/***************************************************************************//** * @file drv_iic.c * @brief Serial API of RT-Thread RTOS for EFM32 * COPYRIGHT (C) 2011, RT-Thread Development Team * @author onelife * @version 0.4 beta ******************************************************************************* * @section License * The license and distribution terms for this file may be found in the file * LICENSE in this distribution or at http://www.rt-thread.org/license/LICENSE ******************************************************************************* * @section Change Logs * Date Author Notes * 2011-01-06 onelife Initial creation for EFM32 * 2011-06-17 onelife Modify init function for efm32lib v2 upgrading * 2011-07-11 onelife Add lock (semaphore) to prevent simultaneously * access * 2011-08-04 onelife Change the usage of the second parameter of Read * and Write functions from (seldom used) "Offset" to "Slave address" * 2011-08-04 onelife Add a timer to prevent from forever waiting ******************************************************************************/ /***************************************************************************//** * @addtogroup efm32 * @{ ******************************************************************************/ /* Includes ------------------------------------------------------------------*/ #include "board.h" #include "hdl_interrupt.h" #include "drv_iic.h" #if (defined(RT_USING_IIC0) || defined(RT_USING_IIC1)) /* Private typedef -----------------------------------------------------------*/ struct efm32_iic_block { struct rt_device device; struct rt_semaphore lock; struct rt_timer timer; }; /* Private define ------------------------------------------------------------*/ /* Private macro -------------------------------------------------------------*/ #ifdef RT_IIC_DEBUG #define iic_debug(format,args...) rt_kprintf(format, ##args) #else #define iic_debug(format,args...) #endif /* Private variables ---------------------------------------------------------*/ #ifdef RT_USING_IIC0 #if (RT_USING_IIC0 > 3) #error "The location number range of IIC is 0~3" #endif static struct efm32_iic_block iic0; #endif #ifdef RT_USING_IIC1 #if (RT_USING_IIC1 > 3) #error "The location number range of IIC is 0~3" #endif static struct efm32_iic_block iic1; #endif /* Private function prototypes -----------------------------------------------*/ /* Private functions ---------------------------------------------------------*/ /***************************************************************************//** * @brief * Initialize IIC device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @return * Error code ******************************************************************************/ static rt_err_t rt_iic_init (rt_device_t dev) { struct efm32_iic_device_t* iic; iic = (struct efm32_iic_device_t*)dev->user_data; if (!(dev->flag & RT_DEVICE_FLAG_ACTIVATED)) { /* Enable IIC */ I2C_Enable(iic->iic_device, true); iic->rx_buffer = RT_NULL; iic->state = 0; dev->flag |= RT_DEVICE_FLAG_ACTIVATED; } return RT_EOK; } /***************************************************************************//** * @brief * Open IIC device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @param[in] oflag * Device open flag * * @return * Error code ******************************************************************************/ static rt_err_t rt_iic_open(rt_device_t dev, rt_uint16_t oflag) { RT_ASSERT(dev != RT_NULL); struct efm32_iic_device_t *iic; iic = (struct efm32_iic_device_t *)(dev->user_data); iic->counter++; iic_debug("IIC: Open with flag %x\n", oflag); return RT_EOK; } /***************************************************************************//** * @brief * Close IIC device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @return * Error code ******************************************************************************/ static rt_err_t rt_iic_close(rt_device_t dev) { RT_ASSERT(dev != RT_NULL); struct efm32_iic_device_t *iic; iic = (struct efm32_iic_device_t *)(dev->user_data); if (--iic->counter == 0) { rt_free(iic->rx_buffer->data_ptr); rt_free(iic->rx_buffer); iic->rx_buffer = RT_NULL; } return RT_EOK; } /***************************************************************************//** * @brief * Read from IIC device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @param[in] pos * Slave address * * @param[in] buffer * Poniter to the buffer * * @param[in] size * Buffer size in byte * * @return * Error code ******************************************************************************/ static rt_size_t rt_iic_read ( rt_device_t dev, rt_off_t pos, void* buffer, rt_size_t size) { rt_err_t err_code; rt_size_t read_size; struct efm32_iic_device_t* iic; I2C_TransferSeq_TypeDef seq; I2C_TransferReturn_TypeDef ret; if (!size) { return 0; } err_code = RT_EOK; read_size = 0; iic = (struct efm32_iic_device_t*)dev->user_data; /* Lock device */ if (rt_hw_interrupt_check()) { ret = rt_sem_take(iic->lock, RT_WAITING_NO); } else { ret = rt_sem_take(iic->lock, RT_WAITING_FOREVER); } if (ret != RT_EOK) { return ret; } if (iic->state & IIC_STATE_MASTER) { seq.addr = (rt_uint16_t)pos << 1; seq.flags = I2C_FLAG_WRITE_READ; /* Set register to be read */ seq.buf[0].data = (rt_uint8_t *)buffer; seq.buf[0].len = 1; /* Set read buffer pointer and size */ seq.buf[1].data = (rt_uint8_t *)buffer; seq.buf[1].len = size; /* Do a polled transfer */ iic->timeout = false; rt_timer_stop(iic->timer); rt_timer_start(iic->timer); ret = I2C_TransferInit(iic->iic_device, &seq); while ((ret == i2cTransferInProgress) && !iic->timeout) { ret = I2C_Transfer(iic->iic_device); } if (ret != i2cTransferDone) { iic_debug("IIC read error: %x\n", ret); iic_debug("IIC read address: %x\n", seq.addr); iic_debug("IIC read data0: %x -> %x\n", seq.buf[0].data, *seq.buf[0].data); iic_debug("IIC read len0: %x\n", seq.buf[0].len); iic_debug("IIC read data1: %x -> %x\n", seq.buf[1].data, *seq.buf[1].data); iic_debug("IIC read len1: %x\n", seq.buf[1].len); err_code = (rt_err_t)ret; } else { read_size = size; iic_debug("IIC read size: %d\n", read_size); } } else { rt_uint8_t* ptr; ptr = buffer; /* interrupt mode Rx */ while (size) { rt_base_t level; struct efm32_iic_int_mode_t *int_rx; int_rx = iic->rx_buffer; /* disable interrupt */ level = rt_hw_interrupt_disable(); if (int_rx->read_index != int_rx->save_index) { /* read a character */ *ptr++ = int_rx->data_ptr[int_rx->read_index]; size--; /* move to next position */ int_rx->read_index ++; if (int_rx->read_index >= IIC_RX_BUFFER_SIZE) { int_rx->read_index = 0; } } else { /* set error code */ err_code = -RT_EEMPTY; /* enable interrupt */ rt_hw_interrupt_enable(level); break; } /* enable interrupt */ rt_hw_interrupt_enable(level); } read_size = (rt_uint32_t)ptr - (rt_uint32_t)buffer; iic_debug("IIC slave read size: %d\n", read_size); } /* Unlock device */ rt_sem_release(iic->lock); /* set error code */ rt_set_errno(err_code); return read_size; } /***************************************************************************//** * @brief * Write to IIC device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @param[in] pos * Slave address * * @param[in] buffer * Poniter to the buffer * * @param[in] size * Buffer size in byte * * @return * Error code ******************************************************************************/ static rt_size_t rt_iic_write ( rt_device_t dev, rt_off_t pos, const void* buffer, rt_size_t size) { rt_err_t err_code; rt_size_t write_size; struct efm32_iic_device_t* iic; I2C_TransferSeq_TypeDef seq; I2C_TransferReturn_TypeDef ret; if (!size) { return 0; } err_code = RT_EOK; write_size = 0; iic = (struct efm32_iic_device_t*)dev->user_data; /* Lock device */ if (rt_hw_interrupt_check()) { ret = rt_sem_take(iic->lock, RT_WAITING_NO); } else { ret = rt_sem_take(iic->lock, RT_WAITING_FOREVER); } if (ret != RT_EOK) { return ret; } if (iic->state & IIC_STATE_MASTER) { seq.addr = (rt_uint16_t)pos << 1; seq.flags = I2C_FLAG_WRITE; /* Set write buffer pointer and size */ seq.buf[0].data = (rt_uint8_t *)buffer; seq.buf[0].len = size; } else { // TODO: Slave mode TX } /* Do a polled transfer */ iic->timeout = false; rt_timer_stop(iic->timer); rt_timer_start(iic->timer); ret = I2C_TransferInit(iic->iic_device, &seq); while ((ret == i2cTransferInProgress) && !iic->timeout) { ret = I2C_Transfer(iic->iic_device); } if (ret != i2cTransferDone) { err_code = (rt_err_t)ret; } else { write_size = size; } /* Unlock device */ rt_sem_release(iic->lock); /* set error code */ rt_set_errno(err_code); return write_size; } /***************************************************************************//** * @brief * Configure IIC device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @param[in] cmd * IIC control command * * @param[in] args * Arguments * * @return * Error code ******************************************************************************/ static rt_err_t rt_iic_control ( rt_device_t dev, rt_uint8_t cmd, void *args) { RT_ASSERT(dev != RT_NULL); rt_err_t ret; struct efm32_iic_device_t *iic; iic = (struct efm32_iic_device_t*)dev->user_data; /* Lock device */ if (rt_hw_interrupt_check()) { ret = rt_sem_take(iic->lock, RT_WAITING_NO); } else { ret = rt_sem_take(iic->lock, RT_WAITING_FOREVER); } if (ret != RT_EOK) { return ret; } switch (cmd) { case RT_DEVICE_CTRL_SUSPEND: /* suspend device */ dev->flag |= RT_DEVICE_FLAG_SUSPENDED; I2C_Enable(iic->iic_device, false); break; case RT_DEVICE_CTRL_RESUME: /* resume device */ dev->flag &= ~RT_DEVICE_FLAG_SUSPENDED; I2C_Enable(iic->iic_device, true); break; case RT_DEVICE_CTRL_IIC_SETTING: { /* change device setting */ struct efm32_iic_control_t *control; control = (struct efm32_iic_control_t *)args; iic->state = control->config & (IIC_STATE_MASTER | IIC_STATE_BROADCAST); iic->address = control->address << 1; if (!(iic->state & IIC_STATE_MASTER)) { if (iic->rx_buffer == RT_NULL) { iic->rx_buffer = rt_malloc(sizeof(struct efm32_iic_int_mode_t)); if (iic->rx_buffer == RT_NULL) { iic_debug("no memory for IIC RX structure\n"); return -RT_ENOMEM; } /* Allocate RX buffer */ if ((iic->rx_buffer->data_ptr = \ rt_malloc(IIC_RX_BUFFER_SIZE)) == RT_NULL) { iic_debug("no memory for IIC RX buffer\n"); rt_free(iic->rx_buffer); return -RT_ENOMEM; } rt_memset(iic->rx_buffer->data_ptr, 0, IIC_RX_BUFFER_SIZE); iic->rx_buffer->data_size = IIC_RX_BUFFER_SIZE; iic->rx_buffer->read_index = 0; iic->rx_buffer->save_index = 0; } /* Enable slave mode */ I2C_SlaveAddressSet(iic->iic_device, iic->address); I2C_SlaveAddressMaskSet(iic->iic_device, 0xFF); iic->iic_device->CTRL |= I2C_CTRL_SLAVE | I2C_CTRL_AUTOACK | I2C_CTRL_AUTOSN; /* Enable interrupts */ I2C_IntEnable(iic->iic_device, I2C_IEN_ADDR | I2C_IEN_RXDATAV | I2C_IEN_SSTOP); I2C_IntClear(iic->iic_device, _I2C_IFC_MASK); /* Enable I2Cn interrupt vector in NVIC */ #ifdef RT_USING_IIC0 if (dev == &iic0.device) { NVIC_ClearPendingIRQ(I2C0_IRQn); NVIC_SetPriority(I2C0_IRQn, EFM32_IRQ_PRI_DEFAULT); NVIC_EnableIRQ(I2C0_IRQn); } #endif #ifdef RT_USING_IIC1 if (dev == &iic1.device) { NVIC_ClearPendingIRQ(I2C1_IRQn); NVIC_SetPriority(I2C1_IRQn, EFM32_IRQ_PRI_DEFAULT); NVIC_EnableIRQ(I2C1_IRQn); } #endif } } break; } /* Unlock device */ rt_sem_release(iic->lock); return RT_EOK; } /***************************************************************************//** * @brief * IIC timeout interrupt handler * * @details * * @note * * @param[in] parameter * Parameter ******************************************************************************/ static void rt_iic_timer(void *timeout) { *(rt_bool_t *)timeout = true; } /***************************************************************************//** * @brief * Register IIC device * * @details * * @note * * @param[in] device * Pointer to device descriptor * * @param[in] name * Device name * * @param[in] flag * Configuration flags * * @param[in] iic * Pointer to IIC device descriptor * * @return * Error code ******************************************************************************/ rt_err_t rt_hw_iic_register( rt_device_t device, const char *name, rt_uint32_t flag, struct efm32_iic_device_t *iic) { RT_ASSERT(device != RT_NULL); if ((flag & RT_DEVICE_FLAG_DMA_TX) || (flag & RT_DEVICE_FLAG_DMA_RX) || (flag & RT_DEVICE_FLAG_INT_TX)) { RT_ASSERT(0); } device->type = RT_Device_Class_I2C; device->rx_indicate = RT_NULL; device->tx_complete = RT_NULL; device->init = rt_iic_init; device->open = rt_iic_open; device->close = rt_iic_close; device->read = rt_iic_read; device->write = rt_iic_write; device->control = rt_iic_control; device->user_data = iic; /* register a character device */ return rt_device_register(device, name, RT_DEVICE_FLAG_RDWR | flag); } /***************************************************************************//** * @brief * IIC slave mode RX data valid interrupt handler * * @details * * @note * * @param[in] dev * Pointer to device descriptor ******************************************************************************/ static void rt_hw_iic_slave_isr(rt_device_t dev) { struct efm32_iic_device_t *iic; struct efm32_iic_int_mode_t *int_rx; rt_uint32_t status; volatile rt_uint32_t temp; /* interrupt mode receive */ RT_ASSERT(dev->flag & RT_DEVICE_FLAG_INT_RX); iic = (struct efm32_iic_device_t*)dev->user_data; int_rx = iic->rx_buffer; status = iic->iic_device->IF; if (status & I2C_IF_ADDR) { /* Address Match */ /* Indicating that reception is started */ temp = iic->iic_device->RXDATA & 0xFFUL; if ((temp != 0x00) || (iic->state & IIC_STATE_BROADCAST)) { iic->state |= IIC_STATE_RX_BUSY; } } else if (status & I2C_IF_RXDATAV) { if (iic->state & IIC_STATE_RX_BUSY) { rt_base_t level; /* disable interrupt */ level = rt_hw_interrupt_disable(); /* save character */ int_rx->data_ptr[int_rx->save_index] = \ (rt_uint8_t)(iic->iic_device->RXDATA & 0xFFUL); int_rx->save_index ++; if (int_rx->save_index >= IIC_RX_BUFFER_SIZE) int_rx->save_index = 0; /* if the next position is read index, discard this 'read char' */ if (int_rx->save_index == int_rx->read_index) { int_rx->read_index ++; if (int_rx->read_index >= IIC_RX_BUFFER_SIZE) { int_rx->read_index = 0; } } /* enable interrupt */ rt_hw_interrupt_enable(level); } else { temp = iic->iic_device->RXDATA; } } if(status & I2C_IF_SSTOP) { /* Stop received, reception is ended */ iic->state &= ~(rt_uint8_t)IIC_STATE_RX_BUSY; } } /***************************************************************************//** * @brief * Initialize the specified IIC unit * * @details * * @note * * @param[in] unitNumber * Unit number * * @param[in] location * Pin location number ******************************************************************************/ static struct efm32_iic_device_t *rt_hw_iic_unit_init( struct efm32_iic_block *block, rt_uint8_t unitNumber, rt_uint8_t location) { struct efm32_iic_device_t *iic; CMU_Clock_TypeDef iicClock; I2C_Init_TypeDef init = I2C_INIT_DEFAULT; efm32_irq_hook_init_t hook; rt_uint8_t name[RT_NAME_MAX]; do { /* Allocate device */ iic = rt_malloc(sizeof(struct efm32_iic_device_t)); if (iic == RT_NULL) { iic_debug("IIC: no memory for IIC%d driver\n", unitNumber); break; } iic->counter = 0; iic->timer = &block->timer; iic->timeout = false; iic->state |= IIC_STATE_MASTER; iic->address = 0x0000; iic->rx_buffer = RT_NULL; /* Initialization */ if (unitNumber >= I2C_COUNT) { break; } switch (unitNumber) { case 0: iic->iic_device = I2C0; iicClock = (CMU_Clock_TypeDef)cmuClock_I2C0; break; #if (I2C_COUNT > 1) case 1: iic->iic_device = I2C1; iicClock = (CMU_Clock_TypeDef)cmuClock_I2C1; break; #endif default: break; } rt_sprintf(name, "iic%d", unitNumber); /* Enabling clock */ CMU_ClockEnable(iicClock, true); /* Reset */ I2C_Reset(iic->iic_device); /* Config GPIO */ GPIO_PinModeSet( (GPIO_Port_TypeDef)AF_PORT(AF_I2C_SCL(unitNumber), location), AF_PIN(AF_I2C_SCL(unitNumber), location), gpioModeWiredAndPullUpFilter, 1); GPIO_PinModeSet( (GPIO_Port_TypeDef)AF_PORT(AF_I2C_SDA(unitNumber), location), AF_PIN(AF_I2C_SDA(unitNumber), location), gpioModeWiredAndPullUpFilter, 1); hook.type = efm32_irq_type_iic; hook.unit = unitNumber; hook.cbFunc = rt_hw_iic_slave_isr; hook.userPtr = (void *)&block->device; efm32_irq_hook_register(&hook); /* Enable SDZ and SCL pins and set location */ iic->iic_device->ROUTE = I2C_ROUTE_SDAPEN | I2C_ROUTE_SCLPEN | \ (location << _I2C_ROUTE_LOCATION_SHIFT); /* Initializing IIC */ init.enable = false; I2C_Init(iic->iic_device, &init); /* Abort current TX data and clear TX buffers */ iic->iic_device->CMD = I2C_CMD_ABORT | I2C_CMD_CLEARPC | I2C_CMD_CLEARTX; /* Initialize lock */ iic->lock = &block->lock; if (rt_sem_init(iic->lock, name, 1, RT_IPC_FLAG_FIFO) != RT_EOK) { break; } /* Initialize timer */ rt_timer_init(iic->timer, name, rt_iic_timer, &iic->timeout, IIC_TIMEOUT_PERIOD, RT_TIMER_FLAG_ONE_SHOT); return iic; } while(0); if (iic) { rt_free(iic); } iic_debug("IIC: Unit %d init failed!\n", unitNumber); return RT_NULL; } /***************************************************************************//** * @brief * Initialize all IIC module related hardware and register IIC device to kernel * * @details * * @note ******************************************************************************/ void rt_hw_iic_init(void) { struct efm32_iic_device_t *iic; rt_uint32_t flag; do { flag = RT_DEVICE_FLAG_RDWR | RT_DEVICE_FLAG_INT_RX; #ifdef RT_USING_IIC0 /* Initialize and register iic0 */ if ((iic = rt_hw_iic_unit_init(&iic0, 0, RT_USING_IIC0)) != RT_NULL) { rt_hw_iic_register(&iic0.device, RT_IIC0_NAME, flag, iic); } else { break; } #endif #ifdef RT_USING_IIC1 /* Initialize and register iic1 */ if ((iic = rt_hw_iic_unit_init(&iic1, 1, RT_USING_IIC1)) != RT_NULL) { rt_hw_iic_register(&iic1.device, RT_IIC1_NAME, flag, iic); } else { break; } #endif iic_debug("IIC: H/W init OK!\n"); return; } while (0); rt_kprintf("IIC: H/W init failed!\n"); } #endif /* (defined(RT_USING_IIC0) || defined(RT_USING_IIC1)) */ /***************************************************************************//** * @} ******************************************************************************/