MdbIsOn;
}
//QString indat_HWversion;
//QString indat_SWversion;
//QString indat_DCstate;
// im shared memory ist kein QString erlaubt!!!!!!!!!!!!!!!!!!!!!!
// nur standard C Typen!!!!!!
void gpi_storeHWver(QString text)
{
// change Qstring to array of chars, because shared mem allowes no QString!
int nn, LL = text.length();
if (LL >= versionBufferLen)
LL=versionBufferLen-1; // leave place for termination
for (nn=0; nn<LL; nn++)
{
SharedMem::write()->indat_HWversion[nn] = text.at(nn).toLatin1();
}
for (nn=LL; nn<versionBufferLen; nn++)
SharedMem::write()->indat_HWversion[nn] =0;
}
QString epi_loadHWver(void)
{
// load array of chars from SM and change to QString
int nn, LL = versionBufferLen;
char cc;
QString myStr;
myStr.clear();
for (nn=0; nn<LL; nn++)
{
cc = SharedMem::read()->indat_HWversion[nn];
myStr.append(cc);
}
return myStr;
}
void gpi_storeSWver(QString text)
{
int nn, LL = text.length();
if (LL >= versionBufferLen)
LL=versionBufferLen-1; // leave place for termination
for (nn=0; nn<LL; nn++)
{
SharedMem::write()->indat_SWversion[nn] = text.at(nn).toLatin1();
}
for (nn=LL; nn<versionBufferLen; nn++)
SharedMem::write()->indat_SWversion[nn] =0;
}
QString epi_loadSWver(void)
{
int nn, LL = versionBufferLen;
char cc;
QString myStr;
myStr.clear();
for (nn=0; nn<LL; nn++)
{
cc = SharedMem::read()->indat_SWversion[nn];
myStr.append(cc);
}
return myStr;
}
void gpi_storeDCstate(QString text)
{
//text.chop(8); // DC2 State is shorter (8byte)
//SharedMem::write()->indat_DCstate=text;
int nn, LL = text.length();
if (LL >= versionBufferLen)
LL=versionBufferLen-1; // leave place for termination
for (nn=0; nn<LL; nn++)
{
SharedMem::write()->indat_DCstate[nn] = text.at(nn).toLatin1();
}
for (nn=LL; nn<versionBufferLen; nn++)
SharedMem::write()->indat_DCstate[nn] =0;
}
QString epi_loadDCstate(void)
{
int nn, LL = versionBufferLen;
char cc;
QString myStr;
myStr.clear();
for (nn=0; nn<LL; nn++)
{
cc = SharedMem::read()->indat_DCstate[nn];
myStr.append(cc);
}
return myStr;
}
// -------------------------------
/*
static uint64_t Sdata_slaveUID;
static uint8_t Sdata_UIDstr[8];
static QString Sdata_DcUidStr;
void write2file_UID(void)
{
QByteArray myBA;
csv_startCreatingFile();
csv_addUintToFile(Sdata_UIDstr[0]);
csv_addUintToFile(Sdata_UIDstr[1]);
csv_addUintToFile(Sdata_UIDstr[2]);
csv_addUintToFile(Sdata_UIDstr[3]);
csv_addUintToFile(Sdata_UIDstr[4]);
csv_addUintToFile(Sdata_UIDstr[5]);
csv_addUintToFile(Sdata_UIDstr[6]);
csv_addUintToFile(Sdata_UIDstr[7]);
csv_addNewlineToFile();
csv_addUlongvalToFile(Sdata_slaveUID);
csv_addNewlineToFile();
csv_addTextToFile(Sdata_DcUidStr);
csv_addNewlineToFile();
myBA=csv_readbackArray();
datei_clearFile(FILENAME_SHARED_UID);
datei_writeToFile(FILENAME_SHARED_UID, myBA);
}
void gpi_storeUID(uint8_t *buf8byteUid)
{
uint64_t udltmp=0;
QString myStr;
//qDebug()<< "store UID ";
for (int ii=0; ii<8; ii++)
{
//qDebug()<< buf8byteUid[ii] << " ";
Sdata_UIDstr[ii]=buf8byteUid[ii];
udltmp|=buf8byteUid[ii];
udltmp<<=8;
}
Sdata_slaveUID=udltmp;
Sdata_DcUidStr.clear();
for (int ii=0;ii<8; ii++)
{
Sdata_DcUidStr+=QString::number(Sdata_UIDstr[ii],16);
Sdata_DcUidStr+=" ";
}
write2file_UID();
}
void epi_getUIDdec(uint8_t *buf8byteUid)
{
//qDebug()<< "get UID ";
for (int ii=0; ii<8; ii++)
{
//qDebug()<<Sdata_UIDstr[ii] << " ";
buf8byteUid[ii]=Sdata_UIDstr[ii];
}
}
QString epi_getUIDstr()
{
// die UID besteht aus 8 bytes (8 dezimalzahlen)
// -> umformen in hexstring
QString myStr;
for (int ii=0;ii<8; ii++)
{
myStr+=QString::number(Sdata_UIDstr[ii],16);
myStr+=" ";
}
return myStr;
}
*/
/* read from file:
void epi_getUIDfromFile(uint8_t *buf8byteUid)
{
QByteArray myBA;
int nn;
myBA=datei_readFromFile(FILENAME_SHARED_UID);
for (nn=0; nn<8; nn++)
buf8byteUid[nn]=csv_getEntryAsUshort(myBA, nn);
}
uint64_t epi_getUIDnumberFromFile(void)
{
QByteArray myBA;
myBA=datei_readFromFile(FILENAME_SHARED_UID);
return csv_getEntryAs2Ulong(myBA, 8);
}
QString epi_getUIDstrFromFile(void)
{
QByteArray myBA;
myBA=datei_readFromFile(FILENAME_SHARED_UID);
return csv_getEntryAsString(myBA, 9);
}
*/
// the same with shared memory :
void gpi_storeUID(uint8_t const *buf8byteUid)
{
uint64_t udltmp=0;
for (int ii=0; ii<8; ii++)
{
// SharedMem::getData()->Sdata.UIDstr[ii] = buf8byteUid[ii];
SharedMem::write()->Sdata.UIDstr[ii] = buf8byteUid[ii];
udltmp |= buf8byteUid[ii];
udltmp <<= 8;
}
// SharedMem::getData()->Sdata.slaveUID = udltmp;
SharedMem::write()->Sdata.slaveUID = udltmp;
}
void epi_getUIDdec(uint8_t *buf8byteUid)
{
for (int ii=0; ii<8; ii++)
{
//buf8byteUid[ii] = SharedMem::getDataConst()->Sdata.UIDstr[ii];
buf8byteUid[ii] = SharedMem::read()->Sdata.UIDstr[ii];
}
}
QString epi_getUIDstr()
{
// die UID besteht aus 8 bytes (8 dezimalzahlen)
// -> umformen in hexstring
QString myStr;
for (int ii=0;ii<8; ii++)
{
//myStr += QString::number(SharedMem::getDataConst()->Sdata.UIDstr[ii], 16);
myStr += QString::number(SharedMem::read()->Sdata.UIDstr[ii], 16);
myStr += " ";
}
return myStr;
}
// ///////////////////////////////////////////////////////////////////////////////////
// Time and Date
// ///////////////////////////////////////////////////////////////////////////////////
/*
struct T_globTime
{
// Reihenfolge nicht vertauschen!!!!!
uint8_t hour;
uint8_t minute;
uint8_t second;
uint8_t Year;
uint8_t Month;
uint8_t DayOfMonth;
uint8_t DayOfWeek; // 1=monday...7
uint8_t reserve1;
uint16_t MinutesOfToday;
uint16_t reserve2;
uint32_t SecondsOfToday;
uint8_t IsLeapyear;
uint8_t nextLeap;
uint8_t lastLeap;
uint8_t hoursOfWeek;
uint16_t minOfWeek;
uint16_t hoursOfMonth;
uint16_t minOfMonth;
uint16_t dayOfYear;
uint16_t hoursOfYear;
uint16_t reserve3;
uint32_t minOfYear;
uint8_t squareOutMode;
uint8_t free1;
uint16_t reserve4;
uint32_t minOfMillenium;
// bis hierher 44byts
uint32_t free2;
uint32_t free3;
uint32_t free4;
};
static T_globTime getGlobalTime;
*/
void gpi_backupSquareMode(uint8_t squMode)
{
SharedMem::write()->getGlobalTime.squareOutMode=squMode;
}
uint8_t epi_getSquareMode()
{
return SharedMem::read()->getGlobalTime.squareOutMode;
}
void gpi_backupTime(uint8_t *timeBuffer, uint8_t Leng)
{
/*
// Daten kommen in gleicher Reihenfolge vom Slave
uint8_t *pTime;
pTime=&getGlobalTime.hour;
if (Leng>44) Leng=44; // mehr brauch ma ned
for (int nn=0; nn<Leng; nn++)
{
*pTime++=timeBuffer[nn];
}*/
// new, FastProt: 0=dayOfWeek 1=min 2=sec 3=hours 4=year 5=month 6=dayOfMonth
SharedMem::write()->getGlobalTime.second=Leng; // nur damit CompilerWarnung weg ist
SharedMem::write()->getGlobalTime.DayOfWeek=timeBuffer[0];
SharedMem::write()->getGlobalTime.minute=timeBuffer[1];
SharedMem::write()->getGlobalTime.second=timeBuffer[2];
SharedMem::write()->getGlobalTime.hour=timeBuffer[3];
SharedMem::write()->getGlobalTime.Year=timeBuffer[4];
SharedMem::write()->getGlobalTime.Month=timeBuffer[5];
SharedMem::write()->getGlobalTime.DayOfMonth=timeBuffer[6];
}
void epi_getTime(uint8_t *hh, uint8_t *mm, uint8_t *ss)
{
*hh=SharedMem::read()->getGlobalTime.hour;
*mm=SharedMem::read()->getGlobalTime.minute;
*ss=SharedMem::read()->getGlobalTime.second;
}
void epi_getDate(uint8_t *yy, uint8_t *mm, uint8_t *dd)
{
*yy=SharedMem::read()->getGlobalTime.Year;
*mm=SharedMem::read()->getGlobalTime.Month;
*dd=SharedMem::read()->getGlobalTime.DayOfMonth;
}
void epi_getToday(uint8_t *dow, uint16_t *minOfToday, uint32_t *secOfToday)
{
*dow=SharedMem::read()->getGlobalTime.DayOfWeek;
*minOfToday=SharedMem::read()->getGlobalTime.MinutesOfToday;
*secOfToday=SharedMem::read()->getGlobalTime.SecondsOfToday;
}
bool epi_isLeapYear(uint8_t *lastLeapYear, uint8_t *NextLeapYear)
{
*lastLeapYear=SharedMem::read()->getGlobalTime.lastLeap;
*NextLeapYear=SharedMem::read()->getGlobalTime.nextLeap;
if (SharedMem::read()->getGlobalTime.IsLeapyear)
return true;
return false;
}
bool epi_isLeapYear()
{
if (SharedMem::read()->getGlobalTime.IsLeapyear)
return true;
return false;
}
void epi_getSpecialWeekTimeDate(uint8_t *DayOfWeek, uint8_t *HoursOfWeek, uint16_t *MinutesOfWeek)
{
*DayOfWeek=SharedMem::read()->getGlobalTime.DayOfWeek;
*HoursOfWeek=SharedMem::read()->getGlobalTime.hoursOfWeek;
*MinutesOfWeek=SharedMem::read()->getGlobalTime.minOfWeek;
}
void epi_getSpecialMonthTimeDate(uint8_t *DayOfMonth, uint16_t *HoursOfMonth, uint16_t *MinutesOfMonth)
{
*DayOfMonth=SharedMem::read()->getGlobalTime.DayOfMonth;
*HoursOfMonth=SharedMem::read()->getGlobalTime.hoursOfMonth;
*MinutesOfMonth=SharedMem::read()->getGlobalTime.minOfMonth;
}
void epi_getSpecialYearTimeDate(uint16_t *DayOfYear, uint16_t *HoursOfYear, uint32_t *MinutesOfYear)
{
*DayOfYear=SharedMem::read()->getGlobalTime.dayOfYear;
*HoursOfYear=SharedMem::read()->getGlobalTime.hoursOfYear;
*MinutesOfYear=SharedMem::read()->getGlobalTime.minOfYear;
}
QString epi_getRtcTimeStr(uint8_t timeStyle)
{
// style: 0: hh:mm 1: hh:mm:ss
QString mystr=nullptr, tempStr=nullptr;
tempStr.setNum(SharedMem::read()->getGlobalTime.hour,10);
mystr=tempStr.rightJustified(2,'0',false); // macht feste Länge, 5->05
mystr.append(':');
//tempStr.clear();
tempStr.setNum(SharedMem::read()->getGlobalTime.minute,10); // mit 16 statt 10 wirds in HEX angezeigt
//mystr.append(tempStr);
mystr+=tempStr.rightJustified(2,'0',false);
//mystr.append(':'); // so
//mystr+=':'; // oder so, =gleich
if (timeStyle==1) // hh:mm:ss
{
mystr.append(':');
tempStr.setNum(SharedMem::read()->getGlobalTime.second,10);
mystr.append(tempStr.rightJustified(2,'0',false)); // wie +=
}
return mystr;
}
QString epi_getRtcDateStr(uint8_t dateStyle)
{
// 1=german dd.mm.yy 2=american yy/mm/dd 3=mm.dd.yy
QString tmpStr=nullptr, YYstr=nullptr, MMstr=nullptr, DDstr=nullptr, mystr=nullptr;
mystr.clear();
tmpStr.setNum(SharedMem::read()->getGlobalTime.Year,10); // itoa decimal
YYstr=tmpStr.rightJustified(4,'0',false); // immer vierstellig
YYstr[0]='2'; // 2000 dazu
tmpStr.setNum(SharedMem::read()->getGlobalTime.Month,10);
MMstr=tmpStr.rightJustified(2,'0',false);
tmpStr.setNum(SharedMem::read()->getGlobalTime.DayOfMonth,10);
DDstr=tmpStr.rightJustified(2,'0',false);
if (dateStyle==1) // Germany dd.mm.yy
{
mystr=DDstr + '.' + MMstr + '.' + YYstr;
} else
if (dateStyle==2) // american yy/mm/dd
{
mystr=YYstr + '/' + MMstr + '/' + DDstr;
} else
// mm.dd.yy
{
mystr=MMstr + '.' + DDstr + '.' + YYstr;
}
return mystr;
}
QString epi_getSlaveTimeDateStr()
{
QString myStr;
myStr=epi_getRtcTimeStr(1) + " " + epi_getRtcDateStr(1);
return myStr;
}
// ///////////////////////////////////////////////////////////////////////////////////
// analog values
// ///////////////////////////////////////////////////////////////////////////////////
//static uint16_t AI_val[MAXNROF_AI];
uint8_t gpi_getMaxNrAIs()
{
return MAXNROF_AI;
}
void gpi_storeAIs(uint8_t aiNr, uint16_t val)
{
if (aiNr<MAXNROF_AI)
SharedMem::write()->AI_val[aiNr]=val;
}
uint16_t epi_loadAIs(uint8_t aiNr)
{
if (aiNr<MAXNROF_AI)
return SharedMem::read()->AI_val[aiNr];
return 0;
}
//--------------
// measurement values
// ADC0: temp
// 1: voltage
// 2: brightness
#define MAXNROF_MEASURE 4
//static uint32_t Sdata_measurement[MAXNROF_MEASURE];
uint32_t epi_loadMeasureValue(uint8_t ValueNr)
{
// ValueNr 0=ADC0, 1=ADC1 aso...
if (ValueNr<MAXNROF_MEASURE)
return SharedMem::read()->Sdata_measurement[ValueNr];
return 0;
}
void gpi_storeMeasureValue(uint8_t ValueNr, uint32_t val)
{
// in mV, also bis 65,535V
if (ValueNr<MAXNROF_MEASURE)
SharedMem::write()->Sdata_measurement[ValueNr]=val;
}
QString epi_getSlaveTemperatureStr()
{
char myStr[8], halfDegree=0, Minus=0, oneChar;
int16_t val=0, pp, einer, zehner;
QString myqStr;
//qDebug() << "AIN0: " << epi_loadAIs(0) << "AIN1: " << epi_loadAIs(1);
uint32_t meas_temper=epi_loadMeasureValue(MEASCHAN_TEMPERATURE);
// im SaxFormat gespeichert, hier umwandeln in String
//qDebug() << "meas_temper: " << meas_temper;
for (pp=0; pp<8; pp++) myStr[pp]=0;
if (meas_temper&1) // ungerade, also ,5°C
{
halfDegree=1;
meas_temper &=0xFFFE; // um 0,5°C abrunden
}
if (meas_temper<100)
{
Minus=1;
val=int16_t(meas_temper)/2;
val-=50;
} else
{
val=int16_t(meas_temper)-100;
val/=2;
}
pp=0; // pointer auf string
if (Minus)
myStr[pp++]='-';
// val is now 0..150 for pos Temp or 0..49 for negativ temperature
if (val<10)
{
// only one digit, just change to ascii
oneChar = char(val)+0x30;
if (tslib_isDecAsciiNumber(oneChar))
myStr[pp++]=oneChar;
else
myStr[pp++]='0';
} else
if (val<100)
{
// 10...99
einer=val%10;
zehner=val/10;
//myStr[pp++]=char(zehner);
//myStr[pp++]=char(einer);
oneChar = char(zehner)+0x30;
if (tslib_isDecAsciiNumber(oneChar))
myStr[pp++]=oneChar;
else
myStr[pp++]='0';
oneChar = char(einer)+0x30;
if (tslib_isDecAsciiNumber(oneChar))
myStr[pp++]=oneChar;
else
myStr[pp++]='0';
} else
{
// 100...150
myStr[pp++]='1'; // hunderter Stelle immer 1
val-=100;
einer=val%10;
zehner=val/10;
//myStr[pp++]=char(zehner)+0x30;
//myStr[pp++]=char(einer)+0x30;
oneChar = char(zehner)+0x30;
if (tslib_isDecAsciiNumber(oneChar))
myStr[pp++]=oneChar;
else
myStr[pp++]='0';
oneChar = char(einer)+0x30;
if (tslib_isDecAsciiNumber(oneChar))
myStr[pp++]=oneChar;
else
myStr[pp++]='0';
}
myStr[pp++]=',';
if (halfDegree)
myStr[pp++]='5';
else
myStr[pp++]='0';
myqStr.clear();
myqStr.append(myStr);
myqStr.append("°C");
return myqStr;
}
QString epi_getSlaveVoltageStr()
{
// value in "meas_volt" in mV, also bis 65,535V. Value range [6000...16000] (6V...16V)
QString myqStr;
uint32_t vor, nach, tmp32;
uint16_t pp;
char myStr[12], ke; //, kz, kh;
uint32_t ultmp=epi_loadMeasureValue(MEASCHAN_VOLTAGE);
for (pp=0; pp<12; pp++) myStr[pp]=0;
//qDebug() << ultmp << "mV";
myqStr.clear();
vor=ultmp/1000;
//qDebug() << "vor: " << vor;
nach=ultmp%1000;
//qDebug() << "nach: " << nach;
pp=0;
if (vor>9)
{
myStr[pp++]=char(vor/10)+0x30;
}
myStr[pp++]=char(vor%10)+0x30;
myStr[pp++]=',';
ke=char(nach/100);
//qDebug() << "ke: " << ke;
myStr[pp++]=char(ke)+0x30;
tmp32=nach%100;
ke=char(tmp32/10);
//qDebug() << "ke: " << ke;
myStr[pp++]=char(ke)+0x30;
tmp32=nach%10;
ke=char(tmp32);
//qDebug() << "ke: " << ke;
myStr[pp++]=char(ke)+0x30;
myStr[pp++]='V';
myqStr.append(myStr);
return myqStr;
}
// ///////////////////////////////////////////////////////////////////////////////////
// digital inputs
// ///////////////////////////////////////////////////////////////////////////////////
/* come all in with 0x1201:
D0: upper door D1: low door D2:vault door
D3: cash box D4: bill box in
D5: bit 0: upper lockbar up bit1:down
D6: bit 0: lower lockbar up bit1:down
D7: 0
D7: DI_contact Power Is On
D8: OptoIn 1,2
D9: Aux0...5
D10:Wake from ptu
D11: DI Wake From Mdb
D12: Ready from printer
D13: Coin Shutter Input
D14: CoinEscrow switch
D15: Mifare IN
D16: Modem_Wake In
D18: DI Mif Pwr is on
D19: DI MDB_TxD_rdBack
D20: DI Aux Pwr is on
D21: DI GSM Pwr from PO2 is ON
D22: DI Credit Pwr from PO2 is on
=DI RdBack Credit Wake
D23: DI Printer Pwr from PO2 is on
D24: DI MDB Pwr from PO2 is on
*/
//static uint8_t di_doorSwitch;
void gpi_storeDI_doorSwitches(uint8_t upperDoor, uint8_t lowerDoor, uint8_t vaultDoor)
{
SharedMem::write()->di_doorSwitch=0;
if (upperDoor) SharedMem::write()->di_doorSwitch |=1;
if (lowerDoor) SharedMem::write()->di_doorSwitch |=2;
if (vaultDoor) SharedMem::write()->di_doorSwitch |=4;
// qDebug()<<"storeINdata: "<<upperDoor << lowerDoor << vaultDoor;
// qDebug()<<"storeINdata: "<<di_doorSwitch;
}
uint8_t epi_getDI_doorSwitches(void)
{
// bit0: upper door 1: low door 2:vault door
return SharedMem::read()->di_doorSwitch;
}
//static uint8_t di_vaultSwitch;
void gpi_storeDI_vaultSwitches(uint8_t CashBoxIn, uint8_t BillBoxIn)
{
SharedMem::write()->di_vaultSwitch=0;
if (CashBoxIn) SharedMem::write()->di_vaultSwitch |=1;
if (BillBoxIn) SharedMem::write()->di_vaultSwitch |=2;
}
uint8_t epi_getDI_vaultSwitches(void)
{
// bit0: cash box 1: bill box in
return SharedMem::read()->di_vaultSwitch;
}
//static uint8_t di_lockSwitch;
void gpi_storeDI_lockSwitches(uint8_t indatUL, uint8_t indatLL)
{
// D5: bit 0: upper lockbar up bit1:down
// D6: bit 0: lower lockbar up bit1:down
SharedMem::write()->di_lockSwitch=0;
if (indatUL & 1) SharedMem::write()->di_lockSwitch |=1;
if (indatUL & 2) SharedMem::write()->di_lockSwitch |=2;
if (indatLL & 1) SharedMem::write()->di_lockSwitch |=4;
if (indatLL & 2) SharedMem::write()->di_lockSwitch |=8;
}
uint8_t epi_getDI_lockSwitches(void)
{
// retval: bit 0: upper lockbar up bit1: upper lockbar is down
// bit 2: lower lockbar up bit1: lower lockbar is down
return SharedMem::read()->di_lockSwitch;
}
//static uint8_t di_opto;
void gpi_storeDI_optos(uint8_t indatOpto)
{
// OptoIn bit 0,1: optoin 1,2
SharedMem::write()->di_opto=0;
if (indatOpto & 1) SharedMem::write()->di_opto |=1;
if (indatOpto & 2) SharedMem::write()->di_opto |=2;
}
uint8_t epi_getDI_optos(void)
{
// bit0: opto in 1 1: opto in 2
return SharedMem::read()->di_opto;
}
//static uint8_t di_aux;
void gpi_storeDI_auxIn(uint8_t indatAuxIn)
{
// Aux0...5
SharedMem::write()->di_aux=indatAuxIn;
}
uint8_t epi_getDI_auxIn(void)
{
// bit0: auxin 1 ... 5: auxin 6
return SharedMem::read()->di_aux;
}
//static bool di_wakeFromPtu;
void gpi_storeDI_ptuWake(uint8_t indat)
{
if (indat)
SharedMem::write()->di_wakeFromPtu=true;
else
SharedMem::write()->di_wakeFromPtu=false;
}
bool epi_getDI_ptuWake(void)
{
return SharedMem::read()->di_wakeFromPtu;
}
//static bool di_wakeFromMdb;
void gpi_storeDI_mbdWake(uint8_t indat)
{
if (indat)
SharedMem::write()->di_wakeFromMdb=true;
else
SharedMem::write()->di_wakeFromMdb=false;
}
bool epi_getDI_mdbWake(void)
{
return SharedMem::read()->di_wakeFromMdb;
}
//static bool di_PrnReady;
void gpi_storeDI_prnReady(uint8_t indat)
{
if (indat)
SharedMem::write()->di_PrnReady=true;
else
SharedMem::write()->di_PrnReady=false;
}
bool epi_getDI_prnReady(void)
{
return SharedMem::read()->di_PrnReady;
}
//static bool di_CoinAttach;
void gpi_storeDI_CoinAttach(uint8_t indat)
{
if (indat)
SharedMem::write()->di_CoinAttach=true;
else
SharedMem::write()->di_CoinAttach=false;
}
bool epi_getDI_CoinAttach(void)
{
return SharedMem::read()->di_CoinAttach;
}
//static bool di_CoinEscrowOpen;
void gpi_storeDI_CoinEscrow(uint8_t indat)
{
if (indat)
SharedMem::write()->di_CoinEscrowOpen=true;
else
SharedMem::write()->di_CoinEscrowOpen=false;
}
bool epi_getDI_CoinEscrow(void)
{
return SharedMem::read()->di_CoinEscrowOpen;
}
//static bool di_mifCardTap;
void gpi_storeDI_mifareCardTapped(uint8_t indat)
{
if (indat)
SharedMem::write()->di_mifCardTap=true;
else
SharedMem::write()->di_mifCardTap=false;
}
bool epi_getDI_mifareCardTapped(void)
{
return SharedMem::read()->di_mifCardTap;
}
//static bool di_wakeFromModem;
void gpi_storeDI_modemWake(uint8_t indat)
{
if (indat)
SharedMem::write()->di_wakeFromModem=true;
else
SharedMem::write()->di_wakeFromModem=false;
}
bool epi_getDI_modemWake(void)
{
return SharedMem::read()->di_wakeFromModem;
}
//static bool di_contactPwrOn;
void gpi_storeDI_contactPowerIsOn(bool di_contact_PwrOn)
{
SharedMem::write()->di_contactPwrOn=di_contact_PwrOn;
}
bool epi_getDI_contactPwr(void)
{
// invertiert!
if (SharedMem::read()->di_contactPwrOn)
return false;
return true;
}
//static bool di_mifarePwrOn;
void gpi_storeDI_MifarePowerIsOn(bool di_mifare_PwrOn)
{
SharedMem::write()->di_mifarePwrOn=di_mifare_PwrOn;
}
bool epi_getDI_mifarePwr(void)
{
return SharedMem::read()->di_mifarePwrOn;
}
//static bool di_rdbk_mdbTxd;
void gpi_storeDI_readbackMdbTxD(bool di_rdbkMdbTxd)
{
SharedMem::write()->di_rdbk_mdbTxd=di_rdbkMdbTxd;
}
bool epi_getDI_mdbTxd(void)
{
return SharedMem::read()->di_rdbk_mdbTxd;
}
//static bool di_AuxPwrOn;
void gpi_storeDI_AuxPowerIsOn(bool di_Aux_PwrOn)
{
SharedMem::write()->di_AuxPwrOn=di_Aux_PwrOn;
}
bool epi_getDI_auxPwr(void)
{
return SharedMem::read()->di_AuxPwrOn;
}
//static bool di_gsmPwrOn;
void gpi_storeDI_GsmPowerIsOn(bool di_gsm_PwrOn)
{
SharedMem::write()->di_gsmPwrOn=di_gsm_PwrOn;
}
bool epi_getDI_gsmPwr(void)
{
return SharedMem::read()->di_gsmPwrOn;
}
//static bool di_creditPwrOn;
void gpi_storeDI_CreditPowerIsOn(bool di_credit_PwrOn)
{
// invertieren!!!
if (di_credit_PwrOn)
SharedMem::write()->di_creditPwrOn=0;
else
SharedMem::write()->di_creditPwrOn=1;
}
bool epi_getDI_creditPwr(void)
{
return SharedMem::read()->di_creditPwrOn;
}
//static bool di_printerPwrOn;
void gpi_storeDI_PrinterPowerIsOn(bool di_printer_PwrOn)
{
SharedMem::write()->di_printerPwrOn=di_printer_PwrOn;
}
bool epi_getDI_printerPwr(void)
{
return SharedMem::read()->di_printerPwrOn;
}
//static bool di_mdbPwrOn;
void gpi_storeDI_MdbPowerIsOn(bool di_mdb_PwrOn)
{
SharedMem::write()->di_mdbPwrOn=di_mdb_PwrOn;
}
bool epi_getDI_mdbPwr(void)
{
return SharedMem::read()->di_mdbPwrOn;
}
//static bool di_rejMot_home;
void gpi_storeDI_rejMot_home(bool di)
{
SharedMem::write()->di_rejMot_home=di;
}
bool epi_getDI_rejectMotor_homepos(void)
{
return SharedMem::read()->di_rejMot_home;
}
//static uint8_t di_npe_sensor;
void gpi_storeDI_paperLow(uint8_t di)
{
// 0: Sensor sees paper 1: no paper 99: off
SharedMem::write()->di_npe_sensor=di;
}
uint8_t epi_getDI_npe_sensor(void)
{
return SharedMem::read()->di_npe_sensor;
}
// ///////////////////////////////////////////////////////////////////////////////////
// readaback digital outputs
// ///////////////////////////////////////////////////////////////////////////////////
/*
D0 bit0: MDB devices 0=off 1=on
bit1: MDB bus power
bit2: MDB WakeOut
D1=Printer
D2=Credit
D3=Modem
D5: serial drv on/off, Serial mux1, Serial mux2
D6: Leds, Fan,
D7: Siren and relay
D8: PtuWakeOut
D9: Power Aux/Barcode
D10: AuxDir 1...6
D11: AuxOut 1...6
D12: Coin shutter output
D13: CoinEscrow Outputs
*/
//static uint8_t do_mbdRxTst;
void gpi_storeDO_mdbRxTst(uint8_t mdbRxTst)
{
SharedMem::write()->do_mbdRxTst=mdbRxTst;
}
bool epi_getDO_mdbRxTestOut(void)
{
if (SharedMem::read()->do_mbdRxTst & 1)
return true;
return false;
}
//static uint8_t do_motorBits;
void gpi_storeDO_motorOutputs(uint8_t Pwr)
{
//D1: motor outputs bit0: upper lock forw bit 1 backw
// Bit2: lowLock forw bit3: LL backw
SharedMem::write()->do_motorBits=Pwr;
}
uint8_t epi_getDO_motorOuts(void)
{
// bit0: upper lock forward bit 1 backward
// bit2: lower lock forward bit 3 backward
return SharedMem::read()->do_motorBits;
}
//static uint8_t do_serialSwitch; // serial drv on/off, Serial mux1, Serial mux2
void gpi_storeDO_serialSwitch(uint8_t state) // serial drv on/off, Serial mux1, Serial mux2
{
SharedMem::write()->do_serialSwitch=state;
}
uint8_t epi_getDO_serialSwitch(void)
{
// serial drv on/off, Serial mux1, Serial mux2
return SharedMem::read()->do_serialSwitch;
}
bool epi_getDO_serialDriverIsOn(void)
{
if ( SharedMem::read()->do_serialSwitch & 1)
return true;
return false;
}
bool epi_getDO_serialMux1isSetToPrinter(void)
{
// mux1 off: serial is switched to printer
if ((SharedMem::read()->do_serialSwitch & 2)==0)
return true;
return false;
}
bool epi_getDO_serialMux1isSetToModem(void)
{
// mux1 on: serial is switched to modem
if ((SharedMem::read()->do_serialSwitch & 2)>0)
return true;
return false;
}
bool epi_getDO_serialMux2isSetToCredit(void)
{
// mux2 off: serial is switched to credit card terminal
if ((SharedMem::read()->do_serialSwitch & 4)==0)
return true;
return false;
}
bool epi_getDO_serialMux2isSetToMifare(void)
{
// mux2 on: serial is switched to mifare reader
if ((SharedMem::read()->do_serialSwitch & 4)>0)
return true;
return false;
}
//static uint8_t do_ledsAndFan;
void gpi_storeDO_ledsAndFan(uint8_t ledState)
{
// bit0: coinled 1:front_illu 2: paper-led 3:pinpad-led 4:start-led 5:service-led 6:fan
SharedMem::write()->do_ledsAndFan=ledState;
}
bool epi_getDO_led_coin(void)
{
if (SharedMem::read()->do_ledsAndFan & 1)
return true;
return false;
}
bool epi_getDO_led_front(void)
{
if (SharedMem::read()->do_ledsAndFan & 2)
return true;
return false;
}
bool epi_getDO_led_ticket(void)
{
if (SharedMem::read()->do_ledsAndFan & 4)
return true;
return false;
}
bool epi_getDO_led_pin(void)
{
if (SharedMem::read()->do_ledsAndFan & 8)
return true;
return false;
}
bool epi_getDO_led_start(void)
{
if (SharedMem::read()->do_ledsAndFan & 16)
return true;
return false;
}
bool epi_getDO_led_inside(void)
{
if (SharedMem::read()->do_ledsAndFan & 32)
return true;
return false;
}
bool epi_getDO_fan(void)
{
if (SharedMem::read()->do_ledsAndFan & 64)
return true;
return false;
}
//static uint8_t do_laermUndRelay;
void gpi_storeDO_sirenAndRelay(uint8_t sirenRelay)
{
// bit0: siren 1:relay
SharedMem::write()->do_laermUndRelay=sirenRelay;
}
bool epi_getDO_sirene(void)
{
if (SharedMem::read()->do_laermUndRelay & 1)
return true;
return false;
}
bool epi_getDO_relay(void)
{
if (SharedMem::read()->do_laermUndRelay & 2)
return true;
return false;
}
//static uint8_t do_ptuWake;
void gpi_storeDO_ptuWake(uint8_t state)
{
SharedMem::write()->do_ptuWake=state;
}
bool epi_getDO_ptuWake(void)
{
if (SharedMem::read()->do_ptuWake>0)
return true;
return false;
}
//static uint8_t do_auxPower;
void gpi_storeDO_auxPower(uint8_t pwr)
{
SharedMem::write()->do_auxPower=pwr;
}
bool epi_getDO_auxPower(void)
{
if (SharedMem::read()->do_auxPower>0)
return true;
return false;
}
//static uint8_t do_coinShutter;
void gpi_storeDO_coinShutter(uint8_t state)
{
SharedMem::write()->do_coinShutter=state;
}
bool epi_getDO_coinShutterOpen(void)
{
// bit0: Coin shutter output, bit1: input-test-output
if (SharedMem::read()->do_coinShutter & 1)
return true;
return false;
}
bool epi_getDO_coinShutterTest(void)
{
// bit0: Coin shutter output, bit1: input-test-output
if (SharedMem::read()->do_coinShutter & 2)
return true;
return false;
}
//static uint8_t do_coinEscrow;
void gpi_storeDO_coinEscrow(uint8_t state)
{
SharedMem::write()->do_coinEscrow=state;
}
uint8_t epi_getDO_coinEscrow(void)
{
// retval: 1:return flap is open 2:take flap is open 0:closed
if (SharedMem::read()->do_coinEscrow &1)
return 1; // return flap is open
if (SharedMem::read()->do_coinEscrow &2)
return 2; // take flap is open
return 0;
}
//static uint8_t do_printerPower;
void gpi_storeDO_printerPwrOn(uint8_t state)
{
SharedMem::write()->do_printerPower=state;
}
uint8_t epi_getDO_printerPwr(void)
{
return SharedMem::read()->do_printerPower;
}
//------------------------------------------------------------------------------------
//------------------------------------------------------------------------------------
//----------------------------- Mifare Card Reader -----------------------------------
//#define NROFMIFSTATEBYTES 40
//static uint8_t Sdata_MIF_STATE[NROFMIFSTATEBYTES];
void gpi_clearMifHwData(void)
{
for (uint8_t nn=0; nn<64; nn++)
SharedMem::write()->Sdata_MIF_DATA[nn]=0;
}
void gpi_storeMifHwData(uint8_t *receivedData)
{
for (uint8_t nn=0; nn<64; nn++)
SharedMem::write()->Sdata_MIF_DATA[nn]=receivedData[nn];
}
uint8_t epi_restoreMifHwData(uint8_t *buf, uint8_t maxBufferSize)
{
if (maxBufferSize<64)
return 1; // error
for (uint8_t nn=0; nn<64; nn++)
buf[nn]=SharedMem::read()->Sdata_MIF_DATA[nn];
return 0; // ois OK
}
void gpi_clearMifAtbData(void)
{
for (uint8_t nn=0; nn<64; nn++)
SharedMem::write()->Sdata_MIF_ATB[nn]=0;
}
void gpi_storeMifAtbData(uint8_t *receivedData)
{
for (uint8_t nn=0; nn<64; nn++)
SharedMem::write()->Sdata_MIF_ATB[nn]=receivedData[nn];
}
uint8_t epi_restoreMifAtbData( uint8_t *buf, uint8_t maxBufferSize)
{
if ( maxBufferSize<64)
return 1; // error
for (uint8_t nn=0; nn<64; nn++)
buf[nn]=SharedMem::read()->Sdata_MIF_ATB[nn];
return 0; // ois OK
}
// not used
//void gpi_storeNewMifareCard(uint8_t typ, uint8_t *holder )
//{
// SharedMem::write()->mif_cardType=typ;
// uint8_t nn;
// //tslib_strcpy(holder, SharedMem::write()->mif_cardHolder, 7);
// for (nn=0; nn<7; nn++)
// SharedMem::write()->mif_cardHolder[nn] = holder[nn];
// SharedMem::write()->mif_cardHolder[7]=0;
//}
// not used
//uint8_t epi_mifGetCardType(uint8_t *holder)
//{
//holder[8] = name of card holder
// retval Type of MifareCard, 1=upper door, 2=lower door 3=test printer 4=test coins
//tslib_strcpy(SharedMem::read()->mif_cardHolder, holder, 7);
// uint8_t nn;
// for (nn=0; nn<7; nn++)
// holder[nn]= SharedMem::read()->mif_cardHolder[nn];
// holder[7]=0;
// return SharedMem::read()->mif_cardType;
// return 0;
//}
//------------------------------------------------------------------------------------
//------------------------------------------------------------------------------------
//static uint8_t Sdata_PRN_STATE[pi_prnStateArraySize];
void epi_restorePrinterState(uint8_t *buf)
{
uint8_t nn;
for (nn=0; nn<pi_prnStateArraySize; nn++)
buf[nn]=SharedMem::read()->Sdata_PRN_STATE[nn];
}
void gpi_storePrinterState(uint8_t *buf)
{
uint8_t nn;
for (nn=0; nn<pi_prnStateArraySize; nn++)
SharedMem::write()->Sdata_PRN_STATE[nn]=buf[nn];
}
//static uint8_t Sdata_PRN_FONTS[pi_prnFontArraySize];
void epi_restorePrinterFonts(uint8_t *buf)
{
uint8_t nn;
for (nn=0; nn<pi_prnFontArraySize; nn++)
buf[nn]=SharedMem::read()->Sdata_PRN_FONTS[nn];
}
void gpi_storePrinterFonts(uint8_t *buf)
{
uint8_t nn;
for (nn=0; nn<pi_prnFontArraySize; nn++)
SharedMem::write()->Sdata_PRN_FONTS[nn]=buf[nn];
/*
qDebug()<<"printer fonts stored " <<Sdata_PRN_FONTS[0]<<" "<<Sdata_PRN_FONTS[1]<<" " \
<<Sdata_PRN_FONTS[2]<<" "<<Sdata_PRN_FONTS[3]<<" " \
<<Sdata_PRN_FONTS[4]<<" "<<Sdata_PRN_FONTS[5]<<" " \
<<Sdata_PRN_FONTS[6]<<" "<<Sdata_PRN_FONTS[7]<<" " \
<<Sdata_PRN_FONTS[8]<<" "<<Sdata_PRN_FONTS[9]<<" " \
<<Sdata_PRN_FONTS[10]<<" "<<Sdata_PRN_FONTS[11];
*/
}
//static bool Sdata_mdb_busRdy;
//static bool Sdata_mdb_V12on;
//static bool Sdata_mdb_V5on;
// DB0: mdb_bus_ready (switched on)
// DB1: rdBackV12devicePower
// DB2: rdBackV5busPwr
void gpi_storeMdbState(uint8_t busReady, uint8_t V12on, uint8_t V5on )
{
SharedMem::write()->Sdata_mdb_busRdy=bool(busReady);
SharedMem::write()->Sdata_mdb_V12on=bool(V12on);
SharedMem::write()->Sdata_mdb_V5on=bool(V5on);
}
bool epi_restoreMdbBusReady(void)
{
return SharedMem::read()->Sdata_mdb_busRdy;
}
bool epi_restoreMdbV12Ready(void)
{
return SharedMem::read()->Sdata_mdb_V12on;
}
bool epi_restoreMdbV5Ready(void)
{
return SharedMem::read()->Sdata_mdb_V5on;
}
//static uint8_t Sdata_mdbNrOfRecData;
//static uint8_t Sdata_RecBuff[40];
// last received mdb answer (from mdb device)
// only needed if a special command was sent directly
// DB0: mdb Device-Nr
// DB1: last sent mdb command
// DB2: nr of received (payload) data bytes (apart from ACK, can be 0....34)
// DB3...DB38: rec.data (payload)
void gpi_storeMdbResponse(uint8_t leng, uint8_t *data)
{
uint8_t nn;
if (leng>40) leng=40;
tslib_strclr(SharedMem::write()->Sdata_RecBuff,0,40);
SharedMem::write()->Sdata_mdbNrOfRecData=leng;
//tslib_strcpy(data, SharedMem::write()->Sdata_RecBuff, uint16_t(Sdata_mdbNrOfRecData));
for (nn=0; nn<leng; nn++)
SharedMem::write()->Sdata_RecBuff[nn] = data[nn];
}
void epi_restoreMdbResponse(uint8_t *leng, uint8_t *data)
{
uint8_t nn, LL;
LL=SharedMem::read()->Sdata_mdbNrOfRecData;
//tslib_strcpy(SharedMem::read()->Sdata_RecBuff, data, SharedMem::read()->Sdata_mdbNrOfRecData);
for (nn=0; nn<LL; nn++)
data[nn] = SharedMem::read()->Sdata_RecBuff[nn];
*leng = LL;
}
//static uint8_t Sdata_empNrOfsettings;
//static uint8_t Sdata_emp_settingsBuff[66];
void gpi_storeEmpSettings(uint8_t leng, uint8_t *data)
{
uint8_t nn;
if (leng>64) leng=64;
SharedMem::write()->Sdata_empNrOfsettings=leng;
//tslib_strcpy(data, SharedMem::write()->Sdata_emp_settingsBuff, leng);
for (nn=0; nn<leng; nn++)
SharedMem::write()->Sdata_emp_settingsBuff[nn] = data[nn];
}
void epi_restoreEmpSettings(uint8_t *leng, uint8_t *data)
{
uint8_t nn, LL;
LL=SharedMem::read()->Sdata_empNrOfsettings;
*leng=LL;
//tslib_strcpy(SharedMem::read()->Sdata_emp_settingsBuff, data, SharedMem::read()->Sdata_empNrOfsettings);
for (nn=0; nn<LL; nn++)
data[nn] = SharedMem::read()->Sdata_emp_settingsBuff[nn];
}
// ......................................................................
// Münzbuffer[10]: Münze für Münze auslesen (LIFO)
// 4.5.21
/*
struct T_coin
{
uint8_t valid;
uint8_t signal;
uint8_t error;
uint8_t pad;
uint16_t value;
};
static struct T_coin gotCoin[MEMDEPTH_GOTCOINS];
static uint8_t ctr_gotCoin;
*/
void sub_enterData(uint8_t valid, uint8_t signal, uint8_t error, uint16_t value )
{
uint8_t pGotCoin;
pGotCoin=SharedMem::read()->ctr_gotCoin;
if (pGotCoin<MEMDEPTH_GOTCOINS)
{
SharedMem::write()->gotCoin[pGotCoin].valid=valid;
SharedMem::write()->gotCoin[pGotCoin].signal=signal;
SharedMem::write()->gotCoin[pGotCoin].error=error;
SharedMem::write()->gotCoin[pGotCoin].value=value;
}
pGotCoin++;
SharedMem::write()->ctr_gotCoin=pGotCoin;
}
void gpi_storeEmpCoinSignal(uint8_t leng, uint8_t *data)
{
// leng is number of coin record with 5 bytes each
uint8_t LL=leng; // nr of coin records
uint16_t vv, pp=0;
vv=uchar2uint(data[pp+4], data[pp+3]);
sub_enterData(data[pp], data[pp+1], data[pp+2], vv );
pp+=5;
LL--;
}
uint8_t epi_isNewCoinLeft(void)
{
// retval: 0...16 coins left in FIFO
return SharedMem::read()->ctr_gotCoin;
}
void epi_restoreEmpCoinSignal(uint8_t *valid, uint8_t *signal, uint8_t *error, uint16_t *value)
{
uint8_t pGotCoin;
pGotCoin=SharedMem::read()->ctr_gotCoin;
pGotCoin--;
if (pGotCoin<MEMDEPTH_GOTCOINS)
{
*valid=SharedMem::read()->gotCoin[pGotCoin].valid;
*signal=SharedMem::read()->gotCoin[pGotCoin].signal;
*error=SharedMem::read()->gotCoin[pGotCoin].error;
*value=SharedMem::read()->gotCoin[pGotCoin].value;
}
SharedMem::write()->ctr_gotCoin=pGotCoin;
}
//static uint8_t Sdata_NrOfDeviceSetting;
//static uint8_t Sdata_DeviceSettingBuff[66];
void gpi_storeRbDeviceSettings(uint8_t leng, uint8_t *data) // getestet am 12.4.23TS
{
uint8_t nn;
if (leng>64) leng=64;
SharedMem::write()->Sdata_NrOfDeviceSetting=leng;
//tslib_strcpy(data, SharedMem::write()->Sdata_DeviceSettingBuff, leng);
for (nn=0; nn<leng; nn++)
SharedMem::write()->Sdata_DeviceSettingBuff[nn] = data[nn];
}
void epi_restoreRbDeviceSettings(uint8_t *leng, uint8_t *data) // getestet am 12.4.23TS
{
uint8_t nn, LL;
LL=SharedMem::read()->Sdata_NrOfDeviceSetting;
*leng=LL;
//tslib_strcpy(SharedMem::read()->Sdata_DeviceSettingBuff, data, SharedMem::read()->Sdata_NrOfDeviceSetting);
for (nn=0; nn<LL; nn++)
data[nn] = SharedMem::read()->Sdata_DeviceSettingBuff[nn];
}
/*
Beispiel:
void gpi_storeUID(uint8_t const *buf8byteUid)
{
uint64_t udltmp=0;
for (int ii=0; ii<8; ii++)
{
SharedMem::getData()->Sdata.UIDstr[ii] = buf8byteUid[ii];
udltmp |= buf8byteUid[ii];
udltmp <<= 8;
}
SharedMem::getData()->Sdata.slaveUID = udltmp;
}
void epi_getUIDdec(uint8_t *buf8byteUid)
{
for (int ii=0; ii<8; ii++)
{
buf8byteUid[ii] = SharedMem::getDataConst()->Sdata.UIDstr[ii];
}
}
*/
//static uint8_t Sdata_NrOfMachineIDSetting;
//static uint8_t Sdata_NrOfMachineIDBuff[66];
void gpi_storeMachineIDsettings(uint8_t leng, uint8_t *data)
{
uint8_t nn;
if (leng>64) leng=64;
//Sdata_NrOfMachineIDSetting=leng;
//tslib_strcpy(data, Sdata_NrOfMachineIDBuff, leng);
SharedMem::write()->SizeMachineIDBuff=leng;
for (nn=0; nn<64; nn++)
SharedMem::write()->MachineIDBuff[nn]=data[nn];
}
void epi_restoreMachineIDsettings(uint8_t *leng, uint8_t *data)
{
//*leng=Sdata_NrOfMachineIDSetting;
//tslib_strcpy(Sdata_NrOfMachineIDBuff, data, Sdata_NrOfMachineIDSetting);
uint8_t uctmp, nn;
uctmp=SharedMem::read()->SizeMachineIDBuff;
*leng=uctmp;
for (nn=0; nn<64; nn++)
data[nn]=SharedMem::read()->MachineIDBuff[nn];
}
//static uint32_t store_insertedAmount;
//static uint16_t store_lastCoinType[64];
//static uint16_t store_lastCoinValue[64];
//static uint8_t p_lastCoin;
//static char store_curPayNewCoin;
void epi_clearCurrentPayment(void)
{
// call at beginning of coin collection
int nn;
SharedMem::write()->store_insertedAmount=0;
SharedMem::write()->p_lastCoin=0;
// 17.5.23TS: ergänzt:
for (nn=0; nn<64; nn++)
{
SharedMem::write()->store_lastCoinType[nn]=0;
SharedMem::write()->store_lastCoinValue[nn]=0;
}
SharedMem::write()->store_curPayNewCoin=0;
}
void gpi_storeCurrentPayment(uint32_t insertedAmount, uint16_t lastCoinType, uint16_t lastCoinValue)
{
uint8_t pLC=SharedMem::read()->p_lastCoin;
SharedMem::write()->store_insertedAmount=insertedAmount;
SharedMem::write()->store_lastCoinType[pLC]=lastCoinType;
SharedMem::write()->store_lastCoinValue[pLC]=lastCoinValue;
pLC++;
SharedMem::write()->p_lastCoin=pLC;
SharedMem::write()->store_curPayNewCoin++;
//qDebug()<<"gpi_storeCurrentPayment "<<insertedAmount<<" " << lastCoinType<<" " << lastCoinValue;
}
uint32_t epi_CurrentPaymentGetAmount(void)
{
return SharedMem::read()->store_insertedAmount;
}
uint16_t epi_CurrentPaymentGetLastCoin(void)
{
uint8_t pp;
pp=SharedMem::read()->p_lastCoin;
if (pp==0)
return 0; // noch keine Münze erhalten
if (pp>0) pp--;
//store_curPayNewCoin=0; // nur 1x melden
return SharedMem::read()->store_lastCoinValue[pp];
}
bool epi_CurrentPaymentGetAllCoins(uint16_t *types, uint16_t *values)
{
// alle bei diesem Verkauf eingeworfenen Münzen sind gespeichert falls die jmd. braucht
uint8_t nn;
uint8_t pp;
pp=SharedMem::read()->p_lastCoin;
if (pp==0)
return false;
for (nn=0; nn<64; nn++)
{
types[nn]= SharedMem::read()->store_lastCoinType[nn];
values[nn]=SharedMem::read()->store_lastCoinValue[nn];
}
return true;
}
//uint64_t stor_wakSrc;
//uint8_t stor_reason;
void gpi_storeWakeSources(uint8_t *receivedData)
{
uint8_t uctmp;
int nn;
SharedMem::write()->stor_wakSrc=0;
for (nn=5; nn>=0; nn--)
{
uctmp=receivedData[nn];
SharedMem::write()->stor_wakSrc |=uctmp;
SharedMem::write()->stor_wakSrc<<=8;
}
SharedMem::write()->stor_reason=receivedData[6];
}
uint64_t epi_getWakeSources(void)
{
return SharedMem::read()->stor_wakSrc;
}
uint8_t epi_getWakeReason(void)
{
return SharedMem::read()->stor_reason;
}
//static uint8_t store_rbDevParamLen;
//static uint8_t store_rbDevParams[66];
void gpi_storeExtendedTime(uint8_t leng, uint8_t *data)
{
uint8_t nn;
if (leng>64) leng=64;
SharedMem::write()->store_rbDevParamLen=leng;
//tslib_strcpy(data, SharedMem::write()->store_rbDevParams, leng);
for (nn=0; nn<leng; nn++)
SharedMem::write()->store_rbDevParams[nn] = data[nn];
}
void epi_restoreExtendedTime(uint8_t *leng, uint8_t *data)
{
uint8_t nn, LL;
LL=SharedMem::read()->store_rbDevParamLen;
*leng=LL;
//tslib_strcpy(SharedMem::read()->store_rbDevParams, data, SharedMem::read()->store_rbDevParamLen);
for (nn=0; nn<LL; nn++)
data[nn] = SharedMem::read()->store_rbDevParams[nn];
}
// store device conditions
//static uint8_t store_deviceCondLen;
//static uint8_t store_deviceCond[66];
void epi_clearDeviceConditions(void)
{
uint8_t nn;
SharedMem::write()->store_deviceCondLen=0;
for (nn=0; nn<64; nn++)
SharedMem::write()->store_deviceCond[nn]=0;
}
void gpi_storeDeviceConditions(uint8_t leng, uint8_t *data)
{
uint8_t nn;
if (leng>64) leng=64;
SharedMem::write()->store_deviceCondLen=leng;
//tslib_strcpy(data, SharedMem::write()->store_deviceCond, leng);
for (nn=0; nn<leng; nn++)
SharedMem::write()->store_deviceCond[nn]=data[nn];
}
void epi_restoreDeviceConditions(uint8_t *leng, uint8_t *data)
{
uint8_t nn, LL;
LL=SharedMem::read()->store_deviceCondLen;
*leng=LL;
//tslib_strcpy(SharedMem::read()->store_deviceCond, data, SharedMem::read()->store_deviceCondLen);
for (nn=0; nn<LL; nn++)
data[nn] = SharedMem::read()->store_deviceCond[nn];
}
// store dynamic machine conditions
//static uint8_t store_machCondLen;
//static uint8_t store_machCond[66];
void epi_clearDynMachineConditions(void)
{
uint8_t nn;
SharedMem::write()->store_machCondLen=0;
for (nn=0; nn<64; nn++)
SharedMem::write()->store_machCond[nn] = 0;
}
void gpi_storeDynMachineConditions(uint8_t leng, uint8_t *data)
{
uint8_t nn;
if (leng>64) leng=64;
SharedMem::write()->store_machCondLen=leng;
// tslib_strcpy(data, SharedMem::write()->store_machCond, leng);
for (nn=0; nn<leng; nn++)
SharedMem::write()->store_machCond[nn] = data[nn];
}
void epi_restoreDynMachineConditions(uint8_t *leng, uint8_t *data)
{
uint8_t nn, LL;
LL=SharedMem::read()->store_machCondLen;
*leng=LL;
//tslib_strcpy(SharedMem::read()->store_machCond, data, SharedMem::read()->store_machCondLen);
for (nn=0; nn<LL; nn++)
data[nn] = SharedMem::read()->store_machCond[nn];
}
//static uint8_t store_DcBackupNrOfAccNr;
//static uint16_t store_DcBackupAccNr[16]; // z.Z. nur 8
void gpi_storeDCbackupAccNr(uint8_t leng, uint8_t *data)
{
if (leng>32) leng=32;
SharedMem::write()->store_DcBackupAccNr[0]=uchar2uint(data[1], data[0]);
SharedMem::write()->store_DcBackupAccNr[1]=uchar2uint(data[3], data[2]);
SharedMem::write()->store_DcBackupAccNr[2]=uchar2uint(data[5], data[4]);
SharedMem::write()->store_DcBackupAccNr[3]=uchar2uint(data[7], data[6]);
SharedMem::write()->store_DcBackupAccNr[4]=uchar2uint(data[9], data[8]);
SharedMem::write()->store_DcBackupAccNr[5]=uchar2uint(data[11], data[10]);
SharedMem::write()->store_DcBackupAccNr[6]=uchar2uint(data[13], data[12]);
SharedMem::write()->store_DcBackupAccNr[7]=uchar2uint(data[15], data[14]);
SharedMem::write()->store_DcBackupNrOfAccNr=8;
}
void epi_restoreDCbackupAccNr(uint8_t *leng, uint16_t *accNrs)
{
// return accNrs[0..7]
uint8_t nn;
*leng=SharedMem::read()->store_DcBackupNrOfAccNr;
for (nn=0; nn<8; nn++)
accNrs[nn]=SharedMem::read()->store_DcBackupAccNr[nn];
}
void epi_iniVRstorage(void)
{
tslib_strclr(SharedMem::write()->store_vaultrecord, 0, PI_SIZOFVAULTRECORD);
SharedMem::write()->store_gotNrBlocksOfVaultRec=0;
}
void gpi_storeVaultRecord(uint8_t blkNr, uint8_t *data )
{
uint16_t start=blkNr, ii;
qDebug()<<"storing vault data "<<blkNr;
SharedMem::write()->store_gotNrBlocksOfVaultRec |= (1<<start); // setze pro Block ein bit, wir brauchen block 0...5
// also muss store_gotNrBlocksOfVaultRec auf 0x1F stehen
start<<=6; // *64
if ((start+64) > PI_SIZOFVAULTRECORD)
start=320; // beginning of 6.block
for (ii=0; ii<64; ii++)
SharedMem::write()->store_vaultrecord[start+ii]=data[ii];
}
bool epi_checkIfVaultRecordAvailable(void)
{
uint8_t data;
data=SharedMem::read()->store_gotNrBlocksOfVaultRec;
// qDebug()<<"epi_checkIfVaultRecordAvailable: "<<data;
if (data==0x3F)
return true;
else
return false;
}
uint8_t epi_getLoadedVaultBlocks(void)
{
// return 0x0011 1111 if all 6 blocks arer loaded (one bit per block)
uint8_t data;
data=SharedMem::read()->store_gotNrBlocksOfVaultRec;
return data;
}
bool epi_restoreVaultRecord(uint16_t *length, uint8_t *buf )
{
uint16_t nn;
uint8_t dat;
*length=384; //genau: 340;
for (nn=0; nn<384; nn++)
{
dat = SharedMem::read()->store_vaultrecord[nn];
buf[nn]=dat;
}
return true;
}
//static uint32_t store_amount;
//static uint16_t store_nrOfCoins;
void gpi_storeCBlevel(uint32_t amount, uint16_t nrOfCoins )
{
SharedMem::write()->store_amount=amount;
SharedMem::write()->store_nrOfCoins=nrOfCoins;
}
uint32_t epi_getCashBoxContent(void)
{
return SharedMem::read()->store_amount;
}
uint16_t epi_getNrOfCoinsInCashBox(void)
{
return SharedMem::read()->store_nrOfCoins;
}
//static bool store_DcDataAreValid;
void gpi_storeDcDataValid(bool isVal)
{
SharedMem::write()->store_DcDataAreValid = isVal;
}
bool epi_areDcDataValid()
{
return SharedMem::read()->store_DcDataAreValid;
}
// ....................................................................................
// 24.5.2023
//static uint8_t storeDCdynPrinterData[64];
//static uint8_t DCdynPrinterDataActual;
/*
uint8_t nn, LL;
LL=SharedMem::read()->Sdata_mdbNrOfRecData;
//tslib_strcpy(SharedMem::read()->Sdata_RecBuff, data, SharedMem::read()->Sdata_mdbNrOfRecData);
for (nn=0; nn<LL; nn++)
data[nn] = SharedMem::read()->Sdata_RecBuff[nn];
*/
void epi_clearDynData(void)
{
uint8_t nn;
SharedMem::write()->DCdynPrinterDataActual=0;
//memset(SharedMem::write()->storeDCdynPrinterData,0, sizeof(storeDCdynPrinterData));
for (nn=0; nn<64; nn++)
SharedMem::write()->storeDCdynPrinterData[nn]=0;
}
void gpi_storeDynData(uint8_t *DCdynDat)
{
uint8_t nn;
// buffer size: 64 byte
//memcpy(SharedMem::write()->storeDCdynPrinterData, DCdynDat, 64);
SharedMem::write()->DCdynPrinterDataActual=1;
for (nn=0; nn<64; nn++)
SharedMem::write()->storeDCdynPrinterData[nn] = DCdynDat[nn];
}
bool epi_getDynPrnData(uint8_t *DCdynDat)
{
// buffer size: 64 byte
// return true if data are new and valid
uint8_t nn;
if (SharedMem::read()->DCdynPrinterDataActual)
{
//memcpy(DCdynDat, SharedMem::read()->storeDCdynPrinterData, 64);
for (nn=0; nn<64; nn++)
DCdynDat[nn] = SharedMem::read()->storeDCdynPrinterData[nn];
return true;
} else
{
return false;
}
}
void gpi_storeNextDCaccNr(uint16_t nxtDcAccNr)
{
SharedMem::write()->store_DCNextAccountNumber = nxtDcAccNr;
}
uint16_t epi_getNextDCaccNr(void )
{
return SharedMem::read()->store_DCNextAccountNumber;
}
void gpi_storeMifCardType(uint16_t length, uint8_t *data)
{
SharedMem::write()->storeMifCardTypDataLen = length;
for (uint8_t ii=0; ii<64; ii++)
SharedMem::write()->storeMcardTypData[ii] = data[ii];
}
void epi_restoreMifCardType(uint16_t *length, uint8_t *data)
{
*length = SharedMem::read()->storeMifCardTypDataLen;
for (uint8_t ii=0; ii<64; ii++)
data[ii] = SharedMem::read()->storeMcardTypData[ii];
}
// before with local memory:
//static uint8_t Sdata_rawData[RAW_BL_DATALEN];
//static uint8_t Sdata_LengthRawData;
void gpi_storeRawReceivedData(uint8_t RdDlen, uint8_t *receivedData)
{
uint8_t nn, lrd;
lrd=RdDlen;
if (lrd>RAW_BL_DATALEN)
lrd=RAW_BL_DATALEN;
SharedMem::write()->Sdata_LengthRawData=lrd;
for (nn=0; nn<lrd; nn++)
SharedMem::write()->Sdata_rawData[nn]=receivedData[nn];
//qDebug()<<"dcBL got data"<< Sdata_LengthRawData << "bytes :)";
}
uint8_t epi_getRawReceivedData(uint8_t *receivedData)
{
uint8_t nn, lrd;
lrd=SharedMem::read()->Sdata_LengthRawData;
for (nn=0; nn<lrd; nn++)
receivedData[nn] = SharedMem::read()->Sdata_rawData[nn];
SharedMem::write()->Sdata_LengthRawData=0; // nur 1x gueltig
return lrd;
}
uint8_t epi_getRawRecLength(void)
{
// retval=length
return SharedMem::read()->Sdata_LengthRawData;
}
/*
QString epi_getRawReceivedString()
{
uint8_t nn; //, ret;
QString myString=nullptr, tmpStr=nullptr;
myString.clear();
if (Sdata_LengthRawData==0)
return myString;
for (nn=0; nn<Sdata_LengthRawData; nn++)
{
tmpStr.clear();
tmpStr.setNum(Sdata_rawData[nn],16); // problem: wenn >0x80 dann wird EIN Byte 16 stellig angezeigt
int ll=tmpStr.length();
if (ll>2)
{
myString.append(tmpStr[ll-2]);
myString.append(tmpStr[ll-1]);
} else
{
myString.append(tmpStr);
}
myString.append(" ");
}
//ret=Sdata_LengthRawData;
//Sdata_LengthRawData=0;
return myString;
}*/
void epi_clrRawReceivedString()
{
SharedMem::write()->Sdata_LengthRawData=0;
}
// Mitteilung von Hwapi zu Datif (request coin type)
void epi_setNowCoinPay(bool on_off)
{
SharedMem::write()->Sdata_coinPaymentNow=on_off;
}
bool gpi_getNowCoinPay (void)
{
return SharedMem::read()->Sdata_coinPaymentNow;
}
// Mitteilung von Hwapi zu Datif: using BL now
void epi_setNowIsBootload(bool on_off)
{
SharedMem::write()->Sdata_bootloadingNow=on_off;
}
bool gpi_getNowIsBootload(void)
{
return SharedMem::read()->Sdata_bootloadingNow;
}
// new from 28.9.23 and earliest from DC version 4.45
// store all versions of the DC-Jsons
//#define numberOfJsons 36
//#define versionStringLength 16
//char store_jsonVersion[versionStringLength][numberOfJsons];
void gpi_storeJsonVersion(uint8_t jsonNr, uint8_t *versionString)
{
// jsonNr=1...36, 1=config file (cust.Nr) 2=devices 3=cash 4=res.
// 5=printer template 1 ..... 36= template 32
// length of buffer is always 16 byte
uint8_t nn, lrd;
char einZeichen;
lrd=jsonNr;
if (lrd>0 && lrd<=numberOfJsons)
{
lrd--;
for (nn=0; nn<versionStringLength; nn++)
{
einZeichen=char(versionString[nn]);
SharedMem::write()->store_jsonVersion[nn][lrd]=einZeichen;
}
}
}
void epi_getJsonVersion(uint8_t jsonNr, char *versionString)
{
// jsonNr=1...36, 1=config file (cust.Nr) 2=devices 3=cash 4=res.
// 5=printer template 1 ..... 36= template 32
// length of buffer is always 16 byte
uint8_t nn, lrd;
lrd=jsonNr;
if (lrd>0 && lrd<=numberOfJsons)
{
lrd--;
for (nn=0; nn<versionStringLength; nn++)
versionString[nn] = SharedMem::read()->store_jsonVersion[nn][lrd];
}
}
void gpi_storeChangerResult(uint8_t result, uint32_t amount)
{
SharedMem::write()->Sdata_changeResult=result;
SharedMem::write()->Sdata_changedAmount=amount;
}
uint8_t epi_getChangerResult(uint32_t *returnedAmount)
{
*returnedAmount=SharedMem::read()->Sdata_changedAmount;
return SharedMem::read()->Sdata_changeResult;
}
void gpi_storeTubeLevel(uint8_t *data)
{
int nn;
for (nn=0; nn<64; nn++)
{
SharedMem::write()->store_tubeLev[nn]=data[nn];
}
}
void epi_restoreTubeLevel(uint8_t *data)
{
int nn;
for (nn=0; nn<64; nn++)
{
data[nn]=SharedMem::read()->store_tubeLev[nn];
}
}