simmel-bootloader/lib/sdk/components/drivers_nrf/uart/nrf_drv_uart.h

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/**
* Copyright (c) 2015 - 2017, Nordic Semiconductor ASA
*
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without modification,
* are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form, except as embedded into a Nordic
* Semiconductor ASA integrated circuit in a product or a software update for
* such product, must reproduce the above copyright notice, this list of
* conditions and the following disclaimer in the documentation and/or other
* materials provided with the distribution.
*
* 3. Neither the name of Nordic Semiconductor ASA nor the names of its
* contributors may be used to endorse or promote products derived from this
* software without specific prior written permission.
*
* 4. This software, with or without modification, must only be used with a
* Nordic Semiconductor ASA integrated circuit.
*
* 5. Any software provided in binary form under this license must not be reverse
* engineered, decompiled, modified and/or disassembled.
*
* THIS SOFTWARE IS PROVIDED BY NORDIC SEMICONDUCTOR ASA "AS IS" AND ANY EXPRESS
* OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY, NONINFRINGEMENT, AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL NORDIC SEMICONDUCTOR ASA OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE
* GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*/
/**@file
* @addtogroup nrf_uart UART driver and HAL
* @ingroup nrf_drivers
* @brief UART API.
* @details The UART driver provides APIs for utilizing the UART peripheral.
*
* @defgroup nrf_drv_uart UART driver
* @{
* @ingroup nrf_uart
*
* @brief UART driver.
*/
#ifndef NRF_DRV_UART_H
#define NRF_DRV_UART_H
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#include "nrf_peripherals.h"
#ifdef UART_PRESENT
#include "nrf_uart.h"
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#endif
#ifdef UARTE_PRESENT
#include "nrf_uarte.h"
#endif
#include "sdk_errors.h"
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#include "sdk_config.h"
#ifdef __cplusplus
extern "C" {
#endif
#ifndef UART1_ENABLED
#define UART1_ENABLED 0
#endif
#ifndef UART0_ENABLED
#define UART0_ENABLED 0
#endif
#define UART0_INSTANCE_INDEX 0
#define UART1_INSTANCE_INDEX UART0_ENABLED
#define UART_ENABLED_COUNT UART0_ENABLED + UART1_ENABLED
#if defined(UARTE_PRESENT) && defined(UART_PRESENT)
#define NRF_DRV_UART_PERIPHERAL(id) \
(CONCAT_3(UART, id, _CONFIG_USE_EASY_DMA) == 1 ? \
(void *)CONCAT_2(NRF_UARTE, id) \
: (void *)CONCAT_2(NRF_UART, id))
#elif defined(UART_PRESENT)
#define NRF_DRV_UART_PERIPHERAL(id) (void *)CONCAT_2(NRF_UART, id)
#else //UARTE_PRESENT !UART_PRESENT
#define NRF_DRV_UART_PERIPHERAL(id) (void *)CONCAT_2(NRF_UARTE, id)
#endif
// This set of macros makes it possible to exclude parts of code, when one type
// of supported peripherals is not used.
#if defined(UARTE_PRESENT) && defined(UART_PRESENT)
#if (UART_EASY_DMA_SUPPORT == 1)
#define UARTE_IN_USE
#endif
#if (UART_LEGACY_SUPPORT == 1)
#define UART_IN_USE
#endif
#if (UART_ENABLED == 1) && ((!defined(UARTE_IN_USE) && !defined(UART_IN_USE)) || ((UART_EASY_DMA_SUPPORT == 0) && (UART_LEGACY_SUPPORT == 0)))
#error "Illegal settings in uart module!"
#endif
#elif defined(UART_PRESENT)
#define UART_IN_USE
#elif defined(UARTE_PRESENT)
#define UARTE_IN_USE
#endif
#if defined(UARTE_PRESENT) && !defined(UART_PRESENT)
typedef nrf_uarte_hwfc_t nrf_uart_hwfc_t;
typedef nrf_uarte_parity_t nrf_uart_parity_t;
typedef nrf_uarte_baudrate_t nrf_uart_baudrate_t;
typedef nrf_uarte_error_mask_t nrf_uart_error_mask_t;
typedef nrf_uarte_task_t nrf_uart_task_t;
typedef nrf_uarte_event_t nrf_uart_event_t;
#ifndef NRF_UART_PSEL_DISCONNECTED
#define NRF_UART_PSEL_DISCONNECTED 0xFFFFFFFF
#endif
#endif
/**
* @brief Structure for the UART driver instance.
*/
typedef struct
{
union
{
#if (defined(UARTE_IN_USE))
NRF_UARTE_Type * p_uarte; ///< Pointer to a structure with UARTE registers.
#endif
#if (defined(UART_IN_USE) || (UART_ENABLED == 0))
NRF_UART_Type * p_uart; ///< Pointer to a structure with UART registers.
#endif
void * p_reg;
} reg;
uint8_t drv_inst_idx; ///< Driver instance index.
} nrf_drv_uart_t;
/**
* @brief Macro for creating an UART driver instance.
*/
#define NRF_DRV_UART_INSTANCE(id) \
{ \
.reg = {NRF_DRV_UART_PERIPHERAL(id)}, \
.drv_inst_idx = CONCAT_3(UART, id, _INSTANCE_INDEX),\
}
/**
* @brief Types of UART driver events.
*/
typedef enum
{
NRF_DRV_UART_EVT_TX_DONE, ///< Requested TX transfer completed.
NRF_DRV_UART_EVT_RX_DONE, ///< Requested RX transfer completed.
NRF_DRV_UART_EVT_ERROR, ///< Error reported by UART peripheral.
} nrf_drv_uart_evt_type_t;
/**@brief Structure for UART configuration. */
typedef struct
{
uint32_t pseltxd; ///< TXD pin number.
uint32_t pselrxd; ///< RXD pin number.
uint32_t pselcts; ///< CTS pin number.
uint32_t pselrts; ///< RTS pin number.
void * p_context; ///< Context passed to interrupt handler.
nrf_uart_hwfc_t hwfc; ///< Flow control configuration.
nrf_uart_parity_t parity; ///< Parity configuration.
nrf_uart_baudrate_t baudrate; ///< Baudrate.
uint8_t interrupt_priority; ///< Interrupt priority.
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#ifdef UARTE_PRESENT
bool use_easy_dma;
#endif
} nrf_drv_uart_config_t;
/**@brief UART default configuration. */
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#ifdef UARTE_PRESENT
#if !UART_LEGACY_SUPPORT
#define DEFAULT_CONFIG_USE_EASY_DMA true
#elif !UART_EASY_DMA_SUPPORT
#define DEFAULT_CONFIG_USE_EASY_DMA false
#else
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#define DEFAULT_CONFIG_USE_EASY_DMA UART0_USE_EASY_DMA
#endif
#define NRF_DRV_UART_DEFAULT_CONFIG \
{ \
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.pseltxd = NRF_UART_PSEL_DISCONNECTED, \
.pselrxd = NRF_UART_PSEL_DISCONNECTED, \
.pselcts = NRF_UART_PSEL_DISCONNECTED, \
.pselrts = NRF_UART_PSEL_DISCONNECTED, \
.p_context = NULL, \
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.hwfc = (nrf_uart_hwfc_t)UART_DEFAULT_CONFIG_HWFC, \
.parity = (nrf_uart_parity_t)UART_DEFAULT_CONFIG_PARITY, \
.baudrate = (nrf_uart_baudrate_t)UART_DEFAULT_CONFIG_BAUDRATE, \
.interrupt_priority = UART_DEFAULT_CONFIG_IRQ_PRIORITY, \
.use_easy_dma = true \
}
#else
#define NRF_DRV_UART_DEFAULT_CONFIG \
{ \
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.pseltxd = NRF_UART_PSEL_DISCONNECTED, \
.pselrxd = NRF_UART_PSEL_DISCONNECTED, \
.pselcts = NRF_UART_PSEL_DISCONNECTED, \
.pselrts = NRF_UART_PSEL_DISCONNECTED, \
.p_context = NULL, \
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.hwfc = (nrf_uart_hwfc_t)UART_DEFAULT_CONFIG_HWFC, \
.parity = (nrf_uart_parity_t)UART_DEFAULT_CONFIG_PARITY, \
.baudrate = (nrf_uart_baudrate_t)UART_DEFAULT_CONFIG_BAUDRATE, \
.interrupt_priority = UART_DEFAULT_CONFIG_IRQ_PRIORITY, \
}
#endif
/**@brief Structure for UART transfer completion event. */
typedef struct
{
uint8_t * p_data; ///< Pointer to memory used for transfer.
uint8_t bytes; ///< Number of bytes transfered.
} nrf_drv_uart_xfer_evt_t;
/**@brief Structure for UART error event. */
typedef struct
{
nrf_drv_uart_xfer_evt_t rxtx; ///< Transfer details includes number of bytes transfered.
uint32_t error_mask;///< Mask of error flags that generated the event.
} nrf_drv_uart_error_evt_t;
/**@brief Structure for UART event. */
typedef struct
{
nrf_drv_uart_evt_type_t type; ///< Event type.
union
{
nrf_drv_uart_xfer_evt_t rxtx; ///< Data provided for transfer completion events.
nrf_drv_uart_error_evt_t error;///< Data provided for error event.
} data;
} nrf_drv_uart_event_t;
/**
* @brief UART interrupt event handler.
*
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* @param[in] p_event Pointer to event structure. Event is allocated on the stack so it is available
* only within the context of the event handler.
* @param[in] p_context Context passed to interrupt handler, set on initialization.
*/
typedef void (*nrf_uart_event_handler_t)(nrf_drv_uart_event_t * p_event, void * p_context);
/**
* @brief Function for initializing the UART driver.
*
* This function configures and enables UART. After this function GPIO pins are controlled by UART.
*
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* @param[in] p_instance Pointer to the driver instance structure.
* @param[in] p_config Initial configuration.
* @param[in] event_handler Event handler provided by the user. If not provided driver works in
* blocking mode.
*
* @retval NRF_SUCCESS If initialization was successful.
* @retval NRF_ERROR_INVALID_STATE If driver is already initialized.
*/
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ret_code_t nrf_drv_uart_init(nrf_drv_uart_t const * p_instance,
nrf_drv_uart_config_t const * p_config,
nrf_uart_event_handler_t event_handler);
/**
* @brief Function for uninitializing the UART driver.
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* @param[in] p_instance Pointer to the driver instance structure.
*/
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void nrf_drv_uart_uninit(nrf_drv_uart_t const * p_instance);
/**
* @brief Function for getting the address of a specific UART task.
*
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* @param[in] p_instance Pointer to the driver instance structure.
* @param[in] task Task.
*
* @return Task address.
*/
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__STATIC_INLINE uint32_t nrf_drv_uart_task_address_get(nrf_drv_uart_t const * p_instance,
nrf_uart_task_t task);
/**
* @brief Function for getting the address of a specific UART event.
*
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* @param[in] p_instance Pointer to the driver instance structure.
* @param[in] event Event.
*
* @return Event address.
*/
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__STATIC_INLINE uint32_t nrf_drv_uart_event_address_get(nrf_drv_uart_t const * p_instance,
nrf_uart_event_t event);
/**
* @brief Function for sending data over UART.
*
* If an event handler was provided in nrf_drv_uart_init() call, this function
* returns immediately and the handler is called when the transfer is done.
* Otherwise, the transfer is performed in blocking mode, i.e. this function
* returns when the transfer is finished. Blocking mode is not using interrupt so
* there is no context switching inside the function.
*
* @note Peripherals using EasyDMA (i.e. UARTE) require that the transfer buffers
* are placed in the Data RAM region. If they are not and UARTE instance is
* used, this function will fail with error code NRF_ERROR_INVALID_ADDR.
*
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* @param[in] p_instance Pointer to the driver instance structure.
* @param[in] p_data Pointer to data.
* @param[in] length Number of bytes to send.
*
* @retval NRF_SUCCESS If initialization was successful.
* @retval NRF_ERROR_BUSY If driver is already transferring.
* @retval NRF_ERROR_FORBIDDEN If the transfer was aborted from a different context
* (blocking mode only, also see @ref nrf_drv_uart_rx_disable).
* @retval NRF_ERROR_INVALID_ADDR If p_data does not point to RAM buffer (UARTE only).
*/
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ret_code_t nrf_drv_uart_tx(nrf_drv_uart_t const * p_instance,
uint8_t const * const p_data, uint8_t length);
/**
* @brief Function for checking if UART is currently transmitting.
*
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* @param[in] p_instance Pointer to the driver instance structure.
*
* @retval true If UART is transmitting.
* @retval false If UART is not transmitting.
*/
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bool nrf_drv_uart_tx_in_progress(nrf_drv_uart_t const * p_instance);
/**
* @brief Function for aborting any ongoing transmission.
* @note @ref NRF_DRV_UART_EVT_TX_DONE event will be generated in non-blocking mode. Event will
* contain number of bytes sent until abort was called. If Easy DMA is not used event will be
* called from the function context. If Easy DMA is used it will be called from UART interrupt
* context.
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*
* @param[in] p_instance Pointer to the driver instance structure.
*/
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void nrf_drv_uart_tx_abort(nrf_drv_uart_t const * p_instance);
/**
* @brief Function for receiving data over UART.
*
* If an event handler was provided in the nrf_drv_uart_init() call, this function
* returns immediately and the handler is called when the transfer is done.
* Otherwise, the transfer is performed in blocking mode, i.e. this function
* returns when the transfer is finished. Blocking mode is not using interrupt so
* there is no context switching inside the function.
* The receive buffer pointer is double buffered in non-blocking mode. The secondary
* buffer can be set immediately after starting the transfer and will be filled
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* when the primary buffer is full. The double buffering feature allows
* receiving data continuously.
*
* @note Peripherals using EasyDMA (i.e. UARTE) require that the transfer buffers
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* are placed in the Data RAM region. If they are not and UARTE driver instance
* is used, this function will fail with error code NRF_ERROR_INVALID_ADDR.
*
* @param[in] p_instance Pointer to the driver instance structure.
* @param[in] p_data Pointer to data.
* @param[in] length Number of bytes to receive.
*
* @retval NRF_SUCCESS If initialization was successful.
* @retval NRF_ERROR_BUSY If the driver is already receiving
* (and the secondary buffer has already been set
* in non-blocking mode).
* @retval NRF_ERROR_FORBIDDEN If the transfer was aborted from a different context
* (blocking mode only, also see @ref nrf_drv_uart_rx_disable).
* @retval NRF_ERROR_INTERNAL If UART peripheral reported an error.
* @retval NRF_ERROR_INVALID_ADDR If p_data does not point to RAM buffer (UARTE only).
*/
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ret_code_t nrf_drv_uart_rx(nrf_drv_uart_t const * p_instance,
uint8_t * p_data, uint8_t length);
/**
* @brief Function for testing the receiver state in blocking mode.
*
* @param[in] p_instance Pointer to the driver instance structure.
*
* @retval true If the receiver has at least one byte of data to get.
* @retval false If the receiver is empty.
*/
bool nrf_drv_uart_rx_ready(nrf_drv_uart_t const * p_instance);
/**
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* @brief Function for enabling the receiver.
*
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* UART has a 6-byte-long RX FIFO and it is used to store incoming data. If a user does not call the
* UART receive function before the FIFO is filled, an overrun error will appear. Enabling the receiver
* without specifying an RX buffer is supported only in UART mode (without Easy DMA). The receiver must be
* explicitly closed by the user @sa nrf_drv_uart_rx_disable. This function asserts if the mode is wrong.
*
* @param[in] p_instance Pointer to the driver instance structure.
*/
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void nrf_drv_uart_rx_enable(nrf_drv_uart_t const * p_instance);
/**
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* @brief Function for disabling the receiver.
*
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* This function must be called to close the receiver after it has been explicitly enabled by
* @sa nrf_drv_uart_rx_enable. The feature is supported only in UART mode (without Easy DMA). The function
* asserts if mode is wrong.
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*
* @param[in] p_instance Pointer to the driver instance structure.
*/
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void nrf_drv_uart_rx_disable(nrf_drv_uart_t const * p_instance);
/**
* @brief Function for aborting any ongoing reception.
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* @note @ref NRF_DRV_UART_EVT_RX_DONE event will be generated in non-blocking mode. The event will
* contain the number of bytes received until abort was called. The event is called from UART interrupt
* context.
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*
* @param[in] p_instance Pointer to the driver instance structure.
*/
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void nrf_drv_uart_rx_abort(nrf_drv_uart_t const * p_instance);
/**
* @brief Function for reading error source mask. Mask contains values from @ref nrf_uart_error_mask_t.
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* @note Function should be used in blocking mode only. In case of non-blocking mode, an error event is
* generated. Function clears error sources after reading.
*
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* @param[in] p_instance Pointer to the driver instance structure.
*
* @retval Mask of reported errors.
*/
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uint32_t nrf_drv_uart_errorsrc_get(nrf_drv_uart_t const * p_instance);
#ifndef SUPPRESS_INLINE_IMPLEMENTATION
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__STATIC_INLINE uint32_t nrf_drv_uart_task_address_get(nrf_drv_uart_t const * p_instance,
nrf_uart_task_t task)
{
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#ifdef UART_IN_USE
return nrf_uart_task_address_get(p_instance->reg.p_uart, task);
#else
return nrf_uarte_task_address_get(p_instance->reg.p_uarte, (nrf_uarte_task_t)task);
#endif
}
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__STATIC_INLINE uint32_t nrf_drv_uart_event_address_get(nrf_drv_uart_t const * p_instance,
nrf_uart_event_t event)
{
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#ifdef UART_IN_USE
return nrf_uart_event_address_get(p_instance->reg.p_uart, event);
#else
return nrf_uarte_event_address_get(p_instance->reg.p_uarte, (nrf_uarte_event_t)event);
#endif
}
#endif //SUPPRESS_INLINE_IMPLEMENTATION
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#ifdef __cplusplus
}
#endif
#endif //NRF_DRV_UART_H
/** @} */