/* * Routines to access hardware * * Copyright (c) 2013 Realtek Semiconductor Corp. * */ #ifndef _HAL_I2C_H_ //#ifndef _HAL_I2C_H_ #define _HAL_I2C_H_ #include "rtl8195a_i2c.h" #include "hal_gdma.h" //================= I2C CONFIGURATION START ================== // I2C SAL User Configuration Flags // I2C SAL operation types #define I2C_POLL_OP_TYPE 1 //1 #define I2C_INTR_OP_TYPE 1 //1 #define I2C_DMA_OP_TYPE 1 //1 // I2C supports user register address #define I2C_USER_REG_ADDR 1 //I2C User specific register address by using //the first I2C data as the register //address // I2C SAL used module. Please set the I2C module flag to 1 to enable the related // I2C module functions. #define I2C0_USED 1 #define I2C1_USED 1 #define I2C2_USED 1 #define I2C3_USED 1 //================= I2C CONFIGURATION END =================== //================= I2C HAL START ========================== // I2C debug output #define I2C_PREFIX "RTL8195A[i2c]: " #define I2C_PREFIX_LVL " [i2c_DBG]: " typedef enum _I2C_DBG_LVL_ { HAL_I2C_LVL = 0x01, SAL_I2C_LVL = 0x02, VERI_I2C_LVL = 0x03, }I2C_DBG_LVL,*PI2C_DBG_LVL; #if CONFIG_DEBUG_LOG > 0 #ifdef CONFIG_DEBUG_LOG_I2C_HAL #define DBG_I2C_LOG_PERD 100 #define I2CDBGLVL 0xFF #define DBG_8195A_I2C(...) do{ \ _DbgDump(I2C_PREFIX __VA_ARGS__);\ }while(0) #define DBG_8195A_I2C_LVL(LVL,...) do{\ if (LVL&I2CDBGLVL){\ _DbgDump(I2C_PREFIX_LVL __VA_ARGS__);\ }\ }while(0) #else #define DBG_I2C_LOG_PERD 100 #define DBG_8195A_I2C(...) #define DBG_8195A_I2C_LVL(...) #endif #else #define DBG_I2C_LOG_PERD 100 #define DBG_8195A_I2C(...) #define DBG_8195A_I2C_LVL(...) #endif #define I2C_MTR_RTY_CNT 1024 //====================================================== // I2C HAL related enumeration // I2C Module Selection typedef enum _I2C_MODULE_SEL_ { I2C0_SEL = 0x0, I2C1_SEL = 0x1, I2C2_SEL = 0x2, I2C3_SEL = 0x3, }I2C_MODULE_SEL,*PI2C_MODULE_SEL; // I2C HAL initial data structure typedef struct _HAL_I2C_INIT_DAT_ { u8 I2CIdx; //I2C index used u8 I2CEn; //I2C module enable u8 I2CMaster; //Master or Slave mode u8 I2CAddrMod; //I2C addressing mode(7-bit, 10-bit) u8 I2CSpdMod; //I2C speed mode(Standard, Fast, High) u8 I2CSetup; //I2C SDA setup time u8 I2CRXTL; //I2C RX FIFO Threshold u8 I2CTXTL; //I2C TX FIFO Threshold u8 I2CBusLd; //I2C bus load (pf) for high speed mode u8 I2CReSTR; //I2C restart support u8 I2CGC; //I2C general support u8 I2CStartB; //I2C start byte support u8 I2CSlvNoAck; //I2C slave no ack support u8 I2CDMACtrl; //I2C DMA feature support u8 I2CCmd; //I2C Command u8 I2CDataLen; //I2C Data Length u8 I2CSlvAckGC; //I2C slave acks to General Call u8 I2CStop; //I2C issues STOP bit or not u16 RSVD0; //Bit0: used to control HalI2CMassSendRtl8195a_Patch sending // RESTART or not by upper layer SW. u8 *I2CRWData; //I2C Read/Write data pointer u16 I2CIntrMSK; //I2C Interrupt Mask u16 I2CIntrClr; //I2C Interrupt register to clear u16 I2CAckAddr; //I2C target address in I2C Master mode, //ack address in I2C Slave mode u16 I2CSdaHd; //I2C SDA hold time u32 I2CClk; //I2C bus clock (in kHz) u8 I2CTxDMARqLv; //I2C TX DMA Empty Level u8 I2CRxDMARqLv; //I2C RX DMA Full Level u16 RSVD1; //Reserved }HAL_I2C_INIT_DAT,*PHAL_I2C_INIT_DAT; // I2C HAL Operations typedef struct _HAL_I2C_OP_ { HAL_Status (*HalI2CInit) (VOID *Data); //HAL I2C initialization HAL_Status (*HalI2CDeInit) (VOID *Data); //HAL I2C de-initialization HAL_Status (*HalI2CSend) (VOID *Data); //HAL I2C send u8 (*HalI2CReceive) (VOID *Data); //HAL I2C receive HAL_Status (*HalI2CEnable) (VOID *Data); //HAL I2C enable module HAL_Status (*HalI2CIntrCtrl) (VOID *Data); //HAL I2C interrupt control u32 (*HalI2CReadReg) (VOID *Data, u8 I2CReg);//HAL I2C read register HAL_Status (*HalI2CWriteReg) (VOID *Data, u8 I2CReg, u32 RegVal);//HAL I2C write register HAL_Status (*HalI2CSetCLK) (VOID *Data); //HAL I2C set bus clock HAL_Status (*HalI2CMassSend) (VOID *Data); //HAL I2C mass send HAL_Status (*HalI2CClrIntr) (VOID *Data); //HAL I2C clear interrupts HAL_Status (*HalI2CClrAllIntr) (VOID *Data); //HAL I2C clear all interrupts HAL_Status (*HalI2CDMACtrl) (VOID *Data); //HAL I2C DMA control }HAL_I2C_OP, *PHAL_I2C_OP; //================= I2C HAL END =========================== //================= I2C SAL START ========================== //I2C SAL Macros //====================================================== // I2C SAL related enumerations // I2C Extend Features typedef enum _I2C_EXD_SUPPORT_{ I2C_EXD_RESTART = 0x1, //BIT_0, RESTART bit I2C_EXD_GENCALL = 0x2, //BIT_1, Master generates General Call. All "send" operations generate General Call addresss I2C_EXD_STARTB = 0x4, //BIT_2, Using START BYTE, instead of START Bit I2C_EXD_SLVNOACK = 0x8, //BIT_3, Slave no ack to master I2C_EXD_BUS400PF = 0x10, //BIT_4, I2C bus loading is 400pf I2C_EXD_SLVACKGC = 0x20, //BIT_5, Slave acks to a General Call I2C_EXD_USER_REG = 0x40, //BIT_6, Using User Register Address I2C_EXD_USER_TWOB = 0x80, //BIT_7, User Register Address is 2-byte I2C_EXD_MTR_ADDR_RTY= 0x100, //BIT_8, Master retries to send start condition and Slave address when the slave doesn't ack // the address. I2C_EXD_MTR_ADDR_UPD= 0x200, //BIT_9, Master dynamically updates slave address I2C_EXD_MTR_HOLD_BUS= 0x400, //BIT_10, Master doesn't generate STOP when the FIFO is empty. This would make Master hold // the bus. }I2C_EXD_SUPPORT,*PI2C_EXD_SUPPORT; // I2C operation type typedef enum _I2C_OP_TYPE_ { I2C_POLL_TYPE = 0x0, I2C_DMA_TYPE = 0x1, I2C_INTR_TYPE = 0x2, }I2C_OP_TYPE, *PI2C_OP_TYPE; // I2C pinmux selection typedef enum _I2C_PINMUX_ { I2C_PIN_S0 = 0x0, I2C_PIN_S1 = 0x1, I2C_PIN_S2 = 0x2, I2C_PIN_S3 = 0x3, //Only valid for I2C0 and I2C3 }I2C_PINMUX, *PI2C_PINMUX; // I2C module status typedef enum _I2C_MODULE_STATUS_ { I2C_DISABLE = 0x0, I2C_ENABLE = 0x1, }I2C_MODULE_STATUS, *PI2C_MODULE_STATUS; // I2C device status typedef enum _I2C_Device_STATUS_ { I2C_STS_UNINITIAL = 0x00, I2C_STS_INITIALIZED = 0x01, I2C_STS_IDLE = 0x02, I2C_STS_TX_READY = 0x03, I2C_STS_TX_ING = 0x04, I2C_STS_RX_READY = 0x05, I2C_STS_RX_ING = 0x06, I2C_STS_ERROR = 0x10, I2C_STS_TIMEOUT = 0x11, }I2C_Device_STATUS, *PI2C_Device_STATUS; // I2C feature status typedef enum _I2C_FEATURE_STATUS_{ I2C_FEATURE_DISABLED = 0, I2C_FEATURE_ENABLED = 1, }I2C_FEATURE_STATUS,*PI2C_FEATURE_STATUS; // I2C device mode typedef enum _I2C_DEV_MODE_ { I2C_SLAVE_MODE = 0x0, I2C_MASTER_MODE = 0x1, }I2C_DEV_MODE, *PI2C_DEV_MODE; // I2C Bus Transmit/Receive typedef enum _I2C_DIRECTION_ { I2C_ONLY_TX = 0x1, I2C_ONLY_RX = 0x2, I2C_TXRX = 0x3, }I2C_DIRECTION, *PI2C_DIRECTION; //I2C DMA module number typedef enum _I2C_DMA_MODULE_SEL_ { I2C_DMA_MODULE_0 = 0x0, I2C_DMA_MODULE_1 = 0x1 }I2C_DMA_MODULE_SEL, *PI2C_DMA_MODULE_SEL; // I2C0 DMA peripheral number typedef enum _I2C0_DMA_PERI_NUM_ { I2C0_DMA_TX_NUM = 0x8, I2C0_DMA_RX_NUM = 0x9, }I2C0_DMA_PERI_NUM,*PI2C0_DMA_PERI_NUM; // I2C1 DMA peripheral number typedef enum _I2C1_DMA_PERI_NUM_ { I2C1_DMA_TX_NUM = 0xA, I2C1_DMA_RX_NUM = 0xB, }I2C1_DMA_PERI_NUM,*PI2C1_DMA_PERI_NUM; // I2C0 DMA module used typedef enum _I2C0_DMA_MODULE_ { I2C0_DMA0 = 0x0, I2C0_DMA1 = 0x1, }I2C0_DMA_MODULE,*PI2C0_DMA_MODULE; // I2C0 DMA module used typedef enum _I2C1_DMA_MODULE_ { I2C1_DMA0 = 0x0, I2C1_DMA1 = 0x1, }I2C1_DMA_MODULE,*PI2C1_DMA_MODULE; // I2C command type typedef enum _I2C_COMMAND_TYPE_ { I2C_WRITE_CMD = 0x0, I2C_READ_CMD = 0x1, }I2C_COMMAND_TYPE,*PI2C_COMMAND_TYPE; // I2C STOP BIT typedef enum _I2C_STOP_TYPE_ { I2C_STOP_DIS = 0x0, I2C_STOP_EN = 0x1, }I2C_STOP_TYPE, *PI2C_STOP_TYPE; // I2C error type typedef enum _I2C_ERR_TYPE_ { I2C_ERR_RX_UNDER = 0x01, //I2C RX FIFO Underflow I2C_ERR_RX_OVER = 0x02, //I2C RX FIFO Overflow I2C_ERR_TX_OVER = 0x04, //I2C TX FIFO Overflow I2C_ERR_TX_ABRT = 0x08, //I2C TX terminated I2C_ERR_SLV_TX_NACK = 0x10, //I2C slave transmission terminated by master NACK, //but there are data in slave TX FIFO I2C_ERR_MST_A_NACK = 0x12, I2C_ERR_MST_D_NACK = 0x13, I2C_ERR_USER_REG_TO = 0x20, I2C_ERR_RX_CMD_TO = 0x21, I2C_ERR_RX_FF_TO = 0x22, I2C_ERR_TX_CMD_TO = 0x23, I2C_ERR_TX_FF_TO = 0x24, I2C_ERR_TX_ADD_TO = 0x25, I2C_ERR_RX_ADD_TO = 0x26, }I2C_ERR_TYPE, *PI2C_ERR_TYPE; // I2C Time Out type typedef enum _I2C_TIMEOUT_TYPE_ { I2C_TIMEOOUT_DISABLE = 0x00, I2C_TIMEOOUT_ENDLESS = -1 // 0xFFFFFFFF, }I2C_TIMEOUT_TYPE, *PI2C_TIMEOUT_TYPE; //====================================================== // SAL I2C related data structures // I2C user callback adapter typedef struct _SAL_I2C_USERCB_ADPT_ { VOID (*USERCB) (VOID *Data); u32 USERData; }SAL_I2C_USERCB_ADPT, *PSAL_I2C_USERCB_ADPT; // I2C user callback structure typedef struct _SAL_I2C_USER_CB_ { PSAL_I2C_USERCB_ADPT pTXCB; //I2C Transmit Callback PSAL_I2C_USERCB_ADPT pTXCCB; //I2C Transmit Complete Callback PSAL_I2C_USERCB_ADPT pRXCB; //I2C Receive Callback PSAL_I2C_USERCB_ADPT pRXCCB; //I2C Receive Complete Callback PSAL_I2C_USERCB_ADPT pRDREQCB; //I2C Read Request Callback PSAL_I2C_USERCB_ADPT pERRCB; //I2C Error Callback PSAL_I2C_USERCB_ADPT pDMATXCB; //I2C DMA Transmit Callback PSAL_I2C_USERCB_ADPT pDMATXCCB; //I2C DMA Transmit Complete Callback PSAL_I2C_USERCB_ADPT pDMARXCB; //I2C DMA Receive Callback PSAL_I2C_USERCB_ADPT pDMARXCCB; //I2C DMA Receive Complete Callback PSAL_I2C_USERCB_ADPT pGENCALLCB; //I2C General Call Callback }SAL_I2C_USER_CB, *PSAL_I2C_USER_CB; // I2C Transmit Buffer typedef struct _SAL_I2C_TRANSFER_BUF_ { u16 DataLen; //I2C Transmfer Length u16 TargetAddr; //I2C Target Address. It's only valid in Master Mode. u32 RegAddr; //I2C Register Address. It's only valid in Master Mode. u32 RSVD; // u8 *pDataBuf; //I2C Transfer Buffer Pointer }SAL_I2C_TRANSFER_BUF,*PSAL_I2C_TRANSFER_BUF; typedef struct _SAL_I2C_DMA_USER_DEF_ { u8 TxDatSrcWdth; u8 TxDatDstWdth; u8 TxDatSrcBstSz; u8 TxDatDstBstSz; u8 TxChNo; u8 RSVD0; u16 RSVD1; u8 RxDatSrcWdth; u8 RxDatDstWdth; u8 RxDatSrcBstSz; u8 RxDatDstBstSz; u8 RxChNo; u8 RSVD2; u16 RSVD3; }SAL_I2C_DMA_USER_DEF, *PSAL_I2C_DMA_USER_DEF; // RTK I2C OP typedef struct _RTK_I2C_OP_ { HAL_Status (*Init) (VOID *Data); HAL_Status (*DeInit) (VOID *Data); HAL_Status (*Send) (VOID *Data); HAL_Status (*Receive) (VOID *Data); HAL_Status (*IoCtrl) (VOID *Data); HAL_Status (*PowerCtrl) (VOID *Data); }RTK_I2C_OP, *PRTK_I2C_OP; // Software API Level I2C Handler typedef struct _SAL_I2C_HND_ { u8 DevNum; //I2C device number u8 PinMux; //I2C pin mux seletion u8 OpType; //I2C operation type selection volatile u8 DevSts; //I2C device status u8 I2CMaster; //I2C Master or Slave mode u8 I2CAddrMod; //I2C 7-bit or 10-bit mode u8 I2CSpdMod; //I2C SS/ FS/ HS speed mode u8 I2CAckAddr; //I2C target address in Master //mode or ack address in Slave //mode u16 I2CClk; //I2C bus clock u8 MasterRead; //I2C Master Read Supported, //An Address will be sent before //read data back. u8 I2CDmaSel; //I2C DMA module select // 0 for DMA0, // 1 for DMA1 u8 I2CTxDMARqLv; //I2C TX DMA Empty Level u8 I2CRxDMARqLv; //I2C RX DMA Full Level u16 RSVD0; //Reserved u32 AddRtyTimeOut; //I2C TimeOut Value for master send address retry //(Originally Reserved.) u32 I2CExd; //I2C extended options: //bit 0: I2C RESTART supported, // 0 for NOT supported, // 1 for supported //bit 1: I2C General Call supported // 0 for NOT supported, // 1 for supported //bit 2: I2C START Byte supported // 0 for NOT supported, // 1 for supported //bit 3: I2C Slave-No-Ack // supported // 0 for NOT supported, // 1 for supported //bit 4: I2C bus loading, // 0 for 100pf, // 1 for 400pf //bit 5: I2C slave ack to General // Call //bit 6: I2C User register address //bit 7: I2C 2-Byte User register // address //bit 8: I2C slave address no ack retry, // It's only for Master mode, // when slave doesn't ack the // address //bit 31~bit 8: Reserved u32 ErrType; // u32 TimeOut; //I2C IO Timeout count, in ms PHAL_I2C_INIT_DAT pInitDat; //Pointer to I2C initial data struct PSAL_I2C_TRANSFER_BUF pTXBuf; //Pointer to I2C TX buffer PSAL_I2C_TRANSFER_BUF pRXBuf; //Pointer to I2C RX buffer PSAL_I2C_USER_CB pUserCB; //Pointer to I2C User Callback PSAL_I2C_DMA_USER_DEF pDMAConf; //Pointer to I2C User Define DMA config }SAL_I2C_HND, *PSAL_I2C_HND; //====================================================== // I2C SAL Function Prototypes // For checking I2C input index valid or not static inline HAL_Status RtkI2CIdxChk( IN u8 I2CIdx ) { if (I2CIdx > I2C3_SEL) return HAL_ERR_UNKNOWN; return HAL_OK; } #if 0 //For checking I2C operation type valid or not static inline HAL_Status RtkI2COpTypeChk( IN VOID *Data ) { PSAL_I2C_HND pSalI2CHND = (PSAL_I2C_HND) Data; if (pSalI2CHND->OpType == I2C_POLL_TYPE) return HAL_ERR_UNKNOWN; if (pSalI2CHND->OpType == I2C_DMA_TYPE) return HAL_ERR_UNKNOWN; if (pSalI2CHND->OpType == I2C_INTR_TYPE) return HAL_ERR_UNKNOWN; pSalI2CHND = pSalI2CHND; return HAL_OK; } #endif //For checking I2C DMA available or not static inline HAL_Status RtkI2CDMAChk( IN VOID *Data ) { PSAL_I2C_HND pSalI2CHND = (PSAL_I2C_HND) Data; if (pSalI2CHND->OpType == I2C_DMA_TYPE) { if (pSalI2CHND->DevNum >= I2C2_SEL) return HAL_ERR_UNKNOWN; } else { return HAL_ERR_UNKNOWN; } return HAL_OK; } //For checking I2C DMA available or not static inline HAL_Status RtkI2CDMAInitChk( IN VOID *Data ) { PSAL_I2C_HND pSalI2CHND = (PSAL_I2C_HND) Data; if (pSalI2CHND->OpType != I2C_DMA_TYPE) { return HAL_ERR_UNKNOWN; } else { return HAL_OK; } } //====================================================== //SAL I2C management function prototype _LONG_CALL_ROM_ HAL_Status RtkI2CLoadDefault(IN VOID *Data); _LONG_CALL_ROM_ HAL_Status RtkI2CInit(IN VOID *Data); _LONG_CALL_ROM_ HAL_Status RtkI2CDeInit(IN VOID *Data); _LONG_CALL_ROM_ HAL_Status RtkI2CSend(IN VOID *Data); _LONG_CALL_ROM_ HAL_Status RtkI2CReceive(IN VOID *Data); _LONG_CALL_ROM_ VOID RtkSalI2COpInit(IN VOID *Data); _LONG_CALL_ROM_ HAL_Status RtkI2CSendUserAddr(IN VOID *Data,IN u8 MtrWr); _LONG_CALL_ROM_ HAL_Status RtkI2CIoCtrl(IN VOID *Data); _LONG_CALL_ROM_ HAL_Status RtkI2CPowerCtrl(IN VOID *Data); _LONG_CALL_ HAL_Status RtkI2CInitForPS(IN VOID *Data); _LONG_CALL_ HAL_Status RtkI2CDeInitForPS(IN VOID *Data); _LONG_CALL_ HAL_Status RtkI2CDisablePS(IN VOID *Data); _LONG_CALL_ HAL_Status RtkI2CEnablePS(IN VOID *Data); //================= I2C SAL END =========================== //================= I2C SAL MANAGEMENT START ================= // I2C SAL management macros #define SAL_USER_CB_NUM (sizeof(SAL_I2C_USER_CB) / sizeof(PSAL_I2C_USERCB_ADPT)) //====================================================== // I2C SAL management data structures // I2C SAL handle private typedef struct _SAL_I2C_HND_PRIV_ { VOID **ppSalI2CHnd; //Pointer to SAL_I2C_HND pointer SAL_I2C_HND SalI2CHndPriv; //Private SAL_I2C_HND }SAL_I2C_HND_PRIV, *PSAL_I2C_HND_PRIV; //I2C SAL management adapter typedef struct _SAL_I2C_MNGT_ADPT_ { PSAL_I2C_HND_PRIV pSalHndPriv; //Pointer to SAL_I2C_HND PHAL_I2C_INIT_DAT pHalInitDat; //Pointer to HAL I2C initial data( HAL_I2C_INIT_DAT ) PHAL_I2C_OP pHalOp; //Pointer to HAL I2C operation( HAL_I2C_OP ) VOID (*pHalOpInit)(VOID*); //Pointer to HAL I2C initialize function PIRQ_HANDLE pIrqHnd; //Pointer to IRQ handler in SAL layer( IRQ_HANDLE ) PSAL_I2C_USER_CB pUserCB; //Pointer to SAL user callbacks (SAL_I2C_USER_CB ) volatile u32 MstRDCmdCnt; //Used for Master Read command count volatile u32 InnerTimeOut; //Used for SAL internal timeout count VOID (*pSalIrqFunc)(VOID*); //Used for SAL I2C interrupt function PSAL_I2C_DMA_USER_DEF pDMAConf; //Pointer to I2C User Define DMA config PHAL_GDMA_ADAPTER pHalTxGdmaAdp; //Pointer to HAL_GDMA_ADAPTER PHAL_GDMA_ADAPTER pHalRxGdmaAdp; //Pointer to HAL_GDMA_ADAPTER PHAL_GDMA_OP pHalGdmaOp; //Pointer to HAL_GDMA_OP VOID (*pHalGdmaOpInit)(VOID*); //Pointer to HAL I2C initialize function PIRQ_HANDLE pIrqTxGdmaHnd; //Pointer to IRQ handler for Tx GDMA PIRQ_HANDLE pIrqRxGdmaHnd; //Pointer to IRQ handler for Rx GDMA VOID (*pSalDMATxIrqFunc)(VOID*); //Used for SAL I2C interrupt function VOID (*pSalDMARxIrqFunc)(VOID*); //Used for SAL I2C interrupt function u32 RSVD; //Reserved }SAL_I2C_MNGT_ADPT, *PSAL_I2C_MNGT_ADPT; //====================================================== //SAL I2C management function prototype PSAL_I2C_MNGT_ADPT RtkI2CGetMngtAdpt(IN u8 I2CIdx); HAL_Status RtkI2CFreeMngtAdpt(IN PSAL_I2C_MNGT_ADPT pSalI2CMngtAdpt); PSAL_I2C_HND RtkI2CGetSalHnd(IN u8 I2CIdx); HAL_Status RtkI2CFreeSalHnd(IN PSAL_I2C_HND pSalI2CHND); u32 RtkSalI2CSts(IN VOID *Data); extern _LONG_CALL_ VOID I2CISRHandle(IN VOID *Data); extern _LONG_CALL_ VOID I2CTXGDMAISRHandle(IN VOID *Data); extern _LONG_CALL_ VOID I2CRXGDMAISRHandle(IN VOID *Data); extern HAL_Status I2CIsTimeout (IN u32 StartCount, IN u32 TimeoutCnt); extern HAL_TIMER_OP HalTimerOp; //====================================================== // Function Prototypes _LONG_CALL_ VOID HalI2COpInit(IN VOID *Data); //================= I2C SAL MANAGEMENT END ================== //================= Rtl8195a I2C V02 function prototype ============ _LONG_CALL_ VOID HalI2COpInitV02(IN VOID *Data); _LONG_CALL_ VOID I2CISRHandleV02(IN VOID *Data); _LONG_CALL_ HAL_Status RtkI2CSendV02(IN VOID *Data); _LONG_CALL_ HAL_Status RtkI2CReceiveV02(IN VOID *Data); _LONG_CALL_ VOID RtkSalI2COpInitV02(IN VOID *Data); //================= Rtl8195a I2C V02 function prototype END========== //================= Rtl8195a I2C V04 function prototype ============ _LONG_CALL_ VOID HalI2COpInit_V04(IN VOID *Data); _LONG_CALL_ VOID I2CISRHandle_V04(IN VOID *Data); //================= Rtl8195a I2C V04 function prototype END========== //====================================================== //SAL I2C patch function prototype HAL_Status RtkI2CSend_Patch(IN VOID *Data); HAL_Status RtkI2CReceive_Patch(IN VOID *Data); VOID HalI2COpInit_Patch(IN VOID *Data); VOID I2CISRHandle_Patch(IN VOID *Data); #ifndef CONFIG_RELEASE_BUILD_LIBRARIES #define RtkI2CSend RtkI2CSend_Patch #define RtkI2CReceive RtkI2CReceive_Patch #endif HAL_Status RtkI2CSend_Patch(IN VOID *Data); HAL_Status RtkI2CReceive_Patch(IN VOID *Data); //================= I2C SAL END =========================== #endif //#ifndef _HAL_I2C_H_