DCLibraries/include/storeINdata.h

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#ifndef STOREINDATA_H
#define STOREINDATA_H
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#include <stdint.h>
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#include "tslib.h"
#include <QString>
#define MAXNROF_AO 3
#define MAXNROF_GENSTR 16
#define MAXNROF_CONTR_PORTS 11
#define MAXNROF_DIports 2
#define MAXNROF_DOports 2
#define MAXNROF_CTR 2
#define MEASCHAN_TEMPERATURE 0
#define MEASCHAN_VOLTAGE 1
// gpi: DC-driver stores data for graphic peripheral interface
// epi: gui reads values from external peripheral interface
// store power on/off condition of the devices to control the data request
void indat_storePrinterPower(bool isOn);
bool indat_isPrinterOn();
void indat_storeMifarePower(bool isOn);
bool indat_isMifareOn();
void indat_storeMDBisOn(bool isOn);
bool indat_isMdbOn();
void gpi_storeHWver(QString text);
QString epi_loadHWver(void);
void gpi_storeSWver(QString text);
QString epi_loadSWver(void);
void gpi_storeDCstate(QString text);
QString epi_loadDCstate(void);
void gpi_storeUID(uint8_t const *buf8byteUid);
//void gpi_storeUID(uint8_t *buf8byteUid);
// buffer size: 8 byte
void epi_getUIDdec(uint8_t *buf8byteUid);
// buffer size: 8 byte
QString epi_getUIDstr();
// ///////////////////////////////////////////////////////////////////////////////////
// Time and Date
// ///////////////////////////////////////////////////////////////////////////////////
uint8_t epi_getSquareMode();
void gpi_backupSquareMode(uint8_t squMode);
void gpi_backupTime(uint8_t *timeBuffer, uint8_t Leng); // 104, <=8byte
void epi_getTime(uint8_t *hh, uint8_t *mm, uint8_t *ss);
void epi_getDate(uint8_t *yy, uint8_t *mm, uint8_t *dd);
void epi_getToday(uint8_t *dow, uint16_t *minOfToday, uint32_t *secOfToday);
bool epi_isLeapYear(uint8_t *lastLeapYear, uint8_t *NextLeapYear);
bool epi_isLeapYear();
void epi_getSpecialWeekTimeDate(uint8_t *DayOfWeek, uint8_t *HoursOfWeek, uint16_t *MinutesOfWeek);
void epi_getSpecialMonthTimeDate(uint8_t *DayOfMonth, uint16_t *HoursOfMonth, uint16_t *MinutesOfMonth);
void epi_getSpecialYearTimeDate(uint16_t *DayOfYear, uint16_t *HoursOfYear, uint32_t *MinutesOfYear);
// ///////////////////////////////////////////////////////////////////////////////////
// Analog values
// ///////////////////////////////////////////////////////////////////////////////////
void gpi_storeAIs(uint8_t aiNr, uint16_t val); // rs -> Sdata
uint8_t gpi_getMaxNrAIs();
uint16_t epi_loadAIs(uint8_t aiNr); // Sdata -> gui
// return value of one ADC with channel nr: aiNr 0...15
uint32_t epi_loadMeasureValue(uint8_t ValueNr);
// ValueNr 0=ADC0, 1=ADC1 aso...
void gpi_storeMeasureValue(uint8_t ValueNr, uint32_t val);
// in mV, also bis 65,535V
QString epi_getSlaveTemperatureStr();
QString epi_getSlaveVoltageStr();
// value in "meas_volt" in mV, also bis 65,535V. Value range [6000...16000] (6V...16V)
// ///////////////////////////////////////////////////////////////////////////////////
// digital inputs
// ///////////////////////////////////////////////////////////////////////////////////
void gpi_storeDI_doorSwitches(uint8_t upperDoor, uint8_t lowerDoor, uint8_t vaultDoor);
uint8_t epi_getDI_doorSwitches(void);
// bit0: upper door 1: low door 2:vault door
void gpi_storeDI_vaultSwitches(uint8_t CashBoxIn, uint8_t BillBoxIn);
uint8_t epi_getDI_vaultSwitches(void);
// bit0: cash box 1: bill box in
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
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
void gpi_storeDI_optos(uint8_t indatOpto);
// OptoIn bit 0,1: optoin 1,2
uint8_t epi_getDI_optos(void);
// bit0: opto in 1 1: opto in 2
void gpi_storeDI_auxIn(uint8_t indatAuxIn);
// Aux0...5
uint8_t epi_getDI_auxIn(void);
// bit0: auxin 1 ... 5: auxin 6
void gpi_storeDI_ptuWake(uint8_t indat);
bool epi_getDI_ptuWake(void);
void gpi_storeDI_mbdWake(uint8_t indat);
bool epi_getDI_mdbWake(void);
void gpi_storeDI_prnReady(uint8_t indat);
bool epi_getDI_prnReady(void);
void gpi_storeDI_CoinAttach(uint8_t indat);
bool epi_getDI_CoinAttach(void);
void gpi_storeDI_CoinEscrow(uint8_t indat);
bool epi_getDI_CoinEscrow(void);
void gpi_storeDI_mifareCardTapped(uint8_t indat);
bool epi_getDI_mifareCardTapped(void);
void gpi_storeDI_modemWake(uint8_t indat);
bool epi_getDI_modemWake(void);
void gpi_storeDI_contactPowerIsOn(bool di_contact_PwrOn);
bool epi_getDI_contactPwr(void);
void gpi_storeDI_MifarePowerIsOn(bool di_mifare_PwrOn);
bool epi_getDI_mifarePwr(void);
void gpi_storeDI_readbackMdbTxD(bool di_rdbkMdbTxd);
bool epi_getDI_mdbTxd(void);
void gpi_storeDI_AuxPowerIsOn(bool di_Aux_PwrOn);
bool epi_getDI_auxPwr(void);
void gpi_storeDI_GsmPowerIsOn(bool di_gsm_PwrOn);
bool epi_getDI_gsmPwr(void);
void gpi_storeDI_CreditPowerIsOn(bool di_credit_PwrOn);
bool epi_getDI_creditPwr(void);
void gpi_storeDI_PrinterPowerIsOn(bool di_printer_PwrOn);
bool epi_getDI_printerPwr(void);
void gpi_storeDI_MdbPowerIsOn(bool di_mdb_PwrOn);
bool epi_getDI_mdbPwr(void);
void gpi_storeDI_rejMot_home(bool di);
bool epi_getDI_rejectMotor_homepos(void);
void gpi_storeDI_paperLow(uint8_t di);
uint8_t epi_getDI_npe_sensor(void);
// 0: Sensor sees paper 1: no paper 99: off
// ///////////////////////////////////////////////////////////////////////////////////
// readback digital outputs
// ///////////////////////////////////////////////////////////////////////////////////
void gpi_storeDO_mdbRxTst(uint8_t do_mbdRxTst);
bool epi_getDO_mdbRxTestOut(void);
void gpi_storeDO_motorOutputs(uint8_t Pwr);
uint8_t epi_getDO_motorOuts(void);
// bit0: upper lock forward bit 1 backward
// bit2: lower lock forward bit 3 backward
void gpi_storeDO_serialSwitch(uint8_t state);
// serial drv on/off, Serial mux1, Serial mux2
uint8_t epi_getDO_serialSwitch(void);
// serial drv on/off, Serial mux1, Serial mux2
bool epi_getDO_serialDriverIsOn(void);
bool epi_getDO_serialMux1isSetToPrinter(void);
// mux1 off: serial is switched to printer
bool epi_getDO_serialMux1isSetToModem(void);
// mux1 on: serial is switched to modem
bool epi_getDO_serialMux2isSetToCredit(void);
// mux2 off: serial is switched to credit card terminal
bool epi_getDO_serialMux2isSetToMifare(void);
// mux2 on: serial is switched to mifare reader
void gpi_storeDO_ledsAndFan(uint8_t ledState);
bool epi_getDO_led_coin(void);
bool epi_getDO_led_front(void);
bool epi_getDO_led_ticket(void);
bool epi_getDO_led_pin(void);
bool epi_getDO_led_start(void);
bool epi_getDO_led_inside(void);
bool epi_getDO_fan(void);
void gpi_storeDO_sirenAndRelay(uint8_t sirenRelay);
bool epi_getDO_sirene(void);
bool epi_getDO_relay(void);
void gpi_storeDO_ptuWake(uint8_t state);
bool epi_getDO_ptuWake(void);
void gpi_storeDO_auxPower(uint8_t pwr);
bool epi_getDO_auxPower(void);
void gpi_storeDO_coinShutter(uint8_t state);
bool epi_getDO_coinShutterOpen(void);
bool epi_getDO_coinShutterTest(void);
void gpi_storeDO_coinEscrow(uint8_t state);
uint8_t epi_getDO_coinEscrow(void);
// retval: 1:return flap is open 2:take flap is open 0:closed
void gpi_storeDO_printerPwrOn(uint8_t state);
uint8_t epi_getDO_printerPwr(void);
// ---------------------------------------------------------------------------------------------
// counterchecks, make sure that DC-outputs are correct
/*
bool epi_cntchk_wakePtu(void);
bool epi_cntchk_enabDrv01(void); // no communication possible if 0 !!!!!
bool epi_cntchk_swRs1toModem(void);
bool epi_cntchk_modemWake(void);
bool epi_cntchk_enabDrv2(void);
bool epi_cntchk_swRs2toMIF(void);
bool epi_cntchk_shutterIsOpen(void);
// counter check if shutter is really open, PJ4 must be OUT and HIGH, PB5 must be OUT and HIGH
// retval TRUE: shutter is open FALSE: shutter is closed
bool epi_cntchk_escrowReturnIsOpen(void);
bool epi_cntchk_escrowTakeIsOpen(void);
bool epi_cntchk_aux1DirOut(uint8_t auxNr);
bool epi_cntchk_aux1OutHigh(uint8_t auxNr);
bool epi_cntchk_ledPaperOn(void);
bool epi_cntchk_ledPinpadOn(void);
bool epi_cntchk_ledStartOn(void);
bool epi_cntchk_ledServiceOn(void);
bool epi_cntchk_ledCoinOn(void);
bool epi_cntchk_ledIllumOn(void);
bool epi_cntchk_FanOn(void);
bool epi_cntchk_RelaisOn(void);
bool epi_cntchk_LaermOn(void);
bool epi_cntchk_Mot1Ron(void);
bool epi_cntchk_Mot1Fon(void);
bool epi_cntchk_Mot2Ron(void);
bool epi_cntchk_Mot2Fon(void);
*/
// ------------------------------------------------------------------------------------
// MDB Sendind Data are store here for next transport to DC (Device Controller)
// Transport to Slave runs every 100ms, answer from mdb-slave (e.g. coin changer) comes right
// with next slave answer
// start with: SENDDIRCMD_EXCHGMDB,
// send crude data from here to DC, DC to mdb slaves, mdb answer, return here within 50ms
uint8_t gpi_storeMdbRecData(uint8_t length, uint8_t *buf);
// datif store received mdb data
uint8_t epi_getMdbResponse(void);
// 0=no response 1=ACK 2=NAK 3=ACK with data
uint8_t epi_getMdbRecLength(void);
// 0...31
uint8_t epi_restoreMdbRecData(uint8_t *buf);
// hwapi reads received mdb data from PI
void gpi_clearMifHwData(void);
void gpi_storeMifHwData(uint8_t *receivedData);
// blkNr=0...11 receivedData[64]
uint8_t epi_restoreMifHwData(uint8_t *buf, uint8_t maxBufferSize);
// blkNr=0...11 return buf[64]
// retval: 1=error 0=OK
void gpi_clearMifAtbData(void);
void gpi_storeMifAtbData(uint8_t *receivedData);
uint8_t epi_restoreMifAtbData( uint8_t *buf, uint8_t maxBufferSize);
void epi_restorePrinterState(uint8_t *buf);
void gpi_storePrinterState(uint8_t *buf);
void epi_restorePrinterFonts(uint8_t *buf);
void gpi_storePrinterFonts(uint8_t *buf);
void gpi_storeMdbState(uint8_t busReady, uint8_t V12on, uint8_t V5on );
bool epi_restoreMdbBusReady(void);
bool epi_restoreMdbV12Ready(void);
bool epi_restoreMdbV5Ready(void);
void gpi_storeMdbResponse(uint8_t leng, uint8_t *data);
void epi_restoreMdbResponse(uint8_t *leng, uint8_t *data);
// 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_storeEmpSettings(uint8_t leng, uint8_t *data);
void epi_restoreEmpSettings(uint8_t *leng, uint8_t *data);
/*
void gpi_storeEmpCoinSignal(uint8_t leng, uint8_t *data);
void epi_restoreEmpCoinSignal(uint8_t *leng, uint8_t *data);
// return 5 byte:
// data[0]=got coin 0xFF=emp reported an error 0=got nothing
// data[1]=emp-signal of last inserted coin
// data[2,3]=emp-value of last inserted coin
// data[4] = emp-error or warning
void epi_clearEmpCoinSignal();
*/
void gpi_storeEmpCoinSignal(uint8_t leng, uint8_t *data);
uint8_t epi_isNewCoinLeft(void);
// retval: 0...16 coins left in FIFO
void epi_restoreEmpCoinSignal(uint8_t *valid, uint8_t *signal, uint8_t *error, uint16_t *value);
void gpi_storeRbDeviceSettings(uint8_t leng, uint8_t *data);
void epi_restoreRbDeviceSettings(uint8_t *leng, uint8_t *data);
void gpi_storeMachineIDsettings(uint8_t leng, uint8_t *data);
void epi_restoreMachineIDsettings(uint8_t *leng, uint8_t *data);
void epi_clearCurrentPayment(void);
void gpi_storeCurrentPayment(uint32_t insertedAmount, uint16_t lastCoinType, uint16_t lastCoinValue);
uint32_t epi_CurrentPaymentGetAmount(void);
uint16_t epi_CurrentPaymentGetLastCoin(void);
bool epi_CurrentPaymentGetAllCoins(uint16_t *types, uint16_t *values);
// alle bei diesem Verkauf eingeworfenen Münzen sind gespeichert falls die jmd. braucht
void gpi_storeWakeSources(uint8_t *receivedData);
uint64_t epi_getWakeSources(void);
uint8_t epi_getWakeReason(void);
void gpi_storeExtendedTime(uint8_t leng, uint8_t *data);
void epi_restoreExtendedTime(uint8_t *leng, uint8_t *data);
void epi_clearDeviceConditions(void);
void gpi_storeDeviceConditions(uint8_t leng, uint8_t *data);
void epi_restoreDeviceConditions(uint8_t *leng, uint8_t *data);
void epi_clearDynMachineConditions(void); // new, 24.6.23
void gpi_storeDynMachineConditions(uint8_t leng, uint8_t *data);
void epi_restoreDynMachineConditions(uint8_t *leng, uint8_t *data);
void gpi_storeDCbackupAccNr(uint8_t leng, uint8_t *data);
void epi_restoreDCbackupAccNr(uint8_t *leng, uint16_t *accNrs);
// return accNrs[0..7]
void epi_iniVRstorage(void);
void gpi_storeVaultRecord(uint8_t blkNr, uint8_t *data );
bool epi_checkIfVaultRecordAvailable(void);
uint8_t epi_getLoadedVaultBlocks(void);
// return 0x0011 1111 if all 6 blocks arer loaded (one bit per block)
bool epi_restoreVaultRecord(uint16_t *length, uint8_t *buf );
// true if completly received
void gpi_storeCBlevel(uint32_t amount, uint16_t nrOfCoins );
uint32_t epi_getCashBoxContent(void);
uint16_t epi_getNrOfCoinsInCashBox(void);
//void gpi_storeNewMifareCard(uint8_t typ, uint8_t *holder );
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
void gpi_storeDcDataValid(bool isVal);
bool epi_areDcDataValid();
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void epi_setDcDataValid(void);
void epi_resetDcDataValid(void);
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void epi_clearDynData(void);
void gpi_storeDynData(uint8_t *DCdynDat);
// buffer size: 64 byte
bool epi_getDynPrnData(uint8_t *DCdynDat);
// buffer size: 64 byte
// return true if data are new and valid
void gpi_storeNextDCaccNr(uint16_t nxtDcAccNr);
uint16_t epi_getNextDCaccNr(void );
void gpi_storeMifCardType(uint16_t length, uint8_t *data);
void epi_restoreMifCardType(uint16_t *length, uint8_t *data);
// move here from dcBL and use shared mem as ptu-updater uses CAslave Lib 6.9.23TS
//#define RAW_BL_DATALEN 150
void gpi_storeRawReceivedData(uint8_t RdDlen, uint8_t *receivedData);
uint8_t epi_getRawReceivedData(uint8_t *receivedData);
// retval=length, will be zeroed after first reading
uint8_t epi_getRawRecLength(void);
// retval=length
//QString epi_getRawReceivedString();
// not used
void epi_clrRawReceivedString();
// 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
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
void epi_setNowCoinPay(bool on_off);
bool gpi_getNowCoinPay(void);
void epi_setNowIsBootload(bool on_off);
bool gpi_getNowIsBootload(void);
void gpi_storeChangerResult(uint8_t result, uint32_t amount);
uint8_t epi_getChangerResult(uint32_t *returnedAmount);
// get result of coin dispensing
// receivedData[0]: 0: not yet started 1:amount returned
// 2:only partial return 3: no return possible
// receivedData[2,3,4,5]: returned amount
void gpi_storeTubeLevel(uint8_t *data);
void epi_restoreTubeLevel(uint8_t *data);
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void gpi_storeBnaParams(uint8_t *data);
void epi_restoreBnaParams(uint8_t *data);
void gpi_storeBnaCollection(uint8_t *data);
void epi_restoreBnaCollection(uint8_t *data);
void gpi_storeBnaContent(uint8_t *data);
void epi_restoreBnaContent(uint8_t *data);
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#endif