Fork of mbed-dev build 137, last build before FAT file system appears to be broken. Also reduced HSE timeout time in STM4XX HAL
Fork of mbed-dev by
targets/TARGET_Maxim/TARGET_MAX32625/mxc/i2cm.c
- Committer:
- <>
- Date:
- 2016-11-08
- Revision:
- 150:02e0a0aed4ec
File content as of revision 150:02e0a0aed4ec:
/******************************************************************************* * Copyright (C) 2016 Maxim Integrated Products, Inc., All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL MAXIM INTEGRATED BE LIABLE FOR ANY CLAIM, DAMAGES * OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. * * Except as contained in this notice, the name of Maxim Integrated * Products, Inc. shall not be used except as stated in the Maxim Integrated * Products, Inc. Branding Policy. * * The mere transfer of this software does not imply any licenses * of trade secrets, proprietary technology, copyrights, patents, * trademarks, maskwork rights, or any other form of intellectual * property whatsoever. Maxim Integrated Products, Inc. retains all * ownership rights. * * $Date: 2016-06-01 08:51:23 -0500 (Wed, 01 Jun 2016) $ * $Revision: 23131 $ * ******************************************************************************/ /** * @file i2cm.c * @brief I2C Master driver source. */ /***** Includes *****/ #include <string.h> #include <math.h> #include "mxc_assert.h" #include "mxc_lock.h" #include "mxc_errors.h" #include "mxc_sys.h" #include "i2cm.h" /***** Definitions *****/ #ifndef MXC_I2CM_TX_TIMEOUT #define MXC_I2CM_TX_TIMEOUT 0x5000 #endif #ifndef MXC_I2CM_RX_TIMEOUT #define MXC_I2CM_RX_TIMEOUT 0x5000 #endif #define I2CM_READ_BIT 0x0001 #define I2CM_FIFO_DEPTH_3Q ((3 * MXC_I2CM_FIFO_DEPTH) / 4) #define I2CM_FIFO_DEPTH_2Q (MXC_I2CM_FIFO_DEPTH / 2) /***** Globals *****/ // Saves the state of the non-blocking requests typedef enum { I2CM_STATE_READING = 0, I2CM_STATE_WRITING = 1 } i2cm_state_t; typedef struct { i2cm_req_t *req; i2cm_state_t state; } i2cm_req_state_t; static i2cm_req_state_t states[MXC_CFG_I2CM_INSTANCES]; /***** Functions *****/ //static void I2CM_Recover(mxc_i2cm_regs_t *i2cm); //static int I2CM_WriteTxFifo(mxc_i2cm_regs_t *regs, mxc_i2cm_fifo_regs_t *fifo, const uint16_t data); //static int I2CM_TxInProgress(mxc_i2cm_regs_t *i2cm); static void I2CM_FreeCallback(int i2cm_num, int error); //static int I2CM_Tx(mxc_i2cm_regs_t *i2cm, mxc_i2cm_fifo_regs_t *fifo, uint8_t addr, // const uint8_t *data, uint32_t len, uint8_t stop); //static int I2CM_Rx(mxc_i2cm_regs_t *i2cm, mxc_i2cm_fifo_regs_t *fifo, uint8_t addr, // uint8_t *data, uint32_t len); static int I2CM_CmdHandler(mxc_i2cm_regs_t *i2cm, mxc_i2cm_fifo_regs_t *fifo, i2cm_req_t *req); static int I2CM_ReadHandler(mxc_i2cm_regs_t *i2cm, i2cm_req_t *req, int i2cm_num); static int I2CM_WriteHandler(mxc_i2cm_regs_t *i2cm, i2cm_req_t *req, int i2cm_num); /******************************************************************************/ int I2CM_Init(mxc_i2cm_regs_t *i2cm, const sys_cfg_i2cm_t *sys_cfg, i2cm_speed_t speed) { int err; // Check the base pointer MXC_ASSERT(MXC_I2CM_GET_IDX(i2cm) >= 0); // Set system level configurations if ((err = SYS_I2CM_Init(i2cm, sys_cfg)) != E_NO_ERROR) { return err; } I2CM_SetFrequency(i2cm,speed); // Reset module i2cm->ctrl = MXC_F_I2CM_CTRL_MSTR_RESET_EN; i2cm->ctrl = 0; // Set timeout to 255 ms and turn on the auto-stop option i2cm->timeout = (MXC_F_I2CM_TIMEOUT_TX_TIMEOUT | MXC_F_I2CM_TIMEOUT_AUTO_STOP_EN); // Enable tx_fifo and rx_fifo i2cm->ctrl |= (MXC_F_I2CM_CTRL_TX_FIFO_EN | MXC_F_I2CM_CTRL_RX_FIFO_EN); return E_NO_ERROR; } /******************************************************************************/ int I2CM_Shutdown(mxc_i2cm_regs_t *i2cm) { int i2cm_num, err; // Check the base pointer i2cm_num = MXC_I2CM_GET_IDX(i2cm); MXC_ASSERT(i2cm_num >= 0); // Disable and clear interrupts i2cm->inten = 0; i2cm->intfl = i2cm->intfl; // Call all of the pending callbacks for this I2CM if(states[i2cm_num].req != NULL) { I2CM_Recover(i2cm); I2CM_FreeCallback(i2cm_num, E_SHUTDOWN); } // Clears system level configurations if ((err = SYS_I2CM_Shutdown(i2cm)) != E_NO_ERROR) { return err; } return E_NO_ERROR; } /******************************************************************************/ int I2CM_Read(mxc_i2cm_regs_t *i2cm, uint8_t addr, const uint8_t *cmd_data, uint32_t cmd_len, uint8_t* data, uint32_t len) { int i2cm_num; int error = E_NO_ERROR; int retval = E_NO_ERROR; mxc_i2cm_fifo_regs_t *fifo; if(data == NULL) { return E_NULL_PTR; } // Make sure the I2CM has been initialized if(i2cm->ctrl == 0) { return E_UNINITIALIZED; } if(!(len > 0)) { return E_NO_ERROR; } // Lock this I2CM i2cm_num = MXC_I2CM_GET_IDX(i2cm); while(mxc_get_lock((uint32_t*)&states[i2cm_num].req,1) != E_NO_ERROR) {} // Get the FIFO pointer for this I2CM fifo = MXC_I2CM_GET_FIFO(i2cm_num); // Disable and clear the interrupts i2cm->inten = 0; i2cm->intfl = i2cm->intfl; // Transmit the command if there is command data and length if((cmd_data != NULL) && (cmd_len > 0)) { retval = I2CM_Tx(i2cm, fifo, addr, cmd_data, cmd_len, 0); } // Read data from the slave if we don't have any errors if(retval == E_NO_ERROR) { retval = I2CM_Rx(i2cm, fifo, addr, data, len); } // Wait for the transaction to complete if((error = I2CM_TxInProgress(i2cm)) != E_NO_ERROR) { retval = error; } // Unlock this I2CM mxc_free_lock((uint32_t*)&states[i2cm_num].req); if(retval != E_NO_ERROR) { return retval; } return len; } /******************************************************************************/ int I2CM_Write(mxc_i2cm_regs_t *i2cm, uint8_t addr, const uint8_t *cmd_data, uint32_t cmd_len, uint8_t* data, uint32_t len) { int i2cm_num; int error = E_NO_ERROR; int retval = E_NO_ERROR; mxc_i2cm_fifo_regs_t *fifo; if(data == NULL) { return E_NULL_PTR; } // Make sure the I2CM has been initialized if(i2cm->ctrl == 0) { return E_UNINITIALIZED; } if(!(len > 0)) { return E_NO_ERROR; } // Lock this I2CM i2cm_num = MXC_I2CM_GET_IDX(i2cm); while(mxc_get_lock((uint32_t*)&states[i2cm_num].req,1) != E_NO_ERROR) {} // Get the FIFO pointer for this I2CM fifo = MXC_I2CM_GET_FIFO(i2cm_num); // Disable and clear the interrupts i2cm->inten = 0; i2cm->intfl = i2cm->intfl; // Transmit the command if there is command data and length, don't send stop bit if((cmd_data != NULL) && (cmd_len > 0)) { retval = I2CM_Tx(i2cm, fifo, addr, cmd_data, cmd_len, 0); } // Write data to the slave, send the stop bit if(retval == E_NO_ERROR) { retval = I2CM_Tx(i2cm, fifo, addr, data, len, 1); } // Wait for the transaction to complete if((error = I2CM_TxInProgress(i2cm)) != E_NO_ERROR) { retval = error; } // Unlock this I2CM mxc_free_lock((uint32_t*)&states[i2cm_num].req); if(retval != E_NO_ERROR) { return retval; } return len; } /******************************************************************************/ int I2CM_ReadAsync(mxc_i2cm_regs_t *i2cm, i2cm_req_t *req) { int i2cm_num, error; if(req->data == NULL) { return E_NULL_PTR; } // Make sure the I2CM has been initialized if(i2cm->ctrl == 0) { return E_UNINITIALIZED; } if(!(req->data_len > 0)) { return E_NO_ERROR; } i2cm_num = MXC_I2CM_GET_IDX(i2cm); // Attempt to register this request if(mxc_get_lock((uint32_t*)&states[i2cm_num].req, (uint32_t)req) != E_NO_ERROR) { return E_BUSY; } states[i2cm_num].state = I2CM_STATE_READING; // Clear the number of bytes counter req->cmd_num = 0; req->data_num = 0; // Disable and clear the interrupts i2cm->inten = 0; i2cm->intfl = i2cm->intfl; // Start the read if((error = I2CM_ReadHandler(i2cm, req, i2cm_num)) != E_NO_ERROR) { I2CM_Recover(i2cm); I2CM_FreeCallback(i2cm_num, error); return error; } return E_NO_ERROR; } /******************************************************************************/ int I2CM_WriteAsync(mxc_i2cm_regs_t *i2cm, i2cm_req_t *req) { int i2cm_num, error; if(req->data == NULL) { return E_NULL_PTR; } // Make sure the I2CM has been initialized if(i2cm->ctrl == 0) { return E_UNINITIALIZED; } if(!(req->data_len > 0)) { return E_NO_ERROR; } i2cm_num = MXC_I2CM_GET_IDX(i2cm); // Attempt to register this request if(mxc_get_lock((uint32_t*)&states[i2cm_num].req, (uint32_t)req) != E_NO_ERROR) { return E_BUSY; } states[i2cm_num].state = I2CM_STATE_WRITING; // Clear the number of bytes counter req->cmd_num = 0; req->data_num = 0; // Disable and clear the interrupts i2cm->inten = 0; i2cm->intfl = i2cm->intfl; // Start the Write if((error = I2CM_WriteHandler(i2cm, req, i2cm_num)) != E_NO_ERROR) { I2CM_Recover(i2cm); I2CM_FreeCallback(i2cm_num, error); return error; } return E_NO_ERROR; } /******************************************************************************/ int I2CM_AbortAsync(i2cm_req_t *req) { int i2cm_num; mxc_i2cm_regs_t *i2cm; // Find the request, set to NULL for(i2cm_num = 0; i2cm_num < MXC_CFG_I2CM_INSTANCES; i2cm_num++) { if(req == states[i2cm_num].req) { i2cm = MXC_I2CM_GET_I2CM(i2cm_num); I2CM_Recover(i2cm); I2CM_FreeCallback(i2cm_num, E_ABORT); return E_NO_ERROR; } } return E_BAD_PARAM; } /******************************************************************************/ void I2CM_Handler(mxc_i2cm_regs_t *i2cm) { uint32_t intfl; int i2cm_num, error; // Save and clear the interrupts intfl = i2cm->intfl; i2cm->intfl = intfl; // Mask the disabled interrupts intfl &= i2cm->inten; i2cm_num = MXC_I2CM_GET_IDX(i2cm); // Check for errors if ((intfl & MXC_F_I2CM_INTFL_TX_NACKED) || (intfl & MXC_F_I2CM_INTFL_TX_LOST_ARBITR)) { I2CM_Recover(i2cm); I2CM_FreeCallback(i2cm_num, E_COMM_ERR); return; } if(intfl & MXC_F_I2CM_INTFL_TX_TIMEOUT) { I2CM_Recover(i2cm); I2CM_FreeCallback(i2cm_num, E_TIME_OUT); return; } // Read or write if(states[i2cm_num].state == I2CM_STATE_READING) { if((error = I2CM_ReadHandler(i2cm, states[i2cm_num].req, i2cm_num)) != E_NO_ERROR) { I2CM_Recover(i2cm); I2CM_FreeCallback(i2cm_num, error); return; } } else if(states[i2cm_num].state == I2CM_STATE_WRITING) { if((error = I2CM_WriteHandler(i2cm, states[i2cm_num].req, i2cm_num)) != E_NO_ERROR) { I2CM_Recover(i2cm); I2CM_FreeCallback(i2cm_num, error); return; } } // Done with the transaction if(intfl & MXC_F_I2CM_INTFL_TX_DONE) { I2CM_Recover(i2cm); I2CM_FreeCallback(i2cm_num, E_NO_ERROR); } } /******************************************************************************/ int I2CM_Busy(mxc_i2cm_regs_t *i2cm) { // Check to see if there are any ongoing transactions if((states[MXC_I2CM_GET_IDX(i2cm)].req == NULL) && !(i2cm->trans & MXC_F_I2CM_TRANS_TX_IN_PROGRESS)) { return E_NO_ERROR; } return E_BUSY; } /******************************************************************************/ int I2CM_PrepForSleep(mxc_i2cm_regs_t *i2cm) { if(I2CM_Busy(i2cm) != E_NO_ERROR) { return E_BUSY; } // Disable interrupts i2cm->inten = 0; return E_NO_ERROR; } /******************************************************************************/ int I2CM_BusCheck(mxc_i2cm_regs_t *i2cm) { // If SCL is low, we don't have the bus if(!(i2cm->bb & MXC_F_I2CM_BB_BB_SCL_IN_VAL)) { return E_BUSY; } // If SDA is low, we don't have the bus if(!(i2cm->bb & MXC_F_I2CM_BB_BB_SDA_IN_VAL)) { return E_BUSY; } return E_NO_ERROR; } /******************************************************************************/ static void I2CM_FreeCallback(int i2cm_num, int error) { // Save the request i2cm_req_t *temp_req = states[i2cm_num].req; // Unlock this UART to write mxc_free_lock((uint32_t*)&states[i2cm_num].req); // Callback if not NULL if(temp_req->callback != NULL) { temp_req->callback(temp_req, error); } } /******************************************************************************/ void I2CM_Recover(mxc_i2cm_regs_t *i2cm) { // Disable and clear interrupts i2cm->inten = 0; i2cm->intfl = i2cm->intfl; i2cm->ctrl = MXC_F_I2CM_CTRL_MSTR_RESET_EN; i2cm->ctrl = MXC_F_I2CM_CTRL_TX_FIFO_EN | MXC_F_I2CM_CTRL_RX_FIFO_EN; } /******************************************************************************/ int I2CM_WriteTxFifo(mxc_i2cm_regs_t *i2cm, mxc_i2cm_fifo_regs_t *fifo, const uint16_t data) { int32_t timeout = MXC_I2CM_TX_TIMEOUT; // Read the TX FIFO to determine if it's full do { // Wait for the TX FIFO to have room and check for errors if (i2cm->intfl & (MXC_F_I2CM_INTFL_TX_NACKED | MXC_F_I2CM_INTFL_TX_LOST_ARBITR)) { return E_COMM_ERR; } if((i2cm->intfl & MXC_F_I2CM_INTFL_TX_TIMEOUT) || !timeout--) { return E_TIME_OUT; } } while (fifo->tx); fifo->tx = data; return E_NO_ERROR; } /******************************************************************************/ int I2CM_TxInProgress(mxc_i2cm_regs_t *i2cm) { int32_t timeout = MXC_I2CM_TX_TIMEOUT; while ((i2cm->trans & MXC_F_I2CM_TRANS_TX_IN_PROGRESS) && --timeout); if (i2cm->intfl & (MXC_F_I2CM_INTFL_TX_NACKED | MXC_F_I2CM_INTFL_TX_LOST_ARBITR)) { I2CM_Recover(i2cm); return E_COMM_ERR; } if((i2cm->intfl & MXC_F_I2CM_INTFL_TX_TIMEOUT) && !timeout--) { I2CM_Recover(i2cm); return E_TIME_OUT; } return E_NO_ERROR; } /******************************************************************************/ int I2CM_Tx(mxc_i2cm_regs_t *i2cm, mxc_i2cm_fifo_regs_t *fifo, uint8_t addr, const uint8_t *data, uint32_t len, uint8_t stop) { uint32_t i; int error; // Write the address to the TXFIFO if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_START | (addr << 1)))) != E_NO_ERROR) { return error; } // Start the transaction if it is not currently ongoing if (!(i2cm->trans & MXC_F_I2CM_TRANS_TX_IN_PROGRESS)) { i2cm->trans |= MXC_F_I2CM_TRANS_TX_START; } // Fill the FIFO for (i = 0; i < len; i++) { if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_TXDATA_ACK | data[i]))) != E_NO_ERROR) { return error; } } // Send the stop condition if(stop) { if ((error = I2CM_WriteTxFifo(i2cm, fifo, MXC_S_I2CM_TRANS_TAG_STOP)) != E_NO_ERROR) { return error; } } return E_NO_ERROR; } /******************************************************************************/ int I2CM_Rx(mxc_i2cm_regs_t *i2cm, mxc_i2cm_fifo_regs_t *fifo, uint8_t addr, uint8_t *data, uint32_t len) { uint32_t i = len; int32_t timeout; uint16_t temp; int error; // Write the address to the TXFIFO if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_START | (addr << 1) | I2CM_READ_BIT))) != E_NO_ERROR) { return error; } // Write to the TXFIFO the number of bytes we want to read while(i > 256) { if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_RXDATA_COUNT | 255))) != E_NO_ERROR) { return error; } i -= 256; } if(i > 1) { if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_RXDATA_COUNT | (i-2)))) != E_NO_ERROR) { return error; } } // Start the transaction if it is not currently ongoing if (!(i2cm->trans & MXC_F_I2CM_TRANS_TX_IN_PROGRESS)) { i2cm->trans |= MXC_F_I2CM_TRANS_TX_START; } // NACK the last read byte if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_RXDATA_NACK))) != E_NO_ERROR) { return error; } // Send the stop condition if ((error = I2CM_WriteTxFifo(i2cm, fifo, MXC_S_I2CM_TRANS_TAG_STOP)) != E_NO_ERROR) { return error; } // Get the data from the RX FIFO i = 0; while (i < len) { // Wait for there to be data in the RX FIFO timeout = MXC_I2CM_RX_TIMEOUT; while (!(i2cm->intfl & MXC_F_I2CM_INTFL_RX_FIFO_NOT_EMPTY) && ((i2cm->bb & MXC_F_I2CM_BB_RX_FIFO_CNT) == 0)) { if((timeout-- < 0) || (i2cm->trans & MXC_F_I2CM_TRANS_TX_TIMEOUT)) { return E_TIME_OUT; } if (i2cm->trans & (MXC_F_I2CM_TRANS_TX_LOST_ARBITR | MXC_F_I2CM_TRANS_TX_NACKED)) { return E_COMM_ERR; } } i2cm->intfl = MXC_F_I2CM_INTFL_RX_FIFO_NOT_EMPTY; // Save the data from the RX FIFO temp = fifo->rx; if (temp & MXC_S_I2CM_RSTLS_TAG_EMPTY) { continue; } data[i++] = (uint8_t)temp; } return E_NO_ERROR; } /******************************************************************************/ static int I2CM_CmdHandler(mxc_i2cm_regs_t *i2cm, mxc_i2cm_fifo_regs_t *fifo, i2cm_req_t *req) { int error; // Start of the command if(req->cmd_num == 0) { // Write the address to the TXFIFO if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_START | (req->addr << 1)))) != E_NO_ERROR) { return error; } // Start the transaction if it is not currently ongoing if (!(i2cm->trans & MXC_F_I2CM_TRANS_TX_IN_PROGRESS)) { i2cm->trans |= MXC_F_I2CM_TRANS_TX_START; } } // Write to the FIFO until it is full or we run out of command bytes while((req->cmd_num < req->cmd_len) && (!fifo->tx)) { fifo->tx = MXC_S_I2CM_TRANS_TAG_TXDATA_ACK | req->cmd_data[req->cmd_num++]; } return E_NO_ERROR; } /******************************************************************************/ static int I2CM_ReadHandler(mxc_i2cm_regs_t *i2cm, i2cm_req_t *req, int i2cm_num) { int error, cmd_remain, data_remain; uint16_t data; uint32_t temp_len, inten; mxc_i2cm_fifo_regs_t *fifo; // Get the FIFO pointer for this I2CM fifo = MXC_I2CM_GET_FIFO(i2cm_num); cmd_remain = req->cmd_len - req->cmd_num; data_remain = req->data_len - req->data_num; // Process the command portion if((cmd_remain) && (req->cmd_data != NULL)) { if((error = I2CM_CmdHandler(i2cm, fifo, req)) != E_NO_ERROR) { return error; } cmd_remain = req->cmd_len - req->cmd_num; } // Process the data portion if((cmd_remain == 0) && (data_remain)) { // Save the data from the RXFIFO data = fifo->rx; while((req->data_num < req->data_len) && !(data & MXC_S_I2CM_RSTLS_TAG_EMPTY)) { req->data[req->data_num++] = data; data = fifo->rx; } // Start of the data portion if(req->data_num == 0) { temp_len = req->data_len; // Write the address to the TXFIFO if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_START | (req->addr << 1) | I2CM_READ_BIT))) != E_NO_ERROR) { return error; } // Write to the TXFIFO the number of bytes we want to read while(temp_len > 256) { if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_RXDATA_COUNT | 255))) != E_NO_ERROR) { return error; } temp_len -= 256; } if(temp_len > 1) { if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_RXDATA_COUNT | (temp_len-2)))) != E_NO_ERROR) { return error; } } // Start the transaction if it is not currently ongoing if (!(i2cm->trans & MXC_F_I2CM_TRANS_TX_IN_PROGRESS)) { i2cm->trans |= MXC_F_I2CM_TRANS_TX_START; } // NACK the last read byte if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_RXDATA_NACK))) != E_NO_ERROR) { return error; } // Send the stop condition if ((error = I2CM_WriteTxFifo(i2cm, fifo, MXC_S_I2CM_TRANS_TAG_STOP)) != E_NO_ERROR) { return error; } } } // Enable the required interrupts inten = MXC_F_I2CM_INTEN_TX_DONE | MXC_F_I2CM_INTEN_TX_NACKED | MXC_F_I2CM_INTEN_TX_LOST_ARBITR | MXC_F_I2CM_INTEN_TX_TIMEOUT; if (cmd_remain) { inten |= (MXC_F_I2CM_INTEN_TX_FIFO_EMPTY | MXC_F_I2CM_INTEN_TX_FIFO_3Q_EMPTY); } data_remain = req->data_len - req->data_num; if (data_remain > I2CM_FIFO_DEPTH_3Q) { inten |= MXC_F_I2CM_INTEN_RX_FIFO_3Q_FULL; } else if (data_remain > I2CM_FIFO_DEPTH_2Q) { inten |= MXC_F_I2CM_INTEN_RX_FIFO_2Q_FULL; } else if (data_remain > 0) { inten |= MXC_F_I2CM_INTEN_RX_FIFO_NOT_EMPTY; } i2cm->inten = inten; return E_NO_ERROR; } /******************************************************************************/ static int I2CM_WriteHandler(mxc_i2cm_regs_t *i2cm, i2cm_req_t *req, int i2cm_num) { int error, cmd_remain, data_remain; uint32_t inten; mxc_i2cm_fifo_regs_t *fifo; // Get the FIFO pointer for this I2CM fifo = MXC_I2CM_GET_FIFO(i2cm_num); cmd_remain = req->cmd_len - req->cmd_num; data_remain = req->data_len - req->data_num; // Process the command portion if((cmd_remain) && (req->cmd_data != NULL)) { if((error = I2CM_CmdHandler(i2cm, fifo, req)) != E_NO_ERROR) { return error; } cmd_remain = req->cmd_len - req->cmd_num; } // Process the data portion if((cmd_remain == 0) && (data_remain)) { // Start of the data portion if(req->data_num == 0) { // Write the address to the TXFIFO if((error = I2CM_WriteTxFifo(i2cm, fifo, (MXC_S_I2CM_TRANS_TAG_START | (req->addr << 1)))) != E_NO_ERROR) { return error; } // Start the transaction if it is not currently ongoing if (!(i2cm->trans & MXC_F_I2CM_TRANS_TX_IN_PROGRESS)) { i2cm->trans |= MXC_F_I2CM_TRANS_TX_START; } } // Write bytes to the FIFO until it's full or we run out of bytes while(req->data_num < req->data_len) { fifo->tx = MXC_S_I2CM_TRANS_TAG_TXDATA_ACK | req->data[req->data_num++]; } // Send the stop condition if ((error = I2CM_WriteTxFifo(i2cm, fifo, MXC_S_I2CM_TRANS_TAG_STOP)) != E_NO_ERROR) { return error; } } // Enable the required interrupts data_remain = req->data_len - req->data_num; inten = MXC_F_I2CM_INTEN_TX_DONE | MXC_F_I2CM_INTEN_TX_NACKED | MXC_F_I2CM_INTEN_TX_LOST_ARBITR | MXC_F_I2CM_INTEN_TX_TIMEOUT; if(data_remain || cmd_remain) { inten |= (MXC_F_I2CM_INTEN_TX_FIFO_EMPTY | MXC_F_I2CM_INTEN_TX_FIFO_3Q_EMPTY); } i2cm->inten = inten; return E_NO_ERROR; } int I2CM_SetFrequency(mxc_i2cm_regs_t *i2cm, int speed) { // Speed converted into Khz float i2cSpeed = speed / 1000.0f; //get clk speed into MHz int sClk = SYS_I2CM_GetFreq(i2cm) / 1000000; // duty cycle of .67 float dc = 2.0f / 3.0f; //Hold Time float hold = (100.0f / i2cSpeed); int riseTime; //max rise time based on speed according to the I2C specs if (i2cSpeed <= 100) { riseTime = 1000; } else if (i2cSpeed <= 400) { riseTime = 300; } else if (i2cSpeed <= 1000) { riseTime = 120; } else { return E_NOT_SUPPORTED; } // Clock cycles to delay int latency = 4; int filtDev, sclHi, sclLow; filtDev = (hold * sClk) / 2; sclHi = (((dc * sClk * 1000.0f / i2cSpeed) - (((2.5f * filtDev) + (riseTime / 1000.0f * sClk) + latency) * (1.0f + dc))) / (1.0f + dc)); sclLow = ((sClk * 1000.0f / i2cSpeed) - (2.5f * filtDev) - (riseTime / 1000.0f * sClk) - latency - sclHi); i2cm->fs_clk_div = ((filtDev << MXC_F_I2CM_FS_CLK_DIV_FS_FILTER_CLK_DIV_POS) | (sclHi << MXC_F_I2CM_FS_CLK_DIV_FS_SCL_HI_CNT_POS) | (sclLow << MXC_F_I2CM_FS_CLK_DIV_FS_SCL_LO_CNT_POS)); return E_NO_ERROR; }