322 lines
7.9 KiB
C
322 lines
7.9 KiB
C
/**
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*****************************************************************************
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* @file cmem7_i2c.c
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*
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* @brief CMEM7 I2C source file
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*
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*
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* @version V1.0
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* @date 3. September 2013
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*
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* @note
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*
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*****************************************************************************
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* @attention
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*
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* THE PRESENT FIRMWARE WHICH IS FOR GUIDANCE ONLY AIMS AT PROVIDING CUSTOMERS
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* WITH CODING INFORMATION REGARDING THEIR PRODUCTS IN ORDER FOR THEM TO SAVE
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* TIME. AS A RESULT, CAPITAL-MICRO SHALL NOT BE HELD LIABLE FOR ANY DIRECT,
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* INDIRECT OR CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING
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* FROM THE CONTENT OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE
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* CODING INFORMATION CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
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*
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* <h2><center>© COPYRIGHT 2013 Capital-micro </center></h2>
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*****************************************************************************
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*/
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#include "cmem7_i2c.h"
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#define I2C_INNER_INT_ALL 0x3FF
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typedef struct {
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union {
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uint32_t DATA_CMD;
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struct {
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uint32_t DATA : 8;
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uint32_t RD_CMD : 1;
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uint32_t WR_CMD : 1;
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uint32_t WR_RD_CMD : 1;
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} DATA_CMD_b;
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} INNER;
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} I2C_INNER_DATA_CMD;
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static uint32_t i2c_GetClock(I2C0_Type* I2Cx) {
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uint32_t dividor;
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if ((uint32_t)I2Cx == (uint32_t)I2C0) {
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dividor = GLOBAL_CTRL->CLK_SEL_0_b.I2C0_CLK;
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} else if ((uint32_t)I2Cx == (uint32_t)I2C1) {
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dividor = GLOBAL_CTRL->CLK_SEL_0_b.I2C1_CLK;
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}
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return SYSTEM_CLOCK_FREQ / (1 << (dividor + 1));
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}
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static uint16_t i2c_NormalizeAddr(I2C0_Type* I2Cx, uint16_t addr) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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if (I2Cx->CTRL_b.MODE == I2C_Mode_Master) {
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if (I2Cx->CTRL_b.MASTER_ADDR_WIDTH == I2C_ADDR_WIDTH_7BIT) {
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addr &= 0x007F;
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} else {
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addr &= 0x3FF;
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}
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}
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if (I2Cx->CTRL_b.MODE == I2C_Mode_Slave) {
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if (I2Cx->CTRL_b.SLAVE_ADDR_WIDTH == I2C_ADDR_WIDTH_7BIT) {
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addr &= 0x007F;
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} else {
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addr &= 0x3FF;
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}
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}
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return addr;
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}
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static void i2c_ReadClear(uint32_t bit) {
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uint32_t tmp;
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tmp = bit;
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tmp = tmp;
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}
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void I2C_Init(I2C0_Type* I2Cx, I2C_InitTypeDef* I2C_Init) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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assert_param(I2C_Init);
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assert_param(IS_I2C_MODE(I2C_Init->I2C_Mode));
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assert_param(IS_I2C_ADDR_WIDTH(I2C_Init->I2C_AddressWidth));
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// reset
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I2Cx->ENABLE_b.RESET = FALSE;
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I2Cx->ENABLE_b.RESET = TRUE;
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// clear interrupt
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I2Cx->INT_MASK = I2C_INNER_INT_ALL;
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i2c_ReadClear(I2Cx->CLR_ALL_INT_b.CLEAR);
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I2Cx->CTRL_b.MODE = I2C_Init->I2C_Mode;
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if (I2Cx->CTRL_b.MODE == I2C_Mode_Master) {
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I2Cx->CTRL_b.MASTER_ADDR_WIDTH = I2C_Init->I2C_AddressWidth;
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I2Cx->TAR_b.START_BYTE = TRUE;
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I2Cx->TAR_b.ADDR10 = i2c_NormalizeAddr(I2Cx, I2C_Init->I2C_Address);
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}
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if (I2Cx->CTRL_b.MODE == I2C_Mode_Slave) {
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I2Cx->CTRL_b.SLAVE_ADDR_WIDTH = I2C_Init->I2C_AddressWidth;
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I2Cx->SAR_b.ADDR10 = i2c_NormalizeAddr(I2Cx, I2C_Init->I2C_Address);
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}
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I2Cx->RX_TL_b.THRESHOLD = 0;
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I2Cx->TX_TL_b.THRESHOLD = 0;
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I2Cx->SLAVE_NACK_b.NACK = FALSE;
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if (I2C_Init->timing) {
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I2Cx->SCL_CNT_b.HIGH_LEVEL_TICK =
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i2c_GetClock(I2Cx) / I2C_Init->timing->I2C_Freq / 2;
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I2Cx->SCL_CNT_b.LOW_LEVEL_TICK =
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i2c_GetClock(I2Cx) / I2C_Init->timing->I2C_Freq / 2;
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I2Cx->SDA_SETUP_b.TSU_DAT = ((uint64_t)I2C_Init->timing->I2C_TsuDat) *
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i2c_GetClock(I2Cx) / 1000000000;
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I2Cx->SDA_SETUP_b.TSETUP = ((uint64_t)I2C_Init->timing->I2C_Tsetup) *
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i2c_GetClock(I2Cx) / 1000000000;
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I2Cx->TSU_STA_SETUP_b.TBUF = ((uint64_t)I2C_Init->timing->I2C_Tbuf) *
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i2c_GetClock(I2Cx) / 1000000000;
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I2Cx->TSU_STA_SETUP_b.TSU_STA = ((uint64_t)I2C_Init->timing->I2C_TsuSta) *
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i2c_GetClock(I2Cx) / 1000000000;
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I2Cx->TSU_STA_SETUP_b.SDA_FILTER_EN = I2C_Init->timing->I2C_SdaFilterEn;
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I2Cx->TSU_STA_SETUP_b.SDA_FILTER_CNT = I2C_Init->timing->I2C_SdaFilterSpike;
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I2Cx->TSU_STA_SETUP_b.SCL_FILTER_EN = I2C_Init->timing->I2C_SclFilterEn;
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I2Cx->TSU_STA_SETUP_b.SCL_FILTER_CNT = I2C_Init->timing->I2C_SclFilterSpike;
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}
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}
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void I2C_Enable(I2C0_Type* I2Cx, BOOL enable) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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I2Cx->ENABLE_b.EN = enable;
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}
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void I2C_EnableInt(I2C0_Type* I2Cx, uint32_t Int, BOOL enable) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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assert_param(IS_I2C_INT(Int));
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if (enable) {
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I2Cx->INT_MASK &= ~Int;
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} else {
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I2Cx->INT_MASK |= Int;
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}
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}
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BOOL I2C_GetIntStatus(I2C0_Type* I2Cx, uint32_t Int) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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assert_param(IS_I2C_INT(Int));
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if (0 != (I2Cx->INT_STATUS & Int)) {
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return TRUE;
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}
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return FALSE;
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}
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void I2C_ClearInt(I2C0_Type* I2Cx, uint32_t Int) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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assert_param(IS_I2C_INT(Int));
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if (Int == I2C_INT_RX_FIFO_NOT_EMPTY) {
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// It can't be clear by sw but read data
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}
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if (Int == I2C_INT_RD_REQUEST) {
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i2c_ReadClear(I2Cx->CLR_RD_REQ_b.CLEAR);
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}
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if (Int == I2C_INT_TX_ABORT) {
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i2c_ReadClear(I2Cx->CLR_TX_ABRT_b.CLEAR);
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}
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if (Int == I2C_INT_RX_DONE) {
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i2c_ReadClear(I2Cx->CLR_RX_DONE_b.CLEAR);
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}
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if (Int == I2C_INT_TX_DONE) {
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i2c_ReadClear(I2Cx->CLR_TX_DONE_b.CLEAR);
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}
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}
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BOOL I2C_GetStatus(I2C0_Type* I2Cx, uint32_t Status) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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assert_param(IS_I2C_STATUS(Status));
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if (0 != (I2Cx->STATUS & Status)) {
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return TRUE;
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}
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return FALSE;
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}
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void I2C_ClearStatus(I2C0_Type* I2Cx, uint32_t Status) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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assert_param(IS_I2C_STATUS(Status));
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if (Status & I2C_STATUS_RX_FIFO_NOT_EMPTY) {
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// It can't be clear by sw but read
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}
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if (Status & I2C_STATUS_RD_REQUEST) {
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i2c_ReadClear(I2Cx->CLR_RD_REQ_b.CLEAR);
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}
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if (Status & I2C_STATUS_TX_ABORT) {
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i2c_ReadClear(I2Cx->CLR_TX_ABRT_b.CLEAR);
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}
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if (Status & I2C_STATUS_RX_DONE) {
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i2c_ReadClear(I2Cx->CLR_RX_DONE_b.CLEAR);
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}
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if (Status & I2C_STATUS_TX_DONE) {
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i2c_ReadClear(I2Cx->CLR_TX_DONE_b.CLEAR);
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}
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}
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BOOL I2C_MasterReadReq(I2C0_Type* I2Cx, uint8_t size) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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if (!I2Cx->ENABLE_b.EN || I2Cx->STATUS_b.BUSY) {
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return FALSE;
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}
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if (I2Cx->CTRL_b.MODE == I2C_Mode_Slave) {
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return FALSE;
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}
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if (size == 0) {
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return FALSE;
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}
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I2Cx->WRITE_READ_CNT_b.RD_BYTE_CNT = size;
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if (size != 0) {
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I2C_INNER_DATA_CMD inner;
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inner.INNER.DATA_CMD_b.DATA = 0;
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inner.INNER.DATA_CMD_b.RD_CMD = TRUE;
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inner.INNER.DATA_CMD_b.WR_CMD = FALSE;
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inner.INNER.DATA_CMD_b.WR_RD_CMD = FALSE;
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I2Cx->DATA_CMD = inner.INNER.DATA_CMD;
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}
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return TRUE;
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}
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uint8_t I2C_ReadFifo(I2C0_Type* I2Cx, uint8_t size, uint8_t* data) {
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uint8_t count;
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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assert_param(data);
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if (!I2Cx->ENABLE_b.EN) {
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return 0;
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}
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count = 0;
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while (I2Cx->STATUS_b.RX_FIFO_NOT_EMPTY && count < size) {
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*(data + count++) = I2Cx->DATA_CMD_b.DATA;
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}
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return count;
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}
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BOOL I2C_WriteReq(I2C0_Type* I2Cx, uint8_t size, uint8_t firstData) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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if (!I2Cx->ENABLE_b.EN || I2Cx->STATUS_b.BUSY) {
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return FALSE;
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}
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if (size == 0) {
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return FALSE;
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}
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I2Cx->WRITE_READ_CNT_b.WR_BYTE_CNT = size;
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if (size != 0) {
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I2C_INNER_DATA_CMD inner;
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inner.INNER.DATA_CMD_b.DATA = firstData ;
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inner.INNER.DATA_CMD_b.RD_CMD = FALSE;
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inner.INNER.DATA_CMD_b.WR_CMD =
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(I2Cx->CTRL_b.MODE == I2C_Mode_Slave) ? FALSE : TRUE;
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inner.INNER.DATA_CMD_b.WR_RD_CMD = FALSE;
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I2Cx->DATA_CMD = inner.INNER.DATA_CMD;
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}
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return TRUE;
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}
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uint8_t I2C_WriteFifo(I2C0_Type* I2Cx, uint8_t size, uint8_t* data) {
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uint8_t count;
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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assert_param(data);
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if (!I2Cx->ENABLE_b.EN) {
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return 0;
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}
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count = 0;
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while (I2Cx->STATUS_b.TX_FIFO_NOT_FULL && count < size) {
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I2Cx->DATA_CMD_b.DATA = *(data + count++);
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}
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return count;
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}
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BOOL I2C_StopReq(I2C0_Type* I2Cx) {
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assert_param(IS_I2C_ALL_PERIPH(I2Cx));
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udelay(600);
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return TRUE;
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}
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