/**************************************************************************//** * @file i2c.c * @version V3.00 * @brief NUC980 series I2C driver source file * * SPDX-License-Identifier: Apache-2.0 * @copyright (C) 2016 Nuvoton Technology Corp. All rights reserved. *****************************************************************************/ #include "nu_i2c.h" #include "nu_sys.h" /** @addtogroup Standard_Driver Standard Driver @{ */ /** @addtogroup I2C_Driver I2C Driver @{ */ /** @addtogroup I2C_EXPORTED_FUNCTIONS I2C Exported Functions @{ */ /** * @brief Enable specify I2C Controller and set Clock Divider * * @param[in] i2c Specify I2C port * @param[in] u32BusClock The target I2C bus clock in Hz * * @return Actual I2C bus clock frequency * * @details The function enable the specify I2C Controller and set proper Clock Divider * in I2C CLOCK DIVIDED REGISTER (I2CLK) according to the target I2C Bus clock. * I2C Bus clock = PCLK / (4*(divider+1). * */ uint32_t I2C_Open(I2C_T *i2c, uint32_t u32BusClock) { uint32_t u32Div; uint32_t u32Pclk; u32Pclk = (sysGetClock(SYS_PCLK01)) * 1000000; u32Div = (uint32_t)(((u32Pclk * 10U) / (u32BusClock * 4U) + 5U) / 10U - 1U); /* Compute proper divider for I2C clock */ i2c->CLKDIV = u32Div; /* Enable I2C */ i2c->CTL0 |= I2C_CTL0_I2CEN_Msk; return (u32Pclk / ((u32Div + 1U) << 2U)); } /** * @brief Disable specify I2C Controller * * @param[in] i2c Specify I2C port * * @return None * * @details Reset I2C Controller and disable specify I2C port. * */ void I2C_Close(I2C_T *i2c) { /* Reset I2C Controller */ if ((uint32_t)i2c == I2C0_BA) { outp32(REG_SYS_APBIPRST1, inpw(REG_SYS_APBIPRST1) | (0x1 << 0)); outp32(REG_SYS_APBIPRST1, inpw(REG_SYS_APBIPRST1) & ~(0x1 << 0)); } else if ((uint32_t)i2c == I2C1_BA) { outp32(REG_SYS_APBIPRST1, inpw(REG_SYS_APBIPRST1) | (0x1 << 1)); outp32(REG_SYS_APBIPRST1, inpw(REG_SYS_APBIPRST1) & ~(0x1 << 1)); } else if ((uint32_t)i2c == I2C2_BA) { outp32(REG_SYS_APBIPRST1, inpw(REG_SYS_APBIPRST1) | (0x1 << 2)); outp32(REG_SYS_APBIPRST1, inpw(REG_SYS_APBIPRST1) & ~(0x1 << 2)); } else if ((uint32_t)i2c == I2C3_BA) { outp32(REG_SYS_APBIPRST1, inpw(REG_SYS_APBIPRST1) | (0x1 << 3)); outp32(REG_SYS_APBIPRST1, inpw(REG_SYS_APBIPRST1) & ~(0x1 << 3)); } /* Disable I2C */ i2c->CTL0 &= ~I2C_CTL0_I2CEN_Msk; } /** * @brief Clear Time-out Counter flag * * @param[in] i2c Specify I2C port * * @return None * * @details When Time-out flag will be set, use this function to clear I2C Bus Time-out counter flag . * */ void I2C_ClearTimeoutFlag(I2C_T *i2c) { i2c->TOCTL |= I2C_TOCTL_TOIF_Msk; } /** * @brief Set Control bit of I2C Controller * * @param[in] i2c Specify I2C port * @param[in] u8Start Set I2C START condition * @param[in] u8Stop Set I2C STOP condition * @param[in] u8Si Clear SI flag * @param[in] u8Ack Set I2C ACK bit * * @return None * * @details The function set I2C Control bit of I2C Bus protocol. * */ void I2C_Trigger(I2C_T *i2c, uint8_t u8Start, uint8_t u8Stop, uint8_t u8Si, uint8_t u8Ack) { uint32_t u32Reg = 0U; if (u8Start) { u32Reg |= I2C_CTL_STA; } if (u8Stop) { u32Reg |= I2C_CTL_STO; } if (u8Si) { u32Reg |= I2C_CTL_SI; } if (u8Ack) { u32Reg |= I2C_CTL_AA; } i2c->CTL0 = (i2c->CTL0 & ~0x3CU) | u32Reg; } /** * @brief Disable Interrupt of I2C Controller * * @param[in] i2c Specify I2C port * * @return None * * @details The function is used for disable I2C interrupt * */ void I2C_DisableInt(I2C_T *i2c) { i2c->CTL0 &= ~I2C_CTL0_INTEN_Msk; } /** * @brief Enable Interrupt of I2C Controller * * @param[in] i2c Specify I2C port * * @return None * * @details The function is used for enable I2C interrupt * */ void I2C_EnableInt(I2C_T *i2c) { i2c->CTL0 |= I2C_CTL0_INTEN_Msk; } /** * @brief Get I2C Bus Clock * * @param[in] i2c Specify I2C port * * @return The actual I2C Bus clock in Hz * * @details To get the actual I2C Bus Clock frequency. */ uint32_t I2C_GetBusClockFreq(I2C_T *i2c) { uint32_t u32Divider = i2c->CLKDIV; uint32_t u32Pclk; u32Pclk = (sysGetClock(SYS_PCLK01)) * 1000000; return (u32Pclk / ((u32Divider + 1U) << 2U)); } /** * @brief Set I2C Bus Clock * * @param[in] i2c Specify I2C port * @param[in] u32BusClock The target I2C Bus Clock in Hz * * @return The actual I2C Bus Clock in Hz * * @details To set the actual I2C Bus Clock frequency. */ uint32_t I2C_SetBusClockFreq(I2C_T *i2c, uint32_t u32BusClock) { uint32_t u32Div; uint32_t u32Pclk; u32Pclk = (sysGetClock(SYS_PCLK01)) * 1000000; u32Div = (uint32_t)(((u32Pclk * 10U) / (u32BusClock * 4U) + 5U) / 10U - 1U); /* Compute proper divider for I2C clock */ i2c->CLKDIV = u32Div; return (u32Pclk / ((u32Div + 1U) << 2U)); } /** * @brief Get Interrupt Flag * * @param[in] i2c Specify I2C port * * @return I2C interrupt flag status * * @details To get I2C Bus interrupt flag. */ uint32_t I2C_GetIntFlag(I2C_T *i2c) { uint32_t u32Value; if ((i2c->CTL0 & I2C_CTL0_SI_Msk) == I2C_CTL0_SI_Msk) { u32Value = 1U; } else { u32Value = 0U; } return u32Value; } /** * @brief Get I2C Bus Status Code * * @param[in] i2c Specify I2C port * * @return I2C Status Code * * @details To get I2C Bus Status Code. */ uint32_t I2C_GetStatus(I2C_T *i2c) { return (i2c->STATUS0); } /** * @brief Read a Byte from I2C Bus * * @param[in] i2c Specify I2C port * * @return I2C Data * * @details To read a bytes data from specify I2C port. */ uint8_t I2C_GetData(I2C_T *i2c) { return (uint8_t)(i2c->DAT); } /** * @brief Send a byte to I2C Bus * * @param[in] i2c Specify I2C port * @param[in] u8Data The data to send to I2C bus * * @return None * * @details This function is used to write a byte to specified I2C port */ void I2C_SetData(I2C_T *i2c, uint8_t u8Data) { i2c->DAT = u8Data; } /** * @brief Set 7-bit Slave Address and GC Mode * * @param[in] i2c Specify I2C port * @param[in] u8SlaveNo Set the number of I2C address register (0~3) * @param[in] u8SlaveAddr 7-bit slave address * @param[in] u8GCMode Enable/Disable GC mode (I2C_GCMODE_ENABLE / I2C_GCMODE_DISABLE) * * @return None * * @details This function is used to set 7-bit slave addresses in I2C SLAVE ADDRESS REGISTER (I2CADDR0~3) * and enable GC Mode. * */ void I2C_SetSlaveAddr(I2C_T *i2c, uint8_t u8SlaveNo, uint8_t u8SlaveAddr, uint8_t u8GCMode) { switch (u8SlaveNo) { case 1: i2c->ADDR1 = ((uint32_t)u8SlaveAddr << 1U) | u8GCMode; break; case 2: i2c->ADDR2 = ((uint32_t)u8SlaveAddr << 1U) | u8GCMode; break; case 3: i2c->ADDR3 = ((uint32_t)u8SlaveAddr << 1U) | u8GCMode; break; case 0: default: i2c->ADDR0 = ((uint32_t)u8SlaveAddr << 1U) | u8GCMode; break; } } /** * @brief Configure the mask bits of 7-bit Slave Address * * @param[in] i2c Specify I2C port * @param[in] u8SlaveNo Set the number of I2C address mask register (0~3) * @param[in] u8SlaveAddrMask A byte for slave address mask * * @return None * * @details This function is used to set 7-bit slave addresses. * */ void I2C_SetSlaveAddrMask(I2C_T *i2c, uint8_t u8SlaveNo, uint8_t u8SlaveAddrMask) { switch (u8SlaveNo) { case 1: i2c->ADDRMSK1 = (uint32_t)u8SlaveAddrMask << 1U; break; case 2: i2c->ADDRMSK2 = (uint32_t)u8SlaveAddrMask << 1U; break; case 3: i2c->ADDRMSK3 = (uint32_t)u8SlaveAddrMask << 1U; break; case 0: default: i2c->ADDRMSK0 = (uint32_t)u8SlaveAddrMask << 1U; break; } } /** * @brief Enable Time-out Counter Function and support Long Time-out * * @param[in] i2c Specify I2C port * @param[in] u8LongTimeout Configure DIV4 to enable Long Time-out (0/1) * * @return None * * @details This function enable Time-out Counter function and configure DIV4 to support Long * Time-out. * */ void I2C_EnableTimeout(I2C_T *i2c, uint8_t u8LongTimeout) { if (u8LongTimeout) { i2c->TOCTL |= I2C_TOCTL_TOCDIV4_Msk; } else { i2c->TOCTL &= ~I2C_TOCTL_TOCDIV4_Msk; } i2c->TOCTL |= I2C_TOCTL_TOCEN_Msk; } /** * @brief Disable Time-out Counter Function * * @param[in] i2c Specify I2C port * * @return None * * @details To disable Time-out Counter function in I2CTOC register. * */ void I2C_DisableTimeout(I2C_T *i2c) { i2c->TOCTL &= ~I2C_TOCTL_TOCEN_Msk; } /** * @brief Enable I2C Wake-up Function * * @param[in] i2c Specify I2C port * * @return None * * @details To enable Wake-up function of I2C Wake-up control register. * */ void I2C_EnableWakeup(I2C_T *i2c) { i2c->WKCTL |= I2C_WKCTL_WKEN_Msk; } /** * @brief Disable I2C Wake-up Function * * @param[in] i2c Specify I2C port * * @return None * * @details To disable Wake-up function of I2C Wake-up control register. * */ void I2C_DisableWakeup(I2C_T *i2c) { i2c->WKCTL &= ~I2C_WKCTL_WKEN_Msk; } /** * @brief Write a byte to Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] data Write a byte data to Slave * * @retval 0 Write data success * @retval 1 Write data fail, or bus occurs error events * * @details The function is used for I2C Master write a byte data to Slave. * */ uint8_t I2C_WriteByte(I2C_T *i2c, uint8_t u8SlaveAddr, uint8_t data) { uint8_t u8Xfering = 1u, u8Err = 0u, u8Ctrl = 0u; I2C_START(i2c); while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Write SLA+W to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x18u: /* Slave Address ACK */ I2C_SET_DATA(i2c, data); /* Write data to I2CDAT */ break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x28u: u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } return (u8Err | u8Xfering); /* return (Success)/(Fail) status */ } /** * @brief Write multi bytes to Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] *data Pointer to array to write data to Slave * @param[in] u32wLen How many bytes need to write to Slave * * @return A length of how many bytes have been transmitted. * * @details The function is used for I2C Master write multi bytes data to Slave. * */ uint32_t I2C_WriteMultiBytes(I2C_T *i2c, uint8_t u8SlaveAddr, uint8_t data[], uint32_t u32wLen) { uint8_t u8Xfering = 1u, u8Err = 0u, u8Ctrl = 0u; uint32_t u32txLen = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Write SLA+W to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x18u: /* Slave Address ACK */ case 0x28u: if (u32txLen < u32wLen) { I2C_SET_DATA(i2c, data[u32txLen++]); /* Write Data to I2CDAT */ } else { u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; } break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } return u32txLen; /* Return bytes length that have been transmitted */ } /** * @brief Specify a byte register address and write a byte to Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] u8DataAddr Specify a address (1 byte) of data write to * @param[in] data A byte data to write it to Slave * * @retval 0 Write data success * @retval 1 Write data fail, or bus occurs error events * * @details The function is used for I2C Master specify a address that data write to in Slave. * */ uint8_t I2C_WriteByteOneReg(I2C_T *i2c, uint8_t u8SlaveAddr, uint8_t u8DataAddr, uint8_t data) { uint8_t u8Xfering = 1u, u8Err = 0u, u8Ctrl = 0u; uint32_t u32txLen = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Send Slave address with write bit */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x18u: /* Slave Address ACK */ I2C_SET_DATA(i2c, u8DataAddr); /* Write Lo byte address of register */ break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x28u: if (u32txLen < 1u) { I2C_SET_DATA(i2c, data); u32txLen++; } else { u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; } break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } return (u8Err | u8Xfering); /* return (Success)/(Fail) status */ } /** * @brief Specify a byte register address and write multi bytes to Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] u8DataAddr Specify a address (1 byte) of data write to * @param[in] *data Pointer to array to write data to Slave * @param[in] u32wLen How many bytes need to write to Slave * * @return A length of how many bytes have been transmitted. * * @details The function is used for I2C Master specify a byte address that multi data bytes write to in Slave. * */ uint32_t I2C_WriteMultiBytesOneReg(I2C_T *i2c, uint8_t u8SlaveAddr, uint8_t u8DataAddr, uint8_t data[], uint32_t u32wLen) { uint8_t u8Xfering = 1u, u8Err = 0u, u8Ctrl = 0u; uint32_t u32txLen = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Write SLA+W to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; break; case 0x18u: /* Slave Address ACK */ I2C_SET_DATA(i2c, u8DataAddr); /* Write Lo byte address of register */ break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x28u: if (u32txLen < u32wLen) { I2C_SET_DATA(i2c, data[u32txLen++]); } else { u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; } break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } return u32txLen; /* Return bytes length that have been transmitted */ } /** * @brief Specify two bytes register address and Write a byte to Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] u16DataAddr Specify a address (2 byte) of data write to * @param[in] data Write a byte data to Slave * * @retval 0 Write data success * @retval 1 Write data fail, or bus occurs error events * * @details The function is used for I2C Master specify two bytes address that data write to in Slave. * */ uint8_t I2C_WriteByteTwoRegs(I2C_T *i2c, uint8_t u8SlaveAddr, uint16_t u16DataAddr, uint8_t data) { uint8_t u8Xfering = 1u, u8Err = 0u, u8Addr = 1u, u8Ctrl = 0u; uint32_t u32txLen = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Write SLA+W to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x18u: /* Slave Address ACK */ I2C_SET_DATA(i2c, (uint8_t)((u16DataAddr & 0xFF00u) >> 8u)); /* Write Hi byte address of register */ break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x28u: if (u8Addr) { I2C_SET_DATA(i2c, (uint8_t)(u16DataAddr & 0xFFu)); /* Write Lo byte address of register */ u8Addr = 0u; } else if ((u32txLen < 1u) && (u8Addr == 0u)) { I2C_SET_DATA(i2c, data); u32txLen++; } else { u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; } break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } return (u8Err | u8Xfering); /* return (Success)/(Fail) status */ } /** * @brief Specify two bytes register address and write multi bytes to Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] u16DataAddr Specify a address (2 bytes) of data write to * @param[in] data[] A data array for write data to Slave * @param[in] u32wLen How many bytes need to write to Slave * * @return A length of how many bytes have been transmitted. * * @details The function is used for I2C Master specify a byte address that multi data write to in Slave. * */ uint32_t I2C_WriteMultiBytesTwoRegs(I2C_T *i2c, uint8_t u8SlaveAddr, uint16_t u16DataAddr, uint8_t data[], uint32_t u32wLen) { uint8_t u8Xfering = 1u, u8Err = 0u, u8Addr = 1u, u8Ctrl = 0u; uint32_t u32txLen = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Write SLA+W to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x18u: /* Slave Address ACK */ I2C_SET_DATA(i2c, (uint8_t)((u16DataAddr & 0xFF00u) >> 8u)); /* Write Hi byte address of register */ break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x28u: if (u8Addr) { I2C_SET_DATA(i2c, (uint8_t)(u16DataAddr & 0xFFu)); /* Write Lo byte address of register */ u8Addr = 0u; } else if ((u32txLen < u32wLen) && (u8Addr == 0u)) { I2C_SET_DATA(i2c, data[u32txLen++]); /* Write data to Register I2CDAT*/ } else { u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; } break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } return u32txLen; /* Return bytes length that have been transmitted */ } /** * @brief Read a byte from Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * * @return Read a byte data from Slave * * @details The function is used for I2C Master to read a byte data from Slave. * */ uint8_t I2C_ReadByte(I2C_T *i2c, uint8_t u8SlaveAddr) { uint8_t u8Xfering = 1u, u8Err = 0u, rdata = 0u, u8Ctrl = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)((u8SlaveAddr << 1u) | 0x01u)); /* Write SLA+R to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x40u: /* Slave Address ACK */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x48u: /* Slave Address NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x58u: rdata = (unsigned char) I2C_GET_DATA(i2c); /* Receive Data */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } if (u8Err) { rdata = 0u; /* If occurs error, return 0 */ } return rdata; /* Return read data */ } /** * @brief Read multi bytes from Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[out] rdata[] A data array to store data from Slave * @param[in] u32rLen How many bytes need to read from Slave * * @return A length of how many bytes have been received * * @details The function is used for I2C Master to read multi data bytes from Slave. * * */ uint32_t I2C_ReadMultiBytes(I2C_T *i2c, uint8_t u8SlaveAddr, uint8_t rdata[], uint32_t u32rLen) { uint8_t u8Xfering = 1u, u8Err = 0u, u8Ctrl = 0u; uint32_t u32rxLen = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)((u8SlaveAddr << 1u) | 0x01u)); /* Write SLA+R to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x40u: /* Slave Address ACK */ u8Ctrl = I2C_CTL_SI_AA; /* Clear SI and set ACK */ break; case 0x48u: /* Slave Address NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x50u: rdata[u32rxLen++] = (unsigned char) I2C_GET_DATA(i2c); /* Receive Data */ if (u32rxLen < (u32rLen - 1u)) { u8Ctrl = I2C_CTL_SI_AA; /* Clear SI and set ACK */ } else { u8Ctrl = I2C_CTL_SI; /* Clear SI */ } break; case 0x58u: rdata[u32rxLen++] = (unsigned char) I2C_GET_DATA(i2c); /* Receive Data */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } return u32rxLen; /* Return bytes length that have been received */ } /** * @brief Specify a byte register address and read a byte from Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] u8DataAddr Specify a address(1 byte) of data read from * * @return Read a byte data from Slave * * @details The function is used for I2C Master specify a byte address that a data byte read from Slave. * * */ uint8_t I2C_ReadByteOneReg(I2C_T *i2c, uint8_t u8SlaveAddr, uint8_t u8DataAddr) { uint8_t u8Xfering = 1u, u8Err = 0u, rdata = 0u, u8Ctrl = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Write SLA+W to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x18u: /* Slave Address ACK */ I2C_SET_DATA(i2c, u8DataAddr); /* Write Lo byte address of register */ break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x28u: u8Ctrl = I2C_CTL_STA_SI; /* Send repeat START */ break; case 0x10u: I2C_SET_DATA(i2c, (uint8_t)((u8SlaveAddr << 1u) | 0x01u)); /* Write SLA+R to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x40u: /* Slave Address ACK */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x48u: /* Slave Address NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x58u: rdata = (uint8_t) I2C_GET_DATA(i2c); /* Receive Data */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } if (u8Err) { rdata = 0u; /* If occurs error, return 0 */ } return rdata; /* Return read data */ } /** * @brief Specify a byte register address and read multi bytes from Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] u8DataAddr Specify a address (1 bytes) of data read from * @param[out] rdata[] A data array to store data from Slave * @param[in] u32rLen How many bytes need to read from Slave * * @return A length of how many bytes have been received * * @details The function is used for I2C Master specify a byte address that multi data bytes read from Slave. * * */ uint32_t I2C_ReadMultiBytesOneReg(I2C_T *i2c, uint8_t u8SlaveAddr, uint8_t u8DataAddr, uint8_t rdata[], uint32_t u32rLen) { uint8_t u8Xfering = 1u, u8Err = 0u, u8Ctrl = 0u; uint32_t u32rxLen = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Write SLA+W to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x18u: /* Slave Address ACK */ I2C_SET_DATA(i2c, u8DataAddr); /* Write Lo byte address of register */ break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x28u: u8Ctrl = I2C_CTL_STA_SI; /* Send repeat START */ break; case 0x10u: I2C_SET_DATA(i2c, (uint8_t)((u8SlaveAddr << 1u) | 0x01u)); /* Write SLA+R to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x40u: /* Slave Address ACK */ u8Ctrl = I2C_CTL_SI_AA; /* Clear SI and set ACK */ break; case 0x48u: /* Slave Address NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x50u: rdata[u32rxLen++] = (uint8_t) I2C_GET_DATA(i2c); /* Receive Data */ if (u32rxLen < (u32rLen - 1u)) { u8Ctrl = I2C_CTL_SI_AA; /* Clear SI and set ACK */ } else { u8Ctrl = I2C_CTL_SI; /* Clear SI */ } break; case 0x58u: rdata[u32rxLen++] = (uint8_t) I2C_GET_DATA(i2c); /* Receive Data */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } return u32rxLen; /* Return bytes length that have been received */ } /** * @brief Specify two bytes register address and read a byte from Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] u16DataAddr Specify an address(2 bytes) of data read from * * @return Read a byte data from Slave * * @details The function is used for I2C Master specify two bytes address that a data byte read from Slave. * * */ uint8_t I2C_ReadByteTwoRegs(I2C_T *i2c, uint8_t u8SlaveAddr, uint16_t u16DataAddr) { uint8_t u8Xfering = 1u, u8Err = 0u, rdata = 0u, u8Addr = 1u, u8Ctrl = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Write SLA+W to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x18u: /* Slave Address ACK */ I2C_SET_DATA(i2c, (uint8_t)((u16DataAddr & 0xFF00u) >> 8u)); /* Write Hi byte address of register */ break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x28u: if (u8Addr) { I2C_SET_DATA(i2c, (uint8_t)(u16DataAddr & 0xFFu)); /* Write Lo byte address of register */ u8Addr = 0u; } else { u8Ctrl = I2C_CTL_STA_SI; /* Clear SI and send repeat START */ } break; case 0x10u: I2C_SET_DATA(i2c, (uint8_t)((u8SlaveAddr << 1u) | 0x01u)); /* Write SLA+R to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x40u: /* Slave Address ACK */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x48u: /* Slave Address NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x58u: rdata = (unsigned char) I2C_GET_DATA(i2c); /* Receive Data */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } if (u8Err) { rdata = 0u; /* If occurs error, return 0 */ } return rdata; /* Return read data */ } /** * @brief Specify two bytes register address and read multi bytes from Slave * * @param[in] *i2c Point to I2C peripheral * @param[in] u8SlaveAddr Access Slave address(7-bit) * @param[in] u16DataAddr Specify a address (2 bytes) of data read from * @param[out] rdata[] A data array to store data from Slave * @param[in] u32rLen How many bytes need to read from Slave * * @return A length of how many bytes have been received * * @details The function is used for I2C Master specify two bytes address that multi data bytes read from Slave. * * */ uint32_t I2C_ReadMultiBytesTwoRegs(I2C_T *i2c, uint8_t u8SlaveAddr, uint16_t u16DataAddr, uint8_t rdata[], uint32_t u32rLen) { uint8_t u8Xfering = 1u, u8Err = 0u, u8Addr = 1u, u8Ctrl = 0u; uint32_t u32rxLen = 0u; I2C_START(i2c); /* Send START */ while (u8Xfering && (u8Err == 0u)) { I2C_WAIT_READY(i2c) {} switch (I2C_GET_STATUS(i2c)) { case 0x08u: I2C_SET_DATA(i2c, (uint8_t)(u8SlaveAddr << 1u | 0x00u)); /* Write SLA+W to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x18u: /* Slave Address ACK */ I2C_SET_DATA(i2c, (uint8_t)((u16DataAddr & 0xFF00u) >> 8u)); /* Write Hi byte address of register */ break; case 0x20u: /* Slave Address NACK */ case 0x30u: /* Master transmit data NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x28u: if (u8Addr) { I2C_SET_DATA(i2c, (uint8_t)(u16DataAddr & 0xFFu)); /* Write Lo byte address of register */ u8Addr = 0u; } else { u8Ctrl = I2C_CTL_STA_SI; /* Clear SI and send repeat START */ } break; case 0x10u: I2C_SET_DATA(i2c, (uint8_t)((u8SlaveAddr << 1u) | 0x01u)); /* Write SLA+R to Register I2CDAT */ u8Ctrl = I2C_CTL_SI; /* Clear SI */ break; case 0x40u: /* Slave Address ACK */ u8Ctrl = I2C_CTL_SI_AA; /* Clear SI and set ACK */ break; case 0x48u: /* Slave Address NACK */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; case 0x50u: rdata[u32rxLen++] = (unsigned char) I2C_GET_DATA(i2c); /* Receive Data */ if (u32rxLen < (u32rLen - 1u)) { u8Ctrl = I2C_CTL_SI_AA; /* Clear SI and set ACK */ } else { u8Ctrl = I2C_CTL_SI; /* Clear SI */ } break; case 0x58u: rdata[u32rxLen++] = (unsigned char) I2C_GET_DATA(i2c); /* Receive Data */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Xfering = 0u; break; case 0x38u: /* Arbitration Lost */ default: /* Unknow status */ u8Ctrl = I2C_CTL_STO_SI; /* Clear SI and send STOP */ u8Err = 1u; break; } I2C_SET_CONTROL_REG(i2c, u8Ctrl); /* Write controlbit to I2C_CTL register */ } return u32rxLen; /* Return bytes length that have been received */ } /** * @brief The macro is used to set STOP condition of I2C Bus * * @param[in] i2c Specify I2C port * * @return None * * @details Set the I2C bus STOP condition in I2C_CTL register. */ void I2C_STOP(I2C_T *i2c) { (i2c)->CTL0 |= (I2C_CTL0_SI_Msk | I2C_CTL0_STO_Msk); while (i2c->CTL0 & I2C_CTL0_STO_Msk) { } } /*@}*/ /* end of group I2C_EXPORTED_FUNCTIONS */ /*@}*/ /* end of group I2C_Driver */ /*@}*/ /* end of group Standard_Driver */ /*** (C) COPYRIGHT 2016 Nuvoton Technology Corp. ***/