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Diff: targets/TARGET_ONSEMI/TARGET_NCS36510/ncs36510_i2c.c
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- 149:156823d33999
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- 159:612c381a210f
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/targets/TARGET_ONSEMI/TARGET_NCS36510/ncs36510_i2c.c Fri Oct 28 11:17:30 2016 +0100 @@ -0,0 +1,228 @@ +/** + ****************************************************************************** + * @file i2c.c + * @brief I2C driver + * @internal + * @author ON Semiconductor + * $Rev: $ + * $Date: 2016-04-12 $ + ****************************************************************************** + * Copyright 2016 Semiconductor Components Industries LLC (d/b/a ON Semiconductor). + * All rights reserved. This software and/or documentation is licensed by ON Semiconductor + * under limited terms and conditions. The terms and conditions pertaining to the software + * and/or documentation are available at http://www.onsemi.com/site/pdf/ONSEMI_T&C.pdf + * (ON Semiconductor Standard Terms and Conditions of Sale, Section 8 Software) and + * if applicable the software license agreement. Do not use this software and/or + * documentation unless you have carefully read and you agree to the limited terms and + * conditions. By using this software and/or documentation, you agree to the limited + * terms and conditions. + * + * THIS SOFTWARE IS PROVIDED "AS IS". NO WARRANTIES, WHETHER EXPRESS, IMPLIED + * OR STATUTORY, INCLUDING, BUT NOT LIMITED TO, IMPLIED WARRANTIES OF + * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. + * ON SEMICONDUCTOR SHALL NOT, IN ANY CIRCUMSTANCES, BE LIABLE FOR SPECIAL, + * INCIDENTAL, OR CONSEQUENTIAL DAMAGES, FOR ANY REASON WHATSOEVER. + * @endinternal + * + * @ingroup i2c + * + * @details + * + * <h1> Reference document(s) </h1> + * <p> + * IPC7208 APB I2C Master Design Specification v1.3 + * </p> + * The I2C bus is an industry-standard two-wire (clock and data) serial communication bus between master(initiator) and slave device. + * Within the procedure of the I2C-bus, unique situations arise which are defined as START and STOP conditions .A HIGH to LOW transition on + * the SDA line while SCL is HIGH is one such unique case. This situation indicates a START condition.A LOW to HIGH transition on the + * SDA line while SCL is HIGH defines a STOP condition.START and STOP conditions are always generated by the master. The bus is considered + * to be busy after the START condition. The bus is considered to be free again a certain time after the STOP condition. + * A master may start a transfer only if the bus is free. Two or more masters may generate a START condition. + * Every byte put on the SDA line must be 8-bits long.Each byte has to be followed by an acknowledge bit. + * This APB(Advanced peripheral bus) I2C Master is an APB Slave peripheral that can also serves as an I2C bus Master. The Command register + * is the programming interface to the I2C Engine. The commands arrive at the I2C Engine via the Command FIFO,so the first valid command + * that is written to the Command register is the first I2C instruction implemented on the I2C bus.Because the command interface provides + * the basic building blocks for any I2C transaction, access to a wide range of I2C slave devices is supported. + * I2C can be enabled by setting bit 7 of the control register . + * There is a generated clock (a divided version of the APB clock) in this module that may be used as the I2C System Clock. + * There are two FIFO in the I2C; Command FIFO and Read data FIFO + * The commands(I2C instructions) and data arrive at the I2C Engine via the Command FIFO. + * if the command FIFO is empty , up to 32 commands can be written to the command interface , it is programmer's responsibility to keep + * the track of command FIFO's status either by interrupt or by polling method by reading status register, which represents Operational + * Status of the I2C Module and its sub-modules.The action from the processor may be necessary after reading the status register.Reading + * the Status register clears the blkInt Interrupt signal.Read data FIFO is where data read by the processor from I2C slave is placed . + * + * + * <h1> Functional description (internal) </h1> + * <p> + * + * </p> + */ +#if DEVICE_I2C +#include "i2c.h" + +/* See i2c.h for details */ +void fI2cInit(i2c_t *obj,PinName sda,PinName scl) +{ + uint32_t clockDivisor; + /* determine the I2C to use */ + I2CName i2c_sda = (I2CName)pinmap_peripheral(sda, PinMap_I2C_SDA); + I2CName i2c_scl = (I2CName)pinmap_peripheral(scl, PinMap_I2C_SCL); + obj->membase = (I2cIpc7208Reg_pt)pinmap_merge(i2c_sda, i2c_scl); + MBED_ASSERT((int)obj->membase != NC); + + /* By default disbale interrupts */ + obj->membase->IER.WORD = False; + + /* enable interrupt associated with the device */ + if(obj->membase == I2C1REG) { + CLOCK_ENABLE(CLOCK_I2C); /* enable i2c peripheral */ + NVIC_ClearPendingIRQ(I2C_IRQn); + NVIC_EnableIRQ(I2C_IRQn); + } else { + CLOCK_ENABLE(CLOCK_I2C2); /* enable i2c peripheral */ + NVIC_ClearPendingIRQ(I2C2_IRQn); + NVIC_EnableIRQ(I2C2_IRQn); + } + + /*select I2C clock source */ + obj->membase->CR.BITS.I2C_CLK_SRC = True; + + /* enable I2C clock divider */ + obj->membase->CR.BITS.I2C_APB_CD_EN = True; + + /* set default baud rate at 100k */ + clockDivisor = ((fClockGetPeriphClockfrequency() / 100000) >> 2) - 2; + obj->membase->CR.BITS.CD_VAL = (clockDivisor & I2C_CLOCKDIVEDER_VAL_MASK); + obj->membase->PRE_SCALE_REG = (clockDivisor & I2C_APB_CLK_DIVIDER_VAL_MASK) >> 5; /**< Zero pre-scale value not allowed */ + + /* Cross bar setting */ + pinmap_pinout(sda, PinMap_I2C_SDA); + pinmap_pinout(scl, PinMap_I2C_SCL); + + /*Enable open drain & pull up for sda & scl pin */ + pin_mode(sda, OpenDrainPullUp); + pin_mode(scl, OpenDrainPullUp); + + /* PAD drive strength */ + PadReg_t *padRegSda = (PadReg_t*)(PADREG_BASE + (sda * PAD_REG_ADRS_BYTE_SIZE)); + PadReg_t *padRegScl = (PadReg_t*)(PADREG_BASE + (scl * PAD_REG_ADRS_BYTE_SIZE)); + + CLOCK_ENABLE(CLOCK_PAD); + padRegSda->PADIO0.BITS.POWER = 1; /* sda: Drive strength */ + padRegScl->PADIO0.BITS.POWER = 1; /* scl: Drive strength */ + CLOCK_DISABLE(CLOCK_PAD); + + CLOCK_ENABLE(CLOCK_GPIO); + GPIOREG->W_OUT |= ((True << sda) | (True << scl)); + CLOCK_DISABLE(CLOCK_GPIO); + + /* Enable i2c module */ + obj->membase->CR.BITS.I2C_MODULE_EN = True; +} + +/* See i2c.h for details */ +void fI2cFrequency(i2c_t *obj, uint32_t hz) +{ + /* Set user baud rate */ + uint32_t clockDivisor; + clockDivisor = ((fClockGetPeriphClockfrequency() / hz) >> 2) - 2; + obj->membase->CR.BITS.CD_VAL = (clockDivisor & I2C_CLOCKDIVEDER_VAL_MASK); + obj->membase->PRE_SCALE_REG = (clockDivisor & I2C_APB_CLK_DIVIDER_VAL_MASK) >> 5; /**< Zero pre-scale value not allowed */ +} + +/* See i2c.h for details */ +int32_t fI2cStart(i2c_t *obj) +{ + /* Send start bit */ + obj->membase->CMD_REG = I2C_CMD_START; + return I2C_API_STATUS_SUCCESS; +} + +/* See i2c.h for details */ +int32_t fI2cStop(i2c_t *obj) +{ + /* Send stop bit */ + obj->membase->CMD_REG = I2C_CMD_STOP; + if (obj->membase->STATUS.WORD & (I2C_STATUS_CMD_FIFO_FULL_BIT | + I2C_STATUS_CMD_FIFO_OFL_BIT | + I2C_STATUS_BUS_ERR_BIT)) { + /* I2c error occured */ + return I2C_ERROR_BUS_BUSY; + } + return I2C_API_STATUS_SUCCESS; +} + +/* See i2c.h for details */ +int32_t fI2cReadB(i2c_t *d, char *buf, int len) +{ + int32_t read = 0; + + while (read < len) { + /* Send read command */ + d->membase->CMD_REG = I2C_CMD_RDAT8; + while(!RD_DATA_READY) { + if (I2C_BUS_ERR_CHECK) { + /* Bus error occured */ + return I2C_ERROR_BUS_BUSY; + } + } + buf[read++] = d->membase->RD_FIFO_REG; /**< Reading 'read FIFO register' will clear status register */ + + if(!(read>=len)) { /* No ACK will be generated for the last read, upper level I2C protocol should generate */ + d->membase->CMD_REG=I2C_CMD_WDAT0; /* TODO based on requirement generate ACK or NACK Based on the requirement. */ + } + + /* check for FIFO underflow */ + if(I2C_UFL_CHECK) { + return I2C_ERROR_NO_SLAVE; /* TODO No error available for this in i2c_api.h */ + } + if(I2C_BUS_ERR_CHECK) { + /* Bus error */ + return I2C_ERROR_BUS_BUSY; + } + } + + return read; +} + +/* See i2c.h for details */ +int32_t fI2cWriteB(i2c_t *d, const char *buf, int len) +{ + int32_t write = 0; + + while (write < len) { + /* Send write command */ + d->membase->CMD_REG = I2C_CMD_WDAT8; + if(buf[write] == I2C_CMD_RDAT8) { + /* SW work around to counter FSM issue. If the only command in the CMD FIFO is the WDAT8 command (data of 0x13) + then as the command is read out (i.e. the FIFO goes empty), the WDAT8 command will be misinterpreted as a + RDAT8 command by the data FSM; resulting in an I2C bus error (NACK instead of an ACK). */ + /* Send 0x13 bit wise */ + d->membase->CMD_REG = I2C_CMD_WDAT0; + d->membase->CMD_REG = I2C_CMD_WDAT0; + d->membase->CMD_REG = I2C_CMD_WDAT0; + d->membase->CMD_REG = I2C_CMD_WDAT1; + + d->membase->CMD_REG = I2C_CMD_WDAT0; + d->membase->CMD_REG = I2C_CMD_WDAT0; + d->membase->CMD_REG = I2C_CMD_WDAT1; + d->membase->CMD_REG = I2C_CMD_WDAT1; + } else { + /* Send data */ + d->membase->CMD_REG = buf[write++]; + } + d->membase->CMD_REG = I2C_CMD_VRFY_ACK; /* TODO Verify ACK based on requirement, Do we need? */ + + while(FIFO_OFL_CHECK); /* Wait till command overflow ends */ + + if (I2C_BUS_ERR_CHECK) { + /* Bus error */ + return I2C_ERROR_BUS_BUSY; + } + } + + return write; +} + +#endif /* DEVICE_I2C */